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# Scala method to combine each element of an iterable with each element of another?

If I have this:

``````val a = Array("a ","b ","c ")
val b = Array("x","y")
``````

I would like to know if such a method exists which would let me traverse the first collection, and for each of it's elements, walk the entire second collection. For example, if we take the array `a`, we would have `a,x`,`a,y`,`b,x`,`b,y`,`c,x`,`c,y`. I know of zip but from what I've seen it only works on collections of the same sizes, and it associates elements from same positions.

-
BTW, that's called the `Cartesian product` of the two arrays. – Malvolio May 11 '11 at 1:52

I'm not sure of a "method", but this can be expressed with just a nested/compound `for`:

``````val a = Array("a ","b ","c ")
val b = Array("x","y")
for (a_ <- a; b_ <- b) yield (a_, b_)

res0: Array[(java.lang.String, java.lang.String)] = Array((a ,x), (a ,y), (b ,x), (b ,y), (c ,x), (c ,y))
``````

Happy coding.

-
Thanks! My version is a little longer :) – Geo May 10 '11 at 20:33
And the “method” version is `a.flatMap(_a => b.map(_b => _a -> _b))` – Jean-Philippe Pellet May 10 '11 at 21:54

I'm using the following extensively in my code. Note that this is working for an arbitrary number of lists. It is creating an Iterator instead of a collection, so you don't have to store the potentially huge result in memory.

Any improvements are very welcome.

``````/**
* An iterator, that traverses every combination of objects in a List of Lists.
* The first Iterable will be incremented fastest. So consider the head as
* the "least significant" bit when counting.*/

class CombinationIterator[A](val components: List[Iterable[A]]) extends Iterator[List[A]]{
private var state: List[BufferedIterator[A]] = components.map(_.iterator.buffered)
private var depleted = state.exists(_.isEmpty)

override def next(): List[A] = {
//this function assumes, that every iterator is non-empty
def advance(s: List[(BufferedIterator[A],Iterable[A])]): List[(BufferedIterator[A],A)] = {
if( s.isEmpty ){
depleted = true
Nil
}
else {

val next = it.next()
if( it.hasNext){
//we have simply incremented the head, so copy the rest
} else {
//we have depleted the head iterator, reset it and increment the rest
}
}
}
//zipping the iterables to the iterators is needed for resseting them

//update state
state = newState

result
}

override def hasNext = !depleted
}
``````

So using this one, you have to write `new CombinationIterator(List(a,b))` to obtain an iterator that goes through every combination.

## Edit: based on user unkown's version

Note that the following version is not optimal (performance wise):

• indexed access into lists (use arrays instead)
• takeWhile evaluates after every element

.

``````scala> def combination(xx: List[List[_]], i: Int): List[_] = xx match {
| case Nil => Nil
| case x :: xs => x(i % x.length) :: combination(xs, i/x.length)
| }
combination: (xx: List[List[_]], i: Int)List[_]

scala> def combinationIterator(ll: List[List[_]]): Iterator[List[_]] = {
| Iterator.from(0).takeWhile(n => n < ll.map(_.length).product).map(combination(ll,_))
| }
combinationIterator: (ll: List[List[_]])Iterator[List[_]]

scala> List(List(1,2,3),List("a","b"),List(0.1,0.2,0.3))
res0: List[List[Any]] = List(List(1, 2, 3), List(a, b), List(0.1, 0.2, 0.3))

scala> combinationIterator(res0)
res1: Iterator[List[_]] = non-empty iterator

scala> res1.mkString("\n")
res2: String =
List(1, a, 0.1)
List(2, a, 0.1)
List(3, a, 0.1)
List(1, b, 0.1)
List(2, b, 0.1)
List(3, b, 0.1)
List(1, a, 0.2)
List(2, a, 0.2)
List(3, a, 0.2)
List(1, b, 0.2)
List(2, b, 0.2)
List(3, b, 0.2)
List(1, a, 0.3)
List(2, a, 0.3)
List(3, a, 0.3)
List(1, b, 0.3)
List(2, b, 0.3)
List(3, b, 0.3)
``````
-

For a list of a unknown number of lists, of different length, and for maybe different types, you can use this:

``````def xproduct (xx: List [List[_]]) : List [List[_]] =
xx match {
case aa :: bb :: Nil =>
aa.map (a => bb.map (b => List (a, b))).flatten
case aa :: bb :: cc =>
xproduct (bb :: cc).map (li => aa.map (a => a :: li)).flatten
case _ => xx
}
``````

You would call it

``````xproduct List (List ("a ", "b ", "c "), List ("x", "y"))
``````

but can call it with Lists of different kind too:

``````scala>  xproduct (List (List ("Beatles", "Stones"), List (8, 9, 10), List ('\$', '€')))
res146: List[List[_]] = List(List(Beatles, 8, \$), List(Stones, 8, \$), List(Beatles, 8, €), List(Stones, 8, €), List(Beatles, 9, \$), List(Stones, 9, \$), List(Beatles, 9, €), List(Stones, 9, €), List(Beatles, 10, \$), List(Stones, 10, \$), List(Beatles, 10, €), List(Stones, 10, €))
``````

Arrays have to be converted to Lists, and the result converted back to Arrays, if you can't use Lists.

### update:

On the way towards a lazy collection, I made a functional mapping from an index (from 0 to combination-size - 1) to the result at that position, easily calculated with modulo and division, just a bit concentration is needed:

``````def combicount (xx: List [List[_]]): Int = (1 /: xx) (_ * _.length)

def combination (xx: List [List[_]], i: Int): List[_] = xx match {
case Nil => Nil
case x :: xs => x(i % x.length) :: combination (xs, i / x.length)
}

def xproduct (xx: List [List[_]]): List [List[_]] =
(0 until combicount (xx)).toList.map (i => combination (xx, i))
``````

It's no problem to use a long instead, or even BigInt.

### update 2, The iterator:

``````class Cartesian (val ll: List[List[_]]) extends Iterator [List[_]] {

def combicount (): Int = (1 /: ll) (_ * _.length)

val last = combicount - 1
var iter = 0

override def hasNext (): Boolean = iter < last
override def next (): List[_] = {
val res = combination (ll, iter)
iter += 1
res
}

def combination (xx: List [List[_]], i: Int): List[_] = xx match {
case Nil => Nil
case x :: xs => x (i % x.length) :: combination (xs, i / x.length)
}
}
``````
-
Can you turn this into a "lazy" collection, e.g. a view? – ziggystar May 11 '11 at 8:14
I don't think so. Before producing the first result for N lists, all results of combining N-1 lists are produced, so in the example above, (B8, B9, B10, S8, S9, S10) are combined, before the first iks combined to ('\$', '€'). – user unknown May 11 '11 at 15:33
.. but you can operate with modulo and division of sublist lengths, to pick certain combinations from a List of List (or Array of Arrays), so for 2*3*2=12 elements, you can enumerate your Collection of Collections, and just return one combination for each call. This should be easily combined with an lazy collection, shouldn't it? I'll try it. – user unknown May 11 '11 at 16:24
@ziggystar: I transformed it to a method, which calculates every combination for an index. But I'm not familiar with lazy collections. How do I turn it into a lazy collection? Where do I find a brief tutorial/explanation, to do it myself? – user unknown May 11 '11 at 17:12
I didn't check if your code works, but the idea sounds reasonable. I also think it's more readable than my version and can be made more efficient by using Arrays. Also the stored state is only one integer (or better make it a long). But it's limited in sequence length by the size of long. – ziggystar May 11 '11 at 18:12

If you want to show off your deep knowledge of higher kinded types and category theory, you can write:

``````trait Applicative[App[_]] {
def pure[A](a: A): App[A]
def fmap[A,B](f: A => B, appA: App[A]): App[B]
def star[A,B](appF: App[A => B], appA: App[A]): App[B]
}

object ListApplicative extends Applicative[List] {
override def pure[A](a: A): List[A] = List(a)
override def fmap[A,B](f: A => B, listA: List[A]): List[B] = listA.map(f)
override def star[A,B](listF: List[A => B], listA: List[A]):List[B] =
for(f <- listF; a <- listA) yield f(a)
}

import ListApplicative._

def pairs[A,B](listA: List[A], listB: List[B]) =
star(fmap((a:A) => ((b:B) => (a,b)), listA), listB)
``````

Other than that I would prefer pst's solution...

-
Oops, humorless downvoter has no humor... – Landei May 11 '11 at 7:03
Except I don't have a deep knowledge of higher kinded types :D – Geo May 11 '11 at 7:11
As virtually nobody else has, nobody will notice... – Landei May 13 '11 at 7:43

Here's one more that does the same thing as @ziggystar's last edit but doesn't use indexed access of lists.

``````def combinationIterator[A](xs: Iterable[Iterable[A]]): Iterator[List[A]] = {
tails.flatMap { tail =>
}
}
}
``````

And the sugary version:

``````def combinationIterator[A](xs: Iterable[Iterable[A]]): Iterator[List[A]] = {
(xs :\ Iterator(List[A]())) { (heads, tails) =>