/**************************************************************************** * drivers/mtd/smart.c * * Licensed to the Apache Software Foundation (ASF) under one or more * contributor license agreements. See the NOTICE file distributed with * this work for additional information regarding copyright ownership. The * ASF licenses this file to you under the Apache License, Version 2.0 (the * "License"); you may not use this file except in compliance with the * License. You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, WITHOUT * WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the * License for the specific language governing permissions and limitations * under the License. * ****************************************************************************/ /**************************************************************************** * Included Files ****************************************************************************/ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /**************************************************************************** * Pre-processor Definitions ****************************************************************************/ #if 0 /* Define to enable checking */ # define CONFIG_SMART_LOCAL_CHECKFREE #endif #define SMART_STATUS_COMMITTED 0x80 #define SMART_STATUS_RELEASED 0x40 #define SMART_STATUS_CRC 0x20 #define SMART_STATUS_SIZEBITS 0x1c #define SMART_STATUS_VERBITS 0x03 #if defined(CONFIG_SMART_CRC_16) #define SMART_STATUS_VERSION 0x02 #elif defined(CONFIG_SMART_CRC_32) #define SMART_STATUS_VERSION 0x03 #else #define SMART_STATUS_VERSION 0x01 #endif #define SMART_SECTSIZE_256 0x00 #define SMART_SECTSIZE_512 0x04 #define SMART_SECTSIZE_1024 0x08 #define SMART_SECTSIZE_2048 0x0c #define SMART_SECTSIZE_4096 0x10 #define SMART_SECTSIZE_8192 0x14 #define SMART_SECTSIZE_16384 0x18 #define SMART_FMT_STAT_UNKNOWN 0 #define SMART_FMT_STAT_FORMATTED 1 #define SMART_FMT_STAT_NOFMT 2 #define SMART_FMT_POS1 sizeof(struct smart_sect_header_s) #define SMART_FMT_POS2 (SMART_FMT_POS1 + 1) #define SMART_FMT_POS3 (SMART_FMT_POS1 + 2) #define SMART_FMT_POS4 (SMART_FMT_POS1 + 3) #define SMART_FMT_SIG1 'S' #define SMART_FMT_SIG2 'M' #define SMART_FMT_SIG3 'R' #define SMART_FMT_SIG4 'T' #define SMART_FMT_VERSION_POS (SMART_FMT_POS1 + 4) #define SMART_FMT_NAMESIZE_POS (SMART_FMT_POS1 + 5) #define SMART_FMT_ROOTDIRS_POS (SMART_FMT_POS1 + 6) #define SMARTFS_FMT_WEAR_POS 36 #define SMART_WEAR_LEVEL_FORMAT_SIG 32 #define SMART_PARTNAME_SIZE 4 #define SMART_FIRST_DIR_SECTOR 3 /* First root directory sector */ #define SMART_FIRST_ALLOC_SECTOR 12 /* First logical sector number * we will use for assignment * of requested alloc sectors. * All entries below this are * reserved (some for root dir * entries other for our use * such as format, sector, * etc.) */ #if defined(CONFIG_MTD_SMART_READAHEAD) || (defined(CONFIG_DRVR_WRITABLE) && \ defined(CONFIG_MTD_SMART_WRITEBUFFER)) # define SMART_HAVE_RWBUFFER 1 #endif #ifndef CONFIG_MTD_SMART_SECTOR_SIZE # define CONFIG_MTD_SMART_SECTOR_SIZE 1024 #endif #ifndef offsetof #define offsetof(type, member) ( (size_t) &( ( (type *) 0)->member)) #endif #define SMART_MAX_ALLOCS 10 #ifndef CONFIG_MTD_SMART_ALLOC_DEBUG #define smart_malloc(d, b, n) kmm_malloc(b) #define smart_zalloc(d, b, n) kmm_zalloc(b) #define smart_free(d, p) kmm_free(p) #endif #define SMART_WEAR_FULL_RELOCATE_THRESHOLD 8 #define SMART_WEAR_REORG_THRESHOLD 14 #define SMART_WEAR_MIN_LEVEL 5 #define SMART_WEAR_FORCE_REORG_THRESHOLD 1 #define SMART_WEAR_BIT_DIVIDE 1 #define SMART_WEAR_ZERO_MASK 0x0f #define SMART_WEAR_BLOCK_MASK 0x01 #define SMART_WEARFLAGS_FORCE_REORG 0x01 #define SMART_WEARFLAGS_WRITE_NEEDED 0x02 #define SET_BITMAP(m, n) do { (m)[(n) / 8] |= 1 << ((n) % 8); } while (0) #define CLR_BITMAP(m, n) do { (m)[(n) / 8] &= ~(1 << ((n) % 8)); } while (0) #define ISSET_BITMAP(m, n) ((m)[(n) / 8] & (1 << ((n) % 8))) #ifdef CONFIG_SMARTFS_ALIGNED_ACCESS # define SMARTFS_NEXTSECTOR(h) \ (uint16_t)((FAR const uint8_t *)(h)->nextsector)[1] << 8 | \ (uint16_t)((FAR const uint8_t *)(h)->nextsector)[0] # define SMARTFS_SET_NEXTSECTOR(h, v) \ do \ { \ ((FAR uint8_t *)(h)->nextsector)[0] = (v) & 0xff; \ ((FAR uint8_t *)(h)->nextsector)[1] = (v) >> 8; \ } while (0) #else # define SMARTFS_NEXTSECTOR(h) (*((FAR uint16_t *)(h)->nextsector)) # define SMARTFS_SET_NEXTSECTOR(h, v) \ do \ { \ ((*((FAR uint16_t *)(h)->nextsector)) = (uint16_t)(v)); \ } while (0) #endif #ifdef CONFIG_MTD_SMART_WEAR_LEVEL /**************************************************************************** * Private Data ****************************************************************************/ /* Bit mapping for wear level bits */ /* These are defined to allow updating the wear leveling with the minimum * number of sector relocations / maximum use of 1 --> 0 transitions when * incrementing the wear level. * * 0: 1111 8: 1011 * 1: 1110 9: 1010 * 2: 1100 10: 0010 * 3: 1000 11: 1101 * 4: 0111 12: 1001 * 5: 0110 13: 0001 * 6: 0100 14: 0011 * 7: 0000 15: 0101 */ static const uint8_t g_wearlevel_to_bitmap4[] = { 0x0f, 0x0e, 0x0c, 0x08, /* Single bit erased (x3) */ 0x07, 0x06, 0x04, 0x00, /* Single bit erased (x3) */ 0x0b, 0x0a, 0x02, /* Single bit erased (x2) */ 0x0d, 0x09, 0x01, /* Single bit erased (x2) */ 0x03, 0x05 }; /* Map a Wear Level bit pattern back to the wear level */ static const uint8_t g_wearbit_to_levelmap4[] = { 7, 13, 10, 14, 6, 15, 5, 4, 3, 12, 9, 8, 2, 11, 1, 0 }; #endif /**************************************************************************** * Private Types ****************************************************************************/ #ifdef CONFIG_MTD_SMART_MINIMIZE_RAM struct smart_cache_s { uint16_t logical; /* Logical sector number */ uint16_t physical; /* Associated physical sector */ uint16_t birth; /* The "birthday" of this entry */ }; #endif /* When CRC is enabled, we allocate sectors in memory only and only write * to the device when an actual writesector is performed. If during the * alloc process we do a physical write, we would either have to hold off on * writing the CRC value (which creates an invalid state on the device) or * we would have to perform a write, release re-write every time which would * increase the wear of the device 2x. */ #ifdef CONFIG_MTD_SMART_ENABLE_CRC struct smart_allocsector_s { struct smart_allocsector_s *next; /* Pointer to next alloc sector */ uint16_t logical; /* Logical sector number */ uint16_t physical; /* Associated physical sector */ }; #endif struct smart_struct_s { FAR struct mtd_dev_s *mtd; /* Contained MTD interface */ struct mtd_geometry_s geo; /* Device geometry */ #if defined(CONFIG_FS_PROCFS) && !defined(CONFIG_FS_PROCFS_EXCLUDE_SMARTFS) uint32_t unusedsectors; /* Count of unused sectors (i.e. free when erased) */ uint32_t blockerases; /* Count of unused sectors (i.e. free when erased) */ #endif uint16_t neraseblocks; /* Number of erase blocks or sub-sectors */ uint16_t lastallocblock; /* Last block we allocated a sector from */ uint16_t freesectors; /* Total number of free sectors */ uint16_t releasesectors; /* Total number of released sectors */ uint16_t mtdblkspersector; /* Number of MTD blocks per SMART Sector */ uint16_t sectorsperblk; /* Number of sectors per erase block */ uint16_t sectorsize; /* Sector size on device */ uint16_t totalsectors; /* Total number of sectors on device */ uint32_t erasesize; /* Size of an erase block */ FAR uint8_t *releasecount; /* Count of released sectors per erase block */ FAR uint8_t *freecount; /* Count of free sectors per erase block */ FAR char *rwbuffer; /* Our sector read/write buffer */ char partname[SMART_PARTNAME_SIZE]; uint8_t formatversion; /* Format version on the device */ uint8_t formatstatus; /* Indicates the status of the device format */ uint8_t namesize; /* Length of filenames on this device */ uint8_t debuglevel; /* Debug reporting level */ uint8_t availsectperblk; /* Number of usable sectors per erase block */ #ifdef CONFIG_SMARTFS_MULTI_ROOT_DIRS uint8_t rootdirentries; /* Number of root directory entries */ uint8_t minor; /* Minor number of the block entry */ #endif #ifdef CONFIG_MTD_SMART_WEAR_LEVEL uint8_t wearflags; /* Indicates force erase of static blocks needed */ uint8_t minwearlevel; /* Min level in the wear level bits */ uint8_t maxwearlevel; /* Max level in the wear level bits */ uint8_t *wearstatus; /* Array of wear leveling bits */ uint32_t uneven_wearcount; /* Number of times the wear level has gone over max */ #endif #ifdef CONFIG_MTD_SMART_ENABLE_CRC FAR struct smart_allocsector_s *allocsector; /* Pointer to first alloc sector */ #endif #ifndef CONFIG_MTD_SMART_MINIMIZE_RAM FAR uint16_t *smap; /* Virtual to physical sector map */ #else FAR uint8_t *sbitmap; /* Virtual sector used bit-map */ FAR struct smart_cache_s *scache; /* Sector cache */ uint16_t cache_entries; /* Number of valid entries in the cache */ uint16_t cache_lastlog; /* Keep track of the last sector accessed */ uint16_t cache_lastphys; /* Keep the physical sector number also */ uint16_t cache_nextbirth; /* Sector cache aging value */ #endif #ifdef CONFIG_MTD_SMART_SECTOR_ERASE_DEBUG FAR uint8_t *erasecounts; /* Number of erases for each erase block */ #endif #ifdef CONFIG_MTD_SMART_ALLOC_DEBUG size_t bytesalloc; struct smart_alloc_s alloc[SMART_MAX_ALLOCS]; /* Array of memory allocations */ #endif }; #ifdef CONFIG_SMARTFS_MULTI_ROOT_DIRS struct smart_multiroot_device_s { FAR struct smart_struct_s *dev; uint8_t rootdirnum; }; #endif /* Format 1 sector header definition */ #if SMART_STATUS_VERSION == 1 #define SMART_FMT_VERSION 1 struct smart_sect_header_s { uint8_t logicalsector[2]; /* The logical sector number */ uint8_t seq; /* Incrementing sequence number */ uint8_t crc8; /* CRC-8 or seq number MSB */ uint8_t status; /* Status of this sector: * Bit 7: 1 = Not committed * 0 = committed * Bit 6: 1 = Not released * 0 = released * Bit 5: Sector CRC enable * Bit 4-2: Sector size on volume * Bit 1-0: Format version (0x1) */ }; typedef uint8_t crc_t; /* Format 2 sector header definition. This is for a 16-bit CRC */ #elif SMART_STATUS_VERSION == 2 #define SMART_FMT_VERSION 2 struct smart_sect_header_s { uint8_t logicalsector[2]; /* The logical sector number */ uint8_t crc16[2]; /* CRC-16 for this sector */ uint8_t status; /* Status of this sector: * Bit 7: 1 = Not committed * 0 = committed * Bit 6: 1 = Not released * 0 = released * Bit 5: Sector CRC enable * Bit 4-2: Sector size on volume * Bit 1-0: Format version (0x2) */ uint8_t seq; /* Incrementing sequence number */ }; typedef uint16_t crc_t; /* Format 3 (32-bit) sector header definition. Actually, this format * isn't used yet and will likely be changed to a format to support * NAND devices (possibly with an 18-bit sector size, allowing up to * 256K sectors on a larger NAND device, though this would take a fair * amount of RAM for management). */ #elif SMART_STATUS_VERSION == 3 #error "32-Bit mode not supported yet" #define SMART_FMT_VERSION 3 struct smart_sect_header_s { uint8_t logicalsector[4]; /* The logical sector number */ uint8_t crc32[4]; /* CRC-32 for this sector */ uint8_t status; /* Status of this sector: * Bit 7: 1 = Not committed * 0 = committed * Bit 6: 1 = Not released * 0 = released * Bit 5: Sector CRC enable * Bit 4-2: Sector size on volume * Bit 1-0: Format version (0x3) */ uint8_t seq; /* Incrementing sequence number */ }; typedef uint32_t crc_t; #endif /* Following two definitions copied from internal definition of fs/smartfs. * Because needed to search chain_header and entry_header. */ #if defined(CONFIG_MTD_SMART_ENABLE_CRC) && defined(CONFIG_SMART_CRC_32) struct smart_chain_header_s { uint8_t nextsector[4]; /* Next logical sector in the chain */ uint8_t used[4]; /* Number of bytes used in this sector */ uint8_t type; /* Type of sector entry (file or dir) */ }; #else struct smart_chain_header_s { uint8_t type; /* Type of sector entry (file or dir) */ uint8_t nextsector[2]; /* Next logical sector in the chain */ uint8_t used[2]; /* Number of bytes used in this sector */ }; #endif struct smart_entry_header_s { uint16_t flags; /* Flags, including permissions: * 15: Empty entry * 14: Active entry * 12-0: Permissions bits */ int16_t firstsector; /* Sector number of the name */ uint32_t utc; /* Time stamp */ }; /**************************************************************************** * Private Function Prototypes ****************************************************************************/ static int smart_open(FAR struct inode *inode); static int smart_close(FAR struct inode *inode); static ssize_t smart_reload(struct smart_struct_s *dev, FAR uint8_t *buffer, off_t startblock, size_t nblocks); static ssize_t smart_read(FAR struct inode *inode, unsigned char *buffer, blkcnt_t start_sector, unsigned int nsectors); static ssize_t smart_write(FAR struct inode *inode, FAR const unsigned char *buffer, blkcnt_t start_sector, unsigned int nsectors); static int smart_geometry(FAR struct inode *inode, FAR struct geometry *geometry); static int smart_ioctl(FAR struct inode *inode, int cmd, unsigned long arg); static int smart_findfreephyssector(FAR struct smart_struct_s *dev, uint8_t canrelocate); static int smart_writesector(FAR struct smart_struct_s *dev, unsigned long arg); static inline int smart_allocsector(FAR struct smart_struct_s *dev, unsigned long requested); static int smart_readsector(FAR struct smart_struct_s *dev, unsigned long arg); #ifdef CONFIG_MTD_SMART_ENABLE_CRC static int smart_validate_crc(FAR struct smart_struct_s *dev); #endif #ifdef CONFIG_MTD_SMART_WEAR_LEVEL static int smart_read_wearstatus(FAR struct smart_struct_s *dev); static int smart_relocate_static_data(FAR struct smart_struct_s *dev, uint16_t block); #endif static int smart_relocate_sector(FAR struct smart_struct_s *dev, uint16_t oldsector, uint16_t newsector); #ifdef CONFIG_MTD_SMART_FSCK static int smart_fsck(FAR struct smart_struct_s *dev); #endif #ifdef CONFIG_SMART_DEV_LOOP static ssize_t smart_loop_read(FAR struct file *filep, FAR char *buffer, size_t buflen); static ssize_t smart_loop_write(FAR struct file *filep, FAR const char *buffer, size_t buflen); static int smart_loop_ioctl(FAR struct file *filep, int cmd, unsigned long arg); #endif /* CONFIG_SMART_DEV_LOOP */ /**************************************************************************** * Private Data ****************************************************************************/ static const struct block_operations g_bops = { smart_open, /* open */ smart_close, /* close */ smart_read, /* read */ smart_write, /* write */ smart_geometry, /* geometry */ smart_ioctl /* ioctl */ }; #ifdef CONFIG_SMART_DEV_LOOP static const struct file_operations g_fops = { NULL, /* open */ NULL, /* close */ smart_loop_read, /* read */ smart_loop_write, /* write */ NULL, /* seek */ smart_loop_ioctl, /* ioctl */ }; #endif /* CONFIG_SMART_DEV_LOOP */ /**************************************************************************** * Private Functions ****************************************************************************/ /**************************************************************************** * Name: smart_open * * Description: Open the block device * ****************************************************************************/ static int smart_open(FAR struct inode *inode) { finfo("Entry\n"); return OK; } /**************************************************************************** * Name: smart_close * * Description: close the block device * ****************************************************************************/ static int smart_close(FAR struct inode *inode) { finfo("Entry\n"); return OK; } /**************************************************************************** * Name: smart_malloc * * Description: Perform allocations and keep track of amount of allocated * memory for this context. * ****************************************************************************/ #ifdef CONFIG_MTD_SMART_ALLOC_DEBUG FAR static void *smart_malloc(FAR struct smart_struct_s *dev, size_t bytes, const char *name) { FAR void *ret = kmm_malloc(bytes); uint8_t x; /* Test if we are allocating the dev struct */ if (dev == NULL) { dev = ret; dev->bytesalloc = 0; for (x = 0; x < SMART_MAX_ALLOCS; x++) { dev->alloc[x].ptr = NULL; } } /* Keep track of the total allocation */ if (ret != NULL) { dev->bytesalloc += bytes; } /* Keep track of individual allocs */ for (x = 0; x < SMART_MAX_ALLOCS; x++) { if (dev->alloc[x].ptr == NULL) { dev->alloc[x].ptr = ret; dev->alloc[x].size = bytes; dev->alloc[x].name = name; break; } } finfo("SMART alloc: %ld\n", dev->bytesalloc); return ret; } #endif /**************************************************************************** * Name: smart_zalloc * * Description: Perform allocations and keep track of amount of allocated * memory for this context. * ****************************************************************************/ #ifdef CONFIG_MTD_SMART_ALLOC_DEBUG FAR static void *smart_zalloc(FAR struct smart_struct_s *dev, size_t bytes, const char *name) { void *mem; mem = smart_malloc(dev, bytes, name); if (mem != NULL) { memset(mem, 0, bytes); } return mem; } #endif /**************************************************************************** * Name: smart_free * * Description: Perform smart memory free operation. * ****************************************************************************/ #ifdef CONFIG_MTD_SMART_ALLOC_DEBUG static void smart_free(FAR struct smart_struct_s *dev, FAR void *ptr) { uint8_t x; for (x = 0; x < SMART_MAX_ALLOCS; x++) { if (dev->alloc[x].ptr == ptr) { dev->alloc[x].ptr = NULL; dev->bytesalloc -= dev->alloc[x].size; kmm_free(ptr); break; } } } #endif /**************************************************************************** * Name: smart_set_count * * Description: Set either the freecount or releasecount value for the * specified eraseblock (depending on which pointer is passed). * ****************************************************************************/ #ifdef CONFIG_MTD_SMART_PACK_COUNTS static void smart_set_count(FAR struct smart_struct_s *dev, FAR uint8_t *pcount, uint16_t block, uint8_t count) { if (dev->sectorsperblk > 16) { pcount[block] = count; } else { /* Save the lower 4 bits of the count in a shared byte */ if (block & 0x01) { pcount[block >> 1] = (pcount[block >> 1] & 0xf0) | (count & 0x0f); } else { pcount[block >> 1] = (pcount[block >> 1] & 0x0f) | ((count & 0x0f) << 4); } /* If we have 16 sectors per block, then the upper bit (representing * 16) all get packed into shared bytes. */ if (dev->sectorsperblk == 16) { if (count == 16) { pcount[(dev->geo.neraseblocks >> 1) + (block >> 3)] |= 1 << (block & 0x07); } else { pcount[(dev->geo.neraseblocks >> 1) + (block >> 3)] &= ~(1 << (block & 0x07)); } } } } #endif /**************************************************************************** * Name: smart_get_count * * Description: Get either the freecount or releasecount value for the * specified eraseblock (depending on which pointer is passed). * ****************************************************************************/ #ifdef CONFIG_MTD_SMART_PACK_COUNTS static uint8_t smart_get_count(FAR struct smart_struct_s *dev, FAR uint8_t *pcount, uint16_t block) { uint8_t count; if (dev->sectorsperblk > 16) { count = pcount[block]; } else { /* Save the lower 4 bits of the count in a shared byte */ if (block & 0x01) { count = pcount[block >> 1] & 0x0f; } else { count = pcount[block >> 1] >> 4; } /* If we have 16 sectors per block, then the upper bit (representing * 16) all get packed into shared bytes. */ if (dev->sectorsperblk == 16) { if (pcount[(dev->geo.neraseblocks >> 1) + (block >> 3)] & (1 << (block & 0x07))) { count |= 0x10; } } } return count; } #endif /**************************************************************************** * Name: smart_add_count * * Description: Add the specified value to and eraseblock count. * ****************************************************************************/ #ifdef CONFIG_MTD_SMART_PACK_COUNTS static void smart_add_count(struct smart_struct_s *dev, uint8_t *pcount, uint16_t block, int adder) { int16_t value; value = smart_get_count(dev, pcount, block) + adder; smart_set_count(dev, pcount, block, value); } #endif /**************************************************************************** * Name: smart_checkfree * * Description: A debug routine for validating the free sector count used * during development of the wear leveling code. * ****************************************************************************/ #ifdef CONFIG_SMART_LOCAL_CHECKFREE int smart_checkfree(FAR struct smart_struct_s *dev, int lineno) { uint16_t x; uint16_t freecount; #ifdef CONFIG_DEBUG_FS uint16_t blockfree; uint16_t blockrelease; static uint16_t prev_freesectors = 0; static uint16_t prev_releasesectors = 0; static uint8_t *prev_freecount = NULL; static uint8_t *prev_releasecount = NULL; #endif freecount = 0; for (x = 0; x < dev->neraseblocks; x++) { #ifdef CONFIG_MTD_SMART_PACK_COUNTS freecount += smart_get_count(dev, dev->freecount, x); #else freecount += dev->freecount[x]; #endif } /* Test if the calculated freesectors equals the reported value */ #ifdef CONFIG_DEBUG_FS if (freecount != dev->freesectors) { fwarn("WARNING: Free count incorrect in line %d! Calculated=%d, " "dev->freesectors=%d\n", lineno, freecount, dev->freesectors); /* Determine what changed from the last time which caused this error */ fwarn(" ... Prev freesectors=%d, prev releasesectors=%d\n", prev_freesectors, prev_releasesectors); if (prev_freecount) { for (x = 0; x < dev->neraseblocks; x++) { #ifdef CONFIG_MTD_SMART_PACK_COUNTS blockfree = smart_get_count(dev, dev->freecount, x); blockrelease = smart_get_count(dev, dev->releasecount, x); #else blockfree = dev->freecount[x]; blockrelease = dev->releasecount[x]; #endif if (prev_freecount[x] != blockfree || prev_releasecount[x] != blockrelease) { /* This block's values are different from the last time ... * report it. */ fwarn(" ... Block %d: Old Free=%d, old release=%d, " "New free=%d, new release = %d\n", x, prev_freecount[x], prev_releasecount[x], blockfree, blockrelease); } } } /* Modify the freesector count to reflect the actual calculated * freecount to get us back in line. */ dev->freesectors = freecount; return -EIO; } /* Make a copy of the freecount and releasecount arrays to compare the * differences between successive calls so we can evaluate what changed * in the event an error is detected. */ if (prev_freecount == NULL) { prev_freecount = (FAR uint8_t *) smart_malloc(dev, dev->neraseblocks << 1, "Free backup"); prev_releasecount = prev_freecount + dev->neraseblocks; } if (prev_freecount != NULL) { for (x = 0; x < dev->neraseblocks; x++) { #ifdef CONFIG_MTD_SMART_PACK_COUNTS prev_freecount[x] = smart_get_count(dev, dev->freecount, x); prev_releasecount[x] = smart_get_count(dev, dev->releasecount, x); #else prev_freecount[x] = dev->freecount[x]; prev_releasecount[x] = dev->releasecount[x]; #endif } } /* Save the previous freesectors count */ prev_freesectors = dev->freesectors; prev_releasesectors = dev->releasesectors; #endif return OK; } #endif /**************************************************************************** * Name: smart_reload * * Description: Read the specified number of sectors * ****************************************************************************/ static ssize_t smart_reload(struct smart_struct_s *dev, FAR uint8_t *buffer, off_t startblock, size_t nblocks) { ssize_t nread; ssize_t mtdblocks; ssize_t mtdstartblock; /* Calculate the number of MTD blocks to read */ mtdblocks = nblocks * dev->mtdblkspersector; /* Calculate the first MTD block number */ mtdstartblock = startblock * dev->mtdblkspersector; /* Read the full erase block into the buffer */ finfo("Read %zu blocks starting at block %zu\n", mtdblocks, mtdstartblock); nread = MTD_BREAD(dev->mtd, mtdstartblock, mtdblocks, buffer); if (nread != mtdblocks) { ferr("ERROR: Read %zd blocks starting at block %" PRIdOFF " failed: %zd\n", nblocks, startblock, nread); } return nread; } /**************************************************************************** * Name: smart_read * * Description: Read the specified number of sectors * ****************************************************************************/ static ssize_t smart_read(FAR struct inode *inode, unsigned char *buffer, blkcnt_t start_sector, unsigned int nsectors) { FAR struct smart_struct_s *dev; finfo("SMART: sector: %" PRIuOFF " nsectors: %u\n", start_sector, nsectors); DEBUGASSERT(inode && inode->i_private); #ifdef CONFIG_SMARTFS_MULTI_ROOT_DIRS dev = ((FAR struct smart_multiroot_device_s *)inode->i_private)->dev; #else dev = (struct smart_struct_s *)inode->i_private; #endif return smart_reload(dev, buffer, start_sector, nsectors); } /**************************************************************************** * Name: smart_write * * Description: Write (or buffer) the specified number of sectors * ****************************************************************************/ static ssize_t smart_write(FAR struct inode *inode, FAR const unsigned char *buffer, blkcnt_t start_sector, unsigned int nsectors) { FAR struct smart_struct_s *dev; off_t alignedblock; off_t mask; off_t blkstowrite; off_t offset; off_t nextblock; off_t mtdblkspererase; off_t eraseblock; size_t remaining; size_t nxfrd; int ret; off_t mtdstartblock; off_t mtdblockcount; finfo("sector: %" PRIuOFF " nsectors: %u\n", start_sector, nsectors); DEBUGASSERT(inode && inode->i_private); #ifdef CONFIG_SMARTFS_MULTI_ROOT_DIRS dev = ((FAR struct smart_multiroot_device_s *)inode->i_private)->dev; #else dev = (FAR struct smart_struct_s *)inode->i_private; #endif /* I think maybe we need to lock on a mutex here */ /* Get the aligned block. Here is is assumed: (1) The number of R/W blocks * per erase block is a power of 2, and (2) the erase begins with that same * alignment. */ mask = dev->sectorsperblk - 1; alignedblock = ((start_sector + mask) & ~mask) * dev->mtdblkspersector; /* Convert SMART blocks into MTD blocks */ mtdstartblock = start_sector * dev->mtdblkspersector; mtdblockcount = nsectors * dev->mtdblkspersector; mtdblkspererase = dev->mtdblkspersector * dev->sectorsperblk; finfo("mtdsector: %" PRIdOFF " mtdnsectors: %" PRIdOFF "\n", mtdstartblock, mtdblockcount); /* Start at first block to be written */ remaining = mtdblockcount; nextblock = mtdstartblock; offset = 0; /* Loop for all blocks to be written */ while (remaining > 0) { /* If this is an aligned block, then erase the block */ if (alignedblock == nextblock) { /* Erase the erase block */ eraseblock = alignedblock / mtdblkspererase; ret = MTD_ERASE(dev->mtd, eraseblock, 1); if (ret < 0) { ferr("ERROR: Erase block=%" PRIdOFF " failed: %d\n", eraseblock, ret); /* Unlock the mutex if we add one */ return ret; } } /* Calculate the number of blocks to write. */ blkstowrite = mtdblkspererase; if (nextblock != alignedblock) { blkstowrite = alignedblock - nextblock; } if (blkstowrite > remaining) { blkstowrite = remaining; } /* Try to write to the sector. */ finfo("Write MTD block %" PRIdOFF " from offset %" PRIdOFF "\n", nextblock, offset); nxfrd = MTD_BWRITE(dev->mtd, nextblock, blkstowrite, &buffer[offset]); if (nxfrd != blkstowrite) { /* The block is not empty!! What to do? */ ferr("ERROR: Write block %" PRIdOFF " failed: %zd.\n", nextblock, nxfrd); /* Unlock the mutex if we add one */ return -EIO; } /* Then update for amount written */ nextblock += blkstowrite; remaining -= blkstowrite; offset += blkstowrite * dev->geo.blocksize; alignedblock += mtdblkspererase; } return nsectors; } /**************************************************************************** * Name: smart_geometry * * Description: Return device geometry * ****************************************************************************/ static int smart_geometry(FAR struct inode *inode, struct geometry *geometry) { FAR struct smart_struct_s *dev; uint32_t erasesize; finfo("Entry\n"); DEBUGASSERT(inode); if (geometry) { #ifdef CONFIG_SMARTFS_MULTI_ROOT_DIRS dev = ((FAR struct smart_multiroot_device_s *)inode->i_private)->dev; #else dev = (FAR struct smart_struct_s *)inode->i_private; #endif geometry->geo_available = true; geometry->geo_mediachanged = false; geometry->geo_writeenabled = true; erasesize = dev->geo.erasesize; geometry->geo_nsectors = dev->geo.neraseblocks * erasesize / dev->sectorsize; geometry->geo_sectorsize = dev->sectorsize; strlcpy(geometry->geo_model, dev->geo.model, sizeof(geometry->geo_model)); finfo("available: true mediachanged: false writeenabled: %s\n", geometry->geo_writeenabled ? "true" : "false"); finfo("nsectors: %" PRIuOFF " sectorsize: %" PRIi16 "\n", geometry->geo_nsectors, geometry->geo_sectorsize); return OK; } return -EINVAL; } /**************************************************************************** * Name: smart_setsectorsize * * Description: Sets the device's sector size and recalculates sector size * dependent variables. * ****************************************************************************/ static int smart_setsectorsize(FAR struct smart_struct_s *dev, uint16_t size) { uint32_t erasesize; uint32_t totalsectors; uint32_t allocsize; /* Validate the size isn't zero so we don't divide by zero below */ if (size == 0) { size = CONFIG_MTD_SMART_SECTOR_SIZE; } if (size == dev->sectorsize) { return OK; } erasesize = dev->geo.erasesize; dev->neraseblocks = dev->geo.neraseblocks; dev->erasesize = erasesize; dev->sectorsize = size; dev->mtdblkspersector = dev->sectorsize / dev->geo.blocksize; DEBUGASSERT(dev->sectorsize >= dev->geo.blocksize); DEBUGASSERT(erasesize / dev->sectorsize <= 256); if (erasesize / dev->sectorsize > 256) { /* We can't throw a error message here because it is too early. * set the erasesize to zero and exit, then we will detect * it during mksmartfs or mount. */ dev->erasesize = 0; dev->sectorsperblk = 256; dev->availsectperblk = 255; } else { /* Set the sectors per erase block and available sectors per erase * block */ dev->sectorsperblk = erasesize / dev->sectorsize; if (dev->sectorsperblk == 256) { dev->availsectperblk = 255; } else if (dev->sectorsperblk == 0) { return -EINVAL; } else { dev->availsectperblk = dev->sectorsperblk; } } #if defined(CONFIG_FS_PROCFS) && !defined(CONFIG_FS_PROCFS_EXCLUDE_SMARTFS) dev->unusedsectors = 0; dev->blockerases = 0; #endif /* Release any existing rwbuffer and smap */ #ifndef CONFIG_MTD_SMART_MINIMIZE_RAM if (dev->smap != NULL) { smart_free(dev, dev->smap); dev->smap = NULL; } #else if (dev->sbitmap != NULL) { smart_free(dev, dev->sbitmap); dev->sbitmap = NULL; } dev->cache_entries = 0; dev->cache_lastlog = 0xffff; dev->cache_nextbirth = 0; #endif if (dev->rwbuffer != NULL) { smart_free(dev, dev->rwbuffer); dev->rwbuffer = NULL; } #ifdef CONFIG_MTD_SMART_WEAR_LEVEL if (dev->wearstatus != NULL) { smart_free(dev, dev->wearstatus); dev->wearstatus = NULL; } #endif /* Allocate a virtual to physical sector map buffer. Also allocate * the storage space for releasecount and freecounts. */ totalsectors = dev->neraseblocks * dev->sectorsperblk; /* Validate the number of total sectors is small enough for a uint16_t */ if (totalsectors > 65536) { ferr("ERROR: Invalid SMART sector count %" PRIu32 "\n", totalsectors); return -EINVAL; } else if (totalsectors == 65536) { /* Special case. We allow 65536 sectors and simply waste 2 sectors * to allow a smaller sector size with almost maximum flash usage. */ totalsectors -= 2; } dev->totalsectors = (uint16_t) totalsectors; #ifndef CONFIG_MTD_SMART_MINIMIZE_RAM allocsize = dev->neraseblocks << 1; dev->smap = (FAR uint16_t *) smart_malloc(dev, totalsectors * sizeof(uint16_t) + allocsize, "Sector map"); if (!dev->smap) { ferr("ERROR: Error allocating SMART virtual map buffer\n"); goto errexit; } dev->releasecount = (FAR uint8_t *) dev->smap + (totalsectors * sizeof(uint16_t)); dev->freecount = dev->releasecount + dev->neraseblocks; #else dev->sbitmap = (FAR uint8_t *) smart_malloc(dev, (totalsectors + 7) >> 3, "Sector Bitmap"); if (dev->sbitmap == NULL) { ferr("ERROR: Error allocating SMART sector cache\n"); goto errexit; } /* Calculate the alloc size of the freesector and release sector arrays */ #ifdef CONFIG_MTD_SMART_PACK_COUNTS if (dev->sectorsperblk > 16) { allocsize = dev->neraseblocks << 1; } else if (dev->sectorsperblk == 16) { allocsize = dev->neraseblocks + (dev->neraseblocks >> 2); } else { allocsize = dev->neraseblocks; } #else allocsize = dev->neraseblocks << 1; #endif /* Allocate the sector cache */ if (dev->scache == NULL) { dev->scache = (FAR struct smart_cache_s *) smart_malloc(dev, CONFIG_MTD_SMART_SECTOR_CACHE_SIZE * sizeof(struct smart_cache_s) + allocsize, "Sector Cache"); } if (!dev->scache) { ferr("ERROR: Error allocating SMART sector cache\n"); goto errexit; } dev->releasecount = (FAR uint8_t *)dev->scache + (CONFIG_MTD_SMART_SECTOR_CACHE_SIZE * sizeof(struct smart_cache_s)); #ifdef CONFIG_MTD_SMART_PACK_COUNTS if (dev->sectorsperblk > 16) { dev->freecount = dev->releasecount + dev->neraseblocks; } else if (dev->sectorsperblk == 16) { dev->freecount = dev->releasecount + (dev->neraseblocks >> 1) + (dev->neraseblocks >> 3); } else { dev->freecount = dev->releasecount + (dev->neraseblocks >> 1); } #else dev->freecount = dev->releasecount + dev->neraseblocks; #endif #endif /* CONFIG_MTD_SMART_MINIMIZE_RAM */ #ifdef CONFIG_MTD_SMART_SECTOR_ERASE_DEBUG /* Allocate a buffer to hold the erase counts */ if (dev->erasecounts == NULL) { dev->erasecounts = (FAR uint8_t *) smart_malloc(dev, dev->neraseblocks, "Erase counts"); } if (!dev->erasecounts) { ferr("ERROR: Error allocating erase count array\n"); goto errexit; } memset(dev->erasecounts, 0, dev->neraseblocks); #endif #ifdef CONFIG_MTD_SMART_WEAR_LEVEL /* Allocate the wear leveling status array */ dev->wearstatus = (FAR uint8_t *) smart_malloc(dev, dev->neraseblocks >> SMART_WEAR_BIT_DIVIDE, "Wear status"); if (!dev->wearstatus) { ferr("ERROR: Error allocating wear level status array\n"); goto errexit; } memset(dev->wearstatus, CONFIG_SMARTFS_ERASEDSTATE, dev->neraseblocks >> SMART_WEAR_BIT_DIVIDE); dev->wearflags = 0; dev->uneven_wearcount = 0; #endif /* Allocate a read/write buffer */ dev->rwbuffer = (FAR char *) smart_malloc(dev, size, "RW Buffer"); if (!dev->rwbuffer) { ferr("ERROR: Error allocating SMART read/write buffer\n"); goto errexit; } return OK; /* On error for any allocation, we jump here and free anything that had * previously been allocated. */ errexit: #ifndef CONFIG_MTD_SMART_MINIMIZE_RAM if (dev->smap) { smart_free(dev, dev->smap); dev->smap = NULL; } #else if (dev->sbitmap) { smart_free(dev, dev->sbitmap); dev->sbitmap = NULL; } if (dev->scache) { smart_free(dev, dev->scache); dev->scache = NULL; } #endif #ifdef CONFIG_MTD_SMART_WEAR_LEVEL if (dev->wearstatus) { smart_free(dev, dev->wearstatus); dev->wearstatus = NULL; } #endif #ifdef CONFIG_MTD_SMART_SECTOR_ERASE_DEBUG if (dev->erasecounts) { smart_free(dev, dev->erasecounts); dev->erasecounts = NULL; } #endif return -ENOMEM; } /**************************************************************************** * Name: smart_bytewrite * * Description: Writes a non-page size count of bytes to the underlying * MTD device. If the MTD driver supports a direct impl of * write, then it uses it, otherwise it does a read-modify-write * and depends on the architecture of the flash to only program * bits that actually changed. * ****************************************************************************/ static ssize_t smart_bytewrite(FAR struct smart_struct_s *dev, size_t offset, int nbytes, FAR const uint8_t *buffer) { ssize_t ret; #ifdef CONFIG_MTD_BYTE_WRITE /* Check if the underlying MTD device supports write */ if (dev->mtd->write != NULL) { /* Use the MTD's write method to write individual bytes */ ret = dev->mtd->write(dev->mtd, offset, nbytes, buffer); } else #endif { /* Perform block-based read-modify-write */ uint32_t startblock; uint16_t nblocks; /* First calculate the start block and number of blocks affected */ startblock = offset / dev->geo.blocksize; nblocks = (offset - startblock * dev->geo.blocksize + nbytes + dev->geo.blocksize - 1) / dev->geo.blocksize; DEBUGASSERT(nblocks <= dev->mtdblkspersector); /* Do a block read */ ret = MTD_BREAD(dev->mtd, startblock, nblocks, (FAR uint8_t *)dev->rwbuffer); if (ret < 0) { ferr("ERROR: Error %zd reading from device\n", -ret); goto errout; } /* Modify the data */ memcpy(&dev->rwbuffer[offset - startblock * dev->geo.blocksize], buffer, nbytes); /* Write the data back to the device */ ret = MTD_BWRITE(dev->mtd, startblock, nblocks, (FAR uint8_t *) dev->rwbuffer); if (ret < 0) { ferr("ERROR: Error %zd writing to device\n", -ret); goto errout; } } ret = nbytes; errout: return ret; } /**************************************************************************** * Name: smart_add_sector_to_cache * * Description: Adds a logical to physical sector mapping to the sector * map cache. The cache is used to minimize RAM by eliminating * a one-to-one mapping of all logical sectors and only keeping * a fixed number of mappings per the * CONFIG_MTD_SMART_SECTOR_CACHE_SIZE parameter. Sectors are * automatically managed and removed based on the time since * they were accessed last. * ****************************************************************************/ #ifdef CONFIG_MTD_SMART_MINIMIZE_RAM static int smart_add_sector_to_cache(FAR struct smart_struct_s *dev, uint16_t logical, uint16_t physical, int line) { uint16_t index; uint16_t x; uint16_t oldest; /* If we aren't full yet, just add the sector to the end of the list */ index = 1; if (dev->cache_entries < CONFIG_MTD_SMART_SECTOR_CACHE_SIZE) { oldest = 0; index = dev->cache_entries++; } else { /* Cache is full. We must find the least accessed entry and replace * it */ oldest = 0xffff; for (x = 0; x < CONFIG_MTD_SMART_SECTOR_CACHE_SIZE; x++) { /* Never replace cache entries for system sectors */ if (dev->scache[x].logical < SMART_FIRST_ALLOC_SECTOR) continue; /* If the hit count is zero, then choose this entry */ if (dev->scache[x].birth < oldest) { oldest = dev->scache[x].birth; index = x; } } } /* Now add the sector at index */ dev->scache[index].logical = logical; dev->scache[index].physical = physical; dev->scache[index].birth = dev->cache_nextbirth++; dev->cache_lastlog = logical; dev->cache_lastphys = physical; if (dev->debuglevel > 1) { _err("Add Cache sector: Log=%d, Phys=%d at index %d from line %d\n", logical, physical, index, line); } /* Test if the birthdays need to be adjusted */ if (oldest >= CONFIG_MTD_SMART_SECTOR_CACHE_SIZE + 1024) { for (x = 0; x < dev->cache_entries; x++) { dev->scache[x].birth -= 1024; } dev->cache_nextbirth -= 1024; } return index; } #endif /**************************************************************************** * Name: smart_cache_lookup * * Description: Perform a cache lookup for the requested logical sector. * If the sector is in the cache, then update the hitcount and * return the physical mapping. If a cache miss occurs, then * the routine will scan the volume to find the logical sector * and add / replace a cache entry with the newly located * sector. * ****************************************************************************/ #ifdef CONFIG_MTD_SMART_MINIMIZE_RAM static uint16_t smart_cache_lookup(FAR struct smart_struct_s *dev, uint16_t logical) { int ret; uint16_t block; uint16_t sector; uint16_t x; uint16_t physical; uint16_t logicalsector; struct smart_sect_header_s header; size_t readaddress; physical = 0xffff; /* Test if searching for the last sector used */ if (logical == dev->cache_lastlog) { return dev->cache_lastphys; } /* First search for the entry in the cache */ for (x = 0; x < dev->cache_entries; x++) { if (dev->scache[x].logical == logical) { /* Entry found in the cache. Grab the physical mapping. */ physical = dev->scache[x].physical; break; } } /* If the entry wasn't found in the cache, then we must search the volume * for it and add it to the cache. */ if (physical == 0xffff) { /* Now scan the MTD device. Instead of scanning start to end, we * span the erase blocks and read one sector from each at a time. * this helps speed up the search on volumes that aren't full * because of sector allocation scheme will use the lower sector * numbers in each erase block first. */ for (sector = 0; sector < dev->availsectperblk && physical == 0xffff; sector++) { /* Now scan across each erase block */ for (block = 0; block < dev->geo.neraseblocks; block++) { /* Calculate the read address for this sector */ readaddress = block * dev->erasesize + sector * dev->sectorsize; /* Read the header for this sector */ ret = MTD_READ(dev->mtd, readaddress, sizeof(struct smart_sect_header_s), (FAR uint8_t *) &header); if (ret != sizeof(struct smart_sect_header_s)) { goto err_out; } /* Get the logical sector number for this physical sector */ logicalsector = *((FAR uint16_t *) header.logicalsector); #if CONFIG_SMARTFS_ERASEDSTATE == 0x00 if (logicalsector == 0) { continue; } #endif /* Test if this sector has been committed */ if ((header.status & SMART_STATUS_COMMITTED) == (CONFIG_SMARTFS_ERASEDSTATE & SMART_STATUS_COMMITTED)) { continue; } /* Test if this sector has been release and skip it if it has */ if ((header.status & SMART_STATUS_RELEASED) != (CONFIG_SMARTFS_ERASEDSTATE & SMART_STATUS_RELEASED)) { continue; } if ((header.status & SMART_STATUS_VERBITS) != SMART_STATUS_VERSION) { continue; } /* Test if this is the sector we are looking for */ if (logicalsector == logical) { /* This is the sector we are looking for! Add it to the * cache */ physical = block * dev->sectorsperblk + sector; smart_add_sector_to_cache(dev, logical, physical, __LINE__); break; } } } } /* Update the last logical sector found variable */ dev->cache_lastlog = logical; dev->cache_lastphys = physical; err_out: return physical; } #endif /**************************************************************************** * Name: smart_update_cache * * Description: Updates a cache entry (if present) replacing the logical * sector's physical sector mapping with the new one provided. * This does not affect the hit count. * ****************************************************************************/ #ifdef CONFIG_MTD_SMART_MINIMIZE_RAM static void smart_update_cache(FAR struct smart_struct_s *dev, uint16_t logical, uint16_t physical) { uint16_t x; /* Scan through all cache entries and find the logical sector entry */ for (x = 0; x < dev->cache_entries; x++) { if (dev->scache[x].logical == logical) { /* Entry found. Update it's physical mapping */ dev->scache[x].physical = physical; /* If we are freeing a sector, then remove the logical entry from * the cache. */ if (physical == 0xffff) { dev->scache[x].logical = dev->scache[dev->cache_entries - 1].logical; dev->scache[x].physical = dev->scache[dev->cache_entries - 1].physical; dev->cache_entries--; } if (dev->debuglevel > 1) { _err("Update Cache: Log=%d, Phys=%d at index %d\n", logical, physical, x); } break; } } if (dev->cache_lastlog == logical) { dev->cache_lastphys = physical; } } #endif /**************************************************************************** * Name: smart_get_wear_level * * Description: Gets the wear level of the specified block. Wear levels are * encoded to minimize the number of zero to one transitions, * possibly allowing updates to made on NOR devices that have * no CRC enabled. * ****************************************************************************/ #ifdef CONFIG_MTD_SMART_WEAR_LEVEL static uint8_t smart_get_wear_level(FAR struct smart_struct_s *dev, uint16_t block) { uint8_t bits; bits = dev->wearstatus[block >> SMART_WEAR_BIT_DIVIDE]; if (block & 0x01) { /* Use the upper nibble */ bits >>= 4; } else { /* Use the lower nibble */ bits &= 0x0f; } /* Lookup and return the level using the BitToLevel map */ return g_wearbit_to_levelmap4[bits]; } #endif /**************************************************************************** * Name: smart_find_wear_minmax * * Description: Find the minimum and maximum wear levels. This is used when * we increment the wear level of a minimum value block so that * we can detect if a new minimum exists and perform * normalization of the wear-levels. * ****************************************************************************/ #ifdef CONFIG_MTD_SMART_WEAR_LEVEL static void smart_find_wear_minmax(FAR struct smart_struct_s *dev) { uint16_t x; unsigned char level; dev->minwearlevel = 15; dev->maxwearlevel = 0; /* Loop through all erase blocks and find min / max level */ for (x = 0; x < dev->geo.neraseblocks; x++) { /* Find wear level of the minimum worn block */ level = smart_get_wear_level(dev, x); if (level < dev->minwearlevel) { dev->minwearlevel = level; } /* Find wear level of the maximum worn block */ if (level > dev->maxwearlevel) { dev->maxwearlevel = level; } } #ifdef CONFIG_MTD_SMART_SECTOR_ERASE_DEBUG /* Also adjust the erase counts */ level = 255; for (x = 0; x < dev->geo.neraseblocks; x++) { if (dev->erasecounts[x] < level) { level = dev->erasecounts[x]; } } if (level != 0) { for (x = 0; x < dev->geo.neraseblocks; x++) { dev->erasecounts[x] -= level; } } #endif } #endif /**************************************************************************** * Name: smart_set_wear_level * * Description: Sets the wear level of the specified block. The wear level * is a 4-bit field packed 2 entries per byte and is mapped to * a bit field which minimizes the number of 0 to 1 transitions * such that entries can be updated on a NOR flash without the * need to relocate the format sector (assuming CRC is not * enabled, in which case a relocated is needed for ANY change). * ****************************************************************************/ #ifdef CONFIG_MTD_SMART_WEAR_LEVEL static int smart_set_wear_level(FAR struct smart_struct_s *dev, uint16_t block, uint8_t level) { uint8_t bits; uint8_t oldlevel; /* Get the old wear level to test if we need to update min / max */ oldlevel = smart_get_wear_level(dev, block); /* Get the bit map for this wear level from the static map array */ if (level > 15) { _err("ERROR: Fatal Design Error! Wear level > 15, block=%d\n", block); /* This is a design flaw, but we still allow processing, otherwise we * will corrupt the volume. It's better to have a few blocks that are * worn a bit more than to create an error condition on the volume. * * Set the level to the maximum value and add to the un-even wear count * to keep track of the number of times this has happened. */ level = 15; dev->uneven_wearcount++; } bits = g_wearlevel_to_bitmap4[level]; if (block & 0x01) { /* Use the upper nibble */ dev->wearstatus[block >> SMART_WEAR_BIT_DIVIDE] &= 0x0f; dev->wearstatus[block >> SMART_WEAR_BIT_DIVIDE] |= bits << 4; } else { /* Use the lower nibble */ dev->wearstatus[block >> SMART_WEAR_BIT_DIVIDE] &= 0xf0; dev->wearstatus[block >> SMART_WEAR_BIT_DIVIDE] |= bits; } /* Mark wear bits as dirty */ dev->wearflags |= SMART_WEARFLAGS_WRITE_NEEDED; /* Test if min / max need to be updated */ if (oldlevel + 1 == level) { /* Test if max needs to be updated */ if (level > dev->maxwearlevel) { dev->maxwearlevel = level; } /* Test if this was the min level. If it was, then * we need to rescan for min. */ if (oldlevel == dev->minwearlevel) { smart_find_wear_minmax(dev); if (oldlevel != dev->minwearlevel) finfo("##### New min wear level = %d\n", dev->minwearlevel); } } return 0; } #endif /**************************************************************************** * Name: smart_scan * * Description: Performs a scan of the MTD device searching for format * information and fills in logical sector mapping, freesector * count, etc. * ****************************************************************************/ static int smart_scan(FAR struct smart_struct_s *dev) { int sector; int ret; uint16_t totalsectors; uint16_t sectorsize; uint16_t prerelease; uint16_t logicalsector; uint16_t winner; uint16_t loser; uint32_t readaddress; uint32_t offset; uint16_t seq1; uint16_t seq2; uint16_t seqwrap; struct smart_sect_header_s header; #ifdef CONFIG_MTD_SMART_MINIMIZE_RAM int dupsector; uint16_t duplogsector; #endif #ifdef CONFIG_SMARTFS_MULTI_ROOT_DIRS int x; char devname[32]; FAR struct smart_multiroot_device_s *rootdirdev; #endif static const uint16_t sizetbl[8] = { CONFIG_MTD_SMART_SECTOR_SIZE, 512, 1024, 4096, 2048, 8192, 16384, 32768 }; finfo("Entry\n"); /* Find the sector size on the volume by reading headers from * sectors of decreasing size. On a formatted volume, the sector * size is saved in the header status byte of search sector, so * by starting with the largest supported sector size and * decreasing from there, we will be sure to find data that is * a header and not sector data. */ sectorsize = 0xffff; offset = 16384; while (sectorsize == 0xffff) { readaddress = 0; while (readaddress < dev->erasesize * dev->geo.neraseblocks) { /* Read the next sector from the device */ ret = MTD_READ(dev->mtd, readaddress, sizeof(struct smart_sect_header_s), (FAR uint8_t *) &header); if (ret != sizeof(struct smart_sect_header_s)) { goto err_out; } if (header.status != CONFIG_SMARTFS_ERASEDSTATE) { sectorsize = sizetbl[(header.status & SMART_STATUS_SIZEBITS) >> 2]; break; } readaddress += offset; } if (sectorsize == 0xffff) { sectorsize = CONFIG_MTD_SMART_SECTOR_SIZE; } offset >>= 1; if (offset < 256 && sectorsize == 0xffff) { /* No valid sectors found on device. Default the * sector size to the CONFIG value */ sectorsize = CONFIG_MTD_SMART_SECTOR_SIZE; } } /* Now set the sectorsize and other sectorsize derived variables */ ret = smart_setsectorsize(dev, sectorsize); if (ret != OK) { goto err_out; } /* Initialize the device variables */ totalsectors = dev->totalsectors; dev->formatstatus = SMART_FMT_STAT_NOFMT; dev->freesectors = dev->availsectperblk * dev->geo.neraseblocks; dev->releasesectors = 0; /* Initialize the freecount and releasecount arrays */ for (sector = 0; sector < dev->neraseblocks; sector++) { if (sector == dev->neraseblocks - 1 && dev->totalsectors == 65534) { prerelease = 2; } else { prerelease = 0; } #ifdef CONFIG_MTD_SMART_PACK_COUNTS smart_set_count(dev, dev->freecount, sector, dev->availsectperblk - prerelease); smart_set_count(dev, dev->releasecount, sector, prerelease); #else dev->freecount[sector] = dev->availsectperblk - prerelease; dev->releasecount[sector] = prerelease; #endif } /* Initialize the sector map */ #ifndef CONFIG_MTD_SMART_MINIMIZE_RAM for (sector = 0; sector < totalsectors; sector++) { dev->smap[sector] = -1; } #else /* Clear all logical sector used bits */ memset(dev->sbitmap, 0, (dev->totalsectors + 7) >> 3); #endif /* Now scan the MTD device */ /* At first, set the loser sector as the invalid value */ loser = totalsectors; for (sector = 0; sector < totalsectors; sector++) { finfo("Scan sector %d\n", sector); winner = sector; /* Calculate the read address for this sector */ readaddress = sector * dev->mtdblkspersector * dev->geo.blocksize; /* Read the header for this sector */ ret = MTD_READ(dev->mtd, readaddress, sizeof(struct smart_sect_header_s), (FAR uint8_t *)&header); if (ret != sizeof(struct smart_sect_header_s)) { goto err_out; } /* Get the logical sector number for this physical sector */ logicalsector = *((FAR uint16_t *) header.logicalsector); #if CONFIG_SMARTFS_ERASEDSTATE == 0x00 if (logicalsector == 0) { logicalsector = -1; } #endif /* Test if this sector has been committed */ if ((header.status & SMART_STATUS_COMMITTED) == (CONFIG_SMARTFS_ERASEDSTATE & SMART_STATUS_COMMITTED)) { continue; } /* This block is committed, therefore not free. Update the * erase block's freecount. */ #ifdef CONFIG_MTD_SMART_PACK_COUNTS smart_add_count(dev, dev->freecount, sector / dev->sectorsperblk, -1); #else dev->freecount[sector / dev->sectorsperblk]--; #endif dev->freesectors--; /* Test if this sector has been release and if it has, * update the erase block's releasecount. */ if ((header.status & SMART_STATUS_RELEASED) != (CONFIG_SMARTFS_ERASEDSTATE & SMART_STATUS_RELEASED)) { /* Keep track of the total number of released sectors and * released sectors per erase block. */ dev->releasesectors++; #ifdef CONFIG_MTD_SMART_PACK_COUNTS smart_add_count(dev, dev->releasecount, sector / dev->sectorsperblk, 1); #else dev->releasecount[sector / dev->sectorsperblk]++; #endif continue; } if ((header.status & SMART_STATUS_VERBITS) != SMART_STATUS_VERSION) { continue; } /* Validate the logical sector number is in bounds */ if (logicalsector >= totalsectors) { /* Error in logical sector read from the MTD device */ ferr("ERROR: Invalid logical sector %d at physical %d.\n", logicalsector, sector); continue; } /* If this is logical sector zero, then read in the signature * information to validate the format signature. */ if (logicalsector == 0) { /* Read the sector data */ ret = MTD_READ(dev->mtd, readaddress, 32, (FAR uint8_t *)dev->rwbuffer); if (ret != 32) { ferr("ERROR: Error reading physical sector %d.\n", sector); goto err_out; } /* Validate the format signature */ if (dev->rwbuffer[SMART_FMT_POS1] != SMART_FMT_SIG1 || dev->rwbuffer[SMART_FMT_POS2] != SMART_FMT_SIG2 || dev->rwbuffer[SMART_FMT_POS3] != SMART_FMT_SIG3 || dev->rwbuffer[SMART_FMT_POS4] != SMART_FMT_SIG4) { /* Invalid signature on a sector claiming to be sector 0! * What should we do? Release it? */ continue; } /* Mark the volume as formatted and set the sector size */ dev->formatstatus = SMART_FMT_STAT_FORMATTED; dev->namesize = dev->rwbuffer[SMART_FMT_NAMESIZE_POS]; dev->formatversion = dev->rwbuffer[SMART_FMT_VERSION_POS]; #ifdef CONFIG_SMARTFS_MULTI_ROOT_DIRS dev->rootdirentries = dev->rwbuffer[SMART_FMT_ROOTDIRS_POS]; /* If rootdirentries is greater than 1, then we need to register * additional block devices. */ for (x = 1; x < dev->rootdirentries; x++) { if (dev->partname[0] != '\0') { snprintf(devname, sizeof(devname), "/dev/smart%d%sd%d", dev->minor, dev->partname, x + 1); } else { snprintf(devname, sizeof(devname), "/dev/smart%dd%d", dev->minor, x + 1); } /* Inode private data is a reference to a struct containing * the SMART device structure and the root directory number. */ rootdirdev = (struct smart_multiroot_device_s *) smart_malloc(dev, sizeof(*rootdirdev), "Root Dir"); if (rootdirdev == NULL) { ferr("ERROR: Memory alloc failed\n"); ret = -ENOMEM; goto err_out; } /* Populate the rootdirdev */ rootdirdev->dev = dev; rootdirdev->rootdirnum = x; /* Inode private data is a reference to the SMART device * structure. */ ret = register_blockdriver(devname, &g_bops, 0, rootdirdev); } #endif } /* Test for duplicate logical sectors on the device */ #ifndef CONFIG_MTD_SMART_MINIMIZE_RAM if (dev->smap[logicalsector] != 0xffff) #else if (dev->sbitmap[logicalsector >> 3] & (1 << (logicalsector & 0x07))) #endif { /* Uh-oh, we found more than 1 physical sector claiming to be * the same logical sector. Use the sequence number information * to resolve who wins. */ #if SMART_STATUS_VERSION == 1 if ((header.status & SMART_STATUS_CRC) != (CONFIG_SMARTFS_ERASEDSTATE & SMART_STATUS_CRC)) { seq2 = header.seq; } else { seq2 = *((FAR uint16_t *) &header.seq); } #else seq2 = header.seq; #endif /* We must re-read the 1st physical sector to get it's seq number */ #ifndef CONFIG_MTD_SMART_MINIMIZE_RAM readaddress = dev->smap[logicalsector] * dev->mtdblkspersector * dev->geo.blocksize; #else /* For minimize RAM, we have to rescan to find the 1st sector * claiming to be this logical sector. */ for (dupsector = 0; dupsector < sector; dupsector++) { /* Calculate the read address for this sector */ readaddress = dupsector * dev->mtdblkspersector * dev->geo.blocksize; /* Read the header for this sector */ ret = MTD_READ(dev->mtd, readaddress, sizeof(struct smart_sect_header_s), (FAR uint8_t *) &header); if (ret != sizeof(struct smart_sect_header_s)) { goto err_out; } /* Get the logical sector number for this physical sector */ duplogsector = *((FAR uint16_t *) header.logicalsector); #if CONFIG_SMARTFS_ERASEDSTATE == 0x00 if (duplogsector == 0) { duplogsector = -1; } #endif /* Test if this sector has been committed */ if ((header.status & SMART_STATUS_COMMITTED) == (CONFIG_SMARTFS_ERASEDSTATE & SMART_STATUS_COMMITTED)) { continue; } /* Test if this sector has been release and skip it if it has */ if ((header.status & SMART_STATUS_RELEASED) != (CONFIG_SMARTFS_ERASEDSTATE & SMART_STATUS_RELEASED)) { continue; } if ((header.status & SMART_STATUS_VERBITS) != SMART_STATUS_VERSION) { continue; } /* Now compare if this logical sector matches the current * sector */ if (duplogsector == logicalsector) { break; } } #endif ret = MTD_READ(dev->mtd, readaddress, sizeof(struct smart_sect_header_s), (FAR uint8_t *) &header); if (ret != sizeof(struct smart_sect_header_s)) { goto err_out; } #if SMART_STATUS_VERSION == 1 if ((header.status & SMART_STATUS_CRC) != (CONFIG_SMARTFS_ERASEDSTATE & SMART_STATUS_CRC)) { seq1 = header.seq; seqwrap = 0xf0; } else { seq1 = *((FAR uint16_t *) &header.seq); seqwrap = 0xfff0; } #else seq1 = header.seq; seqwrap = 0xf0; #endif /* Now determine who wins */ if ((seq1 > seqwrap && seq2 < 10) || seq2 > seq1) { /* Seq 2 is the winner ... bigger or it wrapped */ winner = sector; #ifndef CONFIG_MTD_SMART_MINIMIZE_RAM loser = dev->smap[logicalsector]; #else loser = dupsector; #endif } else { /* We keep the original mapping and seq2 is the loser */ loser = sector; #ifndef CONFIG_MTD_SMART_MINIMIZE_RAM winner = dev->smap[logicalsector]; #else winner = smart_cache_lookup(dev, logicalsector); #endif } finfo("Duplicate Sector winner=%d, loser=%d\n", winner, loser); #ifdef CONFIG_MTD_SMART_ENABLE_CRC /* Check CRC of the winner sector just in case */ ret = MTD_BREAD(dev->mtd, winner * dev->mtdblkspersector, dev->mtdblkspersector, (FAR uint8_t *) dev->rwbuffer); if (ret == dev->mtdblkspersector) { /* Validate the CRC of the read-back data */ ret = smart_validate_crc(dev); } if (ret != OK) { /* The winner sector has CRC error, so we select the loser * sector. After swapping the winner and the loser sector, we * will release the loser sector with CRC error. */ if (sector == winner) { /* winner: sector(CRC error) -> origin * loser : origin -> sector(CRC error) */ winner = loser; loser = sector; } else { /* winner: origin(CRC error) -> sector * loser : sector -> origin(CRC error) */ loser = winner; winner = sector; } finfo("Duplicate Sector winner=%d, loser=%d\n", winner, loser); } #endif /* CONFIG_MTD_SMART_ENABLE_CRC */ /* Now release the loser sector */ readaddress = loser * dev->mtdblkspersector * dev->geo.blocksize; ret = MTD_READ(dev->mtd, readaddress, sizeof(struct smart_sect_header_s), (FAR uint8_t *)&header); if (ret != sizeof(struct smart_sect_header_s)) { goto err_out; } #if CONFIG_SMARTFS_ERASEDSTATE == 0xff header.status &= ~SMART_STATUS_RELEASED; #else header.status |= SMART_STATUS_RELEASED; #endif offset = readaddress + offsetof(struct smart_sect_header_s, status); ret = smart_bytewrite(dev, offset, 1, &header.status); if (ret < 0) { ferr("ERROR: Error %d releasing duplicate sector\n", -ret); goto err_out; } } /* Test if this sector is loser of duplicate logical sector */ if (sector == loser) { continue; } #ifndef CONFIG_MTD_SMART_MINIMIZE_RAM /* Update the logical to physical sector map */ dev->smap[logicalsector] = winner; #else /* Mark the logical sector as used in the bitmap */ dev->sbitmap[logicalsector >> 3] |= 1 << (logicalsector & 0x07); if (logicalsector < SMART_FIRST_ALLOC_SECTOR) { smart_add_sector_to_cache(dev, logicalsector, winner, __LINE__); } #endif } #if defined (CONFIG_MTD_SMART_WEAR_LEVEL) && (SMART_STATUS_VERSION == 1) #ifdef CONFIG_MTD_SMART_CONVERT_WEAR_FORMAT /* We need to check if we are converting an older format with incorrect * wear leveling data in sector zero to the new format. The old format * put all zeros in the wear level bit locations, but the new (better) * way is to leave them 0xff. */ #ifndef CONFIG_MTD_SMART_MINIMIZE_RAM sector = dev->smap[0]; #else sector = smart_cache_lookup(dev, 0); #endif /* Validate the sector is valid ... may be an unformatted device */ if (sector != 0xffff) { /* Read the sector data */ ret = MTD_BREAD(dev->mtd, sector * dev->mtdblkspersector, dev->mtdblkspersector, (uint8_t *) dev->rwbuffer); if (ret != dev->mtdblkspersector) { ferr("ERROR: Error reading physical sector %d.\n", sector); goto err_out; } /* Check for old format wear leveling */ if (dev->rwbuffer[SMART_WEAR_LEVEL_FORMAT_SIG] == 0) { /* Old format detected. We must relocate sector zero and fill it * in with 0xff. */ uint16_t newsector = smart_findfreephyssector(dev, FALSE); if (newsector == 0xffff) { /* Unable to find a free sector!!! */ ferr("ERROR: Can't find a free sector for relocation\n"); ret = -ENOSPC; goto err_out; } memset(&dev->rwbuffer[SMART_WEAR_LEVEL_FORMAT_SIG], 0xff, dev->mtdblkspersector * dev->geo.blocksize - SMART_WEAR_LEVEL_FORMAT_SIG); smart_relocate_sector(dev, sector, newsector); /* Update the free and release sector counts */ dev->freesectors--; dev->releasesectors++; #ifndef CONFIG_MTD_SMART_MINIMIZE_RAM dev->smap[0] = newsector; dev->freecount[newsector / dev->sectorsperblk]--; dev->releasecount[sector / dev->sectorsperblk]++; #else smart_update_cache(dev, 0, newsector); #ifdef CONFIG_MTD_SMART_PACK_COUNTS smart_add_count(dev, dev->freecount, newsector / dev->sectorsperblk, -1); smart_add_count(dev, dev->releasecount, sector / dev->sectorsperblk, 1); #endif #endif } } #endif /* CONFIG_MTD_SMART_CONVERT_WEAR_FORMAT */ #endif /* CONFIG_MTD_SMART_WEAR_LEVEL && SMART_STATUS_VERSION == 1 */ #ifdef CONFIG_MTD_SMART_FSCK smart_fsck(dev); #endif #ifdef CONFIG_MTD_SMART_WEAR_LEVEL /* Read the wear leveling status bits */ smart_read_wearstatus(dev); #endif finfo("SMART Scan\n"); finfo(" Erase size: %10d\n", dev->sectorsperblk * dev->sectorsize); finfo(" Erase count: %10d\n", dev->neraseblocks); finfo(" Sect/block: %10d\n", dev->sectorsperblk); finfo(" MTD Blk/Sect: %10d\n", dev->mtdblkspersector); /* Validate the geometry */ if (dev->mtdblkspersector == 0 || dev->sectorsperblk == 0 || dev->sectorsperblk == 0 || dev->sectorsize == 0) { ferr("ERROR: Invalid Geometry!\n"); ret = -EINVAL; goto err_out; } #ifdef CONFIG_MTD_SMART_ALLOC_DEBUG finfo(" Allocations:\n"); for (sector = 0; sector < SMART_MAX_ALLOCS; sector++) { if (dev->alloc[sector].ptr != NULL) { finfo(" %s: %d\n", dev->alloc[sector].name, dev->alloc[sector].size); } } #endif ret = OK; err_out: return ret; } /**************************************************************************** * Name: smart_getformat * * Description: Populates the SMART format structure based on the format * information for the inode. * ****************************************************************************/ #ifdef CONFIG_SMARTFS_MULTI_ROOT_DIRS static inline int smart_getformat(FAR struct smart_struct_s *dev, FAR struct smart_format_s *fmt, uint8_t rootdirnum) #else static inline int smart_getformat(FAR struct smart_struct_s *dev, FAR struct smart_format_s *fmt) #endif { int ret; finfo("Entry\n"); DEBUGASSERT(fmt); /* Test if we know the format status or not. If we don't know the * status, then we must perform a scan of the device to search * for the format marker */ if (dev->formatstatus != SMART_FMT_STAT_FORMATTED) { /* Perform the scan */ ret = smart_scan(dev); if (ret != OK) { goto err_out; } } /* Now fill in the structure */ if (dev->formatstatus == SMART_FMT_STAT_FORMATTED) { fmt->flags = SMART_FMT_ISFORMATTED; } else { fmt->flags = 0; } fmt->sectorsize = dev->sectorsize; fmt->availbytes = dev->sectorsize - sizeof(struct smart_sect_header_s); fmt->nsectors = dev->totalsectors; fmt->nfreesectors = dev->freesectors; fmt->namesize = dev->namesize; #ifdef CONFIG_SMARTFS_MULTI_ROOT_DIRS fmt->nrootdirentries = dev->rootdirentries; fmt->rootdirnum = rootdirnum; #endif /* Add the released sectors to the reported free sector count */ fmt->nfreesectors += dev->releasesectors; /* Subtract the reserved sector count */ fmt->nfreesectors -= dev->sectorsperblk + 4; ret = OK; err_out: return ret; } /**************************************************************************** * Name: smart_erase_block_if_empty * * Description: Tests the specified erase block if it contains all free or * released sectors and erases it. * ****************************************************************************/ static void smart_erase_block_if_empty(FAR struct smart_struct_s *dev, uint16_t block, uint8_t forceerase) { uint16_t freecount; uint16_t releasecount; uint16_t prerelease; #ifdef CONFIG_MTD_SMART_PACK_COUNTS releasecount = smart_get_count(dev, dev->releasecount, block); freecount = smart_get_count(dev, dev->freecount, block); #else releasecount = dev->releasecount[block]; freecount = dev->freecount[block]; #endif if ((freecount + releasecount == dev->availsectperblk && freecount < 1) || forceerase) { /* Erase the block */ #if defined(CONFIG_FS_PROCFS) && !defined(CONFIG_FS_PROCFS_EXCLUDE_SMARTFS) dev->unusedsectors += freecount; dev->blockerases++; #endif MTD_ERASE(dev->mtd, block, 1); #ifdef CONFIG_MTD_SMART_SECTOR_ERASE_DEBUG if (dev->erasecounts) { dev->erasecounts[block]++; } #endif /* If wear leveling enabled, then we must add one to the wear status */ #ifdef CONFIG_MTD_SMART_WEAR_LEVEL smart_set_wear_level(dev, block, smart_get_wear_level(dev, block) + 1); #endif /* If we have a device with 65534 sectors, then disallow the last two * physical sector if this is the last erase block on the device. */ if (block == dev->geo.neraseblocks - 1 && dev->totalsectors == 65534) { prerelease = 2; } else { prerelease = 0; } dev->freesectors += dev->availsectperblk - prerelease - freecount; dev->releasesectors -= releasecount - prerelease; #ifdef CONFIG_MTD_SMART_PACK_COUNTS smart_set_count(dev, dev->releasecount, block, prerelease); smart_set_count(dev, dev->freecount, block, dev->availsectperblk - prerelease); #else dev->releasecount[block] = prerelease; dev->freecount[block] = dev->availsectperblk - prerelease; #endif /* Now that we have erased this block and updated the release / free * counts, if we are in WEAR LEVELING enabled mode, we must check if * this erase block's wear level has reached the threshold to warrant * moving a minimum wear level block's data into it (i.e. relocating * static data to this block so it will be worn less). */ #ifdef CONFIG_MTD_SMART_WEAR_LEVEL if (!forceerase) { smart_relocate_static_data(dev, block); } #endif #ifdef CONFIG_SMART_LOCAL_CHECKFREE if (smart_checkfree(dev, __LINE__) != OK) { fwarn(" ...while eraseing block %d\n", block); } #endif } } /**************************************************************************** * Name: smart_relocate_static_data * * Description: Tests if the specified block has reached the wear threshold * for static data relocation and if it has, relocates a less * worn block to it. * ****************************************************************************/ #ifdef CONFIG_MTD_SMART_WEAR_LEVEL static int smart_relocate_static_data(FAR struct smart_struct_s *dev, uint16_t block) { uint16_t freecount; uint16_t x; uint16_t sector; uint16_t minblock; uint16_t nextsector; uint16_t newsector; uint16_t mincount; int ret; FAR struct smart_sect_header_s *header; #ifdef CONFIG_MTD_SMART_ENABLE_CRC FAR struct smart_allocsector_s *allocsector; #endif /* Now that we have erased this block and updated the release / free * counts, if we are in WEAR LEVELING enabled mode, we must check if this * erase block's wear level has reached the threshold to warrant moving a * minimum wear level block's data into it (i.e. relocating static data to * this block so it will be worn less). */ ret = OK; header = (FAR struct smart_sect_header_s *) dev->rwbuffer; #ifdef CONFIG_SMART_LOCAL_CHECKFREE if (smart_checkfree(dev, __LINE__) != OK) { fwarn(" ...about to relocate static data %d\n", block); } #endif if (smart_get_wear_level(dev, block) >= SMART_WEAR_FULL_RELOCATE_THRESHOLD) { /* Okay, this block is getting too worn. Move a minimum wear level * block to it in it's entirety. */ /* Scan all erase blocks (or until we find a minimum wear level block * with no free + released blocks. */ freecount = dev->sectorsperblk + 1; minblock = dev->geo.neraseblocks; mincount = 0; for (x = 0; x < dev->geo.neraseblocks; x++) { if (smart_get_wear_level(dev, x) == dev->minwearlevel) { /* Don't allow the format sector or directory sector to * be moved into a worn block. First get the format and * dir sectors. */ mincount++; #ifdef CONFIG_MTD_SMART_PACK_COUNTS if (smart_get_count(dev, dev->releasecount, x) + smart_get_count(dev, dev->freecount, x) < freecount) { freecount = smart_get_count(dev, dev->releasecount, x) + smart_get_count(dev, dev->freecount, x); minblock = x; } #else if (dev->freecount[x] + dev->releasecount[x] < freecount) { freecount = dev->freecount[x] + dev->releasecount[x]; minblock = x; } #endif /* Break if freecount reaches zero */ if (freecount == 0) { /* We found a minimum wear-level block with no free * sectors. relocate this block to the more highly worn * block. */ break; } } } /* Okay, now move block 'x' to block 'block' and erase block 'x' */ x = minblock; /* We are resuing nextsector and newsector variables here simply as * variables for displaying debug data. I have learned through my * years of programming that this is a really good way to create * spaghetti code, but I didn't want to add stack variables just * for debug data, and I *know* these variables aren't being used * yet. */ #ifdef CONFIG_MTD_SMART_PACK_COUNTS nextsector = smart_get_count(dev, dev->freecount, x); newsector = smart_get_count(dev, dev->releasecount, x); #else nextsector = dev->freecount[x]; newsector = dev->releasecount[x]; #endif finfo("Moving block %d, wear %d, free %d, " "released %d to block %d, wear %d\n", x, smart_get_wear_level(dev, x), nextsector, newsector, block, smart_get_wear_level(dev, block)); nextsector = block * dev->sectorsperblk; for (sector = x * dev->sectorsperblk; sector < x * dev->sectorsperblk + dev->availsectperblk; sector++) { /* Read the next sector from this erase block */ ret = MTD_BREAD(dev->mtd, sector * dev->mtdblkspersector, dev->mtdblkspersector, (FAR uint8_t *) dev->rwbuffer); if (ret != dev->mtdblkspersector) { ferr("ERROR: Error reading sector %d\n", sector); ret = -EIO; goto errout; } /* Test if the block is in use */ #ifdef CONFIG_MTD_SMART_ENABLE_CRC /* Check if there is a temporary alloc for this physical sector */ allocsector = dev->allocsector; while (allocsector) { if (allocsector->physical == sector) { break; } allocsector = allocsector->next; } /* If we found a temp allocation, just update the mapped physical * location and move on to the next block ... there is no data to * move yet. */ if (allocsector) { /* Get next sector from 'block' */ newsector = nextsector++; if (newsector == 0xffff) { /* Unable to find a free sector!!! */ ferr("ERROR: Can't find a free sector for relocation\n"); ret = -ENOSPC; goto errout; } /* Update the temporary allocation's physical sector */ allocsector->physical = newsector; *((FAR uint16_t *) header->logicalsector) = allocsector->logical; } else #endif { if (((header->status & SMART_STATUS_COMMITTED) == (CONFIG_SMARTFS_ERASEDSTATE & SMART_STATUS_COMMITTED)) || ((header->status & SMART_STATUS_RELEASED) != (CONFIG_SMARTFS_ERASEDSTATE & SMART_STATUS_RELEASED))) { /* This sector doesn't have live data (free or released). * just continue to the next sector and don't move it. */ continue; } /* Find a new sector where it can live, NOT in this erase * block */ newsector = nextsector++; /* Relocate the sector data */ if ((ret = smart_relocate_sector(dev, sector, newsector)) < 0) { goto errout; } } dev->freesectors--; #ifndef CONFIG_MTD_SMART_MINIMIZE_RAM dev->smap[*((FAR uint16_t *) header->logicalsector)] = newsector; #else smart_update_cache(dev, *((FAR uint16_t *)header->logicalsector), newsector); #endif #ifdef CONFIG_MTD_SMART_PACK_COUNTS smart_add_count(dev, dev->freecount, block, -1); #else dev->freecount[block]--; #endif /* CONFIG_MTD_SMART_PACK_COUNTS */ } #ifdef CONFIG_SMART_LOCAL_CHECKFREE if (smart_checkfree(dev, __LINE__) != OK) { fwarn(" ...about to erase static block %d\n", block); } #endif /* Now erase the block we just relocated, force erasing it */ smart_erase_block_if_empty(dev, x, TRUE); } #ifdef CONFIG_SMART_LOCAL_CHECKFREE if (smart_checkfree(dev, __LINE__) != OK) { fwarn(" ...done erasing static block %d\n", block); } #endif errout: return ret; } #endif /**************************************************************************** * Name: smart_calc_sector_crc * * Description: Calculate the CRC value for the sector data in the RW buffer * based on the configured CRC size. * ****************************************************************************/ #ifdef CONFIG_MTD_SMART_ENABLE_CRC static crc_t smart_calc_sector_crc(FAR struct smart_struct_s *dev) { crc_t crc = 0; #ifdef CONFIG_SMART_CRC_8 /* Calculate CRC on data region of the sector */ crc = crc8((FAR uint8_t *) &dev->rwbuffer[sizeof(struct smart_sect_header_s)], dev->mtdblkspersector * dev->geo.blocksize - sizeof(struct smart_sect_header_s)); /* Add logical sector number and seq to the CRC calculation */ crc = crc8part((FAR uint8_t *)dev->rwbuffer, 3, crc); /* Add status to the CRC calculation */ crc = crc8part((FAR uint8_t *) &dev->rwbuffer[offsetof(struct smart_sect_header_s, status)], 1, crc); #elif defined(CONFIG_SMART_CRC_16) /* Calculate CRC on data region of the sector */ crc = crc16((FAR uint8_t *) &dev->rwbuffer[sizeof(struct smart_sect_header_s)], dev->mtdblkspersector * dev->geo.blocksize - sizeof(struct smart_sect_header_s)); /* Add logical sector number to the CRC calculation */ crc = crc16part((FAR uint8_t *) dev->rwbuffer, 2, crc); /* Add status and seq to the CRC calculation */ crc = crc16part((uint8_t *) &dev->rwbuffer[offsetof(struct smart_sect_header_s, status)], 2, crc); #elif defined(CONFIG_SMART_CRC_32) /* Calculate CRC on data region of the sector */ crc = crc32((FAR uint8_t *) &dev->rwbuffer[sizeof(struct smart_sect_header_s)], dev->mtdblkspersector * dev->geo.blocksize - sizeof(struct smart_sect_header_s)); /* Add logical sector number, status and seq to the CRC calculation */ crc = crc32part((FAR uint8_t *) dev->rwbuffer, 6, crc); #else #error "Unknown CRC size!" #endif return crc; } #endif /* CONFIG_MTD_SMART_ENABLE_CRC */ /**************************************************************************** * Name: smart_llformat * * Description: Performs a low-level format of the flash device. This * involves erasing the device and writing a valid sector * zero (logical) with proper format signature. * * Input Parameters: * * arg: Upper 16 bits contains the sector size * Lower 16 bits contains the number of root dir entries * ****************************************************************************/ static inline int smart_llformat(FAR struct smart_struct_s *dev, unsigned long arg) { FAR struct smart_sect_header_s *sectorheader; size_t wrcount; int x; int ret; uint8_t sectsize; uint8_t prerelease; uint16_t sectorsize; finfo("Entry\n"); /* Get the sector size from the provided arg */ sectorsize = arg >> 16; if (sectorsize == 0) { sectorsize = CONFIG_MTD_SMART_SECTOR_SIZE; } /* Set the sector size for the device */ ret = smart_setsectorsize(dev, sectorsize); if (ret != OK) { return ret; } /* Check for invalid format */ if (dev->erasesize == 0 || dev->sectorsperblk == 0) { dev->erasesize = dev->geo.erasesize; ferr("ERROR: Invalid geometery ... " "Sectors per erase block must be 1-256\n"); ferr(" Erase block size = %" PRId32 "\n", dev->erasesize); ferr(" Sector size = %d\n", dev->sectorsize); ferr(" Sectors/erase block = %" PRId32 "\n", dev->erasesize / dev->sectorsize); return -EINVAL; } /* Erase the MTD device */ ret = MTD_IOCTL(dev->mtd, MTDIOC_BULKERASE, 0); if (ret < 0) { return ret; } /* Now construct a logical sector zero header to write to the device. */ sectorheader = (FAR struct smart_sect_header_s *) dev->rwbuffer; memset(dev->rwbuffer, CONFIG_SMARTFS_ERASEDSTATE, dev->sectorsize); #if SMART_STATUS_VERSION == 1 #ifdef CONFIG_MTD_SMART_ENABLE_CRC /* CRC enabled. Using an 8-bit sequence number */ sectorheader->seq = 0; #else /* CRC not enabled. Using a 16-bit sequence number */ *((FAR uint16_t *) §orheader->seq) = 0; #endif #else /* SMART_STATUS_VERSION == 1 */ sectorheader->seq = 0; #endif /* SMART_STATUS_VERSION == 1 */ /* Set the sector size of this sector */ sectsize = dev->sectorsize < 4096 ? (dev->sectorsize >> 9) : dev->sectorsize == 4096 ? 3 : 5 + (dev->sectorsize >> 14); sectsize <<= 2; /* Set the sector logical sector to zero and setup the header status */ #if ( CONFIG_SMARTFS_ERASEDSTATE == 0xff ) *((FAR uint16_t *) sectorheader->logicalsector) = 0; sectorheader->status = (uint8_t)~(SMART_STATUS_COMMITTED | SMART_STATUS_VERBITS | SMART_STATUS_SIZEBITS) | SMART_STATUS_VERSION | sectsize; #ifdef CONFIG_MTD_SMART_ENABLE_CRC sectorheader->status &= ~SMART_STATUS_CRC; #endif /* CONFIG_MTD_SMART_ENABLE_CRC */ #else /* CONFIG_SMARTFS_ERASEDSTATE == 0xff */ *((FAR uint16_t *) sectorheader->logicalsector) = 0xffff; sectorheader->status = (uint8_t)(SMART_STATUS_COMMITTED | SMART_STATUS_VERSION | sectsize); #ifdef CONFIG_MTD_SMART_ENABLE_CRC sectorheader->status |= SMART_STATUS_CRC; #endif /* CONFIG_MTD_SMART_ENABLE_CRC */ #endif /* CONFIG_SMARTFS_ERASEDSTATE == 0xff */ /* Now add the format signature to the sector */ dev->rwbuffer[SMART_FMT_POS1] = SMART_FMT_SIG1; dev->rwbuffer[SMART_FMT_POS2] = SMART_FMT_SIG2; dev->rwbuffer[SMART_FMT_POS3] = SMART_FMT_SIG3; dev->rwbuffer[SMART_FMT_POS4] = SMART_FMT_SIG4; dev->rwbuffer[SMART_FMT_VERSION_POS] = SMART_FMT_VERSION; dev->rwbuffer[SMART_FMT_NAMESIZE_POS] = CONFIG_SMARTFS_MAXNAMLEN; /* Record the number of root directory entries we have */ dev->rwbuffer[SMART_FMT_ROOTDIRS_POS] = (uint8_t) (arg & 0xff); #ifdef CONFIG_SMART_CRC_8 sectorheader->crc8 = smart_calc_sector_crc(dev); #elif defined(CONFIG_SMART_CRC_16) *((uint16_t *) sectorheader->crc16) = smart_calc_sector_crc(dev); #elif defined(CONFIG_SMART_CRC_32) *((uint32_t *) sectorheader->crc32) = smart_calc_sector_crc(dev); #endif /* Write the sector to the flash */ wrcount = MTD_BWRITE(dev->mtd, 0, dev->mtdblkspersector, (FAR uint8_t *) dev->rwbuffer); if (wrcount != dev->mtdblkspersector) { /* The block is not empty!! What to do? */ ferr("ERROR: Write block 0 failed: %zu.\n", wrcount); /* Unlock the mutex if we add one */ return -EIO; } /* Now initialize our internal control variables */ ret = smart_setsectorsize(dev, sectorsize); if (ret != OK) { return ret; } dev->formatstatus = SMART_FMT_STAT_UNKNOWN; dev->freesectors = dev->availsectperblk * dev->geo.neraseblocks - 1; dev->releasesectors = 0; #ifdef CONFIG_MTD_SMART_WEAR_LEVEL dev->uneven_wearcount = 0; #endif /* Initialize the released and free counts */ for (x = 0; x < dev->neraseblocks; x++) { /* Test for a geometry with 65536 sectors. We allow this, though * we never use the last two sectors in this mode. */ if (x == dev->neraseblocks && dev->totalsectors == 65534) { prerelease = 2; } else { prerelease = 0; } #ifdef CONFIG_MTD_SMART_PACK_COUNTS smart_set_count(dev, dev->releasecount, x, prerelease); smart_set_count(dev, dev->freecount, x, dev->availsectperblk - prerelease); #else dev->releasecount[x] = prerelease; dev->freecount[x] = dev->availsectperblk - prerelease; #endif } /* Account for the format sector */ #ifdef CONFIG_MTD_SMART_PACK_COUNTS smart_set_count(dev, dev->freecount, 0, dev->availsectperblk - 1); #else dev->freecount[0]--; #endif /* Now initialize the logical to physical sector map */ #ifndef CONFIG_MTD_SMART_MINIMIZE_RAM dev->smap[0] = 0; /* Logical sector zero = physical sector 0 */ for (x = 1; x < dev->totalsectors; x++) { /* Mark all other logical sectors as non-existent */ dev->smap[x] = -1; } #endif #ifdef CONFIG_SMARTFS_MULTI_ROOT_DIRS /* Un-register any extra directory device entries */ for (x = 2; x < 8; x++) { snprintf(dev->rwbuffer, 18, "/dev/smart%dd%d", dev->minor, x); unregister_blockdriver(dev->rwbuffer); } #endif return OK; } /**************************************************************************** * Name: smart_relocate_sector * * Description: Relocates the specified sector to the new sector location. * ****************************************************************************/ static int smart_relocate_sector(FAR struct smart_struct_s *dev, uint16_t oldsector, uint16_t newsector) { size_t offset; FAR struct smart_sect_header_s *header; uint8_t newstatus; int ret; header = (FAR struct smart_sect_header_s *) dev->rwbuffer; /* Increment the sequence number and clear the "commit" flag */ #if SMART_STATUS_VERSION == 1 if ((header->status & SMART_STATUS_CRC) != (CONFIG_SMARTFS_ERASEDSTATE & SMART_STATUS_CRC)) { #endif /* Using 8-bit sequence */ header->seq++; if (header->seq == 0xff) { header->seq = 1; } #if SMART_STATUS_VERSION == 1 } else { /* Using 16-bit sequence and no CRC */ (*((FAR uint16_t *) &header->seq))++; if (*((FAR uint16_t *) &header->seq) == 0xffff) { *((FAR uint16_t *) &header->seq) = 1; } } #endif /* When CRC is enabled, we must pre-commit the sector and also * calculate an updated CRC for the sector prior to writing * since we changed the sequence number. */ #ifdef CONFIG_MTD_SMART_ENABLE_CRC /* First pre-commit the sector */ #if CONFIG_SMARTFS_ERASEDSTATE == 0xff header->status &= ~(SMART_STATUS_COMMITTED | SMART_STATUS_CRC); #else header->status |= SMART_STATUS_COMMITTED | SMART_STATUS_CRC; #endif /* Now calculate the new CRC */ #ifdef CONFIG_SMART_CRC_8 header->crc8 = smart_calc_sector_crc(dev); #elif defined(CONFIG_SMART_CRC_16) *((uint16_t *) header->crc16) = smart_calc_sector_crc(dev); #elif defined(CONFIG_SMART_CRC_32) *((uint32_t *) header->crc32) = smart_calc_sector_crc(dev); #endif /* Write the data to the new physical sector location */ ret = MTD_BWRITE(dev->mtd, newsector * dev->mtdblkspersector, dev->mtdblkspersector, (FAR uint8_t *) dev->rwbuffer); if (ret != dev->mtdblkspersector) { ferr("Error writing to new sector %d\n", newsector); goto errout; } #else /* CONFIG_MTD_SMART_ENABLE_CRC */ #if CONFIG_SMARTFS_ERASEDSTATE == 0xff header->status |= SMART_STATUS_COMMITTED; #else header->status &= ~SMART_STATUS_COMMITTED; #endif /* Write the data to the new physical sector location */ ret = MTD_BWRITE(dev->mtd, newsector * dev->mtdblkspersector, dev->mtdblkspersector, (FAR uint8_t *) dev->rwbuffer); if (ret != dev->mtdblkspersector) { ferr("Error writing to new sector %d\n", newsector); goto errout; } /* Commit the sector */ offset = newsector * dev->mtdblkspersector * dev->geo.blocksize + offsetof(struct smart_sect_header_s, status); #if CONFIG_SMARTFS_ERASEDSTATE == 0xff newstatus = header->status & ~SMART_STATUS_COMMITTED; #else newstatus = header->status | SMART_STATUS_COMMITTED; #endif ret = smart_bytewrite(dev, offset, 1, &newstatus); if (ret < 0) { ferr("ERROR: Error %d committing new sector %d\n" -ret, newsector); goto errout; } #endif /* CONFIG_MTD_SMART_ENABLE_CRC */ /* Release the old physical sector */ #if CONFIG_SMARTFS_ERASEDSTATE == 0xff newstatus = header->status & ~(SMART_STATUS_RELEASED | SMART_STATUS_COMMITTED); #else newstatus = header->status | SMART_STATUS_RELEASED | SMART_STATUS_COMMITTED; #endif offset = oldsector * dev->mtdblkspersector * dev->geo.blocksize + offsetof(struct smart_sect_header_s, status); ret = smart_bytewrite(dev, offset, 1, &newstatus); if (ret < 0) { ferr("ERROR: Error %d releasing old sector %d\n" -ret, oldsector); } errout: return ret; } /**************************************************************************** * Name: smart_relocate_block * * Description: Relocates the specified MTD erase block by moving any * active sectors to a different erase block and then erases * the selected block. * ****************************************************************************/ static int smart_relocate_block(FAR struct smart_struct_s *dev, uint16_t block) { uint16_t newsector; uint16_t oldrelease; int x; int ret; FAR struct smart_sect_header_s *header; uint8_t prerelease; uint16_t freecount; #if defined(CONFIG_SMART_LOCAL_CHECKFREE) && defined(CONFIG_DEBUG_FS) uint16_t releasecount; #endif #ifdef CONFIG_MTD_SMART_ENABLE_CRC FAR struct smart_allocsector_s *allocsector; #endif /* Perform collection on block with the most released sectors. * First mark the block as having no free sectors so we don't * try to move sectors into the block we are trying to erase. */ header = (FAR struct smart_sect_header_s *) dev->rwbuffer; #ifdef CONFIG_SMART_LOCAL_CHECKFREE if (smart_checkfree(dev, __LINE__) != OK) { fwarn(" ...while relocating block %d, free=%d\n", block, dev->freesectors); } #endif #ifdef CONFIG_MTD_SMART_PACK_COUNTS freecount = smart_get_count(dev, dev->freecount, block); #if defined(CONFIG_FS_PROCFS) && !defined(CONFIG_FS_PROCFS_EXCLUDE_SMARTFS) #if defined(CONFIG_SMART_LOCAL_CHECKFREE) && defined(CONFIG_DEBUG_FS) releasecount = smart_get_count(dev, dev->releasecount, block); #endif #endif /* Ensure we aren't relocating a block containing the only free sectors */ if (freecount >= dev->freesectors) { ferr("ERROR: Program bug! " "Relocating the only block (%d) with free sectors!\n", block); ret = -EIO; goto errout; } smart_set_count(dev, dev->freecount, block, 0); #else /* CONFIG_MTD_SMART_PACK_COUNTS */ freecount = dev->freecount[block]; #if defined(CONFIG_FS_PROCFS) && !defined(CONFIG_FS_PROCFS_EXCLUDE_SMARTFS) #if defined(CONFIG_SMART_LOCAL_CHECKFREE) && defined(CONFIG_DEBUG_FS) releasecount = dev->releasecount[block]; #endif #endif dev->freecount[block] = 0; #endif /* Next move all live data in the block to a new home. */ for (x = block * dev->sectorsperblk; x < block * dev->sectorsperblk + dev->availsectperblk; x++) { /* Read the next sector from this erase block */ ret = MTD_BREAD(dev->mtd, x * dev->mtdblkspersector, dev->mtdblkspersector, (FAR uint8_t *) dev->rwbuffer); if (ret != dev->mtdblkspersector) { ferr("ERROR: Error reading sector %d\n", x); ret = -EIO; goto errout; } /* Test if the block is in use */ #ifdef CONFIG_MTD_SMART_ENABLE_CRC /* Check if there is a temporary alloc for this physical sector */ allocsector = dev->allocsector; while (allocsector) { if (allocsector->physical == x) break; allocsector = allocsector->next; } /* If we found a temp allocation, just update the mapped physical * location and move on to the next block ... there is no data to * move yet. */ if (allocsector) { newsector = smart_findfreephyssector(dev, FALSE); if (newsector == 0xffff) { /* Unable to find a free sector!!! */ ferr("ERROR: Can't find a free sector for relocation\n"); ret = -ENOSPC; goto errout; } /* Update the temporary allocation's physical sector */ allocsector->physical = newsector; *((FAR uint16_t *) header->logicalsector) = allocsector->logical; } else #endif { if (((header->status & SMART_STATUS_COMMITTED) == (CONFIG_SMARTFS_ERASEDSTATE & SMART_STATUS_COMMITTED)) || ((header->status & SMART_STATUS_RELEASED) != (CONFIG_SMARTFS_ERASEDSTATE & SMART_STATUS_RELEASED))) { /* This sector doesn't have live data (free or released). * just continue to the next sector and don't move it. */ continue; } /* Find a new sector where it can live, NOT in this erase block */ newsector = smart_findfreephyssector(dev, FALSE); if (newsector == 0xffff) { /* Unable to find a free sector!!! */ ferr("ERROR: Can't find a free sector for relocation\n"); ret = -ENOSPC; goto errout; } /* Relocate the sector data */ if ((ret = smart_relocate_sector(dev, x, newsector)) < 0) { goto errout; } } /* Update the variables */ #ifndef CONFIG_MTD_SMART_MINIMIZE_RAM dev->smap[*((FAR uint16_t *) header->logicalsector)] = newsector; #else smart_update_cache(dev, *((FAR uint16_t *) header->logicalsector), newsector); #endif #ifdef CONFIG_MTD_SMART_PACK_COUNTS smart_add_count(dev, dev->freecount, newsector / dev->sectorsperblk, -1); #else dev->freecount[newsector / dev->sectorsperblk]--; #endif } /* Now erase the erase block */ MTD_ERASE(dev->mtd, block, 1); #if defined(CONFIG_FS_PROCFS) && !defined(CONFIG_FS_PROCFS_EXCLUDE_SMARTFS) dev->unusedsectors += freecount; dev->blockerases++; #endif #ifdef CONFIG_MTD_SMART_SECTOR_ERASE_DEBUG if (dev->erasecounts) { dev->erasecounts[block]++; } #endif #ifdef CONFIG_MTD_SMART_WEAR_LEVEL /* Update the new wear level count */ smart_set_wear_level(dev, block, smart_get_wear_level(dev, block) + 1); #endif /* Update the free and release sectors for this erase block. */ if (x == dev->neraseblocks && dev->totalsectors == 65534) { /* We can't use the last two sectors on a 65536 sector device, * so "pre-release" them so they never get allocated. */ prerelease = 2; } else { prerelease = 0; } #ifdef CONFIG_MTD_SMART_PACK_COUNTS oldrelease = smart_get_count(dev, dev->releasecount, block); dev->freesectors += oldrelease - prerelease; dev->releasesectors -= oldrelease - prerelease; smart_set_count(dev, dev->freecount, block, dev->availsectperblk - prerelease); smart_set_count(dev, dev->releasecount, block, prerelease); #else oldrelease = dev->releasecount[block]; dev->freesectors += oldrelease - prerelease; dev->releasesectors -= oldrelease - prerelease; dev->freecount[block] = dev->availsectperblk - prerelease; dev->releasecount[block] = prerelease; #endif #ifdef CONFIG_SMART_LOCAL_CHECKFREE if (smart_checkfree(dev, __LINE__) != OK) { fwarn(" ...while relocating block %d, " "free=%d, release=%d, oldrelease=%d\n", block, freecount, releasecount, oldrelease); } #endif /* Test if this erase causes the block to reach the full relocate * threshold requiring static data relocation. */ #ifdef CONFIG_MTD_SMART_WEAR_LEVEL smart_relocate_static_data(dev, block); #endif return OK; errout: /* Restore the block's freecount if error */ #ifdef CONFIG_MTD_SMART_PACK_COUNTS smart_set_count(dev, dev->freecount, block, freecount); #else dev->freecount[block] = freecount; #endif return ret; } /**************************************************************************** * Name: smart_findfreephyssector * * Description: Finds a free physical sector based on free and released * count logic, taking into account reserved sectors. * ****************************************************************************/ static int smart_findfreephyssector(FAR struct smart_struct_s *dev, uint8_t canrelocate) { uint16_t count; uint16_t allocfreecount; uint16_t allocblock; #ifdef CONFIG_MTD_SMART_WEAR_LEVEL uint16_t wornfreecount; uint16_t wornblock; uint8_t wearlevel; uint8_t wornlevel; uint8_t maxwearlevel; #endif uint16_t physicalsector; uint16_t block; uint32_t readaddr; struct smart_sect_header_s header; int ret; uint16_t i; /* Determine which erase block we should allocate the new * sector from. This is based on the number of free sectors * available in each erase block. */ #ifdef CONFIG_MTD_SMART_WEAR_LEVEL retry: #endif allocfreecount = 0; allocblock = 0xffff; #ifdef CONFIG_MTD_SMART_WEAR_LEVEL wornfreecount = 0; wornblock = 0xffff; wornlevel = 15; maxwearlevel = 0; #endif physicalsector = 0xffff; if (++dev->lastallocblock >= dev->neraseblocks) { dev->lastallocblock = 0; } block = dev->lastallocblock; for (i = 0; i < dev->neraseblocks; i++) { /* Test if this block has more free blocks than the * currently selected block */ #ifdef CONFIG_MTD_SMART_PACK_COUNTS count = smart_get_count(dev, dev->freecount, block); #else count = dev->freecount[block]; #endif #ifdef CONFIG_MTD_SMART_WEAR_LEVEL /* Keep track of the block with the max free sectors that is worn */ wearlevel = smart_get_wear_level(dev, block); if (wearlevel >= SMART_WEAR_FULL_RELOCATE_THRESHOLD) { if (wearlevel > maxwearlevel && count > 0) { maxwearlevel = wearlevel; } if (count > wornfreecount || (count > 0 && wearlevel < wornlevel)) { /* Keep track of this block. If there are only worn blocks * with free sectors left, then we will use it. */ if (i < dev->neraseblocks - 1 || !wornfreecount) { wornfreecount = count; wornblock = block; wornlevel = wearlevel; } } } else #endif if (count > allocfreecount) { /* Assign this block to alloc from */ if (i < dev->neraseblocks - 1 || !allocfreecount) { allocblock = block; allocfreecount = count; } } if (++block >= dev->neraseblocks) { block = 0; } } /* Check if we found an allocblock. */ if (allocblock == 0xffff) { /* No un-worn blocks with free sectors */ #ifdef CONFIG_MTD_SMART_WEAR_LEVEL /* If we are allowed to relocate unworn blocks then do so now */ if (canrelocate && wornfreecount < (dev->sectorsperblk >> 2) && wornlevel == maxwearlevel) { /* Relocate up to 8 unworn blocks */ block = 0; for (i = 0; i < 8; ) { if (smart_get_wear_level(dev, block) < SMART_WEAR_FORCE_REORG_THRESHOLD) { if (smart_relocate_block(dev, block) < 0) { ferr("ERROR: Error relocating block while finding " "free phys sector\n"); return -1; } i++; } block++; } if (i > 0) { /* Disable relocate for retry */ canrelocate = FALSE; goto retry; } } else { dev->wearflags |= SMART_WEARFLAGS_FORCE_REORG; } /* Test if we found a worn block with free sectors */ if (wornblock != 0xffff) { allocblock = wornblock; } else #endif { char buffer[8 * 12 + 1]; long remaining; int j; int k; ferr("ERROR: Program bug! Expected a free sector, free=%d\n", dev->freesectors); for (i = 0, remaining = dev->neraseblocks; remaining > 0; i += 8, remaining -= 8) { for (j = 0, k = 0; j < 8 && j < remaining ; j++) { snprintf(&buffer[k], sizeof(buffer) - k, "%12d", dev->freecount[i + j]); k += strlen(&buffer[k]); } ferr("%04x:%s\n", i, buffer); } /* No free sectors found! Bug? */ return -ENOSPC; } } /* Now find a free physical sector within this selected erase block to * allocate. */ for (i = allocblock * dev->sectorsperblk; i < allocblock * dev->sectorsperblk + dev->availsectperblk; i++) { /* Check if this physical sector is available. */ #ifdef CONFIG_MTD_SMART_ENABLE_CRC /* First check if there is a temporary alloc in place */ FAR struct smart_allocsector_s *allocsect; allocsect = dev->allocsector; while (allocsect) { if (allocsect->physical == i) { break; } allocsect = allocsect->next; } /* If we found this physical sector above, then continue on * to the next physical sector in this block ... this one has * a temporary allocation assigned. */ if (allocsect) { continue; } #endif /* Now check on the physical media */ readaddr = i * dev->mtdblkspersector * dev->geo.blocksize; ret = MTD_READ(dev->mtd, readaddr, sizeof(struct smart_sect_header_s), (FAR uint8_t *) &header); if (ret != sizeof(struct smart_sect_header_s)) { ferr("ERROR: Error reading phys sector %d\n", physicalsector); return -1; } if ((*((FAR uint16_t *) header.logicalsector) == 0xffff) && #if SMART_STATUS_VERSION == 1 (*((FAR uint16_t *) &header.seq) == 0xffff) && #else (header.seq == CONFIG_SMARTFS_ERASEDSTATE) && #endif ((header.status & SMART_STATUS_COMMITTED) == (CONFIG_SMARTFS_ERASEDSTATE & SMART_STATUS_COMMITTED))) { physicalsector = i; dev->lastallocblock = allocblock; break; } else { /* The FLASH may be not erased in the initial delivery state. * Just in case for the recovery of this fatal situation, * after once erasing the sector, return the sector as a free * sector. */ if (1 == dev->availsectperblk) { MTD_ERASE(dev->mtd, allocblock, 1); physicalsector = i; dev->lastallocblock = allocblock; break; } } } if (physicalsector == 0xffff) { ferr("ERROR: Program bug! Expected a free sector\n"); } if (physicalsector >= dev->totalsectors) { ferr("ERROR: Program bug! Selected sector too big!!!\n"); } return physicalsector; } /**************************************************************************** * Name: smart_garbagecollect * * Description: Performs garbage collection if needed. This is determined * by the count of released sectors relative to free and * total sectors. * ****************************************************************************/ static int smart_garbagecollect(FAR struct smart_struct_s *dev) { uint16_t collectblock; uint16_t releasemax; bool collect = TRUE; int x; int ret; #ifdef CONFIG_MTD_SMART_PACK_COUNTS uint8_t count; #endif while (collect) { collect = FALSE; /* Test if the released sectors count is greater than the * free sectors. If it is, then we will do garbage collection. */ if (dev->releasesectors > dev->freesectors && dev->freesectors < (dev->totalsectors >> 5)) { collect = TRUE; } /* Test if we have more reached our reserved free sector limit */ if (dev->freesectors <= (dev->sectorsperblk << 0) + 4) { collect = TRUE; } /* Test if we need to garbage collect */ if (collect) { /* Find the block with the most released sectors */ collectblock = 0xffff; releasemax = 0; for (x = 0; x < dev->neraseblocks; x++) { #ifdef CONFIG_MTD_SMART_WEAR_LEVEL /* Don't collect blocks that have been worn completely */ if (smart_get_wear_level(dev, x) >= SMART_WEAR_REORG_THRESHOLD) { continue; } #endif #ifdef CONFIG_MTD_SMART_PACK_COUNTS count = smart_get_count(dev, dev->releasecount, x); if (count > releasemax) { releasemax = count; collectblock = x; } #else if (dev->releasecount[x] > releasemax) { releasemax = dev->releasecount[x]; collectblock = x; } #endif } #if 0 releasemax = smart_get_count(dev, dev->releasecount, collectblock); #endif if (collectblock == 0xffff) { /* Need to collect, but no sectors with released blocks! */ ret = -ENOSPC; goto errout; } #ifdef CONFIG_SMART_LOCAL_CHECKFREE if (smart_checkfree(dev, __LINE__) != OK) { fwarn(" ...before collecting block %d\n", collectblock); } #endif #ifdef CONFIG_MTD_SMART_PACK_COUNTS finfo("Collecting block %d, free=%d released=%d, " "totalfree=%d, totalrelease=%d\n", collectblock, smart_get_count(dev, dev->freecount, collectblock), smart_get_count(dev, dev->releasecount, collectblock), dev->freesectors, dev->releasesectors); #else finfo("Collecting block %d, free=%d released=%d\n", collectblock, dev->freecount[collectblock], dev->releasecount[collectblock]); #endif /* Relocate the active data in the collection block */ ret = smart_relocate_block(dev, collectblock); #ifdef CONFIG_SMART_LOCAL_CHECKFREE if (smart_checkfree(dev, __LINE__) != OK) { fwarn(" ...while collecting block %d\n", collectblock); } #endif if (ret != OK) { goto errout; } } } return OK; errout: return ret; } /**************************************************************************** * Name: smart_write_wearstatus * * Description: Writes the wear leveling status bits to sector zero (and * possibly others if it doesn't fit) such that is is persisted * across OS reboots. * ****************************************************************************/ #ifdef CONFIG_MTD_SMART_WEAR_LEVEL static int smart_write_wearstatus(struct smart_struct_s *dev) { uint16_t sector; uint16_t remaining; uint16_t towrite; struct smart_read_write_s req; int ret; uint8_t buffer[8]; uint8_t write_buffer = 0; sector = 0; remaining = dev->geo.neraseblocks >> 1; memset(buffer, 0xff, sizeof(buffer)); #if defined(CONFIG_FS_PROCFS) && !defined(CONFIG_FS_PROCFS_EXCLUDE_SMARTFS) if (dev->blockerases > 0) { *((uint32_t *) buffer) = dev->blockerases; write_buffer = 1; } #endif /* Write the uneven wear count just prior to the wear bits */ if (dev->uneven_wearcount != 0) { *((uint32_t *) &buffer[4]) = dev->uneven_wearcount; write_buffer = 1; } /* Test if we need to write either total block erase count or * uneven wearcount (or both) */ if (write_buffer) { req.logsector = sector; req.offset = SMARTFS_FMT_WEAR_POS - 8; req.count = sizeof(buffer); req.buffer = buffer; ret = smart_writesector(dev, (unsigned long) &req); if (ret != OK) { goto errout; } } /* Write all wear level bits to logical sector zero, one, two */ while (remaining) { /* Calculate the number of bytes to write to this sector */ towrite = remaining; if (towrite > dev->sectorsize - (SMARTFS_FMT_WEAR_POS + sizeof(struct smart_sect_header_s))) { towrite = dev->sectorsize - (SMARTFS_FMT_WEAR_POS + sizeof(struct smart_sect_header_s)); } /* Setup the sector write request (we are our own client) */ req.logsector = sector; req.offset = SMARTFS_FMT_WEAR_POS; req.count = towrite; req.buffer = &dev->wearstatus[(dev->geo.neraseblocks >> SMART_WEAR_BIT_DIVIDE) - remaining]; /* Write the sector */ ret = smart_writesector(dev, (unsigned long) &req); if (ret != OK) { goto errout; } /* Decrement the remaining count */ remaining -= towrite; if (remaining) { /* Data doesn't fit in a single sector. Use the reserved sectors */ sector++; if (sector >= SMART_FIRST_DIR_SECTOR) { /* Error, wear status bit too large! */ ferr("ERROR: Invalid geometry " "- wear level status too large\n"); ret = -EINVAL; goto errout; } } } /* Now clear the NEEDS_WRITE wear status bit */ dev->wearflags &= ~SMART_WEARFLAGS_WRITE_NEEDED; ret = OK; errout: return ret; } #endif /**************************************************************************** * Name: smart_read_wearstatus * * Description: Reads the wear leveling status bits from sector zero (and * possibly others if it doesn't fit) such that is is persisted * across OS reboots. * ****************************************************************************/ #ifdef CONFIG_MTD_SMART_WEAR_LEVEL static inline int smart_read_wearstatus(FAR struct smart_struct_s *dev) { struct smart_read_write_s req; uint16_t sector; uint16_t physsector; uint16_t remaining; uint16_t toread; uint8_t buffer[8]; int ret; /* Prepare to read the total block erases and uneven wearcount values */ sector = 0; req.logsector = sector; req.offset = SMARTFS_FMT_WEAR_POS - 8; req.count = sizeof(buffer); req.buffer = buffer; ret = smart_readsector(dev, (unsigned long) &req); if (ret != sizeof(buffer)) { goto errout; } /* Get the uneven wearcount value */ dev->uneven_wearcount = *((uint32_t *) &buffer[4]); /* Check for erased state */ #if ( CONFIG_SMARTFS_ERASEDSTATE == 0xff ) if (dev->uneven_wearcount == 0xffffffff) { dev->uneven_wearcount = 0; } #endif #if defined(CONFIG_FS_PROCFS) && !defined(CONFIG_FS_PROCFS_EXCLUDE_SMARTFS) /* Get the block erases count */ dev->blockerases = *((uint32_t *) buffer); #if ( CONFIG_SMARTFS_ERASEDSTATE == 0xff ) if (dev->blockerases == 0xffffffff) { dev->blockerases = 0; } #endif #endif /* Read all wear level bits from the flash */ remaining = dev->geo.neraseblocks >> 1; while (remaining) { /* Calculate number of bytes to read from this sector */ toread = remaining; if (toread > dev->sectorsize - (SMARTFS_FMT_WEAR_POS + sizeof(struct smart_sect_header_s))) { toread = dev->sectorsize - (SMARTFS_FMT_WEAR_POS + sizeof(struct smart_sect_header_s)); } /* Setup the sector read request (we are our own client) */ req.logsector = sector; req.offset = SMARTFS_FMT_WEAR_POS; req.count = toread; req.buffer = &dev->wearstatus[(dev->geo.neraseblocks >> SMART_WEAR_BIT_DIVIDE) - remaining]; /* Validate wear status sector has been allocated */ #ifndef CONFIG_MTD_SMART_MINIMIZE_RAM physsector = dev->smap[req.logsector]; #else physsector = smart_cache_lookup(dev, req.logsector); #endif if ((sector != 0) && (physsector == 0xffff)) { /* This logical sector does not exist yet. We must allocate it */ ret = smart_allocsector(dev, sector); if (ret != sector) { ferr("ERROR: Unable to allocate wear level status sector %d\n", sector); ret = -EINVAL; goto errout; } } /* Read the sector */ ret = smart_readsector(dev, (unsigned long) &req); if (ret != toread) { goto errout; } /* Decrement the remaining count */ remaining -= toread; if (remaining) { /* Data doesn't fit in a single sector. Use the reserved sectors */ sector++; if (sector >= SMART_FIRST_DIR_SECTOR) { /* Error, wear status bit too large! */ ferr("ERROR: Invalid geometry " "- wear level status too large\n"); ret = -EINVAL; goto errout; } } } /* Now interrogate the status bits */ smart_find_wear_minmax(dev); #ifdef CONFIG_MTD_SMART_SECTOR_ERASE_DEBUG /* Set the erase counts equal to the wear levels */ for (sector = 0; sector < dev->geo.neraseblocks; sector++) { dev->erasecounts[sector] = smart_get_wear_level(dev, sector); } #endif ret = OK; errout: return ret; } #endif /**************************************************************************** * Name: smart_write_alloc_sector * * Description: Writes a newly allocated sector's header to the RW buffer * and updates sector mapping variables. If CRC isn't enabled * it also writes the header to the device. * ****************************************************************************/ static int smart_write_alloc_sector(FAR struct smart_struct_s *dev, uint16_t logical, uint16_t physical) { int ret = 1; uint8_t sectsize; FAR struct smart_sect_header_s *header; memset(dev->rwbuffer, CONFIG_SMARTFS_ERASEDSTATE, dev->sectorsize); header = (FAR struct smart_sect_header_s *) dev->rwbuffer; *((FAR uint16_t *) header->logicalsector) = logical; #if SMART_STATUS_VERSION == 1 #ifdef CONFIG_MTD_SMART_ENABLE_CRC header->seq = 0; #else *((FAR uint16_t *) &header->seq) = 0; #endif /* CONFIG_MTD_SMART_ENABLE_CRC */ #else header->seq = 0; #endif /* Calculate the 3-bit logical sector size in bits 2-4: * 000b - 256 bytes * 001b - 512 bytes * 010b - 1024 bytes * 100b - 2048 bytes * 011b - 4096 bytes * 101b - 8192 bytes * 110b - 16384 bytes * 110b - 32768 bytes */ sectsize = dev->sectorsize < 4096 ? (dev->sectorsize >> 9) : dev->sectorsize == 4096 ? 3 : 5 + (dev->sectorsize >> 14); sectsize <<= 2; #if CONFIG_SMARTFS_ERASEDSTATE == 0xff header->status = ~(SMART_STATUS_COMMITTED | SMART_STATUS_SIZEBITS | SMART_STATUS_VERBITS) | SMART_STATUS_VERSION | sectsize; #ifdef CONFIG_MTD_SMART_ENABLE_CRC header->status &= ~SMART_STATUS_CRC; #endif /* CONFIG_MTD_SMART_ENABLE_CRC */ #else header->status = SMART_STATUS_COMMITTED | SMART_STATUS_VERSION | sectsize; #ifdef CONFIG_MTD_SMART_ENABLE_CRC header->status |= SMART_STATUS_CRC; #endif /* CONFIG_MTD_SMART_ENABLE_CRC */ #endif /* Write the header to the physical sector location */ #ifndef CONFIG_MTD_SMART_ENABLE_CRC finfo("Write MTD block %d\n", physical * dev->mtdblkspersector); ret = MTD_BWRITE(dev->mtd, physical * dev->mtdblkspersector, 1, (FAR uint8_t *) dev->rwbuffer); if (ret != 1) { /* The block is not empty!! What to do? */ ferr("ERROR: Write block %d failed: %d.\n", physical * dev->mtdblkspersector, ret); /* Unlock the mutex if we add one */ return -EIO; } #endif /* CONFIG_MTD_SMART_ENABLE_CRC */ return ret; } /**************************************************************************** * Name: smart_validate_crc * * Description: Validates the CRC data in the sector's header against the * data in the sector. Assumes the entire sector has been * read into the RW buffer already. * ****************************************************************************/ #ifdef CONFIG_MTD_SMART_ENABLE_CRC static int smart_validate_crc(FAR struct smart_struct_s *dev) { crc_t crc; FAR struct smart_sect_header_s *header; /* Calculate CRC on data region of the sector */ crc = smart_calc_sector_crc(dev); header = (FAR struct smart_sect_header_s *) dev->rwbuffer; #ifdef CONFIG_SMART_CRC_8 /* Test 8-bit CRC */ if (crc != header->crc8) { return -EIO; } #elif defined(CONFIG_SMART_CRC_16) /* Test 16-bit CRC */ if (crc != *((uint16_t *) header->crc16)) { return -EIO; } #elif defined(CONFIG_SMART_CRC_32) if (crc != *((uint32_t *) header->crc32)) { return -EIO; } #endif /* CRC checkout out okay */ return OK; } #endif /**************************************************************************** * Name: smart_writesector * * Description: Writes data to the specified logical sector. The sector * should have already been allocated prior to the write. If * the logical sector already has data on the device, it will * be released and a new physical sector will be created and * mapped to the logical sector. * ****************************************************************************/ static int smart_writesector(FAR struct smart_struct_s *dev, unsigned long arg) { int ret; bool needsrelocate = FALSE; uint32_t mtdblock; uint16_t physsector; uint16_t oldphyssector; uint16_t block; FAR struct smart_read_write_s *req; FAR struct smart_sect_header_s *header; size_t offset; uint8_t byte; #if defined(CONFIG_MTD_SMART_WEAR_LEVEL) || !defined(CONFIG_MTD_SMART_ENABLE_CRC) uint16_t x; #endif #ifdef CONFIG_MTD_SMART_ENABLE_CRC FAR struct smart_allocsector_s *allocsector; #endif finfo("Entry\n"); req = (FAR struct smart_read_write_s *) arg; DEBUGASSERT(req->offset <= dev->sectorsize); DEBUGASSERT(req->offset + req->count <= dev->sectorsize); /* Ensure the logical sector has been allocated */ if (req->logsector >= dev->totalsectors) { ferr("ERROR: Logical sector %d too large\n", req->logsector); ret = -EINVAL; goto errout; } header = (FAR struct smart_sect_header_s *)dev->rwbuffer; #ifdef CONFIG_MTD_SMART_WEAR_LEVEL /* Test if an adjustment to the wear levels is needed */ if (dev->minwearlevel >= SMART_WEAR_MIN_LEVEL || (dev->minwearlevel > 0 && dev->maxwearlevel >= SMART_WEAR_REORG_THRESHOLD)) { /* Subtract dev->minwearlevel from all wear levels */ offset = dev->minwearlevel; finfo("Reducing wear level bits by %zu\n", offset); for (x = 0; x < dev->geo.neraseblocks; x++) { smart_set_wear_level(dev, x, smart_get_wear_level(dev, x) - offset); } dev->minwearlevel -= offset; dev->maxwearlevel -= offset; /* Now write the new wear bits to the flash */ dev->wearflags &= ~SMART_WEARFLAGS_FORCE_REORG; dev->wearflags |= SMART_WEARFLAGS_WRITE_NEEDED; } #endif #ifndef CONFIG_MTD_SMART_MINIMIZE_RAM physsector = dev->smap[req->logsector]; #else physsector = smart_cache_lookup(dev, req->logsector); #endif if (physsector == 0xffff) { ferr("ERROR: Logical sector %d not allocated\n", req->logsector); ret = -EINVAL; goto errout; } /* Read the sector data into our buffer */ mtdblock = physsector * dev->mtdblkspersector; ret = MTD_BREAD(dev->mtd, mtdblock, dev->mtdblkspersector, (FAR uint8_t *) dev->rwbuffer); if (ret != dev->mtdblkspersector) { ferr("ERROR: Error reading phys sector %d\n", physsector); ret = -EIO; goto errout; } /* Test if we need to relocate the sector to perform the write */ #ifdef CONFIG_MTD_SMART_ENABLE_CRC allocsector = dev->allocsector; while (allocsector) { /* Test if the requested logical sector is a temp alloc */ if (allocsector->logical == req->logsector) { break; } allocsector = allocsector->next; } /* When CRC is enabled, then we always have to relocate the sector if * it is not a temporary alloc (i.e. initial alloc before the very first * write operation). */ if (!allocsector) { needsrelocate = TRUE; } #else /* When CRC is not enabled, we may be able to simply add the new data to * the sector if it doesn't conflict with existing data on the device. * Test if there is a conflict in the data. */ for (x = 0; x < req->count; x++) { /* Test if the next byte can be written to the flash */ byte = dev->rwbuffer[sizeof(struct smart_sect_header_s) + req->offset + x]; #if CONFIG_SMARTFS_ERASEDSTATE == 0xff if (((byte ^ req->buffer[x]) | byte) != byte) { needsrelocate = TRUE; break; } #else if (((byte ^ req->buffer[x]) | req->buffer[x]) != req->buffer[x]) { needsrelocate = TRUE; break; } #endif } #endif /* CONFIG_MTD_SMART_ENABLE_CRC */ /* If we are not using CRC and on a device that supports re-writing * bits from 1 to 0 without needing a block erase, such as NOR * FLASH, then we can simply update the data in place and don't need * to relocate the sector. Test if we need to relocate or not. */ if (needsrelocate) { /* Find a new physical sector to save data to */ oldphyssector = physsector; physsector = smart_findfreephyssector(dev, FALSE); if (physsector == 0xffff) { ferr("ERROR: Error relocating sector %d\n", req->logsector); ret = -EIO; goto errout; } /* Update the sequence number to indicate the sector was moved */ #if SMART_STATUS_VERSION == 1 if ((header->status & SMART_STATUS_CRC) != (CONFIG_SMARTFS_ERASEDSTATE & SMART_STATUS_CRC)) { #endif header->seq++; if (header->seq == 0xff) { header->seq = 0; } #if SMART_STATUS_VERSION == 1 } else { (*((FAR uint16_t *) &header->seq))++; if (*((FAR uint16_t *) &header->seq) == 0xffff) *((FAR uint16_t *) &header->seq) = 1; } #else header->seq++; #endif #if CONFIG_SMARTFS_ERASEDSTATE == 0xff header->status |= SMART_STATUS_COMMITTED; #else header->status &= SMART_STATUS_COMMITTED; #endif } #ifdef CONFIG_MTD_SMART_ENABLE_CRC /* When CRC is enabled and we have a temp alloc, then fill in the RW buffer * with the header information prior to copying the write data to the buf. */ if (allocsector) { smart_write_alloc_sector(dev, allocsector->logical, allocsector->physical); /* Remove allocsector from the list and free the memory */ if (dev->allocsector == allocsector) { /* We are the head item. Remove ourselves as head */ dev->allocsector = allocsector->next; } else { FAR struct smart_allocsector_s *prev; /* Start at head and find our entry */ prev = dev->allocsector; while (prev && prev->next != allocsector) { /* Scan the list until we find this entry */ prev = prev->next; } if (prev) { /* Remove from the list */ prev->next = allocsector->next; } } /* Now free the memory */ kmm_free(allocsector); } /* Now copy the data to the sector buffer. */ memcpy(&dev->rwbuffer[sizeof(struct smart_sect_header_s) + req->offset], req->buffer, req->count); /* Commit the sector ahead of time. The CRC will protect us */ #if CONFIG_SMARTFS_ERASEDSTATE == 0xff header->status &= ~(SMART_STATUS_COMMITTED | SMART_STATUS_CRC); #else header->status |= SMART_STATUS_COMMITTED | SMART_STATUS_CRC; #endif /* Now calculate the CRC value for the sector */ #ifdef CONFIG_SMART_CRC_8 header->crc8 = smart_calc_sector_crc(dev); #elif defined(CONFIG_SMART_CRC_16) *((uint16_t *) header->crc16) = smart_calc_sector_crc(dev); #elif defined(CONFIG_SMART_CRC_32) *((uint32_t *) header->crc32) = smart_calc_sector_crc(dev); #endif #else /* CONFIG_MTD_SMART_ENABLE_CRC */ /* Now copy the data to the sector buffer. */ memcpy(&dev->rwbuffer[sizeof(struct smart_sect_header_s) + req->offset], req->buffer, req->count); #endif /* CONFIG_MTD_SMART_ENABLE_CRC */ /* Now write the sector buffer to the device. */ if (needsrelocate) { /* Write the entire sector to the new physical location, uncommitted. */ ret = MTD_BWRITE(dev->mtd, physsector * dev->mtdblkspersector, dev->mtdblkspersector, (FAR uint8_t *) dev->rwbuffer); if (ret != dev->mtdblkspersector) { ferr("ERROR: Error writing to physical sector %d\n", physsector); ret = -EIO; goto errout; } /* Commit the new physical sector */ #ifndef CONFIG_MTD_SMART_ENABLE_CRC #if CONFIG_SMARTFS_ERASEDSTATE == 0xff byte = header->status & ~SMART_STATUS_COMMITTED; #else byte = header->status | SMART_STATUS_COMMITTED; #endif offset = physsector * dev->mtdblkspersector * dev->geo.blocksize + offsetof(struct smart_sect_header_s, status); ret = smart_bytewrite(dev, offset, 1, &byte); if (ret != 1) { finfo("Error committing physical sector %d\n", physsector); ret = -EIO; goto errout; } #endif /* Release the old physical sector */ #if CONFIG_SMARTFS_ERASEDSTATE == 0xff byte = header->status & ~(SMART_STATUS_RELEASED | SMART_STATUS_COMMITTED); #else byte = header->status | SMART_STATUS_RELEASED | SMART_STATUS_COMMITTED; #endif offset = mtdblock * dev->geo.blocksize + offsetof(struct smart_sect_header_s, status); ret = smart_bytewrite(dev, offset, 1, &byte); /* Update releasecount for the released sector and freecount for the * newly allocated physical sector. */ block = oldphyssector / dev->sectorsperblk; #ifdef CONFIG_MTD_SMART_PACK_COUNTS smart_add_count(dev, dev->releasecount, block, 1); smart_add_count(dev, dev->freecount, physsector / dev->sectorsperblk, -1); #else dev->releasecount[block]++; dev->freecount[physsector / dev->sectorsperblk]--; #endif dev->freesectors--; dev->releasesectors++; #ifdef CONFIG_SMART_LOCAL_CHECKFREE /* Perform debug free count checking enabled */ smart_checkfree(dev, __LINE__); #endif /* Update the sector map */ #ifndef CONFIG_MTD_SMART_MINIMIZE_RAM dev->smap[req->logsector] = physsector; #else smart_update_cache(dev, req->logsector, physsector); #endif /* Test if releasing the sector created an empty erase block */ smart_erase_block_if_empty(dev, block, FALSE); /* Since we performed a relocation, do garbage collection to * ensure we don't fill up our flash with released blocks. */ smart_garbagecollect(dev); } else /* needsrelocate */ { #ifdef CONFIG_MTD_SMART_ENABLE_CRC /* Write the entire sector to FLASH when CRC enabled */ ret = MTD_BWRITE(dev->mtd, physsector * dev->mtdblkspersector, dev->mtdblkspersector, (FAR uint8_t *) dev->rwbuffer); if (ret != dev->mtdblkspersector) { ferr("ERROR: Error writing to physical sector %d\n", physsector); ret = -EIO; goto errout; } /* Read the sector back and validate the CRC. */ ret = MTD_BREAD(dev->mtd, physsector * dev->mtdblkspersector, dev->mtdblkspersector, (FAR uint8_t *) dev->rwbuffer); if (ret == dev->mtdblkspersector) { /* Validate the CRC of the read-back data */ ret = smart_validate_crc(dev); } if (ret != OK) { /* TODO: Mark this as a bad block! */ ferr("ERROR: Error validating physical sector %d\n", physsector); ret = -EIO; goto errout; } #else /* Not relocated. Just write the portion of the sector that needs * to be written. */ offset = mtdblock * dev->geo.blocksize + sizeof(struct smart_sect_header_s) + req->offset; ret = smart_bytewrite(dev, offset, req->count, req->buffer); #endif } ret = OK; errout: return ret; } /**************************************************************************** * Name: smart_readsector * * Description: Reads data from the specified logical sector. The sector * should have already been allocated prior to the read. * ****************************************************************************/ static int smart_readsector(FAR struct smart_struct_s *dev, unsigned long arg) { int ret; uint16_t physsector; FAR struct smart_read_write_s *req; #ifdef CONFIG_MTD_SMART_ENABLE_CRC #if SMART_STATUS_VERSION == 1 FAR struct smart_sect_header_s *header; #endif #else uint32_t readaddr; struct smart_sect_header_s header; #endif finfo("Entry\n"); req = (FAR struct smart_read_write_s *) arg; DEBUGASSERT(req->offset < dev->sectorsize); DEBUGASSERT(req->offset + req->count + sizeof(struct smart_sect_header_s) <= dev->sectorsize); /* Ensure the logical sector has been allocated */ if (req->logsector >= dev->totalsectors) { ferr("ERROR: Logical sector %d too large\n", req->logsector); return -EINVAL; } #ifndef CONFIG_MTD_SMART_MINIMIZE_RAM physsector = dev->smap[req->logsector]; #else physsector = smart_cache_lookup(dev, req->logsector); #endif if (physsector == 0xffff) { ferr("ERROR: Logical sector %d not allocated\n", req->logsector); return -EINVAL; } #ifdef CONFIG_MTD_SMART_ENABLE_CRC /* When CRC is enabled, we read the entire sector into RAM so we can * validate the CRC. */ ret = MTD_BREAD(dev->mtd, physsector * dev->mtdblkspersector, dev->mtdblkspersector, (FAR uint8_t *) dev->rwbuffer); if (ret != dev->mtdblkspersector) { /* TODO: Mark the block bad */ ferr("ERROR: Error reading phys sector %d\n", physsector); return -EIO; } #if SMART_STATUS_VERSION == 1 /* Test if this sector has CRC enabled or not */ header = (FAR struct smart_sect_header_s *) dev->rwbuffer; if ((header->status & SMART_STATUS_CRC) == (CONFIG_SMARTFS_ERASEDSTATE & SMART_STATUS_CRC)) { /* Format VERSION 1 supports either no CRC or 8-bit CRC. Looks like * CRC not enabled for this sector, so skip the CRC test. */ } else #endif { /* Validate the read CRC against the calculated sector CRC */ ret = smart_validate_crc(dev); if (ret != OK) { /* TODO: Mark the block bad */ ferr("ERROR: Error validating sector %d CRC during read\n", physsector); return -EIO; } } /* Copy data to the output buffer */ memmove((FAR char *) req->buffer, &dev->rwbuffer[req->offset + sizeof(struct smart_sect_header_s)], req->count); ret = req->count; #else /* CONFIG_MTD_SMART_ENABLE_CRC */ /* Read the sector header data to validate as a sanity check */ ret = MTD_READ(dev->mtd, physsector * dev->mtdblkspersector * dev->geo.blocksize, sizeof(struct smart_sect_header_s), (FAR uint8_t *)&header); if (ret != sizeof(struct smart_sect_header_s)) { ferr("ERROR: Error reading sector %d header\n", physsector); return -EIO; } /* Do a sanity check on the header data */ if (((*(FAR uint16_t *) header.logicalsector) != req->logsector) || ((header.status & SMART_STATUS_COMMITTED) == (CONFIG_SMARTFS_ERASEDSTATE & SMART_STATUS_COMMITTED))) { /* Error in sector header! How do we handle this? */ ferr("ERROR: Error in logical sector %d header, phys=%d\n", req->logsector, physsector); return -EIO; } /* Read the sector data into the buffer */ readaddr = (uint32_t)physsector * dev->mtdblkspersector * dev->geo.blocksize + req->offset + sizeof(struct smart_sect_header_s); ret = MTD_READ(dev->mtd, readaddr, req->count, (FAR uint8_t *) req->buffer); if (ret != req->count) { ferr("ERROR: Error reading phys sector %d\n", physsector); return -EIO; } #endif return ret; } /**************************************************************************** * Name: smart_allocsector * * Description: Allocates a new logical sector. If an argument is given, * then it tries to allocate the specified sector number. * ****************************************************************************/ static inline int smart_allocsector(FAR struct smart_struct_s *dev, unsigned long requested) { uint16_t logsector = 0xffff; /* Logical sector number selected */ uint16_t physicalsector; /* The selected physical sector */ #ifndef CONFIG_MTD_SMART_ENABLE_CRC int ret; #endif int x; /* Validate that we have enough sectors available to perform an * allocation. We have to ensure we keep enough reserved sectors * on hand to do released sector garbage collection. */ if (dev->freesectors <= (dev->sectorsperblk << 0) + 4) { /* Do a garbage collect and then test freesectors again */ if (dev->releasesectors + dev->freesectors > dev->sectorsperblk + 4) { for (x = 0; x < dev->availsectperblk; x++) { smart_garbagecollect(dev); if (dev->freesectors > dev->availsectperblk + 4) { break; } } if (dev->freesectors <= (dev->availsectperblk << 0) + 4) { /* No space left!! */ return -ENOSPC; } } else { /* No space left!! */ return -ENOSPC; } } /* Check if a specific sector is being requested and allocate that * sector if it isn't already in use. */ if ((requested > 0) && (requested < dev->totalsectors)) { /* Validate the sector is not already allocated */ #ifndef CONFIG_MTD_SMART_MINIMIZE_RAM if (dev->smap[requested] == (uint16_t) -1) #else if (!(dev->sbitmap[requested >> 3] & (1 << (requested & 0x07)))) #endif { #ifdef CONFIG_MTD_SMART_ENABLE_CRC FAR struct smart_allocsector_s *allocsect; /* Ensure this logical sector doesn't have a temporary alloc */ allocsect = dev->allocsector; while (allocsect) { if (allocsect->logical == requested) { break; } allocsect = allocsect->next; } if (allocsect != NULL) { } else #endif logsector = requested; } } /* Check if we need to scan for an available logical sector */ if (logsector == 0xffff) { /* Loop through all sectors and find one to allocate */ for (x = SMART_FIRST_ALLOC_SECTOR; x < dev->totalsectors; x++) { #ifndef CONFIG_MTD_SMART_MINIMIZE_RAM if (dev->smap[x] == (uint16_t) -1) #else if (!(dev->sbitmap[x >> 3] & (1 << (x & 0x07)))) #endif { #ifdef CONFIG_MTD_SMART_ENABLE_CRC FAR struct smart_allocsector_s *allocsect; /* Ensure this logical sector doesn't have a temporary alloc * when CRC is enabled. With CRC enabled, when a sector is * allocated, we don't actually update the FLASH until the * very end when we have all data so the CRC can be calculated. * Instead, we keep an in-memory linked list of allocated * sectors until the write sector occurs. */ allocsect = dev->allocsector; while (allocsect) { if (allocsect->logical == x) { break; } allocsect = allocsect->next; } if (allocsect != NULL) { /* This logical sector has an in-memory temp alloc */ continue; } #endif /* Unused logical sector found. Use this one */ logsector = x; break; } } } /* Test for an error allocating a sector */ if (logsector == 0xffff) { /* Hmmm. We think we had enough logical sectors, but * something happened and we didn't find any free * logical sectors. What do do? Report an error? * rescan and try again to "self heal" in case of a * bug in our code? */ ferr("ERROR: No free logical sector numbers! Free sectors = %d\n", dev->freesectors); return -EIO; } /* Check if we need to do garbage collection. We have to * ensure we keep enough reserved free sectors to perform garbage * collection as it involves moving sectors from blocks with * released sectors into blocks with free sectors, then * erasing the vacated block. */ smart_garbagecollect(dev); /* Find a free physical sector */ physicalsector = smart_findfreephyssector(dev, FALSE); finfo("Alloc: log=%d, phys=%d, erase block=%d, free=%d, released=%d\n", logsector, physicalsector, physicalsector / dev->sectorsperblk, dev->freesectors, dev->releasesectors); if (physicalsector == 0xffff) { return -ENOSPC; } #ifdef CONFIG_MTD_SMART_ENABLE_CRC /* When CRC is enabled, we don't write the header to the device until * the data is written via writesector. Just add the allocation to * our temporary allocsector list and we'll pick it up later. */ { FAR struct smart_allocsector_s *allocsect = (FAR struct smart_allocsector_s *) kmm_malloc(sizeof(struct smart_allocsector_s)); if (allocsect == NULL) { ferr("ERROR: Out of memory allocting sector\n"); return -ENOMEM; } /* Fill in the struct and add to the list. We are protected by the * smartfs layer's mutex, so no locking is required. */ allocsect->logical = logsector; allocsect->physical = physicalsector; allocsect->next = dev->allocsector; dev->allocsector = allocsect; } #else /* CONFIG_MTD_SMART_ENABLE_CRC */ /* Write the logical sector to the flash. We will fill it in with data * later. */ ret = smart_write_alloc_sector(dev, logsector, physicalsector); if (ret != 1) { /* Error writing sector, return error */ return ret; } #endif /* CONFIG_MTD_SMART_ENABLE_CRC */ /* Map the sector and update the free sector counts */ #ifndef CONFIG_MTD_SMART_MINIMIZE_RAM dev->smap[logsector] = physicalsector; #else dev->sbitmap[logsector >> 3] |= (1 << (logsector & 0x07)); smart_add_sector_to_cache(dev, logsector, physicalsector, __LINE__); #endif #ifdef CONFIG_MTD_SMART_PACK_COUNTS smart_add_count(dev, dev->freecount, physicalsector / dev->sectorsperblk, -1); #else dev->freecount[physicalsector / dev->sectorsperblk]--; #endif dev->freesectors--; /* Return the logical sector number */ return logsector; } /**************************************************************************** * Name: smart_freesector * * Description: Frees a logical sector from the device. Freeing (also * called releasing) is performed by programming the released * bit in the sector header's status byte. * ****************************************************************************/ static inline int smart_freesector(FAR struct smart_struct_s *dev, unsigned long logicalsector) { int ret; int readaddr; uint16_t physsector; uint16_t block; struct smart_sect_header_s header; size_t offset; /* Check if the logical sector is within bounds */ if ((logicalsector > 2) && (logicalsector < dev->totalsectors)) { /* Validate the sector is actually allocated */ #ifndef CONFIG_MTD_SMART_MINIMIZE_RAM if (dev->smap[logicalsector] == (uint16_t) -1) #else if (!(dev->sbitmap[logicalsector >> 3] & (1 << (logicalsector & 0x07)))) #endif { ferr("ERROR: Invalid release - sector %ld not allocated\n", logicalsector); ret = -EINVAL; goto errout; } } /* Okay to release the sector. Read the sector header info */ #ifndef CONFIG_MTD_SMART_MINIMIZE_RAM physsector = dev->smap[logicalsector]; #else physsector = smart_cache_lookup(dev, logicalsector); #endif readaddr = physsector * dev->mtdblkspersector * dev->geo.blocksize; ret = MTD_READ(dev->mtd, readaddr, sizeof(struct smart_sect_header_s), (FAR uint8_t *) &header); if (ret != sizeof(struct smart_sect_header_s)) { goto errout; } /* Do a sanity check on the logical sector number */ if (*((FAR uint16_t *) header.logicalsector) != (uint16_t) logicalsector) { /* Hmmm... something is wrong. This should always match! Bug in our * code? */ ferr("ERROR: Sector %ld logical sector in header doesn't match\n", logicalsector); ret = -EINVAL; goto errout; } /* Mark the sector as released */ #if CONFIG_SMARTFS_ERASEDSTATE == 0xff header.status &= ~SMART_STATUS_RELEASED; #else header.status |= SMART_STATUS_RELEASED; #endif /* Write the status back to the device */ offset = readaddr + offsetof(struct smart_sect_header_s, status); ret = smart_bytewrite(dev, offset, 1, &header.status); if (ret != 1) { ferr("ERROR: Error updating physical sector %d status\n", physsector); goto errout; } /* Update the erase block's release count */ dev->releasesectors++; block = physsector / dev->sectorsperblk; #ifdef CONFIG_MTD_SMART_PACK_COUNTS smart_add_count(dev, dev->releasecount, block, 1); #else dev->releasecount[block]++; #endif /* Unmap this logical sector */ #ifndef CONFIG_MTD_SMART_MINIMIZE_RAM dev->smap[logicalsector] = (uint16_t) -1; #else dev->sbitmap[logicalsector >> 3] &= ~(1 << (logicalsector & 0x07)); smart_update_cache(dev, logicalsector, 0xffff); #endif /* If this block has only released blocks, then erase it */ smart_erase_block_if_empty(dev, block, FALSE); ret = OK; errout: return ret; } /**************************************************************************** * Name: smart_ioctl * * Description: Return device geometry * ****************************************************************************/ static int smart_ioctl(FAR struct inode *inode, int cmd, unsigned long arg) { FAR struct smart_struct_s *dev; int ret; #if defined(CONFIG_FS_PROCFS) && !defined(CONFIG_FS_PROCFS_EXCLUDE_SMARTFS) FAR struct mtd_smart_procfs_data_s *procfs_data; FAR struct mtd_smart_debug_data_s *debug_data; #endif finfo("Entry\n"); DEBUGASSERT(inode && inode->i_private); #ifdef CONFIG_SMARTFS_MULTI_ROOT_DIRS dev = ((FAR struct smart_multiroot_device_s *)inode->i_private)->dev; #else dev = (FAR struct smart_struct_s *)inode->i_private; #endif /* Process the ioctl's we care about first, pass any we don't respond * to directly to the underlying MTD device. */ switch (cmd) { case BIOC_GETFORMAT: /* Return the format information for the device */ #ifdef CONFIG_SMARTFS_MULTI_ROOT_DIRS ret = smart_getformat(dev, (FAR struct smart_format_s *) arg, ((FAR struct smart_multiroot_device_s *) inode->i_private)->rootdirnum); #else ret = smart_getformat(dev, (FAR struct smart_format_s *) arg); #endif goto ok_out; case BIOC_READSECT: /* Do a logical sector read and return the data */ ret = smart_readsector(dev, arg); goto ok_out; case BIOC_LLFORMAT: /* Perform a low-level format on the flash */ ret = smart_llformat(dev, arg); goto ok_out; case BIOC_ALLOCSECT: /* Ensure the FS is not trying to allocate a reserved sector */ if (arg < 3) { arg = (unsigned long) -1; } /* Allocate a logical sector for the upper layer file system */ ret = smart_allocsector(dev, arg); goto ok_out; case BIOC_FREESECT: /* Free the specified logical sector */ ret = smart_freesector(dev, arg); goto ok_out; case BIOC_WRITESECT: /* Write to the sector */ ret = smart_writesector(dev, arg); #ifdef CONFIG_MTD_SMART_WEAR_LEVEL if (dev->wearflags & SMART_WEARFLAGS_WRITE_NEEDED) { /* Write new wear status bits to the device */ smart_write_wearstatus(dev); } #endif goto ok_out; #if defined(CONFIG_FS_PROCFS) && !defined(CONFIG_FS_PROCFS_EXCLUDE_SMARTFS) case BIOC_GETPROCFSD: /* Get ProcFS data */ procfs_data = (FAR struct mtd_smart_procfs_data_s *)arg; procfs_data->totalsectors = dev->totalsectors; procfs_data->sectorsize = dev->sectorsize; procfs_data->freesectors = dev->freesectors; procfs_data->releasesectors = dev->releasesectors; procfs_data->namelen = dev->namesize; procfs_data->formatversion = dev->formatversion; procfs_data->unusedsectors = dev->unusedsectors; procfs_data->blockerases = dev->blockerases; procfs_data->sectorsperblk = dev->sectorsperblk; #ifndef CONFIG_MTD_SMART_MINIMIZE_RAM procfs_data->formatsector = dev->smap[0]; procfs_data->dirsector = dev->smap[3]; #else procfs_data->formatsector = smart_cache_lookup(dev, 0); procfs_data->dirsector = smart_cache_lookup(dev, 3); #endif #ifdef CONFIG_MTD_SMART_SECTOR_ERASE_DEBUG procfs_data->neraseblocks = dev->geo.neraseblocks; procfs_data->erasecounts = dev->erasecounts; #endif #ifdef CONFIG_MTD_SMART_ALLOC_DEBUG procfs_data->allocs = dev->alloc; procfs_data->alloccount = SMART_MAX_ALLOCS; #endif #ifdef CONFIG_MTD_SMART_WEAR_LEVEL procfs_data->uneven_wearcount = dev->uneven_wearcount; #endif ret = OK; goto ok_out; #endif case BIOC_DEBUGCMD: #if defined(CONFIG_FS_PROCFS) && !defined(CONFIG_FS_PROCFS_EXCLUDE_SMARTFS) debug_data = (FAR struct mtd_smart_debug_data_s *) arg; switch (debug_data->debugcmd) { case SMART_DEBUG_CMD_SET_DEBUG_LEVEL: dev->debuglevel = debug_data->debugdata; finfo("Debug level set to %d\n", dev->debuglevel); ret = OK; goto ok_out; } #endif break; } /* No other block driver ioctl commands are not recognized by this * driver. Other possible MTD driver ioctl commands are passed through * to the MTD driver (unchanged). */ ret = MTD_IOCTL(dev->mtd, cmd, arg); if (ret < 0) { ferr("ERROR: MTD ioctl(%04x) failed: %d\n", cmd, ret); } ok_out: return ret; } #ifdef CONFIG_MTD_SMART_FSCK /**************************************************************************** * Name: smart_fsck_crc * * Description: Validate CRC to check smartfs filesystem * ****************************************************************************/ #ifdef CONFIG_MTD_SMART_FSCK_ENABLE_CRC static int smart_fsck_crc(FAR struct smart_struct_s *dev, uint16_t physsector) { int ret; ret = MTD_BREAD(dev->mtd, physsector * dev->mtdblkspersector, dev->mtdblkspersector, (FAR uint8_t *)dev->rwbuffer); if (ret != dev->mtdblkspersector) { ferr("ERROR: Error reading phys sector %d\n", physsector); return ret; } ret = smart_validate_crc(dev); if (ret != OK) { ferr("ERROR: Error validating sector %d CRC\n", physsector); return ret; } return ret; } #endif /**************************************************************************** * Name: smart_fsck_file * * Description: fsck for file entry * ****************************************************************************/ static int smart_fsck_file(FAR struct smart_struct_s *dev, FAR uint8_t *checkmap, uint16_t logsector) { int ret = OK; ssize_t size; uint32_t readaddress; FAR struct smart_sect_header_s *header; FAR struct smart_chain_header_s *chain; FAR uint8_t *usedmap; size_t mapsize; uint16_t physsector; int i; if (logsector >= dev->totalsectors) { ret = -EINVAL; return ret; } /* Allocate a bitmap table for sectors this file is using */ mapsize = (dev->totalsectors + 7) / 8; usedmap = (FAR uint8_t *)kmm_zalloc(mapsize); if (!usedmap) { ferr("ERROR: Out of memory used map\n"); return OK; } do { /* Read the header for file sector */ #ifndef CONFIG_MTD_SMART_MINIMIZE_RAM physsector = dev->smap[logsector]; #else physsector = smart_cache_lookup(dev, logsector); #endif if (physsector >= dev->totalsectors) { ret = -ENXIO; ferr("ERROR: Invalid phys sector %d\n", physsector); break; } #ifdef CONFIG_MTD_SMART_FSCK_ENABLE_CRC if (smart_fsck_crc(dev, physsector) != OK) { ret = -ENOENT; ferr("ERROR: CRC phys sector %d\n", physsector); break; } #endif readaddress = physsector * dev->mtdblkspersector * dev->geo.blocksize; size = MTD_READ(dev->mtd, readaddress, sizeof(struct smart_sect_header_s) + sizeof(struct smart_chain_header_s), (uint8_t *)dev->rwbuffer); if (size != (sizeof(struct smart_sect_header_s) + sizeof(struct smart_chain_header_s))) { ret = -EIO; ferr("Error reading phys sector %d\n", physsector); break; } header = (struct smart_sect_header_s *) & dev->rwbuffer[0]; chain = (struct smart_chain_header_s *) & dev->rwbuffer[sizeof(struct smart_sect_header_s)]; /* Test if the sector has live data (not free or not released) */ if (((header->status & SMART_STATUS_COMMITTED) == (CONFIG_SMARTFS_ERASEDSTATE & SMART_STATUS_COMMITTED)) || ((header->status & SMART_STATUS_RELEASED) != (CONFIG_SMARTFS_ERASEDSTATE & SMART_STATUS_RELEASED))) { ret = -ENOENT; ferr("ERROR: status(%02x) phys sector %d\n", header->status, physsector); break; } SET_BITMAP(usedmap, logsector); /* next logical sector */ logsector = SMARTFS_NEXTSECTOR(chain); } while (logsector != 0xffff); if (ret == OK) { /* These sectors in use are not removed */ for (i = 0; i < mapsize; i++) { checkmap[i] &= ~usedmap[i]; } } else { /* This file has any corruption, these sectors will be removed */ for (i = 0; i < mapsize; i++) { checkmap[i] |= usedmap[i]; } } kmm_free(usedmap); return ret; } /**************************************************************************** * Name: smart_fsck_directory * * Description: fsck for directory entry * ****************************************************************************/ static int smart_fsck_directory(FAR struct smart_struct_s *dev, FAR uint8_t *checkmap, uint16_t logsector) { int ret = OK; int relocate = 0; ssize_t size; FAR uint8_t *rwbuffer; FAR struct smart_sect_header_s *header; FAR struct smart_chain_header_s *chain; FAR struct smart_entry_header_s *entry; uint16_t entrysector; uint16_t physsector; uint16_t nextsector; uint16_t newsector; int entrysize; FAR uint8_t *bottom; FAR uint8_t *cur; #ifdef CONFIG_DEBUG_FS_INFO char entryname[dev->namesize + 1]; #endif if ((logsector < SMART_FIRST_DIR_SECTOR) || (logsector >= dev->totalsectors)) { ret = -EINVAL; ferr("ERROR: Invalid log sector %d\n", logsector); return ret; } /* Allocate sector buffer for Directory entry */ rwbuffer = (uint8_t *)kmm_malloc(dev->sectorsize); if (!rwbuffer) { ferr("ERROR: Out of memory sector buffer\n"); return OK; } /* Read the Directory entry sector */ #ifndef CONFIG_MTD_SMART_MINIMIZE_RAM physsector = dev->smap[logsector]; #else physsector = smart_cache_lookup(dev, logsector); #endif if (physsector >= dev->totalsectors) { ret = -ENXIO; ferr("ERROR: Invalid phys sector %d\n", physsector); goto errout; } size = MTD_BREAD(dev->mtd, physsector * dev->mtdblkspersector, dev->mtdblkspersector, rwbuffer); if (size != dev->mtdblkspersector) { ret = -EIO; ferr("ERROR: reading phys sector %d\n", physsector); goto errout; } header = (struct smart_sect_header_s *) & rwbuffer[0]; chain = (struct smart_chain_header_s *) & rwbuffer[sizeof(struct smart_sect_header_s)]; entry = (struct smart_entry_header_s *) & rwbuffer[sizeof(struct smart_sect_header_s) + sizeof(struct smart_chain_header_s)]; #ifdef CONFIG_MTD_SMART_FSCK_ENABLE_CRC /* Check CRC */ if (smart_fsck_crc(dev, physsector) != OK) { ret = -ENOENT; ferr("ERROR: CRC phys sector %d\n", physsector); goto errout; } #endif /* Test if the sector has live data (not free or not released) */ if (((header->status & SMART_STATUS_COMMITTED) == (CONFIG_SMARTFS_ERASEDSTATE & SMART_STATUS_COMMITTED)) || ((header->status & SMART_STATUS_RELEASED) != (CONFIG_SMARTFS_ERASEDSTATE & SMART_STATUS_RELEASED))) { ret = -ENOENT; ferr("ERROR: status(%02x) phys sector %d\n", header->status, physsector); goto errout; } /* Check next sector recursively */ nextsector = SMARTFS_NEXTSECTOR(chain); if (nextsector != 0xffff) { finfo("Check next log sector %d\n", nextsector); ret = smart_fsck_directory(dev, checkmap, nextsector); if (ret != OK) { /* Invalidate the next sector */ ferr("Invalidate next log sector %d\n", nextsector); SMARTFS_SET_NEXTSECTOR(chain, 0xffff); /* Set flag to relocate later */ relocate = 1; } } #define SMARTFS_DIRENT_EMPTY 0x8000 /* Set to non-erase state when entry used */ #define SMARTFS_DIRENT_ACTIVE 0x4000 /* Set to erase state when entry is active */ #define SMARTFS_DIRENT_TYPE 0x2000 /* Indicates the type of entry (file/dir) */ #define SMARTFS_DIRENT_DELETING 0x1000 /* Directory entry is being deleted */ #define SMARTFS_DIRENT_RESERVED 0x0E00 /* Reserved bits */ /* Check file or directory under this directory entry */ entrysize = sizeof(struct smart_entry_header_s) + dev->namesize; bottom = rwbuffer + dev->sectorsize; cur = &rwbuffer[sizeof(struct smart_sect_header_s) + sizeof(struct smart_chain_header_s)]; while ((cur + entrysize) <= bottom) { ret = OK; entry = (struct smart_entry_header_s *)cur; if (entry->flags == 0xffff) { /* Test if the empty entry is exist or not? */ break; } #ifdef CONFIG_DEBUG_FS_INFO strlcpy(entryname, (const char *) (cur + sizeof(struct smart_entry_header_s)), sizeof(entryname)); finfo("Check entry (name=%s flags=%02x logsector=%02x)\n", entryname, entry->flags, entry->firstsector); #endif if (entry->flags & SMARTFS_DIRENT_ACTIVE) { entrysector = entry->firstsector; if (entry->flags & SMARTFS_DIRENT_TYPE) { /* This entry is for directory */ ret = smart_fsck_directory(dev, checkmap, entrysector); } else { /* This entry is for file */ ret = smart_fsck_file(dev, checkmap, entrysector); } } if (ret != OK) { #ifdef CONFIG_DEBUG_FS_INFO finfo("Remove entry (name=%s flags=%02x)\n", entryname, entry->flags); #endif if ((cur + (2 * entrysize)) <= bottom) { /* Truncate the current entry and overwrite with next entries */ memmove(cur, cur + entrysize, bottom - (cur + entrysize)); memset(bottom - entrysize, CONFIG_SMARTFS_ERASEDSTATE, entrysize); } else { /* Only erase the current entry if next entry does not * exist */ memset(cur, CONFIG_SMARTFS_ERASEDSTATE, entrysize); cur += entrysize; } relocate = 1; } else { cur += entrysize; } } /* Relocate sector */ if (relocate) { newsector = smart_findfreephyssector(dev, FALSE); if (newsector == 0xffff) { ret = -ENOSPC; ferr("Can't find a free sector for relocation\n"); goto errout; } memcpy(dev->rwbuffer, rwbuffer, dev->sectorsize); ret = smart_relocate_sector(dev, physsector, newsector); if (ret < 0) { ret = -EIO; ferr("Can't relocate\n"); goto errout; } /* Update the variables */ #ifndef CONFIG_MTD_SMART_MINIMIZE_RAM dev->smap[*((FAR uint16_t *)header->logicalsector)] = newsector; #else smart_update_cache(dev, *((FAR uint16_t *)header->logicalsector), newsector); #endif #ifdef CONFIG_MTD_SMART_PACK_COUNTS smart_add_count(dev, dev->freecount, newsector / dev->sectorsperblk, -1); #else dev->freecount[newsector / dev->sectorsperblk]--; #endif } kmm_free(rwbuffer); CLR_BITMAP(checkmap, logsector); return OK; errout: kmm_free(rwbuffer); SET_BITMAP(checkmap, logsector); return ret; } /**************************************************************************** * Name: smart_fsck * * Description: Check and repair the file system * ****************************************************************************/ static int smart_fsck(FAR struct smart_struct_s *dev) { uint16_t logsector; #ifndef CONFIG_MTD_SMART_MINIMIZE_RAM uint16_t physsector; #endif FAR uint8_t *checkmap; size_t mapsize; uint8_t rootdirentries; int x; finfo("Entry\n"); /* Allocate a bitmap table for filesystem check */ mapsize = (dev->totalsectors + 7) / 8; checkmap = (FAR uint8_t *)kmm_zalloc(mapsize); if (!checkmap) { ferr("ERROR: Out of memory fsck map\n"); return -ENOMEM; } /* Set all of the sectors have live data into the check bitmap */ #ifndef CONFIG_MTD_SMART_MINIMIZE_RAM for (logsector = 0; logsector < dev->totalsectors; logsector++) { physsector = dev->smap[logsector]; if (physsector < dev->totalsectors) { SET_BITMAP(checkmap, logsector); } } #else memcpy(checkmap, dev->sbitmap, mapsize); #endif /* Check if the sector can be available from root directories */ #ifdef CONFIG_SMARTFS_MULTI_ROOT_DIRS rootdirentries = dev->rootdirentries; #else rootdirentries = 1; #endif for (x = 0; x < rootdirentries; x++) { smart_fsck_directory(dev, checkmap, SMART_FIRST_DIR_SECTOR + x); } /* Release the invalid sector except for format or directory entry sector */ for (logsector = SMART_FIRST_ALLOC_SECTOR; logsector < dev->totalsectors; logsector++) { if (ISSET_BITMAP(checkmap, logsector)) { smart_freesector(dev, logsector); } } /* Free the bitmap table for filesystem check */ kmm_free(checkmap); return OK; } #endif /* CONFIG_MTD_SMART_FSCK */ /**************************************************************************** * Public Functions ****************************************************************************/ /**************************************************************************** * Name: smart_initialize * * Description: * Initialize to provide a block driver wrapper around an MTD interface * * Input Parameters: * minor - The minor device number. The MTD block device will be * registered as as /dev/smartN where N is the minor number. * mtd - The MTD device that supports the FLASH interface. * ****************************************************************************/ int smart_initialize(int minor, FAR struct mtd_dev_s *mtd, FAR const char *partname) { FAR struct smart_struct_s *dev; int ret = -ENOMEM; uint32_t totalsectors; #ifdef CONFIG_SMARTFS_MULTI_ROOT_DIRS FAR struct smart_multiroot_device_s *rootdirdev = NULL; #endif /* Sanity check */ #ifdef CONFIG_DEBUG_FEATURES if (minor < 0 || minor > 255 || !mtd) { return -EINVAL; } #endif /* Allocate a SMART device structure */ dev = (FAR struct smart_struct_s *) smart_zalloc(NULL, sizeof(struct smart_struct_s), "Dev struct"); if (dev) { /* Initialize the SMART device structure */ dev->mtd = mtd; /* Get the device geometry. (casting to uintptr_t first eliminates * complaints on some architectures where the sizeof long is different * from the size of a pointer). */ /* Set these to zero in case the device doesn't support them */ ret = MTD_IOCTL(mtd, MTDIOC_GEOMETRY, (unsigned long)((uintptr_t)&dev->geo)); if (ret < 0) { ferr("ERROR: MTD ioctl(MTDIOC_GEOMETRY) failed: %d\n", ret); goto errout; } /* Set the sector size to the default for now */ dev->sectorsize = 0; ret = smart_setsectorsize(dev, CONFIG_MTD_SMART_SECTOR_SIZE); if (ret != OK) { goto errout; } /* Calculate the totalsectors on this device and validate */ totalsectors = dev->neraseblocks * dev->sectorsperblk; if (totalsectors > 65536) { ferr("ERROR: SMART Sector size too small for device\n"); ret = -EINVAL; goto errout; } else if (totalsectors == 65536) { totalsectors -= 2; } dev->totalsectors = (uint16_t)totalsectors; dev->freesectors = (uint16_t)dev->availsectperblk * dev->geo.neraseblocks; dev->lastallocblock = 0; dev->debuglevel = 0; /* Mark the device format status an unknown */ dev->formatstatus = SMART_FMT_STAT_UNKNOWN; dev->namesize = CONFIG_SMARTFS_MAXNAMLEN; if (partname) { strlcpy(dev->partname, partname, SMART_PARTNAME_SIZE); } else { dev->partname[0] = '\0'; } #ifdef CONFIG_SMARTFS_MULTI_ROOT_DIRS dev->minor = minor; #endif /* Do a scan of the device */ ret = smart_scan(dev); if (ret < 0) { ferr("ERROR: smart_scan failed: %d\n", -ret); goto errout; } /* Create a MTD block device name */ #ifdef CONFIG_SMARTFS_MULTI_ROOT_DIRS if (partname != NULL) { snprintf(dev->rwbuffer, 18, "/dev/smart%d%sd1", minor, partname); } else { snprintf(dev->rwbuffer, 18, "/dev/smart%dd1", minor); } /* Inode private data is a reference to a struct containing * the SMART device structure and the root directory number. */ rootdirdev = (FAR struct smart_multiroot_device_s *) smart_malloc(dev, sizeof(*rootdirdev), "Root Dir"); if (rootdirdev == NULL) { ferr("ERROR: register_blockdriver failed: %d\n", -ret); ret = -ENOMEM; goto errout; } /* Populate the rootdirdev */ rootdirdev->dev = dev; rootdirdev->rootdirnum = 0; ret = register_blockdriver(dev->rwbuffer, &g_bops, 0, rootdirdev); #else if (partname != NULL) { snprintf(dev->rwbuffer, 18, "/dev/smart%d%s", minor, partname); } else { snprintf(dev->rwbuffer, 18, "/dev/smart%d", minor); } /* Inode private data is a reference to the SMART device structure */ ret = register_blockdriver(dev->rwbuffer, &g_bops, 0, dev); #endif if (ret < 0) { ferr("ERROR: register_blockdriver failed: %d\n", -ret); goto errout; } } return OK; errout: #ifndef CONFIG_MTD_SMART_MINIMIZE_RAM smart_free(dev, dev->smap); #else smart_free(dev, dev->sbitmap); smart_free(dev, dev->scache); #endif smart_free(dev, dev->rwbuffer); #ifdef CONFIG_MTD_SMART_WEAR_LEVEL smart_free(dev, dev->wearstatus); #endif #ifdef CONFIG_MTD_SMART_SECTOR_ERASE_DEBUG smart_free(dev, dev->erasecounts); #endif #ifdef CONFIG_SMARTFS_MULTI_ROOT_DIRS if (rootdirdev) { smart_free(dev, rootdirdev); } #endif kmm_free(dev); return ret; } /**************************************************************************** * Name: smart_loop_register_driver * * Description: * Registers SmartFS Loop Driver ****************************************************************************/ #ifdef CONFIG_SMART_DEV_LOOP int smart_loop_register_driver(void) { return register_driver("/dev/smart", &g_fops, 0666, NULL); } #endif /**************************************************************************** * Name: smart_losetup * * Description: Dynamically setups up a SMART enabled loop device that * is backed by a file. The resulting loop device is a * MTD type block device vs. a generic block device. * ****************************************************************************/ #ifdef CONFIG_SMART_DEV_LOOP static int smart_losetup(int minor, FAR const char *filename, int sectsize, int erasesize, off_t offset, bool readonly) { FAR struct mtd_dev_s *mtd; struct stat sb; int x; int ret; char devpath[20]; /* Try to create a filemtd device using the filename provided */ mtd = filemtd_initialize(filename, offset, sectsize, erasesize); if (mtd == NULL) { return -ENOENT; } /* Check if we need to dynamically assign a minor number */ if (minor == -1) { /* Start at zero and stat /dev/smartX until no entry found. * Searching 0 to 256 should be sufficient. */ for (x = 0; x < 256; x++) { snprintf(devpath, sizeof(devpath), "/dev/smart%d", x); ret = nx_stat(devpath, &sb, 1); if (ret < 0) { /* We can use this minor number */ minor = x; break; } } } /* Now create a smart MTD using the filemtd backing it */ ret = smart_initialize(minor, mtd, NULL); if (ret != OK) { filemtd_teardown(mtd); } return ret; } #endif /* CONFIG_SMART_DEV_LOOP */ /**************************************************************************** * Name: loteardown * * Description: * Undo the setup performed by losetup * ****************************************************************************/ #ifdef CONFIG_SMART_DEV_LOOP static int smart_loteardown(FAR const char *devname) { FAR struct smart_struct_s *dev; FAR struct inode *inode; int ret; /* Sanity check */ #ifdef CONFIG_DEBUG_FEATURES if (!devname) { return -EINVAL; } #endif /* Open the block driver associated with devname so that we can get the * inode reference. */ ret = open_blockdriver(devname, MS_RDONLY, &inode); if (ret < 0) { ferr("ERROR: Failed to open %s: %d\n", devname, -ret); return ret; } /* Inode private data is a reference to the loop device structure */ dev = (FAR struct smart_struct_s *)inode->i_private; /* Validate this is a filemtd backended device */ if (!filemtd_isfilemtd(dev->mtd)) { ferr("ERROR: Device is not a SMART loop: %s\n", devname); return -EINVAL; } close_blockdriver(inode); /* Now teardown the filemtd */ filemtd_teardown(dev->mtd); unregister_blockdriver(devname); kmm_free(dev); return OK; } #endif /* CONFIG_SMART_DEV_LOOP */ /**************************************************************************** * Name: smart_loop_read ****************************************************************************/ #ifdef CONFIG_SMART_DEV_LOOP static ssize_t smart_loop_read(FAR struct file *filep, FAR char *buffer, size_t len) { return 0; /* Return EOF */ } #endif /* CONFIG_SMART_DEV_LOOP */ /**************************************************************************** * Name: smart_loop_write ****************************************************************************/ #ifdef CONFIG_SMART_DEV_LOOP static ssize_t smart_loop_write(FAR struct file *filep, FAR const char *buffer, size_t len) { return len; /* Say that everything was written */ } #endif /* CONFIG_SMART_DEV_LOOP */ /**************************************************************************** * Name: smart_loop_ioctl ****************************************************************************/ #ifdef CONFIG_SMART_DEV_LOOP static int smart_loop_ioctl(FAR struct file *filep, int cmd, unsigned long arg) { int ret; switch (cmd) { /* Command: LOOPIOC_SETUP * Description: Setup the loop device * Argument: A pointer to a read-only instance of struct losetup_s. * Dependencies: The loop device must be enabled (CONFIG_DEV_LOOP=y) */ case SMART_LOOPIOC_SETUP: { FAR struct smart_losetup_s *setup = (FAR struct smart_losetup_s *)((uintptr_t)arg); if (setup == NULL) { ret = -EINVAL; } else { ret = smart_losetup(setup->minor, setup->filename, setup->sectsize, setup->erasesize, setup->offset, setup->readonly); } } break; /* Command: LOOPIOC_TEARDOWN * Description: Teardown a loop device previously setup via * LOOPIOC_SETUP * Argument: A read-able pointer to the path of the device to be * torn down * Dependencies: The loop device must be enabled (CONFIG_DEV_LOOP=y) */ case SMART_LOOPIOC_TEARDOWN: { FAR const char *devname = (FAR const char *)((uintptr_t)arg); if (devname == NULL) { ret = -EINVAL; } else { ret = smart_loteardown(devname); } } break; default: ret = -ENOTTY; } return ret; } #endif /* CONFIG_SMART_DEV_LOOP */