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/*++
Copyright (c) 1989-2000 Microsoft Corporation
Module Name:
FatInit.c
Abstract:
This module implements the DRIVER_INITIALIZATION routine for Fat
// @@BEGIN_DDKSPLIT
Author:
Gary Kimura [GaryKi] 28-Dec-1989
Revision History:
// @@END_DDKSPLIT
--*/
#include "FatProcs.h"
NTSTATUSDriverEntry( IN PDRIVER_OBJECT DriverObject, IN PUNICODE_STRING RegistryPath );
VOIDFatUnload( IN PDRIVER_OBJECT DriverObject );
NTSTATUSFatGetCompatibilityModeValue( IN PUNICODE_STRING ValueName, IN OUT PULONG Value );
BOOLEANFatIsFujitsuFMR ( );
#ifdef ALLOC_PRAGMA
#pragma alloc_text(INIT, DriverEntry)
#pragma alloc_text(INIT, FatGetCompatibilityModeValue)
#pragma alloc_text(INIT, FatIsFujitsuFMR)
//#pragma alloc_text(PAGE, FatUnload)
#endif
#define COMPATIBILITY_MODE_KEY_NAME L"\\Registry\\Machine\\System\\CurrentControlSet\\Control\\FileSystem"
#define COMPATIBILITY_MODE_VALUE_NAME L"Win31FileSystem"
#define CODE_PAGE_INVARIANCE_VALUE_NAME L"FatDisableCodePageInvariance"
#define KEY_WORK_AREA ((sizeof(KEY_VALUE_FULL_INFORMATION) + \
sizeof(ULONG)) + 64)
#define REGISTRY_HARDWARE_DESCRIPTION_W \
L"\\Registry\\Machine\\Hardware\\DESCRIPTION\\System"
#define REGISTRY_MACHINE_IDENTIFIER_W L"Identifier"
#define FUJITSU_FMR_NAME_W L"FUJITSU FMR-"
�NTSTATUSDriverEntry( IN PDRIVER_OBJECT DriverObject, IN PUNICODE_STRING RegistryPath )
/*++
Routine Description:
This is the initialization routine for the Fat file system device driver. This routine creates the device object for the FileSystem device and performs all other driver initialization.
Arguments:
DriverObject - Pointer to driver object created by the system.
Return Value:
NTSTATUS - The function value is the final status from the initialization operation.
--*/
{ USHORT MaxDepth; NTSTATUS Status; UNICODE_STRING UnicodeString;
UNICODE_STRING ValueName; ULONG Value;
//
// Create the device object for disks. To avoid problems with filters who
// know this name, we must keep it.
//
RtlInitUnicodeString( &UnicodeString, L"\\Fat" ); Status = IoCreateDevice( DriverObject, 0, &UnicodeString, FILE_DEVICE_DISK_FILE_SYSTEM, 0, FALSE, &FatDiskFileSystemDeviceObject );
if (!NT_SUCCESS( Status )) { return Status; }
//
// Create the device object for "cdroms".
//
RtlInitUnicodeString( &UnicodeString, L"\\FatCdrom" ); Status = IoCreateDevice( DriverObject, 0, &UnicodeString, FILE_DEVICE_CD_ROM_FILE_SYSTEM, 0, FALSE, &FatCdromFileSystemDeviceObject );
if (!NT_SUCCESS( Status )) { IoDeleteDevice( FatDiskFileSystemDeviceObject); return Status; }
DriverObject->DriverUnload = FatUnload;
#ifdef _PNP_POWER_
//
// This driver doesn't talk directly to a device, and (at the moment)
// isn't otherwise concerned about power management.
//
FatDiskFileSystemDeviceObject->DeviceObjectExtension->PowerControlNeeded = FALSE; FatCdromFileSystemDeviceObject->DeviceObjectExtension->PowerControlNeeded = FALSE;#endif
//
// Note that because of the way data caching is done, we set neither
// the Direct I/O or Buffered I/O bit in DeviceObject->Flags. If
// data is not in the cache, or the request is not buffered, we may,
// set up for Direct I/O by hand.
//
//
// Initialize the driver object with this driver's entry points.
//
DriverObject->MajorFunction[IRP_MJ_CREATE] = (PDRIVER_DISPATCH)FatFsdCreate; DriverObject->MajorFunction[IRP_MJ_CLOSE] = (PDRIVER_DISPATCH)FatFsdClose; DriverObject->MajorFunction[IRP_MJ_READ] = (PDRIVER_DISPATCH)FatFsdRead; DriverObject->MajorFunction[IRP_MJ_WRITE] = (PDRIVER_DISPATCH)FatFsdWrite; DriverObject->MajorFunction[IRP_MJ_QUERY_INFORMATION] = (PDRIVER_DISPATCH)FatFsdQueryInformation; DriverObject->MajorFunction[IRP_MJ_SET_INFORMATION] = (PDRIVER_DISPATCH)FatFsdSetInformation; DriverObject->MajorFunction[IRP_MJ_QUERY_EA] = (PDRIVER_DISPATCH)FatFsdQueryEa; DriverObject->MajorFunction[IRP_MJ_SET_EA] = (PDRIVER_DISPATCH)FatFsdSetEa; DriverObject->MajorFunction[IRP_MJ_FLUSH_BUFFERS] = (PDRIVER_DISPATCH)FatFsdFlushBuffers; DriverObject->MajorFunction[IRP_MJ_QUERY_VOLUME_INFORMATION] = (PDRIVER_DISPATCH)FatFsdQueryVolumeInformation; DriverObject->MajorFunction[IRP_MJ_SET_VOLUME_INFORMATION] = (PDRIVER_DISPATCH)FatFsdSetVolumeInformation; DriverObject->MajorFunction[IRP_MJ_CLEANUP] = (PDRIVER_DISPATCH)FatFsdCleanup; DriverObject->MajorFunction[IRP_MJ_DIRECTORY_CONTROL] = (PDRIVER_DISPATCH)FatFsdDirectoryControl; DriverObject->MajorFunction[IRP_MJ_FILE_SYSTEM_CONTROL] = (PDRIVER_DISPATCH)FatFsdFileSystemControl; DriverObject->MajorFunction[IRP_MJ_LOCK_CONTROL] = (PDRIVER_DISPATCH)FatFsdLockControl; DriverObject->MajorFunction[IRP_MJ_DEVICE_CONTROL] = (PDRIVER_DISPATCH)FatFsdDeviceControl; DriverObject->MajorFunction[IRP_MJ_SHUTDOWN] = (PDRIVER_DISPATCH)FatFsdShutdown; DriverObject->MajorFunction[IRP_MJ_PNP] = (PDRIVER_DISPATCH)FatFsdPnp;
DriverObject->FastIoDispatch = &FatFastIoDispatch;
RtlZeroMemory(&FatFastIoDispatch, sizeof(FatFastIoDispatch));
FatFastIoDispatch.SizeOfFastIoDispatch = sizeof(FAST_IO_DISPATCH); FatFastIoDispatch.FastIoCheckIfPossible = FatFastIoCheckIfPossible; // CheckForFastIo
FatFastIoDispatch.FastIoRead = FsRtlCopyRead; // Read
FatFastIoDispatch.FastIoWrite = FsRtlCopyWrite; // Write
FatFastIoDispatch.FastIoQueryBasicInfo = FatFastQueryBasicInfo; // QueryBasicInfo
FatFastIoDispatch.FastIoQueryStandardInfo = FatFastQueryStdInfo; // QueryStandardInfo
FatFastIoDispatch.FastIoLock = FatFastLock; // Lock
FatFastIoDispatch.FastIoUnlockSingle = FatFastUnlockSingle; // UnlockSingle
FatFastIoDispatch.FastIoUnlockAll = FatFastUnlockAll; // UnlockAll
FatFastIoDispatch.FastIoUnlockAllByKey = FatFastUnlockAllByKey; // UnlockAllByKey
FatFastIoDispatch.FastIoQueryNetworkOpenInfo = FatFastQueryNetworkOpenInfo; FatFastIoDispatch.AcquireForCcFlush = FatAcquireForCcFlush; FatFastIoDispatch.ReleaseForCcFlush = FatReleaseForCcFlush; FatFastIoDispatch.MdlRead = FsRtlMdlReadDev; FatFastIoDispatch.MdlReadComplete = FsRtlMdlReadCompleteDev; FatFastIoDispatch.PrepareMdlWrite = FsRtlPrepareMdlWriteDev; FatFastIoDispatch.MdlWriteComplete = FsRtlMdlWriteCompleteDev; //
// Initialize the global data structures
//
//
// The FatData record
//
RtlZeroMemory( &FatData, sizeof(FAT_DATA));
FatData.NodeTypeCode = FAT_NTC_DATA_HEADER; FatData.NodeByteSize = sizeof(FAT_DATA);
InitializeListHead(&FatData.VcbQueue);
FatData.DriverObject = DriverObject; FatData.DiskFileSystemDeviceObject = FatDiskFileSystemDeviceObject; FatData.CdromFileSystemDeviceObject = FatCdromFileSystemDeviceObject;
//
// This list head keeps track of closes yet to be done.
//
InitializeListHead( &FatData.AsyncCloseList ); InitializeListHead( &FatData.DelayedCloseList );
FatData.FatCloseItem = IoAllocateWorkItem( FatDiskFileSystemDeviceObject);
if (FatData.FatCloseItem == NULL) { IoDeleteDevice (FatDiskFileSystemDeviceObject); IoDeleteDevice (FatCdromFileSystemDeviceObject); return STATUS_INSUFFICIENT_RESOURCES; }
//
// Now initialize our general purpose spinlock (gag) and figure out how
// deep and wide we want our delayed lists (along with fooling ourselves
// about the lookaside depths).
//
KeInitializeSpinLock( &FatData.GeneralSpinLock );
switch ( MmQuerySystemSize() ) {
case MmSmallSystem:
MaxDepth = 4; FatMaxDelayedCloseCount = FAT_MAX_DELAYED_CLOSES; break;
case MmMediumSystem:
MaxDepth = 8; FatMaxDelayedCloseCount = 4 * FAT_MAX_DELAYED_CLOSES; break;
case MmLargeSystem:
MaxDepth = 16; FatMaxDelayedCloseCount = 16 * FAT_MAX_DELAYED_CLOSES; break; }
//
// Initialize the cache manager callback routines
//
FatData.CacheManagerCallbacks.AcquireForLazyWrite = &FatAcquireFcbForLazyWrite; FatData.CacheManagerCallbacks.ReleaseFromLazyWrite = &FatReleaseFcbFromLazyWrite; FatData.CacheManagerCallbacks.AcquireForReadAhead = &FatAcquireFcbForReadAhead; FatData.CacheManagerCallbacks.ReleaseFromReadAhead = &FatReleaseFcbFromReadAhead;
FatData.CacheManagerNoOpCallbacks.AcquireForLazyWrite = &FatNoOpAcquire; FatData.CacheManagerNoOpCallbacks.ReleaseFromLazyWrite = &FatNoOpRelease; FatData.CacheManagerNoOpCallbacks.AcquireForReadAhead = &FatNoOpAcquire; FatData.CacheManagerNoOpCallbacks.ReleaseFromReadAhead = &FatNoOpRelease;
//
// Set up global pointer to our process.
//
FatData.OurProcess = PsGetCurrentProcess();
//
// Read the registry to determine if we are in ChicagoMode.
//
ValueName.Buffer = COMPATIBILITY_MODE_VALUE_NAME; ValueName.Length = sizeof(COMPATIBILITY_MODE_VALUE_NAME) - sizeof(WCHAR); ValueName.MaximumLength = sizeof(COMPATIBILITY_MODE_VALUE_NAME);
Status = FatGetCompatibilityModeValue( &ValueName, &Value );
if (NT_SUCCESS(Status) && FlagOn(Value, 1)) {
FatData.ChicagoMode = FALSE;
} else {
FatData.ChicagoMode = TRUE; }
//
// Read the registry to determine if we are going to generate LFNs
// for valid 8.3 names with extended characters.
//
ValueName.Buffer = CODE_PAGE_INVARIANCE_VALUE_NAME; ValueName.Length = sizeof(CODE_PAGE_INVARIANCE_VALUE_NAME) - sizeof(WCHAR); ValueName.MaximumLength = sizeof(CODE_PAGE_INVARIANCE_VALUE_NAME);
Status = FatGetCompatibilityModeValue( &ValueName, &Value );
if (NT_SUCCESS(Status) && FlagOn(Value, 1)) {
FatData.CodePageInvariant = FALSE;
} else {
FatData.CodePageInvariant = TRUE; }
//
// Initialize our global resource and fire up the lookaside lists.
//
ExInitializeResourceLite( &FatData.Resource );
ExInitializeNPagedLookasideList( &FatIrpContextLookasideList, NULL, NULL, POOL_RAISE_IF_ALLOCATION_FAILURE, sizeof(IRP_CONTEXT), TAG_IRP_CONTEXT, MaxDepth );
ExInitializeNPagedLookasideList( &FatNonPagedFcbLookasideList, NULL, NULL, POOL_RAISE_IF_ALLOCATION_FAILURE, sizeof(NON_PAGED_FCB), TAG_FCB_NONPAGED, MaxDepth );
ExInitializeNPagedLookasideList( &FatEResourceLookasideList, NULL, NULL, POOL_RAISE_IF_ALLOCATION_FAILURE, sizeof(ERESOURCE), TAG_ERESOURCE, MaxDepth );
ExInitializeSListHead( &FatCloseContextSList ); ExInitializeFastMutex( &FatCloseQueueMutex ); KeInitializeEvent( &FatReserveEvent, SynchronizationEvent, TRUE );
//
// Register the file system with the I/O system
//
IoRegisterFileSystem(FatDiskFileSystemDeviceObject); ObReferenceObject (FatDiskFileSystemDeviceObject); IoRegisterFileSystem(FatCdromFileSystemDeviceObject); ObReferenceObject (FatCdromFileSystemDeviceObject);
//
// Find out if we are running an a FujitsuFMR machine.
//
FatData.FujitsuFMR = FatIsFujitsuFMR();
//
// And return to our caller
//
return( STATUS_SUCCESS );}
�VOIDFatUnload( IN PDRIVER_OBJECT DriverObject )
/*++
Routine Description:
This is the unload routine for the filesystem
Arguments:
DriverObject - Pointer to driver object created by the system.
Return Value:
None
--*/
{ ExDeleteNPagedLookasideList (&FatEResourceLookasideList); ExDeleteNPagedLookasideList (&FatNonPagedFcbLookasideList); ExDeleteNPagedLookasideList (&FatIrpContextLookasideList); ExDeleteResourceLite( &FatData.Resource ); IoFreeWorkItem (FatData.FatCloseItem); ObDereferenceObject( FatDiskFileSystemDeviceObject); ObDereferenceObject( FatCdromFileSystemDeviceObject);}
�//
// Local Support routine
//
NTSTATUSFatGetCompatibilityModeValue ( IN PUNICODE_STRING ValueName, IN OUT PULONG Value )
/*++
Routine Description:
Given a unicode value name this routine will go into the registry location for the Chicago compatibilitymode information and get the value.
Arguments:
ValueName - the unicode name for the registry value located in the registry. Value - a pointer to the ULONG for the result.
Return Value:
NTSTATUS
If STATUS_SUCCESSFUL is returned, the location *Value will be updated with the DWORD value from the registry. If any failing status is returned, this value is untouched.
--*/
{ HANDLE Handle; NTSTATUS Status; ULONG RequestLength; ULONG ResultLength; UCHAR Buffer[KEY_WORK_AREA]; UNICODE_STRING KeyName; OBJECT_ATTRIBUTES ObjectAttributes; PKEY_VALUE_FULL_INFORMATION KeyValueInformation;
KeyName.Buffer = COMPATIBILITY_MODE_KEY_NAME; KeyName.Length = sizeof(COMPATIBILITY_MODE_KEY_NAME) - sizeof(WCHAR); KeyName.MaximumLength = sizeof(COMPATIBILITY_MODE_KEY_NAME);
InitializeObjectAttributes(&ObjectAttributes, &KeyName, OBJ_CASE_INSENSITIVE, NULL, NULL);
Status = ZwOpenKey(&Handle, KEY_READ, &ObjectAttributes);
if (!NT_SUCCESS(Status)) {
return Status; }
RequestLength = KEY_WORK_AREA;
KeyValueInformation = (PKEY_VALUE_FULL_INFORMATION)Buffer;
while (1) {
Status = ZwQueryValueKey(Handle, ValueName, KeyValueFullInformation, KeyValueInformation, RequestLength, &ResultLength);
ASSERT( Status != STATUS_BUFFER_OVERFLOW );
if (Status == STATUS_BUFFER_OVERFLOW) {
//
// Try to get a buffer big enough.
//
if (KeyValueInformation != (PKEY_VALUE_FULL_INFORMATION)Buffer) {
ExFreePool(KeyValueInformation); }
RequestLength += 256;
KeyValueInformation = (PKEY_VALUE_FULL_INFORMATION) ExAllocatePoolWithTag(PagedPool, RequestLength, ' taF');
if (!KeyValueInformation) { return STATUS_NO_MEMORY; }
} else {
break; } }
ZwClose(Handle);
if (NT_SUCCESS(Status)) {
if (KeyValueInformation->DataLength != 0) {
PULONG DataPtr;
//
// Return contents to the caller.
//
DataPtr = (PULONG) ((PUCHAR)KeyValueInformation + KeyValueInformation->DataOffset); *Value = *DataPtr;
} else {
//
// Treat as if no value was found
//
Status = STATUS_OBJECT_NAME_NOT_FOUND; } }
if (KeyValueInformation != (PKEY_VALUE_FULL_INFORMATION)Buffer) {
ExFreePool(KeyValueInformation); }
return Status;}�//
// Local Support routine
//
BOOLEANFatIsFujitsuFMR ( )
/*++
Routine Description:
This routine tells if is we running on a FujitsuFMR machine.
Arguments:
Return Value:
BOOLEAN - TRUE is we are and FALSE otherwise
--*/
{ ULONG Value; BOOLEAN Result; HANDLE Handle; NTSTATUS Status; ULONG RequestLength; ULONG ResultLength; UCHAR Buffer[KEY_WORK_AREA]; UNICODE_STRING KeyName; UNICODE_STRING ValueName; OBJECT_ATTRIBUTES ObjectAttributes; PKEY_VALUE_FULL_INFORMATION KeyValueInformation;
//
// Set default as PC/AT
//
KeyName.Buffer = REGISTRY_HARDWARE_DESCRIPTION_W; KeyName.Length = sizeof(REGISTRY_HARDWARE_DESCRIPTION_W) - sizeof(WCHAR); KeyName.MaximumLength = sizeof(REGISTRY_HARDWARE_DESCRIPTION_W);
InitializeObjectAttributes(&ObjectAttributes, &KeyName, OBJ_CASE_INSENSITIVE, NULL, NULL);
Status = ZwOpenKey(&Handle, KEY_READ, &ObjectAttributes);
if (!NT_SUCCESS(Status)) {
return FALSE; }
ValueName.Buffer = REGISTRY_MACHINE_IDENTIFIER_W; ValueName.Length = sizeof(REGISTRY_MACHINE_IDENTIFIER_W) - sizeof(WCHAR); ValueName.MaximumLength = sizeof(REGISTRY_MACHINE_IDENTIFIER_W);
RequestLength = KEY_WORK_AREA;
KeyValueInformation = (PKEY_VALUE_FULL_INFORMATION)Buffer;
while (1) {
Status = ZwQueryValueKey(Handle, &ValueName, KeyValueFullInformation, KeyValueInformation, RequestLength, &ResultLength);
// ASSERT( Status != STATUS_BUFFER_OVERFLOW );
if (Status == STATUS_BUFFER_OVERFLOW) {
//
// Try to get a buffer big enough.
//
if (KeyValueInformation != (PKEY_VALUE_FULL_INFORMATION)Buffer) {
ExFreePool(KeyValueInformation); }
RequestLength += 256;
KeyValueInformation = (PKEY_VALUE_FULL_INFORMATION) ExAllocatePool(PagedPool, RequestLength);
if (!KeyValueInformation) { return FALSE; }
} else {
break; } }
ZwClose(Handle);
if (NT_SUCCESS(Status) && (KeyValueInformation->DataLength >= sizeof(FUJITSU_FMR_NAME_W)) && (RtlCompareMemory((PUCHAR)KeyValueInformation + KeyValueInformation->DataOffset, FUJITSU_FMR_NAME_W, sizeof(FUJITSU_FMR_NAME_W) - sizeof(WCHAR)) == sizeof(FUJITSU_FMR_NAME_W) - sizeof(WCHAR))) {
Result = TRUE;
} else {
Result = FALSE; }
if (KeyValueInformation != (PKEY_VALUE_FULL_INFORMATION)Buffer) {
ExFreePool(KeyValueInformation); }
return Result;}
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