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# Why is parameter in contravariant position?

I'm trying to use a covariant type parameter inside a trait to construct a case-class like so:

``````trait MyTrait[+T] {
private case class MyClass(c: T)
}
``````

compiler says:

``````error: covariant type T occurs in contravariant position in type T of value c
``````

I then tried the following but it also didn't work:

``````trait MyTrait[+T] {
private case class MyClass[U <: T](c: U)
}
``````

the error this time is:

``````error: covariant type T occurs in contravariant position in type >: Nothing <: T of type U
``````

Could somebody explain why the T is in a covariant position here and suggest a solution for this problem? Thx!

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Could you explain what it is you really want to do? Why do you want T covariant and not invariant? – Daniel Martin Mar 8 '12 at 15:40

This is a fundamental feature of object-oriented programming that doesn't get as much attention as it deserves.

Suppose you have a collection `C[+T]`. What the `+T` means is that if `U <: T`, then `C[U] <: C[T]`. Fair enough. But what does it mean to be a subclass? It means that every method should work that worked on the original class. So, suppose you have a method `m(t: T)`. This says you can take any `t` and do something with it. But `C[U]` can only do things with `U`, which might not be all of `T`! So you have immediately contradicted your claim that `C[U]` is a subclass of `C[T]`. It's not. There are things you can do with a `C[T]` that you can't do with a `C[U]`.

Now, how do you get around this?

One option is to make the class invariant (drop the `+`). Another option is that if you take a method parameter, to allow any superclass as well: `m[S >: T](s: S)`. Now if `T` changes to `U`, it's no big deal: a superclass of `T` is also a superclass of `U`, and the method will work. (However, you then have to change your method to be able to handle such things.)

With a case class, it's even harder to get it right unless you make it invariant. I recommend doing that, and pushing the generics and variance elsewhere. But I'd need to see more details to be sure that this would work for your use case.

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thank you for your answer. Your solution however does not work for me in this case. Dropping covariance and making the trait invariant would work but it's not what i want here. Allowing the method (or in my case the case-class) to take a supertype is also not satisfying. I'm curious to why things are harder to get right for case-classes. Note that the same code without the case keyword works just fine. – lapislazuli Mar 8 '12 at 16:50
@lapislazuli - Because case classes include a companion method that creates them (taking `T` as an argument), so you have to obey the method restrictions above. If you don't include `case`, then the class doesn't imply a method in the interface that takes `T`s. – Rex Kerr Mar 8 '12 at 16:57
thank you rex, now it makes sense to me! – lapislazuli Mar 8 '12 at 18:21
What's the reason that, in `class F[+A] { def f(x: A) = ??? }`, that `x` is in `contravariant position`? Is it due to the `contravariance` of `T` in Function[-T1, +R? – Kevin Meredith Jul 6 at 2:35

Almost there. Here:

``````scala> trait MyTrait[+T] {
|   private case class MyClass[U >: T](c: U)
| }
defined trait MyTrait
``````

Which means `MyClass[Any]` is valid for all `T`. That is at the root of why one cannot use `T` in that position, but demonstrating it requires more code than I'm in the mood for at the moment. :-)

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