"Class::Prototyped" - Fast prototype-based OO programming in Perl
use strict;
use Class::Prototyped ':EZACCESS';
$, = ' '; $\ = "\n";
my $p = Class::Prototyped->new(
field1 => 123,
sub1 => sub { print "this is sub1 in p" },
sub2 => sub { print "this is sub2 in p" }
);
$p->sub1;
print $p->field1;
$p->field1('something new');
print $p->field1;
my $p2 = Class::Prototyped->new(
'parent*' => $p,
field2 => 234,
sub2 => sub { print "this is sub2 in p2" }
);
$p2->sub1;
$p2->sub2;
print ref($p2), $p2->field1, $p2->field2;
$p2->field1('and now for something different');
print ref($p2), $p2->field1;
$p2->addSlots( sub1 => sub { print "this is sub1 in p2" } );
$p2->sub1;
print ref($p2), "has slots", $p2->reflect->slotNames;
$p2->reflect->include( 'xx.pl' ); # includes xx.pl in $p2's package
print ref($p2), "has slots", $p2->reflect->slotNames;
$p2->aa(); # calls aa from included file xx.pl
$p2->deleteSlots('sub1');
$p2->sub1;
This package provides for efficient and simple prototype-based programming in
Perl. You can provide different subroutines for each object, and also have
objects inherit their behavior and state from another object.
The structure of an object is inspected and modified through
mirrors,
which are created by calling "reflect" on an object or class that
inherits from "Class::Prototyped".
This module requires "Module::Build 0.24" to use the automated
installation procedures. With "Module::Build" installed:
Build.PL
perl build test
perl build install
It can be installed under ActivePerl for Win32 by downloading the PPM from CPAN
(the file has the extension ".ppm.zip"). To install, download the
".ppm.zip" file, uncompress it, and execute:
ppm install Class-Prototyped.ppd
The module can also be installed manually by copying
"lib/Class/Prototyped.pm" to
"perl/site/lib/Class/Prototyped.pm" (along with "Graph.pm"
if you want it).
When I reach for "Class::Prototyped", it's generally because I really
need it. When the cleanest way of solving a problem is for the code that uses
a module to subclass from it, that is generally a sign that
"Class::Prototyped" would be of use. If you find yourself avoiding
the problem by passing anonymous subroutines as parameters to the
"new" method, that's another good sign that you should be using
prototype based programming. If you find yourself storing anonymous
subroutines in databases, configuration files, or text files, and then writing
infrastructure to handle calling those anonymous subroutines, that's yet
another sign. When you expect the people using your module to want to change
the behavior, override subroutines, and so forth, that's a sign.
"Class::Prototyped" borrows very strongly from the language Self (see
http://www.sun.com/research/self for more information). The core concept in
Self is the concept of a slot. Think of slots as being entries in a hash,
except that instead of just pointing to data, they can point to objects, code,
or parent objects.
So what happens when you send a message to an object (that is to say, you make a
method call on the object)? First, Perl looks for that slot in the object. If
it can't find that slot in the object, it searches for that slot in one of the
object's parents (which we'll come back to later). Once it finds the slot, if
the slot is a block of code, it evaluates the code and returns the return
value. If the slot references data, it returns that data. If you assign to a
data slot (through a method call), it modifies the data.
Distinguishing data slots and method slots is easy - the latter are references
to code blocks, the former are not. Distinguishing parent slots is not so
easy, so instead a simple naming convention is used. If the name of the slot
ends in an asterisk, the slot is a parent slot. If you have programmed in
Self, this naming convention will feel very familiar.
In Self, to examine the structure of an object, you use a mirror. Just like
using his shield as a mirror enabled Perseus to slay Medusa, holding up a
mirror enables us to look upon an object's structure without name space
collisions.
Once you have a mirror, you can add and delete slots like so:
my $cp = Class::Prototyped->new();
my $mirror = $cp->reflect();
$mirror->addSlots(
field1 => 'foo',
sub1 => sub {
print "this is sub1 printing field1: '".$_[0]->field1."'\n";
},
);
$mirror->deleteSlot('sub1');
In addition, there is a more verbose syntax for "addSlots" where the
slot name is replaced by an anonymous array - this is most commonly used to
control the slot attributes.
$cp->reflect->addSlot(
[qw(field1 FIELD)] => 'foo',
[qw(sub1 METHOD)] => sub { print "hi there.\n"; },
);
Because the mirror methods "super",
"addSlot"("s"), "deleteSlot"("s"), and
"getSlot"("s") are called frequently on objects, there is
an import keyword ":EZACCESS" that adds methods to the object space
that call the appropriate reflected variants.
Slot attributes allow the user to specify additional information and behavior
relating to a specific slot in an extensible manner. For instance, one might
want to mark a specific field slot as constant or to attach a description to a
given slot.
Slot attributes are divided up in two ways. The first is by the type of slot -
"FIELD", "METHOD", or "PARENT". Some slot
attributes apply to all three, some to just two, and some to only one. The
second division is on the type of slot attribute:
- implementor
- These are responsible for implementing the behavior of a
slot. An example is a "FIELD" slot with the attribute
"constant". A slot is only allowed one implementor. All slot
types have a default implementor. For "FIELD" slots, it is a
read-write scalar. For "METHOD" slots, it is the passed
anonymous subroutine. For "PARENT" slots,
"implementor" and "filter" slot attributes don't
really make sense.
- filter
- These filter access to the "implementor". The
quintessential example is the "profile" attribute. When set,
this increments a counter in $Class::Prototyped::Mirror::PROFILE::counts
every time the underlying "FIELD" or "METHOD" is
accessed. Filter attributes can be stacked, so each attribute is assigned
a rank with lower values being closer to the "implementor" and
higher values being closer to the caller.
- advisory
- These slot attributes serve one of two purposes. They can
be used to store information about the slot (i.e. "description"
attributes), and they can be used to pass information to the
"addSlots" method (i.e. the "promote" attribute, which
can be used to promote a new "PARENT" slot ahead of all the
existing "PARENT" slots).
There is currently no formal interface for creating your own attributes - if you
feel the need for new attributes, please contact the maintainer first to see
if it might make sense to add the new attribute to
"Class::Prototyped". If not, the contact might provide enough
impetus to define a formal interface. The attributes are currently defined in
$Class::Prototyped::Mirror::attributes.
Finally, see the "defaultAttributes" method for information about
setting default attributes. This can be used, for instance, to turn on
profiling everywhere.
In Self, everything is an object and there are no classes at all. Perl, for
better or worse, has a class system based on packages. We decided that it
would be better not to throw out the conventional way of structuring
inheritance hierarchies, so in "Class::Prototyped", classes are
first-class objects.
However, objects are not first-class classes. To understand this dichotomy, we
need to understand that there is a difference between the way
"classes" and the way "objects" are expected to behave.
The central difference is that "classes" are expected to persist
whether or not that are any references to them. If you create a class, the
class exists whether or not it appears in anyone's @ISA and whether or not
there are any objects in it. Once a class is created, it persists until the
program terminates.
Objects, on the other hand, should follow the normal behaviors of
reference-counted destruction - once the number of references to them drops to
zero, they should miraculously disappear - the memory they used needs to be
returned to Perl, their "DESTROY" methods need to be called, and so
forth.
Since we don't require this behavior of classes, it's easy to have a way to get
from a package name to an object - we simply stash the object that implements
the class in $Class::Prototyped::Mirror::objects{$package}. But we can't do
this for objects, because if we do the object will persist forever because
that reference will always exist.
Weak references would solve this problem, but weak references are still
considered alpha and unsupported ("$WeakRef::VERSION = 0.01"), and
we didn't want to make "Class::Prototyped" dependent on such a
module.
So instead, we differentiate between classes and objects. In a nutshell, if an
object has an explicit package name (
i.e. something other than the
auto-generated one), it is considered to be a class, which means it persists
even if the object goes out of scope.
To create such an object, use the "newPackage" method, like so (the
encapsulating block exists solely to demonstrate that classes are not scoped):
{
my $object = Class::Prototyped->newPackage('MyClass',
field => 1,
double => sub {$_[0]->field*2}
);
}
print MyClass->double,"\n";
Notice that the class persists even though $object goes out of scope. If $object
were created with an auto-generated package, that would not be true. Thus, for
instance, it would be a
very, very, very bad idea to add the package
name of an object as a parent to another object - when the first object goes
out of scope, the package will disappear, but the second object will still
have it in it's @ISA.
Except for the crucial difference that you should
never, ever, ever make
use of the package name for an object for any purpose other than printing it
to the screen, objects and classes are simply different ways of inspecting the
same entity.
To go from an object to a package, you can do one of the following:
$package = ref($object);
$package = $object->reflect->package;
The two are equivalent, although the first is much faster. Just remember, if
$object is in an auto-generated package, don't do anything with that $package
but print it.
To go from a package to an object, you do this:
$object = $package->reflect->object;
Note that $package is simple the name of the package - the following code works
perfectly:
$object = MyClass->reflect->object;
But keep in mind that $package has to be a class, not an auto-generated package
name for an object.
This lets us have tons of fun manipulating classes at run time. For instance, if
you wanted to add, at run-time, a new method to the "MyClass" class?
Assuming that the "MyClass" inherits from
"Class::Prototyped" or that you have specified ":REFLECT"
on the "use Class::Prototyped" call, you simply write:
MyClass->reflect->addSlot(myMethod => sub {print "Hi there\n"});
If you want to access a class that doesn't inherit from
"Class::Prototyped", and you want to avoid specifying
":REFLECT" (which adds "reflect" to the
"UNIVERSAL" package), you can make the call like so:
my $mirror = Class::Prototyped::Mirror->new('MyClass');
$mirror->addSlot(myMethod => sub {print "Hi there\n"});
Just as you can "clone" objects, you can "clone" classes
that are derived from "Class::Prototyped". This creates a new object
that has a copy of all of the slots that were defined in the class. Note that
if you simply want to be able to use "Data::Dumper" on a class,
calling "MyClass->reflect->object" is the preferred approach.
Even easier would be to use the "dump" mirror method.
The code that implements reflection on classes automatically creates slot names
for package methods as well as parent slots for the entries in @ISA. This
means that you can code classes like you normally do - by doing the
inheritance in @ISA and writing package methods.
If you manually add subroutines to a package at run-time and want the slot
information updated properly (although this really should be done via the
"addSlots" mechanism, but maybe you're twisted:), you should do
something like:
$package->reflect->_vivified_methods(0);
$package->reflect->_autovivify_methods;
Adding parent slots is no different than adding normal slots - the naming scheme
takes care of differentiating.
Thus, to add $foo as a parent to $bar, you write:
$bar->reflect->addSlot('fooParent*' => $foo);
However, keeping with our concept of classes as first class objects, you can
also write the following:
$bar->reflect->addSlot('mixIn*' => 'MyMix::Class');
It will automatically require the module in the namespace of $bar and make the
module a parent of the object. This can load a module from disk if needed.
If you're lazy, you can add parents without names like so:
$bar->reflect->addSlot('*' => $foo);
The slots will be automatically named for the package passed in - in the case of
"Class::Prototyped" objects, the package is of the form
"PKG0x12345678". In the following example, the parent slot will be
named "MyMix::Class*".
$bar->reflect->addSlot('*' => 'MyMix::Class');
Parent slots are added to the inheritance hierarchy in the order that they were
added. Thus, in the following code, slots that don't exist in $foo are looked
up in $fred (and all of its parent slots) before being looked up in $jill.
$foo->reflect->addSlots('fred*' => $fred, 'jill*' => $jill);
Note that "addSlot" and "addSlots" are identical - the
variants exist only because it looks ugly to add a single slot by calling
"addSlots".
If you need to reorder the parent slots on an object, look at
"promoteParents". That said, there's a shortcut for prepending a
slot to the inheritance hierarchy. Simply define 'promote' as a slot attribute
using the extended slot syntax.
Finally, in keeping with our principle that classes are first-class object, the
inheritance hierarchy of classes can be modified through "addSlots"
and "deleteSlots", just like it can for objects. The following code
adds the $foo object as a parent of the "MyClass" class, prepending
it to the inheritance hierarchy:
MyClass->reflect->addSlots([qw(foo* promote)] => $foo);
In "Class::Prototyped", you do operator overloading by adding slots
with the right name. First, when you do the "use" on
"Class::Prototyped", make sure to pass in ":OVERLOAD" so
that the operator overloading support is enabled.
Then simply pass the desired methods in as part of the object creation like so:
$foo = Class::Prototyped->new(
value => 3,
'""' => sub { my $self = shift; $self->value( $self->value + 1 ) },
);
This creates an object that increments its field "value" by one and
returns that incremented value whenever it is stringified.
Since there is no way to find out which operators are overloaded, if you add
overloading to a
class through the use of "use overload",
that behavior will not show up as slots when reflecting on the class. However,
"addSlots"
does work for adding operator overloading to
classes. Thus, the following code does what is expected:
Class::Prototyped->newPackage('MyClass');
MyClass->reflect->addSlots(
'""' => sub { my $self = shift; $self->value( $self->value + 1 ) },
);
$foo = MyClass->new( value => 2 );
print $foo, "\n";
The special parent slot "class*" is used to indicate object class.
When you create "Class::Prototyped" objects by calling
"Class::Prototyped->new()", the "class*" slot is
not set. If, however, you create objects by calling "new" on
a class or object that inherits from "Class::Prototyped", the slot
"class*" points to the package name if "new" was called on
a named class, or the object if "new" was called on an object.
The value of this slot can be returned quite easily like so:
$foo->reflect->class;
Methods (and fields) inherited from prototypes or classes are
not
generally available using the usual Perl
"$self->SUPER::something()" mechanism.
The reason for this is that "SUPER::something" is hardcoded to the
package in which the subroutine (anonymous or otherwise) was defined. For the
vast majority of programs, this will be "main::", and thus
"SUPER::" will look in @main::ISA (not a very useful place to look).
To get around this, a very clever wrapper can be automatically placed around
your subroutine that will automatically stash away the package to which the
subroutine is attached. From within the subroutine, you can use the
"super" mirror method to make an inherited call. However, because
we'd rather not write code that attempts to guess as to whether or not the
subroutine uses the "super" construct, you have to tell
"addSlots" that the subroutine needs to have this wrapper placed
around it. To do this, simply use the extended "addSlots" syntax
(see the method description for more information) and pass in the slot
attribute 'superable'. The following examples use the minimalist form of the
extended syntax.
For instance, the following code will work:
use Class::Prototyped;
my $p1 = Class::Prototyped->new(
method => sub { print "this is method in p1\n" },
);
my $p2 = Class::Prototyped->new(
'*' => $p1,
[qw(method superable)]' => sub {
print "this is method in p2 calling method in p1: ";
$_[0]->reflect->super('method');
},
);
To make things easier, if you specify ":EZACCESS" during the import,
"super" can be called directly on an object rather than through its
mirror.
The other thing of which you need to be aware is copying methods from one object
to another. The proper way to do this is like so:
$foo->reflect->addSlot($bar->reflect->getSlot('method'));
When the "getSlot" method is called in an array context, it returns
both the complete format for the slot identifier and the slot. This ensures
that slot attributes are passed along, including the "superable"
attribute.
Finally, to help protect the code, the "super" method is smart enough
to determine whether it was called within a wrapped subroutine. If it wasn't,
it croaks indicating that the method should have had the "superable"
attribute set when it was added. If you wish to disable this checking (which
will improve the performance of your code, of course, but could result in
very hard to trace bugs if you haven't been careful), see the import
option ":SUPER_FAST".
It is important to be aware of where the boundaries of prototyped based
programming lie, especially in a language like Perl that is not optimized for
it. For instance, it might make sense to implement every field in a database
as an object. Those field objects would in turn be attached to a record class.
All of those might be implemented using "Class::Prototyped".
However, it would be very inefficient if every record that got read from the
database was stored in a "Class::Prototyped" based object (unless,
of course, you are storing code in the database). In that situation, it is
generally good to choke off the prototype-based behavior for the individual
record objects. For best performance, it is important to confine
"Class::Prototyped" to those portions of the code where behavior is
mutable from outside of the module. See the documentation for the
"new" method of "Class::Prototyped" for more information
about choking off "Class::Prototyped" behavior.
There are a number of performance hits when using "Class::Prototyped",
relative to using more traditional OO code.
It is important to note
that these generally lie in the instantiation and creation of classes and
objects and not in the actual use of them. The scripts in the "perf"
directory were designed for benchmarking some of this material.
The normal way of creating a class is like this:
package Pack_123;
sub a {"hi";}
sub b {"hi";}
sub c {"hi";}
sub d {"hi";}
sub e {"hi";}
The most efficient way of doing that using "proper"
"Class::Prototyped" methodology looks like this:
Class::Prototyped->newPackage("Pack_123");
push(@P_123::slots, a => sub {"hi";});
push(@P_123::slots, b => sub {"hi";});
push(@P_123::slots, c => sub {"hi";});
push(@P_123::slots, d => sub {"hi";});
push(@P_123::slots, e => sub {"hi";});
Pack_123->reflect->addSlots(@P_123::slots);
This approach ensures that the new package gets the proper default attributes
and that the slots are created through "addSlots", thus ensuring
that default attributes are properly implemented. It avoids multiple calls to
"->reflect->addSlot", though, which improves performance. The
idea behind pushing the slots onto an array is that it enables one to
intersperse code with POD, since POD is not permitted inside of a single Perl
statement.
On a Pent 4 1.8GHz machine, the normal code runs in 120 usec, whereas the
"Class::Prototyped" code runs in around 640 usec, or over 5 times
slower. A straight call to "addSlots" with all five methods runs in
around 510 usec. Code that creates the package and the mirror without adding
slots runs in around 135 usec, so we're looking at an overhead of less than
100 usec per slot. In a situation where the "compile" time dominates
the "execution" time (I'm using those terms loosely as much of what
happens in "Class::Prototyped" is technically execution time, but it
is activity that traditionally would happen at compile time),
"Class::Prototyped" might prove to be too much overhead. On the
otherhand, you may find that demand loading can cut much of that overhead and
can be implemented less painfully than might otherwise be thought.
There is no need to even compare here. Blessing a hash into a class takes less
than 2 usec. Creating a new "Class::Prototyped" object takes at
least 60 or 70 times longer. The trick is to avoid creating unnecessary
"Class::Prototyped" objects. If you know that all 10,000 database
records are going to inherit all of their behavior from the parent class,
there is no point in creating 10,000 packages and all the attendant overhead.
The "new" method for "Class::Prototyped" demonstrates how
to ensure that those state objects are created as normal Perl objects.
The good news is that method calls are just as fast as normal Perl method calls,
inherited or not. This is because the existing Perl OO machinery has been
hijacked in "Class::Prototyped". The exception to this is if
"filter" slot attributes have been used, including
"wantarray", "superable", and "profile". In that
situation, the added overhead is that for a normal Perl subroutine call (which
is faster than a method call because it is a static binding)
The hash interface is not particularly fast, and neither is it good programming
practice. Using the method interface to access fields is just as fast,
however, as using normal getter/setter methods.
- ":OVERLOAD"
- This configures the support in
"Class::Prototyped" for using operator overloading.
- ":REFLECT"
- This defines "UNIVERSAL::reflect" to return a
mirror for any class. With a mirror, you can manipulate the class, adding
or deleting methods, changing its inheritance hierarchy, etc.
- ":EZACCESS"
- This adds the methods "addSlot",
"addSlots", "deleteSlot", "deleteSlots",
"getSlot", "getSlots", and "super" to
"Class::Prototyped".
This lets you write:
$foo->addSlot(myMethod => sub {print "Hi there\n"});
instead of having to write:
$foo->reflect->addSlot(myMethod => sub {print "Hi there\n"});
The other methods in "Class::Prototyped::Mirror" should be
accessed through a mirror (otherwise you'll end up with way too much name
space pollution for your objects:).
Note that it is bad form for published modules to use ":EZACCESS"
as you are polluting everyone else's namespace as well. If you
really want ":EZACCESS" for code you plan to publish,
contact the maintainer and we'll see what we can about creating a variant
of ":EZACCESS" that adds the shortcut methods to a single class.
Note that using ":EZACCESS" to do "$obj->addSlot()"
is actually slower than doing
"$obj->reflect->addSlot()".
- ":SUPER_FAST"
- Switches over to the fast version of "super" that
doesn't check to see whether slots that use inherited calls were defined
as superable.
- ":NEW_MAIN"
- Creates a "new" function in "main::"
that creates new "Class::Prototyped" objects. Thus, you can
write code like:
use Class::Prototyped qw(:NEW_MAIN :EZACCESS);
my $foo = new(say_hi => sub {print "Hi!\n";});
$foo->say_hi;
- ":TIED_INTERFACE"
- This is no longer supported. Sorry for the very short
notice - if you have a specific need, please let me know and I will
discuss your needs with you and determine whether they can be addressed in
a manner that doesn't require you to rewrite your code, but still allows
others to make use of less global control over the tied interfaces used.
See "Class::Prototyped::Mirror::tiedInterfacePackage" for the
preferred way of doing this.
A new object is created. If this is called on a class or object that inherits
from "Class::Prototyped", and "class*" is not being passed
as a slot in the argument list, the slot "class*" will be the first
element in the inheritance list.
When called on named classes, either via the package name or via the object
(i.e. "MyPackage->reflect->object()"), "class*" is
set to the package name. When called on an object, "class*" is set
to the object on which "new" was called.
The passed arguments are handed off to "addSlots".
Note that "new" calls "newCore", so if you want to override
"new", but want to ensure that your changes are applicable to
"newPackage", "clone", and "clonePackage", you
may wish to override "newCore".
For instance, the following will define a new "Class::Prototyped"
object with two method slots and one field slot:
my $foo = Class::Prototyped->new(
field1 => 123,
sub1 => sub { print "this is sub1 in foo" },
sub2 => sub { print "this is sub2 in foo" },
);
The following will create a new "MyClass" object with one field slot
and with the parent object $bar at the beginning of the inheritance hierarchy
(just before "class*", which points to "MyClass"):
my $foo = MyClass->new(
field1 => 123,
[qw(bar* promote)] => $bar,
);
The following will create a new object that inherits behavior from $bar with one
field slot, "field1", and one parent slot, "class*", that
points to $bar.
my $foo = $bar->new(
field1 => 123,
);
If you want to create normal Perl objects as child objects of a
"Class::Prototyped" class in order to improve performance, implement
your own standard Perl "new" method:
Class::Prototyped->newPackage('MyClass');
MyClass->reflect->addSlot(
new => sub {
my $class = shift;
my $self = {};
bless $self, $class;
return $self;
}
);
It is still safe to use "$obj->reflect->super()" in code that
runs on such an object. All other reflection will automatically return the
same results as inspecting the class to which the object belongs.
Just like "new", but instead of creating the new object with an
arbitrary package name (actually, not entirely arbitrary - it's generally
based on the hash memory address), the first argument is used as the name of
the package. This creates a named class. The same behavioral rules for
"class*" described above for "new" apply to
"newPackage" (in fact, "new" calls
"newPackage").
If the package name is already in use, this method will croak.
Duplicates an existing object or class and allows you to add or override slots.
The slot definition is the same as in
new().
my $p2 = $p1->clone(
sub1 => sub { print "this is sub1 in p2" },
);
It calls "newCore" to create the new object*, so if you have
overridden "new", you should contemplate overriding
"clone" in order to ensure that behavioral changes made to
"new" that would be applicable to "clone" are implemented.
Or simply override "newCore".
Just like "clone", but instead of creating the new object with an
arbitrary package name (actually, not entirely arbitrary - it's generally
based on the hash memory address), the first argument is used as the name of
the package. This creates a named class.
If the package name is already in use, this method will croak.
This implements the core functionality involved in creating a new object. The
first passed parameter will be the name of the caller - either
"new", "newPackage", "clone", or
"clonePackage". The second parameter is the name of the package if
applicable (i.e. for "newPackage" and "clonePackage")
calls, "undef" if inapplicable. The remainder of the parameters are
any slots to be added to the newly created object/package.
If called with "new" or "newPackage", the "class*"
slot will be prepended to the slot list if applicable. If called with
"clone" or "clonePackage", all slots on the receiver will
be prepended to the slot list.
If you wish to add behavior to object instantiation that needs to be present in
all four of the instantiators (i.e. instance tracking), it may make sense to
override "newCore" so that you implement the code in only one place.
The structure of an object is modified by using a mirror. This is the equivalent
of calling:
Class::Prototyped::Mirror->new($foo);
You should never need to call this method. However, you may want to override it.
Because we had to directly specify "DESTROY" for every object in
order to allow safe destruction during global destruction time when objects
may have already destroyed packages in their @ISA, we had to hook
"DESTROY" for every object. To allow the "destroy"
behavior to be overridden, users should specify a "destroy" method
for their objects (by adding the slot), which will automatically be called by
the "Class::Prototyped::DESTROY" method after the @ISA has been
cleaned up.
This method should be defined to allow inherited method calls (
i.e.
should use ""[qw(destroy superable)]"" to define the
method) and should call "$self->reflect->super('destroy');" at
some point in the code.
Here is a quick overview of the default destruction behavior for objects:
- •
- "Class::Prototyped::DESTROY" is called because it
is linked into the package for all objects at instantiation time
- •
- All no longer existent entries are stripped from @ISA
- •
- The inheritance hierarchy is searched for a
"DESTROY" method that is not
"Class::Prototyped::DESTROY". This "DESTROY" method is
stashed away for a later call.
- •
- The inheritance hierarchy is searched for a
"destroy" method and it is called. Note that the
"Class::Prototyped::destroy" method, which will either be called
directly because it shows up in the inheritance hierarchy or will be
called indirectly through calls to
"$self->reflect->super('destroy');", will delete all
non-parent slots from the object. It leaves parent slots alone because the
destructors for the parent slots should not be called until such time as
the destruction of the object in question is complete (otherwise inherited
destructors might still be executing, even though the object to which they
belong has already been destroyed). This means that the destructors for
objects referenced in non-parent slots may be called, temporarily
interrupting the execution sequence in
"Class::Prototyped::destroy".
- •
- The previously stashed "DESTROY" method is
called.
- •
- The parent slots for the object are finally removed, thus
enabling the destructors for any objects referenced in those parent slots
to run.
- •
- Final "Class::Prototyped" specific cleanup is
run.
These are the methods you can call on the mirror returned from a
"reflect" call. If you specify ":EZACCESS" in the
"use Class::Prototyped" line, "addSlot",
"addSlots", "deleteSlot", "deleteSlots",
"getSlot", "getSlots", and "super" will be
callable on "Class::Prototyped" objects as well.
Normally called via the "reflect" method, this can be called directly
to avoid using the ":REFLECT" import option for reflecting on non
"Class::Prototyped" based classes.
If you add an "AUTOLOAD" slot to an object, you will need to get the
name of the subroutine being called. "autoloadCall()" returns the
name of the subroutine, with the package name stripped off.
Allows you to add or replace slot definitions in the receiver.
$p->reflect->addSlots(
fred => 'this is fred',
doSomething => sub { print 'doing something with ' . $_[1] },
);
$p->doSomething( $p->fred );
In addition to the simple form, there is an extended syntax for specifying the
slot. In place of the slotname, pass an array reference composed like so:
"addSlots( [$slotName, $slotType, %slotAttributes] => $slotValue
);"
$slotName is simply the name of the slot, including the trailing "*"
if it is a parent slot. $slotType should be 'FIELD', 'METHOD', or 'PARENT'.
%slotAttributes should be a list of attribute/value pairs. It is common to use
qw() to reduce the amount of typing:
$p->reflect->addSlot(
[qw(bar FIELD)] => "this is a field",
);
$p->reflect->addSlot(
[qw(bar FIELD constant 1)] => "this is a constant field",
);
$p->reflect->addSlot(
[qw(foo METHOD)] => sub { print "normal method.\n"; },
);
$p->reflect->addSlot(
[qw(foo METHOD superable 1)] => sub { print "superable method.\n"; },
);
$p->reflect->addSlot(
[qw(parent* PARENT)] => $parent,
);
$p->reflect->addSlot(
[qw(parent2* PARENT promote 1)] => $parent2,
);
To make using the extended syntax a bit less cumbersome, however, the following
shortcuts are allowed:
- •
- $slotType can be omitted. In this case, the slot's type
will be determined by inspecting the slot's name (to determine if it is a
parent slot) and the slot's value (to determine whether it is a field or
method slot). The $slotType value can, however, be used to supply a
reference to a code object as the value for a field slot. Note that this
means that "FIELD", "METHOD", and "PARENT"
are not legal attribute names (since this would make parsing
difficult).
- •
- If there is only one attribute and if the value is 1, then
the value can be omitted.
Using both of the above contractions, the following are valid short forms for
the extended syntax:
$p->reflect->addSlot(
[qw(bar constant)] => "this is a constant field",
);
$p->reflect->addSlot(
[qw(foo superable)] => sub { print "superable method.\n"; },
);
$p->reflect->addSlot(
[qw(parent2* promote)] => $parent2,
);
The currently defined slot attributes are as follows:
- "FIELD" Slots
- "constant" ("implementor")
- When true, this defines the field slot as constant,
disabling the ability to modify it using the
"$object->field($newValue)" syntax. The value may still be
modified using the hash syntax (i.e. "$object->{field} =
$newValue"). This is mostly useful if you have an object method call
that takes parameters, but you wish to replace it on a given object with a
hard-coded value by using a field (which makes inspecting the value of the
slot through "Data::Dumper" much easier than if you use a
"METHOD" slot to return the constant, since code objects are
opaque).
- "autoload" ("filter", rank 50)
- The passed value for the "FIELD" slot should be a
subroutine that returns the desired value. Upon the first access, the
subroutine will be called, the return value hard-coded into the object by
adding the slot (including all otherwise specified attributes), and the
value then returned. Useful for implementing constant slots that are
costly to initialize, especially those that return lists of
"Class::Prototyped" objects!
- "profile" ("filter", rank 80)
- Stores profiling information in
$Class::Prototyped::Mirror::PROFILE::counts. If "profile" is set
to 1, increments "$counts->{$package}->{$slotName}"
everytime the slot is accessed. If "profile" is set to 2,
increments
"$counts->{$package}->{$slotName}->{$caller}" everytime
the slot is accessed, where $caller is "$file ($line)".
- "wantarray" ("filter", rank 90)
- If the field specifies a reference to an array and the call
is in list context, dereferences the array and returns a list of
values.
- "description" ("advisory")
- Can be used to specify a description. No real support for
this yet beyond that!
- "METHOD" Slots
- "superable" ("filter", rank 10)
- When true, this enables the
"$self->reflect->super( . . . )" calls for this method
slot.
- "profile" ("filter", rank 90)
- See "FIELD" slots for explanation.
- "overload" ("advisory")
- Set automatically for methods that implement operator
overloading.
- "description" ("advisory")
- See "FIELD" slots for explanation.
- "PARENT" Slots
- "promote" ("advisory")
- When true, this parent slot is promoted ahead of any other
parent slots on the object. This attribute is ephemeral - it is not
returned by calls to "getSlot".
- "description" ("advisory")
- See "FIELD" slots for explanation.
This will let you delete existing slots in the receiver. If those slots were
defined in the receiver's inheritance hierarchy, those inherited definitions
will now be available.
my $p1 = Class::Prototyped->new(
field1 => 123,
sub1 => sub { print "this is sub1 in p1" },
sub2 => sub { print "this is sub2 in p1" }
);
my $p2 = Class::Prototyped->new(
'parent*' => $p1,
sub1 => sub { print "this is sub1 in p2" },
);
$p2->sub1; # calls $p2.sub1
$p2->reflect->deleteSlots('sub1');
$p2->sub1; # calls $p1.sub1
$p2->reflect->deleteSlots('sub1');
$p2->sub1; # still calls $p1.sub1
The call to a method defined on a parent that is obscured by the current one
looks like so:
$self->reflect->super('method_name', @params);
This is passed an optional type parameter. If specified, it should be one of
'FIELD', 'METHOD', or 'PARENT'. For instance, the following will print out a
list of all slots of an object:
print join(', ', $obj->reflect->slotNames)."\n";
The following would print out a list of all field slots:
print join(', ', $obj->reflect->slotNames('FIELD')."\n";
The parent slot names are returned in the same order for which inheritance is
done.
This returns 'FIELD', 'METHOD', or 'PARENT'. It croaks if the slot is not
defined for that object.
Returns a list of all parent object (or package names) for this object.
Returns a list of all parent objects (or package names) in the object's
hierarchy.
Note that this will return duplicate slot names if inherited slots are obscured.
When called in scalar context, this returns the thing in the slot. When called
in list context, it returns both the complete form of the extended syntax for
specifying a slot name and the thing in the slot. There is an optional
parameter that can be used to modify the format of the return value in list
context. The allowable values are:
- •
- 'default' - the extended slot syntax and the slot value are
returned
- •
- 'simple' - the slot name and the slot value are returned.
Note that in this mode, there is no access to any attributes the slot may
have
- •
- 'rotated' - the slot name and the following hash are
returned like so:
$slotName => {
attribs => %slotAttribs,
type => $slotType,
value => $slotValue
},
The latter two options are quite useful when used in conjunction with the
"getSlots" method.
This returns a list of extended syntax slot specifiers and their values ready
for sending to "addSlots". It takes first the optional parameter
passed to "slotNames" which specifies the type of slot ('FIELD',
'METHOD', 'PARENT', or "undef") and then the optional parameter
passed to "getSlot", which specifies the format for the return
value. If the latter is 'simple', the returned values can be passed to
"addSlots", but any non-default slot attributes (i.e.
"superable" or "constant") will be lost. If the latter is
'rotated', the returned values are completely inappropriate for passing to
"addSlots". Both 'simple' and 'rotated' are appropriate for
assigning the return values into a hash.
For instance, to add all of the field slots in $bar to $foo:
$foo->reflect->addSlots($bar->reflect->getSlots('FIELD'));
To get a list of all of the slots in the 'simple' format:
my %barSlots = $bar->reflect->getSlots(undef, 'simple');
To get a list of all of the superable method slots in the 'rotated' format:
my %barMethods = $bar->reflect->getSlots('METHOD', 'rotated');
foreach my $slotName (%barMethods) {
delete $barMethods{$slotName}
unless $barMethods{$slotName}->{attribs}->{superable};
}
This expects a list of parent slot names. There should be no duplicates and all
of the parent slot names should be already existing parent slots on the
object. These parent slots will be moved forward in the hierarchy in the order
that they are passed. Unspecified parent slots will retain their current
positions relative to other unspecified parent slots, but as a group they will
be moved to the end of the hierarchy.
This allows you to specify the sort of tied interface you wish to offer when
code accesses the object as a hash reference. If no parameter is passed, this
will return the current tied interface package active for the object. If a
parameter is passed, it should specify either the package name or an alias.
The currently known aliases are:
- default
- This specifies "Class::Prototyped::Tied::Default"
as the tie class. The default behavior is to allow access to existing
fields, but attempts to create fields, access methods, or delete slots
will croak. This is the tie class used by "Class::Prototyped"
(unless you do something very naughty and call
"Class::Prototyped->reflect->tiedInterfacePackage($not_default)"),
and as such is the fallback behavior for classes and objects if they don't
get a different value from their inheritance.
- autovivify
- This specifies
"Class::Prototyped::Tied::AutoVivify" as the tie class. The
behavior of this package allows access to existing fields, will
automatically create field slots if they don't exist, and will allow
deletion of field slots. Attempts to access or delete method or parent
slots will croak.
Calls to "new" and "clone" will use the tied interface in
use on the existing object/package. When "reflect" is called for the
first time on a class package, it will use the tied interface of its first
parent class (i.e. $ISA[0]). If that package has not yet had
"reflect" called on it, it will check its parent, and so on and so
forth. If none of the packages in the primary inheritance fork have been
reflected upon, the value for "Class::Prototyped" will be used,
which should be "default".
This isn't particularly pretty. The general syntax looks something like:
my $temp = MyClass->reflect->defaultAttributes;
$temp->{METHOD}->{superable} = 1;
MyClass->reflect->defaultAttributes($temp);
The return value from "defaultAttributes" is a hash with the keys
'FIELD', 'METHOD', and 'PARENT'. The values are either "undef" or
hash references consisting of the attributes and their default values. Modify
the data structure as desired and pass it back to
"defaultAttributes" to change the default attributes for that object
or class. Note that default attributes are not inherited dynamically - the
inheritance occurs when a new object is created, but from that point on
changes to a parent object are not inherited by the child. Global changes can
be effected by modifying the "defaultAttributes" for
"Class::Prototyped" in a sufficiently early "BEGIN" block.
Note that making global changes like this is "not" recommended for
production modules as it may interfere with other modules that rely upon
"Class::Prototyped".
delegate name => slot name can be string, regex, or array of same. slot can
be slot name, or object, or 2-element array with slot name or object and
method name. You can delegate to a parent.
You can "require" an arbitrary file in the namespace of an object or
class without adding to the parents using "include()" :
$foo->include( 'xx.pl' );
will include whatever is in xx.pl. Likewise for modules:
$foo->include( 'MyModule' );
will search along your @INC path for "MyModule.pm" and include it.
You can specify a second parameter that will be the name of a subroutine that
you can use in your included code to refer to the object into which the code
is being included (as long as you don't change packages in the included code).
The subroutine will be removed after the include, so don't call it from any
subroutines defined in the included code.
If you have the following in "File.pl":
sub b {'xxx.b'}
sub c { return thisObject(); } # DON'T DO THIS!
thisObject()->reflect->addSlots(
'parent*' => 'A',
d => 'added.d',
e => sub {'xxx.e'},
);
And you include it using:
$mirror->include('File.pl', 'thisObject');
Then the "addSlots" will work fine, but if sub "c" is
called, it won't find "thisObject()".
Written by Ned Konz,
[email protected] and Toby Ovod-Everett,
[email protected]. 5.005_03 porting by chromatic.
Toby Ovod-Everett is currently maintaining the package.
Copyright 2001-2004 Ned Konz and Toby Ovod-Everett. All rights reserved. This
program is free software; you can redistribute it and/or modify it under the
same terms as Perl itself.
Class::SelfMethods
Class::Object
Class::Classless