A canonical example of patching up an otherwise covariant class is as follows:

abstract class Stack[+A] { def push[B >: A]( x: B ) : Stack[B] def top: A def pop: Stack[A]

Now, if I remove the implicit covariance and manually annotate the class, I get this:

abstract class Stack[A] { def push[B >: A]( x: B ) : Stack[B] def top [B >: A]: B def pop [B >: A]: Stack[B] def cast[B >: A]: Stack[B] }

(Quick correctness proof: a `Stack[A]`

has elements of type `A`

, so if `B`

is more permissive we can always return an `A`

in place of `B`

. Similarly, given any stack of `A`

, we can use it in place of a stack of `B`

if B can accept A.)

But now I'm a little confused: there should be contravariance somewhere here, but all of the subtype relations here seem to be the same. What happened?

To elaborate anymore, we define a contravariant functor `F`

such that `(a -> b) -> (F b -> F a)`

. In particular, the functor `F a`

on `a -> r`

is contravariant, as `(a -> b) -> ((b -> r) -> (a -> r))`

simply by composing the functions. From a formalism perspective, I expect arrows to be flipping. So from a purely syntactic perspective, I get confused when no arrows are flipping (but there should be!) Is my annotated way of writing the Scala simply a "natural" representation of the contravariance of functions, such that you don’t even notice it? Is my abstract class wrong? Is there something misleading about the second presentation?

`A <: B`

and a corresponding subtype relation`F A >: F B`

: I expect arrows to flip. But I don't see that anywhere here. So what specific part of the code I've written down makes the argument of`push`

contravariant? – Edward Z. Yang May 24 '11 at 16:20`Stack[Apple]`

is not a super-type of`Stack[Fruit]`

logically, even if you added one. – oxbow_lakes May 24 '11 at 16:36`push`

should be. – Edward Z. Yang May 24 '11 at 16:40