Okay, I love Linux. But I always surprised that I can love Linux ever more everyday. The possibility is basically endless!

I asked about raid0 last week and got a lot of helpful answers. However, this answer from d3Xter really helped me figures how I actually want to configure my system. I decided to buy 2x500GB HDD and 120GB NVME SSD. It’s cheap, very cheap. Like $15 total. If there is anything wrong with them, I lost nothing. But boy did I get surprised. I tested BG3, a game that requires SSD to perform well and I see no difference between my old SSD and my new setup. It loads as fast (well, maybe 10-15s slower, but who cares?), and I do not need to wait for the textures to load, at all. Boot time is amazing. I notice no difference at all between this HDD and my last SSD setup. Which is insane!

But the installation is confusing as hell. I write this pseudo-guide for anyone intersted.

FIRST: DO NOT STORE ANY DATA IN THIS SETUP FOR ANYTHING REMOTE TO IMPORTANT!

I favor performance for the cheapest possible above all else. Unless you want to buy 4 HDD to get raid10, do not store anything other than games and your apps on it. Do not use raid5 in this setup, it sucks.

Second: Get yourself an Arch live USB stick with at least 8GB (4 might works, but smallest one I have is 8GB). I think you can use it on other distro, but Arch is the easiest if you want to install IT on the bcache drive. And make sure you booted into UEFI by typing:

ls /sys/firmware/efi/efivars/

Third: Installing bcache. After you have internet on your live system, remount your live iso so we can use the AUR.

mount -o remount,size=8G /run/archiso/cowspace

Then, install base-devel and git

pacman -S base-devel git --ignore linux

If you have slow internet, you can go to 2nd tty by pressing ctrl + alt + f2 and login as root there to do the next step, otherwise wait for the process to finish. We need to setup a user since makepkg wont run on root. So, type:

useradd -m -G wheel user && passwd user and set your password Then we need the user to able to act as superuser. So, we edit visudo and add this line at the bottom: user ALL=(ALL:ALL)ALL save it and press ctrl + alt + f3, login as user you just set. Clone the bcache-tools AUR repo: git clone https://aur.archlinux.org/bcache-tools.git && cd bcache-tools

If you want you can inspect the PKGBUILD, but we will proceed to make it, type:

makepkg -sri

Once it is done, it will throw error about vmliuz is not found, but the package itself is installed, you just need to tell the kernel to load it. We can achieve that by executing:

sudo modprobe bcache && sudo partprobe

Fouth: Configuring the bcache, btrfs, and raid0 List your drive with lsblk identify your HDD and your SSD. Let’s say in this instance, we have /dev/sda and /dev/sdb as our HDD and /dev/nvme0n1 as our SSD. I use cfdisk to partition my drive, but you can use whatever you want. I make one partition for both HDD, sda1 and sdb1, and make 3 partitions for my SSD. DO NOT FORMATI IT YET. /dev/sda1 : 500 GB HDD with 500GB partition /dev/sdb1 : same as before /dev/nvme0n1p1 : 118G SSD partition as the cache /dev/nvme0n1p2 : 1G partition as /boot. Even if you have one kernel, do not make a /boot partition less than 1G. I knew it in hard way. /dev/nvme0n1p3 : 200M partition as /boot/efi. Same as before, better safe than sorry. YOU NEED TO HAVE SEPARATE BOOT AND EFI PARTITION, OTHERWISE YOU WILL HAVE AN UNBOOTABLE SYSTEM!

Okay, now we configure our raid.

make-bcache -B /dev/sda1 /dev/sdb1

This command will make a partition (?) called bcache0 and bcache1 under both /dev/sdb and /dev/sda if you use

lsblk

Now, we make raid out of those two.

mkfs.btrfs -L ARCHACHED -d raid0 /dev/bcache0 /dev/bcache1

Then the cache.

make-bcache -C /dev/nvme0n1p1

We can register the cache for our raid setup by its cset.uuid. To know what is the uuid, we can use this command.

bcache-super-show /dev/nvme0n1p1 |grep cset.uuid

Example of the output is:

cset.uuid fc3aac3b-9663-4067-88af-c5066a6c661b

From that, we can register it by using this command:

echo fc3aac3b-9663-4067-88af-c5066a6c661b > /sys/block/bcache0/bcache/attach

echo fc3aac3b-9663-4067-88af-c5066a6c661b > /sys/block/bcache1/bcache/attach

Done! If you lsblk now, you can see that there is bcache0 and bcache1 under the nvme0n1p1 partition.

Now, we can configure our boot partition.

mkfs.ext4 /dev/nvme0n1p2 (Remember, this is the 1G partition)

mkfs.vfat -F 32 /dev/nvme0n1p3 (Remember, this is the 200M partition)

We can then mount all of those drive to install Arch.

mount /dev/bcache0 /mnt

btrfs subvolume create /mnt/root

btrfs subvolume create /mnt/var (optional)

btrfs subvolume create /mnt/home (optional)

umount /mnt

mount /dev/bcache0 -o subvol=root,compress=lzo /mnt/

mount --mkdir /dev/bcache0 -o subvol=home,compress=lzo /mnt/home

mount --mkdir /dev/bcache0 -o subvol=var,compress=lzo /mnt/var

mount --mkdir /dev/nvme0n1p2 /mnt/boot

mount --mkdir /dev/nvme0n1p3 /mnt/boot/efi

Fifth: Install Arch Follow arch wiki, lol.

Last: bcache-tools, mkinitcpio, and grub. Go back to tty3, the user one. And copy the bcache-tools package to your newly installed /mnt

sudo cp bcache-tools-1.1-1-x86_64.pkg.tar.zst /mnt

Then go back tty1 and install it on you arch-chroot.

pacman -U bcache-tools-1.1-1-x86_64.pkg.tar.zst

Now, we configure the mkinitcpio. Edit your mkinitcpio by using you editor of choice. And add bcache in in MODULES so it looks like this:

MODULES=(bcache)

And in HOOKS, add it after block and before filesystem. Example:

HOOKS=(base udev block bcache flesystem)

Make your initcpio by executing this command:

mkinitcpio -p linux

Grub is the last. Install it as usual. Just make sure you did the partition right, as mentioned before.

That’s it. You just install Arch Linux on a bcache system. It’s complicated, and headache inducing for sure, but I assure you it is totally worth that pain.

Note: If you have problem after you reboot, and want to arch-chroot, you need to install bcache-tools again. If you want to reformat anything and it shows the device as busy after you did the partprobe, you need to tell the kernel to stop any activity to the drive. In this example the sda is the one you want to edit.

echo 1 > /sys/block/sda/sda1/bcache/stop

Now, if you accidentally execute the command, you can use partprobe again to show it up.

Reference: https://wiki.archlinux.org/title/bcache https://wiki.archlinux.org/title/btrfs https://gist.github.com/HardenedArray/4c1492f537d9785e19406eb5cd991735 https://archive.kernel.org/oldwiki/btrfs.wiki.kernel.org/index.php/Using_Btrfs_with_Multiple_Devices.html

  • FuzzChef@feddit.de
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    1 year ago

    I can’t quite figure out what would be the use cases where bcache would excel, except for hdds without cache or systems with very limited ram. Can you help me out with that?

    • Max-P@lemmy.max-p.me
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      1 year ago

      Basically the idea is that if you have a lot of data, HDDs have much bigger capacities for the price, whereas large SSDs can be expensive. SSDs have gotten cheap, but you can get used enterprise drives on eBay with huge capacities for incredibly cheap. There’s 12TB HDDs for like $100. 12TB of SSDs would run you several hundreds.

      You can slap bcache on a 512GB NVMe backed by a 8TB HDD, and you get 8TB worth of storage, 512GB of which will be cached on the NVMe and thus really fast. But from the user’s perspective, it’s just one big 8TB drive. You don’t have to think about what is where, you just use it. You don’t have to be like, I’m going to use this VM so I’ll move it to the SSD and back to the HDD when done. The first time might be super slow but subsequent use will be very fast. It also caches writes too, so you can write up to 512GB really fast in this example and it’ll slowly get flushed to the HDD in the background. But from your perspective, as soon as it’s written to the SSD, the data is effectively commited to disk. If the application calls fsync to ensure data is written to disk, it’ll complete once it’s fully written to the SSD. You get NVMe read/write speeds and the space of an HDD.

      So one big disk for your Steam library and whatever you play might be slow on the first load but then as you play the game files gets promoted to the NVMe cache and perform mostly at NVMe speeds, and your loading screens are much shorter.

      • LoafyLemon@kbin.social
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        1 year ago

        What are the implications in regards to the lifespan of the disk used as cache? Any potential downsides?

        • Max-P@lemmy.max-p.me
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          1 year ago

          I don’t know, it’s going to depend a lot on usage pattern and cache hit ratio. It will probably do a lot more writes than normal to the cache drive as it evicts older stuff and replaces it. Everything has tradeoffs in the end.

          Another big tradeoff depending on the cache mode (ie. writeback mode) if the SSD dies, you can lose a fair bit of data. Not as catastrophic as a RAID0 would but pretty bad. And you probably want writeback for the fast writes.

          Thus I had 2 SSDs and 2 HDDs in RAID1, with the SSDs caching the HDDs. But it turns out my SSDs are kinda crap (they’re about as fast as the HDDs for sequential read/writes) and I didn’t see as much benefit as I hoped so now they’re independent ZFS pools.

    • Atemu@lemmy.ml
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      1 year ago

      except for hdds without cache

      The “cache” on HDDs is extremely tiny. Maybe a few seconds worth of sequential access at max. It does not exist to cache significant amounts of data for much longer than that.

      At the sizes at which bcache is used, you could permanently hold almost all of your performance-critical data on flash storage while having enough space for tonnes of performance-uncritical data; all in the same storage “package”.

    • Uluganda@lemmy.mlOP
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      1 year ago

      In my case, it basically helps me improve random read significantly. My NVMe is fast, like 3GB/s in sequential and 500MB/s in random, but it’s only 120GB. By using it as a cache in a bcache system, once a random read is performed, the data will be copied from HDD to SSD and if the data is requested again the random read will happen from SSD instead of HDD.

      Thus, using it to play modern gaming is actually do able. Game that requires fast random read, like Baldur’s Gate 3 and Starfield.

      As a lot of people in my og post mentioned, random is more important that sequential. Bcache by default disable sequential cache so you wont fill you cache to fast if a big data is being read, like watching movie, copying video, etc. That’s where Raid0 comes to the rescue. Having Raid0 with 2 drives basically double my sequential read and having 3 triples it.