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Note, this is a homework assignment.

I need to find the mode of an array (positive values) and secondarily return that value if the mode is greater that sizeof(array)/2,the dominant value. Some arrays will have neither. That is simple enough, but there is a constraint that the array must NOT be sorted prior to the determination, additionally, the complexity must be on the order of O(nlogn).

Using this second constraint, and the master theorem we can determine that the time complexity 'T(n) = A*T(n/B) + n^D' where A=B and log_B(A)=D for O(nlogn) to be true. Thus, A=B=D=2. This is also convenient since the dominant value must be dominant in the 1st, 2nd, or both halves of an array.

Using 'T(n) = A*T(n/B) + n^D' we know that the search function will call itself twice at each level (A), divide the problem set by 2 at each level (B). I'm stuck figuring out how to make my algorithm take into account the n^2 at each level.

To make some code of this:

int search(a,b) {
    search(a, a+(b-a)/2);
    search(a+(b-a)/2+1, b);

The "glue" I'm missing here is how to combine these divided functions and I think that will implement the n^2 complexity. There is some trick here where the dominant must be the dominant in the 1st or 2nd half or both, not quite sure how that helps me right now with the complexity constraint.

I've written down some examples of small arrays and I've drawn out ways it would divide. I can't seem to go in the correct direction of finding one, single method that will always return the dominant value.

At level 0, the function needs to call itself to search the first half and second half of the array. That needs to recurse, and call itself. Then at each level, it needs to perform n^2 operations. So in an array [2,0,2,0,2] it would split that into a search on [2,0] and a search on [2,0,2] AND perform 25 operations. A search on [2,0] would call a search on [2] and a search on [0] AND perform 4 operations. I'm assuming these would need to be a search of the array space itself. I was planning to use C++ and use something from STL to iterate and count the values. I could create a large array and just update counts by their index.

share|improve this question
do u mean to find a value in the array which occurs most of the time. and if it occurs sizeof(array)/2 or more, return it? – songlj Feb 7 '13 at 5:11
I don't understand what you're searching for or why you would recurse. – Gabe Feb 7 '13 at 5:25
@Gabe, my guess is that he's looking for the mode of the array.... # that occurs most often based on the comment above. divide-and-conquer type recursion makes it faster. – thang Feb 7 '13 at 5:27
@mike_b: you could iterate the array, incrementing a map<Value,Count>, then iterate the map to find the highest count... will be O(nlogn) as that's the cost of map insertion, and the iterations are less than that anyway. – Tony D Feb 7 '13 at 5:32
I think that he's not supposed to use more memory. what you're suggesting (both of you) is basically radix sort first then determine the mode from there. there is a constraint that the array must NOT be sorted prior to the determination. – thang Feb 7 '13 at 5:33

if some number occurs more than half, it can be done by O(n) time complexity and O(1) space complexity as follow:

int num = a[0], occ = 1;
for (int i=1; i<n; i++) {
    if (a[i] == num) occ++;
    else {
        if (occ < 0) {
            num = a[i];
            occ = 1;

since u r not sure whether such number occurs, all u need to do is to apply the above algorithm to get a number first, then iterate the whole array 2nd time to get the occurance of the number and check whether it is greater than half.

share|improve this answer
you're joking right? – thang Feb 7 '13 at 6:33
@thang why u said im joking? is there anything wrong with my code? – songlj Feb 7 '13 at 7:10
the goal was to find a solution with O(nlogn) complexity. this requires recursion with log n steps. – mike_b Feb 7 '13 at 7:21
@songlj I think the algorithm does not work for some cases try for example, 1, 2, 1, 2, 1, 2, 1, 3, 3, 1 . sorry I am adding this as an answer because I cannot comment yet. EDIT: If we know that the mode appears at least N/2 times in the array This is the Boyer-Moore Majority Algorithm. This stackoverflow.com/questions/3740371/… discusses this specific instance of mode finding. – argsv Jul 25 '14 at 20:21

If you want to find just the dominant mode of an array, and do it recursively, here's the pseudo-code:

def DominantMode(array):
    # if there is only one element, that's the dominant mode
    if len(array) == 1: return array[0]
    # otherwise, find the dominant mode of the left and right halves
    left = DominantMode(array[0:len(array)/2])
    right = DominantMode(array[len(array)/2:len(array)])
    # if both sides have the same dominant mode, the whole array has that mode
    if left == right: return left
    # otherwise, we have to scan the whole array to determine which one wins
    leftCount = sum(element == left for element in array)
    rightCount = sum(element == right for element in array)
    if leftCount > len(array) / 2: return left
    if rightCount > len(array) / 2: return right
    # if neither wins, just return None
    return None

The above algorithm is O(nlogn) time but only O(logn) space.

If you want to find the mode of an array (not just the dominant mode), first compute the histogram. You can do this in O(n) time (visiting each element of the array exactly once) by storing the historgram in a hash table that maps the element value to its frequency.

Once the histogram has been computed, you can iterate over it (visiting each element at most once) to find the highest frequency. Once you find a frequency larger than half the size of the array, you can return immediately and ignore the rest of the histogram. Since the size of the histogram can be no larger than the size of the original array, this step is also O(n) time (and O(n) space).

Since both steps are O(n) time, the resulting algorithmic complexity is O(n) time.

share|improve this answer
The goal was O(nlogn) – mike_b Feb 7 '13 at 5:49
@mike_b: Big-O notation just gives an upper bound; all O(n) functions are also O(nlogn). In other words, the algorithm I gave also has O(nlogn) complexity. – Gabe Feb 7 '13 at 5:57
almost. 1. you need to check the case where left==none or right==none 2. you can run this in place, so O(1) in space. – thang Feb 7 '13 at 6:35
@thang: What would I need to do differently if left==None or right==None? And I don't see how you can recurse log(n) deep without using k*log(n) stack space. – Gabe Feb 7 '13 at 6:55
The instructor is implying that we need to do it without a simply linear search. He doesn't wan't something O(n). He wants a recursively called function, similar to merge sort. what you have now is similar to what I've developed. your right side also has overlap it should be len(array)/2+1. Are you counts scoped only to that instance of the function? if so, there are times when that will not work, the count for a value needs to be maintained across recursive calls. – mike_b Feb 7 '13 at 7:29

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