This is an NP-hard problem. In other words, it's not possible to find an optimal solution without exploring all combinations, and the number of combinations is n^M (where M is the size of you array, and n the number of beans). It's a problem very similar to *clustering*, which is also NP-hard.

If your data set is small enough to deal with, a brute force algorithm is best (explore all combinations).

However, if your data set is big, you'll want a polynomial-time algorithm that won't get you the optimal solution, but a good approximation. In that case, I suggest you use something similar to *K-Means*...

Step 1. Calculate the expected sum per bin. Let *A* be your array, then the expected sum per bin is *SumBin = SUM(A) / n* (the sum of all elements in your array over the number of bins).

Step 2. Put all elements of your array in some collection (e.g. another array) that we'll call *The Bag* (this is just a conceptual, so you understand the next steps).

Step 3. Partition *The Bag* into *n* groups (preferably randomly, so that each element ends up in some bin *i* with probability 1/*n*). At this point, your bins have all the elements, and *The Bag* is empty.

Step 4. Calculate the sum for each bin. If result is the same as last iteration, **exit**. (this is the *expectation* step of *K-Means*)

Step 5. For each bin *i*, if its sum is greater than *SumBin*, pick the first element greater than *SumBin* and put it back in *The Bag*; if its sum is less than *SumBin*, pick the first element less than *SumBin* and put back in *The Bag*. This is the gradient descent step (aka *maximization* step) of *K-Means*.

Step 6. Go to step 3.

This algorithm is just an approximation, but it's fast and guaranteed to converge.

If you are skeptical about a randomized algorithm like the above, after the first iteration when you are back to step 3, instead of assigning elements randomly, you can do so optimally by running the *Hungarian algorithm*, but I am not sure that will guarantee better over-all results.