/* $Id: IOBufMgmt.cpp $ */ /** @file * VBox storage devices: I/O buffer management API. */ /* * Copyright (C) 2016-2019 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. */ #define LOG_GROUP LOG_GROUP_IOBUFMGMT #include #include #include #include #include #include #include #include #include #include /** Set to verify the allocations for distinct memory areas. */ //#define IOBUFMGR_VERIFY_ALLOCATIONS 1 /** The minimum bin size to create - power of two!. */ #define IOBUFMGR_BIN_SIZE_MIN _4K /** The maximum bin size to create - power of two!. */ #define IOBUFMGR_BIN_SIZE_MAX _1M /** Pointer to the internal I/O buffer manager data. */ typedef struct IOBUFMGRINT *PIOBUFMGRINT; /** * Internal I/O buffer descriptor data. */ typedef struct IOBUFDESCINT { /** Data segments. */ RTSGSEG aSegs[10]; /** Data segments used for the current allocation. */ unsigned cSegsUsed; /** Pointer to I/O buffer manager. */ PIOBUFMGRINT pIoBufMgr; } IOBUFDESCINT; /** * A */ typedef struct IOBUFMGRBIN { /** Index of the next free entry. */ unsigned iFree; /** Pointer to the array of free objects for this bin. */ void **papvFree; } IOBUFMGRBIN; typedef IOBUFMGRBIN *PIOBUFMGRBIN; /** * Internal I/O buffer manager data. */ typedef struct IOBUFMGRINT { /** Critical section protecting the allocation path. */ RTCRITSECT CritSectAlloc; /** Flags the manager was created with. */ uint32_t fFlags; /** Maximum size of I/O memory to allocate. */ size_t cbMax; /** Amount of free memory. */ size_t cbFree; /** The order of smallest bin. */ uint32_t u32OrderMin; /** The order of largest bin. */ uint32_t u32OrderMax; /** Pointer to the base memory of the allocation. */ void *pvMem; /** Number of bins for free objects. */ uint32_t cBins; /** Flag whether allocation is on hold waiting for everything to be free * to be able to defragment the memory. */ bool fAllocSuspended; /** Array of bins. */ PIOBUFMGRBIN paBins; #ifdef IOBUFMGR_VERIFY_ALLOCATIONS /** Pointer to the object state (allocated/free) bitmap. */ void *pbmObjState; #endif /** Array of pointer entries for the various bins - variable in size. */ void *apvObj[1]; } IOBUFMGRINT; /* Must be included after IOBUFDESCINT was defined. */ #define IOBUFDESCINT_DECLARED #include "IOBufMgmt.h" /** * Gets the number of bins required between the given minimum and maximum size * to have a bin for every power of two size inbetween. * * @returns The number of bins required. * @param cbMin The size of the smallest bin. * @param cbMax The size of the largest bin. */ DECLINLINE(uint32_t) iobufMgrGetBinCount(uint32_t cbMin, uint32_t cbMax) { uint32_t u32Max = ASMBitLastSetU32(cbMax); uint32_t u32Min = ASMBitLastSetU32(cbMin); Assert(cbMax >= cbMin && cbMax != 0 && cbMin != 0); return u32Max - u32Min + 1; } /** * Returns the number of entries required in the object array to cover all bins. * * @returns Number of entries required in the object array. * @param cbMem Size of the memory buffer. * @param cBins Number of bins available. * @param cbMinBin Minimum object size. */ DECLINLINE(uint32_t) iobufMgrGetObjCount(size_t cbMem, unsigned cBins, size_t cbMinBin) { size_t cObjs = 0; size_t cbBin = cbMinBin; while (cBins-- > 0) { cObjs += cbMem / cbBin; cbBin <<= 1; /* The size doubles for every bin. */ } Assert((uint32_t)cObjs == cObjs); return (uint32_t)cObjs; } DECLINLINE(void) iobufMgrBinObjAdd(PIOBUFMGRBIN pBin, void *pvObj) { LogFlowFunc(("pBin=%#p{.iFree=%u} pvObj=%#p\n", pBin, pBin->iFree, pvObj)); AssertPtr(pvObj); pBin->papvFree[pBin->iFree] = pvObj; pBin->iFree++; LogFlowFunc(("return pBin=%#p{.iFree=%u}\n", pBin, pBin->iFree)); } DECLINLINE(void *) iobufMgrBinObjRemove(PIOBUFMGRBIN pBin) { LogFlowFunc(("pBin=%#p{.iFree=%u}\n", pBin, pBin->iFree)); Assert(pBin->iFree > 0); pBin->iFree--; void *pvObj = pBin->papvFree[pBin->iFree]; AssertPtr(pvObj); LogFlowFunc(("returns pvObj=%#p pBin=%#p{.iFree=%u}\n", pvObj, pBin, pBin->iFree)); return pvObj; } /** * Resets the bins to factory default (memory resigin in the largest bin). * * @returns nothing. * @param pThis The I/O buffer manager instance. */ static void iobufMgrResetBins(PIOBUFMGRINT pThis) { /* Init the bins. */ size_t cbMax = pThis->cbMax; size_t iObj = 0; uint32_t cbBin = IOBUFMGR_BIN_SIZE_MIN; for (unsigned i = 0; i < pThis->cBins; i++) { PIOBUFMGRBIN pBin = &pThis->paBins[i]; pBin->iFree = 0; pBin->papvFree = &pThis->apvObj[iObj]; iObj += cbMax / cbBin; /* Init the biggest possible bin with the free objects. */ if ( (cbBin << 1) > cbMax || i == pThis->cBins - 1) { uint8_t *pbMem = (uint8_t *)pThis->pvMem; while (cbMax) { iobufMgrBinObjAdd(pBin, pbMem); cbMax -= cbBin; pbMem += cbBin; if (cbMax < cbBin) /** @todo Populate smaller bins and don't waste memory. */ break; } /* Limit the number of available bins. */ pThis->cBins = i + 1; break; } cbBin <<= 1; } } /** * Allocate one segment from the manager. * * @returns Number of bytes allocated, 0 if there is no free memory. * @param pThis The I/O buffer manager instance. * @param pSeg The segment to fill in on success. * @param cb Maximum number of bytes to allocate. */ static size_t iobufMgrAllocSegment(PIOBUFMGRINT pThis, PRTSGSEG pSeg, size_t cb) { size_t cbAlloc = 0; /* Round to the next power of two and get the bin to try first. */ uint32_t u32Order = ASMBitLastSetU32((uint32_t)cb) - 1; if (cb & (RT_BIT_32(u32Order) - 1)) u32Order++; u32Order = RT_CLAMP(u32Order, pThis->u32OrderMin, pThis->u32OrderMax); unsigned iBin = u32Order - pThis->u32OrderMin; /* * Check whether the bin can satisfy the request. If not try the next bigger * bin and so on. If there is nothing to find try the smaller bins. */ Assert(iBin < pThis->cBins); PIOBUFMGRBIN pBin = &pThis->paBins[iBin]; /* Reset the bins if there is nothing in the current one but all the memory is marked as free. */ if ( pThis->cbFree == pThis->cbMax && pBin->iFree == 0) iobufMgrResetBins(pThis); if (pBin->iFree == 0) { unsigned iBinCur = iBin; PIOBUFMGRBIN pBinCur = &pThis->paBins[iBinCur]; while (iBinCur < pThis->cBins) { if (pBinCur->iFree != 0) { uint8_t *pbMem = (uint8_t *)iobufMgrBinObjRemove(pBinCur); AssertPtr(pbMem); /* Always split into half. */ while (iBinCur > iBin) { iBinCur--; pBinCur = &pThis->paBins[iBinCur]; iobufMgrBinObjAdd(pBinCur, pbMem + (size_t)RT_BIT(iBinCur + pThis->u32OrderMin)); /* (RT_BIT causes weird MSC warning without cast) */ } /* For the last bin we will get two new memory blocks. */ iobufMgrBinObjAdd(pBinCur, pbMem); Assert(pBin == pBinCur); break; } pBinCur++; iBinCur++; } } /* * If we didn't find something in the higher bins try to accumulate as much as possible from the smaller bins. */ if ( pBin->iFree == 0 && iBin > 0) { #if 1 pThis->fAllocSuspended = true; #else do { iBin--; pBin = &pThis->paBins[iBin]; if (pBin->iFree != 0) { pBin->iFree--; pSeg->pvSeg = pBin->papvFree[pBin->iFree]; pSeg->cbSeg = (size_t)RT_BIT_32(iBin + pThis->u32OrderMin); AssertPtr(pSeg->pvSeg); cbAlloc = pSeg->cbSeg; break; } } while (iBin > 0); #endif } else if (pBin->iFree != 0) { pSeg->pvSeg = iobufMgrBinObjRemove(pBin); pSeg->cbSeg = (size_t)RT_BIT_32(u32Order); cbAlloc = pSeg->cbSeg; AssertPtr(pSeg->pvSeg); pThis->cbFree -= cbAlloc; #ifdef IOBUFMGR_VERIFY_ALLOCATIONS /* Mark the objects as allocated. */ uint32_t iBinStart = ((uintptr_t)pSeg->pvSeg - (uintptr_t)pThis->pvMem) / IOBUFMGR_BIN_SIZE_MIN; Assert( !(((uintptr_t)pSeg->pvSeg - (uintptr_t)pThis->pvMem) % IOBUFMGR_BIN_SIZE_MIN) && !(pSeg->cbSeg % IOBUFMGR_BIN_SIZE_MIN)); uint32_t iBinEnd = iBinStart + (pSeg->cbSeg / IOBUFMGR_BIN_SIZE_MIN); while (iBinStart < iBinEnd) { bool fState = ASMBitTestAndSet(pThis->pbmObjState, iBinStart); //LogFlowFunc(("iBinStart=%u fState=%RTbool -> true\n", iBinStart, fState)); AssertMsg(!fState, ("Trying to allocate an already allocated object\n")); iBinStart++; } #endif } return cbAlloc; } DECLHIDDEN(int) IOBUFMgrCreate(PIOBUFMGR phIoBufMgr, size_t cbMax, uint32_t fFlags) { int rc = VINF_SUCCESS; AssertPtrReturn(phIoBufMgr, VERR_INVALID_POINTER); AssertReturn(cbMax, VERR_NOT_IMPLEMENTED); /* Allocate the basic structure in one go. */ unsigned cBins = iobufMgrGetBinCount(IOBUFMGR_BIN_SIZE_MIN, IOBUFMGR_BIN_SIZE_MAX); uint32_t cObjs = iobufMgrGetObjCount(cbMax, cBins, IOBUFMGR_BIN_SIZE_MIN); PIOBUFMGRINT pThis = (PIOBUFMGRINT)RTMemAllocZ(RT_UOFFSETOF_DYN(IOBUFMGRINT, apvObj[cObjs]) + cBins * sizeof(IOBUFMGRBIN)); if (RT_LIKELY(pThis)) { pThis->fFlags = fFlags; pThis->cbMax = cbMax; pThis->cbFree = cbMax; pThis->cBins = cBins; pThis->fAllocSuspended = false; pThis->u32OrderMin = ASMBitLastSetU32(IOBUFMGR_BIN_SIZE_MIN) - 1; pThis->u32OrderMax = ASMBitLastSetU32(IOBUFMGR_BIN_SIZE_MAX) - 1; pThis->paBins = (PIOBUFMGRBIN)((uint8_t *)pThis + RT_UOFFSETOF_DYN(IOBUFMGRINT, apvObj[cObjs])); #ifdef IOBUFMGR_VERIFY_ALLOCATIONS pThis->pbmObjState = RTMemAllocZ((cbMax / IOBUFMGR_BIN_SIZE_MIN / 8) + 1); if (!pThis->pbmObjState) rc = VERR_NO_MEMORY; #endif if (RT_SUCCESS(rc)) rc = RTCritSectInit(&pThis->CritSectAlloc); if (RT_SUCCESS(rc)) { if (pThis->fFlags & IOBUFMGR_F_REQUIRE_NOT_PAGABLE) rc = RTMemSaferAllocZEx(&pThis->pvMem, RT_ALIGN_Z(pThis->cbMax, _4K), RTMEMSAFER_F_REQUIRE_NOT_PAGABLE); else pThis->pvMem = RTMemPageAllocZ(RT_ALIGN_Z(pThis->cbMax, _4K)); if ( RT_LIKELY(pThis->pvMem) && RT_SUCCESS(rc)) { iobufMgrResetBins(pThis); *phIoBufMgr = pThis; return VINF_SUCCESS; } else rc = VERR_NO_MEMORY; RTCritSectDelete(&pThis->CritSectAlloc); } RTMemFree(pThis); } else rc = VERR_NO_MEMORY; return rc; } DECLHIDDEN(int) IOBUFMgrDestroy(IOBUFMGR hIoBufMgr) { PIOBUFMGRINT pThis = hIoBufMgr; AssertPtrReturn(pThis, VERR_INVALID_HANDLE); int rc = RTCritSectEnter(&pThis->CritSectAlloc); if (RT_SUCCESS(rc)) { if (pThis->cbFree == pThis->cbMax) { if (pThis->fFlags & IOBUFMGR_F_REQUIRE_NOT_PAGABLE) RTMemSaferFree(pThis->pvMem, RT_ALIGN_Z(pThis->cbMax, _4K)); else RTMemPageFree(pThis->pvMem, RT_ALIGN_Z(pThis->cbMax, _4K)); #ifdef IOBUFMGR_VERIFY_ALLOCATIONS AssertPtr(pThis->pbmObjState); RTMemFree(pThis->pbmObjState); pThis->pbmObjState = NULL; #endif RTCritSectLeave(&pThis->CritSectAlloc); RTCritSectDelete(&pThis->CritSectAlloc); RTMemFree(pThis); } else { rc = VERR_INVALID_STATE; RTCritSectLeave(&pThis->CritSectAlloc); } } return rc; } DECLHIDDEN(int) IOBUFMgrAllocBuf(IOBUFMGR hIoBufMgr, PIOBUFDESC pIoBufDesc, size_t cbIoBuf, size_t *pcbIoBufAllocated) { PIOBUFMGRINT pThis = hIoBufMgr; LogFlowFunc(("pThis=%#p pIoBufDesc=%#p cbIoBuf=%zu pcbIoBufAllocated=%#p\n", pThis, pIoBufDesc, cbIoBuf, pcbIoBufAllocated)); AssertPtrReturn(pThis, VERR_INVALID_HANDLE); AssertReturn(cbIoBuf > 0, VERR_INVALID_PARAMETER); if ( !pThis->cbFree || pThis->fAllocSuspended) return VERR_NO_MEMORY; int rc = RTCritSectEnter(&pThis->CritSectAlloc); if (RT_SUCCESS(rc)) { unsigned iSeg = 0; size_t cbLeft = cbIoBuf; size_t cbIoBufAlloc = 0; PRTSGSEG pSeg = &pIoBufDesc->Int.aSegs[0]; while ( iSeg < RT_ELEMENTS(pIoBufDesc->Int.aSegs) && cbLeft) { size_t cbAlloc = iobufMgrAllocSegment(pThis, pSeg, cbLeft); if (!cbAlloc) break; iSeg++; pSeg++; cbLeft -= RT_MIN(cbAlloc, cbLeft); cbIoBufAlloc += cbAlloc; } if (iSeg) RTSgBufInit(&pIoBufDesc->SgBuf, &pIoBufDesc->Int.aSegs[0], iSeg); else rc = VERR_NO_MEMORY; pIoBufDesc->Int.cSegsUsed = iSeg; pIoBufDesc->Int.pIoBufMgr = pThis; *pcbIoBufAllocated = cbIoBufAlloc; Assert( (RT_SUCCESS(rc) && *pcbIoBufAllocated > 0) || RT_FAILURE(rc)); RTCritSectLeave(&pThis->CritSectAlloc); } return rc; } DECLHIDDEN(void) IOBUFMgrFreeBuf(PIOBUFDESC pIoBufDesc) { PIOBUFMGRINT pThis = pIoBufDesc->Int.pIoBufMgr; LogFlowFunc(("pIoBufDesc=%#p{.cSegsUsed=%u}\n", pIoBufDesc, pIoBufDesc->Int.cSegsUsed)); AssertPtr(pThis); int rc = RTCritSectEnter(&pThis->CritSectAlloc); AssertRC(rc); if (RT_SUCCESS(rc)) { for (unsigned i = 0; i < pIoBufDesc->Int.cSegsUsed; i++) { PRTSGSEG pSeg = &pIoBufDesc->Int.aSegs[i]; uint32_t u32Order = ASMBitLastSetU32((uint32_t)pSeg->cbSeg) - 1; unsigned iBin = u32Order - pThis->u32OrderMin; Assert(iBin < pThis->cBins); PIOBUFMGRBIN pBin = &pThis->paBins[iBin]; iobufMgrBinObjAdd(pBin, pSeg->pvSeg); pThis->cbFree += pSeg->cbSeg; #ifdef IOBUFMGR_VERIFY_ALLOCATIONS /* Mark the objects as free. */ uint32_t iBinStart = ((uintptr_t)pSeg->pvSeg - (uintptr_t)pThis->pvMem) / IOBUFMGR_BIN_SIZE_MIN; Assert( !(((uintptr_t)pSeg->pvSeg - (uintptr_t)pThis->pvMem) % IOBUFMGR_BIN_SIZE_MIN) && !(pSeg->cbSeg % IOBUFMGR_BIN_SIZE_MIN)); uint32_t iBinEnd = iBinStart + (pSeg->cbSeg / IOBUFMGR_BIN_SIZE_MIN); while (iBinStart < iBinEnd) { bool fState = ASMBitTestAndClear(pThis->pbmObjState, iBinStart); //LogFlowFunc(("iBinStart=%u fState=%RTbool -> false\n", iBinStart, fState)); AssertMsg(fState, ("Trying to free a non allocated object\n")); iBinStart++; } /* Poison the state. */ pSeg->cbSeg = ~0; pSeg->pvSeg = (void *)~(uintptr_t)0; #endif } if ( pThis->cbFree == pThis->cbMax && pThis->fAllocSuspended) { iobufMgrResetBins(pThis); pThis->fAllocSuspended = false; } RTCritSectLeave(&pThis->CritSectAlloc); } pIoBufDesc->Int.cSegsUsed = 0; #ifdef IOBUFMGR_VERIFY_ALLOCATIONS memset(&pIoBufDesc->SgBuf, 0xff, sizeof(pIoBufDesc->SgBuf)); #endif }