//              Copyright Catch2 Authors
// Distributed under the Boost Software License, Version 1.0.
//   (See accompanying file LICENSE.txt or copy at
//        https://www.boost.org/LICENSE_1_0.txt)

// SPDX-License-Identifier: BSL-1.0

#include <catch2/catch_test_macros.hpp>
#include <catch2/matchers/catch_matchers_container_properties.hpp>
#include <catch2/matchers/catch_matchers_contains.hpp>
#include <catch2/matchers/catch_matchers_range_equals.hpp>
#include <catch2/matchers/catch_matchers_floating_point.hpp>
#include <catch2/matchers/catch_matchers_quantifiers.hpp>
#include <catch2/matchers/catch_matchers_predicate.hpp>
#include <catch2/matchers/catch_matchers_string.hpp>

#include <helpers/range_test_helpers.hpp>

#include <cmath>
#include <list>
#include <map>
#include <type_traits>
#include <vector>
#include <memory>

struct MoveOnlyTestElement {
    int num = 0;
    MoveOnlyTestElement(int n) :num(n) {}

    MoveOnlyTestElement(MoveOnlyTestElement&& rhs) = default;
    MoveOnlyTestElement& operator=(MoveOnlyTestElement&& rhs) = default;

    friend bool operator==(MoveOnlyTestElement const& lhs, MoveOnlyTestElement const& rhs) {
        return lhs.num == rhs.num;
    }

    friend std::ostream& operator<<(std::ostream& out, MoveOnlyTestElement const& elem) {
        out << elem.num;
        return out;
    }
};

TEST_CASE("Basic use of the Contains range matcher", "[matchers][templated][contains]") {
    using Catch::Matchers::Contains;

    SECTION("Different argument ranges, same element type, default comparison") {
        std::array<int, 3> a{ { 1,2,3 } };
        std::vector<int> b{ 0,1,2 };
        std::list<int> c{ 4,5,6 };

        // A contains 1
        REQUIRE_THAT(a,  Contains(1));
        // B contains 1
        REQUIRE_THAT(b,  Contains(1));
        // C does not contain 1
        REQUIRE_THAT(c, !Contains(1));
    }

    SECTION("Different argument ranges, same element type, custom comparison") {
        std::array<int, 3> a{ { 1,2,3 } };
        std::vector<int> b{ 0,1,2 };
        std::list<int> c{ 4,5,6 };

        auto close_enough = [](int lhs, int rhs) { return std::abs(lhs - rhs) <= 1; };

        // A contains 1, which is "close enough" to 0
        REQUIRE_THAT(a,  Contains(0, close_enough));
        // B contains 0 directly
        REQUIRE_THAT(b,  Contains(0, close_enough));
        // C does not contain anything "close enough" to 0
        REQUIRE_THAT(c, !Contains(0, close_enough));
    }

    SECTION("Different element type, custom comparisons") {
        std::array<std::string, 3> a{ { "abc", "abcd" , "abcde" } };

        REQUIRE_THAT(a, Contains(4, [](auto&& lhs, size_t sz) {
            return lhs.size() == sz;
        }));
    }

    SECTION("Can handle type that requires ADL-found free function begin and end") {
        unrelated::needs_ADL_begin<int> in{1, 2, 3, 4, 5};

        REQUIRE_THAT(in,  Contains(1));
        REQUIRE_THAT(in, !Contains(8));
    }

    SECTION("Initialization with move only types") {
        std::array<MoveOnlyTestElement, 3> in{ { MoveOnlyTestElement{ 1 }, MoveOnlyTestElement{ 2 }, MoveOnlyTestElement{ 3 } } };

        REQUIRE_THAT(in,  Contains(MoveOnlyTestElement{ 2 }));
        REQUIRE_THAT(in, !Contains(MoveOnlyTestElement{ 9 }));
    }

    SECTION("Matching using matcher") {
        std::array<double, 4> in{ {1, 2, 3} };

        REQUIRE_THAT(in, Contains(Catch::Matchers::WithinAbs(0.5, 0.5)));
    }
}

namespace {

    struct has_empty {
        bool empty() const { return false; }
    };

} // end unnamed namespace

TEST_CASE("Basic use of the Empty range matcher", "[matchers][templated][empty]") {
    using Catch::Matchers::IsEmpty;
    SECTION("Simple, std-provided containers") {
        std::array<int, 0> empty_array{};
        std::array<double, 1> non_empty_array{};
        REQUIRE_THAT(empty_array, IsEmpty());
        REQUIRE_THAT(non_empty_array, !IsEmpty());

        std::vector<std::string> empty_vec;
        std::vector<char> non_empty_vec{ 'a', 'b', 'c' };
        REQUIRE_THAT(empty_vec, IsEmpty());
        REQUIRE_THAT(non_empty_vec, !IsEmpty());

        std::list<std::list<std::list<int>>> inner_lists_are_empty;
        inner_lists_are_empty.push_back({});
        REQUIRE_THAT(inner_lists_are_empty, !IsEmpty());
        REQUIRE_THAT(inner_lists_are_empty.front(), IsEmpty());
    }
    SECTION("Type with empty") {
        REQUIRE_THAT(has_empty{}, !IsEmpty());
    }
    SECTION("Type requires ADL found empty free function") {
        REQUIRE_THAT(unrelated::ADL_empty{}, IsEmpty());
    }
}

namespace {
    class LessThanMatcher final : public Catch::Matchers::MatcherBase<size_t> {
        size_t m_target;
    public:
        explicit LessThanMatcher(size_t target):
            m_target(target)
        {}

        bool match(size_t const& size) const override {
            return size < m_target;
        }

        std::string describe() const override {
            return "is less than " + std::to_string(m_target);
        }
    };

    LessThanMatcher Lt(size_t sz) {
        return LessThanMatcher{ sz };
    }

    struct has_size {
        size_t size() const {
            return 13;
        }
    };

} // end unnamed namespace

TEST_CASE("Usage of the SizeIs range matcher", "[matchers][templated][size]") {
    using Catch::Matchers::SizeIs;
    SECTION("Some with stdlib containers") {
        std::vector<int> empty_vec;
        REQUIRE_THAT(empty_vec,  SizeIs(0));
        REQUIRE_THAT(empty_vec, !SizeIs(2));
        REQUIRE_THAT(empty_vec,  SizeIs(Lt(2)));

        std::array<int, 2> arr{};
        REQUIRE_THAT(arr,  SizeIs(2));
        REQUIRE_THAT(arr,  SizeIs( Lt(3)));
        REQUIRE_THAT(arr, !SizeIs(!Lt(3)));

        std::map<int, int> map{ {1, 1}, {2, 2}, {3, 3} };
        REQUIRE_THAT(map, SizeIs(3));
    }
    SECTION("Type requires ADL found size free function") {
        REQUIRE_THAT(unrelated::ADL_size{}, SizeIs(12));
    }
    SECTION("Type has size member") {
        REQUIRE_THAT(has_size{}, SizeIs(13));
    }
}


TEST_CASE("Usage of AllMatch range matcher", "[matchers][templated][quantifiers]") {
    using Catch::Matchers::AllMatch;
    using Catch::Matchers::Predicate;

    SECTION("Basic usage") {
        using Catch::Matchers::Contains;
        using Catch::Matchers::SizeIs;

        std::array<std::array<int, 5>, 5> data{{
                                        {{ 0, 1, 2, 3, 5 }},
                                        {{ 4,-3,-2, 5, 0 }},
                                        {{ 0, 0, 0, 5, 0 }},
                                        {{ 0,-5, 0, 5, 0 }},
                                        {{ 1, 0, 0,-1, 5 }}
        }};

        REQUIRE_THAT(data,  AllMatch(SizeIs(5)));
        REQUIRE_THAT(data, !AllMatch(Contains(0) && Contains(1)));
    }

    SECTION("Type requires ADL found begin and end") {
        unrelated::needs_ADL_begin<int> needs_adl{ 1, 2, 3, 4, 5 };
        REQUIRE_THAT( needs_adl, AllMatch( Predicate<int>( []( int elem ) {
                          return elem < 6;
                      } ) ) );
    }

    SECTION("Shortcircuiting") {
        with_mocked_iterator_access<int> mocked{ 1, 2, 3, 4, 5 };
        SECTION("All are read") {
            auto allMatch = AllMatch(Predicate<int>([](int elem) {
                return elem < 10;
            }));
            REQUIRE_THAT(mocked, allMatch);
            REQUIRE(mocked.m_derefed[0]);
            REQUIRE(mocked.m_derefed[1]);
            REQUIRE(mocked.m_derefed[2]);
            REQUIRE(mocked.m_derefed[3]);
            REQUIRE(mocked.m_derefed[4]);
        }
        SECTION("Short-circuited") {
            auto allMatch = AllMatch(Predicate<int>([](int elem) {
                return elem < 3;
            }));
            REQUIRE_THAT(mocked, !allMatch);
            REQUIRE(mocked.m_derefed[0]);
            REQUIRE(mocked.m_derefed[1]);
            REQUIRE(mocked.m_derefed[2]);
            REQUIRE_FALSE(mocked.m_derefed[3]);
            REQUIRE_FALSE(mocked.m_derefed[4]);
        }
    }
}

TEST_CASE("Usage of AnyMatch range matcher", "[matchers][templated][quantifiers]") {
    using Catch::Matchers::AnyMatch;
    using Catch::Matchers::Predicate;

    SECTION("Basic usage") {
        using Catch::Matchers::Contains;
        using Catch::Matchers::SizeIs;

        std::array<std::array<int, 5>, 5> data{ {
                                        {{ 0, 1, 2, 3, 5 }},
                                        {{ 4,-3,-2, 5, 0 }},
                                        {{ 0, 0, 0, 5, 0 }},
                                        {{ 0,-5, 0, 5, 0 }},
                                        {{ 1, 0, 0,-1, 5 }}
        } };

        REQUIRE_THAT(data,  AnyMatch(SizeIs(5)));
        REQUIRE_THAT(data, !AnyMatch(Contains(0) && Contains(10)));
    }

    SECTION( "Type requires ADL found begin and end" ) {
        unrelated::needs_ADL_begin<int> needs_adl{ 1, 2, 3, 4, 5 };
        REQUIRE_THAT( needs_adl, AnyMatch( Predicate<int>( []( int elem ) {
                          return elem < 3;
                      } ) ) );
    }

    SECTION("Shortcircuiting") {
        with_mocked_iterator_access<int> mocked{ 1, 2, 3, 4, 5 };
        SECTION("All are read") {
            auto anyMatch = AnyMatch(
                Predicate<int>( []( int elem ) { return elem > 10; } ) );
            REQUIRE_THAT( mocked, !anyMatch );
            REQUIRE( mocked.m_derefed[0] );
            REQUIRE( mocked.m_derefed[1] );
            REQUIRE( mocked.m_derefed[2] );
            REQUIRE( mocked.m_derefed[3] );
            REQUIRE( mocked.m_derefed[4] );
        }
        SECTION("Short-circuited") {
            auto anyMatch = AnyMatch(
                Predicate<int>( []( int elem ) { return elem < 3; } ) );
            REQUIRE_THAT( mocked, anyMatch );
            REQUIRE( mocked.m_derefed[0] );
            REQUIRE_FALSE( mocked.m_derefed[1] );
            REQUIRE_FALSE( mocked.m_derefed[2] );
            REQUIRE_FALSE( mocked.m_derefed[3] );
            REQUIRE_FALSE( mocked.m_derefed[4] );
        }
    }
}

TEST_CASE("Usage of NoneMatch range matcher", "[matchers][templated][quantifiers]") {
    using Catch::Matchers::NoneMatch;
    using Catch::Matchers::Predicate;

    SECTION("Basic usage") {
        using Catch::Matchers::Contains;
        using Catch::Matchers::SizeIs;

        std::array<std::array<int, 5>, 5> data{ {
                                        {{ 0, 1, 2, 3, 5 }},
                                        {{ 4,-3,-2, 5, 0 }},
                                        {{ 0, 0, 0, 5, 0 }},
                                        {{ 0,-5, 0, 5, 0 }},
                                        {{ 1, 0, 0,-1, 5 }}
        } };

        REQUIRE_THAT(data, NoneMatch(SizeIs(6)));
        REQUIRE_THAT(data, !NoneMatch(Contains(0) && Contains(1)));
    }

    SECTION( "Type requires ADL found begin and end" ) {
        unrelated::needs_ADL_begin<int> needs_adl{ 1, 2, 3, 4, 5 };
        REQUIRE_THAT( needs_adl, NoneMatch( Predicate<int>( []( int elem ) {
                          return elem > 6;
                      } ) ) );
    }

    SECTION("Shortcircuiting") {
        with_mocked_iterator_access<int> mocked{ 1, 2, 3, 4, 5 };
        SECTION("All are read") {
            auto noneMatch = NoneMatch(
                Predicate<int>([](int elem) { return elem > 10; }));
            REQUIRE_THAT(mocked, noneMatch);
            REQUIRE(mocked.m_derefed[0]);
            REQUIRE(mocked.m_derefed[1]);
            REQUIRE(mocked.m_derefed[2]);
            REQUIRE(mocked.m_derefed[3]);
            REQUIRE(mocked.m_derefed[4]);
        }
        SECTION("Short-circuited") {
            auto noneMatch = NoneMatch(
                Predicate<int>([](int elem) { return elem < 3; }));
            REQUIRE_THAT(mocked, !noneMatch);
            REQUIRE(mocked.m_derefed[0]);
            REQUIRE_FALSE(mocked.m_derefed[1]);
            REQUIRE_FALSE(mocked.m_derefed[2]);
            REQUIRE_FALSE(mocked.m_derefed[3]);
            REQUIRE_FALSE(mocked.m_derefed[4]);
        }
    }
}

namespace {
    struct ConvertibleToBool
    {
        bool v;

        explicit operator bool() const
        {
            return v;
        }
    };
}

namespace Catch {
    template <>
    struct StringMaker<ConvertibleToBool> {
        static std::string
        convert( ConvertibleToBool const& convertible_to_bool ) {
            return ::Catch::Detail::stringify( convertible_to_bool.v );
        }
    };
} // namespace Catch

TEST_CASE("Usage of AllTrue range matcher", "[matchers][templated][quantifiers]") {
    using Catch::Matchers::AllTrue;

    SECTION( "Basic usage" ) {
        SECTION( "All true evaluates to true" ) {
            std::array<bool, 5> const data{ { true, true, true, true, true } };
            REQUIRE_THAT( data, AllTrue() );
        }
        SECTION( "Empty evaluates to true" ) {
            std::array<bool, 0> const data{};
            REQUIRE_THAT( data, AllTrue() );
        }
        SECTION( "One false evaluates to false" ) {
            std::array<bool, 5> const data{ { true, true, false, true, true } };
            REQUIRE_THAT( data, !AllTrue() );
        }
        SECTION( "All false evaluates to false" ) {
            std::array<bool, 5> const data{
                { false, false, false, false, false } };
            REQUIRE_THAT( data, !AllTrue() );
        }
    }

    SECTION( "Contained type is convertible to bool" ) {
        SECTION( "All true evaluates to true" ) {
            std::array<ConvertibleToBool, 5> const data{
                { { true }, { true }, { true }, { true }, { true } } };
            REQUIRE_THAT( data, AllTrue() );
        }
        SECTION( "One false evaluates to false" ) {
            std::array<ConvertibleToBool, 5> const data{
                { { true }, { true }, { false }, { true }, { true } } };
            REQUIRE_THAT( data, !AllTrue() );
        }
        SECTION( "All false evaluates to false" ) {
            std::array<ConvertibleToBool, 5> const data{
                { { false }, { false }, { false }, { false }, { false } } };
            REQUIRE_THAT( data, !AllTrue() );
        }
    }

    SECTION( "Shortcircuiting" ) {
        SECTION( "All are read" ) {
            with_mocked_iterator_access<bool> const mocked{
                true, true, true, true, true };
            REQUIRE_THAT( mocked, AllTrue() );
            REQUIRE( mocked.m_derefed[0] );
            REQUIRE( mocked.m_derefed[1] );
            REQUIRE( mocked.m_derefed[2] );
            REQUIRE( mocked.m_derefed[3] );
            REQUIRE( mocked.m_derefed[4] );
        }
        SECTION( "Short-circuited" ) {
            with_mocked_iterator_access<bool> const mocked{
                true, true, false, true, true };
            REQUIRE_THAT( mocked, !AllTrue() );
            REQUIRE( mocked.m_derefed[0] );
            REQUIRE( mocked.m_derefed[1] );
            REQUIRE( mocked.m_derefed[2] );
            REQUIRE_FALSE( mocked.m_derefed[3] );
            REQUIRE_FALSE( mocked.m_derefed[4] );
        }
    }
}

TEST_CASE( "Usage of NoneTrue range matcher", "[matchers][templated][quantifiers]" ) {
    using Catch::Matchers::NoneTrue;

    SECTION( "Basic usage" ) {
        SECTION( "All true evaluates to false" ) {
            std::array<bool, 5> const data{ { true, true, true, true, true } };
            REQUIRE_THAT( data, !NoneTrue() );
        }
        SECTION( "Empty evaluates to true" ) {
            std::array<bool, 0> const data{};
            REQUIRE_THAT( data, NoneTrue() );
        }
        SECTION( "One true evaluates to false" ) {
            std::array<bool, 5> const data{
                { false, false, true, false, false } };
            REQUIRE_THAT( data, !NoneTrue() );
        }
        SECTION( "All false evaluates to true" ) {
            std::array<bool, 5> const data{
                { false, false, false, false, false } };
            REQUIRE_THAT( data, NoneTrue() );
        }
    }

    SECTION( "Contained type is convertible to bool" ) {
        SECTION( "All true evaluates to false" ) {
            std::array<ConvertibleToBool, 5> const data{
                { { true }, { true }, { true }, { true }, { true } } };
            REQUIRE_THAT( data, !NoneTrue() );
        }
        SECTION( "One true evaluates to false" ) {
            std::array<ConvertibleToBool, 5> const data{
                { { false }, { false }, { true }, { false }, { false } } };
            REQUIRE_THAT( data, !NoneTrue() );
        }
        SECTION( "All false evaluates to true" ) {
            std::array<ConvertibleToBool, 5> const data{
                { { false }, { false }, { false }, { false }, { false } } };
            REQUIRE_THAT( data, NoneTrue() );
        }
    }

    SECTION( "Shortcircuiting" ) {
        SECTION( "All are read" ) {
            with_mocked_iterator_access<bool> const mocked{
                false, false, false, false, false };
            REQUIRE_THAT( mocked, NoneTrue() );
            REQUIRE( mocked.m_derefed[0] );
            REQUIRE( mocked.m_derefed[1] );
            REQUIRE( mocked.m_derefed[2] );
            REQUIRE( mocked.m_derefed[3] );
            REQUIRE( mocked.m_derefed[4] );
        }
        SECTION( "Short-circuited" ) {
            with_mocked_iterator_access<bool> const mocked{
                false, false, true, true, true };
            REQUIRE_THAT( mocked, !NoneTrue() );
            REQUIRE( mocked.m_derefed[0] );
            REQUIRE( mocked.m_derefed[1] );
            REQUIRE( mocked.m_derefed[2] );
            REQUIRE_FALSE( mocked.m_derefed[3] );
            REQUIRE_FALSE( mocked.m_derefed[4] );
        }
    }
}

TEST_CASE( "Usage of AnyTrue range matcher", "[matchers][templated][quantifiers]" ) {
    using Catch::Matchers::AnyTrue;

    SECTION( "Basic usage" ) {
        SECTION( "All true evaluates to true" ) {
            std::array<bool, 5> const data{ { true, true, true, true, true } };
            REQUIRE_THAT( data, AnyTrue() );
        }
        SECTION( "Empty evaluates to false" ) {
            std::array<bool, 0> const data{};
            REQUIRE_THAT( data, !AnyTrue() );
        }
        SECTION( "One true evaluates to true" ) {
            std::array<bool, 5> const data{
                { false, false, true, false, false } };
            REQUIRE_THAT( data, AnyTrue() );
        }
        SECTION( "All false evaluates to false" ) {
            std::array<bool, 5> const data{
                { false, false, false, false, false } };
            REQUIRE_THAT( data, !AnyTrue() );
        }
    }

    SECTION( "Contained type is convertible to bool" ) {
        SECTION( "All true evaluates to true" ) {
            std::array<ConvertibleToBool, 5> const data{
                { { true }, { true }, { true }, { true }, { true } } };
            REQUIRE_THAT( data, AnyTrue() );
        }
        SECTION( "One true evaluates to true" ) {
            std::array<ConvertibleToBool, 5> const data{
                { { false }, { false }, { true }, { false }, { false } } };
            REQUIRE_THAT( data, AnyTrue() );
        }
        SECTION( "All false evaluates to false" ) {
            std::array<ConvertibleToBool, 5> const data{
                { { false }, { false }, { false }, { false }, { false } } };
            REQUIRE_THAT( data, !AnyTrue() );
        }
    }

    SECTION( "Shortcircuiting" ) {
        SECTION( "All are read" ) {
            with_mocked_iterator_access<bool> const mocked{
                false, false, false, false, true };
            REQUIRE_THAT( mocked, AnyTrue() );
            REQUIRE( mocked.m_derefed[0] );
            REQUIRE( mocked.m_derefed[1] );
            REQUIRE( mocked.m_derefed[2] );
            REQUIRE( mocked.m_derefed[3] );
            REQUIRE( mocked.m_derefed[4] );
        }
        SECTION( "Short-circuited" ) {
            with_mocked_iterator_access<bool> const mocked{
                false, false, true, true, true };
            REQUIRE_THAT( mocked, AnyTrue() );
            REQUIRE( mocked.m_derefed[0] );
            REQUIRE( mocked.m_derefed[1] );
            REQUIRE( mocked.m_derefed[2] );
            REQUIRE_FALSE( mocked.m_derefed[3] );
            REQUIRE_FALSE( mocked.m_derefed[4] );
        }
    }
}

TEST_CASE("All/Any/None True matchers support types with ADL begin",
          "[approvals][matchers][quantifiers][templated]") {
    using Catch::Matchers::AllTrue;
    using Catch::Matchers::NoneTrue;
    using Catch::Matchers::AnyTrue;


    SECTION( "Type requires ADL found begin and end" ) {
        unrelated::needs_ADL_begin<bool> const needs_adl{
            true, true, true, true, true };
        REQUIRE_THAT( needs_adl, AllTrue() );
    }

    SECTION( "Type requires ADL found begin and end" ) {
        unrelated::needs_ADL_begin<bool> const needs_adl{
            false, false, false, false, false };
        REQUIRE_THAT( needs_adl, NoneTrue() );
    }

    SECTION( "Type requires ADL found begin and end" ) {
        unrelated::needs_ADL_begin<bool> const needs_adl{
            false, false, true, false, false };
        REQUIRE_THAT( needs_adl, AnyTrue() );
    }
}

// Range loop iterating over range with different types for begin and end is a
// C++17 feature, and GCC refuses to compile such code unless the lang mode is
// set to C++17 or later.
#if defined(CATCH_CPP17_OR_GREATER)

TEST_CASE( "The quantifier range matchers support types with different types returned from begin and end",
           "[matchers][templated][quantifiers][approvals]" ) {
    using Catch::Matchers::AllMatch;
    using Catch::Matchers::AllTrue;
    using Catch::Matchers::AnyMatch;
    using Catch::Matchers::AnyTrue;
    using Catch::Matchers::NoneMatch;
    using Catch::Matchers::NoneTrue;

    using Catch::Matchers::Predicate;

    SECTION( "AllAnyNoneMatch" ) {
        has_different_begin_end_types<int> diff_types{ 1, 2, 3, 4, 5 };
        REQUIRE_THAT( diff_types, !AllMatch( Predicate<int>( []( int elem ) {
                          return elem < 3;
                      } ) ) );

        REQUIRE_THAT( diff_types, AnyMatch( Predicate<int>( []( int elem ) {
                          return elem < 2;
                      } ) ) );

        REQUIRE_THAT( diff_types, !NoneMatch( Predicate<int>( []( int elem ) {
                          return elem < 3;
                      } ) ) );
    }
    SECTION( "AllAnyNoneTrue" ) {
        has_different_begin_end_types<bool> diff_types{ false, false, true, false, false };

        REQUIRE_THAT( diff_types, !AllTrue() );
        REQUIRE_THAT( diff_types, AnyTrue() );
        REQUIRE_THAT( diff_types, !NoneTrue() );
    }
}

TEST_CASE( "RangeEquals supports ranges with different types returned from begin and end",
           "[matchers][templated][range][approvals] ") {
    using Catch::Matchers::RangeEquals;
    using Catch::Matchers::UnorderedRangeEquals;

    has_different_begin_end_types<int> diff_types{ 1, 2, 3, 4, 5 };
    std::array<int, 5> arr1{ { 1, 2, 3, 4, 5 } }, arr2{ { 2, 3, 4, 5, 6 } };

    REQUIRE_THAT( diff_types, RangeEquals( arr1 ) );
    REQUIRE_THAT( diff_types, RangeEquals( arr2, []( int l, int r ) {
                      return l + 1 == r;
                  } ) );
    REQUIRE_THAT( diff_types, UnorderedRangeEquals( diff_types ) );
}

TEST_CASE( "RangeContains supports ranges with different types returned from "
           "begin and end",
           "[matchers][templated][range][approvals]" ) {
    using Catch::Matchers::Contains;

    has_different_begin_end_types<size_t> diff_types{ 1, 2, 3, 4, 5 };
    REQUIRE_THAT( diff_types, Contains( size_t( 3 ) ) );
    REQUIRE_THAT( diff_types, Contains( LessThanMatcher( size_t( 4 ) ) ) );
}

#endif

TEST_CASE( "Usage of RangeEquals range matcher", "[matchers][templated][quantifiers]" ) {
    using Catch::Matchers::RangeEquals;

    // In these tests, the types are always the same - type conversion is in the next section
    SECTION( "Basic usage" ) {
        SECTION( "Empty container matches empty container" ) {
            const std::vector<int> empty_vector;
            CHECK_THAT( empty_vector, RangeEquals( empty_vector ) );
        }
        SECTION( "Empty container does not match non-empty container" ) {
            const std::vector<int> empty_vector;
            const std::vector<int> non_empty_vector{ 1 };
            CHECK_THAT( empty_vector, !RangeEquals( non_empty_vector ) );
            // ...and in reverse
            CHECK_THAT( non_empty_vector, !RangeEquals( empty_vector ) );
        }
        SECTION( "Two equal 1-length non-empty containers" ) {
            const std::array<int, 1> non_empty_array{ { 1 } };
            CHECK_THAT( non_empty_array, RangeEquals( non_empty_array ) );
        }
        SECTION( "Two equal-sized, equal, non-empty containers" ) {
            const std::array<int, 3> array_a{ { 1, 2, 3 } };
            CHECK_THAT( array_a, RangeEquals( array_a ) );
        }
        SECTION( "Two equal-sized, non-equal, non-empty containers" ) {
            const std::array<int, 3> array_a{ { 1, 2, 3 } };
            const std::array<int, 3> array_b{ { 2, 2, 3 } };
            const std::array<int, 3> array_c{ { 1, 2, 2 } };
            CHECK_THAT( array_a, !RangeEquals( array_b ) );
            CHECK_THAT( array_a, !RangeEquals( array_c ) );
        }
        SECTION( "Two non-equal-sized, non-empty containers (with same first "
                 "elements)" ) {
            const std::vector<int> vector_a{ 1, 2, 3 };
            const std::vector<int> vector_b{ 1, 2, 3, 4 };
            CHECK_THAT( vector_a, !RangeEquals( vector_b ) );
        }
    }

    SECTION( "Custom predicate" ) {

        auto close_enough = []( int lhs, int rhs ) {
            return std::abs( lhs - rhs ) <= 1;
        };

        SECTION( "Two equal non-empty containers (close enough)" ) {
            const std::vector<int> vector_a{ { 1, 2, 3 } };
            const std::vector<int> vector_a_plus_1{ { 2, 3, 4 } };
            CHECK_THAT( vector_a, RangeEquals( vector_a_plus_1, close_enough ) );
        }
        SECTION( "Two non-equal non-empty containers (close enough)" ) {
            const std::vector<int> vector_a{ { 1, 2, 3 } };
            const std::vector<int> vector_b{ { 3, 3, 4 } };
            CHECK_THAT( vector_a, !RangeEquals( vector_b, close_enough ) );
        }
    }

    SECTION( "Ranges that need ADL begin/end" ) {
        unrelated::needs_ADL_begin<int> const
            needs_adl1{ 1, 2, 3, 4, 5 },
            needs_adl2{ 1, 2, 3, 4, 5 },
            needs_adl3{ 2, 3, 4, 5, 6 };

        REQUIRE_THAT( needs_adl1, RangeEquals( needs_adl2 ) );
        REQUIRE_THAT( needs_adl1, RangeEquals( needs_adl3, []( int l, int r ) {
                          return l + 1 == r;
                      } ) );
    }

    SECTION("Check short-circuiting behaviour") {
        with_mocked_iterator_access<int> const mocked1{ 1, 2, 3, 4 };

        SECTION( "Check short-circuits on failure" ) {
            std::array<int, 4> arr{ { 1, 2, 4, 4 } };

            REQUIRE_THAT( mocked1, !RangeEquals( arr ) );
            REQUIRE( mocked1.m_derefed[0] );
            REQUIRE( mocked1.m_derefed[1] );
            REQUIRE( mocked1.m_derefed[2] );
            REQUIRE_FALSE( mocked1.m_derefed[3] );
        }
        SECTION("All elements are checked on success") {
            std::array<int, 4> arr{ { 1, 2, 3, 4 } };

            REQUIRE_THAT( mocked1, RangeEquals( arr ) );
            REQUIRE( mocked1.m_derefed[0] );
            REQUIRE( mocked1.m_derefed[1] );
            REQUIRE( mocked1.m_derefed[2] );
            REQUIRE( mocked1.m_derefed[3] );
        }
    }
}

TEST_CASE( "Usage of UnorderedRangeEquals range matcher",
           "[matchers][templated][quantifiers]" ) {
    using Catch::Matchers::UnorderedRangeEquals;

    // In these tests, the types are always the same - type conversion is in the
    // next section
    SECTION( "Basic usage" ) {
        SECTION( "Empty container matches empty container" ) {
            const std::vector<int> empty_vector;
            CHECK_THAT( empty_vector, UnorderedRangeEquals( empty_vector ) );
        }
        SECTION( "Empty container does not match non-empty container" ) {
            const std::vector<int> empty_vector;
            const std::vector<int> non_empty_vector{ 1 };
            CHECK_THAT( empty_vector,
                        !UnorderedRangeEquals( non_empty_vector ) );
            // ...and in reverse
            CHECK_THAT( non_empty_vector,
                        !UnorderedRangeEquals( empty_vector ) );
        }
        SECTION( "Two equal 1-length non-empty containers" ) {
            const std::array<int, 1> non_empty_array{ { 1 } };
            CHECK_THAT( non_empty_array,
                        UnorderedRangeEquals( non_empty_array ) );
        }
        SECTION( "Two equal-sized, equal, non-empty containers" ) {
            const std::array<int, 3> array_a{ { 1, 2, 3 } };
            CHECK_THAT( array_a, UnorderedRangeEquals( array_a ) );
        }
        SECTION( "Two equal-sized, non-equal, non-empty containers" ) {
            const std::array<int, 3> array_a{ { 1, 2, 3 } };
            const std::array<int, 3> array_b{ { 2, 2, 3 } };
            CHECK_THAT( array_a, !UnorderedRangeEquals( array_b ) );
        }
        SECTION( "Two non-equal-sized, non-empty containers" ) {
            const std::vector<int> vector_a{ 1, 2, 3 };
            const std::vector<int> vector_b{ 1, 2, 3, 4 };
            CHECK_THAT( vector_a, !UnorderedRangeEquals( vector_b ) );
        }
    }

    SECTION( "Custom predicate" ) {

        auto close_enough = []( int lhs, int rhs ) {
            return std::abs( lhs - rhs ) <= 1;
        };

        SECTION( "Two equal non-empty containers (close enough)" ) {
            const std::vector<int> vector_a{ { 1, 10, 20 } };
            const std::vector<int> vector_a_plus_1{ { 11, 21, 2 } };
            CHECK_THAT( vector_a,
                        UnorderedRangeEquals( vector_a_plus_1, close_enough ) );
        }
        SECTION( "Two non-equal non-empty containers (close enough)" ) {
            const std::vector<int> vector_a{ { 1, 10, 21 } };
            const std::vector<int> vector_b{ { 11, 21, 3 } };
            CHECK_THAT( vector_a,
                        !UnorderedRangeEquals( vector_b, close_enough ) );
        }
    }


    SECTION( "Ranges that need ADL begin/end" ) {
        unrelated::needs_ADL_begin<int> const
            needs_adl1{ 1, 2, 3, 4, 5 },
            needs_adl2{ 1, 2, 3, 4, 5 };

        REQUIRE_THAT( needs_adl1, UnorderedRangeEquals( needs_adl2 ) );
    }
}

/**
 * Return true if the type given has a random access iterator type.
 */
template <typename Container>
static constexpr bool ContainerIsRandomAccess( const Container& ) {
    using array_iter_category = typename std::iterator_traits<
        typename Container::iterator>::iterator_category;

    return std::is_base_of<std::random_access_iterator_tag,
                           array_iter_category>::value;
}

TEST_CASE( "Type conversions of RangeEquals and similar",
           "[matchers][templated][quantifiers]" ) {
    using Catch::Matchers::RangeEquals;
    using Catch::Matchers::UnorderedRangeEquals;

    // In these test, we can always test RangeEquals and
    // UnorderedRangeEquals in the same way, since we're mostly
    // testing the template type deductions (and RangeEquals
    // implies UnorderedRangeEquals)

    SECTION( "Container conversions" ) {
        SECTION( "Two equal containers of different container types" ) {
            const std::array<int, 3> array_int_a{ { 1, 2, 3 } };
            const int c_array[3] = { 1, 2, 3 };
            CHECK_THAT( array_int_a, RangeEquals( c_array ) );
            CHECK_THAT( array_int_a, UnorderedRangeEquals( c_array ) );
        }
        SECTION( "Two equal containers of different container types "
                    "(differ in array N)" ) {
            const std::array<int, 3> array_int_3{ { 1, 2, 3 } };
            const std::array<int, 4> array_int_4{ { 1, 2, 3, 4 } };
            CHECK_THAT( array_int_3, !RangeEquals( array_int_4 ) );
            CHECK_THAT( array_int_3, !UnorderedRangeEquals( array_int_4 ) );
        }
        SECTION( "Two equal containers of different container types and value "
                    "types" ) {
            const std::array<int, 3> array_int_a{ { 1, 2, 3 } };
            const std::vector<int> vector_char_a{ 1, 2, 3 };
            CHECK_THAT( array_int_a, RangeEquals( vector_char_a ) );
            CHECK_THAT( array_int_a, UnorderedRangeEquals( vector_char_a ) );
        }
        SECTION( "Two equal containers, one random access, one not" ) {
            const std::array<int, 3> array_int_a{ { 1, 2, 3 } };
            const std::list<int> list_char_a{ 1, 2, 3 };

            // Verify these types really are different in random access nature
            STATIC_REQUIRE( ContainerIsRandomAccess( array_int_a ) !=
                            ContainerIsRandomAccess( list_char_a ) );

            CHECK_THAT( array_int_a, RangeEquals( list_char_a ) );
            CHECK_THAT( array_int_a, UnorderedRangeEquals( list_char_a ) );
        }
    }

    SECTION( "Value type" ) {
        SECTION( "Two equal containers of different value types" ) {
            const std::vector<int> vector_int_a{ 1, 2, 3 };
            const std::vector<char> vector_char_a{ 1, 2, 3 };
            CHECK_THAT( vector_int_a, RangeEquals( vector_char_a ) );
            CHECK_THAT( vector_int_a, UnorderedRangeEquals( vector_char_a ) );
        }
        SECTION( "Two non-equal containers of different value types" ) {
            const std::vector<int> vector_int_a{ 1, 2, 3 };
            const std::vector<char> vector_char_b{ 1, 2, 2 };
            CHECK_THAT( vector_int_a, !RangeEquals( vector_char_b ) );
            CHECK_THAT( vector_int_a, !UnorderedRangeEquals( vector_char_b ) );
        }
    }

    SECTION( "Ranges with begin that needs ADL" ) {
        unrelated::needs_ADL_begin<int> a{ 1, 2, 3 }, b{ 3, 2, 1 };
        REQUIRE_THAT( a, !RangeEquals( b ) );
        REQUIRE_THAT( a, UnorderedRangeEquals( b ) );
    }

    SECTION( "Custom predicate" ) {

        auto close_enough = []( int lhs, int rhs ) {
            return std::abs( lhs - rhs ) <= 1;
        };

        SECTION( "Two equal non-empty containers (close enough)" ) {
            const std::vector<int> vector_a{ { 1, 2, 3 } };
            const std::array<char, 3> array_a_plus_1{ { 2, 3, 4 } };
            CHECK_THAT( vector_a,
                        RangeEquals( array_a_plus_1, close_enough ) );
            CHECK_THAT( vector_a,
                        UnorderedRangeEquals( array_a_plus_1, close_enough ) );
        }
    }
}