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u-boot/fs/fat/fat.c
Simon Glass 20652517c8 fat: Use standard types for fixed-size values 
Convert all __u8, __u16, and __u32 types to their u8, u16, u32
equivalents throughout the FAT filesystem code.

Series-to: u-boot
Series-cc: heinrich
Cover-letter:
fat: Some code improvements
This is an attempt to improve the structure of the FAT code, since it
doesn't fully follow the U-Boot conventions:

- fat_write.c includes fat.c which is odd
- use of __u32 and its ilk
- use of typedef
- old-style struct comments

This series resolves these problems, making it easier to take on other
improvements in future.
END

Co-developed-by: Claude <noreply@anthropic.com>
Signed-off-by: Simon Glass <simon.glass@canonical.com>
2025-11-13 19:59:03 -07:00

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// SPDX-License-Identifier: GPL-2.0+
/*
* fat.c
*
* R/O (V)FAT 12/16/32 filesystem implementation by Marcus Sundberg
*
* 2002-07-28 - rjones@nexus-tech.net - ported to ppcboot v1.1.6
* 2003-03-10 - kharris@nexus-tech.net - ported to uboot
*/
#define LOG_CATEGORY LOGC_FS
#include <blk.h>
#include <config.h>
#include <exports.h>
#include <fat.h>
#include <fs_legacy.h>
#include <log.h>
#include <asm/byteorder.h>
#include <asm/unaligned.h>
#include <part.h>
#include <malloc.h>
#include <memalign.h>
#include <asm/cache.h>
#include <linux/compiler.h>
#include <linux/ctype.h>
#include <linux/log2.h>
#include "fat_internal.h"
/*
* Convert a string to lowercase. Converts at most 'len' characters,
* 'len' may be larger than the length of 'str' if 'str' is NULL
* terminated.
*/
void downcase(char *str, size_t len)
{
while (*str != '\0' && len--) {
*str = tolower(*str);
str++;
}
}
struct blk_desc *cur_dev;
struct disk_partition cur_part_info;
int disk_read(u32 block, u32 nr_blocks, void *buf)
{
ulong ret;
if (!cur_dev)
return -1;
ret = blk_dread(cur_dev, cur_part_info.start + block, nr_blocks, buf);
if (ret != nr_blocks)
return -1;
return ret;
}
int fat_set_blk_dev(struct blk_desc *dev_desc, struct disk_partition *info)
{
ALLOC_CACHE_ALIGN_BUFFER(unsigned char, buffer, dev_desc->blksz);
cur_dev = dev_desc;
cur_part_info = *info;
/* Make sure it has a valid FAT header */
if (disk_read(0, 1, buffer) != 1) {
cur_dev = NULL;
return -1;
}
/* Check if it's actually a DOS volume */
if (memcmp(buffer + DOS_BOOT_MAGIC_OFFSET, "\x55\xAA", 2)) {
cur_dev = NULL;
return -1;
}
/* Check for FAT12/FAT16/FAT32 filesystem */
if (!memcmp(buffer + DOS_FS_TYPE_OFFSET, "FAT", 3))
return 0;
if (!memcmp(buffer + DOS_FS32_TYPE_OFFSET, "FAT32", 5))
return 0;
cur_dev = NULL;
return -1;
}
int fat_register_device(struct blk_desc *dev_desc, int part_no)
{
struct disk_partition info;
/* First close any currently found FAT filesystem */
cur_dev = NULL;
/* Read the partition table, if present */
if (part_get_info(dev_desc, part_no, &info)) {
if (part_no != 0) {
log_err("Partition %d invalid on device %d\n", part_no,
dev_desc->devnum);
return -1;
}
info.start = 0;
info.size = dev_desc->lba;
info.blksz = dev_desc->blksz;
info.name[0] = 0;
info.type[0] = 0;
info.bootable = 0;
disk_partition_clr_uuid(&info);
}
return fat_set_blk_dev(dev_desc, &info);
}
/*
* Extract zero terminated short name from a directory entry.
*/
static void get_name(struct dir_entry *dirent, char *s_name)
{
char *ptr;
memcpy(s_name, dirent->nameext.name, 8);
s_name[8] = '\0';
ptr = s_name;
while (*ptr && *ptr != ' ')
ptr++;
if (dirent->lcase & CASE_LOWER_BASE)
downcase(s_name, (unsigned)(ptr - s_name));
if (dirent->nameext.ext[0] && dirent->nameext.ext[0] != ' ') {
*ptr++ = '.';
memcpy(ptr, dirent->nameext.ext, 3);
if (dirent->lcase & CASE_LOWER_EXT)
downcase(ptr, 3);
ptr[3] = '\0';
while (*ptr && *ptr != ' ')
ptr++;
}
*ptr = '\0';
if (*s_name == DELETED_FLAG)
*s_name = '\0';
else if (*s_name == aRING)
*s_name = DELETED_FLAG;
}
#if !CONFIG_IS_ENABLED(FAT_WRITE)
/* Stub for read only operation */
int flush_dirty_fat_buffer(struct fsdata *mydata)
{
(void)(mydata);
return 0;
}
#endif
/*
* Get the entry at index 'entry' in a FAT (12/16/32) table.
* On failure 0x00 is returned.
*/
u32 get_fatent(struct fsdata *mydata, u32 entry)
{
u32 bufnum;
u32 offset, off8;
u32 ret = 0x00;
if (CHECK_CLUST(entry, mydata->fatsize)) {
log_err("Invalid FAT entry: %#08x\n", entry);
return ret;
}
switch (mydata->fatsize) {
case 32:
bufnum = entry / FAT32BUFSIZE;
offset = entry - bufnum * FAT32BUFSIZE;
break;
case 16:
bufnum = entry / FAT16BUFSIZE;
offset = entry - bufnum * FAT16BUFSIZE;
break;
case 12:
bufnum = entry / FAT12BUFSIZE;
offset = entry - bufnum * FAT12BUFSIZE;
break;
default:
/* Unsupported FAT size */
return ret;
}
debug("FAT%d: entry: 0x%08x = %d, offset: 0x%04x = %d\n",
mydata->fatsize, entry, entry, offset, offset);
/* Read a new block of FAT entries into the cache. */
if (bufnum != mydata->fatbufnum) {
u32 getsize = FATBUFBLOCKS;
u8 *bufptr = mydata->fatbuf;
u32 fatlength = mydata->fatlength;
u32 startblock = bufnum * FATBUFBLOCKS;
/* Cap length if fatlength is not a multiple of FATBUFBLOCKS */
if (startblock + getsize > fatlength)
getsize = fatlength - startblock;
startblock += mydata->fat_sect; /* Offset from start of disk */
/* Write back the fatbuf to the disk */
if (flush_dirty_fat_buffer(mydata) < 0)
return -1;
if (disk_read(startblock, getsize, bufptr) < 0) {
debug("Error reading FAT blocks\n");
return ret;
}
mydata->fatbufnum = bufnum;
}
/* Get the actual entry from the table */
switch (mydata->fatsize) {
case 32:
ret = FAT2CPU32(((u32 *) mydata->fatbuf)[offset]);
break;
case 16:
ret = FAT2CPU16(((u16 *)mydata->fatbuf)[offset]);
break;
case 12:
off8 = (offset * 3) / 2;
/* fatbut + off8 may be unaligned, read in byte granularity */
ret = mydata->fatbuf[off8] + (mydata->fatbuf[off8 + 1] << 8);
if (offset & 0x1)
ret >>= 4;
ret &= 0xfff;
}
debug("FAT%d: ret: 0x%08x, entry: 0x%08x, offset: 0x%04x\n",
mydata->fatsize, ret, entry, offset);
return ret;
}
/*
* Read at most 'size' bytes from the specified cluster into 'buffer'.
* Return 0 on success, -1 otherwise.
*/
static int
get_cluster(struct fsdata *mydata, u32 clustnum, u8 *buffer, unsigned long size)
{
u32 startsect;
int ret;
if (clustnum > 0) {
startsect = clust_to_sect(mydata, clustnum);
} else {
startsect = mydata->rootdir_sect;
}
debug("gc - clustnum: %d, startsect: %d\n", clustnum, startsect);
if ((unsigned long)buffer & (ARCH_DMA_MINALIGN - 1)) {
ALLOC_CACHE_ALIGN_BUFFER(u8, tmpbuf, mydata->sect_size);
debug("FAT: Misaligned buffer address (%p)\n", buffer);
while (size >= mydata->sect_size) {
ret = disk_read(startsect++, 1, tmpbuf);
if (ret != 1) {
debug("Error reading data (got %d)\n", ret);
return -1;
}
memcpy(buffer, tmpbuf, mydata->sect_size);
buffer += mydata->sect_size;
size -= mydata->sect_size;
}
} else if (size >= mydata->sect_size) {
u32 bytes_read;
u32 sect_count = size / mydata->sect_size;
ret = disk_read(startsect, sect_count, buffer);
if (ret != sect_count) {
debug("Error reading data (got %d)\n", ret);
return -1;
}
bytes_read = sect_count * mydata->sect_size;
startsect += sect_count;
buffer += bytes_read;
size -= bytes_read;
}
if (size) {
ALLOC_CACHE_ALIGN_BUFFER(u8, tmpbuf, mydata->sect_size);
ret = disk_read(startsect, 1, tmpbuf);
if (ret != 1) {
debug("Error reading data (got %d)\n", ret);
return -1;
}
memcpy(buffer, tmpbuf, size);
}
return 0;
}
/**
* get_contents() - read from file
*
* Read at most 'maxsize' bytes from 'pos' in the file associated with 'dentptr'
* into 'buffer'. Update the number of bytes read in *gotsize or return -1 on
* fatal errors.
*
* @mydata: file system description
* @dentprt: directory entry pointer
* @pos: position from where to read
* @buffer: buffer into which to read
* @maxsize: maximum number of bytes to read
* @gotsize: number of bytes actually read
* Return: -1 on error, otherwise 0
*/
static int get_contents(struct fsdata *mydata, struct dir_entry *dentptr, loff_t pos,
u8 *buffer, loff_t maxsize, loff_t *gotsize)
{
loff_t filesize = FAT2CPU32(dentptr->size);
unsigned int bytesperclust = mydata->clust_size * mydata->sect_size;
u32 curclust = START(dentptr);
u32 endclust, newclust;
loff_t actsize;
*gotsize = 0;
debug("Filesize: %llu bytes\n", filesize);
if (pos >= filesize) {
debug("Read position past EOF: %llu\n", pos);
return 0;
}
if (maxsize > 0 && filesize > pos + maxsize)
filesize = pos + maxsize;
debug("%llu bytes\n", filesize);
actsize = bytesperclust;
/* go to cluster at pos */
while (actsize <= pos) {
curclust = get_fatent(mydata, curclust);
if (CHECK_CLUST(curclust, mydata->fatsize)) {
debug("curclust: 0x%x\n", curclust);
printf("Invalid FAT entry\n");
return -1;
}
actsize += bytesperclust;
}
/* actsize > pos */
actsize -= bytesperclust;
filesize -= actsize;
pos -= actsize;
/* align to beginning of next cluster if any */
if (pos) {
u8 *tmp_buffer;
actsize = min(filesize, (loff_t)bytesperclust);
tmp_buffer = malloc_cache_aligned(actsize);
if (!tmp_buffer) {
debug("Error: allocating buffer\n");
return -1;
}
if (get_cluster(mydata, curclust, tmp_buffer, actsize) != 0) {
printf("Error reading cluster\n");
free(tmp_buffer);
return -1;
}
filesize -= actsize;
actsize -= pos;
memcpy(buffer, tmp_buffer + pos, actsize);
free(tmp_buffer);
*gotsize += actsize;
if (!filesize)
return 0;
buffer += actsize;
curclust = get_fatent(mydata, curclust);
if (CHECK_CLUST(curclust, mydata->fatsize)) {
debug("curclust: 0x%x\n", curclust);
printf("Invalid FAT entry\n");
return -1;
}
}
actsize = bytesperclust;
endclust = curclust;
do {
/* search for consecutive clusters */
while (actsize < filesize) {
newclust = get_fatent(mydata, endclust);
if ((newclust - 1) != endclust)
goto getit;
if (CHECK_CLUST(newclust, mydata->fatsize)) {
debug("curclust: 0x%x\n", newclust);
printf("Invalid FAT entry\n");
return -1;
}
endclust = newclust;
actsize += bytesperclust;
}
/* get remaining bytes */
actsize = filesize;
if (get_cluster(mydata, curclust, buffer, (int)actsize) != 0) {
printf("Error reading cluster\n");
return -1;
}
*gotsize += actsize;
return 0;
getit:
if (get_cluster(mydata, curclust, buffer, (int)actsize) != 0) {
printf("Error reading cluster\n");
return -1;
}
*gotsize += (int)actsize;
filesize -= actsize;
buffer += actsize;
curclust = get_fatent(mydata, endclust);
if (CHECK_CLUST(curclust, mydata->fatsize)) {
debug("curclust: 0x%x\n", curclust);
printf("Invalid FAT entry\n");
return -1;
}
actsize = bytesperclust;
endclust = curclust;
} while (1);
}
/*
* Extract the file name information from 'slotptr' into 'l_name',
* starting at l_name[*idx].
* Return 1 if terminator (zero byte) is found, 0 otherwise.
*/
static int slot2str(struct dir_slot *slotptr, char *l_name, int *idx)
{
int j;
for (j = 0; j <= 8; j += 2) {
l_name[*idx] = slotptr->name0_4[j];
if (l_name[*idx] == 0x00)
return 1;
(*idx)++;
}
for (j = 0; j <= 10; j += 2) {
l_name[*idx] = slotptr->name5_10[j];
if (l_name[*idx] == 0x00)
return 1;
(*idx)++;
}
for (j = 0; j <= 2; j += 2) {
l_name[*idx] = slotptr->name11_12[j];
if (l_name[*idx] == 0x00)
return 1;
(*idx)++;
}
return 0;
}
/* Calculate short name checksum */
u8 mkcksum(struct nameext *nameext)
{
int i;
u8 *pos = (void *)nameext;
u8 ret = 0;
for (i = 0; i < 11; i++)
ret = (((ret & 1) << 7) | ((ret & 0xfe) >> 1)) + pos[i];
return ret;
}
/*
* Determine if the FAT type is FAT12 or FAT16
*
* Based on fat_fill_super() from the Linux kernel's fs/fat/inode.c
*/
static int determine_legacy_fat_bits(const struct boot_sector *bs)
{
u16 fat_start = bs->reserved;
u32 dir_start = fat_start + bs->fats * bs->fat_length;
u32 rootdir_sectors = get_unaligned_le16(bs->dir_entries) *
sizeof(struct dir_entry) /
get_unaligned_le16(bs->sector_size);
u32 data_start = dir_start + rootdir_sectors;
u16 sectors = get_unaligned_le16(bs->sectors);
u32 total_sectors = sectors ? sectors : bs->total_sect;
u32 total_clusters = (total_sectors - data_start) /
bs->cluster_size;
return (total_clusters > MAX_FAT12) ? 16 : 12;
}
/*
* Determines if the boot sector's media field is valid
*
* Based on fat_valid_media() from Linux kernel's include/linux/msdos_fs.h
*/
static int fat_valid_media(u8 media)
{
return media >= 0xf8 || media == 0xf0;
}
/*
* Determines if the given boot sector is valid
*
* Based on fat_read_bpb() from the Linux kernel's fs/fat/inode.c
*/
static int is_bootsector_valid(const struct boot_sector *bs)
{
u16 sector_size = get_unaligned_le16(bs->sector_size);
u16 dir_per_block = sector_size / sizeof(struct dir_entry);
if (!bs->reserved)
return 0;
if (!bs->fats)
return 0;
if (!fat_valid_media(bs->media))
return 0;
if (!is_power_of_2(sector_size) ||
sector_size < 512 ||
sector_size > 4096)
return 0;
if (!is_power_of_2(bs->cluster_size))
return 0;
if (!bs->fat_length && !bs->fat32_length)
return 0;
if (get_unaligned_le16(bs->dir_entries) & (dir_per_block - 1))
return 0;
return 1;
}
/*
* Read boot sector and volume info from a FAT filesystem
*/
static int
read_bootsectandvi(struct boot_sector *bs, struct volume_info *volinfo, int *fatsize)
{
u8 *block;
struct volume_info *vistart;
int ret = 0;
if (cur_dev == NULL) {
debug("Error: no device selected\n");
return -1;
}
block = malloc_cache_aligned(cur_dev->blksz);
if (block == NULL) {
debug("Error: allocating block\n");
return -1;
}
if (disk_read(0, 1, block) < 0) {
debug("Error: reading block\n");
ret = -1;
goto out_free;
}
memcpy(bs, block, sizeof(struct boot_sector));
bs->reserved = FAT2CPU16(bs->reserved);
bs->fat_length = FAT2CPU16(bs->fat_length);
bs->secs_track = FAT2CPU16(bs->secs_track);
bs->heads = FAT2CPU16(bs->heads);
bs->total_sect = FAT2CPU32(bs->total_sect);
if (!is_bootsector_valid(bs)) {
debug("Error: bootsector is invalid\n");
ret = -1;
goto out_free;
}
/* FAT32 entries */
if (!bs->fat_length && bs->fat32_length) {
/* Assume FAT32 */
bs->fat32_length = FAT2CPU32(bs->fat32_length);
bs->flags = FAT2CPU16(bs->flags);
bs->root_cluster = FAT2CPU32(bs->root_cluster);
bs->info_sector = FAT2CPU16(bs->info_sector);
bs->backup_boot = FAT2CPU16(bs->backup_boot);
vistart = (struct volume_info *)(block + sizeof(struct boot_sector));
*fatsize = 32;
} else {
vistart = (struct volume_info *)&(bs->fat32_length);
*fatsize = determine_legacy_fat_bits(bs);
}
memcpy(volinfo, vistart, sizeof(struct volume_info));
out_free:
free(block);
return ret;
}
static int get_fs_info(struct fsdata *mydata)
{
struct boot_sector bs;
struct volume_info volinfo;
int ret;
ret = read_bootsectandvi(&bs, &volinfo, &mydata->fatsize);
if (ret) {
debug("Error: reading boot sector\n");
return ret;
}
if (mydata->fatsize == 32) {
mydata->fatlength = bs.fat32_length;
mydata->total_sect = bs.total_sect;
} else {
mydata->fatlength = bs.fat_length;
mydata->total_sect = get_unaligned_le16(bs.sectors);
if (!mydata->total_sect)
mydata->total_sect = bs.total_sect;
}
if (!mydata->total_sect) /* unlikely */
mydata->total_sect = (u32)cur_part_info.size;
mydata->fats = bs.fats;
mydata->fat_sect = bs.reserved;
mydata->rootdir_sect = mydata->fat_sect + mydata->fatlength * bs.fats;
mydata->sect_size = get_unaligned_le16(bs.sector_size);
mydata->clust_size = bs.cluster_size;
if (mydata->sect_size != cur_part_info.blksz) {
log_err("FAT sector size mismatch (fs=%u, dev=%lu)\n",
mydata->sect_size, cur_part_info.blksz);
return -1;
}
if (mydata->clust_size == 0) {
log_err("FAT cluster size not set\n");
return -1;
}
if ((unsigned int)mydata->clust_size * mydata->sect_size >
MAX_CLUSTSIZE) {
log_err("FAT cluster size too big (cs=%u, max=%u)\n",
(uint)mydata->clust_size * mydata->sect_size,
MAX_CLUSTSIZE);
return -1;
}
if (mydata->fatsize == 32) {
mydata->data_begin = mydata->rootdir_sect -
(mydata->clust_size * 2);
mydata->root_cluster = bs.root_cluster;
} else {
mydata->rootdir_size = (get_unaligned_le16(bs.dir_entries) *
sizeof(struct dir_entry)) /
mydata->sect_size;
mydata->data_begin = mydata->rootdir_sect +
mydata->rootdir_size -
(mydata->clust_size * 2);
/*
* The root directory is not cluster-aligned and may be on a
* "negative" cluster, this will be handled specially in
* fat_next_cluster().
*/
mydata->root_cluster = 0;
}
mydata->fatbufnum = -1;
mydata->fat_dirty = 0;
mydata->fatbuf = malloc_cache_aligned(FATBUFSIZE);
if (mydata->fatbuf == NULL) {
debug("Error: allocating memory\n");
return -1;
}
debug("FAT%d, fat_sect: %d, fatlength: %d\n",
mydata->fatsize, mydata->fat_sect, mydata->fatlength);
debug("Rootdir begins at cluster: %d, sector: %d, offset: %x\n"
"Data begins at: %d\n",
mydata->root_cluster,
mydata->rootdir_sect,
mydata->rootdir_sect * mydata->sect_size, mydata->data_begin);
debug("Sector size: %d, cluster size: %d\n", mydata->sect_size,
mydata->clust_size);
return 0;
}
int fat_itr_root(struct fat_itr *itr, struct fsdata *fsdata)
{
if (get_fs_info(fsdata))
return -ENXIO;
itr->fsdata = fsdata;
itr->start_clust = fsdata->root_cluster;
itr->clust = fsdata->root_cluster;
itr->next_clust = fsdata->root_cluster;
itr->dent = NULL;
itr->remaining = 0;
itr->last_cluster = 0;
itr->is_root = 1;
return 0;
}
void fat_itr_child(struct fat_itr *itr, struct fat_itr *parent)
{
struct fsdata *mydata = parent->fsdata; /* for silly macros */
unsigned clustnum = START(parent->dent);
assert(fat_itr_isdir(parent));
itr->fsdata = parent->fsdata;
itr->start_clust = clustnum;
if (clustnum > 0) {
itr->clust = clustnum;
itr->next_clust = clustnum;
itr->is_root = 0;
} else {
itr->clust = parent->fsdata->root_cluster;
itr->next_clust = parent->fsdata->root_cluster;
itr->start_clust = parent->fsdata->root_cluster;
itr->is_root = 1;
}
itr->dent = NULL;
itr->remaining = 0;
itr->last_cluster = 0;
}
/**
* fat_next_cluster() - load next FAT cluster
*
* The function is used when iterating through directories. It loads the
* next cluster with directory entries
*
* @itr: directory iterator
* @nbytes: number of bytes read, 0 on error
* Return: first directory entry, NULL on error
*/
void *fat_next_cluster(struct fat_itr *itr, unsigned int *nbytes)
{
int ret;
u32 sect;
u32 read_size;
/* have we reached the end? */
if (itr->last_cluster)
return NULL;
if (itr->is_root && itr->fsdata->fatsize != 32) {
/*
* The root directory is located before the data area and
* cannot be indexed using the regular unsigned cluster
* numbers (it may start at a "negative" cluster or not at a
* cluster boundary at all), so consider itr->next_clust to be
* a offset in cluster-sized units from the start of rootdir.
*/
unsigned sect_offset = itr->next_clust * itr->fsdata->clust_size;
unsigned remaining_sects = itr->fsdata->rootdir_size - sect_offset;
sect = itr->fsdata->rootdir_sect + sect_offset;
/* do not read past the end of rootdir */
read_size = min_t(u32, itr->fsdata->clust_size,
remaining_sects);
} else {
sect = clust_to_sect(itr->fsdata, itr->next_clust);
read_size = itr->fsdata->clust_size;
}
log_debug("FAT read(sect=%d), clust_size=%d, read_size=%u\n",
sect, itr->fsdata->clust_size, read_size);
/*
* NOTE: do_fat_read_at() had complicated logic to deal w/
* vfat names that span multiple clusters in the fat16 case,
* which get_dentfromdir() probably also needed (and was
* missing). And not entirely sure what fat32 didn't have
* the same issue.. We solve that by only caring about one
* dent at a time and iteratively constructing the vfat long
* name.
*/
ret = disk_read(sect, read_size, itr->block);
if (ret < 0) {
debug("Error: reading block\n");
return NULL;
}
*nbytes = read_size * itr->fsdata->sect_size;
itr->clust = itr->next_clust;
if (itr->is_root && itr->fsdata->fatsize != 32) {
itr->next_clust++;
if (itr->next_clust * itr->fsdata->clust_size >=
itr->fsdata->rootdir_size) {
debug("nextclust: 0x%x\n", itr->next_clust);
itr->last_cluster = 1;
}
} else {
itr->next_clust = get_fatent(itr->fsdata, itr->next_clust);
if (CHECK_CLUST(itr->next_clust, itr->fsdata->fatsize)) {
debug("nextclust: 0x%x\n", itr->next_clust);
itr->last_cluster = 1;
}
}
return itr->block;
}
struct dir_entry *next_dent(struct fat_itr *itr)
{
if (itr->remaining == 0) {
unsigned nbytes;
struct dir_entry *dent = fat_next_cluster(itr, &nbytes);
/* have we reached the last cluster? */
if (!dent) {
/* a sign for no more entries left */
itr->dent = NULL;
return NULL;
}
itr->remaining = nbytes / sizeof(struct dir_entry) - 1;
itr->dent = dent;
} else {
itr->remaining--;
itr->dent++;
}
/* have we reached the last valid entry? */
if (itr->dent->nameext.name[0] == 0)
return NULL;
return itr->dent;
}
static struct dir_entry *extract_vfat_name(struct fat_itr *itr)
{
struct dir_entry *dent = itr->dent;
int seqn = itr->dent->nameext.name[0] & ~LAST_LONG_ENTRY_MASK;
u8 chksum, alias_checksum = ((struct dir_slot *)dent)->alias_checksum;
int n = 0;
while (seqn--) {
char buf[13];
int idx = 0;
slot2str((struct dir_slot *)dent, buf, &idx);
if (n + idx >= sizeof(itr->l_name))
return NULL;
/* shift accumulated long-name up and copy new part in: */
memmove(itr->l_name + idx, itr->l_name, n);
memcpy(itr->l_name, buf, idx);
n += idx;
dent = next_dent(itr);
if (!dent)
return NULL;
}
/*
* We are now at the short file name entry.
* If it is marked as deleted, just skip it.
*/
if (dent->nameext.name[0] == DELETED_FLAG ||
dent->nameext.name[0] == aRING)
return NULL;
itr->l_name[n] = '\0';
chksum = mkcksum(&dent->nameext);
/* checksum mismatch could mean deleted file, etc.. skip it: */
if (chksum != alias_checksum) {
debug("** chksum=%x, alias_checksum=%x, l_name=%s, s_name=%8s.%3s\n",
chksum, alias_checksum, itr->l_name, dent->nameext.name,
dent->nameext.ext);
return NULL;
}
return dent;
}
int fat_itr_next(struct fat_itr *itr)
{
struct dir_entry *dent;
itr->name = NULL;
/*
* One logical directory entry consist of following slots:
* name[0] Attributes
* dent[N - N]: LFN[N - 1] N|0x40 ATTR_VFAT
* ...
* dent[N - 2]: LFN[1] 2 ATTR_VFAT
* dent[N - 1]: LFN[0] 1 ATTR_VFAT
* dent[N]: SFN ATTR_ARCH
*/
while (1) {
dent = next_dent(itr);
if (!dent) {
itr->dent_start = NULL;
return 0;
}
itr->dent_rem = itr->remaining;
itr->dent_start = itr->dent;
itr->dent_clust = itr->clust;
if (dent->nameext.name[0] == DELETED_FLAG)
continue;
if (dent->attr & ATTR_VOLUME) {
if ((dent->attr & ATTR_VFAT) == ATTR_VFAT &&
(dent->nameext.name[0] & LAST_LONG_ENTRY_MASK)) {
/* long file name */
dent = extract_vfat_name(itr);
/*
* If succeeded, dent has a valid short file
* name entry for the current entry.
* If failed, itr points to a current bogus
* entry. So after fetching a next one,
* it may have a short file name entry
* for this bogus entry so that we can still
* check for a short name.
*/
if (!dent)
continue;
itr->name = itr->l_name;
break;
} else {
/* Volume label or VFAT entry, skip */
continue;
}
}
/* short file name */
break;
}
get_name(dent, itr->s_name);
if (!itr->name)
itr->name = itr->s_name;
return 1;
}
int fat_itr_isdir(struct fat_itr *itr)
{
return !!(itr->dent->attr & ATTR_DIR);
}
int fat_itr_resolve(struct fat_itr *itr, const char *path, uint type)
{
const char *next;
/* chomp any extra leading slashes: */
while (path[0] && ISDIRDELIM(path[0]))
path++;
/* are we at the end? */
if (strlen(path) == 0) {
if (!(type & TYPE_DIR))
return -ENOENT;
return 0;
}
/* find length of next path entry: */
next = path;
while (next[0] && !ISDIRDELIM(next[0]))
next++;
if (itr->is_root) {
/* root dir doesn't have "." nor ".." */
if ((((next - path) == 1) && !strncmp(path, ".", 1)) ||
(((next - path) == 2) && !strncmp(path, "..", 2))) {
/* point back to itself */
itr->clust = itr->fsdata->root_cluster;
itr->next_clust = itr->fsdata->root_cluster;
itr->start_clust = itr->fsdata->root_cluster;
itr->dent = NULL;
itr->remaining = 0;
itr->last_cluster = 0;
if (next[0] == 0) {
if (type & TYPE_DIR)
return 0;
else
return -ENOENT;
}
return fat_itr_resolve(itr, next, type);
}
}
while (fat_itr_next(itr)) {
int match = 0;
unsigned n = max(strlen(itr->name), (size_t)(next - path));
/* check both long and short name: */
if (!strncasecmp(path, itr->name, n))
match = 1;
else if (itr->name != itr->s_name &&
!strncasecmp(path, itr->s_name, n))
match = 1;
if (!match)
continue;
if (fat_itr_isdir(itr)) {
/* recurse into directory: */
fat_itr_child(itr, itr);
return fat_itr_resolve(itr, next, type);
} else if (next[0]) {
/*
* If next is not empty then we have a case
* like: /path/to/realfile/nonsense
*/
debug("bad trailing path: %s\n", next);
return -ENOENT;
} else if (!(type & TYPE_FILE)) {
return -ENOTDIR;
} else {
return 0;
}
}
return -ENOENT;
}
int file_fat_detectfs(void)
{
struct boot_sector bs;
struct volume_info volinfo;
int fatsize;
char vol_label[12];
if (cur_dev == NULL) {
printf("No current device\n");
return 1;
}
if (blk_enabled()) {
printf("Interface: %s\n", blk_get_uclass_name(cur_dev->uclass_id));
printf(" Device %d: ", cur_dev->devnum);
dev_print(cur_dev);
}
if (read_bootsectandvi(&bs, &volinfo, &fatsize)) {
printf("\nNo valid FAT fs found\n");
return 1;
}
memcpy(vol_label, volinfo.volume_label, 11);
vol_label[11] = '\0';
printf("Filesystem: FAT%d \"%s\"\n", fatsize, vol_label);
return 0;
}
int fat_exists(const char *filename)
{
struct fsdata fsdata;
struct fat_itr *itr;
int ret;
itr = malloc_cache_aligned(sizeof(struct fat_itr));
if (!itr)
return 0;
ret = fat_itr_root(itr, &fsdata);
if (ret)
goto out;
ret = fat_itr_resolve(itr, filename, TYPE_ANY);
free(fsdata.fatbuf);
out:
free(itr);
return ret == 0;
}
/**
* fat2rtc() - convert FAT time stamp to RTC file stamp
*
* @date: FAT date
* @time: FAT time
* @tm: RTC time stamp
*/
static void __maybe_unused fat2rtc(u16 date, u16 time, struct rtc_time *tm)
{
tm->tm_mday = date & 0x1f;
tm->tm_mon = (date & 0x1e0) >> 5;
tm->tm_year = (date >> 9) + 1980;
tm->tm_sec = (time & 0x1f) << 1;
tm->tm_min = (time & 0x7e0) >> 5;
tm->tm_hour = time >> 11;
rtc_calc_weekday(tm);
tm->tm_yday = 0;
tm->tm_isdst = 0;
}
int fat_size(const char *filename, loff_t *size)
{
struct fsdata fsdata;
struct fat_itr *itr;
int ret;
itr = malloc_cache_aligned(sizeof(struct fat_itr));
if (!itr)
return -ENOMEM;
ret = fat_itr_root(itr, &fsdata);
if (ret)
goto out_free_itr;
ret = fat_itr_resolve(itr, filename, TYPE_FILE);
if (ret) {
/*
* Directories don't have size, but fs_size() is not
* expected to fail if passed a directory path:
*/
free(fsdata.fatbuf);
ret = fat_itr_root(itr, &fsdata);
if (ret)
goto out_free_itr;
ret = fat_itr_resolve(itr, filename, TYPE_DIR);
if (!ret)
*size = 0;
goto out_free_both;
}
*size = FAT2CPU32(itr->dent->size);
out_free_both:
free(fsdata.fatbuf);
out_free_itr:
free(itr);
return ret;
}
int fat_read_file(const char *filename, void *buf, loff_t offset, loff_t len,
loff_t *actread)
{
struct fsdata fsdata;
struct fat_itr *itr;
int ret;
itr = malloc_cache_aligned(sizeof(struct fat_itr));
if (!itr)
return -ENOMEM;
ret = fat_itr_root(itr, &fsdata);
if (ret)
goto out_free_itr;
ret = fat_itr_resolve(itr, filename, TYPE_FILE);
if (ret)
goto out_free_both;
debug("reading %s at pos %llu\n", filename, offset);
/* For saving default max clustersize memory allocated to malloc pool */
struct dir_entry *dentptr = itr->dent;
ret = get_contents(&fsdata, dentptr, offset, buf, len, actread);
out_free_both:
free(fsdata.fatbuf);
out_free_itr:
free(itr);
return ret;
}
int file_fat_read(const char *filename, void *buffer, int maxsize)
{
loff_t actread;
int ret;
ret = fat_read_file(filename, buffer, 0, maxsize, &actread);
if (ret)
return ret;
else
return actread;
}
struct fat_dir {
struct fs_dir_stream parent;
struct fs_dirent dirent;
struct fsdata fsdata;
struct fat_itr itr;
};
int fat_opendir(const char *filename, struct fs_dir_stream **dirsp)
{
struct fat_dir *dir;
int ret;
dir = malloc_cache_aligned(sizeof(*dir));
if (!dir)
return -ENOMEM;
memset(dir, 0, sizeof(*dir));
ret = fat_itr_root(&dir->itr, &dir->fsdata);
if (ret)
goto fail_free_dir;
ret = fat_itr_resolve(&dir->itr, filename, TYPE_DIR);
if (ret)
goto fail_free_both;
*dirsp = (struct fs_dir_stream *)dir;
return 0;
fail_free_both:
free(dir->fsdata.fatbuf);
fail_free_dir:
free(dir);
return ret;
}
int fat_readdir(struct fs_dir_stream *dirs, struct fs_dirent **dentp)
{
struct fat_dir *dir = (struct fat_dir *)dirs;
struct fs_dirent *dent = &dir->dirent;
if (!fat_itr_next(&dir->itr))
return -ENOENT;
memset(dent, 0, sizeof(*dent));
strcpy(dent->name, dir->itr.name);
if (CONFIG_IS_ENABLED(EFI_LOADER)) {
dent->attr = dir->itr.dent->attr;
fat2rtc(le16_to_cpu(dir->itr.dent->cdate),
le16_to_cpu(dir->itr.dent->ctime), &dent->create_time);
fat2rtc(le16_to_cpu(dir->itr.dent->date),
le16_to_cpu(dir->itr.dent->time), &dent->change_time);
fat2rtc(le16_to_cpu(dir->itr.dent->adate),
0, &dent->access_time);
}
if (fat_itr_isdir(&dir->itr)) {
dent->type = FS_DT_DIR;
} else {
dent->type = FS_DT_REG;
dent->size = FAT2CPU32(dir->itr.dent->size);
}
*dentp = dent;
return 0;
}
void fat_closedir(struct fs_dir_stream *dirs)
{
struct fat_dir *dir = (struct fat_dir *)dirs;
free(dir->fsdata.fatbuf);
free(dir);
}
void fat_close(void)
{
}
int fat_uuid(char *uuid_str)
{
struct boot_sector bs;
struct volume_info volinfo;
int fatsize;
int ret;
u8 *id;
ret = read_bootsectandvi(&bs, &volinfo, &fatsize);
if (ret)
return ret;
id = volinfo.volume_id;
sprintf(uuid_str, "%02X%02X-%02X%02X", id[3], id[2], id[1], id[0]);
return 0;
}
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