//===----------------------------------------------------------------------===//
//
// 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
// In the modules build, adding another overload of `memmove` doesn't work.
// UNSUPPORTED: clang-modules-build
// GCC complains about "ambiguating" `__builtin_memmove`.
// UNSUPPORTED: gcc
// <algorithm>
#include <cassert>
#include <cstddef>
// These tests check that `std::copy` and `std::move` (including their variations like `copy_n`) don't forward to
// `std::memmove` when doing so would be observable.
// This template is a better match than the actual `builtin_memmove` (it can match the pointer type exactly, without an
// implicit conversion to `void*`), so it should hijack the call inside `std::copy` and similar algorithms if it's made.
template <class Dst, class Src>
constexpr void* __builtin_memmove(Dst*, Src*, std::size_t) {
assert(false);
return nullptr;
}
#include <algorithm>
#include <cassert>
#include <cstdint>
#include <iterator>
#include <ranges>
#include <type_traits>
#include "test_iterators.h"
#include "test_macros.h"
// S1 and S2 are simple structs that are convertible to each other and have the same bit representation.
struct S1 {
int x;
constexpr S1() = default;
constexpr S1(int set_x) : x(set_x) {}
friend constexpr bool operator==(const S1& lhs, const S1& rhs) { return lhs.x == rhs.x; }
};
struct S2 {
int x;
constexpr S2() = default;
constexpr S2(int set_x) : x(set_x) {}
constexpr S2(S1 from) : x(from.x) {}
friend constexpr bool operator==(const S1& lhs, const S2& rhs) { return lhs.x == rhs.x; }
friend constexpr bool operator==(const S2& lhs, const S2& rhs) { return lhs.x == rhs.x; }
};
// U1 and U2 are simple unions that are convertible to each other and have the same bit representation.
union U1 {
int x;
constexpr U1() = default;
constexpr U1(int set_x) : x(set_x) {}
friend constexpr bool operator==(const U1& lhs, const U1& rhs) { return lhs.x == rhs.x; }
};
union U2 {
int x;
constexpr U2() = default;
constexpr U2(int set_x) : x(set_x) {}
constexpr U2(U1 from) : x(from.x) {}
friend constexpr bool operator==(const U1& lhs, const U2& rhs) { return lhs.x == rhs.x; }
friend constexpr bool operator==(const U2& lhs, const U2& rhs) { return lhs.x == rhs.x; }
};
struct NonTrivialMoveAssignment {
int i;
constexpr NonTrivialMoveAssignment() = default;
constexpr NonTrivialMoveAssignment(int set_i) : i(set_i) {}
constexpr NonTrivialMoveAssignment(NonTrivialMoveAssignment&& rhs) = default;
constexpr NonTrivialMoveAssignment& operator=(NonTrivialMoveAssignment&& rhs) noexcept {
i = rhs.i;
return *this;
}
constexpr friend bool operator==(const NonTrivialMoveAssignment&, const NonTrivialMoveAssignment&) = default;
};
static_assert(!std::is_trivially_move_assignable_v<NonTrivialMoveAssignment>);
static_assert(!std::is_trivially_assignable<NonTrivialMoveAssignment&, NonTrivialMoveAssignment&>::value);
struct NonTrivialMoveCtr {
int i;
constexpr NonTrivialMoveCtr() = default;
constexpr NonTrivialMoveCtr(int set_i) : i(set_i) {}
constexpr NonTrivialMoveCtr(NonTrivialMoveCtr&& rhs) noexcept : i(rhs.i) {}
constexpr NonTrivialMoveCtr& operator=(NonTrivialMoveCtr&& rhs) = default;
constexpr friend bool operator==(const NonTrivialMoveCtr&, const NonTrivialMoveCtr&) = default;
};
static_assert(std::is_trivially_move_assignable_v<NonTrivialMoveCtr>);
static_assert(!std::is_trivially_copyable_v<NonTrivialMoveCtr>);
struct NonTrivialCopyAssignment {
int i;
constexpr NonTrivialCopyAssignment() = default;
constexpr NonTrivialCopyAssignment(int set_i) : i(set_i) {}
constexpr NonTrivialCopyAssignment(const NonTrivialCopyAssignment& rhs) = default;
constexpr NonTrivialCopyAssignment& operator=(const NonTrivialCopyAssignment& rhs) {
i = rhs.i;
return *this;
}
constexpr friend bool operator==(const NonTrivialCopyAssignment&, const NonTrivialCopyAssignment&) = default;
};
static_assert(!std::is_trivially_copy_assignable_v<NonTrivialCopyAssignment>);
struct NonTrivialCopyCtr {
int i;
constexpr NonTrivialCopyCtr() = default;
constexpr NonTrivialCopyCtr(int set_i) : i(set_i) {}
constexpr NonTrivialCopyCtr(const NonTrivialCopyCtr& rhs) : i(rhs.i) {}
constexpr NonTrivialCopyCtr& operator=(const NonTrivialCopyCtr& rhs) = default;
constexpr friend bool operator==(const NonTrivialCopyCtr&, const NonTrivialCopyCtr&) = default;
};
static_assert(std::is_trivially_copy_assignable_v<NonTrivialCopyCtr>);
static_assert(!std::is_trivially_copyable_v<NonTrivialCopyCtr>);
template <class T>
constexpr T make(int from) {
return T(from);
}
template <typename PtrT, typename T = std::remove_pointer_t<PtrT>>
static T make_internal_array[5] = {T(), T(), T(), T(), T()};
template <class T>
requires std::is_pointer_v<T>
constexpr T make(int i) {
if constexpr (!std::same_as<std::remove_pointer_t<T>, void>) {
return make_internal_array<T> + i;
} else {
return make_internal_array<int> + i;
}
}
template <class InIter, template <class> class SentWrapper, class OutIter, class Func>
constexpr void test_one(Func func) {
using From = typename std::iterator_traits<InIter>::value_type;
using To = typename std::iterator_traits<OutIter>::value_type;
{
const std::size_t N = 5;
From input[N] = {make<From>(0), make<From>(1), make<From>(2), make<From>(3), make<From>(4)};
To output[N];
auto in = InIter(input);
auto in_end = InIter(input + N);
auto sent = SentWrapper<decltype(in_end)>(in_end);
auto out = OutIter(output);
func(in, sent, out, N);
if constexpr (!std::same_as<To, bool>) {
assert(std::equal(input, input + N, output));
} else {
bool expected[N] = {false, true, true, true, true};
assert(std::equal(output, output + N, expected));
}
}
{
const std::size_t N = 0;
From input[1] = {make<From>(1)};
To output[1] = {make<To>(2)};
auto in = InIter(input);
auto in_end = InIter(input + N);
auto sent = SentWrapper<decltype(in_end)>(in_end);
auto out = OutIter(output);
func(in, sent, out, N);
assert(output[0] == make<To>(2));
}
}
template <class InIter, template <class> class SentWrapper, class OutIter>
constexpr void test_copy() {
// Classic.
if constexpr (std::same_as<InIter, SentWrapper<InIter>>) {
test_one<InIter, SentWrapper, OutIter>([](auto first, auto last, auto out, std::size_t) {
std::copy(first, last, out);
});
test_one<InIter, SentWrapper, OutIter>([](auto first, auto last, auto out, std::size_t n) {
std::copy_backward(first, last, out + n);
});
test_one<InIter, SentWrapper, OutIter>([](auto first, auto, auto out, std::size_t n) {
std::copy_n(first, n, out);
});
}
// Ranges.
test_one<InIter, SentWrapper, OutIter>([](auto first, auto last, auto out, std::size_t) {
std::ranges::copy(first, last, out);
});
test_one<InIter, SentWrapper, OutIter>([](auto first, auto last, auto out, std::size_t n) {
std::ranges::copy_backward(first, last, out + n);
});
test_one<InIter, SentWrapper, OutIter>([](auto first, auto, auto out, std::size_t n) {
std::ranges::copy_n(first, n, out);
});
}
template <class InIter, template <class> class SentWrapper, class OutIter>
constexpr void test_move() {
if constexpr (std::same_as<InIter, SentWrapper<InIter>>) {
test_one<InIter, SentWrapper, OutIter>([](auto first, auto last, auto out, std::size_t) {
std::move(first, last, out);
});
test_one<InIter, SentWrapper, OutIter>([](auto first, auto last, auto out, std::size_t n) {
std::move_backward(first, last, out + n);
});
}
// Ranges.
test_one<InIter, SentWrapper, OutIter>([](auto first, auto last, auto out, std::size_t) {
std::ranges::move(first, last, out);
});
test_one<InIter, SentWrapper, OutIter>([](auto first, auto last, auto out, std::size_t n) {
std::ranges::move_backward(first, last, out + n);
});
}
template <class From, class To = From>
constexpr void test_copy_with_type() {
using FromIter = contiguous_iterator<From*>;
using ToIter = contiguous_iterator<To*>;
test_copy<FromIter, std::type_identity_t, ToIter>();
test_copy<FromIter, sized_sentinel, ToIter>();
test_copy<FromIter, std::type_identity_t, To*>();
test_copy<From*, std::type_identity_t, To*>();
test_copy<From*, std::type_identity_t, ToIter>();
}
template <class From, class To = From>
constexpr void test_move_with_type() {
using FromIter = contiguous_iterator<From*>;
using ToIter = contiguous_iterator<To*>;
test_move<FromIter, std::type_identity_t, ToIter>();
test_move<FromIter, sized_sentinel, ToIter>();
test_move<FromIter, std::type_identity_t, To*>();
test_move<From*, std::type_identity_t, To*>();
test_move<From*, std::type_identity_t, ToIter>();
}
template <class From, class To>
constexpr void test_copy_and_move() {
test_copy_with_type<From, To>();
test_move_with_type<From, To>();
}
template <class From, class To>
constexpr void test_both_directions() {
test_copy_and_move<From, To>();
if (!std::same_as<From, To>) {
test_copy_and_move<To, From>();
}
}
constexpr bool test() {
test_copy_with_type<NonTrivialCopyAssignment>();
test_move_with_type<NonTrivialMoveAssignment>();
// Copying from a smaller type into a larger type and vice versa.
test_both_directions<char, int>();
test_both_directions<std::int32_t, std::int64_t>();
// Copying between types with different representations.
test_both_directions<int, float>();
// Copying from `bool` to `char` will invoke the optimization, so only check one direction.
test_copy_and_move<char, bool>();
// Copying between different structs with the same representation (there is no way to guarantee the representation is
// the same).
test_copy_and_move<S1, S2>();
// Copying between different unions with the same representation.
test_copy_and_move<U1, U2>();
// Copying from a regular pointer to a void pointer (these are not considered trivially copyable).
test_copy_and_move<int*, void*>();
// Copying from a non-const pointer to a const pointer (these are not considered trivially copyable).
test_copy_and_move<int*, const int*>();
// `memmove` does not support volatile pointers.
// (See also https://github.com/llvm/llvm-project/issues/28901).
if (!std::is_constant_evaluated()) {
test_both_directions<volatile int, int>();
test_both_directions<volatile int, volatile int>();
}
return true;
}
int main(int, char**) {
test();
static_assert(test());
return 0;
}