os/kernelhwsrv/kernel/eka/memmodel/epoc/direct/mchunk.cpp
author sl
Tue, 10 Jun 2014 14:32:02 +0200
changeset 1 260cb5ec6c19
permissions -rw-r--r--
Update contrib.
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// Copyright (c) 1994-2009 Nokia Corporation and/or its subsidiary(-ies).
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// All rights reserved.
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// This component and the accompanying materials are made available
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// under the terms of the License "Eclipse Public License v1.0"
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// which accompanies this distribution, and is available
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// at the URL "http://www.eclipse.org/legal/epl-v10.html".
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//
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// Initial Contributors:
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// Nokia Corporation - initial contribution.
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//
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// Contributors:
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//
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// Description:
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// e32\memmodel\epoc\direct\mchunk.cpp
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// 
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//
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#include <memmodel.h>
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DMemModelChunk::~DMemModelChunk()
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	{
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	__KTRACE_OPT(KTHREAD,Kern::Printf("DMemModelChunk destruct %O",this));
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	if (iRegionSize)
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		{
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		MM::WaitRamAlloc();
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		MM::FreeRegion(iRegionBase,iRegionSize);
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		__KTRACE_OPT(KMEMTRACE, Kern::Printf("MT:D %d %x %O",NTickCount(),this,this););
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		MM::SignalRamAlloc();
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#ifdef BTRACE_CHUNKS
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		BTraceContext4(BTrace::EChunks,BTrace::EChunkDestroyed,this);
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#endif
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		}
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	iRegionSize=0;
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	TDfc* dfc = (TDfc*)__e32_atomic_swp_ord_ptr(&iDestroyedDfc, 0);
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	if(dfc)
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		dfc->Enque();
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	}
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TUint8* DMemModelChunk::Base(DProcess* aProcess)
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	{
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	return iBase;
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	}
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TInt DMemModelChunk::DoCreate(SChunkCreateInfo& anInfo)
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	{
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	__ASSERT_COMPILE(!(EMMChunkAttributesMask & EChunkAttributesMask));
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	if(iAttributes&EMemoryNotOwned)
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		return KErrNotSupported;
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	if (anInfo.iMaxSize<=0)
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		return KErrArgument;
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	TInt r=KErrNone;
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	iMaxSize=MM::RoundToBlockSize(anInfo.iMaxSize);
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	switch (anInfo.iType)
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		{
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		case EDll:
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		case EUserCode:
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		case EUserSelfModCode:
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		case EUserData:
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		case EDllData:
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		case ESharedKernelSingle:
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		case ESharedKernelMultiple:
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		case ESharedIo:
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		case EKernelMessage:
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			MM::WaitRamAlloc();
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			r=MM::AllocRegion(iRegionBase, iMaxSize);
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			if (r==KErrNone)
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				iRegionSize=iMaxSize;
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			else
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				MM::AllocFailed=ETrue;
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			MM::SignalRamAlloc();
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			iBase=(TUint8*)iRegionBase;
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			iSize=iMaxSize;
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			if(r==KErrNone)
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				{
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				iMapAttr = EMapAttrCachedMax;
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				__KTRACE_OPT(KMMU,Kern::Printf("DMemModelChunk::DoCreate clear %x+%x",iRegionBase,iRegionSize));
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				// Clear memory to value determined by chunk member
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				memset((TAny*)iRegionBase, iClearByte, MM::RoundToBlockSize(iRegionSize));
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				}
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			break;
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		default:
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			break;
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		}
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	__KTRACE_OPT(KMMU,Kern::Printf("DMemModelChunk::DoCreate %O ret %d",this,r));
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	__KTRACE_OPT(KMMU,Kern::Printf("RegionBase=%08x, RegionSize=%08x",iRegionBase,iRegionSize));
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	__KTRACE_OPT(KMEMTRACE, {MM::WaitRamAlloc();Kern::Printf("MT:C %d %x %O",NTickCount(),this,this);MM::SignalRamAlloc();});
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#ifdef BTRACE_CHUNKS
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	TKName nameBuf;
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	Name(nameBuf);
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	BTraceContextN(BTrace::EChunks,BTrace::EChunkCreated,this,iMaxSize,nameBuf.Ptr(),nameBuf.Size());
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	if(iOwningProcess)
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		BTrace8(BTrace::EChunks,BTrace::EChunkOwner,this,iOwningProcess);
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	BTraceContext12(BTrace::EChunks,BTrace::EChunkInfo,this,iChunkType,iAttributes);
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#endif
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	return r;
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	}
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void DMemModelChunk::SetFixedAddress(TLinAddr anAddr, TInt aSize)
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	{
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	__KTRACE_OPT(KMMU,Kern::Printf("DMemModelChunk %O SetFixedAddress %08X size %08X",this,anAddr,aSize));
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	iSize=MM::RoundToBlockSize(aSize);
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	if (iSize>iMaxSize)
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		iMaxSize=iSize;
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	iBase=(TUint8*)anAddr;
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	}
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TInt DMemModelChunk::Adjust(TInt aNewSize)
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//
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// Adjust a standard chunk.
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//
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	{
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	__KTRACE_OPT(KMMU,Kern::Printf("DMemModelChunk::Adjust %08x",aNewSize));
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	if (iAttributes & (EDoubleEnded|EDisconnected))
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		return KErrGeneral;
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	if (aNewSize<0 || aNewSize>iMaxSize)
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		return KErrArgument;
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	__KTRACE_OPT(KMMU,Kern::Printf("DMemModelChunk %O adjusted to %x",this,iSize));
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	__KTRACE_OPT(KMEMTRACE, {MM::WaitRamAlloc();Kern::Printf("MT:A %d %x %x %O",NTickCount(),this,iSize,this);MM::SignalRamAlloc();});
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	return KErrNone;
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	}
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TInt DMemModelChunk::AdjustDoubleEnded(TInt aBottom, TInt aTop)
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//
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// Adjust a double-ended chunk.
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//
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	{
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	__KTRACE_OPT(KMMU,Kern::Printf("DMemModelChunk::AdjustDoubleEnded %x-%x",aBottom,aTop));
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	if ((iAttributes & (EDoubleEnded|EDisconnected))!=EDoubleEnded)
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		return KErrGeneral;
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	if (aTop<0 || aBottom<0 || aTop<aBottom || aTop>iMaxSize)
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		return KErrArgument;
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	TInt newSize=aTop-aBottom;
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	if (newSize>iMaxSize)
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		return KErrArgument;
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	iStartPos=aBottom;
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	__KTRACE_OPT(KMMU,Kern::Printf("DMemModelChunk %O adjusted to %x+%x",this,iStartPos,iSize));
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	__KTRACE_OPT(KMEMTRACE, {MM::WaitRamAlloc();Kern::Printf("MT:A %d %x %x %O",NTickCount(),this,iSize,this);MM::SignalRamAlloc();});
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	return KErrNone;
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	}
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TInt DMemModelChunk::Address(TInt aOffset, TInt aSize, TLinAddr& aKernelAddress)
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	{
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	if(TUint(aOffset)>=TUint(iMaxSize))
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		return KErrArgument;
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	if(TUint(aOffset+aSize)>TUint(iMaxSize))
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		return KErrArgument;
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	if(aSize<=0)
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		return KErrArgument;
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	aKernelAddress = (TLinAddr)iBase+aOffset;
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	return KErrNone;
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	}
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TInt DMemModelChunk::PhysicalAddress(TInt aOffset, TInt aSize, TLinAddr& aKernelAddress, TUint32& aPhysicalAddress, TUint32* aPhysicalPageList)
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	{
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	TInt r=Address(aOffset,aSize,aKernelAddress);
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	if(r!=KErrNone)
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		return r;
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	TPhysAddr physStart = Epoc::LinearToPhysical(aKernelAddress);
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	TInt pageShift = 12;
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	TUint32 page = aKernelAddress>>pageShift<<pageShift;
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	TUint32 lastPage = (aKernelAddress+aSize-1)>>pageShift<<pageShift;
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	TUint32* pageList = aPhysicalPageList;
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	TUint32 nextPhys = Epoc::LinearToPhysical(page);
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	TUint32 pageSize = 1<<pageShift;
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	while(page<=lastPage)
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		{
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		TPhysAddr phys = Epoc::LinearToPhysical(page);
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		if(pageList)
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			*pageList++ = phys;
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		if(phys!=nextPhys)
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			nextPhys = KPhysAddrInvalid;
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		else
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			nextPhys += pageSize;
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		page += pageSize;
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		}
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	if(nextPhys==KPhysAddrInvalid)
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		{
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		// Memory is discontiguous...
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		aPhysicalAddress = KPhysAddrInvalid;
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		return 1;
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		}
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	else
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		{
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		// Memory is contiguous...
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		aPhysicalAddress = physStart;
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		return KErrNone;
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		}
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	}
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TInt DMemModelChunk::Commit(TInt aOffset, TInt aSize, TCommitType aCommitType, TUint32* aExtraArg)
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//
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// Commit to a disconnected chunk.
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//
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	{
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	__KTRACE_OPT(KMMU,Kern::Printf("DMemModelChunk::Commit %x+%x type=%d extra=%08x",aOffset,aSize,aCommitType,aExtraArg));
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	if ((iAttributes & (EDoubleEnded|EDisconnected))!=EDisconnected)
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		return KErrGeneral;
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	if (aOffset<0 || aSize<0 || (aOffset+aSize)>iMaxSize)
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		return KErrArgument;
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	if(LOGICAL_XOR((TInt)aCommitType&DChunk::ECommitPhysicalMask, iAttributes&DChunk::EMemoryNotOwned))
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		return KErrNotSupported;  // Commit type doesn't match 'memory owned' type
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	if((TInt)aCommitType&DChunk::ECommitPhysicalMask)
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		return KErrNotSupported;
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	if(aCommitType==DChunk::ECommitContiguous)
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		{
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		// We can't commit contiguous memory, we just have to take what's already there.
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		// So check to see if memory is contiguous, and if not, return KErrNoMemory -
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		// which is what other Memory Models do if they can't find enough contiguous RAM.
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		TLinAddr kernAddr;
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		if(PhysicalAddress(aOffset,aSize,kernAddr,*aExtraArg)!=KErrNone)
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			return KErrNoMemory;
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		}
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	else if(aCommitType!=DChunk::ECommitDiscontiguous)
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		return KErrArgument;
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	return KErrNone;
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	}
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TInt DMemModelChunk::Allocate(TInt aSize, TInt aGuard, TInt aAlign)
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//
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// Allocate offset and commit to a disconnected chunk.
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//
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	{
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	__KTRACE_OPT(KMMU,Kern::Printf("DMemModelChunk::Allocate %x %x %d",aSize,aGuard,aAlign));
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	if ((iAttributes & (EDoubleEnded|EDisconnected))!=EDisconnected)
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		return KErrGeneral;
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	if (aSize<=0 || aSize>iMaxSize)
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		return KErrArgument;
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	TInt r=KErrNotSupported;
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	__KTRACE_OPT(KMMU,Kern::Printf("DMemModelChunk::Allocate returns %x",r));
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	return r;
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	}
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TInt DMemModelChunk::Decommit(TInt anOffset, TInt aSize)
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//
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// Decommit from a disconnected chunk.
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//
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	{
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	__KTRACE_OPT(KMMU,Kern::Printf("DMemModelChunk::Decommit %x+%x",anOffset,aSize));
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	if ((iAttributes & (EDoubleEnded|EDisconnected))!=EDisconnected)
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		return KErrGeneral;
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	if (anOffset<0 || aSize<0 || (anOffset+aSize)>iMaxSize)
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		return KErrArgument;
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	return KErrNone;
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	}
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void DMemModelChunk::Substitute(TInt /*aOffset*/, TPhysAddr /*aOldAddr*/, TPhysAddr /*aNewAddr*/)
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	{
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	MM::Panic(MM::EUnsupportedOperation);
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	}
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TInt DMemModelChunk::Unlock(TInt anOffset, TInt aSize)
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	{
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	__KTRACE_OPT(KMMU,Kern::Printf("DMemModelChunk::Decommit %x+%x",anOffset,aSize));
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	if (!(iAttributes&ECache))
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		return KErrGeneral;
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	if ((iAttributes & (EDoubleEnded|EDisconnected))!=EDisconnected)
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		return KErrGeneral;
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	if (anOffset<0 || aSize<0 || (anOffset+aSize)>iMaxSize)
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		return KErrArgument;
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	return KErrNone;
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	}
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TInt DMemModelChunk::Lock(TInt anOffset, TInt aSize)
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	{
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	__KTRACE_OPT(KMMU,Kern::Printf("DMemModelChunk::Decommit %x+%x",anOffset,aSize));
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	if (!(iAttributes&ECache))
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		return KErrGeneral;
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	if ((iAttributes & (EDoubleEnded|EDisconnected))!=EDisconnected)
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		return KErrGeneral;
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	if (anOffset<0 || aSize<0 || (anOffset+aSize)>iMaxSize)
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		return KErrArgument;
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	return KErrNone;
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	}
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TInt DMemModelChunk::CheckAccess()
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	{
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	DProcess* pP=TheCurrentThread->iOwningProcess;
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	if (iAttributes&EPrivate)
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		{
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		if (iOwningProcess && iOwningProcess!=pP && pP!=K::TheKernelProcess)
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			return KErrAccessDenied;
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		}
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	return KErrNone;
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	}
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TUint32 MM::RoundToBlockSize(TUint32 aSize)
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	{
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	TUint32 m=MM::RamBlockSize-1;
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	return (aSize+m)&~m;
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	}
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void MM::FreeRegion(TLinAddr aBase, TInt aSize)
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	{
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	__KTRACE_OPT(KMMU,Kern::Printf("MM::FreeRegion base %08x size %08x",aBase,aSize));
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	aSize=MM::RoundToBlockSize(aSize);
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	__ASSERT_ALWAYS(aBase>=MM::UserDataSectionBase && aBase+aSize<=MM::UserDataSectionEnd, MM::Panic(MM::EFreeInvalidRegion));
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	TInt block=(aBase-MM::UserDataSectionBase)>>MM::RamBlockShift;
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	TInt nBlocks=aSize>>MM::RamBlockShift;
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	MM::RamAllocator->Free(block, nBlocks);
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	}
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TInt MM::AllocRegion(TLinAddr& aBase, TInt aSize, TInt aAlign)
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	{
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	__KTRACE_OPT(KMMU,Kern::Printf("MM::AllocRegion size 0x%x align %d",aSize,aAlign));
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	TInt align=Max(aAlign-MM::RamBlockShift, 0);
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	TInt nBlocks=MM::RoundToBlockSize(aSize)>>MM::RamBlockShift;
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	TInt base=(TInt)(MM::UserDataSectionBase>>MM::RamBlockShift);
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	TInt block=MM::RamAllocator->AllocAligned(nBlocks, align, base, ETrue);	// returns first block number or -1
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	if (block<0)
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		return KErrNoMemory;
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	MM::RamAllocator->Alloc(block,nBlocks);
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	aBase=MM::UserDataSectionBase+(block<<MM::RamBlockShift);
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	__KTRACE_OPT(KMMU,Kern::Printf("MM::AllocRegion address %08x",aBase));
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	return KErrNone;
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	}
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TInt MM::ClaimRegion(TLinAddr aBase, TInt aSize)
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	{
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	__KTRACE_OPT(KMMU,Kern::Printf("MM::ClaimRegion base %08x size %08x",aBase,aSize));
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	TUint32 m=MM::RamBlockSize-1;
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	aSize=MM::RoundToBlockSize(aSize+(aBase&m));
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	aBase&=~m;
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	if (aBase<MM::UserDataSectionBase || TUint32(aSize)>MM::UserDataSectionEnd-aBase)
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		return KErrArgument;
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	TInt block=(aBase-MM::UserDataSectionBase)>>MM::RamBlockShift;
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	TInt nBlocks=aSize>>MM::RamBlockShift;
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	if (MM::RamAllocator->NotFree(block, nBlocks))
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		return KErrInUse;
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	MM::RamAllocator->Alloc(block, nBlocks);
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	return KErrNone;
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	}
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// Allocate a physically contiguous region
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TInt MM::AllocContiguousRegion(TLinAddr& aBase, TInt aSize, TInt aAlign)
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	{
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#ifndef __CPU_HAS_MMU
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	return MM::AllocRegion(aBase, aSize, aAlign);
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#else
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	__KTRACE_OPT(KMMU,Kern::Printf("MM::AllocContiguousRegion size 0x%x align %d",aSize,aAlign));
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	TBitMapAllocator* sa = MM::SecondaryAllocator;
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	if (!sa)
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		return MM::AllocRegion(aBase, aSize, aAlign);	// only one physical bank
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	TBitMapAllocator* ra = MM::RamAllocator;
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	TInt align=Max(aAlign-MM::RamBlockShift, 0);
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	TUint32 alignmask = (1u<<align)-1;
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	TInt nBlocks=MM::RoundToBlockSize(aSize)>>MM::RamBlockShift;
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	TInt base=(TInt)(MM::UserDataSectionBase>>MM::RamBlockShift);
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	const SRamBank* banks = (const SRamBank*)TheSuperPage().iRamBootData;
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	const SRamBank* pB = banks;
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	TInt bnum = 0;
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	TInt block = -1;
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	for (; pB->iSize; ++pB)
sl@0
   368
		{
sl@0
   369
		TInt nb = pB->iSize >> MM::RamBlockShift;
sl@0
   370
		sa->CopyAlignedRange(ra, bnum, nb);
sl@0
   371
		TInt basealign = (base + bnum) & alignmask;
sl@0
   372
		block = sa->AllocAligned(nBlocks, align, basealign, ETrue);	// returns first block number or -1
sl@0
   373
		if (block>=0)
sl@0
   374
			break;
sl@0
   375
		bnum += nb;
sl@0
   376
		}
sl@0
   377
	if (pB->iSize == 0)
sl@0
   378
		return KErrNoMemory;
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   379
	MM::RamAllocator->Alloc(block + bnum, nBlocks);
sl@0
   380
	aBase = MM::UserDataSectionBase + ((block + bnum)<<MM::RamBlockShift);
sl@0
   381
	__KTRACE_OPT(KMMU,Kern::Printf("MM::AllocContiguousRegion address %08x",aBase));
sl@0
   382
	return KErrNone;
sl@0
   383
#endif
sl@0
   384
	}
sl@0
   385
sl@0
   386
TInt MM::BlockNumber(TPhysAddr aAddr)
sl@0
   387
	{
sl@0
   388
	__KTRACE_OPT(KMMU,Kern::Printf("MM::BlockNumber %08x",aAddr));
sl@0
   389
	const SRamBank* banks = (const SRamBank*)TheSuperPage().iRamBootData;
sl@0
   390
	const SRamBank* pB = banks;
sl@0
   391
	TInt bnum = 0;
sl@0
   392
	for (; pB->iSize; ++pB)
sl@0
   393
		{
sl@0
   394
		if (aAddr >= pB->iBase)
sl@0
   395
			{
sl@0
   396
			TUint32 offset = aAddr - pB->iBase;
sl@0
   397
			if (offset < pB->iSize)
sl@0
   398
				{
sl@0
   399
				TInt bn = bnum + TInt(offset>>MM::RamBlockShift);
sl@0
   400
				__KTRACE_OPT(KMMU,Kern::Printf("MM::BlockNumber %08x->%x",aAddr,bn));
sl@0
   401
				return bn;
sl@0
   402
				}
sl@0
   403
			}
sl@0
   404
		TInt nb = pB->iSize >> MM::RamBlockShift;
sl@0
   405
		bnum += nb;
sl@0
   406
		}
sl@0
   407
	return KErrNotFound;
sl@0
   408
	}
sl@0
   409
sl@0
   410
/********************************************
sl@0
   411
 * Hardware chunk abstraction
sl@0
   412
 ********************************************/
sl@0
   413
sl@0
   414
/**
sl@0
   415
	@pre	Call in a thread context.
sl@0
   416
	@pre	Interrupts must be enabled.
sl@0
   417
	@pre	Kernel must be unlocked.
sl@0
   418
	@pre    No fast mutex can be held.
sl@0
   419
	@pre	Calling thread must be in a critical section.
sl@0
   420
 */
sl@0
   421
EXPORT_C TInt DPlatChunkHw::New(DPlatChunkHw*& aChunk, TPhysAddr aAddr, TInt aSize, TUint aAttribs)
sl@0
   422
	{
sl@0
   423
	CHECK_PRECONDITIONS(MASK_THREAD_CRITICAL,"DPlatChunkHw::New");
sl@0
   424
	__KTRACE_OPT(KMMU,Kern::Printf("DPlatChunkHw::New phys=%08x, size=%x, attribs=%x",aAddr,aSize,aAttribs));
sl@0
   425
	aChunk=NULL;
sl@0
   426
	if (aSize<=0)
sl@0
   427
		return KErrArgument;
sl@0
   428
	DPlatChunkHw* pC=new DPlatChunkHw;
sl@0
   429
	if (!pC)
sl@0
   430
		return KErrNoMemory;
sl@0
   431
	__KTRACE_OPT(KMMU,Kern::Printf("DPlatChunkHw created at %08x",pC));
sl@0
   432
sl@0
   433
	pC->iPhysAddr=aAddr;
sl@0
   434
	pC->iLinAddr=aAddr;
sl@0
   435
	pC->iSize=aSize;
sl@0
   436
	aChunk=pC;
sl@0
   437
	return KErrNone;
sl@0
   438
	}
sl@0
   439
sl@0
   440
sl@0
   441
void DMemModelChunk::BTracePrime(TInt aCategory)
sl@0
   442
	{
sl@0
   443
	DChunk::BTracePrime(aCategory);
sl@0
   444
	
sl@0
   445
#ifdef BTRACE_CHUNKS
sl@0
   446
	if (aCategory == BTrace::EChunks || aCategory == -1)
sl@0
   447
		{
sl@0
   448
		BTrace12(BTrace::EChunks, BTrace::EChunkMemoryAllocated,this,0,this->iSize);
sl@0
   449
		}
sl@0
   450
#endif
sl@0
   451
	}