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The Sieve of Eratosthenes is a reasonably fast method of generating primes up to a limit k as follows:

  1. Begin with the set p = (2, 3, 4, ..., k) and i = 2.
  2. Starting from i^2, remove all multiples of i from p.
  3. Repeat for the next smallest i in p, until i >= sqrt(k).

My current implementation looks like this (with the obvious optimisation of pre-filtering all the even numbers):

# Compute all prime numbers less than k using the Sieve of Eratosthenes
def sieve(k):
    s = set(range(3, k, 2))

    for i in range(3, int(sqrt(k)), 2):
        if i in s:
            for j in range(i ** 2, k, i * 2):

    return sorted(s)

EDIT: Here is the equivalent list based code:

def sieve_list(k):
    s = [True] * k
    s[0] = s[1] = False
    for i in range(4, k, 2):
        s[i] = False

    for i in range(3, int(sqrt(k)) + 2, 2):
        if s[i]:            
            for j in range(i ** 2, k, i * 2):
                s[j] = False

    return [2] + [ i for i in range(3, k, 2) if s[i] ]

This works, but is not entirely correct. The lines:

for i in range(3, int(sqrt(k)), 2):
    if i in s:

Find the next smallest element of s by testing set membership for every odd number. Ideally the implementation should actually be:

while i < sqrt(k):
    i = next smallest element in s

However, since set is unordered, I do not know how (or even if it is possible) to get the next smallest element in a more efficient way. I have considered using a list with True/False flags for primes, but you still have to walk the list looking for the next True element. You can't just actually remove elements from the list either, as this makes efficiently removing composite numbers in step 2 impossible.

Is there a way to find the next smallest element more efficiently? If not, is there some other data structure that allows O(1) removal by value and an efficient way to find the next smallest element?

share|improve this question
p.s. if you're using Python 2.x, use xrange to avoid creating a list every time. – nneonneo Sep 16 '12 at 17:50
If you analyze your algorithm, it's actually pretty efficient. You only do O(n) if i in s calls. The rest of your algorithm is at least O(n) because you have to construct the list and delete O(n) elements from it. Thus, the "inefficient" way you find the minimum doesn't affect the order of your algorithm's running time. – nneonneo Sep 16 '12 at 18:15
O(sqrt(n)) calls actually, so now that I think about it it probably costs almost nothing compared to the rest of the process. Also I realise there is nothing I can do to improve the asymptotic complexity, I was just looking for some small % improvement. – verdesmarald Sep 16 '12 at 18:42
up vote 3 down vote accepted

Sets are unordered because they are internally implemented as a hashset. There's no efficient way to find the minimum element in such a data structure; min(s) would be the most Pythonic way to do so (but it is O(n)).

You can use a collections.deque along with your set. Use the deque to store the list of elements in sorted order. Every time you need to get the minimum, pop elements off the deque until you find one that is in your set. This has amortized O(1) cost across your entire input array (since you only have to pop n times).

I should also point out that there can be no data structure that has O(n) creation from a list (or O(1) insertion), O(1) removal by value and O(1) minimum-finding; such a data structure could be used to trivially implement O(n) general sorting, which is (information-theoretic) impossible. The hashset gets pretty close, but has to sacrifice efficient minimum-finding.

share|improve this answer
Good point about it being impossible, when you put it in terms of sorting it is so obvious! I'm not sure how a deque buys me anything over just walking through the odd numbers and doing if i in s, though. Isn't hashset membership effectively O(1) anyway? – verdesmarald Sep 16 '12 at 18:38
Yes, it is. In your case, I think you are already as efficient as you reasonably need to be. A deque would help if you were removing elements at random. – nneonneo Sep 16 '12 at 18:40
Thanks. Interestingly the list version is faster, even if you just return the set without sorting it (4sec vs 7.5sec for k = 30M). I expected the set to be faster. – verdesmarald Sep 16 '12 at 19:11
set.discard is slower than list[i] = False, and that's the hot loop in your code (because set.discard requires hashing, bucket lookup, possible set resize, etc., and list[i] is just a list indexing operation). Similarly, if i in set is slower than if list[i]. – nneonneo Sep 16 '12 at 19:20

Instead of a set you can use a list. Initialize the list with None for unmarked. You can use the element index as the number.

  1. Initialize the list
  2. Start with p = 2
  3. Mark all multiples of p in the list with 'M' for marked
  4. Find the next unmarked element in the list and make that the new p. If there is none, you are done.

If you need to find the next unmarked index, you can simply look at the elements that come after index p and are equal to None.

share|improve this answer
I already mentioned using a list in the question. The issue with a list is that it is indexed by position not value, so you cannot efficiently remove non-primes in step 2. – verdesmarald Sep 16 '12 at 16:06
My apologies, I did not read closely enough. I think you want to avoid marking non-primes several times. Do you think removing the non-primes from the set will make the algorithm faster? – Hans Then Sep 16 '12 at 16:14
I initially implemented this using list (see edit) but ran into the same problem--you still have to iterate every odd number to find the next prime. I can't see any way around this using list or set. – verdesmarald Sep 16 '12 at 17:07

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