Documentation/filesystems/ext4/directory.rst - linux - Git at Google

 .. SPDX-License-Identifier: GPL-2.0

 Directory Entries
 -----------------

 In an ext4 filesystem, a directory is more or less a flat file that maps
 an arbitrary byte string (usually ASCII) to an inode number on the
 filesystem. There can be many directory entries across the filesystem
 that reference the same inode number--these are known as hard links, and
 that is why hard links cannot reference files on other filesystems. As
 such, directory entries are found by reading the data block(s)
 associated with a directory file for the particular directory entry that
 is desired.

 Linear (Classic) Directories
 ~~~~~~~~~~~~~~~~~~~~~~~~~~~~

 By default, each directory lists its entries in an “almost-linear”
 array. I write “almost” because it's not a linear array in the memory
 sense because directory entries are not split across filesystem blocks.
 Therefore, it is more accurate to say that a directory is a series of
 data blocks and that each block contains a linear array of directory
 entries. The end of each per-block array is signified by reaching the
 end of the block; the last entry in the block has a record length that
 takes it all the way to the end of the block. The end of the entire
 directory is of course signified by reaching the end of the file. Unused
 directory entries are signified by inode = 0. By default the filesystem
 uses ``struct ext4_dir_entry_2`` for directory entries unless the
 “filetype” feature flag is not set, in which case it uses
 ``struct ext4_dir_entry``.

 The original directory entry format is ``struct ext4_dir_entry``, which
 is at most 263 bytes long, though on disk you'll need to reference
 ``dirent.rec_len`` to know for sure.

 .. list-table::
    :widths: 8 8 24 40
    :header-rows: 1

    * - Offset
      - Size
      - Name
      - Description
    * - 0x0
      - \_\_le32
      - inode
      - Number of the inode that this directory entry points to.
    * - 0x4
      - \_\_le16
      - rec\_len
      - Length of this directory entry. Must be a multiple of 4.
    * - 0x6
      - \_\_le16
      - name\_len
      - Length of the file name.
    * - 0x8
      - char
      - name[EXT4\_NAME\_LEN]
      - File name.

 Since file names cannot be longer than 255 bytes, the new directory
 entry format shortens the name\_len field and uses the space for a file
 type flag, probably to avoid having to load every inode during directory
 tree traversal. This format is ``ext4_dir_entry_2``, which is at most
 263 bytes long, though on disk you'll need to reference
 ``dirent.rec_len`` to know for sure.

 .. list-table::
    :widths: 8 8 24 40
    :header-rows: 1

    * - Offset
      - Size
      - Name
      - Description
    * - 0x0
      - \_\_le32
      - inode
      - Number of the inode that this directory entry points to.
    * - 0x4
      - \_\_le16
      - rec\_len
      - Length of this directory entry.
    * - 0x6
      - \_\_u8
      - name\_len
      - Length of the file name.
    * - 0x7
      - \_\_u8
      - file\_type
      - File type code, see ftype_ table below.
    * - 0x8
      - char
      - name[EXT4\_NAME\_LEN]
      - File name.

 .. _ftype:

 The directory file type is one of the following values:

 .. list-table::
    :widths: 16 64
    :header-rows: 1

    * - Value
      - Description
    * - 0x0
      - Unknown.
    * - 0x1
      - Regular file.
    * - 0x2
      - Directory.
    * - 0x3
      - Character device file.
    * - 0x4
      - Block device file.
    * - 0x5
      - FIFO.
    * - 0x6
      - Socket.
    * - 0x7
      - Symbolic link.

 To support directories that are both encrypted and casefolded directories, we
 must also include hash information in the directory entry. We append
 ``ext4_extended_dir_entry_2`` to ``ext4_dir_entry_2`` except for the entries
 for dot and dotdot, which are kept the same. The structure follows immediately
 after ``name`` and is included in the size listed by ``rec_len`` If a directory
 entry uses this extension, it may be up to 271 bytes.

 .. list-table::
    :widths: 8 8 24 40
    :header-rows: 1

    * - Offset
      - Size
      - Name
      - Description
    * - 0x0
      - \_\_le32
      - hash
      - The hash of the directory name
    * - 0x4
      - \_\_le32
      - minor\_hash
      - The minor hash of the directory name


 In order to add checksums to these classic directory blocks, a phony
 ``struct ext4_dir_entry`` is placed at the end of each leaf block to
 hold the checksum. The directory entry is 12 bytes long. The inode
 number and name\_len fields are set to zero to fool old software into
 ignoring an apparently empty directory entry, and the checksum is stored
 in the place where the name normally goes. The structure is
 ``struct ext4_dir_entry_tail``:

 .. list-table::
    :widths: 8 8 24 40
    :header-rows: 1

    * - Offset
      - Size
      - Name
      - Description
    * - 0x0
      - \_\_le32
      - det\_reserved\_zero1
      - Inode number, which must be zero.
    * - 0x4
      - \_\_le16
      - det\_rec\_len
      - Length of this directory entry, which must be 12.
    * - 0x6
      - \_\_u8
      - det\_reserved\_zero2
      - Length of the file name, which must be zero.
    * - 0x7
      - \_\_u8
      - det\_reserved\_ft
      - File type, which must be 0xDE.
    * - 0x8
      - \_\_le32
      - det\_checksum
      - Directory leaf block checksum.

 The leaf directory block checksum is calculated against the FS UUID, the
 directory's inode number, the directory's inode generation number, and
 the entire directory entry block up to (but not including) the fake
 directory entry.

 Hash Tree Directories
 ~~~~~~~~~~~~~~~~~~~~~

 A linear array of directory entries isn't great for performance, so a
 new feature was added to ext3 to provide a faster (but peculiar)
 balanced tree keyed off a hash of the directory entry name. If the
 EXT4\_INDEX\_FL (0x1000) flag is set in the inode, this directory uses a
 hashed btree (htree) to organize and find directory entries. For
 backwards read-only compatibility with ext2, this tree is actually
 hidden inside the directory file, masquerading as “empty” directory data
 blocks! It was stated previously that the end of the linear directory
 entry table was signified with an entry pointing to inode 0; this is
 (ab)used to fool the old linear-scan algorithm into thinking that the
 rest of the directory block is empty so that it moves on.

 The root of the tree always lives in the first data block of the
 directory. By ext2 custom, the '.' and '..' entries must appear at the
 beginning of this first block, so they are put here as two
 ``struct ext4_dir_entry_2``\ s and not stored in the tree. The rest of
 the root node contains metadata about the tree and finally a hash->block
 map to find nodes that are lower in the htree. If
 ``dx_root.info.indirect_levels`` is non-zero then the htree has two
 levels; the data block pointed to by the root node's map is an interior
 node, which is indexed by a minor hash. Interior nodes in this tree
 contains a zeroed out ``struct ext4_dir_entry_2`` followed by a
 minor\_hash->block map to find leafe nodes. Leaf nodes contain a linear
 array of all ``struct ext4_dir_entry_2``; all of these entries
 (presumably) hash to the same value. If there is an overflow, the
 entries simply overflow into the next leaf node, and the
 least-significant bit of the hash (in the interior node map) that gets
 us to this next leaf node is set.

 To traverse the directory as a htree, the code calculates the hash of
 the desired file name and uses it to find the corresponding block
 number. If the tree is flat, the block is a linear array of directory
 entries that can be searched; otherwise, the minor hash of the file name
 is computed and used against this second block to find the corresponding
 third block number. That third block number will be a linear array of
 directory entries.

 To traverse the directory as a linear array (such as the old code does),
 the code simply reads every data block in the directory. The blocks used
 for the htree will appear to have no entries (aside from '.' and '..')
 and so only the leaf nodes will appear to have any interesting content.

 The root of the htree is in ``struct dx_root``, which is the full length
 of a data block:

 .. list-table::
    :widths: 8 8 24 40
    :header-rows: 1

    * - Offset
      - Type
      - Name
      - Description
    * - 0x0
      - \_\_le32
      - dot.inode
      - inode number of this directory.
    * - 0x4
      - \_\_le16
      - dot.rec\_len
      - Length of this record, 12.
    * - 0x6
      - u8
      - dot.name\_len
      - Length of the name, 1.
    * - 0x7
      - u8
      - dot.file\_type
      - File type of this entry, 0x2 (directory) (if the feature flag is set).
    * - 0x8
      - char
      - dot.name[4]
      - “.\\0\\0\\0”
    * - 0xC
      - \_\_le32
      - dotdot.inode
      - inode number of parent directory.
    * - 0x10
      - \_\_le16
      - dotdot.rec\_len
      - block\_size - 12. The record length is long enough to cover all htree
        data.
    * - 0x12
      - u8
      - dotdot.name\_len
      - Length of the name, 2.
    * - 0x13
      - u8
      - dotdot.file\_type
      - File type of this entry, 0x2 (directory) (if the feature flag is set).
    * - 0x14
      - char
      - dotdot\_name[4]
      - “..\\0\\0”
    * - 0x18
      - \_\_le32
      - struct dx\_root\_info.reserved\_zero
      - Zero.
    * - 0x1C
      - u8
      - struct dx\_root\_info.hash\_version
      - Hash type, see dirhash_ table below.
    * - 0x1D
      - u8
      - struct dx\_root\_info.info\_length
      - Length of the tree information, 0x8.
    * - 0x1E
      - u8
      - struct dx\_root\_info.indirect\_levels
      - Depth of the htree. Cannot be larger than 3 if the INCOMPAT\_LARGEDIR
        feature is set; cannot be larger than 2 otherwise.
    * - 0x1F
      - u8
      - struct dx\_root\_info.unused\_flags
      -
    * - 0x20
      - \_\_le16
      - limit
      - Maximum number of dx\_entries that can follow this header, plus 1 for
        the header itself.
    * - 0x22
      - \_\_le16
      - count
      - Actual number of dx\_entries that follow this header, plus 1 for the
        header itself.
    * - 0x24
      - \_\_le32
      - block
      - The block number (within the directory file) that goes with hash=0.
    * - 0x28
      - struct dx\_entry
      - entries[0]
      - As many 8-byte ``struct dx_entry`` as fits in the rest of the data block.

 .. _dirhash:

 The directory hash is one of the following values:

 .. list-table::
    :widths: 16 64
    :header-rows: 1

    * - Value
      - Description
    * - 0x0
      - Legacy.
    * - 0x1
      - Half MD4.
    * - 0x2
      - Tea.
    * - 0x3
      - Legacy, unsigned.
    * - 0x4
      - Half MD4, unsigned.
    * - 0x5
      - Tea, unsigned.
    * - 0x6
      - Siphash.

 Interior nodes of an htree are recorded as ``struct dx_node``, which is
 also the full length of a data block:

 .. list-table::
    :widths: 8 8 24 40
    :header-rows: 1

    * - Offset
      - Type
      - Name
      - Description
    * - 0x0
      - \_\_le32
      - fake.inode
      - Zero, to make it look like this entry is not in use.
    * - 0x4
      - \_\_le16
      - fake.rec\_len
      - The size of the block, in order to hide all of the dx\_node data.
    * - 0x6
      - u8
      - name\_len
      - Zero. There is no name for this “unused” directory entry.
    * - 0x7
      - u8
      - file\_type
      - Zero. There is no file type for this “unused” directory entry.
    * - 0x8
      - \_\_le16
      - limit
      - Maximum number of dx\_entries that can follow this header, plus 1 for
        the header itself.
    * - 0xA
      - \_\_le16
      - count
      - Actual number of dx\_entries that follow this header, plus 1 for the
        header itself.
    * - 0xE
      - \_\_le32
      - block
      - The block number (within the directory file) that goes with the lowest
        hash value of this block. This value is stored in the parent block.
    * - 0x12
      - struct dx\_entry
      - entries[0]
      - As many 8-byte ``struct dx_entry`` as fits in the rest of the data block.

 The hash maps that exist in both ``struct dx_root`` and
 ``struct dx_node`` are recorded as ``struct dx_entry``, which is 8 bytes
 long:

 .. list-table::
    :widths: 8 8 24 40
    :header-rows: 1

    * - Offset
      - Type
      - Name
      - Description
    * - 0x0
      - \_\_le32
      - hash
      - Hash code.
    * - 0x4
      - \_\_le32
      - block
      - Block number (within the directory file, not filesystem blocks) of the
        next node in the htree.

 (If you think this is all quite clever and peculiar, so does the
 author.)

 If metadata checksums are enabled, the last 8 bytes of the directory
 block (precisely the length of one dx\_entry) are used to store a
 ``struct dx_tail``, which contains the checksum. The ``limit`` and
 ``count`` entries in the dx\_root/dx\_node structures are adjusted as
 necessary to fit the dx\_tail into the block. If there is no space for
 the dx\_tail, the user is notified to run e2fsck -D to rebuild the
 directory index (which will ensure that there's space for the checksum.
 The dx\_tail structure is 8 bytes long and looks like this:

 .. list-table::
    :widths: 8 8 24 40
    :header-rows: 1

    * - Offset
      - Type
      - Name
      - Description
    * - 0x0
      - u32
      - dt\_reserved
      - Zero.
    * - 0x4
      - \_\_le32
      - dt\_checksum
      - Checksum of the htree directory block.

 The checksum is calculated against the FS UUID, the htree index header
 (dx\_root or dx\_node), all of the htree indices (dx\_entry) that are in
 use, and the tail block (dx\_tail).
	.. SPDX-License-Identifier: GPL-2.0

	Directory Entries
	-----------------

	In an ext4 filesystem, a directory is more or less a flat file that maps
	an arbitrary byte string (usually ASCII) to an inode number on the
	filesystem. There can be many directory entries across the filesystem
	that reference the same inode number--these are known as hard links, and
	that is why hard links cannot reference files on other filesystems. As
	such, directory entries are found by reading the data block(s)
	associated with a directory file for the particular directory entry that
	is desired.

	Linear (Classic) Directories
	~~~~~~~~~~~~~~~~~~~~~~~~~~~~

	By default, each directory lists its entries in an “almost-linear”
	array. I write “almost” because it's not a linear array in the memory
	sense because directory entries are not split across filesystem blocks.
	Therefore, it is more accurate to say that a directory is a series of
	data blocks and that each block contains a linear array of directory
	entries. The end of each per-block array is signified by reaching the
	end of the block; the last entry in the block has a record length that
	takes it all the way to the end of the block. The end of the entire
	directory is of course signified by reaching the end of the file. Unused
	directory entries are signified by inode = 0. By default the filesystem
	uses ``struct ext4_dir_entry_2`` for directory entries unless the
	“filetype” feature flag is not set, in which case it uses
	``struct ext4_dir_entry``.

	The original directory entry format is ``struct ext4_dir_entry``, which
	is at most 263 bytes long, though on disk you'll need to reference
	``dirent.rec_len`` to know for sure.

	.. list-table::
	:widths: 8 8 24 40
	:header-rows: 1

	* - Offset
	- Size
	- Name
	- Description
	* - 0x0
	- \_\_le32
	- inode
	- Number of the inode that this directory entry points to.
	* - 0x4
	- \_\_le16
	- rec\_len
	- Length of this directory entry. Must be a multiple of 4.
	* - 0x6
	- \_\_le16
	- name\_len
	- Length of the file name.
	* - 0x8
	- char
	- name[EXT4\_NAME\_LEN]
	- File name.

	Since file names cannot be longer than 255 bytes, the new directory
	entry format shortens the name\_len field and uses the space for a file
	type flag, probably to avoid having to load every inode during directory
	tree traversal. This format is ``ext4_dir_entry_2``, which is at most
	263 bytes long, though on disk you'll need to reference
	``dirent.rec_len`` to know for sure.

	.. list-table::
	:widths: 8 8 24 40
	:header-rows: 1

	* - Offset
	- Size
	- Name
	- Description
	* - 0x0
	- \_\_le32
	- inode
	- Number of the inode that this directory entry points to.
	* - 0x4
	- \_\_le16
	- rec\_len
	- Length of this directory entry.
	* - 0x6
	- \_\_u8
	- name\_len
	- Length of the file name.
	* - 0x7
	- \_\_u8
	- file\_type
	- File type code, see ftype_ table below.
	* - 0x8
	- char
	- name[EXT4\_NAME\_LEN]
	- File name.

	.. _ftype:

	The directory file type is one of the following values:

	.. list-table::
	:widths: 16 64
	:header-rows: 1

	* - Value
	- Description
	* - 0x0
	- Unknown.
	* - 0x1
	- Regular file.
	* - 0x2
	- Directory.
	* - 0x3
	- Character device file.
	* - 0x4
	- Block device file.
	* - 0x5
	- FIFO.
	* - 0x6
	- Socket.
	* - 0x7
	- Symbolic link.

	To support directories that are both encrypted and casefolded directories, we
	must also include hash information in the directory entry. We append
	``ext4_extended_dir_entry_2`` to ``ext4_dir_entry_2`` except for the entries
	for dot and dotdot, which are kept the same. The structure follows immediately
	after ``name`` and is included in the size listed by ``rec_len`` If a directory
	entry uses this extension, it may be up to 271 bytes.

	.. list-table::
	:widths: 8 8 24 40
	:header-rows: 1

	* - Offset
	- Size
	- Name
	- Description
	* - 0x0
	- \_\_le32
	- hash
	- The hash of the directory name
	* - 0x4
	- \_\_le32
	- minor\_hash
	- The minor hash of the directory name


	In order to add checksums to these classic directory blocks, a phony
	``struct ext4_dir_entry`` is placed at the end of each leaf block to
	hold the checksum. The directory entry is 12 bytes long. The inode
	number and name\_len fields are set to zero to fool old software into
	ignoring an apparently empty directory entry, and the checksum is stored
	in the place where the name normally goes. The structure is
	``struct ext4_dir_entry_tail``:

	.. list-table::
	:widths: 8 8 24 40
	:header-rows: 1

	* - Offset
	- Size
	- Name
	- Description
	* - 0x0
	- \_\_le32
	- det\_reserved\_zero1
	- Inode number, which must be zero.
	* - 0x4
	- \_\_le16
	- det\_rec\_len
	- Length of this directory entry, which must be 12.
	* - 0x6
	- \_\_u8
	- det\_reserved\_zero2
	- Length of the file name, which must be zero.
	* - 0x7
	- \_\_u8
	- det\_reserved\_ft
	- File type, which must be 0xDE.
	* - 0x8
	- \_\_le32
	- det\_checksum
	- Directory leaf block checksum.

	The leaf directory block checksum is calculated against the FS UUID, the
	directory's inode number, the directory's inode generation number, and
	the entire directory entry block up to (but not including) the fake
	directory entry.

	Hash Tree Directories
	~~~~~~~~~~~~~~~~~~~~~

	A linear array of directory entries isn't great for performance, so a
	new feature was added to ext3 to provide a faster (but peculiar)
	balanced tree keyed off a hash of the directory entry name. If the
	EXT4\_INDEX\_FL (0x1000) flag is set in the inode, this directory uses a
	hashed btree (htree) to organize and find directory entries. For
	backwards read-only compatibility with ext2, this tree is actually
	hidden inside the directory file, masquerading as “empty” directory data
	blocks! It was stated previously that the end of the linear directory
	entry table was signified with an entry pointing to inode 0; this is
	(ab)used to fool the old linear-scan algorithm into thinking that the
	rest of the directory block is empty so that it moves on.

	The root of the tree always lives in the first data block of the
	directory. By ext2 custom, the '.' and '..' entries must appear at the
	beginning of this first block, so they are put here as two
	``struct ext4_dir_entry_2``\ s and not stored in the tree. The rest of
	the root node contains metadata about the tree and finally a hash->block
	map to find nodes that are lower in the htree. If
	``dx_root.info.indirect_levels`` is non-zero then the htree has two
	levels; the data block pointed to by the root node's map is an interior
	node, which is indexed by a minor hash. Interior nodes in this tree
	contains a zeroed out ``struct ext4_dir_entry_2`` followed by a
	minor\_hash->block map to find leafe nodes. Leaf nodes contain a linear
	array of all ``struct ext4_dir_entry_2``; all of these entries
	(presumably) hash to the same value. If there is an overflow, the
	entries simply overflow into the next leaf node, and the
	least-significant bit of the hash (in the interior node map) that gets
	us to this next leaf node is set.

	To traverse the directory as a htree, the code calculates the hash of
	the desired file name and uses it to find the corresponding block
	number. If the tree is flat, the block is a linear array of directory
	entries that can be searched; otherwise, the minor hash of the file name
	is computed and used against this second block to find the corresponding
	third block number. That third block number will be a linear array of
	directory entries.

	To traverse the directory as a linear array (such as the old code does),
	the code simply reads every data block in the directory. The blocks used
	for the htree will appear to have no entries (aside from '.' and '..')
	and so only the leaf nodes will appear to have any interesting content.

	The root of the htree is in ``struct dx_root``, which is the full length
	of a data block:

	.. list-table::
	:widths: 8 8 24 40
	:header-rows: 1

	* - Offset
	- Type
	- Name
	- Description
	* - 0x0
	- \_\_le32
	- dot.inode
	- inode number of this directory.
	* - 0x4
	- \_\_le16
	- dot.rec\_len
	- Length of this record, 12.
	* - 0x6
	- u8
	- dot.name\_len
	- Length of the name, 1.
	* - 0x7
	- u8
	- dot.file\_type
	- File type of this entry, 0x2 (directory) (if the feature flag is set).
	* - 0x8
	- char
	- dot.name[4]
	- “.\\0\\0\\0”
	* - 0xC
	- \_\_le32
	- dotdot.inode
	- inode number of parent directory.
	* - 0x10
	- \_\_le16
	- dotdot.rec\_len
	- block\_size - 12. The record length is long enough to cover all htree
	data.
	* - 0x12
	- u8
	- dotdot.name\_len
	- Length of the name, 2.
	* - 0x13
	- u8
	- dotdot.file\_type
	- File type of this entry, 0x2 (directory) (if the feature flag is set).
	* - 0x14
	- char
	- dotdot\_name[4]
	- “..\\0\\0”
	* - 0x18
	- \_\_le32
	- struct dx\_root\_info.reserved\_zero
	- Zero.
	* - 0x1C
	- u8
	- struct dx\_root\_info.hash\_version
	- Hash type, see dirhash_ table below.
	* - 0x1D
	- u8
	- struct dx\_root\_info.info\_length
	- Length of the tree information, 0x8.
	* - 0x1E
	- u8
	- struct dx\_root\_info.indirect\_levels
	- Depth of the htree. Cannot be larger than 3 if the INCOMPAT\_LARGEDIR
	feature is set; cannot be larger than 2 otherwise.
	* - 0x1F
	- u8
	- struct dx\_root\_info.unused\_flags
	-
	* - 0x20
	- \_\_le16
	- limit
	- Maximum number of dx\_entries that can follow this header, plus 1 for
	the header itself.
	* - 0x22
	- \_\_le16
	- count
	- Actual number of dx\_entries that follow this header, plus 1 for the
	header itself.
	* - 0x24
	- \_\_le32
	- block
	- The block number (within the directory file) that goes with hash=0.
	* - 0x28
	- struct dx\_entry
	- entries[0]
	- As many 8-byte ``struct dx_entry`` as fits in the rest of the data block.

	.. _dirhash:

	The directory hash is one of the following values:

	.. list-table::
	:widths: 16 64
	:header-rows: 1

	* - Value
	- Description
	* - 0x0
	- Legacy.
	* - 0x1
	- Half MD4.
	* - 0x2
	- Tea.
	* - 0x3
	- Legacy, unsigned.
	* - 0x4
	- Half MD4, unsigned.
	* - 0x5
	- Tea, unsigned.
	* - 0x6
	- Siphash.

	Interior nodes of an htree are recorded as ``struct dx_node``, which is
	also the full length of a data block:

	.. list-table::
	:widths: 8 8 24 40
	:header-rows: 1

	* - Offset
	- Type
	- Name
	- Description
	* - 0x0
	- \_\_le32
	- fake.inode
	- Zero, to make it look like this entry is not in use.
	* - 0x4
	- \_\_le16
	- fake.rec\_len
	- The size of the block, in order to hide all of the dx\_node data.
	* - 0x6
	- u8
	- name\_len
	- Zero. There is no name for this “unused” directory entry.
	* - 0x7
	- u8
	- file\_type
	- Zero. There is no file type for this “unused” directory entry.
	* - 0x8
	- \_\_le16
	- limit
	- Maximum number of dx\_entries that can follow this header, plus 1 for
	the header itself.
	* - 0xA
	- \_\_le16
	- count
	- Actual number of dx\_entries that follow this header, plus 1 for the
	header itself.
	* - 0xE
	- \_\_le32
	- block
	- The block number (within the directory file) that goes with the lowest
	hash value of this block. This value is stored in the parent block.
	* - 0x12
	- struct dx\_entry
	- entries[0]
	- As many 8-byte ``struct dx_entry`` as fits in the rest of the data block.

	The hash maps that exist in both ``struct dx_root`` and
	``struct dx_node`` are recorded as ``struct dx_entry``, which is 8 bytes
	long:

	.. list-table::
	:widths: 8 8 24 40
	:header-rows: 1

	* - Offset
	- Type
	- Name
	- Description
	* - 0x0
	- \_\_le32
	- hash
	- Hash code.
	* - 0x4
	- \_\_le32
	- block
	- Block number (within the directory file, not filesystem blocks) of the
	next node in the htree.

	(If you think this is all quite clever and peculiar, so does the
	author.)

	If metadata checksums are enabled, the last 8 bytes of the directory
	block (precisely the length of one dx\_entry) are used to store a
	``struct dx_tail``, which contains the checksum. The ``limit`` and
	``count`` entries in the dx\_root/dx\_node structures are adjusted as
	necessary to fit the dx\_tail into the block. If there is no space for
	the dx\_tail, the user is notified to run e2fsck -D to rebuild the
	directory index (which will ensure that there's space for the checksum.
	The dx\_tail structure is 8 bytes long and looks like this:

	.. list-table::
	:widths: 8 8 24 40
	:header-rows: 1

	* - Offset
	- Type
	- Name
	- Description
	* - 0x0
	- u32
	- dt\_reserved
	- Zero.
	* - 0x4
	- \_\_le32
	- dt\_checksum
	- Checksum of the htree directory block.

	The checksum is calculated against the FS UUID, the htree index header
	(dx\_root or dx\_node), all of the htree indices (dx\_entry) that are in
	use, and the tail block (dx\_tail).