=cut
use Moose;
-use Scalar::Util 'looks_like_number';
+use Scalar::Util 'looks_like_number', 'blessed';
use Moose::Util::TypeConstraints ();
with 'MooseX::Emulate::Class::Accessor::Fast';
use namespace::clean -except => 'meta';
my $self = shift;
return unless $self->has_args_constraints;
- my $total = 0;
- foreach my $tc( @{$self->args_constraints}) {
- if($tc->is_a_type_of('Ref')) {
- if($tc->can('parameters') && $tc->has_parameters) {
- my $total_params = scalar(@{ $tc->parameters||[] });
- $total = $total + $total_params;
- } else {
- # Its a Reftype but we don't know the number of params it
- # actually validates.
+ # If there is one constraint and its a ref, we need to decide
+ # if this number 'unknown' number or if the ref allows us to
+ # determine a length.
+
+ if(scalar @{$self->args_constraints} == 1) {
+ my $tc = $self->args_constraints->[0];
+ if(
+ $tc->can('is_strictly_a_type_of') &&
+ $tc->is_strictly_a_type_of('Tuple'))
+ {
+ my @parameters = @{ $tc->parameters||[]};
+ if( defined($parameters[-1]) and exists($parameters[-1]->{slurpy})) {
return undef;
+ } else {
+ return my $total_params = scalar(@parameters);
}
+ } elsif($tc->is_a_type_of('Ref')) {
+ return undef;
} else {
- $total++;
+ return 1; # Its a normal 1 arg type constraint.
}
+ } else {
+ # We need to loop through and error on ref types. We don't allow a ref type
+ # in the middle.
+ my $total = 0;
+ foreach my $tc( @{$self->args_constraints}) {
+ if($tc->is_a_type_of('Ref')) {
+ die "$tc is a Ref type constraint. You cannot mix Ref and non Ref type constraints in Args for action ${\$self->reverse}";
+ } else {
+ ++$total;
+ }
+ }
+ return $total;
}
-
- return $total;
}
has args_constraints => (
my $self = shift;
return unless $self->has_captures_constraints;
- my $total = 0;
- foreach my $tc( @{$self->captures_constraints}) {
- if($tc->is_a_type_of('Ref')) {
- if($tc->can('parameters') && $tc->has_parameters) {
- my $total_params = scalar(@{ $tc->parameters||[] });
- $total = $total + $total_params;
+ # If there is one constraint and its a ref, we need to decide
+ # if this number 'unknown' number or if the ref allows us to
+ # determine a length.
+
+ if(scalar @{$self->captures_constraints} == 1) {
+ my $tc = $self->captures_constraints->[0];
+ if(
+ $tc->can('is_strictly_a_type_of') &&
+ $tc->is_strictly_a_type_of('Tuple'))
+ {
+ my @parameters = @{ $tc->parameters||[]};
+ if( defined($parameters[-1]) and exists($parameters[-1]->{slurpy})) {
+ return undef;
} else {
- # Its a Reftype but we don't know the number of params it
- # actually validates. This is not currently permitted in
- # a capture...
- die "You cannot use CaptureArgs($tc) in ${\$self->reverse} because we cannot determined the number of its parameters";
+ return my $total_params = scalar(@parameters);
}
+ } elsif($tc->is_a_type_of('Ref')) {
+ die "You cannot use CaptureArgs($tc) in ${\$self->reverse} because we cannot determined the number of its parameters";
} else {
- $total++;
+ return 1; # Its a normal 1 arg type constraint.
+ }
+ } else {
+ # We need to loop through and error on ref types. We don't allow a ref type
+ # in the middle.
+ my $total = 0;
+ foreach my $tc( @{$self->captures_constraints}) {
+ if($tc->is_a_type_of('Ref')) {
+ die "$tc is a Ref type constraint. You cannot mix Ref and non Ref type constraints in CaptureArgs for action ${\$self->reverse}";
+ } else {
+ ++$total;
+ }
}
+ return $total;
}
-
- return $total;
}
has captures_constraints => (
sub resolve_type_constraint {
my ($self, $name) = @_;
- my @tc = eval "package ${\$self->class}; $name";
- return @tc if $tc[0];
- return Moose::Util::TypeConstraints::find_or_parse_type_constraint($name);
+
+ if(defined($name) && blessed($name) && $name->can('check')) {
+ # Its already a TC, good to go.
+ return $name;
+ }
+
+ # This is broken for when there is more than one constraint
+ if($name=~m/::/) {
+ eval "use Type::Registry; 1" || die "Can't resolve type constraint $name without installing Type::Tiny";
+ my $tc = Type::Registry->new->foreign_lookup($name);
+ return defined $tc ? $tc : die "'$name' not a full namespace type constraint in ${\$self->private_path}";
+ }
+
+ my @tc = grep { defined $_ } (eval("package ${\$self->class}; $name"));
+
+ unless(scalar @tc) {
+ # ok... so its not defined in the package. we need to look at all the roles
+ # and superclasses, look for attributes and figure it out.
+ # Superclasses take precedence;
+
+ my @supers = $self->class->can('meta') ? map { $_->meta } $self->class->meta->superclasses : ();
+ my @roles = $self->class->can('meta') ? $self->class->meta->calculate_all_roles : ();
+
+ # So look through all the super and roles in order and return the
+ # first type constraint found. We should probably find all matching
+ # type constraints and try to do some sort of resolution.
+
+ foreach my $parent (@roles, @supers) {
+ if(my $m = $parent->get_method($self->name)) {
+ if($m->can('attributes')) {
+ my ($key, $value) = map { $_ =~ /^(.*?)(?:\(\s*(.+?)\s*\))?$/ }
+ grep { $_=~/^Args\(/ or $_=~/^CaptureArgs\(/ }
+ @{$m->attributes};
+ next unless $value eq $name;
+ my @tc = eval "package ${\$parent->name}; $name";
+ if(scalar(@tc)) {
+ return map { ref($_) ? $_ : Moose::Util::TypeConstraints::find_or_parse_type_constraint($_) } @tc;
+ } else {
+ return;
+ }
+ }
+ }
+ }
+
+ my $classes = join(',', $self->class, @roles, @supers);
+ die "'$name' not a type constraint in '${\$self->private_path}', Looked in: $classes";
+ }
+
+ if(scalar(@tc)) {
+ return map { ref($_) ? $_ : Moose::Util::TypeConstraints::find_or_parse_type_constraint($_) } @tc;
+ } else {
+ return;
+ }
}
has number_of_captures => (
sub match {
my ( $self, $c ) = @_;
+ return $self->match_args($c, $c->req->args);
+}
- # If infinite args, we always match
- return 1 if $self->normalized_arg_number == ~0;
+sub match_args {
+ my ($self, $c, $args) = @_;
+ my @args = @{$args||[]};
# There there are arg constraints, we must see to it that the constraints
# check positive for each arg in the list.
$self->args_constraints->[0]->is_a_type_of('ClassName')
)
) {
- return $self->args_constraints->[0]->check($c->req->args);
+ # Ok, the the type constraint is a ref type, which is allowed to have
+ # any number of args. We need to check the arg length, if one is defined.
+ # If we had a ref type constraint that allowed us to determine the allowed
+ # number of args, we need to match that number. Otherwise if there was an
+ # undetermined number (~0) then we allow all the args. This is more of an
+ # Optimization since Tuple[Int, Int] would fail on 3,4,5 anyway, but this
+ # way we can avoid calling the constraint when the arg length is incorrect.
+ if(
+ $self->normalized_arg_number == ~0 ||
+ scalar( @args ) == $self->normalized_arg_number
+ ) {
+ return $self->args_constraints->[0]->check($args);
+ } else {
+ return 0;
+ }
# Removing coercion stuff for the first go
#if($self->args_constraints->[0]->coercion && $self->attributes->{Coerce}) {
# my $coerced = $self->args_constraints->[0]->coerce($c) || return 0;
} else {
# Because of the way chaining works, we can expect args that are totally not
# what you'd expect length wise. When they don't match length, thats a fail
- return 0 unless scalar( @{ $c->req->args } ) == $self->normalized_arg_number;
+ return 0 unless scalar( @args ) == $self->normalized_arg_number;
- for my $i(0..$#{ $c->req->args }) {
- $self->args_constraints->[$i]->check($c->req->args->[$i]) || return 0;
+ for my $i(0..$#args) {
+ $self->args_constraints->[$i]->check($args[$i]) || return 0;
}
return 1;
}
} else {
+ # If infinite args with no constraints, we always match
+ return 1 if $self->normalized_arg_number == ~0;
+
# Otherwise, we just need to match the number of args.
- return scalar( @{ $c->req->args } ) == $self->normalized_arg_number;
+ return scalar( @args ) == $self->normalized_arg_number;
}
}
my @captures = @{$captures||[]};
return 1 unless scalar(@captures); # If none, just say its ok
+ return $self->has_captures_constraints ?
+ $self->match_captures_constraints($c, $captures) : 1;
- if($self->has_captures_constraints) {
- if(
- $self->captures_constraints_count == 1 &&
- (
- $self->captures_constraints->[0]->is_a_type_of('Ref') ||
- $self->captures_constraints->[0]->is_a_type_of('ClassName')
- )
- ) {
- return $self->captures_constraints->[0]->check($captures);
- } else {
- for my $i(0..$#captures) {
- $self->captures_constraints->[$i]->check($captures[$i]) || return 0;
- }
- return 1;
- }
+ return 1;
+}
+
+sub match_captures_constraints {
+ my ($self, $c, $captures) = @_;
+ my @captures = @{$captures||[]};
+
+ # Match is positive if you don't have any.
+ return 1 unless $self->has_captures_constraints;
+
+ if(
+ $self->captures_constraints_count == 1 &&
+ (
+ $self->captures_constraints->[0]->is_a_type_of('Ref') ||
+ $self->captures_constraints->[0]->is_a_type_of('ClassName')
+ )
+ ) {
+ return $self->captures_constraints->[0]->check($captures);
} else {
+ for my $i(0..$#captures) {
+ $self->captures_constraints->[$i]->check($captures[$i]) || return 0;
+ }
return 1;
- }
- return 1;
+ }
+
}
+
sub compare {
my ($a1, $a2) = @_;
return $a1->normalized_arg_number <=> $a2->normalized_arg_number;
Returning true from this method causes the chain match to continue, returning
makes the chain not match (and alternate, less preferred chains will be attempted).
+=head2 match_captures_constraints ($c, \@captures);
+
+Does the \@captures given match any constraints (if any constraints exist). Returns
+true if you ask but there are no constraints.
+
+=head2 match_args($c, $args)
+
+Does the Args match or not?
+
=head2 resolve_type_constraint
-Trys to find a type constraint if you have on on a type constrained method.
+Tries to find a type constraint if you have on on a type constrained method.
=head2 compare
projects / catagits/Catalyst-Runtime.git / blobdiff