If class FooClass
and struct FooStruct
both implement IFoo
, a variable of type FooClass
is a reference to an implementation of IFoo
, but a variable of type FooStruct
is, itself, an implementation of IFoo
. The reason that covariance is possible with reference types is that if T
derives from U
, every reference to T
will be a reference to a U
; if a reference to a T
is passed a method that expects a reference to a U
, the received parameter will be a reference to U
and the method need not care that it's also a reference to T
.
The reason covariance doesn't work with structure types is that a value of type Int32
isn't a reference to a heap object that implements IComparable<Int32>
--it is an implementation of IComparable<Int32>
. A method with a parameter type IComparable<Int32>
won't be expecting to receive an implementation of IComparable<Int32>
--it will be expecting to receive a reference.
Note that some languages try to pretend that given the declarations Int32 v1; Object v2 = v1;
the type of v1
and the type of the object to which v2
holds a reference are one and the same. In reality, they're different types which inhabit different universes. Any time the runtime environment sees a class other than System.Enum
derived from System.ValueType
, it effectively defines a second type, in a universe of storage-location types which are separate from the heap types. If one says IComprable<Int32> v3 = v1;
, what one is doing is asking the system to create an instance of heap object type Int32
whose contents are loaded from v1
, and store into v3
a reference to that. Although the system allows implicit conversions from structure types to the corresponding heap-object types, and explicit conversions the other way, that doesn't mean the variables and heap objects are the same type. Indeed, the fact that conversion is needed implies that they are not.