# Given a sorted array, find the maximum subarray of repeated values

Yet another interview question asked me to find the maximum possible subarray of repeated values given a sorted array in shortest computational time possible.

``````Let input array be A[1 ... n]
Find an array B of consecutive integers in A such that:
for x in range(len(B)-1):
B[x] == B[x+1]
``````

I believe that the best algorithm is dividing the array in half and going from the middle outwards and comparing from the middle the integers with one another and finding the longest strain of the same integers from the middle. Then I would call the method recursively by dividing the array in half and calling the method on the two halves.

My interviewer said my algorithm is good but my analysis that the algorithm is O(logn) is incorrect but never got around to telling me what the correct answer is. My first question is what is the Big-O analysis of this algorithm? (Show as much work as possible please! Big-O is not my forte.) And my second question is purely for my curiosity whether there is an even more time efficient algorithm?

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I'm quite confused by your question. Could you describe in more detail what the interviewer meant? (What's “strain”?) And could you also describe your solution in more detail? (Possibly using pseudocode.) –  svick Sep 15 '12 at 13:54
Undated with more detail. I used divide and conquer basically. –  user1246462 Sep 15 '12 at 14:00
Please revise your title so it will be more useful to future users of this site. –  Raymond Chen Sep 15 '12 at 14:00
Yes exactly, thank you. My memory of the exact wording is fuzzy. –  user1246462 Sep 15 '12 at 14:01

The best you can do for this problem is an `O(n)` solution, so your algorithm cannot possibly be both correct and `O(lg n)`.

Consider for example, the case where the array contains no repeated elements. To determine this, one needs to examine every element, and examining every element is `O(n)`.

This is a simple algorithm that will find the longest subsequence of a repeated element:

``````start = end = 0
maxLength = 0
i = 0
while i + maxLength < a.length:
if a[i] == a[i + maxLength]:
while i + maxLength < a.length and a[i] == a[i + maxLength]:
maxLength += 1
start = i
end = i + maxLength
i += maxLength

return a[start:end]
``````

If you have reason to believe the subsequence will be long, you can set the initial value of `maxLength` to some heuristically selected value to speed things along, and then only look for shorter sequences if you don't find one (i.e. you end up with `end == 0` after the first pass.)

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There should be a tighter bound than O(n). The OP's algo sounds much more efficient than scanning the array from the first to last element –  Jeow Li Huan Sep 15 '12 at 14:09
We are talking about worst-case complexity here. In the worst case (i.e. every element is unique) you must examine every element = `O(n)`. –  verdesmarald Sep 15 '12 at 14:11
You forgot to say what is the time complexity of your solution. –  svick Sep 15 '12 at 16:29
@svick It's `O(n)`. In the worst case `maxLength` is `1` and `i += maxLength` just becomes `i += 1`. –  verdesmarald Sep 15 '12 at 19:38

Assuming that the longest consecutive integers is only of length 1, you'll be scanning through the entire array A of n items. Thus, the complexity is not in terms of n, but in terms of len(B).

Not sure if the complexity is O(n/len(B)).

Checking the 2 edge case

• When n == len(B), you get instant result (only checking A[0] and A[n-1]
• When n == 1, you get O(n), checking all elements
• When normal case, I'm too lazy to write the algo to analyze...
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I think we all agree that in the worst case scenario, where all of `A` is unique or where all of `A` is the same, you have to examine every element in the array to either determine there are no duplicates or determine all the array contains one number. Like the other posters have said, that's going to be `O(N)`. I'm not sure divide & conquer helps you much with algorithmic complexity on this one, though you may be able to simplify the code a bit by using recursion. Divide & conquer really helps cut down on Big O when you can throw away large portions of the input (e.g. Binary Search), but in the case where you potentially have to examine all the input, it's not going to be much different.

I'm assuming the result here is you're just returning the size of the largest B you've found, though you could easily modify this to return B instead.

So on the algorithm front, given that A is sorted, I'm not sure there's going to be any answer faster/simpler answer than just walking through the array in order. It seems like the simplest answer is to have 2 pointers, one starting at index 0 and one starting at index 1. Compare them and then increment them both; each time they're the same you tick a counter upward to give you the current size of `B` and when they differ you reset that counter to zero. You also keep around a variable for the max size of a B you've found so far and update it every time you find a bigger `B`.

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In this algorithm, `n` elements are visited with a constant number of calculations per each visited element, so the running time is `O(n)`.

Given sorted array `A[1..n]`:

``````max_start = max_end = 1
max_length = 1
start = end = 1
while start < n
while A[start] == A[end] && end < n
end++
if end - start > max_length
max_start = start
max_end = end - 1
max_length = end - start
start = end
``````
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You are better off starting from `end = start + max_length` rather than `end = start + 1`. It's still `O(n)` but it is faster most of the time. –  verdesmarald Sep 15 '12 at 15:12
You are right. The point in this particular algorithm is simplicity so that it will be easier to see how for every element in the array, there are constant extra operations. –  Avi Cohen Sep 15 '12 at 15:25