3

Is it possible to resolve an implicit parameter for a type B if an implicit is defined for its super type A?

Here is an example :

I have an Enumerable typeclass :

trait Enumerable[A] {

  def name(a: A): String

  def list: List[A] 

  //... other methods
}

object Enumeration {
  def name[A, T >: A](a: A)(implicit ev: Enumerable[T]) = ev.name(a)

  def list[T](implicit ev: Enumerable[T]) = ev.list

  // ...
}

Then I define an instance of enumerable :

sealed trait Season

case object Winter extends Season
case object Spring extends Season
case object Summer extends Season
case object Fall extends Season

implicit val seasonEnumerable = new Enumerable[Season] {
  override def list: List[Season] = List(Winter, Spring, Summer, Fall)
}

// working : 
Enumeration.name(Winter: Season) shouldBe "winter"

// faling : 
Enumeration.name(Winter) shouldBe "winter"

Enumeration.name(Winter) is failing if I don't tell scalac that Winter is a Season. I've specified that the implicit parameter in the 'name' method signature is a supertype of A, but it's not sufficient...

Is there a better way to do this?

2 Answers 2

3

Eduardo's answer explains why the version with [A, T >: A] doesn't work. But there is a simpler solution to the problem than he gives: instead of introducing T infer as a type parameter, introduce it by an existential type:

def name[A](a: A)(implicit ev: Enumerable[T >: A] forSome { type T }) = ev.name(a)

Or, using a shorthand,

def name[A](a: A)(implicit ev: Enumerable[_ >: A]) = ev.name(a)

Then the compiler only has to decide what T is when looking for ev.

2
  • Indeed! Thanks :) Could you explain the difference between def name[A](a: A)(implicit ev: Enumerable[_ >: A]) = ev.name(a) and def name[A, T >: A](a: A)(implicit ev: Enumerable[T]) = ev.name(a) ?
    – Loic
    Nov 28, 2016 at 12:04
  • 1
    I've expanded the answer. Nov 28, 2016 at 12:23
3

This is a common inconvenience whenever you need type-dependent types to be inferred. Your method

def name[A, T >: A](a: A)(implicit ev: Enumerable[T])

when called on Winter, first A will be inferred to Winter.type and then T to be A, as it conforms to that bound and there are no more constraints on it at that point. Then of course the compiler won't find an instance of Enumerable[Winter.type].

There's an easy solution with type members though:

trait AnyEnumerable {

  type E

  def name[A <: E](a: A): String
  def list: List[E]
}

object Enumeration {

  def name[A](a: A)(implicit ev: AnyEnumerable { type E >: A }) = ev.name(a)
  def list[T](implicit ev: AnyEnumerable { type E = T }) = ev.list
  // ...
}

// an implicit for `Season`
implicit val seasonEnumerable: AnyEnumerable { type E = Season } = 
  new AnyEnumerable {

    type E = Season

    def name[A <: Season](a: A): String = a.toString
    def list: List[Season] = List(Winter, Spring, Summer, Fall)
  }

// compiles!
val zzz = Enumeration.name(Winter)

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