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Just to clarify, this is not a homework problem :)

I wanted to find primes for a math application I am building & came across Sieve of Eratosthenes approach.

I have written an implementation of it in Python. But it's terribly slow. For say, if I want to find all primes less than 2 million. It takes > 20 mins. (I stopped it at this point). How can I speed this up?

def primes_sieve(limit):
    limitn = limit+1
    primes = range(2, limitn)

    for i in primes:
        factors = range(i, limitn, i)
        for f in factors[1:]:
            if f in primes:
    return primes

print primes_sieve(2000)

UPDATE: I ended up doing profiling on this code & found that quite a lot of time was spent on removing an element from the list. Quite understandable considering it has to traverse the entire list (worst-case) to find the element & then remove it and then readjust the list (maybe some copy goes on?). Anyway, I chucked out list for dictionary. My new implementation -

def primes_sieve1(limit):
    limitn = limit+1
    primes = dict()
    for i in range(2, limitn): primes[i] = True

    for i in primes:
        factors = range(i,limitn, i)
        for f in factors[1:]:
            primes[f] = False
    return [i for i in primes if primes[i]==True]

print primes_sieve1(2000000)
share|improve this question
There's a similar question here stackoverflow.com/questions/2897297 that you might find useful. –  Scott Griffiths Oct 15 '10 at 8:18
Check that answer. –  tzot Oct 15 '10 at 19:57
@Srikar: Rather than iterating upto limit, you can just iterate upto the square root of limit, since any composite number in your dictionary will have one factor less than the square root of limit. –  Bolt64 Aug 17 '13 at 1:36

5 Answers 5

up vote 38 down vote accepted

You're not quite implementing the correct algorithm:

In your first example, primes_sieve doesn't maintain a list of primality flags to strike/unset (as in the algorithm), but instead resizes a list of integers continuously, which is very expensive: removing an item from a list requires shifting all subsequent items down by one.

In the second example, primes_sieve1 maintains a dictionary of primality flags, which is a step in the right direction, but it iterates over the dictionary in undefined order, and redundantly strikes out factors of factors (instead of only factors of primes, as in the algorithm). You could fix this by sorting the keys, and skipping non-primes (which already makes it an order of magnitude faster), but it's still much more efficient to just use a list directly.

The correct algorithm (with a list instead of a dictionary) looks something like:

def primes_sieve2(limit):
    a = [True] * limit                          # Initialize the primality list
    a[0] = a[1] = False

    for (i, isprime) in enumerate(a):
        if isprime:
            yield i
            for n in xrange(i*i, limit, i):     # Mark factors non-prime
                a[n] = False

(Note that this also includes the algorithmic optimization of starting the non-prime marking at the prime's square (i*i) instead of its double.)

share|improve this answer
another optimization, the step size of your xrange(i*i,limit,i) can be made 2*i –  st0le Oct 21 '10 at 12:20
I like your succinct implementation of the Sieve of Eratosthenes. : ) However, I'm having a OverflowError: Python int too large to convert to C long. I changed xrange(i*i, limit, i) to xrange(i, limit, i). Thanks for sharing this code snippet! –  Anne Lagang Apr 2 '12 at 13:26
@st0le: No, the step-size cannot be made 2*i. Just tried it. It yields 14 as a prime. –  Mark Jul 13 '12 at 1:33
@Mark, I'm sorry I didn't really explain it in full. Eliminate all even numbers by doing an iteration with i=2 with steps of i but for the rest you can use 2*i. In fact, in my implementation I use half the booleans since I don't store even numbers and instead use a simple mod 2. You can find my Java implementation here which uses even less (1/8th) the memory. HERE –  st0le Jul 13 '12 at 3:44
+1, just a small detail, if you use [False] * 2 + [True] * (limit-2) in the initialisation, you can avoid IndexError on passing number < 2 as an argument –  Ján Vorčák Nov 10 '13 at 17:57

Removing from the beginning of an array (list) requires moving all of the items after it down. That means that removing every element from a list in this way starting from the front is an O(n^2) operation.

You can do this much more efficiently with sets:

def primes_sieve(limit):
    limitn = limit+1
    not_prime = set()
    primes = []

    for i in range(2, limitn):
        if i in not_prime:

        for f in range(i*2, limitn, i):


    return primes

print primes_sieve(1000000)

... or alternatively, avoid having to rearrange the list:

def primes_sieve(limit):
    limitn = limit+1
    not_prime = [False] * limitn
    primes = []

    for i in range(2, limitn):
        if not_prime[i]:
        for f in xrange(i*2, limitn, i):
            not_prime[f] = True


    return primes
share|improve this answer
See @Piet Delport answer below for an optimization: replace i*2 above with i*i. –  GregS Oct 17 '10 at 14:44

I realise this isn't really answering the question of how to generate primes quickly, but perhaps some will find this alternative interesting: because python provides lazy evaluation via generators, eratosthenes' sieve can be implemented exactly as stated:

def intsfrom(n):
    while True:
        yield n
        n += 1

def sieve(ilist):
    p = next(ilist)
    yield p
    for q in sieve(n for n in ilist if n%p != 0):
        yield q

    for p in sieve(intsfrom(2)):
        print p,

    print ''
except RuntimeError as e:
    print e

The try block is there because the algorithm runs until it blows the stack and without the try block the backtrace is displayed pushing the actual output you want to see off screen.

share|improve this answer
no, it's not the sieve of Eratosthenes, but rather a sieve of trial division. Even that is very suboptimal, because it's not postponed: any candidate number need only be tested by primes not above its square root. Implementing this along the lines of the pseudocode at the bottom of the linked above answer (the latter one) will give your code immense speedup (even before you switch to the proper sieve) and/because it'll greatly minimize the stack usage - so you mightn't need your try block after all. –  Will Ness Jul 21 '14 at 14:11
... see also: more discussion about the "sqrt" issue and its effects, an actual Python code for a postponed trial division, and some related Scala. --- And kudos to you, if you came up with that code on your own! :) –  Will Ness Jul 21 '14 at 14:15
Interesting, although I'm not yet understanding why what I put is different from the sieve of Eratosthenes. I thought it was described as placing all the intergers from 2 in a line, then repeadly take the first in the line as a prime and strike out all multiples. the "n for n in ilist if n%p != 0" bit was supposed to represent striking out the multiples. Admittedly highly suboptimal though, definitely –  Paul Gardiner Feb 18 at 14:05
n for n in ilist if n%p != 0 tests each number n in a range for divisibility by p; but range(p*p, N, p) generates the multiples directly, all by itself, without testing all these numbers. –  Will Ness Feb 25 at 4:06
def eratosthenes(n):
    multiples = []
    for i in range(2, n+1):
        if i not in multiples:
            print (i)
            for j in range(i*i, n+1, i):

share|improve this answer

A simple speed hack: when you define the variable "primes," set the step to 2 to skip all even numbers automatically, and set the starting point to 1.

Then you can further optimize by instead of for i in primes, use for i in primes[:round(len(primes) ** 0.5)]. That will dramatically increase performance. In addition, you can eliminate numbers ending with 5 to further increase speed.

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