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Is there a nice way in Scala to delete multiple indices from a ListBuffer (in a fast way) ?


val indicesToDelete = List(4, 1)
val buffer = ListBuffer(a, b, c, d, e)


ListBuffer(b, c, e)

I could not find a pre-defined function that does the job.

One could sort the indices and remove the elements beginning with the highest index etc, so there will be no complication. But sorting requires O(n * log n). Is there a faster way (maybe something pre-defined I missed) ?

UPDATE 1: The elements should be removed in the existing ListBuffer object, no new ListBuffer object should be created.

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It's not entirely clear from your description whether you want to create a new ListBuffer or mutate the existing one. That's going to have a huge impact on the style of code that needs to be written. Most of the answers written so far seem to have interpreted as "create a new one" but the concern about index renumbering in your description seems to imply in-place delete. –  James Iry Jul 12 '12 at 14:47
One can sort indicesToDelete in O(n) using radix sort –  Sergey Weiss Jul 13 '12 at 9:10
@JamesIry Yes, you are right, this point was not clear. Yes, I wanted to do the removing as an in-place deletion, not creating a new ListBuffer. –  John Threepwood Jul 15 '12 at 17:41

4 Answers 4

up vote 4 down vote accepted

Unlike others, I'm going to assume you want to do your work in-place because you mention a concern about index renumbering. If the sort is all you care about then

1) Stick the indices to be removed into a constant time lookup set instead of a list. A hash set or bit set would seem appropriate depending on the range of indices. 2) Walk the list buffer in reverse order removing indices that are in the to-delete set.

scala> val buffer = ListBuffer("a", "b", "c", "d", "e")
buffer: scala.collection.mutable.ListBuffer[java.lang.String] = ListBuffer(a, b, c, d, e)

scala> val indicesToDelete = BitSet(4, 1)
indicesToDelete: scala.collection.mutable.BitSet = BitSet(1, 4)

scala> for (i <- (buffer.size -1) to 0 by -1) if (indicesToDelete contains i) buffer remove i

scala> buffer
res19: scala.collection.mutable.ListBuffer[java.lang.String] = ListBuffer(a, c, d)

Note that while this removes the n log n sort of indices, that doesn't make this a linear algorithm. In-place delete from an array-like structure isn't cheap. Higher indices have to be copied downward on each delete.

To get a linear delete of indices you need to do something much hairier, you need to 1) walk in the forward direction copying non-deleted elements downward based on the number that you've deleted so far. When you're done you 2) remove the top n elements where n is the number that you deleted.

scala> val buffer = ListBuffer("a", "b", "c", "d", "e")  
buffer: scala.collection.mutable.ListBuffer[java.lang.String] = ListBuffer(a, b, c, d, e)

scala> val indicesToDelete = BitSet(4, 1)
indicesToDelete: scala.collection.mutable.BitSet = BitSet(1, 4)

scala> var deleted = 0
deleted: Int = 0

scala> for (i <- 0 until buffer.size)
     |    if (indicesToDelete contains i) {
     |       deleted += 1
     |    } else if (deleted > 0) {
     |        buffer(i - deleted) = buffer(i)
     |    }

scala> }

scala> buffer trimEnd deleted

scala> buffer
res0: scala.collection.mutable.ListBuffer[java.lang.String] = ListBuffer(a, c, d)
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Thank you, that helped a lot. Yes, I wanted to remove the elements from the ListBuffer I am working with and not create a new one. –  John Threepwood Jul 15 '12 at 17:40

You have to use zipWithIndex, as the other posts already do, because otherwise the indices will shift and you could accidentally remove wrong items. But instead of foldLeft or filter + map I would use collect, what in this case does the same as filter + map, but in a single step.

buffer.zipWithIndex.collect { case (x,i) if !indicesToDelete.contains(i) => x }

this can also be written as

for {
  (x,i) <- buffer.zipWithIndex
  if !indicesToDelete.contains(i)
} yield x
share|improve this answer
Nice. I knew there'd be a more concise way than filter+map. Good old SO. –  Alex Wilson Jul 12 '12 at 10:08
Is this an O(MN) solution? –  xiaowl Jul 12 '12 at 10:12
Depends on indicesToDelete. If it is a List it's O(MN), if it is a Set it is O(N log M). –  drexin Jul 12 '12 at 10:17
@drexin: And O(N) amortized for a HashSet for appropriately small numbers of M. –  Alex Wilson Jul 12 '12 at 10:49
@drexin Good answer, thank you. –  John Threepwood Jul 15 '12 at 17:43

How about:

buffer.zipWithIndex.filter( p => !(indicesToDelete contains p._2) ).map( _._1 )

Which is O(NM) where N is the number in buffer, M the number of elements in indicesToDelete.

And if you're concerned about performance, you could always make indicesToDelete a Set. In which case the performance is O(N): assuming O(1) amortised lookup for a HashSet or O(NlogM) for a TreeSet.

And collating all the good ideas from the other posters:

buffer.view.zipWithIndex.collect { case (x,i) if !indicesToDelete.contains(i) => x }

To give you one pass over the data only.

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You can easily optimize this by utilizing a view like so: buffer.view.zipWithIndex.filter( p => !(indicesToDelete contains p._2) ).map( _._1 ).toList. This way it'll traverse the collection just once –  Nikita Volkov Jul 12 '12 at 10:09
import collection.mutable.ListBuffer

val indicesToDelete = List(4, 1)
val buffer = ListBuffer('a', 'b', 'c', 'd', 'e')

def exclude[T](l:ListBuffer[T], indice: List[Int]) = {
  val set = indice.toSet
  l.zipWithIndex.foldLeft(ListBuffer.empty[T]){ case (c, next) =>
    if(set(next._2+1)) c else c :+ next._1


exclude(buffer, indicesToDelete)
share|improve this answer
This is O(N log M), because every lookup in set is O(log N) –  drexin Jul 12 '12 at 10:20

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