reactos/ntoskrnl/ke/time.c

257 lines
7.1 KiB
C

/*
* PROJECT: ReactOS Kernel
* LICENSE: BSD - See COPYING.ARM in the top level directory
* FILE: ntoskrnl/ke/time.c
* PURPOSE: Implements timebase functionality
* PROGRAMMERS: ReactOS Portable Systems Group
*/
/* INCLUDES *******************************************************************/
#include <ntoskrnl.h>
#define NDEBUG
#include <debug.h>
/* GLOBALS ********************************************************************/
LONG KiTickOffset;
ULONG KeTimeAdjustment;
BOOLEAN KiTimeAdjustmentEnabled = FALSE;
/* FUNCTIONS ******************************************************************/
FORCEINLINE
VOID
KiWriteSystemTime(volatile KSYSTEM_TIME *SystemTime, ULARGE_INTEGER NewTime)
{
#ifdef _WIN64
/* Do a single atomic write */
*(ULONGLONG*)SystemTime = NewTime.QuadPart;
#else
/* Update in 3 steps, so that a reader can recognize partial updates */
SystemTime->High1Time = NewTime.HighPart;
SystemTime->LowPart = NewTime.LowPart;
#endif
SystemTime->High2Time = NewTime.HighPart;
}
FORCEINLINE
VOID
KiCheckForTimerExpiration(
PKPRCB Prcb,
PKTRAP_FRAME TrapFrame,
ULARGE_INTEGER InterruptTime)
{
ULONG Hand;
/* Check for timer expiration */
Hand = KeTickCount.LowPart & (TIMER_TABLE_SIZE - 1);
if (KiTimerTableListHead[Hand].Time.QuadPart <= InterruptTime.QuadPart)
{
/* Check if we are already doing expiration */
if (!Prcb->TimerRequest)
{
/* Request a DPC to handle this */
Prcb->TimerRequest = (ULONG_PTR)TrapFrame;
Prcb->TimerHand = Hand;
HalRequestSoftwareInterrupt(DISPATCH_LEVEL);
}
}
}
VOID
FASTCALL
KeUpdateSystemTime(IN PKTRAP_FRAME TrapFrame,
IN ULONG Increment,
IN KIRQL Irql)
{
PKPRCB Prcb = KeGetCurrentPrcb();
ULARGE_INTEGER CurrentTime, InterruptTime;
LONG OldTickOffset;
/* Check if this tick is being skipped */
if (Prcb->SkipTick)
{
/* Handle it next time */
Prcb->SkipTick = FALSE;
/* Increase interrupt count and end the interrupt */
Prcb->InterruptCount++;
#ifdef _M_IX86 // x86 optimization
KiEndInterrupt(Irql, TrapFrame);
#endif
/* Note: non-x86 return back to the caller! */
return;
}
/* Add the increment time to the shared data */
InterruptTime.QuadPart = *(ULONGLONG*)&SharedUserData->InterruptTime;
InterruptTime.QuadPart += Increment;
KiWriteSystemTime(&SharedUserData->InterruptTime, InterruptTime);
/* Check for timer expiration */
KiCheckForTimerExpiration(Prcb, TrapFrame, InterruptTime);
/* Update the tick offset */
OldTickOffset = InterlockedExchangeAdd(&KiTickOffset, -(LONG)Increment);
/* If the debugger is enabled, check for break-in request */
if (KdDebuggerEnabled && KdPollBreakIn())
{
/* Break-in requested! */
DbgBreakPointWithStatus(DBG_STATUS_CONTROL_C);
}
/* Check for full tick */
if (OldTickOffset <= (LONG)Increment)
{
/* Update the system time */
CurrentTime.QuadPart = *(ULONGLONG*)&SharedUserData->SystemTime;
CurrentTime.QuadPart += KeTimeAdjustment;
KiWriteSystemTime(&SharedUserData->SystemTime, CurrentTime);
/* Update the tick count */
CurrentTime.QuadPart = (*(ULONGLONG*)&KeTickCount) + 1;
KiWriteSystemTime(&KeTickCount, CurrentTime);
/* Update it in the shared user data */
KiWriteSystemTime(&SharedUserData->TickCount, CurrentTime);
/* Check for expiration with the new tick count as well */
KiCheckForTimerExpiration(Prcb, TrapFrame, InterruptTime);
/* Reset the tick offset */
KiTickOffset += KeMaximumIncrement;
/* Update processor/thread runtime */
KeUpdateRunTime(TrapFrame, Irql);
}
else
{
/* Increase interrupt count only */
Prcb->InterruptCount++;
}
#ifdef _M_IX86 // x86 optimization
/* Disable interrupts and end the interrupt */
KiEndInterrupt(Irql, TrapFrame);
#endif
}
VOID
NTAPI
KeUpdateRunTime(IN PKTRAP_FRAME TrapFrame,
IN KIRQL Irql)
{
PKTHREAD Thread = KeGetCurrentThread();
PKPRCB Prcb = KeGetCurrentPrcb();
/* Check if this tick is being skipped */
if (Prcb->SkipTick)
{
/* Handle it next time */
Prcb->SkipTick = FALSE;
return;
}
/* Increase interrupt count */
Prcb->InterruptCount++;
/* Check if we came from user mode */
#ifndef _M_ARM
if (KiUserTrap(TrapFrame) || (TrapFrame->EFlags & EFLAGS_V86_MASK))
#else
if (TrapFrame->PreviousMode == UserMode)
#endif
{
/* Increase thread user time */
Prcb->UserTime++;
Thread->UserTime++;
}
else
{
/* See if we were in an ISR */
Prcb->KernelTime++;
if (Irql > DISPATCH_LEVEL)
{
/* Handle that */
Prcb->InterruptTime++;
}
else if ((Irql < DISPATCH_LEVEL) || !(Prcb->DpcRoutineActive))
{
/* Handle being in kernel mode */
Thread->KernelTime++;
}
else
{
/* Handle being in a DPC */
Prcb->DpcTime++;
#if DBG
/* Update the DPC time */
Prcb->DebugDpcTime++;
/* Check if we have timed out */
if (Prcb->DebugDpcTime == KiDPCTimeout)
{
/* We did! */
DbgPrint("*** DPC routine > 1 sec --- This is not a break in KeUpdateSystemTime\n");
/* Break if debugger is enabled */
if (KdDebuggerEnabled) DbgBreakPoint();
/* Clear state */
Prcb->DebugDpcTime = 0;
}
#endif
}
}
/* Update DPC rates */
Prcb->DpcRequestRate = ((Prcb->DpcData[0].DpcCount - Prcb->DpcLastCount) +
Prcb->DpcRequestRate) >> 1;
Prcb->DpcLastCount = Prcb->DpcData[0].DpcCount;
/* Check if the queue is large enough */
if ((Prcb->DpcData[0].DpcQueueDepth) && !(Prcb->DpcRoutineActive))
{
/* Request a DPC */
Prcb->AdjustDpcThreshold = KiAdjustDpcThreshold;
HalRequestSoftwareInterrupt(DISPATCH_LEVEL);
/* Fix the maximum queue depth */
if ((Prcb->DpcRequestRate < KiIdealDpcRate) &&
(Prcb->MaximumDpcQueueDepth > 1))
{
/* Make it smaller */
Prcb->MaximumDpcQueueDepth--;
}
}
else
{
/* Check if we've reached the adjustment limit */
if (!(--Prcb->AdjustDpcThreshold))
{
/* Reset it, and check the queue maximum */
Prcb->AdjustDpcThreshold = KiAdjustDpcThreshold;
if (KiMaximumDpcQueueDepth != Prcb->MaximumDpcQueueDepth)
{
/* Increase it */
Prcb->MaximumDpcQueueDepth++;
}
}
}
/* Decrement the thread quantum */
Thread->Quantum -= CLOCK_QUANTUM_DECREMENT;
/* Check if the time expired */
if ((Thread->Quantum <= 0) && (Thread != Prcb->IdleThread))
{
/* Schedule a quantum end */
Prcb->QuantumEnd = 1;
HalRequestSoftwareInterrupt(DISPATCH_LEVEL);
}
}