# Fastest way to list all primes below N in python

This is the best algorithm I could come up with after struggling with a couple of Project Euler's questions.

``````def get_primes(n):
numbers = set(range(n, 1, -1))
primes = []
while numbers:
p = numbers.pop()
primes.append(p)
numbers.difference_update(set(range(p*2, n+1, p)))
return primes

>>> timeit.Timer(stmt='get_primes.get_primes(1000000)', setup='import   get_primes').timeit(1)
1.1499958793645562
``````

Can it be made even faster?

EDIT: This code has a flaw: Since `numbers` is an unordered set, there is no guarantee that `numbers.pop()` will remove the lowest number from the set. Nevertheless, it works (at least for me) for some input numbers:

``````>>> sum(get_primes(2000000))
142913828922L
#That's the correct sum of all numbers below 2 million
>>> 529 in get_primes(1000)
False
>>> 529 in get_primes(530)
True
``````

EDIT: The rank so far (pure python, no external sources, all primes below 1 million):

1. Sundaram's Sieve implementation by myself: 327ms
2. Daniel's Sieve: 435ms
3. Alex's recipe from Cookbok: 710ms

-
Code sniplet in question is much faster if numbers declared like numbers = set(range(n, 2, -2)). But can't beat sundaram3. Thanks for the question. –  Shekhar Jan 23 '10 at 14:51
It'd be nice if there could be Python 3 versions of the functions in the answers. –  Michael Foukarakis Sep 10 '11 at 15:19
Surely there's a library to do this so we don't have to roll our own> xkcd promised Python is as simple as `import antigravity`. Isn't there anything like `require 'prime'; Prime.take(10)` (Ruby)? –  Colonel Panic Nov 10 '12 at 17:09
Note that you do not need to pass in a set as your argument to `difference_update`. You can simply do `numbers.difference_update(xrange(p*2, N+1, p))` That will shave a few milliseconds off your time at the very least. –  Shashank Oct 8 '13 at 4:10

Warning: `timeit` results may vary due to differences in hardware or version of Python.

Below is a script which compares a number of implementations:

Many thanks to stephan for bringing sieve_wheel_30 to my attention. Credit goes to Robert William Hanks for primesfrom2to, primesfrom3to, rwh_primes, rwh_primes1, and rwh_primes2.

Of the plain Python methods tested, with psyco, for n=1000000, rwh_primes1 was the fastest tested.

``````+---------------------+-------+
| Method              | ms    |
+---------------------+-------+
| rwh_primes1         | 43.0  |
| sieveOfAtkin        | 46.4  |
| rwh_primes          | 57.4  |
| sieve_wheel_30      | 63.0  |
| rwh_primes2         | 67.8  |
| sieveOfEratosthenes | 147.0 |
| ambi_sieve_plain    | 152.0 |
| sundaram3           | 194.0 |
+---------------------+-------+
``````

Of the plain Python methods tested, without psyco, for n=1000000, rwh_primes2 was the fastest.

``````+---------------------+-------+
| Method              | ms    |
+---------------------+-------+
| rwh_primes2         | 68.1  |
| rwh_primes1         | 93.7  |
| rwh_primes          | 94.6  |
| sieve_wheel_30      | 97.4  |
| sieveOfEratosthenes | 178.0 |
| ambi_sieve_plain    | 286.0 |
| sieveOfAtkin        | 314.0 |
| sundaram3           | 416.0 |
+---------------------+-------+
``````

Of all the methods tested, allowing numpy, for n=1000000, primesfrom2to was the fastest tested.

``````+---------------------+-------+
| Method              | ms    |
+---------------------+-------+
| primesfrom2to       | 15.9  |
| primesfrom3to       | 18.4  |
| ambi_sieve          | 29.3  |
+---------------------+-------+
``````

Timings were measured using the command:

``````python -mtimeit -s"import primes" "primes.{method}(10000000)"
``````

with `{method}` replaced by each of the method names.

primes.py:

``````#!/usr/bin/env python
import psyco; psyco.full()
from math import sqrt, ceil
import numpy as np

def rwh_primes(n):
# http://stackoverflow.com/questions/2068372/fastest-way-to-list-all-primes-below-n-in-python/3035188#3035188
""" Returns  a list of primes < n """
sieve = [True] * n
for i in xrange(3,int(n**0.5)+1,2):
if sieve[i]:
sieve[i*i::2*i]=[False]*((n-i*i-1)/(2*i)+1)
return [2] + [i for i in xrange(3,n,2) if sieve[i]]

def rwh_primes1(n):
# http://stackoverflow.com/questions/2068372/fastest-way-to-list-all-primes-below-n-in-python/3035188#3035188
""" Returns  a list of primes < n """
sieve = [True] * (n/2)
for i in xrange(3,int(n**0.5)+1,2):
if sieve[i/2]:
sieve[i*i/2::i] = [False] * ((n-i*i-1)/(2*i)+1)
return [2] + [2*i+1 for i in xrange(1,n/2) if sieve[i]]

def rwh_primes2(n):
# http://stackoverflow.com/questions/2068372/fastest-way-to-list-all-primes-below-n-in-python/3035188#3035188
""" Input n>=6, Returns a list of primes, 2 <= p < n """
correction = (n%6>1)
n = {0:n,1:n-1,2:n+4,3:n+3,4:n+2,5:n+1}[n%6]
sieve = [True] * (n/3)
sieve[0] = False
for i in xrange(int(n**0.5)/3+1):
if sieve[i]:
k=3*i+1|1
sieve[      ((k*k)/3)      ::2*k]=[False]*((n/6-(k*k)/6-1)/k+1)
sieve[(k*k+4*k-2*k*(i&1))/3::2*k]=[False]*((n/6-(k*k+4*k-2*k*(i&1))/6-1)/k+1)
return [2,3] + [3*i+1|1 for i in xrange(1,n/3-correction) if sieve[i]]

def sieve_wheel_30(N):
# http://zerovolt.com/?p=88
''' Returns a list of primes <= N using wheel criterion 2*3*5 = 30

This code is free for non-commercial purposes, in which case you can just leave this comment as a credit for my work.
If you need this code for commercial purposes, please contact me by sending an email to: info [at] zerovolt [dot] com.'''
__smallp = ( 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, 101, 103, 107, 109, 113, 127, 131, 137, 139,
149, 151, 157, 163, 167, 173, 179, 181, 191, 193, 197, 199, 211, 223, 227,
229, 233, 239, 241, 251, 257, 263, 269, 271, 277, 281, 283, 293, 307, 311,
313, 317, 331, 337, 347, 349, 353, 359, 367, 373, 379, 383, 389, 397, 401,
409, 419, 421, 431, 433, 439, 443, 449, 457, 461, 463, 467, 479, 487, 491,
499, 503, 509, 521, 523, 541, 547, 557, 563, 569, 571, 577, 587, 593, 599,
601, 607, 613, 617, 619, 631, 641, 643, 647, 653, 659, 661, 673, 677, 683,
691, 701, 709, 719, 727, 733, 739, 743, 751, 757, 761, 769, 773, 787, 797,
809, 811, 821, 823, 827, 829, 839, 853, 857, 859, 863, 877, 881, 883, 887,
907, 911, 919, 929, 937, 941, 947, 953, 967, 971, 977, 983, 991, 997)

wheel = (2, 3, 5)
const = 30
if N < 2:
return []
if N <= const:
pos = 0
while __smallp[pos] <= N:
pos += 1
return list(__smallp[:pos])
# make the offsets list
offsets = (7, 11, 13, 17, 19, 23, 29, 1)
# prepare the list
p = [2, 3, 5]
dim = 2 + N // const
tk1  = [True] * dim
tk7  = [True] * dim
tk11 = [True] * dim
tk13 = [True] * dim
tk17 = [True] * dim
tk19 = [True] * dim
tk23 = [True] * dim
tk29 = [True] * dim
tk1[0] = False
# help dictionary d
# d[a , b] = c  ==> if I want to find the smallest useful multiple of (30*pos)+a
# on tkc, then I need the index given by the product of [(30*pos)+a][(30*pos)+b]
# in general. If b < a, I need [(30*pos)+a][(30*(pos+1))+b]
d = {}
for x in offsets:
for y in offsets:
res = (x*y) % const
if res in offsets:
d[(x, res)] = y
# another help dictionary: gives tkx calling tmptk[x]
tmptk = {1:tk1, 7:tk7, 11:tk11, 13:tk13, 17:tk17, 19:tk19, 23:tk23, 29:tk29}
pos, prime, lastadded, stop = 0, 0, 0, int(ceil(sqrt(N)))
# inner functions definition
def del_mult(tk, start, step):
for k in xrange(start, len(tk), step):
tk[k] = False
# end of inner functions definition
cpos = const * pos
while prime < stop:
# 30k + 7
if tk7[pos]:
prime = cpos + 7
p.append(prime)
for off in offsets:
tmp = d[(7, off)]
start = (pos + prime) if off == 7 else (prime * (const * (pos + 1 if tmp < 7 else 0) + tmp) )//const
del_mult(tmptk[off], start, prime)
# 30k + 11
if tk11[pos]:
prime = cpos + 11
p.append(prime)
for off in offsets:
tmp = d[(11, off)]
start = (pos + prime) if off == 11 else (prime * (const * (pos + 1 if tmp < 11 else 0) + tmp) )//const
del_mult(tmptk[off], start, prime)
# 30k + 13
if tk13[pos]:
prime = cpos + 13
p.append(prime)
for off in offsets:
tmp = d[(13, off)]
start = (pos + prime) if off == 13 else (prime * (const * (pos + 1 if tmp < 13 else 0) + tmp) )//const
del_mult(tmptk[off], start, prime)
# 30k + 17
if tk17[pos]:
prime = cpos + 17
p.append(prime)
for off in offsets:
tmp = d[(17, off)]
start = (pos + prime) if off == 17 else (prime * (const * (pos + 1 if tmp < 17 else 0) + tmp) )//const
del_mult(tmptk[off], start, prime)
# 30k + 19
if tk19[pos]:
prime = cpos + 19
p.append(prime)
for off in offsets:
tmp = d[(19, off)]
start = (pos + prime) if off == 19 else (prime * (const * (pos + 1 if tmp < 19 else 0) + tmp) )//const
del_mult(tmptk[off], start, prime)
# 30k + 23
if tk23[pos]:
prime = cpos + 23
p.append(prime)
for off in offsets:
tmp = d[(23, off)]
start = (pos + prime) if off == 23 else (prime * (const * (pos + 1 if tmp < 23 else 0) + tmp) )//const
del_mult(tmptk[off], start, prime)
# 30k + 29
if tk29[pos]:
prime = cpos + 29
p.append(prime)
for off in offsets:
tmp = d[(29, off)]
start = (pos + prime) if off == 29 else (prime * (const * (pos + 1 if tmp < 29 else 0) + tmp) )//const
del_mult(tmptk[off], start, prime)
pos += 1
cpos = const * pos
# 30k + 1
if tk1[pos]:
prime = cpos + 1
p.append(prime)
for off in offsets:
tmp = d[(1, off)]
start = (pos + prime) if off == 1 else (prime * (const * pos + tmp) )//const
del_mult(tmptk[off], start, prime)
# time to add remaining primes
# if lastadded == 1, remove last element and start adding them from tk1
# this way we don't need an "if" within the last while
p.pop()
# now complete for every other possible prime
while pos < len(tk1):
cpos = const * pos
if tk1[pos]: p.append(cpos + 1)
if tk7[pos]: p.append(cpos + 7)
if tk11[pos]: p.append(cpos + 11)
if tk13[pos]: p.append(cpos + 13)
if tk17[pos]: p.append(cpos + 17)
if tk19[pos]: p.append(cpos + 19)
if tk23[pos]: p.append(cpos + 23)
if tk29[pos]: p.append(cpos + 29)
pos += 1
# remove exceeding if present
pos = len(p) - 1
while p[pos] > N:
pos -= 1
if pos < len(p) - 1:
del p[pos+1:]
# return p list
return p

def sieveOfEratosthenes(n):
"""sieveOfEratosthenes(n): return the list of the primes < n."""
# Code from: <dickinsm@gmail.com>, Nov 30 2006
if n <= 2:
return []
sieve = range(3, n, 2)
top = len(sieve)
for si in sieve:
if si:
bottom = (si*si - 3) // 2
if bottom >= top:
break
sieve[bottom::si] = [0] * -((bottom - top) // si)
return [2] + [el for el in sieve if el]

def sieveOfAtkin(end):
"""sieveOfAtkin(end): return a list of all the prime numbers <end
using the Sieve of Atkin."""
# Code by Steve Krenzel, <Sgk284@gmail.com>, improved
# Code: http://krenzel.info/?p=83
# Info: http://en.wikipedia.org/wiki/Sieve_of_Atkin
assert end > 0
lng = ((end-1) // 2)
sieve = [False] * (lng + 1)

x_max, x2, xd = int(sqrt((end-1)/4.0)), 0, 4
for xd in xrange(4, 8*x_max + 2, 8):
x2 += xd
y_max = int(sqrt(end-x2))
n, n_diff = x2 + y_max*y_max, (y_max << 1) - 1
if not (n & 1):
n -= n_diff
n_diff -= 2
for d in xrange((n_diff - 1) << 1, -1, -8):
m = n % 12
if m == 1 or m == 5:
m = n >> 1
sieve[m] = not sieve[m]
n -= d

x_max, x2, xd = int(sqrt((end-1) / 3.0)), 0, 3
for xd in xrange(3, 6 * x_max + 2, 6):
x2 += xd
y_max = int(sqrt(end-x2))
n, n_diff = x2 + y_max*y_max, (y_max << 1) - 1
if not(n & 1):
n -= n_diff
n_diff -= 2
for d in xrange((n_diff - 1) << 1, -1, -8):
if n % 12 == 7:
m = n >> 1
sieve[m] = not sieve[m]
n -= d

x_max, y_min, x2, xd = int((2 + sqrt(4-8*(1-end)))/4), -1, 0, 3
for x in xrange(1, x_max + 1):
x2 += xd
xd += 6
if x2 >= end: y_min = (((int(ceil(sqrt(x2 - end))) - 1) << 1) - 2) << 1
n, n_diff = ((x*x + x) << 1) - 1, (((x-1) << 1) - 2) << 1
for d in xrange(n_diff, y_min, -8):
if n % 12 == 11:
m = n >> 1
sieve[m] = not sieve[m]
n += d

primes = [2, 3]
if end <= 3:
return primes[:max(0,end-2)]

for n in xrange(5 >> 1, (int(sqrt(end))+1) >> 1):
if sieve[n]:
primes.append((n << 1) + 1)
aux = (n << 1) + 1
aux *= aux
for k in xrange(aux, end, 2 * aux):
sieve[k >> 1] = False

s  = int(sqrt(end)) + 1
if s  % 2 == 0:
s += 1
primes.extend([i for i in xrange(s, end, 2) if sieve[i >> 1]])

return primes

def ambi_sieve_plain(n):
s = range(3, n, 2)
for m in xrange(3, int(n**0.5)+1, 2):
if s[(m-3)/2]:
for t in xrange((m*m-3)/2,(n>>1)-1,m):
s[t]=0
return [2]+[t for t in s if t>0]

def sundaram3(max_n):
# http://stackoverflow.com/questions/2068372/fastest-way-to-list-all-primes-below-n-in-python/2073279#2073279
numbers = range(3, max_n+1, 2)
half = (max_n)//2
initial = 4

for step in xrange(3, max_n+1, 2):
for i in xrange(initial, half, step):
numbers[i-1] = 0
initial += 2*(step+1)

if initial > half:
return [2] + filter(None, numbers)

################################################################################
# Using Numpy:
def ambi_sieve(n):
# http://tommih.blogspot.com/2009/04/fast-prime-number-generator.html
s = np.arange(3, n, 2)
for m in xrange(3, int(n ** 0.5)+1, 2):
if s[(m-3)/2]:
s[(m*m-3)/2::m]=0
return np.r_[2, s[s>0]]

def primesfrom3to(n):
# http://stackoverflow.com/questions/2068372/fastest-way-to-list-all-primes-below-n-in-python/3035188#3035188
""" Returns a array of primes, p < n """
assert n>=2
sieve = np.ones(n/2, dtype=np.bool)
for i in xrange(3,int(n**0.5)+1,2):
if sieve[i/2]:
sieve[i*i/2::i] = False
return np.r_[2, 2*np.nonzero(sieve)[0][1::]+1]

def primesfrom2to(n):
# http://stackoverflow.com/questions/2068372/fastest-way-to-list-all-primes-below-n-in-python/3035188#3035188
""" Input n>=6, Returns a array of primes, 2 <= p < n """
sieve = np.ones(n/3 + (n%6==2), dtype=np.bool)
sieve[0] = False
for i in xrange(int(n**0.5)/3+1):
if sieve[i]:
k=3*i+1|1
sieve[      ((k*k)/3)      ::2*k] = False
sieve[(k*k+4*k-2*k*(i&1))/3::2*k] = False
return np.r_[2,3,((3*np.nonzero(sieve)[0]+1)|1)]

if __name__=='__main__':
import itertools
import sys

def test(f1,f2,num):
print('Testing {f1} and {f2} return same results'.format(
f1=f1.func_name,
f2=f2.func_name))
if not all([a==b for a,b in itertools.izip_longest(f1(num),f2(num))]):
sys.exit("Error: %s(%s) != %s(%s)"%(f1.func_name,num,f2.func_name,num))

n=1000000
test(sieveOfAtkin,sieveOfEratosthenes,n)
test(sieveOfAtkin,ambi_sieve,n)
test(sieveOfAtkin,ambi_sieve_plain,n)
test(sieveOfAtkin,sundaram3,n)
test(sieveOfAtkin,sieve_wheel_30,n)
test(sieveOfAtkin,primesfrom3to,n)
test(sieveOfAtkin,primesfrom2to,n)
test(sieveOfAtkin,rwh_primes,n)
test(sieveOfAtkin,rwh_primes1,n)
test(sieveOfAtkin,rwh_primes2,n)
``````

Running the script tests that all implementations give the same result.

-
That's not pure Python, but it's the fastest version so far. thanks! –  jbochi Jan 15 '10 at 1:11
If you're interested in non-pure-Python code, then you should check out `gmpy` -- it has pretty good support for primes, via the `next_prime` method of its `mpz` type. –  Alex Martelli Jan 15 '10 at 1:41
just for correctness, the code example should have `import numpy as np` –  Kimvais Jan 15 '10 at 10:15
@Kimvais: True, thanks. –  unutbu Jan 15 '10 at 10:39
`int(n ** 0.5)` should be `int(math.ceil(n ** 0.5))` or `int(n ** 0.5) + 1`. `ambi_sieve(10)` gives wrong answer otherwise. –  Alok Singhal Jan 20 '10 at 3:48

Related question(dealing with primes generators & including benchmarks):
Speed up bitstring/bit operations in Python?

Faster & more memory-wise pure Python code:

``````def primes(n):
""" Returns  a list of primes < n """
sieve = [True] * n
for i in xrange(3,int(n**0.5)+1,2):
if sieve[i]:
sieve[i*i::2*i]=[False]*((n-i*i-1)/(2*i)+1)
return [2] + [i for i in xrange(3,n,2) if sieve[i]]
``````

or starting with half sieve

``````def primes1(n):
""" Returns  a list of primes < n """
sieve = [True] * (n/2)
for i in xrange(3,int(n**0.5)+1,2):
if sieve[i/2]:
sieve[i*i/2::i] = [False] * ((n-i*i-1)/(2*i)+1)
return [2] + [2*i+1 for i in xrange(1,n/2) if sieve[i]]
``````

Faster & more memory-wise numpy code:

``````import numpy
def primesfrom3to(n):
""" Returns a array of primes, 3 <= p < n """
sieve = numpy.ones(n/2, dtype=numpy.bool)
for i in xrange(3,int(n**0.5)+1,2):
if sieve[i/2]:
sieve[i*i/2::i] = False
return 2*numpy.nonzero(sieve)[0][1::]+1
``````

a faster variation starting with a third of a sieve:

``````import numpy
def primesfrom2to(n):
""" Input n>=6, Returns a array of primes, 2 <= p < n """
sieve = numpy.ones(n/3 + (n%6==2), dtype=numpy.bool)
for i in xrange(1,int(n**0.5)/3+1):
if sieve[i]:
k=3*i+1|1
sieve[       k*k/3     ::2*k] = False
sieve[k*(k-2*(i&1)+4)/3::2*k] = False
return numpy.r_[2,3,((3*numpy.nonzero(sieve)[0][1:]+1)|1)]
``````

A (hard-to-code) pure-python version of the above code would be:

``````def primes2(n):
""" Input n>=6, Returns a list of primes, 2 <= p < n """
n, correction = n-n%6+6, 2-(n%6>1)
sieve = [True] * (n/3)
for i in xrange(1,int(n**0.5)/3+1):
if sieve[i]:
k=3*i+1|1
sieve[      k*k/3      ::2*k] = [False] * ((n/6-k*k/6-1)/k+1)
sieve[k*(k-2*(i&1)+4)/3::2*k] = [False] * ((n/6-k*(k-2*(i&1)+4)/6-1)/k+1)
return [2,3] + [3*i+1|1 for i in xrange(1,n/3-correction) if sieve[i]]
``````

Unfortunately pure-python don't adopt the simpler and faster numpy way of doing Assignment, and calling len() inside the loop as in [False]*len(sieve[((k*k)/3)::2*k]) is too slow. So i had to improvise to correct input (& avoid more math) and do some extreme (& painful) math-magic.
Personally i think it is a shame that numpy (which is so widely used) is not part of python standard library(2 years after python 3 release & no numpy compatibility), and that the improvements in syntax and speed seem to be completely overlooked by python developers.

-
+1: `primesfrom3to` (19.6ms) is signifcantly faster than `ambi_sieve` (29.4ms). Terrific. Thanks for sharing. PS. Since 2 is prime, would you consider changing the return value to `numpy.r_[2, 2*np.nonzero(sieve)[0][1::]+1]`? –  unutbu Jun 14 '10 at 13:11
i use the code that way, fell free to change it for tests if you want, probably with the correction the timing will be almost the same for 1e6 (for 1e7 to 1e9 should be faster), also plz tel me how primes(n) & primes1(n) compare in your machine to the pure python best code for 1e6 & 1e7. –  Robert William Hanks Jun 14 '10 at 19:44
@Robert: I added your implementations to the list compared in my answer. `primes1` and `primesfrom3to` came out on top! The rankings shown are for n=1e6. The order of the rankings did not change with n=1e7. –  unutbu Jun 15 '10 at 1:30
I've added `primes2` and `primesfrom2to` to the methods tested in my post. Both were significant improvements on the prior fastest. Great work! –  unutbu Jul 23 '10 at 13:07
I don't see any measurable speed-up for the new `primesfrom2to()` ideone.com/5YJkw (performance comparison is at the end of the file) –  J.F. Sebastian Jul 25 '10 at 18:03

There's a pretty neat sample from the Python Cookbook here -- the fastest version proposed on that URL is:

``````import itertools
def erat2( ):
D = {  }
yield 2
for q in itertools.islice(itertools.count(3), 0, None, 2):
p = D.pop(q, None)
if p is None:
D[q*q] = q
yield q
else:
x = p + q
while x in D or not (x&1):
x += p
D[x] = p
``````

so that would give

``````get_primes_erat(n):
return list(itertools.takewhile(lambda p: p<n, erat2()))
``````

Measuring at the shell prompt (as I prefer to do) with this code in pri.py, I observe:

``````\$ python2.5 -mtimeit -s'import pri' 'pri.get_primes(1000000)'
10 loops, best of 3: 1.69 sec per loop
\$ python2.5 -mtimeit -s'import pri' 'pri.get_primes_erat(1000000)'
10 loops, best of 3: 673 msec per loop
``````

so it looks like the Cookbook solution is over twice as fast.

-
Wow! That's really fast. Thank you, super Alex! :-) –  jbochi Jan 14 '10 at 23:55
@jbochi, you're welcome -- but do look at that URL, including the credits: it took ten of us to collectively refine the code to this point, including Python-performance luminaries such as Tim Peters and Raymond Hettinger (I wrote the final text of the recipe since I edited the printed Cookbook, but in terms of coding my contribution was on a par with the others') -- in the end, it's really subtle and finely tuned code, and that's not surprising!-) –  Alex Martelli Jan 14 '10 at 23:59
@Alex: Knowing that your code is "only" twice as fast as mine, makes me pretty proud then. :) The URL was also very interesting to read. Thanks again. –  jbochi Jan 15 '10 at 0:13
And it can be made even faster with a minor change: see stackoverflow.com/questions/2211990/… –  tzot Sep 26 '10 at 3:02
... And it can be made yet faster with additional ~1.2x-1.3x speedup, drastic reduction in memory footprint from O(n) to O(sqrt(n)) and improvement in empirical time complexity, by postponing the addition of primes to the dict until their square is seen in the input. Test it here. –  Will Ness Aug 2 '12 at 22:28

Using Sundaram's Sieve, I think I broke pure-Python's record:

``````def sundaram3(max_n):
numbers = range(3, max_n+1, 2)
half = (max_n)//2
initial = 4

for step in xrange(3, max_n+1, 2):
for i in xrange(initial, half, step):
numbers[i-1] = 0
initial += 2*(step+1)

if initial > half:
return [2] + filter(None, numbers)
``````

Comparasion:

``````C:\USERS>python -m timeit -n10 -s "import get_primes" "get_primes.get_primes_erat(1000000)"
10 loops, best of 3: 710 msec per loop

C:\USERS>python -m timeit -n10 -s "import get_primes" "get_primes.daniel_sieve_2(1000000)"
10 loops, best of 3: 435 msec per loop

C:\USERS>python -m timeit -n10 -s "import get_primes" "get_primes.sundaram3(1000000)"
10 loops, best of 3: 327 msec per loop
``````
-
I've not come across Sundaram's Sieve before - very cool! –  Mike Houston Jan 15 '10 at 17:15
I managed to speed up your function about 20% by adding "zero = 0" at the top of the function and then replacing the lambda in your filter with "zero.__sub__". Not the prettiest code in the world, but a bit faster :) –  truppo Jan 20 '10 at 10:34
@truppo: Thanks for your comment! I just realized that passing `None` instead of the original function works and it's even faster than `zero.__sub__` –  jbochi Jan 20 '10 at 11:08
Did you know that if you pass `sundaram3(9)` it will return `[2, 3, 5, 7, 9]`? It seems to do this with numerous -- perhaps all -- odd numbers (even when they aren't prime) –  wrhall Sep 21 '13 at 23:57

The algorithm is fast, but it has a serious flaw:

``````>>> sorted(get_primes(530))
[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, 101, 103, 107, 109, 113, 127, 131, 137, 139, 149, 151, 157, 163,
167, 173, 179, 181, 191, 193, 197, 199, 211, 223, 227, 229, 233, 239, 241, 251,
257, 263, 269, 271, 277, 281, 283, 293, 307, 311, 313, 317, 331, 337, 347, 349,
353, 359, 367, 373, 379, 383, 389, 397, 401, 409, 419, 421, 431, 433, 439, 443,
449, 457, 461, 463, 467, 479, 487, 491, 499, 503, 509, 521, 523, 527, 529]
>>> 17*31
527
>>> 23*23
529
``````

You assume that `numbers.pop()` would return the smallest number in the set, but this is not guaranteed at all. Sets are unordered and `pop()` removes and returns an arbitrary element, so it cannot be used to select the next prime from the remaining numbers.

-
Thanks for pointing this out... I was using lists and I moved to sets to make it faster, but I didn't realize it broke the algorithm. –  jbochi Jan 15 '10 at 1:10

For truly fastest solution with sufficiently large N would be to download a pre-calculated list of primes, store it as a tuple and do something like:

``````for pos,i in enumerate(primes):
if i > N:
print primes[:pos]
``````

If `N > primes[-1]` only then calculate more primes and save the new list in your code, so next time it is equally as fast.

Always think outside the box.

-
To be fair, though, you'd have to count the time downloading, unzipping, and formatting the primes and compare that with the time to generate primes using an algorithm - any one of these algorithms could easily write the results to a file for later use. I think in that case, given enough memory to actually calculate all primes less than 982,451,653, the numpy solution would still be faster. –  Daniel G Jan 15 '10 at 8:49
@Daniel correct. However the store what you have and continue whenever needed still stands... –  Kimvais Jan 15 '10 at 10:11

A deterministic implementation of Miller-Rabin's Primality test on the assumption that N < 9,080,191

``````import sys
import random

def miller_rabin_pass(a, n):
d = n - 1
s = 0
while d % 2 == 0:
d >>= 1
s += 1

a_to_power = pow(a, d, n)
if a_to_power == 1:
return True
for i in xrange(s-1):
if a_to_power == n - 1:
return True
a_to_power = (a_to_power * a_to_power) % n
return a_to_power == n - 1

def miller_rabin(n):
for a in [2, 3, 37, 73]:
if not miller_rabin_pass(a, n):
return False
return True

n = int(sys.argv[1])
primes = [2]
for p in range(3,n,2):
if miller_rabin(p):
primes.append(p)
print len(primes)
``````

According to the article on Wikipedia (http://en.wikipedia.org/wiki/Miller–Rabin_primality_test) testing N < 9,080,191 for a = 2,3,37, and 73 is enough to decide whether N is composite or not.

And I adapted the source code from the probabilistic implementation of original Miller-Rabin's test found here: http://en.literateprograms.org/Miller-Rabin_primality_test_(Python)

-
Thank's for the Miller-Rabin primality test, but this code is actually slower and is not providing the correct results. 37 is prime and does not pass the test. –  jbochi Jan 21 '10 at 10:07
I guess 37 is one of the special cases, my bad. I was hopeful about the deterministic version though :) –  Amaç Herdağdelen Jan 21 '10 at 11:07
There isn't any special case for rabin miller. –  Julián Nov 26 '13 at 23:37
You misread the article. It is 31, not 37. This is why your implementation fails. –  Logan Dec 24 '13 at 22:36

If you have control over N, the very fastest way to list all primes is to precompute them. Seriously. Precomputing is a way overlooked optimization.

-
Or download them from here primes.utm.edu/lists/small/millions, but the idea is to test python's limit and see if beautiful code emerge from optimization. –  jbochi Jan 21 '10 at 10:14

For the fastest code, the numpy solution is the best. For purely academic reasons, though, I'm posting my pure python version, which is a bit less than 50% faster than the cookbook version posted above. Since I make the entire list in memory, you need enough space to hold everything, but it seems to scale fairly well.

``````def daniel_sieve_2(maxNumber):
"""
Given a number, returns all numbers less than or equal to
that number which are prime.
"""
allNumbers = range(3, maxNumber+1, 2)
for mIndex, number in enumerate(xrange(3, maxNumber+1, 2)):
if allNumbers[mIndex] == 0:
continue
# now set all multiples to 0
for index in xrange(mIndex+number, (maxNumber-3)/2+1, number):
allNumbers[index] = 0
return [2] + filter(lambda n: n!=0, allNumbers)
``````

And the results:

``````>>>mine = timeit.Timer("daniel_sieve_2(1000000)",
...                    "from sieves import daniel_sieve_2")
>>>prev = timeit.Timer("get_primes_erat(1000000)",
...                    "from sieves import get_primes_erat")
>>>print "Mine: {0:0.4f} ms".format(min(mine.repeat(3, 1))*1000)
Mine: 428.9446 ms
>>>print "Previous Best {0:0.4f} ms".format(min(prev.repeat(3, 1))*1000)
Previous Best 621.3581 ms
``````
-

Here's the code I normally use to generate primes in Python:

``````\$ python -mtimeit -s'import sieve' 'sieve.sieve(1000000)'
10 loops, best of 3: 445 msec per loop
\$ cat sieve.py
from math import sqrt

def sieve(size):
prime=[True]*size
rng=xrange
limit=int(sqrt(size))

for i in rng(3,limit+1,+2):
if prime[i]:
prime[i*i::+i]=[False]*len(prime[i*i::+i])

return [2]+[i for i in rng(3,size,+2) if prime[i]]

if __name__=='__main__':
print sieve(100)
``````

It can't compete with the faster solutions posted here, but at least it is pure python.

Thanks for posting this question. I really learnt a lot today.

-

A slightly different implementation of a half sieve using Numpy:

http://rebrained.com/?p=458

```import math
import numpy
def prime6(upto):
primes=numpy.arange(3,upto+1,2)
isprime=numpy.ones((upto-1)/2,dtype=bool)
for factor in primes[:int(math.sqrt(upto))]:
if isprime[(factor-2)/2]: isprime[(factor*3-2)/2:(upto-1)/2:factor]=0
return numpy.insert(primes[isprime],0,2)
```

Can someone compare this with the other timings? On my machine it seems pretty comparable to the other Numpy half-sieve.

-
`upto=10**6`: `primesfrom2to()` - 7 ms; `prime6()` - 12 ms ideone.com/oDg2Y –  J.F. Sebastian Sep 4 '10 at 1:57

First time using python, so some of the methods I use in this might seem a bit cumbersome. I just straight converted my c++ code to python and this is what I have (albeit a tad bit slowww in python)

``````#!/usr/bin/env python
import time

def GetPrimes(n):

Sieve = [1 for x in xrange(n)]

Done = False
w = 3

while not Done:

for q in xrange (3, n, 2):
Prod = w*q
if Prod < n:
Sieve[Prod] = 0
else:
break

if w > (n/2):
Done = True
w += 2

return Sieve

start = time.clock()

d = 10000000
Primes = GetPrimes(d)

count = 1 #This is for 2

for x in xrange (3, d, 2):
if Primes[x]:
count+=1

elapsed = (time.clock() - start)
print "\nFound", count, "primes in", elapsed, "seconds!\n"
``````

pythonw Primes.py

Found 664579 primes in 12.799119 seconds!

``````#!/usr/bin/env python
import time

def GetPrimes2(n):

Sieve = [1 for x in xrange(n)]

for q in xrange (3, n, 2):
k = q
for y in xrange(k*3, n, k*2):
Sieve[y] = 0

return Sieve

start = time.clock()

d = 10000000
Primes = GetPrimes2(d)

count = 1 #This is for 2

for x in xrange (3, d, 2):
if Primes[x]:
count+=1

elapsed = (time.clock() - start)
print "\nFound", count, "primes in", elapsed, "seconds!\n"
``````

pythonw Primes2.py

Found 664579 primes in 10.230172 seconds!

``````#!/usr/bin/env python
import time

def GetPrimes3(n):

Sieve = [1 for x in xrange(n)]

for q in xrange (3, n, 2):
k = q
for y in xrange(k*k, n, k << 1):
Sieve[y] = 0

return Sieve

start = time.clock()

d = 10000000
Primes = GetPrimes3(d)

count = 1 #This is for 2

for x in xrange (3, d, 2):
if Primes[x]:
count+=1

elapsed = (time.clock() - start)
print "\nFound", count, "primes in", elapsed, "seconds!\n"
``````

python Primes2.py

Found 664579 primes in 7.113776 seconds!

-

I know the competition is closed for some years. …

Nonetheless this is my suggestion for a pure python prime sieve, based on omitting the multiples of 2, 3 and 5 by using appropriate steps while processing the sieve forward. Nonetheless it is actually slower for N<10^9 than @Robert William Hanks superior solutions rwh_primes2 and rwh_primes1. By using a ctypes.c_ushort sieve array above 1.5* 10^8 it is somehow adaptive to memory limits.

10^6

\$ python -mtimeit -s"import primeSieveSpeedComp" "primeSieveSpeedComp.primeSieveSeq(1000000)" 10 loops, best of 3: 46.7 msec per loop

to compare:\$ python -mtimeit -s"import primeSieveSpeedComp" "primeSieveSpeedComp.rwh_primes1(1000000)" 10 loops, best of 3: 43.2 msec per loop to compare: \$ python -m timeit -s"import primeSieveSpeedComp" "primeSieveSpeedComp.rwh_primes2(1000000)" 10 loops, best of 3: 34.5 msec per loop

10^7

\$ python -mtimeit -s"import primeSieveSpeedComp" "primeSieveSpeedComp.primeSieveSeq(10000000)" 10 loops, best of 3: 530 msec per loop

to compare:\$ python -mtimeit -s"import primeSieveSpeedComp" "primeSieveSpeedComp.rwh_primes1(10000000)" 10 loops, best of 3: 494 msec per loop to compare: \$ python -m timeit -s"import primeSieveSpeedComp" "primeSieveSpeedComp.rwh_primes2(10000000)" 10 loops, best of 3: 375 msec per loop

10^8

\$ python -mtimeit -s"import primeSieveSpeedComp" "primeSieveSpeedComp.primeSieveSeq(100000000)" 10 loops, best of 3: 5.55 sec per loop

to compare: \$ python -mtimeit -s"import primeSieveSpeedComp" "primeSieveSpeedComp.rwh_primes1(100000000)" 10 loops, best of 3: 5.33 sec per loop to compare: \$ python -m timeit -s"import primeSieveSpeedComp" "primeSieveSpeedComp.rwh_primes2(100000000)" 10 loops, best of 3: 3.95 sec per loop

10^9

\$ python -mtimeit -s"import primeSieveSpeedComp" "primeSieveSpeedComp.primeSieveSeq(1000000000)" 10 loops, best of 3: 61.2 sec per loop

to compare: \$ python -mtimeit -n 3 -s"import primeSieveSpeedComp" "primeSieveSpeedComp.rwh_primes1(1000000000)" 3 loops, best of 3: 97.8 sec per loop

to compare: \$ python -m timeit -s"import primeSieveSpeedComp" "primeSieveSpeedComp.rwh_primes2(1000000000)" 10 loops, best of 3: 41.9 sec per loop

You may copy the code below into ubuntus primeSieveSpeedComp to review this tests.

``````def primeSieveSeq(MAX_Int):
if MAX_Int > 5*10**8:
import ctypes
int16Array = ctypes.c_ushort * (MAX_Int >> 1)
sieve = int16Array()
#print 'uses ctypes "unsigned short int Array"'
else:
sieve = (MAX_Int >> 1) * [False]
#print 'uses python list() of long long int'
if MAX_Int < 10**8:
sieve[4::3] = [True]*((MAX_Int - 8)/6+1)
sieve[12::5] = [True]*((MAX_Int - 24)/10+1)
r = [2, 3, 5]
n = 0
for i in xrange(int(MAX_Int**0.5)/30+1):
n += 3
if not sieve[n]:
n2 = (n << 1) + 1
r.append(n2)
n2q = (n2**2) >> 1
sieve[n2q::n2] = [True]*(((MAX_Int >> 1) - n2q - 1) / n2 + 1)
n += 2
if not sieve[n]:
n2 = (n << 1) + 1
r.append(n2)
n2q = (n2**2) >> 1
sieve[n2q::n2] = [True]*(((MAX_Int >> 1) - n2q - 1) / n2 + 1)
n += 1
if not sieve[n]:
n2 = (n << 1) + 1
r.append(n2)
n2q = (n2**2) >> 1
sieve[n2q::n2] = [True]*(((MAX_Int >> 1) - n2q - 1) / n2 + 1)
n += 2
if not sieve[n]:
n2 = (n << 1) + 1
r.append(n2)
n2q = (n2**2) >> 1
sieve[n2q::n2] = [True]*(((MAX_Int >> 1) - n2q - 1) / n2 + 1)
n += 1
if not sieve[n]:
n2 = (n << 1) + 1
r.append(n2)
n2q = (n2**2) >> 1
sieve[n2q::n2] = [True]*(((MAX_Int >> 1) - n2q - 1) / n2 + 1)
n += 2
if not sieve[n]:
n2 = (n << 1) + 1
r.append(n2)
n2q = (n2**2) >> 1
sieve[n2q::n2] = [True]*(((MAX_Int >> 1) - n2q - 1) / n2 + 1)
n += 3
if not sieve[n]:
n2 = (n << 1) + 1
r.append(n2)
n2q = (n2**2) >> 1
sieve[n2q::n2] = [True]*(((MAX_Int >> 1) - n2q - 1) / n2 + 1)
n += 1
if not sieve[n]:
n2 = (n << 1) + 1
r.append(n2)
n2q = (n2**2) >> 1
sieve[n2q::n2] = [True]*(((MAX_Int >> 1) - n2q - 1) / n2 + 1)
if MAX_Int < 10**8:
return [2, 3, 5]+[(p << 1) + 1 for p in [n for n in xrange(3, MAX_Int >> 1) if not sieve[n]]]
n = n >> 1
try:
for i in xrange((MAX_Int-2*n)/30 + 1):
n += 3
if not sieve[n]:
r.append((n << 1) + 1)
n += 2
if not sieve[n]:
r.append((n << 1) + 1)
n += 1
if not sieve[n]:
r.append((n << 1) + 1)
n += 2
if not sieve[n]:
r.append((n << 1) + 1)
n += 1
if not sieve[n]:
r.append((n << 1) + 1)
n += 2
if not sieve[n]:
r.append((n << 1) + 1)
n += 3
if not sieve[n]:
r.append((n << 1) + 1)
n += 1
if not sieve[n]:
r.append((n << 1) + 1)
except:
pass
return r
``````
-

What size of primes do you want? There are some very fast statistical algorithms out there (eg Miller-Rabin), but their overheads mean they turn out slower unless dealing with very big (over 2^64) numbers..

-
I am doing this just for fun. I'd say no more than 10 million. –  jbochi Jan 14 '10 at 23:57

In general if you need fast number computation python is not the best choice. Today there are a lot of faster (and complex) algorithm. For example on my computer I got 2.2 second for your code, with Mathematica I got 0.088005.

First of all: do you need set?

-
If I'm not mistaken, this makes the Numpy version faster than Mathematica. :) –  EOL Jan 15 '10 at 9:15
How you can say it? Have you tried the two solutions on the same machine? –  Ruggero Turra Jan 15 '10 at 10:52
@wiso: He can use your proportions to extrapolate how long Mathematica will take on his machine. If his extrapolation is wrong, then that could mean that the two algorithms are more or less efficient than usual depending on machine setup. –  Brian Jan 15 '10 at 20:54

The easiest optimization to implement is that if you want to check whether n is prime, you only have to check to see if n is divisible by a number up to square_root(n). Is this for Project Euler?

-
I think you misunderstood the problem. jbochi wants to find the first N primes, not test an arbitrary N for primality. Trial division would probably be just about the slowest way of doing it -- the posted answers seem to be variations of the "Sieve of Eratosthenes" algorithm, which doesn't need to do division at all. –  Jim Lewis Jan 20 '10 at 23:19
Indeed I did misread the question.. –  Matt Jan 21 '10 at 2:16

Sorry to bother but erat2() has a serious flaw in the algorithm.

While searching for the next composite, we need to test odd numbers only. q,p both are odd; then q+p is even and doesn't need to be tested, but q+2*p is always odd. This eliminates the "if even" test in the while loop condition and saves about 30% of the runtime.

While we're at it: instead of the elegant 'D.pop(q,None)' get and delete method use 'if q in D: p=D[q],del D[q]' which is twice as fast! At least on my machine (P3-1Ghz). So I suggest this implementation of this clever algorithm:

``````def erat3( ):
from itertools import islice, count

# q is the running integer that's checked for primeness.
# yield 2 and no other even number thereafter
yield 2
D = {}
# no need to mark D[4] as we will test odd numbers only
for q in islice(count(3),0,None,2):
if q in D:                  #  is composite
p = D[q]
del D[q]
# q is composite. p=D[q] is the first prime that
# divides it. Since we've reached q, we no longer
# need it in the map, but we'll mark the next
# multiple of its witnesses to prepare for larger
# numbers.
x = q + p+p        # next odd(!) multiple
while x in D:      # skip composites
x += p+p
D[x] = p
else:                  # is prime
# q is a new prime.
# Yield it and mark its first multiple that isn't
# already marked in previous iterations.
D[q*q] = q
yield q
``````
-
for a postponed addition of primes into the dict (until the square of a prime is seen in the input) see stackoverflow.com/a/10733621/849891 . –  Will Ness Nov 10 '12 at 21:12

The fastest method I've tried so far is based on the Python cookbook `erat2` function:

``````import itertools as it
def erat2a( ):
D = {  }
yield 2
for q in it.islice(it.count(3), 0, None, 2):
p = D.pop(q, None)
if p is None:
D[q*q] = q
yield q
else:
x = q + 2*p
while x in D:
x += 2*p
D[x] = p
``````

See this answer for an explanation of the speeding-up.

-

I may be late to the party but will have to add my own code for this. It uses approximately n/2 in space because we don't need to store even numbers and I also make use of the bitarray python module, further draStically cutting down on memory consumption and enabling computing all primes up to 1,000,000,000

``````from bitarray import bitarray
def primes_to(n):
size = n//2
sieve = bitarray(size)
sieve.setall(1)
limit = int(n**0.5)
for i in range(1,limit):
if sieve[i]:
val = 2*i+1
sieve[(i+i*val)::val] = 0
return [2] + [2*i+1 for i, v in enumerate(sieve) if v and i > 0]

python -m timeit -n10 -s "import euler" "euler.primes_to(1000000000)"
10 loops, best of 3: 46.5 sec per loop
``````

This was run on a 64bit 2.4GHZ MAC OSX 10.8.3

-
posting one timing for an unknown machine says nothing. The accepted answer here says "without psyco, for n=1000000, rwh_primes2 was the fastest". So if you'd provide your timings for that code as well as yours, on the same machine, and at 2, 4, 10 mln as well, then it'd be much more informative. –  Will Ness Apr 17 '13 at 7:32
-1, This code depends on special features of the bitarray implemented in C, which is why the code is fast as most of the work is being done in native code in the slice assignment. The bitarray package BREAKS the standard definition for proper slices (indexed over a range) for mutable sequences in that it allows assigning a single boolean 0/1 or True/False to all elements of the slice, whereas the standard behavior for pure Python seems to be to not allow this and only allow the assignment value of 0 in which case it is treated as a del of all of the slice elements from the sequence/array. –  GordonBGood Aug 19 '13 at 16:46
cont'd: If calling non-standard native code were to be compared, we may as well write a "fastprimes" sequence generator package based on C code such as that of Kim Walisch's primesieve and generate all the primes in the four billion plus 32-bit number range in just a few seconds with a single call to the sequence generator. This would also use almost no memory as the linked code is based on a segmented Sieve of Eratosthenes and thus only uses a few ten's of Kilobytes of RAM, and if a sequence were generated there would be no list storage required. –  GordonBGood Aug 19 '13 at 17:54

This is an elegant and simpler solution to find primes using a stored list. Starts with a 4 variables, you only have to test odd primes for divisors, and you only have to test up to a half of what number you are testing as a prime (no point in testing whether 9, 11, 13 divide into 17). It tests previously stored primes as divisors.`

``````    # Program to calculate Primes
primes = [1,3,5,7]
for n in range(9,100000,2):
for x in range(1,(len(primes)/2)):
if n % primes[x] == 0:
break
else:
primes.append(n)
print primes
``````
-

My guess is that the fastest of all ways is to hard code the primes in your code.

So why not just write a slow script that generates another source file that has all numbers hardwired in it, and then import that source file when you run your actual program.

Of course, this works only if you know the upper bound of N at compile time, but thus is the case for (almost) all project Euler problems.

PS: I might be wrong though iff parsing the source with hard-wired primes is slower than computing them in the first place, but as far I know Python runs from compiled `.pyc` files so reading a binary array with all primes up to N should be bloody fast in that case.

-

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