If one has a List object (non-generic), one can store into it anything that can be cast into Object, but there's no way of knowing at compile time what type of things one will get out of it. By contrast, if one has a generic List<Animal>, the only things one can store into it are Animal or derivatives thereof, and the compiler can know that the only things that will be pulled out of it will be Animal. The compiler can thus allow things to be pulled out of the List and stored directly into fields of type Animal without any need for run-time type checking.
Additionally, if the generic type parameter of a generic class happens to be a value type, use of generic types can eliminate the need for casting to and from Object, a process called "Boxing" which converts value-type entities into reference-type objects; boxing is somewhat slow, and can sometimes alter the semantics of value-type objects, and is thus best avoided when possible.
Note that even though an object of type SomeDerivedClass may be substitutable for TheBaseClass, in general, a GenericSomething<SomeDerivedClass> is not substitutable for a GenericSomething<TheBaseClass>. The problem is that if one could substitute e.g. a List<Giraffe> for a List<Zebra>, one could pass a List<Zebra> to a routine that was expecting to take a List<Giraffe> and store an Elephant in it. There are a couple of cases where substitutability is permitted, though:
- Arrays of a derived type may be passed to routines expecting arrays of base type, provided that those routines don't try to store into those arrays any items that are not of the proper derived type.
- Interfaces may be declared to have "out" type parameters, if the only thing those interfaces will do is return ("output") values of that type. A Giraffe-supplier may be substituted for an Animal-supplier, because all it's going to do is supply Giraffes, which are in turn substitutable for animals. Such interfaces are "covariant" with respect to those parameters.
In addition, it's possible to declare interfaces to declare "in" type parameters, if the only thing the interfaces do is accept parameters of that type by value. An Animal-eater may be substituted a Giraffe-eater, because--being capable of eating all Animals, it is consequently capable of eating all Giraffes. Such interfaces are "contravariant" with respect to those parameters.