Let `array[N]`

an array of `N`

non-negative values. We're trying to recursively partition the array in two (2) subarrays, so that we can achieve the maximum "minimum-sum" of each subarray. The solution is described by the following recursion:

We want to calculate `opt[0][N-1]`

.

Let `c[x][y]`

denote the `sum{array[i]}`

from `x`

up to `y`

(including).
I have managed to unwind the recursion in the following C++ code snippet, using dynamic programming:

```
for ( uint16_t K1 = 0; K1 < N; K1 ++ ) {
for ( uint16_t K2 = 0; K2 < N-K1; K2 ++ ) {
const uint16_t x = K2, y = K2 + K1;
opt[x][y] = 0;
for ( uint16_t w = x; w < y; w ++ ) {
uint32_t left = c[x][w] + opt[x][w];
uint32_t right = c[w+1][y] + opt[w+1][y];
/* Choose minimum between left-right */
uint32_t val = MIN( left, right );
/* Best opt[x][y] ? */
if ( val > opt[x][y] ) {
opt[x][y] = val;
}
}
} /* K2 */
} /* K1 */
```

This technique parses all subarrays, beginning from size `1`

and up to size `N`

. The final solution will thus be stored in `opt[0][N-1]`

.

For example, if `N=6`

, the matrix will be iterated as follows: `(0,0) (1,1) (2,2) (3,3) (4,4) (5,5) (0,1) (1,2) (2,3) (3,4) (4,5) (0,2) (1,3) (2,4) (3,5) (0,3) (1,4) (2,5) (0,4) (1,5) (0,5)`

. The final answer will be in `opt[0][5]`

.

I have tested and verified that the above technique works to unwind the recursion. I am trying to further reduce the complexity, as this will run in O(n^3), if I'm correct. Could this be achieved?

*edit:* I'm also noting the physical meaning of the recursion, as it was asked in the comments. Let `N`

denote `N`

cities across a straight line. We're a landlord who controls these cities; at the **end** of a year, each city `i`

pays an upkeep of `array[i]`

coins as long as it's under our control.

Our cities are under attack by a superior force and defeat is unavoidable. At the beginning of each year, we erect a wall between two adjacent cities `i`

,`i+1`

, `x <= i <= y`

. During each year, the enemy forces will attack either from the west, thus conquering all cities in `[x,i]`

, or will attack from the east, thus conquering all cities in `[i+1,y]`

. The remaining cities will pay us their upkeep at the end of the year. The enemy forces destroy the wall at the end of the year, retreat, and launch a new attack in the following year. The game ends when only 1 city is left standing.

The enemy forces will always attack from the optimal position, in order to reduce our maximum income **over time**. Our strategy is to choose the optimal position of the wall, so as to maximize our total income at the end of the game.

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