PERLOBJ(1) Perl Programmers Reference Guide PERLOBJ(1)
NAME
perlobj - Perl objects
DESCRIPTION
First you need to understand what references are in Perl. See perlref for that. Second, if you
still find the following reference work too complicated, a tutorial on object-oriented programming in
Perl can be found in perltoot and perltooc.
If you're still with us, then here are three very simple definitions that you should find reassuring.
1. An object is simply a reference that happens to know which class it belongs to.
2. A class is simply a package that happens to provide methods to deal with object references.
3. A method is simply a subroutine that expects an object reference (or a package name, for class
methods) as the first argument.
We'll cover these points now in more depth.
An Object is Simply a Reference
Unlike say C++, Perl doesn't provide any special syntax for constructors. A constructor is merely a
subroutine that returns a reference to something "blessed" into a class, generally the class that the
subroutine is defined in. Here is a typical constructor:
package Critter;
sub new { bless {} }
That word "new" isn't special. You could have written a construct this way, too:
package Critter;
sub spawn { bless {} }
This might even be preferable, because the C++ programmers won't be tricked into thinking that "new"
works in Perl as it does in C++. It doesn't. We recommend that you name your constructors whatever
makes sense in the context of the problem you're solving. For example, constructors in the Tk exten-sion extension
sion to Perl are named after the widgets they create.
One thing that's different about Perl constructors compared with those in C++ is that in Perl, they
have to allocate their own memory. (The other things is that they don't automatically call overrid-den overridden
den base-class constructors.) The "{}" allocates an anonymous hash containing no key/value pairs,
and returns it The bless() takes that reference and tells the object it references that it's now a
Critter, and returns the reference. This is for convenience, because the referenced object itself
knows that it has been blessed, and the reference to it could have been returned directly, like this:
sub new {
my $self = {};
bless $self;
return $self;
}
You often see such a thing in more complicated constructors that wish to call methods in the class as
part of the construction:
sub new {
my $self = {};
bless $self;
$self->initialize();
return $self;
}
If you care about inheritance (and you should; see "Modules: Creation, Use, and Abuse" in perlmod-lib), perlmodlib),
lib), then you want to use the two-arg form of bless so that your constructors may be inherited:
sub new {
my $class = shift;
my $self = {};
bless $self, $class;
$self->initialize();
return $self;
}
Or if you expect people to call not just "CLASS->new()" but also "$obj->new()", then use something
like the following. (Note that using this to call new() on an instance does not automatically per-form perform
form any copying. If you want a shallow or deep copy of an object, you'll have to specifically allow
for that.) The initialize() method used will be of whatever $class we blessed the object into:
sub new {
my $this = shift;
my $class = ref($this) || $this;
my $self = {};
bless $self, $class;
$self->initialize();
return $self;
}
Within the class package, the methods will typically deal with the reference as an ordinary refer-ence. reference.
ence. Outside the class package, the reference is generally treated as an opaque value that may be
accessed only through the class's methods.
Although a constructor can in theory re-bless a referenced object currently belonging to another
class, this is almost certainly going to get you into trouble. The new class is responsible for all
cleanup later. The previous blessing is forgotten, as an object may belong to only one class at a
time. (Although of course it's free to inherit methods from many classes.) If you find yourself
having to do this, the parent class is probably misbehaving, though.
A clarification: Perl objects are blessed. References are not. Objects know which package they
belong to. References do not. The bless() function uses the reference to find the object. Consider
the following example:
$a = {};
$b = $a;
bless $a, BLAH;
print "\$b is a ", ref($b), "\n";
This reports $b as being a BLAH, so obviously bless() operated on the object and not on the refer-ence. reference.
ence.
A Class is Simply a Package
Unlike say C++, Perl doesn't provide any special syntax for class definitions. You use a package as
a class by putting method definitions into the class.
There is a special array within each package called @ISA, which says where else to look for a method
if you can't find it in the current package. This is how Perl implements inheritance. Each element
of the @ISA array is just the name of another package that happens to be a class package. The
classes are searched (depth first) for missing methods in the order that they occur in @ISA. The
classes accessible through @ISA are known as base classes of the current class.
All classes implicitly inherit from class "UNIVERSAL" as their last base class. Several commonly
used methods are automatically supplied in the UNIVERSAL class; see "Default UNIVERSAL methods" for
more details.
If a missing method is found in a base class, it is cached in the current class for efficiency.
Changing @ISA or defining new subroutines invalidates the cache and causes Perl to do the lookup
again.
If neither the current class, its named base classes, nor the UNIVERSAL class contains the requested
method, these three places are searched all over again, this time looking for a method named
AUTOLOAD(). If an AUTOLOAD is found, this method is called on behalf of the missing method, setting
the package global $AUTOLOAD to be the fully qualified name of the method that was intended to be
called.
If none of that works, Perl finally gives up and complains.
If you want to stop the AUTOLOAD inheritance say simply
sub AUTOLOAD;
and the call will die using the name of the sub being called.
Perl classes do method inheritance only. Data inheritance is left up to the class itself. By and
large, this is not a problem in Perl, because most classes model the attributes of their object using
an anonymous hash, which serves as its own little namespace to be carved up by the various classes
that might want to do something with the object. The only problem with this is that you can't sure
that you aren't using a piece of the hash that isn't already used. A reasonable workaround is to
prepend your fieldname in the hash with the package name.
sub bump {
my $self = shift;
$self->{ __PACKAGE__ . ".count"}++;
}
A Method is Simply a Subroutine
Unlike say C++, Perl doesn't provide any special syntax for method definition. (It does provide a
little syntax for method invocation though. More on that later.) A method expects its first argu-ment argument
ment to be the object (reference) or package (string) it is being invoked on. There are two ways of
calling methods, which we'll call class methods and instance methods.
A class method expects a class name as the first argument. It provides functionality for the class
as a whole, not for any individual object belonging to the class. Constructors are often class meth-ods, methods,
ods, but see perltoot and perltooc for alternatives. Many class methods simply ignore their first
argument, because they already know what package they're in and don't care what package they were
invoked via. (These aren't necessarily the same, because class methods follow the inheritance tree
just like ordinary instance methods.) Another typical use for class methods is to look up an object
by name:
sub find {
my ($class, $name) = @_;
$objtable{$name};
}
An instance method expects an object reference as its first argument. Typically it shifts the first
argument into a "self" or "this" variable, and then uses that as an ordinary reference.
sub display {
my $self = shift;
my @keys = @_ ? @_ : sort keys %$self;
foreach $key (@keys) {
print "\t$key => $self->{$key}\n";
}
}
Method Invocation
For various historical and other reasons, Perl offers two equivalent ways to write a method call.
The simpler and more common way is to use the arrow notation:
my $fred = Critter->find("Fred");
$fred->display("Height", "Weight");
You should already be familiar with the use of the "->" operator with references. In fact, since
$fred above is a reference to an object, you could think of the method call as just another form of
dereferencing.
Whatever is on the left side of the arrow, whether a reference or a class name, is passed to the
method subroutine as its first argument. So the above code is mostly equivalent to:
my $fred = Critter::find("Critter", "Fred");
Critter::display($fred, "Height", "Weight");
How does Perl know which package the subroutine is in? By looking at the left side of the arrow,
which must be either a package name or a reference to an object, i.e. something that has been blessed
to a package. Either way, that's the package where Perl starts looking. If that package has no sub-routine subroutine
routine with that name, Perl starts looking for it in any base classes of that package, and so on.
If you need to, you can force Perl to start looking in some other package:
my $barney = MyCritter->Critter::find("Barney");
$barney->Critter::display("Height", "Weight");
Here "MyCritter" is presumably a subclass of "Critter" that defines its own versions of find() and
display(). We haven't specified what those methods do, but that doesn't matter above since we've
forced Perl to start looking for the subroutines in "Critter".
As a special case of the above, you may use the "SUPER" pseudo-class to tell Perl to start looking
for the method in the packages named in the current class's @ISA list.
package MyCritter;
use base 'Critter'; # sets @MyCritter::ISA = ('Critter');
sub display {
my ($self, @args) = @_;
$self->SUPER::display("Name", @args);
}
It is important to note that "SUPER" refers to the superclass(es) of the current package and not to
the superclass(es) of the object. Also, the "SUPER" pseudo-class can only currently be used as a mod-ifier modifier
ifier to a method name, but not in any of the other ways that class names are normally used, eg:
something->SUPER::method(...); # OK
SUPER::method(...); # WRONG
SUPER->method(...); # WRONG
Instead of a class name or an object reference, you can also use any expression that returns either
of those on the left side of the arrow. So the following statement is valid:
Critter->find("Fred")->display("Height", "Weight");
and so is the following:
my $fred = (reverse "rettirC")->find(reverse "derF");
The right side of the arrow typically is the method name, but a simple scalar variable containing
either the method name or a subroutine reference can also be used.
Indirect Object Syntax
The other way to invoke a method is by using the so-called "indirect object" notation. This syntax
was available in Perl 4 long before objects were introduced, and is still used with filehandles like
this:
print STDERR "help!!!\n";
The same syntax can be used to call either object or class methods.
my $fred = find Critter "Fred";
display $fred "Height", "Weight";
Notice that there is no comma between the object or class name and the parameters. This is how Perl
can tell you want an indirect method call instead of an ordinary subroutine call.
But what if there are no arguments? In that case, Perl must guess what you want. Even worse, it
must make that guess at compile time. Usually Perl gets it right, but when it doesn't you get a
function call compiled as a method, or vice versa. This can introduce subtle bugs that are hard to
detect.
For example, a call to a method "new" in indirect notation -- as C++ programmers are wont to make --can -can
can be miscompiled into a subroutine call if there's already a "new" function in scope. You'd end up
calling the current package's "new" as a subroutine, rather than the desired class's method. The
compiler tries to cheat by remembering bareword "require"s, but the grief when it messes up just
isn't worth the years of debugging it will take you to track down such subtle bugs.
There is another problem with this syntax: the indirect object is limited to a name, a scalar vari-able, variable,
able, or a block, because it would have to do too much lookahead otherwise, just like any other post-fix postfix
fix dereference in the language. (These are the same quirky rules as are used for the filehandle
slot in functions like "print" and "printf".) This can lead to horribly confusing precedence prob-lems, problems,
lems, as in these next two lines:
move $obj->{FIELD}; # probably wrong!
move $ary[$i]; # probably wrong!
Those actually parse as the very surprising:
$obj->move->{FIELD}; # Well, lookee here
$ary->move([$i]); # Didn't expect this one, eh?
Rather than what you might have expected:
$obj->{FIELD}->move(); # You should be so lucky.
$ary[$i]->move; # Yeah, sure.
To get the correct behavior with indirect object syntax, you would have to use a block around the
indirect object:
move {$obj->{FIELD}};
move {$ary[$i]};
Even then, you still have the same potential problem if there happens to be a function named "move"
in the current package. The "->" notation suffers from neither of these disturbing ambiguities, so
we recommend you use it exclusively. However, you may still end up having to read code using the
indirect object notation, so it's important to be familiar with it.
Default UNIVERSAL methods
The "UNIVERSAL" package automatically contains the following methods that are inherited by all other
classes:
isa(CLASS)
"isa" returns true if its object is blessed into a subclass of "CLASS"
You can also call "UNIVERSAL::isa" as a subroutine with two arguments. Of course, this will do
the wrong thing if someone has overridden "isa" in a class, so don't do it.
If you need to determine whether you've received a valid invocant, use the "blessed" function
from Scalar::Util:
if (blessed($ref) && $ref->isa( 'Some::Class')) {
# ...
}
"blessed" returns the name of the package the argument has been blessed into, or "undef".
can(METHOD)
"can" checks to see if its object has a method called "METHOD", if it does then a reference to
the sub is returned, if it does not then undef is returned.
"UNIVERSAL::can" can also be called as a subroutine with two arguments. It'll always return
undef if its first argument isn't an object or a class name. The same caveats for calling "UNI-VERSAL::isa" "UNIVERSAL::isa"
VERSAL::isa" directly apply here, too.
VERSION( [NEED] )
"VERSION" returns the version number of the class (package). If the NEED argument is given then
it will check that the current version (as defined by the $VERSION variable in the given package)
not less than NEED; it will die if this is not the case. This method is normally called as a
class method. This method is called automatically by the "VERSION" form of "use".
use A 1.2 qw(some imported subs);
# implies:
A->VERSION(1.2);
NOTE: "can" directly uses Perl's internal code for method lookup, and "isa" uses a very similar
method and cache-ing strategy. This may cause strange effects if the Perl code dynamically changes
@ISA in any package.
You may add other methods to the UNIVERSAL class via Perl or XS code. You do not need to "use UNI-VERSAL" UNIVERSAL"
VERSAL" to make these methods available to your program (and you should not do so).
Destructors
When the last reference to an object goes away, the object is automatically destroyed. (This may
even be after you exit, if you've stored references in global variables.) If you want to capture
control just before the object is freed, you may define a DESTROY method in your class. It will
automatically be called at the appropriate moment, and you can do any extra cleanup you need to do.
Perl passes a reference to the object under destruction as the first (and only) argument. Beware
that the reference is a read-only value, and cannot be modified by manipulating $_[0] within the
destructor. The object itself (i.e. the thingy the reference points to, namely "${$_[0]}",
"@{$_[0]}", "%{$_[0]}" etc.) is not similarly constrained.
Since DESTROY methods can be called at unpredictable times, it is important that you localise any
global variables that the method may update. In particular, localise $@ if you use "eval {}" and
localise $? if you use "system" or backticks.
If you arrange to re-bless the reference before the destructor returns, perl will again call the
DESTROY method for the re-blessed object after the current one returns. This can be used for clean
delegation of object destruction, or for ensuring that destructors in the base classes of your choos-ing choosing
ing get called. Explicitly calling DESTROY is also possible, but is usually never needed.
Do not confuse the previous discussion with how objects CONTAINED in the current one are destroyed.
Such objects will be freed and destroyed automatically when the current object is freed, provided no
other references to them exist elsewhere.
Summary
That's about all there is to it. Now you need just to go off and buy a book about object-oriented
design methodology, and bang your forehead with it for the next six months or so.
Two-Phased Garbage Collection
For most purposes, Perl uses a fast and simple, reference-based garbage collection system. That
means there's an extra dereference going on at some level, so if you haven't built your Perl exe-cutable executable
cutable using your C compiler's "-O" flag, performance will suffer. If you have built Perl with "cc
-O", then this probably won't matter.
A more serious concern is that unreachable memory with a non-zero reference count will not normally
get freed. Therefore, this is a bad idea:
{
my $a;
$a = \$a;
}
Even thought $a should go away, it can't. When building recursive data structures, you'll have to
break the self-reference yourself explicitly if you don't care to leak. For example, here's a self-referential selfreferential
referential node such as one might use in a sophisticated tree structure:
sub new_node {
my $class = shift;
my $node = {};
$node->{LEFT} = $node->{RIGHT} = $node;
$node->{DATA} = [ @_ ];
return bless $node => $class;
}
If you create nodes like that, they (currently) won't go away unless you break their self reference
yourself. (In other words, this is not to be construed as a feature, and you shouldn't depend on
it.)
Almost.
When an interpreter thread finally shuts down (usually when your program exits), then a rather costly
but complete mark-and-sweep style of garbage collection is performed, and everything allocated by
that thread gets destroyed. This is essential to support Perl as an embedded or a multithreadable
language. For example, this program demonstrates Perl's two-phased garbage collection:
#!/usr/bin/perl
package Subtle;
sub new {
my $test;
$test = \$test;
warn "CREATING " . \$test;
return bless \$test;
}
sub DESTROY {
my $self = shift;
warn "DESTROYING $self";
}
package main;
warn "starting program";
{
my $a = Subtle->new;
my $b = Subtle->new;
$$a = 0; # break selfref
warn "leaving block";
}
warn "just exited block";
warn "time to die...";
exit;
When run as /foo/test, the following output is produced:
starting program at /foo/test line 18.
CREATING SCALAR(0x8e5b8) at /foo/test line 7.
CREATING SCALAR(0x8e57c) at /foo/test line 7.
leaving block at /foo/test line 23.
DESTROYING Subtle=SCALAR(0x8e5b8) at /foo/test line 13.
just exited block at /foo/test line 26.
time to die... at /foo/test line 27.
DESTROYING Subtle=SCALAR(0x8e57c) during global destruction.
Notice that "global destruction" bit there? That's the thread garbage collector reaching the
unreachable.
Objects are always destructed, even when regular refs aren't. Objects are destructed in a separate
pass before ordinary refs just to prevent object destructors from using refs that have been them-selves themselves
selves destructed. Plain refs are only garbage-collected if the destruct level is greater than 0.
You can test the higher levels of global destruction by setting the PERL_DESTRUCT_LEVEL environment
variable, presuming "-DDEBUGGING" was enabled during perl build time. See "PERL_DESTRUCT_LEVEL" in
perlhack for more information.
A more complete garbage collection strategy will be implemented at a future date.
In the meantime, the best solution is to create a non-recursive container class that holds a pointer
to the self-referential data structure. Define a DESTROY method for the containing object's class
that manually breaks the circularities in the self-referential structure.
SEE ALSO
A kinder, gentler tutorial on object-oriented programming in Perl can be found in perltoot, perlboot
and perltooc. You should also check out perlbot for other object tricks, traps, and tips, as well as
perlmodlib for some style guides on constructing both modules and classes.
perl v5.8.8 2006-01-07 PERLOBJ(1)
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