/* $Id: MMHeap.cpp 13375 2008-10-17 14:18:29Z vboxsync $ */ /** @file * MM - Memory Manager - Heap. */ /* * Copyright (C) 2006-2007 Sun Microsystems, Inc. * * 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. * * Please contact Sun Microsystems, Inc., 4150 Network Circle, Santa * Clara, CA 95054 USA or visit http://www.sun.com if you need * additional information or have any questions. */ /******************************************************************************* * Header Files * *******************************************************************************/ #define LOG_GROUP LOG_GROUP_MM_HEAP #include #include #include #include "MMInternal.h" #include #include #include #include #include #include #include #include /******************************************************************************* * Internal Functions * *******************************************************************************/ static void *mmR3HeapAlloc(PMMHEAP pHeap, MMTAG enmTag, size_t cbSize, bool fZero); /** * Allocate and initialize a heap structure and it's associated substructures. * * @returns VBox status. * @param pVM The handle to the VM the heap should be associated with. * @param ppHeap Where to store the heap pointer. */ int mmR3HeapCreateU(PUVM pUVM, PMMHEAP *ppHeap) { PMMHEAP pHeap = (PMMHEAP)RTMemAllocZ(sizeof(MMHEAP) + sizeof(MMHEAPSTAT)); if (pHeap) { int rc = RTCritSectInit(&pHeap->Lock); if (VBOX_SUCCESS(rc)) { /* * Initialize the global stat record. */ pHeap->pUVM = pUVM; pHeap->Stat.pHeap = pHeap; #ifdef MMR3HEAP_WITH_STATISTICS PMMHEAPSTAT pStat = &pHeap->Stat; STAMR3RegisterU(pUVM, &pStat->cAllocations, STAMTYPE_U64, STAMVISIBILITY_ALWAYS, "/MM/R3Heap/cAllocations", STAMUNIT_CALLS, "Number or MMR3HeapAlloc() calls."); STAMR3RegisterU(pUVM, &pStat->cReallocations, STAMTYPE_U64, STAMVISIBILITY_ALWAYS, "/MM/R3Heap/cReallocations", STAMUNIT_CALLS, "Number of MMR3HeapRealloc() calls."); STAMR3RegisterU(pUVM, &pStat->cFrees, STAMTYPE_U64, STAMVISIBILITY_ALWAYS, "/MM/R3Heap/cFrees", STAMUNIT_CALLS, "Number of MMR3HeapFree() calls."); STAMR3RegisterU(pUVM, &pStat->cFailures, STAMTYPE_U64, STAMVISIBILITY_ALWAYS, "/MM/R3Heap/cFailures", STAMUNIT_COUNT, "Number of failures."); STAMR3RegisterU(pUVM, &pStat->cbCurAllocated, sizeof(pStat->cbCurAllocated) == sizeof(uint32_t) ? STAMTYPE_U32 : STAMTYPE_U64, STAMVISIBILITY_ALWAYS, "/MM/R3Heap/cbCurAllocated", STAMUNIT_BYTES, "Number of bytes currently allocated."); STAMR3RegisterU(pUVM, &pStat->cbAllocated, STAMTYPE_U64, STAMVISIBILITY_ALWAYS, "/MM/R3Heap/cbAllocated", STAMUNIT_BYTES, "Total number of bytes allocated."); STAMR3RegisterU(pUVM, &pStat->cbFreed, STAMTYPE_U64, STAMVISIBILITY_ALWAYS, "/MM/R3Heap/cbFreed", STAMUNIT_BYTES, "Total number of bytes freed."); #endif *ppHeap = pHeap; return VINF_SUCCESS; } AssertRC(rc); RTMemFree(pHeap); } AssertMsgFailed(("failed to allocate heap structure\n")); return VERR_NO_MEMORY; } /** * Destroy a heap. * * @param pHeap Heap handle. */ void mmR3HeapDestroy(PMMHEAP pHeap) { /* * Start by deleting the lock, that'll trap anyone * attempting to use the heap. */ RTCritSectDelete(&pHeap->Lock); /* * Walk the node list and free all the memory. */ PMMHEAPHDR pHdr = pHeap->pHead; while (pHdr) { void *pv = pHdr; pHdr = pHdr->pNext; RTMemFree(pv); } /* * Free the stat nodes. */ /** @todo free all nodes in a AVL tree. */ RTMemFree(pHeap); } /** * Allocate memory associating it with the VM for collective cleanup. * * The memory will be allocated from the default heap but a header * is added in which we keep track of which VM it belongs to and chain * all the allocations together so they can be freed in one go. * * This interface is typically used for memory block which will not be * freed during the life of the VM. * * @returns Pointer to allocated memory. * @param pUVM Pointer to the user mode VM structure. * @param enmTag Statistics tag. Statistics are collected on a per tag * basis in addition to a global one. Thus we can easily * identify how memory is used by the VM. * @param cbSize Size of the block. */ VMMR3DECL(void *) MMR3HeapAllocU(PUVM pUVM, MMTAG enmTag, size_t cbSize) { Assert(pUVM->mm.s.pHeap); return mmR3HeapAlloc(pUVM->mm.s.pHeap, enmTag, cbSize, false); } /** * Allocate memory associating it with the VM for collective cleanup. * * The memory will be allocated from the default heap but a header * is added in which we keep track of which VM it belongs to and chain * all the allocations together so they can be freed in one go. * * This interface is typically used for memory block which will not be * freed during the life of the VM. * * @returns Pointer to allocated memory. * @param pVM VM handle. * @param enmTag Statistics tag. Statistics are collected on a per tag * basis in addition to a global one. Thus we can easily * identify how memory is used by the VM. * @param cbSize Size of the block. */ VMMR3DECL(void *) MMR3HeapAlloc(PVM pVM, MMTAG enmTag, size_t cbSize) { return mmR3HeapAlloc(pVM->pUVM->mm.s.pHeap, enmTag, cbSize, false); } /** * Same as MMR3HeapAllocU(). * * @returns Pointer to allocated memory. * @param pUVM Pointer to the user mode VM structure. * @param enmTag Statistics tag. Statistics are collected on a per tag * basis in addition to a global one. Thus we can easily * identify how memory is used by the VM. * @param cbSize Size of the block. * @param ppv Where to store the pointer to the allocated memory on success. */ VMMR3DECL(int) MMR3HeapAllocExU(PUVM pUVM, MMTAG enmTag, size_t cbSize, void **ppv) { Assert(pUVM->mm.s.pHeap); void *pv = mmR3HeapAlloc(pUVM->mm.s.pHeap, enmTag, cbSize, false); if (pv) { *ppv = pv; return VINF_SUCCESS; } return VERR_NO_MEMORY; } /** * Same as MMR3HeapAlloc(). * * @returns Pointer to allocated memory. * @param pVM VM handle. * @param enmTag Statistics tag. Statistics are collected on a per tag * basis in addition to a global one. Thus we can easily * identify how memory is used by the VM. * @param cbSize Size of the block. * @param ppv Where to store the pointer to the allocated memory on success. */ VMMR3DECL(int) MMR3HeapAllocEx(PVM pVM, MMTAG enmTag, size_t cbSize, void **ppv) { void *pv = mmR3HeapAlloc(pVM->pUVM->mm.s.pHeap, enmTag, cbSize, false); if (pv) { *ppv = pv; return VINF_SUCCESS; } return VERR_NO_MEMORY; } /** * Same as MMR3HeapAlloc() only the memory is zeroed. * * @returns Pointer to allocated memory. * @param pUVM Pointer to the user mode VM structure. * @param enmTag Statistics tag. Statistics are collected on a per tag * basis in addition to a global one. Thus we can easily * identify how memory is used by the VM. * @param cbSize Size of the block. */ VMMR3DECL(void *) MMR3HeapAllocZU(PUVM pUVM, MMTAG enmTag, size_t cbSize) { return mmR3HeapAlloc(pUVM->mm.s.pHeap, enmTag, cbSize, true); } /** * Same as MMR3HeapAlloc() only the memory is zeroed. * * @returns Pointer to allocated memory. * @param pVM VM handle. * @param enmTag Statistics tag. Statistics are collected on a per tag * basis in addition to a global one. Thus we can easily * identify how memory is used by the VM. * @param cbSize Size of the block. */ VMMR3DECL(void *) MMR3HeapAllocZ(PVM pVM, MMTAG enmTag, size_t cbSize) { return mmR3HeapAlloc(pVM->pUVM->mm.s.pHeap, enmTag, cbSize, true); } /** * Same as MMR3HeapAllocZ(). * * @returns Pointer to allocated memory. * @param pUVM Pointer to the user mode VM structure. * @param enmTag Statistics tag. Statistics are collected on a per tag * basis in addition to a global one. Thus we can easily * identify how memory is used by the VM. * @param cbSize Size of the block. * @param ppv Where to store the pointer to the allocated memory on success. */ VMMR3DECL(int) MMR3HeapAllocZExU(PUVM pUVM, MMTAG enmTag, size_t cbSize, void **ppv) { Assert(pUVM->mm.s.pHeap); void *pv = mmR3HeapAlloc(pUVM->mm.s.pHeap, enmTag, cbSize, true); if (pv) { *ppv = pv; return VINF_SUCCESS; } return VERR_NO_MEMORY; } /** * Same as MMR3HeapAllocZ(). * * @returns Pointer to allocated memory. * @param pVM VM handle. * @param enmTag Statistics tag. Statistics are collected on a per tag * basis in addition to a global one. Thus we can easily * identify how memory is used by the VM. * @param cbSize Size of the block. * @param ppv Where to store the pointer to the allocated memory on success. */ VMMR3DECL(int) MMR3HeapAllocZEx(PVM pVM, MMTAG enmTag, size_t cbSize, void **ppv) { void *pv = mmR3HeapAlloc(pVM->pUVM->mm.s.pHeap, enmTag, cbSize, true); if (pv) { *ppv = pv; return VINF_SUCCESS; } return VERR_NO_MEMORY; } /** * Allocate memory from the heap. * * @returns Pointer to allocated memory. * @param pHeap Heap handle. * @param enmTag Statistics tag. Statistics are collected on a per tag * basis in addition to a global one. Thus we can easily * identify how memory is used by the VM. * @param cbSize Size of the block. * @param fZero Whether or not to zero the memory block. */ void *mmR3HeapAlloc(PMMHEAP pHeap, MMTAG enmTag, size_t cbSize, bool fZero) { #ifdef MMR3HEAP_WITH_STATISTICS RTCritSectEnter(&pHeap->Lock); /* * Find/alloc statistics nodes. */ pHeap->Stat.cAllocations++; PMMHEAPSTAT pStat = (PMMHEAPSTAT)RTAvlULGet(&pHeap->pStatTree, (AVLULKEY)enmTag); if (pStat) { pStat->cAllocations++; RTCritSectLeave(&pHeap->Lock); } else { pStat = (PMMHEAPSTAT)RTMemAllocZ(sizeof(MMHEAPSTAT)); if (!pStat) { pHeap->Stat.cFailures++; AssertMsgFailed(("Failed to allocate heap stat record.\n")); RTCritSectLeave(&pHeap->Lock); return NULL; } pStat->Core.Key = (AVLULKEY)enmTag; pStat->pHeap = pHeap; RTAvlULInsert(&pHeap->pStatTree, &pStat->Core); pStat->cAllocations++; RTCritSectLeave(&pHeap->Lock); /* register the statistics */ PUVM pUVM = pHeap->pUVM; char szName[80]; const char *pszTag = mmR3GetTagName(enmTag); RTStrPrintf(szName, sizeof(szName), "/MM/R3Heap/%s/cAllocations", pszTag); STAMR3RegisterU(pUVM, &pStat->cAllocations, STAMTYPE_U64, STAMVISIBILITY_ALWAYS, szName, STAMUNIT_CALLS, "Number or MMR3HeapAlloc() calls."); RTStrPrintf(szName, sizeof(szName), "/MM/R3Heap/%s/cReallocations", pszTag); STAMR3RegisterU(pUVM, &pStat->cReallocations, STAMTYPE_U64, STAMVISIBILITY_ALWAYS, szName, STAMUNIT_CALLS, "Number of MMR3HeapRealloc() calls."); RTStrPrintf(szName, sizeof(szName), "/MM/R3Heap/%s/cFrees", pszTag); STAMR3RegisterU(pUVM, &pStat->cFrees, STAMTYPE_U64, STAMVISIBILITY_ALWAYS, szName, STAMUNIT_CALLS, "Number of MMR3HeapFree() calls."); RTStrPrintf(szName, sizeof(szName), "/MM/R3Heap/%s/cFailures", pszTag); STAMR3RegisterU(pUVM, &pStat->cFailures, STAMTYPE_U64, STAMVISIBILITY_ALWAYS, szName, STAMUNIT_COUNT, "Number of failures."); RTStrPrintf(szName, sizeof(szName), "/MM/R3Heap/%s/cbCurAllocated", pszTag); STAMR3RegisterU(pUVM, &pStat->cbCurAllocated, STAMTYPE_U32, STAMVISIBILITY_ALWAYS, szName, STAMUNIT_BYTES, "Number of bytes currently allocated."); RTStrPrintf(szName, sizeof(szName), "/MM/R3Heap/%s/cbAllocated", pszTag); STAMR3RegisterU(pUVM, &pStat->cbAllocated, STAMTYPE_U64, STAMVISIBILITY_ALWAYS, szName, STAMUNIT_BYTES, "Total number of bytes allocated."); RTStrPrintf(szName, sizeof(szName), "/MM/R3Heap/%s/cbFreed", pszTag); STAMR3RegisterU(pUVM, &pStat->cbFreed, STAMTYPE_U64, STAMVISIBILITY_ALWAYS, szName, STAMUNIT_BYTES, "Total number of bytes freed."); } #endif /* * Validate input. */ if (cbSize == 0) { #ifdef MMR3HEAP_WITH_STATISTICS RTCritSectEnter(&pHeap->Lock); pStat->cFailures++; pHeap->Stat.cFailures++; RTCritSectLeave(&pHeap->Lock); #endif return NULL; } /* * Allocate heap block. */ cbSize = RT_ALIGN_Z(cbSize, MMR3HEAP_SIZE_ALIGNMENT) + sizeof(MMHEAPHDR); PMMHEAPHDR pHdr = (PMMHEAPHDR)(fZero ? RTMemAllocZ(cbSize) : RTMemAlloc(cbSize)); if (!pHdr) { AssertMsgFailed(("Failed to allocate heap block %d, enmTag=%x(%.4s).\n", cbSize, enmTag, &enmTag)); #ifdef MMR3HEAP_WITH_STATISTICS RTCritSectEnter(&pHeap->Lock); pStat->cFailures++; pHeap->Stat.cFailures++; RTCritSectLeave(&pHeap->Lock); #endif return NULL; } Assert(!((uintptr_t)pHdr & (RTMEM_ALIGNMENT - 1))); RTCritSectEnter(&pHeap->Lock); /* * Init and link in the header. */ pHdr->pNext = NULL; pHdr->pPrev = pHeap->pTail; if (pHdr->pPrev) pHdr->pPrev->pNext = pHdr; else pHeap->pHead = pHdr; pHeap->pTail = pHdr; #ifdef MMR3HEAP_WITH_STATISTICS pHdr->pStat = pStat; #else pHdr->pStat = &pHeap->Stat; #endif pHdr->cbSize = cbSize; /* * Update statistics */ #ifdef MMR3HEAP_WITH_STATISTICS pStat->cbAllocated += cbSize; pStat->cbCurAllocated += cbSize; pHeap->Stat.cbAllocated += cbSize; pHeap->Stat.cbCurAllocated += cbSize; #endif RTCritSectLeave(&pHeap->Lock); return pHdr + 1; } /** * Reallocate memory allocated with MMR3HeapAlloc() or MMR3HeapRealloc(). * * @returns Pointer to reallocated memory. * @param pv Pointer to the memory block to reallocate. * Must not be NULL! * @param cbNewSize New block size. */ VMMR3DECL(void *) MMR3HeapRealloc(void *pv, size_t cbNewSize) { AssertMsg(pv, ("Invalid pointer pv=%p\n", pv)); if (!pv) return NULL; /* * If newsize is zero then this is a free. */ if (!cbNewSize) { MMR3HeapFree(pv); return NULL; } /* * Validate header. */ PMMHEAPHDR pHdr = (PMMHEAPHDR)pv - 1; if ( pHdr->cbSize & (MMR3HEAP_SIZE_ALIGNMENT - 1) || (uintptr_t)pHdr & (RTMEM_ALIGNMENT - 1)) { AssertMsgFailed(("Invalid heap header! pv=%p, size=%#x\n", pv, pHdr->cbSize)); return NULL; } Assert(pHdr->pStat != NULL); Assert(!((uintptr_t)pHdr->pNext & (RTMEM_ALIGNMENT - 1))); Assert(!((uintptr_t)pHdr->pPrev & (RTMEM_ALIGNMENT - 1))); PMMHEAP pHeap = pHdr->pStat->pHeap; #ifdef MMR3HEAP_WITH_STATISTICS RTCritSectEnter(&pHeap->Lock); pHdr->pStat->cReallocations++; pHeap->Stat.cReallocations++; RTCritSectLeave(&pHeap->Lock); #endif /* * Rellocate the block. */ cbNewSize = RT_ALIGN_Z(cbNewSize, MMR3HEAP_SIZE_ALIGNMENT) + sizeof(MMHEAPHDR); PMMHEAPHDR pHdrNew = (PMMHEAPHDR)RTMemRealloc(pHdr, cbNewSize); if (!pHdrNew) { #ifdef MMR3HEAP_WITH_STATISTICS RTCritSectEnter(&pHeap->Lock); pHdr->pStat->cFailures++; pHeap->Stat.cFailures++; RTCritSectLeave(&pHeap->Lock); #endif return NULL; } /* * Update pointers. */ if (pHdrNew != pHdr) { RTCritSectEnter(&pHeap->Lock); if (pHdrNew->pPrev) pHdrNew->pPrev->pNext = pHdrNew; else pHeap->pHead = pHdrNew; if (pHdrNew->pNext) pHdrNew->pNext->pPrev = pHdrNew; else pHeap->pTail = pHdrNew; RTCritSectLeave(&pHeap->Lock); } /* * Update statistics. */ #ifdef MMR3HEAP_WITH_STATISTICS RTCritSectEnter(&pHeap->Lock); pHdrNew->pStat->cbAllocated += cbNewSize - pHdrNew->cbSize; pHeap->Stat.cbAllocated += cbNewSize - pHdrNew->cbSize; RTCritSectLeave(&pHeap->Lock); #endif pHdrNew->cbSize = cbNewSize; return pHdrNew + 1; } /** * Duplicates the specified string. * * @returns Pointer to the duplicate. * @returns NULL on failure or when input NULL. * @param pUVM Pointer to the user mode VM structure. * @param enmTag Statistics tag. Statistics are collected on a per tag * basis in addition to a global one. Thus we can easily * identify how memory is used by the VM. * @param psz The string to duplicate. NULL is allowed. */ VMMR3DECL(char *) MMR3HeapStrDupU(PUVM pUVM, MMTAG enmTag, const char *psz) { if (!psz) return NULL; AssertPtr(psz); size_t cch = strlen(psz) + 1; char *pszDup = (char *)MMR3HeapAllocU(pUVM, enmTag, cch); if (pszDup) memcpy(pszDup, psz, cch); return pszDup; } /** * Duplicates the specified string. * * @returns Pointer to the duplicate. * @returns NULL on failure or when input NULL. * @param pVM The VM handle. * @param enmTag Statistics tag. Statistics are collected on a per tag * basis in addition to a global one. Thus we can easily * identify how memory is used by the VM. * @param psz The string to duplicate. NULL is allowed. */ VMMR3DECL(char *) MMR3HeapStrDup(PVM pVM, MMTAG enmTag, const char *psz) { return MMR3HeapStrDupU(pVM->pUVM, enmTag, psz); } /** * Allocating string printf. * * @returns Pointer to the string. * @param pVM The VM * @param enmTag The statistics tag. * @param pszFormat The format string. * @param ... Format arguments. */ VMMR3DECL(char *) MMR3HeapAPrintf(PVM pVM, MMTAG enmTag, const char *pszFormat, ...) { va_list va; va_start(va, pszFormat); char *psz = MMR3HeapAPrintfVU(pVM->pUVM, enmTag, pszFormat, va); va_end(va); return psz; } /** * Allocating string printf. * * @returns Pointer to the string. * @param pUVM Pointer to the user mode VM structure. * @param enmTag The statistics tag. * @param pszFormat The format string. * @param ... Format arguments. */ VMMR3DECL(char *) MMR3HeapAPrintfU(PUVM pUVM, MMTAG enmTag, const char *pszFormat, ...) { va_list va; va_start(va, pszFormat); char *psz = MMR3HeapAPrintfVU(pUVM, enmTag, pszFormat, va); va_end(va); return psz; } /** * Allocating string printf. * * @returns Pointer to the string. * @param pVM The VM * @param enmTag The statistics tag. * @param pszFormat The format string. * @param va Format arguments. */ VMMR3DECL(char *) MMR3HeapAPrintfV(PVM pVM, MMTAG enmTag, const char *pszFormat, va_list va) { return MMR3HeapAPrintfVU(pVM->pUVM, enmTag, pszFormat, va); } /** * Allocating string printf. * * @returns Pointer to the string. * @param pUVM Pointer to the user mode VM structure. * @param enmTag The statistics tag. * @param pszFormat The format string. * @param va Format arguments. */ VMMR3DECL(char *) MMR3HeapAPrintfVU(PUVM pUVM, MMTAG enmTag, const char *pszFormat, va_list va) { /* * The lazy bird way. */ char *psz; int cch = RTStrAPrintfV(&psz, pszFormat, va); if (cch < 0) return NULL; Assert(psz[cch] == '\0'); char *pszRet = (char *)MMR3HeapAllocU(pUVM, enmTag, cch + 1); if (pszRet) memcpy(pszRet, psz, cch + 1); RTStrFree(psz); return pszRet; } /** * Releases memory allocated with MMR3HeapAlloc() or MMR3HeapRealloc(). * * @param pv Pointer to the memory block to free. */ VMMR3DECL(void) MMR3HeapFree(void *pv) { /* Ignore NULL pointers. */ if (!pv) return; /* * Validate header. */ PMMHEAPHDR pHdr = (PMMHEAPHDR)pv - 1; if ( pHdr->cbSize & (MMR3HEAP_SIZE_ALIGNMENT - 1) || (uintptr_t)pHdr & (RTMEM_ALIGNMENT - 1)) { AssertMsgFailed(("Invalid heap header! pv=%p, size=%#x\n", pv, pHdr->cbSize)); return; } Assert(pHdr->pStat != NULL); Assert(!((uintptr_t)pHdr->pNext & (RTMEM_ALIGNMENT - 1))); Assert(!((uintptr_t)pHdr->pPrev & (RTMEM_ALIGNMENT - 1))); /* * Update statistics */ PMMHEAP pHeap = pHdr->pStat->pHeap; RTCritSectEnter(&pHeap->Lock); #ifdef MMR3HEAP_WITH_STATISTICS pHdr->pStat->cFrees++; pHeap->Stat.cFrees++; pHdr->pStat->cbFreed += pHdr->cbSize; pHeap->Stat.cbFreed += pHdr->cbSize; pHdr->pStat->cbCurAllocated -= pHdr->cbSize; pHeap->Stat.cbCurAllocated -= pHdr->cbSize; #endif /* * Unlink it. */ if (pHdr->pPrev) pHdr->pPrev->pNext = pHdr->pNext; else pHeap->pHead = pHdr->pNext; if (pHdr->pNext) pHdr->pNext->pPrev = pHdr->pPrev; else pHeap->pTail = pHdr->pPrev; RTCritSectLeave(&pHeap->Lock); /* * Free the memory. */ RTMemFree(pHdr); } /** * Gets the string name of a memory tag. * * @returns name of enmTag. * @param enmTag The tag. */ const char *mmR3GetTagName(MMTAG enmTag) { switch (enmTag) { #define TAG2STR(tag) case MM_TAG_##tag: return #tag TAG2STR(CFGM); TAG2STR(CFGM_BYTES); TAG2STR(CFGM_STRING); TAG2STR(CFGM_USER); TAG2STR(CSAM); TAG2STR(CSAM_PATCH); TAG2STR(DBGF); TAG2STR(DBGF_INFO); TAG2STR(DBGF_LINE); TAG2STR(DBGF_LINE_DUP); TAG2STR(DBGF_MODULE); TAG2STR(DBGF_OS); TAG2STR(DBGF_STACK); TAG2STR(DBGF_SYMBOL); TAG2STR(DBGF_SYMBOL_DUP); TAG2STR(EM); TAG2STR(IOM); TAG2STR(IOM_STATS); TAG2STR(MM); TAG2STR(MM_LOOKUP_GUEST); TAG2STR(MM_LOOKUP_PHYS); TAG2STR(MM_LOOKUP_VIRT); TAG2STR(MM_PAGE); TAG2STR(PARAV); TAG2STR(PATM); TAG2STR(PATM_PATCH); TAG2STR(PDM); TAG2STR(PDM_DEVICE); TAG2STR(PDM_DEVICE_USER); TAG2STR(PDM_DRIVER); TAG2STR(PDM_DRIVER_USER); TAG2STR(PDM_USB); TAG2STR(PDM_USB_USER); TAG2STR(PDM_LUN); TAG2STR(PDM_QUEUE); TAG2STR(PDM_THREAD); TAG2STR(PDM_ASYNC_COMPLETION); TAG2STR(PGM); TAG2STR(PGM_CHUNK_MAPPING); TAG2STR(PGM_HANDLERS); TAG2STR(PGM_PHYS); TAG2STR(PGM_POOL); TAG2STR(REM); TAG2STR(SELM); TAG2STR(SSM); TAG2STR(STAM); TAG2STR(TM); TAG2STR(TRPM); TAG2STR(VM); TAG2STR(VM_REQ); TAG2STR(VMM); TAG2STR(HWACCM); #undef TAG2STR default: { AssertMsgFailed(("Unknown tag %d! forgot to add it to the switch?\n", enmTag)); static char sz[48]; RTStrPrintf(sz, sizeof(sz), "%d", enmTag); return sz; } } }