# What is the variance of `K >: T` and `K <: T` if `T` is covariant or contravariant?

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?

-
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

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]?

-

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.

-

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.

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