It defines a generator - **a stream transformer called "sieve"**,

```
Sieve s =
while( True ):
p := s.head
s := s.tail
yield p -- produce this
s := Filter (nomultsof p) s -- go next
primes := Sieve (Nums 2)
```

which uses a curried form of an anonymous function equivalent to

```
nomultsof p x = (mod x p) /= 0
```

Both `Sieve`

and `Filter`

are data-constructing operations with internal state and by-value argument passing semantics.

Here we can see that **the most glaring problem** of this code is **not**, repeat **not** that it uses trial division to filter out the multiples from the working sequence, whereas it could find them out directly, by counting up in increments of `p`

. If we were to replace the former with the latter, the resulting code would still have abysmal run-time complexity.

No, its most glaring problem is that it puts a `Filter`

on top of its working sequence **too soon**, when it should really do that *only after* the prime's square is seen in the input. As a result it creates a *quadratic* number of `Filter`

s compared to what's really needed. The chain of `Filter`

s it creates is too long, and most of them aren't even needed at all.

The corrected version, with the filter creation **postponed** until the proper moment, is

```
Sieve ps s =
while( True ):
x := s.head
s := s.tail
yield x -- produce this
p := ps.head
q := p*p
while( (s.head) < q ):
yield (s.head) -- and these
s := s.tail
ps := ps.tail -- go next
s := Filter (nomultsof p) s
primes := Sieve primes (Nums 2)
```

or in Haskell,

```
primes = sieve primes [2..]
sieve ps (x:xs) = x : h ++ sieve pt [x | x <- t, rem x p /= 0]
where (p:pt) = ps
(h,t) = span (< p*p) xs
```

`rem`

is used here instead of `mod`

as it can be much faster in some interpreters, and the numbers are all positive here anyway.

Measuring the local orders of growth of an algorithm by taking its run times `t1,t2`

at problem-size points `n1,n2`

, as `logBase (n2/n1) (t2/t1)`

, we get `O(n^2)`

for the first one, and just above `O(n^1.4)`

for the second (in `n`

primes produced).

Just to clarify it, the missing parts could be defined in this (imaginary) language simply as

```
Nums x = -- numbers from x
while( True ):
yield x
x := x+1
Filter pred s = -- filter a stream by a predicate
while( True ):
if pred (s.head) then yield (s.head)
s := s.tail
```

see also.

*update:* Curiously, the first instance of this code in David Turner's 1976 SASL manual according to A.J.T. Davie's 1992 Haskell book,

```
primes = sieve [2..]
-- [Int] -> [Int]
sieve (p:nos) = p : sieve (remove (multsof p) nos)
```

actually admits *two* *pairs* of implementations for `remove`

and `multsof`

going together -- one pair for the trial division sieve as in this question, and the other for the ordered removal of each prime's multiples directly generated by counting, aka the *genuine* sieve of Eratosthenes (both would be non-postponed, of course). In Haskell,

```
-- Int -> (Int -> Bool) -- Int -> [Int]
multsof p n = (rem n p)==0 multsof p = [p*p, p*p+p..]
-- (Int -> Bool) -> ([Int] -> [Int]) -- [Int] -> ([Int] -> [Int])
remove m xs = filter (not.m) xs remove m xs = minus xs m
```

(If only he would've **postponed** picking the actual **implementation** here...)

As for the postponed code, in a *pseudocode* with "list patterns" it could've been

```
primes = [2, ...sieve primes [3..]]
sieve [p, ...ps] [...h, p*p, ...nos] =
[...h, ...sieve ps (remove (multsof p) nos)]
```

which in modern Haskell can be written with `ViewPatterns`

as

```
{-# LANGUAGE ViewPatterns #-}
primes = 2 : sieve primes [3..]
sieve (p:ps) (span (< p*p) -> (h, _p2 : nos))
= h ++ sieve ps (remove (multsof p) nos)
```

istrial division.istrial division, but on the other its a bad implementation (the author in the article above calls it an "unfaithful sieve"). Proper implementations just check a number to see if it divides by any previously computed prime up to sqrt(whatever you're checking) for a complexity around theta(n * sqrt(n) / (log n)^2). The code above actually tests an input againstallpreviously computed primes yielding a complexity around theta(n^2 / (log n)^2).