The building blocks of GOOPS are classes, slot definitions, instances, generic functions and methods. A class is a grouping of inheritance relations and slot definitions. An instance is an object with slots that are allocated following the rules implied by its class’s superclasses and slot definitions. A generic function is a collection of methods and rules for determining which of those methods to apply when the generic function is invoked. A method is a procedure and a set of specializers that specify the type of arguments to which the procedure is applicable.
Of these entities, GOOPS represents classes, generic functions and methods as “metaobjects”. In other words, the values in a GOOPS program that describe classes, generic functions and methods, are themselves instances (or “objects”) of special GOOPS classes that encapsulate the behaviour, respectively, of classes, generic functions, and methods.
(The other two entities are slot definitions and instances. Slot definitions are not strictly instances, but every slot definition is associated with a GOOPS class that specifies the behaviour of the slot as regards accessibility and protection from garbage collection. Instances are of course objects in the usual sense, and there is no benefit from thinking of them as metaobjects.)
The “metaobject protocol” (or “MOP”) is the specification of the generic functions which determine the behaviour of these metaobjects and the circumstances in which these generic functions are invoked.
For a concrete example of what this means, consider how GOOPS calculates
the set of slots for a class that is being defined using
define-class. The desired set of slots is the union of the new
class’s direct slots and the slots of all its superclasses. But
define-class itself does not perform this calculation. Instead,
there is a method of the
initialize generic function that is
specialized for instances of type
<class>, and it is this method
that performs the slot calculation.
initialize is a generic function which GOOPS calls whenever a new
instance is created, immediately after allocating memory for a new
instance, in order to initialize the new instance’s slots. The sequence
of steps is as follows.
maketo make a new instance of the
<class>class, passing as initialization arguments the superclasses, slot definitions and class options that were specified in the
makeallocates memory for the new instance, and invokes the
initializegeneric function to initialize the new instance’s slots.
initializegeneric function applies the method that is specialized for instances of type
<class>, and this method performs the slot calculation.
In other words, rather than being hardcoded in
default behaviour of class definition is encapsulated by generic
function methods that are specialized for the class
It is possible to create a new class that inherits from
which is called a “metaclass”, and to write a new
method that is specialized for instances of the new metaclass. Then, if
define-class form includes a
#:metaclass class option
whose value is the new metaclass, the class that is defined by the
define-class form will be an instance of the new metaclass rather
than of the default
<class>, and will be defined in accordance
with the new
initialize method. Thus the default slot
calculation, as well as any other aspect of the new class’s relationship
with its superclasses, can be modified or overridden.
In a similar way, the behaviour of generic functions can be modified or
overridden by creating a new class that inherits from the standard
generic function class
<generic>, writing appropriate methods
that are specialized to the new class, and creating new generic
functions that are instances of the new class.
The same is true for method metaobjects. And the same basic mechanism
allows the application class author to write an
that is specialized to their application class, to initialize instances
of that class.
Such is the power of the MOP. Note that
initialize is just one
of a large number of generic functions that can be customized to modify
the behaviour of application objects and classes and of GOOPS itself.
Each following section covers a particular area of GOOPS functionality,
and describes the generic functions that are relevant for customization
of that area.