Ouch. **This algorithm is wrong; there is no proof because it's ***wrong* and therefore it's impossible to prove that it's correct. ;) I'm leaving it here because I'm too attached to delete it entirely, and it's a good demonstration of why you should formally prove algorithms instead of saying "this looks right! There's no possible way this could fail to work!"

I'm giving this solution without proof, for the time being. I have a proof sketch but I'm having trouble proving optimal substructure for this problem. Anyway...

# Problem

Given a square array of numbers, select as many "non-overlapping" numbers as possible so that the sum of the selected numbers is maximised. "Non-overlapping" means that no two numbers can be from the same row or the same column.

# Algorithm

- Let
`A`

be a square array of `n by n`

numbers.
- Let
`Aij`

denote the element of `A`

in the `i`

th row and `j`

th column.
- Let
`S( i1:i2, j1:j2 )`

denote the optimal sum of non-overlapping numbers for a square subarray of `A`

containing the intersection of rows `i1`

to `i2`

and columns `j1`

to `j2`

.

Then the optimal sum of non-overlapping numbers is denoted `S( 1:n , 1:n )`

and is given as follows:

```
S( 1:n , 1:n ) = max { [ S( 2:n , 2:n ) + A11 ]
[ S( 2:n , 1:n-1 ) + A1n ]
[ S( 1:n-1 , 2:n ) + An1 ]
[ S( 1:n-1 , 1:n-1 ) + Ann ] }
(recursively)
Note that S( i:i, j:j ) is simply Aij.
```

That is, the optimal sum for a square array of size `n`

can be determined by separately computing the optimal sum for each of the four sub-arrays of size `n-1`

, and then maximising the sum of the sub-array and the element that was "left out".

```
S for |# # # #|
|# # # #|
|# # # #|
|# # # #|
Is the best of the sums S for:
|# | | #| |# # # | | # # #|
| # # #| |# # # | |# # # | | # # #|
| # # #| |# # # | |# # # | | # # #|
| # # #| |# # # | | #| |# |
```

# Implementation

The recursive algorithm above suggests a recursive solution:

```
def S(A,i1,i2,j1,j2):
if (i1 == i2) and (j1==j2):
return A[i1][j1]
else:
return max ( S( A, i1+1, i2, j1+1, j2) + A[i1][j1] ],
S( A, i1+1, i2, j1, j2-1) + A[i1][j2] ],
S( A, i1, i2-1, j1+1, j2) + A[i2][j1] ],
S( A, i1, i2-1, j1, j2-1) + A[i2][j2] ], )
```

Note that this will make `O(4^n)`

calls to `S()`

!! This is much better than the factorial `O(n!)`

time complexity of the "brute force" solution, but still awful performance.

The important thing to note here is that many of the calls are *repeated with the same parameters*. For example, in solving a 3*3 array, each 2*2 array is solved many times.

This suggests two possible solutions for a speedup:

- Make the recursive function
`S()`

cache results so that it only needs to `S(A,i1,i2,j1,j2)`

once for each `i1,i2,j1,j2`

. This means that `S()`

only needs to calculate `O(n^3)`

results - all other requests will be fufilled from cache. (This is called *memoising*.)
- Instead of starting at the top, with the large
`n*n`

array, and working down through successively smaller subproblems, start at the bottom with the smallest possible subproblems and build **up** to the `n*n`

case. This is called *dynamic programming*. This is also `O(n^3)`

, but it's a much faster `O(n^3)`

because you don't have to hit a cache all the time.

The dynamic programming solution proceeds somewhat like:

- Find optimal solutions to all 1x1 sub-arrays. (Trivial.)
- Find optimal solutions for all 2x2 sub-arrays.
- Find optimal solutions for all 3x3 sub-arrays.
- ...
- Find optimal solutions for all n-1 * n-1 sub-arrays.
- Find optimal solutions for the complete n*n sub-array.

# Notes on this solution:

- No proof yet. I'm working on it.
- You'll note the algorithm above only gives you
`S()`

, the optimal **sum**. It doesn't tell you which numbers actually make up that sum. You get to add in your own method of backtracing your path to the solution.
- The algorithm above doesn't guarantee the property that ties like
`2,2`

vs. `1,3`

will be broken in favour of having all the individual numbers be as large as possible (so that `2,2`

wins.) I believe you can define `max()`

to break ties in favour of the largest numbers possible, and that will do what you want, but I can't prove it.

# General notes:

Dynamic programming is a powerful technique for devising fast algorithms for any problem which exhibits two properties:

*Optimal substructure*: A problem can be broken down into slightly smaller parts, each of which can be used as part of the solution to the original problem.
*Overlapping subproblems* means that there are few actual subproblems to solve, and the solutions to the subproblems are re-used many times.

If the problem has optimal substructure, and the problem breaks down into **slightly** smaller problems - say a problem of size `n`

breaks down into subproblems of size `n-1`

- then the problem can be solved by *dynamic programming*.

If you can split the problem into **much** smaller chunks - say chopping a problem of size `n`

into halves, each of size `n/2`

- that's *divide and conquer*, not dynamic programming. Divide and conquer solutions are generally *very* fast - for example binary search will find an element in a sorted array in `O(log n)`

time.

`O(n^3)`

time, or so. – Li-aung Yip Apr 30 '12 at 5:20`O(n^3)`

time. I have to write it up and formally prove it's correct. It should have significantly better performance than a naive recursive solution... provided I can prove it works. ;) – Li-aung Yip Apr 30 '12 at 16:04