=pod =head1 NAME Moose::Cookbook::Recipe5 - More subtypes, coercion in a B class =head1 SYNOPSIS package Request; use Moose; use Moose::Util::TypeConstraints; use HTTP::Headers (); use Params::Coerce (); use URI (); subtype 'Header' => as 'Object' => where { $_->isa('HTTP::Headers') }; coerce 'Header' => from 'ArrayRef' => via { HTTP::Headers->new( @{ $_ } ) } => from 'HashRef' => via { HTTP::Headers->new( %{ $_ } ) }; subtype 'Uri' => as 'Object' => where { $_->isa('URI') }; coerce 'Uri' => from 'Object' => via { $_->isa('URI') ? $_ : Params::Coerce::coerce( 'URI', $_ ) } => from 'Str' => via { URI->new( $_, 'http' ) }; subtype 'Protocol' => as Str => where { /^HTTP\/[0-9]\.[0-9]$/ }; has 'base' => (is => 'rw', isa => 'Uri', coerce => 1); has 'uri' => (is => 'rw', isa => 'Uri', coerce => 1); has 'method' => (is => 'rw', isa => 'Str'); has 'protocol' => (is => 'rw', isa => 'Protocol'); has 'headers' => ( is => 'rw', isa => 'Header', coerce => 1, default => sub { HTTP::Headers->new } ); =head1 DESCRIPTION This recipe introduces the idea of type coercions, and the C keyword. Coercions can be attached to existing type constraints, and can be used to transform input of one type into input of another type. This can be an extremely powerful tool if used correctly, which is why it is off by default. If you want your accessor to attempt a coercion, you must specifically ask for it with the B option. Now, onto the coercions. First we need to create a subtype to attach our coercion to. Here we create a basic I
subtype, which matches any instance of the class B: subtype 'Header' => as 'Object' => where { $_->isa('HTTP::Headers') }; The simplest thing from here would be create an accessor declaration like this: has 'headers' => ( is => 'rw', isa => 'Header', default => sub { HTTP::Headers->new } ); We would then have a self-validating accessor whose default value is an empty instance of B. This is nice, but it is not ideal. The constructor for B accepts a list of key-value pairs representing the HTTP header fields. In Perl, such a list could easily be stored in an ARRAY or HASH reference. We would like our class's interface to be able to accept this list of key-value pairs in place of the B instance, and just DWIM. This is where coercion can help. First, let's declare our coercion: coerce 'Header' => from 'ArrayRef' => via { HTTP::Headers->new( @{ $_ } ) } => from 'HashRef' => via { HTTP::Headers->new( %{ $_ } ) }; We first tell it that we are attaching the coercion to the 'Header' subtype. We then give it a set of C clauses which map other subtypes to coercion routines (through the C keyword). Fairly simple really; however, this alone does nothing. We have to tell our attribute declaration to actually use the coercion, like so: has 'headers' => ( is => 'rw', isa => 'Header', coerce => 1, default => sub { HTTP::Headers->new } ); This will coerce any B or B which is passed into the C accessor into an instance of B. So the the following lines of code are all equivalent: $foo->headers(HTTP::Headers->new(bar => 1, baz => 2)); $foo->headers([ 'bar', 1, 'baz', 2 ]); $foo->headers({ bar => 1, baz => 2 }); As you can see, careful use of coercions can produce a very open interface for your class, while still retaining the "safety" of your type constraint checks. Our next coercion takes advantage of the power of CPAN to handle the details of our coercion. In this particular case it uses the L module, which fits in rather nicely with L. Again, we create a simple subtype to represent instances of the B class: subtype 'Uri' => as 'Object' => where { $_->isa('URI') }; Then we add the coercion: coerce 'Uri' => from 'Object' => via { $_->isa('URI') ? $_ : Params::Coerce::coerce( 'URI', $_ ) } => from 'Str' => via { URI->new( $_, 'http' ) }; The first C clause we introduce is for the 'Object' subtype. An 'Object' is simply any Ced value. This means that if the coercion encounters another object, it should use this clause. Now we look at the C block. First it checks to see if the object is a B instance. Since the coercion process occurs prior to any type constraint checking, it is entirely possible for this to happen, and if it does happen, we simply want to pass the instance on through. However, if it is not an instance of B, then we need to coerce it. This is where L can do its magic, and we can just use its return value. Simple really, and much less work since we used a module from CPAN :) The second C clause is attached to the 'Str' subtype, and illustrates how coercions can also be used to handle certain 'default' behaviors. In this coercion, we simple take any string and pass it to the B constructor along with the default 'http' scheme type. And of course, our coercions do nothing unless they are told to, like so: has 'base' => (is => 'rw', isa => 'Uri', coerce => 1); has 'uri' => (is => 'rw', isa => 'Uri', coerce => 1); As you can see, re-using the coercion allows us to enforce a consistent and very flexible API across multiple accessors. =head1 CONCLUSION This recipe illustrated the power of coercions to build a more flexible and open API for your accessors, while still retaining all the safety that comes from using Moose's type constraints. Using coercions it becomes simple to manage (from a single location) a consistent API not only across multiple accessors, but across multiple classes as well. In the next recipe, we will introduce roles, a concept originally borrowed from Smalltalk, which made it's way into Perl 6, and now into Moose. =head1 AUTHOR Stevan Little Estevan@iinteractive.comE =head1 COPYRIGHT AND LICENSE Copyright 2006-2008 by Infinity Interactive, Inc. L This library is free software; you can redistribute it and/or modify it under the same terms as Perl itself. =cut