# Given a set of n integers, list all possible subsets with sum>=k

Given an unsorted set of integers in the form of array, find all possible subsets whose sum is greater than or equal to a const integer k, eg:- Our set is {1,2,3} and k=2

Possible subsets:-

`````` {2},
{3},
{1,2},
{1,3},
{2,3},
{1,2,3}
``````

I can only think of a naive algorithm which lists all the subsets of set and checks if sum of subset is >=k or not, but its an exponential algorithm and listing all subsets requires O(2^N). Can I use dynamic programming to solve it in polynomial time?

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If you are interested in printing or listing all these subsets then in worst case you may still have `2^N-1` (all apart from empty) subsets that you need to list. You could however count how many there are with dynamic programming in polynomial. –  cyon Aug 6 '13 at 16:38
@cyon, How can we count the number of such subsets using dynamic programming? –  Hidetoshi Aug 6 '13 at 16:48
Finding if there is a subset which sums to `k`, is NP-Hard (Subset Sum Problem) - so, this question as well. And since you want the actual sets, seems to me that brute forcing generating all subsets is the way to go. (might add some optimizations using branch and bound techniques, but that's about it, IMO) –  amit Aug 6 '13 at 16:51
@amit The Subset Sum Problem refers to finding a subset that sums to exactly `k`, not at least `k`. Finding a subset that sums to at least `k` is O(n) (just add up everything and see if the sum is big enough). –  dfan Aug 6 '13 at 17:12
@dfan But the question is about finding ALL subsets which are greater/equal `k`. To do this, you need to find all subsets that sums to `k`. Finding them out, is NP-Hard. –  amit Aug 6 '13 at 17:14

Listing all the subsets is going to be still `O(2^N)` because in the worst case you may still have to list all subsets apart from the empty one.

Dynamic programming can help you count the number of sets that have `sum >= K`

You go bottom-up keeping track of how many subsets summed to some value from range `[1..K]`. An approach like this will be `O(N*K)` which is going to be only feasible for small `K`.

The idea with the dynamic programming solution is best illustrated with an example. Consider this situation. Assume you know that out of all the sets composed of the first `i` elements you know that `t1` sum to `2` and `t2` sum to `3`. Let's say that the next `i+1` element is `4`. Given all the existing sets we can build all the new sets by either appending the element `i+1` or leaving it out. If we leave it out we get `t1` subsets that sum to `2` and `t2` subsets that sum to `3`. If we append it then we obtain `t1` subsets that sum to `6` (2 + 4) and `t2` that sum to `7` (3 + 4). That gives us the numbers of subsets that sum to `(2,3,6,7)` consisting of the first `i+1` elements. We continue until `N`.

In pseudo-code this could look something like this:

``````int DP[N][K];
int set[N];

//go through all elements in the set by index
for i in range[0..N-1]
//count the one element subset consisting only of set[i]
DP[i][set[i]] = 1

if (i == 0) continue;

//case 1. build and count all subsets that don't contain element set[i]
for k in range[1..K-1]
DP[i][k] += DP[i-1][k]

//case 2. build and count subsets that contain element set[i]
for k in range[0..K-1]
if k + set[i] >= K then break inner loop
DP[i][k+set[i]] += DP[i-1][k]

//result is the number of all subsets - number of subsets with sum < K
//the -1 is for the empty subset
return 2^N - sum(DP[N-1][1..K-1]) - 1
``````
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Thanks, that helped :) –  Hidetoshi Aug 8 '13 at 18:01
Can you please tell me how to do this part --> sum(DP[1...K] –  Rasoolll May 27 at 12:12
@Rasoolll What I mean by that is `sum = DP[1] + DP[2] + .. + DP[K]` –  cyon May 27 at 12:41
DP is a two-dimension array, so DP[0] + ... + DP[K] is not true I think –  Rasoolll May 27 at 12:42
@Rasoolll Oh yes, apologies I didn't pay attention. `sum = DP[N-1][1] + DP[N-1][2] + .. + DP[N-1][K-1]`. Because you are trying to find out for sets consisting of up to `N` (`N-1` because indexed from 0) how many sum to either `1,2,3,..K-1`. When you figure out how many, you subtract this from all subsets to get how many there are that sum to `K, K+1`, etc. My mistake for not explaining it well in the code. –  cyon May 27 at 12:50

Can I use dynamic programming to solve it in polynomial time?

No. The problem is even harder than @amit (in the comments) mentions. Finding if there exists a subset that sums to a specific k is the subset-sum problem, which is NP-hard. Instead you are asking for how many solutions are equal to a specific k, which is in the much more difficult class of P#. In addition, your exact problem is slightly more difficult since you want to not only count, but enumerate all the possible subsets for k and targets < k.

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If k is 0, and every element of the set is positive then you have no choice but to output every possible subset, so the lower-bound to this problem is O(2N) -- the time taken to produce the output.

Unless you know something more about the value k that you haven't told us, there's no faster general solution that to just check every subset.

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