lvmsync
Have you ever wanted to do a partial sync on a block device, possibly over a network, but were stymied by the fact that rsync just didn't work?
Well, fret no longer. As long as you use LVM for your block devices, you too can have efficient delta-transfer of changed blocks.
What is it good for?
Mostly, transferring entire block devices from one machine to another, with minimal downtime. Until now, you had to shutdown your service/VM/whatever, do a big cross-network dd (using netcat or something), and wait while all that transferred.
lvmsync allows you to use the following workflow to transfer a block
device "mostly live" to another machine:
- Take a snapshot of an existing LV.
- Transfer the entire snapshot over the network, while whatever uses the block device itself keeps running.
- When the initial transfer is finished, you shutdown/unmount/whatever the initial block device.
- Run lvmsync on the snapshot to transfer the changed blocks
- The only thing transferred over the network is the blocks that have changed (which, hopefully, will be minimal)
- If you're paranoid, you can md5sum the content of the source and destination block devices, to make sure everything's OK (although this will destroy any performance benefit you got by running lvmsync in the first lace)
- Bring the service/VM/whatever back up in it's new home in a much shorter (as in, "orders of magnitude") time than was previously possible.
lvmsync also has a basic "snapshot-and-rollback" feature, where it can
save a copy of the data in the LV that you're overwriting to a file for
later application if you need to rollback. See "Snapback support" under
"How do I use it?" for more details.
How does it work?
By the magic of LVM snapshots. lvmsync is able to read the metadata that
device-mapper uses to keep track of what parts of the block device have
changed, and use that information to only send those modified blocks over
the network.
If you're really interested in the gory details, there's a brief "Theory of Operation" section at the bottom of this README, or else you can just head straight for the source code.
Installation
To run lvmsync, you'll need to have a working installation of Ruby 1.8 (or
later) on both the machine you're transferring from, and the machine you're
transferring to. On the source, you'll need vgcfgbackup (which is part of
the core LVM2 toolset), and if you want to deal with thin snapshots, you'll
also need thin_dump (which is part of the "thin provisioning tools" which
are highly recommended for anyone working with thin-provisioned LVs). For
transferring dumps between machines, you'll need SSH installed and working
between the two machines.
Installing lvmsync itself is easiest using Rubygems: gem install
lvmsync. This will install all the dependencies and (presumably) put the
lvmsync command itself in root's PATH. If for some reason you want to
install it all by hand, you'll need to copy the contents of lib/ into a
directory in your Ruby library path, copy bin/lvmsync to somewhere on your
PATH, and install the treetop and git-version-bump gems.
How do I use it?
For an overview of all available options, run lvmsync -h.
Efficient block device transfer
At present, the only part of the block device syncing process that is automated is the actual transfer of the snapshot changes -- the rest (making the snapshot, doing the initial transfer, and stopping all writes to the LV) you'll have to do yourself. Those other steps aren't difficult, though, and are trivial to script to suit your local environment (see the example, below).
Once you've got the snapshot installed, done the initial sync, and stopped
I/O, you just call lvmsync like this:
lvmsync <snapshot LV device> <destserver>:<destblock>
This requires that lvmsync is installed on <destserver>, and that you
have the ability to SSH into <destserver> as root. All data transfer
takes place over SSH, because we don't trust any network, and it simplifies
so many things (such as link-level compression, if you want it). If CPU is
an issue, you shouldn't be running LVM on your phone to begin with.
The reason why lvmsync needs you to specify the snapshot you want to sync,
and not the base LV, is that you might have more than one snapshot of a
given LV, and while we can determine the base LV given a snapshot, you can't
work out which snapshot to sync given a base LV. Remember to always specify
the full device path, not just the LV name.
Example
Let's say you've got an LV, named vmsrv1/somevm, and you'd like to
synchronise it to a new VM server, named vmsrv2. Assuming that lvmsync is
installed on vmsrv2 and vmsrv2 has an LV named vmsrv2/somevm large
enough to take the data, the following will do the trick rather nicely (all
commands should be run on vmsrv1:
# Take a snapshot before we do anything, so LVM will record all changes
# made while we're doing the initial sync
lvcreate --snapshot -L10G -n somevm-lvmsync vmsrv1/somevm
# Pre-sync all data across -- this will take some time, but while it's
# happening the VM is still serving traffic. pv is a great tool for
# showing you how fast your data's moving, but you can leave it out of
# the pipeline if you don't have it installed.
dd if=/dev/vmsrv1/somevm-lvmsync bs=1M | pv -ptrb | ssh root@vmsrv2 dd of=/dev/vmsrv2/somevm bs=1M
# Shutdown the VM -- the command you use will probably vary
virsh shutdown somevm
# Once it's shutdown and the block device isn't going to be written to
# any more, then you can run lvmsync
lvmsync /dev/vmsrv1/somevm-lvmsync vmsrv2:/dev/vmsrv2/somevm
# You can now start up the VM on vmsrv2, after a fairly small period of
# downtime. Once you're done, you can remove the snapshot and,
# presumably, the LV itself, from `vmsrv1`
Snapback support
In addition to being able to efficiently transfer the changes to an LV
across a network, lvmsync now supports a simple form of point-in-time
recovery, which I've called 'snapback'.
The way this works is startlingly simple: as lvmsync writes the changed
blocks out to the destination block device, it reads the data that is being
overwritten, and stores it to a file (specified with the --snapback
option). The format of this file is the same as the wire protocol that
lvmsync uses to transfer changed blocks over the network. This means
that, in the event that you need to rollback a block device to an earlier
state, you can do so by simply applying the saved snapback files created
previously, until you get to the desired state.
Example
To setup a snapback process, you need to have a local LV, with a snapshot, whose contents have been sent to a remote server, perhaps something like this:
lvcreate --snapshot -L10G -n somevm-snapback vmsrv1/somevm
dd if=/dev/vmsrv1/somevm-snapback bs=1M | pv -ptrb | \
ssh root@vmsrv2 dd of=/dev/vmsrv2/somevm
Now, you can run something like the following periodically (say, out of cron each hour):
lvcreate --snapshot -L10G -n somevm-snapback-new vmsrv1/somevm
lvmsync /dev/vmsrv1/somevm-snapback vmsrv2:/dev/vmsrv2/somevm --snapback \
/var/snapbacks/somevm.$(date +%Y%m%d-%H%M)
lvremove -f vmsrv1/somevm-snapback
lvrename vmsrv1/somevm-snapback-new somevm-snapback
This will produce files in /var/snapbacks named somevm.<date-time>. You
need to create the somevm-snapback-new snapshot before you start
lvmsync, so that you can guarantee no changes won't get noticed.
There are some fairly large caveats to this method -- the LV will still be collecting writes while you're transferring the snapshots, so you won't get a consistent snapshot (in the event you have to rollback, it's almost certain you'll need to fsck). You'll almost certainly want to incorporate some sort of I/O freezing into the process, but the exact execution of that is system-specific, and left as an exercise for the reader.
Restoring data from a snapback setup is straightforward -- just take each
snapback in reverse order and run it through lvmsync --apply on the
destination machine (vmsrv2 in our example). Say at 1145 vmsrv1
crashed, and it was determined that you needed to rollback to the state of
the system at 8am. You could do this:
lvmsync --apply /var/snapbacks/somevm.20120119-1100 /dev/vmsrv2/somevm
lvmsync --apply /var/snapbacks/somevm.20120119-1000 /dev/vmsrv2/somevm
lvmsync --apply /var/snapbacks/somevm.20120119-0900 /dev/vmsrv2/somevm
And you're done -- /dev/vmsrv2/somevm is now at the state it was at at
8am. A whole pile of fsck will no doubt be required, but hopefully you'll
still be able to salvage something.
If you're wondering why I only restored the 0900 snapback, and not the 0800 one, it's because the snapback made at 0900 copied the changes that were sent at 0800 (and about to be overwritten at 0900) and wrote them to the 0900 snapback file. Confused much? Good.
Transferring snapshots on the same machine
If you need to transfer an LV between different VGs on the same machine,
then running everything through SSH is just an unnecessary overhead. If you
instead just run lvmsync without the <destserver>: in the destination
specification, everything runs locally, like this:
lvmsync /dev/vg0/srclv-snapshot /dev/vg1/destlv
All other parts of the process (creating the snapshot, doing the initial
data move with dd, and so on) are unchanged.
As an aside, if you're trying to move LVs between PVs in the same VG, then
you don't need lvmsync, you need pvmove.
Taking a space- and IO-efficient snapshot of an LV
But wait, there's more! lvmsync also has the ability to dump out the
snapshot data to disk, rather than immediately applying it to another block
device.
To do this, use the --stdout option when you're running lvmsync, and
instead of writing the changes to another block device, it'll instead dump
the "change stream" to stdout (so redirect somewhere useful). This allows
you to dump the changes to a file, or do some sort of fancy footwork to
transfer the data to another lvmsync process to apply the changes to a block
device.
For example, if you just wanted to take a copy of the contents of a snapshot, you could do something like this:
lvmsync --stdout /dev/somevg/somelv-snapshot >~/somechanges
At a later date, if you wanted to apply those writes to a block device, you'd do it like this:
lvmsync --apply ~/somechanges /dev/somevg/someotherlv
You can also do things like do an lvmsync from the destination -- this is useful if (for example) you can SSH from the destination to the source machine, but not the other way around (fkkn firewalls, how do they work?). You could do this by running something like the following on the destination machine:
ssh srcmachine lvmsync --stdout /dev/srcvg/srclv-snap | lvmsync --apply - /dev/destvg/destlv
Theory of Operation
This section is for those people who can't sleep well at night without knowing the magic behind the curtain (and to remind myself occasionally how this stuff works). It is completely unnecessary to read this section in order to work lvmsync.
First, a little bit of background about how snapshot LVs work, before I describe how lvmsync makes use of them.
An LVM snapshot "device" is actually not a block device in the usual sense. It isn't just a big area of disk space where you write things. Instead, it is a "meta" device, which points to both an "origin" LV, which is the LV from which the snapshot was made, and a "metadata" LV, which is where the magic happens.
The "metadata" LV is a list of "chunks" of the origin LV which have been modified, along with the original contents of those chunks. In a way, you can think of it as a sort of "binary diff", which says "these are the ways in which this snapshot LV differs from the origin LV". When a write happens to the origin LV, this "diff" is potentially modified to maintain the original "view" from the time the snapshot was taken.
(Sidenote: this is why you can write to snapshots -- if you write to a snapshot, the "diff" is written to some more, to say "here are some more differences between the origin and the snapshot").
From here, it shouldn't be hard to work out how LVM uses the combination of the origin and metadata LVs to give you a consistent snapshot view -- when you ask to read a chunk, LVM looks in the metadata LV to see if it has the chunk in there, and if not it can be sure that the chunk hasn't changed, so it just reads it from the origin LV. Miiiiighty clever!
In lvmsync, we only make use of a tiny fraction of the data stored in the metadata LV for the snapshot. We don't care what the original contents were (they're what we're trying to get away from). What we want is the list of which chunks have been modified, because that's what we use to work out which blocks on the original LV we need to copy across. lvmsync never actually reads any disk data from the snapshot block device itself -- all it reads is the list of changed blocks, then it reads the changed data from the original LV (which is where the modified blocks are stored).
By specifying a snapshot to lvmsync, you're telling it "this is the list of changes I want you to copy" -- it already knows which original LV it needs to copy from (the snapshot metadata has that info available).
See Also
Whilst I think lvmsync is awesome (and I hope you will too), here are some
other tools that might be of use to you if lvmsync doesn't float your
mustard:
blocksync.py-- Implements the "hash the chunks and send the ones that don't match" strategy of block device syncing. It needs to read the entire block device at each end to work out what to send, so it's not as efficient, but on the other hand it doesn't require LVM.bdsync-- Another "hash the chunks" implementation, with the same limitations and advantages asblocksync.py.ddsnap-- Part of the "Zumastor" project, appears to provide some sort of network-aware block device snapshotting (I'm not sure, the Zumastor homepage includes the word "Enterprise", so I fell asleep before finishing reading). Seems to require kernel patches, so there's a non-trivial barrier to entry, but probably not such a big deal if you're after network-aware snapshots as part of your core infrastructure.