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If all that coding for creating accessors using AUTOLOAD looks messy, rest assured that you really don't need to tackle it, because there's a CPAN module that does it a bit more directly: Class::MethodMaker.
For example, a simplified version of the Animal class might be defined as follows:
package Animal;
use Class::MethodMaker
new_with_init => 'new',
get_set => [-eiffel => [qw(color height name age)]],
abstract => [qw(sound)],
;
sub init {
my $self = shift;
$self->set_color($self->default_color);
}
sub named {
my $self = shift->new;
$self->set_name(shift);
$self;
}
sub speak {
my $self = shift;
print $self->name, " goes ", $self->sound, "\n";
}
sub eat {
my $self = shift;
my $food = shift;
print $self->name, " eats $food\n";
}
sub default_color {
"brown";
}The getters and setters for the four instance attributes (name, height, color, and age) are defined automatically, using the method color to get the color and set_color to set the color. (The eiffel flag says "do it the way the Eiffel language does it," which is the way it should be done here.) The messy blessing step is now hidden behind a simple new method. The initial color is defined as the default color, as before, because the init method is automatically called from new.
However, you can still call Horse->named('Mr. Ed') because it immediately calls the new routine as well.
The sound method is automatically generated as an abstract method. Abstract methods are placeholders, meant to be defined in a subclass. If a subclass fails to define the method, the method generated for Animal's sound dies.
You lose the ability to call the getters (such as name) on the class itself, rather than an instance. In turn, this breaks your prior usage of calling speak and eat on generic animals, since they call the accessors. One way around this is to define a more general version of name to handle either a class or instance and then change the other routines to call it:
sub generic_name {
my $either = shift;
ref $either ? $either->name : "an unnamed $either";
}
sub speak {
my $either = shift;
print $either->generic_name, " goes ", $either->sound, "\n";
}
sub eat {
my $either = shift;
my $food = shift;
print $either->generic_name, " eats $food\n";
}There. Now it's looking nearly drop-in compatible with the previous definition, except for those friend classes that referenced the attribute names directly in the hash as the initial-cap-keyed versions (such as Color) rather than through the accessors ($self->color).
That brings up the maintenance issue again. The more you can decouple your implementation (hash versus array, names of hash keys, or types of elements) from the interface (method names, parameter lists, or types of return values), the more flexible and maintainable your system becomes.
That flexibility is not free, however. The cost of a method call is higher than the cost of a hash lookup, so it may be acceptable (or even necessary) for a friend class to peer inside. You may have to pay the programmer-time price of development and maintenance so you don't pay the runtime price of an overly flexible system.
On the other hand, don't go overboard in the other direction. Many anecdotes float around about systems where everything was so indirected (to be flexible) that the system ran too slowly to be used.
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| 11.4. Using AUTOLOAD for Accessors |  | 11.6. Multiple Inheritance |
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