# What is the right approach when using STL container for median calculation?

Let's say I need to retrieve the median from a sequence of 1000000 random numeric values.

If using anything but `std::list`, I have no (built-in) way to sort sequence for median calculation.

If using `std::list`, I can't randomly access values to retrieve middle (median) of sorted sequence.

Is it better to implement sorting myself and go with e.g. `std::vector`, or is it better to use `std::list` and use `std::list::iterator` to for-loop-walk to the median value? The latter seems less overheadish, but also feels more ugly..

Or are there more and better alternatives for me?

Any random-access container (like `std::vector`) can be sorted with the standard `std::sort` algorithm, available in the `<algorithm>` header.

For finding the median, it would be quicker to use `std::nth_element`; this does enough of a sort to put one chosen element in the correct position, but doesn't completely sort the container. So you could find the median like this:

``````int median(vector<int> &v)
{
size_t n = v.size() / 2;
nth_element(v.begin(), v.begin()+n, v.end());
return v[n];
}
``````
• Huh. I didn't realize that `nth_element` existed, I apparently re-implemented it in my answer... Commented Nov 12, 2009 at 3:10
• It should be noted that `nth_element` modifies the vector in unpredictable ways! You might want to sort a vector of indexes if necessary. Commented Nov 12, 2009 at 13:27
• If the number of items is even, the median is the average of the middle two. Commented Jul 2, 2010 at 1:12
• @sje397 true, this algorithm is incorrect half of the times, namely when the vector contains an even number of elements. Is calling the nth_element function 2 times (for the 2 middle elements) costlier than calling sort once? Thanks. Commented Jan 21, 2015 at 14:06
• @sje397 according to this definition mathworld.wolfram.com/StatisticalMedian.html of median it's true that this current answer is wrong when the vector size is even... but just for fun consider what it is written in Numerical Recipes: When N is even, statistics books define the median as the arithmetic mean of the elements k = N/2 and k = N/2 + 1 (that is, N/2 from the bottom and N/2 from the top). If you accept such pedantry, you must perform two separate selections to find these elements. For N > 100 we usually define k = N/2 to be the median element, pedants be damned. Commented Aug 5, 2020 at 8:23

The median is more complex than Mike Seymour's answer. The median differs depending on whether there are an even or an odd number of items in the sample. If there are an even number of items, the median is the average of the middle two items. This means that the median of a list of integers can be a fraction. Finally, the median of an empty list is undefined. Here is code that passes my basic test cases:

``````///Represents the exception for taking the median of an empty list
class median_of_empty_list_exception:public std::exception{
virtual const char* what() const throw() {
return "Attempt to take the median of an empty list of numbers.  "
"The median of an empty list is undefined.";
}
};

///Return the median of a sequence of numbers defined by the random
///access iterators begin and end.  The sequence must not be empty
///(median is undefined for an empty set).
///
///The numbers must be convertible to double.
template<class RandAccessIter>
double median(RandAccessIter begin, RandAccessIter end)
if(begin == end){ throw median_of_empty_list_exception(); }
std::size_t size = end - begin;
std::size_t middleIdx = size/2;
RandAccessIter target = begin + middleIdx;
std::nth_element(begin, target, end);

if(size % 2 != 0){ //Odd number of elements
return *target;
}else{            //Even number of elements
double a = *target;
RandAccessIter targetNeighbor= target-1;
std::nth_element(begin, targetNeighbor, end);
return (a+*targetNeighbor)/2.0;
}
}
``````
• I know this is from forever ago, but because I just found this on the google: `std::nth_element` actually also guarantees that any preceding elements are <= the target and any following elements are >=. So you could just use `targetNeighbor = std::min_element(begin, target)` and skip the partial sort, which is probably a little bit faster. (`nth_element` is on-average linear, while `min_element` is obviously linear.) And even if you'd rather use `nth_element` again, it'd be equivalent and probably a little faster to just do `nth_element(begin, targetNeighbor, target)`. Commented Feb 8, 2012 at 21:11
• @Dougal I take it you meant `targetNeighbor = std::max_element(begin, target)` in this case?
– izak
Commented May 9, 2013 at 2:41
• @Dougal I know this comment is from forever ago ;), but I have no clue how your approach is supposed to work, are you sure that this gives the correct result? Commented Sep 2, 2016 at 18:42
• @tobi303 Your forever is twice as long as mine. :) And yes, it definitely should: the point is that after calling `std::nth_element`, the sequence is like `[smaller_than_target, target, bigger_than_target]`. So you know that the `target-1`th element is in the first half of the array, and you only need to find the max of the elements before `target` to get the median. Commented Sep 2, 2016 at 18:47
• @AlexisWilke why would these be special cases? If there's 1 element, then `size=1`, `middleIdx=0`, `target=begin`, so `nth_element` is a no-op. If there're 2 elements, `size=2`, `middleIdx=1`, `target=begin+1=end-1`, so the first `nth_element` is called with `(begin, end-1, end)` and the second one with `(begin,begin,end)`. Nowhere does `target` equal `end. Commented May 16, 2019 at 11:16

This algorithm handles both even and odd sized inputs efficiently using the STL nth_element (amortized O(N)) algorithm and the max_element algorithm (O(n)). Note that nth_element has another guaranteed side effect, namely that all of the elements before `n` are all guaranteed to be less than `v[n]`, just not necessarily sorted.

``````//post-condition: After returning, the elements in v may be reordered and the resulting order is implementation defined.
double median(vector<double> &v)
{
if(v.empty()) {
return 0.0;
}
auto n = v.size() / 2;
nth_element(v.begin(), v.begin()+n, v.end());
auto med = v[n];
if(!(v.size() & 1)) { //If the set size is even
auto max_it = max_element(v.begin(), v.begin()+n);
med = (*max_it + med) / 2.0;
}
return med;
}
``````
• I like your answer but returning zero when the vector is empty is not suitable to my application where I would prefer an exception in case of an empty vector. Commented Aug 5, 2020 at 8:18

Here's a more complete version of Mike Seymour's answer:

``````// Could use pass by copy to avoid changing vector
double median(std::vector<int> &v)
{
size_t n = v.size() / 2;
std::nth_element(v.begin(), v.begin()+n, v.end());
int vn = v[n];
if(v.size()%2 == 1)
{
return vn;
}else
{
std::nth_element(v.begin(), v.begin()+n-1, v.end());
return 0.5*(vn+v[n-1]);
}
}
``````

It handles odd- or even-length input.

• For pass by copy, did you mean to remove the reference (`&`) on the input? Commented Jun 17, 2014 at 17:00
• I just meant that comment as a note that one could use pass by copy, in which case yes one should remove the `&`. Commented Jun 17, 2014 at 18:18
• There is a bug in this version. You need to extract `v[n]` before doing nth_element again because after the second round `v[n]` may contain a different value. Commented Dec 5, 2014 at 16:44
• @MatthewFioravante, I see. According to the docs, I guess nth_element does not need to be stable. (edited my answer, accordingly). Commented Dec 11, 2014 at 16:06
• Instead of calling `nth_element` a second time, wouldn't it be much more efficient to just iterate from `v[0]` to `v[n]` and determine the maximum in that half? Commented Oct 23, 2016 at 10:19

putting together all the insights from this thread I ended up having this routine. it works with any stl-container or any class providing input iterators and handles odd- and even-sized containers. It also does its work on a copy of the container, to not modify the original content.

``````template <typename T = double, typename C>
inline const T median(const C &the_container)
{
std::vector<T> tmp_array(std::begin(the_container),
std::end(the_container));
size_t n = tmp_array.size() / 2;
std::nth_element(tmp_array.begin(), tmp_array.begin() + n, tmp_array.end());

if(tmp_array.size() % 2){ return tmp_array[n]; }
else
{
// even sized vector -> average the two middle values
auto max_it = std::max_element(tmp_array.begin(), tmp_array.begin() + n);
return (*max_it + tmp_array[n]) / 2.0;
}
}
``````
• As Matthew Fioravante stackoverflow.com/questions/1719070/… has mentioned, "You need to extract v[n] before doing nth_element again because after the second round v[n] may contain a different value." So, let med = tmp_array[n], then the correct return line is: return (*max_it + med) / 2.0; Commented Jan 19, 2017 at 11:07
• @trig-ger nth_element is only used once in this solution. It is not a problem. Commented Jan 31, 2017 at 18:55
• `static_assert(std::is_same_v<typename C::value_type, T>, "mismatched container and element types")` maybe? Commented May 21, 2021 at 16:17

You can sort an `std::vector` using the library function `std::sort`.

``````std::vector<int> vec;
// ... fill vector with stuff
std::sort(vec.begin(), vec.end());
``````

There exists a linear-time selection algorithm. The below code only works when the container has a random-access iterator, but it can be modified to work without — you'll just have to be a bit more careful to avoid shortcuts like `end - begin` and `iter + n`.

``````#include <algorithm>
#include <cstdlib>
#include <iostream>
#include <sstream>
#include <vector>

template<class A, class C = std::less<typename A::value_type> >
class LinearTimeSelect {
public:
LinearTimeSelect(const A &things) : things(things) {}
typename A::value_type nth(int n) {
return nth(n, things.begin(), things.end());
}
private:
static typename A::value_type nth(int n,
typename A::iterator begin, typename A::iterator end) {
int size = end - begin;
if (size <= 5) {
std::sort(begin, end, C());
return begin[n];
}
typename A::iterator walk(begin), skip(begin);
#ifdef RANDOM // randomized algorithm, average linear-time
typename A::value_type pivot = begin[std::rand() % size];
#else // guaranteed linear-time, but usually slower in practice
while (end - skip >= 5) {
std::sort(skip, skip + 5);
std::iter_swap(walk++, skip + 2);
skip += 5;
}
while (skip != end) std::iter_swap(walk++, skip++);
typename A::value_type pivot = nth((walk - begin) / 2, begin, walk);
#endif
for (walk = skip = begin, size = 0; skip != end; ++skip)
if (C()(*skip, pivot)) std::iter_swap(walk++, skip), ++size;
if (size <= n) return nth(n - size, walk, end);
else return nth(n, begin, walk);
}
A things;
};

int main(int argc, char **argv) {
std::vector<int> seq;
{
int i = 32;
std::istringstream(argc > 1 ? argv[1] : "") >> i;
while (i--) seq.push_back(i);
}
std::random_shuffle(seq.begin(), seq.end());
std::cout << "unordered: ";
for (std::vector<int>::iterator i = seq.begin(); i != seq.end(); ++i)
std::cout << *i << " ";
LinearTimeSelect<std::vector<int> > alg(seq);
std::cout << std::endl << "linear-time medians: "
<< alg.nth((seq.size()-1) / 2) << ", " << alg.nth(seq.size() / 2);
std::sort(seq.begin(), seq.end());
std::cout << std::endl << "medians by sorting: "
<< seq[(seq.size()-1) / 2] << ", " << seq[seq.size() / 2] << std::endl;
return 0;
}
``````

Here is an answer that considers the suggestion by @MatthieuM. ie does not modify the input vector. It uses a single partial sort (on a vector of indices) for both ranges of even and odd cardinality, while empty ranges are handled with exceptions thrown by a vector's `at` method:

``````double median(vector<int> const& v)
{
bool isEven = !(v.size() % 2);
size_t n    = v.size() / 2;

vector<size_t> vi(v.size());
iota(vi.begin(), vi.end(), 0);

partial_sort(begin(vi), vi.begin() + n + 1, end(vi),
[&](size_t lhs, size_t rhs) { return v[lhs] < v[rhs]; });

return isEven ? 0.5 * (v[vi.at(n-1)] + v[vi.at(n)]) : v[vi.at(n)];
}
``````

Demo

Armadillo has an implementation that looks like the one in the answer https://stackoverflow.com/a/34077478 by https://stackoverflow.com/users/2608582/matthew-fioravante

It uses one call to `nth_element` and one call to `max_element` and it is here: https://gitlab.com/conradsnicta/armadillo-code/-/blob/9.900.x/include/armadillo_bits/op_median_meat.hpp#L380

``````//! find the median value of a std::vector (contents is modified)
template<typename eT>
inline
eT
op_median::direct_median(std::vector<eT>& X)
{
arma_extra_debug_sigprint();

const uword n_elem = uword(X.size());
const uword half   = n_elem/2;

typename std::vector<eT>::iterator first    = X.begin();
typename std::vector<eT>::iterator nth      = first + half;
typename std::vector<eT>::iterator pastlast = X.end();

std::nth_element(first, nth, pastlast);

if((n_elem % 2) == 0)  // even number of elements
{
typename std::vector<eT>::iterator start   = X.begin();
typename std::vector<eT>::iterator pastend = start + half;

const eT val1 = (*nth);
const eT val2 = (*(std::max_element(start, pastend)));

return op_mean::robust_mean(val1, val2);
}
else  // odd number of elements
{
return (*nth);
}
}
``````
``````you can use this approch. It also takes care of sliding window.
Here days are no of trailing elements for which we want to find median and this makes sure the original container is not changed

#include<bits/stdc++.h>

using namespace std;

int findMedian(vector<int> arr, vector<int> brr, int d, int i)
{
int x,y;
x= i-d;
y=d;
brr.assign(arr.begin()+x, arr.begin()+x+y);

sort(brr.begin(), brr.end());

if(d%2==0)
{
return((brr[d/2]+brr[d/2 -1]));
}

else
{
return (2*brr[d/2]);
}

// for (int i = 0; i < brr.size(); ++i)
// {
//     cout<<brr[i]<<" ";
// }

return 0;

}

int main()
{
int n;
int days;
int input;
int median;
int count=0;

cin>>n>>days;

vector<int> arr;
vector<int> brr;

for (int i = 0; i < n; ++i)
{
cin>>input;
arr.push_back(input);
}

for (int i = days; i < n; ++i)
{
median=findMedian(arr,brr, days, i);

}

return 0;
}
``````
• Please try to add explanations when you added code snippet Commented Jul 7, 2020 at 5:49