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I'm trying a demo problem of Codility, before I take the real test as part of a job application. One of the demos they have is a problem involving counting the number of disk intersections, for an array of disks.

Task description is

Given an array A of N integers, we draw N discs in a 2D plane such that the I-th disc is centered on (0,I) and has a radius of A[I]. We say that the J-th disc and K-th disc intersect if J ≠ K and J-th and K-th discs have at least one common point. Write a function: class Solution { public int number_of_disc_intersections(int[] A); } that, given an array A describing N discs as explained above, returns the number of pairs of intersecting discs.

You can view the test here.

There are somewhat obvious O(n^2) time complexity solutions, but the aim is for O(n*log(n)).

I've come up with this, which works on any examples I've provided, and the simple test case given by codility ( [1, 5, 2, 1, 4, 0] ), but Codility tells me it fails on most others but I can't quite see why.

It should certainly be O(n log n) as adding each of n disks to a TreeSet is log n, and then we walk through each disks, with only the O(1) operation TreeSet.headSet().

import java.util.*;

class Circle implements Comparable<Circle> {
  long edge;
  int index;

  Circle (long e, int i){
    edge = e;
    index = i;
  }

  long getRightAssumingEdgeIsLeft(){
    return (long)(2*index - edge + 1);
  }

  @Override
  public int compareTo(Circle other){
    return Long.valueOf(edge).compareTo(other.edge);
  }
}

class Solution {
  public int number_of_disc_intersections ( int[] A ) {
    int N = A.length;
    if (N<2) return 0;
    int result = 0;

    SortedSet<Circle> leftEdges  = new TreeSet<Circle>();
    for (int i=0; i<N; i++) {
      leftEdges.add( new Circle( (long)(i-A[i]), i ) );
    }
    int counter = 0;
    for (Circle c : leftEdges) {
      long rightEdge = c.getRightAssumingEdgeIsLeft();
      Circle dummyCircle = new Circle (rightEdge, -1);
      SortedSet<Circle> head = leftEdges.headSet(dummyCircle);
      result +=  head.size() - counter;
      if (result > 10000000) return -1;
      counter++;
    }
    return result;
  }
}
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I think this question belongs more to codereview.stackexchange.com –  PhiLho Dec 26 '12 at 15:36

6 Answers 6

up vote 8 down vote accepted

A different algorithm (O(N log N)):

This bad drawing of the scenario:

enter image description here

Can be translated into a list of ranges: (not exactly the same scenario)

Fig. 2 enter image description here

O(N log N): We first sort the markers, taking care that green markers appear before red ones if we want to count tangent discs as overlaps.

O(N): We scan from left to right, with total initially = 0 and overlaps initially = 0. Every time we hit a green marker, total += 1, and at every red marker, total -= 1. Additionally, at each green marker, if total > 0, then overlaps += total.

The black numbers in Fig. 2 are total at each step; orange is overlaps.

Then overlaps should be the answer.

See a crude implementation here: http://ideone.com/ggiRPA

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2  
This is more elegant, and less confusing. And it works! I've put a Java implementation here, for those curious. The only slight adjustments that I increment total after adding it to overlaps ("this new circle overlaps with total existing circles. And now there is a new circle to think about"). And then the if total>0 condition isn't necessary because total can no longer be negative. There is probably a slightly better way to go through the queues than peeking and polling though. –  user1002973 Dec 26 '12 at 17:54
    
@user1002973 See ideone.com/ggiRPA for a simpler implementation. –  irrelephant Dec 26 '12 at 18:16

There is a simpler way...

  1. Create 2 arrays of N elements (leftEdge, rightEdge).
  2. For each element calculate left and right edge (index -/+ value) and set it in arrays.
  3. Sort arrays.
  4. For each element in rightEdge array loop through leftEdge array to find first greater or equal element. Save number of remaining elements and current index. For next element start loop from saved index...

This way we really loop through each sorted array only once, so algorithm's complexity is O(N log N).

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First thing: you defined compareTo() but not equals(). TreeSet JavaDoc says: "the ordering maintained by a set (whether or not an explicit comparator is provided) must be consistent with equals"

Other oddity: I don't understand what is the edge field, nor why you set it to i - A[i].

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I would add I just don't understand your algorithm, actually... –  PhiLho Dec 26 '12 at 15:28
    
The edge thing is a little unclear. That field usually represents the left edge of the disc - it's i-A[i] because i is the centre and A[i] is the radius. Will try implementing equals as well, I hadn't thought of that. I thought TreeSet only used compareTo though, with implementing equals being good practice for making the code future-proof. –  user1002973 Dec 26 '12 at 15:31
    
If the disks have coordinates on (0, i) (traditionally (x, y) coordinates), then they are vertically aligned, so I don't see why you compute a left edge. Even if that's only a vocabulary thing, I don't see how sorting the circles by their edge position solves the intersection problem (it should be solved on sum of radii being less than the distance between the circles). –  PhiLho Dec 26 '12 at 15:36
    
That's true, I suppose I was visualising them as having coordinates (i,0) rather than (0,i). So my leftEdges should really be called bottomEdges. The reason sorting by their edge position could work is that for a given Circle c, it is quick to calculate how many circles have a left edge further left than c's right edge, i.e. are intersecting. –  user1002973 Dec 26 '12 at 15:46

Assume j is always bigger than i, to satisfy that two circles interact, the inequality below should always works:

|R(i) - R(j)| <= j - i <= R(i) + R(j)

That is another way of saying:

abs(A[i] - A[j]) <= j - i <= A[i] + A[j]

I have not tested, but I think it works. Hope it helps.

#include <stdlib.h>

public int number_of_disc_intersections(int[] A){

    int len = A.length;
    int intersections = 0;

    for(int i = 0; i < len - 1; i++){

        if(A[i] <= 0){
            continue;
        }

        for(int j = i + 1; j < len; j++){

            if(A[j] <= 0){
                continue;       
            }

            if(abs((A[i] - A[j]) <= j - i) && (j - i <= A[i] + A[j])){
                intersections ++;
            }
        }
    }

    return intersections;
}
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1  
This has a quadratic runtime. –  mafp Apr 25 '13 at 22:48

I did the same demo in preparation for a programming position. I didn't get the solution developed in time, and got a terrible score as a result (something in the teens). However, intrigued with the question, I went ahead and completed it on my own. Here is my solution:

 ============================================================================
 Name        : cFundementalsTest.c
 Copyright   : Your copyright notice
 Description : Hello World in C, Ansi-style
 ============================================================================
 */

#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <math.h>

int main(void) {

    int N = 5;
    int A[6] = {1, 5, 2, 1, 4, 0 };

        int pos_1, pos_2;
        int total;
        for(pos_1=0;pos_1<=N;pos_1++)
        {
            for(pos_2=pos_1+1;pos_2<=N;pos_2++)
            {
                if(A[pos_1] + A[pos_2] >= abs(pos_1 - pos_2))
                { // they share a common point
                    total++;
                    printf("%d and %d\n",pos_1, pos_2);
                    if(total > 10000000)
                        return(-1);
                }
            }
        }
        printf ("\n\n the total is %d",total);
}

and here is the results which look correct:

0 and 1
0 and 2
0 and 4
1 and 2
1 and 3
1 and 4
1 and 5
2 and 3
2 and 4
3 and 4
4 and 5

 the total is 11
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This method does not require any special classes such as circles or complex containers such as PriorityQueue or TreeSet. Simple integer arrays are all that are needed. It is O(N * logN). The language is Java.

public int numberOfDiscIntersections(int [] A) {
    // 0 <= A.length <= 100,000
    // 0 <= A[i] <= 2147483647
    int [] leftEdge = new int[A.length];
    int [] rightEdge = new int[A.length];

    int maxLength = 100000;
    // maxLength is used to prevent integers > 2147483647
    // and integers < -2147483647
    for (int i = 0; i < A.length; i++) {
        leftEdge[i] = i - A[i];
        rightEdge[i] = i - maxLength + A[i];
    }
    Arrays.sort(leftEdge);
    Arrays.sort(rightEdge);

    int sum = mergeAndCountOverlaps(leftEdge,rightEdge, maxLength);
    return sum;
}

The merge routine is a modified merge from a merge sort. It merges two sorted arrays, keeping the sort order intact and adding in the overlap count functionality. In this case, we do not need to return the merged array, only the overlap count.

private int mergeAndCountOverlaps(int[] leftEdge, int [] rightEdge, int maxLength) {
    int leftIndex = 0;
    int rightIndex = 0;
    int sum = 0;
    int total = 0;
    while ((leftIndex < leftEdge.length) || (rightIndex < rightEdge.length)) {
        if ((leftIndex < leftEdge.length) && (rightIndex < rightEdge.length)) {
            boolean compareLeftEdgeandRightEdge;
            if (leftEdge[leftIndex] < -2147483647 + maxLength) {
                compareLeftEdgeandRightEdge = leftEdge[leftIndex] <= rightEdge[rightIndex] + maxLength;
            } else {
                compareLeftEdgeandRightEdge = leftEdge[leftIndex] - maxLength <= rightEdge[rightIndex];
            }
            if (compareLeftEdgeandRightEdge) {
                // a new left edge
                sum += total;
                if (sum > 10000000) {
                    return -1;
                }
                total++;
                leftIndex++;
            } else {
                // a new right edge
                total--;
                rightIndex++;
            }
        } else if (leftIndex < leftEdge.length) {
            // a new left edge
            sum += total;
            if (sum > 10000000) {
                return -1;
            }
            total++;
            leftIndex++;
        } else if (rightIndex < rightEdge.length) {
            // a new right edge
            total--;
            rightIndex++;
        }
    }
    return sum;
}
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