// Copyright (c) 1995-2009 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\misc\t_svr3.cpp
//
//
#define __E32TEST_EXTENSION__
#include <e32base.h>
#include <e32base_private.h>
#include <e32test.h>
#include <e32svr.h>
#include "u32std.h"
#include "../misc/prbs.h"
#include "../mmu/freeram.h"
const TInt KStackSize=0x1000;
const TInt KHeapMaxSize=0x100000;
const TInt KMajorVersionNumber=1;
const TInt KMinorVersionNumber=0;
const TInt KBuildVersionNumber=1;
const TInt KNumMessageSlots=20;
_LIT(KServerName,"StressSvr");
LOCAL_D RTest test(_L("T_SVR3"));
class CMySession : public CSession2
{
public:
CMySession();
virtual void ServiceL(const RMessage2& aMessage); //pure virtual fns.
void Process(const RMessage2& aMessage);
public:
TInt iOutstanding;
TUint iSeed[2];
};
class CMyServer : public CServer2
{
public:
enum {ETest};
public:
CMyServer(TInt aPriority);
static CMyServer* New(TInt aPriority);
virtual CSession2* NewSessionL(const TVersion& aVersion, const RMessage2& aMessage) const;//Overloading
};
class CMyActiveScheduler : public CActiveScheduler
{
public:
virtual void Error(TInt anError) const; //Overloading pure virtual function
};
class RStressSvr : public RSessionBase
{
public:
TInt Connect();
TInt Test();
void Test(TRequestStatus& aStatus);
TVersion Version();
};
class CThread : public CActive
{
public:
CThread(TInt aPriority);
~CThread();
virtual void RunL();
virtual void DoCancel();
virtual void DisplayStats()=0;
TInt Start();
public:
virtual TInt StartThread()=0;
public:
RThread iThread;
TInt iExitCount;
TInt iServerTerminatedCount;
TInt iTerminateCount;
};
class CServerThread : public CThread
{
public:
static void NewL();
CServerThread();
virtual TInt StartThread();
virtual void DisplayStats();
public:
TInt iMessagesReceived;
};
class CClientThread : public CThread
{
public:
static void NewL(TInt anId);
CClientThread(TInt anId);
virtual TInt StartThread();
virtual void DisplayStats();
public:
TInt iId;
TInt iCloses;
};
class CRandomTimer : public CActive
{
public:
static void NewL();
CRandomTimer(TInt aPriority);
~CRandomTimer();
virtual void RunL();
virtual void DoCancel();
void Start();
public:
RTimer iTimer;
TUint iSeed[2];
TInt iCount;
};
class CStatsTimer : public CActive
{
public:
static void NewL();
CStatsTimer(TInt aPriority);
~CStatsTimer();
virtual void RunL();
virtual void DoCancel();
void Start();
public:
RTimer iTimer;
TInt iInitFreeRam;
TInt iMaxDelta;
TInt iCount;
};
const TInt KNumClients=3;
LOCAL_D CServerThread* TheServer;
LOCAL_D CClientThread* TheClients[KNumClients];
LOCAL_D CRandomTimer* TheRandomTimer;
CMySession::CMySession()
//
// Constructor
//
{
iSeed[0]=User::TickCount();
}
CMyServer* CMyServer::New(TInt aPriority)
//
// Create a new CMyServer.
//
{
return new CMyServer(aPriority);
}
CMyServer::CMyServer(TInt aPriority)
//
// Constructor.
//
: CServer2(aPriority)
{}
CSession2* CMyServer::NewSessionL(const TVersion& aVersion, const RMessage2&) const
//
// Create a new client for this server.
//
{
TVersion v(KMajorVersionNumber,KMinorVersionNumber,KBuildVersionNumber);
if (!User::QueryVersionSupported(v,aVersion))
User::Leave(KErrNotSupported);
return new(ELeave) CMySession;
}
void CMySession::ServiceL(const RMessage2& aMessage)
//
// Handle messages for this server.
//
{
++TheServer->iMessagesReceived;
switch (aMessage.Function())
{
case CMyServer::ETest:
if (iOutstanding==KNumMessageSlots-1)
Process(aMessage);
else
++iOutstanding;
break;
default:
aMessage.Complete(KErrNotSupported);
break;
}
}
void CMySession::Process(const RMessage2& aMessage)
{
TUint x=Random(iSeed)&16383;
if (x==0)
User::Exit(0); // exit the server
else if (x<8)
aMessage.Terminate(0); // terminate the client
else
aMessage.Complete(KErrNone);
}
void CMyActiveScheduler::Error(TInt anError) const
//
// Called if any Run() method leaves.
//
{
User::Panic(_L("Server Error"),anError);
}
TInt RStressSvr::Connect()
//
// Connect to the server
//
{
return CreateSession(KServerName,Version(),KNumMessageSlots);
}
TInt RStressSvr::Test()
//
// Send a message and wait for completion.
//
{
return SendReceive(CMyServer::ETest);
}
void RStressSvr::Test(TRequestStatus& aStatus)
//
// Send a message asynchronously
//
{
SendReceive(CMyServer::ETest,aStatus);
}
TVersion RStressSvr::Version()
//
// Return the current version.
//
{
TVersion v(KMajorVersionNumber,KMinorVersionNumber,KBuildVersionNumber);
return(v);
}
LOCAL_C TInt ServerThread(TAny*)
{
CMyActiveScheduler* pR=new CMyActiveScheduler;
if (!pR)
return KErrNoMemory;
CActiveScheduler::Install(pR);
CMyServer* pS=CMyServer::New(0);
if (!pS)
return KErrNoMemory;
TInt r=pS->Start(KServerName);
if (r!=KErrNone)
return r;
CActiveScheduler::Start();
delete pS;
delete pR;
return KErrNone;
}
LOCAL_C TInt ClientThread(TAny* aPtr)
{
CClientThread* pT=(CClientThread*)aPtr;
RStressSvr d;
TUint seed[2];
seed[0]=User::TickCount();
seed[1]=0;
FOREVER
{
TInt r;
FOREVER
{
r=d.Connect();
if (r!=KErrNotFound)
break;
User::After(50000);
}
if (r!=KErrNone)
return r;
TRequestStatus s[KNumMessageSlots];
TInt i;
for (i=0; i<KNumMessageSlots-1; i++)
d.Test(s[i]);
TInt n=Random(seed)&16383;
for (i=0; i<n; i++)
d.Test();
d.Close();
++pT->iCloses;
}
}
CThread::CThread(TInt aPriority)
: CActive(aPriority)
{
}
CThread::~CThread()
{
Cancel();
iThread.Kill(0);
iThread.Close();
}
void CThread::RunL()
{
TExitType exitType=iThread.ExitType();
TInt exitReason=iThread.ExitReason();
TBuf<32> exitCat=iThread.ExitCategory();
TBool bad=EFalse;
if (exitType==EExitKill)
{
if (exitReason!=KErrNone && exitReason!=KErrServerTerminated)
bad=ETrue;
}
else if (exitType==EExitPanic)
bad=ETrue;
if (bad)
{
TFullName n(iThread.FullName());
test.Printf(_L("Thread %S exited %d,%d,%S\n"),&n,exitType,exitReason,&exitCat);
CActiveScheduler::Stop();
return;
}
iThread.Close();
if (exitType==EExitTerminate)
++iTerminateCount;
else if (exitReason==KErrNone)
++iExitCount;
else if (exitReason==KErrServerTerminated)
++iServerTerminatedCount;
TInt r=Start();
if (r!=KErrNone)
{
test.Printf(_L("Start thread error %d\n"),r);
CActiveScheduler::Stop();
}
}
void CThread::DoCancel()
{
iThread.LogonCancel(iStatus);
}
TInt CThread::Start()
{
TInt r;
FOREVER
{
r=StartThread();
if (r==KErrNone)
break;
if (r!=KErrAlreadyExists)
break;
User::After(100000);
}
if (r==KErrNone)
{
iThread.Logon(iStatus);
SetActive();
}
return r;
}
CServerThread::CServerThread()
: CThread(0)
{
}
TInt CServerThread::StartThread()
{
TUint seed[2];
seed[1]=0;
seed[0]=User::TickCount();
TInt heapMin=TInt(Random(seed)&0x0f)+1;
heapMin<<=12;
TInt r=iThread.Create(KNullDesC(),ServerThread,KStackSize,heapMin,KHeapMaxSize,this); // use unnamed thread
if (r!=KErrNone)
return r;
iThread.Resume();
return KErrNone;
}
void CServerThread::NewL()
{
CServerThread* pT=new (ELeave) CServerThread;
TheServer=pT;
CActiveScheduler::Add(pT);
User::LeaveIfError(pT->Start());
}
void CServerThread::DisplayStats()
{
test.Printf(_L("Svr : X:%9d ST:%9d T:%9d RX:%9d\n"),iExitCount,iServerTerminatedCount,iTerminateCount,iMessagesReceived);
}
CClientThread::CClientThread(TInt anId)
: CThread(0), iId(anId)
{
}
TInt CClientThread::StartThread()
{
TInt r=iThread.Create(KNullDesC(),ClientThread,KStackSize,NULL,this); // use unnamed thread
if (r!=KErrNone)
return r;
iThread.Resume();
return KErrNone;
}
void CClientThread::NewL(TInt anId)
{
CClientThread* pT=new (ELeave) CClientThread(anId);
TheClients[anId]=pT;
CActiveScheduler::Add(pT);
User::LeaveIfError(pT->Start());
}
void CClientThread::DisplayStats()
{
test.Printf(_L("Cli %1d: X:%9d ST:%9d T:%9d CL:%9d\n"),iId,iExitCount,iServerTerminatedCount,iTerminateCount,iCloses);
}
void CRandomTimer::NewL()
{
CRandomTimer* pR=new (ELeave) CRandomTimer(20);
User::LeaveIfError(pR->iTimer.CreateLocal());
CActiveScheduler::Add(pR);
TheRandomTimer=pR;
pR->Start();
}
CRandomTimer::CRandomTimer(TInt aPriority)
: CActive(aPriority)
{
iSeed[0]=User::TickCount();
}
CRandomTimer::~CRandomTimer()
{
Cancel();
iTimer.Close();
}
void CRandomTimer::RunL()
{
++iCount;
TUint x=Random(iSeed)&3;
CThread* pT;
if (x==0)
pT=TheServer;
else
pT=TheClients[x-1];
pT->iThread.Kill(0);
Start();
}
void CRandomTimer::Start()
{
TUint x=Random(iSeed)&63;
x+=32;
iTimer.HighRes(iStatus, x*1000);
SetActive();
}
void CRandomTimer::DoCancel()
{
iTimer.Cancel();
}
void CStatsTimer::NewL()
{
CStatsTimer* pT=new (ELeave) CStatsTimer(-10);
User::LeaveIfError(pT->iTimer.CreateLocal());
CActiveScheduler::Add(pT);
pT->Start();
}
CStatsTimer::CStatsTimer(TInt aPriority)
: CActive(aPriority)
{
iInitFreeRam = FreeRam();
}
CStatsTimer::~CStatsTimer()
{
Cancel();
iTimer.Close();
}
void CStatsTimer::RunL()
{
TheServer->DisplayStats();
TInt i;
for (i=0; i<KNumClients; i++)
TheClients[i]->DisplayStats();
test.Printf(_L("RndTm: %9d\n"),TheRandomTimer->iCount);
TInt free_ram = FreeRam();
TInt delta_ram = iInitFreeRam - free_ram;
if (delta_ram > iMaxDelta)
iMaxDelta = delta_ram;
if (++iCount==10)
{
test.Printf(_L("Max RAM delta %dK Free RAM %08x\n"), iMaxDelta/1024, free_ram);
iCount=0;
}
Start();
}
void CStatsTimer::Start()
{
iTimer.After(iStatus, 1000000);
SetActive();
}
void CStatsTimer::DoCancel()
{
iTimer.Cancel();
}
void InitialiseL()
{
CActiveScheduler* pA=new (ELeave) CActiveScheduler;
CActiveScheduler::Install(pA);
CServerThread::NewL();
TInt id;
for (id=0; id<KNumClients; id++)
CClientThread::NewL(id);
CRandomTimer::NewL();
CStatsTimer::NewL();
}
GLDEF_C TInt E32Main()
//
// Test timers.
//
{
test.Title();
RThread().SetPriority(EPriorityMore);
TRAPD(r,InitialiseL());
test(r==KErrNone);
CActiveScheduler::Start();
test(0);
return(0);
}
// Override heap creation for this process
// This function runs at the beginning of every thread
// Initial heap is shared but subsequent heaps are single threaded
EXPORT_C TInt UserHeap::SetupThreadHeap(TBool aNotFirst, SStdEpocThreadCreateInfo& aInfo)
{
TInt r = KErrNone;
if (!aInfo.iAllocator && aInfo.iHeapInitialSize>0)
{
// new heap required
RHeap* pH = NULL;
r = CreateThreadHeap(aInfo, pH, 0, aNotFirst);
}
else if (aInfo.iAllocator)
{
// sharing a heap
RAllocator* pA = aInfo.iAllocator;
pA->Open();
User::SwitchAllocator(pA);
}
return r;
}