// Copyright (c) 2002-2009 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:
// e32test\smpsoak\t_smpsoak.cpp
// User Includes
#include <e32hal.h>
#include "t_smpsoak.h"
void ParseCommandLine ();
// Global Variables
static TInt gPageSize;
//Timeout 2 Minutes
static TUint gTimeout = 120;
//class for smpsoak thread and it creates memory, device, timer and spin threads.
class CSMPSoakThread
{
public:
CSMPSoakThread();
~CSMPSoakThread();
void CreateThread();
void ResumeThread();
void CreateChildProcess(TInt aIndex);
void ResumeChildProcess();
void TerminateChildProcess();
private:
//Thread Functions
static TInt SMPStressMemoryThread(TAny*);
static TInt SMPStressDeviceThread(TAny*);
static TInt SMPStressTimerThread(TAny*);
static TInt SMPStressSpinThread(TAny*);
//Thread Priority
void DoCreateThread(TAny*);
void SetThreadPriority();
private:
//Utils for memory thread
void CreateChunk(TChunkInfo * aChunkInfo, TMemory * aMemoryTablePtr);
void CommitChunk(TChunkInfo * aChunkInfo, TMemory * aMemoryTablePtr);
void WriteReadChunk(TChunkInfo * aChunkInfo, TMemory * aMemoryTablePtr);
private:
//Memebers for threads
TInt DoSMPStressMemoryThread();
TInt DoSMPStressDeviceThread();
TInt DoSMPStressTimerThread();
TInt DoSMPStressSpinThread();
private:
TThreadData iThreadData;
RProcess iProcess;
RThread iThread;
TInt iPriority;
private:
// Thread Data for each thread- low priority
static TThread KThreadTableLow[];
// Thread Data for each thread- high priority
static TThread KThreadTableHigh[];
//Process Data for each process
static const TProcess KProcessTable[];
//Memory table for memory thread
static const TMemory KMemoryTable[];
//Device table for device thread
static const TDesC* KDeviceTable[];
};
TThread CSMPSoakThread::KThreadTableLow[] =
{
{ _L("Memory Thread"), CSMPSoakThread::SMPStressMemoryThread, {{EPriorityAbsoluteLow, EPriorityAbsoluteVeryLow, EPriorityNormal, 0}, EPriorityList, KCpuAffinityAny, 250, 1, (TAny *)&KMemoryTable, NULL, NULL}},
{ _L("Device Thread"), CSMPSoakThread::SMPStressDeviceThread, {{EPriorityAbsoluteLow, EPriorityAbsoluteVeryLow, EPriorityNormal, 0}, EPriorityList, KCpuAffinityAny, 300, 1, &KDeviceTable, NULL, NULL}},
{ _L("Spin Thread 0"), CSMPSoakThread::SMPStressSpinThread, {{EPriorityAbsoluteVeryLow, EPriorityNormal, EPriorityNormal, EPriorityNormal}, EPriorityList, KCpuAffinityAny, 200, 0, NULL, NULL, NULL}},
{ _L("Spin Thread 1"), CSMPSoakThread::SMPStressSpinThread, {{EPriorityNormal, EPriorityAbsoluteVeryLow, EPriorityNormal, EPriorityNormal}, EPriorityList, KCpuAffinityAny, 300, 0, NULL, NULL, NULL}},
{ _L("Spin Thread 2"), CSMPSoakThread::SMPStressSpinThread, {{EPriorityNormal, EPriorityNormal, EPriorityAbsoluteVeryLow, EPriorityNormal}, EPriorityList, KCpuAffinityAny, 400, 0, NULL, NULL, NULL}},
{ _L("Spin Thread 3"), CSMPSoakThread::SMPStressSpinThread, {{EPriorityNormal, EPriorityNormal, EPriorityAbsoluteLow, EPriorityAbsoluteVeryLow}, EPriorityList, KCpuAffinityAny, 500, 0, NULL, NULL, NULL}},
{ _L("Timer Thread"), CSMPSoakThread::SMPStressTimerThread, {{EPriorityNormal, 0, 0, 0}, EPriorityList, KCpuAffinityAny, 1000, 4, NULL}},
};
TThread CSMPSoakThread::KThreadTableHigh[] =
{
{ _L("Memory Thread"), CSMPSoakThread::SMPStressMemoryThread, {{EPriorityAbsoluteLow, EPriorityAbsoluteVeryLow, EPriorityNormal, 0}, EPriorityList, KCpuAffinityAny, 250, 1, (TAny *)&KMemoryTable, NULL, NULL}},
{ _L("Device Thread"), CSMPSoakThread::SMPStressDeviceThread, {{EPriorityAbsoluteLow, EPriorityAbsoluteVeryLow, EPriorityNormal, 0}, EPriorityList, KCpuAffinityAny, 300, 1, &KDeviceTable, NULL, NULL}},
{ _L("Spin Thread 0"), CSMPSoakThread::SMPStressSpinThread, {{EPriorityAbsoluteVeryLow, EPriorityNormal, EPriorityNormal, EPriorityNormal}, EPriorityList, KCpuAffinityAny, 200, 0, NULL, NULL, NULL}},
{ _L("Spin Thread 1"), CSMPSoakThread::SMPStressSpinThread, {{EPriorityNormal, EPriorityAbsoluteVeryLow, EPriorityNormal, EPriorityNormal}, EPriorityList, KCpuAffinityAny, 300, 0, NULL, NULL, NULL}},
{ _L("Spin Thread 2"), CSMPSoakThread::SMPStressSpinThread, {{EPriorityNormal, EPriorityNormal, EPriorityAbsoluteVeryLow, EPriorityNormal}, EPriorityList, KCpuAffinityAny, 400, 0, NULL, NULL, NULL}},
{ _L("Spin Thread 3"), CSMPSoakThread::SMPStressSpinThread, {{EPriorityNormal, EPriorityNormal, EPriorityAbsoluteLow, EPriorityAbsoluteVeryLow}, EPriorityList, KCpuAffinityAny, 500, 0, NULL, NULL, NULL}},
{ _L("Timer Thread"), CSMPSoakThread::SMPStressTimerThread, {{EPriorityNormal, 0, 0, 0}, EPriorityList, KCpuAffinityAny, 1000, 4, NULL}},
};
const TProcess CSMPSoakThread::KProcessTable[] =
{
{ _L("t_smpsoakprocess.exe"), _L("-W"), KCpuAffinityAny},
{ _L("t_smpsoakprocess.exe"), _L("-R"), KCpuAffinityAny},
{ _L("t_smpsoakprocess.exe"), _L("-F"), KCpuAffinityAny},
{ _L("t_smpsoakprocess.exe"), _L("-T"), KCpuAffinityAny},
{ _L("t_smpsoakprocess.exe"), _L("-O"), KCpuAffinityAny},
};
const TMemory CSMPSoakThread::KMemoryTable[] =
{
{_L(""), EChunkNormalThread, 0, 10, 100 },
{_L("Global Chunk 1"), EChunkNormalThread, 0, 20, 200 },
{_L(""), EChunkDisconnectedThread, 3, 30, 300 },
{_L("Global Chunk 2"), EChunkDisconnectedThread, 4, 40, 400 },
{_L(""), EChunkDoubleEndedThread, 5, 50, 500 },
{_L("Global Chunk 3"), EChunkDoubleEndedThread, 6, 60, 600 },
{_L(""), EChunkNormalProcess, 0, 10, 100 },
{_L("Global Chunk 4"), EChunkNormalProcess, 0, 20, 200 },
{_L(""), EChunkDisconnectedProcess, 3, 30, 300 },
{_L("Global Chunk 5"), EChunkDisconnectedProcess, 4, 40, 400 },
{_L(""), EChunkDoubleEndedProcess, 5, 50, 500 },
{_L("Global Chunk 6"), EChunkDoubleEndedProcess, 6, 60, 600 },
{_L(""), EChunkNone, 0, 0, 0 },
};
const TDesC* CSMPSoakThread::KDeviceTable[] =
{
&KDevices, &KDevLdd1, &KDevLdd1Name, &KDevLdd2, &KDevLdd2Name, &KDevLdd3, &KDevLdd3Name,
&KDevLdd4, &KDevLdd4Name, NULL
};
//Constructor
CSMPSoakThread::CSMPSoakThread()
{
}
//Destructor
CSMPSoakThread::~CSMPSoakThread()
{
}
//All child process creation
void CSMPSoakThread::CreateChildProcess(TInt aIndex)
{
if(TestSilent)
gCmdLine.Format(KCmdLineBackground,(KProcessTable[aIndex].operation).Ptr());
else if (Period)
gCmdLine.Format(KCmdLinePeriod,gPeriod,(KProcessTable[aIndex].operation).Ptr());
else
gCmdLine.Format(KCmdLineProcess,(KProcessTable[aIndex].operation).Ptr());
TInt r = iProcess.Create(KProcessTable[aIndex].processFileName,gCmdLine);
test_KErrNone(r);
iProcess.SetPriority(EPriorityLow);
gSMPStressDrv.ChangeThreadAffinity(&iThread, KProcessTable[aIndex].cpuAffinity);
PRINT ((_L("SetProcessPriority CPU %d Priority %d\n"),gSMPStressDrv.GetThreadCPU(&iThread), iProcess.Priority()));
}
//Terminate process when user press "Esc key"
void CSMPSoakThread::ResumeChildProcess()
{
iProcess.Resume();
}
//Terminate process when user press "Esc key"
void CSMPSoakThread::TerminateChildProcess()
{
iProcess.Kill(KErrNone);
}
//Changes the thread priority each time time, for each thread by Random, Increment, from List, Fixed.
//pick up the priority option from thread table
void CSMPSoakThread::SetThreadPriority()
{
static TInt64 randSeed = KRandSeed;
static const TThreadPriority priorityTable[]=
{
EPriorityMuchLess, EPriorityLess, EPriorityNormal, EPriorityMore, EPriorityMuchMore,
EPriorityRealTime, EPriorityRealTime, EPriorityAbsoluteVeryLow, EPriorityAbsoluteLowNormal,
EPriorityAbsoluteLow, EPriorityAbsoluteBackgroundNormal, EPriorityAbsoluteBackground,
EPriorityAbsoluteForegroundNormal, EPriorityAbsoluteForeground, EPriorityAbsoluteHighNormal, EPriorityAbsoluteHigh
};
TInt priorityIndex = 0;
switch (iThreadData.threadPriorityChange)
{
case EpriorityFixed:
break;
case EPriorityList:
if (++iPriority >= KPriorityOrder)
iPriority = 0;
if (iThreadData.threadPriorities[iPriority] == 0)
iPriority = 0;
// PRINT(_L("SetPriority List CPU %d index %d priority %d\n"),gSMPStressDrv.GetThreadCPU(&iThread),iPriority, iThreadData.threadPriorities[iPriority]);
iThread.SetPriority((TThreadPriority)iThreadData.threadPriorities[iPriority]);
break;
case EPriorityIncrement:
while (priorityTable[priorityIndex] <= iPriority)
{
priorityIndex++;
}
iPriority = priorityTable[priorityIndex];
if (iPriority > iThreadData.threadPriorities[2])
iPriority = iThreadData.threadPriorities[1];
// PRINT(_L("SetPriority Increment CPU %d iPriority %d\n"),gSMPStressDrv.GetThreadCPU(&iThread), iPriority);
iThread.SetPriority((TThreadPriority)iPriority);
break;
case EPriorityRandom:
iPriority = Math::Rand(randSeed) % (iThreadData.threadPriorities[2] - iThreadData.threadPriorities[1] + 1);
iPriority += iThreadData.threadPriorities[1];
while (priorityTable[priorityIndex] < iPriority)
{
priorityIndex++;
}
iPriority = priorityTable[priorityIndex];
// PRINT(_L("SetPriority Random CPU %d priority %d\n"),gSMPStressDrv.GetThreadCPU(&iThread), iPriority);
iThread.SetPriority((TThreadPriority)iPriority);
break;
}
}
//Resume each thread
void CSMPSoakThread::ResumeThread()
{
iThread.Resume();
}
//thread creation
void CSMPSoakThread::CreateThread()
{
CSMPSoakThread* smpthread = new CSMPSoakThread[KNumThreads];
for (TInt i = 0; i < KNumThreads ; i++)
{
if(ThreadPriorityLow)
{
PRINT ((_L("Thread Table - Priority Low \n")));
smpthread[i].DoCreateThread(&KThreadTableLow[i]);
}
else
{
PRINT ((_L("Thread Table - Priority High \n")));
smpthread[i].DoCreateThread(&KThreadTableHigh[i]);
}
}
PRINT (_L("Resuming all threads\n"));
for (TInt i = 0; i < KNumThreads; i++)
smpthread[i].ResumeThread();
}
/**
* CSMPSoakThread Thread Creation.
* @param aIndex to exercise each row(thread) in the thread table
*
* @return N/A
*
* @pre Initialize thread Table values
* @post None
*/
void CSMPSoakThread::DoCreateThread(TAny* aThread)
{
//Initialize each thread data
iThreadData = ((TThread*)aThread)->threadData;
test.Next(_L("Create Thread"));
PRINT ((_L("%s CPU affinity %d Priority %d\n"),((TThread*)aThread)->threadName.Ptr(),iThreadData.cpuAffinity,iThreadData.threadPriorities[0]));
TInt r = iThread.Create(((TThread*)aThread)->threadName, ((TThread*)aThread)->threadFunction, KDefaultStackSize, KHeapMinSize, KHeapMaxSize,(TAny*)this);
test_KErrNone(r);
if (iThreadData.threadPriorityChange == EPriorityList)
{
iPriority = 0;
}
else
{
iPriority = iThreadData.threadPriorities[0];
}
iThread.SetPriority((TThreadPriority)iThreadData.threadPriorities[0]);
//Set the thread CPU Affinity
gSMPStressDrv.ChangeThreadAffinity(&iThread, iThreadData.cpuAffinity);
}
//Create Chunk - different types
void CSMPSoakThread::CreateChunk (TChunkInfo * aChunkInfo, TMemory * aMemoryTablePtr)
{
//RDebug::Print(_L("Creating chunk name %s type %d bottom %d top %d max %d\n"),aMemoryTablePtr->globalChunkName.Ptr(),aMemoryTablePtr->chunkType,aMemoryTablePtr->initialBottom,aMemoryTablePtr->initialTop,aMemoryTablePtr->maxSize);
TOwnerType ownerType = EOwnerProcess;
aChunkInfo->lastBottom = aMemoryTablePtr->initialBottom;
aChunkInfo->lastTop = aMemoryTablePtr->initialTop;
switch (aMemoryTablePtr->chunkType)
{
case EChunkNormalThread:
ownerType = EOwnerThread; // drop through to create chunk
case EChunkNormalProcess:
if (aMemoryTablePtr->globalChunkName.Length())
{
test_KErrNone(aChunkInfo->chunk.CreateGlobal(aMemoryTablePtr->globalChunkName,aMemoryTablePtr->initialTop*gPageSize,aMemoryTablePtr->maxSize*gPageSize,ownerType));
}
else
{
test_KErrNone(aChunkInfo->chunk.CreateLocal(aMemoryTablePtr->initialTop*gPageSize,aMemoryTablePtr->maxSize*gPageSize,ownerType));
}
aChunkInfo->lastBottom = 0; // ensure that this is zero
break;
case EChunkDisconnectedThread:
ownerType = EOwnerThread; // drop through to create chunk
case EChunkDisconnectedProcess:
if (aMemoryTablePtr->globalChunkName.Length())
{
test_KErrNone(aChunkInfo->chunk.CreateDisconnectedGlobal(aMemoryTablePtr->globalChunkName,aMemoryTablePtr->initialBottom*gPageSize,aMemoryTablePtr->initialTop*gPageSize,aMemoryTablePtr->maxSize*gPageSize,ownerType));
}
else
{
test_KErrNone(aChunkInfo->chunk.CreateDisconnectedLocal(aMemoryTablePtr->initialBottom*gPageSize,aMemoryTablePtr->initialTop*gPageSize,aMemoryTablePtr->maxSize*gPageSize,ownerType));
}
break;
case EChunkDoubleEndedThread:
ownerType = EOwnerThread; // drop through to create chunk
case EChunkDoubleEndedProcess:
if (aMemoryTablePtr->globalChunkName.Length())
{
test_KErrNone(aChunkInfo->chunk.CreateDoubleEndedGlobal(aMemoryTablePtr->globalChunkName,aMemoryTablePtr->initialBottom*gPageSize,aMemoryTablePtr->initialTop*gPageSize,aMemoryTablePtr->maxSize*gPageSize,ownerType));
}
else
{
test_KErrNone(aChunkInfo->chunk.CreateDoubleEndedLocal(aMemoryTablePtr->initialBottom*gPageSize,aMemoryTablePtr->initialTop*gPageSize,aMemoryTablePtr->maxSize*gPageSize,ownerType));
}
break;
}
}
//Commit chunk
void CSMPSoakThread::CommitChunk (TChunkInfo * aChunkInfo, TMemory * aMemoryTablePtr)
{
TInt commitPages;
switch (aMemoryTablePtr->chunkType)
{
case EChunkNormalThread:
case EChunkNormalProcess:
if (aChunkInfo->lastTop < (aMemoryTablePtr->maxSize - 1))
{
aChunkInfo->lastTop += (aMemoryTablePtr->maxSize - 1 - aChunkInfo->lastTop) / 2 + 1;
//PRINT(_L("Adjust chunk memory - top %d pagesize %d\n"),aChunkInfo->lastTop,gPageSize);
test_KErrNone(aChunkInfo->chunk.Adjust(aChunkInfo->lastTop*gPageSize));
}
break;
case EChunkDisconnectedThread:
case EChunkDisconnectedProcess:
commitPages = ((aChunkInfo->lastTop - aChunkInfo->lastBottom) / 2) + 1;
//PRINT(_L("Decommitting from bottom %d of %d pages\n"),aChunkInfo->lastBottom,commitPages);
test_KErrNone(aChunkInfo->chunk.Decommit(aChunkInfo->lastBottom*gPageSize,commitPages * gPageSize));
if ((aChunkInfo->lastBottom > 0) && (aChunkInfo->lastTop <= aMemoryTablePtr->initialTop))
{
aChunkInfo->lastTop = aChunkInfo->lastBottom + commitPages - 1;
aChunkInfo->lastBottom /= 2;
commitPages = aChunkInfo->lastTop - aChunkInfo->lastBottom + 1;
}
else
{
if (aChunkInfo->lastTop < (aMemoryTablePtr->maxSize -1))
{
if (aChunkInfo->lastTop <= aMemoryTablePtr->initialTop)
{
aChunkInfo->lastBottom = aMemoryTablePtr->initialTop + 1;
}
else
{
aChunkInfo->lastBottom = aChunkInfo->lastTop + 1;
}
commitPages = ((aMemoryTablePtr->maxSize - aChunkInfo->lastBottom) / 2) + 1;
aChunkInfo->lastTop = aChunkInfo->lastBottom + commitPages - 1;
}
else
{
commitPages = 0;
}
}
if (commitPages)
{
//PRINT(_L("Commit chunk memory bottom %d size %d pages\n"),aChunkInfo->lastBottom,commitPages);
test_KErrNone(aChunkInfo->chunk.Commit(aChunkInfo->lastBottom*gPageSize,commitPages*gPageSize));
}
break;
case EChunkDoubleEndedThread:
case EChunkDoubleEndedProcess:
if (aChunkInfo->lastBottom > 0 || aChunkInfo->lastTop < (aMemoryTablePtr->maxSize - 1))
{
if (aChunkInfo->lastBottom > 0)
{
aChunkInfo->lastBottom--;
}
if (aChunkInfo->lastTop < (aMemoryTablePtr->maxSize - 1))
{
aChunkInfo->lastTop++;
}
// PRINT(_L("Adjust Double Ended bottom %d top %d\n"),aChunkInfo->lastBottom,aChunkInfo->lastTop);
test_KErrNone(aChunkInfo->chunk.AdjustDoubleEnded(aChunkInfo->lastBottom*gPageSize,aChunkInfo->lastTop*gPageSize));
}
break;
}
}
//Write then read chunk
void CSMPSoakThread::WriteReadChunk (TChunkInfo * aChunkInfo, TMemory * aMemoryTablePtr)
{
if (aChunkInfo->lastTop < (aMemoryTablePtr->maxSize - 1))
{
TInt chunkSize = aChunkInfo->lastTop*gPageSize - aChunkInfo->lastBottom*gPageSize;
//RDebug::Print(_L("WriteReadChunk Last Top %d lastBottom %d\n"),aChunkInfo->lastTop,aChunkInfo->lastBottom);
TUint8 *writeaddr = aChunkInfo->chunk.Base()+ aChunkInfo->lastBottom*gPageSize;
TPtr8 write(writeaddr,chunkSize);
write.Copy(pattern,sizeof(pattern));
test_KErrNone(Mem::Compare(writeaddr,sizeof(pattern),pattern,sizeof(pattern)));
}
}
//Memory Thread : will do memory associated operation
//param aSmp - CSMPSoakUtil pointer
TInt CSMPSoakThread::SMPStressMemoryThread(TAny* aSmp)
{
CSMPSoakThread* self = (CSMPSoakThread*)aSmp;
__ASSERT_ALWAYS(self !=NULL, User::Panic(_L("CSMPSoakThread::SMPStressMemoryThread Panic"),0));
return self->DoSMPStressMemoryThread();
}
// Member for thread function
TInt CSMPSoakThread::DoSMPStressMemoryThread()
{
RTest test(_L("SMPStressMemoryThread"));
test.Start(_L("SMPStressMemoryThread"));
TMemory *memoryTablePtr;
TChunkInfo chunkTable[KNumChunks];
TInt ctIndex = 0;
test_KErrNone(UserHal::PageSizeInBytes(gPageSize));
FOREVER
{
SetThreadPriority();
if (gAbort)
break;
memoryTablePtr = (TMemory *) (iThreadData.listPtr);
ctIndex = 0;
//Create different type of chunks and write/read/verfiy it
while (memoryTablePtr->chunkType != EChunkNone)
{
PRINT((_L("Create Chunk")));
CreateChunk (&chunkTable[ctIndex],memoryTablePtr);
PRINT(_L("Write and Read Chunk"));
WriteReadChunk (&chunkTable[ctIndex],memoryTablePtr);
ctIndex++;
memoryTablePtr++;
}
//Commit different type of chunks
TBool anyCommit;
do
{
anyCommit = EFalse;
memoryTablePtr = (TMemory *) (iThreadData.listPtr);
ctIndex = 0;
while (memoryTablePtr->chunkType != EChunkNone)
{
//Commit Chunks
PRINT((_L("Commit Chunk Memory")));
PRINT ((_L("CommitChunk %d bottom %d top %d\n"),ctIndex,memoryTablePtr->initialBottom,memoryTablePtr->initialTop));
CommitChunk (&chunkTable[ctIndex],memoryTablePtr);
anyCommit = ETrue;
//Write into Chunks
WriteReadChunk (&chunkTable[ctIndex],memoryTablePtr);
PRINT((_L("Write Read Chunk Size %d\n"), (memoryTablePtr->initialTop) - (memoryTablePtr->initialBottom)));
ctIndex++;
memoryTablePtr++;
}
}
while (anyCommit);
//Close the Chunks
memoryTablePtr = (TMemory *) (iThreadData.listPtr);
ctIndex = 0;
while (memoryTablePtr->chunkType != EChunkNone)
{
chunkTable[ctIndex].chunk.Close();
ctIndex++;
memoryTablePtr++;
}
User::After(gPeriod);
}
test.End();
test.Close();
return 0x00;
}
//Device Thread : will do device associated operation
//param aSmp - CSMPSoakUtil pointer
TInt CSMPSoakThread::SMPStressDeviceThread(TAny* aSmp)
{
CSMPSoakThread* self = (CSMPSoakThread*)aSmp;
__ASSERT_ALWAYS(self !=NULL, User::Panic(_L("CSMPSoakThread::SMPStressDeviceThread Panic"),0));
return self->DoSMPStressDeviceThread();
}
// Member for thread function
TInt CSMPSoakThread::DoSMPStressDeviceThread()
{
RTest test(_L("SMPStressDeviceThread"));
test.Start(_L("SMPStressDeviceThread"));
RTimer timer;
RFs session;
TFileName sessionPath;
test_KErrNone(timer.CreateLocal());
TRequestStatus s;
TDesC** ptrDevices = (TDesC**) (iThreadData.listPtr);
PRINT ((_L("Devices Number %d [%s]\n"), ptrDevices[0]->Length(), ptrDevices[0]->Ptr()));
for (TInt i = 1; ptrDevices[i] ; i++)
PRINT ((_L("LDD%d=%s "),i,ptrDevices[i]->Ptr()));
PRINT (_L("\n"));
FOREVER
{
for (TInt i = 0; i < ptrDevices[0]->Length(); i++)
{
TText driveLetter = (*ptrDevices[0])[i];
PRINT ((_L("Device %c\n"),driveLetter));
test_KErrNone(session.Connect());
sessionPath=(_L("?:\\SESSION_TEST\\"));
sessionPath[0]=driveLetter;
test_KErrNone(session.SetSessionPath(sessionPath));
TInt driveNumber;
test_KErrNone(session.CharToDrive(driveLetter, driveNumber));
TBuf<64> fileSystemName;
test_KErrNone(session.FileSystemName(fileSystemName,driveNumber));
PRINT ((_L("File System Name %s\n"),fileSystemName.PtrZ()));
TDriveInfo driveInfo;
test_KErrNone(session.Drive(driveInfo, driveNumber));
TVolumeInfo volumeInfo;
test_KErrNone(session.Volume(volumeInfo, driveNumber));
session.Close();
}
for (TInt i = 1; ptrDevices[i] ; i += 2)
{
RDevice device;
TInt r = User::LoadLogicalDevice(*ptrDevices[i]);
if (r != KErrNone && r != KErrAlreadyExists)
{
test.Printf(_L("LDD %S not present\n"), ptrDevices[i]);
continue;
}
test_KErrNone(device.Open(*ptrDevices[i+1]));
TBuf8<64> deviceCaps;
device.GetCaps(deviceCaps);
TVersion deviceVersion;
device.QueryVersionSupported(deviceVersion);
device.Close();
}
SetThreadPriority();
timer.After(s, iThreadData.delayTime*1000);
User::WaitForRequest(s);
test (s == KErrNone);
if (gAbort)
break;
User::After(gPeriod);
}
timer.Close();
PRINT((_L("SMPStressDeviceThread MyTimer.Cancel() called\n")));
test.End();
test.Close();
return 0x00;
}
//Spin Thread : will do thread sync
//param aSmp - CSMPSoakUtil pointer
TInt CSMPSoakThread::SMPStressSpinThread(TAny* aSmp)
{
CSMPSoakThread* self = (CSMPSoakThread*)aSmp;
__ASSERT_ALWAYS(self !=NULL, User::Panic(_L("CSMPSoakThread::SMPStressSpinThread Panic"),0));
return self->DoSMPStressSpinThread();
}
// Member for thread function
TInt CSMPSoakThread::DoSMPStressSpinThread()
{
RTest test(_L("SMPStressSpinThread"));
test.Start(_L("SMPStressSpinThread"));
TTime startTime;
TTime endTime;
TTimeIntervalMicroSeconds loopTimeMicroSeconds;
PRINT (_L("SMPStressSpinThread\n"));
FOREVER
{
SetThreadPriority();
gSwitchSem.Wait();
startTime.UniversalTime();
do
{
endTime.UniversalTime();
loopTimeMicroSeconds = endTime.MicroSecondsFrom(startTime);
}while (loopTimeMicroSeconds <= iThreadData.delayTime*1000);
if (gAbort)
break;
User::After(gPeriod);
}
test.End();
test.Close();
return 0x00;
}
//Timer Thread : Timer operation and thread sync
//param aSmp - CSMPSoakUtil pointer
TInt CSMPSoakThread::SMPStressTimerThread(TAny* aSmp)
{
CSMPSoakThread* self = (CSMPSoakThread*)aSmp;
__ASSERT_ALWAYS(self !=NULL, User::Panic(_L("CSMPSoakThread::SMPStressTimerThread Panic"),0));
return self->DoSMPStressTimerThread();
}
// Member for thread function
TInt CSMPSoakThread::DoSMPStressTimerThread()
{
RTest test(_L("SMPStressTimerThread"));
test.Start(_L("SMPStressTimerThread"));
PRINT (_L("SMPStressTimerThread\n"));
RTimer timer;
test_KErrNone(timer.CreateLocal());
TRequestStatus s;
FOREVER
{
timer.After(s, iThreadData.delayTime*1000);
User::WaitForRequest(s);
test (s == KErrNone);
PRINT ((_L("*")));
gSwitchSem.Signal(iThreadData.numThreads);
if (gAbort)
break;
User::After(gPeriod);
}
timer.Cancel();
PRINT((_L("SMPStressTimerThread MyTimer.Cancel() called\n")));
test.End();
test.Close();
return 0x00;
}
// CActive class to monitor KeyStrokes from User
class CActiveConsole : public CActive
{
public:
CActiveConsole();
~CActiveConsole();
void GetCharacter();
static TInt Callback(TAny* aCtrl);
static CPeriodic* TimerL();
private:
// Defined as pure virtual by CActive;
// implementation provided by this class.
virtual void DoCancel();
// Defined as pure virtual by CActive;
// implementation provided by this class,
virtual void RunL();
void ProcessKeyPressL(TChar aChar);
private:
};
// Class CActiveConsole
CActiveConsole::CActiveConsole()
: CActive(EPriorityHigh)
{
CActiveScheduler::Add(this);
}
CActiveConsole::~CActiveConsole()
{
Cancel();
}
CPeriodic* CActiveConsole::TimerL()
{
return(CPeriodic::NewL(EPriorityNormal));
}
// Callback function for timer expiry
TInt CActiveConsole::Callback(TAny* aControl)
{
return KErrNone;
}
void CActiveConsole::GetCharacter()
{
test.Console()->Read(iStatus);
SetActive();
}
void CActiveConsole::DoCancel()
{
PRINT(_L("CActiveConsole::DoCancel\n"));
test.Console()->ReadCancel();
}
void CActiveConsole::ProcessKeyPressL(TChar aChar)
{
if (aChar == EKeyEscape)
{
PRINT(_L("CActiveConsole: ESC key pressed -> stopping active scheduler...\n"));
gAbort = ETrue;
CActiveScheduler::Stop();
return;
}
aChar.UpperCase();
GetCharacter();
}
void CActiveConsole::RunL()
{
ProcessKeyPressL(static_cast<TChar>(test.Console()->KeyCode()));
}
// CActiveTimer class to monitor timeout expiry
class CActiveTimer : public CActive
{
public:
CActiveTimer();
~CActiveTimer();
void Delay(TTimeIntervalMicroSeconds32 aDelay);
private:
RTimer iTimer;
// Defined as pure virtual by CActive;
// implementation provided by this class.
virtual void DoCancel();
// Defined as pure virtual by CActive;
// implementation provided by this class,
virtual void RunL();
};
// Class CActiveConsole
CActiveTimer::CActiveTimer()
: CActive(EPriorityHigh)
{
CActiveScheduler::Add(this);
User::LeaveIfError(iTimer.CreateLocal());
}
CActiveTimer::~CActiveTimer()
{
Cancel();
iTimer.Close();
}
void CActiveTimer::Delay(TTimeIntervalMicroSeconds32 aDelay)
{
iTimer.After(iStatus, aDelay);
SetActive();
}
void CActiveTimer::DoCancel()
{
iTimer.Cancel();
}
void CActiveTimer::RunL()
{
PRINT(_L("CActiveTimer: Application runtime expired..."));
gAbort = ETrue;
CActiveScheduler::Stop();
return;
}
//T_SMPSOAK Entry Point
TInt E32Main()
{
test.Title();
__UHEAP_MARK;
test.Start(_L("t_smpsoak.exe"));
// When running as a stand alone test,
// there needs to be a timeout
timeout = ETrue;
ParseCommandLine();
if (gAbort)
return 0x00;
PRINT (_L("Load device driver\n"));
TInt r = User::LoadLogicalDevice(_L("d_smpsoak.ldd"));
if (r == KErrNotFound)
{
PRINT (_L("Test not supported on this platform because the D_SMPSOAK.LDD Driver is Not Present\n"));
test(EFalse);
}
PRINT (_L("Calling SMPStressDrv Open\n"));
r = gSMPStressDrv.Open();
test_KErrNone(r);
PRINT (_L("Creating our local semaphore\n"));
r=gSwitchSem.CreateLocal(0);
test_KErrNone(r);
CSMPSoakThread smpthread;
PRINT ((_L("Creating all threads =%d\n"),KNumThreads));
smpthread.CreateThread();
CSMPSoakThread *smpprocess= new CSMPSoakThread[NumProcess];
PRINT ((_L("Creating all process =%d\n"),NumProcess));
for (TInt i = 0; i < NumProcess; i++)
smpprocess[i].CreateChildProcess(i);
PRINT (_L("Resuming all process \n"));
for (TInt i = 0; i < NumProcess; i++)
smpprocess[i].ResumeChildProcess();
PRINT (_L("Starting ActiveScheduler\n"));
test.Next(_L("Press ESC Key to Shutdown SMPSoak...\n"));
CActiveScheduler* myScheduler = new (ELeave) CActiveScheduler();
test(myScheduler != NULL);
CActiveScheduler::Install(myScheduler);
CPeriodic* theTimer=NULL;
TRAPD(ret,theTimer=CActiveConsole::TimerL())
test_KErrNone(ret);
theTimer->Start(0,KTimerPeriod,TCallBack(CActiveConsole::Callback));
if(timeout)
{
CActiveTimer* myActiveTimer = new CActiveTimer();
test(myActiveTimer != NULL);
myActiveTimer->Delay(gTimeout*1000000);
}
CActiveConsole* myActiveConsole = new CActiveConsole();
test(myActiveConsole != NULL);
myActiveConsole->GetCharacter();
CActiveScheduler::Start();
if (gAbort)
{
PRINT (_L("gAbort TRUE \n"));
for (TInt i = 0; i < NumProcess; i++)
smpprocess[i].TerminateChildProcess();
delete[] smpprocess;
delete theTimer;
gSMPStressDrv.Close();
gSwitchSem.Close();
return 0;
}
__UHEAP_MARKEND;
test.End();
return 0;
}
void ParseCommandLine()
{
TBuf<256> args;
User::CommandLine(args);
TLex lex(args);
PRINT ((_L("****Command line = %s\n"), args.PtrZ()));
FOREVER
{
TPtrC token=lex.NextToken();
if(token.Length()!=0)
{
if (token.Length()==0)
break; // ignore trailing whitespace
else if (token.Mid(0) == _L("-h"))
{
PRINT (_L("T_SMPSOAK.EXE Usage Options:\n"));
PRINT (_L("Type t_smpsoak.exe -h\n"));
ShowHelp();
gAbort = ETrue;
break;
}
else if (token.Mid(0) == _L("-l"))
{
//Read OOM entry from KProcessTable and run
test.Printf(_L("SMPSOAK:lowmem\n"));
NumProcess = KNumProcess+1;
break;
}
else if (token.Mid(0) == _L("-b"))
{
test.Printf(_L("SMPSOAK: Test Silent Mode\n"));
ThreadPriorityLow = ETrue;
TestSilent = ETrue;
// If we have tests running in the background
// we want an endless loop
timeout = EFalse;
break;
}
else if (token.Left(2) == _L("-t"))
{
test.Printf(_L("SMPSOAK:Timeout\n"));
lex.SkipSpaceAndMark();
token.Set(lex.NextToken());
TLex lexNum(token);
lexNum.Val(gTimeout,EDecimal);
test.Printf(_L("Timeout in Seconds=%u \n"),gTimeout);
timeout = ETrue;
break;
}
else if (token.Left(2) == _L("-p"))
{
test.Printf(_L("SMPSOAK:period\n"));
lex.SkipSpaceAndMark();
token.Set(lex.NextToken());
TLex lexNum(token);
lexNum.Val(gPeriod,EDecimal);
test.Printf(_L("period in mSeconds=%d \n"),gPeriod);
Period = ETrue;
break;
}
else
{
test.Printf(_L("Error- Invalid SMPSOAK CMD Line Argument"));
break;
}
}
break;
}
}