# Where's the contravariance?

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?

-
And the question is... what? What does "there should be contravariance here" actually mean? –  oxbow_lakes May 24 '11 at 16:17
When I am told that a relation is contravariant, I expect there to be a subtype relation `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
In scala, the variance annotation "-" indicates that a type is contravariant. Your stack type has no such relation and, in any case, a `Stack[Apple]` is not a super-type of `Stack[Fruit]` logically, even if you added one. –  oxbow_lakes May 24 '11 at 16:36
Stack is certainly not contravariant. But the argument of `push` should be. –  Edward Z. Yang May 24 '11 at 16:40

You're looking at the same relationship. Let's think about what `Stack[+A]` means: if `C` is a subclass of `A`, then `Stack[C]` is treated as a subclass of `Stack[A]`, i.e., it can fill in for class `A` anywhere; with all methods annotated with superset generics, this is of course true, as you have pointed out.

But you haven't designed your original class to make the argument of `push` be in the contravariant position. These relations naturally arise when you impose restrictions on what you can handle--then, if a subclass means that the method can handle less, `C[Subclass]` acts as a superclass of `C[Original]` since `C[Original]` can handle everything that the subclass can handle (and more). But `push` can handle anything the way you've defined it.

So this is exactly how type bounds and variance interact: if you allow type widening in exactly those spots that are in contravariant position (i.e. which would otherwise restrict you), then you are allowed to be covariant. Otherwise you must be invariant or contravariant. (Pop doesn't allow you to be contravariant, so you'd have to be invariant. See, for example, the mutable collections, where invariance is the norm for exactly this reason--you're not free to widen the type on push.)

-
So are you saying I should have written: push[A >: C](X : C) : Stack[A]? –  Edward Z. Yang May 24 '11 at 16:41
@Edward Z. Yang - I am saying that you cannot write `push` for a covariant `Stack` without `B >: A`, and if you write it the natural way you don't see the arrows flipping. You need a case where there is a contrast between arrows that flip and those that don't. –  Rex Kerr May 24 '11 at 17:40