/* $Id: VCICache.cpp 44233 2013-01-04 20:39:56Z vboxsync $ */ /** @file * VCICacheCore - VirtualBox Cache Image, Core Code. */ /* * Copyright (C) 2006-2010 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. */ /******************************************************************************* * Header Files * *******************************************************************************/ #define LOG_GROUP LOG_GROUP_VD_RAW /** @todo logging group */ #include #include #include #include #include #include #include /******************************************************************************* * On disk data structures * *******************************************************************************/ /** @note All structures which are written to the disk are written in camel case * and packed. */ /** Block size used internally, because we cache sectors the smallest unit we * have to care about is 512 bytes. */ #define VCI_BLOCK_SIZE 512 /** Convert block number/size to byte offset/size. */ #define VCI_BLOCK2BYTE(u) ((uint64_t)(u) << 9) /** Convert byte offset/size to block number/size. */ #define VCI_BYTE2BLOCK(u) ((u) >> 9) /** * The VCI header - at the beginning of the file. * * All entries a stored in little endian order. */ #pragma pack(1) typedef struct VciHdr { /** The signature to identify a cache image. */ uint32_t u32Signature; /** Version of the layout of metadata in the cache. */ uint32_t u32Version; /** Maximum size of the cache file in blocks. * This includes all metadata. */ uint64_t cBlocksCache; /** Flag indicating whether the cache was closed cleanly. */ uint8_t fUncleanShutdown; /** Cache type. */ uint32_t u32CacheType; /** Offset of the B+-Tree root in the image in blocks. */ uint64_t offTreeRoot; /** Offset of the block allocation bitmap in blocks. */ uint64_t offBlkMap; /** Size of the block allocation bitmap in blocks. */ uint32_t cBlkMap; /** UUID of the image. */ RTUUID uuidImage; /** Modification UUID for the cache. */ RTUUID uuidModification; /** Reserved for future use. */ uint8_t abReserved[951]; } VciHdr, *PVciHdr; #pragma pack() AssertCompileSize(VciHdr, 2 * VCI_BLOCK_SIZE); /** VCI signature to identify a valid image. */ #define VCI_HDR_SIGNATURE UINT32_C(0x00494356) /* \0ICV */ /** Current version we support. */ #define VCI_HDR_VERSION UINT32_C(0x00000001) /** Value for an unclean cache shutdown. */ #define VCI_HDR_UNCLEAN_SHUTDOWN UINT8_C(0x01) /** Value for a clean cache shutdown. */ #define VCI_HDR_CLEAN_SHUTDOWN UINT8_C(0x00) /** Cache type: Dynamic image growing to the maximum value. */ #define VCI_HDR_CACHE_TYPE_DYNAMIC UINT32_C(0x00000001) /** Cache type: Fixed image, space is preallocated. */ #define VCI_HDR_CACHE_TYPE_FIXED UINT32_C(0x00000002) /** * On disk representation of an extent describing a range of cached data. * * All entries a stored in little endian order. */ #pragma pack(1) typedef struct VciCacheExtent { /** Block address of the previous extent in the LRU list. */ uint64_t u64ExtentPrev; /** Block address of the next extent in the LRU list. */ uint64_t u64ExtentNext; /** Flags (for compression, encryption etc.) - currently unused and should be always 0. */ uint8_t u8Flags; /** Reserved */ uint8_t u8Reserved; /** First block of cached data the extent represents. */ uint64_t u64BlockOffset; /** Number of blocks the extent represents. */ uint32_t u32Blocks; /** First block in the image where the data is stored. */ uint64_t u64BlockAddr; } VciCacheExtent, *PVciCacheExtent; #pragma pack() AssertCompileSize(VciCacheExtent, 38); /** * On disk representation of an internal node. * * All entries a stored in little endian order. */ #pragma pack(1) typedef struct VciTreeNodeInternal { /** First block of cached data the internal node represents. */ uint64_t u64BlockOffset; /** Number of blocks the internal node represents. */ uint32_t u32Blocks; /** Block address in the image where the next node in the tree is stored. */ uint64_t u64ChildAddr; } VciTreeNodeInternal, *PVciTreeNodeInternal; #pragma pack() AssertCompileSize(VciTreeNodeInternal, 20); /** * On-disk representation of a node in the B+-Tree. * * All entries a stored in little endian order. */ #pragma pack(1) typedef struct VciTreeNode { /** Type of the node (root, internal, leaf). */ uint8_t u8Type; /** Data in the node. */ uint8_t au8Data[4095]; } VciTreeNode, *PVciTreeNode; #pragma pack() AssertCompileSize(VciTreeNode, 8 * VCI_BLOCK_SIZE); /** Node type: Internal node containing links to other nodes (VciTreeNodeInternal). */ #define VCI_TREE_NODE_TYPE_INTERNAL UINT8_C(0x01) /** Node type: Leaf of the tree (VciCacheExtent). */ #define VCI_TREE_NODE_TYPE_LEAF UINT8_C(0x02) /** Number of cache extents described by one node. */ #define VCI_TREE_EXTENTS_PER_NODE ((sizeof(VciTreeNode)-1) / sizeof(VciCacheExtent)) /** Number of internal nodes managed by one tree node. */ #define VCI_TREE_INTERNAL_NODES_PER_NODE ((sizeof(VciTreeNode)-1) / sizeof(VciTreeNodeInternal)) /** * VCI block bitmap header. * * All entries a stored in little endian order. */ #pragma pack(1) typedef struct VciBlkMap { /** Magic of the block bitmap. */ uint32_t u32Magic; /** Version of the block bitmap. */ uint32_t u32Version; /** Number of blocks this block map manages. */ uint64_t cBlocks; /** Number of free blocks. */ uint64_t cBlocksFree; /** Number of blocks allocated for metadata. */ uint64_t cBlocksAllocMeta; /** Number of blocks allocated for actual cached data. */ uint64_t cBlocksAllocData; /** Reserved for future use. */ uint8_t au8Reserved[472]; } VciBlkMap, *PVciBlkMap; #pragma pack() AssertCompileSize(VciBlkMap, VCI_BLOCK_SIZE); /** The magic which identifies a block map. */ #define VCI_BLKMAP_MAGIC UINT32_C(0x4b4c4256) /* KLBV */ /** Current version. */ #define VCI_BLKMAP_VERSION UINT32_C(0x00000001) /** Block bitmap entry */ typedef uint8_t VciBlkMapEnt; /******************************************************************************* * Constants And Macros, Structures and Typedefs * *******************************************************************************/ /** * Block range descriptor. */ typedef struct VCIBLKRANGEDESC { /** Previous entry in the list. */ struct VCIBLKRANGEDESC *pPrev; /** Next entry in the list. */ struct VCIBLKRANGEDESC *pNext; /** Start address of the range. */ uint64_t offAddrStart; /** Number of blocks in the range. */ uint64_t cBlocks; /** Flag whether the range is free or allocated. */ bool fFree; } VCIBLKRANGEDESC, *PVCIBLKRANGEDESC; /** * Block map for the cache image - in memory structure. */ typedef struct VCIBLKMAP { /** Number of blocks the map manages. */ uint64_t cBlocks; /** Number of blocks allocated for metadata. */ uint64_t cBlocksAllocMeta; /** Number of blocks allocated for actual cached data. */ uint64_t cBlocksAllocData; /** Number of free blocks. */ uint64_t cBlocksFree; /** Pointer to the head of the block range list. */ PVCIBLKRANGEDESC pRangesHead; /** Pointer to the tail of the block range list. */ PVCIBLKRANGEDESC pRangesTail; } VCIBLKMAP; /** Pointer to a block map. */ typedef VCIBLKMAP *PVCIBLKMAP; /** * B+-Tree node header. */ typedef struct VCITREENODE { /** Type of the node (VCI_TREE_NODE_TYPE_*). */ uint8_t u8Type; /** Block address where the node is stored. */ uint64_t u64BlockAddr; /** Pointer to the parent. */ struct VCITREENODE *pParent; } VCITREENODE, *PVCITREENODE; /** * B+-Tree node pointer. */ typedef struct VCITREENODEPTR { /** Flag whether the node is in memory or still on the disk. */ bool fInMemory; /** Type dependent data. */ union { /** Pointer to a in memory node. */ PVCITREENODE pNode; /** Start block address of the node. */ uint64_t offAddrBlockNode; } u; } VCITREENODEPTR, *PVCITREENODEPTR; /** * Internal node. */ typedef struct VCINODEINTERNAL { /** First block of cached data the internal node represents. */ uint64_t u64BlockOffset; /** Number of blocks the internal node represents. */ uint32_t u32Blocks; /** Pointer to the child node. */ VCITREENODEPTR PtrChild; } VCINODEINTERNAL, *PVCINODEINTERNAL; /** * A in memory internal B+-tree node. */ typedef struct VCITREENODEINT { /** Node core. */ VCITREENODE Core; /** Number of used nodes. */ unsigned cUsedNodes; /** Array of internal nodes. */ VCINODEINTERNAL aIntNodes[VCI_TREE_INTERNAL_NODES_PER_NODE]; } VCITREENODEINT, *PVCITREENODEINT; /** * A in memory cache extent. */ typedef struct VCICACHEEXTENT { /** First block of cached data the extent represents. */ uint64_t u64BlockOffset; /** Number of blocks the extent represents. */ uint32_t u32Blocks; /** First block in the image where the data is stored. */ uint64_t u64BlockAddr; } VCICACHEEXTENT, *PVCICACHEEXTENT; /** * A in memory leaf B+-tree node. */ typedef struct VCITREENODELEAF { /** Node core. */ VCITREENODE Core; /** Next leaf node in the list. */ struct VCITREENODELEAF *pNext; /** Number of used nodes. */ unsigned cUsedNodes; /** The extents in the node. */ VCICACHEEXTENT aExtents[VCI_TREE_EXTENTS_PER_NODE]; } VCITREENODELEAF, *PVCITREENODELEAF; /** * VCI image data structure. */ typedef struct VCICACHE { /** Image name. */ const char *pszFilename; /** Storage handle. */ PVDIOSTORAGE pStorage; /** Pointer to the per-disk VD interface list. */ PVDINTERFACE pVDIfsDisk; /** Pointer to the per-image VD interface list. */ PVDINTERFACE pVDIfsImage; /** Error interface. */ PVDINTERFACEERROR pIfError; /** I/O interface. */ PVDINTERFACEIOINT pIfIo; /** Open flags passed by VBoxHD layer. */ unsigned uOpenFlags; /** Image flags defined during creation or determined during open. */ unsigned uImageFlags; /** Total size of the image. */ uint64_t cbSize; /** Offset of the B+-Tree in the image in bytes. */ uint64_t offTreeRoot; /** Pointer to the root node of the B+-Tree. */ PVCITREENODE pRoot; /** Offset to the block allocation bitmap in bytes. */ uint64_t offBlksBitmap; /** Block map. */ PVCIBLKMAP pBlkMap; } VCICACHE, *PVCICACHE; /** No block free in bitmap error code. */ #define VERR_VCI_NO_BLOCKS_FREE (-65536) /** Flags for the block map allocator. */ #define VCIBLKMAP_ALLOC_DATA 0 #define VCIBLKMAP_ALLOC_META RT_BIT(0) #define VCIBLKMAP_ALLOC_MASK 0x1 /******************************************************************************* * Static Variables * *******************************************************************************/ /** NULL-terminated array of supported file extensions. */ static const char *const s_apszVciFileExtensions[] = { "vci", NULL }; /******************************************************************************* * Internal Functions * *******************************************************************************/ /** * Internal. Flush image data to disk. */ static int vciFlushImage(PVCICACHE pCache) { int rc = VINF_SUCCESS; if ( pCache->pStorage && !(pCache->uOpenFlags & VD_OPEN_FLAGS_READONLY)) { rc = vdIfIoIntFileFlushSync(pCache->pIfIo, pCache->pStorage); } return rc; } /** * Internal. Free all allocated space for representing an image except pCache, * and optionally delete the image from disk. */ static int vciFreeImage(PVCICACHE pCache, bool fDelete) { int rc = VINF_SUCCESS; /* Freeing a never allocated image (e.g. because the open failed) is * not signalled as an error. After all nothing bad happens. */ if (pCache) { if (pCache->pStorage) { /* No point updating the file that is deleted anyway. */ if (!fDelete) vciFlushImage(pCache); vdIfIoIntFileClose(pCache->pIfIo, pCache->pStorage); pCache->pStorage = NULL; } if (fDelete && pCache->pszFilename) vdIfIoIntFileDelete(pCache->pIfIo, pCache->pszFilename); } LogFlowFunc(("returns %Rrc\n", rc)); return rc; } /** * Creates a new block map which can manage the given number of blocks. * * The size of the bitmap is aligned to the VCI block size. * * @returns VBox status code. * @param cBlocks The number of blocks the bitmap can manage. * @param ppBlkMap Where to store the pointer to the block bitmap. * @param pcbBlkMap Where to store the size of the block bitmap in blocks * needed on the disk. */ static int vciBlkMapCreate(uint64_t cBlocks, PVCIBLKMAP *ppBlkMap, uint32_t *pcBlkMap) { int rc = VINF_SUCCESS; uint32_t cbBlkMap = RT_ALIGN_Z(cBlocks / sizeof(VciBlkMapEnt) / 8, VCI_BLOCK_SIZE); PVCIBLKMAP pBlkMap = (PVCIBLKMAP)RTMemAllocZ(sizeof(VCIBLKMAP)); PVCIBLKRANGEDESC pFree = (PVCIBLKRANGEDESC)RTMemAllocZ(sizeof(VCIBLKRANGEDESC)); LogFlowFunc(("cBlocks=%u ppBlkMap=%#p pcBlkMap=%#p\n", cBlocks, ppBlkMap, pcBlkMap)); if (pBlkMap && pFree) { pBlkMap->cBlocks = cBlocks; pBlkMap->cBlocksAllocMeta = 0; pBlkMap->cBlocksAllocData = 0; pBlkMap->cBlocksFree = cBlocks; pFree->pPrev = NULL; pFree->pNext = NULL; pFree->offAddrStart = 0; pFree->cBlocks = cBlocks; pFree->fFree = true; pBlkMap->pRangesHead = pFree; pBlkMap->pRangesTail = pFree; Assert(!((cbBlkMap + sizeof(VciBlkMap)) % VCI_BLOCK_SIZE)); *ppBlkMap = pBlkMap; *pcBlkMap = VCI_BYTE2BLOCK(cbBlkMap + sizeof(VciBlkMap)); } else { if (pBlkMap) RTMemFree(pBlkMap); if (pFree) RTMemFree(pFree); rc = VERR_NO_MEMORY; } LogFlowFunc(("returns rc=%Rrc cBlkMap=%u\n", rc, *pcBlkMap)); return rc; } /** * Frees a block map. * * @returns nothing. * @param pBlkMap The block bitmap to destroy. */ static void vciBlkMapDestroy(PVCIBLKMAP pBlkMap) { LogFlowFunc(("pBlkMap=%#p\n", pBlkMap)); PVCIBLKRANGEDESC pRangeCur = pBlkMap->pRangesHead; while (pRangeCur) { PVCIBLKRANGEDESC pTmp = pRangeCur; RTMemFree(pTmp); pRangeCur = pRangeCur->pNext; } RTMemFree(pBlkMap); LogFlowFunc(("returns\n")); } /** * Loads the block map from the specified medium and creates all necessary * in memory structures to manage used and free blocks. * * @returns VBox status code. * @param pStorage Storage handle to read the block bitmap from. * @param offBlkMap Start of the block bitmap in blocks. * @param cBlkMap Size of the block bitmap on the disk in blocks. * @param ppBlkMap Where to store the block bitmap on success. */ static int vciBlkMapLoad(PVCICACHE pStorage, uint64_t offBlkMap, uint32_t cBlkMap, PVCIBLKMAP *ppBlkMap) { int rc = VINF_SUCCESS; VciBlkMap BlkMap; LogFlowFunc(("pStorage=%#p offBlkMap=%llu cBlkMap=%u ppBlkMap=%#p\n", pStorage, offBlkMap, cBlkMap, ppBlkMap)); if (cBlkMap >= VCI_BYTE2BLOCK(sizeof(VciBlkMap))) { cBlkMap -= VCI_BYTE2BLOCK(sizeof(VciBlkMap)); rc = vdIfIoIntFileReadSync(pStorage->pIfIo, pStorage->pStorage, offBlkMap, &BlkMap, VCI_BYTE2BLOCK(sizeof(VciBlkMap))); if (RT_SUCCESS(rc)) { offBlkMap += VCI_BYTE2BLOCK(sizeof(VciBlkMap)); BlkMap.u32Magic = RT_LE2H_U32(BlkMap.u32Magic); BlkMap.u32Version = RT_LE2H_U32(BlkMap.u32Version); BlkMap.cBlocks = RT_LE2H_U32(BlkMap.cBlocks); BlkMap.cBlocksFree = RT_LE2H_U32(BlkMap.cBlocksFree); BlkMap.cBlocksAllocMeta = RT_LE2H_U32(BlkMap.cBlocksAllocMeta); BlkMap.cBlocksAllocData = RT_LE2H_U32(BlkMap.cBlocksAllocData); if ( BlkMap.u32Magic == VCI_BLKMAP_MAGIC && BlkMap.u32Version == VCI_BLKMAP_VERSION && BlkMap.cBlocks == BlkMap.cBlocksFree + BlkMap.cBlocksAllocMeta + BlkMap.cBlocksAllocData && VCI_BYTE2BLOCK(BlkMap.cBlocks / 8) == cBlkMap) { PVCIBLKMAP pBlkMap = (PVCIBLKMAP)RTMemAllocZ(sizeof(VCIBLKMAP)); if (pBlkMap) { pBlkMap->cBlocks = BlkMap.cBlocks; pBlkMap->cBlocksFree = BlkMap.cBlocksFree; pBlkMap->cBlocksAllocMeta = BlkMap.cBlocksAllocMeta; pBlkMap->cBlocksAllocData = BlkMap.cBlocksAllocData; /* Load the bitmap and construct the range list. */ uint32_t cBlocksFree = 0; uint32_t cBlocksAllocated = 0; PVCIBLKRANGEDESC pRangeCur = (PVCIBLKRANGEDESC)RTMemAllocZ(sizeof(VCIBLKRANGEDESC)); if (pRangeCur) { uint8_t abBitmapBuffer[16 * _1K]; uint32_t cBlocksRead = 0; uint64_t cBlocksLeft = VCI_BYTE2BLOCK(pBlkMap->cBlocks / 8); cBlocksRead = RT_MIN(VCI_BYTE2BLOCK(sizeof(abBitmapBuffer)), cBlocksLeft); rc = vdIfIoIntFileReadSync(pStorage->pIfIo, pStorage->pStorage, offBlkMap, abBitmapBuffer, cBlocksRead); if (RT_SUCCESS(rc)) { pRangeCur->fFree = !(abBitmapBuffer[0] & 0x01); pRangeCur->offAddrStart = 0; pRangeCur->cBlocks = 0; pRangeCur->pNext = NULL; pRangeCur->pPrev = NULL; pBlkMap->pRangesHead = pRangeCur; pBlkMap->pRangesTail = pRangeCur; } while ( RT_SUCCESS(rc) && cBlocksLeft) { int iBit = 0; uint32_t cBits = VCI_BLOCK2BYTE(cBlocksRead) * 8; uint32_t iBitPrev = 0xffffffff; while (cBits) { if (pRangeCur->fFree) { /* Check for the first set bit. */ iBit = ASMBitNextSet(abBitmapBuffer, cBits, iBitPrev); } else { /* Check for the first free bit. */ iBit = ASMBitNextClear(abBitmapBuffer, cBits, iBitPrev); } if (iBit == -1) { /* No change. */ pRangeCur->cBlocks += cBits; cBits = 0; } else { Assert((uint32_t)iBit < cBits); pRangeCur->cBlocks += iBit; /* Create a new range descriptor. */ PVCIBLKRANGEDESC pRangeNew = (PVCIBLKRANGEDESC)RTMemAllocZ(sizeof(VCIBLKRANGEDESC)); if (!pRangeNew) { rc = VERR_NO_MEMORY; break; } pRangeNew->fFree = !pRangeCur->fFree; pRangeNew->offAddrStart = pRangeCur->offAddrStart + pRangeCur->cBlocks; pRangeNew->cBlocks = 0; pRangeNew->pPrev = pRangeCur; pRangeCur->pNext = pRangeNew; pBlkMap->pRangesTail = pRangeNew; pRangeCur = pRangeNew; cBits -= iBit; iBitPrev = iBit; } } cBlocksLeft -= cBlocksRead; offBlkMap += cBlocksRead; if ( RT_SUCCESS(rc) && cBlocksLeft) { /* Read next chunk. */ cBlocksRead = RT_MIN(VCI_BYTE2BLOCK(sizeof(abBitmapBuffer)), cBlocksLeft); rc = vdIfIoIntFileReadSync(pStorage->pIfIo, pStorage->pStorage, offBlkMap, abBitmapBuffer, cBlocksRead); } } } else rc = VERR_NO_MEMORY; if (RT_SUCCESS(rc)) { *ppBlkMap = pBlkMap; LogFlowFunc(("return success\n")); return VINF_SUCCESS; } else RTMemFree(pBlkMap); } else rc = VERR_NO_MEMORY; } else rc = VERR_VD_GEN_INVALID_HEADER; } else if (RT_SUCCESS(rc)) rc = VERR_VD_GEN_INVALID_HEADER; } else rc = VERR_VD_GEN_INVALID_HEADER; LogFlowFunc(("returns rc=%Rrc\n", rc)); return rc; } /** * Saves the block map in the cache image. All necessary on disk structures * are written. * * @returns VBox status code. * @param pBlkMap The block bitmap to save. * @param pStorage Where the block bitmap should be written to. * @param offBlkMap Start of the block bitmap in blocks. * @param cBlkMap Size of the block bitmap on the disk in blocks. */ static int vciBlkMapSave(PVCIBLKMAP pBlkMap, PVCICACHE pStorage, uint64_t offBlkMap, uint32_t cBlkMap) { int rc = VINF_SUCCESS; VciBlkMap BlkMap; LogFlowFunc(("pBlkMap=%#p pStorage=%#p offBlkMap=%llu cBlkMap=%u\n", pBlkMap, pStorage, offBlkMap, cBlkMap)); /* Make sure the number of blocks allocated for us match our expectations. */ if (VCI_BYTE2BLOCK(pBlkMap->cBlocks / 8) + VCI_BYTE2BLOCK(sizeof(VciBlkMap)) == cBlkMap) { /* Setup the header */ memset(&BlkMap, 0, sizeof(VciBlkMap)); BlkMap.u32Magic = RT_H2LE_U32(VCI_BLKMAP_MAGIC); BlkMap.u32Version = RT_H2LE_U32(VCI_BLKMAP_VERSION); BlkMap.cBlocks = RT_H2LE_U32(pBlkMap->cBlocks); BlkMap.cBlocksFree = RT_H2LE_U32(pBlkMap->cBlocksFree); BlkMap.cBlocksAllocMeta = RT_H2LE_U32(pBlkMap->cBlocksAllocMeta); BlkMap.cBlocksAllocData = RT_H2LE_U32(pBlkMap->cBlocksAllocData); rc = vdIfIoIntFileWriteSync(pStorage->pIfIo, pStorage->pStorage, offBlkMap, &BlkMap, VCI_BYTE2BLOCK(sizeof(VciBlkMap))); if (RT_SUCCESS(rc)) { uint8_t abBitmapBuffer[16*_1K]; unsigned iBit = 0; PVCIBLKRANGEDESC pCur = pBlkMap->pRangesHead; offBlkMap += VCI_BYTE2BLOCK(sizeof(VciBlkMap)); /* Write the descriptor ranges. */ while (pCur) { uint64_t cBlocks = pCur->cBlocks; while (cBlocks) { uint64_t cBlocksMax = RT_MIN(cBlocks, sizeof(abBitmapBuffer) * 8 - iBit); if (pCur->fFree) ASMBitClearRange(abBitmapBuffer, iBit, iBit + cBlocksMax); else ASMBitSetRange(abBitmapBuffer, iBit, iBit + cBlocksMax); iBit += cBlocksMax; cBlocks -= cBlocksMax; if (iBit == sizeof(abBitmapBuffer) * 8) { /* Buffer is full, write to file and reset. */ rc = vdIfIoIntFileWriteSync(pStorage->pIfIo, pStorage->pStorage, offBlkMap, abBitmapBuffer, VCI_BYTE2BLOCK(sizeof(abBitmapBuffer))); if (RT_FAILURE(rc)) break; offBlkMap += VCI_BYTE2BLOCK(sizeof(abBitmapBuffer)); iBit = 0; } } pCur = pCur->pNext; } Assert(iBit % 8 == 0); if (RT_SUCCESS(rc) && iBit) rc = vdIfIoIntFileWriteSync(pStorage->pIfIo, pStorage->pStorage, offBlkMap, abBitmapBuffer, VCI_BYTE2BLOCK(iBit / 8)); } } else rc = VERR_INTERNAL_ERROR; /* @todo Better error code. */ LogFlowFunc(("returns rc=%Rrc\n", rc)); return rc; } /** * Finds the range block describing the given block address. * * @returns Pointer to the block range descriptor or NULL if none could be found. * @param pBlkMap The block bitmap to search on. * @param offBlockAddr The block address to search for. */ static PVCIBLKRANGEDESC vciBlkMapFindByBlock(PVCIBLKMAP pBlkMap, uint64_t offBlockAddr) { PVCIBLKRANGEDESC pBlk = pBlkMap->pRangesHead; while ( pBlk && pBlk->offAddrStart < offBlockAddr) pBlk = pBlk->pNext; return pBlk; } /** * Allocates the given number of blocks in the bitmap and returns the start block address. * * @returns VBox status code. * @param pBlkMap The block bitmap to allocate the blocks from. * @param cBlocks How many blocks to allocate. * @param fFlags Allocation flags, comgination of VCIBLKMAP_ALLOC_*. * @param poffBlockAddr Where to store the start address of the allocated region. */ static int vciBlkMapAllocate(PVCIBLKMAP pBlkMap, uint32_t cBlocks, uint32_t fFlags, uint64_t *poffBlockAddr) { PVCIBLKRANGEDESC pBestFit = NULL; PVCIBLKRANGEDESC pCur = NULL; int rc = VINF_SUCCESS; LogFlowFunc(("pBlkMap=%#p cBlocks=%u poffBlockAddr=%#p\n", pBlkMap, cBlocks, poffBlockAddr)); pCur = pBlkMap->pRangesHead; while (pCur) { if ( pCur->fFree && pCur->cBlocks >= cBlocks) { if ( !pBestFit || pCur->cBlocks < pBestFit->cBlocks) { pBestFit = pCur; /* Stop searching if the size is matching exactly. */ if (pBestFit->cBlocks == cBlocks) break; } } pCur = pCur->pNext; } Assert(!pBestFit || pBestFit->fFree); if (pBestFit) { pBestFit->fFree = false; if (pBestFit->cBlocks > cBlocks) { /* Create a new free block. */ PVCIBLKRANGEDESC pFree = (PVCIBLKRANGEDESC)RTMemAllocZ(sizeof(VCIBLKRANGEDESC)); if (pFree) { pFree->fFree = true; pFree->cBlocks = pBestFit->cBlocks - cBlocks; pBestFit->cBlocks -= pFree->cBlocks; pFree->offAddrStart = pBestFit->offAddrStart + cBlocks; /* Link into the list. */ pFree->pNext = pBestFit->pNext; pBestFit->pNext = pFree; pFree->pPrev = pBestFit; if (!pFree->pNext) pBlkMap->pRangesTail = pFree; *poffBlockAddr = pBestFit->offAddrStart; } else { rc = VERR_NO_MEMORY; pBestFit->fFree = true; } } } else rc = VERR_VCI_NO_BLOCKS_FREE; if (RT_SUCCESS(rc)) { if ((fFlags & VCIBLKMAP_ALLOC_MASK) == VCIBLKMAP_ALLOC_DATA) pBlkMap->cBlocksAllocMeta += cBlocks; else pBlkMap->cBlocksAllocData += cBlocks; pBlkMap->cBlocksFree -= cBlocks; } LogFlowFunc(("returns rc=%Rrc offBlockAddr=%llu\n", rc, *poffBlockAddr)); return rc; } /** * Try to extend the space of an already allocated block. * * @returns VBox status code. * @param pBlkMap The block bitmap to allocate the blocks from. * @param cBlocksNew How many blocks the extended block should have. * @param offBlockAddrOld The start address of the block to reallocate. * @param poffBlockAddr Where to store the start address of the allocated region. */ static int vciBlkMapRealloc(PVCIBLKMAP pBlkMap, uint32_t cBlocksNew, uint64_t offBlockAddrOld, uint64_t *poffBlockAddr) { int rc = VINF_SUCCESS; LogFlowFunc(("pBlkMap=%#p cBlocksNew=%u offBlockAddrOld=%llu poffBlockAddr=%#p\n", pBlkMap, cBlocksNew, offBlockAddrOld, poffBlockAddr)); AssertMsgFailed(("Implement\n")); LogFlowFunc(("returns rc=%Rrc offBlockAddr=%llu\n", rc, *poffBlockAddr)); return rc; } /** * Frees a range of blocks. * * @returns nothing. * @param pBlkMap The block bitmap. * @param offBlockAddr Address of the first block to free. * @param cBlocks How many blocks to free. * @param fFlags Allocation flags, comgination of VCIBLKMAP_ALLOC_*. */ static void vciBlkMapFree(PVCIBLKMAP pBlkMap, uint64_t offBlockAddr, uint32_t cBlocks, uint32_t fFlags) { PVCIBLKRANGEDESC pBlk; LogFlowFunc(("pBlkMap=%#p offBlockAddr=%llu cBlocks=%u\n", pBlkMap, offBlockAddr, cBlocks)); while (cBlocks) { pBlk = vciBlkMapFindByBlock(pBlkMap, offBlockAddr); AssertPtr(pBlk); /* Easy case, the whole block is freed. */ if ( pBlk->offAddrStart == offBlockAddr && pBlk->cBlocks <= cBlocks) { pBlk->fFree = true; cBlocks -= pBlk->cBlocks; offBlockAddr += pBlk->cBlocks; /* Check if it is possible to merge free blocks. */ if ( pBlk->pPrev && pBlk->pPrev->fFree) { PVCIBLKRANGEDESC pBlkPrev = pBlk->pPrev; Assert(pBlkPrev->offAddrStart + pBlkPrev->cBlocks == pBlk->offAddrStart); pBlkPrev->cBlocks += pBlk->cBlocks; pBlkPrev->pNext = pBlk->pNext; if (pBlk->pNext) pBlk->pNext->pPrev = pBlkPrev; else pBlkMap->pRangesTail = pBlkPrev; RTMemFree(pBlk); pBlk = pBlkPrev; } /* Now the one to the right. */ if ( pBlk->pNext && pBlk->pNext->fFree) { PVCIBLKRANGEDESC pBlkNext = pBlk->pNext; Assert(pBlk->offAddrStart + pBlk->cBlocks == pBlkNext->offAddrStart); pBlk->cBlocks += pBlkNext->cBlocks; pBlk->pNext = pBlkNext->pNext; if (pBlkNext->pNext) pBlkNext->pNext->pPrev = pBlk; else pBlkMap->pRangesTail = pBlk; RTMemFree(pBlkNext); } } else { /* The block is intersecting. */ AssertMsgFailed(("TODO\n")); } } if ((fFlags & VCIBLKMAP_ALLOC_MASK) == VCIBLKMAP_ALLOC_DATA) pBlkMap->cBlocksAllocMeta -= cBlocks; else pBlkMap->cBlocksAllocData -= cBlocks; pBlkMap->cBlocksFree += cBlocks; LogFlowFunc(("returns\n")); } /** * Converts a tree node from the image to the in memory structure. * * @returns Pointer to the in memory tree node. * @param offBlockAddrNode Block address of the node. * @param pNodeImage Pointer to the image representation of the node. */ static PVCITREENODE vciTreeNodeImage2Host(uint64_t offBlockAddrNode, PVciTreeNode pNodeImage) { PVCITREENODE pNode = NULL; if (pNodeImage->u8Type == VCI_TREE_NODE_TYPE_LEAF) { PVCITREENODELEAF pLeaf = (PVCITREENODELEAF)RTMemAllocZ(sizeof(VCITREENODELEAF)); if (pLeaf) { PVciCacheExtent pExtent = (PVciCacheExtent)&pNodeImage->au8Data[0]; pLeaf->Core.u8Type = VCI_TREE_NODE_TYPE_LEAF; for (unsigned idx = 0; idx < RT_ELEMENTS(pLeaf->aExtents); idx++) { pLeaf->aExtents[idx].u64BlockOffset = RT_LE2H_U64(pExtent->u64BlockOffset); pLeaf->aExtents[idx].u32Blocks = RT_LE2H_U32(pExtent->u32Blocks); pLeaf->aExtents[idx].u64BlockAddr = RT_LE2H_U64(pExtent->u64BlockAddr); pExtent++; if ( pLeaf->aExtents[idx].u32Blocks && pLeaf->aExtents[idx].u64BlockAddr) pLeaf->cUsedNodes++; } pNode = &pLeaf->Core; } } else if (pNodeImage->u8Type == VCI_TREE_NODE_TYPE_INTERNAL) { PVCITREENODEINT pInt = (PVCITREENODEINT)RTMemAllocZ(sizeof(VCITREENODEINT)); if (pInt) { PVciTreeNodeInternal pIntImage = (PVciTreeNodeInternal)&pNodeImage->au8Data[0]; pInt->Core.u8Type = VCI_TREE_NODE_TYPE_INTERNAL; for (unsigned idx = 0; idx < RT_ELEMENTS(pInt->aIntNodes); idx++) { pInt->aIntNodes[idx].u64BlockOffset = RT_LE2H_U64(pIntImage->u64BlockOffset); pInt->aIntNodes[idx].u32Blocks = RT_LE2H_U32(pIntImage->u32Blocks); pInt->aIntNodes[idx].PtrChild.fInMemory = false; pInt->aIntNodes[idx].PtrChild.u.offAddrBlockNode = RT_LE2H_U64(pIntImage->u64ChildAddr); pIntImage++; if ( pInt->aIntNodes[idx].u32Blocks && pInt->aIntNodes[idx].PtrChild.u.offAddrBlockNode) pInt->cUsedNodes++; } pNode = &pInt->Core; } } else AssertMsgFailed(("Invalid node type %d\n", pNodeImage->u8Type)); if (pNode) pNode->u64BlockAddr = offBlockAddrNode; return pNode; } /** * Looks up the cache extent for the given virtual block address. * * @returns Pointer to the cache extent or NULL if none could be found. * @param pCache The cache image instance. * @param offBlockOffset The block offset to search for. * @param ppNextBestFit Where to store the pointer to the next best fit * cache extent above offBlockOffset if existing. - Optional * This is always filled if possible even if the function returns NULL. */ static PVCICACHEEXTENT vciCacheExtentLookup(PVCICACHE pCache, uint64_t offBlockOffset, PVCICACHEEXTENT *ppNextBestFit) { int rc = VINF_SUCCESS; PVCICACHEEXTENT pExtent = NULL; PVCITREENODE pNodeCur = pCache->pRoot; while ( RT_SUCCESS(rc) && pNodeCur && pNodeCur->u8Type != VCI_TREE_NODE_TYPE_LEAF) { PVCITREENODEINT pNodeInt = (PVCITREENODEINT)pNodeCur; Assert(pNodeCur->u8Type == VCI_TREE_NODE_TYPE_INTERNAL); /* Search for the correct internal node. */ unsigned idxMin = 0; unsigned idxMax = pNodeInt->cUsedNodes; unsigned idxCur = pNodeInt->cUsedNodes / 2; while (idxMin < idxMax) { PVCINODEINTERNAL pInt = &pNodeInt->aIntNodes[idxCur]; /* Determine the search direction. */ if (offBlockOffset < pInt->u64BlockOffset) { /* Search left from the current extent. */ idxMax = idxCur; } else if (offBlockOffset >= pInt->u64BlockOffset + pInt->u32Blocks) { /* Search right from the current extent. */ idxMin = idxCur; } else { /* The block lies in the node, stop searching. */ if (pInt->PtrChild.fInMemory) pNodeCur = pInt->PtrChild.u.pNode; else { PVCITREENODE pNodeNew; VciTreeNode NodeTree; /* Read from disk and add to the tree. */ rc = vdIfIoIntFileReadSync(pCache->pIfIo, pCache->pStorage, VCI_BLOCK2BYTE(pInt->PtrChild.u.offAddrBlockNode), &NodeTree, sizeof(NodeTree)); AssertRC(rc); pNodeNew = vciTreeNodeImage2Host(pInt->PtrChild.u.offAddrBlockNode, &NodeTree); if (pNodeNew) { /* Link to the parent. */ pInt->PtrChild.fInMemory = true; pInt->PtrChild.u.pNode = pNodeNew; pNodeNew->pParent = pNodeCur; pNodeCur = pNodeNew; } else rc = VERR_NO_MEMORY; } break; } idxCur = idxMin + (idxMax - idxMin) / 2; } } if ( RT_SUCCESS(rc) && pNodeCur) { PVCITREENODELEAF pLeaf = (PVCITREENODELEAF)pNodeCur; Assert(pNodeCur->u8Type == VCI_TREE_NODE_TYPE_LEAF); /* Search the range. */ unsigned idxMin = 0; unsigned idxMax = pLeaf->cUsedNodes; unsigned idxCur = pLeaf->cUsedNodes / 2; while (idxMin < idxMax) { PVCICACHEEXTENT pExtentCur = &pLeaf->aExtents[idxCur]; /* Determine the search direction. */ if (offBlockOffset < pExtentCur->u64BlockOffset) { /* Search left from the current extent. */ idxMax = idxCur; } else if (offBlockOffset >= pExtentCur->u64BlockOffset + pExtentCur->u32Blocks) { /* Search right from the current extent. */ idxMin = idxCur; } else { /* We found the extent, stop searching. */ pExtent = pExtentCur; break; } idxCur = idxMin + (idxMax - idxMin) / 2; } /* Get the next best fit extent if it exists. */ if (ppNextBestFit) { if (idxCur < pLeaf->cUsedNodes - 1) *ppNextBestFit = &pLeaf->aExtents[idxCur + 1]; else { /* * Go up the tree and find the best extent * in the leftmost tree of the child subtree to the right. */ PVCITREENODEINT pInt = (PVCITREENODEINT)pLeaf->Core.pParent; while (pInt) { } } } } return pExtent; } /** * Internal: Open an image, constructing all necessary data structures. */ static int vciOpenImage(PVCICACHE pCache, unsigned uOpenFlags) { VciHdr Hdr; uint64_t cbFile; int rc; pCache->uOpenFlags = uOpenFlags; pCache->pIfError = VDIfErrorGet(pCache->pVDIfsDisk); pCache->pIfIo = VDIfIoIntGet(pCache->pVDIfsImage); AssertPtrReturn(pCache->pIfIo, VERR_INVALID_PARAMETER); /* * Open the image. */ rc = vdIfIoIntFileOpen(pCache->pIfIo, pCache->pszFilename, VDOpenFlagsToFileOpenFlags(uOpenFlags, false /* fCreate */), &pCache->pStorage); if (RT_FAILURE(rc)) { /* Do NOT signal an appropriate error here, as the VD layer has the * choice of retrying the open if it failed. */ goto out; } rc = vdIfIoIntFileGetSize(pCache->pIfIo, pCache->pStorage, &cbFile); if (RT_FAILURE(rc) || cbFile < sizeof(VciHdr)) { rc = VERR_VD_GEN_INVALID_HEADER; goto out; } rc = vdIfIoIntFileReadSync(pCache->pIfIo, pCache->pStorage, 0, &Hdr, VCI_BYTE2BLOCK(sizeof(Hdr))); if (RT_FAILURE(rc)) { rc = VERR_VD_GEN_INVALID_HEADER; goto out; } Hdr.u32Signature = RT_LE2H_U32(Hdr.u32Signature); Hdr.u32Version = RT_LE2H_U32(Hdr.u32Version); Hdr.cBlocksCache = RT_LE2H_U64(Hdr.cBlocksCache); Hdr.u32CacheType = RT_LE2H_U32(Hdr.u32CacheType); Hdr.offTreeRoot = RT_LE2H_U64(Hdr.offTreeRoot); Hdr.offBlkMap = RT_LE2H_U64(Hdr.offBlkMap); Hdr.cBlkMap = RT_LE2H_U32(Hdr.cBlkMap); if ( Hdr.u32Signature == VCI_HDR_SIGNATURE && Hdr.u32Version == VCI_HDR_VERSION) { pCache->offTreeRoot = Hdr.offTreeRoot; pCache->offBlksBitmap = Hdr.offBlkMap; /* Load the block map. */ rc = vciBlkMapLoad(pCache, pCache->offBlksBitmap, Hdr.cBlkMap, &pCache->pBlkMap); if (RT_SUCCESS(rc)) { /* Load the first tree node. */ VciTreeNode RootNode; rc = vdIfIoIntFileReadSync(pCache->pIfIo, pCache->pStorage, pCache->offTreeRoot, &RootNode, VCI_BYTE2BLOCK(sizeof(VciTreeNode))); if (RT_SUCCESS(rc)) { pCache->pRoot = vciTreeNodeImage2Host(pCache->offTreeRoot, &RootNode); if (!pCache->pRoot) rc = VERR_NO_MEMORY; } } } else rc = VERR_VD_GEN_INVALID_HEADER; out: if (RT_FAILURE(rc)) vciFreeImage(pCache, false); return rc; } /** * Internal: Create a vci image. */ static int vciCreateImage(PVCICACHE pCache, uint64_t cbSize, unsigned uImageFlags, const char *pszComment, unsigned uOpenFlags, PFNVDPROGRESS pfnProgress, void *pvUser, unsigned uPercentStart, unsigned uPercentSpan) { VciHdr Hdr; VciTreeNode NodeRoot; int rc; uint64_t cBlocks = cbSize / VCI_BLOCK_SIZE; /* Size of the cache in blocks. */ pCache->uImageFlags = uImageFlags; pCache->uOpenFlags = uOpenFlags & ~VD_OPEN_FLAGS_READONLY; pCache->pIfError = VDIfErrorGet(pCache->pVDIfsDisk); pCache->pIfIo = VDIfIoIntGet(pCache->pVDIfsImage); AssertPtrReturn(pCache->pIfIo, VERR_INVALID_PARAMETER); if (uImageFlags & VD_IMAGE_FLAGS_DIFF) { rc = vdIfError(pCache->pIfError, VERR_VD_RAW_INVALID_TYPE, RT_SRC_POS, N_("VCI: cannot create diff image '%s'"), pCache->pszFilename); return rc; } do { /* Create image file. */ rc = vdIfIoIntFileOpen(pCache->pIfIo, pCache->pszFilename, VDOpenFlagsToFileOpenFlags(uOpenFlags & ~VD_OPEN_FLAGS_READONLY, true /* fCreate */), &pCache->pStorage); if (RT_FAILURE(rc)) { rc = vdIfError(pCache->pIfError, rc, RT_SRC_POS, N_("VCI: cannot create image '%s'"), pCache->pszFilename); break; } /* Allocate block bitmap. */ uint32_t cBlkMap = 0; rc = vciBlkMapCreate(cBlocks, &pCache->pBlkMap, &cBlkMap); if (RT_FAILURE(rc)) { rc = vdIfError(pCache->pIfError, rc, RT_SRC_POS, N_("VCI: cannot create block bitmap '%s'"), pCache->pszFilename); break; } /* * Allocate space for the header in the block bitmap. * Because the block map is empty the header has to start at block 0 */ uint64_t offHdr = 0; rc = vciBlkMapAllocate(pCache->pBlkMap, VCI_BYTE2BLOCK(sizeof(VciHdr)), VCIBLKMAP_ALLOC_META, &offHdr); if (RT_FAILURE(rc)) { rc = vdIfError(pCache->pIfError, rc, RT_SRC_POS, N_("VCI: cannot allocate space for header in block bitmap '%s'"), pCache->pszFilename); break; } Assert(offHdr == 0); /* * Allocate space for the block map itself. */ uint64_t offBlkMap = 0; rc = vciBlkMapAllocate(pCache->pBlkMap, cBlkMap, VCIBLKMAP_ALLOC_META, &offBlkMap); if (RT_FAILURE(rc)) { rc = vdIfError(pCache->pIfError, rc, RT_SRC_POS, N_("VCI: cannot allocate space for block map in block map '%s'"), pCache->pszFilename); break; } /* * Allocate space for the tree root node. */ uint64_t offTreeRoot = 0; rc = vciBlkMapAllocate(pCache->pBlkMap, VCI_BYTE2BLOCK(sizeof(VciTreeNode)), VCIBLKMAP_ALLOC_META, &offTreeRoot); if (RT_FAILURE(rc)) { rc = vdIfError(pCache->pIfError, rc, RT_SRC_POS, N_("VCI: cannot allocate space for block map in block map '%s'"), pCache->pszFilename); break; } /* * Allocate the in memory root node. */ pCache->pRoot = (PVCITREENODE)RTMemAllocZ(sizeof(VCITREENODELEAF)); if (!pCache->pRoot) { rc = vdIfError(pCache->pIfError, rc, RT_SRC_POS, N_("VCI: cannot allocate B+-Tree root pointer '%s'"), pCache->pszFilename); break; } pCache->pRoot->u8Type = VCI_TREE_NODE_TYPE_LEAF; /* Rest remains 0 as the tree is still empty. */ /* * Now that we are here we have all the basic structures and know where to place them in the image. * It's time to write it now. */ /* Setup the header. */ memset(&Hdr, 0, sizeof(VciHdr)); Hdr.u32Signature = RT_H2LE_U32(VCI_HDR_SIGNATURE); Hdr.u32Version = RT_H2LE_U32(VCI_HDR_VERSION); Hdr.cBlocksCache = RT_H2LE_U64(cBlocks); Hdr.fUncleanShutdown = VCI_HDR_UNCLEAN_SHUTDOWN; Hdr.u32CacheType = uImageFlags & VD_IMAGE_FLAGS_FIXED ? RT_H2LE_U32(VCI_HDR_CACHE_TYPE_FIXED) : RT_H2LE_U32(VCI_HDR_CACHE_TYPE_DYNAMIC); Hdr.offTreeRoot = RT_H2LE_U64(offTreeRoot); Hdr.offBlkMap = RT_H2LE_U64(offBlkMap); Hdr.cBlkMap = RT_H2LE_U32(cBlkMap); rc = vdIfIoIntFileWriteSync(pCache->pIfIo, pCache->pStorage, offHdr, &Hdr, VCI_BYTE2BLOCK(sizeof(VciHdr))); if (RT_FAILURE(rc)) { rc = vdIfError(pCache->pIfError, rc, RT_SRC_POS, N_("VCI: cannot write header '%s'"), pCache->pszFilename); break; } rc = vciBlkMapSave(pCache->pBlkMap, pCache, offBlkMap, cBlkMap); if (RT_FAILURE(rc)) { rc = vdIfError(pCache->pIfError, rc, RT_SRC_POS, N_("VCI: cannot write block map '%s'"), pCache->pszFilename); break; } /* Setup the root tree. */ memset(&NodeRoot, 0, sizeof(VciTreeNode)); NodeRoot.u8Type = RT_H2LE_U32(VCI_TREE_NODE_TYPE_LEAF); rc = vdIfIoIntFileWriteSync(pCache->pIfIo, pCache->pStorage, offTreeRoot, &NodeRoot, VCI_BYTE2BLOCK(sizeof(VciTreeNode))); if (RT_FAILURE(rc)) { rc = vdIfError(pCache->pIfError, rc, RT_SRC_POS, N_("VCI: cannot write root node '%s'"), pCache->pszFilename); break; } rc = vciFlushImage(pCache); if (RT_FAILURE(rc)) { rc = vdIfError(pCache->pIfError, rc, RT_SRC_POS, N_("VCI: cannot flush '%s'"), pCache->pszFilename); break; } pCache->cbSize = cbSize; } while (0); if (RT_SUCCESS(rc) && pfnProgress) pfnProgress(pvUser, uPercentStart + uPercentSpan); if (RT_FAILURE(rc)) vciFreeImage(pCache, rc != VERR_ALREADY_EXISTS); return rc; } /** @copydoc VDCACHEBACKEND::pfnProbe */ static int vciProbe(const char *pszFilename, PVDINTERFACE pVDIfsCache, PVDINTERFACE pVDIfsImage) { VciHdr Hdr; PVDIOSTORAGE pStorage = NULL; uint64_t cbFile; int rc = VINF_SUCCESS; LogFlowFunc(("pszFilename=\"%s\"\n", pszFilename)); PVDINTERFACEIOINT pIfIo = VDIfIoIntGet(pVDIfsImage); AssertPtrReturn(pIfIo, VERR_INVALID_PARAMETER); rc = vdIfIoIntFileOpen(pIfIo, pszFilename, VDOpenFlagsToFileOpenFlags(VD_OPEN_FLAGS_READONLY, false /* fCreate */), &pStorage); if (RT_FAILURE(rc)) goto out; rc = vdIfIoIntFileGetSize(pIfIo, pStorage, &cbFile); if (RT_FAILURE(rc) || cbFile < sizeof(VciHdr)) { rc = VERR_VD_GEN_INVALID_HEADER; goto out; } rc = vdIfIoIntFileReadSync(pIfIo, pStorage, 0, &Hdr, sizeof(Hdr)); if (RT_FAILURE(rc)) { rc = VERR_VD_GEN_INVALID_HEADER; goto out; } Hdr.u32Signature = RT_LE2H_U32(Hdr.u32Signature); Hdr.u32Version = RT_LE2H_U32(Hdr.u32Version); Hdr.cBlocksCache = RT_LE2H_U64(Hdr.cBlocksCache); Hdr.u32CacheType = RT_LE2H_U32(Hdr.u32CacheType); Hdr.offTreeRoot = RT_LE2H_U64(Hdr.offTreeRoot); Hdr.offBlkMap = RT_LE2H_U64(Hdr.offBlkMap); Hdr.cBlkMap = RT_LE2H_U32(Hdr.cBlkMap); if ( Hdr.u32Signature == VCI_HDR_SIGNATURE && Hdr.u32Version == VCI_HDR_VERSION) rc = VINF_SUCCESS; else rc = VERR_VD_GEN_INVALID_HEADER; out: if (pStorage) vdIfIoIntFileClose(pIfIo, pStorage); LogFlowFunc(("returns %Rrc\n", rc)); return rc; } /** @copydoc VDCACHEBACKEND::pfnOpen */ static int vciOpen(const char *pszFilename, unsigned uOpenFlags, PVDINTERFACE pVDIfsDisk, PVDINTERFACE pVDIfsImage, void **ppBackendData) { LogFlowFunc(("pszFilename=\"%s\" uOpenFlags=%#x pVDIfsDisk=%#p pVDIfsImage=%#p ppBackendData=%#p\n", pszFilename, uOpenFlags, pVDIfsDisk, pVDIfsImage, ppBackendData)); int rc; PVCICACHE pCache; /* Check open flags. All valid flags are supported. */ if (uOpenFlags & ~VD_OPEN_FLAGS_MASK) { rc = VERR_INVALID_PARAMETER; goto out; } /* Check remaining arguments. */ if ( !VALID_PTR(pszFilename) || !*pszFilename) { rc = VERR_INVALID_PARAMETER; goto out; } pCache = (PVCICACHE)RTMemAllocZ(sizeof(VCICACHE)); if (!pCache) { rc = VERR_NO_MEMORY; goto out; } pCache->pszFilename = pszFilename; pCache->pStorage = NULL; pCache->pVDIfsDisk = pVDIfsDisk; pCache->pVDIfsImage = pVDIfsImage; rc = vciOpenImage(pCache, uOpenFlags); if (RT_SUCCESS(rc)) *ppBackendData = pCache; else RTMemFree(pCache); out: LogFlowFunc(("returns %Rrc (pBackendData=%#p)\n", rc, *ppBackendData)); return rc; } /** @copydoc VDCACHEBACKEND::pfnCreate */ static int vciCreate(const char *pszFilename, uint64_t cbSize, unsigned uImageFlags, const char *pszComment, PCRTUUID pUuid, unsigned uOpenFlags, unsigned uPercentStart, unsigned uPercentSpan, PVDINTERFACE pVDIfsDisk, PVDINTERFACE pVDIfsImage, PVDINTERFACE pVDIfsOperation, void **ppBackendData) { LogFlowFunc(("pszFilename=\"%s\" cbSize=%llu uImageFlags=%#x pszComment=\"%s\" Uuid=%RTuuid uOpenFlags=%#x uPercentStart=%u uPercentSpan=%u pVDIfsDisk=%#p pVDIfsImage=%#p pVDIfsOperation=%#p ppBackendData=%#p", pszFilename, cbSize, uImageFlags, pszComment, pUuid, uOpenFlags, uPercentStart, uPercentSpan, pVDIfsDisk, pVDIfsImage, pVDIfsOperation, ppBackendData)); int rc; PVCICACHE pCache; PFNVDPROGRESS pfnProgress = NULL; void *pvUser = NULL; PVDINTERFACEPROGRESS pIfProgress = VDIfProgressGet(pVDIfsOperation); if (pIfProgress) { pfnProgress = pIfProgress->pfnProgress; pvUser = pIfProgress->Core.pvUser; } /* Check open flags. All valid flags are supported. */ if (uOpenFlags & ~VD_OPEN_FLAGS_MASK) { rc = VERR_INVALID_PARAMETER; goto out; } /* Check remaining arguments. */ if ( !VALID_PTR(pszFilename) || !*pszFilename) { rc = VERR_INVALID_PARAMETER; goto out; } pCache = (PVCICACHE)RTMemAllocZ(sizeof(VCICACHE)); if (!pCache) { rc = VERR_NO_MEMORY; goto out; } pCache->pszFilename = pszFilename; pCache->pStorage = NULL; pCache->pVDIfsDisk = pVDIfsDisk; pCache->pVDIfsImage = pVDIfsImage; rc = vciCreateImage(pCache, cbSize, uImageFlags, pszComment, uOpenFlags, pfnProgress, pvUser, uPercentStart, uPercentSpan); if (RT_SUCCESS(rc)) { /* So far the image is opened in read/write mode. Make sure the * image is opened in read-only mode if the caller requested that. */ if (uOpenFlags & VD_OPEN_FLAGS_READONLY) { vciFreeImage(pCache, false); rc = vciOpenImage(pCache, uOpenFlags); if (RT_FAILURE(rc)) { RTMemFree(pCache); goto out; } } *ppBackendData = pCache; } else RTMemFree(pCache); out: LogFlowFunc(("returns %Rrc (pBackendData=%#p)\n", rc, *ppBackendData)); return rc; } /** @copydoc VDCACHEBACKEND::pfnClose */ static int vciClose(void *pBackendData, bool fDelete) { LogFlowFunc(("pBackendData=%#p fDelete=%d\n", pBackendData, fDelete)); PVCICACHE pCache = (PVCICACHE)pBackendData; int rc; rc = vciFreeImage(pCache, fDelete); RTMemFree(pCache); LogFlowFunc(("returns %Rrc\n", rc)); return rc; } /** @copydoc VDCACHEBACKEND::pfnRead */ static int vciRead(void *pBackendData, uint64_t uOffset, void *pvBuf, size_t cbToRead, size_t *pcbActuallyRead) { LogFlowFunc(("pBackendData=%#p uOffset=%llu pvBuf=%#p cbToRead=%zu pcbActuallyRead=%#p\n", pBackendData, uOffset, pvBuf, cbToRead, pcbActuallyRead)); PVCICACHE pCache = (PVCICACHE)pBackendData; int rc = VINF_SUCCESS; PVCICACHEEXTENT pExtent; uint64_t cBlocksToRead = VCI_BYTE2BLOCK(cbToRead); uint64_t offBlockAddr = VCI_BYTE2BLOCK(uOffset); AssertPtr(pCache); Assert(uOffset % 512 == 0); Assert(cbToRead % 512 == 0); pExtent = vciCacheExtentLookup(pCache, offBlockAddr, NULL); if (pExtent) { uint64_t offRead = offBlockAddr - pExtent->u64BlockOffset; cBlocksToRead = RT_MIN(cBlocksToRead, pExtent->u32Blocks - offRead); rc = vdIfIoIntFileReadSync(pCache->pIfIo, pCache->pStorage, pExtent->u64BlockAddr + offRead, pvBuf, cBlocksToRead); } else { /** @todo Best fit to check whether we have cached data later and set * pcbActuallyRead accordingly. */ rc = VERR_VD_BLOCK_FREE; } if (pcbActuallyRead) *pcbActuallyRead = VCI_BLOCK2BYTE(cBlocksToRead); out: LogFlowFunc(("returns %Rrc\n", rc)); return rc; } /** @copydoc VDCACHEBACKEND::pfnWrite */ static int vciWrite(void *pBackendData, uint64_t uOffset, const void *pvBuf, size_t cbToWrite, size_t *pcbWriteProcess) { LogFlowFunc(("pBackendData=%#p uOffset=%llu pvBuf=%#p cbToWrite=%zu pcbWriteProcess=%#p\n", pBackendData, uOffset, pvBuf, cbToWrite, pcbWriteProcess)); PVCICACHE pCache = (PVCICACHE)pBackendData; int rc = VINF_SUCCESS; uint64_t cBlocksToWrite = VCI_BYTE2BLOCK(cbToWrite); uint64_t offBlockAddr = VCI_BYTE2BLOCK(uOffset); PVCICACHEEXTENT pExtent; AssertPtr(pCache); Assert(uOffset % 512 == 0); Assert(cbToWrite % 512 == 0); while (cBlocksToWrite) { } *pcbWriteProcess = cbToWrite; /** @todo: Implement. */ out: LogFlowFunc(("returns %Rrc\n", rc)); return rc; } /** @copydoc VDCACHEBACKEND::pfnFlush */ static int vciFlush(void *pBackendData) { LogFlowFunc(("pBackendData=%#p\n", pBackendData)); PVCICACHE pCache = (PVCICACHE)pBackendData; int rc = VINF_SUCCESS; rc = vciFlushImage(pCache); LogFlowFunc(("returns %Rrc\n", rc)); return rc; } /** @copydoc VDCACHEBACKEND::pfnGetVersion */ static unsigned vciGetVersion(void *pBackendData) { LogFlowFunc(("pBackendData=%#p\n", pBackendData)); PVCICACHE pCache = (PVCICACHE)pBackendData; AssertPtr(pCache); if (pCache) return 1; else return 0; } /** @copydoc VDCACHEBACKEND::pfnGetSize */ static uint64_t vciGetSize(void *pBackendData) { LogFlowFunc(("pBackendData=%#p\n", pBackendData)); PVCICACHE pCache = (PVCICACHE)pBackendData; uint64_t cb = 0; AssertPtr(pCache); if (pCache && pCache->pStorage) cb = pCache->cbSize; LogFlowFunc(("returns %llu\n", cb)); return cb; } /** @copydoc VDCACHEBACKEND::pfnGetFileSize */ static uint64_t vciGetFileSize(void *pBackendData) { LogFlowFunc(("pBackendData=%#p\n", pBackendData)); PVCICACHE pCache = (PVCICACHE)pBackendData; uint64_t cb = 0; AssertPtr(pCache); if (pCache) { uint64_t cbFile; if (pCache->pStorage) { int rc = vdIfIoIntFileGetSize(pCache->pIfIo, pCache->pStorage, &cbFile); if (RT_SUCCESS(rc)) cb = cbFile; } } LogFlowFunc(("returns %lld\n", cb)); return cb; } /** @copydoc VDCACHEBACKEND::pfnGetImageFlags */ static unsigned vciGetImageFlags(void *pBackendData) { LogFlowFunc(("pBackendData=%#p\n", pBackendData)); PVCICACHE pCache = (PVCICACHE)pBackendData; unsigned uImageFlags; AssertPtr(pCache); if (pCache) uImageFlags = pCache->uImageFlags; else uImageFlags = 0; LogFlowFunc(("returns %#x\n", uImageFlags)); return uImageFlags; } /** @copydoc VDCACHEBACKEND::pfnGetOpenFlags */ static unsigned vciGetOpenFlags(void *pBackendData) { LogFlowFunc(("pBackendData=%#p\n", pBackendData)); PVCICACHE pCache = (PVCICACHE)pBackendData; unsigned uOpenFlags; AssertPtr(pCache); if (pCache) uOpenFlags = pCache->uOpenFlags; else uOpenFlags = 0; LogFlowFunc(("returns %#x\n", uOpenFlags)); return uOpenFlags; } /** @copydoc VDCACHEBACKEND::pfnSetOpenFlags */ static int vciSetOpenFlags(void *pBackendData, unsigned uOpenFlags) { LogFlowFunc(("pBackendData=%#p\n uOpenFlags=%#x", pBackendData, uOpenFlags)); PVCICACHE pCache = (PVCICACHE)pBackendData; int rc; /* Image must be opened and the new flags must be valid. Just readonly and * info flags are supported. */ if (!pCache || (uOpenFlags & ~(VD_OPEN_FLAGS_READONLY | VD_OPEN_FLAGS_INFO))) { rc = VERR_INVALID_PARAMETER; goto out; } /* Implement this operation via reopening the image. */ rc = vciFreeImage(pCache, false); if (RT_FAILURE(rc)) goto out; rc = vciOpenImage(pCache, uOpenFlags); out: LogFlowFunc(("returns %Rrc\n", rc)); return rc; } /** @copydoc VDCACHEBACKEND::pfnGetComment */ static int vciGetComment(void *pBackendData, char *pszComment, size_t cbComment) { LogFlowFunc(("pBackendData=%#p pszComment=%#p cbComment=%zu\n", pBackendData, pszComment, cbComment)); PVCICACHE pCache = (PVCICACHE)pBackendData; int rc; AssertPtr(pCache); if (pCache) rc = VERR_NOT_SUPPORTED; else rc = VERR_VD_NOT_OPENED; LogFlowFunc(("returns %Rrc comment='%s'\n", rc, pszComment)); return rc; } /** @copydoc VDCACHEBACKEND::pfnSetComment */ static int vciSetComment(void *pBackendData, const char *pszComment) { LogFlowFunc(("pBackendData=%#p pszComment=\"%s\"\n", pBackendData, pszComment)); PVCICACHE pCache = (PVCICACHE)pBackendData; int rc; AssertPtr(pCache); if (pCache) { if (pCache->uOpenFlags & VD_OPEN_FLAGS_READONLY) rc = VERR_VD_IMAGE_READ_ONLY; else rc = VERR_NOT_SUPPORTED; } else rc = VERR_VD_NOT_OPENED; out: LogFlowFunc(("returns %Rrc\n", rc)); return rc; } /** @copydoc VDCACHEBACKEND::pfnGetUuid */ static int vciGetUuid(void *pBackendData, PRTUUID pUuid) { LogFlowFunc(("pBackendData=%#p pUuid=%#p\n", pBackendData, pUuid)); PVCICACHE pCache = (PVCICACHE)pBackendData; int rc; AssertPtr(pCache); if (pCache) rc = VERR_NOT_SUPPORTED; else rc = VERR_VD_NOT_OPENED; LogFlowFunc(("returns %Rrc (%RTuuid)\n", rc, pUuid)); return rc; } /** @copydoc VDCACHEBACKEND::pfnSetUuid */ static int vciSetUuid(void *pBackendData, PCRTUUID pUuid) { LogFlowFunc(("pBackendData=%#p Uuid=%RTuuid\n", pBackendData, pUuid)); PVCICACHE pCache = (PVCICACHE)pBackendData; int rc; LogFlowFunc(("%RTuuid\n", pUuid)); AssertPtr(pCache); if (pCache) { if (!(pCache->uOpenFlags & VD_OPEN_FLAGS_READONLY)) rc = VERR_NOT_SUPPORTED; else rc = VERR_VD_IMAGE_READ_ONLY; } else rc = VERR_VD_NOT_OPENED; LogFlowFunc(("returns %Rrc\n", rc)); return rc; } /** @copydoc VDCACHEBACKEND::pfnGetModificationUuid */ static int vciGetModificationUuid(void *pBackendData, PRTUUID pUuid) { LogFlowFunc(("pBackendData=%#p pUuid=%#p\n", pBackendData, pUuid)); PVCICACHE pCache = (PVCICACHE)pBackendData; int rc; AssertPtr(pCache); if (pCache) rc = VERR_NOT_SUPPORTED; else rc = VERR_VD_NOT_OPENED; LogFlowFunc(("returns %Rrc (%RTuuid)\n", rc, pUuid)); return rc; } /** @copydoc VDCACHEBACKEND::pfnSetModificationUuid */ static int vciSetModificationUuid(void *pBackendData, PCRTUUID pUuid) { LogFlowFunc(("pBackendData=%#p Uuid=%RTuuid\n", pBackendData, pUuid)); PVCICACHE pCache = (PVCICACHE)pBackendData; int rc; AssertPtr(pCache); if (pCache) { if (!(pCache->uOpenFlags & VD_OPEN_FLAGS_READONLY)) rc = VERR_NOT_SUPPORTED; else rc = VERR_VD_IMAGE_READ_ONLY; } else rc = VERR_VD_NOT_OPENED; LogFlowFunc(("returns %Rrc\n", rc)); return rc; } /** @copydoc VDCACHEBACKEND::pfnDump */ static void vciDump(void *pBackendData) { NOREF(pBackendData); } /** @copydoc VDCACHEBACKEND::pfnAsyncRead */ static int vciAsyncRead(void *pBackendData, uint64_t uOffset, size_t cbRead, PVDIOCTX pIoCtx, size_t *pcbActuallyRead) { int rc = VERR_NOT_SUPPORTED; PVCICACHE pCache = (PVCICACHE)pBackendData; return rc; } /** @copydoc VDCACHEBACKEND::pfnAsyncWrite */ static int vciAsyncWrite(void *pBackendData, uint64_t uOffset, size_t cbWrite, PVDIOCTX pIoCtx, size_t *pcbWriteProcess) { int rc = VERR_NOT_SUPPORTED; PVCICACHE pCache = (PVCICACHE)pBackendData; return rc; } /** @copydoc VDCACHEBACKEND::pfnAsyncFlush */ static int vciAsyncFlush(void *pBackendData, PVDIOCTX pIoCtx) { int rc = VERR_NOT_SUPPORTED; PVCICACHE pCache = (PVCICACHE)pBackendData; return rc; } VDCACHEBACKEND g_VciCacheBackend = { /* pszBackendName */ "vci", /* cbSize */ sizeof(VDCACHEBACKEND), /* uBackendCaps */ VD_CAP_CREATE_FIXED | VD_CAP_CREATE_DYNAMIC | VD_CAP_FILE | VD_CAP_VFS, /* papszFileExtensions */ s_apszVciFileExtensions, /* paConfigInfo */ NULL, /* hPlugin */ NIL_RTLDRMOD, /* pfnProbe */ vciProbe, /* pfnOpen */ vciOpen, /* pfnCreate */ vciCreate, /* pfnClose */ vciClose, /* pfnRead */ vciRead, /* pfnWrite */ vciWrite, /* pfnFlush */ vciFlush, /* pfnGetVersion */ vciGetVersion, /* pfnGetSize */ vciGetSize, /* pfnGetFileSize */ vciGetFileSize, /* pfnGetImageFlags */ vciGetImageFlags, /* pfnGetOpenFlags */ vciGetOpenFlags, /* pfnSetOpenFlags */ vciSetOpenFlags, /* pfnGetComment */ vciGetComment, /* pfnSetComment */ vciSetComment, /* pfnGetUuid */ vciGetUuid, /* pfnSetUuid */ vciSetUuid, /* pfnGetModificationUuid */ vciGetModificationUuid, /* pfnSetModificationUuid */ vciSetModificationUuid, /* pfnDump */ vciDump, /* pfnAsyncRead */ vciAsyncRead, /* pfnAsyncWrite */ vciAsyncWrite, /* pfnAsyncFlush */ vciAsyncFlush, /* pfnComposeLocation */ NULL, /* pfnComposeName */ NULL };