std::ranges:: next_permutation, std::ranges:: next_permutation_result

From cppreference.com

Defined in header `<algorithm>`
Call signature
template < std:: bidirectional_iterator I, std:: sentinel_for < I > S, class Comp = ranges:: less , class Proj = std:: identity > requires std:: sortable < I, Comp, Proj > constexpr next_permutation_result < I > next_permutation ( I first, S last, Comp comp = { } , Proj proj = { } ) ;	(1)	(since C++20)
template < ranges:: bidirectional_range R, class Comp = ranges:: less , class Proj = std:: identity > requires std:: sortable < ranges:: iterator_t < R > , Comp, Proj > constexpr next_permutation_result < ranges:: borrowed_iterator_t < R >> next_permutation ( R && r, Comp comp = { } , Proj proj = { } ) ;	(2)	(since C++20)
Helper type
template < class I > using next_permutation_result = ranges:: in_found_result < I > ;	(3)	(since C++20)

1) Transforms the range

first

last

into the next permutation , where the set of all permutations is ordered lexicographically with respect to binary comparison function object comp and projection function object proj . Returns { last, true } if such a "next permutation" exists; otherwise transforms the range into the lexicographically first permutation as if by ranges:: sort ( first, last, comp, proj ) , and returns { last, false } .

2) Same as (1) , but uses r as the source range, as if using ranges:: begin ( r ) as first , and ranges:: end ( r ) as last .

The function-like entities described on this page are algorithm function objects (informally known as niebloids ), that is:

Explicit template argument lists cannot be specified when calling any of them.
None of them are visible to argument-dependent lookup .
When any of them are found by normal unqualified lookup as the name to the left of the function-call operator, argument-dependent lookup is inhibited.

Parameters

first, last	-	the range of elements to permute
r	-	the range of elements to permute
comp	-	comparison function object which returns true if the first argument is less than the second
proj	-	projection to apply to the elements

Return value

1) ranges :: next_permutation_result < I > { last, true } if the new permutation is lexicographically greater than the old one. ranges :: next_permutation_result < I > { last, false } if the last permutation was reached and the range was reset to the first permutation.

2) Same as (1) except that the return type is ranges :: next_permutation_result < ranges:: borrowed_iterator_t < R >> .

Exceptions

Any exceptions thrown from iterator operations or the element swap.

Complexity

At most $\scriptsize N/2$ $N / 2$ swaps, where $\scriptsize N$ $N$ is ranges:: distance ( first, last ) in case (1) or ranges:: distance ( r ) in case (2) . Averaged over the entire sequence of permutations, typical implementations use about 3 comparisons and 1.5 swaps per call.

Notes

Implementations (e.g. MSVC STL ) may enable vectorization when the iterator type models contiguous_iterator and swapping its value type calls neither non-trivial special member function nor ADL -found swap .

Possible implementation

struct next_permutation_fn
{
    template<std::bidirectional_iterator I, std::sentinel_for<I> S,
             class Comp = ranges::less, class Proj = std::identity>
    requires std::sortable<I, Comp, Proj>
    constexpr ranges::next_permutation_result<I>
        operator()(I first, S last, Comp comp = {}, Proj proj = {}) const
    {
        // check that the sequence has at least two elements
        if (first == last)
            return {std::move(first), false};
        I i_last{ranges::next(first, last)};
        I i{i_last};
        if (first == --i)
            return {std::move(i_last), false};
        // main "permutating" loop
        for (;;)
        {
            I i1{i};
            if (std::invoke(comp, std::invoke(proj, *--i), std::invoke(proj, *i1)))
            {
                I j{i_last};
                while (!std::invoke(comp, std::invoke(proj, *i), std::invoke(proj, *--j)))
                {}
                std::iter_swap(i, j);
                std::reverse(i1, i_last);
                return {std::move(i_last), true};
            }
            // permutation "space" is exhausted
            if (i == first)
            {
                std::reverse(first, i_last);
                return {std::move(i_last), false};
            }
        }
    }
 
    template<ranges::bidirectional_range R, class Comp = ranges::less,
             class Proj = std::identity>
    requires std::sortable<ranges::iterator_t<R>, Comp, Proj>
    constexpr ranges::next_permutation_result<ranges::borrowed_iterator_t<R>>
        operator()(R&& r, Comp comp = {}, Proj proj = {}) const
    {
        return (*this)(ranges::begin(r), ranges::end(r),
                       std::move(comp), std::move(proj));
    }
};
 
inline constexpr next_permutation_fn next_permutation {};

Example

Run this code

#include <algorithm>
#include <array>
#include <compare>
#include <functional>
#include <iostream>
#include <string>
 
struct S
{
    char c;
    int i;
    auto operator<=>(const S&) const = default;
    friend std::ostream& operator<<(std::ostream& os, const S& s)
    {
        return os << "{'" << s.c << "', " << s.i << "}";
    }
};
 
auto print = [](auto const& v, char term = ' ')
{
    std::cout << "{ ";
    for (const auto& e : v)
        std::cout << e << ' ';
    std::cout << '}' << term;
};
 
int main()
{
    std::cout << "Generate all permutations (iterators case):\n";
    std::string s{"abc"};
    do
    {
        print(s);
    }
    while (std::ranges::next_permutation(s.begin(), s.end()).found);
 
    std::cout << "\n" "Generate all permutations (range case):\n";
    std::array a{'a', 'b', 'c'};
    do
    {
        print(a);
    }
    while (std::ranges::next_permutation(a).found);
 
    std::cout << "\n" "Generate all permutations using comparator:\n";
    using namespace std::literals;
    std::array z{"█"s, "▄"s, "▁"s};
    do
    {
        print(z);
    }
    while (std::ranges::next_permutation(z, std::greater()).found);
 
    std::cout << "\n" "Generate all permutations using projection:\n";
    std::array<S, 3> r{S{'A',3}, S{'B',2}, S{'C',1}};
    do
    {
        print(r, '\n');
    }
    while (std::ranges::next_permutation(r, {}, &S::c).found);
}

Output:

Generate all permutations (iterators case):
{ a b c } { a c b } { b a c } { b c a } { c a b } { c b a }
Generate all permutations (range case):
{ a b c } { a c b } { b a c } { b c a } { c a b } { c b a }
Generate all permutations using comparator:
{ █ ▄ ▁ } { █ ▁ ▄ } { ▄ █ ▁ } { ▄ ▁ █ } { ▁ █ ▄ } { ▁ ▄ █ }
Generate all permutations using projection:
{ {'A', 3} {'B', 2} {'C', 1} }
{ {'A', 3} {'C', 1} {'B', 2} }
{ {'B', 2} {'A', 3} {'C', 1} }
{ {'B', 2} {'C', 1} {'A', 3} }
{ {'C', 1} {'A', 3} {'B', 2} }
{ {'C', 1} {'B', 2} {'A', 3} }

Compiler support
Freestanding and hosted
Language
Standard library
Standard library headers
Named requirements
Feature test macros (C++20)
Language support library
Concepts library (C++20)
Metaprogramming library (C++11)
Diagnostics library
General utilities library
Strings library
Containers library
Iterators library
Ranges library (C++20)
Algorithms library
Numerics library
Localizations library
Input/output library
Filesystem library (C++17)
Regular expressions library (C++11)
Concurrency support library (C++11)
Execution support library (C++26)
Technical specifications
Symbols index
External libraries

ranges::prev_permutation (C++20)	generates the next smaller lexicographic permutation of a range of elements (algorithm function object)
ranges::is_permutation (C++20)	determines if a sequence is a permutation of another sequence (algorithm function object)
next_permutation	generates the next greater lexicographic permutation of a range of elements (function template)
prev_permutation	generates the next smaller lexicographic permutation of a range of elements (function template)
is_permutation (C++11)	determines if a sequence is a permutation of another sequence (function template)