/* * YAFFS: Yet another FFS. A NAND-flash specific file system. * yaffs_guts.h: Configuration etc for yaffs_guts * * Copyright (C) 2002 Aleph One Ltd. * for Toby Churchill Ltd and Brightstar Engineering * * Created by Charles Manning * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU Lesser General Public License version 2.1 as * published by the Free Software Foundation. * * * Note: Only YAFFS headers are LGPL, YAFFS C code is covered by GPL. * * $Id: yaffs_guts.h,v 1.4 2005/04/24 09:57:06 charles Exp $ */ #ifndef __YAFFS_GUTS_H__ #define __YAFFS_GUTS_H__ #include "devextras.h" #include "yportenv.h" #define YAFFS_OK 1 #define YAFFS_FAIL 0 // Give us a Y=0x59, // Give us an A=0x41, // Give us an FF=0xFF // Give us an S=0x53 // And what have we got... #define YAFFS_MAGIC 0x5941FF53 #define YAFFS_NTNODES_LEVEL0 16 #define YAFFS_TNODES_LEVEL0_BITS 4 #define YAFFS_TNODES_LEVEL0_MASK 0xf #define YAFFS_NTNODES_INTERNAL (YAFFS_NTNODES_LEVEL0 / 2) #define YAFFS_TNODES_INTERNAL_BITS (YAFFS_TNODES_LEVEL0_BITS - 1) #define YAFFS_TNODES_INTERNAL_MASK 0x7 #define YAFFS_TNODES_MAX_LEVEL 6 #ifndef CONFIG_YAFFS_NO_YAFFS1 #define YAFFS_BYTES_PER_SPARE 16 #define YAFFS_BYTES_PER_CHUNK 512 #define YAFFS_CHUNK_SIZE_SHIFT 9 #define YAFFS_CHUNKS_PER_BLOCK 32 #define YAFFS_BYTES_PER_BLOCK (YAFFS_CHUNKS_PER_BLOCK*YAFFS_BYTES_PER_CHUNK) #endif #define YAFFS_MIN_YAFFS2_CHUNK_SIZE 1024 #define YAFFS_MIN_YAFFS2_SPARE_SIZE 32 #define YAFFS_MAX_CHUNK_ID 0x000FFFFF #define YAFFS_UNUSED_OBJECT_ID 0x0003FFFF #define YAFFS_ALLOCATION_NOBJECTS 100 #define YAFFS_ALLOCATION_NTNODES 100 #define YAFFS_ALLOCATION_NLINKS 100 #define YAFFS_NOBJECT_BUCKETS 256 #define YAFFS_OBJECT_SPACE 0x40000 #ifdef CONFIG_YAFFS_UNICODE #define YAFFS_MAX_NAME_LENGTH 127 #define YAFFS_MAX_ALIAS_LENGTH 79 #else #define YAFFS_MAX_NAME_LENGTH 255 #define YAFFS_MAX_ALIAS_LENGTH 159 #endif #define YAFFS_SHORT_NAME_LENGTH 15 #define YAFFS_OBJECTID_ROOT 1 #define YAFFS_OBJECTID_LOSTNFOUND 2 #define YAFFS_OBJECTID_UNLINKED 3 #define YAFFS_OBJECTID_DELETED 4 #define YAFFS_MAX_SHORT_OP_CACHES 20 #define YAFFS_N_TEMP_BUFFERS 4 // Sequence numbers are used in YAFFS2 to determine block allocation order. // The range is limited slightly to help distinguish bad numbers from good. // This also allows us to perhaps in the future use special numbers for // special purposes. // EFFFFF00 allows the allocation of 8 blocks per second (~1Mbytes) for 15 years, // and is a larger number than the lifetime of a 2GB device. #define YAFFS_LOWEST_SEQUENCE_NUMBER 0x00001000 #define YAFFS_HIGHEST_SEQUENCE_NUMBER 0xEFFFFF00 // ChunkCache is used for short read/write operations. typedef struct { struct yaffs_ObjectStruct *object; int chunkId; int lastUse; int dirty; int nBytes; // Only valid if the cache is dirty int locked; // Can't push out or flush while locked.. #ifdef CONFIG_YAFFS_YAFFS2 __u8 *data; #else __u8 data[YAFFS_BYTES_PER_CHUNK]; #endif } yaffs_ChunkCache; #ifndef CONFIG_YAFFS_NO_YAFFS1 // Tags structures in RAM // NB This uses bitfield. Bitfields should not straddle a u32 boundary otherwise // the structure size will get blown out. typedef struct { unsigned chunkId:20; unsigned serialNumber:2; unsigned byteCount:10; unsigned objectId:18; unsigned ecc:12; unsigned unusedStuff:2; } yaffs_Tags; typedef union { yaffs_Tags asTags; __u8 asBytes[8]; } yaffs_TagsUnion; #endif typedef enum { YAFFS_ECC_RESULT_UNKNOWN, YAFFS_ECC_RESULT_NO_ERROR, YAFFS_ECC_RESULT_FIXED, YAFFS_ECC_RESULT_UNFIXED } yaffs_ECCResult; typedef enum { YAFFS_OBJECT_TYPE_UNKNOWN, YAFFS_OBJECT_TYPE_FILE, YAFFS_OBJECT_TYPE_SYMLINK, YAFFS_OBJECT_TYPE_DIRECTORY, YAFFS_OBJECT_TYPE_HARDLINK, YAFFS_OBJECT_TYPE_SPECIAL } yaffs_ObjectType; typedef struct { unsigned validMarker0; unsigned chunkUsed; // Status of the chunk: used or unused unsigned objectId; // If 0 then this is not part of an object (unused) unsigned chunkId; // If 0 then this is a header, else a data chunk unsigned byteCount; // Only valid for data chunks // The following stuff only has meaning when we read yaffs_ECCResult eccResult; // Only valid when we read. unsigned blockBad; // Only valid on reading // YAFFS 1 stuff unsigned chunkDeleted; // The chunk is marked deleted unsigned serialNumber; // Yaffs1 2-bit serial number // YAFFS2 stuff unsigned sequenceNumber; // The sequence number of this block // Extra info if this is an object header (YAFFS2 only) unsigned extraHeaderInfoAvailable; unsigned extraParentObjectId; unsigned extraIsShrinkHeader; yaffs_ObjectType extraObjectType; unsigned extraFileLength; unsigned extraEquivalentObjectId; unsigned validMarker1; } yaffs_ExtendedTags; #ifndef CONFIG_YAFFS_NO_YAFFS1 // Spare structure typedef struct { __u8 tagByte0; __u8 tagByte1; __u8 tagByte2; __u8 tagByte3; __u8 pageStatus; // set to 0 to delete the chunk __u8 blockStatus; __u8 tagByte4; __u8 tagByte5; __u8 ecc1[3]; __u8 tagByte6; __u8 tagByte7; __u8 ecc2[3]; } yaffs_Spare; //Special structure for passing through to mtd struct yaffs_NANDSpare { yaffs_Spare spare; int eccres1; int eccres2; }; #endif // Block data in RAM typedef enum { YAFFS_BLOCK_STATE_UNKNOWN = 0, YAFFS_BLOCK_STATE_SCANNING, YAFFS_BLOCK_STATE_NEEDS_SCANNING, // The block might have something on it (ie it is allocating or full, perhaps empty) // but it needs to be scanned to determine its true state. // This state is only valid during yaffs_Scan. // NB We tolerate empty because the pre-scanner might be incapable of deciding // However, if this state is returned on a YAFFS2 device, then we expect a sequence number YAFFS_BLOCK_STATE_EMPTY, // This block is empty YAFFS_BLOCK_STATE_ALLOCATING, // This block is partially allocated. // This is the one currently being used for page // allocation. Should never be more than one of these YAFFS_BLOCK_STATE_FULL, // All the pages in this block have been allocated. // At least one page holds valid data. YAFFS_BLOCK_STATE_DIRTY, // All pages have been allocated and deleted. // Erase me, reuse me. YAFFS_BLOCK_STATE_COLLECTING, // This block is being garbage collected YAFFS_BLOCK_STATE_DEAD // This block has failed and is not in use } yaffs_BlockState; typedef struct { int softDeletions:12; // number of soft deleted pages int pagesInUse:12; // number of pages in use yaffs_BlockState blockState:4; // One of the above block states __u32 needsRetiring:1; // Data has failed on this block, need to get valid data off // and retire the block. #ifdef CONFIG_YAFFS_YAFFS2 __u32 hasShrinkHeader:1;// This block has at least one object header that does a shrink __u32 sequenceNumber; // block sequence number for yaffs2 #endif } yaffs_BlockInfo; //////////////////// Object structure /////////////////////////// // This is the object structure as stored on NAND typedef struct { yaffs_ObjectType type; // Apply to everything int parentObjectId; __u16 sum__NoLongerUsed; // checksum of name. Calc this off the name to prevent inconsistencies char name[YAFFS_MAX_NAME_LENGTH + 1]; // Thes following apply to directories, files, symlinks - not hard links __u32 st_mode; // protection #ifdef CONFIG_YAFFS_WINCE __u32 notForWinCE[5]; #else __u32 st_uid; // user ID of owner __u32 st_gid; // group ID of owner __u32 st_atime; // time of last access __u32 st_mtime; // time of last modification __u32 st_ctime; // time of last change #endif // File size applies to files only int fileSize; // Equivalent object id applies to hard links only. int equivalentObjectId; // Alias is for symlinks only. char alias[YAFFS_MAX_ALIAS_LENGTH + 1]; __u32 st_rdev; // device stuff for block and char devices (maj/min) #ifdef CONFIG_YAFFS_WINCE __u32 win_ctime[2]; __u32 win_atime[2]; __u32 win_mtime[2]; __u32 roomToGrow[5]; #else __u32 roomToGrow[11]; #endif // isShrink applies to bject headers written when we shrink the file (ie resize) __u32 isShrink; } yaffs_ObjectHeader; //////////////////// Tnode /////////////////////////// union yaffs_Tnode_union { #ifdef CONFIG_YAFFS_TNODE_LIST_DEBUG union yaffs_Tnode_union *internal[YAFFS_NTNODES_INTERNAL+1]; #else union yaffs_Tnode_union *internal[YAFFS_NTNODES_INTERNAL]; #endif __u16 level0[YAFFS_NTNODES_LEVEL0]; }; typedef union yaffs_Tnode_union yaffs_Tnode; struct yaffs_TnodeList_struct { struct yaffs_TnodeList_struct *next; yaffs_Tnode *tnodes; }; typedef struct yaffs_TnodeList_struct yaffs_TnodeList; /////////////////// Object //////////////////////////////// // An object can be one of: // - a directory (no data, has children links // - a regular file (data.... not prunes :->). // - a symlink [symbolic link] (the alias). // - a hard link typedef struct { __u32 fileSize; __u32 scannedFileSize; __u32 shrinkSize; int topLevel; yaffs_Tnode *top; } yaffs_FileStructure; typedef struct { struct list_head children; // list of child links } yaffs_DirectoryStructure; typedef struct { char *alias; } yaffs_SymLinkStructure; typedef struct { struct yaffs_ObjectStruct *equivalentObject; __u32 equivalentObjectId; } yaffs_HardLinkStructure; typedef union { yaffs_FileStructure fileVariant; yaffs_DirectoryStructure directoryVariant; yaffs_SymLinkStructure symLinkVariant; yaffs_HardLinkStructure hardLinkVariant; } yaffs_ObjectVariant; struct yaffs_ObjectStruct { __u8 deleted: 1; // This should only apply to unlinked files. __u8 softDeleted: 1; // it has also been soft deleted __u8 unlinked: 1; // An unlinked file. The file should be in the unlinked pseudo directory. __u8 fake:1; // A fake object has no presence on NAND. __u8 renameAllowed:1; // Some objects are not allowed to be renamed. __u8 unlinkAllowed:1; __u8 dirty:1; // the object needs to be written to flash __u8 valid:1; // When the file system is being loaded up, this // object might be created before the data // is available (ie. file data records appear before the header). __u8 serial; // serial number of chunk in NAND. Store here so we don't have to __u8 deferedFree: 1; // For Linux kernel. Object is removed from NAND, but still in the inode cache. // Free of object is defered. __u8 lazyLoaded; // Vital info has been loaded from tags. Not all info available. // // read back the old one to update. __u16 sum; // sum of the name to speed searching struct yaffs_DeviceStruct *myDev; // The device I'm on struct list_head hashLink; // list of objects in this hash bucket struct list_head hardLinks; // all the equivalent hard linked objects // live on this list // directory structure stuff struct yaffs_ObjectStruct *parent; //my parent directory struct list_head siblings; // siblings in a directory // also used for linking up the free list // Where's my data in NAND? int chunkId; // where it lives int nDataChunks; __u32 objectId; // the object id value __u32 st_mode; // protection #ifdef CONFIG_YAFFS_SHORT_NAMES_IN_RAM char shortName[YAFFS_SHORT_NAME_LENGTH+1]; #endif #ifndef __KERNEL__ __u32 inUse; #endif #ifdef CONFIG_YAFFS_WINCE __u32 win_ctime[2]; __u32 win_mtime[2]; __u32 win_atime[2]; #else __u32 st_uid; // user ID of owner __u32 st_gid; // group ID of owner __u32 st_atime; // time of last access __u32 st_mtime; // time of last modification __u32 st_ctime; // time of last change #endif __u32 st_rdev; // device stuff for block and char devices #ifdef __KERNEL__ struct inode *myInode; #endif yaffs_ObjectType variantType; yaffs_ObjectVariant variant; }; typedef struct yaffs_ObjectStruct yaffs_Object; struct yaffs_ObjectList_struct { yaffs_Object *objects; struct yaffs_ObjectList_struct *next; }; typedef struct yaffs_ObjectList_struct yaffs_ObjectList; typedef struct { struct list_head list; int count; } yaffs_ObjectBucket; ///////////////////// Temporary buffers //////////////////// // These are chunk-sized working buffers. Each device has a few typedef struct { __u8 *buffer; int line; // track from whence this buffer was allocated int maxLine; } yaffs_TempBuffer; //////////////////// Device //////////////////////////////// struct yaffs_DeviceStruct { // Entry parameters set up way early. Yaffs sets up the rest. int nBytesPerChunk; // Should be a power of 2 >= 512 int nChunksPerBlock; // does not need to be a power of 2 int nBytesPerSpare; // spare area size int startBlock; // Start block we're allowed to use int endBlock; // End block we're allowed to use int nReservedBlocks; // We want this tuneable so that we can reduce // reserved blocks on NOR and RAM. int nShortOpCaches; // If <= 0, then short op caching is disabled, else // the number of short op caches (don't use too many). int useHeaderFileSize; // Flag to determine if we should use file sizes from the header int useNANDECC; // Flag to decide whether or not to use NANDECC void *genericDevice; // Pointer to device context // On an mtd this holds the mtd pointer. // NAND access functions (Must be set before calling YAFFS) int (*writeChunkToNAND)(struct yaffs_DeviceStruct *dev,int chunkInNAND, const __u8 *data, const yaffs_Spare *spare); int (*readChunkFromNAND)(struct yaffs_DeviceStruct *dev,int chunkInNAND, __u8 *data, yaffs_Spare *spare); int (*eraseBlockInNAND)(struct yaffs_DeviceStruct *dev,int blockInNAND); int (*initialiseNAND)(struct yaffs_DeviceStruct *dev); #ifdef CONFIG_YAFFS_YAFFS2 int (*writeChunkWithTagsToNAND)(struct yaffs_DeviceStruct *dev,int chunkInNAND, const __u8 *data, yaffs_ExtendedTags *tags); int (*readChunkWithTagsFromNAND)(struct yaffs_DeviceStruct *dev,int chunkInNAND, __u8 *data, yaffs_ExtendedTags *tags); int (*markNANDBlockBad)(struct yaffs_DeviceStruct *dev, int blockNo); int (*queryNANDBlock)(struct yaffs_DeviceStruct *dev, int blockNo, yaffs_BlockState *state, int *sequenceNumber); #endif int isYaffs2; // End of stuff that must be set before initialisation. // Runtime parameters. Set up by YAFFS. __u16 chunkGroupBits; // 0 for devices <= 32MB. else log2(nchunks) - 16 __u16 chunkGroupSize; // == 2^^chunkGroupBits #ifdef __KERNEL__ struct semaphore sem;// Semaphore for waiting on erasure. struct semaphore grossLock; // Gross locking semaphore __u8 * spareBuffer; // For mtdif2 use. Don't know the size of the buffer at compile time so we have to allocate it. void (*putSuperFunc)(struct super_block *sb); #endif int isMounted; // Block Info yaffs_BlockInfo *blockInfo; __u8 *chunkBits; // bitmap of chunks in use int chunkBitmapStride; // Number of bytes of chunkBits per block. // Must be consistent with nChunksPerBlock. int nErasedBlocks; int allocationBlock; // Current block being allocated off __u32 allocationPage; int allocationBlockFinder; // Used to search for next allocation block // Runtime state int nTnodesCreated; yaffs_Tnode *freeTnodes; int nFreeTnodes; yaffs_TnodeList *allocatedTnodeList; int nObjectsCreated; yaffs_Object *freeObjects; int nFreeObjects; yaffs_ObjectList *allocatedObjectList; yaffs_ObjectBucket objectBucket[YAFFS_NOBJECT_BUCKETS]; int nFreeChunks; int currentDirtyChecker; // Used to find current dirtiest block __u32 *gcCleanupList; // objects to delete at the end of a GC. // Operations since mount int nPageWrites; int nPageReads; int nBlockErasures; int nErasureFailures; int nGCCopies; int garbageCollections; int passiveGarbageCollections; int nRetriedWrites; int nRetiredBlocks; int eccFixed; int eccUnfixed; int tagsEccFixed; int tagsEccUnfixed; int nDeletions; int nUnmarkedDeletions; yaffs_Object *rootDir; yaffs_Object *lostNFoundDir; // Buffer areas for storing data to recover from write failures // __u8 bufferedData[YAFFS_CHUNKS_PER_BLOCK][YAFFS_BYTES_PER_CHUNK]; // yaffs_Spare bufferedSpare[YAFFS_CHUNKS_PER_BLOCK]; int bufferedBlock; // Which block is buffered here? int doingBufferedBlockRewrite; yaffs_ChunkCache *srCache; int srLastUse; int cacheHits; // Stuff for background deletion and unlinked files. yaffs_Object *unlinkedDir; // Directory where unlinked and deleted files live. yaffs_Object *deletedDir; // Directory where deleted objects are sent to disappear. yaffs_Object *unlinkedDeletion; // Current file being background deleted. int nDeletedFiles; // Count of files awaiting deletion; int nUnlinkedFiles; // Count of unlinked files. int nBackgroundDeletions; // Count of background deletions. //__u8 *localBuffer; yaffs_TempBuffer tempBuffer[YAFFS_N_TEMP_BUFFERS]; int maxTemp; int unmanagedTempAllocations; int unmanagedTempDeallocations; // yaffs2 runtime stuff unsigned sequenceNumber; //Sequence number of currently allocating block unsigned oldestDirtySequence; }; typedef struct yaffs_DeviceStruct yaffs_Device; // Function to manipulate block info static inline yaffs_BlockInfo* yaffs_GetBlockInfo(yaffs_Device *dev, int blk) { if(blk < dev->startBlock || blk > dev->endBlock) { T(YAFFS_TRACE_ERROR,(TSTR("**>> yaffs: getBlockInfo block %d is not valid\n"),blk)); YBUG(); } return &dev->blockInfo[blk - dev->startBlock]; } //////////// YAFFS Functions ////////////////// int yaffs_GutsInitialise(yaffs_Device *dev); void yaffs_Deinitialise(yaffs_Device *dev); int yaffs_GetNumberOfFreeChunks(yaffs_Device *dev); // Rename int yaffs_RenameObject(yaffs_Object *oldDir, const char *oldName, yaffs_Object *newDir, const char *newName); // generic Object functions int yaffs_Unlink(yaffs_Object *dir, const char *name); int yaffs_DeleteFile(yaffs_Object *obj); // Object access functions. int yaffs_GetObjectName(yaffs_Object *obj,char *name,int buffSize); int yaffs_GetObjectFileLength(yaffs_Object *obj); int yaffs_GetObjectInode(yaffs_Object *obj); unsigned yaffs_GetObjectType(yaffs_Object *obj); int yaffs_GetObjectLinkCount(yaffs_Object *obj); // Change inode attributes int yaffs_SetAttributes(yaffs_Object *obj, struct iattr *attr); int yaffs_GetAttributes(yaffs_Object *obj, struct iattr *attr); // File operations int yaffs_ReadDataFromFile(yaffs_Object *obj, __u8 *buffer, __u32 offset, int nBytes); int yaffs_WriteDataToFile(yaffs_Object *obj, const __u8 *buffer, __u32 offset, int nBytes); int yaffs_ResizeFile(yaffs_Object *obj, int newSize); yaffs_Object *yaffs_MknodFile(yaffs_Object *parent,const char *name, __u32 mode, __u32 uid, __u32 gid); int yaffs_FlushFile(yaffs_Object *obj,int updateTime); // Directory operations yaffs_Object *yaffs_MknodDirectory(yaffs_Object *parent,const char *name, __u32 mode, __u32 uid, __u32 gid); yaffs_Object *yaffs_FindObjectByName(yaffs_Object *theDir,const char *name); int yaffs_ApplyToDirectoryChildren(yaffs_Object *theDir,int (*fn)(yaffs_Object *)); yaffs_Object *yaffs_FindObjectByNumber(yaffs_Device *dev,__u32 number); // Link operations yaffs_Object *yaffs_Link(yaffs_Object *parent, const char *name, yaffs_Object *equivalentObject); yaffs_Object *yaffs_GetEquivalentObject(yaffs_Object *obj); // Symlink operations yaffs_Object *yaffs_MknodSymLink(yaffs_Object *parent, const char *name, __u32 mode, __u32 uid, __u32 gid, const char *alias); char *yaffs_GetSymlinkAlias(yaffs_Object *obj); // Special inodes (fifos, sockets and devices) yaffs_Object *yaffs_MknodSpecial(yaffs_Object *parent,const char *name, __u32 mode, __u32 uid, __u32 gid,__u32 rdev); // Special directories yaffs_Object *yaffs_Root(yaffs_Device *dev); yaffs_Object *yaffs_LostNFound(yaffs_Device *dev); #ifdef CONFIG_YAFFS_WINCE // CONFIG_YAFFS_WINCE special stuff void yfsd_WinFileTimeNow(__u32 target[2]); #endif #ifdef __KERNEL__ void yaffs_HandleDeferedFree(yaffs_Object *obj); #endif // Debug dump int yaffs_DumpObject(yaffs_Object *obj); void yaffs_GutsTest(yaffs_Device *dev); void yaffs_InitialiseTags(yaffs_ExtendedTags *tags); void yaffs_DeleteChunk(yaffs_Device *dev,int chunkId,int markNAND,int lyn); int yaffs_CheckFF(__u8 *buffer,int nBytes); #endif