Redcraft/Redcraft.Utility/Source/Private/Testing/MiscellaneousTesting.cpp

245 lines
8.1 KiB
C++

#include "Testing/MiscellaneousTesting.h"
#include "Miscellaneous/AssertionMacros.h"
#include "Miscellaneous/TypeInfo.h"
#include "Miscellaneous/Compare.h"
NAMESPACE_REDCRAFT_BEGIN
NAMESPACE_MODULE_BEGIN(Redcraft)
NAMESPACE_MODULE_BEGIN(Utility)
NAMESPACE_BEGIN(Testing)
void TestMiscellaneous()
{
TestAssertionMacros();
TestCompare();
TestTypeInfo();
}
NAMESPACE_UNNAMED_BEGIN
void TestNoEntry()
{
check_no_entry();
always_check_no_entry();
}
void TestNoReentry()
{
check_no_reentry();
always_check_no_reentry();
}
void TestNoRecursion(int32 Depth)
{
if (Depth < 0) return;
check_no_recursion();
always_check_no_recursion();
TestNoRecursion(--Depth);
}
void TestUnimplemented()
{
unimplemented();
always_unimplemented();
}
NAMESPACE_UNNAMED_END
void TestAssertionMacros()
{
check(true);
//check(false);
checkf(true, "True!");
//checkf(false, "False!");
always_check(true);
//always_check(false);
always_checkf(true, "True!");
//always_checkf(false, "False!");
//TestNoEntry();
TestNoReentry();
//TestNoReentry();
TestNoRecursion(0);
TestNoRecursion(0);
//TestNoRecursion(1);
//TestUnimplemented();
verify(true);
//verify(false);
int32 A = 1;
int32 B = 0;
verify(B = A);
always_check(B == A);
}
NAMESPACE_UNNAMED_BEGIN
struct FTestPartialOrdering
{
int32 Num;
bool bIsValid;
FTestPartialOrdering(int32 InNum, bool bInIsValid = true) : Num(InNum), bIsValid(bInIsValid) { }
friend bool operator==(FTestPartialOrdering LHS, FTestPartialOrdering RHS) { return LHS.bIsValid && RHS.bIsValid ? LHS.Num == RHS.Num : false; }
friend partial_ordering operator<=>(FTestPartialOrdering LHS, FTestPartialOrdering RHS) { return LHS.bIsValid && RHS.bIsValid ? LHS.Num <=> RHS.Num : partial_ordering::unordered; }
};
struct FTestWeakOrdering
{
int32 Num;
FTestWeakOrdering(int32 InNum) : Num(InNum) { }
friend bool operator==(FTestWeakOrdering LHS, FTestWeakOrdering RHS) { return LHS.Num == RHS.Num; }
friend weak_ordering operator<=>(FTestWeakOrdering LHS, FTestWeakOrdering RHS) { return LHS.Num <=> RHS.Num; }
};
struct FTestStrongOrdering
{
int32 Num;
FTestStrongOrdering(int32 InNum) : Num(InNum) { }
friend bool operator==(FTestStrongOrdering LHS, FTestStrongOrdering RHS) { return LHS.Num == RHS.Num; }
friend strong_ordering operator<=>(FTestStrongOrdering LHS, FTestStrongOrdering RHS) { return LHS.Num <=> RHS.Num; }
};
NAMESPACE_UNNAMED_END
void TestCompare()
{
always_check((-1 <=> 0) == strong_ordering::less);
always_check(( 0 <=> 0) == strong_ordering::equivalent);
always_check(( 0 <=> 0) == strong_ordering::equal);
always_check(( 0 <=> -1) == strong_ordering::greater);
always_check((-1 <=> 0) < 0);
always_check((-1 <=> 0) <= 0);
always_check(( 0 <=> 0) <= 0);
always_check(( 0 <=> 0) == 0);
always_check(( 0 <=> 0) >= 0);
always_check(( 0 <=> -1) >= 0);
always_check(( 0 <=> -1) > 0);
always_check((-1 <=> 1) != 0);
int64 NaNBit = 0xFFF8000000000000;
double NaN = *reinterpret_cast<double*>(&NaNBit);
always_check((-1.0 <=> 0.0) == partial_ordering::less);
always_check(( 0.0 <=> 0.0) == partial_ordering::equivalent);
always_check(( 0.0 <=> -1.0) == partial_ordering::greater);
always_check(( 0.0 <=> NaN) == partial_ordering::unordered);
always_check((-1.0 <=> 0.0) == weak_ordering::less);
always_check(( 0.0 <=> 0.0) == weak_ordering::equivalent);
always_check(( 0.0 <=> -1.0) == weak_ordering::greater);
always_check((-1.0 <=> 0.0) == strong_ordering::less);
always_check(( 0.0 <=> 0.0) == strong_ordering::equivalent);
always_check(( 0.0 <=> 0.0) == strong_ordering::equal);
always_check(( 0.0 <=> -1.0) == strong_ordering::greater);
always_check((-1.0 <=> 0.0) < 0);
always_check((-1.0 <=> 0.0) <= 0);
always_check(( 0.0 <=> 0.0) <= 0);
always_check(( 0.0 <=> 0.0) == 0);
always_check(( 0.0 <=> 0.0) >= 0);
always_check(( 0.0 <=> -1.0) >= 0);
always_check(( 0.0 <=> -1.0) > 0);
always_check((-1.0 <=> 1.0) != 0);
always_check((FTestPartialOrdering(-1) <=> FTestPartialOrdering( 0)) == partial_ordering::less);
always_check((FTestPartialOrdering( 0) <=> FTestPartialOrdering( 0)) == partial_ordering::equivalent);
always_check((FTestPartialOrdering( 0) <=> FTestPartialOrdering(-1)) == partial_ordering::greater);
always_check((FTestPartialOrdering( 0, true) <=> FTestPartialOrdering( 0, false)) == partial_ordering::unordered);
always_check((FTestWeakOrdering(-1) <=> FTestWeakOrdering( 0)) == weak_ordering::less);
always_check((FTestWeakOrdering( 0) <=> FTestWeakOrdering( 0)) == weak_ordering::equivalent);
always_check((FTestWeakOrdering( 0) <=> FTestWeakOrdering(-1)) == weak_ordering::greater);
always_check((FTestStrongOrdering(-1) <=> FTestStrongOrdering( 0)) == strong_ordering::less);
always_check((FTestStrongOrdering( 0) <=> FTestStrongOrdering( 0)) == strong_ordering::equivalent);
always_check((FTestStrongOrdering( 0) <=> FTestStrongOrdering( 0)) == strong_ordering::equal);
always_check((FTestStrongOrdering( 0) <=> FTestStrongOrdering(-1)) == strong_ordering::greater);
always_check((FTestPartialOrdering(-1) < FTestPartialOrdering( 0)));
always_check((FTestPartialOrdering( 0) == FTestPartialOrdering( 0)));
always_check((FTestPartialOrdering( 0) > FTestPartialOrdering(-1)));
always_check((FTestWeakOrdering(-1) < FTestWeakOrdering( 0)));
always_check((FTestWeakOrdering( 0) == FTestWeakOrdering( 0)));
always_check((FTestWeakOrdering( 0) > FTestWeakOrdering(-1)));
always_check((FTestStrongOrdering(-1) < FTestStrongOrdering( 0)));
always_check((FTestStrongOrdering( 0) == FTestStrongOrdering( 0)));
always_check((FTestStrongOrdering( 0) > FTestStrongOrdering(-1)));
always_check((TIsSame<TCommonComparisonCategory<strong_ordering >::Type, strong_ordering >::Value));
always_check((TIsSame<TCommonComparisonCategory<strong_ordering, weak_ordering >::Type, weak_ordering >::Value));
always_check((TIsSame<TCommonComparisonCategory<strong_ordering, weak_ordering, partial_ordering>::Type, partial_ordering>::Value));
always_check(CThreeWayComparable<int32>);
always_check(CThreeWayComparable<FTestPartialOrdering>);
always_check(CThreeWayComparable<FTestWeakOrdering>);
always_check(CThreeWayComparable<FTestStrongOrdering>);
always_check((CThreeWayComparableWith<bool, bool>));
always_check((CThreeWayComparableWith<int16, int32>));
always_check((TIsSame<TCompareThreeWayResult<int32 >::Type, strong_ordering >::Value));
always_check((TIsSame<TCompareThreeWayResult<float >::Type, partial_ordering>::Value));
always_check((TIsSame<TCompareThreeWayResult<FTestPartialOrdering>::Type, partial_ordering>::Value));
always_check((TIsSame<TCompareThreeWayResult<FTestWeakOrdering >::Type, weak_ordering >::Value));
always_check((TIsSame<TCompareThreeWayResult<FTestStrongOrdering >::Type, strong_ordering >::Value));
always_check((TCompareThreeWay<int32>()(0, 0) == strong_ordering::equal));
always_check((TCompareThreeWay<void>() (0, 0.0) == strong_ordering::equal));
always_check((StrongOrder(0, 0) == strong_ordering::equal));
always_check((WeakOrder(0, 0) == strong_ordering::equal));
always_check((PartialOrder(0, 0) == strong_ordering::equal));
always_check((CompareStrongOrderFallback(0, 0) == strong_ordering::equal));
always_check((CompareWeakOrderFallback(0, 0) == strong_ordering::equal));
always_check((ComparePartialOrderFallback(0, 0) == strong_ordering::equal));
}
NAMESPACE_UNNAMED_BEGIN
template <typename...>
struct TTestTemplateType { };
NAMESPACE_UNNAMED_END
void TestTypeInfo()
{
FTypeInfo TempA;
FTypeInfo TempB(Invalid);
always_check(TempA == TempB);
always_check(TempA == Typeid(void));
FTypeInfo TempC(Typeid(TTestTemplateType<int8, int16>));
FTypeInfo TempD = Typeid(TTestTemplateType<int8, int32>);
FTypeInfo TempE, TempF;
TempE = TempC;
TempF = MoveTemp(TempD);
always_check(TempE != TempF);
always_check((TempE < TempF) == (TempF > TempE));
always_check((TempE > TempF) == (TempF < TempE));
always_check((TempE <=> TempF) != 0);
}
NAMESPACE_END(Testing)
NAMESPACE_MODULE_END(Utility)
NAMESPACE_MODULE_END(Redcraft)
NAMESPACE_REDCRAFT_END