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.

9 bits is about 120 MB, which isn't too much on today's personal computers. Actually, it seems that even 232 (the whole range of unsigned 32 bit integers) fits into 512 MB. Sure, that's a lot for a single application, but memory is plenty these days. – delnan Oct 5 '11 at 20:179 bit is 125 * 106 byte (divide by 8) is roughly 122 * 10**3 kilobyte (divide by 1024) is roughly 119 megabyte (divide by 1024). Please explain how you arrive at 1GB? – delnan Oct 5 '11 at 20:34`static`

. – caf Oct 6 '11 at 4:17