/*++ Copyright (c) 1991 Microsoft Corporation Module Name: vdm.c Abstract: This module supplies the entry point to the system for manipulating vdms. Author: Dave Hastings (daveh) 6-Apr-1992 Revision History: --*/ #if defined (_X86_) #include "vdmp.h" #endif #include #include #include #include #include typedef struct _QueryDirPoolData { KEVENT kevent; UNICODE_STRING FileName; WCHAR FileNameBuf[1]; } QDIR_POOLDATA, *PQDIR_POOLDATA; #ifdef ALLOC_PRAGMA #pragma alloc_text(PAGE, VdmQueryDirectoryFile) #endif #if !defined(i386) #ifdef ALLOC_PRAGMA #pragma alloc_text(PAGE, NtVdmControl) #endif NTSTATUS NtVdmControl( IN VDMSERVICECLASS Service, IN OUT PVOID ServiceData ) /*++ Routine Description: This routine is the entry point for controlling Vdms. On risc it returns STATUS_NOT_IMPLEMENTED. On 386 the entry point is in i386\vdmentry.c Arguments: Service -- Specifies what service is to be performed ServiceData -- Supplies a pointer to service specific data Return Value: --*/ { PAGED_CODE(); if (Service == VdmQueryDir) { return VdmQueryDirectoryFile(ServiceData); } return STATUS_NOT_IMPLEMENTED; } #endif extern POBJECT_TYPE IoFileObjectType; NTSTATUS VdmQueryDirectoryFile( PVDMQUERYDIRINFO pVdmQueryDir ) /*++ This VDM specific service allows vdm to restart searches at a specified location in the dir search by using the FileIndex, FileName parameters passed back from previous query calls. See NtQueryDirectoryFile for additional documentation. Arguments: PVDMQUERYDIRINFO pVdmQueryDir FileHandle - Supplies a handle to the directory file for which information should be returned. FileInformation - Supplies a buffer to receive the requested information returned about the contents of the directory. Length - Supplies the length, in bytes, of the FileInformation buffer. FileName - Supplies a file name within the specified directory. FileIndex - Supplies a file index within the specified directory. The FileInformationClass is assumed to be FILE_BOTH_DIR_INFORMATION The Caller's mode is assumed to be UserMode Synchronous IO is used --*/ { KIRQL irql; NTSTATUS status; PKEVENT Event; HANDLE FileHandle; IO_STATUS_BLOCK IoStatusBlock; PVOID FileInformation; ULONG Length; UNICODE_STRING FileName; PUNICODE_STRING pFileNameSrc; ULONG FileIndex; PQDIR_POOLDATA QDirPoolData = NULL; PMDL mdl; PIRP irp; PIO_STACK_LOCATION irpSp; PCHAR SystemBuffer; PFILE_OBJECT fileObject; PDEVICE_OBJECT DeviceObject; PAGED_CODE(); // // We assume that the caller is usermode, so verify all parameters // accordingly // try { // // Copy out the callers service data into local variables // ProbeForRead( pVdmQueryDir, sizeof(VDMQUERYDIRINFO), sizeof(ULONG)); FileHandle = pVdmQueryDir->FileHandle; FileInformation = pVdmQueryDir->FileInformation; Length = pVdmQueryDir->Length; FileIndex = pVdmQueryDir->FileIndex; pFileNameSrc = pVdmQueryDir->FileName; // // Ensure that we have a valid file name string // // // check for pVdmQueryDir->Filename validity first // if (NULL == pFileNameSrc) { return(STATUS_INVALID_PARAMETER); } FileName = ProbeAndReadUnicodeString(pFileNameSrc); if (!FileName.Length || FileName.Length > MAXIMUM_FILENAME_LENGTH<<1) { return(STATUS_INVALID_PARAMETER); } ProbeForRead(FileName.Buffer, FileName.Length, sizeof( UCHAR )); // // The FileInformation buffer must be writeable by the caller. // ProbeForWrite( FileInformation, Length, sizeof( ULONG ) ); // // Ensure that the caller's supplied buffer is at least large enough // to contain the fixed part of the structure required for this // query. // if (Length < sizeof(FILE_BOTH_DIR_INFORMATION)) { return STATUS_INFO_LENGTH_MISMATCH; } // // Allocate from nonpaged pool a buffer large enough to contain // the file name, and the kevent used to wait for io. // QDirPoolData = (PQDIR_POOLDATA) ExAllocatePoolWithQuotaTag( NonPagedPool, sizeof(QDIR_POOLDATA) + FileName.Length, ' MDV'); // // Capture the file name string into the nonpaged pool block. // QDirPoolData->FileName.Length = FileName.Length; QDirPoolData->FileName.MaximumLength = FileName.Length; QDirPoolData->FileName.Buffer = QDirPoolData->FileNameBuf; RtlCopyMemory( QDirPoolData->FileNameBuf, FileName.Buffer, FileName.Length ); } except(EXCEPTION_EXECUTE_HANDLER) { if (QDirPoolData) { ExFreePool(QDirPoolData); } return GetExceptionCode(); } // // There were no blatant errors so far, so reference the file object so // the target device object can be found. Note that if the handle does // not refer to a file object, or if the caller does not have the required // access to the file, then it will fail. // status = ObReferenceObjectByHandle( FileHandle, FILE_LIST_DIRECTORY, IoFileObjectType, UserMode, (PVOID *) &fileObject, (POBJECT_HANDLE_INFORMATION) NULL ); if (!NT_SUCCESS( status )) { if (QDirPoolData) { ExFreePool(QDirPoolData); } return status; } // // We don't handle FO_SYNCHRONOUS_IO, because it requires // io internal functionality. Ntvdm can get away with this // because it serializes access to the dir handle. // // // Initialize the kernel event that will signal I/O completion // Event = &QDirPoolData->kevent; KeInitializeEvent(Event, SynchronizationEvent, FALSE); // // Set the file object to the Not-Signaled state. // KeClearEvent( &fileObject->Event ); // // Get the address of the target device object. // DeviceObject = IoGetRelatedDeviceObject( fileObject ); // // Allocate and initialize the I/O Request Packet (IRP) for this operation. // The allocation is performed with an exception handler in case the // caller does not have enough quota to allocate the packet. irp = IoAllocateIrp( DeviceObject->StackSize, TRUE ); if (!irp) { // // An IRP could not be allocated. Cleanup and return an appropriate // error status code. // ObDereferenceObject( fileObject ); if (QDirPoolData) { ExFreePool(QDirPoolData); } return STATUS_INSUFFICIENT_RESOURCES; } // // Fill in the service independent parameters in the IRP. // irp->Flags = (ULONG)IRP_SYNCHRONOUS_API; irp->RequestorMode = UserMode; irp->UserIosb = &IoStatusBlock; irp->UserEvent = Event; irp->Overlay.AsynchronousParameters.UserApcRoutine = NULL; irp->AssociatedIrp.SystemBuffer = (PVOID) NULL; SystemBuffer = NULL; irp->Tail.Overlay.Thread = PsGetCurrentThread(); irp->Tail.Overlay.OriginalFileObject = fileObject; irp->Tail.Overlay.AuxiliaryBuffer = NULL; irp->MdlAddress = NULL; // // Get a pointer to the stack location for the first driver. This will be // used to pass the function codes and parameters. // irpSp = IoGetNextIrpStackLocation( irp ); irpSp->MajorFunction = IRP_MJ_DIRECTORY_CONTROL; irpSp->MinorFunction = IRP_MN_QUERY_DIRECTORY; irpSp->FileObject = fileObject; // // Copy the caller's parameters to the service-specific portion of the // IRP. // irpSp->Parameters.QueryDirectory.Length = Length; irpSp->Parameters.QueryDirectory.FileInformationClass = FileBothDirectoryInformation; irpSp->Parameters.QueryDirectory.FileIndex = FileIndex; if (QDirPoolData->FileName.Length) { irpSp->Parameters.QueryDirectory.FileName = (PSTRING)&QDirPoolData->FileName; } else { irpSp->Parameters.QueryDirectory.FileName = NULL; } irpSp->Flags = SL_INDEX_SPECIFIED; // // Now determine whether this driver expects to have data buffered to it // or whether it performs direct I/O. This is based on the DO_BUFFERED_IO // flag in the device object. If the flag is set, then a system buffer is // allocated and the driver's data will be copied into it. Otherwise, a // Memory Descriptor List (MDL) is allocated and the caller's buffer is // locked down using it. // if (DeviceObject->Flags & DO_BUFFERED_IO) { // // The file system wants buffered I/O. Pass the address of the // "system buffer" in the IRP. Note that we don't want the buffer // deallocated, nor do we want the I/O system to copy to a user // buffer, so we don't set the corresponding flags in irp->Flags. // try { // // Allocate the intermediary system buffer from nonpaged pool and // charge quota for it. // SystemBuffer = ExAllocatePoolWithQuotaTag( NonPagedPool, Length, ' MDV' ); irp->AssociatedIrp.SystemBuffer = SystemBuffer; } except(EXCEPTION_EXECUTE_HANDLER) { IoFreeIrp(irp); ObDereferenceObject( fileObject ); if (QDirPoolData) { ExFreePool(QDirPoolData); } return GetExceptionCode(); } } else if (DeviceObject->Flags & DO_DIRECT_IO) { // // This is a direct I/O operation. Allocate an MDL and invoke the // memory management routine to lock the buffer into memory. This is // done using an exception handler that will perform cleanup if the // operation fails. // mdl = (PMDL) NULL; try { // // Allocate an MDL, charging quota for it, and hang it off of the // IRP. Probe and lock the pages associated with the caller's // buffer for write access and fill in the MDL with the PFNs of // those pages. // mdl = IoAllocateMdl( FileInformation, Length, FALSE, TRUE, irp ); if (mdl == NULL) { ExRaiseStatus( STATUS_INSUFFICIENT_RESOURCES ); } MmProbeAndLockPages( mdl, UserMode, IoWriteAccess ); } except(EXCEPTION_EXECUTE_HANDLER) { if (irp->MdlAddress != NULL) { IoFreeMdl( irp->MdlAddress ); } IoFreeIrp(irp); ObDereferenceObject( fileObject ); if (QDirPoolData) { ExFreePool(QDirPoolData); } return GetExceptionCode(); } } else { // // Pass the address of the user's buffer so the driver has access to // it. It is now the driver's responsibility to do everything. // irp->UserBuffer = FileInformation; } // // Insert the packet at the head of the IRP list for the thread. // KeRaiseIrql( APC_LEVEL, &irql ); InsertHeadList( &irp->Tail.Overlay.Thread->IrpList, &irp->ThreadListEntry ); KeLowerIrql( irql ); // // invoke the driver and wait for it to complete // status = IoCallDriver(DeviceObject, irp); if (status == STATUS_PENDING) { status = KeWaitForSingleObject( Event, UserRequest, UserMode, FALSE, NULL ); } if (NT_SUCCESS(status)) { status = IoStatusBlock.Status; if (NT_SUCCESS(status) || status == STATUS_BUFFER_OVERFLOW) { if (SystemBuffer) { try { RtlCopyMemory( FileInformation, SystemBuffer, IoStatusBlock.Information ); } except(EXCEPTION_EXECUTE_HANDLER) { status = GetExceptionCode(); } } } } // // Cleanup any memory allocated // if (QDirPoolData) { ExFreePool(QDirPoolData); } if (SystemBuffer) { ExFreePool(SystemBuffer); } return status; }