Louis Dionne 31cbe0f240 [libc++] Remove the c++98 Lit feature from the test suite
C++98 and C++03 are effectively aliases as far as Clang is concerned.
As such, allowing both std=c++98 and std=c++03 as Lit parameters is
just slightly confusing, but provides no value. It's similar to allowing
both std=c++17 and std=c++1z, which we don't do.

This was discovered because we had an internal bot that ran the test
suite under both c++98 AND c++03 -- one of which is redundant.

Differential Revision: https://reviews.llvm.org/D80926
2020-06-03 09:37:22 -04:00

138 lines
4.0 KiB
C++

// -*- C++ -*-
//===------------------------------ span ---------------------------------===//
//
// 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
// <span>
// template<size_t Count>
// constexpr span<element_type, Count> last() const;
//
// constexpr span<element_type, dynamic_extent> last(size_type count) const;
//
// Requires: Count <= size().
#include <span>
#include <cassert>
#include <algorithm>
#include <string>
#include "test_macros.h"
template <typename Span, size_t Count>
constexpr bool testConstexprSpan(Span sp)
{
LIBCPP_ASSERT((noexcept(sp.template last<Count>())));
LIBCPP_ASSERT((noexcept(sp.last(Count))));
auto s1 = sp.template last<Count>();
auto s2 = sp.last(Count);
using S1 = decltype(s1);
using S2 = decltype(s2);
ASSERT_SAME_TYPE(typename Span::value_type, typename S1::value_type);
ASSERT_SAME_TYPE(typename Span::value_type, typename S2::value_type);
static_assert(S1::extent == Count, "");
static_assert(S2::extent == std::dynamic_extent, "");
return
s1.data() == s2.data()
&& s1.size() == s2.size()
&& std::equal(s1.begin(), s1.end(), sp.end() - Count);
}
template <typename Span, size_t Count>
void testRuntimeSpan(Span sp)
{
LIBCPP_ASSERT((noexcept(sp.template last<Count>())));
LIBCPP_ASSERT((noexcept(sp.last(Count))));
auto s1 = sp.template last<Count>();
auto s2 = sp.last(Count);
using S1 = decltype(s1);
using S2 = decltype(s2);
ASSERT_SAME_TYPE(typename Span::value_type, typename S1::value_type);
ASSERT_SAME_TYPE(typename Span::value_type, typename S2::value_type);
static_assert(S1::extent == Count, "");
static_assert(S2::extent == std::dynamic_extent, "");
assert(s1.data() == s2.data());
assert(s1.size() == s2.size());
assert(std::equal(s1.begin(), s1.end(), sp.end() - Count));
}
constexpr int carr1[] = {1,2,3,4};
int arr[] = {5,6,7};
std::string sarr [] = { "ABC", "DEF", "GHI", "JKL", "MNO"};
int main(int, char**)
{
{
using Sp = std::span<const int>;
static_assert(testConstexprSpan<Sp, 0>(Sp{}), "");
static_assert(testConstexprSpan<Sp, 0>(Sp{carr1}), "");
static_assert(testConstexprSpan<Sp, 1>(Sp{carr1}), "");
static_assert(testConstexprSpan<Sp, 2>(Sp{carr1}), "");
static_assert(testConstexprSpan<Sp, 3>(Sp{carr1}), "");
static_assert(testConstexprSpan<Sp, 4>(Sp{carr1}), "");
}
{
using Sp = std::span<const int, 4>;
static_assert(testConstexprSpan<Sp, 0>(Sp{carr1}), "");
static_assert(testConstexprSpan<Sp, 1>(Sp{carr1}), "");
static_assert(testConstexprSpan<Sp, 2>(Sp{carr1}), "");
static_assert(testConstexprSpan<Sp, 3>(Sp{carr1}), "");
static_assert(testConstexprSpan<Sp, 4>(Sp{carr1}), "");
}
{
using Sp = std::span<int>;
testRuntimeSpan<Sp, 0>(Sp{});
testRuntimeSpan<Sp, 0>(Sp{arr});
testRuntimeSpan<Sp, 1>(Sp{arr});
testRuntimeSpan<Sp, 2>(Sp{arr});
testRuntimeSpan<Sp, 3>(Sp{arr});
}
{
using Sp = std::span<int, 3>;
testRuntimeSpan<Sp, 0>(Sp{arr});
testRuntimeSpan<Sp, 1>(Sp{arr});
testRuntimeSpan<Sp, 2>(Sp{arr});
testRuntimeSpan<Sp, 3>(Sp{arr});
}
{
using Sp = std::span<std::string>;
testConstexprSpan<Sp, 0>(Sp{});
testRuntimeSpan<Sp, 0>(Sp{sarr});
testRuntimeSpan<Sp, 1>(Sp{sarr});
testRuntimeSpan<Sp, 2>(Sp{sarr});
testRuntimeSpan<Sp, 3>(Sp{sarr});
testRuntimeSpan<Sp, 4>(Sp{sarr});
testRuntimeSpan<Sp, 5>(Sp{sarr});
}
{
using Sp = std::span<std::string, 5>;
testRuntimeSpan<Sp, 0>(Sp{sarr});
testRuntimeSpan<Sp, 1>(Sp{sarr});
testRuntimeSpan<Sp, 2>(Sp{sarr});
testRuntimeSpan<Sp, 3>(Sp{sarr});
testRuntimeSpan<Sp, 4>(Sp{sarr});
testRuntimeSpan<Sp, 5>(Sp{sarr});
}
return 0;
}