/*
* Copyright (c) 2009 Nokia Corporation and/or its subsidiary(-ies).
* All rights reserved.
* This component and the accompanying materials are made available
* under the terms of "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:
*
*/
#include "MemSpyDriverLogChanHeapBase.h"
// System includes
#include <u32hal.h>
#include <e32rom.h>
#include <memspy/driver/memspydriverobjectsshared.h>
// Shared includes
#include "MemSpyDriverOpCodes.h"
#include "MemSpyDriverObjectsInternal.h"
// User includes
#include "MemSpyDriverHeap.h"
#include "MemSpyDriverUtils.h"
#include "MemSpyDriverDevice.h"
#include "MemSpyDriverOSAdaption.h"
// Constants
const TInt KMemSpyDriverLogChanHeapBaseXferBufferSize = 1024 * 16;
DMemSpyDriverLogChanHeapBase::DMemSpyDriverLogChanHeapBase( DMemSpyDriverDevice& aDevice, DThread& aThread )
: DMemSpyDriverLogChanBase( aDevice, aThread )
{
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::DMemSpyDriverLogChanHeapBase() - this: 0x%08x", this ));
}
DMemSpyDriverLogChanHeapBase::~DMemSpyDriverLogChanHeapBase()
{
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::~DMemSpyDriverLogChanHeapBase() - START - this: 0x%08x", this ));
ReleaseFreeCells();
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::~DMemSpyDriverLogChanHeapBase() - END - this: 0x%08x", this ));
}
TInt DMemSpyDriverLogChanHeapBase::Construct()
{
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::Construct() - START - this: 0x%08x", this ));
const TInt ret = BaseConstruct( KMemSpyDriverLogChanHeapBaseXferBufferSize );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::Construct() - END - this: 0x%08x, err: %d", this, ret ));
return ret;
}
TInt DMemSpyDriverLogChanHeapBase::Request( TInt aFunction, TAny* a1, TAny* a2 )
{
const TInt r = DMemSpyDriverLogChanBase::Request( aFunction, a1, a2 );
return r;
}
DMemSpyDriverLogChanHeapBase::TDrmMatchType DMemSpyDriverLogChanHeapBase::IsDrmThread( DThread& aThread )
{
TDrmMatchType ret = EMatchTypeNone;
//
const TUid procUid = aThread.iOwningProcess->iUids.iUid[ 2 ];
TRACE( Kern::Printf( "DMemSpyDriverLogChanHeapBase::IsDrmThread() - START - aThread: %O, process uid: 0x%08x", &aThread, procUid.iUid ));
// Some more rudimentary checks based upon process name and
// known uids.
TFullName fullName;
aThread.FullName( fullName );
// Exclude threads containing "DRM"
_LIT( KDrmThreadMatchText, "*DRM*" );
const TInt matchPos = fullName.MatchF( KDrmThreadMatchText );
if ( matchPos >= 0 )
{
TRACE( Kern::Printf( "DMemSpyDriverLogChanHeapBase::IsDrmThread() - found \'DRM\' at pos: %d (%S)", matchPos, &fullName ));
ret = EMatchTypeName;
}
else
{
// Some known DRM related process UIDs
switch( procUid.iUid )
{
case 0x10005A22: // DRMEncryptor.exe
case 0x01105901: // DRMEncryptor.exe
case 0x101F85C7: // DRMRightsManager.exe
case 0x10205CA8: // DcfRepSrv.exe
case 0x101F51F2: // RightsServer.exe
case 0x101F6DC5: // DRMHelperServer.exe
case 0x10282F1B: // wmdrmserver.exe
ret = EMatchTypeUid;
break;
default:
ret = EMatchTypeNone;
break;
}
}
TRACE( Kern::Printf( "DMemSpyDriverLogChanHeapBase::IsDrmThread() - END - procUid: 0x%08x, matchType: %d", procUid.iUid, ret ));
return ret;
}
TInt DMemSpyDriverLogChanHeapBase::OpenUserHeap( DThread& aClientThread, TUint aExpectedHeapVTable, RMemSpyDriverRHeapUser& aHeap, DChunk*& aUserHeapChunk, TDes8* aClientHeapChunkName )
{
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::OpenUserHeap() - START - aHeap.ChunkIsInitialised: %d, aExpectedHeapVTable: 0x%08x, aClientThread: %O", aHeap.ChunkIsInitialised(), aExpectedHeapVTable, &aClientThread ));
__ASSERT_ALWAYS( aHeap.ChunkIsInitialised() == EFalse, MemSpyDriverUtils::PanicThread( ClientThread(), EPanicHeapChunkAlreadyCloned ) );
TInt r = KErrNotFound;
aUserHeapChunk = NULL;
NKern::ThreadEnterCS();
const TBool allocatorIsReallyRHeap = GetUserHeapHandle( aClientThread, aHeap, aExpectedHeapVTable );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::OpenUserHeap - allocatorIsReallyRHeap: %d", allocatorIsReallyRHeap));
if ( allocatorIsReallyRHeap )
{
RAllocator* allocator = OSAdaption().DThread().GetAllocator( aClientThread );
// Open client's heap chunk in order to read it's dimensions
const TInt clientsHeapChunkHandle = aHeap.iChunkHandle;
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::OpenUserHeap - clientsHeapChunkHandle: 0x%08x, allocatorAddress: 0x%08x", clientsHeapChunkHandle, allocator));
NKern::LockSystem();
DChunk* clientsHeapChunk = (DChunk*) Kern::ObjectFromHandle( &aClientThread, clientsHeapChunkHandle, EChunk );
NKern::UnlockSystem();
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::OpenUserHeap - clientsHeapChunk: 0x%08x", clientsHeapChunk ));
if ( clientsHeapChunk != NULL )
{
// Get the chunk name (if the caller asked for it)
if ( aClientHeapChunkName )
{
clientsHeapChunk->FullName( *aClientHeapChunkName );
}
// Update the heap chunk pointer. We do this now because this
// should point to the _real_ user-side heap chunk, rather than
// the copy of the chunk that we are about to make.
aUserHeapChunk = clientsHeapChunk;
// Set up ourselves to duplicate their heap chunk
const TInt clientsHeapChunkSize = OSAdaption().DChunk().GetSize( *clientsHeapChunk );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::OpenUserHeap - chunkBase: 0x%08x, size: %8d, maxLen: %8d, chunk: %O", clientsHeapChunk->iBase, clientsHeapChunkSize, clientsHeapChunk->iMaxSize, clientsHeapChunk ));
// Make a new chunk that is the same size, owned by this thread.
TChunkCreateInfo info;
info.iType = TChunkCreateInfo::ESharedKernelSingle;
info.iMaxSize = clientsHeapChunkSize;
info.iOwnsMemory = ETrue; // Use memory from system's free pool
info.iDestroyedDfc = NULL;
#ifdef __EPOC32__
info.iMapAttr = (TInt)EMapAttrFullyBlocking; // Full caching
#endif
// Holds a copy of the client's heap chunk
DChunk* heapCopyChunk;
TLinAddr heapCopyChunkAddress;
TUint32 heapCopyChunkMappingAttributes;
r = Kern::ChunkCreate( info, heapCopyChunk, heapCopyChunkAddress, heapCopyChunkMappingAttributes );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::OpenUserHeap - creating chunk returned: %d", r));
//
if ( r == KErrNone )
{
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::OpenUserHeap - copy chunk base: 0x%08x, heapCopyChunkAddress: 0x%08x", heapCopyChunk->iBase, heapCopyChunkAddress));
// Commit memory for entire buffer
TUint32 physicalAddress = 0;
r = Kern::ChunkCommitContiguous( heapCopyChunk, 0, clientsHeapChunkSize, physicalAddress );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::OpenUserHeap - commiting chunk returned: %d", r));
if ( r != KErrNone)
{
// On error, thow away the chunk we have created
Kern::ChunkClose( heapCopyChunk );
heapCopyChunk = NULL;
}
else
{
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::OpenUserHeap - heapCopyChunk->iSize: 0x%08x, heapCopyChunk->iBase: 0x%08x, heapCopyChunkAddress: 0x%08x, physicalAddress: 0x%08x", heapCopyChunk->iSize, heapCopyChunk->iBase, heapCopyChunkAddress, physicalAddress));
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::OpenUserHeap - trying to copy %d bytes from clients allocator address of 0x%08x", clientsHeapChunkSize, allocator ));
r = Kern::ThreadRawRead( &aClientThread, allocator, (TAny*) heapCopyChunkAddress, clientsHeapChunkSize );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::OpenUserHeap - read result of clients heap data is: %d", r));
if ( r == KErrNone )
{
// Transfer ownership of the copy heap chunk to the heap object. This also calculates the delta
// beween the heap addresses in the client's address space and the kernel address space.
aHeap.AssociateWithKernelChunk( heapCopyChunk, heapCopyChunkAddress, heapCopyChunkMappingAttributes );
}
}
}
}
else
{
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::OpenUserHeap - could not open clients heap chunk by its handle" ) );
r = KErrNotFound;
}
}
else
{
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::OpenUserHeap - clients heap is not an RHeap (allocated vTable mismatch)" ) );
r = KErrNotSupported;
}
NKern::ThreadLeaveCS();
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::OpenUserHeap - r: %d", r ));
return r;
}
TBool DMemSpyDriverLogChanHeapBase::GetUserHeapHandle( DThread& aThread, RMemSpyDriverRHeapUser& aHeap, TUint aExpectedVTable )
{
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::GetUserHeapHandle() - START - aExpectedVTable: 0x%08x", aExpectedVTable) );
RAllocator* allocator = OSAdaption().DThread().GetAllocator( aThread );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::GetUserHeapHandle - allocator addr: 0x%08x", allocator) );
TUint* pAllocator = (TUint*) allocator;
//
TBool vTableOkay = EFalse;
TUint vtable = 0;
// Read a bit more data than is available for debugging purposes
TBuf8<32> vtableBuf;
TInt r = Kern::ThreadRawRead( &aThread, pAllocator, (TUint8*) vtableBuf.Ptr(), vtableBuf.MaxLength() );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::GetUserHeapHandle - read result of vtable data from requested thread is: %d", r));
if ( r == KErrNone )
{
TRACE( MemSpyDriverUtils::DataDump("allocator vtable data - %lS", vtableBuf.Ptr(), vtableBuf.MaxLength(), vtableBuf.MaxLength() ) );
vtableBuf.SetLength( vtableBuf.MaxLength() );
vtable = vtableBuf[0] +
(vtableBuf[1] << 8) +
(vtableBuf[2] << 16) +
(vtableBuf[3] << 24);
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::GetUserHeapHandle - client VTable is: 0x%08x", vtable) );
// Check the v-table to work out if it really is an RHeap
vTableOkay = ( vtable == aExpectedVTable );
if ( vTableOkay )
{
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::GetUserHeapHandle - vtables okay") );
r = aHeap.ReadFromUserAllocator( aThread );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::GetUserHeapHandle - after userget, error: %d", r));
}
else
{
TRACE( Kern::Printf( "DMemSpyDriverLogChanHeapBase::GetUserHeapHandle - vtables dont match! - aExpectedVTable: 0x%08x, allocator addr: 0x%08x, client VTable is: 0x%08x, aThread: %O", aExpectedVTable, allocator, vtable, &aThread ) );
}
}
else
{
TRACE( Kern::Printf( "DMemSpyDriverLogChanHeapBase::GetUserHeapHandle - error during client vTable reading: %d, aThread: %O", r, &aThread ) );
}
//
return (vTableOkay && (r == KErrNone));
}
void DMemSpyDriverLogChanHeapBase::PrintHeapInfo( const TMemSpyHeapInfo& aInfo )
{
const TMemSpyHeapInfoRHeap& rHeapInfo = aInfo.AsRHeap();
const TMemSpyHeapObjectDataRHeap& rHeapObjectData = rHeapInfo.ObjectData();
const TMemSpyHeapStatisticsRHeap& rHeapStats = rHeapInfo.Statistics();
const TMemSpyHeapMetaDataRHeap& rHeapMetaData = rHeapInfo.MetaData();
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() ---------------------------------------------------" ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - RAllocator -" ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() ---------------------------------------------------" ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - RAllocator::iAccessCount: %d", rHeapObjectData.iAccessCount ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - RAllocator::iHandleCount: %d", rHeapObjectData.iHandleCount ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - RAllocator::iHandles: 0x%08x", rHeapObjectData.iHandles ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - RAllocator::iFlags: 0x%08x", rHeapObjectData.iFlags ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - RAllocator::iCellCount: %d", rHeapObjectData.iCellCount ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - RAllocator::iTotalAllocSize: %d", rHeapObjectData.iTotalAllocSize ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - " ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() ---------------------------------------------------" ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - RHeap -" ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() ---------------------------------------------------" ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - RHeap::iMinLength: %d", rHeapObjectData.iMinLength ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - RHeap::iMaxLength: %d", rHeapObjectData.iMaxLength ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - RHeap::iOffset: %d", rHeapObjectData.iOffset ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - RHeap::iGrowBy: %d", rHeapObjectData.iGrowBy ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - RHeap::iChunkHandle: 0x%08x", rHeapObjectData.iChunkHandle ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - RHeap::iBase: 0x%08x", rHeapObjectData.iBase ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - RHeap::iTop: 0x%08x", rHeapObjectData.iTop ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - RHeap::iAlign: %d", rHeapObjectData.iAlign ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - RHeap::iMinCell: %d", rHeapObjectData.iAlign ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - RHeap::iPageSize: %d", rHeapObjectData.iAlign ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - RHeap::iFree.next: 0x%08x", rHeapObjectData.iFree.next ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - RHeap::iFree.len: %d", rHeapObjectData.iFree.len ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - RHeap::iNestingLevel: %d", rHeapObjectData.iNestingLevel ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - RHeap::iAllocCount: %d", rHeapObjectData.iAllocCount ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - RHeap::iFailType: %d", rHeapObjectData.iFailType ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - RHeap::iFailRate: %d", rHeapObjectData.iFailRate ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - RHeap::iFailed: %d", rHeapObjectData.iFailed ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - RHeap::iFailAllocCount: %d", rHeapObjectData.iFailAllocCount ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - RHeap::iRand: %d", rHeapObjectData.iRand ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - RHeap::iTestData: 0x%08x", rHeapObjectData.iTestData ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - " ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() ---------------------------------------------------" ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - Stats (Free) -" ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() ---------------------------------------------------" ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - cell count: %d", rHeapStats.StatsFree().TypeCount() ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - cell size: %d", rHeapStats.StatsFree().TypeSize() ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - cell largest: 0x%08x", rHeapStats.StatsFree().LargestCellAddress() ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - cell largest size: %d", rHeapStats.StatsFree().LargestCellSize() ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - slack: 0x%08x", rHeapStats.StatsFree().SlackSpaceCellAddress() ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - slack size: %d", rHeapStats.StatsFree().SlackSpaceCellSize() ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - checksum: 0x%08x", rHeapStats.StatsFree().Checksum() ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - " ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() ---------------------------------------------------" ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - Stats (Alloc) -" ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() ---------------------------------------------------" ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - cell count: %d", rHeapStats.StatsAllocated().TypeCount() ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - cell size: %d", rHeapStats.StatsAllocated().TypeSize() ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - cell largest: 0x%08x", rHeapStats.StatsAllocated().LargestCellAddress() ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - cell largest size: %d", rHeapStats.StatsAllocated().LargestCellSize() ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - " ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() ---------------------------------------------------" ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - Stats (Common) -" ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() ---------------------------------------------------" ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - total cell count: %d", rHeapStats.StatsCommon().TotalCellCount() ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - " ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() ---------------------------------------------------" ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - Misc. Info -" ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() ---------------------------------------------------" ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - chunk size: %d", rHeapMetaData.ChunkSize() ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - chunk handle: 0x%08x", rHeapMetaData.ChunkHandle() ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - chunk base address: 0x%08x", rHeapMetaData.ChunkBaseAddress() ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - debug allocator: %d", rHeapMetaData.IsDebugAllocator() ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - shared heap: %d", rHeapMetaData.IsSharedHeap() ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - user thread: %d", rHeapMetaData.IsUserThread() ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - cell header size (free): %d", rHeapMetaData.HeaderSizeFree() ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - cell header size (alloc): %d", rHeapMetaData.HeaderSizeAllocated() ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - heap vTable: 0x%08x", rHeapMetaData.VTable() ) );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrintHeapInfo() - heap object size: %d", rHeapMetaData.ClassSize() ) );
}
TBool DMemSpyDriverLogChanHeapBase::IsDebugKernel()
{
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::IsDebugKernel() - START") );
TInt r = KErrNone;
TBool debugKernel = EFalse;
NKern::ThreadEnterCS();
RMemSpyDriverRHeapKernelInPlace rHeap;
r = OpenKernelHeap( rHeap );
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::IsDebugKernel() - open kernel heap returned: %d", r) );
if ( r == KErrNone )
{
debugKernel = IsDebugKernel( rHeap );
// Tidy up
rHeap.DisassociateWithKernelChunk();
}
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::IsDebugKernel() - debugKernel: %d", debugKernel) );
NKern::ThreadLeaveCS();
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::IsDebugKernel() - END - ret: %d", r) );
return debugKernel;
}
TBool DMemSpyDriverLogChanHeapBase::IsDebugKernel( RMemSpyDriverRHeapKernelInPlace& aHeap )
{
TBool debugKernel = EFalse;
//
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::IsDebugKernel() - START") );
NKern::ThreadEnterCS();
// Request that the kernel fail the next heap allocation
aHeap.FailNext();
// Allocate a new cell, and in debug builds of the kernel, this should be NULL
TInt* cell = new TInt();
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::IsDebugKernel() - cell: 0x%08x", cell) );
debugKernel = ( cell == NULL );
delete cell;
NKern::ThreadLeaveCS();
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::IsDebugKernel() - END - debugKernel: %d", debugKernel) );
//
return debugKernel;
}
TInt DMemSpyDriverLogChanHeapBase::GetHeapInfoKernel( RMemSpyDriverRHeapBase& aHeap, TBool aIsDebugAllocator, const TDesC8& aChunkName, TMemSpyHeapInfo* aHeapInfo, TDes8* aTransferBuffer )
{
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::GetHeapInfoKernel() - START - aTransferBuffer: 0x%08x", aTransferBuffer ) );
TInt r = KErrNone;
NKern::ThreadEnterCS();
// This object holds all of the info we will accumulate for the client.
TMemSpyHeapInfo masterHeapInfo;
masterHeapInfo.SetType( TMemSpyHeapInfo::ETypeRHeap );
masterHeapInfo.SetTid( 2 );
masterHeapInfo.SetPid( 1 );
// This is the RHeap-specific object that contains all RHeap info
TMemSpyHeapInfoRHeap& rHeapInfo = masterHeapInfo.AsRHeap();
// This is the object data for the RHeap instance
TMemSpyHeapObjectDataRHeap& rHeapObjectData = rHeapInfo.ObjectData();
aHeap.CopyObjectDataTo( rHeapObjectData );
// When walking the kernel heap we must keep track of the free cells
// without allocating any more memory (on the kernel heap...)
//
// Therefore, we start a stream immediately, which is actually already
// pre-allocated.
//
// Start stream and pad with zero count, which we'll repopulate later on
// once we know the final score.
RMemSpyMemStreamWriter stream;
TInt32* pCount = NULL;
// We must walk the client's heap in order to build statistics
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::GetHeapInfoKernel - calling heap walker constructor..."));
RMemSpyDriverHeapWalker heapWalker( aHeap, aIsDebugAllocator );
if ( aTransferBuffer )
{
// This will allow us to identify that we're writing directly to the stream
stream = OpenXferStream();
iStackStream = &stream;
// Writer marker value which we'll update after the traversal completes
pCount = stream.WriteInt32( 0 );
// Receive cell info as we walk the heap...
heapWalker.SetObserver( this );
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::GetHeapInfoKernel - collecting free cells - iStackStream: 0x%08x, isOpen: %d, pCount: 0x%08x", iStackStream, stream.IsOpen(), pCount ));
}
else
{
iStackStream = NULL;
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::GetHeapInfoKernel - not collecting free cells"));
}
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::GetHeapInfoKernel - locking system..." ));
NKern::LockSystem();
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::GetHeapInfoKernel - disabling interrupts..." ));
const TInt irq = NKern::DisableAllInterrupts();
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::GetHeapInfoKernel - starting traversal..." ));
#if defined( TRACE_TYPE_KERNELHEAP )
heapWalker.SetPrintDebug();
#endif
r = heapWalker.Traverse();
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::GetHeapInfoKernel - restoring interrupts..." ));
NKern::RestoreInterrupts( irq );
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::GetHeapInfoKernel - finished traversal - err: %d, iStackStream: 0x%08x, pCount: 0x%08x, isOpen: %d", r, iStackStream, pCount, ( iStackStream == NULL ? 0 : iStackStream->IsOpen() ) ));
NKern::UnlockSystem();
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::GetHeapInfoKernel - unlocked system" ));
// Write free cells if requested
if ( r == KErrNone && iStackStream && iStackStream->IsOpen() && pCount )
{
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::GetHeapInfoKernel - final free cell count: %d", iFreeCellCount ));
*pCount = iFreeCellCount;
r = stream.WriteAndClose( aTransferBuffer );
iStackStream = NULL;
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::GetHeapInfoKernel - stream commit result: %d", r ));
}
TMemSpyHeapStatisticsRHeap& rHeapStats = rHeapInfo.Statistics();
heapWalker.CopyStatsTo( rHeapStats );
// Get remaining meta data that isn't stored elsewhere
TMemSpyHeapMetaDataRHeap& rHeapMetaData = rHeapInfo.MetaData();
rHeapMetaData.SetChunkName( aChunkName );
rHeapMetaData.SetChunkSize( (TUint) aHeap.Chunk().Size() );
rHeapMetaData.SetChunkHandle( &aHeap.Chunk() );
rHeapMetaData.SetChunkBaseAddress( aHeap.Chunk().Base() );
rHeapMetaData.SetDebugAllocator( aIsDebugAllocator );
rHeapMetaData.SetHeaderSizeFree( RMemSpyDriverRHeapBase::FreeCellHeaderSize() );
rHeapMetaData.SetHeaderSizeAllocated( RMemSpyDriverRHeapBase::AllocatedCellHeaderSize( aIsDebugAllocator ) );
rHeapMetaData.SetUserThread( EFalse );
rHeapMetaData.SetSharedHeap( ETrue );
// Get any heap-specific info
aHeap.GetHeapSpecificInfo( masterHeapInfo );
PrintHeapInfo( masterHeapInfo );
// Update info ready for writing back to the user-side
if ( r == KErrNone )
{
// Write results back to user-side
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::GetHeapInfoKernel - writing to user-side..."));
r = Kern::ThreadRawWrite( &ClientThread(), aHeapInfo, &masterHeapInfo, sizeof( TMemSpyHeapInfo ) );
}
NKern::ThreadLeaveCS();
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::GetHeapInfoKernel() - END - ret: %d", r) );
return r;
}
TBool DMemSpyDriverLogChanHeapBase::HandleHeapCell( TInt aCellType, TAny* aCellAddress, TInt aLength, TInt /*aNestingLevel*/, TInt /*aAllocNumber*/ )
{
TInt error = KErrNone;
//
if ( aCellType == EMemSpyDriverGoodFreeCell || aCellType == EMemSpyDriverBadFreeCellAddress || aCellType == EMemSpyDriverBadFreeCellSize )
{
TMemSpyDriverFreeCell cell;
cell.iType = aCellType;
cell.iAddress = aCellAddress;
cell.iLength = aLength;
//
if ( iStackStream )
{
if ( !iStackStream->IsFull() )
{
++iFreeCellCount;
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::HandleHeapCell - writing free cell %d @ 0x%08x, space left: %u", iFreeCellCount, aCellAddress, iStackStream->Remaining() ));
//
iStackStream->WriteInt32( aCellType );
iStackStream->WriteUint32( reinterpret_cast<TUint32>( aCellAddress ) );
iStackStream->WriteInt32( aLength );
}
else
{
Kern::Printf( "DMemSpyDriverLogChanHeapBase::HandleHeapCell - Kernel Free Cell stack stream IS FULL!" );
error = KErrAbort;
}
}
else
{
NKern::ThreadEnterCS();
error = iFreeCells.Append( cell );
NKern::ThreadLeaveCS();
//
if ( error == KErrNone )
{
++iFreeCellCount;
}
}
}
//
return ( error == KErrNone );
}
void DMemSpyDriverLogChanHeapBase::HandleHeapWalkInit()
{
// Can't delete the free cell list here as we might be walking the kernel heap
iFreeCellCount = 0;
}
TInt DMemSpyDriverLogChanHeapBase::PrepareFreeCellTransferBuffer()
{
// Transfer free cells immediately from xfer stream
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrepareFreeCellTransferBuffer() - START - iHeapStream: 0x%08x", iHeapStream ));
__ASSERT_ALWAYS( !iHeapStream, MemSpyDriverUtils::PanicThread( ClientThread(), EPanicHeapFreeCellStreamNotClosed ) );
//
TInt r = KErrNoMemory;
//
NKern::ThreadEnterCS();
//
iHeapStream = new RMemSpyMemStreamWriter();
if ( iHeapStream )
{
const TInt requiredMemory = CalculateFreeCellBufferSize();
r = OpenXferStream( *iHeapStream, requiredMemory );
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrepareFreeCellTransferBuffer() - requested %d bytes for free cell list, r: %d", requiredMemory, r ));
if ( r == KErrNone )
{
const TInt count = iFreeCells.Count();
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrepareFreeCellTransferBuffer() - free cell count: %d", count ));
//
iHeapStream->WriteInt32( count );
for( TInt i=0; i<count; i++ )
{
const TMemSpyDriverFreeCell& cell = iFreeCells[ i ];
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrepareFreeCellTransferBuffer() - storing entry: %d", i ));
//
iHeapStream->WriteInt32( cell.iType );
iHeapStream->WriteUint32( reinterpret_cast<TUint32>( cell.iAddress ) );
iHeapStream->WriteInt32( cell.iLength );
}
// Finished with the array now
iFreeCells.Reset();
// We return the amount of client-side memory that needs to be allocated to hold the buffer
r = requiredMemory;
}
}
//
NKern::ThreadLeaveCS();
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::PrepareFreeCellTransferBuffer() - END - r: %d", r));
return r;
}
TInt DMemSpyDriverLogChanHeapBase::FetchFreeCells( TDes8* aBufferSink )
{
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::FetchFreeCells() - START - iHeapStream: 0x%08x", iHeapStream ));
__ASSERT_ALWAYS( iHeapStream, MemSpyDriverUtils::PanicThread( ClientThread(), EPanicHeapFreeCellStreamNotOpen ) );
TInt r = KErrNone;
// Write buffer to client
NKern::ThreadEnterCS();
r = iHeapStream->WriteAndClose( aBufferSink );
// Tidy up
ReleaseFreeCells();
NKern::ThreadLeaveCS();
//
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::FetchFreeCells() - END - r: %d", r));
return r;
}
TInt DMemSpyDriverLogChanHeapBase::CalculateFreeCellBufferSize() const
{
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::CalculateFreeCellBufferSize() - START" ));
const TInt count = iFreeCells.Count();
const TInt entrySize = sizeof( TInt32 ) + sizeof( TInt32 ) + sizeof( TUint32 );
const TInt r = ( count * entrySize ) + sizeof( TInt ); // Extra TInt to hold count
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::CalculateFreeCellBufferSize() - END - r: %d, count: %d, entrySize: %d", r, count, entrySize ));
return r;
}
void DMemSpyDriverLogChanHeapBase::ReleaseFreeCells()
{
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::ReleaseFreeCells() - START - this: 0x%08x", this ));
// Housekeeping
NKern::ThreadEnterCS();
iFreeCells.Reset();
//
iStackStream = NULL;
//
delete iHeapStream;
iHeapStream = NULL;
NKern::ThreadLeaveCS();
TRACE( Kern::Printf("DMemSpyDriverLogChanHeapBase::ReleaseFreeCells() - END - this: 0x%08x", this ));
}
TInt DMemSpyDriverLogChanHeapBase::OpenKernelHeap( RHeapK*& aHeap, DChunk*& aChunk, TDes8* aClientHeapChunkName )
{
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::OpenKernelHeap() - START") );
// This is what we're searching for...
RHeapK* kernelHeap = NULL;
DChunk* kernelHeapChunk = NULL;
// Find the SvHeap chunk....
_LIT( KKernelServerHeapChunkName, "SvHeap" );
NKern::ThreadEnterCS();
DObjectCon* chunkContainer = Kern::Containers()[EChunk];
chunkContainer->Wait();
NKern::LockSystem();
const TInt chunkCount = chunkContainer->Count();
for(TInt i=0; i<chunkCount; i++)
{
DChunk* chunk = (DChunk*) (*chunkContainer)[ i ];
//
if ( chunk->NameBuf() )
{
const TInt findResult = chunk->NameBuf()->Find( KKernelServerHeapChunkName );
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::OpenKernelHeap - checking chunk: %O against %S => %d", chunk, &KKernelServerHeapChunkName, findResult ) );
if ( findResult != KErrNotFound )
{
// Found it.
kernelHeapChunk = chunk;
TRACE_KH( Kern::Printf( "DMemSpyDriverLogChanHeapBase::OpenKernelHeap - found chunk with base: 0x%08x", chunk->iBase ) );
break;
}
}
}
NKern::UnlockSystem();
chunkContainer->Signal();
TInt r = KErrNotFound;
if ( kernelHeapChunk != NULL )
{
#ifndef __WINS__
TRACE_KH( Kern::Printf( "DMemSpyDriverLogChanHeapBase::OpenKernelHeap - kernelHeapChunk: 0x%08x", kernelHeapChunk ) );
const TRomHeader& romHdr = Epoc::RomHeader();
const TRomEntry* primaryEntry = (const TRomEntry*) Kern::SuperPage().iPrimaryEntry;
TRACE_KH( Kern::Printf( "DMemSpyDriverLogChanHeapBase::OpenKernelHeap - primaryEntry: 0x%08x, primaryEntry->iAddressLin: 0x%08x", primaryEntry, primaryEntry->iAddressLin ) );
const TRomImageHeader* primaryImageHeader = (const TRomImageHeader*) primaryEntry->iAddressLin;
TRACE_KH( Kern::Printf( "DMemSpyDriverLogChanHeapBase::OpenKernelHeap - primaryEntry: 0x%08x", primaryImageHeader ) );
TRACE_KH( Kern::Printf( "DMemSpyDriverLogChanHeapBase::OpenKernelHeap - TRomImageHeader::iCodeSize: 0x%08x", primaryImageHeader->iCodeSize ) );
TRACE_KH( Kern::Printf( "DMemSpyDriverLogChanHeapBase::OpenKernelHeap - TRomImageHeader::iTextSize: 0x%08x", primaryImageHeader->iTextSize ) );
TRACE_KH( Kern::Printf( "DMemSpyDriverLogChanHeapBase::OpenKernelHeap - TRomImageHeader::iDataSize: 0x%08x", primaryImageHeader->iDataSize ) );
TRACE_KH( Kern::Printf( "DMemSpyDriverLogChanHeapBase::OpenKernelHeap - TRomImageHeader::iBssSize: 0x%08x", primaryImageHeader->iBssSize ) );
TRACE_KH( Kern::Printf( "DMemSpyDriverLogChanHeapBase::OpenKernelHeap - TRomImageHeader::iHeapSizeMin: 0x%08x", primaryImageHeader->iHeapSizeMin ) );
TRACE_KH( Kern::Printf( "DMemSpyDriverLogChanHeapBase::OpenKernelHeap - TRomImageHeader::iHeapSizeMax: 0x%08x", primaryImageHeader->iHeapSizeMax ) );
TRACE_KH( Kern::Printf( "DMemSpyDriverLogChanHeapBase::OpenKernelHeap - TRomImageHeader::iStackSize: 0x%08x", primaryImageHeader->iStackSize ) );
TRACE_KH( Kern::Printf( "DMemSpyDriverLogChanHeapBase::OpenKernelHeap - romHdr.iKernDataAddress: 0x%08x", romHdr.iKernDataAddress ) );
TRACE_KH( Kern::Printf( "DMemSpyDriverLogChanHeapBase::OpenKernelHeap - Kern::RoundToPageSize( romHdr.iTotalSvDataSize ): 0x%08x", Kern::RoundToPageSize( romHdr.iTotalSvDataSize ) ) );
TRACE_KH( Kern::Printf( "DMemSpyDriverLogChanHeapBase::OpenKernelHeap - Kern::RoundToPageSize( kernelProcessCreateInfo.iStackSize ): 0x%08x", Kern::RoundToPageSize( primaryImageHeader->iStackSize ) ) );
TAny* stack = (TAny*)( romHdr.iKernDataAddress + Kern::RoundToPageSize( romHdr.iTotalSvDataSize ));
TRACE_KH( Kern::Printf( "DMemSpyDriverLogChanHeapBase::OpenKernelHeap - aStack: 0x%08x", stack ) );
// NB: This is supposed to be Kern::RoundToPageSize( kernelProcessCreateInfo.iStackSize ) but that
// sometimes returns very dodgy values on ARMv5 Multiple Memory Model when using MemSpy's driver
// installed via a SIS file. No idea why. Cache problem?
TAny* heap = (TAny*)(TLinAddr( stack ) + Kern::RoundToPageSize( primaryImageHeader->iStackSize ));
TRACE_KH( Kern::Printf( "DMemSpyDriverLogChanHeapBase::OpenKernelHeap - aHeap: 0x%08x", heap ) );
kernelHeap = (RHeapK*) heap;
#else
kernelHeap = (RHeapK*) kernelHeapChunk->Base();
#endif
// Finalise construction of heap
if ( kernelHeap != NULL )
{
//TRACE_KH( Kern::Printf( "DMemSpyDriverLogChanHeapBase::OpenKernelHeap - kernelHeap->Base(): 0x%08x, kernelHeapChunk->Base(): 0x%08x", kernelHeap->Base(), kernelHeapChunk->Base() ) );
aHeap = kernelHeap;
aChunk = kernelHeapChunk;
// Get the chunk name (if the caller asked for it)
if ( aClientHeapChunkName )
{
kernelHeapChunk->FullName( *aClientHeapChunkName );
}
// Opened okay
r = KErrNone;
}
else
{
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::OpenKernelHeap - kernel heap was NULL..."));
}
}
else
{
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::OpenKernelHeap - couldnt find kernel chunk..."));
r = KErrNotFound;
}
NKern::ThreadLeaveCS();
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::OpenKernelHeap() - END - ret: %d", r ) );
return r;
}
TInt DMemSpyDriverLogChanHeapBase::OpenKernelHeap( RMemSpyDriverRHeapKernelInPlace& aHeap, TDes8* aClientHeapChunkName )
{
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::OpenKernelHeap(IP) - START") );
RHeapK* heap = NULL;
DChunk* chunk = NULL;
TInt r = OpenKernelHeap( heap, chunk, aClientHeapChunkName );
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::OpenKernelHeap(IP) - open err: %d", r ) );
if ( r == KErrNone )
{
aHeap.SetKernelHeap( *heap );
aHeap.AssociateWithKernelChunk( chunk, TLinAddr( chunk->iBase ), 0 );
}
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::OpenKernelHeap(IP) - END - ret: %d", r ) );
return r;
}
TInt DMemSpyDriverLogChanHeapBase::OpenKernelHeap( RMemSpyDriverRHeapKernelFromCopy& aHeap, TDes8* aClientHeapChunkName )
{
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::OpenKernelHeap(CP) - START") );
RHeapK* heap = NULL;
DChunk* chunk = NULL;
TInt r = OpenKernelHeap( heap, chunk, aClientHeapChunkName );
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::OpenKernelHeap(CP) - open err: %d", r ) );
if ( r == KErrNone )
{
#ifdef __SYMBIAN_KERNEL_HYBRID_HEAP__
// RAllocator::Size() not exported on hybrid heap
const TInt heapSize = heap->DebugFunction(RAllocator::EGetSize);
#else
const TInt heapSize = heap->Size();
#endif
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::OpenKernelHeap(CP) - heapSize: %d, heap: 0x%08x, chunkBase: 0x%08x", heapSize, heap, chunk->Base() ) );
// Make a new chunk that we can copy the kernel heap into. We cannot lock the system the entire time
// we need to do this, therefore there is no guarantee that the chunk will be large enough to hold the
// (current) heap data at the time we need to make the copy. We oversize the chunk by 1mb in the "hope"
// that it will be enough... :(
TChunkCreateInfo info;
info.iType = TChunkCreateInfo::ESharedKernelSingle;
info.iMaxSize = heapSize + ( 1024 * 1024 );
info.iOwnsMemory = ETrue; // Use memory from system's free pool
info.iDestroyedDfc = NULL;
#ifdef __EPOC32__
info.iMapAttr = (TInt)EMapAttrFullyBlocking; // Full caching
#endif
// Holds a copy of the client's heap chunk
DChunk* heapCopyChunk;
TLinAddr heapCopyChunkAddress;
TUint32 heapCopyChunkMappingAttributes;
r = Kern::ChunkCreate( info, heapCopyChunk, heapCopyChunkAddress, heapCopyChunkMappingAttributes );
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::OpenKernelHeap(CP) - creating chunk returned: %d", r));
if ( r == KErrNone )
{
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::OpenKernelHeap(CP) - copy chunk base: 0x%08x, heapCopyChunkAddress: 0x%08x", heapCopyChunk->iBase, heapCopyChunkAddress));
// Commit memory for entire buffer
TUint32 physicalAddress = 0;
r = Kern::ChunkCommitContiguous( heapCopyChunk, 0, heapSize, physicalAddress );
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::OpenKernelHeap(CP) - commiting chunk returned: %d", r));
if ( r != KErrNone)
{
// On error, throw away the chunk we have created
Kern::ChunkClose( heapCopyChunk );
heapCopyChunk = NULL;
}
else
{
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::OpenKernelHeap(CP) - heapCopyChunk->iSize: 0x%08x, heapCopyChunk->iBase: 0x%08x, heapCopyChunkAddress: 0x%08x, physicalAddress: 0x%08x", heapCopyChunk->iSize, heapCopyChunk->iBase, heapCopyChunkAddress, physicalAddress));
NKern::LockSystem();
const TUint32 copyLength = heapSize; // TODO Min( heap->Size(), heapSize );
//TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::OpenKernelHeap(CP) - trying to copy %d (vs orig estimate of %d) bytes from kernel allocator address: 0x%08x", copyLength, heapSize, heap->Base() ));
memcpy( (TUint8*) heapCopyChunkAddress, heap, copyLength );
NKern::UnlockSystem();
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::OpenKernelHeap(CP) - copied kernel heap data" ));
// Transfer ownership of the copy heap chunk to the heap object. This also calculates the delta
// beween the heap addresses in the client's address space and the kernel address space.
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::OpenKernelHeap(CP) - associate chunk and transfer ownership..." ));
aHeap.SetKernelHeap( *heap );
aHeap.AssociateWithKernelChunk( heapCopyChunk, heapCopyChunkAddress, heapCopyChunkMappingAttributes );
}
}
else
{
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::OpenKernelHeap(CP) - copy chunk create error: %d", r ) );
}
}
TRACE_KH( Kern::Printf("DMemSpyDriverLogChanHeapBase::OpenKernelHeap(CP) - END - ret: %d", r ) );
return r;
}