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In regard to this question I was able to multi-assign via unzip on a List[(A,B)]

However, now I'm finding a need to multi-assign on either a List[( (A,B),(C,D) )] or a List[(A,B,C,D)]

I see that there is an unzip for pairs, and an unzip3 for triplets, but how to destructure a pair of Tuple2 OR a single Tuple4 so as to multi-assign? I'll adapt the collection type below accordingly, but whichever one works for 1-step multi-assignment is fine.

// foo can be a List[(A,B,C,D)] OR List[( (A,B),(C,D) )]
val(a,b,c,d) = foo.unzip

This works but is hacked

val(a,b,c_d) foo.unzip3 // foo is a List[(A,B,(C,D))]

because I wind up having to c_d._1 and c_d._2, the very notation I'm trying to avoid by multi-assigning variables

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2  
I'm not the downvoter, but I agree that the question needs some work. For example, List only has one type parameter, so what you mean by List[(A, B), (C, D)] is a little unclear—as is the static type of foo, since it clearly can't be both List[(A, B, C, D)] and List[((A, B), (C, D))]. –  Travis Brown Oct 22 '12 at 10:40
1  
Thanks, the "or" means either one "List[(A,B,C,D)]" or "List[((A,B),(C,D))]" will do. The basic issue appears to be that you have to work with pairs or triplets when unzip'ing, and multi-assigning beyond a single Tuple2 or Tuple3 becomes difficult if not impossible AFAIK –  virtualeyes Oct 22 '12 at 10:45
1  
But the least upper bound of (A, B, C, D) and ((A, B), (C, D)) is Product, so foo would have to be List[Product], which is pretty much useless. Unless you just mean you want the same syntax for both—not that you literally have one variable that can be either? –  Travis Brown Oct 22 '12 at 10:49
1  
I can make the result type (from a database query) whatever I want it to be. List[Product] is indeed useless,, thus the question. When working with a List[Tuple2] you can unzip, multi-assign, and the types are preserved. As soon as you go to List of Tuple4 or List containing a pair of Tuple2, types are lost. I can go with a List[Tuple3] result and unzip3 on that, just hacked since the 3rd param becomes a hash of C & D which I don't like –  virtualeyes Oct 22 '12 at 10:55
1  
+1 just to balance the unexplained downvote, whoever it was cast by. –  missingfaktor Oct 22 '12 at 11:16

5 Answers 5

Maybe this goes without saying, but there's a simple way to do this if you don't mind multiple steps:

val foo = List((1 -> "w", 'x -> 2.0), (101 -> "Y", 'Z -> 3.0))
val (p, q) = foo.unzip
val (a, b) = p.unzip
val (c, d) = p.unzip

If you really want a one-liner, you'll have to resort to something like Scalaz, which provides a Bifunctor instance for tuples that lets you write this, for example:

 import scalaz._, Scalaz._

 val ((a, b), (c, d)) = foo.unzip.bimap(_.unzip, _.unzip)

This is essentially the same as the version above, but having bimap lets us do everything in one line.

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1  
+1, yes, I already did the 2-step approach, just a sucker for 1-liners. re: bimap, at some point I need to dive into Scalaz, clearly a lot of useful stuff there. –  virtualeyes Oct 22 '12 at 15:55

As there are only unzip and unzip3, why don't you just write an extension for that? Something like this should work (2.10 code):

implicit class Unzip4[A,B,C,D](val xs: List[(A,B,C,D)]) extends AnyVal {
  def unzip4: (List[A], List[B], List[C], List[D]) = xs.foldRight[(List[A], List[B], List[C], List[D])]((Nil,Nil,Nil,Nil)) { (x, res) =>
    val (a,b,c,d) = x
    (a :: res._1, b :: res._2, c :: res._3, d :: res._4)
  }
}
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1  
+1, nice, that is clearly more elegant than my working solution with Tuple3/unzip3 approach. On 2.9.2, sounds like this won't fly unless on 2.10 –  virtualeyes Oct 22 '12 at 11:11
1  
You just have to create all the implicit conversion stuff yourself –  drexin Oct 22 '12 at 11:17
1  
It's a one-off problem, producing a schedule of games where container case class has 4 Seq properties, 2 of which are case classes, 1 an Int and the last a String. Normally I can map through a List[TupleN] and create a List of container case class (don't enjoy "tuple._n" notation), but not so easily in this case, thus the unzip4 request –  virtualeyes Oct 22 '12 at 11:52

You can add your own unzip4 method.

import scala.collection._
import generic._

class Unzipper[A, CC[X] <: GenTraversable[X]](s: GenericTraversableTemplate[A, CC]) {
  def unzip4[A1, A2, A3, A4](implicit asQuad: A => (A1, A2, A3, A4)): (CC[A1], CC[A2], CC[A3], CC[A4]) = {
    val b1 = s.genericBuilder[A1]
    val b2 = s.genericBuilder[A2]
    val b3 = s.genericBuilder[A3]
    val b4 = s.genericBuilder[A4]
    for (e <- s) {
      val (a, b, c, d) = asQuad(e)
      b1 += a
      b2 += b
      b3 += c
      b4 += d
    }
    (b1.result, b2.result, b3.result, b4.result)
  }
}

implicit def toUnzipper[A, CC[X] <: GenTraversable[X]](s: GenericTraversableTemplate[A, CC]) = new Unzipper(s)
implicit def t2t2Tot4[A1, A2, A3, A4](tt: ((A1, A2), (A3, A4))) = tt match { case ((a, b), (c, d)) => (a, b, c, d) }
implicit def t1t3Tot4[A1, A2, A3, A4](tt: (A1, (A2, A3, A4))) = tt match { case (a, (b, c, d)) => (a, b, c, d) }
implicit def t3t1Tot4[A1, A2, A3, A4](tt: ((A1, A2, A3), A4)) = tt match { case ((a, b, c), d) => (a, b, c, d) }

Usage:

scala> List((1, 2, 3, 4)).unzip4
res0: (List[Int], List[Int], List[Int], List[Int]) = (List(1),List(2),List(3),List(4))

scala> List((1, 2) -> (3, 4)).unzip4
res1: (List[Int], List[Int], List[Int], List[Int]) = (List(1),List(2),List(3),List(4))

scala> List(1 -> (2, 3, 4)).unzip4
res2: (List[Int], List[Int], List[Int], List[Int]) = (List(1),List(2),List(3),List(4))

scala> List((1, 2, 3) -> 4).unzip4
res3: (List[Int], List[Int], List[Int], List[Int]) = (List(1),List(2),List(3),List(4))
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1  
+1, ok, verified in console, works. Was hoping could pull off with existing collections library, but apparently not... –  virtualeyes Oct 22 '12 at 11:46

You don't actually need any implicit conversions here. The trick is to take advantage of custom extractor objects, like so:

object Unzipped4 {

  def unapply[A, B, C, D](ts: List[(A, B, C, D)]): Some[(List[A], List[B], List[C], List[D])] =
    Some((ts map _._1, ts map _._2, ts map _._3, ts map _._4))

}

You then use it like this:

val Unzipped4(as, bs, cs, ds) = foo

You could actually expand this to an arbitrary Product by using the dynamic access methods on that class, but you'd lose some type safety in the process.

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1  
+1, your handle rings a bell and I remember why, out-of-the-box thinking –  virtualeyes Oct 22 '12 at 20:41

In addition to the great other answers I played around and thought about having nested and arity-generic unzips. My approach uses type classes and loses arity and type safety like productIterator on tuples. Perhaps someone can adapt it using HList from shapeless for the rescue. One also have to implement the pimp my library to use unzip on collections to return the proper (same) collection type unzip was called on and to get rid of Iterable, but I omitted this here to only show the idea of nested arity-generic unzips. Perhaps one can use some kind of LowerPriorityImplicits to implicitly convert any A to Unzippable[A,A] if there isn´t a concrete implicit conversion to Unzippable for a given type.

trait Unzippable[T, +Super] {
  def unzip(t: T): Iterable[Super]
}

implicit object IntUnzippable extends Unzippable[Int, Int] { def unzip(i: Int) = Seq(i) }
implicit object BooleanUnzippable extends Unzippable[Boolean, Boolean] { def unzip(b: Boolean) = Seq(b) }
implicit object StringUnzippable extends Unzippable[String, String] { def unzip(s: String) = Seq(s) }

implicit def Tuple2Unzippable[Super, A <: Super, B <: Super, S, S1 <: S, S2 <: S](implicit ev1: Unzippable[A, S1], ev2: Unzippable[B, S2]) = new Unzippable[(A, B), S] {
  def unzip(t: (A, B)): Iterable[S] = ev1.unzip(t._1) ++ ev2.unzip(t._2)
}

def unzip[A, Super](i: Iterable[A])(implicit ev: Unzippable[A, Super]): Iterable[Iterable[Super]] = i.map(ev.unzip).transpose

object MyTuple3 {
  def unapply[X](i: Iterable[X]): Option[(X, X, X)] = if (i.size != 3) return None else Some((i.head, i.drop(1).head, i.last))
}

val list = (1, ("A", true)) :: (2, ("B", false)) :: (3, ("C", true)) :: Nil
val MyTuple3(nums, letters, bools) = unzip(list)
println((nums, letters, bools)) // (List(1, 2, 3),List(A, B, C),List(true, false, true))
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1  
Basically +1'ing all the answers as, at a minimum, so far they all show a good deal of effort, not to mention expertise of the creators. As to whether or not I grok the intricacies, at this time, no ;-) Funny how a simple question (minus 1'd to start no less) peaked the interest of several scala heavies... –  virtualeyes Oct 22 '12 at 20:40

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