While working on an image processing task I have come across the following problem: There are n points in the unit square with coordinates $x_i$ and $y_i$, each assigned with a positive or negative weight $w_i$. Find a rectangle such that the sum of all weights of those points lying within the rectangle is positive and maximal.

By defining a proper grid, the problem can be rephrased as finding a submatrix in an n-by-n matrix A whose sum of elements is maximal. This is also known as the "maximal subrectangle problem" and has been discussed on SO before. While a brute force approach has a run-time of O(n^5), there is a kind of tricky solution with a run-time of O(n^3). It utilizes a solution for the corresponding one-dimensional problem, called "maximal subarray problem", with an O(n) run-time.

I have implemented both algorithms in R and can solve 100s of points in a few seconds. But with thousands of points it will be much too slow, probably even when outsourcing the loops to some Fortran or C code.

Now look at the matrix A. When assuming (w/o loss of generality) that all points have different x- or y-coordinates, A has a special form: In each row and column of A there is exactly *one* non-zero element. For matrices with this special property I assume there should be an algorithm performing the task in O(n^2) time, or even better.

Here is an example with the optimal rectangle added:

```
set.seed(723)
N <- 50; w <- rnorm(N)
x <- runif(N); y <- runif(N)
clr <- ifelse (w >= 0, "blue", "red")
plot(x, y, pch = 20, col = clr, xlim = c(0, 1), ylim = c(0, 1))
rect(0.075, 0.45, 0.31, 0.95, border="gray")
```

You see that there can be red, ie. negative, points in the optimal rectangle. It also shows that it will not suffice to solve the one-dimensional cases for the x- and y-coordinates.

I will translate the standard solution into Fortran, but I would surely like to have a more efficient algorithm at hand.