/////////////////////////////////////////////////////////////////////////////// // TestEABase.cpp // // Copyright (c) 2003 Electronic Arts, Inc. -- All Rights Reserved. // Created by Paul Pedriana. /////////////////////////////////////////////////////////////////////////////// #include "TestEABase.h" #include "TestEABase.h" // Intentionally double-include the same header file, to test it. #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #if !defined(EA_COMPILER_NO_STANDARD_CPP_LIBRARY) EA_DISABLE_ALL_VC_WARNINGS() #include EA_RESTORE_ALL_VC_WARNINGS() #endif #if defined(EA_COMPILER_MSVC) && defined(EA_PLATFORM_MICROSOFT) EA_DISABLE_ALL_VC_WARNINGS() #define NOMINMAX #include EA_RESTORE_ALL_VC_WARNINGS() #elif defined(EA_PLATFORM_ANDROID) #include #endif #if EA_FP16C // Include emmintrin.h so that the test code can try to call one of the intrinsics. #include "emmintrin.h" #if EA_COMPILER_CLANG // On some versions of clang immintrin.h needs to be included to pull in f16c operations. #include "immintrin.h" #endif #endif EA_DISABLE_SN_WARNING(1229) // function is deprecated. EA_DISABLE_VC_WARNING(4265 4296 4310 4350 4481 4530 4625 4626 4996) // ------------------------------------------------------------------------ // EA_STATIC_WARNING // // ** Temporarily here instead of eabase.h ** // // Unilaterally prints a message during the compilation pre-processing phase. // No string quotes are required, and no trailing semicolon should be used. // As of this writing, clang reports this usage like a warning, but using // -Wno-#pragma-messages causes both the warning and message to go away. // // Example usage: // EA_STATIC_WARNING(This function is deprecated.) // #if defined(_MSC_VER) #define EA_PRAGMA_MESSAGE(x) __pragma(message(#x)) #define EA_STATIC_WARNING(msg) EA_PRAGMA_MESSAGE(msg) #elif defined(__clang__) || (defined(__GNUC__) && (EA_COMPILER_VERSION >= 4005)) || defined(__SN_VER__) #define EA_PRAGMA(x) _Pragma(#x) #define EA_STATIC_WARNING(msg) EA_PRAGMA(message(#msg)) #else #define EA_STATIC_WARNING(msg) #endif /////////////////////////////////////////////////////////////////////////////// // Exercise EA_HAS_INCLUDE /////////////////////////////////////////////////////////////////////////////// #if EA_HAS_INCLUDE_AVAILABLE #if EA_HAS_INCLUDE() #include eastl::map gTestHasIncludeMap; #endif #endif #if EA_HAS_INCLUDE_AVAILABLE #if EA_HAS_INCLUDE() #error "Include Does Not EXIST!" #endif #endif /////////////////////////////////////////////////////////////////////////////// // Exercise EAHave /////////////////////////////////////////////////////////////////////////////// // EA_HAVE_EXTENSIONS_FEATURE // We don't yet have a test for this. // EA_HAVE_DINKUMWARE_CPP_LIBRARY // EA_HAVE_LIBSTDCPP_LIBRARY // EA_HAVE_LIBCPP_LIBRARY #if defined(EA_HAVE_DINKUMWARE_CPP_LIBRARY) #if !defined(_YVALS) #error #endif #elif defined(EA_HAVE_LIBSTDCPP_LIBRARY) #if !defined(__GLIBCXX__) && !defined(__GLIBCPP__) #error #endif #elif defined(EA_HAVE_LIBCPP_LIBRARY) #if !defined(_LIBCPP_VERSION) #error #endif #endif // EA_HAVE_XXX_H #if defined(EA_HAVE_SYS_TYPES_H) #include #endif #if defined(EA_HAVE_IO_H) #include #endif #if defined(EA_HAVE_INTTYPES_H) #include #endif #if defined(EA_HAVE_UNISTD_H) #include #endif #if defined(EA_HAVE_SYS_TIME_H) #include #endif #if defined(EA_HAVE_SYS_PTRACE_H) #include #endif #if defined(EA_HAVE_SYS_STAT_H) #include #endif #if defined(EA_HAVE_LOCALE_H) #include #endif #if defined(EA_HAVE_DIRENT_H) #include #endif #if defined(EA_HAVE_SIGNAL_H) #include #endif #if defined(EA_HAVE_SYS_SIGNAL_H) #include #endif #if defined(EA_HAVE_PTHREAD_H) #include #endif #if defined(EA_HAVE_WCHAR_H) #include #endif #if defined(EA_HAVE_MALLOC_H) #include #endif #if defined(EA_HAVE_ALLOCA_H) #include #endif #if defined(EA_HAVE_EXECINFO_H) #include #endif #if defined(EA_HAVE_SEMAPHORE_H) #include #endif #if defined(EA_HAVE_CPP11_CONTAINERS) #include #include #include #include #endif #if defined(EA_HAVE_CPP11_ATOMIC) #include #endif #if defined(EA_HAVE_CPP11_CONDITION_VARIABLE) #include #endif #if defined(EA_HAVE_CPP11_MUTEX) #include #endif #if defined(EA_HAVE_CPP11_THREAD) #if defined(_MSC_VER) && defined(EA_COMPILER_NO_EXCEPTIONS) || defined(EA_COMPILER_NO_UNWIND) // Skip this #include, as VC++ has a bug: (included by ) fails to compile when exceptions are disabled. #else #include #endif #endif #if defined(EA_HAVE_CPP11_FUTURE) #if defined(_MSC_VER) && defined(EA_COMPILER_NO_EXCEPTIONS) || defined(EA_COMPILER_NO_UNWIND) // Skip this #include, as VC++ has a bug: (included by ) fails to compile when exceptions are disabled. #else #include #endif #endif #if defined(EA_HAVE_CPP11_TYPE_TRAITS) #include #endif #if defined(EA_HAVE_CPP11_TUPLES) #include #endif #if defined(EA_HAVE_CPP11_REGEX) #include #endif #if defined(EA_HAVE_CPP11_RANDOM) #include #endif #if defined(EA_HAVE_CPP11_CHRONO) #include #endif #if defined(EA_HAVE_CPP11_SCOPED_ALLOCATOR) #include #endif #if defined(EA_HAVE_CPP11_INITIALIZER_LIST) #include #else // If there is no initializer_list support the the following should succeed. // The following is disabled because EASTL defines initializer_list itself and that can collide with this: // namespace std{ template class initializer_list{ }; } #endif #if defined(EA_HAVE_CPP11_SYSTEM_ERROR) #include #endif #if defined(EA_HAVE_CPP11_CODECVT) #include #endif #if defined(EA_HAVE_CPP11_TYPEINDEX) #include #endif // EA_HAVE_XXX_IMPL #if defined(EA_HAVE_inet_ntop_IMPL) #include #endif #if defined(EA_HAVE_time_IMPL) #include #endif #if defined(EA_HAVE_clock_gettime_IMPL) #include #endif #if defined(EA_HAVE_getcwd_IMPL) #if defined(EA_PLATFORM_MICROSOFT) #include #else #include #endif #endif #if defined(EA_HAVE_std_terminate_IMPL) #include #endif #if defined(EA_HAVE_CPP11_ITERATOR_IMPL) #include #endif #if defined(EA_HAVE_CPP11_SMART_POINTER_IMPL) #include #endif #if defined(EA_HAVE_CPP11_FUNCTIONAL_IMPL) #include void BindTestFunction(int /*n1*/, int /*n2*/, int /*n3*/, const int& /*n4*/, int /*n5*/) { } struct BindTestStruct { void Test(int /*n1*/, int /*n2*/) const { } }; #endif #if defined(EA_HAVE_CPP11_EXCEPTION_IMPL) #include #endif EA_DISABLE_SN_WARNING(1229) // function is deprecated. // Some CPU/Compiler combinations don't support arbitrary alignment declarations. // In particular some ARM compilers often don't. You can use EAStdC's EAAlignment to // achieve arbitrary alignment if EA_ALIGN doesn't work. #if (EA_ALIGN_MAX_AUTOMATIC < 64) #define ALIGNMENT_AMOUNT_64 EA_ALIGN_MAX_AUTOMATIC #else #define ALIGNMENT_AMOUNT_64 64 #endif #if (EA_ALIGN_MAX_AUTOMATIC < 32) #define ALIGNMENT_AMOUNT_32 EA_ALIGN_MAX_AUTOMATIC #else #define ALIGNMENT_AMOUNT_32 32 #endif #if (EA_ALIGN_MAX_AUTOMATIC < 16) #define ALIGNMENT_AMOUNT_16 EA_ALIGN_MAX_AUTOMATIC #else #define ALIGNMENT_AMOUNT_16 16 #endif // EA_OVERRIDE struct OverrideBase { virtual ~OverrideBase(){} virtual void f(int){} }; struct OverrideDerived : public OverrideBase { void f(int) EA_OVERRIDE {} }; // EA_INHERITANCE_FINAL struct FinalBase EA_INHERITANCE_FINAL { virtual ~FinalBase(){} virtual void f() EA_INHERITANCE_FINAL; }; // EA_SEALED struct SealedBase EA_SEALED { virtual ~SealedBase(){} virtual void f() EA_SEALED; }; // EA_ABSTRACT struct AbstractBase EA_ABSTRACT {virtual ~AbstractBase(){} virtual void f(){} }; // EA_CONSTEXPR / EA_COMPILER_NO_CONSTEXPR EA_CONSTEXPR int GetValue(){ return 37; } // EA_EXTERN_TEMPLATE / EA_COMPILER_NO_EXTERN_TEMPLATE template struct eabase_template; // Forward declarations template bool VerifyValue(T v1, T v2); void DoError(int& nErrorCount, const char* pMessage = NULL); int Stricmp(const char* pString1, const char* pString2); int TestEABase(); int TestEAResult(); int TestEAPlatform(); bool TestNU(); int TestEACompiler(); int TestEACompilerTraits(); template bool VerifyValue(T v1, T v2) { return (v1 == v2); } // Test EA_PLATFORM_XXX support // We don't do anything with the defined values below. We are just doing basic testing // of the usage of #if EA_PLATFORM_XXX #if EA_PLATFORM_WIN64 #define EA_PLATFORM_WIN64_OK #elif EA_PLATFORM_WIN32 #define EA_PLATFORM_WIN64_OK #elif EA_PLATFORM_WINDOWS #define EA_PLATFORM_WINDOWS_OK #elif EA_PLATFORM_POSIX #define EA_PLATFORM_POSIX_OK #elif EA_PLATFORM_UNIX #define EA_PLATFORM_UNIX_OK #elif EA_PLATFORM_APPLE #define EA_PLATFORM_APPLE_OK #elif EA_PLATFORM_CONSOLE #define EA_PLATFORM_CONSOLE_OK #elif EA_PLATFORM_DESKTOP #define EA_PLATFORM_DESKTOP_OK #else #define EA_PLATFORM_OK #endif /* Test EA_DISABLE_WARNING */ EA_DISABLE_VC_WARNING(4548 4127) EA_DISABLE_ALL_VC_WARNINGS() EA_RESTORE_ALL_VC_WARNINGS() EA_DISABLE_GCC_WARNING(-Wuninitialized) EA_DISABLE_SN_WARNING(1787) EA_DISABLE_ALL_SN_WARNINGS() EA_RESTORE_ALL_SN_WARNINGS() EA_DISABLE_GHS_WARNING(123) EA_DISABLE_EDG_WARNING(193) EA_DISABLE_CW_WARNING(10317) EA_DISABLE_ALL_CW_WARNINGS() EA_RESTORE_ALL_CW_WARNINGS() /* Test EA_DISABLE_WARNING */ EA_RESTORE_VC_WARNING() EA_RESTORE_GCC_WARNING() EA_RESTORE_SN_WARNING() EA_RESTORE_GHS_WARNING() EA_RESTORE_EDG_WARNING() EA_RESTORE_CW_WARNING(10317) void DoError(int& nErrorCount, const char* pMessage) { ++nErrorCount; if(pMessage) EA::EAMain::Report("Test error: %s\n", pMessage); } int Stricmp(const char* pString1, const char* pString2) { char c1, c2; while((c1 = (char)tolower(*pString1++)) == (c2 = (char)tolower(*pString2++))) { if(c1 == 0) return 0; } return (c1 - c2); } // EA_PURE static EA_PURE bool PureFunction() { return (strlen("abc") == 3); } // EA_WEAK EA_WEAK int gWeakVariable = 1; // EA_NO_VTABLE struct EA_NO_VTABLE NoVTable1 { virtual ~NoVTable1(){} virtual void InterfaceFunction() { } }; EA_STRUCT_NO_VTABLE(NoVTable2) { virtual ~NoVTable2(){} virtual void InterfaceFunction() { } }; class NoVTable1Subclass : public NoVTable1 { virtual void InterfaceFunction() { } }; class NoVTable2Subclass : public NoVTable2 { virtual void InterfaceFunction() { } }; struct ClassWithDefaultCtor { ClassWithDefaultCtor(int x = 0) { char buffer[16]; sprintf(buffer, "%d", x); } }; struct ClassWithoutDefaultCtor { ClassWithoutDefaultCtor(int x) { char buffer[16]; sprintf(buffer, "%d", x); } }; struct InitPriorityTestClass { int mX; InitPriorityTestClass(int x = 0) { mX = x; } }; struct OffsetofTestClass // Intentionally a non-pod. { int32_t mX; int32_t mY; OffsetofTestClass(int32_t x = 0) : mX(x), mY(0) { } }; struct SizeofMemberTestClass // Intentionally a non-pod. { int32_t mX; int32_t mY; SizeofMemberTestClass(int32_t x = 0) : mX(x), mY(0) { } }; // EA_INIT_PRIORITY InitPriorityTestClass gInitPriorityTestClass0 EA_INIT_PRIORITY(2000); InitPriorityTestClass gInitPriorityTestClass1 EA_INIT_PRIORITY(2000) (1); // EA_INIT_SEG EA_INIT_SEG(compiler) InitPriorityTestClass gInitSegTestSection(2300); // EA_MAY_ALIAS void* EA_MAY_ALIAS gPtr0 = NULL; typedef void* EA_MAY_ALIAS pvoid_may_alias; pvoid_may_alias gPtr1 = NULL; // EA_NO_INLINE static EA_NO_INLINE void DoNothingInline() { } // EA_PREFIX_NO_INLINE / EA_POSTFIX_NO_INLINE static void EA_PREFIX_NO_INLINE DoNothingPrefixInline() EA_POSTFIX_NO_INLINE; static void DoNothingPrefixInline() { } // EA_FORCE_INLINE static EA_FORCE_INLINE void DoNothingForceInline() { } // EA_PREFIX_FORCE_INLINE / EA_POSTFIX_FORCE_INLINE static void EA_PREFIX_FORCE_INLINE DoNothingPrefixForceInline() EA_POSTFIX_FORCE_INLINE; static void DoNothingPrefixForceInline() { } // static_asset at global scope // Should succeed. static_assert(sizeof(int32_t) == 4, "static_assert failure"); // Should fail. //static_assert(sizeof(int32_t) == 8, "static_assert failure"); // EA_STATIC_WARNING EA_DISABLE_CLANG_WARNING(-W#pragma-messages) // Clang treats messages as warnings. EA_STATIC_WARNING(EA_STATIC_WARNING test) EA_RESTORE_CLANG_WARNING() // EA_OPTIMIZE_OFF / EA_OPTIMIZE_ON EA_OPTIMIZE_OFF() static EA_NO_INLINE int DisabledOptimizations(int x) { return x * 37; } EA_OPTIMIZE_ON() // EA_UNUSED static void FunctionWithUnusedVariables(int x) { int y = 0; EA_UNUSED(x); EA_UNUSED(y); } // EA_NON_COPYABLE / EANonCopyable struct NonCopyableA { NonCopyableA(){} int x; EA_NON_COPYABLE(NonCopyableA) }; EA_DISABLE_VC_WARNING(4625 4626) // C4625: A copy constructor was not accessible in a base class and was therefore not generated for a derived class. C4626: An assignment operator was not accessible in a base class and was therefore not generated for a derived class. struct NonCopyableB : public EANonCopyable { #if !EA_COMPILER_NO_DELETED_FUNCTIONS NonCopyableB& operator=(NonCopyableB&& other) = delete; #endif int x; }; EA_RESTORE_VC_WARNING() // Exercize the case of using EA_NON_COPYABLE when struct NonDefaultConstructibleBase { int mX; NonDefaultConstructibleBase(int x) : mX(x){} }; struct NonCopyableSubclass : public NonDefaultConstructibleBase { NonCopyableSubclass(int x) : NonDefaultConstructibleBase(x){} EA_NON_COPYABLE(NonCopyableSubclass) }; // EA_COMPILER_NO_DEFAULTED_FUNCTIONS // EA_COMPILER_NO_DELETED_FUNCTIONS // // We currently test only the ability of the compiler to build the code, // and don't test if the compiler built it correctly. struct DefaultedDeletedTest { #if defined(EA_COMPILER_NO_DEFAULTED_FUNCTIONS) DefaultedDeletedTest(){} #else DefaultedDeletedTest() = default; #endif #if defined(EA_COMPILER_NO_DEFAULTED_FUNCTIONS) ~DefaultedDeletedTest(){} #else ~DefaultedDeletedTest() = delete; #endif }; struct EA_FUNCTION_DELETE_Test { int x; EA_FUNCTION_DELETE_Test(int xValue) : x(xValue){} private: // For portability with pre-C++11 compilers, make the function private. void foo() EA_FUNCTION_DELETE; }; #if !defined(EA_COMPILER_NO_USER_DEFINED_LITERALS) // Conversion example inline long double operator"" _deg(long double degrees) { return (degrees * 3.141592) / 180; } // Custom type example struct UDLTest { UDLTest() : mX(0){} UDLTest(uint64_t x) : mX(x){} uint64_t mX; }; UDLTest operator"" _udl(unsigned long long x) // The type must be unsigned long long and can't be uint64_t, as uint64_t might be unsigned long int. { return UDLTest(x); } #endif #if !defined(EA_COMPILER_NO_INLINE_NAMESPACES) namespace INSNamespace { inline namespace INSNamespace_1 { template class A; } template int g(T){ return 37; } } struct INSClass{ }; namespace INSNamespace { template<> class A{ }; } #endif #if !defined(EA_COMPILER_NO_FUNCTION_TEMPLATE_DEFAULT_ARGS) struct FunctionTemplateTest { template static T AddOne(T value) { return value + 1; } }; #endif #if !defined(EA_COMPILER_NO_NOEXCEPT) int NoExceptTestFunction() EA_NOEXCEPT { return 37; } struct NoExceptTestStruct { int mX; NoExceptTestStruct() : mX(37) {} }; template int NoExceptTestTemplate() EA_NOEXCEPT_IF(EA_NOEXCEPT_EXPR(T())) { T t; return t.mX; } #endif // The following function defintions are intended to generate compilation errors if EA_CHAR16_NATIVE or EA_CHAR32_NATIVE is set to 1 when it should be 0. // i.e. if the types are not actually native then their will be a function redefinition error generated. void NoopTakingString(const wchar_t *) { } #if EA_WCHAR_UNIQUE #if EA_WCHAR_SIZE == 2 // This definition should not conflict with the wchar_t defintion because char16_t should be unique. void NoopTakingString(const char16_t *) { #if !EA_CHAR16_NATIVE #error Expected EA_CHAR16_NATIVE to be 1. #endif } #else // This definition should not conflict with the wchar_t defintion because char32_t should be unique. void NoopTakingString(const char32_t *) { #if !EA_CHAR32_NATIVE #error Expected EA_CHAR32_NATIVE to be 1. #endif } #endif #endif int TestEABase() { int nErrorCount(0); DoNothingInline(); // Test NULL { if(!VerifyValue(NULL, (void*)0)) DoError(nErrorCount, "unspecified test"); } // Verify sized type sizes { if(!VerifyValue(sizeof(int8_t), 1)) DoError(nErrorCount, "int8_t size test"); if(!VerifyValue(sizeof(uint8_t), 1)) DoError(nErrorCount, "uint8_t size test"); if(!VerifyValue(sizeof(int16_t), 2)) DoError(nErrorCount, "int16_t size test"); if(!VerifyValue(sizeof(uint16_t), 2)) DoError(nErrorCount, "uint16_t size test"); if(!VerifyValue(sizeof(int32_t), 4)) DoError(nErrorCount, "int32_t size test"); if(!VerifyValue(sizeof(uint32_t), 4)) DoError(nErrorCount, "uint32_t size test"); if(!VerifyValue(sizeof(int64_t), 8)) DoError(nErrorCount, "int64_t size test"); if(!VerifyValue(sizeof(uint64_t), 8)) DoError(nErrorCount, "uint64_t size test"); #if !defined(FLT_EVAL_METHOD) #error EABase should always define FLT_EVAL_METHOD DoError(nErrorCount, "FLT_EVAL_METHOD test: not defined."); #else #if (FLT_EVAL_METHOD == -1) // In this case the C99 standard states that the // precision of float_t and double_t is indeterminable. #elif (FLT_EVAL_METHOD == 0) if(!VerifyValue(sizeof(float_t), sizeof(float))) DoError(nErrorCount, "float_t size test"); if(!VerifyValue(sizeof(double_t), sizeof(double))) DoError(nErrorCount, "double_t size test"); #elif (FLT_EVAL_METHOD == 1) if(!VerifyValue(sizeof(float_t), sizeof(double))) DoError(nErrorCount, "float_t size test"); if(!VerifyValue(sizeof(double_t), sizeof(double))) DoError(nErrorCount, "double_t size test"); #elif (FLT_EVAL_METHOD == 2) if(!VerifyValue(sizeof(float_t), sizeof(long double))) DoError(nErrorCount, "float_t size test"); if(!VerifyValue(sizeof(double_t), sizeof(long double))) DoError(nErrorCount, "double_t size test"); #else DoError(nErrorCount, "FLT_EVAL_METHOD test: invalid value."); #endif #endif if(sizeof(bool8_t) != 1) DoError(nErrorCount, "bool8_t size test"); if(!VerifyValue(sizeof(intptr_t), sizeof(void*))) DoError(nErrorCount, "intptr_t size test"); if(!VerifyValue(sizeof(uintptr_t), sizeof(void*))) DoError(nErrorCount, "uintptr_t size test"); if(!VerifyValue(sizeof(ssize_t), sizeof(size_t))) DoError(nErrorCount, "ssize_t size test"); EA_DISABLE_VC_WARNING(6326) const ssize_t ss(1); // Verify that ssize_t is a signed type. if(ssize_t((ss ^ ss) - 1) >= 0) DoError(nErrorCount, "ssize_t sign test"); EA_RESTORE_VC_WARNING() if(!VerifyValue(sizeof(char8_t), 1)) DoError(nErrorCount, "char8_t size test"); if(!VerifyValue(sizeof(char16_t), 2)) DoError(nErrorCount, "char16_t size test"); if(!VerifyValue(sizeof(char32_t), 4)) DoError(nErrorCount, "char32_t size test"); #if (EA_WCHAR_SIZE == 2) || (EA_WCHAR_SIZE == 4) if(!VerifyValue(sizeof(wchar_t), EA_WCHAR_SIZE)) DoError(nErrorCount, "EA_WCHAR_SIZE test"); #else DoError(nErrorCount, "EA_WCHAR_SIZE test"); #endif } // Test CHAR8_MIN, etc. { // The C standard allows compilers/platforms to use -127 as the min 8 bit value, but we've never seen it in modern systems. static_assert(((((CHAR8_MIN == -128) && (CHAR8_MAX == 127))) || ((CHAR8_MIN == 0) && (CHAR8_MAX == 255))), "CHAR8_MAX failure"); static_assert(((((CHAR16_MIN == -32768) && (CHAR16_MAX == 32767))) || ((CHAR16_MIN == 0) && (CHAR16_MAX == 65535))), "CHAR16_MAX failure"); static_assert(((((CHAR32_MIN == -INT64_C(2147483648)) && (CHAR32_MAX == INT64_C(2147483647)))) || ((CHAR32_MIN == 0) && (CHAR32_MAX == INT64_C(4294967295)))), "CHAR32_MAX failure"); } // Test char8_t, char16_t, char32_t string literals. { const char8_t* p8 = EA_CHAR8("abc"); const char8_t c8 = EA_CHAR8('a'); #ifdef EA_CHAR16 const char16_t* p16 = EA_CHAR16("abc"); // Under GCC, this assumes compiling with -fshort-wchar const char16_t c16 = EA_CHAR16('\x3001'); #else const char16_t* p16 = NULL; const char16_t c16 = static_cast('X'); #endif #ifdef EA_CHAR32 const char32_t* p32 = EA_CHAR32("abc"); const char32_t c32 = EA_CHAR32('\x3001'); #else const char32_t p32[] = { 'a', 'b', 'c', '\0' }; // Microsoft doesn't support 32 bit strings here, and GCC doesn't use them when we compile with -fshort-wchar (which we do). #ifdef EA_CHAR16 const char32_t c32 = EA_CHAR16('\x3001'); // 16 bit should silently convert to 32 bit. #else const char32_t c32 = static_cast('X'); // 16 bit should silently convert to 32 bit. #endif #endif const wchar_t* pW = EA_WCHAR("abc"); const wchar_t cW = EA_WCHAR('\x3001'); EA_UNUSED(p8); EA_UNUSED(c8); EA_UNUSED(p16); EA_UNUSED(c16); EA_UNUSED(p32); EA_UNUSED(c32); EA_UNUSED(pW); EA_UNUSED(cW); } // Verify sized type signs { int8_t i8(1); if(int8_t((i8 ^ i8) - 1) >= 0) DoError(nErrorCount, "int8_t sign test"); uint8_t u8(1); if(uint8_t((u8 ^ u8) - 1) <= 0) DoError(nErrorCount, "uint8_t sign test"); int16_t i16(1); if(int16_t((i16 ^ i16) - 1) >= 0) DoError(nErrorCount, "int16_t sign test"); uint16_t u16(1); if(uint16_t((u16 ^ u16) - 1) <= 0) DoError(nErrorCount, "uint16_t sign test"); int32_t i32(1); if(int32_t((i32 ^ i32) - 1) >= 0) DoError(nErrorCount, "int32_t sign test"); uint32_t u32(1); if(uint32_t((u32 ^ u32) - 1) <= 0) DoError(nErrorCount, "uint32_t sign test"); int64_t i64(1); if(int64_t((i64 ^ i64) - 1) >= 0) DoError(nErrorCount, "int64_t sign test"); uint64_t u64(1); if(uint64_t((u64 ^ u64) - 1) <= 0) DoError(nErrorCount, "uint64_t sign test"); intptr_t ip(1); if(intptr_t((ip ^ ip) - 1) >= 0) DoError(nErrorCount, "intptr_t sign test"); uintptr_t up(1); if(uintptr_t((up ^ up) - 1) <= 0) DoError(nErrorCount, "uintptr_t sign test"); // The following sign tests have been disabled, as the determination of // the sign of type char and wchar_t are in the hands of the compiler and // the user's configuration of that compiler. //char8_t c8(1); // We expect it to be signed, though the need for such a requirement is debateable. //if(char8_t((c8 ^ c8) - 1) >= 0) // DoError(nErrorCount, "char8_t sign test"); //char16_t c16(1); // We expect it to be unsigned //if(char16_t((c16 ^ c16) - 1) <= 0) // DoError(nErrorCount, "char16_t sign test"); //char32_t c32(1); // We expect it to be unsigned //if(char32_t((c32 ^ c32) - 1) <= 0) // DoError(nErrorCount, "char32_t sign test"); } //Test Constant macros { char buffer[256]; const int8_t i8Min = INT8_C(-128); // Strictly speaking, the C language standard allows this to be -127 as well. const int8_t i8Max = INT8_C(127); const uint8_t u8Min = UINT8_C(0); const uint8_t u8Max = UINT8_C(255); const int16_t i16Min = INT16_C(-32767) - 1; const int16_t i16Max = INT16_C( 32767); const uint16_t u16Min = UINT16_C(0); const uint16_t u16Max = UINT16_C(65535); const int32_t i32Min = INT32_C(-2147483647) - 1; const int32_t i32Max = INT32_C( 2147483647); const uint32_t u32Min = UINT32_C(0); const uint32_t u32Max = UINT32_C(4294967295); #if defined(__GNUC__) && (__GNUC__ < 4) // If using a broken version of UINT64_C/INT64_C macros... const int64_t i64Min = -9223372036854775807LL - 1; const int64_t i64Max = 9223372036854775807LL; const uint64_t u64Min = UINT64_C(0); const uint64_t u64Max = 18446744073709551615ULL; #else const int64_t i64Min = INT64_C(-9223372036854775807) - 1; const int64_t i64Max = INT64_C( 9223372036854775807); const uint64_t u64Min = UINT64_C(0); const uint64_t u64Max = UINT64_C(18446744073709551615); #endif sprintf(buffer, "%d %d %u %u %d %d %u %u %d %d %u %u %" SCNd64" %" SCNd64" %" SCNu64" %" SCNu64, (int)i8Min, (int)i8Max, (unsigned)u8Min, (unsigned)u8Max, (int)i16Min, (int)i16Max, (unsigned)u16Min, (unsigned)u16Max, (int)i32Min, (int)i32Max, (unsigned)u32Min, (unsigned)u32Max, i64Min, i64Max, u64Min, u64Max); if(strcmp(buffer, "-128 127 0 255 -32768 32767 0 65535 -2147483648 2147483647 0 4294967295 -9223372036854775808 9223372036854775807 0 18446744073709551615")) DoError(nErrorCount, "INT_C test"); EA_DISABLE_VC_WARNING(6326) // Verify the use of hex numbers with INT64_C const int64_t i64Hex = INT64_C(0x1111111122222222); if(i64Hex != INT64_C(1229782938533634594)) DoError(nErrorCount, "INT64_C hex error"); EA_RESTORE_VC_WARNING() // Verify the use of hex numbers with UINT64_C const uint64_t u64Hex = UINT64_C(0xaaaaaaaabbbbbbbb); #if defined(__GNUC__) && (__GNUC__ < 4) // If using a broken version of UINT64_C/INT64_C macros... const uint64_t temp = 12297829382759365563ULL; #else const uint64_t temp = UINT64_C(12297829382759365563); #endif EA_DISABLE_VC_WARNING(6326) if(u64Hex != temp) DoError(nErrorCount, "UINT64_C hex error"); EA_RESTORE_VC_WARNING() // Verify that the compiler both allows division with uint64_t but // also that it allows it via UINT64_MAX. A bad implementation of // UINT64_MAX would cause the code below to mis-execute or not compile. EA_DISABLE_VC_WARNING(6326) const uint64_t resultUint64 = UINT64_MAX / 2; if(resultUint64 != UINT64_C(9223372036854775807)) DoError(nErrorCount, "UINT64_MAX error"); EA_RESTORE_VC_WARNING() } { static_assert(INTPTR_MIN == eastl::numeric_limits::min(), "INTPTR_MIN failure"); static_assert(INTPTR_MAX == eastl::numeric_limits::max(), "INTPTR_MAX failure"); //static_assert(UINTPTR_MIN == eastl::numeric_limits::min(), "UINTPTR_MIN failure"); // not specified by the standard static_assert(UINTPTR_MAX == eastl::numeric_limits::max(), "UINTPTR_MAX failure"); static_assert(INTMAX_MIN == eastl::numeric_limits::min(), "INTMAX_MIN failure"); static_assert(INTMAX_MAX == eastl::numeric_limits::max(), "INTMAX_MAX failure"); //static_assert(UINTMAX_MIN == eastl::numeric_limits::MIN(), "UINTMAX_MIN failure"); // not specified by the standard static_assert(UINTMAX_MAX == eastl::numeric_limits::max(), "UINTMAX_MAX failure"); } //Test sized printf format specifiers { char buffer[256]; int8_t d8(INT8_MAX), i8(INT8_MIN), o8(INT8_MAX); uint8_t u8(UINT8_MAX), x8(UINT8_MAX), X8(UINT8_MAX); sprintf(buffer, "%" PRId8 " %" PRIi8 " %" PRIo8 " %" PRIu8 " %" PRIx8 " %" PRIX8, d8, i8, o8, u8, x8, X8); #ifdef EA_COMPILER_GNUC if(Stricmp(buffer, "127 -128 177 255 ff FF")) DoError(nErrorCount, "PRI8 test"); // This is known to fail with compilers such as VC++ which don't support %hh. #endif int16_t d16(INT16_MAX), i16(INT16_MIN), o16(INT16_MAX); uint16_t u16(UINT16_MAX), x16(UINT16_MAX), X16(UINT16_MAX); sprintf(buffer, "%" PRId16 " %" PRIi16 " %" PRIo16 " %" PRIu16 " %" PRIx16 " %" PRIX16, d16, i16, o16, u16, x16, X16); if(Stricmp(buffer, "32767 -32768 77777 65535 ffff FFFF")) DoError(nErrorCount, "PRI16 test"); int32_t d32(INT32_MAX), i32(INT32_MIN), o32(INT32_MAX); uint32_t u32(UINT32_MAX), x32(UINT32_MAX), X32(UINT32_MAX); sprintf(buffer, "%" PRId32 " %" PRIi32 " %" PRIo32 " %" PRIu32 " %" PRIx32 " %" PRIX32, d32, i32, o32, u32, x32, X32); if(Stricmp(buffer, "2147483647 -2147483648 17777777777 4294967295 ffffffff FFFFFFFF")) DoError(nErrorCount, "PRI32 test"); int64_t d64(INT64_MAX), i64(INT64_MIN), o64(INT64_MAX); uint64_t u64(UINT64_MAX), x64(UINT64_MAX), X64(UINT64_MAX); sprintf(buffer, "%" PRId64 " %" PRIi64 " %" PRIo64 " %" PRIu64 " %" PRIx64 " %" PRIX64, d64, i64, o64, u64, x64, X64); if(Stricmp(buffer, "9223372036854775807 -9223372036854775808 777777777777777777777 18446744073709551615 ffffffffffffffff FFFFFFFFFFFFFFFF")) DoError(nErrorCount, "PRI64 test"); // Many compilers give warnings for the following code because they // recognize that a pointer is being formatted as an integer. // This is what we want to do and what the C99 standard intends here. #if defined(_MSC_VER) && (_MSC_VER >= 1300) #pragma warning(disable: 4313) // Warning C4313: 'sprintf' : '%d' in format string conflicts with argument 1 of type 'void *' #pragma warning(disable: 4777) // Warning C4777: 'sprintf' : format string '%lld' requires an argument of type '__int64', but variadic argument 1 has type 'intptr_t' #endif #if !defined(__GNUC__) // GCC generates warnings here which we can't work around. void *dPtr = (void*)INT32_MAX, *iPtr = (void*)INT32_MIN, *oPtr = (void*)INT32_MAX, *uPtr = (void*)(uintptr_t)UINT64_MAX, *xPtr = (void*)(uintptr_t)UINT64_MAX, *XPtr = (void*)(uintptr_t)UINT64_MAX; sprintf(buffer, "%" PRIdPTR " %" PRIiPTR " %" PRIoPTR " %" PRIuPTR " %" PRIxPTR " %" PRIXPTR, (intptr_t)dPtr, (intptr_t)iPtr, (uintptr_t)oPtr, (uintptr_t)uPtr, (uintptr_t)xPtr, (uintptr_t)XPtr); #if (EA_PLATFORM_PTR_SIZE == 4) if(Stricmp(buffer, "2147483647 -2147483648 17777777777 4294967295 ffffffff FFFFFFFF")) DoError(nErrorCount, "PRIPTR test"); #else // EA_PLATFORM_PTR_SIZE == 8 if(Stricmp(buffer, "2147483647 -2147483648 17777777777 18446744073709551615 ffffffffffffffff FFFFFFFFFFFFFFFF")) DoError(nErrorCount, "PRIPTR test"); #endif #endif #if defined(_MSC_VER) && (_MSC_VER >= 1300) #pragma warning(default: 4313) #pragma warning(default: 4777) #endif } //Test sized scanf format specifiers { int numMatched = 0; #ifdef EA_COMPILER_IS_C99 // Enabled for C99 only because this code will simply crash on many platforms if the format specifiers aren't supported. int8_t d8, i8, o8; uint8_t u8, x8; numMatched = sscanf("127 -127 177 255 ff", "%" SCNd8 " %" SCNi8 " %" SCNo8 " %" SCNu8 " %" SCNx8, &d8, &i8, &o8, &u8, &x8); if((numMatched != 5) || (d8 != 127) || (i8 != -127) || (o8 != 127) || (u8 != 255) || (x8 != 255)) DoError(nErrorCount, "SCN8 test"); // This is known to fail with compilers such as VC++ which don't support %hh. #endif int16_t d16, i16, o16; uint16_t u16, x16; numMatched = sscanf("32767 -32768 77777 65535 ffff", "%" SCNd16 " %" SCNi16 " %" SCNo16 " %" SCNu16 " %" SCNx16, &d16, &i16, &o16, &u16, &x16); if((numMatched != 5) || (d16 != 32767) || (i16 != -32768) || (o16 != 32767) || (u16 != 65535) || (x16 != 65535)) DoError(nErrorCount, "SCN16 test"); int32_t d32, i32, o32; uint32_t u32, x32; numMatched = sscanf("2147483647 -2147483648 17777777777 4294967295 ffffffff", "%" SCNd32 " %" SCNi32 " %" SCNo32 " %" SCNu32 " %" SCNx32, &d32, &i32, &o32, &u32, &x32); if((numMatched != 5) || (d32 != INT32_MAX) || (i32 != INT32_MIN) || (o32 != INT32_MAX) || (u32 != UINT32_MAX) || (x32 != UINT32_MAX)) DoError(nErrorCount, "SCN32 test"); int64_t d64, i64, o64; uint64_t u64, x64; numMatched = sscanf("9223372036854775807 -9223372036854775808 777777777777777777777 18446744073709551615 ffffffffffffffff", "%" SCNd64 " %" SCNi64 " %" SCNo64 " %" SCNu64 " %" SCNx64, &d64, &i64, &o64, &u64, &x64); if((numMatched != 5) || (d64 != INT64_MAX) || (i64 != INT64_MIN) || (o64 != INT64_MAX) || (u64 != UINT64_MAX) || (x64 != UINT64_MAX)) DoError(nErrorCount, "SCN64 test"); // Many compilers give warnings for the following code because they // recognize that a pointer is being formatted as an integer. // This is what we want to do and what the C99 standard intends here. #if !defined(__GNUC__) // GCC generates warnings here which we can't work around. void *dPtr, *iPtr, *oPtr, *uPtr, *xPtr; intptr_t dip, iip; uintptr_t ouip, uuip, xuip; EA_DISABLE_VC_WARNING(4777) // format string '%lld' requires an argument of type '__int64 *', but variadic argument 1 has type 'intptr_t *' #if (EA_PLATFORM_PTR_SIZE == 4) numMatched = sscanf("2147483647 -2147483648 17777777777 4294967295 ffffffff", "%" SCNdPTR " %" SCNiPTR " %" SCNoPTR " %" SCNuPTR " %" SCNxPTR, &dip, &iip, &ouip, &uuip, &xuip); #else // EA_PLATFORM_PTR_SIZE == 8 numMatched = sscanf("2147483647 -2147483648 17777777777 18446744073709551615 ffffffffffffffff", "%" SCNdPTR " %" SCNiPTR " %" SCNoPTR " %" SCNuPTR " %" SCNxPTR, &dip, &iip, &ouip, &uuip, &xuip); #endif EA_RESTORE_VC_WARNING() dPtr = (void*)dip; iPtr = (void*)iip; oPtr = (void*)ouip; uPtr = (void*)uuip; xPtr = (void*)xuip; if((numMatched != 5) || (dPtr != (void*)INT32_MAX) || (iPtr != (void*)INT32_MIN) || (oPtr != (void*)INT32_MAX) || (uPtr != (void*)(uintptr_t)UINT64_MAX) || (xPtr != (void*)(uintptr_t)UINT64_MAX)) DoError(nErrorCount, "SCNPTR test"); #endif } // Test min/max { // The C standard allows INT8_MIN to be either -127 or -128. So in order to be able // to test for this in a portable way, we do the logic below whereby we test for // -127 (which all compiles should support) or -127 - 1 which all compilers should // support if INT8_MIN isn't -127. if(!VerifyValue(INT8_MIN, INT8_C(-127)) && !VerifyValue(INT8_MIN, INT8_C(-127) - 1)) DoError(nErrorCount, "INT8_MIN test"); if(!VerifyValue(INT8_MAX, INT8_C(127))) DoError(nErrorCount, "INT8_MAX test"); if(!VerifyValue(UINT8_MAX, UINT8_C(255))) DoError(nErrorCount, "UINT8_MAX test"); if(!VerifyValue(INT16_MIN, INT16_C(-32767)) && !VerifyValue(INT16_MIN, INT16_C(-32767) - 1)) DoError(nErrorCount, "INT16_MIN test"); if(!VerifyValue(INT16_MAX, INT16_C(32767))) DoError(nErrorCount, "INT16_MAX test"); if(!VerifyValue(UINT16_MAX, UINT16_C(65535))) DoError(nErrorCount, "UINT16_MAX test"); if(!VerifyValue(INT32_MIN, INT32_C(-2147483647)) && !VerifyValue(INT32_MIN, INT32_C(-2147483647) - 1)) DoError(nErrorCount, "INT32_MIN test"); if(!VerifyValue(INT32_MAX, INT32_C(2147483647))) DoError(nErrorCount, "INT32_MAX test"); if(!VerifyValue(UINT32_MAX, UINT32_C(4294967295))) DoError(nErrorCount, "UINT32_MAX test"); if(!VerifyValue(INT64_MIN, INT64_C(-9223372036854775807)) && !VerifyValue(INT64_MIN, INT64_C(-9223372036854775807) - 1)) DoError(nErrorCount, "INT64_MIN test"); if(!VerifyValue(INT64_MAX, INT64_C(9223372036854775807))) DoError(nErrorCount, "INT64_MAX test"); #if defined(__GNUC__) && (__GNUC__ < 4) // If using a broken version of UINT64_C/INT64_C macros... const uint64_t temp = 18446744073709551615ULL; #else const uint64_t temp = UINT64_C(18446744073709551615); #endif if(!VerifyValue(UINT64_MAX, temp)) DoError(nErrorCount, "UINT64_MAX test"); } { NoopTakingString(L""); // Compilation errors below indicate that the EA_CHAR16/EA_CHAR32 may be incorrectly defined, or EA_CHAR16_NATIVE/EA_CHAR32_NATIVE is incorrect set to 0. #if EA_WCHAR_SIZE == 2 && defined(EA_CHAR16) const char16_t *str = EA_CHAR16(""); NoopTakingString(str); #elif EA_WCHAR_SIZE == 4 && defined(EA_CHAR32) const char32_t *str = EA_CHAR32(""); NoopTakingString(str); #endif } return nErrorCount; } int TestEAResult() { int nErrorCount(0); EA::result_type resultSuccess(EA::SUCCESS); EA::result_type resultFailure(EA::FAILURE); EA::result_type resultZero(0); // success EA::result_type resultNeg(-1); // failure EA::result_type resultPos(+1); // success if(!EA_SUCCEEDED(resultSuccess)) DoError(nErrorCount, "EA::SUCCESS test"); if(EA_FAILED(resultSuccess)) DoError(nErrorCount, "EA::SUCCESS test"); if(EA_SUCCEEDED(resultFailure)) DoError(nErrorCount, "EA::FAILURE test"); if(!EA_FAILED(resultFailure)) DoError(nErrorCount, "EA::FAILURE test"); if(!EA_SUCCEEDED(resultZero)) DoError(nErrorCount, "EA::SUCCESS test"); if(EA_FAILED(resultZero)) DoError(nErrorCount, "EA::SUCCESS test"); if(EA_SUCCEEDED(resultNeg)) DoError(nErrorCount, "EA::FAILURE test"); if(!EA_FAILED(resultNeg)) DoError(nErrorCount, "EA::FAILURE test"); if(!EA_SUCCEEDED(resultPos)) DoError(nErrorCount, "EA::SUCCESS test"); if(EA_FAILED(resultPos)) DoError(nErrorCount, "EA::SUCCESS test"); return nErrorCount; } int TestEAPlatform() { int nErrorCount(0); // Test EA_PLATFORM_PTR_SIZE { #ifdef EA_PLATFORM_PTR_SIZE if(!VerifyValue(EA_PLATFORM_PTR_SIZE, sizeof(void*))) DoError(nErrorCount, "EA_PLATFORM_PTR_SIZE test"); #else DoError(nErrorCount, "EA_PLATFORM_PTR_SIZE test"); #endif } // Test EA_PLATFORM_NAME { #ifdef EA_PLATFORM_NAME char buffer[256]; sprintf(buffer, "TestEAPlatform: EA_PLATFORM_NAME: %s\n", EA_PLATFORM_NAME); #else DoError(nErrorCount, "EA_PLATFORM_NAME test"); #endif } // Test EA_PLATFORM_DESCRIPTION { #ifdef EA_PLATFORM_DESCRIPTION char buffer[256]; sprintf(buffer, "TestEAPlatform: EA_PLATFORM_DESCRIPTION: %s\n", EA_PLATFORM_DESCRIPTION); #else DoError(nErrorCount, "EA_PLATFORM_DESCRIPTION test"); #endif } // Test EA_SYSTEM_LITTLE_ENDIAN / EA_SYSTEM_BIG_ENDIAN { uint32_t kValue = 0x12345678; uint8_t* pValue = (uint8_t*)&kValue; #ifdef EA_SYSTEM_LITTLE_ENDIAN if(pValue[0] != 0x78) DoError(nErrorCount, "EA_SYSTEM_ENDIAN test"); #elif defined(EA_SYSTEM_BIG_ENDIAN) if(pValue[0] != 0x12) DoError(nErrorCount, "EA_SYSTEM_ENDIAN test"); #else DoError(nErrorCount, "EA_SYSTEM_ENDIAN test"); #endif } // Test EA_ASM_STYLE { #if defined(EA_PROCESSOR_X86) #if defined(EA_ASM_STYLE_ATT) asm volatile ("nop"); #elif defined(EA_ASM_STYLE_INTEL) __asm nop #endif #else // Add other processors here. #endif } return nErrorCount; } // Test compiler limitations // Easiest way to come up with tests for some of the more complicated versions // of these is to look at the Boost /libs/config/test/*.cxx files. Many of the // Boost compiler limitation defines are similar or match exactly to those // defined by EABase. See http://www.boost.org if you want to check this out. #ifndef EA_COMPILER_NO_STATIC_CONSTANTS // If class member static constants are allowed... struct NSC { static const int x = 10; }; #endif #ifndef EA_COMPILER_NO_TEMPLATE_SPECIALIZATION // Todo #endif #ifndef EA_COMPILER_NO_TEMPLATE_PARTIAL_SPECIALIZATION // Todo #endif #ifndef EA_COMPILER_NO_MEMBER_TEMPLATES // Todo #endif #ifndef EA_COMPILER_NO_MEMBER_TEMPLATE_SPECIALIZATION // Todo #endif #ifndef EA_COMPILER_NO_TEMPLATE_TEMPLATES // Todo #endif #ifndef EA_COMPILER_NO_MEMBER_TEMPLATE_FRIENDS // Todo #endif #ifndef EA_COMPILER_NO_VOID_RETURNS void TestNVR1(); void TestNVR(); void TestNVR1() { char buffer[8]; sprintf(buffer, " "); } void TestNVR() { return TestNVR1(); } #endif #ifndef EA_COMPILER_NO_COVARIANT_RETURN_TYPE // Todo #endif #ifndef EA_COMPILER_NO_DEDUCED_TYPENAME // Todo #endif #ifndef EA_COMPILER_NO_ARGUMENT_DEPENDENT_LOOKUP // Todo #endif #if !defined(EA_COMPILER_NO_EXCEPTION_STD_NAMESPACE) && !defined(EA_COMPILER_NO_STANDARD_CPP_LIBRARY) #include static void TestNESN() { // iPhone gives us this error: Undefined symbols for architecture armv6: std::terminate() // Android gives: undefined reference to std::terminate() // We could possibly define our own std::terminate, but that might collide in the future unexpectedly. #if defined(EA_PLATFORM_IPHONE) || defined(EA_PLATFORM_ANDROID) void (*pTerminate)() = NULL; #else void (*pTerminate)() = std::terminate; #endif char buffer[32]; sprintf(buffer, "%p", pTerminate); } #endif #ifndef EA_COMPILER_NO_EXPLICIT_FUNCTION_TEMPLATE_ARGUMENTS // Todo #endif #ifndef EA_COMPILER_NO_EXCEPTIONS static bool TestNE() { EA_DISABLE_VC_WARNING(4571) try{ char buffer1[8]; sprintf(buffer1, " "); throw int(0); } catch(...){ char buffer2[8]; sprintf(buffer2, " "); // If you are tracing this in a debugger and the debugger stops here, then you need to let the app continue. } return true; EA_RESTORE_VC_WARNING() } #endif struct UnwindTest { static int x; enum State{ kStateNone, kStateConstructed, kStateDestructed }; UnwindTest() { x = kStateConstructed; }; ~UnwindTest() { x = kStateDestructed; }; }; int UnwindTest::x = kStateNone; #ifndef EA_COMPILER_NO_EXCEPTIONS static void TestNU1() { UnwindTest ut; #ifndef EA_COMPILER_NO_EXCEPTIONS throw(int(0)); // If you are tracing this in a debugger and the debugger stops here, then you need to let the app continue. #endif } #endif bool TestNU() { bool bReturnValue(false); #ifdef EA_COMPILER_NO_EXCEPTIONS bReturnValue = true; //Nothing to test, so we just return true. #else EA_DISABLE_VC_WARNING(4571) try { TestNU1(); } catch(...) { #ifdef EA_COMPILER_NO_UNWIND if(UnwindTest::x == UnwindTest::kStateConstructed) bReturnValue = true; #else if(UnwindTest::x == UnwindTest::kStateDestructed) bReturnValue = true; #endif } EA_RESTORE_VC_WARNING() #endif return bReturnValue; } #ifndef EA_COMPILER_NO_STANDARD_CPP_LIBRARY #include // We need do nothing more than #include this. #endif #ifndef EA_COMPILER_NO_COVARIANT_RETURN_TYPE // Todo #endif #ifndef EA_COMPILER_NO_COVARIANT_RETURN_TYPE // Todo #endif #if !defined(EA_COMPILER_NO_TRAILING_RETURN_TYPES) // This usage assumes that C++11 auto is supported, which in practice is always the case because // the case because otherwise trailing return types wouldn't be as useful. static auto AddOne(int i)->int { return i + 1; } template struct AddTwoClass { typedef float Local_type; Local_type AddTwo(T t); }; template auto AddTwoClass::AddTwo(T t)->Local_type { return (t + 2.f); // Assumes that t is a numerical type in this case. } #endif #if !defined(EA_COMPILER_NO_VARIADIC_TEMPLATES) template struct VariadicTemplateTuple{}; template struct VariadicTemplatePair { T1 x; T1 y; }; template struct VariadicTemplateZip { template struct with { typedef VariadicTemplateTuple ... > type; }; }; // VariadicTemplateType is Tuple, Pair > typedef VariadicTemplateZip::with::type VariadicTemplateType; #endif #if !defined(EA_COMPILER_NO_TEMPLATE_ALIASES) template using VectorAlias = eastl::vector; #endif #if !defined(EA_COMPILER_NO_VARIABLE_TEMPLATES) template constexpr T pi = T(3.1415926535897932385); #endif int TestEACompiler() { int nErrorCount(0); // As of this writing, eacompiler.h defines at least the following compilers: // EA_COMPILER_GNUC // EA_COMPILER_INTEL // EA_COMPILER_METROWERKS // EA_COMPILER_MSVC, EA_COMPILER_MSVC6, EA_COMPILER_MSVC7, EA_COMPILER_MSVC7_1 // Test EA_COMPILER_NAME { #ifdef EA_COMPILER_NAME char buffer[256]; sprintf(buffer, "TestEACompiler: EA_COMPILER_NAME: %s\n", EA_COMPILER_NAME); #else DoError(nErrorCount, "EA_COMPILER_NAME test"); #endif } // Test EA_COMPILER_VERSION { #ifdef EA_COMPILER_VERSION char buffer[256]; sprintf(buffer, "TestEACompiler: EA_COMPILER_VERSION: %d\n", EA_COMPILER_VERSION); #else DoError(nErrorCount, "EA_COMPILER_VERSION test"); #endif } // Test EA_COMPILER_STRING { #ifdef EA_COMPILER_STRING char buffer[256]; sprintf(buffer, "TestEACompiler: EA_COMPILER_STRING: %s\n", EA_COMPILER_STRING); #else DoError(nErrorCount, "EA_COMPILER_STRING test"); #endif } // Test EA_COMPILER_NO_STATIC_CONSTANTS { char buffer[256]; sprintf(buffer, "%d", (int)NSC::x); if(buffer[0] != '1') DoError(nErrorCount, "EA_COMPILER_NO_STATIC_CONSTANTS test"); } // Test EA_COMPILER_NO_VOID_RETURNS #ifndef EA_COMPILER_NO_VOID_RETURNS TestNVR1(); // Nothing to test for except successful compilation. #endif // Test EA_COMPILER_NO_EXCEPTION_STD_NAMESPACE #if !defined(EA_COMPILER_NO_EXCEPTION_STD_NAMESPACE) && !defined(EA_COMPILER_NO_STANDARD_CPP_LIBRARY) TestNESN(); #endif #if !(defined(EA_PLATFORM_IPHONE) && defined(EA_COMPILER_CLANG)) || defined(__IPHONE_7_0) { // There was a bug in Apple's exception code in iOS SDK versions // prior to 7.0, which is why this test is disabled for versions // of the SDK before 7.0. // Note that __IPHONE_7_0 will be defined for all future SDKs as // well, because Apple simply adds another define with each release // and does not remove the old ones. // Test EA_COMPILER_NO_EXCEPTIONS #ifndef EA_COMPILER_NO_EXCEPTIONS if(!TestNE()) DoError(nErrorCount, "EA_COMPILER_NO_EXCEPTIONS test"); #endif // Test EA_COMPILER_NO_UNWIND if(!TestNU()) DoError(nErrorCount, "EA_COMPILER_NO_UNWIND test"); } #endif // Test EA_COMPILER_NO_RVALUE_REFERENCES #ifndef EA_COMPILER_NO_RVALUE_REFERENCES { // Trivial test int&& i = 2; FunctionWithUnusedVariables(i); } #endif // Test EA_COMPILER_NO_RANGE_BASED_FOR_LOOP #if !defined(EA_COMPILER_NO_RANGE_BASED_FOR_LOOP) { float floatArray[2] = { 0.0f, 1.0f }; for(float& f : floatArray) f += 1.0; EATEST_VERIFY(floatArray[1] == 2.0f); } #endif // Test EA_COMPILER_NO_AUTO #if !defined(EA_COMPILER_NO_AUTO) { auto length = strlen("test"); EATEST_VERIFY(length == 4); } #endif // Test EA_COMPILER_NO_DECLTYPE #if !defined(EA_COMPILER_NO_DECLTYPE) { struct A { double x; }; int b = 9; A a; a.x = 7; decltype(b) x2 = 2; decltype(a.x) x3 = 3.5; EATEST_VERIFY((b + a.x) == 16); EATEST_VERIFY((x3 + x2) == 5.5); } #endif // Test EA_COMPILER_NO_LAMBDA_EXPRESSIONS #if !defined(EA_COMPILER_NO_LAMBDA_EXPRESSIONS) { struct LambaTest { static void SortViaAbs(float* x, size_t n) { eastl::insertion_sort(x, x + n, [](float a, float b) { return (a < b); } ); } }; float floatArray[3] = { 0.f, 1.f, 3.f }; LambaTest::SortViaAbs(floatArray, EAArrayCount(floatArray)); EATEST_VERIFY(floatArray[1] == 1.f); } #endif // Test EA_COMPILER_NO_TRAILING_RETURN_TYPES #if !defined(EA_COMPILER_NO_TRAILING_RETURN_TYPES) { int x = AddOne(2); // AddOne declared above. EATEST_VERIFY(x == 3); AddTwoClass a; float y = a.AddTwo(2.f); EATEST_VERIFY(y == 4.f); } #endif // Test EA_COMPILER_NO_FORWARD_DECLARED_ENUMS // Forward declared enum support requires strongly typed enum support. #if !defined(EA_COMPILER_NO_FORWARD_DECLARED_ENUMS) && !defined(EA_COMPILER_NO_STRONGLY_TYPED_ENUMS) { // This happen to be used below in the EA_COMPILER_NO_STRONGLY_TYPED_ENUMS section. enum class Color; enum class Size : uint8_t; enum Distance: uint8_t; } #endif // Test EA_COMPILER_NO_STRONGLY_TYPED_ENUMS #if !defined(EA_COMPILER_NO_STRONGLY_TYPED_ENUMS) { enum class Color { red, blue, green }; enum class Size : uint8_t { little = 1, med = 1, large = 2 }; enum Distance : uint8_t { close = 1, faraway = 2 }; Color c = Color::red; EATEST_VERIFY(c != Color::blue); Size s = Size::med; EATEST_VERIFY(s != Size::large); static_assert(sizeof(s) == 1, "EA_COMPILER_NO_STRONGLY_TYPED_ENUMS failure"); Distance d = close; EATEST_VERIFY(d != faraway); static_assert(sizeof(d) == 1, "EA_COMPILER_NO_STRONGLY_TYPED_ENUMS failure"); } #endif // Test EA_COMPILER_NO_VARIADIC_TEMPLATES #if !defined(EA_COMPILER_NO_VARIADIC_TEMPLATES) { // This uses types defined above. VariadicTemplateType x; static_assert(sizeof(x) > 0, "EA_COMPILER_NO_VARIADIC_TEMPLATES failure"); char buffer[32]; sprintf(buffer, "%p", &x); // Ignore the result, as we're just verifying that it compiles. } #endif // Test EA_COMPILER_NO_TEMPLATE_ALIASES #if !defined(EA_COMPILER_NO_TEMPLATE_ALIASES) { // This uses types defined above. // Same as vector v; VectorAlias v; EATEST_VERIFY(v.empty()); } #endif // Test EA_COMPILER_NO_VARIABLE_TEMPLATES #if !defined(EA_COMPILER_NO_VARIABLE_TEMPLATES) static_assert(pi == 3, "variable template failure"); static_assert(pi == 3, "variable template failure"); static_assert(pi == 3.1415926535897932385, "variable template failure"); #endif // Test EA_COMPILER_NO_INITIALIZER_LISTS #if !defined(EA_COMPILER_NO_INITIALIZER_LISTS) { int a = { 1 }; EATEST_VERIFY(a == 1); int* e{}; EATEST_VERIFY(!e); double x = double{1}; EATEST_VERIFY(x == 1.0); //Disabled until we have a compiler and standard library that can exercise this. //#include //eastl::vector anim = { {"bear", 4}, {"cassowary", 2}, {"tiger", 7} }; //EATEST_VERIFY(!anim.empty()); // Other tests to do. //std::complex z{1,2}; //eastl::vector{1, 2, 3, 4}; //f({"Nicholas","Annemarie"}); //return { "Norah" }; } #endif // Test EA_COMPILER_NO_NORETURN / EA_NORETURN #if !defined(EA_COMPILER_NO_NORETURN) && !defined(EA_PLATFORM_PS4) // Kettle SDK up to at least v.915 has a broken definition of the exit() function and fails to compile the valid code below. { struct NoReturnTest { EA_NORETURN void DoesNotReturn() { exit(0); } int DoesReturn() { return 17; } }; NoReturnTest nrt; if(nrt.DoesReturn() == 18) nrt.DoesNotReturn(); } #endif // Test EA_COMPILER_NO_CARRIES_DEPENDENCY / EA_CARRIES_DEPENDENCY #if !defined(EA_COMPILER_NO_CARRIES_DEPENDENCY) { struct CarriesDependencyTest { CarriesDependencyTest() : mX(0){} EA_CARRIES_DEPENDENCY int* Test1(){ return &mX; } void Test2(int* f EA_CARRIES_DEPENDENCY) { char buffer[32]; sprintf(buffer, "%p", f); } int mX; }; CarriesDependencyTest cdt; cdt.Test2(cdt.Test1()); } #endif // Test EA_COMPILER_NO_FALLTHROUGH / EA_FALLTHROUGH #if !defined(EA_COMPILER_NO_FALLTHROUGH) { int i = 1; switch (i) { case 1: i++; EA_FALLTHROUGH; case 2: { i = 42; } break; } EATEST_VERIFY(i == 42); } #endif // Test EA_COMPILER_NO_NODISCARD / EA_NODISCARD #if !defined(EA_COMPILER_NO_NODISCARD) { struct EA_NODISCARD DoNotDiscardMe {}; auto result = [](void) -> DoNotDiscardMe { return {}; }(); (void)result; // use the result to avoid [[nodiscard]] compiler warnings } #endif // Test EA_COMPILER_NO_MAYBE_UNUSED / EA_MAYBE_UNUSED #if !defined(EA_COMPILER_NO_MAYBE_UNUSED) { { EA_MAYBE_UNUSED int notAlwaysUsed = 42; // Do not use expressions below. It defeats the purpose of the test. // (void)notAlwaysUsed; // EA_UNUSED(notAlwaysUsed); } { [](EA_MAYBE_UNUSED bool b1, EA_MAYBE_UNUSED bool b2) { EA_ASSERT(b1 && b2); }(true, true); } } #endif #if !defined(EA_COMPILER_NO_NONSTATIC_MEMBER_INITIALIZERS) { struct NonstaticInitializerTest { int a = 7; int b = a; }; NonstaticInitializerTest nit; EATEST_VERIFY((nit.a == 7) && (nit.b == 7)); } #endif #if !defined(EA_COMPILER_NO_RIGHT_ANGLE_BRACKETS) { eastl::vector> listList; EA_UNUSED(listList); } #endif #if !defined(EA_COMPILER_NO_ALIGNOF) { char buffer[32]; sprintf(buffer, "%u", (unsigned)alignof(uint64_t)); } #endif #if !defined(EA_COMPILER_NO_ALIGNAS) { struct alignas(32) AlignAsTest1 { float mData[4]; }; struct alignas(uint64_t) AlignAsTest2 { float mData[4]; }; char buffer[32]; sprintf(buffer, "%u %u", (unsigned)EA_ALIGN_OF(AlignAsTest1), (unsigned)EA_ALIGN_OF(AlignAsTest2)); } #endif #if !defined(EA_COMPILER_NO_DELEGATING_CONSTRUCTORS) { struct DCTest { char mChar; double mDouble; DCTest() : mChar('\0'), mDouble(1.23){ }; DCTest(double d, char c): mChar(c), mDouble(d) { } DCTest(char c) : DCTest(1.23, c) { } DCTest(double d): DCTest(d, 'a') { } DCTest(char*): DCTest() { } }; DCTest dcTest(1.5); EATEST_VERIFY(dcTest.mDouble == 1.5); } #endif #if !defined(EA_COMPILER_NO_INHERITING_CONSTRUCTORS) { struct B1{ B1(int x) : mX(x){} int mX; }; struct B2{ B2(int x = 13, int y = 42) : mX(x), mY(y){} int mX, mY; }; struct D1 : B1 { using B1::B1; }; struct D2 : B2 { using B2::B2; }; D1 d1(3); D2 d2a(17, 22); D2 d2b; EATEST_VERIFY((d1.mX == 3) && (d2a.mX == 17) && (d2a.mY == 22) && (d2b.mX == 13) && (d2b.mY == 42)); } #endif #if !defined(EA_COMPILER_NO_USER_DEFINED_LITERALS) { // The operators are defined above. // Conversion example double x = 90.0_deg; // x = 1.570796 EATEST_VERIFY((x > 1.57) && (x < 1.58)); // Custom type example UDLTest y(123_udl); EATEST_VERIFY(y.mX == 123); } #endif #if !defined(EA_COMPILER_NO_STANDARD_LAYOUT_TYPES) { // We don't currently have a good way of testing this without bringing in . } #endif #if !defined(EA_COMPILER_NO_EXTENDED_SIZEOF) { struct SizeofTest{ int32_t mMember; }; const size_t testSize = sizeof(SizeofTest::mMember); EATEST_VERIFY(testSize == sizeof(int32_t)); char buffer[32]; sprintf(buffer, "%u", (unsigned)testSize); } #endif #if !defined(EA_COMPILER_NO_INLINE_NAMESPACES) { // The namespaces are defined above. INSNamespace::A a; int result = g(a); EATEST_VERIFY(result == 37); } #endif #if !defined(EA_COMPILER_NO_UNRESTRICTED_UNIONS) { struct Point { int mX, mY; Point(int x = 0, int y = 0) : mX(x), mY(y) {} }; union U { int z; double w; Point p; // Illegal in C++03; legal in C++11. U() { new(&p) Point(); } // Due to the Point member, a constructor definition is now required. }; } #endif #if !defined(EA_COMPILER_NO_EXPLICIT_CONVERSION_OPERATORS) { // bool cast test struct Testable { explicit operator bool() const { return false; } Testable() : mX(37) { } int mX; }; Testable a; if(a) EATEST_VERIFY(a.mX == 37); // Class cast test struct Y { int mY; Y(int y = 0) : mY(y) { } }; struct Z { int mZ; Z(int z = 0) : mZ(z) { } explicit operator Y() const { return Y(mZ); } }; Z z(3); Y y1(z); // Direct initialization Y y2 = (Y)z; // Cast notation EATEST_VERIFY((z.mZ == 3) && (y1.mY == 3) && (y2.mY == 3)); } #endif #if !defined(EA_COMPILER_NO_FUNCTION_TEMPLATE_DEFAULT_ARGS) { // FunctionTemplateTest is declared above. int result = FunctionTemplateTest::AddOne((int)3); EATEST_VERIFY(result == 4); } #endif #if !defined(EA_COMPILER_NO_LOCAL_CLASS_TEMPLATE_PARAMETERS) { struct LocalStruct{}; eastl::fixed_vector localStructArray; EATEST_VERIFY(localStructArray.empty()); } #endif #if !defined(EA_COMPILER_NO_NOEXCEPT) { EATEST_VERIFY(NoExceptTestFunction() == 37); EATEST_VERIFY(NoExceptTestTemplate() == 37); } #endif #if !defined(EA_COMPILER_NO_RAW_LITERALS) { // Older versions of GCC are preventing us from using " below in str1. Due to the way the preprocessor // works, it encounters what it sees as a string problem before it handles the #if above. No #ifdefs // can make this problem go away. const char str1[] = R"(This slash is just a slash: \ This quote is just a quote: ' )"; const char str2[] = R"delimiter(This slash is just a slash: \ This paren is just a paren: ) )delimiter"; EA_UNUSED(str1); EA_UNUSED(str2); static_assert(EAArrayCount(str1) == 61, "EA_COMPILER_NO_RAW_LITERALS failure."); static_assert(EAArrayCount(str2) == 61, "EA_COMPILER_NO_RAW_LITERALS failure."); } #endif #if !defined(EA_COMPILER_NO_UNICODE_STRING_LITERALS) { const char8_t str1[] = u8"Unicode: \u2018."; // This assumes that \u and \U are supported by the compiler. const char16_t str2[] = u"Unicode: \U00002018."; const char32_t str3[] = U"Unicode: \U00022018."; static_assert(EAArrayCount(str1) == 14, "EA_COMPILER_NO_UNICODE_STRING_LITERALS failure."); static_assert(EAArrayCount(str2) == 12, "EA_COMPILER_NO_UNICODE_STRING_LITERALS failure."); static_assert(EAArrayCount(str3) == 12, "EA_COMPILER_NO_UNICODE_STRING_LITERALS failure."); } #endif #if !defined(EA_COMPILER_NO_UNICODE_CHAR_NAME_LITERALS) { const char8_t str1[] = "\u2018\u2019"; static_assert(EAArrayCount(str1) == 7, "EA_COMPILER_NO_UNICODE_CHAR_NAME_LITERALS failure."); #if (EA_WCHAR_SIZE >= 2) const wchar_t str2[] = L"\U00002018\U00002019"; static_assert(EAArrayCount(str2) == 3, "EA_COMPILER_NO_UNICODE_CHAR_NAME_LITERALS failure."); // This test assumes that wchar_t is a 16bit or greater value. #endif #if defined(EA_CHAR16_NATIVE) && EA_CHAR16_NATIVE const char16_t str3[] = u"\U00002018\U00002019"; static_assert(EAArrayCount(str3) == 3, "EA_COMPILER_NO_UNICODE_CHAR_NAME_LITERALS failure."); #endif } #endif #ifndef EA_COMPILER_NO_RVALUE_REFERENCES { const int MAX_ARR_SIZE = 4096; struct StructWithArray { int arr[MAX_ARR_SIZE]; }; static_assert(EAArrayCount(StructWithArray().arr) == MAX_ARR_SIZE, ""); } #endif #if !defined(EA_COMPILER_NO_UNIFIED_INITIALIZATION_SYNTAX) { struct InitTest1 { int mX; double mY; }; struct InitTest2 { InitTest2(int x, double y) : mX{x}, mY{y} {} int mX; double mY; }; InitTest1 var1{5, 3.2}; InitTest2 var2{2, 4.3}; EATEST_VERIFY(var1.mY == 3.2); EATEST_VERIFY(var2.mY == 4.3); } #endif #if !defined(EA_COMPILER_NO_EXTENDED_FRIEND_DECLARATIONS) { class G; class X1 { friend G; }; } #endif #if !defined(EA_COMPILER_NO_THREAD_LOCAL) { // We don't yet test this because we don't have a sufficient compiler to test it with. } #endif return nErrorCount; } #if defined(EA_COMPILER_MSVC) && EA_COMPILER_VERSION >= 1900 // VS2015+ EA_DISABLE_VC_WARNING(5029); // nonstandard extension used: alignment attributes in C++ apply to variables, data members and tag types only #endif int TestEACompilerTraits() { int nErrorCount(0); // EA_COMPILER_IS_ANSIC // EA_COMPILER_IS_C99 // EA_COMPILER_IS_CPLUSPLUS // EA_COMPILER_MANAGED_CPP { // EA_COMPILER_INTMAX_SIZE #if (EA_COMPILER_INTMAX_SIZE == 16) /* To do: Test this when we get a machine that supports it (e.g. Linux64)/ #if defined(__GNUC__) #define int128_t __int128_t #define uint128_t __uint128_t #endif int128_t x = UINT128_C(0x12345678123456781234567812345678); uint128_t y = (x * 2); if(x == (int128_t)y) DoError(nErrorCount, "EA_COMPILER_INTMAX_SIZE test"); */ #elif (EA_COMPILER_INTMAX_SIZE == 8) int64_t x = UINT64_C(0x1234567812345678); uint64_t y = (x * 2); if(x == (int64_t)y) DoError(nErrorCount, "EA_COMPILER_INTMAX_SIZE test"); #elif (EA_COMPILER_INTMAX_SIZE == 32) int32_t x = UINT64_C(0x12345678); uint32_t y = (x * 2); if(x == (int32_t)y) DoError(nErrorCount, "EA_COMPILER_INTMAX_SIZE test"); #else int16_t x = UINT16_C(0x1234); uint16_t y = (x * 2); if(x == (int16_t)y) DoError(nErrorCount, "EA_COMPILER_INTMAX_SIZE test"); #endif } { // EA_OFFSETOF const size_t o = EA_OFFSETOF(OffsetofTestClass, mY); EA_DISABLE_VC_WARNING(6326) if(o != 4) DoError(nErrorCount, "EA_OFFSETOF test"); EA_RESTORE_VC_WARNING() } { // EA_SIZEOF_MEMBER const size_t s = EA_SIZEOF_MEMBER(SizeofMemberTestClass, mY); EA_DISABLE_VC_WARNING(6326) if(s != 4) DoError(nErrorCount, "EA_SIZEOF_MEMBER test"); EA_RESTORE_VC_WARNING() // There have been problems on some platforms (SNC version < 405) where extended sizeof was not properly // supported when used within a member function, so we test for that here. class TestClass { public: void TestExtendedSizeof(int& nErrorCount) { EA_DISABLE_VC_WARNING(6326) const size_t sizeOfmY = EA_SIZEOF_MEMBER(SizeofMemberTestClass, mY); if(sizeOfmY != 4) DoError(nErrorCount, "EA_SIZEOF_MEMBER test: within member function"); EA_RESTORE_VC_WARNING() } }tc; tc.TestExtendedSizeof(nErrorCount); } { // EA_ALIGN_OF, EA_PREFIX_ALIGN, etc. size_t a = EA_ALIGN_OF(int); EA_PREFIX_ALIGN(4) int b = 5; EA_ALIGN(8) int c; int d EA_POSTFIX_ALIGN(8); int e EA_POSTFIX_ALIGN(8) = 5; int f EA_POSTFIX_ALIGN(8)(5); struct EA_ALIGN(8) G { int x; }; struct EA_PREFIX_ALIGN(8) GG { int x; } EA_POSTFIX_ALIGN(8); EA_ALIGNED(int, h, 8) = 5; EA_ALIGNED(int, i, ALIGNMENT_AMOUNT_16)(5); EA_ALIGNED(int, j[3], ALIGNMENT_AMOUNT_16); EA_ALIGNED(int, k[3], ALIGNMENT_AMOUNT_16) = { 1, 2, 3 }; struct EA_ALIGN(8) L { int x; int y; }; EA_DISABLE_VC_WARNING(4359) // ARM64: C4359: 'TestEACompilerTraits::X': Alignment specifier is less than actual alignment (4), and will be ignored. EA_ALIGN(ALIGNMENT_AMOUNT_32) struct X { int x; int y; } m; EA_RESTORE_VC_WARNING() //int N[3] EA_PACKED; // Some compilers (e.g. GCC) don't support this or ignore this and generate a warning. struct P { int x EA_PACKED; int y EA_PACKED; }; struct Q { int x; int y; } EA_PACKED; typedef EA_ALIGNED(int, r, ALIGNMENT_AMOUNT_16); r rInstance; typedef EA_ALIGNED(Q, X16, ALIGNMENT_AMOUNT_16); X16 x16Instance; char buffer[256]; sprintf(buffer, "%p %p %p %p %p %p %p %p %p %p %p %p %p", &a, &b, &c, &d, &e, &f, &h, &i, &j, &k, &m, &rInstance, &x16Instance); } { // Test EA_ALIGN_OF if(EA_ALIGN_OF(int8_t) != sizeof(int8_t)) // This may not be a kosher test. DoError(nErrorCount, "EA_ALIGN_OF test (int16_t)"); if(EA_ALIGN_OF(int16_t) != sizeof(int16_t)) // This may not be a kosher test. DoError(nErrorCount, "EA_ALIGN_OF test (int16_t)"); if(EA_ALIGN_OF(int32_t) != sizeof(int32_t)) // This may not be a kosher test. DoError(nErrorCount, "EA_ALIGN_OF test (int32_t)"); #if !defined(EA_ABI_ARM_APPLE) if(EA_ALIGN_OF(int64_t) != sizeof(int64_t)) // This may not be a kosher test. DoError(nErrorCount, "EA_ALIGN_OF test (int64_t)"); #endif typedef void (*AlignTestFunctionType)(); if(EA_ALIGN_OF(AlignTestFunctionType) != sizeof(void*)) // This may not be a kosher test. DoError(nErrorCount, "EA_ALIGN_OF test (AlignTestFunctionType)"); } { // Test EA_ALIGN #ifdef EA_ALIGN char buffer[32]; EA_ALIGN(ALIGNMENT_AMOUNT_64) int x(0); sprintf(buffer, "%d", x); if(buffer[0] != '0') DoError(nErrorCount, "EA_ALIGN test 1"); if((intptr_t)&x & (ALIGNMENT_AMOUNT_64 -1)) DoError(nErrorCount, "EA_ALIGN test 2"); EA_ALIGN(ALIGNMENT_AMOUNT_64) ClassWithDefaultCtor cdcA; //EA_ALIGN(64) ClassWithoutDefaultCtor cwdcA; if((intptr_t)&cdcA & (ALIGNMENT_AMOUNT_64 -1)) DoError(nErrorCount, "EA_ALIGN test 3"); EA_ALIGN(ALIGNMENT_AMOUNT_64) ClassWithDefaultCtor cdcB(3); if((intptr_t)&cdcB & (ALIGNMENT_AMOUNT_64 -1)) DoError(nErrorCount, "EA_ALIGN test 4"); EA_ALIGN(ALIGNMENT_AMOUNT_64) ClassWithoutDefaultCtor cwdcB(3); if((intptr_t)&cwdcB & (ALIGNMENT_AMOUNT_64 -1)) DoError(nErrorCount, "EA_ALIGN test 5"); #else DoError(nErrorCount, "EA_ALIGN test 6"); #endif } { // Test EA_PREFIX_ALIGN #ifdef EA_PREFIX_ALIGN char buffer[32]; EA_PREFIX_ALIGN(ALIGNMENT_AMOUNT_64) int x(0); sprintf(buffer, "%d", x); if(buffer[0] != '0') DoError(nErrorCount, "EA_PREFIX_ALIGN test 1"); EA_PREFIX_ALIGN(64) ClassWithDefaultCtor cdcA; //EA_PREFIX_ALIGN(64) ClassWithoutDefaultCtor cwdcA; EA_PREFIX_ALIGN(64) ClassWithDefaultCtor cdcB(3); EA_PREFIX_ALIGN(64) ClassWithoutDefaultCtor cwdcB(3); #else DoError(nErrorCount, "EA_PREFIX_ALIGN test 2"); #endif } { // Test EA_POSTFIX_ALIGN #ifdef EA_POSTFIX_ALIGN char buffer[32]; int x EA_POSTFIX_ALIGN(ALIGNMENT_AMOUNT_64) = 0; sprintf(buffer, "%d", x); if(buffer[0] != '0') DoError(nErrorCount, "EA_POSTFIX_ALIGN test 1"); ClassWithDefaultCtor cdcA EA_POSTFIX_ALIGN(ALIGNMENT_AMOUNT_64); //ClassWithoutDefaultCtor cwdcA EA_POSTFIX_ALIGN(64); ClassWithDefaultCtor cdcB EA_POSTFIX_ALIGN(ALIGNMENT_AMOUNT_64)(3); ClassWithoutDefaultCtor cwdcB EA_POSTFIX_ALIGN(ALIGNMENT_AMOUNT_64)(3); #else DoError(nErrorCount, "EA_POSTFIX_ALIGN test 2"); #endif } { // Test EA_ALIGNED #ifdef EA_ALIGNED char buffer[64]; // Verify that a simple declaration works. EA_ALIGNED(int, xA, ALIGNMENT_AMOUNT_64); xA = 0; sprintf(buffer, "%d", xA); if((intptr_t)&xA & (ALIGNMENT_AMOUNT_64 -1)) DoError(nErrorCount, "EA_ALIGNED test 1"); // Verify that a declaration with assignment works. EA_ALIGNED(int, xB, ALIGNMENT_AMOUNT_64) = 0; sprintf(buffer, "%d", xB); if((intptr_t)&xB & (ALIGNMENT_AMOUNT_64 -1)) DoError(nErrorCount, "EA_ALIGNED test 2"); // Verify that a declaration with construction works. EA_ALIGNED(int, xC, ALIGNMENT_AMOUNT_64)(0); sprintf(buffer, "%d", xC); if((intptr_t)&xC & (ALIGNMENT_AMOUNT_64 -1)) DoError(nErrorCount, "EA_ALIGNED test 3"); // Verify that a typedefd declaration works. typedef EA_ALIGNED(int, int16, ALIGNMENT_AMOUNT_16); int16 n16 = 0; sprintf(buffer, "%p", &n16); if((intptr_t)&n16 & (ALIGNMENT_AMOUNT_16 - 1)) DoError(nErrorCount, "EA_ALIGNED test 4"); // Verify that the following tests compile. These tests are here // because the SN compiler (EDG front-end) has some problems with // GCC compatibility related to the 'aligned' __attribute__. ClassWithDefaultCtor cdc; ClassWithoutDefaultCtor cwdc(3); sprintf(buffer, "%p%p", &cdc, &cwdc); // Verify that regular usage of EA_ALIGNED works. EA_ALIGNED(ClassWithDefaultCtor, cdc16A, ALIGNMENT_AMOUNT_16); //EA_ALIGNED(ClassWithoutDefaultCtor, cwdcA, 16); // Doesn't have a default ctor, so this can't be done. sprintf(buffer, "%p%p", &cdc16A, (void*)NULL); // Verify that argument usage of EA_ALIGNED works. EA_ALIGNED(ClassWithDefaultCtor, cdcB, ALIGNMENT_AMOUNT_16)(3); EA_ALIGNED(ClassWithoutDefaultCtor, cwdcB, ALIGNMENT_AMOUNT_16)(3); sprintf(buffer, "%p%p", &cdcB, &cwdcB); // Verify that usage of EA_ALIGNED works within a typedef. typedef EA_ALIGNED(ClassWithDefaultCtor, ClassWithDefaultCtor16, ALIGNMENT_AMOUNT_16); ClassWithDefaultCtor16 cdcC(3); typedef EA_ALIGNED(ClassWithoutDefaultCtor, ClassWithoutDefaultCtor16, ALIGNMENT_AMOUNT_16); ClassWithoutDefaultCtor16 cwdcC(3); sprintf(buffer, "%p%p", &cdcC, &cwdcC); #else DoError(nErrorCount, "EA_ALIGNED test"); #endif } { // Test EA_NO_INLINE / EA_PREFIX_NO_INLINE / EA_POSTFIX_NO_INLINE DoNothingInline(); DoNothingPrefixInline(); } { // Test EA_FORCE_INLINE / EA_PREFIX_FORCE_INLINE / EA_POSTFIX_FORCE_INLINE DoNothingForceInline(); DoNothingPrefixForceInline(); } { // Test EA_FORCE_INLINE_LAMBDA auto testLambda = []() EA_FORCE_INLINE_LAMBDA { }; testLambda(); } { // Test EA_PACKED #ifdef EA_PACKED char buffer[32]; struct X { int x; } EA_PACKED; X x = { 0 }; sprintf(buffer, "%d", x.x); if(buffer[0] != '0') DoError(nErrorCount, "EA_PACKED test"); #else DoError(nErrorCount, "EA_PACKED test"); #endif } { // Test EA_LIKELY if(EA_UNLIKELY(nErrorCount > 0)) { if(EA_LIKELY(nErrorCount == 999999)) // Actually this isn't likely, but that's beside the point. DoError(nErrorCount, "EA_LIKELY test"); } } { // Test EA_INIT_PRIORITY // We don't test that the init priority succeeded in modifying the init priority. // We merely test that this compiles on all platforms and assume the compiler's // support of this is not broken. if(gInitPriorityTestClass0.mX != 0) DoError(nErrorCount, "EA_INIT_PRIORITY test."); if(gInitPriorityTestClass1.mX != 1) DoError(nErrorCount, "EA_INIT_PRIORITY test."); } { // Test EA_INIT_SEG // We don't test that the init_seg succeeded in modifying the init priority. // We merely test that this compiles on all platforms and assume the compiler's // support of this is not broken. if(gInitSegTestSection.mX != 2300) DoError(nErrorCount, "EA_INIT_SEG test."); } { // Test EA_MAY_ALIAS // We don't test that the init priority succeeded in modifying the init priority. // We merely test that this compiles on all platforms and assume the compiler's // support of this is not broken. if(gPtr0 != NULL) DoError(nErrorCount, "EA_MAY_ALIAS test."); if(gPtr1 != NULL) DoError(nErrorCount, "EA_MAY_ALIAS test."); } { // Test EA_ASSUME switch (nErrorCount / (nErrorCount + 1)) { case 0: Stricmp("nop0", "nop0"); break; case 1: Stricmp("nop1", "nop1"); break; default: EA_ASSUME(0); } } { // Test EA_PURE if(!PureFunction()) DoError(nErrorCount, "EA_PURE test"); } { // EA_WEAK if(gWeakVariable != 1) DoError(nErrorCount, "EA_WEAK test"); } { // Test EA_NO_VTABLE NoVTable1 nvt1; NoVTable2 nvt2; nvt1.InterfaceFunction(); nvt2.InterfaceFunction(); } { // Test EA_WCHAR_SIZE EA_DISABLE_VC_WARNING(6326) #ifdef EA_WCHAR_SIZE if((EA_WCHAR_SIZE != 1) && (EA_WCHAR_SIZE != 2) && (EA_WCHAR_SIZE != 4)) DoError(nErrorCount, "EA_WCHAR_SIZE test"); #else DoError(nErrorCount, "EA_WCHAR_SIZE test"); #endif EA_RESTORE_VC_WARNING() } { // Test EA_RESTRICT struct TestRestrict{ static size_t Test(char* EA_RESTRICT p){ return sizeof(p); } }; char* p = NULL; if(TestRestrict::Test(p) == 0) // This isn't a real test. If there is a failure, it will happen at compile time. DoError(nErrorCount, "EA_RESTRICT test"); } { // Test EA_DEPRECATED /* This causes warnings on compilers, so just disable it. #if defined(EA_DEPRECATED) && (!defined(__GNUC__) || ((__GNUC__ * 100 + __GNUC_MINOR__) < 402)) // GCC 4.2+ is converting deprecated into an error instead of a warning. char buffer[32]; EA_DEPRECATED int x(0); sprintf(buffer, "%d", x); (void)x; if(buffer[0] != '0') DoError(nErrorCount, "EA_DEPRECATED test"); #elif !defined (EA_DEPRECATED) DoError(nErrorCount, "EA_DEPRECATED test"); #endif */ } { // Test EA_PASCAL #ifdef EA_PASCAL struct X{ void EA_PASCAL DoNothing(){} }; X x; x.DoNothing(); #else DoError(nErrorCount, "EA_PASCAL test"); #endif } { // Test EA_PASCAL_FUNC #ifdef EA_PASCAL_FUNC struct X{ void EA_PASCAL_FUNC(DoNothing()){} }; X x; x.DoNothing(); #else DoError(nErrorCount, "EA_PASCAL_FUNC test"); #endif } // EA_SSE // Not sure how to properly test at this time. { // EA_FP16C #if EA_FP16C // For this test just try to call an intrinsic that is only // available when FP16C is available. The test can make sure the // platform actually supports FP16C when it claims to support it, // but it can't verify a platform doesn't support FP16C. _mm_cvtph_ps(_mm_set1_epi32(42)); #endif } { // EA_IMPORT // Not possible to do this because import means it will come from outside. //struct X{ EA_IMPORT void DoNothing(){} }; //X x; //x.DoNothing(); } { // EA_EXPORT struct X{ EA_EXPORT void DoNothing(){} }; X x; x.DoNothing(); } // EA_PREPROCESSOR_JOIN // EA_STRINGIFY { char buffer[32]; char bufferExpected[32]; const int line = (__LINE__ + 2); sprintf(buffer, "%s %s", EA_STRINGIFY(EA_PREPROCESSOR_JOIN(test_, __LINE__)), EA_STRINGIFY(__LINE__)); sprintf(bufferExpected, "test_%d %d", line, line); if(strcmp(buffer, bufferExpected) != 0) DoError(nErrorCount, "EA_PREPROCESSOR_JOIN/EA_STRINGIFY test"); } { // EAArrayCount const int testArray[13] = { 0 }; const size_t arrayCount = EAArrayCount(testArray); EA_DISABLE_VC_WARNING(6326) if((arrayCount != 13) || (testArray[0] != 0)) DoError(nErrorCount, "EAArrayCount test"); EA_RESTORE_VC_WARNING() const float testArray2[EAArrayCount(testArray)] = {}; static_assert(EAArrayCount(testArray2) == EAArrayCount(testArray), "Array counts should be equivalent."); static_assert(EAArrayCount(testArray2) == 13, "Float array should have 13 elements."); EA_DISABLE_VC_WARNING(6326) if (EAArrayCount(testArray2) != EAArrayCount(testArray)) DoError(nErrorCount, "EAArrayCount - Array counts should be equivalent."); EA_RESTORE_VC_WARNING() EA_DISABLE_VC_WARNING(6326) if (EAArrayCount(testArray2) != 13) DoError(nErrorCount, "EAArrayCount - Float array should have 13 elements."); EA_UNUSED(testArray2); EA_RESTORE_VC_WARNING() // Regresssion of user bug report that static_assert fails with some C++11 compilers. // We revised the templated definition of EAArrayCount to deal with the failure. struct Example { int32_t mItems[7]; Example() { static_assert(EAArrayCount(mItems) == 7, "invalid size"); memset(mItems, 0x77, sizeof(mItems)); } // This was failing with the original templated version of EAArrayCount. }; Example example; EATEST_VERIFY(example.mItems[0] == 0x77777777); } { // static_assert // Should succeed. static_assert(sizeof(int32_t) == 4, "static_assert failure"); // Should fail. //static_assert(sizeof(int32_t) == 8, "static_assert failure"); } { // EA_OPTIMIZE_OFF / EA_OPTIMIZE_ON int result = DisabledOptimizations(2); if(result != 2*37) DoError(nErrorCount, "EA_OPTIMIZE_OFF test"); } { // EA_UNUSED FunctionWithUnusedVariables(3); } { // EA_EXTERN_TEMPLATE eabase_template x; x.value = 0; if(x.GetValue() != 0) DoError(nErrorCount, "EA_EXTERN_TEMPLATE test"); } { // EA_FUNCTION_DELETE EA_FUNCTION_DELETE_Test test(17); EATEST_VERIFY(test.x == 17); } { // EA_NON_COPYABLE / EANonCopyable NonCopyableA ncA1; ncA1.x = 1; //NonCopyableA ncA2(ncA1); // Both of these lines should result in //ncA1 = ncA1; // compiler errors if enabled. EA_UNUSED(ncA1); NonCopyableB ncB1; ncB1.x = 1; //NonCopyableB ncB2(ncB1); // Both of these lines should result in //ncB1 = ncB1; // compiler errors if enabled. EA_UNUSED(ncB1); NonCopyableSubclass ncs1(3); //NonCopyableSubclass ncs2(ncs1); // Both of these lines should result in //ncs2 = ncs2; // compiler errors if enabled. EATEST_VERIFY(ncs1.mX == 3); struct NonCopyableLocal { NonCopyableLocal(){} int x; EA_NON_COPYABLE(NonCopyableLocal) }; NonCopyableLocal ncLocal1; ncLocal1.x = 1; //NonCopyableLocal ncLocal2(ncLocal1); // Both of these lines should result in //ncLocal1 = ncLocal1; // compiler errors if enabled. EA_UNUSED(ncLocal1); } return nErrorCount; } #if defined(EA_COMPILER_MSVC) && EA_COMPILER_VERSION >= 1900 // VS2015+ EA_RESTORE_VC_WARNING(); #endif ///////////////////////////////////////////////// // nullptr test ///////////////////////////////////////////////// #if !defined(EA_HAVE_nullptr_IMPL) #define EA_RTTI_ENABLED 0 // This is something that ideally would be defined in EABase. int mfCCount = 0; struct C { void mf() { mfCCount++; } }; int fDoubleCount = 0; static void f(double*) { fDoubleCount++; } int fIntCount = 0; static void f(int) { fIntCount++; } int gTCount = 0; template void g(T*) { gTCount++; } int hTCount = 0; template void h(T) { hTCount++; } #endif static int TestNullPtr() { int nErrorCount(0); #if defined(EA_HAVE_nullptr_IMPL) // If the compiler provides a native version... // Don't question it. VC++ nullptr -seems- to be not entirely conforming anyway. #else using namespace std; // DoError("TestNullptr\n"); void* pv = nullptr; // OK EATEST_VERIFY(pv == 0); EATEST_VERIFY(pv == nullptr); #ifndef __MWERKS__ // Currently the Metrowerks compiler crashes on this code. EATEST_VERIFY(nullptr == pv); #endif pv = &pv; // OK EATEST_VERIFY(pv != 0); #if !defined(__GNUC__) || (__GNUC__ > 3) EATEST_VERIFY(pv != nullptr); #endif const char* pc = nullptr; // OK EATEST_VERIFY(pc == 0); EATEST_VERIFY(pc == nullptr); #ifndef __MWERKS__ EATEST_VERIFY(nullptr == pc); #endif C* pC = nullptr; // OK EATEST_VERIFY(pC == 0); EATEST_VERIFY(pC == nullptr); #ifndef __MWERKS__ EATEST_VERIFY(nullptr == pC); #endif f(nullptr); // OK. Calls f(double*). EATEST_VERIFY(fDoubleCount == 1); f(0); // OK. Calls f(int) EATEST_VERIFY(fIntCount == 1); //g(nullptr); // Not OK. Can't deduce T h(0); // OK. Deduces T = int EATEST_VERIFY(hTCount == 1); h(nullptr); // OK. Deduces T = nullptr_t EATEST_VERIFY(hTCount == 2); h((float*)nullptr); // OK. Deduces T = float* EATEST_VERIFY(hTCount == 3); void (C::*pmf)() = 0; // OK EATEST_VERIFY(pmf == 0); #if !defined(__GNUC__) || (__GNUC__ > 3) void (C::*pmf2)() = nullptr; // OK EA_UNUSED(pmf2); #ifndef __MWERKS__ // CodeWarrior is not following the C++ Standard properly. EATEST_VERIFY(pmf2 == 0); EATEST_VERIFY(pmf2 == nullptr); EATEST_VERIFY(nullptr == pmf2); #endif #endif #if !defined(__GNUC__) || (__GNUC__ > 3) void (C::*pmf3)() = &C::mf; #ifndef __MWERKS__ EATEST_VERIFY(pmf3 != nullptr); #endif #endif nullptr_t n1 = nullptr, n2 = nullptr; // OK n1 = n2; // OK h(n1); //const int const0 = 0; //if(const0 == nullptr) {} // Not OK. //int n = 0; //if(n == nullptr) {} // Not OK. //nullptr_t* pN = &n1; // Not OK. Address can't be taken. EATEST_VERIFY(!nullptr); // Supposedly OK, but VC++ doesn't accept it. if(nullptr) // Supposedly OK, but VC++ doesn't accept it. EATEST_VERIFY(false); int val = 0; char* ch3 = val ? nullptr : nullptr; // OK. EATEST_VERIFY(ch3 == 0); //char* ch4 = val ? 0 : nullptr; // Not OK. Types are not compatible. //int n3 = val ? nullptr : nullptr; // Not OK. nullptr can't be converted to int. //int n4 = val ? 0 : nullptr; // Not OK. Types are not compatible. // void* p = 0; // reinterpret_cast(p); // Not OK. But all compilers allow this. A reinterpret_cast cannot be used to convert a value of any type to the type std::nullptr_t. //This is supposed to succeed, but we can't make it so, given the conflicting requirements of the C++ and nullptr standards. //EATEST_VERIFY(sizeof(nullptr) == sizeof(void*)); // I don't currently have a means to make this work. See the class for why. #ifndef __MWERKS__ nullptr_t n3 = nullptr, n4 = nullptr; EATEST_VERIFY(n3 == n4); EATEST_VERIFY(!(n3 != n4)); EATEST_VERIFY(n3 <= n4); EATEST_VERIFY(n3 >= n4); EATEST_VERIFY(!(n3 < n4)); EATEST_VERIFY(!(n3 > n4)); #endif #if EA_RTTI_ENABLED typeid(nullptr); // OK #endif #ifndef EA_COMPILER_NO_EXCEPTIONS try{ pv = 0; throw nullptr; // OK } catch(nullptr_t n) { EATEST_VERIFY(n == pv); // OK h(n); } #endif #endif // EA_HAVE_nullptr_IMPL return nErrorCount; } static int TestEAHave() { int nErrorCount(0); // EA_HAVE_XXX_DECL // // We don't have a simple way to test these, as they indicate the presence of // declarations and not necessarily the presence of implementations. // // EA_HAVE_mkstemps_DECL // EA_HAVE_gettimeofday_DECL // EA_HAVE_strcasecmp_DECL // EA_HAVE_strncasecmp_DECL // EA_HAVE_mmap_DECL // EA_HAVE_fopen_DECL // EA_HAVE_ISNAN(x) // EA_HAVE_ISINF(x) // EA_HAVE_itoa_DECL // EA_HAVE_nanosleep_DECL // EA_HAVE_utime_DECL // EA_HAVE_ftruncate_DECL // EA_HAVE_localtime_DECL // EA_HAVE_pthread_getattr_np_DECL #if defined(EA_HAVE_ISNAN) EATEST_VERIFY(EA_HAVE_ISNAN(1.f) == 0); #endif #if defined(EA_HAVE_ISINF) EATEST_VERIFY(EA_HAVE_ISINF(1.f) == 0); #endif // EA_HAVE_XXX_IMPL #if defined(EA_HAVE_WCHAR_IMPL) size_t wlen = wcslen(L"test"); EATEST_VERIFY(wlen == 4); // Expect success. #endif #if defined(EA_HAVE_getenv_IMPL) char* p = getenv("nonexistent_asdf"); EATEST_VERIFY(!p); // Expect failure. #endif #if defined(EA_HAVE_setenv_IMPL) // http://pubs.opengroup.org/onlinepubs/009695399/functions/setenv.html // int setenv(const char *envname, const char *envval, int overwrite); setenv("test_asdf", "value", 0); // We ignore the return value, as we can't tell if the platform allows it. #endif #if defined(EA_HAVE_unsetenv_IMPL) unsetenv("test_asdf"); // Ignore the return value. #endif #if defined(EA_HAVE_putenv_IMPL) // int putenv(char* string); char str[] = "a=b"; #if defined(EA_PLATFORM_MICROSOFT) && defined(EA_COMPILER_MICROSOFT) // Microsoft uses _putenv, while others use putenv. int putenvSuccess = _putenv(str); #else int putenvSuccess = putenv(str); #endif EATEST_VERIFY(putenvSuccess == 0); #endif #if defined(EA_HAVE_time_IMPL) time_t timeResult = time(NULL); EATEST_VERIFY(timeResult != 0); // Expect success. #endif #if defined(EA_HAVE_clock_IMPL) // http://www.cplusplus.com/reference/ctime/clock/ clock_t clockResult = clock(); EATEST_VERIFY(clockResult != (clock_t) -1); // Expect success. #endif #if defined(EA_HAVE_fopen_IMPL) // We don't have a portable way of testing the success of this, as different platforms have different file systems and requirements. // since we want this to fail, we will use a normal Windows path as some platforms /require/ a windows-like mount path else they call abort() FILE* pFile = fopen("Q:\\nonexistent_pleasedontexist", "r"); EATEST_VERIFY(pFile == NULL); // Expect failure. if(pFile) fclose(pFile); #endif #if defined(EA_HAVE_inet_ntop_IMPL) char inetResult[32]; const char* pInetNtopResult = inet_ntop(0, "", inetResult, (uint16_t)EAArrayCount(inetResult)); // Cast to uint16_t because different libraries declare this arg differently, and this is a lowest common denominator. EATEST_VERIFY(pInetNtopResult == NULL); // Expect failure. #endif #if defined(EA_HAVE_inet_pton_IMPL) char inetPtonResult[32]; int inetResultVal = inet_pton(0, "", inetPtonResult); EATEST_VERIFY(inetResultVal <= 0); // Expect failure. #endif #if defined(EA_HAVE_clock_gettime_IMPL) struct timespec tp; int clockGettimeResult = clock_gettime(CLOCK_MONOTONIC, &tp); EATEST_VERIFY(clockGettimeResult <= 0); // Expect success or error. #endif #if defined(EA_HAVE_getcwd_IMPL) { char cwdBuffer[1]; char *result = getcwd(cwdBuffer, EAArrayCount(cwdBuffer)); EA_UNUSED(result); } #endif #if defined(EA_HAVE_tmpnam_IMPL) { char tmpnamBuffer[L_tmpnam]; char *result = tmpnam(tmpnamBuffer); EA_UNUSED(result); } #endif #if defined(EA_HAVE_nullptr_IMPL) // This is exercised elsewhere in this test. #endif #if defined(EA_HAVE_std_terminate_IMPL) if(nErrorCount == INT_MIN) // This is impossible. std::terminate(); #endif #if defined(EA_HAVE_CPP11_ITERATOR_IMPL) // : std::begin, std::end, std::prev, std::next, std::move_iterator. #if defined(EA_HAVE_CPP11_INITIALIZER_LIST) eastl::vector intArray; EATEST_VERIFY(std::begin(intArray) == std::end(intArray)); #endif char charArray[16] = { 0 }; EATEST_VERIFY(std::begin(charArray) != std::end(charArray)); #endif #if defined(EA_HAVE_CPP11_SMART_POINTER_IMPL) // std::weak_ptr, std::shared_ptr, std::unique_ptr, std::bad_weak_ptr std::shared_ptr spInt; std::weak_ptr wpInt; std::unique_ptr upInt; //std::bad_weak_ptr bwpInt; #endif #if defined(EA_HAVE_CPP11_FUNCTIONAL_IMPL) && !defined(EA_PLATFORM_ANDROID) // Our Android build system is failing to link _1, _2, etc. // function, mem_fn, bad_function_call, is_bind_expression, is_placeholder, reference_wrapper, hash, bind, ref, cref. // It turns out that all compiler/library combinations that support this also support C++11 auto, so we can use it. #if !defined(EA_PLATFORM_ANDROID) // Our Android build system is failing to link _1, _2, etc. using namespace std::placeholders; //for _1, _2, _3... int n = 7; auto f = std::bind(BindTestFunction, _2, _1, 42, std::cref(n), n); f(1, 2, 1001); // 1 is bound by _2, 2 is bound by _1, 1001 is unused BindTestStruct bts; auto f2 = std::bind(&BindTestStruct::Test, bts, 95, _1); f2(5); #endif std::hash hash32; EATEST_VERIFY(hash32(37) == hash32(37)); #endif #if defined(EA_HAVE_CPP11_EXCEPTION_IMPL) // current_exception, rethrow_exception, exception_ptr, make_exception_ptr #if !defined(EA_COMPILER_NO_EXCEPTIONS) EA_DISABLE_VC_WARNING(4571) if(nErrorCount == 9999999) // This will never be true. { std::exception_ptr ep = std::make_exception_ptr(std::logic_error("logic_error")); try { std::rethrow_exception(ep); } catch (...) { ep = std::current_exception(); std::rethrow_exception(ep); } } EA_RESTORE_VC_WARNING() #endif #endif #if defined(EA_HAVE_CPP11_TYPE_TRAITS) // Some form of type traits have been supported by compilers since well before C++11. But C++11 introduced // a number of type traits that weren't previously supported by compilers. We require that full C++11 type // traits be supported. See the C++11 Standard, section 20.9.2. // We currently test a sampling of specific traits that didn't exist in preliminary standard library versions. bool ttResult = std::is_nothrow_move_constructible::value; EATEST_VERIFY(ttResult); ttResult = std::is_standard_layout::value; EATEST_VERIFY(ttResult); #endif return nErrorCount; } static int TestEAAlignment() { // This test does a couple of allocations and for each allocation it determines // the minimal alignment. If this (local) minimum is less than the global minimum // then the global minimum is updated. After all the allocation sizes and iterations // it checks this minimum to make sure that the EABase EA_PLATFORM_MIN_MALLOC_ALIGNMENT // is at least that number, since you would never want to ask for finer grained // allocations as malloc can't give them. int nErrorCount(0); const size_t MAX_SIZE = 128; const size_t NUM_ITERATIONS = 32; size_t minAlignment = MAX_SIZE; for(size_t size = 1; size <= MAX_SIZE; ++size) { for(size_t iteration = 0; iteration < NUM_ITERATIONS; ++iteration) { void* ptr = malloc(size); size_t address = static_cast(reinterpret_cast(ptr)); size_t alignment = MAX_SIZE; do { if((address & (alignment - 1)) == 0) { break; } else { alignment >>= 1; } } while(alignment > 0); if(alignment < minAlignment) minAlignment = alignment; free(ptr); } } EATEST_VERIFY_F(EA_PLATFORM_MIN_MALLOC_ALIGNMENT <= minAlignment, "'EA_PLATFORM_MIN_MALLOC_ALIGNMENT=%d' <= 'minAlignment=%d' failure on '%s'", EA_PLATFORM_MIN_MALLOC_ALIGNMENT, minAlignment, EA_PLATFORM_DESCRIPTION); return nErrorCount; } #include #include #include static void TestEAStdargReferenceHelp(char* p, va_list_reference args) { EA::StdC::Sprintf(p, "%d", va_arg(args, int)); } static void TestEAStdargReference(char* p1, char* p2, ...) // Must be called with two ints for ... { va_list args; va_start(args, p2); TestEAStdargReferenceHelp(p1, args); // We pass args to TestEAStdargReferenceHelp by reference, which results in args being TestEAStdargReferenceHelp(p2, args); // modified upon return. So upon this second call args should have used the first int arg. va_end(args); } static void TestEAStdargCopy(char* p1, char* p2, ...) // Must be called with two ints for ... { va_list args, argsCopy; va_start(args, p2); va_copy(argsCopy, args); EA::StdC::Vsprintf(p1, "%d", args); EA::StdC::Vsprintf(p2, "%d", argsCopy); va_end(args); va_end(argsCopy); } static int TestEAStdarg() { int nErrorCount(0); // VA_ARG_COUNT static_assert(VA_ARG_COUNT() == 0, "VA_ARG_COUNT()"); static_assert(VA_ARG_COUNT(1) == 1, "VA_ARG_COUNT(1)"); static_assert(VA_ARG_COUNT(2, 2) == 2, "VA_ARG_COUNT(2)"); static_assert(VA_ARG_COUNT(3, 3, 3) == 3, "VA_ARG_COUNT(3)"); static_assert(VA_ARG_COUNT(4, 4, 4, 4) == 4, "VA_ARG_COUNT(4)"); static_assert(VA_ARG_COUNT(5, 5, 5, 5, 5) == 5, "VA_ARG_COUNT(5)"); char buffer1[64]; char buffer2[64]; // va_copy TestEAStdargCopy(buffer1, buffer2, 17, 99); EATEST_VERIFY((EA::StdC::AtoI32(buffer1) == 17) && (EA::StdC::AtoI32(buffer2) == 17)); // va_list_reference TestEAStdargReference(buffer1, buffer2, 17, 99); EATEST_VERIFY((EA::StdC::AtoI32(buffer1) == 17) && (EA::StdC::AtoI32(buffer2) == 99)); return nErrorCount; } static int TestEAUnits() { int nErrorCount(0); static_assert(EA_BYTE(64) == 64, "SI units mismatch"); static_assert(EA_BYTE(1000) == 1000, "SI units mismatch"); static_assert(EA_KILOBYTE(1) != EA_KIBIBYTE(1), "SI units mismatch"); static_assert(EA_MEGABYTE(1) != EA_MEBIBYTE(1), "SI units mismatch"); static_assert(EA_GIGABYTE(1) != EA_GIBIBYTE(1), "SI units mismatch"); static_assert((4 % EA_BYTE(4*10)) == 4, "Order of operations error"); //If unit macros aren't enclosed in parentheses, this will cause order of operation problems in this situation. static_assert((4 % EA_MEBIBYTE(4)) == 4, "Order of operations error"); //If unit macros aren't enclosed in parentheses, this will cause order of operation problems in this situation. #ifndef EA_PROCESSOR_X86 static_assert(EA_TERABYTE(1) != EA_TEBIBYTE(1), "SI units mismatch"); static_assert(EA_PETABYTE(1) != EA_PEBIBYTE(1), "SI units mismatch"); static_assert(EA_EXABYTE(1) != EA_EXBIBYTE(1), "SI units mismatch"); #endif static_assert(EA_KILOBYTE(1) == 1000, "SI units mismatch"); static_assert(EA_MEGABYTE(2) == EA_KILOBYTE(2) * 1000, "SI units mismatch"); static_assert(EA_GIGABYTE(3) == EA_MEGABYTE(3) * 1000, "SI units mismatch"); #ifndef EA_PROCESSOR_X86 static_assert(EA_TERABYTE(4) == EA_GIGABYTE(4) * 1000, "SI units mismatch"); static_assert(EA_PETABYTE(5) == EA_TERABYTE(5) * 1000, "SI units mismatch"); static_assert(EA_EXABYTE(6) == EA_PETABYTE(6) * 1000, "SI units mismatch"); #endif static_assert(EA_KIBIBYTE(1) == 1024, "SI units mismatch"); static_assert(EA_MEBIBYTE(2) == EA_KIBIBYTE(2) * 1024, "SI units mismatch"); static_assert(EA_GIBIBYTE(3) == EA_MEBIBYTE(3) * 1024, "SI units mismatch"); #ifndef EA_PROCESSOR_X86 static_assert(EA_TEBIBYTE(4) == EA_GIBIBYTE(4) * 1024, "SI units mismatch"); static_assert(EA_PEBIBYTE(5) == EA_TEBIBYTE(5) * 1024, "SI units mismatch"); static_assert(EA_EXBIBYTE(6) == EA_PEBIBYTE(6) * 1024, "SI units mismatch"); #endif return nErrorCount; } template static void TestInt128T(MakeInt128T MakeInt128, const char* errorMsg, int& nErrorCount) { auto VERIFY = [&](bool result) { if(!result) DoError(nErrorCount, errorMsg); }; const auto TestValue = MakeInt128(0x1234567812345678, 0x1234567812345678); const Int128T zero = MakeInt128(0, 0); const Int128T one = MakeInt128(0, 1); const Int128T two = MakeInt128(0, 2); const Int128T big = MakeInt128(0x1234567812345678, 0x1234567812345678);; const Int128T negative_one = MakeInt128(0xffffffffffffffff, 0xffffffffffffffff); const Int128T half_range = MakeInt128(0x0, 0xffffffffffffffff); { // Int128T a1 = 42.f; // Int128T a2 = 42.0f; // Int128T a3 = 42; // Int128T a4 = 42u; // Int128T a5 = 42ul; // Int128T a6 = 42ull; } // default ctor { { Int128T a; (void)a; } { Int128T a{}; (void)a; } static_assert(eastl::is_trivially_default_constructible_v, "128-bit integer failure"); } // operator- { VERIFY(negative_one == -one); } // operator~ { auto not_one = ~one; VERIFY(not_one == MakeInt128(0xffffffffffffffff, 0xfffffffffffffffe)); } // operator+ { VERIFY(zero == +zero); VERIFY(one == +one); VERIFY(big == +big); } // operator+ // operator- // operator* // operator/ // operator% { auto i = MakeInt128(42, 42); i = i + one; VERIFY(i == MakeInt128(42, 43)); i = i - one; VERIFY(i == MakeInt128(42, 42)); i = i * two; VERIFY(i == MakeInt128(84, 84)); i = i / two; VERIFY(i == MakeInt128(42, 42)); } // operator== / operator!= { VERIFY(TestValue == MakeInt128(0x1234567812345678, 0x1234567812345678)); VERIFY(TestValue == TestValue); VERIFY(MakeInt128(0x1, 0x1) != MakeInt128(0x1, 0x2)); } // operator< { VERIFY(zero < one); VERIFY(one < two); VERIFY(zero < two); VERIFY(zero < big); VERIFY(one < big); VERIFY(MakeInt128(123, 122) < MakeInt128(123, 123)); VERIFY(MakeInt128(122, 123) < MakeInt128(123, 123)); } // operator> / operator>= { VERIFY(TestValue > MakeInt128(0, 0x1234567812345678)); VERIFY(TestValue >= MakeInt128(0, 0x1234567812345678)); VERIFY(TestValue >= TestValue); VERIFY(TestValue >= TestValue); } // operator< / operator<= { VERIFY(MakeInt128(0, 0x1234567812345678) < TestValue); VERIFY(MakeInt128(0, 0x1234567812345678) <= TestValue); VERIFY(TestValue <= TestValue); VERIFY(TestValue <= TestValue); } // operator++ { auto i = MakeInt128(0, 0); VERIFY(i++ == MakeInt128(0, 0)); VERIFY(++i == MakeInt128(0, 2)); VERIFY(++i == MakeInt128(0, 3)); VERIFY(i++ == MakeInt128(0, 3)); { auto n1 = half_range; VERIFY(++n1 == MakeInt128(1, 0)); } } // operator-- { auto i = MakeInt128(0, 5); VERIFY(i-- == MakeInt128(0, 4)); VERIFY(--i == MakeInt128(0, 4)); VERIFY(--i == MakeInt128(0, 3)); VERIFY(i-- == MakeInt128(0, 2)); { auto n1 = MakeInt128(1, 0); VERIFY(n1-- == half_range); } } // operator+= // operator-= // operator*= // operator/= // operator%= { auto n = MakeInt128(0, 5); n += MakeInt128(0, 15); VERIFY(n == MakeInt128(0, 20)); n -= MakeInt128(0, 18); VERIFY(n == MakeInt128(0, 2)); n *= MakeInt128(0, 2); VERIFY(n == MakeInt128(0, 4)); n /= MakeInt128(0, 2); VERIFY(n == MakeInt128(0, 2)); n %= MakeInt128(0, 2); VERIFY(n == MakeInt128(0, 0)); } // operator>> // operator<< // operator>>= // operator<<= { auto n = MakeInt128(0, 0x4); { auto a = n >> 1; VERIFY(a == MakeInt128(0, 0x2)); a >>= 1; VERIFY(a == MakeInt128(0, 0x1)); } { auto a = n << 1; VERIFY(a == MakeInt128(0, 0x8)); a <<= 1; VERIFY(a == MakeInt128(0, 0x10)); } { auto a = half_range; a <<= 1; VERIFY(a == MakeInt128(0x1, 0xfffffffffffffffe)); } { auto a = half_range; a >>= 1; VERIFY(a == MakeInt128(0x0, 0x7fffffffffffffff)); } } // operator^ // operator| // operator& // operator^= // operator|= // operator&= { const auto n1 = MakeInt128(0xAAAAAAAAAAAAAAAA, 0xAAAAAAAAAAAAAAAA); const auto n2 = MakeInt128(0x5555555555555555, 0x5555555555555555); { auto i = n1 ^ n2; VERIFY(i == negative_one); auto n3 = n1; n3 ^= n2; VERIFY(n3 == negative_one); } { auto i = n1 | n2; VERIFY(i == negative_one); auto n3 = n1; n3 |= n2; VERIFY(n3 == negative_one); } { auto i = n1 & n2; VERIFY(i == zero); auto n3 = n1; n3 &= n2; VERIFY(n3 == zero); } } // Test loop counter { { int counter = 0; Int128T i = MakeInt128(0,0); for (; i < MakeInt128(0,10); i++) counter++; VERIFY(i == MakeInt128(0, counter)); } { // int counter = 0; // for (Int128T i = 0; i < 10; i++) // counter++; // VERIFY(i == counter); } } } static int TestEAInt128_t() { int nErrorCount(0); TestInt128T(UINT128_C, "uint128_t test failure", nErrorCount); TestInt128T(INT128_C, "int128_t test failure", nErrorCount); return nErrorCount; } // EA_WCHAR_UNIQUE template struct wchar_unique { enum { value = 1 }; }; // if wchar_t is unique then wchar_unique::value should be 1 template <> struct wchar_unique { enum { value = 0 }; }; // if wchar_unique is not unique then it should match one of the specializations and the value will be 0. template <> struct wchar_unique { enum { value = 0 }; }; template <> struct wchar_unique { enum { value = 0 }; }; #if EA_WCHAR_UNIQUE static_assert( wchar_unique::value == 1, "WCHAR_UNIQUE appears to be incorrectly defined to 1 by EABase" ); #else static_assert( wchar_unique::value == 0, "WCHAR_UNIQUE appears to be incorrectly defined to 0 by EABase" ); #endif // // Tests for EA_IS_ENABLED // #define EABASE_TEST_FEATURE_A EA_ENABLED #if EA_IS_ENABLED(EABASE_TEST_FEATURE_A) // Feature A is enabled #else #error Error EABASE_TEST_FEATURE_A should be enabled. #endif // Make sure it is possible to successfully negate the test. #if !EA_IS_ENABLED(EABASE_TEST_FEATURE_A) #error Error EABASE_TEST_FEATURE_A should be enabled. #endif #define EABASE_TEST_FEATURE_B EA_DISABLED #if EA_IS_ENABLED(EABASE_TEST_FEATURE_B) #error Error EABASE_TEST_FEATURE_B should be disabled. #endif // Make sure it is possible to successfully negate the test. #if !EA_IS_ENABLED(EABASE_TEST_FEATURE_B) // Feature B is not enabled #else #error Error EABASE_TEST_FEATURE_B should be disabled. #endif // The test below should cause compilation to fail if it is uncommented. However we can't // obviously enable the test because it will break the build. It should be tested manually // if changes to EA_IS_ENABLED are made. // // #if EA_IS_ENABLED(EABASE_TEST_FEATURE_WITH_NO_DEFINE) // #endif int EAMain(int, char**) { int nErrorCount = 0; int nTotalErrorCount = 0; nErrorCount = TestEABase(); EA::EAMain::Report("EABase test failure count: %d\n\n", nErrorCount); nTotalErrorCount += nErrorCount; nErrorCount = TestEAResult(); EA::EAMain::Report("EAResult test failure count: %d\n\n", nErrorCount); nTotalErrorCount += nErrorCount; nErrorCount = TestEAPlatform(); EA::EAMain::Report("EAPlatform test failure count: %d\n\n", nErrorCount); nTotalErrorCount += nErrorCount; nErrorCount = TestEACompiler(); EA::EAMain::Report("EACompiler test failure count: %d\n\n", nErrorCount); nTotalErrorCount += nErrorCount; nErrorCount = TestEACompilerTraits(); EA::EAMain::Report("EACompilerTraits test failure count: %d\n\n", nErrorCount); nTotalErrorCount += nErrorCount; nErrorCount = TestNullPtr(); EA::EAMain::Report("nullptr test failure count: %d\n\n", nErrorCount); nTotalErrorCount += nErrorCount; nErrorCount = TestEAHave(); EA::EAMain::Report("EAHave test failure count: %d\n\n", nErrorCount); nTotalErrorCount += nErrorCount; nErrorCount = TestEAAlignment(); EA::EAMain::Report("EAAlignment test failure count: %d\n\n", nErrorCount); nTotalErrorCount += nErrorCount; nErrorCount = TestEAStdarg(); EA::EAMain::Report("EAStdarg test failure count: %d\n\n", nErrorCount); nTotalErrorCount += nErrorCount; nErrorCount = TestEAUnits(); EA::EAMain::Report("EAUnits test failure count: %d\n\n", nErrorCount); nTotalErrorCount += nErrorCount; nErrorCount = TestEAInt128_t(); EA::EAMain::Report("EAInt128_t test failure count: %d\n\n", nErrorCount); nTotalErrorCount += nErrorCount; if (nTotalErrorCount == 0) EA::EAMain::Report("\nAll tests completed successfully.\n"); else EA::EAMain::Report("\nTests failed. Total error count: %d\n", nTotalErrorCount); return nTotalErrorCount; } EA_RESTORE_VC_WARNING() // for the following from above: EA_DISABLE_VC_WARNING(4265 4296 4310 4350 4481 4530 4625 4626 4996)