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I have tried to give a more precise approximation to Sieve of Eratosthenes.

Elementary operations and weights that I used:

 prime[p]         -> 1 operation
 m = p * p        -> 2 operations
 prime[m] = false -> 1 operation
 m = m + p        -> 2 operations

My proof:

Is my proof correct? I found in the literature that the complexity is O(nlog(log(n))) or O(nlog(log(n))/log(n)).

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After a few logarithm manipulations you will see that O(nloglogn)==O(nloglog(sqrt(n))). –  icepack Mar 26 '13 at 10:42
    
Can you show me? I can't see it right now. –  flatronka Mar 26 '13 at 10:51
    
Besides that, your proof seems incorrect: 1. Your internal loop will be executed only if index of outer loop is marked as prime - you disregard this fact. 2. I don't see any relation between your (1) and (4),(5). The sum split should look completely different –  icepack Mar 26 '13 at 10:53
    
Thanks for your answer, I think that this is not true O(nloglogn)==O(nloglog(sqrt(n))). 1. Yeah you are all right but I compute an upper bound so that is doesn't matter so much. 2. the n is constant so \sum\frac{n}{p} => n\sum\frac{1}{p}, -\sum\frac{p^2}{p} = -\sump –  flatronka Mar 26 '13 at 11:05
    
Agree about the sum split. Please explain how did you get to the result in (4). –  icepack Mar 26 '13 at 11:12

1 Answer 1

up vote 1 down vote accepted

Yes, that's correct, O(nloglogn)==O(nloglog(sqrt(n))):

enter image description here

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thank you for your time and help :D, this is the perfect answer what I expected :D. –  flatronka Mar 26 '13 at 14:56

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