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authorDaniel Baumann <daniel.baumann@progress-linux.org>2024-04-17 08:06:26 +0000
committerDaniel Baumann <daniel.baumann@progress-linux.org>2024-04-17 08:06:26 +0000
commit1660d4b7a65d9ad2ce0deaa19d35579ca4084ac5 (patch)
tree6cf8220b628ebd2ccfc1375dd6516c6996e9abcc /docs/v2.0.0-ReleaseNotes
parentInitial commit. (diff)
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Signed-off-by: Daniel Baumann <daniel.baumann@progress-linux.org>
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+Cryptsetup 2.0.0 Release Notes
+==============================
+Stable release with experimental features.
+
+This version introduces a new on-disk LUKS2 format.
+
+The legacy LUKS (referenced as LUKS1) will be fully supported
+forever as well as a traditional and fully backward compatible format.
+
+NOTE: This version changes soname of libcryptsetup library and increases
+major version for all public symbols.
+Most of the old functions are fully backward compatible, so only
+recompilation of programs should be needed.
+
+Please note that authenticated disk encryption, non-cryptographic
+data integrity protection (dm-integrity), use of Argon2 Password-Based
+Key Derivation Function and the LUKS2 on-disk format itself are new
+features and can contain some bugs.
+
+To provide all security features of authenticated encryption we need
+better nonce-reuse resistant algorithm in kernel (see note below).
+For now, please use authenticated encryption as experimental feature.
+
+Please do not use LUKS2 without properly configured backup or in
+production systems that need to be compatible with older systems.
+
+Changes since version 2.0.0-RC1
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+* Limit KDF requested (for format) memory by available physical memory.
+ On some systems too high requested amount of memory causes OOM killer
+ to kill the process (instead of returning ENOMEM).
+ We never try to use more than half of available physical memory.
+
+* Ignore device alignment if it is not multiple of minimal-io.
+ Some USB enclosures seems to report bogus topology info that
+ prevents to use LUKS detached header.
+
+Changes since version 2.0.0-RC0
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
+* Enable to use system libargon2 instead of bundled version.
+ Renames --disable-argon2 to --disable-internal-argon2 option
+ and adds --enable-libargon2 flag to allow system libargon2.
+
+* Changes in build system (Automake)
+ - The build system now uses non-recursive automake (except for tests).
+ (Tools binaries are now located in buildroot directory.)
+ - New --disable-cryptsetup option to disable build of cryptsetup tool.
+ - Enable build of cryptsetup-reencrypt by default.
+
+* Install tmpfiles.d configuration for LUKS2 locking directory.
+ You can overwrite this using --with-tmpfilesdir configure option.
+ If your distro does not support tmpfiles.d directory, you have
+ to create locking directory (/run/lock/cryptsetup) in cryptsetup
+ package (or init scripts).
+
+* Adds limited support for offline reencryption of LUKS2 format.
+
+* Decrease size of testing images (and the whole release archive).
+
+* Fixes for several memory leaks found by Valgrind and Coverity tools.
+
+* Fixes for several typos in man pages and error messages.
+
+* LUKS header file in luksFormat is now automatically created
+ if it does not exist.
+
+* Do not allow resize if device size is not aligned to sector size.
+
+Cryptsetup 2.0.0 RC0 Release Notes
+==================================
+
+Important features
+~~~~~~~~~~~~~~~~~~
+
+* New command integritysetup: support for the new dm-integrity kernel target.
+
+ The dm-integrity is a new kernel device-mapper target that introduces
+ software emulation of per-sector integrity fields on the disk sector level.
+ It is available since Linux kernel version 4.12.
+
+ The provided per-sector metadata fields can be used for storing a data
+ integrity checksum (for example CRC32).
+ The dm-integrity implements data journal that enforces atomic update
+ of a sector and its integrity metadata.
+
+ Integritysetup is a CLI utility that can setup standalone dm-integrity
+ devices (that internally check integrity of data).
+
+ Integritysetup is intended to be used for settings that require
+ non-cryptographic data integrity protection with no data encryption.
+ For setting integrity protected encrypted devices, see disk authenticated
+ encryption below.
+
+ Note that after formatting the checksums need to be initialized;
+ otherwise device reads will fail because of integrity errors.
+ Integritysetup by default tries to wipe the device with zero blocks
+ to avoid this problem. Device wipe can be time-consuming, you can skip
+ this step by specifying --no-wipe option.
+ (But note that not wiping device can cause some operations to fail
+ if a write is not multiple of page size and kernel page cache tries
+ to read sectors with not yet initialized checksums.)
+
+ The default setting is tag size 4 bytes per-sector and CRC32C protection.
+ To format device with these defaults:
+ $ integritysetup format <device>
+ $ integritysetup open <device> <name>
+
+ Note that used algorithm (unlike tag size) is NOT stored in device
+ kernel superblock and if you use different algorithm, you MUST specify
+ it in every open command, for example:
+ $ integritysetup format <device> --tag-size 32 --integrity sha256
+ $ integritysetup open <device> <name> --integrity sha256
+
+ For more info, see integrity man page.
+
+* Veritysetup command can now format and activate dm-verity devices
+ that contain Forward Error Correction (FEC) (Reed-Solomon code is used).
+ This feature is used on most of Android devices already (available since
+ Linux kernel 4.5).
+
+ There are new options --fec-device, --fec-offset to specify data area
+ with correction code and --fec-roots that set Redd-Solomon generator roots.
+ This setting can be used for format command (veritysetup will calculate
+ and store RS codes) or open command (veritysetup configures kernel
+ dm-verity to use RS codes).
+
+ For more info see veritysetup man page.
+
+* Support for larger sector sizes for crypt devices.
+
+ LUKS2 and plain crypt devices can be now configured with larger encryption
+ sector (typically 4096 bytes, sector size must be the power of two,
+ maximal sector size is 4096 bytes for portability).
+ Large sector size can decrease encryption overhead and can also help
+ with some specific crypto hardware accelerators that perform very
+ badly with 512 bytes sectors.
+
+ Note that if you configure such a larger sector of the device that does use
+ smaller physical sector, there is a possibility of a data corruption during
+ power fail (partial sector writes).
+
+ WARNING: If you use different sector size for a plain device after data were
+ stored, the decryption will produce garbage.
+
+ For LUKS2, the sector size is stored in metadata and cannot be changed later.
+
+LUKS2 format and features
+~~~~~~~~~~~~~~~~~~~~~~~~~
+The LUKS2 is an on-disk storage format designed to provide simple key
+management, primarily intended for Full Disk Encryption based on dm-crypt.
+
+The LUKS2 is inspired by LUKS1 format and in some specific situations (most
+of the default configurations) can be converted in-place from LUKS1.
+
+The LUKS2 format is designed to allow future updates of various
+parts without the need to modify binary structures and internally
+uses JSON text format for metadata. Compilation now requires the json-c library
+that is used for JSON data processing.
+
+On-disk format provides redundancy of metadata, detection
+of metadata corruption and automatic repair from metadata copy.
+
+NOTE: For security reasons, there is no redundancy in keyslots binary data
+(encrypted keys) but the format allows adding such a feature in future.
+
+NOTE: to operate correctly, LUKS2 requires locking of metadata.
+Locking is performed by using flock() system call for images in file
+and for block device by using a specific lock file in /run/lock/cryptsetup.
+
+This directory must be created by distribution (do not rely on internal
+fallback). For systemd-based distribution, you can simply install
+scripts/cryptsetup.conf into tmpfiles.d directory.
+
+For more details see LUKS2-format.txt and LUKS2-locking.txt in the docs
+directory. (Please note this is just overview, there will be more formal
+documentation later.)
+
+LUKS2 use
+~~~~~~~~~
+
+LUKS2 allows using all possible configurations as LUKS1.
+
+To format device as LUKS2, you have to add "--type luks2" during format:
+
+ $ cryptsetup luksFormat --type luks2 <device>
+
+All commands issued later will recognize the new format automatically.
+
+The newly added features in LUKS2 include:
+
+* Authenticated disk (sector) encryption (EXPERIMENTAL)
+
+ Legacy Full disk encryption (FDE), for example, LUKS1, is a length-preserving
+ encryption (plaintext is the same size as a ciphertext).
+ Such FDE can provide data confidentiality, but cannot provide sound data
+ integrity protection.
+
+ Full disk authenticated encryption is a way how to provide both
+ confidentiality and data integrity protection. Integrity protection here means
+ not only detection of random data corruption (silent data corruption) but also
+ prevention of an unauthorized intentional change of disk sector content.
+
+ NOTE: Integrity protection of this type cannot prevent a replay attack.
+ An attacker can replace the device or its part of the old content, and it
+ cannot be detected.
+ If you need such protection, better use integrity protection on a higher layer.
+
+ For data integrity protection on the sector level, we need additional
+ per-sector metadata space. In LUKS2 this space is provided by a new
+ device-mapper dm-integrity target (available since kernel 4.12).
+ Here the integrity target provides only reliable per-sector metadata store,
+ and the whole authenticated encryption is performed inside dm-crypt stacked
+ over the dm-integrity device.
+
+ For encryption, Authenticated Encryption with Additional Data (AEAD) is used.
+ Every sector is processed as a encryption request of this format:
+
+ |----- AAD -------|------ DATA -------|-- AUTH TAG --|
+ | (authenticated) | (auth+encryption) | |
+ | sector_LE | IV | sector in/out | tag in/out |
+
+ AEAD encrypts the whole sector and also authenticates sector number
+ (to detect sector relocation) and also authenticates Initialization Vector.
+
+ AEAD encryption produces encrypted data and authentication tag.
+ The authenticated tag is then stored in per-sector metadata space provided
+ by dm-integrity.
+
+ Most of the current AEAD algorithms requires IV as a nonce, value that is
+ never reused. Because sector number, as an IV, cannot be used in this
+ environment, we use a new random IV (IV is a random value generated by system
+ RNG on every write). This random IV is then stored in the per-sector metadata
+ as well.
+
+ Because the authentication tag (and IV) requires additional space, the device
+ provided for a user has less capacity. Also, the data journalling means that
+ writes are performed twice, decreasing throughput.
+
+ This integrity protection works better with SSDs. If you want to ignore
+ dm-integrity data journal (because journalling is performed on some higher
+ layer or you just want to trade-off performance to safe recovery), you can
+ switch journal off with --integrity-no-journal option.
+ (This flag can be stored persistently as well.)
+
+ Note that (similar to integritysetup) the device read will fail if
+ authentication tag is not initialized (no previous write).
+ By default cryptsetup run wipe of a device (writing zeroes) to initialize
+ authentication tags. This operation can be very time-consuming.
+ You can skip device wipe using --integrity-no-wipe option.
+
+ To format LUKS2 device with integrity protection, use new --integrity option.
+
+ For now, there are very few AEAD algorithms that can be used, and some
+ of them are known to be problematic. In this release we support only
+ a few of AEAD algorithms (options are for now hard coded), later this
+ extension will be completely algorithm-agnostic.
+
+ For testing of authenticated encryption, these algorithms work for now:
+
+ 1) aes-xts-plain64 with hmac-sha256 or hmac-sha512 as the authentication tag.
+ (Common FDE mode + independent authentication tag. Authentication key
+ for HMAC is independently generated. This mode is very slow.)
+ $ cryptsetup luksFormat --type luks2 <device> --cipher aes-xts-plain64 --integrity hmac-sha256
+
+ 2) aes-gcm-random (native AEAD mode)
+ DO NOT USE in production! The GCM mode uses only 96-bit nonce,
+ and possible collision means fatal security problem.
+ GCM mode has very good hardware support through AES-NI, so it is useful
+ for performance testing.
+ $ cryptsetup luksFormat --type luks2 <device> --cipher aes-gcm-random --integrity aead
+
+ 3) ChaCha20 with Poly1305 authenticator (according to RFC7539)
+ $ cryptsetup luksFormat --type luks2 <device> --cipher chacha20-random --integrity poly1305
+
+ To specify AES128/AES256 just specify proper key size (without possible
+ authentication key). Other symmetric ciphers, like Serpent or Twofish,
+ should work as well. The mode 1) and 2) should be compatible with IEEE 1619.1
+ standard recommendation.
+
+ There will be better suitable authenticated modes available soon
+ For now we are just preparing framework to enable it (and hopefully improve security of FDE).
+
+ FDE authenticated encryption is not a replacement for filesystem layer
+ authenticated encryption. The goal is to provide at least something because
+ data integrity protection is often completely ignored in today systems.
+
+* New memory-hard PBKDF
+
+ LUKS1 introduced Password-Based Key Derivation Function v2 as a tool to
+ increase attacker cost for a dictionary and brute force attacks.
+ The PBKDF2 uses iteration count to increase time of key derivation.
+ Unfortunately, with modern GPUs, the PBKDF2 calculations can be run
+ in parallel and PBKDF2 can no longer provide the best available protection.
+ Increasing iteration count just cannot prevent massive parallel dictionary
+ password attacks in long-term.
+
+ To solve this problem, a new PBKDF, based on so-called memory-hard functions
+ can be used. Key derivation with memory-hard function requires a certain
+ amount of memory to compute its output. The memory requirement is very
+ costly for GPUs and prevents these systems to operate effectively,
+ increasing cost for attackers.
+
+ LUKS2 introduces support for Argon2i and Argon2id as a PBKDF.
+ Argon2 is the winner of Password Hashing Competition and is currently
+ in final RFC draft specification.
+
+ For now, libcryptsetup contains the embedded copy of reference implementation
+ of Argon2 (that is easily portable to all architectures).
+ Later, once this function is available in common crypto libraries, it will
+ switch to external implementation. (This happened for LUKS1 and PBKDF2
+ as well years ago.)
+ With using reference implementation (that is not optimized for speed), there
+ is some performance penalty. However, using memory-hard PBKDF should still
+ significantly complicate GPU-optimized dictionary and brute force attacks.
+
+ The Argon2 uses three costs: memory, time (number of iterations) and parallel
+ (number of threads).
+ Note that time and memory cost highly influences each other (accessing a lot
+ of memory takes more time).
+
+ There is a new benchmark that tries to calculate costs to take similar way as
+ in LUKS1 (where iteration is measured to take 1-2 seconds on user system).
+ Because now there are more cost variables, it prefers time cost (iterations)
+ and tries to find required memory that fits. (IOW required memory cost can be
+ lower if the benchmarks are not able to find required parameters.)
+ The benchmark cannot run too long, so it tries to approximate next step
+ for benchmarking.
+
+ For now, default LUKS2 PBKDF algorithm is Argon2i (data independent variant)
+ with memory cost set to 128MB, time to 800ms and parallel thread according
+ to available CPU cores but no more than 4.
+
+ All default parameters can be set during compile time and also set on
+ the command line by using --pbkdf, --pbkdf-memory, --pbkdf-parallel and
+ --iter-time options.
+ (Or without benchmark directly by using --pbkdf-force-iterations, see below.)
+
+ You can still use PBKDF2 even for LUKS2 by specifying --pbkdf pbkdf2 option.
+ (Then only iteration count is applied.)
+
+* Use of kernel keyring
+
+ Kernel keyring is a storage for sensitive material (like cryptographic keys)
+ inside Linux kernel.
+
+ LUKS2 uses keyring for two major functions:
+
+ - To store volume key for dm-crypt where it avoids sending volume key in
+ every device-mapper ioctl structure. Volume key is also no longer directly
+ visible in a dm-crypt mapping table. The key is not available for the user
+ after dm-crypt configuration (obviously except direct memory scan).
+ Use of kernel keyring can be disabled in runtime by --disable-keyring option.
+
+ - As a tool to automatically unlock LUKS device if a passphrase is put into
+ kernel keyring and proper keyring token is configured.
+
+ This allows storing a secret (passphrase) to kernel per-user keyring by
+ some external tool (for example some TPM handler) and LUKS2, if configured,
+ will automatically search in the keyring and unlock the system.
+ For more info see Tokens section below.
+
+* Persistent flags
+ The activation flags (like allow-discards) can be stored in metadata and used
+ automatically by all later activations (even without using crypttab).
+
+ To store activation flags permanently, use activation command with required
+ flags and add --persistent option.
+
+ For example, to mark device to always activate with TRIM enabled,
+ use (for LUKS2 type):
+
+ $ cryptsetup open <device> <name> --allow-discards --persistent
+
+ You can check persistent flags in dump command output:
+
+ $ cryptsetup luksDump <device>
+
+* Tokens and auto-activation
+
+ A LUKS2 token is an object that can be described "how to get passphrase or key"
+ to unlock particular keyslot.
+ (Also it can be used to store any additional metadata, and with
+ the libcryptsetup interface it can be used to define user token types.)
+
+ Cryptsetup internally implements keyring token. Cryptsetup tries to use
+ available tokens before asking for the passphrase. For keyring token,
+ it means that if the passphrase is available under specified identifier
+ inside kernel keyring, the device is automatically activated using this
+ stored passphrase.
+
+ Example of using LUKS2 keyring token:
+
+ # Adding token to metadata with "my_token" identifier (by default it applies to all keyslots).
+ $ cryptsetup token add --key-description "my_token" <device>
+
+ # Storing passphrase to user keyring (this can be done by an external application)
+ $ echo -n <passphrase> | keyctl padd user my_token @u
+
+ # Now cryptsetup activates automatically if it finds correct passphrase
+ $ cryptsetup open <device> <name>
+
+ The main reason to use tokens this way is to separate possible hardware
+ handlers from cryptsetup code.
+
+* Keyslot priorities
+
+ LUKS2 keyslot can have a new priority attribute.
+ The default is "normal". The "prefer" priority tell the keyslot to be tried
+ before other keyslots. Priority "ignore" means that keyslot will never be
+ used if not specified explicitly (it can be used for backup administrator
+ passwords that are used only situations when a user forgets own passphrase).
+
+ The priority of keyslot can be set with new config command, for example
+ $ cryptsetup config <device> --key-slot 1 --priority prefer
+
+ Setting priority to normal will reset slot to normal state.
+
+* LUKS2 label and subsystem
+
+ The header now contains additional fields for label and subsystem (additional
+ label). These fields can be used similar to filesystem label and will be
+ visible in udev rules to possible filtering. (Note that blkid do not yet
+ contain the LUKS scanning code).
+
+ By default both labels are empty. Label and subsystem are always set together
+ (no option means clear the label) with the config command:
+
+ $ cryptsetup config <device> --label my_device --subsystem ""
+
+* In-place conversion form LUKS1
+
+ To allow easy testing and transition to the new LUKS2 format, there is a new
+ convert command that allows in-place conversion from the LUKS1 format and,
+ if there are no incompatible options, also conversion back from LUKS2
+ to LUKS1 format.
+
+ Note this command can be used only on some LUKS1 devices (some device header
+ sizes are not supported).
+ This command is dangerous, never run it without header backup!
+ If something fails in the middle of conversion (IO error), the header
+ is destroyed. (Note that conversion requires move of keyslot data area to
+ a different offset.)
+
+ To convert header in-place to LUKS2 format, use
+ $ cryptsetup convert <device> --type luks2
+
+ To convert it back to LUKS1 format, use
+ $ cryptsetup convert <device> --type luks1
+
+ You can verify LUKS version with luksDump command.
+ $ cryptsetup luksDump <device>
+
+ Note that some LUKS2 features will make header incompatible with LUKS1 and
+ conversion will be rejected (for example using new Argon2 PBKDF or integrity
+ extensions). Some minor attributes can be lost in conversion.
+
+Other changes
+~~~~~~~~~~~~~
+
+* Explicit KDF iterations count setting
+
+ With new PBKDF interface, there is also the possibility to setup PBKDF costs
+ directly, avoiding benchmarks. This can be useful if device is formatted to be
+ primarily used on a different system.
+
+ The option --pbkdf-force-iterations is available for both LUKS1 and LUKS2
+ format. Using this option can cause device to have either very low or very
+ high PBKDF costs.
+ In the first case it means bad protection to dictionary attacks, in the second
+ case, it can mean extremely high unlocking time or memory requirements.
+ Use only if you are sure what you are doing!
+
+ Not that this setting also affects iteration count for the key digest.
+ For LUKS1 iteration count for digest will be approximately 1/8 of requested
+ value, for LUKS2 and "pbkdf2" digest minimal PBKDF2 iteration count (1000)
+ will be used. You cannot set lower iteration count than the internal minimum
+ (1000 for PBKDF2).
+
+ To format LUKS1 device with forced iteration count (and no benchmarking), use
+ $ cryptsetup luksFormat <device> --pbkdf-force-iterations 22222
+
+ For LUKS2 it is always better to specify full settings (do not rely on default
+ cost values).
+ For example, we can set to use Argon2id with iteration cost 5, memory 128000
+ and parallel set 1:
+ $ cryptsetup luksFormat --type luks2 <device> \
+ --pbkdf argon2id --pbkdf-force-iterations 5 --pbkdf-memory 128000 --pbkdf-parallel 1
+
+* VeraCrypt PIM
+
+ Cryptsetup can now also open VeraCrypt device that uses Personal Iteration
+ Multiplier (PIM). PIM is an integer value that user must remember additionally
+ to passphrase and influences PBKDF2 iteration count (without it VeraCrypt uses
+ a fixed number of iterations).
+
+ To open VeraCrypt device with PIM settings, use --veracrypt-pim (to specify
+ PIM on the command line) or --veracrypt-query-pim to query PIM interactively.
+
+* Support for plain64be IV
+
+ The plain64be is big-endian variant of plain64 Initialization Vector. It is
+ used in some images of hardware-based disk encryption systems. Supporting this
+ variant allows using dm-crypt to map such images through cryptsetup.
+
+* Deferral removal
+
+ Cryptsetup now can mark device for deferred removal by using a new option
+ --deferred. This means that close command will not fail if the device is still
+ in use, but will instruct the kernel to remove the device automatically after
+ use count drops to zero (for example, once the filesystem is unmounted).
+
+* A lot of updates to man pages and many minor changes that would make this
+ release notes too long ;-)
+
+Libcryptsetup API changes
+~~~~~~~~~~~~~~~~~~~~~~~~~
+
+These API functions were removed, libcryptsetup no longer handles password
+retries from terminal (application should handle terminal operations itself):
+ crypt_set_password_callback;
+ crypt_set_timeout;
+ crypt_set_password_retry;
+ crypt_set_password_verify;
+
+This call is removed (no need to keep typo backward compatibility,
+the proper function is crypt_set_iteration_time :-)
+ crypt_set_iterarion_time;
+
+These calls were removed because are not safe, use per-context
+error callbacks instead:
+ crypt_last_error;
+ crypt_get_error;
+
+The PBKDF benchmark was replaced by a new function that uses new KDF structure
+ crypt_benchmark_kdf; (removed)
+ crypt_benchmark_pbkdf; (new API call)
+
+These new calls are now exported, for details see libcryptsetup.h:
+ crypt_keyslot_add_by_key;
+ crypt_keyslot_set_priority;
+ crypt_keyslot_get_priority;
+
+ crypt_token_json_get;
+ crypt_token_json_set;
+ crypt_token_status;
+ crypt_token_luks2_keyring_get;
+ crypt_token_luks2_keyring_set;
+ crypt_token_assign_keyslot;
+ crypt_token_unassign_keyslot;
+ crypt_token_register;
+
+ crypt_activate_by_token;
+ crypt_activate_by_keyring;
+ crypt_deactivate_by_name;
+
+ crypt_metadata_locking;
+ crypt_volume_key_keyring;
+ crypt_get_integrity_info;
+ crypt_get_sector_size;
+ crypt_persistent_flags_set;
+ crypt_persistent_flags_get;
+ crypt_set_pbkdf_type;
+ crypt_get_pbkdf_type;
+
+ crypt_convert;
+ crypt_keyfile_read;
+ crypt_wipe;
+
+Unfinished things & TODO for next releases
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+* There will be better documentation and examples.
+
+* There will be some more formal definition of the threat model for integrity
+ protection. (And a link to some papers discussing integrity protection,
+ once it is, hopefully, accepted and published.)
+
+* Offline re-encrypt tool LUKS2 support is currently limited.
+ There will be online LUKS2 re-encryption tool in future.
+
+* Authenticated encryption will use new algorithms from CAESAR competition
+ (https://competitions.cr.yp.to/caesar.html) once these algorithms are available
+ in kernel (more on this later).
+ NOTE: Currently available authenticated modes (GCM, Chacha20-poly1305)
+ in kernel have too small 96-bit nonces that are problematic with
+ randomly generated IVs (the collision probability is not negligible).
+ For the GCM, nonce collision is a fatal problem.
+
+* Authenticated encryption do not set encryption for dm-integrity journal.
+
+ While it does not influence data confidentiality or integrity protection,
+ an attacker can get some more information from data journal or cause that
+ system will corrupt sectors after journal replay. (That corruption will be
+ detected though.)
+
+* Some utilities (blkid, systemd-cryptsetup) have already support for LUKS
+ but not yet in released version (support in crypttab etc).
+
+* There are some examples of user-defined tokens inside misc/luks2_keyslot_example
+ directory (like a simple external program that uses libssh to unlock LUKS2
+ using remote keyfile).
+
+* The python binding (pycryptsetup) contains only basic functionality for LUKS1
+ (it is not updated for new features) and will be deprecated soon in favor
+ of python bindings to libblockdev library (that can already handle LUKS1 devices).