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//========= Copyright Valve Corporation, All rights reserved. ============//
//
// Purpose:
//
// $NoKeywords: $
//
//===========================================================================//
# ifndef PLATFORM_H
# define PLATFORM_H
# if defined(__x86_64__) || defined(_WIN64)
# define PLATFORM_64BITS 1
# endif
# if defined(__GCC__) || defined(__GNUC__)
# define COMPILER_GCC 1
# endif
# ifdef __clang__
# define COMPILER_CLANG 1
# endif
# if defined( _X360 )
# define NO_STEAM
# define NO_VOICE
// for the 360, the ppc platform and the rtos are tightly coupled
// setup the 360 environment here !once! for much less leaf module include wackiness
// these are critical order and purposely appear *before* anything else
# define _XBOX
# include <xtl.h>
# include <xaudio2.h>
# include <xbdm.h>
# include <Xgraphics.h>
# include <xui.h>
# include <pmcpbsetup.h>
# include <XMAHardwareAbstraction.h>
# undef _XBOX
# endif
# define __STDC_LIMIT_MACROS
# include <stdint.h>
# include "wchartypes.h"
# include "basetypes.h"
# include "tier0/valve_off.h"
# ifdef _DEBUG
# if !defined( PLAT_COMPILE_TIME_ASSERT )
# define PLAT_COMPILE_TIME_ASSERT( pred ) switch(0){case 0:case pred:;}
# endif
# else
# if !defined( PLAT_COMPILE_TIME_ASSERT )
# define PLAT_COMPILE_TIME_ASSERT( pred )
# endif
# endif
# ifdef _WIN32
# pragma once
# endif
// feature enables
# define NEW_SOFTWARE_LIGHTING
# ifdef POSIX
// need this for _alloca
# include <alloca.h>
# include <unistd.h>
# include <signal.h>
# include <time.h>
# endif
# include <malloc.h>
# include <new>
// need this for memset
# include <string.h>
# include "tier0/valve_minmax_on.h" // GCC 4.2.2 headers screw up our min/max defs.
# ifdef _RETAIL
# define IsRetail() true
# else
# define IsRetail() false
# endif
# ifdef _DEBUG
# define IsRelease() false
# define IsDebug() true
# else
# define IsRelease() true
# define IsDebug() false
# endif
// Deprecating, infavor of IsX360() which will revert to IsXbox()
// after confidence of xbox 1 code flush
# define IsXbox() false
# ifdef _WIN32
# define IsLinux() false
# define IsOSX() false
# define IsPosix() false
# define PLATFORM_WINDOWS 1 // Windows PC or Xbox 360
# ifndef _X360
# define IsWindows() true
# define IsPC() true
# define IsConsole() false
# define IsX360() false
# define IsPS3() false
# define IS_WINDOWS_PC
# define PLATFORM_WINDOWS_PC 1 // Windows PC
# ifdef _WIN64
# define IsPlatformWindowsPC64() true
# define IsPlatformWindowsPC32() false
# define PLATFORM_WINDOWS_PC64 1
# else
# define IsPlatformWindowsPC64() false
# define IsPlatformWindowsPC32() true
# define PLATFORM_WINDOWS_PC32 1
# endif
# else
# define PLATFORM_X360 1
# ifndef _CONSOLE
# define _CONSOLE
# endif
# define IsWindows() false
# define IsPC() false
# define IsConsole() true
# define IsX360() true
# define IsPS3() false
# endif
// Adding IsPlatformOpenGL() to help fix a bunch of code that was using IsPosix() to infer if the DX->GL translation layer was being used.
# if defined( DX_TO_GL_ABSTRACTION )
# define IsPlatformOpenGL() true
# else
# define IsPlatformOpenGL() false
# endif
# elif defined(POSIX)
# define IsPC() true
# define IsWindows() false
# define IsConsole() false
# define IsX360() false
# define IsPS3() false
# if defined( LINUX )
# define IsLinux() true
# else
# define IsLinux() false
# endif
# if defined( OSX )
# define IsOSX() true
# else
# define IsOSX() false
# endif
# define IsPosix() true
# define IsPlatformOpenGL() true
# else
# error
# endif
typedef unsigned char uint8 ;
typedef signed char int8 ;
# if defined( _WIN32 )
typedef __int16 int16 ;
typedef unsigned __int16 uint16 ;
typedef __int32 int32 ;
typedef unsigned __int32 uint32 ;
typedef __int64 int64 ;
typedef unsigned __int64 uint64 ;
# ifdef PLATFORM_64BITS
typedef __int64 intp ; // intp is an integer that can accomodate a pointer
typedef unsigned __int64 uintp ; // (ie, sizeof(intp) >= sizeof(int) && sizeof(intp) >= sizeof(void *)
# else
typedef __int32 intp ;
typedef unsigned __int32 uintp ;
# endif
# if defined( _X360 )
# ifdef __m128
# undef __m128
# endif
# define __m128 __vector4
# endif
// Use this to specify that a function is an override of a virtual function.
// This lets the compiler catch cases where you meant to override a virtual
// function but you accidentally changed the function signature and created
// an overloaded function. Usage in function declarations is like this:
// int GetData() const OVERRIDE;
# define OVERRIDE override
# else // _WIN32
typedef short int16 ;
typedef unsigned short uint16 ;
typedef int int32 ;
typedef unsigned int uint32 ;
typedef long long int64 ;
typedef unsigned long long uint64 ;
# ifdef PLATFORM_64BITS
typedef long long intp ;
typedef unsigned long long uintp ;
# else
typedef int intp ;
typedef unsigned int uintp ;
# endif
typedef void * HWND ;
// Avoid redefinition warnings if a previous header defines this.
# undef OVERRIDE
# if __cplusplus >= 201103L
# define OVERRIDE override
# if defined(__clang__)
// warning: 'override' keyword is a C++11 extension [-Wc++11-extensions]
// Disabling this warning is less intrusive than enabling C++11 extensions
# pragma GCC diagnostic ignored "-Wc++11-extensions"
# endif
# else
# define OVERRIDE
# endif
# endif // else _WIN32
//-----------------------------------------------------------------------------
// Set up platform type defines.
//-----------------------------------------------------------------------------
# if defined( PLATFORM_X360 ) || defined( _PS3 )
# if !defined( _GAMECONSOLE )
# define _GAMECONSOLE
# endif
# define IsPC() false
# define IsGameConsole() true
# else
# define IsPC() true
# define IsGameConsole() false
# endif
# ifdef PLATFORM_64BITS
# define IsPlatform64Bits() true
# else
# define IsPlatform64Bits() false
# endif
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# ifdef _ANDROID
# define IsAndroid() true
# else
# define IsAndroid() false
# endif
2020-04-22 16:56:21 +00:00
// From steam/steamtypes.h
// RTime32
// We use this 32 bit time representing real world time.
// It offers 1 second resolution beginning on January 1, 1970 (Unix time)
typedef uint32 RTime32 ;
typedef float float32 ;
typedef double float64 ;
// for when we don't care about how many bits we use
typedef unsigned int uint ;
# ifdef _MSC_VER
# pragma once
// Ensure that everybody has the right compiler version installed. The version
// number can be obtained by looking at the compiler output when you type 'cl'
// and removing the last two digits and the periods: 16.00.40219.01 becomes 160040219
# if _MSC_FULL_VER > 180000000
# if _MSC_FULL_VER < 180030723
# error You must install VS 2013 Update 3
# endif
# elif _MSC_FULL_VER > 160000000
# if _MSC_FULL_VER < 160040219
# error You must install VS 2010 SP1
# endif
# else
# if _MSC_FULL_VER < 140050727
# error You must install VS 2005 SP1
# endif
# endif
# endif
// This can be used to ensure the size of pointers to members when declaring
// a pointer type for a class that has only been forward declared
# ifdef _MSC_VER
# define SINGLE_INHERITANCE __single_inheritance
# define MULTIPLE_INHERITANCE __multiple_inheritance
# else
# define SINGLE_INHERITANCE
# define MULTIPLE_INHERITANCE
# endif
# ifdef _MSC_VER
# define NO_VTABLE __declspec( novtable )
# else
# define NO_VTABLE
# endif
# ifdef _MSC_VER
// This indicates that a function never returns, which helps with
// generating accurate compiler warnings
# define NORETURN __declspec( noreturn )
# else
# define NORETURN
# endif
// This can be used to declare an abstract (interface only) class.
// Classes marked abstract should not be instantiated. If they are, and access violation will occur.
//
// Example of use:
//
// abstract_class CFoo
// {
// ...
// }
//
// MSDN __declspec(novtable) documentation: http://msdn.microsoft.com/library/default.asp?url=/library/en-us/vclang/html/_langref_novtable.asp
//
// Note: NJS: This is not enabled for regular PC, due to not knowing the implications of exporting a class with no no vtable.
// It's probable that this shouldn't be an issue, but an experiment should be done to verify this.
//
# ifndef _X360
# define abstract_class class
# else
# define abstract_class class NO_VTABLE
# endif
// MSVC CRT uses 0x7fff while gcc uses MAX_INT, leading to mismatches between platforms
// As a result, we pick the least common denominator here. This should be used anywhere
// you might typically want to use RAND_MAX
# define VALVE_RAND_MAX 0x7fff
/*
FIXME : Enable this when we no longer fear change = )
// need these for the limits
# include <limits.h>
# include <float.h>
// Maximum and minimum representable values
# define INT8_MAX SCHAR_MAX
# define INT16_MAX SHRT_MAX
# define INT32_MAX LONG_MAX
# define INT64_MAX (((int64)~0) >> 1)
# define INT8_MIN SCHAR_MIN
# define INT16_MIN SHRT_MIN
# define INT32_MIN LONG_MIN
# define INT64_MIN (((int64)1) << 63)
# define UINT8_MAX ((uint8)~0)
# define UINT16_MAX ((uint16)~0)
# define UINT32_MAX ((uint32)~0)
# define UINT64_MAX ((uint64)~0)
# define UINT8_MIN 0
# define UINT16_MIN 0
# define UINT32_MIN 0
# define UINT64_MIN 0
# ifndef UINT_MIN
# define UINT_MIN UINT32_MIN
# endif
# define FLOAT32_MAX FLT_MAX
# define FLOAT64_MAX DBL_MAX
# define FLOAT32_MIN FLT_MIN
# define FLOAT64_MIN DBL_MIN
*/
// portability / compiler settings
# if defined(_WIN32) && !defined(WINDED)
# if defined(_M_IX86)
# define __i386__ 1
# endif
# elif POSIX
# if defined( OSX ) && defined( CARBON_WORKAROUND )
# define DWORD unsigned int
# else
typedef unsigned int DWORD ;
# endif
typedef unsigned short WORD ;
typedef void * HINSTANCE ;
# define _MAX_PATH PATH_MAX
# define __cdecl
# define __stdcall
# define __declspec
# endif // defined(_WIN32) && !defined(WINDED)
# define MAX_FILEPATH 512
// Defines MAX_PATH
# ifndef MAX_PATH
# define MAX_PATH 260
# endif
# ifdef _WIN32
# define MAX_UNICODE_PATH 32767
# else
# define MAX_UNICODE_PATH MAX_PATH
# endif
# define MAX_UNICODE_PATH_IN_UTF8 MAX_UNICODE_PATH*4
# if !defined( offsetof )
# ifdef __GNUC__
# define offsetof( type, var ) __builtin_offsetof( type, var )
# else
# define offsetof(s,m) (size_t)&(((s *)0)->m)
# endif
# endif // !defined( offsetof )
# define ALIGN_VALUE( val, alignment ) ( ( val + alignment - 1 ) & ~( alignment - 1 ) ) // need macro for constant expression
// Used to step into the debugger
# if defined( _WIN32 ) && !defined( _X360 )
# define DebuggerBreak() __debugbreak()
# elif defined( _X360 )
# define DebuggerBreak() DebugBreak()
# else
// On OSX, SIGTRAP doesn't really stop the thread cold when debugging.
// So if being debugged, use INT3 which is precise.
# ifdef OSX
# define DebuggerBreak() if ( Plat_IsInDebugSession() ) { __asm ( "int $3" ); } else { raise(SIGTRAP); }
# else
# define DebuggerBreak() raise(SIGTRAP)
# endif
# endif
# define DebuggerBreakIfDebugging() if ( !Plat_IsInDebugSession() ) ; else DebuggerBreak()
# ifdef STAGING_ONLY
# define DebuggerBreakIfDebugging_StagingOnly() if ( !Plat_IsInDebugSession() ) ; else DebuggerBreak()
# else
# define DebuggerBreakIfDebugging_StagingOnly()
# endif
// Allows you to specify code that should only execute if we are in a staging build. Otherwise the code noops.
# ifdef STAGING_ONLY
# define STAGING_ONLY_EXEC( _exec ) do { _exec; } while (0)
# else
# define STAGING_ONLY_EXEC( _exec ) do { } while (0)
# endif
// C functions for external declarations that call the appropriate C++ methods
# ifndef EXPORT
# ifdef _WIN32
# define EXPORT _declspec( dllexport )
# else
# define EXPORT /* */
# endif
# endif
# if defined __i386__ && !defined __linux__
# define id386 1
# else
# define id386 0
# endif // __i386__
// decls for aligning data
# ifdef _WIN32
# define DECL_ALIGN(x) __declspec(align(x))
# elif GNUC
# define DECL_ALIGN(x) __attribute__((aligned(x)))
# else
# define DECL_ALIGN(x) /* */
# endif
# ifdef _MSC_VER
// MSVC has the align at the start of the struct
# define ALIGN4 DECL_ALIGN(4)
# define ALIGN8 DECL_ALIGN(8)
# define ALIGN16 DECL_ALIGN(16)
# define ALIGN32 DECL_ALIGN(32)
# define ALIGN128 DECL_ALIGN(128)
# define ALIGN4_POST
# define ALIGN8_POST
# define ALIGN16_POST
# define ALIGN32_POST
# define ALIGN128_POST
# elif defined( GNUC )
// gnuc has the align decoration at the end
# define ALIGN4
# define ALIGN8
# define ALIGN16
# define ALIGN32
# define ALIGN128
# define ALIGN4_POST DECL_ALIGN(4)
# define ALIGN8_POST DECL_ALIGN(8)
# define ALIGN16_POST DECL_ALIGN(16)
# define ALIGN32_POST DECL_ALIGN(32)
# define ALIGN128_POST DECL_ALIGN(128)
# else
# error
# endif
// Pull in the /analyze code annotations.
# include "annotations.h"
//-----------------------------------------------------------------------------
// Convert int<-->pointer, avoiding 32/64-bit compiler warnings:
//-----------------------------------------------------------------------------
# define INT_TO_POINTER( i ) (void *)( ( i ) + (char *)NULL )
# define POINTER_TO_INT( p ) ( (int)(uintp)( p ) )
//-----------------------------------------------------------------------------
// Stack-based allocation related helpers
//-----------------------------------------------------------------------------
# if defined( GNUC )
# define stackalloc( _size ) alloca( ALIGN_VALUE( _size, 16 ) )
# ifdef _LINUX
# define mallocsize( _p ) ( malloc_usable_size( _p ) )
# elif defined(OSX)
# define mallocsize( _p ) ( malloc_size( _p ) )
# else
# error
# endif
# elif defined ( _WIN32 )
# define stackalloc( _size ) _alloca( ALIGN_VALUE( _size, 16 ) )
# define mallocsize( _p ) ( _msize( _p ) )
# endif
# define stackfree( _p ) 0
// Linux had a few areas where it didn't construct objects in the same order that Windows does.
// So when CVProfile::CVProfile() would access g_pMemAlloc, it would crash because the allocator wasn't initalized yet.
# ifdef POSIX
# define CONSTRUCT_EARLY __attribute__((init_priority(101)))
# else
# define CONSTRUCT_EARLY
# endif
# if defined(_MSC_VER)
# define SELECTANY __declspec(selectany)
# define RESTRICT __restrict
# define RESTRICT_FUNC __declspec(restrict)
# define FMTFUNCTION( a, b )
# elif defined(GNUC)
# define SELECTANY __attribute__((weak))
# if defined(LINUX) && !defined(DEDICATED)
# define RESTRICT
# else
# define RESTRICT __restrict
# endif
# define RESTRICT_FUNC
// squirrel.h does a #define printf DevMsg which leads to warnings when we try
// to use printf as the prototype format function. Using __printf__ instead.
# define FMTFUNCTION( fmtargnumber, firstvarargnumber ) __attribute__ (( format( __printf__, fmtargnumber, firstvarargnumber )))
# else
# define SELECTANY static
# define RESTRICT
# define RESTRICT_FUNC
# define FMTFUNCTION( a, b )
# endif
# if defined( _WIN32 )
// Used for dll exporting and importing
# define DLL_EXPORT extern "C" __declspec( dllexport )
# define DLL_IMPORT extern "C" __declspec( dllimport )
// Can't use extern "C" when DLL exporting a class
# define DLL_CLASS_EXPORT __declspec( dllexport )
# define DLL_CLASS_IMPORT __declspec( dllimport )
// Can't use extern "C" when DLL exporting a global
# define DLL_GLOBAL_EXPORT extern __declspec( dllexport )
# define DLL_GLOBAL_IMPORT extern __declspec( dllimport )
# define DLL_LOCAL
# elif defined GNUC
// Used for dll exporting and importing
# define DLL_EXPORT extern "C" __attribute__ ((visibility("default")))
# define DLL_IMPORT extern "C"
// Can't use extern "C" when DLL exporting a class
# define DLL_CLASS_EXPORT __attribute__ ((visibility("default")))
# define DLL_CLASS_IMPORT
// Can't use extern "C" when DLL exporting a global
# define DLL_GLOBAL_EXPORT extern __attribute ((visibility("default")))
# define DLL_GLOBAL_IMPORT extern
# define DLL_LOCAL __attribute__ ((visibility("hidden")))
# else
# error "Unsupported Platform."
# endif
// Used for standard calling conventions
# if defined( _WIN32 ) && !defined( _X360 )
# define STDCALL __stdcall
# define FASTCALL __fastcall
# define FORCEINLINE __forceinline
// GCC 3.4.1 has a bug in supporting forced inline of templated functions
// this macro lets us not force inlining in that case
# define FORCEINLINE_TEMPLATE __forceinline
# elif defined( _X360 )
# define STDCALL __stdcall
# ifdef FORCEINLINE
# undef FORCEINLINE
# endif
# define FORCEINLINE __forceinline
# define FORCEINLINE_TEMPLATE __forceinline
# else
# define STDCALL
# define FASTCALL
# ifdef _LINUX_DEBUGGABLE
# define FORCEINLINE
# else
# define FORCEINLINE inline __attribute__ ((always_inline))
# endif
// GCC 3.4.1 has a bug in supporting forced inline of templated functions
// this macro lets us not force inlining in that case
# define FORCEINLINE_TEMPLATE inline
// #define __stdcall __attribute__ ((__stdcall__))
# endif
// Force a function call site -not- to inlined. (useful for profiling)
# define DONT_INLINE(a) (((int)(a)+1)?(a):(a))
// Pass hints to the compiler to prevent it from generating unnessecary / stupid code
// in certain situations. Several compilers other than MSVC also have an equivilent
// construct.
//
// Essentially the 'Hint' is that the condition specified is assumed to be true at
// that point in the compilation. If '0' is passed, then the compiler assumes that
// any subsequent code in the same 'basic block' is unreachable, and thus usually
// removed.
# ifdef _MSC_VER
# define HINT(THE_HINT) __assume((THE_HINT))
# else
# define HINT(THE_HINT) 0
# endif
// Marks the codepath from here until the next branch entry point as unreachable,
// and asserts if any attempt is made to execute it.
# define UNREACHABLE() { Assert(0); HINT(0); }
// In cases where no default is present or appropriate, this causes MSVC to generate
// as little code as possible, and throw an assertion in debug.
# define NO_DEFAULT default: UNREACHABLE();
# ifdef _WIN32
// Remove warnings from warning level 4.
# pragma warning(disable : 4514) // warning C4514: 'acosl' : unreferenced inline function has been removed
# pragma warning(disable : 4100) // warning C4100: 'hwnd' : unreferenced formal parameter
# pragma warning(disable : 4127) // warning C4127: conditional expression is constant
# pragma warning(disable : 4512) // warning C4512: 'InFileRIFF' : assignment operator could not be generated
# pragma warning(disable : 4611) // warning C4611: interaction between '_setjmp' and C++ object destruction is non-portable
# pragma warning(disable : 4710) // warning C4710: function 'x' not inlined
# pragma warning(disable : 4702) // warning C4702: unreachable code
# pragma warning(disable : 4505) // unreferenced local function has been removed
# pragma warning(disable : 4239) // nonstandard extension used : 'argument' ( conversion from class Vector to class Vector& )
# pragma warning(disable : 4097) // typedef-name 'BaseClass' used as synonym for class-name 'CFlexCycler::CBaseFlex'
# pragma warning(disable : 4324) // Padding was added at the end of a structure
# pragma warning(disable : 4244) // type conversion warning.
# pragma warning(disable : 4305) // truncation from 'const double ' to 'float '
# pragma warning(disable : 4786) // Disable warnings about long symbol names
# pragma warning(disable : 4250) // 'X' : inherits 'Y::Z' via dominance
# pragma warning(disable : 4201) // nonstandard extension used : nameless struct/union
# pragma warning(disable : 4481) // warning C4481: nonstandard extension used: override specifier 'override'
# pragma warning(disable : 4748) // warning C4748: /GS can not protect parameters and local variables from local buffer overrun because optimizations are disabled in function
# if _MSC_VER >= 1300
# pragma warning(disable : 4511) // Disable warnings about private copy constructors
# pragma warning(disable : 4121) // warning C4121: 'symbol' : alignment of a member was sensitive to packing
# pragma warning(disable : 4530) // warning C4530: C++ exception handler used, but unwind semantics are not enabled. Specify /EHsc (disabled due to std headers having exception syntax)
# endif
# if _MSC_VER >= 1400
# pragma warning(disable : 4996) // functions declared deprecated
# endif
# endif // _WIN32
# if defined( LINUX ) && ((__GNUC__ * 100) + __GNUC_MINOR__) >= 406
// based on some Jonathan Wakely macros on the net...
# define GCC_DIAG_STR(s) #s
# define GCC_DIAG_JOINSTR(x,y) GCC_DIAG_STR(x ## y)
# define GCC_DIAG_DO_PRAGMA(x) _Pragma (#x)
# define GCC_DIAG_PRAGMA(x) GCC_DIAG_DO_PRAGMA(GCC diagnostic x)
# define GCC_DIAG_PUSH_OFF(x) GCC_DIAG_PRAGMA(push) GCC_DIAG_PRAGMA(ignored GCC_DIAG_JOINSTR(-W,x))
# define GCC_DIAG_POP() GCC_DIAG_PRAGMA(pop)
# else
# define GCC_DIAG_PUSH_OFF(x)
# define GCC_DIAG_POP()
# endif
# ifdef LINUX
# pragma GCC diagnostic ignored "-Wconversion-null" // passing NULL to non-pointer argument 1
# pragma GCC diagnostic ignored "-Wpointer-arith" // NULL used in arithmetic. Ie, vpanel == NULL where VPANEL is uint.
# pragma GCC diagnostic ignored "-Wswitch" // enumeration values not handled in switch
# endif
# ifdef OSX
# pragma GCC diagnostic ignored "-Wconversion-null" // passing NULL to non-pointer argument 1
# pragma GCC diagnostic ignored "-Wnull-arithmetic" // NULL used in arithmetic. Ie, vpanel == NULL where VPANEL is uint.
# pragma GCC diagnostic ignored "-Wswitch-enum" // enumeration values not handled in switch
# pragma GCC diagnostic ignored "-Wswitch" // enumeration values not handled in switch
# endif
// When we port to 64 bit, we'll have to resolve the int, ptr vs size_t 32/64 bit problems...
2021-04-25 20:36:09 +00:00
# if !defined( _WIN64 ) && defined( _WIN32 )
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# pragma warning( disable : 4267 ) // conversion from 'size_t' to 'int', possible loss of data
# pragma warning( disable : 4311 ) // pointer truncation from 'char *' to 'int'
# pragma warning( disable : 4312 ) // conversion from 'unsigned int' to 'memhandle_t' of greater size
# endif
# ifdef POSIX
# define _stricmp stricmp
# define strcmpi stricmp
# define stricmp strcasecmp
# define _vsnprintf vsnprintf
# define _alloca alloca
# ifdef _snprintf
# undef _snprintf
# endif
# define _snprintf snprintf
# define GetProcAddress dlsym
# define _chdir chdir
# define _strnicmp strnicmp
# define strnicmp strncasecmp
# define _getcwd getcwd
# define _snwprintf swprintf
# define swprintf_s swprintf
# define wcsicmp _wcsicmp
# define _wcsicmp wcscmp
# define _finite finite
# define _tempnam tempnam
# define _unlink unlink
# define _access access
# define _mkdir(dir) mkdir( dir, S_IRWXU | S_IRWXG | S_IRWXO )
# define _wtoi(arg) wcstol(arg, NULL, 10)
# define _wtoi64(arg) wcstoll(arg, NULL, 10)
typedef uint32 HMODULE ;
typedef void * HANDLE ;
# endif
//-----------------------------------------------------------------------------
// fsel
//-----------------------------------------------------------------------------
# ifndef _X360
static FORCEINLINE float fsel ( float fComparand , float fValGE , float fLT )
{
return fComparand > = 0 ? fValGE : fLT ;
}
static FORCEINLINE double fsel ( double fComparand , double fValGE , double fLT )
{
return fComparand > = 0 ? fValGE : fLT ;
}
# else
// __fsel(double fComparand, double fValGE, double fLT) == fComparand >= 0 ? fValGE : fLT
// this is much faster than if ( aFloat > 0 ) { x = .. }
# define fsel __fsel
# endif
//-----------------------------------------------------------------------------
// FP exception handling
//-----------------------------------------------------------------------------
//#define CHECK_FLOAT_EXCEPTIONS 1
# if !defined( _X360 )
# if defined( _MSC_VER )
# if defined( PLATFORM_WINDOWS_PC64 )
inline void SetupFPUControlWord ( )
{
}
# else
inline void SetupFPUControlWordForceExceptions ( )
{
// use local to get and store control word
uint16 tmpCtrlW ;
__asm
{
fnclex /* clear all current exceptions */
fnstcw word ptr [ tmpCtrlW ] /* get current control word */
and [ tmpCtrlW ] , 0F CC0h /* Keep infinity control + rounding control */
or [ tmpCtrlW ] , 0230 h /* set to 53-bit, mask only inexact, underflow */
fldcw word ptr [ tmpCtrlW ] /* put new control word in FPU */
}
}
# ifdef CHECK_FLOAT_EXCEPTIONS
inline void SetupFPUControlWord ( )
{
SetupFPUControlWordForceExceptions ( ) ;
}
# else
inline void SetupFPUControlWord ( )
{
// use local to get and store control word
uint16 tmpCtrlW ;
__asm
{
fnstcw word ptr [ tmpCtrlW ] /* get current control word */
and [ tmpCtrlW ] , 0F CC0h /* Keep infinity control + rounding control */
or [ tmpCtrlW ] , 023F h /* set to 53-bit, mask only inexact, underflow */
fldcw word ptr [ tmpCtrlW ] /* put new control word in FPU */
}
}
# endif
# endif
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# elif defined (__arm__)
inline void SetupFPUControlWord ( ) { }
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# else
inline void SetupFPUControlWord ( )
{
__volatile unsigned short int __cw ;
__asm __volatile ( " fnstcw %0 " : " =m " ( __cw ) ) ;
__cw = __cw & 0x0FCC0 ; // keep infinity control, keep rounding mode
__cw = __cw | 0x023F ; // set 53-bit, no exceptions
__asm __volatile ( " fldcw %0 " : : " m " ( __cw ) ) ;
}
# endif // _MSC_VER
# else
# ifdef _DEBUG
FORCEINLINE bool IsFPUControlWordSet ( )
{
float f = 0.996f ;
union
{
double flResult ;
int pResult [ 2 ] ;
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}
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flResult = __fctiw ( f ) ;
return ( pResult [ 1 ] = = 1 ) ;
}
# endif
inline void SetupFPUControlWord ( )
{
// Set round-to-nearest in FPSCR
// (cannot assemble, must use op-code form)
__emit ( 0xFF80010C ) ; // mtfsfi 7,0
// Favour compatibility over speed (make sure the VPU set to Java-compliant mode)
// NOTE: the VPU *always* uses round-to-nearest
__vector4 a = { 0.0f , 0.0f , 0.0f , 0.0f } ;
a ; // Avoid compiler warning
__asm
{
mtvscr a ; // Clear the Vector Status & Control Register to zero
}
}
# endif // _X360
//-----------------------------------------------------------------------------
// Purpose: Standard functions for handling endian-ness
//-----------------------------------------------------------------------------
//-------------------------------------
// Basic swaps
//-------------------------------------
template < typename T >
inline T WordSwapC ( T w )
{
uint16 temp ;
temp = ( ( * ( ( uint16 * ) & w ) & 0xff00 ) > > 8 ) ;
temp | = ( ( * ( ( uint16 * ) & w ) & 0x00ff ) < < 8 ) ;
return * ( ( T * ) & temp ) ;
}
template < typename T >
inline T DWordSwapC ( T dw )
{
uint32 temp ;
temp = * ( ( uint32 * ) & dw ) > > 24 ;
temp | = ( ( * ( ( uint32 * ) & dw ) & 0x00FF0000 ) > > 8 ) ;
temp | = ( ( * ( ( uint32 * ) & dw ) & 0x0000FF00 ) < < 8 ) ;
temp | = ( ( * ( ( uint32 * ) & dw ) & 0x000000FF ) < < 24 ) ;
return * ( ( T * ) & temp ) ;
}
template < typename T >
inline T QWordSwapC ( T dw )
{
// Assert sizes passed to this are already correct, otherwise
// the cast to uint64 * below is unsafe and may have wrong results
// or even crash.
PLAT_COMPILE_TIME_ASSERT ( sizeof ( dw ) = = sizeof ( uint64 ) ) ;
uint64 temp ;
temp = * ( ( uint64 * ) & dw ) > > 56 ;
temp | = ( ( * ( ( uint64 * ) & dw ) & 0x00FF000000000000ull ) > > 40 ) ;
temp | = ( ( * ( ( uint64 * ) & dw ) & 0x0000FF0000000000ull ) > > 24 ) ;
temp | = ( ( * ( ( uint64 * ) & dw ) & 0x000000FF00000000ull ) > > 8 ) ;
temp | = ( ( * ( ( uint64 * ) & dw ) & 0x00000000FF000000ull ) < < 8 ) ;
temp | = ( ( * ( ( uint64 * ) & dw ) & 0x0000000000FF0000ull ) < < 24 ) ;
temp | = ( ( * ( ( uint64 * ) & dw ) & 0x000000000000FF00ull ) < < 40 ) ;
temp | = ( ( * ( ( uint64 * ) & dw ) & 0x00000000000000FFull ) < < 56 ) ;
return * ( ( T * ) & temp ) ;
}
//-------------------------------------
// Fast swaps
//-------------------------------------
# if defined( _X360 )
# define WordSwap WordSwap360Intr
# define DWordSwap DWordSwap360Intr
template < typename T >
inline T WordSwap360Intr ( T w )
{
T output ;
__storeshortbytereverse ( w , 0 , & output ) ;
return output ;
}
template < typename T >
inline T DWordSwap360Intr ( T dw )
{
T output ;
__storewordbytereverse ( dw , 0 , & output ) ;
return output ;
}
# elif defined( _MSC_VER ) && !defined( PLATFORM_WINDOWS_PC64 )
# define WordSwap WordSwapAsm
# define DWordSwap DWordSwapAsm
# pragma warning(push)
# pragma warning (disable:4035) // no return value
template < typename T >
inline T WordSwapAsm ( T w )
{
__asm
{
mov ax , w
xchg al , ah
}
}
template < typename T >
inline T DWordSwapAsm ( T dw )
{
__asm
{
mov eax , dw
bswap eax
}
}
# pragma warning(pop)
# else
# define WordSwap WordSwapC
# define DWordSwap DWordSwapC
# endif
// No ASM implementation for this yet
# define QWordSwap QWordSwapC
//-------------------------------------
// The typically used methods.
//-------------------------------------
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# if (defined(__i386__) || (defined(__arm__) && defined(ANDROID))) && !defined(VALVE_LITTLE_ENDIAN)
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# define VALVE_LITTLE_ENDIAN 1
# endif
# if defined( _SGI_SOURCE ) || defined( _X360 )
# define VALVE_BIG_ENDIAN 1
# endif
// If a swapped float passes through the fpu, the bytes may get changed.
// Prevent this by swapping floats as DWORDs.
# define SafeSwapFloat( pOut, pIn ) (*((uint*)pOut) = DWordSwap( *((uint*)pIn) ))
# if defined(VALVE_LITTLE_ENDIAN)
# define BigShort( val ) WordSwap( val )
# define BigWord( val ) WordSwap( val )
# define BigLong( val ) DWordSwap( val )
# define BigDWord( val ) DWordSwap( val )
# define LittleShort( val ) ( val )
# define LittleWord( val ) ( val )
# define LittleLong( val ) ( val )
# define LittleDWord( val ) ( val )
# define LittleQWord( val ) ( val )
# define SwapShort( val ) BigShort( val )
# define SwapWord( val ) BigWord( val )
# define SwapLong( val ) BigLong( val )
# define SwapDWord( val ) BigDWord( val )
// Pass floats by pointer for swapping to avoid truncation in the fpu
# define BigFloat( pOut, pIn ) SafeSwapFloat( pOut, pIn )
# define LittleFloat( pOut, pIn ) ( *pOut = *pIn )
# define SwapFloat( pOut, pIn ) BigFloat( pOut, pIn )
# elif defined(VALVE_BIG_ENDIAN)
# define BigShort( val ) ( val )
# define BigWord( val ) ( val )
# define BigLong( val ) ( val )
# define BigDWord( val ) ( val )
# define LittleShort( val ) WordSwap( val )
# define LittleWord( val ) WordSwap( val )
# define LittleLong( val ) DWordSwap( val )
# define LittleDWord( val ) DWordSwap( val )
# define LittleQWord( val ) QWordSwap( val )
# define SwapShort( val ) LittleShort( val )
# define SwapWord( val ) LittleWord( val )
# define SwapLong( val ) LittleLong( val )
# define SwapDWord( val ) LittleDWord( val )
// Pass floats by pointer for swapping to avoid truncation in the fpu
# define BigFloat( pOut, pIn ) ( *pOut = *pIn )
# define LittleFloat( pOut, pIn ) SafeSwapFloat( pOut, pIn )
# define SwapFloat( pOut, pIn ) LittleFloat( pOut, pIn )
# else
// @Note (toml 05-02-02): this technique expects the compiler to
// optimize the expression and eliminate the other path. On any new
// platform/compiler this should be tested.
inline uint16 BigWord ( uint16 val ) { int test = 1 ; return ( * ( char * ) & test = = 1 ) ? WordSwap ( val ) : val ; }
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# define BigShort( val ) BigWord( val )
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inline uint32 BigDWord ( uint32 val ) { int test = 1 ; return ( * ( char * ) & test = = 1 ) ? DWordSwap ( val ) : val ; }
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# define BigLong( val ) BigDWord( val )
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inline uint16 LittleWord ( uint16 val ) { int test = 1 ; return ( * ( char * ) & test = = 1 ) ? val : WordSwap ( val ) ; }
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# define LittleShort( val ) LittleWord( val )
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inline uint32 LittleDWord ( uint32 val ) { int test = 1 ; return ( * ( char * ) & test = = 1 ) ? val : DWordSwap ( val ) ; }
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# define LittleLong( val ) LittleDWord( val )
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inline uint64 LittleQWord ( uint64 val ) { int test = 1 ; return ( * ( char * ) & test = = 1 ) ? val : QWordSwap ( val ) ; }
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inline uint16 SwapWord ( uint16 val ) { return WordSwap ( val ) ; }
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# define SwapShort( val ) SwapWord( val )
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inline uint32 SwapDWord ( uint32 val ) { return DWordSwap ( val ) ; }
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# define SwapLong( val ) SwapDWord( val )
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// Pass floats by pointer for swapping to avoid truncation in the fpu
inline void BigFloat ( float * pOut , const float * pIn ) { int test = 1 ; ( * ( char * ) & test = = 1 ) ? SafeSwapFloat ( pOut , pIn ) : ( * pOut = * pIn ) ; }
inline void LittleFloat ( float * pOut , const float * pIn ) { int test = 1 ; ( * ( char * ) & test = = 1 ) ? ( * pOut = * pIn ) : SafeSwapFloat ( pOut , pIn ) ; }
inline void SwapFloat ( float * pOut , const float * pIn ) { SafeSwapFloat ( pOut , pIn ) ; }
# endif
# if _X360
FORCEINLINE unsigned long LoadLittleDWord ( const unsigned long * base , unsigned int dwordIndex )
{
return __loadwordbytereverse ( dwordIndex < < 2 , base ) ;
}
FORCEINLINE void StoreLittleDWord ( unsigned long * base , unsigned int dwordIndex , unsigned long dword )
{
__storewordbytereverse ( dword , dwordIndex < < 2 , base ) ;
}
# else
FORCEINLINE unsigned long LoadLittleDWord ( const unsigned long * base , unsigned int dwordIndex )
{
return LittleDWord ( base [ dwordIndex ] ) ;
}
FORCEINLINE void StoreLittleDWord ( unsigned long * base , unsigned int dwordIndex , unsigned long dword )
{
base [ dwordIndex ] = LittleDWord ( dword ) ;
}
# endif
//-----------------------------------------------------------------------------
// DLL export for platform utilities
//-----------------------------------------------------------------------------
# ifndef STATIC_TIER0
# ifdef TIER0_DLL_EXPORT
# define PLATFORM_INTERFACE DLL_EXPORT
# define PLATFORM_OVERLOAD DLL_GLOBAL_EXPORT
# define PLATFORM_CLASS DLL_CLASS_EXPORT
# else
# define PLATFORM_INTERFACE DLL_IMPORT
# define PLATFORM_OVERLOAD DLL_GLOBAL_IMPORT
# define PLATFORM_CLASS DLL_CLASS_IMPORT
# endif
# else // BUILD_AS_DLL
# define PLATFORM_INTERFACE extern
# define PLATFORM_OVERLOAD
# define PLATFORM_CLASS
# endif // BUILD_AS_DLL
// When in benchmark mode, the timer returns a simple incremented value each time you call it.
//
// It should not be changed after startup unless you really know what you're doing. The only place
// that should do this is the benchmark code itself so it can output a legit duration.
PLATFORM_INTERFACE void Plat_SetBenchmarkMode ( bool bBenchmarkMode ) ;
PLATFORM_INTERFACE bool Plat_IsInBenchmarkMode ( ) ;
PLATFORM_INTERFACE double Plat_FloatTime ( ) ; // Returns time in seconds since the module was loaded.
PLATFORM_INTERFACE uint32 Plat_MSTime ( ) ; // Time in milliseconds.
PLATFORM_INTERFACE uint64 Plat_USTime ( ) ; // Time in microseconds.
PLATFORM_INTERFACE char * Plat_ctime ( const time_t * timep , char * buf , size_t bufsize ) ;
PLATFORM_INTERFACE void Plat_GetModuleFilename ( char * pOut , int nMaxBytes ) ;
PLATFORM_INTERFACE void Plat_ExitProcess ( int nCode ) ;
//called to exit the process due to a fatal error. This allows for the application to handle providing a hook as well which can be called
//before exiting
PLATFORM_INTERFACE void Plat_ExitProcessWithError ( int nCode , bool bGenerateMinidump = false ) ;
//sets the callback that will be triggered by Plat_ExitProcessWithError. NULL is valid. The return value true indicates that
//the exit has been handled and no further processing should be performed. False will cause a minidump to be generated, and the process
//to be terminated
typedef bool ( * ExitProcessWithErrorCBFn ) ( int nCode ) ;
PLATFORM_INTERFACE void Plat_SetExitProcessWithErrorCB ( ExitProcessWithErrorCBFn pfnCB ) ;
PLATFORM_INTERFACE struct tm * Plat_gmtime ( const time_t * timep , struct tm * result ) ;
PLATFORM_INTERFACE time_t Plat_timegm ( struct tm * timeptr ) ;
PLATFORM_INTERFACE struct tm * Plat_localtime ( const time_t * timep , struct tm * result ) ;
# if defined( _WIN32 ) && defined( _MSC_VER ) && ( _MSC_VER >= 1400 )
extern " C " unsigned __int64 __rdtsc ( ) ;
# pragma intrinsic(__rdtsc)
# endif
inline uint64 Plat_Rdtsc ( )
{
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# if defined( __arm__ ) && defined (POSIX)
struct timespec t ;
clock_gettime ( CLOCK_REALTIME , & t ) ;
return t . tv_sec * 1000000000ULL + t . tv_nsec ;
# elif defined( _X360 )
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return ( uint64 ) __mftb32 ( ) ;
# elif defined( _WIN64 )
return ( uint64 ) __rdtsc ( ) ;
# elif defined( _WIN32 )
# if defined( _MSC_VER ) && ( _MSC_VER >= 1400 )
return ( uint64 ) __rdtsc ( ) ;
# else
__asm rdtsc ;
__asm ret ;
# endif
# elif defined( __i386__ )
uint64 val ;
__asm__ __volatile__ ( " rdtsc " : " =A " ( val ) ) ;
return val ;
# elif defined( __x86_64__ )
uint32 lo , hi ;
__asm__ __volatile__ ( " rdtsc " : " =a " ( lo ) , " =d " ( hi ) ) ;
return ( ( ( uint64 ) hi ) < < 32 ) | lo ;
# else
# error
# endif
}
// b/w compatibility
# define Sys_FloatTime Plat_FloatTime
// Protect against bad auto operator=
# define DISALLOW_OPERATOR_EQUAL( _classname ) \
private : \
_classname & operator = ( const _classname & ) ; \
public :
// Define a reasonable operator=
# define IMPLEMENT_OPERATOR_EQUAL( _classname ) \
public : \
_classname & operator = ( const _classname & src ) \
{ \
memcpy ( this , & src , sizeof ( _classname ) ) ; \
return * this ; \
}
// Processor Information:
struct CPUInformation
{
int m_Size ; // Size of this structure, for forward compatability.
bool m_bRDTSC : 1 , // Is RDTSC supported?
m_bCMOV : 1 , // Is CMOV supported?
m_bFCMOV : 1 , // Is FCMOV supported?
m_bSSE : 1 , // Is SSE supported?
m_bSSE2 : 1 , // Is SSE2 Supported?
m_b3DNow : 1 , // Is 3DNow! Supported?
m_bMMX : 1 , // Is MMX supported?
m_bHT : 1 ; // Is HyperThreading supported?
uint8 m_nLogicalProcessors ; // Number op logical processors.
uint8 m_nPhysicalProcessors ; // Number of physical processors
bool m_bSSE3 : 1 ,
m_bSSSE3 : 1 ,
m_bSSE4a : 1 ,
m_bSSE41 : 1 ,
m_bSSE42 : 1 ;
int64 m_Speed ; // In cycles per second.
tchar * m_szProcessorID ; // Processor vendor Identification.
uint32 m_nModel ;
uint32 m_nFeatures [ 3 ] ;
CPUInformation ( ) : m_Size ( 0 ) { }
} ;
// Have to return a pointer, not a reference, because references are not compatible with the
// extern "C" implied by PLATFORM_INTERFACE.
PLATFORM_INTERFACE const CPUInformation * GetCPUInformation ( ) ;
# define MEMORY_INFORMATION_VERSION 0
struct MemoryInformation
{
int m_nStructVersion ;
uint m_nPhysicalRamMbTotal ;
uint m_nPhysicalRamMbAvailable ;
uint m_nVirtualRamMbTotal ;
uint m_nVirtualRamMbAvailable ;
inline MemoryInformation ( )
{
memset ( this , 0 , sizeof ( * this ) ) ;
m_nStructVersion = MEMORY_INFORMATION_VERSION ;
}
} ;
// Returns true if the passed in MemoryInformation structure was filled out, otherwise false.
PLATFORM_INTERFACE bool GetMemoryInformation ( MemoryInformation * pOutMemoryInfo ) ;
PLATFORM_INTERFACE float GetCPUUsage ( ) ;
PLATFORM_INTERFACE void GetCurrentDate ( int * pDay , int * pMonth , int * pYear ) ;
// ---------------------------------------------------------------------------------- //
// Performance Monitoring Events - L2 stats etc...
// ---------------------------------------------------------------------------------- //
PLATFORM_INTERFACE void InitPME ( ) ;
PLATFORM_INTERFACE void ShutdownPME ( ) ;
//-----------------------------------------------------------------------------
// Thread related functions
//-----------------------------------------------------------------------------
// Sets a hardware data breakpoint on the given address. Currently Win32-only.
// Specify 1, 2, or 4 bytes for nWatchBytes; pass 0 to unregister the address.
PLATFORM_INTERFACE void Plat_SetHardwareDataBreakpoint ( const void * pAddress , int nWatchBytes , bool bBreakOnRead ) ;
// Apply current hardware data breakpoints to a newly created thread.
PLATFORM_INTERFACE void Plat_ApplyHardwareDataBreakpointsToNewThread ( unsigned long dwThreadID ) ;
//-----------------------------------------------------------------------------
// Process related functions
//-----------------------------------------------------------------------------
PLATFORM_INTERFACE const tchar * Plat_GetCommandLine ( ) ;
# ifndef _WIN32
// helper function for OS's that don't have a ::GetCommandLine() call
PLATFORM_INTERFACE void Plat_SetCommandLine ( const char * cmdLine ) ;
# endif
PLATFORM_INTERFACE const char * Plat_GetCommandLineA ( ) ;
//-----------------------------------------------------------------------------
// Security related functions
//-----------------------------------------------------------------------------
// Ensure that the hardware key's drivers have been installed.
PLATFORM_INTERFACE bool Plat_VerifyHardwareKeyDriver ( ) ;
// Ok, so this isn't a very secure way to verify the hardware key for now. It
// is primarially depending on the fact that all the binaries have been wrapped
// with the secure wrapper provided by the hardware keys vendor.
PLATFORM_INTERFACE bool Plat_VerifyHardwareKey ( ) ;
// The same as above, but notifies user with a message box when the key isn't in
// and gives him an opportunity to correct the situation.
PLATFORM_INTERFACE bool Plat_VerifyHardwareKeyPrompt ( ) ;
// Can be called in real time, doesn't perform the verify every frame. Mainly just
// here to allow the game to drop out quickly when the key is removed, rather than
// allowing the wrapper to pop up it's own blocking dialog, which the engine doesn't
// like much.
PLATFORM_INTERFACE bool Plat_FastVerifyHardwareKey ( ) ;
//-----------------------------------------------------------------------------
// Just logs file and line to simple.log
//-----------------------------------------------------------------------------
PLATFORM_INTERFACE void * Plat_SimpleLog ( const tchar * file , int line ) ;
# if _X360
# define Plat_FastMemset XMemSet
# define Plat_FastMemcpy XMemCpy
# else
# define Plat_FastMemset memset
# define Plat_FastMemcpy memcpy
# endif
//-----------------------------------------------------------------------------
// Returns true if debugger attached, false otherwise
//-----------------------------------------------------------------------------
# if defined(_WIN32) || defined(LINUX) || defined(OSX)
PLATFORM_INTERFACE bool Plat_IsInDebugSession ( ) ;
PLATFORM_INTERFACE void Plat_DebugString ( const char * ) ;
# else
inline bool Plat_IsInDebugSession ( bool bForceRecheck = false ) { return false ; }
# define Plat_DebugString(s) ((void)0)
# endif
//-----------------------------------------------------------------------------
// Returns true if running on a 64 bit (windows) OS
//-----------------------------------------------------------------------------
PLATFORM_INTERFACE bool Is64BitOS ( ) ;
//-----------------------------------------------------------------------------
// XBOX Components valid in PC compilation space
//-----------------------------------------------------------------------------
# define XBOX_DVD_SECTORSIZE 2048
# define XBOX_DVD_ECC_SIZE 32768 // driver reads in quantum ECC blocks
# define XBOX_HDD_SECTORSIZE 512
// Custom windows messages for Xbox input
# define WM_XREMOTECOMMAND (WM_USER + 100)
# define WM_XCONTROLLER_KEY (WM_USER + 101)
# define WM_SYS_UI (WM_USER + 102)
# define WM_SYS_SIGNINCHANGED (WM_USER + 103)
# define WM_SYS_STORAGEDEVICESCHANGED (WM_USER + 104)
# define WM_SYS_PROFILESETTINGCHANGED (WM_USER + 105)
# define WM_SYS_MUTELISTCHANGED (WM_USER + 106)
# define WM_SYS_INPUTDEVICESCHANGED (WM_USER + 107)
# define WM_SYS_INPUTDEVICECONFIGCHANGED (WM_USER + 108)
# define WM_LIVE_CONNECTIONCHANGED (WM_USER + 109)
# define WM_LIVE_INVITE_ACCEPTED (WM_USER + 110)
# define WM_LIVE_LINK_STATE_CHANGED (WM_USER + 111)
# define WM_LIVE_CONTENT_INSTALLED (WM_USER + 112)
# define WM_LIVE_MEMBERSHIP_PURCHASED (WM_USER + 113)
# define WM_LIVE_VOICECHAT_AWAY (WM_USER + 114)
# define WM_LIVE_PRESENCE_CHANGED (WM_USER + 115)
# define WM_FRIENDS_PRESENCE_CHANGED (WM_USER + 116)
# define WM_FRIENDS_FRIEND_ADDED (WM_USER + 117)
# define WM_FRIENDS_FRIEND_REMOVED (WM_USER + 118)
# define WM_CUSTOM_GAMEBANNERPRESSED (WM_USER + 119)
# define WM_CUSTOM_ACTIONPRESSED (WM_USER + 120)
# define WM_XMP_STATECHANGED (WM_USER + 121)
# define WM_XMP_PLAYBACKBEHAVIORCHANGED (WM_USER + 122)
# define WM_XMP_PLAYBACKCONTROLLERCHANGED (WM_USER + 123)
inline const char * GetPlatformExt ( void )
{
return IsX360 ( ) ? " .360 " : " " ;
}
// flat view, 6 hw threads
# define XBOX_PROCESSOR_0 ( 1<<0 )
# define XBOX_PROCESSOR_1 ( 1<<1 )
# define XBOX_PROCESSOR_2 ( 1<<2 )
# define XBOX_PROCESSOR_3 ( 1<<3 )
# define XBOX_PROCESSOR_4 ( 1<<4 )
# define XBOX_PROCESSOR_5 ( 1<<5 )
// core view, 3 cores with 2 hw threads each
# define XBOX_CORE_0_HWTHREAD_0 XBOX_PROCESSOR_0
# define XBOX_CORE_0_HWTHREAD_1 XBOX_PROCESSOR_1
# define XBOX_CORE_1_HWTHREAD_0 XBOX_PROCESSOR_2
# define XBOX_CORE_1_HWTHREAD_1 XBOX_PROCESSOR_3
# define XBOX_CORE_2_HWTHREAD_0 XBOX_PROCESSOR_4
# define XBOX_CORE_2_HWTHREAD_1 XBOX_PROCESSOR_5
//-----------------------------------------------------------------------------
// Include additional dependant header components.
//-----------------------------------------------------------------------------
# include "tier0/fasttimer.h"
# if defined( _X360 )
# include "xbox/xbox_core.h"
# endif
//-----------------------------------------------------------------------------
// Methods to invoke the constructor, copy constructor, and destructor
//-----------------------------------------------------------------------------
template < class T >
inline T * Construct ( T * pMemory )
{
return reinterpret_cast < T * > ( : : new ( pMemory ) T ) ;
}
template < class T , typename ARG1 >
inline T * Construct ( T * pMemory , ARG1 a1 )
{
return reinterpret_cast < T * > ( : : new ( pMemory ) T ( a1 ) ) ;
}
template < class T , typename ARG1 , typename ARG2 >
inline T * Construct ( T * pMemory , ARG1 a1 , ARG2 a2 )
{
return reinterpret_cast < T * > ( : : new ( pMemory ) T ( a1 , a2 ) ) ;
}
template < class T , typename ARG1 , typename ARG2 , typename ARG3 >
inline T * Construct ( T * pMemory , ARG1 a1 , ARG2 a2 , ARG3 a3 )
{
return reinterpret_cast < T * > ( : : new ( pMemory ) T ( a1 , a2 , a3 ) ) ;
}
template < class T , typename ARG1 , typename ARG2 , typename ARG3 , typename ARG4 >
inline T * Construct ( T * pMemory , ARG1 a1 , ARG2 a2 , ARG3 a3 , ARG4 a4 )
{
return reinterpret_cast < T * > ( : : new ( pMemory ) T ( a1 , a2 , a3 , a4 ) ) ;
}
template < class T , typename ARG1 , typename ARG2 , typename ARG3 , typename ARG4 , typename ARG5 >
inline T * Construct ( T * pMemory , ARG1 a1 , ARG2 a2 , ARG3 a3 , ARG4 a4 , ARG5 a5 )
{
return reinterpret_cast < T * > ( : : new ( pMemory ) T ( a1 , a2 , a3 , a4 , a5 ) ) ;
}
template < class T , class P >
inline void ConstructOneArg ( T * pMemory , P const & arg )
{
: : new ( pMemory ) T ( arg ) ;
}
template < class T , class P1 , class P2 >
inline void ConstructTwoArg ( T * pMemory , P1 const & arg1 , P2 const & arg2 )
{
: : new ( pMemory ) T ( arg1 , arg2 ) ;
}
template < class T , class P1 , class P2 , class P3 >
inline void ConstructThreeArg ( T * pMemory , P1 const & arg1 , P2 const & arg2 , P3 const & arg3 )
{
: : new ( pMemory ) T ( arg1 , arg2 , arg3 ) ;
}
template < class T >
inline T * CopyConstruct ( T * pMemory , T const & src )
{
return reinterpret_cast < T * > ( : : new ( pMemory ) T ( src ) ) ;
}
template < class T >
inline void Destruct ( T * pMemory )
{
pMemory - > ~ T ( ) ;
# ifdef _DEBUG
memset ( reinterpret_cast < void * > ( pMemory ) , 0xDD , sizeof ( T ) ) ;
# endif
}
// The above will error when binding to a type of: foo(*)[] -- there is no provision in c++ for knowing how many objects
// to destruct without preserving the count and calling the necessary destructors.
template < class T , size_t N >
inline void Destruct ( T ( * pMemory ) [ N ] )
{
for ( size_t i = 0 ; i < N ; i + + )
{
( pMemory [ i ] ) - > ~ T ( ) ;
}
# ifdef _DEBUG
memset ( reinterpret_cast < void * > ( pMemory ) , 0xDD , sizeof ( * pMemory ) ) ;
# endif
}
//
// GET_OUTER()
//
// A platform-independent way for a contained class to get a pointer to its
// owner. If you know a class is exclusively used in the context of some
// "outer" class, this is a much more space efficient way to get at the outer
// class than having the inner class store a pointer to it.
//
// class COuter
// {
// class CInner // Note: this does not need to be a nested class to work
// {
// void PrintAddressOfOuter()
// {
// printf( "Outer is at 0x%x\n", GET_OUTER( COuter, m_Inner ) );
// }
// };
//
// CInner m_Inner;
// friend class CInner;
// };
# define GET_OUTER( OuterType, OuterMember ) \
( ( OuterType * ) ( ( uint8 * ) this - offsetof ( OuterType , OuterMember ) ) )
/* TEMPLATE_FUNCTION_TABLE()
( Note added to platform . h so platforms that correctly support templated
functions can handle portions as templated functions rather than wrapped
functions )
Helps automate the process of creating an array of function
templates that are all specialized by a single integer .
This sort of thing is often useful in optimization work .
For example , using TEMPLATE_FUNCTION_TABLE , this :
TEMPLATE_FUNCTION_TABLE ( int , Function , ( int blah , int blah ) , 10 )
{
return argument * argument ;
}
is equivilent to the following :
( NOTE : the function has to be wrapped in a class due to code
generation bugs involved with directly specializing a function
based on a constant . )
template < int argument >
class FunctionWrapper
{
public :
int Function ( int blah , int blah )
{
return argument * argument ;
}
}
typedef int ( * FunctionType ) ( int blah , int blah ) ;
class FunctionName
{
public :
enum { count = 10 } ;
FunctionType functions [ 10 ] ;
} ;
FunctionType FunctionName : : functions [ ] =
{
FunctionWrapper < 0 > : : Function ,
FunctionWrapper < 1 > : : Function ,
FunctionWrapper < 2 > : : Function ,
FunctionWrapper < 3 > : : Function ,
FunctionWrapper < 4 > : : Function ,
FunctionWrapper < 5 > : : Function ,
FunctionWrapper < 6 > : : Function ,
FunctionWrapper < 7 > : : Function ,
FunctionWrapper < 8 > : : Function ,
FunctionWrapper < 9 > : : Function
} ;
*/
PLATFORM_INTERFACE bool vtune ( bool resume ) ;
# define TEMPLATE_FUNCTION_TABLE(RETURN_TYPE, NAME, ARGS, COUNT) \
\
typedef RETURN_TYPE ( FASTCALL * __Type_ # # NAME ) ARGS ; \
\
template < const int nArgument > \
struct __Function_ # # NAME \
{ \
static RETURN_TYPE FASTCALL Run ARGS ; \
} ; \
\
template < const int i > \
struct __MetaLooper_ # # NAME : __MetaLooper_ # # NAME < i - 1 > \
{ \
__Type_ # # NAME func ; \
inline __MetaLooper_ # # NAME ( ) { func = __Function_ # # NAME < i > : : Run ; } \
} ; \
\
template < > \
struct __MetaLooper_ # # NAME < 0 > \
{ \
__Type_ # # NAME func ; \
inline __MetaLooper_ # # NAME ( ) { func = __Function_ # # NAME < 0 > : : Run ; } \
} ; \
\
class NAME \
{ \
private : \
static const __MetaLooper_ # # NAME < COUNT > m ; \
public : \
enum { count = COUNT } ; \
static const __Type_ # # NAME * functions ; \
} ; \
const __MetaLooper_ # # NAME < COUNT > NAME : : m ; \
const __Type_ # # NAME * NAME : : functions = ( __Type_ # # NAME * ) & m ; \
template < const int nArgument > \
RETURN_TYPE FASTCALL __Function_ # # NAME < nArgument > : : Run ARGS
# define LOOP_INTERCHANGE(BOOLEAN, CODE)\
if ( ( BOOLEAN ) ) \
{ \
CODE ; \
} else \
{ \
CODE ; \
}
//-----------------------------------------------------------------------------
// Dynamic libs support
//-----------------------------------------------------------------------------
#if 0 // defined( PLATFORM_WINDOWS_PC )
PLATFORM_INTERFACE void * Plat_GetProcAddress ( const char * pszModule , const char * pszName ) ;
template < typename FUNCPTR_TYPE >
class CDynamicFunction
{
public :
CDynamicFunction ( const char * pszModule , const char * pszName , FUNCPTR_TYPE pfnFallback = NULL )
{
m_pfn = pfnFallback ;
void * pAddr = Plat_GetProcAddress ( pszModule , pszName ) ;
if ( pAddr )
{
m_pfn = ( FUNCPTR_TYPE ) pAddr ;
}
}
operator bool ( ) { return m_pfn ! = NULL ; }
bool operator ! ( ) { return ! m_pfn ; }
operator FUNCPTR_TYPE ( ) { return m_pfn ; }
private :
FUNCPTR_TYPE m_pfn ;
} ;
# endif
// Watchdog timer support. Call Plat_BeginWatchdogTimer( nn ) to kick the timer off. if you don't call
// Plat_EndWatchdogTimer within nn seconds, the program will kick off an exception. This is for making
// sure that hung dedicated servers abort (and restart) instead of staying hung. Calling
// Plat_EndWatchdogTimer more than once or when there is no active watchdog is fine. Only does anything
// under linux right now. It should be possible to implement this functionality in windows via a
// thread, if desired.
PLATFORM_INTERFACE void Plat_BeginWatchdogTimer ( int nSecs ) ;
PLATFORM_INTERFACE void Plat_EndWatchdogTimer ( void ) ;
PLATFORM_INTERFACE int Plat_GetWatchdogTime ( void ) ;
typedef void ( * Plat_WatchDogHandlerFunction_t ) ( void ) ;
PLATFORM_INTERFACE void Plat_SetWatchdogHandlerFunction ( Plat_WatchDogHandlerFunction_t function ) ;
//-----------------------------------------------------------------------------
# include "tier0/valve_on.h"
# if defined(TIER0_DLL_EXPORT)
extern " C " int V_tier0_stricmp ( const char * s1 , const char * s2 ) ;
# undef stricmp
# undef strcmpi
# define stricmp(s1,s2) V_tier0_stricmp( s1, s2 )
# define strcmpi(s1,s2) V_tier0_stricmp( s1, s2 )
# endif
# endif /* PLATFORM_H */