[[Property:title|I2E: Genericity]] [[Property:weight|-6]] [[Property:uuid|091c0b65-73de-b454-b3f2-d8752983780e]] Building software components (classes) as implementations of abstract data types yields systems with a solid architecture but does not in itself ensure reusability and extendibility. Two key techniques address the problem: genericity (unconstrained or constrained) and inheritance. Let us look first at the unconstrained form. To make a class generic is to give it '''formal generic parameters''' representing as unknown types, as in these examples from EiffelBase, an open-source library covering basic data structures and algorithms: ARRAY [G] LIST [G] LINKED_LIST [G] These classes describe data structures -- arrays, lists without commitment to a specific representation, lists in linked representation -- containing objects of a certain type. The formal generic parameter G denotes this type. A class such as these doesn't quite yet describe a type, but a type template, since G itself denotes an unknown type. To derive a directly usable list or array type, you must provide a type corresponding to G, called an '''actual generic parameter'''; this may be either an expanded type, including basic types such as INTEGER, or a reference type. Here are some possible generic derivations: il: LIST [INTEGER] aa: ARRAY [ACCOUNT] aal: LIST [ARRAY [ACCOUNT]] As the last example indicates, an actual generic parameter may itself be generically derived. It would not be possible, without genericity, to have static type checking in a realistic object-oriented language. A variant of this mechanism, constrained genericity, will enable a class to place specific requirements on possible actual generic parameters. Constrained genericity will be described after inheritance.