Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

Suppose I want a Scala data structure that implements a 2-dimensional table of counts that can change over time (i.e., individual cells in the table can be incremented or decremented). What should I be using to do this?

I could use a 2-dimensional array:

val x = Array.fill[Int](1, 2) = 0
x(1)(2) += 1

But Arrays are mutable, and I guess I should slightly prefer immutable data structures.

So I thought about using a 2-dimensional Vector:

val x = Vector.fill[Int](1, 2) = 0
// how do I update this? I want to write something like val newX : Vector[Vector[Int]] = x.add((1, 2), 1)
// but I'm not sure how

But I'm not sure how to get a new vector with only a single element changed.

What's the best approach?

share|improve this question
1  
vector's .update method is guaranteed to be done in effectively constant time –  om-nom-nom Sep 26 '12 at 21:56
2  
@om-nom-nom - Albeit with a very, very large constant factor compared to changing a primitive in an array. About 500x in my hands for a 100x100 Array / Vector, if you just want to update one random cell in the matrix over and over again. –  Rex Kerr Sep 26 '12 at 22:12

3 Answers 3

up vote 3 down vote accepted

Best depends on what your criteria are. The simplest immutable variant is to use a map from (Int,Int) to your count:

var c = (for (i <- 0 to 99; j <- 0 to 99) yield (i,j) -> 0).toMap

Then you access your values with c(i,j) and set them with c += ((i,j) -> n); c += ((i,j) -> (c(i,j)+1)) is a little bit annoying, but it's not too bad.

Faster is to use nested Vectors--by about a factor of 2 to 3, depending on whether you tend to re-set the same element over and over or not--but it has an ugly update method:

var v = Vector.fill(100,100)(0)
v(82)(49)     // Easy enough
v = v.updated(82, v(82).updated(49, v(82)(49)+1)    // Ouch!

Faster yet (by about 2x) is to have only one vector which you index into:

var u = Vector.fill(100*100)(0)
u(82*100 + 49)    // Um, you think I can always remember to do this right?
u = u.updated(82*100 + 49, u(82*100 + 49)+1)       // Well, that's actually better

If you don't need immutability and your table size isn't going to change, just use an array as you've shown. It's ~200x faster than the fastest vector solution if all you're doing is incrementing and decrementing an integer.

share|improve this answer
    
Looks like this is the case David Maclver talked about –  om-nom-nom Sep 26 '12 at 22:47
    
@om-nom-nom - No, he was saying functional isn't automatically better. This is showing that immutable isn't automatically better. Normally the two go hand-in-hand, but they're not the same thing. –  Rex Kerr Sep 27 '12 at 9:23

There isn't a built-in method for this, perhaps because it would require the Vector to know that it contains Vectors, or Vectors or Vectors etc, whereas most methods are generic, and it would require a separate method for each number of dimensions, because you need to specify a co-ordinate arg for each dimension.

However, you can add these yourself; the following will take you up to 4D, although you could just add the bits for 2D if that's all you need:

object UpdatableVector {
  implicit def vectorToUpdatableVector2[T](v: Vector[Vector[T]]) = new UpdatableVector2(v)
  implicit def vectorToUpdatableVector3[T](v: Vector[Vector[Vector[T]]]) = new UpdatableVector3(v)
  implicit def vectorToUpdatableVector4[T](v: Vector[Vector[Vector[Vector[T]]]]) = new UpdatableVector4(v)

  class UpdatableVector2[T](v: Vector[Vector[T]]) {
    def updated2(c1: Int, c2: Int)(newVal: T) =
      v.updated(c1, v(c1).updated(c2, newVal))
  }

  class UpdatableVector3[T](v: Vector[Vector[Vector[T]]]) {
    def updated3(c1: Int, c2: Int, c3: Int)(newVal: T) =
      v.updated(c1, v(c1).updated2(c2, c3)(newVal))
  }

  class UpdatableVector4[T](v: Vector[Vector[Vector[Vector[T]]]]) {
    def updated4(c1: Int, c2: Int, c3: Int, c4: Int)(newVal: T) =
      v.updated(c1, v(c1).updated3(c2, c3, c4)(newVal))
  }
}

In Scala 2.10 you don't need the implicit defs and can just add the implicit keyword to the class definitions.

Test:

  import UpdatableVector._

  val v2 = Vector.fill(2,2)(0)
  val r2 = v2.updated2(1,1)(42)
  println(r2) // Vector(Vector(0, 0), Vector(0, 42))

  val v3 = Vector.fill(2,2,2)(0)
  val r3 = v3.updated3(1,1,1)(42)
  println(r3) // etc

Hope that's useful.

share|improve this answer

If you want to do this in a very general and functional (but not necessarily performant) way, you can use lenses. Here's an example of how you could use Scalaz 7's implementation, for example:

import scalaz._

def at[A](i: Int): Lens[Seq[A], A] = Lens.lensg(a => a.updated(i, _), (_(i)))
def at2d[A](i: Int, j: Int) = at[Seq[A]](i) andThen at(j)

And a little bit of setup:

val table = Vector.tabulate(3, 4)(_ + _)

def show[A](t: Seq[Seq[A]]) = t.map(_ mkString " ") mkString "\n"

Which gives us:

scala> show(table)
res0: String = 
0 1 2 3
1 2 3 4
2 3 4 5

We can use our lens like this:

scala> show(at2d(1, 2).set(table, 9))
res1: String = 
0 1 2 3
1 2 9 4
2 3 4 5

Or we can just get the value at a given cell:

scala> val v: Int = at2d(2, 3).get(table)
v: Int = 5

Or do a lot of more complex things, like apply a function to a particular cell:

scala> show(at2d(2, 2).mod(((_: Int) * 2), table))
res8: String = 
0 1 2 3
1 2 3 4
2 3 8 5

And so on.

share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.