At the very least your code should be

```
primes = [2,3,5,7,11,13]
genPrimes primes max = go primes (length primes) 1 (last primes + 2)
where
go prs len d t
| len >= max = prs
| (prs !! d) > (floor . sqrt . fromIntegral) t
= go (prs++[t]) (len+1) 1 (t + 2)
| t `rem` (prs !! d) == 0 = go prs len 1 (t + 2)
| t `rem` (prs !! d) /= 0 = go prs len (d + 1) t
test n = print $ genPrimes primes n
main = test 20
```

Then you reorganize it thus (abstracting away the tests performed for each candidate number, as the `noDivs`

function):

```
genPrimes primes max = go primes (length primes) (last primes + 2)
where
go prs len t
| len >= max = prs
| noDivs (floor . sqrt . fromIntegral $ t) t prs
= go (prs++[t]) (len+1) (t + 2)
| otherwise = go prs len (t + 2)
noDivs lim t (p:rs)
| p > lim = True
| t `rem` p == 0 = False
| otherwise = noDivs lim t rs
```

then you rewrite `noDivs`

as

```
noDivs lim t = foldr (\p r -> p > lim || rem t p /= 0 && r) False
```

then you notice that `go`

just filters numbers through such that pass the `noDivs`

test:

```
genPrimes primes max = take max (primes ++ filter theTest [t, t+2..])
where
t = last primes + 2
theTest t = noDivs (floor . sqrt . fromIntegral $ t) t
```

but this doesn't work yet, because `theTest`

needs to pass `primes`

(whole new primes as they are being found) to `noDivs`

, but we *are building* this `whole_primes`

list (as `take max (primes ++ ...)`

), so is there a vicious circle? No, because we only test up to the square root of a number:

```
genPrimes primes max = take max wholePrimes
where
wholePrimes = primes ++ filter theTest [t, t+2..]
t = last primes + 2
theTest t = noDivs (floor . sqrt . fromIntegral $ t) t wholePrimes
```

This is working now. But finally, there's nothing special in `genPrimes`

now, it's just a glorified call to `take`

, and initial `primes`

list can actually be shrunk, so we get (changing the arguments arrangement for `noDivs`

a little, to make its interface more general):

```
primes = 2 : 3 : filter (noDivs $ tail primes) [5, 7..]
noDivs factors t = -- return True if the supplied list of factors is too short
let lim = (floor . sqrt . fromIntegral $ t)
in foldr (\p r-> p > lim || rem t p /= 0 && r) True factors
-- all ((/=0).rem t) $ takeWhile (<= lim) factors
-- all ((/=0).rem t) $ takeWhile ((<= t).(^2)) factors
-- and [rem t f /= 0 | f <- takeWhile ((<= t).(^2)) factors]
```

The global `primes`

list is indefinitely defined now (i.e. "infinite"). Next step is to realize that between the consecutive squares of primes the length of the list of factors to test by will be the same, incrementing by 1 for each new segment. Then, that having all the factors upfront as the prefix (of known length) of the global `primes`

list, we can directly *generate* their multiples (thus each being generated just from its prime factors), instead of testing each number whether it is a multiple of any one of the prime factors below its square root, in sequence.