376 lines
16 KiB
Plaintext
376 lines
16 KiB
Plaintext
=head1 NAME
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perlmod - Perl modules (packages and symbol tables)
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=head1 DESCRIPTION
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=head2 Packages
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Perl provides a mechanism for alternative namespaces to protect packages
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from stomping on each other's variables. In fact, there's really no such
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thing as a global variable in Perl (although some identifiers default
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to the main package instead of the current one). The package statement
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declares the compilation unit as
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being in the given namespace. The scope of the package declaration
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is from the declaration itself through the end of the enclosing block,
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C<eval>, C<sub>, or end of file, whichever comes first (the same scope
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as the my() and local() operators). All further unqualified dynamic
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identifiers will be in this namespace. A package statement only affects
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dynamic variables--including those you've used local() on--but
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I<not> lexical variables created with my(). Typically it would be
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the first declaration in a file to be included by the C<require> or
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C<use> operator. You can switch into a package in more than one place;
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it merely influences which symbol table is used by the compiler for the
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rest of that block. You can refer to variables and filehandles in other
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packages by prefixing the identifier with the package name and a double
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colon: C<$Package::Variable>. If the package name is null, the C<main>
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package is assumed. That is, C<$::sail> is equivalent to C<$main::sail>.
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The old package delimiter was a single quote, but double colon is now the
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preferred delimiter, in part because it's more readable to humans, and
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in part because it's more readable to B<emacs> macros. It also makes C++
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programmers feel like they know what's going on--as opposed to using the
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single quote as separator, which was there to make Ada programmers feel
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like they knew what's going on. Because the old-fashioned syntax is still
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supported for backwards compatibility, if you try to use a string like
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C<"This is $owner's house">, you'll be accessing C<$owner::s>; that is,
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the $s variable in package C<owner>, which is probably not what you meant.
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Use braces to disambiguate, as in C<"This is ${owner}'s house">.
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Packages may be nested inside other packages: C<$OUTER::INNER::var>. This
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implies nothing about the order of name lookups, however. All symbols
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are either local to the current package, or must be fully qualified
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from the outer package name down. For instance, there is nowhere
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within package C<OUTER> that C<$INNER::var> refers to C<$OUTER::INNER::var>.
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It would treat package C<INNER> as a totally separate global package.
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Only identifiers starting with letters (or underscore) are stored in a
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package's symbol table. All other symbols are kept in package C<main>,
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including all of the punctuation variables like $_. In addition, when
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unqualified, the identifiers STDIN, STDOUT, STDERR, ARGV, ARGVOUT, ENV,
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INC, and SIG are forced to be in package C<main>, even when used for other
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purposes than their builtin one. Note also that, if you have a package
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called C<m>, C<s>, or C<y>, then you can't use the qualified form of an
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identifier because it will be interpreted instead as a pattern match,
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a substitution, or a transliteration.
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(Variables beginning with underscore used to be forced into package
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main, but we decided it was more useful for package writers to be able
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to use leading underscore to indicate private variables and method names.
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$_ is still global though.)
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Eval()ed strings are compiled in the package in which the eval() was
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compiled. (Assignments to C<$SIG{}>, however, assume the signal
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handler specified is in the C<main> package. Qualify the signal handler
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name if you wish to have a signal handler in a package.) For an
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example, examine F<perldb.pl> in the Perl library. It initially switches
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to the C<DB> package so that the debugger doesn't interfere with variables
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in the script you are trying to debug. At various points, however, it
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temporarily switches back to the C<main> package to evaluate various
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expressions in the context of the C<main> package (or wherever you came
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from). See L<perldebug>.
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The special symbol C<__PACKAGE__> contains the current package, but cannot
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(easily) be used to construct variables.
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See L<perlsub> for other scoping issues related to my() and local(),
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and L<perlref> regarding closures.
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=head2 Symbol Tables
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The symbol table for a package happens to be stored in the hash of that
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name with two colons appended. The main symbol table's name is thus
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C<%main::>, or C<%::> for short. Likewise symbol table for the nested
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package mentioned earlier is named C<%OUTER::INNER::>.
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The value in each entry of the hash is what you are referring to when you
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use the C<*name> typeglob notation. In fact, the following have the same
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effect, though the first is more efficient because it does the symbol
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table lookups at compile time:
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local *main::foo = *main::bar;
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local $main::{foo} = $main::{bar};
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You can use this to print out all the variables in a package, for
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instance. The standard F<dumpvar.pl> library and the CPAN module
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Devel::Symdump make use of this.
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Assignment to a typeglob performs an aliasing operation, i.e.,
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*dick = *richard;
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causes variables, subroutines, formats, and file and directory handles
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accessible via the identifier C<richard> also to be accessible via the
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identifier C<dick>. If you want to alias only a particular variable or
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subroutine, you can assign a reference instead:
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*dick = \$richard;
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Which makes $richard and $dick the same variable, but leaves
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@richard and @dick as separate arrays. Tricky, eh?
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This mechanism may be used to pass and return cheap references
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into or from subroutines if you won't want to copy the whole
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thing. It only works when assigning to dynamic variables, not
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lexicals.
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%some_hash = (); # can't be my()
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*some_hash = fn( \%another_hash );
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sub fn {
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local *hashsym = shift;
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# now use %hashsym normally, and you
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# will affect the caller's %another_hash
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my %nhash = (); # do what you want
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return \%nhash;
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}
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On return, the reference will overwrite the hash slot in the
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symbol table specified by the *some_hash typeglob. This
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is a somewhat tricky way of passing around references cheaply
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when you won't want to have to remember to dereference variables
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explicitly.
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Another use of symbol tables is for making "constant" scalars.
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*PI = \3.14159265358979;
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Now you cannot alter $PI, which is probably a good thing all in all.
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This isn't the same as a constant subroutine, which is subject to
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optimization at compile-time. This isn't. A constant subroutine is one
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prototyped to take no arguments and to return a constant expression.
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See L<perlsub> for details on these. The C<use constant> pragma is a
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convenient shorthand for these.
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You can say C<*foo{PACKAGE}> and C<*foo{NAME}> to find out what name and
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package the *foo symbol table entry comes from. This may be useful
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in a subroutine that gets passed typeglobs as arguments:
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sub identify_typeglob {
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my $glob = shift;
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print 'You gave me ', *{$glob}{PACKAGE}, '::', *{$glob}{NAME}, "\n";
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}
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identify_typeglob *foo;
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identify_typeglob *bar::baz;
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This prints
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You gave me main::foo
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You gave me bar::baz
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The *foo{THING} notation can also be used to obtain references to the
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individual elements of *foo, see L<perlref>.
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=head2 Package Constructors and Destructors
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There are two special subroutine definitions that function as package
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constructors and destructors. These are the C<BEGIN> and C<END>
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routines. The C<sub> is optional for these routines.
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A C<BEGIN> subroutine is executed as soon as possible, that is, the moment
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it is completely defined, even before the rest of the containing file
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is parsed. You may have multiple C<BEGIN> blocks within a file--they
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will execute in order of definition. Because a C<BEGIN> block executes
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immediately, it can pull in definitions of subroutines and such from other
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files in time to be visible to the rest of the file. Once a C<BEGIN>
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has run, it is immediately undefined and any code it used is returned to
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Perl's memory pool. This means you can't ever explicitly call a C<BEGIN>.
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An C<END> subroutine is executed as late as possible, that is, when
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the interpreter is being exited, even if it is exiting as a result of
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a die() function. (But not if it's polymorphing into another program
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via C<exec>, or being blown out of the water by a signal--you have to
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trap that yourself (if you can).) You may have multiple C<END> blocks
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within a file--they will execute in reverse order of definition; that is:
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last in, first out (LIFO).
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Inside an C<END> subroutine, C<$?> contains the value that the script is
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going to pass to C<exit()>. You can modify C<$?> to change the exit
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value of the script. Beware of changing C<$?> by accident (e.g. by
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running something via C<system>).
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Note that when you use the B<-n> and B<-p> switches to Perl, C<BEGIN> and
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C<END> work just as they do in B<awk>, as a degenerate case. As currently
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implemented (and subject to change, since its inconvenient at best),
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both C<BEGIN> I<and> C<END> blocks are run when you use the B<-c> switch
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for a compile-only syntax check, although your main code is not.
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=head2 Perl Classes
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There is no special class syntax in Perl, but a package may function
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as a class if it provides subroutines to act as methods. Such a
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package may also derive some of its methods from another class (package)
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by listing the other package name in its global @ISA array (which
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must be a package global, not a lexical).
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For more on this, see L<perltoot> and L<perlobj>.
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=head2 Perl Modules
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A module is just a package that is defined in a library file of
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the same name, and is designed to be reusable. It may do this by
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providing a mechanism for exporting some of its symbols into the symbol
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table of any package using it. Or it may function as a class
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definition and make its semantics available implicitly through method
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calls on the class and its objects, without explicit exportation of any
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symbols. Or it can do a little of both.
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For example, to start a normal module called Some::Module, create
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a file called Some/Module.pm and start with this template:
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package Some::Module; # assumes Some/Module.pm
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use strict;
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BEGIN {
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use Exporter ();
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use vars qw($VERSION @ISA @EXPORT @EXPORT_OK %EXPORT_TAGS);
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# set the version for version checking
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$VERSION = 1.00;
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# if using RCS/CVS, this may be preferred
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$VERSION = do { my @r = (q$Revision: 2.21 $ =~ /\d+/g); sprintf "%d."."%02d" x $#r, @r }; # must be all one line, for MakeMaker
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@ISA = qw(Exporter);
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@EXPORT = qw(&func1 &func2 &func4);
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%EXPORT_TAGS = ( ); # eg: TAG => [ qw!name1 name2! ],
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# your exported package globals go here,
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# as well as any optionally exported functions
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@EXPORT_OK = qw($Var1 %Hashit &func3);
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}
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use vars @EXPORT_OK;
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# non-exported package globals go here
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use vars qw(@more $stuff);
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# initalize package globals, first exported ones
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$Var1 = '';
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%Hashit = ();
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# then the others (which are still accessible as $Some::Module::stuff)
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$stuff = '';
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@more = ();
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# all file-scoped lexicals must be created before
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# the functions below that use them.
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# file-private lexicals go here
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my $priv_var = '';
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my %secret_hash = ();
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# here's a file-private function as a closure,
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# callable as &$priv_func; it cannot be prototyped.
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my $priv_func = sub {
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# stuff goes here.
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};
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# make all your functions, whether exported or not;
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# remember to put something interesting in the {} stubs
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sub func1 {} # no prototype
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sub func2() {} # proto'd void
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sub func3($$) {} # proto'd to 2 scalars
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# this one isn't exported, but could be called!
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sub func4(\%) {} # proto'd to 1 hash ref
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END { } # module clean-up code here (global destructor)
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Then go on to declare and use your variables in functions
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without any qualifications.
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See L<Exporter> and the L<perlmodlib> for details on
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mechanics and style issues in module creation.
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Perl modules are included into your program by saying
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use Module;
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or
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use Module LIST;
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This is exactly equivalent to
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BEGIN { require Module; import Module; }
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or
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BEGIN { require Module; import Module LIST; }
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As a special case
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use Module ();
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is exactly equivalent to
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BEGIN { require Module; }
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All Perl module files have the extension F<.pm>. C<use> assumes this so
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that you don't have to spell out "F<Module.pm>" in quotes. This also
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helps to differentiate new modules from old F<.pl> and F<.ph> files.
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Module names are also capitalized unless they're functioning as pragmas,
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"Pragmas" are in effect compiler directives, and are sometimes called
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"pragmatic modules" (or even "pragmata" if you're a classicist).
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The two statements:
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require SomeModule;
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require "SomeModule.pm";
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differ from each other in two ways. In the first case, any double
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colons in the module name, such as C<Some::Module>, are translated
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into your system's directory separator, usually "/". The second
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case does not, and would have to be specified literally. The other difference
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is that seeing the first C<require> clues in the compiler that uses of
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indirect object notation involving "SomeModule", as in C<$ob = purge SomeModule>,
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are method calls, not function calls. (Yes, this really can make a difference.)
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Because the C<use> statement implies a C<BEGIN> block, the importation
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of semantics happens at the moment the C<use> statement is compiled,
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before the rest of the file is compiled. This is how it is able
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to function as a pragma mechanism, and also how modules are able to
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declare subroutines that are then visible as list operators for
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the rest of the current file. This will not work if you use C<require>
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instead of C<use>. With require you can get into this problem:
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require Cwd; # make Cwd:: accessible
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$here = Cwd::getcwd();
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use Cwd; # import names from Cwd::
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$here = getcwd();
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require Cwd; # make Cwd:: accessible
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$here = getcwd(); # oops! no main::getcwd()
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In general, C<use Module ()> is recommended over C<require Module>,
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because it determines module availability at compile time, not in the
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middle of your program's execution. An exception would be if two modules
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each tried to C<use> each other, and each also called a function from
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that other module. In that case, it's easy to use C<require>s instead.
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Perl packages may be nested inside other package names, so we can have
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package names containing C<::>. But if we used that package name
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directly as a filename it would makes for unwieldy or impossible
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filenames on some systems. Therefore, if a module's name is, say,
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C<Text::Soundex>, then its definition is actually found in the library
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file F<Text/Soundex.pm>.
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Perl modules always have a F<.pm> file, but there may also be dynamically
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linked executables or autoloaded subroutine definitions associated with
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the module. If so, these will be entirely transparent to the user of
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the module. It is the responsibility of the F<.pm> file to load (or
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arrange to autoload) any additional functionality. The POSIX module
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happens to do both dynamic loading and autoloading, but the user can
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say just C<use POSIX> to get it all.
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For more information on writing extension modules, see L<perlxstut>
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and L<perlguts>.
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=head1 SEE ALSO
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See L<perlmodlib> for general style issues related to building Perl
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modules and classes as well as descriptions of the standard library and
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CPAN, L<Exporter> for how Perl's standard import/export mechanism works,
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L<perltoot> for an in-depth tutorial on creating classes, L<perlobj>
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for a hard-core reference document on objects, and L<perlsub> for an
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explanation of functions and scoping.
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