std::ranges::is_permutation

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< cpp‎ | algorithm‎ | ranges
 
 
Algorithm library
Constrained algorithms and algorithms on ranges (C++20)
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(C++17)
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(C++11)                (C++11)(C++11)

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(C++11)
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(C++11)
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C library
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Constrained algorithms
All names in this menu belong to namespace std::ranges
Non-modifying sequence operations
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Binary search operations (on sorted ranges)
       
       
Set operations (on sorted ranges)
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Permutation operations
is_permutation
    
Fold operations
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(C++23)            
Operations on uninitialized storage
Return types
 
Defined in header <algorithm>
Call signature
template< std::forward_iterator I1, std::sentinel_for<I1> S1,

          std::forward_iterator I2, std::sentinel_for<I2> S2,
          class Proj1 = std::identity, class Proj2 = std::identity,
          std::indirect_equivalence_relation<std::projected<I1, Proj1>,
                                             std::projected<I2, Proj2>>
                                                 Pred = ranges::equal_to >
constexpr bool
    is_permutation( I1 first1, S1 last1, I2 first2, S2 last2, Pred pred = {},

                    Proj1 proj1 = {}, Proj2 proj2 = {} );
(1) (since C++20)
template< ranges::forward_range R1, ranges::forward_range R2,

          class Proj1 = std::identity, class Proj2 = std::identity,
          std::indirect_equivalence_relation<
              std::projected<ranges::iterator_t<R1>, Proj1>,
              std::projected<ranges::iterator_t<R2>, Proj2>>
                  Pred = ranges::equal_to >
constexpr bool
    is_permutation( R1&& r1, R2&& r2, Pred pred = {},

                    Proj1 proj1 = {}, Proj2 proj2 = {} );
(2) (since C++20)
1) Returns true if there exists a permutation of the elements in range [first1last1) that makes the range equal to [first2last2) (after application of corresponding projections Proj1, Proj2, and using the binary predicate Pred as a comparator). Otherwise returns false.
2) Same as (1), but uses r1 as the first source range and r2 as the second source range, as if using ranges::begin(r1) as first1, ranges::end(r1) as last1, ranges::begin(r2) as first2, and ranges::end(r2) as last2.

The function-like entities described on this page are niebloids, that is:

In practice, they may be implemented as function objects, or with special compiler extensions.

Parameters

first1, last1 - the first range of the elements
first2, last2 - the second range of the elements
r1 - the first range of the elements
r2 - the second range of the elements
pred - predicate to apply to the projected elements
proj1 - projection to apply to the elements in the first range
proj2 - projection to apply to the elements in the second range

Return value

true if the range [first1last1) is a permutation of the range [first2last2).

Complexity

At most O(N2) applications of the predicate and each projection, or exactly N if the sequences are already equal, where N is ranges::distance(first1, last1). However if ranges::distance(first1, last1) != ranges::distance(first2, last2), no applications of the predicate and projections are made.

Notes

The permutation relation is an equivalence relation.

The ranges::is_permutation can be used in testing, e.g. to check the correctness of rearranging algorithms such as sorting, shuffling, partitioning. If p is an original sequence and q is a "mutated" sequence, then ranges::is_permutation(p, q) == true means that q consist of "the same" elements (maybe permuted) as p.

Possible implementation

struct is_permutation_fn
{
    template<std::forward_iterator I1, std::sentinel_for<I1> S1,
             std::forward_iterator I2, std::sentinel_for<I2> S2,
             class Proj1 = std::identity, class Proj2 = std::identity,
             std::indirect_equivalence_relation<std::projected<I1, Proj1>,
                                                std::projected<I2, Proj2>>
                                                    Pred = ranges::equal_to>
    constexpr bool operator()(I1 first1, S1 last1, I2 first2, S2 last2,
                              Pred pred = {}, Proj1 proj1 = {}, Proj2 proj2 = {}) const
    {
        // skip common prefix
        auto ret = std::ranges::mismatch(first1, last1, first2, last2,
                                         std::ref(pred), std::ref(proj1), std::ref(proj2));
        first1 = ret.in1, first2 = ret.in2;
 
        // iterate over the rest, counting how many times each element
        // from [first1, last1) appears in [first2, last2)
        for (auto i {first1}; i != last1; ++i)
        {
            const auto i_proj {std::invoke(proj1, *i)};
            auto i_cmp = [&]<typename T>(T&& t)
            { 
                return std::invoke(pred, i_proj, std::forward<T>(t));
            };
 
            if (i != ranges::find_if(first1, i, i_cmp, proj1))
                continue; // this *i has been checked
 
            if (const auto m {ranges::count_if(first2, last2, i_cmp, proj2)};
                m == 0 or m != ranges::count_if(i, last1, i_cmp, proj1))
                return false;
        }
        return true;
    }
 
    template<ranges::forward_range R1, ranges::forward_range R2,
             class Proj1 = std::identity, class Proj2 = std::identity,
             std::indirect_equivalence_relation<
                 std::projected<ranges::iterator_t<R1>, Proj1>,
                 std::projected<ranges::iterator_t<R2>, Proj2>>
                     Pred = ranges::equal_to>
    constexpr bool operator()(R1&& r1, R2&& r2, Pred pred = {},
                              Proj1 proj1 = {}, Proj2 proj2 = {}) const
    {
        return (*this)(ranges::begin(r1), ranges::end(r1),
                       ranges::begin(r2), ranges::end(r2),
                       std::move(pred), std::move(proj1), std::move(proj2));
    }
};
 
inline constexpr is_permutation_fn is_permutation {};

Example

#include <algorithm>
#include <array>
#include <cmath>
#include <iostream>
#include <ranges>
 
auto& operator<<(auto& os, std::ranges::forward_range auto const& v)
{
    os << "{ ";
    for (const auto& e : v)
        os << e << ' ';
    return os << "}";
}
 
int main()
{
    static constexpr auto r1 = {1, 2, 3, 4, 5};
    static constexpr auto r2 = {3, 5, 4, 1, 2};
    static constexpr auto r3 = {3, 5, 4, 1, 1};
 
    static_assert(
        std::ranges::is_permutation(r1, r1) &&
        std::ranges::is_permutation(r1, r2) &&
        std::ranges::is_permutation(r2, r1) &&
        std::ranges::is_permutation(r1.begin(), r1.end(), r2.begin(), r2.end()));
 
    std::cout
        << std::boolalpha
        << "is_permutation(" << r1 << ", " << r2 << "): "
        << std::ranges::is_permutation(r1, r2) << '\n'
        << "is_permutation(" << r1 << ", " << r3 << "): "
        << std::ranges::is_permutation(r1, r3) << '\n'
 
        << "is_permutation with custom predicate and projections: "
        << std::ranges::is_permutation(
            std::array {-14, -11, -13, -15, -12},  // 1st range
            std::array {'F', 'E', 'C', 'B', 'D'},  // 2nd range
            [](int x, int y) { return abs(x) == abs(y); }, // predicate
            [](int x) { return x + 10; },          // projection for 1st range
            [](char y) { return int(y - 'A'); })   // projection for 2nd range
        << '\n';
}

Output:

is_permutation({ 1 2 3 4 5 }, { 3 5 4 1 2 }): true
is_permutation({ 1 2 3 4 5 }, { 3 5 4 1 1 }): false
is_permutation with custom predicate and projections: true

See also

generates the next greater lexicographic permutation of a range of elements
(niebloid)
generates the next smaller lexicographic permutation of a range of elements
(niebloid)
determines if a sequence is a permutation of another sequence
(function template)
generates the next greater lexicographic permutation of a range of elements
(function template)
generates the next smaller lexicographic permutation of a range of elements
(function template)
specifies that a relation imposes an equivalence relation
(concept)