I really want to run ceph because it fits a number of criteria I have: gradually adding storage, mismatched disks, fault tolerance, erasure encoding, encryption, support out-of-the-box from other software (like Incus).
But then I look at the hardware suggestions, and they seem like an up-front investment and ongoing cost to keep at least three machines evenly matched on RAM and physical storage. I also want more of a single-box NAS.
Would it be idiotic to put a ceph setup all on one machine? I could run three mons on it with separate physical device backing each so I don’t lose everything from a disk failure with those. I’m not too concerned about speed or network partitioning, this would be lukewarm storage for me.
Why then not just use ZFS or BTRFS? Way less overhead.
Ceph’s main advantage is the distribution of storage over multiple nodes, which you’re not planning on doing?
I mean, yeah, I’d prefer ZFS but, unless I am missing something, it is a massive pain to add disks to an existing pool. You have to buy a new set of disks and create a new pool to transition from RAID z1 to z2. That’s basically the only reason it fails the criteria I have. I think I’d also prefer erasure encoding instead of z2, but it seems like regular scrub operations could keep it reliable.
BTRFS sounds like it has too many footguns for me, and its raid5/6 equivalents are “not for production at this time.”
LVM, mdraid, dm-crypt? LVM will let you make volumes and pools of basically any shape or size.
Adding new disks to an existing ZFS pool is as easy as figuring out what new redundancy scheme you want, then adding them with that scheme to the pool. E.g. you have an existing pool with a RAIDz1 vdev with 3 4TB disks. You found some cheap recertified disks and want to expand with more redundancy to mitigate the risk. You buy 4 16TB disks, create a RAIDz2 vdev and add that to the existing pool. The pool grows in storage by whatever is the space available from the new vdev. Critically pools are JBODs of vdevs. You can add any number or type of vdevs to a pool. The redundancy is done at the vdev level. Thus you can have a pool with a mix of any RAIDzN and/or mirrors. You don’t create a new pool and transition to it. You add another vdev with whatever redundancy topology you want to the existing pool and keep writing data to it. You don’t even have to offline it. If you add a second RAIDz1 to an existing RAIDz1, you’d get similar redundancy to moving from RAIDz1 to RAIDz2.
Finally if you have some even stranger hardware lying around, you can combine it in appropriately sized volumes via LVM and give that to ZFS, as someone already suggested. I used to have a mirror with one real 8TB disk and one 8TB LVM volume consisting of 1TB, 3TB and 4TB disk. Worked like a charm.
“As easy as buying four same-sized disks all at once” is kinda missing the point.
How do I migrate data from the existing z1 to the z2? And then how can I re-add the disks that were in z1 after I have moved the data? Buy yet another disk and add a z2 vdev with my now 4 disks, I guess. Unless it is possible to format and add them to the new z2?
If the vdevs are not all the same redundancy level am I right that there’s no guarantee which level of redundancy any particular file is getting?
You don’t migrate the data from the existing z1. It keeps running and stays in use. You add another z1 or z2 to the pool.
If the vdevs are not all the same redundancy level am I right that there’s no guarantee which level of redundancy any particular file is getting?
This is a problem. You don’t know which file ends up on which vdev. If you only use mirror vdevs then you could remove vdevs you no longer want to use and ZFS will transfer the data from them to the remaining vdevs, assuming there’s space. As far as I know you can’t remove vdevs from pools that have RAIDz vdevs, you can only add vdevs. So if you want to have guaranteed 2-drive failure for every file, then yes, you’d have to create a new pool with RAIDz2, move data to it. Then you could add your existing drives to it in another RAIDz2 vdev.
Removing RAIDz vdevs might become possible in the future. There’s already a feature that allows expanding existing RAIDz vdevs but it’s fairly new so I’m personally not considering it in my expansion plans.
You end up wasting a ton of space though because each vdev has its own parity drives.
What you lose in space, you gain in redundancy. As long as you’re not looking for the absolute least redundant setup, it’s not a bad tradeoff. Typically running a large stripe array with a single redundancy disk isn’t a great idea. And if you’re running mirrors anyway, you don’t lose any additional space to redundancy.
Yep I feel this way.
No point in pricing a single HDD because I’m shooting for parity on every vdev I spin up.
Fair enough, it does add a good chunk of power usage though as HDDs are pretty power heavy at 5-7W or so.
No matter what setup you use, if you want redundancy, it’ll cost space. In a perfect world, 30% waste would allow you to lose up to 30% of your disk space and still be OK.
…but that extra percentage of used space is the intrinsic cost.
Found an interesting read regarding the matter here:
https://old.reddit.com/r/ceph/comments/mppwas/single_node_ceph_vs_zfsbtrfs/
Most seem to recommend going for ZFS instead if using a single machine but there is a person discussing his first hand experience with single node Ceph.This was really neat, kinda boils down to “you don’t want to deal with the complexity and it’s horrifically slow.”
Neat! Thank you
Since you are talking mismatched disks, I have gone to unraid after running a ceph cluster. I found it easy to keep adding and upgrading disks in unraid where it made more sense than maintaining or adding nodes. While I like the concept of being able to add nodes for very large storage arrays. My current unraid server is 180tb.
It is super simple to add/upgrade the storage one disk at a time.
Oh, neat, I’ll have to look into that more. It’s able to have some redundancy and does some sort of rebalancing on disk failures?
It has parity disks, which always need to be the largest disks in your array. You can run with either a single one double parity disk.
It seems to work well, as that’s how I’ve had to replace a dozen disks in the last year upgrading from 8tb disks to 18 or 22tb disks.
Create 3 VM’s and pass-through disks to each VM. Boom ceph cluster on a single computer.
ZFS/BRTFS might still be better, but if you really want Ceph this should work and provide expansion and redundancy at a block device level, though you wont have any hardware redundancy regarding power/nodes.
Ceph is a huge amount of overhead, both engineering and compute resources, for this usecase.
Acronyms, initialisms, abbreviations, contractions, and other phrases which expand to something larger, that I’ve seen in this thread:
Fewer Letters More Letters LVM (Linux) Logical Volume Manager for filesystem mapping RAID Redundant Array of Independent Disks for mass storage ZFS Solaris/Linux filesystem focusing on data integrity
3 acronyms in this thread; the most compressed thread commented on today has 9 acronyms.
[Thread #581 for this sub, first seen 7th Mar 2024, 17:15] [FAQ] [Full list] [Contact] [Source code]
I did it for a while and last everything. Go for it if your have adequate backups.