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?

`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`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`filter`

s 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