My original approach. This doesn't work in the case where the optimal solution requires overlapping rectangles (e.g. a "+" of 1s on a background of 0s).
- Find the minimum bounding rectangle containing all the 1s.
- Your first rectangle extends from the top-left of this bounding rectangle and your second bounding rectangle extends from the
bottom-right of this bounding rectangle.
- For each row R between the top and bottom of the bounding rectangle, create candidate rectangles extending from the top to R and
from the bottom to R, both the width of the bounding rectangle.
- Reduce both of these candidates so that they are minimum bounding rectangles of the 1s within them. These rectangle pairs all satisfy
Point 1. Keep the minimum one over all R.
- Repeat from Step 2 to cover every pair of corners in the overall bounding rectangle and keep the best solution overall.
After several aborted attempts at an efficient solution, each of which failed in certain cases, I think the only approach that will find the best solution is as follows:
You only need to consider the bounding rectangle of the 1s. The two bounding rectangles will not lie outside this region. Suppose the bounding rectangle goes from row (R1, C1) to (R2, C2).
For S1 in R1 to R2
For S2 in S1 to R2
For D1 in C1 to C2
For D2 in D1 to C2
Reduce the rectangle (S1, C1)-(S2, C2) to be the minimum bounding rectangle of the 1s it contains
Reduce the rectangle (R1, D1)-(R2, D2) to be the minimum bounding rectangle of the 1s it contains that aren't already in the other rectangle. This is a candidate solution.
Reduce the rectangle (R1, D1)-(R2, D2) to be the minimum bounding rectangle of the 1s it contains.
Reduce the rectangle (S1, C1)-(S2, C2) to be the minimum bounding rectangle of the 1s it contains that aren't already in the other rectangle. This is another candidate solution.
Pick the best candidate solution you find.
The best solution won't have overlapping rectangles because such a solution could always be improved by reducing one of the rectangles so it no longer overlaps. Hence we only need to pick one R in Step 3 (instead of independent maximum rows for each rectangle).
- It doesn't matter whether you split by row (R) or by column (C), but there's no need to do both. For speed, you might choose rows when the bounding rectangle is short and fat, and columns when it is tall and thin.
- If you find a candidate solution where neither rectangle contains any zeroes then it must be the best solution and you can stop.