# Scala: cross (cartesian) product with multiple sources and heterogeneous types

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?

-

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 `Traversable`s 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))
``````
-
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
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