# How to find a number as a sum of prime numbers?

Lets see we want to find all numbers between 1 to 1000 which are represented as a sum of two prime numbers. e.g 8 = 3+5, 24 = 13+11

Now this can be done in O(n^2) by iterating through the list of prime numbers between 1 to 1000.

Is there anyway of doing the same thing in less than O(n^2).Is there a method for doing this in linear time ?

-
"Goldbach's conjecture is one of the oldest and best-known unsolved problems in number theory and in all of mathematics. It states: Every even integer greater than 2 can be expressed as the sum of two primes." : en.wikipedia.org/wiki/Goldbach's_conjecture – Mitch Wheat Feb 6 '13 at 3:20
What if only distinct prime numbers are allowed ?. – user1822249 Feb 6 '13 at 3:33

## 2 Answers

Make an array `p` of 1000 booleans. Set `p[i]` to `true` if `i` is prime, and `false` otherwise.

Then the `O(N^2)` algorithm becomes easy: go through numbers `k` 1 through 1000 in the outer loop, then go through all primes `x` greater than `k` in an inner loop, and check if there exists a prime such that `p[k-x]` is `true`:

``````for k in 1..1000
for x in primes greater than k
if (p[x-k])
print k can be represented as x plus (x-k)
break
``````

I doubt that the check could be performed in constant time for a total running time of `O(N)` for the 1000 numbers, because computer-aided verification currently proceeds at a rather slow speeds.

-

For all the even numbers we know now, they can be represented as the sum of 2 prime numbers(see Goldbach's conjecture)

For all the odd numbers, if it can be represented as the sum of 2 prime numbers, one of the them must be 2, and the other should be an odd prime.

So the total number should be (1000/2 - 1) + (prime number count from 3 to 997),

in which,

(1000/2 - 1) is the total number of series 4, 6, 8, 10...

(prime number count from 3 to 997) is the total number of series 5(2+3), 7(2+5), 9(2+7), 13(2+11) ...

-