The runtime of the described algorithm is `O(n^2)`

. The outer loop is executed `n/2`

times, thus the inner counter `j`

is resetted `n/2`

times, and thus the inner loop is executed total of `O(n^2)`

times.

I am not sure I am following the logic behind your idea, but here are two approaches how I'd implement it [in high level pseudo-code]:

(1) create a histogram out of the data:

- create a
`Map<Integer,Integer>`

[the key is the element and the value is the number of occurances]
- iterate the array, and for each element count how many times it appears
- iterate the histogram and find if there is a unique maxima.
- If there is - return true, else return false.

This approach is average of `O(n)`

if you use a `HashMap`

as the map.

(2) sort and find max occurances:

- Sort the array - as the result, all equal elements are adjacent to each other. You can use
`Arrays.sort(array)`

for sorting.
- Count how many times each element appears [similar to the histogram idea], and find if there is a unique maxima. You don't actually need to maintain the data for
*all* elements, it's enough to maintain for the top 2, and at the end to see if they are identical.

This solution is `O(nlogn)`

average + worst case [actually, depending on the sort - merge sort gives you `O(nlogn)`

worst case, while quick-sort gives you `O(n^2)`

worst case, and both are `O(nlogn)`

on average case].

EDIT:

I misunderstood the problem at hand, I thought you are looking if there is a unique maxima. These 2 solutions still fits for the problem, you just need to modify the last step of each [to check if the most occuring element appears more then half of the times, which is again fairly easy and doable in `O(n)`

].

Also, there is another solution: Use selection algorithm to find the median, and after finding it, check if it is a majority element, and return if it is. Since selection algorithm is divide-and-conquer based solution, I think it fits your needs.