The standard improvement to apply would be to treat each `i`

-th bit as representing the number `2*i+1`

, thus representing *odds only*, cutting the size of the array in half. This would also entail, for each new prime `p`

, starting the marking-off from `p*p`

and incrementing by `2*p`

, to skip over evens. `2`

itself is a special case. See also this question with a lot of answers.

Another strategy is to switch to the *segmented sieve*. That way you only need about `pi(sqrt(m)) = 2*sqrt(m)/log(m)`

memory (`m`

being your upper limit) set aside for the initial sequence of primes with which you'd sieve smaller fixed-sized array, sequentially representing segments of numbers. If you only need primes in some narrow far away range `[m-d,m]`

, you'd skip directly to sieving that range after all the needed primes have been gathered, as shown e.g. in this answer.

Per your specifics, to get primes up to 10^9 in value, working with one contiguous array is still possible. Using a **bitarray** for *odds only*, you'd need 10^9/16 bytes, i.e. about 60 MB of memory. Easier to work by segments; we only need 3402 primes, below 31627, to sieve each segment array below 10^9.

`static`

. – caf Oct 6 '11 at 4:17