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I'm trying to construct multiple cross products of traversables of different (but each homogeneous) types. The desired return type is a traversable of a tuple with the type matching the types in the input traversables. For example:

List(1, 2, 3) cross Seq("a", "b") cross Set(0.5, 7.3)

This should give a Traversable[(Int, String, Double)] with all possible combinations from the three sources. The case of combining only two sources was nicely answered here. The given idea is:

implicit class Crossable[X](xs: Traversable[X]) {
  def cross[A](ys: Traversable[A]) = for { x <- xs; y <- ys } yield (x, y)
}

The comments there briefly mention the problem of more sources, but I'm looking to find a solution that does not depend on either shapeless or scalaz (on the other hand, I don't mind having some boilerplate to scale up to Tuple22). What I would like to do is something like the following:

implicit class Crossable[X](xs: Traversable[X]) {
  def cross[A](ys: Traversable[A]) = for { x <- xs; y <- ys } yield (x, y)
  def cross[A,B](ys: Traversable[(A,B)]) = // ... extend all Tuple2's in ys with x in xs to Tuple3's
  def cross[A,B,C](ys: Traversable[(A,B,C)]) = // ...
  // ...
}

This obviously does not work due to type erasure (and, unfortunately, would probably require to use parenthesis in the example above, because cross would be right associative).

My question is: Is it somehow possible to exploit Scala 2.10's reflection features to solve the problem? In general, matching both A and X to the various tuple types (and their type parameters, which seems challenging) and merging them to larger tuples should provide a solution satisfying the associative law, right?

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1 Answer 1

up vote 2 down vote accepted

I had a go at it and came up with this:

trait Crosser[A,B,C] {
  def cross( as: Traversable[A], bs: Traversable[B] ): Traversable[C]
}

trait LowPriorityCrosserImplicits {
  private type T[X] = Traversable[X]

  implicit def crosser2[A,B] = new Crosser[A,B,(A,B)] {
    def cross( as: T[A], bs: T[B] ): T[(A,B)] = for { a <- as; b <- bs } yield (a, b)
  }
}

object Crosser extends LowPriorityCrosserImplicits {
  private type T[X] = Traversable[X]

  implicit def crosser3[A,B,C] = new Crosser[(A,B),C,(A,B,C)] {
    def cross( abs: T[(A,B)], cs: T[C] ): T[(A,B,C)] = for { (a,b) <- abs; c <- cs } yield (a, b, c)
  }

  implicit def crosser4[A,B,C,D] = new Crosser[(A,B,C),D,(A,B,C,D)] {
    def cross( abcs: T[(A,B,C)], ds: T[D] ): T[(A,B,C,D)] = for { (a,b,c) <- abcs; d <- ds } yield (a, b, c, d)
  }

  // and so on ...
}

implicit class Crossable[A](xs: Traversable[A]) {
  def cross[B,C](ys: Traversable[B])(implicit crosser: Crosser[A,B,C]): Traversable[C] = crosser.cross( xs, ys )
}

The main idea is to defer the work to a type class (Crosser) and implement all the different arities simply by specialising for Traversables of tuples with the corresponding arity minus one. Some test in the REPL:

scala> List(1, 2, 3) cross Seq("a", "b") cross Set(0.5, 7.3)
res10: Traversable[(Int, String, Double)] = List((1,a,0.5), (1,a,7.3), (1,b,0.5), (1,b,7.3), (2,a,0.5), (2,a,7.3), (2,b,0.5), (2,b,7.3), (3,a,0.5), (3,a,7.3), (3,b,0.5), (3,b,7.3))
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Wow, that is pretty cool! Thank you very much! Adding right associative versions also seems straightforward with this approach. I noticed you got rid of "ambiguous implicit" compiler errors by introducing crosser2 in a trait (which otherwise would always match). I assume there must be some kind of class hierarchy dependent priority rule for implicits? What is still puzzling me: Why are crosser2, crosser3, ... actually in scope? I was expecting that I have to import Crosser._ to bring them in scope, but this does not seem to be the case. –  bluenote10 Apr 26 '13 at 8:13
    
In case anyone else wants to use this: I just wrote a small code generator (gotta learn macros some day) and uploaded a Gist containing all the boilerplate up to a reasonably high level (starting with the 19th type parameter I got strange compiler errors, but 18 should be more than enough for me). –  bluenote10 Apr 26 '13 at 9:19
1  
The reason why you don't need to do import Crosser._, is because Crosser is passed implicitly in Crossable.cross, and implicit resolution rules say that when looking up for an implicit value of type T, the compiler will automatically look into the members of the companion object of T (if any). See SLS 7.2 –  Régis Jean-Gilles Apr 26 '13 at 9:30

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