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.

If T is covariant or contravariant, can I determine the variance of:

K >: T

or

K <: T

I ask this because I see in the book "programming in scala", it says, in the code:

trait Cat[T] {
   def meow[K]
}

The position of K is negative, it must be contravariant(Let's assume it's not a nonvariant type).

Since we can't just declare covariance or contravariance just with a single type K, we have to use upper bound or lower bound, so the K may be:

K >: T

or

K <: T

But how can I determine new type is covariant or contravariant?

share|improve this question
    
do you mean "contravariant/covariant" instead of "contravariance/covariance"? –  Erik Allik Apr 29 at 14:13
    
Thank you, sorry for my bad English –  Freewind Apr 29 at 14:19
    
I don't see a relation between K and T in trait Cat[T]{ def meow[K] } so it doesn't seem like there needs to be a relationship. –  wheaties Apr 29 at 14:21
    
K is just indicating the position in that piece of code, actually, it may be K >: T or K <: T –  Freewind Apr 29 at 14:30
    
Unless K itself is a type parameter of Cat, I don't see how Cat can have any variance relationship with K... unless I'm mistaken. Also, I think it's a misnomer to say that "a type is covariant/contravariant"... because a type can only be *variant with respect to one or more of its type parameters. –  Erik Allik Apr 29 at 14:43

3 Answers 3

As I already noted in a comment, type variance can only be talked of in relation to a type parameter. A type itself isn't covariant or contravariant or invariant. Since K does not appear in the type parameter list of Cat, Cat has no variance in relation to K. Consider:

trait Cat[T] {
  def meow[K]
}

class SiameseCat[T] extends Cat[T] {
  def meow[K] = println("loud meow")
}

class Foo
class Bar extends Foo
class Baz extends Bar

val barSiamese = new SiameseCat[Bar]

// COMPILATION ERROR: personality.analysis.demo.Bar <: personality.analysis.demo.Foo, but class SiameseCat is invariant in type T
val fooSiamese: SiameseCat[Foo] = barSiamese
// SAME
val bazSiamese: SiameseCat[Baz] = barSiamese

// NO ERROR
barSiamese.meow[Foo]
barSiamese.meow[Bar]
barSiamese.meow[Baz]
barSiamese.meow[Int]
barSiamese.meow[Unit]

Arguably, in more lax speech, you can say a type is *variant if it's obviously a container type and takes just one type parameter, such as List[T]; i.e. one can say List is covariant, but this actually expands to "List[T] is covariant with respect to T".

However, if K did in fact appear in the type parameter list of Cat, it would make it possible to declare Cat as covariant with respect to K by prepending a + to K: Cat[T, +K], which will be allowed by the compiler because K only appears in variance-neutral positions in the body of Cat:

def meow[K]  // <-- meow doesn't take any parameters and returns `Unit`, so `K` is irrelevant with respect to variance

if, however, you were returning K from meow, you'd only be able to mark Cat as invariant or covariant with respect to K:

def meow: K  // contravariance made impossible

conversely, this:

def meow(x: K)  // covariance made impossible

would force you to either go with Cat[T, -K] (contravariant) or just Cat[T, K] (invariant).

For the reason why, either google, or see a recent answer of mine @ why the first type parameter is defined as contravariant in Function1[-A, +B]?

share|improve this answer

The type parameters of methods such as K in def meow[K] can't be co- or contravariant. The notion can only apply to type parameters of types.

Since we can't just declare covariance or contravariance just with a single type K, we have to use upper bound or lower bound

This also doesn't make sense. We can declare that MyClass is covariant in K like this:

class MyClass[+K]

This is completely unrelated to lower/upper bounds: you can have a variant type parameter with or without a bound.

share|improve this answer

Two type of variance for:

class X1
class X2 extends X1
class X3 extends X2

1) Declaration-site variance:

// covariant type-constructor:
class Cat[+T]

var cat : Cat[X2] = new Cat[X2]
var cat = new Cat[X3]
// cat = new Cat[X1] // not compiled

2) Using-site variance (by upper or lower bound limitation):

//covariant variable for invariant type constructor:
class Cat[T]

var cat : Cat[_ <: X2] = new Cat[X2]
cat = new Cat[X3]
// cat = new Cat[X1] // not compiled

Decalration-site variance used in type-constructor(container) declaration and using-site variance commonly used in method or variavle declararion.

share|improve this answer
    
What is the Foo in Cat[_ <: Foo]? –  Freewind Apr 30 at 5:54
    
My apologies. Bug fixed –  Yury Apr 30 at 6:00

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.