After getting through some of the SO posts, i found Sieve of Eratosthenes is the best & fastest way of generating prime numbers.

I want to generate the prime numbers between two numbers, say a and b.

AFAIK, in Sieve's method, the space complexity is O( b ).

PS: I wrote Big-O and not Theta, because i don't know whether the space requirement can be reduced.

Can we reduce the space complexity in Sieve of Eratosthenes ?

  • It's the best method for certain a and b. For numbers large enough for b bytes or bits to be too much space, there are other methods. But despite O(b) sounding scary, it can take you quite far -- one GB of memory should enable bs up to 8.5 billion (more than you can enumerate in 32 bit!) if you use a single bit per number. – user395760 Sep 14 '12 at 19:11
  • Does there exist a way where i need a space equal to difference between a and b? Say, we know the range between a and b. – Green goblin Sep 14 '12 at 19:16
  • No, because you have to know all of the primes from 0 to a. Otherwise you can't run the sieve. – Jim Mischel Sep 14 '12 at 19:24
  • 4
    I think you only need the primes from 2 to sqrt(b), because if a number is composite, then at least one of the factors must be less than (or equal to) the sqrt. (Search for segmented sieve for more information) – Peter de Rivaz Sep 14 '12 at 19:33
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    @PeterdeRivaz, I think your approach is about testing one number for primality, which is different from applying the sieve algorithm to find all primes in a given range. The Wikipedia page distinguishes Trial Division as a separate technique. So it's not clear how this will help with the original question. – Hew Wolff Sep 14 '12 at 20:02

If you have enough space to store all the primes up to sqrt(b) then you can sieve for the primes in the range a to b using additional space O(b-a).

In Python this might look like:

def primesieve(ps,start,n):
  """Sieve the interval [start,start+n) for primes.

     Returns a list P of length n.  
     P[x]==1 if the number start+x is prime.  
     Relies on being given a list of primes in ps from 2 up to sqrt(start+n)."""
  for p in ps:
    for k in range((-start)%p,n,p):
      if k+start<=p: continue
  return P

You could easily make this take half the space by only sieving the odd numbers.


There are two basic choices here: sieve the range [a..b] by primes below sqrt(b) (the "offset" sieve of Eratosthenes), or by odd numbers. That's right; just eliminate the multiples of each odd as you would of each prime. Sieve the range in one chunk, or in several "segments" if the range is too wide (but efficiency can deteriorate if the chunks are too narrow).

In Haskell executable pseudocode,

primesRange_by_Odds a b = foldl (\r x-> r `minus` [q x, q x+2*x..b])
                                [3,5..floor(sqrt(fromIntegral b))]
    o   = 1 + 2*div a 2                        -- odd start of range
    q x = x*x - 2*x*min 0 (div (x*x-o) (2*x))  -- 1st odd multiple of x >= x*x in range

Sieving by odds will have the additional space complexity of O(1) (on top of the output / range). That is because we can enumerate the odds just by iteratively adding 2 — unlike primes of sieve of Eratosthenes, below sqrt(b), for which we have to reserve additional space of O(pi(sqrt(b))) = ~ 2*sqrt(b)/log(b) (where pi() is a prime-counting function).


Sorenson Sieve might be worth a peek if space complexity is really an issue. Got the reference from the wikipedia page you shared.

  • +1 though Sorensen is not a variant of Eratosthenes, but a totally different sieve, with worse time and better space complexity. BTW sieving by odds has probably even worse time cpxty, but it is O(1) additional space (besides the output). :) I've added an answer about it too. :) – Will Ness Sep 19 '12 at 15:27

Search for "segmented sieve of Eratosthenes" at your favorite search engine. If you don't want to go searching, I have an implementation at my blog.

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