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git01.mediatek.com / filogic / uboot / fd6561bd49ae313a8e2002940d9d635cc27b4bf4 / . / fs / exfat / node.c
blob: 88b1357189c2f3ac2aed6e7bda3550074e437736 [file] [log] [blame]
/*
node.c (09.10.09)
exFAT file system implementation library.
Free exFAT implementation.
Copyright (C) 2010-2023 Andrew Nayenko
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 2 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License along
with this program; if not, write to the Free Software Foundation, Inc.,
51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
*/
#include "exfat.h"
#include <errno.h>
#include <string.h>
#include <inttypes.h>
#define EXFAT_ENTRY_NONE (-1)
struct exfat_node* exfat_get_node(struct exfat_node* node)
{
/* if we switch to multi-threaded mode we will need atomic
increment here and atomic decrement in exfat_put_node() */
node->references++;
return node;
}
void exfat_put_node(struct exfat* ef, struct exfat_node* node)
{
char buffer[EXFAT_UTF8_NAME_BUFFER_MAX];
--node->references;
if (node->references < 0)
{
exfat_get_name(node, buffer);
exfat_bug("reference counter of '%s' is below zero", buffer);
}
else if (node->references == 0 && node != ef->root)
{
if (node->is_dirty)
{
exfat_get_name(node, buffer);
exfat_warn("dirty node '%s' with zero references", buffer);
}
}
}
/**
* This function must be called on rmdir and unlink (after the last
* exfat_put_node()) to free clusters.
*/
int exfat_cleanup_node(struct exfat* ef, struct exfat_node* node)
{
int rc = 0;
if (node->references != 0)
exfat_bug("unable to cleanup a node with %d references",
node->references);
if (node->is_unlinked)
{
/* free all clusters and node structure itself */
rc = exfat_truncate(ef, node, 0, true);
/* free the node even in case of error or its memory will be lost */
free(node);
}
return rc;
}
static int read_entries(struct exfat* ef, struct exfat_node* dir,
struct exfat_entry* entries, int n, off_t offset)
{
ssize_t size;
if (!(dir->attrib & EXFAT_ATTRIB_DIR))
exfat_bug("attempted to read entries from a file");
size = exfat_generic_pread(ef, dir, entries,
sizeof(struct exfat_entry[n]), offset);
if (size == (ssize_t) sizeof(struct exfat_entry) * n)
return 0; /* success */
if (size == 0)
return -ENOENT;
if (size < 0)
return -EIO;
exfat_error("read %zd bytes instead of %zu bytes", size,
sizeof(struct exfat_entry[n]));
return -EIO;
}
static int write_entries(struct exfat* ef, struct exfat_node* dir,
const struct exfat_entry* entries, int n, off_t offset)
{
ssize_t size;
if (!(dir->attrib & EXFAT_ATTRIB_DIR))
exfat_bug("attempted to write entries into a file");
size = exfat_generic_pwrite(ef, dir, entries,
sizeof(struct exfat_entry[n]), offset);
if (size == (ssize_t) sizeof(struct exfat_entry) * n)
return 0; /* success */
if (size < 0)
return -EIO;
exfat_error("wrote %zd bytes instead of %zu bytes", size,
sizeof(struct exfat_entry[n]));
return -EIO;
}
static struct exfat_node* allocate_node(void)
{
struct exfat_node* node = malloc(sizeof(struct exfat_node));
if (node == NULL)
{
exfat_error("failed to allocate node");
return NULL;
}
memset(node, 0, sizeof(struct exfat_node));
return node;
}
static void init_node_meta1(struct exfat_node* node,
const struct exfat_entry_meta1* meta1)
{
node->attrib = le16_to_cpu(meta1->attrib);
node->continuations = meta1->continuations;
node->mtime = exfat_exfat2unix(meta1->mdate, meta1->mtime,
meta1->mtime_cs, meta1->mtime_tzo);
/* there is no centiseconds field for atime */
node->atime = exfat_exfat2unix(meta1->adate, meta1->atime,
0, meta1->atime_tzo);
}
static void init_node_meta2(struct exfat_node* node,
const struct exfat_entry_meta2* meta2)
{
node->valid_size = le64_to_cpu(meta2->valid_size);
node->size = le64_to_cpu(meta2->size);
node->start_cluster = le32_to_cpu(meta2->start_cluster);
node->fptr_cluster = node->start_cluster;
node->is_contiguous = ((meta2->flags & EXFAT_FLAG_CONTIGUOUS) != 0);
}
static void init_node_name(struct exfat_node* node,
const struct exfat_entry* entries, int n)
{
int i;
for (i = 0; i < n; i++)
memcpy(node->name + i * EXFAT_ENAME_MAX,
((const struct exfat_entry_name*) &entries[i])->name,
EXFAT_ENAME_MAX * sizeof(le16_t));
}
static bool check_entries(const struct exfat_entry* entry, int n)
{
int previous = EXFAT_ENTRY_NONE;
int current;
int i;
/* check transitions between entries types */
for (i = 0; i < n + 1; previous = current, i++)
{
bool valid = false;
current = (i < n) ? entry[i].type : EXFAT_ENTRY_NONE;
switch (previous)
{
case EXFAT_ENTRY_NONE:
valid = (current == EXFAT_ENTRY_FILE);
break;
case EXFAT_ENTRY_FILE:
valid = (current == EXFAT_ENTRY_FILE_INFO);
break;
case EXFAT_ENTRY_FILE_INFO:
valid = (current == EXFAT_ENTRY_FILE_NAME);
break;
case EXFAT_ENTRY_FILE_NAME:
valid = (current == EXFAT_ENTRY_FILE_NAME ||
current == EXFAT_ENTRY_NONE ||
current >= EXFAT_ENTRY_FILE_TAIL);
break;
case EXFAT_ENTRY_FILE_TAIL ... 0xff:
valid = (current >= EXFAT_ENTRY_FILE_TAIL ||
current == EXFAT_ENTRY_NONE);
break;
}
if (!valid)
{
exfat_error("unexpected entry type %#x after %#x at %d/%d",
current, previous, i, n);
return false;
}
}
return true;
}
static bool check_node(const struct exfat* ef, struct exfat_node* node,
le16_t actual_checksum, const struct exfat_entry_meta1* meta1)
{
int cluster_size = CLUSTER_SIZE(*ef->sb);
uint64_t clusters_heap_size =
(uint64_t) le32_to_cpu(ef->sb->cluster_count) * cluster_size;
char buffer[EXFAT_UTF8_NAME_BUFFER_MAX];
bool ret = true;
/*
Validate checksum first. If it's invalid all other fields probably
contain just garbage.
*/
if (le16_to_cpu(actual_checksum) != le16_to_cpu(meta1->checksum))
{
exfat_get_name(node, buffer);
exfat_error("'%s' has invalid checksum (%#hx != %#hx)", buffer,
le16_to_cpu(actual_checksum), le16_to_cpu(meta1->checksum));
if (!EXFAT_REPAIR(invalid_node_checksum, ef, node))
ret = false;
}
/*
exFAT does not support sparse files but allows files with uninitialized
clusters. For such files valid_size means initialized data size and
cannot be greater than file size. See SetFileValidData() function
description in MSDN.
*/
if (node->valid_size > node->size)
{
exfat_get_name(node, buffer);
exfat_error("'%s' has valid size (%"PRIu64") greater than size "
"(%"PRIu64")", buffer, node->valid_size, node->size);
ret = false;
}
/*
Empty file must have zero start cluster. Non-empty file must start
with a valid cluster. Directories cannot be empty (i.e. must always
have a valid start cluster), but we will check this later while
reading that directory to give user a chance to read this directory.
*/
if (node->size == 0 && node->start_cluster != EXFAT_CLUSTER_FREE)
{
exfat_get_name(node, buffer);
exfat_error("'%s' is empty but start cluster is %#x", buffer,
node->start_cluster);
ret = false;
}
if (node->size > 0 && CLUSTER_INVALID(*ef->sb, node->start_cluster))
{
exfat_get_name(node, buffer);
exfat_error("'%s' points to invalid cluster %#x", buffer,
node->start_cluster);
ret = false;
}
/* File or directory cannot be larger than clusters heap. */
if (node->size > clusters_heap_size)
{
exfat_get_name(node, buffer);
exfat_error("'%s' is larger than clusters heap: %"PRIu64" > %"PRIu64,
buffer, node->size, clusters_heap_size);
ret = false;
}
/* Empty file or directory must be marked as non-contiguous. */
if (node->size == 0 && node->is_contiguous)
{
exfat_get_name(node, buffer);
exfat_error("'%s' is empty but marked as contiguous (%#hx)", buffer,
node->attrib);
ret = false;
}
/* Directory size must be aligned on at cluster boundary. */
if ((node->attrib & EXFAT_ATTRIB_DIR) && node->size % cluster_size != 0)
{
exfat_get_name(node, buffer);
exfat_error("'%s' directory size %"PRIu64" is not divisible by %d", buffer,
node->size, cluster_size);
ret = false;
}
return ret;
}
static int parse_file_entries(struct exfat* ef, struct exfat_node* node,
const struct exfat_entry* entries, int n)
{
const struct exfat_entry_meta1* meta1;
const struct exfat_entry_meta2* meta2;
int mandatory_entries;
if (!check_entries(entries, n))
return -EIO;
meta1 = (const struct exfat_entry_meta1*) &entries[0];
if (meta1->continuations < 2)
{
exfat_error("too few continuations (%hhu)", meta1->continuations);
return -EIO;
}
meta2 = (const struct exfat_entry_meta2*) &entries[1];
if (meta2->flags & ~(EXFAT_FLAG_ALWAYS1 | EXFAT_FLAG_CONTIGUOUS))
{
exfat_error("unknown flags in meta2 (%#hhx)", meta2->flags);
return -EIO;
}
mandatory_entries = 2 + DIV_ROUND_UP(meta2->name_length, EXFAT_ENAME_MAX);
if (meta1->continuations < mandatory_entries - 1)
{
exfat_error("too few continuations (%hhu < %d)",
meta1->continuations, mandatory_entries - 1);
return -EIO;
}
init_node_meta1(node, meta1);
init_node_meta2(node, meta2);
init_node_name(node, entries + 2, mandatory_entries - 2);
if (!check_node(ef, node, exfat_calc_checksum(entries, n), meta1))
return -EIO;
return 0;
}
static int parse_file_entry(struct exfat* ef, struct exfat_node* parent,
struct exfat_node** node, off_t* offset, int n)
{
struct exfat_entry entries[n];
int rc;
rc = read_entries(ef, parent, entries, n, *offset);
if (rc != 0)
return rc;
/* a new node has zero references */
*node = allocate_node();
if (*node == NULL)
return -ENOMEM;
(*node)->entry_offset = *offset;
rc = parse_file_entries(ef, *node, entries, n);
if (rc != 0)
{
free(*node);
return rc;
}
*offset += sizeof(struct exfat_entry[n]);
return 0;
}
static void decompress_upcase(uint16_t* output, const le16_t* source,
size_t size)
{
size_t si;
size_t oi;
for (oi = 0; oi < EXFAT_UPCASE_CHARS; oi++)
output[oi] = oi;
for (si = 0, oi = 0; si < size && oi < EXFAT_UPCASE_CHARS; si++)
{
uint16_t ch = le16_to_cpu(source[si]);
if (ch == 0xffff && si + 1 < size) /* indicates a run */
oi += le16_to_cpu(source[++si]);
else
output[oi++] = ch;
}
}
/*
* Read one entry in a directory at offset position and build a new node
* structure.
*/
static int readdir(struct exfat* ef, struct exfat_node* parent,
struct exfat_node** node, off_t* offset)
{
int rc;
struct exfat_entry entry;
const struct exfat_entry_meta1* meta1;
const struct exfat_entry_upcase* upcase;
const struct exfat_entry_bitmap* bitmap;
const struct exfat_entry_label* label;
uint64_t upcase_size = 0;
le16_t* upcase_comp = NULL;
le16_t label_name[EXFAT_ENAME_MAX];
for (;;)
{
rc = read_entries(ef, parent, &entry, 1, *offset);
if (rc != 0)
return rc;
switch (entry.type)
{
case EXFAT_ENTRY_FILE:
meta1 = (const struct exfat_entry_meta1*) &entry;
return parse_file_entry(ef, parent, node, offset,
1 + meta1->continuations);
case EXFAT_ENTRY_UPCASE:
if (ef->upcase != NULL)
break;
upcase = (const struct exfat_entry_upcase*) &entry;
if (CLUSTER_INVALID(*ef->sb, le32_to_cpu(upcase->start_cluster)))
{
exfat_error("invalid cluster 0x%x in upcase table",
le32_to_cpu(upcase->start_cluster));
return -EIO;
}
upcase_size = le64_to_cpu(upcase->size);
if (upcase_size == 0 ||
upcase_size > EXFAT_UPCASE_CHARS * sizeof(uint16_t) ||
upcase_size % sizeof(uint16_t) != 0)
{
exfat_error("bad upcase table size (%"PRIu64" bytes)",
upcase_size);
return -EIO;
}
upcase_comp = malloc(upcase_size);
if (upcase_comp == NULL)
{
exfat_error("failed to allocate upcase table (%"PRIu64" bytes)",
upcase_size);
return -ENOMEM;
}
/* read compressed upcase table */
if (exfat_pread(ef->dev, upcase_comp, upcase_size,
exfat_c2o(ef, le32_to_cpu(upcase->start_cluster))) < 0)
{
free(upcase_comp);
exfat_error("failed to read upper case table "
"(%"PRIu64" bytes starting at cluster %#x)",
upcase_size,
le32_to_cpu(upcase->start_cluster));
return -EIO;
}
/* decompress upcase table */
ef->upcase = calloc(EXFAT_UPCASE_CHARS, sizeof(uint16_t));
if (ef->upcase == NULL)
{
free(upcase_comp);
exfat_error("failed to allocate decompressed upcase table");
return -ENOMEM;
}
decompress_upcase(ef->upcase, upcase_comp,
upcase_size / sizeof(uint16_t));
free(upcase_comp);
break;
case EXFAT_ENTRY_BITMAP:
bitmap = (const struct exfat_entry_bitmap*) &entry;
ef->cmap.start_cluster = le32_to_cpu(bitmap->start_cluster);
if (CLUSTER_INVALID(*ef->sb, ef->cmap.start_cluster))
{
exfat_error("invalid cluster 0x%x in clusters bitmap",
ef->cmap.start_cluster);
return -EIO;
}
ef->cmap.size = le32_to_cpu(ef->sb->cluster_count);
if (le64_to_cpu(bitmap->size) < DIV_ROUND_UP(ef->cmap.size, 8))
{
exfat_error("invalid clusters bitmap size: %"PRIu64
" (expected at least %u)",
le64_to_cpu(bitmap->size),
DIV_ROUND_UP(ef->cmap.size, 8));
return -EIO;
}
/* FIXME bitmap can be rather big, up to 512 MB */
ef->cmap.chunk_size = ef->cmap.size;
ef->cmap.chunk = malloc(BMAP_SIZE(ef->cmap.chunk_size));
if (ef->cmap.chunk == NULL)
{
exfat_error("failed to allocate clusters bitmap chunk "
"(%"PRIu64" bytes)", le64_to_cpu(bitmap->size));
return -ENOMEM;
}
if (exfat_pread(ef->dev, ef->cmap.chunk,
BMAP_SIZE(ef->cmap.chunk_size),
exfat_c2o(ef, ef->cmap.start_cluster)) < 0)
{
exfat_error("failed to read clusters bitmap "
"(%"PRIu64" bytes starting at cluster %#x)",
le64_to_cpu(bitmap->size), ef->cmap.start_cluster);
return -EIO;
}
break;
case EXFAT_ENTRY_LABEL:
label = (const struct exfat_entry_label*) &entry;
if (label->length > EXFAT_ENAME_MAX)
{
exfat_error("too long label (%hhu chars)", label->length);
return -EIO;
}
/* copy to a temporary buffer to avoid unaligned access to a
packed member */
memcpy(label_name, label->name, sizeof(label_name));
if (exfat_utf16_to_utf8(ef->label, label_name,
sizeof(ef->label), EXFAT_ENAME_MAX) != 0)
return -EIO;
break;
default:
if (!(entry.type & EXFAT_ENTRY_VALID))
break; /* deleted entry, ignore it */
exfat_error("unknown entry type %#hhx", entry.type);
if (!EXFAT_REPAIR(unknown_entry, ef, parent, &entry, *offset))
return -EIO;
}
*offset += sizeof(entry);
}
/* we never reach here */
}
int exfat_cache_directory(struct exfat* ef, struct exfat_node* dir)
{
off_t offset = 0;
int rc;
struct exfat_node* node;
struct exfat_node* current = NULL;
if (dir->is_cached)
return 0; /* already cached */
while ((rc = readdir(ef, dir, &node, &offset)) == 0)
{
node->parent = dir;
if (current != NULL)
{
current->next = node;
node->prev = current;
}
else
dir->child = node;
current = node;
}
if (rc != -ENOENT)
{
/* rollback */
for (current = dir->child; current; current = node)
{
node = current->next;
free(current);
}
dir->child = NULL;
return rc;
}
dir->is_cached = true;
return 0;
}
static void tree_attach(struct exfat_node* dir, struct exfat_node* node)
{
node->parent = dir;
if (dir->child)
{
dir->child->prev = node;
node->next = dir->child;
}
dir->child = node;
}
static void tree_detach(struct exfat_node* node)
{
if (node->prev)
node->prev->next = node->next;
else /* this is the first node in the list */
node->parent->child = node->next;
if (node->next)
node->next->prev = node->prev;
node->parent = NULL;
node->prev = NULL;
node->next = NULL;
}
static void reset_cache(struct exfat* ef, struct exfat_node* node)
{
char buffer[EXFAT_UTF8_NAME_BUFFER_MAX];
while (node->child)
{
struct exfat_node* p = node->child;
reset_cache(ef, p);
tree_detach(p);
free(p);
}
node->is_cached = false;
if (node->references != 0)
{
exfat_get_name(node, buffer);
exfat_warn("non-zero reference counter (%d) for '%s'",
node->references, buffer);
}
if (node != ef->root && node->is_dirty)
{
exfat_get_name(node, buffer);
exfat_bug("node '%s' is dirty", buffer);
}
while (node->references)
exfat_put_node(ef, node);
}
void exfat_reset_cache(struct exfat* ef)
{
reset_cache(ef, ef->root);
}
int exfat_flush_node(struct exfat* ef, struct exfat_node* node)
{
struct exfat_entry entries[1 + node->continuations];
struct exfat_entry_meta1* meta1 = (struct exfat_entry_meta1*) &entries[0];
struct exfat_entry_meta2* meta2 = (struct exfat_entry_meta2*) &entries[1];
int rc;
le16_t edate, etime;
if (!node->is_dirty)
return 0; /* no need to flush */
if (ef->ro)
exfat_bug("unable to flush node to read-only FS");
if (node->parent == NULL)
return 0; /* do not flush unlinked node */
rc = read_entries(ef, node->parent, entries, 1 + node->continuations,
node->entry_offset);
if (rc != 0)
return rc;
if (!check_entries(entries, 1 + node->continuations))
return -EIO;
meta1->attrib = cpu_to_le16(node->attrib);
exfat_unix2exfat(node->mtime, &edate, &etime,
&meta1->mtime_cs, &meta1->mtime_tzo);
meta1->mdate = edate;
meta1->mtime = etime;
exfat_unix2exfat(node->atime, &edate, &etime,
NULL, &meta1->atime_tzo);
meta1->adate = edate;
meta1->atime = etime;
meta2->valid_size = cpu_to_le64(node->valid_size);
meta2->size = cpu_to_le64(node->size);
meta2->start_cluster = cpu_to_le32(node->start_cluster);
meta2->flags = EXFAT_FLAG_ALWAYS1;
/* empty files must not be marked as contiguous */
if (node->size != 0 && node->is_contiguous)
meta2->flags |= EXFAT_FLAG_CONTIGUOUS;
/* name hash remains unchanged, no need to recalculate it */
meta1->checksum = exfat_calc_checksum(entries, 1 + node->continuations);
rc = write_entries(ef, node->parent, entries, 1 + node->continuations,
node->entry_offset);
if (rc != 0)
return rc;
node->is_dirty = false;
return exfat_flush(ef);
}
static int erase_entries(struct exfat* ef, struct exfat_node* dir, int n,
off_t offset)
{
struct exfat_entry entries[n];
int rc;
int i;
rc = read_entries(ef, dir, entries, n, offset);
if (rc != 0)
return rc;
for (i = 0; i < n; i++)
entries[i].type &= ~EXFAT_ENTRY_VALID;
return write_entries(ef, dir, entries, n, offset);
}
static int erase_node(struct exfat* ef, struct exfat_node* node)
{
int rc;
exfat_get_node(node->parent);
rc = erase_entries(ef, node->parent, 1 + node->continuations,
node->entry_offset);
if (rc != 0)
{
exfat_put_node(ef, node->parent);
return rc;
}
rc = exfat_flush_node(ef, node->parent);
exfat_put_node(ef, node->parent);
return rc;
}
static int shrink_directory(struct exfat* ef, struct exfat_node* dir,
off_t deleted_offset)
{
const struct exfat_node* node;
const struct exfat_node* last_node;
uint64_t entries = 0;
uint64_t new_size;
if (!(dir->attrib & EXFAT_ATTRIB_DIR))
exfat_bug("attempted to shrink a file");
if (!dir->is_cached)
exfat_bug("attempted to shrink uncached directory");
for (last_node = node = dir->child; node; node = node->next)
{
if (deleted_offset < node->entry_offset)
{
/* there are other entries after the removed one, no way to shrink
this directory */
return 0;
}
if (last_node->entry_offset < node->entry_offset)
last_node = node;
}
if (last_node)
{
/* offset of the last entry */
entries += last_node->entry_offset / sizeof(struct exfat_entry);
/* two subentries with meta info */
entries += 2;
/* subentries with file name */
entries += DIV_ROUND_UP(exfat_utf16_length(last_node->name),
EXFAT_ENAME_MAX);
}
new_size = DIV_ROUND_UP(entries * sizeof(struct exfat_entry),
CLUSTER_SIZE(*ef->sb)) * CLUSTER_SIZE(*ef->sb);
if (new_size == 0) /* directory always has at least 1 cluster */
new_size = CLUSTER_SIZE(*ef->sb);
if (new_size == dir->size)
return 0;
return exfat_truncate(ef, dir, new_size, true);
}
static int delete(struct exfat* ef, struct exfat_node* node)
{
struct exfat_node* parent = node->parent;
off_t deleted_offset = node->entry_offset;
int rc;
exfat_get_node(parent);
rc = erase_node(ef, node);
if (rc != 0)
{
exfat_put_node(ef, parent);
return rc;
}
tree_detach(node);
rc = shrink_directory(ef, parent, deleted_offset);
node->is_unlinked = true;
if (rc != 0)
{
exfat_flush_node(ef, parent);
exfat_put_node(ef, parent);
return rc;
}
exfat_update_mtime(parent);
rc = exfat_flush_node(ef, parent);
exfat_put_node(ef, parent);
return rc;
}
int exfat_unlink(struct exfat* ef, struct exfat_node* node)
{
if (node->attrib & EXFAT_ATTRIB_DIR)
return -EISDIR;
return delete(ef, node);
}
int exfat_rmdir(struct exfat* ef, struct exfat_node* node)
{
int rc;
if (!(node->attrib & EXFAT_ATTRIB_DIR))
return -ENOTDIR;
/* check that directory is empty */
rc = exfat_cache_directory(ef, node);
if (rc != 0)
return rc;
if (node->child)
return -ENOTEMPTY;
return delete(ef, node);
}
static int check_slot(struct exfat* ef, struct exfat_node* dir, off_t offset,
int n)
{
struct exfat_entry entries[n];
int rc;
int i;
/* Root directory contains entries, that don't have any nodes associated
with them (clusters bitmap, upper case table, label). We need to be
careful not to overwrite them. */
if (dir != ef->root)
return 0;
rc = read_entries(ef, dir, entries, n, offset);
if (rc != 0)
return rc;
for (i = 0; i < n; i++)
if (entries[i].type & EXFAT_ENTRY_VALID)
return -EINVAL;
return 0;
}
static int find_slot(struct exfat* ef, struct exfat_node* dir,
off_t* offset, int n)
{
bitmap_t* dmap;
struct exfat_node* p;
size_t i;
int contiguous = 0;
if (!dir->is_cached)
exfat_bug("directory is not cached");
/* build a bitmap of valid entries in the directory */
dmap = calloc(BMAP_SIZE(dir->size / sizeof(struct exfat_entry)),
sizeof(bitmap_t));
if (dmap == NULL)
{
exfat_error("failed to allocate directory bitmap (%"PRIu64")",
dir->size / sizeof(struct exfat_entry));
return -ENOMEM;
}
for (p = dir->child; p != NULL; p = p->next)
for (i = 0; i < 1u + p->continuations; i++)
BMAP_SET(dmap, p->entry_offset / sizeof(struct exfat_entry) + i);
/* find a slot in the directory entries bitmap */
for (i = 0; i < dir->size / sizeof(struct exfat_entry); i++)
{
if (BMAP_GET(dmap, i) == 0)
{
if (contiguous++ == 0)
*offset = (off_t) i * sizeof(struct exfat_entry);
if (contiguous == n)
{
int rc;
/* suitable slot is found, check that it's not occupied */
rc = check_slot(ef, dir, *offset, n);
if (rc == -EINVAL)
{
/* slot at (i-n) is occupied, go back and check (i-n+1) */
i -= contiguous - 1;
contiguous = 0;
}
else
{
/* slot is free or an error occurred */
free(dmap);
return rc;
}
}
}
else
contiguous = 0;
}
free(dmap);
/* no suitable slots found, extend the directory */
if (contiguous == 0)
*offset = dir->size;
return exfat_truncate(ef, dir,
ROUND_UP(dir->size + sizeof(struct exfat_entry[n - contiguous]),
CLUSTER_SIZE(*ef->sb)),
true);
}
static int commit_entry(struct exfat* ef, struct exfat_node* dir,
const le16_t* name, off_t offset, uint16_t attrib)
{
struct exfat_node* node;
const size_t name_length = exfat_utf16_length(name);
const int name_entries = DIV_ROUND_UP(name_length, EXFAT_ENAME_MAX);
struct exfat_entry entries[2 + name_entries];
struct exfat_entry_meta1* meta1 = (struct exfat_entry_meta1*) &entries[0];
struct exfat_entry_meta2* meta2 = (struct exfat_entry_meta2*) &entries[1];
int i;
int rc;
le16_t edate, etime;
memset(entries, 0, sizeof(struct exfat_entry[2]));
meta1->type = EXFAT_ENTRY_FILE;
meta1->continuations = 1 + name_entries;
meta1->attrib = cpu_to_le16(attrib);
exfat_unix2exfat(time(NULL), &edate, &etime,
&meta1->crtime_cs, &meta1->crtime_tzo);
meta1->adate = meta1->mdate = meta1->crdate = edate;
meta1->atime = meta1->mtime = meta1->crtime = etime;
meta1->mtime_cs = meta1->crtime_cs; /* there is no atime_cs */
meta1->atime_tzo = meta1->mtime_tzo = meta1->crtime_tzo;
meta2->type = EXFAT_ENTRY_FILE_INFO;
meta2->flags = EXFAT_FLAG_ALWAYS1;
meta2->name_length = name_length;
meta2->name_hash = exfat_calc_name_hash(ef, name, name_length);
meta2->start_cluster = cpu_to_le32(EXFAT_CLUSTER_FREE);
for (i = 0; i < name_entries; i++)
{
struct exfat_entry_name* name_entry;
name_entry = (struct exfat_entry_name*) &entries[2 + i];
name_entry->type = EXFAT_ENTRY_FILE_NAME;
name_entry->__unknown = 0;
memcpy(name_entry->name, name + i * EXFAT_ENAME_MAX,
EXFAT_ENAME_MAX * sizeof(le16_t));
}
meta1->checksum = exfat_calc_checksum(entries, 2 + name_entries);
rc = write_entries(ef, dir, entries, 2 + name_entries, offset);
if (rc != 0)
return rc;
node = allocate_node();
if (node == NULL)
return -ENOMEM;
node->entry_offset = offset;
memcpy(node->name, name, name_length * sizeof(le16_t));
init_node_meta1(node, meta1);
init_node_meta2(node, meta2);
tree_attach(dir, node);
return 0;
}
static int create(struct exfat* ef, const char* path, uint16_t attrib)
{
struct exfat_node* dir;
struct exfat_node* existing;
off_t offset = -1;
le16_t name[EXFAT_NAME_MAX + 1];
int rc;
rc = exfat_split(ef, &dir, &existing, name, path);
if (rc != 0)
return rc;
if (existing != NULL)
{
exfat_put_node(ef, existing);
exfat_put_node(ef, dir);
return -EEXIST;
}
rc = find_slot(ef, dir, &offset,
2 + DIV_ROUND_UP(exfat_utf16_length(name), EXFAT_ENAME_MAX));
if (rc != 0)
{
exfat_put_node(ef, dir);
return rc;
}
rc = commit_entry(ef, dir, name, offset, attrib);
if (rc != 0)
{
exfat_put_node(ef, dir);
return rc;
}
exfat_update_mtime(dir);
rc = exfat_flush_node(ef, dir);
exfat_put_node(ef, dir);
return rc;
}
int exfat_mknod(struct exfat* ef, const char* path)
{
return create(ef, path, EXFAT_ATTRIB_ARCH);
}
int exfat_mkdir(struct exfat* ef, const char* path)
{
int rc;
struct exfat_node* node;
rc = create(ef, path, EXFAT_ATTRIB_DIR);
if (rc != 0)
return rc;
rc = exfat_lookup(ef, &node, path);
if (rc != 0)
return 0;
/* directories always have at least one cluster */
rc = exfat_truncate(ef, node, CLUSTER_SIZE(*ef->sb), true);
if (rc != 0)
{
delete(ef, node);
exfat_put_node(ef, node);
return rc;
}
rc = exfat_flush_node(ef, node);
if (rc != 0)
{
delete(ef, node);
exfat_put_node(ef, node);
return rc;
}
exfat_put_node(ef, node);
return 0;
}
static int rename_entry(struct exfat* ef, struct exfat_node* dir,
struct exfat_node* node, const le16_t* name, off_t new_offset)
{
const size_t name_length = exfat_utf16_length(name);
const int name_entries = DIV_ROUND_UP(name_length, EXFAT_ENAME_MAX);
struct exfat_entry entries[2 + name_entries];
struct exfat_entry_meta1* meta1 = (struct exfat_entry_meta1*) &entries[0];
struct exfat_entry_meta2* meta2 = (struct exfat_entry_meta2*) &entries[1];
int rc;
int i;
rc = read_entries(ef, node->parent, entries, 2, node->entry_offset);
if (rc != 0)
return rc;
meta1->continuations = 1 + name_entries;
meta2->name_length = name_length;
meta2->name_hash = exfat_calc_name_hash(ef, name, name_length);
rc = erase_node(ef, node);
if (rc != 0)
return rc;
node->entry_offset = new_offset;
node->continuations = 1 + name_entries;
for (i = 0; i < name_entries; i++)
{
struct exfat_entry_name* name_entry;
name_entry = (struct exfat_entry_name*) &entries[2 + i];
name_entry->type = EXFAT_ENTRY_FILE_NAME;
name_entry->__unknown = 0;
memcpy(name_entry->name, name + i * EXFAT_ENAME_MAX,
EXFAT_ENAME_MAX * sizeof(le16_t));
}
meta1->checksum = exfat_calc_checksum(entries, 2 + name_entries);
rc = write_entries(ef, dir, entries, 2 + name_entries, new_offset);
if (rc != 0)
return rc;
memcpy(node->name, name, (EXFAT_NAME_MAX + 1) * sizeof(le16_t));
tree_detach(node);
tree_attach(dir, node);
return 0;
}
int exfat_rename(struct exfat* ef, const char* old_path, const char* new_path)
{
struct exfat_node* node;
struct exfat_node* existing;
struct exfat_node* dir;
off_t offset = -1;
le16_t name[EXFAT_NAME_MAX + 1];
int rc;
rc = exfat_lookup(ef, &node, old_path);
if (rc != 0)
return rc;
rc = exfat_split(ef, &dir, &existing, name, new_path);
if (rc != 0)
{
exfat_put_node(ef, node);
return rc;
}
/* check that target is not a subdirectory of the source */
if (node->attrib & EXFAT_ATTRIB_DIR)
{
struct exfat_node* p;
for (p = dir; p; p = p->parent)
if (node == p)
{
if (existing != NULL)
exfat_put_node(ef, existing);
exfat_put_node(ef, dir);
exfat_put_node(ef, node);
return -EINVAL;
}
}
if (existing != NULL)
{
/* remove target if it's not the same node as source */
if (existing != node)
{
if (existing->attrib & EXFAT_ATTRIB_DIR)
{
if (node->attrib & EXFAT_ATTRIB_DIR)
rc = exfat_rmdir(ef, existing);
else
rc = -ENOTDIR;
}
else
{
if (!(node->attrib & EXFAT_ATTRIB_DIR))
rc = exfat_unlink(ef, existing);
else
rc = -EISDIR;
}
exfat_put_node(ef, existing);
if (rc != 0)
{
/* free clusters even if something went wrong; otherwise they
will be just lost */
exfat_cleanup_node(ef, existing);
exfat_put_node(ef, dir);
exfat_put_node(ef, node);
return rc;
}
rc = exfat_cleanup_node(ef, existing);
if (rc != 0)
{
exfat_put_node(ef, dir);
exfat_put_node(ef, node);
return rc;
}
}
else
exfat_put_node(ef, existing);
}
rc = find_slot(ef, dir, &offset,
2 + DIV_ROUND_UP(exfat_utf16_length(name), EXFAT_ENAME_MAX));
if (rc != 0)
{
exfat_put_node(ef, dir);
exfat_put_node(ef, node);
return rc;
}
rc = rename_entry(ef, dir, node, name, offset);
if (rc != 0)
{
exfat_put_node(ef, dir);
exfat_put_node(ef, node);
return rc;
}
rc = exfat_flush_node(ef, dir);
exfat_put_node(ef, dir);
exfat_put_node(ef, node);
/* node itself is not marked as dirty, no need to flush it */
return rc;
}
void exfat_utimes(struct exfat_node* node, const struct timespec tv[2])
{
node->atime = tv[0].tv_sec;
node->mtime = tv[1].tv_sec;
node->is_dirty = true;
}
void exfat_update_atime(struct exfat_node* node)
{
node->atime = time(NULL);
node->is_dirty = true;
}
void exfat_update_mtime(struct exfat_node* node)
{
node->mtime = time(NULL);
node->is_dirty = true;
}
const char* exfat_get_label(struct exfat* ef)
{
return ef->label;
}
static int find_label(struct exfat* ef, off_t* offset)
{
struct exfat_entry entry;
int rc;
for (*offset = 0; ; *offset += sizeof(entry))
{
rc = read_entries(ef, ef->root, &entry, 1, *offset);
if (rc != 0)
return rc;
if (entry.type == EXFAT_ENTRY_LABEL)
return 0;
}
}
int exfat_set_label(struct exfat* ef, const char* label)
{
le16_t label_utf16[EXFAT_ENAME_MAX + 1];
int rc;
off_t offset;
struct exfat_entry_label entry;
memset(label_utf16, 0, sizeof(label_utf16));
rc = exfat_utf8_to_utf16(label_utf16, label, EXFAT_ENAME_MAX + 1,
strlen(label));
if (rc != 0)
return rc;
rc = find_label(ef, &offset);
if (rc == -ENOENT)
rc = find_slot(ef, ef->root, &offset, 1);
if (rc != 0)
return rc;
entry.type = EXFAT_ENTRY_LABEL;
entry.length = exfat_utf16_length(label_utf16);
memcpy(entry.name, label_utf16, sizeof(entry.name));
if (entry.length == 0)
entry.type ^= EXFAT_ENTRY_VALID;
rc = write_entries(ef, ef->root, (struct exfat_entry*) &entry, 1, offset);
if (rc != 0)
return rc;
strcpy(ef->label, label);
return 0;
}