# Create a Map of Iterables only using immutable collections

I have an iterable `val pairs: Iterable[Pair[Key, Value]]`, that has some key=>value pairs.

Now, I want to create a `Map[Key, Iterable[Value]]`, that has for each key an `Iterable` of all values of given key in `pairs`. (I don't actually need a `Seq`, any `Iterable` is fine).

I can do it using mutable `Map` and/or using mutable `ListBuffer`s.

However, everyone tells me that the "right" scala is without using mutable collections. So, is it possible to do this only with immutable collections? (for example, with using `map`, `foldLeft`, etc.)

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I have found out a really simple way to do this

``````pairs.groupBy{_._1}.mapValues{_.map{_._2}}
``````

And that's it.

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That won't give you an immutable map if `pairs` is mutable –  Luigi Plinge Jul 3 '12 at 2:31
That's true, but I already had pairs immutable in my case. I will edit the question (which is cheating a bit ;) ) –  Karel Bílek Jul 5 '12 at 13:49

Anything that you can do with a non-cyclic mutable data structure you can also do with an immutable data structure. The trick is pretty simple:

``````loop -> recursion or fold
``````

So, for example, in your case you're probably looping through the `Iterable` and adding a value each time. If we apply our handy trick, we

``````def mkMap[K,V](data: Iterable[(K,V)]): Map[K, Iterable[V]] = {
@annotation.tailrec def mkMapInner(
data: Iterator[(K,V)],
map: Map[K,Vector[V]] = Map.empty[K,Vector[V]]
): Map[K,Vector[V]] = {
if (data.hasNext) {
val (k,v) = data.next
mkMapInner(data, map + (k -> map.get(k).map(_ :+ v).getOrElse(Vector(v))))
}
else map
}
mkMapInner(data.iterator)
}
``````

Here I've chosen to implement the loop-replacement by declaring a recursive inner method (with @annotation.tailrec to check that the recursion is optimized to a while loop so it won't break the stack)

Let's test it out:

``````val pairs = Iterable((1,"flounder"),(2,"salmon"),(1,"halibut"))
scala> mkMap(pairs)
res2: Map[Int,Iterable[java.lang.String]] =
Map(1 -> Vector(flounder, halibut), 2 -> Vector(salmon))
``````

Now, it turns out that Scala's collection libraries also contain something useful for this:

``````scala> pairs.groupBy(_._1).mapValues{ _.map{_._2 } }
``````

with the `groupBy` being the key method, and the rest cleaning up what it produces into the form you want.

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Thanks for answer; I have found out identical thing myself, consuting scaladoc for a while :) –  Karel Bílek Jul 2 '12 at 21:48
So you have! I wanted to give the full "what to do about mutable patterns" part of the answer, though, because you can't always find the desired methods in the Scala library, but the loop-to-recursion thing is a general strategy. –  Rex Kerr Jul 2 '12 at 21:56
Can you describe more, what is going on in line 8 (first line beginning with mkMapInner)? I am kind of lost in the syntax. –  Karel Bílek Jul 2 '12 at 22:00
`mkMapInner` is just a method (inside the other method!). Pretend `@annotation.tailrec` doesn't exist, and that the method has arguments `data: Iterator[(K,V)]` and `map: Map[K,Vector[V]]`. The `Map.empty` thing is a default argument, and I wrote the method definition on four lines instead of one just because it got too long. After I'm done with the inner function, all the outer function does is call it (with an `Iterator`, since that's what the inner one wants). –  Rex Kerr Jul 2 '12 at 22:19

For the record, you can write this pretty cleanly with a fold. I'm going to assume that your `Pair` is the one in the standard library (aka `Tuple2`):

``````pairs.foldLeft(Map.empty[Key, Seq[Value]]) {
case (m, (k, v)) => m.updated(k, m.getOrElse(k, Seq.empty) :+ v)
}
``````

Although of course in this case the `groupBy` approach is more convenient.

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``````val ps = collection.mutable.ListBuffer(1 -> 2, 3 -> 4, 1 -> 5)

ps.groupBy(_._1).mapValues(_ map (_._2))
// = Map(1 -> ListBuffer(2, 5), 3 -> ListBuffer(4))
``````

This gives a mutable `ListBuffer` in the output map. If you want your output to be immutable (not sure if this is quite what you're asking), use `collection.breakOut`:

``````ps.groupBy(_._1).mapValues(_.map(_._2)(collection.breakOut))
// = Map(1 -> Vector(2, 5), 3 -> Vector(4))
``````

It seems like `Vector` is the default for `breakOut`, but to be sure, you can specify the return type on the left hand side: `val myMap: Map[Int,Vector[Int]] = ...`.

As a method:

``````def immutableGroup[A,B](xs: Traversable[(A,B)]): Map[A,Vector[B]] =
xs.groupBy(_._1).mapValues(_.map(_._2)(collection.breakOut))
``````
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I perform this function so often that I have an implicit written called `groupByKey` that does precisely this:

``````class EnrichedWithGroupByKey[A, Repr <: Traversable[A]](self: TraversableLike[A, Repr]) {
def groupByKey[T, U, That](implicit ev: A <:< (T, U), bf: CanBuildFrom[Repr, U, That]): Map[T, That] =
self.groupBy(_._1).map { case (k, vs) => k -> (bf(self.asInstanceOf[Repr]) ++= vs.map(_._2)).result }
}
implicit def enrichWithGroupByKey[A, Repr <: Traversable[A]](self: TraversableLike[A, Repr]) = new EnrichedWithGroupByKey[A, Repr](self)
``````

And you use it like this:

``````scala> List(("a", 1), ("b", 2), ("b", 3), ("a", 4)).groupByKey
res0: Map[java.lang.String,List[Int]] = Map(a -> List(1, 4), b -> List(2, 3))
``````

Note that I use `.map { case (k, vs) => k -> ... }` instead of `mapValues` because `mapValues` creates a view, instead of just performing the map immediately. If you plan on accessing those values many times, you'll want to avoid the view approach because it will mean recomputing the `.map(_._2)` every time.

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