# All possible permutations of values for such a map

Consider such a map:

Map("one" -> Iterable(1,2,3,4), "two" -> Iterable(3,4,5), "three" -> Iterable(1,2))

I want to get a list of all possible permutations of elements under Iterable, one element for each key. For this example, this would be something like:

// first element of "one", first element of "two", first element of "three"
// second  element of "one", second element of "two", second element of "three"
// third  element of "one", third element of "two", first element of "three"
// etc.
Seq(Iterable(1,3,1), Iterable(2,4,2), Iterable(3,5,1),...)

What would be a good way to accomplish that?

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That's not permutations. Permutations are single set in all possible orders, so like 1,2,3; 1,3,2; 2,1,3; 2,3,1; 3,1,2; 3,2,1. What you probably mean is "transposition" (elements by second index first and than first index). –  Jan Hudec May 23 '11 at 13:14
What defines the order of keys, given that Map keys are otherwise not ordered? –  Paul May 23 '11 at 13:36
@Paul I don't want it to be ordered. Consider Iterable(1,2,3), Iterable(2,3,1), Iterable(3,1,2) and Iterable(3,2,1) are the same. –  folone May 23 '11 at 13:58
So you want to treat the keys in the map as unordered, the values within each value iterator as unordered, the results as an unordered set of unordered values (one from each map value)? Just checking, because your example IS ordered (as it is a Seq) –  Paul May 23 '11 at 14:25
You want the cartesian product. –  Raphael May 23 '11 at 17:15

val m = Map("one" -> Iterable(1,2,3,4), "two" -> Iterable(5,6,7), "three" -> Iterable(8,9))

If you want every combination:

for (a <- m("one"); b <- m("two"); c <- m("three")) yield Iterable(a,b,c)

If you want each iterable to march up together, but stop when the shortest is exhuasted:

(m("one"), m("two"), m("three")).zipped.map((a,b,c) => Iterable(a,b,c))

If you want each iterable to wrap around but stop when the longest one has been exhausted:

val maxlen = m.values.map(_.size).max
def icf[A](i: Iterable[A]) = Iterator.continually(i).flatMap(identity).take(maxlen).toList
(icf(m("one")), icf(m("two")), icf(m("three"))).zipped.map((a,b,c) => Iterable(a,b,c))

Edit: If you want arbitrary numbers of input lists, then you're best off with recursive functions. For Cartesian products:

def cart[A](iia: Iterable[Iterable[A]]): List[List[A]] = {
if (iia.isEmpty) List()
else {
val t = iia.tail
if (t.isEmpty) h.map(a => List(a)).toList
else h.toList.map(a => cart(t).map(x => a :: x)).flatten
}
}

and to replace zipped you want something like:

def zipper[A](iia: Iterable[Iterable[A]]): List[List[A]] = {
def zipp(iia: Iterable[Iterator[A]], part: List[List[A]] = Nil): List[List[A]] = {
if (iia.isEmpty || !iia.forall(_.hasNext)) part
else zipp(iia, iia.map(_.next).toList :: part)
}
zipp(iia.map(_.iterator))
}

You can try these out with cart(m.values), zipper(m.values), and zipper(m.values.map(icf)).

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All these have hard-wired the number of keys to use. Is there a neat way to deal with a map with any number of entries? –  Paul May 23 '11 at 18:59
@Paul - Examples given. –  Rex Kerr May 23 '11 at 20:33
Great, thank you. I'll go educate myself about Cartesian products. –  folone May 24 '11 at 6:28

If you are out for an cartesian product, I have a solution for lists of lists of something.

xproduct (List (List (1, 2, 3, 4), List (3, 4, 5), List (1, 2)))
res3: List[List[_]] = List(List(1, 3, 1), List(2, 3, 1), List(3, 3, 1), List(4, 3, 1), List(1, 3, 2), List(2, 3, 2), List(3, 3, 2), List(4, 3, 2), List(1, 4, 1), List(2, 4, 1), List(3, 4, 1), List(4, 4, 1), List(1, 4, 2), List(2, 4, 2), List(3, 4, 2), List(4, 4, 2), List(1, 5, 1), List(2, 5, 1), List(3, 5, 1), List(4, 5, 1), List(1, 5, 2), List(2, 5, 2), List(3, 5, 2), List(4, 5, 2))

Invoke it with Rex' m:

xproduct (List (m("one").toList, m("two").toList, m("three").toList))
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