# Prime factorization for big numbers

I am trying to find the complexity of a factorization for big numbers. Which is the best algorithm and which is the complexity of finding a number's prime factors? Assume that the length of the number is n.

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The best know algoritm for factoring integer larger than 100 digits is General number field sieve. It's complexity is explained on the page that the link links to.

Wikipedia has a nice article about other algoritms: http://en.wikipedia.org/wiki/Integer_factorization

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One algorithm is to divide `n` to `2, 3, 5, ..., (biggest prime <= [n/2])`. Every time you need to find out weather the `number` you're dividing `n` on is prime or not. The complexity of this is about `[number/2]`. After that you divide `n` on that `number` (if the `number` is prime), while the remainder is `0`.

So the complexity is about `n^2`.

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This is only practical for a relatively small (maybe a machine word) value of (n) - and you need only factor up to the largest prime <= `sqrt(n)`. A 128-bit composite: 231001791278426996257482433637885512171, only (39) decimal digits, has (2) prime factors, both 64-bit. You may need to divide by all primes up to: 15198743082190283416 to find them! –  Brett Hale May 12 '12 at 16:00
The algoritm you mention is called the Sieve of Eratosthenes. It complexity is not n^2. You can read about it here: en.wikipedia.org/wiki/Sieve_of_Eratosthenes –  koenpeters May 12 '12 at 18:47
It's actually `O(n^0.5)` Sorry about being harsh, but your suggestion is impractical and the method is not optimized eithor. You only need to check for prime numbers upto `sqrt(N)` –  st0le May 16 '12 at 5:58