1. Introduction
---------------
Kernels more recent than 2.6.12 have dropped support for devfs, which
means that initrd-tools can no longer be used to boot into an encrypted
root partition. Instead, a similar functionality has been developed for
use with an initramfs-image.


2. A fresh installation
-----------------------
If you plan to perform a completely new installation of Debian onto a
machine and to do so using an encrypted root partition, you might want
to consider using a version of Debian Installer with partman-crypto
(see http://wiki.debian.org/DebianInstaller/PartmanCrypto).

The installation will then take care of all the details and perform the
necessary configuration for you, meaning that you should not have to
read the rest of this document to get a machine with an encrypted
root filesystem up and running.


However, if you are not planning to perform a new installation from scratch,
the following information might be useful to you.


3. Requirements
---------------
In order to boot from an encrypted root filesystem, you need an
initramfs-image which includes the necessary kernel modules and scripts to
setup the root device after the kernel has been initialized, but before the
rest of the operating system is booted.

To do so, you need two partitions:
- an unencrypted /boot partition
- an encrypted / partition

In addition, you need to have both initramfs-tools and busybox installed.

NOTE: You should make sure that your swap partition is either encrypted, or
that you are using a swap file on an encrypted partition, as crypto keys and
other sensitive information might otherwise be written out to the swap
partition in unencrypted form.


4. Setup (regular dm-crypt)
---------------------------
First of all, you must edit /etc/crypttab and add a line describing your
root device, for example:

  cryptroot /dev/sda2 none cipher=aes-xts-plain64,size=256,hash=sha1

This will allow cryptsetup to create /dev/mapper/cryptroot from the
encrypted partition /dev/sda2 during boot.

In addition, you must also make sure that the root device is listed in
/etc/fstab, for example:

  /dev/mapper/cryptroot / ext4 defaults 0 1

This will allow the initramfs support scripts to know which of the devices
in the crypttab that is the root device.

After doing these changes, you should regenerate the initramfs by running
"initramfs-update -u", then make sure that your boot loader is configured
to feed the initramfs to the kernel when booting. The kernel root argument
should also be changed to /dev/mapper/cryptroot.

Now, reboot the machine, and if everything is correctly configured, you
should be given a prompt to type in the passphrase for the encrypted
root partition before the boot can continue.

NOTE: the initramfs scripts default to using the sha256 hash function while
the plain cryptsetup binary defaults to using the ripemd160 hash function.
In order to ensure that the crypto setup works in a consistent manner, you
should make sure that the hash function is specified in the /etc/crypttab file
if you are using regular dm-crypt (with LUKS the hash function to use is stored
in the LUKS header).


5. Setup (using LUKS)
---------------------
If you are using the LUKS feature of cryptsetup, the above setup recipe should
still apply, but since most options can be derived from the information stored
in the LUKS header on-disk, the line to add to /etc/crypttab should look
something like this:

  cryptroot /dev/sda2 none luks


6. Exotic key types
-------------------
The above examples assume that you use a regular passphrase as the key to the
encrypted filesystem. However, if you wish to make use of more complex setups
(such as root-key-on-usb-memory), you can create a script which does all the
steps necessary to retrieve the key and then prints it to stdout.

Then add a keyscript=/path/to/your/script.sh to the options (fourth column) in
the above mentioned /etc/crypttab line, so that it looks something like this:

  cryptroot /dev/sda2 none luks,keyscript=/usr/local/sbin/cryptkey

Next, regenerate your initramfs image. This will copy the script into the
initramfs image under the /lib/cryptsetup/keyscripts/ directory.

NOTE: there is a limited set of tools available when the script is executing
as part of the initramfs bootup, you have to make sure that you do not use
any tools which are not available or your script, and therefore boot, will
fail.


7. "cryptopts" boot argument
----------------------------
In general, you should use the above approach with a line describing your
root partition in /etc/crypttab and /etc/fstab. However, if for some reason
you wish to override the settings that are derived from these files and
stored in the initramfs image, you can use the "cryptopts" boot argument
(this *only* works for the root partition).

The format of cryptopts is:
cryptopts=<opt1>=<value1>,<opt2>=<value2>...

Beside the "hash", "size", "cipher" and "lvm" options that correspond to the
same options in the fourth field of /etc/crypttab, the options "target",
"source" and "key" are also supported. They correspond to the first, second
and third field of /etc/crypttab, respectively. See the crypttab man page
for further details.

Several "cryptopts" boot arguments can also be specified in case more than
one mapping needs to be setup in the initramfs stage of the boot.

Example boot arguments:
root=/dev/mapper/crypt0 cryptopts=target=crypt0,source=/dev/sda1,cipher=aes-xts-plain64,size=256,hash=sha1

8. Resume device support
------------------------
The initramfs scripts will also try to automatically determine the devices,
if any, that are used for software suspend (swsusp, suspend2 or uswsusp) and
to set them up during the initramfs stage in order to allow suspend and resume
in combination with encryption to keep the resume image safe from potential
attackers.

If your resume device and your root partition use two different cryptsetup
mappings, you might want to use the "decrypt_derived" keyscript as described
below.

9. The "decrypt_derived" keyscript
----------------------------------
Assume that you have two entries in /etc/crypttab:

cryptroot /dev/sda1 none luks
cryptswap /dev/sda2 none luks

If cryptswap is used as your suspend/resume device, you'd normally need to
enter two different passphrases during the boot, but the "decrypt_derived"
script can generate the key for the second mapping using a hash of the key
for the first mapping.

In short, you'll need to do something like the following to take advantage
of the decrypt_derived script:

1) swapoff -a
2) cryptsetup luksClose cryptswap
3) edit /etc/crypttab and change the cryptswap line to e.g.:
cryptswap /dev/sda2 cryptroot cipher=aes-xts-plain65,size=256,hash=sha1,keyscript=decrypt_derived,swap
4) /etc/init.d/cryptdisks start
5) Make sure that /dev/mapper/cryptswap has been created
6) swapon -a
7) (optional) update-initramfs -u

After you've followed the above steps, your swap device should be setup
automatically after the root device has been setup during the boot stage.

WARNING: If you use the decrypt_derived keyscript for devices with persistent
data (i.e. not swap or temp devices), then you will lose access to that data
permanently if something damages the LUKS header of the LUKS device you derive
from. The same applies if you luksFormat the device, even if you use the same
passphrase(s). A LUKS header backup, or better a backup of the data on the
derived device may be a good idea. See the Cryptsetup FAQ on how to do this
right.

Note: If you don't use suspend device support, it's better to use completely
random keys for your encrypted swap device. See the section '2. Encrypted
swap partition(s)' in /usr/share/doc/cryptsetup/README.Debian for information
on how to setup this.

10. The "passdev" keyscript
----------------------------
If you have a keyfile on a removable device (e.g. a USB-key), you can use the
passdev keyscript. It will wait for the device to appear, mount it read-only,
read the key and then unmount the device.

The "key" part of /etc/crypttab will be interpreted as <device>:<path>[:<timeout>],
it is strongly recommended that you use one of the persistent device names from
/dev/disk/*, e.g. /dev/disk/by-label/myusbkey.

This is an example of a suitable line in cryptsetup:
cryptroot /dev/sda2 /dev/disk/by-label/myusbkey:/keys/root.key cipher=aes-xts-plain64,size=256,hash=sha1,keyscript=passdev

The above line would cause the boot to pause until /dev/disk/by-label/myusbkey
appears in the fs, then mount that device and use the file /keys/root.key
on the device as the key (without any hashing) as the key for the fs.

The timeout option has to be in seconds.

If any modules are required in order to mount the filesystem on the removable
device, then initramfs-tools needs to be configured to add these modules to
the initramfs. This can be done by listing the required modules in
/etc/initramfs-tools/modules.

11. Limitation: renaming of target name for encrypted root device
-----------------------------------------------------------------
As spotted by Adam Lee in bug report #671037[1], it's not possible to simply
rename the target name for encrypted root devices. It breaks the initramfs
creation process. The bug report submitter found a solution to work around this
limitation:

0. enter another system (like livecd)
1. open luks device with the new name, change the target name to the new one
2. chroot into it (now, the current target name is the same as it in conf)
3. update-initramfs -u
4. reboot

[1] http://bugs.debian.org/671037

 -- David Härdeman <david@hardeman.nu>
 -- Jonas Meurer <mejo@debian.org>  Thu, 01 Nov 2012 13:44:31 +0100