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// Copyright (c) 1998-2009 Nokia Corporation and/or its subsidiary(-ies).
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// All rights reserved.
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// This component and the accompanying materials are made available
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// under the terms of the License "Eclipse Public License v1.0"
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// which accompanies this distribution, and is available
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// at the URL "http://www.eclipse.org/legal/epl-v10.html".
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//
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// Initial Contributors:
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// Nokia Corporation - initial contribution.
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//
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// Contributors:
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//
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// Description:
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// e32\nkern\nk_timer.cpp
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// Fast Millisecond Timer Implementation
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// This file is just a template - you'd be mad not to machine code this
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//
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//
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#include "nk_priv.h"
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const TInt KTimerQDfcPriority=6;
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GLDEF_D NTimerQ TheTimerQ;
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#ifndef __MSTIM_MACHINE_CODED__
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#ifdef _DEBUG
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#define __DEBUG_CALLBACK(n) {if (iDebugFn) (*iDebugFn)(iDebugPtr,n);}
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#else
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#define __DEBUG_CALLBACK(n)
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#endif
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/** Starts a nanokernel timer in one-shot mode with ISR callback.
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Queues the timer to expire in the specified number of nanokernel ticks. The
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actual wait time will be at least that much and may be up to one tick more.
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The expiry handler will be called in ISR context.
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Note that NKern::TimerTicks() can be used to convert milliseconds to ticks.
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@param aTime Timeout in nanokernel ticks
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@return KErrNone if no error; KErrInUse if timer is already active.
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@pre Any context
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@see NKern::TimerTicks()
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*/
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EXPORT_C TInt NTimer::OneShot(TInt aTime)
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{
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return OneShot(aTime,FALSE);
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}
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/** Starts a nanokernel timer in one-shot mode with ISR or DFC callback.
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Queues the timer to expire in the specified number of nanokernel ticks. The
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actual wait time will be at least that much and may be up to one tick more.
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The expiry handler will be called in either ISR context or in the context
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of the nanokernel timer thread (DfcThread1).
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Note that NKern::TimerTicks() can be used to convert milliseconds to ticks.
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@param aTime Timeout in nanokernel ticks
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@param aDfc TRUE if DFC callback required, FALSE if ISR callback required.
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@return KErrNone if no error; KErrInUse if timer is already active.
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@pre Any context
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@see NKern::TimerTicks()
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*/
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EXPORT_C TInt NTimer::OneShot(TInt aTime, TBool aDfc)
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{
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__NK_ASSERT_DEBUG(aTime>=0);
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/** iFunction could be set to NULL after NTimer::OneShot(TInt, TDfc&) call.
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Call-back mechanism cannot be changed in the life time of a timer. */
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__NK_ASSERT_DEBUG(iFunction!=NULL);
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TInt irq=NKern::DisableAllInterrupts();
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if (iState!=EIdle)
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{
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NKern::RestoreInterrupts(irq);
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return KErrInUse;
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}
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iCompleteInDfc=TUint8(aDfc?1:0);
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iTriggerTime=TheTimerQ.iMsCount+(TUint32)aTime;
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TheTimerQ.Add(this);
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NKern::RestoreInterrupts(irq);
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return KErrNone;
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}
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/** Starts a nanokernel timer in one-shot mode with callback in dfc thread that provided DFC belongs to.
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Queues the timer to expire in the specified number of nanokernel ticks. The
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actual wait time will be at least that much and may be up to one tick more.
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On expiry aDfc will be queued in ISR context.
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Note that NKern::TimerTicks() can be used to convert milliseconds to ticks.
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@param aTime Timeout in nanokernel ticks
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@param aDfc - Dfc to be queued when the timer expires.
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@return KErrNone if no error; KErrInUse if timer is already active.
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@pre Any context
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@see NKern::TimerTicks()
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*/
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EXPORT_C TInt NTimer::OneShot(TInt aTime, TDfc& aDfc)
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{
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__NK_ASSERT_DEBUG(aTime>=0);
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TInt irq=NKern::DisableAllInterrupts();
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if (iState!=EIdle)
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{
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NKern::RestoreInterrupts(irq);
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return KErrInUse;
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}
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iCompleteInDfc = 0;
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iFunction = NULL;
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iPtr = (TAny*) &aDfc;
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iTriggerTime=TheTimerQ.iMsCount+(TUint32)aTime;
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TheTimerQ.Add(this);
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NKern::RestoreInterrupts(irq);
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return KErrNone;
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}
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/** Starts a nanokernel timer in zero-drift periodic mode with ISR or DFC callback.
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Queues the timer to expire in the specified number of nanokernel ticks,
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measured from the time at which it last expired. This allows exact periodic
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timers to be implemented with no drift caused by delays in requeueing the
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timer.
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The expiry handler will be called in the same context as the previous timer
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expiry. Generally the way this is used is that NTimer::OneShot() is used to start
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the first time interval and this specifies whether the callback is in ISR context
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or in the context of the nanokernel timer thread (DfcThread1) or other Dfc thread.
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The expiry handler then uses NTimer::Again() to requeue the timer.
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@param aTime Timeout in nanokernel ticks
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@return KErrNone if no error; KErrInUse if timer is already active;
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KErrArgument if the requested expiry time is in the past.
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@pre Any context
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*/
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EXPORT_C TInt NTimer::Again(TInt aTime)
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//
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// Wait aTime from last trigger time - used for periodic timers
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//
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{
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__NK_ASSERT_DEBUG(aTime>0);
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TInt irq=NKern::DisableAllInterrupts();
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if (iState!=EIdle)
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{
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NKern::RestoreInterrupts(irq);
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return KErrInUse;
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}
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TUint32 nextTick=TheTimerQ.iMsCount;
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TUint32 trigger=iTriggerTime+(TUint32)aTime;
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TUint32 d=trigger-nextTick;
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if (d>=0x80000000)
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{
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NKern::RestoreInterrupts(irq);
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return KErrArgument; // requested time is in the past
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}
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iTriggerTime=trigger;
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TheTimerQ.Add(this);
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NKern::RestoreInterrupts(irq);
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return KErrNone;
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}
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/** Cancels a nanokernel timer.
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Removes this timer from the nanokernel timer queue. Does nothing if the
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timer is inactive or has already expired.
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Note that if the timer was queued and DFC callback requested it is possible
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for the expiry handler to run even after Cancel() has been called. This will
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occur in the case where DfcThread1 is preempted just before calling the
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expiry handler for this timer and the preempting thread/ISR/IDFC calls
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Cancel() on the timer.
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@pre Any context
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@return TRUE if timer was actually cancelled
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@return FALSE if timer was not cancelled - this could be because it was not
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active or because its expiry handler was already running on
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another CPU or in the timer DFC.
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*/
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EXPORT_C TBool NTimer::Cancel()
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{
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TBool result = TRUE;
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TInt irq=NKern::DisableAllInterrupts();
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if (iState>ETransferring) // idle or transferring timers are not on a queue
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Deque();
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switch (iState)
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{
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case ETransferring: // signal DFC to abort this iteration
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TheTimerQ.iTransferringCancelled=TRUE;
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break;
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case ECritical: // signal DFC to abort this iteration
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TheTimerQ.iCriticalCancelled=TRUE;
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break;
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case EFinal:
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{
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// Need to clear bit in iPresent if both final queues now empty
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// NOTE: Timer might actually be on the completed queue rather than the final queue
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// but the check is harmless in any case.
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TInt i=iTriggerTime & NTimerQ::ETimerQMask;
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NTimerQ::STimerQ& q=TheTimerQ.iTickQ[i];
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if (q.iIntQ.IsEmpty() && q.iDfcQ.IsEmpty())
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TheTimerQ.iPresent &= ~(1<<i);
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break;
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}
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case EIdle: // nothing to do
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result = FALSE;
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case EHolding: // just deque
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case EOrdered: // just deque
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break;
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}
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iState=EIdle;
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NKern::RestoreInterrupts(irq);
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return result;
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}
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#endif
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/** Check if a nanokernel timer is pending or not
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@return TRUE if the timer is pending (OneShot() etc. would return KErrInUse)
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@return FALSE if the timer is idle (OneShot() etc. would succeed)
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@pre Any context
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@publishedPartner
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@prototype
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*/
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EXPORT_C TBool NTimer::IsPending()
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{
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return iState != EIdle;
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}
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/** Obtains the address of the nanokernel timer queue object.
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Not intended for general use. Intended only for base ports in order to get
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the address used to call NTimerQ::Tick() with.
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@return The address of the nanokernel timer queue object
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@pre Any context
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*/
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EXPORT_C TAny* NTimerQ::TimerAddress()
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{
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return &TheTimerQ;
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}
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NTimerQ::NTimerQ()
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: iDfc(NTimerQ::DfcFn,this,NULL,KTimerQDfcPriority)
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{
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// NOTE: All other members are initialised to zero since the single instance
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// of NTimerQ resides in .bss
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}
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void NTimerQ::Init1(TInt aTickPeriod)
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{
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TheTimerQ.iTickPeriod=aTickPeriod;
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__KTRACE_OPT(KBOOT,DEBUGPRINT("NTimerQ::Init1 - period %d us",aTickPeriod));
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__KTRACE_OPT(KMEMTRACE, DEBUGPRINT("MT:P %d",aTickPeriod));
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}
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void NTimerQ::Init3(TDfcQue* aDfcQ)
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{
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__KTRACE_OPT(KBOOT,DEBUGPRINT("NTimerQ::Init3 DFCQ at %08x",aDfcQ));
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TheTimerQ.iDfc.SetDfcQ(aDfcQ);
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}
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#ifndef __MSTIM_MACHINE_CODED__
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void NTimerQ::Add(NTimer* aTimer)
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//
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// Internal function to add a timer to the queue.
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// Enter and return with all interrupts disabled.
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//
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{
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TInt t=TInt(aTimer->iTriggerTime-iMsCount);
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if (t<ENumTimerQueues)
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AddFinal(aTimer);
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else
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{
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// >=32ms to expiry, so put on holding queue
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aTimer->iState=NTimer::EHolding;
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iHoldingQ.Add(aTimer);
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}
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}
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void NTimerQ::AddFinal(NTimer* aTimer)
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//
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// Internal function to add a timer to the corresponding final queue.
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// Enter and return with all interrupts disabled.
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//
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{
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TInt i=aTimer->iTriggerTime & ETimerQMask;
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SDblQue* pQ;
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if (aTimer->iCompleteInDfc)
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pQ=&iTickQ[i].iDfcQ;
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else
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pQ=&iTickQ[i].iIntQ;
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iPresent |= (1<<i);
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aTimer->iState=NTimer::EFinal;
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pQ->Add(aTimer);
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}
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void NTimerQ::DfcFn(TAny* aPtr)
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{
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((NTimerQ*)aPtr)->Dfc();
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}
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void NTimerQ::Dfc()
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//
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// Do deferred timer queue processing and/or DFC completions
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//
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{
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TInt irq;
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// First transfer entries on the Ordered queue to the Final queues
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FOREVER
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{
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irq=NKern::DisableAllInterrupts();
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if (iOrderedQ.IsEmpty())
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break;
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|
333 |
NTimer* pC=(NTimer*)iOrderedQ.First();
|
sl@0
|
334 |
TInt remain=pC->iTriggerTime-iMsCount;
|
sl@0
|
335 |
if (remain>=ENumTimerQueues)
|
sl@0
|
336 |
break;
|
sl@0
|
337 |
|
sl@0
|
338 |
// If remaining time <32 ticks, add it to final queue;
|
sl@0
|
339 |
// also if remain < 0 we've 'missed it' so add to final queue.
|
sl@0
|
340 |
pC->Deque();
|
sl@0
|
341 |
AddFinal(pC);
|
sl@0
|
342 |
NKern::RestoreInterrupts(irq);
|
sl@0
|
343 |
__DEBUG_CALLBACK(0);
|
sl@0
|
344 |
}
|
sl@0
|
345 |
NKern::RestoreInterrupts(irq);
|
sl@0
|
346 |
__DEBUG_CALLBACK(1);
|
sl@0
|
347 |
|
sl@0
|
348 |
// Next transfer entries on the Holding queue to the Ordered queue or final queue
|
sl@0
|
349 |
FOREVER
|
sl@0
|
350 |
{
|
sl@0
|
351 |
irq=NKern::DisableAllInterrupts();
|
sl@0
|
352 |
if (iHoldingQ.IsEmpty())
|
sl@0
|
353 |
break;
|
sl@0
|
354 |
NTimer* pC=(NTimer*)iHoldingQ.First();
|
sl@0
|
355 |
pC->Deque();
|
sl@0
|
356 |
pC->iState=NTimer::ETransferring;
|
sl@0
|
357 |
iTransferringCancelled=FALSE;
|
sl@0
|
358 |
TUint32 trigger=pC->iTriggerTime;
|
sl@0
|
359 |
if (TInt(trigger-iMsCount)<ENumTimerQueues)
|
sl@0
|
360 |
{
|
sl@0
|
361 |
// <32ms remaining so put it on final queue
|
sl@0
|
362 |
AddFinal(pC);
|
sl@0
|
363 |
}
|
sl@0
|
364 |
else
|
sl@0
|
365 |
{
|
sl@0
|
366 |
FOREVER
|
sl@0
|
367 |
{
|
sl@0
|
368 |
NKern::RestoreInterrupts(irq);
|
sl@0
|
369 |
__DEBUG_CALLBACK(2);
|
sl@0
|
370 |
|
sl@0
|
371 |
// we now need to walk ordered queue to find correct position for pC
|
sl@0
|
372 |
SDblQueLink* anchor=&iOrderedQ.iA;
|
sl@0
|
373 |
iCriticalCancelled=FALSE;
|
sl@0
|
374 |
irq=NKern::DisableAllInterrupts();
|
sl@0
|
375 |
NTimer* pN=(NTimer*)iOrderedQ.First();
|
sl@0
|
376 |
while (pN!=anchor && !iTransferringCancelled)
|
sl@0
|
377 |
{
|
sl@0
|
378 |
if ((pN->iTriggerTime-trigger)<0x80000000u)
|
sl@0
|
379 |
break; // insert before pN
|
sl@0
|
380 |
pN->iState=NTimer::ECritical;
|
sl@0
|
381 |
NKern::RestoreInterrupts(irq);
|
sl@0
|
382 |
__DEBUG_CALLBACK(3);
|
sl@0
|
383 |
irq=NKern::DisableAllInterrupts();
|
sl@0
|
384 |
if (iCriticalCancelled)
|
sl@0
|
385 |
break;
|
sl@0
|
386 |
pN->iState=NTimer::EOrdered;
|
sl@0
|
387 |
pN=(NTimer*)pN->iNext;
|
sl@0
|
388 |
}
|
sl@0
|
389 |
|
sl@0
|
390 |
if (iTransferringCancelled)
|
sl@0
|
391 |
break; // this one has been cancelled, go on to next one
|
sl@0
|
392 |
if (!iCriticalCancelled)
|
sl@0
|
393 |
{
|
sl@0
|
394 |
pC->InsertBefore(pN);
|
sl@0
|
395 |
pC->iState=NTimer::EOrdered;
|
sl@0
|
396 |
break; // done this one
|
sl@0
|
397 |
}
|
sl@0
|
398 |
}
|
sl@0
|
399 |
}
|
sl@0
|
400 |
NKern::RestoreInterrupts(irq);
|
sl@0
|
401 |
__DEBUG_CALLBACK(4);
|
sl@0
|
402 |
}
|
sl@0
|
403 |
NKern::RestoreInterrupts(irq);
|
sl@0
|
404 |
__DEBUG_CALLBACK(5);
|
sl@0
|
405 |
|
sl@0
|
406 |
// Finally do call backs for timers which requested DFC callback
|
sl@0
|
407 |
FOREVER
|
sl@0
|
408 |
{
|
sl@0
|
409 |
irq=NKern::DisableAllInterrupts();
|
sl@0
|
410 |
if (iCompletedQ.IsEmpty())
|
sl@0
|
411 |
break;
|
sl@0
|
412 |
NTimer* pC=(NTimer*)iCompletedQ.First();
|
sl@0
|
413 |
pC->Deque();
|
sl@0
|
414 |
pC->iState=NTimer::EIdle;
|
sl@0
|
415 |
TAny* p=pC->iPtr;
|
sl@0
|
416 |
NTimerFn f=pC->iFunction;
|
sl@0
|
417 |
NKern::RestoreInterrupts(irq);
|
sl@0
|
418 |
__DEBUG_CALLBACK(7);
|
sl@0
|
419 |
(*f)(p);
|
sl@0
|
420 |
}
|
sl@0
|
421 |
NKern::RestoreInterrupts(irq);
|
sl@0
|
422 |
}
|
sl@0
|
423 |
|
sl@0
|
424 |
|
sl@0
|
425 |
/** Tick over the nanokernel timer queue.
|
sl@0
|
426 |
This function should be called by the base port in the system tick timer ISR.
|
sl@0
|
427 |
It should not be called at any other time.
|
sl@0
|
428 |
The value of 'this' to pass is the value returned by NTimerQ::TimerAddress().
|
sl@0
|
429 |
|
sl@0
|
430 |
@see NTimerQ::TimerAddress()
|
sl@0
|
431 |
*/
|
sl@0
|
432 |
EXPORT_C void NTimerQ::Tick()
|
sl@0
|
433 |
{
|
sl@0
|
434 |
#ifdef _DEBUG
|
sl@0
|
435 |
// If there are threads waiting to be released by the tick, enqueue the dfc
|
sl@0
|
436 |
if (!TheScheduler.iDelayedQ.IsEmpty())
|
sl@0
|
437 |
TheScheduler.iDelayDfc.Add();
|
sl@0
|
438 |
#endif
|
sl@0
|
439 |
TheScheduler.TimesliceTick();
|
sl@0
|
440 |
TInt irq=NKern::DisableAllInterrupts();
|
sl@0
|
441 |
TInt i=iMsCount & ETimerQMask;
|
sl@0
|
442 |
iMsCount++;
|
sl@0
|
443 |
STimerQ* pQ=iTickQ+i;
|
sl@0
|
444 |
iPresent &= ~(1<<i);
|
sl@0
|
445 |
TBool doDfc=FALSE;
|
sl@0
|
446 |
if (!pQ->iDfcQ.IsEmpty())
|
sl@0
|
447 |
{
|
sl@0
|
448 |
// transfer DFC completions to completed queue and queue DFC
|
sl@0
|
449 |
iCompletedQ.MoveFrom(&pQ->iDfcQ);
|
sl@0
|
450 |
doDfc=TRUE;
|
sl@0
|
451 |
}
|
sl@0
|
452 |
if ((i&(ETimerQMask>>1))==0)
|
sl@0
|
453 |
{
|
sl@0
|
454 |
// Every 16 ticks we check if a DFC is required.
|
sl@0
|
455 |
// This allows a DFC latency of up to 16 ticks before timers are missed.
|
sl@0
|
456 |
if (!iHoldingQ.IsEmpty())
|
sl@0
|
457 |
doDfc=TRUE; // if holding queue nonempty, queue DFC to sort
|
sl@0
|
458 |
else if (!iOrderedQ.IsEmpty())
|
sl@0
|
459 |
{
|
sl@0
|
460 |
// if first ordered queue entry expires in <32ms, queue the DFC to transfer
|
sl@0
|
461 |
NTimer* pC=(NTimer*)iOrderedQ.First();
|
sl@0
|
462 |
#ifdef __EPOC32__
|
sl@0
|
463 |
__ASSERT_WITH_MESSAGE_DEBUG(iMsCount<=pC->iTriggerTime, "iMsCount has exceeded pC->iTriggerTime; function called later than expected ","NTimerQ::Tick()");
|
sl@0
|
464 |
#endif
|
sl@0
|
465 |
if (TInt(pC->iTriggerTime-iMsCount)<ENumTimerQueues)
|
sl@0
|
466 |
doDfc=TRUE;
|
sl@0
|
467 |
}
|
sl@0
|
468 |
}
|
sl@0
|
469 |
if (!pQ->iIntQ.IsEmpty())
|
sl@0
|
470 |
{
|
sl@0
|
471 |
// transfer ISR completions to a temporary queue
|
sl@0
|
472 |
// careful here - higher priority interrupts could dequeue timers!
|
sl@0
|
473 |
SDblQue q(&pQ->iIntQ,0);
|
sl@0
|
474 |
while(!q.IsEmpty())
|
sl@0
|
475 |
{
|
sl@0
|
476 |
NTimer* pC=(NTimer*)q.First();
|
sl@0
|
477 |
pC->Deque();
|
sl@0
|
478 |
pC->iState=NTimer::EIdle;
|
sl@0
|
479 |
NKern::RestoreInterrupts(irq);
|
sl@0
|
480 |
if (pC->iFunction)
|
sl@0
|
481 |
(*pC->iFunction)(pC->iPtr);
|
sl@0
|
482 |
else
|
sl@0
|
483 |
((TDfc*)(pC->iPtr))->Add();
|
sl@0
|
484 |
irq=NKern::DisableAllInterrupts();
|
sl@0
|
485 |
}
|
sl@0
|
486 |
}
|
sl@0
|
487 |
NKern::RestoreInterrupts(irq);
|
sl@0
|
488 |
if (doDfc)
|
sl@0
|
489 |
iDfc.Add();
|
sl@0
|
490 |
}
|
sl@0
|
491 |
|
sl@0
|
492 |
|
sl@0
|
493 |
/** Return the number of ticks before the next nanokernel timer expiry.
|
sl@0
|
494 |
May on occasion return a pessimistic estimate (i.e. too low).
|
sl@0
|
495 |
Used by base port to disable the system tick interrupt when the system
|
sl@0
|
496 |
is idle.
|
sl@0
|
497 |
|
sl@0
|
498 |
@return The number of ticks before the next nanokernel timer expiry.
|
sl@0
|
499 |
|
sl@0
|
500 |
@pre Interrupts must be disabled.
|
sl@0
|
501 |
|
sl@0
|
502 |
@post Interrupts are disabled.
|
sl@0
|
503 |
*/
|
sl@0
|
504 |
EXPORT_C TInt NTimerQ::IdleTime()
|
sl@0
|
505 |
{
|
sl@0
|
506 |
CHECK_PRECONDITIONS(MASK_INTERRUPTS_DISABLED,"NTimerQ::IdleTime");
|
sl@0
|
507 |
#ifdef _DEBUG
|
sl@0
|
508 |
// If there are threads waiting to be released by the tick we can't idle
|
sl@0
|
509 |
if (!TheScheduler.iDelayedQ.IsEmpty())
|
sl@0
|
510 |
return 1;
|
sl@0
|
511 |
#endif
|
sl@0
|
512 |
NTimerQ& m=TheTimerQ;
|
sl@0
|
513 |
TUint32 next=m.iMsCount; // number of next tick
|
sl@0
|
514 |
TUint32 p=m.iPresent;
|
sl@0
|
515 |
TInt r=KMaxTInt;
|
sl@0
|
516 |
if (p)
|
sl@0
|
517 |
{
|
sl@0
|
518 |
// Final queues nonempty
|
sl@0
|
519 |
TInt nx=next&0x1f; // number of next tick modulo 32
|
sl@0
|
520 |
p=(p>>nx)|(p<<(32-nx)); // rotate p right by nx (so lsb corresponds to next tick)
|
sl@0
|
521 |
r=__e32_find_ls1_32(p); // find number of zeros before LS 1
|
sl@0
|
522 |
}
|
sl@0
|
523 |
if (!m.iHoldingQ.IsEmpty())
|
sl@0
|
524 |
{
|
sl@0
|
525 |
// Sort operation required - need to process next tick divisible by 16
|
sl@0
|
526 |
TInt nx=next&0x0f; // number of next tick modulo 16
|
sl@0
|
527 |
TInt r2=nx?(16-nx):0; // number of ticks before next divisible by 16
|
sl@0
|
528 |
if (r2<r)
|
sl@0
|
529 |
r=r2;
|
sl@0
|
530 |
}
|
sl@0
|
531 |
if (!m.iOrderedQ.IsEmpty())
|
sl@0
|
532 |
{
|
sl@0
|
533 |
// Timers present on ordered queue
|
sl@0
|
534 |
NTimer* pC=(NTimer*)m.iOrderedQ.First();
|
sl@0
|
535 |
TUint32 tt=pC->iTriggerTime;
|
sl@0
|
536 |
tt=(tt&~0x0f)-16; // time at which transfer to final queue would occur
|
sl@0
|
537 |
TInt r3=(TInt)(tt-next);
|
sl@0
|
538 |
if (r3<r)
|
sl@0
|
539 |
r=r3;
|
sl@0
|
540 |
}
|
sl@0
|
541 |
return r;
|
sl@0
|
542 |
}
|
sl@0
|
543 |
#endif
|
sl@0
|
544 |
|
sl@0
|
545 |
|
sl@0
|
546 |
/** Advance the nanokernel timer queue by the specified number of ticks.
|
sl@0
|
547 |
It is assumed that no timers expire as a result of this.
|
sl@0
|
548 |
Used by base port when system comes out of idle mode after disabling the
|
sl@0
|
549 |
system tick interrupt to bring the timer queue up to date.
|
sl@0
|
550 |
|
sl@0
|
551 |
@param aTicks Number of ticks skipped due to tick suppression
|
sl@0
|
552 |
|
sl@0
|
553 |
@pre Interrupts must be disabled.
|
sl@0
|
554 |
|
sl@0
|
555 |
@post Interrupts are disabled.
|
sl@0
|
556 |
*/
|
sl@0
|
557 |
EXPORT_C void NTimerQ::Advance(TInt aTicks)
|
sl@0
|
558 |
{
|
sl@0
|
559 |
CHECK_PRECONDITIONS(MASK_INTERRUPTS_DISABLED,"NTimerQ::Advance");
|
sl@0
|
560 |
TheTimerQ.iMsCount+=(TUint32)aTicks;
|
sl@0
|
561 |
}
|
sl@0
|
562 |
|
sl@0
|
563 |
|
sl@0
|
564 |
/** Returns the period of the nanokernel timer.
|
sl@0
|
565 |
@return Period in microseconds
|
sl@0
|
566 |
@pre any context
|
sl@0
|
567 |
@see NTimer
|
sl@0
|
568 |
*/
|
sl@0
|
569 |
EXPORT_C TInt NKern::TickPeriod()
|
sl@0
|
570 |
{
|
sl@0
|
571 |
return TheTimerQ.iTickPeriod;
|
sl@0
|
572 |
}
|
sl@0
|
573 |
|
sl@0
|
574 |
|
sl@0
|
575 |
/** Converts a time interval to timer ticks.
|
sl@0
|
576 |
|
sl@0
|
577 |
@param aMilliseconds time interval in milliseconds.
|
sl@0
|
578 |
@return Number of nanokernel timer ticks. Non-integral results are rounded up.
|
sl@0
|
579 |
|
sl@0
|
580 |
@pre aMilliseconds should be <=2147483 to avoid integer overflow.
|
sl@0
|
581 |
@pre any context
|
sl@0
|
582 |
*/
|
sl@0
|
583 |
EXPORT_C TInt NKern::TimerTicks(TInt aMilliseconds)
|
sl@0
|
584 |
{
|
sl@0
|
585 |
__ASSERT_WITH_MESSAGE_DEBUG(aMilliseconds<=2147483,"aMilliseconds should be <=2147483","NKern::TimerTicks");
|
sl@0
|
586 |
TUint32 msp=TheTimerQ.iTickPeriod;
|
sl@0
|
587 |
if (msp==1000) // will be true except on pathological hardware
|
sl@0
|
588 |
return aMilliseconds;
|
sl@0
|
589 |
TUint32 us=(TUint32)aMilliseconds*1000;
|
sl@0
|
590 |
return (us+msp-1)/msp;
|
sl@0
|
591 |
}
|
sl@0
|
592 |
|