1) First, I agree with others that pointed out that this is actually a one dimensional problem: given a set of **segments**, find all the pairs that intersect.

2) Note that you can't guarantee anything better than O(N^2) in the worst case, since the segments may all overlap each other.

3) Assuming that the number of rectangles is big, and that the number of intersections is not always cuadratic in N, I would use the sweep technique:

A) Sort all segment start points and end points in increasing order.

B) Traverse the list, and collect intersections on the way. Each iteration represents a piece of the axis being scanned, where the segments covering it are easily determined.

4) Note that if you only need the **number** of intersections, then you can do it in O(N log N) time.

Here is a generic utility that does the job efficiently. At the bottom you can find a usage example. Remember that this solution is only relevant if you don't expect many intersections. Also, it is an overkill for a small number of segment (I suppose that this is your case - since you are working with N < 100 UI items). However, I wrote it as an exercise and enjoyed it :)

```
import java.util.ArrayList;
import java.util.Collections;
import java.util.HashMap;
import java.util.List;
import java.util.AbstractMap.SimpleEntry;
public class SegmentSet <T> {
private List<Segment> segments = new ArrayList<Segment>();
//note that x2 is inclusive
public void add(int x1, int x2, T identity) {
segments.add(new Segment(x1,x2, identity));
}
public List<SimpleEntry<T, T>> getAllIntersectingPairs() {
// Build a list of all segment edges
ArrayList<Edge> edges = new ArrayList<Edge>(2 * segments.size());
int i=0;
for(Segment seg : segments) {
edges.add(new Edge(EdgeType.START, seg.x1, seg));
edges.add(new Edge(EdgeType.END, seg.x2, seg));
}
// Sort the edges in ascending order
Collections.sort(edges);
// Sweep
ArrayList<SimpleEntry<T, T>> res = new ArrayList<SimpleEntry<T, T>>();
HashMap<Segment, Object> currSegments = new HashMap<Segment, Object>();
for (Edge edge : edges) {
if (edge.type == EdgeType.START) {
for (Segment seg : currSegments.keySet())
res.add(new SimpleEntry<T, T>(edge.seg.identity, seg.identity));
currSegments.put(edge.seg, null);
} else {
currSegments.remove(edge.seg);
}
}
return res;
}
public class Segment {
public final int x1;
public final int x2;
public final T identity;
public Segment(int x1, int x2, T identity) {
this.x1 = x1;
this.x2 = x2;
this.identity = identity;
}
}
private enum EdgeType {START, END};
private class Edge implements Comparable<Edge>{
public final EdgeType type;
public final int x;
public Segment seg;
public Edge(EdgeType type, int x, Segment seg) {
this.type = type;
this.x = x;
this.seg = seg;
}
@Override
public int compareTo(Edge o) {
if (x > o.x)
return 1;
if (x < o.x)
return -1;
// A start Edge will come before an end edge in case of equal X value
return type.ordinal() - o.type.ordinal();
}
}
public static void main(String[] args) {
SegmentSet<String> set = new SegmentSet<String>();
set.add(10,100,"A");
set.add(110,200,"B");
set.add(0,400,"C");
System.out.println(set.getAllIntersectingPairs());
}
}
```