In Haskell you can construct parametrized types as in the following example:

data Tree a = Leaf | Node a (Tree a) (Tree a)

..and afterwards make them an instance of a typeclass if the type parameter is also an instance of the very same typeclass (Eq is used as an example here, it could be anything):

instance (Eq m) => Eq (Tree m) where
  Leaf == Leaf = True
  Node a b c == Node x y z = (a == x) && (b == y) && (c == z)
  _ == _ = False

I am wondering how a similar thing would be possible in Scala. To start let's create the parametrized type:

abstract class Tree[T]
case class Leaf[T]() extends Tree [T]
case class Node[T](value: T, left: Tree[T], right: Tree[T]) extends Tree [T]

..and pick an even simpler trait as the typeclass being implemented:

trait Serializable {
  def toDifferentString(): String

Now what I'd like be able to do is provide an implementation of the Serializable trait for Tree, if The T type is Serializable.

I can see a couple of ways of how to do it partially, but none that would get me the Haskell-like result:

  • add a type constraint :< in the Tree abstract class, but then it's getting less generic and I'm assuming I can modify the Tree class
  • create an implicit conversion from Tree[Serializable] to Serializable, but I'm not even sure it would work and how robust it would be.

What is a good way of approaching the issue?

  • 1
    I'm trying to finally straighten up my Haskell/Scala knowledge, so the help will be much appreciated. Feel free to correct me if any of the terms I used don't mean what I think they mean. – nietaki Sep 9 '13 at 9:26

The type class pattern in Scala works like this:

trait Serializable[-T] {
  def toDifferentString(v: T): String

class SerializableTree[T : Serializable] extends Serializable[Tree[T]] {
  def toDifferentString(t: Tree[T]) = t match {
    case Leaf() => ""
    case Node(v, left, right) => 
      val vStr = implicitly[Serializable[T]].toDifferentString(v)
      val lStr = toDifferentString(left)
      val rStr = toDifferentString(right)
      s"Node($vStr, $lStr, $rStr)"

object SerializableTree {
  implicit def st[T : Serializable]: Serializable[Tree[T]] = new SerializableTree[T]

Type classes in Scala are implemented as a pattern, where the type class provides one or more methods that take as one of their parameters the class for which they are providing these methods.

The notation T : Serializable is a context bound, and is equivalent to an implicit parameter of type Serializable[T]. This implicit parameter is being retrieved by implicitly[Serializable[T]] (the method implicitly[A] return the implicit parameter of type A).

The object SerializableTree contains the necessary definition to produce the serializers for trees, so it has to be imported to be used. Often, common definitions for type classes are put on the object companion of the type class itself, which makes it available without an import.

Because I made Serializable contravariant, a Serializable[Tree[T]] can be used where a Serializable[Node[T]] or Serializable[Leaf[T]] is required.

  • 1
    Also note that this definition will not work for Node or Leaf, since Serializable is not covariant in T. In fact, it would be helpful if Tree (and its subclasses) were covariant. Could you expand on that please? I know the meaning of (co)variance, but I can't see how it would work here. – nietaki Sep 9 '13 at 10:43
  • @nietaki My mistake. Serializable needs to be contra-variant, which it can be, and there's no need for covariance of Tree (though it's still helpful in many situations). I assume the last paragraph should explain what role contravariance plays here, but, if not, I encourage you to compare the behavior of the contravariant and invariant versions of Serializable when passed a Node vs a Tree. – Daniel C. Sobral Sep 9 '13 at 10:53

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