// Copyright (c) 1998-2009 Nokia Corporation and/or its subsidiary(-ies).
// All rights reserved.
// This component and the accompanying materials are made available
// under the terms of the License "Eclipse Public License v1.0"
// which accompanies this distribution, and is available
// at the URL "http://www.eclipse.org/legal/epl-v10.html".
//
// Initial Contributors:
// Nokia Corporation - initial contribution.
//
// Contributors:
//
// Description:
// e32\include\memmodel\epoc\mmubase\mmubase.h
//
// WARNING: This file contains some APIs which are internal and are subject
// to change without notice. Such APIs should therefore not be used
// outside the Kernel and Hardware Services package.
//
#ifndef __MMUBASE_H__
#define __MMUBASE_H__
#include <plat_priv.h>
#include <memmodel/epoc/mmubase/kblockmap.h>
/******************************************************************************
* Definitions common to all MMU memory models
******************************************************************************/
/**
@internalComponent
*/
struct SPageInfo
{
enum TType
{
EInvalid=0, // No physical RAM exists for this page
EFixed=1, // RAM fixed at boot time,
EUnused=2, // Page is unused
EChunk=3, // iOwner=DChunk* iOffset=index into chunk
ECodeSegMemory=4, // iOwner=DCodeSegMemory* iOffset=index into CodeSeg memory (Multiple Memory Model only)
// EHwChunk=5, // Not used
EPageTable=6, // iOwner=0 iOffset=index into KPageTableBase
EPageDir=7, // iOwner=ASID iOffset=index into Page Directory
EPtInfo=8, // iOwner=0 iOffset=index into KPageTableInfoBase
EShadow=9, // iOwner=phys ROM page iOffset=index into ROM
EPagedROM=10, // iOwner=0, iOffset=index into ROM
EPagedCode=11, // iOwner=DCodeSegMemory* iOffset=index into code chunk (not offset into CodeSeg!)
EPagedData=12, // NOT YET SUPPORTED
EPagedCache=13, // iOwner=DChunk* iOffset=index into chunk
EPagedFree=14, // In demand paging 'live list' but not used for any purpose
};
enum TState
{
EStateNormal = 0, // no special state
EStatePagedYoung = 1, // demand paged and is on the young list
EStatePagedOld = 2, // demand paged and is on the old list
EStatePagedDead = 3, // demand paged and is currently being modified
EStatePagedLocked = 4 // demand paged but is temporarily not being demand paged
};
inline TType Type()
{
return (TType)iType;
}
inline TState State()
{
return (TState)iState;
}
inline TAny* Owner()
{
return iOwner;
}
inline TUint32 Offset()
{
return iOffset;
}
inline TInt LockCount()
{
return iLockCount;
}
/** Return the index of the zone the page is in
*/
inline TUint8 Zone()
{
return iZone;
}
#ifdef _DEBUG
void Set(TType aType, TAny* aOwner, TUint32 aOffset);
void Change(TType aType,TState aState);
void SetState(TState aState);
void SetModifier(TAny* aModifier);
TInt CheckModified(TAny* aModifier);
void SetZone(TUint8 aZoneIndex);
#else
inline void Set(TType aType, TAny* aOwner, TUint32 aOffset)
{
(TUint16&)iType = aType; // also sets iState to EStateNormal
iOwner = aOwner;
iOffset = aOffset;
iModifier = 0;
}
inline void Change(TType aType,TState aState)
{
iType = aType;
iState = aState;
iModifier = 0;
}
inline void SetState(TState aState)
{
iState = aState;
iModifier = 0;
}
inline void SetModifier(TAny* aModifier)
{
iModifier = aModifier;
}
inline TInt CheckModified(TAny* aModifier)
{
return iModifier!=aModifier;
}
inline void SetZone(TUint8 aZoneIndex)
{
iZone = aZoneIndex;
}
#endif // !_DEBUG
void Lock();
TInt Unlock();
inline void SetFixed()
{
Set(EFixed,0,0);
iLockCount = 1;
}
inline void SetUnused()
{
__NK_ASSERT_DEBUG(0 == LockCount());
(TUint16&)iType = EUnused; // also sets iState to zero
iModifier = 0;
// do not modify iOffset in this function because cache cleaning operations
// rely on using this value
}
inline void SetChunk(TAny* aChunk, TUint32 aOffset)
{
Set(EChunk,aChunk,aOffset);
}
inline void SetCodeSegMemory(TAny* aCodeSegMemory,TUint32 aOffset)
{
Set(ECodeSegMemory,aCodeSegMemory,aOffset);
}
// inline void SetHwChunk(TAny* aChunk, TUint32 aOffset)
// {
// Set(EHwChunk,aChunk,aOffset);
// }
inline void SetPageTable(TUint32 aId)
{
Set(EPageTable,0,aId);
}
inline void SetPageDir(TUint32 aOsAsid, TInt aOffset)
{
Set(EPageDir,(TAny*)aOsAsid,aOffset);
}
inline void SetPtInfo(TUint32 aOffset)
{
Set(EPtInfo,0,aOffset);
}
inline void SetShadow(TPhysAddr aOrigPhys, TUint32 aOffset)
{
Set(EShadow,(TAny*)aOrigPhys,aOffset);
}
inline void SetPagedROM(TUint32 aOffset)
{
Set(EPagedROM,0,aOffset);
}
inline void SetPagedCode(TAny* aCodeSegMemory, TUint32 aOffset)
{
Set(EPagedCode,aCodeSegMemory,aOffset);
}
inline static SPageInfo* FromLink(SDblQueLink* aLink)
{ return (SPageInfo*)((TInt)aLink-_FOFF(SPageInfo,iLink)); }
inline TUint& PagedLock()
{ return (TUint&)iLink.iPrev; }
/**
Return the SPageInfo for a given page of physical RAM.
*/
inline static SPageInfo* FromPhysAddr(TPhysAddr aAddress);
/**
Return physical address of the RAM page which this SPageInfo object is associated.
If the address has no SPageInfo, then a null pointer is returned.
*/
static SPageInfo* SafeFromPhysAddr(TPhysAddr aAddress);
/**
Return physical address of the RAM page which this SPageInfo object is associated.
*/
inline TPhysAddr PhysAddr();
private:
TUint8 iType; // enum TType
TUint8 iState; // enum TState
TUint8 iZone; // The index of the zone the page is in, for use by DRamAllocator
TUint8 iSpare1;
TAny* iOwner; // owning object
TUint32 iOffset; // page offset withing owning object
TAny* iModifier; // pointer to object currently manipulating page
TUint32 iLockCount; // non-zero if page acquired by code outside of the kernel
TUint32 iSpare2;
public:
SDblQueLink iLink; // used for placing page into linked lists
};
/******************************************************************************
Per-page table info
Page count 0-256
Usage unused
chunk ptr (26 bits) offset (12 bits)
HW chunk ptr (26 bits) offset (12 bits)
global offset (12 bits)
shadow page offset (12 bits)
*******************************************************************************/
/**
@internalComponent
*/
struct SPageTableInfo
{
enum TAttribs
{
EUnused=0,
EChunk=1,
// EHwChunk=2,
EGlobal=3,
EShadow=4,
};
enum {EAttShift=6, EAttMask=0x3f};
inline TInt Attribs()
{return iAttPtr&EAttMask;}
inline TInt Count()
{return iCount;}
inline TUint32 Offset()
{return iOffset;}
inline TUint32 Ptr()
{return iAttPtr>>EAttShift;}
inline void SetUnused()
{iCount=0; iOffset=0; iAttPtr=0;}
inline void SetChunk(TUint32 aChunk, TUint32 aOffset)
{iOffset=aOffset; iAttPtr=(aChunk<<EAttShift)|EChunk;}
// inline void SetHwChunk(TUint32 aChunk, TUint32 aOffset)
// {iOffset=aOffset; iAttPtr=(aChunk<<EAttShift)|EHwChunk;}
inline void SetGlobal(TUint32 aOffset)
{iOffset=aOffset; iAttPtr=EGlobal;}
inline void SetShadow(TUint32 aOffset)
{iCount=0; iOffset=aOffset; iAttPtr=EShadow;}
TUint16 iCount;
TUint16 iOffset;
TUint32 iAttPtr;
};
/******************************************************************************
Bitmap Allocators
PageTableAllocator free page tables within allocated pages
PageTableLinearAllocator free linear addresses for page tables
ASIDAllocator free process slots
Page directory linear address = PageDirBase + (ASID<<PageDirSizeShift)
Page table linear address = PageTableBase + (PTID<<PageTableSizeShift)
Terminology
Page table cluster = no. of page tables in one page
Page table block = no. of SPageTableInfo structures in one page
Page table group = no. of page tables mapped with a single page table
Local = specific to process
Shared = subset of processes but not necessarily all
Global = all processes
*******************************************************************************/
/********************************************
* Address range allocator
********************************************/
/**
@internalComponent
*/
class TLinearSection
{
public:
static TLinearSection* New(TLinAddr aBase, TLinAddr aEnd);
public:
TLinAddr iBase;
TLinAddr iEnd;
TBitMapAllocator iAllocator; // bitmap of used PDE positions
};
/******************************************************************************
* Base class for MMU stuff
******************************************************************************/
/**
@internalComponent
*/
const TPhysAddr KRomPhysAddrInvalid=0xFFFFFFFFu;
/**
@internalComponent
*/
const TUint16 KPageTableNotPresentId=0xFFFF;
/**
@internalComponent
*/
const TInt KUnmapPagesTLBFlushDeferred=0x80000000;
/**
@internalComponent
*/
const TInt KUnmapPagesCountMask=0xffff;
/**
@internalComponent
*/
const TInt KMaxPages = 32;
/**
@internalComponent
*/
typedef TUint32 TPde;
/**
@internalComponent
*/
typedef TUint32 TPte;
class THwChunkAddressAllocator;
class RamCacheBase;
class Defrag;
class DRamAllocator;
class DMemModelCodeSegMemory;
class DMemModelChunk;
/**
@internalComponent
*/
class MmuBase
{
public:
enum TPanic
{
EAsyncFreePageStillInUse=0,
EPtLinAllocCreateFailed=1,
EPtAllocCreateFailed=2,
EPageInfoCreateFailed=3,
EAsyncFreeListCreateFailed=4,
EPtBlockCountCreateFailed=5,
EPtGroupCountCreateFailed=6,
EInvalidPageTableAtBoot=7,
ERamAllocMutexCreateFailed=8,
EHwChunkMutexCreateFailed=9,
ECreateKernelSectionFailed=10,
ECreateHwChunkAllocFailed=11,
EFreeHwChunkAddrInvalid=12,
EFreeHwChunkIndexInvalid=13,
EBadMappedPageAfterBoot=14,
ERecoverRamDriveAllocPTIDFailed=15,
EMapPageTableBadExpand=16,
ERecoverRamDriveBadPageTable=17,
ERecoverRamDriveBadPage=18,
EBadFreePhysicalRam=19,
EPageLockedTooManyTimes=20,
EPageUnlockedTooManyTimes=21,
EPageInfoSetWhenNotUnused=22,
ERamCacheAllocFailed=23,
EDefragAllocFailed=24,
EDefragUnknownPageType=25,
EDefragUnknownPageTableType=27,
EDefragUnknownChunkType=28,
EDefragStackAllocFailed=29,
EDefragKernelChunkNoPageTable=30,
EDefragProcessWrongPageDir=31,
};
public:
MmuBase();
// non virtual
TInt AllocPageTable();
TInt DoAllocPageTable(TPhysAddr& aPhysAddr);
TInt InitPageTableInfo(TInt aId);
TInt MapPageTable(TInt aId, TPhysAddr aPhysAddr, TBool aAllowExpand=ETrue);
void FreePageTable(TInt aId);
TBool DoFreePageTable(TInt aId);
TInt AllocPhysicalRam(TInt aSize, TPhysAddr& aPhysAddr, TInt aAlign=0);
TInt ZoneAllocPhysicalRam(TUint* aZoneIdList, TUint aZoneIdCount, TInt aSize, TPhysAddr& aPhysAddr, TInt aAlign=0);
TInt AllocPhysicalRam(TInt aNumPages, TPhysAddr* aPageList);
TInt ZoneAllocPhysicalRam(TUint* aZoneIdList, TUint aZoneIdCount, TInt aNumPages, TPhysAddr* aPageList);
TInt FreePhysicalRam(TPhysAddr aPhysAddr, TInt aSize);
TInt FreePhysicalRam(TInt aNumPages, TPhysAddr* aPageList);
TInt FreeRamZone(TUint aZoneId, TPhysAddr& aZoneBase, TUint& aZoneBytes);
TInt ClaimPhysicalRam(TPhysAddr aPhysAddr, TInt aSize);
TInt GetPageTableId(TPhysAddr aPtPhys);
void MapRamPage(TLinAddr aAddr, TPhysAddr aPage, TPte aPtePerm);
void UnmapAndFree(TLinAddr aAddr, TInt aNumPages);
void FreePages(TPhysAddr* aPageList, TInt aCount, TZonePageType aPageType);
void CreateKernelSection(TLinAddr aEnd, TInt aHwChunkAlign);
TInt AllocateAllPageTables(TLinAddr aLinAddr, TInt aSize, TPde aPdePerm, TInt aMapShift, SPageTableInfo::TAttribs aAttrib);
TInt AllocShadowPage(TLinAddr aRomAddr);
TInt FreeShadowPage(TLinAddr aRomAddr);
TInt FreezeShadowPage(TLinAddr aRomAddr);
TInt FreeRamInBytes();
TInt GetRamZonePageCount(TUint aId, SRamZonePageCount& aPageData);
TInt ModifyRamZoneFlags(TUint aId, TUint aClearMask, TUint aSetMask);
// RAM allocator and defrag interfaces.
void RamAllocLock();
void RamAllocUnlock();
TUint NumberOfFreeDpPages();
TInt MovePage(TPhysAddr aOld, TPhysAddr& aNew, TUint aBlockZoneId, TBool aBlockRest);
TInt DiscardPage(TPhysAddr aAddr, TUint aBlockZoneId, TBool aBlockRest);
// virtual
virtual void Init1();
virtual void Init2();
virtual void Init3();
virtual THwChunkAddressAllocator* MappingRegion(TUint aMapAttr);
virtual TInt RecoverRamDrive();
virtual TInt CopyToShadowMemory(TLinAddr aDest, TLinAddr aSrc, TUint32 aLength);
// cpu dependent page moving method - cutils.cia
TInt MoveKernelStackPage(DChunk* aChunk, TUint32 aOffset, TPhysAddr aOld, TPhysAddr& aNew, TUint aBlockZoneId, TBool aBlockRest);
// pure virtual
virtual void DoInit2()=0;
virtual TBool PteIsPresent(TPte aPte)=0;
virtual TPhysAddr PtePhysAddr(TPte aPte, TInt aPteIndex)=0;
virtual TPhysAddr PdePhysAddr(TLinAddr aAddr)=0;
virtual void SetupInitialPageInfo(SPageInfo* aPageInfo, TLinAddr aChunkAddr, TInt aPdeIndex)=0;
virtual void SetupInitialPageTableInfo(TInt aId, TLinAddr aChunkAddr, TInt aNumPtes)=0;
virtual void AssignPageTable(TInt aId, TInt aUsage, TAny* aObject, TLinAddr aAddr, TPde aPdePerm)=0;
virtual TInt UnassignPageTable(TLinAddr aAddr)=0;
virtual void BootstrapPageTable(TInt aXptId, TPhysAddr aXptPhys, TInt aId, TPhysAddr aPhysAddr)=0;
virtual void FixupXPageTable(TInt aId, TLinAddr aTempMap, TPhysAddr aOld, TPhysAddr aNew)=0;
virtual TInt PageTableId(TLinAddr aAddr)=0;
virtual TInt BootPageTableId(TLinAddr aAddr, TPhysAddr& aPtPhys)=0;
virtual void ClearPageTable(TInt aId, TInt aFirstIndex=0)=0;
virtual TPhysAddr LinearToPhysical(TLinAddr aAddr)=0;
virtual TInt LinearToPhysical(TLinAddr aAddr, TInt aSize, TPhysAddr& aPhysicalAddress, TPhysAddr* aPhysicalPageList=NULL)=0;
virtual void MapRamPages(TInt aId, SPageInfo::TType aType, TAny* aPtr, TUint32 aOffset, const TPhysAddr* aPageList, TInt aNumPages, TPte aPtePerm)=0;
virtual void MapPhysicalPages(TInt aId, SPageInfo::TType aType, TAny* aPtr, TUint32 aOffset, TPhysAddr aPhysAddr, TInt aNumPages, TPte aPtePerm)=0;
virtual void RemapPage(TInt aId, TUint32 aAddr, TPhysAddr aOldAddr, TPhysAddr aNewAddr, TPte aPtePerm, DProcess* aProcess)=0;
virtual TInt UnmapPages(TInt aId, TUint32 aAddr, TInt aNumPages, TPhysAddr* aPageList, TBool aSetPagesFree, TInt& aNumPtes, TInt& aNumFree, DProcess* aProcess)=0;
virtual void ClearRamDrive(TLinAddr aStart)=0;
virtual TInt PdePtePermissions(TUint& aMapAttr, TPde& aPde, TPte& aPte, TBool aGlobal)=0;
virtual void Map(TLinAddr aLinAddr, TPhysAddr aPhysAddr, TInt aSize, TPde aPdePerm, TPte aPtePerm, TInt aMapShift)=0;
virtual void Unmap(TLinAddr aLinAddr, TInt aSize)=0;
virtual void InitShadowPageTable(TInt aId, TLinAddr aRomAddr, TPhysAddr aOrigPhys)=0;
virtual void InitShadowPage(TPhysAddr aShadowPhys, TLinAddr aRomAddr)=0;
virtual void DoUnmapShadowPage(TInt aId, TLinAddr aRomAddr, TPhysAddr aOrigPhys)=0;
virtual TInt UnassignShadowPageTable(TLinAddr aRomAddr, TPhysAddr aOrigPhys)=0;
virtual void DoFreezeShadowPage(TInt aId, TLinAddr aRomAddr)=0;
virtual void FlushShadow(TLinAddr aRomAddr)=0;
virtual void AssignShadowPageTable(TInt aId, TLinAddr aRomAddr)=0;
virtual void ClearPages(TInt aNumPages, TPhysAddr* aPageList, TUint8 aClearByte = KChunkClearByteDefault)=0;
virtual void Pagify(TInt aId, TLinAddr aLinAddr)=0;
virtual void CacheMaintenanceOnDecommit(const TPhysAddr* aPhysAdr, TInt aPageCount)=0;
virtual void CacheMaintenanceOnDecommit(const TPhysAddr aPhysAdr)=0;
virtual void CacheMaintenanceOnPreserve(const TPhysAddr* aPhysAdr, TInt aPageCount, TUint aMapAttr)=0;
virtual void CacheMaintenanceOnPreserve(const TPhysAddr aPhysAdr, TUint aMapAttr)=0;
virtual void CacheMaintenanceOnPreserve(TPhysAddr aPhysAddr, TInt aSize, TLinAddr aLinAddr, TUint iMapAttr)=0;
// memory model dependent page moving methods - mdefrag.cpp
virtual TInt MoveCodeSegMemoryPage(DMemModelCodeSegMemory* aCodeSegMemory, TUint32 aOffset, TPhysAddr aOld, TPhysAddr& aNew, TUint aBlockZoneId, TBool aBlockRest)=0;
virtual TInt MoveCodeChunkPage(DChunk* aChunk, TUint32 aOffset, TPhysAddr aOld, TPhysAddr& aNew, TUint aBlockZoneId, TBool aBlockRest)=0;
virtual TInt MoveDataChunkPage(DChunk* aChunk, TUint32 aOffset, TPhysAddr aOld, TPhysAddr& aNew, TUint aBlockZoneId, TBool aBlockRest)=0;
// cpu and memory model dependent page moving methods - xmmu.cpp
virtual TInt RamDefragFault(TAny* aExceptionInfo)=0;
virtual void DisablePageModification(DMemModelChunk* aChunk, TInt aOffset)=0;
virtual TPte PtePermissions(TChunkType aChunkType)=0;
public:
static TUint32 RoundToPageSize(TUint32 aSize);
static TUint32 RoundToChunkSize(TUint32 aSize);
static TInt RoundUpRangeToPageSize(TUint32& aBase, TUint32& aSize);
static void Wait();
static void Signal();
static void WaitHwChunk();
static void SignalHwChunk();
static void Panic(TPanic aPanic);
public:
inline TLinAddr PageTableLinAddr(TInt aId)
{return iPageTableLinBase+(aId<<iPageTableShift);}
inline SPageTableInfo& PtInfo(TInt aId)
{return iPtInfo[aId];}
inline TLinAddr PtInfoBlockLinAddr(TInt aBlock)
{return (TLinAddr)iPtInfo+(aBlock<<iPageShift);}
/** Get the page table info block number from a page table ID
@param aId The ID of the page table.
@return The page table info block
*/
inline TInt PtInfoBlock(TInt aId)
{return aId >> iPtBlockShift;}
/**
@return The page table entry for the page table info pages.
*/
inline TPte PtInfoPtePerm()
{return iPtInfoPtePerm;}
public:
TInt AllocRamPages(TPhysAddr* aPageList, TInt aNumPages, TZonePageType aPageType, TUint aBlockedZoneId=KRamZoneInvalidId, TBool aBlockRest=EFalse);
TInt ZoneAllocRamPages(TUint* aZoneIdList, TUint aZoneIdCount, TPhysAddr* aPageList, TInt aNumPages, TZonePageType aPageType);
TInt AllocContiguousRam(TInt aSize, TPhysAddr& aPhysAddr, TInt aAlign);
TInt ZoneAllocContiguousRam(TUint* aZoneIdList, TUint aZoneIdCount, TInt aSize, TPhysAddr& aPhysAddr, TInt aAlign);
public:
TInt iPageSize; // page size in bytes
TInt iPageMask; // page size - 1
TInt iPageShift; // log2(page size)
TInt iChunkSize; // PDE size in bytes
TInt iChunkMask; // PDE size - 1
TInt iChunkShift; // log2(PDE size)
TInt iPageTableSize; // 2nd level page table size in bytes
TInt iPageTableMask; // 2nd level page table size - 1
TInt iPageTableShift; // log2(2nd level page table size)
TInt iPtClusterSize; // number of page tables per page
TInt iPtClusterMask; // number of page tables per page - 1
TInt iPtClusterShift; // log2(number of page tables per page)
TInt iPtBlockSize; // number of SPageTableInfo per page
TInt iPtBlockMask; // number of SPageTableInfo per page - 1
TInt iPtBlockShift; // log2(number of SPageTableInfo per page)
TInt iPtGroupSize; // number of page tables mapped by a page table
TInt iPtGroupMask; // number of page tables mapped by a page table - 1
TInt iPtGroupShift; // log2(number of page tables mapped by a page table)
TInt iMaxPageTables; // maximum number of page tables (<65536)
TInt* iPtBlockCount; // number of page table pages in each block
TInt* iPtGroupCount; // number of page table pages in each group
TInt iNumPages; // Number of pages being managed
SPageTableInfo* iPtInfo; // per-page table information array
TLinAddr iPageTableLinBase; // base address of page tables
DRamAllocator* iRamPageAllocator;
TBitMapAllocator* iPageTableAllocator; // NULL if page table size = page size
TBitMapAllocator* iPageTableLinearAllocator;
TInt iInitialFreeMemory;
TBool iAllocFailed;
TPte iPtInfoPtePerm;
TPte iPtPtePerm;
TPde iPtPdePerm;
TPte* iTempPte; // PTE used for temporary mappings
TLinAddr iTempAddr; // address corresponding to iTempPte
TLinearSection* iKernelSection; // bitmap used to allocate kernel section addresses
THwChunkAddressAllocator* iHwChunkAllocator; // address allocator for HW chunks in kernel section
TUint32 iMapSizes; // bit mask of supported mapping sizes
TUint iDecommitThreshold; // threshold for selective/global cache flush on decommit for VIPT caches
TLinAddr iRomLinearBase;
TLinAddr iRomLinearEnd;
TPte iShadowPtePerm;
TPde iShadowPdePerm;
// Page moving and defrag fault handling members.
TLinAddr iAltStackBase;
TLinAddr iDisabledAddr;
TInt iDisabledAddrAsid;
TPte* iDisabledPte;
TPte iDisabledOldVal;
RamCacheBase* iRamCache;
Defrag* iDefrag;
static DMutex* HwChunkMutex; // mutex protecting HW chunk address allocators
static DMutex* RamAllocatorMutex; // the main mutex protecting alloc/dealloc and most map/unmap
static MmuBase* TheMmu; // pointer to the single instance of this class
static const SRamZone* RamZoneConfig; /**<Pointer to variant specified array containing details on RAM banks and their allocation preferences*/
static TRamZoneCallback RamZoneCallback; /**<Pointer to callback function to be invoked when RAM power state changes*/
public:
friend class Monitor;
};
/******************************************************************************
* Address allocator for HW chunks
******************************************************************************/
/**
@internalComponent
*/
class THwChunkRegion
{
public:
inline THwChunkRegion(TInt aIndex, TInt aSize, TPde aPdePerm)
: iIndex((TUint16)aIndex), iRegionSize((TUint16)aSize), iPdePerm(aPdePerm)
{}
public:
TUint16 iIndex; // index of base of this region in linear section
TUint16 iRegionSize; // number of PDEs covered; 0 means page table
union
{
TPde iPdePerm; // PDE permissions for this region
THwChunkRegion* iNext; // used during deallocation
};
};
/**
@internalComponent
*/
class THwChunkPageTable : public THwChunkRegion
{
public:
THwChunkPageTable(TInt aIndex, TInt aSize, TPde aPdePerm);
static THwChunkPageTable* New(TInt aIndex, TPde aPdePerm);
public:
TBitMapAllocator iAllocator; // bitmap of used page positions
};
/**
@internalComponent
*/
class THwChunkAddressAllocator : public RPointerArray<THwChunkRegion>
{
public:
static THwChunkAddressAllocator* New(TInt aAlign, TLinearSection* aSection);
TLinAddr Alloc(TInt aSize, TInt aAlign, TInt aOffset, TPde aPdePerm);
THwChunkRegion* Free(TLinAddr aAddr, TInt aSize);
public:
THwChunkAddressAllocator();
TLinAddr SearchExisting(TInt aNumPages, TInt aPageAlign, TInt aPageOffset, TPde aPdePerm);
void Discard(THwChunkRegion* aRegion);
static TInt Order(const THwChunkRegion& a1, const THwChunkRegion& a2);
THwChunkRegion* NewRegion(TInt aIndex, TInt aSize, TPde aPdePerm);
THwChunkPageTable* NewPageTable(TInt aIndex, TPde aPdePerm, TInt aInitB, TInt aInitC);
public:
TInt iAlign; // alignment required for allocated addresses
TLinearSection* iSection; // linear section in which allocation occurs
};
/** Hardware chunk
@internalComponent
*/
class DMemModelChunkHw : public DPlatChunkHw
{
public:
virtual TInt Close(TAny* aPtr);
public:
TInt AllocateLinearAddress(TPde aPdePerm);
void DeallocateLinearAddress();
public:
THwChunkAddressAllocator* iAllocator;
};
/******************************************************************************
* MMU-specifc code segment data
******************************************************************************/
/**
@internalComponent
*/
class DMmuCodeSegMemory : public DEpocCodeSegMemory
{
public:
DMmuCodeSegMemory(DEpocCodeSeg* aCodeSeg);
~DMmuCodeSegMemory();
virtual TInt Create(TCodeSegCreateInfo& aInfo);
virtual TInt Loaded(TCodeSegCreateInfo& aInfo);
/**
Apply code relocations and import fixups to one page of code.
@param aBuffer The buffer containg the code
@param aCodeAddress The address the page will be mapped at
*/
void ApplyCodeFixups(TUint32* aBuffer, TLinAddr aCodeAddress);
/**
Apply code relocations and import fixups to one page of code.
Called by DMemModelCodeSegMemory::Loaded to fixup pages which are already paged-in.
@param aBuffer The buffer containg the code
@param aCodeAddress The address the page will be mapped at
*/
TInt ApplyCodeFixupsOnLoad(TUint32* aBuffer, TLinAddr aCodeAddress);
private:
TInt ReadBlockMap(const TCodeSegCreateInfo& aInfo);
TInt ReadFixupTables(const TCodeSegCreateInfo& aInfo);
public:
TBool iIsDemandPaged;
TInt iPageCount; // Number of pages used for code
TInt iDataPageCount; // Number of extra pages used to store data section
TUint8* iCodeRelocTable; // Code relocation information
TInt iCodeRelocTableSize; // Size of code relocation table in bytes
TUint8* iImportFixupTable; // Import fixup information
TInt iImportFixupTableSize; // Size of import fixup table in bytes
TUint32 iCodeDelta; // Code relocation delta
TUint32 iDataDelta; // Data relocation delta
TInt iCompressionType; // Compression scheme in use
TInt32* iCodePageOffsets; // Array of compressed page offsets within the file
TInt iCodeLocalDrive; // Local drive number
TBlockMap iBlockMap; // Kernel-side representation of block map
TInt iCodeStartInFile; // Offset of (possibly compressed) code from start of file
TAny* iDataSectionMemory; // pointer to saved copy of data section (when demand paging)
TInt iCodeAllocBase;
};
#endif