88

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:
                primes.remove(f)
    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)
6

26 Answers 26

128

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 range(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.)

17
  • 9
    another optimization, the step size of your xrange(i*i,limit,i) can be made 2*i
    – st0le
    Oct 21, 2010 at 12:20
  • 3
    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! Apr 2, 2012 at 13:26
  • 13
    @st0le: No, the step-size cannot be made 2*i. Just tried it. It yields 14 as a prime.
    – mpen
    Jul 13, 2012 at 1:33
  • 2
    @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, 2012 at 3:44
  • 4
    +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
    – Jan Vorcak
    Nov 10, 2013 at 17:57
15
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):
                multiples.append(j)

eratosthenes(100)
2
  • 6
    instead of a list, I would use a set in order to speed up the membership test Sep 4, 2016 at 13:36
  • 1
    The last output showing 'None' , how I can remove it? Sep 17, 2018 at 12:12
8

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:
            continue

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

        primes.append(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]:
            continue
        for f in xrange(i*2, limitn, i):
            not_prime[f] = True

        primes.append(i)

    return primes
1
  • 2
    See @Piet Delport answer below for an optimization: replace i*2 above with i*i. Oct 17, 2010 at 14:44
5

Much faster:

import time
def get_primes(n):
  m = n+1
  #numbers = [True for i in range(m)]
  numbers = [True] * m #EDIT: faster
  for i in range(2, int(n**0.5 + 1)):
    if numbers[i]:
      for j in range(i*i, m, i):
        numbers[j] = False
  primes = []
  for i in range(2, m):
    if numbers[i]:
      primes.append(i)
  return primes

start = time.time()
primes = get_primes(10000)
print(time.time() - start)
print(get_primes(100))
3

Using a bit of numpy, I could find all primes below 100 million in a little over 2 seconds.

There are two key features one should note

  • Cut out multiples of i only for i up to root of n
  • Setting multiples of i to False using x[2*i::i] = False is much faster than an explicit python for loop.

These two significantly speed up your code. For limits below one million, there is no perceptible running time.

import numpy as np

def primes(n):
    x = np.ones((n+1,), dtype=np.bool)
    x[0] = False
    x[1] = False
    for i in range(2, int(n**0.5)+1):
        if x[i]:
            x[2*i::i] = False

    primes = np.where(x == True)[0]
    return primes

print(len(primes(100_000_000)))
2

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


try:
    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.

4
  • 4
    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, 2014 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, 2014 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 Feb 18, 2015 at 14:05
  • 1
    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, 2015 at 4:06
2

By combining contributions from many enthusiasts (including Glenn Maynard and MrHIDEn from above comments), I came up with following piece of code in python 2:

def simpleSieve(sieveSize):
    #creating Sieve.
    sieve = [True] * (sieveSize+1)
    # 0 and 1 are not considered prime.
    sieve[0] = False
    sieve[1] = False
    for i in xrange(2,int(math.sqrt(sieveSize))+1):
        if sieve[i] == False:
            continue
        for pointer in xrange(i**2, sieveSize+1, i):
            sieve[pointer] = False
    # Sieve is left with prime numbers == True
    primes = []
    for i in xrange(sieveSize+1):
        if sieve[i] == True:
            primes.append(i)
    return primes

sieveSize = input()
primes = simpleSieve(sieveSize)

Time taken for computation on my machine for different inputs in power of 10 is:

  • 3 : 0.3 ms
  • 4 : 2.4 ms
  • 5 : 23 ms
  • 6 : 0.26 s
  • 7 : 3.1 s
  • 8 : 33 s
3
  • the comparison with True or False are unneeded more so as they are already Boolean, Sep 4, 2016 at 13:32
  • @Copperfield Thanks! It helped in increasing speed by 10-20%.
    – Ajay
    Sep 4, 2016 at 20:04
  • This sieve = [True] * (sieveSize+1) is faster than my solution, but sieve[0]/[1] and xrange(sieveSize+1) at primes[] does not improve anything. xrange(2, sieveSize+1) is good enouth. :). Also instead of for i in xrange(2,int(math.sqrt(sieveSize))+1): we can just use for i in xrange(2, int((sieveSize+1)**0.5): Good code. :)
    – MrHIDEn
    Nov 28, 2016 at 8:49
1

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.

1

My implementation:

import math
n = 100
marked = {}
for i in range(2, int(math.sqrt(n))):
    if not marked.get(i):
        for x in range(i * i, n, i):
            marked[x] = True

for i in range(2, n):
    if not marked.get(i):
        print i
1
  • I just testet your code and I see dict solution is 2 times slower than list solution.
    – MrHIDEn
    Nov 28, 2016 at 8:54
1

Here's a version that's a bit more memory-efficient (and: a proper sieve, not trial divisions). Basically, instead of keeping an array of all the numbers, and crossing out those that aren't prime, this keeps an array of counters - one for each prime it's discovered - and leap-frogging them ahead of the putative prime. That way, it uses storage proportional to the number of primes, not up to to the highest prime.

import itertools

def primes():

    class counter:
        def __init__ (this,  n): this.n, this.current,  this.isVirgin = n, n*n,  True
            # isVirgin means it's never been incremented
        def advancePast (this,  n): # return true if the counter advanced
            if this.current > n:
                if this.isVirgin: raise StopIteration # if this is virgin, then so will be all the subsequent counters.  Don't need to iterate further.
                return False
            this.current += this.n # pre: this.current == n; post: this.current > n.
            this.isVirgin = False # when it's gone, it's gone
            return True

    yield 1
    multiples = []
    for n in itertools.count(2):
        isPrime = True
        for p in (m.advancePast(n) for m in multiples):
            if p: isPrime = False
        if isPrime:
            yield n
            multiples.append (counter (n))

You'll note that primes() is a generator, so you can keep the results in a list or you can use them directly. Here's the first n primes:

import itertools

for k in itertools.islice (primes(),  n):
    print (k)

And, for completeness, here's a timer to measure the performance:

import time

def timer ():
    t,  k = time.process_time(),  10
    for p in primes():
        if p>k:
            print (time.process_time()-t,  " to ",  p,  "\n")
            k *= 10
            if k>100000: return

Just in case you're wondering, I also wrote primes() as a simple iterator (using __iter__ and __next__), and it ran at almost the same speed. Surprised me too!

3
  • interesting idea - it would improve performance if you store the prime counters in a min-heap though (inner loop would be O(log num_primes) instead of O(num_primes)) Jul 25, 2017 at 17:34
  • Why? Even if they were in a heap, we still have to account for every one.
    – Jules May
    Jul 26, 2017 at 10:26
  • If you store each prime in the heap keyed by it's next value you would only have to look at primes whose next value is the current value n. the largest primes will sink to the bottom of the heap and would need to be evaluated much more rarely than the smaller primes. Jul 26, 2017 at 19:30
1

I prefer NumPy because of speed.

import numpy as np

# Find all prime numbers using Sieve of Eratosthenes
def get_primes1(n):
    m = int(np.sqrt(n))
    is_prime = np.ones(n, dtype=bool)
    is_prime[:2] = False  # 0 and 1 are not primes

    for i in range(2, m):
        if is_prime[i] == False:
            continue
        is_prime[i*i::i] = False

    return np.nonzero(is_prime)[0]

# Find all prime numbers using brute-force.
def isprime(n):
    ''' Check if integer n is a prime '''
    n = abs(int(n))  # n is a positive integer
    if n < 2:  # 0 and 1 are not primes
        return False
    if n == 2:  # 2 is the only even prime number
        return True
    if not n & 1:  # all other even numbers are not primes
        return False
    # Range starts with 3 and only needs to go up the square root
    # of n for all odd numbers
    for x in range(3, int(n**0.5)+1, 2):
        if n % x == 0:
            return False
    return True

# To apply a function to a numpy array, one have to vectorize the function
def get_primes2(n):
    vectorized_isprime = np.vectorize(isprime)
    a = np.arange(n)
    return a[vectorized_isprime(a)]

Check the output:

n = 100
print(get_primes1(n))
print(get_primes2(n))    
    [ 2  3  5  7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97]
    [ 2  3  5  7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97]

Compare the speed of Sieve of Eratosthenes and brute-force on Jupyter Notebook. Sieve of Eratosthenes in 539 times faster than brute-force for million elements.

%timeit get_primes1(1000000)
%timeit get_primes2(1000000)
4.79 ms ± 90.3 µs per loop (mean ± std. dev. of 7 runs, 100 loops each)
2.58 s ± 31.2 ms per loop (mean ± std. dev. of 7 runs, 1 loop each)
1
  • Should your inner loop content not better be (taking previous answers and comments into account) the one line if is_prime[i]: is_prime[i*i::2*i]=False? May 6, 2019 at 8:02
1

I figured it must be possible to simply use the empty list as the terminating condition for the loop and came up with this:

limit = 100
ints = list(range(2, limit))   # Will end up empty

while len(ints) > 0:
    prime = ints[0]
    print prime
    ints.remove(prime)
    i = 2
    multiple = prime * i
    while multiple <= limit:
        if multiple in ints:
            ints.remove(multiple)
        i += 1
        multiple = prime * i
1
import math
def sieve(n):
    primes = [True]*n
    primes[0] = False
    primes[1] = False
    for i in range(2,int(math.sqrt(n))+1):
            j = i*i
            while j < n:
                    primes[j] = False
                    j = j+i
    return [x for x in range(n) if primes[x] == True]
1

i think this is shortest code for finding primes with eratosthenes method

def prime(r):
    n = range(2,r)
    while len(n)>0:
        yield n[0]
        n = [x for x in n if x not in range(n[0],r,n[0])]


print(list(prime(r)))
1
  • 1
    The performance is absolutely horrible, though. It creates a whole new list at each iteration. Oct 28, 2020 at 19:07
1

The fastest implementation I could come up with:

isprime = [True]*N
isprime[0] = isprime[1] = False
for i in range(4, N, 2):
    isprime[i] = False
for i in range(3, N, 2):
    if isprime[i]:
        for j in range(i*i, N, 2*i):
            isprime[j] = False
1

I just came up with this. It may not be the fastest, but I'm not using anything other than straight additions and comparisons. Of course, what stops you here is the recursion limit.

def nondivsby2():
    j = 1
    while True:
        j += 2
        yield j

def nondivsbyk(k, nondivs):
    j = 0
    for i in nondivs:
        while j < i:
            j += k
        if j > i:
            yield i

def primes():
    nd = nondivsby2()
    while True:
        p = next(nd)
        nd = nondivsbyk(p, nd)
        yield p

def main():
    for p in primes():
        print(p)
6
  • very nice formulation, clean and clear and succinct! I'll bookmark it. of course, to produce the 100th prime with it, the nd chain will be 99 levels deep. but only 10 are truly needed. and it becomes worse and worse the farther we go along the primes list. can you find a way to deal with this problem? :)
    – Will Ness
    Oct 6, 2020 at 13:30
  • also, I don't see any recursion here really, so there shouldn't be any limit to it here either. (of course I don't know Python almost at all)
    – Will Ness
    Oct 6, 2020 at 13:33
  • I was surprised at first, when I got the RecursionError: maximum recursion depth exceeded exception. But then I thought it makes some sense. Because we can think of the generators as object with a __next__ function. So each nondivsbyk generator is an object of the same class (only different initialization). SUppose we call that class_nondivsbyk, so when one calls the other its actually class_nondivsbyk.__next__ calling another class_nondivsbyk.__next__ on another object.
    – tamir
    Oct 8, 2020 at 6:30
  • About the 100th prime requiring only the first 10 primes, so first I can say that (as long as I don't want to give an upper limit) we need to 'collect' the primes on the way, so creating these generators seems necessary. I really don't know at the moment if I could 'skip' those irrelevant ones for the computation. Because now, I let each check if it's a divider, but if I put them aside, I would need something else to 'trigger' them when the numbers increase and I don't know how to integrate that to the recursion. I also made a "flat" version, I can take a look at that there. Thanks @WillNess
    – tamir
    Oct 8, 2020 at 6:38
  • the two nds after the assignment nd = nondivsbyk(p, nd) are supposed to be two different objects. i.e., nd is a variable referring to a object, first; then new generator object is constructed by the function call, and assigned to the same variable (which forgets its old value). but inside, the new generator object refers to the older - different - object. but as I said, I don't know Python. about the 10 primes vs the 100 -- here's a hint: hopefully each call to primes() creates a separate, new, generator object. (or what's the proper terminology?)
    – Will Ness
    Oct 8, 2020 at 18:07
1

I made a one liner version of the Sieve of Eratosthenes

sieve = lambda j: [print(x) for x in filter(lambda n: 0 not in map(lambda i: n % i, range(2, n)) and (n!=1)&(n!=0), range(j + 1))]

In terms of performance, I am pretty sure this isn't the fastest thing by any means, and in terms of readability / following PEP8, this is pretty terrible, but it's more the novelty of the length than anything.

EDIT: Note that this simply prints the sieve & does not return (if you attempt to print it you will get a list of Nones, if you want to return, change the print(x) in the list comprehension to just "x".

1

Empirical Analysis and Visualization of Various Approaches to the Sieve of Eratosthenes

I discovered this algorithm at the end of the 10th chapter (Maps, Hash Tables, and Skip Lists) of "Data Structures & Algorithms in Python". I ended up writing three versions:

  • A naive implementation with a nasty cubic runtime (amongst many other issues, later resolved).
  • A suboptimal version after some thorough research, but I still wanted to get rid of the square-based multiples.
  • A fast and efficient version on par with the selected answer performance-wise, but with additive multiples (more intuitive for those less-mathematically inclined).

Naive SOE

Out of all the issues, the additional space usage in the return statement takes the cake as the worst.

def naive_sieve(m: int):
    BA = [True] * m
    for i, k in zip(range(2, m + 1), range(len(BA))):
        if BA[k] is False: continue
        for j in range(2, i):
            if i % j == 0:
                BA[k] = False
                f = k + j
                while f < len(BA):
                    BA[f] = False
                    f += j
                break
    return [i for i,j in zip(range(2, m + 1), BA) if j is True]

Suboptimal SOE

A drastic improvement, but still lacking on space usage, and an unfriendly inner-loop interval progression.

def suboptimal_sieve(m: int):
    BA = [True] * m
    for i, k in zip(range(2, m + 1), range(2, len(BA))):
        if BA[k] is False: continue
        for j in range(i**2, m, i):
            BA[j] = False
    return [i for i,j in zip(range(2, m + 1), BA[2:]) if j is True]

Fast SOE

Easy to understand (note the usage of fractional exponent to be explicitly consistent with the mathematical definition of roots) and just as performant as @Pi Delport's answer.

def fast_sieve(m: int):
    BA = [True] * m
    rtm = int(m**(1/2)) + 1
    for i in range(2, len(BA)):
        if BA[i]:
            yield i
            if i < rtm:
                f = i
                while f < len(BA):
                    BA[f] = False
                    f += i

Empirical Analysis

To compare all three implementations, along with the selected answer from @Pi Delport, I ran it through 45 iterations from primes in range 100, until primes in range 4500, at intervals of 100 (that's the sweet spot for the visualization, because despite the consistency of the shape of the graphs, the growth of the naive implementation dwarves the visibility of the other three). You can tweak the visualization code on the GitHub gist, but here's one sample output:

Empirical Analysis and Visualization of Various Approaches to the Sieve of Eratosthenes

0

not sure if my code is efficeient, anyone care to comment?

from math import isqrt

def isPrime(n):
    if n >= 2: # cheating the 2, is 2 even prime?
        for i in range(3, int(n / 2 + 1),2): # dont waste time with even numbers
            if n % i == 0:
                return False
    return True

def primesTo(n): 
    x = [2] if n >= 2 else [] # cheat the only even prime
    if n >= 2:
        for i in range(3, n + 1,2): # dont waste time with even numbers
            if isPrime(i):
                x.append(i)  
    return x

def primes2(n): # trying to do this using set methods and the "Sieve of Eratosthenes"
    base = {2} # again cheating the 2
    base.update(set(range(3, n + 1, 2))) # build the base of odd numbers
    for i in range(3, isqrt(n) + 1, 2): # apply the sieve
        base.difference_update(set(range(2 * i, n + 1 , i)))
    return list(base)

print(primesTo(10000)) # 2 different methods for comparison
print(primes2(10000))
0
0

Probably the quickest way to have primary numbers is the following:

import sympy
list(sympy.primerange(lower, upper+1))

In case you don't need to store them, just use the code above without conversion to the list. sympy.primerange is a generator, so it does not consume memory.

1
  • Please explain in the body of your answer why this is necessary and what improvement it brings to make it look a meaningful answer.
    – dmitryro
    Nov 28, 2020 at 14:52
0

Using recursion and walrus operator:

def prime_factors(n):
    for i in range(2, int(n ** 0.5) + 1):
        if (q_r := divmod(n, i))[1] == 0:
            return [i] + factor_list(q_r[0])
    return [n]
0

Basic sieve

with numpy is amazing fast. May be the fastest implementation

# record: sieve 1_000_000_000 in 6.9s (core i7 - 2.6Ghz)
def sieve_22max_naive(bound):
    sieve = np.ones(bound, dtype=bool)  # default all prime
    sieve[:2] = False  # 0, 1 is not prime

    sqrt_bound = math.ceil(math.sqrt(bound))

    for i in range(2, sqrt_bound):
        if sieve[i]:
            inc = i if i == 2 else 2 * i
            sieve[i * i:bound:inc] = False

    return np.arange(bound)[sieve]


if __name__ == '__main__':
    start = time.time()
    prime_list = sieve_22max_naive(1_000_000_000)
    print(f'Count: {len(prime_list):,}\n'
          f'Greatest: {prime_list[-1]:,}\n'
          f'Elapsed: %.3f' % (time.time() - start))

Segment sieve (use less memory)

# find prime in range [from..N), base on primes in range [2..from)
def sieve_era_part(primes, nfrom, n):
    sieve_part = np.ones(n - nfrom, dtype=bool)  # default all prime

    limit = math.ceil(math.sqrt(n))
    # [2,3,5,7,11...p] can find primes < (p+2)^2
    if primes[-1] < limit - 2:
        print(f'Not enough base primes to find up to {n:,}')
        return

    for p in primes:
        if p >= limit: break

        mul = p * p
        inc = p * (2 if p > 2 else 1)
        if mul < nfrom:
            mul = math.ceil(nfrom / p) * p
            (mul := mul + p) if p > 2 and (mul & 1) == 0 else ...  # odd, not even

        sieve_part[mul - nfrom::inc] = False

    return np.arange(nfrom, n)[sieve_part]
    # return np.where(sieve_part)[0] + nfrom
    # return [i + nfrom for i, is_p in enumerate(sieve_part) if is_p]
    # return [i for i in range(max(nfrom, 2), n) if sieve_part[i - nfrom]]


# find nth prime number, use less memory,
# extend bound to SEG_SIZE each loop
# record: 50_847_534 nth prime in 6.78s, core i7 - 9850H 2.6GHhz
def nth_prime(n):
    # find prime up to bound
    bound = 500_000
    primes = sieve_22max_naive(bound)

    SEG_SIZE = int(50e6)

    while len(primes) < n:
        # sieve for next segment
        new_primes = sieve_era_part(primes, bound, bound + SEG_SIZE)
        # extend primes
        bound += SEG_SIZE
        primes = np.append(primes, new_primes)

    return primes[n - 1]


if __name__ == '__main__':
    start = time.time()
    prime = nth_prime(50_847_534)
    print(f'{prime:,} Time %.6f' % (time.time() - start))
0

here is my solution, the same as Wikipedia

import math


def sieve_of_eratosthenes(n):
    a = [i for i in range(2, n+1)]
    clone_a = a[:]
    b = [i for i in range(2, int(math.sqrt(n))+1)]
    for i in b:
        if i in a:
            c = [pow(i, 2)+(j*i) for j in range(0, n+1)]
            for j in c:
                if j in clone_a:
                    clone_a.remove(j)
    return clone_a


if __name__ == '__main__':
    print(sieve_of_eratosthenes(23))
0

Thanks for interesting question!

Right now I wrote from scratch two versions of classical Sieve of Eratosthenes.

One is single-core (CPU core), another one is multi-core (using all CPU cores).

Main speedup of both (single and multi core) versions was due to using Numpy, official Python package. Install in once through command python -m pip install numpy. Another great speedup of multi-core version was due to usage of all CPU cores, which gives almost speedup N times for N cores, compared to single core version.

Right now I have only two-core laptop. My program produced following timings:

Computing primes less than 8M
Number of CPU cores 2
Original time 72.57 sec
Simple time 5.694 sec
Simple boost (compared to original) 12.745x
Multi core time 2.642 sec
Multi core boost (compared to simple) 2.155x

Original above means your code from your question's body, the second one that you optimized already. Simple is my single core version. Multi is my multi core version.

As you see above computing primes less than 8 Million took 72 seconds on your original code, my single core version took 5.7 seconds, which is 12.7x times faster than your code, and my 2-core version took 2.6 seconds, which is 2.1x times faster than my single core and 27x times faster than your original code.

In other words I got 27x times speedup in my multi-core code compared to your code, really a lot! And this is only on 2-core laptop. If you have 8 cores or more then you'll get much bigger speedup. But remember that real speedup on multi core machine will be only for quite big prime number limit, try 64 Million limit or bigger, for this modify line primes_limit_M = 8 in my code to set amount of Millions.

Just to dwell into details. My single core version is almost like your code, but uses Numpy which makes any array operations very fast, instead of using pure pythonic loops with lists.

Multi core version also uses Numpy, but splits array with sieved range into as many pieces as there are CPU cores on your machine, each piece of array having equal size. Then every CPU core sets boolean flags in its own part of array. This technique gives speedup only till you hit speed limit of your memory (RAM), so after some point with growth of amount of CPU cores you don't get extra speedup.

By default I use all CPU cores in multi core version, but you may experiment by setting less cores than you have on your machine, this may give even better speedup, because it is not guaranteed that most of cores will give exactly fastest result. Tweak amount of cores through changing line cpu_cores = mp.cpu_count() to something like cpu_cores = 3.

Try it online!

def SieveOfEratosthenes_Original(end):
    import numpy as np
    limit = end - 1
    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 np.array([i for i in primes if primes[i]==True], dtype = np.uint32)

def SieveOfEratosthenes_Simple(end):
    # https://en.wikipedia.org/wiki/Sieve_of_Eratosthenes
    import numpy as np
    composites = np.zeros((end,), dtype = np.uint8)
    composites[:2] = 1
    for p, c in enumerate(composites):
        if c:
            continue
        composites[p * p :: p] = 1
    return np.array([p for p, c in enumerate(composites) if not c],
        dtype = np.uint32)

def SieveOfEratosthenes_Task(small_primes, begin, end):
    import numpy as np
    composites = np.zeros((end - begin,), dtype = np.uint8)
    offsets = np.full((len(small_primes),), begin, dtype = np.uint32)
    offsets = small_primes - offsets % small_primes
    offsets[offsets == small_primes] = 0
    for off, p in zip(offsets, small_primes):
        composites[off :: p] = 1
    return np.array([begin + i for i, c in enumerate(composites) if not c],
        dtype = np.uint32)

def SieveOfEratosthenes_MultiCore(end, *, nthreads = None):
    import math, multiprocessing as mp, numpy as np
    end_small = math.ceil(math.sqrt(end)) + 1
    small_primes = SieveOfEratosthenes_Simple(end_small)
    if nthreads is None:
        nthreads = mp.cpu_count()
    block = (end - end_small + nthreads - 1) // nthreads
    with mp.Pool(nthreads) as pool:
        return np.concatenate([small_primes] + pool.starmap(SieveOfEratosthenes_Task, [
            (small_primes, min(end_small + ithr * block, end), min(end_small + (ithr + 1) * block, end))
            for ithr in range(nthreads)]))

def Test():
    import time, numpy as np, multiprocessing as mp
    primes_limit_M = 8
    cpu_cores = mp.cpu_count()
    end = primes_limit_M * 2 ** 20
    print(f'Computing primes less than {primes_limit_M}M')
    print('Number of CPU cores', cpu_cores, flush = True)
    
    tim_orig = time.time()
    res_orig = SieveOfEratosthenes_Original(end)
    tim_orig = time.time() - tim_orig
    print('Original time', round(tim_orig, 3), 'sec', flush = True)
    
    tim_simple = time.time()
    res_simple = SieveOfEratosthenes_Simple(end)
    tim_simple = time.time() - tim_simple
    print('Simple time', round(tim_simple, 3), 'sec', flush = True)
    
    assert np.all(res_orig == res_simple)
    print(f'Simple boost (compared to original) {tim_orig / tim_simple:.3f}x')
    
    tim_multi = time.time()
    res_multi = SieveOfEratosthenes_MultiCore(end, nthreads = cpu_cores)
    tim_multi = time.time() - tim_multi
    print('Multi core time', round(tim_multi, 3), 'sec', flush = True)
    
    assert np.all(res_simple == res_multi)
    print(f'Multi core boost (compared to simple) {tim_simple / tim_multi:.3f}x')
    
if __name__ == '__main__':
    Test()
0
import math

def atkin_sieve(limit):
   primes = [False] * (limit + 1)
   square_limit = int(math.sqrt(limit))

# Отметить все числа, делящиеся нацело на 2, 3 или 5
for i in range(1, square_limit + 1):
    for j in range(1, square_limit + 1):
        num = 4 * i**2 + j**2
        if num <= limit and (num % 12 == 1 or num % 12 == 5):
            primes[num] = not primes[num]

        num = 3 * i**2 + j**2
        if num <= limit and num % 12 == 7:
            primes[num] = not primes[num]

        num = 3 * i**2 - j**2
        if i > j and num <= limit and num % 12 == 11:
            primes[num] = not primes[num]

# Удалить кратные квадратам простых чисел
for i in range(5, square_limit):
    if primes[i]:
        for j in range(i**2, limit + 1, i**2):
            primes[j] = False

# Вернуть список простых чисел
return [2, 3] + [i for i in range(5, limit) if primes[i]]

# Пример использования
print(atkin_sieve(100))
0

If your looking for even faster, you can use numba and cuda as well if you have a Nvidia processor. Feel free to optimize as needed. We use 2**24 which is ~16 million numbers at 239 ms on an Nvidia 3070.


from numba import cuda
import numpy as np

@cuda.jit
def findprimes(primes, sqrt_limit):
    index = cuda.grid(1)
    if index >= primes.size or index < 2:
        return
    if index <= sqrt_limit:
        if primes[index]:
            for multiple in range(index*index, primes.size, index):
                primes[multiple] = False

def fast_sieve_gpu(m):
    primes = np.ones(m, dtype=bool)
    primes[0] = primes[1] = False
    sqrt_limit = int(np.sqrt(m))
    d_primes = cuda.to_device(primes)
    threads_per_block = 128
    blocks_per_grid = (m + threads_per_block - 1) // threads_per_block
    findprimes[blocks_per_grid, threads_per_block](d_primes, sqrt_limit)
    primes = d_primes.copy_to_host()
    prime_numbers = np.nonzero(primes)[0]
    return prime_numbers

m = 2**24 # 16777216
prime_numbers = fast_sieve_gpu(m)
print(prime_numbers)
%timeit fast_sieve_gpu(m)

# Output (this is 2**24 which is 16x of 2**20) : 
# [       2        3        5 ... 16777183 16777199 16777213]
# 239 ms ± 2.66 ms per loop (mean ± std. dev. of 7 runs, 1 loop each)

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

Not the answer you're looking for? Browse other questions tagged or ask your own question.