winnt.h

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    };
    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;
    };
    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)

//
// 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.
//

#define Int32x32To64(a, b) ((LONGLONG)((LONG)(a)) * (LONGLONG)((LONG)(b)))
#define UInt32x32To64(a, b) ((ULONGLONG)((DWORD)(a)) * (ULONGLONG)((DWORD)(b)))

#define Int64ShllMod32(a, b) ((ULONGLONG)(a) << (b))
#define Int64ShraMod32(a, b) ((LONGLONG)(a) >> (b))
#define Int64ShrlMod32(a, b) ((ULONGLONG)(a) >> (b))

#elif defined(_M_MRX000)

//
// MIPS uses intrinsic functions to perform shifts by 0..31 and multiplies of
// 32-bits times 32-bits to 64-bits.
//

#define Int32x32To64 __emul
#define UInt32x32To64 __emulu

#define Int64ShllMod32 __ll_lshift
#define Int64ShraMod32 __ll_rshift
#define Int64ShrlMod32 __ull_rshift

#if defined (__cplusplus)
extern "C" {
#endif

LONGLONG
NTAPI
Int32x32To64 (
    LONG Multiplier,
    LONG Multiplicand
    );

ULONGLONG
NTAPI
UInt32x32To64 (
    DWORD Multiplier,
    DWORD Multiplicand
    );

ULONGLONG
NTAPI
Int64ShllMod32 (
    ULONGLONG Value,
    DWORD ShiftCount
    );

LONGLONG
NTAPI
Int64ShraMod32 (
    LONGLONG Value,
    DWORD ShiftCount
    );

ULONGLONG
NTAPI
Int64ShrlMod32 (
    ULONGLONG Value,
    DWORD ShiftCount
    );

#if defined (__cplusplus)
};
#endif

#pragma intrinsic(__emul)
#pragma intrinsic(__emulu)

#pragma intrinsic(__ll_lshift)
#pragma intrinsic(__ll_rshift)
#pragma intrinsic(__ull_rshift)

#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 ) (LONGLONG)((LONGLONG)(LONG)(a) * (LONG)(b))
#define UInt32x32To64( a, b ) (ULONGLONG)((ULONGLONG)(DWORD)(a) * (DWORD)(b))

#if !defined (__BORLANDC__)

ULONGLONG
NTAPI
Int64ShllMod32 (
    ULONGLONG Value,
    DWORD ShiftCount
    );

LONGLONG
NTAPI
Int64ShraMod32 (
    LONGLONG Value,
    DWORD ShiftCount
    );

ULONGLONG
NTAPI
Int64ShrlMod32 (
    ULONGLONG Value,
    DWORD ShiftCount
    );

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

__inline ULONGLONG
NTAPI
Int64ShllMod32 (
    ULONGLONG Value,
    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 (
    LONGLONG Value,
    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 (
    ULONGLONG Value,
    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)
#endif

#else
/* For Borland, let the compiler generate calls to __int64 helper functions */

#define Int64ShllMod32(a, b) ((DWORDLONG)(a) << (b))
#define Int64ShraMod32(a, b) ((LONGLONG)(a) >> (b))
#define Int64ShrlMod32(a, b) ((DWORDLONG)(a) >> (b))

#endif /* !defined (__BORLANDC__) */

#elif defined(_M_ALPHA)

//
// Alpha has 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) ((LONGLONG)((LONG)(a)) * (LONGLONG)((LONG)(b)))
#define UInt32x32To64(a, b) ((ULONGLONG)((DWORD)(a)) * (ULONGLONG)((DWORD)(b)))

#define Int64ShllMod32(a, b) ((ULONGLONG)(a) << (b))
#define Int64ShraMod32(a, b) ((LONGLONG)(a) >> (b))
#define Int64ShrlMod32(a, b) ((ULONGLONG)(a) >> (b))


#elif defined(_M_PPC)

#define Int32x32To64(a, b) ((LONGLONG)((LONG)(a)) * (LONGLONG)((LONG)(b)))
#define UInt32x32To64(a, b) ((ULONGLONG)((DWORD)(a)) * (ULONGLONG)((DWORD)(b)))

#define Int64ShllMod32(a, b) ((ULONGLONG)(a) << (b))
#define Int64ShraMod32(a, b) ((LONGLONG)(a) >> (b))
#define Int64ShrlMod32(a, b) ((ULONGLONG)(a) >> (b))

#elif defined(_68K_) || defined(_MPPC_)

//
// The Macintosh 68K and PowerPC compilers do not currently support int64.
//

#define Int32x32To64(a, b) ((LONGLONG)((LONG)(a)) * (LONGLONG)((LONG)(b)))
#define UInt32x32To64(a, b) ((DWORDLONG)((DWORD)(a)) * (DWORDLONG)((DWORD)(b)))

#define Int64ShllMod32(a, b) ((DWORDLONG)(a) << (b))
#define Int64ShraMod32(a, b) ((LONGLONG)(a) >> (b))
#define Int64ShrlMod32(a, b) ((DWORDLONG)(a) >> (b))

#elif defined(_M_IA64)

//
// IA64 has 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) ((LONGLONG)((LONG)(a)) * (LONGLONG)((LONG)(b)))
#define UInt32x32To64(a, b) ((ULONGLONG)((DWORD)(a)) * (ULONGLONG)((DWORD)(b)))

#define Int64ShllMod32(a, b) ((ULONGLONG)(a) << (b))
#define Int64ShraMod32(a, b) ((LONGLONG)(a) >> (b))
#define Int64ShrlMod32(a, b) ((ULONGLONG)(a) >> (b))

#else

#error Must define a target architecture.

#endif

#define ANSI_NULL ((CHAR)0)     
#define UNICODE_NULL ((WCHAR)0) 
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 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)))


#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


//
//  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
//

//
//  Primary language IDs.
//

#define LANG_NEUTRAL                     0x00

#define LANG_AFRIKAANS                   0x36
#define LANG_ALBANIAN                    0x1c
#define LANG_ARABIC                      0x01
#define LANG_ARMENIAN                    0x2b
#define LANG_ASSAMESE                    0x4d
#define LANG_AZERI                       0x2c
#define LANG_BASQUE                      0x2d
#define LANG_BELARUSIAN                  0x23
#define LANG_BENGALI                     0x45
#define LANG_BULGARIAN                   0x02
#define LANG_CATALAN                     0x03
#define LANG_CHINESE                     0x04
#define LANG_CROATIAN                    0x1a
#define LANG_CZECH                       0x05
#define LANG_DANISH                      0x06
#define LANG_DUTCH                       0x13
#define LANG_ENGLISH                     0x09
#define LANG_ESTONIAN                    0x25
#define LANG_FAEROESE                    0x38
#define LANG_FARSI                       0x29
#define LANG_FINNISH                     0x0b