Documentation/filesystems/ext4/blockgroup.rst - linux/kernel/git/bpf/bpf - Git at Google

 .. SPDX-License-Identifier: GPL-2.0

 Layout
 ------

 The layout of a standard block group is approximately as follows (each
 of these fields is discussed in a separate section below):

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

    * - Group 0 Padding
      - ext4 Super Block
      - Group Descriptors
      - Reserved GDT Blocks
      - Data Block Bitmap
      - inode Bitmap
      - inode Table
      - Data Blocks
    * - 1024 bytes
      - 1 block
      - many blocks
      - many blocks
      - 1 block
      - 1 block
      - many blocks
      - many more blocks

 For the special case of block group 0, the first 1024 bytes are unused,
 to allow for the installation of x86 boot sectors and other oddities.
 The superblock will start at offset 1024 bytes, whichever block that
 happens to be (usually 0). However, if for some reason the block size =
 1024, then block 0 is marked in use and the superblock goes in block 1.
 For all other block groups, there is no padding.

 The ext4 driver primarily works with the superblock and the group
 descriptors that are found in block group 0. Redundant copies of the
 superblock and group descriptors are written to some of the block groups
 across the disk in case the beginning of the disk gets trashed, though
 not all block groups necessarily host a redundant copy (see following
 paragraph for more details). If the group does not have a redundant
 copy, the block group begins with the data block bitmap. Note also that
 when the filesystem is freshly formatted, mkfs will allocate “reserve
 GDT block” space after the block group descriptors and before the start
 of the block bitmaps to allow for future expansion of the filesystem. By
 default, a filesystem is allowed to increase in size by a factor of
 1024x over the original filesystem size.

 The location of the inode table is given by ``grp.bg_inode_table_*``. It
 is continuous range of blocks large enough to contain
 ``sb.s_inodes_per_group * sb.s_inode_size`` bytes.

 As for the ordering of items in a block group, it is generally
 established that the super block and the group descriptor table, if
 present, will be at the beginning of the block group. The bitmaps and
 the inode table can be anywhere, and it is quite possible for the
 bitmaps to come after the inode table, or for both to be in different
 groups (flex\_bg). Leftover space is used for file data blocks, indirect
 block maps, extent tree blocks, and extended attributes.

 Flexible Block Groups
 ---------------------

 Starting in ext4, there is a new feature called flexible block groups
 (flex\_bg). In a flex\_bg, several block groups are tied together as one
 logical block group; the bitmap spaces and the inode table space in the
 first block group of the flex\_bg are expanded to include the bitmaps
 and inode tables of all other block groups in the flex\_bg. For example,
 if the flex\_bg size is 4, then group 0 will contain (in order) the
 superblock, group descriptors, data block bitmaps for groups 0-3, inode
 bitmaps for groups 0-3, inode tables for groups 0-3, and the remaining
 space in group 0 is for file data. The effect of this is to group the
 block group metadata close together for faster loading, and to enable
 large files to be continuous on disk. Backup copies of the superblock
 and group descriptors are always at the beginning of block groups, even
 if flex\_bg is enabled. The number of block groups that make up a
 flex\_bg is given by 2 ^ ``sb.s_log_groups_per_flex``.

 Meta Block Groups
 -----------------

 Without the option META\_BG, for safety concerns, all block group
 descriptors copies are kept in the first block group. Given the default
 128MiB(2^27 bytes) block group size and 64-byte group descriptors, ext4
 can have at most 2^27/64 = 2^21 block groups. This limits the entire
 filesystem size to 2^21 ∗ 2^27 = 2^48bytes or 256TiB.

 The solution to this problem is to use the metablock group feature
 (META\_BG), which is already in ext3 for all 2.6 releases. With the
 META\_BG feature, ext4 filesystems are partitioned into many metablock
 groups. Each metablock group is a cluster of block groups whose group
 descriptor structures can be stored in a single disk block. For ext4
 filesystems with 4 KB block size, a single metablock group partition
 includes 64 block groups, or 8 GiB of disk space. The metablock group
 feature moves the location of the group descriptors from the congested
 first block group of the whole filesystem into the first group of each
 metablock group itself. The backups are in the second and last group of
 each metablock group. This increases the 2^21 maximum block groups limit
 to the hard limit 2^32, allowing support for a 512PiB filesystem.

 The change in the filesystem format replaces the current scheme where
 the superblock is followed by a variable-length set of block group
 descriptors. Instead, the superblock and a single block group descriptor
 block is placed at the beginning of the first, second, and last block
 groups in a meta-block group. A meta-block group is a collection of
 block groups which can be described by a single block group descriptor
 block. Since the size of the block group descriptor structure is 32
 bytes, a meta-block group contains 32 block groups for filesystems with
 a 1KB block size, and 128 block groups for filesystems with a 4KB
 blocksize. Filesystems can either be created using this new block group
 descriptor layout, or existing filesystems can be resized on-line, and
 the field s\_first\_meta\_bg in the superblock will indicate the first
 block group using this new layout.

 Please see an important note about ``BLOCK_UNINIT`` in the section about
 block and inode bitmaps.

 Lazy Block Group Initialization
 -------------------------------

 A new feature for ext4 are three block group descriptor flags that
 enable mkfs to skip initializing other parts of the block group
 metadata. Specifically, the INODE\_UNINIT and BLOCK\_UNINIT flags mean
 that the inode and block bitmaps for that group can be calculated and
 therefore the on-disk bitmap blocks are not initialized. This is
 generally the case for an empty block group or a block group containing
 only fixed-location block group metadata. The INODE\_ZEROED flag means
 that the inode table has been initialized; mkfs will unset this flag and
 rely on the kernel to initialize the inode tables in the background.

 By not writing zeroes to the bitmaps and inode table, mkfs time is
 reduced considerably. Note the feature flag is RO\_COMPAT\_GDT\_CSUM,
 but the dumpe2fs output prints this as “uninit\_bg”. They are the same
 thing.
	.. SPDX-License-Identifier: GPL-2.0

	Layout
	------

	The layout of a standard block group is approximately as follows (each
	of these fields is discussed in a separate section below):

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

	* - Group 0 Padding
	- ext4 Super Block
	- Group Descriptors
	- Reserved GDT Blocks
	- Data Block Bitmap
	- inode Bitmap
	- inode Table
	- Data Blocks
	* - 1024 bytes
	- 1 block
	- many blocks
	- many blocks
	- 1 block
	- 1 block
	- many blocks
	- many more blocks

	For the special case of block group 0, the first 1024 bytes are unused,
	to allow for the installation of x86 boot sectors and other oddities.
	The superblock will start at offset 1024 bytes, whichever block that
	happens to be (usually 0). However, if for some reason the block size =
	1024, then block 0 is marked in use and the superblock goes in block 1.
	For all other block groups, there is no padding.

	The ext4 driver primarily works with the superblock and the group
	descriptors that are found in block group 0. Redundant copies of the
	superblock and group descriptors are written to some of the block groups
	across the disk in case the beginning of the disk gets trashed, though
	not all block groups necessarily host a redundant copy (see following
	paragraph for more details). If the group does not have a redundant
	copy, the block group begins with the data block bitmap. Note also that
	when the filesystem is freshly formatted, mkfs will allocate “reserve
	GDT block” space after the block group descriptors and before the start
	of the block bitmaps to allow for future expansion of the filesystem. By
	default, a filesystem is allowed to increase in size by a factor of
	1024x over the original filesystem size.

	The location of the inode table is given by ``grp.bg_inode_table_*``. It
	is continuous range of blocks large enough to contain
	``sb.s_inodes_per_group * sb.s_inode_size`` bytes.

	As for the ordering of items in a block group, it is generally
	established that the super block and the group descriptor table, if
	present, will be at the beginning of the block group. The bitmaps and
	the inode table can be anywhere, and it is quite possible for the
	bitmaps to come after the inode table, or for both to be in different
	groups (flex\_bg). Leftover space is used for file data blocks, indirect
	block maps, extent tree blocks, and extended attributes.

	Flexible Block Groups
	---------------------

	Starting in ext4, there is a new feature called flexible block groups
	(flex\_bg). In a flex\_bg, several block groups are tied together as one
	logical block group; the bitmap spaces and the inode table space in the
	first block group of the flex\_bg are expanded to include the bitmaps
	and inode tables of all other block groups in the flex\_bg. For example,
	if the flex\_bg size is 4, then group 0 will contain (in order) the
	superblock, group descriptors, data block bitmaps for groups 0-3, inode
	bitmaps for groups 0-3, inode tables for groups 0-3, and the remaining
	space in group 0 is for file data. The effect of this is to group the
	block group metadata close together for faster loading, and to enable
	large files to be continuous on disk. Backup copies of the superblock
	and group descriptors are always at the beginning of block groups, even
	if flex\_bg is enabled. The number of block groups that make up a
	flex\_bg is given by 2 ^ ``sb.s_log_groups_per_flex``.

	Meta Block Groups
	-----------------

	Without the option META\_BG, for safety concerns, all block group
	descriptors copies are kept in the first block group. Given the default
	128MiB(2^27 bytes) block group size and 64-byte group descriptors, ext4
	can have at most 2^27/64 = 2^21 block groups. This limits the entire
	filesystem size to 2^21 ∗ 2^27 = 2^48bytes or 256TiB.

	The solution to this problem is to use the metablock group feature
	(META\_BG), which is already in ext3 for all 2.6 releases. With the
	META\_BG feature, ext4 filesystems are partitioned into many metablock
	groups. Each metablock group is a cluster of block groups whose group
	descriptor structures can be stored in a single disk block. For ext4
	filesystems with 4 KB block size, a single metablock group partition
	includes 64 block groups, or 8 GiB of disk space. The metablock group
	feature moves the location of the group descriptors from the congested
	first block group of the whole filesystem into the first group of each
	metablock group itself. The backups are in the second and last group of
	each metablock group. This increases the 2^21 maximum block groups limit
	to the hard limit 2^32, allowing support for a 512PiB filesystem.

	The change in the filesystem format replaces the current scheme where
	the superblock is followed by a variable-length set of block group
	descriptors. Instead, the superblock and a single block group descriptor
	block is placed at the beginning of the first, second, and last block
	groups in a meta-block group. A meta-block group is a collection of
	block groups which can be described by a single block group descriptor
	block. Since the size of the block group descriptor structure is 32
	bytes, a meta-block group contains 32 block groups for filesystems with
	a 1KB block size, and 128 block groups for filesystems with a 4KB
	blocksize. Filesystems can either be created using this new block group
	descriptor layout, or existing filesystems can be resized on-line, and
	the field s\_first\_meta\_bg in the superblock will indicate the first
	block group using this new layout.

	Please see an important note about ``BLOCK_UNINIT`` in the section about
	block and inode bitmaps.

	Lazy Block Group Initialization
	-------------------------------

	A new feature for ext4 are three block group descriptor flags that
	enable mkfs to skip initializing other parts of the block group
	metadata. Specifically, the INODE\_UNINIT and BLOCK\_UNINIT flags mean
	that the inode and block bitmaps for that group can be calculated and
	therefore the on-disk bitmap blocks are not initialized. This is
	generally the case for an empty block group or a block group containing
	only fixed-location block group metadata. The INODE\_ZEROED flag means
	that the inode table has been initialized; mkfs will unset this flag and
	rely on the kernel to initialize the inode tables in the background.

	By not writing zeroes to the bitmaps and inode table, mkfs time is
	reduced considerably. Note the feature flag is RO\_COMPAT\_GDT\_CSUM,
	but the dumpe2fs output prints this as “uninit\_bg”. They are the same
	thing.