mro - Method Resolution Order
The "mro" namespace provides several utilities for dealing with method resolution order and method caching in general.
These interfaces are only available in Perl 5.9.5 and higher. See MRO::Compat on CPAN for a mostly forwards compatible implementation for older Perls.
It's possible to change the MRO of a given class either by using use
mro
as shown in the synopsis, or by using the mro::set_mro function
below.
The special methods next::method
, next::can
, and
maybe::next::method
are not available until this mro
module
has been loaded via use
or require
.
In addition to the traditional Perl default MRO (depth first
search, called DFS
here), Perl now offers the C3 MRO as
well. Perl's support for C3 is based on the work done in
Stevan Little's module Class::C3, and most of the C3-related
documentation here is ripped directly from there.
C3 is the name of an algorithm which aims to provide a sane method resolution order under multiple inheritance. It was first introduced in the language Dylan (see links in the SEE ALSO section), and then later adopted as the preferred MRO (Method Resolution Order) for the new-style classes in Python 2.3. Most recently it has been adopted as the "canonical" MRO for Perl 6 classes, and the default MRO for Parrot objects as well.
C3 works by always preserving local precedence ordering. This essentially means that no class will appear before any of its subclasses. Take, for instance, the classic diamond inheritance pattern:
- <A>
- / \
- <B> <C>
- \ /
- <D>
The standard Perl 5 MRO would be (D, B, A, C). The result being that A appears before C, even though C is the subclass of A. The C3 MRO algorithm however, produces the following order: (D, B, C, A), which does not have this issue.
This example is fairly trivial; for more complex cases and a deeper explanation, see the links in the SEE ALSO section.
Returns an arrayref which is the linearized MRO of the given class.
Uses whichever MRO is currently in effect for that class by default,
or the given MRO (either c3
or dfs
if specified as $type
).
The linearized MRO of a class is an ordered array of all of the classes one would search when resolving a method on that class, starting with the class itself.
If the requested class doesn't yet exist, this function will still
succeed, and return [ $classname ]
Note that UNIVERSAL
(and any members of UNIVERSAL
's MRO) are not
part of the MRO of a class, even though all classes implicitly inherit
methods from UNIVERSAL
and its parents.
Sets the MRO of the given class to the $type
argument (either
c3
or dfs
).
Returns the MRO of the given class (either c3
or dfs
).
Gets the mro_isarev
for this class, returned as an
arrayref of class names. These are every class that "isa"
the given class name, even if the isa relationship is
indirect. This is used internally by the MRO code to
keep track of method/MRO cache invalidations.
As with mro::get_linear_isa
above, UNIVERSAL
is special.
UNIVERSAL
(and parents') isarev lists do not include
every class in existence, even though all classes are
effectively descendants for method inheritance purposes.
Returns a boolean status indicating whether or not
the given classname is either UNIVERSAL
itself,
or one of UNIVERSAL
's parents by @ISA
inheritance.
Any class for which this function returns true is "universal" in the sense that all classes potentially inherit methods from it.
Increments PL_sub_generation
, which invalidates method
caching in all packages.
Invalidates the method cache of any classes dependent on the given class. This is not normally necessary. The only known case where pure perl code can confuse the method cache is when you manually install a new constant subroutine by using a readonly scalar value, like the internals of constant do. If you find another case, please report it so we can either fix it or document the exception here.
Returns an integer which is incremented every time a
real local method in the package $classname
changes,
or the local @ISA
of $classname
is modified.
This is intended for authors of modules which do lots
of class introspection, as it allows them to very quickly
check if anything important about the local properties
of a given class have changed since the last time they
looked. It does not increment on method/@ISA
changes in superclasses.
It's still up to you to seek out the actual changes, and there might not actually be any. Perhaps all of the changes since you last checked cancelled each other out and left the package in the state it was in before.
This integer normally starts off at a value of 1
when a package stash is instantiated. Calling it
on packages whose stashes do not exist at all will
return 0
. If a package stash is completely
deleted (not a normal occurrence, but it can happen
if someone does something like undef %PkgName::
),
the number will be reset to either 0
or 1
,
depending on how completely the package was wiped out.
This is somewhat like SUPER
, but it uses the C3 method
resolution order to get better consistency in multiple
inheritance situations. Note that while inheritance in
general follows whichever MRO is in effect for the
given class, next::method
only uses the C3 MRO.
One generally uses it like so:
Note that you don't (re-)specify the method name. It forces you to always use the same method name as the method you started in.
It can be called on an object or a class, of course.
The way it resolves which actual method to call is:
First, it determines the linearized C3 MRO of the object or class it is being called on.
Then, it determines the class and method name of the context it was invoked from.
Finally, it searches down the C3 MRO list until it reaches the contextually enclosing class, then searches further down the MRO list for the next method with the same name as the contextually enclosing method.
Failure to find a next method will result in an exception being thrown (see below for alternatives).
This is substantially different than the behavior
of SUPER
under complex multiple inheritance.
(This becomes obvious when one realizes that the
common superclasses in the C3 linearizations of
a given class and one of its parents will not
always be ordered the same for both.)
Caveat: Calling next::method
from methods defined outside the class:
There is an edge case when using next::method
from within a subroutine
which was created in a different module than the one it is called from. It
sounds complicated, but it really isn't. Here is an example which will not
work correctly:
The problem exists because the anonymous subroutine being assigned to the
*Foo::foo
glob will show up in the call stack as being called
__ANON__
and not foo
as you might expect. Since next::method
uses
caller
to find the name of the method it was called in, it will fail in
this case.
But fear not, there's a simple solution. The module Sub::Name
will
reach into the perl internals and assign a name to an anonymous subroutine
for you. Simply do this:
and things will Just Work.
This is similar to next::method
, but just returns either a code
reference or undef
to indicate that no further methods of this name
exist.
In simple cases, it is equivalent to:
- $self->next::method(@_) if $self->next::can;
But there are some cases where only this solution
works (like goto &maybe::next::method
);
The Pugs prototype Perl 6 Object Model uses C3
Parrot now uses C3
Brandon L. Black, <blblack@gmail.com>
Based on Stevan Little's Class::C3