Skip to content

Instantly share code, notes, and snippets.

Show Gist options
  • Save Tokukarin/a2f02336064f433dc8bb92f46e70613e to your computer and use it in GitHub Desktop.
Save Tokukarin/a2f02336064f433dc8bb92f46e70613e to your computer and use it in GitHub Desktop.
dm-crypt + dm-integrity + dm-raid = awesome!
#!/usr/bin/env bash
#
# Author: Markus (MawKKe) [email protected]
# Date: 2018-03-19
#
#
# What?
#
# Linux dm-crypt + dm-integrity + dm-raid (RAID1)
#
# = Secure, redundant array with data integrity protection
#
# Why?
#
# You see, RAID1 is dead simple tool for disk redundancy,
# but it does NOT protect you from bit rot. There is no way
# for RAID1 to distinguish which drive has the correct data if rot occurs.
# This is a silent killer.
#
# But with dm-integrity, you can now have error detection
# at the block level. But it alone does not provide error correction
# and is pretty useless with just one disk (disks fail, shit happens).
#
# But if you use dm-integrity *below* RAID1, now you have disk redundancy,
# AND error checking AND error correction. Invalid data received from
# a drive will cause a checksum error which the RAID array notices and
# replaces with correct data.
#
# If you throw encryption into the mix, you'll have secure,
# redundant array. Oh, and the data integrity can be protected with
# authenticated encryption, so no-one can tamper your data maliciously.
#
# How cool is that?
#
# Also: If you use RAID1 arrays as LVM physical volumes, the overall
# architecture is quite similar to ZFS! All with native Linux tools,
# and no hacky solaris compatibility layers or licencing issues!
#
# (I guess you can use whatever RAID level you want, but RAID1 is the
# simplest and fastest to set up)
#
#
# Let's try it out!
#
# ---
# NOTE: The dm-integrity target is available since Linux kernel version 4.12.
# NOTE: This example requires LUKS2 which is only recently released (2018-03)
# NOTE: The authenticated encryption is still experimental (2018-03)
# ---
set -eux
# 1) Make dummy disks
cd /tmp
truncate -s 500M disk1.img
truncate -s 500M disk2.img
# Format the disk with luksFormat:
dd if=/dev/urandom of=key.bin bs=512 count=1
cryptsetup luksFormat -q --type luks2 --integrity hmac-sha256 disk1.img key.bin
cryptsetup luksFormat -q --type luks2 --integrity hmac-sha256 disk2.img key.bin
# The luksFormat's might take a while since the --integrity causes the disks to be wiped.
# dm-integrity is usually configured with 'integritysetup' (see below), but as
# it happens, cryptsetup can do all the integrity configuration automatically if
# the --integrity flag is specified.
# Open/attach the encrypted disks
cryptsetup luksOpen disk1.img disk1luks --key-file key.bin
cryptsetup luksOpen disk2.img disk2luks --key-file key.bin
# Create raid1:
mdadm \
--create \
--verbose --level 1 \
--metadata=1.2 \
--raid-devices=2 \
/dev/md/mdtest \
/dev/mapper/disk1luks \
/dev/mapper/disk2luks
# Create a filesystem, add to LVM volume group, etc...
mkfs.ext4 /dev/md/mdtest
# Cool! Now you can 'scrub' the raid setup, which verifies
# the contents of each drive. Ordinarily detecting an error would
# be problematic, but since we are now using dm-integrity, the raid1
# *knows* which one has the correct data, and is able to fix it automatically.
#
# To scrub the array:
#
# $ echo check > /sys/block/md127/md/sync_action
#
# ... wait a while
#
# $ dmesg | tail -n 30
#
# You should see
#
# [957578.661711] md: data-check of RAID array md127
# [957586.932826] md: md127: data-check done.
#
#
# Let's simulate disk corruption:
#
# $ dd if=/dev/urandom of=disk2.img seek=30000 count=30 bs=1k conv=notrunc
#
# (this writes 30kB of random data into disk2.img)
#
#
# Run scrub again:
#
# $ echo check > /sys/block/md127/md/sync_action
#
# ... wait a while
#
# $ dmesg | tail -n 30
#
# Now you should see
# ...
# [959146.618086] md: data-check of RAID array md127
# [959146.962543] device-mapper: crypt: INTEGRITY AEAD ERROR, sector 39784
# [959146.963086] device-mapper: crypt: INTEGRITY AEAD ERROR, sector 39840
# [959154.932650] md: md127: data-check done.
#
# But now if you run scrub yet again:
# ...
# [959212.329473] md: data-check of RAID array md127
# [959220.566150] md: md127: data-check done.
#
# And since we didn't get any errors a second time, we can deduce that the invalid
# data was repaired automatically.
#
# Great! We are done.
#
# --------
#
# If you don't need encryption, then you can use 'integritysetup' instead of cryptsetup.
# It works in similar fashion:
#
# $ integritysetup format --integrity sha256 disk1.img
# $ integritysetup format --integrity sha256 disk2.img
# $ integritysetup open --integrity sha256 disk1.img disk1int
# $ integritysetup open --integrity sha256 disk2.img disk2int
# $ mdadm --create ...
#
# ...and so on. Though now you can detect and repair disk errors but have no protection
# against malicious cold-storage attacks. Data is also readable by anybody.
#
# 2018-03 NOTE:
#
# if you override the default --integrity value (whatever it is) during formatting,
# then you must specify it again when opening, like in the example above. For some
# reason the algorithm is not autodetected. I guess there is no header written onto
# disk like is with LUKS ?
#
# ----------
#
# Read more:
# https://fosdem.org/2018/schedule/event/cryptsetup/
# https://gitlab.com/cryptsetup/cryptsetup/wikis/DMCrypt
# https://gitlab.com/cryptsetup/cryptsetup/wikis/DMIntegrity
# https://mirrors.edge.kernel.org/pub/linux/utils/cryptsetup/v2.0/v2.0.0-rc0-ReleaseNotes
Sign up for free to join this conversation on GitHub. Already have an account? Sign in to comment