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u-boot-brain/fs/ext4/ext4_common.c
Stefan Brüns 9f5dd8b6e2 ext4: Add helper functions for block group descriptor field access 
The helper functions encapsulate access of the block group descriptors,
independent of group descriptor size. The helpers also deal with the
endianess of the fields, and with split fields like free_blocks/
free_blocks_high.

Signed-off-by: Stefan Brüns <stefan.bruens@rwth-aachen.de>
2016-09-23 09:18:56 -04:00

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/*
* (C) Copyright 2011 - 2012 Samsung Electronics
* EXT4 filesystem implementation in Uboot by
* Uma Shankar <uma.shankar@samsung.com>
* Manjunatha C Achar <a.manjunatha@samsung.com>
*
* ext4ls and ext4load : Based on ext2 ls load support in Uboot.
*
* (C) Copyright 2004
* esd gmbh <www.esd-electronics.com>
* Reinhard Arlt <reinhard.arlt@esd-electronics.com>
*
* based on code from grub2 fs/ext2.c and fs/fshelp.c by
* GRUB -- GRand Unified Bootloader
* Copyright (C) 2003, 2004 Free Software Foundation, Inc.
*
* ext4write : Based on generic ext4 protocol.
*
* SPDX-License-Identifier: GPL-2.0+
*/
#include <common.h>
#include <ext_common.h>
#include <ext4fs.h>
#include <inttypes.h>
#include <malloc.h>
#include <memalign.h>
#include <stddef.h>
#include <linux/stat.h>
#include <linux/time.h>
#include <asm/byteorder.h>
#include "ext4_common.h"
struct ext2_data *ext4fs_root;
struct ext2fs_node *ext4fs_file;
__le32 *ext4fs_indir1_block;
int ext4fs_indir1_size;
int ext4fs_indir1_blkno = -1;
__le32 *ext4fs_indir2_block;
int ext4fs_indir2_size;
int ext4fs_indir2_blkno = -1;
__le32 *ext4fs_indir3_block;
int ext4fs_indir3_size;
int ext4fs_indir3_blkno = -1;
struct ext2_inode *g_parent_inode;
static int symlinknest;
#if defined(CONFIG_EXT4_WRITE)
struct ext2_block_group *ext4fs_get_group_descriptor
(const struct ext_filesystem *fs, uint32_t bg_idx)
{
return (struct ext2_block_group *)(fs->gdtable + (bg_idx * fs->gdsize));
}
static inline void ext4fs_sb_free_inodes_dec(struct ext2_sblock *sb)
{
sb->free_inodes = cpu_to_le32(le32_to_cpu(sb->free_inodes) - 1);
}
static inline void ext4fs_sb_free_blocks_dec(struct ext2_sblock *sb)
{
sb->free_blocks = cpu_to_le32(le32_to_cpu(sb->free_blocks) - 1);
}
static inline void ext4fs_bg_free_inodes_dec(struct ext2_block_group *bg)
{
bg->free_inodes = cpu_to_le16(le16_to_cpu(bg->free_inodes) - 1);
}
static inline void ext4fs_bg_free_blocks_dec(struct ext2_block_group *bg)
{
bg->free_blocks = cpu_to_le16(le16_to_cpu(bg->free_blocks) - 1);
}
static inline void ext4fs_bg_itable_unused_dec(struct ext2_block_group *bg)
{
bg->bg_itable_unused = cpu_to_le16(le16_to_cpu(bg->bg_itable_unused) - 1);
}
uint64_t ext4fs_sb_get_free_blocks(const struct ext2_sblock *sb)
{
uint64_t free_blocks = le32_to_cpu(sb->free_blocks);
free_blocks += (uint64_t)le32_to_cpu(sb->free_blocks_high) << 32;
return free_blocks;
}
void ext4fs_sb_set_free_blocks(struct ext2_sblock *sb, uint64_t free_blocks)
{
sb->free_blocks = cpu_to_le32(free_blocks & 0xffffffff);
sb->free_blocks_high = cpu_to_le16(free_blocks >> 32);
}
uint32_t ext4fs_bg_get_free_blocks(const struct ext2_block_group *bg,
const struct ext_filesystem *fs)
{
uint32_t free_blocks = le16_to_cpu(bg->free_blocks);
if (fs->gdsize == 64)
free_blocks += le16_to_cpu(bg->free_blocks_high) << 16;
return free_blocks;
}
static inline
uint32_t ext4fs_bg_get_free_inodes(const struct ext2_block_group *bg,
const struct ext_filesystem *fs)
{
uint32_t free_inodes = le16_to_cpu(bg->free_inodes);
if (fs->gdsize == 64)
free_inodes += le16_to_cpu(bg->free_inodes_high) << 16;
return free_inodes;
}
static inline uint16_t ext4fs_bg_get_flags(const struct ext2_block_group *bg)
{
return le16_to_cpu(bg->bg_flags);
}
static inline void ext4fs_bg_set_flags(struct ext2_block_group *bg,
uint16_t flags)
{
bg->bg_flags = cpu_to_le16(flags);
}
/* Block number of the block bitmap */
uint64_t ext4fs_bg_get_block_id(const struct ext2_block_group *bg,
const struct ext_filesystem *fs)
{
uint64_t block_nr = le32_to_cpu(bg->block_id);
if (fs->gdsize == 64)
block_nr += (uint64_t)le32_to_cpu(bg->block_id_high) << 32;
return block_nr;
}
/* Block number of the inode bitmap */
uint64_t ext4fs_bg_get_inode_id(const struct ext2_block_group *bg,
const struct ext_filesystem *fs)
{
uint64_t block_nr = le32_to_cpu(bg->inode_id);
if (fs->gdsize == 64)
block_nr += (uint64_t)le32_to_cpu(bg->inode_id_high) << 32;
return block_nr;
}
#endif
/* Block number of the inode table */
uint64_t ext4fs_bg_get_inode_table_id(const struct ext2_block_group *bg,
const struct ext_filesystem *fs)
{
uint64_t block_nr = le32_to_cpu(bg->inode_table_id);
if (fs->gdsize == 64)
block_nr +=
(uint64_t)le32_to_cpu(bg->inode_table_id_high) << 32;
return block_nr;
}
#if defined(CONFIG_EXT4_WRITE)
uint32_t ext4fs_div_roundup(uint32_t size, uint32_t n)
{
uint32_t res = size / n;
if (res * n != size)
res++;
return res;
}
void put_ext4(uint64_t off, void *buf, uint32_t size)
{
uint64_t startblock;
uint64_t remainder;
unsigned char *temp_ptr = NULL;
struct ext_filesystem *fs = get_fs();
int log2blksz = fs->dev_desc->log2blksz;
ALLOC_CACHE_ALIGN_BUFFER(unsigned char, sec_buf, fs->dev_desc->blksz);
startblock = off >> log2blksz;
startblock += part_offset;
remainder = off & (uint64_t)(fs->dev_desc->blksz - 1);
if (fs->dev_desc == NULL)
return;
if ((startblock + (size >> log2blksz)) >
(part_offset + fs->total_sect)) {
printf("part_offset is " LBAFU "\n", part_offset);
printf("total_sector is %" PRIu64 "\n", fs->total_sect);
printf("error: overflow occurs\n");
return;
}
if (remainder) {
blk_dread(fs->dev_desc, startblock, 1, sec_buf);
temp_ptr = sec_buf;
memcpy((temp_ptr + remainder), (unsigned char *)buf, size);
blk_dwrite(fs->dev_desc, startblock, 1, sec_buf);
} else {
if (size >> log2blksz != 0) {
blk_dwrite(fs->dev_desc, startblock, size >> log2blksz,
(unsigned long *)buf);
} else {
blk_dread(fs->dev_desc, startblock, 1, sec_buf);
temp_ptr = sec_buf;
memcpy(temp_ptr, buf, size);
blk_dwrite(fs->dev_desc, startblock, 1,
(unsigned long *)sec_buf);
}
}
}
static int _get_new_inode_no(unsigned char *buffer)
{
struct ext_filesystem *fs = get_fs();
unsigned char input;
int operand, status;
int count = 1;
int j = 0;
/* get the blocksize of the filesystem */
unsigned char *ptr = buffer;
while (*ptr == 255) {
ptr++;
count += 8;
if (count > le32_to_cpu(ext4fs_root->sblock.inodes_per_group))
return -1;
}
for (j = 0; j < fs->blksz; j++) {
input = *ptr;
int i = 0;
while (i <= 7) {
operand = 1 << i;
status = input & operand;
if (status) {
i++;
count++;
} else {
*ptr |= operand;
return count;
}
}
ptr = ptr + 1;
}
return -1;
}
static int _get_new_blk_no(unsigned char *buffer)
{
int operand;
int count = 0;
int i;
unsigned char *ptr = buffer;
struct ext_filesystem *fs = get_fs();
while (*ptr == 255) {
ptr++;
count += 8;
if (count == (fs->blksz * 8))
return -1;
}
if (fs->blksz == 1024)
count += 1;
for (i = 0; i <= 7; i++) {
operand = 1 << i;
if (*ptr & operand) {
count++;
} else {
*ptr |= operand;
return count;
}
}
return -1;
}
int ext4fs_set_block_bmap(long int blockno, unsigned char *buffer, int index)
{
int i, remainder, status;
unsigned char *ptr = buffer;
unsigned char operand;
i = blockno / 8;
remainder = blockno % 8;
int blocksize = EXT2_BLOCK_SIZE(ext4fs_root);
i = i - (index * blocksize);
if (blocksize != 1024) {
ptr = ptr + i;
operand = 1 << remainder;
status = *ptr & operand;
if (status)
return -1;
*ptr = *ptr | operand;
return 0;
} else {
if (remainder == 0) {
ptr = ptr + i - 1;
operand = (1 << 7);
} else {
ptr = ptr + i;
operand = (1 << (remainder - 1));
}
status = *ptr & operand;
if (status)
return -1;
*ptr = *ptr | operand;
return 0;
}
}
void ext4fs_reset_block_bmap(long int blockno, unsigned char *buffer, int index)
{
int i, remainder, status;
unsigned char *ptr = buffer;
unsigned char operand;
i = blockno / 8;
remainder = blockno % 8;
int blocksize = EXT2_BLOCK_SIZE(ext4fs_root);
i = i - (index * blocksize);
if (blocksize != 1024) {
ptr = ptr + i;
operand = (1 << remainder);
status = *ptr & operand;
if (status)
*ptr = *ptr & ~(operand);
} else {
if (remainder == 0) {
ptr = ptr + i - 1;
operand = (1 << 7);
} else {
ptr = ptr + i;
operand = (1 << (remainder - 1));
}
status = *ptr & operand;
if (status)
*ptr = *ptr & ~(operand);
}
}
int ext4fs_set_inode_bmap(int inode_no, unsigned char *buffer, int index)
{
int i, remainder, status;
unsigned char *ptr = buffer;
unsigned char operand;
inode_no -= (index * le32_to_cpu(ext4fs_root->sblock.inodes_per_group));
i = inode_no / 8;
remainder = inode_no % 8;
if (remainder == 0) {
ptr = ptr + i - 1;
operand = (1 << 7);
} else {
ptr = ptr + i;
operand = (1 << (remainder - 1));
}
status = *ptr & operand;
if (status)
return -1;
*ptr = *ptr | operand;
return 0;
}
void ext4fs_reset_inode_bmap(int inode_no, unsigned char *buffer, int index)
{
int i, remainder, status;
unsigned char *ptr = buffer;
unsigned char operand;
inode_no -= (index * le32_to_cpu(ext4fs_root->sblock.inodes_per_group));
i = inode_no / 8;
remainder = inode_no % 8;
if (remainder == 0) {
ptr = ptr + i - 1;
operand = (1 << 7);
} else {
ptr = ptr + i;
operand = (1 << (remainder - 1));
}
status = *ptr & operand;
if (status)
*ptr = *ptr & ~(operand);
}
uint16_t ext4fs_checksum_update(uint32_t i)
{
struct ext2_block_group *desc;
struct ext_filesystem *fs = get_fs();
uint16_t crc = 0;
__le32 le32_i = cpu_to_le32(i);
desc = (struct ext2_block_group *)&fs->bgd[i];
if (le32_to_cpu(fs->sb->feature_ro_compat) & EXT4_FEATURE_RO_COMPAT_GDT_CSUM) {
int offset = offsetof(struct ext2_block_group, bg_checksum);
crc = ext2fs_crc16(~0, fs->sb->unique_id,
sizeof(fs->sb->unique_id));
crc = ext2fs_crc16(crc, &le32_i, sizeof(le32_i));
crc = ext2fs_crc16(crc, desc, offset);
offset += sizeof(desc->bg_checksum); /* skip checksum */
assert(offset == sizeof(*desc));
}
return crc;
}
static int check_void_in_dentry(struct ext2_dirent *dir, char *filename)
{
int dentry_length;
int sizeof_void_space;
int new_entry_byte_reqd;
short padding_factor = 0;
if (dir->namelen % 4 != 0)
padding_factor = 4 - (dir->namelen % 4);
dentry_length = sizeof(struct ext2_dirent) +
dir->namelen + padding_factor;
sizeof_void_space = le16_to_cpu(dir->direntlen) - dentry_length;
if (sizeof_void_space == 0)
return 0;
padding_factor = 0;
if (strlen(filename) % 4 != 0)
padding_factor = 4 - (strlen(filename) % 4);
new_entry_byte_reqd = strlen(filename) +
sizeof(struct ext2_dirent) + padding_factor;
if (sizeof_void_space >= new_entry_byte_reqd) {
dir->direntlen = cpu_to_le16(dentry_length);
return sizeof_void_space;
}
return 0;
}
int ext4fs_update_parent_dentry(char *filename, int file_type)
{
unsigned int *zero_buffer = NULL;
char *root_first_block_buffer = NULL;
int blk_idx;
long int first_block_no_of_root = 0;
int totalbytes = 0;
unsigned int new_entry_byte_reqd;
int sizeof_void_space = 0;
int templength = 0;
int inodeno = -1;
int status;
struct ext_filesystem *fs = get_fs();
/* directory entry */
struct ext2_dirent *dir;
char *temp_dir = NULL;
uint32_t new_blk_no;
uint32_t new_size;
uint32_t new_blockcnt;
uint32_t directory_blocks;
zero_buffer = zalloc(fs->blksz);
if (!zero_buffer) {
printf("No Memory\n");
return -1;
}
root_first_block_buffer = zalloc(fs->blksz);
if (!root_first_block_buffer) {
free(zero_buffer);
printf("No Memory\n");
return -1;
}
new_entry_byte_reqd = ROUND(strlen(filename) +
sizeof(struct ext2_dirent), 4);
restart:
directory_blocks = le32_to_cpu(g_parent_inode->size) >>
LOG2_BLOCK_SIZE(ext4fs_root);
blk_idx = directory_blocks - 1;
restart_read:
/* read the block no allocated to a file */
first_block_no_of_root = read_allocated_block(g_parent_inode, blk_idx);
if (first_block_no_of_root <= 0)
goto fail;
status = ext4fs_devread((lbaint_t)first_block_no_of_root
* fs->sect_perblk,
0, fs->blksz, root_first_block_buffer);
if (status == 0)
goto fail;
if (ext4fs_log_journal(root_first_block_buffer, first_block_no_of_root))
goto fail;
dir = (struct ext2_dirent *)root_first_block_buffer;
totalbytes = 0;
while (le16_to_cpu(dir->direntlen) > 0) {
unsigned short used_len = ROUND(dir->namelen +
sizeof(struct ext2_dirent), 4);
/* last entry of block */
if (fs->blksz - totalbytes == le16_to_cpu(dir->direntlen)) {
/* check if new entry fits */
if ((used_len + new_entry_byte_reqd) <=
le16_to_cpu(dir->direntlen)) {
dir->direntlen = cpu_to_le16(used_len);
break;
} else {
if (blk_idx > 0) {
printf("Block full, trying previous\n");
blk_idx--;
goto restart_read;
}
printf("All blocks full: Allocate new\n");
if (le32_to_cpu(g_parent_inode->flags) &
EXT4_EXTENTS_FL) {
printf("Directory uses extents\n");
goto fail;
}
if (directory_blocks >= INDIRECT_BLOCKS) {
printf("Directory exceeds limit\n");
goto fail;
}
new_blk_no = ext4fs_get_new_blk_no();
if (new_blk_no == -1) {
printf("no block left to assign\n");
goto fail;
}
put_ext4((uint64_t)new_blk_no * fs->blksz, zero_buffer, fs->blksz);
g_parent_inode->b.blocks.
dir_blocks[directory_blocks] =
cpu_to_le32(new_blk_no);
new_size = le32_to_cpu(g_parent_inode->size);
new_size += fs->blksz;
g_parent_inode->size = cpu_to_le32(new_size);
new_blockcnt = le32_to_cpu(g_parent_inode->blockcnt);
new_blockcnt += fs->sect_perblk;
g_parent_inode->blockcnt = cpu_to_le32(new_blockcnt);
if (ext4fs_put_metadata
(root_first_block_buffer,
first_block_no_of_root))
goto fail;
goto restart;
}
}
templength = le16_to_cpu(dir->direntlen);
totalbytes = totalbytes + templength;
sizeof_void_space = check_void_in_dentry(dir, filename);
if (sizeof_void_space)
break;
dir = (struct ext2_dirent *)((char *)dir + templength);
}
/* make a pointer ready for creating next directory entry */
templength = le16_to_cpu(dir->direntlen);
totalbytes = totalbytes + templength;
dir = (struct ext2_dirent *)((char *)dir + templength);
/* get the next available inode number */
inodeno = ext4fs_get_new_inode_no();
if (inodeno == -1) {
printf("no inode left to assign\n");
goto fail;
}
dir->inode = cpu_to_le32(inodeno);
if (sizeof_void_space)
dir->direntlen = cpu_to_le16(sizeof_void_space);
else
dir->direntlen = cpu_to_le16(fs->blksz - totalbytes);
dir->namelen = strlen(filename);
dir->filetype = FILETYPE_REG; /* regular file */
temp_dir = (char *)dir;
temp_dir = temp_dir + sizeof(struct ext2_dirent);
memcpy(temp_dir, filename, strlen(filename));
/* update or write the 1st block of root inode */
if (ext4fs_put_metadata(root_first_block_buffer,
first_block_no_of_root))
goto fail;
fail:
free(zero_buffer);
free(root_first_block_buffer);
return inodeno;
}
static int search_dir(struct ext2_inode *parent_inode, char *dirname)
{
int status;
int inodeno = 0;
int offset;
int blk_idx;
long int blknr;
char *block_buffer = NULL;
struct ext2_dirent *dir = NULL;
struct ext_filesystem *fs = get_fs();
uint32_t directory_blocks;
char *direntname;
directory_blocks = le32_to_cpu(parent_inode->size) >>
LOG2_BLOCK_SIZE(ext4fs_root);
block_buffer = zalloc(fs->blksz);
if (!block_buffer)
goto fail;
/* get the block no allocated to a file */
for (blk_idx = 0; blk_idx < directory_blocks; blk_idx++) {
blknr = read_allocated_block(parent_inode, blk_idx);
if (blknr <= 0)
goto fail;
/* read the directory block */
status = ext4fs_devread((lbaint_t)blknr * fs->sect_perblk,
0, fs->blksz, (char *)block_buffer);
if (status == 0)
goto fail;
offset = 0;
do {
dir = (struct ext2_dirent *)(block_buffer + offset);
direntname = (char*)(dir) + sizeof(struct ext2_dirent);
int direntlen = le16_to_cpu(dir->direntlen);
if (direntlen < sizeof(struct ext2_dirent))
break;
if (dir->inode && (strlen(dirname) == dir->namelen) &&
(strncmp(dirname, direntname, dir->namelen) == 0)) {
inodeno = le32_to_cpu(dir->inode);
break;
}
offset += direntlen;
} while (offset < fs->blksz);
if (inodeno > 0) {
free(block_buffer);
return inodeno;
}
}
fail:
free(block_buffer);
return -1;
}
static int find_dir_depth(char *dirname)
{
char *token = strtok(dirname, "/");
int count = 0;
while (token != NULL) {
token = strtok(NULL, "/");
count++;
}
return count + 1 + 1;
/*
* for example for string /home/temp
* depth=home(1)+temp(1)+1 extra for NULL;
* so count is 4;
*/
}
static int parse_path(char **arr, char *dirname)
{
char *token = strtok(dirname, "/");
int i = 0;
/* add root */
arr[i] = zalloc(strlen("/") + 1);
if (!arr[i])
return -ENOMEM;
memcpy(arr[i++], "/", strlen("/"));
/* add each path entry after root */
while (token != NULL) {
arr[i] = zalloc(strlen(token) + 1);
if (!arr[i])
return -ENOMEM;
memcpy(arr[i++], token, strlen(token));
token = strtok(NULL, "/");
}
arr[i] = NULL;
return 0;
}
int ext4fs_iget(int inode_no, struct ext2_inode *inode)
{
if (ext4fs_read_inode(ext4fs_root, inode_no, inode) == 0)
return -1;
return 0;
}
/*
* Function: ext4fs_get_parent_inode_num
* Return Value: inode Number of the parent directory of file/Directory to be
* created
* dirname : Input parmater, input path name of the file/directory to be created
* dname : Output parameter, to be filled with the name of the directory
* extracted from dirname
*/
int ext4fs_get_parent_inode_num(const char *dirname, char *dname, int flags)
{
int i;
int depth = 0;
int matched_inode_no;
int result_inode_no = -1;
char **ptr = NULL;
char *depth_dirname = NULL;
char *parse_dirname = NULL;
struct ext2_inode *parent_inode = NULL;
struct ext2_inode *first_inode = NULL;
struct ext2_inode temp_inode;
if (*dirname != '/') {
printf("Please supply Absolute path\n");
return -1;
}
/* TODO: input validation make equivalent to linux */
depth_dirname = zalloc(strlen(dirname) + 1);
if (!depth_dirname)
return -ENOMEM;
memcpy(depth_dirname, dirname, strlen(dirname));
depth = find_dir_depth(depth_dirname);
parse_dirname = zalloc(strlen(dirname) + 1);
if (!parse_dirname)
goto fail;
memcpy(parse_dirname, dirname, strlen(dirname));
/* allocate memory for each directory level */
ptr = zalloc((depth) * sizeof(char *));
if (!ptr)
goto fail;
if (parse_path(ptr, parse_dirname))
goto fail;
parent_inode = zalloc(sizeof(struct ext2_inode));
if (!parent_inode)
goto fail;
first_inode = zalloc(sizeof(struct ext2_inode));
if (!first_inode)
goto fail;
memcpy(parent_inode, ext4fs_root->inode, sizeof(struct ext2_inode));
memcpy(first_inode, parent_inode, sizeof(struct ext2_inode));
if (flags & F_FILE)
result_inode_no = EXT2_ROOT_INO;
for (i = 1; i < depth; i++) {
matched_inode_no = search_dir(parent_inode, ptr[i]);
if (matched_inode_no == -1) {
if (ptr[i + 1] == NULL && i == 1) {
result_inode_no = EXT2_ROOT_INO;
goto end;
} else {
if (ptr[i + 1] == NULL)
break;
printf("Invalid path\n");
result_inode_no = -1;
goto fail;
}
} else {
if (ptr[i + 1] != NULL) {
memset(parent_inode, '\0',
sizeof(struct ext2_inode));
if (ext4fs_iget(matched_inode_no,
parent_inode)) {
result_inode_no = -1;
goto fail;
}
result_inode_no = matched_inode_no;
} else {
break;
}
}
}
end:
if (i == 1)
matched_inode_no = search_dir(first_inode, ptr[i]);
else
matched_inode_no = search_dir(parent_inode, ptr[i]);
if (matched_inode_no != -1) {
ext4fs_iget(matched_inode_no, &temp_inode);
if (le16_to_cpu(temp_inode.mode) & S_IFDIR) {
printf("It is a Directory\n");
result_inode_no = -1;
goto fail;
}
}
if (strlen(ptr[i]) > 256) {
result_inode_no = -1;
goto fail;
}
memcpy(dname, ptr[i], strlen(ptr[i]));
fail:
free(depth_dirname);
free(parse_dirname);
for (i = 0; i < depth; i++) {
if (!ptr[i])
break;
free(ptr[i]);
}
free(ptr);
free(parent_inode);
free(first_inode);
return result_inode_no;
}
static int unlink_filename(char *filename, unsigned int blknr)
{
int totalbytes = 0;
int templength = 0;
int status, inodeno;
int found = 0;
char *root_first_block_buffer = NULL;
struct ext2_dirent *dir = NULL;
struct ext2_dirent *previous_dir = NULL;
char *ptr = NULL;
struct ext_filesystem *fs = get_fs();
int ret = -1;
/* get the first block of root */
root_first_block_buffer = zalloc(fs->blksz);
if (!root_first_block_buffer)
return -ENOMEM;
status = ext4fs_devread((lbaint_t)blknr * fs->sect_perblk, 0,
fs->blksz, root_first_block_buffer);
if (status == 0)
goto fail;
if (ext4fs_log_journal(root_first_block_buffer, blknr))
goto fail;
dir = (struct ext2_dirent *)root_first_block_buffer;
ptr = (char *)dir;
totalbytes = 0;
while (le16_to_cpu(dir->direntlen) >= 0) {
/*
* blocksize-totalbytes because last
* directory length i.e., *dir->direntlen
* is free availble space in the block that
* means it is a last entry of directory entry
*/
if (dir->inode && (strlen(filename) == dir->namelen) &&
(strncmp(ptr + sizeof(struct ext2_dirent),
filename, dir->namelen) == 0)) {
printf("file found, deleting\n");
inodeno = le32_to_cpu(dir->inode);
if (previous_dir) {
uint16_t new_len;
new_len = le16_to_cpu(previous_dir->direntlen);
new_len += le16_to_cpu(dir->direntlen);
previous_dir->direntlen = cpu_to_le16(new_len);
} else {
dir->inode = 0;
}
found = 1;
break;
}
if (fs->blksz - totalbytes == le16_to_cpu(dir->direntlen))
break;
/* traversing the each directory entry */
templength = le16_to_cpu(dir->direntlen);
totalbytes = totalbytes + templength;
previous_dir = dir;
dir = (struct ext2_dirent *)((char *)dir + templength);
ptr = (char *)dir;
}
if (found == 1) {
if (ext4fs_put_metadata(root_first_block_buffer, blknr))
goto fail;
ret = inodeno;
}
fail:
free(root_first_block_buffer);
return ret;
}
int ext4fs_filename_unlink(char *filename)
{
int blk_idx;
long int blknr = -1;
int inodeno = -1;
uint32_t directory_blocks;
directory_blocks = le32_to_cpu(g_parent_inode->size) >>
LOG2_BLOCK_SIZE(ext4fs_root);
/* read the block no allocated to a file */
for (blk_idx = 0; blk_idx < directory_blocks; blk_idx++) {
blknr = read_allocated_block(g_parent_inode, blk_idx);
if (blknr <= 0)
break;
inodeno = unlink_filename(filename, blknr);
if (inodeno != -1)
return inodeno;
}
return -1;
}
uint32_t ext4fs_get_new_blk_no(void)
{
short i;
short status;
int remainder;
unsigned int bg_idx;
static int prev_bg_bitmap_index = -1;
unsigned int blk_per_grp = le32_to_cpu(ext4fs_root->sblock.blocks_per_group);
struct ext_filesystem *fs = get_fs();
char *journal_buffer = zalloc(fs->blksz);
char *zero_buffer = zalloc(fs->blksz);
if (!journal_buffer || !zero_buffer)
goto fail;
struct ext2_block_group *bgd = (struct ext2_block_group *)fs->gdtable;
if (fs->first_pass_bbmap == 0) {
for (i = 0; i < fs->no_blkgrp; i++) {
if (le16_to_cpu(bgd[i].free_blocks)) {
if (le16_to_cpu(bgd[i].bg_flags) & EXT4_BG_BLOCK_UNINIT) {
uint16_t new_flags;
put_ext4((uint64_t)le32_to_cpu(bgd[i].block_id) * fs->blksz,
zero_buffer, fs->blksz);
new_flags = le16_to_cpu(bgd[i].bg_flags) & ~EXT4_BG_BLOCK_UNINIT;
bgd[i].bg_flags = cpu_to_le16(new_flags);
memcpy(fs->blk_bmaps[i], zero_buffer,
fs->blksz);
}
fs->curr_blkno =
_get_new_blk_no(fs->blk_bmaps[i]);
if (fs->curr_blkno == -1)
/* if block bitmap is completely fill */
continue;
fs->curr_blkno = fs->curr_blkno +
(i * fs->blksz * 8);
fs->first_pass_bbmap++;
ext4fs_bg_free_blocks_dec(&bgd[i]);
ext4fs_sb_free_blocks_dec(fs->sb);
status = ext4fs_devread(
(lbaint_t)le32_to_cpu(bgd[i].block_id) *
fs->sect_perblk, 0,
fs->blksz,
journal_buffer);
if (status == 0)
goto fail;
if (ext4fs_log_journal(journal_buffer,
le32_to_cpu(bgd[i].block_id)))
goto fail;
goto success;
} else {
debug("no space left on block group %d\n", i);
}
}
goto fail;
} else {
fs->curr_blkno++;
restart:
/* get the blockbitmap index respective to blockno */
bg_idx = fs->curr_blkno / blk_per_grp;
if (fs->blksz == 1024) {
remainder = fs->curr_blkno % blk_per_grp;
if (!remainder)
bg_idx--;
}
/*
* To skip completely filled block group bitmaps
* Optimize the block allocation
*/
if (bg_idx >= fs->no_blkgrp)
goto fail;
if (bgd[bg_idx].free_blocks == 0) {
debug("block group %u is full. Skipping\n", bg_idx);
fs->curr_blkno = (bg_idx + 1) * blk_per_grp;
if (fs->blksz == 1024)
fs->curr_blkno += 1;
goto restart;
}
if (le16_to_cpu(bgd[bg_idx].bg_flags) & EXT4_BG_BLOCK_UNINIT) {
uint16_t new_flags;
put_ext4((uint64_t)le32_to_cpu(bgd[bg_idx].block_id) * fs->blksz,
zero_buffer, fs->blksz);
memcpy(fs->blk_bmaps[bg_idx], zero_buffer, fs->blksz);
new_flags = le16_to_cpu(bgd[bg_idx].bg_flags) & ~EXT4_BG_BLOCK_UNINIT;
bgd[bg_idx].bg_flags = cpu_to_le16(new_flags);
}
if (ext4fs_set_block_bmap(fs->curr_blkno, fs->blk_bmaps[bg_idx],
bg_idx) != 0) {
debug("going for restart for the block no %ld %u\n",
fs->curr_blkno, bg_idx);
fs->curr_blkno++;
goto restart;
}
/* journal backup */
if (prev_bg_bitmap_index != bg_idx) {
status = ext4fs_devread(
(lbaint_t)le32_to_cpu(bgd[bg_idx].block_id)
* fs->sect_perblk,
0, fs->blksz, journal_buffer);
if (status == 0)
goto fail;
if (ext4fs_log_journal(journal_buffer,
le32_to_cpu(bgd[bg_idx].block_id)))
goto fail;
prev_bg_bitmap_index = bg_idx;
}
ext4fs_bg_free_blocks_dec(&bgd[bg_idx]);
ext4fs_sb_free_blocks_dec(fs->sb);
goto success;
}
success:
free(journal_buffer);
free(zero_buffer);
return fs->curr_blkno;
fail:
free(journal_buffer);
free(zero_buffer);
return -1;
}
int ext4fs_get_new_inode_no(void)
{
short i;
short status;
unsigned int ibmap_idx;
static int prev_inode_bitmap_index = -1;
unsigned int inodes_per_grp = le32_to_cpu(ext4fs_root->sblock.inodes_per_group);
struct ext_filesystem *fs = get_fs();
char *journal_buffer = zalloc(fs->blksz);
char *zero_buffer = zalloc(fs->blksz);
if (!journal_buffer || !zero_buffer)
goto fail;
struct ext2_block_group *bgd = (struct ext2_block_group *)fs->gdtable;
int has_gdt_chksum = le32_to_cpu(fs->sb->feature_ro_compat) &
EXT4_FEATURE_RO_COMPAT_GDT_CSUM ? 1 : 0;
if (fs->first_pass_ibmap == 0) {
for (i = 0; i < fs->no_blkgrp; i++) {
if (bgd[i].free_inodes) {
if (has_gdt_chksum)
bgd[i].bg_itable_unused =
bgd[i].free_inodes;
if (le16_to_cpu(bgd[i].bg_flags) & EXT4_BG_INODE_UNINIT) {
int new_flags;
put_ext4((uint64_t)le32_to_cpu(bgd[i].inode_id) * fs->blksz,
zero_buffer, fs->blksz);
new_flags = le16_to_cpu(bgd[i].bg_flags) & ~EXT4_BG_INODE_UNINIT;
bgd[i].bg_flags = cpu_to_le16(new_flags);
memcpy(fs->inode_bmaps[i],
zero_buffer, fs->blksz);
}
fs->curr_inode_no =
_get_new_inode_no(fs->inode_bmaps[i]);
if (fs->curr_inode_no == -1)
/* if block bitmap is completely fill */
continue;
fs->curr_inode_no = fs->curr_inode_no +
(i * inodes_per_grp);
fs->first_pass_ibmap++;
ext4fs_bg_free_inodes_dec(&bgd[i]);
if (has_gdt_chksum)
ext4fs_bg_itable_unused_dec(&bgd[i]);
ext4fs_sb_free_inodes_dec(fs->sb);
status = ext4fs_devread(
(lbaint_t)le32_to_cpu(bgd[i].inode_id) *
fs->sect_perblk, 0,
fs->blksz,
journal_buffer);
if (status == 0)
goto fail;
if (ext4fs_log_journal(journal_buffer,
le32_to_cpu(bgd[i].inode_id)))
goto fail;
goto success;
} else
debug("no inode left on block group %d\n", i);
}
goto fail;
} else {
restart:
fs->curr_inode_no++;
/* get the blockbitmap index respective to blockno */
ibmap_idx = fs->curr_inode_no / inodes_per_grp;
if (le16_to_cpu(bgd[ibmap_idx].bg_flags) & EXT4_BG_INODE_UNINIT) {
int new_flags;
put_ext4((uint64_t)le32_to_cpu(bgd[ibmap_idx].inode_id) * fs->blksz,
zero_buffer, fs->blksz);
new_flags = le16_to_cpu(bgd[ibmap_idx].bg_flags) & ~EXT4_BG_INODE_UNINIT;
bgd[ibmap_idx].bg_flags = cpu_to_le16(new_flags);
memcpy(fs->inode_bmaps[ibmap_idx], zero_buffer,
fs->blksz);
}
if (ext4fs_set_inode_bmap(fs->curr_inode_no,
fs->inode_bmaps[ibmap_idx],
ibmap_idx) != 0) {
debug("going for restart for the block no %d %u\n",
fs->curr_inode_no, ibmap_idx);
goto restart;
}
/* journal backup */
if (prev_inode_bitmap_index != ibmap_idx) {
memset(journal_buffer, '\0', fs->blksz);
status = ext4fs_devread(
(lbaint_t)le32_to_cpu(bgd[ibmap_idx].inode_id)
* fs->sect_perblk,
0, fs->blksz, journal_buffer);
if (status == 0)
goto fail;
if (ext4fs_log_journal(journal_buffer,
le32_to_cpu(bgd[ibmap_idx].inode_id)))
goto fail;
prev_inode_bitmap_index = ibmap_idx;
}
ext4fs_bg_free_inodes_dec(&bgd[ibmap_idx]);
if (has_gdt_chksum)
bgd[ibmap_idx].bg_itable_unused =
bgd[ibmap_idx].free_inodes;
ext4fs_sb_free_inodes_dec(fs->sb);
goto success;
}
success:
free(journal_buffer);
free(zero_buffer);
return fs->curr_inode_no;
fail:
free(journal_buffer);
free(zero_buffer);
return -1;
}
static void alloc_single_indirect_block(struct ext2_inode *file_inode,
unsigned int *total_remaining_blocks,
unsigned int *no_blks_reqd)
{
short i;
short status;
long int actual_block_no;
long int si_blockno;
/* si :single indirect */
__le32 *si_buffer = NULL;
__le32 *si_start_addr = NULL;
struct ext_filesystem *fs = get_fs();
if (*total_remaining_blocks != 0) {
si_buffer = zalloc(fs->blksz);
if (!si_buffer) {
printf("No Memory\n");
return;
}
si_start_addr = si_buffer;
si_blockno = ext4fs_get_new_blk_no();
if (si_blockno == -1) {
printf("no block left to assign\n");
goto fail;
}
(*no_blks_reqd)++;
debug("SIPB %ld: %u\n", si_blockno, *total_remaining_blocks);
status = ext4fs_devread((lbaint_t)si_blockno * fs->sect_perblk,
0, fs->blksz, (char *)si_buffer);
memset(si_buffer, '\0', fs->blksz);
if (status == 0)
goto fail;
for (i = 0; i < (fs->blksz / sizeof(int)); i++) {
actual_block_no = ext4fs_get_new_blk_no();
if (actual_block_no == -1) {
printf("no block left to assign\n");
goto fail;
}
*si_buffer = cpu_to_le32(actual_block_no);
debug("SIAB %u: %u\n", *si_buffer,
*total_remaining_blocks);
si_buffer++;
(*total_remaining_blocks)--;
if (*total_remaining_blocks == 0)
break;
}
/* write the block to disk */
put_ext4(((uint64_t) ((uint64_t)si_blockno * (uint64_t)fs->blksz)),
si_start_addr, fs->blksz);
file_inode->b.blocks.indir_block = cpu_to_le32(si_blockno);
}
fail:
free(si_start_addr);
}
static void alloc_double_indirect_block(struct ext2_inode *file_inode,
unsigned int *total_remaining_blocks,
unsigned int *no_blks_reqd)
{
short i;
short j;
short status;
long int actual_block_no;
/* di:double indirect */
long int di_blockno_parent;
long int di_blockno_child;
__le32 *di_parent_buffer = NULL;
__le32 *di_child_buff = NULL;
__le32 *di_block_start_addr = NULL;
__le32 *di_child_buff_start = NULL;
struct ext_filesystem *fs = get_fs();
if (*total_remaining_blocks != 0) {
/* double indirect parent block connecting to inode */
di_blockno_parent = ext4fs_get_new_blk_no();
if (di_blockno_parent == -1) {
printf("no block left to assign\n");
goto fail;
}
di_parent_buffer = zalloc(fs->blksz);
if (!di_parent_buffer)
goto fail;
di_block_start_addr = di_parent_buffer;
(*no_blks_reqd)++;
debug("DIPB %ld: %u\n", di_blockno_parent,
*total_remaining_blocks);
status = ext4fs_devread((lbaint_t)di_blockno_parent *
fs->sect_perblk, 0,
fs->blksz, (char *)di_parent_buffer);
if (!status) {
printf("%s: Device read error!\n", __func__);
goto fail;
}
memset(di_parent_buffer, '\0', fs->blksz);
/*
* start:for each double indirect parent
* block create one more block
*/
for (i = 0; i < (fs->blksz / sizeof(int)); i++) {
di_blockno_child = ext4fs_get_new_blk_no();
if (di_blockno_child == -1) {
printf("no block left to assign\n");
goto fail;
}
di_child_buff = zalloc(fs->blksz);
if (!di_child_buff)
goto fail;
di_child_buff_start = di_child_buff;
*di_parent_buffer = cpu_to_le32(di_blockno_child);
di_parent_buffer++;
(*no_blks_reqd)++;
debug("DICB %ld: %u\n", di_blockno_child,
*total_remaining_blocks);
status = ext4fs_devread((lbaint_t)di_blockno_child *
fs->sect_perblk, 0,
fs->blksz,
(char *)di_child_buff);
if (!status) {
printf("%s: Device read error!\n", __func__);
goto fail;
}
memset(di_child_buff, '\0', fs->blksz);
/* filling of actual datablocks for each child */
for (j = 0; j < (fs->blksz / sizeof(int)); j++) {
actual_block_no = ext4fs_get_new_blk_no();
if (actual_block_no == -1) {
printf("no block left to assign\n");
goto fail;
}
*di_child_buff = cpu_to_le32(actual_block_no);
debug("DIAB %ld: %u\n", actual_block_no,
*total_remaining_blocks);
di_child_buff++;
(*total_remaining_blocks)--;
if (*total_remaining_blocks == 0)
break;
}
/* write the block table */
put_ext4(((uint64_t) ((uint64_t)di_blockno_child * (uint64_t)fs->blksz)),
di_child_buff_start, fs->blksz);
free(di_child_buff_start);
di_child_buff_start = NULL;
if (*total_remaining_blocks == 0)
break;
}
put_ext4(((uint64_t) ((uint64_t)di_blockno_parent * (uint64_t)fs->blksz)),
di_block_start_addr, fs->blksz);
file_inode->b.blocks.double_indir_block = cpu_to_le32(di_blockno_parent);
}
fail:
free(di_block_start_addr);
}
static void alloc_triple_indirect_block(struct ext2_inode *file_inode,
unsigned int *total_remaining_blocks,
unsigned int *no_blks_reqd)
{
short i;
short j;
short k;
long int actual_block_no;
/* ti: Triple Indirect */
long int ti_gp_blockno;
long int ti_parent_blockno;
long int ti_child_blockno;
__le32 *ti_gp_buff = NULL;
__le32 *ti_parent_buff = NULL;
__le32 *ti_child_buff = NULL;
__le32 *ti_gp_buff_start_addr = NULL;
__le32 *ti_pbuff_start_addr = NULL;
__le32 *ti_cbuff_start_addr = NULL;
struct ext_filesystem *fs = get_fs();
if (*total_remaining_blocks != 0) {
/* triple indirect grand parent block connecting to inode */
ti_gp_blockno = ext4fs_get_new_blk_no();
if (ti_gp_blockno == -1) {
printf("no block left to assign\n");
return;
}
ti_gp_buff = zalloc(fs->blksz);
if (!ti_gp_buff)
return;
ti_gp_buff_start_addr = ti_gp_buff;
(*no_blks_reqd)++;
debug("TIGPB %ld: %u\n", ti_gp_blockno,
*total_remaining_blocks);
/* for each 4 byte grand parent entry create one more block */
for (i = 0; i < (fs->blksz / sizeof(int)); i++) {
ti_parent_blockno = ext4fs_get_new_blk_no();
if (ti_parent_blockno == -1) {
printf("no block left to assign\n");
goto fail;
}
ti_parent_buff = zalloc(fs->blksz);
if (!ti_parent_buff)
goto fail;
ti_pbuff_start_addr = ti_parent_buff;
*ti_gp_buff = cpu_to_le32(ti_parent_blockno);
ti_gp_buff++;
(*no_blks_reqd)++;
debug("TIPB %ld: %u\n", ti_parent_blockno,
*total_remaining_blocks);
/* for each 4 byte entry parent create one more block */
for (j = 0; j < (fs->blksz / sizeof(int)); j++) {
ti_child_blockno = ext4fs_get_new_blk_no();
if (ti_child_blockno == -1) {
printf("no block left assign\n");
goto fail1;
}
ti_child_buff = zalloc(fs->blksz);
if (!ti_child_buff)
goto fail1;
ti_cbuff_start_addr = ti_child_buff;
*ti_parent_buff = cpu_to_le32(ti_child_blockno);
ti_parent_buff++;
(*no_blks_reqd)++;
debug("TICB %ld: %u\n", ti_parent_blockno,
*total_remaining_blocks);
/* fill actual datablocks for each child */
for (k = 0; k < (fs->blksz / sizeof(int));
k++) {
actual_block_no =
ext4fs_get_new_blk_no();
if (actual_block_no == -1) {
printf("no block left\n");
free(ti_cbuff_start_addr);
goto fail1;
}
*ti_child_buff = cpu_to_le32(actual_block_no);
debug("TIAB %ld: %u\n", actual_block_no,
*total_remaining_blocks);
ti_child_buff++;
(*total_remaining_blocks)--;
if (*total_remaining_blocks == 0)
break;
}
/* write the child block */
put_ext4(((uint64_t) ((uint64_t)ti_child_blockno *
(uint64_t)fs->blksz)),
ti_cbuff_start_addr, fs->blksz);
free(ti_cbuff_start_addr);
if (*total_remaining_blocks == 0)
break;
}
/* write the parent block */
put_ext4(((uint64_t) ((uint64_t)ti_parent_blockno * (uint64_t)fs->blksz)),
ti_pbuff_start_addr, fs->blksz);
free(ti_pbuff_start_addr);
if (*total_remaining_blocks == 0)
break;
}
/* write the grand parent block */
put_ext4(((uint64_t) ((uint64_t)ti_gp_blockno * (uint64_t)fs->blksz)),
ti_gp_buff_start_addr, fs->blksz);
file_inode->b.blocks.triple_indir_block = cpu_to_le32(ti_gp_blockno);
free(ti_gp_buff_start_addr);
return;
}
fail1:
free(ti_pbuff_start_addr);
fail:
free(ti_gp_buff_start_addr);
}
void ext4fs_allocate_blocks(struct ext2_inode *file_inode,
unsigned int total_remaining_blocks,
unsigned int *total_no_of_block)
{
short i;
long int direct_blockno;
unsigned int no_blks_reqd = 0;
/* allocation of direct blocks */
for (i = 0; total_remaining_blocks && i < INDIRECT_BLOCKS; i++) {
direct_blockno = ext4fs_get_new_blk_no();
if (direct_blockno == -1) {
printf("no block left to assign\n");
return;
}
file_inode->b.blocks.dir_blocks[i] = cpu_to_le32(direct_blockno);
debug("DB %ld: %u\n", direct_blockno, total_remaining_blocks);
total_remaining_blocks--;
}
alloc_single_indirect_block(file_inode, &total_remaining_blocks,
&no_blks_reqd);
alloc_double_indirect_block(file_inode, &total_remaining_blocks,
&no_blks_reqd);
alloc_triple_indirect_block(file_inode, &total_remaining_blocks,
&no_blks_reqd);
*total_no_of_block += no_blks_reqd;
}
#endif
static struct ext4_extent_header *ext4fs_get_extent_block
(struct ext2_data *data, char *buf,
struct ext4_extent_header *ext_block,
uint32_t fileblock, int log2_blksz)
{
struct ext4_extent_idx *index;
unsigned long long block;
int blksz = EXT2_BLOCK_SIZE(data);
int i;
while (1) {
index = (struct ext4_extent_idx *)(ext_block + 1);
if (le16_to_cpu(ext_block->eh_magic) != EXT4_EXT_MAGIC)
return NULL;
if (ext_block->eh_depth == 0)
return ext_block;
i = -1;
do {
i++;
if (i >= le16_to_cpu(ext_block->eh_entries))
break;
} while (fileblock >= le32_to_cpu(index[i].ei_block));
if (--i < 0)
return NULL;
block = le16_to_cpu(index[i].ei_leaf_hi);
block = (block << 32) + le32_to_cpu(index[i].ei_leaf_lo);
if (ext4fs_devread((lbaint_t)block << log2_blksz, 0, blksz,
buf))
ext_block = (struct ext4_extent_header *)buf;
else
return NULL;
}
}
static int ext4fs_blockgroup
(struct ext2_data *data, int group, struct ext2_block_group *blkgrp)
{
long int blkno;
unsigned int blkoff, desc_per_blk;
int log2blksz = get_fs()->dev_desc->log2blksz;
desc_per_blk = EXT2_BLOCK_SIZE(data) / sizeof(struct ext2_block_group);
blkno = le32_to_cpu(data->sblock.first_data_block) + 1 +
group / desc_per_blk;
blkoff = (group % desc_per_blk) * sizeof(struct ext2_block_group);
debug("ext4fs read %d group descriptor (blkno %ld blkoff %u)\n",
group, blkno, blkoff);
return ext4fs_devread((lbaint_t)blkno <<
(LOG2_BLOCK_SIZE(data) - log2blksz),
blkoff, sizeof(struct ext2_block_group),
(char *)blkgrp);
}
int ext4fs_read_inode(struct ext2_data *data, int ino, struct ext2_inode *inode)
{
struct ext2_block_group blkgrp;
struct ext2_sblock *sblock = &data->sblock;
struct ext_filesystem *fs = get_fs();
int log2blksz = get_fs()->dev_desc->log2blksz;
int inodes_per_block, status;
long int blkno;
unsigned int blkoff;
/* It is easier to calculate if the first inode is 0. */
ino--;
status = ext4fs_blockgroup(data, ino / le32_to_cpu
(sblock->inodes_per_group), &blkgrp);
if (status == 0)
return 0;
inodes_per_block = EXT2_BLOCK_SIZE(data) / fs->inodesz;
blkno = le32_to_cpu(blkgrp.inode_table_id) +
(ino % le32_to_cpu(sblock->inodes_per_group)) / inodes_per_block;
blkoff = (ino % inodes_per_block) * fs->inodesz;
/* Read the inode. */
status = ext4fs_devread((lbaint_t)blkno << (LOG2_BLOCK_SIZE(data) -
log2blksz), blkoff,
sizeof(struct ext2_inode), (char *)inode);
if (status == 0)
return 0;
return 1;
}
long int read_allocated_block(struct ext2_inode *inode, int fileblock)
{
long int blknr;
int blksz;
int log2_blksz;
int status;
long int rblock;
long int perblock_parent;
long int perblock_child;
unsigned long long start;
/* get the blocksize of the filesystem */
blksz = EXT2_BLOCK_SIZE(ext4fs_root);
log2_blksz = LOG2_BLOCK_SIZE(ext4fs_root)
- get_fs()->dev_desc->log2blksz;
if (le32_to_cpu(inode->flags) & EXT4_EXTENTS_FL) {
char *buf = zalloc(blksz);
if (!buf)
return -ENOMEM;
struct ext4_extent_header *ext_block;
struct ext4_extent *extent;
int i = -1;
ext_block =
ext4fs_get_extent_block(ext4fs_root, buf,
(struct ext4_extent_header *)
inode->b.blocks.dir_blocks,
fileblock, log2_blksz);
if (!ext_block) {
printf("invalid extent block\n");
free(buf);
return -EINVAL;
}
extent = (struct ext4_extent *)(ext_block + 1);
do {
i++;
if (i >= le16_to_cpu(ext_block->eh_entries))
break;
} while (fileblock >= le32_to_cpu(extent[i].ee_block));
if (--i >= 0) {
fileblock -= le32_to_cpu(extent[i].ee_block);
if (fileblock >= le16_to_cpu(extent[i].ee_len)) {
free(buf);
return 0;
}
start = le16_to_cpu(extent[i].ee_start_hi);
start = (start << 32) +
le32_to_cpu(extent[i].ee_start_lo);
free(buf);
return fileblock + start;
}
printf("Extent Error\n");
free(buf);
return -1;
}
/* Direct blocks. */
if (fileblock < INDIRECT_BLOCKS)
blknr = le32_to_cpu(inode->b.blocks.dir_blocks[fileblock]);
/* Indirect. */
else if (fileblock < (INDIRECT_BLOCKS + (blksz / 4))) {
if (ext4fs_indir1_block == NULL) {
ext4fs_indir1_block = zalloc(blksz);
if (ext4fs_indir1_block == NULL) {
printf("** SI ext2fs read block (indir 1)"
"malloc failed. **\n");
return -1;
}
ext4fs_indir1_size = blksz;
ext4fs_indir1_blkno = -1;
}
if (blksz != ext4fs_indir1_size) {
free(ext4fs_indir1_block);
ext4fs_indir1_block = NULL;
ext4fs_indir1_size = 0;
ext4fs_indir1_blkno = -1;
ext4fs_indir1_block = zalloc(blksz);
if (ext4fs_indir1_block == NULL) {
printf("** SI ext2fs read block (indir 1):"
"malloc failed. **\n");
return -1;
}
ext4fs_indir1_size = blksz;
}
if ((le32_to_cpu(inode->b.blocks.indir_block) <<
log2_blksz) != ext4fs_indir1_blkno) {
status =
ext4fs_devread((lbaint_t)le32_to_cpu
(inode->b.blocks.
indir_block) << log2_blksz, 0,
blksz, (char *)ext4fs_indir1_block);
if (status == 0) {
printf("** SI ext2fs read block (indir 1)"
"failed. **\n");
return -1;
}
ext4fs_indir1_blkno =
le32_to_cpu(inode->b.blocks.
indir_block) << log2_blksz;
}
blknr = le32_to_cpu(ext4fs_indir1_block
[fileblock - INDIRECT_BLOCKS]);
}
/* Double indirect. */
else if (fileblock < (INDIRECT_BLOCKS + (blksz / 4 *
(blksz / 4 + 1)))) {
long int perblock = blksz / 4;
long int rblock = fileblock - (INDIRECT_BLOCKS + blksz / 4);
if (ext4fs_indir1_block == NULL) {
ext4fs_indir1_block = zalloc(blksz);
if (ext4fs_indir1_block == NULL) {
printf("** DI ext2fs read block (indir 2 1)"
"malloc failed. **\n");
return -1;
}
ext4fs_indir1_size = blksz;
ext4fs_indir1_blkno = -1;
}
if (blksz != ext4fs_indir1_size) {
free(ext4fs_indir1_block);
ext4fs_indir1_block = NULL;
ext4fs_indir1_size = 0;
ext4fs_indir1_blkno = -1;
ext4fs_indir1_block = zalloc(blksz);
if (ext4fs_indir1_block == NULL) {
printf("** DI ext2fs read block (indir 2 1)"
"malloc failed. **\n");
return -1;
}
ext4fs_indir1_size = blksz;
}
if ((le32_to_cpu(inode->b.blocks.double_indir_block) <<
log2_blksz) != ext4fs_indir1_blkno) {
status =
ext4fs_devread((lbaint_t)le32_to_cpu
(inode->b.blocks.
double_indir_block) << log2_blksz,
0, blksz,
(char *)ext4fs_indir1_block);
if (status == 0) {
printf("** DI ext2fs read block (indir 2 1)"
"failed. **\n");
return -1;
}
ext4fs_indir1_blkno =
le32_to_cpu(inode->b.blocks.double_indir_block) <<
log2_blksz;
}
if (ext4fs_indir2_block == NULL) {
ext4fs_indir2_block = zalloc(blksz);
if (ext4fs_indir2_block == NULL) {
printf("** DI ext2fs read block (indir 2 2)"
"malloc failed. **\n");
return -1;
}
ext4fs_indir2_size = blksz;
ext4fs_indir2_blkno = -1;
}
if (blksz != ext4fs_indir2_size) {
free(ext4fs_indir2_block);
ext4fs_indir2_block = NULL;
ext4fs_indir2_size = 0;
ext4fs_indir2_blkno = -1;
ext4fs_indir2_block = zalloc(blksz);
if (ext4fs_indir2_block == NULL) {
printf("** DI ext2fs read block (indir 2 2)"
"malloc failed. **\n");
return -1;
}
ext4fs_indir2_size = blksz;
}
if ((le32_to_cpu(ext4fs_indir1_block[rblock / perblock]) <<
log2_blksz) != ext4fs_indir2_blkno) {
status = ext4fs_devread((lbaint_t)le32_to_cpu
(ext4fs_indir1_block
[rblock /
perblock]) << log2_blksz, 0,
blksz,
(char *)ext4fs_indir2_block);
if (status == 0) {
printf("** DI ext2fs read block (indir 2 2)"
"failed. **\n");
return -1;
}
ext4fs_indir2_blkno =
le32_to_cpu(ext4fs_indir1_block[rblock
/
perblock]) <<
log2_blksz;
}
blknr = le32_to_cpu(ext4fs_indir2_block[rblock % perblock]);
}
/* Tripple indirect. */
else {
rblock = fileblock - (INDIRECT_BLOCKS + blksz / 4 +
(blksz / 4 * blksz / 4));
perblock_child = blksz / 4;
perblock_parent = ((blksz / 4) * (blksz / 4));
if (ext4fs_indir1_block == NULL) {
ext4fs_indir1_block = zalloc(blksz);
if (ext4fs_indir1_block == NULL) {
printf("** TI ext2fs read block (indir 2 1)"
"malloc failed. **\n");
return -1;
}
ext4fs_indir1_size = blksz;
ext4fs_indir1_blkno = -1;
}
if (blksz != ext4fs_indir1_size) {
free(ext4fs_indir1_block);
ext4fs_indir1_block = NULL;
ext4fs_indir1_size = 0;
ext4fs_indir1_blkno = -1;
ext4fs_indir1_block = zalloc(blksz);
if (ext4fs_indir1_block == NULL) {
printf("** TI ext2fs read block (indir 2 1)"
"malloc failed. **\n");
return -1;
}
ext4fs_indir1_size = blksz;
}
if ((le32_to_cpu(inode->b.blocks.triple_indir_block) <<
log2_blksz) != ext4fs_indir1_blkno) {
status = ext4fs_devread
((lbaint_t)
le32_to_cpu(inode->b.blocks.triple_indir_block)
<< log2_blksz, 0, blksz,
(char *)ext4fs_indir1_block);
if (status == 0) {
printf("** TI ext2fs read block (indir 2 1)"
"failed. **\n");
return -1;
}
ext4fs_indir1_blkno =
le32_to_cpu(inode->b.blocks.triple_indir_block) <<
log2_blksz;
}
if (ext4fs_indir2_block == NULL) {
ext4fs_indir2_block = zalloc(blksz);
if (ext4fs_indir2_block == NULL) {
printf("** TI ext2fs read block (indir 2 2)"
"malloc failed. **\n");
return -1;
}
ext4fs_indir2_size = blksz;
ext4fs_indir2_blkno = -1;
}
if (blksz != ext4fs_indir2_size) {
free(ext4fs_indir2_block);
ext4fs_indir2_block = NULL;
ext4fs_indir2_size = 0;
ext4fs_indir2_blkno = -1;
ext4fs_indir2_block = zalloc(blksz);
if (ext4fs_indir2_block == NULL) {
printf("** TI ext2fs read block (indir 2 2)"
"malloc failed. **\n");
return -1;
}
ext4fs_indir2_size = blksz;
}
if ((le32_to_cpu(ext4fs_indir1_block[rblock /
perblock_parent]) <<
log2_blksz)
!= ext4fs_indir2_blkno) {
status = ext4fs_devread((lbaint_t)le32_to_cpu
(ext4fs_indir1_block
[rblock /
perblock_parent]) <<
log2_blksz, 0, blksz,
(char *)ext4fs_indir2_block);
if (status == 0) {
printf("** TI ext2fs read block (indir 2 2)"
"failed. **\n");
return -1;
}
ext4fs_indir2_blkno =
le32_to_cpu(ext4fs_indir1_block[rblock /
perblock_parent])
<< log2_blksz;
}
if (ext4fs_indir3_block == NULL) {
ext4fs_indir3_block = zalloc(blksz);
if (ext4fs_indir3_block == NULL) {
printf("** TI ext2fs read block (indir 2 2)"
"malloc failed. **\n");
return -1;
}
ext4fs_indir3_size = blksz;
ext4fs_indir3_blkno = -1;
}
if (blksz != ext4fs_indir3_size) {
free(ext4fs_indir3_block);
ext4fs_indir3_block = NULL;
ext4fs_indir3_size = 0;
ext4fs_indir3_blkno = -1;
ext4fs_indir3_block = zalloc(blksz);
if (ext4fs_indir3_block == NULL) {
printf("** TI ext2fs read block (indir 2 2)"
"malloc failed. **\n");
return -1;
}
ext4fs_indir3_size = blksz;
}
if ((le32_to_cpu(ext4fs_indir2_block[rblock
/
perblock_child]) <<
log2_blksz) != ext4fs_indir3_blkno) {
status =
ext4fs_devread((lbaint_t)le32_to_cpu
(ext4fs_indir2_block
[(rblock / perblock_child)
% (blksz / 4)]) << log2_blksz, 0,
blksz, (char *)ext4fs_indir3_block);
if (status == 0) {
printf("** TI ext2fs read block (indir 2 2)"
"failed. **\n");
return -1;
}
ext4fs_indir3_blkno =
le32_to_cpu(ext4fs_indir2_block[(rblock /
perblock_child) %
(blksz /
4)]) <<
log2_blksz;
}
blknr = le32_to_cpu(ext4fs_indir3_block
[rblock % perblock_child]);
}
debug("read_allocated_block %ld\n", blknr);
return blknr;
}
/**
* ext4fs_reinit_global() - Reinitialize values of ext4 write implementation's
* global pointers
*
* This function assures that for a file with the same name but different size
* the sequential store on the ext4 filesystem will be correct.
*
* In this function the global data, responsible for internal representation
* of the ext4 data are initialized to the reset state. Without this, during
* replacement of the smaller file with the bigger truncation of new file was
* performed.
*/
void ext4fs_reinit_global(void)
{
if (ext4fs_indir1_block != NULL) {
free(ext4fs_indir1_block);
ext4fs_indir1_block = NULL;
ext4fs_indir1_size = 0;
ext4fs_indir1_blkno = -1;
}
if (ext4fs_indir2_block != NULL) {
free(ext4fs_indir2_block);
ext4fs_indir2_block = NULL;
ext4fs_indir2_size = 0;
ext4fs_indir2_blkno = -1;
}
if (ext4fs_indir3_block != NULL) {
free(ext4fs_indir3_block);
ext4fs_indir3_block = NULL;
ext4fs_indir3_size = 0;
ext4fs_indir3_blkno = -1;
}
}
void ext4fs_close(void)
{
if ((ext4fs_file != NULL) && (ext4fs_root != NULL)) {
ext4fs_free_node(ext4fs_file, &ext4fs_root->diropen);
ext4fs_file = NULL;
}
if (ext4fs_root != NULL) {
free(ext4fs_root);
ext4fs_root = NULL;
}
ext4fs_reinit_global();
}
int ext4fs_iterate_dir(struct ext2fs_node *dir, char *name,
struct ext2fs_node **fnode, int *ftype)
{
unsigned int fpos = 0;
int status;
loff_t actread;
struct ext2fs_node *diro = (struct ext2fs_node *) dir;
#ifdef DEBUG
if (name != NULL)
printf("Iterate dir %s\n", name);
#endif /* of DEBUG */
if (!diro->inode_read) {
status = ext4fs_read_inode(diro->data, diro->ino, &diro->inode);
if (status == 0)
return 0;
}
/* Search the file. */
while (fpos < le32_to_cpu(diro->inode.size)) {
struct ext2_dirent dirent;
status = ext4fs_read_file(diro, fpos,
sizeof(struct ext2_dirent),
(char *)&dirent, &actread);
if (status < 0)
return 0;
if (dirent.direntlen == 0) {
printf("Failed to iterate over directory %s\n", name);
return 0;
}
if (dirent.namelen != 0) {
char filename[dirent.namelen + 1];
struct ext2fs_node *fdiro;
int type = FILETYPE_UNKNOWN;
status = ext4fs_read_file(diro,
fpos +
sizeof(struct ext2_dirent),
dirent.namelen, filename,
&actread);
if (status < 0)
return 0;
fdiro = zalloc(sizeof(struct ext2fs_node));
if (!fdiro)
return 0;
fdiro->data = diro->data;
fdiro->ino = le32_to_cpu(dirent.inode);
filename[dirent.namelen] = '\0';
if (dirent.filetype != FILETYPE_UNKNOWN) {
fdiro->inode_read = 0;
if (dirent.filetype == FILETYPE_DIRECTORY)
type = FILETYPE_DIRECTORY;
else if (dirent.filetype == FILETYPE_SYMLINK)
type = FILETYPE_SYMLINK;
else if (dirent.filetype == FILETYPE_REG)
type = FILETYPE_REG;
} else {
status = ext4fs_read_inode(diro->data,
le32_to_cpu
(dirent.inode),
&fdiro->inode);
if (status == 0) {
free(fdiro);
return 0;
}
fdiro->inode_read = 1;
if ((le16_to_cpu(fdiro->inode.mode) &
FILETYPE_INO_MASK) ==
FILETYPE_INO_DIRECTORY) {
type = FILETYPE_DIRECTORY;
} else if ((le16_to_cpu(fdiro->inode.mode)
& FILETYPE_INO_MASK) ==
FILETYPE_INO_SYMLINK) {
type = FILETYPE_SYMLINK;
} else if ((le16_to_cpu(fdiro->inode.mode)
& FILETYPE_INO_MASK) ==
FILETYPE_INO_REG) {
type = FILETYPE_REG;
}
}
#ifdef DEBUG
printf("iterate >%s<\n", filename);
#endif /* of DEBUG */
if ((name != NULL) && (fnode != NULL)
&& (ftype != NULL)) {
if (strcmp(filename, name) == 0) {
*ftype = type;
*fnode = fdiro;
return 1;
}
} else {
if (fdiro->inode_read == 0) {
status = ext4fs_read_inode(diro->data,
le32_to_cpu(
dirent.inode),
&fdiro->inode);
if (status == 0) {
free(fdiro);
return 0;
}
fdiro->inode_read = 1;
}
switch (type) {
case FILETYPE_DIRECTORY:
printf("<DIR> ");
break;
case FILETYPE_SYMLINK:
printf("<SYM> ");
break;
case FILETYPE_REG:
printf(" ");
break;
default:
printf("< ? > ");
break;
}
printf("%10u %s\n",
le32_to_cpu(fdiro->inode.size),
filename);
}
free(fdiro);
}
fpos += le16_to_cpu(dirent.direntlen);
}
return 0;
}
static char *ext4fs_read_symlink(struct ext2fs_node *node)
{
char *symlink;
struct ext2fs_node *diro = node;
int status;
loff_t actread;
if (!diro->inode_read) {
status = ext4fs_read_inode(diro->data, diro->ino, &diro->inode);
if (status == 0)
return NULL;
}
symlink = zalloc(le32_to_cpu(diro->inode.size) + 1);
if (!symlink)
return NULL;
if (le32_to_cpu(diro->inode.size) < sizeof(diro->inode.b.symlink)) {
strncpy(symlink, diro->inode.b.symlink,
le32_to_cpu(diro->inode.size));
} else {
status = ext4fs_read_file(diro, 0,
le32_to_cpu(diro->inode.size),
symlink, &actread);
if ((status < 0) || (actread == 0)) {
free(symlink);
return NULL;
}
}
symlink[le32_to_cpu(diro->inode.size)] = '\0';
return symlink;
}
static int ext4fs_find_file1(const char *currpath,
struct ext2fs_node *currroot,
struct ext2fs_node **currfound, int *foundtype)
{
char fpath[strlen(currpath) + 1];
char *name = fpath;
char *next;
int status;
int type = FILETYPE_DIRECTORY;
struct ext2fs_node *currnode = currroot;
struct ext2fs_node *oldnode = currroot;
strncpy(fpath, currpath, strlen(currpath) + 1);
/* Remove all leading slashes. */
while (*name == '/')
name++;
if (!*name) {
*currfound = currnode;
return 1;
}
for (;;) {
int found;
/* Extract the actual part from the pathname. */
next = strchr(name, '/');
if (next) {
/* Remove all leading slashes. */
while (*next == '/')
*(next++) = '\0';
}
if (type != FILETYPE_DIRECTORY) {
ext4fs_free_node(currnode, currroot);
return 0;
}
oldnode = currnode;
/* Iterate over the directory. */
found = ext4fs_iterate_dir(currnode, name, &currnode, &type);
if (found == 0)
return 0;
if (found == -1)
break;
/* Read in the symlink and follow it. */
if (type == FILETYPE_SYMLINK) {
char *symlink;
/* Test if the symlink does not loop. */
if (++symlinknest == 8) {
ext4fs_free_node(currnode, currroot);
ext4fs_free_node(oldnode, currroot);
return 0;
}
symlink = ext4fs_read_symlink(currnode);
ext4fs_free_node(currnode, currroot);
if (!symlink) {
ext4fs_free_node(oldnode, currroot);
return 0;
}
debug("Got symlink >%s<\n", symlink);
if (symlink[0] == '/') {
ext4fs_free_node(oldnode, currroot);
oldnode = &ext4fs_root->diropen;
}
/* Lookup the node the symlink points to. */
status = ext4fs_find_file1(symlink, oldnode,
&currnode, &type);
free(symlink);
if (status == 0) {
ext4fs_free_node(oldnode, currroot);
return 0;
}
}
ext4fs_free_node(oldnode, currroot);
/* Found the node! */
if (!next || *next == '\0') {
*currfound = currnode;
*foundtype = type;
return 1;
}
name = next;
}
return -1;
}
int ext4fs_find_file(const char *path, struct ext2fs_node *rootnode,
struct ext2fs_node **foundnode, int expecttype)
{
int status;
int foundtype = FILETYPE_DIRECTORY;
symlinknest = 0;
if (!path)
return 0;
status = ext4fs_find_file1(path, rootnode, foundnode, &foundtype);
if (status == 0)
return 0;
/* Check if the node that was found was of the expected type. */
if ((expecttype == FILETYPE_REG) && (foundtype != expecttype))
return 0;
else if ((expecttype == FILETYPE_DIRECTORY)
&& (foundtype != expecttype))
return 0;
return 1;
}
int ext4fs_open(const char *filename, loff_t *len)
{
struct ext2fs_node *fdiro = NULL;
int status;
if (ext4fs_root == NULL)
return -1;
ext4fs_file = NULL;
status = ext4fs_find_file(filename, &ext4fs_root->diropen, &fdiro,
FILETYPE_REG);
if (status == 0)
goto fail;
if (!fdiro->inode_read) {
status = ext4fs_read_inode(fdiro->data, fdiro->ino,
&fdiro->inode);
if (status == 0)
goto fail;
}
*len = le32_to_cpu(fdiro->inode.size);
ext4fs_file = fdiro;
return 0;
fail:
ext4fs_free_node(fdiro, &ext4fs_root->diropen);
return -1;
}
int ext4fs_mount(unsigned part_length)
{
struct ext2_data *data;
int status;
struct ext_filesystem *fs = get_fs();
data = zalloc(SUPERBLOCK_SIZE);
if (!data)
return 0;
/* Read the superblock. */
status = ext4_read_superblock((char *)&data->sblock);
if (status == 0)
goto fail;
/* Make sure this is an ext2 filesystem. */
if (le16_to_cpu(data->sblock.magic) != EXT2_MAGIC)
goto fail;
/*
* The 64bit feature was enabled when metadata_csum was enabled
* and we do not support metadata_csum (and cannot reliably find
* files when it is set. Refuse to mount.
*/
if (le32_to_cpu(data->sblock.feature_incompat) & EXT4_FEATURE_INCOMPAT_64BIT) {
printf("Unsupported feature found (64bit, possibly metadata_csum), not mounting\n");
goto fail;
}
if (le32_to_cpu(data->sblock.revision_level) == 0) {
fs->inodesz = 128;
} else {
debug("EXT4 features COMPAT: %08x INCOMPAT: %08x RO_COMPAT: %08x\n",
__le32_to_cpu(data->sblock.feature_compatibility),
__le32_to_cpu(data->sblock.feature_incompat),
__le32_to_cpu(data->sblock.feature_ro_compat));
fs->inodesz = le16_to_cpu(data->sblock.inode_size);
fs->gdsize = le32_to_cpu(data->sblock.feature_incompat) &
EXT4_FEATURE_INCOMPAT_64BIT ?
le16_to_cpu(data->sblock.descriptor_size) : 32;
}
debug("EXT2 rev %d, inode_size %d, descriptor size %d\n",
le32_to_cpu(data->sblock.revision_level),
fs->inodesz, fs->gdsize);
data->diropen.data = data;
data->diropen.ino = 2;
data->diropen.inode_read = 1;
data->inode = &data->diropen.inode;
status = ext4fs_read_inode(data, 2, data->inode);
if (status == 0)
goto fail;
ext4fs_root = data;
return 1;
fail:
printf("Failed to mount ext2 filesystem...\n");
free(data);
ext4fs_root = NULL;
return 0;
}
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