Normally, definition of primes stream in Richard Bird's formulation of the sieve of Eratosthenes is self-referential:

```
ps = ((2:) . minus [3..] . foldr (\p r-> p*p:union [p*p+p, p*p+2*p..] r) []) ps
```

The primes `ps`

produced by this definition are used as input to it. To prevent a *vicious circle* the definition is primed with the initial value, 2. This corresponds to the mathematical definition of the sieve of Eratosthenes as finding primes in gaps between the composites, enumerated for each prime by counting up in constant increments, **P** = {2,3,4 ...} \ **U** {{*p*^{2}, *p*^{2} + p, *p*^{2} + 2p ...} | *p* in **P**}.

The produced stream is used as input in its own definition. This causes the retention of the whole primes stream in memory (or most of it, see below). The fixpoint here is *sharing*, *corecursive*:

```
fix f = x where x = f x -- sharing fixpoint combinator
primes = fix ((2:).minus[3..].foldr (\p r-> p*p:union [p*p+p, p*p+2*p..] r) [])
```

**The idea****, then, is** to separate this into two streams of primes. First, `primes'`

is defined with reference to itself. Then, `primesLME`

is defined with reference to `primes'`

. So the idea is to have two feeds: one feed loop which is also feeding into a second definition "above" it.

Thus, when `primesLME`

produces some prime `p`

, the `primes'`

stream needs only be instantiated up to about `sqrt p`

, and any primes produced by `primesLME`

can get discarded and GCed by the system.

⁄
⁄
primesLME
⁄
⁄
⁄
⁄
primes'
^ \
/ |
\_______/

Primes produced by `primes'`

can not be immediately discarded, because they are needed for `primes'`

stream itself. When `primes'`

has produced a prime `q`

, only its part below `sqrt q`

can be discarded, just after it has been consumed by the `foldr`

part of the computation. IOW this sequence definition maintains back pointers into itself down to the `sqrt`

of its farthest (biggest) produced value (as it is been consumed by its consumer(s)).

So with one feed loop almost the whole sequence would have to be retained in memory, and with the double feed only the inner loop needs to be mostly retained, which only reaches up to `sqrt`

of the current value produced by the main stream. Thus the overall space complexity is reduced from about `O(N)`

to about `O(sqrt(N))`

- a drastic reduction.

For this to work the code must be compiled with optimizations, say with `-O2`

switch, and run standalone. You may also have to use `-fno-cse`

switch. And it will depend on particulars of a given GHC version, and whether there is only one reference to `primesLME`

in the testing code:

```
main = getLine >>= (print . take 5 . (`drop` primesLME) . (+(-1)) . read)
```

might work. In fact when tested at Ideone, it does show a practically constant memory consumption.

**And it's the Sieve of Eratosthenes, not Euler's sieve.**

The initial definitions are:

```
eratos (x:xs) = x : eratos (minus xs $ map (*x) [x ..]) -- ps = eratos [2..]
eulers (x:xs) = x : eulers (minus xs $ map (*x) (x:xs)) -- ps = eulers [2..]
```

Both are very inefficient, because of premature handling of the multiples. It is easy to remedy the first by *fusing* the `map`

and the enumeration into one enumeration moved further away (from `x`

to `x*x`

), so that its handling can be then postponed - because here each prime's multiples are *independently generated* (enumerated at fixed intervals):

```
eratos (p:ps) xs | (h,t) <- span (< p*p) xs = -- ps = 2 : eratos ps [2..]
h ++ eratos (minus t [p*p, p*p + p ..])
```

which is the same as the Bird's sieve at the top of this post, *segment*-wise:

```
ps = concatMap snd $ iterate
(\((n, p2:t@(q2:_)),_) -> ((n+1,t),
minus [p2+1 .. q2-1] $ foldr union []
[[p2+i-r, p2+i+i-r .. q2-1] | i <- take n ps, let r=rem p2 i]))
((1,map (^2) ps), [2,3])
```

Not so for the second definition.

*addition:* you can see the same idea implemented with Python generators, for comparison, here.

In fact, the above mentioned Python code employs a *telescopic, multistage* recursive production of ephemeral primes streams; in Haskell we can arrange for it using *non-sharing*, *recursive* fixpoint combinator, `_Y`

:

```
primesL = 2 : _Y ( (3:) . gaps 5 . joinL . map (\p->[p*p, p*p+2*p..]) )
where
_Y g = g (_Y g) -- non-sharing, recursive fixpoint combinator
-- = x where x = g x -- corecursive, sharing definition
-- = g x where x = g x -- corecursive, sharing, two stages
gaps k s@(x:xs) | k<x = k : gaps (k+2) s -- == [k,k+2..]`minus`s,
| True = gaps (k+2) xs -- where k<=x
```