Disclaimer: I wrote
TEnumerable<T>. If I were to do it again, I'd probably have written it with less performance and more simplicity in mind, as I've learned this optimization confuses a lot of people.
It's designed to avoid a virtual call in
for-in loops while maintaining compatibility with polymorphism. This is the general pattern:
Base defines protected virtual abstract method
V and public non-virtual method
M dispatches to
V, so polymorphic calls via a
Base-typed variable will route to overridden behaviour of
Descendant classes such as
Desc implement static override of
Base.M) which contains the implementation, and implement an override of
V which calls
Desc.M. Calls of
Desc-typed variables go direct to the implementation without a virtual dispatch.
Concrete example: when the compiler generates code for this sequence:
for x in someCollection do
... the compiler looks for a method called
GetEnumerator on the static type of
someCollection, and a method called
MoveNext on the type it returns (and similarly for
Current property). If this method has static dispatch, a virtual call can be eliminated.
This is most important for loops, and thus
Current accessor. But in order for the optimization to work, the return type of the
GetEnumerator method must be covariant, that is, it needs to statically return the correct derived enumerator type. But in Delphi, unlike C++ , it is not possible to override an ancestor method with a more-derived return-type, so the same trick needs to be applied for a different reason, to change the return type in descendants.
The optimization also potentially permits inlining of the
GetCurrent method calls, as it is very difficult for a static compiler to "see through" virtual calls and still be fast.
 C++ support return-value covariance on overridden methods.