# Scala: iterate a sequence while modifying it?

I'm trying to implement the Sieve of Eratosthenes in Scala.

I start by initializing a sequence of all odd numbers plus 2:

``````// (end goal is to find all prime factors of bigNumber)
val largestPrime : Long = Math.ceil(Math.sqrt(bigNumber)).toLong
var nums : Seq[Long] = (3L to largestPrime by 2L).toSeq
nums +: 2L
``````

Now `nums` contains Seq( 2,3,5,7,9,11,13,15,...,(largestPrime) ). Then, by the Sieve, I want to iterate over each element, and filter all multiples of that element from the Seq. It would look something like this, except this simply iterates over every odd number:

``````for(i : Long <- 3L to largestPrime by 2L) {
nums = nums.filter((j : Long) => j == i || j % i != 0)
}
``````

So instead, I would want to use something like this:

``````for(i <- nums) {
// filter
}
``````

But of course, this simply copies the sequence into an iterator and then iterates over every value in `nums` as it was at the beginning of the for loop (so in this case, it's exactly equivalent to the previous example). I want it to, every iteration, grab the next value from `nums`.

How is the best way to implement this? Should I use an index variable and a while loop? I'm not sure how to get an element from a sequence (i.e. how to get element x of the sequence, where x is the index). Or is there a more functional way to do this?

Edit: I just found the `scanLeft` function, I'm trying to grasp how to use it as I suspect it might be of use in this case...

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Let's start off with what I deem to be the biggest problem above. You have this:

``````for (i <- mi) { mi = something else }
``````

This will not change the `mi` that is being iterated over. That `mi` will stay the same throughout. It might be that you can mutate the value of `mi`, but changing it won't work. Mutating it may not work either, by the way.

So, how do you do it? You don't use for comprehensions -- or, at least, not this way. You can look at my own version here, which iterates through a different collection than the one being mutated. Or here is a one-liner:

``````(n: Int) => (2 to n) |> (r => r.foldLeft(r.toSet)((ps, x) => if (ps(x)) ps -- (x * x to n by x) else ps))
``````

Now, back to what you want to do... when you use a for-comprehension, you are actually calling the method `foreach`, `map` or `flatMap` on it, so you'd need a collection which is capable of handling one of these methods and not having trouble with the "next" element changing from one iteration to the next. As I said, I'm not sure any of Scala's collection fit the bill. You'd be better off using a `while` loop and keeping track of things yourself if you go this way. For instance:

``````def primes(n: Int) = {
val primes = LinkedList(3 to n by 2: _*)
var p = primes
while (p.nonEmpty) {
var scanner = p
while (scanner.next.nonEmpty) {
scanner.next = scanner.next.next
else
scanner = scanner.next
}
p = p.next
}
primes
}
``````

Note that I keep a pointer to the start of the `LinkedList`, move `p` through each known prime, and move `scanner` through all remaining numbers to cut the non-primes.

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The example in the docs on scala.collection.immutable.Stream is of a sieve:

``````object Main extends Application {

def from(n: Int): Stream[Int] =
Stream.cons(n, from(n + 1))

def sieve(s: Stream[Int]): Stream[Int] =

def primes = sieve(from(2))

primes take 10 print
}
``````
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It's horribly inefficient though. I tried learning scala by creating a more efficient version, and blogged about it datacute.wordpress.com/2008/04/16/basic-primes-in-scala –  Stephen Denne Dec 23 '10 at 23:35
This is NOT a Sieve of Eratosthenes (which you do not claim it to be, but the question is about Sieve of Eratosthenes). –  Daniel C. Sobral Dec 24 '10 at 1:02
@Daniel thanks for your answer, especially the link to your version which very clearly implements Eratosthenes process –  Stephen Denne Dec 24 '10 at 1:59
the one liner does implements Eratosthenes too, actually. –  Daniel C. Sobral Dec 24 '10 at 2:34

Neither a good functional solution nor a solution which reveals obscure Scala Library treasures but it’s rather easy building a specialised iterator yourself.

``````class ModifyingIterator(var collection: Seq[Long]) extends Iterator[Long] {
def next = {
current = collection.find(_ > current).get
current
}
def hasNext = collection.exists(_ > current)
}

val mi = new ModifyingIterator(nums)

for (i <- mi) {
mi.collection = mi.collection.filter((j : Long) => j == i || j % i != 0)
}
println(mi.collection)
``````

`ModifyingIterator` keeps track of the current item and allows for reassigning the collection which is used for iterating. The next item is always larger than the current item.

Of course, one should probably employ a better data structure which does not keep track of the current value but keep a pointer to the current item in order to get rid of the useless search every time.

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Ouch, you keep scanning a `Seq` again and again! –  Daniel C. Sobral Dec 24 '10 at 1:04
As I’ve said, it definitely should be improved. :) –  Debilski Dec 24 '10 at 11:40

There is an interesting paper: http://www.cs.hmc.edu/~oneill/papers/Sieve-JFP.pdf

I tried to translate the Haskell code given in that paper to Scala, but I didn't test the performance.

``````object primes {

type SI = Stream[Int]

def sieve:SI = {
def wheel2357:SI = Stream(4,2,4,6,2,6,4,2,4,6,6,
2,6,4,2,6,4,6,8,4,2,4,2,4,8,6,4,6,2,4,6,2,6,
6,4,2,4,6,2,6,4,2,4,2,10,2,10,2) append wheel2357
def spin(s:SI, n:Int):SI = Stream.cons(n, spin(s.tail, n + s.head))

case class It(value:Int, step:Int) {
def next = new It(value + step, step)

def atLeast(c:Int):It =
if (value >= c) this
else new It(value + step, step).atLeast(c)
}

implicit object ItOrdering extends Ordering[It] {
def compare(thiz:It, that:It) = {
val r = thiz.value - that.value
if (r == 0) thiz.step - that.step else r
}

}

import scala.collection.immutable.TreeSet

def sieve(cand:SI, set:Set[It]):SI = {
val set1 = TreeSet[It]() ++ set.dropWhile(_.value < c) ++
set.takeWhile(_.value < c).map(_.atLeast(c))
if (set1.elements.next.value == c) {
val set2 = TreeSet[It]() ++ set1.dropWhile(_.value == c) ++
set1.takeWhile(_.value == c).map(_.next)
sieve(cand.tail, set2)
} else {
Stream.cons(c, sieve(cand.tail, set1 + It(c*c,2*c)))
}
}
Stream(2,3,5,7,11) append sieve(spin(wheel2357,13),
new TreeSet[It] + It(121,22))
}

def main(args:Array[String]) {
sieve.takeWhile(_ < 1000).foreach(println)
}
}
``````
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