# Array “maximum difference” algorithm that runs in O(n)?

Given an array of N integers, sort the array, and find the 2 consecutive numbers in the sorted array with the maximum difference. Example – on input [1,7,3,2] output 4 (the sorted array is [1,2,3,7], and the maximum difference is 7-3=4).

Algorithm A runs in O(NlogN) time.

I need to find an algorithm identical in function to algorithm A, that runs in O(N) time.

UPDATE:

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And what paths have you explored so far? –  Daniel Fischer Apr 21 '12 at 20:59
You just need to return the maximum difference, right? You don't have to return the sorted array as well? –  Adam Mihalcin Apr 21 '12 at 21:02
Counting and Radix sorts might give you O(n). From there you can easily figure out the max diff using an O(n) algorithm. O(n) + O(n) = O(n). –  OJ. Apr 21 '12 at 21:06
Yes, I only need maximum difference. Integer sizes are not limited, so Counting/Radix this time wont work –  daremy Apr 21 '12 at 21:11

Let the array be X and let n = length(X). Put each element x in bucket number floor((x - min(X)) * (n - 1) / (max(X) - min(X))). The width of each bucket is (max(X) - min(X))/(n - 1) and the maximum adjacent difference is at least that much, so the numbers in question wind up in different buckets. Now all we have to do is consider the pairs where one is the max in bucket i and the other is the min in bucket j where i < j and all buckets k in (i, j) are empty. This is linear time.

Proof that we really need floor: let the function be f(X). If we could compute f(X) in linear time, then surely we could decide in linear time whether

0 < f(X) ≤ (max(X) - min(X))/(length(X) - 1),

i.e., whether the elements of X are evenly spaced and not all identical. Let this predicate be P(X). The support of P has factorial(length(X)) connected components, so the usual Ω(n log n) lower bounds for algebraic models of computation apply.

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1. Find minimum and maximum
2. Pick a random number `k` from the array
3. Sort the algorithm by placing all the values smaller than `k` to the left and larger than `k` to the right.
4. You know the minimum and the maximum of both of the groups, calculate the gape of the left group assuming that the values are on a strait line. Do the same for the right group.
5. Go to 2 with the group that got the bigger gape, you know the min and max of that group. Do this until the selected group got no more than 4 values.
6. You got now a group with only 4 elements, sort and find the solution.

Here is an example of how this algorithm works:

• Input: 9 5 3 4 12 9 31 17
• Pick random number: k = 9
• Sort by smaller and bigger values of k
• 5 3 4 9 9 12 31 17, k is in index 3
• Left group gape = (9 + 3) / (4 - 1) = 4
• Right group gape = (31 + 9) / (5 - 1) = 10
• We pick the right group 9 9 12 31 17
• Pick random number: k = 12
• Sort by smaller and bigger values of k
• 9 9 12 31 17, k is in index 2
• Left group gape = (12 + 9) / (3 - 1) = 11.5
• Right group gape = (31 + 12) / (3 - 1) = 21.5
• The maximum gape in 12 31 17 is 31 - 17 = 14

My algorithm is very similar to Selection Algorithm for finding the k index value of sorted algorithm in linear time.

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Execute a Counting Sort and then scan the result for the largest difference.

Because of the consecutive number requirement, at first glance it seems like any solution will require sorting, and this means at best O(n log n) unless your number range is sufficiently constrained for a Counting Sort. But if it is, you win with O(n).

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As OJ points out, a radix sort should also work. I've always liked radix sort but unfortunately most problems seem to involve character data... –  DigitalRoss Apr 21 '12 at 21:16
Yes, in normal real-life situation it would work, but in this task integer range isn't limited. I suppose it can be done without sorting at all. –  daremy Apr 21 '12 at 21:18
It is always O(n), check my solution. –  Ilya_Gazman May 16 at 6:57