# Finding difference less than the average in an unsorted array?

I need to find 2 elements in an unsorted array such that the difference between them is less than or equal to (Maximum - Minimum)/(number of elements in the array).

In O(n).

I know the max and min values.

Can anyone think of something?

Thank you!

• @Binary Worrier: what diffrence does it make? ;-) Dec 15 '08 at 12:15
• @splattne a lot, but it means at least a retag Dec 15 '08 at 12:16
• @Greg Dean: oh, that is the DIFFRENCE! ;-) Dec 15 '08 at 12:17
• @Splattne: Part of my job is to mentor junior programmers at different levels. Just providing a complete answer does the learner little good. If it's homework, I'll give helpful suggestions on how to solve the problem, without giving a full solution. Also +1 Greg Dean, it should be retagged Dec 15 '08 at 12:22
• So, it's okay to correct the title "diffrence" myself and the other spelling mistakes. No one will understand my "funny" comment then. ;-) Dec 15 '08 at 12:33

Step 1: Use Bucket Sort. Don't sort the individual buckets.

Should be pretty obvious what to do from here, and how to size the buckets.

• This is the correct solution. I'm not sure about "pretty obvious", the one thing to worry about is there are two situations to check: one where one pidgeonhole has more than one pidgeon, and one where all pidgeonholes have exactly 1 pidgeon. Dec 15 '08 at 16:50
• Sid Datta goes into more detail. Dec 15 '08 at 21:56
1. Number of buckets = `2n`.

values in each bucket = `(min + k((max-min)/2n)) <= value < (min + (k+1)((max-min)/2n)).`

0 <= k < 2n

Range of each bucket = `((max-min)/2n)`

2. Assign each element into buckets. Dont sort inside buckets.

3. If any bucket has more than 1 element, the maximum possible difference between them is `((max-min)/2n)` . Hence you have your answer.

4. If any two consecutive buckets have more than zero elements each, maximum difference between them is `((max-min)/2n)*2 = ((max-min)/n)` . Hence you have your answer.

• this works, although you can make do with n buckets, you just have to compare consecutive values. Dec 15 '08 at 21:56
• I think this misses the solution in some cases. What if the n items appear in alternate buckets, so there are never two non-empty buckets in a row, but there's one value near the "top" of bucket j, and another value near the "bottom" of bucket j+2. They're less than (max-min)/n apart. Dec 16 '08 at 19:34
• As Jimmy says, though, in this case the buckets have fully sorted the array, meaning that you can finish with an O(n) pass to either find a solution or prove there isn't one. Dec 16 '08 at 19:35

The correct question should be: in an array A=[a0,a2,..an] find two elements a, b such that the difference between them is less than or equal to: (M-m)/n > | a - b| where M=max(A) and m = min(A).

The solution I’ll suggest is using quickSelect, time complexity of O(n) in expectation. it’s actual worst case is O(n^2). This is a tradeoff because most times it's O(n), but it demand O(1) space complexity (if quickSelect is implemented iteratively and my pseudo code is implemented with a while loop instead of recursion).

main idea: At each iteration we find the median using quickSelect, if `|max - medianValue | > |min - medianValue |` we know that we should search to the left side of the array. That is because we have the same amount of elements at both side, but the median value is closer to the minimum thus there should be elements with smaller difference between them. Else we should search at the right side.

each time we do that we know the new maximum or minimum of the subArray should be the median. we continue the search, each time dividing the array’s size by 2.

proof of runtime in expectation: assume each iteration over n elements take c*n + d in expectation. thus we have:

(cn + d) + 0.5(cn + d) + 0.25 (c*n + d) + … +(1/log_{2}(n)) (cn + d) <=

<=(1+0.5+0.25+….)d + (c*n + 0.5*cn +….) = (1+0.5+0.25+….)d + cn(1+0.5+0.25+….) =

=2*d +2*c*n

meaning we have O(n) in expectation.

pseudo-code using recursion:

``````run(arr):
M = max(arr)
m = min(arr)
return findPairBelowAverageDiff(arr,0,arr.length,m,M)

findPairBelowAverageDiff(arr, start, end,  min,  max) :
if start + 1 < end:
medianPos = start + (end - start) / 2
// median that is between start and end in the arr.
quickSelect(arr,  start,  medianPos,  end)
if max - arr[medianPos] > arr[medianPos] - min:
return findPairBelowAverageDiff(arr, start, medianPos,
min, arr[medianPos])
else :
return findPairBelowAverageDiff(arr, medianPos,
end, arr[medianPos], max);
else :
return (arr[start],  arr[start + 1])
``````