## Abstract

Either use a sorting algorithm according to smallest X value of the rectangle, or store your rectangles in an R-tree and search it.

## Straight-forward approach (with sorting)

Let us denote `low_x()`

- the smallest (leftmost) X value of a rectangle, and `high_x()`

- the highest (rightmost) X value of a rectangle.

Algorithm:

```
Sort the rectangles according to low_x(). # O(n log n)
For each rectangle in sorted array: # O(n)
Finds its highest X point. # O(1)
Compare it with all rectangles whose low_x() is smaller # O(log n)
than this.high(x)
```

### Complexity analysis

This should work on `O(n log n)`

on uniformly distributed rectangles.

The worst case would be `O(n^2)`

, for example when the rectangles don't overlap but are one above another. In this case, generalize the algorithm to have `low_y()`

and `high_y()`

too.

## Data-structure approach: R-Trees

R-trees (a spatial generalization of B-trees) are one of the best ways to store geospatial data, and can be useful in this problem. Simply store your rectangles in an R-tree, and you can spot intersections with a straightforward `O(n log n)`

complexity. (`n`

searches, `log n`

time for each).