// Copyright (c) 2004-2009 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\mmu\d_memorytest.cpp
//
//
#include <kernel/kern_priv.h>
#include <kernel/cache.h>
#include "d_memorytest.h"
//
// Class definitions
//
class DMemoryTestFactory : public DLogicalDevice
{
public:
~DMemoryTestFactory();
virtual TInt Install();
virtual void GetCaps(TDes8& aDes) const;
virtual TInt Create(DLogicalChannelBase*& aChannel);
};
class DMemoryTestChannel : public DLogicalChannelBase
{
public:
DMemoryTestChannel();
~DMemoryTestChannel();
virtual TInt DoCreate(TInt aUnit, const TDesC8* anInfo, const TVersion& aVer);
virtual TInt Request(TInt aFunction, TAny* a1, TAny* a2);
private:
TInt TestAllocZerosMemory();
TInt TestReAllocZerosMemory();
TInt AllocTest1();
TInt ReAllocTest1();
TInt ReAllocTest2(TUint8*& mem1, TUint8*& mem2, TUint8*& mem3);
TInt AllocPhysTest(TUint32 aIters, TUint32 aSize);
TInt AllocPhysTest1(TUint32 aIters, TUint32 aSize);
public:
DMemoryTestFactory* iFactory;
TVirtualPinObject* iVirtualPinObject;
struct{
TPhysicalPinObject* iObject;
TPhysAddr iPhysAddr;
TPhysAddr iPhysPageList[KUCPageCount];
TUint iColour;
TUint32 iActualMapAttr;
}iPhysicalPinning;
struct{
TKernelMapObject* iObject;
TPhysAddr iPhysPageList[KUCPageCount];
TLinAddr iLinAddr;
}iKernelMapping;
TUint32 iPageSize;
};
//
// DMemoryTestFactory
//
TInt DMemoryTestFactory::Install()
{
return SetName(&KMemoryTestLddName);
}
DMemoryTestFactory::~DMemoryTestFactory()
{
}
void DMemoryTestFactory::GetCaps(TDes8& /*aDes*/) const
{
// Not used but required as DLogicalDevice::GetCaps is pure virtual
}
TInt DMemoryTestFactory::Create(DLogicalChannelBase*& aChannel)
{
aChannel = NULL;
DMemoryTestChannel* channel=new DMemoryTestChannel;
if(!channel)
return KErrNoMemory;
channel->iFactory = this;
aChannel = channel;
return KErrNone;
}
DECLARE_STANDARD_LDD()
{
return new DMemoryTestFactory;
}
//
// DMemoryTestChannel
//
TInt DMemoryTestChannel::DoCreate(TInt /*aUnit*/, const TDesC8* /*aInfo*/, const TVersion& /*aVer*/)
{
return KErrNone;
}
DMemoryTestChannel::DMemoryTestChannel()
{
iPageSize = Kern::RoundToPageSize(1);
}
DMemoryTestChannel::~DMemoryTestChannel()
{
Kern::DestroyVirtualPinObject(iVirtualPinObject);
}
TInt DMemoryTestChannel::Request(TInt aFunction, TAny* a1, TAny* a2)
{
TInt r=KErrNotSupported;
switch(aFunction)
{
case RMemoryTestLdd::EReadWriteMemory:
case RMemoryTestLdd::EReadMemory:
case RMemoryTestLdd::EWriteMemory:
{
TUint32 value=(TUint32)a2;
#ifdef _DEBUG
TInt debugMask = Kern::CurrentThread().iDebugMask;
Kern::CurrentThread().iDebugMask = debugMask&~(1<<KPANIC);
#endif
XTRAP(r, XT_DEFAULT,
if(aFunction==RMemoryTestLdd::EReadWriteMemory)
{
kumemget32(&value,a1,4);
kumemput32(a1,&value,4);
}
else if(aFunction==RMemoryTestLdd::EReadMemory)
kumemget32(&value,a1,4);
else if(aFunction==RMemoryTestLdd::EWriteMemory)
kumemput32(a1,&value,4);
);
#ifdef _DEBUG
Kern::CurrentThread().iDebugMask = debugMask;
#endif
if(aFunction==RMemoryTestLdd::EReadMemory)
kumemput32(a2,&value,sizeof(value));
return r;
}
case RMemoryTestLdd::ETestAllocZerosMemory:
case RMemoryTestLdd::ETestReAllocZerosMemory:
{
NKern::ThreadEnterCS();
TInt r;
if (aFunction==RMemoryTestLdd::ETestAllocZerosMemory)
r=TestAllocZerosMemory();
else
r=TestReAllocZerosMemory();
NKern::ThreadLeaveCS();
return r;
}
case RMemoryTestLdd::ETestAllocPhysTest:
{
NKern::ThreadEnterCS();
r=AllocPhysTest((TUint32)a1,(TUint32)a2);
NKern::ThreadLeaveCS();
return r;
}
case RMemoryTestLdd::ETestAllocPhysTest1:
{
NKern::ThreadEnterCS();
r=AllocPhysTest1((TUint32)a1,(TUint32)a2);
NKern::ThreadLeaveCS();
return r;
}
case RMemoryTestLdd::ECreateVirtualPinObject:
{
NKern::ThreadEnterCS();
r=Kern::CreateVirtualPinObject(iVirtualPinObject);
NKern::ThreadLeaveCS();
return r;
}
case RMemoryTestLdd::EPinVirtualMemory:
return Kern::PinVirtualMemory(iVirtualPinObject, (TLinAddr)a1, (TUint)a2);
case RMemoryTestLdd::EUnpinVirtualMemory:
Kern::UnpinVirtualMemory(iVirtualPinObject);
return KErrNone;
case RMemoryTestLdd::EDestroyVirtualPinObject:
{
NKern::ThreadEnterCS();
Kern::DestroyVirtualPinObject(iVirtualPinObject);
NKern::ThreadLeaveCS();
return KErrNone;
}
case RMemoryTestLdd::ESetPanicTrace:
{
TBool old = false;
#ifdef _DEBUG
DThread& thread = Kern::CurrentThread();
TInt debugMask = thread.iDebugMask;
if(debugMask&(1<<KPANIC))
old = true;
if(a1)
debugMask |= (1<<KPANIC);
else
debugMask &= ~(1<<KPANIC);
thread.iDebugMask = debugMask;
#endif
return old;
}
case RMemoryTestLdd::EIsMemoryPresent:
#ifndef __WINS__
return Epoc::LinearToPhysical((TLinAddr)a1) != KPhysAddrInvalid;
#else
Kern::PanicCurrentThread(_L("IsMemoryPresent should not be used on the emulator"), KErrNotSupported);
return KErrNotSupported;
#endif
case RMemoryTestLdd::ECreatePhysicalPinObject:
{
NKern::ThreadEnterCS();
r=Kern::CreatePhysicalPinObject(iPhysicalPinning.iObject);
NKern::ThreadLeaveCS();
return r;
}
case RMemoryTestLdd::EPinPhysicalMemory:
return Kern::PinPhysicalMemory(iPhysicalPinning.iObject, (TLinAddr)a1, (TUint)a2, EFalse, iPhysicalPinning.iPhysAddr,
iPhysicalPinning.iPhysPageList, iPhysicalPinning.iActualMapAttr, iPhysicalPinning.iColour, NULL);
case RMemoryTestLdd::EPinPhysicalMemoryRO:
return Kern::PinPhysicalMemory(iPhysicalPinning.iObject, (TLinAddr)a1, (TUint)a2, ETrue, iPhysicalPinning.iPhysAddr,
iPhysicalPinning.iPhysPageList, iPhysicalPinning.iActualMapAttr, iPhysicalPinning.iColour, NULL);
case RMemoryTestLdd::ECheckPageList:
{
#ifdef __WINS__
return KErrNotSupported;
#else
TInt i;
for (i=0;i<KUCPageCount; i++)
{
TPhysAddr addr = Epoc::LinearToPhysical((TLinAddr)a1 + i*iPageSize);
if (addr==KPhysAddrInvalid) return KErrGeneral;
if (addr!=iPhysicalPinning.iPhysPageList[i]) return KErrNotFound;
}
return KErrNone;
#endif
}
case RMemoryTestLdd::ESyncPinnedPhysicalMemory:
return Cache::SyncPhysicalMemoryBeforeDmaWrite(iPhysicalPinning.iPhysPageList,
iPhysicalPinning.iColour, (TUint)a1, (TUint)a2, iPhysicalPinning.iActualMapAttr);
case RMemoryTestLdd::EMovePinnedPhysicalMemory:
{
#ifdef __WINS__
return KErrNotSupported;
#else
TPhysAddr newPage;
NKern::ThreadEnterCS();
r = Epoc::MovePhysicalPage(iPhysicalPinning.iPhysPageList[(TUint)a1], newPage);
NKern::ThreadLeaveCS();
return r;
#endif
}
case RMemoryTestLdd::EInvalidatePinnedPhysicalMemory:
{
r = Cache::SyncPhysicalMemoryBeforeDmaRead(iPhysicalPinning.iPhysPageList,
iPhysicalPinning.iColour, (TUint)a1, (TUint)a2, iPhysicalPinning.iActualMapAttr);
if (r==KErrNone)
r = Cache::SyncPhysicalMemoryAfterDmaRead(iPhysicalPinning.iPhysPageList,
iPhysicalPinning.iColour, (TUint)a1, (TUint)a2, iPhysicalPinning.iActualMapAttr);
return r;
}
case RMemoryTestLdd::EUnpinPhysicalMemory:
return Kern::UnpinPhysicalMemory(iPhysicalPinning.iObject);
case RMemoryTestLdd::EDestroyPhysicalPinObject:
{
NKern::ThreadEnterCS();
r=Kern::DestroyPhysicalPinObject(iPhysicalPinning.iObject);
NKern::ThreadLeaveCS();
return r;
}
case RMemoryTestLdd::EPinKernelPhysicalMemory:
{
TPhysicalPinObject* pinObject;
TPhysAddr aAddress;
TPhysAddr aPages[2];
TUint aColour=0;
TUint32 actualMemAttr;
NKern::ThreadEnterCS();
Kern::CreatePhysicalPinObject(pinObject);
r = Kern::PinPhysicalMemory(pinObject, (TLinAddr)&aAddress, 4, EFalse, aAddress, aPages, actualMemAttr, aColour, NULL);
Cache::SyncPhysicalMemoryBeforeDmaWrite(aPages, aColour, 10, 30, actualMemAttr);
Kern::UnpinPhysicalMemory(pinObject);
Kern::DestroyPhysicalPinObject(pinObject);
NKern::ThreadLeaveCS();
return r;
}
case RMemoryTestLdd::ECreateKernelMapObject:
{
NKern::ThreadEnterCS();
r=Kern::CreateKernelMapObject(iKernelMapping.iObject, (TUint)a1);
NKern::ThreadLeaveCS();
return r;
}
case RMemoryTestLdd::EKernelMapMemory:
return Kern::MapAndPinMemory( iKernelMapping.iObject, NULL, (TLinAddr)a1, (TUint)a2, 0,
iKernelMapping.iLinAddr, iKernelMapping.iPhysPageList);
case RMemoryTestLdd::EKernelMapMemoryRO:
return Kern::MapAndPinMemory( iKernelMapping.iObject, NULL, (TLinAddr)a1, (TUint)a2, Kern::EKernelMap_ReadOnly,
iKernelMapping.iLinAddr, iKernelMapping.iPhysPageList);
case RMemoryTestLdd::EKernelMapMemoryInvalid:
return Kern::MapAndPinMemory( iKernelMapping.iObject, NULL, (TLinAddr)a1, (TUint)a2, (TUint)~Kern::EKernelMap_ReadOnly,
iKernelMapping.iLinAddr, iKernelMapping.iPhysPageList);
case RMemoryTestLdd::EKernelMapCheckPageList:
{
#ifdef __WINS__
return KErrNotSupported;
#else
TUint i = 0;
for (; i < (TUint)KUCPageCount; i++)
{
// Compare the user side address to physical addresses
TPhysAddr addr = Epoc::LinearToPhysical((TLinAddr)a1 + i*iPageSize);
if (addr == KPhysAddrInvalid)
return KErrGeneral;
if (addr != iKernelMapping.iPhysPageList[i])
return KErrNotFound;
// Compare the kernel side address to physical addresses
addr = Epoc::LinearToPhysical(iKernelMapping.iLinAddr + i*iPageSize);
if (addr == KPhysAddrInvalid)
return KErrGeneral;
if (addr != iKernelMapping.iPhysPageList[i])
return KErrNotFound;
}
return KErrNone;
#endif
}
case RMemoryTestLdd::EKernelMapSyncMemory:
Cache::SyncMemoryBeforeDmaWrite(iKernelMapping.iLinAddr, KUCPageCount*iPageSize);
return KErrNone;
case RMemoryTestLdd::EKernelMapInvalidateMemory:
{
Cache::SyncMemoryBeforeDmaRead(iKernelMapping.iLinAddr, KUCPageCount*iPageSize);
Cache::SyncMemoryAfterDmaRead(iKernelMapping.iLinAddr, KUCPageCount*iPageSize);
return KErrNone;
}
case RMemoryTestLdd::EKernelMapMoveMemory:
{
#ifdef __WINS__
return KErrNotSupported;
#else
TPhysAddr newPage;
NKern::ThreadEnterCS();
r = Epoc::MovePhysicalPage(iKernelMapping.iPhysPageList[(TUint)a1], newPage);
NKern::ThreadLeaveCS();
return r;
#endif
}
case RMemoryTestLdd::EKernelMapReadModifyMemory:
{
TUint8* p = (TUint8*)iKernelMapping.iLinAddr;
// Verify the contents of the data when accessed via the kernel mapping.
TUint i = 0;
for (i = 0; i < KUCPageCount*iPageSize; i++)
{
if (*p++ != (TUint8)i)
return KErrCorrupt;
}
// Modify the data via the kernel mapping.
p = (TUint8*)iKernelMapping.iLinAddr;
for (i = 0; i < KUCPageCount*iPageSize; i++)
{
*p++ = (TUint8)(i + 1);
}
return KErrNone;
}
case RMemoryTestLdd::EKernelUnmapMemory:
Kern::UnmapAndUnpinMemory(iKernelMapping.iObject);
return KErrNone;
case RMemoryTestLdd::EDestroyKernelMapObject:
{
NKern::ThreadEnterCS();
Kern::DestroyKernelMapObject(iKernelMapping.iObject);
NKern::ThreadLeaveCS();
return KErrNone;
}
default:
return KErrNotSupported;
}
}
// Fail a test by returning an error code indicating the problem
#define FAIL_ALLOC_TEST(testIndex, byteOffset, unexepectedValue) \
err = ((testIndex) << 16) | ((byteOffset) << 8) | (unexepectedValue)
TInt DMemoryTestChannel::TestAllocZerosMemory()
{
TInt count = 100;
TInt r = KErrNotSupported;
do { //re-try up to 100 times if memory conditions are not correct
r=AllocTest1();
} while(((r == KErrNoMemory)||(r == KErrUnknown)) && --count);
return r;
}
TInt DMemoryTestChannel::AllocTest1()
{
const TInt KSize = 256;
TInt err = KErrNone;
TUint8* mem1 = (TUint8*)Kern::Alloc(KSize);
if (!mem1)
return KErrNoMemory;
memset(mem1, KSize, 0xff);
Kern::Free(mem1);
TUint8* mem2 = (TUint8*)Kern::Alloc(KSize);
if (!mem2)
return KErrNoMemory;
if (mem1 != mem2)
err = KErrUnknown; // Test inconclusive, can retry
for (TInt i = 0 ; i<KSize && err==KErrNone; ++i)
{
if (mem2[i] != 0)
FAIL_ALLOC_TEST(1, i, mem2[i]);
}
Kern::Free(mem2);
return err;
}
TInt DMemoryTestChannel::TestReAllocZerosMemory()
{
TInt count = 100;
TInt r = KErrNotSupported;
do { //re-try up to 100 times if memory conditions are not correct
r=ReAllocTest1();
} while(((r == KErrNoMemory)||(r == KErrUnknown)) && --count);
if (r!=KErrNone)
return r;
count = 100;
do { // re-try up to 100 times if memory conditions are not correct
TUint8* mem1 = NULL;
TUint8* mem2 = NULL;
TUint8* mem3 = NULL;
r=ReAllocTest2(mem1, mem2, mem3);
if (mem1)
Kern::Free(mem1);
if (mem2)
Kern::Free(mem2);
if (mem3)
Kern::Free(mem3);
} while(((r == KErrNoMemory)||(r == KErrUnknown)) && --count);
return r;
}
// The actual size of the block allocated given the size requested.
#define ALIGNED_SIZE(aReqSize) (_ALIGN_UP(aReqSize + RHeap::EAllocCellSize, RHeap::ECellAlignment) - RHeap::EAllocCellSize)
// We only acllocate blocks where the size we get is the size we ask for - this
// just makes testing easier.
const TInt KSize = ALIGNED_SIZE(200), KHalfSize = ALIGNED_SIZE(100), KSmallSize = ALIGNED_SIZE(50);
TInt DMemoryTestChannel::ReAllocTest1()
{
// Test case where cell grows
//
// Expected heap layout:
// 1: [-mem1-------]
// 2: [-mem1-]
// 3: [-mem1-------]
TInt err = KErrNone;
TUint8* mem1 = (TUint8*)Kern::Alloc(KSize); // 1
if (!mem1)
return KErrNoMemory;
memset(mem1, 0xff, KSize);
TUint8* mem2 = (TUint8*)Kern::ReAlloc(mem1, KHalfSize); // 2
if (mem1 != mem2)
{
mem1 = 0;
Kern::Free(mem2);
return KErrUnknown; // Don't expect move on shrink
}
mem2 = (TUint8*)Kern::ReAlloc(mem1, KSize); // 3
if (mem1 != mem2)
{
mem1 = 0;
Kern::Free(mem2);
return KErrUnknown; // Expect growth into original area
}
TInt i;
for (i = 0 ; i<KHalfSize && err==KErrNone; ++i)
{
if (mem1[i] != 0xff)
FAIL_ALLOC_TEST(2, i, mem1[i]);
}
for (i = KHalfSize ; i<KSize && err==KErrNone; ++i)
{
if (mem1[i] != 0)
FAIL_ALLOC_TEST(3, i, mem1[i]);
}
Kern::Free(mem1);
return err;
}
TInt DMemoryTestChannel::ReAllocTest2(TUint8*& mem1, TUint8*& mem2, TUint8*& mem3)
{
// Test case where cell is moved
//
// Expected heap layout:
// 1: [ mem1 ]
// 2: [ mem1 ] [ mem2 ]
// 3: [ mem1 ] [ mem2 ] [ mem3 ]
// 4: [ mem2 ] [ mem1 ]
mem1 = (TUint8*)Kern::Alloc(KSmallSize); // 1
if (!mem1)
return KErrNoMemory;
memset(mem1, 0xff, KSmallSize);
mem2 = (TUint8*)Kern::Alloc(KSmallSize); // 2
if (!mem2)
return KErrNoMemory;
if (mem2 <= (mem1 + KSmallSize))
return KErrUnknown; // Expect mem2 higher than mem1
memset(mem2, 0xee, KSmallSize);
mem3 = (TUint8*)Kern::Alloc(KSize); // 3
if (!mem3)
return KErrNoMemory;
if (mem3 <= (mem2 + KSmallSize))
return KErrUnknown; // Expect mem3 higher than mem2
memset(mem3, 0xdd, KSize);
Kern::Free(mem3);
TUint8* m3 = mem3;
mem3 = NULL;
TUint8* mem4 = (TUint8*)Kern::ReAlloc(mem1, KSize); // 4
if (!mem4)
return KErrNoMemory;
if (mem4 == mem1)
return KErrUnknown; // Expect move on grow
mem1=mem4;
if (mem4 != m3)
return KErrUnknown; // Expect to realloc to use old mem3 space
TInt i;
TInt err = KErrNone;
for (i = 0 ; i<KSmallSize && err==KErrNone; ++i)
{
if (mem1[i] != 0xff)
FAIL_ALLOC_TEST(4, i, mem1[i]);
}
for (i = KSmallSize; i<KSize && err==KErrNone; ++i)
{
if (mem1[i] != 0)
FAIL_ALLOC_TEST(5, i, mem1[i]);
}
return err;
}
#ifdef __EPOC32__
#define CHECK(c) { if(!(c)) { Kern::Printf("Fail %d", __LINE__); ; ret = __LINE__;} }
TInt DMemoryTestChannel::AllocPhysTest(TUint32 aIters, TUint32 aSize)
{
TInt ret = KErrNone;
TUint32 index;
TUint32 pageSize = 0;
CHECK(Kern::HalFunction(EHalGroupKernel,EKernelHalPageSizeInBytes,&pageSize,0)==KErrNone);
TUint32 numPages = aSize / pageSize;
TUint32 pageIndex;
TPhysAddr* addrArray = (TPhysAddr *)Kern::AllocZ(sizeof(TPhysAddr) * numPages);
CHECK(addrArray);
if(!addrArray)
{
return KErrNoMemory;
}
for (index = 0; index < aIters; index ++)
{
for (pageIndex = 0; pageIndex < numPages; pageIndex ++)
{
ret = Epoc::AllocPhysicalRam(pageSize, addrArray[pageIndex], 0);
if (ret != KErrNone)
{
break;
}
}
for (pageIndex = 0; pageIndex < numPages; pageIndex ++)
{
if (addrArray[pageIndex])
{
Epoc::FreePhysicalRam(addrArray[pageIndex], pageSize);
addrArray[pageIndex] = NULL;
}
}
if (ret != KErrNone)
{
break;
}
}
Kern::Free(addrArray);
return ret;
}
#else
TInt DMemoryTestChannel::AllocPhysTest(TUint32 , TUint32 )
{
return KErrNone;
}
#endif
#ifdef __EPOC32__
TInt DMemoryTestChannel::AllocPhysTest1(TUint32 aIters, TUint32 aSize)
{
TInt ret = KErrNone;
TUint32 index;
TUint32 pageSize = 0;
CHECK(Kern::HalFunction(EHalGroupKernel,EKernelHalPageSizeInBytes,&pageSize,0)==KErrNone);
TUint32 numPages = aSize / pageSize;
TPhysAddr* addrArray = (TPhysAddr *)Kern::AllocZ(sizeof(TPhysAddr) * numPages);
for (index = 0; index < aIters; index ++)
{
ret = Epoc::AllocPhysicalRam(numPages, addrArray);
if (ret != KErrNone)
{
break;
}
Epoc::FreePhysicalRam(numPages, addrArray);
}
Kern::Free(addrArray);
return ret;
}
#else
TInt DMemoryTestChannel::AllocPhysTest1(TUint32 , TUint32 )
{
return KErrNone;
}
#endif