/*-- Copyright (c) 1997 Microsoft Corporation Module Name: neckbadd.c Abstract: Environment: Kernel mode only. Notes: Revision History: --*/ #include "neckbadd.h" #ifdef ALLOC_PRAGMA #pragma alloc_text (INIT, DriverEntry) #pragma alloc_text (PAGE, NecKbdCreateClose) #pragma alloc_text (PAGE, NecKbdInternIoCtl) #pragma alloc_text (PAGE, NecKbdUnload) #endif NTSTATUS DriverEntry ( IN PDRIVER_OBJECT DriverObject, IN PUNICODE_STRING RegistryPath ) /*++ Routine Description: Initialize the entry points of the driver. --*/ { NTSTATUS status = STATUS_SUCCESS; ULONG i; UNREFERENCED_PARAMETER (RegistryPath); // // Fill in all the dispatch entry points with the pass through function // and the explicitly fill in the functions we are going to intercept // for (i = 0; i < IRP_MJ_MAXIMUM_FUNCTION; i++) { DriverObject->MajorFunction[i] = NecKbdDispatchPassThrough; } DriverObject->MajorFunction [IRP_MJ_CREATE] = DriverObject->MajorFunction [IRP_MJ_CLOSE] = NecKbdCreateClose; DriverObject->MajorFunction [IRP_MJ_PNP] = NecKbdPnP; DriverObject->MajorFunction [IRP_MJ_POWER] = NecKbdPower; DriverObject->MajorFunction [IRP_MJ_INTERNAL_DEVICE_CONTROL] = NecKbdInternIoCtl; DriverObject->DriverUnload = NecKbdUnload; DriverObject->DriverExtension->AddDevice = NecKbdAddDevice; NecKbdServiceParameters(RegistryPath); return STATUS_SUCCESS; } NTSTATUS NecKbdAddDevice( IN PDRIVER_OBJECT Driver, IN PDEVICE_OBJECT PDO ) { PDEVICE_EXTENSION devExt; IO_ERROR_LOG_PACKET errorLogEntry; PDEVICE_OBJECT device; NTSTATUS status = STATUS_SUCCESS; PAGED_CODE(); status = IoCreateDevice(Driver, // driver sizeof(DEVICE_EXTENSION), // size of extension NULL, // device name FILE_DEVICE_8042_PORT, // device type 0, // device characteristics FALSE, // exclusive &device // new device ); if (!NT_SUCCESS(status)) { return (status); } RtlZeroMemory(device->DeviceExtension, sizeof(DEVICE_EXTENSION)); devExt = (PDEVICE_EXTENSION) device->DeviceExtension; devExt->TopOfStack = IoAttachDeviceToDeviceStack(device, PDO); if (devExt->TopOfStack == NULL) { IoDeleteDevice(device); return STATUS_DEVICE_NOT_CONNECTED; } ASSERT(devExt->TopOfStack); devExt->Self = device; devExt->PDO = PDO; devExt->DeviceState = PowerDeviceD0; devExt->Removed = FALSE; devExt->Started = FALSE; device->Flags |= DO_BUFFERED_IO; device->Flags |= DO_POWER_PAGABLE; device->Flags &= ~DO_DEVICE_INITIALIZING; return status; } NTSTATUS NecKbdComplete( IN PDEVICE_OBJECT DeviceObject, IN PIRP Irp, IN PVOID Context ) { PKEVENT event; PIO_STACK_LOCATION irpStack; NTSTATUS status = STATUS_SUCCESS; event = (PKEVENT) Context; UNREFERENCED_PARAMETER(DeviceObject); if (Irp->PendingReturned) { IoMarkIrpPending(Irp); } // // We could switch on the major and minor functions of the IRP to perform // different functions, but we know that Context is an event that needs // to be set. // KeSetEvent(event, 0, FALSE); // // Allows the caller to use the IRP after it is completed // return STATUS_MORE_PROCESSING_REQUIRED; } NTSTATUS NecKbdCreateClose ( IN PDEVICE_OBJECT DeviceObject, IN PIRP Irp ) /*++ Routine Description: Maintain a simple count of the creates and closes sent against this device --*/ { PIO_STACK_LOCATION irpStack; NTSTATUS status = STATUS_SUCCESS; PDEVICE_EXTENSION devExt; PAGED_CODE(); irpStack = IoGetCurrentIrpStackLocation(Irp); devExt = (PDEVICE_EXTENSION) DeviceObject->DeviceExtension; switch (irpStack->MajorFunction) { case IRP_MJ_CREATE: if (NULL == devExt->UpperConnectData.ClassService) { // // No Connection yet. How can we be enabled? // status = STATUS_INVALID_DEVICE_STATE; } break; case IRP_MJ_CLOSE: break; } Irp->IoStatus.Status = status; // // Pass on the create and the close // return NecKbdDispatchPassThrough(DeviceObject, Irp); } NTSTATUS NecKbdDispatchPassThrough( IN PDEVICE_OBJECT DeviceObject, IN PIRP Irp ) /*++ Routine Description: Passes a request on to the lower driver. --*/ { PIO_STACK_LOCATION irpStack = IoGetCurrentIrpStackLocation(Irp); // // Pass the IRP to the target // IoSkipCurrentIrpStackLocation(Irp); return IoCallDriver( ((PDEVICE_EXTENSION) DeviceObject->DeviceExtension)->TopOfStack, Irp); } NTSTATUS NecKbdInternIoCtl( IN PDEVICE_OBJECT DeviceObject, IN PIRP Irp ) /*++ Routine Description: This routine is the dispatch routine for internal device control requests. Arguments: DeviceObject - Pointer to the device object. Irp - Pointer to the request packet. Return Value: Status is returned. --*/ { PIO_STACK_LOCATION irpStack; PDEVICE_EXTENSION devExt; KEVENT event; PCONNECT_DATA connectData; PKEYBOARD_TYPEMATIC_PARAMETERS TypematicParameters; NTSTATUS status = STATUS_SUCCESS; // // Get a pointer to the device extension. // devExt = (PDEVICE_EXTENSION) DeviceObject->DeviceExtension; // // Initialize the returned Information field. // Irp->IoStatus.Information = 0; // // Get a pointer to the current parameters for this request. The // information is contained in the current stack location. // irpStack = IoGetCurrentIrpStackLocation(Irp); // // Case on the device control subfunction that is being performed by the // requestor. // switch (irpStack->Parameters.DeviceIoControl.IoControlCode) { // // Connect a keyboard class device driver to the port driver. // case IOCTL_INTERNAL_KEYBOARD_CONNECT: // // Only allow a connection if the keyboard hardware is present. // Also, only allow one connection. // if (devExt->UpperConnectData.ClassService != NULL) { status = STATUS_SHARING_VIOLATION; break; } else if (irpStack->Parameters.DeviceIoControl.InputBufferLength < sizeof(CONNECT_DATA)) { // // invalid buffer // status = STATUS_INVALID_PARAMETER; break; } // // Copy the connection parameters to the device extension. // connectData = ((PCONNECT_DATA) (irpStack->Parameters.DeviceIoControl.Type3InputBuffer)); devExt->UpperConnectData = *connectData; connectData->ClassDeviceObject = devExt->Self; connectData->ClassService = NecKbdServiceCallback; break; // // Disconnect a keyboard class device driver from the port driver. // case IOCTL_INTERNAL_KEYBOARD_DISCONNECT: // // Clear the connection parameters in the device extension. // // devExt->UpperConnectData.ClassDeviceObject = NULL; // devExt->UpperConnectData.ClassService = NULL; status = STATUS_NOT_IMPLEMENTED; break; case IOCTL_KEYBOARD_SET_TYPEMATIC: // // Might want to capture these in the future // case IOCTL_KEYBOARD_QUERY_ATTRIBUTES: case IOCTL_KEYBOARD_QUERY_INDICATOR_TRANSLATION: case IOCTL_KEYBOARD_QUERY_INDICATORS: case IOCTL_KEYBOARD_SET_INDICATORS: case IOCTL_KEYBOARD_QUERY_TYPEMATIC: default: break; } if (!NT_SUCCESS(status)) { return status; } return NecKbdDispatchPassThrough(DeviceObject, Irp); } NTSTATUS NecKbdPnP( IN PDEVICE_OBJECT DeviceObject, IN PIRP Irp ) /*++ Routine Description: This routine is the dispatch routine for plug and play irps Arguments: DeviceObject - Pointer to the device object. Irp - Pointer to the request packet. Return Value: Status is returned. --*/ { PDEVICE_EXTENSION devExt; PIO_STACK_LOCATION irpStack; NTSTATUS status = STATUS_SUCCESS; KIRQL oldIrql; KEVENT event; PAGED_CODE(); devExt = (PDEVICE_EXTENSION) DeviceObject->DeviceExtension; irpStack = IoGetCurrentIrpStackLocation(Irp); switch (irpStack->MinorFunction) { case IRP_MN_START_DEVICE: { // // The device is starting. // // We cannot touch the device (send it any non pnp irps) until a // start device has been passed down to the lower drivers. // IoCopyCurrentIrpStackLocationToNext(Irp); KeInitializeEvent(&event, NotificationEvent, FALSE ); IoSetCompletionRoutine(Irp, (PIO_COMPLETION_ROUTINE) NecKbdComplete, &event, TRUE, TRUE, TRUE); // No need for Cancel status = IoCallDriver(devExt->TopOfStack, Irp); if (STATUS_PENDING == status) { KeWaitForSingleObject( &event, Executive, // Waiting for reason of a driver KernelMode, // Waiting in kernel mode FALSE, // No allert NULL); // No timeout } if (NT_SUCCESS(status) && NT_SUCCESS(Irp->IoStatus.Status)) { // // As we are successfully now back from our start device // we can do work. // devExt->Started = TRUE; devExt->Removed = FALSE; } // // We must now complete the IRP, since we stopped it in the // completetion routine with MORE_PROCESSING_REQUIRED. // Irp->IoStatus.Status = status; Irp->IoStatus.Information = 0; IoCompleteRequest(Irp, IO_NO_INCREMENT); break; } case IRP_MN_REMOVE_DEVICE: IoSkipCurrentIrpStackLocation(Irp); IoCallDriver(devExt->TopOfStack, Irp); devExt->Removed = TRUE; IoDetachDevice(devExt->TopOfStack); IoDeleteDevice(DeviceObject); status = STATUS_SUCCESS; break; case IRP_MN_QUERY_REMOVE_DEVICE: case IRP_MN_QUERY_STOP_DEVICE: case IRP_MN_CANCEL_REMOVE_DEVICE: case IRP_MN_CANCEL_STOP_DEVICE: case IRP_MN_FILTER_RESOURCE_REQUIREMENTS: case IRP_MN_STOP_DEVICE: case IRP_MN_QUERY_DEVICE_RELATIONS: case IRP_MN_QUERY_INTERFACE: case IRP_MN_QUERY_CAPABILITIES: case IRP_MN_QUERY_DEVICE_TEXT: case IRP_MN_QUERY_RESOURCES: case IRP_MN_QUERY_RESOURCE_REQUIREMENTS: case IRP_MN_READ_CONFIG: case IRP_MN_WRITE_CONFIG: case IRP_MN_EJECT: case IRP_MN_SET_LOCK: case IRP_MN_QUERY_ID: case IRP_MN_QUERY_PNP_DEVICE_STATE: default: // // Here the filter driver might modify the behavior of these IRPS // Please see PlugPlay documentation for use of these IRPs. // IoSkipCurrentIrpStackLocation(Irp); status = IoCallDriver(devExt->TopOfStack, Irp); break; } return status; } NTSTATUS NecKbdPower( IN PDEVICE_OBJECT DeviceObject, IN PIRP Irp ) /*++ Routine Description: This routine is the dispatch routine for power irps Does nothing except record the state of the device. Arguments: DeviceObject - Pointer to the device object. Irp - Pointer to the request packet. Return Value: Status is returned. --*/ { PIO_STACK_LOCATION irpStack; NTSTATUS status; PDEVICE_EXTENSION devExt; POWER_STATE powerState; POWER_STATE_TYPE powerType; devExt = (PDEVICE_EXTENSION) DeviceObject->DeviceExtension; irpStack = IoGetCurrentIrpStackLocation(Irp); powerType = irpStack->Parameters.Power.Type; powerState = irpStack->Parameters.Power.State; switch (irpStack->MinorFunction) { case IRP_MN_SET_POWER: Print(("NecKbdPower:Power Setting %s state to %d\n", ((powerType == SystemPowerState) ? "System" : "Device"), powerState.SystemState)); if (powerType == DevicePowerState) { devExt->DeviceState = powerState.DeviceState; } break; case IRP_MN_QUERY_POWER: Print(("NecKbdPower:Power query %s status to %d\n", ((powerType == SystemPowerState) ? "System" : "Device"), powerState.SystemState)); break; default: Print(("NecKbdPower:Power minor (0x%x) no known\n", irpStack->MinorFunction)); break; } PoStartNextPowerIrp(Irp); IoSkipCurrentIrpStackLocation(Irp); PoCallDriver(devExt->TopOfStack, Irp); return STATUS_SUCCESS; } VOID NecKbdServiceCallback( IN PDEVICE_OBJECT DeviceObject, IN PKEYBOARD_INPUT_DATA InputDataStart, IN PKEYBOARD_INPUT_DATA InputDataEnd, IN OUT PULONG InputDataConsumed ) { PDEVICE_EXTENSION devExt; PKEYBOARD_INPUT_DATA CurrentInputData, CurrentInputDataStart; KEYBOARD_INPUT_DATA TempInputData[2]; devExt = (PDEVICE_EXTENSION) DeviceObject->DeviceExtension; RtlZeroMemory(TempInputData, sizeof(KEYBOARD_INPUT_DATA) * 2); CurrentInputData = CurrentInputDataStart = InputDataStart; while (CurrentInputData < InputDataEnd) { // Print(("NecKbdServiceCallBack: captured scancode: 0x%2x(%2x)\n", // CurrentInputData->MakeCode, // CurrentInputData->Flags // )); if (devExt->KeyStatusFlags & STOP_PREFIX) { if (((CurrentInputData->MakeCode != NUMLOCK_KEY) || ((CurrentInputData->Flags & (KEY_E0|KEY_E1)) != 0) || ((CurrentInputData->Flags & KEY_BREAK) != (devExt->CachedInputData.Flags & KEY_BREAK)))) { Print(("NecKbdServiceCallBack: clearing prefix of STOP(%s)\n", (CurrentInputData->Flags & KEY_BREAK) ? "Break" : "Make" )); // // send cached input data // CLASSSERVICE_CALLBACK( &(devExt->CachedInputData), &(devExt->CachedInputData) + 1); devExt->KeyStatusFlags &= ~STOP_PREFIX; } } switch (CurrentInputData->MakeCode) { case CAPS_KEY: case KANA_KEY: if (CurrentInputData->Flags & (KEY_E0|KEY_E1)) { break; } if (!(CurrentInputData->Flags & KEY_BREAK)) { Print(("NecKbdServiceCallBack: Captured %s (Make)\n", ((CurrentInputData->MakeCode == CAPS_KEY) ? "CAPS" : "KANA") )); if (((CurrentInputData->MakeCode == CAPS_KEY)&&(devExt->KeyStatusFlags & CAPS_PRESSING))|| ((CurrentInputData->MakeCode == KANA_KEY)&&(devExt->KeyStatusFlags & KANA_PRESSING))) { // // ignore repeated make code // Print(("NecKbdServiceCallBack: ignoring repeated %s(Break)\n", ((CurrentInputData->MakeCode == CAPS_KEY) ? "CAPS" : "KANA") )); } else { if (CurrentInputDataStart <= CurrentInputData) { CLASSSERVICE_CALLBACK( CurrentInputDataStart, CurrentInputData + 1); } // // Send break code // RtlCopyMemory( (PCHAR)&(TempInputData[0]), (PCHAR)CurrentInputData, sizeof(KEYBOARD_INPUT_DATA) ); TempInputData[0].Flags |= KEY_BREAK; Print(("NecKbdServiceCallBack: Sending %s(Break)\n", ((CurrentInputData->MakeCode == CAPS_KEY) ? "CAPS" : "KANA") )); CLASSSERVICE_CALLBACK( &(TempInputData[0]), &(TempInputData[1])); } if (CurrentInputData->MakeCode == CAPS_KEY) { devExt->KeyStatusFlags |= CAPS_PRESSING; } else { devExt->KeyStatusFlags |= KANA_PRESSING; } } else { // // Break generates no scancode. // Print(("NecKbdServiceCallBack: ignoring %s(Break)\n", ((CurrentInputData->MakeCode == CAPS_KEY) ? "CAPS" : "KANA") )); if (CurrentInputDataStart < CurrentInputData) { CLASSSERVICE_CALLBACK( CurrentInputDataStart, CurrentInputData); } if (CurrentInputData->MakeCode == CAPS_KEY) { devExt->KeyStatusFlags &= ~CAPS_PRESSING; } else { devExt->KeyStatusFlags &= ~KANA_PRESSING; } } CurrentInputDataStart = CurrentInputData + 1; break; case CTRL_KEY: if ((CurrentInputData->Flags & (KEY_E0|KEY_E1)) == KEY_E1) { Print(("NecKbdServiceCallBack: prefix of STOP(%s)\n", (CurrentInputData->Flags & KEY_BREAK) ? "Break" : "Make" )); if (CurrentInputDataStart < CurrentInputData) { CLASSSERVICE_CALLBACK( CurrentInputDataStart, CurrentInputData); } RtlCopyMemory( (PCHAR)&(devExt->CachedInputData), (PCHAR)CurrentInputData, sizeof(KEYBOARD_INPUT_DATA) ); devExt->KeyStatusFlags |= STOP_PREFIX; CurrentInputDataStart = CurrentInputData + 1; } break; case NUMLOCK_KEY: if ((CurrentInputData->Flags & (KEY_E0|KEY_E1)) == 0) { if (devExt->KeyStatusFlags & STOP_PREFIX) { if ((CurrentInputData->Flags & KEY_BREAK) == (devExt->CachedInputData.Flags & KEY_BREAK)) { // // it is STOP key // Print(("NecKbdServiceCallBack: Captured STOP(%s)\n", ((CurrentInputData->Flags & KEY_BREAK) ? "Break" : "Make") )); devExt->KeyStatusFlags &= ~STOP_PREFIX; // // make packets for 0x1d // RtlCopyMemory( (PCHAR)&(TempInputData[0]), (PCHAR)CurrentInputData, sizeof(KEYBOARD_INPUT_DATA) ); TempInputData[0].MakeCode = CTRL_KEY; TempInputData[0].Flags &= ~(KEY_E0|KEY_E1); // // make packet for 0x46+E0 // RtlCopyMemory( (PCHAR)&(TempInputData[1]), (PCHAR)CurrentInputData, sizeof(KEYBOARD_INPUT_DATA) ); TempInputData[1].MakeCode = STOP_KEY; TempInputData[1].Flags |= KEY_E0; TempInputData[1].Flags &= ~KEY_E1; // // send packets 0x1d, 0x46+E0 // CLASSSERVICE_CALLBACK( &(TempInputData[0]), &(TempInputData[1])); CurrentInputDataStart = CurrentInputData + 1; } else { // // invalid prefix. send it as is. // Print(("NecKbdServiceCallBack: invalid prefix for STOP(%s)\n", ((CurrentInputData->Flags & KEY_BREAK) ? "Break" : "Make") )); } } else { // // it is vf3 key. it behaves as F13 or NumLock // Print(("NecKbdServiceCallBack: Captured vf3(VfKeyEmulation is %s)\n", ((VfKeyEmulation) ? "On" : "Off") )); if (!(VfKeyEmulation)) { CurrentInputData->MakeCode = VF3_KEY; CurrentInputData->Flags &= ~(KEY_E0|KEY_E1); } } } break; // // ScrollLock can emulate VF4 // case SCROLL_LOCK_KEY: if ((CurrentInputData->Flags & (KEY_E0|KEY_E1)) == 0) { Print(("NecKbdServiceCallBack: Captured vf4(VfKeyEmulation is %s)\n", ((VfKeyEmulation) ? "On" : "Off") )); if (!(VfKeyEmulation)) { CurrentInputData->MakeCode = VF4_KEY; CurrentInputData->Flags &= ~(KEY_E0|KEY_E1); } } break; // // hankaku/zenkaku can emulate VF5 // case HANKAKU_ZENKAKU_KEY: if ((CurrentInputData->Flags & (KEY_E0|KEY_E1)) == 0) { Print(("NecKbdServiceCallBack: Captured vf5(VfKeyEmulation is %s)\n", ((VfKeyEmulation) ? "On" : "Off") )); if (!(VfKeyEmulation)) { CurrentInputData->MakeCode = VF5_KEY; CurrentInputData->Flags &= ~(KEY_E0|KEY_E1); } } break; // // the others(sent as is) // default: break; } CurrentInputData++; } // // flush InputData // if (CurrentInputDataStart < InputDataEnd) { if (devExt->KeyStatusFlags & STOP_PREFIX) { CLASSSERVICE_CALLBACK( CurrentInputDataStart, InputDataEnd - 1); } else { CLASSSERVICE_CALLBACK( CurrentInputDataStart, InputDataEnd); } } } VOID NecKbdUnload( IN PDRIVER_OBJECT Driver ) /*++ Routine Description: Free all the allocated resources associated with this driver. Arguments: DriverObject - Pointer to the driver object. Return Value: None. --*/ { PAGED_CODE(); ASSERT(NULL == Driver->DeviceObject); return; } VOID NecKbdServiceParameters( IN PUNICODE_STRING RegistryPath ) /*++ Routine Description: This routine retrieves this driver's service parameters information from the registry. Arguments: RegistryPath - Pointer to the null-terminated Unicode name of the registry path for this driver. Return Value: None. --*/ { NTSTATUS Status = STATUS_SUCCESS; PRTL_QUERY_REGISTRY_TABLE Parameters = NULL; PWSTR Path = NULL; UNICODE_STRING ParametersPath; ULONG QueriedVfKeyEmulation = 0; ULONG DefaultVfKeyEmulation = 0; USHORT queries = 1; PAGED_CODE(); ParametersPath.Buffer = NULL; // // Registry path is already null-terminated, so just use it. // Path = RegistryPath->Buffer; if (NT_SUCCESS(Status)) { // // Allocate the Rtl query table. // Parameters = ExAllocatePool( PagedPool, sizeof(RTL_QUERY_REGISTRY_TABLE) * (queries + 1) ); if (!Parameters) { Print(("NecKbdServiceParameters: couldn't allocate table for Rtl query to %ws for %ws\n", pwParameters, Path )); Status = STATUS_UNSUCCESSFUL; } else { RtlZeroMemory( Parameters, sizeof(RTL_QUERY_REGISTRY_TABLE) * (queries + 1) ); // // Form a path to this driver's Parameters subkey. // RtlInitUnicodeString( &ParametersPath, NULL ); ParametersPath.MaximumLength = RegistryPath->Length + (wcslen(pwParameters) * sizeof(WCHAR) ) + sizeof(UNICODE_NULL); ParametersPath.Buffer = ExAllocatePool( PagedPool, ParametersPath.MaximumLength ); if (!ParametersPath.Buffer) { Print(("NecKbdServiceParameters: Couldn't allocate string for path to %ws for %ws\n", pwParameters, Path )); Status = STATUS_UNSUCCESSFUL; } } } if (NT_SUCCESS(Status)) { // // Form the parameters path. // RtlZeroMemory( ParametersPath.Buffer, ParametersPath.MaximumLength ); RtlAppendUnicodeToString( &ParametersPath, Path ); RtlAppendUnicodeToString( &ParametersPath, pwParameters ); // // Gather all of the "user specified" information from // the registry. // Parameters[0].Flags = RTL_QUERY_REGISTRY_DIRECT; Parameters[0].Name = pwVfKeyEmulation; Parameters[0].EntryContext = &QueriedVfKeyEmulation; Parameters[0].DefaultType = REG_DWORD; Parameters[0].DefaultData = &DefaultVfKeyEmulation; Parameters[0].DefaultLength = sizeof(ULONG); Status = RtlQueryRegistryValues( RTL_REGISTRY_ABSOLUTE | RTL_REGISTRY_OPTIONAL, ParametersPath.Buffer, Parameters, NULL, NULL ); if (!NT_SUCCESS(Status)) { Print(("NecKbdServiceParameters: RtlQueryRegistryValues failed (0x%x)\n", Status)); } } if (!NT_SUCCESS(Status)) { // // assign driver defaults. // VfKeyEmulation = (DefaultVfKeyEmulation == 0) ? FALSE : TRUE; } else { VfKeyEmulation = (QueriedVfKeyEmulation == 0) ? FALSE : TRUE; } Print(("NecKbdServiceParameters: VfKeyEmulation is %s\n", VfKeyEmulation ? "Enable" : "Disable")); // // Free the allocated memory before returning. // if (ParametersPath.Buffer) ExFreePool(ParametersPath.Buffer); if (Parameters) ExFreePool(Parameters); }