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205 lines
12 KiB
Markdown
205 lines
12 KiB
Markdown
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---
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title: Jumping on the BTRFS hype wagon
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date: 2024-01-27
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tags: [linux]
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sources:
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- <https://wiki.archlinux.org/title/btrfs>
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- <https://docs.kernel.org/filesystems/btrfs.html>
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- <https://en.wikipedia.org/wiki/Btrfs>
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- <https://www.thegeekdiary.com/features-of-the-btrfs-filesystem/>
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---
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After a long time constantly hearing about BTRFS filesystem, I decided to make the jump, leaving EXT4 behind. And I
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have to say, I couldn't be happier.
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For those unaware, BTRFS is a B-tree based filesystem, which you can use as an alternative to EXT4, with some really
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cool new features, which I'll mention in the post here. In many ways, it is similar to ZFS, but it is meant for
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personal use, rather than being enterprise focused, and unlike with ZFS, there aren't any licensing controversies
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accompanying it.
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## Subvolumes
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First thing to mention (and for me probably the most important thing) about BTRFS is it's feature allowing you to
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create subvolumes.
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Volumes are sort of like partitions, however instead of being done on the device level, specified in a partition table
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with concrete start and end sectors, making it occupy a very specific, well, "partiton" of the drive, subvolumes are a
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feature of the filesystem, allowing you to split it up into individual portions, that all live on a single BTRFS
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partition.
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### Dynamic space
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This is really cool, because these subvolumes can act almost like plain folders within the BTRFS root, and that means
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they don't have to have a size specified. They will all simply share the single partition, and all of the subvolumes
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will have the same amount of free space as there is available on the entire partition.
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You can therefore really easily create separate subvolumes for your home (/home) and root (/), mount them individually,
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and pretty much treat them like regular partitions, but without having to make the decision about how to divide your
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disk space between them during installation.
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For me, this is a HUGE benefit, because I'm a major proponent for the split architecture, where your home and root (or
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at least root and some kind of persistent data partition) are separate. This is because it allows you to only wipe out
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one of them when reinstalling, without the need to copy-over potentially hundreds of gigabytes of data from a backup.
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In EXT4, it was always annoying to have to decide on how much space to allocate to each partition, because I knew that
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I could use the extra space for my data, but if I ever ran out of space in my root partition, it would pretty much mean
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I'm gonna have to reinstall, and re-partition, as there's really no good way to expand a partition without corrupting
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the one right below.
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This setup finally changed that, and I can keep my data separate and persistent across installations, without having to
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compromise on space for my root partition.
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{{< notice tip >}}
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While subvolumes are dynamic by default, it is actually possible to set a cap for the max size that subvolume can reach
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if you need to do so. This can be useful to prevent something growing unpredictably in size. This limit can later be
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easily increased if needed, making it far superior to regular partitions, which would need to be moved/recreated.
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{{< /notice >}}
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### Automatic compression
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Another great feature BTRFS subvolumes give you is the ability to specify different compression levels on each of your
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subvolumes. BTRFS allows you to pick from various compression algorithms, but the most common one which you'll probably
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want to use too is `zstd`. You can then a compression level 1-10, which will control how aggressive the compression
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will be.
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This is really nice, because you can set up a separate subvolume for your cache or static data files, to be compressed
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at high levels, which will cost some CPU time and slow down the read/write speeds to the data stored there, but at the
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benefit of greatly reducing the disk size, while keeping your root subvolume, which will be written to a lot at a low
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compression level (or even disable the compression there), and will therefore have a much quicker disk speeds.
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Because cache files usually aren't accessed that often, and contain a lot of data (like for example the pacman package
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cache, which will contain the older versions of packages you installed, to allow easily reverting), I find it really
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worth it to be able to create a highly compressed subvolume mounted on `/var/cache`. Additionally, I also have a pretty
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high compression level on my data subvolume, though since it does contain videos, I don't necessarily use the highest
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compression level there, to allow me to seamlessly watch them without disk buffering.
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## Snapshots
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Another really cool feature that BTRFS has is the ability to take instant snapshots of a volume, for great backups.
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This is possible because the snapshot create will essentially just be a link, pointing to the current state of the
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subvolume it targets, so the only thing that happens on the file-system side is basically a creation of that link,
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there's no copying done anywhere!
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### Technical explanation
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You can basically think of these as hard-links, pointing to the subvolume itself. Since BTRFS is a **copy-on-write**
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filesystem, rather than modifying the blocks affected (a single file can take up a lot of physical blocks), which is
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what EXT4 would do, it instead creates new blocks, where the data for that file is written to, and updating the file
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metadata, telling it that it should now use these new blocks.
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This is really nice, because when writing to the disk, you're gonna be writing a whole block at a time anyway, so
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instead of overwriting the existing old one, BTRFS will use a new one, leaving the old ones behind. So if a file is
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composed of a lot of blocks, only the blocks that actually changed will be copied, and BTRFS will store the information
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that a part of that file is now in some other physical blocks.
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(Not updating the original location also eliminates the risk of a partial update or data corruption during a power
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failure.)
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That means you can create hard-links that point to the original blocks, rather than the original files, and since BTRFS
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won't change those original blocks, but instead will copy the changes to new blocks, these hard-links remain unaffected
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by any new changes.
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In an EXT4 filesystem, is you have a hard-link, it will always be linked to the inode, representing the hard-linked
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file, and whenever the file is updated, it's the blocks specified by that inode that get updated, meaning you'll end up
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with it being modified both on the original (system) file, and in the hard-link pointing to it.
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This kind of hard-link behavior is also possible on BTRFS systems, however you can also hard-link in a way that doesn't
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update, and instead just holds the original blocks, so as the real system is changing, it's pretty much only the
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deltas/diffs that get stored, making the backup only take as much space, as the newly made changes since it was taken.
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Once a snapshot is deleted, the old blocks that aren't used in the primary volume anymore will be allowed to get
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overwritten, hence gaining that space back.
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### Backups at no cost
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Because of the way BTRFS handles snapshots, it therefore allows us to make backups which are essentially just the size
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of a single link, and are instant. They only get expensive as the original subvolume gets updated. This means it's
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really beneficial to set up an auto-snapshot routine with auto-rotation, and taking a lot of snapshots. For example,
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this is mine:
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- 8 hourly snapshots (taken using cron, once we reach 9th snapshot, the oldest one is deleted)
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- 4 quaterly snapshots (taken using cron, every 15 minutes, except on the full hour, as that's covered by hourly)
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- 8 daily snapshots (taken by anacron, every day)
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- 4 weekly snapshots (taken by anacron)
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- 3 monthly snapshots (taken by anacron)
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Notice just how many hourly and quaterly snapshots I'm able to take, literally I make a snapshot of my system every 15
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minutes, and i don't even notice!! It comes at no performance cost, not high CPU usage as the files are being copied
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over, all perfectly seamless.
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To achieve this, I made a bash script that can handle this auto-rotation and snapshot taking, which I'm just calling
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from cron/anacron. If you're interested, you can find it in my
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[dotfiles](https://github.com/ItsDrike/dotfiles/blob/main/root/usr/local/bin/btrfs-backup).
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The only backups that I do see some actual space cost from are the monthly ones, which do get out of sync eventually,
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and so a lot of files are indeed different there.
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### Stupid simple restore
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Snapshots of subvolumes themselves are just another subvolumes, and if you need to restore a snapshot, all you need to
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do is change the path where your main subvolume is pointing to, switching it to that backup, and done, you've restored
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from a snapshot.
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This is super cool, because you can for example take some snapshots during your installation, and if you want to
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reinstall, you can just revert back to those.
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Another really useful thing this allows is to take a snapshot before installing some big app that you really only need
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to use once, and then revert back, making sure that no residual files from that app will be left behind. Having
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quaterly snapshots is especially useful here, since you may install something you think you'll want to be using for a
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long time, only to realize it's actually not all that good.
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{{< notice warning >}}
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With all this great talk about snapshots, you may think that once set up, you'll never need to do those tedious full
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system backups ever again. Well, that's not true. While snapshots really are amazing, remember that they still all live
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on a single partition in a single drive. If this drive were to fail, all of your data on it, including the snapshots
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might get corrupted.
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For that reason, it is very important that you don't just blindly replace your full backup strategies here.
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{{< /notice >}}
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## Multiple system versions
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Another amazing thing you can set up is creating automated boot records for every snapshot, allowing you to boot into
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an older version of your system completely seamlessly.
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All you need to do to make this work is changing the kernel arguments and defining a different subvolume as your
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root, specifically, the subvolume containing the snapshot you want to boot into.
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Not only is this really useful for getting into an older system version by booting into snapshots, you can actually use
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non-snapshot subvolumes too. That means you could easily even keep multiple distributions on a single BTRFS partition.
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(With dynamic space, shared for each system.)
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## Built-in RAID
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BTRFS also has a built-in support for RAID-0, RAID-1 and RAID-10 levels.
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This type of RAID will ensure that for every block, there are "x" amount of copies. For RAID-1 for example, BTRFS
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just stores two copies of everything on two different devices.
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Unlike a simple `mdadm` software raid, BTRFS supports self-healing redundant arrays and online balancing, as BTRFS
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maintains CRC's for all metadata and data so everything is checksummed to preserve the integrity of data against
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corruption. With RAID-1 or RAID-10 configuration, if the checksum fails on the first read, data is pulled off from
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another copy.
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## Great SSD performance
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Another benefit of BTRFS is it's automatic detection of solid state drives (SSDs). If an SSD is detected, BTRFS will
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turn off all optimization for rotational media (i.e. optimizations to reduce seeking, by storing related data close
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together on spinning drives, which isn't important with SSDs). Alongside that, there's also TRIM support, which tells
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the SSD which blocks are no longer needed and are available to be written over.
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These will improve reading/writing speed, since the useless CPU intensive operations for spinning drives are disabled,
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and it can also extend your SSD's lifespan, due to that TRIM support.
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## Efficient storage for small files
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All Linux filesystems address storage in blocks. These blocks have some pre-defined size, like say 4KB. That means
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storing a file that's smaller than this size will result in the block not being completely utilized. Using a smaller
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block size isn't a good option either, because it means having to store more metadata (there's more blocks to keep
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track of).
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On BTRFS, for very small files, the data will actually be stored in the metadata, without taking up any of the data
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blocks!
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