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I have the following set of sets. I don't know ahead of time how long it will be.

val sets = Set(Set("a","b","c"), Set("1","2"), Set("S","T"))

I would like to expand it into a cartesian product:

Set("a&1&S", "a&1&T", "a&2&S", ..., "c&2&T")

How would you do that?

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up vote 17 down vote accepted

I think I figured out how to do that.

def combine(acc:Set[String], set:Set[String]) = for (a <- acc; s <- set) yield {
  a + "&" + s 

val expanded = sets.reduceLeft(combine)

expanded: scala.collection.immutable.Set[java.lang.String] = Set(b&2&T, a&1&S, 
  a&1&T, b&1&S, b&1&T, c&1&T, a&2&T, c&1&S, c&2&T, a&2&S, c&2&S, b&2&S)
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Synchronicity! In my solution, deferred construction of the Strings until the last step, but they are basically the same. – retronym May 23 '10 at 15:59

Nice question. Here's one way:

scala> val seqs = Seq(Seq("a","b","c"), Seq("1","2"), Seq("S","T"))                  
seqs: Seq[Seq[java.lang.String]] = List(List(a, b, c), List(1, 2), List(S, T))

scala> val seqs2 =
seqs2: Seq[Seq[Seq[java.lang.String]]] = List(List(List(a), List(b), List(c)), List(List(1), List(2)), List(List(S), List(T)))

scala> val combined = seqs2.reduceLeft((xs, ys) => for {x <- xs; y <- ys} yield x ++ y)
combined: Seq[Seq[java.lang.String]] = List(List(a, 1, S), List(a, 1, T), List(a, 2, S), List(a, 2, T), List(b, 1, S), List(b, 1, T), List(b, 2, S), List(b, 2, T), List(c, 1, S), List(c, 1, T), List(c, 2, S), List(c, 2, T))

res11: Seq[String] = List(a&1&S, a&1&T, a&2&S, a&2&T, b&1&S, b&1&T, b&2&S, b&2&T, c&1&S, c&1&T, c&2&S, c&2&T)
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Thanks. I first tried with foldLeft and eventually figured out I needed to use reduceLeft instead (kept getting an empty result). Is the conversion to Seq only necessary to preserve ordering? – huynhjl May 23 '10 at 16:02
Combining at the end will actually be helpful because the sets are in fact in the same space and I need to combine "b&a&a" into "a&b" (remove dups and order the combination). – huynhjl May 23 '10 at 16:10
@huynhjl The use of seq (to begin with) was probably so that retronym could avoid importing scala.collection.immutable.Set, and maybe to show that this could be done with the more general interface. – Ken Bloom May 23 '10 at 16:23
Seq vs Set on the first line doesn't really matter, I just found it easier to use Seq to preserve ordering. The choice on the second line does matter, you could use Set to remove duplicates, for example. – retronym May 23 '10 at 16:25

Came after the batle ;) but another one:

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Expanding on dsg's answer, you can write it more clearly (I think) this way, if you don't mind the curried function:

def combine[A](f: A => A => A)(xs:Iterable[Iterable[A]]) =
   xs reduceLeft { (x, y) => x.view flatMap { y map f(_) } }

Another alternative (slightly longer, but much more readable):

def combine[A](f: (A, A) => A)(xs:Iterable[Iterable[A]]) =
   xs reduceLeft { (x, y) => for (a <- x.view; b <- y) yield f(a, b) }


combine[String](a => b => a + "&" + b)(sets)   // curried version

combine[String](_ + "&" + _)(sets)             // uncurried version
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awesome, thanks! – dsg Dec 23 '10 at 5:13

Expanding on @Patrick's answer. Now it's more general and lazier:

def combine[A](f:(A, A) => A)(xs:Iterable[Iterable[A]]) =
    xs.reduceLeft { (x, y) => x.view.flatMap {a =>, _)) } } 

Having it be lazy allows you to save space, since you don't store the exponentially many items in the expanded set; instead, you generate them on the fly. But, if you actually want the full set, you can still get it like so:

val expanded = combine{(x:String, y:String) => x + "&" + y}(sets).toSet
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Here's a more general solution that allows for an application of map prior to taking the cartesian product: – dsg Dec 19 '11 at 6:15

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