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scala> class C
defined class C

scala> class subC extends C
defined class subC

scala> class A { type T = C}
defined class A

scala> class subA extends A { override type T = subC}
<console>:10: error: overriding type T in class A, which equals C;
 type T has incompatible type
      class subA extends A { override type T = subC}

In the example above, I get an error message, that I can not override the type field in class A ( even if the chosen type subC extends the class C).

Is overriding a type field possible at all ? And if yes, what is wrong with the example above ?

share|improve this question

You wouldn't speak of 'overriding' with respect to types, but rather narrowing their bounds.

  1. type T ... no bounds
  2. type T <: C ... T is C or a subtype of C (which is called upper bound)
  3. type T >: C ... T is C or a supertype of C (which is called lower bound)
  4. type T = C ... T is exactly C (type alias)

Therefore, if T is a type member of trait A, and SubA is a subtype of A, in case (2) SubA may narrow T to a more particular subtype C, whereas in case (3) it could narrow it to a higher supertype of C. Case (1) doesn't impose any restrictions for SubA, while case (4) means that T is 'final' so to speak.

This has consequences for the useability of T in A—whether it may appear as a method argument's type or a method's return type.


trait C { def foo = () }
trait SubC extends C { def bar = () }

trait MayNarrow1 {
  type T <: C  // allows contravariant positions in MayNarrow1
  def m(t: T): Unit =  // this

object Narrowed1 extends MayNarrow1 {
   type T = SubC

object Narrowed2 extends MayNarrow1 {
  type T = SubC
  override def m(t: T): Unit =

It is possible to define method m in MayNarrow1 because type T occurs in contravariant position (as a method argument's type), therefore it is still valid even if T is narrowed down in a subtype of MayNarrow1 (the method body can treat t as if it were type C).

In contrast, type T = C inevitably fixes T, which would kind of correspond to making a method final. By fixing T, it can be used in a covariant position (as a method's return type):

trait Fixed extends MayNarrow1 {
  type T = C   // make that T <: C to see that it won't compile
  final def test: T = new C {}

You can now easily see that it must be forbidden to further 'override' T:

trait Impossible extends Fixed {
  override type T = SubC  // oops...

To be complete, here is the less common case of a lower bound:

trait MayNarrow2 {
  type T >: SubC  // allows covariant positions in MayNarrow2
  def test: T = new SubC {}

object Narrowed3 extends MayNarrow2 {
  type T = C

object Narrowed4 extends MayNarrow2 {
  type T = C
  override def test: T = new C {}
share|improve this answer
Note: for the subtle difference between abstract type members with bounds versus type parameters with variance annotations see Geoffrey Washburn's post in… – 0__ Jun 30 '12 at 17:31

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