Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free.

I have many (hundreds of thousands, m) sets of doubles d, ~5-10 (n, constant small) long. These doubles are essentially randomly distributed. I need to get the median of each set: because m is very large, we need to calculate the median pretty quickly...these sets are pretty small though, so I think that is going to play a significant role in choosing how to do the median. I know I can use nth_element to get the median in O(n) with the selection algorithm, which I know I'm not going to beat in complexity. However, because of the small constant n, I am probably looking for the method that simply has the smallest overhead.

I have found a bunch of different ways to do the median (below) but am just curios if anyone knows the "correct" method to use here.

Min max heaps (O(n) build time, constant access, probably too much overhead)

This question from 2010 Which may be out of date (new STL/Boost code may already implement this stuff), also focuses more on time complexity than overhead.

share|improve this question
Are they std::sets of doubles? –  BoBTFish Mar 27 '13 at 16:22
"Hundreds of thousands" is not "many" by any reasonable standard these days. If you have a couple hundred thousands of 5-10 tuples of doubles, the algorithm won't matter. A crude Python script iterating over the lines, doing a full sort and printing the middle element should do it in a couple of seconds. –  TC1 Mar 27 '13 at 16:22
Do you know how fast nth_element performs with your setup? How many times faster do you need to be? –  Oliver Charlesworth Mar 27 '13 at 16:32
Well nth_element will probably do the QSort based k-th statistic algorithm underneath. Anything using heaps etc means allocating additional space, which might in and of itself already add more overhead than you can afford. I'd say benchmark nth_element, you won't get much above that. –  TC1 Mar 27 '13 at 16:35
@MadScienceDreams The added info about N(m) being a constant n (you have lottsa-lists, but they're all n elements long; this was not evident in the question as-stated) is important. In that you can choose a potentially unrolled algorithm based on that size. –  WhozCraig Mar 27 '13 at 16:38

2 Answers 2

up vote 1 down vote accepted

This may not scale well to your data sizes, but it's a code snippet I found (can't remember where) and use in my image processing functions to get the median of 9 unsigned char pixels.

// optimised median search on 9 values
#define PIX_SWAP(a, b) { unsigned char uTemp = (a); (a) = (b); (b) = uTemp; }
#define PIX_SORT(a, b) { if ((a) > (b)) PIX_SWAP((a), (b)); }

unsigned char GetMedian9(unsigned char *pNine)
    // nb - this is theoretically the fastest way to get the median of 9 values
    PIX_SORT(pNine[1], pNine[2]); PIX_SORT(pNine[4], pNine[5]); PIX_SORT(pNine[7], pNine[8]); 
    PIX_SORT(pNine[0], pNine[1]); PIX_SORT(pNine[3], pNine[4]); PIX_SORT(pNine[6], pNine[7]); 
    PIX_SORT(pNine[1], pNine[2]); PIX_SORT(pNine[4], pNine[5]); PIX_SORT(pNine[7], pNine[8]); 
    PIX_SORT(pNine[0], pNine[3]); PIX_SORT(pNine[5], pNine[8]); PIX_SORT(pNine[4], pNine[7]); 
    PIX_SORT(pNine[3], pNine[6]); PIX_SORT(pNine[1], pNine[4]); PIX_SORT(pNine[2], pNine[5]); 
    PIX_SORT(pNine[4], pNine[7]); PIX_SORT(pNine[4], pNine[2]); PIX_SORT(pNine[6], pNine[4]); 
    PIX_SORT(pNine[4], pNine[2]); return(pNine[4]);

#undef PIX_SWAP
#undef PIX_SORT

EDIT - Ok, it's also referenced in this answer too

share|improve this answer
Isn't this what nth_element does? –  IdeaHat Mar 27 '13 at 16:31
@MadScienceDreams - if so, then I can't see how you can do better. Might be worth some profiling though. Do you need the exact median? There are some algorithms for giving an approximation that might be faster. –  Roger Rowland Mar 27 '13 at 16:33
Approx may be ok, especially if I have some sense of the probability of correct median...I'll start the search now for "approximate median", but do you have any quick search seeds? –  IdeaHat Mar 27 '13 at 16:42
No, I stumbled across many "approximate median" algorithms but I needed exact. Also found a nice constant-time median filter for images - i.e. independent of window size, but we're off-topic with that. –  Roger Rowland Mar 27 '13 at 16:44

if it is std::set (you didnt answer to BoBTFish) then it is already sorted. Hence, you will get the median by iterating to n/2 which is always better or equal O(n), typically is should be O(ld n). n-th element will not help here.

share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.