Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

Sorry I have asked some questions like this one, but I still can't get a clear answer, maybe my bad English and unclear expression puzzled the kind people.

When I read the "Type Parameterization" in this article: http://www.artima.com/pins1ed/type-parameterization.html, I see there are some explanation about the type positions:

As a somewhat contrived example, consider the following class definition, where the variance of several positions is annotated with ^+ (for positive) or ^- (for negative):

   abstract class Cat[-T, +U] {
     def meow[W^-](volume: T^-, listener: Cat[U^+, T^-]^-)
     : Cat[Cat[U^+, T^-]^-, U^+]^+
   }

I can understand most of this class, except the W position. I don't understand why it marked as negative, and there is no explanation in the whole document.

It also says:

Type parameters annotated with + may only be used in positive positions, while type parameters annotated with - may only be used in negative positions.

How can I find a type with - annotation in position W to fit this negative position?

share|improve this question
    
It is a contrived example. This means it is not obliged to make any practical sense. It just illustrates a language feature (badly). –  n.m. Apr 29 '14 at 16:19
    
The example is contrived, but the positions are not. You can just focus on the meow[W^-] with the same question, and ignore the other crazy parts. –  Freewind Apr 29 '14 at 16:37
1  
Thinking about it a bit, the example is actually erroneous. W does not denote a type here and thus has no variance position. –  n.m. Apr 29 '14 at 16:53
    
@n.m. The article claims it has a position along with the method value parameters: The positions of the type parameter, W, and the two value parameters, volume and listener, are all negative –  n0741337 Apr 29 '14 at 16:58
1  
I have read this claim. It makes no sense. Position of W is not something that can have variance, because T and U, the parameters of the class, cannot appear in that position. –  n.m. Apr 29 '14 at 17:28

2 Answers 2

up vote 3 down vote accepted

The language reference says:

  • The variance position of a method parameter is the opposite of the variance position of the enclosing parameter clause.
  • The variance position of a type parameter is the opposite of the variance position of the enclosing type parameter clause.
  • The variance position of the lower bound of a type declaration or type parameter is the opposite of the variance position of the type declaration or parameter.

OK what does it mean for a type parameter to have a variance position?

class Moo[+A, -B] {
  def foo[X] (bar : Y) ...

So Y is in a contravariant position, this is clear. We can put B in its position, but not A.

But what does it mean for X to be in a contravariant position? We cannot substitute A or B or anything there, it's just a formal parameter!

That's true, but this thing can have subordinate positions which are types, and have variance. So we need to count the position of X when tracking how many times we flip variance. There's no subordinate clauses of X here, but consider this:

class Moo[+A, -B] {
  def foo[X >: Z] (bar : B) ...

We probably can replace Z with either A or B, but which is correct? Well, the position of Z is the opposite of that of X, and the position of X is the opposite of that of the top-level, which is covariant, so Z must be covariant too. Let's check:

abstract class Moo[+A, -B] {
      def foo[X >: A] (bar : B)
}    
defined class Moo

Looks like we are right!

share|improve this answer

There is a familiar example in the spec:

http://www.scala-lang.org/files/archive/spec/2.11/04-basic-declarations-and-definitions.html#variance-annotations

Sequence.append is example 4.5.2 in the pdf, but the markdown isn't numbered at the moment.

abstract class Sequence[+A] {
  def append[B >: A](x: Sequence[B]): Sequence[B]
}

In real life, see the doc for Seq.++, ignoring the "use case" and clicking on the "full signature" to show the lower bound.

This is the same pattern as in other widening operations like Option.getOrElse, where you're getting back a possibly wider type than you started with.

Here's an example of how it makes sense in terms of substitution:

Given a Seq[Fruit], I can append a Seq[Orange]. Since Apple <: Fruit, I can also append the oranges to a Seq[Apple] and get fruits back.

That's why the B type parameter wants to be bound by a covariant parameter. The variance position of B is classified as negative, for purposes of variance checking, but B itself is not annotated.

Funny thing is that this parses:

scala> trait X { def append[-](): Unit }
defined trait X
share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.