Let `dp[i, j] = true`

iff we can make sum `j`

using one number from each of the sets `1, 2, ..., i`

.

```
dp[i, 0] = true for all i
for i = 1 to numSets do
for num = 1 to sets[i].Count do
for j = maxSum - sets[i, num] downto -maxSum do
dp[i, j + sets[i, num]] |= dp[i - 1, j]
```

You can use a map to handle negative indexes or add an offset to make them positive. `maxSum`

is the maximum value your sum can take (for example sum of maximums of all sets or sum of absolute values of minimums, whichever is larger). There might be ways to update `maxSum`

as you go as an optimization.

For your example, this will run like so:

```
(-2, -1, 0), (-1,4), (-2, 2, 3), (-3, -2, 4, 6), (-2)
```

Iteration over the first set will give `dp[1, -2] = dp[1, -1] = dp[1, 0] = true`

.

Iteration over the second will give `dp[2, -3] = true (because dp[2, -2 + -1] |= dp[1, -1] = true), dp[2, -2] = true (because dp[2, -1 + -1] |= dp[1, -1] = true`

) etc.

If `dp[numSets, 0] = true`

, there is a solution, which you can reconstruct by keeping tracking of which last number you picked for each `dp[i, j]`

.

The complexity is `O(numSets * K * maxSum)`

, where `K`

is the number of elements of a set. This is pseudopolynomial. It might be fast enough if your values are small. If your values are large but you have few sets with few elements, you are better off bruteforcing it using backtracking.