I am currently trying to fully understand stream. The concept is not complicated. It is like a list, but the tail part is a thunk instead of concrete sub list.

I can write stream like this:

type 'a stream_t = Nil | Cons of 'a * (unit -> 'a stream_t)

let hd = function
  | Nil -> failwith "hd"
  | Cons (v, _) -> v

let tl = function
  | Nil -> failwith "tl"
  | Cons (_, g) -> g()

let rec take n = function
  | Nil -> []
  | Cons (_, _)  when n = 0 -> []
  | Cons (hd, g) -> hd::take (n-1) (g())

let rec filter f = function
  | Nil -> Nil
  | Cons (hd, g) ->
    if f hd then Cons (hd, fun() -> filter f (g()))
    else filter f (g())

So far so good and I can write a simple stream:

let rec from i = Cons (i, fun() -> from (i+1))

Now, if I was asked to do a primes stream, I feel very difficult. I want to use sieve algorithm. Without thinking of stream, I can do it easily. But for stream, I can't do.

I searched for the code:

(* delete multiples of p from a stream *)
let sift p = filter (fun n -> n mod p <> 0)

(* sieve of Eratosthenes *)
let rec sieve = function
  | Nil -> Nil
  | Cons (p, g) -> 
    let next = sift p (g()) in
    Cons (p, fun () -> sieve next)

(* primes *)
let primes = sieve (from 2)

I can almost understand that it is working. But where is the trick?

Also how to do a stream of permutation of a list?

  • 2
    It's hard to answer because there is no trick. The sieve function works because the head of the stream is always the next prime. The filter function skips over elements that don't pass a test. So in practice the nested filters cause each new int to be tested against all primes seen so far (largest first). – Jeffrey Scofield Oct 28 '14 at 2:13
  • @JeffreyScofield Will this kind of filter nesting cause stackoverflow? – Jackson Tale Oct 28 '14 at 10:44
  • When you reach a new prime, it looks to me like there is a nested call to filter for each prime seen so far. So yes, the stack will get deeper and deeper until it overflows. There are around n / ln n primes less than n, so the depth grows relatively quickly if this is right. – Jeffrey Scofield Oct 28 '14 at 15:04
  • I ran a test on my MacBook Pro, and the code does indeed cause a stack overflow after producing the prime 7720123. The constant accumulation of filters to call also makes the code pretty slow (quadratic in n), so it took 5 hours to reach this prime. – Jeffrey Scofield Oct 29 '14 at 14:19
  • 1
    @JacksonTale: I highly recommend that you check out the paper The Genuine Sieve of Erasthostenes (pdf link), by Melissa O'Neil. She explains why your algorithm has bad asymptotic complexity and also gives a more efficient algorithm thats as efficient as the sieving algorithm you would use on an array. – hugomg Oct 30 '14 at 2:47

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