Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

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?


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?

share|improve this question
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, _)))
share|improve this answer
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.

share|improve this answer

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.

share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.