Fix for bug 2283 (RVCT 4.0 support is missing from PDK 3.0.h)
Have multiple extension sections in the bld.inf, one for each version
of the compiler. The RVCT version building the tools will build the
runtime libraries for its version, but make sure we extract all the other
versions from zip archives. Also add the archive for RVCT4.
// 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
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;
}