/* $Id: alloc-ef-r0drv.cpp 62592 2016-07-27 13:24:48Z vboxsync $ */ /** @file * IPRT - Memory Allocation, electric fence for ring-0 drivers. */ /* * Copyright (C) 2006-2016 Oracle Corporation * * 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. * * The contents of this file may alternatively be used under the terms * of the Common Development and Distribution License Version 1.0 * (CDDL) only, as it comes in the "COPYING.CDDL" file of the * VirtualBox OSE distribution, in which case the provisions of the * CDDL are applicable instead of those of the GPL. * * You may elect to license modified versions of this file under the * terms and conditions of either the GPL or the CDDL or both. */ /********************************************************************************************************************************* * Header Files * *********************************************************************************************************************************/ #define RTMEM_NO_WRAP_TO_EF_APIS #include "internal/iprt.h" #include #include #include #include #include #include #include #include #include #include #include #include "internal/mem.h" /********************************************************************************************************************************* * Defined Constants And Macros * *********************************************************************************************************************************/ #if defined(DOXYGEN_RUNNING) # define RTR0MEM_EF_IN_FRONT #endif /** @def RTR0MEM_EF_SIZE * The size of the fence. This must be page aligned. */ #define RTR0MEM_EF_SIZE PAGE_SIZE /** @def RTR0MEM_EF_ALIGNMENT * The allocation alignment, power of two of course. * * Use this for working around misaligned sizes, usually stemming from * allocating a string or something after the main structure. When you * encounter this, please fix the allocation to RTMemAllocVar or RTMemAllocZVar. */ #if 0 # define RTR0MEM_EF_ALIGNMENT (ARCH_BITS / 8) #else # define RTR0MEM_EF_ALIGNMENT 1 #endif /** @def RTR0MEM_EF_IN_FRONT * Define this to put the fence up in front of the block. * The default (when this isn't defined) is to up it up after the block. */ //# define RTR0MEM_EF_IN_FRONT /** @def RTR0MEM_EF_FREE_DELAYED * This define will enable free() delay and protection of the freed data * while it's being delayed. The value of RTR0MEM_EF_FREE_DELAYED defines * the threshold of the delayed blocks. * Delayed blocks does not consume any physical memory, only virtual address space. */ #define RTR0MEM_EF_FREE_DELAYED (20 * _1M) /** @def RTR0MEM_EF_FREE_FILL * This define will enable memset(,RTR0MEM_EF_FREE_FILL,)'ing the user memory * in the block before freeing/decommitting it. This is useful in GDB since GDB * appears to be able to read the content of the page even after it's been * decommitted. */ #define RTR0MEM_EF_FREE_FILL 'f' /** @def RTR0MEM_EF_FILLER * This define will enable memset(,RTR0MEM_EF_FILLER,)'ing the allocated * memory when the API doesn't require it to be zero'd. */ #define RTR0MEM_EF_FILLER 0xef /** @def RTR0MEM_EF_NOMAN_FILLER * This define will enable memset(,RTR0MEM_EF_NOMAN_FILLER,)'ing the * unprotected but not allocated area of memory, the so called no man's land. */ #define RTR0MEM_EF_NOMAN_FILLER 0xaa /** @def RTR0MEM_EF_FENCE_FILLER * This define will enable memset(,RTR0MEM_EF_FENCE_FILLER,)'ing the * fence itself, as debuggers can usually read them. */ #define RTR0MEM_EF_FENCE_FILLER 0xcc /********************************************************************************************************************************* * Header Files * *********************************************************************************************************************************/ #ifdef RT_OS_WINDOWS # include #elif !defined(RT_OS_FREEBSD) # include #endif #include #include /********************************************************************************************************************************* * Structures and Typedefs * *********************************************************************************************************************************/ /** * Allocation types. */ typedef enum RTMEMTYPE { RTMEMTYPE_RTMEMALLOC, RTMEMTYPE_RTMEMALLOCZ, RTMEMTYPE_RTMEMREALLOC, RTMEMTYPE_RTMEMFREE, RTMEMTYPE_NEW, RTMEMTYPE_NEW_ARRAY, RTMEMTYPE_DELETE, RTMEMTYPE_DELETE_ARRAY } RTMEMTYPE; /** * Node tracking a memory allocation. */ typedef struct RTR0MEMEFBLOCK { /** Avl node code, key is the user block pointer. */ AVLPVNODECORE Core; /** Allocation type. */ RTMEMTYPE enmType; /** The memory object. */ RTR0MEMOBJ hMemObj; /** The unaligned size of the block. */ size_t cbUnaligned; /** The aligned size of the block. */ size_t cbAligned; /** The allocation tag (read-only string). */ const char *pszTag; /** The return address of the allocator function. */ void *pvCaller; /** Line number of the alloc call. */ unsigned iLine; /** File from within the allocation was made. */ const char *pszFile; /** Function from within the allocation was made. */ const char *pszFunction; } RTR0MEMEFBLOCK, *PRTR0MEMEFBLOCK; /********************************************************************************************************************************* * Global Variables * *********************************************************************************************************************************/ /** Spinlock protecting the all the block's globals. */ static volatile uint32_t g_BlocksLock; /** Tree tracking the allocations. */ static AVLPVTREE g_BlocksTree; #ifdef RTR0MEM_EF_FREE_DELAYED /** Tail of the delayed blocks. */ static volatile PRTR0MEMEFBLOCK g_pBlocksDelayHead; /** Tail of the delayed blocks. */ static volatile PRTR0MEMEFBLOCK g_pBlocksDelayTail; /** Number of bytes in the delay list (includes fences). */ static volatile size_t g_cbBlocksDelay; #endif /* RTR0MEM_EF_FREE_DELAYED */ /** Array of pointers free watches for. */ void *gapvRTMemFreeWatch[4] = {NULL, NULL, NULL, NULL}; /** Enable logging of all freed memory. */ bool gfRTMemFreeLog = false; /********************************************************************************************************************************* * Internal Functions * *********************************************************************************************************************************/ /** * @callback_method_impl{FNRTSTROUTPUT} */ static DECLCALLBACK(size_t) rtR0MemEfWrite(void *pvArg, const char *pachChars, size_t cbChars) { if (cbChars) { RTLogWriteDebugger(pachChars, cbChars); RTLogWriteStdOut(pachChars, cbChars); RTLogWriteUser(pachChars, cbChars); } return cbChars; } /** * Complains about something. */ static void rtR0MemComplain(const char *pszOp, const char *pszFormat, ...) { va_list args; RTStrFormat(rtR0MemEfWrite, NULL, NULL, NULL, "RTMem error: %s: ", pszOp); va_start(args, pszFormat); RTStrFormatV(rtR0MemEfWrite, NULL, NULL, NULL, pszFormat, args); va_end(args); RTAssertDoPanic(); } /** * Log an event. */ DECLINLINE(void) rtR0MemLog(const char *pszOp, const char *pszFormat, ...) { #if 0 va_list args; RTStrFormat(rtR0MemEfWrite, NULL, NULL, NULL, "RTMem info: %s: ", pszOp); va_start(args, pszFormat); RTStrFormatV(rtR0MemEfWrite, NULL, NULL, NULL, pszFormat, args); va_end(args); #else NOREF(pszOp); NOREF(pszFormat); #endif } /** * Acquires the lock. */ DECLINLINE(RTCCUINTREG) rtR0MemBlockLock(void) { RTCCUINTREG uRet; unsigned c = 0; if (RTThreadPreemptIsEnabled(NIL_RTTHREAD)) { for (;;) { uRet = ASMIntDisableFlags(); if (ASMAtomicCmpXchgU32(&g_BlocksLock, 1, 0)) break; ASMSetFlags(uRet); RTThreadSleepNoLog(((++c) >> 2) & 31); } } else { for (;;) { uRet = ASMIntDisableFlags(); if (ASMAtomicCmpXchgU32(&g_BlocksLock, 1, 0)) break; ASMSetFlags(uRet); ASMNopPause(); if (++c & 3) ASMNopPause(); } } return uRet; } /** * Releases the lock. */ DECLINLINE(void) rtR0MemBlockUnlock(RTCCUINTREG fSavedIntFlags) { Assert(g_BlocksLock == 1); ASMAtomicXchgU32(&g_BlocksLock, 0); ASMSetFlags(fSavedIntFlags); } /** * Creates a block. */ DECLINLINE(PRTR0MEMEFBLOCK) rtR0MemBlockCreate(RTMEMTYPE enmType, size_t cbUnaligned, size_t cbAligned, const char *pszTag, void *pvCaller, RT_SRC_POS_DECL) { PRTR0MEMEFBLOCK pBlock = (PRTR0MEMEFBLOCK)RTMemAlloc(sizeof(*pBlock)); if (pBlock) { pBlock->enmType = enmType; pBlock->cbUnaligned = cbUnaligned; pBlock->cbAligned = cbAligned; pBlock->pszTag = pszTag; pBlock->pvCaller = pvCaller; pBlock->iLine = iLine; pBlock->pszFile = pszFile; pBlock->pszFunction = pszFunction; } return pBlock; } /** * Frees a block. */ DECLINLINE(void) rtR0MemBlockFree(PRTR0MEMEFBLOCK pBlock) { RTMemFree(pBlock); } /** * Insert a block from the tree. */ DECLINLINE(void) rtR0MemBlockInsert(PRTR0MEMEFBLOCK pBlock, void *pv, RTR0MEMOBJ hMemObj) { pBlock->Core.Key = pv; pBlock->hMemObj = hMemObj; RTCCUINTREG fSavedIntFlags = rtR0MemBlockLock(); bool fRc = RTAvlPVInsert(&g_BlocksTree, &pBlock->Core); rtR0MemBlockUnlock(fSavedIntFlags); AssertRelease(fRc); } /** * Remove a block from the tree and returns it to the caller. */ DECLINLINE(PRTR0MEMEFBLOCK) rtR0MemBlockRemove(void *pv) { RTCCUINTREG fSavedIntFlags = rtR0MemBlockLock(); PRTR0MEMEFBLOCK pBlock = (PRTR0MEMEFBLOCK)RTAvlPVRemove(&g_BlocksTree, pv); rtR0MemBlockUnlock(fSavedIntFlags); return pBlock; } /** * Gets a block. */ DECLINLINE(PRTR0MEMEFBLOCK) rtR0MemBlockGet(void *pv) { RTCCUINTREG fSavedIntFlags = rtR0MemBlockLock(); PRTR0MEMEFBLOCK pBlock = (PRTR0MEMEFBLOCK)RTAvlPVGet(&g_BlocksTree, pv); rtR0MemBlockUnlock(fSavedIntFlags); return pBlock; } /** * Dumps one allocation. */ static DECLCALLBACK(int) RTMemDumpOne(PAVLPVNODECORE pNode, void *pvUser) { PRTR0MEMEFBLOCK pBlock = (PRTR0MEMEFBLOCK)pNode; RTStrFormat(rtR0MemEfWrite, NULL, NULL, NULL, "%p %08lx(+%02lx) %p\n", pBlock->Core.Key, (unsigned long)pBlock->cbUnaligned, (unsigned long)(pBlock->cbAligned - pBlock->cbUnaligned), pBlock->pvCaller); NOREF(pvUser); return 0; } /** * Dumps the allocated blocks. * This is something which you should call from gdb. */ RT_C_DECLS_BEGIN void RTMemDump(void); RT_C_DECLS_END void RTMemDump(void) { RTStrFormat(rtR0MemEfWrite, NULL, NULL, NULL, "address size(alg) caller\n"); RTAvlPVDoWithAll(&g_BlocksTree, true, RTMemDumpOne, NULL); } #ifdef RTR0MEM_EF_FREE_DELAYED /** * Insert a delayed block. */ DECLINLINE(void) rtR0MemBlockDelayInsert(PRTR0MEMEFBLOCK pBlock) { size_t cbBlock = RT_ALIGN_Z(pBlock->cbAligned, PAGE_SIZE) + RTR0MEM_EF_SIZE; pBlock->Core.pRight = NULL; pBlock->Core.pLeft = NULL; RTCCUINTREG fSavedIntFlags = rtR0MemBlockLock(); if (g_pBlocksDelayHead) { g_pBlocksDelayHead->Core.pLeft = (PAVLPVNODECORE)pBlock; pBlock->Core.pRight = (PAVLPVNODECORE)g_pBlocksDelayHead; g_pBlocksDelayHead = pBlock; } else { g_pBlocksDelayTail = pBlock; g_pBlocksDelayHead = pBlock; } g_cbBlocksDelay += cbBlock; rtR0MemBlockUnlock(fSavedIntFlags); } /** * Removes a delayed block. */ DECLINLINE(PRTR0MEMEFBLOCK) rtR0MemBlockDelayRemove(void) { PRTR0MEMEFBLOCK pBlock = NULL; RTCCUINTREG fSavedIntFlags = rtR0MemBlockLock(); if (g_cbBlocksDelay > RTR0MEM_EF_FREE_DELAYED) { pBlock = g_pBlocksDelayTail; if (pBlock) { g_pBlocksDelayTail = (PRTR0MEMEFBLOCK)pBlock->Core.pLeft; if (pBlock->Core.pLeft) pBlock->Core.pLeft->pRight = NULL; else g_pBlocksDelayHead = NULL; g_cbBlocksDelay -= RT_ALIGN_Z(pBlock->cbAligned, PAGE_SIZE) + RTR0MEM_EF_SIZE; } } rtR0MemBlockUnlock(fSavedIntFlags); return pBlock; } #endif /* RTR0MEM_EF_FREE_DELAYED */ static void rtR0MemFreeBlock(PRTR0MEMEFBLOCK pBlock, const char *pszOp) { void *pv = pBlock->Core.Key; # ifdef RTR0MEM_EF_IN_FRONT void *pvBlock = (char *)pv - RTR0MEM_EF_SIZE; # else void *pvBlock = (void *)((uintptr_t)pv & ~(uintptr_t)PAGE_OFFSET_MASK); # endif size_t cbBlock = RT_ALIGN_Z(pBlock->cbAligned, PAGE_SIZE) + RTR0MEM_EF_SIZE; int rc = RTR0MemObjProtect(pBlock->hMemObj, 0 /*offSub*/, RT_ALIGN_Z(cbBlock, PAGE_SIZE), RTMEM_PROT_READ | RTMEM_PROT_WRITE); if (RT_FAILURE(rc)) rtR0MemComplain(pszOp, "RTR0MemObjProtect([%p], 0, %#x, RTMEM_PROT_READ | RTMEM_PROT_WRITE) -> %Rrc\n", pvBlock, cbBlock, rc); rc = RTR0MemObjFree(pBlock->hMemObj, true /*fFreeMappings*/); if (RT_FAILURE(rc)) rtR0MemComplain(pszOp, "RTR0MemObjFree([%p LB %#x]) -> %Rrc\n", pvBlock, cbBlock, rc); pBlock->hMemObj = NIL_RTR0MEMOBJ; rtR0MemBlockFree(pBlock); } /** * Initialize call, we shouldn't fail here. */ void rtR0MemEfInit(void) { } /** * @callback_method_impl{AVLPVCALLBACK} */ static DECLCALLBACK(int) rtR0MemEfDestroyBlock(PAVLPVNODECORE pNode, void *pvUser) { PRTR0MEMEFBLOCK pBlock = (PRTR0MEMEFBLOCK)pNode; /* Note! pszFile and pszFunction may be invalid at this point. */ rtR0MemComplain("rtR0MemEfDestroyBlock", "Leaking %zu bytes at %p (iLine=%u pvCaller=%p)\n", pBlock->cbAligned, pBlock->Core.Key, pBlock->iLine, pBlock->pvCaller); rtR0MemFreeBlock(pBlock, "rtR0MemEfDestroyBlock"); NOREF(pvUser); return VINF_SUCCESS; } /** * Termination call. * * Will check and free memory. */ void rtR0MemEfTerm(void) { #ifdef RTR0MEM_EF_FREE_DELAYED /* * Release delayed frees. */ RTCCUINTREG fSavedIntFlags = rtR0MemBlockLock(); for (;;) { PRTR0MEMEFBLOCK pBlock = g_pBlocksDelayTail; if (pBlock) { g_pBlocksDelayTail = (PRTR0MEMEFBLOCK)pBlock->Core.pLeft; if (pBlock->Core.pLeft) pBlock->Core.pLeft->pRight = NULL; else g_pBlocksDelayHead = NULL; rtR0MemBlockUnlock(fSavedIntFlags); rtR0MemFreeBlock(pBlock, "rtR0MemEfTerm"); rtR0MemBlockLock(); } else break; } g_cbBlocksDelay = 0; rtR0MemBlockUnlock(fSavedIntFlags); #endif /* * Complain about leaks. Then release them. */ RTAvlPVDestroy(&g_BlocksTree, rtR0MemEfDestroyBlock, NULL); } /** * Internal allocator. */ static void * rtR0MemAlloc(const char *pszOp, RTMEMTYPE enmType, size_t cbUnaligned, size_t cbAligned, const char *pszTag, void *pvCaller, RT_SRC_POS_DECL) { /* * Sanity. */ if ( RT_ALIGN_Z(RTR0MEM_EF_SIZE, PAGE_SIZE) != RTR0MEM_EF_SIZE && RTR0MEM_EF_SIZE <= 0) { rtR0MemComplain(pszOp, "Invalid E-fence size! %#x\n", RTR0MEM_EF_SIZE); return NULL; } if (!cbUnaligned) { #if 1 rtR0MemComplain(pszOp, "Request of ZERO bytes allocation!\n"); return NULL; #else cbAligned = cbUnaligned = 1; #endif } #ifndef RTR0MEM_EF_IN_FRONT /* Alignment decreases fence accuracy, but this is at least partially * counteracted by filling and checking the alignment padding. When the * fence is in front then then no extra alignment is needed. */ cbAligned = RT_ALIGN_Z(cbAligned, RTR0MEM_EF_ALIGNMENT); #endif /* * Allocate the trace block. */ PRTR0MEMEFBLOCK pBlock = rtR0MemBlockCreate(enmType, cbUnaligned, cbAligned, pszTag, pvCaller, RT_SRC_POS_ARGS); if (!pBlock) { rtR0MemComplain(pszOp, "Failed to allocate trace block!\n"); return NULL; } /* * Allocate a block with page alignment space + the size of the E-fence. */ void *pvBlock = NULL; RTR0MEMOBJ hMemObj; size_t cbBlock = RT_ALIGN_Z(cbAligned, PAGE_SIZE) + RTR0MEM_EF_SIZE; int rc = RTR0MemObjAllocPage(&hMemObj, cbBlock, false /*fExecutable*/); if (RT_SUCCESS(rc)) pvBlock = RTR0MemObjAddress(hMemObj); if (pvBlock) { /* * Calc the start of the fence and the user block * and then change the page protection of the fence. */ #ifdef RTR0MEM_EF_IN_FRONT void *pvEFence = pvBlock; void *pv = (char *)pvEFence + RTR0MEM_EF_SIZE; # ifdef RTR0MEM_EF_NOMAN_FILLER memset((char *)pv + cbUnaligned, RTR0MEM_EF_NOMAN_FILLER, cbBlock - RTR0MEM_EF_SIZE - cbUnaligned); # endif #else void *pvEFence = (char *)pvBlock + (cbBlock - RTR0MEM_EF_SIZE); void *pv = (char *)pvEFence - cbAligned; # ifdef RTR0MEM_EF_NOMAN_FILLER memset(pvBlock, RTR0MEM_EF_NOMAN_FILLER, cbBlock - RTR0MEM_EF_SIZE - cbAligned); memset((char *)pv + cbUnaligned, RTR0MEM_EF_NOMAN_FILLER, cbAligned - cbUnaligned); # endif #endif #ifdef RTR0MEM_EF_FENCE_FILLER memset(pvEFence, RTR0MEM_EF_FENCE_FILLER, RTR0MEM_EF_SIZE); #endif rc = RTR0MemObjProtect(hMemObj, (uint8_t *)pvEFence - (uint8_t *)pvBlock, RTR0MEM_EF_SIZE, RTMEM_PROT_NONE); if (!rc) { rtR0MemBlockInsert(pBlock, pv, hMemObj); if (enmType == RTMEMTYPE_RTMEMALLOCZ) memset(pv, 0, cbUnaligned); #ifdef RTR0MEM_EF_FILLER else memset(pv, RTR0MEM_EF_FILLER, cbUnaligned); #endif rtR0MemLog(pszOp, "returns %p (pvBlock=%p cbBlock=%#x pvEFence=%p cbUnaligned=%#x)\n", pv, pvBlock, cbBlock, pvEFence, cbUnaligned); return pv; } rtR0MemComplain(pszOp, "RTMemProtect failed, pvEFence=%p size %d, rc=%d\n", pvEFence, RTR0MEM_EF_SIZE, rc); RTR0MemObjFree(hMemObj, true /*fFreeMappings*/); } else { rtR0MemComplain(pszOp, "Failed to allocated %zu (%zu) bytes (rc=%Rrc).\n", cbBlock, cbUnaligned, rc); if (RT_SUCCESS(rc)) RTR0MemObjFree(hMemObj, true /*fFreeMappings*/); } rtR0MemBlockFree(pBlock); return NULL; } /** * Internal free. */ static void rtR0MemFree(const char *pszOp, RTMEMTYPE enmType, void *pv, void *pvCaller, RT_SRC_POS_DECL) { NOREF(enmType); RT_SRC_POS_NOREF(); /* * Simple case. */ if (!pv) return; /* * Check watch points. */ for (unsigned i = 0; i < RT_ELEMENTS(gapvRTMemFreeWatch); i++) if (gapvRTMemFreeWatch[i] == pv) RTAssertDoPanic(); /* * Find the block. */ PRTR0MEMEFBLOCK pBlock = rtR0MemBlockRemove(pv); if (pBlock) { if (gfRTMemFreeLog) RTLogPrintf("RTMem %s: pv=%p pvCaller=%p cbUnaligned=%#x\n", pszOp, pv, pvCaller, pBlock->cbUnaligned); #ifdef RTR0MEM_EF_NOMAN_FILLER /* * Check whether the no man's land is untouched. */ # ifdef RTR0MEM_EF_IN_FRONT void *pvWrong = ASMMemFirstMismatchingU8((char *)pv + pBlock->cbUnaligned, RT_ALIGN_Z(pBlock->cbAligned, PAGE_SIZE) - pBlock->cbUnaligned, RTR0MEM_EF_NOMAN_FILLER); # else /* Alignment must match allocation alignment in rtMemAlloc(). */ void *pvWrong = ASMMemFirstMismatchingU8((char *)pv + pBlock->cbUnaligned, pBlock->cbAligned - pBlock->cbUnaligned, RTR0MEM_EF_NOMAN_FILLER); if (pvWrong) RTAssertDoPanic(); pvWrong = ASMMemFirstMismatchingU8((void *)((uintptr_t)pv & ~(uintptr_t)PAGE_OFFSET_MASK), RT_ALIGN_Z(pBlock->cbAligned, PAGE_SIZE) - pBlock->cbAligned, RTR0MEM_EF_NOMAN_FILLER); # endif if (pvWrong) RTAssertDoPanic(); #endif #ifdef RTR0MEM_EF_FREE_FILL /* * Fill the user part of the block. */ memset(pv, RTR0MEM_EF_FREE_FILL, pBlock->cbUnaligned); #endif #if defined(RTR0MEM_EF_FREE_DELAYED) && RTR0MEM_EF_FREE_DELAYED > 0 /* * We're doing delayed freeing. * That means we'll expand the E-fence to cover the entire block. */ int rc = RTR0MemObjProtect(pBlock->hMemObj, # ifdef RTR0MEM_EF_IN_FRONT RTR0MEM_EF_SIZE, # else 0 /*offSub*/, # endif RT_ALIGN_Z(pBlock->cbAligned, PAGE_SIZE), RTMEM_PROT_NONE); if (RT_SUCCESS(rc)) { /* * Insert it into the free list and process pending frees. */ rtR0MemBlockDelayInsert(pBlock); while ((pBlock = rtR0MemBlockDelayRemove()) != NULL) rtR0MemFreeBlock(pBlock, pszOp); } else rtR0MemComplain(pszOp, "Failed to expand the efence of pv=%p cb=%d, rc=%d.\n", pv, pBlock, rc); #else /* !RTR0MEM_EF_FREE_DELAYED */ rtR0MemFreeBlock(pBlock, pszOp); #endif /* !RTR0MEM_EF_FREE_DELAYED */ } else rtR0MemComplain(pszOp, "pv=%p not found! Incorrect free!\n", pv); } /** * Internal realloc. */ static void *rtR0MemRealloc(const char *pszOp, RTMEMTYPE enmType, void *pvOld, size_t cbNew, const char *pszTag, void *pvCaller, RT_SRC_POS_DECL) { /* * Allocate new and copy. */ if (!pvOld) return rtR0MemAlloc(pszOp, enmType, cbNew, cbNew, pszTag, pvCaller, RT_SRC_POS_ARGS); if (!cbNew) { rtR0MemFree(pszOp, RTMEMTYPE_RTMEMREALLOC, pvOld, pvCaller, RT_SRC_POS_ARGS); return NULL; } /* * Get the block, allocate the new, copy the data, free the old one. */ PRTR0MEMEFBLOCK pBlock = rtR0MemBlockGet(pvOld); if (pBlock) { void *pvRet = rtR0MemAlloc(pszOp, enmType, cbNew, cbNew, pszTag, pvCaller, RT_SRC_POS_ARGS); if (pvRet) { memcpy(pvRet, pvOld, RT_MIN(cbNew, pBlock->cbUnaligned)); rtR0MemFree(pszOp, RTMEMTYPE_RTMEMREALLOC, pvOld, pvCaller, RT_SRC_POS_ARGS); } return pvRet; } rtR0MemComplain(pszOp, "pvOld=%p was not found!\n", pvOld); return NULL; } RTDECL(void *) RTMemEfTmpAlloc(size_t cb, const char *pszTag, RT_SRC_POS_DECL) RT_NO_THROW_DEF { return rtR0MemAlloc("TmpAlloc", RTMEMTYPE_RTMEMALLOC, cb, cb, pszTag, ASMReturnAddress(), RT_SRC_POS_ARGS); } RTDECL(void *) RTMemEfTmpAllocZ(size_t cb, const char *pszTag, RT_SRC_POS_DECL) RT_NO_THROW_DEF { return rtR0MemAlloc("TmpAlloc", RTMEMTYPE_RTMEMALLOCZ, cb, cb, pszTag, ASMReturnAddress(), RT_SRC_POS_ARGS); } RTDECL(void) RTMemEfTmpFree(void *pv, RT_SRC_POS_DECL) RT_NO_THROW_DEF { if (pv) rtR0MemFree("Free", RTMEMTYPE_RTMEMFREE, pv, ASMReturnAddress(), RT_SRC_POS_ARGS); } RTDECL(void *) RTMemEfAlloc(size_t cb, const char *pszTag, RT_SRC_POS_DECL) RT_NO_THROW_DEF { return rtR0MemAlloc("Alloc", RTMEMTYPE_RTMEMALLOC, cb, cb, pszTag, ASMReturnAddress(), RT_SRC_POS_ARGS); } RTDECL(void *) RTMemEfAllocZ(size_t cb, const char *pszTag, RT_SRC_POS_DECL) RT_NO_THROW_DEF { return rtR0MemAlloc("AllocZ", RTMEMTYPE_RTMEMALLOCZ, cb, cb, pszTag, ASMReturnAddress(), RT_SRC_POS_ARGS); } RTDECL(void *) RTMemEfAllocVar(size_t cbUnaligned, const char *pszTag, RT_SRC_POS_DECL) RT_NO_THROW_DEF { size_t cbAligned; if (cbUnaligned >= 16) cbAligned = RT_ALIGN_Z(cbUnaligned, 16); else cbAligned = RT_ALIGN_Z(cbUnaligned, sizeof(void *)); return rtR0MemAlloc("Alloc", RTMEMTYPE_RTMEMALLOC, cbUnaligned, cbAligned, pszTag, ASMReturnAddress(), RT_SRC_POS_ARGS); } RTDECL(void *) RTMemEfAllocZVar(size_t cbUnaligned, const char *pszTag, RT_SRC_POS_DECL) RT_NO_THROW_DEF { size_t cbAligned; if (cbUnaligned >= 16) cbAligned = RT_ALIGN_Z(cbUnaligned, 16); else cbAligned = RT_ALIGN_Z(cbUnaligned, sizeof(void *)); return rtR0MemAlloc("AllocZ", RTMEMTYPE_RTMEMALLOCZ, cbUnaligned, cbAligned, pszTag, ASMReturnAddress(), RT_SRC_POS_ARGS); } RTDECL(void *) RTMemEfRealloc(void *pvOld, size_t cbNew, const char *pszTag, RT_SRC_POS_DECL) RT_NO_THROW_DEF { return rtR0MemRealloc("Realloc", RTMEMTYPE_RTMEMREALLOC, pvOld, cbNew, pszTag, ASMReturnAddress(), RT_SRC_POS_ARGS); } RTDECL(void) RTMemEfFree(void *pv, RT_SRC_POS_DECL) RT_NO_THROW_DEF { if (pv) rtR0MemFree("Free", RTMEMTYPE_RTMEMFREE, pv, ASMReturnAddress(), RT_SRC_POS_ARGS); } RTDECL(void *) RTMemEfDup(const void *pvSrc, size_t cb, const char *pszTag, RT_SRC_POS_DECL) RT_NO_THROW_DEF { void *pvDst = RTMemEfAlloc(cb, pszTag, RT_SRC_POS_ARGS); if (pvDst) memcpy(pvDst, pvSrc, cb); return pvDst; } RTDECL(void *) RTMemEfDupEx(const void *pvSrc, size_t cbSrc, size_t cbExtra, const char *pszTag, RT_SRC_POS_DECL) RT_NO_THROW_DEF { void *pvDst = RTMemEfAlloc(cbSrc + cbExtra, pszTag, RT_SRC_POS_ARGS); if (pvDst) { memcpy(pvDst, pvSrc, cbSrc); memset((uint8_t *)pvDst + cbSrc, 0, cbExtra); } return pvDst; } /* * * The NP (no position) versions. * */ RTDECL(void *) RTMemEfTmpAllocNP(size_t cb, const char *pszTag) RT_NO_THROW_DEF { return rtR0MemAlloc("TmpAlloc", RTMEMTYPE_RTMEMALLOC, cb, cb, pszTag, ASMReturnAddress(), NULL, 0, NULL); } RTDECL(void *) RTMemEfTmpAllocZNP(size_t cb, const char *pszTag) RT_NO_THROW_DEF { return rtR0MemAlloc("TmpAllocZ", RTMEMTYPE_RTMEMALLOCZ, cb, cb, pszTag, ASMReturnAddress(), NULL, 0, NULL); } RTDECL(void) RTMemEfTmpFreeNP(void *pv) RT_NO_THROW_DEF { if (pv) rtR0MemFree("Free", RTMEMTYPE_RTMEMFREE, pv, ASMReturnAddress(), NULL, 0, NULL); } RTDECL(void *) RTMemEfAllocNP(size_t cb, const char *pszTag) RT_NO_THROW_DEF { return rtR0MemAlloc("Alloc", RTMEMTYPE_RTMEMALLOC, cb, cb, pszTag, ASMReturnAddress(), NULL, 0, NULL); } RTDECL(void *) RTMemEfAllocZNP(size_t cb, const char *pszTag) RT_NO_THROW_DEF { return rtR0MemAlloc("AllocZ", RTMEMTYPE_RTMEMALLOCZ, cb, cb, pszTag, ASMReturnAddress(), NULL, 0, NULL); } RTDECL(void *) RTMemEfAllocVarNP(size_t cbUnaligned, const char *pszTag) RT_NO_THROW_DEF { size_t cbAligned; if (cbUnaligned >= 16) cbAligned = RT_ALIGN_Z(cbUnaligned, 16); else cbAligned = RT_ALIGN_Z(cbUnaligned, sizeof(void *)); return rtR0MemAlloc("Alloc", RTMEMTYPE_RTMEMALLOC, cbUnaligned, cbAligned, pszTag, ASMReturnAddress(), NULL, 0, NULL); } RTDECL(void *) RTMemEfAllocZVarNP(size_t cbUnaligned, const char *pszTag) RT_NO_THROW_DEF { size_t cbAligned; if (cbUnaligned >= 16) cbAligned = RT_ALIGN_Z(cbUnaligned, 16); else cbAligned = RT_ALIGN_Z(cbUnaligned, sizeof(void *)); return rtR0MemAlloc("AllocZ", RTMEMTYPE_RTMEMALLOCZ, cbUnaligned, cbAligned, pszTag, ASMReturnAddress(), NULL, 0, NULL); } RTDECL(void *) RTMemEfReallocNP(void *pvOld, size_t cbNew, const char *pszTag) RT_NO_THROW_DEF { return rtR0MemRealloc("Realloc", RTMEMTYPE_RTMEMREALLOC, pvOld, cbNew, pszTag, ASMReturnAddress(), NULL, 0, NULL); } RTDECL(void) RTMemEfFreeNP(void *pv) RT_NO_THROW_DEF { if (pv) rtR0MemFree("Free", RTMEMTYPE_RTMEMFREE, pv, ASMReturnAddress(), NULL, 0, NULL); } RTDECL(void *) RTMemEfDupNP(const void *pvSrc, size_t cb, const char *pszTag) RT_NO_THROW_DEF { void *pvDst = RTMemEfAlloc(cb, pszTag, NULL, 0, NULL); if (pvDst) memcpy(pvDst, pvSrc, cb); return pvDst; } RTDECL(void *) RTMemEfDupExNP(const void *pvSrc, size_t cbSrc, size_t cbExtra, const char *pszTag) RT_NO_THROW_DEF { void *pvDst = RTMemEfAlloc(cbSrc + cbExtra, pszTag, NULL, 0, NULL); if (pvDst) { memcpy(pvDst, pvSrc, cbSrc); memset((uint8_t *)pvDst + cbSrc, 0, cbExtra); } return pvDst; }