new file mode 100644
@@ -0,0 +1,66 @@
+.. SPDX-License-Identifier: GPL-2.0
+
+================================
+Block Device Filtering Mechanism
+================================
+
+The block device filtering mechanism provides the ability to attach block
+device filters. Block device filters allow performing additional processing
+for I/O units.
+
+Introduction
+============
+
+The idea of handling I/O units on block devices is not new. Back in the
+2.6 kernel, there was an undocumented possibility of handling I/O units
+by substituting the make_request_fn() function, which belonged to the
+request_queue structure. But none of the in-tree kernel modules used this
+feature, and it was eliminated in the 5.10 kernel.
+
+The block device filtering mechanism returns the ability to handle I/O units.
+It is possible to safely attach a filter to a block device "on the fly" without
+changing the structure of the block device's stack.
+
+It supports attaching one filter to one block device, because there is only
+one filter implementation in the kernel yet.
+See Documentation/block/blksnap.rst.
+
+Design
+======
+
+The block device filtering mechanism provides registration and unregistration
+for filter operations. The struct blkfilter_operations contains a pointer to
+the callback functions for the filter. After registering the filter operations,
+the filter can be managed using block device ioctls BLKFILTER_ATTACH,
+BLKFILTER_DETACH and BLKFILTER_CTL.
+
+When the filter is attached, the callback function is called for each I/O unit
+for a block device, providing I/O unit filtering. Depending on the result of
+filtering the I/O unit, it can either be passed for subsequent processing by
+the block layer, or skipped.
+
+The filter can be implemented as a loadable module. In this case, the filter
+module cannot be unloaded while the filter is attached to at least one of the
+block devices.
+
+Interface description
+=====================
+
+The ioctl BLKFILTER_ATTACH allows user-space programs to attach a block device
+filter to a block device. The ioctl BLKFILTER_DETACH allows user-space programs
+to detach it. Both ioctls use &struct blkfilter_name. The ioctl BLKFILTER_CTL
+allows user-space programs to send a filter-specific command. It use &struct
+blkfilter_ctl.
+
+.. kernel-doc:: include/uapi/linux/blk-filter.h
+
+To register in the system, the filter uses the &struct blkfilter_operations,
+which contains callback functions, unique filter name and module owner. When
+attaching a filter to a block device, the filter creates a &struct blkfilter.
+The pointer to the &struct blkfilter allows the filter to determine for which
+block device the callback functions are being called.
+
+.. kernel-doc:: include/linux/blk-filter.h
+
+.. kernel-doc:: block/blk-filter.c
+ :export:
new file mode 100644
@@ -0,0 +1,351 @@
+.. SPDX-License-Identifier: GPL-2.0
+
+========================================
+Block Devices Snapshots Module (blksnap)
+========================================
+
+Introduction
+============
+
+At first glance, there is no novelty in the idea of creating snapshots for
+block devices. The Linux kernel already has mechanisms for creating snapshots.
+Device Mapper includes dm-snap, which allows to create snapshots of block
+devices. BTRFS supports snapshots at the filesystem level. However, both of
+these options have specificities that do not allow to use them as a universal
+tool for creating backups.
+
+The main properties that a backup tool should have are:
+
+- Simplicity and universality of use
+- Reliability
+- Minimal consumption of system resources during backup
+- Minimal time required for recovery or replication of the entire system
+
+Taking above properties into account, blksnap module features:
+
+- Change tracker
+- Snapshots at the block device level
+- Dynamic allocation of space for storing differences
+- Snapshot overflow resistance
+- Coherent snapshot of multiple block devices
+
+Features
+========
+
+Change tracker
+--------------
+
+The change tracker allows to determine which blocks were changed during the
+time between the last snapshot created and any of the previous snapshots.
+With a map of changes, it is enough to copy only the changed blocks, and no
+need to reread the entire block device completely. The change tracker allows
+to implement the logic of both incremental and differential backups.
+Incremental backup is critical for large file repositories whose size can be
+hundreds of terabytes and whose full backup time can take more than a day.
+On such servers, the use of backup tools without a change tracker becomes
+practically impossible.
+
+Snapshot at the block device level
+----------------------------------
+
+A snapshot at the block device level allows to simplify the backup algorithm
+and reduce consumption of system resources. It also allows to perform linear
+reading of disk space directly, which allows to achieve maximum reading speed
+with minimal use of processor time. At the same time, the universality of
+creating snapshots for any block device is achieved, regardless of the file
+system located on it. The exceptions are BTRFS, ZFS and cluster file systems.
+
+Dynamic allocation of storage space for differences
+---------------------------------------------------
+
+To store differences, the module does not require a pre-reserved space on
+filesystem. The space for storing differences can be allocated in file in any
+filesystem. In addition, the size of the difference storage can be increased
+after the snapshot is created, but only for a filesystem that supports
+fallocate. A shared difference storage for all images of snapshot block devices
+allows to optimize the use of storage space. However, there is one limitation.
+A snapshot cannot be taken from a block device on which the difference storage
+is located.
+
+Snapshot overflow resistance
+----------------------------
+
+To create images of snapshots of block devices, the module stores blocks
+of the original block device that have been changed since the snapshot
+was taken. To do this, the module handles write requests and reads blocks
+that need to be overwritten. This algorithm guarantees safety of the data
+of the original block device in the event of an overflow of the snapshot,
+and even in the case of unpredictable critical errors. If a problem occurs
+during backup, the difference storage is released, the snapshot is closed,
+no backup is created, but the server continues to work.
+
+Coherent snapshot of multiple block devices
+-------------------------------------------
+
+A snapshot is created simultaneously for all block devices for which a backup
+is being created, ensuring their coherent state.
+
+
+Algorithms
+==========
+
+Overview
+--------
+
+The blksnap module is a block-level filter. It handles all write I/O units.
+The filter is attached to the block device when the snapshot is created
+for the first time. The change tracker marks all overwritten blocks.
+Information about the history of changes on the block device is available
+while holding the snapshot. The module reads the blocks that need to be
+overwritten and stores them in the difference storage. When reading from
+a snapshot image, reading is performed either from the original device or
+from the difference storage.
+
+Change tracking
+---------------
+
+A change tracker map is created for each block device. One byte of this map
+corresponds to one block. The block size is set by the
+``tracking_block_minimum_shift`` and ``tracking_block_maximum_count``
+module parameters. The ``tracking_block_minimum_shift`` parameter limits
+the minimum block size for tracking, while ``tracking_block_maximum_count``
+defines the maximum allowed number of blocks. The size of the change tracker
+block is determined depending on the size of the block device when adding
+a tracking device, that is, when the snapshot is taken for the first time.
+The block size must be a power of two. The ``tracking_block_maximum_shift``
+module parameter allows to limit the maximum block size for tracking. If the
+block size reaches the allowable limit, the number of blocks will exceed the
+``tracking_block_maximum_count`` parameter.
+
+The byte of the change map stores a number from 0 to 255. This is the
+snapshot number, since the creation of which there have been changes in
+the block. Each time a snapshot is created, the number of the current
+snapshot is increased by one. This number is written to the cell of the
+change map when writing to the block. Thus, knowing the number of one of
+the previous snapshots and the number of the last snapshot, one can determine
+from the change map which blocks have been changed. When the number of the
+current change reaches the maximum allowed value for the map of 255, at the
+time when the next snapshot is created, the map of changes is reset to zero,
+and the number of the current snapshot is assigned the value 1. The change
+tracker is reset, and a new UUID is generated - a unique identifier of the
+snapshot generation. The snapshot generation identifier allows to identify
+that a change tracking reset has been performed.
+
+The change map has two copies. One copy is active, it tracks the current
+changes on the block device. The second copy is available for reading
+while the snapshot is being held, and contains the history up to the moment
+the snapshot is taken. Copies are synchronized at the moment of snapshot
+creation. After the snapshot is released, a second copy of the map is not
+needed, but it is not released, so as not to allocate memory for it again
+the next time the snapshot is created.
+
+Copy on write
+-------------
+
+Data is copied in blocks, or rather in chunks. The term "chunk" is used to
+avoid confusion with change tracker blocks and I/O blocks. In addition,
+the "chunk" in the blksnap module means about the same as the "chunk" in
+the dm-snap module.
+
+The size of the chunk is determined by the ``chunk_minimum_shift`` and
+``chunk_maximum_count`` module parameters. The ``chunk_minimum_shift``
+parameter limits the minimum size of the chunk, while ``chunk_maximum_count``
+defines the maximum allowed number of chunks. The size of the chunk is
+determined depending on the size of the block device at the time of taking the
+snapshot. The size of the chunk must be a power of two. The module parameter
+``chunk_maximum_shift`` allows to limit the maximum chunk size. If the chunk
+size reaches the allowable limit, the number of chunks will exceed the
+``chunk_maximum_count`` parameter.
+
+One chunk is described by the ``struct chunk`` structure. A map of structures
+is created for each block device. The structure contains all the necessary
+information to copy the chunks data from the original block device to the
+difference storage. This information allows to describe the snapshot image.
+A semaphore is located in the structure, which allows synchronization of threads
+accessing the chunk.
+
+The block level in Linux has a feature. If a read I/O unit was sent, and a
+write I/O unit was sent after it, then a write can be performed first, and only
+then a read. Therefore, the copy-on-write algorithm is executed synchronously.
+If the write request is handled, the execution of this I/O unit will be delayed
+until the overwritten chunks are read from the original device for later
+storing to the difference store. But if, when handling a write I/O unit, it
+turns out that the written range of sectors has already been prepared for
+storing to the difference storage, then the I/O unit is simply passed.
+
+This algorithm makes it possible to efficiently perform backup even systems
+with a Round-Robin databases. Such databases can be overwritten several times
+during the system backup. Of course, the value of a backup of the RRD monitoring
+system data can be questioned. However, it is often a task to make a backup
+of the entire enterprise infrastructure in order to restore or replicate it
+entirely in case of problems.
+
+There is also a flaw in the algorithm. When overwriting at least one sector,
+an entire chunk is copied. Thus, a situation of rapid filling of the difference
+storage when writing data to a block device in small portions in random order
+is possible. This situation is possible in case of strong fragmentation of
+data on the filesystem. But it must be borne in mind that with such data
+fragmentation, performance of systems usually degrades greatly. So, this
+problem does not occur on real servers, although it can easily be created
+by artificial tests.
+
+Difference storage
+------------------
+
+The difference storage can be a block device or it can be a file on a
+filesystem. Using a block device allows to achieve slightly higher performance,
+but in this case, the block device is used by the kernel module exclusively.
+Usually the disk space is marked up so that there is no available free space
+for backup purposes. Using a file allows to place the difference storage on a
+filesystem.
+
+The difference storage can be expanded already while the snapshot is being held,
+but only if the filesystem supports fallocate(). If the free space in the
+difference storage remains less than half of the value of the module parameter
+``diff_storage_minimum``, then the kernel module can expand the difference
+storage file within the specified limits. This limit is set when creating a
+snapshot.
+
+If free space in the difference storage runs out, an event to user land is
+generated about the overflow of the snapshot. Such a snapshot is considered
+corrupted, and read I/O units to snapshot images will be terminated with an
+error code. The difference storage stores outdated data required for snapshot
+images, so when the snapshot is overflowed, the backup process is interrupted,
+but the system maintains its operability without data loss.
+
+The difference storage has a limitation. The device cannot be added to the
+snapshot where the difference storage is located. In this case, the difference
+storage can be located in virtual memory, which consists of RAM and a swap
+partition (or file). To do this, it is enough to use a file in /dev/shm, or a
+new tmpfs filesystem can be created for this purpose. Obviously, this variant
+can be useful if the system has a lot of RAM or a large swap. The good news is
+that the modern Linux kernel allows to increase the size of the swap file "on
+the fly" without changing the system configuration.
+
+A regular file or a block device file for the difference storage must be opened
+with the O_EXCL flag. If an unnamed file with the O_TMPFILE flag is created,
+then such a file will be automatically released when the snapshot is destroyed.
+In addition, the use of an unnamed temporary file ensures that no one can open
+this file and read its contents.
+
+Performing I/O for a snapshot image
+-----------------------------------
+
+To read snapshot data, when taking a snapshot, block devices of snapshot images
+are created. The snapshot image block devices support the write operation.
+This allows to perform additional data preparation on the filesystem before
+creating a backup.
+
+To process the I/O unit, clones of the I/O unit are created, which redirect
+the I/O unit either to the original block device or to the difference storage.
+When processing of cloned I/O units is completed, the original I/O unit is
+marked as completed too.
+
+An I/O unit can be partially processed without accessing to block devices if
+the I/O unit refers to a chunk that is in the queue for storing to the
+difference storage. In this case, the data is read or written in a buffer in
+memory.
+
+If, when processing the write I/O unit, it turns out that the data of the
+referred chunk has not yet been stored to the difference storage or has not
+even been read from the original device, then an I/O unit to read data from the
+original device is initiated beforehand. After the reading from original device
+is performed, their data from the I/O unit is partially overwritten directly in
+the buffer of the chunk in memory, and the chunk is scheduled to be saved to the
+difference storage.
+
+How to use
+==========
+
+Depending on the needs and the selected license, you can choose different
+options for managing the module:
+
+- Using ioctl directly
+- Using a static C++ library
+- Using the blksnap console tool
+
+Using a BLKFILTER_CTL for block device
+--------------------------------------
+
+BLKFILTER_CTL allows to send a filter-specific command to the filter on block
+device and get the result of its execution. The module provides the
+``include/uapi/blksnap.h`` header file with a description of the commands and
+their data structures.
+
+1. ``BLKFILTER_CTL_BLKSNAP_CBTINFO`` allows to get information from the
+ change tracker.
+2. ``BLKFILTER_CTL_BLKSNAP_CBTMAP`` reads the change tracker table. If a write
+ operation was performed for the snapshot, then the change tracker takes this
+ into account. Therefore, it is necessary to receive tracker data after write
+ operations have been completed.
+3. ``BLKFILTER_CTL_BLKSNAP_CBTDIRTY`` mark blocks as changed in the change
+ tracker table. This is necessary if post-processing is performed after the
+ backup is created, which changes the backup blocks.
+4. ``BLKFILTER_CTL_BLKSNAP_SNAPSHOTADD`` adds a block device to the snapshot.
+5. ``BLKFILTER_CTL_BLKSNAP_SNAPSHOTINFO`` allows to get the name of the snapshot
+ image block device and the presence of an error.
+
+Using ioctl
+-----------
+
+Using a BLKFILTER_CTL ioctl does not allow to fully implement the management of
+the blksnap module. A control file ``blksnap-control`` is created to manage
+snapshots. The control commands are also described in the file
+``include/uapi/blksnap.h``.
+
+1. ``BLKSNAP_IOCTL_VERSION`` get the version number.
+2. ``BLKSNAP_IOCTL_SNAPSHOT_CREATE`` initiates a snapshot and prepares a
+ difference storage.
+3. ``BLKSNAP_IOCTL_SNAPSHOT_TAKE`` creates block devices of block device
+ snapshot images.
+4. ``BLKSNAP_IOCTL_SNAPSHOT_COLLECT`` collect all created snapshots.
+5. ``BLKSNAP_IOCTL_SNAPSHOT_WAIT_EVENT`` allows to track the status of
+ snapshots and receive events about the requirement to expand the difference
+ storage or about snapshot overflow.
+6. ``BLKSNAP_IOCTL_SNAPSHOT_DESTROY`` releases the snapshot.
+
+Static C++ library
+------------------
+
+The [#userspace_libs]_ library was created primarily to simplify creation of
+tests in C++, and it is also a good example of using the module interface.
+When creating applications, direct use of control calls is preferable.
+However, the library can be used in an application with a GPL-2+ license,
+or a library with an LGPL-2+ license can be created, with which even a
+proprietary application can be dynamically linked.
+
+blksnap console tool
+--------------------
+
+The blksnap [#userspace_tools]_ console tool allows to control the module from
+the command line. The tool contains detailed built-in help. To get list of
+commands with usage description, see ``blksnap --help`` command. The ``blksnap
+<command name> --help`` command allows to get detailed information about the
+parameters of each command call. This option may be convenient when creating
+proprietary software, as it allows not to compile with the open source code.
+At the same time, the blksnap tool can be used for creating backup scripts.
+For example, rsync can be called to synchronize files on the filesystem of
+the mounted snapshot image and files in the archive on a filesystem that
+supports compression.
+
+Tests
+-----
+
+A set of tests was created for regression testing [#userspace_tests]_.
+Tests with simple algorithms that use the ``blksnap`` console tool to
+control the module are written in Bash. More complex testing algorithms
+are implemented in C++.
+
+References
+==========
+
+.. [#userspace_libs] https://github.com/veeam/blksnap/tree/stable-v2.0/lib
+
+.. [#userspace_tools] https://github.com/veeam/blksnap/tree/stable-v2.0/tools
+
+.. [#userspace_tests] https://github.com/veeam/blksnap/tree/stable-v2.0/tests
+
+Module interface description
+============================
+
+.. kernel-doc:: include/uapi/linux/blksnap.h
@@ -10,6 +10,8 @@ Block
bfq-iosched
biovecs
blk-mq
+ blkfilter
+ blksnap
cmdline-partition
data-integrity
deadline-iosched
The blkfilter.rst document contains: * Describes the purpose of the mechanism * A little historical background on the capabilities of handling I/O units of the Linux kernel * Brief description of the design * Reference to interface description The blksnap.rst document contains: * Describes the purpose of the block device snapshots * Description of features * Description of algorithms * Recommendations about using the module from the user-space side * Reference to module interface description Signed-off-by: Sergei Shtepa <sergei.shtepa@linux.dev> --- Documentation/block/blkfilter.rst | 66 ++++++ Documentation/block/blksnap.rst | 351 ++++++++++++++++++++++++++++++ Documentation/block/index.rst | 2 + 3 files changed, 419 insertions(+) create mode 100644 Documentation/block/blkfilter.rst create mode 100644 Documentation/block/blksnap.rst