/*++ Copyright (c) 1994 Microsoft Corporation Module Name: rxworkq.h Abstract: This module defines the data structures required to implement the dispatching mechanism in RDBSS for use by RDBSS as well as all the mini redirectors. Author: Balan Sethu Raman [SethuR] 20-Mar-96 --*/ #ifndef _RXWORKQ_H_ #define _RXWORKQ_H_ // // The worker thread routine prototype definition. // typedef VOID (NTAPI *PRX_WORKERTHREAD_ROUTINE) ( IN PVOID Context ); // // The RDBSS needs to keep track of the work items on a per device object basis. // This enables the race conditions associated with loading/unloading as well as // a mechanism for preventing a single mini redirector from unfairly hogging all // the resources. // #ifdef __cplusplus typedef struct _RX_WORK_QUEUE_ITEM_ : public WORK_QUEUE_ITEM { // the work queue item as defined in NTOS #else // !__cplusplus typedef struct _RX_WORK_QUEUE_ITEM_ { WORK_QUEUE_ITEM; // the work queue item as defined in NTOS #endif // __cplusplus PRDBSS_DEVICE_OBJECT pDeviceObject; } RX_WORK_QUEUE_ITEM, *PRX_WORK_QUEUE_ITEM; // // There are certain scenarios in which dispatching of work items is inevitable. // In such instance the WORK_QUEUE_ITEM is allocated as part of another data // structure to avoid frequent allocation/freeing. In other scenarios where // dispatching is rare it pays to avoid the allocation of the memory till it // is rquired. The RDBSS work queue implementations provide for both these // scenarios in the form of dispatching and posting work queue requests. In // the case of dispatching no memory for the WORK_QUEUE_ITEM need be allocated // by the caller while for posting the memory for WORK_QUEUE_ITEM needs to be // allocated by the caller. // typedef struct _RX_WORK_DISPATCH_ITEM_ { RX_WORK_QUEUE_ITEM WorkQueueItem; PRX_WORKERTHREAD_ROUTINE DispatchRoutine; PVOID DispatchRoutineParameter; } RX_WORK_DISPATCH_ITEM, *PRX_WORK_DISPATCH_ITEM; // // The work queues typically come up in a active state and continue till either // a non recoverable situation is encountered ( lack of system resources ) when // it transitions to the Inactive state. When a rundown is initiated it transitions // to the rundown in progress state. // typedef enum _RX_WORK_QUEUE_STATE_ { RxWorkQueueActive, RxWorkQueueInactive, RxWorkQueueRundownInProgress } RX_WORK_QUEUE_STATE, *PRX_WORK_QUEUE_STATE; // // The rundown of work queues is not complete when the threads have been spun down. // The termination of the threads needs to be ensured before the data structures // can be torn down. The work queue implementation follows a protocol in which // each of the threads being spundown stashes a reference to the thread object // in the rundown context. The rundown issuing thread ( which does not belong to // the work queue ) waits for the completion of all the threads spundown before // tearing down the data structures. // typedef struct _RX_WORK_QUEUE_RUNDOWN_CONTEXT_ { KEVENT RundownCompletionEvent; LONG NumberOfThreadsSpunDown; PETHREAD *ThreadPointers; } RX_WORK_QUEUE_RUNDOWN_CONTEXT, *PRX_WORK_QUEUE_RUNDOWN_CONTEXT; // // The work queue implementation is built around a KQUEUE implementation. The // additional support involves the regulation of number of threads that are // actively waiting for the work items. Each work queue data structure is // allocated in nonpaged pool and has its own synchronization mechanism ( spinlock). // // In addition to the bookkeeing information, i.e., state, type etc. it also includes // statistics that are gathered over the lifetime of the queue. This will // provide valuable information in tuning a work queue instance. The number of items // that have been processed , the number of items that have to be processed and // the cumulative queue length is recorded. The cumulative queue length is the // intersiting metric, it is the sum of the number of items awaiting to be processed // each time an additional work item was queued. The cumulative queue length // divided by the sum of the total number of items processed and the anumber of // items to be processed gives an indication of the average length of the // queue. A value much greater than one signifies that the minimum number of // worker threads associated with the work queue can be increased. A value much // less than one signifies that the maximum number of work threads associated // with the queue can be decreased. // typedef struct _RX_WORK_QUEUE_ { USHORT State; BOOLEAN SpinUpRequestPending; UCHAR Type; KSPIN_LOCK SpinLock; PRX_WORK_QUEUE_RUNDOWN_CONTEXT pRundownContext; LONG NumberOfWorkItemsDispatched; LONG NumberOfWorkItemsToBeDispatched; LONG CumulativeQueueLength; LONG NumberOfSpinUpRequests; LONG MaximumNumberOfWorkerThreads; LONG MinimumNumberOfWorkerThreads; LONG NumberOfActiveWorkerThreads; LONG NumberOfIdleWorkerThreads; LONG NumberOfFailedSpinUpRequests; LONG WorkQueueItemForSpinUpWorkerThreadInUse; RX_WORK_QUEUE_ITEM WorkQueueItemForTearDownWorkQueue; RX_WORK_QUEUE_ITEM WorkQueueItemForSpinUpWorkerThread; RX_WORK_QUEUE_ITEM WorkQueueItemForSpinDownWorkerThread; KQUEUE Queue; // The next field is for debugging purposes and will be removed from the // FREE build. PETHREAD *ThreadPointers; } RX_WORK_QUEUE, *PRX_WORK_QUEUE; // // The dispatching mechanism in RDBSS provides for multiple levels of work queues // on a per processor basis. There are three levels of work queues currently // supported, Critical,Delayed and HyperCritical. The distinction between Critical // and delayed is one of priority where as HyperCritical iss different from the // other two in that the routines should not block, i.e., wait for any resource. // This requirement cannot be enforced hence the effectiveness of the dispatching // mechanism relies on the implicit cooperation of the clients. // typedef struct _RX_WORK_QUEUE_DISPATCHER_ { RX_WORK_QUEUE WorkQueue[MaximumWorkQueue]; } RX_WORK_QUEUE_DISPATCHER, *PRX_WORK_QUEUE_DISPATCHER; // // The dispatcher typically come up in a active state and continue till either // a non recoverable situation is encountered ( lack of system resources ) when // it transitions to the Inactive state. When a rundown is initiated it transitions // to the rundown in progress state. // typedef enum _RX_DISPATCHER_STATE_ { RxDispatcherActive, RxDispatcherInactive } RX_DISPATCHER_STATE, *PRX_DISPATCHER_STATE; // // The RDBSS dispatching mechanism on any machine is an array of the dispatchers // associated with each processor. When a work queue item is queued a best effort // is made to contain the work emanating from a processor onto the same processor. // This ensures that processor affinities setup by the NT dispatcher are not // destroyed by the RDBSS dispatching mechanism as this could lead to excessive // sloshing. When the work needs to be moved there are two metrics that will be // useful in making the decision, teh amount of delay that will be experienced // by the work item in the current queue and the effort involved in moving the // work item to the other queue. It is very easy to quantify the former but very // difficult to quantify the later. // typedef struct _RX_DISPATCHER_ { LONG NumberOfProcessors; PEPROCESS OwnerProcess; PRX_WORK_QUEUE_DISPATCHER pWorkQueueDispatcher; RX_DISPATCHER_STATE State; LIST_ENTRY SpinUpRequests; KSPIN_LOCK SpinUpRequestsLock; KEVENT SpinUpRequestsEvent; KEVENT SpinUpRequestsTearDownEvent; } RX_DISPATCHER, *PRX_DISPATCHER; // // The function prototypes used for dispatching/posting work queue items // extern NTSTATUS NTAPI RxPostToWorkerThread ( IN PRDBSS_DEVICE_OBJECT pMRxDeviceObject, IN WORK_QUEUE_TYPE WorkQueueType, IN PRX_WORK_QUEUE_ITEM pWorkQueueItem, IN PRX_WORKERTHREAD_ROUTINE Routine, IN PVOID pContext ); extern NTSTATUS NTAPI RxDispatchToWorkerThread( IN PRDBSS_DEVICE_OBJECT pMRxDeviceObject, IN WORK_QUEUE_TYPE WorkQueueType, IN PRX_WORKERTHREAD_ROUTINE Routine, IN PVOID pContext); extern BOOLEAN //should only be called from raised IRQL NTAPI RxIsWorkItemQueued( IN OUT PWORK_QUEUE_ITEM WorkItem ); // // The routines for initializing/tearing down the dispatching mechanism // extern NTSTATUS RxInitializeDispatcher(); extern NTSTATUS RxTearDownDispatcher(); extern NTSTATUS RxInitializeMRxDispatcher( IN OUT PRDBSS_DEVICE_OBJECT pMRxDeviceObject); extern NTSTATUS RxSpinDownMRxDispatcher( IN OUT PRDBSS_DEVICE_OBJECT pMRxDeviceObject); #endif _RXWORKQ_H_