Enhance the base/rom extension to generate the symbol file of the rom built.
The symbol file is placed in epoc32/rom/<baseport_name>, along with the rom log and final oby file.
// 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\emul\t_emul.cpp
// Overview:
// Test the mechanism to escape threads from the emulator in order
// to block on Windows objects
// Test launching processes doesn't leak windows TLS indices
// API Information:
// Emulator
// Details:
// - Test the mechanism to escape threads from the emulator in order
// to block on Windows objects:
// - test escape and re-enter mechanism.
// - block on Windows in EPOC thread and escaped EPOC thread.
// Platforms/Drives/Compatibility:
// All.
// Assumptions/Requirement/Pre-requisites:
// Failures and causes:
// Base Port information:
//
//
#define __E32TEST_EXTENSION__
#include <f32file.h>
#include <e32atomics.h>
#include <e32std.h>
#include <e32std_private.h>
#include <e32ldr.h>
#include <e32ldr_private.h>
#include "e32test.h"
#include "emulator.h"
#include "t_emul.h"
#define WIN32_LEAN_AND_MEAN
#pragma warning( disable : 4201 ) // nonstandard extension used : nameless struct/union
#include <windows.h>
#pragma warning( default : 4201 ) // nonstandard extension used : nameless struct/union
LOCAL_D RTest test(_L("t_emul"));
static TInt ELock;
static HANDLE ESemaphore;
static TInt EResult;
TInt EscapeTimeoutThread(TAny*)
{
User::After(1000000);
if (__e32_atomic_add_ord32(&ELock, 1) == 0)
{
EResult=KErrTimedOut;
ReleaseSemaphore(ESemaphore,1,NULL);
}
return KErrNone;
}
TInt EscapeSignalThread(TAny*)
{
if (__e32_atomic_add_ord32(&ELock, 1) == 0)
{
EResult=KErrNone;
ReleaseSemaphore(ESemaphore,1,NULL);
}
return KErrNone;
}
TInt DoTestEscape(TBool aDoEscape)
//
// Test the mechanism to escape threads from the emulator in order to block on Windows objects
//
{
ELock = 0;
EResult = KRequestPending;
ESemaphore = CreateSemaphoreA(NULL,0,1,NULL);
test (ESemaphore != NULL);
RThread t1,t2;
TRequestStatus s1,s2;
TInt r = t1.Create(KNullDesC,&EscapeSignalThread,0x1000,NULL,NULL);
test (r == KErrNone);
t1.SetPriority(EPriorityLess);
t1.Logon(s1);
t1.Resume();
r = t2.Create(KNullDesC,&EscapeTimeoutThread,0x1000,NULL,NULL);
test (r == KErrNone);
t2.SetPriority(EPriorityMore);
t2.Logon(s2);
t2.Resume();
//
if (aDoEscape)
Emulator::Escape();
r = WaitForSingleObject(ESemaphore,INFINITE);
if (aDoEscape)
Emulator::Reenter();
test (r==WAIT_OBJECT_0);
//
r = EResult;
t1.Kill(0);
t2.Kill(0);
t1.Close();
t2.Close();
User::WaitForRequest(s1);
User::WaitForRequest(s2);
//
CloseHandle(ESemaphore);
return r;
}
void TestEscape()
//
// Test the mechanism to escape threads from the emulator in order to block on Windows objects
//
{
test.Start(_L("Test escape and reenter mechanism"));
for (TInt i = 0;i<10000;++i)
{
Emulator::Escape();
if (i%100 == 0)
Sleep(10);
Emulator::Reenter();
}
test.Next(_L("Block on Windows in EPOC thread"));
TInt r = DoTestEscape(EFalse);
test (r == KErrTimedOut);
test.Next(_L("Block on Windows in escaped EPOC thread"));
r = DoTestEscape(ETrue);
test (r == KErrNone);
test.End();
}
TInt CountRemainingTlsIndicies()
{
const TInt KMax = 2000;
TBool allocated[KMax];
memclr(allocated, sizeof(TBool) * KMax);
TInt i;
for (i = 0 ; i < KMax ; ++i)
{
TInt index = TlsAlloc();
if (index == TLS_OUT_OF_INDEXES)
break;
test(index >= 0 && index < KMax);
allocated[index] = ETrue;
}
for (TInt j = 0 ; j < KMax ; ++j)
{
if (allocated[j])
test(TlsFree(j));
}
return i;
}
void RunSlave(TSlaveAction aAction)
{
RProcess p;
TBuf<8> arg;
arg.Format(_L("%d"), aAction);
test_KErrNone(p.Create(KTEmulSlaveName, arg));
p.Resume();
TRequestStatus status;
p.Logon(status);
User::WaitForRequest(status);
test_KErrNone(status.Int());
test_Equal(EExitKill, p.ExitType());
p.Close();
}
void TestRuntimeCleanup()
{
test.Start(_L("Test Codewarrior runtime library is correctly cleaned up"));
TInt initIndicies = CountRemainingTlsIndicies();
test.Next(_L("Test creating a process doesn't leak windows TLS indicies"));
RunSlave(ESlaveDoNothing);
test_Equal(initIndicies, CountRemainingTlsIndicies());
test.Next(_L("Test leaving in an exe doesn't leak windows TLS indicies"));
RunSlave(ESlaveTrapExceptionInExe);
test_Equal(initIndicies, CountRemainingTlsIndicies());
test.Next(_L("Test leaving in a linked DLL doesn't leak windows TLS indicies"));
RunSlave(ESlaveTrapExceptionInLinkedDll);
test_Equal(initIndicies, CountRemainingTlsIndicies());
test.Next(_L("Test leaving in a loaded DLL doesn't leak windows TLS indicies"));
RunSlave(ESlaveTrapExceptionInLoadedDll);
test_Equal(initIndicies, CountRemainingTlsIndicies());
test.Next(_L("Test cleanup doesn't happen while DLL still loaded"));
RLibrary l;
test_KErrNone(l.Load(KTEmulDll2Name));
RunSlave(ESlaveTrapExceptionInLoadedDll);
TInt midCount = CountRemainingTlsIndicies();
test(initIndicies > midCount);
test.Next(_L("Test previous detach doesn't cause runtime to be re-initalised"));
TTrapExceptionInDllFunc func =
(TTrapExceptionInDllFunc)l.Lookup(KTrapExceptionInDllOrdinal);
test_NotNull(func);
func();
test_Equal(midCount, CountRemainingTlsIndicies());
l.Close();
test_Equal(initIndicies, CountRemainingTlsIndicies());
test.End();
}
void DoSomething2L()
{
test.Printf(_L("@\n"));
}
void DoSomething1L()
{
TInt i = -1, j = 1;
for ( ; ; )
{
i++;
//DoSomething2L() must only be called once , else we know that trap mechanism didn't work
test( i<2);
if (i == j)
{
User::Leave(KErrNotFound);
}
TRAP_IGNORE(DoSomething2L());
TRAPD(errr, DoSomething2L());
TInt r;
TRAP(r, DoSomething2L());
}
}
void LeaveIfArgIsTwo(TInt aCall);
class CFred : public CBase
{
public:
static CFred* NewLC();
CFred();
~CFred();
};
void DoSomething3L()
{
// Push something on the cleanup stack so we can see whyen it gets cleaned up.
CFred *fred = CFred::NewLC();
TInt beforeFunc=0;
TInt betweenFuncAndTRAPD=0;
TInt afterTRAPD=0;
for(TInt loop=1; loop<=2; ++loop)
{
++beforeFunc;
test.Printf(_L("Before LeaveIfArgIsTwo()\n"));
// The first time around the loop, this function call works.
// The second time, it leaves KErrGeneral
// Then when TRAP mechanism isn't working properly the emulator (correctly)
// would delete fred, and (incorrectly) jump to the line
// just after the TRAPD call a few lines further down the file!
LeaveIfArgIsTwo(loop);
++betweenFuncAndTRAPD;
test.Printf(_L("Between LeaveIfArgIsTwo() and TRAPD\n"));
TRAPD(err, test.Printf(_L("Inside TRAPD\n") ) );
// It should only be possible to reach this section of code by executing all the lines
// between LeaveIfArgIsTwo and here.
++afterTRAPD;
}
// Should NEVER get here because LeaveIfArgIsTwo did a leave the second time around the loop
test.Printf(_L("After loop (should NEVER get here) -\n\
beforeFunc %d\n\
betweenFuncAndTRAPD %d\n\
afterTRAPD %d\n"),
beforeFunc, betweenFuncAndTRAPD, afterTRAPD);
test.Printf(_L("It should be impossible for afterTRAPD to be larger than betweenFuncAndTRAPD\n"));
test(afterTRAPD <= betweenFuncAndTRAPD);
// Cleanup our cleanup stack.
CleanupStack::PopAndDestroy(&fred);
}
void LeaveIfArgIsTwo(TInt aCall)
{
test.Printf(_L("aCall %d\n"), aCall);
if(aCall == 2)
{
User::Leave(KErrGeneral);
}
}
CFred *CFred::NewLC()
{
CFred *self = new(ELeave) CFred;
CleanupStack::PushL(self);
return self;
}
CFred::CFred()
{
test.Printf(_L("CFred %x\n"), this);
}
CFred::~CFred()
{
test.Printf(_L("~CFred %x\n"), this);
}
GLDEF_C TInt E32Main()
//
//
//
{
test.Title();
test.Start(_L("Starting tests ..."));
// Turn off evil lazy dll unloading
RLoader l;
test(l.Connect()==KErrNone);
test(l.CancelLazyDllUnload()==KErrNone);
l.Close();
TestEscape();
#ifdef __CW32__
TestRuntimeCleanup();
#endif
// The following tests were added to test that the TRAP mechanism works correctly in case of
// nested TRAP's. A compiler bug (winscw) caused the following tests to fail, since the wrong
// trap handler would be invoked, when User::Leave() was called.
test.Next(_L("Check User::Leave is handled by the correct TRAP handler when nested TRAPs are present - Simple scenario\n"));
TRAPD(err, DoSomething1L());
test(err == KErrNotFound);
test.Next(_L("Check User::Leave is handled by the correct TRAP handler when nested TRAPs are present - Cleanup stack scenario\n"));
__UHEAP_MARK;
CTrapCleanup* tc = CTrapCleanup::New();
if (tc == 0) return KErrNoMemory;
TRAPD(err2, DoSomething3L());
test(err2==KErrGeneral);
delete tc;
__UHEAP_MARKEND;
test.End();
test.Close();
return KErrNone;
}