Provided by: libtype-tiny-perl_2.002001-1_all bug

NAME

       Type::Tiny::Manual::UsingWithMoo3 - alternative use of Type::Tiny with Moo

MANUAL

   Type Registries
       In all the examples so far, we have imported a collection of type constraints into each
       class:

         package Horse {
           use Moo;
           use Types::Standard qw( Str ArrayRef HashRef Int Any InstanceOf );
           use Types::Common::Numeric qw( PositiveInt );
           use Types::Common::String qw( NonEmptyStr );

           has name    => ( is => 'ro', isa => Str );
           has father  => ( is => 'ro', isa => InstanceOf["Horse"] );
           ...;
         }

       This creates a bunch of subs in the Horse namespace, one for each type.  We've used
       namespace::autoclean to clean these up later.

       But it is also possible to avoid pulling all these into the Horse namespace. Instead we'll
       use a type registry:

         package Horse {
           use Moo;
           use Type::Registry qw( t );

           t->add_types('-Standard');
           t->add_types('-Common::String');
           t->add_types('-Common::Numeric');

           t->alias_type('InstanceOf["Horse"]' => 'Horsey');

           has name     => ( is => 'ro', isa => t('Str') );
           has father   => ( is => 'ro', isa => t('Horsey') );
           has mother   => ( is => 'ro', isa => t('Horsey') );
           has children => ( is => 'ro', isa => t('ArrayRef[Horsey]') );
           ...;
         }

       You don't even need to import the "t()" function. Types::Registry can be used in an
       entirely object-oriented way.

         package Horse {
           use Moo;
           use Type::Registry;

           my $reg = Type::Registry->for_me;

           $reg->add_types('-Standard');
           $reg->add_types('-Common::String');
           $reg->add_types('-Common::Numeric');

           $reg->alias_type('InstanceOf["Horse"]' => 'Horsey');

           has name => ( is => 'ro', isa => $reg->lookup('Str') );
           ...;
         }

       You could create two registries with entirely different definitions for the same named
       type.

         my $dracula = Aristocrat->new(name => 'Dracula');

         package AristocracyTracker {
           use Type::Registry;

           my $reg1 = Type::Registry->new;
           $reg1->add_types('-Common::Numeric');
           $reg1->alias_type('PositiveInt' => 'Count');

           my $reg2 = Type::Registry->new;
           $reg2->add_types('-Standard');
           $reg2->alias_type('InstanceOf["Aristocrat"]' => 'Count');

           $reg1->lookup("Count")->assert_valid("1");
           $reg2->lookup("Count")->assert_valid($dracula);
         }

       Type::Registry uses "AUTOLOAD", so things like this work:

         $reg->ArrayRef->of( $reg->Int );

       Although you can create as many registries as you like, Type::Registry will create a
       default registry for each package.

         # Create a new empty registry.
         #
         my $reg = Type::Registry->new;

         # Get the default registry for my package.
         # It will be pre-populated with any types we imported using `use`.
         #
         my $reg = Type::Registry->for_me;

         # Get the default registry for some other package.
         #
         my $reg = Type::Registry->for_class("Horse");

       Type registries are a convenient place to store a bunch of types without polluting your
       namespace. They are not the same as type libraries though.  Types::Standard,
       Types::Common::String, and Types::Common::Numeric are type libraries; packages that export
       types for others to use. We will look at how to make one of those later.

       For now, here's the best way to think of the difference:

       •   Type registry

           Curate a collection of types for me to use here in this class.  This collection is an
           implementation detail.

       •   Type library

           Export a collection of types to be used across multiple classes.  This collection is
           part of your API.

   Importing Functions
       We've seen how, for instance, Types::Standard exports a sub called "Int" that returns the
       Int type object.

         use Types::Standard qw( Int );

         my $type = Int;
         $type->check($value) or die $type->get_message($value);

       Type libraries are also capable of exporting other convenience functions.

       "is_*"

       This is a shortcut for checking a value meets a type constraint:

         use Types::Standard qw( is_Int );

         if ( is_Int $value ) {
           ...;
         }

       Calling "is_Int($value)" will often be marginally faster than calling "Int->check($value)"
       because it avoids a method call.  (Method calls in Perl end up slower than normal function
       calls.)

       Using things like "is_ArrayRef" in your code might be preferable to "ref($value) eq
       "ARRAY"" because it's neater, leads to more consistent type checking, and might even be
       faster. (Type::Tiny can be pretty fast; it is sometimes able to export these functions as
       XS subs.)

       If checking type constraints like "is_ArrayRef" or "is_InstanceOf", there's no way to give
       a parameter. "is_ArrayRef[Int]($value)" doesn't work, and neither does "is_ArrayRef(Int,
       $value)" nor "is_ArrayRef($value, Int)". For some types like "is_InstanceOf", this makes
       them fairly useless; without being able to give a class name, it just acts the same as
       "is_Object". See "Exporting Parameterized Types" for a solution. Also, check out isa.

       There also exists a generic "is" function.

         use Types::Standard qw( ArrayRef Int );
         use Type::Utils qw( is );

         if ( is ArrayRef[Int], \@numbers ) {
           ...;
         }

       "assert_*"

       While "is_Int($value)" returns a boolean, "assert_Int($value)" will throw an error if the
       value does not meet the constraint, and return the value otherwise. So you can do:

         my $sum = assert_Int($x) + assert_Int($y);

       And you will get the sum of integers $x and $y, and an explosion if either of them is not
       an integer!

       Assert is useful for quick parameter checks if you are avoiding Type::Params for some
       strange reason:

         sub add_numbers {
           my $x = assert_Num(shift);
           my $y = assert_Num(shift);
           return $x + $y;
         }

       You can also use a generic "assert" function.

         use Type::Utils qw( assert );

         sub add_numbers {
           my $x = assert Num, shift;
           my $y = assert Num, shift;
           return $x + $y;
         }

       "to_*"

       This is a shortcut for coercion:

         my $truthy = to_Bool($value);

       It trusts that the coercion has worked okay. You can combine it with an assertion if you
       want to make sure.

         my $truthy = assert_Bool(to_Bool($value));

       Shortcuts for exporting functions

       This is a little verbose:

         use Types::Standard qw( Bool is_Bool assert_Bool to_Bool );

       Isn't this a little bit nicer?

         use Types::Standard qw( +Bool );

       The plus sign tells a type library to export not only the type itself, but all of the
       convenience functions too.

       You can also use:

         use Types::Standard -types;   # export Int, Bool, etc
         use Types::Standard -is;      # export is_Int, is_Bool, etc
         use Types::Standard -assert;  # export assert_Int, assert_Bool, etc
         use Types::Standard -to;      # export to_Bool, etc
         use Types::Standard -all;     # just export everything!!!

       So if you imagine the functions exported by Types::Standard are like this:

         qw(
           Str             is_Str          assert_Str
           Num             is_Num          assert_Num
           Int             is_Int          assert_Int
           Bool            is_Bool         assert_Bool     to_Bool
           ArrayRef        is_ArrayRef     assert_ArrayRef
         );
         # ... and more

       Then "+" exports a horizonal group of those, and "-" exports a vertical group.

   Exporting Parameterized Types
       It's possible to export parameterizable types like ArrayRef, but it is also possible to
       export parameterized types.

         use Types::Standard qw( ArrayRef Int );
         use Types::Standard (
           '+ArrayRef' => { of => Int, -as => 'IntList' },
         );

         has numbers => (is => 'ro', isa => IntList);

       Using "is_IntList($value)" should be significantly faster than
       "ArrayRef->of(Int)->check($value)".

       This trick only works for parameterized types that have a single parameter, like ArrayRef,
       HashRef, InstanceOf, etc.  (Sorry, "Dict" and "Tuple"!)

   Lexical imports
       Type::Tiny 2.0 combined with Perl 5.37.2+ allows lexically scoped imports.  So:

         my $is_ok = do {
           use Types::Standard -lexical, qw( Str ArrayRef );
           ArrayRef->of( Str )->check( \@things );
         };

         # The Str and ArrayRef types aren't defined here.

   Do What I Mean!
         use Type::Utils qw( dwim_type );

         dwim_type("ArrayRef[Int]")

       "dwim_type" will look up a type constraint from a string and attempt to guess what you
       meant.

       If it's a type constraint that you seem to have imported with "use", then it should find
       it. Otherwise, if you're using Moose or Mouse, it'll try asking those. Or if it's in
       Types::Standard, it'll look there. And if it still has no idea, then it will assume
       dwim_type("Foo") means dwim_type("InstanceOf['Foo']").

       It just does a big old bunch of guessing.

       The "is" function will use "dwim_type" if you pass it a string as a type.

         use Type::Utils qw( is );

         if ( is "ArrayRef[Int]", \@numbers ) {
           ...;
         }

   Types::Common
       Notice that in a lot of examples we're importing one or two functions each from a few
       different modules:

         use Types::Common::Numeric qw( PositiveInt );
         use Types::Common::String qw( NonEmptyStr );
         use Types::Standard qw( ArrayRef Slurpy );
         use Type::Params qw( signature );

       A module called Types::Common exists which acts as a single place you can use for
       importing most of Type::Tiny's commonly used types and functions.

         use Types::Common qw(
           PositiveInt NonEmptyStr ArrayRef Slurpy
           signature
         );

       Types::Common provides:

       •   All the types from Types::Standard.

       •   All the types from Types::Common::Numeric and Types::Common::String.

       •   All the types from Types::TypeTiny.

       •   The "-sigs" tag from Type::Params.

       •   The "t()" function from Type::Registry.

NEXT STEPS

       You now know pretty much everything there is to know about how to use type libraries.

       Here's your next step:

       •   Type::Tiny::Manual::Libraries

           Defining your own type libraries, including extending existing libraries, defining new
           types, adding coercions, defining parameterizable types, and the declarative style.

AUTHOR

       Toby Inkster <tobyink@cpan.org>.

COPYRIGHT AND LICENCE

       This software is copyright (c) 2013-2014, 2017-2023 by Toby Inkster.

       This is free software; you can redistribute it and/or modify it under the same terms as
       the Perl 5 programming language system itself.

DISCLAIMER OF WARRANTIES

       THIS PACKAGE IS PROVIDED "AS IS" AND WITHOUT ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING,
       WITHOUT LIMITATION, THE IMPLIED WARRANTIES OF MERCHANTIBILITY AND FITNESS FOR A PARTICULAR
       PURPOSE.