//===----------------------------------------------------------------------===//
//
// The LLVM Compiler Infrastructure
//
// This file is dual licensed under the MIT and the University of Illinois Open
// Source Licenses. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
#ifndef SUPPORT_CHARCONV_TEST_HELPERS_H
#define SUPPORT_CHARCONV_TEST_HELPERS_H
#include <charconv>
#include <cassert>
#include <limits>
#include <string.h>
#include <stdlib.h>
#include "test_macros.h"
#if TEST_STD_VER <= 11
#error This file requires C++14
#endif
using std::false_type;
using std::true_type;
template <typename To, typename From>
constexpr auto
is_non_narrowing(From a) -> decltype(To{a}, true_type())
{
return {};
}
template <typename To>
constexpr auto
is_non_narrowing(...) -> false_type
{
return {};
}
template <typename X, typename T>
constexpr bool
_fits_in(T, true_type /* non-narrowing*/, ...)
{
return true;
}
template <typename X, typename T, typename xl = std::numeric_limits<X>>
constexpr bool
_fits_in(T v, false_type, true_type /* T signed*/, true_type /* X signed */)
{
return xl::lowest() <= v && v <= (xl::max)();
}
template <typename X, typename T, typename xl = std::numeric_limits<X>>
constexpr bool
_fits_in(T v, false_type, true_type /* T signed */, false_type /* X unsigned*/)
{
return 0 <= v && std::make_unsigned_t<T>(v) <= (xl::max)();
}
template <typename X, typename T, typename xl = std::numeric_limits<X>>
constexpr bool
_fits_in(T v, false_type, false_type /* T unsigned */, ...)
{
return v <= std::make_unsigned_t<X>((xl::max)());
}
template <typename X, typename T>
constexpr bool
fits_in(T v)
{
return _fits_in<X>(v, is_non_narrowing<X>(v), std::is_signed<T>(),
std::is_signed<X>());
}
template <typename X>
struct to_chars_test_base
{
template <typename T, size_t N, typename... Ts>
void test(T v, char const (&expect)[N], Ts... args)
{
using std::to_chars;
std::to_chars_result r;
constexpr size_t len = N - 1;
static_assert(len > 0, "expected output won't be empty");
if (!fits_in<X>(v))
return;
r = to_chars(buf, buf + len - 1, X(v), args...);
assert(r.ptr == buf + len - 1);
assert(r.ec == std::errc::value_too_large);
r = to_chars(buf, buf + sizeof(buf), X(v), args...);
assert(r.ptr == buf + len);
assert(r.ec == std::errc{});
assert(memcmp(buf, expect, len) == 0);
}
template <typename... Ts>
void test_value(X v, Ts... args)
{
using std::to_chars;
std::to_chars_result r;
r = to_chars(buf, buf + sizeof(buf), v, args...);
assert(r.ec == std::errc{});
*r.ptr = '\0';
auto a = fromchars(buf, r.ptr, args...);
assert(v == a);
auto ep = r.ptr - 1;
r = to_chars(buf, ep, v, args...);
assert(r.ptr == ep);
assert(r.ec == std::errc::value_too_large);
}
private:
static auto fromchars(char const* p, char const* ep, int base, true_type)
{
char* last;
auto r = strtoll(p, &last, base);
assert(last == ep);
return r;
}
static auto fromchars(char const* p, char const* ep, int base, false_type)
{
char* last;
auto r = strtoull(p, &last, base);
assert(last == ep);
return r;
}
static auto fromchars(char const* p, char const* ep, int base = 10)
{
return fromchars(p, ep, base, std::is_signed<X>());
}
char buf[100];
};
template <typename X>
struct roundtrip_test_base
{
template <typename T, typename... Ts>
void test(T v, Ts... args)
{
using std::from_chars;
using std::to_chars;
std::from_chars_result r2;
std::to_chars_result r;
X x = 0xc;
if (fits_in<X>(v))
{
r = to_chars(buf, buf + sizeof(buf), v, args...);
assert(r.ec == std::errc{});
r2 = from_chars(buf, r.ptr, x, args...);
assert(r2.ptr == r.ptr);
assert(x == X(v));
}
else
{
r = to_chars(buf, buf + sizeof(buf), v, args...);
assert(r.ec == std::errc{});
r2 = from_chars(buf, r.ptr, x, args...);
if (std::is_signed<T>::value && v < 0 && std::is_unsigned<X>::value)
{
assert(x == 0xc);
assert(r2.ptr == buf);
assert(r2.ec == std::errc::invalid_argument);
}
else
{
assert(x == 0xc);
assert(r2.ptr == r.ptr);
assert(r2.ec == std::errc::result_out_of_range);
}
}
}
private:
char buf[100];
};
template <typename... T>
struct type_list
{
};
template <typename L1, typename L2>
struct type_concat;
template <typename... Xs, typename... Ys>
struct type_concat<type_list<Xs...>, type_list<Ys...>>
{
using type = type_list<Xs..., Ys...>;
};
template <typename L1, typename L2>
using concat_t = typename type_concat<L1, L2>::type;
template <typename L1, typename L2>
constexpr auto concat(L1, L2) -> concat_t<L1, L2>
{
return {};
}
auto all_signed = type_list<char, signed char, short, int, long, long long>();
auto all_unsigned = type_list<unsigned char, unsigned short, unsigned int,
unsigned long, unsigned long long>();
auto integrals = concat(all_signed, all_unsigned);
template <template <typename> class Fn, typename... Ts>
void
run(type_list<Ts...>)
{
int ls[sizeof...(Ts)] = {(Fn<Ts>{}(), 0)...};
(void)ls;
}
#endif // SUPPORT_CHARCONV_TEST_HELPERS_H