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Type::Params(3pm)              User Contributed Perl Documentation              Type::Params(3pm)

NAME
       Type::Params - Params::Validate-like parameter validation using Type::Tiny type
       constraints and coercions

SYNOPSIS
        use v5.12;
        use strict;
        use warnings;

        package Horse {
          use Moo;
          use Types::Standard qw( Object );
          use Type::Params qw( compile );
          use namespace::autoclean;

          ...;   # define attributes, etc

          sub add_child {
            state $check = compile( Object, Object );  # method signature

            my ($self, $child) = $check->(@_);         # unpack @_
            push @{ $self->children }, $child;

            return $self;
          }
        }

        package main;

        my $boldruler = Horse->new;

        $boldruler->add_child( Horse->new );

        $boldruler->add_child( 123 );   # dies (123 is not an Object!)

STATUS
       This module is covered by the Type-Tiny stability policy.

DESCRIPTION
       This documents the details of the Type::Params package.  Type::Tiny::Manual is a better
       starting place if you're new.

       Type::Params uses Type::Tiny constraints to validate the parameters to a sub. It takes the
       slightly unorthodox approach of separating validation into two stages:

       1.  Compiling the parameter specification into a coderef; then

       2.  Using the coderef to validate parameters.

       The first stage is slow (it might take a couple of milliseconds), but you only need to do
       it the first time the sub is called. The second stage is fast; according to my benchmarks
       faster even than the XS version of Params::Validate.

       If you're using a modern version of Perl, you can use the "state" keyword which was a
       feature added to Perl in 5.10. If you're stuck on Perl 5.8, the example from the SYNOPSIS
       could be rewritten as:

          my $add_child_check;
          sub add_child {
            $add_child_check ||= compile( Object, Object );

            my ($self, $child) = $add_child_check->(@_);  # unpack @_
            push @{ $self->children }, $child;

            return $self;
          }

       Not quite as neat, but not awful either.

       If you don't like the two step, there's a shortcut reducing it to one step:

          use Type::Params qw( validate );

          sub add_child {
            my ($self, $child) = validate(\@_, Object, Object);
            push @{ $self->children }, $child;
            return $self;
          }

       Type::Params has a few tricks up its sleeve to make sure performance doesn't suffer too
       much with the shortcut, but it's never going to be as fast as the two stage
       compile/execute.

   Functions
       "compile(@spec)"

       Given specifications for positional parameters, compiles a coderef that can check against
       them.

       The generalized form of specifications for positional parameters is:

        state $check = compile(
          \%general_opts,
          $type_for_arg_1, \%opts_for_arg_1,
          $type_for_arg_2, \%opts_for_arg_2,
          $type_for_arg_3, \%opts_for_arg_3,
          ...,
          slurpy($slurpy_type),
        );

       If a hashref of options is empty, it can simply be omitted. Much of the time, you won't
       need to specify any options.

        # In this example, we omit all the hashrefs
        #
        my $check = compile(
          Str,
          Int,
          Optional[ArrayRef],
        );

        my ($str, $int, $arr) = $check->("Hello", 42, []);   # ok
        my ($str, $int, $arr) = $check->("", -1);            # ok
        my ($str, $int, $arr) = $check->("", -1, "bleh");    # dies

       The coderef returned (i.e. $check) will check the arguments passed to it conform to the
       spec (coercing them if appropriate), and return them as a list if they do. If they don't,
       it will throw an exception.

       The first hashref, before any type constraints, is for general options which affect the
       entire compiled coderef. Currently supported general options are:

       "head" Int|ArrayRef[TypeTiny]
           Parameters to shift off @_ before doing the main type check.  These parameters may
           also be checked, and cannot be optional or slurpy.  They may not have defaults.

             my $check = compile(
               { head => [ Int, Int ] },
               Str,
               Str,
             );

             # ... is basically the same as...

             my $check = compile(
               Int,
               Int,
               Str,
               Str,
             );

           A number may be given if you do not care to check types:

             my $check = compile(
               { head => 2 },
               Str,
               Str,
             );

             # ... is basically the same as...

             my $check = compile(
               Any,
               Any,
               Str,
               Str,
             );

           This is mostly useless for "compile", but can be useful for "compile_named" and
           "compile_named_oo".

       "tail" Int|ArrayRef[TypeTiny]
           Similar to "head", but pops parameters off the end of @_ instead.  This is actually
           useful for "compile" because it allows you to sneak in some required parameters after
           a slurpy or optional parameter.

             my $check = compile(
               { tail => [ CodeRef ] },
               slurpy ArrayRef[Str],
             );

             my ($strings, $coderef) = $check->("foo", "bar", sub { ... });

       "want_source" Bool
           Instead of returning a coderef, return Perl source code string. Handy for debugging.

       "want_details" Bool
           Instead of returning a coderef, return a hashref of stuff including the coderef. This
           is mostly for people extending Type::Params and I won't go into too many details about
           what else this hashref contains.

       "description" Str
           Description of the coderef that will show up in stack traces. Defaults to "parameter
           validation for X" where X is the caller sub name.

       "subname" Str
           If you wish to use the default description, but need to change the sub name, use this.

       "caller_level" Int
           If you wish to use the default description, but need to change the caller level for
           detecting the sub name, use this.

       The types for each parameter may be any Type::Tiny type constraint, or anything that
       Type::Tiny knows how to coerce into a Type::Tiny type constraint, such as a MooseX::Types
       type constraint or a coderef.

       Type coercions are automatically applied for all types that have coercions.

       If you wish to avoid coercions for a type, use Type::Tiny's "no_coercions" method.

        my $check = compile(
          Int,
          ArrayRef->of(Bool)->no_coercions,
        );

       Note that having any coercions in a specification, even if they're not used in a
       particular check, will slightly slow down $check because it means that $check can't just
       check @_ and return it unaltered if it's valid -- it needs to build a new array to return.

       Optional parameters can be given using the Optional[] type constraint. In the example
       above, the third parameter is optional.  If it's present, it's required to be an arrayref,
       but if it's absent, it is ignored.

       Optional parameters need to be after required parameters in the spec.

       An alternative way to specify optional parameters is using a parameter options hashref.

        my $check = compile(
          Str,
          Int,
          ArrayRef, { optional => 1 },
        );

       The following parameter options are supported:

       "optional" Bool
           This is an alternative way of indicating that a parameter is optional.

            state $check = compile(
              Int,
              Int, { optional => 1 },
              Optional[Int],
            );

           The two are not exactly equivalent. The exceptions thrown will differ in the type name
           they mention. (Int versus Optional[Int].)

       "default" CodeRef|Ref|Str|Undef
           A default may be provided for a parameter.

            state $check = compile(
              Int,
              Int, { default => "666" },
              Int, { default => "999" },
            );

           Supported defaults are any strings (including numerical ones), "undef", and empty
           hashrefs and arrayrefs. Non-empty hashrefs and arrayrefs are not allowed as defaults.

           Alternatively, you may provide a coderef to generate a default value:

            state $check = compile(
              Int,
              Int, { default => sub { 6 * 111 } },
              Int, { default => sub { 9 * 111 } },
            );

           That coderef may generate any value, including non-empty arrayrefs and non-empty
           hashrefs. For undef, simple strings, numbers, and empty structures, avoiding using a
           coderef will make your parameter processing faster.

           The default will be validated against the type constraint, and potentially coerced.

           Note that having any defaults in a specification, even if they're not used in a
           particular check, will slightly slow down $check because it means that $check can't
           just check @_ and return it unaltered if it's valid -- it needs to build a new array
           to return.

       As a special case, the numbers 0 and 1 may be used as shortcuts for Optional[Any] and Any.

        # Positional parameters
        state $check = compile(1, 0, 0);
        my ($foo, $bar, $baz) = $check->(@_);  # $bar and $baz are optional

       After any required and optional parameters may be a slurpy parameter.  Any additional
       arguments passed to $check will be slurped into an arrayref or hashref and checked against
       the slurpy parameter.  Defaults are not supported for slurpy parameters.

       Example with a slurpy ArrayRef:

        sub xyz {
          state $check = compile(Int, Int, slurpy ArrayRef[Int]);
          my ($foo, $bar, $baz) = $check->(@_);
        }

        xyz(1..5);  # $foo = 1
                    # $bar = 2
                    # $baz = [ 3, 4, 5 ]

       Example with a slurpy HashRef:

        my $check = compile(
          Int,
          Optional[Str],
          slurpy HashRef[Int],
        );

        my ($x, $y, $z) = $check->(1, "y", foo => 666, bar => 999);
        # $x is 1
        # $y is "y"
        # $z is { foo => 666, bar => 999 }

       Any type constraints derived from ArrayRef or HashRef should work, but a type does need to
       inherit from one of those because otherwise Type::Params cannot know what kind of
       structure to slurp the remaining arguments into.

       slurpy Any is also allowed as a special case, and is treated as slurpy ArrayRef.

       From Type::Params 1.005000 onwards, slurpy hashrefs can be passed in as a true hashref
       (which will be shallow cloned) rather than key-value pairs.

        sub xyz {
          state $check = compile(Int, slurpy HashRef);
          my ($num, $hr) = $check->(@_);
          ...
        }

        xyz( 5,   foo => 1, bar => 2   );   # works
        xyz( 5, { foo => 1, bar => 2 } );   # works from 1.005000

       This feature is only implemented for slurpy hashrefs, not slurpy arrayrefs.

       Note that having a slurpy parameter will slightly slow down $check because it means that
       $check can't just check @_ and return it unaltered if it's valid -- it needs to build a
       new array to return.

       "validate(\@_, @spec)"

       This example of "compile":

        sub foo {
          state $check = compile(@spec);
          my @args = $check->(@_);
          ...;
        }

       Can be written using "validate" as:

        sub foo {
          my @args = validate(\@_, @spec);
          ...;
        }

       Performance using "compile" will always beat "validate" though.

       "compile_named(@spec)"

       "compile_named" is a variant of "compile" for named parameters instead of positional
       parameters.

       The format of the specification is changed to include names for each parameter:

        state $check = compile_named(
          \%general_opts,
          foo   => $type_for_foo, \%opts_for_foo,
          bar   => $type_for_bar, \%opts_for_bar,
          baz   => $type_for_baz, \%opts_for_baz,
          ...,
          extra => slurpy($slurpy_type),
        );

       The $check coderef will return a hashref.

        my $check = compile_named(
          foo => Int,
          bar => Str, { default => "hello" },
        );

        my $args = $check->(foo => 42);
        # $args->{foo} is 42
        # $args->{bar} is "hello"

       The %general_opts hash supports the same options as "compile" plus a few additional
       options:

       "class" ClassName
           The check coderef will, instead of returning a simple hashref, call
           "$class->new($hashref)" and return the result.

       "constructor" Str
           Specifies an alternative method name instead of "new" for the "class" option described
           above.

       "class" Tuple[ClassName, Str]
           Shortcut for declaring both the "class" and "constructor" options at once.

       "bless" ClassName
           Like "class", but bypass the constructor and directly bless the hashref.

       "named_to_list" Bool
           Instead of returning a hashref, return a hash slice.

            myfunc(bar => "x", foo => "y");

            sub myfunc {
               state $check = compile_named(
                  { named_to_list => 1 },
                  foo => Str, { optional => 1 },
                  bar => Str, { optional => 1 },
               );
               my ($foo, $bar) = $check->(@_);
               ...; ## $foo is "y" and $bar is "x"
            }

           The order of keys for the hash slice is the same as the order of the names passed to
           "compile_named". For missing named parameters, "undef" is returned in the list.

           Basically in the above example, "myfunc" takes named parameters, but receieves
           positional parameters.

       "named_to_list" ArrayRef[Str]
           As above, but explicitly specify the keys of the hash slice.

       Like "compile", the numbers 0 and 1 may be used as shortcuts for Optional[Any] and Any.

        state $check = compile_named(foo => 1, bar => 0, baz => 0);
        my $args = $check->(@_);  # $args->{bar} and $args->{baz} are optional

       Slurpy parameters are slurped into a nested hashref.

         my $check = compile(
           foo    => Str,
           bar    => Optional[Str],
           extra  => slurpy HashRef[Str],
         );
         my $args = $check->(foo => "aaa", quux => "bbb");

         print $args->{foo}, "\n";             # aaa
         print $args->{extra}{quux}, "\n";     # bbb

       slurpy Any is treated as slurpy HashRef.

       The "head" and "tail" options are supported. This allows for a mixture of positional and
       named arguments, as long as the positional arguments are non-optional and at the head and
       tail of @_.

         my $check = compile(
           { head => [ Int, Int ], tail => [ CodeRef ] },
           foo => Str,
           bar => Str,
           baz => Str,
         );

         my ($int1, $int2, $args, $coderef)
           = $check->( 666, 999, foo=>'x', bar=>'y', baz=>'z', sub {...} );

         say $args->{bar};  # 'y'

       This can be combined with "named_to_list":

         my $check = compile(
           { head => [ Int, Int ], tail => [ CodeRef ], named_to_list => 1 },
           foo => Str,
           bar => Str,
           baz => Str,
         );

         my ($int1, $int2, $foo, $bar, $baz, $coderef)
           = $check->( 666, 999, foo=>'x', bar=>'y', baz=>'z', sub {...} );

         say $bar;  # 'y'

       "validate_named(\@_, @spec)"

       Like "compile" has "validate", "compile_named" has "validate_named".  Just like
       "validate", it's the slower way to do things, so stick with "compile_named".

       "compile_named_oo(@spec)"

       Here's a quick example function:

          sub add_contact_to_database {
             state $check = compile_named(
                dbh     => Object,
                id      => Int,
                name    => Str,
             );
             my $arg = $check->(@_);

             my $sth = $arg->{db}->prepare('INSERT INTO contacts VALUES (?, ?)');
             $sth->execute($arg->{id}, $arg->{name});
          }

       Looks simple, right? Did you spot that it will always die with an error message Can't call
       method "prepare" on an undefined value?

       This is because we defined a parameter called 'dbh' but later tried to refer to it as
       $arg{db}. Here, Perl gives us a pretty clear error, but sometimes the failures will be far
       more subtle. Wouldn't it be nice if instead we could do this?

          sub add_contact_to_database {
             state $check = compile_named_oo(
                dbh     => Object,
                id      => Int,
                name    => Str,
             );
             my $arg = $check->(@_);

             my $sth = $arg->dbh->prepare('INSERT INTO contacts VALUES (?, ?)');
             $sth->execute($arg->id, $arg->name);
          }

       If we tried to call "$arg->db", it would fail because there was no such method.

       Well, that's exactly what "compile_named_oo" does.

       As well as giving you nice protection against mistyped parameter names, It also looks
       kinda pretty, I think. Hash lookups are a little faster than method calls, of course
       (though Type::Params creates the methods using Class::XSAccessor if it's installed, so
       they're still pretty fast).

       An optional parameter "foo" will also get a nifty "$arg->has_foo" predicate method. Yay!

       "compile_named_oo" gives you some extra options for parameters.

          sub add_contact_to_database {
             state $check = compile_named_oo(
                dbh     => Object,
                id      => Int,    { default => '0', getter => 'identifier' },
                name    => Str,    { optional => 1, predicate => 'has_name' },
             );
             my $arg = $check->(@_);

             my $sth = $arg->dbh->prepare('INSERT INTO contacts VALUES (?, ?)');
             $sth->execute($arg->identifier, $arg->name) if $arg->has_name;
          }

       "getter" Str
           The "getter" option lets you choose the method name for getting the argument value.

       "predicate" Str
           The "predicate" option lets you choose the method name for checking the existence of
           an argument. By setting an explicit predicate method name, you can force a predicate
           method to be generated for non-optional arguments.

       The objects returned by "compile_named_oo" are blessed into lightweight classes which have
       been generated on the fly. Don't expect the names of the classes to be stable or
       predictable. It's probably a bad idea to be checking "can", "isa", or "DOES" on any of
       these objects. If you're doing that, you've missed the point of them.

       They don't have any constructor ("new" method). The $check coderef effectively is the
       constructor.

       "validate_named_oo(\@_, @spec)"

       This function doesn't even exist. :D

       "multisig(@alternatives)"

       Type::Params can export a "multisig" function that compiles multiple alternative
       signatures into one, and uses the first one that works:

          state $check = multisig(
             [ Int, ArrayRef ],
             [ HashRef, Num ],
             [ CodeRef ],
          );

          my ($int, $arrayref) = $check->( 1, [] );      # okay
          my ($hashref, $num)  = $check->( {}, 1.1 );    # okay
          my ($code)           = $check->( sub { 1 } );  # okay

          $check->( sub { 1 }, 1.1 );  # throws an exception

       Coercions, slurpy parameters, etc still work.

       The magic global "${^TYPE_PARAMS_MULTISIG}" is set to the index of the first signature
       which succeeded.

       The present implementation involves compiling each signature independently, and trying
       them each (in their given order!) in an "eval" block. The only slightly intelligent part
       is that it checks if "scalar(@_)" fits into the signature properly (taking into account
       optional and slurpy parameters), and skips evals which couldn't possibly succeed.

       It's also possible to list coderefs as alternatives in "multisig":

          state $check = multisig(
             [ Int, ArrayRef ],
             sub { ... },
             [ HashRef, Num ],
             [ CodeRef ],
             compile_named( needle => Value, haystack => Ref ),
          );

       The coderef is expected to die if that alternative should be abandoned (and the next
       alternative tried), or return the list of accepted parameters. Here's a full example:

          sub get_from {
             state $check = multisig(
                [ Int, ArrayRef ],
                [ Str, HashRef ],
                sub {
                   my ($meth, $obj);
                   die unless is_Object($obj);
                   die unless $obj->can($meth);
                   return ($meth, $obj);
                },
             );

             my ($needle, $haystack) = $check->(@_);

             for (${^TYPE_PARAMS_MULTISIG}) {
                return $haystack->[$needle] if $_ == 0;
                return $haystack->{$needle} if $_ == 1;
                return $haystack->$needle   if $_ == 2;
             }
          }

          get_from(0, \@array);      # returns $array[0]
          get_from('foo', \%hash);   # returns $hash{foo}
          get_from('foo', $obj);     # returns $obj->foo

       The default error message is just "Parameter validation failed".  You can pass an option
       hashref as the first argument with an informative message string:

          sub foo {
             state $OptionsDict = Dict[...];
             state $check = multisig(
                { message => 'USAGE: $object->foo(\%options?, $string)' },
                [ Object, $OptionsDict, StringLike ],
                [ Object, StringLike ],
             );
             my ($self, @args) = $check->(@_);
             my ($opts, $str)  = ${^TYPE_PARAMS_MULTISIG} ? ({}, @args) : @_;
             ...;
          }

          $obj->foo(\%opts, "Hello");
          $obj->foo("World");

       "wrap_subs( $subname1, $wrapper1, ... )"

       It's possible to turn the check inside-out and instead of the sub calling the check, the
       check can call the original sub.

       Normal way:

          use Type::Param qw(compile);
          use Types::Standard qw(Int Str);

          sub foobar {
             state $check = compile(Int, Str);
             my ($foo, $bar) = @_;
             ...;
          }

       Inside-out way:

          use Type::Param qw(wrap_subs);
          use Types::Standard qw(Int Str);

          sub foobar {
             my ($foo, $bar) = @_;
             ...;
          }

          wrap_subs foobar => [Int, Str];

       "wrap_subs" takes a hash of subs to wrap. The keys are the sub names and the values are
       either arrayrefs of arguments to pass to "compile" to make a check, or coderefs that have
       already been built by "compile", "compile_named", or "compile_named_oo".

       "wrap_methods( $subname1, $wrapper1, ... )"

       "wrap_methods" also exists, which shifts off the invocant from @_ before the check, but
       unshifts it before calling the original sub.

          use Type::Param qw(wrap_subs);
          use Types::Standard qw(Int Str);

          sub foobar {
             my ($self, $foo, $bar) = @_;
             ...;
          }

          wrap_subs foobar => [Int, Str];

       Invocant

       Type::Params exports a type Invocant on request. This gives you a type constraint which
       accepts classnames and blessed objects.

        use Type::Params qw( compile Invocant );

        sub my_method {
          state $check = compile(Invocant, ArrayRef, Int);
          my ($self_or_class, $arr, $ix) = $check->(@_);

          return $arr->[ $ix ];
        }

       ArgsObject

       Type::Params exports a parameterizable type constraint ArgsObject.  It accepts the kinds
       of objects returned by "compile_named_oo" checks.

         package Foo {
           use Moo;
           use Type::Params 'ArgsObject';

           has args => (
             is  => 'ro',
             isa => ArgsObject['Bar::bar'],
           );
         }

         package Bar {
           use Types::Standard -types;
           use Type::Params 'compile_named_oo';

           sub bar {
             state $check = compile_named_oo(
               xxx => Int,
               yyy => ArrayRef,
             );
             my $args = &$check;

             return 'Foo'->new( args => $args );
           }
         }

         Bar::bar( xxx => 42, yyy => [] );

       The parameter "Bar::bar" refers to the caller when the check is compiled, rather than when
       the parameters are checked.

ENVIRONMENT
       "PERL_TYPE_PARAMS_XS"
           Affects the building of accessors for "compile_named_oo". If set to true, will use
           Class::XSAccessor. If set to false, will use pure Perl. If this environment variable
           does not exist, will use Class::XSAccessor if it is available.

BUGS
       Please report any bugs to <https://github.com/tobyink/p5-type-tiny/issues>.

SEE ALSO
       The Type::Tiny homepage <https://typetiny.toby.ink/>.

       Type::Tiny, Type::Coercion, Types::Standard.

AUTHOR
       Toby Inkster <tobyink AT cpan.org>.

COPYRIGHT AND LICENCE
       This software is copyright (c) 2013-2014, 2017-2021 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.

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