winnt.h

winnt.h

https://docs.microsoft.com/en-us/windows/win32/api/winnt/

/*++ BUILD Version: 0091 Increment this if a change has global effects

Copyright (c) Microsoft Corporation. All rights reserved.

Module Name:

winnt.h

Abstract:

This module defines the 32-Bit Windows types and constants that are
defined by NT, but exposed through the Win32 API.

Revision History:

--*/

#ifndef _WINNT_
#define _WINNT_

#if _MSC_VER >= 1200
#pragma warning(push)
#endif
#pragma warning(disable:4201) // named type definition in parentheses
#pragma warning(disable:4214) // bit field types other than int

#ifdef __cplusplus
extern "C" {
#endif

#include <ctype.h>
#define ANYSIZE_ARRAY 1

//
// For compilers that don‘t support nameless unions/structs
//
#ifndef DUMMYUNIONNAME
#if defined(NONAMELESSUNION) || !defined(_MSC_EXTENSIONS)
#define DUMMYUNIONNAME u
#define DUMMYUNIONNAME2 u2
#define DUMMYUNIONNAME3 u3
#define DUMMYUNIONNAME4 u4
#define DUMMYUNIONNAME5 u5
#define DUMMYUNIONNAME6 u6
#define DUMMYUNIONNAME7 u7
#define DUMMYUNIONNAME8 u8
#define DUMMYUNIONNAME9 u9
#else
#define DUMMYUNIONNAME
#define DUMMYUNIONNAME2
#define DUMMYUNIONNAME3
#define DUMMYUNIONNAME4
#define DUMMYUNIONNAME5
#define DUMMYUNIONNAME6
#define DUMMYUNIONNAME7
#define DUMMYUNIONNAME8
#define DUMMYUNIONNAME9
#endif
#endif // DUMMYUNIONNAME

#ifndef DUMMYSTRUCTNAME
#if defined(NONAMELESSUNION) || !defined(_MSC_EXTENSIONS)
#define DUMMYSTRUCTNAME s
#define DUMMYSTRUCTNAME2 s2
#define DUMMYSTRUCTNAME3 s3
#define DUMMYSTRUCTNAME4 s4
#define DUMMYSTRUCTNAME5 s5
#else
#define DUMMYSTRUCTNAME
#define DUMMYSTRUCTNAME2
#define DUMMYSTRUCTNAME3
#define DUMMYSTRUCTNAME4
#define DUMMYSTRUCTNAME5
#endif
#endif // DUMMYSTRUCTNAME

#include <specstrings.h>
#include <kernelspecs.h>

#if defined(STRICT_GS_ENABLED)
#pragma strict_gs_check(push, on)
#endif

#if defined(_M_MRX000) && !(defined(MIDL_PASS) || defined(RC_INVOKED)) && defined(ENABLE_RESTRICTED)
#define RESTRICTED_POINTER __restrict
#else
#define RESTRICTED_POINTER
#endif

#if defined(_M_MRX000) || defined(_M_ALPHA) || defined(_M_PPC) || defined(_M_IA64) || defined(_M_AMD64)
#define ALIGNMENT_MACHINE
#define UNALIGNED __unaligned
#if defined(_WIN64)
#define UNALIGNED64 __unaligned
#else
#define UNALIGNED64
#endif
#else
#undef ALIGNMENT_MACHINE
#define UNALIGNED
#define UNALIGNED64
#endif


#if defined(_WIN64) || defined(_M_ALPHA)
#define MAX_NATURAL_ALIGNMENT sizeof(ULONGLONG)
#define MEMORY_ALLOCATION_ALIGNMENT 16
#else
#define MAX_NATURAL_ALIGNMENT sizeof(DWORD)
#define MEMORY_ALLOCATION_ALIGNMENT 8
#endif

//
// TYPE_ALIGNMENT will return the alignment requirements of a given type for
// the current platform.
//

#ifdef __cplusplus
#if _MSC_VER >= 1300
#define TYPE_ALIGNMENT( t ) __alignof(t)
#endif
#else
#define TYPE_ALIGNMENT( t ) \
FIELD_OFFSET( struct { char x; t test; }, test )
#endif

#if defined(_WIN64)

#if defined(_AMD64_)
#define PROBE_ALIGNMENT( _s ) TYPE_ALIGNMENT( DWORD )
#elif defined(_IA64_)
#define PROBE_ALIGNMENT( _s ) (TYPE_ALIGNMENT( _s ) > TYPE_ALIGNMENT( DWORD ) ? \
TYPE_ALIGNMENT( _s ) : TYPE_ALIGNMENT( DWORD ))
#else
#error "No Target Architecture"
#endif

#define PROBE_ALIGNMENT32( _s ) TYPE_ALIGNMENT( DWORD )

#else

#define PROBE_ALIGNMENT( _s ) TYPE_ALIGNMENT( DWORD )

#endif

//
// C_ASSERT() can be used to perform many compile-time assertions:
// type sizes, field offsets, etc.
//
// An assertion failure results in error C2118: negative subscript.
//

#ifndef SORTPP_PASS
#define C_ASSERT(e) typedef char __C_ASSERT__[(e)?1:-1]
#else
#define C_ASSERT(e) /* nothing */
#endif

#include <basetsd.h>


#if (defined(_M_IX86) || defined(_M_IA64) || defined(_M_AMD64)) && !defined(MIDL_PASS)
#define DECLSPEC_IMPORT __declspec(dllimport)
#else
#define DECLSPEC_IMPORT
#endif

#ifndef DECLSPEC_NORETURN
#if (_MSC_VER >= 1200) && !defined(MIDL_PASS)
#define DECLSPEC_NORETURN __declspec(noreturn)
#else
#define DECLSPEC_NORETURN
#endif
#endif

#ifndef DECLSPEC_NOTHROW
#if (_MSC_VER >= 1200) && !defined(MIDL_PASS)
#define DECLSPEC_NOTHROW __declspec(nothrow)
#else
#define DECLSPEC_NOTHROW
#endif
#endif

#ifndef DECLSPEC_ALIGN
#if (_MSC_VER >= 1300) && !defined(MIDL_PASS)
#define DECLSPEC_ALIGN(x) __declspec(align(x))
#else
#define DECLSPEC_ALIGN(x)
#endif
#endif

#ifndef SYSTEM_CACHE_ALIGNMENT_SIZE
#if defined(_AMD64_) || defined(_X86_)
#define SYSTEM_CACHE_ALIGNMENT_SIZE 64
#else
#define SYSTEM_CACHE_ALIGNMENT_SIZE 128
#endif
#endif

#ifndef DECLSPEC_CACHEALIGN
#define DECLSPEC_CACHEALIGN DECLSPEC_ALIGN(SYSTEM_CACHE_ALIGNMENT_SIZE)
#endif

#ifndef DECLSPEC_UUID
#if (_MSC_VER >= 1100) && defined (__cplusplus)
#define DECLSPEC_UUID(x) __declspec(uuid(x))
#else
#define DECLSPEC_UUID(x)
#endif
#endif

#ifndef DECLSPEC_NOVTABLE
#if (_MSC_VER >= 1100) && defined(__cplusplus)
#define DECLSPEC_NOVTABLE __declspec(novtable)
#else
#define DECLSPEC_NOVTABLE
#endif
#endif

#ifndef DECLSPEC_SELECTANY
#if (_MSC_VER >= 1100)
#define DECLSPEC_SELECTANY __declspec(selectany)
#else
#define DECLSPEC_SELECTANY
#endif
#endif

#ifndef NOP_FUNCTION
#if (_MSC_VER >= 1210)
#define NOP_FUNCTION __noop
#else
#define NOP_FUNCTION (void)0
#endif
#endif

#ifndef DECLSPEC_ADDRSAFE
#if (_MSC_VER >= 1200) && (defined(_M_ALPHA) || defined(_M_AXP64))
#define DECLSPEC_ADDRSAFE __declspec(address_safe)
#else
#define DECLSPEC_ADDRSAFE
#endif
#endif

#ifndef DECLSPEC_NOINLINE
#if (_MSC_VER >= 1300)
#define DECLSPEC_NOINLINE __declspec(noinline)
#else
#define DECLSPEC_NOINLINE
#endif
#endif

#ifndef FORCEINLINE
#if (_MSC_VER >= 1200)
#define FORCEINLINE __forceinline
#else
#define FORCEINLINE __inline
#endif
#endif

#ifndef DECLSPEC_DEPRECATED
#if (_MSC_VER >= 1300) && !defined(MIDL_PASS)
#define DECLSPEC_DEPRECATED __declspec(deprecated)
#define DEPRECATE_SUPPORTED
#else
#define DECLSPEC_DEPRECATED
#undef DEPRECATE_SUPPORTED
#endif
#endif

#ifdef DEPRECATE_DDK_FUNCTIONS
#ifdef _NTDDK_
#define DECLSPEC_DEPRECATED_DDK DECLSPEC_DEPRECATED
#ifdef DEPRECATE_SUPPORTED
#define PRAGMA_DEPRECATED_DDK 1
#endif
#else
#define DECLSPEC_DEPRECATED_DDK
#define PRAGMA_DEPRECATED_DDK 1
#endif
#else
#define DECLSPEC_DEPRECATED_DDK
#define PRAGMA_DEPRECATED_DDK 0
#endif

//
// Void
//

typedef void *PVOID;
typedef void * POINTER_64 PVOID64;


#if (_MSC_VER >= 800) || defined(_STDCALL_SUPPORTED)
#define NTAPI __stdcall
#else
#define _cdecl
#define __cdecl
#define NTAPI
#endif

#if !defined(_M_CEE_PURE)
#define NTAPI_INLINE NTAPI
#else
#define NTAPI_INLINE
#endif

//
// Define API decoration for direct importing system DLL references.
//

#if !defined(_NTSYSTEM_)
#define NTSYSAPI DECLSPEC_IMPORT
#define NTSYSCALLAPI DECLSPEC_IMPORT
#else
#define NTSYSAPI
#if defined(_NTDLLBUILD_)
#define NTSYSCALLAPI
#else
#define NTSYSCALLAPI DECLSPEC_ADDRSAFE
#endif

#endif


//
// Basics
//

#ifndef VOID
#define VOID void
typedef char CHAR;
typedef short SHORT;
typedef long LONG;
#if !defined(MIDL_PASS)
typedef int INT;
#endif
#endif

//
// UNICODE (Wide Character) types
//

#ifndef _MAC
typedef wchar_t WCHAR; // wc, 16-bit UNICODE character
#else
// some Macintosh compilers don‘t define wchar_t in a convenient location, or define it as a char
typedef unsigned short WCHAR; // wc, 16-bit UNICODE character
#endif

typedef WCHAR *PWCHAR, *LPWCH, *PWCH;
typedef CONST WCHAR *LPCWCH, *PCWCH;

typedef __nullterminated WCHAR *NWPSTR, *LPWSTR, *PWSTR;
typedef __nullterminated PWSTR *PZPWSTR;
typedef __nullterminated CONST PWSTR *PCZPWSTR;
typedef __nullterminated WCHAR UNALIGNED *LPUWSTR, *PUWSTR;
typedef __nullterminated CONST WCHAR *LPCWSTR, *PCWSTR;
typedef __nullterminated PCWSTR *PZPCWSTR;
typedef __nullterminated CONST WCHAR UNALIGNED *LPCUWSTR, *PCUWSTR;

typedef __nullnullterminated WCHAR *PZZWSTR;
typedef __nullnullterminated CONST WCHAR *PCZZWSTR;
typedef __nullnullterminated WCHAR UNALIGNED *PUZZWSTR;
typedef __nullnullterminated CONST WCHAR UNALIGNED *PCUZZWSTR;

typedef __possibly_notnullterminated WCHAR *PNZWCH;
typedef __possibly_notnullterminated CONST WCHAR *PCNZWCH;
typedef __possibly_notnullterminated WCHAR UNALIGNED *PUNZWCH;
typedef __possibly_notnullterminated CONST WCHAR UNALIGNED *PCUNZWCH;

#if _WIN32_WINNT >= 0x0600 || (defined(__cplusplus) && defined(WINDOWS_ENABLE_CPLUSPLUS))

typedef CONST WCHAR *LPCWCHAR, *PCWCHAR;
typedef CONST WCHAR UNALIGNED *LPCUWCHAR, *PCUWCHAR;

//
// UCS (Universal Character Set) types
//

typedef unsigned long UCSCHAR;

//
// Even pre-Unicode agreement, UCS values are always in the
// range U+00000000 to U+7FFFFFFF, so we‘ll pick an obvious
// value.

#define UCSCHAR_INVALID_CHARACTER (0xffffffff)

#define MIN_UCSCHAR (0)

//
// We‘ll assume here that the ISO-10646 / Unicode agreement
// not to assign code points after U+0010FFFF holds so that
// we do not have to have separate "UCSCHAR" and "UNICODECHAR"
// types.
//

#define MAX_UCSCHAR (0x0010FFFF)

typedef UCSCHAR *PUCSCHAR;
typedef const UCSCHAR *PCUCSCHAR;

typedef UCSCHAR *PUCSSTR;
typedef UCSCHAR UNALIGNED *PUUCSSTR;

typedef const UCSCHAR *PCUCSSTR;
typedef const UCSCHAR UNALIGNED *PCUUCSSTR;

typedef UCSCHAR UNALIGNED *PUUCSCHAR;
typedef const UCSCHAR UNALIGNED *PCUUCSCHAR;

#endif // _WIN32_WINNT >= 0x0600


//
// ANSI (Multi-byte Character) types
//
typedef CHAR *PCHAR, *LPCH, *PCH;
typedef CONST CHAR *LPCCH, *PCCH;

typedef __nullterminated CHAR *NPSTR, *LPSTR, *PSTR;
typedef __nullterminated PSTR *PZPSTR;
typedef __nullterminated CONST PSTR *PCZPSTR;
typedef __nullterminated CONST CHAR *LPCSTR, *PCSTR;
typedef __nullterminated PCSTR *PZPCSTR;

typedef __nullnullterminated CHAR *PZZSTR;
typedef __nullnullterminated CONST CHAR *PCZZSTR;

typedef __possibly_notnullterminated CHAR *PNZCH;
typedef __possibly_notnullterminated CONST CHAR *PCNZCH;

//
// Neutral ANSI/UNICODE types and macros
//
#ifdef UNICODE // r_winnt

#ifndef _TCHAR_DEFINED
typedef WCHAR TCHAR, *PTCHAR;
typedef WCHAR TBYTE , *PTBYTE ;
#define _TCHAR_DEFINED
#endif /* !_TCHAR_DEFINED */

typedef LPWCH LPTCH, PTCH;
typedef LPCWCH LPCTCH, PCTCH;
typedef LPWSTR PTSTR, LPTSTR;
typedef LPCWSTR PCTSTR, LPCTSTR;
typedef LPUWSTR PUTSTR, LPUTSTR;
typedef LPCUWSTR PCUTSTR, LPCUTSTR;
typedef LPWSTR LP;
typedef PZZWSTR PZZTSTR;
typedef PCZZWSTR PCZZTSTR;
typedef PUZZWSTR PUZZTSTR;
typedef PCUZZWSTR PCUZZTSTR;
typedef PNZWCH PNZTCH;
typedef PCNZWCH PCNZTCH;
typedef PUNZWCH PUNZTCH;
typedef PCUNZWCH PCUNZTCH;
#define __TEXT(quote) L##quote // r_winnt

#else /* UNICODE */ // r_winnt

#ifndef _TCHAR_DEFINED
typedef char TCHAR, *PTCHAR;
typedef unsigned char TBYTE , *PTBYTE ;
#define _TCHAR_DEFINED
#endif /* !_TCHAR_DEFINED */

typedef LPCH LPTCH, PTCH;
typedef LPCCH LPCTCH, PCTCH;
typedef LPSTR PTSTR, LPTSTR, PUTSTR, LPUTSTR;
typedef LPCSTR PCTSTR, LPCTSTR, PCUTSTR, LPCUTSTR;
typedef PZZSTR PZZTSTR, PUZZTSTR;
typedef PCZZSTR PCZZTSTR, PCUZZTSTR;
typedef PNZCH PNZTCH, PUNZTCH;
typedef PCNZCH PCNZTCH, PCUNZTCH;
#define __TEXT(quote) quote // r_winnt

#endif /* UNICODE */ // r_winnt
#define TEXT(quote) __TEXT(quote) // r_winnt


typedef SHORT *PSHORT;
typedef LONG *PLONG;

#define ALL_PROCESSOR_GROUPS 0xffff

//
// Structure to represent a system wide processor number. It contains a
// group number and relative processor number within the group.
//

typedef struct _PROCESSOR_NUMBER {
WORD Group;
BYTE Number;
BYTE Reserved;
} PROCESSOR_NUMBER, *PPROCESSOR_NUMBER;

//
// Structure to represent a group-specific affinity, such as that of a
// thread. Specifies the group number and the affinity within that group.
//

typedef struct _GROUP_AFFINITY {
KAFFINITY Mask;
WORD Group;
WORD Reserved[3];
} GROUP_AFFINITY, *PGROUP_AFFINITY;

//
// Handle to an Object
//

#ifdef STRICT
typedef void *HANDLE;
#if 0 && (_MSC_VER > 1000)
#define DECLARE_HANDLE(name) struct name##__; typedef struct name##__ *name
#else
#define DECLARE_HANDLE(name) struct name##__{int unused;}; typedef struct name##__ *name
#endif
#else
typedef PVOID HANDLE;
#define DECLARE_HANDLE(name) typedef HANDLE name
#endif
typedef HANDLE *PHANDLE;

//
// Flag (bit) fields
//

typedef BYTE FCHAR;
typedef WORD FSHORT;
typedef DWORD FLONG;

// Component Object Model defines, and macros

#ifndef _HRESULT_DEFINED
#define _HRESULT_DEFINED
#ifdef __midl
typedef LONG HRESULT;
#else
typedef __success(return >= 0) long HRESULT;
#endif // __midl
#endif // !_HRESULT_DEFINED

#ifdef __cplusplus
#define EXTERN_C extern "C"
#else
#define EXTERN_C extern
#endif

#if defined(_WIN32) || defined(_MPPC_)

// Win32 doesn‘t support __export

#ifdef _68K_
#define STDMETHODCALLTYPE __cdecl
#else
#define STDMETHODCALLTYPE __stdcall
#endif
#define STDMETHODVCALLTYPE __cdecl

#define STDAPICALLTYPE __stdcall
#define STDAPIVCALLTYPE __cdecl

#else

#define STDMETHODCALLTYPE __export __stdcall
#define STDMETHODVCALLTYPE __export __cdecl

#define STDAPICALLTYPE __export __stdcall
#define STDAPIVCALLTYPE __export __cdecl

#endif


#define STDAPI EXTERN_C HRESULT STDAPICALLTYPE
#define STDAPI_(type) EXTERN_C type STDAPICALLTYPE

#define STDMETHODIMP HRESULT STDMETHODCALLTYPE
#define STDMETHODIMP_(type) type STDMETHODCALLTYPE

#define STDOVERRIDEMETHODIMP __override STDMETHODIMP
#define STDOVERRIDEMETHODIMP_(type) __override STDMETHODIMP_(type)

#define IFACEMETHODIMP __override STDMETHODIMP
#define IFACEMETHODIMP_(type) __override STDMETHODIMP_(type)

// The ‘V‘ versions allow Variable Argument lists.

#define STDAPIV EXTERN_C HRESULT STDAPIVCALLTYPE
#define STDAPIV_(type) EXTERN_C type STDAPIVCALLTYPE

#define STDMETHODIMPV HRESULT STDMETHODVCALLTYPE
#define STDMETHODIMPV_(type) type STDMETHODVCALLTYPE

#define STDOVERRIDEMETHODIMPV __override STDMETHODIMPV
#define STDOVERRIDEMETHODIMPV_(type) __override STDMETHODIMPV_(type)

#define IFACEMETHODIMPV __override STDMETHODIMPV
#define IFACEMETHODIMPV_(type) __override STDMETHODIMPV_(type)

typedef char CCHAR;
typedef DWORD LCID;
typedef PDWORD PLCID;
typedef WORD LANGID;
#define APPLICATION_ERROR_MASK 0x20000000
#define ERROR_SEVERITY_SUCCESS 0x00000000
#define ERROR_SEVERITY_INFORMATIONAL 0x40000000
#define ERROR_SEVERITY_WARNING 0x80000000
#define ERROR_SEVERITY_ERROR 0xC0000000

//
// _M_IX86 included so that EM CONTEXT structure compiles with
// x86 programs. *** TBD should this be for all architectures?
//

//
// 16 byte aligned type for 128 bit floats
//

//
// For we define a 128 bit structure and use __declspec(align(16)) pragma to
// align to 128 bits.
//

#if defined(_M_IA64) && !defined(MIDL_PASS)
__declspec(align(16))
#endif
typedef struct _FLOAT128 {
__int64 LowPart;
__int64 HighPart;
} FLOAT128;

typedef FLOAT128 *PFLOAT128;


//
// __int64 is only supported by 2.0 and later midl.
// __midl is set by the 2.0 midl and not by 1.0 midl.
//

#define _ULONGLONG_
#if (!defined (_MAC) && (!defined(MIDL_PASS) || defined(__midl)) && (!defined(_M_IX86) || (defined(_INTEGRAL_MAX_BITS) && _INTEGRAL_MAX_BITS >= 64)))
typedef __int64 LONGLONG;
typedef unsigned __int64 ULONGLONG;

#define MAXLONGLONG (0x7fffffffffffffff)


#else

#if defined(_MAC) && defined(_MAC_INT_64)
typedef __int64 LONGLONG;
typedef unsigned __int64 ULONGLONG;

#define MAXLONGLONG (0x7fffffffffffffff)


#else
typedef double LONGLONG;
typedef double ULONGLONG;
#endif //_MAC and int64

#endif

typedef LONGLONG *PLONGLONG;
typedef ULONGLONG *PULONGLONG;

// Update Sequence Number

typedef LONGLONG USN;

#if defined(MIDL_PASS)
typedef struct _LARGE_INTEGER {
#else // MIDL_PASS
typedef union _LARGE_INTEGER {
struct {
DWORD LowPart;
LONG HighPart;
} DUMMYSTRUCTNAME;
struct {
DWORD LowPart;
LONG HighPart;
} u;
#endif //MIDL_PASS
LONGLONG QuadPart;
} LARGE_INTEGER;

typedef LARGE_INTEGER *PLARGE_INTEGER;

#if defined(MIDL_PASS)
typedef struct _ULARGE_INTEGER {
#else // MIDL_PASS
typedef union _ULARGE_INTEGER {
struct {
DWORD LowPart;
DWORD HighPart;
} DUMMYSTRUCTNAME;
struct {
DWORD LowPart;
DWORD HighPart;
} u;
#endif //MIDL_PASS
ULONGLONG QuadPart;
} ULARGE_INTEGER;

typedef ULARGE_INTEGER *PULARGE_INTEGER;

// end_ntminiport end_ntndis end_ntminitape


//
// Locally Unique Identifier
//

typedef struct _LUID {
DWORD LowPart;
LONG HighPart;
} LUID, *PLUID;

#define _DWORDLONG_
typedef ULONGLONG DWORDLONG;
typedef DWORDLONG *PDWORDLONG;


//
// Define operations to logically shift an int64 by 0..31 bits and to multiply
// 32-bits by 32-bits to form a 64-bit product.
//

#if defined(MIDL_PASS) || defined(RC_INVOKED) || defined(_M_CEE_PURE) \
|| defined(_68K_) || defined(_MPPC_) \
|| defined(_M_IA64) || defined(_M_AMD64)

//
// Midl does not understand inline assembler. Therefore, the Rtl functions
// are used for shifts by 0..31 and multiplies of 32-bits times 32-bits to
// form a 64-bit product.
//
//
// IA64 and AMD64 have native 64-bit operations that are just as fast as their
// 32-bit counter parts. Therefore, the int64 data type is used directly to form
// shifts of 0..31 and multiplies of 32-bits times 32-bits to form a 64-bit
// product.
//

#define Int32x32To64(a, b) (((__int64)((long)(a))) * ((__int64)((long)(b))))
#define UInt32x32To64(a, b) (((unsigned __int64)((unsigned int)(a))) * ((unsigned __int64)((unsigned int)(b))))

#define Int64ShllMod32(a, b) (((unsigned __int64)(a)) << (b))
#define Int64ShraMod32(a, b) (((__int64)(a)) >> (b))
#define Int64ShrlMod32(a, b) (((unsigned __int64)(a)) >> (b))


#elif defined(_M_IX86)

//
// The x86 C compiler understands inline assembler. Therefore, inline functions
// that employ inline assembler are used for shifts of 0..31. The multiplies
// rely on the compiler recognizing the cast of the multiplicand to int64 to
// generate the optimal code inline.
//

#define Int32x32To64(a, b) ((__int64)(((__int64)((long)(a))) * ((long)(b))))
#define UInt32x32To64(a, b) ((unsigned __int64)(((unsigned __int64)((unsigned int)(a))) * ((unsigned int)(b))))


ULONGLONG
NTAPI
Int64ShllMod32 (
__in ULONGLONG Value,
__in DWORD ShiftCount
);

LONGLONG
NTAPI
Int64ShraMod32 (
__in LONGLONG Value,
__in DWORD ShiftCount
);

ULONGLONG
NTAPI
Int64ShrlMod32 (
__in ULONGLONG Value,
__in DWORD ShiftCount
);

#if _MSC_VER >= 1200
#pragma warning(push)
#endif
#pragma warning(disable:4035 4793) // re-enable below

__inline ULONGLONG
NTAPI
Int64ShllMod32 (
__in ULONGLONG Value,
__in DWORD ShiftCount
)
{
__asm {
mov ecx, ShiftCount
mov eax, dword ptr [Value]
mov edx, dword ptr [Value+4]
shld edx, eax, cl
shl eax, cl
}
}

__inline LONGLONG
NTAPI
Int64ShraMod32 (
__in LONGLONG Value,
__in DWORD ShiftCount
)
{
__asm {
mov ecx, ShiftCount
mov eax, dword ptr [Value]
mov edx, dword ptr [Value+4]
shrd eax, edx, cl
sar edx, cl
}
}

__inline ULONGLONG
NTAPI
Int64ShrlMod32 (
__in ULONGLONG Value,
__in DWORD ShiftCount
)
{
__asm {
mov ecx, ShiftCount
mov eax, dword ptr [Value]
mov edx, dword ptr [Value+4]
shrd eax, edx, cl
shr edx, cl
}
}

#if _MSC_VER >= 1200
#pragma warning(pop)
#else
#pragma warning(default:4035 4793)
#endif

#else

#error Must define a target architecture.

#endif

//
// Define rotate intrinsics.
//

#ifdef __cplusplus
extern "C" {
#endif

#if defined(_M_AMD64)

#define RotateLeft8 _rotl8
#define RotateLeft16 _rotl16
#define RotateRight8 _rotr8
#define RotateRight16 _rotr16

unsigned char
__cdecl
_rotl8 (
__in unsigned char Value,
__in unsigned char Shift
);

unsigned short
__cdecl
_rotl16 (
__in unsigned short Value,
__in unsigned char Shift
);

unsigned char
__cdecl
_rotr8 (
__in unsigned char Value,
__in unsigned char Shift
);

unsigned short
__cdecl
_rotr16 (
__in unsigned short Value,
__in unsigned char Shift
);

#pragma intrinsic(_rotl8)
#pragma intrinsic(_rotl16)
#pragma intrinsic(_rotr8)
#pragma intrinsic(_rotr16)

#endif /* _M_AMD64 */

#if _MSC_VER >= 1300

#define RotateLeft32 _rotl
#define RotateLeft64 _rotl64
#define RotateRight32 _rotr
#define RotateRight64 _rotr64

__checkReturn
unsigned int
__cdecl
_rotl (
__in unsigned int Value,
__in int Shift
);

__checkReturn
unsigned __int64
__cdecl
_rotl64 (
__in unsigned __int64 Value,
__in int Shift
);

__checkReturn
unsigned int
__cdecl
_rotr (
__in unsigned int Value,
__in int Shift
);

__checkReturn
unsigned __int64
__cdecl
_rotr64 (
__in unsigned __int64 Value,
__in int Shift
);

#pragma intrinsic(_rotl)
#pragma intrinsic(_rotl64)
#pragma intrinsic(_rotr)
#pragma intrinsic(_rotr64)

#endif /* _MSC_VER >= 1300 */

#ifdef __cplusplus
}
#endif

#define ANSI_NULL ((CHAR)0)
#define UNICODE_NULL ((WCHAR)0)
#define UNICODE_STRING_MAX_BYTES ((WORD ) 65534)
#define UNICODE_STRING_MAX_CHARS (32767)
typedef BYTE BOOLEAN;
typedef BOOLEAN *PBOOLEAN;
//
// Doubly linked list structure. Can be used as either a list head, or
// as link words.
//

typedef struct _LIST_ENTRY {
struct _LIST_ENTRY *Flink;
struct _LIST_ENTRY *Blink;
} LIST_ENTRY, *PLIST_ENTRY, *RESTRICTED_POINTER PRLIST_ENTRY;

//
// Singly linked list structure. Can be used as either a list head, or
// as link words.
//

typedef struct _SINGLE_LIST_ENTRY {
struct _SINGLE_LIST_ENTRY *Next;
} SINGLE_LIST_ENTRY, *PSINGLE_LIST_ENTRY;


//
// These are needed for portable debugger support.
//

typedef struct LIST_ENTRY32 {
DWORD Flink;
DWORD Blink;
} LIST_ENTRY32;
typedef LIST_ENTRY32 *PLIST_ENTRY32;

typedef struct LIST_ENTRY64 {
ULONGLONG Flink;
ULONGLONG Blink;
} LIST_ENTRY64;
typedef LIST_ENTRY64 *PLIST_ENTRY64;


#include <guiddef.h>

#ifndef __OBJECTID_DEFINED
#define __OBJECTID_DEFINED

typedef struct _OBJECTID { // size is 20
GUID Lineage;
DWORD Uniquifier;
} OBJECTID;
#endif // !_OBJECTID_DEFINED

#define MINCHAR 0x80
#define MAXCHAR 0x7f
#define MINSHORT 0x8000
#define MAXSHORT 0x7fff
#define MINLONG 0x80000000
#define MAXLONG 0x7fffffff
#define MAXBYTE 0xff
#define MAXWORD 0xffff
#define MAXDWORD 0xffffffff
//
// Calculate the byte offset of a field in a structure of type type.
//

#define FIELD_OFFSET(type, field) ((LONG)(LONG_PTR)&(((type *)0)->field))

//
// Calculate the size of a field in a structure of type type, without
// knowing or stating the type of the field.
//
#define RTL_FIELD_SIZE(type, field) (sizeof(((type *)0)->field))

//
// Calculate the size of a structure of type type up through and
// including a field.
//
#define RTL_SIZEOF_THROUGH_FIELD(type, field) \
(FIELD_OFFSET(type, field) + RTL_FIELD_SIZE(type, field))

//
// RTL_CONTAINS_FIELD usage:
//
// if (RTL_CONTAINS_FIELD(pBlock, pBlock->cbSize, dwMumble)) { // safe to use pBlock->dwMumble
//
#define RTL_CONTAINS_FIELD(Struct, Size, Field) \
( (((PCHAR)(&(Struct)->Field)) + sizeof((Struct)->Field)) <= (((PCHAR)(Struct))+(Size)) )

//
// Return the number of elements in a statically sized array.
// DWORD Buffer[100];
// RTL_NUMBER_OF(Buffer) == 100
// This is also popularly known as: NUMBER_OF, ARRSIZE, _countof, NELEM, etc.
//
#define RTL_NUMBER_OF_V1(A) (sizeof(A)/sizeof((A)[0]))

#if defined(__cplusplus) && \
!defined(MIDL_PASS) && \
!defined(RC_INVOKED) && \
!defined(_PREFAST_) && \
(_MSC_FULL_VER >= 13009466) && \
!defined(SORTPP_PASS)
//
// RtlpNumberOf is a function that takes a reference to an array of N Ts.
//
// typedef T array_of_T[N];
// typedef array_of_T &reference_to_array_of_T;
//
// RtlpNumberOf returns a pointer to an array of N chars.
// We could return a reference instead of a pointer but older compilers do not accept that.
//
// typedef char array_of_char[N];
// typedef array_of_char *pointer_to_array_of_char;
//
// sizeof(array_of_char) == N
// sizeof(*pointer_to_array_of_char) == N
//
// pointer_to_array_of_char RtlpNumberOf(reference_to_array_of_T);
//
// We never even call RtlpNumberOf, we just take the size of dereferencing its return type.
// We do not even implement RtlpNumberOf, we just decare it.
//
// Attempts to pass pointers instead of arrays to this macro result in compile time errors.
// That is the point.
//
extern "C++" // templates cannot be declared to have ‘C‘ linkage
template <typename T, size_t N>
char (*RtlpNumberOf( UNALIGNED T (&)[N] ))[N];

#define RTL_NUMBER_OF_V2(A) (sizeof(*RtlpNumberOf(A)))

//
// This does not work with:
//
// void Foo()
// {
// struct { int x; } y[2];
// RTL_NUMBER_OF_V2(y); // illegal use of anonymous local type in template instantiation
// }
//
// You must instead do:
//
// struct Foo1 { int x; };
//
// void Foo()
// {
// Foo1 y[2];
// RTL_NUMBER_OF_V2(y); // ok
// }
//
// OR
//
// void Foo()
// {
// struct { int x; } y[2];
// RTL_NUMBER_OF_V1(y); // ok
// }
//
// OR
//
// void Foo()
// {
// struct { int x; } y[2];
// _ARRAYSIZE(y); // ok
// }
//

#else
#define RTL_NUMBER_OF_V2(A) RTL_NUMBER_OF_V1(A)
#endif

#ifdef ENABLE_RTL_NUMBER_OF_V2
#define RTL_NUMBER_OF(A) RTL_NUMBER_OF_V2(A)
#else
#define RTL_NUMBER_OF(A) RTL_NUMBER_OF_V1(A)
#endif

//
// ARRAYSIZE is more readable version of RTL_NUMBER_OF_V2, and uses
// it regardless of ENABLE_RTL_NUMBER_OF_V2
//
// _ARRAYSIZE is a version useful for anonymous types
//
#define ARRAYSIZE(A) RTL_NUMBER_OF_V2(A)
#define _ARRAYSIZE(A) RTL_NUMBER_OF_V1(A)

//
// An expression that yields the type of a field in a struct.
//
#define RTL_FIELD_TYPE(type, field) (((type*)0)->field)

// RTL_ to avoid collisions in the global namespace.
//
// Given typedef struct _FOO { BYTE Bar[123]; } FOO;
// RTL_NUMBER_OF_FIELD(FOO, Bar) == 123
//
#define RTL_NUMBER_OF_FIELD(type, field) (RTL_NUMBER_OF(RTL_FIELD_TYPE(type, field)))

//
// eg:
// typedef struct FOO {
// DWORD Integer;
// PVOID Pointer;
// } FOO;
//
// RTL_PADDING_BETWEEN_FIELDS(FOO, Integer, Pointer) == 0 for Win32, 4 for Win64
//
#define RTL_PADDING_BETWEEN_FIELDS(T, F1, F2) \
((FIELD_OFFSET(T, F2) > FIELD_OFFSET(T, F1)) \
? (FIELD_OFFSET(T, F2) - FIELD_OFFSET(T, F1) - RTL_FIELD_SIZE(T, F1)) \
: (FIELD_OFFSET(T, F1) - FIELD_OFFSET(T, F2) - RTL_FIELD_SIZE(T, F2)))

// RTL_ to avoid collisions in the global namespace.
#if defined(__cplusplus)
#define RTL_CONST_CAST(type) const_cast<type>
#else
#define RTL_CONST_CAST(type) (type)
#endif


// like sizeof
// usually this would be * CHAR_BIT, but we don‘t necessarily have #include <limits.h>
#define RTL_BITS_OF(sizeOfArg) (sizeof(sizeOfArg) * 8)

#define RTL_BITS_OF_FIELD(type, field) (RTL_BITS_OF(RTL_FIELD_TYPE(type, field)))

//
// Calculate the address of the base of the structure given its type, and an
// address of a field within the structure.
//

#define CONTAINING_RECORD(address, type, field) ((type *)( \
(PCHAR)(address) - \
(ULONG_PTR)(&((type *)0)->field)))

// end_ntminiport end_ntndis

//
// Exception handler routine definition.
//

#include <excpt.h>

typedef
__drv_sameIRQL
__drv_functionClass(EXCEPTION_ROUTINE)
EXCEPTION_DISPOSITION
NTAPI
EXCEPTION_ROUTINE (
__inout struct _EXCEPTION_RECORD *ExceptionRecord,
__in PVOID EstablisherFrame,
__inout struct _CONTEXT *ContextRecord,
__in PVOID DispatcherContext
);

typedef EXCEPTION_ROUTINE *PEXCEPTION_ROUTINE;


#define VER_SERVER_NT 0x80000000
#define VER_WORKSTATION_NT 0x40000000
#define VER_SUITE_SMALLBUSINESS 0x00000001
#define VER_SUITE_ENTERPRISE 0x00000002
#define VER_SUITE_BACKOFFICE 0x00000004
#define VER_SUITE_COMMUNICATIONS 0x00000008
#define VER_SUITE_TERMINAL 0x00000010
#define VER_SUITE_SMALLBUSINESS_RESTRICTED 0x00000020
#define VER_SUITE_EMBEDDEDNT 0x00000040
#define VER_SUITE_DATACENTER 0x00000080
#define VER_SUITE_SINGLEUSERTS 0x00000100
#define VER_SUITE_PERSONAL 0x00000200
#define VER_SUITE_BLADE 0x00000400
#define VER_SUITE_EMBEDDED_RESTRICTED 0x00000800
#define VER_SUITE_SECURITY_APPLIANCE 0x00001000
#define VER_SUITE_STORAGE_SERVER 0x00002000
#define VER_SUITE_COMPUTE_SERVER 0x00004000
#define VER_SUITE_WH_SERVER 0x00008000


//
// Product types
// This list grows with each OS release.
//
// There is no ordering of values to ensure callers
// do an equality test i.e. greater-than and less-than
// comparisons are not useful.
//
// NOTE: Values in this list should never be deleted.
// When a product-type ‘X‘ gets dropped from a
// OS release onwards, the value of ‘X‘ continues
// to be used in the mapping table of GetProductInfo.
//

#define PRODUCT_UNDEFINED 0x00000000

#define PRODUCT_ULTIMATE 0x00000001
#define PRODUCT_HOME_BASIC 0x00000002
#define PRODUCT_HOME_PREMIUM 0x00000003
#define PRODUCT_ENTERPRISE 0x00000004
#define PRODUCT_HOME_BASIC_N 0x00000005
#define PRODUCT_BUSINESS 0x00000006
#define PRODUCT_STANDARD_SERVER 0x00000007
#define PRODUCT_DATACENTER_SERVER 0x00000008
#define PRODUCT_SMALLBUSINESS_SERVER 0x00000009
#define PRODUCT_ENTERPRISE_SERVER 0x0000000A
#define PRODUCT_STARTER 0x0000000B
#define PRODUCT_DATACENTER_SERVER_CORE 0x0000000C
#define PRODUCT_STANDARD_SERVER_CORE 0x0000000D
#define PRODUCT_ENTERPRISE_SERVER_CORE 0x0000000E
#define PRODUCT_ENTERPRISE_SERVER_IA64 0x0000000F
#define PRODUCT_BUSINESS_N 0x00000010
#define PRODUCT_WEB_SERVER 0x00000011
#define PRODUCT_CLUSTER_SERVER 0x00000012
#define PRODUCT_HOME_SERVER 0x00000013
#define PRODUCT_STORAGE_EXPRESS_SERVER 0x00000014
#define PRODUCT_STORAGE_STANDARD_SERVER 0x00000015
#define PRODUCT_STORAGE_WORKGROUP_SERVER 0x00000016
#define PRODUCT_STORAGE_ENTERPRISE_SERVER 0x00000017
#define PRODUCT_SERVER_FOR_SMALLBUSINESS 0x00000018
#define PRODUCT_SMALLBUSINESS_SERVER_PREMIUM 0x00000019
#define PRODUCT_HOME_PREMIUM_N 0x0000001A
#define PRODUCT_ENTERPRISE_N 0x0000001B
#define PRODUCT_ULTIMATE_N 0x0000001C
#define PRODUCT_WEB_SERVER_CORE 0x0000001D
#define PRODUCT_MEDIUMBUSINESS_SERVER_MANAGEMENT 0x0000001E
#define PRODUCT_MEDIUMBUSINESS_SERVER_SECURITY 0x0000001F
#define PRODUCT_MEDIUMBUSINESS_SERVER_MESSAGING 0x00000020
#define PRODUCT_SERVER_FOUNDATION 0x00000021
#define PRODUCT_HOME_PREMIUM_SERVER 0x00000022
#define PRODUCT_SERVER_FOR_SMALLBUSINESS_V 0x00000023
#define PRODUCT_STANDARD_SERVER_V 0x00000024
#define PRODUCT_DATACENTER_SERVER_V 0x00000025
#define PRODUCT_ENTERPRISE_SERVER_V 0x00000026
#define PRODUCT_DATACENTER_SERVER_CORE_V 0x00000027
#define PRODUCT_STANDARD_SERVER_CORE_V 0x00000028
#define PRODUCT_ENTERPRISE_SERVER_CORE_V 0x00000029
#define PRODUCT_HYPERV 0x0000002A
#define PRODUCT_STORAGE_EXPRESS_SERVER_CORE 0x0000002B
#define PRODUCT_STORAGE_STANDARD_SERVER_CORE 0x0000002C
#define PRODUCT_STORAGE_WORKGROUP_SERVER_CORE 0x0000002D
#define PRODUCT_STORAGE_ENTERPRISE_SERVER_CORE 0x0000002E
#define PRODUCT_STARTER_N 0x0000002F
#define PRODUCT_PROFESSIONAL 0x00000030
#define PRODUCT_PROFESSIONAL_N 0x00000031
#define PRODUCT_SB_SOLUTION_SERVER 0x00000032
#define PRODUCT_SERVER_FOR_SB_SOLUTIONS 0x00000033
#define PRODUCT_STANDARD_SERVER_SOLUTIONS 0x00000034
#define PRODUCT_STANDARD_SERVER_SOLUTIONS_CORE 0x00000035
#define PRODUCT_SB_SOLUTION_SERVER_EM 0x00000036
#define PRODUCT_SERVER_FOR_SB_SOLUTIONS_EM 0x00000037
#define PRODUCT_SOLUTION_EMBEDDEDSERVER 0x00000038
#define PRODUCT_SOLUTION_EMBEDDEDSERVER_CORE 0x00000039
#define PRODUCT_SMALLBUSINESS_SERVER_PREMIUM_CORE 0x0000003F
#define PRODUCT_ESSENTIALBUSINESS_SERVER_MGMT 0x0000003B
#define PRODUCT_ESSENTIALBUSINESS_SERVER_ADDL 0x0000003C
#define PRODUCT_ESSENTIALBUSINESS_SERVER_MGMTSVC 0x0000003D
#define PRODUCT_ESSENTIALBUSINESS_SERVER_ADDLSVC 0x0000003E
#define PRODUCT_CLUSTER_SERVER_V 0x00000040
#define PRODUCT_EMBEDDED 0x00000041
#define PRODUCT_STARTER_E 0x00000042
#define PRODUCT_HOME_BASIC_E 0x00000043
#define PRODUCT_HOME_PREMIUM_E 0x00000044
#define PRODUCT_PROFESSIONAL_E 0x00000045
#define PRODUCT_ENTERPRISE_E 0x00000046
#define PRODUCT_ULTIMATE_E 0x00000047

#define PRODUCT_UNLICENSED 0xABCDABCD

#include <sdkddkver.h>

//
// Language IDs.
//
// Note that the named locale APIs (eg GetLocaleInfoEx) are preferred.
//
// Not all locales have unique Language IDs
//
// The following two combinations of primary language ID and
// sublanguage ID have special semantics:
//
// Primary Language ID Sublanguage ID Result
// ------------------- --------------- ------------------------
// LANG_NEUTRAL SUBLANG_NEUTRAL Language neutral
// LANG_NEUTRAL SUBLANG_DEFAULT User default language
// LANG_NEUTRAL SUBLANG_SYS_DEFAULT System default language
// LANG_INVARIANT SUBLANG_NEUTRAL Invariant locale
//
// It is recommended that applications test for locale names instead of
// Language IDs / LCIDs.

//
// Primary language IDs.
//
// WARNING: These aren‘t always unique. Bosnian, Serbian & Croation for example.
//
// It is recommended that applications test for locale names or actual LCIDs.
//
// Note that the LANG, SUBLANG construction is not always consistent.
// The named locale APIs (eg GetLocaleInfoEx) are recommended.
//
#define LANG_NEUTRAL 0x00
#define LANG_INVARIANT 0x7f

#define LANG_AFRIKAANS 0x36
#define LANG_ALBANIAN 0x1c
#define LANG_ALSATIAN 0x84
#define LANG_AMHARIC 0x5e
#define LANG_ARABIC 0x01
#define LANG_ARMENIAN 0x2b
#define LANG_ASSAMESE 0x4d
#define LANG_AZERI 0x2c
#define LANG_BASHKIR 0x6d
#define LANG_BASQUE 0x2d
#define LANG_BELARUSIAN 0x23
#define LANG_BENGALI 0x45
#define LANG_BRETON 0x7e
#define LANG_BOSNIAN 0x1a // Use with SUBLANG_BOSNIAN_* Sublanguage IDs
#define LANG_BOSNIAN_NEUTRAL 0x781a // Use with the ConvertDefaultLocale function
#define LANG_BULGARIAN 0x02
#define LANG_CATALAN 0x03
#define LANG_CHINESE 0x04 // Use with SUBLANG_CHINESE_* Sublanguage IDs
#define LANG_CHINESE_SIMPLIFIED 0x04 // Use with the ConvertDefaultLocale function
#define LANG_CHINESE_TRADITIONAL 0x7c04 // Use with the ConvertDefaultLocale function
#define LANG_CORSICAN 0x83
#define LANG_CROATIAN 0x1a
#define LANG_CZECH 0x05
#define LANG_DANISH 0x06
#define LANG_DARI 0x8c
#define LANG_DIVEHI 0x65
#define LANG_DUTCH 0x13
#define LANG_ENGLISH 0x09
#define LANG_ESTONIAN 0x25
#define LANG_FAEROESE 0x38
#define LANG_FARSI 0x29 // Deprecated: use LANG_PERSIAN instead
#define LANG_FILIPINO 0x64
#define LANG_FINNISH 0x0b
#define LANG_FRENCH 0x0c
#define LANG_FRISIAN 0x62
#define LANG_GALICIAN 0x56
#define LANG_GEORGIAN 0x37
#define LANG_GERMAN 0x07
#define LANG_GREEK 0x08
#define LANG_GREENLANDIC 0x6f
#define LANG_GUJARATI 0x47
#define LANG_HAUSA 0x68
#define LANG_HEBREW 0x0d
#define LANG_HINDI 0x39
#define LANG_HUNGARIAN 0x0e
#define LANG_ICELANDIC 0x0f
#define LANG_IGBO 0x70
#define LANG_INDONESIAN 0x21
#define LANG_INUKTITUT 0x5d
#define LANG_IRISH 0x3c // Use with the SUBLANG_IRISH_IRELAND Sublanguage ID
#define LANG_ITALIAN 0x10
#define LANG_JAPANESE 0x11
#define LANG_KANNADA 0x4b
#define LANG_KASHMIRI 0x60
#define LANG_KAZAK 0x3f
#define LANG_KHMER 0x53
#define LANG_KICHE 0x86
#define LANG_KINYARWANDA 0x87
#define LANG_KONKANI 0x57
#define LANG_KOREAN 0x12
#define LANG_KYRGYZ 0x40
#define LANG_LAO 0x54
#define LANG_LATVIAN 0x26
#define LANG_LITHUANIAN 0x27
#define LANG_LOWER_SORBIAN 0x2e
#define LANG_LUXEMBOURGISH 0x6e
#define LANG_MACEDONIAN 0x2f // the Former Yugoslav Republic of Macedonia
#define LANG_MALAY 0x3e
#define LANG_MALAYALAM 0x4c
#define LANG_MALTESE 0x3a
#define LANG_MANIPURI 0x58
#define LANG_MAORI 0x81
#define LANG_MAPUDUNGUN 0x7a
#define LANG_MARATHI 0x4e
#define LANG_MOHAWK 0x7c
#define LANG_*N 0x50
#define LANG_NEPALI 0x61
#define LANG_NORWEGIAN 0x14
#define LANG_OCCITAN 0x82
#define LANG_ORIYA 0x48
#define LANG_PASHTO 0x63
#define LANG_PERSIAN 0x29
#define LANG_POLISH 0x15
#define LANG_PORTUGUESE 0x16
#define LANG_PUNJABI 0x46
#define LANG_QUECHUA 0x6b
#define LANG_ROMANIAN 0x18
#define LANG_ROMANSH 0x17
#define LANG_RUSSIAN 0x19
#define LANG_SAMI 0x3b
#define LANG_SANSKRIT 0x4f
#define LANG_SCOTTISH_GAELIC 0x91
#define LANG_SERBIAN 0x1a // Use with the SUBLANG_SERBIAN_* Sublanguage IDs
#define LANG_SERBIAN_NEUTRAL 0x7c1a // Use with the ConvertDefaultLocale function
#define LANG_SINDHI 0x59
#define LANG_SINHALESE 0x5b
#define LANG_SLOVAK 0x1b
#define LANG_SLOVENIAN 0x24
#define LANG_SOTHO 0x6c
#define LANG_SPANISH 0x0a
#define LANG_SWAHILI 0x41
#define LANG_SWEDISH 0x1d
#define LANG_SYRIAC 0x5a
#define LANG_TAJIK 0x28
#define LANG_TAMAZIGHT 0x5f
#define LANG_TAMIL 0x49
#define LANG_TATAR 0x44
#define LANG_TELUGU 0x4a
#define LANG_THAI 0x1e
#define LANG_* 0x51
#define LANG_TIGRIGNA 0x73
#define LANG_TSWANA 0x32
#define LANG_TURKISH 0x1f
#define LANG_TURKMEN 0x42
#define LANG_UIGHUR 0x80
#define LANG_UKRAINIAN 0x22
#define LANG_UPPER_SORBIAN 0x2e
#define LANG_URDU 0x20
#define LANG_UZBEK 0x43
#define LANG_VIETNAMESE 0x2a
#define LANG_WELSH 0x52
#define LANG_WOLOF 0x88
#define LANG_XHOSA 0x34
#define LANG_YAKUT 0x85
#define LANG_YI 0x78
#define LANG_YORUBA 0x6a
#define LANG_ZULU 0x35

//
// Sublanguage IDs.
//
// The name immediately following SUBLANG_ dictates which primary
// language ID that sublanguage ID can be combined with to form a
// valid language ID.
//
// Note that the LANG, SUBLANG construction is not always consistent.
// The named locale APIs (eg GetLocaleInfoEx) are recommended.
//

#define SUBLANG_NEUTRAL 0x00 // language neutral
#define SUBLANG_DEFAULT 0x01 // user default
#define SUBLANG_SYS_DEFAULT 0x02 // system default
#define SUBLANG_CUSTOM_DEFAULT 0x03 // default custom language/locale
#define SUBLANG_CUSTOM_UNSPECIFIED 0x04 // custom language/locale
#define SUBLANG_UI_CUSTOM_DEFAULT 0x05 // Default custom MUI language/locale


#define SUBLANG_AFRIKAANS_SOUTH_AFRICA 0x01 // Afrikaans (South Africa) 0x0436 af-ZA
#define SUBLANG_ALBANIAN_ALBANIA 0x01 // Albanian (Albania) 0x041c sq-AL
#define SUBLANG_ALSATIAN_FRANCE 0x01 // Alsatian (France) 0x0484
#define SUBLANG_AMHARIC_ETHIOPIA 0x01 // Amharic (Ethiopia) 0x045e
#define SUBLANG_ARABIC_SAUDI_ARABIA 0x01 // Arabic (Saudi Arabia)
#define SUBLANG_ARABIC_IRAQ 0x02 // Arabic (Iraq)
#define SUBLANG_ARABIC_EGYPT 0x03 // Arabic (Egypt)
#define SUBLANG_ARABIC_LIBYA 0x04 // Arabic (Libya)
#define SUBLANG_ARABIC_ALGERIA 0x05 // Arabic (Algeria)
#define SUBLANG_ARABIC_MOROCCO 0x06 // Arabic (Morocco)
#define SUBLANG_ARABIC_TUNISIA 0x07 // Arabic (Tunisia)
#define SUBLANG_ARABIC_OMAN 0x08 // Arabic (Oman)
#define SUBLANG_ARABIC_YEMEN 0x09 // Arabic (Yemen)
#define SUBLANG_ARABIC_SYRIA 0x0a // Arabic (Syria)
#define SUBLANG_ARABIC_JORDAN 0x0b // Arabic (Jordan)
#define SUBLANG_ARABIC_LEBANON 0x0c // Arabic (Lebanon)
#define SUBLANG_ARABIC_KUWAIT 0x0d // Arabic (Kuwait)
#define SUBLANG_ARABIC_UAE 0x0e // Arabic (U.A.E)
#define SUBLANG_ARABIC_BAHRAIN 0x0f // Arabic (Bahrain)
#define SUBLANG_ARABIC_QATAR 0x10 // Arabic (Qatar)
#define SUBLANG_ARMENIAN_ARMENIA 0x01 // Armenian (Armenia) 0x042b hy-AM
#define SUBLANG_ASSAMESE_INDIA 0x01 // Assamese (India) 0x044d
#define SUBLANG_AZERI_LATIN 0x01 // Azeri (Latin)
#define SUBLANG_AZERI_CYRILLIC 0x02 // Azeri (Cyrillic)
#define SUBLANG_BASHKIR_RUSSIA 0x01 // Bashkir (Russia) 0x046d ba-RU
#define SUBLANG_BASQUE_BASQUE 0x01 // Basque (Basque) 0x042d eu-ES
#define SUBLANG_BELARUSIAN_BELARUS 0x01 // Belarusian (Belarus) 0x0423 be-BY
#define SUBLANG_BENGALI_INDIA 0x01 // Bengali (India)
#define SUBLANG_BENGALI_BANGLADESH 0x02 // Bengali (Bangladesh)
#define SUBLANG_BOSNIAN_BOSNIA_HERZEGOVINA_LATIN 0x05 // Bosnian (Bosnia and Herzegovina - Latin) 0x141a bs-BA-Latn
#define SUBLANG_BOSNIAN_BOSNIA_HERZEGOVINA_CYRILLIC 0x08 // Bosnian (Bosnia and Herzegovina - Cyrillic) 0x201a bs-BA-Cyrl
#define SUBLANG_BRETON_FRANCE 0x01 // Breton (France) 0x047e
#define SUBLANG_BULGARIAN_BULGARIA 0x01 // Bulgarian (Bulgaria) 0x0402
#define SUBLANG_CATALAN_CATALAN 0x01 // Catalan (Catalan) 0x0403
#define SUBLANG_CHINESE_TRADITIONAL 0x01 // Chinese (*) 0x0404 zh-TW
#define SUBLANG_CHINESE_SIMPLIFIED 0x02 // Chinese (PR China) 0x0804 zh-CN
#define SUBLANG_CHINESE_HONGKONG 0x03 // Chinese (* S.A.R., P.R.C.) 0x0c04 zh-HK
#define SUBLANG_CHINESE_SINGAPORE 0x04 // Chinese (Singapore) 0x1004 zh-SG
#define SUBLANG_CHINESE_MACAU 0x05 // Chinese (Macau S.A.R.) 0x1404 zh-MO
#define SUBLANG_CORSICAN_FRANCE 0x01 // Corsican (France) 0x0483
#define SUBLANG_CZECH_CZECH_REPUBLIC 0x01 // Czech (Czech Republic) 0x0405
#define SUBLANG_CROATIAN_CROATIA 0x01 // Croatian (Croatia)
#define SUBLANG_CROATIAN_BOSNIA_HERZEGOVINA_LATIN 0x04 // Croatian (Bosnia and Herzegovina - Latin) 0x101a hr-BA
#define SUBLANG_DANISH_DENMARK 0x01 // Danish (Denmark) 0x0406
#define SUBLANG_DARI_AFGHANISTAN 0x01 // Dari (Afghanistan)
#define SUBLANG_DIVEHI_MALDIVES 0x01 // Divehi (Maldives) 0x0465 div-MV
#define SUBLANG_DUTCH 0x01 // Dutch
#define SUBLANG_DUTCH_BELGIAN 0x02 // Dutch (Belgian)
#define SUBLANG_ENGLISH_US 0x01 // English (USA)
#define SUBLANG_ENGLISH_UK 0x02 // English (UK)
#define SUBLANG_ENGLISH_AUS 0x03 // English (Australian)
#define SUBLANG_ENGLISH_CAN 0x04 // English (Canadian)
#define SUBLANG_ENGLISH_NZ 0x05 // English (New Zealand)
#define SUBLANG_ENGLISH_EIRE 0x06 // English (Irish)
#define SUBLANG_ENGLISH_SOUTH_AFRICA 0x07 // English (South Africa)
#define SUBLANG_ENGLISH_JAMAICA 0x08 // English (Jamaica)
#define SUBLANG_ENGLISH_CARIBBEAN 0x09 // English (Caribbean)
#define SUBLANG_ENGLISH_BELIZE 0x0a // English (Belize)
#define SUBLANG_ENGLISH_TRINIDAD 0x0b // English (Trinidad)
#define SUBLANG_ENGLISH_ZIMBABWE 0x0c // English (Zimbabwe)
#define SUBLANG_ENGLISH_PHILIPPINES 0x0d // English (Philippines)
#define SUBLANG_ENGLISH_INDIA 0x10 // English (India)
#define SUBLANG_ENGLISH_MALAYSIA 0x11 // English (Malaysia)
#define SUBLANG_ENGLISH_SINGAPORE 0x12 // English (Singapore)
#define SUBLANG_ESTONIAN_ESTONIA 0x01 // Estonian (Estonia) 0x0425 et-EE
#define SUBLANG_FAEROESE_FAROE_ISLANDS 0x01 // Faroese (Faroe Islands) 0x0438 fo-FO
#define SUBLANG_FILIPINO_PHILIPPINES 0x01 // Filipino (Philippines) 0x0464 fil-PH
#define SUBLANG_FINNISH_FINLAND 0x01 // Finnish (Finland) 0x040b
#define SUBLANG_FRENCH 0x01 // French
#define SUBLANG_FRENCH_BELGIAN 0x02 // French (Belgian)
#define SUBLANG_FRENCH_CANADIAN 0x03 // French (Canadian)
#define SUBLANG_FRENCH_SWISS 0x04 // French (Swiss)
#define SUBLANG_FRENCH_LUXEMBOURG 0x05 // French (Luxembourg)
#define SUBLANG_FRENCH_MONACO 0x06 // French (Monaco)
#define SUBLANG_FRISIAN_NETHERLANDS 0x01 // Frisian (Netherlands) 0x0462 fy-NL
#define SUBLANG_GALICIAN_GALICIAN 0x01 // Galician (Galician) 0x0456 gl-ES
#define SUBLANG_GEORGIAN_GEORGIA 0x01 // Georgian (Georgia) 0x0437 ka-GE
#define SUBLANG_GERMAN 0x01 // German
#define SUBLANG_GERMAN_SWISS 0x02 // German (Swiss)
#define SUBLANG_GERMAN_AUSTRIAN 0x03 // German (Austrian)
#define SUBLANG_GERMAN_LUXEMBOURG 0x04 // German (Luxembourg)
#define SUBLANG_GERMAN_LIECHTENSTEIN 0x05 // German (Liechtenstein)
#define SUBLANG_GREEK_GREECE 0x01 // Greek (Greece)
#define SUBLANG_GREENLANDIC_GREENLAND 0x01 // Greenlandic (Greenland) 0x046f kl-GL
#define SUBLANG_GUJARATI_INDIA 0x01 // Gujarati (India (Gujarati Script)) 0x0447 gu-IN
#define SUBLANG_HAUSA_NIGERIA_LATIN 0x01 // Hausa (Latin, Nigeria) 0x0468 ha-NG-Latn
#define SUBLANG_HEBREW_ISRAEL 0x01 // Hebrew (Israel) 0x040d
#define SUBLANG_HINDI_INDIA 0x01 // Hindi (India) 0x0439 hi-IN
#define SUBLANG_HUNGARIAN_HUNGARY 0x01 // Hungarian (Hungary) 0x040e
#define SUBLANG_ICELANDIC_ICELAND 0x01 // Icelandic (Iceland) 0x040f
#define SUBLANG_IGBO_NIGERIA 0x01 // Igbo (Nigeria) 0x0470 ig-NG
#define SUBLANG_INDONESIAN_INDONESIA 0x01 // Indonesian (Indonesia) 0x0421 id-ID
#define SUBLANG_INUKTITUT_CANADA 0x01 // Inuktitut (Syllabics) (Canada) 0x045d iu-CA-Cans
#define SUBLANG_INUKTITUT_CANADA_LATIN 0x02 // Inuktitut (Canada - Latin)
#define SUBLANG_IRISH_IRELAND 0x02 // Irish (Ireland)
#define SUBLANG_ITALIAN 0x01 // Italian
#define SUBLANG_ITALIAN_SWISS 0x02 // Italian (Swiss)
#define SUBLANG_JAPANESE_JAPAN 0x01 // Japanese (Japan) 0x0411
#define SUBLANG_KANNADA_INDIA 0x01 // Kannada (India (Kannada Script)) 0x044b kn-IN
#define SUBLANG_KASHMIRI_SASIA 0x02 // Kashmiri (South Asia)
#define SUBLANG_KASHMIRI_INDIA 0x02 // For app compatibility only
#define SUBLANG_KAZAK_KAZAKHSTAN 0x01 // Kazakh (Kazakhstan) 0x043f kk-KZ
#define SUBLANG_KHMER_CAMBODIA 0x01 // Khmer (Cambodia) 0x0453 kh-KH
#define SUBLANG_KICHE_GUATEMALA 0x01 // K‘iche (Guatemala)
#define SUBLANG_KINYARWANDA_RWANDA 0x01 // Kinyarwanda (Rwanda) 0x0487 rw-RW
#define SUBLANG_KONKANI_INDIA 0x01 // Konkani (India) 0x0457 kok-IN
#define SUBLANG_KOREAN 0x01 // Korean (Extended Wansung)
#define SUBLANG_KYRGYZ_KYRGYZSTAN 0x01 // Kyrgyz (Kyrgyzstan) 0x0440 ky-KG
#define SUBLANG_LAO_LAO 0x01 // Lao (Lao PDR) 0x0454 lo-LA
#define SUBLANG_LATVIAN_LATVIA 0x01 // Latvian (Latvia) 0x0426 lv-LV
#define SUBLANG_LITHUANIAN 0x01 // Lithuanian
#define SUBLANG_LOWER_SORBIAN_GERMANY 0x02 // Lower Sorbian (Germany) 0x082e wee-DE
#define SUBLANG_LUXEMBOURGISH_LUXEMBOURG 0x01 // Luxembourgish (Luxembourg) 0x046e lb-LU
#define SUBLANG_MACEDONIAN_MACEDONIA 0x01 // Macedonian (Macedonia (FYROM)) 0x042f mk-MK
#define SUBLANG_MALAY_MALAYSIA 0x01 // Malay (Malaysia)
#define SUBLANG_MALAY_BRUNEI_DARUSSALAM 0x02 // Malay (Brunei Darussalam)
#define SUBLANG_MALAYALAM_INDIA 0x01 // Malayalam (India (Malayalam Script) ) 0x044c ml-IN
#define SUBLANG_MALTESE_MALTA 0x01 // Maltese (Malta) 0x043a mt-MT
#define SUBLANG_MAORI_NEW_ZEALAND 0x01 // Maori (New Zealand) 0x0481 mi-NZ
#define SUBLANG_MAPUDUNGUN_CHILE 0x01 // Mapudungun (Chile) 0x047a arn-CL
#define SUBLANG_MARATHI_INDIA 0x01 // Marathi (India) 0x044e mr-IN
#define SUBLANG_MOHAWK_MOHAWK 0x01 // Mohawk (Mohawk) 0x047c moh-CA
#define SUBLANG_*N_CYRILLIC_* 0x01 // *n (Cyrillic, *)
#define SUBLANG_*N_PRC 0x02 // *n (PRC)
#define SUBLANG_NEPALI_INDIA 0x02 // Nepali (India)
#define SUBLANG_NEPALI_NEPAL 0x01 // Nepali (Nepal) 0x0461 ne-NP
#define SUBLANG_NORWEGIAN_BOKMAL 0x01 // Norwegian (Bokmal)
#define SUBLANG_NORWEGIAN_NYNORSK 0x02 // Norwegian (Nynorsk)
#define SUBLANG_OCCITAN_FRANCE 0x01 // Occitan (France) 0x0482 oc-FR
#define SUBLANG_ORIYA_INDIA 0x01 // Oriya (India (Oriya Script)) 0x0448 or-IN
#define SUBLANG_PASHTO_AFGHANISTAN 0x01 // Pashto (Afghanistan)
#define SUBLANG_PERSIAN_IRAN 0x01 // Persian (Iran) 0x0429 fa-IR
#define SUBLANG_POLISH_POLAND 0x01 // Polish (Poland) 0x0415
#define SUBLANG_PORTUGUESE 0x02 // Portuguese
#define SUBLANG_PORTUGUESE_BRAZILIAN 0x01 // Portuguese (Brazilian)
#define SUBLANG_PUNJABI_INDIA 0x01 // Punjabi (India (Gurmukhi Script)) 0x0446 pa-IN
#define SUBLANG_QUECHUA_BOLIVIA 0x01 // Quechua (Bolivia)
#define SUBLANG_QUECHUA_ECUADOR 0x02 // Quechua (Ecuador)
#define SUBLANG_QUECHUA_PERU 0x03 // Quechua (Peru)
#define SUBLANG_ROMANIAN_ROMANIA 0x01 // Romanian (Romania) 0x0418
#define SUBLANG_ROMANSH_SWITZERLAND 0x01 // Romansh (Switzerland) 0x0417 rm-CH
#define SUBLANG_RUSSIAN_RUSSIA 0x01 // Russian (Russia) 0x0419
#define SUBLANG_SAMI_NORTHERN_NORWAY 0x01 // Northern Sami (Norway)
#define SUBLANG_SAMI_NORTHERN_SWEDEN 0x02 // Northern Sami (Sweden)
#define SUBLANG_SAMI_NORTHERN_FINLAND 0x03 // Northern Sami (Finland)
#define SUBLANG_SAMI_LULE_NORWAY 0x04 // Lule Sami (Norway)
#define SUBLANG_SAMI_LULE_SWEDEN 0x05 // Lule Sami (Sweden)
#define SUBLANG_SAMI_SOUTHERN_NORWAY 0x06 // Southern Sami (Norway)
#define SUBLANG_SAMI_SOUTHERN_SWEDEN 0x07 // Southern Sami (Sweden)
#define SUBLANG_SAMI_SKOLT_FINLAND 0x08 // Skolt Sami (Finland)
#define SUBLANG_SAMI_INARI_FINLAND 0x09 // Inari Sami (Finland)
#define SUBLANG_SANSKRIT_INDIA 0x01 // Sanskrit (India) 0x044f sa-IN
#define SUBLANG_SCOTTISH_GAELIC 0x01 // Scottish Gaelic (United Kingdom) 0x0491 gd-GB
#define SUBLANG_SERBIAN_BOSNIA_HERZEGOVINA_LATIN 0x06 // Serbian (Bosnia and Herzegovina - Latin)
#define SUBLANG_SERBIAN_BOSNIA_HERZEGOVINA_CYRILLIC 0x07 // Serbian (Bosnia and Herzegovina - Cyrillic)
#define SUBLANG_SERBIAN_MONTENEGRO_LATIN 0x0b // Serbian (Montenegro - Latn)
#define SUBLANG_SERBIAN_MONTENEGRO_CYRILLIC 0x0c // Serbian (Montenegro - Cyrillic)
#define SUBLANG_SERBIAN_SERBIA_LATIN 0x09 // Serbian (Serbia - Latin)
#define SUBLANG_SERBIAN_SERBIA_CYRILLIC 0x0a // Serbian (Serbia - Cyrillic)
#define SUBLANG_SERBIAN_CROATIA 0x01 // Croatian (Croatia) 0x041a hr-HR
#define SUBLANG_SERBIAN_LATIN 0x02 // Serbian (Latin)
#define SUBLANG_SERBIAN_CYRILLIC 0x03 // Serbian (Cyrillic)
#define SUBLANG_SINDHI_INDIA 0x01 // Sindhi (India) reserved 0x0459
#define SUBLANG_SINDHI_PAKISTAN 0x02 // Sindhi (Pakistan) reserved 0x0859
#define SUBLANG_SINDHI_AFGHANISTAN 0x02 // For app compatibility only
#define SUBLANG_SINHALESE_SRI_LANKA 0x01 // Sinhalese (Sri Lanka)
#define SUBLANG_SOTHO_NORTHERN_SOUTH_AFRICA 0x01 // Northern Sotho (South Africa)
#define SUBLANG_SLOVAK_SLOVAKIA 0x01 // Slovak (Slovakia) 0x041b sk-SK
#define SUBLANG_SLOVENIAN_SLOVENIA 0x01 // Slovenian (Slovenia) 0x0424 sl-SI
#define SUBLANG_SPANISH 0x01 // Spanish (Castilian)
#define SUBLANG_SPANISH_MEXICAN 0x02 // Spanish (Mexican)
#define SUBLANG_SPANISH_MODERN 0x03 // Spanish (Modern)
#define SUBLANG_SPANISH_GUATEMALA 0x04 // Spanish (Guatemala)
#define SUBLANG_SPANISH_COSTA_RICA 0x05 // Spanish (Costa Rica)
#define SUBLANG_SPANISH_PANAMA 0x06 // Spanish (Panama)
#define SUBLANG_SPANISH_DOMINICAN_REPUBLIC 0x07 // Spanish (Dominican Republic)
#define SUBLANG_SPANISH_VENEZUELA 0x08 // Spanish (Venezuela)
#define SUBLANG_SPANISH_COLOMBIA 0x09 // Spanish (Colombia)
#define SUBLANG_SPANISH_PERU 0x0a // Spanish (Peru)
#define SUBLANG_SPANISH_ARGENTINA 0x0b // Spanish (Argentina)
#define SUBLANG_SPANISH_ECUADOR 0x0c // Spanish (Ecuador)
#define SUBLANG_SPANISH_CHILE 0x0d // Spanish (Chile)
#define SUBLANG_SPANISH_URUGUAY 0x0e // Spanish (Uruguay)
#define SUBLANG_SPANISH_PARAGUAY 0x0f // Spanish (Paraguay)
#define SUBLANG_SPANISH_BOLIVIA 0x10 // Spanish (Bolivia)
#define SUBLANG_SPANISH_EL_SALVADOR 0x11 // Spanish (El Salvador)
#define SUBLANG_SPANISH_HONDURAS 0x12 // Spanish (Honduras)
#define SUBLANG_SPANISH_NICARAGUA 0x13 // Spanish (Nicaragua)
#define SUBLANG_SPANISH_PUERTO_RICO 0x14 // Spanish (Puerto Rico)
#define SUBLANG_SPANISH_US 0x15 // Spanish (United States)
#define SUBLANG_SWAHILI_KENYA 0x01 // Swahili (Kenya) 0x0441 sw-KE
#define SUBLANG_SWEDISH 0x01 // Swedish
#define SUBLANG_SWEDISH_FINLAND 0x02 // Swedish (Finland)
#define SUBLANG_SYRIAC_SYRIA 0x01 // Syriac (Syria) 0x045a syr-SY
#define SUBLANG_TAJIK_TAJIKISTAN 0x01 // Tajik (Tajikistan) 0x0428 tg-TJ-Cyrl
#define SUBLANG_TAMAZIGHT_ALGERIA_LATIN 0x02 // Tamazight (Latin, Algeria) 0x085f tmz-DZ-Latn
#define SUBLANG_TAMIL_INDIA 0x01 // Tamil (India)
#define SUBLANG_TATAR_RUSSIA 0x01 // Tatar (Russia) 0x0444 tt-RU
#define SUBLANG_TELUGU_INDIA 0x01 // Telugu (India (Telugu Script)) 0x044a te-IN
#define SUBLANG_THAI_THAILAND 0x01 // Thai (Thailand) 0x041e th-TH
#define SUBLANG_*_PRC 0x01 // * (PRC)
#define SUBLANG_TIGRIGNA_ERITREA 0x02 // Tigrigna (Eritrea)
#define SUBLANG_TSWANA_SOUTH_AFRICA 0x01 // Setswana / Tswana (South Africa) 0x0432 tn-ZA
#define SUBLANG_TURKISH_TURKEY 0x01 // Turkish (Turkey) 0x041f tr-TR
#define SUBLANG_TURKMEN_TURKMENISTAN 0x01 // Turkmen (Turkmenistan) 0x0442 tk-TM
#define SUBLANG_UIGHUR_PRC 0x01 // Uighur (PRC) 0x0480 ug-CN
#define SUBLANG_UKRAINIAN_UKRAINE 0x01 // Ukrainian (Ukraine) 0x0422 uk-UA
#define SUBLANG_UPPER_SORBIAN_GERMANY 0x01 // Upper Sorbian (Germany) 0x042e wen-DE
#define SUBLANG_URDU_PAKISTAN 0x01 // Urdu (Pakistan)
#define SUBLANG_URDU_INDIA 0x02 // Urdu (India)
#define SUBLANG_UZBEK_LATIN 0x01 // Uzbek (Latin)
#define SUBLANG_UZBEK_CYRILLIC 0x02 // Uzbek (Cyrillic)
#define SUBLANG_VIETNAMESE_VIETNAM 0x01 // Vietnamese (Vietnam) 0x042a vi-VN
#define SUBLANG_WELSH_UNITED_KINGDOM 0x01 // Welsh (United Kingdom) 0x0452 cy-GB
#define SUBLANG_WOLOF_SENEGAL 0x01 // Wolof (Senegal)
#define SUBLANG_XHOSA_SOUTH_AFRICA 0x01 // isiXhosa / Xhosa (South Africa) 0x0434 xh-ZA
#define SUBLANG_YAKUT_RUSSIA 0x01 // Yakut (Russia) 0x0485 sah-RU
#define SUBLANG_YI_PRC 0x01 // Yi (PRC)) 0x0478
#define SUBLANG_YORUBA_NIGERIA 0x01 // Yoruba (Nigeria) 046a yo-NG
#define SUBLANG_ZULU_SOUTH_AFRICA 0x01 // isiZulu / Zulu (South Africa) 0x0435 zu-ZA

 


//
// Sorting IDs.
//
// Note that the named locale APIs (eg CompareStringExEx) are recommended.
//

#define SORT_DEFAULT 0x0 // sorting default

#define SORT_INVARIANT_MATH 0x1 // Invariant (Mathematical Symbols)

#define SORT_JAPANESE_XJIS 0x0 // Japanese XJIS order
#define SORT_JAPANESE_UNICODE 0x1 // Japanese Unicode order (no longer supported)
#define SORT_JAPANESE_RADICALSTROKE 0x4 // Japanese radical/stroke order

#define SORT_CHINESE_BIG5 0x0 // Chinese BIG5 order
#define SORT_CHINESE_PRCP 0x0 // PRC Chinese Phonetic order
#define SORT_CHINESE_UNICODE 0x1 // Chinese Unicode order (no longer supported)
#define SORT_CHINESE_PRC 0x2 // PRC Chinese Stroke Count order
#define SORT_CHINESE_BOPOMOFO 0x3 // Traditional Chinese Bopomofo order
#define SORT_CHINESE_RADICALSTROKE 0x4 // Traditional Chinese radical/stroke order.

#define SORT_KOREAN_KSC 0x0 // Korean KSC order
#define SORT_KOREAN_UNICODE 0x1 // Korean Unicode order (no longer supported)

#define SORT_GERMAN_PHONE_BOOK 0x1 // German Phone Book order

#define SORT_HUNGARIAN_DEFAULT 0x0 // Hungarian Default order
#define SORT_HUNGARIAN_TECHNICAL 0x1 // Hungarian Technical order

#define SORT_GEORGIAN_TRADITIONAL 0x0 // Georgian Traditional order
#define SORT_GEORGIAN_MODERN 0x1 // Georgian Modern order

// end_r_winnt

//
// A language ID is a 16 bit value which is the combination of a
// primary language ID and a secondary language ID. The bits are
// allocated as follows:
//
// +-----------------------+-------------------------+
// | Sublanguage ID | Primary Language ID |
// +-----------------------+-------------------------+
// 15 10 9 0 bit
//
// WARNING: This pattern isn‘t always follows, Serbina, Bosnian & Croation
// for example.
//
// It is recommended that applications test for locale names or actual LCIDs.
//
// Language ID creation/extraction macros:
//
// MAKELANGID - construct language id from a primary language id and
// a sublanguage id.
// PRIMARYLANGID - extract primary language id from a language id.
// SUBLANGID - extract sublanguage id from a language id.
//
// Note that the LANG, SUBLANG construction is not always consistent.
// The named locale APIs (eg GetLocaleInfoEx) are recommended.
//
// Language IDs do not exist for all locales
//
#define MAKELANGID(p, s) ((((WORD )(s)) << 10) | (WORD )(p))
#define PRIMARYLANGID(lgid) ((WORD )(lgid) & 0x3ff)
#define SUBLANGID(lgid) ((WORD )(lgid) >> 10)


//
// A locale ID is a 32 bit value which is the combination of a
// language ID, a sort ID, and a reserved area. The bits are
// allocated as follows:
//
// +-------------+---------+-------------------------+
// | Reserved | Sort ID | Language ID |
// +-------------+---------+-------------------------+
// 31 20 19 16 15 0 bit
//
// WARNING: This pattern isn‘t always followed (es-ES_tradnl vs es-ES for example)
//
// It is recommended that applications test for locale names or actual LCIDs.
//
// Locale ID creation/extraction macros:
//
// MAKELCID - construct the locale id from a language id and a sort id.
// MAKESORTLCID - construct the locale id from a language id, sort id, and sort version.
// LANGIDFROMLCID - extract the language id from a locale id.
// SORTIDFROMLCID - extract the sort id from a locale id.
// SORTVERSIONFROMLCID - extract the sort version from a locale id.
//
// Note that the LANG, SUBLANG construction is not always consistent.
// The named locale APIs (eg GetLocaleInfoEx) are recommended.
//
// LCIDs do not exist for all locales.
//
#define NLS_VALID_LOCALE_MASK 0x000fffff

#define MAKELCID(lgid, srtid) ((DWORD)((((DWORD)((WORD )(srtid))) << 16) | \
((DWORD)((WORD )(lgid)))))
#define MAKESORTLCID(lgid, srtid, ver) \
((DWORD)((MAKELCID(lgid, srtid)) | \
(((DWORD)((WORD )(ver))) << 20)))
#define LANGIDFROMLCID(lcid) ((WORD )(lcid))
#define SORTIDFROMLCID(lcid) ((WORD )((((DWORD)(lcid)) >> 16) & 0xf))
#define SORTVERSIONFROMLCID(lcid) ((WORD )((((DWORD)(lcid)) >> 20) & 0xf))

// 8 characters for language
// 8 characters for region
// 64 characters for suffix (script)
// 2 characters for ‘-‘ separators
// 2 characters for prefix like "i-" or "x-"
// 1 null termination
#define LOCALE_NAME_MAX_LENGTH 85

//
// Default System and User IDs for language and locale.
// Locale names such as LOCALE_NAME_SYSTEM_DEFAULT, LOCALE_NAME_USER_DEFAULT,
// and LOCALE_NAME_INVARIANT are preferred.
//

#define LANG_SYSTEM_DEFAULT (MAKELANGID(LANG_NEUTRAL, SUBLANG_SYS_DEFAULT))
#define LANG_USER_DEFAULT (MAKELANGID(LANG_NEUTRAL, SUBLANG_DEFAULT))

#define LOCALE_SYSTEM_DEFAULT (MAKELCID(LANG_SYSTEM_DEFAULT, SORT_DEFAULT))
#define LOCALE_USER_DEFAULT (MAKELCID(LANG_USER_DEFAULT, SORT_DEFAULT))

//
// Other special IDs for language and locale.
//
#define LOCALE_CUSTOM_DEFAULT \
(MAKELCID(MAKELANGID(LANG_NEUTRAL, SUBLANG_CUSTOM_DEFAULT), SORT_DEFAULT))

#define LOCALE_CUSTOM_UNSPECIFIED \
(MAKELCID(MAKELANGID(LANG_NEUTRAL, SUBLANG_CUSTOM_UNSPECIFIED), SORT_DEFAULT))

#define LOCALE_CUSTOM_UI_DEFAULT \
(MAKELCID(MAKELANGID(LANG_NEUTRAL, SUBLANG_UI_CUSTOM_DEFAULT), SORT_DEFAULT))

#define LOCALE_NEUTRAL \
(MAKELCID(MAKELANGID(LANG_NEUTRAL, SUBLANG_NEUTRAL), SORT_DEFAULT))

#define LOCALE_INVARIANT \
(MAKELCID(MAKELANGID(LANG_INVARIANT, SUBLANG_NEUTRAL), SORT_DEFAULT))

// begin_ntminiport begin_ntndis begin_ntminitape

//
// Macros used to eliminate compiler warning generated when formal
// parameters or local variables are not declared.
//
// Use DBG_UNREFERENCED_PARAMETER() when a parameter is not yet
// referenced but will be once the module is completely developed.
//
// Use DBG_UNREFERENCED_LOCAL_VARIABLE() when a local variable is not yet
// referenced but will be once the module is completely developed.
//
// Use UNREFERENCED_PARAMETER() if a parameter will never be referenced.
//
// DBG_UNREFERENCED_PARAMETER and DBG_UNREFERENCED_LOCAL_VARIABLE will
// eventually be made into a null macro to help determine whether there
// is unfinished work.
//

#if ! defined(lint)
#define UNREFERENCED_PARAMETER(P) (P)
#define DBG_UNREFERENCED_PARAMETER(P) (P)
#define DBG_UNREFERENCED_LOCAL_VARIABLE(V) (V)

#else // lint

// Note: lint -e530 says don‘t complain about uninitialized variables for
// this varible. Error 527 has to do with unreachable code.
// -restore restores checking to the -save state

#define UNREFERENCED_PARAMETER(P) \
/*lint -save -e527 -e530 */ \
{ \
(P) = (P); \
} \
/*lint -restore */
#define DBG_UNREFERENCED_PARAMETER(P) \
/*lint -save -e527 -e530 */ \
{ \
(P) = (P); \
} \
/*lint -restore */
#define DBG_UNREFERENCED_LOCAL_VARIABLE(V) \
/*lint -save -e527 -e530 */ \
{ \
(V) = (V); \
} \
/*lint -restore */

#endif // lint

//
// Macro used to eliminate compiler warning 4715 within a switch statement
// when all possible cases have already been accounted for.
//
// switch (a & 3) {
// case 0: return 1;
// case 1: return Foo();
// case 2: return Bar();
// case 3: return 1;
// DEFAULT_UNREACHABLE;
//

#if (_MSC_VER > 1200)
#define DEFAULT_UNREACHABLE default: __assume(0)
#else

//
// Older compilers do not support __assume(), and there is no other free
// method of eliminating the warning.
//

#define DEFAULT_UNREACHABLE

#endif

#ifdef __cplusplus

// Define operator overloads to enable bit operations on enum values that are
// used to define flags. Use DEFINE_ENUM_FLAG_OPERATORS(YOUR_TYPE) to enable these
// operators on YOUR_TYPE.

// Moved here from objbase.w.

#define DEFINE_ENUM_FLAG_OPERATORS(ENUMTYPE) \
extern "C++" { \
inline ENUMTYPE operator | (ENUMTYPE a, ENUMTYPE b) { return ENUMTYPE(((int)a) | ((int)b)); } \
inline ENUMTYPE &operator |= (ENUMTYPE &a, ENUMTYPE b) { return (ENUMTYPE &)(((int &)a) |= ((int)b)); } \
inline ENUMTYPE operator & (ENUMTYPE a, ENUMTYPE b) { return ENUMTYPE(((int)a) & ((int)b)); } \
inline ENUMTYPE &operator &= (ENUMTYPE &a, ENUMTYPE b) { return (ENUMTYPE &)(((int &)a) &= ((int)b)); } \
inline ENUMTYPE operator ~ (ENUMTYPE a) { return ENUMTYPE(~((int)a)); } \
inline ENUMTYPE operator ^ (ENUMTYPE a, ENUMTYPE b) { return ENUMTYPE(((int)a) ^ ((int)b)); } \
inline ENUMTYPE &operator ^= (ENUMTYPE &a, ENUMTYPE b) { return (ENUMTYPE &)(((int &)a) ^= ((int)b)); } \
}
#else
#define DEFINE_ENUM_FLAG_OPERATORS(ENUMTYPE) // NOP, C allows these operators.
#endif

// Compile-time macros for initializing flag values in const data.
//
// When using DEFINE_ENUM_FLAG_OPERATORS for enum values you should use the macros below
// when you need to initialize global const data. Without these macros the inline operators
// from DEFINE_ENUM_FLAG_OPERATORS force a runtime initialization rather than a
// compile time initialization. This applies even if you have declared the data as const.
#define COMPILETIME_OR_2FLAGS(a,b) ((UINT)(a)|(UINT)(b))
#define COMPILETIME_OR_3FLAGS(a,b,c) ((UINT)(a)|(UINT)(b)|(UINT)(c))
#define COMPILETIME_OR_4FLAGS(a,b,c,d) ((UINT)(a)|(UINT)(b)|(UINT)(c)|(UINT)(d))
#define COMPILETIME_OR_5FLAGS(a,b,c,d,e) ((UINT)(a)|(UINT)(b)|(UINT)(c)|(UINT)(d)|(UINT)(e))

#ifndef WIN32_NO_STATUS
/*lint -save -e767 */
#define STATUS_WAIT_0 ((DWORD )0x00000000L)
#define STATUS_ABANDONED_WAIT_0 ((DWORD )0x00000080L)
#define STATUS_USER_APC ((DWORD )0x000000C0L)
#define STATUS_TIMEOUT ((DWORD )0x00000102L)
#define STATUS_PENDING ((DWORD )0x00000103L)
#define DBG_EXCEPTION_HANDLED ((DWORD )0x00010001L)
#define DBG_CONTINUE ((DWORD )0x00010002L)
#define STATUS_SEGMENT_NOTIFICATION ((DWORD )0x40000005L)
#define DBG_TERMINATE_THREAD ((DWORD )0x40010003L)
#define DBG_TERMINATE_PROCESS ((DWORD )0x40010004L)
#define DBG_CONTROL_C ((DWORD )0x40010005L)
#define DBG_PRINTEXCEPTION_C ((DWORD )0x40010006L)
#define DBG_RIPEXCEPTION ((DWORD )0x40010007L)
#define DBG_CONTROL_BREAK ((DWORD )0x40010008L)
#define DBG_COMMAND_EXCEPTION ((DWORD )0x40010009L)
#define STATUS_GUARD_PAGE_VIOLATION ((DWORD )0x80000001L)
#define STATUS_DATATYPE_MISALIGNMENT ((DWORD )0x80000002L)
#define STATUS_BREAKPOINT ((DWORD )0x80000003L)
#define STATUS_SINGLE_STEP ((DWORD )0x80000004L)
#define STATUS_LONGJUMP ((DWORD )0x80000026L)
#define STATUS_UNWIND_CONSOLIDATE ((DWORD )0x80000029L)
#define DBG_EXCEPTION_NOT_HANDLED ((DWORD )0x80010001L)
#define STATUS_ACCESS_VIOLATION ((DWORD )0xC0000005L)
#define STATUS_IN_PAGE_ERROR ((DWORD )0xC0000006L)
#define STATUS_INVALID_HANDLE ((DWORD )0xC0000008L)
#define STATUS_INVALID_PARAMETER ((DWORD )0xC000000DL)
#define STATUS_NO_MEMORY ((DWORD )0xC0000017L)
#define STATUS_ILLEGAL_INSTRUCTION ((DWORD )0xC000001DL)
#define STATUS_NONCONTINUABLE_EXCEPTION ((DWORD )0xC0000025L)
#define STATUS_INVALID_DISPOSITION ((DWORD )0xC0000026L)
#define STATUS_ARRAY_BOUNDS_EXCEEDED ((DWORD )0xC000008CL)
#define STATUS_FLOAT_DENORMAL_OPERAND ((DWORD )0xC000008DL)
#define STATUS_FLOAT_DIVIDE_BY_ZERO ((DWORD )0xC000008EL)
#define STATUS_FLOAT_INEXACT_RESULT ((DWORD )0xC000008FL)
#define STATUS_FLOAT_INVALID_OPERATION ((DWORD )0xC0000090L)
#define STATUS_FLOAT_OVERFLOW ((DWORD )0xC0000091L)
#define STATUS_FLOAT_STACK_CHECK ((DWORD )0xC0000092L)
#define STATUS_FLOAT_UNDERFLOW ((DWORD )0xC0000093L)
#define STATUS_INTEGER_DIVIDE_BY_ZERO ((DWORD )0xC0000094L)
#define STATUS_INTEGER_OVERFLOW ((DWORD )0xC0000095L)
#define STATUS_PRIVILEGED_INSTRUCTION ((DWORD )0xC0000096L)
#define STATUS_STACK_OVERFLOW ((DWORD )0xC00000FDL)
#define STATUS_DLL_NOT_FOUND ((DWORD )0xC0000135L)
#define STATUS_ORDINAL_NOT_FOUND ((DWORD )0xC0000138L)
#define STATUS_ENTRYPOINT_NOT_FOUND ((DWORD )0xC0000139L)
#define STATUS_CONTROL_C_EXIT ((DWORD )0xC000013AL)
#define STATUS_DLL_INIT_FAILED ((DWORD )0xC0000142L)
#define STATUS_FLOAT_MULTIPLE_FAULTS ((DWORD )0xC00002B4L)
#define STATUS_FLOAT_MULTIPLE_TRAPS ((DWORD )0xC00002B5L)
#define STATUS_REG_NAT_CONSUMPTION ((DWORD )0xC00002C9L)
#define STATUS_STACK_BUFFER_OVERRUN ((DWORD )0xC0000409L)
#define STATUS_INVALID_CRUNTIME_PARAMETER ((DWORD )0xC0000417L)
#define STATUS_ASSERTION_FAILURE ((DWORD )0xC0000420L)
#if defined(STATUS_SUCCESS) || (_WIN32_WINNT > 0x0500) || (_WIN32_FUSION >= 0x0100)
#define STATUS_SXS_EARLY_DEACTIVATION ((DWORD )0xC015000FL)
#define STATUS_SXS_INVALID_DEACTIVATION ((DWORD )0xC0150010L)
#endif
/*lint -restore */
#endif
#define MAXIMUM_WAIT_OBJECTS 64 // Maximum number of wait objects

#define MAXIMUM_SUSPEND_COUNT MAXCHAR // Maximum times thread can be suspended

typedef ULONG_PTR KSPIN_LOCK;
typedef KSPIN_LOCK *PKSPIN_LOCK;


//
// Define 128-bit 16-byte aligned xmm register type.
//

typedef struct DECLSPEC_ALIGN(16) _M128A {
ULONGLONG Low;
LONGLONG High;
} M128A, *PM128A;

//
// Format of data for (F)XSAVE/(F)XRSTOR instruction
//

typedef struct DECLSPEC_ALIGN(16) _XSAVE_FORMAT {
WORD ControlWord;
WORD StatusWord;
BYTE TagWord;
BYTE Reserved1;
WORD ErrorOpcode;
DWORD ErrorOffset;
WORD ErrorSelector;
WORD Reserved2;
DWORD DataOffset;
WORD DataSelector;
WORD Reserved3;
DWORD MxCsr;
DWORD MxCsr_Mask;
M128A FloatRegisters[8];

#if defined(_WIN64)

M128A XmmRegisters[16];
BYTE Reserved4[96];

#else

M128A XmmRegisters[8];
BYTE Reserved4[192];

//
// The fields below are not part of XSAVE/XRSTOR format.
// They are written by the OS which is relying on a fact that
// neither (FX)SAVE nor (F)XSTOR used this area.
//

DWORD StackControl[7]; // KERNEL_STACK_CONTROL structure actualy
DWORD Cr0NpxState;

#endif

} XSAVE_FORMAT, *PXSAVE_FORMAT;

typedef struct DECLSPEC_ALIGN(8) _XSAVE_AREA_HEADER {
DWORD64 Mask;
DWORD64 Reserved[7];
} XSAVE_AREA_HEADER, *PXSAVE_AREA_HEADER;

typedef struct DECLSPEC_ALIGN(16) _XSAVE_AREA {
XSAVE_FORMAT LegacyState;
XSAVE_AREA_HEADER Header;
} XSAVE_AREA, *PXSAVE_AREA;

typedef struct _XSTATE_CONTEXT {
DWORD64 Mask;
DWORD Length;
DWORD Reserved1;
__field_bcount_opt(Length) PXSAVE_AREA Area;

#if defined(_X86_)
DWORD Reserved2;
#endif

PVOID Buffer;

#if defined(_X86_)
DWORD Reserved3;
#endif

} XSTATE_CONTEXT, *PXSTATE_CONTEXT;


#define XSAVE_ALIGN 64
#define MINIMAL_XSTATE_AREA_LENGTH sizeof(XSAVE_AREA)


//
// This structure specifies an offset (from the beginning of CONTEXT_EX
// structure) and size of a single chunk of an extended context structure.
//
// N.B. Offset may be negative.
//

typedef struct _CONTEXT_CHUNK {
LONG Offset;
DWORD Length;
} CONTEXT_CHUNK, *PCONTEXT_CHUNK;

//
// CONTEXT_EX structure is an extension to CONTEXT structure. It defines
// a context record as a set of disjoint variable-sized buffers (chunks)
// each containing a portion of processor state. Currently there are only
// two buffers (chunks) are defined:
//
// - Legacy, that stores traditional CONTEXT structure;
// - XState, that stores XSAVE save area buffer starting from
// XSAVE_AREA_HEADER, i.e. without the first 512 bytes.
//
// There a few assumptions exists that simplify conversion of PCONTEXT
// pointer to PCONTEXT_EX pointer.
//
// 1. APIs that work with PCONTEXT pointers assume that CONTEXT_EX is
// stored right after the CONTEXT structure. It is also assumed that
// CONTEXT_EX is present if and only if corresponding CONTEXT_XXX
// flags are set in CONTEXT.ContextFlags.
//
// 2. CONTEXT_EX.Legacy is always present if CONTEXT_EX structure is
// present. All other chunks are optional.
//
// 3. CONTEXT.ContextFlags unambigiously define which chunks are
// present. I.e. if CONTEXT_XSTATE is set CONTEXT_EX.XState is valid.
//

typedef struct _CONTEXT_EX {

//
// The total length of the structure starting from the chunk with
// the smallest offset. N.B. that the offset may be negative.
//

CONTEXT_CHUNK All;

//
// Wrapper for the traditional CONTEXT structure. N.B. the size of
// the chunk may be less than sizeof(CONTEXT) is some cases (when
// CONTEXT_EXTENDED_REGISTERS is not set on x86 for instance).
//

CONTEXT_CHUNK Legacy;

//
// CONTEXT_XSTATE: Extended processor state chunk. The state is
// stored in the same format XSAVE operation strores it with
// exception of the first 512 bytes, i.e. staring from
// XSAVE_AREA_HEADER. The lower two bits corresponding FP and
// SSE state must be zero.
//

CONTEXT_CHUNK XState;

} CONTEXT_EX, *PCONTEXT_EX;

#define CONTEXT_EX_LENGTH ALIGN_UP_BY(sizeof(CONTEXT_EX), STACK_ALIGN)

//
// These macros make context chunks manupulations easier.
//

#define RTL_CONTEXT_EX_OFFSET(ContextEx, Chunk) \
((ContextEx)->Chunk.Offset)

#define RTL_CONTEXT_EX_LENGTH(ContextEx, Chunk) \
((ContextEx)->Chunk.Length)

#define RTL_CONTEXT_EX_CHUNK(Base, Layout, Chunk) \
((PVOID)((PCHAR)(Base) + RTL_CONTEXT_EX_OFFSET(Layout, Chunk)))

#define RTL_CONTEXT_OFFSET(Context, Chunk) \
RTL_CONTEXT_EX_OFFSET((PCONTEXT_EX)(Context + 1), Chunk)

#define RTL_CONTEXT_LENGTH(Context, Chunk) \
RTL_CONTEXT_EX_LENGTH((PCONTEXT_EX)(Context + 1), Chunk)

#define RTL_CONTEXT_CHUNK(Context, Chunk) \
RTL_CONTEXT_EX_CHUNK((PCONTEXT_EX)(Context + 1), \
(PCONTEXT_EX)(Context + 1), \
Chunk)


#if !defined(__midl) && !defined(MIDL_PASS)

//
// XSAVE/XRSTOR save area should be aligned on 64 byte boundary
//

C_ASSERT((sizeof(XSAVE_FORMAT) & (XSAVE_ALIGN - 1)) == 0);
C_ASSERT((FIELD_OFFSET(XSAVE_AREA, Header) & (XSAVE_ALIGN - 1)) == 0);

// XSAVE_AREA structure must be sized uniformly on all architectures
C_ASSERT(MINIMAL_XSTATE_AREA_LENGTH == 512 + 64);

#endif


#ifdef _AMD64_


#if defined(_M_AMD64) && !defined(RC_INVOKED) && !defined(MIDL_PASS)

//
// Define bit test intrinsics.
//

#ifdef __cplusplus
extern "C" {
#endif

#define BitTest _bittest
#define BitTestAndComplement _bittestandcomplement
#define BitTestAndSet _bittestandset
#define BitTestAndReset _bittestandreset
#define InterlockedBitTestAndSet _interlockedbittestandset
#define InterlockedBitTestAndReset _interlockedbittestandreset

#define BitTest64 _bittest64
#define BitTestAndComplement64 _bittestandcomplement64
#define BitTestAndSet64 _bittestandset64
#define BitTestAndReset64 _bittestandreset64
#define InterlockedBitTestAndSet64 _interlockedbittestandset64
#define InterlockedBitTestAndReset64 _interlockedbittestandreset64

__checkReturn
BOOLEAN
_bittest (
__in_bcount((Offset+7)/8) LONG const *Base,
__in LONG Offset
);

BOOLEAN
_bittestandcomplement (
__inout_bcount((Offset+7)/8) LONG *Base,
__in LONG Offset
);

BOOLEAN
_bittestandset (
__inout_bcount((Offset+7)/8) LONG *Base,
__in LONG Offset
);

BOOLEAN
_bittestandreset (
__inout_bcount((Offset+7)/8) LONG *Base,
__in LONG Offset
);

BOOLEAN
_interlockedbittestandset (
__inout_bcount((Offset+7)/8) __drv_interlocked LONG volatile *Base,
__in LONG Offset
);

BOOLEAN
_interlockedbittestandreset (
__inout_bcount((Offset+7)/8) __drv_interlocked LONG volatile *Base,
__in LONG Offset
);

BOOLEAN
_bittest64 (
__in_bcount((Offset+7)/8) LONG64 const *Base,
__in LONG64 Offset
);

BOOLEAN
_bittestandcomplement64 (
__inout_bcount((Offset+7)/8) LONG64 *Base,
__in LONG64 Offset
);

BOOLEAN
_bittestandset64 (
__inout_bcount((Offset+7)/8) LONG64 *Base,
__in LONG64 Offset
);

BOOLEAN
_bittestandreset64 (
__inout_bcount((Offset+7)/8) LONG64 *Base,
__in LONG64 Offset
);

BOOLEAN
_interlockedbittestandset64 (
__inout_bcount((Offset+7)/8) __drv_interlocked LONG64 volatile *Base,
__in LONG64 Offset
);

BOOLEAN
_interlockedbittestandreset64 (
__inout_bcount((Offset+7)/8) __drv_interlocked LONG64 volatile *Base,
__in LONG64 Offset
);

#pragma intrinsic(_bittest)
#pragma intrinsic(_bittestandcomplement)
#pragma intrinsic(_bittestandset)
#pragma intrinsic(_bittestandreset)
#pragma intrinsic(_interlockedbittestandset)
#pragma intrinsic(_interlockedbittestandreset)

#pragma intrinsic(_bittest64)
#pragma intrinsic(_bittestandcomplement64)
#pragma intrinsic(_bittestandset64)
#pragma intrinsic(_bittestandreset64)
#pragma intrinsic(_interlockedbittestandset64)
#pragma intrinsic(_interlockedbittestandreset64)

//
// Define bit scan intrinsics.
//

#define BitScanForward _BitScanForward
#define BitScanReverse _BitScanReverse
#define BitScanForward64 _BitScanForward64
#define BitScanReverse64 _BitScanReverse64

__success(return!=0)
BOOLEAN
_BitScanForward (
__out DWORD *Index,
__in DWORD Mask
);

__success(return!=0)
BOOLEAN
_BitScanReverse (
__out DWORD *Index,
__in DWORD Mask
);

__success(return!=0)
BOOLEAN
_BitScanForward64 (
__out DWORD *Index,
__in DWORD64 Mask
);

__success(return!=0)
BOOLEAN
_BitScanReverse64 (
__out DWORD *Index,
__in DWORD64 Mask
);

#pragma intrinsic(_BitScanForward)
#pragma intrinsic(_BitScanReverse)
#pragma intrinsic(_BitScanForward64)
#pragma intrinsic(_BitScanReverse64)

//
// Interlocked intrinsic functions.
//

#define InterlockedIncrement16 _InterlockedIncrement16
#define InterlockedDecrement16 _InterlockedDecrement16
#define InterlockedCompareExchange16 _InterlockedCompareExchange16

#define InterlockedAnd _InterlockedAnd
#define InterlockedAndAcquire _InterlockedAnd
#define InterlockedAndRelease _InterlockedAnd
#define InterlockedOr _InterlockedOr
#define InterlockedOrAcquire _InterlockedOr
#define InterlockedOrRelease _InterlockedOr
#define InterlockedXor _InterlockedXor
#define InterlockedIncrement _InterlockedIncrement
#define InterlockedIncrementAcquire InterlockedIncrement
#define InterlockedIncrementRelease InterlockedIncrement
#define InterlockedDecrement _InterlockedDecrement
#define InterlockedDecrementAcquire InterlockedDecrement
#define InterlockedDecrementRelease InterlockedDecrement
#define InterlockedAdd _InterlockedAdd
#define InterlockedExchange _InterlockedExchange
#define InterlockedExchangeAdd _InterlockedExchangeAdd
#define InterlockedCompareExchange _InterlockedCompareExchange
#define InterlockedCompareExchangeAcquire InterlockedCompareExchange
#define InterlockedCompareExchangeRelease InterlockedCompareExchange

#define InterlockedAnd64 _InterlockedAnd64
#define InterlockedAnd64Acquire _InterlockedAnd64
#define InterlockedAnd64Release _InterlockedAnd64
#define InterlockedAndAffinity InterlockedAnd64
#define InterlockedOr64 _InterlockedOr64
#define InterlockedOr64Acquire _InterlockedOr64
#define InterlockedOr64Release _InterlockedOr64
#define InterlockedOrAffinity InterlockedOr64
#define InterlockedXor64 _InterlockedXor64
#define InterlockedIncrement64 _InterlockedIncrement64
#define InterlockedDecrement64 _InterlockedDecrement64
#define InterlockedAdd64 _InterlockedAdd64
#define InterlockedExchange64 _InterlockedExchange64
#define InterlockedExchangeAcquire64 InterlockedExchange64
#define InterlockedExchangeAdd64 _InterlockedExchangeAdd64
#define InterlockedCompareExchange64 _InterlockedCompareExchange64
#define InterlockedCompareExchangeAcquire64 InterlockedCompareExchange64
#define InterlockedCompareExchangeRelease64 InterlockedCompareExchange64

#define InterlockedExchangePointer _InterlockedExchangePointer
#define InterlockedCompareExchangePointer _InterlockedCompareExchangePointer
#define InterlockedCompareExchangePointerAcquire _InterlockedCompareExchangePointer
#define InterlockedCompareExchangePointerRelease _InterlockedCompareExchangePointer

#define InterlockedExchangeAddSizeT(a, b) InterlockedExchangeAdd64((LONG64 *)a, b)
#define InterlockedIncrementSizeT(a) InterlockedIncrement64((LONG64 *)a)
#define InterlockedDecrementSizeT(a) InterlockedDecrement64((LONG64 *)a)

SHORT
InterlockedIncrement16 (
__inout __drv_interlocked SHORT volatile *Addend
);

SHORT
InterlockedDecrement16 (
__inout __drv_interlocked SHORT volatile *Addend
);

SHORT
InterlockedCompareExchange16 (
__inout __drv_interlocked SHORT volatile *Destination,
__in SHORT ExChange,
__in SHORT Comperand
);

LONG
InterlockedAnd (
__inout __drv_interlocked LONG volatile *Destination,
__in LONG Value
);

LONG
InterlockedOr (
__inout __drv_interlocked LONG volatile *Destination,
__in LONG Value
);

LONG
InterlockedXor (
__inout __drv_interlocked LONG volatile *Destination,
__in LONG Value
);

LONG64
InterlockedAnd64 (
__inout __drv_interlocked LONG64 volatile *Destination,
__in LONG64 Value
);

LONG64
InterlockedOr64 (
__inout __drv_interlocked LONG64 volatile *Destination,
__in LONG64 Value
);

LONG64
InterlockedXor64 (
__inout __drv_interlocked LONG64 volatile *Destination,
__in LONG64 Value
);

LONG
InterlockedIncrement(
__inout __drv_interlocked LONG volatile *Addend
);

LONG
InterlockedDecrement(
__inout __drv_interlocked LONG volatile *Addend
);

LONG
InterlockedExchange(
__inout __drv_interlocked LONG volatile *Target,
__in LONG Value
);

LONG
InterlockedExchangeAdd(
__inout __drv_interlocked LONG volatile *Addend,
__in LONG Value
);

#if !defined(_X86AMD64_)

__forceinline
LONG
InterlockedAdd(
__inout __drv_interlocked LONG volatile *Addend,
__in LONG Value
)

{
return InterlockedExchangeAdd(Addend, Value) + Value;
}

#endif

LONG
InterlockedCompareExchange (
__inout __drv_interlocked LONG volatile *Destination,
__in LONG ExChange,
__in LONG Comperand
);

LONG64
InterlockedIncrement64(
__inout __drv_interlocked LONG64 volatile *Addend
);

LONG64
InterlockedDecrement64(
__inout __drv_interlocked LONG64 volatile *Addend
);

LONG64
InterlockedExchange64(
__inout __drv_interlocked LONG64 volatile *Target,
__in LONG64 Value
);

LONG64
InterlockedExchangeAdd64(
__inout __drv_interlocked LONG64 volatile *Addend,
__in LONG64 Value
);

#if !defined(_X86AMD64_)

__forceinline
LONG64
InterlockedAdd64(
__inout __drv_interlocked LONG64 volatile *Addend,
__in LONG64 Value
)

{
return InterlockedExchangeAdd64(Addend, Value) + Value;
}

#endif

LONG64
InterlockedCompareExchange64 (
__inout __drv_interlocked LONG64 volatile *Destination,
__in LONG64 ExChange,
__in LONG64 Comperand
);

PVOID
InterlockedCompareExchangePointer (
__inout __drv_interlocked PVOID volatile *Destination,
__in_opt PVOID Exchange,
__in_opt PVOID Comperand
);

PVOID
InterlockedExchangePointer(
__inout __drv_interlocked PVOID volatile *Target,
__in_opt PVOID Value
);

#pragma intrinsic(_InterlockedIncrement16)
#pragma intrinsic(_InterlockedDecrement16)
#pragma intrinsic(_InterlockedCompareExchange16)
#pragma intrinsic(_InterlockedAnd)
#pragma intrinsic(_InterlockedOr)
#pragma intrinsic(_InterlockedXor)
#pragma intrinsic(_InterlockedIncrement)
#pragma intrinsic(_InterlockedDecrement)
#pragma intrinsic(_InterlockedExchange)
#pragma intrinsic(_InterlockedExchangeAdd)
#pragma intrinsic(_InterlockedCompareExchange)
#pragma intrinsic(_InterlockedAnd64)
#pragma intrinsic(_InterlockedOr64)
#pragma intrinsic(_InterlockedXor64)
#pragma intrinsic(_InterlockedIncrement64)
#pragma intrinsic(_InterlockedDecrement64)
#pragma intrinsic(_InterlockedExchange64)
#pragma intrinsic(_InterlockedExchangeAdd64)
#pragma intrinsic(_InterlockedCompareExchange64)
#pragma intrinsic(_InterlockedExchangePointer)
#pragma intrinsic(_InterlockedCompareExchangePointer)

#if _MSC_FULL_VER >= 140041204

#define InterlockedAnd8 _InterlockedAnd8
#define InterlockedOr8 _InterlockedOr8
#define InterlockedXor8 _InterlockedXor8
#define InterlockedAnd16 _InterlockedAnd16
#define InterlockedOr16 _InterlockedOr16
#define InterlockedXor16 _InterlockedXor16

char
InterlockedAnd8 (
__inout __drv_interlocked char volatile *Destination,
__in char Value
);

char
InterlockedOr8 (
__inout __drv_interlocked char volatile *Destination,
__in char Value
);

char
InterlockedXor8 (
__inout __drv_interlocked char volatile *Destination,
__in char Value
);

SHORT
InterlockedAnd16(
__inout __drv_interlocked SHORT volatile *Destination,
__in SHORT Value
);

SHORT
InterlockedOr16(
__inout __drv_interlocked SHORT volatile *Destination,
__in SHORT Value
);

SHORT
InterlockedXor16(
__inout __drv_interlocked SHORT volatile *Destination,
__in SHORT Value
);

#pragma intrinsic (_InterlockedAnd8)
#pragma intrinsic (_InterlockedOr8)
#pragma intrinsic (_InterlockedXor8)
#pragma intrinsic (_InterlockedAnd16)
#pragma intrinsic (_InterlockedOr16)
#pragma intrinsic (_InterlockedXor16)

#endif

//
// Define function to flush a cache line.
//

#define CacheLineFlush(Address) _mm_clflush(Address)

VOID
_mm_clflush (
__in VOID const *Address
);

#pragma intrinsic(_mm_clflush)

VOID
_ReadWriteBarrier (
VOID
);

#pragma intrinsic(_ReadWriteBarrier)

//
// Define memory fence intrinsics
//

#define FastFence __faststorefence
#define LoadFence _mm_lfence
#define MemoryFence _mm_mfence
#define StoreFence _mm_sfence

VOID
__faststorefence (
VOID
);

VOID
_mm_lfence (
VOID
);

VOID
_mm_mfence (
VOID
);

VOID
_mm_sfence (
VOID
);

VOID
_mm_pause (
VOID
);

VOID
_mm_prefetch (
__in CHAR CONST *a,
__in int sel
);

VOID
_m_prefetchw (
__in volatile CONST VOID *Source
);

//
// Define constants for use with _mm_prefetch.
//

#define _MM_HINT_T0 1
#define _MM_HINT_T1 2
#define _MM_HINT_T2 3
#define _MM_HINT_NTA 0

#pragma intrinsic(__faststorefence)
#pragma intrinsic(_mm_pause)
#pragma intrinsic(_mm_prefetch)
#pragma intrinsic(_mm_lfence)
#pragma intrinsic(_mm_mfence)
#pragma intrinsic(_mm_sfence)
#pragma intrinsic(_m_prefetchw)

#define YieldProcessor _mm_pause
#define MemoryBarrier __faststorefence
#define PreFetchCacheLine(l, a) _mm_prefetch((CHAR CONST *) a, l)
#define PrefetchForWrite(p) _m_prefetchw(p)
#define ReadForWriteAccess(p) (_m_prefetchw(p), *(p))

//
// PreFetchCacheLine level defines.
//

#define PF_TEMPORAL_LEVEL_1 _MM_HINT_T0
#define PF_TEMPORAL_LEVEL_2 _MM_HINT_T1
#define PF_TEMPORAL_LEVEL_3 _MM_HINT_T2
#define PF_NON_TEMPORAL_LEVEL_ALL _MM_HINT_NTA

//
// Define get/set MXCSR intrinsics.
//

#define ReadMxCsr _mm_getcsr
#define WriteMxCsr _mm_setcsr

unsigned int
_mm_getcsr (
VOID
);

VOID
_mm_setcsr (
__in unsigned int MxCsr
);

#pragma intrinsic(_mm_getcsr)
#pragma intrinsic(_mm_setcsr)

//
// Assert exception.
//

VOID
__int2c (
VOID
);

#pragma intrinsic(__int2c)

__analysis_noreturn
FORCEINLINE
VOID
DbgRaiseAssertionFailure (
VOID
)

{
__int2c();
}

//
// Define function to get the caller‘s EFLAGs value.
//

#define GetCallersEflags() __getcallerseflags()

unsigned __int32
__getcallerseflags (
VOID
);

#pragma intrinsic(__getcallerseflags)

//
// Define function to get segment limit.
//

#define GetSegmentLimit __segmentlimit

DWORD
__segmentlimit (
__in DWORD Selector
);

#pragma intrinsic(__segmentlimit)

//
// Define function to read the value of a performance counter.
//

#define ReadPMC __readpmc

DWORD64
__readpmc (
__in DWORD Counter
);

#pragma intrinsic(__readpmc)

//
// Define function to read the value of the time stamp counter
//

#define ReadTimeStampCounter() __rdtsc()

DWORD64
__rdtsc (
VOID
);

#pragma intrinsic(__rdtsc)

//
// Define functions to move strings as bytes, words, dwords, and qwords.
//

VOID
__movsb (
__out_ecount_full(Count) PBYTE Destination,
__in_ecount(Count) BYTE const *Source,
__in SIZE_T Count
);

VOID
__movsw (
__out_ecount_full(Count) PWORD Destination,
__in_ecount(Count) WORD const *Source,
__in SIZE_T Count
);

VOID
__movsd (
__out_ecount_full(Count) PDWORD Destination,
__in_ecount(Count) DWORD const *Source,
__in SIZE_T Count
);

VOID
__movsq (
__out_ecount_full(Count) PDWORD64 Destination,
__in_ecount(Count) DWORD64 const *Source,
__in SIZE_T Count
);

#pragma intrinsic(__movsb)
#pragma intrinsic(__movsw)
#pragma intrinsic(__movsd)
#pragma intrinsic(__movsq)

//
// Define functions to store strings as bytes, words, dwords, and qwords.
//

VOID
__stosb (
__out_ecount_full(Count) PBYTE Destination,
__in BYTE Value,
__in SIZE_T Count
);

VOID
__stosw (
__out_ecount_full(Count) PWORD Destination,
__in WORD Value,
__in SIZE_T Count
);

VOID
__stosd (
__out_ecount_full(Count) PDWORD Destination,
__in DWORD Value,
__in SIZE_T Count
);

VOID
__stosq (
__out_ecount_full(Count) PDWORD64 Destination,
__in DWORD64 Value,
__in SIZE_T Count
);

#pragma intrinsic(__stosb)
#pragma intrinsic(__stosw)
#pragma intrinsic(__stosd)
#pragma intrinsic(__stosq)

//
// Define functions to capture the high 64-bits of a 128-bit multiply.
//

#define MultiplyHigh __mulh
#define UnsignedMultiplyHigh __umulh

LONGLONG
MultiplyHigh (
__in LONG64 Multiplier,
__in LONG64 Multiplicand
);

ULONGLONG
UnsignedMultiplyHigh (
__in DWORD64 Multiplier,
__in DWORD64 Multiplicand
);

#pragma intrinsic(__mulh)
#pragma intrinsic(__umulh)

//
// Define functions to perform 128-bit shifts
//

#define ShiftLeft128 __shiftleft128
#define ShiftRight128 __shiftright128

DWORD64
ShiftLeft128 (
__in DWORD64 LowPart,
__in DWORD64 HighPart,
__in BYTE Shift
);

DWORD64
ShiftRight128 (
__in DWORD64 LowPart,
__in DWORD64 HighPart,
__in BYTE Shift
);

#pragma intrinsic(__shiftleft128)
#pragma intrinsic(__shiftright128)

//
// Define functions to perform 128-bit multiplies.
//

#define Multiply128 _mul128

LONG64
Multiply128 (
__in LONG64 Multiplier,
__in LONG64 Multiplicand,
__out LONG64 *HighProduct
);

#pragma intrinsic(_mul128)

#ifndef UnsignedMultiply128

#define UnsignedMultiply128 _umul128

DWORD64
UnsignedMultiply128 (
__in DWORD64 Multiplier,
__in DWORD64 Multiplicand,
__out DWORD64 *HighProduct
);

#pragma intrinsic(_umul128)

#endif

__forceinline
LONG64
MultiplyExtract128 (
__in LONG64 Multiplier,
__in LONG64 Multiplicand,
__in BYTE Shift
)

{

LONG64 extractedProduct;
LONG64 highProduct;
LONG64 lowProduct;
BOOLEAN negate;
DWORD64 uhighProduct;
DWORD64 ulowProduct;

lowProduct = Multiply128(Multiplier, Multiplicand, &highProduct);
negate = FALSE;
uhighProduct = (DWORD64)highProduct;
ulowProduct = (DWORD64)lowProduct;
if (highProduct < 0) {
negate = TRUE;
uhighProduct = (DWORD64)(-highProduct);
ulowProduct = (DWORD64)(-lowProduct);
if (ulowProduct != 0) {
uhighProduct -= 1;
}
}

extractedProduct = (LONG64)ShiftRight128(ulowProduct, uhighProduct, Shift);
if (negate != FALSE) {
extractedProduct = -extractedProduct;
}

return extractedProduct;
}

__forceinline
DWORD64
UnsignedMultiplyExtract128 (
__in DWORD64 Multiplier,
__in DWORD64 Multiplicand,
__in BYTE Shift
)

{

DWORD64 extractedProduct;
DWORD64 highProduct;
DWORD64 lowProduct;

lowProduct = UnsignedMultiply128(Multiplier, Multiplicand, &highProduct);
extractedProduct = ShiftRight128(lowProduct, highProduct, Shift);
return extractedProduct;
}

//
// Define functions to read and write the uer TEB and the system PCR/PRCB.
//

BYTE
__readgsbyte (
__in DWORD Offset
);

WORD
__readgsword (
__in DWORD Offset
);

DWORD
__readgsdword (
__in DWORD Offset
);

DWORD64
__readgsqword (
__in DWORD Offset
);

VOID
__writegsbyte (
__in DWORD Offset,
__in BYTE Data
);

VOID
__writegsword (
__in DWORD Offset,
__in WORD Data
);

VOID
__writegsdword (
__in DWORD Offset,
__in DWORD Data
);

VOID
__writegsqword (
__in DWORD Offset,
__in DWORD64 Data
);

#pragma intrinsic(__readgsbyte)
#pragma intrinsic(__readgsword)
#pragma intrinsic(__readgsdword)
#pragma intrinsic(__readgsqword)
#pragma intrinsic(__writegsbyte)
#pragma intrinsic(__writegsword)
#pragma intrinsic(__writegsdword)
#pragma intrinsic(__writegsqword)

#if !defined(_MANAGED)

VOID
__incgsbyte (
__in DWORD Offset
);

VOID
__addgsbyte (
__in DWORD Offset,
__in BYTE Value
);

VOID
__incgsword (
__in DWORD Offset
);

VOID
__addgsword (
__in DWORD Offset,
__in WORD Value
);

VOID
__incgsdword (
__in DWORD Offset
);

VOID
__addgsdword (
__in DWORD Offset,
__in DWORD Value
);

VOID
__incgsqword (
__in DWORD Offset
);

VOID
__addgsqword (
__in DWORD Offset,
__in DWORD64 Value
);

#if 0
#pragma intrinsic(__incgsbyte)
#pragma intrinsic(__addgsbyte)
#pragma intrinsic(__incgsword)
#pragma intrinsic(__addgsword)
#pragma intrinsic(__incgsdword)
#pragma intrinsic(__addgsdword)
#pragma intrinsic(__incgsqword)
#pragma intrinsic(__addgsqword)
#endif

#endif

#ifdef __cplusplus
}
#endif

#endif // defined(_M_AMD64) && !defined(RC_INVOKED) && !defined(MIDL_PASS)

//
// The following values specify the type of access in the first parameter
// of the exception record whan the exception code specifies an access
// violation.
//

#define EXCEPTION_READ_FAULT 0 // exception caused by a read
#define EXCEPTION_WRITE_FAULT 1 // exception caused by a write
#define EXCEPTION_EXECUTE_FAULT 8 // exception caused by an instruction fetch

// begin_wx86
//
// The following flags control the contents of the CONTEXT structure.
//

#if !defined(RC_INVOKED)

#define CONTEXT_AMD64 0x100000

// end_wx86

#define CONTEXT_CONTROL (CONTEXT_AMD64 | 0x1L)
#define CONTEXT_INTEGER (CONTEXT_AMD64 | 0x2L)
#define CONTEXT_SEGMENTS (CONTEXT_AMD64 | 0x4L)
#define CONTEXT_FLOATING_POINT (CONTEXT_AMD64 | 0x8L)
#define CONTEXT_DEBUG_REGISTERS (CONTEXT_AMD64 | 0x10L)

#define CONTEXT_FULL (CONTEXT_CONTROL | CONTEXT_INTEGER | CONTEXT_FLOATING_POINT)

#define CONTEXT_ALL (CONTEXT_CONTROL | CONTEXT_INTEGER | CONTEXT_SEGMENTS | CONTEXT_FLOATING_POINT | CONTEXT_DEBUG_REGISTERS)

#define CONTEXT_XSTATE (CONTEXT_AMD64 | 0x20L)

#define CONTEXT_EXCEPTION_ACTIVE 0x8000000
#define CONTEXT_SERVICE_ACTIVE 0x10000000
#define CONTEXT_EXCEPTION_REQUEST 0x40000000
#define CONTEXT_EXCEPTION_REPORTING 0x80000000

// begin_wx86

#endif // !defined(RC_INVOKED)

//
// Define initial MxCsr and FpCsr control.
//

#define INITIAL_MXCSR 0x1f80 // initial MXCSR value
#define INITIAL_FPCSR 0x027f // initial FPCSR value

// end_ntddk
// begin_wdm begin_ntosp

typedef XSAVE_FORMAT XMM_SAVE_AREA32, *PXMM_SAVE_AREA32;

// end_wdm end_ntosp
// begin_ntddk

//
// Context Frame
//
// This frame has a several purposes: 1) it is used as an argument to
// NtContinue, 2) it is used to constuct a call frame for APC delivery,
// and 3) it is used in the user level thread creation routines.
//
//
// The flags field within this record controls the contents of a CONTEXT
// record.
//
// If the context record is used as an input parameter, then for each
// portion of the context record controlled by a flag whose value is
// set, it is assumed that that portion of the context record contains
// valid context. If the context record is being used to modify a threads
// context, then only that portion of the threads context is modified.
//
// If the context record is used as an output parameter to capture the
// context of a thread, then only those portions of the thread‘s context
// corresponding to set flags will be returned.
//
// CONTEXT_CONTROL specifies SegSs, Rsp, SegCs, Rip, and EFlags.
//
// CONTEXT_INTEGER specifies Rax, Rcx, Rdx, Rbx, Rbp, Rsi, Rdi, and R8-R15.
//
// CONTEXT_SEGMENTS specifies SegDs, SegEs, SegFs, and SegGs.
//
// CONTEXT_FLOATING_POINT specifies Xmm0-Xmm15.
//
// CONTEXT_DEBUG_REGISTERS specifies Dr0-Dr3 and Dr6-Dr7.
//

typedef struct DECLSPEC_ALIGN(16) _CONTEXT {

//
// Register parameter home addresses.
//
// N.B. These fields are for convience - they could be used to extend the
// context record in the future.
//

DWORD64 P1Home;
DWORD64 P2Home;
DWORD64 P3Home;
DWORD64 P4Home;
DWORD64 P5Home;
DWORD64 P6Home;

//
// Control flags.
//

DWORD ContextFlags;
DWORD MxCsr;

//
// Segment Registers and processor flags.
//

WORD SegCs;
WORD SegDs;
WORD SegEs;
WORD SegFs;
WORD SegGs;
WORD SegSs;
DWORD EFlags;

//
// Debug registers
//

DWORD64 Dr0;
DWORD64 Dr1;
DWORD64 Dr2;
DWORD64 Dr3;
DWORD64 Dr6;
DWORD64 Dr7;

//
// Integer registers.
//

DWORD64 Rax;
DWORD64 Rcx;
DWORD64 Rdx;
DWORD64 Rbx;
DWORD64 Rsp;
DWORD64 Rbp;
DWORD64 Rsi;
DWORD64 Rdi;
DWORD64 R8;
DWORD64 R9;
DWORD64 R10;
DWORD64 R11;
DWORD64 R12;
DWORD64 R13;
DWORD64 R14;
DWORD64 R15;

//
// Program counter.
//

DWORD64 Rip;

//
// Floating point state.
//

union {
XMM_SAVE_AREA32 FltSave;
struct {
M128A Header[2];
M128A Legacy[8];
M128A Xmm0;
M128A Xmm1;
M128A Xmm2;
M128A Xmm3;
M128A Xmm4;
M128A Xmm5;
M128A Xmm6;
M128A Xmm7;
M128A Xmm8;
M128A Xmm9;
M128A Xmm10;
M128A Xmm11;
M128A Xmm12;
M128A Xmm13;
M128A Xmm14;
M128A Xmm15;
} DUMMYSTRUCTNAME;
} DUMMYUNIONNAME;

//
// Vector registers.
//

M128A VectorRegister[26];
DWORD64 VectorControl;

//
// Special debug control registers.
//

DWORD64 DebugControl;
DWORD64 LastBranchToRip;
DWORD64 LastBranchFromRip;
DWORD64 LastExceptionToRip;
DWORD64 LastExceptionFromRip;
} CONTEXT, *PCONTEXT;

//
// Define function table entry - a function table entry is generated for
// each frame function.
//

#define RUNTIME_FUNCTION_INDIRECT 0x1

typedef struct _RUNTIME_FUNCTION {
DWORD BeginAddress;
DWORD EndAddress;
DWORD UnwindData;
} RUNTIME_FUNCTION, *PRUNTIME_FUNCTION;

//
// Define unwind history table structure.
//

#define UNWIND_HISTORY_TABLE_SIZE 12

typedef struct _UNWIND_HISTORY_TABLE_ENTRY {
DWORD64 ImageBase;
PRUNTIME_FUNCTION FunctionEntry;
} UNWIND_HISTORY_TABLE_ENTRY, *PUNWIND_HISTORY_TABLE_ENTRY;

typedef struct _UNWIND_HISTORY_TABLE {
DWORD Count;
BYTE LocalHint;
BYTE GlobalHint;
BYTE Search;
BYTE Once;
DWORD64 LowAddress;
DWORD64 HighAddress;
UNWIND_HISTORY_TABLE_ENTRY Entry[UNWIND_HISTORY_TABLE_SIZE];
} UNWIND_HISTORY_TABLE, *PUNWIND_HISTORY_TABLE;

//
// Define dynamic function table entry.
//

typedef
__drv_functionClass(GET_RUNTIME_FUNCTION_CALLBACK)
PRUNTIME_FUNCTION
GET_RUNTIME_FUNCTION_CALLBACK (
__in DWORD64 ControlPc,
__in_opt PVOID Context
);
typedef GET_RUNTIME_FUNCTION_CALLBACK *PGET_RUNTIME_FUNCTION_CALLBACK;

typedef
__drv_functionClass(OUT_OF_PROCESS_FUNCTION_TABLE_CALLBACK)
DWORD
OUT_OF_PROCESS_FUNCTION_TABLE_CALLBACK (
__in HANDLE Process,
__in PVOID TableAddress,
__out PDWORD Entries,
__out PRUNTIME_FUNCTION* Functions
);
typedef OUT_OF_PROCESS_FUNCTION_TABLE_CALLBACK *POUT_OF_PROCESS_FUNCTION_TABLE_CALLBACK;

#define OUT_OF_PROCESS_FUNCTION_TABLE_CALLBACK_EXPORT_NAME \
"OutOfProcessFunctionTableCallback"

//
// Define runtime exception handling prototypes.
//

NTSYSAPI
VOID
__cdecl
RtlRestoreContext (
__in PCONTEXT ContextRecord,
__in_opt struct _EXCEPTION_RECORD *ExceptionRecord
);


NTSYSAPI
BOOLEAN
__cdecl
RtlAddFunctionTable (
__in_ecount(EntryCount) PRUNTIME_FUNCTION FunctionTable,
__in DWORD EntryCount,
__in DWORD64 BaseAddress
);

NTSYSAPI
PRUNTIME_FUNCTION
NTAPI
RtlLookupFunctionEntry (
__in DWORD64 ControlPc,
__out PDWORD64 ImageBase,
__inout_opt PUNWIND_HISTORY_TABLE HistoryTable
);

//
// Nonvolatile context pointer record.
//

typedef struct _KNONVOLATILE_CONTEXT_POINTERS {
union {
PM128A FloatingContext[16];
struct {
PM128A Xmm0;
PM128A Xmm1;
PM128A Xmm2;
PM128A Xmm3;
PM128A Xmm4;
PM128A Xmm5;
PM128A Xmm6;
PM128A Xmm7;
PM128A Xmm8;
PM128A Xmm9;
PM128A Xmm10;
PM128A Xmm11;
PM128A Xmm12;
PM128A Xmm13;
PM128A Xmm14;
PM128A Xmm15;
} DUMMYSTRUCTNAME;
} DUMMYUNIONNAME;

union {
PDWORD64 IntegerContext[16];
struct {
PDWORD64 Rax;
PDWORD64 Rcx;
PDWORD64 Rdx;
PDWORD64 Rbx;
PDWORD64 Rsp;
PDWORD64 Rbp;
PDWORD64 Rsi;
PDWORD64 Rdi;
PDWORD64 R8;
PDWORD64 R9;
PDWORD64 R10;
PDWORD64 R11;
PDWORD64 R12;
PDWORD64 R13;
PDWORD64 R14;
PDWORD64 R15;
} DUMMYSTRUCTNAME;
} DUMMYUNIONNAME2;

} KNONVOLATILE_CONTEXT_POINTERS, *PKNONVOLATILE_CONTEXT_POINTERS;

NTSYSAPI
PEXCEPTION_ROUTINE
NTAPI
RtlVirtualUnwind (
__in DWORD HandlerType,
__in DWORD64 ImageBase,
__in DWORD64 ControlPc,
__in PRUNTIME_FUNCTION FunctionEntry,
__inout PCONTEXT ContextRecord,
__out PVOID *HandlerData,
__out PDWORD64 EstablisherFrame,
__inout_opt PKNONVOLATILE_CONTEXT_POINTERS ContextPointers
);

NTSYSAPI
BOOLEAN
__cdecl
RtlInstallFunctionTableCallback (
__in DWORD64 TableIdentifier,
__in DWORD64 BaseAddress,
__in DWORD Length,
__in PGET_RUNTIME_FUNCTION_CALLBACK Callback,
__in_opt PVOID Context,
__in_opt PCWSTR OutOfProcessCallbackDll
);

NTSYSAPI
BOOLEAN
__cdecl
RtlDeleteFunctionTable (
__in PRUNTIME_FUNCTION FunctionTable
);

#endif // _AMD64_


#ifdef _X86_

//
// Disable these two pragmas that evaluate to "sti" "cli" on x86 so that driver
// writers to not leave them inadvertantly in their code.
//

#if !defined(MIDL_PASS)
#if !defined(RC_INVOKED)

#if _MSC_VER >= 1200
#pragma warning(push)
#endif
#pragma warning(disable:4164) // disable C4164 warning so that apps that
// build with /Od don‘t get weird errors !
#ifdef _M_IX86
#pragma function(_enable)
#pragma function(_disable)
#endif

#if _MSC_VER >= 1200
#pragma warning(pop)
#else
#pragma warning(default:4164) // reenable C4164 warning
#endif

#endif
#endif

// end_ntddk end_nthal
#if defined(_M_IX86) && !defined(RC_INVOKED) && !defined(MIDL_PASS)

#ifdef __cplusplus
extern "C" {
#endif

 

#if (_MSC_FULL_VER >= 14000101)


//
// Define bit test intrinsics.
//

#define BitTest _bittest
#define BitTestAndComplement _bittestandcomplement
#define BitTestAndSet _bittestandset
#define BitTestAndReset _bittestandreset
#define InterlockedBitTestAndSet _interlockedbittestandset
#define InterlockedBitTestAndReset _interlockedbittestandreset

__checkReturn
BOOLEAN
_bittest (
__in_bcount((Offset+7)/8) LONG const *Base,
__in LONG Offset
);

BOOLEAN
_bittestandcomplement (
__inout_bcount((Offset+7)/8) LONG *Base,
__in LONG Offset
);

BOOLEAN
_bittestandset (
__inout_bcount((Offset+7)/8) LONG *Base,
__in LONG Offset
);

BOOLEAN
_bittestandreset (
__inout_bcount((Offset+7)/8) LONG *Base,
__in LONG Offset
);

BOOLEAN
_interlockedbittestandset (
__inout_bcount((Offset+7)/8) __drv_interlocked LONG volatile *Base,
__in LONG Offset
);

BOOLEAN
_interlockedbittestandreset (
__inout_bcount((Offset+7)/8) __drv_interlocked LONG volatile *Base,
__in LONG Offset
);

#pragma intrinsic(_bittest)
#pragma intrinsic(_bittestandcomplement)
#pragma intrinsic(_bittestandset)
#pragma intrinsic(_bittestandreset)
#pragma intrinsic(_interlockedbittestandset)
#pragma intrinsic(_interlockedbittestandreset)

//
// Define bit scan intrinsics.
//

#define BitScanForward _BitScanForward
#define BitScanReverse _BitScanReverse

__success(return != 0)
BOOLEAN
_BitScanForward (
__out DWORD *Index,
__in DWORD Mask
);

__success(return != 0)
BOOLEAN
_BitScanReverse (
__out DWORD *Index,
__in DWORD Mask
);

#pragma intrinsic(_BitScanForward)
#pragma intrinsic(_BitScanReverse)

#else

#pragma warning(push)
#pragma warning(disable:4035 4793)

FORCEINLINE
BOOLEAN
InterlockedBitTestAndSet (
__inout_bcount((Bit+7)/8) __drv_interlocked LONG volatile *Base,
__in LONG Bit
)
{
__asm {
mov eax, Bit
mov ecx, Base
lock bts [ecx], eax
setc al
};
}

FORCEINLINE
BOOLEAN
InterlockedBitTestAndReset (
__inout_bcount((Bit+7)/8) __drv_interlocked LONG volatile *Base,
__in LONG Bit
)
{
__asm {
mov eax, Bit
mov ecx, Base
lock btr [ecx], eax
setc al
};
}
#pragma warning(pop)

#endif /* _MSC_FULL_VER >= 14000101 */

//
// [pfx_parse] - guard against PREfix intrinsic error
//
#if (_MSC_FULL_VER >= 140040816) || (defined(_PREFAST_) && (_MSC_VER >= 1400))

#define InterlockedAnd16 _InterlockedAnd16
#define InterlockedCompareExchange16 _InterlockedCompareExchange16
#define InterlockedOr16 _InterlockedOr16

SHORT
_InterlockedAnd16 (
__inout __drv_interlocked SHORT volatile *Destination,
__in SHORT Value
);

SHORT
_InterlockedCompareExchange16 (
__inout __drv_interlocked SHORT volatile *Destination,
__in SHORT ExChange,
__in SHORT Comperand
);

SHORT
_InterlockedOr16 (
__inout __drv_interlocked SHORT volatile *Destination,
__in SHORT Value
);

#pragma intrinsic(_InterlockedAnd16)
#pragma intrinsic(_InterlockedCompareExchange16)
#pragma intrinsic(_InterlockedOr16)

#endif /* _MSC_FULL_VER >= 140040816 */

#if !defined(_M_CEE_PURE)
#pragma warning(push)
#pragma warning(disable:4035 4793)

FORCEINLINE
BOOLEAN
InterlockedBitTestAndComplement (
__inout_bcount((Bit+7)/8) __drv_interlocked LONG volatile *Base,
__in LONG Bit
)
{
__asm {
mov eax, Bit
mov ecx, Base
lock btc [ecx], eax
setc al
};
}
#pragma warning(pop)
#endif /* _M_CEE_PURE */

//
// [pfx_parse]
// guard against __readfsbyte parsing error
//
#if (_MSC_FULL_VER >= 13012035) || defined(_PREFIX_) || defined(_PREFAST_)

//
// Define FS referencing intrinsics
//

BYTE
__readfsbyte (
__in DWORD Offset
);

WORD
__readfsword (
__in DWORD Offset
);

DWORD
__readfsdword (
__in DWORD Offset
);

VOID
__writefsbyte (
__in DWORD Offset,
__in BYTE Data
);

VOID
__writefsword (
__in DWORD Offset,
__in WORD Data
);

VOID
__writefsdword (
__in DWORD Offset,
__in DWORD Data
);

#pragma intrinsic(__readfsbyte)
#pragma intrinsic(__readfsword)
#pragma intrinsic(__readfsdword)
#pragma intrinsic(__writefsbyte)
#pragma intrinsic(__writefsword)
#pragma intrinsic(__writefsdword)

#endif /* _MSC_FULL_VER >= 13012035 */

#if (_MSC_FULL_VER >= 140050727) || defined(_PREFIX_) || defined(_PREFAST_)

#if !defined(_MANAGED)

VOID
__incfsbyte (
__in DWORD Offset
);

VOID
__addfsbyte (
__in DWORD Offset,
__in BYTE Value
);

VOID
__incfsword (
__in DWORD Offset
);

VOID
__addfsword (
__in DWORD Offset,
__in WORD Value
);

VOID
__incfsdword (
__in DWORD Offset
);

VOID
__addfsdword (
__in DWORD Offset,
__in DWORD Value
);

#pragma intrinsic(__incfsbyte)
#pragma intrinsic(__addfsbyte)
#pragma intrinsic(__incfsword)
#pragma intrinsic(__addfsword)
#pragma intrinsic(__incfsdword)
#pragma intrinsic(__addfsdword)

#endif

#endif /* _MSC_FULL_VER >= 140050727 */

#if (_MSC_FULL_VER >= 140041204) || defined(_PREFIX_) || defined(_PREFAST_)

VOID
_mm_pause (
VOID
);

#pragma intrinsic(_mm_pause)

#define YieldProcessor _mm_pause

#else

#if !defined(_M_CEE_PURE)
#define YieldProcessor() __asm { rep nop }
#endif // !defined(_M_CEE_PURE)

#endif // (_MSC_FULL_VER >= 140041204)

#ifdef __cplusplus
}
#endif

#endif /* !defined(MIDL_PASS) || defined(_M_IX86) */

#if !defined(MIDL_PASS) && defined(_M_IX86)

#if !defined(_M_CEE_PURE)

#pragma warning( push )
#pragma warning( disable : 4793 )
FORCEINLINE
VOID
MemoryBarrier (
VOID
)
{
LONG Barrier;
__asm {
xchg Barrier, eax
}
}
#pragma warning( pop )

#endif /* _M_CEE_PURE */
//
// Prefetch is not supported on all x86 procssors.
//

#define PreFetchCacheLine(l, a)
#define PrefetchForWrite(p)
#define ReadForWriteAccess(p) (*(p))

//
// PreFetchCacheLine level defines.
//

#define PF_TEMPORAL_LEVEL_1
#define PF_NON_TEMPORAL_LEVEL_ALL

//
// Define function to read the value of a performance counter.
//

#if _MSC_FULL_VER >= 140050727

#define ReadPMC __readpmc

DWORD64
__readpmc (
__in DWORD Counter
);

#pragma intrinsic(__readpmc)

#else

FORCEINLINE
DWORD64
ReadPMC (
__in DWORD Counter
)

{
__asm {
mov ecx, Counter
rdpmc
};
}

#endif

//
// Define function to read the value of the time stamp counter
//

#if _MSC_FULL_VER >= 140040310

#define ReadTimeStampCounter() __rdtsc()

DWORD64
__rdtsc (
VOID
);

#pragma intrinsic(__rdtsc)

#else

FORCEINLINE
DWORD64
ReadTimeStampCounter (
VOID
)

{
__asm rdtsc
}

#endif

// end_ntddk
// begin_wdm

#if defined(_X86_) && defined(_M_IX86) && !defined(RC_INVOKED) && !defined(MIDL_PASS)

#if _MSC_FULL_VER >= 140030222

VOID
__int2c (
VOID
);

#pragma intrinsic(__int2c)

__analysis_noreturn
FORCEINLINE
VOID
DbgRaiseAssertionFailure (
VOID
)

{
__int2c();
}

#else
#pragma warning( push )
#pragma warning( disable : 4793 )

__analysis_noreturn
FORCEINLINE
VOID
DbgRaiseAssertionFailure (
VOID
)

{
__asm int 0x2c
}

#pragma warning( pop )

#endif

#endif

// end_wdm

#if (_MSC_FULL_VER >= 13012035)

__inline PVOID GetFiberData( void ) { return *(PVOID *) (ULONG_PTR) __readfsdword (0x10);}
__inline PVOID GetCurrentFiber( void ) { return (PVOID) (ULONG_PTR) __readfsdword (0x10);}

#else
#if _MSC_VER >= 1200
#pragma warning(push)
#endif
#pragma warning (disable:4035 4793) // disable 4035 (function must return something)
__inline PVOID GetFiberData( void ) { __asm {
mov eax, fs:[0x10]
mov eax,[eax]
}
}
__inline PVOID GetCurrentFiber( void ) { __asm mov eax, fs:[0x10] }

#if _MSC_VER >= 1200
#pragma warning(pop)
#else
#pragma warning (default:4035 4793) // Reenable it
#endif
#endif // (_MSC_FULL_VER >= 13012035)

// begin_ntddk
#endif // !defined(MIDL_PASS) && defined(_M_IX86)
// end_ntddk

//
// The following values specify the type of failing access when the status is
// STATUS_ACCESS_VIOLATION and the first parameter in the execpetion record.
//

#define EXCEPTION_READ_FAULT 0 // Access violation was caused by a read
#define EXCEPTION_WRITE_FAULT 1 // Access violation was caused by a write
#define EXCEPTION_EXECUTE_FAULT 8 // Access violation was caused by an instruction fetch

// begin_wx86
// begin_ntddk

//
// Define the size of the 80387 save area, which is in the context frame.
//

#define SIZE_OF_80387_REGISTERS 80

//
// The following flags control the contents of the CONTEXT structure.
//

#if !defined(RC_INVOKED)

#define CONTEXT_i386 0x00010000 // this assumes that i386 and
#define CONTEXT_i486 0x00010000 // i486 have identical context records

// end_wx86

#define CONTEXT_CONTROL (CONTEXT_i386 | 0x00000001L) // SS:SP, CS:IP, FLAGS, BP
#define CONTEXT_INTEGER (CONTEXT_i386 | 0x00000002L) // AX, BX, CX, DX, SI, DI
#define CONTEXT_SEGMENTS (CONTEXT_i386 | 0x00000004L) // DS, ES, FS, GS
#define CONTEXT_FLOATING_POINT (CONTEXT_i386 | 0x00000008L) // 387 state
#define CONTEXT_DEBUG_REGISTERS (CONTEXT_i386 | 0x00000010L) // DB 0-3,6,7
#define CONTEXT_EXTENDED_REGISTERS (CONTEXT_i386 | 0x00000020L) // cpu specific extensions

#define CONTEXT_FULL (CONTEXT_CONTROL | CONTEXT_INTEGER |\
CONTEXT_SEGMENTS)

#define CONTEXT_ALL (CONTEXT_CONTROL | CONTEXT_INTEGER | CONTEXT_SEGMENTS | \
CONTEXT_FLOATING_POINT | CONTEXT_DEBUG_REGISTERS | \
CONTEXT_EXTENDED_REGISTERS)

#define CONTEXT_XSTATE (CONTEXT_i386 | 0x00000040L)

// begin_wx86

#endif // !defined(RC_INVOKED)

typedef struct _FLOATING_SAVE_AREA {
DWORD ControlWord;
DWORD StatusWord;
DWORD TagWord;
DWORD ErrorOffset;
DWORD ErrorSelector;
DWORD DataOffset;
DWORD DataSelector;
BYTE RegisterArea[SIZE_OF_80387_REGISTERS];
DWORD Cr0NpxState;
} FLOATING_SAVE_AREA;

typedef FLOATING_SAVE_AREA *PFLOATING_SAVE_AREA;


// end_ntddk
// begin_wdm begin_ntosp

#define MAXIMUM_SUPPORTED_EXTENSION 512

#if !defined(__midl) && !defined(MIDL_PASS)

C_ASSERT(sizeof(XSAVE_FORMAT) == MAXIMUM_SUPPORTED_EXTENSION);

#endif

// end_wdm end_ntosp
// begin_ntddk

#include "pshpack4.h"

//
// Context Frame
//
// This frame has a several purposes: 1) it is used as an argument to
// NtContinue, 2) is is used to constuct a call frame for APC delivery,
// and 3) it is used in the user level thread creation routines.
//
// The layout of the record conforms to a standard call frame.
//

typedef struct _CONTEXT {

//
// The flags values within this flag control the contents of
// a CONTEXT record.
//
// If the context record is used as an input parameter, then
// for each portion of the context record controlled by a flag
// whose value is set, it is assumed that that portion of the
// context record contains valid context. If the context record
// is being used to modify a threads context, then only that
// portion of the threads context will be modified.
//
// If the context record is used as an IN OUT parameter to capture
// the context of a thread, then only those portions of the thread‘s
// context corresponding to set flags will be returned.
//
// The context record is never used as an OUT only parameter.
//

DWORD ContextFlags;

//
// This section is specified/returned if CONTEXT_DEBUG_REGISTERS is
// set in ContextFlags. Note that CONTEXT_DEBUG_REGISTERS is NOT
// included in CONTEXT_FULL.
//

DWORD Dr0;
DWORD Dr1;
DWORD Dr2;
DWORD Dr3;
DWORD Dr6;
DWORD Dr7;

//
// This section is specified/returned if the
// ContextFlags word contians the flag CONTEXT_FLOATING_POINT.
//

FLOATING_SAVE_AREA FloatSave;

//
// This section is specified/returned if the
// ContextFlags word contians the flag CONTEXT_SEGMENTS.
//

DWORD SegGs;
DWORD SegFs;
DWORD SegEs;
DWORD SegDs;

//
// This section is specified/returned if the
// ContextFlags word contians the flag CONTEXT_INTEGER.
//

DWORD Edi;
DWORD Esi;
DWORD Ebx;
DWORD Edx;
DWORD Ecx;
DWORD Eax;

//
// This section is specified/returned if the
// ContextFlags word contians the flag CONTEXT_CONTROL.
//

DWORD Ebp;
DWORD Eip;
DWORD SegCs; // MUST BE SANITIZED
DWORD EFlags; // MUST BE SANITIZED
DWORD Esp;
DWORD SegSs;

//
// This section is specified/returned if the ContextFlags word
// contains the flag CONTEXT_EXTENDED_REGISTERS.
// The format and contexts are processor specific
//

BYTE ExtendedRegisters[MAXIMUM_SUPPORTED_EXTENSION];

} CONTEXT;

typedef CONTEXT *PCONTEXT;

#include "poppack.h"

// begin_ntminiport
#endif //_X86_


#ifndef _LDT_ENTRY_DEFINED
#define _LDT_ENTRY_DEFINED

typedef struct _LDT_ENTRY {
WORD LimitLow;
WORD BaseLow;
union {
struct {
BYTE BaseMid;
BYTE Flags1; // Declare as bytes to avoid alignment
BYTE Flags2; // Problems.
BYTE BaseHi;
} Bytes;
struct {
DWORD BaseMid : 8;
DWORD Type : 5;
DWORD Dpl : 2;
DWORD Pres : 1;
DWORD LimitHi : 4;
DWORD Sys : 1;
DWORD Reserved_0 : 1;
DWORD Default_Big : 1;
DWORD Granularity : 1;
DWORD BaseHi : 8;
} Bits;
} HighWord;
} LDT_ENTRY, *PLDT_ENTRY;

#endif


#if defined(_M_IA64) && !defined(RC_INVOKED) && !defined(MIDL_PASS)

#ifdef __cplusplus
extern "C" {
#endif

//
// Define bit test intrinsics.
//

#define BitTest _bittest
#define BitTestAndComplement _bittestandcomplement
#define BitTestAndSet _bittestandset
#define BitTestAndReset _bittestandreset

#define BitTest64 _bittest64
#define BitTestAndComplement64 _bittestandcomplement64
#define BitTestAndSet64 _bittestandset64
#define BitTestAndReset64 _bittestandreset64

__checkReturn
BOOLEAN
_bittest (
__in_bcount((Offset+7)/8) LONG const *Base,
__in LONG Offset
);

BOOLEAN
_bittestandcomplement (
__inout_bcount((Offset+7)/8) LONG *Base,
__in LONG Offset
);

BOOLEAN
_bittestandset (
__inout_bcount((Offset+7)/8) LONG *Base,
__in LONG Offset
);

BOOLEAN
_bittestandreset (
__inout_bcount((Offset+7)/8) LONG *Base,
__in LONG Offset
);

__checkReturn
BOOLEAN
_bittest64 (
__in_bcount((Offset+7)/8) LONG64 const *Base,
__in LONG64 Offset
);

BOOLEAN
_bittestandcomplement64 (
__inout_bcount((Offset+7)/8) LONG64 *Base,
__in LONG64 Offset
);

BOOLEAN
_bittestandset64 (
__inout_bcount((Offset+7)/8) LONG64 *Base,
__in LONG64 Offset
);

BOOLEAN
_bittestandreset64 (
__inout_bcount((Offset+7)/8) LONG64 *Base,
__in LONG64 Offset
);

#pragma intrinsic(_bittest)
#pragma intrinsic(_bittestandcomplement)
#pragma intrinsic(_bittestandset)
#pragma intrinsic(_bittestandreset)

#pragma intrinsic(_bittest64)
#pragma intrinsic(_bittestandcomplement64)
#pragma intrinsic(_bittestandset64)
#pragma intrinsic(_bittestandreset64)

//
// Define bit scan intrinsics.
//

#define BitScanForward _BitScanForward
#define BitScanReverse _BitScanReverse
#define BitScanForward64 _BitScanForward64
#define BitScanReverse64 _BitScanReverse64

__success(return!=0)
BOOLEAN
_BitScanForward (
__out DWORD *Index,
__in DWORD Mask
);

__success(return!=0)
BOOLEAN
_BitScanReverse (
__out DWORD *Index,
__in DWORD Mask
);

__success(return!=0)
BOOLEAN
_BitScanForward64 (
__out DWORD *Index,
__in DWORD64 Mask
);

__success(return!=0)
BOOLEAN
_BitScanReverse64 (
__out DWORD *Index,
__in DWORD64 Mask
);

#pragma intrinsic(_BitScanForward)
#pragma intrinsic(_BitScanReverse)
#pragma intrinsic(_BitScanForward64)
#pragma intrinsic(_BitScanReverse64)

#define InterlockedCompareExchange16 _InterlockedCompareExchange16

SHORT
_InterlockedCompareExchange16 (
__inout __drv_interlocked SHORT volatile *Destination,
__in SHORT ExChange,
__in SHORT Comperand
);

#pragma intrinsic(_InterlockedCompareExchange16)

#ifdef __cplusplus
}
#endif

#define InterlockedAdd _InterlockedAdd
#define InterlockedAddAcquire _InterlockedAdd_acq
#define InterlockedAddRelease _InterlockedAdd_rel

#define InterlockedIncrement _InterlockedIncrement
#define InterlockedIncrementAcquire _InterlockedIncrement_acq
#define InterlockedIncrementRelease _InterlockedIncrement_rel

#define InterlockedDecrement _InterlockedDecrement
#define InterlockedDecrementAcquire _InterlockedDecrement_acq
#define InterlockedDecrementRelease _InterlockedDecrement_rel

#define InterlockedExchange _InterlockedExchange
#define InterlockedExchangeAcquire _InterlockedExchange_acq

#define InterlockedExchangeAdd _InterlockedExchangeAdd
#define InterlockedExchangeAddAcquire _InterlockedExchangeAdd_acq
#define InterlockedExchangeAddRelease _InterlockedExchangeAdd_rel

#define InterlockedAdd64 _InterlockedAdd64
#define InterlockedAddAcquire64 _InterlockedAdd64_acq
#define InterlockedAddRelease64 _InterlockedAdd64_rel

#define InterlockedIncrement64 _InterlockedIncrement64
#define InterlockedIncrementAcquire64 _InterlockedIncrement64_acq
#define InterlockedIncrementRelease64 _InterlockedIncrement64_rel

#define InterlockedDecrement64 _InterlockedDecrement64
#define InterlockedDecrementAcquire64 _InterlockedDecrement64_acq
#define InterlockedDecrementRelease64 _InterlockedDecrement64_rel

#define InterlockedExchange64 _InterlockedExchange64
#define InterlockedExchangeAcquire64 _InterlockedExchange64_acq

#define InterlockedExchangeAdd64 _InterlockedExchangeAdd64
#define InterlockedExchangeAddAcquire64 _InterlockedExchangeAdd64_acq
#define InterlockedExchangeAddRelease64 _InterlockedExchangeAdd64_rel

#define InterlockedCompareExchange64 _InterlockedCompareExchange64
#define InterlockedCompareExchangeAcquire64 _InterlockedCompareExchange64_acq
#define InterlockedCompareExchangeRelease64 _InterlockedCompareExchange64_rel

#define InterlockedCompare64Exchange128 _InterlockedCompare64Exchange128
#define InterlockedCompare64ExchangeAcquire128 _InterlockedCompare64Exchange128_acq
#define InterlockedCompare64ExchangeRelease128 _InterlockedCompare64Exchange128_rel

#define InterlockedCompareExchange _InterlockedCompareExchange
#define InterlockedCompareExchangeAcquire _InterlockedCompareExchange_acq
#define InterlockedCompareExchangeRelease _InterlockedCompareExchange_rel

#define InterlockedExchangePointer _InterlockedExchangePointer
#define InterlockedExchangePointerAcquire _InterlockedExchangePointer_acq

#define InterlockedCompareExchangePointer _InterlockedCompareExchangePointer
#define InterlockedCompareExchangePointerRelease _InterlockedCompareExchangePointer_rel
#define InterlockedCompareExchangePointerAcquire _InterlockedCompareExchangePointer_acq


#define InterlockedExchangeAddSizeT(a, b) InterlockedExchangeAdd64((LONG64 *)a, b)
#define InterlockedIncrementSizeT(a) InterlockedIncrement64((LONG64 *)a)
#define InterlockedDecrementSizeT(a) InterlockedDecrement64((LONG64 *)a)

#define InterlockedOr _InterlockedOr
#define InterlockedOrAcquire _InterlockedOr_acq
#define InterlockedOrRelease _InterlockedOr_rel
#define InterlockedOr8 _InterlockedOr8
#define InterlockedOr8Acquire _InterlockedOr8_acq
#define InterlockedOr8Release _InterlockedOr8_rel
#define InterlockedOr16 _InterlockedOr16
#define InterlockedOr16Acquire _InterlockedOr16_acq
#define InterlockedOr16Release _InterlockedOr16_rel
#define InterlockedOr64 _InterlockedOr64
#define InterlockedOr64Acquire _InterlockedOr64_acq
#define InterlockedOr64Release _InterlockedOr64_rel
#define InterlockedXor _InterlockedXor
#define InterlockedXorAcquire _InterlockedXor_acq
#define InterlockedXorRelease _InterlockedXor_rel
#define InterlockedXor8 _InterlockedXor8
#define InterlockedXor8Acquire _InterlockedXor8_acq
#define InterlockedXor8Release _InterlockedXor8_rel
#define InterlockedXor16 _InterlockedXor16
#define InterlockedXor16Acquire _InterlockedXor16_acq
#define InterlockedXor16Release _InterlockedXor16_rel
#define InterlockedXor64 _InterlockedXor64
#define InterlockedXor64Acquire _InterlockedXor64_acq
#define InterlockedXor64Release _InterlockedXor64_rel
#define InterlockedAnd _InterlockedAnd
#define InterlockedAndAcquire _InterlockedAnd_acq
#define InterlockedAndRelease _InterlockedAnd_rel
#define InterlockedAnd8 _InterlockedAnd8
#define InterlockedAnd8Acquire _InterlockedAnd8_acq
#define InterlockedAnd8Release _InterlockedAnd8_rel
#define InterlockedAnd16 _InterlockedAnd16
#define InterlockedAnd16Acquire _InterlockedAnd16_acq
#define InterlockedAnd16Release _InterlockedAnd16_rel
#define InterlockedAnd64 _InterlockedAnd64
#define InterlockedAnd64Acquire _InterlockedAnd64_acq
#define InterlockedAnd64Release _InterlockedAnd64_rel

#ifdef __cplusplus
extern "C" {
#endif

LONG
__cdecl
InterlockedAdd (
__inout __drv_interlocked LONG volatile *Addend,
__in LONG Value
);

LONG
__cdecl
InterlockedAddAcquire (
__inout __drv_interlocked LONG volatile *Addend,
__in LONG Value
);

LONG
__cdecl
InterlockedAddRelease (
__inout __drv_interlocked LONG volatile *Addend,
__in LONG Value
);

LONGLONG
__cdecl
InterlockedAdd64 (
__inout __drv_interlocked LONGLONG volatile *Addend,
__in LONGLONG Value
);

LONGLONG
__cdecl
InterlockedAddAcquire64 (
__inout __drv_interlocked LONGLONG volatile *Addend,
__in LONGLONG Value
);


LONGLONG
__cdecl
InterlockedAddRelease64 (
__inout __drv_interlocked LONGLONG volatile *Addend,
__in LONGLONG Value
);

LONG
__cdecl
InterlockedIncrement(
__inout __drv_interlocked LONG volatile *Addend
);

LONG
__cdecl
InterlockedDecrement(
__inout __drv_interlocked LONG volatile *Addend
);

LONG
__cdecl
InterlockedIncrementAcquire(
__inout __drv_interlocked LONG volatile *Addend
);

LONG
__cdecl
InterlockedDecrementAcquire(
__inout __drv_interlocked LONG volatile *Addend
);

LONG
__cdecl
InterlockedIncrementRelease(
__inout __drv_interlocked LONG volatile *Addend
);

LONG
__cdecl
InterlockedDecrementRelease(
__inout __drv_interlocked LONG volatile *Addend
);

LONG
__cdecl
InterlockedExchange(
__inout __drv_interlocked LONG volatile *Target,
__in LONG Value
);

LONG
__cdecl
InterlockedExchangeAcquire(
__inout __drv_interlocked LONG volatile *Target,
__in LONG Value
);

LONG
__cdecl
InterlockedExchangeAdd(
__inout __drv_interlocked LONG volatile *Addend,
__in LONG Value
);

LONG
__cdecl
InterlockedExchangeAddAcquire(
__inout __drv_interlocked LONG volatile *Addend,
__in LONG Value
);

LONG
__cdecl
InterlockedExchangeAddRelease(
__inout __drv_interlocked LONG volatile *Addend,
__in LONG Value
);

LONG
__cdecl
InterlockedCompareExchange (
__inout __drv_interlocked LONG volatile *Destination,
__in LONG ExChange,
__in LONG Comperand
);


LONG
__cdecl
InterlockedCompareExchangeRelease (
__inout __drv_interlocked LONG volatile *Destination,
__in LONG ExChange,
__in LONG Comperand
);


LONG
__cdecl
InterlockedCompareExchangeAcquire (
__inout __drv_interlocked LONG volatile *Destination,
__in LONG ExChange,
__in LONG Comperand
);


LONGLONG
__cdecl
InterlockedIncrement64(
__inout __drv_interlocked LONGLONG volatile *Addend
);

LONGLONG
__cdecl
InterlockedIncrementAcquire64(
__inout __drv_interlocked LONGLONG volatile *Addend
);

LONGLONG
__cdecl
InterlockedIncrementRelease64(
__inout __drv_interlocked LONGLONG volatile *Addend
);

LONGLONG
__cdecl
InterlockedDecrement64(
__inout __drv_interlocked LONGLONG volatile *Addend
);

LONGLONG
__cdecl
InterlockedDecrementAcquire64(
__inout __drv_interlocked LONGLONG volatile *Addend
);

LONGLONG
__cdecl
InterlockedDecrementRelease64(
__inout __drv_interlocked LONGLONG volatile *Addend
);

LONGLONG
__cdecl
InterlockedExchange64(
__inout __drv_interlocked LONGLONG volatile *Target,
__in LONGLONG Value
);

LONGLONG
__cdecl
InterlockedExchangeAcquire64(
__inout __drv_interlocked LONGLONG volatile *Target,
__in LONGLONG Value
);

LONGLONG
__cdecl
InterlockedExchangeAdd64(
__inout __drv_interlocked LONGLONG volatile *Addend,
__in LONGLONG Value
);

LONGLONG
__cdecl
InterlockedExchangeAddAcquire64(
__inout __drv_interlocked LONGLONG volatile *Addend,
__in LONGLONG Value
);

LONGLONG
__cdecl
InterlockedExchangeAddRelease64(
__inout __drv_interlocked LONGLONG volatile *Addend,
__in LONGLONG Value
);

LONGLONG
__cdecl
InterlockedCompareExchange64 (
__inout __drv_interlocked LONGLONG volatile *Destination,
__in LONGLONG ExChange,
__in LONGLONG Comperand
);

LONGLONG
__cdecl
InterlockedCompareExchangeAcquire64 (
__inout __drv_interlocked LONGLONG volatile *Destination,
__in LONGLONG ExChange,
__in LONGLONG Comperand
);

LONGLONG
__cdecl
InterlockedCompareExchangeRelease64 (
__inout __drv_interlocked LONGLONG volatile *Destination,
__in LONGLONG ExChange,
__in LONGLONG Comperand
);

LONG64
__cdecl
InterlockedCompare64Exchange128(
__inout_bcount(16) __drv_interlocked LONG64 volatile *Destination,
__in LONG64 ExchangeHigh,
__in LONG64 ExchangeLow,
__in LONG64 Comperand
);

LONG64
__cdecl
InterlockedCompare64ExchangeAcquire128(
__inout_bcount(16) __drv_interlocked LONG64 volatile *Destination,
__in LONG64 ExchangeHigh,
__in LONG64 ExchangeLow,
__in LONG64 Comperand
);

LONG64
__cdecl
InterlockedCompare64ExchangeRelease128(
__inout_bcount(16) __drv_interlocked LONG64 volatile *Destination,
__in LONG64 ExchangeHigh,
__in LONG64 ExchangeLow,
__in LONG64 Comperand
);

PVOID
__cdecl
InterlockedCompareExchangePointer (
__inout __drv_interlocked PVOID volatile *Destination,
__in PVOID Exchange,
__in PVOID Comperand
);

PVOID
__cdecl
InterlockedCompareExchangePointerAcquire (
__inout __drv_interlocked PVOID volatile *Destination,
__in PVOID Exchange,
__in PVOID Comperand
);

PVOID
__cdecl
InterlockedCompareExchangePointerRelease (
__inout __drv_interlocked PVOID volatile *Destination,
__in PVOID Exchange,
__in PVOID Comperand
);

PVOID
__cdecl
InterlockedExchangePointer(
__inout __drv_interlocked PVOID volatile *Target,
__in PVOID Value
);

PVOID
__cdecl
InterlockedExchangePointerAcquire(
__inout __drv_interlocked PVOID volatile *Target,
__in PVOID Value
);

LONG
__cdecl
InterlockedOr (
__inout __drv_interlocked LONG volatile *Destination,
__in LONG Value
);

LONG
__cdecl
InterlockedOrAcquire (
__inout __drv_interlocked LONG volatile *Destination,
__in LONG Value
);

LONG
__cdecl
InterlockedOrRelease (
__inout __drv_interlocked LONG volatile *Destination,
__in LONG Value
);

CHAR
__cdecl
InterlockedOr8 (
__inout __drv_interlocked CHAR volatile *Destination,
__in CHAR Value
);

CHAR
__cdecl
InterlockedOr8Acquire (
__inout __drv_interlocked CHAR volatile *Destination,
__in CHAR Value
);

CHAR
__cdecl
InterlockedOr8Release (
__inout __drv_interlocked CHAR volatile *Destination,
__in CHAR Value
);

SHORT
__cdecl
InterlockedOr16(
__inout __drv_interlocked SHORT volatile *Destination,
__in SHORT Value
);

SHORT
__cdecl
InterlockedOr16Acquire (
__inout __drv_interlocked SHORT volatile *Destination,
__in SHORT Value
);

SHORT
__cdecl
InterlockedOr16Release (
__inout __drv_interlocked SHORT volatile *Destination,
__in SHORT Value
);

LONGLONG
__cdecl
InterlockedOr64 (
__inout __drv_interlocked LONGLONG volatile *Destination,
__in LONGLONG Value
);

LONGLONG
__cdecl
InterlockedOr64Acquire (
__inout __drv_interlocked LONGLONG volatile *Destination,
__in LONGLONG Value
);

LONGLONG
__cdecl
InterlockedOr64Release (
__inout __drv_interlocked LONGLONG volatile *Destination,
__in LONGLONG Value
);

LONG
__cdecl
InterlockedXor (
__inout __drv_interlocked LONG volatile *Destination,
__in LONG Value
);

LONG
__cdecl
InterlockedXorAcquire (
__inout __drv_interlocked LONG volatile *Destination,
__in LONG Value
);

LONG
__cdecl
InterlockedXorRelease (
__inout __drv_interlocked LONG volatile *Destination,
__in LONG Value
);

CHAR
__cdecl
InterlockedXor8 (
__inout __drv_interlocked CHAR volatile *Destination,
__in CHAR Value
);

CHAR
__cdecl
InterlockedXor8Acquire (
__inout __drv_interlocked CHAR volatile *Destination,
__in CHAR Value
);

CHAR
__cdecl
InterlockedXor8Release (
__inout __drv_interlocked CHAR volatile *Destination,
__in CHAR Value
);

SHORT
__cdecl
InterlockedXor16(
__inout __drv_interlocked SHORT volatile *Destination,
__in SHORT Value
);

SHORT
__cdecl
InterlockedXor16Acquire (
__inout __drv_interlocked SHORT volatile *Destination,
__in SHORT Value
);

SHORT
__cdecl
InterlockedXor16Release (
__inout __drv_interlocked SHORT volatile *Destination,
__in SHORT Value
);

LONGLONG
__cdecl
InterlockedXor64 (
__inout __drv_interlocked LONGLONG volatile *Destination,
__in LONGLONG Value
);

LONGLONG
__cdecl
InterlockedXor64Acquire (
__inout __drv_interlocked LONGLONG volatile *Destination,
__in LONGLONG Value
);

LONGLONG
__cdecl
InterlockedXor64Release (
__inout __drv_interlocked LONGLONG volatile *Destination,
__in LONGLONG Value
);

LONG
__cdecl
InterlockedAnd (
__inout __drv_interlocked LONG volatile *Destination,
__in LONG Value
);

LONG
__cdecl
InterlockedAndAcquire (
__inout __drv_interlocked LONG volatile *Destination,
__in LONG Value
);

LONG
__cdecl
InterlockedAndRelease (
__inout __drv_interlocked LONG volatile *Destination,
__in LONG Value
);

CHAR
__cdecl
InterlockedAnd8 (
__inout __drv_interlocked CHAR volatile *Destination,
__in CHAR Value
);

CHAR
__cdecl
InterlockedAnd8Acquire (
__inout __drv_interlocked CHAR volatile *Destination,
__in CHAR Value
);

CHAR
__cdecl
InterlockedAnd8Release (
__inout __drv_interlocked CHAR volatile *Destination,
__in CHAR Value
);

SHORT
__cdecl
InterlockedAnd16(
__inout __drv_interlocked SHORT volatile *Destination,
__in SHORT Value
);

SHORT
__cdecl
InterlockedAnd16Acquire (
__inout __drv_interlocked SHORT volatile *Destination,
__in SHORT Value
);

SHORT
__cdecl
InterlockedAnd16Release (
__inout __drv_interlocked SHORT volatile *Destination,
__in SHORT Value
);

LONGLONG
__cdecl
InterlockedAnd64 (
__inout __drv_interlocked LONGLONG volatile *Destination,
__in LONGLONG Value
);

LONGLONG
__cdecl
InterlockedAnd64Acquire (
__inout __drv_interlocked LONGLONG volatile *Destination,
__in LONGLONG Value
);

LONGLONG
__cdecl
InterlockedAnd64Release (
__inout __drv_interlocked LONGLONG volatile *Destination,
__in LONGLONG Value
);

#pragma intrinsic(_InterlockedAdd)
#pragma intrinsic(_InterlockedIncrement)
#pragma intrinsic(_InterlockedIncrement_acq)
#pragma intrinsic(_InterlockedIncrement_rel)
#pragma intrinsic(_InterlockedDecrement)
#pragma intrinsic(_InterlockedDecrement_acq)
#pragma intrinsic(_InterlockedDecrement_rel)
#pragma intrinsic(_InterlockedExchange)
#pragma intrinsic(_InterlockedCompareExchange)
#pragma intrinsic(_InterlockedCompareExchange_acq)
#pragma intrinsic(_InterlockedCompareExchange_rel)
#pragma intrinsic(_InterlockedExchangeAdd)
#pragma intrinsic(_InterlockedAdd64)
#pragma intrinsic(_InterlockedIncrement64)
#pragma intrinsic(_InterlockedDecrement64)
#pragma intrinsic(_InterlockedExchange64)
#pragma intrinsic(_InterlockedExchange64_acq)
#pragma intrinsic(_InterlockedCompareExchange64)
#pragma intrinsic(_InterlockedCompareExchange64_acq)
#pragma intrinsic(_InterlockedCompareExchange64_rel)
#pragma intrinsic(_InterlockedCompare64Exchange128)
#pragma intrinsic(_InterlockedCompare64Exchange128_acq)
#pragma intrinsic(_InterlockedCompare64Exchange128_rel)
#pragma intrinsic(_InterlockedExchangeAdd64)
#pragma intrinsic(_InterlockedExchangePointer)
#pragma intrinsic(_InterlockedCompareExchangePointer)
#pragma intrinsic(_InterlockedCompareExchangePointer_acq)
#pragma intrinsic(_InterlockedCompareExchangePointer_rel)
#pragma intrinsic(_InterlockedAdd_acq)
#pragma intrinsic(_InterlockedAdd_rel)
#pragma intrinsic(_InterlockedExchange_acq)
#pragma intrinsic(_InterlockedExchangeAdd_acq)
#pragma intrinsic(_InterlockedExchangeAdd_rel)
#pragma intrinsic(_InterlockedAdd64_acq)
#pragma intrinsic(_InterlockedAdd64_rel)
#pragma intrinsic(_InterlockedIncrement64_acq)
#pragma intrinsic(_InterlockedIncrement64_rel)
#pragma intrinsic(_InterlockedDecrement64_acq)
#pragma intrinsic(_InterlockedDecrement64_rel)
#pragma intrinsic(_InterlockedExchangeAdd64_acq)
#pragma intrinsic(_InterlockedExchangeAdd64_rel)
#pragma intrinsic(_InterlockedExchangePointer_acq)
#pragma intrinsic (_InterlockedOr)
#pragma intrinsic (_InterlockedOr_acq)
#pragma intrinsic (_InterlockedOr_rel)
#pragma intrinsic (_InterlockedOr8)
#pragma intrinsic (_InterlockedOr8_acq)
#pragma intrinsic (_InterlockedOr8_rel)
#pragma intrinsic (_InterlockedOr16)
#pragma intrinsic (_InterlockedOr16_acq)
#pragma intrinsic (_InterlockedOr16_rel)
#pragma intrinsic (_InterlockedOr64)
#pragma intrinsic (_InterlockedOr64_acq)
#pragma intrinsic (_InterlockedOr64_rel)
#pragma intrinsic (_InterlockedXor)
#pragma intrinsic (_InterlockedXor_acq)
#pragma intrinsic (_InterlockedXor_rel)
#pragma intrinsic (_InterlockedXor8)
#pragma intrinsic (_InterlockedXor8_acq)
#pragma intrinsic (_InterlockedXor8_rel)
#pragma intrinsic (_InterlockedXor16)
#pragma intrinsic (_InterlockedXor16_acq)
#pragma intrinsic (_InterlockedXor16_rel)
#pragma intrinsic (_InterlockedXor64)
#pragma intrinsic (_InterlockedXor64_acq)
#pragma intrinsic (_InterlockedXor64_rel)
#pragma intrinsic (_InterlockedAnd)
#pragma intrinsic (_InterlockedAnd_acq)
#pragma intrinsic (_InterlockedAnd_rel)
#pragma intrinsic (_InterlockedAnd8)
#pragma intrinsic (_InterlockedAnd8_acq)
#pragma intrinsic (_InterlockedAnd8_rel)
#pragma intrinsic (_InterlockedAnd16)
#pragma intrinsic (_InterlockedAnd16_acq)
#pragma intrinsic (_InterlockedAnd16_rel)
#pragma intrinsic (_InterlockedAnd64)
#pragma intrinsic (_InterlockedAnd64_acq)
#pragma intrinsic (_InterlockedAnd64_rel)

#if !defined (InterlockedAnd64)

#define InterlockedAnd64 InterlockedAnd64_Inline

LONGLONG
FORCEINLINE
InterlockedAnd64_Inline (
__inout __drv_interlocked LONGLONG volatile *Destination,
__in LONGLONG Value
)
{
LONGLONG Old;

do {
Old = *Destination;
} while (InterlockedCompareExchange64(Destination,
Old & Value,
Old) != Old);

return Old;
}

#endif

#define InterlockedAndAffinity InterlockedAnd64

#if !defined (InterlockedOr64)

#define InterlockedOr64 InterlockedOr64_Inline

LONGLONG
FORCEINLINE
InterlockedOr64_Inline (
__inout __drv_interlocked LONGLONG volatile *Destination,
__in LONGLONG Value
)
{
LONGLONG Old;

do {
Old = *Destination;
} while (InterlockedCompareExchange64(Destination,
Old | Value,
Old) != Old);

return Old;
}

#endif

#define InterlockedOrAffinity InterlockedOr64

#if !defined (InterlockedXor64)

#define InterlockedXor64 InterlockedXor64_Inline

LONGLONG
FORCEINLINE
InterlockedXor64_Inline (
__inout __drv_interlocked LONGLONG volatile *Destination,
__in LONGLONG Value
)
{
LONGLONG Old;

do {
Old = *Destination;
} while (InterlockedCompareExchange64(Destination,
Old ^ Value,
Old) != Old);

return Old;
}

#endif

#if !defined (InterlockedBitTestAndSet)

#define InterlockedBitTestAndSet InterlockedBitTestAndSet_Inline

BOOLEAN
FORCEINLINE
InterlockedBitTestAndSet_Inline (
__inout __drv_interlocked LONG volatile *Base,
__in LONG Bit
)
{
LONG tBit;

tBit = 1<<(Bit & (sizeof (*Base)*8-1));
return (BOOLEAN) ((InterlockedOr (&Base[Bit/(sizeof (*Base)*8)], tBit)&tBit) != 0);
}

#endif

#if !defined (InterlockedBitTestAndReset)

#define InterlockedBitTestAndReset InterlockedBitTestAndReset_Inline

BOOLEAN
FORCEINLINE
InterlockedBitTestAndReset_Inline (
__inout __drv_interlocked LONG volatile *Base,
__in LONG Bit
)
{
LONG tBit;

tBit = 1<<(Bit & (sizeof (*Base)*8-1));
return (BOOLEAN) ((InterlockedAnd (&Base[Bit/(sizeof (*Base)*8)], ~tBit)&tBit) != 0);
}

#endif

#if !defined (InterlockedBitTestAndSet64)

#define InterlockedBitTestAndSet64 InterlockedBitTestAndSet64_Inline

BOOLEAN
FORCEINLINE
InterlockedBitTestAndSet64_Inline (
__inout __drv_interlocked LONG64 volatile *Base,
__in LONG64 Bit
)
{
LONG64 tBit;

tBit = 1i64<<(Bit & (sizeof (*Base)*8-1));
return (BOOLEAN) ((InterlockedOr64 (&Base[Bit/(sizeof (*Base)*8)], tBit)&tBit) != 0);
}

#endif

#if !defined (InterlockedBitTestAndReset64)

#define InterlockedBitTestAndReset64 InterlockedBitTestAndReset64_Inline

BOOLEAN
FORCEINLINE
InterlockedBitTestAndReset64_Inline (
__inout __drv_interlocked LONG64 volatile *Base,
__in LONG64 Bit
)
{
LONG64 tBit;

tBit = 1i64<<(Bit & (sizeof (*Base)*8-1));
return (BOOLEAN) ((InterlockedAnd64 (&Base[Bit/(sizeof (*Base)*8)], ~tBit)&tBit) != 0);
}

#endif

#if !defined (InterlockedBitTestAndComplement)

#define InterlockedBitTestAndComplement InterlockedBitTestAndComplement_Inline

BOOLEAN
FORCEINLINE
InterlockedBitTestAndComplement_Inline (
__inout __drv_interlocked LONG volatile *Base,
__in LONG Bit
)
{
LONG tBit;

tBit = 1<<(Bit & (sizeof (*Base)*8-1));
return (BOOLEAN) ((InterlockedXor (&Base[Bit/(sizeof (*Base)*8)], tBit)&tBit) != 0);
}

#endif

#if !defined (InterlockedBitTestAndComplement64)

#define InterlockedBitTestAndComplement64 InterlockedBitTestAndComplement64_Inline

BOOLEAN
FORCEINLINE
InterlockedBitTestAndComplement64_Inline (
__inout __drv_interlocked LONG64 volatile *Base,
__in LONG64 Bit
)
{
LONG64 tBit;

tBit = 1i64<<(Bit & (sizeof (*Base)*8-1));
return (BOOLEAN) ((InterlockedXor64 (&Base[Bit/(sizeof (*Base)*8)], tBit)&tBit) != 0);
}

#endif

#ifdef __cplusplus
}
#endif

#endif /* defined(_M_IA64) && !defined(RC_INVOKED) && !defined(MIDL_PASS) */


#if !defined(__midl) && !defined(GENUTIL) && !defined(_GENIA64_) && defined(_IA64_)

void * __cdecl _rdteb(void);
void * __cdecl _rdtebex(void);
#ifdef _M_IA64

#pragma intrinsic(_rdteb)
// _rdtebex() is a kernel safe version of _rdteb()
#pragma intrinsic(_rdtebex)
#define NtCurrentTeb() ((struct _TEB *)_rdtebex())

//
// Define functions to get the address of the current fiber and the
// current fiber data.
//

#define GetCurrentFiber() (((PNT_TIB)NtCurrentTeb())->FiberData)
#define GetFiberData() (*(PVOID *)(GetCurrentFiber()))


// begin_ntddk

#ifdef __cplusplus
extern "C" {
#endif

// end_ntddk
// begin_wdm

#if defined(_IA64_) && defined(_M_IA64) && !defined(RC_INVOKED) && !defined(MIDL_PASS)

void
__break(
__in int StIIM
);

#pragma intrinsic (__break)

#define BREAK_DEBUG_BASE 0x080000
#define ASSERT_BREAKPOINT (BREAK_DEBUG_BASE+3) // Cause a STATUS_ASSERTION_FAILURE exception to be raised.

__analysis_noreturn
FORCEINLINE
VOID
DbgRaiseAssertionFailure (
VOID
)

{
__break(ASSERT_BREAKPOINT);
}

#endif

// end_wdm
// begin_ntddk

void
__yield(
void
);

void
__mf(
void
);

void
__lfetch(
int Level,
__in volatile VOID CONST *Address
);

void
__lfetchfault(
__in int Level,
__in volatile VOID CONST *Address
);

void
__lfetch_excl(
__in int Level,
__in volatile VOID CONST *Address
);

void
__lfetchfault_excl(
__in int Level,
__in volatile VOID CONST *Address
);

//
// __lfetch control defines.
//

#define MD_LFHINT_NONE 0x00
#define MD_LFHINT_NT1 0x01
#define MD_LFHINT_NT2 0x02
#define MD_LFHINT_NTA 0x03

#pragma intrinsic (__yield)
#pragma intrinsic (__lfetch)
#pragma intrinsic (__lfetchfault)
#pragma intrinsic (__lfetchfault_excl)
#pragma intrinsic (__lfetch_excl)
#pragma intrinsic (__mf)

//
// Define function to read the value of the time stamp counter
//
// N.B. The register number for the time stamp counter is CV_IA64_ApITC which
// is 3116.
//

#define ReadTimeStampCounter() __getReg(3116)

unsigned __int64
__getReg (
__in int Number
);

#pragma intrinsic(__getReg)

#define YieldProcessor __yield
#define MemoryBarrier __mf
#define PreFetchCacheLine __lfetch
#define PrefetchForWrite(p)
#define ReadForWriteAccess(p) (__lfetch_excl(MD_LFHINT_NONE, (p)), (*(p)))


//
// PreFetchCacheLine level defines.
//

#define PF_TEMPORAL_LEVEL_1 MD_LFHINT_NONE
#define PF_TEMPORAL_LEVEL_2 MD_LFHINT_NT1
#define PF_TEMPORAL_LEVEL_3 MD_LFHINT_NT2
#define PF_NON_TEMPORAL_LEVEL_ALL MD_LFHINT_NTA

//
// Define functions to capture the high 64-bits of a 128-bit multiply.
//

#define UnsignedMultiplyHigh __UMULH

ULONGLONG
UnsignedMultiplyHigh (
__in ULONGLONG Multiplier,
__in ULONGLONG Multiplicand
);

#pragma intrinsic(__UMULH)

#if (_MSC_VER >= 1400)

#define UnsignedMultiply128 _umul128

DWORD64
UnsignedMultiply128 (
__in unsigned __int64 Multiplier,
__in unsigned __int64 Multiplicand,
__out __deref_out_range(==,Multiplier * Multiplicand) unsigned __int64 *HighProduct
);

#pragma intrinsic(_umul128)

#endif

#ifdef __cplusplus
}
#endif

// end_ntddk

#else
struct _TEB *
NtCurrentTeb(void);
#endif

#endif // !defined(__midl) && !defined(GENUTIL) && !defined(_GENIA64_) && defined(_M_IA64)

#ifdef _IA64_

// begin_ntddk

//
// The following values specify the type of failing access when the status is
// STATUS_ACCESS_VIOLATION and the first parameter in the exception record.
//

#define EXCEPTION_READ_FAULT 0 // Access violation was caused by a read
#define EXCEPTION_WRITE_FAULT 1 // Access violation was caused by a write
#define EXCEPTION_EXECUTE_FAULT 2 // Access violation was caused by an instruction fetch

//
// The following flags control the contents of the CONTEXT structure.
//

#if !defined(RC_INVOKED)

#define CONTEXT_IA64 0x00080000

#define CONTEXT_CONTROL (CONTEXT_IA64 | 0x00000001L)
#define CONTEXT_LOWER_FLOATING_POINT (CONTEXT_IA64 | 0x00000002L)
#define CONTEXT_HIGHER_FLOATING_POINT (CONTEXT_IA64 | 0x00000004L)
#define CONTEXT_INTEGER (CONTEXT_IA64 | 0x00000008L)
#define CONTEXT_DEBUG (CONTEXT_IA64 | 0x00000010L)
#define CONTEXT_IA32_CONTROL (CONTEXT_IA64 | 0x00000020L) // Includes StIPSR


#define CONTEXT_FLOATING_POINT (CONTEXT_LOWER_FLOATING_POINT | CONTEXT_HIGHER_FLOATING_POINT)
#define CONTEXT_FULL (CONTEXT_CONTROL | CONTEXT_FLOATING_POINT | CONTEXT_INTEGER | CONTEXT_IA32_CONTROL)
#define CONTEXT_ALL (CONTEXT_CONTROL | CONTEXT_FLOATING_POINT | CONTEXT_INTEGER | CONTEXT_DEBUG | CONTEXT_IA32_CONTROL)

#define CONTEXT_EXCEPTION_ACTIVE 0x8000000
#define CONTEXT_SERVICE_ACTIVE 0x10000000
#define CONTEXT_EXCEPTION_REQUEST 0x40000000
#define CONTEXT_EXCEPTION_REPORTING 0x80000000

#endif // !defined(RC_INVOKED)

//
// Context Frame
//
// This frame has a several purposes: 1) it is used as an argument to
// NtContinue, 2) it is used to construct a call frame for APC delivery,
// 3) it is used to construct a call frame for exception dispatching
// in user mode, 4) it is used in the user level thread creation
// routines, and 5) it is used to to pass thread state to debuggers.
//
// N.B. Because this record is used as a call frame, it must be EXACTLY
// a multiple of 16 bytes in length and aligned on a 16-byte boundary.
//

typedef struct _CONTEXT {

//
// The flags values within this flag control the contents of
// a CONTEXT record.
//
// If the context record is used as an input parameter, then
// for each portion of the context record controlled by a flag
// whose value is set, it is assumed that that portion of the
// context record contains valid context. If the context record
// is being used to modify a thread‘s context, then only that
// portion of the threads context will be modified.
//
// If the context record is used as an __inout parameter to capture
// the context of a thread, then only those portions of the thread‘s
// context corresponding to set flags will be returned.
//
// The context record is never used as an __out only parameter.
//

DWORD ContextFlags;
DWORD Fill1[3]; // for alignment of following on 16-byte boundary

//
// This section is specified/returned if the ContextFlags word contains
// the flag CONTEXT_DEBUG.
//
// N.B. CONTEXT_DEBUG is *not* part of CONTEXT_FULL.
//

ULONGLONG DbI0;
ULONGLONG DbI1;
ULONGLONG DbI2;
ULONGLONG DbI3;
ULONGLONG DbI4;
ULONGLONG DbI5;
ULONGLONG DbI6;
ULONGLONG DbI7;

ULONGLONG DbD0;
ULONGLONG DbD1;
ULONGLONG DbD2;
ULONGLONG DbD3;
ULONGLONG DbD4;
ULONGLONG DbD5;
ULONGLONG DbD6;
ULONGLONG DbD7;

//
// This section is specified/returned if the ContextFlags word contains
// the flag CONTEXT_LOWER_FLOATING_POINT.
//

FLOAT128 FltS0;
FLOAT128 FltS1;
FLOAT128 FltS2;
FLOAT128 FltS3;
FLOAT128 FltT0;
FLOAT128 FltT1;
FLOAT128 FltT2;
FLOAT128 FltT3;
FLOAT128 FltT4;
FLOAT128 FltT5;
FLOAT128 FltT6;
FLOAT128 FltT7;
FLOAT128 FltT8;
FLOAT128 FltT9;

//
// This section is specified/returned if the ContextFlags word contains
// the flag CONTEXT_HIGHER_FLOATING_POINT.
//

FLOAT128 FltS4;
FLOAT128 FltS5;
FLOAT128 FltS6;
FLOAT128 FltS7;
FLOAT128 FltS8;
FLOAT128 FltS9;
FLOAT128 FltS10;
FLOAT128 FltS11;
FLOAT128 FltS12;
FLOAT128 FltS13;
FLOAT128 FltS14;
FLOAT128 FltS15;
FLOAT128 FltS16;
FLOAT128 FltS17;
FLOAT128 FltS18;
FLOAT128 FltS19;

FLOAT128 FltF32;
FLOAT128 FltF33;
FLOAT128 FltF34;
FLOAT128 FltF35;
FLOAT128 FltF36;
FLOAT128 FltF37;
FLOAT128 FltF38;
FLOAT128 FltF39;

FLOAT128 FltF40;
FLOAT128 FltF41;
FLOAT128 FltF42;
FLOAT128 FltF43;
FLOAT128 FltF44;
FLOAT128 FltF45;
FLOAT128 FltF46;
FLOAT128 FltF47;
FLOAT128 FltF48;
FLOAT128 FltF49;

FLOAT128 FltF50;
FLOAT128 FltF51;
FLOAT128 FltF52;
FLOAT128 FltF53;
FLOAT128 FltF54;
FLOAT128 FltF55;
FLOAT128 FltF56;
FLOAT128 FltF57;
FLOAT128 FltF58;
FLOAT128 FltF59;

FLOAT128 FltF60;
FLOAT128 FltF61;
FLOAT128 FltF62;
FLOAT128 FltF63;
FLOAT128 FltF64;
FLOAT128 FltF65;
FLOAT128 FltF66;
FLOAT128 FltF67;
FLOAT128 FltF68;
FLOAT128 FltF69;

FLOAT128 FltF70;
FLOAT128 FltF71;
FLOAT128 FltF72;
FLOAT128 FltF73;
FLOAT128 FltF74;
FLOAT128 FltF75;
FLOAT128 FltF76;
FLOAT128 FltF77;
FLOAT128 FltF78;
FLOAT128 FltF79;

FLOAT128 FltF80;
FLOAT128 FltF81;
FLOAT128 FltF82;
FLOAT128 FltF83;
FLOAT128 FltF84;
FLOAT128 FltF85;
FLOAT128 FltF86;
FLOAT128 FltF87;
FLOAT128 FltF88;
FLOAT128 FltF89;

FLOAT128 FltF90;
FLOAT128 FltF91;
FLOAT128 FltF92;
FLOAT128 FltF93;
FLOAT128 FltF94;
FLOAT128 FltF95;
FLOAT128 FltF96;
FLOAT128 FltF97;
FLOAT128 FltF98;
FLOAT128 FltF99;

FLOAT128 FltF100;
FLOAT128 FltF101;
FLOAT128 FltF102;
FLOAT128 FltF103;
FLOAT128 FltF104;
FLOAT128 FltF105;
FLOAT128 FltF106;
FLOAT128 FltF107;
FLOAT128 FltF108;
FLOAT128 FltF109;

FLOAT128 FltF110;
FLOAT128 FltF111;
FLOAT128 FltF112;
FLOAT128 FltF113;
FLOAT128 FltF114;
FLOAT128 FltF115;
FLOAT128 FltF116;
FLOAT128 FltF117;
FLOAT128 FltF118;
FLOAT128 FltF119;

FLOAT128 FltF120;
FLOAT128 FltF121;
FLOAT128 FltF122;
FLOAT128 FltF123;
FLOAT128 FltF124;
FLOAT128 FltF125;
FLOAT128 FltF126;
FLOAT128 FltF127;

//
// This section is specified/returned if the ContextFlags word contains
// the flag CONTEXT_LOWER_FLOATING_POINT | CONTEXT_HIGHER_FLOATING_POINT | CONTEXT_CONTROL.
//

ULONGLONG StFPSR; // FP status

//
// This section is specified/returned if the ContextFlags word contains
// the flag CONTEXT_INTEGER.
//
// N.B. The registers gp, sp, rp are part of the control context
//

ULONGLONG IntGp; // r1, volatile
ULONGLONG IntT0; // r2-r3, volatile
ULONGLONG IntT1; //
ULONGLONG IntS0; // r4-r7, preserved
ULONGLONG IntS1;
ULONGLONG IntS2;
ULONGLONG IntS3;
ULONGLONG IntV0; // r8, volatile
ULONGLONG IntT2; // r9-r11, volatile
ULONGLONG IntT3;
ULONGLONG IntT4;
ULONGLONG IntSp; // stack pointer (r12), special
ULONGLONG IntTeb; // teb (r13), special
ULONGLONG IntT5; // r14-r31, volatile
ULONGLONG IntT6;
ULONGLONG IntT7;
ULONGLONG IntT8;
ULONGLONG IntT9;
ULONGLONG IntT10;
ULONGLONG IntT11;
ULONGLONG IntT12;
ULONGLONG IntT13;
ULONGLONG IntT14;
ULONGLONG IntT15;
ULONGLONG IntT16;
ULONGLONG IntT17;
ULONGLONG IntT18;
ULONGLONG IntT19;
ULONGLONG IntT20;
ULONGLONG IntT21;
ULONGLONG IntT22;

ULONGLONG IntNats; // Nat bits for r1-r31
// r1-r31 in bits 1 thru 31.
ULONGLONG Preds; // predicates, preserved

ULONGLONG BrRp; // return pointer, b0, preserved
ULONGLONG BrS0; // b1-b5, preserved
ULONGLONG BrS1;
ULONGLONG BrS2;
ULONGLONG BrS3;
ULONGLONG BrS4;
ULONGLONG BrT0; // b6-b7, volatile
ULONGLONG BrT1;

//
// This section is specified/returned if the ContextFlags word contains
// the flag CONTEXT_CONTROL.
//

// Other application registers
ULONGLONG ApUNAT; // User Nat collection register, preserved
ULONGLONG ApLC; // Loop counter register, preserved
ULONGLONG ApEC; // Epilog counter register, preserved
ULONGLONG ApCCV; // CMPXCHG value register, volatile
ULONGLONG ApDCR; // Default control register (TBD)

// Register stack info
ULONGLONG RsPFS; // Previous function state, preserved
ULONGLONG RsBSP; // Backing store pointer, preserved
ULONGLONG RsBSPSTORE;
ULONGLONG RsRSC; // RSE configuration, volatile
ULONGLONG RsRNAT; // RSE Nat collection register, preserved

// Trap Status Information
ULONGLONG StIPSR; // Interruption Processor Status
ULONGLONG StIIP; // Interruption IP
ULONGLONG StIFS; // Interruption Function State

// iA32 related control registers
ULONGLONG StFCR; // copy of Ar21
ULONGLONG Eflag; // Eflag copy of Ar24
ULONGLONG SegCSD; // iA32 CSDescriptor (Ar25)
ULONGLONG SegSSD; // iA32 SSDescriptor (Ar26)
ULONGLONG Cflag; // Cr0+Cr4 copy of Ar27
ULONGLONG StFSR; // x86 FP status (copy of AR28)
ULONGLONG StFIR; // x86 FP status (copy of AR29)
ULONGLONG StFDR; // x86 FP status (copy of AR30)

ULONGLONG UNUSEDPACK; // added to pack StFDR to 16-bytes

} CONTEXT, *PCONTEXT;

//
// Plabel descriptor structure definition
//

typedef struct _PLABEL_DESCRIPTOR {
ULONGLONG EntryPoint;
ULONGLONG GlobalPointer;
} PLABEL_DESCRIPTOR, *PPLABEL_DESCRIPTOR;

//
// Function table entry structure definition.
//

typedef struct _RUNTIME_FUNCTION {
DWORD BeginAddress;
DWORD EndAddress;
DWORD UnwindInfoAddress;
} RUNTIME_FUNCTION, *PRUNTIME_FUNCTION;

//
// Define unwind history table structure.
//

#define UNWIND_HISTORY_TABLE_SIZE 12

typedef struct _UNWIND_HISTORY_TABLE_ENTRY {
DWORD64 ImageBase;
DWORD64 Gp;
PRUNTIME_FUNCTION FunctionEntry;
} UNWIND_HISTORY_TABLE_ENTRY, *PUNWIND_HISTORY_TABLE_ENTRY;

typedef struct _UNWIND_HISTORY_TABLE {
DWORD Count;
BYTE LocalHint;
BYTE GlobalHint;
BYTE Search;
BYTE Once;
DWORD64 LowAddress;
DWORD64 HighAddress;
UNWIND_HISTORY_TABLE_ENTRY Entry[UNWIND_HISTORY_TABLE_SIZE];
} UNWIND_HISTORY_TABLE, *PUNWIND_HISTORY_TABLE;

//
// Define dynamic function table entry.
//

typedef
__drv_functionClass(GET_RUNTIME_FUNCTION_CALLBACK)
PRUNTIME_FUNCTION
GET_RUNTIME_FUNCTION_CALLBACK (
__in DWORD64 ControlPc,
__in_opt PVOID Context
);
typedef GET_RUNTIME_FUNCTION_CALLBACK *PGET_RUNTIME_FUNCTION_CALLBACK;

typedef
__drv_functionClass(OUT_OF_PROCESS_FUNCTION_TABLE_CALLBACK)
__checkReturn
DWORD
OUT_OF_PROCESS_FUNCTION_TABLE_CALLBACK (
__in HANDLE Process,
__in PVOID TableAddress,
__out PDWORD Entries,
__deref_out PRUNTIME_FUNCTION* Functions
);
typedef OUT_OF_PROCESS_FUNCTION_TABLE_CALLBACK *POUT_OF_PROCESS_FUNCTION_TABLE_CALLBACK;

#define OUT_OF_PROCESS_FUNCTION_TABLE_CALLBACK_EXPORT_NAME \
"OutOfProcessFunctionTableCallback"

__drv_maxIRQL(PASSIVE_LEVEL)
__success(return!=0)
NTSYSAPI
BOOLEAN
NTAPI
RtlAddFunctionTable(
__in_ecount(EntryCount) PRUNTIME_FUNCTION FunctionTable,
__in DWORD EntryCount,
__in ULONGLONG BaseAddress,
__in ULONGLONG TargetGp
);

__drv_maxIRQL(PASSIVE_LEVEL)
__success(return!=0)
NTSYSAPI
BOOLEAN
NTAPI
RtlInstallFunctionTableCallback (
__in DWORD64 TableIdentifier,
__in DWORD64 BaseAddress,
__in DWORD Length,
__in DWORD64 TargetGp,
__in PGET_RUNTIME_FUNCTION_CALLBACK Callback,
__in_opt PVOID Context,
__in_opt PCWSTR OutOfProcessCallbackDll
);

__drv_maxIRQL(PASSIVE_LEVEL)
__success(return!=0)
NTSYSAPI
BOOLEAN
NTAPI
RtlDeleteFunctionTable (
__in PRUNTIME_FUNCTION FunctionTable
);

__drv_maxIRQL(SYNCH_LEVEL)
__drv_minIRQL(PASSIVE_LEVEL)
NTSYSAPI
PRUNTIME_FUNCTION
NTAPI
RtlLookupFunctionEntry (
__in ULONGLONG ControlPc,
__out PULONGLONG ImageBase,
__out PULONGLONG TargetGp
);

//
// Nonvolatile context pointer record.
//
// The IA64 architecture currently doesn‘t have any nonvolatile kernel context
// as we capture everything in either the trap or exception frames on
// transition from user to kernel mode. We allocate a single bogus
// pointer field as usually this structure is made up of pointers to
// places in the kernel stack where the various nonvolatile items were
// pushed on to the kernel stack.
//
// TBD *** Need to fill in this structure with the relevant fields
// when we start storing the nonvolatile information only when
// necessary.
//

typedef struct _KNONVOLATILE_CONTEXT_POINTERS {
PFLOAT128 FltS0;
PFLOAT128 FltS1;
PFLOAT128 FltS2;
PFLOAT128 FltS3;
PFLOAT128 HighFloatingContext[10];
PFLOAT128 FltS4;
PFLOAT128 FltS5;
PFLOAT128 FltS6;
PFLOAT128 FltS7;
PFLOAT128 FltS8;
PFLOAT128 FltS9;
PFLOAT128 FltS10;
PFLOAT128 FltS11;
PFLOAT128 FltS12;
PFLOAT128 FltS13;
PFLOAT128 FltS14;
PFLOAT128 FltS15;
PFLOAT128 FltS16;
PFLOAT128 FltS17;
PFLOAT128 FltS18;
PFLOAT128 FltS19;

PULONGLONG IntS0;
PULONGLONG IntS1;
PULONGLONG IntS2;
PULONGLONG IntS3;
PULONGLONG IntSp;
PULONGLONG IntS0Nat;
PULONGLONG IntS1Nat;
PULONGLONG IntS2Nat;
PULONGLONG IntS3Nat;
PULONGLONG IntSpNat;

PULONGLONG Preds;

PULONGLONG BrRp;
PULONGLONG BrS0;
PULONGLONG BrS1;
PULONGLONG BrS2;
PULONGLONG BrS3;
PULONGLONG BrS4;

PULONGLONG ApUNAT;
PULONGLONG ApLC;
PULONGLONG ApEC;
PULONGLONG RsPFS;

PULONGLONG StFSR;
PULONGLONG StFIR;
PULONGLONG StFDR;
PULONGLONG Cflag;

PULONGLONG StFPSR;

} KNONVOLATILE_CONTEXT_POINTERS, *PKNONVOLATILE_CONTEXT_POINTERS;

typedef struct _FRAME_POINTERS {
ULONGLONG MemoryStackFp;
ULONGLONG BackingStoreFp;
} FRAME_POINTERS, *PFRAME_POINTERS;

NTSYSAPI
ULONGLONG
NTAPI
RtlVirtualUnwind (
__in ULONGLONG ImageBase,
__in ULONGLONG ControlPc,
__in PRUNTIME_FUNCTION FunctionEntry,
__inout PCONTEXT ContextRecord,
__out PBOOLEAN InFunction,
__out PFRAME_POINTERS EstablisherFrame,
__inout_opt PKNONVOLATILE_CONTEXT_POINTERS ContextPointers
);

NTSYSAPI
VOID
NTAPI
RtlRestoreContext (
__in PCONTEXT ContextRecord,
__in_opt struct _EXCEPTION_RECORD *ExceptionRecord
);

NTSYSAPI
VOID
NTAPI
__jump_unwind (
ULONGLONG TargetMsFrame,
ULONGLONG TargetBsFrame,
ULONGLONG TargetPc
);

#endif // _IA64_


#if !defined(RC_INVOKED)

#define WOW64_CONTEXT_i386 0x00010000 // this assumes that i386 and
#define WOW64_CONTEXT_i486 0x00010000 // i486 have identical context records

#define WOW64_CONTEXT_CONTROL (WOW64_CONTEXT_i386 | 0x00000001L) // SS:SP, CS:IP, FLAGS, BP
#define WOW64_CONTEXT_INTEGER (WOW64_CONTEXT_i386 | 0x00000002L) // AX, BX, CX, DX, SI, DI
#define WOW64_CONTEXT_SEGMENTS (WOW64_CONTEXT_i386 | 0x00000004L) // DS, ES, FS, GS
#define WOW64_CONTEXT_FLOATING_POINT (WOW64_CONTEXT_i386 | 0x00000008L) // 387 state
#define WOW64_CONTEXT_DEBUG_REGISTERS (WOW64_CONTEXT_i386 | 0x00000010L) // DB 0-3,6,7
#define WOW64_CONTEXT_EXTENDED_REGISTERS (WOW64_CONTEXT_i386 | 0x00000020L) // cpu specific extensions

#define WOW64_CONTEXT_FULL (WOW64_CONTEXT_CONTROL | WOW64_CONTEXT_INTEGER | WOW64_CONTEXT_SEGMENTS)

#define WOW64_CONTEXT_ALL (WOW64_CONTEXT_CONTROL | WOW64_CONTEXT_INTEGER | WOW64_CONTEXT_SEGMENTS | \
WOW64_CONTEXT_FLOATING_POINT | WOW64_CONTEXT_DEBUG_REGISTERS | \
WOW64_CONTEXT_EXTENDED_REGISTERS)

#define WOW64_CONTEXT_XSTATE (WOW64_CONTEXT_i386 | 0x00000040L)

#endif // !defined(RC_INVOKED)

//
// Define the size of the 80387 save area, which is in the context frame.
//

#define WOW64_SIZE_OF_80387_REGISTERS 80

#define WOW64_MAXIMUM_SUPPORTED_EXTENSION 512

typedef struct _WOW64_FLOATING_SAVE_AREA {
DWORD ControlWord;
DWORD StatusWord;
DWORD TagWord;
DWORD ErrorOffset;
DWORD ErrorSelector;
DWORD DataOffset;
DWORD DataSelector;
BYTE RegisterArea[WOW64_SIZE_OF_80387_REGISTERS];
DWORD Cr0NpxState;
} WOW64_FLOATING_SAVE_AREA;

typedef WOW64_FLOATING_SAVE_AREA *PWOW64_FLOATING_SAVE_AREA;

#include "pshpack4.h"

//
// Context Frame
//
// This frame has a several purposes: 1) it is used as an argument to
// NtContinue, 2) is is used to constuct a call frame for APC delivery,
// and 3) it is used in the user level thread creation routines.
//
// The layout of the record conforms to a standard call frame.
//

typedef struct _WOW64_CONTEXT {

//
// The flags values within this flag control the contents of
// a CONTEXT record.
//
// If the context record is used as an input parameter, then
// for each portion of the context record controlled by a flag
// whose value is set, it is assumed that that portion of the
// context record contains valid context. If the context record
// is being used to modify a threads context, then only that
// portion of the threads context will be modified.
//
// If the context record is used as an IN OUT parameter to capture
// the context of a thread, then only those portions of the thread‘s
// context corresponding to set flags will be returned.
//
// The context record is never used as an OUT only parameter.
//

DWORD ContextFlags;

//
// This section is specified/returned if CONTEXT_DEBUG_REGISTERS is
// set in ContextFlags. Note that CONTEXT_DEBUG_REGISTERS is NOT
// included in CONTEXT_FULL.
//

DWORD Dr0;
DWORD Dr1;
DWORD Dr2;
DWORD Dr3;
DWORD Dr6;
DWORD Dr7;

//
// This section is specified/returned if the
// ContextFlags word contians the flag CONTEXT_FLOATING_POINT.
//

WOW64_FLOATING_SAVE_AREA FloatSave;

//
// This section is specified/returned if the
// ContextFlags word contians the flag CONTEXT_SEGMENTS.
//

DWORD SegGs;
DWORD SegFs;
DWORD SegEs;
DWORD SegDs;

//
// This section is specified/returned if the
// ContextFlags word contians the flag CONTEXT_INTEGER.
//

DWORD Edi;
DWORD Esi;
DWORD Ebx;
DWORD Edx;
DWORD Ecx;
DWORD Eax;

//
// This section is specified/returned if the
// ContextFlags word contians the flag CONTEXT_CONTROL.
//

DWORD Ebp;
DWORD Eip;
DWORD SegCs; // MUST BE SANITIZED
DWORD EFlags; // MUST BE SANITIZED
DWORD Esp;
DWORD SegSs;

//
// This section is specified/returned if the ContextFlags word
// contains the flag CONTEXT_EXTENDED_REGISTERS.
// The format and contexts are processor specific
//

BYTE ExtendedRegisters[WOW64_MAXIMUM_SUPPORTED_EXTENSION];

} WOW64_CONTEXT;

typedef WOW64_CONTEXT *PWOW64_CONTEXT;

#include "poppack.h"


typedef struct _WOW64_LDT_ENTRY {
WORD LimitLow;
WORD BaseLow;
union {
struct {
BYTE BaseMid;
BYTE Flags1; // Declare as bytes to avoid alignment
BYTE Flags2; // Problems.
BYTE BaseHi;
} Bytes;
struct {
DWORD BaseMid : 8;
DWORD Type : 5;
DWORD Dpl : 2;
DWORD Pres : 1;
DWORD LimitHi : 4;
DWORD Sys : 1;
DWORD Reserved_0 : 1;
DWORD Default_Big : 1;
DWORD Granularity : 1;
DWORD BaseHi : 8;
} Bits;
} HighWord;
} WOW64_LDT_ENTRY, *PWOW64_LDT_ENTRY;

typedef struct _WOW64_DESCRIPTOR_TABLE_ENTRY {
DWORD Selector;
WOW64_LDT_ENTRY Descriptor;
} WOW64_DESCRIPTOR_TABLE_ENTRY, *PWOW64_DESCRIPTOR_TABLE_ENTRY;

#define EXCEPTION_NONCONTINUABLE 0x1 // Noncontinuable exception
#define EXCEPTION_MAXIMUM_PARAMETERS 15 // maximum number of exception parameters

//
// Exception record definition.
//

typedef struct _EXCEPTION_RECORD {
DWORD ExceptionCode;
DWORD ExceptionFlags;
struct _EXCEPTION_RECORD *ExceptionRecord;
PVOID ExceptionAddress;
DWORD NumberParameters;
ULONG_PTR ExceptionInformation[EXCEPTION_MAXIMUM_PARAMETERS];
} EXCEPTION_RECORD;

typedef EXCEPTION_RECORD *PEXCEPTION_RECORD;

typedef struct _EXCEPTION_RECORD32 {
DWORD ExceptionCode;
DWORD ExceptionFlags;
DWORD ExceptionRecord;
DWORD ExceptionAddress;
DWORD NumberParameters;
DWORD ExceptionInformation[EXCEPTION_MAXIMUM_PARAMETERS];
} EXCEPTION_RECORD32, *PEXCEPTION_RECORD32;

typedef struct _EXCEPTION_RECORD64 {
DWORD ExceptionCode;
DWORD ExceptionFlags;
DWORD64 ExceptionRecord;
DWORD64 ExceptionAddress;
DWORD NumberParameters;
DWORD __unusedAlignment;
DWORD64 ExceptionInformation[EXCEPTION_MAXIMUM_PARAMETERS];
} EXCEPTION_RECORD64, *PEXCEPTION_RECORD64;

//
// Typedef for pointer returned by exception_info()
//

typedef struct _EXCEPTION_POINTERS {
PEXCEPTION_RECORD ExceptionRecord;
PCONTEXT ContextRecord;
} EXCEPTION_POINTERS, *PEXCEPTION_POINTERS;

// end_wdm

NTSYSAPI
VOID
NTAPI
RtlUnwind (
__in_opt PVOID TargetFrame,
__in_opt PVOID TargetIp,
__in_opt PEXCEPTION_RECORD ExceptionRecord,
__in PVOID ReturnValue
);

#if defined(_IA64_)

NTSYSAPI
VOID
NTAPI
RtlUnwind2 (
__in_opt FRAME_POINTERS TargetFrame,
__in_opt PVOID TargetIp,
__in_opt PEXCEPTION_RECORD ExceptionRecord,
__in PVOID ReturnValue,
__in PCONTEXT ContextRecord
);

#endif

#if defined(_AMD64_)

NTSYSAPI
VOID
NTAPI
RtlUnwindEx (
__in_opt PVOID TargetFrame,
__in_opt PVOID TargetIp,
__in_opt PEXCEPTION_RECORD ExceptionRecord,
__in PVOID ReturnValue,
__in PCONTEXT ContextRecord,
__in_opt PUNWIND_HISTORY_TABLE HistoryTable
);

#elif defined(_IA64_)

NTSYSAPI
VOID
NTAPI
RtlUnwindEx (
__in_opt FRAME_POINTERS TargetFrame,
__in_opt PVOID TargetIp,
__in_opt PEXCEPTION_RECORD ExceptionRecord,
__in PVOID ReturnValue,
__in PCONTEXT ContextRecord,
__in_opt PUNWIND_HISTORY_TABLE HistoryTable
);

#endif

typedef PVOID PACCESS_TOKEN;
typedef PVOID PSECURITY_DESCRIPTOR;
typedef PVOID PSID;
////////////////////////////////////////////////////////////////////////
// //
// ACCESS MASK //
// //
////////////////////////////////////////////////////////////////////////

//
// Define the access mask as a longword sized structure divided up as
// follows:
//
// 3 3 2 2 2 2 2 2 2 2 2 2 1 1 1 1 1 1 1 1 1 1
// 1 0 9 8 7 6 5 4 3 2 1 0 9 8 7 6 5 4 3 2 1 0 9 8 7 6 5 4 3 2 1 0
// +---------------+---------------+-------------------------------+
// |G|G|G|G|Res‘d|A| StandardRights| SpecificRights |
// |R|W|E|A| |S| | |
// +-+-------------+---------------+-------------------------------+
//
// typedef struct _ACCESS_MASK {
// WORD SpecificRights;
// BYTE StandardRights;
// BYTE AccessSystemAcl : 1;
// BYTE Reserved : 3;
// BYTE GenericAll : 1;
// BYTE GenericExecute : 1;
// BYTE GenericWrite : 1;
// BYTE GenericRead : 1;
// } ACCESS_MASK;
// typedef ACCESS_MASK *PACCESS_MASK;
//
// but to make life simple for programmer‘s we‘ll allow them to specify
// a desired access mask by simply OR‘ing together mulitple single rights
// and treat an access mask as a DWORD. For example
//
// DesiredAccess = DELETE | READ_CONTROL
//
// So we‘ll declare ACCESS_MASK as DWORD
//

// begin_wdm
typedef DWORD ACCESS_MASK;
typedef ACCESS_MASK *PACCESS_MASK;

////////////////////////////////////////////////////////////////////////
// //
// ACCESS TYPES //
// //
////////////////////////////////////////////////////////////////////////


// begin_wdm
//
// The following are masks for the predefined standard access types
//

#define DELETE (0x00010000L)
#define READ_CONTROL (0x00020000L)
#define WRITE_DAC (0x00040000L)
#define WRITE_OWNER (0x00080000L)
#define SYNCHRONIZE (0x00100000L)

#define STANDARD_RIGHTS_REQUIRED (0x000F0000L)

#define STANDARD_RIGHTS_READ (READ_CONTROL)
#define STANDARD_RIGHTS_WRITE (READ_CONTROL)
#define STANDARD_RIGHTS_EXECUTE (READ_CONTROL)

#define STANDARD_RIGHTS_ALL (0x001F0000L)

#define SPECIFIC_RIGHTS_ALL (0x0000FFFFL)

//
// AccessSystemAcl access type
//

#define ACCESS_SYSTEM_SECURITY (0x01000000L)

//
// MaximumAllowed access type
//

#define MAXIMUM_ALLOWED (0x02000000L)

//
// These are the generic rights.
//

#define GENERIC_READ (0x80000000L)
#define GENERIC_WRITE (0x40000000L)
#define GENERIC_EXECUTE (0x20000000L)
#define GENERIC_ALL (0x10000000L)


//
// Define the generic mapping array. This is used to denote the
// mapping of each generic access right to a specific access mask.
//

typedef struct _GENERIC_MAPPING {
ACCESS_MASK GenericRead;
ACCESS_MASK GenericWrite;
ACCESS_MASK GenericExecute;
ACCESS_MASK GenericAll;
} GENERIC_MAPPING;
typedef GENERIC_MAPPING *PGENERIC_MAPPING;

 

////////////////////////////////////////////////////////////////////////
// //
// LUID_AND_ATTRIBUTES //
// //
////////////////////////////////////////////////////////////////////////
//
//


#include <pshpack4.h>

typedef struct _LUID_AND_ATTRIBUTES {
LUID Luid;
DWORD Attributes;
} LUID_AND_ATTRIBUTES, * PLUID_AND_ATTRIBUTES;
typedef LUID_AND_ATTRIBUTES LUID_AND_ATTRIBUTES_ARRAY[ANYSIZE_ARRAY];
typedef LUID_AND_ATTRIBUTES_ARRAY *PLUID_AND_ATTRIBUTES_ARRAY;

#include <poppack.h>


////////////////////////////////////////////////////////////////////////
// //
// Security Id (SID) //
// //
////////////////////////////////////////////////////////////////////////
//
//
// Pictorially the structure of an SID is as follows:
//
// 1 1 1 1 1 1
// 5 4 3 2 1 0 9 8 7 6 5 4 3 2 1 0
// +---------------------------------------------------------------+
// | SubAuthorityCount |Reserved1 (SBZ)| Revision |
// +---------------------------------------------------------------+
// | IdentifierAuthority[0] |
// +---------------------------------------------------------------+
// | IdentifierAuthority[1] |
// +---------------------------------------------------------------+
// | IdentifierAuthority[2] |
// +---------------------------------------------------------------+
// | |
// +- - - - - - - - SubAuthority[] - - - - - - - - -+
// | |
// +---------------------------------------------------------------+
//
//


// begin_ntifs

#ifndef SID_IDENTIFIER_AUTHORITY_DEFINED
#define SID_IDENTIFIER_AUTHORITY_DEFINED
typedef struct _SID_IDENTIFIER_AUTHORITY {
BYTE Value[6];
} SID_IDENTIFIER_AUTHORITY, *PSID_IDENTIFIER_AUTHORITY;
#endif


#ifndef SID_DEFINED
#define SID_DEFINED
typedef struct _SID {
BYTE Revision;
BYTE SubAuthorityCount;
SID_IDENTIFIER_AUTHORITY IdentifierAuthority;
#ifdef MIDL_PASS
[size_is(SubAuthorityCount)] DWORD SubAuthority[*];
#else // MIDL_PASS
DWORD SubAuthority[ANYSIZE_ARRAY];
#endif // MIDL_PASS
} SID, *PISID;
#endif

#define SID_REVISION (1) // Current revision level
#define SID_MAX_SUB_AUTHORITIES (15)
#define SID_RECOMMENDED_SUB_AUTHORITIES (1) // Will change to around 6

// in a future release.
#ifndef MIDL_PASS
#define SECURITY_MAX_SID_SIZE \
(sizeof(SID) - sizeof(DWORD) + (SID_MAX_SUB_AUTHORITIES * sizeof(DWORD)))
#endif // MIDL_PASS


typedef enum _SID_NAME_USE {
SidTypeUser = 1,
SidTypeGroup,
SidTypeDomain,
SidTypeAlias,
SidTypeWellKnownGroup,
SidTypeDeletedAccount,
SidTypeInvalid,
SidTypeUnknown,
SidTypeComputer,
SidTypeLabel
} SID_NAME_USE, *PSID_NAME_USE;

typedef struct _SID_AND_ATTRIBUTES {
#ifdef MIDL_PASS
PISID Sid;
#else // MIDL_PASS
PSID Sid;
#endif // MIDL_PASS
DWORD Attributes;
} SID_AND_ATTRIBUTES, * PSID_AND_ATTRIBUTES;

typedef SID_AND_ATTRIBUTES SID_AND_ATTRIBUTES_ARRAY[ANYSIZE_ARRAY];
typedef SID_AND_ATTRIBUTES_ARRAY *PSID_AND_ATTRIBUTES_ARRAY;

#define SID_HASH_SIZE 32
typedef ULONG_PTR SID_HASH_ENTRY, *PSID_HASH_ENTRY;

typedef struct _SID_AND_ATTRIBUTES_HASH {
DWORD SidCount;
PSID_AND_ATTRIBUTES SidAttr;
SID_HASH_ENTRY Hash[SID_HASH_SIZE];
} SID_AND_ATTRIBUTES_HASH, *PSID_AND_ATTRIBUTES_HASH;


/////////////////////////////////////////////////////////////////////////////
// //
// Universal well-known SIDs //
// //
// Null SID S-1-0-0 //
// World S-1-1-0 //
// Local S-1-2-0 //
// Creator Owner ID S-1-3-0 //
// Creator Group ID S-1-3-1 //
// Creator Owner Server ID S-1-3-2 //
// Creator Group Server ID S-1-3-3 //
// //
// (Non-unique IDs) S-1-4 //
// //
/////////////////////////////////////////////////////////////////////////////

#define SECURITY_NULL_SID_AUTHORITY {0,0,0,0,0,0}
#define SECURITY_WORLD_SID_AUTHORITY {0,0,0,0,0,1}
#define SECURITY_LOCAL_SID_AUTHORITY {0,0,0,0,0,2}
#define SECURITY_CREATOR_SID_AUTHORITY {0,0,0,0,0,3}
#define SECURITY_NON_UNIQUE_AUTHORITY {0,0,0,0,0,4}
#define SECURITY_RESOURCE_MANAGER_AUTHORITY {0,0,0,0,0,9}


#define SECURITY_NULL_RID (0x00000000L)
#define SECURITY_WORLD_RID (0x00000000L)
#define SECURITY_LOCAL_RID (0x00000000L)
#define SECURITY_LOCAL_LOGON_RID (0x00000001L)

#define SECURITY_CREATOR_OWNER_RID (0x00000000L)
#define SECURITY_CREATOR_GROUP_RID (0x00000001L)

#define SECURITY_CREATOR_OWNER_SERVER_RID (0x00000002L)
#define SECURITY_CREATOR_GROUP_SERVER_RID (0x00000003L)

#define SECURITY_CREATOR_OWNER_RIGHTS_RID (0x00000004L)

///////////////////////////////////////////////////////////////////////////////
// //
// NT well-known SIDs //
// //
// NT Authority S-1-5 //
// Dialup S-1-5-1 //
// //
// Network S-1-5-2 //
// Batch S-1-5-3 //
// Interactive S-1-5-4 //
// (Logon IDs) S-1-5-5-X-Y //
// Service S-1-5-6 //
// AnonymousLogon S-1-5-7 (aka null logon session) //
// Proxy S-1-5-8 //
// Enterprise DC (EDC) S-1-5-9 (aka domain controller account) //
// Self S-1-5-10 (self RID) //
// Authenticated User S-1-5-11 (Authenticated user somewhere) //
// Restricted Code S-1-5-12 (Running restricted code) //
// Terminal Server S-1-5-13 (Running on Terminal Server) //
// Remote Logon S-1-5-14 (Remote Interactive Logon) //
// This Organization S-1-5-15 //
// //
// IUser S-1-5-17
// Local System S-1-5-18 //
// Local Service S-1-5-19 //
// Network Service S-1-5-20 //
// //
// (NT non-unique IDs) S-1-5-0x15-... (NT Domain Sids) //
// //
// (Built-in domain) S-1-5-0x20 //
// //
// (Security Package IDs) S-1-5-0x40 //
// NTLM Authentication S-1-5-0x40-10 //
// SChannel Authentication S-1-5-0x40-14 //
// Digest Authentication S-1-5-0x40-21 //
// //
// Other Organization S-1-5-1000 (>=1000 can not be filtered) //
// //
// //
// NOTE: the relative identifier values (RIDs) determine which security //
// boundaries the SID is allowed to cross. Before adding new RIDs, //
// a determination needs to be made regarding which range they should //
// be added to in order to ensure proper "SID filtering" //
// //
///////////////////////////////////////////////////////////////////////////////


#define SECURITY_NT_AUTHORITY {0,0,0,0,0,5} // ntifs

#define SECURITY_DIALUP_RID (0x00000001L)
#define SECURITY_NETWORK_RID (0x00000002L)
#define SECURITY_BATCH_RID (0x00000003L)
#define SECURITY_INTERACTIVE_RID (0x00000004L)
#define SECURITY_LOGON_IDS_RID (0x00000005L)
#define SECURITY_LOGON_IDS_RID_COUNT (3L)
#define SECURITY_SERVICE_RID (0x00000006L)
#define SECURITY_ANONYMOUS_LOGON_RID (0x00000007L)
#define SECURITY_PROXY_RID (0x00000008L)
#define SECURITY_ENTERPRISE_CONTROLLERS_RID (0x00000009L)
#define SECURITY_SERVER_LOGON_RID SECURITY_ENTERPRISE_CONTROLLERS_RID
#define SECURITY_PRINCIPAL_SELF_RID (0x0000000AL)
#define SECURITY_AUTHENTICATED_USER_RID (0x0000000BL)
#define SECURITY_RESTRICTED_CODE_RID (0x0000000CL)
#define SECURITY_TERMINAL_SERVER_RID (0x0000000DL)
#define SECURITY_REMOTE_LOGON_RID (0x0000000EL)
#define SECURITY_THIS_ORGANIZATION_RID (0x0000000FL)
#define SECURITY_IUSER_RID (0x00000011L)
#define SECURITY_LOCAL_SYSTEM_RID (0x00000012L)
#define SECURITY_LOCAL_SERVICE_RID (0x00000013L)
#define SECURITY_NETWORK_SERVICE_RID (0x00000014L)

#define SECURITY_NT_NON_UNIQUE (0x00000015L)
#define SECURITY_NT_NON_UNIQUE_SUB_AUTH_COUNT (3L)

#define SECURITY_ENTERPRISE_READONLY_CONTROLLERS_RID (0x00000016L)

#define SECURITY_BUILTIN_DOMAIN_RID (0x00000020L)
#define SECURITY_WRITE_RESTRICTED_CODE_RID (0x00000021L)


#define SECURITY_PACKAGE_BASE_RID (0x00000040L)
#define SECURITY_PACKAGE_RID_COUNT (2L)
#define SECURITY_PACKAGE_NTLM_RID (0x0000000AL)
#define SECURITY_PACKAGE_SCHANNEL_RID (0x0000000EL)
#define SECURITY_PACKAGE_DIGEST_RID (0x00000015L)

#define SECURITY_CRED_TYPE_BASE_RID (0x00000041L)
#define SECURITY_CRED_TYPE_RID_COUNT (2L)
#define SECURITY_CRED_TYPE_THIS_ORG_CERT_RID (0x00000001L)

#define SECURITY_MIN_BASE_RID (0x00000050L)

#define SECURITY_SERVICE_ID_BASE_RID (0x00000050L)
#define SECURITY_SERVICE_ID_RID_COUNT (6L)

#define SECURITY_RESERVED_ID_BASE_RID (0x00000051L)

#define SECURITY_APPPOOL_ID_BASE_RID (0x00000052L)
#define SECURITY_APPPOOL_ID_RID_COUNT (6L)

#define SECURITY_VIRTUALSERVER_ID_BASE_RID (0x00000053L)
#define SECURITY_VIRTUALSERVER_ID_RID_COUNT (6L)

#define SECURITY_USERMODEDRIVERHOST_ID_BASE_RID (0x00000054L)
#define SECURITY_USERMODEDRIVERHOST_ID_RID_COUNT (6L)

#define SECURITY_CLOUD_INFRASTRUCTURE_SERVICES_ID_BASE_RID (0x00000055L)
#define SECURITY_CLOUD_INFRASTRUCTURE_SERVICES_ID_RID_COUNT (6L)

#define SECURITY_WMIHOST_ID_BASE_RID (0x00000056L)
#define SECURITY_WMIHOST_ID_RID_COUNT (6L)

#define SECURITY_TASK_ID_BASE_RID (0x00000057L)

#define SECURITY_NFS_ID_BASE_RID (0x00000058L)

#define SECURITY_COM_ID_BASE_RID (0x00000059L)

#define SECURITY_VIRTUALACCOUNT_ID_RID_COUNT (6L)

#define SECURITY_MAX_BASE_RID (0x0000006FL)
#define SECURITY_MAX_ALWAYS_FILTERED (0x000003E7L)
#define SECURITY_MIN_NEVER_FILTERED (0x000003E8L)

#define SECURITY_OTHER_ORGANIZATION_RID (0x000003E8L)

//
//Service SID type RIDs are in the range 0x50- 0x6F. Therefore, we are giving the next available RID to Windows Mobile team.
//
#define SECURITY_WINDOWSMOBILE_ID_BASE_RID (0x00000070L)


/////////////////////////////////////////////////////////////////////////////
// //
// well-known domain relative sub-authority values (RIDs)... //
// //
/////////////////////////////////////////////////////////////////////////////

 

#define DOMAIN_GROUP_RID_ENTERPRISE_READONLY_DOMAIN_CONTROLLERS (0x000001F2L)

#define FOREST_USER_RID_MAX (0x000001F3L)

// Well-known users ...

#define DOMAIN_USER_RID_ADMIN (0x000001F4L)
#define DOMAIN_USER_RID_GUEST (0x000001F5L)
#define DOMAIN_USER_RID_KRBTGT (0x000001F6L)

#define DOMAIN_USER_RID_MAX (0x000003E7L)


// well-known groups ...

#define DOMAIN_GROUP_RID_ADMINS (0x00000200L)
#define DOMAIN_GROUP_RID_USERS (0x00000201L)
#define DOMAIN_GROUP_RID_GUESTS (0x00000202L)
#define DOMAIN_GROUP_RID_COMPUTERS (0x00000203L)
#define DOMAIN_GROUP_RID_CONTROLLERS (0x00000204L)
#define DOMAIN_GROUP_RID_CERT_ADMINS (0x00000205L)
#define DOMAIN_GROUP_RID_SCHEMA_ADMINS (0x00000206L)
#define DOMAIN_GROUP_RID_ENTERPRISE_ADMINS (0x00000207L)
#define DOMAIN_GROUP_RID_POLICY_ADMINS (0x00000208L)
#define DOMAIN_GROUP_RID_READONLY_CONTROLLERS (0x00000209L)

// well-known aliases ...

#define DOMAIN_ALIAS_RID_ADMINS (0x00000220L)
#define DOMAIN_ALIAS_RID_USERS (0x00000221L)
#define DOMAIN_ALIAS_RID_GUESTS (0x00000222L)
#define DOMAIN_ALIAS_RID_POWER_USERS (0x00000223L)

#define DOMAIN_ALIAS_RID_ACCOUNT_OPS (0x00000224L)
#define DOMAIN_ALIAS_RID_SYSTEM_OPS (0x00000225L)
#define DOMAIN_ALIAS_RID_PRINT_OPS (0x00000226L)
#define DOMAIN_ALIAS_RID_BACKUP_OPS (0x00000227L)

#define DOMAIN_ALIAS_RID_REPLICATOR (0x00000228L)
#define DOMAIN_ALIAS_RID_RAS_SERVERS (0x00000229L)
#define DOMAIN_ALIAS_RID_PREW2KCOMPACCESS (0x0000022AL)
#define DOMAIN_ALIAS_RID_REMOTE_DESKTOP_USERS (0x0000022BL)
#define DOMAIN_ALIAS_RID_NETWORK_CONFIGURATION_OPS (0x0000022CL)
#define DOMAIN_ALIAS_RID_INCOMING_FOREST_TRUST_BUILDERS (0x0000022DL)

#define DOMAIN_ALIAS_RID_MONITORING_USERS (0x0000022EL)
#define DOMAIN_ALIAS_RID_LOGGING_USERS (0x0000022FL)
#define DOMAIN_ALIAS_RID_AUTHORIZATIONACCESS (0x00000230L)
#define DOMAIN_ALIAS_RID_TS_LICENSE_SERVERS (0x00000231L)
#define DOMAIN_ALIAS_RID_DCOM_USERS (0x00000232L)
#define DOMAIN_ALIAS_RID_IUSERS (0x00000238L)
#define DOMAIN_ALIAS_RID_CRYPTO_OPERATORS (0x00000239L)
#define DOMAIN_ALIAS_RID_CACHEABLE_PRINCIPALS_GROUP (0x0000023BL)
#define DOMAIN_ALIAS_RID_NON_CACHEABLE_PRINCIPALS_GROUP (0x0000023CL)
#define DOMAIN_ALIAS_RID_EVENT_LOG_READERS_GROUP (0x0000023DL)
#define DOMAIN_ALIAS_RID_CERTSVC_DCOM_ACCESS_GROUP (0x0000023EL)


#define SECURITY_MANDATORY_LABEL_AUTHORITY {0,0,0,0,0,16}
#define SECURITY_MANDATORY_UNTRUSTED_RID (0x00000000L)
#define SECURITY_MANDATORY_LOW_RID (0x00001000L)
#define SECURITY_MANDATORY_MEDIUM_RID (0x00002000L)
#define SECURITY_MANDATORY_MEDIUM_PLUS_RID (SECURITY_MANDATORY_MEDIUM_RID + 0x100)
#define SECURITY_MANDATORY_HIGH_RID (0x00003000L)
#define SECURITY_MANDATORY_SYSTEM_RID (0x00004000L)
#define SECURITY_MANDATORY_PROTECTED_PROCESS_RID (0x00005000L)

//
// SECURITY_MANDATORY_MAXIMUM_USER_RID is the highest RID that
// can be set by a usermode caller.
//

#define SECURITY_MANDATORY_MAXIMUM_USER_RID SECURITY_MANDATORY_SYSTEM_RID

#define MANDATORY_LEVEL_TO_MANDATORY_RID(IL) (IL * 0x1000)

 

//
// Well known SID definitions for lookup.
//

typedef enum {

WinNullSid = 0,
WinWorldSid = 1,
WinLocalSid = 2,
WinCreatorOwnerSid = 3,
WinCreatorGroupSid = 4,
WinCreatorOwnerServerSid = 5,
WinCreatorGroupServerSid = 6,
WinNtAuthoritySid = 7,
WinDialupSid = 8,
WinNetworkSid = 9,
WinBatchSid = 10,
WinInteractiveSid = 11,
WinServiceSid = 12,
WinAnonymousSid = 13,
WinProxySid = 14,
WinEnterpriseControllersSid = 15,
WinSelfSid = 16,
WinAuthenticatedUserSid = 17,
WinRestrictedCodeSid = 18,
WinTerminalServerSid = 19,
WinRemoteLogonIdSid = 20,
WinLogonIdsSid = 21,
WinLocalSystemSid = 22,
WinLocalServiceSid = 23,
WinNetworkServiceSid = 24,
WinBuiltinDomainSid = 25,
WinBuiltinAdministratorsSid = 26,
WinBuiltinUsersSid = 27,
WinBuiltinGuestsSid = 28,
WinBuiltinPowerUsersSid = 29,
WinBuiltinAccountOperatorsSid = 30,
WinBuiltinSystemOperatorsSid = 31,
WinBuiltinPrintOperatorsSid = 32,
WinBuiltinBackupOperatorsSid = 33,
WinBuiltinReplicatorSid = 34,
WinBuiltinPreWindows2000CompatibleAccessSid = 35,
WinBuiltinRemoteDesktopUsersSid = 36,
WinBuiltinNetworkConfigurationOperatorsSid = 37,
WinAccountAdministratorSid = 38,
WinAccountGuestSid = 39,
WinAccountKrbtgtSid = 40,
WinAccountDomainAdminsSid = 41,
WinAccountDomainUsersSid = 42,
WinAccountDomainGuestsSid = 43,
WinAccountComputersSid = 44,
WinAccountControllersSid = 45,
WinAccountCertAdminsSid = 46,
WinAccountSchemaAdminsSid = 47,
WinAccountEnterpriseAdminsSid = 48,
WinAccountPolicyAdminsSid = 49,
WinAccountRasAndIasServersSid = 50,
WinNTLMAuthenticationSid = 51,
WinDigestAuthenticationSid = 52,
WinSChannelAuthenticationSid = 53,
WinThisOrganizationSid = 54,
WinOtherOrganizationSid = 55,
WinBuiltinIncomingForestTrustBuildersSid = 56,
WinBuiltinPerfMonitoringUsersSid = 57,
WinBuiltinPerfLoggingUsersSid = 58,
WinBuiltinAuthorizationAccessSid = 59,
WinBuiltinTerminalServerLicenseServersSid = 60,
WinBuiltinDCOMUsersSid = 61,
WinBuiltinIUsersSid = 62,
WinIUserSid = 63,
WinBuiltinCryptoOperatorsSid = 64,
WinUntrustedLabelSid = 65,
WinLowLabelSid = 66,
WinMediumLabelSid = 67,
WinHighLabelSid = 68,
WinSystemLabelSid = 69,
WinWriteRestrictedCodeSid = 70,
WinCreatorOwnerRightsSid = 71,
WinCacheablePrincipalsGroupSid = 72,
WinNonCacheablePrincipalsGroupSid = 73,
WinEnterpriseReadonlyControllersSid = 74,
WinAccountReadonlyControllersSid = 75,
WinBuiltinEventLogReadersGroup = 76,
WinNewEnterpriseReadonlyControllersSid = 77,
WinBuiltinCertSvcDComAccessGroup = 78,
WinMediumPlusLabelSid = 79,
WinLocalLogonSid = 80,
WinConsoleLogonSid = 81,
WinThisOrganizationCertificateSid = 82,
} WELL_KNOWN_SID_TYPE;

//
// Allocate the System Luid. The first 1000 LUIDs are reserved.
// Use #999 here (0x3e7 = 999)
//

#define SYSTEM_LUID { 0x3e7, 0x0 }
#define ANONYMOUS_LOGON_LUID { 0x3e6, 0x0 }
#define LOCALSERVICE_LUID { 0x3e5, 0x0 }
#define NETWORKSERVICE_LUID { 0x3e4, 0x0 }
#define IUSER_LUID { 0x3e3, 0x0 }

// end_ntifs

////////////////////////////////////////////////////////////////////////
// //
// User and Group related SID attributes //
// //
////////////////////////////////////////////////////////////////////////

//
// Group attributes
//

#define SE_GROUP_MANDATORY (0x00000001L)
#define SE_GROUP_ENABLED_BY_DEFAULT (0x00000002L)
#define SE_GROUP_ENABLED (0x00000004L)
#define SE_GROUP_OWNER (0x00000008L)
#define SE_GROUP_USE_FOR_DENY_ONLY (0x00000010L)
#define SE_GROUP_INTEGRITY (0x00000020L)
#define SE_GROUP_INTEGRITY_ENABLED (0x00000040L)
#define SE_GROUP_LOGON_ID (0xC0000000L)
#define SE_GROUP_RESOURCE (0x20000000L)

#define SE_GROUP_VALID_ATTRIBUTES (SE_GROUP_MANDATORY | \
SE_GROUP_ENABLED_BY_DEFAULT | \
SE_GROUP_ENABLED | \
SE_GROUP_OWNER | \
SE_GROUP_USE_FOR_DENY_ONLY | \
SE_GROUP_LOGON_ID | \
SE_GROUP_RESOURCE | \
SE_GROUP_INTEGRITY | \
SE_GROUP_INTEGRITY_ENABLED)

//
// User attributes
//

// (None yet defined.)


////////////////////////////////////////////////////////////////////////
// //
// ACL and ACE //
// //
////////////////////////////////////////////////////////////////////////

//
// Define an ACL and the ACE format. The structure of an ACL header
// followed by one or more ACEs. Pictorally the structure of an ACL header
// is as follows:
//
// 3 3 2 2 2 2 2 2 2 2 2 2 1 1 1 1 1 1 1 1 1 1
// 1 0 9 8 7 6 5 4 3 2 1 0 9 8 7 6 5 4 3 2 1 0 9 8 7 6 5 4 3 2 1 0
// +-------------------------------+---------------+---------------+
// | AclSize | Sbz1 | AclRevision |
// +-------------------------------+---------------+---------------+
// | Sbz2 | AceCount |
// +-------------------------------+-------------------------------+
//
// The current AclRevision is defined to be ACL_REVISION.
//
// AclSize is the size, in bytes, allocated for the ACL. This includes
// the ACL header, ACES, and remaining free space in the buffer.
//
// AceCount is the number of ACES in the ACL.
//

// begin_wdm
// This is the *current* ACL revision

#define ACL_REVISION (2)
#define ACL_REVISION_DS (4)

// This is the history of ACL revisions. Add a new one whenever
// ACL_REVISION is updated

#define ACL_REVISION1 (1)
#define MIN_ACL_REVISION ACL_REVISION2
#define ACL_REVISION2 (2)
#define ACL_REVISION3 (3)
#define ACL_REVISION4 (4)
#define MAX_ACL_REVISION ACL_REVISION4

typedef struct _ACL {
BYTE AclRevision;
BYTE Sbz1;
WORD AclSize;
WORD AceCount;
WORD Sbz2;
} ACL;
typedef ACL *PACL;

// end_wdm
// begin_ntifs

//
// The structure of an ACE is a common ace header followed by ace type
// specific data. Pictorally the structure of the common ace header is
// as follows:
//
// 3 3 2 2 2 2 2 2 2 2 2 2 1 1 1 1 1 1 1 1 1 1
// 1 0 9 8 7 6 5 4 3 2 1 0 9 8 7 6 5 4 3 2 1 0 9 8 7 6 5 4 3 2 1 0
// +---------------+-------+-------+---------------+---------------+
// | AceSize | AceFlags | AceType |
// +---------------+-------+-------+---------------+---------------+
//
// AceType denotes the type of the ace, there are some predefined ace
// types
//
// AceSize is the size, in bytes, of ace.
//
// AceFlags are the Ace flags for audit and inheritance, defined shortly.

typedef struct _ACE_HEADER {
BYTE AceType;
BYTE AceFlags;
WORD AceSize;
} ACE_HEADER;
typedef ACE_HEADER *PACE_HEADER;

//
// The following are the predefined ace types that go into the AceType
// field of an Ace header.
//

#define ACCESS_MIN_MS_ACE_TYPE (0x0)
#define ACCESS_ALLOWED_ACE_TYPE (0x0)
#define ACCESS_DENIED_ACE_TYPE (0x1)
#define SYSTEM_AUDIT_ACE_TYPE (0x2)
#define SYSTEM_ALARM_ACE_TYPE (0x3)
#define ACCESS_MAX_MS_V2_ACE_TYPE (0x3)

#define ACCESS_ALLOWED_COMPOUND_ACE_TYPE (0x4)
#define ACCESS_MAX_MS_V3_ACE_TYPE (0x4)

#define ACCESS_MIN_MS_OBJECT_ACE_TYPE (0x5)
#define ACCESS_ALLOWED_OBJECT_ACE_TYPE (0x5)
#define ACCESS_DENIED_OBJECT_ACE_TYPE (0x6)
#define SYSTEM_AUDIT_OBJECT_ACE_TYPE (0x7)
#define SYSTEM_ALARM_OBJECT_ACE_TYPE (0x8)
#define ACCESS_MAX_MS_OBJECT_ACE_TYPE (0x8)

#define ACCESS_MAX_MS_V4_ACE_TYPE (0x8)
#define ACCESS_MAX_MS_ACE_TYPE (0x8)

#define ACCESS_ALLOWED_CALLBACK_ACE_TYPE (0x9)
#define ACCESS_DENIED_CALLBACK_ACE_TYPE (0xA)
#define ACCESS_ALLOWED_CALLBACK_OBJECT_ACE_TYPE (0xB)
#define ACCESS_DENIED_CALLBACK_OBJECT_ACE_TYPE (0xC)
#define SYSTEM_AUDIT_CALLBACK_ACE_TYPE (0xD)
#define SYSTEM_ALARM_CALLBACK_ACE_TYPE (0xE)
#define SYSTEM_AUDIT_CALLBACK_OBJECT_ACE_TYPE (0xF)
#define SYSTEM_ALARM_CALLBACK_OBJECT_ACE_TYPE (0x10)

#define SYSTEM_MANDATORY_LABEL_ACE_TYPE (0x11)
#define ACCESS_MAX_MS_V5_ACE_TYPE (0x11)


//
// The following are the inherit flags that go into the AceFlags field
// of an Ace header.
//

#define OBJECT_INHERIT_ACE (0x1)
#define CONTAINER_INHERIT_ACE (0x2)
#define NO_PROPAGATE_INHERIT_ACE (0x4)
#define INHERIT_ONLY_ACE (0x8)
#define INHERITED_ACE (0x10)
#define VALID_INHERIT_FLAGS (0x1F)


// The following are the currently defined ACE flags that go into the
// AceFlags field of an ACE header. Each ACE type has its own set of
// AceFlags.
//
// SUCCESSFUL_ACCESS_ACE_FLAG - used only with system audit and alarm ACE
// types to indicate that a message is generated for successful accesses.
//
// FAILED_ACCESS_ACE_FLAG - used only with system audit and alarm ACE types
// to indicate that a message is generated for failed accesses.
//

//
// SYSTEM_AUDIT and SYSTEM_ALARM AceFlags
//
// These control the signaling of audit and alarms for success or failure.
//

#define SUCCESSFUL_ACCESS_ACE_FLAG (0x40)
#define FAILED_ACCESS_ACE_FLAG (0x80)


//
// We‘ll define the structure of the predefined ACE types. Pictorally
// the structure of the predefined ACE‘s is as follows:
//
// 3 3 2 2 2 2 2 2 2 2 2 2 1 1 1 1 1 1 1 1 1 1
// 1 0 9 8 7 6 5 4 3 2 1 0 9 8 7 6 5 4 3 2 1 0 9 8 7 6 5 4 3 2 1 0
// +---------------+-------+-------+---------------+---------------+
// | AceFlags | Resd |Inherit| AceSize | AceType |
// +---------------+-------+-------+---------------+---------------+
// | Mask |
// +---------------------------------------------------------------+
// | |
// + +
// | |
// + Sid +
// | |
// + +
// | |
// +---------------------------------------------------------------+
//
// Mask is the access mask associated with the ACE. This is either the
// access allowed, access denied, audit, or alarm mask.
//
// Sid is the Sid associated with the ACE.
//

// The following are the four predefined ACE types.

// Examine the AceType field in the Header to determine
// which structure is appropriate to use for casting.


typedef struct _ACCESS_ALLOWED_ACE {
ACE_HEADER Header;
ACCESS_MASK Mask;
DWORD SidStart;
} ACCESS_ALLOWED_ACE;

typedef ACCESS_ALLOWED_ACE *PACCESS_ALLOWED_ACE;

typedef struct _ACCESS_DENIED_ACE {
ACE_HEADER Header;
ACCESS_MASK Mask;
DWORD SidStart;
} ACCESS_DENIED_ACE;
typedef ACCESS_DENIED_ACE *PACCESS_DENIED_ACE;

typedef struct _SYSTEM_AUDIT_ACE {
ACE_HEADER Header;
ACCESS_MASK Mask;
DWORD SidStart;
} SYSTEM_AUDIT_ACE;
typedef SYSTEM_AUDIT_ACE *PSYSTEM_AUDIT_ACE;

typedef struct _SYSTEM_ALARM_ACE {
ACE_HEADER Header;
ACCESS_MASK Mask;
DWORD SidStart;
} SYSTEM_ALARM_ACE;
typedef SYSTEM_ALARM_ACE *PSYSTEM_ALARM_ACE;

typedef struct _SYSTEM_MANDATORY_LABEL_ACE {
ACE_HEADER Header;
ACCESS_MASK Mask;
DWORD SidStart;
} SYSTEM_MANDATORY_LABEL_ACE, *PSYSTEM_MANDATORY_LABEL_ACE;

#define SYSTEM_MANDATORY_LABEL_NO_WRITE_UP 0x1
#define SYSTEM_MANDATORY_LABEL_NO_READ_UP 0x2
#define SYSTEM_MANDATORY_LABEL_NO_EXECUTE_UP 0x4

#define SYSTEM_MANDATORY_LABEL_VALID_MASK (SYSTEM_MANDATORY_LABEL_NO_WRITE_UP | \
SYSTEM_MANDATORY_LABEL_NO_READ_UP | \
SYSTEM_MANDATORY_LABEL_NO_EXECUTE_UP)
// end_ntifs


typedef struct _ACCESS_ALLOWED_OBJECT_ACE {
ACE_HEADER Header;
ACCESS_MASK Mask;
DWORD Flags;
GUID ObjectType;
GUID InheritedObjectType;
DWORD SidStart;
} ACCESS_ALLOWED_OBJECT_ACE, *PACCESS_ALLOWED_OBJECT_ACE;

typedef struct _ACCESS_DENIED_OBJECT_ACE {
ACE_HEADER Header;
ACCESS_MASK Mask;
DWORD Flags;
GUID ObjectType;
GUID InheritedObjectType;
DWORD SidStart;
} ACCESS_DENIED_OBJECT_ACE, *PACCESS_DENIED_OBJECT_ACE;

typedef struct _SYSTEM_AUDIT_OBJECT_ACE {
ACE_HEADER Header;
ACCESS_MASK Mask;
DWORD Flags;
GUID ObjectType;
GUID InheritedObjectType;
DWORD SidStart;
} SYSTEM_AUDIT_OBJECT_ACE, *PSYSTEM_AUDIT_OBJECT_ACE;

typedef struct _SYSTEM_ALARM_OBJECT_ACE {
ACE_HEADER Header;
ACCESS_MASK Mask;
DWORD Flags;
GUID ObjectType;
GUID InheritedObjectType;
DWORD SidStart;
} SYSTEM_ALARM_OBJECT_ACE, *PSYSTEM_ALARM_OBJECT_ACE;

//
// Callback ace support in post Win2000.
// Resource managers can put their own data after Sidstart + Length of the sid
//

typedef struct _ACCESS_ALLOWED_CALLBACK_ACE {
ACE_HEADER Header;
ACCESS_MASK Mask;
DWORD SidStart;
// Opaque resouce manager specific data
} ACCESS_ALLOWED_CALLBACK_ACE, *PACCESS_ALLOWED_CALLBACK_ACE;

typedef struct _ACCESS_DENIED_CALLBACK_ACE {
ACE_HEADER Header;
ACCESS_MASK Mask;
DWORD SidStart;
// Opaque resouce manager specific data
} ACCESS_DENIED_CALLBACK_ACE, *PACCESS_DENIED_CALLBACK_ACE;

typedef struct _SYSTEM_AUDIT_CALLBACK_ACE {
ACE_HEADER Header;
ACCESS_MASK Mask;
DWORD SidStart;
// Opaque resouce manager specific data
} SYSTEM_AUDIT_CALLBACK_ACE, *PSYSTEM_AUDIT_CALLBACK_ACE;

typedef struct _SYSTEM_ALARM_CALLBACK_ACE {
ACE_HEADER Header;
ACCESS_MASK Mask;
DWORD SidStart;
// Opaque resouce manager specific data
} SYSTEM_ALARM_CALLBACK_ACE, *PSYSTEM_ALARM_CALLBACK_ACE;

typedef struct _ACCESS_ALLOWED_CALLBACK_OBJECT_ACE {
ACE_HEADER Header;
ACCESS_MASK Mask;
DWORD Flags;
GUID ObjectType;
GUID InheritedObjectType;
DWORD SidStart;
// Opaque resouce manager specific data
} ACCESS_ALLOWED_CALLBACK_OBJECT_ACE, *PACCESS_ALLOWED_CALLBACK_OBJECT_ACE;

typedef struct _ACCESS_DENIED_CALLBACK_OBJECT_ACE {
ACE_HEADER Header;
ACCESS_MASK Mask;
DWORD Flags;
GUID ObjectType;
GUID InheritedObjectType;
DWORD SidStart;
// Opaque resouce manager specific data
} ACCESS_DENIED_CALLBACK_OBJECT_ACE, *PACCESS_DENIED_CALLBACK_OBJECT_ACE;

typedef struct _SYSTEM_AUDIT_CALLBACK_OBJECT_ACE {
ACE_HEADER Header;
ACCESS_MASK Mask;
DWORD Flags;
GUID ObjectType;
GUID InheritedObjectType;
DWORD SidStart;
// Opaque resouce manager specific data
} SYSTEM_AUDIT_CALLBACK_OBJECT_ACE, *PSYSTEM_AUDIT_CALLBACK_OBJECT_ACE;

typedef struct _SYSTEM_ALARM_CALLBACK_OBJECT_ACE {
ACE_HEADER Header;
ACCESS_MASK Mask;
DWORD Flags;
GUID ObjectType;
GUID InheritedObjectType;
DWORD SidStart;
// Opaque resouce manager specific data
} SYSTEM_ALARM_CALLBACK_OBJECT_ACE, *PSYSTEM_ALARM_CALLBACK_OBJECT_ACE;

//
// Currently define Flags for "OBJECT" ACE types.
//

#define ACE_OBJECT_TYPE_PRESENT 0x1
#define ACE_INHERITED_OBJECT_TYPE_PRESENT 0x2


//
// The following declarations are used for setting and querying information
// about and ACL. First are the various information classes available to
// the user.
//

typedef enum _ACL_INFORMATION_CLASS {
AclRevisionInformation = 1,
AclSizeInformation
} ACL_INFORMATION_CLASS;

//
// This record is returned/sent if the user is requesting/setting the
// AclRevisionInformation
//

typedef struct _ACL_REVISION_INFORMATION {
DWORD AclRevision;
} ACL_REVISION_INFORMATION;
typedef ACL_REVISION_INFORMATION *PACL_REVISION_INFORMATION;

//
// This record is returned if the user is requesting AclSizeInformation
//

typedef struct _ACL_SIZE_INFORMATION {
DWORD AceCount;
DWORD AclBytesInUse;
DWORD AclBytesFree;
} ACL_SIZE_INFORMATION;
typedef ACL_SIZE_INFORMATION *PACL_SIZE_INFORMATION;


////////////////////////////////////////////////////////////////////////
// //
// SECURITY_DESCRIPTOR //
// //
////////////////////////////////////////////////////////////////////////
//
// Define the Security Descriptor and related data types.
// This is an opaque data structure.
//

// begin_wdm
//
// Current security descriptor revision value
//

#define SECURITY_DESCRIPTOR_REVISION (1)
#define SECURITY_DESCRIPTOR_REVISION1 (1)

// end_wdm
// begin_ntifs

#define SECURITY_DESCRIPTOR_MIN_LENGTH (sizeof(SECURITY_DESCRIPTOR))


typedef WORD SECURITY_DESCRIPTOR_CONTROL, *PSECURITY_DESCRIPTOR_CONTROL;

#define SE_OWNER_DEFAULTED (0x0001)
#define SE_GROUP_DEFAULTED (0x0002)
#define SE_DACL_PRESENT (0x0004)
#define SE_DACL_DEFAULTED (0x0008)
#define SE_SACL_PRESENT (0x0010)
#define SE_SACL_DEFAULTED (0x0020)
#define SE_DACL_AUTO_INHERIT_REQ (0x0100)
#define SE_SACL_AUTO_INHERIT_REQ (0x0200)
#define SE_DACL_AUTO_INHERITED (0x0400)
#define SE_SACL_AUTO_INHERITED (0x0800)
#define SE_DACL_PROTECTED (0x1000)
#define SE_SACL_PROTECTED (0x2000)
#define SE_RM_CONTROL_VALID (0x4000)
#define SE_SELF_RELATIVE (0x8000)

//
// Where:
//
// SE_OWNER_DEFAULTED - This boolean flag, when set, indicates that the
// SID pointed to by the Owner field was provided by a
// defaulting mechanism rather than explicitly provided by the
// original provider of the security descriptor. This may
// affect the treatment of the SID with respect to inheritence
// of an owner.
//
// SE_GROUP_DEFAULTED - This boolean flag, when set, indicates that the
// SID in the Group field was provided by a defaulting mechanism
// rather than explicitly provided by the original provider of
// the security descriptor. This may affect the treatment of
// the SID with respect to inheritence of a primary group.
//
// SE_DACL_PRESENT - This boolean flag, when set, indicates that the
// security descriptor contains a discretionary ACL. If this
// flag is set and the Dacl field of the SECURITY_DESCRIPTOR is
// null, then a null ACL is explicitly being specified.
//
// SE_DACL_DEFAULTED - This boolean flag, when set, indicates that the
// ACL pointed to by the Dacl field was provided by a defaulting
// mechanism rather than explicitly provided by the original
// provider of the security descriptor. This may affect the
// treatment of the ACL with respect to inheritence of an ACL.
// This flag is ignored if the DaclPresent flag is not set.
//
// SE_SACL_PRESENT - This boolean flag, when set, indicates that the
// security descriptor contains a system ACL pointed to by the
// Sacl field. If this flag is set and the Sacl field of the
// SECURITY_DESCRIPTOR is null, then an empty (but present)
// ACL is being specified.
//
// SE_SACL_DEFAULTED - This boolean flag, when set, indicates that the
// ACL pointed to by the Sacl field was provided by a defaulting
// mechanism rather than explicitly provided by the original
// provider of the security descriptor. This may affect the
// treatment of the ACL with respect to inheritence of an ACL.
// This flag is ignored if the SaclPresent flag is not set.
//
// SE_SELF_RELATIVE - This boolean flag, when set, indicates that the
// security descriptor is in self-relative form. In this form,
// all fields of the security descriptor are contiguous in memory
// and all pointer fields are expressed as offsets from the
// beginning of the security descriptor. This form is useful
// for treating security descriptors as opaque data structures
// for transmission in communication protocol or for storage on
// secondary media.
//
//
//
// Pictorially the structure of a security descriptor is as follows:
//
// 3 3 2 2 2 2 2 2 2 2 2 2 1 1 1 1 1 1 1 1 1 1
// 1 0 9 8 7 6 5 4 3 2 1 0 9 8 7 6 5 4 3 2 1 0 9 8 7 6 5 4 3 2 1 0
// +---------------------------------------------------------------+
// | Control |Reserved1 (SBZ)| Revision |
// +---------------------------------------------------------------+
// | Owner |
// +---------------------------------------------------------------+
// | Group |
// +---------------------------------------------------------------+
// | Sacl |
// +---------------------------------------------------------------+
// | Dacl |
// +---------------------------------------------------------------+
//
// In general, this data structure should be treated opaquely to ensure future
// compatibility.
//
//

typedef struct _SECURITY_DESCRIPTOR_RELATIVE {
BYTE Revision;
BYTE Sbz1;
SECURITY_DESCRIPTOR_CONTROL Control;
DWORD Owner;
DWORD Group;
DWORD Sacl;
DWORD Dacl;
} SECURITY_DESCRIPTOR_RELATIVE, *PISECURITY_DESCRIPTOR_RELATIVE;

typedef struct _SECURITY_DESCRIPTOR {
BYTE Revision;
BYTE Sbz1;
SECURITY_DESCRIPTOR_CONTROL Control;
PSID Owner;
PSID Group;
PACL Sacl;
PACL Dacl;

} SECURITY_DESCRIPTOR, *PISECURITY_DESCRIPTOR;

// end_ntifs

// Where:
//
// Revision - Contains the revision level of the security
// descriptor. This allows this structure to be passed between
// systems or stored on disk even though it is expected to
// change in the future.
//
// Control - A set of flags which qualify the meaning of the
// security descriptor or individual fields of the security
// descriptor.
//
// Owner - is a pointer to an SID representing an object‘s owner.
// If this field is null, then no owner SID is present in the
// security descriptor. If the security descriptor is in
// self-relative form, then this field contains an offset to
// the SID, rather than a pointer.
//
// Group - is a pointer to an SID representing an object‘s primary
// group. If this field is null, then no primary group SID is
// present in the security descriptor. If the security descriptor
// is in self-relative form, then this field contains an offset to
// the SID, rather than a pointer.
//
// Sacl - is a pointer to a system ACL. This field value is only
// valid if the DaclPresent control flag is set. If the
// SaclPresent flag is set and this field is null, then a null
// ACL is specified. If the security descriptor is in
// self-relative form, then this field contains an offset to
// the ACL, rather than a pointer.
//
// Dacl - is a pointer to a discretionary ACL. This field value is
// only valid if the DaclPresent control flag is set. If the
// DaclPresent flag is set and this field is null, then a null
// ACL (unconditionally granting access) is specified. If the
// security descriptor is in self-relative form, then this field
// contains an offset to the ACL, rather than a pointer.
//

 


////////////////////////////////////////////////////////////////////////
// //
// Object Type list for AccessCheckByType //
// //
////////////////////////////////////////////////////////////////////////

typedef struct _OBJECT_TYPE_LIST {
WORD Level;
WORD Sbz;
GUID *ObjectType;
} OBJECT_TYPE_LIST, *POBJECT_TYPE_LIST;

//
// DS values for Level
//

#define ACCESS_OBJECT_GUID 0
#define ACCESS_PROPERTY_SET_GUID 1
#define ACCESS_PROPERTY_GUID 2

#define ACCESS_MAX_LEVEL 4

//
// Parameters to NtAccessCheckByTypeAndAditAlarm
//

typedef enum _AUDIT_EVENT_TYPE {
AuditEventObjectAccess,
AuditEventDirectoryServiceAccess
} AUDIT_EVENT_TYPE, *PAUDIT_EVENT_TYPE;

#define AUDIT_ALLOW_NO_PRIVILEGE 0x1

//
// DS values for Source and ObjectTypeName
//

#define ACCESS_DS_SOURCE_A "DS"
#define ACCESS_DS_SOURCE_W L"DS"
#define ACCESS_DS_OBJECT_TYPE_NAME_A "Directory Service Object"
#define ACCESS_DS_OBJECT_TYPE_NAME_W L"Directory Service Object"

////////////////////////////////////////////////////////////////////////
// //
// Privilege Related Data Structures //
// //
////////////////////////////////////////////////////////////////////////

// end_ntifs
// begin_wdm
//
// Privilege attributes
//

#define SE_PRIVILEGE_ENABLED_BY_DEFAULT (0x00000001L)
#define SE_PRIVILEGE_ENABLED (0x00000002L)
#define SE_PRIVILEGE_REMOVED (0X00000004L)
#define SE_PRIVILEGE_USED_FOR_ACCESS (0x80000000L)

#define SE_PRIVILEGE_VALID_ATTRIBUTES (SE_PRIVILEGE_ENABLED_BY_DEFAULT | \
SE_PRIVILEGE_ENABLED | \
SE_PRIVILEGE_REMOVED | \
SE_PRIVILEGE_USED_FOR_ACCESS)


//
// Privilege Set Control flags
//

#define PRIVILEGE_SET_ALL_NECESSARY (1)

//
// Privilege Set - This is defined for a privilege set of one.
// If more than one privilege is needed, then this structure
// will need to be allocated with more space.
//
// Note: don‘t change this structure without fixing the INITIAL_PRIVILEGE_SET
// structure (defined in se.h)
//

typedef struct _PRIVILEGE_SET {
DWORD PrivilegeCount;
DWORD Control;
LUID_AND_ATTRIBUTES Privilege[ANYSIZE_ARRAY];
} PRIVILEGE_SET, * PPRIVILEGE_SET;

 


//
// Values for different access granted\denied reasons:
// AccessReasonAceN = AccessReasonAce + N.
// AccessReasonPrivilegeN = AccessReasonPrivilege + N.
//

#define ACCESS_REASON_TYPE_MASK 0xffff0000
#define ACCESS_REASON_DATA_MASK 0x0000ffff

typedef enum _ACCESS_REASON_TYPE{

AccessReasonNone = 0x00000000, // Indicate no reason for the bit. The bit may not be checked, or just no known reason.

//
// The lowest 2 bytes store the index of the ACE that grant/deny this bit.
// If the corresponding access maskt is zero, then it is deny ACE; otherwise,
// it is allow ACE.
//
AccessReasonAllowedAce = 0x00010000, // Granted a permission.
AccessReasonDeniedAce = 0x00020000, // Denied a permission.

AccessReasonAllowedParentAce = 0x00030000, // Granted a permission from parent ACE
AccessReasonDeniedParentAce = 0x00040000, // Denied a permission from parent ACE

AccessReasonMissingPrivilege = 0x00100000,
AccessReasonFromPrivilege = 0x00200000,


AccessReasonIntegrityLevel = 0x00300000,

AccessReasonOwnership = 0x00400000,

AccessReasonNullDacl = 0x00500000,
AccessReasonEmptyDacl = 0x00600000,

AccessReasonNoSD = 0x00700000,
AccessReasonNoGrant = 0x00800000 // this access bit is not granted by any ACE.
} ACCESS_REASON_TYPE;

//
// Structure to hold access denied\granted reason for every bit of ACCESS_MASK.
// There are 32-bits in ACCESS_MASK and only 27-bits are actually valid on
// return from AccessCheck because MAXIMUM_ALLOWED, GENERIC_READ,
// GENERIC_WRITE, GENERIC_EXECUTE, and GENERIC_ALL are never returned.
//
// The content in Data fields depends on the Access Reason, for example,
// if the reason is AccessReasonAce, the Data will be the ACE ID.
// If there are more than one reason (more than one bit is set), the array size
// of the Data is equal to the number of bits set (or number of reasons).
// The Data could be null for a particular reason.
//

typedef DWORD ACCESS_REASON;

typedef struct _ACCESS_REASONS{
ACCESS_REASON Data[32];
} ACCESS_REASONS, *PACCESS_REASONS;


/*
The following data structures are defined to consolidate various falvors of
access check functions. In particular for Windows 7, the new access check
function will enable security attribute check, plus returning the reason
for a access check result.

The new access check function based on these data structures will
form the foundation to reimplement other flavors of access check
functions.

*/

//
// Structure to hold pointer to security descriptor and its unique id, which
// can be used for caching access check results.
// (NOTE NOTE) The cache key can be constructed by SecurityDescriptorId, Token and
// PrincipalSelfSid. Watch how GenericMapping affects the cache results.
//
#define SE_SECURITY_DESCRIPTOR_FLAG_NO_OWNER_ACE 0x00000001
#define SE_SECURITY_DESCRIPTOR_FLAG_NO_LABEL_ACE 0x00000002
#define SE_SECURITY_DESCRIPTOR_VALID_FLAGS 0x00000003

typedef struct _SE_SECURITY_DESCRIPTOR
{
DWORD Size;
DWORD Flags;
PSECURITY_DESCRIPTOR SecurityDescriptor;
} SE_SECURITY_DESCRIPTOR, *PSE_SECURITY_DESCRIPTOR;

typedef struct _SE_ACCESS_REQUEST
{
DWORD Size;
PSE_SECURITY_DESCRIPTOR SeSecurityDescriptor;
ACCESS_MASK DesiredAccess;
ACCESS_MASK PreviouslyGrantedAccess;
PSID PrincipalSelfSid; // Need to watch how this field affects the cache.
PGENERIC_MAPPING GenericMapping;
DWORD ObjectTypeListCount;
POBJECT_TYPE_LIST ObjectTypeList;
} SE_ACCESS_REQUEST, *PSE_ACCESS_REQUEST;


typedef struct _SE_ACCESS_REPLY
{
DWORD Size;
DWORD ResultListCount; // Indicate the array size of GrantedAccess and AccessStatus, it only can be either 1 or ObjectTypeListCount.
PACCESS_MASK GrantedAccess;
PDWORD AccessStatus;
PACCESS_REASONS AccessReason;
PPRIVILEGE_SET* Privileges;
} SE_ACCESS_REPLY, *PSE_ACCESS_REPLY;


////////////////////////////////////////////////////////////////////////
// //
// NT Defined Privileges //
// //
////////////////////////////////////////////////////////////////////////

#define SE_CREATE_TOKEN_NAME TEXT("SeCreateTokenPrivilege")
#define SE_ASSIGNPRIMARYTOKEN_NAME TEXT("SeAssignPrimaryTokenPrivilege")
#define SE_LOCK_MEMORY_NAME TEXT("SeLockMemoryPrivilege")
#define SE_INCREASE_QUOTA_NAME TEXT("SeIncreaseQuotaPrivilege")
#define SE_UNSOLICITED_INPUT_NAME TEXT("SeUnsolicitedInputPrivilege")
#define SE_MACHINE_ACCOUNT_NAME TEXT("SeMachineAccountPrivilege")
#define SE_TCB_NAME TEXT("SeTcbPrivilege")
#define SE_SECURITY_NAME TEXT("SeSecurityPrivilege")
#define SE_TAKE_OWNERSHIP_NAME TEXT("SeTakeOwnershipPrivilege")
#define SE_LOAD_DRIVER_NAME TEXT("SeLoadDriverPrivilege")
#define SE_SYSTEM_PROFILE_NAME TEXT("SeSystemProfilePrivilege")
#define SE_SYSTEMTIME_NAME TEXT("SeSystemtimePrivilege")
#define SE_PROF_SINGLE_PROCESS_NAME TEXT("SeProfileSingleProcessPrivilege")
#define SE_INC_BASE_PRIORITY_NAME TEXT("SeIncreaseBasePriorityPrivilege")
#define SE_CREATE_PAGEFILE_NAME TEXT("SeCreatePagefilePrivilege")
#define SE_CREATE_PERMANENT_NAME TEXT("SeCreatePermanentPrivilege")
#define SE_BACKUP_NAME TEXT("SeBackupPrivilege")
#define SE_RESTORE_NAME TEXT("SeRestorePrivilege")
#define SE_SHUTDOWN_NAME TEXT("SeShutdownPrivilege")
#define SE_DEBUG_NAME TEXT("SeDebugPrivilege")
#define SE_AUDIT_NAME TEXT("SeAuditPrivilege")
#define SE_SYSTEM_ENVIRONMENT_NAME TEXT("SeSystemEnvironmentPrivilege")
#define SE_CHANGE_NOTIFY_NAME TEXT("SeChangeNotifyPrivilege")
#define SE_REMOTE_SHUTDOWN_NAME TEXT("SeRemoteShutdownPrivilege")
#define SE_UNDOCK_NAME TEXT("SeUndockPrivilege")
#define SE_SYNC_AGENT_NAME TEXT("SeSyncAgentPrivilege")
#define SE_ENABLE_DELEGATION_NAME TEXT("SeEnableDelegationPrivilege")
#define SE_MANAGE_VOLUME_NAME TEXT("SeManageVolumePrivilege")
#define SE_IMPERSONATE_NAME TEXT("SeImpersonatePrivilege")
#define SE_CREATE_GLOBAL_NAME TEXT("SeCreateGlobalPrivilege")
#define SE_TRUSTED_CREDMAN_ACCESS_NAME TEXT("SeTrustedCredManAccessPrivilege")
#define SE_RELABEL_NAME TEXT("SeRelabelPrivilege")
#define SE_INC_WORKING_SET_NAME TEXT("SeIncreaseWorkingSetPrivilege")
#define SE_TIME_ZONE_NAME TEXT("SeTimeZonePrivilege")
#define SE_CREATE_SYMBOLIC_LINK_NAME TEXT("SeCreateSymbolicLinkPrivilege")

 

////////////////////////////////////////////////////////////////////
// //
// Security Quality Of Service //
// //
// //
////////////////////////////////////////////////////////////////////

// begin_wdm
//
// Impersonation Level
//
// Impersonation level is represented by a pair of bits in Windows.
// If a new impersonation level is added or lowest value is changed from
// 0 to something else, fix the Windows CreateFile call.
//

typedef enum _SECURITY_IMPERSONATION_LEVEL {
SecurityAnonymous,
SecurityIdentification,
SecurityImpersonation,
SecurityDelegation
} SECURITY_IMPERSONATION_LEVEL, * PSECURITY_IMPERSONATION_LEVEL;

#define SECURITY_MAX_IMPERSONATION_LEVEL SecurityDelegation
#define SECURITY_MIN_IMPERSONATION_LEVEL SecurityAnonymous
#define DEFAULT_IMPERSONATION_LEVEL SecurityImpersonation
#define VALID_IMPERSONATION_LEVEL(L) (((L) >= SECURITY_MIN_IMPERSONATION_LEVEL) && ((L) <= SECURITY_MAX_IMPERSONATION_LEVEL))


////////////////////////////////////////////////////////////////////
// //
// Token Object Definitions //
// //
// //
////////////////////////////////////////////////////////////////////


//
// Token Specific Access Rights.
//

#define TOKEN_ASSIGN_PRIMARY (0x0001)
#define TOKEN_DUPLICATE (0x0002)
#define TOKEN_IMPERSONATE (0x0004)
#define TOKEN_QUERY (0x0008)
#define TOKEN_QUERY_SOURCE (0x0010)
#define TOKEN_ADJUST_PRIVILEGES (0x0020)
#define TOKEN_ADJUST_GROUPS (0x0040)
#define TOKEN_ADJUST_DEFAULT (0x0080)
#define TOKEN_ADJUST_SESSIONID (0x0100)

#define TOKEN_ALL_ACCESS_P (STANDARD_RIGHTS_REQUIRED |\
TOKEN_ASSIGN_PRIMARY |\
TOKEN_DUPLICATE |\
TOKEN_IMPERSONATE |\
TOKEN_QUERY |\
TOKEN_QUERY_SOURCE |\
TOKEN_ADJUST_PRIVILEGES |\
TOKEN_ADJUST_GROUPS |\
TOKEN_ADJUST_DEFAULT )

#if ((defined(_WIN32_WINNT) && (_WIN32_WINNT > 0x0400)) || (!defined(_WIN32_WINNT)))
#define TOKEN_ALL_ACCESS (TOKEN_ALL_ACCESS_P |\
TOKEN_ADJUST_SESSIONID )
#else
#define TOKEN_ALL_ACCESS (TOKEN_ALL_ACCESS_P)
#endif

#define TOKEN_READ (STANDARD_RIGHTS_READ |\
TOKEN_QUERY)


#define TOKEN_WRITE (STANDARD_RIGHTS_WRITE |\
TOKEN_ADJUST_PRIVILEGES |\
TOKEN_ADJUST_GROUPS |\
TOKEN_ADJUST_DEFAULT)

#define TOKEN_EXECUTE (STANDARD_RIGHTS_EXECUTE)

//
//
// Token Types
//

typedef enum _TOKEN_TYPE {
TokenPrimary = 1,
TokenImpersonation
} TOKEN_TYPE;
typedef TOKEN_TYPE *PTOKEN_TYPE;

//
// Token elevation values describe the relative strength of a given token.
// A full token is a token with all groups and privileges to which the principal
// is authorized. A limited token is one with some groups or privileges removed.
//

typedef enum _TOKEN_ELEVATION_TYPE {
TokenElevationTypeDefault = 1,
TokenElevationTypeFull,
TokenElevationTypeLimited,
} TOKEN_ELEVATION_TYPE, *PTOKEN_ELEVATION_TYPE;

//
// Token Information Classes.
//


typedef enum _TOKEN_INFORMATION_CLASS {
TokenUser = 1,
TokenGroups,
TokenPrivileges,
TokenOwner,
TokenPrimaryGroup,
TokenDefaultDacl,
TokenSource,
TokenType,
TokenImpersonationLevel,
TokenStatistics,
TokenRestrictedSids,
TokenSessionId,
TokenGroupsAndPrivileges,
TokenSessionReference,
TokenSandBoxInert,
TokenAuditPolicy,
TokenOrigin,
TokenElevationType,
TokenLinkedToken,
TokenElevation,
TokenHasRestrictions,
TokenAccessInformation,
TokenVirtualizationAllowed,
TokenVirtualizationEnabled,
TokenIntegrityLevel,
TokenUIAccess,
TokenMandatoryPolicy,
TokenLogonSid,
MaxTokenInfoClass // MaxTokenInfoClass should always be the last enum
} TOKEN_INFORMATION_CLASS, *PTOKEN_INFORMATION_CLASS;

//
// Token information class structures
//


typedef struct _TOKEN_USER {
SID_AND_ATTRIBUTES User;
} TOKEN_USER, *PTOKEN_USER;

typedef struct _TOKEN_GROUPS {
DWORD GroupCount;
#ifdef MIDL_PASS
[size_is(GroupCount)] SID_AND_ATTRIBUTES Groups[*];
#else // MIDL_PASS
SID_AND_ATTRIBUTES Groups[ANYSIZE_ARRAY];
#endif // MIDL_PASS
} TOKEN_GROUPS, *PTOKEN_GROUPS;


typedef struct _TOKEN_PRIVILEGES {
DWORD PrivilegeCount;
LUID_AND_ATTRIBUTES Privileges[ANYSIZE_ARRAY];
} TOKEN_PRIVILEGES, *PTOKEN_PRIVILEGES;


typedef struct _TOKEN_OWNER {
PSID Owner;
} TOKEN_OWNER, *PTOKEN_OWNER;


typedef struct _TOKEN_PRIMARY_GROUP {
PSID PrimaryGroup;
} TOKEN_PRIMARY_GROUP, *PTOKEN_PRIMARY_GROUP;


typedef struct _TOKEN_DEFAULT_DACL {
PACL DefaultDacl;
} TOKEN_DEFAULT_DACL, *PTOKEN_DEFAULT_DACL;

typedef struct _TOKEN_GROUPS_AND_PRIVILEGES {
DWORD SidCount;
DWORD SidLength;
PSID_AND_ATTRIBUTES Sids;
DWORD RestrictedSidCount;
DWORD RestrictedSidLength;
PSID_AND_ATTRIBUTES RestrictedSids;
DWORD PrivilegeCount;
DWORD PrivilegeLength;
PLUID_AND_ATTRIBUTES Privileges;
LUID AuthenticationId;
} TOKEN_GROUPS_AND_PRIVILEGES, *PTOKEN_GROUPS_AND_PRIVILEGES;

typedef struct _TOKEN_LINKED_TOKEN {
HANDLE LinkedToken;
} TOKEN_LINKED_TOKEN, *PTOKEN_LINKED_TOKEN;

typedef struct _TOKEN_ELEVATION {
DWORD TokenIsElevated;
} TOKEN_ELEVATION, *PTOKEN_ELEVATION;

typedef struct _TOKEN_MANDATORY_LABEL {
SID_AND_ATTRIBUTES Label;
} TOKEN_MANDATORY_LABEL, *PTOKEN_MANDATORY_LABEL;

#define TOKEN_MANDATORY_POLICY_OFF 0x0
#define TOKEN_MANDATORY_POLICY_NO_WRITE_UP 0x1
#define TOKEN_MANDATORY_POLICY_NEW_PROCESS_MIN 0x2

#define TOKEN_MANDATORY_POLICY_VALID_MASK (TOKEN_MANDATORY_POLICY_NO_WRITE_UP | \
TOKEN_MANDATORY_POLICY_NEW_PROCESS_MIN)

typedef struct _TOKEN_MANDATORY_POLICY {
DWORD Policy;
} TOKEN_MANDATORY_POLICY, *PTOKEN_MANDATORY_POLICY;

typedef struct _TOKEN_ACCESS_INFORMATION {
PSID_AND_ATTRIBUTES_HASH SidHash;
PSID_AND_ATTRIBUTES_HASH RestrictedSidHash;
PTOKEN_PRIVILEGES Privileges;
LUID AuthenticationId;
TOKEN_TYPE TokenType;
SECURITY_IMPERSONATION_LEVEL ImpersonationLevel;
TOKEN_MANDATORY_POLICY MandatoryPolicy;
DWORD Flags;
} TOKEN_ACCESS_INFORMATION, *PTOKEN_ACCESS_INFORMATION;

//
// Valid bits for each TOKEN_AUDIT_POLICY policy mask field.
//

#define POLICY_AUDIT_SUBCATEGORY_COUNT (53)

typedef struct _TOKEN_AUDIT_POLICY {
BYTE PerUserPolicy[((POLICY_AUDIT_SUBCATEGORY_COUNT) >> 1) + 1];
} TOKEN_AUDIT_POLICY, *PTOKEN_AUDIT_POLICY;

#define TOKEN_SOURCE_LENGTH 8

typedef struct _TOKEN_SOURCE {
CHAR SourceName[TOKEN_SOURCE_LENGTH];
LUID SourceIdentifier;
} TOKEN_SOURCE, *PTOKEN_SOURCE;


typedef struct _TOKEN_STATISTICS {
LUID TokenId;
LUID AuthenticationId;
LARGE_INTEGER ExpirationTime;
TOKEN_TYPE TokenType;
SECURITY_IMPERSONATION_LEVEL ImpersonationLevel;
DWORD DynamicCharged;
DWORD DynamicAvailable;
DWORD GroupCount;
DWORD PrivilegeCount;
LUID ModifiedId;
} TOKEN_STATISTICS, *PTOKEN_STATISTICS;

 

typedef struct _TOKEN_CONTROL {
LUID TokenId;
LUID AuthenticationId;
LUID ModifiedId;
TOKEN_SOURCE TokenSource;
} TOKEN_CONTROL, *PTOKEN_CONTROL;

typedef struct _TOKEN_ORIGIN {
LUID OriginatingLogonSession ;
} TOKEN_ORIGIN, * PTOKEN_ORIGIN ;


typedef enum _MANDATORY_LEVEL {
MandatoryLevelUntrusted = 0,
MandatoryLevelLow,
MandatoryLevelMedium,
MandatoryLevelHigh,
MandatoryLevelSystem,
MandatoryLevelSecureProcess,
MandatoryLevelCount
} MANDATORY_LEVEL, *PMANDATORY_LEVEL;

 


//
// Security Tracking Mode
//

#define SECURITY_DYNAMIC_TRACKING (TRUE)
#define SECURITY_STATIC_TRACKING (FALSE)

typedef BOOLEAN SECURITY_CONTEXT_TRACKING_MODE,
* PSECURITY_CONTEXT_TRACKING_MODE;

 

//
// Quality Of Service
//

typedef struct _SECURITY_QUALITY_OF_SERVICE {
DWORD Length;
SECURITY_IMPERSONATION_LEVEL ImpersonationLevel;
SECURITY_CONTEXT_TRACKING_MODE ContextTrackingMode;
BOOLEAN EffectiveOnly;
} SECURITY_QUALITY_OF_SERVICE, * PSECURITY_QUALITY_OF_SERVICE;


//
// Used to represent information related to a thread impersonation
//

typedef struct _SE_IMPERSONATION_STATE {
PACCESS_TOKEN Token;
BOOLEAN CopyOnOpen;
BOOLEAN EffectiveOnly;
SECURITY_IMPERSONATION_LEVEL Level;
} SE_IMPERSONATION_STATE, *PSE_IMPERSONATION_STATE;

#define DISABLE_MAX_PRIVILEGE 0x1
#define SANDBOX_INERT 0x2
#define LUA_TOKEN 0x4
#define WRITE_RESTRICTED 0x8

typedef DWORD SECURITY_INFORMATION, *PSECURITY_INFORMATION;

#define OWNER_SECURITY_INFORMATION (0x00000001L)
#define GROUP_SECURITY_INFORMATION (0x00000002L)
#define DACL_SECURITY_INFORMATION (0x00000004L)
#define SACL_SECURITY_INFORMATION (0x00000008L)
#define LABEL_SECURITY_INFORMATION (0x00000010L)

#define PROTECTED_DACL_SECURITY_INFORMATION (0x80000000L)
#define PROTECTED_SACL_SECURITY_INFORMATION (0x40000000L)
#define UNPROTECTED_DACL_SECURITY_INFORMATION (0x20000000L)
#define UNPROTECTED_SACL_SECURITY_INFORMATION (0x10000000L)

#define PROCESS_TERMINATE (0x0001)
#define PROCESS_CREATE_THREAD (0x0002)
#define PROCESS_SET_SESSIONID (0x0004)
#define PROCESS_VM_OPERATION (0x0008)
#define PROCESS_VM_READ (0x0010)
#define PROCESS_VM_WRITE (0x0020)
#define PROCESS_DUP_HANDLE (0x0040)
#define PROCESS_CREATE_PROCESS (0x0080)
#define PROCESS_SET_QUOTA (0x0100)
#define PROCESS_SET_INFORMATION (0x0200)
#define PROCESS_QUERY_INFORMATION (0x0400)
#define PROCESS_SUSPEND_RESUME (0x0800)
#define PROCESS_QUERY_LIMITED_INFORMATION (0x1000)
#if (NTDDI_VERSION >= NTDDI_VISTA)
#define PROCESS_ALL_ACCESS (STANDARD_RIGHTS_REQUIRED | SYNCHRONIZE | \
0xFFFF)
#else
#define PROCESS_ALL_ACCESS (STANDARD_RIGHTS_REQUIRED | SYNCHRONIZE | \
0xFFF)
#endif

#if defined(_WIN64)

#define MAXIMUM_PROC_PER_GROUP 64

#else

#define MAXIMUM_PROC_PER_GROUP 32

#endif

#define MAXIMUM_PROCESSORS MAXIMUM_PROC_PER_GROUP

#define THREAD_TERMINATE (0x0001)
#define THREAD_SUSPEND_RESUME (0x0002)
#define THREAD_GET_CONTEXT (0x0008)
#define THREAD_SET_CONTEXT (0x0010)
#define THREAD_QUERY_INFORMATION (0x0040)
#define THREAD_SET_INFORMATION (0x0020)
#define THREAD_SET_THREAD_TOKEN (0x0080)
#define THREAD_IMPERSONATE (0x0100)
#define THREAD_DIRECT_IMPERSONATION (0x0200)
// begin_wdm
#define THREAD_SET_LIMITED_INFORMATION (0x0400) // winnt
#define THREAD_QUERY_LIMITED_INFORMATION (0x0800) // winnt
#if (NTDDI_VERSION >= NTDDI_VISTA)
#define THREAD_ALL_ACCESS (STANDARD_RIGHTS_REQUIRED | SYNCHRONIZE | \
0xFFFF)
#else
#define THREAD_ALL_ACCESS (STANDARD_RIGHTS_REQUIRED | SYNCHRONIZE | \
0x3FF)
#endif
#define JOB_OBJECT_ASSIGN_PROCESS (0x0001)
#define JOB_OBJECT_SET_ATTRIBUTES (0x0002)
#define JOB_OBJECT_QUERY (0x0004)
#define JOB_OBJECT_TERMINATE (0x0008)
#define JOB_OBJECT_SET_SECURITY_ATTRIBUTES (0x0010)
#define JOB_OBJECT_ALL_ACCESS (STANDARD_RIGHTS_REQUIRED | SYNCHRONIZE | \
0x1F )

typedef struct _JOB_SET_ARRAY {
HANDLE JobHandle; // Handle to job object to insert
DWORD MemberLevel; // Level of this job in the set. Must be > 0. Can be sparse.
DWORD Flags; // Unused. Must be zero
} JOB_SET_ARRAY, *PJOB_SET_ARRAY;

#define FLS_MAXIMUM_AVAILABLE 128
#define TLS_MINIMUM_AVAILABLE 64

typedef struct _NT_TIB {
struct _EXCEPTION_REGISTRATION_RECORD *ExceptionList;
PVOID StackBase;
PVOID StackLimit;
PVOID SubSystemTib;
#if defined(_MSC_EXTENSIONS)
union {
PVOID FiberData;
DWORD Version;
};
#else
PVOID FiberData;
#endif
PVOID ArbitraryUserPointer;
struct _NT_TIB *Self;
} NT_TIB;
typedef NT_TIB *PNT_TIB;

//
// 32 and 64 bit specific version for wow64 and the debugger
//
typedef struct _NT_TIB32 {
DWORD ExceptionList;
DWORD StackBase;
DWORD StackLimit;
DWORD SubSystemTib;

#if defined(_MSC_EXTENSIONS)
union {
DWORD FiberData;
DWORD Version;
};
#else
DWORD FiberData;
#endif

DWORD ArbitraryUserPointer;
DWORD Self;
} NT_TIB32, *PNT_TIB32;

typedef struct _NT_TIB64 {
DWORD64 ExceptionList;
DWORD64 StackBase;
DWORD64 StackLimit;
DWORD64 SubSystemTib;

#if defined(_MSC_EXTENSIONS)
union {
DWORD64 FiberData;
DWORD Version;
};

#else
DWORD64 FiberData;
#endif

DWORD64 ArbitraryUserPointer;
DWORD64 Self;
} NT_TIB64, *PNT_TIB64;

 

#define THREAD_BASE_PRIORITY_LOWRT 15 // value that gets a thread to LowRealtime-1
#define THREAD_BASE_PRIORITY_MAX 2 // maximum thread base priority boost
#define THREAD_BASE_PRIORITY_MIN (-2) // minimum thread base priority boost
#define THREAD_BASE_PRIORITY_IDLE (-15) // value that gets a thread to idle

typedef struct _UMS_CREATE_THREAD_ATTRIBUTES {
DWORD UmsVersion;
PVOID UmsContext;
PVOID UmsCompletionList;
} UMS_CREATE_THREAD_ATTRIBUTES, *PUMS_CREATE_THREAD_ATTRIBUTES;

typedef struct _QUOTA_LIMITS {
SIZE_T PagedPoolLimit;
SIZE_T NonPagedPoolLimit;
SIZE_T MinimumWorkingSetSize;
SIZE_T MaximumWorkingSetSize;
SIZE_T PagefileLimit;
LARGE_INTEGER TimeLimit;
} QUOTA_LIMITS, *PQUOTA_LIMITS;

#define QUOTA_LIMITS_HARDWS_MIN_ENABLE 0x00000001
#define QUOTA_LIMITS_HARDWS_MIN_DISABLE 0x00000002
#define QUOTA_LIMITS_HARDWS_MAX_ENABLE 0x00000004
#define QUOTA_LIMITS_HARDWS_MAX_DISABLE 0x00000008
#define QUOTA_LIMITS_USE_DEFAULT_LIMITS 0x00000010

typedef union _RATE_QUOTA_LIMIT {
DWORD RateData;
struct {
DWORD RatePercent : 7;
DWORD Reserved0 : 25;
} DUMMYSTRUCTNAME;
} RATE_QUOTA_LIMIT, *PRATE_QUOTA_LIMIT;

typedef struct _QUOTA_LIMITS_EX {
SIZE_T PagedPoolLimit;
SIZE_T NonPagedPoolLimit;
SIZE_T MinimumWorkingSetSize;
SIZE_T MaximumWorkingSetSize;
SIZE_T PagefileLimit; // Limit expressed in pages
LARGE_INTEGER TimeLimit;
SIZE_T WorkingSetLimit; // Limit expressed in pages
SIZE_T Reserved2;
SIZE_T Reserved3;
SIZE_T Reserved4;
DWORD Flags;
RATE_QUOTA_LIMIT CpuRateLimit;
} QUOTA_LIMITS_EX, *PQUOTA_LIMITS_EX;

typedef struct _IO_COUNTERS {
ULONGLONG ReadOperationCount;
ULONGLONG WriteOperationCount;
ULONGLONG OtherOperationCount;
ULONGLONG ReadTransferCount;
ULONGLONG WriteTransferCount;
ULONGLONG OtherTransferCount;
} IO_COUNTERS;
typedef IO_COUNTERS *PIO_COUNTERS;

#define MAX_HW_COUNTERS 16
#define THREAD_PROFILING_FLAG_DISPATCH 0x00000001

typedef enum _HARDWARE_COUNTER_TYPE {
PMCCounter,
MaxHardwareCounterType
} HARDWARE_COUNTER_TYPE, *PHARDWARE_COUNTER_TYPE;

typedef struct _JOBOBJECT_BASIC_ACCOUNTING_INFORMATION {
LARGE_INTEGER TotalUserTime;
LARGE_INTEGER TotalKernelTime;
LARGE_INTEGER ThisPeriodTotalUserTime;
LARGE_INTEGER ThisPeriodTotalKernelTime;
DWORD TotalPageFaultCount;
DWORD TotalProcesses;
DWORD ActiveProcesses;
DWORD TotalTerminatedProcesses;
} JOBOBJECT_BASIC_ACCOUNTING_INFORMATION, *PJOBOBJECT_BASIC_ACCOUNTING_INFORMATION;

typedef struct _JOBOBJECT_BASIC_LIMIT_INFORMATION {
LARGE_INTEGER PerProcessUserTimeLimit;
LARGE_INTEGER PerJobUserTimeLimit;
DWORD LimitFlags;
SIZE_T MinimumWorkingSetSize;
SIZE_T MaximumWorkingSetSize;
DWORD ActiveProcessLimit;
ULONG_PTR Affinity;
DWORD PriorityClass;
DWORD SchedulingClass;
} JOBOBJECT_BASIC_LIMIT_INFORMATION, *PJOBOBJECT_BASIC_LIMIT_INFORMATION;

typedef struct _JOBOBJECT_EXTENDED_LIMIT_INFORMATION {
JOBOBJECT_BASIC_LIMIT_INFORMATION BasicLimitInformation;
IO_COUNTERS IoInfo;
SIZE_T ProcessMemoryLimit;
SIZE_T JobMemoryLimit;
SIZE_T PeakProcessMemoryUsed;
SIZE_T PeakJobMemoryUsed;
} JOBOBJECT_EXTENDED_LIMIT_INFORMATION, *PJOBOBJECT_EXTENDED_LIMIT_INFORMATION;

typedef struct _JOBOBJECT_BASIC_PROCESS_ID_LIST {
DWORD NumberOfAssignedProcesses;
DWORD NumberOfProcessIdsInList;
ULONG_PTR ProcessIdList[1];
} JOBOBJECT_BASIC_PROCESS_ID_LIST, *PJOBOBJECT_BASIC_PROCESS_ID_LIST;

typedef struct _JOBOBJECT_BASIC_UI_RESTRICTIONS {
DWORD UIRestrictionsClass;
} JOBOBJECT_BASIC_UI_RESTRICTIONS, *PJOBOBJECT_BASIC_UI_RESTRICTIONS;

//
// N.B. The JOBOBJECT_SECURITY_LIMIT_INFORMATION information class is no longer supported.
//

typedef struct _JOBOBJECT_SECURITY_LIMIT_INFORMATION {
DWORD SecurityLimitFlags ;
HANDLE JobToken ;
PTOKEN_GROUPS SidsToDisable ;
PTOKEN_PRIVILEGES PrivilegesToDelete ;
PTOKEN_GROUPS RestrictedSids ;
} JOBOBJECT_SECURITY_LIMIT_INFORMATION, *PJOBOBJECT_SECURITY_LIMIT_INFORMATION ;

typedef struct _JOBOBJECT_END_OF_JOB_TIME_INFORMATION {
DWORD EndOfJobTimeAction;
} JOBOBJECT_END_OF_JOB_TIME_INFORMATION, *PJOBOBJECT_END_OF_JOB_TIME_INFORMATION;

typedef struct _JOBOBJECT_ASSOCIATE_COMPLETION_PORT {
PVOID CompletionKey;
HANDLE CompletionPort;
} JOBOBJECT_ASSOCIATE_COMPLETION_PORT, *PJOBOBJECT_ASSOCIATE_COMPLETION_PORT;

typedef struct _JOBOBJECT_BASIC_AND_IO_ACCOUNTING_INFORMATION {
JOBOBJECT_BASIC_ACCOUNTING_INFORMATION BasicInfo;
IO_COUNTERS IoInfo;
} JOBOBJECT_BASIC_AND_IO_ACCOUNTING_INFORMATION, *PJOBOBJECT_BASIC_AND_IO_ACCOUNTING_INFORMATION;

typedef struct _JOBOBJECT_JOBSET_INFORMATION {
DWORD MemberLevel;
} JOBOBJECT_JOBSET_INFORMATION, *PJOBOBJECT_JOBSET_INFORMATION;

#define JOB_OBJECT_TERMINATE_AT_END_OF_JOB 0
#define JOB_OBJECT_POST_AT_END_OF_JOB 1

//
// Completion Port Messages for job objects
//
// These values are returned via the lpNumberOfBytesTransferred parameter
//

#define JOB_OBJECT_MSG_END_OF_JOB_TIME 1
#define JOB_OBJECT_MSG_END_OF_PROCESS_TIME 2
#define JOB_OBJECT_MSG_ACTIVE_PROCESS_LIMIT 3
#define JOB_OBJECT_MSG_ACTIVE_PROCESS_ZERO 4
#define JOB_OBJECT_MSG_NEW_PROCESS 6
#define JOB_OBJECT_MSG_EXIT_PROCESS 7
#define JOB_OBJECT_MSG_ABNORMAL_EXIT_PROCESS 8
#define JOB_OBJECT_MSG_PROCESS_MEMORY_LIMIT 9
#define JOB_OBJECT_MSG_JOB_MEMORY_LIMIT 10

//
// Basic Limits
//
#define JOB_OBJECT_LIMIT_WORKINGSET 0x00000001
#define JOB_OBJECT_LIMIT_PROCESS_TIME 0x00000002
#define JOB_OBJECT_LIMIT_JOB_TIME 0x00000004
#define JOB_OBJECT_LIMIT_ACTIVE_PROCESS 0x00000008
#define JOB_OBJECT_LIMIT_AFFINITY 0x00000010
#define JOB_OBJECT_LIMIT_PRIORITY_CLASS 0x00000020
#define JOB_OBJECT_LIMIT_PRESERVE_JOB_TIME 0x00000040
#define JOB_OBJECT_LIMIT_SCHEDULING_CLASS 0x00000080

//
// Extended Limits
//
#define JOB_OBJECT_LIMIT_PROCESS_MEMORY 0x00000100
#define JOB_OBJECT_LIMIT_JOB_MEMORY 0x00000200
#define JOB_OBJECT_LIMIT_DIE_ON_UNHANDLED_EXCEPTION 0x00000400
#define JOB_OBJECT_LIMIT_BREAKAWAY_OK 0x00000800
#define JOB_OBJECT_LIMIT_SILENT_BREAKAWAY_OK 0x00001000
#define JOB_OBJECT_LIMIT_KILL_ON_JOB_CLOSE 0x00002000

#define JOB_OBJECT_LIMIT_SUBSET_AFFINITY 0x00004000
#define JOB_OBJECT_LIMIT_RESERVED3 0x00008000
#define JOB_OBJECT_LIMIT_RESERVED4 0x00010000
#define JOB_OBJECT_LIMIT_RESERVED5 0x00020000
#define JOB_OBJECT_LIMIT_RESERVED6 0x00040000


#define JOB_OBJECT_LIMIT_VALID_FLAGS 0x0007ffff

#define JOB_OBJECT_BASIC_LIMIT_VALID_FLAGS 0x000000ff
#define JOB_OBJECT_EXTENDED_LIMIT_VALID_FLAGS 0x00007fff
#define JOB_OBJECT_RESERVED_LIMIT_VALID_FLAGS 0x0007ffff

//
// UI restrictions for jobs
//

#define JOB_OBJECT_UILIMIT_NONE 0x00000000

#define JOB_OBJECT_UILIMIT_HANDLES 0x00000001
#define JOB_OBJECT_UILIMIT_READCLIPBOARD 0x00000002
#define JOB_OBJECT_UILIMIT_WRITECLIPBOARD 0x00000004
#define JOB_OBJECT_UILIMIT_SYSTEMPARAMETERS 0x00000008
#define JOB_OBJECT_UILIMIT_DISPLAYSETTINGS 0x00000010
#define JOB_OBJECT_UILIMIT_GLOBALATOMS 0x00000020
#define JOB_OBJECT_UILIMIT_DESKTOP 0x00000040
#define JOB_OBJECT_UILIMIT_EXITWINDOWS 0x00000080

#define JOB_OBJECT_UILIMIT_ALL 0x000000FF

#define JOB_OBJECT_UI_VALID_FLAGS 0x000000FF

#define JOB_OBJECT_SECURITY_NO_ADMIN 0x00000001
#define JOB_OBJECT_SECURITY_RESTRICTED_TOKEN 0x00000002
#define JOB_OBJECT_SECURITY_ONLY_TOKEN 0x00000004
#define JOB_OBJECT_SECURITY_FILTER_TOKENS 0x00000008

#define JOB_OBJECT_SECURITY_VALID_FLAGS 0x0000000f

typedef enum _JOBOBJECTINFOCLASS {
JobObjectBasicAccountingInformation = 1,
JobObjectBasicLimitInformation,
JobObjectBasicProcessIdList,
JobObjectBasicUIRestrictions,
JobObjectSecurityLimitInformation, // deprecated
JobObjectEndOfJobTimeInformation,
JobObjectAssociateCompletionPortInformation,
JobObjectBasicAndIoAccountingInformation,
JobObjectExtendedLimitInformation,
JobObjectJobSetInformation,
JobObjectGroupInformation,
MaxJobObjectInfoClass
} JOBOBJECTINFOCLASS;

//
#define EVENT_MODIFY_STATE 0x0002
#define EVENT_ALL_ACCESS (STANDARD_RIGHTS_REQUIRED|SYNCHRONIZE|0x3)

#define MUTANT_QUERY_STATE 0x0001

#define MUTANT_ALL_ACCESS (STANDARD_RIGHTS_REQUIRED|SYNCHRONIZE|\
MUTANT_QUERY_STATE)

#define SEMAPHORE_MODIFY_STATE 0x0002
#define SEMAPHORE_ALL_ACCESS (STANDARD_RIGHTS_REQUIRED|SYNCHRONIZE|0x3)

//
// Timer Specific Access Rights.
//

#define TIMER_QUERY_STATE 0x0001
#define TIMER_MODIFY_STATE 0x0002

#define TIMER_ALL_ACCESS (STANDARD_RIGHTS_REQUIRED|SYNCHRONIZE|\
TIMER_QUERY_STATE|TIMER_MODIFY_STATE)


#define TIME_ZONE_ID_UNKNOWN 0
#define TIME_ZONE_ID_STANDARD 1
#define TIME_ZONE_ID_DAYLIGHT 2


typedef enum _LOGICAL_PROCESSOR_RELATIONSHIP {
RelationProcessorCore,
RelationNumaNode,
RelationCache,
RelationProcessorPackage,
RelationGroup,
RelationAll = 0xffff
} LOGICAL_PROCESSOR_RELATIONSHIP;

#define LTP_PC_SMT 0x1

typedef enum _PROCESSOR_CACHE_TYPE {
CacheUnified,
CacheInstruction,
CacheData,
CacheTrace
} PROCESSOR_CACHE_TYPE;

#define CACHE_FULLY_ASSOCIATIVE 0xFF

typedef struct _CACHE_DESCRIPTOR {
BYTE Level;
BYTE Associativity;
WORD LineSize;
DWORD Size;
PROCESSOR_CACHE_TYPE Type;
} CACHE_DESCRIPTOR, *PCACHE_DESCRIPTOR;

typedef struct _SYSTEM_LOGICAL_PROCESSOR_INFORMATION {
ULONG_PTR ProcessorMask;
LOGICAL_PROCESSOR_RELATIONSHIP Relationship;
union {
struct {
BYTE Flags;
} ProcessorCore;
struct {
DWORD NodeNumber;
} NumaNode;
CACHE_DESCRIPTOR Cache;
ULONGLONG Reserved[2];
} DUMMYUNIONNAME;
} SYSTEM_LOGICAL_PROCESSOR_INFORMATION, *PSYSTEM_LOGICAL_PROCESSOR_INFORMATION;

typedef struct _PROCESSOR_RELATIONSHIP {
BYTE Flags;
BYTE Reserved[21];
WORD GroupCount;
__field_ecount(GroupCount) GROUP_AFFINITY GroupMask[ANYSIZE_ARRAY];
} PROCESSOR_RELATIONSHIP, *PPROCESSOR_RELATIONSHIP;

typedef struct _NUMA_NODE_RELATIONSHIP {
DWORD NodeNumber;
BYTE Reserved[20];
GROUP_AFFINITY GroupMask;
} NUMA_NODE_RELATIONSHIP, *PNUMA_NODE_RELATIONSHIP;

typedef struct _CACHE_RELATIONSHIP {
BYTE Level;
BYTE Associativity;
WORD LineSize;
DWORD CacheSize;
PROCESSOR_CACHE_TYPE Type;
BYTE Reserved[20];
GROUP_AFFINITY GroupMask;
} CACHE_RELATIONSHIP, *PCACHE_RELATIONSHIP;

typedef struct _PROCESSOR_GROUP_INFO {
BYTE MaximumProcessorCount;
BYTE ActiveProcessorCount;
BYTE Reserved[38];
KAFFINITY ActiveProcessorMask;
} PROCESSOR_GROUP_INFO, *PPROCESSOR_GROUP_INFO;

typedef struct _GROUP_RELATIONSHIP {
WORD MaximumGroupCount;
WORD ActiveGroupCount;
BYTE Reserved[20];
PROCESSOR_GROUP_INFO GroupInfo[ANYSIZE_ARRAY];
} GROUP_RELATIONSHIP, *PGROUP_RELATIONSHIP;

__struct_bcount(Size) struct _SYSTEM_LOGICAL_PROCESSOR_INFORMATION_EX {
LOGICAL_PROCESSOR_RELATIONSHIP Relationship;
DWORD Size;
union {
PROCESSOR_RELATIONSHIP Processor;
NUMA_NODE_RELATIONSHIP NumaNode;
CACHE_RELATIONSHIP Cache;
GROUP_RELATIONSHIP Group;
} DUMMYUNIONNAME;
};

typedef struct _SYSTEM_LOGICAL_PROCESSOR_INFORMATION_EX SYSTEM_LOGICAL_PROCESSOR_INFORMATION_EX, *PSYSTEM_LOGICAL_PROCESSOR_INFORMATION_EX;

// end_wdm end_ntminiport

typedef struct _SYSTEM_PROCESSOR_CYCLE_TIME_INFORMATION {
DWORD64 CycleTime;
} SYSTEM_PROCESSOR_CYCLE_TIME_INFORMATION, *PSYSTEM_PROCESSOR_CYCLE_TIME_INFORMATION;


#define PROCESSOR_INTEL_386 386
#define PROCESSOR_INTEL_486 486
#define PROCESSOR_INTEL_PENTIUM 586
#define PROCESSOR_INTEL_IA64 2200
#define PROCESSOR_AMD_X8664 8664
#define PROCESSOR_MIPS_R4000 4000 // incl R4101 & R3910 for Windows CE
#define PROCESSOR_ALPHA_21064 21064
#define PROCESSOR_PPC_601 601
#define PROCESSOR_PPC_603 603
#define PROCESSOR_PPC_604 604
#define PROCESSOR_PPC_620 620
#define PROCESSOR_HITACHI_SH3 10003 // Windows CE
#define PROCESSOR_HITACHI_SH3E 10004 // Windows CE
#define PROCESSOR_HITACHI_SH4 10005 // Windows CE
#define PROCESSOR_MOTOROLA_821 821 // Windows CE
#define PROCESSOR_SHx_SH3 103 // Windows CE
#define PROCESSOR_SHx_SH4 104 // Windows CE
#define PROCESSOR_STRONGARM 2577 // Windows CE - 0xA11
#define PROCESSOR_ARM720 1824 // Windows CE - 0x720
#define PROCESSOR_ARM820 2080 // Windows CE - 0x820
#define PROCESSOR_ARM920 2336 // Windows CE - 0x920
#define PROCESSOR_ARM_7TDMI 70001 // Windows CE
#define PROCESSOR_OPTIL 0x494f // MSIL

#define PROCESSOR_ARCHITECTURE_INTEL 0
#define PROCESSOR_ARCHITECTURE_MIPS 1
#define PROCESSOR_ARCHITECTURE_ALPHA 2
#define PROCESSOR_ARCHITECTURE_PPC 3
#define PROCESSOR_ARCHITECTURE_SHX 4
#define PROCESSOR_ARCHITECTURE_ARM 5
#define PROCESSOR_ARCHITECTURE_IA64 6
#define PROCESSOR_ARCHITECTURE_ALPHA64 7
#define PROCESSOR_ARCHITECTURE_MSIL 8
#define PROCESSOR_ARCHITECTURE_AMD64 9
#define PROCESSOR_ARCHITECTURE_IA32_ON_WIN64 10

#define PROCESSOR_ARCHITECTURE_UNKNOWN 0xFFFF

#define PF_FLOATING_POINT_PRECISION_ERRATA 0
#define PF_FLOATING_POINT_EMULATED 1
#define PF_COMPARE_EXCHANGE_DOUBLE 2
#define PF_MMX_INSTRUCTIONS_AVAILABLE 3
#define PF_PPC_MOVEMEM_64BIT_OK 4
#define PF_ALPHA_BYTE_INSTRUCTIONS 5
#define PF_XMMI_INSTRUCTIONS_AVAILABLE 6
#define PF_3DNOW_INSTRUCTIONS_AVAILABLE 7
#define PF_RDTSC_INSTRUCTION_AVAILABLE 8
#define PF_PAE_ENABLED 9
#define PF_XMMI64_INSTRUCTIONS_AVAILABLE 10
#define PF_SSE_DAZ_MODE_AVAILABLE 11
#define PF_NX_ENABLED 12
#define PF_SSE3_INSTRUCTIONS_AVAILABLE 13
#define PF_COMPARE_EXCHANGE128 14
#define PF_COMPARE64_EXCHANGE128 15
#define PF_CHANNELS_ENABLED 16
#define PF_XSAVE_ENABLED 17

//
// Known extended CPU state feature IDs
//

#define XSTATE_LEGACY_FLOATING_POINT 0
#define XSTATE_LEGACY_SSE 1
#define XSTATE_GSSE 2

#define XSTATE_MASK_LEGACY_FLOATING_POINT (1i64 << (XSTATE_LEGACY_FLOATING_POINT))
#define XSTATE_MASK_LEGACY_SSE (1i64 << (XSTATE_LEGACY_SSE))
#define XSTATE_MASK_LEGACY (XSTATE_MASK_LEGACY_FLOATING_POINT | XSTATE_MASK_LEGACY_SSE)
#define XSTATE_MASK_GSSE (1i64 << (XSTATE_GSSE))

#define MAXIMUM_XSTATE_FEATURES 64

//
// Extended processor state configuration
//

typedef struct _XSTATE_FEATURE {
DWORD Offset;
DWORD Size;
} XSTATE_FEATURE, *PXSTATE_FEATURE;

typedef struct _XSTATE_CONFIGURATION {
// Mask of enabled features
DWORD64 EnabledFeatures;

// Total size of the save area
DWORD Size;

DWORD OptimizedSave : 1;

// List of features (
XSTATE_FEATURE Features[MAXIMUM_XSTATE_FEATURES];

} XSTATE_CONFIGURATION, *PXSTATE_CONFIGURATION;


typedef struct _MEMORY_BASIC_INFORMATION {
PVOID BaseAddress;
PVOID AllocationBase;
DWORD AllocationProtect;
SIZE_T RegionSize;
DWORD State;
DWORD Protect;
DWORD Type;
} MEMORY_BASIC_INFORMATION, *PMEMORY_BASIC_INFORMATION;

typedef struct _MEMORY_BASIC_INFORMATION32 {
DWORD BaseAddress;
DWORD AllocationBase;
DWORD AllocationProtect;
DWORD RegionSize;
DWORD State;
DWORD Protect;
DWORD Type;
} MEMORY_BASIC_INFORMATION32, *PMEMORY_BASIC_INFORMATION32;

typedef struct DECLSPEC_ALIGN(16) _MEMORY_BASIC_INFORMATION64 {
ULONGLONG BaseAddress;
ULONGLONG AllocationBase;
DWORD AllocationProtect;
DWORD __alignment1;
ULONGLONG RegionSize;
DWORD State;
DWORD Protect;
DWORD Type;
DWORD __alignment2;
} MEMORY_BASIC_INFORMATION64, *PMEMORY_BASIC_INFORMATION64;

#define SECTION_QUERY 0x0001
#define SECTION_MAP_WRITE 0x0002
#define SECTION_MAP_READ 0x0004
#define SECTION_MAP_EXECUTE 0x0008
#define SECTION_EXTEND_SIZE 0x0010
#define SECTION_MAP_EXECUTE_EXPLICIT 0x0020 // not included in SECTION_ALL_ACCESS

#define SECTION_ALL_ACCESS (STANDARD_RIGHTS_REQUIRED|SECTION_QUERY|\
SECTION_MAP_WRITE | \
SECTION_MAP_READ | \
SECTION_MAP_EXECUTE | \
SECTION_EXTEND_SIZE)

#define SESSION_QUERY_ACCESS 0x0001
#define SESSION_MODIFY_ACCESS 0x0002

#define SESSION_ALL_ACCESS (STANDARD_RIGHTS_REQUIRED | \
SESSION_QUERY_ACCESS | \
SESSION_MODIFY_ACCESS)

#define PAGE_NOACCESS 0x01
#define PAGE_READONLY 0x02
#define PAGE_READWRITE 0x04
#define PAGE_WRITECOPY 0x08
#define PAGE_EXECUTE 0x10
#define PAGE_EXECUTE_READ 0x20
#define PAGE_EXECUTE_READWRITE 0x40
#define PAGE_EXECUTE_WRITECOPY 0x80
#define PAGE_GUARD 0x100
#define PAGE_NOCACHE 0x200
#define PAGE_WRITECOMBINE 0x400
#define MEM_COMMIT 0x1000
#define MEM_RESERVE 0x2000
#define MEM_DECOMMIT 0x4000
#define MEM_RELEASE 0x8000
#define MEM_FREE 0x10000
#define MEM_PRIVATE 0x20000
#define MEM_MAPPED 0x40000
#define MEM_RESET 0x80000
#define MEM_TOP_DOWN 0x100000
#define MEM_WRITE_WATCH 0x200000
#define MEM_PHYSICAL 0x400000
#define MEM_ROTATE 0x800000
#define MEM_LARGE_PAGES 0x20000000
#define MEM_4MB_PAGES 0x80000000
#define SEC_FILE 0x800000
#define SEC_IMAGE 0x1000000
#define SEC_PROTECTED_IMAGE 0x2000000
#define SEC_RESERVE 0x4000000
#define SEC_COMMIT 0x8000000
#define SEC_NOCACHE 0x10000000
#define SEC_WRITECOMBINE 0x40000000
#define SEC_LARGE_PAGES 0x80000000
#define MEM_IMAGE SEC_IMAGE
#define WRITE_WATCH_FLAG_RESET 0x01

//
// Define access rights to files and directories
//

//
// The FILE_READ_DATA and FILE_WRITE_DATA constants are also defined in
// devioctl.h as FILE_READ_ACCESS and FILE_WRITE_ACCESS. The values for these
// constants *MUST* always be in sync.
// The values are redefined in devioctl.h because they must be available to
// both DOS and NT.
//

#define FILE_READ_DATA ( 0x0001 ) // file & pipe
#define FILE_LIST_DIRECTORY ( 0x0001 ) // directory

#define FILE_WRITE_DATA ( 0x0002 ) // file & pipe
#define FILE_ADD_FILE ( 0x0002 ) // directory

#define FILE_APPEND_DATA ( 0x0004 ) // file
#define FILE_ADD_SUBDIRECTORY ( 0x0004 ) // directory
#define FILE_CREATE_PIPE_INSTANCE ( 0x0004 ) // named pipe


#define FILE_READ_EA ( 0x0008 ) // file & directory

#define FILE_WRITE_EA ( 0x0010 ) // file & directory

#define FILE_EXECUTE ( 0x0020 ) // file
#define FILE_TRAVERSE ( 0x0020 ) // directory

#define FILE_DELETE_CHILD ( 0x0040 ) // directory

#define FILE_READ_ATTRIBUTES ( 0x0080 ) // all

#define FILE_WRITE_ATTRIBUTES ( 0x0100 ) // all

#define FILE_ALL_ACCESS (STANDARD_RIGHTS_REQUIRED | SYNCHRONIZE | 0x1FF)

#define FILE_GENERIC_READ (STANDARD_RIGHTS_READ |\
FILE_READ_DATA |\
FILE_READ_ATTRIBUTES |\
FILE_READ_EA |\
SYNCHRONIZE)


#define FILE_GENERIC_WRITE (STANDARD_RIGHTS_WRITE |\
FILE_WRITE_DATA |\
FILE_WRITE_ATTRIBUTES |\
FILE_WRITE_EA |\
FILE_APPEND_DATA |\
SYNCHRONIZE)


#define FILE_GENERIC_EXECUTE (STANDARD_RIGHTS_EXECUTE |\
FILE_READ_ATTRIBUTES |\
FILE_EXECUTE |\
SYNCHRONIZE)

#define FILE_SHARE_READ 0x00000001
#define FILE_SHARE_WRITE 0x00000002
#define FILE_SHARE_DELETE 0x00000004
#define FILE_ATTRIBUTE_READONLY 0x00000001
#define FILE_ATTRIBUTE_HIDDEN 0x00000002
#define FILE_ATTRIBUTE_SYSTEM 0x00000004
#define FILE_ATTRIBUTE_DIRECTORY 0x00000010
#define FILE_ATTRIBUTE_ARCHIVE 0x00000020
#define FILE_ATTRIBUTE_DEVICE 0x00000040
#define FILE_ATTRIBUTE_NORMAL 0x00000080
#define FILE_ATTRIBUTE_TEMPORARY 0x00000100
#define FILE_ATTRIBUTE_SPARSE_FILE 0x00000200
#define FILE_ATTRIBUTE_REPARSE_POINT 0x00000400
#define FILE_ATTRIBUTE_COMPRESSED 0x00000800
#define FILE_ATTRIBUTE_OFFLINE 0x00001000
#define FILE_ATTRIBUTE_NOT_CONTENT_INDEXED 0x00002000
#define FILE_ATTRIBUTE_ENCRYPTED 0x00004000
#define FILE_ATTRIBUTE_VIRTUAL 0x00010000
#define FILE_NOTIFY_CHANGE_FILE_NAME 0x00000001
#define FILE_NOTIFY_CHANGE_DIR_NAME 0x00000002
#define FILE_NOTIFY_CHANGE_ATTRIBUTES 0x00000004
#define FILE_NOTIFY_CHANGE_SIZE 0x00000008
#define FILE_NOTIFY_CHANGE_LAST_WRITE 0x00000010
#define FILE_NOTIFY_CHANGE_LAST_ACCESS 0x00000020
#define FILE_NOTIFY_CHANGE_CREATION 0x00000040
#define FILE_NOTIFY_CHANGE_SECURITY 0x00000100
#define FILE_ACTION_ADDED 0x00000001
#define FILE_ACTION_REMOVED 0x00000002
#define FILE_ACTION_MODIFIED 0x00000003
#define FILE_ACTION_RENAMED_OLD_NAME 0x00000004
#define FILE_ACTION_RENAMED_NEW_NAME 0x00000005
#define MAILSLOT_NO_MESSAGE ((DWORD)-1)
#define MAILSLOT_WAIT_FOREVER ((DWORD)-1)
#define FILE_CASE_SENSITIVE_SEARCH 0x00000001
#define FILE_CASE_PRESERVED_NAMES 0x00000002
#define FILE_UNICODE_ON_DISK 0x00000004
#define FILE_PERSISTENT_ACLS 0x00000008
#define FILE_FILE_COMPRESSION 0x00000010
#define FILE_VOLUME_QUOTAS 0x00000020
#define FILE_SUPPORTS_SPARSE_FILES 0x00000040
#define FILE_SUPPORTS_REPARSE_POINTS 0x00000080
#define FILE_SUPPORTS_REMOTE_STORAGE 0x00000100
#define FILE_VOLUME_IS_COMPRESSED 0x00008000
#define FILE_SUPPORTS_OBJECT_IDS 0x00010000
#define FILE_SUPPORTS_ENCRYPTION 0x00020000
#define FILE_NAMED_STREAMS 0x00040000
#define FILE_READ_ONLY_VOLUME 0x00080000
#define FILE_SEQUENTIAL_WRITE_ONCE 0x00100000
#define FILE_SUPPORTS_TRANSACTIONS 0x00200000
#define FILE_SUPPORTS_HARD_LINKS 0x00400000
#define FILE_SUPPORTS_EXTENDED_ATTRIBUTES 0x00800000
#define FILE_SUPPORTS_OPEN_BY_FILE_ID 0x01000000
#define FILE_SUPPORTS_USN_JOURNAL 0x02000000

//
// Define the file notification information structure
//

typedef struct _FILE_NOTIFY_INFORMATION {
DWORD NextEntryOffset;
DWORD Action;
DWORD FileNameLength;
WCHAR FileName[1];
} FILE_NOTIFY_INFORMATION, *PFILE_NOTIFY_INFORMATION;


//
// Define segement buffer structure for scatter/gather read/write.
//

typedef union _FILE_SEGMENT_ELEMENT {
PVOID64 Buffer;
ULONGLONG Alignment;
}FILE_SEGMENT_ELEMENT, *PFILE_SEGMENT_ELEMENT;

//
// The reparse GUID structure is used by all 3rd party layered drivers to
// store data in a reparse point. For non-Microsoft tags, The GUID field
// cannot be GUID_NULL.
// The constraints on reparse tags are defined below.
// Microsoft tags can also be used with this format of the reparse point buffer.
//

typedef struct _REPARSE_GUID_DATA_BUFFER {
DWORD ReparseTag;
WORD ReparseDataLength;
WORD Reserved;
GUID ReparseGuid;
struct {
BYTE DataBuffer[1];
} GenericReparseBuffer;
} REPARSE_GUID_DATA_BUFFER, *PREPARSE_GUID_DATA_BUFFER;

#define REPARSE_GUID_DATA_BUFFER_HEADER_SIZE FIELD_OFFSET(REPARSE_GUID_DATA_BUFFER, GenericReparseBuffer)

 

//
// Maximum allowed size of the reparse data.
//

#define MAXIMUM_REPARSE_DATA_BUFFER_SIZE ( 16 * 1024 )

//
// Predefined reparse tags.
// These tags need to avoid conflicting with IO_REMOUNT defined in ntos\inc\io.h
//

#define IO_REPARSE_TAG_RESERVED_ZERO (0)
#define IO_REPARSE_TAG_RESERVED_ONE (1)

//
// The value of the following constant needs to satisfy the following conditions:
// (1) Be at least as large as the largest of the reserved tags.
// (2) Be strictly smaller than all the tags in use.
//

#define IO_REPARSE_TAG_RESERVED_RANGE IO_REPARSE_TAG_RESERVED_ONE

//
// The reparse tags are a DWORD. The 32 bits are laid out as follows:
//
// 3 3 2 2 2 2 2 2 2 2 2 2 1 1 1 1 1 1 1 1 1 1
// 1 0 9 8 7 6 5 4 3 2 1 0 9 8 7 6 5 4 3 2 1 0 9 8 7 6 5 4 3 2 1 0
// +-+-+-+-+-----------------------+-------------------------------+
// |M|R|N|R| Reserved bits | Reparse Tag Value |
// +-+-+-+-+-----------------------+-------------------------------+
//
// M is the Microsoft bit. When set to 1, it denotes a tag owned by Microsoft.
// All ISVs must use a tag with a 0 in this position.
// Note: If a Microsoft tag is used by non-Microsoft software, the
// behavior is not defined.
//
// R is reserved. Must be zero for non-Microsoft tags.
//
// N is name surrogate. When set to 1, the file represents another named
// entity in the system.
//
// The M and N bits are OR-able.
// The following macros check for the M and N bit values:
//

//
// Macro to determine whether a reparse point tag corresponds to a tag
// owned by Microsoft.
//

#define IsReparseTagMicrosoft(_tag) ( \
((_tag) & 0x80000000) \
)

//
// Macro to determine whether a reparse point tag is a name surrogate
//

#define IsReparseTagNameSurrogate(_tag) ( \
((_tag) & 0x20000000) \
)

#define IO_REPARSE_TAG_MOUNT_POINT (0xA0000003L)
#define IO_REPARSE_TAG_HSM (0xC0000004L)
#define IO_REPARSE_TAG_HSM2 (0x80000006L)
#define IO_REPARSE_TAG_SIS (0x80000007L)
#define IO_REPARSE_TAG_WIM (0x80000008L)
#define IO_REPARSE_TAG_CSV (0x80000009L)
#define IO_REPARSE_TAG_DFS (0x8000000AL)
#define IO_REPARSE_TAG_SYMLINK (0xA000000CL)
#define IO_REPARSE_TAG_DFSR (0x80000012L)

//
// I/O Completion Specific Access Rights.
//

#define IO_COMPLETION_MODIFY_STATE 0x0002
#define IO_COMPLETION_ALL_ACCESS (STANDARD_RIGHTS_REQUIRED|SYNCHRONIZE|0x3)

//
// Object Manager Symbolic Link Specific Access Rights.
//

#define DUPLICATE_CLOSE_SOURCE 0x00000001
#define DUPLICATE_SAME_ACCESS 0x00000002

//
// =========================================
// Define GUIDs which represent well-known power schemes
// =========================================
//

//
// Maximum Power Savings - indicates that very aggressive power savings measures will be used to help
// stretch battery life.
//
// {a1841308-3541-4fab-bc81-f71556f20b4a}
//
DEFINE_GUID( GUID_MAX_POWER_SAVINGS, 0xA1841308, 0x3541, 0x4FAB, 0xBC, 0x81, 0xF7, 0x15, 0x56, 0xF2, 0x0B, 0x4A );

//
// No Power Savings - indicates that almost no power savings measures will be used.
//
// {8c5e7fda-e8bf-4a96-9a85-a6e23a8c635c}
//
DEFINE_GUID( GUID_MIN_POWER_SAVINGS, 0x8C5E7FDA, 0xE8BF, 0x4A96, 0x9A, 0x85, 0xA6, 0xE2, 0x3A, 0x8C, 0x63, 0x5C );

//
// Typical Power Savings - indicates that fairly aggressive power savings measures will be used.
//
// {381b4222-f694-41f0-9685-ff5bb260df2e}
//
DEFINE_GUID( GUID_TYPICAL_POWER_SAVINGS, 0x381B4222, 0xF694, 0x41F0, 0x96, 0x85, 0xFF, 0x5B, 0xB2, 0x60, 0xDF, 0x2E );

//
// This is a special GUID that represents "no subgroup" of settings. That is, it indicates
// that settings that are in the root of the power policy hierarchy as opposed to settings
// that are buried under a subgroup of settings. This should be used when querying for
// power settings that may not fall into a subgroup.
//
DEFINE_GUID( NO_SUBGROUP_GUID, 0xFEA3413E, 0x7E05, 0x4911, 0x9A, 0x71, 0x70, 0x03, 0x31, 0xF1, 0xC2, 0x94 );

//
// This is a special GUID that represents "every power scheme". That is, it indicates
// that any write to this power scheme should be reflected to every scheme present.
// This allows users to write a single setting once and have it apply to all schemes. They
// can then apply custom settings to specific power schemes that they care about.
//
DEFINE_GUID( ALL_POWERSCHEMES_GUID, 0x68A1E95E, 0x13EA, 0x41E1, 0x80, 0x11, 0x0C, 0x49, 0x6C, 0xA4, 0x90, 0xB0 );

//
// This is a special GUID that represents a ‘personality‘ that each power scheme will have.
// In other words, each power scheme will have this key indicating "I‘m most like *this* base
// power scheme." This individual setting will have one of three settings:
// GUID_MAX_POWER_SAVINGS
// GUID_MIN_POWER_SAVINGS
// GUID_TYPICAL_POWER_SAVINGS
//
// This allows several features:
// 1. Drivers and applications can register for notification of this GUID. So when this power
// scheme is activiated, this GUID‘s setting will be sent across the system and drivers/applications
// can see "GUID_MAX_POWER_SAVINGS" which will tell them in a generic fashion "get real aggressive
// about conserving power".
// 2. UserB may install a driver or application which creates power settings, and UserB may modify
// those power settings. Now UserA logs in. How does he see those settings? They simply don‘t
// exist in his private power key. Well they do exist over in the system power key. When we
// enumerate all the power settings in this system power key and don‘t find a corresponding entry
// in the user‘s private power key, then we can go look at this "personality" key in the users
// power scheme. We can then go get a default value for the power setting, depending on which
// "personality" power scheme is being operated on. Here‘s an example:
// A. UserB installs an application that creates a power setting Seetting1
// B. UserB changes Setting1 to have a value of 50 because that‘s one of the possible settings
// available for setting1.
// C. UserB logs out
// D. UserA logs in and his active power scheme is some custom scheme that was derived from
// the GUID_TYPICAL_POWER_SAVINGS. But remember that UserA has no setting1 in his
// private power key.
// E. When activating UserA‘s selected power scheme, all power settings in the system power key will
// be enumerated (including Setting1).
// F. The power manager will see that UserA has no Setting1 power setting in his private power scheme.
// G. The power manager will query UserA‘s power scheme for its personality and retrieve
// GUID_TYPICAL_POWER_SAVINGS.
// H. The power manager then looks in Setting1 in the system power key and looks in its set of default
// values for the corresponding value for GUID_TYPICAL_POWER_SAVINGS power schemes.
// I. This derived power setting is applied.
DEFINE_GUID( GUID_POWERSCHEME_PERSONALITY, 0x245D8541, 0x3943, 0x4422, 0xB0, 0x25, 0x13, 0xA7, 0x84, 0xF6, 0x79, 0xB7 );

//
// Define a special GUID which will be used to define the active power scheme.
// User will register for this power setting GUID, and when the active power
// scheme changes, they‘ll get a callback where the payload is the GUID
// representing the active powerscheme.
// ( 31F9F286-5084-42FE-B720-2B0264993763 }
//
DEFINE_GUID( GUID_ACTIVE_POWERSCHEME, 0x31F9F286, 0x5084, 0x42FE, 0xB7, 0x20, 0x2B, 0x02, 0x64, 0x99, 0x37, 0x63 );

//
// =========================================
// Define GUIDs which represent well-known power settings
// =========================================
//

// Video settings
// --------------
//
// Specifies the subgroup which will contain all of the video
// settings for a single policy.
//
DEFINE_GUID( GUID_VIDEO_SUBGROUP, 0x7516B95F, 0xF776, 0x4464, 0x8C, 0x53, 0x06, 0x16, 0x7F, 0x40, 0xCC, 0x99 );

//
// Specifies (in seconds) how long we wait after the last user input has been
// recieved before we power off the video.
//
DEFINE_GUID( GUID_VIDEO_POWERDOWN_TIMEOUT, 0x3C0BC021, 0xC8A8, 0x4E07, 0xA9, 0x73, 0x6B, 0x14, 0xCB, 0xCB, 0x2B, 0x7E );

//
// Specifies whether adaptive display dimming is turned on or off.
// 82DBCF2D-CD67-40C5-BFDC-9F1A5CCD4663
//
DEFINE_GUID( GUID_VIDEO_ANNOYANCE_TIMEOUT, 0x82DBCF2D, 0xCD67, 0x40C5, 0xBF, 0xDC, 0x9F, 0x1A, 0x5C, 0xCD, 0x46, 0x63 );

//
// Specifies how much adaptive dim time out will be increased by.
// EED904DF-B142-4183-B10B-5A1197A37864
//
DEFINE_GUID( GUID_VIDEO_ADAPTIVE_PERCENT_INCREASE, 0xEED904DF, 0xB142, 0x4183, 0xB1, 0x0B, 0x5A, 0x11, 0x97, 0xA3, 0x78, 0x64 );

//
// Specifies (in seconds) how long we wait after the last user input has been
// recieved before we dim the video.
//
DEFINE_GUID( GUID_VIDEO_DIM_TIMEOUT, 0x17aaa29b, 0x8b43, 0x4b94, 0xaa, 0xfe, 0x35, 0xf6, 0x4d, 0xaa, 0xf1, 0xee);

//
// Specifies if the operating system should use adaptive timers (based on
// previous behavior) to power down the video,
//
DEFINE_GUID( GUID_VIDEO_ADAPTIVE_POWERDOWN, 0x90959D22, 0xD6A1, 0x49B9, 0xAF, 0x93, 0xBC, 0xE8, 0x85, 0xAD, 0x33, 0x5B );

//
// Specifies if the monitor is currently being powered or not.
// 02731015-4510-4526-99E6-E5A17EBD1AEA
//
DEFINE_GUID( GUID_MONITOR_POWER_ON, 0x02731015, 0x4510, 0x4526, 0x99, 0xE6, 0xE5, 0xA1, 0x7E, 0xBD, 0x1A, 0xEA );

//
// Monitor brightness policy when in normal state
// {aded5e82-b909-4619-9949-f5d71dac0bcb}
DEFINE_GUID(GUID_DEVICE_POWER_POLICY_VIDEO_BRIGHTNESS, 0xaded5e82L, 0xb909, 0x4619, 0x99, 0x49, 0xf5, 0xd7, 0x1d, 0xac, 0x0b, 0xcb);

//
//
// Monitor brightness policy when in dim state
// {f1fbfde2-a960-4165-9f88-50667911ce96}
DEFINE_GUID(GUID_DEVICE_POWER_POLICY_VIDEO_DIM_BRIGHTNESS, 0xf1fbfde2, 0xa960, 0x4165, 0x9f, 0x88, 0x50, 0x66, 0x79, 0x11, 0xce, 0x96);

//
// Current Monitor brightness
// {8ffee2c6-2d01-46be-adb9-398addc5b4ff}
DEFINE_GUID(GUID_VIDEO_CURRENT_MONITOR_BRIGHTNESS, 0x8ffee2c6, 0x2d01, 0x46be, 0xad, 0xb9, 0x39, 0x8a, 0xdd, 0xc5, 0xb4, 0xff);


//
// Specifies if the operating system should use ambient light sensor to change
// disply brightness adatively.
// {FBD9AA66-9553-4097-BA44-ED6E9D65EAB8}
DEFINE_GUID(GUID_VIDEO_ADAPTIVE_DISPLAY_BRIGHTNESS, 0xFBD9AA66, 0x9553, 0x4097, 0xBA, 0x44, 0xED, 0x6E, 0x9D, 0x65, 0xEA, 0xB8);

//
// Specifies a change in the session‘s display state.
// 73A5E93A-5BB1-4F93-895B-DBD0DA855967
//
// N.B. This is a session-specific notification, sent only to interactive
// session registrants. Session 0 and kernel mode consumers do not receive
// this notification.
DEFINE_GUID( GUID_SESSION_DISPLAY_STATE, 0x73A5E93A, 0x5BB1, 0x4F93, 0x89, 0x5B, 0xDB, 0xD0, 0xDA, 0x85, 0x59, 0x67 );

//
// Specifies a change in the current monitor‘s display state.
// 6fe69556-704a-47a0-8f24-c28d936fda47
//
DEFINE_GUID(GUID_CONSOLE_DISPLAY_STATE, 0x6fe69556, 0x704a, 0x47a0, 0x8f, 0x24, 0xc2, 0x8d, 0x93, 0x6f, 0xda, 0x47);

//
// Defines a guid for enabling/disabling the ability to create display required
// power requests.
//
// {A9CEB8DA-CD46-44FB-A98B-02AF69DE4623}
//
DEFINE_GUID( GUID_ALLOW_DISPLAY_REQUIRED, 0xA9CEB8DA, 0xCD46, 0x44FB, 0xA9, 0x8B, 0x02, 0xAF, 0x69, 0xDE, 0x46, 0x23 );

// Harddisk settings
// -----------------
//
// Specifies the subgroup which will contain all of the harddisk
// settings for a single policy.
//
DEFINE_GUID( GUID_DISK_SUBGROUP, 0x0012EE47, 0x9041, 0x4B5D, 0x9B, 0x77, 0x53, 0x5F, 0xBA, 0x8B, 0x14, 0x42 );

//
// Specifies (in seconds) how long we wait after the last disk access
// before we power off the disk.
//
DEFINE_GUID( GUID_DISK_POWERDOWN_TIMEOUT, 0x6738E2C4, 0xE8A5, 0x4A42, 0xB1, 0x6A, 0xE0, 0x40, 0xE7, 0x69, 0x75, 0x6E );

//
// Specifies the amount of contiguous disk activity time to ignore when
// calculating disk idleness.
//
// 80e3c60e-bb94-4ad8-bbe0-0d3195efc663
//

DEFINE_GUID( GUID_DISK_BURST_IGNORE_THRESHOLD, 0x80e3c60e, 0xbb94, 0x4ad8, 0xbb, 0xe0, 0x0d, 0x31, 0x95, 0xef, 0xc6, 0x63 );

//
// Specifies if the operating system should use adaptive timers (based on
// previous behavior) to power down the disk,
//
DEFINE_GUID( GUID_DISK_ADAPTIVE_POWERDOWN, 0x396A32E1, 0x499A, 0x40B2, 0x91, 0x24, 0xA9, 0x6A, 0xFE, 0x70, 0x76, 0x67 );

// System sleep settings
// ---------------------
//
// Specifies the subgroup which will contain all of the sleep
// settings for a single policy.
// { 238C9FA8-0AAD-41ED-83F4-97BE242C8F20 }
//
DEFINE_GUID( GUID_SLEEP_SUBGROUP, 0x238C9FA8, 0x0AAD, 0x41ED, 0x83, 0xF4, 0x97, 0xBE, 0x24, 0x2C, 0x8F, 0x20 );

//
// Specifies an idle treshold percentage (0-100). The system must be this idle
// over a period of time in order to idle to sleep.
//
// N.B. DEPRECATED IN WINDOWS 6.1
//
DEFINE_GUID( GUID_SLEEP_IDLE_THRESHOLD, 0x81cd32e0, 0x7833, 0x44f3, 0x87, 0x37, 0x70, 0x81, 0xf3, 0x8d, 0x1f, 0x70 );

//
// Specifies (in seconds) how long we wait after the system is deemed
// "idle" before moving to standby (S1, S2 or S3).
//
DEFINE_GUID( GUID_STANDBY_TIMEOUT, 0x29F6C1DB, 0x86DA, 0x48C5, 0x9F, 0xDB, 0xF2, 0xB6, 0x7B, 0x1F, 0x44, 0xDA );

//
// Specifies (in seconds) how long the system should go back to sleep after
// waking unattended. 0 indicates that the standard standby/hibernate idle
// policy should be used instead.
//
// {7bc4a2f9-d8fc-4469-b07b-33eb785aaca0}
//
DEFINE_GUID( GUID_UNATTEND_SLEEP_TIMEOUT, 0x7bc4a2f9, 0xd8fc, 0x4469, 0xb0, 0x7b, 0x33, 0xeb, 0x78, 0x5a, 0xac, 0xa0 );

//
// Specifies (in seconds) how long we wait after the system is deemed
// "idle" before moving to hibernate (S4).
//
DEFINE_GUID( GUID_HIBERNATE_TIMEOUT, 0x9D7815A6, 0x7EE4, 0x497E, 0x88, 0x88, 0x51, 0x5A, 0x05, 0xF0, 0x23, 0x64 );

//
// Specifies whether or not Fast S4 should be enabled if the system supports it
// 94AC6D29-73CE-41A6-809F-6363BA21B47E
//
DEFINE_GUID( GUID_HIBERNATE_FASTS4_POLICY, 0x94AC6D29, 0x73CE, 0x41A6, 0x80, 0x9F, 0x63, 0x63, 0xBA, 0x21, 0xB4, 0x7E );

//
// Define a GUID for controlling the criticality of sleep state transitions.
// Critical sleep transitions do not query applications, services or drivers
// before transitioning the platform to a sleep state.
//
// {B7A27025-E569-46c2-A504-2B96CAD225A1}
//
DEFINE_GUID( GUID_CRITICAL_POWER_TRANSITION, 0xB7A27025, 0xE569, 0x46c2, 0xA5, 0x04, 0x2B, 0x96, 0xCA, 0xD2, 0x25, 0xA1);

//
// Specifies if the system is entering or exiting ‘away mode‘.
// 98A7F580-01F7-48AA-9C0F-44352C29E5C0
//
DEFINE_GUID( GUID_SYSTEM_AWAYMODE, 0x98A7F580, 0x01F7, 0x48AA, 0x9C, 0x0F, 0x44, 0x35, 0x2C, 0x29, 0xE5, 0xC0 );

// Specify whether away mode is allowed
//
// {25DFA149-5DD1-4736-B5AB-E8A37B5B8187}
//
DEFINE_GUID( GUID_ALLOW_AWAYMODE, 0x25dfa149, 0x5dd1, 0x4736, 0xb5, 0xab, 0xe8, 0xa3, 0x7b, 0x5b, 0x81, 0x87 );

//
// Defines a guid for enabling/disabling standby (S1-S3) states. This does not
// affect hibernation (S4).
//
// {abfc2519-3608-4c2a-94ea-171b0ed546ab}
//
DEFINE_GUID( GUID_ALLOW_STANDBY_STATES, 0xabfc2519, 0x3608, 0x4c2a, 0x94, 0xea, 0x17, 0x1b, 0x0e, 0xd5, 0x46, 0xab );

//
// Defines a guid for enabling/disabling the ability to wake via RTC.
//
// {BD3B718A-0680-4D9D-8AB2-E1D2B4AC806D}
//
DEFINE_GUID( GUID_ALLOW_RTC_WAKE, 0xBD3B718A, 0x0680, 0x4D9D, 0x8A, 0xB2, 0xE1, 0xD2, 0xB4, 0xAC, 0x80, 0x6D );

//
// Defines a guid for enabling/disabling the ability to create system required
// power requests.
//
// {A4B195F5-8225-47D8-8012-9D41369786E2}
//
DEFINE_GUID( GUID_ALLOW_SYSTEM_REQUIRED, 0xA4B195F5, 0x8225, 0x47D8, 0x80, 0x12, 0x9D, 0x41, 0x36, 0x97, 0x86, 0xE2 );

// System button actions
// ---------------------
//
//
// Specifies the subgroup which will contain all of the system button
// settings for a single policy.
//
DEFINE_GUID( GUID_SYSTEM_BUTTON_SUBGROUP, 0x4F971E89, 0xEEBD, 0x4455, 0xA8, 0xDE, 0x9E, 0x59, 0x04, 0x0E, 0x73, 0x47 );

// Specifies (in a POWER_ACTION_POLICY structure) the appropriate action to
// take when the system power button is pressed.
//
DEFINE_GUID( GUID_POWERBUTTON_ACTION, 0x7648EFA3, 0xDD9C, 0x4E3E, 0xB5, 0x66, 0x50, 0xF9, 0x29, 0x38, 0x62, 0x80 );
DEFINE_GUID( GUID_POWERBUTTON_ACTION_FLAGS, 0x857E7FAC, 0x034B, 0x4704, 0xAB, 0xB1, 0xBC, 0xA5, 0x4A, 0xA3, 0x14, 0x78 );

//
// Specifies (in a POWER_ACTION_POLICY structure) the appropriate action to
// take when the system sleep button is pressed.
//
DEFINE_GUID( GUID_SLEEPBUTTON_ACTION, 0x96996BC0, 0xAD50, 0x47EC, 0x92, 0x3B, 0x6F, 0x41, 0x87, 0x4D, 0xD9, 0xEB );
DEFINE_GUID( GUID_SLEEPBUTTON_ACTION_FLAGS, 0x2A160AB1, 0xB69D, 0x4743, 0xB7, 0x18, 0xBF, 0x14, 0x41, 0xD5, 0xE4, 0x93 );

//
// Specifies (in a POWER_ACTION_POLICY structure) the appropriate action to
// take when the system sleep button is pressed.
// { A7066653-8D6C-40A8-910E-A1F54B84C7E5 }
//
DEFINE_GUID( GUID_USERINTERFACEBUTTON_ACTION, 0xA7066653, 0x8D6C, 0x40A8, 0x91, 0x0E, 0xA1, 0xF5, 0x4B, 0x84, 0xC7, 0xE5 );

//
// Specifies (in a POWER_ACTION_POLICY structure) the appropriate action to
// take when the system lid is closed.
//
DEFINE_GUID( GUID_LIDCLOSE_ACTION, 0x5CA83367, 0x6E45, 0x459F, 0xA2, 0x7B, 0x47, 0x6B, 0x1D, 0x01, 0xC9, 0x36 );
DEFINE_GUID( GUID_LIDCLOSE_ACTION_FLAGS, 0x97E969AC, 0x0D6C, 0x4D08, 0x92, 0x7C, 0xD7, 0xBD, 0x7A, 0xD7, 0x85, 0x7B );
DEFINE_GUID( GUID_LIDOPEN_POWERSTATE, 0x99FF10E7, 0x23B1, 0x4C07, 0xA9, 0xD1, 0x5C, 0x32, 0x06, 0xD7, 0x41, 0xB4 );


// Battery Discharge Settings
// --------------------------
//
// Specifies the subgroup which will contain all of the battery discharge
// settings for a single policy.
//
DEFINE_GUID( GUID_BATTERY_SUBGROUP, 0xE73A048D, 0xBF27, 0x4F12, 0x97, 0x31, 0x8B, 0x20, 0x76, 0xE8, 0x89, 0x1F );

//
// 4 battery discharge alarm settings.
//
// GUID_BATTERY_DISCHARGE_ACTION_x - This is the action to take. It is a value
// of type POWER_ACTION
// GUID_BATTERY_DISCHARGE_LEVEL_x - This is the battery level (%)
// GUID_BATTERY_DISCHARGE_FLAGS_x - Flags defined below:
// POWER_ACTION_POLICY->EventCode flags
// BATTERY_DISCHARGE_FLAGS_EVENTCODE_MASK
// BATTERY_DISCHARGE_FLAGS_ENABLE
DEFINE_GUID( GUID_BATTERY_DISCHARGE_ACTION_0, 0x637EA02F, 0xBBCB, 0x4015, 0x8E, 0x2C, 0xA1, 0xC7, 0xB9, 0xC0, 0xB5, 0x46 );
DEFINE_GUID( GUID_BATTERY_DISCHARGE_LEVEL_0, 0x9A66D8D7, 0x4FF7, 0x4EF9, 0xB5, 0xA2, 0x5A, 0x32, 0x6C, 0xA2, 0xA4, 0x69 );
DEFINE_GUID( GUID_BATTERY_DISCHARGE_FLAGS_0, 0x5dbb7c9f, 0x38e9, 0x40d2, 0x97, 0x49, 0x4f, 0x8a, 0x0e, 0x9f, 0x64, 0x0f );

DEFINE_GUID( GUID_BATTERY_DISCHARGE_ACTION_1, 0xD8742DCB, 0x3E6A, 0x4B3C, 0xB3, 0xFE, 0x37, 0x46, 0x23, 0xCD, 0xCF, 0x06 );
DEFINE_GUID( GUID_BATTERY_DISCHARGE_LEVEL_1, 0x8183BA9A, 0xE910, 0x48DA, 0x87, 0x69, 0x14, 0xAE, 0x6D, 0xC1, 0x17, 0x0A );
DEFINE_GUID( GUID_BATTERY_DISCHARGE_FLAGS_1, 0xbcded951, 0x187b, 0x4d05, 0xbc, 0xcc, 0xf7, 0xe5, 0x19, 0x60, 0xc2, 0x58 );

DEFINE_GUID( GUID_BATTERY_DISCHARGE_ACTION_2, 0x421CBA38, 0x1A8E, 0x4881, 0xAC, 0x89, 0xE3, 0x3A, 0x8B, 0x04, 0xEC, 0xE4 );
DEFINE_GUID( GUID_BATTERY_DISCHARGE_LEVEL_2, 0x07A07CA2, 0xADAF, 0x40D7, 0xB0, 0x77, 0x53, 0x3A, 0xAD, 0xED, 0x1B, 0xFA );
DEFINE_GUID( GUID_BATTERY_DISCHARGE_FLAGS_2, 0x7fd2f0c4, 0xfeb7, 0x4da3, 0x81, 0x17, 0xe3, 0xfb, 0xed, 0xc4, 0x65, 0x82 );

DEFINE_GUID( GUID_BATTERY_DISCHARGE_ACTION_3, 0x80472613, 0x9780, 0x455E, 0xB3, 0x08, 0x72, 0xD3, 0x00, 0x3C, 0xF2, 0xF8 );
DEFINE_GUID( GUID_BATTERY_DISCHARGE_LEVEL_3, 0x58AFD5A6, 0xC2DD, 0x47D2, 0x9F, 0xBF, 0xEF, 0x70, 0xCC, 0x5C, 0x59, 0x65 );
DEFINE_GUID( GUID_BATTERY_DISCHARGE_FLAGS_3, 0x73613ccf, 0xdbfa, 0x4279, 0x83, 0x56, 0x49, 0x35, 0xf6, 0xbf, 0x62, 0xf3 );

// Processor power settings
// ------------------------
//

// Specifies the subgroup which will contain all of the processor
// settings for a single policy.
//
DEFINE_GUID( GUID_PROCESSOR_SETTINGS_SUBGROUP, 0x54533251, 0x82BE, 0x4824, 0x96, 0xC1, 0x47, 0xB6, 0x0B, 0x74, 0x0D, 0x00 );

//
// Specifies various attributes that control processor performance/throttle
// states.
//
DEFINE_GUID( GUID_PROCESSOR_THROTTLE_POLICY, 0x57027304, 0x4AF6, 0x4104, 0x92, 0x60, 0xE3, 0xD9, 0x52, 0x48, 0xFC, 0x36 );

#define PERFSTATE_POLICY_CHANGE_IDEAL 0
#define PERFSTATE_POLICY_CHANGE_SINGLE 1
#define PERFSTATE_POLICY_CHANGE_ROCKET 2
#define PERFSTATE_POLICY_CHANGE_MAX PERFSTATE_POLICY_CHANGE_ROCKET

//
// Specifies a percentage (between 0 and 100) that the processor frequency
// should never go above. For example, if this value is set to 80, then
// the processor frequency will never be throttled above 80 percent of its
// maximum frequency by the system.
//
DEFINE_GUID( GUID_PROCESSOR_THROTTLE_MAXIMUM, 0xBC5038F7, 0x23E0, 0x4960, 0x96, 0xDA, 0x33, 0xAB, 0xAF, 0x59, 0x35, 0xEC );

//
// Specifies a percentage (between 0 and 100) that the processor frequency
// should not drop below. For example, if this value is set to 50, then the
// processor frequency will never be throttled below 50 percent of its
// maximum frequency by the system.
//
DEFINE_GUID( GUID_PROCESSOR_THROTTLE_MINIMUM, 0x893DEE8E, 0x2BEF, 0x41E0, 0x89, 0xC6, 0xB5, 0x5D, 0x09, 0x29, 0x96, 0x4C );

//
// Specifies whether throttle states are allowed to be used even when
// performance states are available.
//
// {3b04d4fd-1cc7-4f23-ab1c-d1337819c4bb}
//
DEFINE_GUID( GUID_PROCESSOR_ALLOW_THROTTLING, 0x3b04d4fd, 0x1cc7, 0x4f23, 0xab, 0x1c, 0xd1, 0x33, 0x78, 0x19, 0xc4, 0xbb );

//
// Specifies processor power settings for CState policy data
// {68F262A7-F621-4069-B9A5-4874169BE23C}
//
DEFINE_GUID( GUID_PROCESSOR_IDLESTATE_POLICY, 0x68f262a7, 0xf621, 0x4069, 0xb9, 0xa5, 0x48, 0x74, 0x16, 0x9b, 0xe2, 0x3c);

//
// Specifies processor power settings for PerfState policy data
// {BBDC3814-18E9-4463-8A55-D197327C45C0}
//
DEFINE_GUID( GUID_PROCESSOR_PERFSTATE_POLICY, 0xBBDC3814, 0x18E9, 0x4463, 0x8A, 0x55, 0xD1, 0x97, 0x32, 0x7C, 0x45, 0xC0);

//
// Specifies the increase busy percentage threshold that must be met before
// increasing the processor performance state.
//
// {06cadf0e-64ed-448a-8927-ce7bf90eb35d}
//
DEFINE_GUID( GUID_PROCESSOR_PERF_INCREASE_THRESHOLD, 0x06cadf0e, 0x64ed, 0x448a, 0x89, 0x27, 0xce, 0x7b, 0xf9, 0x0e, 0xb3, 0x5d );

//
// Specifies the decrease busy percentage threshold that must be met before
// decreasing the processor performance state.
//
// {12a0ab44-fe28-4fa9-b3bd-4b64f44960a6}
//
DEFINE_GUID( GUID_PROCESSOR_PERF_DECREASE_THRESHOLD, 0x12a0ab44, 0xfe28, 0x4fa9, 0xb3, 0xbd, 0x4b, 0x64, 0xf4, 0x49, 0x60, 0xa6 );

//
// Specifies, either as ideal, single or rocket, how aggressive performance
// states should be selected when increasing the processor performance state.
//
// {465E1F50-B610-473a-AB58-00D1077DC418}
//
DEFINE_GUID( GUID_PROCESSOR_PERF_INCREASE_POLICY, 0x465e1f50, 0xb610, 0x473a, 0xab, 0x58, 0x0, 0xd1, 0x7, 0x7d, 0xc4, 0x18);

//
// Specifies, either as ideal, single or rocket, how aggressive performance
// states should be selected when decreasing the processor performance state.
//
// {40FBEFC7-2E9D-4d25-A185-0CFD8574BAC6}
//
DEFINE_GUID( GUID_PROCESSOR_PERF_DECREASE_POLICY, 0x40fbefc7, 0x2e9d, 0x4d25, 0xa1, 0x85, 0xc, 0xfd, 0x85, 0x74, 0xba, 0xc6);

//
// Specifies, in milliseconds, the minimum amount of time that must elapse after
// the last processor performance state change before increasing the processor
// performance state.
//
// {984CF492-3BED-4488-A8F9-4286C97BF5AA}
//
DEFINE_GUID( GUID_PROCESSOR_PERF_INCREASE_TIME, 0x984cf492, 0x3bed, 0x4488, 0xa8, 0xf9, 0x42, 0x86, 0xc9, 0x7b, 0xf5, 0xaa);

//
// Specifies, in milliseconds, the minimum amount of time that must elapse after
// the last processor performance state change before increasing the processor
// performance state.
//
// {D8EDEB9B-95CF-4f95-A73C-B061973693C8}
//
DEFINE_GUID( GUID_PROCESSOR_PERF_DECREASE_TIME, 0xd8edeb9b, 0x95cf, 0x4f95, 0xa7, 0x3c, 0xb0, 0x61, 0x97, 0x36, 0x93, 0xc8);

//
// Specifies the time, in milliseconds, that must expire before considering
// a change in the processor performance states or parked core set.
//
// {4D2B0152-7D5C-498b-88E2-34345392A2C5}
//
DEFINE_GUID( GUID_PROCESSOR_PERF_TIME_CHECK, 0x4d2b0152, 0x7d5c, 0x498b, 0x88, 0xe2, 0x34, 0x34, 0x53, 0x92, 0xa2, 0xc5);

//
// Specifies whether a processor may opportunistically increase frequency above
// the maximum when operating contitions allow it to do so safely.
//
// {45BCC044-D885-43e2-8605-EE0EC6E96B59}
//
DEFINE_GUID(GUID_PROCESSOR_PERF_BOOST_POLICY,
0x45bcc044, 0xd885, 0x43e2, 0x86, 0x5, 0xee, 0xe, 0xc6, 0xe9, 0x6b, 0x59);

#define PROCESSOR_PERF_BOOST_POLICY_DISABLED 0
#define PROCESSOR_PERF_BOOST_POLICY_MAX 100

//
// Specifies if idle state promotion and demotion values should be scaled based
// on the current peformance state.
//
// {6C2993B0-8F48-481f-BCC6-00DD2742AA06}
//
DEFINE_GUID( GUID_PROCESSOR_IDLE_ALLOW_SCALING, 0x6c2993b0, 0x8f48, 0x481f, 0xbc, 0xc6, 0x0, 0xdd, 0x27, 0x42, 0xaa, 0x6);

//
// Specifies if idle states should be disabled.
//
// {5D76A2CA-E8C0-402f-A133-2158492D58AD}
//
DEFINE_GUID( GUID_PROCESSOR_IDLE_DISABLE, 0x5d76a2ca, 0xe8c0, 0x402f, 0xa1, 0x33, 0x21, 0x58, 0x49, 0x2d, 0x58, 0xad);

//
// Specifies the time that elapsed since the last idle state promotion or
// demotion before idle states may be promoted or demoted again (in
// microseconds).
//
// {C4581C31-89AB-4597-8E2B-9C9CAB440E6B}
//
DEFINE_GUID( GUID_PROCESSOR_IDLE_TIME_CHECK, 0xc4581c31, 0x89ab, 0x4597, 0x8e, 0x2b, 0x9c, 0x9c, 0xab, 0x44, 0xe, 0x6b);


//
// Specifies the upper busy threshold that must be met before demoting the
// processor to a lighter idle state (in percentage).
//
// {4B92D758-5A24-4851-A470-815D78AEE119}
//
DEFINE_GUID( GUID_PROCESSOR_IDLE_DEMOTE_THRESHOLD, 0x4b92d758, 0x5a24, 0x4851, 0xa4, 0x70, 0x81, 0x5d, 0x78, 0xae, 0xe1, 0x19);

//
// Specifies the lower busy threshold that must be met before promoting the
// processor to a deeper idle state (in percentage).
//
// {7B224883-B3CC-4d79-819F-8374152CBE7C}
//
DEFINE_GUID( GUID_PROCESSOR_IDLE_PROMOTE_THRESHOLD, 0x7b224883, 0xb3cc, 0x4d79, 0x81, 0x9f, 0x83, 0x74, 0x15, 0x2c, 0xbe, 0x7c);

//
// Specifies the utilization threshold in percent that must be crossed in order to un-park cores.
//
// {df142941-20f3-4edf-9a4a-9c83d3d717d1}
//
DEFINE_GUID( GUID_PROCESSOR_CORE_PARKING_INCREASE_THRESHOLD, 0xdf142941, 0x20f3, 0x4edf, 0x9a, 0x4a, 0x9c, 0x83, 0xd3, 0xd7, 0x17, 0xd1 );

//
// Specifies the utilization threshold in percent that must be crossed in order to park cores.
//
// {68dd2f27-a4ce-4e11-8487-3794e4135dfa}
//
DEFINE_GUID( GUID_PROCESSOR_CORE_PARKING_DECREASE_THRESHOLD, 0x68dd2f27, 0xa4ce, 0x4e11, 0x84, 0x87, 0x37, 0x94, 0xe4, 0x13, 0x5d, 0xfa);

//
// Specifies, either as ideal, single or rocket, how aggressive core parking is when cores must be unparked.
//
// {c7be0679-2817-4d69-9d02-519a537ed0c6}
//
DEFINE_GUID( GUID_PROCESSOR_CORE_PARKING_INCREASE_POLICY, 0xc7be0679, 0x2817, 0x4d69, 0x9d, 0x02, 0x51, 0x9a, 0x53, 0x7e, 0xd0, 0xc6);

#define CORE_PARKING_POLICY_CHANGE_IDEAL 0
#define CORE_PARKING_POLICY_CHANGE_SINGLE 1
#define CORE_PARKING_POLICY_CHANGE_ROCKET 2
#define CORE_PARKING_POLICY_CHANGE_MAX CORE_PARKING_POLICY_CHANGE_ROCKET

//
// Specifies, either as ideal, single or rocket, how aggressive core parking is when cores must be parked.
//
// {71021b41-c749-4d21-be74-a00f335d582b}
//
DEFINE_GUID( GUID_PROCESSOR_CORE_PARKING_DECREASE_POLICY, 0x71021b41, 0xc749, 0x4d21, 0xbe, 0x74, 0xa0, 0x0f, 0x33, 0x5d, 0x58, 0x2b);

//
// Specifies, on a per processor group basis, the maximum number of cores that can be kept unparked.
//
// {ea062031-0e34-4ff1-9b6d-eb1059334028}
//
DEFINE_GUID( GUID_PROCESSOR_CORE_PARKING_MAX_CORES, 0xea062031, 0x0e34, 0x4ff1, 0x9b, 0x6d, 0xeb, 0x10, 0x59, 0x33, 0x40, 0x28);

//
// Specifies, on a per processor group basis, the minimum number of cores that must be kept unparked.
//
// {0cc5b647-c1df-4637-891a-dec35c318583}
//
DEFINE_GUID( GUID_PROCESSOR_CORE_PARKING_MIN_CORES, 0x0cc5b647, 0xc1df, 0x4637, 0x89, 0x1a, 0xde, 0xc3, 0x5c, 0x31, 0x85, 0x83);

//
// Specifies, in milliseconds, the minimum amount of time a core must be parked before it can be unparked.
//
// {2ddd5a84-5a71-437e-912a-db0b8c788732}
//
DEFINE_GUID( GUID_PROCESSOR_CORE_PARKING_INCREASE_TIME, 0x2ddd5a84, 0x5a71, 0x437e, 0x91, 0x2a, 0xdb, 0x0b, 0x8c, 0x78, 0x87, 0x32);

//
// Specifies, in milliseconds, the minimum amount of time a core must be unparked before it can be parked.
//
// {dfd10d17-d5eb-45dd-877a-9a34ddd15c82}
//
DEFINE_GUID( GUID_PROCESSOR_CORE_PARKING_DECREASE_TIME, 0xdfd10d17, 0xd5eb, 0x45dd, 0x87, 0x7a, 0x9a, 0x34, 0xdd, 0xd1, 0x5c, 0x82);

//
// Specifies the factor by which to decrease affinity history on each core after each check.
//
// {8f7b45e3-c393-480a-878c-f67ac3d07082}
//
DEFINE_GUID( GUID_PROCESSOR_CORE_PARKING_AFFINITY_HISTORY_DECREASE_FACTOR, 0x8f7b45e3, 0xc393, 0x480a, 0x87, 0x8c, 0xf6, 0x7a, 0xc3, 0xd0, 0x70, 0x82);

//
// Specifies the threshold above which a core is considered to have had significant affinitized work scheduled to it while parked.
//
// {5b33697b-e89d-4d38-aa46-9e7dfb7cd2f9}
//
DEFINE_GUID( GUID_PROCESSOR_CORE_PARKING_AFFINITY_HISTORY_THRESHOLD, 0x5b33697b, 0xe89d, 0x4d38, 0xaa, 0x46, 0x9e, 0x7d, 0xfb, 0x7c, 0xd2, 0xf9);

//
// Specifies the weighting given to each occurence where affinitized work was scheduled to a parked core.
//
// {e70867f1-fa2f-4f4e-aea1-4d8a0ba23b20}
//
DEFINE_GUID( GUID_PROCESSOR_CORE_PARKING_AFFINITY_WEIGHTING, 0xe70867f1, 0xfa2f, 0x4f4e, 0xae, 0xa1, 0x4d, 0x8a, 0x0b, 0xa2, 0x3b, 0x20);

//
// Specifies the factor by which to decrease the over utilization history on each core after the current performance check.
//
// {1299023c-bc28-4f0a-81ec-d3295a8d815d}
//
DEFINE_GUID( GUID_PROCESSOR_CORE_PARKING_OVER_UTILIZATION_HISTORY_DECREASE_FACTOR, 0x1299023c, 0xbc28, 0x4f0a, 0x81, 0xec, 0xd3, 0x29, 0x5a, 0x8d, 0x81, 0x5d);

//
// Specifies the threshold above which a core is considered to have been recently over utilized while parked.
//
// {9ac18e92-aa3c-4e27-b307-01ae37307129}
//
DEFINE_GUID( GUID_PROCESSOR_CORE_PARKING_OVER_UTILIZATION_HISTORY_THRESHOLD, 0x9ac18e92, 0xaa3c, 0x4e27, 0xb3, 0x07, 0x01, 0xae, 0x37, 0x30, 0x71, 0x29);

//
// Specifies the weighting given to each occurence where a parked core is found to be over utilized.
//
// {8809c2d8-b155-42d4-bcda-0d345651b1db}
//
DEFINE_GUID( GUID_PROCESSOR_CORE_PARKING_OVER_UTILIZATION_WEIGHTING, 0x8809c2d8, 0xb155, 0x42d4, 0xbc, 0xda, 0x0d, 0x34, 0x56, 0x51, 0xb1, 0xdb);

//
// Specifies, in percentage, the busy threshold that must be met before a parked core is considered over utilized.
//
// {943c8cb6-6f93-4227-ad87-e9a3feec08d1}
//
DEFINE_GUID( GUID_PROCESSOR_CORE_PARKING_OVER_UTILIZATION_THRESHOLD, 0x943c8cb6, 0x6f93, 0x4227, 0xad, 0x87, 0xe9, 0xa3, 0xfe, 0xec, 0x08, 0xd1);

//
// Specifies if at least one processor per core should always remain unparked.
//
// {a55612aa-f624-42c6-a443-7397d064c04f}
//

DEFINE_GUID( GUID_PROCESSOR_PARKING_CORE_OVERRIDE, 0xa55612aa, 0xf624, 0x42c6, 0xa4, 0x43, 0x73, 0x97, 0xd0, 0x64, 0xc0, 0x4f);

//
// Specifies what performance state a processor should enter when first parked.
//
// {447235c7-6a8d-4cc0-8e24-9eaf70b96e2b}
//

DEFINE_GUID( GUID_PROCESSOR_PARKING_PERF_STATE, 0x447235c7, 0x6a8d, 0x4cc0, 0x8e, 0x24, 0x9e, 0xaf, 0x70, 0xb9, 0x6e, 0x2b);

//
// Specifies the number of perf time check intervals to average utility over.
//
// {7d24baa7-0b84-480f-840c-1b0743c00f5f}
//
DEFINE_GUID( GUID_PROCESSOR_PERF_HISTORY, 0x7d24baa7, 0x0b84, 0x480f, 0x84, 0x0c, 0x1b, 0x07, 0x43, 0xc0, 0x0f, 0x5f);

//
// Specifies active vs passive cooling. Although not directly related to
// processor settings, it is the processor that gets throttled if we‘re doing
// passive cooling, so it is fairly strongly related.
// {94D3A615-A899-4AC5-AE2B-E4D8F634367F}
//
DEFINE_GUID( GUID_SYSTEM_COOLING_POLICY, 0x94D3A615, 0xA899, 0x4AC5, 0xAE, 0x2B, 0xE4, 0xD8, 0xF6, 0x34, 0x36, 0x7F);

// Lock Console on Wake
// --------------------
//

// Specifies the behavior of the system when we wake from standby or
// hibernate. If this is set, then we will cause the console to lock
// after we resume.
//
DEFINE_GUID( GUID_LOCK_CONSOLE_ON_WAKE, 0x0E796BDB, 0x100D, 0x47D6, 0xA2, 0xD5, 0xF7, 0xD2, 0xDA, 0xA5, 0x1F, 0x51 );

// Device idle characteristics
// ---------------------------
//
// Specifies whether to use the "performance" or "conservative" timeouts for
// device idle management.
//
// 4faab71a-92e5-4726-b531-224559672d19
//
DEFINE_GUID( GUID_DEVICE_IDLE_POLICY, 0x4faab71a, 0x92e5, 0x4726, 0xb5, 0x31, 0x22, 0x45, 0x59, 0x67, 0x2d, 0x19 );

#define POWER_DEVICE_IDLE_POLICY_PERFORMANCE 0
#define POWER_DEVICE_IDLE_POLICY_CONSERVATIVE 1

// AC/DC power source
// ------------------
//

// Specifies the power source for the system. consumers may register for
// notification when the power source changes and will be notified with
// one of 3 values:
// 0 - Indicates the system is being powered by an AC power source.
// 1 - Indicates the system is being powered by a DC power source.
// 2 - Indicates the system is being powered by a short-term DC power
// source. For example, this would be the case if the system is
// being powed by a short-term battery supply in a backing UPS
// system. When this value is recieved, the consumer should make
// preparations for either a system hibernate or system shutdown.
//
// { 5D3E9A59-E9D5-4B00-A6BD-FF34FF516548 }
DEFINE_GUID( GUID_ACDC_POWER_SOURCE, 0x5D3E9A59, 0xE9D5, 0x4B00, 0xA6, 0xBD, 0xFF, 0x34, 0xFF, 0x51, 0x65, 0x48 );

// Lid state changes
// -----------------
//
// Specifies the current state of the lid (open or closed). The callback won‘t
// be called at all until a lid device is found and its current state is known.
//
// Values:
//
// 0 - closed
// 1 - opened
//
// { BA3E0F4D-B817-4094-A2D1-D56379E6A0F3 }
//

DEFINE_GUID( GUID_LIDSWITCH_STATE_CHANGE, 0xBA3E0F4D, 0xB817, 0x4094, 0xA2, 0xD1, 0xD5, 0x63, 0x79, 0xE6, 0xA0, 0xF3 );

// Battery life remaining
// ----------------------
//

// Specifies the percentage of battery life remaining. The consumer
// may register for notification in order to track battery life in
// a fine-grained manner.
//
// Once registered, the consumer can expect to be notified as the battery
// life percentage changes.
//
// The consumer will recieve a value between 0 and 100 (inclusive) which
// indicates percent battery life remaining.
//
// { A7AD8041-B45A-4CAE-87A3-EECBB468A9E1 }
DEFINE_GUID( GUID_BATTERY_PERCENTAGE_REMAINING, 0xA7AD8041, 0xB45A, 0x4CAE, 0x87, 0xA3, 0xEE, 0xCB, 0xB4, 0x68, 0xA9, 0xE1 );


// Notification to listeners that the system is fairly busy and won‘t be moving
// into an idle state any time soon. This can be used as a hint to listeners
// that now might be a good time to do background tasks.
//
DEFINE_GUID( GUID_IDLE_BACKGROUND_TASK, 0x515C31D8, 0xF734, 0x163D, 0xA0, 0xFD, 0x11, 0xA0, 0x8C, 0x91, 0xE8, 0xF1 );

// Notification to listeners that the system is fairly busy and won‘t be moving
// into an idle state any time soon. This can be used as a hint to listeners
// that now might be a good time to do background tasks.
//
// { CF23F240-2A54-48D8-B114-DE1518FF052E }
DEFINE_GUID( GUID_BACKGROUND_TASK_NOTIFICATION, 0xCF23F240, 0x2A54, 0x48D8, 0xB1, 0x14, 0xDE, 0x15, 0x18, 0xFF, 0x05, 0x2E );

// Define a GUID that will represent the action of a direct experience button
// on the platform. Users will register for this DPPE setting and recieve
// notification when the h/w button is pressed.
//
// { 1A689231-7399-4E9A-8F99-B71F999DB3FA }
//
DEFINE_GUID( GUID_APPLAUNCH_BUTTON, 0x1A689231, 0x7399, 0x4E9A, 0x8F, 0x99, 0xB7, 0x1F, 0x99, 0x9D, 0xB3, 0xFA );

// PCI Express power settings
// ------------------------
//

// Specifies the subgroup which will contain all of the PCI Express
// settings for a single policy.
//
// {501a4d13-42af-4429-9fd1-a8218c268e20}
//
DEFINE_GUID( GUID_PCIEXPRESS_SETTINGS_SUBGROUP, 0x501a4d13, 0x42af,0x4429, 0x9f, 0xd1, 0xa8, 0x21, 0x8c, 0x26, 0x8e, 0x20 );

// Specifies the PCI Express ASPM power policy.
//
// {ee12f906-d277-404b-b6da-e5fa1a576df5}
//
DEFINE_GUID( GUID_PCIEXPRESS_ASPM_POLICY, 0xee12f906, 0xd277, 0x404b, 0xb6, 0xda, 0xe5, 0xfa, 0x1a, 0x57, 0x6d, 0xf5 );

// POWER Shutdown settings
// ------------------------
//

// Specifies if forced shutdown should be used for all button and lid initiated
// shutdown actions.
//
// {833a6b62-dfa4-46d1-82f8-e09e34d029d6}
//

DEFINE_GUID( GUID_ENABLE_SWITCH_FORCED_SHUTDOWN, 0x833a6b62, 0xdfa4, 0x46d1, 0x82, 0xf8, 0xe0, 0x9e, 0x34, 0xd0, 0x29, 0xd6 );


typedef enum _SYSTEM_POWER_STATE {
PowerSystemUnspecified = 0,
PowerSystemWorking = 1,
PowerSystemSleeping1 = 2,
PowerSystemSleeping2 = 3,
PowerSystemSleeping3 = 4,
PowerSystemHibernate = 5,
PowerSystemShutdown = 6,
PowerSystemMaximum = 7
} SYSTEM_POWER_STATE, *PSYSTEM_POWER_STATE;

#define POWER_SYSTEM_MAXIMUM 7

typedef enum {
PowerActionNone = 0,
PowerActionReserved,
PowerActionSleep,
PowerActionHibernate,
PowerActionShutdown,
PowerActionShutdownReset,
PowerActionShutdownOff,
PowerActionWarmEject
} POWER_ACTION, *PPOWER_ACTION;

typedef enum _DEVICE_POWER_STATE {
PowerDeviceUnspecified = 0,
PowerDeviceD0,
PowerDeviceD1,
PowerDeviceD2,
PowerDeviceD3,
PowerDeviceMaximum
} DEVICE_POWER_STATE, *PDEVICE_POWER_STATE;

typedef enum _MONITOR_DISPLAY_STATE {
PowerMonitorOff = 0,
PowerMonitorOn,
PowerMonitorDim
} MONITOR_DISPLAY_STATE, *PMONITOR_DISPLAY_STATE;


#define ES_SYSTEM_REQUIRED ((DWORD)0x00000001)
#define ES_DISPLAY_REQUIRED ((DWORD)0x00000002)
#define ES_USER_PRESENT ((DWORD)0x00000004)
#define ES_AWAYMODE_REQUIRED ((DWORD)0x00000040)
#define ES_CONTINUOUS ((DWORD)0x80000000)

typedef DWORD EXECUTION_STATE, *PEXECUTION_STATE;

typedef enum {
LT_DONT_CARE,
LT_LOWEST_LATENCY
} LATENCY_TIME;

#if (_WIN32_WINNT >= _WIN32_WINNT_WIN7)

#define DIAGNOSTIC_REASON_VERSION 0

#define DIAGNOSTIC_REASON_SIMPLE_STRING 0x00000001
#define DIAGNOSTIC_REASON_DETAILED_STRING 0x00000002
#define DIAGNOSTIC_REASON_NOT_SPECIFIED 0x80000000
#define DIAGNOSTIC_REASON_INVALID_FLAGS (~0x80000003)

#endif // (_WIN32_WINNT >= _WIN32_WINNT_WIN7)

//
// Defines for power request APIs
//

#define POWER_REQUEST_CONTEXT_VERSION 0

#define POWER_REQUEST_CONTEXT_SIMPLE_STRING 0x00000001
#define POWER_REQUEST_CONTEXT_DETAILED_STRING 0x00000002

//
// N.B. The maximum is a macro (rather than part of enum) for cgen to be able
// to parse power.h correctly. When a new power request type is added, the
// PowerRequestMaximum should be manually incremented.
//

typedef enum _POWER_REQUEST_TYPE {
PowerRequestDisplayRequired,
PowerRequestSystemRequired,
PowerRequestAwayModeRequired
} POWER_REQUEST_TYPE, *PPOWER_REQUEST_TYPE;

#define PowerRequestMaximum 3

// end_ntminiport

#if (NTDDI_VERSION >= NTDDI_WINXP)

//-----------------------------------------------------------------------------
// Device Power Information
// Accessable via CM_Get_DevInst_Registry_Property_Ex(CM_DRP_DEVICE_POWER_DATA)
//-----------------------------------------------------------------------------

#define PDCAP_D0_SUPPORTED 0x00000001
#define PDCAP_D1_SUPPORTED 0x00000002
#define PDCAP_D2_SUPPORTED 0x00000004
#define PDCAP_D3_SUPPORTED 0x00000008
#define PDCAP_WAKE_FROM_D0_SUPPORTED 0x00000010
#define PDCAP_WAKE_FROM_D1_SUPPORTED 0x00000020
#define PDCAP_WAKE_FROM_D2_SUPPORTED 0x00000040
#define PDCAP_WAKE_FROM_D3_SUPPORTED 0x00000080
#define PDCAP_WARM_EJECT_SUPPORTED 0x00000100

typedef struct CM_Power_Data_s {
DWORD PD_Size;
DEVICE_POWER_STATE PD_MostRecentPowerState;
DWORD PD_Capabilities;
DWORD PD_D1Latency;
DWORD PD_D2Latency;
DWORD PD_D3Latency;
DEVICE_POWER_STATE PD_PowerStateMapping[POWER_SYSTEM_MAXIMUM];
SYSTEM_POWER_STATE PD_DeepestSystemWake;
} CM_POWER_DATA, *PCM_POWER_DATA;

#endif // (NTDDI_VERSION >= NTDDI_WINXP)

// begin_wdm

typedef enum {
SystemPowerPolicyAc,
SystemPowerPolicyDc,
VerifySystemPolicyAc,
VerifySystemPolicyDc,
SystemPowerCapabilities,
SystemBatteryState,
SystemPowerStateHandler,
ProcessorStateHandler,
SystemPowerPolicyCurrent,
AdministratorPowerPolicy,
SystemReserveHiberFile,
ProcessorInformation,
SystemPowerInformation,
ProcessorStateHandler2,
LastWakeTime, // Compare with KeQueryInterruptTime()
LastSleepTime, // Compare with KeQueryInterruptTime()
SystemExecutionState,
SystemPowerStateNotifyHandler,
ProcessorPowerPolicyAc,
ProcessorPowerPolicyDc,
VerifyProcessorPowerPolicyAc,
VerifyProcessorPowerPolicyDc,
ProcessorPowerPolicyCurrent,
SystemPowerStateLogging,
SystemPowerLoggingEntry,
SetPowerSettingValue,
NotifyUserPowerSetting,
PowerInformationLevelUnused0,
PowerInformationLevelUnused1,
SystemVideoState,
TraceApplicationPowerMessage,
TraceApplicationPowerMessageEnd,
ProcessorPerfStates,
ProcessorIdleStates,
ProcessorCap,
SystemWakeSource,
SystemHiberFileInformation,
TraceServicePowerMessage,
ProcessorLoad,
PowerShutdownNotification,
MonitorCapabilities,
SessionPowerInit,
SessionDisplayState,
PowerRequestCreate,
PowerRequestAction,
GetPowerRequestList,
ProcessorInformationEx,
NotifyUserModeLegacyPowerEvent,
GroupPark,
ProcessorIdleDomains,
WakeTimerList,
SystemHiberFileSize,
PowerInformationLevelMaximum
} POWER_INFORMATION_LEVEL;

//
// Power Setting definitions
//

typedef enum {
PoAc,
PoDc,
PoHot,
PoConditionMaximum
} SYSTEM_POWER_CONDITION;

typedef struct {

//
// Version of this structure. Currently should be set to
// POWER_SETTING_VALUE_VERSION.
//
DWORD Version;


//
// GUID representing the power setting being applied.
//
GUID Guid;


//
// What power state should this setting be applied to? E.g.
// AC, DC, thermal, ...
//
SYSTEM_POWER_CONDITION PowerCondition;

//
// Length (in bytes) of the ‘Data‘ member.
//
DWORD DataLength;

//
// Data which contains the actual setting value.
//
BYTE Data[ANYSIZE_ARRAY];
} SET_POWER_SETTING_VALUE, *PSET_POWER_SETTING_VALUE;

#define POWER_SETTING_VALUE_VERSION (0x1)

typedef struct {
GUID Guid;
} NOTIFY_USER_POWER_SETTING, *PNOTIFY_USER_POWER_SETTING;

//
// Package definition for an experience button device notification. When
// someone registers for GUID_EXPERIENCE_BUTTON, this is the definition of
// the setting data they‘ll get.
//
typedef struct _APPLICATIONLAUNCH_SETTING_VALUE {

//
// System time when the most recent button press ocurred. Note that this is
// specified in 100ns internvals since January 1, 1601.
//
LARGE_INTEGER ActivationTime;

//
// Reserved for internal use.
//
DWORD Flags;

//
// which instance of this device was pressed?
//
DWORD ButtonInstanceID;


} APPLICATIONLAUNCH_SETTING_VALUE, *PAPPLICATIONLAUNCH_SETTING_VALUE;

//
// define platform roles
//

typedef enum {
PlatformRoleUnspecified = 0,
PlatformRoleDesktop,
PlatformRoleMobile,
PlatformRoleWorkstation,
PlatformRoleEnterpriseServer,
PlatformRoleSOHOServer,
PlatformRoleAppliancePC,
PlatformRolePerformanceServer,
PlatformRoleMaximum
} POWER_PLATFORM_ROLE;

//
// System power manager capabilities
//

#if (NTDDI_VERSION >= NTDDI_WINXP) || !defined(_BATCLASS_)
typedef struct {
DWORD Granularity;
DWORD Capacity;
} BATTERY_REPORTING_SCALE, *PBATTERY_REPORTING_SCALE;
#endif // (NTDDI_VERSION >= NTDDI_WINXP) || !defined(_BATCLASS_)

//

typedef struct {
DWORD Frequency;
DWORD Flags;
DWORD PercentFrequency;
} PPM_WMI_LEGACY_PERFSTATE, *PPPM_WMI_LEGACY_PERFSTATE;

typedef struct {
DWORD Latency;
DWORD Power;
DWORD TimeCheck;
BYTE PromotePercent;
BYTE DemotePercent;
BYTE StateType;
BYTE Reserved;
DWORD StateFlags;
DWORD Context;
DWORD IdleHandler;
DWORD Reserved1; // reserved for future use
} PPM_WMI_IDLE_STATE, *PPPM_WMI_IDLE_STATE;

typedef struct {
DWORD Type;
DWORD Count;
DWORD TargetState; // current idle state
DWORD OldState; // previous idle state
DWORD64 TargetProcessors;
PPM_WMI_IDLE_STATE State[ANYSIZE_ARRAY];
} PPM_WMI_IDLE_STATES, *PPPM_WMI_IDLE_STATES;

typedef struct {
DWORD Type;
DWORD Count;
DWORD TargetState; // current idle state
DWORD OldState; // previous idle state
PVOID TargetProcessors;
PPM_WMI_IDLE_STATE State[ANYSIZE_ARRAY];
} PPM_WMI_IDLE_STATES_EX, *PPPM_WMI_IDLE_STATES_EX;

typedef struct {
DWORD Frequency; // in Mhz
DWORD Power; // in milliwatts
BYTE PercentFrequency;
BYTE IncreaseLevel; // goto higher state
BYTE DecreaseLevel; // goto lower state
BYTE Type; // performance or throttle
DWORD IncreaseTime; // in tick counts
DWORD DecreaseTime; // in tick counts
DWORD64 Control; // control value
DWORD64 Status; // control value
DWORD HitCount;
DWORD Reserved1; // reserved for future use
DWORD64 Reserved2;
DWORD64 Reserved3;
} PPM_WMI_PERF_STATE, *PPPM_WMI_PERF_STATE;

typedef struct {
DWORD Count;
DWORD MaxFrequency;
DWORD CurrentState; // current state
DWORD MaxPerfState; // fastest state considering policy restrictions
DWORD MinPerfState; // slowest state considering policy restrictions
DWORD LowestPerfState; // slowest perf state, fixed, aka the "knee"
DWORD ThermalConstraint;
BYTE BusyAdjThreshold;
BYTE PolicyType; // domain coordination
BYTE Type;
BYTE Reserved;
DWORD TimerInterval;
DWORD64 TargetProcessors; // domain affinity
DWORD PStateHandler;
DWORD PStateContext;
DWORD TStateHandler;
DWORD TStateContext;
DWORD FeedbackHandler;
DWORD Reserved1;
DWORD64 Reserved2;
PPM_WMI_PERF_STATE State[ANYSIZE_ARRAY];
} PPM_WMI_PERF_STATES, *PPPM_WMI_PERF_STATES;

typedef struct {
DWORD Count;
DWORD MaxFrequency;
DWORD CurrentState; // current state
DWORD MaxPerfState; // fastest state considering policy restrictions
DWORD MinPerfState; // slowest state considering policy restrictions
DWORD LowestPerfState; // slowest perf state, fixed, aka the "knee"
DWORD ThermalConstraint;
BYTE BusyAdjThreshold;
BYTE PolicyType; // domain coordination
BYTE Type;
BYTE Reserved;
DWORD TimerInterval;
PVOID TargetProcessors; // domain affinity
DWORD PStateHandler;
DWORD PStateContext;
DWORD TStateHandler;
DWORD TStateContext;
DWORD FeedbackHandler;
DWORD Reserved1;
DWORD64 Reserved2;
PPM_WMI_PERF_STATE State[ANYSIZE_ARRAY];
} PPM_WMI_PERF_STATES_EX, *PPPM_WMI_PERF_STATES_EX;

//
// Legacy processor idle accounting.
//

#define PROC_IDLE_BUCKET_COUNT 6

typedef struct {
DWORD IdleTransitions;
DWORD FailedTransitions;
DWORD InvalidBucketIndex;
DWORD64 TotalTime;
DWORD IdleTimeBuckets[PROC_IDLE_BUCKET_COUNT];
} PPM_IDLE_STATE_ACCOUNTING, *PPPM_IDLE_STATE_ACCOUNTING;

typedef struct {
DWORD StateCount;
DWORD TotalTransitions;
DWORD ResetCount;
DWORD64 StartTime;
PPM_IDLE_STATE_ACCOUNTING State[ANYSIZE_ARRAY];
} PPM_IDLE_ACCOUNTING, *PPPM_IDLE_ACCOUNTING;

//
// Processor idle accounting.
//

#define PROC_IDLE_BUCKET_COUNT_EX 16

typedef struct {
DWORD64 TotalTimeUs;
DWORD MinTimeUs;
DWORD MaxTimeUs;
DWORD Count;
} PPM_IDLE_STATE_BUCKET_EX, *PPPM_IDLE_STATE_BUCKET_EX;

typedef struct {
DWORD64 TotalTime;
DWORD IdleTransitions;
DWORD FailedTransitions;
DWORD InvalidBucketIndex;
DWORD MinTimeUs;
DWORD MaxTimeUs;
PPM_IDLE_STATE_BUCKET_EX IdleTimeBuckets[PROC_IDLE_BUCKET_COUNT_EX];
} PPM_IDLE_STATE_ACCOUNTING_EX, *PPPM_IDLE_STATE_ACCOUNTING_EX;

typedef struct {
DWORD StateCount;
DWORD TotalTransitions;
DWORD ResetCount;
DWORD64 StartTime;
__field_ecount(StateCount) PPM_IDLE_STATE_ACCOUNTING_EX State[ANYSIZE_ARRAY];
} PPM_IDLE_ACCOUNTING_EX, *PPPM_IDLE_ACCOUNTING_EX;

//
// Definitions of coordination types for _PSD, _TSD, and _CSD BIOS objects from
// the Acpi 3.0 specification
//

#define ACPI_PPM_SOFTWARE_ALL 0xFC
#define ACPI_PPM_SOFTWARE_ANY 0xFD
#define ACPI_PPM_HARDWARE_ALL 0xFE

//
// Definition of Microsoft PPM coordination types.
//

#define MS_PPM_SOFTWARE_ALL 0x1

//
// Processor firmware rundown feature bit definitions.
//

#define PPM_FIRMWARE_ACPI1C2 0x00000001
#define PPM_FIRMWARE_ACPI1C3 0x00000002
#define PPM_FIRMWARE_ACPI1TSTATES 0x00000004
#define PPM_FIRMWARE_CST 0x00000008
#define PPM_FIRMWARE_CSD 0x00000010
#define PPM_FIRMWARE_PCT 0x00000020
#define PPM_FIRMWARE_PSS 0x00000040
#define PPM_FIRMWARE_XPSS 0x00000080
#define PPM_FIRMWARE_PPC 0x00000100
#define PPM_FIRMWARE_PSD 0x00000200
#define PPM_FIRMWARE_PTC 0x00000400
#define PPM_FIRMWARE_TSS 0x00000800
#define PPM_FIRMWARE_TPC 0x00001000
#define PPM_FIRMWARE_TSD 0x00002000
#define PPM_FIRMWARE_PCCH 0x00004000
#define PPM_FIRMWARE_PCCP 0x00008000

//
// Processor Power Management WMI interface.
//

// {A5B32DDD-7F39-4abc-B892-900E43B59EBB}
DEFINE_GUID(PPM_PERFSTATE_CHANGE_GUID,
0xa5b32ddd, 0x7f39, 0x4abc, 0xb8, 0x92, 0x90, 0xe, 0x43, 0xb5, 0x9e, 0xbb);

// {995e6b7f-d653-497a-b978-36a30c29bf01}
DEFINE_GUID(PPM_PERFSTATE_DOMAIN_CHANGE_GUID,
0x995e6b7f, 0xd653, 0x497a, 0xb9, 0x78, 0x36, 0xa3, 0xc, 0x29, 0xbf, 0x1);

// {4838fe4f-f71c-4e51-9ecc-8430a7ac4c6c}
DEFINE_GUID(PPM_IDLESTATE_CHANGE_GUID,
0x4838fe4f, 0xf71c, 0x4e51, 0x9e, 0xcc, 0x84, 0x30, 0xa7, 0xac, 0x4c, 0x6c);

// {5708cc20-7d40-4bf4-b4aa-2b01338d0126}
DEFINE_GUID(PPM_PERFSTATES_DATA_GUID,
0x5708cc20, 0x7d40, 0x4bf4, 0xb4, 0xaa, 0x2b, 0x01, 0x33, 0x8d, 0x01, 0x26);

// {ba138e10-e250-4ad7-8616-cf1a7ad410e7}
DEFINE_GUID(PPM_IDLESTATES_DATA_GUID,
0xba138e10, 0xe250, 0x4ad7, 0x86, 0x16, 0xcf, 0x1a, 0x7a, 0xd4, 0x10, 0xe7);

// {e2a26f78-ae07-4ee0-a30f-ce354f5a94cd}
DEFINE_GUID(PPM_IDLE_ACCOUNTING_GUID,
0xe2a26f78, 0xae07, 0x4ee0, 0xa3, 0x0f, 0xce, 0x54, 0xf5, 0x5a, 0x94, 0xcd);

// {d67abd39-81f8-4a5e-8152-72e31ec912ee}
DEFINE_GUID(PPM_IDLE_ACCOUNTING_EX_GUID,
0xd67abd39, 0x81f8, 0x4a5e, 0x81, 0x52, 0x72, 0xe3, 0x1e, 0xc9, 0x12, 0xee);

// {a852c2c8-1a4c-423b-8c2c-f30d82931a88}
DEFINE_GUID(PPM_THERMALCONSTRAINT_GUID,
0xa852c2c8, 0x1a4c, 0x423b, 0x8c, 0x2c, 0xf3, 0x0d, 0x82, 0x93, 0x1a, 0x88);

// {7fd18652-0cfe-40d2-b0a1-0b066a87759e}
DEFINE_GUID(PPM_PERFMON_PERFSTATE_GUID,
0x7fd18652, 0xcfe, 0x40d2, 0xb0, 0xa1, 0xb, 0x6, 0x6a, 0x87, 0x75, 0x9e);

// {48f377b8-6880-4c7b-8bdc-380176c6654d}
DEFINE_GUID(PPM_THERMAL_POLICY_CHANGE_GUID,
0x48f377b8, 0x6880, 0x4c7b, 0x8b, 0xdc, 0x38, 0x1, 0x76, 0xc6, 0x65, 0x4d);


typedef struct {
DWORD State;
DWORD Status;
DWORD Latency;
DWORD Speed;
DWORD Processor;
} PPM_PERFSTATE_EVENT, *PPPM_PERFSTATE_EVENT;

typedef struct {
DWORD State;
DWORD Latency;
DWORD Speed;
DWORD64 Processors;
} PPM_PERFSTATE_DOMAIN_EVENT, *PPPM_PERFSTATE_DOMAIN_EVENT;

typedef struct {
DWORD NewState;
DWORD OldState;
DWORD64 Processors;
} PPM_IDLESTATE_EVENT, *PPPM_IDLESTATE_EVENT;

typedef struct {
DWORD ThermalConstraint;
DWORD64 Processors;
} PPM_THERMALCHANGE_EVENT, *PPPM_THERMALCHANGE_EVENT;

#pragma warning(push)
#pragma warning(disable:4121)

typedef struct {
BYTE Mode;
DWORD64 Processors;
} PPM_THERMAL_POLICY_EVENT, *PPPM_THERMAL_POLICY_EVENT;

#pragma warning(pop)

// Power Policy Management interfaces
//

typedef struct {
POWER_ACTION Action;
DWORD Flags;
DWORD EventCode;
} POWER_ACTION_POLICY, *PPOWER_ACTION_POLICY;

// POWER_ACTION_POLICY->Flags:
#define POWER_ACTION_QUERY_ALLOWED 0x00000001
#define POWER_ACTION_UI_ALLOWED 0x00000002
#define POWER_ACTION_OVERRIDE_APPS 0x00000004
#define POWER_ACTION_PSEUDO_TRANSITION 0x08000000
#define POWER_ACTION_LIGHTEST_FIRST 0x10000000
#define POWER_ACTION_LOCK_CONSOLE 0x20000000
#define POWER_ACTION_DISABLE_WAKES 0x40000000
#define POWER_ACTION_CRITICAL 0x80000000

// POWER_ACTION_POLICY->EventCode flags
#define POWER_LEVEL_USER_NOTIFY_TEXT 0x00000001
#define POWER_LEVEL_USER_NOTIFY_SOUND 0x00000002
#define POWER_LEVEL_USER_NOTIFY_EXEC 0x00000004
#define POWER_USER_NOTIFY_BUTTON 0x00000008
#define POWER_USER_NOTIFY_SHUTDOWN 0x00000010
#define POWER_USER_NOTIFY_FORCED_SHUTDOWN 0x00000020
#define POWER_FORCE_TRIGGER_RESET 0x80000000

// Note: for battery alarm EventCodes, the ID of the battery alarm << 16 is ORed
// into the flags. For example: DISCHARGE_POLICY_LOW << 16

//
// The GUID_BATTERY_DISCHARGE_FLAGS_x power settings use a subset of EventCode
// flags. The POWER_FORCE_TRIGGER_RESET flag doesn‘t make sense for a battery
// alarm so it is overloaded for other purposes (gerneral enable/disable).
#define BATTERY_DISCHARGE_FLAGS_EVENTCODE_MASK 0x00000007
#define BATTERY_DISCHARGE_FLAGS_ENABLE 0x80000000

// system battery drain policies
typedef struct {
BOOLEAN Enable;
BYTE Spare[3];
DWORD BatteryLevel;
POWER_ACTION_POLICY PowerPolicy;
SYSTEM_POWER_STATE MinSystemState;
} SYSTEM_POWER_LEVEL, *PSYSTEM_POWER_LEVEL;

// Discharge policy constants
#define NUM_DISCHARGE_POLICIES 4
#define DISCHARGE_POLICY_CRITICAL 0
#define DISCHARGE_POLICY_LOW 1


// system power policies
typedef struct _SYSTEM_POWER_POLICY {
DWORD Revision; // 1

// events
POWER_ACTION_POLICY PowerButton;
POWER_ACTION_POLICY SleepButton;
POWER_ACTION_POLICY LidClose;
SYSTEM_POWER_STATE LidOpenWake;
DWORD Reserved;

// "system idle" detection
POWER_ACTION_POLICY Idle;
DWORD IdleTimeout;
BYTE IdleSensitivity;

BYTE DynamicThrottle;
BYTE Spare2[2];

// meaning of power action "sleep"
SYSTEM_POWER_STATE MinSleep;
SYSTEM_POWER_STATE MaxSleep;
SYSTEM_POWER_STATE ReducedLatencySleep;
DWORD WinLogonFlags;

DWORD Spare3;

// parameters for dozing
//
DWORD DozeS4Timeout;

// battery policies
DWORD BroadcastCapacityResolution;
SYSTEM_POWER_LEVEL DischargePolicy[NUM_DISCHARGE_POLICIES];

// video policies
DWORD VideoTimeout;
BOOLEAN VideoDimDisplay;
DWORD VideoReserved[3];

// hard disk policies
DWORD SpindownTimeout;

// processor policies
BOOLEAN OptimizeForPower;
BYTE FanThrottleTolerance;
BYTE ForcedThrottle;
BYTE MinThrottle;
POWER_ACTION_POLICY OverThrottled;

} SYSTEM_POWER_POLICY, *PSYSTEM_POWER_POLICY;


// processor power policy state

//
// Processor Idle State Policy.
//

#define PROCESSOR_IDLESTATE_POLICY_COUNT 0x3

typedef struct {
DWORD TimeCheck;
BYTE DemotePercent;
BYTE PromotePercent;
BYTE Spare[2];
} PROCESSOR_IDLESTATE_INFO, *PPROCESSOR_IDLESTATE_INFO;

typedef struct {
WORD Revision;
union {
WORD AsWORD ;
struct {
WORD AllowScaling : 1;
WORD Disabled : 1;
WORD Reserved : 14;
} DUMMYSTRUCTNAME;
} Flags;

DWORD PolicyCount;
PROCESSOR_IDLESTATE_INFO Policy[PROCESSOR_IDLESTATE_POLICY_COUNT];
} PROCESSOR_IDLESTATE_POLICY, *PPROCESSOR_IDLESTATE_POLICY;

//
// Legacy Processor Policy. This is only provided to allow legacy
// applications to compile. New applications must use
// PROCESSOR_IDLESTATE_POLICY.
//

#define PO_THROTTLE_NONE 0
#define PO_THROTTLE_CONSTANT 1
#define PO_THROTTLE_DEGRADE 2
#define PO_THROTTLE_ADAPTIVE 3
#define PO_THROTTLE_MAXIMUM 4 // not a policy, just a limit


typedef struct _PROCESSOR_POWER_POLICY_INFO {

// Time based information (will be converted to kernel units)
DWORD TimeCheck; // in US
DWORD DemoteLimit; // in US
DWORD PromoteLimit; // in US

// Percentage based information
BYTE DemotePercent;
BYTE PromotePercent;
BYTE Spare[2];

// Flags
DWORD AllowDemotion:1;
DWORD AllowPromotion:1;
DWORD Reserved:30;

} PROCESSOR_POWER_POLICY_INFO, *PPROCESSOR_POWER_POLICY_INFO;

// processor power policy
typedef struct _PROCESSOR_POWER_POLICY {
DWORD Revision; // 1

// Dynamic Throttling Policy
BYTE DynamicThrottle;
BYTE Spare[3];

// Flags
DWORD DisableCStates:1;
DWORD Reserved:31;

// System policy information
// The Array is last, in case it needs to be grown and the structure
// revision incremented.
DWORD PolicyCount;
PROCESSOR_POWER_POLICY_INFO Policy[3];

} PROCESSOR_POWER_POLICY, *PPROCESSOR_POWER_POLICY;

//
// Processor Perf State Policy.
//

typedef struct {
DWORD Revision;
BYTE MaxThrottle;
BYTE MinThrottle;
BYTE BusyAdjThreshold;
union {
BYTE Spare;
union {
BYTE AsBYTE ;
struct {
BYTE NoDomainAccounting : 1;
BYTE IncreasePolicy: 2;
BYTE DecreasePolicy: 2;
BYTE Reserved : 3;
} DUMMYSTRUCTNAME;
} Flags;
} DUMMYUNIONNAME;

DWORD TimeCheck;
DWORD IncreaseTime;
DWORD DecreaseTime;
DWORD IncreasePercent;
DWORD DecreasePercent;
} PROCESSOR_PERFSTATE_POLICY, *PPROCESSOR_PERFSTATE_POLICY;

// administrator power policy overrides
typedef struct _ADMINISTRATOR_POWER_POLICY {

// meaning of power action "sleep"
SYSTEM_POWER_STATE MinSleep;
SYSTEM_POWER_STATE MaxSleep;

// video policies
DWORD MinVideoTimeout;
DWORD MaxVideoTimeout;

// disk policies
DWORD MinSpindownTimeout;
DWORD MaxSpindownTimeout;
} ADMINISTRATOR_POWER_POLICY, *PADMINISTRATOR_POWER_POLICY;


typedef struct {
// Misc supported system features
BOOLEAN PowerButtonPresent;
BOOLEAN SleepButtonPresent;
BOOLEAN LidPresent;
BOOLEAN SystemS1;
BOOLEAN SystemS2;
BOOLEAN SystemS3;
BOOLEAN SystemS4; // hibernate
BOOLEAN SystemS5; // off
BOOLEAN HiberFilePresent;
BOOLEAN FullWake;
BOOLEAN VideoDimPresent;
BOOLEAN ApmPresent;
BOOLEAN UpsPresent;

// Processors
BOOLEAN ThermalControl;
BOOLEAN ProcessorThrottle;
BYTE ProcessorMinThrottle;

#if (NTDDI_VERSION < NTDDI_WINXP)
BYTE ProcessorThrottleScale;
BYTE spare2[4];
#else
BYTE ProcessorMaxThrottle;
BOOLEAN FastSystemS4;
BYTE spare2[3];
#endif // (NTDDI_VERSION < NTDDI_WINXP)

// Disk
BOOLEAN DiskSpinDown;
BYTE spare3[8];

// System Battery
BOOLEAN SystemBatteriesPresent;
BOOLEAN BatteriesAreShortTerm;
BATTERY_REPORTING_SCALE BatteryScale[3];

// Wake
SYSTEM_POWER_STATE AcOnLineWake;
SYSTEM_POWER_STATE SoftLidWake;
SYSTEM_POWER_STATE RtcWake;
SYSTEM_POWER_STATE MinDeviceWakeState; // note this may change on driver load
SYSTEM_POWER_STATE DefaultLowLatencyWake;
} SYSTEM_POWER_CAPABILITIES, *PSYSTEM_POWER_CAPABILITIES;

typedef struct {
BOOLEAN AcOnLine;
BOOLEAN BatteryPresent;
BOOLEAN Charging;
BOOLEAN Discharging;
BOOLEAN Spare1[4];

DWORD MaxCapacity;
DWORD RemainingCapacity;
DWORD Rate;
DWORD EstimatedTime;

DWORD DefaultAlert1;
DWORD DefaultAlert2;
} SYSTEM_BATTERY_STATE, *PSYSTEM_BATTERY_STATE;

 

//
// Image Format
//


#ifndef _MAC

#include "pshpack4.h" // 4 byte packing is the default

#define IMAGE_DOS_SIGNATURE 0x5A4D // MZ
#define IMAGE_OS2_SIGNATURE 0x454E // NE
#define IMAGE_OS2_SIGNATURE_LE 0x454C // LE
#define IMAGE_VXD_SIGNATURE 0x454C // LE
#define IMAGE_NT_SIGNATURE 0x00004550 // PE00

#include "pshpack2.h" // 16 bit headers are 2 byte packed

#else

#include "pshpack1.h"

#define IMAGE_DOS_SIGNATURE 0x4D5A // MZ
#define IMAGE_OS2_SIGNATURE 0x4E45 // NE
#define IMAGE_OS2_SIGNATURE_LE 0x4C45 // LE
#define IMAGE_NT_SIGNATURE 0x50450000 // PE00
#endif

typedef struct _IMAGE_DOS_HEADER { // DOS .EXE header
WORD e_magic; // Magic number
WORD e_cblp; // Bytes on last page of file
WORD e_cp; // Pages in file
WORD e_crlc; // Relocations
WORD e_cparhdr; // Size of header in paragraphs
WORD e_minalloc; // Minimum extra paragraphs needed
WORD e_maxalloc; // Maximum extra paragraphs needed
WORD e_ss; // Initial (relative) SS value
WORD e_sp; // Initial SP value
WORD e_csum; // Checksum
WORD e_ip; // Initial IP value
WORD e_cs; // Initial (relative) CS value
WORD e_lfarlc; // File address of relocation table
WORD e_ovno; // Overlay number
WORD e_res[4]; // Reserved words
WORD e_oemid; // OEM identifier (for e_oeminfo)
WORD e_oeminfo; // OEM information; e_oemid specific
WORD e_res2[10]; // Reserved words
LONG e_lfanew; // File address of new exe header
} IMAGE_DOS_HEADER, *PIMAGE_DOS_HEADER;

typedef struct _IMAGE_OS2_HEADER { // OS/2 .EXE header
WORD ne_magic; // Magic number
CHAR ne_ver; // Version number
CHAR ne_rev; // Revision number
WORD ne_enttab; // Offset of Entry Table
WORD ne_cbenttab; // Number of bytes in Entry Table
LONG ne_crc; // Checksum of whole file
WORD ne_flags; // Flag word
WORD ne_autodata; // Automatic data segment number
WORD ne_heap; // Initial heap allocation
WORD ne_stack; // Initial stack allocation
LONG ne_csip; // Initial CS:IP setting
LONG ne_sssp; // Initial SS:SP setting
WORD ne_cseg; // Count of file segments
WORD ne_cmod; // Entries in Module Reference Table
WORD ne_cbnrestab; // Size of non-resident name table
WORD ne_segtab; // Offset of Segment Table
WORD ne_rsrctab; // Offset of Resource Table
WORD ne_restab; // Offset of resident name table
WORD ne_modtab; // Offset of Module Reference Table
WORD ne_imptab; // Offset of Imported Names Table
LONG ne_nrestab; // Offset of Non-resident Names Table
WORD ne_cmovent; // Count of movable entries
WORD ne_align; // Segment alignment shift count
WORD ne_cres; // Count of resource segments
BYTE ne_exetyp; // Target Operating system
BYTE ne_flagsothers; // Other .EXE flags
WORD ne_pretthunks; // offset to return thunks
WORD ne_psegrefbytes; // offset to segment ref. bytes
WORD ne_swaparea; // Minimum code swap area size
WORD ne_expver; // Expected Windows version number
} IMAGE_OS2_HEADER, *PIMAGE_OS2_HEADER;

typedef struct _IMAGE_VXD_HEADER { // Windows VXD header
WORD e32_magic; // Magic number
BYTE e32_border; // The byte ordering for the VXD
BYTE e32_worder; // The word ordering for the VXD
DWORD e32_level; // The EXE format level for now = 0
WORD e32_cpu; // The CPU type
WORD e32_os; // The OS type
DWORD e32_ver; // Module version
DWORD e32_mflags; // Module flags
DWORD e32_mpages; // Module # pages
DWORD e32_startobj; // Object # for instruction pointer
DWORD e32_eip; // Extended instruction pointer
DWORD e32_stackobj; // Object # for stack pointer
DWORD e32_esp; // Extended stack pointer
DWORD e32_pagesize; // VXD page size
DWORD e32_lastpagesize; // Last page size in VXD
DWORD e32_fixupsize; // Fixup section size
DWORD e32_fixupsum; // Fixup section checksum
DWORD e32_ldrsize; // Loader section size
DWORD e32_ldrsum; // Loader section checksum
DWORD e32_objtab; // Object table offset
DWORD e32_objcnt; // Number of objects in module
DWORD e32_objmap; // Object page map offset
DWORD e32_itermap; // Object iterated data map offset
DWORD e32_rsrctab; // Offset of Resource Table
DWORD e32_rsrccnt; // Number of resource entries
DWORD e32_restab; // Offset of resident name table
DWORD e32_enttab; // Offset of Entry Table
DWORD e32_dirtab; // Offset of Module Directive Table
DWORD e32_dircnt; // Number of module directives
DWORD e32_fpagetab; // Offset of Fixup Page Table
DWORD e32_frectab; // Offset of Fixup Record Table
DWORD e32_impmod; // Offset of Import Module Name Table
DWORD e32_impmodcnt; // Number of entries in Import Module Name Table
DWORD e32_impproc; // Offset of Import Procedure Name Table
DWORD e32_pagesum; // Offset of Per-Page Checksum Table
DWORD e32_datapage; // Offset of Enumerated Data Pages
DWORD e32_preload; // Number of preload pages
DWORD e32_nrestab; // Offset of Non-resident Names Table
DWORD e32_cbnrestab; // Size of Non-resident Name Table
DWORD e32_nressum; // Non-resident Name Table Checksum
DWORD e32_autodata; // Object # for automatic data object
DWORD e32_debuginfo; // Offset of the debugging information
DWORD e32_debuglen; // The length of the debugging info. in bytes
DWORD e32_instpreload; // Number of instance pages in preload section of VXD file
DWORD e32_instdemand; // Number of instance pages in demand load section of VXD file
DWORD e32_heapsize; // Size of heap - for 16-bit apps
BYTE e32_res3[12]; // Reserved words
DWORD e32_winresoff;
DWORD e32_winreslen;
WORD e32_devid; // Device ID for VxD
WORD e32_ddkver; // DDK version for VxD
} IMAGE_VXD_HEADER, *PIMAGE_VXD_HEADER;

#ifndef _MAC
#include "poppack.h" // Back to 4 byte packing
#endif

//
// File header format.
//

typedef struct _IMAGE_FILE_HEADER {
WORD Machine;
WORD NumberOfSections;
DWORD TimeDateStamp;
DWORD PointerToSymbolTable;
DWORD NumberOfSymbols;
WORD SizeOfOptionalHeader;
WORD Characteristics;
} IMAGE_FILE_HEADER, *PIMAGE_FILE_HEADER;

#define IMAGE_SIZEOF_FILE_HEADER 20

#define IMAGE_FILE_RELOCS_STRIPPED 0x0001 // Relocation info stripped from file.
#define IMAGE_FILE_EXECUTABLE_IMAGE 0x0002 // File is executable (i.e. no unresolved externel references).
#define IMAGE_FILE_LINE_NUMS_STRIPPED 0x0004 // Line nunbers stripped from file.
#define IMAGE_FILE_LOCAL_SYMS_STRIPPED 0x0008 // Local symbols stripped from file.
#define IMAGE_FILE_AGGRESIVE_WS_TRIM 0x0010 // Agressively trim working set
#define IMAGE_FILE_LARGE_ADDRESS_AWARE 0x0020 // App can handle >2gb addresses
#define IMAGE_FILE_BYTES_REVERSED_LO 0x0080 // Bytes of machine word are reversed.
#define IMAGE_FILE_32BIT_MACHINE 0x0100 // 32 bit word machine.
#define IMAGE_FILE_DEBUG_STRIPPED 0x0200 // Debugging info stripped from file in .DBG file
#define IMAGE_FILE_REMOVABLE_RUN_FROM_SWAP 0x0400 // If Image is on removable media, copy and run from the swap file.
#define IMAGE_FILE_NET_RUN_FROM_SWAP 0x0800 // If Image is on Net, copy and run from the swap file.
#define IMAGE_FILE_SYSTEM 0x1000 // System File.
#define IMAGE_FILE_DLL 0x2000 // File is a DLL.
#define IMAGE_FILE_UP_SYSTEM_ONLY 0x4000 // File should only be run on a UP machine
#define IMAGE_FILE_BYTES_REVERSED_HI 0x8000 // Bytes of machine word are reversed.

#define IMAGE_FILE_MACHINE_UNKNOWN 0
#define IMAGE_FILE_MACHINE_I386 0x014c // Intel 386.
#define IMAGE_FILE_MACHINE_R3000 0x0162 // MIPS little-endian, 0x160 big-endian
#define IMAGE_FILE_MACHINE_R4000 0x0166 // MIPS little-endian
#define IMAGE_FILE_MACHINE_R10000 0x0168 // MIPS little-endian
#define IMAGE_FILE_MACHINE_WCEMIPSV2 0x0169 // MIPS little-endian WCE v2
#define IMAGE_FILE_MACHINE_ALPHA 0x0184 // Alpha_AXP
#define IMAGE_FILE_MACHINE_SH3 0x01a2 // SH3 little-endian
#define IMAGE_FILE_MACHINE_SH3DSP 0x01a3
#define IMAGE_FILE_MACHINE_SH3E 0x01a4 // SH3E little-endian
#define IMAGE_FILE_MACHINE_SH4 0x01a6 // SH4 little-endian
#define IMAGE_FILE_MACHINE_SH5 0x01a8 // SH5
#define IMAGE_FILE_MACHINE_ARM 0x01c0 // ARM Little-Endian
#define IMAGE_FILE_MACHINE_THUMB 0x01c2
#define IMAGE_FILE_MACHINE_AM33 0x01d3
#define IMAGE_FILE_MACHINE_POWERPC 0x01F0 // IBM PowerPC Little-Endian
#define IMAGE_FILE_MACHINE_POWERPCFP 0x01f1
#define IMAGE_FILE_MACHINE_IA64 0x0200 // Intel 64
#define IMAGE_FILE_MACHINE_MIPS16 0x0266 // MIPS
#define IMAGE_FILE_MACHINE_ALPHA64 0x0284 // ALPHA64
#define IMAGE_FILE_MACHINE_MIPSFPU 0x0366 // MIPS
#define IMAGE_FILE_MACHINE_MIPSFPU16 0x0466 // MIPS
#define IMAGE_FILE_MACHINE_AXP64 IMAGE_FILE_MACHINE_ALPHA64
#define IMAGE_FILE_MACHINE_TRICORE 0x0520 // Infineon
#define IMAGE_FILE_MACHINE_CEF 0x0CEF
#define IMAGE_FILE_MACHINE_EBC 0x0EBC // EFI Byte Code
#define IMAGE_FILE_MACHINE_AMD64 0x8664 // AMD64 (K8)
#define IMAGE_FILE_MACHINE_M32R 0x9041 // M32R little-endian
#define IMAGE_FILE_MACHINE_CEE 0xC0EE

//
// Directory format.
//

typedef struct _IMAGE_DATA_DIRECTORY {
DWORD VirtualAddress;
DWORD Size;
} IMAGE_DATA_DIRECTORY, *PIMAGE_DATA_DIRECTORY;

#define IMAGE_NUMBEROF_DIRECTORY_ENTRIES 16

//
// Optional header format.
//

typedef struct _IMAGE_OPTIONAL_HEADER {
//
// Standard fields.
//

WORD Magic;
BYTE MajorLinkerVersion;
BYTE MinorLinkerVersion;
DWORD SizeOfCode;
DWORD SizeOfInitializedData;
DWORD SizeOfUninitializedData;
DWORD AddressOfEntryPoint;
DWORD BaseOfCode;
DWORD BaseOfData;

//
// NT additional fields.
//

DWORD ImageBase;
DWORD SectionAlignment;
DWORD FileAlignment;
WORD MajorOperatingSystemVersion;
WORD MinorOperatingSystemVersion;
WORD MajorImageVersion;
WORD MinorImageVersion;
WORD MajorSubsystemVersion;
WORD MinorSubsystemVersion;
DWORD Win32VersionValue;
DWORD SizeOfImage;
DWORD SizeOfHeaders;
DWORD CheckSum;
WORD Subsystem;
WORD DllCharacteristics;
DWORD SizeOfStackReserve;
DWORD SizeOfStackCommit;
DWORD SizeOfHeapReserve;
DWORD SizeOfHeapCommit;
DWORD LoaderFlags;
DWORD NumberOfRvaAndSizes;
IMAGE_DATA_DIRECTORY DataDirectory[IMAGE_NUMBEROF_DIRECTORY_ENTRIES];
} IMAGE_OPTIONAL_HEADER32, *PIMAGE_OPTIONAL_HEADER32;

typedef struct _IMAGE_ROM_OPTIONAL_HEADER {
WORD Magic;
BYTE MajorLinkerVersion;
BYTE MinorLinkerVersion;
DWORD SizeOfCode;
DWORD SizeOfInitializedData;
DWORD SizeOfUninitializedData;
DWORD AddressOfEntryPoint;
DWORD BaseOfCode;
DWORD BaseOfData;
DWORD BaseOfBss;
DWORD GprMask;
DWORD CprMask[4];
DWORD GpValue;
} IMAGE_ROM_OPTIONAL_HEADER, *PIMAGE_ROM_OPTIONAL_HEADER;

typedef struct _IMAGE_OPTIONAL_HEADER64 {
WORD Magic;
BYTE MajorLinkerVersion;
BYTE MinorLinkerVersion;
DWORD SizeOfCode;
DWORD SizeOfInitializedData;
DWORD SizeOfUninitializedData;
DWORD AddressOfEntryPoint;
DWORD BaseOfCode;
ULONGLONG ImageBase;
DWORD SectionAlignment;
DWORD FileAlignment;
WORD MajorOperatingSystemVersion;
WORD MinorOperatingSystemVersion;
WORD MajorImageVersion;
WORD MinorImageVersion;
WORD MajorSubsystemVersion;
WORD MinorSubsystemVersion;
DWORD Win32VersionValue;
DWORD SizeOfImage;
DWORD SizeOfHeaders;
DWORD CheckSum;
WORD Subsystem;
WORD DllCharacteristics;
ULONGLONG SizeOfStackReserve;
ULONGLONG SizeOfStackCommit;
ULONGLONG SizeOfHeapReserve;
ULONGLONG SizeOfHeapCommit;
DWORD LoaderFlags;
DWORD NumberOfRvaAndSizes;
IMAGE_DATA_DIRECTORY DataDirectory[IMAGE_NUMBEROF_DIRECTORY_ENTRIES];
} IMAGE_OPTIONAL_HEADER64, *PIMAGE_OPTIONAL_HEADER64;

#define IMAGE_NT_OPTIONAL_HDR32_MAGIC 0x10b
#define IMAGE_NT_OPTIONAL_HDR64_MAGIC 0x20b
#define IMAGE_ROM_OPTIONAL_HDR_MAGIC 0x107

#ifdef _WIN64
typedef IMAGE_OPTIONAL_HEADER64 IMAGE_OPTIONAL_HEADER;
typedef PIMAGE_OPTIONAL_HEADER64 PIMAGE_OPTIONAL_HEADER;
#define IMAGE_NT_OPTIONAL_HDR_MAGIC IMAGE_NT_OPTIONAL_HDR64_MAGIC
#else
typedef IMAGE_OPTIONAL_HEADER32 IMAGE_OPTIONAL_HEADER;
typedef PIMAGE_OPTIONAL_HEADER32 PIMAGE_OPTIONAL_HEADER;
#define IMAGE_NT_OPTIONAL_HDR_MAGIC IMAGE_NT_OPTIONAL_HDR32_MAGIC
#endif

typedef struct _IMAGE_NT_HEADERS64 {
DWORD Signature;
IMAGE_FILE_HEADER FileHeader;
IMAGE_OPTIONAL_HEADER64 OptionalHeader;
} IMAGE_NT_HEADERS64, *PIMAGE_NT_HEADERS64;

typedef struct _IMAGE_NT_HEADERS {
DWORD Signature;
IMAGE_FILE_HEADER FileHeader;
IMAGE_OPTIONAL_HEADER32 OptionalHeader;
} IMAGE_NT_HEADERS32, *PIMAGE_NT_HEADERS32;

typedef struct _IMAGE_ROM_HEADERS {
IMAGE_FILE_HEADER FileHeader;
IMAGE_ROM_OPTIONAL_HEADER OptionalHeader;
} IMAGE_ROM_HEADERS, *PIMAGE_ROM_HEADERS;

#ifdef _WIN64
typedef IMAGE_NT_HEADERS64 IMAGE_NT_HEADERS;
typedef PIMAGE_NT_HEADERS64 PIMAGE_NT_HEADERS;
#else
typedef IMAGE_NT_HEADERS32 IMAGE_NT_HEADERS;
typedef PIMAGE_NT_HEADERS32 PIMAGE_NT_HEADERS;
#endif

// IMAGE_FIRST_SECTION doesn‘t need 32/64 versions since the file header is the same either way.

#define IMAGE_FIRST_SECTION( ntheader ) ((PIMAGE_SECTION_HEADER) \
((ULONG_PTR)(ntheader) + \
FIELD_OFFSET( IMAGE_NT_HEADERS, OptionalHeader ) + \
((ntheader))->FileHeader.SizeOfOptionalHeader \
))

// Subsystem Values

#define IMAGE_SUBSYSTEM_UNKNOWN 0 // Unknown subsystem.
#define IMAGE_SUBSYSTEM_NATIVE 1 // Image doesn‘t require a subsystem.
#define IMAGE_SUBSYSTEM_WINDOWS_GUI 2 // Image runs in the Windows GUI subsystem.
#define IMAGE_SUBSYSTEM_WINDOWS_CUI 3 // Image runs in the Windows character subsystem.
#define IMAGE_SUBSYSTEM_OS2_CUI 5 // image runs in the OS/2 character subsystem.
#define IMAGE_SUBSYSTEM_POSIX_CUI 7 // image runs in the Posix character subsystem.
#define IMAGE_SUBSYSTEM_NATIVE_WINDOWS 8 // image is a native Win9x driver.
#define IMAGE_SUBSYSTEM_WINDOWS_CE_GUI 9 // Image runs in the Windows CE subsystem.
#define IMAGE_SUBSYSTEM_EFI_APPLICATION 10 //
#define IMAGE_SUBSYSTEM_EFI_BOOT_SERVICE_DRIVER 11 //
#define IMAGE_SUBSYSTEM_EFI_RUNTIME_DRIVER 12 //
#define IMAGE_SUBSYSTEM_EFI_ROM 13
#define IMAGE_SUBSYSTEM_XBOX 14
#define IMAGE_SUBSYSTEM_WINDOWS_BOOT_APPLICATION 16

// DllCharacteristics Entries

// IMAGE_LIBRARY_PROCESS_INIT 0x0001 // Reserved.
// IMAGE_LIBRARY_PROCESS_TERM 0x0002 // Reserved.
// IMAGE_LIBRARY_THREAD_INIT 0x0004 // Reserved.
// IMAGE_LIBRARY_THREAD_TERM 0x0008 // Reserved.
#define IMAGE_DLLCHARACTERISTICS_DYNAMIC_BASE 0x0040 // DLL can move.
#define IMAGE_DLLCHARACTERISTICS_FORCE_INTEGRITY 0x0080 // Code Integrity Image
#define IMAGE_DLLCHARACTERISTICS_NX_COMPAT 0x0100 // Image is NX compatible
#define IMAGE_DLLCHARACTERISTICS_NO_ISOLATION 0x0200 // Image understands isolation and doesn‘t want it
#define IMAGE_DLLCHARACTERISTICS_NO_SEH 0x0400 // Image does not use SEH. No SE handler may reside in this image
#define IMAGE_DLLCHARACTERISTICS_NO_BIND 0x0800 // Do not bind this image.
// 0x1000 // Reserved.
#define IMAGE_DLLCHARACTERISTICS_WDM_DRIVER 0x2000 // Driver uses WDM model
// 0x4000 // Reserved.
#define IMAGE_DLLCHARACTERISTICS_TERMINAL_SERVER_AWARE 0x8000

// Directory Entries

#define IMAGE_DIRECTORY_ENTRY_EXPORT 0 // Export Directory
#define IMAGE_DIRECTORY_ENTRY_IMPORT 1 // Import Directory
#define IMAGE_DIRECTORY_ENTRY_RESOURCE 2 // Resource Directory
#define IMAGE_DIRECTORY_ENTRY_EXCEPTION 3 // Exception Directory
#define IMAGE_DIRECTORY_ENTRY_SECURITY 4 // Security Directory
#define IMAGE_DIRECTORY_ENTRY_BASERELOC 5 // Base Relocation Table
#define IMAGE_DIRECTORY_ENTRY_DEBUG 6 // Debug Directory
// IMAGE_DIRECTORY_ENTRY_COPYRIGHT 7 // (X86 usage)
#define IMAGE_DIRECTORY_ENTRY_ARCHITECTURE 7 // Architecture Specific Data
#define IMAGE_DIRECTORY_ENTRY_GLOBALPTR 8 // RVA of GP
#define IMAGE_DIRECTORY_ENTRY_TLS 9 // TLS Directory
#define IMAGE_DIRECTORY_ENTRY_LOAD_CONFIG 10 // Load Configuration Directory
#define IMAGE_DIRECTORY_ENTRY_BOUND_IMPORT 11 // Bound Import Directory in headers
#define IMAGE_DIRECTORY_ENTRY_IAT 12 // Import Address Table
#define IMAGE_DIRECTORY_ENTRY_DELAY_IMPORT 13 // Delay Load Import Descriptors
#define IMAGE_DIRECTORY_ENTRY_COM_DESCRIPTOR 14 // COM Runtime descriptor

//
// Non-COFF Object file header
//

typedef struct ANON_OBJECT_HEADER {
WORD Sig1; // Must be IMAGE_FILE_MACHINE_UNKNOWN
WORD Sig2; // Must be 0xffff
WORD Version; // >= 1 (implies the CLSID field is present)
WORD Machine;
DWORD TimeDateStamp;
CLSID ClassID; // Used to invoke CoCreateInstance
DWORD SizeOfData; // Size of data that follows the header
} ANON_OBJECT_HEADER;

typedef struct ANON_OBJECT_HEADER_V2 {
WORD Sig1; // Must be IMAGE_FILE_MACHINE_UNKNOWN
WORD Sig2; // Must be 0xffff
WORD Version; // >= 2 (implies the Flags field is present - otherwise V1)
WORD Machine;
DWORD TimeDateStamp;
CLSID ClassID; // Used to invoke CoCreateInstance
DWORD SizeOfData; // Size of data that follows the header
DWORD Flags; // 0x1 -> contains metadata
DWORD MetaDataSize; // Size of CLR metadata
DWORD MetaDataOffset; // Offset of CLR metadata
} ANON_OBJECT_HEADER_V2;

typedef struct ANON_OBJECT_HEADER_BIGOBJ {
/* same as ANON_OBJECT_HEADER_V2 */
WORD Sig1; // Must be IMAGE_FILE_MACHINE_UNKNOWN
WORD Sig2; // Must be 0xffff
WORD Version; // >= 2 (implies the Flags field is present)
WORD Machine; // Actual machine - IMAGE_FILE_MACHINE_xxx
DWORD TimeDateStamp;
CLSID ClassID; // {D1BAA1C7-BAEE-4ba9-AF20-FAF66AA4DCB8}
DWORD SizeOfData; // Size of data that follows the header
DWORD Flags; // 0x1 -> contains metadata
DWORD MetaDataSize; // Size of CLR metadata
DWORD MetaDataOffset; // Offset of CLR metadata

/* bigobj specifics */
DWORD NumberOfSections; // extended from WORD
DWORD PointerToSymbolTable;
DWORD NumberOfSymbols;
} ANON_OBJECT_HEADER_BIGOBJ;

//
// Section header format.
//

#define IMAGE_SIZEOF_SHORT_NAME 8

typedef struct _IMAGE_SECTION_HEADER {
BYTE Name[IMAGE_SIZEOF_SHORT_NAME];
union {
DWORD PhysicalAddress;
DWORD VirtualSize;
} Misc;
DWORD VirtualAddress;
DWORD SizeOfRawData;
DWORD PointerToRawData;
DWORD PointerToRelocations;
DWORD PointerToLinenumbers;
WORD NumberOfRelocations;
WORD NumberOfLinenumbers;
DWORD Characteristics;
} IMAGE_SECTION_HEADER, *PIMAGE_SECTION_HEADER;

#define IMAGE_SIZEOF_SECTION_HEADER 40

//
// Section characteristics.
//
// IMAGE_SCN_TYPE_REG 0x00000000 // Reserved.
// IMAGE_SCN_TYPE_DSECT 0x00000001 // Reserved.
// IMAGE_SCN_TYPE_NOLOAD 0x00000002 // Reserved.
// IMAGE_SCN_TYPE_GROUP 0x00000004 // Reserved.
#define IMAGE_SCN_TYPE_NO_PAD 0x00000008 // Reserved.
// IMAGE_SCN_TYPE_COPY 0x00000010 // Reserved.

#define IMAGE_SCN_CNT_CODE 0x00000020 // Section contains code.
#define IMAGE_SCN_CNT_INITIALIZED_DATA 0x00000040 // Section contains initialized data.
#define IMAGE_SCN_CNT_UNINITIALIZED_DATA 0x00000080 // Section contains uninitialized data.

#define IMAGE_SCN_LNK_OTHER 0x00000100 // Reserved.
#define IMAGE_SCN_LNK_INFO 0x00000200 // Section contains comments or some other type of information.
// IMAGE_SCN_TYPE_OVER 0x00000400 // Reserved.
#define IMAGE_SCN_LNK_REMOVE 0x00000800 // Section contents will not become part of image.
#define IMAGE_SCN_LNK_COMDAT 0x00001000 // Section contents comdat.
// 0x00002000 // Reserved.
// IMAGE_SCN_MEM_PROTECTED - Obsolete 0x00004000
#define IMAGE_SCN_NO_DEFER_SPEC_EXC 0x00004000 // Reset speculative exceptions handling bits in the TLB entries for this section.
#define IMAGE_SCN_GPREL 0x00008000 // Section content can be accessed relative to GP
#define IMAGE_SCN_MEM_FARDATA 0x00008000
// IMAGE_SCN_MEM_SYSHEAP - Obsolete 0x00010000
#define IMAGE_SCN_MEM_PURGEABLE 0x00020000
#define IMAGE_SCN_MEM_16BIT 0x00020000
#define IMAGE_SCN_MEM_LOCKED 0x00040000
#define IMAGE_SCN_MEM_PRELOAD 0x00080000

#define IMAGE_SCN_ALIGN_1BYTES 0x00100000 //
#define IMAGE_SCN_ALIGN_2BYTES 0x00200000 //
#define IMAGE_SCN_ALIGN_4BYTES 0x00300000 //
#define IMAGE_SCN_ALIGN_8BYTES 0x00400000 //
#define IMAGE_SCN_ALIGN_16BYTES 0x00500000 // Default alignment if no others are specified.
#define IMAGE_SCN_ALIGN_32BYTES 0x00600000 //
#define IMAGE_SCN_ALIGN_64BYTES 0x00700000 //
#define IMAGE_SCN_ALIGN_128BYTES 0x00800000 //
#define IMAGE_SCN_ALIGN_256BYTES 0x00900000 //
#define IMAGE_SCN_ALIGN_512BYTES 0x00A00000 //
#define IMAGE_SCN_ALIGN_1024BYTES 0x00B00000 //
#define IMAGE_SCN_ALIGN_2048BYTES 0x00C00000 //
#define IMAGE_SCN_ALIGN_4096BYTES 0x00D00000 //
#define IMAGE_SCN_ALIGN_8192BYTES 0x00E00000 //
// Unused 0x00F00000
#define IMAGE_SCN_ALIGN_MASK 0x00F00000

#define IMAGE_SCN_LNK_NRELOC_OVFL 0x01000000 // Section contains extended relocations.
#define IMAGE_SCN_MEM_DISCARDABLE 0x02000000 // Section can be discarded.
#define IMAGE_SCN_MEM_NOT_CACHED 0x04000000 // Section is not cachable.
#define IMAGE_SCN_MEM_NOT_PAGED 0x08000000 // Section is not pageable.
#define IMAGE_SCN_MEM_SHARED 0x10000000 // Section is shareable.
#define IMAGE_SCN_MEM_EXECUTE 0x20000000 // Section is executable.
#define IMAGE_SCN_MEM_READ 0x40000000 // Section is readable.
#define IMAGE_SCN_MEM_WRITE 0x80000000 // Section is writeable.

//
// TLS Chaacteristic Flags
//
#define IMAGE_SCN_SCALE_INDEX 0x00000001 // Tls index is scaled

#ifndef _MAC
#include "pshpack2.h" // Symbols, relocs, and linenumbers are 2 byte packed
#endif

//
// Symbol format.
//

typedef struct _IMAGE_SYMBOL {
union {
BYTE ShortName[8];
struct {
DWORD Short; // if 0, use LongName
DWORD Long; // offset into string table
} Name;
DWORD LongName[2]; // PBYTE [2]
} N;
DWORD Value;
SHORT SectionNumber;
WORD Type;
BYTE StorageClass;
BYTE NumberOfAuxSymbols;
} IMAGE_SYMBOL;
typedef IMAGE_SYMBOL UNALIGNED *PIMAGE_SYMBOL;

#define IMAGE_SIZEOF_SYMBOL 18

typedef struct _IMAGE_SYMBOL_EX {
union {
BYTE ShortName[8];
struct {
DWORD Short; // if 0, use LongName
DWORD Long; // offset into string table
} Name;
DWORD LongName[2]; // PBYTE [2]
} N;
DWORD Value;
LONG SectionNumber;
WORD Type;
BYTE StorageClass;
BYTE NumberOfAuxSymbols;
} IMAGE_SYMBOL_EX;
typedef IMAGE_SYMBOL_EX UNALIGNED *PIMAGE_SYMBOL_EX;

//
// Section values.
//
// Symbols have a section number of the section in which they are
// defined. Otherwise, section numbers have the following meanings:
//

#define IMAGE_SYM_UNDEFINED (SHORT)0 // Symbol is undefined or is common.
#define IMAGE_SYM_ABSOLUTE (SHORT)-1 // Symbol is an absolute value.
#define IMAGE_SYM_DEBUG (SHORT)-2 // Symbol is a special debug item.
#define IMAGE_SYM_SECTION_MAX 0xFEFF // Values 0xFF00-0xFFFF are special
#define IMAGE_SYM_SECTION_MAX_EX MAXLONG

//
// Type (fundamental) values.
//

#define IMAGE_SYM_TYPE_NULL 0x0000 // no type.
#define IMAGE_SYM_TYPE_VOID 0x0001 //
#define IMAGE_SYM_TYPE_CHAR 0x0002 // type character.
#define IMAGE_SYM_TYPE_SHORT 0x0003 // type short integer.
#define IMAGE_SYM_TYPE_INT 0x0004 //
#define IMAGE_SYM_TYPE_LONG 0x0005 //
#define IMAGE_SYM_TYPE_FLOAT 0x0006 //
#define IMAGE_SYM_TYPE_DOUBLE 0x0007 //
#define IMAGE_SYM_TYPE_STRUCT 0x0008 //
#define IMAGE_SYM_TYPE_UNION 0x0009 //
#define IMAGE_SYM_TYPE_ENUM 0x000A // enumeration.
#define IMAGE_SYM_TYPE_MOE 0x000B // member of enumeration.
#define IMAGE_SYM_TYPE_BYTE 0x000C //
#define IMAGE_SYM_TYPE_WORD 0x000D //
#define IMAGE_SYM_TYPE_UINT 0x000E //
#define IMAGE_SYM_TYPE_DWORD 0x000F //
#define IMAGE_SYM_TYPE_PCODE 0x8000 //
//
// Type (derived) values.
//

#define IMAGE_SYM_DTYPE_NULL 0 // no derived type.
#define IMAGE_SYM_DTYPE_POINTER 1 // pointer.
#define IMAGE_SYM_DTYPE_FUNCTION 2 // function.
#define IMAGE_SYM_DTYPE_ARRAY 3 // array.

//
// Storage classes.
//
#define IMAGE_SYM_CLASS_END_OF_FUNCTION (BYTE )-1
#define IMAGE_SYM_CLASS_NULL 0x0000
#define IMAGE_SYM_CLASS_AUTOMATIC 0x0001
#define IMAGE_SYM_CLASS_EXTERNAL 0x0002
#define IMAGE_SYM_CLASS_STATIC 0x0003
#define IMAGE_SYM_CLASS_REGISTER 0x0004
#define IMAGE_SYM_CLASS_EXTERNAL_DEF 0x0005
#define IMAGE_SYM_CLASS_LABEL 0x0006
#define IMAGE_SYM_CLASS_UNDEFINED_LABEL 0x0007
#define IMAGE_SYM_CLASS_MEMBER_OF_STRUCT 0x0008
#define IMAGE_SYM_CLASS_ARGUMENT 0x0009
#define IMAGE_SYM_CLASS_STRUCT_TAG 0x000A
#define IMAGE_SYM_CLASS_MEMBER_OF_UNION 0x000B
#define IMAGE_SYM_CLASS_UNION_TAG 0x000C
#define IMAGE_SYM_CLASS_TYPE_DEFINITION 0x000D
#define IMAGE_SYM_CLASS_UNDEFINED_STATIC 0x000E
#define IMAGE_SYM_CLASS_ENUM_TAG 0x000F
#define IMAGE_SYM_CLASS_MEMBER_OF_ENUM 0x0010
#define IMAGE_SYM_CLASS_REGISTER_PARAM 0x0011
#define IMAGE_SYM_CLASS_BIT_FIELD 0x0012

#define IMAGE_SYM_CLASS_FAR_EXTERNAL 0x0044 //

#define IMAGE_SYM_CLASS_BLOCK 0x0064
#define IMAGE_SYM_CLASS_FUNCTION 0x0065
#define IMAGE_SYM_CLASS_END_OF_STRUCT 0x0066
#define IMAGE_SYM_CLASS_FILE 0x0067
// new
#define IMAGE_SYM_CLASS_SECTION 0x0068
#define IMAGE_SYM_CLASS_WEAK_EXTERNAL 0x0069

#define IMAGE_SYM_CLASS_CLR_TOKEN 0x006B

// type packing constants

#define N_BTMASK 0x000F
#define N_TMASK 0x0030
#define N_TMASK1 0x00C0
#define N_TMASK2 0x00F0
#define N_BTSHFT 4
#define N_TSHIFT 2
// MACROS

// Basic Type of x
#define BTYPE(x) ((x) & N_BTMASK)

// Is x a pointer?
#ifndef ISPTR
#define ISPTR(x) (((x) & N_TMASK) == (IMAGE_SYM_DTYPE_POINTER << N_BTSHFT))
#endif

// Is x a function?
#ifndef ISFCN
#define ISFCN(x) (((x) & N_TMASK) == (IMAGE_SYM_DTYPE_FUNCTION << N_BTSHFT))
#endif

// Is x an array?

#ifndef ISARY
#define ISARY(x) (((x) & N_TMASK) == (IMAGE_SYM_DTYPE_ARRAY << N_BTSHFT))
#endif

// Is x a structure, union, or enumeration TAG?
#ifndef ISTAG
#define ISTAG(x) ((x)==IMAGE_SYM_CLASS_STRUCT_TAG || (x)==IMAGE_SYM_CLASS_UNION_TAG || (x)==IMAGE_SYM_CLASS_ENUM_TAG)
#endif

#ifndef INCREF
#define INCREF(x) ((((x)&~N_BTMASK)<<N_TSHIFT)|(IMAGE_SYM_DTYPE_POINTER<<N_BTSHFT)|((x)&N_BTMASK))
#endif
#ifndef DECREF
#define DECREF(x) ((((x)>>N_TSHIFT)&~N_BTMASK)|((x)&N_BTMASK))
#endif

#include <pshpack2.h>

typedef struct IMAGE_AUX_SYMBOL_TOKEN_DEF {
BYTE bAuxType; // IMAGE_AUX_SYMBOL_TYPE
BYTE bReserved; // Must be 0
DWORD SymbolTableIndex;
BYTE rgbReserved[12]; // Must be 0
} IMAGE_AUX_SYMBOL_TOKEN_DEF;

typedef IMAGE_AUX_SYMBOL_TOKEN_DEF UNALIGNED *PIMAGE_AUX_SYMBOL_TOKEN_DEF;

#include <poppack.h>

//
// Auxiliary entry format.
//

typedef union _IMAGE_AUX_SYMBOL {
struct {
DWORD TagIndex; // struct, union, or enum tag index
union {
struct {
WORD Linenumber; // declaration line number
WORD Size; // size of struct, union, or enum
} LnSz;
DWORD TotalSize;
} Misc;
union {
struct { // if ISFCN, tag, or .bb
DWORD PointerToLinenumber;
DWORD PointerToNextFunction;
} Function;
struct { // if ISARY, up to 4 dimen.
WORD Dimension[4];
} Array;
} FcnAry;
WORD TvIndex; // tv index
} Sym;
struct {
BYTE Name[IMAGE_SIZEOF_SYMBOL];
} File;
struct {
DWORD Length; // section length
WORD NumberOfRelocations; // number of relocation entries
WORD NumberOfLinenumbers; // number of line numbers
DWORD CheckSum; // checksum for communal
SHORT Number; // section number to associate with
BYTE Selection; // communal selection type
BYTE bReserved;
SHORT HighNumber; // high bits of the section number
} Section;
IMAGE_AUX_SYMBOL_TOKEN_DEF TokenDef;
struct {
DWORD crc;
BYTE rgbReserved[14];
} CRC;
} IMAGE_AUX_SYMBOL;
typedef IMAGE_AUX_SYMBOL UNALIGNED *PIMAGE_AUX_SYMBOL;

typedef union _IMAGE_AUX_SYMBOL_EX {
struct {
DWORD WeakDefaultSymIndex; // the weak extern default symbol index
DWORD WeakSearchType;
BYTE rgbReserved[12];
} Sym;
struct {
BYTE Name[sizeof(IMAGE_SYMBOL_EX)];
} File;
struct {
DWORD Length; // section length
WORD NumberOfRelocations; // number of relocation entries
WORD NumberOfLinenumbers; // number of line numbers
DWORD CheckSum; // checksum for communal
SHORT Number; // section number to associate with
BYTE Selection; // communal selection type
BYTE bReserved;
SHORT HighNumber; // high bits of the section number
BYTE rgbReserved[2];
} Section;
struct{
IMAGE_AUX_SYMBOL_TOKEN_DEF TokenDef;
BYTE rgbReserved[2];
};
struct {
DWORD crc;
BYTE rgbReserved[16];
} CRC;
} IMAGE_AUX_SYMBOL_EX;
typedef IMAGE_AUX_SYMBOL_EX UNALIGNED *PIMAGE_AUX_SYMBOL_EX;

typedef enum IMAGE_AUX_SYMBOL_TYPE {
IMAGE_AUX_SYMBOL_TYPE_TOKEN_DEF = 1,
} IMAGE_AUX_SYMBOL_TYPE;


//
// Communal selection types.
//

#define IMAGE_COMDAT_SELECT_NODUPLICATES 1
#define IMAGE_COMDAT_SELECT_ANY 2
#define IMAGE_COMDAT_SELECT_SAME_SIZE 3
#define IMAGE_COMDAT_SELECT_EXACT_MATCH 4
#define IMAGE_COMDAT_SELECT_ASSOCIATIVE 5
#define IMAGE_COMDAT_SELECT_LARGEST 6
#define IMAGE_COMDAT_SELECT_NEWEST 7

#define IMAGE_WEAK_EXTERN_SEARCH_NOLIBRARY 1
#define IMAGE_WEAK_EXTERN_SEARCH_LIBRARY 2
#define IMAGE_WEAK_EXTERN_SEARCH_ALIAS 3

//
// Relocation format.
//

typedef struct _IMAGE_RELOCATION {
union {
DWORD VirtualAddress;
DWORD RelocCount; // Set to the real count when IMAGE_SCN_LNK_NRELOC_OVFL is set
} DUMMYUNIONNAME;
DWORD SymbolTableIndex;
WORD Type;
} IMAGE_RELOCATION;
typedef IMAGE_RELOCATION UNALIGNED *PIMAGE_RELOCATION;

//
// I386 relocation types.
//
#define IMAGE_REL_I386_ABSOLUTE 0x0000 // Reference is absolute, no relocation is necessary
#define IMAGE_REL_I386_DIR16 0x0001 // Direct 16-bit reference to the symbols virtual address
#define IMAGE_REL_I386_REL16 0x0002 // PC-relative 16-bit reference to the symbols virtual address
#define IMAGE_REL_I386_DIR32 0x0006 // Direct 32-bit reference to the symbols virtual address
#define IMAGE_REL_I386_DIR32NB 0x0007 // Direct 32-bit reference to the symbols virtual address, base not included
#define IMAGE_REL_I386_SEG12 0x0009 // Direct 16-bit reference to the segment-selector bits of a 32-bit virtual address
#define IMAGE_REL_I386_SECTION 0x000A
#define IMAGE_REL_I386_SECREL 0x000B
#define IMAGE_REL_I386_TOKEN 0x000C // clr token
#define IMAGE_REL_I386_SECREL7 0x000D // 7 bit offset from base of section containing target
#define IMAGE_REL_I386_REL32 0x0014 // PC-relative 32-bit reference to the symbols virtual address

//
// MIPS relocation types.
//
#define IMAGE_REL_MIPS_ABSOLUTE 0x0000 // Reference is absolute, no relocation is necessary
#define IMAGE_REL_MIPS_REFHALF 0x0001
#define IMAGE_REL_MIPS_REFWORD 0x0002
#define IMAGE_REL_MIPS_JMPADDR 0x0003
#define IMAGE_REL_MIPS_REFHI 0x0004
#define IMAGE_REL_MIPS_REFLO 0x0005
#define IMAGE_REL_MIPS_GPREL 0x0006
#define IMAGE_REL_MIPS_LITERAL 0x0007
#define IMAGE_REL_MIPS_SECTION 0x000A
#define IMAGE_REL_MIPS_SECREL 0x000B
#define IMAGE_REL_MIPS_SECRELLO 0x000C // Low 16-bit section relative referemce (used for >32k TLS)
#define IMAGE_REL_MIPS_SECRELHI 0x000D // High 16-bit section relative reference (used for >32k TLS)
#define IMAGE_REL_MIPS_TOKEN 0x000E // clr token
#define IMAGE_REL_MIPS_JMPADDR16 0x0010
#define IMAGE_REL_MIPS_REFWORDNB 0x0022
#define IMAGE_REL_MIPS_PAIR 0x0025

//
// Alpha Relocation types.
//
#define IMAGE_REL_ALPHA_ABSOLUTE 0x0000
#define IMAGE_REL_ALPHA_REFLONG 0x0001
#define IMAGE_REL_ALPHA_REFQUAD 0x0002
#define IMAGE_REL_ALPHA_GPREL32 0x0003
#define IMAGE_REL_ALPHA_LITERAL 0x0004
#define IMAGE_REL_ALPHA_LITUSE 0x0005
#define IMAGE_REL_ALPHA_GPDISP 0x0006
#define IMAGE_REL_ALPHA_BRADDR 0x0007
#define IMAGE_REL_ALPHA_HINT 0x0008
#define IMAGE_REL_ALPHA_INLINE_REFLONG 0x0009
#define IMAGE_REL_ALPHA_REFHI 0x000A
#define IMAGE_REL_ALPHA_REFLO 0x000B
#define IMAGE_REL_ALPHA_PAIR 0x000C
#define IMAGE_REL_ALPHA_MATCH 0x000D
#define IMAGE_REL_ALPHA_SECTION 0x000E
#define IMAGE_REL_ALPHA_SECREL 0x000F
#define IMAGE_REL_ALPHA_REFLONGNB 0x0010
#define IMAGE_REL_ALPHA_SECRELLO 0x0011 // Low 16-bit section relative reference
#define IMAGE_REL_ALPHA_SECRELHI 0x0012 // High 16-bit section relative reference
#define IMAGE_REL_ALPHA_REFQ3 0x0013 // High 16 bits of 48 bit reference
#define IMAGE_REL_ALPHA_REFQ2 0x0014 // Middle 16 bits of 48 bit reference
#define IMAGE_REL_ALPHA_REFQ1 0x0015 // Low 16 bits of 48 bit reference
#define IMAGE_REL_ALPHA_GPRELLO 0x0016 // Low 16-bit GP relative reference
#define IMAGE_REL_ALPHA_GPRELHI 0x0017 // High 16-bit GP relative reference

//
// IBM PowerPC relocation types.
//
#define IMAGE_REL_PPC_ABSOLUTE 0x0000 // NOP
#define IMAGE_REL_PPC_ADDR64 0x0001 // 64-bit address
#define IMAGE_REL_PPC_ADDR32 0x0002 // 32-bit address
#define IMAGE_REL_PPC_ADDR24 0x0003 // 26-bit address, shifted left 2 (branch absolute)
#define IMAGE_REL_PPC_ADDR16 0x0004 // 16-bit address
#define IMAGE_REL_PPC_ADDR14 0x0005 // 16-bit address, shifted left 2 (load doubleword)
#define IMAGE_REL_PPC_REL24 0x0006 // 26-bit PC-relative offset, shifted left 2 (branch relative)
#define IMAGE_REL_PPC_REL14 0x0007 // 16-bit PC-relative offset, shifted left 2 (br cond relative)
#define IMAGE_REL_PPC_TOCREL16 0x0008 // 16-bit offset from TOC base
#define IMAGE_REL_PPC_TOCREL14 0x0009 // 16-bit offset from TOC base, shifted left 2 (load doubleword)

#define IMAGE_REL_PPC_ADDR32NB 0x000A // 32-bit addr w/o image base
#define IMAGE_REL_PPC_SECREL 0x000B // va of containing section (as in an image sectionhdr)
#define IMAGE_REL_PPC_SECTION 0x000C // sectionheader number
#define IMAGE_REL_PPC_IFGLUE 0x000D // substitute TOC restore instruction iff symbol is glue code
#define IMAGE_REL_PPC_IMGLUE 0x000E // symbol is glue code; virtual address is TOC restore instruction
#define IMAGE_REL_PPC_SECREL16 0x000F // va of containing section (limited to 16 bits)
#define IMAGE_REL_PPC_REFHI 0x0010
#define IMAGE_REL_PPC_REFLO 0x0011
#define IMAGE_REL_PPC_PAIR 0x0012
#define IMAGE_REL_PPC_SECRELLO 0x0013 // Low 16-bit section relative reference (used for >32k TLS)
#define IMAGE_REL_PPC_SECRELHI 0x0014 // High 16-bit section relative reference (used for >32k TLS)
#define IMAGE_REL_PPC_GPREL 0x0015
#define IMAGE_REL_PPC_TOKEN 0x0016 // clr token

#define IMAGE_REL_PPC_TYPEMASK 0x00FF // mask to isolate above values in IMAGE_RELOCATION.Type

// Flag bits in IMAGE_RELOCATION.TYPE

#define IMAGE_REL_PPC_NEG 0x0100 // subtract reloc value rather than adding it
#define IMAGE_REL_PPC_BRTAKEN 0x0200 // fix branch prediction bit to predict branch taken
#define IMAGE_REL_PPC_BRNTAKEN 0x0400 // fix branch prediction bit to predict branch not taken
#define IMAGE_REL_PPC_TOCDEFN 0x0800 // toc slot defined in file (or, data in toc)

//
// Hitachi SH3 relocation types.
//
#define IMAGE_REL_SH3_ABSOLUTE 0x0000 // No relocation
#define IMAGE_REL_SH3_DIRECT16 0x0001 // 16 bit direct
#define IMAGE_REL_SH3_DIRECT32 0x0002 // 32 bit direct
#define IMAGE_REL_SH3_DIRECT8 0x0003 // 8 bit direct, -128..255
#define IMAGE_REL_SH3_DIRECT8_WORD 0x0004 // 8 bit direct .W (0 ext.)
#define IMAGE_REL_SH3_DIRECT8_LONG 0x0005 // 8 bit direct .L (0 ext.)
#define IMAGE_REL_SH3_DIRECT4 0x0006 // 4 bit direct (0 ext.)
#define IMAGE_REL_SH3_DIRECT4_WORD 0x0007 // 4 bit direct .W (0 ext.)
#define IMAGE_REL_SH3_DIRECT4_LONG 0x0008 // 4 bit direct .L (0 ext.)
#define IMAGE_REL_SH3_PCREL8_WORD 0x0009 // 8 bit PC relative .W
#define IMAGE_REL_SH3_PCREL8_LONG 0x000A // 8 bit PC relative .L
#define IMAGE_REL_SH3_PCREL12_WORD 0x000B // 12 LSB PC relative .W
#define IMAGE_REL_SH3_STARTOF_SECTION 0x000C // Start of EXE section
#define IMAGE_REL_SH3_SIZEOF_SECTION 0x000D // Size of EXE section
#define IMAGE_REL_SH3_SECTION 0x000E // Section table index
#define IMAGE_REL_SH3_SECREL 0x000F // Offset within section
#define IMAGE_REL_SH3_DIRECT32_NB 0x0010 // 32 bit direct not based
#define IMAGE_REL_SH3_GPREL4_LONG 0x0011 // GP-relative addressing
#define IMAGE_REL_SH3_TOKEN 0x0012 // clr token
#define IMAGE_REL_SHM_PCRELPT 0x0013 // Offset from current
// instruction in longwords
// if not NOMODE, insert the
// inverse of the low bit at
// bit 32 to select PTA/PTB
#define IMAGE_REL_SHM_REFLO 0x0014 // Low bits of 32-bit address
#define IMAGE_REL_SHM_REFHALF 0x0015 // High bits of 32-bit address
#define IMAGE_REL_SHM_RELLO 0x0016 // Low bits of relative reference
#define IMAGE_REL_SHM_RELHALF 0x0017 // High bits of relative reference
#define IMAGE_REL_SHM_PAIR 0x0018 // offset operand for relocation

#define IMAGE_REL_SH_NOMODE 0x8000 // relocation ignores section mode


#define IMAGE_REL_ARM_ABSOLUTE 0x0000 // No relocation required
#define IMAGE_REL_ARM_ADDR32 0x0001 // 32 bit address
#define IMAGE_REL_ARM_ADDR32NB 0x0002 // 32 bit address w/o image base
#define IMAGE_REL_ARM_BRANCH24 0x0003 // 24 bit offset << 2 & sign ext.
#define IMAGE_REL_ARM_BRANCH11 0x0004 // Thumb: 2 11 bit offsets
#define IMAGE_REL_ARM_TOKEN 0x0005 // clr token
#define IMAGE_REL_ARM_GPREL12 0x0006 // GP-relative addressing (ARM)
#define IMAGE_REL_ARM_GPREL7 0x0007 // GP-relative addressing (Thumb)
#define IMAGE_REL_ARM_BLX24 0x0008
#define IMAGE_REL_ARM_BLX11 0x0009
#define IMAGE_REL_ARM_SECTION 0x000E // Section table index
#define IMAGE_REL_ARM_SECREL 0x000F // Offset within section

#define IMAGE_REL_AM_ABSOLUTE 0x0000
#define IMAGE_REL_AM_ADDR32 0x0001
#define IMAGE_REL_AM_ADDR32NB 0x0002
#define IMAGE_REL_AM_CALL32 0x0003
#define IMAGE_REL_AM_FUNCINFO 0x0004
#define IMAGE_REL_AM_REL32_1 0x0005
#define IMAGE_REL_AM_REL32_2 0x0006
#define IMAGE_REL_AM_SECREL 0x0007
#define IMAGE_REL_AM_SECTION 0x0008
#define IMAGE_REL_AM_TOKEN 0x0009

//
// x64 relocations
//
#define IMAGE_REL_AMD64_ABSOLUTE 0x0000 // Reference is absolute, no relocation is necessary
#define IMAGE_REL_AMD64_ADDR64 0x0001 // 64-bit address (VA).
#define IMAGE_REL_AMD64_ADDR32 0x0002 // 32-bit address (VA).
#define IMAGE_REL_AMD64_ADDR32NB 0x0003 // 32-bit address w/o image base (RVA).
#define IMAGE_REL_AMD64_REL32 0x0004 // 32-bit relative address from byte following reloc
#define IMAGE_REL_AMD64_REL32_1 0x0005 // 32-bit relative address from byte distance 1 from reloc
#define IMAGE_REL_AMD64_REL32_2 0x0006 // 32-bit relative address from byte distance 2 from reloc
#define IMAGE_REL_AMD64_REL32_3 0x0007 // 32-bit relative address from byte distance 3 from reloc
#define IMAGE_REL_AMD64_REL32_4 0x0008 // 32-bit relative address from byte distance 4 from reloc
#define IMAGE_REL_AMD64_REL32_5 0x0009 // 32-bit relative address from byte distance 5 from reloc
#define IMAGE_REL_AMD64_SECTION 0x000A // Section index
#define IMAGE_REL_AMD64_SECREL 0x000B // 32 bit offset from base of section containing target
#define IMAGE_REL_AMD64_SECREL7 0x000C // 7 bit unsigned offset from base of section containing target
#define IMAGE_REL_AMD64_TOKEN 0x000D // 32 bit metadata token
#define IMAGE_REL_AMD64_SREL32 0x000E // 32 bit signed span-dependent value emitted into object
#define IMAGE_REL_AMD64_PAIR 0x000F
#define IMAGE_REL_AMD64_SSPAN32 0x0010 // 32 bit signed span-dependent value applied at link time

//
// IA64 relocation types.
//
#define IMAGE_REL_IA64_ABSOLUTE 0x0000
#define IMAGE_REL_IA64_IMM14 0x0001
#define IMAGE_REL_IA64_IMM22 0x0002
#define IMAGE_REL_IA64_IMM64 0x0003
#define IMAGE_REL_IA64_DIR32 0x0004
#define IMAGE_REL_IA64_DIR64 0x0005
#define IMAGE_REL_IA64_PCREL21B 0x0006
#define IMAGE_REL_IA64_PCREL21M 0x0007
#define IMAGE_REL_IA64_PCREL21F 0x0008
#define IMAGE_REL_IA64_GPREL22 0x0009
#define IMAGE_REL_IA64_LTOFF22 0x000A
#define IMAGE_REL_IA64_SECTION 0x000B
#define IMAGE_REL_IA64_SECREL22 0x000C
#define IMAGE_REL_IA64_SECREL64I 0x000D
#define IMAGE_REL_IA64_SECREL32 0x000E
//
#define IMAGE_REL_IA64_DIR32NB 0x0010
#define IMAGE_REL_IA64_SREL14 0x0011
#define IMAGE_REL_IA64_SREL22 0x0012
#define IMAGE_REL_IA64_SREL32 0x0013
#define IMAGE_REL_IA64_UREL32 0x0014
#define IMAGE_REL_IA64_PCREL60X 0x0015 // This is always a BRL and never converted
#define IMAGE_REL_IA64_PCREL60B 0x0016 // If possible, convert to MBB bundle with NOP.B in slot 1
#define IMAGE_REL_IA64_PCREL60F 0x0017 // If possible, convert to MFB bundle with NOP.F in slot 1
#define IMAGE_REL_IA64_PCREL60I 0x0018 // If possible, convert to MIB bundle with NOP.I in slot 1
#define IMAGE_REL_IA64_PCREL60M 0x0019 // If possible, convert to MMB bundle with NOP.M in slot 1
#define IMAGE_REL_IA64_IMMGPREL64 0x001A
#define IMAGE_REL_IA64_TOKEN 0x001B // clr token
#define IMAGE_REL_IA64_GPREL32 0x001C
#define IMAGE_REL_IA64_ADDEND 0x001F

//
// CEF relocation types.
//
#define IMAGE_REL_CEF_ABSOLUTE 0x0000 // Reference is absolute, no relocation is necessary
#define IMAGE_REL_CEF_ADDR32 0x0001 // 32-bit address (VA).
#define IMAGE_REL_CEF_ADDR64 0x0002 // 64-bit address (VA).
#define IMAGE_REL_CEF_ADDR32NB 0x0003 // 32-bit address w/o image base (RVA).
#define IMAGE_REL_CEF_SECTION 0x0004 // Section index
#define IMAGE_REL_CEF_SECREL 0x0005 // 32 bit offset from base of section containing target
#define IMAGE_REL_CEF_TOKEN 0x0006 // 32 bit metadata token

//
// clr relocation types.
//
#define IMAGE_REL_CEE_ABSOLUTE 0x0000 // Reference is absolute, no relocation is necessary
#define IMAGE_REL_CEE_ADDR32 0x0001 // 32-bit address (VA).
#define IMAGE_REL_CEE_ADDR64 0x0002 // 64-bit address (VA).
#define IMAGE_REL_CEE_ADDR32NB 0x0003 // 32-bit address w/o image base (RVA).
#define IMAGE_REL_CEE_SECTION 0x0004 // Section index
#define IMAGE_REL_CEE_SECREL 0x0005 // 32 bit offset from base of section containing target
#define IMAGE_REL_CEE_TOKEN 0x0006 // 32 bit metadata token


#define IMAGE_REL_M32R_ABSOLUTE 0x0000 // No relocation required
#define IMAGE_REL_M32R_ADDR32 0x0001 // 32 bit address
#define IMAGE_REL_M32R_ADDR32NB 0x0002 // 32 bit address w/o image base
#define IMAGE_REL_M32R_ADDR24 0x0003 // 24 bit address
#define IMAGE_REL_M32R_GPREL16 0x0004 // GP relative addressing
#define IMAGE_REL_M32R_PCREL24 0x0005 // 24 bit offset << 2 & sign ext.
#define IMAGE_REL_M32R_PCREL16 0x0006 // 16 bit offset << 2 & sign ext.
#define IMAGE_REL_M32R_PCREL8 0x0007 // 8 bit offset << 2 & sign ext.
#define IMAGE_REL_M32R_REFHALF 0x0008 // 16 MSBs
#define IMAGE_REL_M32R_REFHI 0x0009 // 16 MSBs; adj for LSB sign ext.
#define IMAGE_REL_M32R_REFLO 0x000A // 16 LSBs
#define IMAGE_REL_M32R_PAIR 0x000B // Link HI and LO
#define IMAGE_REL_M32R_SECTION 0x000C // Section table index
#define IMAGE_REL_M32R_SECREL32 0x000D // 32 bit section relative reference
#define IMAGE_REL_M32R_TOKEN 0x000E // clr token

#define IMAGE_REL_EBC_ABSOLUTE 0x0000 // No relocation required
#define IMAGE_REL_EBC_ADDR32NB 0x0001 // 32 bit address w/o image base
#define IMAGE_REL_EBC_REL32 0x0002 // 32-bit relative address from byte following reloc
#define IMAGE_REL_EBC_SECTION 0x0003 // Section table index
#define IMAGE_REL_EBC_SECREL 0x0004 // Offset within section

#define EXT_IMM64(Value, Address, Size, InstPos, ValPos) /* Intel-IA64-Filler */ \
Value |= (((ULONGLONG)((*(Address) >> InstPos) & (((ULONGLONG)1 << Size) - 1))) << ValPos) // Intel-IA64-Filler

#define INS_IMM64(Value, Address, Size, InstPos, ValPos) /* Intel-IA64-Filler */\
*(PDWORD)Address = (*(PDWORD)Address & ~(((1 << Size) - 1) << InstPos)) | /* Intel-IA64-Filler */\
((DWORD)((((ULONGLONG)Value >> ValPos) & (((ULONGLONG)1 << Size) - 1))) << InstPos) // Intel-IA64-Filler

#define EMARCH_ENC_I17_IMM7B_INST_WORD_X 3 // Intel-IA64-Filler
#define EMARCH_ENC_I17_IMM7B_SIZE_X 7 // Intel-IA64-Filler
#define EMARCH_ENC_I17_IMM7B_INST_WORD_POS_X 4 // Intel-IA64-Filler
#define EMARCH_ENC_I17_IMM7B_VAL_POS_X 0 // Intel-IA64-Filler

#define EMARCH_ENC_I17_IMM9D_INST_WORD_X 3 // Intel-IA64-Filler
#define EMARCH_ENC_I17_IMM9D_SIZE_X 9 // Intel-IA64-Filler
#define EMARCH_ENC_I17_IMM9D_INST_WORD_POS_X 18 // Intel-IA64-Filler
#define EMARCH_ENC_I17_IMM9D_VAL_POS_X 7 // Intel-IA64-Filler

#define EMARCH_ENC_I17_IMM5C_INST_WORD_X 3 // Intel-IA64-Filler
#define EMARCH_ENC_I17_IMM5C_SIZE_X 5 // Intel-IA64-Filler
#define EMARCH_ENC_I17_IMM5C_INST_WORD_POS_X 13 // Intel-IA64-Filler
#define EMARCH_ENC_I17_IMM5C_VAL_POS_X 16 // Intel-IA64-Filler

#define EMARCH_ENC_I17_IC_INST_WORD_X 3 // Intel-IA64-Filler
#define EMARCH_ENC_I17_IC_SIZE_X 1 // Intel-IA64-Filler
#define EMARCH_ENC_I17_IC_INST_WORD_POS_X 12 // Intel-IA64-Filler
#define EMARCH_ENC_I17_IC_VAL_POS_X 21 // Intel-IA64-Filler

#define EMARCH_ENC_I17_IMM41a_INST_WORD_X 1 // Intel-IA64-Filler
#define EMARCH_ENC_I17_IMM41a_SIZE_X 10 // Intel-IA64-Filler
#define EMARCH_ENC_I17_IMM41a_INST_WORD_POS_X 14 // Intel-IA64-Filler
#define EMARCH_ENC_I17_IMM41a_VAL_POS_X 22 // Intel-IA64-Filler

#define EMARCH_ENC_I17_IMM41b_INST_WORD_X 1 // Intel-IA64-Filler
#define EMARCH_ENC_I17_IMM41b_SIZE_X 8 // Intel-IA64-Filler
#define EMARCH_ENC_I17_IMM41b_INST_WORD_POS_X 24 // Intel-IA64-Filler
#define EMARCH_ENC_I17_IMM41b_VAL_POS_X 32 // Intel-IA64-Filler

#define EMARCH_ENC_I17_IMM41c_INST_WORD_X 2 // Intel-IA64-Filler
#define EMARCH_ENC_I17_IMM41c_SIZE_X 23 // Intel-IA64-Filler
#define EMARCH_ENC_I17_IMM41c_INST_WORD_POS_X 0 // Intel-IA64-Filler
#define EMARCH_ENC_I17_IMM41c_VAL_POS_X 40 // Intel-IA64-Filler

#define EMARCH_ENC_I17_SIGN_INST_WORD_X 3 // Intel-IA64-Filler
#define EMARCH_ENC_I17_SIGN_SIZE_X 1 // Intel-IA64-Filler
#define EMARCH_ENC_I17_SIGN_INST_WORD_POS_X 27 // Intel-IA64-Filler
#define EMARCH_ENC_I17_SIGN_VAL_POS_X 63 // Intel-IA64-Filler

#define X3_OPCODE_INST_WORD_X 3 // Intel-IA64-Filler
#define X3_OPCODE_SIZE_X 4 // Intel-IA64-Filler
#define X3_OPCODE_INST_WORD_POS_X 28 // Intel-IA64-Filler
#define X3_OPCODE_SIGN_VAL_POS_X 0 // Intel-IA64-Filler

#define X3_I_INST_WORD_X 3 // Intel-IA64-Filler
#define X3_I_SIZE_X 1 // Intel-IA64-Filler
#define X3_I_INST_WORD_POS_X 27 // Intel-IA64-Filler
#define X3_I_SIGN_VAL_POS_X 59 // Intel-IA64-Filler

#define X3_D_WH_INST_WORD_X 3 // Intel-IA64-Filler
#define X3_D_WH_SIZE_X 3 // Intel-IA64-Filler
#define X3_D_WH_INST_WORD_POS_X 24 // Intel-IA64-Filler
#define X3_D_WH_SIGN_VAL_POS_X 0 // Intel-IA64-Filler

#define X3_IMM20_INST_WORD_X 3 // Intel-IA64-Filler
#define X3_IMM20_SIZE_X 20 // Intel-IA64-Filler
#define X3_IMM20_INST_WORD_POS_X 4 // Intel-IA64-Filler
#define X3_IMM20_SIGN_VAL_POS_X 0 // Intel-IA64-Filler

#define X3_IMM39_1_INST_WORD_X 2 // Intel-IA64-Filler
#define X3_IMM39_1_SIZE_X 23 // Intel-IA64-Filler
#define X3_IMM39_1_INST_WORD_POS_X 0 // Intel-IA64-Filler
#define X3_IMM39_1_SIGN_VAL_POS_X 36 // Intel-IA64-Filler

#define X3_IMM39_2_INST_WORD_X 1 // Intel-IA64-Filler
#define X3_IMM39_2_SIZE_X 16 // Intel-IA64-Filler
#define X3_IMM39_2_INST_WORD_POS_X 16 // Intel-IA64-Filler
#define X3_IMM39_2_SIGN_VAL_POS_X 20 // Intel-IA64-Filler

#define X3_P_INST_WORD_X 3 // Intel-IA64-Filler
#define X3_P_SIZE_X 4 // Intel-IA64-Filler
#define X3_P_INST_WORD_POS_X 0 // Intel-IA64-Filler
#define X3_P_SIGN_VAL_POS_X 0 // Intel-IA64-Filler

#define X3_TMPLT_INST_WORD_X 0 // Intel-IA64-Filler
#define X3_TMPLT_SIZE_X 4 // Intel-IA64-Filler
#define X3_TMPLT_INST_WORD_POS_X 0 // Intel-IA64-Filler
#define X3_TMPLT_SIGN_VAL_POS_X 0 // Intel-IA64-Filler

#define X3_BTYPE_QP_INST_WORD_X 2 // Intel-IA64-Filler
#define X3_BTYPE_QP_SIZE_X 9 // Intel-IA64-Filler
#define X3_BTYPE_QP_INST_WORD_POS_X 23 // Intel-IA64-Filler
#define X3_BTYPE_QP_INST_VAL_POS_X 0 // Intel-IA64-Filler

#define X3_EMPTY_INST_WORD_X 1 // Intel-IA64-Filler
#define X3_EMPTY_SIZE_X 2 // Intel-IA64-Filler
#define X3_EMPTY_INST_WORD_POS_X 14 // Intel-IA64-Filler
#define X3_EMPTY_INST_VAL_POS_X 0 // Intel-IA64-Filler

//
// Line number format.
//

typedef struct _IMAGE_LINENUMBER {
union {
DWORD SymbolTableIndex; // Symbol table index of function name if Linenumber is 0.
DWORD VirtualAddress; // Virtual address of line number.
} Type;
WORD Linenumber; // Line number.
} IMAGE_LINENUMBER;
typedef IMAGE_LINENUMBER UNALIGNED *PIMAGE_LINENUMBER;

#ifndef _MAC
#include "poppack.h" // Back to 4 byte packing
#endif

//
// Based relocation format.
//

typedef struct _IMAGE_BASE_RELOCATION {
DWORD VirtualAddress;
DWORD SizeOfBlock;
// WORD TypeOffset[1];
} IMAGE_BASE_RELOCATION;
typedef IMAGE_BASE_RELOCATION UNALIGNED * PIMAGE_BASE_RELOCATION;

//
// Based relocation types.
//

#define IMAGE_REL_BASED_ABSOLUTE 0
#define IMAGE_REL_BASED_HIGH 1
#define IMAGE_REL_BASED_LOW 2
#define IMAGE_REL_BASED_HIGHLOW 3
#define IMAGE_REL_BASED_HIGHADJ 4
#define IMAGE_REL_BASED_MIPS_JMPADDR 5
#define IMAGE_REL_BASED_MIPS_JMPADDR16 9
#define IMAGE_REL_BASED_IA64_IMM64 9
#define IMAGE_REL_BASED_DIR64 10


//
// Archive format.
//

#define IMAGE_ARCHIVE_START_SIZE 8
#define IMAGE_ARCHIVE_START "!<arch>\n"
#define IMAGE_ARCHIVE_END "`\n"
#define IMAGE_ARCHIVE_PAD "\n"
#define IMAGE_ARCHIVE_LINKER_MEMBER "/ "
#define IMAGE_ARCHIVE_LONGNAMES_MEMBER "// "

typedef struct _IMAGE_ARCHIVE_MEMBER_HEADER {
BYTE Name[16]; // File member name - `/‘ terminated.
BYTE Date[12]; // File member date - decimal.
BYTE UserID[6]; // File member user id - decimal.
BYTE GroupID[6]; // File member group id - decimal.
BYTE Mode[8]; // File member mode - octal.
BYTE Size[10]; // File member size - decimal.
BYTE EndHeader[2]; // String to end header.
} IMAGE_ARCHIVE_MEMBER_HEADER, *PIMAGE_ARCHIVE_MEMBER_HEADER;

#define IMAGE_SIZEOF_ARCHIVE_MEMBER_HDR 60

//
// DLL support.
//

//
// Export Format
//

typedef struct _IMAGE_EXPORT_DIRECTORY {
DWORD Characteristics;
DWORD TimeDateStamp;
WORD MajorVersion;
WORD MinorVersion;
DWORD Name;
DWORD Base;
DWORD NumberOfFunctions;
DWORD NumberOfNames;
DWORD AddressOfFunctions; // RVA from base of image
DWORD AddressOfNames; // RVA from base of image
DWORD AddressOfNameOrdinals; // RVA from base of image
} IMAGE_EXPORT_DIRECTORY, *PIMAGE_EXPORT_DIRECTORY;

//
// Import Format
//

typedef struct _IMAGE_IMPORT_BY_NAME {
WORD Hint;
BYTE Name[1];
} IMAGE_IMPORT_BY_NAME, *PIMAGE_IMPORT_BY_NAME;

#include "pshpack8.h" // Use align 8 for the 64-bit IAT.

typedef struct _IMAGE_THUNK_DATA64 {
union {
ULONGLONG ForwarderString; // PBYTE
ULONGLONG Function; // PDWORD
ULONGLONG Ordinal;
ULONGLONG AddressOfData; // PIMAGE_IMPORT_BY_NAME
} u1;
} IMAGE_THUNK_DATA64;
typedef IMAGE_THUNK_DATA64 * PIMAGE_THUNK_DATA64;

#include "poppack.h" // Back to 4 byte packing

typedef struct _IMAGE_THUNK_DATA32 {
union {
DWORD ForwarderString; // PBYTE
DWORD Function; // PDWORD
DWORD Ordinal;
DWORD AddressOfData; // PIMAGE_IMPORT_BY_NAME
} u1;
} IMAGE_THUNK_DATA32;
typedef IMAGE_THUNK_DATA32 * PIMAGE_THUNK_DATA32;

#define IMAGE_ORDINAL_FLAG64 0x8000000000000000
#define IMAGE_ORDINAL_FLAG32 0x80000000
#define IMAGE_ORDINAL64(Ordinal) (Ordinal & 0xffff)
#define IMAGE_ORDINAL32(Ordinal) (Ordinal & 0xffff)
#define IMAGE_SNAP_BY_ORDINAL64(Ordinal) ((Ordinal & IMAGE_ORDINAL_FLAG64) != 0)
#define IMAGE_SNAP_BY_ORDINAL32(Ordinal) ((Ordinal & IMAGE_ORDINAL_FLAG32) != 0)

//
// Thread Local Storage
//

typedef VOID
(NTAPI *PIMAGE_TLS_CALLBACK) (
PVOID DllHandle,
DWORD Reason,
PVOID Reserved
);

typedef struct _IMAGE_TLS_DIRECTORY64 {
ULONGLONG StartAddressOfRawData;
ULONGLONG EndAddressOfRawData;
ULONGLONG AddressOfIndex; // PDWORD
ULONGLONG AddressOfCallBacks; // PIMAGE_TLS_CALLBACK *;
DWORD SizeOfZeroFill;
DWORD Characteristics;
} IMAGE_TLS_DIRECTORY64;
typedef IMAGE_TLS_DIRECTORY64 * PIMAGE_TLS_DIRECTORY64;

typedef struct _IMAGE_TLS_DIRECTORY32 {
DWORD StartAddressOfRawData;
DWORD EndAddressOfRawData;
DWORD AddressOfIndex; // PDWORD
DWORD AddressOfCallBacks; // PIMAGE_TLS_CALLBACK *
DWORD SizeOfZeroFill;
DWORD Characteristics;
} IMAGE_TLS_DIRECTORY32;
typedef IMAGE_TLS_DIRECTORY32 * PIMAGE_TLS_DIRECTORY32;

#ifdef _WIN64
#define IMAGE_ORDINAL_FLAG IMAGE_ORDINAL_FLAG64
#define IMAGE_ORDINAL(Ordinal) IMAGE_ORDINAL64(Ordinal)
typedef IMAGE_THUNK_DATA64 IMAGE_THUNK_DATA;
typedef PIMAGE_THUNK_DATA64 PIMAGE_THUNK_DATA;
#define IMAGE_SNAP_BY_ORDINAL(Ordinal) IMAGE_SNAP_BY_ORDINAL64(Ordinal)
typedef IMAGE_TLS_DIRECTORY64 IMAGE_TLS_DIRECTORY;
typedef PIMAGE_TLS_DIRECTORY64 PIMAGE_TLS_DIRECTORY;
#else
#define IMAGE_ORDINAL_FLAG IMAGE_ORDINAL_FLAG32
#define IMAGE_ORDINAL(Ordinal) IMAGE_ORDINAL32(Ordinal)
typedef IMAGE_THUNK_DATA32 IMAGE_THUNK_DATA;
typedef PIMAGE_THUNK_DATA32 PIMAGE_THUNK_DATA;
#define IMAGE_SNAP_BY_ORDINAL(Ordinal) IMAGE_SNAP_BY_ORDINAL32(Ordinal)
typedef IMAGE_TLS_DIRECTORY32 IMAGE_TLS_DIRECTORY;
typedef PIMAGE_TLS_DIRECTORY32 PIMAGE_TLS_DIRECTORY;
#endif

typedef struct _IMAGE_IMPORT_DESCRIPTOR {
union {
DWORD Characteristics; // 0 for terminating null import descriptor
DWORD OriginalFirstThunk; // RVA to original unbound IAT (PIMAGE_THUNK_DATA)
} DUMMYUNIONNAME;
DWORD TimeDateStamp; // 0 if not bound,
// -1 if bound, and real date\time stamp
// in IMAGE_DIRECTORY_ENTRY_BOUND_IMPORT (new BIND)
// O.W. date/time stamp of DLL bound to (Old BIND)

DWORD ForwarderChain; // -1 if no forwarders
DWORD Name;
DWORD FirstThunk; // RVA to IAT (if bound this IAT has actual addresses)
} IMAGE_IMPORT_DESCRIPTOR;
typedef IMAGE_IMPORT_DESCRIPTOR UNALIGNED *PIMAGE_IMPORT_DESCRIPTOR;

//
// New format import descriptors pointed to by DataDirectory[ IMAGE_DIRECTORY_ENTRY_BOUND_IMPORT ]
//

typedef struct _IMAGE_BOUND_IMPORT_DESCRIPTOR {
DWORD TimeDateStamp;
WORD OffsetModuleName;
WORD NumberOfModuleForwarderRefs;
// Array of zero or more IMAGE_BOUND_FORWARDER_REF follows
} IMAGE_BOUND_IMPORT_DESCRIPTOR, *PIMAGE_BOUND_IMPORT_DESCRIPTOR;

typedef struct _IMAGE_BOUND_FORWARDER_REF {
DWORD TimeDateStamp;
WORD OffsetModuleName;
WORD Reserved;
} IMAGE_BOUND_FORWARDER_REF, *PIMAGE_BOUND_FORWARDER_REF;

//
// Resource Format.
//

//
// Resource directory consists of two counts, following by a variable length
// array of directory entries. The first count is the number of entries at
// beginning of the array that have actual names associated with each entry.
// The entries are in ascending order, case insensitive strings. The second
// count is the number of entries that immediately follow the named entries.
// This second count identifies the number of entries that have 16-bit integer
// Ids as their name. These entries are also sorted in ascending order.
//
// This structure allows fast lookup by either name or number, but for any
// given resource entry only one form of lookup is supported, not both.
// This is consistant with the syntax of the .RC file and the .RES file.
//

typedef struct _IMAGE_RESOURCE_DIRECTORY {
DWORD Characteristics;
DWORD TimeDateStamp;
WORD MajorVersion;
WORD MinorVersion;
WORD NumberOfNamedEntries;
WORD NumberOfIdEntries;
// IMAGE_RESOURCE_DIRECTORY_ENTRY DirectoryEntries[];
} IMAGE_RESOURCE_DIRECTORY, *PIMAGE_RESOURCE_DIRECTORY;

#define IMAGE_RESOURCE_NAME_IS_STRING 0x80000000
#define IMAGE_RESOURCE_DATA_IS_DIRECTORY 0x80000000
//
// Each directory contains the 32-bit Name of the entry and an offset,
// relative to the beginning of the resource directory of the data associated
// with this directory entry. If the name of the entry is an actual text
// string instead of an integer Id, then the high order bit of the name field
// is set to one and the low order 31-bits are an offset, relative to the
// beginning of the resource directory of the string, which is of type
// IMAGE_RESOURCE_DIRECTORY_STRING. Otherwise the high bit is clear and the
// low-order 16-bits are the integer Id that identify this resource directory
// entry. If the directory entry is yet another resource directory (i.e. a
// subdirectory), then the high order bit of the offset field will be
// set to indicate this. Otherwise the high bit is clear and the offset
// field points to a resource data entry.
//

typedef struct _IMAGE_RESOURCE_DIRECTORY_ENTRY {
union {
struct {
DWORD NameOffset:31;
DWORD NameIsString:1;
} DUMMYSTRUCTNAME;
DWORD Name;
WORD Id;
} DUMMYUNIONNAME;
union {
DWORD OffsetToData;
struct {
DWORD OffsetToDirectory:31;
DWORD DataIsDirectory:1;
} DUMMYSTRUCTNAME2;
} DUMMYUNIONNAME2;
} IMAGE_RESOURCE_DIRECTORY_ENTRY, *PIMAGE_RESOURCE_DIRECTORY_ENTRY;

//
// For resource directory entries that have actual string names, the Name
// field of the directory entry points to an object of the following type.
// All of these string objects are stored together after the last resource
// directory entry and before the first resource data object. This minimizes
// the impact of these variable length objects on the alignment of the fixed
// size directory entry objects.
//

typedef struct _IMAGE_RESOURCE_DIRECTORY_STRING {
WORD Length;
CHAR NameString[ 1 ];
} IMAGE_RESOURCE_DIRECTORY_STRING, *PIMAGE_RESOURCE_DIRECTORY_STRING;


typedef struct _IMAGE_RESOURCE_DIR_STRING_U {
WORD Length;
WCHAR NameString[ 1 ];
} IMAGE_RESOURCE_DIR_STRING_U, *PIMAGE_RESOURCE_DIR_STRING_U;


//
// Each resource data entry describes a leaf node in the resource directory
// tree. It contains an offset, relative to the beginning of the resource
// directory of the data for the resource, a size field that gives the number
// of bytes of data at that offset, a CodePage that should be used when
// decoding code point values within the resource data. Typically for new
// applications the code page would be the unicode code page.
//

typedef struct _IMAGE_RESOURCE_DATA_ENTRY {
DWORD OffsetToData;
DWORD Size;
DWORD CodePage;
DWORD Reserved;
} IMAGE_RESOURCE_DATA_ENTRY, *PIMAGE_RESOURCE_DATA_ENTRY;

//
// Load Configuration Directory Entry
//

typedef struct {
DWORD Size;
DWORD TimeDateStamp;
WORD MajorVersion;
WORD MinorVersion;
DWORD GlobalFlagsClear;
DWORD GlobalFlagsSet;
DWORD CriticalSectionDefaultTimeout;
DWORD DeCommitFreeBlockThreshold;
DWORD DeCommitTotalFreeThreshold;
DWORD LockPrefixTable; // VA
DWORD MaximumAllocationSize;
DWORD VirtualMemoryThreshold;
DWORD ProcessHeapFlags;
DWORD ProcessAffinityMask;
WORD CSDVersion;
WORD Reserved1;
DWORD EditList; // VA
DWORD SecurityCookie; // VA
DWORD SEHandlerTable; // VA
DWORD SEHandlerCount;
} IMAGE_LOAD_CONFIG_DIRECTORY32, *PIMAGE_LOAD_CONFIG_DIRECTORY32;

typedef struct {
DWORD Size;
DWORD TimeDateStamp;
WORD MajorVersion;
WORD MinorVersion;
DWORD GlobalFlagsClear;
DWORD GlobalFlagsSet;
DWORD CriticalSectionDefaultTimeout;
ULONGLONG DeCommitFreeBlockThreshold;
ULONGLONG DeCommitTotalFreeThreshold;
ULONGLONG LockPrefixTable; // VA
ULONGLONG MaximumAllocationSize;
ULONGLONG VirtualMemoryThreshold;
ULONGLONG ProcessAffinityMask;
DWORD ProcessHeapFlags;
WORD CSDVersion;
WORD Reserved1;
ULONGLONG EditList; // VA
ULONGLONG SecurityCookie; // VA
ULONGLONG SEHandlerTable; // VA
ULONGLONG SEHandlerCount;
} IMAGE_LOAD_CONFIG_DIRECTORY64, *PIMAGE_LOAD_CONFIG_DIRECTORY64;

#ifdef _WIN64
typedef IMAGE_LOAD_CONFIG_DIRECTORY64 IMAGE_LOAD_CONFIG_DIRECTORY;
typedef PIMAGE_LOAD_CONFIG_DIRECTORY64 PIMAGE_LOAD_CONFIG_DIRECTORY;
#else
typedef IMAGE_LOAD_CONFIG_DIRECTORY32 IMAGE_LOAD_CONFIG_DIRECTORY;
typedef PIMAGE_LOAD_CONFIG_DIRECTORY32 PIMAGE_LOAD_CONFIG_DIRECTORY;
#endif

//
// WIN CE Exception table format
//

//
// Function table entry format. Function table is pointed to by the
// IMAGE_DIRECTORY_ENTRY_EXCEPTION directory entry.
//

typedef struct _IMAGE_CE_RUNTIME_FUNCTION_ENTRY {
DWORD FuncStart;
DWORD PrologLen : 8;
DWORD FuncLen : 22;
DWORD ThirtyTwoBit : 1;
DWORD ExceptionFlag : 1;
} IMAGE_CE_RUNTIME_FUNCTION_ENTRY, * PIMAGE_CE_RUNTIME_FUNCTION_ENTRY;

typedef struct _IMAGE_ALPHA64_RUNTIME_FUNCTION_ENTRY {
ULONGLONG BeginAddress;
ULONGLONG EndAddress;
ULONGLONG ExceptionHandler;
ULONGLONG HandlerData;
ULONGLONG PrologEndAddress;
} IMAGE_ALPHA64_RUNTIME_FUNCTION_ENTRY, *PIMAGE_ALPHA64_RUNTIME_FUNCTION_ENTRY;

typedef struct _IMAGE_ALPHA_RUNTIME_FUNCTION_ENTRY {
DWORD BeginAddress;
DWORD EndAddress;
DWORD ExceptionHandler;
DWORD HandlerData;
DWORD PrologEndAddress;
} IMAGE_ALPHA_RUNTIME_FUNCTION_ENTRY, *PIMAGE_ALPHA_RUNTIME_FUNCTION_ENTRY;

typedef struct _IMAGE_RUNTIME_FUNCTION_ENTRY {
DWORD BeginAddress;
DWORD EndAddress;
DWORD UnwindInfoAddress;
} _IMAGE_RUNTIME_FUNCTION_ENTRY, *_PIMAGE_RUNTIME_FUNCTION_ENTRY;

typedef _IMAGE_RUNTIME_FUNCTION_ENTRY IMAGE_IA64_RUNTIME_FUNCTION_ENTRY;
typedef _PIMAGE_RUNTIME_FUNCTION_ENTRY PIMAGE_IA64_RUNTIME_FUNCTION_ENTRY;

#if defined(_AXP64_)

typedef IMAGE_ALPHA64_RUNTIME_FUNCTION_ENTRY IMAGE_AXP64_RUNTIME_FUNCTION_ENTRY;
typedef PIMAGE_ALPHA64_RUNTIME_FUNCTION_ENTRY PIMAGE_AXP64_RUNTIME_FUNCTION_ENTRY;
typedef IMAGE_ALPHA64_RUNTIME_FUNCTION_ENTRY IMAGE_RUNTIME_FUNCTION_ENTRY;
typedef PIMAGE_ALPHA64_RUNTIME_FUNCTION_ENTRY PIMAGE_RUNTIME_FUNCTION_ENTRY;

#elif defined(_ALPHA_)

typedef IMAGE_ALPHA_RUNTIME_FUNCTION_ENTRY IMAGE_RUNTIME_FUNCTION_ENTRY;
typedef PIMAGE_ALPHA_RUNTIME_FUNCTION_ENTRY PIMAGE_RUNTIME_FUNCTION_ENTRY;

#else

typedef _IMAGE_RUNTIME_FUNCTION_ENTRY IMAGE_RUNTIME_FUNCTION_ENTRY;
typedef _PIMAGE_RUNTIME_FUNCTION_ENTRY PIMAGE_RUNTIME_FUNCTION_ENTRY;

#endif

//
// Debug Format
//

typedef struct _IMAGE_DEBUG_DIRECTORY {
DWORD Characteristics;
DWORD TimeDateStamp;
WORD MajorVersion;
WORD MinorVersion;
DWORD Type;
DWORD SizeOfData;
DWORD AddressOfRawData;
DWORD PointerToRawData;
} IMAGE_DEBUG_DIRECTORY, *PIMAGE_DEBUG_DIRECTORY;

#define IMAGE_DEBUG_TYPE_UNKNOWN 0
#define IMAGE_DEBUG_TYPE_COFF 1
#define IMAGE_DEBUG_TYPE_CODEVIEW 2
#define IMAGE_DEBUG_TYPE_FPO 3
#define IMAGE_DEBUG_TYPE_MISC 4
#define IMAGE_DEBUG_TYPE_EXCEPTION 5
#define IMAGE_DEBUG_TYPE_FIXUP 6
#define IMAGE_DEBUG_TYPE_OMAP_TO_SRC 7
#define IMAGE_DEBUG_TYPE_OMAP_FROM_SRC 8
#define IMAGE_DEBUG_TYPE_BORLAND 9
#define IMAGE_DEBUG_TYPE_RESERVED10 10
#define IMAGE_DEBUG_TYPE_CLSID 11


typedef struct _IMAGE_COFF_SYMBOLS_HEADER {
DWORD NumberOfSymbols;
DWORD LvaToFirstSymbol;
DWORD NumberOfLinenumbers;
DWORD LvaToFirstLinenumber;
DWORD RvaToFirstByteOfCode;
DWORD RvaToLastByteOfCode;
DWORD RvaToFirstByteOfData;
DWORD RvaToLastByteOfData;
} IMAGE_COFF_SYMBOLS_HEADER, *PIMAGE_COFF_SYMBOLS_HEADER;

#define FRAME_FPO 0
#define FRAME_TRAP 1
#define FRAME_TSS 2
#define FRAME_NONFPO 3

typedef struct _FPO_DATA {
DWORD ulOffStart; // offset 1st byte of function code
DWORD cbProcSize; // # bytes in function
DWORD cdwLocals; // # bytes in locals/4
WORD cdwParams; // # bytes in params/4
WORD cbProlog : 8; // # bytes in prolog
WORD cbRegs : 3; // # regs saved
WORD fHasSEH : 1; // TRUE if SEH in func
WORD fUseBP : 1; // TRUE if EBP has been allocated
WORD reserved : 1; // reserved for future use
WORD cbFrame : 2; // frame type
} FPO_DATA, *PFPO_DATA;
#define SIZEOF_RFPO_DATA 16


#define IMAGE_DEBUG_MISC_EXENAME 1

typedef struct _IMAGE_DEBUG_MISC {
DWORD DataType; // type of misc data, see defines
DWORD Length; // total length of record, rounded to four
// byte multiple.
BOOLEAN Unicode; // TRUE if data is unicode string
BYTE Reserved[ 3 ];
BYTE Data[ 1 ]; // Actual data
} IMAGE_DEBUG_MISC, *PIMAGE_DEBUG_MISC;


//
// Function table extracted from MIPS/ALPHA/IA64 images. Does not contain
// information needed only for runtime support. Just those fields for
// each entry needed by a debugger.
//

typedef struct _IMAGE_FUNCTION_ENTRY {
DWORD StartingAddress;
DWORD EndingAddress;
DWORD EndOfPrologue;
} IMAGE_FUNCTION_ENTRY, *PIMAGE_FUNCTION_ENTRY;

typedef struct _IMAGE_FUNCTION_ENTRY64 {
ULONGLONG StartingAddress;
ULONGLONG EndingAddress;
union {
ULONGLONG EndOfPrologue;
ULONGLONG UnwindInfoAddress;
} DUMMYUNIONNAME;
} IMAGE_FUNCTION_ENTRY64, *PIMAGE_FUNCTION_ENTRY64;

//
// Debugging information can be stripped from an image file and placed
// in a separate .DBG file, whose file name part is the same as the
// image file name part (e.g. symbols for CMD.EXE could be stripped
// and placed in CMD.DBG). This is indicated by the IMAGE_FILE_DEBUG_STRIPPED
// flag in the Characteristics field of the file header. The beginning of
// the .DBG file contains the following structure which captures certain
// information from the image file. This allows a debug to proceed even if
// the original image file is not accessable. This header is followed by
// zero of more IMAGE_SECTION_HEADER structures, followed by zero or more
// IMAGE_DEBUG_DIRECTORY structures. The latter structures and those in
// the image file contain file offsets relative to the beginning of the
// .DBG file.
//
// If symbols have been stripped from an image, the IMAGE_DEBUG_MISC structure
// is left in the image file, but not mapped. This allows a debugger to
// compute the name of the .DBG file, from the name of the image in the
// IMAGE_DEBUG_MISC structure.
//

typedef struct _IMAGE_SEPARATE_DEBUG_HEADER {
WORD Signature;
WORD Flags;
WORD Machine;
WORD Characteristics;
DWORD TimeDateStamp;
DWORD CheckSum;
DWORD ImageBase;
DWORD SizeOfImage;
DWORD NumberOfSections;
DWORD ExportedNamesSize;
DWORD DebugDirectorySize;
DWORD SectionAlignment;
DWORD Reserved[2];
} IMAGE_SEPARATE_DEBUG_HEADER, *PIMAGE_SEPARATE_DEBUG_HEADER;

typedef struct _NON_PAGED_DEBUG_INFO {
WORD Signature;
WORD Flags;
DWORD Size;
WORD Machine;
WORD Characteristics;
DWORD TimeDateStamp;
DWORD CheckSum;
DWORD SizeOfImage;
ULONGLONG ImageBase;
//DebugDirectorySize
//IMAGE_DEBUG_DIRECTORY
} NON_PAGED_DEBUG_INFO, *PNON_PAGED_DEBUG_INFO;

#ifndef _MAC
#define IMAGE_SEPARATE_DEBUG_SIGNATURE 0x4944
#define NON_PAGED_DEBUG_SIGNATURE 0x494E
#else
#define IMAGE_SEPARATE_DEBUG_SIGNATURE 0x4449 // DI
#define NON_PAGED_DEBUG_SIGNATURE 0x4E49 // NI
#endif

#define IMAGE_SEPARATE_DEBUG_FLAGS_MASK 0x8000
#define IMAGE_SEPARATE_DEBUG_MISMATCH 0x8000 // when DBG was updated, the
// old checksum didn‘t match.

//
// The .arch section is made up of headers, each describing an amask position/value
// pointing to an array of IMAGE_ARCHITECTURE_ENTRY‘s. Each "array" (both the header
// and entry arrays) are terminiated by a quadword of 0xffffffffL.
//
// NOTE: There may be quadwords of 0 sprinkled around and must be skipped.
//

typedef struct _ImageArchitectureHeader {
unsigned int AmaskValue: 1; // 1 -> code section depends on mask bit
// 0 -> new instruction depends on mask bit
int :7; // MBZ
unsigned int AmaskShift: 8; // Amask bit in question for this fixup
int :16; // MBZ
DWORD FirstEntryRVA; // RVA into .arch section to array of ARCHITECTURE_ENTRY‘s
} IMAGE_ARCHITECTURE_HEADER, *PIMAGE_ARCHITECTURE_HEADER;

typedef struct _ImageArchitectureEntry {
DWORD FixupInstRVA; // RVA of instruction to fixup
DWORD NewInst; // fixup instruction (see alphaops.h)
} IMAGE_ARCHITECTURE_ENTRY, *PIMAGE_ARCHITECTURE_ENTRY;

#include "poppack.h" // Back to the initial value

// The following structure defines the new import object. Note the values of the first two fields,
// which must be set as stated in order to differentiate old and new import members.
// Following this structure, the linker emits two null-terminated strings used to recreate the
// import at the time of use. The first string is the import‘s name, the second is the dll‘s name.

#define IMPORT_OBJECT_HDR_SIG2 0xffff

typedef struct IMPORT_OBJECT_HEADER {
WORD Sig1; // Must be IMAGE_FILE_MACHINE_UNKNOWN
WORD Sig2; // Must be IMPORT_OBJECT_HDR_SIG2.
WORD Version;
WORD Machine;
DWORD TimeDateStamp; // Time/date stamp
DWORD SizeOfData; // particularly useful for incremental links

union {
WORD Ordinal; // if grf & IMPORT_OBJECT_ORDINAL
WORD Hint;
} DUMMYUNIONNAME;

WORD Type : 2; // IMPORT_TYPE
WORD NameType : 3; // IMPORT_NAME_TYPE
WORD Reserved : 11; // Reserved. Must be zero.
} IMPORT_OBJECT_HEADER;

typedef enum IMPORT_OBJECT_TYPE
{
IMPORT_OBJECT_CODE = 0,
IMPORT_OBJECT_DATA = 1,
IMPORT_OBJECT_CONST = 2,
} IMPORT_OBJECT_TYPE;

typedef enum IMPORT_OBJECT_NAME_TYPE
{
IMPORT_OBJECT_ORDINAL = 0, // Import by ordinal
IMPORT_OBJECT_NAME = 1, // Import name == public symbol name.
IMPORT_OBJECT_NAME_NO_PREFIX = 2, // Import name == public symbol name skipping leading ?, @, or optionally _.
IMPORT_OBJECT_NAME_UNDECORATE = 3, // Import name == public symbol name skipping leading ?, @, or optionally _
// and truncating at first @
} IMPORT_OBJECT_NAME_TYPE;


#ifndef __IMAGE_COR20_HEADER_DEFINED__
#define __IMAGE_COR20_HEADER_DEFINED__

typedef enum ReplacesCorHdrNumericDefines
{
// COM+ Header entry point flags.
COMIMAGE_FLAGS_ILONLY =0x00000001,
COMIMAGE_FLAGS_32BITREQUIRED =0x00000002,
COMIMAGE_FLAGS_IL_LIBRARY =0x00000004,
COMIMAGE_FLAGS_STRONGNAMESIGNED =0x00000008,
COMIMAGE_FLAGS_NATIVE_ENTRYPOINT =0x00000010,
COMIMAGE_FLAGS_TRACKDEBUGDATA =0x00010000,

// Version flags for image.
COR_VERSION_MAJOR_V2 =2,
COR_VERSION_MAJOR =COR_VERSION_MAJOR_V2,
COR_VERSION_MINOR =0,
COR_DELETED_NAME_LENGTH =8,
COR_VTABLEGAP_NAME_LENGTH =8,

// Maximum size of a NativeType descriptor.
NATIVE_TYPE_MAX_CB =1,
COR_ILMETHOD_SECT_SMALL_MAX_DATASIZE=0xFF,

// #defines for the MIH FLAGS
IMAGE_COR_MIH_METHODRVA =0x01,
IMAGE_COR_MIH_EHRVA =0x02,
IMAGE_COR_MIH_BASICBLOCK =0x08,

// V-table constants
COR_VTABLE_32BIT =0x01, // V-table slots are 32-bits in size.
COR_VTABLE_64BIT =0x02, // V-table slots are 64-bits in size.
COR_VTABLE_FROM_UNMANAGED =0x04, // If set, transition from unmanaged.
COR_VTABLE_FROM_UNMANAGED_RETAIN_APPDOMAIN =0x08, // If set, transition from unmanaged with keeping the current appdomain.
COR_VTABLE_CALL_MOST_DERIVED =0x10, // Call most derived method described by

// EATJ constants
IMAGE_COR_EATJ_THUNK_SIZE =32, // Size of a jump thunk reserved range.

// Max name lengths
//@todo: Change to unlimited name lengths.
MAX_CLASS_NAME =1024,
MAX_PACKAGE_NAME =1024,
} ReplacesCorHdrNumericDefines;

// CLR 2.0 header structure.
typedef struct IMAGE_COR20_HEADER
{
// Header versioning
DWORD cb;
WORD MajorRuntimeVersion;
WORD MinorRuntimeVersion;

// Symbol table and startup information
IMAGE_DATA_DIRECTORY MetaData;
DWORD Flags;

// If COMIMAGE_FLAGS_NATIVE_ENTRYPOINT is not set, EntryPointToken represents a managed entrypoint.
// If COMIMAGE_FLAGS_NATIVE_ENTRYPOINT is set, EntryPointRVA represents an RVA to a native entrypoint.
union {
DWORD EntryPointToken;
DWORD EntryPointRVA;
} DUMMYUNIONNAME;

// Binding information
IMAGE_DATA_DIRECTORY Resources;
IMAGE_DATA_DIRECTORY StrongNameSignature;

// Regular fixup and binding information
IMAGE_DATA_DIRECTORY CodeManagerTable;
IMAGE_DATA_DIRECTORY VTableFixups;
IMAGE_DATA_DIRECTORY ExportAddressTableJumps;

// Precompiled image info (internal use only - set to zero)
IMAGE_DATA_DIRECTORY ManagedNativeHeader;

} IMAGE_COR20_HEADER, *PIMAGE_COR20_HEADER;

#endif // __IMAGE_COR20_HEADER_DEFINED__

//
// End Image Format
//

//
// for move macros
//
#ifdef _MAC
#ifndef _INC_STRING
#include <string.h>
#endif /* _INC_STRING */
#else
#include <string.h>
#endif // _MAC


#ifndef _SLIST_HEADER_
#define _SLIST_HEADER_

#if defined(_WIN64)

//
// The type SINGLE_LIST_ENTRY is not suitable for use with SLISTs. For
// WIN64, an entry on an SLIST is required to be 16-byte aligned, while a
// SINGLE_LIST_ENTRY structure has only 8 byte alignment.
//
// Therefore, all SLIST code should use the SLIST_ENTRY type instead of the
// SINGLE_LIST_ENTRY type.
//

#pragma warning(push)
#pragma warning(disable:4324) // structure padded due to align()
typedef struct DECLSPEC_ALIGN(16) _SLIST_ENTRY *PSLIST_ENTRY;
typedef struct DECLSPEC_ALIGN(16) _SLIST_ENTRY {
PSLIST_ENTRY Next;
} SLIST_ENTRY;
#pragma warning(pop)

typedef struct _SLIST_ENTRY32 {
DWORD Next;
} SLIST_ENTRY32, *PSLIST_ENTRY32;

#else

#define SLIST_ENTRY SINGLE_LIST_ENTRY
#define _SLIST_ENTRY _SINGLE_LIST_ENTRY
#define PSLIST_ENTRY PSINGLE_LIST_ENTRY

typedef SLIST_ENTRY SLIST_ENTRY32, *PSLIST_ENTRY32;

#endif // _WIN64

#if defined(_WIN64)

typedef union DECLSPEC_ALIGN(16) _SLIST_HEADER {
struct { // original struct
ULONGLONG Alignment;
ULONGLONG Region;
} DUMMYSTRUCTNAME;
struct { // 8-byte header
ULONGLONG Depth:16;
ULONGLONG Sequence:9;
ULONGLONG NextEntry:39;
ULONGLONG HeaderType:1; // 0: 8-byte; 1: 16-byte
ULONGLONG Init:1; // 0: uninitialized; 1: initialized
ULONGLONG Reserved:59;
ULONGLONG Region:3;
} Header8;
struct { // ia64 16-byte header
ULONGLONG Depth:16;
ULONGLONG Sequence:48;
ULONGLONG HeaderType:1; // 0: 8-byte; 1: 16-byte
ULONGLONG Init:1; // 0: uninitialized; 1: initialized
ULONGLONG Reserved:2;
ULONGLONG NextEntry:60; // last 4 bits are always 0‘s
} Header16;
struct { // x64 16-byte header
ULONGLONG Depth:16;
ULONGLONG Sequence:48;
ULONGLONG HeaderType:1; // 0: 8-byte; 1: 16-byte
ULONGLONG Reserved:3;
ULONGLONG NextEntry:60; // last 4 bits are always 0‘s
} HeaderX64;
} SLIST_HEADER, *PSLIST_HEADER;

typedef union _SLIST_HEADER32{
ULONGLONG Alignment;
struct {
SLIST_ENTRY32 Next;
WORD Depth;
WORD Sequence;
} DUMMYSTRUCTNAME;
} SLIST_HEADER32, *PSLIST_HEADER32;

#else

typedef union _SLIST_HEADER {
ULONGLONG Alignment;
struct {
SLIST_ENTRY Next;
WORD Depth;
WORD Sequence;
} DUMMYSTRUCTNAME;
} SLIST_HEADER, *PSLIST_HEADER;

typedef SLIST_HEADER SLIST_HEADER32, *PSLIST_HEADER32;

#endif // _WIN64

#endif // _SLIST_HEADER_


NTSYSAPI
VOID
NTAPI
RtlInitializeSListHead (
__out PSLIST_HEADER ListHead
);

__checkReturn
NTSYSAPI
PSLIST_ENTRY
NTAPI
RtlFirstEntrySList (
__in const SLIST_HEADER *ListHead
);

NTSYSAPI
PSLIST_ENTRY
NTAPI
RtlInterlockedPopEntrySList (
__inout PSLIST_HEADER ListHead
);

NTSYSAPI
PSLIST_ENTRY
NTAPI
RtlInterlockedPushEntrySList (
__inout PSLIST_HEADER ListHead,
__inout __drv_aliasesMem PSLIST_ENTRY ListEntry
);

NTSYSAPI
PSLIST_ENTRY
NTAPI
RtlInterlockedFlushSList (
__inout PSLIST_HEADER ListHead
);

NTSYSAPI
WORD
NTAPI
RtlQueryDepthSList (
__in PSLIST_HEADER ListHead
);

#if defined(_IA64_)

NTSYSAPI
PSLIST_ENTRY32
NTAPI
RtlInterlockedPopEntrySList32 (
__inout PSLIST_HEADER32 ListHead
);

#endif

// begin_ntddk

#ifndef _RTL_RUN_ONCE_DEF
#define _RTL_RUN_ONCE_DEF

//
// Run once
//

#define RTL_RUN_ONCE_INIT {0} // Static initializer

//
// Run once flags
//

#define RTL_RUN_ONCE_CHECK_ONLY 0x00000001UL
#define RTL_RUN_ONCE_ASYNC 0x00000002UL
#define RTL_RUN_ONCE_INIT_FAILED 0x00000004UL

//
// The context stored in the run once structure must leave the following number
// of low order bits unused.
//

#define RTL_RUN_ONCE_CTX_RESERVED_BITS 2

typedef union _RTL_RUN_ONCE {
PVOID Ptr;
} RTL_RUN_ONCE, *PRTL_RUN_ONCE;

typedef
__drv_functionClass(RTL_RUN_ONCE_INIT_FN)
__drv_sameIRQL
DWORD /* LOGICAL */
NTAPI
RTL_RUN_ONCE_INIT_FN (
__inout PRTL_RUN_ONCE RunOnce,
__inout_opt PVOID Parameter,
__deref_opt_inout_opt PVOID *Context
);
typedef RTL_RUN_ONCE_INIT_FN *PRTL_RUN_ONCE_INIT_FN;

#endif // _RTL_RUN_ONCE_DEF

#if (NTDDI_VERSION >= NTDDI_LONGHORN)

__drv_maxIRQL(APC_LEVEL)
NTSYSAPI
VOID
NTAPI
RtlRunOnceInitialize (
__out PRTL_RUN_ONCE RunOnce
);

__drv_maxIRQL(APC_LEVEL)
__drv_inTry
NTSYSAPI
DWORD
NTAPI
RtlRunOnceExecuteOnce (
__inout PRTL_RUN_ONCE RunOnce,
__in __callback PRTL_RUN_ONCE_INIT_FN InitFn,
__inout_opt PVOID Parameter,
__deref_opt_out_opt PVOID *Context
);

__drv_maxIRQL(APC_LEVEL)
__checkReturn
NTSYSAPI
DWORD
NTAPI
RtlRunOnceBeginInitialize (
__inout PRTL_RUN_ONCE RunOnce,
__in DWORD Flags,
__deref_opt_out_opt PVOID *Context
);

__drv_maxIRQL(APC_LEVEL)
NTSYSAPI
DWORD
NTAPI
RtlRunOnceComplete (
__inout PRTL_RUN_ONCE RunOnce,
__in DWORD Flags,
__in_opt PVOID Context
);

#endif // NTDDI_VERSION >= NTDDI_LONGHORN

#define HEAP_NO_SERIALIZE 0x00000001
#define HEAP_GROWABLE 0x00000002
#define HEAP_GENERATE_EXCEPTIONS 0x00000004
#define HEAP_ZERO_MEMORY 0x00000008
#define HEAP_REALLOC_IN_PLACE_ONLY 0x00000010
#define HEAP_TAIL_CHECKING_ENABLED 0x00000020
#define HEAP_FREE_CHECKING_ENABLED 0x00000040
#define HEAP_DISABLE_COALESCE_ON_FREE 0x00000080
#define HEAP_CREATE_ALIGN_16 0x00010000
#define HEAP_CREATE_ENABLE_TRACING 0x00020000
#define HEAP_CREATE_ENABLE_EXECUTE 0x00040000
#define HEAP_MAXIMUM_TAG 0x0FFF
#define HEAP_PSEUDO_TAG_FLAG 0x8000
#define HEAP_TAG_SHIFT 18
#if !defined(MIDL_PASS)
FORCEINLINE
DWORD
HEAP_MAKE_TAG_FLAGS (
__in DWORD TagBase,
__in DWORD Tag
)

{
__assume_bound(TagBase);
return ((DWORD)((TagBase) + ((Tag) << HEAP_TAG_SHIFT)));
}
#endif

#if (NTDDI_VERSION > NTDDI_WINXP)
NTSYSAPI
WORD
NTAPI
RtlCaptureStackBackTrace(
__in DWORD FramesToSkip,
__in DWORD FramesToCapture,
__out_ecount(FramesToCapture) PVOID *BackTrace,
__out_opt PDWORD BackTraceHash
);
#endif

#if (NTDDI_VERSION > NTDDI_WIN2K)
NTSYSAPI
VOID
NTAPI
RtlCaptureContext (
__out PCONTEXT ContextRecord
);
#endif


#define IS_TEXT_UNICODE_ASCII16 0x0001
#define IS_TEXT_UNICODE_REVERSE_ASCII16 0x0010

#define IS_TEXT_UNICODE_STATISTICS 0x0002
#define IS_TEXT_UNICODE_REVERSE_STATISTICS 0x0020

#define IS_TEXT_UNICODE_CONTROLS 0x0004
#define IS_TEXT_UNICODE_REVERSE_CONTROLS 0x0040

#define IS_TEXT_UNICODE_SIGNATURE 0x0008
#define IS_TEXT_UNICODE_REVERSE_SIGNATURE 0x0080

#define IS_TEXT_UNICODE_ILLEGAL_CHARS 0x0100
#define IS_TEXT_UNICODE_ODD_LENGTH 0x0200
#define IS_TEXT_UNICODE_DBCS_LEADBYTE 0x0400
#define IS_TEXT_UNICODE_NULL_BYTES 0x1000

#define IS_TEXT_UNICODE_UNICODE_MASK 0x000F
#define IS_TEXT_UNICODE_REVERSE_MASK 0x00F0
#define IS_TEXT_UNICODE_NOT_UNICODE_MASK 0x0F00
#define IS_TEXT_UNICODE_NOT_ASCII_MASK 0xF000

#define COMPRESSION_FORMAT_NONE (0x0000)
#define COMPRESSION_FORMAT_DEFAULT (0x0001)
#define COMPRESSION_FORMAT_LZNT1 (0x0002)
#define COMPRESSION_ENGINE_STANDARD (0x0000)
#define COMPRESSION_ENGINE_MAXIMUM (0x0100)
#define COMPRESSION_ENGINE_HIBER (0x0200)

#if _DBG_MEMCPY_INLINE_ && !defined(MIDL_PASS) && !defined(_MEMCPY_INLINE_) && !defined(_CRTBLD)
#define _MEMCPY_INLINE_
FORCEINLINE
PVOID
__cdecl
memcpy_inline (
__out_bcount_full(size) void *dst,
__in_bcount(size) const void *src,
__in size_t size
)
{
//
// Make sure the source and destination do not overlap such that the
// move destroys the destination.
//
if (((char *)dst > (char *)src) &&
((char *)dst < ((char *)src + size))) {
__debugbreak();
}
return memcpy(dst, src, size);
}
#define memcpy memcpy_inline
#endif

#if (NTDDI_VERSION >= NTDDI_WIN2K)
__checkReturn
NTSYSAPI
SIZE_T
NTAPI
RtlCompareMemory (
__in const VOID *Source1,
__in const VOID *Source2,
__in SIZE_T Length
);

#endif

#define RtlEqualMemory(Destination,Source,Length) (!memcmp((Destination),(Source),(Length)))
#define RtlMoveMemory(Destination,Source,Length) memmove((Destination),(Source),(Length))
#define RtlCopyMemory(Destination,Source,Length) memcpy((Destination),(Source),(Length))
#define RtlFillMemory(Destination,Length,Fill) memset((Destination),(Fill),(Length))
#define RtlZeroMemory(Destination,Length) memset((Destination),0,(Length))


#if !defined(MIDL_PASS)

FORCEINLINE
PVOID
RtlSecureZeroMemory(
__out_bcount_full(cnt) PVOID ptr,
__in SIZE_T cnt
)
{
volatile char *vptr = (volatile char *)ptr;

#if defined(_M_AMD64)

__stosb((PBYTE )((DWORD64)vptr), 0, cnt);

#else

while (cnt) {
*vptr = 0;
vptr++;
cnt--;
}

#endif

return ptr;
}

#endif


#define SEF_DACL_AUTO_INHERIT 0x01
#define SEF_SACL_AUTO_INHERIT 0x02
#define SEF_DEFAULT_DESCRIPTOR_FOR_OBJECT 0x04
#define SEF_AVOID_PRIVILEGE_CHECK 0x08
#define SEF_AVOID_OWNER_CHECK 0x10
#define SEF_DEFAULT_OWNER_FROM_PARENT 0x20
#define SEF_DEFAULT_GROUP_FROM_PARENT 0x40
#define SEF_MACL_NO_WRITE_UP 0x100
#define SEF_MACL_NO_READ_UP 0x200
#define SEF_MACL_NO_EXECUTE_UP 0x400
#define SEF_AVOID_OWNER_RESTRICTION 0x1000

#define SEF_MACL_VALID_FLAGS (SEF_MACL_NO_WRITE_UP | \
SEF_MACL_NO_READ_UP | \
SEF_MACL_NO_EXECUTE_UP)


typedef struct _MESSAGE_RESOURCE_ENTRY {
WORD Length;
WORD Flags;
BYTE Text[ 1 ];
} MESSAGE_RESOURCE_ENTRY, *PMESSAGE_RESOURCE_ENTRY;

#define MESSAGE_RESOURCE_UNICODE 0x0001

typedef struct _MESSAGE_RESOURCE_BLOCK {
DWORD LowId;
DWORD HighId;
DWORD OffsetToEntries;
} MESSAGE_RESOURCE_BLOCK, *PMESSAGE_RESOURCE_BLOCK;

typedef struct _MESSAGE_RESOURCE_DATA {
DWORD NumberOfBlocks;
MESSAGE_RESOURCE_BLOCK Blocks[ 1 ];
} MESSAGE_RESOURCE_DATA, *PMESSAGE_RESOURCE_DATA;


NTSYSAPI
PVOID
NTAPI
RtlPcToFileHeader(
__in PVOID PcValue,
__out PVOID *BaseOfImage
);

typedef struct _OSVERSIONINFOA {
DWORD dwOSVersionInfoSize;
DWORD dwMajorVersion;
DWORD dwMinorVersion;
DWORD dwBuildNumber;
DWORD dwPlatformId;
CHAR szCSDVersion[ 128 ]; // Maintenance string for PSS usage
} OSVERSIONINFOA, *POSVERSIONINFOA, *LPOSVERSIONINFOA;

typedef struct _OSVERSIONINFOW {
DWORD dwOSVersionInfoSize;
DWORD dwMajorVersion;
DWORD dwMinorVersion;
DWORD dwBuildNumber;
DWORD dwPlatformId;
WCHAR szCSDVersion[ 128 ]; // Maintenance string for PSS usage
} OSVERSIONINFOW, *POSVERSIONINFOW, *LPOSVERSIONINFOW, RTL_OSVERSIONINFOW, *PRTL_OSVERSIONINFOW;
#ifdef UNICODE
typedef OSVERSIONINFOW OSVERSIONINFO;
typedef POSVERSIONINFOW POSVERSIONINFO;
typedef LPOSVERSIONINFOW LPOSVERSIONINFO;
#else
typedef OSVERSIONINFOA OSVERSIONINFO;
typedef POSVERSIONINFOA POSVERSIONINFO;
typedef LPOSVERSIONINFOA LPOSVERSIONINFO;
#endif // UNICODE

typedef struct _OSVERSIONINFOEXA {
DWORD dwOSVersionInfoSize;
DWORD dwMajorVersion;
DWORD dwMinorVersion;
DWORD dwBuildNumber;
DWORD dwPlatformId;
CHAR szCSDVersion[ 128 ]; // Maintenance string for PSS usage
WORD wServicePackMajor;
WORD wServicePackMinor;
WORD wSuiteMask;
BYTE wProductType;
BYTE wReserved;
} OSVERSIONINFOEXA, *POSVERSIONINFOEXA, *LPOSVERSIONINFOEXA;
typedef struct _OSVERSIONINFOEXW {
DWORD dwOSVersionInfoSize;
DWORD dwMajorVersion;
DWORD dwMinorVersion;
DWORD dwBuildNumber;
DWORD dwPlatformId;
WCHAR szCSDVersion[ 128 ]; // Maintenance string for PSS usage
WORD wServicePackMajor;
WORD wServicePackMinor;
WORD wSuiteMask;
BYTE wProductType;
BYTE wReserved;
} OSVERSIONINFOEXW, *POSVERSIONINFOEXW, *LPOSVERSIONINFOEXW, RTL_OSVERSIONINFOEXW, *PRTL_OSVERSIONINFOEXW;
#ifdef UNICODE
typedef OSVERSIONINFOEXW OSVERSIONINFOEX;
typedef POSVERSIONINFOEXW POSVERSIONINFOEX;
typedef LPOSVERSIONINFOEXW LPOSVERSIONINFOEX;
#else
typedef OSVERSIONINFOEXA OSVERSIONINFOEX;
typedef POSVERSIONINFOEXA POSVERSIONINFOEX;
typedef LPOSVERSIONINFOEXA LPOSVERSIONINFOEX;
#endif // UNICODE

//
// RtlVerifyVersionInfo() conditions
//

#define VER_EQUAL 1
#define VER_GREATER 2
#define VER_GREATER_EQUAL 3
#define VER_LESS 4
#define VER_LESS_EQUAL 5
#define VER_AND 6
#define VER_OR 7

#define VER_CONDITION_MASK 7
#define VER_NUM_BITS_PER_CONDITION_MASK 3

//
// RtlVerifyVersionInfo() type mask bits
//

#define VER_MINORVERSION 0x0000001
#define VER_MAJORVERSION 0x0000002
#define VER_BUILDNUMBER 0x0000004
#define VER_PLATFORMID 0x0000008
#define VER_SERVICEPACKMINOR 0x0000010
#define VER_SERVICEPACKMAJOR 0x0000020
#define VER_SUITENAME 0x0000040
#define VER_PRODUCT_TYPE 0x0000080

//
// RtlVerifyVersionInfo() os product type values
//

#define VER_NT_WORKSTATION 0x0000001
#define VER_NT_DOMAIN_CONTROLLER 0x0000002
#define VER_NT_SERVER 0x0000003

//
// dwPlatformId defines:
//

#define VER_PLATFORM_WIN32s 0
#define VER_PLATFORM_WIN32_WINDOWS 1
#define VER_PLATFORM_WIN32_NT 2


//
//
// VerifyVersionInfo() macro to set the condition mask
//
// For documentation sakes here‘s the old version of the macro that got
// changed to call an API
// #define VER_SET_CONDITION(_m_,_t_,_c_) _m_=(_m_|(_c_<<(1<<_t_)))
//

#define VER_SET_CONDITION(_m_,_t_,_c_) \
((_m_)=VerSetConditionMask((_m_),(_t_),(_c_)))

#if (NTDDI_VERSION >= NTDDI_WIN2K)
NTSYSAPI
ULONGLONG
NTAPI
VerSetConditionMask(
__in ULONGLONG ConditionMask,
__in DWORD TypeMask,
__in BYTE Condition
);
#endif

//

#if (NTDDI_VERSION >= NTDDI_VISTA)

NTSYSAPI
BOOLEAN
NTAPI
RtlGetProductInfo(
__in DWORD OSMajorVersion,
__in DWORD OSMinorVersion,
__in DWORD SpMajorVersion,
__in DWORD SpMinorVersion,
__out PDWORD ReturnedProductType
);

#endif

#define RTL_UMS_VERSION (0x0100)

typedef enum _RTL_UMS_THREAD_INFO_CLASS {
UmsThreadInvalidInfoClass = 0,
UmsThreadUserContext,
UmsThreadPriority,
UmsThreadAffinity,
UmsThreadTeb,
UmsThreadIsSuspended,
UmsThreadIsTerminated,
UmsThreadMaxInfoClass
} RTL_UMS_THREAD_INFO_CLASS, *PRTL_UMS_THREAD_INFO_CLASS;

typedef enum _RTL_UMS_SCHEDULER_REASON {
UmsSchedulerStartup = 0,
UmsSchedulerThreadBlocked,
UmsSchedulerThreadYield,
} RTL_UMS_SCHEDULER_REASON, *PRTL_UMS_SCHEDULER_REASON;

typedef
__drv_functionClass(RTL_UMS_SCHEDULER_ENTRY_POINT)
VOID
NTAPI
RTL_UMS_SCHEDULER_ENTRY_POINT(
__in RTL_UMS_SCHEDULER_REASON Reason,
__in ULONG_PTR ActivationPayload,
__in PVOID SchedulerParam
);

typedef RTL_UMS_SCHEDULER_ENTRY_POINT *PRTL_UMS_SCHEDULER_ENTRY_POINT;


#if (NTDDI_VERSION >= NTDDI_WIN7)


NTSYSAPI
DWORD
NTAPI
RtlCopyExtendedContext (
__out PCONTEXT_EX Destination,
__in DWORD ContextFlags,
__in PCONTEXT_EX Source
);

NTSYSAPI
DWORD
NTAPI
RtlInitializeExtendedContext (
__out PVOID Context,
__in DWORD ContextFlags,
__out PCONTEXT_EX* ContextEx
);

NTSYSAPI
DWORD64
NTAPI
RtlGetEnabledExtendedFeatures (
__in DWORD64 FeatureMask
);


NTSYSAPI
DWORD
NTAPI
RtlGetExtendedContextLength (
__in DWORD ContextFlags,
__out PDWORD ContextLength
);

NTSYSAPI
DWORD64
NTAPI
RtlGetExtendedFeaturesMask (
__in PCONTEXT_EX ContextEx
);

NTSYSAPI
PVOID
NTAPI
RtlLocateExtendedFeature (
__in PCONTEXT_EX ContextEx,
__in DWORD FeatureId,
__out_opt PDWORD Length
);

NTSYSAPI
PCONTEXT
NTAPI
RtlLocateLegacyContext (
__in PCONTEXT_EX ContextEx,
__out_opt PDWORD Length
);

NTSYSAPI
VOID
NTAPI
RtlSetExtendedFeaturesMask (
__out PCONTEXT_EX ContextEx,
__in DWORD64 FeatureMask
);

#endif


typedef struct _RTL_CRITICAL_SECTION_DEBUG {
WORD Type;
WORD CreatorBackTraceIndex;
struct _RTL_CRITICAL_SECTION *CriticalSection;
LIST_ENTRY ProcessLocksList;
DWORD EntryCount;
DWORD ContentionCount;
DWORD Flags;
WORD CreatorBackTraceIndexHigh;
WORD SpareWORD ;
} RTL_CRITICAL_SECTION_DEBUG, *PRTL_CRITICAL_SECTION_DEBUG, RTL_RESOURCE_DEBUG, *PRTL_RESOURCE_DEBUG;

#define RTL_CRITSECT_TYPE 0
#define RTL_RESOURCE_TYPE 1

//
// These flags define the upper byte of the critical section SpinCount field
//
#define RTL_CRITICAL_SECTION_FLAG_NO_DEBUG_INFO 0x01000000
#define RTL_CRITICAL_SECTION_FLAG_DYNAMIC_SPIN 0x02000000
#define RTL_CRITICAL_SECTION_FLAG_STATIC_INIT 0x04000000
#define RTL_CRITICAL_SECTION_ALL_FLAG_BITS 0xFF000000
#define RTL_CRITICAL_SECTION_FLAG_RESERVED (RTL_CRITICAL_SECTION_ALL_FLAG_BITS & (~(RTL_CRITICAL_SECTION_FLAG_NO_DEBUG_INFO | RTL_CRITICAL_SECTION_FLAG_DYNAMIC_SPIN | RTL_CRITICAL_SECTION_FLAG_STATIC_INIT)))

//
// These flags define possible values stored in the Flags field of a critsec debuginfo.
//
#define RTL_CRITICAL_SECTION_DEBUG_FLAG_STATIC_INIT 0x00000001

#pragma pack(push, 8)

typedef struct _RTL_CRITICAL_SECTION {
PRTL_CRITICAL_SECTION_DEBUG DebugInfo;

//
// The following three fields control entering and exiting the critical
// section for the resource
//

LONG LockCount;
LONG RecursionCount;
HANDLE OwningThread; // from the thread‘s ClientId->UniqueThread
HANDLE LockSemaphore;
ULONG_PTR SpinCount; // force size on 64-bit systems when packed
} RTL_CRITICAL_SECTION, *PRTL_CRITICAL_SECTION;

#pragma pack(pop)

typedef struct _RTL_SRWLOCK {
PVOID Ptr;
} RTL_SRWLOCK, *PRTL_SRWLOCK;
#define RTL_SRWLOCK_INIT {0}
typedef struct _RTL_CONDITION_VARIABLE {
PVOID Ptr;
} RTL_CONDITION_VARIABLE, *PRTL_CONDITION_VARIABLE;
#define RTL_CONDITION_VARIABLE_INIT {0}
#define RTL_CONDITION_VARIABLE_LOCKMODE_SHARED 0x1
typedef
VOID
(NTAPI *PAPCFUNC)(
__in ULONG_PTR Parameter
);
typedef LONG (NTAPI *PVECTORED_EXCEPTION_HANDLER)(
struct _EXCEPTION_POINTERS *ExceptionInfo
);

typedef enum _HEAP_INFORMATION_CLASS {

HeapCompatibilityInformation,
HeapEnableTerminationOnCorruption


} HEAP_INFORMATION_CLASS;


#define WT_EXECUTEDEFAULT 0x00000000
#define WT_EXECUTEINIOTHREAD 0x00000001
#define WT_EXECUTEINUITHREAD 0x00000002
#define WT_EXECUTEINWAITTHREAD 0x00000004
#define WT_EXECUTEONLYONCE 0x00000008
#define WT_EXECUTEINTIMERTHREAD 0x00000020
#define WT_EXECUTELONGFUNCTION 0x00000010
#define WT_EXECUTEINPERSISTENTIOTHREAD 0x00000040
#define WT_EXECUTEINPERSISTENTTHREAD 0x00000080
#define WT_TRANSFER_IMPERSONATION 0x00000100
#define WT_SET_MAX_THREADPOOL_THREADS(Flags, Limit) ((Flags) |= (Limit)<<16)
typedef VOID (NTAPI * WAITORTIMERCALLBACKFUNC) (PVOID, BOOLEAN );
typedef VOID (NTAPI * WORKERCALLBACKFUNC) (PVOID );
typedef VOID (NTAPI * APC_CALLBACK_FUNCTION) (DWORD , PVOID, PVOID);
typedef
VOID
(NTAPI *PFLS_CALLBACK_FUNCTION) (
IN PVOID lpFlsData
);

typedef
BOOLEAN
(NTAPI *PSECURE_MEMORY_CACHE_CALLBACK) (
__in_bcount(Range) PVOID Addr,
__in SIZE_T Range
);

#define WT_EXECUTEINLONGTHREAD 0x00000010
#define WT_EXECUTEDELETEWAIT 0x00000008

typedef enum _ACTIVATION_CONTEXT_INFO_CLASS {
ActivationContextBasicInformation = 1,
ActivationContextDetailedInformation = 2,
AssemblyDetailedInformationInActivationContext = 3,
FileInformationInAssemblyOfAssemblyInActivationContext = 4,
RunlevelInformationInActivationContext = 5,
CompatibilityInformationInActivationContext = 6,
ActivationContextManifestResourceName = 7,
MaxActivationContextInfoClass,

//
// compatibility with old names
//
AssemblyDetailedInformationInActivationContxt = 3,
FileInformationInAssemblyOfAssemblyInActivationContxt = 4
} ACTIVATION_CONTEXT_INFO_CLASS;

#define ACTIVATIONCONTEXTINFOCLASS ACTIVATION_CONTEXT_INFO_CLASS


typedef struct _ACTIVATION_CONTEXT_QUERY_INDEX {
DWORD ulAssemblyIndex;
DWORD ulFileIndexInAssembly;
} ACTIVATION_CONTEXT_QUERY_INDEX, * PACTIVATION_CONTEXT_QUERY_INDEX;

typedef const struct _ACTIVATION_CONTEXT_QUERY_INDEX * PCACTIVATION_CONTEXT_QUERY_INDEX;


#define ACTIVATION_CONTEXT_PATH_TYPE_NONE (1)
#define ACTIVATION_CONTEXT_PATH_TYPE_WIN32_FILE (2)
#define ACTIVATION_CONTEXT_PATH_TYPE_URL (3)
#define ACTIVATION_CONTEXT_PATH_TYPE_ASSEMBLYREF (4)

typedef struct _ASSEMBLY_FILE_DETAILED_INFORMATION {
DWORD ulFlags;
DWORD ulFilenameLength;
DWORD ulPathLength;

PCWSTR lpFileName;
PCWSTR lpFilePath;
} ASSEMBLY_FILE_DETAILED_INFORMATION, *PASSEMBLY_FILE_DETAILED_INFORMATION;
typedef const ASSEMBLY_FILE_DETAILED_INFORMATION *PCASSEMBLY_FILE_DETAILED_INFORMATION;

//
// compatibility with old names
// The new names use "file" consistently.
//
#define _ASSEMBLY_DLL_REDIRECTION_DETAILED_INFORMATION _ASSEMBLY_FILE_DETAILED_INFORMATION
#define ASSEMBLY_DLL_REDIRECTION_DETAILED_INFORMATION ASSEMBLY_FILE_DETAILED_INFORMATION
#define PASSEMBLY_DLL_REDIRECTION_DETAILED_INFORMATION PASSEMBLY_FILE_DETAILED_INFORMATION
#define PCASSEMBLY_DLL_REDIRECTION_DETAILED_INFORMATION PCASSEMBLY_FILE_DETAILED_INFORMATION

typedef struct _ACTIVATION_CONTEXT_ASSEMBLY_DETAILED_INFORMATION {
DWORD ulFlags;
DWORD ulEncodedAssemblyIdentityLength; // in bytes
DWORD ulManifestPathType; // ACTIVATION_CONTEXT_PATH_TYPE_*
DWORD ulManifestPathLength; // in bytes
LARGE_INTEGER liManifestLastWriteTime; // FILETIME
DWORD ulPolicyPathType; // ACTIVATION_CONTEXT_PATH_TYPE_*
DWORD ulPolicyPathLength; // in bytes
LARGE_INTEGER liPolicyLastWriteTime; // FILETIME
DWORD ulMetadataSatelliteRosterIndex;

DWORD ulManifestVersionMajor; // 1
DWORD ulManifestVersionMinor; // 0
DWORD ulPolicyVersionMajor; // 0
DWORD ulPolicyVersionMinor; // 0
DWORD ulAssemblyDirectoryNameLength; // in bytes

PCWSTR lpAssemblyEncodedAssemblyIdentity;
PCWSTR lpAssemblyManifestPath;
PCWSTR lpAssemblyPolicyPath;
PCWSTR lpAssemblyDirectoryName;

DWORD ulFileCount;
} ACTIVATION_CONTEXT_ASSEMBLY_DETAILED_INFORMATION, * PACTIVATION_CONTEXT_ASSEMBLY_DETAILED_INFORMATION;

typedef const struct _ACTIVATION_CONTEXT_ASSEMBLY_DETAILED_INFORMATION * PCACTIVATION_CONTEXT_ASSEMBLY_DETAILED_INFORMATION ;

typedef enum
{
ACTCTX_RUN_LEVEL_UNSPECIFIED = 0,
ACTCTX_RUN_LEVEL_AS_INVOKER,
ACTCTX_RUN_LEVEL_HIGHEST_AVAILABLE,
ACTCTX_RUN_LEVEL_REQUIRE_ADMIN,
ACTCTX_RUN_LEVEL_NUMBERS
} ACTCTX_REQUESTED_RUN_LEVEL;

typedef struct _ACTIVATION_CONTEXT_RUN_LEVEL_INFORMATION {
DWORD ulFlags;
ACTCTX_REQUESTED_RUN_LEVEL RunLevel;
DWORD UiAccess;
} ACTIVATION_CONTEXT_RUN_LEVEL_INFORMATION, * PACTIVATION_CONTEXT_RUN_LEVEL_INFORMATION;

typedef const struct _ACTIVATION_CONTEXT_RUN_LEVEL_INFORMATION * PCACTIVATION_CONTEXT_RUN_LEVEL_INFORMATION ;

typedef enum
{
ACTCTX_COMPATIBILITY_ELEMENT_TYPE_UNKNOWN = 0,
ACTCTX_COMPATIBILITY_ELEMENT_TYPE_OS,
ACTCTX_COMPATIBILITY_ELEMENT_TYPE_MITIGATION
} ACTCTX_COMPATIBILITY_ELEMENT_TYPE;

typedef struct _COMPATIBILITY_CONTEXT_ELEMENT {
GUID Id;
ACTCTX_COMPATIBILITY_ELEMENT_TYPE Type;
} COMPATIBILITY_CONTEXT_ELEMENT, *PCOMPATIBILITY_CONTEXT_ELEMENT;

typedef const struct _COMPATIBILITY_CONTEXT_ELEMENT *PCCOMPATIBILITY_CONTEXT_ELEMENT;

#pragma warning(push)
#pragma warning(disable:4200)

typedef struct _ACTIVATION_CONTEXT_COMPATIBILITY_INFORMATION {
DWORD ElementCount;
COMPATIBILITY_CONTEXT_ELEMENT Elements[];
} ACTIVATION_CONTEXT_COMPATIBILITY_INFORMATION, * PACTIVATION_CONTEXT_COMPATIBILITY_INFORMATION;

#pragma warning(pop)

typedef const struct _ACTIVATION_CONTEXT_COMPATIBILITY_INFORMATION * PCACTIVATION_CONTEXT_COMPATIBILITY_INFORMATION;

#define MAX_SUPPORTED_OS_NUM (4)
#define INVALID_OS_COUNT (0xffff)

typedef struct _SUPPORTED_OS_INFO {
WORD OsCount;
WORD MitigationExist;
WORD OsList[MAX_SUPPORTED_OS_NUM];
} SUPPORTED_OS_INFO, *PSUPPORTED_OS_INFO;

typedef struct _ACTIVATION_CONTEXT_DETAILED_INFORMATION {
DWORD dwFlags;
DWORD ulFormatVersion;
DWORD ulAssemblyCount;
DWORD ulRootManifestPathType;
DWORD ulRootManifestPathChars;
DWORD ulRootConfigurationPathType;
DWORD ulRootConfigurationPathChars;
DWORD ulAppDirPathType;
DWORD ulAppDirPathChars;
PCWSTR lpRootManifestPath;
PCWSTR lpRootConfigurationPath;
PCWSTR lpAppDirPath;
} ACTIVATION_CONTEXT_DETAILED_INFORMATION, *PACTIVATION_CONTEXT_DETAILED_INFORMATION;

typedef const struct _ACTIVATION_CONTEXT_DETAILED_INFORMATION *PCACTIVATION_CONTEXT_DETAILED_INFORMATION;

typedef struct _HARDWARE_COUNTER_DATA {
HARDWARE_COUNTER_TYPE Type;
DWORD Reserved;
DWORD64 Value;
} HARDWARE_COUNTER_DATA, *PHARDWARE_COUNTER_DATA;

#define PERFORMANCE_DATA_VERSION 1

typedef struct _PERFORMANCE_DATA {
WORD Size;
BYTE Version;
BYTE HwCountersCount;
DWORD ContextSwitchCount;
DWORD64 WaitReasonBitMap;
DWORD64 CycleTime;
DWORD RetryCount;
DWORD Reserved;
HARDWARE_COUNTER_DATA HwCounters[MAX_HW_COUNTERS];
} PERFORMANCE_DATA, *PPERFORMANCE_DATA;

#define READ_THREAD_PROFILING_FLAG_DISPATCHING 0x00000001
#define READ_THREAD_PROFILING_FLAG_HARDWARE_COUNTERS 0x00000002
#define DLL_PROCESS_ATTACH 1
#define DLL_THREAD_ATTACH 2
#define DLL_THREAD_DETACH 3
#define DLL_PROCESS_DETACH 0

//
// Defines for the READ flags for Eventlogging
//
#define EVENTLOG_SEQUENTIAL_READ 0x0001
#define EVENTLOG_SEEK_READ 0x0002
#define EVENTLOG_FORWARDS_READ 0x0004
#define EVENTLOG_BACKWARDS_READ 0x0008

//
// The types of events that can be logged.
//
#define EVENTLOG_SUCCESS 0x0000
#define EVENTLOG_ERROR_TYPE 0x0001
#define EVENTLOG_WARNING_TYPE 0x0002
#define EVENTLOG_INFORMATION_TYPE 0x0004
#define EVENTLOG_AUDIT_SUCCESS 0x0008
#define EVENTLOG_AUDIT_FAILURE 0x0010

//
// Defines for the WRITE flags used by Auditing for paired events
// These are not implemented in Product 1
//

#define EVENTLOG_START_PAIRED_EVENT 0x0001
#define EVENTLOG_END_PAIRED_EVENT 0x0002
#define EVENTLOG_END_ALL_PAIRED_EVENTS 0x0004
#define EVENTLOG_PAIRED_EVENT_ACTIVE 0x0008
#define EVENTLOG_PAIRED_EVENT_INACTIVE 0x0010

//
// Structure that defines the header of the Eventlog record. This is the
// fixed-sized portion before all the variable-length strings, binary
// data and pad bytes.
//
// TimeGenerated is the time it was generated at the client.
// TimeWritten is the time it was put into the log at the server end.
//

typedef struct _EVENTLOGRECORD {
DWORD Length; // Length of full record
DWORD Reserved; // Used by the service
DWORD RecordNumber; // Absolute record number
DWORD TimeGenerated; // Seconds since 1-1-1970
DWORD TimeWritten; // Seconds since 1-1-1970
DWORD EventID;
WORD EventType;
WORD NumStrings;
WORD EventCategory;
WORD ReservedFlags; // For use with paired events (auditing)
DWORD ClosingRecordNumber; // For use with paired events (auditing)
DWORD StringOffset; // Offset from beginning of record
DWORD UserSidLength;
DWORD UserSidOffset;
DWORD DataLength;
DWORD DataOffset; // Offset from beginning of record
//
// Then follow:
//
// WCHAR SourceName[]
// WCHAR Computername[]
// SID UserSid
// WCHAR Strings[]
// BYTE Data[]
// CHAR Pad[]
// DWORD Length;
//
} EVENTLOGRECORD, *PEVENTLOGRECORD;

//SS: start of changes to support clustering
//SS: ideally the
#define MAXLOGICALLOGNAMESIZE 256

#if _MSC_VER >= 1200
#pragma warning(push)
#endif
#pragma warning(disable : 4200) /* nonstandard extension used : zero-sized array in struct/union */

struct _EVENTSFORLOGFILE;
typedef struct _EVENTSFORLOGFILE EVENTSFORLOGFILE, *PEVENTSFORLOGFILE;

struct _PACKEDEVENTINFO;
typedef struct _PACKEDEVENTINFO PACKEDEVENTINFO, *PPACKEDEVENTINFO;

#if defined(_MSC_EXTENSIONS)

struct _EVENTSFORLOGFILE
{
DWORD ulSize;
WCHAR szLogicalLogFile[MAXLOGICALLOGNAMESIZE]; //name of the logical file-security/application/system
DWORD ulNumRecords;
EVENTLOGRECORD pEventLogRecords[];
};

struct _PACKEDEVENTINFO
{
DWORD ulSize; //total size of the structure
DWORD ulNumEventsForLogFile; //number of EventsForLogFile structure that follow
DWORD ulOffsets[]; //the offsets from the start of this structure to the EVENTSFORLOGFILE structure
};

#endif

#if _MSC_VER >= 1200
#pragma warning(pop)
#else
#pragma warning(default : 4200) /* nonstandard extension used : zero-sized array in struct/union */
#endif
//SS: end of changes to support clustering
//

// begin_wdm
//
// Registry Specific Access Rights.
//

#define KEY_QUERY_VALUE (0x0001)
#define KEY_SET_VALUE (0x0002)
#define KEY_CREATE_SUB_KEY (0x0004)
#define KEY_ENUMERATE_SUB_KEYS (0x0008)
#define KEY_NOTIFY (0x0010)
#define KEY_CREATE_LINK (0x0020)
#define KEY_WOW64_32KEY (0x0200)
#define KEY_WOW64_64KEY (0x0100)
#define KEY_WOW64_RES (0x0300)

#define KEY_READ ((STANDARD_RIGHTS_READ |\
KEY_QUERY_VALUE |\
KEY_ENUMERATE_SUB_KEYS |\
KEY_NOTIFY) \
& \
(~SYNCHRONIZE))


#define KEY_WRITE ((STANDARD_RIGHTS_WRITE |\
KEY_SET_VALUE |\
KEY_CREATE_SUB_KEY) \
& \
(~SYNCHRONIZE))

#define KEY_EXECUTE ((KEY_READ) \
& \
(~SYNCHRONIZE))

#define KEY_ALL_ACCESS ((STANDARD_RIGHTS_ALL |\
KEY_QUERY_VALUE |\
KEY_SET_VALUE |\
KEY_CREATE_SUB_KEY |\
KEY_ENUMERATE_SUB_KEYS |\
KEY_NOTIFY |\
KEY_CREATE_LINK) \
& \
(~SYNCHRONIZE))

//
// Open/Create Options
//

#define REG_OPTION_RESERVED (0x00000000L) // Parameter is reserved

#define REG_OPTION_NON_VOLATILE (0x00000000L) // Key is preserved
// when system is rebooted

#define REG_OPTION_VOLATILE (0x00000001L) // Key is not preserved
// when system is rebooted

#define REG_OPTION_CREATE_LINK (0x00000002L) // Created key is a
// symbolic link

#define REG_OPTION_BACKUP_RESTORE (0x00000004L) // open for backup or restore
// special access rules
// privilege required

#define REG_OPTION_OPEN_LINK (0x00000008L) // Open symbolic link

#define REG_LEGAL_OPTION \
(REG_OPTION_RESERVED |\
REG_OPTION_NON_VOLATILE |\
REG_OPTION_VOLATILE |\
REG_OPTION_CREATE_LINK |\
REG_OPTION_BACKUP_RESTORE |\
REG_OPTION_OPEN_LINK)

#define REG_OPEN_LEGAL_OPTION \
(REG_OPTION_RESERVED |\
REG_OPTION_BACKUP_RESTORE |\
REG_OPTION_OPEN_LINK)

//
// Key creation/open disposition
//

#define REG_CREATED_NEW_KEY (0x00000001L) // New Registry Key created
#define REG_OPENED_EXISTING_KEY (0x00000002L) // Existing Key opened

//
// hive format to be used by Reg(Nt)SaveKeyEx
//
#define REG_STANDARD_FORMAT 1
#define REG_LATEST_FORMAT 2
#define REG_NO_COMPRESSION 4

//
// Key restore & hive load flags
//

#define REG_WHOLE_HIVE_VOLATILE (0x00000001L) // Restore whole hive volatile
#define REG_REFRESH_HIVE (0x00000002L) // Unwind changes to last flush
#define REG_NO_LAZY_FLUSH (0x00000004L) // Never lazy flush this hive
#define REG_FORCE_RESTORE (0x00000008L) // Force the restore process even when we have open handles on subkeys
#define REG_APP_HIVE (0x00000010L) // Loads the hive visible to the calling process
#define REG_PROCESS_PRIVATE (0x00000020L) // Hive cannot be mounted by any other process while in use
#define REG_START_JOURNAL (0x00000040L) // Starts Hive Journal
#define REG_HIVE_EXACT_FILE_GROWTH (0x00000080L) // Grow hive file in exact 4k increments
#define REG_HIVE_NO_RM (0x00000100L) // No RM is started for this hive (no transactions)
#define REG_HIVE_SINGLE_LOG (0x00000200L) // Legacy single logging is used for this hive
#define REG_BOOT_HIVE (0x00000400L) // This hive might be used by the OS loader

//
// Unload Flags
//
#define REG_FORCE_UNLOAD 1

//
// Notify filter values
//

#define REG_NOTIFY_CHANGE_NAME (0x00000001L) // Create or delete (child)
#define REG_NOTIFY_CHANGE_ATTRIBUTES (0x00000002L)
#define REG_NOTIFY_CHANGE_LAST_SET (0x00000004L) // time stamp
#define REG_NOTIFY_CHANGE_SECURITY (0x00000008L)

#define REG_LEGAL_CHANGE_FILTER \
(REG_NOTIFY_CHANGE_NAME |\
REG_NOTIFY_CHANGE_ATTRIBUTES |\
REG_NOTIFY_CHANGE_LAST_SET |\
REG_NOTIFY_CHANGE_SECURITY)

// end_wdm

//
//
// Predefined Value Types.
//

#define REG_NONE ( 0 ) // No value type
#define REG_SZ ( 1 ) // Unicode nul terminated string
#define REG_EXPAND_SZ ( 2 ) // Unicode nul terminated string
// (with environment variable references)
#define REG_BINARY ( 3 ) // Free form binary
#define REG_DWORD ( 4 ) // 32-bit number
#define REG_DWORD_LITTLE_ENDIAN ( 4 ) // 32-bit number (same as REG_DWORD)
#define REG_DWORD_BIG_ENDIAN ( 5 ) // 32-bit number
#define REG_LINK ( 6 ) // Symbolic Link (unicode)
#define REG_MULTI_SZ ( 7 ) // Multiple Unicode strings
#define REG_RESOURCE_LIST ( 8 ) // Resource list in the resource map
#define REG_FULL_RESOURCE_DESCRIPTOR ( 9 ) // Resource list in the hardware description
#define REG_RESOURCE_REQUIREMENTS_LIST ( 10 )
#define REG_QWORD ( 11 ) // 64-bit number
#define REG_QWORD_LITTLE_ENDIAN ( 11 ) // 64-bit number (same as REG_QWORD)

// end_wdm

// begin_wdm
//
// Service Types (Bit Mask)
//
#define SERVICE_KERNEL_DRIVER 0x00000001
#define SERVICE_FILE_SYSTEM_DRIVER 0x00000002
#define SERVICE_ADAPTER 0x00000004
#define SERVICE_RECOGNIZER_DRIVER 0x00000008

#define SERVICE_DRIVER (SERVICE_KERNEL_DRIVER | \
SERVICE_FILE_SYSTEM_DRIVER | \
SERVICE_RECOGNIZER_DRIVER)

#define SERVICE_WIN32_OWN_PROCESS 0x00000010
#define SERVICE_WIN32_SHARE_PROCESS 0x00000020
#define SERVICE_WIN32 (SERVICE_WIN32_OWN_PROCESS | \
SERVICE_WIN32_SHARE_PROCESS)

#define SERVICE_INTERACTIVE_PROCESS 0x00000100

#define SERVICE_TYPE_ALL (SERVICE_WIN32 | \
SERVICE_ADAPTER | \
SERVICE_DRIVER | \
SERVICE_INTERACTIVE_PROCESS)

//
// Start Type
//

#define SERVICE_BOOT_START 0x00000000
#define SERVICE_SYSTEM_START 0x00000001
#define SERVICE_AUTO_START 0x00000002
#define SERVICE_DEMAND_START 0x00000003
#define SERVICE_DISABLED 0x00000004

//
// Error control type
//
#define SERVICE_ERROR_IGNORE 0x00000000
#define SERVICE_ERROR_NORMAL 0x00000001
#define SERVICE_ERROR_SEVERE 0x00000002
#define SERVICE_ERROR_CRITICAL 0x00000003

//
//
// Define the registry driver node enumerations
//

typedef enum _CM_SERVICE_NODE_TYPE {
DriverType = SERVICE_KERNEL_DRIVER,
FileSystemType = SERVICE_FILE_SYSTEM_DRIVER,
Win32ServiceOwnProcess = SERVICE_WIN32_OWN_PROCESS,
Win32ServiceShareProcess = SERVICE_WIN32_SHARE_PROCESS,
AdapterType = SERVICE_ADAPTER,
RecognizerType = SERVICE_RECOGNIZER_DRIVER
} SERVICE_NODE_TYPE;

typedef enum _CM_SERVICE_LOAD_TYPE {
BootLoad = SERVICE_BOOT_START,
SystemLoad = SERVICE_SYSTEM_START,
AutoLoad = SERVICE_AUTO_START,
DemandLoad = SERVICE_DEMAND_START,
DisableLoad = SERVICE_DISABLED
} SERVICE_LOAD_TYPE;

typedef enum _CM_ERROR_CONTROL_TYPE {
IgnoreError = SERVICE_ERROR_IGNORE,
NormalError = SERVICE_ERROR_NORMAL,
SevereError = SERVICE_ERROR_SEVERE,
CriticalError = SERVICE_ERROR_CRITICAL
} SERVICE_ERROR_TYPE;

//
// Service node Flags. These flags are used by the OS loader to promote
// a driver‘s start type to boot start if the system is booting using
// the specified mechanism. The flags should be set in the driver‘s
// registry configuration.
//
// CM_SERVICE_NETWORK_BOOT_LOAD - Specified if a driver should be
// promoted on network boot.
//
// CM_SERVICE_VIRTUAL_DISK_BOOT_LOAD - Specified if a driver should be
// promoted on booting from a VHD.
//
// CM_SERVICE_USB_DISK_BOOT_LOAD - Specified if a driver should be promoted
// while booting from a USB disk.
//

#define CM_SERVICE_NETWORK_BOOT_LOAD 0x00000001
#define CM_SERVICE_VIRTUAL_DISK_BOOT_LOAD 0x00000002
#define CM_SERVICE_USB_DISK_BOOT_LOAD 0x00000004

//
// Mask defining the legal promotion flag values.
//

#define CM_SERVICE_VALID_PROMOTION_MASK (CM_SERVICE_NETWORK_BOOT_LOAD | \
CM_SERVICE_VIRTUAL_DISK_BOOT_LOAD | \
CM_SERVICE_USB_DISK_BOOT_LOAD)

 

//
// IOCTL_TAPE_ERASE definitions
//

#define TAPE_ERASE_SHORT 0L
#define TAPE_ERASE_LONG 1L

typedef struct _TAPE_ERASE {
DWORD Type;
BOOLEAN Immediate;
} TAPE_ERASE, *PTAPE_ERASE;

//
// IOCTL_TAPE_PREPARE definitions
//

#define TAPE_LOAD 0L
#define TAPE_UNLOAD 1L
#define TAPE_TENSION 2L
#define TAPE_LOCK 3L
#define TAPE_UNLOCK 4L
#define TAPE_FORMAT 5L

typedef struct _TAPE_PREPARE {
DWORD Operation;
BOOLEAN Immediate;
} TAPE_PREPARE, *PTAPE_PREPARE;

//
// IOCTL_TAPE_WRITE_MARKS definitions
//

#define TAPE_SETMARKS 0L
#define TAPE_FILEMARKS 1L
#define TAPE_SHORT_FILEMARKS 2L
#define TAPE_LONG_FILEMARKS 3L

typedef struct _TAPE_WRITE_MARKS {
DWORD Type;
DWORD Count;
BOOLEAN Immediate;
} TAPE_WRITE_MARKS, *PTAPE_WRITE_MARKS;

//
// IOCTL_TAPE_GET_POSITION definitions
//

#define TAPE_ABSOLUTE_POSITION 0L
#define TAPE_LOGICAL_POSITION 1L
#define TAPE_PSEUDO_LOGICAL_POSITION 2L

typedef struct _TAPE_GET_POSITION {
DWORD Type;
DWORD Partition;
LARGE_INTEGER Offset;
} TAPE_GET_POSITION, *PTAPE_GET_POSITION;

//
// IOCTL_TAPE_SET_POSITION definitions
//

#define TAPE_REWIND 0L
#define TAPE_ABSOLUTE_BLOCK 1L
#define TAPE_LOGICAL_BLOCK 2L
#define TAPE_PSEUDO_LOGICAL_BLOCK 3L
#define TAPE_SPACE_END_OF_DATA 4L
#define TAPE_SPACE_RELATIVE_BLOCKS 5L
#define TAPE_SPACE_FILEMARKS 6L
#define TAPE_SPACE_SEQUENTIAL_FMKS 7L
#define TAPE_SPACE_SETMARKS 8L
#define TAPE_SPACE_SEQUENTIAL_SMKS 9L

typedef struct _TAPE_SET_POSITION {
DWORD Method;
DWORD Partition;
LARGE_INTEGER Offset;
BOOLEAN Immediate;
} TAPE_SET_POSITION, *PTAPE_SET_POSITION;

//
// IOCTL_TAPE_GET_DRIVE_PARAMS definitions
//

//
// Definitions for FeaturesLow parameter
//

#define TAPE_DRIVE_FIXED 0x00000001
#define TAPE_DRIVE_SELECT 0x00000002
#define TAPE_DRIVE_INITIATOR 0x00000004

#define TAPE_DRIVE_ERASE_SHORT 0x00000010
#define TAPE_DRIVE_ERASE_LONG 0x00000020
#define TAPE_DRIVE_ERASE_BOP_ONLY 0x00000040
#define TAPE_DRIVE_ERASE_IMMEDIATE 0x00000080

#define TAPE_DRIVE_TAPE_CAPACITY 0x00000100
#define TAPE_DRIVE_TAPE_REMAINING 0x00000200
#define TAPE_DRIVE_FIXED_BLOCK 0x00000400
#define TAPE_DRIVE_VARIABLE_BLOCK 0x00000800

#define TAPE_DRIVE_WRITE_PROTECT 0x00001000
#define TAPE_DRIVE_EOT_WZ_SIZE 0x00002000

#define TAPE_DRIVE_ECC 0x00010000
#define TAPE_DRIVE_COMPRESSION 0x00020000
#define TAPE_DRIVE_PADDING 0x00040000
#define TAPE_DRIVE_REPORT_SMKS 0x00080000

#define TAPE_DRIVE_GET_ABSOLUTE_BLK 0x00100000
#define TAPE_DRIVE_GET_LOGICAL_BLK 0x00200000
#define TAPE_DRIVE_SET_EOT_WZ_SIZE 0x00400000

#define TAPE_DRIVE_EJECT_MEDIA 0x01000000
#define TAPE_DRIVE_CLEAN_REQUESTS 0x02000000
#define TAPE_DRIVE_SET_CMP_BOP_ONLY 0x04000000

#define TAPE_DRIVE_RESERVED_BIT 0x80000000 //don‘t use this bit!
// //can‘t be a low features bit!
// //reserved; high features only

//
// Definitions for FeaturesHigh parameter
//

#define TAPE_DRIVE_LOAD_UNLOAD 0x80000001
#define TAPE_DRIVE_TENSION 0x80000002
#define TAPE_DRIVE_LOCK_UNLOCK 0x80000004
#define TAPE_DRIVE_REWIND_IMMEDIATE 0x80000008

#define TAPE_DRIVE_SET_BLOCK_SIZE 0x80000010
#define TAPE_DRIVE_LOAD_UNLD_IMMED 0x80000020
#define TAPE_DRIVE_TENSION_IMMED 0x80000040
#define TAPE_DRIVE_LOCK_UNLK_IMMED 0x80000080

#define TAPE_DRIVE_SET_ECC 0x80000100
#define TAPE_DRIVE_SET_COMPRESSION 0x80000200
#define TAPE_DRIVE_SET_PADDING 0x80000400
#define TAPE_DRIVE_SET_REPORT_SMKS 0x80000800

#define TAPE_DRIVE_ABSOLUTE_BLK 0x80001000
#define TAPE_DRIVE_ABS_BLK_IMMED 0x80002000
#define TAPE_DRIVE_LOGICAL_BLK 0x80004000
#define TAPE_DRIVE_LOG_BLK_IMMED 0x80008000

#define TAPE_DRIVE_END_OF_DATA 0x80010000
#define TAPE_DRIVE_RELATIVE_BLKS 0x80020000
#define TAPE_DRIVE_FILEMARKS 0x80040000
#define TAPE_DRIVE_SEQUENTIAL_FMKS 0x80080000

#define TAPE_DRIVE_SETMARKS 0x80100000
#define TAPE_DRIVE_SEQUENTIAL_SMKS 0x80200000
#define TAPE_DRIVE_REVERSE_POSITION 0x80400000
#define TAPE_DRIVE_SPACE_IMMEDIATE 0x80800000

#define TAPE_DRIVE_WRITE_SETMARKS 0x81000000
#define TAPE_DRIVE_WRITE_FILEMARKS 0x82000000
#define TAPE_DRIVE_WRITE_SHORT_FMKS 0x84000000
#define TAPE_DRIVE_WRITE_LONG_FMKS 0x88000000

#define TAPE_DRIVE_WRITE_MARK_IMMED 0x90000000
#define TAPE_DRIVE_FORMAT 0xA0000000
#define TAPE_DRIVE_FORMAT_IMMEDIATE 0xC0000000
#define TAPE_DRIVE_HIGH_FEATURES 0x80000000 //mask for high features flag

typedef struct _TAPE_GET_DRIVE_PARAMETERS {
BOOLEAN ECC;
BOOLEAN Compression;
BOOLEAN DataPadding;
BOOLEAN ReportSetmarks;
DWORD DefaultBlockSize;
DWORD MaximumBlockSize;
DWORD MinimumBlockSize;
DWORD MaximumPartitionCount;
DWORD FeaturesLow;
DWORD FeaturesHigh;
DWORD EOTWarningZoneSize;
} TAPE_GET_DRIVE_PARAMETERS, *PTAPE_GET_DRIVE_PARAMETERS;

//
// IOCTL_TAPE_SET_DRIVE_PARAMETERS definitions
//

typedef struct _TAPE_SET_DRIVE_PARAMETERS {
BOOLEAN ECC;
BOOLEAN Compression;
BOOLEAN DataPadding;
BOOLEAN ReportSetmarks;
DWORD EOTWarningZoneSize;
} TAPE_SET_DRIVE_PARAMETERS, *PTAPE_SET_DRIVE_PARAMETERS;

//
// IOCTL_TAPE_GET_MEDIA_PARAMETERS definitions
//

typedef struct _TAPE_GET_MEDIA_PARAMETERS {
LARGE_INTEGER Capacity;
LARGE_INTEGER Remaining;
DWORD BlockSize;
DWORD PartitionCount;
BOOLEAN WriteProtected;
} TAPE_GET_MEDIA_PARAMETERS, *PTAPE_GET_MEDIA_PARAMETERS;

//
// IOCTL_TAPE_SET_MEDIA_PARAMETERS definitions
//

typedef struct _TAPE_SET_MEDIA_PARAMETERS {
DWORD BlockSize;
} TAPE_SET_MEDIA_PARAMETERS, *PTAPE_SET_MEDIA_PARAMETERS;

//
// IOCTL_TAPE_CREATE_PARTITION definitions
//

#define TAPE_FIXED_PARTITIONS 0L
#define TAPE_SELECT_PARTITIONS 1L
#define TAPE_INITIATOR_PARTITIONS 2L

typedef struct _TAPE_CREATE_PARTITION {
DWORD Method;
DWORD Count;
DWORD Size;
} TAPE_CREATE_PARTITION, *PTAPE_CREATE_PARTITION;


//
// WMI Methods
//
#define TAPE_QUERY_DRIVE_PARAMETERS 0L
#define TAPE_QUERY_MEDIA_CAPACITY 1L
#define TAPE_CHECK_FOR_DRIVE_PROBLEM 2L
#define TAPE_QUERY_IO_ERROR_DATA 3L
#define TAPE_QUERY_DEVICE_ERROR_DATA 4L

typedef struct _TAPE_WMI_OPERATIONS {
DWORD Method;
DWORD DataBufferSize;
PVOID DataBuffer;
} TAPE_WMI_OPERATIONS, *PTAPE_WMI_OPERATIONS;

//
// Type of drive errors
//
typedef enum _TAPE_DRIVE_PROBLEM_TYPE {
TapeDriveProblemNone, TapeDriveReadWriteWarning,
TapeDriveReadWriteError, TapeDriveReadWarning,
TapeDriveWriteWarning, TapeDriveReadError,
TapeDriveWriteError, TapeDriveHardwareError,
TapeDriveUnsupportedMedia, TapeDriveScsiConnectionError,
TapeDriveTimetoClean, TapeDriveCleanDriveNow,
TapeDriveMediaLifeExpired, TapeDriveSnappedTape
} TAPE_DRIVE_PROBLEM_TYPE;

#ifndef _NTTMAPI_
#define _NTTMAPI_


#ifdef __cplusplus
extern "C" {
#endif


#include <ktmtypes.h>

//
// Types for Nt level TM calls
//

//
// KTM Tm object rights
//
#define TRANSACTIONMANAGER_QUERY_INFORMATION ( 0x0001 )
#define TRANSACTIONMANAGER_SET_INFORMATION ( 0x0002 )
#define TRANSACTIONMANAGER_RECOVER ( 0x0004 )
#define TRANSACTIONMANAGER_RENAME ( 0x0008 )
#define TRANSACTIONMANAGER_CREATE_RM ( 0x0010 )

// The following right is intended for DTC‘s use only; it will be
// deprecated, and no one else should take a dependency on it.
#define TRANSACTIONMANAGER_BIND_TRANSACTION ( 0x0020 )

//
// Generic mappings for transaction manager rights.
//

#define TRANSACTIONMANAGER_GENERIC_READ (STANDARD_RIGHTS_READ |\
TRANSACTIONMANAGER_QUERY_INFORMATION)

#define TRANSACTIONMANAGER_GENERIC_WRITE (STANDARD_RIGHTS_WRITE |\
TRANSACTIONMANAGER_SET_INFORMATION |\
TRANSACTIONMANAGER_RECOVER |\
TRANSACTIONMANAGER_RENAME |\
TRANSACTIONMANAGER_CREATE_RM)

#define TRANSACTIONMANAGER_GENERIC_EXECUTE (STANDARD_RIGHTS_EXECUTE)

#define TRANSACTIONMANAGER_ALL_ACCESS (STANDARD_RIGHTS_REQUIRED |\
TRANSACTIONMANAGER_GENERIC_READ |\
TRANSACTIONMANAGER_GENERIC_WRITE |\
TRANSACTIONMANAGER_GENERIC_EXECUTE |\
TRANSACTIONMANAGER_BIND_TRANSACTION)


//
// KTM transaction object rights.
//
#define TRANSACTION_QUERY_INFORMATION ( 0x0001 )
#define TRANSACTION_SET_INFORMATION ( 0x0002 )
#define TRANSACTION_ENLIST ( 0x0004 )
#define TRANSACTION_COMMIT ( 0x0008 )
#define TRANSACTION_ROLLBACK ( 0x0010 )
#define TRANSACTION_PROPAGATE ( 0x0020 )
#define TRANSACTION_RIGHT_RESERVED1 ( 0x0040 )

//
// Generic mappings for transaction rights.
// Resource managers, when enlisting, should generally use the macro
// TRANSACTION_RESOURCE_MANAGER_RIGHTS when opening a transaction.
// It‘s the same as generic read and write except that it does not allow
// a commit decision to be made.
//

#define TRANSACTION_GENERIC_READ (STANDARD_RIGHTS_READ |\
TRANSACTION_QUERY_INFORMATION |\
SYNCHRONIZE)

#define TRANSACTION_GENERIC_WRITE (STANDARD_RIGHTS_WRITE |\
TRANSACTION_SET_INFORMATION |\
TRANSACTION_COMMIT |\
TRANSACTION_ENLIST |\
TRANSACTION_ROLLBACK |\
TRANSACTION_PROPAGATE |\
SYNCHRONIZE)

#define TRANSACTION_GENERIC_EXECUTE (STANDARD_RIGHTS_EXECUTE |\
TRANSACTION_COMMIT |\
TRANSACTION_ROLLBACK |\
SYNCHRONIZE)

#define TRANSACTION_ALL_ACCESS (STANDARD_RIGHTS_REQUIRED |\
TRANSACTION_GENERIC_READ |\
TRANSACTION_GENERIC_WRITE |\
TRANSACTION_GENERIC_EXECUTE)

#define TRANSACTION_RESOURCE_MANAGER_RIGHTS (TRANSACTION_GENERIC_READ |\
STANDARD_RIGHTS_WRITE |\
TRANSACTION_SET_INFORMATION |\
TRANSACTION_ENLIST |\
TRANSACTION_ROLLBACK |\
TRANSACTION_PROPAGATE |\
SYNCHRONIZE)

//
// KTM resource manager object rights.
//
#define RESOURCEMANAGER_QUERY_INFORMATION ( 0x0001 )
#define RESOURCEMANAGER_SET_INFORMATION ( 0x0002 )
#define RESOURCEMANAGER_RECOVER ( 0x0004 )
#define RESOURCEMANAGER_ENLIST ( 0x0008 )
#define RESOURCEMANAGER_GET_NOTIFICATION ( 0x0010 )
#define RESOURCEMANAGER_REGISTER_PROTOCOL ( 0x0020 )
#define RESOURCEMANAGER_COMPLETE_PROPAGATION ( 0x0040 )

//
// Generic mappings for resource manager rights.
//
#define RESOURCEMANAGER_GENERIC_READ (STANDARD_RIGHTS_READ |\
RESOURCEMANAGER_QUERY_INFORMATION |\
SYNCHRONIZE)

#define RESOURCEMANAGER_GENERIC_WRITE (STANDARD_RIGHTS_WRITE |\
RESOURCEMANAGER_SET_INFORMATION |\
RESOURCEMANAGER_RECOVER |\
RESOURCEMANAGER_ENLIST |\
RESOURCEMANAGER_GET_NOTIFICATION |\
RESOURCEMANAGER_REGISTER_PROTOCOL |\
RESOURCEMANAGER_COMPLETE_PROPAGATION |\
SYNCHRONIZE)

#define RESOURCEMANAGER_GENERIC_EXECUTE (STANDARD_RIGHTS_EXECUTE |\
RESOURCEMANAGER_RECOVER |\
RESOURCEMANAGER_ENLIST |\
RESOURCEMANAGER_GET_NOTIFICATION |\
RESOURCEMANAGER_COMPLETE_PROPAGATION |\
SYNCHRONIZE)

#define RESOURCEMANAGER_ALL_ACCESS (STANDARD_RIGHTS_REQUIRED |\
RESOURCEMANAGER_GENERIC_READ |\
RESOURCEMANAGER_GENERIC_WRITE |\
RESOURCEMANAGER_GENERIC_EXECUTE)


//
// KTM enlistment object rights.
//
#define ENLISTMENT_QUERY_INFORMATION ( 0x0001 )
#define ENLISTMENT_SET_INFORMATION ( 0x0002 )
#define ENLISTMENT_RECOVER ( 0x0004 )
#define ENLISTMENT_SUBORDINATE_RIGHTS ( 0x0008 )
#define ENLISTMENT_SUPERIOR_RIGHTS ( 0x0010 )

//
// Generic mappings for enlistment rights.
//
#define ENLISTMENT_GENERIC_READ (STANDARD_RIGHTS_READ |\
ENLISTMENT_QUERY_INFORMATION)

#define ENLISTMENT_GENERIC_WRITE (STANDARD_RIGHTS_WRITE |\
ENLISTMENT_SET_INFORMATION |\
ENLISTMENT_RECOVER |\
ENLISTMENT_SUBORDINATE_RIGHTS |\
ENLISTMENT_SUPERIOR_RIGHTS)

#define ENLISTMENT_GENERIC_EXECUTE (STANDARD_RIGHTS_EXECUTE |\
ENLISTMENT_RECOVER |\
ENLISTMENT_SUBORDINATE_RIGHTS |\
ENLISTMENT_SUPERIOR_RIGHTS)

#define ENLISTMENT_ALL_ACCESS (STANDARD_RIGHTS_REQUIRED |\
ENLISTMENT_GENERIC_READ |\
ENLISTMENT_GENERIC_WRITE |\
ENLISTMENT_GENERIC_EXECUTE)


//
// Transaction outcomes.
//
// TODO: warning, must match values in KTRANSACTION_OUTCOME duplicated def
// in tm.h.
//

typedef enum _TRANSACTION_OUTCOME {
TransactionOutcomeUndetermined = 1,
TransactionOutcomeCommitted,
TransactionOutcomeAborted,
} TRANSACTION_OUTCOME;


typedef enum _TRANSACTION_STATE {
TransactionStateNormal = 1,
TransactionStateIndoubt,
TransactionStateCommittedNotify,
} TRANSACTION_STATE;


typedef struct _TRANSACTION_BASIC_INFORMATION {
GUID TransactionId;
DWORD State;
DWORD Outcome;
} TRANSACTION_BASIC_INFORMATION, *PTRANSACTION_BASIC_INFORMATION;

typedef struct _TRANSACTIONMANAGER_BASIC_INFORMATION {
GUID TmIdentity;
LARGE_INTEGER VirtualClock;
} TRANSACTIONMANAGER_BASIC_INFORMATION, *PTRANSACTIONMANAGER_BASIC_INFORMATION;

typedef struct _TRANSACTIONMANAGER_LOG_INFORMATION {
GUID LogIdentity;
} TRANSACTIONMANAGER_LOG_INFORMATION, *PTRANSACTIONMANAGER_LOG_INFORMATION;

typedef struct _TRANSACTIONMANAGER_LOGPATH_INFORMATION {
DWORD LogPathLength;
__field_ecount(LogPathLength) WCHAR LogPath[1]; // Variable size
// Data[1]; // Variable size data not declared
} TRANSACTIONMANAGER_LOGPATH_INFORMATION, *PTRANSACTIONMANAGER_LOGPATH_INFORMATION;

typedef struct _TRANSACTIONMANAGER_RECOVERY_INFORMATION {
ULONGLONG LastRecoveredLsn;
} TRANSACTIONMANAGER_RECOVERY_INFORMATION, *PTRANSACTIONMANAGER_RECOVERY_INFORMATION;


// end_wdm
typedef struct _TRANSACTIONMANAGER_OLDEST_INFORMATION {
GUID OldestTransactionGuid;
} TRANSACTIONMANAGER_OLDEST_INFORMATION, *PTRANSACTIONMANAGER_OLDEST_INFORMATION;
// begin_wdm


typedef struct _TRANSACTION_PROPERTIES_INFORMATION {
DWORD IsolationLevel;
DWORD IsolationFlags;
LARGE_INTEGER Timeout;
DWORD Outcome;
DWORD DescriptionLength;
WCHAR Description[1]; // Variable size
// Data[1]; // Variable size data not declared
} TRANSACTION_PROPERTIES_INFORMATION, *PTRANSACTION_PROPERTIES_INFORMATION;

// The following info-class is intended for DTC‘s use only; it will be
// deprecated, and no one else should take a dependency on it.
typedef struct _TRANSACTION_BIND_INFORMATION {
HANDLE TmHandle;
} TRANSACTION_BIND_INFORMATION, *PTRANSACTION_BIND_INFORMATION;

typedef struct _TRANSACTION_ENLISTMENT_PAIR {
GUID EnlistmentId;
GUID ResourceManagerId;
} TRANSACTION_ENLISTMENT_PAIR, *PTRANSACTION_ENLISTMENT_PAIR;

typedef struct _TRANSACTION_ENLISTMENTS_INFORMATION {
DWORD NumberOfEnlistments;
TRANSACTION_ENLISTMENT_PAIR EnlistmentPair[1]; // Variable size
} TRANSACTION_ENLISTMENTS_INFORMATION, *PTRANSACTION_ENLISTMENTS_INFORMATION;

typedef struct _TRANSACTION_SUPERIOR_ENLISTMENT_INFORMATION {
TRANSACTION_ENLISTMENT_PAIR SuperiorEnlistmentPair;
} TRANSACTION_SUPERIOR_ENLISTMENT_INFORMATION, *PTRANSACTION_SUPERIOR_ENLISTMENT_INFORMATION;


typedef struct _RESOURCEMANAGER_BASIC_INFORMATION {
GUID ResourceManagerId;
DWORD DescriptionLength;
WCHAR Description[1]; // Variable size
} RESOURCEMANAGER_BASIC_INFORMATION, *PRESOURCEMANAGER_BASIC_INFORMATION;

typedef struct _RESOURCEMANAGER_COMPLETION_INFORMATION {
HANDLE IoCompletionPortHandle;
ULONG_PTR CompletionKey;
} RESOURCEMANAGER_COMPLETION_INFORMATION, *PRESOURCEMANAGER_COMPLETION_INFORMATION;

// end_wdm

// begin_wdm
typedef enum _TRANSACTION_INFORMATION_CLASS {
TransactionBasicInformation,
TransactionPropertiesInformation,
TransactionEnlistmentInformation,
TransactionSuperiorEnlistmentInformation
// end_wdm
,
// The following info-classes are intended for DTC‘s use only; it will be
// deprecated, and no one else should take a dependency on it.
TransactionBindInformation, // private and deprecated
TransactionDTCPrivateInformation // private and deprecated
,
// begin_wdm
} TRANSACTION_INFORMATION_CLASS;

// begin_wdm
typedef enum _TRANSACTIONMANAGER_INFORMATION_CLASS {
TransactionManagerBasicInformation,
TransactionManagerLogInformation,
TransactionManagerLogPathInformation,
TransactionManagerRecoveryInformation = 4
// end_wdm
,
// The following info-classes are intended for internal use only; they
// are considered deprecated, and no one else should take a dependency
// on them.
TransactionManagerOnlineProbeInformation = 3,
TransactionManagerOldestTransactionInformation = 5
// end_wdm

// begin_wdm
} TRANSACTIONMANAGER_INFORMATION_CLASS;


// begin_wdm
typedef enum _RESOURCEMANAGER_INFORMATION_CLASS {
ResourceManagerBasicInformation,
ResourceManagerCompletionInformation,
} RESOURCEMANAGER_INFORMATION_CLASS;


typedef struct _ENLISTMENT_BASIC_INFORMATION {
GUID EnlistmentId;
GUID TransactionId;
GUID ResourceManagerId;
} ENLISTMENT_BASIC_INFORMATION, *PENLISTMENT_BASIC_INFORMATION;

typedef struct _ENLISTMENT_CRM_INFORMATION {
GUID CrmTransactionManagerId;
GUID CrmResourceManagerId;
GUID CrmEnlistmentId;
} ENLISTMENT_CRM_INFORMATION, *PENLISTMENT_CRM_INFORMATION;


// begin_wdm
typedef enum _ENLISTMENT_INFORMATION_CLASS {
EnlistmentBasicInformation,
EnlistmentRecoveryInformation,
EnlistmentCrmInformation
} ENLISTMENT_INFORMATION_CLASS;

typedef struct _TRANSACTION_LIST_ENTRY {
UOW UOW;
} TRANSACTION_LIST_ENTRY, *PTRANSACTION_LIST_ENTRY;

typedef struct _TRANSACTION_LIST_INFORMATION {
DWORD NumberOfTransactions;
TRANSACTION_LIST_ENTRY TransactionInformation[1]; // Var size
} TRANSACTION_LIST_INFORMATION, *PTRANSACTION_LIST_INFORMATION;


//
// Types of objects known to the kernel transaction manager.
//

typedef enum _KTMOBJECT_TYPE {

KTMOBJECT_TRANSACTION,
KTMOBJECT_TRANSACTION_MANAGER,
KTMOBJECT_RESOURCE_MANAGER,
KTMOBJECT_ENLISTMENT,
KTMOBJECT_INVALID

} KTMOBJECT_TYPE, *PKTMOBJECT_TYPE;


//
// KTMOBJECT_CURSOR
//
// Used by NtEnumerateTransactionObject to enumerate a transaction
// object namespace (e.g. enlistments in a resource manager).
//

typedef struct _KTMOBJECT_CURSOR {

//
// The last GUID enumerated; zero if beginning enumeration.
//

GUID LastQuery;

//
// A count of GUIDs filled in by this last enumeration.
//

DWORD ObjectIdCount;

//
// ObjectIdCount GUIDs from the namespace specified.
//

GUID ObjectIds[1];

} KTMOBJECT_CURSOR, *PKTMOBJECT_CURSOR;

// begin_wdm

#ifdef __cplusplus
}
#endif

#endif // _NTTMAPI_
typedef DWORD TP_VERSION, *PTP_VERSION;

typedef struct _TP_CALLBACK_INSTANCE TP_CALLBACK_INSTANCE, *PTP_CALLBACK_INSTANCE;

typedef VOID (NTAPI *PTP_SIMPLE_CALLBACK)(
__inout PTP_CALLBACK_INSTANCE Instance,
__inout_opt PVOID Context
);

typedef struct _TP_POOL TP_POOL, *PTP_POOL;

typedef enum _TP_CALLBACK_PRIORITY {
TP_CALLBACK_PRIORITY_HIGH,
TP_CALLBACK_PRIORITY_NORMAL,
TP_CALLBACK_PRIORITY_LOW,
TP_CALLBACK_PRIORITY_INVALID
} TP_CALLBACK_PRIORITY;

typedef struct _TP_POOL_STACK_INFORMATION {
SIZE_T StackReserve;
SIZE_T StackCommit;
}TP_POOL_STACK_INFORMATION, *PTP_POOL_STACK_INFORMATION;

typedef struct _TP_CLEANUP_GROUP TP_CLEANUP_GROUP, *PTP_CLEANUP_GROUP;

typedef VOID (NTAPI *PTP_CLEANUP_GROUP_CANCEL_CALLBACK)(
__inout_opt PVOID ObjectContext,
__inout_opt PVOID CleanupContext
);

//
// Do not manipulate this structure directly! Allocate space for it
// and use the inline interfaces below.
//

#if (_WIN32_WINNT >= _WIN32_WINNT_WIN7)

typedef struct _TP_CALLBACK_ENVIRON_V3 {
TP_VERSION Version;
PTP_POOL Pool;
PTP_CLEANUP_GROUP CleanupGroup;
PTP_CLEANUP_GROUP_CANCEL_CALLBACK CleanupGroupCancelCallback;
PVOID RaceDll;
struct _ACTIVATION_CONTEXT *ActivationContext;
PTP_SIMPLE_CALLBACK FinalizationCallback;
union {
DWORD Flags;
struct {
DWORD LongFunction : 1;
DWORD Persistent : 1;
DWORD Private : 30;
} s;
} u;
TP_CALLBACK_PRIORITY CallbackPriority;
DWORD Size;
} TP_CALLBACK_ENVIRON_V3;

typedef TP_CALLBACK_ENVIRON_V3 TP_CALLBACK_ENVIRON, *PTP_CALLBACK_ENVIRON;

#else

typedef struct _TP_CALLBACK_ENVIRON_V1 {
TP_VERSION Version;
PTP_POOL Pool;
PTP_CLEANUP_GROUP CleanupGroup;
PTP_CLEANUP_GROUP_CANCEL_CALLBACK CleanupGroupCancelCallback;
PVOID RaceDll;
struct _ACTIVATION_CONTEXT *ActivationContext;
PTP_SIMPLE_CALLBACK FinalizationCallback;
union {
DWORD Flags;
struct {
DWORD LongFunction : 1;
DWORD Persistent : 1;
DWORD Private : 30;
} s;
} u;
} TP_CALLBACK_ENVIRON_V1;

typedef TP_CALLBACK_ENVIRON_V1 TP_CALLBACK_ENVIRON, *PTP_CALLBACK_ENVIRON;

#endif

#if !defined(MIDL_PASS)

FORCEINLINE
VOID
TpInitializeCallbackEnviron(
__out PTP_CALLBACK_ENVIRON CallbackEnviron
)
{

#if (_WIN32_WINNT >= _WIN32_WINNT_WIN7)

CallbackEnviron->Version = 3;

#else

CallbackEnviron->Version = 1;

#endif

CallbackEnviron->Pool = NULL;
CallbackEnviron->CleanupGroup = NULL;
CallbackEnviron->CleanupGroupCancelCallback = NULL;
CallbackEnviron->RaceDll = NULL;
CallbackEnviron->ActivationContext = NULL;
CallbackEnviron->FinalizationCallback = NULL;
CallbackEnviron->u.Flags = 0;

#if (_WIN32_WINNT >= _WIN32_WINNT_WIN7)

CallbackEnviron->CallbackPriority = TP_CALLBACK_PRIORITY_NORMAL;
CallbackEnviron->Size = sizeof(TP_CALLBACK_ENVIRON);

#endif

}

FORCEINLINE
VOID
TpSetCallbackThreadpool(
__inout PTP_CALLBACK_ENVIRON CallbackEnviron,
__in PTP_POOL Pool
)
{
CallbackEnviron->Pool = Pool;
}

FORCEINLINE
VOID
TpSetCallbackCleanupGroup(
__inout PTP_CALLBACK_ENVIRON CallbackEnviron,
__in PTP_CLEANUP_GROUP CleanupGroup,
__in_opt PTP_CLEANUP_GROUP_CANCEL_CALLBACK CleanupGroupCancelCallback
)
{
CallbackEnviron->CleanupGroup = CleanupGroup;
CallbackEnviron->CleanupGroupCancelCallback = CleanupGroupCancelCallback;
}

FORCEINLINE
VOID
TpSetCallbackActivationContext(
__inout PTP_CALLBACK_ENVIRON CallbackEnviron,
__in_opt struct _ACTIVATION_CONTEXT *ActivationContext
)
{
CallbackEnviron->ActivationContext = ActivationContext;
}

FORCEINLINE
VOID
TpSetCallbackNoActivationContext(
__inout PTP_CALLBACK_ENVIRON CallbackEnviron
)
{
CallbackEnviron->ActivationContext = (struct _ACTIVATION_CONTEXT *)(LONG_PTR) -1; // INVALID_ACTIVATION_CONTEXT
}

FORCEINLINE
VOID
TpSetCallbackLongFunction(
__inout PTP_CALLBACK_ENVIRON CallbackEnviron
)
{
CallbackEnviron->u.s.LongFunction = 1;
}

FORCEINLINE
VOID
TpSetCallbackRaceWithDll(
__inout PTP_CALLBACK_ENVIRON CallbackEnviron,
__in PVOID DllHandle
)
{
CallbackEnviron->RaceDll = DllHandle;
}

FORCEINLINE
VOID
TpSetCallbackFinalizationCallback(
__inout PTP_CALLBACK_ENVIRON CallbackEnviron,
__in PTP_SIMPLE_CALLBACK FinalizationCallback
)
{
CallbackEnviron->FinalizationCallback = FinalizationCallback;
}

#if (_WIN32_WINNT >= _WIN32_WINNT_WIN7)

FORCEINLINE
VOID
TpSetCallbackPriority(
__inout PTP_CALLBACK_ENVIRON CallbackEnviron,
__in TP_CALLBACK_PRIORITY Priority
)
{
CallbackEnviron->CallbackPriority = Priority;
}

#endif

FORCEINLINE
VOID
TpSetCallbackPersistent(
__inout PTP_CALLBACK_ENVIRON CallbackEnviron
)
{
CallbackEnviron->u.s.Persistent = 1;
}


FORCEINLINE
VOID
TpDestroyCallbackEnviron(
__in PTP_CALLBACK_ENVIRON CallbackEnviron
)
{
//
// For the current version of the callback environment, no actions
// need to be taken to tear down an initialized structure. This
// may change in a future release.
//

UNREFERENCED_PARAMETER(CallbackEnviron);
}

#endif // !defined(MIDL_PASS)


typedef struct _TP_WORK TP_WORK, *PTP_WORK;

typedef VOID (NTAPI *PTP_WORK_CALLBACK)(
__inout PTP_CALLBACK_INSTANCE Instance,
__inout_opt PVOID Context,
__inout PTP_WORK Work
);

typedef struct _TP_TIMER TP_TIMER, *PTP_TIMER;

typedef VOID (NTAPI *PTP_TIMER_CALLBACK)(
__inout PTP_CALLBACK_INSTANCE Instance,
__inout_opt PVOID Context,
__inout PTP_TIMER Timer
);

typedef DWORD TP_WAIT_RESULT;

typedef struct _TP_WAIT TP_WAIT, *PTP_WAIT;

typedef VOID (NTAPI *PTP_WAIT_CALLBACK)(
__inout PTP_CALLBACK_INSTANCE Instance,
__inout_opt PVOID Context,
__inout PTP_WAIT Wait,
__in TP_WAIT_RESULT WaitResult
);

typedef struct _TP_IO TP_IO, *PTP_IO;

#if defined(_M_AMD64) && !defined(__midl)

__forceinline
struct _TEB *
NtCurrentTeb (
VOID
)

{
return (struct _TEB *)__readgsqword(FIELD_OFFSET(NT_TIB, Self));
}

__forceinline
PVOID
GetCurrentFiber (
VOID
)

{

return (PVOID)__readgsqword(FIELD_OFFSET(NT_TIB, FiberData));
}

__forceinline
PVOID
GetFiberData (
VOID
)

{

return *(PVOID *)GetCurrentFiber();
}

#endif // _M_AMD64 && !defined(__midl)


#if defined(_M_IX86) && !defined(MIDL_PASS)

#define PcTeb 0x18

#if (_MSC_FULL_VER >= 13012035)

__inline struct _TEB * NtCurrentTeb( void ) { return (struct _TEB *) (ULONG_PTR) __readfsdword (PcTeb); }

#else

#if _MSC_VER >= 1200
#pragma warning(push)
#endif

#pragma warning (disable:4035) // disable 4035 (function must return something)

__inline struct _TEB * NtCurrentTeb( void ) { __asm mov eax, fs:[PcTeb] }

#if _MSC_VER >= 1200
#pragma warning(pop)
#else
#pragma warning (default:4035) // reenable it
#endif

#endif

#endif // defined(_M_IX86) && !defined(MIDL_PASS)

#if (_WIN32_WINNT > 0x0500) || (_WIN32_FUSION >= 0x0100) || ISOLATION_AWARE_ENABLED // winnt_only
#define ACTIVATION_CONTEXT_SECTION_ASSEMBLY_INFORMATION (1)
#define ACTIVATION_CONTEXT_SECTION_DLL_REDIRECTION (2)
#define ACTIVATION_CONTEXT_SECTION_WINDOW_CLASS_REDIRECTION (3)
#define ACTIVATION_CONTEXT_SECTION_COM_SERVER_REDIRECTION (4)
#define ACTIVATION_CONTEXT_SECTION_COM_INTERFACE_REDIRECTION (5)
#define ACTIVATION_CONTEXT_SECTION_COM_TYPE_LIBRARY_REDIRECTION (6)
#define ACTIVATION_CONTEXT_SECTION_COM_PROGID_REDIRECTION (7)
#define ACTIVATION_CONTEXT_SECTION_GLOBAL_OBJECT_RENAME_TABLE (8)
#define ACTIVATION_CONTEXT_SECTION_CLR_SURROGATES (9)
#define ACTIVATION_CONTEXT_SECTION_APPLICATION_SETTINGS (10)
#define ACTIVATION_CONTEXT_SECTION_COMPATIBILITY_INFO (11)
#endif // winnt_only

#ifdef __cplusplus
}
#endif

#if _MSC_VER >= 1200
#pragma warning(pop)
#else
#pragma warning(default:4201)
#pragma warning(default:4214)
#endif

#endif /* _WINNT_ */

 

 

winnt.h

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