What is the fastest algorithm to find an element with highest frequency in an array

I have two input arrays X and Y. I want to return that element of array X which occurs with highest frequency in array Y.

The naive way of doing this requires that for each element x of array X, I linearly search array Y for its number of occurrences and then return that element x which has highest frequency. Here is the pseudo algorithm:

`````` max_frequency = 0
max_x = -1             // -1 indicates no element found
For each x in X
frequency = 0
For each y in Y
if y == x
frequency++
End For
If frequency > max_frequency
max_frequency = frequency
max_x = x
End If
End For
return max_x
``````

As there are two nested loops, time complexity for this algorithm would be O(n^2). Can I do this in O(nlogn) or faster ?

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When discussing a problem with two or more dimensions, it's usually a good idea to discuss complexity using a variable for each. Since `X < Y`, we can take `Y = N` and get a quadratic complexity. Practically speaking, `O(X * Y)` is a better statement of how much work is actually happening. – phs Mar 23 '13 at 22:41

Use a hash table mapping keys to counts. For each element in the array, do like `counts[element] = counts[element] + 1` or your language's equivalent.

At the end, loop through the mappings in the hash table and find the max.

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For clarity, that time complexity is `O(X + Y)`, and is the best presented here. – phs Mar 23 '13 at 22:39

Alternatively, if you can have additional data structures, you walk the array Y, for each number updating its frequency in a hash table. This takes `O(N(Y)` time. Then walk X finding which element in X has highest frequency. This takes `O(N(X))` time. Overall: linear time, and since you have to look at each element of both `X` and `Y` in any implementation at least once (EDIT: This is not strictly speaking true in all cases/all implementations, as jwpat7 points out, though it true in the worst case), you can't do it any faster than that.

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It isn't true that you have to look at each element of both X and Y in any implementation at least once. For example, suppose we count occurrences for each value in Y. If f is the most-frequent element in Y and we encounter f while scanning through X, we need not look at the rest of X. Or, if some element X0 of X occurs k times, as soon as the size of Y minus the sum of frequencies of elements of X scanned so far falls below k, we need not consider any further elements of X. – jwpat7 Mar 23 '13 at 21:51
@jwpat7: You are right, and I stand corrected. I was thinking about an average/worst case. Now that you bring it up, there are other border cases as well, such as when `X` contains one element, or if you look through `X` first and then look through Y you can stop looking at `Y[n+1]` if you already know that `Y[n]` is the most frequent element in `Y` and is also in `X.` – angelatlarge Mar 23 '13 at 22:06

The time complexity of common algorithms are listed below:

``````Algorithm     |   Best    |   Worst   |  Average
--------------+-----------+-----------+----------
MergeSort     | O(n lg n) | O(n lg n) | O(n lg n)
InsertionSort |   O(n)    |  O(n^2)   |  O(n^2)
QuickSort     | O(n lg n) |  O(n^2)   | O(n lg n)
HeapSort      | O(n lg n) | O(n lg n) | O(n lg n)
BinarySearch  |   O(1)    |  O(lg n)  |  O(lg n)
``````

In general, when traversing through a list to fulfill a certain criteria, you really can't do any better than linear time. If you are required to sort the array, I would say stick with Mergesort (very dependable) to find the element with highest frequency in an array.

Note: This is under the assumption that you want to use a sorting algorithm. Otherwise, if you are allowed to use any data structure, I would go with a hashmap/hashtable type structure with constant lookup time. That way, you just match keys and update the frequency key-value pair. Hope this helps.

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Traversing a list is typically done in linear time. Unless you have some real need to sort, many many cases can be handled in O(N). – cHao Mar 23 '13 at 21:20
@cHao Agreed. Depends on question requirements. – David Mar 23 '13 at 21:23
what binary search does has to do to this table? – SomeWittyUsername Mar 23 '13 at 21:29
I donot want to use hashtable or any linked list based structures. Static arrays or dynamic arrays are the data structures I prefer to use. – nurabha Mar 23 '13 at 21:36
@nurabha Your best bet is to use a sorting algorithm then with nlogn time complexity. – David Mar 23 '13 at 21:37

1st step: Sort both X and Y. Assuming their corresponding lengths are m and n, complexity of this step will be `O(n log n) + O(m log m)`.

2nd step: count each Xi in Y and track maximum count so far. Search of Xi in sorted Y is `O(log n)`. Total 2nd step complexity is: `O(m log n)`

Total complexity: `O(n log n) + O(m log m) + O(m log n)`, or simpified: `O(max(n,m) log n)`

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Merge Sorting Based on Divide and Conquer Concept gives you O(nlogn) complexity

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Your suggested approach will be O(n^2) if both lists are length n. What's more likely is that the lists can be different lengths, so the time complexity could be expressed as O(mn).

You can separate your problem into two phases: 1. Order the unique elements from Y by their frequency 2. Find the first item from this list that exists in X

As this sounds like a homework question I'll let you think about how fast you can make these individual steps. The sum of these costs will give you the overall cost of the algorithm. There are many approaches that will be cheaper than the product of the two list lengths that you currently have.

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Sort X and Y. Then do merge sort. Count the frequencies from Y every time it encounters with same element in X.

So complexity, O(nlogn) + O(mlogm) + O(m+n) = O(klogk) where n,m = length of X, Y; k = max(m,n)

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Could do a quicksort and then traverse it with a variable that counts how many of a number are in a row + what that number is. That should give you nlogn

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