windows-nt/Source/XPSP1/NT/base/mvdm/meinc/vmm.h

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/*****************************************************************************
*
* (C) Copyright MICROSOFT Corp., 1988-1990
*
* Title: VMM.H - Include file for Virtual Machine Manager
*
* Version: 1.00
*
* Date: 05-May-1988
*
* Author: RAL
*
*-----------------------------------------------------------------------------
*
* Change log:
*
* DATE REV DESCRIPTION
* ----------- --- -----------------------------------------------------------
* 05-May-1988 RAL Original
* 13-Nov-1991 PBS C version
* 17-Dec-1993 Adds Far East VxDs identifiers
*/
#ifndef _VMM_
#define _VMM_
/*
* NON Windows/386 Virtual Device sources can include this file to get
* some useful equates by declaring the symbol "Not_VxD" If this symbol
* is defined, then everything that has to do with the specifics of the
* 32 bit environment for virtual devices is removed. Useful equates
* include: device ID's, pushad structure, BeginDoc, EndDoc, BeginMsg,
* EndMsg, page table equates, etc.
*/
#define FALSE 0 // False
#define VMM_TRUE (~FALSE) // The opposite of False!
#define DEBLEVELRETAIL 0
#define DEBLEVELNORMAL 1
#define DEBLEVELMAX 2
#ifndef DEBLEVEL
#ifdef DEBUG
#define DEBLEVEL DEBLEVELNORMAL
#else
#define DEBLEVEL DEBLEVELRETAIL
#endif
#endif
#ifndef WIN31COMPAT
#define WIN40SERVICES
#ifndef WIN40COMPAT
#define WIN403SERVICES /*OPK-3 Services*/
#define WIN41SERVICES
#ifndef WIN41COMPAT
#define WIN49SERVICES
#endif
#endif
#endif
#ifdef WIN42SERVICES
#define WIN41SERVICES
#define WIN403SERVICES
#define WIN40SERVICES
#endif
#ifdef WIN41SERVICES
#define WIN403SERVICES
#define WIN40SERVICES
#endif
#ifdef WIN403SERVICES
#define WIN40SERVICES
#endif
/* ASM
ifdef MASM6
ifndef NO_MASM6_OPTIONS
;
; option switches necessary to build VMM/VxD sources with MASM 6
;
option oldmacros
ifndef NEWSTRUCTS ; define NEWSTRUCTS for MASM6 struct semantics
option oldstructs
endif
option noscoped
option segment:flat
option offset:flat
option proc:private
endif
endif
;
; These null macros are recognized by a utility program that produces
; documentation files.
;
IFDEF MASM6
BeginDoc MACRO
ENDM
EndDoc MACRO
ENDM
BeginMsg MACRO
ENDM
EndMsg MACRO
ENDM
ELSE
BeginDoc EQU <>
EndDoc EQU <>
BeginMsg EQU <>
EndMsg EQU <>
ENDIF
*/
/******************************************************************************
*
* EQUATES FOR REQUIRED DEVICES
*
* Device ID formulation note:
*
* The high bit of the device ID is reserved for future use.
* Microsoft reserves the device ID's 0-1FFh for standard devices. If
* an OEM VxD is a replacement for a standard VxD, then it must use the
* standard VxD ID.
*
* OEMS WHO WANT A VXD DEVICE ID ASSIGNED TO THEM,
* PLEASE CONTACT MICROSOFT PRODUCT SUPPORT. ID's are only required for
* devices which provide services, V86 API's or PM API's. Also, calling
* services or API's by VxD name is now supported in version 4.0, so an
* ID may not be necessary as long as a unique 8 character name is used.
*
*****************************************************************************/
#define UNDEFINED_DEVICE_ID 0x00000
#define VMM_DEVICE_ID 0x00001 /* Used for dynalink table */
#define DEBUG_DEVICE_ID 0x00002
#define VPICD_DEVICE_ID 0x00003
#define VDMAD_DEVICE_ID 0x00004
#define VTD_DEVICE_ID 0x00005
#define V86MMGR_DEVICE_ID 0x00006
#define PAGESWAP_DEVICE_ID 0x00007
#define PARITY_DEVICE_ID 0x00008
#define REBOOT_DEVICE_ID 0x00009
#define VDD_DEVICE_ID 0x0000A
#define VSD_DEVICE_ID 0x0000B
#define VMD_DEVICE_ID 0x0000C
#define VKD_DEVICE_ID 0x0000D
#define VCD_DEVICE_ID 0x0000E
#define VPD_DEVICE_ID 0x0000F
#define BLOCKDEV_DEVICE_ID 0x00010
#define IOS_DEVICE_ID BLOCKDEV_DEVICE_ID
#define VMCPD_DEVICE_ID 0x00011
#define EBIOS_DEVICE_ID 0x00012
#define BIOSXLAT_DEVICE_ID 0x00013
#define VNETBIOS_DEVICE_ID 0x00014
#define DOSMGR_DEVICE_ID 0x00015
#define WINLOAD_DEVICE_ID 0x00016
#define SHELL_DEVICE_ID 0x00017
#define VMPOLL_DEVICE_ID 0x00018
#define VPROD_DEVICE_ID 0x00019
#define DOSNET_DEVICE_ID 0x0001A
#define VFD_DEVICE_ID 0x0001B
#define VDD2_DEVICE_ID 0x0001C /* Secondary display adapter */
#define WINDEBUG_DEVICE_ID 0x0001D
#define TSRLOAD_DEVICE_ID 0x0001E /* TSR instance utility ID */
#define BIOSHOOK_DEVICE_ID 0x0001F /* Bios interrupt hooker VxD */
#define INT13_DEVICE_ID 0x00020
#define PAGEFILE_DEVICE_ID 0x00021 /* Paging File device */
#define SCSI_DEVICE_ID 0x00022 /* SCSI device */
#define MCA_POS_DEVICE_ID 0x00023 /* MCA_POS device */
#define SCSIFD_DEVICE_ID 0x00024 /* SCSI FastDisk device */
#define VPEND_DEVICE_ID 0x00025 /* Pen device */
#define APM_DEVICE_ID 0x00026 /* Power Management device */
#define VPOWERD_DEVICE_ID APM_DEVICE_ID /* We overload APM since we replace it */
#define VXDLDR_DEVICE_ID 0x00027 /* VxD Loader device */
#define NDIS_DEVICE_ID 0x00028 /* NDIS wrapper */
#define BIOS_EXT_DEVICE_ID 0x00029 /* Fix Broken BIOS device */
#define VWIN32_DEVICE_ID 0x0002A /* for new WIN32-VxD */
#define VCOMM_DEVICE_ID 0x0002B /* New COMM device driver */
#define SPOOLER_DEVICE_ID 0x0002C /* Local Spooler */
#define WIN32S_DEVICE_ID 0x0002D /* Win32S on Win 3.1 driver */
#define DEBUGCMD_DEVICE_ID 0x0002E /* Debug command extensions */
/* #define RESERVED_DEVICE_ID 0x0002F /* Not currently in use */
/* #define ATI_HELPER_DEVICE_ID 0x00030 /* grabbed by ATI */
/* 31-32 USED BY WFW NET COMPONENTS */
/* #define VNB_DEVICE_ID 0x00031 /* Netbeui of snowball */
/* #define SERVER_DEVICE_ID 0x00032 /* Server of snowball */
#define CONFIGMG_DEVICE_ID 0x00033 /* Configuration manager (Plug&Play) */
#define DWCFGMG_DEVICE_ID 0x00034 /* Configuration manager for win31 and DOS */
#define SCSIPORT_DEVICE_ID 0x00035 /* Dragon miniport loader/driver */
#define VFBACKUP_DEVICE_ID 0x00036 /* allows backup apps to work with NEC */
#define ENABLE_DEVICE_ID 0x00037 /* for access VxD */
#define VCOND_DEVICE_ID 0x00038 /* Virtual Console Device - check vcond.inc */
/* 39 used by WFW VFat Helper device */
/* 3A used by WFW E-FAX */
/* #define EFAX_DEVICE_ID 0x0003A /* EFAX VxD ID */
/* 3B used by MS-DOS 6.1 for the DblSpace VxD which has APIs */
/* #define DSVXD_DEVICE_ID 0x0003B /* Dbl Space VxD ID */
#define ISAPNP_DEVICE_ID 0x0003C /* ISA P&P Enumerator */
#define BIOS_DEVICE_ID 0x0003D /* BIOS P&P Enumerator */
/* #define WINSOCK_DEVICE_ID 0x0003E /* WinSockets */
/* #define WSIPX_DEVICE_ID 0x0003F /* WinSockets for IPX */
#define IFSMgr_Device_ID 0x00040 /* Installable File System Manager */
#define VCDFSD_DEVICE_ID 0x00041 /* Static CDFS ID */
#define MRCI2_DEVICE_ID 0x00042 /* DrvSpace compression engine */
#define PCI_DEVICE_ID 0x00043 /* PCI P&P Enumerator */
#define PELOADER_DEVICE_ID 0x00044 /* PE Image Loader */
#define EISA_DEVICE_ID 0x00045 /* EISA P&P Enumerator */
#define DRAGCLI_DEVICE_ID 0x00046 /* Dragon network client */
#define DRAGSRV_DEVICE_ID 0x00047 /* Dragon network server */
#define PERF_DEVICE_ID 0x00048 /* Config/stat info */
#define AWREDIR_DEVICE_ID 0x00049 /* AtWork Network FSD */
#define DDS_DEVICE_ID 0x0004A /* Device driver services */
#define NTKERN_DEVICE_ID 0x0004B /* NT kernel device id */
#define VDOSKEYD_DEVICE_ID 0x0004B /* DOSKEY device id */
#define ACPI_DEVICE_ID 0x0004C /* Advanced Configuration and Power Interfacec */
#define UDF_DEVICE_ID 0x0004D /* UDF FSD device id */
#define SMCLIB_DEVICE_ID 0x0004E /* Smart Card port driver */
#define NTMAP_DEVICE_ID 0x0004F /* WDM storage mapper */
#define NTMAPHLP_DEVICE_ID 0x00050
#define USBNTMAP_DEVICE_ID 0x00051 /* USB WDM storage mapper */
#define USBMPHLP_DEVICE_ID 0x00052 /* USB WDM storage helper */
/*
* Far East DOS support VxD ID
*/
#define ETEN_Device_ID 0x00060 /* ETEN DOS (Taiwan) driver */
#define CHBIOS_Device_ID 0x00061 /* CHBIOS DOS (Korean) driver */
#define VMSGD_Device_ID 0x00062 /* DBCS Message Mode driver */
#define VPPID_Device_ID 0x00063 /* PC-98 System Control PPI */
#define VIME_Device_ID 0x00064 /* Virtual DOS IME */
#define VHBIOSD_Device_ID 0x00065 /* HBIOS (Korean) for HWin31 driver */
#define VPBIOSD_DEVICE_ID 0x00066 /* PRC DOS driver */
#define VXDMON_DEVICE_ID 0x00067 /* SFP/SR IFSHook VxD */
#define BASEID_FOR_NAMEBASEDVXD 0xf000 /* Name based VxD IDs start here */
#define BASEID_FOR_NAMEBASEDVXD_MASK 0x0fff /* Mask to get the real vxd id */
/*
* Initialization order equates. Devices are initialized in order from
* LOWEST to HIGHEST. If 2 or more devices have the same initialization
* order value, then they are initialized in order of occurance, so a
* specific order is not guaranteed. Holes have been left to allow maximum
* flexibility in ordering devices.
*/
#define VMM_INIT_ORDER 0x000000000
#define DEBUG_INIT_ORDER 0x000000000 /* normally using 0 is bad */
#define DEBUGCMD_INIT_ORDER 0x000000000 /* but debug must be first */
#define PERF_INIT_ORDER 0x000900000
#define APM_INIT_ORDER 0x001000000
#define VPOWERD_INIT_ORDER APM_INIT_ORDER /* We overload APM since we replace it */
#define BIOSHOOK_INIT_ORDER 0x006000000
#define VPROD_INIT_ORDER 0x008000000
#define VPICD_INIT_ORDER 0x00C000000
#define VTD_INIT_ORDER 0x014000000
#define VWIN32_INIT_ORDER 0x014100000
#define VXDLDR_INIT_ORDER 0x016000000
#define NTKERN_INIT_ORDER 0x016200000 /* Must be after VxDLdr and before configmg */
#define CONFIGMG_INIT_ORDER 0x016400000 /* Must now be before enumerators */
#define ENUMERATOR_INIT_ORDER 0x016800000 /* Should be before IOS */
#define ISAPNP_INIT_ORDER ENUMERATOR_INIT_ORDER
#define EISA_INIT_ORDER ENUMERATOR_INIT_ORDER
#define PCI_INIT_ORDER ENUMERATOR_INIT_ORDER
#define BIOS_INIT_ORDER ENUMERATOR_INIT_ORDER+1 /* To simplify reenumeration */
#define ACPI_INIT_ORDER ENUMERATOR_INIT_ORDER+2 /* To simplify reenumeration */
#define NTMAP_INIT_ORDER ENUMERATOR_INIT_ORDER+3 /* To simplify reenumeration */
#define USBNTMAP_INIT_ORDER ENUMERATOR_INIT_ORDER+4 /* To simplify reenumeration */
#define VCDFSD_INIT_ORDER 0x016F00000
#define IOS_INIT_ORDER 0x017000000
#define PAGEFILE_INIT_ORDER 0x018000000
#define PAGESWAP_INIT_ORDER 0x01C000000
#define PARITY_INIT_ORDER 0x020000000
#define REBOOT_INIT_ORDER 0x024000000
#define EBIOS_INIT_ORDER 0x026000000
#define VDD_INIT_ORDER 0x028000000
#define VSD_INIT_ORDER 0x02C000000
#define VCD_INIT_ORDER 0x030000000
#define COMMDRVR_INIT_ORDER (VCD_INIT_ORDER - 1)
#define PRTCL_INIT_ORDER (COMMDRVR_INIT_ORDER - 2)
#define MODEM_INIT_ORDER (COMMDRVR_INIT_ORDER - 3)
#define PORT_INIT_ORDER (COMMDRVR_INIT_ORDER - 4)
#define VMD_INIT_ORDER 0x034000000
#define VKD_INIT_ORDER 0x038000000
#define VPD_INIT_ORDER 0x03C000000
#define BLOCKDEV_INIT_ORDER 0x040000000
#define MCA_POS_INIT_ORDER 0x041000000
#define SCSIFD_INIT_ORDER 0x041400000
#define SCSIMASTER_INIT_ORDER 0x041800000
#define INT13_INIT_ORDER 0x042000000
#define VMCPD_INIT_ORDER 0x048000000
#define BIOSXLAT_INIT_ORDER 0x050000000
#define VNETBIOS_INIT_ORDER 0x054000000
#define DOSMGR_INIT_ORDER 0x058000000
#define DOSNET_INIT_ORDER 0x05C000000
#define WINLOAD_INIT_ORDER 0x060000000
#define VMPOLL_INIT_ORDER 0x064000000
#define UNDEFINED_INIT_ORDER 0x080000000
#define VCOND_INIT_ORDER UNDEFINED_INIT_ORDER
#define WINDEBUG_INIT_ORDER 0x081000000
#define VDMAD_INIT_ORDER 0x090000000
#define V86MMGR_INIT_ORDER 0x0A0000000
#define IFSMgr_Init_Order 0x10000 + V86MMGR_Init_Order
#define FSD_Init_Order 0x00100 + IFSMgr_Init_Order
#define VFD_INIT_ORDER 0x50000 + IFSMgr_Init_Order
/* Device that must touch memory in 1st Mb at crit init (after V86mmgr) */
#define UNDEF_TOUCH_MEM_INIT_ORDER 0x0A8000000
#define SHELL_INIT_ORDER 0x0B0000000
/* ASM
;******************************************************************************
;
; Macro to cause a delay in between I/O accesses to the same device.
;
;------------------------------------------------------------------------------
IO_Delay macro
jmp $+2
ENDM
*/
#define VXD_FAILURE 0
#define VXD_SUCCESS 1
typedef ULONG HVM; /* VM handle typedef */
/*
* Registers as they appear on the stack after a PUSHAD.
*/
struct Pushad_Struc {
ULONG Pushad_EDI; /* Client's EDI */
ULONG Pushad_ESI; /* Client's ESI */
ULONG Pushad_EBP; /* Client's EBP */
ULONG Pushad_ESP; /* ESP before pushad */
ULONG Pushad_EBX; /* Client's EBX */
ULONG Pushad_EDX; /* Client's EDX */
ULONG Pushad_ECX; /* Client's ECX */
ULONG Pushad_EAX; /* Client's EAX */
};
/* XLATOFF */
#ifdef RC_INVOKED
#define NOBASEDEFS
#endif
#ifndef NOBASEDEFS
#pragma warning (disable:4209) // turn off redefinition warning
typedef unsigned char UCHAR;
typedef unsigned short USHORT;
#pragma warning (default:4209) // turn off redefinition warning
#endif
#define GetVxDServiceOrdinal(service) __##service
#define Begin_Service_Table(device, seg) \
enum device##_SERVICES { \
device##_dummy = (device##_DEVICE_ID << 16) - 1,
#define Declare_Service(service, local) \
GetVxDServiceOrdinal(service),
#define Declare_SCService(service, args, local) \
GetVxDServiceOrdinal(service),
#define End_Service_Table(device, seg) \
Num_##device##_Services};
#define VXDINLINE static __inline
/* XLATON */
#ifndef Not_VxD
/* XLATOFF */
#define VxD_LOCKED_CODE_SEG code_seg("_LTEXT", "LCODE")
#define VxD_LOCKED_DATA_SEG data_seg("_LDATA", "LCODE")
#define VxD_INIT_CODE_SEG code_seg("_ITEXT", "ICODE")
#define VxD_INIT_DATA_SEG data_seg("_IDATA", "ICODE")
#define VxD_ICODE_SEG code_seg("_ITEXT", "ICODE")
#define VxD_IDATA_SEG data_seg("_IDATA", "ICODE")
#define VxD_PAGEABLE_CODE_SEG code_seg("_PTEXT", "PCODE")
#define VxD_PAGEABLE_DATA_SEG data_seg("_PDATA", "PDATA")
#define VxD_STATIC_CODE_SEG code_seg("_STEXT", "SCODE")
#define VxD_STATIC_DATA_SEG data_seg("_SDATA", "SCODE")
#define VxD_DEBUG_ONLY_CODE_SEG code_seg("_DB1CODE", "DBOCODE")
#define VxD_DEBUG_ONLY_DATA_SEG data_seg("_DB2DATA", "DBOCODE")
#define VxD_SYSEXIT_CODE_SEG code_seg("SYSEXIT", "SYSEXITCODE")
#define VxD_INT21_CODE_SEG code_seg("INT21", "INT21CODE")
#define VxD_RARE_CODE_SEG code_seg("RARE", "RARECODE")
#define VxD_W16_CODE_SEG code_seg("W16", "W16CODE")
#define VxD_W32_CODE_SEG code_seg("W32", "W32CODE")
#define VxD_VMCREATE_CODE_SEG code_seg("VMCREATE", "VMCREATECODE")
#define VxD_VMDESTROY_CODE_SEG code_seg("VMDESTROY", "VMDESTROYCODE")
#define VxD_THCREATE_CODE_SEG code_seg("THCREATE", "THCREATECODE")
#define VxD_THDESTROY_CODE_SEG code_seg("THDESTROY", "THDESTROYCODE")
#define VxD_VMSUSPEND_CODE_SEG code_seg("VMSUSPEND", "VMSUSPENDCODE")
#define VxD_VMRESUME_CODE_SEG code_seg("VMRESUME", "VMRESUMECODE")
#define VxD_PNP_CODE_SEG code_seg("PNP", "PNPCODE")
#define VxD_DOSVM_CODE_SEG code_seg("DOSVM", "DOSVMCODE")
#define VxD_LOCKABLE_CODE_SEG code_seg("LOCKABLE", "LOCKABLECODE")
#define VxD_LOCKABLE_DATA_SEG data_seg("LOCKABLE_DATA", "LOCKABLECODE")
#define VxD_LOCKED_CONST_SEG const_seg("_LCONST", "LCODE")
#define VxD_INIT_CONST_SEG const_seg("_ICONST", "ICODE")
#define VxD_PAGEABLE_CONST_SEG const_seg("_PCONST", "PCODE")
#define VxD_LOCKABLE_CONST_SEG const_seg("LOCKABLE_CONST", "LOCKABLECODE")
/* XLATON */
/* ASM
??_CUR_CODE_SEG = 0
??_LCODE = 1
??_ICODE = 2
??_PCODE = 3
??_SCODE = 4
??_DBOCODE = 5
??_16ICODE = 6
??_RCODE = 7
??_LOCKABLECODE = 8
?_LCODE equ <(??_CUR_CODE_SEG MOD 16) - ??_LCODE>
?_ICODE equ <(??_CUR_CODE_SEG MOD 16) - ??_ICODE>
?_PCODE equ <(??_CUR_CODE_SEG MOD 16) - ??_PCODE>
?_SCODE equ <(??_CUR_CODE_SEG MOD 16) - ??_SCODE>
?_DBOCODE equ <(??_CUR_CODE_SEG MOD 16) - ??_DBOCODE>
?_16ICODE equ <(??_CUR_CODE_SEG MOD 16) - ??_16ICODE>
?_RCODE equ <(??_CUR_CODE_SEG MOD 16) - ??_RCODE>
?_LOCKABLECODE equ <(??_CUR_CODE_SEG MOD 16) - ??_LOCKABLECODE>
ifndef NO_SEGMENTS
;
; SEGMENT definitions and order
;
IFDEF MASM6
_FLAT EQU FLAT
ELSE
_FLAT EQU USE32
ENDIF
;* 32 bit locked code
_LTEXT SEGMENT DWORD PUBLIC _FLAT 'LCODE'
_LTEXT ENDS
_TEXT SEGMENT DWORD PUBLIC _FLAT 'LCODE'
_TEXT ENDS
;* 32 bit pageable code
_PTEXT SEGMENT DWORD PUBLIC _FLAT 'PCODE'
_PTEXT ENDS
MakeCodeSeg MACRO seglist, classname, grpname, iseg
IRP segname,<seglist> ;; For each name in the list
IFNB <classname>
segname SEGMENT DWORD PUBLIC _FLAT "&classname&CODE"
ELSE
segname SEGMENT DWORD PUBLIC _FLAT "&segname&CODE"
ENDIF
IFB <iseg>
VxD_&&segname&&_CODE_SEG MACRO
segname SEGMENT
??_CUR_CODE_SEG = ??_CUR_CODE_SEG SHL 4 + ??_PCODE
ASSUME cs:FLAT, ds:FLAT, es:FLAT, ss:FLAT
ENDM
ELSE
VxD_&&segname&&_CODE_SEG MACRO
segname SEGMENT
??_CUR_CODE_SEG = ??_CUR_CODE_SEG SHL 4 + iseg
ASSUME cs:FLAT, ds:FLAT, es:FLAT, ss:FLAT
ENDM
ENDIF
VxD_&&segname&&_CODE_ENDS MACRO
??_CUR_CODE_SEG = ??_CUR_CODE_SEG SHR 4
segname ENDS
ENDM
segname ENDS
IFNDEF BLD_COFF
IFNB <grpname>
_&grpname GROUP segname
ELSE
_&&segname GROUP segname
ENDIF
ENDIF
ENDM ;; End for each segment
ENDM
MakeCodeSeg <L0CKABLE_BEGIN, LOCKABLE, LOCKABLE_END>, \
LOCKABLE, LOCKABLE, ??_LOCKABLECODE
MakeCodeSeg INT21
MakeCodeSeg SYSEXIT
MakeCodeSeg RARE
MakeCodeSeg W16
MakeCodeSeg W32
MakeCodeSeg VMCREATE
MakeCodeSeg VMDESTROY
MakeCodeSeg THCREATE
MakeCodeSeg THDESTROY
MakeCodeSeg VMSUSPEND
MakeCodeSeg VMRESUME
MakeCodeSeg PNP
MakeCodeSeg DOSVM
;*** DefLockableCodeBegin - define beginning of lockable code
;
; Defines a label with the given name to mark the beginning
; of the lockable code area for this VxD. In the debug version,
; also defines a DWORD containing DFS_TEST_BLOCK so that
; procedures in the lockable code segment defined with
; BeginProc may call _Debug_Flags_Service with flags appropriate
; to the code's current state.
DefLockableCodeBegin MACRO name, private
VxD_L0CKABLE_BEGIN_CODE_SEG
IFB <private>
PUBLIC name
ENDIF
name LABEL NEAR
ifdef BLD_COFF
DD ?
endif
VxD_L0CKABLE_BEGIN_CODE_ENDS
ifndef WIN31COMPAT
if DEBLEVEL
VxD_LOCKED_DATA_SEG
PUBLIC name&_Debug_Flags
name&_Debug_Flags DD DFS_TEST_BLOCK
VxD_LOCKED_DATA_ENDS
??_debug_flags equ <name&_Debug_Flags>
endif
endif
ENDM
;*** DefLockableCodeEnd - define end of lockable code
;
; Defines a label with the given name to mark the end
; of the lockable code area for this VxD. By subtracting
; the offset of the beginning label from the offset of
; the ending label, the VxD may determine how many bytes
; of memory to lock or unlock.
DefLockableCodeEnd MACRO name, private
VxD_LOCKABLE_END_CODE_SEG
IFB <private>
PUBLIC name
ENDIF
name LABEL NEAR
ifdef BLD_COFF
DD ?
endif
VxD_LOCKABLE_END_CODE_ENDS
ENDM
;*** CodeLockFlags - declare locked code debug flags
;
; This macro declares the locked code debug flags.
CodeLockFlags MACRO name
ifndef WIN31COMPAT
if DEBLEVEL
ifndef name&_Debug_Flags
VxD_LOCKED_DATA_SEG
extrn name&_Debug_Flags:dword
VxD_LOCKED_DATA_ENDS
??_debug_flags equ <name&_Debug_Flags>
endif
endif
endif
ENDM
;*** MarkCodeLocked - signify that lockable code is locked
;
; This macro clears DFS_TEST_BLOCK in the debug flags
; DWORD.
MarkCodeLocked MACRO
ifndef WIN31COMPAT
if DEBLEVEL
ifdef ??_debug_flags
pushfd
and ??_debug_flags,NOT DFS_TEST_BLOCK
popfd
endif
endif
endif
ENDM
;*** MarkCodeUnlocked - signify that lockable code is unlocked
;
; This macro sets DFS_TEST_BLOCK in the debug flags
; DWORD.
MarkCodeUnlocked MACRO
ifndef WIN31COMPAT
if DEBLEVEL
ifdef ??_debug_flags
pushfd
or ??_debug_flags,DFS_TEST_BLOCK
popfd
endif
endif
endif
ENDM
;* 32 bit initialization code
_ITEXT SEGMENT DWORD PUBLIC _FLAT 'ICODE'
_ITEXT ENDS
;* 32 bit locked data
_LDATA SEGMENT DWORD PUBLIC _FLAT 'LCODE'
_LDATA ENDS
_DATA SEGMENT DWORD PUBLIC _FLAT 'LCODE'
_DATA ENDS
;* 32 bit pageable data
_PDATA SEGMENT DWORD PUBLIC _FLAT 'PDATA'
_PDATA ENDS
;* 32 Bit initialization data
_IDATA SEGMENT DWORD PUBLIC _FLAT 'ICODE'
_IDATA ENDS
;* Created by C8
_BSS SEGMENT DWORD PUBLIC _FLAT 'LCODE'
_BSS ENDS
CONST SEGMENT DWORD PUBLIC _FLAT 'LCODE'
CONST ENDS
_TLS SEGMENT DWORD PUBLIC _FLAT 'LCODE'
_TLS ENDS
;* 32 Bit static code for DL-VxDs
_STEXT SEGMENT DWORD PUBLIC _FLAT 'SCODE'
_STEXT ENDS
;* 32 Bit static data for DL-VxDs
_SDATA SEGMENT DWORD PUBLIC _FLAT 'SCODE'
_SDATA ENDS
;* dummy segment for IsDebugOnlyLoaded
_DB0START SEGMENT DWORD PUBLIC _FLAT 'DBOCODE'
_DB0START ENDS
;* 32 bit debug only code; loaded only if debugger is present
_DB1CODE SEGMENT DWORD PUBLIC _FLAT 'DBOCODE'
_DB1CODE ENDS
;* 32 bit debug only data; loaded only if debugger is present
_DB2DATA SEGMENT DWORD PUBLIC _FLAT 'DBOCODE'
_DB2DATA ENDS
if DEBLEVEL
;* Start of 32 bit path coverage data
_PATHSTART SEGMENT DWORD PUBLIC _FLAT 'LCODE'
_PATHSTART ENDS
;* 32 bit path coverage data
_PATHDATA SEGMENT DWORD PUBLIC _FLAT 'LCODE'
_PATHDATA ENDS
;* End of 32 bit path coverage data
_PATHEND SEGMENT DWORD PUBLIC _FLAT 'LCODE'
_PATHEND ENDS
endif
;* 16 bit code/data that is put into IGROUP automaticly
_16ICODE SEGMENT WORD USE16 PUBLIC '16ICODE'
_16ICODE ENDS
;* Real Mode initialization code/data for devices
_RCODE SEGMENT WORD USE16 PUBLIC 'RCODE'
_RCODE ENDS
IFNDEF BLD_COFF
_LGROUP GROUP _LTEXT, _TEXT, _LDATA, _DATA, _BSS, CONST, _TLS
_IGROUP GROUP _ITEXT, _IDATA
_SGROUP GROUP _STEXT, _SDATA
_DBOGROUP GROUP _DB0START, _DB1CODE, _DB2DATA
IF DEBLEVEL
_PGROUP GROUP _PATHSTART, _PATHDATA, _PATHEND
ENDIF
ENDIF
endif ; NO_SEGMENTS
ASSUME CS:FLAT, DS:FLAT, ES:FLAT, SS:FLAT
OFFSET32 EQU <OFFSET FLAT:>
BeginDoc
;==============================================================================
; The following macros are used in defining the routines
; in a VxD which are going to be registered with VMM as callable entry
; points. Once registered, the entry points can be called by any other
; devices via the "VxDCall" macro, defined below. In the comments below,
; replace "VxD" with the appropriate device name.
;
;*******
; In the VxD.INC file, put the following lines, replacing <function_name>
; with an appropriate name describing the function of the routine.
;
; Begin_Service_Table VxD[,<segname>]
; VxD_Service <function_name>[,<local segname>]
; VxD_Service <function_name>[,<local segname>]
; . . .
; VxD_Service <function_name>[,<local segname>]
; End_Service_Table VxD[,<segname>]
;
; Note that <segname> is an optional argument and, if specified, the
; table is put in the segment defined by the macro "yyy_Data_Seg",
; where yyy=segname. Otherwise the segment is defined by the
; "VxD_Data_Seg" macro, defined below.
; Note that <local segname> is an optional argument and, if specified,
; the procedure's segment is defined by the macro "zzz_Code_Seg",
; where zzz=segname. Otherwise the segment is defined by the
; "VxD_Code_Seg" macro, defined below.
;
;*******
; One VxD module should have the following in order to define the entry points:
;Create_VxD_Service_Table = 1 ; Only in module where table is
; INCLUDE VxD.INC ; Include the table definition
;
;*******
; All modules that want to call the services defined in the table should include
; VxD.INC, but not define the label "Create_VxD_Service_Table". This
; will define the service names to be used with the VxDCall macro.
;
EndDoc
Begin_Service_Table MACRO Device_Name, Def_Segment
IFDEF Device_Name&_Name_Based
IFNDEF @@NextInternalID
@@NextInternalID = 0
ENDIF
@@NextInternalID = (@@NextInternalID + 1)
Device_Name&_Internal_ID = @@NextInternalID + BASEID_FOR_NAMEBASEDVXD
DefineVxDName Device_Name, %Device_Name&_Internal_ID
ENDIF
IFB <Def_Segment>
BST2 Device_Name, VxD
ELSE
BST2 Device_Name, Def_Segment
ENDIF
ENDM
DefineVxDName MACRO Device_Name, InternalID
@@VxDName&InternalID EQU <___&Device_Name&STable>
ENDM
BST2 MACRO Device_Name, Def_Segment
Num_&Device_Name&_Services = 0
IFDEF Create_&Device_Name&_Service_Table
Def_Segment&_LOCKED_DATA_SEG
Device_Name&_Service_Table LABEL DWORD
Device_Name&_Service MACRO Procedure, Local_Seg, Condition, StdCallBytes, fastcall
LOCAL $$&Procedure, extrnproc, tableproc
extrnproc MACRO
IFNB <fastcall>
IFB <StdCallBytes>
.err ;StdCallBytes required
ENDIF
EXTRN @&&Procedure&&@&&StdCallBytes:NEAR
ELSE
IFNB <StdCallBytes>
EXTRN _&&Procedure&&@&&StdCallBytes:NEAR
ELSE
EXTRN Procedure:NEAR
ENDIF
ENDIF
ENDM
tableproc MACRO
IFNB <fastcall>
dd OFFSET32 @&&Procedure&&@&&StdCallBytes
ELSE
IFNB <StdCallBytes>
dd OFFSET32 _&&Procedure&&@&&StdCallBytes
ELSE
dd OFFSET32 Procedure
ENDIF
ENDIF
ENDM
IFNB <Condition>
$$&&Procedure MACRO extern
IFDEF &Condition
IFNB <extern>
extrnproc
ELSE
tableproc
ENDIF
ELSE
IFB <extern>
dd 0
ENDIF
ENDIF
ENDM
ENDIF
IFDIFI <Procedure>, <RESERVED>
IFDIFI <Local_Seg>, <RESERVED>
PUBLIC _&&Procedure
IF1
_&&Procedure LABEL DWORD
IFNB <fastcall>
PUBLIC __&&Procedure
__&&Procedure LABEL DWORD
ENDIF
ENDIF
IFDIFI <Local_Seg>, <LOCAL>
IFNB <Local_Seg>
Local_Seg&&_SEG
ELSE
Def_Segment&_CODE_SEG
ENDIF
IFNB <Condition>
$$&&Procedure extern
ELSE
extrnproc
ENDIF
IFNB <Local_Seg>
Local_Seg&&_ENDS
ELSE
Def_Segment&_CODE_ENDS
ENDIF
ENDIF
IFNB <Condition>
$$&&Procedure
ELSE
tableproc
ENDIF
IFDEF Device_Name&_Name_Based
@@&&Procedure = (Device_Name&_Internal_ID SHL 16) + Num_&Device_Name&_Services
ELSE
@@&&Procedure = (Device_Name&_Device_ID SHL 16) + Num_&Device_Name&_Services
ENDIF
ELSE
dd 0
ENDIF
ELSE
dd 0
ENDIF
Num_&Device_Name&_Services = Num_&Device_Name&_Services + 1
IFNB <Condition>
Purge $$&&Procedure
ENDIF
Purge extrnproc
Purge tableproc
ENDM
Device_Name&_StdCall_Service MACRO Procedure, Args, Local_Seg, Condition
Device_Name&_Service Procedure, Local_Seg, Condition, %Args*4
??_standardccall&&_Procedure = Args
ENDM
Device_Name&_FastCall_Service MACRO Procedure, Args, Local_Seg, Condition
Device_Name&_Service Procedure, Local_Seg, Condition, %Args*4, TRUE
??_fastcall&&_Procedure = Args
ENDM
ELSE
; Local_Seg and Condition are placeholders only in this form
IFDEF Device_Name&_Name_Based
Device_Name&_Service MACRO Procedure, Local_Seg, Condition
IFDIFI <Procedure>, <RESERVED>
@@&&Procedure = (Device_Name&_Internal_ID SHL 16) + Num_&Device_Name&_Services
ENDIF
Num_&Device_Name&_Services = Num_&Device_Name&_Services + 1
ENDM
ELSE
Device_Name&_Service MACRO Procedure, Local_Seg, Condition
IFDIFI <Procedure>, <RESERVED>
@@&&Procedure = (Device_Name&_Device_ID SHL 16) + Num_&Device_Name&_Services
ENDIF
Num_&Device_Name&_Services = Num_&Device_Name&_Services + 1
ENDM
ENDIF
Device_Name&_StdCall_Service MACRO Procedure, Args, Local_Seg, Condition
Device_Name&_Service Procedure, Local_Seg, Condition
??_standardccall_&&Procedure = Args
ENDM
Device_Name&_FastCall_Service MACRO Procedure, Args, Local_Seg, Condition
Device_Name&_Service Procedure, Local_Seg, Condition
??_fastcall_&&Procedure = Args
ENDM
ENDIF
ENDM
;------------------------------------------------------------------------------
End_Service_Table MACRO Device_Name, Def_Segment
PURGE Device_Name&_Service
IFDEF Create_&Device_Name&_Service_Table
IFB <Def_Segment>
VxD_LOCKED_DATA_ENDS
ELSE
Def_Segment&_LOCKED_DATA_ENDS
ENDIF
ENDIF
ENDM
GetVxDServiceOrdinal macro reg,service
mov reg,@@&service
endm
GetVxDServiceAddress macro reg,service
mov reg,OFFSET32 service
endm
;*** Begin_Win32_Services - begin defining Win32 Service Table
;
; This macro is used to begin the definition of the Win32
; Service table. It is modelled after, but not identical
; to, the Begin_Service_Table macro. If the the special
; symbol Create_Win32_Services is defined to be true, then
; the actual table is emitted. Otherwise, only the service
; numbers are defined.
;
; ENTRY VxDName - the name of the VxD; it is assumed
; that a corresponding Device_ID is
; also defined.
; EXIT The macro VxDName&_Win32_Sevice is defined; it
; accepts a service name as its only parameter.
; This macro is then used to define each service.
Begin_Win32_Services MACRO VxDName
ifndef Create_Win32_Services
Create_Win32_Services = 0
endif
.errb <VxDName>, <VxD name missing>
??w32svcno = 0
if Create_Win32_Services
VxDName&_Win32_Services label dword
dd csvc&VxDName, 0
endif
??inw32svc = 1
VxDName&_Win32_Service MACRO Name
.erre ??inw32svc, <Missing Begin_Win32_Services>
if Create_Win32_Services
dd OFFSET32 Name,cparm&&Name
endif
@32&&Name equ ((VxDName&_Device_ID SHL 16) + ??w32svcno)
??w32svcno = ??w32svcno + 1
ENDM
ENDM
;*** End_Win32_Services - mark end of Win32 Service Table
;
; This macro completes initialization of the Win32
; Service table.
;
; ENTRY VxDName - the same name passed to
; Begin_Win32_services
End_Win32_Services MACRO VxDName
.errb <VxDName>, <VxD name misssing>
if Create_Win32_Services
csvc&VxDName equ ($ - VxDName&_Win32_Services)/8 - 1
endif
??inw32svc = 0
PURGE VxDName&_Win32_Service
ENDM
;*** Declare_Win32_Service - declare an external Win32 Service
;
; This macro is used to declare a Win32 service that
; is defined elsewhere, perhaps in a C module.
;
; ENTRY Name - the service name
; cParms - the number of DWORD parameters
; EXIT The name is defined as external
Declare_Win32_Service MACRO Name, cParms
ifndef Create_Win32_Services
Create_Win32_Services = 0
endif
if Create_Win32_Services
?merge <Name>,,,,<EQU>,<_>,<Name>,<@>,%(cParms*4 + 8)
?merge <cparm>,<Name>,,,<EQU>,<cParms>
VxD_CODE_SEG
?merge <EXTRN>,,,,,<_>,<Name>,<@>,%(cParms*4 + 8),<:NEAR>
VxD_CODE_ENDS
endif
ENDM
;*** Win32call - call a Win32 service from a ring 3 thunk
;
; This macro is used to call a Win32 service from
; a ring 3 thunk. Note that control will not return
; to the instruction following the call, but to the
; instruction following the call to the thunk.
;
; ENTRY Service - the name of the service
; CallBack - the fword containing the callback
Win32call MACRO Service, CallBack
ifndef Create_Win32_Services
Create_Win32_Services = 0
endif
ife Create_Win32_Services
mov eax,@32&Service
ifdef IS_16
movzx esp,sp
endif
call fword ptr [CallBack]
ifdef DEBUG
int 3
endif
endif
ENDM
*/
/*XLATOFF*/
#define GetVxDServiceAddress(service) service
#define VxDCall(service) \
_asm _emit 0xcd \
_asm _emit 0x20 \
_asm _emit (GetVxDServiceOrdinal(service) & 0xff) \
_asm _emit (GetVxDServiceOrdinal(service) >> 8) & 0xff \
_asm _emit (GetVxDServiceOrdinal(service) >> 16) & 0xff \
_asm _emit (GetVxDServiceOrdinal(service) >> 24) & 0xff \
#define VMMCall VxDCall
#define VxDJmp(service) \
_asm _emit 0xcd \
_asm _emit 0x20 \
_asm _emit (GetVxDServiceOrdinal(service) & 0xff) \
_asm _emit ((GetVxDServiceOrdinal(service) >> 8) & 0xff) | 0x80 \
_asm _emit (GetVxDServiceOrdinal(service) >> 16) & 0xff \
_asm _emit (GetVxDServiceOrdinal(service) >> 24) & 0xff \
#define VMMJmp VxDJmp
#define SERVICE __cdecl
#define ASYNC_SERVICE __cdecl
#define WIN32_SERVICE void __stdcall
#ifndef FASTCALL
#define FASTCALL __fastcall
#endif
/*XLATON*/
/* ASM
;******************************************************************************
;
; Dword_Align -- Aligns code to dword boundry by inserting nops
;
;------------------------------------------------------------------------------
Dword_Align MACRO Seg_Name
LOCAL segn
IFDEF MASM6
align 4
ELSE
IFNB <Seg_Name>
segn equ Seg_Name
ELSE
IFE ?_LCODE
segn equ <_LTEXT>
ELSE
IFE ?_ICODE
segn equ <_ITEXT>
ELSE
IFE ?_PCODE
segn equ <_PTEXT>
ELSE
IFE ?_SCODE
segn equ <_STEXT>
ELSE
.err <Dword_Align not supported>
ENDIF
ENDIF
ENDIF
ENDIF
ENDIF
IF (($-OFFSET segn:0) MOD 4)
db 4 - (($-OFFSET segn:0) MOD 4) DUP (90h)
ENDIF
ENDIF
ENDM
BeginDoc
;******************************************************************************
;
; Fatal_Error
;
; DESCRIPTION:
; This macro is used to crash Windows/386 when an unrecoverable error
; is detected. If Msg_Ptr is ommitted then no error message will be
; displayed, otherwise Msg_Ptr is the address
; when the
;
; PARAMETERS:
; Msg_Ptr (OPTIONAL) - Points to an ASCIIZ string to display.
;
; EXIT:
; To DOS (hopefully). This macro never returns.
;
;==============================================================================
EndDoc
Fatal_Error MACRO Msg_Ptr, Exit_Flags
pushad
IFB <Msg_Ptr>
xor esi, esi
ELSE
mov esi, Msg_Ptr
IFB <Exit_Flags>
xor eax, eax
ELSE
mov eax, Exit_Flags
ENDIF
ENDIF
VMMCall Fatal_Error_Handler
ENDM
EF_Hang_On_Exit EQU 1h
*/
/******************************************************************************
*
* The following are control block headers and flags of interest to VxDs.
*
*****************************************************************************/
struct cb_s {
ULONG CB_VM_Status; /* VM status flags */
ULONG CB_High_Linear; /* Address of VM mapped high */
ULONG CB_Client_Pointer;
ULONG CB_VMID;
ULONG CB_Signature;
};
#define VMCB_ID 0x62634D56 /* VMcb */
/*
* VM status indicates globally interesting VM states
*/
#define VMSTAT_EXCLUSIVE_BIT 0x00 /* VM is exclusive mode */
#define VMSTAT_EXCLUSIVE (1L << VMSTAT_EXCLUSIVE_BIT)
#define VMSTAT_BACKGROUND_BIT 0x01 /* VM runs in background */
#define VMSTAT_BACKGROUND (1L << VMSTAT_BACKGROUND_BIT)
#define VMSTAT_CREATING_BIT 0x02 /* In process of creating */
#define VMSTAT_CREATING (1L << VMSTAT_CREATING_BIT)
#define VMSTAT_SUSPENDED_BIT 0x03 /* VM not scheduled */
#define VMSTAT_SUSPENDED (1L << VMSTAT_SUSPENDED_BIT)
#define VMSTAT_NOT_EXECUTEABLE_BIT 0x04 /* VM partially destroyed */
#define VMSTAT_NOT_EXECUTEABLE (1L << VMSTAT_NOT_EXECUTEABLE_BIT)
#define VMSTAT_PM_EXEC_BIT 0x05 /* Currently in PM app */
#define VMSTAT_PM_EXEC (1L << VMSTAT_PM_EXEC_BIT)
#define VMSTAT_PM_APP_BIT 0x06 /* PM app present in VM */
#define VMSTAT_PM_APP (1L << VMSTAT_PM_APP_BIT)
#define VMSTAT_PM_USE32_BIT 0x07 /* PM app is 32-bit */
#define VMSTAT_PM_USE32 (1L << VMSTAT_PM_USE32_BIT)
#define VMSTAT_VXD_EXEC_BIT 0x08 /* Call from VxD */
#define VMSTAT_VXD_EXEC (1L << VMSTAT_VXD_EXEC_BIT)
#define VMSTAT_HIGH_PRI_BACK_BIT 0x09 /* High pri background */
#define VMSTAT_HIGH_PRI_BACK (1L << VMSTAT_HIGH_PRI_BACK_BIT)
#define VMSTAT_BLOCKED_BIT 0x0A /* Blocked on semaphore */
#define VMSTAT_BLOCKED (1L << VMSTAT_BLOCKED_BIT)
#define VMSTAT_AWAKENING_BIT 0x0B /* Woke up after blocked */
#define VMSTAT_AWAKENING (1L << VMSTAT_AWAKENING_BIT)
#define VMSTAT_PAGEABLEV86BIT 0x0C /* part of V86 is pageable (PM app) */
#define VMSTAT_PAGEABLEV86_BIT VMSTAT_PAGEABLEV86BIT
#define VMSTAT_PAGEABLEV86 (1L << VMSTAT_PAGEABLEV86BIT)
#define VMSTAT_V86INTSLOCKEDBIT 0x0D /* Locked regardless of pager type */
#define VMSTAT_V86INTSLOCKED_BIT VMSTAT_V86INTSLOCKEDBIT
#define VMSTAT_V86INTSLOCKED (1L << VMSTAT_V86INTSLOCKEDBIT)
#define VMSTAT_IDLE_TIMEOUT_BIT 0x0E /* Scheduled by time-slicer */
#define VMSTAT_IDLE_TIMEOUT (1L << VMSTAT_IDLE_TIMEOUT_BIT)
#define VMSTAT_IDLE_BIT 0x0F /* VM has released time slice */
#define VMSTAT_IDLE (1L << VMSTAT_IDLE_BIT)
#define VMSTAT_CLOSING_BIT 0x10 /* Close_VM called for VM */
#define VMSTAT_CLOSING (1L << VMSTAT_CLOSING_BIT)
#define VMSTAT_TS_SUSPENDED_BIT 0x11 /* VM suspended by */
#define VMSTAT_TS_SUSPENDED (1L << VMSTAT_TS_SUSPENDED_BIT)
#define VMSTAT_TS_MAXPRI_BIT 0x12 /* this is fgd_pri 10,000 internally*/
#define VMSTAT_TS_MAXPRI (1L << VMSTAT_TS_MAXPRI_BIT)
#define VMSTAT_USE32_MASK (VMSTAT_PM_USE32 | VMSTAT_VXD_EXEC)
struct tcb_s {
ULONG TCB_Flags; /* Thread status flags */
ULONG TCB_Reserved1; /* Used internally by VMM */
ULONG TCB_Reserved2; /* Used internally by VMM */
ULONG TCB_Signature;
ULONG TCB_ClientPtr; /* Client registers of thread */
ULONG TCB_VMHandle; /* VM that thread is part of */
USHORT TCB_ThreadId; /* Unique Thread ID */
USHORT TCB_PMLockOrigSS; /* Original SS:ESP before lock stack */
ULONG TCB_PMLockOrigESP;
ULONG TCB_PMLockOrigEIP; /* Original CS:EIP before lock stack */
ULONG TCB_PMLockStackCount;
USHORT TCB_PMLockOrigCS;
USHORT TCB_PMPSPSelector;
ULONG TCB_ThreadType; /* dword passed to VMMCreateThread */
USHORT TCB_pad1; /* reusable; for dword align */
UCHAR TCB_pad2; /* reusable; for dword align */
UCHAR TCB_extErrLocus; /* extended error Locus */
USHORT TCB_extErr; /* extended error Code */
UCHAR TCB_extErrAction; /* " " Action */
UCHAR TCB_extErrClass; /* " " Class */
ULONG TCB_extErrPtr; /* " pointer */
};
typedef struct tcb_s TCB;
typedef TCB *PTCB;
#define SCHED_OBJ_ID_THREAD 0x42434854 // THCB in ASCII
/*
* Thread status indicates globally interesting thread states.
* Flags are for information only and must not be modified.
*/
#define THFLAG_SUSPENDED_BIT 0x03 // Thread not scheduled
#define THFLAG_SUSPENDED (1L << THFLAG_SUSPENDED_BIT)
#define THFLAG_NOT_EXECUTEABLE_BIT 0x04 // Thread partially destroyed
#define THFLAG_NOT_EXECUTEABLE (1L << THFLAG_NOT_EXECUTEABLE_BIT)
#define THFLAG_THREAD_CREATION_BIT 0x08 // Thread in status nascendi
#define THFLAG_THREAD_CREATION (1L << THFLAG_THREAD_CREATION_BIT)
#define THFLAG_THREAD_BLOCKED_BIT 0x0A // Blocked on semaphore
#define THFLAG_THREAD_BLOCKED (1L << THFLAG_THREAD_BLOCKED_BIT)
#define THFLAG_RING0_THREAD_BIT 0x1C // thread runs only at ring 0
#define THFLAG_RING0_THREAD (1L << THFLAG_RING0_THREAD_BIT)
#define THFLAG_ASYNC_THREAD_BIT 0x1F // thread is asynchronous
#define THFLAG_ASYNC_THREAD (1L << THFLAG_ASYNC_THREAD_BIT)
#define THFLAG_CHARSET_BITS 0x10 // Default character set
#define THFLAG_CHARSET_MASK (3L << THFLAG_CHARSET_BITS)
#define THFLAG_ANSI (0L << THFLAG_CHARSET_BITS)
#define THFLAG_OEM (1L << THFLAG_CHARSET_BITS)
#define THFLAG_UNICODE (2L << THFLAG_CHARSET_BITS)
#define THFLAG_RESERVED (3L << THFLAG_CHARSET_BITS)
#define THFLAG_EXTENDED_HANDLES_BIT 0x12 // Thread uses extended file handles
#define THFLAG_EXTENDED_HANDLES (1L << THFLAG_EXTENDED_HANDLES_BIT)
/* the win32 loader opens win32 exes with this bit set to notify IFS
* so a defragger won't move these files
* the bit is turned off once the open completes.
* file open flags are overloaded which is why this is here
*/
#define THFLAG_OPEN_AS_IMMOVABLE_FILE_BIT 0x13 // File thus opened not moved
#define THFLAG_OPEN_AS_IMMOVABLE_FILE (1L << THFLAG_OPEN_AS_IMMOVABLE_FILE_BIT)
/*
* Protected mode application control blocks
*/
struct pmcb_s {
ULONG PMCB_Flags;
ULONG PMCB_Parent;
};
/*
* The reference data for fault error codes 1-5 (GSDVME_PRIVINST through
* GSDVME_INVALFLT) is a pointer to the following fault information structure.
*/
struct VMFaultInfo {
ULONG VMFI_EIP; // faulting EIP
WORD VMFI_CS; // faulting CS
WORD VMFI_Ints; // interrupts in service, if any
};
typedef struct VMFaultInfo *PVMFaultInfo;
/******************************************************************************
* V M M S E R V I C E S
******************************************************************************/
/*XLATOFF*/
#define VMM_Service Declare_Service
#define VMM_StdCall_Service Declare_SCService
#define VMM_FastCall_Service Declare_SCService
#pragma warning (disable:4003) // turn off not enough params warning
/*XLATON*/
/*MACROS*/
Begin_Service_Table(VMM, VMM)
VMM_Service (Get_VMM_Version, LOCAL) // MUST REMAIN SERVICE 0!
VMM_Service (Get_Cur_VM_Handle)
VMM_Service (Test_Cur_VM_Handle)
VMM_Service (Get_Sys_VM_Handle)
VMM_Service (Test_Sys_VM_Handle)
VMM_Service (Validate_VM_Handle)
VMM_Service (Get_VMM_Reenter_Count)
VMM_Service (Begin_Reentrant_Execution)
VMM_Service (End_Reentrant_Execution)
VMM_Service (Install_V86_Break_Point)
VMM_Service (Remove_V86_Break_Point)
VMM_Service (Allocate_V86_Call_Back)
VMM_Service (Allocate_PM_Call_Back)
VMM_Service (Call_When_VM_Returns)
VMM_Service (Schedule_Global_Event)
VMM_Service (Schedule_VM_Event)
VMM_Service (Call_Global_Event)
VMM_Service (Call_VM_Event)
VMM_Service (Cancel_Global_Event)
VMM_Service (Cancel_VM_Event)
VMM_Service (Call_Priority_VM_Event)
VMM_Service (Cancel_Priority_VM_Event)
VMM_Service (Get_NMI_Handler_Addr)
VMM_Service (Set_NMI_Handler_Addr)
VMM_Service (Hook_NMI_Event)
VMM_Service (Call_When_VM_Ints_Enabled)
VMM_Service (Enable_VM_Ints)
VMM_Service (Disable_VM_Ints)
VMM_Service (Map_Flat)
VMM_Service (Map_Lin_To_VM_Addr)
// Scheduler services
VMM_Service (Adjust_Exec_Priority)
VMM_Service (Begin_Critical_Section)
VMM_Service (End_Critical_Section)
VMM_Service (End_Crit_And_Suspend)
VMM_Service (Claim_Critical_Section)
VMM_Service (Release_Critical_Section)
VMM_Service (Call_When_Not_Critical)
VMM_Service (Create_Semaphore)
VMM_Service (Destroy_Semaphore)
VMM_Service (Wait_Semaphore)
VMM_Service (Signal_Semaphore)
VMM_Service (Get_Crit_Section_Status)
VMM_Service (Call_When_Task_Switched)
VMM_Service (Suspend_VM)
VMM_Service (Resume_VM)
VMM_Service (No_Fail_Resume_VM)
VMM_Service (Nuke_VM)
VMM_Service (Crash_Cur_VM)
VMM_Service (Get_Execution_Focus)
VMM_Service (Set_Execution_Focus)
VMM_Service (Get_Time_Slice_Priority)
VMM_Service (Set_Time_Slice_Priority)
VMM_Service (Get_Time_Slice_Granularity)
VMM_Service (Set_Time_Slice_Granularity)
VMM_Service (Get_Time_Slice_Info)
VMM_Service (Adjust_Execution_Time)
VMM_Service (Release_Time_Slice)
VMM_Service (Wake_Up_VM)
VMM_Service (Call_When_Idle)
VMM_Service (Get_Next_VM_Handle)
// Time-out and system timer services
VMM_Service (Set_Global_Time_Out)
VMM_Service (Set_VM_Time_Out)
VMM_Service (Cancel_Time_Out)
VMM_Service (Get_System_Time)
VMM_Service (Get_VM_Exec_Time)
VMM_Service (Hook_V86_Int_Chain)
VMM_Service (Get_V86_Int_Vector)
VMM_Service (Set_V86_Int_Vector)
VMM_Service (Get_PM_Int_Vector)
VMM_Service (Set_PM_Int_Vector)
VMM_Service (Simulate_Int)
VMM_Service (Simulate_Iret)
VMM_Service (Simulate_Far_Call)
VMM_Service (Simulate_Far_Jmp)
VMM_Service (Simulate_Far_Ret)
VMM_Service (Simulate_Far_Ret_N)
VMM_Service (Build_Int_Stack_Frame)
VMM_Service (Simulate_Push)
VMM_Service (Simulate_Pop)
// Heap Manager
VMM_Service (_HeapAllocate)
VMM_Service (_HeapReAllocate)
VMM_Service (_HeapFree)
VMM_Service (_HeapGetSize)
/*ENDMACROS*/
/****************************************************
*
* Flags for heap allocator calls
*
* NOTE: HIGH 8 BITS (bits 24-31) are reserved
*
***************************************************/
//
// Flags affecting the returned block
//
#define HEAPZEROINIT 0x00000001
#define HEAPZEROREINIT 0x00000002
#define HEAPNOCOPY 0x00000004
//
// Alignment flags
//
#define HEAPALIGN_SHIFT 16
#define HEAPALIGN_MASK 0x000F0000
#define HEAPALIGN_4 0x00000000 // dword aligned
#define HEAPALIGN_8 0x00000000 // quadword aligned
#define HEAPALIGN_16 0x00000000 // paragraph aligned
#define HEAPALIGN_32 0x00010000 // etc.
#define HEAPALIGN_64 0x00020000
#define HEAPALIGN_128 0x00030000
#define HEAPALIGN_256 0x00040000
#define HEAPALIGN_512 0x00050000
#define HEAPALIGN_1K 0x00060000
#define HEAPALIGN_2K 0x00070000
#define HEAPALIGN_4K 0x00080000
#define HEAPALIGN_8K 0x00090000
#define HEAPALIGN_16K 0x000A0000
#define HEAPALIGN_32K 0x000B0000
#define HEAPALIGN_64K 0x000C0000
#define HEAPALIGN_128K 0x000D0000
//
// Flags indicating which system heap to use. There are four bits reserved
// to identify the heap to use. Four are currently defined by the system.
//
#define HEAPTYPESHIFT 8
#define HEAPTYPEMASK 0x00000700
#define HEAPLOCKEDHIGH 0x00000000
#define HEAPLOCKEDIFDP 0x00000100
#define HEAPSWAP 0x00000200
#define HEAPINIT 0x00000400 // will be automatically freed after
// init complete
//
// other flags
//
#define HEAPCLEAN 0x00000800
#define HEAPCONTIG 0x00001000 // memory must be physically contiguous
#define HEAPFORGET 0x00002000 // this memory will never be freed
//
// Combinations of flags understood by HeapAllocateEx
//
#define HEAPLOCKEDLOW 0x00000300
#define HEAPSYSVM 0x00000500
#define HEAPPREEMPT 0x00000600 // code in this heap is preemptable
// Page Manager
/*MACROS*/
VMM_Service (_PageAllocate)
VMM_Service (_PageReAllocate)
VMM_Service (_PageFree)
VMM_Service (_PageLock)
VMM_Service (_PageUnLock)
VMM_Service (_PageGetSizeAddr)
VMM_Service (_PageGetAllocInfo)
VMM_Service (_GetFreePageCount)
VMM_Service (_GetSysPageCount)
VMM_Service (_GetVMPgCount)
VMM_Service (_MapIntoV86)
VMM_Service (_PhysIntoV86)
VMM_Service (_TestGlobalV86Mem)
VMM_Service (_ModifyPageBits)
VMM_Service (_CopyPageTable)
VMM_Service (_LinMapIntoV86)
VMM_Service (_LinPageLock)
VMM_Service (_LinPageUnLock)
VMM_Service (_SetResetV86Pageable)
VMM_Service (_GetV86PageableArray)
VMM_Service (_PageCheckLinRange)
VMM_Service (_PageOutDirtyPages)
VMM_Service (_PageDiscardPages)
/*ENDMACROS*/
/****************************************************
*
* Flags for other page allocator calls
*
* NOTE: HIGH 8 BITS (bits 24-31) are reserved
*
***************************************************/
#define PAGEZEROINIT 0x00000001
#define PAGEUSEALIGN 0x00000002
#define PAGECONTIG 0x00000004
#define PAGEFIXED 0x00000008
#define PAGEDEBUGNULFAULT 0x00000010
#define PAGEZEROREINIT 0x00000020
#define PAGENOCOPY 0x00000040
#define PAGELOCKED 0x00000080
#define PAGELOCKEDIFDP 0x00000100
#define PAGESETV86PAGEABLE 0x00000200
#define PAGECLEARV86PAGEABLE 0x00000400
#define PAGESETV86INTSLOCKED 0x00000800
#define PAGECLEARV86INTSLOCKED 0x00001000
#define PAGEMARKPAGEOUT 0x00002000
#define PAGEPDPSETBASE 0x00004000
#define PAGEPDPCLEARBASE 0x00008000
#define PAGEDISCARD 0x00010000
#define PAGEPDPQUERYDIRTY 0x00020000
#define PAGEMAPFREEPHYSREG 0x00040000
#define PAGEPHYSONLY 0x04000000
//efine PAGEDONTUSE 0x08000000 // ;Internal
#define PAGENOMOVE 0x10000000
#define PAGEMAPGLOBAL 0x40000000
#define PAGEMARKDIRTY 0x80000000
/****************************************************
*
* Flags for _PhysIntoV86,
* _MapIntoV86, and _LinMapIntoV86
*
***************************************************/
#define MAPV86_IGNOREWRAP 0x00000001
/****************************************************
*
* Flags for MapPhysToLinear
*
*
***************************************************/
#define MPL_NonCached 0x00000000
#define MPL_HardwareCoherentCached 0x00000001
#define MPL_FrameBufferCached 0x00000002
#define MPL_Cached 0x00000004
#define MPL_Undoable 0x00000008
#define MPL_Flags 0x0000000F // OR of the above
// Informational services
/*MACROS*/
VMM_Service (_GetNulPageHandle)
VMM_Service (_GetFirstV86Page)
VMM_Service (_MapPhysToLinear)
VMM_Service (_GetAppFlatDSAlias)
VMM_Service (_SelectorMapFlat)
VMM_Service (_GetDemandPageInfo)
VMM_Service (_GetSetPageOutCount)
/*ENDMACROS*/
/*
* Flags bits for _GetSetPageOutCount
*/
#define GSPOC_F_GET 0x00000001
// Device VM page manager
/*MACROS*/
VMM_Service (Hook_V86_Page)
VMM_Service (_Assign_Device_V86_Pages)
VMM_Service (_DeAssign_Device_V86_Pages)
VMM_Service (_Get_Device_V86_Pages_Array)
VMM_Service (MMGR_SetNULPageAddr)
// GDT/LDT management
VMM_Service (_Allocate_GDT_Selector)
VMM_Service (_Free_GDT_Selector)
VMM_Service (_Allocate_LDT_Selector)
VMM_Service (_Free_LDT_Selector)
VMM_Service (_BuildDescriptorDWORDs)
VMM_Service (_GetDescriptor)
VMM_Service (_SetDescriptor)
/*ENDMACROS*/
/*
* Flag equates for _Allocate_GDT_Selector
*/
#define ALLOCFROMEND 0x40000000
/*
* Flag equates for _BuildDescriptorDWORDs
*/
#define BDDEXPLICITDPL 0x00000001
/*
* Flag equates for _Allocate_LDT_Selector
*/
#define ALDTSPECSEL 0x00000001
/*MACROS*/
VMM_Service (_MMGR_Toggle_HMA)
/*ENDMACROS*/
/*
* Flag equates for _MMGR_Toggle_HMA
*/
#define MMGRHMAPHYSICAL 0x00000001
#define MMGRHMAENABLE 0x00000002
#define MMGRHMADISABLE 0x00000004
#define MMGRHMAQUERY 0x00000008
/*MACROS*/
VMM_Service (Get_Fault_Hook_Addrs)
VMM_Service (Hook_V86_Fault)
VMM_Service (Hook_PM_Fault)
VMM_Service (Hook_VMM_Fault)
VMM_Service (Begin_Nest_V86_Exec)
VMM_Service (Begin_Nest_Exec)
VMM_Service (Exec_Int)
VMM_Service (Resume_Exec)
VMM_Service (End_Nest_Exec)
VMM_Service (Allocate_PM_App_CB_Area, VMM_ICODE)
VMM_Service (Get_Cur_PM_App_CB)
VMM_Service (Set_V86_Exec_Mode)
VMM_Service (Set_PM_Exec_Mode)
VMM_Service (Begin_Use_Locked_PM_Stack)
VMM_Service (End_Use_Locked_PM_Stack)
VMM_Service (Save_Client_State)
VMM_Service (Restore_Client_State)
VMM_Service (Exec_VxD_Int)
VMM_Service (Hook_Device_Service)
VMM_Service (Hook_Device_V86_API)
VMM_Service (Hook_Device_PM_API)
VMM_Service (System_Control)
// I/O and software interrupt hooks
VMM_Service (Simulate_IO)
VMM_Service (Install_Mult_IO_Handlers)
VMM_Service (Install_IO_Handler)
VMM_Service (Enable_Global_Trapping)
VMM_Service (Enable_Local_Trapping)
VMM_Service (Disable_Global_Trapping)
VMM_Service (Disable_Local_Trapping)
// Linked List Abstract Data Type Services
VMM_Service (List_Create)
VMM_Service (List_Destroy)
VMM_Service (List_Allocate)
VMM_Service (List_Attach)
VMM_Service (List_Attach_Tail)
VMM_Service (List_Insert)
VMM_Service (List_Remove)
VMM_Service (List_Deallocate)
VMM_Service (List_Get_First)
VMM_Service (List_Get_Next)
VMM_Service (List_Remove_First)
/*ENDMACROS*/
/*
* Flags used by List_Create
*/
#define LF_ASYNC_BIT 0
#define LF_ASYNC (1 << LF_ASYNC_BIT)
#define LF_USE_HEAP_BIT 1
#define LF_USE_HEAP (1 << LF_USE_HEAP_BIT)
#define LF_ALLOC_ERROR_BIT 2
#define LF_ALLOC_ERROR (1 << LF_ALLOC_ERROR_BIT)
/*
* Swappable lists must use the heap.
*/
#define LF_SWAP (LF_USE_HEAP + (1 << 3))
/******************************************************************************
* I N I T I A L I Z A T I O N P R O C E D U R E S
******************************************************************************/
// Instance data manager
/*MACROS*/
VMM_Service (_AddInstanceItem)
// System structure data manager
VMM_Service (_Allocate_Device_CB_Area)
VMM_Service (_Allocate_Global_V86_Data_Area, VMM_ICODE)
VMM_Service (_Allocate_Temp_V86_Data_Area)
VMM_Service (_Free_Temp_V86_Data_Area)
/*ENDMACROS*/
/*
* Flag bits for _Allocate_Global_V86_Data_Area
*/
#define GVDAWordAlign 0x00000001
#define GVDADWordAlign 0x00000002
#define GVDAParaAlign 0x00000004
#define GVDAPageAlign 0x00000008
#define GVDAInstance 0x00000100
#define GVDAZeroInit 0x00000200
#define GVDAReclaim 0x00000400
#define GVDAInquire 0x00000800
#define GVDAHighSysCritOK 0x00001000
#define GVDAOptInstance 0x00002000
#define GVDAForceLow 0x00004000
/*
* Flag bits for _Allocate_Temp_V86_Data_Area
*/
#define TVDANeedTilInitComplete 0x00000001
// Initialization information calls (win.ini and environment parameters)
/*MACROS*/
VMM_Service (Get_Profile_Decimal_Int, VMM_ICODE)
VMM_Service (Convert_Decimal_String, VMM_ICODE)
VMM_Service (Get_Profile_Fixed_Point, VMM_ICODE)
VMM_Service (Convert_Fixed_Point_String, VMM_ICODE)
VMM_Service (Get_Profile_Hex_Int, VMM_ICODE)
VMM_Service (Convert_Hex_String, VMM_ICODE)
VMM_Service (Get_Profile_Boolean, VMM_ICODE)
VMM_Service (Convert_Boolean_String, VMM_ICODE)
VMM_Service (Get_Profile_String, VMM_ICODE)
VMM_Service (Get_Next_Profile_String, VMM_ICODE)
VMM_Service (Get_Environment_String, VMM_ICODE)
VMM_Service (Get_Exec_Path, VMM_ICODE)
VMM_Service (Get_Config_Directory, VMM_ICODE)
VMM_Service (OpenFile, VMM_ICODE)
/*ENDMACROS*/
// OpenFile, if called after init, must point EDI to a buffer of at least
// this size.
#define VMM_OPENFILE_BUF_SIZE 260
/*MACROS*/
VMM_Service (Get_PSP_Segment, VMM_ICODE)
VMM_Service (GetDOSVectors, VMM_ICODE)
VMM_Service (Get_Machine_Info)
/*ENDMACROS*/
#define GMIF_80486_BIT 0x10
#define GMIF_80486 (1 << GMIF_80486_BIT)
#define GMIF_PCXT_BIT 0x11
#define GMIF_PCXT (1 << GMIF_PCXT_BIT)
#define GMIF_MCA_BIT 0x12
#define GMIF_MCA (1 << GMIF_MCA_BIT)
#define GMIF_EISA_BIT 0x13
#define GMIF_EISA (1 << GMIF_EISA_BIT)
#define GMIF_CPUID_BIT 0x14
#define GMIF_CPUID (1 << GMIF_CPUID_BIT)
#define GMIF_80586_BIT 0x15
#define GMIF_80586 (1 << GMIF_80586_BIT)
// Following service is not restricted to initialization
/*MACROS*/
VMM_Service (GetSet_HMA_Info)
VMM_Service (RESERVED_Set_System_Exit_Code, RESERVED) // Obsoleted in 4.90
VMM_Service (Fatal_Error_Handler)
VMM_Service (Fatal_Memory_Error)
// Called by VTD only
VMM_Service (Update_System_Clock)
/******************************************************************************
* D E B U G G I N G E X T E R N S
******************************************************************************/
VMM_Service (Test_Debug_Installed) // Valid call in retail also
VMM_Service (Out_Debug_String)
VMM_Service (Out_Debug_Chr)
VMM_Service (In_Debug_Chr)
VMM_Service (Debug_Convert_Hex_Binary)
VMM_Service (Debug_Convert_Hex_Decimal)
VMM_Service (Debug_Test_Valid_Handle)
VMM_Service (Validate_Client_Ptr)
VMM_Service (Test_Reenter)
VMM_Service (Queue_Debug_String)
VMM_Service (Log_Proc_Call)
VMM_Service (Debug_Test_Cur_VM)
VMM_Service (Get_PM_Int_Type)
VMM_Service (Set_PM_Int_Type)
VMM_Service (Get_Last_Updated_System_Time)
VMM_Service (Get_Last_Updated_VM_Exec_Time)
VMM_Service (Test_DBCS_Lead_Byte) // for DBCS Enabling
/*ENDMACROS*/
/* ASM
.errnz @@Test_DBCS_Lead_Byte - 100D1h ; VMM service table changed above this service
*/
/*************************************************************************
*************************************************************************
* END OF 3.00 SERVICE TABLE MUST NOT SHUFFLE SERVICES BEFORE THIS POINT
* FOR COMPATIBILITY.
*************************************************************************
*************************************************************************/
/*MACROS*/
VMM_Service (_AddFreePhysPage, VMM_ICODE)
VMM_Service (_PageResetHandlePAddr)
VMM_Service (_SetLastV86Page, VMM_ICODE)
VMM_Service (_GetLastV86Page)
VMM_Service (_MapFreePhysReg)
VMM_Service (_UnmapFreePhysReg)
VMM_Service (_XchgFreePhysReg)
VMM_Service (_SetFreePhysRegCalBk, VMM_ICODE)
VMM_Service (Get_Next_Arena, VMM_ICODE)
VMM_Service (Get_Name_Of_Ugly_TSR, VMM_ICODE)
VMM_Service (Get_Debug_Options, VMM_ICODE)
/*ENDMACROS*/
/*
* Flags for AddFreePhysPage
*/
// 4.90: AFPP_SWAPOUT is no longer interesting: we no longer restore to DOS
//#define AFPP_SWAPOUT 0x0001 // physical memory that must be swapped out
// // and subsequently restored at system exit
#define AFPP_MAPNUL 0x0002 // 4.90: Memory must be map nul (for V86 pages)
/*
* Flags for PageChangePager
*/
#define PCP_CHANGEPAGER 0x1 // change the pager for the page range
#define PCP_CHANGEPAGERDATA 0x2 // change the pager data dword for the pages
#define PCP_VIRGINONLY 0x4 // make the above changes to virgin pages only
/*
* Bits for the ECX return of Get_Next_Arena
*/
#define GNA_HIDOSLINKED 0x0002 // High DOS arenas linked when WIN386 started
#define GNA_ISHIGHDOS 0x0004 // High DOS arenas do exist
/*MACROS*/
VMM_Service (Set_Physical_HMA_Alias, VMM_ICODE)
VMM_Service (_GetGlblRng0V86IntBase, VMM_ICODE)
VMM_Service (_Add_Global_V86_Data_Area, VMM_ICODE)
VMM_Service (GetSetDetailedVMError)
/*ENDMACROS*/
/*
* Error code values for the GetSetDetailedVMError service. PLEASE NOTE
* that all of these error code values need to have bits set in the high
* word. This is to prevent collisions with other VMDOSAPP standard errors.
* Also, the low word must be non-zero.
*
* First set of errors (high word = 0001) are intended to be used
* when a VM is CRASHED (VNE_Crashed or VNE_Nuked bit set on
* VM_Not_Executeable).
*
* PLEASE NOTE that each of these errors (high word == 0001) actually
* has two forms:
*
* 0001xxxxh
* 8001xxxxh
*
* The device which sets the error initially always sets the error with
* the high bit CLEAR. The system will then optionally set the high bit
* depending on the result of the attempt to "nicely" crash the VM. This
* bit allows the system to tell the user whether the crash is likely or
* unlikely to destabalize the system.
*/
#define GSDVME_PRIVINST 0x00010001 /* Privledged instruction */
#define GSDVME_INVALINST 0x00010002 /* Invalid instruction */
#define GSDVME_INVALPGFLT 0x00010003 /* Invalid page fault */
#define GSDVME_INVALGPFLT 0x00010004 /* Invalid GP fault */
#define GSDVME_INVALFLT 0x00010005 /* Unspecified invalid fault */
#define GSDVME_USERNUKE 0x00010006 /* User requested NUKE of VM */
#define GSDVME_DEVNUKE 0x00010007 /* Device specific problem */
#define GSDVME_DEVNUKEHDWR 0x00010008 /* Device specific problem:
* invalid hardware fiddling
* by VM (invalid I/O)
*/
#define GSDVME_NUKENOMSG 0x00010009 /* Supress standard messages:
* SHELL_Message used for
* custom msg.
*/
#define GSDVME_OKNUKEMASK 0x80000000 /* "Nice nuke" bit */
/*
* Second set of errors (high word = 0002) are intended to be used
* when a VM start up is failed (VNE_CreateFail, VNE_CrInitFail, or
* VNE_InitFail bit set on VM_Not_Executeable).
*/
#define GSDVME_INSMEMV86 0x00020001 /* base V86 mem - V86MMGR */
#define GSDVME_INSV86SPACE 0x00020002 /* Kb Req too large - V86MMGR */
#define GSDVME_INSMEMXMS 0x00020003 /* XMS Kb Req - V86MMGR */
#define GSDVME_INSMEMEMS 0x00020004 /* EMS Kb Req - V86MMGR */
#define GSDVME_INSMEMV86HI 0x00020005 /* Hi DOS V86 mem - DOSMGR
* V86MMGR
*/
#define GSDVME_INSMEMVID 0x00020006 /* Base Video mem - VDD */
#define GSDVME_INSMEMVM 0x00020007 /* Base VM mem - VMM
* CB, Inst Buffer
*/
#define GSDVME_INSMEMDEV 0x00020008 /* Couldn't alloc base VM
* memory for device.
*/
#define GSDVME_CRTNOMSG 0x00020009 /* Supress standard messages:
* SHELL_Message used for
* custom msg.
*/
/*MACROS*/
VMM_Service (Is_Debug_Chr)
// Mono_Out services
VMM_Service (Clear_Mono_Screen)
VMM_Service (Out_Mono_Chr)
VMM_Service (Out_Mono_String)
VMM_Service (Set_Mono_Cur_Pos)
VMM_Service (Get_Mono_Cur_Pos)
VMM_Service (Get_Mono_Chr)
// Service locates a byte in ROM
VMM_Service (Locate_Byte_In_ROM, VMM_ICODE)
VMM_Service (Hook_Invalid_Page_Fault)
VMM_Service (Unhook_Invalid_Page_Fault)
/*ENDMACROS*/
/*
* Flag bits of IPF_Flags
*/
#define IPF_PGDIR 0x00000001 /* Page directory entry not-present */
#define IPF_V86PG 0x00000002 /* Unexpected not present Page in V86 */
#define IPF_V86PGH 0x00000004 /* Like IPF_V86PG at high linear */
#define IPF_INVTYP 0x00000008 /* page has invalid not present type */
#define IPF_PGERR 0x00000010 /* pageswap device failure */
#define IPF_REFLT 0x00000020 /* re-entrant page fault */
#define IPF_VMM 0x00000040 /* Page fault caused by a VxD */
#define IPF_PM 0x00000080 /* Page fault by VM in Prot Mode */
#define IPF_V86 0x00000100 /* Page fault by VM in V86 Mode */
/*MACROS*/
VMM_Service (RESERVED_Set_Delete_On_Exit_File, RESERVED) /* STOP WORKING IN 4.90 */
VMM_Service (Close_VM)
/*ENDMACROS*/
/*
* Flags for Close_VM service
*/
#define CVF_CONTINUE_EXEC_BIT 0
#define CVF_CONTINUE_EXEC (1 << CVF_CONTINUE_EXEC_BIT)
/*MACROS*/
VMM_Service (Enable_Touch_1st_Meg) // Debugging only
VMM_Service (Disable_Touch_1st_Meg) // Debugging only
VMM_Service (Install_Exception_Handler)
VMM_Service (Remove_Exception_Handler)
VMM_Service (Get_Crit_Status_No_Block)
/*ENDMACROS*/
/* ASM
; Check if VMM service table has changed above this service
.errnz @@Get_Crit_Status_No_Block - 100F1h
*/
#ifdef WIN40SERVICES
/*************************************************************************
*************************************************************************
*
* END OF 3.10 SERVICE TABLE MUST NOT SHUFFLE SERVICES BEFORE THIS POINT
* FOR COMPATIBILITY.
*************************************************************************
*************************************************************************/
/*MACROS*/
VMM_Service (_GetLastUpdatedThreadExecTime)
VMM_Service (_Trace_Out_Service)
VMM_Service (_Debug_Out_Service)
VMM_Service (_Debug_Flags_Service)
/*ENDMACROS*/
#endif /* WIN40SERVICES */
/*
* Flags for _Debug_Flags_Service service.
*
* Don't change these unless you really really know what you're doing.
* We need to define these even if we are in WIN31COMPAT mode.
*/
#define DFS_LOG_BIT 0
#define DFS_LOG (1 << DFS_LOG_BIT)
#define DFS_PROFILE_BIT 1
#define DFS_PROFILE (1 << DFS_PROFILE_BIT)
#define DFS_TEST_CLD_BIT 2
#define DFS_TEST_CLD (1 << DFS_TEST_CLD_BIT)
#define DFS_NEVER_REENTER_BIT 3
#define DFS_NEVER_REENTER (1 << DFS_NEVER_REENTER_BIT)
#define DFS_TEST_REENTER_BIT 4
#define DFS_TEST_REENTER (1 << DFS_TEST_REENTER_BIT)
#define DFS_NOT_SWAPPING_BIT 5
#define DFS_NOT_SWAPPING (1 << DFS_NOT_SWAPPING_BIT)
#define DFS_TEST_BLOCK_BIT 6
#define DFS_TEST_BLOCK (1 << DFS_TEST_BLOCK_BIT)
#define DFS_RARE_SERVICES 0xFFFFFF80
#define DFS_EXIT_NOBLOCK (DFS_RARE_SERVICES+0)
#define DFS_ENTER_NOBLOCK (DFS_RARE_SERVICES+DFS_TEST_BLOCK)
#define DFS_TEST_NEST_EXEC (DFS_RARE_SERVICES+1)
#define DFS_WIMP_DEBUG (DFS_RARE_SERVICES+2)
#ifdef WIN40SERVICES
/*MACROS*/
VMM_Service (VMMAddImportModuleName)
VMM_Service (VMM_Add_DDB)
VMM_Service (VMM_Remove_DDB)
VMM_Service (Test_VM_Ints_Enabled)
VMM_Service (_BlockOnID)
VMM_Service (Schedule_Thread_Event)
VMM_Service (Cancel_Thread_Event)
VMM_Service (Set_Thread_Time_Out)
VMM_Service (Set_Async_Time_Out)
VMM_Service (_AllocateThreadDataSlot)
VMM_Service (_FreeThreadDataSlot)
/*ENDMACROS*/
/*
* Flag equates for _CreateMutex
*/
#define MUTEX_MUST_COMPLETE 1L
#define MUTEX_NO_CLEANUP_THREAD_STATE 2L
/*MACROS*/
VMM_Service (_CreateMutex)
VMM_Service (_DestroyMutex)
VMM_Service (_GetMutexOwner)
VMM_Service (Call_When_Thread_Switched)
VMM_Service (VMMCreateThread)
VMM_Service (_GetThreadExecTime)
VMM_Service (VMMTerminateThread)
VMM_Service (Get_Cur_Thread_Handle)
VMM_Service (Test_Cur_Thread_Handle)
VMM_Service (Get_Sys_Thread_Handle)
VMM_Service (Test_Sys_Thread_Handle)
VMM_Service (Validate_Thread_Handle)
VMM_Service (Get_Initial_Thread_Handle)
VMM_Service (Test_Initial_Thread_Handle)
VMM_Service (Debug_Test_Valid_Thread_Handle)
VMM_Service (Debug_Test_Cur_Thread)
VMM_Service (VMM_GetSystemInitState)
VMM_Service (Cancel_Call_When_Thread_Switched)
VMM_Service (Get_Next_Thread_Handle)
VMM_Service (Adjust_Thread_Exec_Priority)
VMM_Service (_Deallocate_Device_CB_Area)
VMM_Service (Remove_IO_Handler)
VMM_Service (Remove_Mult_IO_Handlers)
VMM_Service (Unhook_V86_Int_Chain)
VMM_Service (Unhook_V86_Fault)
VMM_Service (Unhook_PM_Fault)
VMM_Service (Unhook_VMM_Fault)
VMM_Service (Unhook_Device_Service)
VMM_Service (_PageReserve)
VMM_Service (_PageCommit)
VMM_Service (_PageDecommit)
VMM_Service (_PagerRegister)
VMM_Service (_PagerQuery)
VMM_Service (_PagerDeregister)
VMM_Service (_ContextCreate)
VMM_Service (_ContextDestroy)
VMM_Service (_PageAttach)
VMM_Service (_PageFlush)
VMM_Service (_SignalID)
VMM_Service (_PageCommitPhys)
VMM_Service (_Register_Win32_Services)
VMM_Service (Cancel_Call_When_Not_Critical)
VMM_Service (Cancel_Call_When_Idle)
VMM_Service (Cancel_Call_When_Task_Switched)
VMM_Service (_Debug_Printf_Service)
VMM_Service (_EnterMutex)
VMM_Service (_LeaveMutex)
VMM_Service (Simulate_VM_IO)
VMM_Service (Signal_Semaphore_No_Switch)
VMM_Service (_ContextSwitch)
VMM_Service (_PageModifyPermissions)
VMM_Service (_PageQuery)
VMM_Service (_EnterMustComplete)
VMM_Service (_LeaveMustComplete)
VMM_Service (_ResumeExecMustComplete)
/*ENDMACROS*/
/*
* Flag equates for _GetThreadTerminationStatus
*/
#define THREAD_TERM_STATUS_CRASH_PEND 1L
#define THREAD_TERM_STATUS_NUKE_PEND 2L
#define THREAD_TERM_STATUS_SUSPEND_PEND 4L
/*MACROS*/
VMM_Service (_GetThreadTerminationStatus)
VMM_Service (_GetInstanceInfo)
/*ENDMACROS*/
/*
* Return values for _GetInstanceInfo
*/
#define INSTINFO_NONE 0 /* no data instanced in range */
#define INSTINFO_SOME 1 /* some data instanced in range */
#define INSTINFO_ALL 2 /* all data instanced in range */
/*MACROS*/
VMM_Service (_ExecIntMustComplete)
VMM_Service (_ExecVxDIntMustComplete)
VMM_Service (Begin_V86_Serialization)
VMM_Service (Unhook_V86_Page)
VMM_Service (VMM_GetVxDLocationList)
VMM_Service (VMM_GetDDBList)
VMM_Service (Unhook_NMI_Event)
VMM_Service (Get_Instanced_V86_Int_Vector)
VMM_Service (Get_Set_Real_DOS_PSP)
/*ENDMACROS*/
#define GSRDP_Set 0x0001
/*MACROS*/
VMM_Service (Call_Priority_Thread_Event)
VMM_Service (Get_System_Time_Address)
VMM_Service (Get_Crit_Status_Thread)
VMM_Service (Get_DDB)
VMM_Service (Directed_Sys_Control)
/*ENDMACROS*/
// Registry APIs for VxDs
/*MACROS*/
VMM_Service (_RegOpenKey)
VMM_Service (_RegCloseKey)
VMM_Service (_RegCreateKey)
VMM_Service (_RegDeleteKey)
VMM_Service (_RegEnumKey)
VMM_Service (_RegQueryValue)
VMM_Service (_RegSetValue)
VMM_Service (_RegDeleteValue)
VMM_Service (_RegEnumValue)
VMM_Service (_RegQueryValueEx)
VMM_Service (_RegSetValueEx)
/*ENDMACROS*/
#ifndef REG_SZ // define only if not there already
#define REG_SZ 0x0001
#define REG_BINARY 0x0003
#endif
#ifndef HKEY_LOCAL_MACHINE // define only if not there already
#define HKEY_CLASSES_ROOT 0x80000000
#define HKEY_CURRENT_USER 0x80000001
#define HKEY_LOCAL_MACHINE 0x80000002
#define HKEY_USERS 0x80000003
#define HKEY_PERFORMANCE_DATA 0x80000004
#define HKEY_CURRENT_CONFIG 0x80000005
#define HKEY_DYN_DATA 0x80000006
#endif
/*MACROS*/
VMM_Service (_CallRing3)
VMM_Service (Exec_PM_Int)
VMM_Service (_RegFlushKey)
VMM_Service (_PageCommitContig)
VMM_Service (_GetCurrentContext)
VMM_Service (_LocalizeSprintf)
VMM_Service (_LocalizeStackSprintf)
VMM_Service (Call_Restricted_Event)
VMM_Service (Cancel_Restricted_Event)
VMM_Service (Register_PEF_Provider, VMM_ICODE)
VMM_Service (_GetPhysPageInfo)
VMM_Service (_RegQueryInfoKey)
VMM_Service (MemArb_Reserve_Pages)
/*ENDMACROS*/
/*
* Return values for _GetPhysPageInfo
*/
#define PHYSINFO_NONE 0 /* no pages in the specified range exist */
#define PHYSINFO_SOME 1 /* some pages in the specified range exist */
#define PHYSINFO_ALL 2 /* all pages in the specified range exist */
// New timeslicer services
/*MACROS*/
VMM_Service (Time_Slice_Sys_VM_Idle)
VMM_Service (Time_Slice_Sleep)
VMM_Service (Boost_With_Decay)
VMM_Service (Set_Inversion_Pri)
VMM_Service (Reset_Inversion_Pri)
VMM_Service (Release_Inversion_Pri)
VMM_Service (Get_Thread_Win32_Pri)
VMM_Service (Set_Thread_Win32_Pri)
VMM_Service (Set_Thread_Static_Boost)
VMM_Service (Set_VM_Static_Boost)
VMM_Service (Release_Inversion_Pri_ID)
VMM_Service (Attach_Thread_To_Group)
VMM_Service (Detach_Thread_From_Group)
VMM_Service (Set_Group_Static_Boost)
VMM_Service (_GetRegistryPath, VMM_ICODE)
VMM_Service (_GetRegistryKey)
/*ENDMACROS*/
// TYPE definitions for _GetRegistryKey
#define REGTYPE_ENUM 0
#define REGTYPE_CLASS 1
#define REGTYPE_VXD 2
// Flag definitions for _GetRegistryKey
#define REGKEY_OPEN 0
#define REGKEY_CREATE_IFNOTEXIST 1
// Flag definitions for _Assert_Range
#define ASSERT_RANGE_NULL_BAD 0x00000000
#define ASSERT_RANGE_NULL_OK 0x00000001
#define ASSERT_RANGE_IS_ASCIIZ 0x00000002
#define ASSERT_RANGE_IS_NOT_ASCIIZ 0x00000000
#define ASSERT_RANGE_NO_DEBUG 0x80000000
#define ASSERT_RANGE_BITS 0x80000003
/*MACROS*/
VMM_Service (Cleanup_Thread_State)
VMM_Service (_RegRemapPreDefKey)
VMM_Service (End_V86_Serialization)
VMM_Service (_Assert_Range)
VMM_Service (_Sprintf)
VMM_Service (_PageChangePager)
VMM_Service (_RegCreateDynKey)
VMM_Service (_RegQueryMultipleValues)
// Additional timeslicer services
VMM_Service (Boost_Thread_With_VM)
/*ENDMACROS*/
// Flag definitions for Get_Boot_Flags
#define BOOT_CLEAN 0x00000001
#define BOOT_DOSCLEAN 0x00000002
#define BOOT_NETCLEAN 0x00000004
#define BOOT_INTERACTIVE 0x00000008
/*MACROS*/
VMM_Service (Get_Boot_Flags)
VMM_Service (Set_Boot_Flags)
// String and memory services
VMM_Service (_lstrcpyn)
VMM_Service (_lstrlen)
VMM_Service (_lmemcpy)
VMM_Service (_GetVxDName)
// For vwin32 use only
VMM_Service (Force_Mutexes_Free)
VMM_Service (Restore_Forced_Mutexes)
/*ENDMACROS*/
// Reclaimable low memory services
/*MACROS*/
VMM_Service (_AddReclaimableItem)
VMM_Service (_SetReclaimableItem)
VMM_Service (_EnumReclaimableItem)
/*ENDMACROS*/
// completely wake sys VM from idle state
/*MACROS*/
VMM_Service (Time_Slice_Wake_Sys_VM)
VMM_Service (VMM_Replace_Global_Environment)
VMM_Service (Begin_Non_Serial_Nest_V86_Exec)
VMM_Service (Get_Nest_Exec_Status)
/*ENDMACROS*/
// Bootlogging services
/*MACROS*/
VMM_Service (Open_Boot_Log)
VMM_Service (Write_Boot_Log)
VMM_Service (Close_Boot_Log)
VMM_Service (EnableDisable_Boot_Log)
VMM_Service (_Call_On_My_Stack)
/*ENDMACROS*/
// Another instance data service
/*MACROS*/
VMM_Service (Get_Inst_V86_Int_Vec_Base)
/*ENDMACROS*/
// Case insensitive functions -- SEE WARNINGS IN DOCS BEFORE USING!
/*MACROS*/
VMM_Service (_lstrcmpi)
VMM_Service (_strupr)
/*ENDMACROS*/
/*MACROS*/
VMM_Service (Log_Fault_Call_Out)
VMM_Service (_AtEventTime)
/*ENDMACROS*/
#endif /* WIN40SERVICES */
#ifdef WIN403SERVICES
//
// 4.03 Services
//
/*MACROS*/
VMM_Service (_PageOutPages)
/*ENDMACROS*/
// Flag definitions for _PageOutPages
#define PAGEOUT_PRIVATE 0x00000001
#define PAGEOUT_SHARED 0x00000002
#define PAGEOUT_SYSTEM 0x00000004
#define PAGEOUT_REGION 0x00000008
#define PAGEOUT_ALL (PAGEOUT_PRIVATE | PAGEOUT_SHARED | PAGEOUT_SYSTEM)
/*MACROS*/
VMM_Service (_Call_On_My_Not_Flat_Stack)
VMM_Service (_LinRegionLock)
VMM_Service (_LinRegionUnLock)
VMM_Service (_AttemptingSomethingDangerous)
VMM_Service (_Vsprintf)
VMM_Service (_Vsprintfw)
VMM_Service (Load_FS_Service)
VMM_Service (Assert_FS_Service)
VMM_StdCall_Service (ObsoleteRtlUnwind, 4)
VMM_StdCall_Service (ObsoleteRtlRaiseException, 1)
VMM_StdCall_Service (ObsoleteRtlRaiseStatus, 1)
VMM_StdCall_Service (ObsoleteKeGetCurrentIrql, 0)
VMM_FastCall_Service (ObsoleteKfRaiseIrql, 1)
VMM_FastCall_Service (ObsoleteKfLowerIrql, 1)
VMM_Service (_Begin_Preemptable_Code)
VMM_Service (_End_Preemptable_Code)
VMM_FastCall_Service (Set_Preemptable_Count, 1)
VMM_StdCall_Service (ObsoleteKeInitializeDpc, 3)
VMM_StdCall_Service (ObsoleteKeInsertQueueDpc, 3)
VMM_StdCall_Service (ObsoleteKeRemoveQueueDpc, 1)
VMM_StdCall_Service (HeapAllocateEx, 4)
VMM_StdCall_Service (HeapReAllocateEx, 5)
VMM_StdCall_Service (HeapGetSizeEx, 2)
VMM_StdCall_Service (HeapFreeEx, 2)
VMM_Service (_Get_CPUID_Flags)
VMM_StdCall_Service (KeCheckDivideByZeroTrap, 1)
/*ENDMACROS*/
#define GCIF_FPU_BIT 0
#define GCIF_FPU (1 << GCIF_FPU_BIT)
#define GCIF_VME_BIT 1
#define GCIF_VME (1 << GCIF_VME_BIT)
#define GCIF_DE_BIT 2
#define GCIF_DE (1 << GCIF_DE_BIT)
#define GCIF_PSE_BIT 3
#define GCIF_PSE (1 << GCIF_PSE_BIT)
#define GCIF_TSC_BIT 4
#define GCIF_TSC (1 << GCIF_TSC_BIT)
#define GCIF_MSR_BIT 5
#define GCIF_MSR (1 << GCIF_MSR_BIT)
#define GCIF_PAE_BIT 6
#define GCIF_PAE (1 << GCIF_PAE_BIT)
#define GCIF_MCE_BIT 7
#define GCIF_MCE (1 << GCIF_MCE_BIT)
#define GCIF_CXS_BIT 8
#define GCIF_CXS (1 << GCIF_CXS_BIT)
#define GCIF_APIC_BIT 9
#define GCIF_APIC (1 << GCIF_APIC_BIT)
//
// Bit 10 and 11 are apparently Intel reserved
//
#define GCIF_MTTR_BIT 12
#define GCIF_MTTR (1 << GCIF_MTTR_BIT)
#define GCIF_PGE_BIT 13
#define GCIF_PGE (1 << GCIF_PGE_BIT)
#define GCIF_MCA_BIT 14
#define GCIF_MCA (1 << GCIF_MCA_BIT)
#define GCIF_CMOV_BIT 15
#define GCIF_CMOV (1 << GCIF_CMOV_BIT)
#endif /* WIN403SERVICES */
#ifdef WIN41SERVICES
/*MACROS*/
VMM_Service (_RegisterGARTHandler)
VMM_Service (_GARTReserve)
VMM_Service (_GARTCommit)
VMM_Service (_GARTUnCommit)
VMM_Service (_GARTFree)
VMM_Service (_GARTMemAttributes)
VMM_StdCall_Service (KfRaiseIrqlToDpcLevel, 0)
VMM_Service (VMMCreateThreadEx)
VMM_Service (_FlushCaches)
/*ENDMACROS*/
/*
* Flags for the VMM GART services.
* WARNING: THESE FLAGS SHOULD HAVE SAME VALUE AS THE VMM FLAGS DEFINED IN PCI.H
* IF YOU CHANGE THE VALUE AT EITHER PLACE, YOU NEED TO UPDATE THE OTHER.
*/
#define PG_UNCACHED 0x00000001 // Uncached memory
#define PG_WRITECOMBINED 0x00000002 // Write combined memory
/*
* Flags for the FlushCaches service.
*/
#define FLUSHCACHES_NORMAL 0x00000000
#define FLUSHCACHES_GET_CACHE_LINE_PTR 0x00000001
#define FLUSHCACHES_GET_CACHE_SIZE_PTR 0x00000002
#define FLUSHCACHES_TAKE_OVER 0x00000003
#define FLUSHCACHES_FORCE_PAGES_OUT 0x00000004
#define FLUSHCACHES_LOCK_LOCKABLE 0x00000005
#define FLUSHCACHES_UNLOCK_LOCKABLE 0x00000006
#define FLUSHCACHES_CRASH_DUMP 0x00000007 // VMM 4.90
#define FLUSHCACHES_PREPARE_S2_OR_S3 0x00000008 // VMM 4.90
//
// The following four are for VPOWERD only. All services return 0 on success,
// -1 on failure.
//
// PREPARE_FOR_HIBERNATE is called in between the pageable and locked suspend
// phases during a S4 sleep state. It allocates about half of memory and do
// other pageable things to prepare for hibernate. If someone else fails the
// hibernation UNPREPARE_FOR_HIBERNATE should be called to free the stuff.
//
// BUILD_HIBNERNATE_FILE is called after the locked phase (ie with inetrrupts
// disabled. The code builds an hibernation file into the other half of
// memory. This service cannot fail since all allocation have already been
// done. This service return twice: 0 when we properly completed this phase.
// and -1 when we are resuming.
//
// Once the hibernate file is done, the machine actually does the resume
// locked phase of suspend, to get the paging/boot device going. Then
// WRITE_HIBERNATE_FILE is called to actually write the file. If that succeed,
// VPOWERD will enter S5. If it fails, the file will get deleted.
//
// UNPREPARE_FOR_HIBERNATE should be called on the resume path.
//
#define FLUSHCACHES_PREPARE_FOR_HIBERNATE 0x00000009 // VMM 4.90
#define FLUSHCACHES_BUILD_HIBERNATE_FILE 0x0000000A // VMM 4.90
#define FLUSHCACHES_WRITE_HIBERNATE_FILE 0x0000000B // VMM 4.90
#define FLUSHCACHES_UNPREPARE_FOR_HIBERNATE 0x0000000C // VMM 4.90
//
// This is for any dirver that needs to get a pointer to the ACPI tables.
//
#define FLUSHCACHES_GET_ACPI_TABLES 0x0000000D // VMM 4.90
//
// PREALLOC for hibernate should be only called by VPOWERD. It is called
// very only on the suspend process, if done for hibernate
//
#define FLUSHCACHES_PREALLOC_HIBERNATE_FILE 0x0000000E // VMM 4.90
// Free hibernate block should only be called by VPOWERD. It is called
// upon returning from hibernation just after leaving the ints off phase.
#define FLUSHCACHES_FREE_HIBERNATE_BLOCK 0x0000000F // VMM 4.90
/*MACROS*/
VMM_Service (Set_Thread_Win32_Pri_NoYield)
VMM_Service (_FlushMappedCacheBlock)
VMM_Service (_ReleaseMappedCacheBlock)
VMM_Service (Run_Preemptable_Events)
VMM_Service (_MMPreSystemExit)
VMM_Service (_MMPageFileShutDown)
VMM_Service (_Set_Global_Time_Out_Ex)
VMM_Service (Query_Thread_Priority)
/*ENDMACROS*/
#endif /* WIN41SERVICES */
#ifdef WIN49SERVICES
/*MACROS*/
//
// In order to properly undo a _MapPhysToLinear, you must have pass the
// MPL_Undoable flag and you must pass the linear address you got back
// as well as the size.
//
VMM_Service (_UnmapPhysToLinear)
VMM_Service (_VmmRtInfo)
// IMPORTANT NOTE: Since the following MP services are commented out for now,
// if you are adding any services to VMM, add them above this comment,
// BEFORE the MP services.
/*ENDMACROS*/
#ifdef MULTI_PROC_SUPPORT
/*MACROS*/
//
// Warning: MP initializes at VMM's device init. Do not call before device
// init.
//
VMM_Service (_MPGetProcessorCount)
VMM_Service (_MPEnterSingleProcessor)
VMM_Service (_MPLeaveSingleProcessor)
/*ENDMACROS*/
#endif
/*MACROS*/
/*ENDMACROS*/
#endif /* WIN49SERVICES */
/*MACROS*/
End_Service_Table(VMM, VMM)
/*ENDMACROS*/
/*XLATOFF*/
#pragma warning (default:4003) // turn on not enough params warning
#ifndef try
#define try __try
#define except __except
#define finally __finally
#define leave __leave
#ifndef exception_code
#define exception_code __exception_code
#endif
#endif
#ifndef EXCEPTION_EXECUTE_HANDLER
#define EXCEPTION_EXECUTE_HANDLER 1
#define EXCEPTION_CONTINUE_SEARCH 0
#define EXCEPTION_CONTINUE_EXECUTION -1
#endif
/*XLATON*/
#define COMNFS_FLAT 0xFFFFFFFF
// Flag definitions for _Add/_Set/_EnumReclaimableItem
#define RS_RECLAIM 0x00000001
#define RS_RESTORE 0x00000002
#define RS_DOSARENA 0x00000004
// Structure definition for _EnumReclaimableItem
struct ReclaimStruc {
ULONG RS_Linear; // low (< 1meg) address of item
ULONG RS_Bytes; // size of item in bytes
ULONG RS_CallBack; // callback, if any (zero if none)
ULONG RS_RefData; // reference data for callback, if any
ULONG RS_HookTable; // real-mode hook table (zero if none)
ULONG RS_Flags; // 0 or more of the RS_* equates
};
typedef struct ReclaimStruc *PReclaimStruc;
//
// Structures for Force_Mutexes_Free/Restore_Forced_Mutexes
//
typedef struct frmtx {
struct frmtx *frmtx_pfrmtxNext;
DWORD frmtx_hmutex;
DWORD frmtx_cEnterCount;
DWORD frmtx_pthcbOwner;
DWORD frmtx_htimeout;
} FRMTX;
typedef struct vmmfrinfo {
struct frmtx vmmfrinfo_frmtxDOS;
struct frmtx vmmfrinfo_frmtxV86;
struct frmtx vmmfrinfo_frmtxOther;
} VMMFRINFO;
/*
* Data structure for _GetDemandPageInfo
*/
typedef struct DemandInfoStruc {
ULONG DILin_Total_Count; /* # pages in linear address space */
ULONG DIPhys_Count; /* Count of phys pages */
ULONG DIFree_Count; /* Count of free phys pages */
ULONG DIUnlock_Count; /* Count of unlocked Phys Pages */
ULONG DILinear_Base_Addr; /* Base of pageable address space */
ULONG DILin_Total_Free; /* Total Count of free linear pages */
/*
* The following 5 fields are all running totals, kept from the time
* the system was started
*/
ULONG DIPage_Faults; /* total page faults */
ULONG DIPage_Ins; /* calls to pagers to page in a page */
ULONG DIPage_Outs; /* calls to pagers to page out a page*/
ULONG DIPage_Discards; /* pages discarded w/o calling pager */
ULONG DIInstance_Faults; /* instance page faults */
ULONG DIPagingFileMax; /* maximum # of pages that could be in paging file */
ULONG DIPagingFileInUse; /* # of pages of paging file currently in use */
ULONG DICommit_Count; /* Total committed memory, in pages */
ULONG DIReserved[2]; /* Reserved for expansion */
} DEMANDINFOSTRUC;
/*
* Data structure for _AddInstanceItem
*/
struct InstDataStruc {
ULONG InstLinkF; /* INIT <0> RESERVED */
ULONG InstLinkB; /* INIT <0> RESERVED */
ULONG InstLinAddr; /* Linear address of start of block */
ULONG InstSize; /* Size of block in bytes */
ULONG InstType; /* Type of block */
};
/*
* Values for InstType
*/
#define INDOS_FIELD 0x100 /* Bit indicating INDOS switch requirements */
#define ALWAYS_FIELD 0x200 /* Bit indicating ALWAYS switch requirements */
#define OPTIONAL_FIELD 0x400 /* Bit indicating optional instancing requirements */
/*
* Data structure for Hook_Invalid_Page_Fault handlers.
*
* This is the structure of the "invalid page fault information"
* which is pointed to by EDI when Invalid page fault hookers
* are called.
*
* Page faults can occur on a VM which is not current by touching the VM at
* its high linear address. In this case, IPF_FaultingVM may not be the
* current VM, it will be set to the VM whos high linear address was touched.
*/
struct IPF_Data {
ULONG IPF_LinAddr; /* CR2 address of fault */
ULONG IPF_MapPageNum; /* Possible converted page # of fault */
ULONG IPF_PTEEntry; /* Contents of PTE that faulted */
ULONG IPF_FaultingVM; /* May not = Current VM (IPF_V86PgH set) */
ULONG IPF_Flags; /* Flags */
};
/*
*
* Install_Exception_Handler data structure
*
*/
struct Exception_Handler_Struc {
ULONG EH_Reserved;
ULONG EH_Start_EIP;
ULONG EH_End_EIP;
ULONG EH_Handler;
};
/*
* Flags passed in new memory manager functions
*/
/* PageReserve arena values */
#define PR_PRIVATE 0x80000400 /* anywhere in private arena */
#define PR_SHARED 0x80060000 /* anywhere in shared arena */
#define PR_SYSTEM 0x80080000 /* anywhere in system arena */
/* PageReserve flags */
#define PR_FIXED 0x00000008 /* don't move during PageReAllocate */
#define PR_4MEG 0x00000001 /* allocate on 4mb boundary */
#define PR_STATIC 0x00000010 /* see PageReserve documentation */
/* PageCommit default pager handle values */
#define PD_ZEROINIT 0x00000001 /* swappable zero-initialized pages */
#define PD_NOINIT 0x00000002 /* swappable uninitialized pages */
#define PD_FIXEDZERO 0x00000003 /* fixed zero-initialized pages */
#define PD_FIXED 0x00000004 /* fixed uninitialized pages */
/* PageCommit flags */
#define PC_FIXED 0x00000008 /* pages are permanently locked */
#define PC_LOCKED 0x00000080 /* pages are made present and locked*/
#define PC_LOCKEDIFDP 0x00000100 /* pages are locked if swap via DOS */
#define PC_WRITEABLE 0x00020000 /* make the pages writeable */
#define PC_USER 0x00040000 /* make the pages ring 3 accessible */
#define PC_INCR 0x40000000 /* increment "pagerdata" each page */
#define PC_PRESENT 0x80000000 /* make pages initially present */
#define PC_STATIC 0x20000000 /* allow commit in PR_STATIC object */
#define PC_DIRTY 0x08000000 /* make pages initially dirty */
#define PC_CACHEDIS 0x00100000 /* Allocate uncached pages - new for WDM */
#define PC_CACHEWT 0x00080000 /* Allocate write through cache pages - new for WDM */
#define PC_PAGEFLUSH 0x00008000 /* Touch device mapped pages on alloc - new for WDM */
#ifdef WRITE_WATCH
#define PC_WRITE_WATCH 0x00200000 /* to request write_watch in this region */
#endif // WRITE_WATCH
/* PageCommitContig additional flags */
#define PCC_ZEROINIT 0x00000001 /* zero-initialize new pages */
#define PCC_NOLIN 0x10000000 /* don't map to any linear address */
/*MTRR type flags */
#define MTRR_UC 0
#define MTRR_WC 1
#define MTRR_WT 4
#define MTRR_WP 5
#define MTRR_WB 6
/*
* Structure and flags for PageQuery
*/
#ifndef _WINNT_
typedef struct _MEMORY_BASIC_INFORMATION {
ULONG mbi_BaseAddress;
ULONG mbi_AllocationBase;
ULONG mbi_AllocationProtect;
ULONG mbi_RegionSize;
ULONG mbi_State;
ULONG mbi_Protect;
ULONG mbi_Type;
} MEMORY_BASIC_INFORMATION, *PMEMORY_BASIC_INFORMATION;
#define PAGE_NOACCESS 0x01
#define PAGE_READONLY 0x02
#define PAGE_READWRITE 0x04
#define MEM_COMMIT 0x1000
#define MEM_RESERVE 0x2000
#define MEM_FREE 0x10000
#define MEM_PRIVATE 0x20000
#endif
/***ET+ PD - Pager Descriptor
*
* A PD describes a set of routines to call to bring a page into
* the system or to get it out. Each committed page in the system
* has an associated PD, a handle to which is stored in the page's
* VP.
*
* For any field that is 0, the pager will not be notified
* when that action takes place.
*
* For the purpose of pagers, a page can be in one of the two states
* describing its current contents:
*
* clean - page has not been written to since its last page out
* dirty - page has been written to since its last page out
*
* A page also is in one of two persistent states:
*
* virgin - page has never been written to since it was committed
* tainted - page has been written to since it was committed
*
* Note that a tainted page may be either dirty or clean, but a
* virgin page is by definition clean.
*
* Examples of PDs:
*
* For 32-bit EXE code or read-only data:
*
* pd_virginin = routine to load page from an exe file
* pd_taintedin = 0
* pd_cleanout = 0
* pd_dirtyout = 0
* pd_virginfree = 0
* pd_taintedfree = 0
* pd_dirty = 0
* pd_type = PD_PAGERONLY
*
* For 32-bit EXE writeable data:
*
* pd_virginin = routine to load page from an exe file
* pd_taintedin = routine to load page from swap file
* pd_cleanout = 0
* pd_dirtyout = routine to write a page out to the swap file
* pd_virginfree = 0
* pd_taintedfree = routine to free page from the swap file
* pd_dirty = routine to free page from the swap file
* pd_type = PD_SWAPPER
*
* For zero-initialized swappable data:
*
* pd_virginin = routine to zero-fill a page
* pd_taintedin = routine to load page from swap file
* pd_cleanout = 0
* pd_dirtyout = routine to write a page out to the swap file
* pd_virginfree = 0
* pd_taintedfree = routine to free page from the swap file
* pd_dirty = routine to free page from the swap file
* pd_type = PD_SWAPPER
*/
/* typedefs for various pager functions */
typedef ULONG _cdecl FUNPAGE(PULONG ppagerdata, PVOID ppage, ULONG faultpage);
typedef FUNPAGE * PFUNPAGE;
struct pd_s {
/*
* The following four fields are entry points in the pager which
* we call to page in or page out a page. The following parameters
* are passed to the pager during these calls:
*
* ppagerdata - pointer to the pager-specific dword of data
* stored with the virtual page. The pager is
* free to modify the contents of this dword
* DURING the page in or out, but not afterwards.
*
* ppage - pointer to page going in or out (a ring 0 alias
* to the physical page). The pager should use this
* address to access the contents of the page.
*
* faultpage - faulting linear page number for page-ins, -1 for
* page-outs. This address should not be accessed
* by the pager. It is provided for information
* only. Note that a single page can be mapped at
* more than one linear address because of the
* MapIntoV86 and LinMapIntoV86 services.
*
* The pager should return non-0 if the page was successfully
* paged, or 0 if it failed.
*/
PFUNPAGE pd_virginin; /* in - while page has never been written to */
PFUNPAGE pd_taintedin; /* in - page written to at least once */
PFUNPAGE pd_cleanout; /* out - page not written to since last out */
PFUNPAGE pd_dirtyout; /* out - page was written to since last out */
/*
* The pd_*free routines are used to inform the pager when the last
* reference to a virtual page controlled by the pager is
* decommitted. A common use of this notification is to
* free space in a backing file, or write the page contents
* into the backing file.
*
* These calls take the same parameters as the page-out and -in
* functions, but no return value is recognized. The "ppage"
* and "faultpage" parameters will always be 0.
*/
PFUNPAGE pd_virginfree; /* decommit of never-written-to page */
PFUNPAGE pd_taintedfree; /* decommit of page written to at least once*/
/*
* The pd_dirty routine is used to inform the pager when the
* memory manager detects that a page has been written to. The memory
* manager does not detect the write at the instant it occurs, so
* the pager should not depend upon prompt notification. A common
* use of this notification might be to invalidate cached data.
* If the page was dirtied in more than one memory context,
* the pager's pd_dirty routine will be called once for each
* context.
*
* These calls take the same parameters as the page-out and -in
* functions except that the "ppage" parameter isn't valid and
* no return value is recognized.
*/
PFUNPAGE pd_dirty;
/*
* The pd_type field gives the sytem information about the
* overcommit characteristics of pages controlled by this pager.
* The following are allowable values for the field:
*
* PD_SWAPPER - under some conditions, pages of this type
* may be paged out into the swap file
* PD_PAGERONLY - pages controlled by this pager will never
* be paged out to the swap file
*
* In addition, the following value may be or'ed in to the pd_type field:
*
* PD_NESTEXEC - must be specified if either the pd_cleanout or pd_dirtyout
* functions perform nested excecution or block using the
* BLOCK_SVC_INTS flag. To be safe, this flag should always be
* specified if the pager does any sort of file i/o to anything
* other than the default paging file.
*/
ULONG pd_type;
};
typedef struct pd_s PD;
typedef PD * PPD;
/* values for pd_type */
#define PD_SWAPPER 0 /* pages need direct accounting in swap file */
#define PD_PAGERONLY 1 /* pages will never be swapped */
#define PD_NESTEXEC 2 /* page out funtion uses nested execution */
#endif // Not_VxD
/*
* The size of a page of memory
*/
#define PAGESHIFT 12
#define PAGESIZE (1 << PAGESHIFT)
#define PAGEMASK (PAGESIZE - 1)
/* XLATOFF */
#ifndef PAGE
#define PAGE(p) ((DWORD)(p) >> PAGESHIFT)
#endif
/* XLATON */
#define NPAGES(cb) (((DWORD)(cb) + PAGEMASK) >> PAGESHIFT)
/*
* Address space (arena) boundaries
*/
#define MAXSYSTEMLADDR ((ULONG) 0xffbfffff) /* 4 gig - 4meg */
#define MINSYSTEMLADDR ((ULONG) 0xc0000000) /* 3 gig */
#ifdef WOW
#define MAXSHAREDLADDR ((ULONG) 0x7fffffff)
#define MINSHAREDLADDR ((ULONG) 0x40000000) /* 1 gig */
#define MAXPRIVATELADDR ((ULONG) 0x3fffffff)
#else
#define MAXSHAREDLADDR ((ULONG) 0xbfffffff)
#define MINSHAREDLADDR ((ULONG) 0x80000000) /* 2 gig */
#define MAXPRIVATELADDR ((ULONG) 0x7fffffff)
#endif
#define MINPRIVATELADDR ((ULONG) 0x00400000) /* 4 meg */
#define MAXDOSLADDR ((ULONG) 0x003fffff)
#define MINDOSLADDR ((ULONG) 0x00000000)
#define MAXSYSTEMPAGE (MAXSYSTEMLADDR >> PAGESHIFT)
#define MINSYSTEMPAGE (MINSYSTEMLADDR >> PAGESHIFT)
#define MAXSHAREDPAGE (MAXSHAREDLADDR >> PAGESHIFT)
#define MINSHAREDPAGE (MINSHAREDLADDR >> PAGESHIFT)
#define MAXPRIVATEPAGE (MAXPRIVATELADDR >> PAGESHIFT)
#define MINPRIVATEPAGE (MINPRIVATELADDR >> PAGESHIFT)
#define MAXDOSPAGE (MAXDOSLADDR >> PAGESHIFT)
#define MINDOSPAGE (MINDOSLADDR >> PAGESHIFT)
#define CBPRIVATE (1 + MAXPRIVATELADDR - MINPRIVATELADDR)
#define CBSHARED (1 + MAXSHAREDLADDR - MINSHAREDLADDR)
#define CBSYSTEM (1 + MAXSYSTEMLADDR - MINSYSTEMLADDR)
#define CBDOS (1 + MAXDOSLADDR - MINDOSLADDR)
#define CPGPRIVATE (1 + MAXPRIVATEPAGE - MINPRIVATEPAGE)
#define CPGSHARED (1 + MAXSHAREDPAGE - MINSHAREDPAGE)
#define CPGSYSTEM (1 + MAXSYSTEMPAGE - MINSYSTEMPAGE)
#define CPGDOS (1 + MAXDOSPAGE - MINDOSPAGE)
/*XLATOFF*/
/*
* Largest object that could theoretically be allocated
*/
#define CBMAXALLOC (max(CBSHARED,max(CBPRIVATE, CBSYSTEM)))
#define CPGMAXALLOC (max(CPGSHARED,max(CPGPRIVATE, CPGSYSTEM)))
/*XLATON*/
/* ASM
IFDEF DEBUG
DebFar EQU NEAR PTR
ELSE
DebFar EQU SHORT
ENDIF
*/
#define ASD_MAX_REF_DATA 256 // If bigger than this, a checksum is used
struct _vmmguid {
unsigned long Data1;
unsigned short Data2;
unsigned short Data3;
unsigned char Data4[8];
};
typedef struct _vmmguid VMMGUID;
typedef VMMGUID *VMMREFIID;
typedef DWORD ASD_RESULT;
#define ASD_ERROR_NONE 0x00000000
#define ASD_CHECK_FAIL 0x00000001 // The flag is set that this failed before
#define ASD_CHECK_SUCCESS 0x00000002 // The flag is set that this succeeded before
#define ASD_CHECK_UNKNOWN 0x00000003 // No flag is set
#define ASD_ERROR_BAD_TIME 0x00000004 // Under cli
#define ASD_REGISTRY_ERROR 0x00000005 // Unknown registry error
#define ASD_CLEAN_BOOT 0x00000006 // Clean booting fails everything
#define ASD_OUT_OF_MEMORY 0x00000007 // Ran out of memory (extremely rare)
#define ASD_FILE_ERROR 0x00000008 // Int 21 to flush the info file failed
#define ASD_ALREADY_SET 0x00000009 // ASD_CHECK* done twice on same vgOperation/pRefData
#define ASD_MISSING_CHECK 0x0000000A // ASD_DONE* on something not set
#define ASD_BAD_PARAMETER 0x0000000B // Invalid operation, refiid or ref pointer
#define ASD_OP_CHECK_AND_WRITE_FAIL_IF_UNKNOWN 0x00000000
#define ASD_OP_CHECK_AND_ALWAYS_WRITE_FAIL 0x00000001
#define ASD_OP_CHECK 0x00000002
#define ASD_OP_DONE_AND_SET_SUCCESS 0x00000003
#define ASD_OP_SET_FAIL 0x00000004
#define ASD_OP_SET_SUCCESS 0x00000005
#define ASD_OP_SET_UNKNOWN 0x00000006
#define ASD_OP_DONE 0x00000007
#define ASD_FLAG_STRING 0x00000001
#ifndef Not_VxD
/******************************************************************************
*
* EQUATES FOR SYSTEM_CONTROL CALLS
*
*****************************************************************************/
/*
* SYS_CRITICAL_INIT is a device init call. Devices that have a
* critical function that needs initializing before interrupts are
* enabled should do it at Sys_Critical_Init. Devices which REQUIRE a
* certain range of V86 pages to operate (such as the VDD video memory)
* should claim them at Sys_Critical_Init. SYS VM Simulate_Int,
* Exec_Int ACTIVITY IS NOT ALLOWED. Returning carry aborts device
* load only.
*/
#define SYS_CRITICAL_INIT 0x0000 /* Devices req'd for virt mode */
/*
* DEVICE_INIT is where most devices do the bulk of their initialization.
* SYS VM Simulate_Int, Exec_Int activity is allowed. Returning carry
* aborts device load only.
*/
#define DEVICE_INIT 0x0001 /* All other devices init */
/*
* INIT_COMPLETE is the final phase of device init called just before the
* WIN386 INIT pages are released and the Instance snapshot is taken.
* Devices which wish to search for a region of V86 pages >= A0h to use
* should do it at INIT_COMPLETE.
* SYS VM Simulate_Int, Exec_Int activity is allowed. Returning carry
* aborts device load only.
*/
#define INIT_COMPLETE 0x0002 /* All devices initialized */
/* --------------- INITIALIZATION CODE AND DATA DISCARDED ------------------ */
/*
* Same as VM_Init, except for SYS VM.
*/
#define SYS_VM_INIT 0x0003 /* Execute the system VM */
/*
* Same as VM_Terminate, except for SYS VM (Normal WIN386 exit ONLY, on a crash
* exit this call is not made). SYS VM Simulate_Int, Exec_Int activity is
* allowed. This and Sys_VM_Terminate2 are your last chances to access
* and/or lock pageable data.
*/
#define SYS_VM_TERMINATE 0x0004 /* System VM terminated */
/*
* System_Exit call is made when WIN386 is exiting either normally or via
* a crash. INTERRUPTS ARE ENABLED.
* SYS VM Simulate_Int, Exec_Int ACTIVITY IS NOT ALLOWED.
*/
#define SYSTEM_EXIT 0x0005 /* Devices prepare to exit */
/*
* SYS_CRITICAL_EXIT call is made when WIN386 is exiting either normally or via
* a crash. INTERRUPTS ARE DISABLED. SYS VM Simulate_Int, Exec_Int ACTIVITY
* IS NOT ALLOWED.
*/
#define SYS_CRITICAL_EXIT 0x0006 /* System critical devices reset */
/*
* Create_VM creates a new VM. EBX = VM handle of new VM. Returning
* Carry will fail the Create_VM.
*/
#define CREATE_VM 0x0007
/*
* Second phase of Create_VM. EBX = VM handle of new VM. Returning
* Carry will cause the VM to go Not_Executeable, then be destroyed.
* VM Simulate_Int, Exec_Int activity is NOT allowed.
*/
#define VM_CRITICAL_INIT 0x0008
/*
* Third phase of Create_VM. EBX = VM handle of new VM. Returning
* Carry will cause the VM to go Not_Executeable, then be destroyed.
* VM Simulate_Int, Exec_Int activity is allowed.
*/
#define VM_INIT 0x0009
/*
* NORMAL (First phase) of Destroy_VM. EBX = VM Hanlde. This occurs
* on normal termination of the VM. Call cannot be failed. VM
* Simulate_Int, Exec_Int activity is allowed.
*/
#define VM_TERMINATE 0x000A /* Still in VM -- About to die */
/*
* Second phase of Destroy_VM. EBX = VM Handle, EDX = Flags (see
* below). Note that in the case of destroying a running VM, this is
* the first call made (VM_Terminate call does not occur). Call cannot
* be failed. VM Simulate_Int, Exec_Int activity is NOT allowed.
*/
#define VM_NOT_EXECUTEABLE 0x000B /* Most devices die (except VDD) */
/*
* Final phase of Destroy_VM. EBX = VM Handle. Note that considerable
* time can elaps between the VM_Not_Executeable call and this call.
* Call cannot be failed. VM Simulate_Int, Exec_Int activity is NOT
* allowed.
*/
#define DESTROY_VM 0x000C /* VM's control block about to go */
/*
* Flags for VM_Not_Executeable control call (passed in EDX)
*/
#define VNE_CRASHED_BIT 0x00 /* VM was crashed */
#define VNE_CRASHED (1 << VNE_CRASHED_BIT)
#define VNE_NUKED_BIT 0x01 /* VM was destroyed while active */
#define VNE_NUKED (1 << VNE_NUKED_BIT)
#define VNE_CREATEFAIL_BIT 0x02 /* Some device failed Create_VM */
#define VNE_CREATEFAIL (1 << VNE_CREATEFAIL_BIT)
#define VNE_CRINITFAIL_BIT 0x03 /* Some device failed VM_Critical_Init */
#define VNE_CRINITFAIL (1 << VNE_CRINITFAIL_BIT)
#define VNE_INITFAIL_BIT 0x04 /* Some device failed VM_Init */
#define VNE_INITFAIL (1 << VNE_INITFAIL_BIT)
#define VNE_CLOSED_BIT 0x05
#define VNE_CLOSED (1 << VNE_CLOSED_BIT)
/*
* EBX = VM Handle. Call cannot be failed.
*/
#define VM_SUSPEND 0x000D /* VM not runnable until resume */
/*
* EBX = VM Handle. Returning carry fails and backs out the resume.
*/
#define VM_RESUME 0x000E /* VM is leaving suspended state */
/*
* EBX = VM Handle to set device focus to. EDX = Device ID if device
* specific setfocus, == 0 if device critical setfocus (all devices).
* THIS CALL CANNOT BE FAILED.
*
* NOTE: In case where EDX == 0, ESI is a FLAG word that indicates
* special functions. Currently Bit 0 being set indicates that this
* Device critical set focus is also "VM critical". It means that we
* do not want some other VM to take the focus from this app now. This
* is primarily used when doing a device critical set focus to Windows
* (the SYS VM) it is interpreted by the SHELL to mean "if an old app
* currently has the Windows activation, set the activation to the
* Windows Shell, not back to the old app". ALSO in the case where Bit
* 0 is set, EDI = The VM handle of the VM that is "having trouble".
* Set this to 0 if there is no specific VM associated with the
* problem.
*/
#define SET_DEVICE_FOCUS 0x000F
/*
* EBX = VM Handle going into message mode. THIS CALL CANNOT BE FAILED.
*/
#define BEGIN_MESSAGE_MODE 0x0010
/*
* EBX = VM Handle leaving message mode. THIS CALL CANNOT BE FAILED.
*/
#define END_MESSAGE_MODE 0x0011
/* ----------------------- SPECIAL CONTROL CALLS --------------------------- */
/*
* Request for reboot. Call cannot be failed.
*/
#define REBOOT_PROCESSOR 0x0012 /* Request a machine reboot */
/*
* Query_Destroy is an information call made by the SHELL device before
* an attempt is made to initiate a destroy VM sequence on a running VM
* which has not exited normally. EBX = VM Handle. Returning carry
* indicates that a device "has a problem" with allowing this. THE
* DESTROY SEQUENCE CANNOT BE ABORTED HOWEVER, this decision is up to
* the user. All this does is indicate that there is a "problem" with
* allowing the destroy. The device which returns carry should call
* the SHELL_Message service to post an informational dialog about the
* reason for the problem.
*/
#define QUERY_DESTROY 0x0013 /* OK to destroy running VM? */
/* ----------------------- DEBUGGING CONTROL CALL -------------------------- */
/*
* Special call for device specific DEBUG information display and activity.
*/
#define DEBUG_QUERY 0x0014
/* -------- CALLS FOR BEGIN/END OF PROTECTED MODE VM EXECUTION ------------- */
/*
* About to run a protected mode application.
* EBX = Current VM handle.
* EDX = Flags
* EDI -> Application Control Block
* Returning with carry set fails the call.
*/
#define BEGIN_PM_APP 0x0015
/*
* Flags for Begin_PM_App (passed in EDX)
*/
#define BPA_32_BIT 0x01
#define BPA_32_BIT_FLAG 1
/*
* Protected mode application is terminating.
* EBX = Current VM handle. THIS CALL CAN NOT FAIL.
* EDI -> Application Control Block
*/
#define END_PM_APP 0x0016
/*
* Called whenever system is about to be rebooted. Allows VxDs to clean
* up in preperation for reboot.
*/
#define DEVICE_REBOOT_NOTIFY 0x0017
#define CRIT_REBOOT_NOTIFY 0x0018
/*
* Called when VM is about to be terminated using the Close_VM service
* EBX = Current VM handle (Handle of VM to close)
* EDX = Flags
* CVNF_CRIT_CLOSE = 1 if VM is in critical section while closing
*/
#define CLOSE_VM_NOTIFY 0x0019
#define CVNF_CRIT_CLOSE_BIT 0
#define CVNF_CRIT_CLOSE (1 << CVNF_CRIT_CLOSE_BIT)
/*
* Power management event notification.
* EBX = 0
* ESI = event notification message
* EDI -> DWORD return value; VxD's modify the DWORD to return info, not EDI
* EDX is reserved
*/
#define POWER_EVENT 0x001A
#define SYS_DYNAMIC_DEVICE_INIT 0x001B
#define SYS_DYNAMIC_DEVICE_EXIT 0x001C
/*
* Create_THREAD creates a new thread. EDI = handle of new thread.
* Returning Carry will fail the Create_THREAD. Message is sent in the
* context of the creating thread.
*
*/
#define CREATE_THREAD 0x001D
/*
* Second phase of creating a thread. EDI = handle of new thread. Call cannot
* be failed. VM Simulate_Int, Exec_Int activity is not allowed (because
* never allowed in non-initial threads). Message is sent in the context
* of the newly created thread.
*
*/
#define THREAD_INIT 0x001E
/*
* Normal (first) phase of Destroy_THREAD. EDI = handle of thread.
* This occurs on normal termination of the thread. Call cannot be failed.
* Simulate_Int, Exec_Int activity is allowed.
*/
#define TERMINATE_THREAD 0x001F
/*
* Second phase of Destroy_THREAD. EDI = Handle of thread,
* EDX = flags (see below). Note that in the case of destroying a
* running thread, this is the first call made (THREAD_Terminate call
* does not occur). Call cannot be failed. VM Simulate_Int, Exec_Int
* activity is NOT allowed.
*
*/
#define THREAD_Not_Executeable 0x0020
/*
* Final phase of Destroy_THREAD. EDI = Thread Handle. Note that considerable
* time can elapse between the THREAD_Not_Executeable call and this call.
* Call cannot be failed. VM Simulate_Int, Exec_Int activity is NOT
* allowed.
*
*/
#define DESTROY_THREAD 0x0021
/* -------------------- CALLS FOR PLUG&PLAY ------------------------- */
/*
* Configuration manager or a devloader is telling a DLVxD that a new devnode
* has been created. EBX is the handle of the new devnode and EDX is the load
* type (one of the DLVxD_LOAD_* defined in CONFIGMG.H). This is a 'C'
* system control call. Contrarily to the other calls, carry flags must be
* set if any error code other than CR_SUCCESS is to be return.
*
*/
#define PNP_NEW_DEVNODE 0x0022
/* -------------------- CALLS FOR Win32 ------------------------- */
/* vWin32 communicates with Vxds on behalf of Win32 apps thru this mechanism.
* BUGBUG: need more doc here, describing the interface
*/
#define W32_DEVICEIOCONTROL 0x0023
/* sub-functions */
#define DIOC_GETVERSION 0x0
#define DIOC_OPEN DIOC_GETVERSION
#define DIOC_CLOSEHANDLE -1
/* -------------------- MORE SYSTEM CALLS ------------------------- */
/*
* All these messages are sent immediately following the corresponding
* message of the same name, except that the "2" messages are sent
* in *reverse* init order.
*/
#define SYS_VM_TERMINATE2 0x0024
#define SYSTEM_EXIT2 0x0025
#define SYS_CRITICAL_EXIT2 0x0026
#define VM_TERMINATE2 0x0027
#define VM_NOT_EXECUTEABLE2 0x0028
#define DESTROY_VM2 0x0029
#define VM_SUSPEND2 0x002A
#define END_MESSAGE_MODE2 0x002B
#define END_PM_APP2 0x002C
#define DEVICE_REBOOT_NOTIFY2 0x002D
#define CRIT_REBOOT_NOTIFY2 0x002E
#define CLOSE_VM_NOTIFY2 0x002F
/*
* VCOMM gets Address of Contention handler from VxDs by sending this
* control message
*/
#define GET_CONTENTION_HANDLER 0x0030
#define KERNEL32_INITIALIZED 0x0031
#define KERNEL32_SHUTDOWN 0x0032
#define CREATE_PROCESS 0x0033
#define DESTROY_PROCESS 0x0034
#ifndef WIN40COMPAT
#define SYS_DYNAMIC_DEVICE_REINIT 0x0035
#endif
#define SYS_POWER_DOWN 0x0036
#define MAX_SYSTEM_CONTROL 0x0036
/*
* Dynamic VxD's can communicate with each other using Directed_Sys_Control
* and a private control message in the following range:
*/
#define BEGIN_RESERVED_PRIVATE_SYSTEM_CONTROL 0x70000000
#define END_RESERVED_PRIVATE_SYSTEM_CONTROL 0x7FFFFFFF
#endif // Not_VxD
/*
* Values returned from VMM_GetSystemInitState in EAX.
*
* Comments represent operations performed by VMM; #define's indicate
* what VMM_GetSystemInitState will return if you call it between the
* previous operation and the next.
*
* Future versions of Windows may have additional init states between the
* ones defined here, so you should be careful to use range checks instead
* of test for equality.
*/
/* Protected mode is entered */
#define SYSSTATE_PRESYSCRITINIT 0x00000000
/* SYS_CRITICAL_INIT is broadcast */
#define SYSSTATE_PREDEVICEINIT 0x10000000
/* DEVICE_INIT is broadcast */
#define SYSSTATE_PREINITCOMPLETE 0x20000000
/* INIT_COMPLETE is broadcast */
/* VxD initialization complete */
#define SYSSTATE_VXDINITCOMPLETED 0x40000000
/* KERNEL32_INITIALIZED is broadcast */
#define SYSSTATE_KERNEL32INITED 0x50000000
/* All initialization completed */
/* System running normally */
/* System shutdown initiated */
/* KERNEL32_SHUTDOWN is broadcast */
#define SYSSTATE_KERNEL32TERMINATED 0xA0000000
/* System shutdown continues */
#define SYSSTATE_PRESYSVMTERMINATE 0xB0000000
/* SYS_VM_TERMINATE is broadcast */
#define SYSSTATE_PRESYSTEMEXIT 0xE0000000
/* SYSTEM_EXIT is broadcast */
#define SYSSTATE_PRESYSTEMEXIT2 0xE4000000
/* SYSTEM_EXIT2 is broadcast */
#define SYSSTATE_PRESYSCRITEXIT 0xF0000000
/* SYS_CRITICAL_EXIT is broadcast */
#define SYSSTATE_PRESYSCRITEXIT2 0xF4000000
/* SYS_CRITICAL_EXIT2 is broadcast */
#define SYSSTATE_POSTSYSCRITEXIT2 0xFFF00000
/* Return to real mode */
/* Alternate path: CAD reboot */
#define SYSSTATE_PREDEVICEREBOOT 0xFFFF0000
/* DEVICE_REBOOT_NOTIFY is broadcast */
#define SYSSTATE_PRECRITREBOOT 0xFFFFF000
/* CRIT_REBOOT_NOTIFY is broadcast */
#define SYSSTATE_PREREBOOTCPU 0xFFFFFF00
/* REBOOT_PROCESSOR is broadcast */
/* Return to real mode */
/* ASM
BeginDoc
;******************************************************************************
; BeginProc is a macro for defining entry points to routines in VMM and in the
; VxDs. It correctly defines the procedure name for VxD services, DWORD
; aligns the procedure, takes care of public declaration and does some
; calling verification for debug versions of the software. EndProc is a
; macro which defines the end of the procedure.
;
; Valid parameters to the BeginProc macro are:
; PUBLIC ; Used outside this module (default)
; LOCAL ; Local to this module
; HIGH_FREQ ; DWORD align procedure
; SERVICE ; Routine is called via VxDCall
; ASYNC_SERVICE ; Same as "SERVICE" plus routine can
; ; be called under interrupt.
; HOOK_PROC ; Proc is a handler installed with
; ; with a call to Hook_xxx_Fault
; ; or Hook_Device_Service. The
; ; following parameter must be
; ; the label of a DWORD location
; ; which will hold the ptr to next
; ; hook proc. e.g.
;
; ;BeginProc foo, SERVICE, HOOK_PROC, foo_next_ptr
;
; NO_LOG ; Disable Queue_Out call logging
; NO_PROFILE ; Disable DynaLink profile counts
; NO_TEST_CLD ; Disable direction flag check
;
; TEST_BLOCK ; Trap if in NOBLOCK state
; ; (default if in pageable code seg)
; TEST_REENTER ; Trap if Get_VMM_Reenter_Count != 0
; ; (default for non-async services)
; NEVER_REENTER ; Trap if VMM has been reentered
; NOT_SWAPPING ; Trap if this thread is swapping
;
; NO_PROLOG ; Disable all prolog tests
;
; ESP ; Use ESP instead of EBP for stack
; ; frame base
; PCALL ; pascal calling convention
; SCALL ; stdcall calling convention
; FASTCALL ; stdcall, but first 2 parameters are passed in ECX & EDX
; CCALL ; "C" calling convention
; ICALL ; default calling convention
; W32SVC ; Win32 service
;
; segment type ; Place function in specified segment
;
; The NO_PROFILE flag merely suppresses incrementing the profile count.
; The DWORD of profiling information will still be emitted to appease
; the debugger. If you want to increment the profile count manually,
; use the IncProfileCount macro.
;
; TEST_REENTER and NEVER_REENTER differ in that the VMM reentry count
; returned by Get_VMM_Reenter_Count is artifically forced to zero by
; Begin_Reentrant_Execution, whereas the counter checked by NEVER_REENTER
; reflects the genuine count of VMM reentry.
;
; A segment type (such as LOCKED, PAGEABLE, STATIC, INIT, DEBUG_ONLY) can be
; provided, in which case the BeginProc and EndProc macros will
; automatically place the appropriate segment directives around the
; definition of the function.
;
; segment type ; Place function in specified segment
;
; After the routine header in which the routine entry conditions, exit
; conditions, side affects and functionality are specified, the BeginProc
; macro should be used to define the routine's entry point. It has up to
; four parameters as specified below. For example:
;
;BeginProc <Function_Name>,PUBLIC, HIGH_FREQ, SERVICE, ASYNC_SERVICE, ESP
;
; <code>
;
;EndProc <Function_Name>
;==============================================================================
EndDoc
;
; BeginProc handling takes place in the following phases:
;
; Phase 1: Parsing the arguments.
; Phase 2: Setting default flags.
; Phase 3: Combining the flags.
; Phase 4: Code emitted before the label
; Phase 5: Munge the name as exported to C/Pascal/whoever
; Phase 6: _Debug_Flags_Service prolog
; Phase 7: Code emitted after the label
;
??_pf_Check equ 1 ;; Do Enter/LeaveProc checking?
??_pf_ArgsUsed equ 2 ;; ArgVars were used
??_pf_Entered equ 4 ;; EnterProc performed
??_pf_Left equ 8 ;; LeaveProc performed
??_pf_Returned equ 16 ;; Return performed
??_inline = 0 ; Inline the service
??_inline_end equ <> ; End of code to inline
??_pushed = 0 ; For WIN31COMPAT
??_align = 0 ; For WIN31COMPAT
??_ends equ <> ; BeginProc segment
INLINE_MAGIC_W equ 02EBh ; Inline service magic number (JMP $+4)
INLINE_MAGIC_B equ 0F1h ; Inline service magic number
BeginProc macro Name, P1, P2, P3, P4, P5, P6, P7, LastArg
local Profile_Data, prelabeldata, ??_hookvar
??_frame = 0 ;; local frame base
??_aframe = 0 ;; argument frame base
??_taframe = 0 ;; true argument frame base
??_initaframe = 0 ;; initial aframe value
??_numargs = 0 ;; number of argvars
??_numlocals = 0 ;; number of localvars
??_numlocalsymbols = 0 ;; number of local symbols
??_procflags = 0 ;; misc. Enter/LeaveProc flags
??_esp = 0 ;; if VMM_TRUE, use esp instead of ebp
??_pushed = 0 ;; number of bytes pushed
??_align = 0 ;; set if proc should be dword aligned
??_hook = 0 ;; set if proc is a Hook_Proc
??_inline = 0 ;; Assume not inlined
??_hookarg = 0
??_service = 0
??_async_service = 0
IF DEBLEVEL GT DEBLEVELNORMAL
??_log = DFS_LOG ;; logging on by default
??_profile = DFS_PROFILE ;; service profiling on by default
??_test_cld = DFS_TEST_CLD ;; test that direction is clear
ELSE
??_log = 0 ;; logging off
IFDEF DEBUG
IFDEF profileall
IF ?_ICODE
??_profile = DFS_PROFILE ;; service profiling on by default
ELSE
??_profile = 0 ;; service profiling off
ENDIF
ELSE
??_profile = 0 ;; service profiling off
ENDIF
ELSE
??_profile = 0 ;; service profiling off
ENDIF
??_test_cld = 0 ;; test that direction is clear
ENDIF
??_might_block = 0 ;; entering fn might cause VM to block
??_test_reenter = 0 ;; don't test for VMM reentry
??_never_reenter = 0 ;; don't test for genuine VMM reentry
??_not_swapping = 0 ;; don't test that we're not swapping
??_prolog_disabled = 0 ;; use a prolog by default
??_public = 1 ;; everything's public by default
??_cleanoff = 0 ;; don't cleanoff parameters
??_ccall = 0
??_pcall = 0
??_scall = 0
??_fastcall = 0
??_w32svc = 0
??_fleave = FALSE
; ??_dfs = 0 ;; parm for _Debug_Flags_Service
??_name equ <Name>
.errnb ??_ends, <Cannot nest functions with named segments>
.errnb <LastArg>, <Too many arguments to BeginProc>
;; Phase 1: Parsing the arguments
irp arg, <P1, P2, P3, P4, P5, P6, P7>
if ??_hookarg
??_hookarg = 0
??_hookvar equ <arg>
elseifdef ?&&arg&&_BeginProc
?&&arg&&_BeginProc
elseifdef VxD_&&arg&&_CODE_SEG
??_ends textequ <VxD_&&arg&&_CODE_ENDS>
VxD_&&arg&&_CODE_SEG
else
.err <Bad param "&arg" to BeginProc>
endif
endm
ife ??_service
??_inline = 0 ;; Only services can be inlined
endif
;; Phase 2: Setting default flags
ifndef Not_VxD
ife ??_service
ifndef profileall
??_profile = 0 ;; only services can be profiled
endif
ifdef VMMSYS
??_prolog_disabled = 1
endif
else
??_test_cld = DFS_TEST_CLD
endif ; ife ??_service
ife ?_16ICODE
??_prolog_disabled = 1
else
ife ?_RCODE ;; if real-mode code segment
??_prolog_disabled = 1 ;; don't do anything stupid
else ;; else protected mode code segment
ife ?_PCODE ;; if swappable code
??_might_block = DFS_TEST_BLOCK
endif
if ??_service
ife ??_async_service
??_test_reenter = DFS_TEST_REENTER
endif
endif
endif ; ife ?_RCODE
endif ; ife ?_16ICODE
endif ; Not_VxD
if ??_esp
;; just return address on stack
??_basereg equ <esp+??_pushed>
??_initaframe = 4
else
;; ret addr and EBP on stack
??_basereg equ <ebp>
??_initaframe = 8
endif
@Caller equ <dword ptr [??_basereg+??_initaframe-4]>
??_cleanoff = ??_pcall or ??_scall or ??_fastcall
;; Phase 3: Combining the flags
??_dfs = ??_never_reenter + ??_test_reenter + ??_not_swapping + \
??_log + ??_profile + ??_test_cld + ??_might_block
if ??_prolog_disabled
??_dfs = 0
endif
;; Phase 4: Pre-label code
ifndef Not_VxD
if ??_hook
if ??_align
Dword_Align
endif
prelabeldata:
ifndef ??_hookvar
.err <HOOK_PROC requires next arg to be name of dword location>
endif
jmp short Name
jmp [??_hookvar]
ifdef DEBUG
Profile_Data dd 0
endif
if ??_align
.errnz ($ - prelabeldata) mod 4
endif
endif
ifdef DEBUG
?prolog_&Name label near
if (??_service OR ??_profile) AND (??_hook EQ 0)
jmp short Name
if ??_align
Dword_Align ; This also aligns the proc
endif ; since Profile_Data is a dd
IF ?_ICODE
ifdef profileall
?ProfileHeader_BeginProc Profile_Data, %@filename
else
Profile_Data dd 0
endif
ELSE
Profile_Data dd 0
ENDIF
endif
endif
if ??_align
Dword_Align
endif
endif ; Not_VxD
Name proc near ;; The label
;; Phase 5: Munge the name as exported to C/Pascal/whoever
;; Warning! Phase 5 cannot emit code!
ife ??_pcall or ??_ccall or ??_scall or ??_fastcall ;; if no munging
if ??_public
public Name
else
ifdef DEBUG
% ?merge @FileName,$,Name,:
% ?merge public,,,,,@FileName,$,Name
endif
endif
endif
if ??_ccall
if ??_public
_&Name equ Name
ifdef Not_VxD
public C Name
else
public _&Name
endif
endif
endif
if ??_pcall
if ??_public
?toupper Name
?merge public,,,,%?upper
endif
endif
;; Phase 6: _Debug_Flags_Service prolog
;; DO NOT CHANGE UNTIL YOU UNDERSTAND _Debug_Flags_Service
ife ??_scall or ??_fastcall or ??_inline
?_BeginProc_Debug_Prologue
endif
;; Phase 7: Post-label code
if ??_inline
??_inline_end textequ <__&Name&_END__>
dw INLINE_MAGIC_W
db INLINE_MAGIC_B
db ??_inline_end - ($ + 1)
endif
endm
?_BeginProc_Debug_Prologue MACRO
ifndef Not_VxD
ifdef DEBUG
if ??_dfs EQ DFS_LOG
VMMCall Log_Proc_Call ;; no test, just log
else
if ??_dfs EQ DFS_TEST_REENTER
VMMCall Test_Reenter ;; no log, just reenter
else
if ??_dfs or ?_LOCKABLECODE eq 0
ifdef WIN31COMPAT
if ??_dfs AND DFS_LOG
VMMCall Log_Proc_Call
endif
if ??_dfs AND DFS_TEST_REENTER
VMMCall Test_Reenter
endif
else
ife ?_LOCKABLECODE
ifdef ??_debug_flags
push ??_debug_flags
if ??_dfs
pushfd
or dword ptr [esp+4],??_dfs
popfd
endif
VMMCall _Debug_Flags_Service
elseif ??_dfs
push ??_dfs
VMMCall _Debug_Flags_Service
endif
else
push ??_dfs
VMMCall _Debug_Flags_Service
endif
endif
else
ifdef profileall
IncProfileCount
endif
endif ;if ??_dfs
endif ; if ??_dfs EQ DFS_TEST_REENTER
endif ; if ??_dfs EQ DFS_LOG
endif ; DEBUG
endif ; Not_VxD
ENDM
;
; For each BeginProc keyword, there is a corresponding macro ?XX_BeginProc.
;
; The macro ?_BeginProc is so that the null keyword is not an error.
?_BeginProc macro
endm
?PUBLIC_BeginProc macro
??_public = 1
endm
?LOCAL_BeginProc macro
??_public = 0
endm
?HIGH_FREQ_BeginProc macro
??_align = 1
endm
?HOOK_PROC_BeginProc macro
??_hook = 1
??_hookarg = 1 ; next arg is dword storage location
endm
?SERVICE_BeginProc macro
??_service = 1
.erre ?_16ICODE, <SERVICEs must be in 32 bit code>
.erre ?_RCODE, <SERVICEs must be in 32 bit code>
endm
?INLINE_BeginProc macro
??_inline = 1
endm
?ASYNC_SERVICE_BeginProc macro
??_service = 1
??_async_service = 1
.errnz ?_LCODE, <ASYNC_SERVICE's must be in LOCKED code>
endm
?NO_LOG_BeginProc macro
??_log = 0
endm
?NO_PROFILE_BeginProc macro
??_profile = 0
endm
?NO_TEST_CLD_BeginProc macro
??_test_cld = 0
endm
?TEST_BLOCK_BeginProc macro
??_might_block = DFS_TEST_BLOCK
endm
?TEST_REENTER_BeginProc macro
??_test_reenter = DFS_TEST_REENTER
endm
?NEVER_REENTER_BeginProc macro
??_never_reenter = DFS_NEVER_REENTER
endm
?NOT_SWAPPING_BeginProc macro
??_not_swapping = DFS_NOT_SWAPPING
endm
?NO_PROLOG_BeginProc macro
??_prolog_disabled = 1
endm
?ESP_BeginProc macro
??_esp = VMM_TRUE
ifndef Not_VxD
.erre ?_16ICODE, <Beginproc ESP attribute invalid in 16 bit seg.>
.erre ?_RCODE, <Beginproc ESP attribute invalid in real-mode seg.>
endif
endm
?CCALL_BeginProc macro
??_ccall = 1
endm
?PCALL_BeginProc macro
??_pcall = 1
endm
?SCALL_BeginProc macro
??_scall = 1
endm
?FASTCALL_BeginProc macro
??_fastcall = 1
endm
?ICALL_BeginProc macro
??_scall = 1 ;; internal calling convention is StdCall
endm
?W32SVC_BeginProc macro
??_scall = 1
??_w32svc = 1
endm
ifdef DEBUG
ifdef profileall
?ProfileHeader_BeginProc macro PL, filename
ifndef _&filename&__proc_list
_&filename&__proc_list = 0
PUBLIC _&filename&__proc_list
endif
dd OFFSET32 _&filename&__proc_list
PL dd 0
_&filename&__proc_list = PL
endm
endif
IncProfileCount macro
if ??_service OR ??_profile
inc dword ptr [??_name-4]
else
ifndef profileall
.err <IncProfileCount can be used only in services.>
endif
endif
endm
else
IncProfileCount macro
endm
endif
;*** ArgVar - declares stack arguments
;
; Usage:
;
; name = name of argument.
; length = a numeric expression denoting the size (in bytes)
; of the argument. The symbols BYTE, WORD, and DWORD
; are synonyms for 1, 2, and 4 respectively.
; NB! All arguments sizes are rounded up to the nearest
; multiple of 4.
; used = usually blank, but can be the symbol NOTUSED
; to indicate that the argument will not be used
; by the procedure.
;
ArgVar macro name,length,used
??_numargs = ??_numargs + 1
if ??_pcall
?mkarg <name>, <length>, <used>, %??_numargs
else
?arg <name>, <length>, <used>
endif
??_procflags = ??_procflags OR ??_pf_Check
endm
?mkarg macro name, length, used, num
.xcref ?MKA&num
?deflocal <name>
?MKA&num &macro
?argvar <name>, <length>, <used>
&endm
??_aframe = ??_aframe + 4
endm
.xcref ?mkarg
?argvar macro name,length,used
local a
a = ??_taframe
??_aframe = ??_aframe + 4
??_taframe = ??_taframe + 4
ifidni <length>,<BYTE>
?setname <name>, <byte ptr [??_basereg+??_initaframe+a]>, <used>
elseifidni <length>,<WORD>
?setname <name>, <word ptr [??_basereg+??_initaframe+a]>, <used>
elseifidni <length>,<DWORD>
?setname <name>, <dword ptr [??_basereg+??_initaframe+a]>, <used>
?setname <name&l>,<word ptr [??_basereg+??_initaframe+a]>, <used>
?setname <name&ll>,<byte ptr [??_basereg+??_initaframe+a]>, <used>
?setname <name&lh>,<byte ptr [??_basereg+??_initaframe+a+1]>, <used>
?setname <name&h>,<word ptr [??_basereg+??_initaframe+a+2]>, <used>
?setname <name&hl>,<byte ptr [??_basereg+??_initaframe+a+2]>, <used>
?setname <name&hh>,<byte ptr [??_basereg+??_initaframe+a+3]>, <used>
else
??_aframe = ??_aframe - 4 + ((length + 3)/4)*4
??_taframe = ??_taframe - 4 + ((length + 3)/4)*4
?setname <name>, <[??_basereg+??_initaframe+a]>, <used>
endif
endm
?arg macro name,length,used
if ??_fastcall
if ??_numargs le 2
if length gt 4
.err <First 2 parameters are dwords (ecx,edx) for fastcall functions>
endif
??_aframe = ??_aframe + 4
if ??_numargs eq 1
?merge ecx_,name,,,equ,ecx
else
?merge edx_,name,,,equ,edx
endif
else
?argvar name, length, used
endif
else
?argvar name, length, used
endif
endm
;*** ?setname - optionally creates the name of an ArgVar
;
; If <used> is <NOTUSED>, then the name is defined to something
; bogus.
?setname macro name, value, used
?deflocal <name>
ifidni <used>, <NOTUSED>
name equ _inaccessible_NOTUSED_
else
name equ value
??_procflags = ??_procflags OR ??_pf_ArgsUsed OR ??_pf_Check
endif
endm
;*** LocalVar - declares local stack variables
;
; Usage:
;
; name = name of local variable
; length = a numeric expression denoting the size (in bytes)
; of the argument. The symbols BYTE, WORD, and DWORD
; are synonyms for 1, 2, and 4 respectively.
; NB! All arguments sizes are rounded up to the nearest
; multiple of 4 (unless PACK is indicated)
; flag = usually blank, but can be the symbol PACK
; to suppress the usual padding and aligning of variables
; PACK is typically used when declaring a bunch of
; byte or word variables. Make sure that the total
; size of PACKed variables is a multiple of 4.
;
LocalVar macro name,length,flag
local a
??_numlocals = ??_numlocals + 1
??_pad = 1
ifidni <flag>, <PACK>
??_pad = 0
endif
ifidni <length>,<BYTE>
??_frame = ??_frame + 1 + 3 * ??_pad
a = ??_frame
?deflocal <name>
name equ byte ptr [??_basereg-a]
elseifidni <length>,<WORD>
??_frame = ??_frame + 2 + 2 * ??_pad
a = ??_frame
?deflocal <name>
name equ word ptr [??_basereg-a]
elseifidni <length>,<DWORD>
??_frame = ??_frame + 4
a = ??_frame
?deflocal <name, name&l, name&ll, name&lh, name&h, name&hl, name&hh>
name equ dword ptr [??_basereg-a]
name&l equ word ptr [??_basereg-a]
name&ll equ byte ptr [??_basereg-a]
name&lh equ byte ptr [??_basereg-a+1]
name&h equ word ptr [??_basereg-a+2]
name&hl equ byte ptr [??_basereg-a+2]
name&hh equ byte ptr [??_basereg-a+3]
else
??_frame = ??_frame + ((length + 3)/4)*4
a = ??_frame
?deflocal <name>
name equ [??_basereg-a]
endif
??_procflags = ??_procflags OR ??_pf_Check
endm
?deflocal macro name
irp nm, <name>
??_numlocalsymbols = ??_numlocalsymbols + 1
?dodeflocal <nm>, %(??_numlocalsymbols)
endm
endm
.xcref ?deflocal
?dodeflocal macro name, num
.xcref ?LOC&num
?LOC&num &macro
name equ <__inaccessible__NOTINSCOPE__>
&endm
endm
.xcref ?dodeflocal
;*** EnterProc - generates stack frame on entry
EnterProc macro
.errnz ??_frame and 3, <Total size of local variables not a multiple of 4.>
if ??_scall
if ??_public
ifdef Not_VxD
?merge %??_name,@,%(??_aframe),,label,near
?merge public,,,,C,%??_name,@,%(??_aframe)
else
?merge _,%??_name,@,%(??_aframe),label,near
?merge public,,,,,_,%??_name,@,%(??_aframe)
endif
endif
?_BeginProc_Debug_Prologue
endif
if ??_fastcall
if ??_public
ifdef Not_VxD
?merge %??_name,@,%(??_aframe),,label,near
?merge public,,,,C,%??_name,@,%(??_aframe)
else
?merge @,%??_name,@,%(??_aframe),label,near
?merge public,,,,,@,%??_name,@,%(??_aframe)
endif
endif
?_BeginProc_Debug_Prologue
endif
if ??_pcall
??_aframe = 0
?count = ??_numargs
rept ??_numargs
?invprg <?MKA>,%?count
?count = ?count - 1
endm
endif
??_fleave = FALSE
if ??_esp
if ??_frame
sub esp, ??_frame
??_pushed = ??_pushed + ??_frame
??_fleave = VMM_TRUE
endif
else
if ??_frame eq 0
if (??_taframe eq 0) OR ((??_procflags AND ??_pf_ArgsUsed) EQ 0)
ifdef DEBUG
push ebp
mov ebp,esp
??_fleave = VMM_TRUE
endif
else
push ebp
mov ebp,esp
??_fleave = VMM_TRUE
endif
else
enter ??_frame, 0
??_fleave = VMM_TRUE
endif
endif
??_procflags = ??_procflags OR ??_pf_Entered
endm
;*** LeaveProc - removes stack frame on exit
;
; NOTE: If there are localvar and ESP kind of stack frame
; LeaveProc will destroy flags unless the "PRESERVE_FLAGS"
; flag is given. PRESERVE_FLAGS generates bigger, slower
; code, so use it only when necessary.
;
; WARNING: For "ESP" type stack frames, this macro DOES NOT adjust
; the internal stack depth for the local frame. This is
; to allow jumping around the LeaveProc/Return to code
; after the LeaveProc/Return to use args/local variables,
; but code that uses the stack frame executed after the
; LeaveProc won't work.
LeaveProc macro flags
if ??_fleave
if ??_esp
ifidni <flags>,<PRESERVE_FLAGS>
lea esp,[esp + ??_frame]
else
add esp,??_frame
endif
else
leave
endif
endif
??_procflags = ??_procflags OR ??_pf_Left
endm
;*** Return - return appropriately from a procedure
;
; For "ccall" functions it's just a ret; for "pcall" and "scall"
; it cleans the parameters off.
;
Return macro
if ??_cleanoff OR ??_w32svc
if ??_inline
.err <Service cannot be inlined!>
endif
if ??_w32svc AND (??_taframe LT 8)
ret 8
else
ret ??_taframe
endif
else
if ??_inline
??_inline_end LABEL NEAR
??_inline = 0
endif
ret
endif
??_procflags = ??_procflags OR ??_pf_Returned
endm
;*** EndProc - end the procedure
;
EndProc macro Name, Flag
Name endp ;; Masm will provide error msg for us
if ??_w32svc
if ??_taframe lt 8
cparm&Name equ 0
else
cparm&Name equ (??_taframe/4 - 2)
endif
endif
if ??_inline
.err <Return macro missing in INLINEd procedure Name>
endif
if ??_procflags AND ??_pf_Left
if ??_fleave
if ??_esp
??_pushed = ??_pushed - ??_frame
endif
endif
endif
ifdifi <Flag>,<NOCHECK>
if ??_pushed ne 0
%out Warning: stack not balanced in Name
endif
if ??_procflags AND ??_pf_Check
ife ??_procflags AND ??_pf_Entered
%out Warning: ArgVar/LocalVar without EnterProc in Name
endif
ife ??_procflags AND ??_pf_Left
%out Warning: ArgVar/LocalVar without LeaveProc in Name
endif
ife ??_procflags AND ??_pf_Returned
%out Warning: ArgVar/LocalVar without Return in Name
endif
endif
endif
ifdifi <Flag>,<KEEPFRAMEVARS>
?count = 0
rept ??_numlocalsymbols
?count = ?count + 1
?invprg <?LOC>,%?count
endm
endif
??_ends
??_ends equ <>
??_inline_end equ <>
endm
;*** cCall - "C" call
;
; Arguments pushed in "C" order, caller cleans stack
;
; USES: Flags.
cCall macro name, arglst, flags
ife .TYPE name
CondExtern name, near
endif
ifdef ??_nonstandardccall_&name
PushCParams <arglst>, <FAST>
else
PushCParams <arglst>, <flags>
endif
call name
ifdef ??_nonstandardccall_&name
ClearCParams PRESERVE_FLAGS
else
ClearCParams <flags>
endif
endm
.xcref cCall
;*** pCall - pascal call
;
; Arguments pushed in pascal order, callee cleans stack
;
pCall macro name, arglst
local ??saved
ife .TYPE name
?toupper name
else
?upper equ <name>
endif
CondExtern %?upper, near
??saved = ??_pushed
irp x,<arglst>
push x
??_pushed = ??_pushed + 4
endm
call ?upper
??_pushed = ??saved
endm
.xcref pCall
;*** sCall - standard call
;
; Arguments pushed in "C" order, callee cleans stack,
; @argc appended to name
;
sCall macro name, arglst
local ??saved
??saved = ??_pushed
PushCParams <arglst>
?scall _, name, %(??_argc * 4)
??_pushed = ??saved
endm
.xcref sCall
;*** fCall - fastcall call
;
; Arguments pushed in "C" order (except first two parms,
; which are passed in ECX and EDX), callee cleans stack, and
; @argc appended to name.
;
; The only useful value for flags is PRESERVE_FLAGS,
; which can also be achieved by simply declaring the function
; as non-standard, like so:
;
; DeclareNonstandardCcallService <functionname>
;
fCall macro name, arglst, flags
local ??saved
??saved = ??_pushed
ife .TYPE name
CondExtern name, near
endif
PushCParams <arglst>, <FASTCALL>
?scall @, name, %(??_argc * 4)
ifdef ??_nonstandardccall_&name
ClearCParams PRESERVE_FLAGS
else
ClearCParams <flags>
endif
??_pushed = ??saved
endm
.xcref fCall
;*** iCall - internal routine call
;
; Set to whatever type we want to use as a default.
iCall equ <sCall>
;*** PushCParams
;
; Processes argument list
;
; arglist = <arg1, arg2, arg3, ...>
; flags = the word SMALL if we should prefer size over speed
; the word FAST if we should prefer speed over size
;
; The default flag is SMALL, unless the current procedure
; is High_Freq, in which case we default to FAST.
;
; To disable this optimization, define the symbol NONSTANDARD_CCALL.
;
IFNDEF STANDARD_CCALL
NONSTANDARD_CCALL = 1 ;; disabled by default for now
ENDIF
PushCParams macro arglst, flags
LOCAL ??_pushedargs
??_argc = 0 ;; number of dwords on stack (global)
IFDEF NONSTANDARD_CCALL
??_popargs = 0 ;; establish default
ELSE
??_popargs = ??_align EQ 0 ;; establish default
ENDIF
ifidni <flags>, <SMALL>
??_popargs = 1 ;; size, not speed
elseifidni <flags>, <FAST>
??_popargs = 0 ;; speed, not size
elseifidni <flags>, <FASTCALL>
??_popargs = 0 ;; speed, not size
endif
irp x,<arglst>
??_argc = ??_argc + 1
ifidni <flags>, <FASTCALL>
if ??_argc eq 1
ifdifi <x>, <ecx>
.err <first parameter must be ECX for fastcall functions>
endif
elseif ??_argc eq 2
ifdifi <x>, <edx>
.err <first parameter must be EDX for fastcall functions>
endif
else
?marg <x>,%??_argc
endif
else
?marg <x>,%??_argc
endif
endm
?count = ??_argc
ifidni <flags>, <FASTCALL>
??_pushedargs = ??_argc-2
else
??_pushedargs = ??_argc
endif
if ??_pushedargs GT 0
rept ??_argc
?invprg <?AM>,%?count
?count = ?count - 1
endm
endif
endm
;*** ClearCParams
;
; Processes stack clean up
;
; This routine will trade size for speed (if requested)
; by using `pop ecx' to clean off one or two arguments.
; This relies on the convention that C-call routines do
; not return useful information in ECX.
;
; To disable this optimization, define the symbol NONSTANDARD_CCALL.
;
; If flags must be preserved, pass PRESERVE_FLAGS as an argument.
; This will generate bigger, slower code, so use it only when
; necessary.
ClearCParams macro fPreserveFlags
if ??_argc ne 0
if (??_popargs) AND (??_argc LE 2)
rept ??_argc
pop ecx
endm
elseifidni <fPreserveFlags>, <PRESERVE_FLAGS>
lea esp, [esp][??_argc * 4]
else
add esp,??_argc * 4
endif
endif
??_pushed = ??_pushed - (??_argc * 4)
endm
; Makes a macro that will push argment when invoke - used by cCall only
?marg macro name, num
.xcref
.xcref ?AM&num
.cref
?AM&num &macro
push name
??_pushed = ??_pushed + 4
&endm
endm
.xcref ?marg
; Concatenates, invokes and purges a macro name - used by PushCParams
?invprg macro name1, name2
name1&name2
purge name1&name2
endm
.xcref ?invprg
; Calls a concatenated standard call name and makes it external
?scall macro prefix, name1, name2
CondExtern prefix&name1&@&name2, near
call prefix&name1&@&name2
endm
.xcref ?scall
; Equates name to a name
?merge macro l1, l2, l3, l4, op, r1, r2, r3, r4, r5, r6, r7, r8, r9
l1&l2&l3&l4 op r1&r2&r3&r4&r5&r6&r7&r8&r9
endm
; Converts string to upper-case, returned in ?upper
?toupper macro s
?upper equ <>
irpc x,<s>
if '&x' GE 'a'
if '&x' LE 'z'
?t1 substr <ABCDEFGHIJKLMNOPQRSTUVWXYZ>,'&x'-'a'+1,1
?upper catstr ?upper,?t1
else
?upper catstr ?upper,<&x>
endif
else
?upper catstr ?upper,<&x>
endif
endm
endm
.xcref
;*** CondExtern - Make name external if not already defined
;
; This operation is quite different between MASM 5.1 and 6.0.
;
CondExtern macro name,dist
ifdef MASM6
ifndef name
externdef name:dist
endif
else
if2
ifndef name
extrn name:dist
endif
endif
endif
endm
;*** SaveReg - Save register, "fd" pushes flags, "ad" pushes all
SaveReg macro reglist ;; push those registers
irp reg,<reglist>
ifidni <reg>, <fd>
pushfd
??_pushed = ??_pushed + 4
else
ifidni <reg>, <ad>
pushad
??_pushed = ??_pushed + SIZE Pushad_Struc
else
push reg
??_pushed = ??_pushed + 4
endif
endif
endm
endm
;*** RestoreReg - Restore register, "fd" pops flags, "ad" pops all
;
; Note that registers must be restored in reverse order that they
; were saved.
;
RestoreReg macro reglist ;; pop those registers
irp reg,<reglist>
ifidni <reg>, <fd>
popfd
??_pushed = ??_pushed - 4
else
ifidni <reg>, <ad>
popad
??_pushed = ??_pushed - SIZE Pushad_Struc
else
pop reg
??_pushed = ??_pushed - 4
endif
endif
endm
endm
*/
#ifdef DEBUG
/******************************************************************************
* The following macros are for enabling procedure call profile counting
* of VxD's written in assembler.
*
* Begin_Profile_List needs to be used in the file that declares the device
* immediately after the Declare_Virtual_Device line. Then one Profile_Link
* line is required for each individual source file. The list is ended with
* the End_Profile_List macro. Profiling only works for debug builds and
* the sources must all be built with "-Dprofileall" masm switch.
******************************************************************************/
/* ASM
Begin_Profile_List macro devname
ifdef profileall
VxD_DATA_SEG
db 'PROCLIST'
PUBLIC devname&_Proc_Profile_List
devname&_Proc_Profile_List label dword
endif
endm
Profile_Link macro modname
ifdef profileall
ifdifi <modname>,@filename
EXTRN _&modname&__proc_list:near
endif
dd OFFSET32 _&modname&__proc_list
endif
endm
End_Profile_List macro
ifdef profileall
dd 0
VxD_DATA_ENDS
endif
endm
*/
#endif
#ifndef Not_VxD
/******************************************************************************
* S C H E D U L E R B O O S T V A L U E S
*****************************************************************************/
#define RESERVED_LOW_BOOST 0x00000001
#define CUR_RUN_VM_BOOST 0x00000004
#define LOW_PRI_DEVICE_BOOST 0x00000010
#define HIGH_PRI_DEVICE_BOOST 0x00001000
#define CRITICAL_SECTION_BOOST 0x00100000
#define TIME_CRITICAL_BOOST 0x00400000
#define RESERVED_HIGH_BOOST 0x40000000
/******************************************************************************
* F L A G S F O R C A L L _ P R I O R I T Y _ V M _ E V E N T
*****************************************************************************/
#define PEF_WAIT_FOR_STI_BIT 0
#define PEF_WAIT_FOR_STI (1 << PEF_WAIT_FOR_STI_BIT)
#define PEF_WAIT_NOT_CRIT_BIT 1
#define PEF_WAIT_NOT_CRIT (1 << PEF_WAIT_NOT_CRIT_BIT)
#define PEF_DONT_UNBOOST_BIT 2
#define PEF_DONT_UNBOOST (1 << PEF_DONT_UNBOOST_BIT)
#define PEF_ALWAYS_SCHED_BIT 3
#define PEF_ALWAYS_SCHED (1 << PEF_ALWAYS_SCHED_BIT)
#define PEF_TIME_OUT_BIT 4
#define PEF_TIME_OUT (1 << PEF_TIME_OUT_BIT)
#define PEF_WAIT_NOT_HW_INT_BIT 5
#define PEF_WAIT_NOT_HW_INT (1 << PEF_WAIT_NOT_HW_INT_BIT)
#define PEF_WAIT_NOT_NESTED_EXEC_BIT 6
#define PEF_WAIT_NOT_NESTED_EXEC (1 << PEF_WAIT_NOT_NESTED_EXEC_BIT)
#define PEF_WAIT_IN_PM_BIT 7
#define PEF_WAIT_IN_PM (1 << PEF_WAIT_IN_PM_BIT)
#define PEF_THREAD_EVENT_BIT 8
#define PEF_THREAD_EVENT (1 << PEF_THREAD_EVENT_BIT)
#define PEF_WAIT_FOR_THREAD_STI_BIT 9
#define PEF_WAIT_FOR_THREAD_STI (1 << PEF_WAIT_FOR_THREAD_STI_BIT)
#define PEF_RING0_EVENT_BIT 10
#define PEF_RING0_EVENT (1 << PEF_RING0_EVENT_BIT)
#define PEF_WAIT_CRIT_BIT 11
#define PEF_WAIT_CRIT (1 << PEF_WAIT_CRIT_BIT)
#define PEF_WAIT_CRIT_VM_BIT 12
#define PEF_WAIT_CRIT_VM (1 << PEF_WAIT_CRIT_VM_BIT)
#define PEF_PROCESS_LAST_BIT 13
#define PEF_PROCESS_LAST (1 << PEF_PROCESS_LAST_BIT)
#define PEF_WAIT_PREEMPTABLE_BIT 14
#define PEF_WAIT_PREEMPTABLE (1 << PEF_WAIT_PREEMPTABLE_BIT)
#define PEF_WAIT_FOR_PASSIVE_BIT 15
#define PEF_WAIT_FOR_PASSIVE (1 << PEF_WAIT_FOR_PASSIVE_BIT)
//
// The next two are equivalent of SHELL_Call_At_Appy_Time and ExQueueWorkItem,
// they are mostly to be used by _Set_Global_Time_Out_Ex. No other flag can be
// set with them. Note that the dispatching of the callback of these two new
// PEF (with both Call_Restricted_Event and _Set_Global_Time_Out_Ex) follow
// the original convention but EDX (the ref data) is CDECL pushed/pop on the
// stack, so that the callback function can be a standard
// VOID CDECL FOO(ULONG BAR);
//
#define PEF_WAIT_FOR_APPY_BIT 16
#define PEF_WAIT_FOR_APPY (1 << PEF_WAIT_FOR_APPY_BIT)
#define PEF_WAIT_FOR_WORKER_BIT 17
#define PEF_WAIT_FOR_WORKER (1 << PEF_WAIT_FOR_WORKER_BIT)
// synonyms for event restrictions above
#define PEF_WAIT_NOT_TIME_CRIT_BIT PEF_WAIT_NOT_HW_INT_BIT
#define PEF_WAIT_NOT_TIME_CRIT PEF_WAIT_NOT_HW_INT
#define PEF_WAIT_NOT_PM_LOCKED_STACK_BIT PEF_WAIT_NOT_NESTED_EXEC_BIT
#define PEF_WAIT_NOT_PM_LOCKED_STACK PEF_WAIT_NOT_NESTED_EXEC
//
// If you may want to call CONFIGMG synchronously at some point.
//
#define PEF_WAIT_FOR_CONFIGMG_CALLABLE PEF_WAIT_FOR_WORKER
//
// If you will want to call CONFIGMG synchronously (slower callback, but no
// context switch in CONFIGMG).
//
#define PEF_WAIT_FOR_CONFIGMG_QUICK PEF_WAIT_FOR_APPY
/******************************************************************************
* F L A G S F O R B E G I N _ C R I T I C A L _ S E C T I O N,
* E N T E R _ M U T E X
* A N D W A I T _ S E M A P H O R E
*****************************************************************************/
#define BLOCK_SVC_INTS_BIT 0
#define BLOCK_SVC_INTS (1 << BLOCK_SVC_INTS_BIT)
#define BLOCK_SVC_IF_INTS_LOCKED_BIT 1
#define BLOCK_SVC_IF_INTS_LOCKED (1 << BLOCK_SVC_IF_INTS_LOCKED_BIT)
#define BLOCK_ENABLE_INTS_BIT 2
#define BLOCK_ENABLE_INTS (1 << BLOCK_ENABLE_INTS_BIT)
#define BLOCK_POLL_BIT 3
#define BLOCK_POLL (1 << BLOCK_POLL_BIT)
#define BLOCK_THREAD_IDLE_BIT 4
#define BLOCK_THREAD_IDLE (1 << BLOCK_THREAD_IDLE_BIT)
#define BLOCK_FORCE_SVC_INTS_BIT 5
#define BLOCK_FORCE_SVC_INTS (1 << BLOCK_FORCE_SVC_INTS_BIT)
/******************************************************************************
* The following structures are pointed to by EBP when VxD routines are
* entered, both for VxD control calls and traps(I/O traps, software INT
* traps, etc.). The first structure as DWORD values, the second WORD
* values and the last has BYTE values.
*****************************************************************************/
struct Client_Reg_Struc {
ULONG Client_EDI; /* Client's EDI */
ULONG Client_ESI; /* Client's ESI */
ULONG Client_EBP; /* Client's EBP */
ULONG Client_res0; /* ESP at pushall */
ULONG Client_EBX; /* Client's EBX */
ULONG Client_EDX; /* Client's EDX */
ULONG Client_ECX; /* Client's ECX */
ULONG Client_EAX; /* Client's EAX */
ULONG Client_Error; /* Dword error code */
ULONG Client_EIP; /* EIP */
USHORT Client_CS; /* CS */
USHORT Client_res1; /* (padding) */
ULONG Client_EFlags; /* EFLAGS */
ULONG Client_ESP; /* ESP */
USHORT Client_SS; /* SS */
USHORT Client_res2; /* (padding) */
USHORT Client_ES; /* ES */
USHORT Client_res3; /* (padding) */
USHORT Client_DS; /* DS */
USHORT Client_res4; /* (padding) */
USHORT Client_FS; /* FS */
USHORT Client_res5; /* (padding) */
USHORT Client_GS; /* GS */
USHORT Client_res6; /* (padding) */
ULONG Client_Alt_EIP;
USHORT Client_Alt_CS;
USHORT Client_res7;
ULONG Client_Alt_EFlags;
ULONG Client_Alt_ESP;
USHORT Client_Alt_SS;
USHORT Client_res8;
USHORT Client_Alt_ES;
USHORT Client_res9;
USHORT Client_Alt_DS;
USHORT Client_res10;
USHORT Client_Alt_FS;
USHORT Client_res11;
USHORT Client_Alt_GS;
USHORT Client_res12;
};
struct Client_Word_Reg_Struc {
USHORT Client_DI; /* Client's DI */
USHORT Client_res13; /* (padding) */
USHORT Client_SI; /* Client's SI */
USHORT Client_res14; /* (padding) */
USHORT Client_BP; /* Client's BP */
USHORT Client_res15; /* (padding) */
ULONG Client_res16; /* ESP at pushall */
USHORT Client_BX; /* Client's BX */
USHORT Client_res17; /* (padding) */
USHORT Client_DX; /* Client's DX */
USHORT Client_res18; /* (padding) */
USHORT Client_CX; /* Client's CX */
USHORT Client_res19; /* (padding) */
USHORT Client_AX; /* Client's AX */
USHORT Client_res20; /* (padding) */
ULONG Client_res21; /* Dword error code */
USHORT Client_IP; /* Client's IP */
USHORT Client_res22; /* (padding) */
ULONG Client_res23; /* CS */
USHORT Client_Flags; /* Client's flags (low) */
USHORT Client_res24; /* (padding) */
USHORT Client_SP; /* SP */
USHORT Client_res25;
ULONG Client_res26[5];
USHORT Client_Alt_IP;
USHORT Client_res27;
ULONG Client_res28;
USHORT Client_Alt_Flags;
USHORT Client_res29;
USHORT Client_Alt_SP;
};
struct Client_Byte_Reg_Struc {
ULONG Client_res30[4]; /* EDI, ESI, EBP, ESP at pushall */
UCHAR Client_BL; /* Client's BL */
UCHAR Client_BH; /* Client's BH */
USHORT Client_res31;
UCHAR Client_DL; /* Client's DL */
UCHAR Client_DH; /* Client's DH */
USHORT Client_res32;
UCHAR Client_CL; /* Client's CL */
UCHAR Client_CH; /* Client's CH */
USHORT Client_res33;
UCHAR Client_AL; /* Client's AL */
UCHAR Client_AH; /* Client's AH */
};
typedef union tagCLIENT_STRUC { /* */
struct Client_Reg_Struc CRS;
struct Client_Word_Reg_Struc CWRS;
struct Client_Byte_Reg_Struc CBRS;
} CLIENT_STRUCT;
typedef struct Client_Reg_Struc CRS;
typedef CRS *PCRS;
#if 0 /* causes problems with MASM 6 */
/* ASM
.ERRNZ Client_SP - Client_ESP
.ERRNZ Client_AL - Client_EAX
*/
#endif
#define DYNA_LINK_INT 0x20
/* ASM
;*** DeclareNonstandardCcallService
;
; Declare services as conforming to the C calling convention
; for parameter-passing, but *not* conforming to the C calling
; convention for register usage.
;
; Services which do not use the C calling convention for
; parameter-passing need not be declared as nonstandard.
;
; arglst - list of services to declare as nonstandard
;
DeclareNonstandardCcallService macro arglst
irp x,<arglst>
??_nonstandardccall_&&x = 1
endm
endm
;
; The following VMM services are nonstandard:
; _BlockOnID and _LocalizeSprintf modify no registers except flags.
; _SetLastV86Page modifies no registers except EAX and flags.
;
DeclareNonstandardCcallService <_BlockOnID, _LocalizeSprintf>
DeclareNonstandardCcallService <_SetLastV86Page>
BeginDoc
;******************************************************************************
; The VMMCall and VxDCall macros provide a dynamic link to the VMM and VxD
; service routines. For example:
;
; VMMCall Enable_VM_Ints ; Equivalent to STI in VM code
;
; mov eax,[My_IRQ_Handle]
; VxDCall VPICD_Set_Int_Request ; Set IRQ for my device's interrupt
;
; Note that Enable_VM_Ints is defined in VMM.INC and VPICD_Set_Int_Request is
; defined in VPICD.INC
;
;==============================================================================
EndDoc
BeginDoc
;******************************************************************************
; VxDCall
;==============================================================================
;
; BlockOnID is always FAST because it doesn't
; conform to the C calling convention. (It preserves
; all registers.)
EndDoc
DefTable MACRO vt, vn
vt EQU <vn>
ENDM
GenDD2 MACRO vt, sn, jf
dd OFFSET32 vt[sn+jf]
ENDM
GenDD MACRO P, vid, snum, jflag
LOCAL vtable
IFDEF @@VxDName&vid
Deftable vtable, %@@VxDName&vid
EXTRN vtable:DWORD
GenDD2 %vtable, snum, jflag
ELSE
dd @@&P+jflag
ENDIF
ENDM
VxDCall MACRO P, Param, flags
??_vxdid = (@@&P SHR 16)
??_servicenum = (@@&P AND 0FFFFh)
ifdef ??_standardccall_&P
PushCParams <Param>, <FAST>
.errnz ??_argc ne ??_standardccall_&P, <wrong # of parameters passed to &P&>
else
ifdef ??_fastcall_&P
PushCParams <Param>, <FASTCALL>
.errnz ??_argc ne (??_fastcall_&P), <wrong # of parameters passed to fastcall function &P&>
else
ifdef ??_nonstandardccall_&P
PushCParams <Param>, <flags>
else
PushCParams <Param>, <FAST>
endif
endif
endif
int Dyna_Link_Int
GenDD P, %??_vxdid, %??_servicenum, 0
ifndef ??_standardccall_&P
ifndef ??_fastcall_&P
ifdef ??_nonstandardccall_&P
ClearCParams PRESERVE_FLAGS
else
ClearCParams
endif
else
if(??_argc gt 2)
??_pushed = ??_pushed - ((??_argc - 2) * 4)
endif
endif
else
??_pushed = ??_pushed - (??_argc * 4)
endif
ENDM
VxDJmp MACRO P, Param
??_vxdid = (@@&P SHR 16)
??_servicenum = (@@&P AND 0FFFFh)
ifdef ??_fastcall_&P
PushCParams <Param>, <FASTCALL>
.errnz ??_argc gt 2, <More than 2 parameters may not be passed to fastcall functions thru VxDJmp>
else
.errnb <Param>, <Parameters may not be passed to VxDJmp or VMMJmp>
endif
int Dyna_Link_Int
GenDD P, %??_vxdid, %??_servicenum, DL_Jmp_Mask
ENDM
DL_Jmp_Mask EQU 8000h
DL_Jmp_Bit EQU 0Fh
VMMCall MACRO P, Param
.ERRNZ (@@&P SHR 16) - VMM_DEVICE_ID
VxDCall <P>, <Param>
ENDM
VMMJmp MACRO P, Param
.ERRNZ (@@&P SHR 16) - VMM_DEVICE_ID
VxDJmp <P>, <Param>
ENDM
WDMCall MACRO P, Param, flags
ifdef ??_standardccall_&P
PushCParams <Param>, <FAST>
.errnz ??_argc ne ??_standardccall_&P, <wrong # of parameters passed to &P&>
else
ifdef ??_fastcall_&P
PushCParams <Param>, <FASTCALL>
.errnz ??_argc ne (??_fastcall_&P), <wrong # of parameters passed to fastcall function &P&>
else
ifdef ??_nonstandardccall_&P
PushCParams <Param>, <flags>
else
PushCParams <Param>, <FAST>
endif
endif
endif
mov eax,WDM@@&P
int WDM_DynaLink_Int
nop
nop
nop
ifndef ??_standardccall_&P
ifndef ??_fastcall_&P
ifdef ??_nonstandardccall_&P
ClearCParams PRESERVE_FLAGS
else
ClearCParams
endif
else
if(??_argc gt 2)
??_pushed = ??_pushed - ((??_argc - 2) * 4)
endif
endif
else
??_pushed = ??_pushed - (??_argc * 4)
endif
ENDM
WDMJmp MACRO P, Param
ifdef ??_fastcall_&P
PushCParams <Param>, <FASTCALL>
.errnz ??_argc gt 2, <More than 2 parameters may not be passed to fastcall functions thru VxDJmp>
else
.errnb <Param>, <Parameters may not be passed to WDMJmp>
endif
mov eax, WDM@@&P+WDM_DL_Jmp_Mask
int WDM_DynaLink_Int
nop
nop
nop
ENDM
WDM_DL_Jmp_Mask EQU 80000000h
WDM_DL_Jmp_Bit EQU 31
BeginDoc
;******************************************************************************
; Segment definition macros
;
; The segment definition macros are a convenience used in defining the
; segments used by the device driver. They are:
;VxD_INIT_CODE_SEG defines start of initialization code segment
;VxD_INIT_CODE_ENDS defines end of initialization code segment
;VxD_ICODE_SEG is an alias for VxD_INIT_CODE_SEG
;VxD_ICODE_ENDS is an alias for VxD_INIT_CODE_ENDS
;VxD_IDATA_SEG defines start of initialization data segment
;VxD_IDATA_ENDS defines end of initialization data segment
;VxD_CODE_SEG defines start of always present code segment
;VxD_CODE_ENDS defines end of always present code segment
;VxD_DATA_SEG defines start of always present data segment
;VxD_DATA_ENDS defines end of always present data segment
;VxD_LOCKED_CODE_SEG defines start of always present code segment
;VxD_LOCKED_CODE_ENDS defines end of always present code segment
;VxD_PAGEABLE_CODE_SEG defines start of swappable code segment
;VxD_PAGEABLE_CODE_ENDS defines end of swappable code segment
;VxD_DEBUG_ONLY_CODE_SEG defines code only loaded if debugger is present
;VxD_DEBUG_ONLY_CODE_ENDS
;VxD_DEBUG_ONLY_DATA_SEG defines data only loaded if debugger is present
;VxD_DEBUG_ONLY_DATA_ENDS
;==============================================================================
EndDoc
; Resident protected mode code
VxD_CODE_SEG EQU <VxD_LOCKED_CODE_SEG>
VxD_CODE_ENDS EQU <VxD_LOCKED_CODE_ENDS>
VxD_LOCKED_CODE_SEG MACRO
_LTEXT SEGMENT
??_CUR_CODE_SEG = ??_CUR_CODE_SEG SHL 4 + ??_LCODE
ASSUME cs:FLAT, ds:FLAT, es:FLAT, ss:FLAT
ENDM
VxD_LOCKED_CODE_ENDS MACRO
??_CUR_CODE_SEG = ??_CUR_CODE_SEG SHR 4
_LTEXT ENDS
ENDM
; Pageable protected mode code
VxD_PAGEABLE_CODE_SEG MACRO
_PTEXT SEGMENT
??_CUR_CODE_SEG = ??_CUR_CODE_SEG SHL 4 + ??_PCODE
ASSUME cs:FLAT, ds:FLAT, es:FLAT, ss:FLAT
ENDM
VxD_PAGEABLE_CODE_ENDS MACRO
??_CUR_CODE_SEG = ??_CUR_CODE_SEG SHR 4
_PTEXT ENDS
ENDM
; Debug only protected mode code
VxD_DEBUG_ONLY_CODE_SEG MACRO
_DB1CODE SEGMENT
??_CUR_CODE_SEG = ??_CUR_CODE_SEG SHL 4 + ??_DBOCODE
ASSUME cs:FLAT, ds:FLAT, es:FLAT, ss:FLAT
ENDM
VxD_DEBUG_ONLY_CODE_ENDS MACRO
??_CUR_CODE_SEG = ??_CUR_CODE_SEG SHR 4
_DB1CODE ENDS
ENDM
; Protected mode initialization code
VxD_INIT_CODE_SEG MACRO
_ITEXT SEGMENT
??_CUR_CODE_SEG = ??_CUR_CODE_SEG SHL 4 + ??_ICODE
ASSUME cs:FLAT, ds:FLAT, es:FLAT, ss:FLAT
ENDM
VxD_INIT_CODE_ENDS MACRO
??_CUR_CODE_SEG = ??_CUR_CODE_SEG SHR 4
_ITEXT ENDS
ENDM
VxD_ICODE_SEG equ VxD_INIT_CODE_SEG
VxD_ICODE_ENDS equ VxD_INIT_CODE_ENDS
; Resident protected mode data
VxD_DATA_SEG EQU <VxD_LOCKED_DATA_SEG>
VxD_DATA_ENDS EQU <VxD_LOCKED_DATA_ENDS>
VxD_LOCKED_DATA_SEG MACRO NO_ALIGN
_LDATA SEGMENT
IFB <NO_ALIGN>
ALIGN 4
ENDIF
ENDM
VxD_LOCKED_DATA_ENDS MACRO
_LDATA ENDS
ENDM
; Protected mode initialization data
VxD_IDATA_SEG MACRO
_IDATA SEGMENT
ENDM
VxD_IDATA_ENDS MACRO
_IDATA ENDS
ENDM
; Pageable protected mode data
VxD_PAGEABLE_DATA_SEG MACRO NO_ALIGN
_PDATA SEGMENT
IFB <NO_ALIGN>
ALIGN 4
ENDIF
ENDM
VxD_PAGEABLE_DATA_ENDS MACRO
_PDATA ENDS
ENDM
; Static code segment for DL-VxDs
VxD_STATIC_CODE_SEG MACRO
_STEXT SEGMENT
??_CUR_CODE_SEG = ??_CUR_CODE_SEG SHL 4 + ??_SCODE
ASSUME cs:FLAT, ds:FLAT, es:FLAT, ss:FLAT
ENDM
VxD_STATIC_CODE_ENDS MACRO
??_CUR_CODE_SEG = ??_CUR_CODE_SEG SHR 4
_STEXT ENDS
ENDM
; Static data segment for DL-VxDs
VxD_STATIC_DATA_SEG MACRO NO_ALIGN
_SDATA SEGMENT
IFB <NO_ALIGN>
ALIGN 4
ENDIF
ENDM
VxD_STATIC_DATA_ENDS MACRO
_SDATA ENDS
ENDM
; Debug only protected mode data
VxD_DEBUG_ONLY_DATA_SEG MACRO NO_ALIGN
_DB2DATA SEGMENT
IFB <NO_ALIGN>
ALIGN 4
ENDIF
ENDM
VxD_DEBUG_ONLY_DATA_ENDS MACRO
_DB2DATA ENDS
ENDM
; 16 bit code/data put in the init group (IGROUP)
VxD_16BIT_INIT_SEG MACRO
_16ICODE SEGMENT
ASSUME CS:_16ICODE, DS:NOTHING, ES:NOTHING, SS:NOTHING
??_CUR_CODE_SEG = ??_CUR_CODE_SEG SHL 4 + ??_16ICODE
ENDM
VxD_16BIT_INIT_ENDS MACRO
??_CUR_CODE_SEG = ??_CUR_CODE_SEG SHR 4
_16ICODE ENDS
ENDM
; Real mode segment (16 bit)
VxD_REAL_INIT_SEG MACRO
_RCODE SEGMENT
ASSUME CS:_RCODE, DS:_RCODE, ES:_RCODE, SS:_RCODE
??_CUR_CODE_SEG = ??_CUR_CODE_SEG SHL 4 + ??_RCODE
ENDM
VxD_REAL_INIT_ENDS MACRO
??_CUR_CODE_SEG = ??_CUR_CODE_SEG SHR 4
_RCODE ENDS
ENDM
*/
#endif // Not_VxD
#ifndef DDK_VERSION
#ifdef WIN31COMPAT
#define DDK_VERSION 0x30A /* 3.10 */
#else // WIN31COMPAT
#ifdef WIN40COMPAT
#define DDK_VERSION 0x400 /* 4.00 */
#else // WIN40COMPAT
#ifdef WIN41COMPAT
#define DDK_VERSION 0x40A /*Memphis is 4.1 */
#else // WIN41COMPAT
#define DDK_VERSION 0x45A /*Millennium is 4.90 */
#endif // WIN41COMPAT
#endif // WIN40COMPAT
#endif // WIN31COMPAT
#endif // DDK_VERSION
struct VxD_Desc_Block {
ULONG DDB_Next; /* VMM RESERVED FIELD */
USHORT DDB_SDK_Version; /* INIT <DDK_VERSION> RESERVED FIELD */
USHORT DDB_Req_Device_Number; /* INIT <UNDEFINED_DEVICE_ID> */
UCHAR DDB_Dev_Major_Version; /* INIT <DDK_VERSION SHR 8> Major device number */
UCHAR DDB_Dev_Minor_Version; /* INIT <DDK_VERSION AND 0FFh> Minor device number */
USHORT DDB_Flags; /* INIT <0> for init calls complete */
UCHAR DDB_Name[8]; /* AINIT <" "> Device name */
ULONG DDB_Init_Order; /* INIT <UNDEFINED_INIT_ORDER> */
ULONG DDB_Control_Proc; /* Offset of control procedure */
ULONG DDB_V86_API_Proc; /* INIT <0> Offset of API procedure */
ULONG DDB_PM_API_Proc; /* INIT <0> Offset of API procedure */
ULONG DDB_V86_API_CSIP; /* INIT <0> CS:IP of API entry point */
ULONG DDB_PM_API_CSIP; /* INIT <0> CS:IP of API entry point */
ULONG DDB_Reference_Data; /* Reference data from real mode */
ULONG DDB_Service_Table_Ptr; /* INIT <0> Pointer to service table */
ULONG DDB_Service_Table_Size; /* INIT <0> Number of services */
ULONG DDB_Win32_Service_Table; /* INIT <0> Pointer to Win32 services */
ULONG DDB_Prev; /* INIT <'Prev'> Ptr to prev 4.0 DDB */
ULONG DDB_Size; /* INIT <SIZE(VxD_Desc_Block)> Reserved */
ULONG DDB_Reserved1; /* INIT <'Rsv1'> Reserved */
ULONG DDB_Reserved2; /* INIT <'Rsv2'> Reserved */
ULONG DDB_Reserved3; /* INIT <'Rsv3'> Reserved */
};
typedef struct VxD_Desc_Block *PVMMDDB;
typedef PVMMDDB *PPVMMDDB;
#ifndef Not_VxD
/* XLATOFF */
typedef (_cdecl * VXD_C_SERVICE)();
typedef VXD_C_SERVICE VXD_SERVICE_TABLE[];
#define Declare_Virtual_Device(quote_name, name, ctrl_proc, device_num, init_order, V86_proc, PM_proc, ref_data) \
struct VxD_Desc_Block name##_DDB={ \
0, \
DDK_VERSION, \
device_num, \
DDK_VERSION >> 8, \
DDK_VERSION & 0XFF, \
0, \
quote_name, \
init_order, \
(ULONG)ctrl_proc, \
(ULONG)V86_proc, \
(ULONG)PM_proc, \
0, \
0, \
ref_data, \
0, \
0, \
0, \
0, \
sizeof(struct VxD_Desc_Block), \
'Rsv1', \
'Rsv2', \
'Rsv3' \
};
#define Declare_Virtual_Device_With_Table(quote_name, name, ctrl_proc, device_num, init_order, V86_proc, PM_proc, ref_data, table_ptr) \
struct VxD_Desc_Block name##_DDB={ \
0, \
DDK_VERSION, \
device_num, \
DDK_VERSION >> 8, \
DDK_VERSION & 0XFF, \
0, \
quote_name, \
init_order, \
(ULONG)ctrl_proc, \
(ULONG)V86_proc, \
(ULONG)PM_proc, \
0, \
0, \
ref_data, \
(ULONG)table_ptr, \
(ULONG)(sizeof(table_ptr)/sizeof(VXD_C_SERVICE)), \
0, \
0, \
sizeof(struct VxD_Desc_Block), \
'Rsv1', \
'Rsv2', \
'Rsv3' \
};
/* XLATON */
/*
* Flag values for DDB_Flags
*/
#define DDB_SYS_CRIT_INIT_DONE_BIT 0
#define DDB_SYS_CRIT_INIT_DONE (1 << DDB_SYS_CRIT_INIT_DONE_BIT)
#define DDB_DEVICE_INIT_DONE_BIT 1
#define DDB_DEVICE_INIT_DONE (1 << DDB_DEVICE_INIT_DONE_BIT)
#define DDB_HAS_WIN32_SVCS_BIT 14
#define DDB_HAS_WIN32_SVCS (1 << DDB_HAS_WIN32_SVCS_BIT)
#define DDB_DYNAMIC_VXD_BIT 15
#define DDB_DYNAMIC_VXD (1 << DDB_DYNAMIC_VXD_BIT)
#define DDB_DEVICE_DYNALINKED_BIT 13
#define DDB_DEVICE_DYNALINKED (1 << DDB_DEVICE_DYNALINKED_BIT)
/* ASM
BeginDoc
;******************************************************************************
;
; Declare_Virtual_Device macro
;
; ???? Write something here ????
;
;==============================================================================
EndDoc
Declare_Virtual_Device MACRO Name, Major_Ver, Minor_Ver, Ctrl_Proc, Device_Num, Init_Order, V86_Proc, PM_Proc, Reference_Data
LOCAL V86_API_Offset, PM_API_Offset, Serv_Tab_Offset, Serv_Tab_Len, Ref_Data_Offset
dev_id_err MACRO
IFNDEF Name&_Name_Based
.err <Device ID required when providing services>
ENDIF
ENDM
IFB <V86_Proc>
V86_API_Offset EQU 0
ELSE
IFB <Device_Num>
dev_id_err
ENDIF
V86_API_Offset EQU <OFFSET32 V86_Proc>
ENDIF
IFB <PM_Proc>
PM_API_Offset EQU 0
ELSE
IFB <Device_Num>
dev_id_err
ENDIF
PM_API_Offset EQU <OFFSET32 PM_Proc>
ENDIF
IFDEF Name&_Service_Table
IFB <Device_Num>
dev_id_err
ELSE
IFE Device_Num - UNDEFINED_DEVICE_ID
dev_id_err
ENDIF
ENDIF
Serv_Tab_Offset EQU <OFFSET32 Name&_Service_Table>
Serv_Tab_Len EQU Num_&Name&_Services
ELSE
Serv_Tab_Offset EQU 0
Serv_Tab_Len EQU 0
ENDIF
IFNB <Device_Num>
.erre (Device_Num LT BASEID_FOR_NAMEBASEDVXD), <Device ID must be less than BASEID_FOR_NAMEBASEDVXD>
ENDIF
IFB <Reference_Data>
Ref_Data_Offset EQU 0
ELSE
Ref_Data_Offset EQU <OFFSET32 Reference_Data>
ENDIF
IFDEF DEBUG
VxD_IDATA_SEG
db 0dh, 0ah, 'D_E_B_U_G===>'
db "&Name", '<===', 0dh, 0ah
VxD_IDATA_ENDS
ENDIF
VxD_LOCKED_DATA_SEG
PUBLIC Name&_DDB
Name&_DDB VxD_Desc_Block <,,Device_Num,Major_Ver,Minor_Ver,,"&Name",Init_Order,\
OFFSET32 Ctrl_Proc, V86_API_Offset, PM_API_Offset, \
,,Ref_Data_Offset,Serv_Tab_Offset, Serv_Tab_Len>
VxD_LOCKED_DATA_ENDS
ENDM
;BeginDoc ; comment out to make masm work ???
;******************************************************************************
; The Begin_Control_Dispatch macro is used for building a table for dispatching
; messages passed to the VxD_Control procedure. It is used with
; Control_Dispatch and End_Control_Dispatch. The only parameter is used to
; contruct the procedure label by adding "_Control" to the end (normally the
; device name is used i.e. VKD results in creating the procedure VKD_Control,
; this created procedure label must be included in Declare_Virtual_Device)
;
; An example of building a complete dispatch table:
;
; Begin_Control_Dispatch MyDevice
; Control_Dispatch Device_Init, MyDeviceInitProcedure
; Control_Dispatch Sys_VM_Init, MyDeviceSysInitProcedure
; Control_Dispatch Create_VM, MyDeviceCreateVMProcedure
; End_Control_Dispatch MyDevice
;
; (NOTE: Control_Dispatch can be used without Begin_Control_Dispatch, but
; then it is the programmer's responsibility for declaring a procedure
; in locked code (VxD_LOCKED_CODE_SEG) and returning Carry clear for
; any messages not processed. The advantage in using
; Begin_Control_Dispatch is when a large # of messages are processed by
; a device, because a jump table is built which will usually require
; less code space then the compares and jumps that are done when
; Control_Dispatch is used alone.
;
;==============================================================================
;EndDoc
Begin_Control_Dispatch MACRO VxD_Name, p1, p2
??_cd_low = 0FFFFFFFFh
??_cd_high = 0
BeginProc VxD_Name&_Control, p1, p2, LOCKED
ENDM
End_Control_Dispatch MACRO VxD_Name
LOCAL ignore, table
procoff MACRO num
IFDEF ??_cd_&&num
dd OFFSET32 ??_cd_&&num
ELSE
dd OFFSET32 ignore
ENDIF
ENDM
IF ??_cd_low EQ ??_cd_high
cmp eax, ??_cd_low
?merge <jz>,,,,,<??_cd_>, %(??_cd_low)
clc
ret
ELSE
IF ??_cd_low GT 0
sub eax, ??_cd_low
ENDIF ; ??cd_low GT 0
cmp eax, ??_cd_high - ??_cd_low + 1
jae short ignore
jmp [eax*4+table]
ignore:
clc ;; this is not redundant
ret
table label dword
REPT ??_cd_high - ??_cd_low + 1
procoff %(??_cd_low)
??_cd_low = ??_cd_low + 1
ENDM
ENDIF
EndProc VxD_Name&_Control
PURGE procoff
PURGE Begin_Control_Dispatch
PURGE Control_Dispatch
PURGE End_Control_Dispatch
ENDM
BeginDoc
;******************************************************************************
; The Control_Dispatch macro is used for dispatching based on message
; passed to the VxD_Control procedure. E.G.:
;
; Control_Dispatch Device_Init, MyDeviceInitProcedure
;
; For "C" control functions:
;
; Control_Dispatch Device_Init, MyDeviceInitProcedure, sCall, <arglst>
;
; The "callc" can be sCall, cCall or pCall depending on the calling
; convention. "arglst" is the list of registers to pass as parameters
; to "C" control procedure. The "C" control procedure returns VXD_SUCCESS
; or VXD_FAILURE and the carry flag gets set appropriately.
;
; (NOTE: Control_Dispatch can be used with Begin_Control_Dispatch and
; End_Control_Dispatch to create a jump table for dispatching messages,
; when a large # of messages are processed.)
;
;==============================================================================
EndDoc
Control_Dispatch MACRO Service, Procedure, callc, arglst
LOCAL Skip_Interseg_Jump
.errnz ?_LCODE, <Control_Dispatch must be in VxD_LOCKED_CODE_SEG.>
IFB <callc>
IFDEF ??_cd_low
Equate_Service MACRO Serv
??_cd_&&Serv equ Procedure
ENDM
Equate_Service %(Service)
IF Service LT ??_cd_low
??_cd_low = Service
ENDIF
IF Service GT ??_cd_high
??_cd_high = Service
ENDIF
PURGE Equate_Service
ELSE
cmp eax, Service
jz Procedure
ENDIF
ELSE ; ifb callc
cmp eax, Service
jne SHORT Skip_Interseg_Jump
callc Procedure, <arglst>
IF Service EQ PNP_NEW_DEVNODE
stc
ELSE
cmp eax,1
ENDIF
ret
Skip_Interseg_Jump:
ENDIF ; ifb callc
ENDM
*/
/******************************************************************************
* The following are the definitions for the "type of I/O" parameter passed
* to a I/O trap routine.
*****************************************************************************/
#define BYTE_INPUT 0x000
#define BYTE_OUTPUT 0x004
#define WORD_INPUT 0x008
#define WORD_OUTPUT 0x00C
#define DWORD_INPUT 0x010
#define DWORD_OUTPUT 0x014
#define OUTPUT_BIT 2
#define OUTPUT (1 << OUTPUT_BIT)
#define WORD_IO_BIT 3
#define WORD_IO (1 << WORD_IO_BIT)
#define DWORD_IO_BIT 4
#define DWORD_IO (1 << DWORD_IO_BIT)
#define STRING_IO_BIT 5
#define STRING_IO (1 << STRING_IO_BIT)
#define REP_IO_BIT 6
#define REP_IO (1 << REP_IO_BIT)
#define ADDR_32_IO_BIT 7
#define ADDR_32_IO (1 << ADDR_32_IO_BIT)
#define REVERSE_IO_BIT 8
#define REVERSE_IO (1 << REVERSE_IO_BIT)
#define IO_SEG_MASK 0x0FFFF0000 /* Use this to get segment */
#define IO_SEG_SHIFT 0x10 /* Must shift right this many */
/* ASM
BeginDoc
;******************************************************************************
;
; Dispatch_Byte_IO macro
;
; Dispatch_Byte_IO Byte_In_Proc, Byte_Out_Proc
;==============================================================================
EndDoc
Dispatch_Byte_IO MACRO In_Proc, Out_Proc
LOCAL Byte_IO
cmp ecx, Byte_Output
jbe SHORT Byte_IO
VMMJmp Simulate_IO
Byte_IO:
IFIDNI <In_Proc>, <Fall_Through>
je Out_Proc
ELSE
IFIDNI <Out_Proc>, <Fall_Through>
jb In_Proc
ELSE
je Out_Proc
jmp In_Proc
ENDIF
ENDIF
ENDM
BeginDoc
;******************************************************************************
;
; Emulate_Non_Byte_IO
;
; Emulate_Non_Byte_IO
;
;==============================================================================
EndDoc
Emulate_Non_Byte_IO MACRO
LOCAL Byte_IO
cmp ecx, Byte_Output
jbe SHORT Byte_IO
VMMJmp Simulate_IO
Byte_IO:
ENDM
*/
/* ASM
BeginDoc
;******************************************************************************
;
; Begin_VxD_IO_Table
;
; Example:
; Begin_VxD_IO_Table MyTableName
;
;==============================================================================
EndDoc
*/
struct VxD_IOT_Hdr {
USHORT VxD_IO_Ports;
};
struct VxD_IO_Struc {
USHORT VxD_IO_Port;
ULONG VxD_IO_Proc;
};
/* ASM
.ERRNZ SIZE VxD_IOT_Hdr - 2 ; Begin_VxD_IO_Table creates a 1 word count hdr
Begin_VxD_IO_Table MACRO Table_Name
PUBLIC Table_Name
Table_Name LABEL WORD
ifndef MASM6
IF2
IFNDEF Table_Name&_Entries
.err <No End_VxD_IO_Table for &Table_Name>
ENDIF
dw Table_Name&_Entries
ELSE
dw ?
ENDIF
ELSE ; MASM6 - skip the warning message - we'll get it anyway
dw Table_Name&_Entries
ENDIF ; MASM6
ENDM
.ERRNZ SIZE VxD_IO_Struc - 6 ; VxD_IO creates 6 byte I/O port entries
VxD_IO MACRO Port, Proc_Name
dw Port
dd OFFSET32 Proc_Name
ENDM
End_VxD_IO_Table MACRO Table_Name
IFNDEF Table_Name
.err <No Begin_VxD_IO_Table for &Table_Name>
ELSE
Table_Name&_Entries EQU (($-Table_Name)-2) / (SIZE VxD_IO_Struc)
IF Table_Name&_Entries LE 0
.err <Invalid number of port traps in &Table_Name>
ENDIF
ENDIF
ENDM
;******************************************************************************
;
; Push_Client_State takes an optional argument which if equal to the symbol
; USES_EDI saves code size by suppressing the preservation of the EDI register.
;
; Similarly, Pop_Client_State takes an optional argument which if equal to
; the symbol USES_ESI saves code size by suppressing the preservation of
; the ESI register.
;
;******************************************************************************
Push_Client_State MACRO Can_Trash_EDI
sub esp, SIZE Client_Reg_Struc
??_pushed = ??_pushed + SIZE Client_Reg_Struc
ifidni <Can_Trash_EDI>, <USES_EDI>
mov edi, esp
VMMCall Save_Client_State
else
push edi
lea edi, [esp+4]
VMMCall Save_Client_State
pop edi
endif
ENDM
Pop_Client_State MACRO Can_Trash_ESI
ifdifi <Can_Trash_ESI>, <USES_ESI>
push esi
lea esi, [esp+4]
VMMCall Restore_Client_State
pop esi
else
mov esi, esp
VMMCall Restore_Client_State
endif
add esp, SIZE Client_Reg_Struc
??_pushed = ??_pushed - SIZE Client_Reg_Struc
ENDM
BeginDoc
;******************************************************************************
;
; CallRet -- Call procedure and return. For debugging purposes only.
; If compiled with debugging then this will generate a call
; followed by a return. If non-debugging version then the
; specified label will be jumped to.
;
; PARAMETERS:
; Label_Name = Procedure to be called
;
; EXIT:
; Return from current procedure
;
;------------------------------------------------------------------------------
EndDoc
CallRet MACRO P1, P2
IFDEF DEBUG
IFIDNI <P1>, <SHORT>
call P2
ELSE
call P1
ENDIF
ret
ELSE
jmp P1 P2
ENDIF
ENDM
BeginDoc
;******************************************************************************
;
; CallJmp -- Call procedure then jump to label. For debugging purposes only.
; If compiled with debugging then this will generate a call
; followed by a jmp. If non-debugging version then the desired return
; address will be pushed on the stack and the specified label will
; be jumped to.
;
; PARAMETERS:
; Function_Name = Procedure to be called
; Return_Label = Address to return to
;
; EXIT:
;
;------------------------------------------------------------------------------
EndDoc
CallJmp MACRO Function_Name, Return_Label
IFDEF DEBUG
call Function_Name
jmp Return_Label
ELSE
push Return_Label
jmp Function_Name
ENDIF
ENDM
BeginDoc
;******************************************************************************
;
; VxDCallRet
; VMMCallRet -- CallRet for VxDCall and VMMCall.
;
;------------------------------------------------------------------------------
EndDoc
IFDEF DEBUG
VxDCallRet macro p:req
VxDCall p
ret
endm
VMMCallRet macro p:req
VMMCall p
ret
endm
ELSE ; RETAIL
VxDCallRet equ <VxDJmp>
VMMCallRet equ <VMMJmp>
ENDIF
; ebp offsets to segments pushed by PMode_Fault in Fault_Dispatch
PClient_DS equ WORD PTR -4
PClient_ES equ WORD PTR -8
PClient_FS equ WORD PTR -12
PClient_GS equ WORD PTR -16
;******************************************************************************
;
; Client_Ptr_Flat takes an optional third argument which if equal to the
; symbol USES_EAX saves code size by supressing the preservation of the
; EAX register. The USES_EAX flag is ignored if the destination register
; is itself EAX.
;
;******************************************************************************
Client_Ptr_Flat MACRO Reg_32, Cli_Seg, Cli_Off, Can_Trash_EAX
IFDIFI <Reg_32>, <EAX>
IFDIFI <Can_Trash_EAX>, <USES_EAX>
xchg Reg_32, eax
ENDIF
ENDIF
IFB <Cli_Off>
mov ax, (Client_&Cli_Seg * 100h) + 0FFh
ELSE
mov ax, (Client_&Cli_Seg * 100h) + Client_&Cli_Off
ENDIF
VMMCall Map_Flat
IFDIFI <Reg_32>, <EAX>
xchg Reg_32, eax
ENDIF
ENDM
;------------------------------------------------------------------------------
VxDint MACRO Int_Number
if (OPATTR Int_Number) AND 4
push Int_Number
else
push DWORD PTR Int_Number
endif
VMMCall Exec_VxD_Int
ENDM
VxDintMustComplete MACRO Int_Number
if (OPATTR Int_Number) AND 4
push Int_Number
else
push DWORD PTR Int_Number
endif
VMMCall _ExecVxDIntMustComplete
ENDM
Load_FS macro
VMMCall Load_FS_Service
endm
*/
/*XLATOFF*/
#define Load_FS VMMCall(Load_FS_Service)
/*XLATON*/
#endif // Not_VxD
/******************************************************************************
*
* The following equates are for flags sent to the real mode
* initialization portion of a device driver:
*
*****************************************************************************/
#define DUPLICATE_DEVICE_ID_BIT 0 /* loaded */
#define DUPLICATE_DEVICE_ID (1 << DUPLICATE_DEVICE_ID_BIT)
#define DUPLICATE_FROM_INT2F_BIT 1 /* loaded from INT 2F list */
#define DUPLICATE_FROM_INT2F (1 << DUPLICATE_FROM_INT2F_BIT)
#define LOADING_FROM_INT2F_BIT 2 /* in the INT 2F device list */
#define LOADING_FROM_INT2F (1 << LOADING_FROM_INT2F_BIT)
/******************************************************************************
*
* The following equates are used to indicate the result of the real mode
* initialization portion of a device driver:
*
*****************************************************************************/
#define DEVICE_LOAD_OK 0 /* load protected mode portion */
#define ABORT_DEVICE_LOAD 1 /* don't load protected mode portion */
#define ABORT_WIN386_LOAD 2 /* fatal-error: abort load of Win386 */
#define DEVICE_NOT_NEEDED 3 /* don't load protected mode portion */
/* b/c the driver's presence is not needed */
#define NO_FAIL_MESSAGE_BIT 15 /* set bit to suppress error message */
#define NO_FAIL_MESSAGE (1 << NO_FAIL_MESSAGE_BIT)
/******************************************************************************
*
* The following equates define the loader services available to the real-mode
* initialization portion of a device driver:
*
*****************************************************************************/
#define LDRSRV_GET_PROFILE_STRING 0 /* search SYSTEM.INI for string */
#define LDRSRV_GET_NEXT_PROFILE_STRING 1 /* search for next string */
#define LDRSRV_RESERVED 2 /* RESERVED */
#define LDRSRV_GET_PROFILE_BOOLEAN 3 /* search SYSTEM.INI for boolean */
#define LDRSRV_GET_PROFILE_DECIMAL_INT 4 /* search SYSTEM.INI for integer */
#define LDRSRV_GET_PROFILE_HEX_INT 5 /* search SYSTEM.INI for hex int */
#define LDRSRV_COPY_EXTENDED_MEMORY 6 /* allocate/init extended memory */
#define LDRSRV_GET_MEMORY_INFO 7 /* get info about machine memory */
/* Add the new loader services contiguously here */
/****** Registry services for Real mode init time *************
* The parameters for these are as defined in Windows.h for the
* corresponding Win Reg API and should be on Stack. These are
* C Callable except that the function no has to be in AX
* ************************************************************
*/
#define LDRSRV_RegOpenKey 0x100
#define LDRSRV_RegCreateKey 0x101
#define LDRSRV_RegCloseKey 0x102
#define LDRSRV_RegDeleteKey 0x103
#define LDRSRV_RegSetValue 0x104
#define LDRSRV_RegQueryValue 0x105
#define LDRSRV_RegEnumKey 0x106
#define LDRSRV_RegDeleteValue 0x107
#define LDRSRV_RegEnumValue 0x108
#define LDRSRV_RegQueryValueEx 0x109
#define LDRSRV_RegSetValueEx 0x10A
#define LDRSRV_RegFlushKey 0x10B
/*
* For the Copy_Extended_Memory service, the following types of memory can be
* requested:
*/
#define LDRSRV_COPY_INIT 1 /* memory discarded after init */
#define LDRSRV_COPY_LOCKED 2 /* locked memory */
#define LDRSRV_COPY_PAGEABLE 3 /* pageable memory */
/****************************************************************************
*
* Object types supported by the vxd loader
*
* Notes : Low bit of all CODE type objects should be set (VXDLDR uses this)
* Also Init type objects should be added to the second part of the
* list (which starts with ICODE_OBJ).
*
*****************************************************************************/
#define RCODE_OBJ -1
#define LCODE_OBJ 0x01
#define LDATA_OBJ 0x02
#define PCODE_OBJ 0x03
#define PDATA_OBJ 0x04
#define SCODE_OBJ 0x05
#define SDATA_OBJ 0x06
#define CODE16_OBJ 0x07
#define LMSG_OBJ 0x08
#define PMSG_OBJ 0x09
#define DBOC_OBJ 0x0B
#define DBOD_OBJ 0x0C
#define PLCODE_OBJ 0x0D
#define PPCODE_OBJ 0x0F
#define ICODE_OBJ 0x11
#define IDATA_OBJ 0x12
#define ICODE16_OBJ 0x13
#define IMSG_OBJ 0x14
struct ObjectLocation {
ULONG OL_LinearAddr ;
ULONG OL_Size ;
UCHAR OL_ObjType ;
} ;
#define MAXOBJECTS 25
/*****************************************************************************
*
* Device_Location structure
*
*****************************************************************************/
struct Device_Location_List {
ULONG DLL_DDB ;
UCHAR DLL_NumObjects ;
struct ObjectLocation DLL_ObjLocation[1];
};
/* ========================================================================= */
/*
* CR0 bit assignments
*/
#define PE_BIT 0 /* 1 = Protected Mode */
#define PE_MASK (1 << PE_BIT)
#define MP_BIT 1 /* 1 = Monitor Coprocessor */
#define MP_MASK (1 << MP_BIT)
#define EM_BIT 2 /* 1 = Emulate Math Coprocessor */
#define EM_MASK (1 << EM_BIT)
#define TS_BIT 3 /* 1 = Task Switch occured */
#define TS_MASK (1 << TS_BIT)
#define ET_BIT 4 /* 1 = 387 present, 0 = 287 present */
#define ET_MASK (1 << ET_BIT)
#define PG_BIT 31 /* 1 = paging enabled, 0 = paging disabled */
#define PG_MASK (1 << PG_BIT)
/*
* EFLAGs bit assignments
*/
#define CF_BIT 0
#define CF_MASK (1 << CF_BIT)
#define PF_BIT 2
#define PF_MASK (1 << PF_BIT)
#define AF_BIT 4
#define AF_MASK (1 << AF_BIT)
#define ZF_BIT 6
#define ZF_MASK (1 << ZF_BIT)
#define SF_BIT 7
#define SF_MASK (1 << SF_BIT)
#define TF_BIT 8
#define TF_MASK (1 << TF_BIT)
#define IF_BIT 9
#define IF_MASK (1 << IF_BIT)
#define DF_BIT 10
#define DF_MASK (1 << DF_BIT)
#define OF_BIT 11 /* Overflow flag */
#define OF_MASK (1 << OF_BIT)
#define IOPL_MASK 0x3000 /* IOPL flags */
#define IOPL_BIT0 12
#define IOPL_BIT1 13
#define NT_BIT 14 /* Nested task flag */
#define NT_MASK (1 << NT_BIT)
#define RF_BIT 16 /* Resume flag */
#define RF_MASK (1 << RF_BIT)
#define VM_BIT 17 /* Virtual Mode flag */
#define VM_MASK (1 << VM_BIT)
#define AC_BIT 18 /* Alignment check */
#define AC_MASK (1 << AC_BIT)
#define VIF_BIT 19 /* Virtual Interrupt flag */
#define VIF_MASK (1 << VIF_BIT)
#define VIP_BIT 20 /* Virtual Interrupt pending */
#define VIP_MASK (1 << VIP_BIT)
/* ASM
;------------------------------------------------------------------------------
;
; Temporary MASM macros (to be removed when supported by MASM)
;
;------------------------------------------------------------------------------
IFDEF MASM6
loopde EQU <looped>
loopdne EQU <loopned>
loopdz EQU <loopzd>
loopdnz EQU <loopnzd>
ELSE
loopd EQU <loop>
loopde EQU <loope>
loopdne EQU <loopne>
loopdz EQU <loopz>
loopdnz EQU <loopnz>
ENDIF
*/
/******************************************************************************
* PAGE TABLE EQUATES
*****************************************************************************/
#define P_SIZE 0x1000 /* page size */
/******************************************************************************
*
* PAGE TABLE ENTRY BITS
*
*****************************************************************************/
#define P_PRESBIT 0
#define P_PRES (1 << P_PRESBIT)
#define P_WRITEBIT 1
#define P_WRITE (1 << P_WRITEBIT)
#define P_USERBIT 2
#define P_USER (1 << P_USERBIT)
#define P_ACCBIT 5
#define P_ACC (1 << P_ACCBIT)
#define P_DIRTYBIT 6
#define P_DIRTY (1 << P_DIRTYBIT)
#define P_AVAIL (P_PRES+P_WRITE+P_USER) /* avail to user & present */
/****************************************************
*
* Page types for page allocator calls
*
***************************************************/
#define PG_VM 0
#define PG_SYS 1
#define PG_RESERVED1 2
#define PG_PRIVATE 3
#define PG_RESERVED2 4
#define PG_RELOCK 5 /* PRIVATE to MMGR */
#define PG_INSTANCE 6
#define PG_HOOKED 7
#define PG_IGNORE 0xFFFFFFFF
/****************************************************
*
* Definitions for the access byte in a descriptor
*
***************************************************/
/*
* Following fields are common to segment and control descriptors
*/
#define D_PRES 0x080 /* present in memory */
#define D_NOTPRES 0 /* not present in memory */
#define D_DPL0 0 /* Ring 0 */
#define D_DPL1 0x020 /* Ring 1 */
#define D_DPL2 0x040 /* Ring 2 */
#define D_DPL3 0x060 /* Ring 3 */
#define D_SEG 0x010 /* Segment descriptor */
#define D_CTRL 0 /* Control descriptor */
#define D_GRAN_BYTE 0x000 /* Segment length is byte granular */
#define D_GRAN_PAGE 0x080 /* Segment length is page granular */
#define D_DEF16 0x000 /* Default operation size is 16 bits */
#define D_DEF32 0x040 /* Default operation size is 32 bits */
/*
* Following fields are specific to segment descriptors
*/
#define D_CODE 0x08 /* code */
#define D_DATA 0 /* data */
#define D_X 0 /* if code, exec only */
#define D_RX 0x02 /* if code, readable */
#define D_C 0x04 /* if code, conforming */
#define D_R 0 /* if data, read only */
#define D_W 0x02 /* if data, writable */
#define D_ED 0x04 /* if data, expand down */
#define D_ACCESSED 1 /* segment accessed bit */
/*
* Useful combination access rights bytes
*/
#define RW_DATA_TYPE (D_PRES+D_SEG+D_DATA+D_W)
#define R_DATA_TYPE (D_PRES+D_SEG+D_DATA+D_R)
#define CODE_TYPE (D_PRES+D_SEG+D_CODE+D_RX)
#define D_PAGE32 (D_GRAN_PAGE+D_DEF32) /* 32 bit Page granular */
/*
* Masks for selector fields
*/
#define SELECTOR_MASK 0xFFF8 /* selector index */
#define SEL_LOW_MASK 0xF8 /* mask for low byte of sel indx */
#define TABLE_MASK 0x04 /* table bit */
#ifndef WOW32_EXTENSIONS
#define RPL_MASK 0x03 /* privilige bits */
#define RPL_CLR (~RPL_MASK) /* clear ring bits */
#endif // ndef WOW32_EXTENSIONS
#define IVT_ROM_DATA_SIZE 0x500
/*XLATOFF*/
#ifndef Not_VxD
#define ENABLE_INTERRUPTS() {__asm sti}
#define DISABLE_INTERRUPTS() {__asm cli}
#define SAVE_FLAGS(flags) {\
_asm pushfd \
_asm pop flags \
}
#define RESTORE_FLAGS(flags) {\
_asm push flags \
_asm popfd \
}
#define IO_Delay() {\
_asm _emit 0xeb \
_asm _emit 0x00 \
}
#define Touch_Register(Register) {_asm xor Register, Register}
typedef DWORD HEVENT;
#define VMM_GET_DDB_NAMED 0
#pragma warning (disable:4209) // turn off redefine warning (with basedef.h)
typedef ULONG HTIMEOUT; // timeout handle
typedef ULONG CMS; // count of milliseconds
#pragma warning (default:4209) // turn on redefine warning (with basedef.h)
typedef DWORD VMM_SEMAPHORE;
typedef struct _HEAP_ALLOCATE_INFO {
DWORD StructSize;
PVOID CallerAddress;
ULONG Tag;
} HEAP_ALLOCATE_INFO, *PHEAP_ALLOCATE_INFO;
PVOID
_stdcall
HeapAllocateEx(
ULONG cBytes,
PVOID Reserved,
PHEAP_ALLOCATE_INFO AllocateInfo,
ULONG Flags
);
VOID
_stdcall
HeapFreeEx(
PVOID MemBlk,
PVOID Reserved
);
#ifndef WANTVXDWRAPS
WORD VXDINLINE
Get_VMM_Version()
{
WORD w;
VMMCall(Get_VMM_Version);
_asm mov [w], ax
return(w);
}
PVOID VXDINLINE
_HeapAllocate(ULONG Bytes, ULONG Flags)
{
PVOID p;
Touch_Register(eax)
Touch_Register(ecx)
Touch_Register(edx)
_asm push [Flags]
_asm push [Bytes]
VMMCall(_HeapAllocate)
_asm add esp, 8
_asm mov [p], eax
return(p);
}
ULONG VXDINLINE
_HeapFree(PVOID Address, ULONG Flags)
{
ULONG ul;
Touch_Register(eax)
Touch_Register(ecx)
Touch_Register(edx)
_asm push [Flags]
_asm push [Address]
VMMCall(_HeapFree)
_asm add esp, 8
_asm mov [ul], eax
return(ul);
}
HEVENT VXDINLINE
Call_Global_Event(void (__cdecl *pfnEvent)(), ULONG ulRefData)
{
HEVENT hevent;
_asm mov edx, [ulRefData]
_asm mov esi, [pfnEvent]
VMMCall(Call_Global_Event)
_asm mov [hevent], esi
return(hevent);
}
HEVENT VXDINLINE
Schedule_Global_Event(void (__cdecl *pfnEvent)(), ULONG ulRefData)
{
HEVENT hevent;
_asm mov edx, [ulRefData]
_asm mov esi, [pfnEvent]
VMMCall(Schedule_Global_Event)
_asm mov [hevent], esi
return(hevent);
}
void VXDINLINE
Cancel_Global_Event( HEVENT hevent )
{
_asm mov esi, hevent
VMMCall( Cancel_Global_Event );
}
HVM VXDINLINE
Get_Sys_VM_Handle(VOID)
{
HVM hvm;
Touch_Register(ebx)
VxDCall(Get_Sys_VM_Handle);
_asm mov [hvm], ebx
return(hvm);
}
VOID VXDINLINE
Fatal_Error_Handler(PCHAR pszMessage, DWORD dwExitFlag)
{
_asm mov esi, [pszMessage]
_asm mov eax, [dwExitFlag]
VMMCall(Fatal_Error_Handler);
}
VMM_SEMAPHORE VXDINLINE
Create_Semaphore(LONG lTokenCount)
{
VMM_SEMAPHORE vmm_semaphore;
_asm mov ecx, [lTokenCount]
VMMCall(Create_Semaphore)
_asm cmc
_asm sbb ecx, ecx
_asm and eax, ecx
_asm mov [vmm_semaphore], eax
return(vmm_semaphore);
}
void VXDINLINE
Destroy_Semaphore(VMM_SEMAPHORE vsSemaphore)
{
_asm mov eax, [vsSemaphore]
VMMCall(Destroy_Semaphore)
}
void VXDINLINE
Signal_Semaphore(VMM_SEMAPHORE vsSemaphore)
{
_asm mov eax, [vsSemaphore]
VMMCall(Signal_Semaphore)
}
void VXDINLINE
Wait_Semaphore(VMM_SEMAPHORE vsSemaphore, DWORD dwFlags)
{
_asm mov eax, [vsSemaphore]
_asm mov ecx, [dwFlags]
VMMCall(Wait_Semaphore)
}
HVM VXDINLINE
Get_Execution_Focus(void)
{
HVM hvm;
Touch_Register(ebx)
VMMCall(Get_Execution_Focus)
_asm mov [hvm], ebx
return(hvm);
}
void VXDINLINE
Begin_Critical_Section(ULONG Flags)
{
_asm mov ecx, [Flags]
VMMCall(Begin_Critical_Section)
}
void VXDINLINE
End_Critical_Section(void)
{
VMMCall(End_Critical_Section)
}
void VXDINLINE
Fatal_Memory_Handler(void)
{
VMMCall(Fatal_Memory_Error);
}
void VXDINLINE
Begin_Nest_Exec(void)
{
VMMCall(Begin_Nest_Exec)
}
void VXDINLINE
End_Nest_Exec(void)
{
VMMCall(End_Nest_Exec)
}
void VXDINLINE
Resume_Exec(void)
{
VMMCall(Resume_Exec)
}
HTIMEOUT VXDINLINE
Set_VM_Time_Out(void (*pfnTimeout)(), CMS cms, ULONG ulRefData)
{
HTIMEOUT htimeout;
_asm mov eax, [cms]
_asm mov edx, [ulRefData]
_asm mov esi, [pfnTimeout]
VMMCall(Set_VM_Time_Out)
_asm mov [htimeout], esi
return(htimeout);
}
HTIMEOUT VXDINLINE
Set_Global_Time_Out(void (__cdecl *pfnTimeout)(), CMS cms, ULONG ulRefData)
{
HTIMEOUT htimeout;
_asm mov eax, [cms]
_asm mov edx, [ulRefData]
_asm mov esi, [pfnTimeout]
VMMCall(Set_Global_Time_Out)
_asm mov [htimeout], esi
return(htimeout);
}
void VXDINLINE
Cancel_Time_Out(HTIMEOUT htimeout)
{
_asm mov esi, htimeout
VMMCall(Cancel_Time_Out)
}
void VXDINLINE
Update_System_Clock(ULONG msElapsed)
{
__asm mov ecx,[msElapsed]
VMMCall(Update_System_Clock)
}
void VXDINLINE
Enable_Touch_1st_Meg(void)
{
VMMCall(Enable_Touch_1st_Meg)
}
void VXDINLINE
Disable_Touch_1st_Meg(void)
{
VMMCall(Disable_Touch_1st_Meg)
}
void VXDINLINE
Out_Debug_String(char *psz)
{
__asm pushad
__asm mov esi, [psz]
VMMCall(Out_Debug_String)
__asm popad
}
void VXDINLINE
Queue_Debug_String(char *psz, ULONG ulEAX, ULONG ulEBX)
{
_asm push esi
_asm push [ulEAX]
_asm push [ulEBX]
_asm mov esi, [psz]
VMMCall(Queue_Debug_String)
_asm pop esi
}
#ifdef WIN40SERVICES
HTIMEOUT VXDINLINE
Set_Async_Time_Out(void (*pfnTimeout)(), CMS cms, ULONG ulRefData)
{
HTIMEOUT htimeout;
_asm mov eax, [cms]
_asm mov edx, [ulRefData]
_asm mov esi, [pfnTimeout]
VMMCall(Set_Async_Time_Out)
_asm mov [htimeout], esi
return(htimeout);
}
VXDINLINE struct VxD_Desc_Block *
VMM_Get_DDB(WORD DeviceID, PCHAR Name)
{
struct VxD_Desc_Block *p;
_asm movzx eax, [DeviceID]
_asm mov edi, [Name]
VMMCall(Get_DDB);
_asm mov [p], ecx
return(p);
}
DWORD VXDINLINE
VMM_Directed_Sys_Control(struct VxD_Desc_Block *DDB, DWORD SysControl, DWORD rEBX, DWORD rEDX, DWORD rESI, DWORD rEDI)
{
DWORD dw;
_asm mov eax, [SysControl]
_asm mov ebx, [rEBX]
_asm mov ecx, [DDB]
_asm mov edx, [rEDX]
_asm mov esi, [rESI]
_asm mov edi, [rEDI]
VMMCall(Directed_Sys_Control);
_asm mov [dw], eax
return(dw);
}
void VXDINLINE
_Trace_Out_Service(char *psz)
{
__asm push psz
VMMCall(_Trace_Out_Service)
}
void VXDINLINE
_Debug_Out_Service(char *psz)
{
__asm push psz
VMMCall(_Debug_Out_Service)
}
void VXDINLINE
_Debug_Flags_Service(ULONG flags)
{
__asm push flags
VMMCall(_Debug_Flags_Service)
}
void VXDINLINE _cdecl
_Debug_Printf_Service(char *pszfmt, ...)
{
__asm lea eax,(pszfmt + 4)
__asm push eax
__asm push pszfmt
VMMCall(_Debug_Printf_Service)
__asm add esp, 2*4
}
#endif // WIN40SERVICES
#endif // WANTVXDWRAPS
#endif // Not_VxD
/*XLATON*/
#endif /* _VMM_ */