Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I have the following problem:
Given that the even numbers greater than 4 can be obtained by addition of 2 prime numbers, I have to write an algorithm which check it. The algorithm should take less time that O(n^2).

For example there is a set of numbers from 6 to n. If we have the number 6 the answer is 6=3+3 and for 22=17+5 and so on.

My first idea:

S - set of n numbers
for i=1 to n {
  //removing odd numbers
   if (S[i]%2!=0)
      continue;

   result = false;
   for j=2 to S[i]-2{
       if (j.isPrime) // prime test can be done in O(log^2(n))
          if ((S[i]-j).isPrime)
               result = true;
               break;
          else
               continue;
   }

   if (result == false)
       break;
}

Since I use 2 for-loops, the total running time of this algorithm should be O(n*n)*O(log^2(n)) = O(n^2*log^2(n)) which is not less than O(n^2). Does anybody have an idea to reduce the running time to get the required time of less than O(n^2)?

share|improve this question

3 Answers 3

If set contains big numbers I've got nothing.

If max(S) < n ^ 2 / log(n) than:

You should preprocess which numbers from interval [1, max(S)] are primes. For preprocessing you can use sieve of Eratosthenes

Then, you are able to check if number is a prime in O(1) and complexity of your solution becomes O(N^2).

share|improve this answer
    
Your idea sounds good, but unfortunately I have to do it in LESS than O(n^2). –  Viv Apr 1 '12 at 16:26
    
I just have idea. There are approx. n / lg (n) prime numbers that are <= n (en.wikipedia.org/wiki/…). If you select random 10 * lg(n) prime numbers, than there is good chance that you select prime number X, that N - X is also a prime. –  Jarosław Gomułka Apr 1 '12 at 19:43

This is Goldbach's conjecture. Primality testing is known to be in P (polynomial time), but the break-even is ridiculously high - in practice, you will not be able to do this in anywhere near O(n^2).

If we assume you only need to deal with relatively small numbers, and can precompute the primes up to a certain limit, you still need to find candidate pairs. The prime counting function gives approximately:
n / ln(n) primes, less than (n). Subtracting the candidate prime (p) from (n) gives an odd number (q). If you can look up the primality of (q) with a complexity of: n.ln(n), or better - i.e., an O(1) lookup table for all odd numbers less than the limit - you can achieve O(n^2) or better.

share|improve this answer

You can run only until square root of N, this sufficient for determine if the number is prime or not.
this will reduce your running time.

also take a look at the following question - Program to find prime numbers

share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

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