// Copyright (c) 1998-2009 Nokia Corporation and/or its subsidiary(-ies).
// All rights reserved.
// This component and the accompanying materials are made available
// under the terms of the License "Eclipse Public License v1.0"
// which accompanies this distribution, and is available
// at the URL "http://www.eclipse.org/legal/epl-v10.html".
//
// Initial Contributors:
// Nokia Corporation - initial contribution.
//
// Contributors:
//
// Description:
// e32\nkern\nkerns.cpp
//
//
// NThreadBase member data
#define __INCLUDE_NTHREADBASE_DEFINES__
#include <e32cmn.h>
#include <e32cmn_private.h>
#include "nk_priv.h"
extern "C" void ExcFault(TAny*);
/******************************************************************************
* Thread
******************************************************************************/
void InvalidExec()
{
FAULT();
}
static const SFastExecTable DefaultFastExecTable={0,{0}};
static const SSlowExecTable DefaultSlowExecTable={0,(TLinAddr)InvalidExec,0,{{0,0}}};
const SNThreadHandlers NThread_Default_Handlers =
{
NTHREAD_DEFAULT_EXIT_HANDLER,
NTHREAD_DEFAULT_STATE_HANDLER,
NTHREAD_DEFAULT_EXCEPTION_HANDLER,
NTHREAD_DEFAULT_TIMEOUT_HANDLER
};
/** Create a fast mutex
@publishedPartner
@released
*/
EXPORT_C NFastMutex::NFastMutex()
: iHoldingThread(0), iWaiting(0)
{
}
/** Create a spin lock
@internalComponent
*/
EXPORT_C TSpinLock::TSpinLock(TUint)
: iLock(0)
{
}
/** Create a R/W spin lock
@internalComponent
*/
EXPORT_C TRWSpinLock::TRWSpinLock(TUint)
: iLock(0)
{
}
NThreadBase::NThreadBase()
{
// from TPriListLink
iPriority = 0;
iSpare1 = 0;
iSpare2 = 0;
iSpare3 = 0;
iRequestSemaphore.iOwningThread=(NThreadBase*)this;
new (&iTimer) NTimer(TimerExpired,this);
iRequestSemaphore.iOwningThread = this;
iHeldFastMutex = 0;
iWaitFastMutex = 0;
iAddressSpace = 0;
iTime = 0;
iTimeslice = 0;
iWaitObj = 0;
iSuspendCount = 0;
iCsCount = 0;
iCsFunction = 0;
iReturnValue = 0;
iStackBase = 0;
iStackSize = 0;
iHandlers = 0;
iFastExecTable = 0;
iSlowExecTable = 0;
iSavedSP = 0;
iExtraContext = 0;
iExtraContextSize = 0;
iLastStartTime = 0;
iTotalCpuTime = 0;
iTag = 0;
iVemsData = 0;
iUserModeCallbacks = 0;
iSpare7 = 0;
iSpare8 = 0;
}
TInt NThreadBase::Create(SNThreadCreateInfo& aInfo, TBool aInitial)
{
if (aInfo.iPriority<0 || aInfo.iPriority>63)
return KErrArgument;
if (aInfo.iPriority==0 && !aInitial)
return KErrArgument;
new (this) NThreadBase;
iStackBase=(TLinAddr)aInfo.iStackBase;
iStackSize=aInfo.iStackSize;
iTimeslice=(aInfo.iTimeslice>0)?aInfo.iTimeslice:-1;
iTime=iTimeslice;
#ifdef _DEBUG
// When the crazy scheduler is active, refuse to set any priority higher than 1
if (KCrazySchedulerEnabled())
iPriority=TUint8(Min(1,aInfo.iPriority));
else
#endif
{
iPriority=TUint8(aInfo.iPriority);
}
iHandlers = aInfo.iHandlers ? aInfo.iHandlers : &NThread_Default_Handlers;
iFastExecTable=aInfo.iFastExecTable?aInfo.iFastExecTable:&DefaultFastExecTable;
iSlowExecTable=(aInfo.iSlowExecTable?aInfo.iSlowExecTable:&DefaultSlowExecTable)->iEntries;
iSpare2=(TUint8)aInfo.iAttributes; // iSpare2 is NThread attributes
if (aInitial)
{
iNState=EReady;
iSuspendCount=0;
TheScheduler.Add(this);
TheScheduler.iCurrentThread=this;
TheScheduler.iKernCSLocked=0; // now that current thread is defined
}
else
{
iNState=ESuspended;
iSuspendCount=-1;
}
return KErrNone;
}
void NThread_Default_State_Handler(NThread* __DEBUG_ONLY(aThread), TInt __DEBUG_ONLY(aOperation), TInt __DEBUG_ONLY(aParameter))
{
__KTRACE_OPT(KPANIC,DEBUGPRINT("Unknown NState %d: thread %T op %08x par %08x",aThread,aThread->iNState,aOperation,aParameter));
FAULT();
}
void NThread_Default_Exception_Handler(TAny* aContext, NThread*)
{
ExcFault(aContext);
}
/** Create a nanothread.
This function is intended to be used by the EPOC kernel and by personality
layers. A nanothread may not use most of the functions available to normal
Symbian OS threads. Use Kern::ThreadCreate() to create a Symbian OS thread.
@param aThread Pointer to control block for thread to create.
@param aInfo Information needed for creating the thread.
@see SNThreadCreateInfo
@see Kern::ThreadCreate
@pre Call in a thread context.
@pre Interrupts must be enabled.
@pre Kernel must be unlocked.
*/
EXPORT_C TInt NKern::ThreadCreate(NThread* aThread, SNThreadCreateInfo& aInfo)
{
CHECK_PRECONDITIONS(MASK_KERNEL_UNLOCKED|MASK_INTERRUPTS_ENABLED|MASK_NOT_ISR|MASK_NOT_IDFC,"NKern::ThreadCreate");
return aThread->Create(aInfo,FALSE);
}
// User-mode callbacks
TUserModeCallback::TUserModeCallback(TUserModeCallbackFunc aFunc) :
iNext(KUserModeCallbackUnqueued),
iFunc(aFunc)
{
}
TUserModeCallback::~TUserModeCallback()
{
__NK_ASSERT_DEBUG(iNext == KUserModeCallbackUnqueued);
}
TInt NKern::QueueUserModeCallback(NThreadBase* aThread, TUserModeCallback* aCallback)
{
if (aCallback->iNext != KUserModeCallbackUnqueued)
return KErrInUse;
TInt r = KErrDied;
NKern::Lock();
TUserModeCallback* listHead = aThread->iUserModeCallbacks;
if (((TLinAddr)listHead & 3) == 0)
{
aCallback->iNext = listHead;
aThread->iUserModeCallbacks = aCallback;
r = KErrNone;
}
NKern::Unlock();
return r;
}
// Called with interrupts disabled
// The vast majority of times this is called with zero or one callback pending
void NThreadBase::CallUserModeCallbacks()
{
while (iUserModeCallbacks != NULL)
{
// Remove first callback
TUserModeCallback* callback = iUserModeCallbacks;
iUserModeCallbacks = callback->iNext;
// Enter critical section to ensure callback is called
NKern::ThreadEnterCS();
// Re-enable interrupts and call callback
NKern::EnableAllInterrupts();
callback->iNext = KUserModeCallbackUnqueued;
callback->iFunc(callback, EUserModeCallbackRun);
// Leave critical section: thread may die at this point
NKern::ThreadLeaveCS();
NKern::DisableAllInterrupts();
}
}
void NKern::CancelUserModeCallbacks()
{
// Call any queued callbacks with the EUserModeCallbackCancel reason code, in the current
// thread.
NThreadBase* thread = NCurrentThread();
NKern::Lock();
TUserModeCallback* listHead = thread->iUserModeCallbacks;
thread->iUserModeCallbacks = NULL;
NKern::Unlock();
while (listHead != NULL)
{
TUserModeCallback* callback = listHead;
listHead = listHead->iNext;
callback->iNext = KUserModeCallbackUnqueued;
callback->iFunc(callback, EUserModeCallbackCancel);
}
}
void NKern::MoveUserModeCallbacks(NThreadBase* aDestThread, NThreadBase* aSrcThread)
{
// Move all queued user-mode callbacks from the source thread to the destination thread, and
// prevent any more from being queued. Used by the kernel thread code so that callbacks get
// cancelled in another thread if the thread they were originally queued on dies.
NKern::Lock();
TUserModeCallback* sourceListStart = aSrcThread->iUserModeCallbacks;
aSrcThread->iUserModeCallbacks = (TUserModeCallback*)1;
NKern::Unlock();
__NK_ASSERT_DEBUG(((TUint)sourceListStart & 3) == 0); // check this only gets called once per thread
if (sourceListStart == NULL)
return;
TUserModeCallback* sourceListEnd = sourceListStart;
while (sourceListEnd->iNext != NULL)
sourceListEnd = sourceListEnd->iNext;
NKern::Lock();
TUserModeCallback* destListStart = aDestThread->iUserModeCallbacks;
__NK_ASSERT_DEBUG(((TUint)destListStart & 3) == 0);
sourceListEnd->iNext = destListStart;
aDestThread->iUserModeCallbacks = sourceListStart;
NKern::Unlock();
}
/** Initialise the null thread
@internalComponent
*/
void NKern::Init(NThread* aThread, SNThreadCreateInfo& aInfo)
{
aInfo.iFunction=NULL; // irrelevant
aInfo.iPriority=0; // null thread has lowest priority
aInfo.iTimeslice=0; // null thread not timesliced
aInfo.iAttributes=0; // null thread does not require implicit locks
aThread->Create(aInfo,TRUE); // create the null thread
}
extern "C" {
TUint32 CrashState;
}
EXPORT_C TBool NKern::Crashed()
{
return CrashState!=0;
}
/** @internalTechnology */
EXPORT_C void NKern::RecordIntLatency(TInt /*aLatency*/, TInt /*aIntMask*/)
{
}
/** @internalTechnology */
EXPORT_C void NKern::RecordThreadLatency(TInt /*aLatency*/)
{
}
/********************************************
* Deterministic Priority List Implementation
********************************************/
/** Construct a priority list with the specified number of priorities
@param aNumPriorities The number of priorities (must be 1-64).
*/
EXPORT_C TPriListBase::TPriListBase(TInt aNumPriorities)
{
memclr(this, sizeof(TPriListBase)+(aNumPriorities-1)*sizeof(SDblQueLink*) );
}
/********************************************
* Miscellaneous
********************************************/
/** Returns number of nanokernel timer ticks since system started.
@return tick count
@pre any context
*/
EXPORT_C TUint32 NKern::TickCount()
{
return NTickCount();
}
TUint32 BTrace::BigTraceId = 0;
TBool BTrace::DoOutBig(TUint32 a0, TUint32 a1, const TAny* aData, TInt aDataSize, TUint32 aContext, TUint32 aPc)
{
SBTraceData& traceData = BTraceData;
// see if trace is small enough to fit in single record...
if(TUint(aDataSize)<=TUint(KMaxBTraceDataArray+4))
{
a0 += aDataSize;
TUint32 a2 = 0;
TUint32 a3 = 0;
if(aDataSize)
{
a2 = *((TUint32*&)aData)++; // first 4 bytes into a2
if(aDataSize>=4 && aDataSize<=8)
a3 = *(TUint32*)aData; // only 4 more bytes, so pass by value, not pointer
else
a3 = (TUint32)aData;
}
return traceData.iHandler(a0,0,aContext,a1,a2,a3,0,aPc);
}
// adjust for header2, extra, and size word...
a0 |= BTrace::EHeader2Present<<(BTrace::EFlagsIndex*8)|BTrace::EExtraPresent<<(BTrace::EFlagsIndex*8);
a0 += 12;
TUint32 traceId = __e32_atomic_add_ord32(&BigTraceId, 1);
TUint32 header2 = BTrace::EMultipartFirst;
TInt offset = 0;
do
{
TUint32 size = aDataSize-offset;
if(size>KMaxBTraceDataArray)
size = KMaxBTraceDataArray;
else
header2 = BTrace::EMultipartLast;
if(size<=4)
*(TUint32*)&aData = *(TUint32*)aData; // 4 bytes or less are passed by value, not pointer
TBool result = traceData.iHandler(a0+size,header2,aContext,aDataSize,a1,(TUint32)aData,traceId,aPc);
if(!result)
return result;
offset += size;
*(TUint8**)&aData += size;
header2 = BTrace::EMultipartMiddle;
a1 = offset;
}
while(offset<aDataSize);
return TRUE;
}
EXPORT_C TSpinLock* BTrace::LockPtr()
{
return 0;
}