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I have a piece of code that I can't get to behave in the way I'd like. I have a class defined in the following way (stripped down for this):

class Behaviour[T](private val rule: Time => T) {
  def map1[U, V](behaviour: Behaviour[U], func: (T, U) => V): Behaviour[V] = {
    new Behaviour(time => func(this.at(time), behaviour.at(time)))
  }
}

When playing around with this class I tried to something that I thought would be trivial:

val beh = Behaviour(time => 5)
val beh2 = Behaviour(time => 5)
beh.map1(beh2, (a, b) => a + b)

For the last line I receive the following error:

<console>:13: error: missing parameter type
          beh.map1(beh2, (a, b) => a + b)
                             ^

I can of course specify the closure parameter types and it works correctly but why doesn't type inference work here? Of course I could also specify the generic types for the function (see below for both solutions).

I thought Scala carried out a 'scan' to infer types and would see beh2 and passed into the function and assume U here to be Int. Is there some way I can fix this without specify the types of the input parameters (for the closure or the generics)?

EDIT: Examples of the two fixes I have:

beh.map1[Int, Int](beh2, (a, b) => a + b)
beh.map1(beh2, (a, b : Int) => a + b)
share|improve this question
up vote 15 down vote accepted

See this scala-debate thread for a discussion of what's going on here. The problem is that Scala's type inference happens per parameter list, not per parameter.

As Josh Suereth notes in that thread, there's a good reason for the current approach. If Scala had per-parameter type inference, the compiler couldn't infer an upper bound across types in the same parameter list. Consider the following:

trait X
class Y extends X
class Z extends X

val y = new Y
val z = new Z

def f[A](a: A, b: A): (A, A) = (a, b)
def g[A](a: A)(b: A): (A, A) = (a, b)

f(y, z) works exactly as we'd expect, but g(y)(z) gives a type mismatch, since by the time the compiler gets to the second argument list it's already chosen Y as the type for A.

share|improve this answer

One of the ways to fix this is to define multiple argument lists. So your map1 method would be defined like this:

def map1[U, V](behaviour: Behaviour[U])(func: (T, U) => V): Behaviour[V] = ...

and you can use it like this:

beh.map1(beh2)((a, b) => a + b)
beh.map1(beh2)(_ + _)

I'm not completely sure why type inference does not work in your case, but I believe that it has something to do with usage of U type parameter. You are using it twice - for the first and second argument. It's probably too complicated for compiler to figure it out. In case of 2 argument lists, U would be inferred during first argument list compilation, and the second argument list will use already inferred type.

share|improve this answer
    
Thanks very much that works just fine! I'll accept the answer if none can come with an explanation for what's happening in the next day. – seadowg Feb 2 '12 at 19:22

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