A TundraWare Inc. Technical Note
Author: | Tim Daneliuk (tundra@tundraware.com) |
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Version: | $Id: baremetal.rst,v 1.111 2014/08/23 15:31:28 tundra Exp $ |
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Many commercial and open source solutions exist to solve the problem of creating backups that can be restored to "bare metal". That is, restoring a system image back to a disk when the machine will no longer boot or a disk has to be replaced. Image backups are preferred when rebuilding systems so you don't have to manually reinstall every application, system setting and so forth.
The purpose here was to do just that - create images capable of being "poured" onto, say, a blank, new hard drive, but using only standard linux command line tools.
Warning
Doing this wrong can clobber your systems and its data. What you see here is just a simple example for purposes of explaining the general approach. You should not trust this approach unless you prove these procedures are satisfactory in YOUR OWN ENVIRONMENT.
The idea is to make an image snapshot right after you build a machine, and anytime thereafter you make significant changes to its operating system and application configuration. You might do this, say, right before patching a server so that, if patching breaks the server to the point where it will no longer boot, you can just "pour" the previous image onto the disk.
To do this, we reboot our target machine using the Linux System Rescue CD. This CD has all the tools on it we need to do both image creation and restoration. You can find the iso image for this disk here:
http://sourceforge.net/projects/systemrescuecd/
You will also need access to a place to store and retrieve your images. In the examples below, we used a NAS NFS share, though you could also use another local hard drive, SAN connected storage or even a USB-connected drive.
In our examples below, we're imaging a CentOS 6.5 machine. The only thing we need to image is the operating system itself. In this example, we know there are 2 partitions of interest:
sda1
- The/boot
partition - about 500MB
sda2
- The rest of the operating system, in this case contained- in LVM containers - about 52GB
The idea is that if the machine were to go dead, a disk failed, or what have you, this would be sufficient to get the replacement booting properly again. Presumably, you could then restore any data files you have from your standard backup/restore tools.
Boot from the System Rescue CD
mount nas1:/shared /shared # Mount shared storage
sfdisk -d /dev/sda >/shared/ptbl # Preserve the partition table
dd if=/dev/sda of=/shared/MBR bs=512 count=1 # Backup the Master Boot Record
dd if=/dev/sda1 of=/shared/boot.dd bs=12M # Backup /boot
dd if=/dev/sda2 of=/shared/root.dd bs=12M # Backup rootvg LVM (rest of OS)
reboot machine to make it operational again
How long this takes depends on what your write speed to the shared
storage is and how big your partitions are. In this case sda1
is
only about 500MB and completed rather quickly. But sda2
was about
52GB and took around 25 min to complete on a slow nfs mount - about
26MB/min in this case or about a quarter of the capacity of the 1Ge
network connecting the NAS.
The bs=12
is environment-specific and you'll have to find a setting for this
that makes best use of your network and NAS or other storage device.
Now, imagine that your OS is borked or the hard disk had to be replaced and you need to take the image from the backup above and getting running on the machine.
Boot from the System Rescue CD
mount nas1:/shared /shared # Mount shared storage
dd if=/dev/zero of=/dev/sda bs=512 count=10 # Nuke any old boot/partion info on the disk
sfdisk /dev/sda </shared/ptbl # Restore the partition table
dd if=/shared/MBR of=/dev/sda bs=512 count=1 # Restore the Master Boot Record
dd if=/shared/boot.dd of=/dev/sda1 bs=12M # Restore /boot
dd if=/shared/root.dd of=/dev/sda2 bs=12M # Restore rootvg LVM (rest of OS)
Reboot machine to make it operational again
On the same network described above, restoring the 52MB rootvg
took about 35 mins.
Because this is partition based - that is, you are imaging and
restoring partitions, not disks - you can actually restore to a
physical disk that is a different size than the one from which the
image was taken. Obviously, there has to be enough room for all the
data on the new disk. This makes it easy to lay your operating system
down on a new, larger disk. Do an image of the old disk, restore it
to the new disk, and then, while still running under the System
Rescue CD
, run parted
or gparted
to expand the partitions to
use the additional disk space.
Warning
Do NOT try this with a machine that boots from SAN!!! SAN-booted machines put information into their bootloaders about the boot LUN's WWID and the necessary configuration of HBAs to see those LUNs. If you present a bigger LUN with a different WWID, the OS bootstrap will probably fail, even though you can properly restore the image. There are ways around this. This document is not the place to find these ways.
Upside:
- You can use standard Linux commands to do imaged backups of your machine.
- You can use this to migrate an OS to a bigger disk.
Downside:
- You cannot do this while the machine is up and running so imaging this way requires a machine outage.
- Every block in the partition gets copied whether it is used or not.
These tests were conducted on slow, consumer grade servers connected via 1Ge through an unmanaged switch. In an Enterprise class networking and NAS environment, we'd expect to see considerably faster backup and reimaging times, thereby minimizing server outage times.
In theory this should also work on SAN-booted machines so long as the exact same LUN (WWID and size) is presented for the restore as was used for the backup. However, this was not tested and theory and Reality usually collide in rather nasty ways. Mr. Murphy is not our friend.
Same story for VMs. Not tested. It's unclear whether a VM booted from a rescue disk would see the underlying disk storage (VMDK or whatever).
Again, theoretically this should work with other operating system partitions and data partitions. But ... not tested.
This works well for Unix-style operating systems because they boot with a full complement of drivers and discover what is on the machine at boot time.
However, Windows may have a fit if you do this, especially if you restore to machine substantially different than the one where the backup image was created. First of all, Windows doesn't carry around any drivers it doesn't think it needs. Secondly, Windows licensing logic is designed to prevent this sort of thing as a deterrent to software piracy. This doesn't mean it cannot be done - it can - but it may take some extra fiddling after you reboot Windows.
This approach assumes the disk us partitioned using standard
fdisk
type tools. Some OSs - notably the *BSD
varianst (aka
"God's Own Operating System") - have the option to use their own disk
slicing and labeling tools. This general approach will work, but
you have to tweak it to ensure you preserve those boot loaders and
custom slicing tables.
This document is Copyright (c) 2014, TundraWare Inc., Des Plaines, IL 60018, All Rights Reserved.
Permission is hereby granted for the free duplication and dissemination of this document if the following conditions are met:
You can find the latest version of this document at:
http://www.tundraware.com/TechnicalNotes/Baremetal
A pdf version of this document can be downloaded at:
http://www.tundraware.com/TechnicalNotes/Baremetal/baremetal.pdf
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