The pseudo-polytime algorithm for a knapsack can be used for `k=2`

. The best we can do is sum(S)/2. Run the knapsack algorithm

```
for s in S:
for i in 0 to sum(S):
if arr[i] then arr[i+s] = true;
```

then look at sum(S)/2, followed by sum(S)/2 +/- 1, etc.

For 'k>=3' I believe this is NP-complete, like the 3-partition problem.

The simplest way to do it for k>=3 is just to brute force it, here's one way, not sure if it's the fastest or cleanest.

```
import copy
arr = [1,2,3,4]
def t(k,accum,index):
print accum,k
if index == len(arr):
if(k==0):
return copy.deepcopy(accum);
else:
return [];
element = arr[index];
result = []
for set_i in range(len(accum)):
if k>0:
clone_new = copy.deepcopy(accum);
clone_new[set_i].append([element]);
result.extend( t(k-1,clone_new,index+1) );
for elem_i in range(len(accum[set_i])):
clone_new = copy.deepcopy(accum);
clone_new[set_i][elem_i].append(element)
result.extend( t(k,clone_new,index+1) );
return result
print t(3,[[]],0);
```

Simulated annealing might be good, but since the 'neighbors' of a particular solution aren't really clear, a genetic algorithm might be better suited to this. You'd start out by randomly picking a group of subsets and 'mutate' by moving numbers between subsets.

dope. I'll definitely think about it = ) – Phonon Mar 28 '11 at 13:01