FCL/sf/os/osrndtools: comparison memspy/Engine/Source/Helpers/MemSpyEngineHelperHeap.cpp

equal deleted inserted replaced

-:ca8a1b6995f6
+:52e343bb8f80
 _LIT( KCellTypeGoodFreeCell,             "[Free Cell]                 ");
 _LIT( KCellTypeBadAllocatedCellSize,     "[Bad Allocated Cell Size]   ");
 _LIT( KCellTypeBadAllocatedCellAddress,  "[Bad Allocated Cell Address]");
 _LIT( KCellTypeBadFreeCellAddress,       "[Bad Free Cell Address]     ");
 _LIT( KCellTypeBadFreeCellSize,          "[Bad Free Cell Size]        ");
-_LIT( KCellTypeBad,                      "[Bad Cell]                  ");
 _LIT( KCellTypeUnknown,                  "[Unknown!]                  ");
 _LIT( KCellListLineFormat, "%S cell: 0x%08x, cellLen: %8d, allocNum: %8d, nestingLev: %8d, cellData: 0x%08x, cellDataAddr: 0x%08x, headerSize: %02d");
 _LIT( KMemSpyMarkerHeapData, "<%SMEMSPY_HEAP_DATA_%03d>" );
 _LIT( KMemSpyMarkerCSV, "<%SMEMSPY_HEAP_CSV>" );
 _LIT( KMemSpyPrefixHeapData, "HeapData - %S - ");
 const TInt error = iEngine.Driver().GetHeapInfoUser( heapInfo, aThread.Id(), freeCells );
 if ( error == KErrNone )
 {
 UpdateSharedHeapInfoL( aThread.Process().Id(), aThread.Id(), heapInfo );
 }
-if  ( error == KErrNone && heapInfo.Type() != TMemSpyHeapInfo::ETypeUnknown )
+if  ( error == KErrNone && heapInfo.Type() == TMemSpyHeapInfo::ETypeRHeap )
 {
 // Get thread name for context
 const TFullName pName( aThread.FullName() );
 // Begin a new data stream
 while( r == KErrNone )
 {
 TUint fourByteCellData = 0;
 TPtrC pType(KNullDesC);
 //
-				if (cellType & EMemSpyDriverAllocatedCellMask)
+switch(cellType)
-					{
+{
+case EMemSpyDriverGoodAllocatedCell:
+{
 r = iEngine.Driver().WalkHeapReadCellData( cellAddress, cellData, 4 );
 if  ( r == KErrNone )
 {
 fourByteCellData = DescriptorAsDWORD( cellData );
 }
 pType.Set(KCellTypeGoodAllocatedCell);
+break;
 }
-				else if (cellType & EMemSpyDriverFreeCellMask)
+case EMemSpyDriverGoodFreeCell:
-					{
 pType.Set(KCellTypeGoodFreeCell);
-					}
+break;
-				else if (cellType & EMemSpyDriverBadCellMask)
+case EMemSpyDriverBadAllocatedCellSize:
-					{
+pType.Set(KCellTypeBadAllocatedCellSize);
-					switch (cellType)
+break;
-						{
+case EMemSpyDriverBadAllocatedCellAddress:
-					case EMemSpyDriverHeapBadAllocatedCellSize:
+pType.Set(KCellTypeBadAllocatedCellAddress);
-						pType.Set(KCellTypeBadAllocatedCellSize);
+break;
-						break;
+case EMemSpyDriverBadFreeCellAddress:
-					case EMemSpyDriverHeapBadAllocatedCellAddress:
+pType.Set(KCellTypeBadFreeCellAddress);
-						pType.Set(KCellTypeBadAllocatedCellAddress);
+break;
-						break;
+case EMemSpyDriverBadFreeCellSize:
-					case EMemSpyDriverHeapBadFreeCellAddress:
+pType.Set(KCellTypeBadFreeCellSize);
-						pType.Set(KCellTypeBadFreeCellAddress);
+break;
-						break;
+default:
-					case EMemSpyDriverHeapBadFreeCellSize:
-						pType.Set(KCellTypeBadFreeCellSize);
-						break;
-					default:
-						pType.Set(KCellTypeBad);
-						break;
-						}
-					}
-				else
-					{
 pType.Set(KCellTypeUnknown);
+break;
 }
 if  ( r == KErrNone )
 {
 pTempBuffer.Format( KCellListLineFormat, &pType, cellAddress, cellLength, cellAllocationNumber, cellNestingLevel, fourByteCellData, cellPayloadAddress, cellHeaderSize );
 void CMemSpyEngineHelperHeap::OutputHeapDataUserL( const CMemSpyThread& aThread, TBool aCreateDataStream )
 {
 // Make sure the process is suspended for the entire time we are manipulating it's heap
 iEngine.ProcessSuspendLC( aThread.Process().Id() );
-// Get the heap info, including cell information
+// Get the heap info, including free cell information
-RArray<TMemSpyDriverCell> cells;
+RArray<TMemSpyDriverFreeCell> freeCells;
-CleanupClosePushL( cells );
+CleanupClosePushL( freeCells );
 TMemSpyHeapInfo heapInfo;
 TRACE( RDebug::Printf( "CMemSpyEngineHelperHeap::OutputHeapDataUserL() - checksum1: 0x%08x", heapInfo.AsRHeap().Statistics().StatsFree().Checksum() ) );
-GetHeapInfoUserL(aThread.Process().Id(), aThread.Id(), heapInfo, &cells, ETrue);
+GetHeapInfoUserL( aThread.Process().Id(), aThread.Id(), heapInfo, &freeCells );
 TRACE( RDebug::Printf( "CMemSpyEngineHelperHeap::OutputHeapDataUserL() - checksum2: 0x%08x", heapInfo.AsRHeap().Statistics().StatsFree().Checksum() ) );
 // Get the heap data
 const TFullName pName( aThread.FullName() );
-OutputHeapDataUserL( aThread.Process().Id(), aThread.Id(), pName, heapInfo, aCreateDataStream, &cells );
+OutputHeapDataUserL( aThread.Process().Id(), aThread.Id(), pName, heapInfo, aCreateDataStream, &freeCells );
-CleanupStack::PopAndDestroy( &cells );
+CleanupStack::PopAndDestroy( &freeCells );
 // Resume process
 CleanupStack::PopAndDestroy();
 }
-EXPORT_C void CMemSpyEngineHelperHeap::OutputHeapDataUserL(const TProcessId& aPid, const TThreadId& aTid, const TDesC& aThreadName, const TMemSpyHeapInfo& aInfo, const RArray<TMemSpyDriverCell>* aCells)
+EXPORT_C void CMemSpyEngineHelperHeap::OutputHeapDataUserL( const TProcessId& aPid, const TThreadId& aTid, const TDesC& aThreadName, const TMemSpyHeapInfo& aInfo, const RArray<TMemSpyDriverFreeCell>* aFreeCells )
 {
-OutputHeapDataUserL(aPid, aTid, aThreadName, aInfo, ETrue, aCells);
+OutputHeapDataUserL( aPid, aTid, aThreadName, aInfo, ETrue, aFreeCells );
 }
-void CMemSpyEngineHelperHeap::OutputHeapDataUserL( const TProcessId& aPid, const TThreadId& aTid, const TDesC& aThreadName, const TMemSpyHeapInfo& aInfo, TBool aCreateDataStream, const RArray<TMemSpyDriverCell>* aCells )
+void CMemSpyEngineHelperHeap::OutputHeapDataUserL( const TProcessId& aPid, const TThreadId& aTid, const TDesC& aThreadName, const TMemSpyHeapInfo& aInfo, TBool aCreateDataStream, const RArray<TMemSpyDriverFreeCell>* aFreeCells )
 {
 TBuf<KMaxFullName + 100> printFormat;
 // Begin a new data stream
 if  ( aCreateDataStream )
 // Set overall prefix
 iEngine.Sink().OutputPrefixSetFormattedLC( KMemSpyPrefixHeapData, &aThreadName );
 // Info section
-OutputHeapInfoL( aInfo, aThreadName, aCells );
+OutputHeapInfoL( aInfo, aThreadName, aFreeCells );
 // Code segments (needed for map file reading...)
 _LIT(KCellListCodeSegInfoFormat, "CodeSegs - ");
 iEngine.HelperCodeSegment().OutputCodeSegmentsL( aPid, printFormat, KCellListCodeSegInfoFormat, '-', ETrue );
 // a mismatch in free cell information).
 const TUint32 checksum = aInfo.AsRHeap().Statistics().StatsFree().Checksum();
 TRACE( RDebug::Printf( "CMemSpyEngineHelperHeap::OutputHeapDataUserL() - checksum: 0x%08x", checksum ) );
 TInt r = iEngine.Driver().GetHeapData( aTid, checksum, pData, readAddress, remaining );
-	TUint prevEndAddress = readAddress + pData.Length();
+if  ( r == KErrNone )
-if (r == KErrNone)
+{
-{
+while ( r == KErrNone )
-while (r == KErrNone)
 {
-			if (readAddress > prevEndAddress)
-				{
-				// We've hit a discontinuity, ie one or more unmapped pages
-				_LIT(KBreak, "........");
-				iEngine.Sink().OutputLineL(KBreak);
-				}
 _LIT(KHeapDumpDataFormat, "%S");
-iEngine.Sink().OutputBinaryDataL(KHeapDumpDataFormat, pData.Ptr(), (const TUint8*) readAddress, pData.Length());
+iEngine.Sink().OutputBinaryDataL( KHeapDumpDataFormat, pData.Ptr(), (const TUint8*) readAddress, pData.Length() );
-			readAddress += pData.Length();
+if  ( remaining > 0 )
-if (remaining > 0)
+r = iEngine.Driver().GetHeapDataNext( aTid, pData, readAddress, remaining );
-				{
-				prevEndAddress = readAddress;
-r = iEngine.Driver().GetHeapDataNext(aTid, pData, readAddress, remaining);
-				}
 else
 break;
 }
 }
 else
-EXPORT_C void CMemSpyEngineHelperHeap::OutputHeapInfoL( const TMemSpyHeapInfo& aInfo, const TDesC& aThreadName, const RArray<TMemSpyDriverCell>* aCells )
-	{
-CMemSpyEngineOutputList* list = NewHeapSummaryExtendedLC(aInfo, aCells);
+EXPORT_C void CMemSpyEngineHelperHeap::OutputHeapInfoL( const TMemSpyHeapInfo& aInfo, const TDesC& aThreadName, const RArray<TMemSpyDriverFreeCell>* aFreeCells )
+{
+CMemSpyEngineOutputList* list = NewHeapSummaryExtendedLC( aInfo, aFreeCells );
 // Format the thread name according to upper/lower case request parameters
 _LIT( KOverallCaption1, "HEAP INFO FOR THREAD '%S'");
 list->InsertItemFormatUCL( 0, KOverallCaption1, &aThreadName );
 list->InsertUnderlineForItemAtL( 0 );
 void CMemSpyEngineHelperHeap::OutputCSVEntryL( TInt aIndex, const TMemSpyHeapInfo& aInfo, const TDesC& aThreadName, const TDesC& aProcessName )
 {
 const TMemSpyHeapInfoRHeap& rHeapInfo = aInfo.AsRHeap();
 const TMemSpyHeapMetaDataRHeap& rHeapMetaData = rHeapInfo.MetaData();
+const TMemSpyHeapObjectDataRHeap& rHeapObjectData = rHeapInfo.ObjectData();
 const TMemSpyHeapStatisticsRHeap& rHeapStats = rHeapInfo.Statistics();
 // Example:
 //
 //  <ENTRY_001>
 iEngine.Sink().OutputLineFormattedL( KFmtFieldContent,
 &KFmtFields,
 aIndex,
 aInfo.Tid(),
 rHeapMetaData.ChunkHandle(),
-/*rHeapObjectData.Base(),*/ rHeapMetaData.iAllocatorAddress,
+rHeapObjectData.Base(),
-/*rHeapObjectData.Size(),*/ rHeapMetaData.iHeapSize,
+rHeapObjectData.Size(),
-/*rHeapObjectData.iMinLength,*/ rHeapMetaData.iMinHeapSize,
+rHeapObjectData.iMinLength,
-/*rHeapObjectData.iMaxLength,*/ rHeapMetaData.iMaxHeapSize,
+rHeapObjectData.iMaxLength,
-/*rHeapObjectData.iFree.next,*/ NULL,
+rHeapObjectData.iFree.next,
-/*rHeapObjectData.iFree.len,*/ 0,
+rHeapObjectData.iFree.len,
 rHeapStats.StatsFree().TypeCount(),
 rHeapStats.StatsFree().TypeSize(),
 rHeapStats.StatsFree().SlackSpaceCellSize(),
 rHeapStats.StatsFree().LargestCellSize(),
 rHeapStats.StatsAllocated().LargestCellSize(),
-/*rHeapObjectData.iCellCount,*/ rHeapStats.StatsAllocated().TypeCount(),
+rHeapObjectData.iCellCount,
-/*rHeapObjectData.iMinCell,*/ 0,
+rHeapObjectData.iMinCell,
-/*rHeapObjectData.iTotalAllocSize,*/ rHeapStats.StatsAllocated().TypeSize(),
+rHeapObjectData.iTotalAllocSize,
 rHeapMetaData.IsSharedHeap(),
 &KFmtFields,
 aIndex
 );
 if  ( aIncludeKernel )
 {
 // Get kernel heap info
 GetHeapInfoKernelL( info );
-if ( info.Type() != TMemSpyHeapInfo::ETypeUnknown )
+if ( info.Type() == TMemSpyHeapInfo::ETypeRHeap )
 {
 TName threadName;
 MemSpyEngineUtils::GetKernelHeapThreadAndProcessNames( threadName, processName );
 OutputCSVEntryL( index++, info, threadName, processName );
 }
 const TInt error = iEngine.Driver().GetHeapInfoUser( info, thread.Id() );
 if ( error == KErrNone )
 {
 UpdateSharedHeapInfoL( process.Id(), thread.Id(), info );
 }
-if  ( error == KErrNone && info.Type() != TMemSpyHeapInfo::ETypeUnknown )
+if  ( error == KErrNone && info.Type() == TMemSpyHeapInfo::ETypeRHeap )
 {
 OutputCSVEntryL( index++, info, threadName, processName );
 }
 }
-EXPORT_C void CMemSpyEngineHelperHeap::GetHeapInfoUserL(const TProcessId& aProcess, const TThreadId& aThread, TMemSpyHeapInfo& aInfo, RArray<TMemSpyDriverFreeCell>* aFreeCells)
+EXPORT_C void CMemSpyEngineHelperHeap::GetHeapInfoUserL( const TProcessId& aProcess, const TThreadId& aThread, TMemSpyHeapInfo& aInfo, RArray<TMemSpyDriverFreeCell>* aFreeCells )
-{
-	GetHeapInfoUserL(aProcess, aThread, aInfo, aFreeCells, EFalse);
-	}
-EXPORT_C void CMemSpyEngineHelperHeap::GetHeapInfoUserL(const TProcessId& aProcess, const TThreadId& aThread, TMemSpyHeapInfo& aInfo, RArray<TMemSpyDriverCell>* aCells, TBool aCollectAllocatedCellsAsWellAsFree)
 {
 iEngine.ProcessSuspendLC( aProcess );
 TRACE( RDebug::Printf( "CMemSpyEngineHelperHeap::GetHeapInfoUserL() - checksum1: 0x%08x", aInfo.AsRHeap().Statistics().StatsFree().Checksum() ) );
 TInt r = KErrNone;
 //
-if  (aCells)
+if  ( aFreeCells )
 {
-r = iEngine.Driver().GetHeapInfoUser( aInfo, aThread, *aCells, aCollectAllocatedCellsAsWellAsFree);
+r = iEngine.Driver().GetHeapInfoUser( aInfo, aThread, *aFreeCells );
 }
 else
 {
 r = iEngine.Driver().GetHeapInfoUser( aInfo, aThread );
 }
 // Dump section
 _LIT(KHeaderDump, "Heap Data");
 iEngine.Sink().OutputSectionHeadingL( KHeaderDump, '-' );
-/*TOMSCI TODO this stuff needs fixing
+_LIT(KHeapDumpDataFormat, "%S");
-	_LIT(KHeapDumpDataFormat, "%S");
 const TUint8* heapBaseAddress = info.AsRHeap().ObjectData().Base();
 iEngine.Sink().OutputBinaryDataL( KHeapDumpDataFormat, data->Ptr(), heapBaseAddress, data->Length() );
-	*/
 CleanupStack::PopAndDestroy(); // clear prefix
 CleanupStack::PopAndDestroy( data );
 CleanupStack::PopAndDestroy( &freeCells );
 if ( aInfo.Type() == TMemSpyHeapInfo::ETypeUnknown )
 {
 _LIT( KItem0_Type_Unknown, "Unknown" );
 list->AddItemL( KItem0, KItem0_Type_Unknown );
 }
-else
+else if ( aInfo.Type() == TMemSpyHeapInfo::ETypeRHeap )
 {
 const TMemSpyHeapInfoRHeap& rHeap = aInfo.AsRHeap();
 const TMemSpyHeapMetaDataRHeap& metaData = rHeap.MetaData();
+const TMemSpyHeapObjectDataRHeap& objectData = rHeap.ObjectData();
 const TMemSpyHeapStatisticsRHeap& statistics = rHeap.Statistics();
 _LIT( KItem0_Type_RHeap, "RHeap" );
-_LIT( KItem0_Type_RHybridHeap, "RHybridHeap" );
+list->AddItemL( KItem0, KItem0_Type_RHeap );
-		if (aInfo.Type() == TMemSpyHeapInfo::ETypeRHeap)
-			{
-	        list->AddItemL( KItem0, KItem0_Type_RHeap );
-			}
-		else
-			{
-	        list->AddItemL( KItem0, KItem0_Type_RHybridHeap );
-			}
 // Heap size is the size of the heap minus the size of the embedded (in-place) RHeap.
 _LIT( KItem1, "Heap size" );
-list->AddItemL(KItem1, metaData.iHeapSize);
+list->AddItemL( KItem1, objectData.Size() );
-_LIT( KItem8b, "Allocator address" );
+_LIT( KItem8b, "Heap base address" );
-list->AddItemHexL( KItem8b, (TUint)metaData.iAllocatorAddress );
+list->AddItemHexL( KItem8b, (TUint) objectData.Base() );
 _LIT( KItem1b, "Shared" );
 list->AddItemYesNoL( KItem1b, metaData.IsSharedHeap() );
 // This is the size (rounded to the page) of memory associated with
 list->AddItemL( KItem7, statistics.StatsFree().SlackSpaceCellSize() );
 // Fragmentation is a measurement of free space scattered throughout the heap, but ignoring
 // any slack space at the end (which can often be recovered, to the granularity of one page of ram)
 _LIT( KItem8a, "Fragmentation" );
-list->AddItemPercentageL( KItem8a, metaData.iHeapSize, ( statistics.StatsFree().TypeSize()  - statistics.StatsFree().SlackSpaceCellSize() ) );
+list->AddItemPercentageL( KItem8a, objectData.Size(), ( statistics.StatsFree().TypeSize()  - statistics.StatsFree().SlackSpaceCellSize() ) );
+_LIT( KItem13, "Header size (A)" );
+list->AddItemL( KItem13, metaData.HeaderSizeAllocated() );
+_LIT( KItem14, "Header size (F)" );
+list->AddItemL( KItem14, metaData.HeaderSizeFree() );
+_LIT( KItem9a, "Overhead (alloc)" );
+const TInt allocOverhead = metaData.HeaderSizeAllocated() * statistics.StatsAllocated().TypeCount();
+list->AddItemL( KItem9a, allocOverhead );
+_LIT( KItem9b, "Overhead (free)" );
+const TInt freeOverhead = metaData.HeaderSizeFree() * statistics.StatsFree().TypeCount();
+list->AddItemL( KItem9b, freeOverhead );
 _LIT( KItem9c, "Overhead (total)" );
-		const TInt totalOverhead = metaData.iHeapSize - statistics.StatsAllocated().TypeSize();
+const TInt totalOverhead = freeOverhead + allocOverhead;
 list->AddItemL( KItem9c, totalOverhead );
 _LIT( KItem9d, "Overhead" );
-list->AddItemPercentageL( KItem9d, metaData.iHeapSize, totalOverhead  );
+list->AddItemPercentageL( KItem9d, objectData.Size(), totalOverhead  );
 _LIT( KItem10, "Min. length" );
-list->AddItemL( KItem10, metaData.iMinHeapSize );
+list->AddItemL( KItem10, objectData.iMinLength );
 _LIT( KItem11, "Max. length" );
-list->AddItemL( KItem11, metaData.iMaxHeapSize );
+list->AddItemL( KItem11, objectData.iMaxLength );
 _LIT( KItem12, "Debug Allocator Library" );
 list->AddItemYesNoL( KItem12, metaData.IsDebugAllocator() );
 }
 return list;
 }
-EXPORT_C CMemSpyEngineOutputList* CMemSpyEngineHelperHeap::NewHeapSummaryExtendedLC( const TMemSpyHeapInfo& aInfo, const RArray<TMemSpyDriverCell>* aCells )
+EXPORT_C CMemSpyEngineOutputList* CMemSpyEngineHelperHeap::NewHeapSummaryExtendedLC( const TMemSpyHeapInfo& aInfo, const RArray<TMemSpyDriverFreeCell>* aFreeCells )
-	{
+{
 CMemSpyEngineOutputList* list = CMemSpyEngineOutputList::NewLC( iEngine.Sink() );
 //
 AppendMetaDataL( aInfo, *list );
+AppendObjectDataL( aInfo, *list );
 AppendStatisticsL( aInfo, *list );
 //
-if  ( aCells )
+if  ( aFreeCells )
 {
-AppendCellsL( *aCells, *list );
+AppendFreeCellsL( *aFreeCells, *list );
 }
 //
 return list;
 }
-//cigasto: not formatted - raw heap info
-EXPORT_C TMemSpyHeapData CMemSpyEngineHelperHeap::NewHeapRawInfo( const TMemSpyHeapInfo& aInfo )
-	{
-	_LIT(KUnknown, "Unknown");
-	TMemSpyHeapData list;
-	list.iType.Copy(KUnknown);
-	// Heap type
-	if (aInfo.Type() != TMemSpyHeapInfo::ETypeUnknown)
-		{
-		const TMemSpyHeapInfoRHeap& rHeap = aInfo.AsRHeap();
-		const TMemSpyHeapMetaDataRHeap& metaData = rHeap.MetaData();
-		const TMemSpyHeapStatisticsRHeap& statistics = rHeap.Statistics();
-		_LIT(KRHeap, "RHeap");
-		_LIT(KRHybridHeap, "RHybridHeap");
-		switch (aInfo.Type())
-			{
-			case TMemSpyHeapInfo::ETypeRHeap:
-				list.iType.Copy(KRHeap);
-				break;
-			case TMemSpyHeapInfo::ETypeRHybridHeap:
-				list.iType.Copy(KRHybridHeap);
-				break;
-			default:
-				break;
-			}
-	    // Heap size is the total amount of memory committed to the heap, which includes the size of the embedded (in-place) RHeap/RHybridHeap.
-	    list.iSize = metaData.iHeapSize;
-	    list.iBaseAddress = (TUint)metaData.iAllocatorAddress; // TODO we can't do the base address any more, allocator address is the closest thing
-	    list.iShared = metaData.IsSharedHeap();
-	    list.iChunkSize = metaData.ChunkSize();
-	    list.iAllocationsCount = statistics.StatsAllocated().TypeCount();
-	    list.iFreeCount = statistics.StatsFree().TypeCount();
-	    list.iBiggestAllocation = statistics.StatsAllocated().LargestCellSize();
-	    list.iBiggestFree = statistics.StatsFree().LargestCellSize();
-	    list.iTotalAllocations =  statistics.StatsAllocated().TypeSize();
-	    list.iTotalFree =  statistics.StatsFree().TypeSize();
-	    list.iSlackFreeSpace = statistics.StatsFree().SlackSpaceCellSize();
-	    list.iFragmentation = statistics.StatsFree().TypeSize() - statistics.StatsFree().SlackSpaceCellSize(); //to calculate percentage value use iSize as 100% value
-	    list.iHeaderSizeA = 0; //metaData.HeaderSizeAllocated();
-	    list.iHeaderSizeF = 0; //metaData.HeaderSizeFree();
-	    TInt allocOverhead = rHeap.Overhead(); //metaData.HeaderSizeAllocated() * statistics.StatsAllocated().TypeCount();
-	    list.iAllocationOverhead = allocOverhead;
-	    //TInt freeOverhead = metaData.HeaderSizeFree() * statistics.StatsFree().TypeCount();
-	    list.iFreeOverhead = 0; // TODO there is no way of calculating this
-	    list.iTotalOverhead = allocOverhead; // freeOverhead + allocOverhead
-	    list.iOverhead = allocOverhead; //freeOverhead + allocOverhead; //to calculate percentage value use iSize as 100% value
-	    list.iMinLength = metaData.iMinHeapSize;
-	    list.iMaxLength = metaData.iMaxHeapSize;
-	    list.iDebugAllocatorLibrary = metaData.IsDebugAllocator();
-		}
-	return list;
-	}
 aList.AddItemL( KOverallCaption1 );
 aList.AddUnderlineForPreviousItemL( '=', 0 );
 // Type
 _LIT( KMetaData_Type,  "Type:" );
-if ( aInfo.Type() == TMemSpyHeapInfo::ETypeUnknown )
+if ( aInfo.Type() != TMemSpyHeapInfo::ETypeRHeap )
 {
 _LIT( KMetaData_Type_Unknown,  "Unknown" );
 aList.AddItemL( KMetaData_Type, KMetaData_Type_Unknown );
 }
 else
 {
 const TMemSpyHeapMetaDataRHeap& metaData = rHeap.MetaData();
 // Type
 _LIT( KMetaData_Type_RHeap,  "Symbian OS RHeap" );
-_LIT( KMetaData_Type_RHybridHeap,  "Symbian OS RHybridHeap" );
+aList.AddItemL( KMetaData_Type, KMetaData_Type_RHeap );
-		if (aInfo.Type() == TMemSpyHeapInfo::ETypeRHeap)
-			{
-	        aList.AddItemL( KMetaData_Type, KMetaData_Type_RHeap );
-			}
-		else
-			{
-			aList.AddItemL( KMetaData_Type, KMetaData_Type_RHybridHeap );
-			}
 // VTable
-//_LIT( KMetaData_VTable,  "VTable:" );
+_LIT( KMetaData_VTable,  "VTable:" );
-//aList.AddItemHexL( KMetaData_VTable, metaData.VTable() );
+aList.AddItemHexL( KMetaData_VTable, metaData.VTable() );
 // Object size
-//_LIT( KMetaData_ObjectSize,  "Object Size:" );
+_LIT( KMetaData_ObjectSize,  "Object Size:" );
-//aList.AddItemL( KMetaData_ObjectSize, metaData.ClassSize() );
+aList.AddItemL( KMetaData_ObjectSize, metaData.ClassSize() );
 // Chunk name
 _LIT( KMetaData_ChunkName,  "Chunk Name:" );
 TPtrC pChunkName( metaData.ChunkName() );
 aList.AddItemL( KMetaData_ChunkName, pChunkName );
 // Debug allocator
 _LIT( KMetaData_DebugAllocator,  "Debug Allocator:" );
 aList.AddItemYesNoL( KMetaData_DebugAllocator, metaData.IsDebugAllocator() );
+// Cell header overhead (free cells)
+_LIT( KMetaData_CellHeaderOverheadFree,  "Overhead (Free):" );
+aList.AddItemL( KMetaData_CellHeaderOverheadFree, metaData.HeaderSizeFree() );
+// Cell header overhead (allocated cells)
+_LIT( KMetaData_CellHeaderOverheadAlloc,  "Overhead (Alloc):" );
+aList.AddItemL( KMetaData_CellHeaderOverheadAlloc, metaData.HeaderSizeAllocated() );
 // Shared Heap
 _LIT( KMetaData_Shared,  "Shared:" );
 aList.AddItemYesNoL( KMetaData_Shared, metaData.IsSharedHeap() );
 // Add ROM info
 }
 aList.AddBlankItemL( 1 );
 }
+void CMemSpyEngineHelperHeap::AppendObjectDataL( const TMemSpyHeapInfo& aInfo, CMemSpyEngineOutputList& aList )
+{
+if ( aInfo.Type() == TMemSpyHeapInfo::ETypeRHeap )
+{
+const TMemSpyHeapInfoRHeap& rHeap = aInfo.AsRHeap();
+const TMemSpyHeapObjectDataRHeap& objectData = rHeap.ObjectData();
+// Make caption
+_LIT( KOverallCaption1, "RAllocator" );
+aList.AddItemL( KOverallCaption1 );
+aList.AddUnderlineForPreviousItemL( '=', 0 );
+// RAllocator
+_LIT( KObjectData_RAllocator_iAccessCount,  "RAllocator::iAccessCount" );
+aList.AddItemL( KObjectData_RAllocator_iAccessCount, objectData.iAccessCount );
+_LIT( KObjectData_RAllocator_iHandleCount,  "RAllocator::iHandleCount" );
+aList.AddItemL( KObjectData_RAllocator_iHandleCount, objectData.iHandleCount );
+_LIT( KObjectData_RAllocator_iHandles,  "RAllocator::iHandles" );
+aList.AddItemL( KObjectData_RAllocator_iHandles, objectData.iHandles );
+_LIT( KObjectData_RAllocator_iFlags,  "RAllocator::iFlags" );
+aList.AddItemHexL( KObjectData_RAllocator_iFlags, objectData.iFlags );
+_LIT( KObjectData_RAllocator_iCellCount,  "RAllocator::iCellCount" );
+aList.AddItemL( KObjectData_RAllocator_iCellCount, objectData.iCellCount );
+_LIT( KObjectData_RAllocator_iTotalAllocSize,  "RAllocator::iTotalAllocSize" );
+aList.AddItemL( KObjectData_RAllocator_iTotalAllocSize, objectData.iTotalAllocSize );
+aList.AddBlankItemL( 1 );
+// Make caption
+_LIT( KOverallCaption2, "RHeap" );
+aList.AddItemL( KOverallCaption2 );
+aList.AddUnderlineForPreviousItemL( '=', 0 );
+// RHeap
+_LIT( KObjectData_RHeap_iMinLength,  "RHeap::iMinLength" );
+aList.AddItemL( KObjectData_RHeap_iMinLength, objectData.iMinLength );
+_LIT( KObjectData_RHeap_iMaxLength,  "RHeap::iMaxLength" );
+aList.AddItemL( KObjectData_RHeap_iMaxLength, objectData.iMaxLength );
+_LIT( KObjectData_RHeap_iOffset,  "RHeap::iOffset" );
+aList.AddItemL( KObjectData_RHeap_iOffset, objectData.iOffset );
+_LIT( KObjectData_RHeap_iGrowBy,  "RHeap::iGrowBy" );
+aList.AddItemL( KObjectData_RHeap_iGrowBy, objectData.iGrowBy );
+_LIT( KObjectData_RHeap_iChunkHandle,  "RHeap::iChunkHandle" );
+aList.AddItemHexL( KObjectData_RHeap_iChunkHandle, objectData.iChunkHandle );
+_LIT( KObjectData_RHeap_iBase,  "RHeap::iBase" );
+aList.AddItemL( KObjectData_RHeap_iBase, objectData.iBase );
+_LIT( KObjectData_RHeap_iTop,  "RHeap::iTop" );
+aList.AddItemL( KObjectData_RHeap_iTop, objectData.iTop );
+_LIT( KObjectData_RHeap_iAlign,  "RHeap::iAlign" );
+aList.AddItemL( KObjectData_RHeap_iAlign, objectData.iAlign );
+_LIT( KObjectData_RHeap_iMinCell,  "RHeap::iMinCell" );
+aList.AddItemL( KObjectData_RHeap_iMinCell, objectData.iMinCell );
+_LIT( KObjectData_RHeap_iPageSize,  "RHeap::iPageSize" );
+aList.AddItemL( KObjectData_RHeap_iPageSize, objectData.iPageSize );
+_LIT( KObjectData_RHeap_iFree_next,  "RHeap::iFree.next" );
+aList.AddItemL( KObjectData_RHeap_iFree_next, objectData.iFree.next );
+_LIT( KObjectData_RHeap_iFree_len,  "RHeap::iFree.len" );
+aList.AddItemL( KObjectData_RHeap_iFree_len, objectData.iFree.len );
+_LIT( KObjectData_RHeap_iNestingLevel,  "RHeap::iNestingLevel" );
+aList.AddItemL( KObjectData_RHeap_iNestingLevel, objectData.iNestingLevel );
+_LIT( KObjectData_RHeap_iAllocCount,  "RHeap::iAllocCount" );
+aList.AddItemL( KObjectData_RHeap_iAllocCount, objectData.iAllocCount );
+_LIT( KObjectData_RHeap_iFailType,  "RHeap::iFailType" );
+aList.AddItemL( KObjectData_RHeap_iFailType, (TInt) objectData.iFailType );
+_LIT( KObjectData_RHeap_iFailRate,  "RHeap::iFailRate" );
+aList.AddItemL( KObjectData_RHeap_iFailRate, objectData.iFailRate );
+_LIT( KObjectData_RHeap_iFailed,  "RHeap::iFailed" );
+aList.AddItemTrueFalseL( KObjectData_RHeap_iFailed, objectData.iFailed );
+_LIT( KObjectData_RHeap_iFailAllocCount,  "RHeap::iFailAllocCount" );
+aList.AddItemL( KObjectData_RHeap_iFailAllocCount, objectData.iFailAllocCount );
+_LIT( KObjectData_RHeap_iRand,  "RHeap::iRand" );
+aList.AddItemL( KObjectData_RHeap_iRand, objectData.iRand );
+_LIT( KObjectData_RHeap_iTestData,  "RHeap::iTestData" );
+aList.AddItemL( KObjectData_RHeap_iTestData, objectData.iTestData );
+aList.AddBlankItemL( 1 );
+}
+}
 void CMemSpyEngineHelperHeap::AppendStatisticsL( const TMemSpyHeapInfo& aInfo, CMemSpyEngineOutputList& aList )
 {
-if (aInfo.Type() != TMemSpyHeapInfo::ETypeUnknown)
+if ( aInfo.Type() == TMemSpyHeapInfo::ETypeRHeap )
 {
 const TMemSpyHeapInfoRHeap& rHeap = aInfo.AsRHeap();
 const TMemSpyHeapStatisticsRHeap& rHeapStats = rHeap.Statistics();
 // Shared captions
 aList.AddItemL( KStatsData_CellCount, rHeapStats.StatsFree().TypeCount() );
 aList.AddItemL( KStatsData_CellSize, rHeapStats.StatsFree().TypeSize() );
 aList.AddItemL( KStatsData_LargestCellAddress, rHeapStats.StatsFree().LargestCellAddress() );
 aList.AddItemL( KStatsData_LargestCellSize, rHeapStats.StatsFree().LargestCellSize() );
-		if (aInfo.Type() == TMemSpyHeapInfo::ETypeRHeap)
+_LIT( KStatsData_Free_SlackCellAddress,  "Slack:" );
-			{
+aList.AddItemL( KStatsData_Free_SlackCellAddress, rHeapStats.StatsFree().SlackSpaceCellAddress() );
-			_LIT( KStatsData_Free_SlackCellAddress,  "Slack:" );
+_LIT( KStatsData_Free_SlackCellSize,  "Slack size:" );
-			aList.AddItemL( KStatsData_Free_SlackCellAddress, rHeapStats.StatsFree().SlackSpaceCellAddress() );
+aList.AddItemL( KStatsData_Free_SlackCellSize, rHeapStats.StatsFree().SlackSpaceCellSize() );
-			_LIT( KStatsData_Free_SlackCellSize,  "Slack size:" );
-			aList.AddItemL( KStatsData_Free_SlackCellSize, rHeapStats.StatsFree().SlackSpaceCellSize() );
-			}
 _LIT( KStatsData_Free_Checksum,  "Checksum:" );
 aList.AddItemHexL( KStatsData_Free_Checksum, rHeapStats.StatsFree().Checksum() );
 aList.AddBlankItemL( 1 );
 aList.AddItemL( KStatsData_CellSize, rHeapStats.StatsAllocated().TypeSize() );
 aList.AddItemL( KStatsData_LargestCellAddress, rHeapStats.StatsAllocated().LargestCellAddress() );
 aList.AddItemL( KStatsData_LargestCellSize, rHeapStats.StatsAllocated().LargestCellSize() );
 aList.AddBlankItemL( 1 );
-}
-}
+// Common
+_LIT( KOverallCaption3, "Common Statistics" );
+aList.AddItemL( KOverallCaption3 );
-void CMemSpyEngineHelperHeap::AppendCellsL(const RArray<TMemSpyDriverCell>& aCells, CMemSpyEngineOutputList& aList)
+aList.AddUnderlineForPreviousItemL( '=', 0 );
-{
-// For reasons that may or may not turn out to be sensible, we separate free and allocated cells in the output data
+_LIT( KStatsData_Common_TotalCellCount,  "Total cell count:" );
+aList.AddItemL( KStatsData_Common_TotalCellCount, rHeapStats.StatsCommon().TotalCellCount() );
+_LIT( KStatsData_Common_TotalSize,  "Total cell size:" );
+aList.AddItemL( KStatsData_Common_TotalSize, rHeapStats.StatsAllocated().TypeSize() + rHeapStats.StatsFree().TypeSize() );
+aList.AddBlankItemL( 1 );
+}
+}
+void CMemSpyEngineHelperHeap::AppendFreeCellsL( const RArray<TMemSpyDriverFreeCell>& aFreeCells, CMemSpyEngineOutputList& aList )
+{
+// Free space
 _LIT( KOverallCaption1, "Free Cell List" );
 aList.AddItemL( KOverallCaption1 );
 aList.AddUnderlineForPreviousItemL( '=', 0 );
 TBuf<128> caption;
 _LIT( KCaptionFormat, "FC %04d" );
-_LIT( KValueFormat, "0x%08x %8d %d" );
+_LIT( KValueFormat, "0x%08x %8d %1d" );
-	TBool foundAllocatedCells = EFalse;
+const TInt count = aFreeCells.Count();
-const TInt count = aCells.Count();
 for( TInt i=0; i<count; i++ )
 {
-const TMemSpyDriverCell& cell = aCells[ i ];
+const TMemSpyDriverFreeCell& cell = aFreeCells[ i ];
-		if (cell.iType & EMemSpyDriverAllocatedCellMask)
+caption.Format( KCaptionFormat, i + 1 );
-			{
+aList.AddItemFormatL( caption, KValueFormat, cell.iAddress, cell.iLength, cell.iType );
-			foundAllocatedCells = ETrue;
+}
-			}
+}
-		else if (cell.iType & EMemSpyDriverFreeCellMask)
-			{
-	        caption.Format( KCaptionFormat, i + 1 );
-		    aList.AddItemFormatL( caption, KValueFormat, cell.iAddress, cell.iLength, cell.iType );
-			}
-}
-	if (foundAllocatedCells)
-		{
-aList.AddBlankItemL( 1 );
-		_LIT( KOverallCaption1, "Allocated Cell List" );
-		aList.AddItemL( KOverallCaption1 );
-		aList.AddUnderlineForPreviousItemL( '=', 0 );
-		TBuf<128> caption;
-		_LIT( KCaptionFormat, "AC %04d" );
-		_LIT( KValueFormat, "0x%08x %8d %d" );
-		for (TInt i = 0; i < count; i++)
-			{
-			const TMemSpyDriverCell& cell = aCells[ i ];
-			if (cell.iType & EMemSpyDriverAllocatedCellMask)
-				{
-				caption.Format( KCaptionFormat, i + 1 );
-				aList.AddItemFormatL( caption, KValueFormat, cell.iAddress, cell.iLength, cell.iType );
-				}
-			}
-		}
-}
 void CMemSpyEngineHelperHeap::UpdateSharedHeapInfoL( const TProcessId& aProcess, const TThreadId& aThread, TMemSpyHeapInfo& aInfo )
 {
 RArray<TThreadId> threads;
 CleanupClosePushL( threads );

branch	RCL_3
changeset 44	52e343bb8f80
parent 43	ca8a1b6995f6
child 49	7fdc9a71d314