/*++ Copyright (c) 1989 Microsoft Corporation Module Name: waitsup.c Abstract: This module contains the support routines necessary to support the generic kernel wait functions. Functions are provided to test if a wait can be satisfied, to satisfy a wait, and to unwwait a thread. Author: David N. Cutler (davec) 24-Mar-1989 Environment: Kernel mode only. Revision History: --*/ #include "ki.h" VOID FASTCALL KiUnlinkThread ( IN PRKTHREAD Thread, IN LONG_PTR WaitStatus ) /*++ Routine Description: This function unlinks a thread from the appropriate wait queues and sets the thread's wait completion status. Arguments: Thread - Supplies a pointer to a dispatcher object of type thread. WaitStatus - Supplies the wait completion status. Return Value: None. --*/ { PKQUEUE Queue; PKTIMER Timer; PRKWAIT_BLOCK WaitBlock; // // Set wait completion status, remove wait blocks from object wait // lists, and remove thread from wait list. // Thread->WaitStatus |= WaitStatus; WaitBlock = Thread->WaitBlockList; do { RemoveEntryList(&WaitBlock->WaitListEntry); WaitBlock = WaitBlock->NextWaitBlock; } while (WaitBlock != Thread->WaitBlockList); if (Thread->WaitListEntry.Flink != NULL) { RemoveEntryList(&Thread->WaitListEntry); } // // If thread timer is still active, then cancel thread timer. // Timer = &Thread->Timer; if (Timer->Header.Inserted != FALSE) { KiRemoveTreeTimer(Timer); } // // If the thread is processing a queue entry, then increment the // count of currently active threads. // Queue = Thread->Queue; if (Queue != NULL) { Queue->CurrentCount += 1; } return; } VOID FASTCALL KiUnwaitThread ( IN PRKTHREAD Thread, IN LONG_PTR WaitStatus, IN KPRIORITY Increment, IN PLIST_ENTRY ThreadList OPTIONAL ) /*++ Routine Description: This function unwaits a thread, sets the thread's wait completion status, calculates the thread's new priority, and either readies the thread for execution or adds the thread to a list of threads to be readied later. Arguments: Thread - Supplies a pointer to a dispatcher object of type thread. WaitStatus - Supplies the wait completion status. Increment - Supplies the priority increment that is to be applied to the thread's priority. ThreadList - Supplies an optional pointer to a listhead. Return Value: None. --*/ { KPRIORITY NewPriority; PKPROCESS Process; // // Unlink thread from the appropriate wait queues and set the wait // completion status. // KiUnlinkThread(Thread, WaitStatus); // // If the thread runs at a realtime priority level, then reset the // thread quantum. Otherwise, compute the next thread priority and // charge the thread for the wait operation. // Process = Thread->ApcState.Process; if (Thread->Priority < LOW_REALTIME_PRIORITY) { if ((Thread->PriorityDecrement == 0) && (Thread->DisableBoost == FALSE)) { NewPriority = Thread->BasePriority + Increment; // // If the specified thread is from a process with a foreground // memory priority, then add the foreground boost separation. // if (((PEPROCESS)Process)->Vm.Flags.MemoryPriority == MEMORY_PRIORITY_FOREGROUND) { NewPriority += PsPrioritySeperation; } // // If the new thread priority is greater than the current thread // priority, then boost the thread priority, but not above low // real time minus one. // if (NewPriority > Thread->Priority) { if (NewPriority >= LOW_REALTIME_PRIORITY) { NewPriority = LOW_REALTIME_PRIORITY - 1; } // // If the new thread priority is greater than the thread base // priority plus the specified increment (i.e., the foreground // separation was added), then set the priority decrement to // remove the separation boost after one quantum. // if (NewPriority > (Thread->BasePriority + Increment)) { Thread->PriorityDecrement = (SCHAR)(NewPriority - Thread->BasePriority - Increment); Thread->DecrementCount = ROUND_TRIP_DECREMENT_COUNT; } Thread->Priority = (SCHAR)NewPriority; } } if (Thread->BasePriority >= TIME_CRITICAL_PRIORITY_BOUND) { Thread->Quantum = Process->ThreadQuantum; } else { // // If the thread is being unwaited to execute a kernel APC, // then do not charge the thread any quantum. The wait code // will charge quantum after the kernel APC has executed and // the wait is actually satisifed. // if (WaitStatus != STATUS_KERNEL_APC) { Thread->Quantum -= WAIT_QUANTUM_DECREMENT; if (Thread->Quantum <= 0) { Thread->Quantum = Process->ThreadQuantum; Thread->Priority -= (Thread->PriorityDecrement + 1); if (Thread->Priority < Thread->BasePriority) { Thread->Priority = Thread->BasePriority; } Thread->PriorityDecrement = 0; } } } } else { Thread->Quantum = Process->ThreadQuantum; } // // If a thread list is specified, then add the thread to the enb of the // specified list. Otherwise, ready the thread for execution. // if (ARGUMENT_PRESENT(ThreadList)) { InsertTailList(ThreadList, &Thread->WaitListEntry); } else { KiReadyThread(Thread); } return; } VOID KeBoostCurrentThread( VOID ) /*++ Routine Description: This function boosts the priority of the current thread for one quantum, then reduce the thread priority to the base priority of the thread. Arguments: None. Return Value: None. --*/ { KIRQL OldIrql; PKTHREAD Thread; // // Get current thread address, raise IRQL to synchronization level, and // lock the dispatcher database // Thread = KeGetCurrentThread(); redoboost: KiLockDispatcherDatabase(&OldIrql); // // If a priority boost is not already active for the current thread // and the thread priority is less than 14, then boost the thread // priority to 14 and give the thread a large quantum. Otherwise, // if a priority boost is active, then decrement the round trip // count. If the count goes to zero, then release the dispatcher // database lock, lower the thread priority to the base priority, // and then attempt to boost the priority again. This will give // other threads a chance to run. If the count does not reach zero, // then give the thread another large qunatum. // // If the thread priority is above 14, then no boost is applied. // if ((Thread->PriorityDecrement == 0) && (Thread->Priority < 14)) { Thread->PriorityDecrement = 14 - Thread->BasePriority; Thread->DecrementCount = ROUND_TRIP_DECREMENT_COUNT; Thread->Priority = 14; Thread->Quantum = Thread->ApcState.Process->ThreadQuantum * 2; } else if (Thread->PriorityDecrement != 0) { Thread->DecrementCount -= 1; if (Thread->DecrementCount == 0) { KiUnlockDispatcherDatabase(OldIrql); KeSetPriorityThread(Thread, Thread->BasePriority); goto redoboost; } else { Thread->Quantum = Thread->ApcState.Process->ThreadQuantum * 2; } } KiUnlockDispatcherDatabase(OldIrql); return; } VOID FASTCALL KiWaitSatisfyAll ( IN PRKWAIT_BLOCK WaitBlock ) /*++ Routine Description: This function satisfies a wait all and performs any side effects that are necessary. Arguments: WaitBlock - Supplies a pointer to a wait block. Return Value: None. --*/ { PKMUTANT Object; PRKTHREAD Thread; PRKWAIT_BLOCK WaitBlock1; // // If the wait type was WaitAny, then perform neccessary side effects on // the object specified by the wait block. Else perform necessary side // effects on all the objects that were involved in the wait operation. // WaitBlock1 = WaitBlock; Thread = WaitBlock1->Thread; do { if (WaitBlock1->WaitKey != (CSHORT)STATUS_TIMEOUT) { Object = (PKMUTANT)WaitBlock1->Object; KiWaitSatisfyAny(Object, Thread); } WaitBlock1 = WaitBlock1->NextWaitBlock; } while (WaitBlock1 != WaitBlock); return; } VOID FASTCALL KiWaitTest ( IN PVOID Object, IN KPRIORITY Increment ) /*++ Routine Description: This function tests if a wait can be satisfied when an object attains a state of signaled. If a wait can be satisfied, then the subject thread is unwaited with a completion status that is the WaitKey of the wait block from the object wait list. As many waits as possible are satisfied. Arguments: Object - Supplies a pointer to a dispatcher object. Return Value: None. --*/ { PKEVENT Event; PLIST_ENTRY ListHead; PRKWAIT_BLOCK NextBlock; PKMUTANT Mutant; LIST_ENTRY ReadyList; PRKTHREAD Thread; PLIST_ENTRY ThreadEntry; PRKWAIT_BLOCK WaitBlock; PLIST_ENTRY WaitEntry; NTSTATUS WaitStatus; // // As long as the signal state of the specified object is Signaled and // there are waiters in the object wait list, then try to satisfy a wait. // Event = (PKEVENT)Object; ListHead = &Event->Header.WaitListHead; WaitEntry = ListHead->Flink; InitializeListHead(&ReadyList); while ((Event->Header.SignalState > 0) && (WaitEntry != ListHead)) { WaitBlock = CONTAINING_RECORD(WaitEntry, KWAIT_BLOCK, WaitListEntry); Thread = WaitBlock->Thread; WaitStatus = STATUS_KERNEL_APC; // // N.B. The below code only satisfies the wait for wait any types. // Wait all types are satisfied in the wait code itself. This // is done with a eye to the future when the dispatcher lock is // split into a lock per waitable object type and a scheduling // state lock. For now, a kernel APC is simulated for wait all // types. // if (WaitBlock->WaitType == WaitAny) { WaitStatus = (NTSTATUS)WaitBlock->WaitKey; KiWaitSatisfyAny((PKMUTANT)Event, Thread); } KiUnwaitThread(Thread, WaitStatus, Increment, &ReadyList); WaitEntry = ListHead->Flink; } // // Ready any threads which have been made eligible to run. This // must be done AFTER the event is no longer needed to avoid running // the thread which owns the event before this routine is finished // looking at it. // while (!IsListEmpty(&ReadyList)) { ThreadEntry = RemoveHeadList(&ReadyList); Thread = CONTAINING_RECORD(ThreadEntry, KTHREAD, WaitListEntry); KiReadyThread(Thread); } return; }