From patchwork Tue Apr 4 14:08:27 2023 Content-Type: text/plain; charset="utf-8" MIME-Version: 1.0 Content-Transfer-Encoding: 7bit X-Patchwork-Submitter: Sergei Shtepa X-Patchwork-Id: 13202179 Return-Path: X-Spam-Checker-Version: SpamAssassin 3.4.0 (2014-02-07) on aws-us-west-2-korg-lkml-1.web.codeaurora.org Received: from vger.kernel.org (vger.kernel.org [23.128.96.18]) by smtp.lore.kernel.org (Postfix) with ESMTP id 161A0C77B6E for ; Wed, 5 Apr 2023 16:16:21 +0000 (UTC) Received: (majordomo@vger.kernel.org) by vger.kernel.org via listexpand id S232991AbjDEQQT (ORCPT ); Wed, 5 Apr 2023 12:16:19 -0400 Received: from lindbergh.monkeyblade.net ([23.128.96.19]:44230 "EHLO lindbergh.monkeyblade.net" rhost-flags-OK-OK-OK-OK) by vger.kernel.org with ESMTP id S230059AbjDEQP5 (ORCPT ); Wed, 5 Apr 2023 12:15:57 -0400 Received: from mx2.veeam.com (mx2.veeam.com [64.129.123.6]) by lindbergh.monkeyblade.net (Postfix) with ESMTPS id 30A987ECC; Wed, 5 Apr 2023 09:15:13 -0700 (PDT) Received: from mx1.veeam.com (mx1.veeam.com [172.18.34.147]) (using TLSv1.2 with cipher ECDHE-RSA-AES256-GCM-SHA384 (256/256 bits)) (No client certificate requested) by mx2.veeam.com (Postfix) with ESMTPS id 69A13411C6; Wed, 5 Apr 2023 12:13:42 -0400 (EDT) DKIM-Signature: v=1; a=rsa-sha256; c=relaxed/relaxed; d=veeam.com; s=mx2-2022; t=1680711222; bh=vI25glQHCKQl7a1zjzkrzoHXKxdZUuMwIgZtjSxTbJw=; h=From:To:CC:Subject:Date:In-Reply-To:References:From; b=nFlhpqtpYB21tDmChegSoSKngtgm1BJNb/Xk63WwbFXUitFDzNDcD/F0cB4r4A8oV qQnwY+2RfZWJMsdm8xXTJgbOerebZKE+DOp6Q5KMANO67VLGB4YrReOU6DP+FKhwhu 095IYv2+P4xCuOB1aawe7cybi93kGSn/NtXnW2RQrdWGFTvkEIb3Gcmt9CSbQebRKM 079JoZu2wofXuRFJh+JUROWmok6e72DBcoLCIThNFUSNVx6XmlTdXvoHp7AV15d+jv V2MANM0hRph5Uc24z7JRxnyxWeaWY2BcOd1xkCXcULSSmzRDNlGyysZBbW+pZlfTz6 ERmRCV3a/cCBA== Received: from mx4.veeam.com (mx4.amust.local [172.31.224.40]) (using TLSv1.2 with cipher ECDHE-RSA-AES256-GCM-SHA384 (256/256 bits)) (No client certificate requested) by mx1.veeam.com (Postfix) with ESMTPS id 56437423F1; Wed, 5 Apr 2023 06:09:16 -0400 (EDT) Received: from mail.veeam.com (prgmbx01.amust.local [172.24.128.102]) (using TLSv1.2 with cipher ECDHE-RSA-AES256-GCM-SHA384 (256/256 bits)) (No client certificate requested) by mx4.veeam.com (Postfix) with ESMTPS id 85C267D642; Tue, 4 Apr 2023 17:09:04 +0300 (MSK) Received: from ssh-deb10-ssd-vb.amust.local (172.24.10.107) by prgmbx01.amust.local (172.24.128.102) with Microsoft SMTP Server (version=TLS1_2, cipher=TLS_ECDHE_RSA_WITH_AES_256_GCM_SHA384) id 15.2.1118.26; Tue, 4 Apr 2023 16:09:01 +0200 From: Sergei Shtepa To: , , , CC: , , , , , , , , , , , , Subject: [PATCH v3 03/11] documentation: Block Devices Snapshots Module Date: Tue, 4 Apr 2023 16:08:27 +0200 Message-ID: <20230404140835.25166-4-sergei.shtepa@veeam.com> X-Mailer: git-send-email 2.20.1 In-Reply-To: <20230404140835.25166-1-sergei.shtepa@veeam.com> References: <20230404140835.25166-1-sergei.shtepa@veeam.com> MIME-Version: 1.0 X-Originating-IP: [172.24.10.107] X-ClientProxiedBy: prgmbx02.amust.local (172.24.128.103) To prgmbx01.amust.local (172.24.128.102) X-EsetResult: clean, is OK X-EsetId: 37303A2924031554657367 X-Veeam-MMEX: True Precedence: bulk List-ID: X-Mailing-List: linux-fsdevel@vger.kernel.org The document contains: * Describes the purpose of the mechanism * 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 --- Documentation/block/blksnap.rst | 345 ++++++++++++++++++++++++++++++++ Documentation/block/index.rst | 1 + MAINTAINERS | 6 + 3 files changed, 352 insertions(+) create mode 100644 Documentation/block/blksnap.rst diff --git a/Documentation/block/blksnap.rst b/Documentation/block/blksnap.rst new file mode 100644 index 000000000000..7752f33809bb --- /dev/null +++ b/Documentation/block/blksnap.rst @@ -0,0 +1,345 @@ +.. 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 file system level. However, both +of these options have flaws 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 versatility of use +- Reliability +- Minimal consumption of system resources during backup +- Minimal time required for recovery or replication of the entire system + +Therefore, the features of the blksnap module are: + +- 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. +Having 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 versatility 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 block +device range. A range of sectors can be allocated on any block device +immediately before creating a snapshot in individual files on the file +system. In addition, the size of the difference storage can be increased +after the snapshot is created by adding new sector ranges on block devices. +Sector ranges can be allocated on any block devices of the system, including +those on which the snapshot was created. A shared difference storage for +all images of snapshot block devices allows to optimize the use of disk space. + +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. An array 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 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 a write request is handled, the execution of this I/O unit will be +delayed until the overwritten chunks are copied to the difference storage. +But if, when handling a write I/O unit, it turns out that the recorded range +of sectors has already been copied to the difference storage, then the I/O +unit is simply passed. + +This algorithm allows to efficiently perform backups of systems that run +Round Robin Database. 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 file system. 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 is a pool of disk space areas, and it is shared with +all block devices in the snapshot. Therefore, there is no need to divide +the difference storage area between block devices, and the difference storage +itself can be located on different block devices. + +There is no need to allocate a large disk space immediately before creating +a snapshot. Even while the snapshot is being held, the difference storage +can be expanded. It is enough to have free space on the file system. + +Areas of disk space can be allocated on the file system using fallocate(), +and the file location can be requested using Fiemap Ioctl or Fibmap Ioctl. +Unfortunately, not all file systems support these mechanisms, but the most +common XFS, EXT4 and BTRFS file systems support it. BTRFS requires additional +conversion of virtual offsets to physical ones. + +While holding the snapshot, the user process can poll the status of the module. +When free space in the difference storage is reduced to a threshold value, the +module generates an event about it. The user process can prepare a new area +and pass it to the module to expand the difference storage. The threshold +value is determined as half of the value of the ``diff_storage_minimum`` +module parameter. + +If free space in the difference storage runs out, an event 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. + +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 file system 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. ``blk_snap_ioctl_snapshot_create`` initiates the snapshot creation process. +3. ``blk_snap_ioctl_snapshot_append_storage`` add the range of blocks to + difference storage. +4. ``blk_snap_ioctl_snapshot_take`` creates block devices of block device + snapshot images. +5. ``blk_snap_ioctl_snapshot_collect`` collect all created snapshots. +6. ``blk_snap_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. +7. ``blk_snap_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 +the list of commands, enter the ``blksnap --help`` command. The ``blksnap + --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 file system of +the mounted snapshot image and files in the archive on a file system 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 diff --git a/Documentation/block/index.rst b/Documentation/block/index.rst index e56d89db7b85..34937516c865 100644 --- a/Documentation/block/index.rst +++ b/Documentation/block/index.rst @@ -11,6 +11,7 @@ Block biovecs blk-mq blkfilter + blksnap cmdline-partition data-integrity deadline-iosched diff --git a/MAINTAINERS b/MAINTAINERS index fb6b7abe83e1..4bdb30369a74 100644 --- a/MAINTAINERS +++ b/MAINTAINERS @@ -3580,6 +3580,12 @@ F: block/blk-filter.c F: include/linux/blk-filter.h F: include/uapi/linux/blk-filter.h +BLOCK DEVICE SNAPSHOTS MODULE +M: Sergei Shtepa +L: linux-block@vger.kernel.org +S: Supported +F: Documentation/block/blksnap.rst + BLOCK LAYER M: Jens Axboe L: linux-block@vger.kernel.org