//===----------------------------------------------------------------------===// // // 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, c++20 // friend constexpr bool operator==(const iterator& x, const iterator& y) // requires (equality_comparable>> && ...); // friend constexpr auto operator<=>(const iterator& x, const iterator& y) // requires all-random-access; #include #include #include "test_iterators.h" #include "test_range.h" #include "../types.h" // This is for testing that zip iterator never calls underlying iterator's >, >=, <=, !=. // The spec indicates that zip iterator's >= is negating zip iterator's < instead of calling underlying iterator's >=. // Declare all the operations >, >=, <= etc to make it satisfy random_access_iterator concept, // but not define them. If the zip iterator's >,>=, <=, etc isn't implemented in the way defined by the standard // but instead calling underlying iterator's >,>=,<=, we will get a linker error for the runtime tests and // non-constant expression for the compile time tests. struct LessThanIterator { int* it_ = nullptr; LessThanIterator() = default; constexpr LessThanIterator(int* it) : it_(it) {} using iterator_category = std::random_access_iterator_tag; using value_type = int; using difference_type = std::intptr_t; constexpr int& operator*() const { return *it_; } constexpr int& operator[](difference_type n) const { return it_[n]; } constexpr LessThanIterator& operator++() { ++it_; return *this; } constexpr LessThanIterator& operator--() { --it_; return *this; } constexpr LessThanIterator operator++(int) { return LessThanIterator(it_++); } constexpr LessThanIterator operator--(int) { return LessThanIterator(it_--); } constexpr LessThanIterator& operator+=(difference_type n) { it_ += n; return *this; } constexpr LessThanIterator& operator-=(difference_type n) { it_ -= n; return *this; } constexpr friend LessThanIterator operator+(LessThanIterator x, difference_type n) { x += n; return x; } constexpr friend LessThanIterator operator+(difference_type n, LessThanIterator x) { x += n; return x; } constexpr friend LessThanIterator operator-(LessThanIterator x, difference_type n) { x -= n; return x; } constexpr friend difference_type operator-(LessThanIterator x, LessThanIterator y) { return x.it_ - y.it_; } constexpr friend bool operator==(LessThanIterator const&, LessThanIterator const&) = default; friend bool operator!=(LessThanIterator const&, LessThanIterator const&); constexpr friend bool operator<(LessThanIterator const& x, LessThanIterator const& y) { return x.it_ < y.it_; } friend bool operator<=(LessThanIterator const&, LessThanIterator const&); friend bool operator>(LessThanIterator const&, LessThanIterator const&); friend bool operator>=(LessThanIterator const&, LessThanIterator const&); }; static_assert(std::random_access_iterator); struct SmallerThanRange : IntBufferView { using IntBufferView::IntBufferView; constexpr LessThanIterator begin() const { return {buffer_}; } constexpr LessThanIterator end() const { return {buffer_ + size_}; } }; static_assert(std::ranges::random_access_range); struct ForwardCommonView : IntBufferView { using IntBufferView::IntBufferView; using iterator = forward_iterator; constexpr iterator begin() const { return iterator(buffer_); } constexpr iterator end() const { return iterator(buffer_ + size_); } }; constexpr void compareOperatorTest(auto&& iter1, auto&& iter2) { assert(!(iter1 < iter1)); assert(iter1 < iter2); assert(!(iter2 < iter1)); assert(iter1 <= iter1); assert(iter1 <= iter2); assert(!(iter2 <= iter1)); assert(!(iter1 > iter1)); assert(!(iter1 > iter2)); assert(iter2 > iter1); assert(iter1 >= iter1); assert(!(iter1 >= iter2)); assert(iter2 >= iter1); assert(iter1 == iter1); assert(!(iter1 == iter2)); assert(iter2 == iter2); assert(!(iter1 != iter1)); assert(iter1 != iter2); assert(!(iter2 != iter2)); } constexpr void inequalityOperatorsDoNotExistTest(auto&& iter1, auto&& iter2) { using Iter1 = decltype(iter1); using Iter2 = decltype(iter2); static_assert(!std::is_invocable_v, Iter1, Iter2>); static_assert(!std::is_invocable_v, Iter1, Iter2>); static_assert(!std::is_invocable_v, Iter1, Iter2>); static_assert(!std::is_invocable_v, Iter1, Iter2>); } constexpr bool test() { { // Test a new-school iterator with operator<=>; the iterator should also have operator<=>. using It = three_way_contiguous_iterator; using SubRange = std::ranges::subrange; static_assert(std::three_way_comparable); using R = std::ranges::zip_view; static_assert(std::three_way_comparable>); int a[] = {1, 2, 3, 4}; int b[] = {5, 6, 7, 8, 9}; auto r = std::views::zip(SubRange(It(a), It(a + 4)), SubRange(It(b), It(b + 5))); auto iter1 = r.begin(); auto iter2 = iter1 + 1; compareOperatorTest(iter1, iter2); assert((iter1 <=> iter2) == std::strong_ordering::less); assert((iter1 <=> iter1) == std::strong_ordering::equal); assert((iter2 <=> iter1) == std::strong_ordering::greater); } { // Test an old-school iterator with no operator<=>; the transform iterator shouldn't have // operator<=> either. using It = random_access_iterator; using Subrange = std::ranges::subrange; static_assert(!std::three_way_comparable); using R = std::ranges::zip_view; static_assert(std::three_way_comparable>); int a[] = {1, 2, 3, 4}; int b[] = {5, 6, 7, 8, 9}; auto r = std::views::zip(Subrange(It(a), It(a + 4)), Subrange(It(b), It(b + 5))); auto iter1 = r.begin(); auto iter2 = iter1 + 1; compareOperatorTest(iter1, iter2); } { // non random_access_range int buffer1[1] = {1}; int buffer2[2] = {1, 2}; std::ranges::zip_view v{InputCommonView(buffer1), InputCommonView(buffer2)}; using View = decltype(v); static_assert(!std::ranges::forward_range); static_assert(std::ranges::input_range); static_assert(std::ranges::common_range); auto it1 = v.begin(); auto it2 = v.end(); assert(it1 != it2); ++it1; assert(it1 == it2); inequalityOperatorsDoNotExistTest(it1, it2); } { // in this case sentinel is computed by getting each of the underlying sentinel, so only one // underlying iterator is comparing equal int buffer1[1] = {1}; int buffer2[2] = {1, 2}; std::ranges::zip_view v{ForwardCommonView(buffer1), ForwardCommonView(buffer2)}; using View = decltype(v); static_assert(std::ranges::common_range); static_assert(!std::ranges::bidirectional_range); auto it1 = v.begin(); auto it2 = v.end(); assert(it1 != it2); ++it1; // it1: // it2: assert(it1 == it2); inequalityOperatorsDoNotExistTest(it1, it2); } { // only < and == are needed int a[] = {1, 2, 3, 4}; int b[] = {5, 6, 7, 8, 9}; auto r = std::views::zip(SmallerThanRange(a), SmallerThanRange(b)); auto iter1 = r.begin(); auto iter2 = iter1 + 1; compareOperatorTest(iter1, iter2); } { // underlying iterator does not support == using IterNoEqualView = BasicView, sentinel_wrapper>>; int buffer[] = {1}; std::ranges::zip_view r(IterNoEqualView{buffer}); auto it = r.begin(); using Iter = decltype(it); static_assert(!weakly_equality_comparable_with); inequalityOperatorsDoNotExistTest(it, it); } return true; } int main(int, char**) { test(); static_assert(test()); return 0; }