windows-nt/Source/XPSP1/NT/base/fs/rdr2/rdbss/obsolete/obsolete.h
2020-09-26 16:20:57 +08:00

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//joejoe stuff in here is obsolete and will be removed in time.........
#define REPINNED_BCBS_ARRAY_SIZE (4)
typedef struct _REPINNED_BCBS {
//
// A pointer to the next structure contains additional repinned bcbs
//
struct _REPINNED_BCBS *Next;
//
// A fixed size array of pinned bcbs. Whenever a new bcb is added to
// the repinned bcb structure it is added to this array. If the
// array is already full then another repinned bcb structure is allocated
// and pointed to with Next.
//
PBCB Bcb[ REPINNED_BCBS_ARRAY_SIZE ];
} REPINNED_BCBS;
typedef REPINNED_BCBS *PREPINNED_BCBS;
//
// The Vcb (Volume control Block) record corresponds to every volume mounted
// by the file system. They are ordered in a queue off of RxData.VcbQueue.
// This structure must be allocated from non-paged pool
//
typedef enum _VCB_CONDITION {
VcbGood = 1,
VcbNotMounted
} VCB_CONDITION;
typedef struct _VCB {
//
// The type and size of this record (must be RDBSS_NTC_VCB)
//
NODE_TYPE_CODE NodeTypeCode;
NODE_BYTE_SIZE NodeByteSize;
//
// The links for the device queue off of RxData.VcbQueue
//
LIST_ENTRY VcbLinks;
//
// A pointer the device object passed in by the I/O system on a mount
// This is the target device object that the file system talks to when it
// needs to do any I/O (e.g., the disk stripper device object).
//
//
PDEVICE_OBJECT TargetDeviceObject;
//
// A pointer to the VPB for the volume passed in by the I/O system on
// a mount.
//
PVPB Vpb;
//
// The internal state of the device. This is a collection of fsd device
// state flags.
//
ULONG VcbState;
VCB_CONDITION VcbCondition;
//
// A pointer to the root DCB for this volume
//
struct _FCB *RootDcb;
//
// A count of the number of file objects that have opened the volume
// for direct access, and their share access state.
//
CLONG DirectAccessOpenCount;
SHARE_ACCESS ShareAccess;
//
// A count of the number of file objects that have any file/directory
// opened on this volume, not including direct access. And also the
// count of the number of file objects that have a file opened for
// only read access (i.e., they cannot be modifying the disk).
//
CLONG OpenFileCount;
CLONG ReadOnlyCount;
//
// The bios parameter block field contains
// an unpacked copy of the bpb for the volume, it is initialized
// during mount time and can be read by everyone else after that.
//
BIOS_PARAMETER_BLOCK Bpb;
//
// The following structure contains information useful to the
// allocation support routines. Many of them are computed from
// elements of the Bpb, but are too involved to recompute every time
// they are needed.
//
struct {
ULONG RootDirectoryLbo; // Lbo of beginning of root directory
ULONG RootDirectorySize; // size of root directory in bytes
ULONG FileAreaLbo; // Lbo of beginning of file area
ULONG NumberOfClusters; // total number of clusters on the volume
ULONG NumberOfFreeClusters; // number of free clusters on the volume
UCHAR RxIndexBitSize; // indicates if 12 or 16 bit rx table
UCHAR LogOfBytesPerSector; // Log(Bios->BytesPerSector)
UCHAR LogOfBytesPerCluster; // Log(Bios->SectorsPerCluster)
} AllocationSupport;
//
// The following Mcb is used to keep track of dirty sectors in the Rx.
// Runs of holes denote clean sectors while runs of LBO == VBO denote
// dirty sectors. The VBOs are that of the volume file, starting at
// 0. The granuality of dirt is one sectors, and additions are only
// made in sector chunks to prevent problems with several simultaneous
// updaters.
//
MCB DirtyRxMcb;
//
// The FreeClusterBitMap keeps track of all the clusters in the rx.
// A 1 means occupied while a 0 means free. It allows quick location
// of contiguous runs of free clusters. It is initialized on mount
// or verify.
//
RTL_BITMAP FreeClusterBitMap;
//
// The following event controls access to the free cluster bit map
//
KEVENT FreeClusterBitMapEvent;
//
// A resource variable to control access to the volume specific data
// structures
//
ERESOURCE Resource;
//
// The following field points to the file object used to do I/O to
// the virtual volume file. The virtual volume file maps sectors
// 0 through the end of rx and is of a fixed size (determined during
// mount)
//
PFILE_OBJECT VirtualVolumeFile;
//
// The following field contains a record of special pointers used by
// MM and Cache to manipluate section objects. Note that the values
// are set outside of the file system. However the file system on an
// open/create will set the file object's SectionObject field to point
// to this field
//
SECTION_OBJECT_POINTERS SectionObjectPointers;
//
// The following fields is a hint cluster index used by the file system
// when allocating a new cluster.
//
ULONG ClusterHint;
//
// This field will point to a double space control block if this Vcb
// is a DoubleSpace volume.
//
struct _DSCB *Dscb;
//
// The following link connects all DoubleSpace volumes mounted from
// Cvfs on this volume.
//
LIST_ENTRY ParentDscbLinks;
//
// This field contains the "DeviceObject" that this volume is
// currently mounted on. Note that this field can dynamically
// change because of DoubleSpace automount, as opposed to
// Vcb->Vpb->RealDevice which is constant.
//
PDEVICE_OBJECT CurrentDevice;
//
// This is a pointer to the file object and the Fcb which represent the ea data.
//
PFILE_OBJECT VirtualEaFile;
struct _FCB *EaFcb;
//
// The following field is a pointer to the file object that has the
// volume locked. if the VcbState has the locked flag set.
//
PFILE_OBJECT FileObjectWithVcbLocked;
//
// The following is the head of a list of notify Irps.
//
LIST_ENTRY DirNotifyList;
//
// The following is used to synchronize the dir notify list.
//
PNOTIFY_SYNC NotifySync;
//
// The following event is used to synchronize directory stream file
// object creation.
//
KEVENT DirectoryFileCreationEvent;
//
// This field holds the thread address of the current (or most recent
// depending on VcbState) thread doing a verify operation on this volume.
//
PKTHREAD VerifyThread;
//
// The following two structures are used for CleanVolume callbacks.
//
KDPC CleanVolumeDpc;
KTIMER CleanVolumeTimer;
//
// This field records the last time RxMarkVolumeDirty was called, and
// avoids excessive calls to push the CleanVolume forward in time.
//
LARGE_INTEGER LastRxMarkVolumeDirtyCall;
} VCB;
typedef VCB *PVCB;
#define VCB_STATE_FLAG_LOCKED (0x00000001)
#define VCB_STATE_FLAG_REMOVABLE_MEDIA (0x00000002)
#define VCB_STATE_FLAG_VOLUME_DIRTY (0x00000004)
#define VCB_STATE_FLAG_MOUNTED_DIRTY (0x00000010)
#define VCB_STATE_FLAG_SHUTDOWN (0x00000040)
#define VCB_STATE_FLAG_CLOSE_IN_PROGRESS (0x00000080)
#define VCB_STATE_FLAG_DELETED_FCB (0x00000100)
#define VCB_STATE_FLAG_CREATE_IN_PROGRESS (0x00000200)
#define VCB_STATE_FLAG_FLOPPY (0x00000400)
#define VCB_STATE_FLAG_BOOT_OR_PAGING_FILE (0x00000800)
#define VCB_STATE_FLAG_COMPRESSED_VOLUME (0x00001000)
#define VCB_STATE_FLAG_ASYNC_CLOSE_ACTIVE (0x00002000)
#define VCB_STATE_FLAG_WRITE_PROTECTED (0x00004000)
//
// A double space control block for maintaining the double space environment
//
typedef struct _DSCB {
//
// The type and size of this record (must be RDBSS_NTC_DSCB)
//
NODE_TYPE_CODE NodeTypeCode;
NODE_BYTE_SIZE NodeByteSize;
//
// The following field is used to read/write (via pin access) the
// ancillary cvf structures (i.e., the bitmap and rx extensions).
//
//cvfoff PFILE_OBJECT CvfFileObject;
//
// A pointer to the compressed volume control block;
//
PVCB Vcb;
//
// A pointer to our parent volume control block;
//
PVCB ParentVcb;
//
// The following link connects all DoubleSpace volumes mounted from
// Cvfs on our parent's volume.
//
LIST_ENTRY ChildDscbLinks;
//
// This field contains the device object that we created to represent
// the "real" device holding the double space volume.
//
PDEVICE_OBJECT NewDevice;
//
// The following fields contain the unpacked header information for
// the cvf, and the exact layout of each component in the cvf. With
// this information we can always determine the size and location of
// each cvf component.
//
//cvfoff CVF_HEADER CvfHeader;
//cvfoff CVF_LAYOUT CvfLayout;
//
// The following fields describe the shape and size of the virtual rx
// partition
//
struct {
//cvfoff COMPONENT_LOCATION Rx;
//cvfoff COMPONENT_LOCATION RootDirectory;
//cvfoff COMPONENT_LOCATION FileArea;
ULONG BytesPerCluster;
} VfpLayout;
//
// The following fields keep track of allocation information.
//
ULONG SectorsAllocated;
ULONG SectorsRepresented;
#ifdef DOUBLE_SPACE_WRITE
//
// Have a resource that is used to synchronize access to this structure
//
PERESOURCE Resource;
//
// Use a bitmap here to keep track of free sectors
//
RTL_BITMAP Bitmap;
#endif // DOUBLE_SPACE_WRITE
} DSCB;
typedef DSCB *PDSCB;