/*++ Copyright (c) 1991 Microsoft Corporation Module Name: timer.c Abstract: This module contains code which implements the receive and send timeouts for each connection. Netbios timeouts are specified in 0.5 second units. For each application using Netbios there is a single timer started when the first connection specifies a non-zero rto or sto. This regular 1 second pulse is used for all connections by this application. It is stopped when the application exits (and closes the connection to \Device\Netbios). If a send timesout the connection is disconnected as per Netbios 3.0. Individual receives can timeout without affecting the session. Author: Colin Watson (ColinW) 15-Sep-1991 Environment: Kernel mode Revision History: --*/ #include "nb.h" #ifdef ALLOC_PRAGMA #pragma alloc_text(PAGE, NbStartTimer) #pragma alloc_text(PAGE, NbTimer) #endif VOID RunTimerForLana( PFCB pfcb, PLANA_INFO plana, int index ); VOID NbStartTimer( IN PFCB pfcb ) /*++ Routine Description: This routine starts the timer ticking for this FCB. Arguments: pfcb - Pointer to our FCB. Return Value: none. --*/ { LARGE_INTEGER DueTime; PAGED_CODE(); DueTime.QuadPart = Int32x32To64( 500, -MILLISECONDS ); // This is the first connection with timeouts specified. // // set up the timer so that every 500 milliseconds we scan all the // connections for timed out receive and sends. // IF_NBDBG (NB_DEBUG_CALL) { NbPrint( ("Start the timer for fcb: %lx\n", pfcb)); } if ( pfcb->TimerRunning == TRUE ) { return; } KeInitializeDpc ( &pfcb->Dpc, NbTimerDPC, pfcb); KeInitializeTimer (&pfcb->Timer); pfcb->TimerRunning = TRUE; (VOID)KeSetTimer ( &pfcb->Timer, DueTime, &pfcb->Dpc); } VOID NbTimerDPC( IN PKDPC Dpc, IN PVOID Context, IN PVOID SystemArgument1, IN PVOID SystemArgument2 ) /*++ Routine Description: This routine is called to search for timed out send and receive requests. This routine is called at raised Irql. Arguments: Context - Pointer to our FCB. Return Value: none. --*/ { PFCB pfcb = (PFCB) Context; ExQueueWorkItem( &pfcb->WorkEntry, DelayedWorkQueue ); UNREFERENCED_PARAMETER (Dpc); UNREFERENCED_PARAMETER (SystemArgument1); UNREFERENCED_PARAMETER (SystemArgument2); } VOID NbTimer( PVOID Context ) { ULONG lana_index; int index; PFCB pfcb = (PFCB) Context; LARGE_INTEGER DueTime; PAGED_CODE(); // // For each network adapter that is allocated, scan each connection. // LOCK_RESOURCE(pfcb); IF_NBDBG (NB_DEBUG_TIMER) { NbPrint((" NbTimeout\n" )); } if ( pfcb->TimerRunning != TRUE ) { // // Driver is being closed. We are trying to cancel the timer // but the dpc was already fired. Set the timer cancelled event // to the signalled state and exit. // UNLOCK_RESOURCE(pfcb); KeSetEvent( pfcb->TimerCancelled, 0, FALSE); return; } for ( lana_index = 0; lana_index <= pfcb->MaxLana; lana_index++ ) { // For each network. PLANA_INFO plana = pfcb->ppLana[lana_index]; if (( plana != NULL ) && ( plana->Status == NB_INITIALIZED)) { // For each connection on that network. for ( index = 1; index <= MAXIMUM_CONNECTION; index++) { if ( plana->ConnectionBlocks[index] != NULL ) { IF_NBDBG (NB_DEBUG_TIMER) { NbPrint((" Check Lana:%x Lsn: %x\n", lana_index, index )); } RunTimerForLana(pfcb, plana, index); } } } } DueTime.QuadPart = Int32x32To64( 500, -MILLISECONDS ); (VOID)KeSetTimer ( &pfcb->Timer, DueTime, &pfcb->Dpc); UNLOCK_RESOURCE(pfcb); } VOID RunTimerForLana( PFCB pfcb, PLANA_INFO plana, int index ) { KIRQL OldIrql; // Used when SpinLock held. PPCB ppcb; PCB pcb; ppcb = &plana->ConnectionBlocks[index]; pcb = *ppcb; if (( pcb->Status != SESSION_ESTABLISHED ) && ( pcb->Status != HANGUP_PENDING )) { // Only examine valid connections. return; } LOCK_SPINLOCK( pfcb, OldIrql ); if (( pcb->ReceiveTimeout != 0 ) && ( !IsListEmpty( &pcb->ReceiveList))) { PDNCB pdncb; PLIST_ENTRY ReceiveEntry = pcb->ReceiveList.Flink; pdncb = CONTAINING_RECORD( ReceiveEntry, DNCB, ncb_next); if ( pdncb->tick_count <= 1) { PIRP Irp = pdncb->irp; // Read request timed out. IF_NBDBG (NB_DEBUG_TIMER) { NbPrint(("Timeout Read pncb: %lx\n", pdncb)); } NCB_COMPLETE( pdncb, NRC_CMDTMO ); RemoveEntryList( &pdncb->ncb_next ); IoAcquireCancelSpinLock(&Irp->CancelIrql); // // Remove the cancel request for this IRP. If its cancelled then its // ok to just process it because we will be returning it to the caller. // Irp->Cancel = FALSE; IoSetCancelRoutine(Irp, NULL); IoReleaseCancelSpinLock(Irp->CancelIrql); // repair the Irp so that the NCB gets copied back. Irp->IoStatus.Status = STATUS_SUCCESS; Irp->IoStatus.Information = FIELD_OFFSET( DNCB, ncb_cmd_cplt ); IoCompleteRequest( Irp, IO_NETWORK_INCREMENT); } else { IF_NBDBG (NB_DEBUG_TIMER) { NbPrint(("Tick Read pdncb: %lx, count: %x\n", pdncb, pdncb->tick_count)); } pdncb->tick_count -= 1; } } if (( pcb->SendTimeout != 0 ) && (!IsListEmpty( &pcb->SendList))) { PDNCB pdncb; PLIST_ENTRY SendEntry = pcb->SendList.Flink; pdncb = CONTAINING_RECORD( SendEntry, DNCB, ncb_next); if ( pdncb->tick_count <= 1) { // Send request timed out- hangup connection. IF_NBDBG (NB_DEBUG_TIMER) { NbPrint(("Timeout send pncb: %lx\n", pdncb)); } NCB_COMPLETE( pdncb, NRC_CMDTMO ); pcb->Status = SESSION_ABORTED; UNLOCK_SPINLOCK( pfcb, OldIrql ); CloseConnection( ppcb ); // // No need to worry about looking for a timed out hangup, the session // will be closed as soon as the transport cancels the send. // return; } else { IF_NBDBG (NB_DEBUG_TIMER) { NbPrint(("Tick Write pdncb: %lx, count: %x\n", pdncb, pdncb->tick_count)); } pdncb->tick_count -= 1; } } if (( pcb->pdncbHangup != NULL ) && ( pcb->Status == HANGUP_PENDING )) { if ( pcb->pdncbHangup->tick_count <= 1) { IF_NBDBG (NB_DEBUG_TIMER) { NbPrint(("Timeout send pncb: %lx\n", pcb->pdncbHangup)); } NCB_COMPLETE( pcb->pdncbHangup, NRC_CMDTMO ); UNLOCK_SPINLOCK( pfcb, OldIrql ); AbandonConnection( ppcb ); LOCK_SPINLOCK( pfcb, OldIrql ); } else { IF_NBDBG (NB_DEBUG_TIMER) { NbPrint(("Tick Hangup pdncb: %lx, count: %x\n", pcb->pdncbHangup, pcb->pdncbHangup->tick_count)); } pcb->pdncbHangup->tick_count -= 1; } } UNLOCK_SPINLOCK( pfcb, OldIrql ); }