ref: 63a33e39df4b7faedccb566ff9012d38e5b82064
dir: /lwext4/ext4_dir.c/
/*
* Copyright (c) 2013 Grzegorz Kostka ([email protected])
*
*
* HelenOS:
* Copyright (c) 2012 Martin Sucha
* Copyright (c) 2012 Frantisek Princ
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
*
* - Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* - Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* - The name of the author may not be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
* IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
* OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
* IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
* NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
* THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
/** @addtogroup lwext4
* @{
*/
/**
* @file ext4_dir.h
* @brief Directory handle procedures.
*/
#include <ext4_config.h>
#include <ext4_dir.h>
#include <ext4_dir_idx.h>
#include <ext4_inode.h>
#include <ext4_fs.h>
#include <string.h>
uint32_t ext4_dir_entry_ll_get_inode(struct ext4_directory_entry_ll *de)
{
return to_le32(de->inode);
}
void ext4_dir_entry_ll_set_inode(struct ext4_directory_entry_ll *de,
uint32_t inode)
{
de->inode = to_le32(inode);
}
uint16_t ext4_dir_entry_ll_get_entry_length(struct ext4_directory_entry_ll *de)
{
return to_le16(de->entry_length);
}
void ext4_dir_entry_ll_set_entry_length(struct ext4_directory_entry_ll *de,
uint16_t len)
{
de->entry_length = to_le16(len);
}
uint16_t ext4_dir_entry_ll_get_name_length(struct ext4_sblock *sb,
struct ext4_directory_entry_ll *de)
{
uint16_t v = de->name_length;
if ((ext4_get32(sb, rev_level) == 0) &&
(ext4_get32(sb, minor_rev_level) < 5))
v |= ((uint16_t)de->in.name_length_high) << 8;
return v;
}
void ext4_dir_entry_ll_set_name_length(struct ext4_sblock *sb,
struct ext4_directory_entry_ll *de, uint16_t len)
{
de->name_length = (len << 8) >> 8;
if ((ext4_get32(sb, rev_level) == 0) &&
(ext4_get32(sb, minor_rev_level) < 5))
de->in.name_length_high = len >> 8;
}
uint8_t ext4_dir_entry_ll_get_inode_type(struct ext4_sblock *sb,
struct ext4_directory_entry_ll *de)
{
if ((ext4_get32(sb, rev_level) > 0) ||
(ext4_get32(sb, minor_rev_level) >= 5))
return de->in.inode_type;
return EXT4_DIRECTORY_FILETYPE_UNKNOWN;
}
void ext4_dir_entry_ll_set_inode_type(struct ext4_sblock *sb,
struct ext4_directory_entry_ll *de, uint8_t type)
{
if ((ext4_get32(sb, rev_level) > 0) ||
(ext4_get32(sb, minor_rev_level) >= 5))
de->in.inode_type = type;
}
/****************************************************************************/
/**@brief Do some checks before returning iterator.
* @param it Iterator to be checked
* @param block_size Size of data block
* @return Error code
*/
static int ext4_dir_iterator_set(struct ext4_directory_iterator *it,
uint32_t block_size)
{
it->current = NULL;
uint32_t offset_in_block = it->current_offset % block_size;
/* Ensure proper alignment */
if ((offset_in_block % 4) != 0)
return EIO;
/* Ensure that the core of the entry does not overflow the block */
if (offset_in_block > block_size - 8)
return EIO;
struct ext4_directory_entry_ll *entry =
(void *)(it->current_block.data + offset_in_block);
/* Ensure that the whole entry does not overflow the block */
uint16_t length = ext4_dir_entry_ll_get_entry_length(entry);
if (offset_in_block + length > block_size)
return EIO;
/* Ensure the name length is not too large */
if (ext4_dir_entry_ll_get_name_length(
&it->inode_ref->fs->sb, entry) > length-8)
return EIO;
/* Everything OK - "publish" the entry */
it->current = entry;
return EOK;
}
/**@brief Seek to next valid directory entry.
* Here can be jumped to the next data block.
* @param it Initialized iterator
* @param pos Position of the next entry
* @return Error code
*/
static int ext4_dir_iterator_seek(struct ext4_directory_iterator *it,
uint64_t pos)
{
uint64_t size = ext4_inode_get_size(&it->inode_ref->fs->sb,
it->inode_ref->inode);
/* The iterator is not valid until we seek to the desired position */
it->current = NULL;
/* Are we at the end? */
if (pos >= size) {
if (it->current_block.lb_id) {
int rc = ext4_block_set(it->inode_ref->fs->bdev,
&it->current_block);
it->current_block.lb_id = 0;
if (rc != EOK)
return rc;
}
it->current_offset = pos;
return EOK;
}
/* Compute next block address */
uint32_t block_size =
ext4_sb_get_block_size(&it->inode_ref->fs->sb);
uint64_t current_block_idx = it->current_offset / block_size;
uint64_t next_block_idx = pos / block_size;
/*
* If we don't have a block or are moving accross block boundary,
* we need to get another block
*/
if ((it->current_block.lb_id == 0) ||
(current_block_idx != next_block_idx)) {
if (it->current_block.lb_id) {
int rc = ext4_block_set(it->inode_ref->fs->bdev, &it->current_block);
it->current_block.lb_id = 0;
if (rc != EOK)
return rc;
}
uint32_t next_block_phys_idx;
int rc = ext4_fs_get_inode_data_block_index(it->inode_ref,
next_block_idx, &next_block_phys_idx);
if (rc != EOK)
return rc;
rc = ext4_block_get(it->inode_ref->fs->bdev, &it->current_block,
next_block_phys_idx);
if (rc != EOK) {
it->current_block.lb_id = 0;
return rc;
}
}
it->current_offset = pos;
return ext4_dir_iterator_set(it, block_size);
}
int ext4_dir_iterator_init(struct ext4_directory_iterator *it,
struct ext4_inode_ref *inode_ref, uint64_t pos)
{
it->inode_ref = inode_ref;
it->current = 0;
it->current_offset = 0;
it->current_block.lb_id = 0;
return ext4_dir_iterator_seek(it, pos);
}
int ext4_dir_iterator_next(struct ext4_directory_iterator *it)
{
int r = EOK;
uint16_t skip;
while(r == EOK){
skip = ext4_dir_entry_ll_get_entry_length(it->current);
r = ext4_dir_iterator_seek(it, it->current_offset + skip);
if(!it->current)
break;
/*Skip NULL referenced entry*/
if(it->current->inode != 0)
break;
}
return r;
}
int ext4_dir_iterator_fini(struct ext4_directory_iterator *it)
{
it->current = 0;
if (it->current_block.lb_id)
return ext4_block_set(it->inode_ref->fs->bdev, &it->current_block);
return EOK;
}
void ext4_dir_write_entry(struct ext4_sblock *sb,
struct ext4_directory_entry_ll *entry, uint16_t entry_len,
struct ext4_inode_ref *child, const char *name, size_t name_len)
{
/* Check maximum entry length */
uint32_t block_size = ext4_sb_get_block_size(sb);
ext4_assert(entry_len <= block_size);
/* Set basic attributes */
ext4_dir_entry_ll_set_inode(entry, child->index);
ext4_dir_entry_ll_set_entry_length(entry, entry_len);
ext4_dir_entry_ll_set_name_length(sb, entry, name_len);
/* Write name */
memcpy(entry->name, name, name_len);
/* Set type of entry */
if (ext4_inode_is_type(sb, child->inode, EXT4_INODE_MODE_DIRECTORY))
ext4_dir_entry_ll_set_inode_type(sb, entry,
EXT4_DIRECTORY_FILETYPE_DIR);
else
ext4_dir_entry_ll_set_inode_type(sb, entry,
EXT4_DIRECTORY_FILETYPE_REG_FILE);
}
int ext4_dir_add_entry(struct ext4_inode_ref *parent, const char *name,
uint32_t name_len, struct ext4_inode_ref *child)
{
struct ext4_fs *fs = parent->fs;
#if CONFIG_DIR_INDEX_ENABLE
/* Index adding (if allowed) */
if ((ext4_sb_check_feature_compatible(&fs->sb,
EXT4_FEATURE_COMPAT_DIR_INDEX)) &&
(ext4_inode_has_flag(parent->inode, EXT4_INODE_FLAG_INDEX))) {
int rc = ext4_dir_dx_add_entry(parent, child, name);
/* Check if index is not corrupted */
if (rc != EXT4_ERR_BAD_DX_DIR) {
if (rc != EOK)
return rc;
return EOK;
}
/* Needed to clear dir index flag if corrupted */
ext4_inode_clear_flag(parent->inode, EXT4_INODE_FLAG_INDEX);
parent->dirty = true;
}
#endif
/* Linear algorithm */
uint32_t iblock = 0;
uint32_t fblock = 0;
uint32_t block_size = ext4_sb_get_block_size(&fs->sb);
uint32_t inode_size = ext4_inode_get_size(&fs->sb, parent->inode);
uint32_t total_blocks = inode_size / block_size;
/* Find block, where is space for new entry and try to add */
bool success = false;
for (iblock = 0; iblock < total_blocks; ++iblock) {
int rc = ext4_fs_get_inode_data_block_index(parent,
iblock, &fblock);
if (rc != EOK)
return rc;
struct ext4_block block;
rc = ext4_block_get(fs->bdev, &block, fblock);
if (rc != EOK)
return rc;
/* If adding is successful, function can finish */
rc = ext4_dir_try_insert_entry(&fs->sb, &block,
child, name, name_len);
if (rc == EOK)
success = true;
rc = ext4_block_set(fs->bdev, &block);
if (rc != EOK)
return rc;
if (success)
return EOK;
}
/* No free block found - needed to allocate next data block */
iblock = 0;
fblock = 0;
int rc = ext4_fs_append_inode_block(parent, &fblock, &iblock);
if (rc != EOK)
return rc;
/* Load new block */
struct ext4_block new_block;
rc = ext4_block_get(fs->bdev, &new_block, fblock);
if (rc != EOK)
return rc;
/* Fill block with zeroes */
memset(new_block.data, 0, block_size);
struct ext4_directory_entry_ll *block_entry = (void *)new_block.data;
ext4_dir_write_entry(&fs->sb, block_entry, block_size,
child, name, name_len);
/* Save new block */
new_block.dirty = true;
rc = ext4_block_set(fs->bdev, &new_block);
return rc;
}
int ext4_dir_find_entry(struct ext4_directory_search_result *result,
struct ext4_inode_ref *parent, const char *name, uint32_t name_len)
{
struct ext4_sblock *sb = &parent->fs->sb;
#if CONFIG_DIR_INDEX_ENABLE
/* Index search */
if ((ext4_sb_check_feature_compatible(sb,
EXT4_FEATURE_COMPAT_DIR_INDEX)) &&
(ext4_inode_has_flag(parent->inode, EXT4_INODE_FLAG_INDEX))) {
int rc = ext4_dir_dx_find_entry(result, parent, name_len,
name);
/* Check if index is not corrupted */
if (rc != EXT4_ERR_BAD_DX_DIR) {
if (rc != EOK)
return rc;
return EOK;
}
/* Needed to clear dir index flag if corrupted */
ext4_inode_clear_flag(parent->inode, EXT4_INODE_FLAG_INDEX);
parent->dirty = true;
}
#endif
/* Linear algorithm */
uint32_t iblock;
uint32_t fblock;
uint32_t block_size = ext4_sb_get_block_size(sb);
uint32_t inode_size = ext4_inode_get_size(sb, parent->inode);
uint32_t total_blocks = inode_size / block_size;
/* Walk through all data blocks */
for (iblock = 0; iblock < total_blocks; ++iblock) {
/* Load block address */
int rc = ext4_fs_get_inode_data_block_index(parent, iblock,
&fblock);
if (rc != EOK)
return rc;
/* Load data block */
struct ext4_block block;
rc = ext4_block_get( parent->fs->bdev, &block, fblock);
if (rc != EOK)
return rc;
/* Try to find entry in block */
struct ext4_directory_entry_ll *res_entry;
rc = ext4_dir_find_in_block(&block, sb, name_len, name,
&res_entry);
if (rc == EOK) {
result->block = block;
result->dentry = res_entry;
return EOK;
}
/* Entry not found - put block and continue to the next block */
rc = ext4_block_set(parent->fs->bdev, &block);
if (rc != EOK)
return rc;
}
/* Entry was not found */
result->block.lb_id = 0;
result->dentry = NULL;
return ENOENT;
}
int ext4_dir_remove_entry(struct ext4_inode_ref *parent, const char *name,
uint32_t name_len)
{
/* Check if removing from directory */
if (!ext4_inode_is_type(&parent->fs->sb, parent->inode,
EXT4_INODE_MODE_DIRECTORY))
return ENOTDIR;
/* Try to find entry */
struct ext4_directory_search_result result;
int rc = ext4_dir_find_entry(&result, parent, name, name_len);
if (rc != EOK)
return rc;
/* Invalidate entry */
ext4_dir_entry_ll_set_inode(result.dentry, 0);
/* Store entry position in block */
uint32_t pos = (uint8_t *) result.dentry - result.block.data;
/*
* If entry is not the first in block, it must be merged
* with previous entry
*/
if (pos != 0) {
uint32_t offset = 0;
/* Start from the first entry in block */
struct ext4_directory_entry_ll *tmp_dentry = (void *)result.block.data;
uint16_t tmp_dentry_length =
ext4_dir_entry_ll_get_entry_length(tmp_dentry);
/* Find direct predecessor of removed entry */
while ((offset + tmp_dentry_length) < pos) {
offset +=
ext4_dir_entry_ll_get_entry_length(tmp_dentry);
tmp_dentry = (void *)(result.block.data + offset);
tmp_dentry_length =
ext4_dir_entry_ll_get_entry_length(tmp_dentry);
}
ext4_assert(tmp_dentry_length + offset == pos);
/* Add to removed entry length to predecessor's length */
uint16_t del_entry_length =
ext4_dir_entry_ll_get_entry_length(result.dentry);
ext4_dir_entry_ll_set_entry_length(tmp_dentry,
tmp_dentry_length + del_entry_length);
}
result.block.dirty = true;
return ext4_dir_destroy_result(parent, &result);
}
int ext4_dir_try_insert_entry(struct ext4_sblock *sb,
struct ext4_block *target_block, struct ext4_inode_ref *child,
const char *name, uint32_t name_len)
{
/* Compute required length entry and align it to 4 bytes */
uint32_t block_size = ext4_sb_get_block_size(sb);
uint16_t required_len = sizeof(struct ext4_fake_directory_entry) + name_len;
if ((required_len % 4) != 0)
required_len += 4 - (required_len % 4);
/* Initialize pointers, stop means to upper bound */
struct ext4_directory_entry_ll *dentry = (void *)target_block->data;
struct ext4_directory_entry_ll *stop =
(void *)(target_block->data + block_size);
/*
* Walk through the block and check for invalid entries
* or entries with free space for new entry
*/
while (dentry < stop) {
uint32_t inode = ext4_dir_entry_ll_get_inode(dentry);
uint16_t rec_len = ext4_dir_entry_ll_get_entry_length(dentry);
/* If invalid and large enough entry, use it */
if ((inode == 0) && (rec_len >= required_len)) {
ext4_dir_write_entry(sb, dentry, rec_len, child,
name, name_len);
target_block->dirty = true;
return EOK;
}
/* Valid entry, try to split it */
if (inode != 0) {
uint16_t used_name_len =
ext4_dir_entry_ll_get_name_length(sb, dentry);
uint16_t used_space =
sizeof(struct ext4_fake_directory_entry) + used_name_len;
if ((used_name_len % 4) != 0)
used_space += 4 - (used_name_len % 4);
uint16_t free_space = rec_len - used_space;
/* There is free space for new entry */
if (free_space >= required_len) {
/* Cut tail of current entry */
ext4_dir_entry_ll_set_entry_length(dentry, used_space);
struct ext4_directory_entry_ll *new_entry =
(void *) ((uint8_t *)dentry + used_space);
ext4_dir_write_entry(sb, new_entry,
free_space, child, name, name_len);
target_block->dirty = true;
return EOK;
}
}
/* Jump to the next entry */
dentry = (void *) ((uint8_t *)dentry + rec_len);
}
/* No free space found for new entry */
return ENOSPC;
}
int ext4_dir_find_in_block(struct ext4_block *block, struct ext4_sblock *sb,
size_t name_len, const char *name,
struct ext4_directory_entry_ll **res_entry)
{
/* Start from the first entry in block */
struct ext4_directory_entry_ll *dentry =
(struct ext4_directory_entry_ll *) block->data;
/* Set upper bound for cycling */
uint8_t *addr_limit = block->data + ext4_sb_get_block_size(sb);
/* Walk through the block and check entries */
while ((uint8_t *) dentry < addr_limit) {
/* Termination condition */
if ((uint8_t *) dentry + name_len > addr_limit)
break;
/* Valid entry - check it */
if (dentry->inode != 0) {
/* For more effectivity compare firstly only lengths */
if (ext4_dir_entry_ll_get_name_length(sb, dentry) ==
name_len) {
/* Compare names */
if (memcmp((uint8_t *) name, dentry->name, name_len) == 0) {
*res_entry = dentry;
return EOK;
}
}
}
uint16_t dentry_len =
ext4_dir_entry_ll_get_entry_length(dentry);
/* Corrupted entry */
if (dentry_len == 0)
return EINVAL;
/* Jump to next entry */
dentry = (struct ext4_directory_entry_ll *)
((uint8_t *) dentry + dentry_len);
}
/* Entry not found */
return ENOENT;
}
int ext4_dir_destroy_result(struct ext4_inode_ref *parent,
struct ext4_directory_search_result *result)
{
if (result->block.lb_id)
return ext4_block_set(parent->fs->bdev, &result->block);
return EOK;
}
/**
* @}
*/