how to solve this problem:
We are given N pairs of integers. For each pair of integers, we have to assign one integer to A and the other to B, such that the difference between the sum of integers assigned to A and the sum of integers assigned to B is minimum.
I can't think of anything better than O(2^N).
I thought of greedy but it doesn't always give the optimal result.



Transform the problem into this: Given: a sequence of nonnegative integers (the absolute difference between the original pairs) This is the Balanced Partition Problem which is NPcomplete. The two problems are equivalent; that is, you can transform the Balanced Partition Problem into your problem: associate, for each element n_{i} of the sequence, the integer pair (n_{i}, 0). Thus, you aren't going to do better than O(2^{N}).
I suspect^{*} that if you first sort the sequence in descending order, then a greedy algorithm will give optimal results. This will be an O(N log N) algorithm.



Let the pairs be (A_0,B_0),...,(A_n,B_n). Let D_i = A_iB_i. Then your problem is equivalent to choosing signs for the D_i to minimize the sum, which is equivalent to finding a subset of the D_i which sum to half the total sum, which is equivalent to subsetsum, which is NPcomplete. So you won't do better than 2^n. Except: if the numbers are small, you can try a dynamic programming approach: DP[i][n] is true iff you can choose a subset summing to n using D_0,..,D_i. You start with DP[0][0] being true, and then DP[i+1][n] is true iff DP[i][n] was true or DP[i][nD[i+1]] is true. This solution is O(n*(the maximum possible sum)) 

