perlmod - Perl modules |
perlmod - Perl modules (packages and symbol tables)
Perl provides a mechanism for alternative namespaces to protect
packages from stomping on each other's variables. In fact, there's
really no such thing as a global variable in Perl. The package
statement declares the compilation unit as being in the given
namespace. The scope of the package declaration is from the
declaration itself through the end of the enclosing block, eval
,
or file, whichever comes first (the same scope as the my()
and
local()
operators). Unqualified dynamic identifiers will be in
this namespace, except for those few identifiers that if unqualified,
default to the main package instead of the current one as described
below. A package statement affects only dynamic variables--including
those you've used local()
on--but not lexical variables created
with my(). Typically it would be the first declaration in a file
included by the do
, require
, or use
operators. You can
switch into a package in more than one place; it merely influences
which symbol table is used by the compiler for the rest of that
block. You can refer to variables and filehandles in other packages
by prefixing the identifier with the package name and a double
colon: $Package::Variable
. If the package name is null, the
main
package is assumed. That is, $::sail
is equivalent to
$main::sail
.
The old package delimiter was a single quote, but double colon is now the
preferred delimiter, in part because it's more readable to humans, and
in part because it's more readable to emacs macros. It also makes C++
programmers feel like they know what's going on--as opposed to using the
single quote as separator, which was there to make Ada programmers feel
like they knew what was going on. Because the old-fashioned syntax is still
supported for backwards compatibility, if you try to use a string like
"This is $owner's house"
, you'll be accessing $owner::s
; that is,
the $s variable in package owner
, which is probably not what you meant.
Use braces to disambiguate, as in "This is ${owner}'s house"
.
Packages may themselves contain package separators, as in
$OUTER::INNER::var
. This implies nothing about the order of
name lookups, however. There are no relative packages: all symbols
are either local to the current package, or must be fully qualified
from the outer package name down. For instance, there is nowhere
within package OUTER
that $INNER::var
refers to
$OUTER::INNER::var
. INNER
refers to a totally
separate global package.
Only identifiers starting with letters (or underscore) are stored
in a package's symbol table. All other symbols are kept in package
main
, including all punctuation variables, like $_. In addition,
when unqualified, the identifiers STDIN, STDOUT, STDERR, ARGV,
ARGVOUT, ENV, INC, and SIG are forced to be in package main
,
even when used for other purposes than their built-in ones. If you
have a package called m
, s
, or y
, then you can't use the
qualified form of an identifier because it would be instead interpreted
as a pattern match, a substitution, or a transliteration.
Variables beginning with underscore used to be forced into package
main, but we decided it was more useful for package writers to be able
to use leading underscore to indicate private variables and method names.
However, variables and functions named with a single _
, such as
$_ and sub _
, are still forced into the package main
. See also
Technical Note on the Syntax of Variable Names in the perlvar manpage.
eval
ed strings are compiled in the package in which the eval()
was
compiled. (Assignments to $SIG{}
, however, assume the signal
handler specified is in the main
package. Qualify the signal handler
name if you wish to have a signal handler in a package.) For an
example, examine perldb.pl in the Perl library. It initially switches
to the DB
package so that the debugger doesn't interfere with variables
in the program you are trying to debug. At various points, however, it
temporarily switches back to the main
package to evaluate various
expressions in the context of the main
package (or wherever you came
from). See the perldebug manpage.
The special symbol __PACKAGE__
contains the current package, but cannot
(easily) be used to construct variable names.
See the perlsub manpage for other scoping issues related to my()
and local(),
and the perlref manpage regarding closures.
The symbol table for a package happens to be stored in the hash of that
name with two colons appended. The main symbol table's name is thus
%main::
, or %::
for short. Likewise the symbol table for the nested
package mentioned earlier is named %OUTER::INNER::
.
The value in each entry of the hash is what you are referring to when you
use the *name
typeglob notation. In fact, the following have the same
effect, though the first is more efficient because it does the symbol
table lookups at compile time:
local *main::foo = *main::bar; local $main::{foo} = $main::{bar};
(Be sure to note the vast difference between the second line above
and local $main::foo = $main::bar
. The former is accessing the hash
%main::
, which is the symbol table of package main
. The latter is
simply assigning scalar $bar
in package main
to scalar $foo
of
the same package.)
You can use this to print out all the variables in a package, for instance. The standard but antiquated dumpvar.pl library and the CPAN module Devel::Symdump make use of this.
Assignment to a typeglob performs an aliasing operation, i.e.,
*dick = *richard;
causes variables, subroutines, formats, and file and directory handles
accessible via the identifier richard
also to be accessible via the
identifier dick
. If you want to alias only a particular variable or
subroutine, assign a reference instead:
*dick = \$richard;
Which makes $richard and $dick the same variable, but leaves @richard and @dick as separate arrays. Tricky, eh?
There is one subtle difference between the following statements:
*foo = *bar; *foo = \$bar;
*foo = *bar
makes the typeglobs themselves synonymous while
*foo = \$bar
makes the SCALAR portions of two distinct typeglobs
refer to the same scalar value. This means that the following code:
$bar = 1; *foo = \$bar; # Make $foo an alias for $bar
{ local $bar = 2; # Restrict changes to block print $foo; # Prints '1'! }
Would print '1', because $foo
holds a reference to the original
$bar
-- the one that was stuffed away by local()
and which will be
restored when the block ends. Because variables are accessed through the
typeglob, you can use *foo = *bar
to create an alias which can be
localized. (But be aware that this means you can't have a separate
@foo
and @bar
, etc.)
What makes all of this important is that the Exporter module uses glob aliasing as the import/export mechanism. Whether or not you can properly localize a variable that has been exported from a module depends on how it was exported:
@EXPORT = qw($FOO); # Usual form, can't be localized @EXPORT = qw(*FOO); # Can be localized
You can work around the first case by using the fully qualified name
($Package::FOO
) where you need a local value, or by overriding it
by saying *FOO = *Package::FOO
in your script.
The *x = \$y
mechanism may be used to pass and return cheap references
into or from subroutines if you don't want to copy the whole
thing. It only works when assigning to dynamic variables, not
lexicals.
%some_hash = (); # can't be my() *some_hash = fn( \%another_hash ); sub fn { local *hashsym = shift; # now use %hashsym normally, and you # will affect the caller's %another_hash my %nhash = (); # do what you want return \%nhash; }
On return, the reference will overwrite the hash slot in the symbol table specified by the *some_hash typeglob. This is a somewhat tricky way of passing around references cheaply when you don't want to have to remember to dereference variables explicitly.
Another use of symbol tables is for making ``constant'' scalars.
*PI = \3.14159265358979;
Now you cannot alter $PI
, which is probably a good thing all in all.
This isn't the same as a constant subroutine, which is subject to
optimization at compile-time. A constant subroutine is one prototyped
to take no arguments and to return a constant expression. See
the perlsub manpage for details on these. The use constant
pragma is a
convenient shorthand for these.
You can say *foo{PACKAGE}
and *foo{NAME}
to find out what name and
package the *foo symbol table entry comes from. This may be useful
in a subroutine that gets passed typeglobs as arguments:
sub identify_typeglob { my $glob = shift; print 'You gave me ', *{$glob}{PACKAGE}, '::', *{$glob}{NAME}, "\n"; } identify_typeglob *foo; identify_typeglob *bar::baz;
This prints
You gave me main::foo You gave me bar::baz
The *foo{THING}
notation can also be used to obtain references to the
individual elements of *foo. See the perlref manpage.
Subroutine definitions (and declarations, for that matter) need not necessarily be situated in the package whose symbol table they occupy. You can define a subroutine outside its package by explicitly qualifying the name of the subroutine:
package main; sub Some_package::foo { ... } # &foo defined in Some_package
This is just a shorthand for a typeglob assignment at compile time:
BEGIN { *Some_package::foo = sub { ... } }
and is not the same as writing:
{ package Some_package; sub foo { ... } }
In the first two versions, the body of the subroutine is lexically in the main package, not in Some_package. So something like this:
package main;
$Some_package::name = "fred"; $main::name = "barney";
sub Some_package::foo { print "in ", __PACKAGE__, ": \$name is '$name'\n"; }
Some_package::foo();
prints:
in main: $name is 'barney'
rather than:
in Some_package: $name is 'fred'
This also has implications for the use of the SUPER:: qualifier (see the perlobj manpage).
Four special subroutines act as package constructors and destructors.
These are the BEGIN
, CHECK
, INIT
, and END
routines. The
sub
is optional for these routines.
A BEGIN
subroutine is executed as soon as possible, that is, the moment
it is completely defined, even before the rest of the containing file
is parsed. You may have multiple BEGIN
blocks within a file--they
will execute in order of definition. Because a BEGIN
block executes
immediately, it can pull in definitions of subroutines and such from other
files in time to be visible to the rest of the file. Once a BEGIN
has run, it is immediately undefined and any code it used is returned to
Perl's memory pool. This means you can't ever explicitly call a BEGIN
.
An END
subroutine is executed as late as possible, that is, after
perl has finished running the program and just before the interpreter
is being exited, even if it is exiting as a result of a die()
function.
(But not if it's polymorphing into another program via exec
, or
being blown out of the water by a signal--you have to trap that yourself
(if you can).) You may have multiple END
blocks within a file--they
will execute in reverse order of definition; that is: last in, first
out (LIFO). END
blocks are not executed when you run perl with the
-c
switch, or if compilation fails.
Inside an END
subroutine, $?
contains the value that the program is
going to pass to exit()
. You can modify $?
to change the exit
value of the program. Beware of changing $?
by accident (e.g. by
running something via system
).
CHECK
and INIT
blocks are useful to catch the transition between
the compilation phase and the execution phase of the main program.
CHECK
blocks are run just after the Perl compile phase ends and before
the run time begins, in LIFO order. CHECK
blocks are used in
the Perl compiler suite to save the compiled state of the program.
INIT
blocks are run just before the Perl runtime begins execution, in
``first in, first out'' (FIFO) order. For example, the code generators
documented in perlcc make use of INIT
blocks to initialize and
resolve pointers to XSUBs.
When you use the -n and -p switches to Perl, BEGIN
and
END
work just as they do in awk, as a degenerate case.
Both BEGIN
and CHECK
blocks are run when you use the -c
switch for a compile-only syntax check, although your main code
is not.
There is no special class syntax in Perl, but a package may act
as a class if it provides subroutines to act as methods. Such a
package may also derive some of its methods from another class (package)
by listing the other package name(s)
in its global @ISA array (which
must be a package global, not a lexical).
For more on this, see the perltoot manpage and the perlobj manpage.
A module is just a set of related functions in a library file, i.e., a Perl package with the same name as the file. It is specifically designed to be reusable by other modules or programs. It may do this by providing a mechanism for exporting some of its symbols into the symbol table of any package using it, or it may function as a class definition and make its semantics available implicitly through method calls on the class and its objects, without explicitly exporting anything. Or it can do a little of both.
For example, to start a traditional, non-OO module called Some::Module, create a file called Some/Module.pm and start with this template:
package Some::Module; # assumes Some/Module.pm
use strict; use warnings;
BEGIN { use Exporter (); our ($VERSION, @ISA, @EXPORT, @EXPORT_OK, %EXPORT_TAGS);
# set the version for version checking $VERSION = 1.00; # if using RCS/CVS, this may be preferred $VERSION = sprintf "%d.%03d", q$Revision: 1.1 $ =~ /(\d+)/g;
@ISA = qw(Exporter); @EXPORT = qw(&func1 &func2 &func4); %EXPORT_TAGS = ( ); # eg: TAG => [ qw!name1 name2! ],
# your exported package globals go here, # as well as any optionally exported functions @EXPORT_OK = qw($Var1 %Hashit &func3); } our @EXPORT_OK;
# exported package globals go here our $Var1; our %Hashit;
# non-exported package globals go here our @more; our $stuff;
# initialize package globals, first exported ones $Var1 = ''; %Hashit = ();
# then the others (which are still accessible as $Some::Module::stuff) $stuff = ''; @more = ();
# all file-scoped lexicals must be created before # the functions below that use them.
# file-private lexicals go here my $priv_var = ''; my %secret_hash = ();
# here's a file-private function as a closure, # callable as &$priv_func; it cannot be prototyped. my $priv_func = sub { # stuff goes here. };
# make all your functions, whether exported or not; # remember to put something interesting in the {} stubs sub func1 {} # no prototype sub func2() {} # proto'd void sub func3($$) {} # proto'd to 2 scalars
# this one isn't exported, but could be called! sub func4(\%) {} # proto'd to 1 hash ref
END { } # module clean-up code here (global destructor)
## YOUR CODE GOES HERE
1; # don't forget to return a true value from the file
Then go on to declare and use your variables in functions without any qualifications. See the Exporter manpage and the the perlmodlib manpage for details on mechanics and style issues in module creation.
Perl modules are included into your program by saying
use Module;
or
use Module LIST;
This is exactly equivalent to
BEGIN { require Module; import Module; }
or
BEGIN { require Module; import Module LIST; }
As a special case
use Module ();
is exactly equivalent to
BEGIN { require Module; }
All Perl module files have the extension .pm. The use
operator
assumes this so you don't have to spell out ``Module.pm'' in quotes.
This also helps to differentiate new modules from old .pl and
.ph files. Module names are also capitalized unless they're
functioning as pragmas; pragmas are in effect compiler directives,
and are sometimes called ``pragmatic modules'' (or even ``pragmata''
if you're a classicist).
The two statements:
require SomeModule; require "SomeModule.pm";
differ from each other in two ways. In the first case, any double
colons in the module name, such as Some::Module
, are translated
into your system's directory separator, usually ``/''. The second
case does not, and would have to be specified literally. The other
difference is that seeing the first require
clues in the compiler
that uses of indirect object notation involving ``SomeModule'', as
in $ob = purge SomeModule
, are method calls, not function calls.
(Yes, this really can make a difference.)
Because the use
statement implies a BEGIN
block, the importing
of semantics happens as soon as the use
statement is compiled,
before the rest of the file is compiled. This is how it is able
to function as a pragma mechanism, and also how modules are able to
declare subroutines that are then visible as list or unary operators for
the rest of the current file. This will not work if you use require
instead of use
. With require
you can get into this problem:
require Cwd; # make Cwd:: accessible $here = Cwd::getcwd();
use Cwd; # import names from Cwd:: $here = getcwd();
require Cwd; # make Cwd:: accessible $here = getcwd(); # oops! no main::getcwd()
In general, use Module ()
is recommended over require Module
,
because it determines module availability at compile time, not in the
middle of your program's execution. An exception would be if two modules
each tried to use
each other, and each also called a function from
that other module. In that case, it's easy to use require
instead.
Perl packages may be nested inside other package names, so we can have
package names containing ::
. But if we used that package name
directly as a filename it would make for unwieldy or impossible
filenames on some systems. Therefore, if a module's name is, say,
Text::Soundex
, then its definition is actually found in the library
file Text/Soundex.pm.
Perl modules always have a .pm file, but there may also be
dynamically linked executables (often ending in .so) or autoloaded
subroutine definitions (often ending in .al) associated with the
module. If so, these will be entirely transparent to the user of
the module. It is the responsibility of the .pm file to load
(or arrange to autoload) any additional functionality. For example,
although the POSIX module happens to do both dynamic loading and
autoloading, the user can say just use POSIX
to get it all.
Since 5.6.0, Perl has had support for a new type of threads called interpreter threads (ithreads). These threads can be used explicitly and implicitly.
Ithreads work by cloning the data tree so that no data is shared
between different threads. These threads can be used by using the threads
module or by doing fork()
on win32 (fake fork()
support). When a
thread is cloned all Perl data is cloned, however non-Perl data cannot
be cloned automatically. Perl after 5.7.2 has support for the CLONE
special subroutine . In CLONE
you can do whatever you need to do,
like for example handle the cloning of non-Perl data, if necessary.
CLONE
will be executed once for every package that has it defined
(or inherits it). It will be called in the context of the new thread,
so all modifications are made in the new area.
If you want to CLONE all objects you will need to keep track of them per package. This is simply done using a hash and Scalar::Util::weaken().
See the perlmodlib manpage for general style issues related to building Perl modules and classes, as well as descriptions of the standard library and CPAN, the Exporter manpage for how Perl's standard import/export mechanism works, the perltoot manpage and the perltooc manpage for an in-depth tutorial on creating classes, the perlobj manpage for a hard-core reference document on objects, the perlsub manpage for an explanation of functions and scoping, and the perlxstut manpage and the perlguts manpage for more information on writing extension modules.
perlmod - Perl modules |