dm-crypt/Device encryption

An encrypted block device is protected by a key. A key is either:

• a passphrase: see Security#Passwords.
• a keyfile, see #Keyfiles.

Both key types have default maximum sizes: passphrases can be up to 512 characters and keyfiles up to 8192 KiB.

An important distinction of LUKS to note at this point is that the key is used to unlock the master-key of a LUKS-encrypted device and can be changed with root access. Other encryption modes do not support changing the key after setup, because they do not employ a master-key for the encryption. See Data-at-rest encryption#Block device encryption for details.

The cryptsetup action to set up a new dm-crypt device in LUKS encryption mode is . Unlike what the name implies, it does not format the device, but sets up the LUKS device header and encrypts the master-key with the desired cryptographic options.

In order to create a new LUKS container with the compiled-in defaults listed by , simply execute:

# cryptsetup luksFormat device

As of cryptsetup 2.4.0, this is equivalent to:

# cryptsetup --type luks2 --cipher aes-xts-plain64 --hash sha256 --iter-time 2000 --key-size 256 --pbkdf argon2id --use-urandom --verify-passphrase luksFormat device

Defaults are compared with a cryptographically higher specification example in the table below, with accompanying comments:

The properties of LUKS features and options are described in the LUKS1 (pdf) and LUKS2 (pdf) specifications.

From cryptsetup FAQ§2.1 and §3.4:

The unlock time for a key-slot [...] is calculated when setting a passphrase. By default it is 1 second (2 seconds for LUKS2). [...]

Passphrase iteration count is based on time and hence security level depends on CPU power of the system the LUKS container is created on. [...]

If you set a passphrase on a fast machine and then unlock it on a slow machine, the unlocking time can be much longer.

As such, it is better to always create a container on the machine where it will be most often accessed.

Read the rest of those sections for advice on how to correctly adjust the iteration count should the need arise.

See Advanced Format#dm-crypt.

In dm-crypt plain mode, there is no master-key on the device, hence, there is no need to set it up. Instead the encryption options to be employed are used directly to create the mapping between an encrypted disk and a named device. The mapping can be created against a partition or a full device. In the latter case not even a partition table is needed.

To create a plain mode mapping with cryptsetup's default parameters:

# cryptsetup options open --type plain device dmname

Executing it will prompt for a password, which should have very high entropy. Below a comparison of default parameters with the example in dm-crypt/Encrypting an entire system#Plain dm-crypt.

Using the device , the above right column example results in:

# cryptsetup --cipher=aes-xts-plain64 --offset=0 --key-file=/dev/sdZ --key-size=512 open --type=plain /dev/sdX enc

Unlike encrypting with LUKS, the above command must be executed in full whenever the mapping needs to be re-established, so it is important to remember the cipher, hash and key file details. We can now check that the mapping has been made:

# fdisk -l

An entry should now exist for .

In order to setup a partition as an encrypted LUKS partition execute:

# cryptsetup luksFormat device

You will then be prompted to enter a password and verify it.

See #Encryption options for LUKS mode for command line options.

You can check the results with:

# cryptsetup luksDump device

You will note that the dump not only shows the cipher header information, but also the key-slots in use for the LUKS partition.

The following example will create an encrypted root partition on /dev/sda1 using the default AES cipher in XTS mode with an effective 256-bit encryption

# cryptsetup -s 512 luksFormat /dev/sda1

When creating a new LUKS encrypted partition, a keyfile may be associated with the partition on its creation using:

# cryptsetup luksFormat device /path/to/mykeyfile

See #Keyfiles for instructions on how to generate and manage keyfiles.

Once the LUKS partitions have been created, they can then be unlocked.

The unlocking process will map the partitions to a new device name using the device mapper. This alerts the kernel that is actually an encrypted device and should be addressed through LUKS using the /dev/mapper/dm_name so as not to overwrite the encrypted data. To guard against accidental overwriting, read about the possibilities to backup the cryptheader after finishing setup.

In order to open an encrypted LUKS partition execute:

# cryptsetup open device dm_name

You will then be prompted for the password to unlock the partition. Usually the device mapped name is descriptive of the function of the partition that is mapped. For example the following unlocks a root luks partition /dev/sda1 and maps it to device mapper named :

# cryptsetup open /dev/sda1 root 

Once opened, the root partition device address would be instead of the partition (e.g. /dev/sda1).

For setting up LVM ontop the encryption layer the device file for the decrypted volume group would be anything like instead of /dev/sda1. LVM will then give additional names to all logical volumes created, e.g. and .

In order to write encrypted data into the partition it must be accessed through the device mapped name. The first step of access will typically be to create a file system. For example:

# mkfs -t ext4 /dev/mapper/root

The device can then be mounted like any other partition.

To close the LUKS container, unmount the partition and do:

# cryptsetup close root

See Trusted Platform Module#Data-at-rest encryption with LUKS.

The creation and subsequent access of a dm-crypt plain mode encryption both require not more than using the cryptsetup action with correct parameters. The following shows that with two examples of non-root devices, but adds a quirk by stacking both (i.e. the second is created inside the first). Obviously, stacking the encryption doubles overhead. The usecase here is simply to illustrate another example of the cipher option usage.

A first mapper is created with cryptsetup's plain-mode defaults, as described in the table's left column above

# cryptsetup --type plain -v open /dev/sd''xY'' plain1

Enter passphrase: 
Command successful.

Now we add the second block device inside it, using different encryption parameters and with an (optional) offset, create a file system and mount it

# mkfs -t ext2 /dev/mapper/plain2
# mount -t ext2 /dev/mapper/plain2 /mnt
# echo "This is stacked. one passphrase per foot to shoot." > /mnt/stacked.txt

We close the stack to check access works

# cryptsetup close plain2
# cryptsetup close plain1

First, let us try to open the file system directly:

# cryptsetup --type plain --cipher=serpent-xts-plain64 --hash=sha256 --key-size=256 --offset=10 open /dev/sdxY plain2

Why that did not work? Because the "plain2" starting block (10) is still encrypted with the cipher from "plain1". It can only be accessed via the stacked mapper. The error is arbitrary though, trying a wrong passphrase or wrong options will yield the same. For dm-crypt plain mode, the action will not error out itself.

Trying again in correct order:

# cryptsetup close plain2    # dysfunctional mapper from previous try

dm-crypt will handle stacked encryption with some mixed modes too. For example LUKS mode could be stacked on the "plain1" mapper. Its header would then be encrypted inside "plain1" when that is closed.

Available for plain mode only is the option --shared. With it a single device can be segmented into different non-overlapping mappers. We do that in the next example, using a loopaes compatible cipher mode for "plain2" this time:

As the device tree shows both reside on the same level, i.e. are not stacked and "plain2" can be opened individually.

It is possible to define additional keys for the LUKS partition. This enables the user to create access keys for safe backup storage In so-called key escrow, one key is used for daily usage, another kept in escrow to gain access to the partition in case the daily passphrase is forgotten or a keyfile is lost/damaged. A different key-slot could also be used to grant access to a partition to a user by issuing a second key and later revoking it again.

Once an encrypted partition has been created, the initial keyslot 0 is created (if no other was specified manually). Additional keyslots are numbered from 1 to 7. Which keyslots are used can be seen by issuing

# cryptsetup luksDump /dev/device

Where is the block device containing the LUKS header. This and all the following commands in this section work on header backup files as well.

Adding new keyslots is accomplished with the action. For safety it will always, even for already unlocked devices, ask for a valid existing key (a passphrase for any existing slot) before a new one may be entered:

If is given, cryptsetup will add a new keyslot for additionalkeyfile. Otherwise it prompts for a new passphrase. To authorize the action with an existing keyfile, the or option followed by the "old" will try to unlock all available keyfile keyslots:

# cryptsetup luksAddKey /dev/device [/path/to/additionalkeyfile] -d /path/to/keyfile

If it is intended to use multiple keys and change or revoke them, the or -S option may be used to specify the slot:

To show an associated action in this example, we decide to change the key right away:

before continuing to remove it.

There are three different actions to remove keys from the header:

• removes a key by specifying its passphrase/key-file.
• removes a key by specifying its slot (needs another valid key). Obviously, this is extremely useful if you have forgotten a passphrase, lost a key-file, or have no access to it.
• removes all active keys.

For above warning it is good to know the key we want to keep is valid. An easy check is to unlock the device with the option, which will specify which slot it occupies:

# cryptsetup --test-passphrase -v open /dev/''device''

Enter passphrase for /dev/''device'': 
Key slot 1 unlocked.
Command successful.

Now we can remove the key added in the previous subsection using its passphrase:

If we had used the same passphrase for two keyslots, the first slot would be wiped now. Only executing it again would remove the second one.

Alternatively, we can specify the key slot:

Note that in both cases, no confirmation was required.

To re-iterate the warning above: If the same passphrase had been used for key slots 1 and 6, both would be gone now.

If the header of a LUKS encrypted partition gets destroyed, you will not be able to decrypt your data. It is just as much of a dilemma as forgetting the passphrase or damaging a key-file used to unlock the partition. Damage may occur by your own fault while re-partitioning the disk later or by third-party programs misinterpreting the partition table. Therefore, having a backup of the header and storing it on another disk might be a good idea.

Cryptsetup's action stores a binary backup of the LUKS header and keyslot area:

# cryptsetup luksHeaderBackup /dev/device --header-backup-file /mnt/backup/file.img

where is the partition containing the LUKS volume.

You can also back up the plain text header into ramfs and encrypt it with e.g. GPG before writing it to persistent storage:

# mount --mkdir -t ramfs ramfs /root/tmp
# cryptsetup luksHeaderBackup /dev/device --header-backup-file /root/tmp/file.img
# gpg2 --recipient User_ID --encrypt /root/tmp/file.img 
# cp /root/tmp/file.img.gpg /mnt/backup/
# umount /root/tmp

In order to evade restoring a wrong header, you can ensure it does work by using it as a remote first:

# mount /dev/mapper/test /mnt/test && ls /mnt/test 
# umount /mnt/test 
# cryptsetup close test 

Now that the check succeeded, the restore may be performed:

# cryptsetup luksHeaderRestore /dev/device --header-backup-file ./mnt/backup/file.img

Now that all the keyslot areas are overwritten; only active keyslots from the backup file are available after issuing the command.

The header always resides at the beginning of the device and a backup can be performed without access to cryptsetup as well. First you have to find out the payload offset of the crypted partition:

Second check the sector size of the drive

# fdisk -l /dev/''device'' | grep "Sector size"

Sector size (logical/physical): 512 bytes / 512 bytes

Now that you know the values, you can backup the header with a simple dd command:

# dd if=/dev/device of=/path/to/file.img bs=512 count=4040

and store it safely.

A restore can then be performed using the same values as when backing up:

# dd if=./file.img of=/dev/device bs=512 count=4040

The cryptsetup package features two options for re-encryption.

cryptsetup reencrypt

Argument to itself: Preferred method. Currently LUKS2 devices only. Actions can be performed online. Supports multiple parallel re-encryption jobs. Resilient to system failures. See cryptsetup(8) for more information.

cryptsetup-reencrypt

Legacy tool, supports LUKS1 in addition to LUKS2. Actions can be performed on unmounted devices only. Single process at a time. Sensitive to system failures. See for more information.

Both can be used to convert an existing unencrypted file system to a LUKS encrypted one or permanently remove LUKS encryption from a device (using ). As its name suggests it can also be used to re-encrypt an existing LUKS encrypted device, though, re-encryption is not possible for a detached LUKS header or other encryption modes (e.g. plain-mode). For re-encryption it is possible to change the #Encryption options for LUKS mode.

One application of re-encryption may be to secure the data again after a passphrase or keyfile has been compromised and one cannot be certain that no copy of the LUKS header has been obtained. For example, if only a passphrase has been shoulder-surfed but no physical/logical access to the device happened, it would be enough to change the respective passphrase/key only (#Key management).

The following shows an example to encrypt an unencrypted file system partition and a re-encryption of an existing LUKS device.

A LUKS encryption header is always stored at the beginning of the device. Since an existing file system will usually be allocated all partition sectors, the first step is to shrink it to make space for the LUKS header.

The default LUKS2 header requires 16 MiB. If the current file system occupies all the available space, we will have to shrink it at least that much. To shrink an existing ext4 file system on to its current possible minimum:

# umount /mnt

Now we encrypt it, using the default cipher we do not have to specify it explicitly:

# cryptsetup reencrypt --encrypt --reduce-device-size 16M /dev/sd''xY''

WARNING!

========

This will overwrite data on LUKS2-temp-12345678-9012-3456-7890-123456789012.new irrevocably.

Are you sure? (Type 'yes' in capital letters): YES
Enter passphrase for LUKS2-temp-12345678-9012-3456-7890-123456789012.new: 
Verify passphrase: 

After it finished, the whole partition is encrypted, not only the space the file system was shrunk to. As a final step we extend the original ext4 file system to occupy all available space again, on the now encrypted partition:

# mount /dev/mapper/recrypt /mnt

The file system is now ready to use. You may want to add it to your crypttab.

In this example an existing LUKS device is re-encrypted.

In order to re-encrypt a device with its existing encryption options, they do not need to be specified:

# cryptsetup-reencrypt /dev/sd''xY''

Existing keys are retained when re-encrypting a device with a different cipher and/or hash. Another use case is to re-encrypt LUKS devices which have non-current encryption options. Apart from above warning on specifying options correctly, the ability to change the LUKS header may also be limited by its size. For example, if the device was initially encrypted using a CBC mode cipher and 128 bit key-size, the LUKS header will be half the size of above mentioned sectors:

While it is possible to upgrade the encryption of such a device, it is currently only feasible in two steps. First, re-encrypting with the same encryption options, but using the option to make further space for the larger LUKS header. Second, re-encypt the whole device again with the desired cipher. For this reason and the fact that a backup should be created in any case, creating a new, fresh encrypted device to restore into is always the faster option.

The cryptsetup package has option that needed for conversion between LUKS1 and LUKS2 container types. The argument is required.

Migration from LUKS1 to LUKS2:

# cryptsetup convert --type luks2 /dev/sdxY

Rollback to LUKS1 (for example, to boot from GRUB with encrypted /boot):

# cryptsetup convert --type luks1 /dev/sdxY

Cannot convert to LUKS1 format - keyslot 0 is not LUKS1 compatible.

# cryptsetup luksConvertKey --pbkdf pbkdf2 /dev/sdxY

Assume that an encrypted loopback file system is stored in a file , looped to , mapped to secret and mounted on , as in the example at dm-crypt/Encrypting a non-root file system#File container.

If the container file is currently mapped and/or mounted, unmount and/or close it:

# umount /mnt/secret
# cryptsetup close secret
# losetup -d /dev/loop0

Next, expand the container file with the size of the data you want to add. In this example, the file will be expanded with 1M * 1024, which is 1G.

# dd if=/dev/urandom bs=1M count=1024 | cat - >> /bigsecret

Now map the container to the loop device:

# losetup /dev/loop0 /bigsecret
# cryptsetup open /dev/loop0 secret

After this, resize the encrypted part of the container to the new maximum size of the container file:

# cryptsetup resize secret

Finally, perform a file system check and, if it is ok, resize it (example for ext2/3/4):

# e2fsck -f /dev/mapper/secret
# resize2fs /dev/mapper/secret

You can now mount the container again:

# mount /dev/mapper/secret /mnt/secret

If the device was formatted with integrity support (e.g., ) and the backing block device is shrinked, it cannot be opened with this error: .

To fix this issue without wiping the device again, it can be formatted with the previous master key (keeping the per-sector tags valid).

# cryptsetup luksDump /dev/sdX2 --dump-master-key --master-key-file=/tmp/masterkey-in-tmpfs.key
# cryptsetup luksFormat /dev/sdX2 --type luks2 --integrity hmac-sha256 --master-key-file=/tmp/masterkey-in-tmpfs.key --integrity-no-wipe
# rm /tmp/masterkey-in-tmpfs.key

This is a keyfile containing a simple passphrase. The benefit of this type of keyfile is that if the file is lost the data it contained is known and hopefully easily remembered by the owner of the encrypted volume. However the disadvantage is that this does not add any security over entering a passphrase during the initial system start.

Example: 1234

This is a keyfile containing a block of random characters. The benefit of this type of keyfile is that it is much more resistant to dictionary attacks than a simple passphrase. An additional strength of keyfiles can be utilized in this situation which is the length of data used. Since this is not a string meant to be memorized by a person for entry, it is trivial to create files containing thousands of random characters as the key. The disadvantage is that if this file is lost or changed, it will most likely not be possible to access the encrypted volume without a backup passphrase.

Example:

This is a binary file that has been defined as a keyfile. When identifying files as candidates for a keyfile, it is recommended to choose files that are relatively static such as photos, music, video clips. The benefit of these files is that they serve a dual function which can make them harder to identify as keyfiles. Instead of having a text file with a large amount of random text, the keyfile would look like a regular image file or music clip to the casual observer. The disadvantage is that if this file is lost or changed, it will most likely not be possible to access the encrypted volume without a backup passphrase. Additionally, there is a theoretical loss of randomness when compared to a randomly generated text file. This is due to the fact that images, videos and music have some intrinsic relationship between neighboring bits of data that does not exist for a random text file. However this is controversial and has never been exploited publicly.

Example: images, text, video, ...

A keyfile can be of arbitrary content and size.

Here dd is used to generate a keyfile of 2048 random bytes, storing it in the file :

# dd bs=512 count=4 if=/dev/random of=/etc/mykeyfile iflag=fullblock

If you are planning to store the keyfile on an external device, you can also simply change the outputfile to the corresponding directory:

# dd bs=512 count=4 if=/dev/random of=/media/usbstick/mykeyfile iflag=fullblock

To deny any access for other users than :

# chmod 600 /etc/mykeyfile

If you stored your temporary keyfile on a physical storage device, and want to delete it, remember to not just remove the keyfile later on, but use something like

# shred --remove --zero mykeyfile

to securely overwrite it. For overaged file systems like FAT or ext2 this will suffice while in the case of journaling file systems, flash memory hardware and other cases it is highly recommended to wipe the entire device.

Alternatively, you can mount a ramfs for storing the keyfile temporarily:

# mount --mkdir -t ramfs ramfs /root/myramfs
# cd /root/myramfs

The advantage is that it resides in RAM and not on a physical disk, therefore it can not be recovered after unmounting the ramfs. After copying the keyfile to another secure and persistent file system, unmount the ramfs again with

# umount /root/myramfs

Add a keyslot for the keyfile to the LUKS header:

Use the option when opening the LUKS device:

# cryptsetup open /dev/sda2 dm_name --key-file /etc/mykeyfile

This is simply a matter of configuring mkinitcpio to include the necessary modules or files and configuring the cryptkey kernel parameter to know where to find the keyfile.

Two cases are covered below:

1. Using a keyfile stored on an external medium (e.g. a USB stick)
2. Using a keyfile embedded in the initramfs

You have to add the kernel module for the drive's file system to the MODULES array in . For example, add ext4 if the file system is Ext4 or vfat in case it is FAT:

MODULES=(vfat)

If there are messages about bad superblock and bad codepage at boot, then you need an extra codepage module to be loaded. For instance, you may need module for codepage.

Regenerate the initramfs.

• For a busybox-based initramfs using the encrypt hook, see dm-crypt/System configuration#cryptkey.
• For a systemd based initramfs using the sd-encrypt hook, see dm-crypt/System configuration#rd.luks.key.

This method allows to use a specially named keyfile that will be embedded in the initramfs and picked up by the hook to unlock the root file system () automatically. It may be useful to apply when using the GRUB early cryptodisk feature, in order to avoid entering two passphrases during boot.

The hook lets the user specify a keyfile with the cryptkey kernel parameter: in the case of initramfs, the syntax is . See dm-crypt/System configuration#cryptkey. Besides, this kernel parameter defaults to use , and if the initramfs contains a valid key with this name, decryption will occur automatically without the need to configure the cryptkey parameter.

If using instead of , specify the location of the keyfile with the rd.luks.key kernel parameter: in the case of initramfs, the syntax is . See dm-crypt/System configuration#rd.luks.key. This kernel parameter defaults to using (where is the used for decryption in #Encrypting devices with cryptsetup) and can be omitted if initramfs contains a valid key with this path.

Generate the keyfile, give it suitable permissions and add it as a LUKS key:

# dd bs=512 count=4 if=/dev/random of=/crypto_keyfile.bin iflag=fullblock
# chmod 600 /crypto_keyfile.bin
# cryptsetup luksAddKey /dev/sdX# /crypto_keyfile.bin

Include the key in mkinitcpio's FILES array:

/etc/mkinitcpio.conf

FILES=(/crypto_keyfile.bin)

Finally regenerate the initramfs.

On the next reboot you should only have to enter your container decryption passphrase once.

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