static int ext2fs_read_inode
(struct ext2_data *data, int ino, struct ext2_inode *inode) {
struct ext2_block_group blkgrp;
struct ext2_sblock *sblock = &data->sblock;
int inodes_per_block;
int status;
unsigned int blkno;
unsigned int blkoff;
/* It is easier to calculate if the first inode is 0. */
ino--;
#ifdef DEBUG
printf ("ext2fs read inode %d\n", ino);
#endif
status = ext2fs_blockgroup (data,
ino /
__le32_to_cpu (sblock->inodes_per_group),
&blkgrp);
if (status == 0) {
return (0);
}
#ifdef CFG_EXT2_SUPPORT_DYNAMIC_REV
inodes_per_block = EXT2_BLOCK_SIZE (data) / ext2_inode_size;
#else
inodes_per_block = EXT2_BLOCK_SIZE (data) / 128;
#endif
blkno = (ino % __le32_to_cpu (sblock->inodes_per_group)) /
inodes_per_block;
blkoff = (ino % __le32_to_cpu (sblock->inodes_per_group)) %
inodes_per_block;
#ifdef DEBUG
printf ("ext2fs read inode blkno %d blkoff %d\n", blkno, blkoff);
#endif
/* Read the inode. */
#ifdef CFG_EXT2_SUPPORT_DYNAMIC_REV
status = ext2fs_devread (((__le32_to_cpu (blkgrp.inode_table_id) +
blkno) << LOG2_EXT2_BLOCK_SIZE (data)),
ext2_inode_size * blkoff,
sizeof (struct ext2_inode), (char *) inode);
#else
status = ext2fs_devread (((__le32_to_cpu (blkgrp.inode_table_id) +
blkno) << LOG2_EXT2_BLOCK_SIZE (data)),
sizeof (struct ext2_inode) * blkoff,
sizeof (struct ext2_inode), (char *) inode);
#endif
if (status == 0) {
return (0);
}
return (1);
}
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 = data->fs;
int inodes_per_block, ret;
long int blkno;
unsigned int blkoff;
/* It is easier to calculate if the first inode is 0. */
ino--;
ret = ext4fs_blockgroup(data, ino / __le32_to_cpu
(sblock->inodes_per_group), &blkgrp);
if (ret)
return ret;
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. */
ret = ext4fs_devread(fs, blkno << LOG2_EXT2_BLOCK_SIZE(data), blkoff,
sizeof(struct ext2_inode), (char *)inode);
if (ret)
return ret;
return 0;
}
/* Read the inode INO for the file described by DATA into INODE. */
static grub_err_t
grub_ext2_read_inode (struct grub_ext2_data *data,
int ino, struct grub_ext2_inode *inode)
{
struct grub_ext2_block_group blkgrp;
struct grub_ext2_sblock *sblock = &data->sblock;
int inodes_per_block;
unsigned int blkno;
unsigned int blkoff;
/* It is easier to calculate if the first inode is 0. */
ino--;
grub_ext2_blockgroup (data,
ino / grub_le_to_cpu32 (sblock->inodes_per_group),
&blkgrp);
if (grub_errno)
return grub_errno;
inodes_per_block = EXT2_BLOCK_SIZE (data) / EXT2_INODE_SIZE (data);
blkno = (ino % grub_le_to_cpu32 (sblock->inodes_per_group))
/ inodes_per_block;
blkoff = (ino % grub_le_to_cpu32 (sblock->inodes_per_group))
% inodes_per_block;
/* Read the inode. */
if (grub_disk_read (data->disk,
((grub_le_to_cpu32 (blkgrp.inode_table_id) + blkno)
<< LOG2_EXT2_BLOCK_SIZE (data)),
EXT2_INODE_SIZE (data) * blkoff,
sizeof (struct grub_ext2_inode), inode))
return grub_errno;
return 0;
}
int ext2fs_read_file
(struct ext2fs_node *node, int pos, unsigned int len, char *buf)
{
int i;
int blockcnt;
int log2blocksize = LOG2_EXT2_BLOCK_SIZE (node->data);
int blocksize = 1 << (log2blocksize + DISK_SECTOR_BITS);
unsigned int filesize = __le32_to_cpu(node->inode.size);
/* Adjust len so it we can't read past the end of the file. */
if (len > filesize) {
len = filesize;
}
blockcnt = ((len + pos) + blocksize - 1) / blocksize;
for (i = pos / blocksize; i < blockcnt; i++) {
int blknr;
int blockoff = pos % blocksize;
int blockend = blocksize;
int skipfirst = 0;
blknr = ext2fs_read_block (node, i);
if (blknr < 0) {
return (-1);
}
blknr = blknr << log2blocksize;
/* Last block. */
if (i == blockcnt - 1) {
blockend = (len + pos) % blocksize;
/* The last portion is exactly blocksize. */
if (!blockend) {
blockend = blocksize;
}
}
/* First block. */
if (i == pos / blocksize) {
skipfirst = blockoff;
blockend -= skipfirst;
}
/* If the block number is 0 this block is not stored on disk but
is zero filled instead. */
if (blknr) {
int status;
status = ext2fs_devread (blknr, skipfirst, blockend, buf);
if (status == 0) {
return (-1);
}
} else {
memset (buf, 0, blocksize - skipfirst);
}
buf += blocksize - skipfirst;
}
return (len);
}
/* Read into BLKGRP the blockgroup descriptor of blockgroup GROUP of
the mounted filesystem DATA. */
inline static grub_err_t
grub_ext2_blockgroup (struct grub_ext2_data *data, int group,
struct grub_ext2_block_group *blkgrp)
{
return grub_disk_read (data->disk,
((grub_le_to_cpu32 (data->sblock.first_data_block) + 1)
<< LOG2_EXT2_BLOCK_SIZE (data)),
group * sizeof (struct grub_ext2_block_group),
sizeof (struct grub_ext2_block_group), blkgrp);
}
static int ext2fs_blockgroup
(struct ext2_data *data, int group, struct ext2_block_group *blkgrp) {
#ifdef DEBUG
printf ("ext2fs read blockgroup\n");
#endif
return (ext2fs_devread
(((__le32_to_cpu (data->sblock.first_data_block) +
1) << LOG2_EXT2_BLOCK_SIZE (data)),
group * sizeof (struct ext2_block_group),
sizeof (struct ext2_block_group), (char *) blkgrp));
}
/* Read LEN bytes from the file described by DATA starting with byte
POS. Return the amount of read bytes in READ. */
static grub_ssize_t
grub_ext2_read_file (grub_fshelp_node_t node,
void NESTED_FUNC_ATTR (*read_hook) (grub_disk_addr_t sector,
unsigned offset, unsigned length),
int pos, grub_size_t len, char *buf)
{
return grub_fshelp_read_file (node->data->disk, node, read_hook,
pos, len, buf, grub_ext2_read_block,
node->inode.size,
LOG2_EXT2_BLOCK_SIZE (node->data));
}
/* Read LEN bytes from the file described by DATA starting with byte
POS. Return the amount of read bytes in READ. */
static grub_ssize_t
grub_ext2_read_file (grub_fshelp_node_t node,
void (*read_hook) (grub_disk_addr_t sector,
unsigned offset, unsigned length,
void *closure),
void *closure, int flags,
int pos, grub_size_t len, char *buf)
{
return grub_fshelp_read_file (node->data->disk, node, read_hook, closure,
flags, pos, len, buf, grub_ext2_read_block,
node->inode.size,
LOG2_EXT2_BLOCK_SIZE (node->data));
}
static quik_err_t
ext2fs_read_inode(struct ext2_data *data,
int ino,
struct ext2_inode *inode)
{
struct ext2_block_group blkgrp;
struct ext2_sblock *sblock = &data->sblock;
int inodes_per_block;
quik_err_t err;
unsigned int blkno;
unsigned int blkoff;
#ifdef DEBUG
printk ("ext2fs read inode %d, inode_size %d\n", ino, inode_size);
#endif
/* It is easier to calculate if the first inode is 0. */
ino--;
err = ext2fs_blockgroup(data, ino / __le32_to_cpu
(sblock->inodes_per_group), &blkgrp);
if (err != ERR_NONE) {
return err;
}
inodes_per_block = EXT2_BLOCK_SIZE(data) / inode_size;
blkno = __le32_to_cpu(blkgrp.inode_table_id) +
(ino % __le32_to_cpu(sblock->inodes_per_group))
/ inodes_per_block;
blkoff = (ino % inodes_per_block) * inode_size;
#ifdef DEBUG
printk ("ext2fs read inode blkno %d blkoff %d\n", blkno, blkoff);
#endif
/* Read the inode. */
err = part_read(data->part,
blkno << LOG2_EXT2_BLOCK_SIZE (data), blkoff,
sizeof(struct ext2_inode), (char *) inode);
if (err != ERR_NONE) {
return err;
}
return ERR_NONE;
}
static int ext2fs_blockgroup
(struct ext2_data *data, int group, struct ext2_block_group *blkgrp) {
unsigned int blkno;
unsigned int blkoff;
unsigned int desc_per_blk;
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);
#ifdef DEBUG
printf ("ext2fs read %d group descriptor (blkno %d blkoff %d)\n",
group, blkno, blkoff);
#endif
return (ext2fs_devread (blkno << LOG2_EXT2_BLOCK_SIZE(data),
blkoff, sizeof(struct ext2_block_group), (char *)blkgrp));
}
static int ext4fs_blockgroup
(struct ext2_data *data, int group, struct ext2_block_group *blkgrp)
{
long int blkno;
unsigned int blkoff, desc_per_blk;
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(blkno << LOG2_EXT2_BLOCK_SIZE(data),
blkoff, sizeof(struct ext2_block_group),
(char *)blkgrp);
}
static struct grub_ext4_extent_header *
grub_ext4_find_leaf (struct grub_ext2_data *data, char *buf,
struct grub_ext4_extent_header *ext_block,
grub_uint32_t fileblock)
{
struct grub_ext4_extent_idx *index;
while (1)
{
int i;
grub_disk_addr_t block;
index = (struct grub_ext4_extent_idx *) (ext_block + 1);
if (grub_le_to_cpu16(ext_block->magic) != EXT4_EXT_MAGIC)
return 0;
if (ext_block->depth == 0)
return ext_block;
for (i = 0; i < grub_le_to_cpu16 (ext_block->entries); i++)
{
if (fileblock < grub_le_to_cpu32(index[i].block))
break;
}
if (--i < 0)
return 0;
block = grub_le_to_cpu16 (index[i].leaf_hi);
block = (block << 32) + grub_le_to_cpu32 (index[i].leaf);
if (grub_disk_read (data->disk,
block << LOG2_EXT2_BLOCK_SIZE (data),
0, EXT2_BLOCK_SIZE(data), buf))
return 0;
ext_block = (struct grub_ext4_extent_header *) buf;
}
}
static int ext2fs_read_inode
(struct ext2_data *data, int ino, struct ext2_inode *inode) {
struct ext2_block_group blkgrp;
struct ext2_sblock *sblock = &data->sblock;
int inodes_per_block;
int status;
unsigned int blkno;
unsigned int blkoff;
#ifdef DEBUG
printf ("ext2fs read inode %d, inode_size %d\n", ino, inode_size);
#endif
/* It is easier to calculate if the first inode is 0. */
ino--;
status = ext2fs_blockgroup (data, ino / __le32_to_cpu
(sblock->inodes_per_group), &blkgrp);
if (status == 0) {
return (0);
}
inodes_per_block = EXT2_BLOCK_SIZE(data) / inode_size;
blkno = __le32_to_cpu (blkgrp.inode_table_id) +
(ino % __le32_to_cpu (sblock->inodes_per_group))
/ inodes_per_block;
blkoff = (ino % inodes_per_block) * inode_size;
#ifdef DEBUG
printf ("ext2fs read inode blkno %d blkoff %d\n", blkno, blkoff);
#endif
/* Read the inode. */
status = ext2fs_devread (blkno << LOG2_EXT2_BLOCK_SIZE (data), blkoff,
sizeof (struct ext2_inode), (char *) inode);
if (status == 0) {
return (0);
}
return (1);
}
static int ext2fs_read_block(struct ext2fs_node *node, int fileblock)
{
struct ext2_data *data = node->data;
struct ext2_inode *inode = &node->inode;
int blknr;
int blksz = EXT2_BLOCK_SIZE (data);
int log2_blksz = LOG2_EXT2_BLOCK_SIZE (data);
int status;
/* 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 (indir1_block == NULL) {
indir1_block = (uint32_t *) malloc (blksz);
if (indir1_block == NULL) {
printf ("** ext2fs read block (indir 1) malloc failed. **\n");
return (-1);
}
indir1_size = blksz;
indir1_blkno = -1;
}
if (blksz != indir1_size) {
free (indir1_block);
indir1_block = NULL;
indir1_size = 0;
indir1_blkno = -1;
indir1_block = (uint32_t *) malloc (blksz);
if (indir1_block == NULL) {
printf ("** ext2fs read block (indir 1) malloc failed. **\n");
return (-1);
}
indir1_size = blksz;
}
if ((__le32_to_cpu (inode->b.blocks.indir_block) <<
log2_blksz) != indir1_blkno) {
status = ext2fs_devread (__le32_to_cpu(inode->b.blocks.indir_block) << log2_blksz,
0, blksz,
(char *) indir1_block);
if (status == 0) {
printf ("** ext2fs read block (indir 1) failed. **\n");
return (0);
}
indir1_blkno =
__le32_to_cpu (inode->b.blocks.
indir_block) << log2_blksz;
}
blknr = __le32_to_cpu (indir1_block
[fileblock - INDIRECT_BLOCKS]);
}
/* Double indirect. */
else if (fileblock <
(INDIRECT_BLOCKS + (blksz / 4 * (blksz / 4 + 1)))) {
unsigned int perblock = blksz / 4;
unsigned int rblock = fileblock - (INDIRECT_BLOCKS
+ blksz / 4);
if (indir1_block == NULL) {
indir1_block = (uint32_t *) malloc (blksz);
if (indir1_block == NULL) {
printf ("** ext2fs read block (indir 2 1) malloc failed. **\n");
return (-1);
}
indir1_size = blksz;
indir1_blkno = -1;
}
if (blksz != indir1_size) {
free (indir1_block);
indir1_block = NULL;
indir1_size = 0;
indir1_blkno = -1;
indir1_block = (uint32_t *) malloc (blksz);
if (indir1_block == NULL) {
printf ("** ext2fs read block (indir 2 1) malloc failed. **\n");
return (-1);
}
indir1_size = blksz;
}
if ((__le32_to_cpu (inode->b.blocks.double_indir_block) <<
log2_blksz) != indir1_blkno) {
status = ext2fs_devread (__le32_to_cpu(inode->b.blocks.double_indir_block) << log2_blksz,
0, blksz,
(char *) indir1_block);
if (status == 0) {
printf ("** ext2fs read block (indir 2 1) failed. **\n");
return (-1);
}
indir1_blkno =
__le32_to_cpu (inode->b.blocks.double_indir_block) << log2_blksz;
}
if (indir2_block == NULL) {
indir2_block = (uint32_t *) malloc (blksz);
if (indir2_block == NULL) {
printf ("** ext2fs read block (indir 2 2) malloc failed. **\n");
return (-1);
}
indir2_size = blksz;
indir2_blkno = -1;
}
if (blksz != indir2_size) {
free (indir2_block);
indir2_block = NULL;
indir2_size = 0;
indir2_blkno = -1;
indir2_block = (uint32_t *) malloc (blksz);
if (indir2_block == NULL) {
printf ("** ext2fs read block (indir 2 2) malloc failed. **\n");
return (-1);
}
indir2_size = blksz;
}
if ((__le32_to_cpu (indir1_block[rblock / perblock]) <<
log2_blksz) != indir2_blkno) {
status = ext2fs_devread (__le32_to_cpu(indir1_block[rblock / perblock]) << log2_blksz,
0, blksz,
(char *) indir2_block);
if (status == 0) {
printf ("** ext2fs read block (indir 2 2) failed. **\n");
return (-1);
}
indir2_blkno =
__le32_to_cpu (indir1_block[rblock / perblock]) << log2_blksz;
}
blknr = __le32_to_cpu (indir2_block[rblock % perblock]);
}
/* Tripple indirect. */
else {
printf ("** ext2fs doesn't support tripple indirect blocks. **\n");
return (-1);
}
#ifdef DEBUG
printf ("ext2fs_read_block %08x\n", blknr);
#endif
return (blknr);
}
quik_err_t
ext2fs_read_file(ext2fs_node_t node,
unsigned pos,
length_t len,
char *buf)
{
unsigned i;
unsigned blockcnt;
quik_err_t err;
int log2blocksize = LOG2_EXT2_BLOCK_SIZE(node->data);
int blocksize = 1 << (log2blocksize + DISK_SECTOR_BITS);
unsigned int filesize = __le32_to_cpu(node->inode.size);
/* Adjust len so it we can't read past the end of the file. */
if (len > filesize) {
len = filesize;
}
blockcnt = ((len + pos) + blocksize - 1) / blocksize;
for (i = pos / blocksize; i < blockcnt; i++) {
unsigned blknr;
unsigned blockoff = pos % blocksize;
length_t blockend = blocksize;
spinner(5);
int skipfirst = 0;
err = ext2fs_read_block(node, i, &blknr);
if (err != ERR_NONE) {
return err;
}
blknr = blknr << log2blocksize;
/* Last block. */
if (i == blockcnt - 1) {
blockend = (len + pos) % blocksize;
/* The last portion is exactly blocksize. */
if (!blockend) {
blockend = blocksize;
}
}
/* First block. */
if (i == pos / blocksize) {
skipfirst = blockoff;
blockend -= skipfirst;
}
/* If the block number is 0 this block is not stored on disk but
is zero filled instead. */
if (blknr) {
err = part_read(node->data->part, blknr,
skipfirst, blockend, buf);
if (err != ERR_NONE) {
return err;
}
} else {
memset(buf, 0, blocksize - skipfirst);
}
buf += blocksize - skipfirst;
}
return ERR_NONE;
}
static grub_disk_addr_t
grub_ext2_read_block (grub_fshelp_node_t node, grub_disk_addr_t fileblock)
{
struct grub_ext2_data *data = node->data;
struct grub_ext2_inode *inode = &node->inode;
int blknr = -1;
unsigned int blksz = EXT2_BLOCK_SIZE (data);
int log2_blksz = LOG2_EXT2_BLOCK_SIZE (data);
if (grub_le_to_cpu32(inode->flags) & EXT4_EXTENTS_FLAG)
{
char buf[EXT2_BLOCK_SIZE(data)];
struct grub_ext4_extent_header *leaf;
struct grub_ext4_extent *ext;
int i;
leaf = grub_ext4_find_leaf (data, buf,
(struct grub_ext4_extent_header *) inode->blocks.dir_blocks,
fileblock);
if (! leaf)
{
grub_error (GRUB_ERR_BAD_FS, "invalid extent");
return -1;
}
ext = (struct grub_ext4_extent *) (leaf + 1);
for (i = 0; i < grub_le_to_cpu16 (leaf->entries); i++)
{
if (fileblock < grub_le_to_cpu32 (ext[i].block))
break;
}
if (--i >= 0)
{
fileblock -= grub_le_to_cpu32 (ext[i].block);
if (fileblock >= grub_le_to_cpu16 (ext[i].len))
return 0;
else
{
grub_disk_addr_t start;
start = grub_le_to_cpu16 (ext[i].start_hi);
start = (start << 32) + grub_le_to_cpu32 (ext[i].start);
return fileblock + start;
}
}
else
{
grub_error (GRUB_ERR_BAD_FS, "something wrong with extent");
return -1;
}
}
/* Direct blocks. */
if (fileblock < INDIRECT_BLOCKS)
blknr = grub_le_to_cpu32 (inode->blocks.dir_blocks[fileblock]);
/* Indirect. */
else if (fileblock < INDIRECT_BLOCKS + blksz / 4)
{
grub_uint32_t indir[blksz / 4];
if (grub_disk_read (data->disk,
((grub_disk_addr_t)
grub_le_to_cpu32 (inode->blocks.indir_block))
<< log2_blksz,
0, blksz, indir))
return grub_errno;
blknr = grub_le_to_cpu32 (indir[fileblock - INDIRECT_BLOCKS]);
}
/* Double indirect. */
else if (fileblock < INDIRECT_BLOCKS + blksz / 4 * (blksz / 4 + 1))
{
unsigned int perblock = blksz / 4;
unsigned int rblock = fileblock - (INDIRECT_BLOCKS
+ blksz / 4);
grub_uint32_t indir[blksz / 4];
if (grub_disk_read (data->disk,
((grub_disk_addr_t)
grub_le_to_cpu32 (inode->blocks.double_indir_block))
<< log2_blksz,
0, blksz, indir))
return grub_errno;
if (grub_disk_read (data->disk,
((grub_disk_addr_t)
grub_le_to_cpu32 (indir[rblock / perblock]))
<< log2_blksz,
0, blksz, indir))
return grub_errno;
blknr = grub_le_to_cpu32 (indir[rblock % perblock]);
}
/* triple indirect. */
else
{
grub_error (GRUB_ERR_NOT_IMPLEMENTED_YET,
"ext2fs doesn't support triple indirect blocks");
}
return blknr;
}
static int ext2fs_read_block (ext2fs_node_t node, int fileblock, int *stream) {
#else
static int ext2fs_read_block (ext2fs_node_t node, int fileblock) {
#endif
struct ext2_data *data = node->data;
struct ext2_inode *inode = &node->inode;
int blknr;
int blksz = EXT2_BLOCK_SIZE (data);
int log2_blksz = LOG2_EXT2_BLOCK_SIZE (data);
int status;
#ifdef CFG_OPTIMIZE_EXT2_READ
*stream = 1;/* itself */
#endif
/* Direct blocks. */
if (fileblock < INDIRECT_BLOCKS) {
blknr = __le32_to_cpu (inode->b.blocks.dir_blocks[fileblock]);
#ifdef CFG_OPTIMIZE_EXT2_READ
while(((inode->b.blocks.dir_blocks[fileblock + 1] -
inode->b.blocks.dir_blocks[fileblock]) == 1) &&
(fileblock < INDIRECT_BLOCKS - 1)) {
fileblock++;
*stream += 1;
}
#endif
}
/* Indirect. */
else if (fileblock < (INDIRECT_BLOCKS + (blksz / 4))) {
if (indir1_block == NULL) {
indir1_block = (uint32_t *) malloc (blksz);
if (indir1_block == NULL) {
printf ("** ext2fs read block (indir 1) malloc failed. **\n");
return (-1);
}
indir1_size = blksz;
indir1_blkno = -1;
}
if (blksz != indir1_size) {
free (indir1_block);
indir1_block = NULL;
indir1_size = 0;
indir1_blkno = -1;
indir1_block = (uint32_t *) malloc (blksz);
if (indir1_block == NULL) {
printf ("** ext2fs read block (indir 1) malloc failed. **\n");
return (-1);
}
indir1_size = blksz;
}
if ((__le32_to_cpu (inode->b.blocks.indir_block) <<
log2_blksz) != indir1_blkno) {
status = ext2fs_devread (__le32_to_cpu(inode->b.blocks.indir_block) << log2_blksz,
0, blksz,
(char *) indir1_block);
if (status == 0) {
printf ("** ext2fs read block (indir 1) failed. **\n");
return (0);
}
indir1_blkno =
__le32_to_cpu (inode->b.blocks.
indir_block) << log2_blksz;
}
blknr = __le32_to_cpu (indir1_block
[fileblock - INDIRECT_BLOCKS]);
#ifdef CFG_OPTIMIZE_EXT2_READ
while(((__le32_to_cpu (indir1_block[fileblock - INDIRECT_BLOCKS + 1]) - \
__le32_to_cpu (indir1_block[fileblock - INDIRECT_BLOCKS])) == 1) && (fileblock < (blksz - 1))) {
fileblock++;
*stream += 1;
}
#endif
}
/* Double indirect. */
else if (fileblock <
(INDIRECT_BLOCKS + (blksz / 4 * (blksz / 4 + 1)))) {
unsigned int perblock = blksz / 4;
unsigned int rblock = fileblock - (INDIRECT_BLOCKS
+ blksz / 4);
#ifdef CFG_OPTIMIZE_EXT2_READ
int rbcnt = 0;
#endif
if (indir1_block == NULL) {
indir1_block = (uint32_t *) malloc (blksz);
if (indir1_block == NULL) {
printf ("** ext2fs read block (indir 2 1) malloc failed. **\n");
return (-1);
}
indir1_size = blksz;
indir1_blkno = -1;
}
if (blksz != indir1_size) {
free (indir1_block);
indir1_block = NULL;
indir1_size = 0;
indir1_blkno = -1;
indir1_block = (uint32_t *) malloc (blksz);
if (indir1_block == NULL) {
printf ("** ext2fs read block (indir 2 1) malloc failed. **\n");
return (-1);
}
indir1_size = blksz;
}
if ((__le32_to_cpu (inode->b.blocks.double_indir_block) <<
log2_blksz) != indir1_blkno) {
status = ext2fs_devread (__le32_to_cpu(inode->b.blocks.double_indir_block) << log2_blksz,
0, blksz,
(char *) indir1_block);
if (status == 0) {
printf ("** ext2fs read block (indir 2 1) failed. **\n");
return (-1);
}
indir1_blkno =
__le32_to_cpu (inode->b.blocks.double_indir_block) << log2_blksz;
}
if (indir2_block == NULL) {
indir2_block = (uint32_t *) malloc (blksz);
if (indir2_block == NULL) {
printf ("** ext2fs read block (indir 2 2) malloc failed. **\n");
return (-1);
}
indir2_size = blksz;
indir2_blkno = -1;
}
if (blksz != indir2_size) {
free (indir2_block);
indir2_block = NULL;
indir2_size = 0;
indir2_blkno = -1;
indir2_block = (uint32_t *) malloc (blksz);
if (indir2_block == NULL) {
printf ("** ext2fs read block (indir 2 2) malloc failed. **\n");
return (-1);
}
indir2_size = blksz;
}
if ((__le32_to_cpu (indir1_block[rblock / perblock]) <<
log2_blksz) != indir1_blkno) {
status = ext2fs_devread (__le32_to_cpu(indir1_block[rblock / perblock]) << log2_blksz,
0, blksz,
(char *) indir2_block);
if (status == 0) {
printf ("** ext2fs read block (indir 2 2) failed. **\n");
return (-1);
}
indir2_blkno =
__le32_to_cpu (indir1_block[rblock / perblock]) << log2_blksz;
}
blknr = __le32_to_cpu (indir2_block[rblock % perblock]);
#ifdef CFG_OPTIMIZE_EXT2_READ
rbcnt = rblock % perblock;
while(((__le32_to_cpu (indir2_block[rbcnt + 1]) - \
__le32_to_cpu (indir2_block[rbcnt])) == 1) && (rbcnt < (blksz - 1))) {
rbcnt++;
*stream += 1;
}
#endif
}
/* Tripple indirect. */
else {
printf ("** ext2fs doesn't support tripple indirect blocks. **\n");
return (-1);
}
#ifdef DEBUG
printf ("ext2fs_read_block %08x\n", blknr);
#endif
return (blknr);
}
#ifdef CFG_OPTIMIZE_EXT2_READ
int ext2fs_read_file
(ext2fs_node_t node, int pos, unsigned int len, char *buf) {
int log2blocksize = LOG2_EXT2_BLOCK_SIZE (node->data);
int blocksize = 1 << (log2blocksize + DISK_SECTOR_BITS);
unsigned int filesize = __le32_to_cpu(node->inode.size);
int blknr;
int blockend;
int status;
int remain = len;
char *buffer = buf;
int stream = 0;
int cur = pos / blocksize;
int blockoff = pos % blocksize;
/* Adjust len so it we can't read past the end of the file. */
if (len > filesize) {
len = filesize;
}
while (remain > 0) {
blknr = ext2fs_read_block (node, cur, &stream);
if (blknr < 0) {
return (-1);
}
blknr = blknr << log2blocksize;
if(remain < blocksize * stream) {
blockend = remain;
} else {
blockend = blocksize * stream;
}
status = ext2fs_devread (blknr, blockoff, blockend, buffer);
if (status == 0) {
return (-1);
}
remain -= blockend;
buffer += blockend;
cur += stream;
blockoff = 0;
if(remain == 0)
return (len);
else if(remain < 0)
return (-1);
}
return (len);
}
static quik_err_t
ext2fs_read_block(ext2fs_node_t node,
int fileblock,
unsigned *block_nr)
{
struct ext2_data *data = node->data;
struct ext2_inode *inode = &node->inode;
unsigned blknr;
int blksz = EXT2_BLOCK_SIZE(data);
int log2_blksz = LOG2_EXT2_BLOCK_SIZE(data);
quik_err_t err;
/* 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 (indir1_block == NULL) {
indir1_block = (uint32_t *) malloc(blksz);
if (indir1_block == NULL) {
return ERR_NO_MEM;
}
indir1_size = blksz;
indir1_blkno = -1;
}
if (blksz != indir1_size) {
free(indir1_block);
indir1_block = NULL;
indir1_size = 0;
indir1_blkno = -1;
indir1_block = (uint32_t *) malloc(blksz);
if (indir1_block == NULL) {
return ERR_NO_MEM;
}
indir1_size = blksz;
}
if ((__le32_to_cpu(inode->b.blocks.indir_block) <<
log2_blksz) != indir1_blkno) {
err = part_read(data->part,
__le32_to_cpu(inode->b.blocks.indir_block) << log2_blksz,
0, blksz,
(char *) indir1_block);
if (err != ERR_NONE) {
return err;
}
indir1_blkno =
__le32_to_cpu(inode->b.blocks.
indir_block) << log2_blksz;
}
blknr = __le32_to_cpu(indir1_block
[fileblock - INDIRECT_BLOCKS]);
}
/* Double indirect. */
else if (fileblock <
(INDIRECT_BLOCKS + (blksz / 4 * (blksz / 4 + 1)))) {
unsigned int perblock = blksz / 4;
unsigned int rblock = fileblock - (INDIRECT_BLOCKS
+ blksz / 4);
if (indir1_block == NULL) {
indir1_block = (uint32_t *) malloc(blksz);
if (indir1_block == NULL) {
return ERR_NO_MEM;
}
indir1_size = blksz;
indir1_blkno = -1;
}
if (blksz != indir1_size) {
free(indir1_block);
indir1_block = NULL;
indir1_size = 0;
indir1_blkno = -1;
indir1_block = (uint32_t *) malloc(blksz);
if (indir1_block == NULL) {
return ERR_NO_MEM;
}
indir1_size = blksz;
}
if ((__le32_to_cpu(inode->b.blocks.double_indir_block) <<
log2_blksz) != indir1_blkno) {
err = part_read(data->part,
__le32_to_cpu(inode->b.blocks.double_indir_block) << log2_blksz,
0, blksz,
(char *) indir1_block);
if (err != ERR_NONE) {
return err;
}
indir1_blkno =
__le32_to_cpu(inode->b.blocks.double_indir_block) << log2_blksz;
}
if (indir2_block == NULL) {
indir2_block = (uint32_t *) malloc(blksz);
if (indir2_block == NULL) {
return ERR_NO_MEM;
}
indir2_size = blksz;
indir2_blkno = -1;
}
if (blksz != indir2_size) {
free(indir2_block);
indir2_block = NULL;
indir2_size = 0;
indir2_blkno = -1;
indir2_block = (uint32_t *) malloc(blksz);
if (indir2_block == NULL) {
return ERR_NO_MEM;
}
indir2_size = blksz;
}
if ((__le32_to_cpu(indir1_block[rblock / perblock]) <<
log2_blksz) != indir2_blkno) {
err = part_read(data->part,
__le32_to_cpu(indir1_block[rblock / perblock]) << log2_blksz,
0, blksz,
(char *) indir2_block);
if (err != ERR_NONE) {
return err;
}
indir2_blkno =
__le32_to_cpu(indir1_block[rblock / perblock]) << log2_blksz;
}
blknr = __le32_to_cpu(indir2_block[rblock % perblock]);
}
/* Triple indirect. */
else {
return ERR_FS_CORRUPT;
}
#ifdef DEBUG
printk("ext2fs_read_block %x\n", blknr);
#endif
*block_nr = blknr;
return ERR_NONE;
}
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_EXT2_BLOCK_SIZE(ext4fs_root);
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 >= le32_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 >= le32_to_cpu(extent[i].ee_len)) {
free(buf);
return 0;
}
start = le32_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(__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 0;
}
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(__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(__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
(__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(__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(__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("ext4fs_read_block %ld\n", blknr);
return blknr;
}
long int read_allocated_block(struct ext2fs_node *node, int fileblock)
{
long int blknr;
int blksz;
int log2_blksz;
long int rblock;
long int perblock_parent;
long int perblock_child;
unsigned long long start;
struct ext2_inode *inode = &node->inode;
struct ext2_data *data = node->data;
int ret;
/* get the blocksize of the filesystem */
blksz = EXT2_BLOCK_SIZE(node->data);
log2_blksz = LOG2_EXT2_BLOCK_SIZE(node->data);
if (le32_to_cpu(inode->flags) & EXT4_EXTENTS_FL) {
char *buf = zalloc(blksz);
struct ext4_extent_header *ext_block;
struct ext4_extent *extent;
int i = -1;
if (!buf)
return -ENOMEM;
ext_block = ext4fs_get_extent_block(node->data, buf,
(struct ext4_extent_header *)inode->b.blocks.dir_blocks,
fileblock, log2_blksz);
if (!ext_block) {
pr_err("invalid extent block\n");
free(buf);
return -EINVAL;
}
extent = (struct ext4_extent *)(ext_block + 1);
do {
i++;
if (i >= le32_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 >= le32_to_cpu(extent[i].ee_len)) {
free(buf);
return 0;
}
start = le32_to_cpu(extent[i].ee_start_hi);
start = (start << 32) +
le32_to_cpu(extent[i].ee_start_lo);
free(buf);
return fileblock + start;
}
free(buf);
return -EIO;
}
if (fileblock < INDIRECT_BLOCKS) {
/* Direct blocks. */
blknr = __le32_to_cpu(inode->b.blocks.dir_blocks[fileblock]);
} else if (fileblock < (INDIRECT_BLOCKS + (blksz / 4))) {
/* Indirect. */
ret = ext4fs_get_indir_block(node, &data->indir1,
__le32_to_cpu(inode->b.blocks.indir_block) << log2_blksz);
if (ret)
return ret;
blknr = __le32_to_cpu(data->indir1.data[fileblock - INDIRECT_BLOCKS]);
} else if (fileblock < (INDIRECT_BLOCKS + (blksz / 4 *
(blksz / 4 + 1)))) {
/* Double indirect. */
long int perblock = blksz / 4;
long int rblock = fileblock - (INDIRECT_BLOCKS + blksz / 4);
ret = ext4fs_get_indir_block(node, &data->indir1,
__le32_to_cpu(inode->b.blocks.double_indir_block) << log2_blksz);
if (ret)
return ret;
ret = ext4fs_get_indir_block(node, &data->indir2,
__le32_to_cpu(data->indir1.data[rblock / perblock]) << log2_blksz);
if (ret)
return ret;
blknr = __le32_to_cpu(data->indir2.data[rblock % perblock]);
} else {
/* Triple indirect. */
rblock = fileblock - (INDIRECT_BLOCKS + blksz / 4 +
(blksz / 4 * blksz / 4));
perblock_child = blksz / 4;
perblock_parent = ((blksz / 4) * (blksz / 4));
ret = ext4fs_get_indir_block(node, &data->indir1,
__le32_to_cpu(inode->b.blocks.triple_indir_block) << log2_blksz);
if (ret)
return ret;
ret = ext4fs_get_indir_block(node, &data->indir2,
__le32_to_cpu(data->indir1.data[rblock / perblock_parent]) << log2_blksz);
if (ret)
return ret;
ret = ext4fs_get_indir_block(node, &data->indir3,
__le32_to_cpu(data->indir2.data[rblock / perblock_child]) << log2_blksz);
if (ret)
return ret;
blknr = __le32_to_cpu(data->indir3.data[rblock % perblock_child]);
}
return blknr;
}