reactos/drivers/storage/class/disk/pnp.c

/*++

Copyright (C) Microsoft Corporation, 1991 - 1999

Module Name:

    pnp.c

Abstract:

    SCSI disk class driver

Environment:

    kernel mode only

Notes:

Revision History:

--*/

#include "disk.h"


#ifdef DEBUG_USE_WPP
#include "pnp.tmh"
#endif

#ifndef __REACTOS__
extern PULONG InitSafeBootMode;
#else
extern NTSYSAPI ULONG InitSafeBootMode;
#endif
ULONG diskDeviceSequenceNumber = 0;
extern BOOLEAN DiskIsPastReinit;


#ifdef ALLOC_PRAGMA

#pragma alloc_text(PAGE, DiskAddDevice)
#pragma alloc_text(PAGE, DiskInitFdo)
#pragma alloc_text(PAGE, DiskStartFdo)
#pragma alloc_text(PAGE, DiskGenerateDeviceName)
#pragma alloc_text(PAGE, DiskCreateSymbolicLinks)
#pragma alloc_text(PAGE, DiskDeleteSymbolicLinks)
#pragma alloc_text(PAGE, DiskRemoveDevice)
#endif


NTSTATUS
NTAPI /* ReactOS Change: GCC Does not support STDCALL by default */
DiskAddDevice(
    IN PDRIVER_OBJECT DriverObject,
    IN PDEVICE_OBJECT PhysicalDeviceObject
    )

/*++

Routine Description:

    This routine gets a port drivers capabilities, obtains the
    inquiry data, searches the SCSI bus for the port driver and creates
    the device objects for the disks found.

Arguments:

    DriverObject - Pointer to driver object created by system.

    Pdo - Device object use to send requests to port driver.

Return Value:

    True is returned if one disk was found and successfully created.

--*/

{
    ULONG rootPartitionMountable = FALSE;

    PCONFIGURATION_INFORMATION configurationInformation;
    ULONG diskCount;

    NTSTATUS status;

    PAGED_CODE();

    //
    // See if we should be allowing file systems to mount on partition zero.
    //

    TRY {
        HANDLE deviceKey = NULL;

        UNICODE_STRING diskKeyName;
        OBJECT_ATTRIBUTES objectAttributes = {0};
        HANDLE diskKey;

        RTL_QUERY_REGISTRY_TABLE queryTable[2] = { 0 };

        status = IoOpenDeviceRegistryKey(PhysicalDeviceObject,
                                         PLUGPLAY_REGKEY_DEVICE,
                                         KEY_READ,
                                         &deviceKey);

        if(!NT_SUCCESS(status)) {
            TracePrint((TRACE_LEVEL_ERROR, TRACE_FLAG_PNP, "DiskAddDevice: Error %#08lx opening device key "
                           "for pdo %p\n",
                        status, PhysicalDeviceObject));
            LEAVE;
        }

        RtlInitUnicodeString(&diskKeyName, L"Disk");
        InitializeObjectAttributes(&objectAttributes,
                                   &diskKeyName,
                                   OBJ_CASE_INSENSITIVE | OBJ_KERNEL_HANDLE,
                                   deviceKey,
                                   NULL);

        status = ZwOpenKey(&diskKey, KEY_READ, &objectAttributes);
        ZwClose(deviceKey);

        if(!NT_SUCCESS(status)) {
            TracePrint((TRACE_LEVEL_ERROR, TRACE_FLAG_PNP, "DiskAddDevice: Error %#08lx opening disk key "
                           "for pdo %p device key %p\n",
                        status, PhysicalDeviceObject, deviceKey));
            LEAVE;
        }

        queryTable[0].Flags = RTL_QUERY_REGISTRY_DIRECT | RTL_QUERY_REGISTRY_TYPECHECK;
        queryTable[0].Name = L"RootPartitionMountable";
        queryTable[0].EntryContext = &(rootPartitionMountable);
        queryTable[0].DefaultType = (REG_DWORD << RTL_QUERY_REGISTRY_TYPECHECK_SHIFT) | REG_NONE;

#ifdef _MSC_VER
#pragma prefast(suppress:6309, "We don't have QueryRoutine so Context doesn't make any sense")
#endif
        status = RtlQueryRegistryValues(RTL_REGISTRY_HANDLE,
                                        diskKey,
                                        queryTable,
                                        NULL,
                                        NULL);

        if(!NT_SUCCESS(status)) {
            TracePrint((TRACE_LEVEL_ERROR, TRACE_FLAG_PNP, "DiskAddDevice: Error %#08lx reading value from "
                           "disk key %p for pdo %p\n",
                        status, diskKey, PhysicalDeviceObject));
        }

        ZwClose(diskKey);

    } FINALLY {

        //
        // Do nothing.
        //

        if(!NT_SUCCESS(status)) {
            TracePrint((TRACE_LEVEL_WARNING, TRACE_FLAG_PNP, "DiskAddDevice: Will %sallow file system to mount on "
                           "partition zero of disk %p\n",
                        (rootPartitionMountable ? "" : "not "),
                        PhysicalDeviceObject));
        }
    }

    //
    // Create device objects for disk
    //

    diskCount = 0;

    status = DiskCreateFdo(
                 DriverObject,
                 PhysicalDeviceObject,
                 &diskCount,
                 (BOOLEAN) !rootPartitionMountable
                 );

    //
    // Get the number of disks already initialized.
    //

    configurationInformation = IoGetConfigurationInformation();

    if (NT_SUCCESS(status)) {

        //
        // Increment system disk device count.
        //

        configurationInformation->DiskCount++;

    }

    return status;

} // end DiskAddDevice()


NTSTATUS
NTAPI /* ReactOS Change: GCC Does not support STDCALL by default */
DiskInitFdo(
    IN PDEVICE_OBJECT Fdo
    )

/*++

Routine Description:

    This routine is called to do one-time initialization of new device objects


Arguments:

    Fdo - a pointer to the functional device object for this device

Return Value:

    status

--*/

{
    PFUNCTIONAL_DEVICE_EXTENSION fdoExtension = Fdo->DeviceExtension;
    PDISK_DATA diskData = (PDISK_DATA) fdoExtension->CommonExtension.DriverData;

    ULONG srbFlags = 0;
    ULONG timeOut = 0;
    ULONG bytesPerSector;

    PULONG dmSkew;

    NTSTATUS status = STATUS_SUCCESS;

    PAGED_CODE();

    //
    // Build the lookaside list for srb's for the physical disk. Should only
    // need a couple.  If this fails then we don't have an emergency SRB so
    // fail the call to initialize.
    //

    ClassInitializeSrbLookasideList((PCOMMON_DEVICE_EXTENSION) fdoExtension,
                                    PARTITION0_LIST_SIZE);

    if (fdoExtension->DeviceDescriptor->RemovableMedia)
    {
        SET_FLAG(Fdo->Characteristics, FILE_REMOVABLE_MEDIA);
    }

    //
    // Initialize the srb flags.
    //

    //
    // Because all requests share a common sense buffer, it is possible
    // for the buffer to be overwritten if the port driver completes
    // multiple failed requests that require a request sense before the
    // class driver's completion routine can consume the data in the buffer.
    // To prevent this, we allow the port driver to allocate a unique sense
    // buffer each time it needs one.  We are responsible for freeing this
    // buffer.  This also allows the adapter to be configured to support
    // additional sense data beyond the minimum 18 bytes.
    //

    SET_FLAG(fdoExtension->SrbFlags, SRB_FLAGS_PORT_DRIVER_ALLOCSENSE);

    if (fdoExtension->DeviceDescriptor->CommandQueueing &&
        fdoExtension->AdapterDescriptor->CommandQueueing) {

        SET_FLAG(fdoExtension->SrbFlags, SRB_FLAGS_QUEUE_ACTION_ENABLE);

    }

    //
    // Look for controllers that require special flags.
    //

    ClassScanForSpecial(fdoExtension, DiskBadControllers, DiskSetSpecialHacks);

    //
    // Clear buffer for drive geometry.
    //

    RtlZeroMemory(&(fdoExtension->DiskGeometry),
                  sizeof(DISK_GEOMETRY));

    //
    // Allocate request sense buffer.
    //

    fdoExtension->SenseData = ExAllocatePoolWithTag(NonPagedPoolNxCacheAligned,
                                                    SENSE_BUFFER_SIZE_EX,
                                                    DISK_TAG_START);

    if (fdoExtension->SenseData == NULL) {

        //
        // The buffer can not be allocated.
        //

        TracePrint((TRACE_LEVEL_ERROR, TRACE_FLAG_PNP, "DiskInitFdo: Can not allocate request sense buffer\n"));

        status = STATUS_INSUFFICIENT_RESOURCES;
        return status;
    }

    //
    // Set the buffer size of SenseData
    //

    fdoExtension->SenseDataLength = SENSE_BUFFER_SIZE_EX;

    //
    // Physical device object will describe the entire
    // device, starting at byte offset 0.
    //

    fdoExtension->CommonExtension.StartingOffset.QuadPart = (LONGLONG)(0);

    //
    // Set timeout value in seconds.
    //
    if ( (fdoExtension->MiniportDescriptor != NULL) &&
         (fdoExtension->MiniportDescriptor->IoTimeoutValue > 0) ) {
        //
        // use the value set by Storport miniport driver
        //
        fdoExtension->TimeOutValue = fdoExtension->MiniportDescriptor->IoTimeoutValue;
    } else {
        //
        // get timeout value from registry
        //
        timeOut = ClassQueryTimeOutRegistryValue(Fdo);

        if (timeOut) {
            fdoExtension->TimeOutValue = timeOut;
        } else {
            fdoExtension->TimeOutValue = SCSI_DISK_TIMEOUT;
        }
    }
    //
    // If this is a removable drive, build an entry in devicemap\scsi
    // indicating it's physicaldriveN name, set up the appropriate
    // update partitions routine and set the flags correctly.
    // note: only do this after the timeout value is set, above.
    //

    if (TEST_FLAG(Fdo->Characteristics, FILE_REMOVABLE_MEDIA)) {

        ClassUpdateInformationInRegistry( Fdo,
                                          "PhysicalDrive",
                                          fdoExtension->DeviceNumber,
                                          NULL,
                                          0);
        //
        // Enable media change notification for removable disks
        //
        ClassInitializeMediaChangeDetection(fdoExtension,
                                            (PUCHAR)"Disk");

    } else {

        SET_FLAG(fdoExtension->DeviceFlags, DEV_SAFE_START_UNIT);
        SET_FLAG(fdoExtension->SrbFlags, SRB_FLAGS_NO_QUEUE_FREEZE);

    }

    //
    // The commands we send during the init could cause the flags to change
    // in case of any error.  Save the SRB flags locally and restore it at
    // the end of this function, so that the class driver can get it.
    //

    srbFlags = fdoExtension->SrbFlags;


    //
    // Read the drive capacity.  Don't use the disk version of the routine here
    // since we don't know the disk signature yet - the disk version will
    // attempt to determine the BIOS reported geometry.
    //

    (VOID)ClassReadDriveCapacity(Fdo);

    //
    // Set up sector size fields.
    //
    // Stack variables will be used to update
    // the partition device extensions.
    //
    // The device extension field SectorShift is
    // used to calculate sectors in I/O transfers.
    //
    // The DiskGeometry structure is used to service
    // IOCTls used by the format utility.
    //

    bytesPerSector = fdoExtension->DiskGeometry.BytesPerSector;

    //
    // Make sure sector size is not zero.
    //

    if (bytesPerSector == 0) {

        //
        // Default sector size for disk is 512.
        //

        bytesPerSector = fdoExtension->DiskGeometry.BytesPerSector = 512;
        fdoExtension->SectorShift = 9;
    }

    //
    // Determine is DM Driver is loaded on an IDE drive that is
    // under control of Atapi - this could be either a crashdump or
    // an Atapi device is sharing the controller with an IDE disk.
    //

    HalExamineMBR(fdoExtension->CommonExtension.DeviceObject,
                  fdoExtension->DiskGeometry.BytesPerSector,
                  (ULONG)0x54,
                  (PVOID *)&dmSkew);

    if (dmSkew) {

        //
        // Update the device extension, so that the call to IoReadPartitionTable
        // will get the correct information. Any I/O to this disk will have
        // to be skewed by *dmSkew sectors aka DMByteSkew.
        //

        fdoExtension->DMSkew     = *dmSkew;
        fdoExtension->DMActive   = TRUE;
        fdoExtension->DMByteSkew = fdoExtension->DMSkew * bytesPerSector;

        FREE_POOL(dmSkew);
    }

#if defined(_X86_) || defined(_AMD64_)

    //
    // Try to read the signature off the disk and determine the correct drive
    // geometry based on that.  This requires rereading the disk size to get
    // the cylinder count updated correctly.
    //

    if(!TEST_FLAG(Fdo->Characteristics, FILE_REMOVABLE_MEDIA)) {

        DiskReadSignature(Fdo);
        DiskReadDriveCapacity(Fdo);

        if (diskData->GeometrySource == DiskGeometryUnknown)
        {
            //
            // Neither the  BIOS  nor the port driver could provide us with a  reliable
            // geometry.  Before we use the default,  look to see if it was partitioned
            // under Windows NT4 [or earlier] and apply the one that was used back then
            //

            if (DiskIsNT4Geometry(fdoExtension))
            {
                diskData->RealGeometry = fdoExtension->DiskGeometry;
                diskData->RealGeometry.SectorsPerTrack   = 0x20;
                diskData->RealGeometry.TracksPerCylinder = 0x40;
                fdoExtension->DiskGeometry = diskData->RealGeometry;

                diskData->GeometrySource = DiskGeometryFromNT4;
            }
        }
    }

#endif

    DiskCreateSymbolicLinks(Fdo);

    //
    // Get the SCSI address if it's available for use with SMART ioctls.
    // SMART ioctls are used for failure prediction, so we need to get
    // the SCSI address before initializing failure prediction.
    //

    {
        PIRP irp;
        KEVENT event;
        IO_STATUS_BLOCK statusBlock = { 0 };

        KeInitializeEvent(&event, SynchronizationEvent, FALSE);

        irp = IoBuildDeviceIoControlRequest(IOCTL_SCSI_GET_ADDRESS,
                                            fdoExtension->CommonExtension.LowerDeviceObject,
                                            NULL,
                                            0L,
                                            &(diskData->ScsiAddress),
                                            sizeof(SCSI_ADDRESS),
                                            FALSE,
                                            &event,
                                            &statusBlock);

        status = STATUS_UNSUCCESSFUL;

        if(irp != NULL) {

            status = IoCallDriver(fdoExtension->CommonExtension.LowerDeviceObject, irp);

            if(status == STATUS_PENDING) {
                KeWaitForSingleObject(&event,
                                      Executive,
                                      KernelMode,
                                      FALSE,
                                      NULL);
                status = statusBlock.Status;
            }
        }
    }

    //
    // Determine the type of disk and enable failure prediction in the hardware
    // and enable failure prediction polling.
    //

    if (InitSafeBootMode == 0) // __REACTOS__
    {
        DiskDetectFailurePrediction(fdoExtension,
                                    &diskData->FailurePredictionCapability,
                                    NT_SUCCESS(status));

        if (diskData->FailurePredictionCapability != FailurePredictionNone)
        {
            //
            // Cool, we've got some sort of failure prediction, enable it
            // at the hardware and then enable polling for it
            //

            //
            // By default we allow performance to be degradeded if failure
            // prediction is enabled.
            //

            diskData->AllowFPPerfHit = TRUE;

            //
            // Enable polling only after Atapi and SBP2 add support for the new
            // SRB flag that indicates that the request should not reset the
            // drive spin down idle timer.
            //

            status = DiskEnableDisableFailurePredictPolling(fdoExtension,
                                          TRUE,
                                          DISK_DEFAULT_FAILURE_POLLING_PERIOD);

            TracePrint((TRACE_LEVEL_INFORMATION, TRACE_FLAG_PNP, "DiskInitFdo: Failure Prediction Poll enabled as "
                           "%d for device %p, Status = %lx\n",
                     diskData->FailurePredictionCapability,
                     Fdo,
                     status));
        }
    } else {

        //
        // In safe boot mode we do not enable failure prediction, as perhaps
        // it is the reason why normal boot does not work
        //

        diskData->FailurePredictionCapability = FailurePredictionNone;

    }

    //
    // Initialize the verify mutex
    //

    KeInitializeMutex(&diskData->VerifyMutex, MAX_SECTORS_PER_VERIFY);

    //
    // Initialize the flush group context
    //

    RtlZeroMemory(&diskData->FlushContext, sizeof(DISK_GROUP_CONTEXT));

    InitializeListHead(&diskData->FlushContext.CurrList);
    InitializeListHead(&diskData->FlushContext.NextList);

    KeInitializeSpinLock(&diskData->FlushContext.Spinlock);
    KeInitializeEvent(&diskData->FlushContext.Event, SynchronizationEvent, FALSE);


    //
    // Restore the saved value
    //
    fdoExtension->SrbFlags = srbFlags;

    return STATUS_SUCCESS;

} // end DiskInitFdo()

NTSTATUS
NTAPI /* ReactOS Change: GCC Does not support STDCALL by default */
DiskStopDevice(
    IN PDEVICE_OBJECT DeviceObject,
    IN UCHAR Type
    )

{
    UNREFERENCED_PARAMETER(DeviceObject);
    UNREFERENCED_PARAMETER(Type);
    return STATUS_SUCCESS;
}

NTSTATUS
DiskGenerateDeviceName(
    IN ULONG DeviceNumber,
    OUT PCCHAR *RawName
    )

/*++

Routine Description:

    This routine will allocate a unicode string buffer and then fill it in
    with a generated name for the specified device object.

    It is the responsibility of the user to allocate a UNICODE_STRING structure
    to pass in and to free UnicodeName->Buffer when done with it.

Arguments:

    DeviceObject - a pointer to the device object

    UnicodeName - a unicode string to put the name buffer into

Return Value:

    status

--*/

#define FDO_NAME_FORMAT "\\Device\\Harddisk%d\\DR%d"

{
    CHAR rawName[64] = { 0 };
    NTSTATUS status;

    PAGED_CODE();

        status = RtlStringCchPrintfA(rawName, sizeof(rawName) - 1, FDO_NAME_FORMAT, DeviceNumber,
                                    diskDeviceSequenceNumber++);
        if (!NT_SUCCESS(status)) {
            TracePrint((TRACE_LEVEL_ERROR, TRACE_FLAG_PNP, "DiskGenerateDeviceName: Format FDO name failed with error: 0x%X\n", status));
            return status;
        }

    *RawName = ExAllocatePoolWithTag(PagedPool,
                                     strlen(rawName) + 1,
                                     DISK_TAG_NAME);

    if(*RawName == NULL) {
        return STATUS_INSUFFICIENT_RESOURCES;
    }

    status = RtlStringCchCopyA(*RawName, strlen(rawName) + 1, rawName);
    if (!NT_SUCCESS(status)) {
        TracePrint((TRACE_LEVEL_ERROR, TRACE_FLAG_PNP, "DiskGenerateDeviceName: Device name copy failed with error: 0x%X\n", status));
        FREE_POOL(*RawName);
        return status;
    }

    TracePrint((TRACE_LEVEL_INFORMATION, TRACE_FLAG_PNP, "DiskGenerateDeviceName: generated \"%s\"\n", rawName));

    return STATUS_SUCCESS;
}


VOID
DiskCreateSymbolicLinks(
    IN PDEVICE_OBJECT DeviceObject
    )

/*++

Routine Description:

    This routine will generate a symbolic link for the specified device object
    using the well known form \\Device\HarddiskX\PartitionY, where X and Y is
    always 0 which represents the entire disk object.

    This routine will not try to delete any previous symbolic link for the
    same generated name - the caller must make sure the symbolic link has
    been broken before calling this routine.

Arguments:

    DeviceObject - the device object to make a well known name for

Return Value:

    STATUS

--*/

{
    PCOMMON_DEVICE_EXTENSION commonExtension = DeviceObject->DeviceExtension;
    PDISK_DATA diskData = commonExtension->DriverData;

    WCHAR wideSourceName[64] = { 0 };
    UNICODE_STRING unicodeSourceName;

    NTSTATUS status;

    PAGED_CODE();

    //
    // Build the destination for the link first using the device name
    // stored in the device object
    //

    NT_ASSERT(commonExtension->DeviceName.Buffer);

    if(!diskData->LinkStatus.WellKnownNameCreated) {
        //
        // Put together the source name using the partition and device number
        // in the device extension and disk data segment
        //

        status = RtlStringCchPrintfW(wideSourceName, sizeof(wideSourceName) / sizeof(wideSourceName[0]) - 1,
                                     L"\\Device\\Harddisk%d\\Partition0",
                                     commonExtension->PartitionZeroExtension->DeviceNumber);

        if (NT_SUCCESS(status)) {

            RtlInitUnicodeString(&unicodeSourceName, wideSourceName);

            TracePrint((TRACE_LEVEL_INFORMATION, TRACE_FLAG_PNP, "DiskCreateSymbolicLink: Linking %wZ to %wZ\n",
                       &unicodeSourceName,
                       &commonExtension->DeviceName));

            status = IoCreateSymbolicLink(&unicodeSourceName,
                                          &commonExtension->DeviceName);

            if(NT_SUCCESS(status)){
                diskData->LinkStatus.WellKnownNameCreated = TRUE;
            }
        }
    }

    if (!diskData->LinkStatus.PhysicalDriveLinkCreated) {

        //
        // Create a physical drive N link using the device number we saved
        // away during AddDevice.
        //

        status = RtlStringCchPrintfW(wideSourceName, sizeof(wideSourceName) / sizeof(wideSourceName[0]) - 1,
                                     L"\\DosDevices\\PhysicalDrive%d",
                                     commonExtension->PartitionZeroExtension->DeviceNumber);
        if (NT_SUCCESS(status)) {

            RtlInitUnicodeString(&unicodeSourceName, wideSourceName);

            TracePrint((TRACE_LEVEL_INFORMATION, TRACE_FLAG_PNP, "DiskCreateSymbolicLink: Linking %wZ to %wZ\n",
                        &unicodeSourceName,
                        &(commonExtension->DeviceName)));

            status = IoCreateSymbolicLink(&unicodeSourceName,
                                          &(commonExtension->DeviceName));

            if(NT_SUCCESS(status)) {
                diskData->LinkStatus.PhysicalDriveLinkCreated = TRUE;
            }
        }
    }


    return;
}


VOID
DiskDeleteSymbolicLinks(
    IN PDEVICE_OBJECT DeviceObject
    )

/*++

Routine Description:

    This routine will delete the well known name (symlink) for the specified
    device.  It generates the link name using information stored in the
    device extension

Arguments:

    DeviceObject - the device object we are unlinking

Return Value:

    status

--*/

{
    PCOMMON_DEVICE_EXTENSION commonExtension = DeviceObject->DeviceExtension;
    PDISK_DATA diskData = commonExtension->DriverData;

    WCHAR wideLinkName[64] = { 0 };
    UNICODE_STRING unicodeLinkName;
    NTSTATUS status;

    PAGED_CODE();

    if(diskData->LinkStatus.WellKnownNameCreated) {

        status = RtlStringCchPrintfW(wideLinkName, sizeof(wideLinkName) / sizeof(wideLinkName[0]) - 1,
                                    L"\\Device\\Harddisk%d\\Partition0",
                                    commonExtension->PartitionZeroExtension->DeviceNumber);
        if (NT_SUCCESS(status)) {
            RtlInitUnicodeString(&unicodeLinkName, wideLinkName);
            IoDeleteSymbolicLink(&unicodeLinkName);
        }
        diskData->LinkStatus.WellKnownNameCreated = FALSE;
    }

    if(diskData->LinkStatus.PhysicalDriveLinkCreated) {

        status = RtlStringCchPrintfW(wideLinkName, sizeof(wideLinkName) / sizeof(wideLinkName[0]) - 1,
                                    L"\\DosDevices\\PhysicalDrive%d",
                                    commonExtension->PartitionZeroExtension->DeviceNumber);
        if (NT_SUCCESS(status)) {
            RtlInitUnicodeString(&unicodeLinkName, wideLinkName);
            IoDeleteSymbolicLink(&unicodeLinkName);
        }
        diskData->LinkStatus.PhysicalDriveLinkCreated = FALSE;
    }


    return;
}


NTSTATUS
NTAPI /* ReactOS Change: GCC Does not support STDCALL by default */
DiskRemoveDevice(
    IN PDEVICE_OBJECT DeviceObject,
    IN UCHAR Type
    )

/*++

Routine Description:

    This routine will release any resources the device may have allocated for
    this device object and return.

Arguments:

    DeviceObject - the device object being removed

Return Value:

    status

--*/

{
    PCOMMON_DEVICE_EXTENSION commonExtension = DeviceObject->DeviceExtension;
    PFUNCTIONAL_DEVICE_EXTENSION fdoExtension = DeviceObject->DeviceExtension;

    PAGED_CODE();

    //
    // Handle query and cancel
    //

    if((Type == IRP_MN_QUERY_REMOVE_DEVICE) ||
       (Type == IRP_MN_CANCEL_REMOVE_DEVICE)) {
        return STATUS_SUCCESS;
    }

    //
    // Delete our object directory.
    //

    if(fdoExtension->DeviceDirectory != NULL) {
        ZwMakeTemporaryObject(fdoExtension->DeviceDirectory);
        ZwClose(fdoExtension->DeviceDirectory);
        fdoExtension->DeviceDirectory = NULL;
    }

    if(Type == IRP_MN_REMOVE_DEVICE) {

        FREE_POOL(fdoExtension->SenseData);

        IoGetConfigurationInformation()->DiskCount--;

    }

    DiskDeleteSymbolicLinks(DeviceObject);

    if (Type == IRP_MN_REMOVE_DEVICE)
    {
        ClassDeleteSrbLookasideList(commonExtension);
    }

    return STATUS_SUCCESS;
}


NTSTATUS
NTAPI /* ReactOS Change: GCC Does not support STDCALL by default */
DiskStartFdo(
    IN PDEVICE_OBJECT Fdo
    )

/*++

Routine Description:

    This routine will query the underlying device for any information necessary
    to complete initialization of the device.  This will include physical
    disk geometry, mode sense information and such.

    This routine does not perform partition enumeration - that is left to the
    re-enumeration routine

    If this routine fails it will return an error value.  It does not clean up
    any resources - that is left for the Stop/Remove routine.

Arguments:

    Fdo - a pointer to the functional device object for this device

Return Value:

    status

--*/

{
    PFUNCTIONAL_DEVICE_EXTENSION fdoExtension = Fdo->DeviceExtension;
    PCOMMON_DEVICE_EXTENSION commonExtension = &(fdoExtension->CommonExtension);
    PDISK_DATA diskData = commonExtension->DriverData;
    STORAGE_HOTPLUG_INFO hotplugInfo = { 0 };
    DISK_CACHE_INFORMATION cacheInfo = { 0 };
    ULONG isPowerProtected = 0;
    NTSTATUS status;

    PAGED_CODE();

    //
    // Get the hotplug information, so we can turn off write cache if needed
    //
    // NOTE: Capabilities info is not good enough to determine hotplugedness
    //       as  we cannot determine device relations  information and other
    //       dependencies. Get the hotplug info instead
    //

    {
        PIRP irp;
        KEVENT event;
        IO_STATUS_BLOCK statusBlock = { 0 };

        KeInitializeEvent(&event, SynchronizationEvent, FALSE);

        irp = IoBuildDeviceIoControlRequest(IOCTL_STORAGE_GET_HOTPLUG_INFO,
                                            Fdo,
                                            NULL,
                                            0L,
                                            &hotplugInfo,
                                            sizeof(STORAGE_HOTPLUG_INFO),
                                            FALSE,
                                            &event,
                                            &statusBlock);

        if (irp != NULL) {

            // send to self -- classpnp handles this
            status = IoCallDriver(Fdo, irp);
            if (status == STATUS_PENDING) {
                KeWaitForSingleObject(&event,
                                      Executive,
                                      KernelMode,
                                      FALSE,
                                      NULL);

                status = statusBlock.Status;
            }
            NT_ASSERT(NT_SUCCESS(status));
        }
    }

    //
    // Clear the DEV_WRITE_CACHE flag now  and set
    // it below only if we read that from the disk
    //
    CLEAR_FLAG(fdoExtension->DeviceFlags, DEV_WRITE_CACHE);
    ADJUST_FUA_FLAG(fdoExtension);

    diskData->WriteCacheOverride = DiskWriteCacheDefault;

    //
    // Look into the registry to  see if the user
    // has chosen to override the default setting
    //
    ClassGetDeviceParameter(fdoExtension,
                            DiskDeviceParameterSubkey,
                            DiskDeviceUserWriteCacheSetting,
                            (PULONG)&diskData->WriteCacheOverride);

    if (diskData->WriteCacheOverride == DiskWriteCacheDefault)
    {
        //
        // The user has not overridden the default settings
        //
        if (TEST_FLAG(fdoExtension->ScanForSpecialFlags, CLASS_SPECIAL_DISABLE_WRITE_CACHE))
        {
            //
            // This flag indicates that we have faulty firmware and this
            // may cause the filesystem to refuse to mount on this media
            //
            TracePrint((TRACE_LEVEL_WARNING, TRACE_FLAG_PNP, "DiskStartFdo: Turning off write cache for %p due to a firmware issue\n", Fdo));

            diskData->WriteCacheOverride = DiskWriteCacheDisable;
        }
        else if (hotplugInfo.DeviceHotplug && !hotplugInfo.WriteCacheEnableOverride)
        {
            //
            // This flag indicates that the device is hotpluggable making it unsafe to enable caching
            //
            TracePrint((TRACE_LEVEL_WARNING, TRACE_FLAG_PNP, "DiskStartFdo: Turning off write cache for %p due to hotpluggable device\n", Fdo));

            diskData->WriteCacheOverride = DiskWriteCacheDisable;
        }
        else if (hotplugInfo.MediaHotplug)
        {
            //
            // This flag indicates that the media in the device cannot be reliably locked
            //
            TracePrint((TRACE_LEVEL_WARNING, TRACE_FLAG_PNP, "DiskStartFdo: Turning off write cache for %p due to unlockable media\n", Fdo));

            diskData->WriteCacheOverride = DiskWriteCacheDisable;
        }
        else
        {
            //
            // Even though the device does  not seem to have any obvious problems
            // we leave it to the user to modify the previous write cache setting
            //
        }
    }

    //
    // Query the disk to see if write cache is enabled
    // and  set the DEV_WRITE_CACHE flag appropriately
    //

    status = DiskGetCacheInformation(fdoExtension, &cacheInfo);

    if (NT_SUCCESS(status))
    {
        if (cacheInfo.WriteCacheEnabled == TRUE)
        {
            SET_FLAG(fdoExtension->DeviceFlags, DEV_WRITE_CACHE);
            ADJUST_FUA_FLAG(fdoExtension);

            if (diskData->WriteCacheOverride == DiskWriteCacheDisable)
            {
                //
                // Write cache is currently enabled on this
                // device, but we would like to turn it off
                //
                cacheInfo.WriteCacheEnabled = FALSE;

                DiskSetCacheInformation(fdoExtension, &cacheInfo);
            }
        }
        else
        {
            if (diskData->WriteCacheOverride == DiskWriteCacheEnable)
            {
                //
                // Write cache is currently disabled on this
                // device, but we  would  like to turn it on
                //
                cacheInfo.WriteCacheEnabled = TRUE;

                DiskSetCacheInformation(fdoExtension, &cacheInfo);
            }
        }
    }

    //
    // Query the registry to see if this disk is power-protected or not
    //

    CLEAR_FLAG(fdoExtension->DeviceFlags, DEV_POWER_PROTECTED);

    ClassGetDeviceParameter(fdoExtension, DiskDeviceParameterSubkey, DiskDeviceCacheIsPowerProtected, &isPowerProtected);

    if (isPowerProtected == 1)
    {
        SET_FLAG(fdoExtension->DeviceFlags, DEV_POWER_PROTECTED);
    }

    ADJUST_FUA_FLAG(fdoExtension);

    return STATUS_SUCCESS;

} // end DiskStartFdo()