NTSTATUS NdFatCommonFlushBuffers ( IN PIRP_CONTEXT IrpContext, IN PIRP Irp ) /*++ Routine Description: This is the common routine for flushing a buffer. Arguments: Irp - Supplies the Irp to process Return Value: NTSTATUS - The return status for the operation --*/ { NTSTATUS Status; PIO_STACK_LOCATION IrpSp; PFILE_OBJECT FileObject; TYPE_OF_OPEN TypeOfOpen; PVCB Vcb; PFCB Fcb; PCCB Ccb; BOOLEAN VcbAcquired = FALSE; BOOLEAN FcbAcquired = FALSE; PDIRENT Dirent; PBCB DirentBcb = NULL; PVOLUME_DEVICE_OBJECT volDo = CONTAINING_RECORD( IrpContext->Vcb, VOLUME_DEVICE_OBJECT, Vcb ); BOOLEAN secondarySessionResourceAcquired = FALSE; PSECONDARY_REQUEST secondaryRequest = NULL; PNDFS_REQUEST_HEADER ndfsRequestHeader; PNDFS_WINXP_REQUEST_HEADER ndfsWinxpRequestHeader; PNDFS_WINXP_REPLY_HEADER ndfsWinxpReplytHeader; LARGE_INTEGER timeOut; PAGED_CODE(); IrpSp = IoGetCurrentIrpStackLocation( Irp ); DebugTrace(+1, Dbg, "FatCommonFlushBuffers\n", 0); DebugTrace( 0, Dbg, "Irp = %08lx\n", Irp); DebugTrace( 0, Dbg, "->FileObject = %08lx\n", IrpSp->FileObject); // // Extract and decode the file object // FileObject = IrpSp->FileObject; TypeOfOpen = FatDecodeFileObject( FileObject, &Vcb, &Fcb, &Ccb ); // // CcFlushCache is always synchronous, so if we can't wait enqueue // the irp to the Fsp. // if ( !FlagOn(IrpContext->Flags, IRP_CONTEXT_FLAG_WAIT) ) { Status = FatFsdPostRequest( IrpContext, Irp ); DebugTrace(-1, Dbg, "FatCommonFlushBuffers -> %08lx\n", Status ); return Status; } Status = STATUS_SUCCESS; try { if (!FlagOn(Ccb->NdFatFlags, ND_FAT_CCB_FLAG_UNOPENED)) { do { secondarySessionResourceAcquired = SecondaryAcquireResourceExclusiveLite( IrpContext, &volDo->Secondary->SessionResource, BooleanFlagOn(IrpContext->Flags, IRP_CONTEXT_FLAG_WAIT) ); if (FlagOn(volDo->Secondary->Thread.Flags, SECONDARY_THREAD_FLAG_REMOTE_DISCONNECTED) ) { PrintIrp( Dbg2, "SECONDARY_THREAD_FLAG_REMOTE_DISCONNECTED", NULL, IrpContext->OriginatingIrp ); FatRaiseStatus( IrpContext, STATUS_CANT_WAIT ); } secondaryRequest = ALLOC_WINXP_SECONDARY_REQUEST( volDo->Secondary, IRP_MJ_FLUSH_BUFFERS, 0 ); if (secondaryRequest == NULL) { Status = STATUS_INSUFFICIENT_RESOURCES; break; } ndfsRequestHeader = &secondaryRequest->NdfsRequestHeader; INITIALIZE_NDFS_REQUEST_HEADER( ndfsRequestHeader, NDFS_COMMAND_EXECUTE, volDo->Secondary, IRP_MJ_FLUSH_BUFFERS, 0 ); ndfsWinxpRequestHeader = (PNDFS_WINXP_REQUEST_HEADER)(ndfsRequestHeader+1); ASSERT( ndfsWinxpRequestHeader == (PNDFS_WINXP_REQUEST_HEADER)secondaryRequest->NdfsRequestData ); INITIALIZE_NDFS_WINXP_REQUEST_HEADER( ndfsWinxpRequestHeader, IrpContext->OriginatingIrp, IoGetCurrentIrpStackLocation(IrpContext->OriginatingIrp), Ccb->PrimaryFileHandle ); ASSERT( !ExIsResourceAcquiredSharedLite(&IrpContext->Vcb->Resource) ); secondaryRequest->RequestType = SECONDARY_REQ_SEND_MESSAGE; QueueingSecondaryRequest( volDo->Secondary, secondaryRequest ); timeOut.QuadPart = -NDFAT_TIME_OUT; Status = KeWaitForSingleObject( &secondaryRequest->CompleteEvent, Executive, KernelMode, FALSE, &timeOut ); if (Status != STATUS_SUCCESS) { ASSERT( NDFAT_BUG ); break; } KeClearEvent (&secondaryRequest->CompleteEvent); if (BooleanFlagOn(volDo->Secondary->Thread.Flags, SECONDARY_THREAD_FLAG_REMOTE_DISCONNECTED)) { FatRaiseStatus( IrpContext, STATUS_CANT_WAIT ); } if (secondaryRequest->ExecuteStatus == STATUS_SUCCESS) { ndfsWinxpReplytHeader = (PNDFS_WINXP_REPLY_HEADER)secondaryRequest->NdfsReplyData; ASSERT(ndfsWinxpReplytHeader->Status == STATUS_SUCCESS); } if (secondaryRequest) { DereferenceSecondaryRequest( secondaryRequest ); secondaryRequest = NULL; } if ( secondarySessionResourceAcquired == TRUE ) { SecondaryReleaseResourceLite( IrpContext, &volDo->Secondary->SessionResource ); secondarySessionResourceAcquired = FALSE; } break; } while(0); } Status = STATUS_SUCCESS; // // Case on the type of open that we are trying to flush // switch (TypeOfOpen) { case VirtualVolumeFile: case EaFile: case DirectoryFile: DebugTrace(0, Dbg, "Flush that does nothing\n", 0); break; case UserFileOpen: DebugTrace(0, Dbg, "Flush User File Open\n", 0); (VOID)FatAcquireExclusiveFcb( IrpContext, Fcb ); FcbAcquired = TRUE; FatVerifyFcb( IrpContext, Fcb ); // // If the file is cached then flush its cache // Status = FatFlushFile( IrpContext, Fcb, Flush ); // // Also update and flush the file's dirent in the parent directory if the // file flush worked. // if (NT_SUCCESS( Status )) { // // Insure that we get the filesize to disk correctly. This is // benign if it was already good. // // (why do we need to do this?) // SetFlag(FileObject->Flags, FO_FILE_SIZE_CHANGED); #if 0 FatUpdateDirentFromFcb( IrpContext, FileObject, Fcb, Ccb ); #endif // // Flush the volume file to get any allocation information // updates to disk. // if (FlagOn(Fcb->FcbState, FCB_STATE_FLUSH_FAT)) { Status = FatFlushFat( IrpContext, Vcb ); ClearFlag(Fcb->FcbState, FCB_STATE_FLUSH_FAT); } // // Set the write through bit so that these modifications // will be completed with the request. // SetFlag(IrpContext->Flags, IRP_CONTEXT_FLAG_WRITE_THROUGH); } break; case UserDirectoryOpen: // // If the user had opened the root directory then we'll // oblige by flushing the volume. // if (NodeType(Fcb) != FAT_NTC_ROOT_DCB) { DebugTrace(0, Dbg, "Flush a directory does nothing\n", 0); break; } case UserVolumeOpen: DebugTrace(0, Dbg, "Flush User Volume Open, or root dcb\n", 0); // // Acquire exclusive access to the Vcb. // { BOOLEAN Finished; Finished = FatAcquireExclusiveSecondaryVcb( IrpContext, Vcb ); ASSERT( Finished ); } VcbAcquired = TRUE; // // Mark the volume clean and then flush the volume file, // and then all directories // Status = FatFlushVolume( IrpContext, Vcb, Flush ); // // If the volume was dirty, do the processing that the delayed // callback would have done. // if (FlagOn(Vcb->VcbState, VCB_STATE_FLAG_VOLUME_DIRTY)) { // // Cancel any pending clean volumes. // (VOID)KeCancelTimer( &Vcb->CleanVolumeTimer ); (VOID)KeRemoveQueueDpc( &Vcb->CleanVolumeDpc ); // // The volume is now clean, note it. // if (!FlagOn(Vcb->VcbState, VCB_STATE_FLAG_MOUNTED_DIRTY)) { FatMarkVolume( IrpContext, Vcb, VolumeClean ); ClearFlag( Vcb->VcbState, VCB_STATE_FLAG_VOLUME_DIRTY ); } // // Unlock the volume if it is removable. // if (FlagOn(Vcb->VcbState, VCB_STATE_FLAG_REMOVABLE_MEDIA) && !FlagOn(Vcb->VcbState, VCB_STATE_FLAG_BOOT_OR_PAGING_FILE)) { FatToggleMediaEjectDisable( IrpContext, Vcb, FALSE ); } } break; default: FatBugCheck( TypeOfOpen, 0, 0 ); } FatUnpinBcb( IrpContext, DirentBcb ); FatUnpinRepinnedBcbs( IrpContext ); } finally { DebugUnwind( FatCommonFlushBuffers ); if (secondaryRequest) DereferenceSecondaryRequest( secondaryRequest ); if (secondarySessionResourceAcquired) { SecondaryReleaseResourceLite( IrpContext, &volDo->Secondary->SessionResource ); } FatUnpinBcb( IrpContext, DirentBcb ); if (VcbAcquired) { FatReleaseSecondaryVcb( IrpContext, Vcb ); } if (FcbAcquired) { FatReleaseFcb( IrpContext, Fcb ); } // // If this is a normal termination then pass the request on // to the target device object. // if (!AbnormalTermination()) { NTSTATUS DriverStatus; PIO_STACK_LOCATION NextIrpSp; // // Get the next stack location, and copy over the stack location // NextIrpSp = IoGetNextIrpStackLocation( Irp ); *NextIrpSp = *IrpSp; // // Set up the completion routine // IoSetCompletionRoutine( Irp, FatFlushCompletionRoutine, ULongToPtr( Status ), TRUE, TRUE, TRUE ); // // Send the request. // DriverStatus = IoCallDriver(Vcb->TargetDeviceObject, Irp); Status = (DriverStatus == STATUS_INVALID_DEVICE_REQUEST) ? Status : DriverStatus; // // Free the IrpContext and return to the caller. // FatCompleteRequest( IrpContext, FatNull, STATUS_SUCCESS ); } DebugTrace(-1, Dbg, "FatCommonFlushBuffers -> %08lx\n", Status); } return Status; }
NTSTATUS FatCommonSetVolumeInfo ( IN PIRP_CONTEXT IrpContext, IN PIRP Irp ) /*++ Routine Description: This is the common routine for setting Volume Information called by both the fsd and fsp threads. Arguments: Irp - Supplies the Irp being processed Return Value: NTSTATUS - The return status for the operation --*/ { NTSTATUS Status; PIO_STACK_LOCATION IrpSp; PVCB Vcb; PFCB Fcb; PCCB Ccb; TYPE_OF_OPEN TypeOfOpen; ULONG Length; FS_INFORMATION_CLASS FsInformationClass; PVOID Buffer; // // Get the current stack location // IrpSp = IoGetCurrentIrpStackLocation( Irp ); DebugTrace(+1, Dbg, "FatCommonSetVolumeInfo...\n", 0); DebugTrace( 0, Dbg, "Irp = %08lx\n", Irp ); DebugTrace( 0, Dbg, "->Length = %08lx\n", IrpSp->Parameters.SetVolume.Length); DebugTrace( 0, Dbg, "->FsInformationClass = %08lx\n", IrpSp->Parameters.SetVolume.FsInformationClass); DebugTrace( 0, Dbg, "->Buffer = %08lx\n", Irp->AssociatedIrp.SystemBuffer); // // Reference our input parameters to make things easier // Length = IrpSp->Parameters.SetVolume.Length; FsInformationClass = IrpSp->Parameters.SetVolume.FsInformationClass; Buffer = Irp->AssociatedIrp.SystemBuffer; // // Decode the file object to get the Vcb // TypeOfOpen = FatDecodeFileObject( IrpSp->FileObject, &Vcb, &Fcb, &Ccb ); if (TypeOfOpen != UserVolumeOpen) { FatCompleteRequest( IrpContext, Irp, STATUS_ACCESS_DENIED ); DebugTrace(-1, Dbg, "FatCommonSetVolumeInfo -> STATUS_ACCESS_DENIED\n", 0); return STATUS_ACCESS_DENIED; } // // Acquire exclusive access to the Vcb and enqueue the Irp if we didn't // get access // if (!FatAcquireExclusiveVcb( IrpContext, Vcb )) { DebugTrace(0, Dbg, "Cannot acquire Vcb\n", 0); Status = FatFsdPostRequest( IrpContext, Irp ); DebugTrace(-1, Dbg, "FatCommonSetVolumeInfo -> %08lx\n", Status ); return Status; } try { // // Make sure the vcb is in a usable condition. This will raise // and error condition if the volume is unusable // // Also verify the Root Dcb since we need info from there. // FatVerifyFcb( IrpContext, Vcb->RootDcb ); // // Based on the information class we'll do different actions. Each // of the procedures that we're calling performs the action if // possible and returns true if it successful and false if it couldn't // wait for any I/O to complete. // switch (FsInformationClass) { case FileFsLabelInformation: Status = FatSetFsLabelInfo( IrpContext, Vcb, Buffer ); break; default: Status = STATUS_INVALID_PARAMETER; break; } FatUnpinRepinnedBcbs( IrpContext ); } finally { DebugUnwind( FatCommonSetVolumeInfo ); FatReleaseVcb( IrpContext, Vcb ); if (!AbnormalTermination()) { FatCompleteRequest( IrpContext, Irp, Status ); } DebugTrace(-1, Dbg, "FatCommonSetVolumeInfo -> %08lx\n", Status); } return Status; }
NTSTATUS NdasFatSecondaryQueryDirectory ( IN PIRP_CONTEXT IrpContext, IN PIRP Irp ) /*++ Routine Description: This routine performs the query directory operation. It is responsible for either completing of enqueuing the input Irp. Arguments: Irp - Supplies the Irp to process Return Value: NTSTATUS - The return status for the operation --*/ { NTSTATUS Status; PIO_STACK_LOCATION IrpSp; PVCB Vcb; PDCB Dcb; PCCB Ccb; PBCB Bcb; ULONG i; PUCHAR Buffer; CLONG UserBufferLength; PUNICODE_STRING UniArgFileName; WCHAR LongFileNameBuffer[ FAT_CREATE_INITIAL_NAME_BUF_SIZE]; UNICODE_STRING LongFileName; FILE_INFORMATION_CLASS FileInformationClass; ULONG FileIndex; BOOLEAN RestartScan; BOOLEAN ReturnSingleEntry; BOOLEAN IndexSpecified; BOOLEAN InitialQuery; VBO CurrentVbo; BOOLEAN UpdateCcb; PDIRENT Dirent; UCHAR Fat8Dot3Buffer[12]; OEM_STRING Fat8Dot3String; ULONG DiskAllocSize; ULONG NextEntry; ULONG LastEntry; PFILE_DIRECTORY_INFORMATION DirInfo; PFILE_FULL_DIR_INFORMATION FullDirInfo; PFILE_BOTH_DIR_INFORMATION BothDirInfo; PFILE_ID_FULL_DIR_INFORMATION IdFullDirInfo; PFILE_ID_BOTH_DIR_INFORMATION IdBothDirInfo; PFILE_NAMES_INFORMATION NamesInfo; #if 1 PVOLUME_DEVICE_OBJECT volDo; BOOLEAN secondarySessionResourceAcquired = FALSE; PSECONDARY_REQUEST secondaryRequest = NULL; PNDFS_REQUEST_HEADER ndfsRequestHeader; PNDFS_WINXP_REQUEST_HEADER ndfsWinxpRequestHeader; PNDFS_WINXP_REPLY_HEADER ndfsWinxpReplytHeader; _U8 *ndfsWinxpRequestData; LARGE_INTEGER timeOut; struct QueryDirectory queryDirectory; PVOID inputBuffer; ULONG inputBufferLength; ULONG returnedDataSize; #endif PAGED_CODE(); // // Get the current Stack location // IrpSp = IoGetCurrentIrpStackLocation( Irp ); // // Display the input values. // DebugTrace(+1, Dbg, "FatQueryDirectory...\n", 0); DebugTrace( 0, Dbg, " Wait = %08lx\n", FlagOn(IrpContext->Flags, IRP_CONTEXT_FLAG_WAIT)); DebugTrace( 0, Dbg, " Irp = %08lx\n", Irp); DebugTrace( 0, Dbg, " ->Length = %08lx\n", IrpSp->Parameters.QueryDirectory.Length); DebugTrace( 0, Dbg, " ->FileName = %08lx\n", IrpSp->Parameters.QueryDirectory.FileName); DebugTrace( 0, Dbg, " ->FileInformationClass = %08lx\n", IrpSp->Parameters.QueryDirectory.FileInformationClass); DebugTrace( 0, Dbg, " ->FileIndex = %08lx\n", IrpSp->Parameters.QueryDirectory.FileIndex); DebugTrace( 0, Dbg, " ->UserBuffer = %08lx\n", Irp->AssociatedIrp.SystemBuffer); DebugTrace( 0, Dbg, " ->RestartScan = %08lx\n", FlagOn( IrpSp->Flags, SL_RESTART_SCAN )); DebugTrace( 0, Dbg, " ->ReturnSingleEntry = %08lx\n", FlagOn( IrpSp->Flags, SL_RETURN_SINGLE_ENTRY )); DebugTrace( 0, Dbg, " ->IndexSpecified = %08lx\n", FlagOn( IrpSp->Flags, SL_INDEX_SPECIFIED )); // // Reference our input parameters to make things easier // UserBufferLength = IrpSp->Parameters.QueryDirectory.Length; FileInformationClass = IrpSp->Parameters.QueryDirectory.FileInformationClass; FileIndex = IrpSp->Parameters.QueryDirectory.FileIndex; UniArgFileName = (PUNICODE_STRING) IrpSp->Parameters.QueryDirectory.FileName; RestartScan = BooleanFlagOn(IrpSp->Flags, SL_RESTART_SCAN); ReturnSingleEntry = BooleanFlagOn(IrpSp->Flags, SL_RETURN_SINGLE_ENTRY); IndexSpecified = BooleanFlagOn(IrpSp->Flags, SL_INDEX_SPECIFIED); // // Check on the type of open. We return invalid parameter for all // but UserDirectoryOpens. Also check that the filename is a valid // UNICODE string. // if (FatDecodeFileObject( IrpSp->FileObject, &Vcb, &Dcb, &Ccb) != UserDirectoryOpen || (UniArgFileName && UniArgFileName->Length % sizeof(WCHAR))) { FatCompleteRequest( IrpContext, Irp, STATUS_INVALID_PARAMETER ); DebugTrace(-1, Dbg, "FatQueryDirectory -> STATUS_INVALID_PARAMETER\n", 0); return STATUS_INVALID_PARAMETER; } #if 1 if (FlagOn(Ccb->NdasFatFlags, ND_FAT_CCB_FLAG_UNOPENED)) { ASSERT( FlagOn(Ccb->NdasFatFlags, ND_FAT_CCB_FLAG_CORRUPTED) ); FatCompleteRequest( IrpContext, Irp, STATUS_FILE_CORRUPT_ERROR ); DebugTrace2( -1, Dbg, ("NtfsCommonDirectoryControl -> STATUS_FILE_CORRUPT_ERROR\n") ); return STATUS_FILE_CORRUPT_ERROR; } #endif // // Initialize the local variables. // Bcb = NULL; UpdateCcb = TRUE; Dirent = NULL; Fat8Dot3String.MaximumLength = 12; Fat8Dot3String.Buffer = Fat8Dot3Buffer; LongFileName.Length = 0; LongFileName.MaximumLength = sizeof( LongFileNameBuffer); LongFileName.Buffer = LongFileNameBuffer; InitialQuery = (BOOLEAN)((Ccb->UnicodeQueryTemplate.Buffer == NULL) && !FlagOn(Ccb->Flags, CCB_FLAG_MATCH_ALL)); Status = STATUS_SUCCESS; Irp->IoStatus.Information = 0; DiskAllocSize = 1 << Vcb->AllocationSupport.LogOfBytesPerCluster; // // If this is the initial query, then grab exclusive access in // order to update the search string in the Ccb. We may // discover that we are not the initial query once we grab the Fcb // and downgrade our status. // if (InitialQuery) { if (!FatAcquireExclusiveFcb( IrpContext, Dcb )) { DebugTrace(0, Dbg, "FatQueryDirectory -> Enqueue to Fsp\n", 0); Status = FatFsdPostRequest( IrpContext, Irp ); DebugTrace(-1, Dbg, "FatQueryDirectory -> %08lx\n", Status); return Status; } if (Ccb->UnicodeQueryTemplate.Buffer != NULL) { InitialQuery = FALSE; FatConvertToSharedFcb( IrpContext, Dcb ); } } else { if (!FatAcquireSharedFcb( IrpContext, Dcb )) { DebugTrace(0, Dbg, "FatQueryDirectory -> Enqueue to Fsp\n", 0); Status = FatFsdPostRequest( IrpContext, Irp ); DebugTrace(-1, Dbg, "FatQueryDirectory -> %08lx\n", Status); return Status; } } try { ULONG BaseLength; ULONG BytesConverted; // // If we are in the Fsp now because we had to wait earlier, // we must map the user buffer, otherwise we can use the // user's buffer directly. // Buffer = FatMapUserBuffer( IrpContext, Irp ); #if 1 volDo = CONTAINING_RECORD( Vcb, VOLUME_DEVICE_OBJECT, Vcb ); secondarySessionResourceAcquired = SecondaryAcquireResourceExclusiveLite( IrpContext, &volDo->SessionResource, BooleanFlagOn(IrpContext->Flags, IRP_CONTEXT_FLAG_WAIT) ); if (FlagOn(volDo->Secondary->Thread.Flags, SECONDARY_THREAD_FLAG_REMOTE_DISCONNECTED)) { NDASFAT_ASSERT( FlagOn(IrpContext->Flags, IRP_CONTEXT_FLAG_WAIT) ); SetFlag( IrpContext->NdasFatFlags, NDAS_FAT_IRP_CONTEXT_FLAG_DONT_POST_REQUEST ); FatRaiseStatus( IrpContext, STATUS_CANT_WAIT ); } queryDirectory.FileIndex = IrpSp->Parameters.QueryDirectory.FileIndex; queryDirectory.FileInformationClass = IrpSp->Parameters.QueryDirectory.FileInformationClass; queryDirectory.FileName = IrpSp->Parameters.QueryDirectory.FileName; queryDirectory.Length = IrpSp->Parameters.QueryDirectory.Length; inputBuffer = (queryDirectory.FileName) ? (queryDirectory.FileName->Buffer) : NULL; inputBufferLength = (queryDirectory.FileName) ? (queryDirectory.FileName->Length) : 0; if (queryDirectory.FileName) { DebugTrace2( 0, Dbg, ("NdNtfsSecondaryQueryDirectory: queryFileName = %wZ\n", queryDirectory.FileName) ); } ASSERT( inputBufferLength <= volDo->Secondary->Thread.SessionContext.PrimaryMaxDataSize ); ASSERT( UserBufferLength <= volDo->Secondary->Thread.SessionContext.SecondaryMaxDataSize ); secondaryRequest = AllocateWinxpSecondaryRequest( volDo->Secondary, IRP_MJ_DIRECTORY_CONTROL, ((inputBufferLength > UserBufferLength) ? inputBufferLength : UserBufferLength) ); if (secondaryRequest == NULL) { try_return( Status = STATUS_INSUFFICIENT_RESOURCES ); } ndfsRequestHeader = &secondaryRequest->NdfsRequestHeader; INITIALIZE_NDFS_REQUEST_HEADER( ndfsRequestHeader, NDFS_COMMAND_EXECUTE, volDo->Secondary, IRP_MJ_DIRECTORY_CONTROL, inputBufferLength ); ndfsWinxpRequestHeader = (PNDFS_WINXP_REQUEST_HEADER)(ndfsRequestHeader+1); ASSERT( ndfsWinxpRequestHeader == (PNDFS_WINXP_REQUEST_HEADER)secondaryRequest->NdfsRequestData ); INITIALIZE_NDFS_WINXP_REQUEST_HEADER( ndfsWinxpRequestHeader, Irp, IrpSp, Ccb->PrimaryFileHandle ); ndfsWinxpRequestHeader->QueryDirectory.Length = UserBufferLength; ndfsWinxpRequestHeader->QueryDirectory.FileInformationClass = queryDirectory.FileInformationClass; ndfsWinxpRequestHeader->QueryDirectory.FileIndex = queryDirectory.FileIndex; ndfsWinxpRequestData = (_U8 *)(ndfsWinxpRequestHeader+1); if (inputBufferLength) RtlCopyMemory( ndfsWinxpRequestData, inputBuffer, inputBufferLength ); secondaryRequest->RequestType = SECONDARY_REQ_SEND_MESSAGE; QueueingSecondaryRequest( volDo->Secondary, secondaryRequest ); timeOut.QuadPart = -NDASFAT_TIME_OUT; Status = KeWaitForSingleObject( &secondaryRequest->CompleteEvent, Executive, KernelMode, FALSE, &timeOut ); KeClearEvent( &secondaryRequest->CompleteEvent ); if (Status != STATUS_SUCCESS) { secondaryRequest = NULL; try_return( Status = STATUS_IO_DEVICE_ERROR ); } SecondaryReleaseResourceLite( IrpContext, &volDo->SessionResource ); secondarySessionResourceAcquired = FALSE; if (secondaryRequest->ExecuteStatus != STATUS_SUCCESS) { if (IrpContext->OriginatingIrp) PrintIrp( Dbg2, "secondaryRequest->ExecuteStatus != STATUS_SUCCESS", NULL, IrpContext->OriginatingIrp ); DebugTrace2( 0, Dbg2, ("secondaryRequest->ExecuteStatus != STATUS_SUCCESS file = %s, line = %d\n", __FILE__, __LINE__) ); NDASFAT_ASSERT( FlagOn(IrpContext->Flags, IRP_CONTEXT_FLAG_WAIT) ); SetFlag( IrpContext->NdasFatFlags, NDAS_FAT_IRP_CONTEXT_FLAG_DONT_POST_REQUEST ); FatRaiseStatus( IrpContext, STATUS_CANT_WAIT ); } ndfsWinxpReplytHeader = (PNDFS_WINXP_REPLY_HEADER)secondaryRequest->NdfsReplyData; Status = Irp->IoStatus.Status = ndfsWinxpReplytHeader->Status; Irp->IoStatus.Information = ndfsWinxpReplytHeader->Information; returnedDataSize = secondaryRequest->NdfsReplyHeader.MessageSize - sizeof(NDFS_REPLY_HEADER) - sizeof(NDFS_WINXP_REPLY_HEADER); if (returnedDataSize) { ASSERT( ndfsWinxpReplytHeader->Information != 0 ); ASSERT(returnedDataSize <= ADD_ALIGN8(queryDirectory.Length)); ASSERT( Buffer ); RtlCopyMemory( Buffer, (_U8 *)(ndfsWinxpReplytHeader+1), (returnedDataSize < queryDirectory.Length) ? returnedDataSize : queryDirectory.Length ); } #endif #if 0 // // Make sure the Dcb is still good. // FatVerifyFcb( IrpContext, Dcb ); // // Determine where to start the scan. Highest priority is given // to the file index. Lower priority is the restart flag. If // neither of these is specified, then the Vbo offset field in the // Ccb is used. // if (IndexSpecified) { CurrentVbo = FileIndex + sizeof( DIRENT ); } else if (RestartScan) { CurrentVbo = 0; } else { CurrentVbo = Ccb->OffsetToStartSearchFrom; } // // If this is the first try then allocate a buffer for the file // name. // if (InitialQuery) { // // If either: // // - No name was specified // - An empty name was specified // - We received a '*' // - The user specified the DOS equivolent of ????????.??? // // then match all names. // if ((UniArgFileName == NULL) || (UniArgFileName->Length == 0) || (UniArgFileName->Buffer == NULL) || ((UniArgFileName->Length == sizeof(WCHAR)) && (UniArgFileName->Buffer[0] == L'*')) || ((UniArgFileName->Length == 12*sizeof(WCHAR)) && (RtlEqualMemory( UniArgFileName->Buffer, Fat8QMdot3QM, 12*sizeof(WCHAR) )))) { Ccb->ContainsWildCards = TRUE; SetFlag( Ccb->Flags, CCB_FLAG_MATCH_ALL ); } else { BOOLEAN ExtendedName = FALSE; OEM_STRING LocalBestFit; // // First and formost, see if the name has wild cards. // Ccb->ContainsWildCards = FsRtlDoesNameContainWildCards( UniArgFileName ); // // Now check to see if the name contains any extended // characters // for (i=0; i < UniArgFileName->Length / sizeof(WCHAR); i++) { if (UniArgFileName->Buffer[i] >= 0x80) { ExtendedName = TRUE; break; } } // // OK, now do the conversions we need. // if (ExtendedName) { Status = RtlUpcaseUnicodeString( &Ccb->UnicodeQueryTemplate, UniArgFileName, TRUE ); if (!NT_SUCCESS(Status)) { try_return( Status ); } SetFlag( Ccb->Flags, CCB_FLAG_FREE_UNICODE ); // // Upcase the name and convert it to the Oem code page. // Status = RtlUpcaseUnicodeStringToCountedOemString( &LocalBestFit, UniArgFileName, TRUE ); // // If this conversion failed for any reason other than // an unmappable character fail the request. // if (!NT_SUCCESS(Status)) { if (Status == STATUS_UNMAPPABLE_CHARACTER) { SetFlag( Ccb->Flags, CCB_FLAG_SKIP_SHORT_NAME_COMPARE ); } else { try_return( Status ); } } else { SetFlag( Ccb->Flags, CCB_FLAG_FREE_OEM_BEST_FIT ); } } else { PVOID Buffers; // // This case is optimized because I know I only have to // worry about a-z. // Buffers = FsRtlAllocatePoolWithTag( PagedPool, UniArgFileName->Length + UniArgFileName->Length / sizeof(WCHAR), TAG_FILENAME_BUFFER ); Ccb->UnicodeQueryTemplate.Buffer = Buffers; Ccb->UnicodeQueryTemplate.Length = UniArgFileName->Length; Ccb->UnicodeQueryTemplate.MaximumLength = UniArgFileName->Length; LocalBestFit.Buffer = (PUCHAR)Buffers + UniArgFileName->Length; LocalBestFit.Length = UniArgFileName->Length / sizeof(WCHAR); LocalBestFit.MaximumLength = LocalBestFit.Length; SetFlag( Ccb->Flags, CCB_FLAG_FREE_UNICODE ); for (i=0; i < UniArgFileName->Length / sizeof(WCHAR); i++) { WCHAR c = UniArgFileName->Buffer[i]; LocalBestFit.Buffer[i] = (UCHAR) (Ccb->UnicodeQueryTemplate.Buffer[i] = (c < 'a' ? c : c <= 'z' ? c - ('a' - 'A') : c)); } } // // At this point we now have the upcased unicode name, // and the two Oem names if they could be represented in // this code page. // // Now determine if the Oem names are legal for what we // going to try and do. Mark them as not usable is they // are not legal. Note that we can optimize extended names // since they are actually both the same string. // if (!FlagOn( Ccb->Flags, CCB_FLAG_SKIP_SHORT_NAME_COMPARE ) && !FatIsNameShortOemValid( IrpContext, LocalBestFit, Ccb->ContainsWildCards, FALSE, FALSE )) { if (ExtendedName) { RtlFreeOemString( &LocalBestFit ); ClearFlag( Ccb->Flags, CCB_FLAG_FREE_OEM_BEST_FIT ); } SetFlag( Ccb->Flags, CCB_FLAG_SKIP_SHORT_NAME_COMPARE ); } // // OK, now both locals oem strings correctly reflect their // usability. Now we want to load up the Ccb structure. // // Now we will branch on two paths of wheather the name // is wild or not. // if (!FlagOn( Ccb->Flags, CCB_FLAG_SKIP_SHORT_NAME_COMPARE )) { if (Ccb->ContainsWildCards) { Ccb->OemQueryTemplate.Wild = LocalBestFit; } else { FatStringTo8dot3( IrpContext, LocalBestFit, &Ccb->OemQueryTemplate.Constant ); if (FlagOn(Ccb->Flags, CCB_FLAG_FREE_OEM_BEST_FIT)) { RtlFreeOemString( &LocalBestFit ); ClearFlag( Ccb->Flags, CCB_FLAG_FREE_OEM_BEST_FIT ); } } } } // // We convert to shared access. // FatConvertToSharedFcb( IrpContext, Dcb ); } LastEntry = 0; NextEntry = 0; switch (FileInformationClass) { case FileDirectoryInformation: BaseLength = FIELD_OFFSET( FILE_DIRECTORY_INFORMATION, FileName[0] ); break; case FileFullDirectoryInformation: BaseLength = FIELD_OFFSET( FILE_FULL_DIR_INFORMATION, FileName[0] ); break; case FileIdFullDirectoryInformation: BaseLength = FIELD_OFFSET( FILE_ID_FULL_DIR_INFORMATION, FileName[0] ); break; case FileNamesInformation: BaseLength = FIELD_OFFSET( FILE_NAMES_INFORMATION, FileName[0] ); break; case FileBothDirectoryInformation: BaseLength = FIELD_OFFSET( FILE_BOTH_DIR_INFORMATION, FileName[0] ); break; case FileIdBothDirectoryInformation: BaseLength = FIELD_OFFSET( FILE_ID_BOTH_DIR_INFORMATION, FileName[0] ); break; default: try_return( Status = STATUS_INVALID_INFO_CLASS ); } // // At this point we are about to enter our query loop. We have // determined the index into the directory file to begin the // search. LastEntry and NextEntry are used to index into the user // buffer. LastEntry is the last entry we've added, NextEntry is // current one we're working on. If NextEntry is non-zero, then // at least one entry was added. // while ( TRUE ) { VBO NextVbo; ULONG FileNameLength; ULONG BytesRemainingInBuffer; DebugTrace(0, Dbg, "FatQueryDirectory -> Top of loop\n", 0); // // If the user had requested only a single match and we have // returned that, then we stop at this point. // if (ReturnSingleEntry && NextEntry != 0) { try_return( Status ); } // // We call FatLocateDirent to lock down the next matching dirent. // FatLocateDirent( IrpContext, Dcb, Ccb, CurrentVbo, &Dirent, &Bcb, &NextVbo, NULL, &LongFileName); // // If we didn't receive a dirent, then we are at the end of the // directory. If we have returned any files, we exit with // success, otherwise we return STATUS_NO_MORE_FILES. // if (!Dirent) { DebugTrace(0, Dbg, "FatQueryDirectory -> No dirent\n", 0); if (NextEntry == 0) { UpdateCcb = FALSE; if (InitialQuery) { Status = STATUS_NO_SUCH_FILE; } else { Status = STATUS_NO_MORE_FILES; } } try_return( Status ); } // // Protect access to the user buffer with an exception handler. // Since (at our request) IO doesn't buffer these requests, we have // to guard against a user messing with the page protection and other // such trickery. // try { if (LongFileName.Length == 0) { // // Now we have an entry to return to our caller. We'll convert // the name from the form in the dirent to a <name>.<ext> form. // We'll case on the type of information requested and fill up // the user buffer if everything fits. // Fat8dot3ToString( IrpContext, Dirent, TRUE, &Fat8Dot3String ); // // Determine the UNICODE length of the file name. // FileNameLength = RtlOemStringToCountedUnicodeSize(&Fat8Dot3String); // // Here are the rules concerning filling up the buffer: // // 1. The Io system garentees that there will always be // enough room for at least one base record. // // 2. If the full first record (including file name) cannot // fit, as much of the name as possible is copied and // STATUS_BUFFER_OVERFLOW is returned. // // 3. If a subsequent record cannot completely fit into the // buffer, none of it (as in 0 bytes) is copied, and // STATUS_SUCCESS is returned. A subsequent query will // pick up with this record. // BytesRemainingInBuffer = UserBufferLength - NextEntry; if ( (NextEntry != 0) && ( (BaseLength + FileNameLength > BytesRemainingInBuffer) || (UserBufferLength < NextEntry) ) ) { DebugTrace(0, Dbg, "Next entry won't fit\n", 0); try_return( Status = STATUS_SUCCESS ); } ASSERT( BytesRemainingInBuffer >= BaseLength ); // // Zero the base part of the structure. // RtlZeroMemory( &Buffer[NextEntry], BaseLength ); switch ( FileInformationClass ) { // // Now fill the base parts of the strucure that are applicable. // case FileBothDirectoryInformation: case FileFullDirectoryInformation: case FileIdBothDirectoryInformation: case FileIdFullDirectoryInformation: DebugTrace(0, Dbg, "FatQueryDirectory -> Getting file full directory information\n", 0); // // Get the Ea file length. // FullDirInfo = (PFILE_FULL_DIR_INFORMATION)&Buffer[NextEntry]; // // If the EAs are corrupt, ignore the error. We don't want // to abort the directory query. // try { FatGetEaLength( IrpContext, Vcb, Dirent, &FullDirInfo->EaSize ); } except(EXCEPTION_EXECUTE_HANDLER) { FatResetExceptionState( IrpContext ); FullDirInfo->EaSize = 0; } case FileDirectoryInformation: DirInfo = (PFILE_DIRECTORY_INFORMATION)&Buffer[NextEntry]; FatGetDirTimes( IrpContext, Dirent, DirInfo ); DirInfo->EndOfFile.QuadPart = Dirent->FileSize; if (!FlagOn( Dirent->Attributes, FAT_DIRENT_ATTR_DIRECTORY )) { DirInfo->AllocationSize.QuadPart = (((Dirent->FileSize + DiskAllocSize - 1) / DiskAllocSize) * DiskAllocSize ); } DirInfo->FileAttributes = Dirent->Attributes != 0 ? Dirent->Attributes : FILE_ATTRIBUTE_NORMAL; DirInfo->FileIndex = NextVbo; DirInfo->FileNameLength = FileNameLength; DebugTrace(0, Dbg, "FatQueryDirectory -> Name = \"%Z\"\n", &Fat8Dot3String); break; case FileNamesInformation: DebugTrace(0, Dbg, "FatQueryDirectory -> Getting file names information\n", 0); NamesInfo = (PFILE_NAMES_INFORMATION)&Buffer[NextEntry]; NamesInfo->FileIndex = NextVbo; NamesInfo->FileNameLength = FileNameLength; DebugTrace(0, Dbg, "FatQueryDirectory -> Name = \"%Z\"\n", &Fat8Dot3String ); break; default: FatBugCheck( FileInformationClass, 0, 0 ); } BytesConverted = 0; Status = RtlOemToUnicodeN( (PWCH)&Buffer[NextEntry + BaseLength], BytesRemainingInBuffer - BaseLength, &BytesConverted, Fat8Dot3String.Buffer, Fat8Dot3String.Length ); // // Check for the case that a single entry doesn't fit. // This should only get this far on the first entry // if (BytesConverted < FileNameLength) { ASSERT( NextEntry == 0 ); Status = STATUS_BUFFER_OVERFLOW; } // // Set up the previous next entry offset // *((PULONG)(&Buffer[LastEntry])) = NextEntry - LastEntry; // // And indicate how much of the user buffer we have currently // used up. We must compute this value before we long align // ourselves for the next entry // Irp->IoStatus.Information = QuadAlign( Irp->IoStatus.Information ) + BaseLength + BytesConverted; // // If something happened with the conversion, bail here. // if ( !NT_SUCCESS( Status ) ) { try_return( NOTHING ); } } else { ULONG ShortNameLength; FileNameLength = LongFileName.Length; // // Here are the rules concerning filling up the buffer: // // 1. The Io system garentees that there will always be // enough room for at least one base record. // // 2. If the full first record (including file name) cannot // fit, as much of the name as possible is copied and // STATUS_BUFFER_OVERFLOW is returned. // // 3. If a subsequent record cannot completely fit into the // buffer, none of it (as in 0 bytes) is copied, and // STATUS_SUCCESS is returned. A subsequent query will // pick up with this record. // BytesRemainingInBuffer = UserBufferLength - NextEntry; if ( (NextEntry != 0) && ( (BaseLength + FileNameLength > BytesRemainingInBuffer) || (UserBufferLength < NextEntry) ) ) { DebugTrace(0, Dbg, "Next entry won't fit\n", 0); try_return( Status = STATUS_SUCCESS ); } ASSERT( BytesRemainingInBuffer >= BaseLength ); // // Zero the base part of the structure. // RtlZeroMemory( &Buffer[NextEntry], BaseLength ); switch ( FileInformationClass ) { // // Now fill the base parts of the strucure that are applicable. // case FileBothDirectoryInformation: case FileIdBothDirectoryInformation: BothDirInfo = (PFILE_BOTH_DIR_INFORMATION)&Buffer[NextEntry]; // // Now we have an entry to return to our caller. We'll convert // the name from the form in the dirent to a <name>.<ext> form. // We'll case on the type of information requested and fill up // the user buffer if everything fits. // Fat8dot3ToString( IrpContext, Dirent, FALSE, &Fat8Dot3String ); ASSERT( Fat8Dot3String.Length <= 12 ); Status = RtlOemToUnicodeN( &BothDirInfo->ShortName[0], 12*sizeof(WCHAR), &ShortNameLength, Fat8Dot3String.Buffer, Fat8Dot3String.Length ); ASSERT( Status != STATUS_BUFFER_OVERFLOW ); ASSERT( ShortNameLength <= 12*sizeof(WCHAR) ); // // Copy the length into the dirinfo structure. Note // that the LHS below is a USHORT, so it can not // be specificed as the OUT parameter above. // BothDirInfo->ShortNameLength = (UCHAR)ShortNameLength; // // If something happened with the conversion, bail here. // if ( !NT_SUCCESS( Status ) ) { try_return( NOTHING ); } case FileFullDirectoryInformation: case FileIdFullDirectoryInformation: DebugTrace(0, Dbg, "FatQueryDirectory -> Getting file full directory information\n", 0); // // Get the Ea file length. // FullDirInfo = (PFILE_FULL_DIR_INFORMATION)&Buffer[NextEntry]; // // If the EAs are corrupt, ignore the error. We don't want // to abort the directory query. // try { FatGetEaLength( IrpContext, Vcb, Dirent, &FullDirInfo->EaSize ); } except(EXCEPTION_EXECUTE_HANDLER) { FatResetExceptionState( IrpContext ); FullDirInfo->EaSize = 0; } case FileDirectoryInformation: DirInfo = (PFILE_DIRECTORY_INFORMATION)&Buffer[NextEntry]; FatGetDirTimes( IrpContext, Dirent, DirInfo ); DirInfo->EndOfFile.QuadPart = Dirent->FileSize; if (!FlagOn( Dirent->Attributes, FAT_DIRENT_ATTR_DIRECTORY )) { DirInfo->AllocationSize.QuadPart = ( (( Dirent->FileSize + DiskAllocSize - 1 ) / DiskAllocSize ) * DiskAllocSize ); } DirInfo->FileAttributes = Dirent->Attributes != 0 ? Dirent->Attributes : FILE_ATTRIBUTE_NORMAL; DirInfo->FileIndex = NextVbo; DirInfo->FileNameLength = FileNameLength; DebugTrace(0, Dbg, "FatQueryDirectory -> Name = \"%Z\"\n", &Fat8Dot3String); break; case FileNamesInformation: DebugTrace(0, Dbg, "FatQueryDirectory -> Getting file names information\n", 0); NamesInfo = (PFILE_NAMES_INFORMATION)&Buffer[NextEntry]; NamesInfo->FileIndex = NextVbo; NamesInfo->FileNameLength = FileNameLength; DebugTrace(0, Dbg, "FatQueryDirectory -> Name = \"%Z\"\n", &Fat8Dot3String ); break; default: FatBugCheck( FileInformationClass, 0, 0 ); } BytesConverted = BytesRemainingInBuffer - BaseLength >= FileNameLength ? FileNameLength : BytesRemainingInBuffer - BaseLength; RtlCopyMemory( &Buffer[NextEntry + BaseLength], &LongFileName.Buffer[0], BytesConverted ); // // Set up the previous next entry offset // *((PULONG)(&Buffer[LastEntry])) = NextEntry - LastEntry; // // And indicate how much of the user buffer we have currently // used up. We must compute this value before we long align // ourselves for the next entry // Irp->IoStatus.Information = QuadAlign( Irp->IoStatus.Information ) + BaseLength + BytesConverted; // // Check for the case that a single entry doesn't fit. // This should only get this far on the first entry. // if (BytesConverted < FileNameLength) { ASSERT( NextEntry == 0 ); try_return( Status = STATUS_BUFFER_OVERFLOW ); } } // // Finish up by filling in the FileId // switch ( FileInformationClass ) { case FileIdBothDirectoryInformation: IdBothDirInfo = (PFILE_ID_BOTH_DIR_INFORMATION)&Buffer[NextEntry]; IdBothDirInfo->FileId.QuadPart = FatGenerateFileIdFromDirentAndOffset( Dcb, Dirent, NextVbo ); break; case FileIdFullDirectoryInformation: IdFullDirInfo = (PFILE_ID_FULL_DIR_INFORMATION)&Buffer[NextEntry]; IdFullDirInfo->FileId.QuadPart = FatGenerateFileIdFromDirentAndOffset( Dcb, Dirent, NextVbo ); break; default: break; } } except (EXCEPTION_EXECUTE_HANDLER) { // // We had a problem filling in the user's buffer, so stop and // fail this request. This is the only reason any exception // would have occured at this level. // Irp->IoStatus.Information = 0; UpdateCcb = FALSE; try_return( Status = GetExceptionCode()); } // // Set ourselves up for the next iteration // LastEntry = NextEntry; NextEntry += (ULONG)QuadAlign(BaseLength + BytesConverted); CurrentVbo = NextVbo + sizeof( DIRENT ); } #endif try_exit: NOTHING; } finally {
NTSTATUS FatCommonQueryVolumeInfo ( IN PIRP_CONTEXT IrpContext, IN PIRP Irp ) /*++ Routine Description: This is the common routine for querying volume information called by both the fsd and fsp threads. Arguments: Irp - Supplies the Irp being processed Return Value: NTSTATUS - The return status for the operation --*/ { NTSTATUS Status; PIO_STACK_LOCATION IrpSp; PVCB Vcb; PFCB Fcb; PCCB Ccb; ULONG Length; FS_INFORMATION_CLASS FsInformationClass; PVOID Buffer; BOOLEAN WeAcquiredVcb = FALSE; // // Get the current stack location // IrpSp = IoGetCurrentIrpStackLocation( Irp ); DebugTrace(+1, Dbg, "FatCommonQueryVolumeInfo...\n", 0); DebugTrace( 0, Dbg, "Irp = %08lx\n", Irp ); DebugTrace( 0, Dbg, "->Length = %08lx\n", IrpSp->Parameters.QueryVolume.Length); DebugTrace( 0, Dbg, "->FsInformationClass = %08lx\n", IrpSp->Parameters.QueryVolume.FsInformationClass); DebugTrace( 0, Dbg, "->Buffer = %08lx\n", Irp->AssociatedIrp.SystemBuffer); // // Reference our input parameters to make things easier // Length = IrpSp->Parameters.QueryVolume.Length; FsInformationClass = IrpSp->Parameters.QueryVolume.FsInformationClass; Buffer = Irp->AssociatedIrp.SystemBuffer; // // Decode the file object to get the Vcb // (VOID) FatDecodeFileObject( IrpSp->FileObject, &Vcb, &Fcb, &Ccb ); ASSERT( Vcb != NULL ); try { // // Make sure the vcb is in a usable condition. This will raise // and error condition if the volume is unusable // // Also verify the Root Dcb since we need info from there. // FatVerifyFcb( IrpContext, Vcb->RootDcb ); // // Based on the information class we'll do different actions. Each // of the procedures that we're calling fills up the output buffer // if possible and returns true if it successfully filled the buffer // and false if it couldn't wait for any I/O to complete. // switch (FsInformationClass) { case FileFsVolumeInformation: // // This is the only routine we need the Vcb shared because of // copying the volume label. All other routines copy fields that // cannot change or are just manifest constants. // if (!FatAcquireSharedVcb( IrpContext, Vcb )) { DebugTrace(0, Dbg, "Cannot acquire Vcb\n", 0); Status = FatFsdPostRequest( IrpContext, Irp ); IrpContext = NULL; Irp = NULL; } else { WeAcquiredVcb = TRUE; Status = FatQueryFsVolumeInfo( IrpContext, Vcb, Buffer, &Length ); } break; case FileFsSizeInformation: Status = FatQueryFsSizeInfo( IrpContext, Vcb, Buffer, &Length ); break; case FileFsDeviceInformation: Status = FatQueryFsDeviceInfo( IrpContext, Vcb, Buffer, &Length ); break; case FileFsAttributeInformation: Status = FatQueryFsAttributeInfo( IrpContext, Vcb, Buffer, &Length ); break; case FileFsFullSizeInformation: Status = FatQueryFsFullSizeInfo( IrpContext, Vcb, Buffer, &Length ); break; default: Status = STATUS_INVALID_PARAMETER; break; } // // Set the information field to the number of bytes actually filled in. // if (Irp != NULL) { Irp->IoStatus.Information = IrpSp->Parameters.QueryVolume.Length - Length; } } finally { DebugUnwind( FatCommonQueryVolumeInfo ); if ( WeAcquiredVcb ) { FatReleaseVcb( IrpContext, Vcb ); } if (!AbnormalTermination()) { FatCompleteRequest( IrpContext, Irp, Status ); } DebugTrace(-1, Dbg, "FatCommonQueryVolumeInfo -> %08lx\n", Status); } return Status; }