gecko-dev/mfbt/tests/TestTypedEnum.cpp

571 строка
20 KiB
C++

/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
#include "mozilla/Assertions.h"
#include "mozilla/Attributes.h"
#include "mozilla/TypedEnum.h"
#include "mozilla/TypedEnumBits.h"
#include <stdint.h>
// A rough feature check for is_literal_type. Not very carefully checked.
// Feel free to amend as needed.
// We leave ANDROID out because it's using stlport which doesn't have std::is_literal_type.
#if __cplusplus >= 201103L && !defined(ANDROID)
# if defined(__clang__)
/*
* Per Clang documentation, "Note that marketing version numbers should not
* be used to check for language features, as different vendors use different
* numbering schemes. Instead, use the feature checking macros."
*/
# ifndef __has_extension
# define __has_extension __has_feature /* compatibility, for older versions of clang */
# endif
# if __has_extension(is_literal) && __has_include(<type_traits>)
# define MOZ_HAVE_IS_LITERAL
# endif
# elif defined(__GNUC__)
# if defined(__GXX_EXPERIMENTAL_CXX0X__)
# if MOZ_GCC_VERSION_AT_LEAST(4, 6, 0)
# define MOZ_HAVE_IS_LITERAL
# endif
# endif
# elif defined(_MSC_VER)
# if _MSC_VER >= 1700
# define MOZ_HAVE_IS_LITERAL
# endif
# endif
#endif
#if defined(MOZ_HAVE_IS_LITERAL) && defined(MOZ_HAVE_CXX11_CONSTEXPR)
#include <type_traits>
template<typename T>
void
RequireLiteralType()
{
static_assert(std::is_literal_type<T>::value, "Expected a literal type");
}
#else // not MOZ_HAVE_IS_LITERAL
template<typename T>
void
RequireLiteralType()
{
}
#endif
template<typename T>
void
RequireLiteralType(const T&)
{
RequireLiteralType<T>();
}
MOZ_BEGIN_ENUM_CLASS(AutoEnum)
A,
B = -3,
C
MOZ_END_ENUM_CLASS(AutoEnum)
MOZ_BEGIN_ENUM_CLASS(CharEnum, char)
A,
B = 3,
C
MOZ_END_ENUM_CLASS(CharEnum)
MOZ_BEGIN_ENUM_CLASS(AutoEnumBitField)
A = 0x10,
B = 0x20,
C
MOZ_END_ENUM_CLASS(AutoEnumBitField)
MOZ_BEGIN_ENUM_CLASS(CharEnumBitField, char)
A = 0x10,
B,
C = 0x40
MOZ_END_ENUM_CLASS(CharEnumBitField)
struct Nested
{
MOZ_BEGIN_NESTED_ENUM_CLASS(AutoEnum)
A,
B,
C = -1
MOZ_END_NESTED_ENUM_CLASS(AutoEnum)
MOZ_BEGIN_NESTED_ENUM_CLASS(CharEnum, char)
A = 4,
B,
C = 1
MOZ_END_NESTED_ENUM_CLASS(CharEnum)
MOZ_BEGIN_NESTED_ENUM_CLASS(AutoEnumBitField)
A,
B = 0x20,
C
MOZ_END_NESTED_ENUM_CLASS(AutoEnumBitField)
MOZ_BEGIN_NESTED_ENUM_CLASS(CharEnumBitField, char)
A = 1,
B = 1,
C = 1
MOZ_END_NESTED_ENUM_CLASS(CharEnumBitField)
};
MOZ_MAKE_ENUM_CLASS_BITWISE_OPERATORS(AutoEnumBitField)
MOZ_MAKE_ENUM_CLASS_BITWISE_OPERATORS(CharEnumBitField)
MOZ_MAKE_ENUM_CLASS_BITWISE_OPERATORS(Nested::AutoEnumBitField)
MOZ_MAKE_ENUM_CLASS_BITWISE_OPERATORS(Nested::CharEnumBitField)
#define MAKE_STANDARD_BITFIELD_FOR_TYPE(IntType) \
MOZ_BEGIN_ENUM_CLASS(BitFieldFor_##IntType, IntType) \
A = 1, \
B = 2, \
C = 4, \
MOZ_END_ENUM_CLASS(BitFieldFor_##IntType) \
MOZ_MAKE_ENUM_CLASS_BITWISE_OPERATORS(BitFieldFor_##IntType)
MAKE_STANDARD_BITFIELD_FOR_TYPE(int8_t)
MAKE_STANDARD_BITFIELD_FOR_TYPE(uint8_t)
MAKE_STANDARD_BITFIELD_FOR_TYPE(int16_t)
MAKE_STANDARD_BITFIELD_FOR_TYPE(uint16_t)
MAKE_STANDARD_BITFIELD_FOR_TYPE(int32_t)
MAKE_STANDARD_BITFIELD_FOR_TYPE(uint32_t)
MAKE_STANDARD_BITFIELD_FOR_TYPE(int64_t)
MAKE_STANDARD_BITFIELD_FOR_TYPE(uint64_t)
MAKE_STANDARD_BITFIELD_FOR_TYPE(char)
typedef signed char signed_char;
MAKE_STANDARD_BITFIELD_FOR_TYPE(signed_char)
typedef unsigned char unsigned_char;
MAKE_STANDARD_BITFIELD_FOR_TYPE(unsigned_char)
MAKE_STANDARD_BITFIELD_FOR_TYPE(short)
typedef unsigned short unsigned_short;
MAKE_STANDARD_BITFIELD_FOR_TYPE(unsigned_short)
MAKE_STANDARD_BITFIELD_FOR_TYPE(int)
typedef unsigned int unsigned_int;
MAKE_STANDARD_BITFIELD_FOR_TYPE(unsigned_int)
MAKE_STANDARD_BITFIELD_FOR_TYPE(long)
typedef unsigned long unsigned_long;
MAKE_STANDARD_BITFIELD_FOR_TYPE(unsigned_long)
typedef long long long_long;
MAKE_STANDARD_BITFIELD_FOR_TYPE(long_long)
typedef unsigned long long unsigned_long_long;
MAKE_STANDARD_BITFIELD_FOR_TYPE(unsigned_long_long)
#undef MAKE_STANDARD_BITFIELD_FOR_TYPE
template<typename T>
void
TestNonConvertibilityForOneType()
{
using mozilla::IsConvertible;
#if defined(MOZ_HAVE_CXX11_STRONG_ENUMS) && defined(MOZ_HAVE_EXPLICIT_CONVERSION)
static_assert(!IsConvertible<T, bool>::value, "should not be convertible");
static_assert(!IsConvertible<T, int>::value, "should not be convertible");
static_assert(!IsConvertible<T, uint64_t>::value, "should not be convertible");
#endif
static_assert(!IsConvertible<bool, T>::value, "should not be convertible");
static_assert(!IsConvertible<int, T>::value, "should not be convertible");
static_assert(!IsConvertible<uint64_t, T>::value, "should not be convertible");
}
template<typename TypedEnum>
void
TestTypedEnumBasics()
{
const TypedEnum a = TypedEnum::A;
int unused = int(a);
(void) unused;
RequireLiteralType(TypedEnum::A);
RequireLiteralType(a);
TestNonConvertibilityForOneType<TypedEnum>();
}
// Op wraps a bitwise binary operator, passed as a char template parameter,
// and applies it to its arguments (t1, t2). For example,
//
// Op<'|'>(t1, t2)
//
// is the same as
//
// t1 | t2.
//
template<char o, typename T1, typename T2>
auto Op(const T1& t1, const T2& t2)
-> decltype(t1 | t2) // See the static_assert's below --- the return type
// depends solely on the operands type, not on the
// choice of operation.
{
using mozilla::IsSame;
static_assert(IsSame<decltype(t1 | t2), decltype(t1 & t2)>::value,
"binary ops should have the same result type");
static_assert(IsSame<decltype(t1 | t2), decltype(t1 ^ t2)>::value,
"binary ops should have the same result type");
static_assert(o == '|' ||
o == '&' ||
o == '^', "unexpected operator character");
return o == '|' ? t1 | t2
: o == '&' ? t1 & t2
: t1 ^ t2;
}
// OpAssign wraps a bitwise binary operator, passed as a char template
// parameter, and applies the corresponding compound-assignment operator to its
// arguments (t1, t2). For example,
//
// OpAssign<'|'>(t1, t2)
//
// is the same as
//
// t1 |= t2.
//
template<char o, typename T1, typename T2>
T1& OpAssign(T1& t1, const T2& t2)
{
static_assert(o == '|' ||
o == '&' ||
o == '^', "unexpected operator character");
switch (o) {
case '|': return t1 |= t2;
case '&': return t1 &= t2;
case '^': return t1 ^= t2;
default: MOZ_CRASH();
}
}
// Tests a single binary bitwise operator, using a single set of three operands.
// The operations tested are:
//
// result = t1 Op t2;
// result Op= t3;
//
// Where Op is the operator specified by the char template parameter 'o' and can
// be any of '|', '&', '^'.
//
// Note that the operands t1, t2, t3 are intentionally passed with free types
// (separate template parameters for each) because their type may actually be
// different from TypedEnum:
// 1) Their type could be CastableTypedEnumResult<TypedEnum> if they are
// the result of a bitwise operation themselves;
// 2) In the non-c++11 legacy path, the type of enum values is also
// different from TypedEnum.
//
template<typename TypedEnum, char o, typename T1, typename T2, typename T3>
void TestBinOp(const T1& t1, const T2& t2, const T3& t3)
{
typedef typename mozilla::detail::UnsignedIntegerTypeForEnum<TypedEnum>::Type
UnsignedIntegerType;
// Part 1:
// Test the bitwise binary operator i.e.
// result = t1 Op t2;
auto result = Op<o>(t1, t2);
typedef decltype(result) ResultType;
RequireLiteralType<ResultType>();
TestNonConvertibilityForOneType<ResultType>();
UnsignedIntegerType unsignedIntegerResult
= Op<o>(UnsignedIntegerType(t1), UnsignedIntegerType(t2));
MOZ_RELEASE_ASSERT(unsignedIntegerResult == UnsignedIntegerType(result));
MOZ_RELEASE_ASSERT(TypedEnum(unsignedIntegerResult) == TypedEnum(result));
MOZ_RELEASE_ASSERT((!unsignedIntegerResult) == (!result));
MOZ_RELEASE_ASSERT((!!unsignedIntegerResult) == (!!result));
MOZ_RELEASE_ASSERT(bool(unsignedIntegerResult) == bool(result));
// Part 2:
// Test the compound-assignment operator, i.e.
// result Op= t3;
TypedEnum newResult = result;
OpAssign<o>(newResult, t3);
UnsignedIntegerType unsignedIntegerNewResult = unsignedIntegerResult;
OpAssign<o>(unsignedIntegerNewResult, UnsignedIntegerType(t3));
MOZ_RELEASE_ASSERT(TypedEnum(unsignedIntegerNewResult) == newResult);
// Part 3:
// Test additional boolean operators that we unfortunately had to add to
// CastableTypedEnumResult at some point to please some compiler,
// even though bool convertibility should have been enough.
MOZ_RELEASE_ASSERT(result == TypedEnum(result));
MOZ_RELEASE_ASSERT(!(result != TypedEnum(result)));
MOZ_RELEASE_ASSERT((result && true) == bool(result));
MOZ_RELEASE_ASSERT((result && false) == false);
MOZ_RELEASE_ASSERT((true && result) == bool(result));
MOZ_RELEASE_ASSERT((false && result && false) == false);
MOZ_RELEASE_ASSERT((result || false) == bool(result));
MOZ_RELEASE_ASSERT((result || true) == true);
MOZ_RELEASE_ASSERT((false || result) == bool(result));
MOZ_RELEASE_ASSERT((true || result) == true);
}
// Similar to TestBinOp but testing the unary ~ operator.
template<typename TypedEnum, typename T>
void TestTilde(const T& t)
{
typedef typename mozilla::detail::UnsignedIntegerTypeForEnum<TypedEnum>::Type
UnsignedIntegerType;
auto result = ~t;
typedef decltype(result) ResultType;
RequireLiteralType<ResultType>();
TestNonConvertibilityForOneType<ResultType>();
UnsignedIntegerType unsignedIntegerResult = ~(UnsignedIntegerType(t));
MOZ_RELEASE_ASSERT(unsignedIntegerResult == UnsignedIntegerType(result));
MOZ_RELEASE_ASSERT(TypedEnum(unsignedIntegerResult) == TypedEnum(result));
MOZ_RELEASE_ASSERT((!unsignedIntegerResult) == (!result));
MOZ_RELEASE_ASSERT((!!unsignedIntegerResult) == (!!result));
MOZ_RELEASE_ASSERT(bool(unsignedIntegerResult) == bool(result));
}
// Helper dispatching a given triple of operands to all operator-specific
// testing functions.
template<typename TypedEnum, typename T1, typename T2, typename T3>
void TestAllOpsForGivenOperands(const T1& t1, const T2& t2, const T3& t3)
{
TestBinOp<TypedEnum, '|'>(t1, t2, t3);
TestBinOp<TypedEnum, '&'>(t1, t2, t3);
TestBinOp<TypedEnum, '^'>(t1, t2, t3);
TestTilde<TypedEnum>(t1);
}
// Helper building various triples of operands using a given operator,
// and testing all operators with them.
template<typename TypedEnum, char o>
void TestAllOpsForOperandsBuiltUsingGivenOp()
{
// The type of enum values like TypedEnum::A may be different from
// TypedEnum. That is the case in the legacy non-C++11 path. We want to
// ensure good test coverage even when these two types are distinct.
// To that effect, we have both 'auto' typed variables, preserving the
// original type of enum values, and 'plain' typed variables, that
// are plain TypedEnum's.
const TypedEnum a_plain = TypedEnum::A;
const TypedEnum b_plain = TypedEnum::B;
const TypedEnum c_plain = TypedEnum::C;
auto a_auto = TypedEnum::A;
auto b_auto = TypedEnum::B;
auto c_auto = TypedEnum::C;
auto ab_plain = Op<o>(a_plain, b_plain);
auto bc_plain = Op<o>(b_plain, c_plain);
auto ab_auto = Op<o>(a_auto, b_auto);
auto bc_auto = Op<o>(b_auto, c_auto);
// On each row below, we pass a triple of operands. Keep in mind that this
// is going to be received as (t1, t2, t3) and the actual tests performed
// will be of the form
//
// result = t1 Op t2;
// result Op= t3;
//
// For this reason, we carefully ensure that the values of (t1, t2)
// systematically cover all types of such pairs; to limit complexity,
// we are not so careful with t3, and we just try to pass t3's
// that may lead to nontrivial bitwise operations.
TestAllOpsForGivenOperands<TypedEnum>(a_plain, b_plain, c_plain);
TestAllOpsForGivenOperands<TypedEnum>(a_plain, bc_plain, b_auto);
TestAllOpsForGivenOperands<TypedEnum>(ab_plain, c_plain, a_plain);
TestAllOpsForGivenOperands<TypedEnum>(ab_plain, bc_plain, a_auto);
TestAllOpsForGivenOperands<TypedEnum>(a_plain, b_auto, c_plain);
TestAllOpsForGivenOperands<TypedEnum>(a_plain, bc_auto, b_auto);
TestAllOpsForGivenOperands<TypedEnum>(ab_plain, c_auto, a_plain);
TestAllOpsForGivenOperands<TypedEnum>(ab_plain, bc_auto, a_auto);
TestAllOpsForGivenOperands<TypedEnum>(a_auto, b_plain, c_plain);
TestAllOpsForGivenOperands<TypedEnum>(a_auto, bc_plain, b_auto);
TestAllOpsForGivenOperands<TypedEnum>(ab_auto, c_plain, a_plain);
TestAllOpsForGivenOperands<TypedEnum>(ab_auto, bc_plain, a_auto);
TestAllOpsForGivenOperands<TypedEnum>(a_auto, b_auto, c_plain);
TestAllOpsForGivenOperands<TypedEnum>(a_auto, bc_auto, b_auto);
TestAllOpsForGivenOperands<TypedEnum>(ab_auto, c_auto, a_plain);
TestAllOpsForGivenOperands<TypedEnum>(ab_auto, bc_auto, a_auto);
}
// Tests all bitwise operations on a given TypedEnum bitfield.
template<typename TypedEnum>
void
TestTypedEnumBitField()
{
TestTypedEnumBasics<TypedEnum>();
TestAllOpsForOperandsBuiltUsingGivenOp<TypedEnum, '|'>();
TestAllOpsForOperandsBuiltUsingGivenOp<TypedEnum, '&'>();
TestAllOpsForOperandsBuiltUsingGivenOp<TypedEnum, '^'>();
}
// Checks that enum bitwise expressions have the same non-convertibility properties as
// c++11 enum classes do, i.e. not implicitly convertible to anything
// (though *explicitly* convertible).
void TestNoConversionsBetweenUnrelatedTypes()
{
using mozilla::IsConvertible;
// Two typed enum classes having the same underlying integer type, to ensure that
// we would catch bugs accidentally allowing conversions in that case.
typedef CharEnumBitField T1;
typedef Nested::CharEnumBitField T2;
static_assert(!IsConvertible<T1, T2>::value,
"should not be convertible");
static_assert(!IsConvertible<T1, decltype(T2::A)>::value,
"should not be convertible");
static_assert(!IsConvertible<T1, decltype(T2::A | T2::B)>::value,
"should not be convertible");
static_assert(!IsConvertible<decltype(T1::A), T2>::value,
"should not be convertible");
static_assert(!IsConvertible<decltype(T1::A), decltype(T2::A)>::value,
"should not be convertible");
static_assert(!IsConvertible<decltype(T1::A), decltype(T2::A | T2::B)>::value,
"should not be convertible");
// The following are #ifdef MOZ_HAVE_EXPLICIT_CONVERSION because
// without support for explicit conversion operators, we can't easily have these
// bad conversions completely removed. They still do fail to compile in practice,
// but not in a way that we can static_assert on.
#ifdef MOZ_HAVE_EXPLICIT_CONVERSION
static_assert(!IsConvertible<decltype(T1::A | T1::B), T2>::value,
"should not be convertible");
static_assert(!IsConvertible<decltype(T1::A | T1::B), decltype(T2::A)>::value,
"should not be convertible");
static_assert(!IsConvertible<decltype(T1::A | T1::B), decltype(T2::A | T2::B)>::value,
"should not be convertible");
#endif
}
MOZ_BEGIN_ENUM_CLASS(Int8EnumWithHighBits, int8_t)
A = 0x20,
B = 0x40
MOZ_END_ENUM_CLASS(Int8EnumWithHighBits)
MOZ_MAKE_ENUM_CLASS_BITWISE_OPERATORS(Int8EnumWithHighBits)
MOZ_BEGIN_ENUM_CLASS(Uint8EnumWithHighBits, uint8_t)
A = 0x40,
B = 0x80
MOZ_END_ENUM_CLASS(Uint8EnumWithHighBits)
MOZ_MAKE_ENUM_CLASS_BITWISE_OPERATORS(Uint8EnumWithHighBits)
MOZ_BEGIN_ENUM_CLASS(Int16EnumWithHighBits, int16_t)
A = 0x2000,
B = 0x4000
MOZ_END_ENUM_CLASS(Int16EnumWithHighBits)
MOZ_MAKE_ENUM_CLASS_BITWISE_OPERATORS(Int16EnumWithHighBits)
MOZ_BEGIN_ENUM_CLASS(Uint16EnumWithHighBits, uint16_t)
A = 0x4000,
B = 0x8000
MOZ_END_ENUM_CLASS(Uint16EnumWithHighBits)
MOZ_MAKE_ENUM_CLASS_BITWISE_OPERATORS(Uint16EnumWithHighBits)
MOZ_BEGIN_ENUM_CLASS(Int32EnumWithHighBits, int32_t)
A = 0x20000000,
B = 0x40000000
MOZ_END_ENUM_CLASS(Int32EnumWithHighBits)
MOZ_MAKE_ENUM_CLASS_BITWISE_OPERATORS(Int32EnumWithHighBits)
MOZ_BEGIN_ENUM_CLASS(Uint32EnumWithHighBits, uint32_t)
A = 0x40000000u,
B = 0x80000000u
MOZ_END_ENUM_CLASS(Uint32EnumWithHighBits)
MOZ_MAKE_ENUM_CLASS_BITWISE_OPERATORS(Uint32EnumWithHighBits)
MOZ_BEGIN_ENUM_CLASS(Int64EnumWithHighBits, int64_t)
A = 0x2000000000000000ll,
B = 0x4000000000000000ll
MOZ_END_ENUM_CLASS(Int64EnumWithHighBits)
MOZ_MAKE_ENUM_CLASS_BITWISE_OPERATORS(Int64EnumWithHighBits)
MOZ_BEGIN_ENUM_CLASS(Uint64EnumWithHighBits, uint64_t)
A = 0x4000000000000000ull,
B = 0x8000000000000000ull
MOZ_END_ENUM_CLASS(Uint64EnumWithHighBits)
MOZ_MAKE_ENUM_CLASS_BITWISE_OPERATORS(Uint64EnumWithHighBits)
// Checks that we don't accidentally truncate high bits by coercing to the wrong
// integer type internally when implementing bitwise ops.
template<typename EnumType, typename IntType>
void TestIsNotTruncated()
{
EnumType a = EnumType::A;
EnumType b = EnumType::B;
MOZ_RELEASE_ASSERT(IntType(a));
MOZ_RELEASE_ASSERT(IntType(b));
MOZ_RELEASE_ASSERT(a | EnumType::B);
MOZ_RELEASE_ASSERT(a | b);
MOZ_RELEASE_ASSERT(EnumType::A | EnumType::B);
EnumType c = EnumType::A | EnumType::B;
MOZ_RELEASE_ASSERT(IntType(c));
MOZ_RELEASE_ASSERT(c & c);
MOZ_RELEASE_ASSERT(c | c);
MOZ_RELEASE_ASSERT(c == (EnumType::A | EnumType::B));
MOZ_RELEASE_ASSERT(a != (EnumType::A | EnumType::B));
MOZ_RELEASE_ASSERT(b != (EnumType::A | EnumType::B));
MOZ_RELEASE_ASSERT(c & EnumType::A);
MOZ_RELEASE_ASSERT(c & EnumType::B);
EnumType d = EnumType::A;
d |= EnumType::B;
MOZ_RELEASE_ASSERT(d == c);
}
int
main()
{
TestTypedEnumBasics<AutoEnum>();
TestTypedEnumBasics<CharEnum>();
TestTypedEnumBasics<Nested::AutoEnum>();
TestTypedEnumBasics<Nested::CharEnum>();
TestTypedEnumBitField<AutoEnumBitField>();
TestTypedEnumBitField<CharEnumBitField>();
TestTypedEnumBitField<Nested::AutoEnumBitField>();
TestTypedEnumBitField<Nested::CharEnumBitField>();
TestTypedEnumBitField<BitFieldFor_uint8_t>();
TestTypedEnumBitField<BitFieldFor_int8_t>();
TestTypedEnumBitField<BitFieldFor_uint16_t>();
TestTypedEnumBitField<BitFieldFor_int16_t>();
TestTypedEnumBitField<BitFieldFor_uint32_t>();
TestTypedEnumBitField<BitFieldFor_int32_t>();
TestTypedEnumBitField<BitFieldFor_uint64_t>();
TestTypedEnumBitField<BitFieldFor_int64_t>();
TestTypedEnumBitField<BitFieldFor_char>();
TestTypedEnumBitField<BitFieldFor_signed_char>();
TestTypedEnumBitField<BitFieldFor_unsigned_char>();
TestTypedEnumBitField<BitFieldFor_short>();
TestTypedEnumBitField<BitFieldFor_unsigned_short>();
TestTypedEnumBitField<BitFieldFor_int>();
TestTypedEnumBitField<BitFieldFor_unsigned_int>();
TestTypedEnumBitField<BitFieldFor_long>();
TestTypedEnumBitField<BitFieldFor_unsigned_long>();
TestTypedEnumBitField<BitFieldFor_long_long>();
TestTypedEnumBitField<BitFieldFor_unsigned_long_long>();
TestNoConversionsBetweenUnrelatedTypes();
TestIsNotTruncated<Int8EnumWithHighBits, int8_t>();
TestIsNotTruncated<Int16EnumWithHighBits, int16_t>();
TestIsNotTruncated<Int32EnumWithHighBits, int32_t>();
TestIsNotTruncated<Int64EnumWithHighBits, int64_t>();
TestIsNotTruncated<Uint8EnumWithHighBits, uint8_t>();
TestIsNotTruncated<Uint16EnumWithHighBits, uint16_t>();
TestIsNotTruncated<Uint32EnumWithHighBits, uint32_t>();
TestIsNotTruncated<Uint64EnumWithHighBits, uint64_t>();
return 0;
}