# Method return type covariance

How can I define that method returns List[+AnyRef]? I tried:

``````def a[T <: AnyRef](): List[T] = List[AnyRef]()
``````

But for some reason it does not compile.

EDIT: according to Wong I should use

``````def a[T <: AnyRef](): List[T] = List[T]()
``````

but is there any way to be able to return any subtype of AnyRef, for example

``````def a[T <: AnyRef](): List[T] = if (value) List[T]() else List[Option[String]]()
``````

Here Option[String] is descendant of Anyref, but compiler does not accept it

So main question is if I can declare method with covariant return type like List[+AnyRef]

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If the compiler can't figure out what you want, how are we supposed to figure it out without further explanation? –  Kim Stebel Feb 9 '11 at 6:44
You figure it out by typing it into the interpreter. –  Y.H Wong Feb 9 '11 at 7:01
Just finished editing my answer. Let me know if it's too much :) –  Y.H Wong Feb 10 '11 at 7:45

Let's make a couple observations and experiment with a few ways of letting the compiler to decide on your return type:

1) Notice the statement `if (value) List[T]() else List[Option[String]]()` returns 2 different specific types but the `if` statement must return the same type from its then and else clauses. So when this statement returns a value, the compiler will need to infer the most general type for the 2 clauses to bring in a consistent constraint.

2) Notice that type variable `T` is dependent on the exact type you pass in when you call `a()`, for example `a[scala.io.Source]()`. In the method declaration you gave `T` an upper bound `T <: AnyRef`, which means the compiler has to find the most general type that is the union of any type that is a subtype of AnyRef and Option[String].

3) Notice the return type that is inferred by the compiler by removing the return type declaration. i.e. `def a[T <: AnyRef]() = if (true) List[T]() else List[Option[T]]()`. The compiler gave `a()` a return type `List[AnyRef]`. This sort of make sense because that is the only possibility for the most general type between anything `T` that is a subtype of `AnyRef` and `Option[of that anything T]`.

4) Now try `def a[T <: AnyRef]() = if (true) List[T]() else List[Option[String]]()`. The return type inferred is now `List[java.lang.Object]`. The reason is the `String` class in Scala 2.8 is actually `java.lang.String`, so according to my best guess, now the most general type has to escape the `scala.*` hierarchy and end up in `java.lang.Object` for unknown reasons.

5) Since `AnyRef` is really just alias of `java.lang.Object`, you can do `def a[T <: AnyRef](): List[AnyRef] = if (true) List[T]() else List[Option[String]]()` to force a return type of `List[AnyRef]`.

If you just want to return any subtype of AnyRef, you basically have to do this:

``````def a(): List[AnyRef] = ...
``````

which basically returns the super class, and you have to cast the returned `List[AnyRef]` down using `.asInstanceOf[T]`. Alternatively:

``````def a[T <: AnyRef](): List[T] = List[T]()
``````

will gives you a specific type T, but you can't return 2 different types in an `if` statement like in your example, where one may be more specific and the other, and expect it to always return the more specific type supplied by you when you call the method. Because the compiler has no way to guarantee the type in your `if` statement will always be List[T] just by doing type checking. Did I make it clearer?

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@Thanks but it is not exactly what I wanted, see edit –  Nutel Feb 9 '11 at 15:06

``````val x = a()
``````

What is the type of `x`? One thing you cannot say is that the type of `x` depends on something -- it can only depend on the static context of the line above and the method's type signature. So the example in which you return `T` or `Option[String]` can never work, because there is no way to tell which will be returned from the method signature.

What, exactly, is your use case? How do you intend to use it, that you want such a thing?

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``````def a[T <: AnyRef](): List[T] = List[AnyRef]()
doesn't compile because the return value is a `List[AnyRef]`, which isn't a `List[T]`. The other way around does:
``````def a[T <: AnyRef](): List[AnyRef] = List[T]()