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I am trying to implement a function that would work on types that have a map and a flatMap method. I have already made it for Traversable, but this does not include Future and Option directly. So I have decided to go with my own interface, using a typeclass:

trait CanMap[A, M[_]] {
  def map[B](l: M[A])(f: A => B): M[B]
  def flatMap[B](l: M[A])(f: A => M[B]): M[B]
}

I already implemented this for Option:

  implicit def canmapopt[A] = new CanMap[A, Option] {
    def map[B](l: Option[A])(f: A => B): Option[B] = l.map(f)
    def flatMap[B](l: Option[A])(f: A => Option[B]): Option[B] = l.flatMap(f)
  }

and this one works very well. Now I wanted to implement it for any subtype of Traversable, I tried an implementation very close to the one for Option:

  implicit def canmaptrav[A, B, T[B] <: Traversable[B]] = new CanMap[A, T] {
    def map[B](l: T[A])(f: A => B): T[B] = l.map(f)
    def flatMap[B](l: T[A])(f: A => T[B]): T[B] = l.flatMap(f)
  }

but I get the error:

  type mismatch;  found   : Traversable[B]  required: T[B]  Note: implicit method canmaptrav is not applicable here because it comes after the application point and it lacks an explicit result type

for the return type of l.map. I cannot understand why l.map(f) would return a Traversable and not the specific type T[B]. So I tried to explicitelly put the right type of CanBuildFrom in the context:

  implicit def canmaptrav[A, B, T[B] <: Traversable[B]](implicit cbf: CanBuildFrom[T[A], B, T[B]]) = new CanMap[A, T] {
    def map[B](l: T[A])(f: A => B): T[B] = l.map(f)
    def flatMap[B](l: T[A])(f: A => T[B]): T[B] = l.flatMap(f)
  }

The error persists.

Any idea where I went wrong? It might be obvious but I am getting confused with the generic type signatures I guess.

Update: Solution

First of all, as the answers pointed out, CanMap is mostly a Functor/Monad, so if you dare, you can use scalaz to implement this. However, if you are like me and want to try without it, here is the solution, based on the answer by Kipton Barros:

trait CanMap[A, B, M[_]] {
  def map(l: M[A])(f: A => B): M[B]
  def flatMap(l: M[A])(f: A => M[B]): M[B]
}

implicit def canmapopt[A, B] = new CanMap[A, B, Option] {
  def map(l: Option[A])(f: A => B): Option[B] = l.map(f)
  def flatMap(l: Option[A])(f: A => Option[B]): Option[B] = l.flatMap(f)
}

implicit def canmaptrav[A, B, M[+_]](implicit bf: CanBuildFrom[M[A], B, M[B]], ev: M[A] => TraversableLike[A, M[A]], eb: M[B] => TraversableLike[B, M[B]]) = new CanMap[A, B, M] {
  def map(l: M[A])(f: (A) => B): M[B] = l.map(f)
  def flatMap(l: M[A])(f: A => M[B]): M[B] = l.flatMap[B, M[B]] { (a: A) =>
    f(a)
  }
} 

The trick is to use an implicit conversion M[A] => TraversableLike[A, M[A]] instead of trying to subtype Traversable.

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3 Answers 3

up vote 4 down vote accepted

The first problem is that there's a lot going on "under the hood" in the Traversable map method. It does a bit of work to return the most specific collection type, which is why you need CanBuildFrom. The second problem is that Option does not implement the Traversable interface, so its map method doesn't take a CanBuildFrom.

Here's the closest I could get,

import scala.collection.generic.CanBuildFrom
import collection.TraversableLike

trait CanMap[A, M[_]] {
  def map[B](l: M[A])(f: A => B)(implicit bf: CanBuildFrom[M[A], B, M[B]]): M[B]
}

object Test {

  // ugly hack to work around nonexistent CanBuildFrom for Option
  implicit def optionBuilder[A, B]: CanBuildFrom[Option[A], B, Option[B]] = null

  implicit def canmapopt[A] = new CanMap[A, Option] {
    def map[B](l: Option[A])(f: A => B)(implicit bf: CanBuildFrom[Option[A], B, Option[B]]): Option[B] = l.map(f)
  }

  implicit def canmaptrav[A, M[_]](implicit ev: M[A] => TraversableLike[A, M[A]]) = new CanMap[A, M] {
    def map[B](l: M[A])(f: (A) => B)(implicit bf: CanBuildFrom[M[A], B, M[B]]): M[B] = l.map(f)
  }

  // example usage

  def mapper[A, B, M[_]](l: M[A])(f: A => B)(implicit cm: CanMap[A,M], bf: CanBuildFrom[M[A], B, M[B]]) = {
    cm.map(l)(f)
  }
  mapper(List(1,2,3))(_ + 1)          // List(2,3,4)
  mapper(Some(2): Option[Int])(_ + 1) // Some(3)
  // (cast to Option[Int] is needed to find the canmapopt implicit)
}

By the way, the implicit conversion to TraversableLike makes this also work with arrays,

 mapper(Array(1,2,3))(_ + 1)         // Array(2, 3, 4)
share|improve this answer
    
Excellent! the TraversableLike implicit conversion is cool :) I had to adapt your solution a bit, moving the CanBuildFrom as an implicit to canmaptrav, so that it doesn't "poison" the canmapopt. To be able to implement the flatMap, I also had to add another implicit CanBuildFrom for type M[B] to canmaptrav. B is then now a parameter in CanMap[A, B, M[_]] and not anymore to the functions. –  Mortimer Apr 16 '13 at 13:20
    
Glad you found a solution. Including type B in CanMap simplifies things a lot, but the disadvantage is that each CanMap object only maps to one specific type. I looked at the Scalaz. They completely avoid CanBuildFrom, which has upsides (simpler) and downsides (target type not as specific; won't work automatically with arrays for example). –  Kipton Barros Apr 16 '13 at 15:01
    
I don't really have the issue of B having to be a specific type as it's also a parameter of the implicits providing the CanMap. So it's made concrete dynamically by scala depending on where I use it. –  Mortimer Apr 16 '13 at 18:22

Firstly I tried your two failed attempts and didn't got much out of it. Then I decided to go simple and do my own CanMap implementation. I ended up with this:

  def canmaptrav[A] = new CanMap[A, Traversable]{
    def map[B](l: Traversable[A])(f: A => B): Traversable[B]= l.map(f)
    def flatMap[B](l: Traversable[A])(f: A => Traversable[B]): Traversable[B] = l.flatMap(f)
  }

Looking exactly the CanMap[_,Option]. Assuming the subtypes you are looking for is for use cases like this:

canmaptrav[Int].map(List(1,2,3,4))(_ + 1)       //> res0: Traversable[Int] = List(2, 3, 4, 5)
canmaptrav[Int].map(Vector(1,2,3,4))(_ + 1)     //> res1: Traversable[Int] = Vector(2, 3, 4, 5)

Now, if you want res1 and res0 types to be the concrete types (List, Vector) than the approach will have to indeed rely on the CanBuildFrom from.

BTW, you know that the CanMap is almost the Monad interface, right?

share|improve this answer
    
yep, I had done that, but I wanted to get the right type out of the map/flatMap, that's why I went down the crazy road of CanBuildFrom. –  Mortimer Apr 16 '13 at 13:26

Scalaz already includes these typeclasses and they are called Monad and Functor. A short example:

// map
def foo[F[_] : Functor](xs: F[Int]) = xs.map(_ + 1)

scala> foo(List(1,2,3))
res2: List[Int] = List(2, 3, 4)

// flatMap
def flatten[M[_] : Monad](xs: M[M[Int]]) = xs.flatMap(identity)

scala> flatten(List(List(1,2,3)))
res3: List[Int] = List(1, 2, 3)

edit:

The functor instance for Future could look like this:

implicit object FutureFunctor extends Functor[Future] {
  def map[A,B](fa: Future[A])(f: A => B) = fa.map(f)
}
share|improve this answer
    
thanks, indeed, scalaz provides everything I need, but I wanted to do it without the whole scalaz library. In particular because I looked at the code, and I really didn't get how to use it, I couldn't even get it to download as a dependence. Scalaz looks cool, but it's too complex to start with just to get a Monad typeclass. –  Mortimer Apr 16 '13 at 13:22

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