As you probably know, the `SUBSET-SUM`

problem is defined as determining if a subset of a set of whole numbers sum to a specified whole number. (there is another definition of subset-sum, where a group of integers sum to zero, but let's use this definition for now)

For example `((1,2,4,5),6)`

is `true`

because `(2,4)`

sums to `6`

. We say that `(2,4)`

is a `"solution"`

Furthermore, `((1,5,10),7)`

is `false`

because nothing in the arguments sum to `7`

My question is, given a set of argument numbers for `SUBSET-SUM`

is there a polynomial upper bound on the number of possible solutions. In the first example there was `(2,4)`

and `(1,5)`

.

We know that since `SUBSET-SUM`

is NP-complete deciding in polynomail time probably is impossible. However my question is not related to the decision time, I'm asking strictly about the size of the list of solutions.

Obviously the size of the power set of the argument numbers can be an upper bound on solution list size, however this has exponential growth. My intuition is that there should be a polynomial bound, but I cannot prove this.

**nb** I know this sounds like a homework question, but please trust me it isn't. I am trying to teach myself certain aspects of CS theory and this is where my thoughts have taken me.

`((2 2 2 2 2 2 2 2 2 2) 10)`

. Here, there's 252 combinations of 5 2's you can choose to get 10. If you count answers with the same numbers but different indices as the same, then there's only one solution in this case. Would you count the above as 252 solutions or just 1? – Joey Adams Jan 3 '10 at 5:29