mirror of
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e080a26725
As commit 2e6506e1c4
("mm/migrate: fix deadlock in
migrate_pages_batch() on large folios") has landed upstream, large
folios can be safely enabled for compressed inodes since all
prerequisites have already landed in 6.11-rc1.
Stress tests has been running on my fleet for over 20 days without any
regression. Additionally, users [1] have requested it for months.
Let's allow large folios for EROFS full cases upstream now for wider
testing.
[1] https://lore.kernel.org/r/CAGsJ_4wtE8OcpinuqVwG4jtdx6Qh5f+TON6wz+4HMCq=A2qFcA@mail.gmail.com
Cc: Barry Song <21cnbao@gmail.com>
Cc: Matthew Wilcox (Oracle) <willy@infradead.org>
[ Gao Xiang: minor commit typo fixes. ]
Signed-off-by: Gao Xiang <hsiangkao@linux.alibaba.com>
Link: https://lore.kernel.org/r/20240819025207.3808649-1-hsiangkao@linux.alibaba.com
369 lines
18 KiB
ReStructuredText
369 lines
18 KiB
ReStructuredText
.. SPDX-License-Identifier: GPL-2.0
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======================================
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EROFS - Enhanced Read-Only File System
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======================================
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Overview
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========
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EROFS filesystem stands for Enhanced Read-Only File System. It aims to form a
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generic read-only filesystem solution for various read-only use cases instead
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of just focusing on storage space saving without considering any side effects
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of runtime performance.
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It is designed to meet the needs of flexibility, feature extendability and user
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payload friendly, etc. Apart from those, it is still kept as a simple
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random-access friendly high-performance filesystem to get rid of unneeded I/O
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amplification and memory-resident overhead compared to similar approaches.
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It is implemented to be a better choice for the following scenarios:
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- read-only storage media or
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- part of a fully trusted read-only solution, which means it needs to be
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immutable and bit-for-bit identical to the official golden image for
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their releases due to security or other considerations and
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- hope to minimize extra storage space with guaranteed end-to-end performance
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by using compact layout, transparent file compression and direct access,
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especially for those embedded devices with limited memory and high-density
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hosts with numerous containers.
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Here are the main features of EROFS:
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- Little endian on-disk design;
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- Block-based distribution and file-based distribution over fscache are
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supported;
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- Support multiple devices to refer to external blobs, which can be used
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for container images;
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- 32-bit block addresses for each device, therefore 16TiB address space at
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most with 4KiB block size for now;
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- Two inode layouts for different requirements:
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===================== ============ ======================================
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compact (v1) extended (v2)
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===================== ============ ======================================
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Inode metadata size 32 bytes 64 bytes
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Max file size 4 GiB 16 EiB (also limited by max. vol size)
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Max uids/gids 65536 4294967296
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Per-inode timestamp no yes (64 + 32-bit timestamp)
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Max hardlinks 65536 4294967296
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Metadata reserved 8 bytes 18 bytes
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===================== ============ ======================================
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- Support extended attributes as an option;
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- Support a bloom filter that speeds up negative extended attribute lookups;
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- Support POSIX.1e ACLs by using extended attributes;
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- Support transparent data compression as an option:
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LZ4, MicroLZMA and DEFLATE algorithms can be used on a per-file basis; In
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addition, inplace decompression is also supported to avoid bounce compressed
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buffers and unnecessary page cache thrashing.
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- Support chunk-based data deduplication and rolling-hash compressed data
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deduplication;
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- Support tailpacking inline compared to byte-addressed unaligned metadata
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or smaller block size alternatives;
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- Support merging tail-end data into a special inode as fragments.
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- Support large folios to make use of THPs (Transparent Hugepages);
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- Support direct I/O on uncompressed files to avoid double caching for loop
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devices;
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- Support FSDAX on uncompressed images for secure containers and ramdisks in
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order to get rid of unnecessary page cache.
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- Support file-based on-demand loading with the Fscache infrastructure.
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The following git tree provides the file system user-space tools under
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development, such as a formatting tool (mkfs.erofs), an on-disk consistency &
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compatibility checking tool (fsck.erofs), and a debugging tool (dump.erofs):
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- git://git.kernel.org/pub/scm/linux/kernel/git/xiang/erofs-utils.git
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For more information, please also refer to the documentation site:
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- https://erofs.docs.kernel.org
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Bugs and patches are welcome, please kindly help us and send to the following
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linux-erofs mailing list:
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- linux-erofs mailing list <linux-erofs@lists.ozlabs.org>
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Mount options
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=============
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=================== =========================================================
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(no)user_xattr Setup Extended User Attributes. Note: xattr is enabled
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by default if CONFIG_EROFS_FS_XATTR is selected.
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(no)acl Setup POSIX Access Control List. Note: acl is enabled
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by default if CONFIG_EROFS_FS_POSIX_ACL is selected.
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cache_strategy=%s Select a strategy for cached decompression from now on:
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========== =============================================
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disabled In-place I/O decompression only;
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readahead Cache the last incomplete compressed physical
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cluster for further reading. It still does
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in-place I/O decompression for the rest
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compressed physical clusters;
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readaround Cache the both ends of incomplete compressed
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physical clusters for further reading.
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It still does in-place I/O decompression
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for the rest compressed physical clusters.
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========== =============================================
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dax={always,never} Use direct access (no page cache). See
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Documentation/filesystems/dax.rst.
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dax A legacy option which is an alias for ``dax=always``.
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device=%s Specify a path to an extra device to be used together.
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fsid=%s Specify a filesystem image ID for Fscache back-end.
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domain_id=%s Specify a domain ID in fscache mode so that different images
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with the same blobs under a given domain ID can share storage.
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=================== =========================================================
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Sysfs Entries
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=============
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Information about mounted erofs file systems can be found in /sys/fs/erofs.
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Each mounted filesystem will have a directory in /sys/fs/erofs based on its
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device name (i.e., /sys/fs/erofs/sda).
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(see also Documentation/ABI/testing/sysfs-fs-erofs)
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On-disk details
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===============
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Summary
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-------
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Different from other read-only file systems, an EROFS volume is designed
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to be as simple as possible::
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|-> aligned with the block size
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____________________________________________________________
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| |SB| | ... | Metadata | ... | Data | Metadata | ... | Data |
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|_|__|_|_____|__________|_____|______|__________|_____|______|
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0 +1K
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All data areas should be aligned with the block size, but metadata areas
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may not. All metadatas can be now observed in two different spaces (views):
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1. Inode metadata space
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Each valid inode should be aligned with an inode slot, which is a fixed
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value (32 bytes) and designed to be kept in line with compact inode size.
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Each inode can be directly found with the following formula:
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inode offset = meta_blkaddr * block_size + 32 * nid
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::
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|-> aligned with 8B
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|-> followed closely
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+ meta_blkaddr blocks |-> another slot
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_____________________________________________________________________
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| ... | inode | xattrs | extents | data inline | ... | inode ...
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|________|_______|(optional)|(optional)|__(optional)_|_____|__________
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|-> aligned with the inode slot size
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. .
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. .
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. .
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. .
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. .
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. .
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.____________________________________________________|-> aligned with 4B
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| xattr_ibody_header | shared xattrs | inline xattrs |
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|____________________|_______________|_______________|
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|-> 12 bytes <-|->x * 4 bytes<-| .
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. . .
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. . .
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. . .
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._______________________________.______________________.
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| id | id | id | id | ... | id | ent | ... | ent| ... |
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|____|____|____|____|______|____|_____|_____|____|_____|
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|-> aligned with 4B
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|-> aligned with 4B
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Inode could be 32 or 64 bytes, which can be distinguished from a common
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field which all inode versions have -- i_format::
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__________________ __________________
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| i_format | | i_format |
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|__________________| |__________________|
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| ... | | ... |
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| | | |
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|__________________| 32 bytes | |
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|__________________| 64 bytes
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Xattrs, extents, data inline are placed after the corresponding inode with
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proper alignment, and they could be optional for different data mappings.
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_currently_ total 5 data layouts are supported:
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== ====================================================================
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0 flat file data without data inline (no extent);
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1 fixed-sized output data compression (with non-compacted indexes);
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2 flat file data with tail packing data inline (no extent);
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3 fixed-sized output data compression (with compacted indexes, v5.3+);
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4 chunk-based file (v5.15+).
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== ====================================================================
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The size of the optional xattrs is indicated by i_xattr_count in inode
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header. Large xattrs or xattrs shared by many different files can be
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stored in shared xattrs metadata rather than inlined right after inode.
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2. Shared xattrs metadata space
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Shared xattrs space is similar to the above inode space, started with
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a specific block indicated by xattr_blkaddr, organized one by one with
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proper align.
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Each share xattr can also be directly found by the following formula:
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xattr offset = xattr_blkaddr * block_size + 4 * xattr_id
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::
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|-> aligned by 4 bytes
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+ xattr_blkaddr blocks |-> aligned with 4 bytes
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_________________________________________________________________________
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| ... | xattr_entry | xattr data | ... | xattr_entry | xattr data ...
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|________|_____________|_____________|_____|______________|_______________
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Directories
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-----------
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All directories are now organized in a compact on-disk format. Note that
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each directory block is divided into index and name areas in order to support
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random file lookup, and all directory entries are _strictly_ recorded in
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alphabetical order in order to support improved prefix binary search
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algorithm (could refer to the related source code).
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::
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___________________________
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/ |
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/ ______________|________________
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/ / | nameoff1 | nameoffN-1
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____________.______________._______________v________________v__________
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| dirent | dirent | ... | dirent | filename | filename | ... | filename |
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|___.0___|____1___|_____|___N-1__|____0_____|____1_____|_____|___N-1____|
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\ ^
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\ | * could have
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\ | trailing '\0'
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\________________________| nameoff0
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Directory block
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Note that apart from the offset of the first filename, nameoff0 also indicates
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the total number of directory entries in this block since it is no need to
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introduce another on-disk field at all.
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Chunk-based files
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-----------------
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In order to support chunk-based data deduplication, a new inode data layout has
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been supported since Linux v5.15: Files are split in equal-sized data chunks
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with ``extents`` area of the inode metadata indicating how to get the chunk
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data: these can be simply as a 4-byte block address array or in the 8-byte
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chunk index form (see struct erofs_inode_chunk_index in erofs_fs.h for more
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details.)
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By the way, chunk-based files are all uncompressed for now.
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Long extended attribute name prefixes
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-------------------------------------
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There are use cases where extended attributes with different values can have
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only a few common prefixes (such as overlayfs xattrs). The predefined prefixes
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work inefficiently in both image size and runtime performance in such cases.
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The long xattr name prefixes feature is introduced to address this issue. The
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overall idea is that, apart from the existing predefined prefixes, the xattr
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entry could also refer to user-specified long xattr name prefixes, e.g.
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"trusted.overlay.".
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When referring to a long xattr name prefix, the highest bit (bit 7) of
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erofs_xattr_entry.e_name_index is set, while the lower bits (bit 0-6) as a whole
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represent the index of the referred long name prefix among all long name
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prefixes. Therefore, only the trailing part of the name apart from the long
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xattr name prefix is stored in erofs_xattr_entry.e_name, which could be empty if
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the full xattr name matches exactly as its long xattr name prefix.
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All long xattr prefixes are stored one by one in the packed inode as long as
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the packed inode is valid, or in the meta inode otherwise. The
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xattr_prefix_count (of the on-disk superblock) indicates the total number of
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long xattr name prefixes, while (xattr_prefix_start * 4) indicates the start
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offset of long name prefixes in the packed/meta inode. Note that, long extended
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attribute name prefixes are disabled if xattr_prefix_count is 0.
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Each long name prefix is stored in the format: ALIGN({__le16 len, data}, 4),
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where len represents the total size of the data part. The data part is actually
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represented by 'struct erofs_xattr_long_prefix', where base_index represents the
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index of the predefined xattr name prefix, e.g. EROFS_XATTR_INDEX_TRUSTED for
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"trusted.overlay." long name prefix, while the infix string keeps the string
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after stripping the short prefix, e.g. "overlay." for the example above.
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Data compression
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----------------
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EROFS implements fixed-sized output compression which generates fixed-sized
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compressed data blocks from variable-sized input in contrast to other existing
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fixed-sized input solutions. Relatively higher compression ratios can be gotten
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by using fixed-sized output compression since nowadays popular data compression
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algorithms are mostly LZ77-based and such fixed-sized output approach can be
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benefited from the historical dictionary (aka. sliding window).
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In details, original (uncompressed) data is turned into several variable-sized
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extents and in the meanwhile, compressed into physical clusters (pclusters).
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In order to record each variable-sized extent, logical clusters (lclusters) are
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introduced as the basic unit of compress indexes to indicate whether a new
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extent is generated within the range (HEAD) or not (NONHEAD). Lclusters are now
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fixed in block size, as illustrated below::
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|<- variable-sized extent ->|<- VLE ->|
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clusterofs clusterofs clusterofs
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_________v_________________________________v_______________________v________
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... | . | | . | | . ...
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____|____._________|______________|________.___ _|______________|__.________
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|-> lcluster <-|-> lcluster <-|-> lcluster <-|-> lcluster <-|
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(HEAD) (NONHEAD) (HEAD) (NONHEAD) .
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. CBLKCNT . .
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. . .
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. . .
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_______._____________________________.______________._________________
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... | | | | ...
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_______|______________|______________|______________|_________________
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|-> big pcluster <-|-> pcluster <-|
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A physical cluster can be seen as a container of physical compressed blocks
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which contains compressed data. Previously, only lcluster-sized (4KB) pclusters
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were supported. After big pcluster feature is introduced (available since
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Linux v5.13), pcluster can be a multiple of lcluster size.
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For each HEAD lcluster, clusterofs is recorded to indicate where a new extent
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starts and blkaddr is used to seek the compressed data. For each NONHEAD
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lcluster, delta0 and delta1 are available instead of blkaddr to indicate the
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distance to its HEAD lcluster and the next HEAD lcluster. A PLAIN lcluster is
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also a HEAD lcluster except that its data is uncompressed. See the comments
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around "struct z_erofs_vle_decompressed_index" in erofs_fs.h for more details.
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If big pcluster is enabled, pcluster size in lclusters needs to be recorded as
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well. Let the delta0 of the first NONHEAD lcluster store the compressed block
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count with a special flag as a new called CBLKCNT NONHEAD lcluster. It's easy
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to understand its delta0 is constantly 1, as illustrated below::
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__________________________________________________________
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| HEAD | NONHEAD | NONHEAD | ... | NONHEAD | HEAD | HEAD |
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|__:___|_(CBLKCNT)_|_________|_____|_________|__:___|____:_|
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|<----- a big pcluster (with CBLKCNT) ------>|<-- -->|
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a lcluster-sized pcluster (without CBLKCNT) ^
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If another HEAD follows a HEAD lcluster, there is no room to record CBLKCNT,
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but it's easy to know the size of such pcluster is 1 lcluster as well.
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Since Linux v6.1, each pcluster can be used for multiple variable-sized extents,
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therefore it can be used for compressed data deduplication.
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