I am given the set {1, 2, 3, ... ,N}. I have to find the maximum size of a subset of the given set so that the sum of any 2 numbers from the subset is not divisible by a given number K. N and K can be up to 2*10^9 so i need a very fast algorithm. I only came up with an algorithm of complexity O(K), which is slow.

first calculate all of the set elements mod k.and solve simple problem: find the maximum size of a subset of the given set so that the sum of any 2 numbers from the subset is not equal by a given number K. i divide this set to two sets (i and ki) that you can not choose set(i) and set(ki) Simultaneously.
choose
finally you can add one element from that the element mod k equal 0 or k/2. this solution with an algorithm of complexity O(K). you can improve this idea with dynamic array:
now you can choose with an algorithm of complexity O(myset.count).and your algorithm is more than O(myset.count) because you need O(myset.count) for read your set. complexity of this solution is O(myset.count^2),that you can choose algorithm depended your input.with compare between O(myset.count^2) and o(k). and for better solution you can sort myset based on mod k. 


I'm assuming that the set of numbers is always 1 through N for some N. Consider the first N(N mod K) numbers. The form floor(N/K) sequences of K consecutive numbers, with reductions mod K from 0 through K1. For each group, floor(K/2) have to be dropped for having a reduction mod K that is the negation mod K of another subset of floor(K/2). You can keep ceiling(K/2) from each set of K consecutive numbers. Now consider the remaining N mod K numbers. They have reductions mod K starting at 1. I have not worked out the exact limits, but if N mod K is less than about K/2 you will be able to keep all of them. If not, you will be able to keep about the first ceiling(K/2) of them. ========================================================================== I believe the concept here is correct, but I have not yet worked out all the details. ========================================================================== Here is my analysis of the problem and answer. In what follows x is floor(x). This solution is similar to the one in @Constantine's answer, but differs in a few cases. Consider the first K*N/K elements. They consist of N/K repeats of the reductions modulo K. In general, we can include N/K elements that are k modulo K subject to the following limits: If (k+k)%K is zero, we can include only one element that is k modulo K. That is the case for k=0 and k=(K/2)%K, which can only happen for even K. That means we get N/K * (K1)/2 elements from the repeats. We need to correct for the omitted elements. If N >= K we need to add 1 for the 0 mod K elements. If K is even and N>=K/2 we also need to add 1 for the (K/2)%K elements. Finally, if M(N)!=0 we need to add a partial or complete copy of the repeat elements, min(N%K,(K1)/2). The final formula is:
This differs from @Constantine's version in some cases involving even K. For example, consider N=4, K=6. The correct answer is 3, the size of the set {1, 2, 3}. @Constantine's formula gives (61)/2 = 5/2 = 2. The formula above gets 0 for each of the first two lines, 1 from the third line, and 2 from the final line, giving the correct answer. 


formula is
where a/b for example 9/2 = 4 7/2 = 3 example n = 30 , k =7 ; 1 2 3 4 5 6 7 1 2 3 4 5 6 7.  is first line . 8 9 10 11 12 13 14  second line if we getting first 3 number in each line we may get size of this subset. also we may adding one number from ( 7 14 28) getting first 3 number (1 2 3) is a number (k1)/2 . a number of this line is n/k . if there is not residue we may add one number (for example last number). if residue < (k1)/2 we get all number in last line else getting (K1)/2. thanks for exception case. ost = 0 if k>n 

