I'm playing with scala generics and type bounds to understand its possible use cases. I'm puzzled with a scenario.

Let's say I have a trait Combinable

trait Combinable[T] {
    def combine(other: T): T
}

and I want to implement an implicit def for Vector[A]:

implicit def vectorCombinable[A](self: Vector[A]) = new Combinable[Vector[A]] { // note: using scala 2.11, no SAM support
    override def combine(other: Vector[A]): Vector[A] = self ++ other
}

Everything is fine so far, the problem starts if I replace Vector with type B upper bounded to GenTraversable:

implicit def vectorCombinable[A, B <: GenTraversable[A]](self: B): Combinable[B] = new Combinable[B] {
    override def combine(other: B): B = self ++ other
}

I simply want this method to return in type B, but self ++ other fails with the following compilation error:

Expression of type GenTraversable[A] doesn't conform to expected type B

  • What is self reduce other in the first place? reduce expects a reduction function (A, A) => A, and returns an A. What is self reduce other supposed to mean, and how can it be a Vector? I cannot understand the "Everything is fine so far" - it doesn't compile already there? – Andrey Tyukin Mar 9 at 15:08
  • Sorry @AndreyTyukin, I tried too many things, that's why I typed wrong, edited now. self ++ other appends these two GenTraversables. And I don't want it to return GenTraversable, but B instead. I hope my intention is clear now. – Feyyaz Mar 9 at 15:13
up vote 3 down vote accepted

You can do it like this:

implicit def vectorCombinable[A, B <: GenTraversableLike[A, B]]
  (self: B with GenTraversable[A])
  (implicit cbf: CanBuildFrom[B, A, B])
: Combinable[B] = new Combinable[B] {
  override def combine(other: B): B = self ++ other
}

First, you need B to extend GenTraversableLike, because scala.collection.???Like classes contain both the type of their elements and the full type of the sequence in their signature. For example Vector[Int] extends GenTraversableLike[Int, Vector[Int]]. The operations defined on ???Like classes thus can use the full type of the sequence.

Second, you need self to be B with GenTraversable[A], because the compiler should be able to figure out both the type of the sequence and the type of its elements from a single signature.

Third, you have to provide an implicit CanBuildFrom[B, A, B], that proves that you can build a sequence B with elements of type A from a sequence B. This proof will be supplied to the ++ method of GenTraversable

After all that, it works OK:

scala> List(1,2,3).combine(List(4,5,6))
res0: List[Int] = List(1, 2, 3, 4, 5, 6)

scala> Set(1,2,3).combine(Set(4,5,6))
res1: scala.collection.immutable.Set[Int] = Set(5, 1, 6, 2, 3, 4)

scala> Map(1 -> "a", 2 -> "b").combine(Map(1 -> "c", 3 -> "d"))
res2: scala.collection.immutable.Map[Int,String] = Map(1 -> c, 2 -> b, 3 -> d)
  • Ah, it shifts all un-naturality to the use site, where an additional CBF has to be supplied. Ok, if the OP can accept that a CBF has to be provided for every combine, this indeed is another possibility. Didn't think about that. Nice! – Andrey Tyukin Mar 9 at 20:31

Basically, you can't do it, because a GenTraversable[A] does not tell you anything specific about the return type of ++, especially it cannot guarantee you that it will return a B.

Even if you extended B <: GenTraversableLike[A, B], you would still have the same problem that ++ expects an implicit CanBuildFrom[Blah, Blahh, That] and returns a That.

To guarantee that your method combine returns the same type of collection, without relying on any external CanBuildFroms, you could do this:

import scala.collection._
import scala.collection.generic.GenericTraversableTemplate
import scala.language.implicitConversions
import scala.language.higherKinds

trait Combinable[T] {
    def combine(other: T): T
}

implicit def genericCombinable
  [A, CC[X] <: 
    GenericTraversableTemplate[X, CC] with 
    GenTraversable[X] with 
    TraversableOnce[X]
  ]
  (c: CC[A])
: Combinable[CC[A]] = {
  new Combinable[CC[A]] {
    override def combine(other: CC[A]): CC[A] = {
      val bldr = c.genericBuilder[A]
      bldr ++= c
      bldr ++= other
      bldr.result
    }
  }
}

Now it compiles and works with most collections from the standard library, because most of them tend to implement GenericTraversableTemplate anyway.

I would advice you not to spend too much time on this. For example, scala cats didn't bother to provide a generic instance of Monoid for all possible kinds of GenTraversable, they've simply implemented Monoid on List and Vector (and a few other classes) instead, but not for GenTraversable (correct me if I'm wrong). Therefore, I would not assume that this is a simple thing to do.

One last note: the compiler should give you warnings because of implicit conversions, and rightly so.

  • Thanks for your answer Andrey. Yes that looks very strange, but I got your point. You are right about unconventional naming, I renamed it to Combinable.combine to prevent confusion. – Feyyaz Mar 9 at 20:22
  • What do you mean "it did not compile"? Did the code in my answer not compile? That was not the plan. Have I messed it up while trying to indent? It definitely did compile here locally... – Andrey Tyukin Mar 9 at 20:24
  • It turned out to be IntelliJ mistake, compiles fine. No worries. – Feyyaz Mar 9 at 20:25
  • 1
    @Feyyaz I've updated the answer to match the question. – Andrey Tyukin Mar 9 at 20:36

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