/* $Id: MMInternal.h 6796 2008-02-04 18:19:58Z vboxsync $ */ /** @file * MM - Internal header file. */ /* * Copyright (C) 2006-2007 innotek GmbH * * This file is part of VirtualBox Open Source Edition (OSE), as * available from http://www.virtualbox.org. This file is free software; * you can redistribute it and/or modify it under the terms of the GNU * General Public License (GPL) as published by the Free Software * Foundation, in version 2 as it comes in the "COPYING" file of the * VirtualBox OSE distribution. VirtualBox OSE is distributed in the * hope that it will be useful, but WITHOUT ANY WARRANTY of any kind. */ #ifndef ___MMInternal_h #define ___MMInternal_h #include #include #include #include #include #include #if !defined(IN_MM_R3) && !defined(IN_MM_R0) && !defined(IN_MM_GC) # error "Not in MM! This is an internal header!" #endif /** @defgroup grp_mm_int Internals * @internal * @ingroup grp_mm * @{ */ /** @name VM Ring-3 Heap Internals * @{ */ /** @def MMR3HEAP_WITH_STATISTICS * Enable MMR3Heap statistics. */ #if !defined(MMR3HEAP_WITH_STATISTICS) && defined(VBOX_WITH_STATISTICS) # define MMR3HEAP_WITH_STATISTICS #endif /** @def MMR3HEAP_SIZE_ALIGNMENT * The allocation size alignment of the MMR3Heap. */ #define MMR3HEAP_SIZE_ALIGNMENT 16 /** * Heap statistics record. * There is one global and one per allocation tag. */ typedef struct MMHEAPSTAT { /** Core avl node, key is the tag. */ AVLULNODECORE Core; /** Pointer to the heap the memory belongs to. */ struct MMHEAP *pHeap; #ifdef MMR3HEAP_WITH_STATISTICS /** Number of allocation. */ uint64_t cAllocations; /** Number of reallocations. */ uint64_t cReallocations; /** Number of frees. */ uint64_t cFrees; /** Failures. */ uint64_t cFailures; /** Number of bytes allocated (sum). */ uint64_t cbAllocated; /** Number of bytes freed. */ uint64_t cbFreed; /** Number of bytes currently allocated. */ size_t cbCurAllocated; #endif } MMHEAPSTAT; /** Pointer to heap statistics record. */ typedef MMHEAPSTAT *PMMHEAPSTAT; /** * Additional heap block header for relating allocations to the VM. */ typedef struct MMHEAPHDR { /** Pointer to the next record. */ struct MMHEAPHDR *pNext; /** Pointer to the previous record. */ struct MMHEAPHDR *pPrev; /** Pointer to the heap statistics record. * (Where the a PVM can be found.) */ PMMHEAPSTAT pStat; /** Size of the allocation (including this header). */ size_t cbSize; } MMHEAPHDR; /** Pointer to MM heap header. */ typedef MMHEAPHDR *PMMHEAPHDR; /** MM Heap structure. */ typedef struct MMHEAP { /** Lock protecting the heap. */ RTCRITSECT Lock; /** Heap block list head. */ PMMHEAPHDR pHead; /** Heap block list tail. */ PMMHEAPHDR pTail; /** Heap per tag statistics tree. */ PAVLULNODECORE pStatTree; /** The VM handle. */ PUVM pUVM; /** Heap global statistics. */ MMHEAPSTAT Stat; } MMHEAP; /** Pointer to MM Heap structure. */ typedef MMHEAP *PMMHEAP; /** @} */ /** @name Hypervisor Heap Internals * @{ */ /** @def MMHYPER_HEAP_FREE_DELAY * If defined, it indicates the number of frees that should be delayed. */ #if defined(__DOXYGEN__) # define MMHYPER_HEAP_FREE_DELAY 64 #endif /** @def MMHYPER_HEAP_FREE_POISON * If defined, it indicates that freed memory should be poisoned * with the value it has. */ #if defined(VBOX_STRICT) || defined(__DOXYGEN__) # define MMHYPER_HEAP_FREE_POISON 0xCB #endif /** * Hypervisor heap statistics record. * There is one global and one per allocation tag. */ typedef struct MMHYPERSTAT { /** Core avl node, key is the tag. * @todo The type is wrong! Get your lazy a$$ over and create that offsetted uint32_t version we need here! */ AVLOGCPHYSNODECORE Core; /** Aligning the 64-bit fields on a 64-bit line. */ uint32_t u32Padding0; /** Indicator for whether these statistics are registered with STAM or not. */ bool fRegistered; /** Number of allocation. */ uint64_t cAllocations; /** Number of frees. */ uint64_t cFrees; /** Failures. */ uint64_t cFailures; /** Number of bytes allocated (sum). */ uint64_t cbAllocated; /** Number of bytes freed (sum). */ uint64_t cbFreed; /** Number of bytes currently allocated. */ uint32_t cbCurAllocated; /** Max number of bytes allocated. */ uint32_t cbMaxAllocated; } MMHYPERSTAT; /** Pointer to hypervisor heap statistics record. */ typedef MMHYPERSTAT *PMMHYPERSTAT; /** * Hypervisor heap chunk. */ typedef struct MMHYPERCHUNK { /** Previous block in the list of all blocks. * This is relative to the start of the heap. */ uint32_t offNext; /** Offset to the previous block relative to this one. */ int32_t offPrev; /** The statistics record this allocation belongs to (self relative). */ int32_t offStat; /** Offset to the heap block (self relative). */ int32_t offHeap; } MMHYPERCHUNK; /** Pointer to a hypervisor heap chunk. */ typedef MMHYPERCHUNK *PMMHYPERCHUNK; /** * Hypervisor heap chunk. */ typedef struct MMHYPERCHUNKFREE { /** Main list. */ MMHYPERCHUNK core; /** Offset of the next chunk in the list of free nodes. */ uint32_t offNext; /** Offset of the previous chunk in the list of free nodes. */ int32_t offPrev; /** Size of the block. */ uint32_t cb; } MMHYPERCHUNKFREE; /** Pointer to a free hypervisor heap chunk. */ typedef MMHYPERCHUNKFREE *PMMHYPERCHUNKFREE; /** * The hypervisor heap. */ typedef struct MMHYPERHEAP { /** The typical magic (MMHYPERHEAP_MAGIC). */ uint32_t u32Magic; /** The heap size. (This structure is not included!) */ uint32_t cbHeap; /** The HC Ring-3 address of the VM. */ R3PTRTYPE(PVM) pVMHC; /** The HC Ring-3 address of the heap. */ R3R0PTRTYPE(uint8_t *) pbHeapHC; /** The GC address of the heap. */ GCPTRTYPE(uint8_t *) pbHeapGC; /** The GC address of the VM. */ GCPTRTYPE(PVM) pVMGC; /** The amount of free memory in the heap. */ uint32_t cbFree; /** Offset of the first free chunk in the heap. * The offset is relative to the start of the heap. */ uint32_t offFreeHead; /** Offset of the last free chunk in the heap. * The offset is relative to the start of the heap. */ uint32_t offFreeTail; /** Offset of the first page aligned block in the heap. * The offset is equal to cbHeap initially. */ uint32_t offPageAligned; /** Tree of hypervisor heap statistics. */ AVLOGCPHYSTREE HyperHeapStatTree; #ifdef MMHYPER_HEAP_FREE_DELAY /** Where to insert the next free. */ uint32_t iDelayedFree; /** Array of delayed frees. Circular. Offsets relative to this structure. */ struct { /** The free caller address. */ RTUINTPTR uCaller; /** The offset of the freed chunk. */ uint32_t offChunk; } aDelayedFrees[MMHYPER_HEAP_FREE_DELAY]; #else /** Padding the structure to a 64-bit aligned size. */ uint32_t u32Padding0; #endif } MMHYPERHEAP; /** Pointer to the hypervisor heap. */ typedef MMHYPERHEAP *PMMHYPERHEAP; /** Magic value for MMHYPERHEAP. (C. S. Lewis) */ #define MMHYPERHEAP_MAGIC 0x18981129 /** * Hypervisor heap minimum alignment (16 bytes). */ #define MMHYPER_HEAP_ALIGN_MIN 16 /** * The aligned size of the the MMHYPERHEAP structure. */ #define MMYPERHEAP_HDR_SIZE RT_ALIGN_Z(sizeof(MMHYPERHEAP), MMHYPER_HEAP_ALIGN_MIN * 4) /** @name Hypervisor heap chunk flags. * The flags are put in the first bits of the MMHYPERCHUNK::offPrev member. * These bits aren't used anyway because of the chunk minimal alignment (16 bytes). * @{ */ /** The chunk is free. (The code ASSUMES this is 0!) */ #define MMHYPERCHUNK_FLAGS_FREE 0x0 /** The chunk is in use. */ #define MMHYPERCHUNK_FLAGS_USED 0x1 /** The type mask. */ #define MMHYPERCHUNK_FLAGS_TYPE_MASK 0x1 /** The flag mask */ #define MMHYPERCHUNK_FLAGS_MASK 0x1 /** Checks if the chunk is free. */ #define MMHYPERCHUNK_ISFREE(pChunk) ( (((pChunk)->offPrev) & MMHYPERCHUNK_FLAGS_TYPE_MASK) == MMHYPERCHUNK_FLAGS_FREE ) /** Checks if the chunk is used. */ #define MMHYPERCHUNK_ISUSED(pChunk) ( (((pChunk)->offPrev) & MMHYPERCHUNK_FLAGS_TYPE_MASK) == MMHYPERCHUNK_FLAGS_USED ) /** Toggles FREE/USED flag of a chunk. */ #define MMHYPERCHUNK_SET_TYPE(pChunk, type) do { (pChunk)->offPrev = ((pChunk)->offPrev & ~MMHYPERCHUNK_FLAGS_TYPE_MASK) | ((type) & MMHYPERCHUNK_FLAGS_TYPE_MASK); } while (0) /** Gets the prev offset without the flags. */ #define MMHYPERCHUNK_GET_OFFPREV(pChunk) ((int32_t)((pChunk)->offPrev & ~MMHYPERCHUNK_FLAGS_MASK)) /** Sets the prev offset without changing the flags. */ #define MMHYPERCHUNK_SET_OFFPREV(pChunk, off) do { (pChunk)->offPrev = (off) | ((pChunk)->offPrev & MMHYPERCHUNK_FLAGS_MASK); } while (0) #if 0 /** Clears one or more flags. */ #define MMHYPERCHUNK_FLAGS_OP_CLEAR(pChunk, fFlags) do { ((pChunk)->offPrev) &= ~((fFlags) & MMHYPERCHUNK_FLAGS_MASK); } while (0) /** Sets one or more flags. */ #define MMHYPERCHUNK_FLAGS_OP_SET(pChunk, fFlags) do { ((pChunk)->offPrev) |= ((fFlags) & MMHYPERCHUNK_FLAGS_MASK); } while (0) /** Checks if one is set. */ #define MMHYPERCHUNK_FLAGS_OP_ISSET(pChunk, fFlag) (!!(((pChunk)->offPrev) & ((fFlag) & MMHYPERCHUNK_FLAGS_MASK))) #endif /** @} */ /** @} */ /** @name Page Pool Internals * @{ */ /** * Page sub pool * * About the allocation of this structrue. To keep the number of heap blocks, * the number of heap calls, and fragmentation low we allocate all the data * related to a MMPAGESUBPOOL node in one chunk. That means that after the * bitmap (which is of variable size) comes the SUPPAGE records and then * follows the lookup tree nodes. */ typedef struct MMPAGESUBPOOL { /** Pointer to next sub pool. */ struct MMPAGESUBPOOL *pNext; /** Pointer to next sub pool in the free chain. * This is NULL if we're not in the free chain or at the end of it. */ struct MMPAGESUBPOOL *pNextFree; /** Pointer to array of lock ranges. * This is allocated together with the MMPAGESUBPOOL and thus needs no freeing. * It follows immediately after the bitmap. * The reserved field is a pointer to this structure. */ PSUPPAGE paPhysPages; /** Pointer to the first page. */ void *pvPages; /** Size of the subpool. */ unsigned cPages; /** Number of free pages. */ unsigned cPagesFree; /** The allocation bitmap. * This may extend beyond the end of the defined array size. */ unsigned auBitmap[1]; /* ... SUPPAGE aRanges[1]; */ } MMPAGESUBPOOL; /** Pointer to page sub pool. */ typedef MMPAGESUBPOOL *PMMPAGESUBPOOL; /** * Page pool. */ typedef struct MMPAGEPOOL { /** List of subpools. */ PMMPAGESUBPOOL pHead; /** Head of subpools with free pages. */ PMMPAGESUBPOOL pHeadFree; /** AVLPV tree for looking up HC virtual addresses. * The tree contains MMLOOKUPVIRTPP records. */ PAVLPVNODECORE pLookupVirt; /** Tree for looking up HC physical addresses. * The tree contains MMLOOKUPPHYSHC records. */ AVLHCPHYSTREE pLookupPhys; /** Pointer to the VM this pool belongs. */ PVM pVM; /** Flag indicating the allocation method. * Set: SUPLowAlloc(). * Clear: SUPPageAlloc() + SUPPageLock(). */ bool fLow; /** Number of subpools. */ uint32_t cSubPools; /** Number of pages in pool. */ uint32_t cPages; #ifdef VBOX_WITH_STATISTICS /** Number of free pages in pool. */ uint32_t cFreePages; /** Number of alloc calls. */ STAMCOUNTER cAllocCalls; /** Number of free calls. */ STAMCOUNTER cFreeCalls; /** Number of to phys conversions. */ STAMCOUNTER cToPhysCalls; /** Number of to virtual conversions. */ STAMCOUNTER cToVirtCalls; /** Number of real errors. */ STAMCOUNTER cErrors; #endif } MMPAGEPOOL; /** Pointer to page pool. */ typedef MMPAGEPOOL *PMMPAGEPOOL; /** * Lookup record for HC virtual memory in the page pool. */ typedef struct MMPPLOOKUPHCPTR { /** The key is virtual address. */ AVLPVNODECORE Core; /** Pointer to subpool if lookup record for a pool. */ struct MMPAGESUBPOOL *pSubPool; } MMPPLOOKUPHCPTR; /** Pointer to virtual memory lookup record. */ typedef MMPPLOOKUPHCPTR *PMMPPLOOKUPHCPTR; /** * Lookup record for HC physical memory. */ typedef struct MMPPLOOKUPHCPHYS { /** The key is physical address. */ AVLHCPHYSNODECORE Core; /** Pointer to SUPPAGE record for this physical address. */ PSUPPAGE pPhysPage; } MMPPLOOKUPHCPHYS; /** Pointer to physical memory lookup record. */ typedef MMPPLOOKUPHCPHYS *PMMPPLOOKUPHCPHYS; /** @} */ /** * Type of memory that's locked. */ typedef enum MMLOCKEDTYPE { /** Hypervisor: Ring-3 memory locked by MM. */ MM_LOCKED_TYPE_HYPER, /** Hypervisor: Ring-3 memory locked by MM that shouldn't be freed up. */ MM_LOCKED_TYPE_HYPER_NOFREE, /** Hypervisor: Pre-locked ring-3 pages. */ MM_LOCKED_TYPE_HYPER_PAGES, /** Guest: Physical VM memory (RAM & MMIO2). */ MM_LOCKED_TYPE_PHYS } MMLOCKEDTYPE; /** Pointer to memory type. */ typedef MMLOCKEDTYPE *PMMLOCKEDTYPE; /** * Converts a SUPPAGE pointer to a MMLOCKEDMEM pointer. * @returns Pointer to the MMLOCKEDMEM record the range is associated with. * @param pSupPage Pointer to SUPPAGE structure managed by MM. */ #define MM_SUPRANGE_TO_MMLOCKEDMEM(pSupPage) ((PMMLOCKEDMEM)pSupPage->uReserved) /** * Locked memory record. */ typedef struct MMLOCKEDMEM { /** Address (host mapping). */ void *pv; /** Size. */ size_t cb; /** Next record. */ struct MMLOCKEDMEM *pNext; /** Record type. */ MMLOCKEDTYPE eType; /** Type specific data. */ union { /** Data for MM_LOCKED_TYPE_HYPER, MM_LOCKED_TYPE_HYPER_NOFREE and MM_LOCKED_TYPE_HYPER_PAGES. */ struct { unsigned uNothing; } hyper; /** Data for MM_LOCKED_TYPE_PHYS. */ struct { /** The GC physical address. * (Assuming that this is a linear range of GC physical pages.) */ RTGCPHYS GCPhys; } phys; } u; /** Physical Page Array. (Variable length.) * The uReserved field contains pointer to the MMLOCKMEM record. * Use the macro MM_SUPPAGE_TO_MMLOCKEDMEM() to convert. * * For MM_LOCKED_TYPE_PHYS the low 12 bits of the pvPhys member * are bits (MM_RAM_FLAGS_*) and not part of the physical address. */ SUPPAGE aPhysPages[1]; } MMLOCKEDMEM; /** Pointer to locked memory. */ typedef MMLOCKEDMEM *PMMLOCKEDMEM; /** * A registered Rom range. * * This is used to track ROM registrations both for debug reasons * and for resetting shadow ROM at reset. * * This is allocated of the MMR3Heap and thus only accessibel from ring-3. */ typedef struct MMROMRANGE { /** Pointer to the next */ struct MMROMRANGE *pNext; /** Address of the range. */ RTGCPHYS GCPhys; /** Size of the range. */ uint32_t cbRange; /** Shadow ROM? */ bool fShadow; /** Is the shadow ROM currently wriable? */ bool fWritable; /** The address of the virgin ROM image for shadow ROM. */ const void *pvBinary; /** The address of the guest RAM that's shadowing the ROM. (lazy bird) */ void *pvCopy; /** The ROM description. */ const char *pszDesc; } MMROMRANGE; /** Pointer to a ROM range. */ typedef MMROMRANGE *PMMROMRANGE; /** * Hypervisor memory mapping type. */ typedef enum MMLOOKUPHYPERTYPE { /** Invalid record. This is used for record which are incomplete. */ MMLOOKUPHYPERTYPE_INVALID = 0, /** Mapping of locked memory. */ MMLOOKUPHYPERTYPE_LOCKED, /** Mapping of contiguous HC physical memory. */ MMLOOKUPHYPERTYPE_HCPHYS, /** Mapping of contiguous GC physical memory. */ MMLOOKUPHYPERTYPE_GCPHYS, /** Dynamic mapping area (MMR3HyperReserve). * A conversion will require to check what's in the page table for the pages. */ MMLOOKUPHYPERTYPE_DYNAMIC } MMLOOKUPHYPERTYPE; /** * Lookup record for the hypervisor memory area. */ typedef struct MMLOOKUPHYPER { /** Byte offset from the start of this record to the next. * If the value is NIL_OFFSET the chain is terminated. */ int32_t offNext; /** Offset into the hypvervisor memory area. */ uint32_t off; /** Size of this part. */ uint32_t cb; /** Locking type. */ MMLOOKUPHYPERTYPE enmType; /** Type specific data */ union { /** Locked memory. */ struct { /** Host context pointer. */ R3PTRTYPE(void *) pvHC; /** Host context ring-0 pointer. */ RTR0PTR pvR0; /** Pointer to the locked mem record. */ R3PTRTYPE(PMMLOCKEDMEM) pLockedMem; } Locked; /** Contiguous physical memory. */ struct { /** Host context pointer. */ R3PTRTYPE(void *) pvHC; /** HC physical address corresponding to pvHC. */ RTHCPHYS HCPhys; } HCPhys; /** Contiguous guest physical memory. */ struct { /** HC physical address corresponding to pvHC. */ RTGCPHYS GCPhys; } GCPhys; } u; /** Description. */ R3PTRTYPE(const char *) pszDesc; } MMLOOKUPHYPER; /** Pointer to a hypervisor memory lookup record. */ typedef MMLOOKUPHYPER *PMMLOOKUPHYPER; /** * Converts a MM pointer into a VM pointer. * @returns Pointer to the VM structure the MM is part of. * @param pMM Pointer to MM instance data. */ #define MM2VM(pMM) ( (PVM)((char*)pMM - pMM->offVM) ) /** * MM Data (part of VM) */ typedef struct MM { /** Offset to the VM structure. * See MM2VM(). */ RTINT offVM; /** Set if MMR3InitPaging has been called. */ bool fDoneMMR3InitPaging; /** Set if PGM has been initialized and we can safely call PGMR3Map(). */ bool fPGMInitialized; #if GC_ARCH_BITS == 64 || HC_ARCH_BITS == 64 uint32_t u32Padding1; /**< alignment padding. */ #endif /** Lookup list for the Hypervisor Memory Area. * The offset is relative to the start of the heap. * Use pHyperHeapHC or pHyperHeapGC to calculate the address. */ RTUINT offLookupHyper; /** The offset of the next static mapping in the Hypervisor Memory Area. */ RTUINT offHyperNextStatic; /** The size of the HMA. * Starts at 12MB and will be fixed late in the init process. */ RTUINT cbHyperArea; /** Guest address of the Hypervisor Memory Area. */ RTGCPTR pvHyperAreaGC; /** The hypervisor heap (GC Ptr). */ GCPTRTYPE(PMMHYPERHEAP) pHyperHeapGC; /** The hypervisor heap (HC Ptr). */ R3R0PTRTYPE(PMMHYPERHEAP) pHyperHeapHC; /** List of memory locks. (HC only) */ R3PTRTYPE(PMMLOCKEDMEM) pLockedMem; /** Page pool. (HC only) */ R3R0PTRTYPE(PMMPAGEPOOL) pPagePool; /** Page pool pages in low memory. (HC only) */ R3R0PTRTYPE(PMMPAGEPOOL) pPagePoolLow; /** Pointer to the dummy page. * The dummy page is a paranoia thingy used for instance for pure MMIO RAM ranges * to make sure any bugs will not harm whatever the system stores in the first * physical page. */ R3PTRTYPE(void *) pvDummyPage; /** Physical address of the dummy page. */ RTHCPHYS HCPhysDummyPage; /** Size of the base RAM in bytes. (The CFGM RamSize value.) */ uint64_t cbRamBase; /** The number of base RAM pages that PGM has reserved (GMM). * @remarks Shadow ROMs will be counted twice (RAM+ROM), so it won't be 1:1 with * what the guest sees. */ uint64_t cBasePages; /** The number of shadow pages PGM has reserved (GMM). */ uint32_t cShadowPages; /** The number of fixed pages we've reserved (GMM). */ uint32_t cFixedPages; /** The head of the ROM ranges. */ R3PTRTYPE(PMMROMRANGE) pRomHead; } MM; /** Pointer to MM Data (part of VM). */ typedef MM *PMM; /** * MM data kept in the UVM. */ typedef struct MMUSERPERVM { /** Pointer to the MM R3 Heap. */ R3PTRTYPE(PMMHEAP) pHeap; } MMUSERPERVM; /** Pointer to the MM data kept in the UVM. */ typedef MMUSERPERVM *PMMUSERPERVM; __BEGIN_DECLS int mmR3UpdateReservation(PVM pVM); int mmR3PagePoolInit(PVM pVM); void mmR3PagePoolTerm(PVM pVM); int mmR3HeapCreateU(PUVM pUVM, PMMHEAP *ppHeap); void mmR3HeapDestroy(PMMHEAP pHeap); int mmR3HyperInit(PVM pVM); int mmR3HyperInitPaging(PVM pVM); int mmR3LockMem(PVM pVM, void *pv, size_t cb, MMLOCKEDTYPE eType, PMMLOCKEDMEM *ppLockedMem, bool fSilentFailure); int mmR3MapLocked(PVM pVM, PMMLOCKEDMEM pLockedMem, RTGCPTR Addr, unsigned iPage, size_t cPages, unsigned fFlags); const char *mmR3GetTagName(MMTAG enmTag); void mmR3PhysRomReset(PVM pVM); /** * Converts a pool address to a physical address. * The specified allocation type must match with the address. * * @returns Physical address. * @returns NIL_RTHCPHYS if not found or eType is not matching. * @param pPool Pointer to the page pool. * @param pv The address to convert. * @thread The Emulation Thread. */ MMDECL(RTHCPHYS) mmPagePoolPtr2Phys(PMMPAGEPOOL pPool, void *pv); /** * Converts a pool physical address to a linear address. * The specified allocation type must match with the address. * * @returns Physical address. * @returns NULL if not found or eType is not matching. * @param pPool Pointer to the page pool. * @param HCPhys The address to convert. * @thread The Emulation Thread. */ MMDECL(void *) mmPagePoolPhys2Ptr(PMMPAGEPOOL pPool, RTHCPHYS HCPhys); __END_DECLS /** @} */ #endif