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In the Scala Collections framework, I think there are some behaviors that are counterintuitive when using map().

We can distinguish two kinds of transformations on (immutable) collections. Those whose implementation calls newBuilder to recreate the resulting collection, and those who go though an implicit CanBuildFrom to obtain the builder.

The first category contains all transformations where the type of the contained elements does not change. They are, for example, filter, partition, drop, take, span, etc. These transformations are free to call newBuilder and to recreate the same collection type as the one they are called on, no matter how specific: filtering a List[Int] can always return a List[Int]; filtering a BitSet (or the RNA example structure described in this article on the architecture of the collections framework) can always return another BitSet (or RNA). Let's call them the filtering transformations.

The second category of transformations need CanBuildFroms to be more flexible, as the type of the contained elements may change, and as a result of this, the type of the collection itself maybe cannot be reused: a BitSet cannot contain Strings; an RNA contains only Bases. Examples of such transformations are map, flatMap, collect, scanLeft, ++, etc. Let's call them the mapping transformations.

Now here's the main issue to discuss. No matter what the static type of the collection is, all filtering transformations will return the same collection type, while the collection type returned by a mapping operation can vary depending on the static type.

scala> import collection.immutable.TreeSet
import collection.immutable.TreeSet

scala> val treeset = TreeSet(1,2,3,4,5) // static type == dynamic type
treeset: scala.collection.immutable.TreeSet[Int] = TreeSet(1, 2, 3, 4, 5)

scala> val set: Set[Int] = TreeSet(1,2,3,4,5) // static type != dynamic type
set: Set[Int] = TreeSet(1, 2, 3, 4, 5)

scala> treeset.filter(_ % 2 == 0)
res0: scala.collection.immutable.TreeSet[Int] = TreeSet(2, 4) // fine, a TreeSet again

scala> set.filter(_ % 2 == 0)    
res1: scala.collection.immutable.Set[Int] = TreeSet(2, 4) // fine

scala> treeset.map(_ + 1)        
res2: scala.collection.immutable.SortedSet[Int] = TreeSet(2, 3, 4, 5, 6) // still fine

scala> set.map(_ + 1)    
res3: scala.collection.immutable.Set[Int] = Set(4, 5, 6, 2, 3) // uh?!

Now, I understand why this works like this. It is explained there and there. In short: the implicit CanBuildFrom is inserted based on the static type, and, depending on the implementation of its def apply(from: Coll) method, may or may not be able to recreate the same collection type.

Now my only point is, when we know that we are using a mapping operation yielding a collection with the same element type (which the compiler can statically determine), we could mimic the way the filtering transformations work and use the collection's native builder. We can reuse BitSet when mapping to Ints, create a new TreeSet with the same ordering, etc.

Then we would avoid cases where

for (i <- set) {
  val x = i + 1
  println(x)
}

does not print the incremented elements of the TreeSet in the same order as

for (i <- set; x = i + 1)
  println(x)

So:

  • Do you think this would be a good idea to change the behavior of the mapping transformations as described?
  • What are the inevitable caveats I have grossly overlooked?
  • How could it be implemented?

I was thinking about something like an implicit sameTypeEvidence: A =:= B parameter, maybe with a default value of null (or rather an implicit canReuseCalleeBuilderEvidence: B <:< A = null), which could be used at runtime to give more information to the CanBuildFrom, which in turn could be used to determine the type of builder to return.

share|improve this question
    
True that your two examples of for( i <- set ... ) are confusing, and I didn't quite follow from where that comes from. But generally, if you are relying on a sorted set, make sure your (known) type is a sorted set. I don't see why if at some point you assign a TreeSet to a val set: Set[...] you could possible want that set to behave like a sorted set. An assignment like val set: Set[...] = ... clearly says to me that you are expecting a set without any implications about the set order. If you want a sorted set, request it. So I don't really see your use case here. –  0__ Apr 15 '11 at 16:14
    
Set vs SortedSet is just an instance of the more general problem. Suppose, as in the example of the article I link, that you hand out your instance of RNA to some general lib that only knows IndexedSeq[Base] does does a map() on it. You'll only get back a Vector[Base] and not an RNA. More generally speaking, it would be nice if the returned collection is as specific as it can be, consistently with filter, etc. –  Jean-Philippe Pellet Apr 15 '11 at 18:23
    
Plus, as a library designer, you might not rely on a SortedSet, but your clients may. I'd hate to have to write processSortedSet[E](xs: SortedSet[E]) in addition to processSet[E](xs: Set[E]). Wouldn't you? –  Jean-Philippe Pellet Apr 16 '11 at 9:22
    
And why not something around processSet[E, S <: Set[E]](xs: S) : S (look for the pimp-my-library questions that involve collections to find the signatures needed to pass in and out any collection type) –  0__ Apr 16 '11 at 23:50
1  
The idea of a sameTypeEvidence is interesting but it won't make the API simpler. The implication of changing the standard libraries cannot be taken lightly. Sometimes some changes improving things in one part could have adverse effects in some other situations. You could try the idea in your own code with a pimp pattern and if you feel that's successful reach out to the mailing list. –  huynhjl Apr 17 '11 at 21:24

1 Answer 1

I looked again at it, and I think your problem doesn't arise from a particular deficiency of Scala collections, but rather a missing builder for TreeSet. Because the following does work as intended:

val list = List(1,2,3,4,5)
val seq1: Seq[Int] = list
seq1.map( _ + 1 ) // yields List

val vector = Vector(1,2,3,4,5)
val seq2: Seq[Int] = vector
seq2.map( _ + 1 ) // yields Vector

So the reason is that TreeSet is missing a specialised companion object/builder:

seq1.companion.newBuilder[Int]    // ListBuffer
seq2.companion.newBuilder[Int]    // VectorBuilder
treeset.companion.newBuilder[Int] // Set (oops!)

So my guess is, if you take proper provision for such a companion for your RNA class, you may find that both map and filter work as you wish...?

share|improve this answer
    
Thanks for investigating, Sciss! You can try the RNA example, it's linked there: stackoverflow.com/questions/5660656/… and comes from Martin Odersky's article there: scala-lang.org/docu/files/collections-api/collections-impl.html and it seems to me that nothing is missing. And indeed, the collections framework cannot do better than the current behavior unless map() knows that the transformation maps objects to the same type. –  Jean-Philippe Pellet Apr 17 '11 at 17:18
1  
As for the TreeSet case: TreeSet does have a TreeSet builder, which requires an implicit Ordering parameter in its newBuilder method, thus treeset.companion cannot be TreeSet because TreeSet.newBuilder does not override Set.newBuilder. Again, we can only solve this if we know we're mapping to the same type. –  Jean-Philippe Pellet Apr 17 '11 at 17:23
2  
There's a very similar problem over in the Haskell world: Sets and Maps can't implement the map function either because they can't enforce the Ord constraint. –  Lambda Fairy Dec 14 '11 at 0:51

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