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So I've spent hours trying to work out exactly how this code produces prime numbers.

lazy val ps: Stream[Int] = 2 #:: Stream.from(3).filter(i =>
   ps.takeWhile{j => j * j <= i}.forall{ k => i % k > 0});

I've used a number of printlns etc, but nothings making it clearer.

This is what I think the code does:

/**
 * [2,3] 
 * 
 * takeWhile 2*2 <= 3 
 * takeWhile 2*2 <= 4 found match
 *      (4 % [2,3] > 1) return false.
 * takeWhile 2*2 <= 5 found match
 *      (5 % [2,3] > 1) return true 
 *          Add 5 to the list
 * takeWhile 2*2 <= 6 found match
 *      (6 % [2,3,5] > 1) return false
 * takeWhile 2*2 <= 7
 *      (7 % [2,3,5] > 1) return true
 *          Add 7 to the list
 */

But If I change j*j in the list to be 2*2 which I assumed would work exactly the same, it causes a stackoverflow error.

I'm obviously missing something fundamental here, and could really use someone explaining this to me like I was a five year old.

Any help would be greatly appreciated.

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1  
Why use "lazy"? Initializing the Stream doesn't take much time or memory, and it works fine without ps being lazy, right? –  AmigoNico Mar 24 '13 at 16:57
    
@AmigoNico mmlac brought this to my attention in a comment on my answer -- lazy may actually be necessary since the val has a recursive definition. Curiously, in my own testing in Scala 2.10.4, lazy was not required at the REPL but was required in ordinary code -- presumably a REPL bug. –  Aaron Novstrup Dec 8 '14 at 6:06
    
Ah, of course it does. I should have looked more closely. –  AmigoNico Dec 8 '14 at 12:40

3 Answers 3

up vote 17 down vote accepted

I'm not sure that seeking a procedural/imperative explanation is the best way to gain understanding here. Streams come from functional programming and they're best understood from that perspective. The key aspects of the definition you've given are:

  1. It's lazy. Other than the first element in the stream, nothing is computed until you ask for it. If you never ask for the 5th prime, it will never be computed.

  2. It's recursive. The list of prime numbers is defined in terms of itself.

  3. It's infinite. Streams have the interesting property (because they're lazy) that they can represent a sequence with an infinite number of elements. Stream.from(3) is an example of this: it represents the list [3, 4, 5, ...].

Let's see if we can understand why your definition computes the sequence of prime numbers.

The definition starts out with 2 #:: .... This just says that the first number in the sequence is 2 - simple enough so far.

The next part tells us how to compute the rest of the prime numbers. We start with all the counting numbers starting at 3 (Stream.from(3)), but we obviously need to filter a bunch of these numbers out. So let's consider each number i. If i is not a multiple of a lesser prime number, then i is prime. That is, i is prime if, for all primes k less than i, i % k > 0. In Scala, we could express this as

nums.filter(i => ps.takeWhile(k => k < i).forall(k => i % k > 0))

However, it isn't actually necessary to check all lesser prime numbers -- we really only need to check the prime numbers whose square is less than or equal to i (this is a fact from number theory). So we could instead write

nums.filter(i => ps.takeWhile(k => k * k <= i).forall(k => i % k > 0))

So we've derived your definition.

Now, if you happened to try the first definition (with k < i), you would have found that it didn't work. Why not? It has to do with the fact that this is a recursive definition.

Suppose we're trying to decide what comes after 2 in the sequence. The definition tells us to first see whether 3 belongs. To do so, we get the list of primes up to the first one greater than or equal to 3 (takeWhile(k => k < i)). The first prime is 2, which is less than 3 -- so far so good. But we don't yet know the second prime, so we need to compute it. Fine, so we need to first see whether 3 belongs ... BOOM!

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1  
Thank you Aaron. Very much appreciated. I did in fact try the k < i ( as well as countless other scenarios trying to work this out) I now understand why it went BOOM! Thanks again. –  Alan Hollis Mar 24 '13 at 12:17
    
The best explanation out of all. Thanks :) –  Jatin Apr 23 '13 at 6:20
    
Will break in current scalac with "forward reference extends over definition of value ps" error. Tested 2.11.4, 2.10.4 and 2.9.0 –  mmlac Dec 7 '14 at 10:58
    
@mmlac What breaks? The OP's original code? Only in 2.11? –  Aaron Novstrup Dec 7 '14 at 18:15
    
@AaronNovstrup If I understand your solution correctly, this should work. Error inline. gist.github.com/mmlac/fb5e850b17ebdd2d94bc –  mmlac Dec 8 '14 at 2:00

Your explanations are mostly correct, you made only two mistakes:

takeWhile doesn't include the last checked element:

scala> List(1,2,3).takeWhile(_<2)
res1: List[Int] = List(1)

You assume that ps always contains only a two and a three but because Stream is lazy it is possible to add new elements to it. In fact each time a new prime is found it is added to ps and in the next step takeWhile will consider this new added element. Here, it is important to remember that the tail of a Stream is computed only when it is needed, thus takeWhile can't see it before forall is evaluated to true.

Keep these two things in mind and you should came up with this:

ps = [2]
i = 3
  takeWhile
    2*2 <= 3 -> false
  forall on []
    -> true
ps = [2,3]
i = 4
  takeWhile
    2*2 <= 4 -> true
    3*3 <= 4 -> false
  forall on [2]
    4%2 > 0 -> false
ps = [2,3]
i = 5
  takeWhile
    2*2 <= 5 -> true
    3*3 <= 5 -> false
  forall on [2]
    5%2 > 0 -> true
ps = [2,3,5]
i = 6
...

While these steps describe the behavior of the code, it is not fully correct because not only adding elements to the Stream is lazy but every operation on it. This means that when you call xs.takeWhile(f) not all values until the point when f is false are computed at once - they are computed when forall wants to see them (because it is the only function here that needs to look at all elements before it definitely can result to true, for false it can abort earlier). Here the computation order when laziness is considered everywhere (example only looking at 9):

ps = [2,3,5,7]
i = 9
  takeWhile on 2
    2*2 <= 9 -> true
  forall on 2
    9%2 > 0 -> true
  takeWhile on 3
    3*3 <= 9 -> true
  forall on 3
    9%3 > 0 -> false
ps = [2,3,5,7]
i = 10
...

Because forall is aborted when it evaluates to false, takeWhile doesn't calculate the remaining possible elements.

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Thank you so much for taking the time to reply to this. This is making a lot sense to me now, the clarification of how the lazy keyword works also really helped explain why I was getting the println outputs I was getting. –  Alan Hollis Mar 24 '13 at 12:06
1  
@AlanHollis: the lazy keyword is not needed in this case, the code also works without it. This is because Stream internally is already lazy. The keyword just makes the call to the reference lazy, not the data structure itself. –  sschaef Mar 24 '13 at 12:17
    
@WillNess: yes, that is true. I changed it. –  sschaef Mar 24 '13 at 16:07

Here's a pseudocode1 translation of your code, with some variables renamed for clarity (p stands for "prime"):

ps = 2 : filter (\i-> all (\p->rem i p > 0) (takeWhile (\p->p^2 <= i) ps)) [3..]

which is also

ps = 2 : [i | i <- [3..], and [rem i p > 0 | p <- takeWhile (\p->p^2 <= i) ps]]

which is a bit more visually apparent, using list comprehensions. and checks that all entries in a list of Booleans are True (read | as "for", <- as "drawn from", , as "such that" and (\p-> ...) as "lambda of p").

So you see, ps is a lazy list of 2, and then of numbers i drawn from a stream [3,4,5,...] such that for all p drawn from ps such that p^2 <= i, it is true that i % p > 0. Which is actually an optimal trial division algorithm. :)

There's a subtlety here of course: the list ps is open-ended. We use it as it is being "fleshed-out" (that of course, because it is lazy). When ps are taken from ps, it could potentially be a case that we run past its end, in which case we'd have a non-terminating calculation on our hands (a "black hole"). It just so happens :) (and needs to ⁄ can be proved mathematically) that this is impossible with the above definition. So 2 is put into ps unconditionally, so there's something in it to begin with.

But if we try to "simplify",

bad = 2 : [i | i <- [3..], and [rem i p > 0 | p <- takeWhile (\p->p < i) bad]]

it stops working after producing just one number, 2: when considering 3 as the candidate, takeWhile (\p->p < 3) bad demands the next number in bad after 2, but there aren't yet any more numbers there. It "jumps ahead of itself".

This is "fixed" with

bad = 2 : [i | i <- [3..], and [rem i p > 0 | p <- [2..(i-1)] ]]

but that is a much much slower trial division algorithm, very far from the optimal one.

--

1 (Haskell actually, it's just easier for me that way :) )

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Thank you Will Ness, the psuedocode helped a lot. I think because the ordering of the all and the takeWhile funtions are left->right which makes it easier to read. The fixed version helped me understand where I was going wrong trying to achieve the same thing in a less complex manor! Thanks again, Alan –  Alan Hollis Mar 24 '13 at 13:22
    
@AlanHollis glad that helped. :) wan't sure at all if it would. :) With 2 instead of j we get ps = 2 : [i | i <- [3..], and [rem i p > 0 | p <- takeWhile (\p->4 <= i) ps]] so for i==3 it's takeWhile (\p->False) ps == [] and 3 goes through OK (because and [] == True), but for i==4 it is takeWhile(p->True) ps which never stops asking new numbers from ps. –  Will Ness Mar 24 '13 at 14:54

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