I have an integer array with some finite number of values. My job is to find the minimum difference between any two elements in the array.

Consider that the array contains

4, 9, 1, 32, 13

Here the difference is minimum between 4 and 1 and so answer is 3.

What should be the algorithm to approach this problem. Also, I don't know why but I feel that using trees, this problem can be solved relatively easier. Can that be done?


The minimum difference will be one of the differences from among the consecutive pairs in sorted order. Sort the array, and go through the pairs of adjacent numbers looking for the smallest difference:

int[] a = new int[] {4, 9, 1, 32, 13};
int minDiff = a[1]-a[0];
for (int i = 2 ; i != a.length ; i++) {
    minDiff = Math.min(minDiff, a[i]-a[i-1]);

This prints 3.

  • Okay.. I get what you are saying. But sorting itself will take O(n.log n) time. I'm just curious, but can we do without sorting !! – OneMoreError Sep 2 '12 at 2:20
  • 3
    @CSSS if you do a radix sort it is O(n) – oldrinb Sep 2 '12 at 2:23
  • @CSSS I don't think you can do it faster than O(N*LogN). You have to go through elements of the array at least once, and for each element you'll need to find its best "counterpart" for subtraction. The best you can do there is Log(N) if you use a tree. – dasblinkenlight Sep 2 '12 at 2:24
  • 5
    @CSSS Walk the array, and build a binary search tree from its elements. Every time you add a node to your BST, check the difference between the newly added element and each of the nodes that you walk while finding the place of the new element in the tree. The counterpart with the smallest difference will be among one of these nodes. Inserting a node in a tree takes Log(N), for a total of O(N*Log(N)). – dasblinkenlight Sep 2 '12 at 2:43
  • 3
    Yea, building a binary search tree is just another flavour of sorting in reality. – Stephen C Sep 2 '12 at 3:58

You can take advantage of the fact that you are considering integers to make a linear algorithm:

  1. First pass: compute the maximum and the minimum
  2. Second pass: allocate a boolean array of length (max - min + 1), false initialized, and change the (value - min)th value to true for every value in the array
  3. Third pass: compute the differences between the indexes of the true valued entries of the boolean array.
  • 4
    This is linear in N, but also gets a linear dependency on max-min which can make it pretty bad. – DarioP Nov 23 '15 at 10:46

While all the answers are correct, I wanted to show the underlying algorithm responsible for n log n run time. The divide and conquer way of finding the minimum distance between the two points or finding the closest points in a 1-D plane.

The general algorithm:

enter image description here

  • Let m = median(S).
  • Divide S into S1, S2 at m.
  • δ1 = Closest-Pair(S1).
  • δ2 = Closest-Pair(S2).
  • δ12 is minimum distance across the cut.
  • Return δ = min(δ1, δ2, δ12).

Here is a sample I created in Javascript:

// Points in 1-D
var points = [4, 9, 1, 32, 13];

var smallestDiff;

function mergeSort(arr) {
  if (arr.length == 1)
    return arr;

  if (arr.length > 1) {
    let breakpoint = Math.ceil((arr.length / 2));
    // Left list starts with 0, breakpoint-1
    let leftList = arr.slice(0, breakpoint);
    // Right list starts with breakpoint, length-1
    let rightList = arr.slice(breakpoint, arr.length);

    // Make a recursive call
    leftList = mergeSort(leftList);
    rightList = mergeSort(rightList);

    var a = merge(leftList, rightList);
    return a;

function merge(leftList, rightList) {
  let result = [];
  while (leftList.length && rightList.length) {
    // Sorting the x coordinates
    if (leftList[0] <= rightList[0]) {
    } else {

  while (leftList.length)

  while (rightList.length)

  let diff;
  if (result.length > 1) {
    diff = result[1] - result[0];
  } else {
    diff = result[0];

  if (smallestDiff) {
    if (diff < smallestDiff)
      smallestDiff = diff;
  } else {
    smallestDiff = diff;
  return result;


console.log(`Smallest difference: ${smallestDiff}`);


I would put them in a heap in O(nlogn) then pop one by one and get the minimum difference between every element that I pop. Finally I would have the minimum difference. However, there might be a better solution.


This is actually a restatement of the closest-pair problem in one-dimension. https://en.wikipedia.org/wiki/Closest_pair_of_points_problem http://www.cs.umd.edu/~samir/grant/cp.pdf

As the Wikipedia article cited below points out, the best decision-tree model of this problem also runs in Ω(nlogn) time.

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