Unsealed types should not implement
IEquatable<T>, since the only way to ensure (or even make it likely) that derived types will implement it correctly is to implement
IEquatable<T>.Equals(T) so as to call
Object.Equals(Object). Since whole purpose of
IEquatable<T> is to avoid wasting CPU time converting things to
Object before comparing them, an implementation which calls
Object.Equals(Object) couldn't do anything faster than the default behavior that would be achieved if the interface wasn't implemented.
Sealed class types may achieve a slight performance advantage by implementing
IEquatable<T>; the preferred style is to have
Object.Equals(Object) try to cast the parameter to
T; if the cast succeeds, use the
IEquatable<T>.Equals implementation; otherwise return
false. In no case should
Object.Equals(Object) yield different results when passed the same object instance.
Structure types may use the same pattern as sealed class types. The method of attempting the cast is a little different, since a failed cast can't return
null, but the pattern should still be the same. If a struct implements a mutating interface (as is the case with e.g.
List<T>.Enumerator, a struct that implements
IEnumerator<T>), the proper behavior of equality comparisons is a bit murky.
Note, btw, that
IEquatable<T> should be considered independent of each other. While it will often be the case that when
X.CompareTo(Y) is zero,
X.Equals(Y) will return true, some types may have a natural ordering where two things may be different without either ranking about the other. For example, one might have a
NamedThing<T> type which combines a
string and a
T. Such a type would support a natural ordering on the name, but not necessarily on
T. Two instances whose names match but whose
T's differ should return
Equals. Because of this, overriding
IComparable does not require overriding
Equals is not changed.