FYI, the new edition of the book has an answer, but it is so vague, I don't know what it would entail.

In any case, I would use divide and conquer + dynamic programming to solve this. Let's define MaxSum(x, y) as the maximum sum of any subarray inside the rectangle bounded by the top-left most corner of the N X N array, with height y and width x. (so the answer to the question would be in MaxSum(n-1, n-1))

```
MaxSum(x, y) is the max between:
1) MaxSum(x, y-1)
2) MaxSum(x-1, y)
3) Array[x, y] (the number in this N X N array for this specific location)
4) MaxEnding(x, y-1) + SUM of all elements from Array[MaxEndingXStart(x, y-1), y] to Array[x, y]
5) MaxEnding(x-1, y) + SUM of all elements from Array[x, MaxEndingYStart(x-1, y)] to Array[x, y]
```

MaxEnding(x, y-1) is the maximum sum of any subarray that INCLUDES the # in Array[x, y-1].
Likewise, MaxEnding(x-1, y) is the maximum sum of any subarray that INCLUDES the # in Array[x-1, y].
MaxEndingXStart(x, y-1) is the STARTING x coordinate of the subarray that has the maximum sum of any subarray that INCLUDEs the # in Array[x, y-1].
MaxEndingYStart (x-1, y) is the STARTING y coordinate of the subarray that has the maximum sum of any subarray that INCLUDES the # in Array[x-1, y].

The 2 sum's in #4 and #5 below can be computed easily by keeping the sum of all elements encountered in a specific row, as you go through each column, then subtracting 2 sums to get the sum for a specific section.

To implement this, you would need to do a bottom-up approach, since you need to compute Max(x, y-1), Max(x-1, y), MaxEnding(x, y-1), and MaxEnding(x-1, y).. so you can do lookups when you compute MaxEnding(x, y).

```
//first do some preprocessing and store Max(0, i) for all i from 0 to n-1.
//and store Max(i, 0) for all i from 0 to n-1.
for(int i =1; i < n; i++){
for(int j=1; j < n; j++) {
//LOGIC HERE
}
}
```