Data
has two parameters, E
which must ultimately be an instance of itself, and S
which must be able to Writer
an instance of itself (more specifically, the same kind of instance of itself specified by E
). Finally, Data<E,S>
also qualifies as/inherits capabilities from Entity
parametrized by the same E
and S
(i.e., Entity
is of Data<E,S>
and Writer<E>
).
A concrete implementation might look something like
NumericalData extends Data<NumericalData, NumWriter>
where NumWriter
implements/extends Writer<NumericalData>
and NumericalData
also qualifies as an Entity<NumericalData, NumWriter>
.
EDIT:
Why do something like this? One might want to define generic methods in the abstract class that rely on an argument/return meeting the criteria Data<E,S>
, but also want to be able to return/work with the more explicit type. For example, in Data<E,S>
, there might be
E doSomething(E toThis) { toThis.aDataClassMethod(); return toThis; }
The class can make the first call, because it knows E
is a Data<E,S>
, and return the more specific type because it knows toThis
is an E
.
To be honest, recursive generics are typically the road to too clever. They can be useful, but many times they're just "neat" and one tries to bend the problem around something clever rather than vice versa.