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MinecraftConsoles/Minecraft.Client/Windows64/Iggy/include/rrCore.h
void_17 b9a2951901 Revert "Get rid of MSVC's __int64" 
This reverts commit d63f79325f.
2026-03-02 17:39:35 +07:00

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/// ========================================================================
// (C) Copyright 1994- 2014 RAD Game Tools, Inc. Global types header file
// ========================================================================
#ifndef __RADRR_COREH__
#define __RADRR_COREH__
#define RADCOPYRIGHT "Copyright (C) 1994-2014, RAD Game Tools, Inc."
// __RAD16__ means 16 bit code (Win16)
// __RAD32__ means 32 bit code (DOS, Win386, Win32s, Mac AND Win64)
// __RAD64__ means 64 bit code (x64)
// Note oddness - __RAD32__ essentially means "at *least* 32-bit code".
// So, on 64-bit systems, both __RAD32__ and __RAD64__ will be defined.
// __RADDOS__ means DOS code (16 or 32 bit)
// __RADWIN__ means Windows API (Win16, Win386, Win32s, Win64, Xbox, Xenon)
// __RADWINEXT__ means Windows 386 extender (Win386)
// __RADNT__ means Win32 or Win64 code
// __RADWINRTAPI__ means Windows RT API (Win 8, Win Phone, ARM, Durango)
// __RADMAC__ means Macintosh
// __RADCARBON__ means Carbon
// __RADMACH__ means MachO
// __RADXBOX__ means the XBox console
// __RADXENON__ means the Xenon console
// __RADDURANGO__ or __RADXBOXONE__ means Xbox One
// __RADNGC__ means the Nintendo GameCube
// __RADWII__ means the Nintendo Wii
// __RADWIIU__ means the Nintendo Wii U
// __RADNDS__ means the Nintendo DS
// __RADTWL__ means the Nintendo DSi (__RADNDS__ also defined)
// __RAD3DS__ means the Nintendo 3DS
// __RADPS2__ means the Sony PlayStation 2
// __RADPSP__ means the Sony PlayStation Portable
// __RADPS3__ means the Sony PlayStation 3
// __RADPS4__ means the Sony PlayStation 4
// __RADANDROID__ means Android NDK
// __RADNACL__ means Native Client SDK
// __RADNTBUILDLINUX__ means building Linux on NT
// __RADLINUX__ means actually building on Linux (most likely with GCC)
// __RADPSP2__ means NGP
// __RADBSD__ means a BSD-style UNIX (OS X, FreeBSD, OpenBSD, NetBSD)
// __RADPOSIX__ means POSIX-compliant
// __RADQNX__ means QNX
// __RADIPHONE__ means iphone
// __RADIPHONESIM__ means iphone simulator
// __RADX86__ means Intel x86
// __RADMMX__ means Intel x86 MMX instructions are allowed
// __RADX64__ means Intel/AMD x64 (NOT IA64=Itanium)
// __RAD68K__ means 68K
// __RADPPC__ means PowerPC
// __RADMIPS__ means Mips (only R5900 right now)
// __RADARM__ mean ARM processors
// __RADLITTLEENDIAN__ means processor is little-endian (x86)
// __RADBIGENDIAN__ means processor is big-endian (680x0, PPC)
// __RADNOVARARGMACROS__ means #defines can't use ...
#ifdef WINAPI_FAMILY
// If this is #defined, we might be in a Windows Store App. But
// VC++ by default #defines this to a symbolic name, not an integer
// value, and those names are defined in "winapifamily.h". So if
// WINAPI_FAMILY is #defined, #include the header so we can parse it.
#include <winapifamily.h>
#define RAD_WINAPI_IS_APP (!WINAPI_FAMILY_PARTITION(WINAPI_PARTITION_DESKTOP))
#else
#define RAD_WINAPI_IS_APP 0
#endif
#ifndef __RADRES__
// Theoretically, this is to pad structs on platforms that don't support pragma pack or do it poorly. (PS3, PS2)
// In general it is assumed that your padding is set via pragma, so this is just a struct.
#define RADSTRUCT struct
#ifdef __GNUC_MINOR__
// make a combined GCC version for testing :
#define __RAD_GCC_VERSION__ (__GNUC__ * 10000 \
+ __GNUC_MINOR__ * 100 \
+ __GNUC_PATCHLEVEL__)
/* Test for GCC > 3.2.0 */
// #if GCC_VERSION > 30200
#endif
#if defined(__RADX32__)
#define __RADX86__
#define __RADMMX__
#define __RAD32__
#define __RADLITTLEENDIAN__
#define RADINLINE inline
#define RADRESTRICT __restrict
// known platforms under the RAD generic build type
#if defined(_WIN32) || defined(_Windows) || defined(WIN32) || defined(__WINDOWS__) || defined(_WINDOWS)
#define __RADNT__
#define __RADWIN__
#elif (defined(__MWERKS__) && !defined(__INTEL__)) || defined(__MRC__) || defined(THINK_C) || defined(powerc) || defined(macintosh) || defined(__powerc) || defined(__APPLE__) || defined(__MACH__)
#define __RADMAC__
#undef RADSTRUCT
#define RADSTRUCT struct __attribute__((__packed__))
#elif defined(__linux__)
#define __RADLINUX__
#undef RADSTRUCT
#define RADSTRUCT struct __attribute__((__packed__))
#endif
#elif defined(ANDROID)
#define __RADANDROID__
#define __RAD32__
#define __RADLITTLEENDIAN__
#ifdef __i386__
#define __RADX86__
#else
#define __RADARM__
#endif
#define RADINLINE inline
#define RADRESTRICT __restrict
#undef RADSTRUCT
#define RADSTRUCT struct __attribute__((__packed__))
#elif defined(__QNX__)
#define __RAD32__
#define __RADQNX__
#ifdef __arm__
#define __RADARM__
#elif defined __i386__
#define __RADX86__
#else
#error Unknown processor
#endif
#define __RADLITTLEENDIAN__
#define RADINLINE inline
#define RADRESTRICT __restrict
#undef RADSTRUCT
#define RADSTRUCT struct __attribute__((__packed__))
#elif defined(__linux__) && defined(__arm__) //This should pull in Raspberry Pi as well
#define __RAD32__
#define __RADLINUX__
#define __RADARM__
#define __RADLITTLEENDIAN__
#define RADINLINE inline
#define RADRESTRICT __restrict
#undef RADSTRUCT
#define RADSTRUCT struct __attribute__((__packed__))
#elif defined(__native_client__)
#define __RADNACL__
#define __RAD32__
#define __RADLITTLEENDIAN__
#define __RADX86__
#define RADINLINE inline
#define RADRESTRICT __restrict
#undef RADSTRUCT
#define RADSTRUCT struct __attribute__((__packed__))
#elif defined(_DURANGO) || defined(_SEKRIT) || defined(_SEKRIT1) || defined(_XBOX_ONE)
#define __RADDURANGO__ 1
#define __RADXBOXONE__ 1
#if !defined(__RADSEKRIT__) // keep sekrit around for a bit for compat
#define __RADSEKRIT__ 1
#endif
#define __RADWIN__
#define __RAD32__
#define __RAD64__
#define __RADX64__
#define __RADMMX__
#define __RADX86__
#define __RAD64REGS__
#define __RADLITTLEENDIAN__
#define RADINLINE __inline
#define RADRESTRICT __restrict
#define __RADWINRTAPI__
#elif defined(__ORBIS__)
#define __RADPS4__
#if !defined(__RADSEKRIT2__) // keep sekrit2 around for a bit for compat
#define __RADSEKRIT2__ 1
#endif
#define __RAD32__
#define __RAD64__
#define __RADX64__
#define __RADMMX__
#define __RADX86__
#define __RAD64REGS__
#define __RADLITTLEENDIAN__
#define RADINLINE inline
#define RADRESTRICT __restrict
#undef RADSTRUCT
#define RADSTRUCT struct __attribute__((__packed__))
#elif defined(WINAPI_FAMILY) && RAD_WINAPI_IS_APP
#define __RADWINRTAPI__
#define __RADWIN__
#define RADINLINE __inline
#define RADRESTRICT __restrict
#if defined(_M_IX86) // WinRT on x86
#define __RAD32__
#define __RADX86__
#define __RADMMX__
#define __RADLITTLEENDIAN__
#elif defined(_M_X64) // WinRT on x64
#define __RAD32__
#define __RAD64__
#define __RADX86__
#define __RADX64__
#define __RADMMX__
#define __RAD64REGS__
#define __RADLITTLEENDIAN__
#elif defined(_M_ARM) // WinRT on ARM
#define __RAD32__
#define __RADARM__
#define __RADLITTLEENDIAN__
#else
#error Unrecognized WinRT platform!
#endif
#elif defined(_WIN64)
#define __RADWIN__
#define __RADNT__
// See note at top for why both __RAD32__ and __RAD64__ are defined.
#define __RAD32__
#define __RAD64__
#define __RADX64__
#define __RADMMX__
#define __RADX86__
#define __RAD64REGS__
#define __RADLITTLEENDIAN__
#define RADINLINE __inline
#define RADRESTRICT __restrict
#elif defined(GENERIC_ARM)
#define __RAD32__
#define __RADARM__
#define __RADLITTLEENDIAN__
#define __RADFIXEDPOINT__
#define RADINLINE inline
#if (defined(__GCC__) || defined(__GNUC__))
#define RADRESTRICT __restrict
#else
#define RADRESTRICT // __restrict not supported on cw
#endif
#undef RADSTRUCT
#define RADSTRUCT struct __attribute__((__packed__))
#elif defined(CAFE) // has to be before HOLLYWOOD_REV since it also defines it
#define __RADWIIU__
#define __RAD32__
#define __RADPPC__
#define __RADBIGENDIAN__
#define RADINLINE inline
#define RADRESTRICT __restrict
#undef RADSTRUCT
#define RADSTRUCT struct __attribute__((__packed__))
#elif defined(HOLLYWOOD_REV) || defined(REVOLUTION)
#define __RADWII__
#define __RAD32__
#define __RADPPC__
#define __RADBIGENDIAN__
#define RADINLINE inline
#define RADRESTRICT __restrict
#elif defined(NN_PLATFORM_CTR)
#define __RAD3DS__
#define __RAD32__
#define __RADARM__
#define __RADLITTLEENDIAN__
#define RADINLINE inline
#define RADRESTRICT
#undef RADSTRUCT
#define RADSTRUCT struct __attribute__((__packed__))
#elif defined(GEKKO)
#define __RADNGC__
#define __RAD32__
#define __RADPPC__
#define __RADBIGENDIAN__
#define RADINLINE inline
#define RADRESTRICT // __restrict not supported on cw
#elif defined(SDK_ARM9) || defined(SDK_TWL) || (defined(__arm) && defined(__MWERKS__))
#define __RADNDS__
#define __RAD32__
#define __RADARM__
#define __RADLITTLEENDIAN__
#define __RADFIXEDPOINT__
#define RADINLINE inline
#if (defined(__GCC__) || defined(__GNUC__))
#define RADRESTRICT __restrict
#else
#define RADRESTRICT // __restrict not supported on cw
#endif
#if defined(SDK_TWL)
#define __RADTWL__
#endif
#elif defined(R5900)
#define __RADPS2__
#define __RAD32__
#define __RADMIPS__
#define __RADLITTLEENDIAN__
#define RADINLINE inline
#define RADRESTRICT __restrict
#define __RAD64REGS__
#define U128 u_long128
#if !defined(__MWERKS__)
#undef RADSTRUCT
#define RADSTRUCT struct __attribute__((__packed__))
#endif
#elif defined(__psp__)
#define __RADPSP__
#define __RAD32__
#define __RADMIPS__
#define __RADLITTLEENDIAN__
#define RADINLINE inline
#define RADRESTRICT __restrict
#undef RADSTRUCT
#define RADSTRUCT struct __attribute__((__packed__))
#elif defined(__psp2__)
#undef RADSTRUCT
#define RADSTRUCT struct __attribute__((__packed__))
#define __RADPSP2__
#define __RAD32__
#define __RADARM__
#define __RADLITTLEENDIAN__
#define RADINLINE inline
#define RADRESTRICT __restrict
// need packed attribute for struct with snc?
#elif defined(__CELLOS_LV2__)
// CB change : 10-29-10 : RAD64REGS on PPU but NOT SPU
#ifdef __SPU__
#define __RADSPU__
#define __RAD32__
#define __RADCELL__
#define __RADBIGENDIAN__
#define RADINLINE inline
#define RADRESTRICT __restrict
#else
#define __RAD64REGS__
#define __RADPS3__
#define __RADPPC__
#define __RAD32__
#define __RADCELL__
#define __RADBIGENDIAN__
#define RADINLINE inline
#define RADRESTRICT __restrict
#define __RADALTIVEC__
#endif
#undef RADSTRUCT
#define RADSTRUCT struct __attribute__((__packed__))
#ifndef __LP32__
#error "PS3 32bit ABI support only"
#endif
#elif (defined(__MWERKS__) && !defined(__INTEL__)) || defined(__MRC__) || defined(THINK_C) || defined(powerc) || defined(macintosh) || defined(__powerc) || defined(__APPLE__) || defined(__MACH__)
#ifdef __APPLE__
#include "TargetConditionals.h"
#endif
#if ((defined(TARGET_OS_IPHONE) && TARGET_OS_IPHONE) || (defined(TARGET_IPHONE_SIMULATOR) && TARGET_IPHONE_SIMULATOR))
// iPhone/iPad/iOS
#define __RADIPHONE__
#define __RADMACAPI__
#define __RAD32__
#if defined(__x86_64__)
#define __RAD64__
#endif
#define __RADLITTLEENDIAN__
#define RADINLINE inline
#define RADRESTRICT __restrict
#define __RADMACH__
#undef RADSTRUCT
#define RADSTRUCT struct __attribute__((__packed__))
#if defined(TARGET_IPHONE_SIMULATOR) && TARGET_IPHONE_SIMULATOR
#if defined( __x86_64__)
#define __RADX64__
#else
#define __RADX86__
#endif
#define __RADIPHONESIM__
#elif defined(TARGET_OS_IPHONE) && TARGET_OS_IPHONE
#define __RADARM__
#endif
#else
// An actual MacOSX machine
#define __RADMAC__
#define __RADMACAPI__
#if defined(powerc) || defined(__powerc) || defined(__ppc__)
#define __RADPPC__
#define __RADBIGENDIAN__
#define __RADALTIVEC__
#define RADRESTRICT
#elif defined(__i386__)
#define __RADX86__
#define __RADMMX__
#define __RADLITTLEENDIAN__
#define RADRESTRICT __restrict
#elif defined(__x86_64__)
#define __RAD32__
#define __RAD64__
#define __RADX86__
#define __RADX64__
#define __RAD64REGS__
#define __RADMMX__
#define __RADLITTLEENDIAN__
#define RADRESTRICT __restrict
#else
#define __RAD68K__
#define __RADBIGENDIAN__
#define __RADALTIVEC__
#define RADRESTRICT
#endif
#define __RAD32__
#if defined(__MWERKS__)
#if (defined(__cplusplus) || ! __option(only_std_keywords))
#define RADINLINE inline
#endif
#ifdef __MACH__
#define __RADMACH__
#endif
#elif defined(__MRC__)
#if defined(__cplusplus)
#define RADINLINE inline
#endif
#elif defined(__GNUC__) || defined(__GNUG__) || defined(__MACH__)
#define RADINLINE inline
#define __RADMACH__
#undef RADRESTRICT /* could have been defined above... */
#define RADRESTRICT __restrict
#undef RADSTRUCT
#define RADSTRUCT struct __attribute__((__packed__))
#endif
#ifdef __RADX86__
#ifndef __RADCARBON__
#define __RADCARBON__
#endif
#endif
#ifdef TARGET_API_MAC_CARBON
#if TARGET_API_MAC_CARBON
#ifndef __RADCARBON__
#define __RADCARBON__
#endif
#endif
#endif
#endif
#elif defined(__linux__)
#define __RADLINUX__
#define __RADMMX__
#define __RADLITTLEENDIAN__
#define __RADX86__
#ifdef __x86_64
#define __RAD32__
#define __RAD64__
#define __RADX64__
#define __RAD64REGS__
#else
#define __RAD32__
#endif
#define RADINLINE inline
#define RADRESTRICT __restrict
#undef RADSTRUCT
#define RADSTRUCT struct __attribute__((__packed__))
#else
#if _MSC_VER >= 1400
#undef RADRESTRICT
#define RADRESTRICT __restrict
#else
#define RADRESTRICT
#define __RADNOVARARGMACROS__
#endif
#if defined(_XENON) || ( defined(_XBOX_VER) && (_XBOX_VER == 200) )
// Remember that Xenon also defines _XBOX
#define __RADPPC__
#define __RADBIGENDIAN__
#define __RADALTIVEC__
#else
#define __RADX86__
#define __RADMMX__
#define __RADLITTLEENDIAN__
#endif
#ifdef __MWERKS__
#define _WIN32
#endif
#ifdef __DOS__
#define __RADDOS__
#define S64_DEFINED // turn off these types
#define U64_DEFINED
#define S64 double //should error
#define U64 double //should error
#define __RADNOVARARGMACROS__
#endif
#ifdef __386__
#define __RAD32__
#endif
#ifdef _Windows //For Borland
#ifdef __WIN32__
#define WIN32
#else
#define __WINDOWS__
#endif
#endif
#ifdef _WINDOWS //For MS
#ifndef _WIN32
#define __WINDOWS__
#endif
#endif
#ifdef _WIN32
#if defined(_XENON) || ( defined(_XBOX_VER) && (_XBOX_VER == 200) )
// Remember that Xenon also defines _XBOX
#define __RADXENON__
#define __RAD64REGS__
#elif defined(_XBOX)
#define __RADXBOX__
#elif !defined(__RADWINRTAPI__)
#define __RADNT__
#endif
#define __RADWIN__
#define __RAD32__
#else
#ifdef __NT__
#if defined(_XENON) || (_XBOX_VER == 200)
// Remember that Xenon also defines _XBOX
#define __RADXENON__
#define __RAD64REGS__
#elif defined(_XBOX)
#define __RADXBOX__
#else
#define __RADNT__
#endif
#define __RADWIN__
#define __RAD32__
#else
#ifdef __WINDOWS_386__
#define __RADWIN__
#define __RADWINEXT__
#define __RAD32__
#define S64_DEFINED // turn off these types
#define U64_DEFINED
#define S64 double //should error
#define U64 double //should error
#else
#ifdef __WINDOWS__
#define __RADWIN__
#define __RAD16__
#else
#ifdef WIN32
#if defined(_XENON) || (_XBOX_VER == 200)
// Remember that Xenon also defines _XBOX
#define __RADXENON__
#elif defined(_XBOX)
#define __RADXBOX__
#else
#define __RADNT__
#endif
#define __RADWIN__
#define __RAD32__
#endif
#endif
#endif
#endif
#endif
#ifdef __WATCOMC__
#define RADINLINE
#else
#define RADINLINE __inline
#endif
#endif
#if defined __RADMAC__ || defined __RADIPHONE__
#define __RADBSD__
#endif
#if defined __RADBSD__ || defined __RADLINUX__
#define __RADPOSIX__
#endif
#if (!defined(__RADDOS__) && !defined(__RADWIN__) && !defined(__RADMAC__) && \
!defined(__RADNGC__) && !defined(__RADNDS__) && !defined(__RADXBOX__) && \
!defined(__RADXENON__) && !defined(__RADDURANGO__) && !defined(__RADPS4__) && !defined(__RADLINUX__) && !defined(__RADPS2__) && \
!defined(__RADPSP__) && !defined(__RADPSP2__) && !defined(__RADPS3__) && !defined(__RADSPU__) && \
!defined(__RADWII__) && !defined(__RADIPHONE__) && !defined(__RADX32__) && !defined(__RADARM__) && \
!defined(__RADWIIU__) && !defined(__RADANDROID__) && !defined(__RADNACL__) && !defined (__RADQNX__) )
#error "RAD.H did not detect your platform. Define DOS, WINDOWS, WIN32, macintosh, powerpc, or appropriate console."
#endif
#ifdef __RADFINAL__
#define RADTODO(str) { char __str[0]=str; }
#else
#define RADTODO(str)
#endif
#ifdef __RADX32__
#if defined(_MSC_VER)
#define RADLINK __stdcall
#define RADEXPLINK __stdcall
#else
#define RADLINK __attribute__((stdcall))
#define RADEXPLINK __attribute__((stdcall))
#endif
#define RADEXPFUNC RADDEFFUNC
#elif (defined(__RADNGC__) || defined(__RADWII__) || defined( __RADPS2__) || \
defined(__RADPSP__) || defined(__RADPSP2__) || defined(__RADPS3__) || \
defined(__RADSPU__) || defined(__RADNDS__) || defined(__RADIPHONE__) || \
(defined(__RADARM__) && !defined(__RADWINRTAPI__)) || defined(__RADWIIU__) || defined(__RADPS4__) )
#define RADLINK
#define RADEXPLINK
#define RADEXPFUNC RADDEFFUNC
#define RADASMLINK
#elif defined(__RADANDROID__)
#define RADLINK
#define RADEXPLINK
#define RADEXPFUNC RADDEFFUNC
#define RADASMLINK
#elif defined(__RADNACL__)
#define RADLINK
#define RADEXPLINK
#define RADEXPFUNC RADDEFFUNC
#define RADASMLINK
#elif defined(__RADLINUX__) || defined (__RADQNX__)
#ifdef __RAD64__
#define RADLINK
#define RADEXPLINK
#else
#define RADLINK __attribute__((cdecl))
#define RADEXPLINK __attribute__((cdecl))
#endif
#define RADEXPFUNC RADDEFFUNC
#define RADASMLINK
#elif defined(__RADMAC__)
// this define is for CodeWarrior 11's stupid new libs (even though
// we don't use longlong's).
#define __MSL_LONGLONG_SUPPORT__
#define RADLINK
#define RADEXPLINK
#if defined(__CFM68K__) || defined(__MWERKS__)
#ifdef __RADINDLL__
#define RADEXPFUNC RADDEFFUNC __declspec(export)
#else
#define RADEXPFUNC RADDEFFUNC __declspec(import)
#endif
#else
#if defined(__RADMACH__) && !defined(__MWERKS__)
#ifdef __RADINDLL__
#define RADEXPFUNC RADDEFFUNC __attribute__((visibility("default")))
#else
#define RADEXPFUNC RADDEFFUNC
#endif
#else
#define RADEXPFUNC RADDEFFUNC
#endif
#endif
#define RADASMLINK
#else
#ifdef __RADNT__
#ifndef _WIN32
#define _WIN32
#endif
#ifndef WIN32
#define WIN32
#endif
#endif
#ifdef __RADWIN__
#ifdef __RAD32__
#ifdef __RADXBOX__
#define RADLINK __stdcall
#define RADEXPLINK __stdcall
#define RADEXPFUNC RADDEFFUNC
#elif defined(__RADXENON__) || defined(__RADDURANGO__)
#define RADLINK __stdcall
#define RADEXPLINK __stdcall
#define RADEXPFUNC RADDEFFUNC
#elif defined(__RADWINRTAPI__)
#define RADLINK __stdcall
#define RADEXPLINK __stdcall
#if ( defined(__RADINSTATICLIB__) || defined(__RADNOEXPORTS__ ) || ( defined(__RADNOEXEEXPORTS__) && ( !defined(__RADINDLL__) ) && ( !defined(__RADINSTATICLIB__) ) ) )
#define RADEXPFUNC RADDEFFUNC
#else
#ifndef __RADINDLL__
#define RADEXPFUNC RADDEFFUNC __declspec(dllimport)
#else
#define RADEXPFUNC RADDEFFUNC __declspec(dllexport)
#endif
#endif
#elif defined(__RADNTBUILDLINUX__)
#define RADLINK __cdecl
#define RADEXPLINK __cdecl
#define RADEXPFUNC RADDEFFUNC
#else
#ifdef __RADNT__
#define RADLINK __stdcall
#define RADEXPLINK __stdcall
#if ( defined(__RADINSTATICLIB__) || defined(__RADNOEXPORTS__ ) || ( defined(__RADNOEXEEXPORTS__) && ( !defined(__RADINDLL__) ) && ( !defined(__RADINSTATICLIB__) ) ) )
#define RADEXPFUNC RADDEFFUNC
#else
#ifndef __RADINDLL__
#define RADEXPFUNC RADDEFFUNC __declspec(dllimport)
#ifdef __BORLANDC__
#if __BORLANDC__<=0x460
#undef RADEXPFUNC
#define RADEXPFUNC RADDEFFUNC
#endif
#endif
#else
#define RADEXPFUNC RADDEFFUNC __declspec(dllexport)
#endif
#endif
#else
#define RADLINK __pascal
#define RADEXPLINK __far __pascal
#define RADEXPFUNC RADDEFFUNC
#endif
#endif
#else
#define RADLINK __pascal
#define RADEXPLINK __far __pascal __export
#define RADEXPFUNC RADDEFFUNC
#endif
#else
#define RADLINK __pascal
#define RADEXPLINK __pascal
#define RADEXPFUNC RADDEFFUNC
#endif
#define RADASMLINK __cdecl
#endif
#if !defined(__RADXBOX__) && !defined(__RADXENON__) && !defined(__RADDURANGO__) && !defined(__RADXBOXONE__)
#ifdef __RADWIN__
#ifndef _WINDOWS
#define _WINDOWS
#endif
#endif
#endif
#ifdef __RADLITTLEENDIAN__
#ifdef __RADBIGENDIAN__
#error both endians !?
#endif
#endif
#if !defined(__RADLITTLEENDIAN__) && !defined(__RADBIGENDIAN__)
#error neither endian!
#endif
//-----------------------------------------------------------------
#ifndef RADDEFFUNC
#ifdef __cplusplus
#define RADDEFFUNC extern "C"
#define RADDEFSTART extern "C" {
#define RADDEFEND }
#define RADDEFINEDATA extern "C"
#define RADDECLAREDATA extern "C"
#define RADDEFAULT( val ) =val
#define RR_NAMESPACE rr
#define RR_NAMESPACE_START namespace RR_NAMESPACE {
#define RR_NAMESPACE_END };
#define RR_NAMESPACE_USE using namespace RR_NAMESPACE;
#else
#define RADDEFFUNC
#define RADDEFSTART
#define RADDEFEND
#define RADDEFINEDATA
#define RADDECLAREDATA extern
#define RADDEFAULT( val )
#define RR_NAMESPACE
#define RR_NAMESPACE_START
#define RR_NAMESPACE_END
#define RR_NAMESPACE_USE
#endif
#endif
// probably s.b: RAD_DECLARE_ALIGNED(type, name, alignment)
#if (defined(__RADWII__) || defined(__RADWIIU__) || defined(__RADPSP__) || defined(__RADPSP2__) || \
defined(__RADPS3__) || defined(__RADSPU__) || defined(__RADPS4__) || \
defined(__RADLINUX__) || defined(__RADMAC__)) || defined(__RADNDS__) || defined(__RAD3DS__) || \
defined(__RADIPHONE__) || defined(__RADANDROID__) || defined (__RADQNX__)
#define RAD_ALIGN(type,var,num) type __attribute__ ((aligned (num))) var
#elif (defined(__RADNGC__) || defined(__RADPS2__))
#define RAD_ALIGN(type,var,num) __attribute__ ((aligned (num))) type var
#elif (defined(_MSC_VER) && (_MSC_VER >= 1300)) || defined(__RADWINRTAPI__)
#define RAD_ALIGN(type,var,num) type __declspec(align(num)) var
#else
// NOTE: / / is a guaranteed parse error in C/C++.
#define RAD_ALIGN(type,var,num) RAD_ALIGN_USED_BUT_NOT_DEFINED / /
#endif
// WARNING : RAD_TLS should really only be used for debug/tools stuff
// it's not reliable because even if we are built as a lib, our lib can
// be put into a DLL and then it doesn't work
#if defined(__RADNT__) || defined(__RADXENON__)
#ifndef __RADINDLL__
// note that you can't use this in windows DLLs
#define RAD_TLS(type,var) __declspec(thread) type var
#endif
#elif defined(__RADPS3__) || defined(__RADLINUX__) || defined(__RADMAC__)
// works on PS3/gcc I believe :
#define RAD_TLS(type,var) __thread type var
#else
// RAD_TLS not defined
#endif
// Note that __RAD16__/__RAD32__/__RAD64__ refers to the size of a pointer.
// The size of integers is specified explicitly in the code, i.e. u32 or whatever.
#define RAD_S8 signed char
#define RAD_U8 unsigned char
#if defined(__RAD64__)
// Remember that __RAD32__ will also be defined!
#if defined(__RADX64__)
// x64 still has 32-bit ints!
#define RAD_U32 unsigned int
#define RAD_S32 signed int
// But pointers are 64 bits.
#if (_MSC_VER >= 1300 && defined(_Wp64) && _Wp64 )
#define RAD_SINTa __w64 signed __int64
#define RAD_UINTa __w64 unsigned __int64
#else // non-vc.net compiler or /Wp64 turned off
#define RAD_UINTa unsigned long long
#define RAD_SINTa signed long long
#endif
#else
#error Unknown 64-bit processor (see radbase.h)
#endif
#elif defined(__RAD32__)
#define RAD_U32 unsigned int
#define RAD_S32 signed int
// Pointers are 32 bits.
#if ( ( defined(_MSC_VER) && (_MSC_VER >= 1300 ) ) && ( defined(_Wp64) && ( _Wp64 ) ) )
#define RAD_SINTa __w64 signed long
#define RAD_UINTa __w64 unsigned long
#else // non-vc.net compiler or /Wp64 turned off
#ifdef _Wp64
#define RAD_SINTa signed long
#define RAD_UINTa unsigned long
#else
#define RAD_SINTa signed int
#define RAD_UINTa unsigned int
#endif
#endif
#else
#define RAD_U32 unsigned long
#define RAD_S32 signed long
// Pointers in 16-bit land are still 32 bits.
#define RAD_UINTa unsigned long
#define RAD_SINTa signed long
#endif
#define RAD_F32 float
#if defined(__RADPS2__) || defined(__RADPSP__)
typedef RADSTRUCT RAD_F64 // do this so that we don't accidentally use doubles
{ // while using the same space
RAD_U32 vals[ 2 ];
} RAD_F64;
#define RAD_F64_OR_32 float // type is F64 if available, otherwise F32
#else
#define RAD_F64 double
#define RAD_F64_OR_32 double // type is F64 if available, otherwise F32
#endif
#if (defined(__RADMAC__) || defined(__MRC__) || defined( __RADNGC__ ) || \
defined(__RADLINUX__) || defined( __RADWII__ ) || defined(__RADWIIU__) || \
defined(__RADNDS__) || defined(__RADPSP__) || defined(__RADPS3__) || defined(__RADPS4__) || \
defined(__RADSPU__) || defined(__RADIPHONE__) || defined(__RADNACL__) || defined( __RADANDROID__) || defined( __RADQNX__ ) )
#define RAD_U64 unsigned long long
#define RAD_S64 signed long long
#elif defined(__RADPS2__)
#define RAD_U64 unsigned long
#define RAD_S64 signed long
#elif defined(__RADARM__)
#define RAD_U64 unsigned long long
#define RAD_S64 signed long long
#elif defined(__RADX64__) || defined(__RAD32__)
#define RAD_U64 unsigned __int64
#define RAD_S64 signed __int64
#else
// 16-bit
typedef RADSTRUCT RAD_U64 // do this so that we don't accidentally use U64s
{ // while using the same space
RAD_U32 vals[ 2 ];
} RAD_U64;
typedef RADSTRUCT RAD_S64 // do this so that we don't accidentally use S64s
{ // while using the same space
RAD_S32 vals[ 2 ];
} RAD_S64;
#endif
#if defined(__RAD32__)
#define PTR4
#define RAD_U16 unsigned short
#define RAD_S16 signed short
#else
#define PTR4 __far
#define RAD_U16 unsigned int
#define RAD_S16 signed int
#endif
//-------------------------------------------------
// RAD_PTRBITS and such defined here without using sizeof()
// so that they can be used in align() and other macros
#ifdef __RAD64__
#define RAD_PTRBITS 64
#define RAD_PTRBYTES 8
#define RAD_TWOPTRBYTES 16
#else
#define RAD_PTRBITS 32
#define RAD_PTRBYTES 4
#define RAD_TWOPTRBYTES 8
#endif
//-------------------------------------------------
// UINTr = int the size of a register
#ifdef __RAD64REGS__
#define RAD_UINTr RAD_U64
#define RAD_SINTr RAD_S64
#else
#define RAD_UINTr RAD_U32
#define RAD_SINTr RAD_S32
#endif
//===========================================================================
/*
// CB : meh this is enough of a mess that it's probably best to just let each
#if defined(__RADX86__) && defined(_MSC_VER) && _MSC_VER >= 1300
#define __RADX86INTRIN2003__
#endif
*/
// RADASSUME(expr) tells the compiler that expr is always true
// RADUNREACHABLE must never be reachable - even in event of error
// eg. it's okay for compiler to generate completely invalid code after RADUNREACHABLE
#ifdef _MSC_VER
#define RADFORCEINLINE __forceinline
#if _MSC_VER >= 1300
#define RADNOINLINE __declspec(noinline)
#else
#define RADNOINLINE
#endif
#define RADUNREACHABLE __assume(0)
#define RADASSUME(exp) __assume(exp)
#elif defined(__clang__)
#ifdef _DEBUG
#define RADFORCEINLINE inline
#else
#define RADFORCEINLINE inline __attribute((always_inline))
#endif
#define RADNOINLINE __attribute__((noinline))
#define RADUNREACHABLE __builtin_unreachable()
#if __has_builtin(__builtin_assume)
#define RADASSUME(exp) __builtin_assume(exp)
#else
#define RADASSUME(exp) RAD_STATEMENT_WRAPPER( if ( ! (exp) ) __builtin_unreachable(); )
#endif
#elif (defined(__GCC__) || defined(__GNUC__)) || defined(ANDROID)
#ifdef _DEBUG
#define RADFORCEINLINE inline
#else
#define RADFORCEINLINE inline __attribute((always_inline))
#endif
#define RADNOINLINE __attribute__((noinline))
#if __RAD_GCC_VERSION__ >= 40500
#define RADUNREACHABLE __builtin_unreachable()
#define RADASSUME(exp) RAD_STATEMENT_WRAPPER( if ( ! (exp) ) __builtin_unreachable(); )
#else
#define RADUNREACHABLE RAD_INFINITE_LOOP( RR_BREAK(); )
#define RADASSUME(exp)
#endif
#elif defined(__CWCC__)
#define RADFORCEINLINE inline
#define RADNOINLINE __attribute__((never_inline))
#define RADUNREACHABLE
#define RADASSUME(x) (void)0
#else
// ? #define RADFORCEINLINE ?
#define RADFORCEINLINE inline
#define RADNOINLINE
#define RADASSUME(x) (void)0
#endif
//===========================================================================
// RAD_ALIGN_HINT tells the compiler how a given pointer is aligned
// it *must* be true, but the compiler may or may not use that information
// it is not for cases where the pointer is to an inherently aligned data type,
// it's when the compiler cannot tell the alignment but you have extra information.
// eg :
// U8 * ptr = rrMallocAligned(256,16);
// RAD_ALIGN_HINT(ptr,16,0);
#ifdef __RADSPU__
#define RAD_ALIGN_HINT(ptr,alignment,offset) __align_hint(ptr,alignment,offset); RR_ASSERT( ((UINTa)(ptr) & ((alignment)-1)) == (UINTa)(offset) )
#else
#define RAD_ALIGN_HINT(ptr,alignment,offset) RADASSUME( ((UINTa)(ptr) & ((alignment)-1)) == (UINTa)(offset) )
#endif
//===========================================================================
// RAD_EXPECT is to tell the compiler the *likely* value of an expression
// different than RADASSUME in that expr might not have that value
// it's use for branch code layout and static branch prediction
// condition can technically be a variable but should usually be 0 or 1
#if (defined(__GCC__) || defined(__GNUC__)) || defined(__clang__)
// __builtin_expect returns value of expr
#define RAD_EXPECT(expr,cond) __builtin_expect(expr,cond)
#else
#define RAD_EXPECT(expr,cond) (expr)
#endif
// helpers for doing an if ( ) with expect :
// if ( RAD_LIKELY(expr) ) { ... }
#define RAD_LIKELY(expr) RAD_EXPECT(expr,1)
#define RAD_UNLIKELY(expr) RAD_EXPECT(expr,0)
//===========================================================================
// __RADX86ASM__ means you can use __asm {} style inline assembly
#if defined(__RADX86__) && !defined(__RADX64__) && defined(_MSC_VER)
#define __RADX86ASM__
#endif
//-------------------------------------------------
// typedefs :
#ifndef RADNOTYPEDEFS
#ifndef S8_DEFINED
#define S8_DEFINED
typedef RAD_S8 S8;
#endif
#ifndef U8_DEFINED
#define U8_DEFINED
typedef RAD_U8 U8;
#endif
#ifndef S16_DEFINED
#define S16_DEFINED
typedef RAD_S16 S16;
#endif
#ifndef U16_DEFINED
#define U16_DEFINED
typedef RAD_U16 U16;
#endif
#ifndef S32_DEFINED
#define S32_DEFINED
typedef RAD_S32 S32;
#endif
#ifndef U32_DEFINED
#define U32_DEFINED
typedef RAD_U32 U32;
#endif
#ifndef S64_DEFINED
#define S64_DEFINED
typedef RAD_S64 S64;
#endif
#ifndef U64_DEFINED
#define U64_DEFINED
typedef RAD_U64 U64;
#endif
#ifndef F32_DEFINED
#define F32_DEFINED
typedef RAD_F32 F32;
#endif
#ifndef F64_DEFINED
#define F64_DEFINED
typedef RAD_F64 F64;
#endif
#ifndef F64_OR_32_DEFINED
#define F64_OR_32_DEFINED
typedef RAD_F64_OR_32 F64_OR_32;
#endif
// UINTa and SINTa are the ints big enough for an address
#ifndef SINTa_DEFINED
#define SINTa_DEFINED
typedef RAD_SINTa SINTa;
#endif
#ifndef UINTa_DEFINED
#define UINTa_DEFINED
typedef RAD_UINTa UINTa;
#endif
#ifndef UINTr_DEFINED
#define UINTr_DEFINED
typedef RAD_UINTr UINTr;
#endif
#ifndef SINTr_DEFINED
#define SINTr_DEFINED
typedef RAD_SINTr SINTr;
#endif
#elif !defined(RADNOTYPEDEFINES)
#ifndef S8_DEFINED
#define S8_DEFINED
#define S8 RAD_S8
#endif
#ifndef U8_DEFINED
#define U8_DEFINED
#define U8 RAD_U8
#endif
#ifndef S16_DEFINED
#define S16_DEFINED
#define S16 RAD_S16
#endif
#ifndef U16_DEFINED
#define U16_DEFINED
#define U16 RAD_U16
#endif
#ifndef S32_DEFINED
#define S32_DEFINED
#define S32 RAD_S32
#endif
#ifndef U32_DEFINED
#define U32_DEFINED
#define U32 RAD_U32
#endif
#ifndef S64_DEFINED
#define S64_DEFINED
#define S64 RAD_S64
#endif
#ifndef U64_DEFINED
#define U64_DEFINED
#define U64 RAD_U64
#endif
#ifndef F32_DEFINED
#define F32_DEFINED
#define F32 RAD_F32
#endif
#ifndef F64_DEFINED
#define F64_DEFINED
#define F64 RAD_F64
#endif
#ifndef F64_OR_32_DEFINED
#define F64_OR_32_DEFINED
#define F64_OR_32 RAD_F64_OR_32
#endif
// UINTa and SINTa are the ints big enough for an address (pointer)
#ifndef SINTa_DEFINED
#define SINTa_DEFINED
#define SINTa RAD_SINTa
#endif
#ifndef UINTa_DEFINED
#define UINTa_DEFINED
#define UINTa RAD_UINTa
#endif
#ifndef UINTr_DEFINED
#define UINTr_DEFINED
#define UINTr RAD_UINTr
#endif
#ifndef SINTr_DEFINED
#define SINTr_DEFINED
#define SINTr RAD_SINTr
#endif
#endif
/// Some error-checking.
#if defined(__RAD64__) && !defined(__RAD32__)
// See top of file for why this is.
#error __RAD64__ must not be defined without __RAD32__ (see radbase.h)
#endif
#ifdef _MSC_VER
// microsoft compilers
#if _MSC_VER >= 1400
#define RAD_STATEMENT_START \
do {
#define RAD_STATEMENT_END_FALSE \
__pragma(warning(push)) \
__pragma(warning(disable:4127)) \
} while(0) \
__pragma(warning(pop))
#define RAD_STATEMENT_END_TRUE \
__pragma(warning(push)) \
__pragma(warning(disable:4127)) \
} while(1) \
__pragma(warning(pop))
#else
#define RAD_USE_STANDARD_LOOP_CONSTRUCT
#endif
#else
#define RAD_USE_STANDARD_LOOP_CONSTRUCT
#endif
#ifdef RAD_USE_STANDARD_LOOP_CONSTRUCT
#define RAD_STATEMENT_START \
do {
#define RAD_STATEMENT_END_FALSE \
} while ( (void)0,0 )
#define RAD_STATEMENT_END_TRUE \
} while ( (void)1,1 )
#endif
#define RAD_STATEMENT_WRAPPER( code ) \
RAD_STATEMENT_START \
code \
RAD_STATEMENT_END_FALSE
#define RAD_INFINITE_LOOP( code ) \
RAD_STATEMENT_START \
code \
RAD_STATEMENT_END_TRUE
// Must be placed after variable declarations for code compiled as .c
#if defined(_MSC_VER) && _MSC_VER >= 1700 // in 2012 aka 11.0 and later
# define RR_UNUSED_VARIABLE(x) (void) x
#else
# define RR_UNUSED_VARIABLE(x) (void)(sizeof(x))
#endif
//-----------------------------------------------
// RR_UINT3264 is a U64 in 64-bit code and a U32 in 32-bit code
// eg. it's pointer sized and the same type as a U32/U64 of the same size
//
// @@ CB 05/21/2012 : I think RR_UINT3264 may be deprecated
// it was useful back when UINTa was /Wp64
// but since we removed that maybe it's not anymore ?
//
#ifdef __RAD64__
#define RR_UINT3264 U64
#else
#define RR_UINT3264 U32
#endif
//RR_COMPILER_ASSERT( sizeof(RR_UINT3264) == sizeof(UINTa) );
//--------------------------------------------------
// RR_LINESTRING is the current line number as a string
#define RR_STRINGIZE( L ) #L
#define RR_DO_MACRO( M, X ) M(X)
#define RR_STRINGIZE_DELAY( X ) RR_DO_MACRO( RR_STRINGIZE, X )
#define RR_LINESTRING RR_STRINGIZE_DELAY( __LINE__ )
#define RR_CAT(X,Y) X ## Y
// RR_STRING_JOIN joins strings in the preprocessor and works with LINESTRING
#define RR_STRING_JOIN(arg1, arg2) RR_STRING_JOIN_DELAY(arg1, arg2)
#define RR_STRING_JOIN_DELAY(arg1, arg2) RR_STRING_JOIN_IMMEDIATE(arg1, arg2)
#define RR_STRING_JOIN_IMMEDIATE(arg1, arg2) arg1 ## arg2
// RR_NUMBERNAME is a macro to make a name unique, so that you can use it to declare
// variable names and they won't conflict with each other
// using __LINE__ is broken in MSVC with /ZI , but __COUNTER__ is an MSVC extension that works
#ifdef _MSC_VER
#define RR_NUMBERNAME(name) RR_STRING_JOIN(name,__COUNTER__)
#else
#define RR_NUMBERNAME(name) RR_STRING_JOIN(name,__LINE__)
#endif
//--------------------------------------------------
// current plan is to use "rrbool" with plain old "true" and "false"
// if true and false give us trouble we might have to go to rrtrue and rrfalse
// BTW there's a danger for evil bugs here !! If you're checking == true
// then the rrbool must be set to exactly "1" not just "not zero" !!
#ifndef RADNOTYPEDEFS
#ifndef RRBOOL_DEFINED
#define RRBOOL_DEFINED
typedef S32 rrbool;
typedef S32 RRBOOL;
#endif
#elif !defined(RADNOTYPEDEFINES)
#ifndef RRBOOL_DEFINED
#define RRBOOL_DEFINED
#define rrbool S32
#define RRBOOL S32
#endif
#endif
//--------------------------------------------------
// Range macros
#ifndef RR_MIN
#define RR_MIN(a,b) ( (a) < (b) ? (a) : (b) )
#endif
#ifndef RR_MAX
#define RR_MAX(a,b) ( (a) > (b) ? (a) : (b) )
#endif
#ifndef RR_ABS
#define RR_ABS(a) ( ((a) < 0) ? -(a) : (a) )
#endif
#ifndef RR_CLAMP
#define RR_CLAMP(val,lo,hi) RR_MAX( RR_MIN(val,hi), lo )
#endif
//--------------------------------------------------
// Data layout macros
#define RR_ARRAY_SIZE(array) ( sizeof(array)/sizeof(array[0]) )
// MEMBER_OFFSET tells you the offset of a member in a type
#ifdef __RAD3DS__
#define RR_MEMBER_OFFSET(type,member) (unsigned int)(( (char *) &(((type *)0)->member) - (char *) 0 ))
#elif defined(__RADANDROID__) || defined(__RADPSP__) || defined(__RADPS3__) || defined(__RADSPU__)
// offsetof() gets mucked with by system headers on android, making things dependent on #include order.
#define RR_MEMBER_OFFSET(type,member) __builtin_offsetof(type, member)
#elif defined(__RADLINUX__)
#define RR_MEMBER_OFFSET(type,member) (offsetof(type, member))
#else
#define RR_MEMBER_OFFSET(type,member) ( (size_t) (UINTa) &(((type *)0)->member) )
#endif
// MEMBER_SIZE tells you the size of a member in a type
#define RR_MEMBER_SIZE(type,member) ( sizeof( ((type *) 0)->member) )
// just to make gcc shut up about derefing null :
#define RR_MEMBER_OFFSET_PTR(type,member,ptr) ( (SINTa) &(((type *)(ptr))->member) - (SINTa)(ptr) )
#define RR_MEMBER_SIZE_PTR(type,member,ptr) ( sizeof( ((type *) (ptr))->member) )
// MEMBER_TO_OWNER takes a pointer to a member and gives you back the base of the object
// you should then RR_ASSERT( &(ret->member) == ptr );
#define RR_MEMBER_TO_OWNER(type,member,ptr) (type *)( ((char *)(ptr)) - RR_MEMBER_OFFSET_PTR(type,member,ptr) )
//--------------------------------------------------
// Cache / prefetch macros :
// RR_PREFETCH for various platforms :
//
// RR_PREFETCH_SEQUENTIAL : prefetch memory for reading in a sequential scan
// platforms that automatically prefetch sequential (eg. PC) should be a no-op here
// RR_PREFETCH_WRITE_INVALIDATE : prefetch memory for writing - contents of memory are undefined
// (may be a no-op, may be a normal prefetch, may zero memory)
// warning : RR_PREFETCH_WRITE_INVALIDATE may write memory so don't do it past the end of buffers
#ifdef __RADX86__
#define RR_PREFETCH_SEQUENTIAL(ptr,offset) // nop
#define RR_PREFETCH_WRITE_INVALIDATE(ptr,offset) // nop
#elif defined(__RADXENON__)
#define RR_PREFETCH_SEQUENTIAL(ptr,offset) __dcbt((int)(offset),(void *)(ptr))
#define RR_PREFETCH_WRITE_INVALIDATE(ptr,offset) __dcbz128((int)(offset),(void *)(ptr))
#elif defined(__RADPS3__)
#define RR_PREFETCH_SEQUENTIAL(ptr,offset) __dcbt((char *)(ptr) + (int)(offset))
#define RR_PREFETCH_WRITE_INVALIDATE(ptr,offset) __dcbz((char *)(ptr) + (int)(offset))
#elif defined(__RADSPU__)
#define RR_PREFETCH_SEQUENTIAL(ptr,offset) // intentional NOP
#define RR_PREFETCH_WRITE_INVALIDATE(ptr,offset) // nop
#elif defined(__RADWII__) || defined(__RADWIIU__)
#define RR_PREFETCH_SEQUENTIAL(ptr,offset) // intentional NOP for now
#define RR_PREFETCH_WRITE_INVALIDATE(ptr,offset) // nop
#elif defined(__RAD3DS__)
#define RR_PREFETCH_SEQUENTIAL(ptr,offset) __pld((char *)(ptr) + (int)(offset))
#define RR_PREFETCH_WRITE_INVALIDATE(ptr,offset) __pldw((char *)(ptr) + (int)(offset))
#else
// other platform
#define RR_PREFETCH_SEQUENTIAL(ptr,offset) // need_prefetch // compile error
#define RR_PREFETCH_WRITE_INVALIDATE(ptr,offset) // need_writezero // error
#endif
//--------------------------------------------------
// LIGHTWEIGHT ASSERTS without rrAssert.h
RADDEFSTART
// set up RR_BREAK :
#ifdef __RADNGC__
#define RR_BREAK() asm(" .long 0x00000001")
#define RR_CACHE_LINE_SIZE xxx
#elif defined(__RADWII__)
#define RR_BREAK() __asm__ volatile("trap")
#define RR_CACHE_LINE_SIZE 32
#elif defined(__RADWIIU__)
#define RR_BREAK() asm("trap")
#define RR_CACHE_LINE_SIZE 32
#elif defined(__RAD3DS__)
#define RR_BREAK() *((int volatile*)0)=0
#define RR_CACHE_LINE_SIZE 32
#elif defined(__RADNDS__)
#define RR_BREAK() asm("BKPT 0")
#define RR_CACHE_LINE_SIZE xxx
#elif defined(__RADPS2__)
#define RR_BREAK() __asm__ volatile("break")
#define RR_CACHE_LINE_SIZE 64
#elif defined(__RADPSP__)
#define RR_BREAK() __asm__("break 0")
#define RR_CACHE_LINE_SIZE 64
#elif defined(__RADPSP2__)
#define RR_BREAK() { __asm__ volatile("bkpt 0x0000"); }
#define RR_CACHE_LINE_SIZE 32
#elif defined (__RADQNX__)
#define RR_BREAK() __builtin_trap()
#define RR_CACHE_LINE_SIZE 32
#elif defined (__RADARM__) && defined (__RADLINUX__)
#define RR_BREAK() __builtin_trap()
#define RR_CACHE_LINE_SIZE 32
#elif defined(__RADSPU__)
#define RR_BREAK() __asm volatile ("stopd 0,1,1")
#define RR_CACHE_LINE_SIZE 128
#elif defined(__RADPS3__)
// #ifdef snPause // in LibSN.h
// snPause
// __asm__ volatile ( "tw 31,1,1" )
#define RR_BREAK() __asm__ volatile ( "tw 31,1,1" )
//#define RR_BREAK() __asm__ volatile("trap");
#define RR_CACHE_LINE_SIZE 128
#elif defined(__RADMAC__)
#if defined(__GNUG__) || defined(__GNUC__)
#ifdef __RADX86__
#define RR_BREAK() __asm__ volatile ( "int $3" )
#else
#define RR_BREAK() __builtin_trap()
#endif
#else
#ifdef __RADMACH__
void DebugStr(unsigned char const *);
#else
void pascal DebugStr(unsigned char const *);
#endif
#define RR_BREAK() DebugStr("\pRR_BREAK() was called")
#endif
#define RR_CACHE_LINE_SIZE 64
#elif defined(__RADIPHONE__)
#define RR_BREAK() __builtin_trap()
#define RR_CACHE_LINE_SIZE 32
#elif defined(__RADXENON__)
#define RR_BREAK() __debugbreak()
#define RR_CACHE_LINE_SIZE 128
#elif defined(__RADANDROID__)
#define RR_BREAK() __builtin_trap()
#define RR_CACHE_LINE_SIZE 32
#elif defined(__RADPS4__)
#define RR_BREAK() __builtin_trap()
#define RR_CACHE_LINE_SIZE 64
#elif defined(__RADNACL__)
#define RR_BREAK() __builtin_trap()
#define RR_CACHE_LINE_SIZE 64
#else
// x86 :
#define RR_CACHE_LINE_SIZE 64
#ifdef __RADLINUX__
#define RR_BREAK() __asm__ volatile ( "int $3" )
#elif defined(__WATCOMC__)
void RR_BREAK( void );
#pragma aux RR_BREAK = "int 0x3";
#elif defined(__RADWIN__) && defined(_MSC_VER) && _MSC_VER >= 1300
#define RR_BREAK __debugbreak
#else
#define RR_BREAK() RAD_STATEMENT_WRAPPER( __asm {int 3} )
#endif
#endif
// simple RR_ASSERT :
// CB 5-27-10 : use RR_DO_ASSERTS to toggle asserts on and off :
#if (defined(_DEBUG) && !defined(NDEBUG)) || defined(ASSERT_IN_RELEASE)
#define RR_DO_ASSERTS
#endif
/*********
rrAsserts :
RR_ASSERT(exp) - the normal assert thing, toggled with RR_DO_ASSERTS
RR_ASSERT_ALWAYS(exp) - assert that you want to test even in ALL builds (including final!)
RR_ASSERT_RELEASE(exp) - assert that you want to test even in release builds (not for final!)
RR_ASSERT_LITE(exp) - normal assert is not safe from threads or inside malloc; use this instead
RR_DURING_ASSERT(exp) - wrap operations that compute stuff for assert in here
RR_DO_ASSERTS - toggle tells you if asserts are enabled or not
RR_BREAK() - generate a debug break - always !
RR_ASSERT_BREAK() - RR_BREAK for asserts ; disable with RAD_NO_BREAK
RR_ASSERT_FAILURE(str) - just break with a messsage; like assert with no condition
RR_ASSERT_FAILURE_ALWAYS(str) - RR_ASSERT_FAILURE in release builds too
RR_CANT_GET_HERE() - put in spots execution should never go
RR_COMPILER_ASSERT(exp) - checks constant conditions at compile time
RADTODO - note to search for nonfinal stuff
RR_PRAGMA_MESSAGE - message dealy, use with #pragma in MSVC
*************/
//-----------------------------------------------------------
#if defined(__GNUG__) || defined(__GNUC__) || (defined(_MSC_VER) && _MSC_VER > 1200)
#define RR_FUNCTION_NAME __FUNCTION__
#else
#define RR_FUNCTION_NAME 0
// __func__ is in the C99 standard
#endif
//-----------------------------------------------------------
// rrDisplayAssertion might just log, or it might pop a message box, depending on settings
// rrDisplayAssertion returns whether you should break or not
typedef rrbool (RADLINK fp_rrDisplayAssertion)(int * Ignored, const char * fileName,const int line,const char * function,const char * message);
extern fp_rrDisplayAssertion * g_fp_rrDisplayAssertion;
// if I have func pointer, call it, else true ; true = do int 3
#define rrDisplayAssertion(i,n,l,f,m) ( ( g_fp_rrDisplayAssertion ) ? (*g_fp_rrDisplayAssertion)(i,n,l,f,m) : 1 )
//-----------------------------------------------------------
// RAD_NO_BREAK : option if you don't like your assert to break
// CB : RR_BREAK is *always* a break ; RR_ASSERT_BREAK is optional
#ifdef RAD_NO_BREAK
#define RR_ASSERT_BREAK() 0
#else
#define RR_ASSERT_BREAK() RR_BREAK()
#endif
// assert_always is on FINAL !
#define RR_ASSERT_ALWAYS(exp) RAD_STATEMENT_WRAPPER( static int Ignored=0; if ( ! (exp) ) { if ( rrDisplayAssertion(&Ignored,__FILE__,__LINE__,RR_FUNCTION_NAME,#exp) ) RR_ASSERT_BREAK(); } )
// RR_ASSERT_FAILURE is like an assert without a condition - if you hit it, you're bad
#define RR_ASSERT_FAILURE_ALWAYS(str) RAD_STATEMENT_WRAPPER( static int Ignored=0; if ( rrDisplayAssertion(&Ignored,__FILE__,__LINE__,RR_FUNCTION_NAME,str) ) RR_ASSERT_BREAK(); )
#define RR_ASSERT_LITE_ALWAYS(exp) RAD_STATEMENT_WRAPPER( if ( ! (exp) ) { RR_ASSERT_BREAK(); } )
//-----------------------------------
#ifdef RR_DO_ASSERTS
#define RR_ASSERT(exp) RR_ASSERT_ALWAYS(exp)
#define RR_ASSERT_LITE(exp) RR_ASSERT_LITE_ALWAYS(exp)
#define RR_ASSERT_NO_ASSUME(exp) RR_ASSERT_ALWAYS(exp)
// RR_DURING_ASSERT is to set up expressions or declare variables that are only used in asserts
#define RR_DURING_ASSERT(exp) exp
#define RR_ASSERT_FAILURE(str) RR_ASSERT_FAILURE_ALWAYS(str)
// RR_CANT_GET_HERE is for like defaults in switches that should never be hit
#define RR_CANT_GET_HERE() RAD_STATEMENT_WRAPPER( RR_ASSERT_FAILURE("can't get here"); RADUNREACHABLE; )
#else // RR_DO_ASSERTS //-----------------------------------
#define RR_ASSERT(exp) (void)0
#define RR_ASSERT_LITE(exp) (void)0
#define RR_ASSERT_NO_ASSUME(exp) (void)0
#define RR_DURING_ASSERT(exp) (void)0
#define RR_ASSERT_FAILURE(str) (void)0
#define RR_CANT_GET_HERE() RADUNREACHABLE
#endif // RR_DO_ASSERTS //-----------------------------------
//=================================================================
// RR_ASSERT_RELEASE is on in release build, but not final
#ifndef __RADFINAL__
#define RR_ASSERT_RELEASE(exp) RR_ASSERT_ALWAYS(exp)
#define RR_ASSERT_LITE_RELEASE(exp) RR_ASSERT_LITE_ALWAYS(exp)
#else
#define RR_ASSERT_RELEASE(exp) (void)0
#define RR_ASSERT_LITE_RELEASE(exp) (void)0
#endif
// BH: This never gets compiled away except for __RADFINAL__
#define RR_ASSERT_ALWAYS_NO_SHIP RR_ASSERT_RELEASE
#define rrAssert RR_ASSERT
#define rrassert RR_ASSERT
#ifdef _MSC_VER
// without this, our assert errors...
#if _MSC_VER >= 1300
#pragma warning( disable : 4127) // conditional expression is constant
#endif
#endif
//---------------------------------------
// Get/Put from memory in little or big endian :
//
// val = RR_GET32_BE(ptr)
// RR_PUT32_BE(ptr,val)
//
// available here :
// RR_[GET/PUT][16/32]_[BE/LE][_UNALIGNED][_OFFSET]
//
// if you don't specify _UNALIGNED , then ptr & offset shoud both be aligned to type size
// _OFFSET is in *bytes* !
// you can #define RR_GET_RESTRICT to make all RR_GETs be RESTRICT
// if you set nothing they are not
#ifdef RR_GET_RESTRICT
#define RR_GET_PTR_POST RADRESTRICT
#endif
#ifndef RR_GET_PTR_POST
#define RR_GET_PTR_POST
#endif
// native version of get/put is always trivial :
#define RR_GET16_NATIVE(ptr) *((const U16 * RR_GET_PTR_POST)(ptr))
#define RR_PUT16_NATIVE(ptr,val) *((U16 * RR_GET_PTR_POST)(ptr)) = (val)
// offset is in bytes
#define RR_U16_PTR_OFFSET(ptr,offset) ((U16 * RR_GET_PTR_POST)((char *)(ptr) + (offset)))
#define RR_GET16_NATIVE_OFFSET(ptr,offset) *( RR_U16_PTR_OFFSET((ptr),offset) )
#define RR_PUT16_NATIVE_OFFSET(ptr,val,offset) *( RR_U16_PTR_OFFSET((ptr),offset)) = (val)
#define RR_GET32_NATIVE(ptr) *((const U32 * RR_GET_PTR_POST)(ptr))
#define RR_PUT32_NATIVE(ptr,val) *((U32 * RR_GET_PTR_POST)(ptr)) = (val)
// offset is in bytes
#define RR_U32_PTR_OFFSET(ptr,offset) ((U32 * RR_GET_PTR_POST)((char *)(ptr) + (offset)))
#define RR_GET32_NATIVE_OFFSET(ptr,offset) *( RR_U32_PTR_OFFSET((ptr),offset) )
#define RR_PUT32_NATIVE_OFFSET(ptr,val,offset) *( RR_U32_PTR_OFFSET((ptr),offset)) = (val)
#define RR_GET64_NATIVE(ptr) *((const U64 * RR_GET_PTR_POST)(ptr))
#define RR_PUT64_NATIVE(ptr,val) *((U64 * RR_GET_PTR_POST)(ptr)) = (val)
// offset is in bytes
#define RR_U64_PTR_OFFSET(ptr,offset) ((U64 * RR_GET_PTR_POST)((char *)(ptr) + (offset)))
#define RR_GET64_NATIVE_OFFSET(ptr,offset) *( RR_U64_PTR_OFFSET((ptr),offset) )
#define RR_PUT64_NATIVE_OFFSET(ptr,val,offset) *( RR_U64_PTR_OFFSET((ptr),offset)) = (val)
//---------------------------------------------------
#ifdef __RADLITTLEENDIAN__
#define RR_GET16_LE RR_GET16_NATIVE
#define RR_PUT16_LE RR_PUT16_NATIVE
#define RR_GET16_LE_OFFSET RR_GET16_NATIVE_OFFSET
#define RR_PUT16_LE_OFFSET RR_PUT16_NATIVE_OFFSET
#define RR_GET32_LE RR_GET32_NATIVE
#define RR_PUT32_LE RR_PUT32_NATIVE
#define RR_GET32_LE_OFFSET RR_GET32_NATIVE_OFFSET
#define RR_PUT32_LE_OFFSET RR_PUT32_NATIVE_OFFSET
#define RR_GET64_LE RR_GET64_NATIVE
#define RR_PUT64_LE RR_PUT64_NATIVE
#define RR_GET64_LE_OFFSET RR_GET64_NATIVE_OFFSET
#define RR_PUT64_LE_OFFSET RR_PUT64_NATIVE_OFFSET
#else
#define RR_GET16_BE RR_GET16_NATIVE
#define RR_PUT16_BE RR_PUT16_NATIVE
#define RR_GET16_BE_OFFSET RR_GET16_NATIVE_OFFSET
#define RR_PUT16_BE_OFFSET RR_PUT16_NATIVE_OFFSET
#define RR_GET32_BE RR_GET32_NATIVE
#define RR_PUT32_BE RR_PUT32_NATIVE
#define RR_GET32_BE_OFFSET RR_GET32_NATIVE_OFFSET
#define RR_PUT32_BE_OFFSET RR_PUT32_NATIVE_OFFSET
#define RR_GET64_BE RR_GET64_NATIVE
#define RR_PUT64_BE RR_PUT64_NATIVE
#define RR_GET64_BE_OFFSET RR_GET64_NATIVE_OFFSET
#define RR_PUT64_BE_OFFSET RR_PUT64_NATIVE_OFFSET
#endif
//-------------------------
// non-native Get/Put implementations go here :
#if defined(__RADX86__)
// good implementation for X86 :
#if (_MSC_VER >= 1300)
unsigned short __cdecl _byteswap_ushort (unsigned short _Short);
unsigned long __cdecl _byteswap_ulong (unsigned long _Long);
#pragma intrinsic(_byteswap_ushort, _byteswap_ulong)
#define RR_BSWAP16 _byteswap_ushort
#define RR_BSWAP32 _byteswap_ulong
unsigned __int64 __cdecl _byteswap_uint64 (unsigned __int64 val);
#pragma intrinsic(_byteswap_uint64)
#define RR_BSWAP64 _byteswap_uint64
#elif defined(_MSC_VER) // VC6
RADFORCEINLINE unsigned long RR_BSWAP16 (unsigned long _Long)
{
__asm {
mov eax, [_Long]
rol ax, 8
mov [_Long], eax;
}
return _Long;
}
RADFORCEINLINE unsigned long RR_BSWAP32 (unsigned long _Long)
{
__asm {
mov eax, [_Long]
bswap eax
mov [_Long], eax
}
return _Long;
}
RADFORCEINLINE unsigned __int64 RR_BSWAP64 (unsigned __int64 _Long)
{
__asm {
mov eax, DWORD PTR _Long
mov edx, DWORD PTR _Long+4
bswap eax
bswap edx
mov DWORD PTR _Long, edx
mov DWORD PTR _Long+4, eax
}
return _Long;
}
#elif defined(__GNUC__) || defined(__clang__)
// GCC has __builtin_bswap16, but Clang only seems to have added it recently.
// We use __builtin_bswap32/64 but 16 just uses the macro version. (No big
// deal if that turns into shifts anyway)
#define RR_BSWAP16(u16) ( (U16) ( ((u16) >> 8) | ((u16) << 8) ) )
#define RR_BSWAP32 __builtin_bswap32
#define RR_BSWAP64 __builtin_bswap64
#endif
#define RR_GET16_BE(ptr) RR_BSWAP16(*((U16 *)(ptr)))
#define RR_PUT16_BE(ptr,val) *((U16 *)(ptr)) = (U16) RR_BSWAP16(val)
#define RR_GET16_BE_OFFSET(ptr,offset) RR_BSWAP16(*RR_U16_PTR_OFFSET(ptr,offset))
#define RR_PUT16_BE_OFFSET(ptr,val,offset) *RR_U16_PTR_OFFSET(ptr,offset) = RR_BSWAP16(val)
#define RR_GET32_BE(ptr) RR_BSWAP32(*((U32 *)(ptr)))
#define RR_PUT32_BE(ptr,val) *((U32 *)(ptr)) = RR_BSWAP32(val)
#define RR_GET32_BE_OFFSET(ptr,offset) RR_BSWAP32(*RR_U32_PTR_OFFSET(ptr,offset))
#define RR_PUT32_BE_OFFSET(ptr,val,offset) *RR_U32_PTR_OFFSET(ptr,offset) = RR_BSWAP32(val)
#define RR_GET64_BE(ptr) RR_BSWAP64(*((U64 *)(ptr)))
#define RR_PUT64_BE(ptr,val) *((U64 *)(ptr)) = RR_BSWAP64(val)
#define RR_GET64_BE_OFFSET(ptr,offset) RR_BSWAP64(*RR_U64_PTR_OFFSET(ptr,offset))
#define RR_PUT64_BE_OFFSET(ptr,val,offset) *RR_U64_PTR_OFFSET(ptr,offset) = RR_BSWAP64(val)
// end _MSC_VER
#elif defined(__RADXENON__) // Xenon has built-in funcs for this
unsigned short __loadshortbytereverse(int offset, const void *base);
unsigned long __loadwordbytereverse (int offset, const void *base);
void __storeshortbytereverse(unsigned short val, int offset, void *base);
void __storewordbytereverse (unsigned int val, int offset, void *base);
#define RR_GET16_LE(ptr) __loadshortbytereverse(0, ptr)
#define RR_PUT16_LE(ptr,val) __storeshortbytereverse((U16) (val), 0, ptr)
#define RR_GET16_LE_OFFSET(ptr,offset) __loadshortbytereverse(offset, ptr)
#define RR_PUT16_LE_OFFSET(ptr,val,offset) __storeshortbytereverse((U16) (val), offset, ptr)
#define RR_GET32_LE(ptr) __loadwordbytereverse(0, ptr)
#define RR_PUT32_LE(ptr,val) __storewordbytereverse((U32) (val), 0, ptr)
#define RR_GET32_LE_OFFSET(ptr,offset) __loadwordbytereverse(offset, ptr)
#define RR_PUT32_LE_OFFSET(ptr,val,offset) __storewordbytereverse((U32) (val), offset, ptr)
#define RR_GET64_LE(ptr) ( ((U64)RR_GET32_OFFSET_LE(ptr,4)<<32) | RR_GET32_LE(ptr) )
#define RR_PUT64_LE(ptr,val) RR_PUT32_LE(ptr, (U32) (val)), RR_PUT32_OFFSET_LE(ptr, (U32) ((val)>>32),4)
#elif defined(__RADPS3__)
#include <ppu_intrinsics.h>
#define RR_GET16_LE(ptr) __lhbrx(ptr)
#define RR_PUT16_LE(ptr,val) __sthbrx(ptr, (U16) (val))
#define RR_GET16_LE_OFFSET(ptr,offset) __lhbrx(RR_U16_PTR_OFFSET(ptr, offset))
#define RR_PUT16_LE_OFFSET(ptr,val,offset) __sthbrx(RR_U16_PTR_OFFSET(ptr, offset), (U16) (val))
#define RR_GET32_LE(ptr) __lwbrx(ptr)
#define RR_PUT32_LE(ptr,val) __stwbrx(ptr, (U32) (val))
#define RR_GET64_LE(ptr) __ldbrx(ptr)
#define RR_PUT64_LE(ptr,val) __stdbrx(ptr, (U32) (val))
#define RR_GET32_LE_OFFSET(ptr,offset) __lwbrx(RR_U32_PTR_OFFSET(ptr, offset))
#define RR_PUT32_LE_OFFSET(ptr,val,offset) __stwbrx(RR_U32_PTR_OFFSET(ptr, offset), (U32) (val))
#elif defined(__RADWII__)
#define RR_GET16_LE(ptr) __lhbrx(ptr, 0)
#define RR_PUT16_LE(ptr,val) __sthbrx((U16) (val), ptr, 0)
#define RR_GET16_LE_OFFSET(ptr,offset) __lhbrx(ptr, offset)
#define RR_PUT16_LE_OFFSET(ptr,val,offset) __sthbrx((U16) (val), ptr, offset)
#define RR_GET32_LE(ptr) __lwbrx(ptr, 0)
#define RR_PUT32_LE(ptr,val) __stwbrx((U32) (val), ptr, 0)
#define RR_GET32_LE_OFFSET(ptr,offset) __lwbrx(ptr, offset)
#define RR_PUT32_LE_OFFSET(ptr,val,offset) __stwbrx((U32) (val), ptr, offset)
#elif defined(__RAD3DS__)
#define RR_GET16_BE(ptr) __rev16(*(U16 *) (ptr))
#define RR_PUT16_BE(ptr,val) *(U16 *) (ptr) = __rev16(val)
#define RR_GET16_BE_OFFSET(ptr,offset) __rev16(*RR_U16_PTR_OFFSET(ptr,offset))
#define RR_PUT16_BE_OFFSET(ptr,offset,val) *RR_U16_PTR_OFFSET(ptr,offset) = __rev16(val)
#define RR_GET32_BE(ptr) __rev(*(U32 *) (ptr))
#define RR_PUT32_BE(ptr,val) *(U32 *) (ptr) = __rev(val)
#define RR_GET32_BE_OFFSET(ptr,offset) __rev(*RR_U32_PTR_OFFSET(ptr,offset))
#define RR_PUT32_BE_OFFSET(ptr,offset,val) *RR_U32_PTR_OFFSET(ptr,offset) = __rev(val)
#elif defined(__RADIPHONE__)
// iPhone does not seem to have intrinsics for this, so use generic fallback!
// Bswap is just here for use of implementing get/put
// caller should use Get/Put , not bswap
#define RR_BSWAP16(u16) ( (U16) ( ((u16) >> 8) | ((u16) << 8) ) )
#define RR_BSWAP32(u32) ( (U32) ( ((u32) >> 24) | (((u32)<<8) & 0x00FF0000) | (((u32)>>8) & 0x0000FF00) | ((u32) << 24) ) )
#define RR_GET16_BE(ptr) RR_BSWAP16(*((U16 *)(ptr)))
#define RR_PUT16_BE(ptr,val) *((U16 *)(ptr)) = RR_BSWAP16(val)
#define RR_GET32_BE(ptr) RR_BSWAP32(*((U32 *)(ptr)))
#define RR_PUT32_BE(ptr,val) *((U32 *)(ptr)) = RR_BSWAP32(val)
#elif defined(__RADWIIU__)
#include <ppc_ghs.h>
#define RR_GET16_LE(ptr) (*(__bytereversed U16 *) (ptr))
#define RR_PUT16_LE(ptr,val) *(__bytereversed U16 *) (ptr) = val
#define RR_GET16_LE_OFFSET(ptr,offset) (*(__bytereversed U16 *)RR_U16_PTR_OFFSET(ptr,offset))
#define RR_PUT16_LE_OFFSET(ptr,val,offset) *(__bytereversed U16 *)RR_U16_PTR_OFFSET(ptr,offset) = val
#define RR_GET32_LE(ptr) (*(__bytereversed U32 *) (ptr))
#define RR_PUT32_LE(ptr,val) *(__bytereversed U32 *) (ptr) = val
#define RR_GET32_LE_OFFSET(ptr,offset) (*(__bytereversed U32 *)RR_U32_PTR_OFFSET(ptr,offset))
#define RR_PUT32_LE_OFFSET(ptr,val,offset) *(__bytereversed U32 *)RR_U32_PTR_OFFSET(ptr,offset) = val
#define RR_GET64_LE(ptr) (*(__bytereversed U64 *) (ptr))
#define RR_PUT64_LE(ptr,val) *(__bytereversed U64 *) (ptr) = val
#define RR_GET64_LE_OFFSET(ptr,offset) (*(__bytereversed U64 *)RR_U32_PTR_OFFSET(ptr,offset))
#define RR_PUT64_LE_OFFSET(ptr,val,offset) *(__bytereversed U64 *)RR_U32_PTR_OFFSET(ptr,offset) = val
#elif defined(__RADWINRTAPI__) && defined(__RADARM__)
#include <intrin.h>
#define RR_BSWAP16(u16) _arm_rev16(u16)
#define RR_BSWAP32(u32) _arm_rev(u32)
#define RR_GET16_BE(ptr) RR_BSWAP16(*((U16 *)(ptr)))
#define RR_PUT16_BE(ptr,val) *((U16 *)(ptr)) = RR_BSWAP16(val)
#define RR_GET32_BE(ptr) RR_BSWAP32(*((U32 *)(ptr)))
#define RR_PUT32_BE(ptr,val) *((U32 *)(ptr)) = RR_BSWAP32(val)
#elif defined(__RADPSP2__)
// no rev16 exposed
#define RR_BSWAP16(u16) ( (U16) ( ((u16) >> 8) | ((u16) << 8) ) )
#define RR_BSWAP32(u32) __builtin_rev(u32)
#define RR_GET16_BE(ptr) RR_BSWAP16(*((U16 *)(ptr)))
#define RR_PUT16_BE(ptr,val) *((U16 *)(ptr)) = RR_BSWAP16(val)
#define RR_GET32_BE(ptr) RR_BSWAP32(*((U32 *)(ptr)))
#define RR_PUT32_BE(ptr,val) *((U32 *)(ptr)) = RR_BSWAP32(val)
#else // other platforms ?
// fall back :
// Bswap is just here for use of implementing get/put
// caller should use Get/Put , not bswap
#define RR_BSWAP16(u16) ( (U16) ( ((u16) >> 8) | ((u16) << 8) ) )
#define RR_BSWAP32(u32) ( (U32) ( ((u32) >> 24) | (((u32)<<8) & 0x00FF0000) | (((u32)>>8) & 0x0000FF00) | ((u32) << 24) ) )
#define RR_BSWAP64(u64) ( ((U64) RR_BSWAP32((U32) (u64)) << 32) | (U64) RR_BSWAP32((U32) ((u64) >> 32)) )
#ifdef __RADLITTLEENDIAN__
// comment out fallbacks so users will get errors
//#define RR_GET16_BE(ptr) RR_BSWAP16(*((U16 *)(ptr)))
//#define RR_PUT16_BE(ptr,val) *((U16 *)(ptr)) = RR_BSWAP16(val)
//#define RR_GET32_BE(ptr) RR_BSWAP32(*((U32 *)(ptr)))
//#define RR_PUT32_BE(ptr,val) *((U32 *)(ptr)) = RR_BSWAP32(val)
#else
// comment out fallbacks so users will get errors
//#define RR_GET16_LE(ptr) RR_BSWAP16(*((U16 *)(ptr)))
//#define RR_PUT16_LE(ptr,val) *((U16 *)(ptr)) = RR_BSWAP16(val)
//#define RR_GET32_LE(ptr) RR_BSWAP32(*((U32 *)(ptr)))
//#define RR_PUT32_LE(ptr,val) *((U32 *)(ptr)) = RR_BSWAP32(val)
#endif
#endif
//===================================================================
// @@ TEMP : Aliases for old names : remove me when possible :
#define RR_GET32_OFFSET_LE RR_GET32_LE_OFFSET
#define RR_GET32_OFFSET_BE RR_GET32_BE_OFFSET
#define RR_PUT32_OFFSET_LE RR_PUT32_LE_OFFSET
#define RR_PUT32_OFFSET_BE RR_PUT32_BE_OFFSET
#define RR_GET16_OFFSET_LE RR_GET16_LE_OFFSET
#define RR_GET16_OFFSET_BE RR_GET16_BE_OFFSET
#define RR_PUT16_OFFSET_LE RR_PUT16_LE_OFFSET
#define RR_PUT16_OFFSET_BE RR_PUT16_BE_OFFSET
//===================================================================
// UNALIGNED VERSIONS :
#if defined(__RADX86__) || defined(__RADPPC__) // platforms where unaligned is fast :
#define RR_GET32_BE_UNALIGNED(ptr) RR_GET32_BE(ptr)
#define RR_GET32_BE_UNALIGNED_OFFSET(ptr,offset) RR_GET32_BE_OFFSET(ptr,offset)
#define RR_GET16_BE_UNALIGNED(ptr) RR_GET16_BE(ptr)
#define RR_GET16_BE_UNALIGNED_OFFSET(ptr,offset) RR_GET16_BE_OFFSET(ptr,offset)
#define RR_GET32_LE_UNALIGNED(ptr) RR_GET32_LE(ptr)
#define RR_GET32_LE_UNALIGNED_OFFSET(ptr,offset) RR_GET32_LE_OFFSET(ptr,offset)
#define RR_GET16_LE_UNALIGNED(ptr) RR_GET16_LE(ptr)
#define RR_GET16_LE_UNALIGNED_OFFSET(ptr,offset) RR_GET16_LE_OFFSET(ptr,offset)
#elif defined(__RAD3DS__)
// arm has a "__packed" qualifier to tell the compiler to do unaligned accesses
#define RR_U16_PTR_OFFSET_UNALIGNED(ptr,offset) ((__packed U16 * RR_GET_PTR_POST)((char *)(ptr) + (offset)))
#define RR_U32_PTR_OFFSET_UNALIGNED(ptr,offset) ((__packed U32 * RR_GET_PTR_POST)((char *)(ptr) + (offset)))
#define RR_GET32_BE_UNALIGNED(ptr) __rev(*RR_U32_PTR_OFFSET_UNALIGNED(ptr,0))
#define RR_GET32_BE_UNALIGNED_OFFSET(ptr,offset) __rev(*RR_U32_PTR_OFFSET_UNALIGNED(ptr,offset))
#define RR_GET16_BE_UNALIGNED(ptr) __rev16(*RR_U16_PTR_OFFSET_UNALIGNED(ptr,0))
#define RR_GET16_BE_UNALIGNED_OFFSET(ptr,offset) __rev16(*RR_U16_PTR_OFFSET_UNALIGNED(ptr,offset))
#define RR_GET32_LE_UNALIGNED(ptr) *RR_U32_PTR_OFFSET_UNALIGNED(ptr,0)
#define RR_GET32_LE_UNALIGNED_OFFSET(ptr,offset) *RR_U32_PTR_OFFSET_UNALIGNED(ptr,offset)
#define RR_GET16_LE_UNALIGNED(ptr) *RR_U16_PTR_OFFSET_UNALIGNED(ptr,0)
#define RR_GET16_LE_UNALIGNED_OFFSET(ptr,offset) *RR_U16_PTR_OFFSET_UNALIGNED(ptr,offset)
#elif defined(__RADPSP2__)
#define RR_U16_PTR_OFFSET_UNALIGNED(ptr,offset) ((U16 __unaligned * RR_GET_PTR_POST)((char *)(ptr) + (offset)))
#define RR_U32_PTR_OFFSET_UNALIGNED(ptr,offset) ((U32 __unaligned * RR_GET_PTR_POST)((char *)(ptr) + (offset)))
#define RR_GET32_BE_UNALIGNED(ptr) RR_BSWAP32(*RR_U32_PTR_OFFSET_UNALIGNED(ptr,0))
#define RR_GET32_BE_UNALIGNED_OFFSET(ptr,offset) RR_BSWAP32(*RR_U32_PTR_OFFSET_UNALIGNED(ptr,offset))
#define RR_GET16_BE_UNALIGNED(ptr) RR_BSWAP16(*RR_U16_PTR_OFFSET_UNALIGNED(ptr,0))
#define RR_GET16_BE_UNALIGNED_OFFSET(ptr,offset) RR_BSWAP16(*RR_U16_PTR_OFFSET_UNALIGNED(ptr,offset))
#define RR_GET32_LE_UNALIGNED(ptr) *RR_U32_PTR_OFFSET_UNALIGNED(ptr,0)
#define RR_GET32_LE_UNALIGNED_OFFSET(ptr,offset) *RR_U32_PTR_OFFSET_UNALIGNED(ptr,offset)
#define RR_GET16_LE_UNALIGNED(ptr) *RR_U16_PTR_OFFSET_UNALIGNED(ptr,0)
#define RR_GET16_LE_UNALIGNED_OFFSET(ptr,offset) *RR_U16_PTR_OFFSET_UNALIGNED(ptr,offset)
#else
// Unaligned via bytes :
#define RR_GET32_BE_UNALIGNED(ptr) ( \
( (U32)(((const U8 * RR_GET_PTR_POST)(ptr)))[0] << 24 ) | \
( (U32)(((const U8 * RR_GET_PTR_POST)(ptr)))[1] << 16 ) | \
( (U32)(((const U8 * RR_GET_PTR_POST)(ptr)))[2] << 8 ) | \
( (U32)(((const U8 * RR_GET_PTR_POST)(ptr)))[3] << 0 ) )
#define RR_GET32_BE_UNALIGNED_OFFSET(ptr,offset) ( \
( (U32)(((const U8 * RR_GET_PTR_POST)(ptr))+(offset))[0] << 24 ) | \
( (U32)(((const U8 * RR_GET_PTR_POST)(ptr))+(offset))[1] << 16 ) | \
( (U32)(((const U8 * RR_GET_PTR_POST)(ptr))+(offset))[2] << 8 ) | \
( (U32)(((const U8 * RR_GET_PTR_POST)(ptr))+(offset))[3] << 0 ) )
#define RR_GET16_BE_UNALIGNED(ptr) ( \
( (U16)(((const U8 * RR_GET_PTR_POST)(ptr)))[0] << 8 ) | \
( (U16)(((const U8 * RR_GET_PTR_POST)(ptr)))[1] << 0 ) )
#define RR_GET16_BE_UNALIGNED_OFFSET(ptr,offset) ( \
( (U16)(((const U8 * RR_GET_PTR_POST)(ptr))+(offset))[0] << 8 ) | \
( (U16)(((const U8 * RR_GET_PTR_POST)(ptr))+(offset))[1] << 0 ) )
#define RR_GET32_LE_UNALIGNED(ptr) ( \
( (U32)(((const U8 * RR_GET_PTR_POST)(ptr)))[3] << 24 ) | \
( (U32)(((const U8 * RR_GET_PTR_POST)(ptr)))[2] << 16 ) | \
( (U32)(((const U8 * RR_GET_PTR_POST)(ptr)))[1] << 8 ) | \
( (U32)(((const U8 * RR_GET_PTR_POST)(ptr)))[0] << 0 ) )
#define RR_GET32_LE_UNALIGNED_OFFSET(ptr,offset) ( \
( (U32)(((const U8 * RR_GET_PTR_POST)(ptr))+(offset))[3] << 24 ) | \
( (U32)(((const U8 * RR_GET_PTR_POST)(ptr))+(offset))[2] << 16 ) | \
( (U32)(((const U8 * RR_GET_PTR_POST)(ptr))+(offset))[1] << 8 ) | \
( (U32)(((const U8 * RR_GET_PTR_POST)(ptr))+(offset))[0] << 0 ) )
#define RR_GET16_LE_UNALIGNED(ptr) ( \
( (U16)(((const U8 * RR_GET_PTR_POST)(ptr)))[1] << 8 ) | \
( (U16)(((const U8 * RR_GET_PTR_POST)(ptr)))[0] << 0 ) )
#define RR_GET16_LE_UNALIGNED_OFFSET(ptr,offset) ( \
( (U16)(((const U8 * RR_GET_PTR_POST)(ptr))+(offset))[1] << 8 ) | \
( (U16)(((const U8 * RR_GET_PTR_POST)(ptr))+(offset))[0] << 0 ) )
#endif
//===================================================================
// RR_ROTL32 : 32-bit rotate
//
#ifdef _MSC_VER
unsigned long __cdecl _lrotl(unsigned long, int);
#pragma intrinsic(_lrotl)
#define RR_ROTL32(x,k) _lrotl((unsigned long)(x),(int)(k))
#elif defined(__RADCELL__) || defined(__RADLINUX__) || defined(__RADWII__) || defined(__RADMACAPI__) || defined(__RADWIIU__) || defined(__RADPS4__) || defined(__RADPSP2__)
// Compiler turns this into rotate correctly :
#define RR_ROTL32(u32,num) ( ( (u32) << (num) ) | ( (u32) >> (32 - (num))) )
#elif defined(__RAD3DS__)
#define RR_ROTL32(u32,num) __ror(u32, (-(num))&31)
#else
// comment out fallbacks so users will get errors
// fallback implementation using shift and or :
//#define RR_ROTL32(u32,num) ( ( (u32) << (num) ) | ( (u32) >> (32 - (num))) )
#endif
//===================================================================
// RR_ROTL64 : 64-bit rotate
#if ( defined(_MSC_VER) && _MSC_VER >= 1300)
unsigned __int64 __cdecl _rotl64(unsigned __int64 _Val, int _Shift);
#pragma intrinsic(_rotl64)
#define RR_ROTL64(x,k) _rotl64((unsigned __int64)(x),(int)(k))
#elif defined(__RADCELL__)
// PS3 GCC turns this into rotate correctly :
#define RR_ROTL64(u64,num) ( ( (u64) << (num) ) | ( (u64) >> (64 - (num))) )
#elif defined(__RADLINUX__) || defined(__RADMACAPI__)
//APTODO: Just to compile linux. Should we be doing better than this? If not, combine with above.
#define RR_ROTL64(u64,num) ( ( (u64) << (num) ) | ( (u64) >> (64 - (num))) )
#else
// comment out fallbacks so users will get errors
// fallback implementation using shift and or :
//#define RR_ROTL64(u64,num) ( ( (u64) << (num) ) | ( (u64) >> (64 - (num))) )
#endif
//===================================================================
RADDEFEND
//===================================================================
// RR_COMPILER_ASSERT
#if defined(__cplusplus) && !defined(RR_COMPILER_ASSERT)
#if defined(_MSC_VER) && (_MSC_VER >=1400)
// better version of COMPILER_ASSERT using boost technique
template <int x> struct RR_COMPILER_ASSERT_FAILURE;
template <> struct RR_COMPILER_ASSERT_FAILURE<1> { enum { value = 1 }; };
template<int x> struct rr_compiler_assert_test{};
// __LINE__ macro broken when -ZI is used see Q199057
#define RR_COMPILER_ASSERT( B ) \
typedef rr_compiler_assert_test<\
sizeof(RR_COMPILER_ASSERT_FAILURE< (B) ? 1 : 0 >)\
> rr_compiler_assert_typedef_
#endif
#endif
#ifndef RR_COMPILER_ASSERT
// this happens at declaration time, so if it's inside a function in a C file, drop {} around it
#define RR_COMPILER_ASSERT(exp) typedef char RR_STRING_JOIN(_dummy_array, __LINE__) [ (exp) ? 1 : -1 ]
#endif
//===================================================================
// some error checks :
RR_COMPILER_ASSERT( sizeof(RAD_UINTa) == sizeof( RR_STRING_JOIN(RAD_U,RAD_PTRBITS) ) );
RR_COMPILER_ASSERT( sizeof(RAD_UINTa) == RAD_PTRBYTES );
RR_COMPILER_ASSERT( RAD_TWOPTRBYTES == 2* RAD_PTRBYTES );
//===================================================================
#endif // __RADRES__
//include "testconstant.inl" // uncomment and include to test statement constants
#endif // __RADRR_COREH__
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