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//===----------------------------------------------------------------------===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
// UNSUPPORTED: c++03, c++11, c++14, c++17
// UNSUPPORTED: libcpp-has-no-incomplete-ranges
// <algorithm>
//
// Range algorithms should use `std::invoke` to call the given projection(s) (and predicates, where applicable).
#include <algorithm>
#include <array>
#include <concepts>
#include <initializer_list>
#include <iterator>
#include <ranges>
struct Foo {
int val;
constexpr bool unary_pred() const { return val > 0; }
constexpr bool binary_pred(const Foo& rhs) const { return val < rhs.val; }
constexpr auto operator<=>(const Foo&) const = default;
};
struct Bar {
Foo val;
Bar create() const { return Bar(); }
};
// Invokes both the (iterator, sentinel, ...) and the (range, ...) overloads of the given niebloid.
// (in, ...)
template <class Func, std::ranges::range Input, class... Args>
constexpr void test(Func&& func, Input& in, Args&&... args) {
func(in.begin(), in.end(), std::forward<Args>(args)...);
func(in, std::forward<Args>(args)...);
}
// (in1, in2, ...)
template <class Func, std::ranges::range Input, class... Args>
constexpr void test(Func&& func, Input& in1, Input& in2, Args&&... args) {
func(in1.begin(), in1.end(), in2.begin(), in2.end(), std::forward<Args>(args)...);
func(in1, in2, std::forward<Args>(args)...);
}
// (in, mid, ...)
template <class Func, std::ranges::range Input, class... Args>
constexpr void test_mid(Func&& func, Input& in, std::ranges::iterator_t<Input> mid, Args&&... args) {
func(in.begin(), mid, in.end(), std::forward<Args>(args)...);
func(in, mid, std::forward<Args>(args)...);
}
constexpr bool test_all() {
std::array in = {Bar{Foo{1}}, Bar{Foo{2}}, Bar{Foo{3}}};
std::array in2 = {Bar{Foo{4}}, Bar{Foo{5}}, Bar{Foo{6}}};
auto mid = in.begin() + 1;
std::array output = {Bar{Foo{7}}, Bar{Foo{8}}, Bar{Foo{9}}, Bar{Foo{10}}, Bar{Foo{11}}, Bar{Foo{12}}};
auto out = output.begin();
auto out2 = output.begin() + 1;
Bar a{Foo{1}};
Bar b{Foo{2}};
//Bar c{Foo{3}};
Foo x{2};
size_t count = 1;
test(std::ranges::any_of, in, &Foo::unary_pred, &Bar::val);
test(std::ranges::all_of, in, &Foo::unary_pred, &Bar::val);
test(std::ranges::none_of, in, &Foo::unary_pred, &Bar::val);
test(std::ranges::find, in, x, &Bar::val);
test(std::ranges::find_if, in, &Foo::unary_pred, &Bar::val);
test(std::ranges::find_if_not, in, &Foo::unary_pred, &Bar::val);
test(std::ranges::find_first_of, in, in2, &Foo::binary_pred, &Bar::val, &Bar::val);
test(std::ranges::adjacent_find, in, &Foo::binary_pred, &Bar::val);
test(std::ranges::mismatch, in, in2, &Foo::binary_pred, &Bar::val, &Bar::val);
test(std::ranges::equal, in, in2, &Foo::binary_pred, &Bar::val, &Bar::val);
test(std::ranges::lexicographical_compare, in, in2, &Foo::binary_pred, &Bar::val, &Bar::val);
test(std::ranges::partition_point, in, &Foo::unary_pred, &Bar::val);
test(std::ranges::lower_bound, in, x, &Foo::binary_pred, &Bar::val);
test(std::ranges::upper_bound, in, x, &Foo::binary_pred, &Bar::val);
test(std::ranges::equal_range, in, x, &Foo::binary_pred, &Bar::val);
test(std::ranges::binary_search, in, x, &Foo::binary_pred, &Bar::val);
// min
std::ranges::min(a, b, &Foo::binary_pred, &Bar::val);
std::ranges::min(std::initializer_list<Bar>{a, b}, &Foo::binary_pred, &Bar::val);
std::ranges::min(in, &Foo::binary_pred, &Bar::val);
// max
std::ranges::max(a, b, &Foo::binary_pred, &Bar::val);
std::ranges::max(std::initializer_list<Bar>{a, b}, &Foo::binary_pred, &Bar::val);
std::ranges::max(in, &Foo::binary_pred, &Bar::val);
// minmax
std::ranges::minmax(a, b, &Foo::binary_pred, &Bar::val);
std::ranges::minmax(std::initializer_list<Bar>{a, b}, &Foo::binary_pred, &Bar::val);
std::ranges::minmax(in, &Foo::binary_pred, &Bar::val);
test(std::ranges::min_element, in, &Foo::binary_pred, &Bar::val);
test(std::ranges::max_element, in, &Foo::binary_pred, &Bar::val);
test(std::ranges::minmax_element, in, &Foo::binary_pred, &Bar::val);
test(std::ranges::count, in, x, &Bar::val);
test(std::ranges::count_if, in, &Foo::unary_pred, &Bar::val);
test(std::ranges::search, in, in2, &Foo::binary_pred, &Bar::val, &Bar::val);
test(std::ranges::search_n, in, count, x, &Foo::binary_pred, &Bar::val);
test(std::ranges::find_end, in, in2, &Foo::binary_pred, &Bar::val, &Bar::val);
test(std::ranges::is_partitioned, in, &Foo::unary_pred, &Bar::val);
test(std::ranges::is_sorted, in, &Foo::binary_pred, &Bar::val);
test(std::ranges::is_sorted_until, in, &Foo::binary_pred, &Bar::val);
test(std::ranges::includes, in, in2, &Foo::binary_pred, &Bar::val, &Bar::val);
test(std::ranges::is_heap, in, &Foo::binary_pred, &Bar::val);
test(std::ranges::is_heap_until, in, &Foo::binary_pred, &Bar::val);
//std::ranges::clamp(b, a, c, &Foo::binary_pred);
//test(std::ranges::is_permutation, in, in2, &Foo::binary_pred, &Bar::val, &Bar::val);
test(std::ranges::for_each, in, &Foo::unary_pred, &Bar::val);
std::ranges::for_each_n(in.begin(), count, &Foo::unary_pred, &Bar::val);
// `copy`, `copy_n` and `copy_backward` have neither a projection nor a predicate.
test(std::ranges::copy_if, in, out, &Foo::unary_pred, &Bar::val);
// `move` and `move_backward` have neither a projection nor a predicate.
// `fill` and `fill_n` have neither a projection nor a predicate.
{
std::array out_transform = {false, true, true};
test(std::ranges::transform, in, out_transform.begin(), &Foo::unary_pred, &Bar::val);
}
// Whether `ranges::generate{,_n}` invokes `gen` via `std::invoke` is not observable.
test(std::ranges::remove_copy, in, out, x, &Bar::val);
test(std::ranges::remove_copy_if, in, out, &Foo::unary_pred, &Bar::val);
// `replace*` algorithms only use the projection to compare the elements, not to write them.
test(std::ranges::replace, in, x, a, &Bar::val);
test(std::ranges::replace_if, in, &Foo::unary_pred, a, &Bar::val);
test(std::ranges::replace_copy, in, out, x, a, &Bar::val);
test(std::ranges::replace_copy_if, in, out, &Foo::unary_pred, a, &Bar::val);
// `swap_ranges` has neither a projection nor a predicate.
// `reverse_copy` has neither a projection nor a predicate.
// `rotate_copy` has neither a projection nor a predicate.
// `sample` has no requirement that the given generator be invoked via `std::invoke`.
test(std::ranges::unique_copy, in, out, &Foo::binary_pred, &Bar::val);
test(std::ranges::partition_copy, in, out, out2, &Foo::unary_pred, &Bar::val);
test(std::ranges::partial_sort_copy, in, in2, &Foo::binary_pred, &Bar::val, &Bar::val);
test(std::ranges::merge, in, in2, out, &Foo::binary_pred, &Bar::val, &Bar::val);
test(std::ranges::set_difference, in, in2, out, &Foo::binary_pred, &Bar::val, &Bar::val);
test(std::ranges::set_intersection, in, in2, out, &Foo::binary_pred, &Bar::val, &Bar::val);
test(std::ranges::set_symmetric_difference, in, in2, out, &Foo::binary_pred, &Bar::val, &Bar::val);
test(std::ranges::set_union, in, in2, out, &Foo::binary_pred, &Bar::val, &Bar::val);
test(std::ranges::remove, in, x, &Bar::val);
test(std::ranges::remove_if, in, &Foo::unary_pred, &Bar::val);
// `reverse` has neither a projection nor a predicate.
// `rotate` has neither a projection nor a predicate.
// `shuffle` has neither a projection nor a predicate.
test(std::ranges::unique, in, &Foo::binary_pred, &Bar::val);
test(std::ranges::partition, in, &Foo::unary_pred, &Bar::val);
if (!std::is_constant_evaluated())
test(std::ranges::stable_partition, in, &Foo::unary_pred, &Bar::val);
test(std::ranges::sort, in, &Foo::binary_pred, &Bar::val);
if (!std::is_constant_evaluated())
test(std::ranges::stable_sort, in, &Foo::binary_pred, &Bar::val);
test_mid(std::ranges::partial_sort, in, mid, &Foo::binary_pred, &Bar::val);
test_mid(std::ranges::nth_element, in, mid, &Foo::binary_pred, &Bar::val);
if (!std::is_constant_evaluated())
test_mid(std::ranges::inplace_merge, in, mid, &Foo::binary_pred, &Bar::val);
test(std::ranges::make_heap, in, &Foo::binary_pred, &Bar::val);
test(std::ranges::push_heap, in, &Foo::binary_pred, &Bar::val);
test(std::ranges::pop_heap, in, &Foo::binary_pred, &Bar::val);
test(std::ranges::sort_heap, in, &Foo::binary_pred, &Bar::val);
//test(std::ranges::prev_permutation, in, &Foo::binary_pred, &Bar::val);
//test(std::ranges::next_permutation, in, &Foo::binary_pred, &Bar::val);
return true;
}
int main(int, char**) {
test_all();
static_assert(test_all());
return 0;
}
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