xenial (3) Moose::Cookbook::Basics::Company_Subtypes.3pm.gz
NAME
Moose::Cookbook::Basics::Company_Subtypes - Demonstrates the use of subtypes and how to model classes
related to companies, people, employees, etc.
VERSION
version 2.1604
SYNOPSIS
package Address;
use Moose;
use Moose::Util::TypeConstraints;
use Locale::US;
use Regexp::Common 'zip';
my $STATES = Locale::US->new;
subtype 'USState'
=> as Str
=> where {
( exists $STATES->{code2state}{ uc($_) }
|| exists $STATES->{state2code}{ uc($_) } );
};
subtype 'USZipCode'
=> as Value
=> where {
/^$RE{zip}{US}{-extended => 'allow'}$/;
};
has 'street' => ( is => 'rw', isa => 'Str' );
has 'city' => ( is => 'rw', isa => 'Str' );
has 'state' => ( is => 'rw', isa => 'USState' );
has 'zip_code' => ( is => 'rw', isa => 'USZipCode' );
package Company;
use Moose;
use Moose::Util::TypeConstraints;
has 'name' => ( is => 'rw', isa => 'Str', required => 1 );
has 'address' => ( is => 'rw', isa => 'Address' );
has 'employees' => (
is => 'rw',
isa => 'ArrayRef[Employee]',
default => sub { [] },
);
sub BUILD {
my ( $self, $params ) = @_;
foreach my $employee ( @{ $self->employees } ) {
$employee->employer($self);
}
}
after 'employees' => sub {
my ( $self, $employees ) = @_;
return unless $employees;
foreach my $employee ( @$employees ) {
$employee->employer($self);
}
};
package Person;
use Moose;
has 'first_name' => ( is => 'rw', isa => 'Str', required => 1 );
has 'last_name' => ( is => 'rw', isa => 'Str', required => 1 );
has 'middle_initial' => (
is => 'rw', isa => 'Str',
predicate => 'has_middle_initial'
);
has 'address' => ( is => 'rw', isa => 'Address' );
sub full_name {
my $self = shift;
return $self->first_name
. (
$self->has_middle_initial
? ' ' . $self->middle_initial . '. '
: ' '
) . $self->last_name;
}
package Employee;
use Moose;
extends 'Person';
has 'title' => ( is => 'rw', isa => 'Str', required => 1 );
has 'employer' => ( is => 'rw', isa => 'Company', weak_ref => 1 );
override 'full_name' => sub {
my $self = shift;
super() . ', ' . $self->title;
};
DESCRIPTION
This recipe introduces the "subtype" sugar function from Moose::Util::TypeConstraints. The "subtype"
function lets you declaratively create type constraints without building an entire class.
In the recipe we also make use of Locale::US and Regexp::Common to build constraints, showing how
constraints can make use of existing CPAN tools for data validation.
Finally, we introduce the "required" attribute option.
In the "Address" class we define two subtypes. The first uses the Locale::US module to check the validity
of a state. It accepts either a state abbreviation of full name.
A state will be passed in as a string, so we make our "USState" type a subtype of Moose's builtin "Str"
type. This is done using the "as" sugar. The actual constraint is defined using "where". This function
accepts a single subroutine reference. That subroutine will be called with the value to be checked in $_
(1). It is expected to return a true or false value indicating whether the value is valid for the type.
We can now use the "USState" type just like Moose's builtin types:
has 'state' => ( is => 'rw', isa => 'USState' );
When the "state" attribute is set, the value is checked against the "USState" constraint. If the value is
not valid, an exception will be thrown.
The next "subtype", "USZipCode", uses Regexp::Common. Regexp::Common includes a regex for validating US
zip codes. We use this constraint for the "zip_code" attribute.
subtype 'USZipCode'
=> as Value
=> where {
/^$RE{zip}{US}{-extended => 'allow'}$/;
};
Using a subtype instead of requiring a class for each type greatly simplifies the code. We don't really
need a class for these types, as they're just strings, but we do want to ensure that they're valid.
The type constraints we created are reusable. Type constraints are stored by name in a global registry,
which means that we can refer to them in other classes. Because the registry is global, we do recommend
that you use some sort of namespacing in real applications, like "MyApp::Type::USState" (just as you
would do with class names).
These two subtypes allow us to define a simple "Address" class.
Then we define our "Company" class, which has an address. As we saw in earlier recipes, Moose
automatically creates a type constraint for each our classes, so we can use that for the "Company"
class's "address" attribute:
has 'address' => ( is => 'rw', isa => 'Address' );
A company also needs a name:
has 'name' => ( is => 'rw', isa => 'Str', required => 1 );
This introduces a new attribute option, "required". If an attribute is required, then it must be passed
to the class's constructor, or an exception will be thrown. It's important to understand that a
"required" attribute can still be false or "undef", if its type constraint allows that.
The next attribute, "employees", uses a parameterized type constraint:
has 'employees' => (
is => 'rw',
isa => 'ArrayRef[Employee]'
default => sub { [] },
);
This constraint says that "employees" must be an array reference where each element of the array is an
"Employee" object. It's worth noting that an empty array reference also satisfies this constraint, such
as the value given as the default here.
Parameterizable type constraints (or "container types"), such as "ArrayRef[`a]", can be made more
specific with a type parameter. In fact, we can arbitrarily nest these types, producing something like
"HashRef[ArrayRef[Int]]". However, you can also just use the type by itself, so "ArrayRef" is legal. (2)
If you jump down to the definition of the "Employee" class, you will see that it has an "employer"
attribute.
When we set the "employees" for a "Company" we want to make sure that each of these employee objects
refers back to the right "Company" in its "employer" attribute.
To do that, we need to hook into object construction. Moose lets us do this by writing a "BUILD" method
in our class. When your class defines a "BUILD" method, it will be called by the constructor immediately
after object construction, but before the object is returned to the caller. Note that all "BUILD" methods
in your class hierarchy will be called automatically; there is no need to (and you should not) call the
superclass "BUILD" method.
The "Company" class uses the "BUILD" method to ensure that each employee of a company has the proper
"Company" object in its "employer" attribute:
sub BUILD {
my ( $self, $params ) = @_;
foreach my $employee ( @{ $self->employees } ) {
$employee->employer($self);
}
}
The "BUILD" method is executed after type constraints are checked, so it is safe to assume that if
"$self->employees" has a value, it will be an array reference, and that the elements of that array
reference will be "Employee" objects.
We also want to make sure that whenever the "employees" attribute for a "Company" is changed, we also
update the "employer" for each employee.
To do this we can use an "after" modifier:
after 'employees' => sub {
my ( $self, $employees ) = @_;
return unless $employees;
foreach my $employee ( @$employees ) {
$employee->employer($self);
}
};
Again, as with the "BUILD" method, we know that the type constraint check has already happened, so we
know that if $employees is defined it will contain an array reference of "Employee" objects.
Note that "employees" is a read/write accessor, so we must return early if it's called as a reader.
The Person class does not really demonstrate anything new. It has several "required" attributes. It also
has a "predicate" method, which we first used in Moose::Cookbook::Basics::BinaryTree_AttributeFeatures.
The only new feature in the "Employee" class is the "override" method modifier:
override 'full_name' => sub {
my $self = shift;
super() . ', ' . $self->title;
};
This is just a sugary alternative to Perl's built in "SUPER::" feature. However, there is one difference.
You cannot pass any arguments to "super". Instead, Moose simply passes the same parameters that were
passed to the method.
A more detailed example of usage can be found in t/recipes/moose_cookbook_basics_recipe4.t.
CONCLUSION
This recipe was intentionally longer and more complex. It illustrates how Moose classes can be used
together with type constraints, as well as the density of information that you can get out of a small
amount of typing when using Moose.
This recipe also introduced the "subtype" function, the "required" attribute, and the "override" method
modifier.
We will revisit type constraints in future recipes, and cover type coercion as well.
FOOTNOTES
(1) The value being checked is also passed as the first argument to the "where" block, so it can be
accessed as $_[0].
(2) Note that "ArrayRef[]" will not work. Moose will not parse this as a container type, and instead you
will have a new type named "ArrayRef[]", which doesn't make any sense.
AUTHORS
• Stevan Little <stevan.little@iinteractive.com> • Dave Rolsky <autarch@urth.org> • Jesse Luehrs <doy@tozt.net> • Shawn M Moore <code@sartak.org> • יובל קוג'מן (Yuval Kogman) <nothingmuch@woobling.org> • Karen Etheridge <ether@cpan.org> • Florian Ragwitz <rafl@debian.org> • Hans Dieter Pearcey <hdp@weftsoar.net> • Chris Prather <chris@prather.org> • Matt S Trout <mst@shadowcat.co.uk>
COPYRIGHT AND LICENSE
This software is copyright (c) 2006 by Infinity Interactive, Inc..
This is free software; you can redistribute it and/or modify it under the same terms as the Perl 5
programming language system itself.