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The std::sort algorithm (and its cousins std::partial_sort and std::nth_element) from the C++ Standard Library is in most implementations a complicated and hybrid amalgation of more elementary sorting algorithms, such as selection sort, instertion sort, quick sort, merge sort, or heap sort.

There are many questions here and on sister sites such as http://codereview.stackexchange.com/ related to bugs, complexity and other aspects of implementations of these classic sorting algorithms. Most of the offered implementations consist of raw loops, use index manipulation and concrete types, and are generally non-trivial to analyze in terms of correctness and efficiency.

Question: how can the above mentioned classic sorting algorithms be implemented using modern C++?

  • no raw loops, but combining the Standard Library's algorithmic building blocks from <algorithm>
  • iterator interface and use of templates instead of index manipulation and concrete types
  • C++14 style, including the full Standard Library, as well as syntactic noise reducers such as auto, template aliases, transparant comparators and polymorphic lambdas.


  • for further references on implementations of sorting algorithms see Wikipedia, Rosetta Code or http://www.sorting-algorithms.com/
  • according to Sean Parent's conventions (slide 39), a raw loop is a for-loop longer than composition of two functions with an operator. So f(g(x)); or f(x); g(x); or f(x) + g(x); are not raw loops, and neither are the loops in selection_sort and insertion_sort below.
  • I follow Scott Meyers's terminology to denote the current C++1y already as C++14, and to denote C++98 and C++03 both as C++98, so don't flame me for that.
  • As suggested in the comments by @Mehrdad, I provide four implementations as a Live Example at the end of the answer: C++14, C++11, C++98 and Boost and C++98.
  • The answer itself is presented in terms of C++14 only. Where relevant, I denote the syntactic and library differences where the various language versions differ.
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It would be great to add the C++Faq tag to the question, though it would require to lose at least one of the others. I would suggest removing the versions (as it is a generic C++ question, with implementations available in most versions with some adaptation). –  Matthieu M. Jul 9 '14 at 12:20
@TemplateRex Well, technically, if it's not FAQ then this question is too broad (guessing - I didn't downvote). Btw. good job, lots of useful information, thanks :) –  BartoszKP Jul 15 '14 at 21:15

1 Answer 1

up vote 258 down vote accepted

Algorithmic building blocks

We begin by assembling the algorithmic building blocks from the Standard Library:

#include <algorithm>    // min_element, iter_swap, 
                        // upper_bound, rotate, 
                        // nth_element, partition, 
                        // inplace_merge,
                        // make_heap, sort_heap, push_heap, pop_heap,
                        // is_heap, is_sorted
#include <cassert>      // assert 
#include <functional>   // less
#include <iterator>     // distance, begin, end, next
  • the iterator tools such as non-member std::begin() / std::end() as well as with std::next() are only available as of C++11 and beyond. For C++98, one needs to write these oneself. There are substitutes from Boost.Range in boost::begin() / boost::end(), and from Boost.Utility in boost::next().
  • the std::is_sorted algorithm is only available for C++11 and beyond. For C++98, this can be implemented in terms of std::adjacent_find and a hand-written function object. Boost.Algorithm also provides a boost::algorithm::is_sorted as a substitute.
  • the std::xxx_heap related algorithms are only available for C++11 and beyond. For C++98, this excludes heap_sort from being written in terms of standard algorithms. Boost.Range provides boost::xxx_heap and boost::make_iterator_range as substitutes.

Syntactical goodies

C++14 provides transparant comparators of the form std::less<> that act polymorphically on their arguments. This avoids having to provide an iterator's type. This can be used in combination with C++11's default function template arguments to create a single overload for sorting algorithms that take < as comparison and those that have a user-defined comparison function object.

template<class It, class Compare = std::less<>>
void xxx_sort(It first, It last, Compare cmp = Compare{});

In C++11, one can define a reusable template alias to extract an iterator's value type which adds minor clutter to the sort algorithms' signatures:

template<class It>
using value_type_t = typename std::iterator_traits<It>::value_type;

template<class It, class Compare = std::less<value_type_t<It>>>
void xxx_sort(It first, It last, Compare cmp = Compare{});

In C++98, one needs to write two overloads and use the verbose typename xxx<yyy>::type syntax

template<class It, class Compare>
void xxx_sort(It first, It last, Compare cmp); // general implementation

template<class It>
void xxx_sort(It first, It last)
    xxx_sort(first, last, std::less<typename std::iterator_traits<It>::value_type>());
  • Another syntactical nicety is that C++14 facilitates wrapping user-defined comparators through polymorphic lambdas (with auto parameters that are deduced like function template arguments).
  • C++11 only has monomorphic lambdas, that require the use of the above template alias value_type_t.
  • In C++98, one either needs to write a standalone function object or resort to the verbose std::bind1st / std::bind2nd / std::not1 type of syntax.
  • Boost.Bind improves this with boost::bind and _1 / _2 placeholder syntax.
  • C++11 and beyond also have std::find_if_not, whereas C++98 needs std::find_if with a std::not1 around a function object.

C++ Style

There is no generally acceptable C++14 style yet. For better of for worse, I closely follow Scott Meyers's draft Effective Modern C++ and Herb Sutter's revamped GotW. I use the following style recommendations:

  • Herb Sutter's "Almost Always Auto" and Scott Meyers's "Prefer auto to specific type declarations" recommendation, for which the brevity is unsurpassed, although its clarity is sometimes disputed.
  • Scott Meyers's "Distinguish () and {} when creating objects" and consistently choose braced-initialization {} instead of the good old parenthesized initialization () (in order to side-step all most-vexing-parse issues in generic code).
  • Scott Meyers's "Prefer alias declarations to typedefs". For templates this is a must anyway, and using it everywhere instead of typedef saves time and adds consistency.
  • I use a for (auto it = first; it != last; ++it) pattern in some places, in order to allow for loop invariant checking for already sorted sub-ranges. In production code, the use of while (first != last) and a ++first somewhere inside the loop might be slightly better.

Selection sort

Selection sort does not adapt to the data in any way, so its runtime is always O(N^2). However, selection sort has the property of minimizing the number of swaps. In applications where the cost of swapping items is high, selection sort very well may be the algorithm of choice.

To implement it using the Standard Library, repeatedly use std::min_element to find the remaining minimum element, and iter_swap to swap it into place:

template<class FwdIt, class Compare = std::less<>>
void selection_sort(FwdIt first, FwdIt last, Compare cmp = Compare{})
    for (auto it = first; it != last; ++it) {
        auto const selection = std::min_element(it, last, cmp);
        std::iter_swap(selection, it); 
        assert(std::is_sorted(first, std::next(it), cmp));

Note that selection_sort has the already processed range [first, it) sorted as its loop invariant. The minimal requirements are forward iterators, compared to std::sort's random access iterators.

Details omitted:

  • selection sort can be optimized with an early test if (std::distance(first, last) <= 1) return; (or for forward / bidirectional iterators: if (first == last || std::next(first) == last) return;).
  • for bidirectional iterators, the above test can be combined with a loop over the interval [first, std::prev(last)), because the last element is guaranteed to be the minimal remaining element and doesn't require a swap.

Insertion sort

Although it is one of the elementary sorting algorithms with O(N^2) worst-case time, insertion sort is the algorithm of choice either when the data is nearly sorted (because it is adaptive) or when the problem size is small (because it has low overhead). For these reasons, and because it is also stable, insertion sort is often used as the recursive base case (when the problem size is small) for higher overhead divide-and-conquer sorting algorithms, such as merge sort or quick sort.

To implement insertion_sort with the Standard Library, repeatedly use std::upper_bound to find the location where the current element needs to go, and use std::rotate to shift the remaining elements upward in the input range:

template<class FwdIt, class Compare = std::less<>>
void insertion_sort(FwdIt first, FwdIt last, Compare cmp = Compare{})
    for (auto it = first; it != last; ++it) {
        auto const insertion = std::upper_bound(first, it, *it, cmp);
        std::rotate(insertion, it, std::next(it)); 
        assert(std::is_sorted(first, std::next(it), cmp));

Note that insertion_sort has the already processed range [first, it) sorted as its loop invariant. Insertion sort also works with forward iterators.

Details omitted:

  • insertion sort can be optimized with an early test if (std::distance(first, last) <= 1) return; (or for forward / bidirectional iterators: if (first == last || std::next(first) == last) return;) and a loop over the interval [std::next(first), last), because the first element is guaranteed to be in place and doesn't require a rotate.
  • for bidirectional iterators, the binary search to find the insertion point can be replaced with a reverse linear search using the Standard Library's std::find_if_not algorithm.

Four Live Examples (C++14, C++11, C++98 and Boost, C++98) for the fragment below:

using RevIt = std::reverse_iterator<BiDirIt>;
auto const insertion = std::find_if_not(RevIt(it), RevIt(first), 
    [=](auto const& elem){ return cmp(*it, elem); }
  • For random inputs this gives O(N^2) comparisons, but this improves to O(N) comparisons for almost sorted inputs. The binary search always uses O(N log N) comparisons.
  • For small input ranges, the better memory locality (cache, prefetching) of a linear search might also dominate a binary search (one should test this, of course).

Quick sort

When carefully implemented, quick sort is robust and has low overhead. When a stable sort is not needed, quick sort is an excellent general-purpose sort.

The simplest version of quick_sort is straightforward to implement using the Standard Library: use a few iterator utilities to locate the middle of the input range [first, last) as the pivot, use std::nth_element to separate the input range into element that are either smaller or equal to or larger than the selected pivot. Finally the two segments are recursively sorted:

template<class FwdIt, class Compare = std::less<>>
void quick_sort(FwdIt first, FwdIt last, Compare cmp = Compare{})
    auto const N = std::distance(first, last);
    if (N <= 1) return;
    auto const pivot = std::next(first, N / 2);
    std::nth_element(first, pivot, last, cmp);
    quick_sort(first, pivot, cmp); // assert(std::is_sorted(first, pivot, cmp));
    quick_sort(pivot, last, cmp);  // assert(std::is_sorted(pivot, last, cmp));

Note that although quick sort in general works with forward iterators, the above implementation cheats on this promise by using std::nth_element, which requires random access iterators (it can be remedied by choosing the pivot differently, see below).

However, quick sort is rather tricky to get correct and efficient, as each of the above steps has to be carefully checked and optimized for production level code.

Details omitted:

  • the above implementation is particularly vulnerable to special inputs, e.g. it has O(N^2) complexity for the "organ pipe" input 1, 2, 3, ..., N/2, ... 3, 2, 1
  • median-of-3 pivot selection from randomly chosen elements from the input range in combination with std::partition to segment the input range around the pivot.
  • This guards against almost sorted inputs for which the complexity would otherwise deteriorate to O(N^2) and would also weaken the requirements to the advertised forward iterators (since C++11, before that it was bidirectional iterators) instead of random access iterators that are imposed by std::nth_element.
  • 3-way partitioning (separating elements smaller than, equal to and larger than the pivot) version should be used instead of the 2-way partitioning code (keeping elements equal to and larger than the pivot together). The latter exhibits poor locality, and, critically, exhibits O(N^2) time when there are few unique keys.

Merge sort

If using O(N) extra space is of no concern, then merge sort is an excellent choice: it is the only stable O(N log N) sorting algorithm.

It is simple to implement using Standard algorithms: use a few iterator utilities to locate the middle of the input range [first, last) and combine two recursively sorted segments with a std::inplace_merge:

template<class BiDirIt, class Compare = std::less<>>
void merge_sort(BiDirIt first, BiDirIt last, Compare cmp = Compare{})
    auto const N = std::distance(first, last);
    if (N <= 1) return;                   
    auto const middle = std::next(first, N / 2);
    merge_sort(first, middle, cmp); // assert(std::is_sorted(first, middle, cmp));
    merge_sort(middle, last, cmp);  // assert(std::is_sorted(middle, last, cmp));
    std::inplace_merge(first, middle, last, cmp); // assert(std::is_sorted(first, last, cmp));

Merge sort requires bidirectional iterators, the bottleneck being the std::inplace_merge. Note that when sorting linked lists, merge sort requires only O(log N) extra space (for recursion). The latter algorithm is implemented by std::list<T>::sort in the Standard Library.

Heap sort

Heap sort is simple to implement, performs an O(N log N) in-place sort, but is not stable.

The first loop, O(N) "heapify" phase, puts the array into heap order. The second loop, the O(N log N) "sortdown" phase, repeatedly extracts the maximum and restores heap order. The Standard Library makes this extremely straightforward:

template<class RandomIt, class Compare = std::less<>>
void heap_sort(RandomIt first, RandomIt last, Compare cmp = Compare{})
    lib::make_heap(first, last, cmp); // assert(std::is_heap(first, last, cmp));
    lib::sort_heap(first, last, cmp); // assert(std::is_sorted(first, last, cmp));

In case you consider it "cheating" to use std::make_heap and std::sort_heap, you can go one level deeper and write those functions yourself in terms of std::push_heap and std::pop_heap, respectively:

namespace lib {

// NOTE: is O(N log N), not O(N) as std::make_heap
template<class RandomIt, class Compare = std::less<>>
void make_heap(RandomIt first, RandomIt last, Compare cmp = Compare{})
    for (auto it = first; it != last;) {
        std::push_heap(first, ++it, cmp); 
        assert(std::is_heap(first, it, cmp));           

template<class RandomIt, class Compare = std::less<>>
void sort_heap(RandomIt first, RandomIt last, Compare cmp = Compare{})
    for (auto it = last; it != first;) {
        std::pop_heap(first, it--, cmp);
        assert(std::is_heap(first, it, cmp));           

}   // namespace lib

The Standard Library specifies both push_heap and pop_heap as complexity O(log N). Note however that the outer loop over the range [first, last) results in O(N log N) complexity for make_heap, whereas std::make_heap has only O(N) complexity. For the overall O(N log N) complexity of heap_sort it doesn't matter.

Details omitted: O(N) implementation of make_heap


Here is are four Live Examples (C++14, C++11, C++98 and Boost, C++98) testing all five algorithms on a variety of inputs (not meant to be exhaustive or rigorous). Just note the huge differences in the LOC: C++11/C++14 need around 120 LOC, C++98 and Boost 180 (+50%) and C++98 more than +100% (note that heap sort could not even be done in terms of standard algorithms).

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I kinda disagree with the auto it = first pattern. Some iterators are not trivially copyable and I doubt that you can rely on the compiler to optimize the copy, just use the first iterator when possible, it is passed by value for this reason. –  sbabbi Jul 9 '14 at 10:25
While I disagree with your use of auto (and many people disagree with me), I enjoyed seeing the standard library algorithms being used well. I'd been wanting to see some examples of this kind of code after seeing Sean Parent's talk. Also, I had no idea std::iter_swap existed, although it seems strange to me that it's in <algorithm>. –  Joseph Mansfield Jul 9 '14 at 10:29
@sbabbi The entire standard library is based on the principle that iterators are cheap to copy; it passes them by value, for example. If copying an iterator isn't cheap, then you're going to suffer performance problems everywhere. –  James Kanze Jul 9 '14 at 13:02
@gnzlbg The asserts you can comment out, of course. The early test can be tag-dispatched per iterator category, with the current version for random access, and if (first == last || std::next(first) == last). I might update that later. Implementing the stuff in the "omitted details" sections is beyond the scope of the question, IMO, because they contain links to entire Q&As themselves. Implementing real-word sorting routines is hard! –  TemplateRex Aug 7 '14 at 13:27
Great post. Though, you've cheated with your quicksort by using nth_element in my opinion. nth_element does half a quicksort already (including the partitioning step and a recursion on the half that includes the n-th element you're interested in). –  sellibitze Aug 7 '14 at 16:10

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