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I don't know the technical terminology for this, but as stated in the title, I'm looking for a function or feature of a typeclass that transforms a function outputting a pair of containers into a container containing a pair. Its signature should look like

def f[M[_], A, B, C](g: A => (M[B], M[C])): A => M[(B, C)]

To achieve this, it may be necessary to first specify a typeclass allowing a mapping (M[A], M[B]) => M[(A, B)] and then composing a g with the functionality of this typclass.

As a concrete example, suppose we have a function f: Int => Option[Int] and a function g: Int => Option[Long]. We can "pair" the functions using the arrow syntax from scalaz (val h = f &&& g) such that the resulting function (h) has type Int => (Option[Int], Option[Long]). We can then sequence the Options by using a for-comprehension or by composing with (a, b) => a tuple b. How does this generalize?

EDIT:

Shortly after posting this, I discovered that the tuple functionality in scalaz7 was coming from the Apply typeclass and not from Option directly. Apparently this is is a weaker class than Applicative, which explains why this works using a monadic for-comprehension. Thus Apply should get the job done in the general case. My question is now: how can I transform the original A => (M[B], M[C]) directly into an A => M[(B, C)], without composing Apply's functionality with that of the original function?

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1  
Maybe a stupid question, as I don't speak scalaz, but is "a function outputting a pair of containers into a container containing a pair" not zip? I looked for it in the scalaz docs and this looks like it does something similar to what you want: docs.typelevel.org/api/scalaz/nightly/index.html#scalaz.Zip –  bazzargh Feb 22 at 0:03
    
Yes, it looks like that's it! –  Ben Sidhom Feb 22 at 0:12

3 Answers 3

Try this? I have not scalaz installed.

def f[M <: Monad[M[_]], A, B, C](g: A => (M[B], M[C])): A => M[(B, C)] = (a: A) => {
   g(a) match {
     // For general monads, converts (M[B],M[C]) to M[(B, C)]
     case (b, c) => b.map((_, c)).flatMap(k => k._2.map((k._1, _)))
   }
}
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Right, I know how to do that in the specific case of Option. I was trying to generalize the approach in a more concise fashion. Please see my edit. –  Ben Sidhom Feb 21 at 23:46
    
After investigating a bit, it may need to be done through the Apply type class. –  Ben Sidhom Feb 21 at 23:47
    
Thanks. This works, but it it turns out this can be done with Apply alone (i.e., it can be generalized further). See my answer below. Do you know if there's a shorter, clearer way of achieving this? –  Ben Sidhom Feb 22 at 0:06

Apply had what I needed and the below seems to work. I was hoping for more concise syntactic sugar, but it gets the job done:

  def pairApply[M[_] : Apply, A, B, C](g: A => (M[B], M[C])): A => M[(B, C)] = {
    g andThen (x => implicitly[Apply[M]].tuple2(x._1, x._2))
  }

Following bazzargh's comment, this can be made a little clearer by using scalaz's Zip:

  def zipPair[M[_] : Zip, A, B, C](g: A => (M[B], M[C])): A => M[(B, C)] = {
    g andThen (x => x._1 fzip x._2)
  }

The composition is still not ideal though.

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There's also bisequence, which lets you turn a tuple of applicatives inside out:

def zipPair[M[_]: Applicative, A, B, C](g: A => (M[B], M[C])): A => M[(B, C)] =
  g.andThen(_.bisequence[M, B, C])

It's a little more general than Zip, too, since it will work on any type with a Bitraverse instance (e.g. Either), not just tuples.

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