How can I sum a list of options List[Option[Double]] with the following rules?

  • List(Some(1), ..., Some(n)) --> Some(1 + ... + n)
  • List(Some(1), ..., Some(n), None) --> None
  • List(None, ..., None) --> None
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    val l = list.flatten; if (l.size == list.size) Some(l.sum) else None – Jus12 Sep 5 '16 at 20:43
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    @Jus12 Another inefficient solution, this requires 2 full traversals of the list, it's not a valid suggestion as a result. – flavian Sep 5 '16 at 21:04

This is a straight foldMap method call, if you're using Cats, you should probably just use that, as it folds over a collection summing the values using a Monoid.

Otherwise, to avoid the traversal of the entire list with a forall to check if the entire set of options is defined, you could use a foldLeft, and use the fact that you can yield a None the first time you find an empty element in the chain.

def sumList[ T ] (list: List[Option[T]])(implicit ev: Numeric[T]): Option[T] = {
  list.foldLeft(Option(ev.zero)) { case (acc, el) => 
    el.flatMap(value => acc.map(ac => ev.plus(ac, value)))

sumList(List(None, None, Some(5)))
res10: Option[Int] = None

scala> sumList(List(None, None, Some(5F)))
res11: Option[Float] = None

scala> sumList[Double](List(None, None, None))
res13: Option[Double] = None

scala> sumList(List(Some(5), Some(15)))
res14: Option[Int] = Some(20)

And to avoid return you could simply use recursion(update, return is not needed above, but maybe this is easier to follow):

def sumListRec[T](list: List[Option[T]], acc: T)(implicit ev: Numeric[T]): Option[T] = {
  list match {
    // if the list still has elements
    case head :: tail => head match {
      // add the value to the accumulator and keep going
      case Some(value) => sumListRec(tail, ev.plus(acc, value))
      // if you found a None, disregard whatever sum we built so far
      // and just return None
      case None => None
    // If the list is empty, it means we've successfully reached
    // the end of the list, so we just return the sum we built.
    case Nil => Some(acc)

Watch it in action:

scala> sumListRec(List(Some(5D), Some(5D)), 0D)
res5: Option[Double] = Some(10.0)

sumListRec(List(None, None, Some(5D)), 0D)
res2: Option[Double] = None

scala> sumListRec(List(None, None), 0D)
res6: Option[Double] = None
| improve this answer | |
  • I like the recursive solution. Just used inside the same function without the acc and initialized it with implicitly[Numeric[T]].zero. – DennisVDB Sep 5 '16 at 20:42
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    This solution is way way more complicated than it needs to be. – michau Sep 5 '16 at 20:52
  • @michau That's because yours is inefficient, and will continue the traversal regardless of having encountered a None. The devil is in the details. It's also ugly Scala wise, and you revolve to a direct call to .get. – flavian Sep 5 '16 at 21:02
  • As Donald Knuth said: premature optimization is the root of all evil. There was no indication from OP that his case is one of those 3% that need the most efficient solution, rather than one of those 97% that need the most readable solution. – michau Sep 5 '16 at 21:10
  • @michau This is CompSci 101... nothing premature. – flavian Sep 5 '16 at 21:10

If you use Scalaz this is super easy:

| improve this answer | |
  • Impressive! I agree with the Knuth proverb, but: how efficient is this? – sscarduzio Sep 5 '16 at 23:08
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    @sscarduzio If the list is full of Some instances it'll walk it twice (effectively) to get the result. The first time will produce a List of all the Int values and then it'll walk that list to produce the sum. But if that's slow you're probably better off eliminating the List of Options before anything else. – Sean Parsons Sep 6 '16 at 9:41

There is even a simpler way just using fold:

val ls = List(Some(2.1d), Some(5.6d), Some(4.3d), Some(1.2))

ls.fold(Option(0d))((rs,x) => for(n <- x; m <- rs) yield {n+m})

=> Some(13.2)

val ls = List(Some(2.1d),None, Some(5.6d), Some(4.3d), Some(1.2))

ls.fold(Option(0d))((rs,x) => for(n <- x; m <- rs) yield {n+m})

=> None

| improve this answer | |

You can do it like this. Edit: changed the code to return immediately after encountering None. I admit, this optimisation neither complicates code too much nor impedes readability (as I thought before).

def sumOpt(list: List[Option[Double]]): Option[Double] = list.reduce((x,y) => {
  if (x.isEmpty || y.isEmpty) return None
  else Some(x.get + y.get)
| improve this answer | |
  • Do you really need the return keyword? – Jus12 Sep 6 '16 at 2:46
  • Yes, because I want to return from sumOpt, not from the anonymous function. That allows me to stop immediately after encountering None. – michau Sep 6 '16 at 6:07

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