/*++ Copyright (c) 1989-1999 Microsoft Corporation Module Name: connect.c Abstract: This module contains the code for passing on connect IRPs to TDI providers. Author: David Treadwell (davidtr) 2-Mar-1992 Revision History: Vadim Eydelman (vadime) 1999 JoinLeaf implementation Datagram connect via transport Connect optimizations and syncronization with user mode code. --*/ #include "afdp.h" NTSTATUS AfdDoDatagramConnect ( IN PFILE_OBJECT FileObject, IN PIRP Irp, IN BOOLEAN HalfConnect ); NTSTATUS AfdRestartConnect ( IN PDEVICE_OBJECT DeviceObject, IN PIRP Irp, IN PVOID Context ); NTSTATUS AfdRestartDgConnect ( IN PDEVICE_OBJECT DeviceObject, IN PIRP Irp, IN PVOID Context ); VOID AfdSetupConnectDataBuffers ( IN PAFD_ENDPOINT Endpoint, IN PAFD_CONNECTION Connection, IN OUT PTDI_CONNECTION_INFORMATION *RequestConnectionInformation, IN OUT PTDI_CONNECTION_INFORMATION *ReturnConnectionInformation ); BOOLEAN AfdConnectionStart ( IN PAFD_ENDPOINT Endpoint ); VOID AfdEnableFailedConnectEvent( IN PAFD_ENDPOINT Endpoint ); NTSTATUS AfdRestartJoin ( IN PDEVICE_OBJECT DeviceObject, IN PIRP Irp, IN PVOID Context ); VOID AfdJoinInviteSetup ( PAFD_ENDPOINT RootEndpoint, PAFD_ENDPOINT LeafEndpoint ); VOID AfdConnectApcKernelRoutine ( IN struct _KAPC *Apc, IN OUT PKNORMAL_ROUTINE *NormalRoutine, IN OUT PVOID *NormalContext, IN OUT PVOID *SystemArgument1, IN OUT PVOID *SystemArgument2 ); VOID AfdConnectApcRundownRoutine ( IN struct _KAPC *Apc ); VOID AfdFinishConnect ( PAFD_ENDPOINT Endpoint, PIRP Irp, PAFD_ENDPOINT RootEndpoint ); NTSTATUS AfdRestartSuperConnect ( IN PDEVICE_OBJECT DeviceObject, IN PIRP Irp, IN PVOID Context ); #ifdef ALLOC_PRAGMA #pragma alloc_text( PAGE, AfdConnect ) #pragma alloc_text( PAGEAFD, AfdDoDatagramConnect ) #pragma alloc_text( PAGEAFD, AfdRestartConnect ) #pragma alloc_text( PAGEAFD, AfdRestartDgConnect ) #pragma alloc_text( PAGEAFD, AfdSetupConnectDataBuffers ) #pragma alloc_text( PAGEAFD, AfdEnableFailedConnectEvent ) #pragma alloc_text( PAGE, AfdJoinLeaf ) #pragma alloc_text( PAGEAFD, AfdRestartJoin ) #pragma alloc_text( PAGEAFD, AfdJoinInviteSetup ) #pragma alloc_text( PAGE, AfdConnectApcKernelRoutine ) #pragma alloc_text( PAGE, AfdConnectApcRundownRoutine ) #pragma alloc_text( PAGEAFD, AfdFinishConnect ) #pragma alloc_text( PAGE, AfdSuperConnect ) #pragma alloc_text( PAGEAFD, AfdRestartSuperConnect ) #endif typedef struct _AFD_CONNECT_CONTEXT { TDI_CONNECTION_INFORMATION RequestConnectionInfo; TDI_CONNECTION_INFORMATION ReturnConnectionInfo; TRANSPORT_ADDRESS RemoteAddress; } AFD_CONNECT_CONTEXT, *PAFD_CONNECT_CONTEXT; C_ASSERT ( (FIELD_OFFSET (AFD_CONNECTION, SListEntry) % MEMORY_ALLOCATION_ALIGNMENT) == 0 ); NTSTATUS FASTCALL AfdConnect ( IN PIRP Irp, IN PIO_STACK_LOCATION IrpSp ) /*++ Routine Description: Handles the IOCTL_AFD_CONNECT IOCTL. Arguments: Irp - Pointer to I/O request packet. IrpSp - pointer to the IO stack location to use for this request. Return Value: NTSTATUS -- Indicates whether the request was successfully queued. --*/ { NTSTATUS status; PAFD_ENDPOINT endpoint; PAFD_CONNECTION connection; PAFD_CONNECT_CONTEXT context; HANDLE connectEndpointHandle; PFILE_OBJECT fileObject; PTRANSPORT_ADDRESS remoteAddress; ULONG remoteAddressLength; BOOLEAN sanActive; PTDI_CONNECTION_INFORMATION requestConnectionInfo, returnConnectionInfo; PAGED_CODE( ); // // Initialize for proper cleanup // fileObject = NULL; context = NULL; #ifdef _WIN64 if (IoIs32bitProcess (Irp)) { if (IrpSp->Parameters.DeviceIoControl.InputBufferLength< (ULONG)FIELD_OFFSET(AFD_CONNECT_JOIN_INFO32, RemoteAddress.Address[0].Address) || (IrpSp->Parameters.DeviceIoControl.OutputBufferLength!=0 && IrpSp->Parameters.DeviceIoControl.OutputBufferLength< sizeof (IO_STATUS_BLOCK32))){ status = STATUS_INVALID_PARAMETER; goto complete; } AFD_W4_INIT status = STATUS_SUCCESS; try { if( Irp->RequestorMode != KernelMode ) { ProbeForRead( IrpSp->Parameters.DeviceIoControl.Type3InputBuffer, IrpSp->Parameters.DeviceIoControl.InputBufferLength, PROBE_ALIGNMENT32 (AFD_CONNECT_JOIN_INFO32) ); } sanActive = ((PAFD_CONNECT_JOIN_INFO32)IrpSp->Parameters.DeviceIoControl.Type3InputBuffer)->SanActive; connectEndpointHandle = ((PAFD_CONNECT_JOIN_INFO32)IrpSp->Parameters.DeviceIoControl.Type3InputBuffer)->ConnectEndpoint; remoteAddress = (PTRANSPORT_ADDRESS) &((PAFD_CONNECT_JOIN_INFO32)IrpSp->Parameters.DeviceIoControl.Type3InputBuffer)->RemoteAddress; ASSERT (((ULONG_PTR)remoteAddress & (PROBE_ALIGNMENT(TRANSPORT_ADDRESS)-1))==0); remoteAddressLength = IrpSp->Parameters.DeviceIoControl.InputBufferLength - FIELD_OFFSET (AFD_CONNECT_JOIN_INFO32, RemoteAddress); } except (AFD_EXCEPTION_FILTER (status)) { ASSERT (NT_ERROR (status)); goto complete; } } else #endif //_WIN64 { // // Determine where in the system buffer the request and return // connection information structures exist. Pass pointers to // these locations instead of the user-mode pointers in the // tdiRequest structure so that the memory will be nonpageable. // if (IrpSp->Parameters.DeviceIoControl.InputBufferLength< (ULONG)FIELD_OFFSET(AFD_CONNECT_JOIN_INFO, RemoteAddress.Address[0].Address) || (IrpSp->Parameters.DeviceIoControl.OutputBufferLength!=0 && IrpSp->Parameters.DeviceIoControl.OutputBufferLength < sizeof (IO_STATUS_BLOCK))) { status = STATUS_INVALID_PARAMETER; goto complete; } AFD_W4_INIT status = STATUS_SUCCESS; try { PAFD_CONNECT_JOIN_INFO connectInfo; if( Irp->RequestorMode != KernelMode ) { ProbeForRead( IrpSp->Parameters.DeviceIoControl.Type3InputBuffer, IrpSp->Parameters.DeviceIoControl.InputBufferLength, PROBE_ALIGNMENT (AFD_CONNECT_JOIN_INFO) ); } connectInfo = IrpSp->Parameters.DeviceIoControl.Type3InputBuffer; sanActive = connectInfo->SanActive; connectEndpointHandle = connectInfo->ConnectEndpoint; remoteAddress = &connectInfo->RemoteAddress; remoteAddressLength = IrpSp->Parameters.DeviceIoControl.InputBufferLength - FIELD_OFFSET (AFD_CONNECT_JOIN_INFO, RemoteAddress); } except (AFD_EXCEPTION_FILTER (status)) { ASSERT (NT_ERROR (status)); goto complete; } } // // Do sanity check on remoteAddressLength to prevent addition overflow below // if ((LONG)remoteAddressLength < 0) { // // address length is unreasonably large // status = STATUS_INVALID_PARAMETER; goto complete; } // // Check for if the caller is unaware of the SAN // provider activation and report the error. // if (!sanActive && AfdSanServiceHelper!=NULL) { KdPrintEx(( DPFLTR_WSOCKTRANSPORT_ID, DPFLTR_INFO_LEVEL, "AFD: Process %p is being told to enable SAN on connect\n", PsGetCurrentProcessId ())); status = STATUS_INVALID_PARAMETER_12; goto complete; } AFD_W4_INIT ASSERT (status == STATUS_SUCCESS); try { context = AFD_ALLOCATE_POOL_WITH_QUOTA (NonPagedPool, FIELD_OFFSET (AFD_CONNECT_CONTEXT, RemoteAddress) + remoteAddressLength, AFD_TDI_POOL_TAG ); // AFD_ALLOCATE_POOL_WITH_QUOTA macro sets POOL_RAISE_IF_ALLOCATION_FAILURE flag ASSERT (context!=NULL); Irp->AssociatedIrp.SystemBuffer = context; RtlZeroMemory (context, FIELD_OFFSET (AFD_CONNECT_CONTEXT, RemoteAddress)); RtlCopyMemory (&context->RemoteAddress, remoteAddress, remoteAddressLength); // // Validate internal consistency of the transport address structure. // Note that we HAVE to do this after copying since the malicious // application can change the content of the buffer on us any time // and our check will be bypassed. // if ((context->RemoteAddress.TAAddressCount!=1) || (LONG)remoteAddressLength< FIELD_OFFSET (TRANSPORT_ADDRESS, Address[0].Address[context->RemoteAddress.Address[0].AddressLength])) { ExRaiseStatus (STATUS_INVALID_PARAMETER); } context->RequestConnectionInfo.RemoteAddress = &context->RemoteAddress; context->RequestConnectionInfo.RemoteAddressLength = remoteAddressLength; if (IrpSp->Parameters.DeviceIoControl.OutputBufferLength>0 && Irp->RequestorMode==UserMode) { ProbeForWriteIoStatusEx ( ((PIO_STATUS_BLOCK)Irp->UserBuffer), IoIs32bitProcess (Irp)); } } except (AFD_EXCEPTION_FILTER(status)) { ASSERT (NT_ERROR (status)); goto complete; } fileObject = IrpSp->FileObject; endpoint = fileObject->FsContext; if (endpoint->Type==AfdBlockTypeHelper) { // // This is async connect which uses helper endpoint to // communicate to AFD. Get the real endpoint. // status = ObReferenceObjectByHandle( connectEndpointHandle, (IrpSp->Parameters.DeviceIoControl.IoControlCode>>14) & 3, // DesiredAccess *IoFileObjectType, // ObjectType Irp->RequestorMode, (PVOID *)&fileObject, NULL ); if (!NT_SUCCESS (status)) { goto complete; } if (fileObject->DeviceObject!=AfdDeviceObject) { status = STATUS_INVALID_HANDLE; goto complete_deref; } endpoint = fileObject->FsContext; IrpSp->FileObject = fileObject; } else { ObReferenceObject (fileObject); } IF_DEBUG(CONNECT) { KdPrintEx(( DPFLTR_WSOCKTRANSPORT_ID, DPFLTR_TRACE_LEVEL, "AfdConnect: starting connect on endpoint %p\n", endpoint )); } // // If this is a datagram endpoint, simply remember the specified // address so that we can use it on sends, receives, writes, and // reads. // if ( IS_DGRAM_ENDPOINT(endpoint) ) { return AfdDoDatagramConnect( fileObject, Irp, FALSE ); } if (!AFD_START_STATE_CHANGE (endpoint, AfdEndpointStateConnected)) { status = STATUS_INVALID_PARAMETER; goto complete_deref; } if ( endpoint->Type != AfdBlockTypeEndpoint && endpoint->Type != AfdBlockTypeVcConnecting ) { status = STATUS_INVALID_PARAMETER; goto complete_state_change; } // // If the endpoint is not bound, then this is an invalid request. // Listening endpoints are not allowed as well. // if ( endpoint->Listening || endpoint->State != AfdEndpointStateBound ) { status = STATUS_INVALID_PARAMETER; goto complete_state_change; } // // Create a connection object to use for the connect operation. // status = AfdCreateConnection( endpoint->TransportInfo, endpoint->AddressHandle, IS_TDI_BUFFERRING(endpoint), endpoint->InLine, endpoint->OwningProcess, &connection ); if ( !NT_SUCCESS(status) ) { goto complete_state_change; } // // Set up a referenced pointer from the connection to the endpoint. // Note that we set up the connection's pointer to the endpoint // BEFORE the endpoint's pointer to the connection so that AfdPoll // doesn't try to back reference the endpoint from the connection. // REFERENCE_ENDPOINT( endpoint ); connection->Endpoint = endpoint; // // Remember that this is now a connecting type of endpoint, and set // up a pointer to the connection in the endpoint. This is // implicitly a referenced pointer. // endpoint->Common.VcConnecting.Connection = connection; endpoint->Type = AfdBlockTypeVcConnecting; ASSERT( IS_TDI_BUFFERRING(endpoint) == connection->TdiBufferring ); // // Add an additional reference to the connection. This prevents the // connection from being closed until the disconnect event handler // is called. // AfdAddConnectedReference( connection ); // // If there are connect data buffers, move them from the endpoint // structure to the connection structure and set up the necessary // pointers in the connection request we're going to give to the TDI // provider. Do this in a subroutine so this routine can be pageable. // requestConnectionInfo = &context->RequestConnectionInfo; returnConnectionInfo = &context->ReturnConnectionInfo; if ( endpoint->Common.VirtualCircuit.ConnectDataBuffers != NULL ) { AfdSetupConnectDataBuffers( endpoint, connection, &requestConnectionInfo, &returnConnectionInfo ); } // // Since we may be reissuing a connect after a previous failed connect, // reenable the failed connect event bit. // AfdEnableFailedConnectEvent( endpoint ); // // Reference the connection block so it does not go away even if // endpoint's reference to it is removed (in cleanup) // REFERENCE_CONNECTION (connection); // // Build a TDI kernel-mode connect request in the next stack location // of the IRP. // TdiBuildConnect( Irp, connection->DeviceObject, connection->FileObject, AfdRestartConnect, connection, &AfdInfiniteTimeout, requestConnectionInfo, returnConnectionInfo ); AFD_VERIFY_ADDRESS (connection, &requestConnectionInfo->RemoteAddress); // // Call the transport to actually perform the connect operation. // return AfdIoCallDriver( endpoint, connection->DeviceObject, Irp ); complete_state_change: AFD_END_STATE_CHANGE (endpoint); complete_deref: ASSERT (fileObject!=NULL); ObDereferenceObject (fileObject); complete: if (context!=NULL) { AFD_FREE_POOL (context, AFD_TDI_POOL_TAG); ASSERT (Irp->AssociatedIrp.SystemBuffer==context); Irp->AssociatedIrp.SystemBuffer = NULL; } Irp->IoStatus.Information = 0; Irp->IoStatus.Status = status; IoCompleteRequest( Irp, AfdPriorityBoost ); return status; } // AfdConnect NTSTATUS AfdDoDatagramConnect ( IN PFILE_OBJECT FileObject, IN PIRP Irp, IN BOOLEAN HalfConnect ) { PAFD_ENDPOINT endpoint; AFD_LOCK_QUEUE_HANDLE lockHandle; NTSTATUS status; PAFD_CONNECT_CONTEXT context; endpoint = FileObject->FsContext; context = Irp->AssociatedIrp.SystemBuffer; if (!AFD_START_STATE_CHANGE (endpoint, AfdEndpointStateConnected)) { status = STATUS_INVALID_PARAMETER; goto complete; } if (endpoint->State!=AfdEndpointStateBound && endpoint->State!=AfdEndpointStateConnected) { status = STATUS_INVALID_PARAMETER; goto complete_state_change; } // // Save the remote address on the endpoint. We'll use this to // send datagrams in the future and to compare received datagram's // source addresses. // AfdAcquireSpinLock( &endpoint->SpinLock, &lockHandle ); if ((endpoint->Common.Datagram.RemoteAddress==NULL) || (endpoint->Common.Datagram.RemoteAddressLength< (ULONG)context->RequestConnectionInfo.RemoteAddressLength)) { PTRANSPORT_ADDRESS remoteAddress; remoteAddress = AFD_ALLOCATE_REMOTE_ADDRESS ( context->RequestConnectionInfo.RemoteAddressLength); if (remoteAddress == NULL) { AfdReleaseSpinLock( &endpoint->SpinLock, &lockHandle ); status = STATUS_INSUFFICIENT_RESOURCES; goto complete_state_change; } if ( endpoint->Common.Datagram.RemoteAddress != NULL ) { AFD_RETURN_REMOTE_ADDRESS ( endpoint->Common.Datagram.RemoteAddress, endpoint->Common.Datagram.RemoteAddressLength ); } endpoint->Common.Datagram.RemoteAddress = remoteAddress; } RtlCopyMemory( endpoint->Common.Datagram.RemoteAddress, context->RequestConnectionInfo.RemoteAddress, context->RequestConnectionInfo.RemoteAddressLength ); endpoint->Common.Datagram.RemoteAddressLength = context->RequestConnectionInfo.RemoteAddressLength; endpoint->DisconnectMode = 0; endpoint->Common.Datagram.HalfConnect = HalfConnect; if (!IS_TDI_DGRAM_CONNECTION(endpoint)) { endpoint->State = AfdEndpointStateConnected; // // Indicate that the connect completed. Implicitly, the // successful completion of a connect also means that the caller // can do a send on the socket. // endpoint->EnableSendEvent = TRUE; AfdIndicateEventSelectEvent( endpoint, AFD_POLL_CONNECT | AFD_POLL_SEND, STATUS_SUCCESS ); AfdReleaseSpinLock( &endpoint->SpinLock, &lockHandle ); AfdIndicatePollEvent( endpoint, AFD_POLL_CONNECT | AFD_POLL_SEND, STATUS_SUCCESS ); status = STATUS_SUCCESS; } else { // // Reset the connect status to success so that the poll code will // know if a connect failure occurs. // Do this inline as we already hold spinlock // endpoint->EventsActive &= ~AFD_POLL_CONNECT_FAIL; endpoint->EventStatus[AFD_POLL_CONNECT_FAIL_BIT] = STATUS_SUCCESS; AfdReleaseSpinLock( &endpoint->SpinLock, &lockHandle ); // // Build a TDI kernel-mode connect request in the next stack location // of the IRP. // TdiBuildConnect( Irp, endpoint->AddressDeviceObject, endpoint->AddressFileObject, AfdRestartDgConnect, endpoint, &AfdInfiniteTimeout, &context->RequestConnectionInfo, &context->ReturnConnectionInfo ); // // Call the transport to actually perform the connect operation. // return AfdIoCallDriver( endpoint, endpoint->AddressDeviceObject, Irp ); } complete_state_change: AFD_END_STATE_CHANGE (endpoint); complete: ObDereferenceObject (FileObject); AFD_FREE_POOL (context, AFD_TDI_POOL_TAG); ASSERT (Irp->AssociatedIrp.SystemBuffer==context); Irp->AssociatedIrp.SystemBuffer = NULL; Irp->IoStatus.Information = 0; Irp->IoStatus.Status = status; IoCompleteRequest( Irp, AfdPriorityBoost ); return status; } // AfdDoDatagramConnect VOID AfdSetupConnectDataBuffers ( IN PAFD_ENDPOINT Endpoint, IN PAFD_CONNECTION Connection, IN OUT PTDI_CONNECTION_INFORMATION *RequestConnectionInformation, IN OUT PTDI_CONNECTION_INFORMATION *ReturnConnectionInformation ) { AFD_LOCK_QUEUE_HANDLE lockHandle; ASSERT (Endpoint->Type!=AfdBlockTypeDatagram); AfdAcquireSpinLock( &Endpoint->SpinLock, &lockHandle ); if ( Endpoint->Common.VirtualCircuit.ConnectDataBuffers != NULL ) { PTDI_CONNECTION_INFORMATION requestConnectionInformation, returnConnectionInformation; ASSERT( Connection->ConnectDataBuffers == NULL ); Connection->ConnectDataBuffers = Endpoint->Common.VirtualCircuit.ConnectDataBuffers; Endpoint->Common.VirtualCircuit.ConnectDataBuffers = NULL; requestConnectionInformation = &Connection->ConnectDataBuffers->RequestConnectionInfo, requestConnectionInformation->UserData = Connection->ConnectDataBuffers->SendConnectData.Buffer; requestConnectionInformation->UserDataLength = Connection->ConnectDataBuffers->SendConnectData.BufferLength; requestConnectionInformation->Options = Connection->ConnectDataBuffers->SendConnectOptions.Buffer; requestConnectionInformation->OptionsLength = Connection->ConnectDataBuffers->SendConnectOptions.BufferLength; requestConnectionInformation->RemoteAddress = (*RequestConnectionInformation)->RemoteAddress; requestConnectionInformation->RemoteAddressLength = (*RequestConnectionInformation)->RemoteAddressLength; *RequestConnectionInformation = requestConnectionInformation; returnConnectionInformation = &Connection->ConnectDataBuffers->ReturnConnectionInfo; returnConnectionInformation->UserData = Connection->ConnectDataBuffers->ReceiveConnectData.Buffer; returnConnectionInformation->UserDataLength = Connection->ConnectDataBuffers->ReceiveConnectData.BufferLength; returnConnectionInformation->Options = Connection->ConnectDataBuffers->ReceiveConnectOptions.Buffer; returnConnectionInformation->OptionsLength = Connection->ConnectDataBuffers->ReceiveConnectOptions.BufferLength; returnConnectionInformation->RemoteAddress = (*ReturnConnectionInformation)->RemoteAddress; returnConnectionInformation->RemoteAddressLength = (*ReturnConnectionInformation)->RemoteAddressLength; *ReturnConnectionInformation = returnConnectionInformation; } AfdReleaseSpinLock( &Endpoint->SpinLock, &lockHandle ); } // AfdSetupConnectDataBuffers NTSTATUS AfdRestartConnect ( IN PDEVICE_OBJECT DeviceObject, IN PIRP Irp, IN PVOID Context ) /*++ Routine Description: Handles the IOCTL_AFD_CONNECT IOCTL. Arguments: Irp - Pointer to I/O request packet. IrpSp - pointer to the IO stack location to use for this request. Return Value: NTSTATUS -- Indicates whether the request was successfully queued. --*/ { PAFD_ENDPOINT endpoint; PAFD_CONNECTION connection; AFD_LOCK_QUEUE_HANDLE lockHandle; PIO_STACK_LOCATION irpSp; PFILE_OBJECT fileObject; PAFD_CONNECT_CONTEXT context; UNREFERENCED_PARAMETER (DeviceObject); connection = Context; ASSERT( connection->Type == AfdBlockTypeConnection ); irpSp = IoGetCurrentIrpStackLocation( Irp ); fileObject = irpSp->FileObject; ASSERT( fileObject->DeviceObject==AfdDeviceObject ); endpoint = fileObject->FsContext; ASSERT( endpoint->Type == AfdBlockTypeVcConnecting ); ASSERT( endpoint==connection->Endpoint ); context = Irp->AssociatedIrp.SystemBuffer; ASSERT( context != NULL ); IF_DEBUG(CONNECT) { KdPrintEx(( DPFLTR_WSOCKTRANSPORT_ID, DPFLTR_TRACE_LEVEL, "AfdRestartConnect: connect completed, status = %X, endpoint = %p\n", Irp->IoStatus.Status, endpoint )); } if ( connection->ConnectDataBuffers != NULL ) { // // If there are connect buffers on this endpoint, remember the // size of the return connect data. // AfdAcquireSpinLock( &endpoint->SpinLock, &lockHandle ); // // Double-check under the lock // if ( connection->ConnectDataBuffers != NULL ) { NTSTATUS status; status = AfdSaveReceivedConnectData( &connection->ConnectDataBuffers, IOCTL_AFD_SET_CONNECT_DATA, connection->ConnectDataBuffers->ReturnConnectionInfo.UserData, connection->ConnectDataBuffers->ReturnConnectionInfo.UserDataLength ); ASSERT (NT_SUCCESS (status)); status = AfdSaveReceivedConnectData( &connection->ConnectDataBuffers, IOCTL_AFD_SET_CONNECT_OPTIONS, connection->ConnectDataBuffers->ReturnConnectionInfo.Options, connection->ConnectDataBuffers->ReturnConnectionInfo.OptionsLength ); ASSERT (NT_SUCCESS (status)); } AfdReleaseSpinLock( &endpoint->SpinLock, &lockHandle ); } // // Indicate that the connect completed. Implicitly, the successful // completion of a connect also means that the caller can do a send // on the socket. // if ( NT_SUCCESS(Irp->IoStatus.Status)) { // // If the request succeeded, set the endpoint to the connected // state. The endpoint type has already been set to // AfdBlockTypeVcConnecting. // endpoint->State = AfdEndpointStateConnected; ASSERT( endpoint->Type == AfdBlockTypeVcConnecting ); // // Remember the time that the connection started. // connection->ConnectTime = KeQueryInterruptTime(); } else { // // The connect failed, so reset the type to open. // Otherwise, we won't be able to start another connect // endpoint->Type = AfdBlockTypeEndpoint; AfdAcquireSpinLock( &endpoint->SpinLock, &lockHandle ); if (endpoint->Common.VcConnecting.Connection!=NULL) { ASSERT (connection==endpoint->Common.VcConnecting.Connection); endpoint->Common.VcConnecting.Connection = NULL; // // Manually delete the connected reference if somebody else // hasn't already done so. We can't use // AfdDeleteConnectedReference() because it refuses to delete // the connected reference until the endpoint has been cleaned // up. // if ( connection->ConnectedReferenceAdded ) { connection->ConnectedReferenceAdded = FALSE; AfdReleaseSpinLock( &endpoint->SpinLock, &lockHandle ); DEREFERENCE_CONNECTION( connection ); } else { AfdReleaseSpinLock( &endpoint->SpinLock, &lockHandle ); } // // Dereference the connection block stored on the endpoint. // This should cause the connection object reference count to go // to zero to the connection object can be deleted. // DEREFERENCE_CONNECTION( connection ); } else { // // The endpoint's reference to connection was removed // (perhaps in cleanup); // AfdReleaseSpinLock( &endpoint->SpinLock, &lockHandle ); } } AFD_FREE_POOL (context, AFD_TDI_POOL_TAG); Irp->AssociatedIrp.SystemBuffer = NULL; // // If pending has be returned for this irp then mark the current // stack as pending. // if ( Irp->PendingReturned ) { IoMarkIrpPending(Irp); } AfdCompleteOutstandingIrp( endpoint, Irp ); // // Dereference connection to account for reference we added in AfdConnect // DEREFERENCE_CONNECTION( connection ); // // Try to queue kernel APC to the user thread that // started the connection operation, so we can // communicate the status of the connect operation to // msafd.dll before we inform the application through // the select or EventSelect. Otherwise, we run into the // race condition when application learns about connect first, // calls msafd.dll that is not aware of the completion and // returns WSAENOTCONN. // if ((Irp->RequestorMode==UserMode) && // Must be user mode calls (Irp->UserBuffer!=NULL) && // Must be interested in status // Thread should be able to // run APCs. (KeInitializeApc (&endpoint->Common.VcConnecting.Apc, PsGetThreadTcb (Irp->Tail.Overlay.Thread), Irp->ApcEnvironment, AfdConnectApcKernelRoutine, AfdConnectApcRundownRoutine, (PKNORMAL_ROUTINE)NULL, KernelMode, NULL ), KeInsertQueueApc (&endpoint->Common.VcConnecting.Apc, Irp, NULL, AfdPriorityBoost))) { // // We will complete the IRP in the APC. // return STATUS_MORE_PROCESSING_REQUIRED; } else { // // APC was not necessary or did not work. // Complete it here. // AfdFinishConnect (endpoint, Irp, NULL); return STATUS_SUCCESS; } } // AfdRestartConnect VOID AfdConnectApcKernelRoutine ( IN struct _KAPC *Apc, IN OUT PKNORMAL_ROUTINE *NormalRoutine, IN OUT PVOID *NormalContext, IN OUT PVOID *SystemArgument1, IN OUT PVOID *SystemArgument2 ) { PIRP irp; PIO_STACK_LOCATION irpSp; PAFD_ENDPOINT endpoint, rootEndpoint; UNREFERENCED_PARAMETER (NormalContext); #if DBG try { ASSERT (*NormalRoutine==NULL); #else UNREFERENCED_PARAMETER (NormalRoutine); #endif // // Validate parameters. // endpoint = CONTAINING_RECORD (Apc, AFD_ENDPOINT, Common.VcConnecting.Apc); ASSERT (IS_AFD_ENDPOINT_TYPE (endpoint)); irp = *SystemArgument1; ASSERT (irp->UserBuffer!=NULL && irp->RequestorMode==UserMode); irpSp = IoGetCurrentIrpStackLocation( irp ); rootEndpoint = *SystemArgument2; ASSERT (rootEndpoint==NULL || IS_AFD_ENDPOINT_TYPE (endpoint)); // // Update the status for the user mode caller before // signalling events. // try { #ifdef _WIN64 if (IoIs32bitProcess (irp)) { ((PIO_STATUS_BLOCK32)irp->UserBuffer)->Status = (LONG)irp->IoStatus.Status; } else #endif //_WIN64 { ((PIO_STATUS_BLOCK)irp->UserBuffer)->Status = irp->IoStatus.Status; } } except (AFD_EXCEPTION_FILTER_NO_STATUS()) { NOTHING; } AfdFinishConnect (endpoint, irp, rootEndpoint); IoCompleteRequest (irp, AfdPriorityBoost); #if DBG } except (AfdApcExceptionFilter (GetExceptionInformation (), __FILE__, __LINE__)) { DbgBreakPoint (); } #endif } VOID AfdConnectApcRundownRoutine ( IN struct _KAPC *Apc ) { PIRP irp; PAFD_ENDPOINT endpoint, rootEndpoint; #if DBG try { #endif endpoint = CONTAINING_RECORD (Apc, AFD_ENDPOINT, Common.VcConnecting.Apc); ASSERT (IS_AFD_ENDPOINT_TYPE (endpoint)); irp = Apc->SystemArgument1; rootEndpoint = Apc->SystemArgument2; ASSERT (rootEndpoint==NULL || IS_AFD_ENDPOINT_TYPE (endpoint)); ASSERT (irp->UserBuffer!=NULL && irp->RequestorMode==UserMode); // // Thread is exiting, don't bother updating user mode status. // Just signal the events and complet the IRP. // AfdFinishConnect (endpoint, irp, rootEndpoint); IoCompleteRequest (irp, AfdPriorityBoost); #if DBG } except (AfdApcExceptionFilter (GetExceptionInformation (), __FILE__, __LINE__)) { DbgBreakPoint (); } #endif } VOID AfdFinishConnect ( PAFD_ENDPOINT Endpoint, PIRP Irp, PAFD_ENDPOINT RootEndpoint ) { PIO_STACK_LOCATION irpSp; PFILE_OBJECT fileObject; AFD_LOCK_QUEUE_HANDLE lockHandle; ULONG eventMask; if (NT_SUCCESS(Irp->IoStatus.Status)) { eventMask = AFD_POLL_CONNECT; } else { eventMask = AFD_POLL_CONNECT_FAIL; } irpSp = IoGetCurrentIrpStackLocation( Irp ); fileObject = irpSp->FileObject; if (RootEndpoint != NULL) { AfdAcquireSpinLock(&RootEndpoint->SpinLock, &lockHandle); // // mswsock.dll will reissue join leaf call for non-blocking sockets // in its async helper if the original requesting thread exits // causing the connect IRP to cancel. We only want to signal events // based upon the final resolution of the join leaf call (once only)! // However if the endpoint is now cleaning up, a followup call to // join leaf will fail without signalling the events. // if (RootEndpoint->EndpointCleanedUp || (Irp->IoStatus.Status != STATUS_CANCELLED) || !RootEndpoint->NonBlocking) { AfdIndicateEventSelectEvent(RootEndpoint, eventMask, Irp->IoStatus.Status); AfdReleaseSpinLock(&RootEndpoint->SpinLock, &lockHandle); AfdIndicatePollEvent(RootEndpoint, eventMask, Irp->IoStatus.Status); // // Only indicate connection once to the root control plane. // eventMask = 0; } else { AfdReleaseSpinLock(&RootEndpoint->SpinLock, &lockHandle); } AFD_END_STATE_CHANGE(RootEndpoint); if (!NT_SUCCESS(Irp->IoStatus.Status)) DEREFERENCE_ENDPOINT(RootEndpoint); } // if (RootEndpoint != NULL) AfdAcquireSpinLock(&Endpoint->SpinLock, &lockHandle); if (NT_SUCCESS(Irp->IoStatus.Status)) { eventMask |= AFD_POLL_SEND; Endpoint->EnableSendEvent = TRUE; if (Endpoint->Common.VcConnecting.Connection != NULL) { Endpoint->Common.VcConnecting.Connection->State = AfdConnectionStateConnected; if (IS_DATA_ON_CONNECTION(Endpoint->Common.VcConnecting.Connection)) { eventMask |= AFD_POLL_RECEIVE; } } } else { // // mswsock.dll will reissue connect call for non-blocking sockets // in its async helper if the original requesting thread exits // causing the connect IRP to cancel. We only want to signal events // based upon the final resolution of the connect call (once only)! // However if the endpoint is now cleaning up, a followup call to // connect will fail without signalling the events. // if ((Irp->IoStatus.Status == STATUS_CANCELLED) && !Endpoint->EndpointCleanedUp && Endpoint->NonBlocking) { eventMask = 0; } } // if (NT_SUCCESS(Irp->IoStatus.Status)) if (eventMask) { AfdIndicateEventSelectEvent(Endpoint, eventMask, Irp->IoStatus.Status); AfdReleaseSpinLock(&Endpoint->SpinLock, &lockHandle); AfdIndicatePollEvent(Endpoint, eventMask, Irp->IoStatus.Status); } else { AfdReleaseSpinLock(&Endpoint->SpinLock, &lockHandle); } AFD_END_STATE_CHANGE(Endpoint); ObDereferenceObject(fileObject); } NTSTATUS AfdRestartDgConnect ( IN PDEVICE_OBJECT DeviceObject, IN PIRP Irp, IN PVOID Context ) /*++ Routine Description: Handles the IOCTL_AFD_CONNECT IOCTL. Arguments: Irp - Pointer to I/O request packet. IrpSp - pointer to the IO stack location to use for this request. Return Value: NTSTATUS -- Indicates whether the request was successfully queued. --*/ { PAFD_ENDPOINT endpoint; PIO_STACK_LOCATION irpSp; PFILE_OBJECT fileObject; AFD_LOCK_QUEUE_HANDLE lockHandle; ULONG eventMask; UNREFERENCED_PARAMETER (DeviceObject); endpoint = Context; ASSERT( IS_DGRAM_ENDPOINT(endpoint) ); irpSp = IoGetCurrentIrpStackLocation( Irp ); fileObject = irpSp->FileObject; ASSERT (endpoint == fileObject->FsContext); IF_DEBUG(CONNECT) { KdPrintEx(( DPFLTR_WSOCKTRANSPORT_ID, DPFLTR_TRACE_LEVEL, "AfdRestartDgConnect: connect completed, status = %X, endpoint = %p\n", Irp->IoStatus.Status, endpoint )); } // // Indicate that the connect completed. Implicitly, the successful // completion of a connect also means that the caller can do a send // on the socket. // AfdAcquireSpinLock (&endpoint->SpinLock, &lockHandle); if ( NT_SUCCESS(Irp->IoStatus.Status) ) { endpoint->State = AfdEndpointStateConnected; endpoint->EnableSendEvent = TRUE; eventMask = AFD_POLL_CONNECT | AFD_POLL_SEND; } else { eventMask = AFD_POLL_CONNECT_FAIL; } AfdIndicateEventSelectEvent (endpoint, eventMask, Irp->IoStatus.Status); AfdReleaseSpinLock (&endpoint->SpinLock, &lockHandle); AfdIndicatePollEvent (endpoint, eventMask, Irp->IoStatus.Status); AFD_END_STATE_CHANGE (endpoint); ASSERT (Irp->AssociatedIrp.SystemBuffer!=NULL); AFD_FREE_POOL (Irp->AssociatedIrp.SystemBuffer, AFD_TDI_POOL_TAG); Irp->AssociatedIrp.SystemBuffer = NULL; // // If pending has be returned for this irp then mark the current // stack as pending. // if ( Irp->PendingReturned ) { IoMarkIrpPending(Irp); } AfdCompleteOutstandingIrp( endpoint, Irp ); // // Remove reference added in AfdConnect // ObDereferenceObject (fileObject); return STATUS_SUCCESS; } // AfdRestartDgConnect VOID AfdEnableFailedConnectEvent( IN PAFD_ENDPOINT Endpoint ) /*++ Routine Description: Reenables the failed connect poll bit on the specified endpoint. This is off in a separate (nonpageable) routine so that the bulk of AfdConnect() can remain pageable. Arguments: Endpoint - The endpoint to enable. Return Value: None. --*/ { AFD_LOCK_QUEUE_HANDLE lockHandle; AfdAcquireSpinLock( &Endpoint->SpinLock, &lockHandle ); ASSERT( ( Endpoint->EventsActive & AFD_POLL_CONNECT ) == 0 ); Endpoint->EventsActive &= ~AFD_POLL_CONNECT_FAIL; Endpoint->EventStatus[AFD_POLL_CONNECT_FAIL_BIT] = STATUS_SUCCESS; IF_DEBUG(EVENT_SELECT) { KdPrintEx(( DPFLTR_WSOCKTRANSPORT_ID, DPFLTR_TRACE_LEVEL, "AfdConnect: Endp %08lX, Active %08lX\n", Endpoint, Endpoint->EventsActive )); } AfdReleaseSpinLock( &Endpoint->SpinLock, &lockHandle ); } // AfdEnableFailedConnectEvent NTSTATUS FASTCALL AfdJoinLeaf ( IN PIRP Irp, IN PIO_STACK_LOCATION IrpSp ) /*++ Routine Description: Handles the IOCTL_AFD_JOIN_LEAF IOCTL. Arguments: Irp - Pointer to I/O request packet. IrpSp - pointer to the IO stack location to use for this request. Return Value: NTSTATUS -- Indicates whether the request was successfully queued. --*/ { NTSTATUS status; PAFD_ENDPOINT leafEndpoint; PAFD_CONNECTION connection; PAFD_CONNECT_CONTEXT context; HANDLE connectEndpointHandle; HANDLE rootEndpointHandle; PFILE_OBJECT fileObject; PTRANSPORT_ADDRESS remoteAddress; ULONG remoteAddressLength; PTDI_CONNECTION_INFORMATION requestConnectionInfo, returnConnectionInfo; PAGED_CODE( ); // // Initialize for proper cleanup // fileObject = NULL; connection = NULL; context = NULL; #ifdef _WIN64 if (IoIs32bitProcess (Irp)) { if (IrpSp->Parameters.DeviceIoControl.InputBufferLength< (ULONG)FIELD_OFFSET(AFD_CONNECT_JOIN_INFO32, RemoteAddress.Address[0].Address) || (IrpSp->Parameters.DeviceIoControl.OutputBufferLength!=0 && IrpSp->Parameters.DeviceIoControl.OutputBufferLength< sizeof (IO_STATUS_BLOCK32))){ status = STATUS_INVALID_PARAMETER; goto complete; } AFD_W4_INIT status = STATUS_SUCCESS; try { if( Irp->RequestorMode != KernelMode ) { ProbeForRead( IrpSp->Parameters.DeviceIoControl.Type3InputBuffer, IrpSp->Parameters.DeviceIoControl.InputBufferLength, PROBE_ALIGNMENT32 (AFD_CONNECT_JOIN_INFO32) ); } connectEndpointHandle = ((PAFD_CONNECT_JOIN_INFO32)IrpSp->Parameters.DeviceIoControl.Type3InputBuffer)->ConnectEndpoint; rootEndpointHandle = ((PAFD_CONNECT_JOIN_INFO32)IrpSp->Parameters.DeviceIoControl.Type3InputBuffer)->RootEndpoint; remoteAddress = (PTRANSPORT_ADDRESS)&((PAFD_CONNECT_JOIN_INFO32)IrpSp->Parameters.DeviceIoControl.Type3InputBuffer)->RemoteAddress; ASSERT (((ULONG_PTR)remoteAddress & (PROBE_ALIGNMENT(TRANSPORT_ADDRESS)-1))==0); remoteAddressLength = IrpSp->Parameters.DeviceIoControl.InputBufferLength - FIELD_OFFSET (AFD_CONNECT_JOIN_INFO32, RemoteAddress); } except (AFD_EXCEPTION_FILTER (status)) { ASSERT (NT_ERROR (status)); goto complete; } } else #endif //_WIN64 { // // Determine where in the system buffer the request and return // connection information structures exist. Pass pointers to // these locations instead of the user-mode pointers in the // tdiRequest structure so that the memory will be nonpageable. // if (IrpSp->Parameters.DeviceIoControl.InputBufferLength< (ULONG)FIELD_OFFSET (AFD_CONNECT_JOIN_INFO, RemoteAddress.Address[0].Address) || (IrpSp->Parameters.DeviceIoControl.OutputBufferLength!=0 && IrpSp->Parameters.DeviceIoControl.OutputBufferLength < sizeof (IO_STATUS_BLOCK))) { status = STATUS_INVALID_PARAMETER; goto complete; } AFD_W4_INIT status = STATUS_SUCCESS; try { if( Irp->RequestorMode != KernelMode ) { ProbeForRead( IrpSp->Parameters.DeviceIoControl.Type3InputBuffer, IrpSp->Parameters.DeviceIoControl.InputBufferLength, PROBE_ALIGNMENT (AFD_CONNECT_JOIN_INFO) ); } connectEndpointHandle = ((PAFD_CONNECT_JOIN_INFO)IrpSp->Parameters.DeviceIoControl.Type3InputBuffer)->ConnectEndpoint; rootEndpointHandle = ((PAFD_CONNECT_JOIN_INFO)IrpSp->Parameters.DeviceIoControl.Type3InputBuffer)->RootEndpoint; remoteAddress = &((PAFD_CONNECT_JOIN_INFO)IrpSp->Parameters.DeviceIoControl.Type3InputBuffer)->RemoteAddress; remoteAddressLength = IrpSp->Parameters.DeviceIoControl.InputBufferLength - FIELD_OFFSET (AFD_CONNECT_JOIN_INFO, RemoteAddress); } except (AFD_EXCEPTION_FILTER (status)) { ASSERT (NT_ERROR (status)); goto complete; } } // // Do sanity check on remoteAddressLength to prevent addition overflow below // if ((LONG)remoteAddressLength < 0) { // // address length is unreasonably large // status = STATUS_INVALID_PARAMETER; goto complete; } AFD_W4_INIT ASSERT (status == STATUS_SUCCESS); try { context = AFD_ALLOCATE_POOL_WITH_QUOTA (NonPagedPool, FIELD_OFFSET (AFD_CONNECT_CONTEXT, RemoteAddress) + remoteAddressLength, AFD_TDI_POOL_TAG ); // AFD_ALLOCATE_POOL_WITH_QUOTA macro sets POOL_RAISE_IF_ALLOCATION_FAILURE flag ASSERT (context!=NULL); Irp->AssociatedIrp.SystemBuffer = context; RtlZeroMemory (context, FIELD_OFFSET (AFD_CONNECT_CONTEXT, RemoteAddress)); RtlCopyMemory (&context->RemoteAddress, remoteAddress, remoteAddressLength); // // Validate internal consistency of the transport address structure. // Note that we HAVE to do this after copying since the malicious // application can change the content of the buffer on us any time // and our check will be bypassed. // if ((context->RemoteAddress.TAAddressCount!=1) || (LONG)remoteAddressLength< FIELD_OFFSET (TRANSPORT_ADDRESS, Address[0].Address[context->RemoteAddress.Address[0].AddressLength])) { ExRaiseStatus (STATUS_INVALID_PARAMETER); } context->RequestConnectionInfo.RemoteAddress = &context->RemoteAddress; context->RequestConnectionInfo.RemoteAddressLength = remoteAddressLength; if (IrpSp->Parameters.DeviceIoControl.OutputBufferLength>0 && Irp->RequestorMode==UserMode) { ProbeForWriteIoStatusEx ( ((PIO_STATUS_BLOCK)Irp->UserBuffer), IoIs32bitProcess (Irp)); } } except (AFD_EXCEPTION_FILTER(status)) { ASSERT (NT_ERROR (status)); goto complete; } fileObject = IrpSp->FileObject; leafEndpoint = fileObject->FsContext; if (leafEndpoint->Type==AfdBlockTypeHelper) { // // This is async join leaf which uses helper endpoint to // communicate to AFD. Get the real endpoint. // status = ObReferenceObjectByHandle( connectEndpointHandle, (IrpSp->Parameters.DeviceIoControl.IoControlCode>>14) & 3, // DesiredAccess *IoFileObjectType, // ObjectType Irp->RequestorMode, (PVOID *)&fileObject, NULL ); if (!NT_SUCCESS (status)) { goto complete; } if (fileObject->DeviceObject!=AfdDeviceObject) { status = STATUS_INVALID_HANDLE; goto complete_deref; } leafEndpoint = fileObject->FsContext; IrpSp->FileObject = fileObject; } else ObReferenceObject (fileObject); if (rootEndpointHandle!=NULL) { // // Root inviting leaf // PFILE_OBJECT rootObject; PAFD_ENDPOINT rootEndpoint; status = ObReferenceObjectByHandle( rootEndpointHandle, (IrpSp->Parameters.DeviceIoControl.IoControlCode>>14) & 3, // DesiredAccess *IoFileObjectType, // ObjectType Irp->RequestorMode, (PVOID *)&rootObject, NULL ); if (!NT_SUCCESS (status)) { goto complete_deref; } if (rootObject->DeviceObject!=AfdDeviceObject) { ObDereferenceObject (rootObject); status = STATUS_INVALID_HANDLE; goto complete_deref; } // // Get the endpoint structure of the file object // rootEndpoint = rootObject->FsContext; if (!AFD_START_STATE_CHANGE (leafEndpoint, AfdEndpointStateConnected)) { ObDereferenceObject (rootObject); status = STATUS_INVALID_PARAMETER; goto complete_deref; } // // Verify root and leaf endpoint's type and states // if (IS_VC_ENDPOINT(rootEndpoint) && rootEndpoint->afdC_Root && rootEndpoint->State==AfdEndpointStateConnected && (leafEndpoint->Type == AfdBlockTypeEndpoint || leafEndpoint->Type == AfdBlockTypeVcConnecting) && leafEndpoint->TransportInfo==rootEndpoint->TransportInfo && leafEndpoint->State==AfdEndpointStateOpen) { // // Create a connection object to use for the connect operation. // status = AfdCreateConnection( rootEndpoint->TransportInfo, rootEndpoint->AddressHandle, IS_TDI_BUFFERRING(rootEndpoint), leafEndpoint->InLine, leafEndpoint->OwningProcess, &connection ); // // No more joins are allowed while this one is active // if (AFD_START_STATE_CHANGE (rootEndpoint, rootEndpoint->State)) { AfdJoinInviteSetup (rootEndpoint, leafEndpoint); } else { status = STATUS_INVALID_PARAMETER; } } else { status = STATUS_INVALID_PARAMETER; } // // We referenced root endpoint in invite routine, so // we no longer need reference to root file object // ObDereferenceObject (rootObject); if (!NT_SUCCESS (status)) { goto complete_state_change; } } else { // // If this is a datagram endpoint, simply remember the specified // address so that we can use it on sends, and writes. // if ( IS_DGRAM_ENDPOINT(leafEndpoint) ) { if (leafEndpoint->State!=AfdEndpointStateConnected) { return AfdDoDatagramConnect( fileObject, Irp, TRUE); } else { // // If endpoint is already connected, that connection takes // precedence // status = STATUS_SUCCESS; goto complete_deref; } } else { if (!AFD_START_STATE_CHANGE (leafEndpoint, AfdEndpointStateConnected)) { status = STATUS_INVALID_PARAMETER; goto complete_deref; } if ((leafEndpoint->Type != AfdBlockTypeEndpoint && leafEndpoint->Type != AfdBlockTypeVcConnecting) || leafEndpoint->State != AfdEndpointStateBound) { status = STATUS_INVALID_PARAMETER; goto complete_state_change; } // // Create a connection object to use for the connect operation. // status = AfdCreateConnection( leafEndpoint->TransportInfo, leafEndpoint->AddressHandle, IS_TDI_BUFFERRING(leafEndpoint), leafEndpoint->InLine, leafEndpoint->OwningProcess, &connection ); if ( !NT_SUCCESS(status) ) { goto complete_state_change; } } } IF_DEBUG(CONNECT) { KdPrintEx(( DPFLTR_WSOCKTRANSPORT_ID, DPFLTR_TRACE_LEVEL, "AfdJoinLeaf: starting join for endpoint %p\n", leafEndpoint )); } // // Set up a referenced pointer from the connection to the endpoint. // Note that we set up the connection's pointer to the endpoint // BEFORE the endpoint's pointer to the connection so that AfdPoll // doesn't try to back reference the endpoint from the connection. // REFERENCE_ENDPOINT( leafEndpoint ); connection->Endpoint = leafEndpoint; // // Remember that this is now a connecting type of endpoint, and set // up a pointer to the connection in the endpoint. This is // implicitly a referenced pointer. // leafEndpoint->Common.VcConnecting.Connection = connection; leafEndpoint->Type = AfdBlockTypeVcConnecting; ASSERT( IS_TDI_BUFFERRING(leafEndpoint) == connection->TdiBufferring ); // // Add an additional reference to the connection. This prevents the // connection from being closed until the disconnect event handler // is called. // AfdAddConnectedReference( connection ); // // If there are connect data buffers, move them from the endpoint // structure to the connection structure and set up the necessary // pointers in the connection request we're going to give to the TDI // provider. Do this in a subroutine so this routine can be pageable. // requestConnectionInfo = &context->RequestConnectionInfo; returnConnectionInfo = &context->ReturnConnectionInfo; if ( leafEndpoint->Common.VirtualCircuit.ConnectDataBuffers != NULL ) { AfdSetupConnectDataBuffers( leafEndpoint, connection, &requestConnectionInfo, &returnConnectionInfo ); } // // Since we may be reissuing a connect after a previous failed connect, // reenable the failed connect event bit. // AfdEnableFailedConnectEvent( leafEndpoint ); REFERENCE_CONNECTION (connection); // // Build a TDI kernel-mode connect request in the next stack location // of the IRP. // TdiBuildConnect( Irp, connection->DeviceObject, connection->FileObject, AfdRestartJoin, connection, &AfdInfiniteTimeout, requestConnectionInfo, returnConnectionInfo ); AFD_VERIFY_ADDRESS (connection, &context->ReturnConnectionInfo->RemoteAddress); // // Call the transport to actually perform the connect operation. // return AfdIoCallDriver( leafEndpoint, connection->DeviceObject, Irp ); complete_state_change: AFD_END_STATE_CHANGE (leafEndpoint); complete_deref: ObDereferenceObject (fileObject); complete: if (context!=NULL) { AFD_FREE_POOL (context, AFD_TDI_POOL_TAG); ASSERT (Irp->AssociatedIrp.SystemBuffer==context); Irp->AssociatedIrp.SystemBuffer = NULL; } if (connection!=NULL) { DEREFERENCE_CONNECTION (connection); } Irp->IoStatus.Information = 0; Irp->IoStatus.Status = status; IoCompleteRequest( Irp, AfdPriorityBoost ); return status; } // AfdJoinLeaf VOID AfdJoinInviteSetup ( PAFD_ENDPOINT RootEndpoint, PAFD_ENDPOINT LeafEndpoint ) { NTSTATUS status; AFD_LOCK_QUEUE_HANDLE lockHandle; RootEndpoint->EventsActive &= ~AFD_POLL_CONNECT; AfdAcquireSpinLock (&LeafEndpoint->SpinLock, &lockHandle); LeafEndpoint->TdiServiceFlags = RootEndpoint->TdiServiceFlags; // // Set up a referenced pointer to the root endpoint. This is // necessary so that the endpoint does not go away until all // leaf endpoints have gone away. Without this, we can free // several shared strucutures that are associated with root // endpoint and then attempt to use them in leaf endpoints. // REFERENCE_ENDPOINT (RootEndpoint); LeafEndpoint->Common.VcConnecting.ListenEndpoint = RootEndpoint; // // Set up a referenced pointer in the accepted endpoint to the // TDI address object. // ObReferenceObject( RootEndpoint->AddressFileObject ); AfdRecordAddrRef(); LeafEndpoint->AddressFileObject = RootEndpoint->AddressFileObject; LeafEndpoint->AddressDeviceObject = RootEndpoint->AddressDeviceObject; // // Copy the pointer to the local address. Because we keep listen // endpoint alive for as long as any of its connection is // active, we can rely on the fact that address structure won't go // away as well. // LeafEndpoint->LocalAddress = RootEndpoint->LocalAddress; LeafEndpoint->LocalAddressLength = RootEndpoint->LocalAddressLength; status = STATUS_SUCCESS; AfdReleaseSpinLock (&LeafEndpoint->SpinLock, &lockHandle); } // AfdJoinInviteSetup NTSTATUS AfdRestartJoin ( IN PDEVICE_OBJECT DeviceObject, IN PIRP Irp, IN PVOID Context ) /*++ Routine Description: Handles the IOCTL_AFD_CONNECT IOCTL. Arguments: Irp - Pointer to I/O request packet. IrpSp - pointer to the IO stack location to use for this request. Return Value: NTSTATUS -- Indicates whether the request was successfully queued. --*/ { PAFD_ENDPOINT endpoint, rootEndpoint; PAFD_CONNECTION connection; AFD_LOCK_QUEUE_HANDLE lockHandle; PIO_STACK_LOCATION irpSp; PFILE_OBJECT fileObject; PAFD_CONNECT_CONTEXT context; UNREFERENCED_PARAMETER (DeviceObject); connection = Context; ASSERT( connection->Type == AfdBlockTypeConnection ); irpSp = IoGetCurrentIrpStackLocation( Irp ); fileObject = irpSp->FileObject; ASSERT( fileObject->DeviceObject == AfdDeviceObject ); endpoint = fileObject->FsContext; ASSERT( endpoint->Type == AfdBlockTypeVcConnecting ); context = Irp->AssociatedIrp.SystemBuffer; ASSERT( context != NULL ); IF_DEBUG(CONNECT) { KdPrintEx(( DPFLTR_WSOCKTRANSPORT_ID, DPFLTR_TRACE_LEVEL, "AfdRestartJoin: join completed, status = %X, " "LeafEndpoint = %p, RootEndpoint = %p\n", Irp->IoStatus.Status, endpoint, endpoint->Common.VcConnecting.ListenEndpoint )); } // // If this endpoint has root associated with it, // we need to update it as well. // rootEndpoint = endpoint->Common.VcConnecting.ListenEndpoint; ASSERT ( rootEndpoint==NULL || (rootEndpoint->afdC_Root && (rootEndpoint->Type == AfdBlockTypeVcConnecting || rootEndpoint->Type == AfdBlockTypeVcBoth) ) ); // // If there are connect buffers on this endpoint, remember the // size of the return connect data. // if ( connection->ConnectDataBuffers != NULL ) { AfdAcquireSpinLock( &endpoint->SpinLock, &lockHandle ); // // Double-check under the lock // if ( connection->ConnectDataBuffers != NULL ) { NTSTATUS status; status = AfdSaveReceivedConnectData( &connection->ConnectDataBuffers, IOCTL_AFD_SET_CONNECT_DATA, connection->ConnectDataBuffers->ReturnConnectionInfo.UserData, connection->ConnectDataBuffers->ReturnConnectionInfo.UserDataLength ); ASSERT (NT_SUCCESS (status)); status = AfdSaveReceivedConnectData( &connection->ConnectDataBuffers, IOCTL_AFD_SET_CONNECT_OPTIONS, connection->ConnectDataBuffers->ReturnConnectionInfo.Options, connection->ConnectDataBuffers->ReturnConnectionInfo.OptionsLength ); ASSERT (NT_SUCCESS (status)); } AfdReleaseSpinLock( &endpoint->SpinLock, &lockHandle ); } // // Indicate that the connect completed. Implicitly, the successful // completion of a connect also means that the caller can do a send // on the socket. // if ( NT_SUCCESS(Irp->IoStatus.Status) ) { // // If the request succeeded, set the endpoint to the connected // state. The endpoint type has already been set to // AfdBlockTypeVcConnecting. // endpoint->State = AfdEndpointStateConnected; ASSERT( endpoint->Type == AfdBlockTypeVcConnecting ); // // Remember the time that the connection started. // connection->ConnectTime = KeQueryInterruptTime(); } else { // // The connect failed, so reset the type to open. // If we don't reset, we won't be able to start // another join // endpoint->Type = AfdBlockTypeEndpoint; AfdAcquireSpinLock( &endpoint->SpinLock, &lockHandle ); // // Remove references to listening endpoint and connection // Actual dereferncing is below after we release the spinlock if (rootEndpoint!=NULL) { endpoint->Common.VcConnecting.ListenEndpoint = NULL; // // We used the local address from the listening endpoint, // simply reset it, it will be freed when listening endpoint // is freed. // ASSERT (endpoint->LocalAddress==rootEndpoint->LocalAddress); endpoint->LocalAddress = NULL; endpoint->LocalAddressLength = 0; } if (endpoint->Common.VcConnecting.Connection != NULL) { endpoint->Common.VcConnecting.Connection = NULL; // // Manually delete the connected reference if somebody else // hasn't already done so. We can't use // AfdDeleteConnectedReference() because it refuses to delete // the connected reference until the endpoint has been cleaned // up. // if ( connection->ConnectedReferenceAdded ) { connection->ConnectedReferenceAdded = FALSE; AfdReleaseSpinLock( &endpoint->SpinLock, &lockHandle ); DEREFERENCE_CONNECTION( connection ); } else { AfdReleaseSpinLock( &endpoint->SpinLock, &lockHandle ); } // // Dereference the connection block stored on the endpoint. // This should cause the connection object reference count to go // to zero to the connection object can be deleted. // DEREFERENCE_CONNECTION( connection ); } else { AfdReleaseSpinLock( &endpoint->SpinLock, &lockHandle ); } } AFD_FREE_POOL (context, AFD_TDI_POOL_TAG); Irp->AssociatedIrp.SystemBuffer = NULL; // // If pending has be returned for this irp then mark the current // stack as pending. // if ( Irp->PendingReturned ) { IoMarkIrpPending(Irp); } AfdCompleteOutstandingIrp( endpoint, Irp ); // // Dereference connection to account for reference // we added in AfdConnect // DEREFERENCE_CONNECTION( connection ); // // Try to queue kernel APC to the user thread that // started the connection operation, so we can // communicate the status of the connect operation to // msafd.dll before we inform the application through // the select or EventSelect. Otherwise, we run into the // race condition when application learns about connect first, // calls msafd.dll that is not aware of the completion and // returns WSAENOTCONN. // if ((Irp->RequestorMode==UserMode) && // Must be user mode calls (Irp->UserBuffer!=NULL) && // Must be interested in status // Thread should be able to // run APCs. (KeInitializeApc (&endpoint->Common.VcConnecting.Apc, PsGetThreadTcb (Irp->Tail.Overlay.Thread), Irp->ApcEnvironment, AfdConnectApcKernelRoutine, AfdConnectApcRundownRoutine, (PKNORMAL_ROUTINE)NULL, KernelMode, NULL ), KeInsertQueueApc (&endpoint->Common.VcConnecting.Apc, Irp, rootEndpoint, AfdPriorityBoost))) { // // We will complete the IRP in the APC. // return STATUS_MORE_PROCESSING_REQUIRED; } else { // // APC was not necessary or did not work. // Complete it here. // AfdFinishConnect (endpoint, Irp, rootEndpoint); return STATUS_SUCCESS; } } // AfdRestartJoin NTSTATUS FASTCALL AfdSuperConnect ( IN PIRP Irp, IN PIO_STACK_LOCATION IrpSp ) /*++ Routine Description: Handles the IOCTL_AFD_SUPER_CONNECT IOCTL. Arguments: Irp - Pointer to I/O request packet. IrpSp - pointer to the IO stack location to use for this request. Return Value: NTSTATUS -- Indicates whether the request was successfully queued. --*/ { NTSTATUS status; PAFD_ENDPOINT endpoint; PAFD_CONNECTION connection; PAFD_BUFFER afdBuffer; PAFD_SUPER_CONNECT_INFO connectInfo; PTRANSPORT_ADDRESS remoteAddress; PVOID context; PTDI_CONNECTION_INFORMATION requestConnectionInfo, returnConnectionInfo; PAGED_CODE( ); // // Initialize for proper cleanup // afdBuffer = NULL; endpoint = IrpSp->FileObject->FsContext; if (IrpSp->Parameters.DeviceIoControl.InputBufferLength< (ULONG)FIELD_OFFSET(AFD_SUPER_CONNECT_INFO, RemoteAddress.Address[0].Address)) { status = STATUS_INVALID_PARAMETER; goto complete; } AFD_W4_INIT status = STATUS_SUCCESS; try { if( Irp->RequestorMode != KernelMode ) { ProbeForRead( IrpSp->Parameters.DeviceIoControl.Type3InputBuffer, IrpSp->Parameters.DeviceIoControl.InputBufferLength, PROBE_ALIGNMENT (AFD_SUPER_CONNECT_INFO) ); if (IrpSp->Parameters.DeviceIoControl.OutputBufferLength!=0) { ProbeForRead (Irp->UserBuffer, IrpSp->Parameters.DeviceIoControl.OutputBufferLength, sizeof (UCHAR)); } } connectInfo = IrpSp->Parameters.DeviceIoControl.Type3InputBuffer; // // Check for if the caller is unaware of the SAN // provider activation and report the error. // if (!connectInfo->SanActive && AfdSanServiceHelper!=NULL) { KdPrintEx(( DPFLTR_WSOCKTRANSPORT_ID, DPFLTR_INFO_LEVEL, "AFD: Process %p is being told to enable SAN on connect\n", PsGetCurrentProcessId ())); status = STATUS_INVALID_PARAMETER_12; goto complete; } afdBuffer = AfdGetBufferRaiseOnFailure ( endpoint, IrpSp->Parameters.DeviceIoControl.OutputBufferLength, IrpSp->Parameters.DeviceIoControl.InputBufferLength- FIELD_OFFSET(AFD_SUPER_CONNECT_INFO, RemoteAddress), endpoint->OwningProcess ); remoteAddress = afdBuffer->TdiInfo.RemoteAddress; afdBuffer->TdiInfo.RemoteAddressLength = IrpSp->Parameters.DeviceIoControl.InputBufferLength- FIELD_OFFSET(AFD_SUPER_CONNECT_INFO, RemoteAddress); RtlCopyMemory (afdBuffer->TdiInfo.RemoteAddress, &connectInfo->RemoteAddress, afdBuffer->TdiInfo.RemoteAddressLength); // // Validate internal consistency of the transport address structure. // Note that we HAVE to do this after copying since the malicious // application can change the content of the buffer on us any time // and our check will be bypassed. // if ((remoteAddress->TAAddressCount!=1) || (LONG)afdBuffer->TdiInfo.RemoteAddressLength< FIELD_OFFSET (TRANSPORT_ADDRESS, Address[0].Address[remoteAddress->Address[0].AddressLength])) { ExRaiseStatus (STATUS_INVALID_PARAMETER); } if (IrpSp->Parameters.DeviceIoControl.OutputBufferLength>0) { RtlCopyMemory (afdBuffer->Buffer, Irp->UserBuffer, IrpSp->Parameters.DeviceIoControl.OutputBufferLength ); afdBuffer->DataLength = IrpSp->Parameters.DeviceIoControl.OutputBufferLength; } else { afdBuffer->DataLength = 0; } } except (AFD_EXCEPTION_FILTER(status)) { ASSERT (NT_ERROR (status)); goto complete; } if (!AFD_START_STATE_CHANGE (endpoint, AfdEndpointStateConnected)) { status = STATUS_INVALID_PARAMETER; goto complete; } // // If the endpoint is not bound, then this is an invalid request. // Listening endpoints are not allowed as well. // We do not support sending data with TDI buffering transports too. // if ( endpoint->Type != AfdBlockTypeEndpoint || endpoint->State != AfdEndpointStateBound || endpoint->Listening || (IS_TDI_BUFFERRING (endpoint) && IrpSp->Parameters.DeviceIoControl.OutputBufferLength!=0)) { if (endpoint->State==AfdEndpointStateConnected) { status = STATUS_CONNECTION_ACTIVE; } else { status = STATUS_INVALID_PARAMETER; } goto complete_state_change; } IF_DEBUG(CONNECT) { KdPrintEx(( DPFLTR_WSOCKTRANSPORT_ID, DPFLTR_TRACE_LEVEL, "AfdSuperConnect: starting connect on endpoint %p\n", endpoint )); } // // Create a connection object to use for the connect operation. // status = AfdCreateConnection( endpoint->TransportInfo, endpoint->AddressHandle, IS_TDI_BUFFERRING(endpoint), endpoint->InLine, endpoint->OwningProcess, &connection ); if ( !NT_SUCCESS(status) ) { goto complete_state_change; } // // Set up a referenced pointer from the connection to the endpoint. // Note that we set up the connection's pointer to the endpoint // BEFORE the endpoint's pointer to the connection so that AfdPoll // doesn't try to back reference the endpoint from the connection. // REFERENCE_ENDPOINT( endpoint ); connection->Endpoint = endpoint; // // Remember that this is now a connecting type of endpoint, and set // up a pointer to the connection in the endpoint. This is // implicitly a referenced pointer. // endpoint->Common.VcConnecting.Connection = connection; endpoint->Type = AfdBlockTypeVcConnecting; ASSERT( IS_TDI_BUFFERRING(endpoint) == connection->TdiBufferring ); // // Add an additional reference to the connection. This prevents the // connection from being closed until the disconnect event handler // is called. // AfdAddConnectedReference( connection ); // // Since we may be reissuing a connect after a previous failed connect, // reenable the failed connect event bit. // AfdEnableFailedConnectEvent( endpoint ); // // Copy remote address to the user mode context // context = AfdLockEndpointContext (endpoint); if ( (((CLONG)(endpoint->Common.VcConnecting.RemoteSocketAddressOffset+ endpoint->Common.VcConnecting.RemoteSocketAddressLength)) < endpoint->ContextLength) && (endpoint->Common.VcConnecting.RemoteSocketAddressLength >= remoteAddress->Address[0].AddressLength + sizeof(u_short))) { RtlMoveMemory ((PUCHAR)context + endpoint->Common.VcConnecting.RemoteSocketAddressOffset, &remoteAddress->Address[0].AddressType, remoteAddress->Address[0].AddressLength + sizeof(u_short)); } else { KdPrintEx(( DPFLTR_WSOCKTRANSPORT_ID, DPFLTR_WARNING_LEVEL, "AfdSuperConnect: Could not copy remote address for AcceptEx on endpoint: %p, process: %p\n", endpoint, endpoint->OwningProcess)); } AfdUnlockEndpointContext (endpoint, context); // // Reference the connection block so it does not go away even if // endpoint's reference to it is removed (in cleanup) // REFERENCE_CONNECTION (connection); // // If there are connect data buffers, move them from the endpoint // structure to the connection structure and set up the necessary // pointers in the connection request we're going to give to the TDI // provider. Do this in a subroutine so this routine can be pageable. // requestConnectionInfo = &afdBuffer->TdiInfo; afdBuffer->TdiInfo.UserDataLength = 0; afdBuffer->TdiInfo.UserData = NULL; afdBuffer->TdiInfo.OptionsLength = 0; afdBuffer->TdiInfo.Options = NULL; // // Temporarily use IRP embedded in afd buffer // for return connection information. // { C_ASSERT (sizeof (TDI_CONNECTION_INFORMATION)<= sizeof (IO_STACK_LOCATION)); } returnConnectionInfo = (PTDI_CONNECTION_INFORMATION)IoGetNextIrpStackLocation (afdBuffer->Irp); RtlZeroMemory (returnConnectionInfo, sizeof (*returnConnectionInfo)); if ( endpoint->Common.VirtualCircuit.ConnectDataBuffers != NULL ) { AfdSetupConnectDataBuffers( endpoint, connection, &requestConnectionInfo, &returnConnectionInfo ); } afdBuffer->Context = connection; // // Build a TDI kernel-mode connect request in the next stack location // of the IRP. // TdiBuildConnect( Irp, connection->DeviceObject, connection->FileObject, AfdRestartSuperConnect, afdBuffer, &AfdInfiniteTimeout, requestConnectionInfo, returnConnectionInfo ); AFD_VERIFY_ADDRESS (connection, afdBuffer->TdiInfo.RemoteAddress); ObReferenceObject (IrpSp->FileObject); // // Call the transport to actually perform the connect operation. // return AfdIoCallDriver( endpoint, connection->DeviceObject, Irp ); complete_state_change: AFD_END_STATE_CHANGE (endpoint); complete: if (afdBuffer!=NULL) { AfdReturnBuffer (&afdBuffer->Header, endpoint->OwningProcess); } Irp->IoStatus.Information = 0; Irp->IoStatus.Status = status; IoCompleteRequest( Irp, AfdPriorityBoost ); return status; } // AfdSuperConnect NTSTATUS AfdRestartSuperConnect ( IN PDEVICE_OBJECT DeviceObject, IN PIRP Irp, IN PVOID Context ) /*++ Routine Description: Handles the IOCTL_AFD_CONNECT IOCTL. Arguments: Irp - Pointer to I/O request packet. IrpSp - pointer to the IO stack location to use for this request. Return Value: NTSTATUS -- Indicates whether the request was successfully queued. --*/ { PAFD_ENDPOINT endpoint; PAFD_CONNECTION connection; AFD_LOCK_QUEUE_HANDLE lockHandle; PIO_STACK_LOCATION irpSp; PAFD_BUFFER afdBuffer; UNREFERENCED_PARAMETER (DeviceObject); afdBuffer = Context; connection = afdBuffer->Context; ASSERT( connection->Type == AfdBlockTypeConnection ); irpSp = IoGetCurrentIrpStackLocation( Irp ); endpoint = irpSp->FileObject->FsContext; ASSERT( endpoint->Type == AfdBlockTypeVcConnecting ); ASSERT( endpoint==connection->Endpoint ); IF_DEBUG(CONNECT) { KdPrintEx(( DPFLTR_WSOCKTRANSPORT_ID, DPFLTR_TRACE_LEVEL, "AfdRestartConnect: connect completed, status = %X, endpoint = %p\n", Irp->IoStatus.Status, endpoint )); } if ( connection->ConnectDataBuffers != NULL ) { // // If there are connect buffers on this endpoint, remember the // size of the return connect data. // AfdAcquireSpinLock( &endpoint->SpinLock, &lockHandle ); // // Double-check under the lock // if ( connection->ConnectDataBuffers != NULL ) { AfdSaveReceivedConnectData( &connection->ConnectDataBuffers, IOCTL_AFD_SET_CONNECT_DATA, connection->ConnectDataBuffers->ReturnConnectionInfo.UserData, connection->ConnectDataBuffers->ReturnConnectionInfo.UserDataLength ); AfdSaveReceivedConnectData( &connection->ConnectDataBuffers, IOCTL_AFD_SET_CONNECT_OPTIONS, connection->ConnectDataBuffers->ReturnConnectionInfo.Options, connection->ConnectDataBuffers->ReturnConnectionInfo.OptionsLength ); } AfdReleaseSpinLock( &endpoint->SpinLock, &lockHandle ); } // // Indicate that the connect completed. Implicitly, the successful // completion of a connect also means that the caller can do a send // on the socket. // if ( NT_SUCCESS(Irp->IoStatus.Status)) { // // If the request succeeded, set the endpoint to the connected // state. The endpoint type has already been set to // AfdBlockTypeVcConnecting. // endpoint->State = AfdEndpointStateConnected; ASSERT( endpoint->Type == AfdBlockTypeVcConnecting ); // // Remember the time that the connection started. // connection->ConnectTime = KeQueryInterruptTime(); } else { // // The connect failed, so reset the type to open. // Otherwise, we won't be able to start another connect // endpoint->Type = AfdBlockTypeEndpoint; AfdAcquireSpinLock( &endpoint->SpinLock, &lockHandle ); if (endpoint->Common.VcConnecting.Connection!=NULL) { ASSERT (connection==endpoint->Common.VcConnecting.Connection); endpoint->Common.VcConnecting.Connection = NULL; // // Manually delete the connected reference if somebody else // hasn't already done so. We can't use // AfdDeleteConnectedReference() because it refuses to delete // the connected reference until the endpoint has been cleaned // up. // if ( connection->ConnectedReferenceAdded ) { connection->ConnectedReferenceAdded = FALSE; AfdReleaseSpinLock( &endpoint->SpinLock, &lockHandle ); DEREFERENCE_CONNECTION( connection ); } else { AfdReleaseSpinLock( &endpoint->SpinLock, &lockHandle ); } // // Dereference the connection block stored on the endpoint. // This should cause the connection object reference count to go // to zero to the connection object can be deleted. // DEREFERENCE_CONNECTION( connection ); } else { // // The endpoint's reference to connection was removed // (perhaps in cleanup); // AfdReleaseSpinLock( &endpoint->SpinLock, &lockHandle ); } } // // If pending has be returned for this irp then mark the current // stack as pending. // if ( Irp->PendingReturned ) { IoMarkIrpPending(Irp); } AfdCompleteOutstandingIrp( endpoint, Irp ); AfdFinishConnect (endpoint, Irp, NULL); if (NT_SUCCESS (Irp->IoStatus.Status) && afdBuffer->DataLength>0) { AfdAcquireSpinLock (&endpoint->SpinLock, &lockHandle); if ( !connection->CleanupBegun && !connection->Aborted ) { NTSTATUS status; // // Update count of send bytes pending on the connection. // connection->VcBufferredSendBytes += afdBuffer->DataLength; connection->VcBufferredSendCount += 1; AfdReleaseSpinLock (&endpoint->SpinLock, &lockHandle); afdBuffer->Mdl->ByteCount = afdBuffer->DataLength; ASSERT (afdBuffer->Context == connection ); TdiBuildSend( afdBuffer->Irp, connection->DeviceObject, connection->FileObject, AfdRestartBufferSend, afdBuffer, afdBuffer->Mdl, 0, afdBuffer->DataLength ); Irp->IoStatus.Information = afdBuffer->DataLength; // // Call the transport to actually perform the send. // status = IoCallDriver ( connection->DeviceObject, afdBuffer->Irp ); if (!NT_SUCCESS (status)) { Irp->IoStatus.Status = status; Irp->IoStatus.Information = 0; } goto exit; } if (connection->CleanupBegun) { Irp->IoStatus.Status = STATUS_LOCAL_DISCONNECT; } else { ASSERT (connection->Aborted); Irp->IoStatus.Status = STATUS_REMOTE_DISCONNECT; } AfdReleaseSpinLock (&endpoint->SpinLock, &lockHandle); } afdBuffer->DataOffset = 0; AfdReturnBuffer (&afdBuffer->Header, endpoint->OwningProcess); // // Dereference connection to account for reference we added in AfdConnect // DEREFERENCE_CONNECTION (connection); exit: return STATUS_SUCCESS; } // AfdRestartSuperConnect