// 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\heap\t_heapdb.cpp
// Tests the _DEBUG build dependent aspects of RHeap
// Overview:
// Tests debug build dependent aspects of RHeap.
// API Information:
// RHeap.
// Details:
// Test1:
// - Allocate a variety of user heap objects and verify the nesting level, allocation count,
// allocation level and length are correct. Also check for heap corruption.
// Test 2:
// - Some assorted indirect calls to alloc, and verify the nesting level, allocation count,
// allocation level and length are correct. Also check for heap corruption.
// Test3:
// - Allocate a variety of objects and verify that the UHEAP_CHECKALL count is correct.
// - Verify the nesting of UHEAP_MARK and UHEAP_MARKEND macros.
// - Check the validity of the current thread's default heap.
// Test4:
// - Allocate memory for different heaps, check the total number of allocated cells
// for different heaps and for the current nested level is as expected.
// Test5:
// - Simulate heap allocation failures, allocate the memory from user and
// kernel heap and check results are as expected.
// Platforms/Drives/Compatibility:
// All
// Assumptions/Requirement/Pre-requisites:
// Failures and causes:
// Base Port information:
//
//
#include <e32test.h>
#include <e32def.h>
#include <e32def_private.h>
LOCAL_D RTest test(_L("T_HEAPDB"));
#if defined(_DEBUG)
RHeap::SHeapCellInfo CellInfo[4];
class RTestHeap : public RHeap
{
public:
void AttachInfo(SHeapCellInfo* aInfo)
{iTestData = aInfo;}
};
void AttachToHeap(RHeap* aHeap, TInt aInfo)
{
if (!aHeap)
aHeap = (RHeap*)&User::Allocator();
((RTestHeap*)aHeap)->AttachInfo(CellInfo + aInfo);
}
void TestCellInfo(TInt aInfo, TInt aNest, TInt aAllocCount, TInt aLevelAlloc, TInt aSize, TAny* aAddr)
{
RHeap::SHeapCellInfo& ci = CellInfo[aInfo];
RHeap::SDebugCell& cell = *ci.iStranded;
test(cell.nestingLevel == aNest);
test(cell.allocCount == aAllocCount);
test(ci.iLevelAlloc == aLevelAlloc);
test(cell.len == aSize + RHeap::EAllocCellSize);
test((&cell+1) == aAddr);
}
const TInt KMaxFailureRate=100;
const TInt KThreadMemError=-50;
const TInt KCellSize=(sizeof(RHeap::SCell)); // Size of free cell header
const TInt KHeadSize=(sizeof(RHeap::SDebugCell)); // Size of allocated cell header with space for heaven info
LOCAL_D TInt heapCount=1;
LOCAL_D RSemaphore threadSemaphore;
LOCAL_D TBool array1[KMaxFailureRate+1];
LOCAL_D TBool array2[KMaxFailureRate+1];
LOCAL_C TInt ThreadEntryPoint(TAny*)
{
threadSemaphore.Wait();
if (User::Alloc(4)==NULL)
return(KThreadMemError);
else
return(KErrNone);
}
class TestRHeapDebug
{
public:
void Test1(void);
void Test2(void);
void Test3(void);
void Test4(void);
void Test5(void);
};
LOCAL_C RHeap* allocHeap(TInt aSize)
//
// Allocate a chunk heap with max size aSize
//
{
TName n;
n.Format(_L("TESTHEAP%d"),heapCount++);
return(User::ChunkHeap(&n,aSize,aSize));
}
void TestRHeapDebug::Test1(void)
{
TAny* p;
///////////////////////
// Test heaven cell is found for each method of allocating memory
////////////////////////
// new(TInt aSize)
__UHEAP_MARK;
__UHEAP_CHECKALL(0);
__UHEAP_CHECK(0);
p=new TUint;
__UHEAP_CHECKALL(1);
__UHEAP_CHECK(1);
__UHEAP_MARKEND;
__UHEAP_CHECK(0);
__UHEAP_CHECKALL(1);
TestCellInfo(0, 1, 1, 1, User::AllocLen(p), p);
User::Free(p);
// new(TInt aSize,TInt anExtraSize)
__UHEAP_MARK;
p=new(4) TUint;
__UHEAP_MARKEND;
TestCellInfo(0, 1, 1, 1, User::AllocLen(p), p);
User::Free(p);
// new(TInt aSize,TLeave)
__UHEAP_MARK;
p=new(ELeave) TUint;
__UHEAP_MARKEND;
TestCellInfo(0, 1, 1, 1, User::AllocLen(p), p);
User::Free(p);
// Alloc
__UHEAP_MARK;
p=User::Alloc(32);
__UHEAP_MARKEND;
TestCellInfo(0, 1, 1, 1, User::AllocLen(p), p);
User::Free(p);
// AllocL
__UHEAP_MARK;
p=User::AllocL(32);
__UHEAP_MARKEND;
TestCellInfo(0, 1, 1, 1, User::AllocLen(p), p);
User::Free(p);
// ReAlloc with Null parameter
__UHEAP_MARK;
p=User::ReAlloc(NULL, 32);
__UHEAP_MARKEND;
TestCellInfo(0, 1, 1, 1, User::AllocLen(p), p);
User::Free(p);
// ReAllocL with Null parameter
__UHEAP_MARK;
p=User::ReAllocL(NULL, 32);
__UHEAP_MARKEND;
TestCellInfo(0, 1, 1, 1, User::AllocLen(p), p);
User::Free(p);
// ReAlloc with non Null parameter
__UHEAP_MARK;
p=User::Alloc(128);
p=User::ReAlloc(p, 4);
__UHEAP_MARKEND;
TestCellInfo(0, 1, 1, 1, User::AllocLen(p), p);
User::Free(p);
// ReAlloc with non Null parameter such that cell is moved in memory
__UHEAP_MARK;
p=User::Alloc(128);
TAny* temp=User::Alloc(128);
p=User::ReAlloc(p, 526);
User::Free(temp);
__UHEAP_MARKEND;
TestCellInfo(0, 1, 3, 1, User::AllocLen(p), p);
User::Free(p);
// ReAllocL with non Null parameter
__UHEAP_MARK;
p=User::Alloc(32);
p=User::ReAllocL(p, 128);
__UHEAP_MARKEND;
TestCellInfo(0, 1, 1, 1, User::AllocLen(p), p);
User::Free(p);
}
void TestRHeapDebug::Test2(void)
{
// Some assorted indirect calls to alloc
__UHEAP_MARK;
CBufFlat* pBuf=CBufFlat::NewL(10);
__UHEAP_MARKEND;
TestCellInfo(0, 1, 1, 1, User::AllocLen(pBuf), pBuf);
delete pBuf;
__UHEAP_MARK;
HBufC8* pHBufC=HBufC8::New(10);
__UHEAP_MARKEND;
TestCellInfo(0, 1, 1, 1, User::AllocLen(pHBufC), pHBufC);
delete pHBufC;
// can also create a HBufC8 from a descriptor by using TDesC::Alloc
}
void TestRHeapDebug::Test3(void)
{
// Check num of cells detected is correct and CHECKTOTALNUM is ok
// NOTE: CHECKTOTALNUM counts the TOTAL number of allocations in the heap regardless of
// any MARKSTARTs
// NOTE: the alloc count commences from the FIRST occurrence of a MARKSTART, so if one is nested
// in another the alloc count will only start from the second MARKSTART if it applies to a
// different heap.
__UHEAP_MARK;
__UHEAP_CHECKALL(0);
TAny* p1= new TUint;
__UHEAP_CHECKALL(1);
TAny* p2= new(20) TUint;
__UHEAP_CHECKALL(2);
TAny* p3= User::Alloc(15);
__UHEAP_CHECKALL(3);
__UHEAP_MARK;
__UHEAP_CHECK(0);
TAny* p4=User::Alloc(1);
TAny* p5 =new TUint;
__UHEAP_CHECK(2);
__UHEAP_CHECKALL(5);
__UHEAP_MARKEND;
TestCellInfo(0, 2, 4, 2, User::AllocLen(p4), p4);
__UHEAP_CHECKALL(5);
__UHEAP_CHECK(3);
__UHEAP_MARKENDC(3);
User::Free(p1);
User::Free(p2);
User::Free(p3);
User::Free(p4);
User::Free(p5);
// Check some nesting out
p1=new TUint;
__UHEAP_MARK;
p2=new TUint;
__UHEAP_MARK;
p3=new TUint;
__UHEAP_MARK;
p4=new TUint;
__UHEAP_MARKEND;
TestCellInfo(0, 3, 3, 1, User::AllocLen(p4), p4);
__UHEAP_MARKEND;
TestCellInfo(0, 2, 2, 1, User::AllocLen(p3), p3);
__UHEAP_MARKEND;
TestCellInfo(0, 1, 1, 1, User::AllocLen(p2), p2);
User::Free(p1);
User::Free(p2);
User::Free(p3);
User::Free(p4);
User::Check();
}
void TestRHeapDebug::Test4(void)
{
// Test with different heaps
TAny* p1=new TUint;
__UHEAP_MARK; // Default start
__UHEAP_CHECKALL(1);
__UHEAP_CHECK(0);
TAny* p2=new TUint;
RHeap* pHeap1=allocHeap(1000);
AttachToHeap(pHeap1,1);
__RHEAP_MARK(pHeap1); // Heap1 start
__RHEAP_CHECKALL(pHeap1,0);
__RHEAP_CHECK(pHeap1,0);
TAny* p3=pHeap1->Alloc(4);
__RHEAP_CHECKALL(pHeap1,1);
__RHEAP_CHECK(pHeap1,1);
__RHEAP_CHECKALL(pHeap1,1);
__UHEAP_CHECKALL(3);
RHeap* pHeap2=allocHeap(1000);
AttachToHeap(pHeap2,2);
RHeap* pHeap3=allocHeap(1000);
AttachToHeap(pHeap3,3);
__UHEAP_CHECKALL(5);
__RHEAP_MARK(pHeap2); // Heap2 start
__RHEAP_MARK(pHeap3); // Heap3 start
TAny* p4=pHeap2->Alloc(8);
TAny* p5=pHeap2->Alloc(37);
TAny* p6=pHeap3->Alloc(32);
TAny* p7=pHeap1->Alloc(43);
__UHEAP_CHECKALL(5);
__RHEAP_CHECKALL(pHeap1,2);
__RHEAP_CHECKALL(pHeap2,2);
__RHEAP_CHECKALL(pHeap3,1);
__RHEAP_MARKEND(pHeap3); // Heap3 end
TestCellInfo(3, 1, 1, 1, pHeap3->AllocLen(p6), p6);
__RHEAP_MARKEND(pHeap2); // Heap2 end
TestCellInfo(2, 1, 1, 2, pHeap2->AllocLen(p4), p4);
pHeap1->Free(p3);
__RHEAP_MARKEND(pHeap1); // Heap1 end
TestCellInfo(1, 1, 2, 1, pHeap1->AllocLen(p7), p7);
User::Free(p1);
User::Free(p2);
pHeap2->Free(p4);
pHeap2->Free(p5);
pHeap3->Free(p6);
pHeap1->Free(p7);
__UHEAP_CHECKALL(3);
pHeap2->Close();
pHeap3->Close();
__UHEAP_MARKEND;
pHeap1->Close();
__UHEAP_CHECKALL(0);
}
void TestRHeapDebug::Test5()
// Check the alloc failure macros
{
TAny *p, *p1;
RHeap* pHeap=allocHeap(1000);
// DETERMINISTIC FAILURE
__UHEAP_RESET;
__UHEAP_FAILNEXT(1);
test(User::Alloc(1)==NULL);
p=User::Alloc(1);
test(p!=NULL);
User::FreeZ(p);
__UHEAP_RESET;
__RHEAP_RESET(pHeap);
__RHEAP_FAILNEXT(pHeap,1);
test(pHeap->Alloc(1)==NULL);
p=pHeap->Alloc(1);
test(p!=NULL);
pHeap->FreeZ(p);
__RHEAP_RESET(pHeap);
__KHEAP_RESET;
__KHEAP_FAILNEXT(1);
RSemaphore semaphore;
test(semaphore.CreateLocal(1)==KErrNoMemory); // allocated from the kernel heap
test(semaphore.CreateLocal(1)==KErrNone);
semaphore.Close();
__KHEAP_RESET;
__UHEAP_SETFAIL(RHeap::EDeterministic,0);
test(User::Alloc(1)==NULL);
__UHEAP_RESET;
__RHEAP_SETFAIL(pHeap,RHeap::EDeterministic,0);
test(pHeap->Alloc(1)==NULL);
__RHEAP_RESET(pHeap);
__KHEAP_SETFAIL(RHeap::EDeterministic,0);
test(semaphore.CreateLocal(1)==KErrNoMemory);
__KHEAP_RESET;
TInt determinism;
for(determinism=1; determinism<=KMaxFailureRate; determinism++)
{
__UHEAP_SETFAIL(RHeap::EDeterministic,determinism);
__RHEAP_SETFAIL(pHeap,RHeap::EDeterministic,determinism);
for(TInt ii=1; ii<=determinism; ii++)
{
p=User::Alloc(1);
p1=pHeap->Alloc(1);
if(ii%determinism==0)
{
test(p==NULL);
test(p1==NULL);
}
else
{
test(p!=NULL);
test(p1!=NULL);
pHeap->Free(p1);
User::Free(p);
}
}
}
__UHEAP_RESET;
__RHEAP_RESET(pHeap);
// Test SetKernelAllocFail
// its not possible to test SetKernelAllocFail as above as it is not possible to control the
// number of calls to Alloc for the dernel heap - but the following will definitely fail:
__KHEAP_SETFAIL(RHeap::EDeterministic,1);
RSemaphore r;
test(r.CreateLocal(1)==KErrNoMemory); // allocated from the kernel heap
__KHEAP_SETFAIL(RHeap::EDeterministic,50);
test(r.CreateLocal(1)==KErrNone);
r.Close();
__KHEAP_RESET;
// RANDOM TESTS
TInt numOccurences1, numOccurences2;
__UHEAP_SETFAIL(RHeap::ERandom,1);
test(User::Alloc(1)==NULL);
__UHEAP_RESET;
__RHEAP_SETFAIL(pHeap,RHeap::ERandom,1);
test(pHeap->Alloc(1)==NULL);
__RHEAP_RESET(pHeap);
// __KHEAP_SETFAIL(RHeap::ERandom,1);
// test(semaphore.CreateLocal(1)==KErrNoMemory);
// __KHEAP_RESET;
__UHEAP_SETFAIL(RHeap::ETrueRandom,1);
test(User::Alloc(1)==NULL);
__UHEAP_RESET;
__RHEAP_SETFAIL(pHeap,RHeap::ETrueRandom,1);
test(pHeap->Alloc(1)==NULL);
__RHEAP_RESET(pHeap);
// __KHEAP_SETFAIL(RHeap::ETrueRandom,1);
// test(semaphore.CreateLocal(1)==KErrNoMemory);
// __KHEAP_RESET;
for(determinism=1; determinism<=KMaxFailureRate; determinism++)
{
__UHEAP_SETFAIL(RHeap::ERandom,determinism);
__RHEAP_SETFAIL(pHeap,RHeap::ERandom,determinism);
TInt ii;
for(ii=1; ii<=determinism; ii++)
{
p=User::Alloc(1);
p1=pHeap->Alloc(1);
array1[ii]=(p==NULL);
array2[ii]=(p==NULL);
if(p)
User::Free(p);
if(p1)
pHeap->Free(p1);
}
numOccurences1=0;
numOccurences2=0;
for(ii=1; ii<=determinism; ii++)
{
if(array1[ii])
numOccurences1++;
if(array2[ii])
numOccurences2++;
}
test(numOccurences1==1);
test(numOccurences2==1);
}
__UHEAP_RESET;
__RHEAP_RESET(pHeap);
__UHEAP_SETFAIL(RHeap::ERandom,5);
TInt ii;
for(ii=1; ii<=50; ii++)
{
p=User::Alloc(1);
array1[ii]=(p==NULL);
if(p)
User::Free(p);
}
numOccurences1=0;
numOccurences2=0;
for(ii=1; ii<=50; ii++)
{
if(array1[ii])
{
numOccurences1++;
numOccurences2++;
}
if(ii%5==0)
{
test(numOccurences1==1);
numOccurences1=0;
}
}
test(numOccurences2==50/5);
// Cannot really test random failure of the kernel heap accurately
pHeap->Close();
//client.Disconnect();
// Test failing the heap of a child thread
// 1st test that it allocates normally
TRequestStatus stat;
RThread thread;
test(threadSemaphore.CreateLocal(0)==KErrNone);
test(thread.Create(_L("Thread"),ThreadEntryPoint,KDefaultStackSize,0x200,0x200,NULL)==KErrNone);
thread.Logon(stat);
thread.Resume();
threadSemaphore.Signal();
User::WaitForRequest(stat);
test(thread.ExitReason()==KErrNone);
thread.Close();
#if defined(CAN_TEST_THREADS)
// Now make the thread's heap fail
test(thread.Create(_L("Thread"),ThreadEntryPoint,KDefaultStackSize,0x200,0x200,NULL)==KErrNone);
thread.Logon(stat);
thread.Resume();
TH_FAILNEXT(thread.Handle());
threadSemaphore.Signal();
User::WaitForRequest(stat);
test(thread.ExitReason()==KThreadMemError);
thread.Close();
threadSemaphore.Close();
#endif
}
GLDEF_C TInt E32Main(void)
{
test.Title();
AttachToHeap(NULL,0);
test.Start(_L("Test1"));
TestRHeapDebug T;
T.Test1();
test.Next(_L("Test2"));
T.Test2();
test.Next(_L("Test3"));
T.Test3();
test.Next(_L("Test4"));
T.Test4();
test.Next(_L("Test5"));
T.Test5();
test.End();
return(0);
}
#else
GLDEF_C TInt E32Main()
//
// Test unavailable in release build.
//
{
test.Title();
test.Start(_L("No tests for release builds"));
test.End();
return(0);
}
#endif