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I believe one can define covariance (at least, for objects) as 'the ability to use a value of a narrower (sub) type in place of a value of some wider (super) type', and that contravariance is the exact opposite of this.

Apparently, Scala functions are instances of Function[-A1,...,+B] for contravariant parameter types A1, etc. and covariant return type, B. While this is handy for subtyping on Functions, shouldn't the above definition mean I can pass any supertypes as parameters?

Please advise where I'm mistaken.

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can you give an example of what you think should be possible, but gives you errors? –  dhg May 15 '12 at 15:28

3 Answers 3

up vote 33 down vote accepted

Covariance and contravariance are qualities of the class not qualities of the parameters. (They are qualities that depend on the parameters, but they make statements about the class.)

So, Function1[-A,+B] means that a function that takes superclasses of A can be viewed as a subclass of the original function.

Let's see this in practice:

class A
class B extends A
val printB: B => Unit = { b => println("Blah blah") }
val printA: A => Unit = { a => println("Blah blah blah") }

Now suppose you require a function that knows how to print a B:

def needsB(f: B => Unit, b: B) = f(b)

You could pass in printB. But you could also pass in printA, since it also knows how to print Bs (and more!), just as if A => Unit was a subclass of B => Unit. This is exactly what contravariance means. It doesn't mean you can pass Option[Double] into printB and get anything but a compile-time error!

(Covariance is the other case: M[B] <: M[A] if B <: A.)

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Thank you, that was very clear. Attempting to (re)define: 'co/contra-variance are properties dictating the subtype relation between types, subject to the nature of the same relation between their component types'. Abstract, I know, but I prefer to have a definition devoid of examples (although yours was very helpful). –  bjt38 May 15 '12 at 17:08

There are two separate ideas at work here. One is using subtyping to allow more specific arguments to be passed to a function (called subsumption). The other is how to check subtyping on functions themselves.

For type-checking the arguments to a function, you only have to check that the given arguments are subtypes of the declared argument types. The result also has to be a subtype of the declared type. This is where you actually check subtyping.

The contra/co-variance of the parameters & result only factor in when you want to check whether a given function type is a subtype of another function type. So if a parameter has type Function[A1, ... ,B], then the argument has to be a function type Function[C1, ..., D] where A1 <: C1 ... and D <: B.

This reasoning isn't specific to Scala and applies to other statically-typed languages with subtyping.

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Covariant means converting from wider (super) to narrower (sub). For example, we have two class: one is animal (super) and the other one is cat then using covariant, we can convert animal to cat.

Contra-variant is just the opposite of covariant, which means cat to animal.

Invariant means it's unable to convert.

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