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Two sorted arrays of length n are given and the question is to find, in O(n) time, the median of their sum array, which contains all the possible pairwise sums between every element of array A and every element of array B.

For instance: Let A[2,4,6] and B[1,3,5] be the two given arrays. The sum array is [2+1,2+3,2+5,4+1,4+3,4+5,6+1,6+3,6+5]. Find the median of this array in O(n).

Solving the question in O(n^2) is pretty straight-forward but is there any O(n) solution to this problem?

Note: This is an interview question asked to one of my friends and the interviewer was quite sure that it can be solved in O(n) time.

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Do you know if the median of the sum is the sum of the medians ? – GameAlchemist Jun 26 '13 at 9:55
Hey, OP states the sum of arrays more like Cartesian product, the result array contains N*N elements. Be aware. – Mikhail Jun 26 '13 at 10:02
Ugh. It's definitely possible (Mirzaian–Arjomandi 1985), but expecting the O(n) algorithm in an interview is lunacy. – David Eisenstat Jun 26 '13 at 13:01
@user814628 that's O(n^2) not O(n) – aaronman Jun 26 '13 at 22:13
Here is a link to Mirzaian–Arjomandi 1985, as mentioned by David: – simonzack Jun 26 '13 at 22:34

4 Answers 4

The correct O(n) solution is quite complicated, and takes a significant amount of text, code and skill to explain and prove. More precisely, it takes 3 pages to do so convincingly, as can be seen in details here (found by simonzack in the comments).

It is basically a clever divide-and-conquer algorithm that, among other things, takes advantage of the fact that in a sorted n-by-n matrix, one can find in O(n) the amount of elements that are smaller/greater than a given number k. It recursively breaks down the matrix into smaller submatrixes (by taking only the odd rows and columns, resulting in a submatrix that has n/2 colums and n/2 rows) which combined with the step above, results in a complexity of O(n) + O(n/2) + O(n/4)... = O(2*n) = O(n). It is crazy!

I can't explain it better than the paper, which is why I'll explain a simpler, O(n logn) solution instead :).

O(n * logn) solution:

It's an interview! You can't get that O(n) solution in time. So hey, why not provide a solution that, although not optimal, shows you can do better than the other obvious O(n²) candidates?

I'll make use of the O(n) algorithm mentioned above, to find the amount of numbers that are smaller/greater than a given number k in a sorted n-by-n matrix. Keep in mind that we don't need an actual matrix! The Cartesian sum of two arrays of size n, as described by the OP, results in a sorted n-by-n matrix, which we can simulate by considering the elements of the array as follows:

a[3] = {1, 5, 9};
b[3] = {4, 6, 8};
//a + b:
{1+4, 1+6, 1+8,
 5+4, 5+6, 5+8,
 9+4, 9+6, 9+8}

Thus each row contains non-decreasing numbers, and so does each column. Now, pretend you're given a number k. We want to find in O(n) how many of the numbers in this matrix are smaller than k, and how many are greater. Clearly, if both values are less than (n²+1)/2, that means k is our median!

The algorithm is pretty simple:

int smaller_than_k(int k){
    int x = 0, j = n-1;
    for(int i = 0; i < n; ++i){
        while(j >= 0 && k <= a[i]+b[j]){
        x += j+1;
    return x;

This basically counts how many elements fit the condition at each row. Since the rows and columns are already sorted as seen above, this will provide the correct result. And as both i and j iterate at most n times each, the algorithm is O(n) [Note that j does not get reset within the for loop]. The greater_than_k algorithm is similar.

Now, how do we choose k? That is the logn part. Binary Search! As has been mentioned in other answers/comments, the median must be a value contained within this array:

candidates[n] = {a[0]+b[n-1], a[1]+b[n-2],... a[n-1]+b[0]};.

Simply sort this array [also O(n*logn)], and run the binary search on it. Since the array is now in non-decreasing order, it is straight-forward to notice that the amount of numbers smaller than each candidate[i] is also a non-decreasing value (monotonic function), which makes it suitable for the binary search. The largest number k = candidate[i] whose result smaller_than_k(k) returns smaller than (n²+1)/2 is the answer, and is obtained in log(n) iterations:

int b_search(){
    int lo = 0, hi = n, mid, n2 = (n²+1)/2;
    while(hi-lo > 1){
        mid = (hi+lo)/2;
        if(smaller_than_k(candidate[mid]) < n2)
            lo = mid;
            hi = mid;
    return candidate[lo]; // the median
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"And as both i and j iterate at most n times each, the algorithm is O(n)" => Shouldn't it be O(n^2)? – Khanh Nguyen Jun 27 '13 at 2:18
You're right! That's a clever way to count using sortedness. – Khanh Nguyen Jun 27 '13 at 2:51
But there's another problem: if I am right, after getting the candidates sorted, you run smaller_than_k(k) on each candidate, until you find the one. Wouldn't that make it O(n^2) in the worst case? – Khanh Nguyen Jun 27 '13 at 2:53
That's correct. This is a best answer so far. – Khanh Nguyen Jun 27 '13 at 3:10
The median doesn't necessarily lie on the diagonal of the matrix (the given candidates matrix), as @Mikhail wonders. Consider [1,2,3,4] and [10,20,30,40]. candidates is [14,23,32,41] but the median is the average of 24 and 31. – xan Jul 2 '13 at 20:10

Let's say the arrays are A = {A[1] ... A[n]}, and B = {B[1] ... B[n]}, and the pairwise sum array is C = {A[i] + B[j], where 1 <= i <= n, 1 <= j <= n} which has n^2 elements and we need to find its median.

Median of C must be an element of the array D = {A[1] + B[n], A[2] + B[n - 1], ... A[n] + B[1]}: if you fix A[i], and consider all the sums A[i] + B[j], you would see that the only A[i] + B[j = n + 1 - i] (which is one of D) could be the median. That is, it may not be the median, but if it is not, then all other A[i] + B[j] are also not median.

This can be proved by considering all B[j] and count the number of values that are lower and number of values that are greater than A[i] + B[j] (we can do this quite accurately because the two arrays are sorted -- the calculation is a bit messy thought). You'd see that for A[i] + B[n + 1 - j] these two counts are most "balanced".

The problem then reduces to finding median of D, which has only n elements. An algorithm such as Hoare's will work.

UPDATE: this answer is wrong. The real conclusion here is that the median is one of D's element, but then D's median is the not the same as C's median.

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this is what aaronman said, isn't it? i thought there was a counter-example? – andrew cooke Jun 27 '13 at 0:58
if you can't read deleted posts, consider [0 1 1 1 2] and [0 0 0 1 2]. if i've understood you correctly, your "diagonal" is [2 2 1 1 2] and the median of that is 2. but the correct result is 1. – andrew cooke Jun 27 '13 at 1:00
Somone found the solution in the paper, but it would be nice if it could be delivered in code in c++ or java, or at least explained in less mathematical terms than in the paper – aaronman Jun 27 '13 at 1:01
@aaronman You (or I) don't have to delete your answer when it is wrong. There is no rules SO saying that you can't post wrong answer, as long as you invest enought time and effort into it. Just downvote it, leave a note for later viewers. All we are trying to do is contribute a good answer. My answer was wrong, but it is an idea. By leaving it here, future viewers won't make the same mistake (and hopefully derive an answer by improving it). And, if you haven't deleted your post, I wouldn't have wasted my time on trying the same idea! – Khanh Nguyen Jun 27 '13 at 1:37
If you know the answer is wrong, you should probably delete it. – David Heffernan Jun 27 '13 at 6:06

Doesn't this work?:

You can compute the rank of a number in linear time as long as A and B are sorted. The technique you use for computing the rank can also be used to find all things in A+B that are between some lower bound and some upper bound in time linear the size of the output plus |A|+|B|.

Randomly sample n things from A+B. Take the median, say foo. Compute the rank of foo. With constant probability, foo's rank is within n of the median's rank. Keep doing this (an expected constant number of times) until you have lower and upper bounds on the median that are within 2n of each other. (This whole process takes expected linear time, but it's obviously slow.)

All you have to do now is enumerate everything between the bounds and do a linear-time selection on a linear-sized list.

(Unrelatedly, I wouldn't excuse the interviewer for asking such an obviously crappy interview question. Stuff like this in no way indicates your ability to code.)

EDIT: You can compute the rank of a number x by doing something like this:

Set i = j = 0.
While j < |B| and A[i] + B[j] <= x, j++.
While i < |A| {
  While A[i] + B[j] > x and j >= 0, j--.
  If j < 0, break.
  rank += j+1.

FURTHER EDIT: Actually, the above trick only narrows down the candidate space to about n log(n) members of A+B. Then you have a general selection problem within a universe of size n log(n); you can do basically the same trick one more time and find a range of size proportional to sqrt(n) log(n) where you do selection.

Here's why: If you sample k things from an n-set and take the median, then the sample median's order is between the (1/2 - sqrt(log(n) / k))th and the (1/2 + sqrt(log(n) / k))th elements with at least constant probability. When n = |A+B|, we'll want to take k = sqrt(n) and we get a range of about sqrt(n log n) elements --- that's about |A| log |A|. But then you do it again and you get a range on the order of sqrt(n) polylog(n).

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So the rank takes higher than linear (nested for loop) solution is not linear – aaronman Jun 27 '13 at 1:33
Anything that says "randomly" usually has worst case complexity infinity. – aschepler Jun 27 '13 at 1:43
No, the rank computation is obviously linear. And this is called a "Las Vegas" algorithm; it always returns the correct answer and its expected runtime is nice. – tmyklebu Jun 27 '13 at 2:26
All you have to do now is enumerate everything between the bounds and do a linear-time selection on a linear-sized list. How exactly do you plan on computing this list? Keep in mind the numbers do not need to be small, your list of 2n numbers could have a lower bound of 10^7 and higher bound of 10^9 and you need to figure out what are those 2n numbers in it. Other than that, your solution is kind of similar to mine, except I use a binary search instead of a random algorithm. – i Code 4 Food Jun 27 '13 at 4:15
@Arthur: You compute that list just like you compute the ranks. Find lower and upper bounds on j for each i so that everything within the range lies between the bounds. Then you can enumerate those few elements of A+B that matter. Random sampling tricks like this are usually the key to defeating binary search. (As a bonus, it often runs faster in practice. I wasn't convinced of its practical use either until I saw someone actually use a trick like this.) – tmyklebu Jun 27 '13 at 5:11

You should use a selection algorithm to find the median of an unsorted list in O(n). Look at this:

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