dm-crypt

dm-crypt is a transparent disk encryption subsystem in Linux kernel versions 2.6 and later and in DragonFly BSD. It is part of the device mapper infrastructure, and uses cryptographic routines from the kernel's Crypto API. Unlike its predecessor cryptoloop, dm-crypt was designed to support advanced modes of operation, such as XTS, LRW and ESSIV (see disk encryption theory for further information), in order to avoid watermarking attacks.[1] In addition to that, dm-crypt also addresses some reliability problems of cryptoloop.[2]

dm-crypt is implemented as a device mapper target and may be stacked on top of other device mapper transformations. It can thus encrypt whole disks (including removable media), partitions, software RAID volumes, logical volumes, as well as files. It appears as a block device, which can be used to back file systems, swap or as an LVM physical volume.

Some Linux distributions support the use of dm-crypt on the root file system. These distributions use initrd to prompt the user to enter a passphrase at the console, or insert a smart card prior to the normal boot process.[3]

Frontends

The dm-crypt device mapper target resides entirely in kernel space, and is only concerned with encryption of the block device  it does not interpret any data itself. It relies on user space front-ends to create and activate encrypted volumes, and manage authentication. At least two frontends are currently available: cryptsetup and cryptmount.

cryptsetup

cryptsetup
Original author(s)Jana Saout, Clemens Fruhwirth, Milan Broz[4]
Stable release
2.2.1 / 6 September 2019 (2019-09-06)[5]
Written inC
Operating systemUnix-like
Platformx86, x86-64, ARMv8, ARMv7, ppc64le, MIPS
Size7 MB
Available in16 languages[6]
List of languages
English, Portuguese, Chinese (Simplified), Czech, Danish, Dutch, Finnish, French, German, Italian, Japanese, Polish, Russian, Spanish, Swedish, Ukrainian
TypeDisk encryption software
LicenseGPLv2[7]
Sub-Libraries:
LGPLv2.1+[8]
Websitegitlab.com/cryptsetup/cryptsetup

The cryptsetup command-line interface, by default, does not write any headers to the encrypted volume, and hence only provides the bare essentials: encryption settings have to be provided every time the disk is mounted (although usually employed with automated scripts), and only one key can be used per volume; the symmetric encryption key is directly derived from the supplied passphrase.

Because it lacks a "salt", using cryptsetup is less secure in this mode than is the case with Linux Unified Key Setup (LUKS).[9] However, the simplicity of cryptsetup makes it useful when combined with third-party software, for example, with smart card authentication.

cryptsetup also provides commands to deal with the LUKS on-disk format. This format provides additional features such as key management and key stretching (using PBKDF2), and remembers encrypted volume configuration across reboots.[3][10]

cryptmount

The cryptmount interface is an alternative to the "cryptsetup" tool that allows any user to mount and unmount a dm-crypt file system when needed, without needing superuser privileges after the device has been configured by a superuser.

Features

The fact that disk encryption (volume encryption) software like dm-crypt only deals with transparent encryption of abstract block devices gives it a lot of flexibility. This means that it can be used for encrypting any disk-backed file systems supported by the operating system, as well as swap space; write barriers implemented by file systems are preserved.[11][12] Encrypted volumes can be stored on disk partitions, logical volumes, whole disks as well as file-backed disk images (through the use of loop devices with the losetup utility). dm-crypt can also be configured to encrypt RAID volumes and LVM physical volumes.

dm-crypt can also be configured to provide pre-boot authentication through an initrd, thus encrypting all the data on a computer  except the bootloader, the kernel and the initrd image itself.[3]

When using the cipher block chaining mode of operation with predictable initialization vectors as other disk encryption software, the disk is vulnerable to watermarking attacks. This means that an attacker is able to detect the presence of specially crafted data on the disk. To address this problem in its predecessors, dm-crypt included provisions for more elaborate, disk encryption-specific modes of operation.[1] Support for ESSIV (encrypted salt-sector initialization vector) was introduced in Linux kernel version 2.6.10, LRW in 2.6.20 and XTS in 2.6.24.

The Linux Crypto API includes support for most popular block ciphers and hash functions, which are all usable with dm-crypt.

Crypted FS support include LUKS volumes, loop-AES and since Linux kernel 3.13, the TrueCrypt target called "tcw".[13][14][15]

Compatibility

dm-crypt and LUKS encrypted disks can be accessed and used under MS Windows using the now defunct FreeOTFE (formerly DoxBox, LibreCrypt), provided that the filesystem used is supported by Windows (e.g. FAT/FAT32/NTFS). Encrypted ext2 and ext3 filesystems are supported by using Ext2Fsd or so-called "Ext2 Installable File System for Windows";[16] FreeOTFE also supports them.

Cryptsetup/LUKS and the required infrastructure have also been implemented on the DragonFly BSD operating system.[17]

gollark: `fork` is cool though, you can use it to cheat at some game things.
gollark: For events on, well, windows mostly.
gollark: Doesn't Windows sort of have a general message queue system?
gollark: The whole in band signalling of terminal things is somewhat bee too.
gollark: Instead of silly command line arguments you would pass processes arbitrary JSONish objects.

See also

References

  1. Clemens Fruhwirth (2005-07-18). "New Methods in Hard Disk Encryption" (PDF). Vienna University of Technology. Retrieved 2007-04-20. Cite journal requires |journal= (help)
  2. Mike Peters (2004-06-08). "Encrypting partitions using dm-crypt and the 2.6 series kernel". Archived from the original on 2012-07-11. Retrieved 2012-02-20. Cite journal requires |journal= (help)
  3. W. Michael Petullo (2007-01-18). "Disk encryption in Fedora: Past, present and future". Red Hat Magazine. Retrieved 2007-04-20.
  4. "AUTHORS". GitLab. Retrieved 7 September 2019.
  5. "Cryptsetup 2.2.1 Release Notes". GitLab. Retrieved 7 September 2019.
  6. "The cryptsetup textual domain". Translation Project. Retrieved 7 September 2019.
  7. "COPYING". GitLab. Retrieved 7 September 2019.
  8. "COPYING.LGPL". GitLab. Retrieved 7 September 2019.
  9. "cryptsetup FAQ".
  10. Clemens Fruhwirth (2004-07-15). "TKS1 – An anti-forensic, two level, and iterated key setup scheme" (PDF). draft. Retrieved 2006-12-12.
  11. Milan Broz (2012-04-24). "[dm-crypt] Does dm-crypt support journaling filesystem transactional guarantees?". saout.de. Retrieved 2014-07-08.
  12. Mikulas Patocka (2009-06-22). "kernel/git/torvalds/linux.git". Linux kernel source tree. kernel.org. Retrieved 2014-07-08.
  13. "dm-crypt: Linux kernel device-mapper crypto target – IV generators". cryptsetup. 2014-01-11. Retrieved 2015-04-05.
  14. "dm-crypt: Linux kernel device-mapper crypto target". Retrieved 2015-04-05.
  15. "[dm-devel] [PATCH 2/2] dm-crypt: Add TCW IV mode for old CBC TCRYPT containers". redhat.com. Retrieved 2014-06-17.
  16. "Ext2 IFS For Windows". fs-driver.org. Retrieved 15 February 2015.
  17. Alex Hornung (2010-07-23). "HEADS UP: dm, lvm, cryptsetup and initrd on master".
This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.