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Why is the first one so much faster than the second? I get that storing the primes as 1s and 0s is simpler, but the speed increase is ridiculous. And at the end, it still goes through a list 2 million items long, how is that even remotely possible in the 1s it takes to compile?

def prime_sieve(limit):
    primes = [1 for x in xrange(limit)]
    primes[0] = 0
    primes[1] = 0
    imax = int(math.sqrt(limit) + 1)

    i = 2
    while (i < imax):
        j = i + i
        while j < limit:
            primes[j] = 0
            j += i
        while True:
            i += 1
            if primes[i] == 1:
    return primes

s = prime_sieve(2000000)
print(sum(i for i in xrange(len(s)) if s[i] == 1))
def sieve(max):
    primes = range(2, max+1)
    for i in primes:
        j = 2
        while i * j <= primes[-1]:
            if i * j in primes:
                j += 1
    return primes

count = 0
for x in sieve(2000000):
    count += x
print count
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This question appears to be off-topic because it belongs on codereview.stackexchange.com –  jonrsharpe Jan 20 '14 at 18:54
Add a print i in both outermost loops and run both functions for some small input, say 100. See what numbers are tested in both functions! –  tobias_k Jan 20 '14 at 18:57
there's an error in the code (except for the obvious wrong indentation inside the function sieve): 6th line from the bottom should be un-indented back at the equal level with the if above it. –  Will Ness Jan 21 '14 at 16:46

1 Answer 1

Because when you remove stuff you can't use direct addressing anymore. Direct addressing is the key to the sieve of Eratosthenes's speed (similar to the integer sorting's speed advantage over the comparison-based sorting).

In your first code, primes[j] = 0 is an O(1) operation. But in the second, primes.remove(i*j) is an O(n) operation (according to this).

You also start enumerating the multiples of i at 2*i instead of i^2. It's much less of a problem though compared with the above.

To properly compare algorithmic speed, always compare empirical orders of growth. Here are the results:

# First code:
# --i+i--                                 # --i*i--
#   N       n    time-space   ~ n^        #    N     n     time-space   ~ n^
#  10k     1229  0.02s-7.9M               #
#  2mln  148933  1.13s-7.9M               #  2mln  148933  1.12s-7.9M  
#  4mln  283146  2.30s-7.9M  n^1.11       #  4mln  283146  2.25s-7.9M  n^1.09
#  8mln  539777  4.58s-7.9M  n^1.07       #  8mln  539777  4.38s-7.9M  n^1.03
# 16mln 1031130  9.12s-7.9M  n^1.06       # 16mln 1031130  8.82s-7.9M  n^1.08

# Second code:
# --j=2--                                 # --j=i--
#   5k      669  0.35s-7.9M               #   5k      669  0.28s-7.9M
#  10k     1229  1.37s-7.9M  n^2.24       #  10k     1229  1.16s-7.9M  n^2.34
#  20k     2262  5.21s-7.9M  n^2.19       #  20k     2262  4.66s-7.9M  n^2.28
#  30k     3245 11.76s-7.9M  n^2.26       #  30k     3245 11.24s-7.9M  n^2.44

N is upper limit, and n - number of primes below it. The exponents are of course approximate, and their deltas are not measured, but they do give us a general picture. A quadratic (or worse) algorithm is surely much different from the linearithmic one.

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