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zephyr/subsys/fs/littlefs_fs.c
Lukasz Majewski c9902412e6 fs: Extend the littlefs code to support block devices 
Up till now the littlefs only has been supporting the flash medium in
Zephyr.

This change provides code to also use littlefs stored on the block
devices - like SD card (accessed via SPI).

When FS_LITTLEFS_BLK_DEV Kconfig option is defined, the support for
using littlefs on block devices is enabled.

Signed-off-by: Lukasz Majewski <lukma@denx.de>
2022-01-17 12:53:43 -05:00

985 lines
23 KiB
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/*
* Copyright (c) 2019 Bolt Innovation Management, LLC
* Copyright (c) 2019 Peter Bigot Consulting, LLC
*
* SPDX-License-Identifier: Apache-2.0
*/
#include <stdio.h>
#include <string.h>
#include <kernel.h>
#include <errno.h>
#include <init.h>
#include <fs/fs.h>
#include <fs/fs_sys.h>
#define LFS_LOG_REGISTER
#include <lfs_util.h>
#include <lfs.h>
#include <fs/littlefs.h>
#include <drivers/flash.h>
#include <storage/flash_map.h>
#include <storage/disk_access.h>
#include "fs_impl.h"
struct lfs_file_data {
struct lfs_file file;
struct lfs_file_config config;
void *cache_block;
};
#define LFS_FILEP(fp) (&((struct lfs_file_data *)(fp->filep))->file)
/* Global memory pool for open files and dirs */
K_MEM_SLAB_DEFINE_STATIC(file_data_pool, sizeof(struct lfs_file_data),
CONFIG_FS_LITTLEFS_NUM_FILES, 4);
K_MEM_SLAB_DEFINE_STATIC(lfs_dir_pool, sizeof(struct lfs_dir),
CONFIG_FS_LITTLEFS_NUM_DIRS, 4);
/* Inferred overhead, in bytes, for each k_heap_aligned allocation for
* the filecache heap. This relates to the CHUNK_UNIT parameter in
* the heap implementation, but that value is not visible outside the
* kernel.
* FIXME: value for this macro should be rather taken from the Kernel
* internals than set by user, but we do not have a way to do so now.
*/
#define FC_HEAP_PER_ALLOC_OVERHEAD CONFIG_FS_LITTLEFS_HEAP_PER_ALLOC_OVERHEAD_SIZE
#if (CONFIG_FS_LITTLEFS_FC_HEAP_SIZE - 0) <= 0
BUILD_ASSERT((CONFIG_FS_LITTLEFS_HEAP_PER_ALLOC_OVERHEAD_SIZE % 8) == 0);
/* Auto-generate heap size from cache size and number of files */
#undef CONFIG_FS_LITTLEFS_FC_HEAP_SIZE
#define CONFIG_FS_LITTLEFS_FC_HEAP_SIZE \
((CONFIG_FS_LITTLEFS_CACHE_SIZE + FC_HEAP_PER_ALLOC_OVERHEAD) * \
CONFIG_FS_LITTLEFS_NUM_FILES)
#endif /* CONFIG_FS_LITTLEFS_FC_HEAP_SIZE */
static K_HEAP_DEFINE(file_cache_heap, CONFIG_FS_LITTLEFS_FC_HEAP_SIZE);
static inline bool littlefs_on_blkdev(struct fs_mount_t *mountp)
{
return IS_ENABLED(CONFIG_FS_LITTLEFS_BLK_DEV) &&
mountp->flags & FS_MOUNT_FLAG_USE_DISK_ACCESS;
}
static inline void *fc_allocate(size_t size)
{
void *ret = NULL;
ret = k_heap_alloc(&file_cache_heap, size, K_NO_WAIT);
return ret;
}
static inline void fc_release(void *buf)
{
k_heap_free(&file_cache_heap, buf);
}
static inline void fs_lock(struct fs_littlefs *fs)
{
k_mutex_lock(&fs->mutex, K_FOREVER);
}
static inline void fs_unlock(struct fs_littlefs *fs)
{
k_mutex_unlock(&fs->mutex);
}
static int lfs_to_errno(int error)
{
if (error >= 0) {
return error;
}
switch (error) {
default:
case LFS_ERR_IO: /* Error during device operation */
return -EIO;
case LFS_ERR_CORRUPT: /* Corrupted */
return -EFAULT;
case LFS_ERR_NOENT: /* No directory entry */
return -ENOENT;
case LFS_ERR_EXIST: /* Entry already exists */
return -EEXIST;
case LFS_ERR_NOTDIR: /* Entry is not a dir */
return -ENOTDIR;
case LFS_ERR_ISDIR: /* Entry is a dir */
return -EISDIR;
case LFS_ERR_NOTEMPTY: /* Dir is not empty */
return -ENOTEMPTY;
case LFS_ERR_BADF: /* Bad file number */
return -EBADF;
case LFS_ERR_FBIG: /* File too large */
return -EFBIG;
case LFS_ERR_INVAL: /* Invalid parameter */
return -EINVAL;
case LFS_ERR_NOSPC: /* No space left on device */
return -ENOSPC;
case LFS_ERR_NOMEM: /* No more memory available */
return -ENOMEM;
}
}
static int errno_to_lfs(int error)
{
if (error >= 0) {
return LFS_ERR_OK;
}
switch (error) {
default:
case -EIO: /* Error during device operation */
return LFS_ERR_IO;
case -EFAULT: /* Corrupted */
return LFS_ERR_CORRUPT;
case -ENOENT: /* No directory entry */
return LFS_ERR_NOENT;
case -EEXIST: /* Entry already exists */
return LFS_ERR_EXIST;
case -ENOTDIR: /* Entry is not a dir */
return LFS_ERR_NOTDIR;
case -EISDIR: /* Entry is a dir */
return LFS_ERR_ISDIR;
case -ENOTEMPTY: /* Dir is not empty */
return LFS_ERR_NOTEMPTY;
case -EBADF: /* Bad file number */
return LFS_ERR_BADF;
case -EFBIG: /* File too large */
return LFS_ERR_FBIG;
case -EINVAL: /* Invalid parameter */
return LFS_ERR_INVAL;
case -ENOSPC: /* No space left on device */
return LFS_ERR_NOSPC;
case -ENOMEM: /* No more memory available */
return LFS_ERR_NOMEM;
}
}
static int lfs_api_read(const struct lfs_config *c, lfs_block_t block,
lfs_off_t off, void *buffer, lfs_size_t size)
{
const struct flash_area *fa = c->context;
size_t offset = block * c->block_size + off;
int rc = flash_area_read(fa, offset, buffer, size);
return errno_to_lfs(rc);
}
static int lfs_api_prog(const struct lfs_config *c, lfs_block_t block,
lfs_off_t off, const void *buffer, lfs_size_t size)
{
const struct flash_area *fa = c->context;
size_t offset = block * c->block_size + off;
int rc = flash_area_write(fa, offset, buffer, size);
return errno_to_lfs(rc);
}
static int lfs_api_erase(const struct lfs_config *c, lfs_block_t block)
{
const struct flash_area *fa = c->context;
size_t offset = block * c->block_size;
int rc = flash_area_erase(fa, offset, c->block_size);
return errno_to_lfs(rc);
}
#ifdef CONFIG_FS_LITTLEFS_BLK_DEV
static int lfs_api_read_blk(const struct lfs_config *c, lfs_block_t block,
lfs_off_t off, void *buffer, lfs_size_t size)
{
const char *disk = c->context;
int rc = disk_access_read(disk, buffer, block,
size / c->block_size);
return errno_to_lfs(rc);
}
static int lfs_api_prog_blk(const struct lfs_config *c, lfs_block_t block,
lfs_off_t off, const void *buffer, lfs_size_t size)
{
const char *disk = c->context;
int rc = disk_access_write(disk, buffer, block, size / c->block_size);
return errno_to_lfs(rc);
}
static int lfs_api_sync_blk(const struct lfs_config *c)
{
const char *disk = c->context;
int rc = disk_access_ioctl(disk, DISK_IOCTL_CTRL_SYNC, NULL);
return errno_to_lfs(rc);
}
#else
static int lfs_api_read_blk(const struct lfs_config *c, lfs_block_t block,
lfs_off_t off, void *buffer, lfs_size_t size)
{
return 0;
}
static int lfs_api_prog_blk(const struct lfs_config *c, lfs_block_t block,
lfs_off_t off, const void *buffer, lfs_size_t size)
{
return 0;
}
static int lfs_api_sync_blk(const struct lfs_config *c)
{
return 0;
}
#endif /* CONFIG_FS_LITTLEFS_BLK_DEV */
static int lfs_api_erase_blk(const struct lfs_config *c, lfs_block_t block)
{
return 0;
}
static int lfs_api_sync(const struct lfs_config *c)
{
return LFS_ERR_OK;
}
static void release_file_data(struct fs_file_t *fp)
{
struct lfs_file_data *fdp = fp->filep;
if (fdp->config.buffer) {
fc_release(fdp->cache_block);
}
k_mem_slab_free(&file_data_pool, &fp->filep);
fp->filep = NULL;
}
static int lfs_flags_from_zephyr(unsigned int zflags)
{
int flags = (zflags & FS_O_CREATE) ? LFS_O_CREAT : 0;
/* LFS_O_READONLY and LFS_O_WRONLY can be selected at the same time,
* this is not a mistake, together they create RDWR access.
*/
flags |= (zflags & FS_O_READ) ? LFS_O_RDONLY : 0;
flags |= (zflags & FS_O_WRITE) ? LFS_O_WRONLY : 0;
flags |= (zflags & FS_O_APPEND) ? LFS_O_APPEND : 0;
return flags;
}
static int littlefs_open(struct fs_file_t *fp, const char *path,
fs_mode_t zflags)
{
struct fs_littlefs *fs = fp->mp->fs_data;
struct lfs *lfs = &fs->lfs;
int flags = lfs_flags_from_zephyr(zflags);
int ret = k_mem_slab_alloc(&file_data_pool, &fp->filep, K_NO_WAIT);
if (ret != 0) {
return ret;
}
struct lfs_file_data *fdp = fp->filep;
memset(fdp, 0, sizeof(*fdp));
fdp->cache_block = fc_allocate(lfs->cfg->cache_size);
if (fdp->cache_block == NULL) {
ret = -ENOMEM;
goto out;
}
fdp->config.buffer = fdp->cache_block;
path = fs_impl_strip_prefix(path, fp->mp);
fs_lock(fs);
ret = lfs_file_opencfg(&fs->lfs, &fdp->file,
path, flags, &fdp->config);
fs_unlock(fs);
out:
if (ret < 0) {
release_file_data(fp);
}
return lfs_to_errno(ret);
}
static int littlefs_close(struct fs_file_t *fp)
{
struct fs_littlefs *fs = fp->mp->fs_data;
fs_lock(fs);
int ret = lfs_file_close(&fs->lfs, LFS_FILEP(fp));
fs_unlock(fs);
release_file_data(fp);
return lfs_to_errno(ret);
}
static int littlefs_unlink(struct fs_mount_t *mountp, const char *path)
{
struct fs_littlefs *fs = mountp->fs_data;
path = fs_impl_strip_prefix(path, mountp);
fs_lock(fs);
int ret = lfs_remove(&fs->lfs, path);
fs_unlock(fs);
return lfs_to_errno(ret);
}
static int littlefs_rename(struct fs_mount_t *mountp, const char *from,
const char *to)
{
struct fs_littlefs *fs = mountp->fs_data;
from = fs_impl_strip_prefix(from, mountp);
to = fs_impl_strip_prefix(to, mountp);
fs_lock(fs);
int ret = lfs_rename(&fs->lfs, from, to);
fs_unlock(fs);
return lfs_to_errno(ret);
}
static ssize_t littlefs_read(struct fs_file_t *fp, void *ptr, size_t len)
{
struct fs_littlefs *fs = fp->mp->fs_data;
fs_lock(fs);
ssize_t ret = lfs_file_read(&fs->lfs, LFS_FILEP(fp), ptr, len);
fs_unlock(fs);
return lfs_to_errno(ret);
}
static ssize_t littlefs_write(struct fs_file_t *fp, const void *ptr, size_t len)
{
struct fs_littlefs *fs = fp->mp->fs_data;
fs_lock(fs);
ssize_t ret = lfs_file_write(&fs->lfs, LFS_FILEP(fp), ptr, len);
fs_unlock(fs);
return lfs_to_errno(ret);
}
BUILD_ASSERT((FS_SEEK_SET == LFS_SEEK_SET)
&& (FS_SEEK_CUR == LFS_SEEK_CUR)
&& (FS_SEEK_END == LFS_SEEK_END));
static int littlefs_seek(struct fs_file_t *fp, off_t off, int whence)
{
struct fs_littlefs *fs = fp->mp->fs_data;
fs_lock(fs);
off_t ret = lfs_file_seek(&fs->lfs, LFS_FILEP(fp), off, whence);
fs_unlock(fs);
if (ret >= 0) {
ret = 0;
}
return lfs_to_errno(ret);
}
static off_t littlefs_tell(struct fs_file_t *fp)
{
struct fs_littlefs *fs = fp->mp->fs_data;
fs_lock(fs);
off_t ret = lfs_file_tell(&fs->lfs, LFS_FILEP(fp));
fs_unlock(fs);
return ret;
}
static int littlefs_truncate(struct fs_file_t *fp, off_t length)
{
struct fs_littlefs *fs = fp->mp->fs_data;
fs_lock(fs);
int ret = lfs_file_truncate(&fs->lfs, LFS_FILEP(fp), length);
fs_unlock(fs);
return lfs_to_errno(ret);
}
static int littlefs_sync(struct fs_file_t *fp)
{
struct fs_littlefs *fs = fp->mp->fs_data;
fs_lock(fs);
int ret = lfs_file_sync(&fs->lfs, LFS_FILEP(fp));
fs_unlock(fs);
return lfs_to_errno(ret);
}
static int littlefs_mkdir(struct fs_mount_t *mountp, const char *path)
{
struct fs_littlefs *fs = mountp->fs_data;
path = fs_impl_strip_prefix(path, mountp);
fs_lock(fs);
int ret = lfs_mkdir(&fs->lfs, path);
fs_unlock(fs);
return lfs_to_errno(ret);
}
static int littlefs_opendir(struct fs_dir_t *dp, const char *path)
{
struct fs_littlefs *fs = dp->mp->fs_data;
if (k_mem_slab_alloc(&lfs_dir_pool, &dp->dirp, K_NO_WAIT) != 0) {
return -ENOMEM;
}
memset(dp->dirp, 0, sizeof(struct lfs_dir));
path = fs_impl_strip_prefix(path, dp->mp);
fs_lock(fs);
int ret = lfs_dir_open(&fs->lfs, dp->dirp, path);
fs_unlock(fs);
if (ret < 0) {
k_mem_slab_free(&lfs_dir_pool, &dp->dirp);
}
return lfs_to_errno(ret);
}
static void info_to_dirent(const struct lfs_info *info, struct fs_dirent *entry)
{
entry->type = ((info->type == LFS_TYPE_DIR) ?
FS_DIR_ENTRY_DIR : FS_DIR_ENTRY_FILE);
entry->size = info->size;
strncpy(entry->name, info->name, sizeof(entry->name));
entry->name[sizeof(entry->name) - 1] = '\0';
}
static int littlefs_readdir(struct fs_dir_t *dp, struct fs_dirent *entry)
{
struct fs_littlefs *fs = dp->mp->fs_data;
fs_lock(fs);
struct lfs_info info;
int ret = lfs_dir_read(&fs->lfs, dp->dirp, &info);
fs_unlock(fs);
if (ret > 0) {
info_to_dirent(&info, entry);
ret = 0;
} else if (ret == 0) {
entry->name[0] = 0;
}
return lfs_to_errno(ret);
}
static int littlefs_closedir(struct fs_dir_t *dp)
{
struct fs_littlefs *fs = dp->mp->fs_data;
fs_lock(fs);
int ret = lfs_dir_close(&fs->lfs, dp->dirp);
fs_unlock(fs);
k_mem_slab_free(&lfs_dir_pool, &dp->dirp);
return lfs_to_errno(ret);
}
static int littlefs_stat(struct fs_mount_t *mountp,
const char *path, struct fs_dirent *entry)
{
struct fs_littlefs *fs = mountp->fs_data;
path = fs_impl_strip_prefix(path, mountp);
fs_lock(fs);
struct lfs_info info;
int ret = lfs_stat(&fs->lfs, path, &info);
fs_unlock(fs);
if (ret >= 0) {
info_to_dirent(&info, entry);
ret = 0;
}
return lfs_to_errno(ret);
}
static int littlefs_statvfs(struct fs_mount_t *mountp,
const char *path, struct fs_statvfs *stat)
{
struct fs_littlefs *fs = mountp->fs_data;
struct lfs *lfs = &fs->lfs;
stat->f_bsize = lfs->cfg->prog_size;
stat->f_frsize = lfs->cfg->block_size;
stat->f_blocks = lfs->cfg->block_count;
path = fs_impl_strip_prefix(path, mountp);
fs_lock(fs);
ssize_t ret = lfs_fs_size(lfs);
fs_unlock(fs);
if (ret >= 0) {
stat->f_bfree = stat->f_blocks - ret;
ret = 0;
}
return lfs_to_errno(ret);
}
/* Return maximum page size in a flash area. There's no flash_area
* API to implement this, so we have to make one here.
*/
struct get_page_ctx {
const struct flash_area *area;
lfs_size_t max_size;
};
static bool get_page_cb(const struct flash_pages_info *info, void *ctxp)
{
struct get_page_ctx *ctx = ctxp;
size_t info_start = info->start_offset;
size_t info_end = info_start + info->size - 1U;
size_t area_start = ctx->area->fa_off;
size_t area_end = area_start + ctx->area->fa_size - 1U;
/* Ignore pages outside the area */
if (info_end < area_start) {
return true;
}
if (info_start > area_end) {
return false;
}
if (info->size > ctx->max_size) {
ctx->max_size = info->size;
}
return true;
}
/* Iterate over all page groups in the flash area and return the
* largest page size we see. This works as long as the partition is
* aligned so that erasing with this size is supported throughout the
* partition.
*/
static lfs_size_t get_block_size(const struct flash_area *fa)
{
struct get_page_ctx ctx = {
.area = fa,
.max_size = 0,
};
const struct device *dev = flash_area_get_device(fa);
flash_page_foreach(dev, get_page_cb, &ctx);
return ctx.max_size;
}
static int littlefs_flash_init(struct fs_mount_t *mountp)
{
unsigned int area_id = (uintptr_t)mountp->storage_dev;
struct fs_littlefs *fs = mountp->fs_data;
const struct flash_area **fap = (const struct flash_area **)&fs->backend;
const struct device *dev;
int ret;
/* Open flash area */
ret = flash_area_open(area_id, fap);
if ((ret < 0) || (*fap == NULL)) {
LOG_ERR("can't open flash area %d", area_id);
return -ENODEV;
}
LOG_DBG("FS area %u at 0x%x for %u bytes", area_id,
(uint32_t)(*fap)->fa_off, (uint32_t)(*fap)->fa_size);
dev = flash_area_get_device(*fap);
if (dev == NULL) {
LOG_ERR("can't get flash device: %s",
log_strdup((*fap)->fa_dev_name));
return -ENODEV;
}
fs->backend = (void *) *fap;
return 0;
}
static int littlefs_mount(struct fs_mount_t *mountp)
{
int ret = 0;
struct fs_littlefs *fs = mountp->fs_data;
bool block_dev = littlefs_on_blkdev(mountp);
LOG_INF("LittleFS version %u.%u, disk version %u.%u",
LFS_VERSION_MAJOR, LFS_VERSION_MINOR,
LFS_DISK_VERSION_MAJOR, LFS_DISK_VERSION_MINOR);
if (fs->backend) {
return -EBUSY;
}
/* Create and take mutex. */
k_mutex_init(&fs->mutex);
fs_lock(fs);
if (IS_ENABLED(CONFIG_FS_LITTLEFS_BLK_DEV) && block_dev) {
fs->backend = mountp->storage_dev;
ret = disk_access_init((char *) fs->backend);
if (ret < 0) {
LOG_ERR("Storage init ERROR!");
goto out;
}
} else {
ret = littlefs_flash_init(mountp);
if (ret < 0) {
goto out;
}
}
BUILD_ASSERT(CONFIG_FS_LITTLEFS_READ_SIZE > 0);
BUILD_ASSERT(CONFIG_FS_LITTLEFS_PROG_SIZE > 0);
BUILD_ASSERT(CONFIG_FS_LITTLEFS_CACHE_SIZE > 0);
BUILD_ASSERT(CONFIG_FS_LITTLEFS_LOOKAHEAD_SIZE > 0);
BUILD_ASSERT((CONFIG_FS_LITTLEFS_LOOKAHEAD_SIZE % 8) == 0);
BUILD_ASSERT((CONFIG_FS_LITTLEFS_CACHE_SIZE
% CONFIG_FS_LITTLEFS_READ_SIZE) == 0);
BUILD_ASSERT((CONFIG_FS_LITTLEFS_CACHE_SIZE
% CONFIG_FS_LITTLEFS_PROG_SIZE) == 0);
struct lfs_config *lcp = &fs->cfg;
lfs_size_t read_size = lcp->read_size;
if (read_size == 0) {
read_size = CONFIG_FS_LITTLEFS_READ_SIZE;
}
lfs_size_t prog_size = lcp->prog_size;
if (prog_size == 0) {
prog_size = CONFIG_FS_LITTLEFS_PROG_SIZE;
}
/* Yes, you can override block size. */
lfs_size_t block_size = lcp->block_size;
if (block_size == 0) {
if (IS_ENABLED(CONFIG_FS_LITTLEFS_BLK_DEV) && block_dev) {
ret = disk_access_ioctl((char *) fs->backend,
DISK_IOCTL_GET_SECTOR_SIZE,
&block_size);
if (ret < 0) {
LOG_ERR("Unable to get sector size");
goto out;
}
} else {
block_size = get_block_size((struct flash_area *)fs->backend);
}
}
if (block_size == 0) {
__ASSERT_NO_MSG(block_size != 0);
ret = -EINVAL;
goto out;
}
int32_t block_cycles = lcp->block_cycles;
if (block_cycles == 0) {
block_cycles = CONFIG_FS_LITTLEFS_BLOCK_CYCLES;
}
if (block_cycles <= 0) {
/* Disable leveling (littlefs v2.1+ semantics) */
block_cycles = -1;
}
lfs_size_t cache_size = lcp->cache_size;
if (cache_size == 0) {
cache_size = CONFIG_FS_LITTLEFS_CACHE_SIZE;
}
lfs_size_t lookahead_size = lcp->lookahead_size;
if (lookahead_size == 0) {
lookahead_size = CONFIG_FS_LITTLEFS_LOOKAHEAD_SIZE;
}
/* No, you don't get to override this. */
lfs_size_t block_count;
if (IS_ENABLED(CONFIG_FS_LITTLEFS_BLK_DEV) && block_dev) {
ret = disk_access_ioctl((char *) fs->backend,
DISK_IOCTL_GET_SECTOR_COUNT,
&block_count);
if (ret < 0) {
LOG_ERR("Unable to get sector count!");
ret = -EINVAL;
goto out;
}
LOG_INF("FS at %s: is %u 0x%x-byte blocks with %u cycle",
(char *) fs->backend, block_count, block_size,
block_cycles);
} else {
block_count = ((struct flash_area *)fs->backend)->fa_size
/ block_size;
const struct device *dev =
flash_area_get_device((struct flash_area *)fs->backend);
LOG_INF("FS at %s:0x%x is %u 0x%x-byte blocks with %u cycle",
log_strdup(dev->name),
(uint32_t)((struct flash_area *)fs->backend)->fa_off,
block_count, block_size, block_cycles);
LOG_INF("sizes: rd %u ; pr %u ; ca %u ; la %u",
read_size, prog_size, cache_size, lookahead_size);
}
__ASSERT_NO_MSG(prog_size != 0);
__ASSERT_NO_MSG(read_size != 0);
__ASSERT_NO_MSG(cache_size != 0);
__ASSERT_NO_MSG(block_size != 0);
__ASSERT((block_size % prog_size) == 0,
"erase size must be multiple of write size");
__ASSERT((block_size % cache_size) == 0,
"cache size incompatible with block size");
lcp->context = fs->backend;
/* Set the validated/defaulted values. */
if (IS_ENABLED(CONFIG_FS_LITTLEFS_BLK_DEV) && block_dev) {
lcp->read = lfs_api_read_blk;
lcp->prog = lfs_api_prog_blk;
lcp->erase = lfs_api_erase_blk;
lcp->read_size = block_size;
lcp->prog_size = block_size;
lcp->cache_size = block_size;
lcp->lookahead_size = block_size * 4;
lcp->sync = lfs_api_sync_blk;
LOG_INF("sizes: rd %u ; pr %u ; ca %u ; la %u",
lcp->read_size, lcp->prog_size, lcp->cache_size,
lcp->lookahead_size);
} else {
__ASSERT((((struct flash_area *)fs->backend)->fa_size %
block_size) == 0,
"partition size must be multiple of block size");
lcp->read = lfs_api_read;
lcp->prog = lfs_api_prog;
lcp->erase = lfs_api_erase;
lcp->read_size = read_size;
lcp->prog_size = prog_size;
lcp->cache_size = cache_size;
lcp->lookahead_size = lookahead_size;
lcp->sync = lfs_api_sync;
}
lcp->block_size = block_size;
lcp->block_count = block_count;
lcp->block_cycles = block_cycles;
/* Mount it, formatting if needed. */
ret = lfs_mount(&fs->lfs, &fs->cfg);
if (ret < 0 &&
(mountp->flags & FS_MOUNT_FLAG_NO_FORMAT) == 0) {
LOG_WRN("can't mount (LFS %d); formatting", ret);
if ((mountp->flags & FS_MOUNT_FLAG_READ_ONLY) == 0) {
ret = lfs_format(&fs->lfs, &fs->cfg);
if (ret < 0) {
LOG_ERR("format failed (LFS %d)", ret);
ret = lfs_to_errno(ret);
goto out;
}
} else {
LOG_ERR("can not format read-only system");
ret = -EROFS;
goto out;
}
ret = lfs_mount(&fs->lfs, &fs->cfg);
if (ret < 0) {
LOG_ERR("remount after format failed (LFS %d)", ret);
ret = lfs_to_errno(ret);
goto out;
}
}
LOG_INF("%s mounted", log_strdup(mountp->mnt_point));
out:
if (ret < 0) {
fs->backend = NULL;
}
fs_unlock(fs);
return ret;
}
static int littlefs_unmount(struct fs_mount_t *mountp)
{
struct fs_littlefs *fs = mountp->fs_data;
fs_lock(fs);
lfs_unmount(&fs->lfs);
if (!littlefs_on_blkdev(mountp)) {
flash_area_close(fs->backend);
}
fs->backend = NULL;
fs_unlock(fs);
LOG_INF("%s unmounted", log_strdup(mountp->mnt_point));
return 0;
}
/* File system interface */
static const struct fs_file_system_t littlefs_fs = {
.open = littlefs_open,
.close = littlefs_close,
.read = littlefs_read,
.write = littlefs_write,
.lseek = littlefs_seek,
.tell = littlefs_tell,
.truncate = littlefs_truncate,
.sync = littlefs_sync,
.opendir = littlefs_opendir,
.readdir = littlefs_readdir,
.closedir = littlefs_closedir,
.mount = littlefs_mount,
.unmount = littlefs_unmount,
.unlink = littlefs_unlink,
.rename = littlefs_rename,
.mkdir = littlefs_mkdir,
.stat = littlefs_stat,
.statvfs = littlefs_statvfs,
};
#define DT_DRV_COMPAT zephyr_fstab_littlefs
#define FS_PARTITION(inst) DT_PHANDLE_BY_IDX(DT_DRV_INST(inst), partition, 0)
#define DEFINE_FS(inst) \
static uint8_t __aligned(4) \
read_buffer_##inst[DT_INST_PROP(inst, cache_size)]; \
static uint8_t __aligned(4) \
prog_buffer_##inst[DT_INST_PROP(inst, cache_size)]; \
static uint32_t lookahead_buffer_##inst[DT_INST_PROP(inst, lookahead_size) \
/ sizeof(uint32_t)]; \
BUILD_ASSERT(DT_INST_PROP(inst, read_size) > 0); \
BUILD_ASSERT(DT_INST_PROP(inst, prog_size) > 0); \
BUILD_ASSERT(DT_INST_PROP(inst, cache_size) > 0); \
BUILD_ASSERT(DT_INST_PROP(inst, lookahead_size) > 0); \
BUILD_ASSERT((DT_INST_PROP(inst, lookahead_size) % 8) == 0); \
BUILD_ASSERT((DT_INST_PROP(inst, cache_size) \
% DT_INST_PROP(inst, read_size)) == 0); \
BUILD_ASSERT((DT_INST_PROP(inst, cache_size) \
% DT_INST_PROP(inst, prog_size)) == 0); \
static struct fs_littlefs fs_data_##inst = { \
.cfg = { \
.read_size = DT_INST_PROP(inst, read_size), \
.prog_size = DT_INST_PROP(inst, prog_size), \
.cache_size = DT_INST_PROP(inst, cache_size), \
.lookahead_size = DT_INST_PROP(inst, lookahead_size), \
.read_buffer = read_buffer_##inst, \
.prog_buffer = prog_buffer_##inst, \
.lookahead_buffer = lookahead_buffer_##inst, \
}, \
}; \
struct fs_mount_t FS_FSTAB_ENTRY(DT_DRV_INST(inst)) = { \
.type = FS_LITTLEFS, \
.mnt_point = DT_INST_PROP(inst, mount_point), \
.fs_data = &fs_data_##inst, \
.storage_dev = (void *)DT_FIXED_PARTITION_ID(FS_PARTITION(inst)), \
.flags = FSTAB_ENTRY_DT_MOUNT_FLAGS(DT_DRV_INST(inst)), \
};
DT_INST_FOREACH_STATUS_OKAY(DEFINE_FS)
#define REFERENCE_MOUNT(inst) (&FS_FSTAB_ENTRY(DT_DRV_INST(inst))),
static void mount_init(struct fs_mount_t *mp)
{
LOG_INF("littlefs partition at %s", mp->mnt_point);
if ((mp->flags & FS_MOUNT_FLAG_AUTOMOUNT) != 0) {
int rc = fs_mount(mp);
if (rc < 0) {
LOG_ERR("Automount %s failed: %d",
mp->mnt_point, rc);
} else {
LOG_INF("Automount %s succeeded",
mp->mnt_point);
}
}
}
static int littlefs_init(const struct device *dev)
{
ARG_UNUSED(dev);
static struct fs_mount_t *partitions[] = {
DT_INST_FOREACH_STATUS_OKAY(REFERENCE_MOUNT)
};
int rc = fs_register(FS_LITTLEFS, &littlefs_fs);
if (rc == 0) {
struct fs_mount_t **mpi = partitions;
while (mpi < (partitions + ARRAY_SIZE(partitions))) {
mount_init(*mpi++);
}
}
return rc;
}
SYS_INIT(littlefs_init, POST_KERNEL, 99);
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