# Finding the median of an unsorted array

To find the median of an unsorted array, we can make a min-heap in O(nlogn) time for n elements, and then we can extract one by one n/2 elements to get the median. But this approach would take O(nlogn) time.

Can we do the same by some method in O(n) time? If we can, then please tell or suggest some method.Thanks in advance.

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Keep in mind that if it takes O(nlogn) then you might as well just sort the array and divide the index by 2. –  Zombies Oct 27 '13 at 7:07

You can use the Median of Medians algorithm to find median of an unsorted array in linear time.

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It's approximate but should work fairly well. –  Kevin Kostlan Nov 19 '14 at 16:01

Quickselect works in O(n), this is also used in the partition step of Quicksort.

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I don't think quickselect would necessarily give the median in ONLY ONE run. It depends on your pivot choice. –  Yash Oct 29 '14 at 10:47

You can use the Top K algorithm which run in O(n)

Implementation in python :

``````import random

def partition(L, v):
smaller = []
bigger = []
for val in L:
if val < v: smaller += [val]
if val > v: bigger += [val]
return (smaller, [v], bigger)

def top_k(L, k):
v = L[random.randrange(len(L))]
(left, middle, right) = partition(L, v)
# middle used below (in place of [v]) for clarity
if len(left) == k:   return left
if len(left)+1 == k: return left + middle
return left + middle + top_k(right, k - len(left) - len(middle))

def median(L):
n = len(L)
l = top_k(L, n / 2 + 1)
return max(l)
``````
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It can be done using Quickselect Algorithm in O(n), do refer to Kth order statistics (randomized algorithms).

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As wikipedia says, Median-of-Medians is theoretically o(N), but it is not used in practice because the overhead of finding "good" pivots makes it too slow.
http://en.wikipedia.org/wiki/Selection_algorithm

Here is Java source for a Quickselect algorithm to find the k'th element in an array:

``````/**
* Returns position of k'th largest element of sub-list.
*
* @param list list to search, whose sub-list may be shuffled before
*            returning
* @param lo first element of sub-list in list
* @param hi just after last element of sub-list in list
* @param k
* @return position of k'th largest element of (possibly shuffled) sub-list.
*/
static int select(double[] list, int lo, int hi, int k) {
int n = hi - lo;
if (n < 2)
return lo;

double pivot = list[lo + (k * 7919) % n]; // Pick a random pivot

// Triage list to [<pivot][=pivot][>pivot]
int nLess = 0, nSame = 0, nMore = 0;
int lo3 = lo;
int hi3 = hi;
while (lo3 < hi3) {
double e = list[lo3];
int cmp = compare(e, pivot);
if (cmp < 0) {
nLess++;
lo3++;
} else if (cmp > 0) {
swap(list, lo3, --hi3);
if (nSame > 0)
swap(list, hi3, hi3 + nSame);
nMore++;
} else {
nSame++;
swap(list, lo3, --hi3);
}
}
assert (nSame > 0);
assert (nLess + nSame + nMore == n);
assert (list[lo + nLess] == pivot);
assert (list[hi - nMore - 1] == pivot);
if (k >= n - nMore)
return select(list, hi - nMore, hi, k - nLess - nSame);
else if (k < nLess)
return select(list, lo, lo + nLess, k);
return lo + k;
}
``````

I have not included the source of the compare and swap methods, so it's easy to change the code to work with Object[] instead of double[].

In practice, you can expect the above code to be o(N).

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