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ReStructuredText
627 lines
29 KiB
ReStructuredText
=====================================
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Filesystem-level encryption (fscrypt)
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=====================================
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Introduction
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============
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fscrypt is a library which filesystems can hook into to support
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transparent encryption of files and directories.
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Note: "fscrypt" in this document refers to the kernel-level portion,
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implemented in ``fs/crypto/``, as opposed to the userspace tool
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`fscrypt <https://github.com/google/fscrypt>`_. This document only
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covers the kernel-level portion. For command-line examples of how to
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use encryption, see the documentation for the userspace tool `fscrypt
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<https://github.com/google/fscrypt>`_. Also, it is recommended to use
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the fscrypt userspace tool, or other existing userspace tools such as
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`fscryptctl <https://github.com/google/fscryptctl>`_ or `Android's key
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management system
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<https://source.android.com/security/encryption/file-based>`_, over
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using the kernel's API directly. Using existing tools reduces the
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chance of introducing your own security bugs. (Nevertheless, for
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completeness this documentation covers the kernel's API anyway.)
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Unlike dm-crypt, fscrypt operates at the filesystem level rather than
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at the block device level. This allows it to encrypt different files
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with different keys and to have unencrypted files on the same
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filesystem. This is useful for multi-user systems where each user's
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data-at-rest needs to be cryptographically isolated from the others.
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However, except for filenames, fscrypt does not encrypt filesystem
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metadata.
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Unlike eCryptfs, which is a stacked filesystem, fscrypt is integrated
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directly into supported filesystems --- currently ext4, F2FS, and
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UBIFS. This allows encrypted files to be read and written without
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caching both the decrypted and encrypted pages in the pagecache,
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thereby nearly halving the memory used and bringing it in line with
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unencrypted files. Similarly, half as many dentries and inodes are
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needed. eCryptfs also limits encrypted filenames to 143 bytes,
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causing application compatibility issues; fscrypt allows the full 255
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bytes (NAME_MAX). Finally, unlike eCryptfs, the fscrypt API can be
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used by unprivileged users, with no need to mount anything.
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fscrypt does not support encrypting files in-place. Instead, it
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supports marking an empty directory as encrypted. Then, after
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userspace provides the key, all regular files, directories, and
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symbolic links created in that directory tree are transparently
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encrypted.
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Threat model
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============
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Offline attacks
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---------------
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Provided that userspace chooses a strong encryption key, fscrypt
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protects the confidentiality of file contents and filenames in the
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event of a single point-in-time permanent offline compromise of the
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block device content. fscrypt does not protect the confidentiality of
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non-filename metadata, e.g. file sizes, file permissions, file
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timestamps, and extended attributes. Also, the existence and location
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of holes (unallocated blocks which logically contain all zeroes) in
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files is not protected.
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fscrypt is not guaranteed to protect confidentiality or authenticity
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if an attacker is able to manipulate the filesystem offline prior to
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an authorized user later accessing the filesystem.
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Online attacks
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--------------
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fscrypt (and storage encryption in general) can only provide limited
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protection, if any at all, against online attacks. In detail:
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fscrypt is only resistant to side-channel attacks, such as timing or
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electromagnetic attacks, to the extent that the underlying Linux
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Cryptographic API algorithms are. If a vulnerable algorithm is used,
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such as a table-based implementation of AES, it may be possible for an
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attacker to mount a side channel attack against the online system.
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Side channel attacks may also be mounted against applications
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consuming decrypted data.
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After an encryption key has been provided, fscrypt is not designed to
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hide the plaintext file contents or filenames from other users on the
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same system, regardless of the visibility of the keyring key.
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Instead, existing access control mechanisms such as file mode bits,
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POSIX ACLs, LSMs, or mount namespaces should be used for this purpose.
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Also note that as long as the encryption keys are *anywhere* in
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memory, an online attacker can necessarily compromise them by mounting
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a physical attack or by exploiting any kernel security vulnerability
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which provides an arbitrary memory read primitive.
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While it is ostensibly possible to "evict" keys from the system,
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recently accessed encrypted files will remain accessible at least
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until the filesystem is unmounted or the VFS caches are dropped, e.g.
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using ``echo 2 > /proc/sys/vm/drop_caches``. Even after that, if the
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RAM is compromised before being powered off, it will likely still be
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possible to recover portions of the plaintext file contents, if not
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some of the encryption keys as well. (Since Linux v4.12, all
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in-kernel keys related to fscrypt are sanitized before being freed.
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However, userspace would need to do its part as well.)
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Currently, fscrypt does not prevent a user from maliciously providing
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an incorrect key for another user's existing encrypted files. A
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protection against this is planned.
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Key hierarchy
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=============
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Master Keys
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-----------
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Each encrypted directory tree is protected by a *master key*. Master
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keys can be up to 64 bytes long, and must be at least as long as the
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greater of the key length needed by the contents and filenames
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encryption modes being used. For example, if AES-256-XTS is used for
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contents encryption, the master key must be 64 bytes (512 bits). Note
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that the XTS mode is defined to require a key twice as long as that
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required by the underlying block cipher.
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To "unlock" an encrypted directory tree, userspace must provide the
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appropriate master key. There can be any number of master keys, each
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of which protects any number of directory trees on any number of
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filesystems.
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Userspace should generate master keys either using a cryptographically
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secure random number generator, or by using a KDF (Key Derivation
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Function). Note that whenever a KDF is used to "stretch" a
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lower-entropy secret such as a passphrase, it is critical that a KDF
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designed for this purpose be used, such as scrypt, PBKDF2, or Argon2.
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Per-file keys
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-------------
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Master keys are not used to encrypt file contents or names directly.
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Instead, a unique key is derived for each encrypted file, including
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each regular file, directory, and symbolic link. This has several
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advantages:
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- In cryptosystems, the same key material should never be used for
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different purposes. Using the master key as both an XTS key for
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contents encryption and as a CTS-CBC key for filenames encryption
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would violate this rule.
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- Per-file keys simplify the choice of IVs (Initialization Vectors)
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for contents encryption. Without per-file keys, to ensure IV
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uniqueness both the inode and logical block number would need to be
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encoded in the IVs. This would make it impossible to renumber
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inodes, which e.g. ``resize2fs`` can do when resizing an ext4
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filesystem. With per-file keys, it is sufficient to encode just the
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logical block number in the IVs.
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- Per-file keys strengthen the encryption of filenames, where IVs are
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reused out of necessity. With a unique key per directory, IV reuse
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is limited to within a single directory.
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- Per-file keys allow individual files to be securely erased simply by
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securely erasing their keys. (Not yet implemented.)
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A KDF (Key Derivation Function) is used to derive per-file keys from
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the master key. This is done instead of wrapping a randomly-generated
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key for each file because it reduces the size of the encryption xattr,
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which for some filesystems makes the xattr more likely to fit in-line
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in the filesystem's inode table. With a KDF, only a 16-byte nonce is
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required --- long enough to make key reuse extremely unlikely. A
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wrapped key, on the other hand, would need to be up to 64 bytes ---
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the length of an AES-256-XTS key. Furthermore, currently there is no
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requirement to support unlocking a file with multiple alternative
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master keys or to support rotating master keys. Instead, the master
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keys may be wrapped in userspace, e.g. as done by the `fscrypt
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<https://github.com/google/fscrypt>`_ tool.
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The current KDF encrypts the master key using the 16-byte nonce as an
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AES-128-ECB key. The output is used as the derived key. If the
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output is longer than needed, then it is truncated to the needed
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length. Truncation is the norm for directories and symlinks, since
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those use the CTS-CBC encryption mode which requires a key half as
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long as that required by the XTS encryption mode.
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Note: this KDF meets the primary security requirement, which is to
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produce unique derived keys that preserve the entropy of the master
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key, assuming that the master key is already a good pseudorandom key.
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However, it is nonstandard and has some problems such as being
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reversible, so it is generally considered to be a mistake! It may be
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replaced with HKDF or another more standard KDF in the future.
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Encryption modes and usage
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==========================
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fscrypt allows one encryption mode to be specified for file contents
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and one encryption mode to be specified for filenames. Different
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directory trees are permitted to use different encryption modes.
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Currently, the following pairs of encryption modes are supported:
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- AES-256-XTS for contents and AES-256-CTS-CBC for filenames
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- AES-128-CBC for contents and AES-128-CTS-CBC for filenames
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- Speck128/256-XTS for contents and Speck128/256-CTS-CBC for filenames
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It is strongly recommended to use AES-256-XTS for contents encryption.
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AES-128-CBC was added only for low-powered embedded devices with
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crypto accelerators such as CAAM or CESA that do not support XTS.
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Similarly, Speck128/256 support was only added for older or low-end
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CPUs which cannot do AES fast enough -- especially ARM CPUs which have
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NEON instructions but not the Cryptography Extensions -- and for which
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it would not otherwise be feasible to use encryption at all. It is
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not recommended to use Speck on CPUs that have AES instructions.
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Speck support is only available if it has been enabled in the crypto
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API via CONFIG_CRYPTO_SPECK. Also, on ARM platforms, to get
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acceptable performance CONFIG_CRYPTO_SPECK_NEON must be enabled.
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New encryption modes can be added relatively easily, without changes
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to individual filesystems. However, authenticated encryption (AE)
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modes are not currently supported because of the difficulty of dealing
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with ciphertext expansion.
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For file contents, each filesystem block is encrypted independently.
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Currently, only the case where the filesystem block size is equal to
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the system's page size (usually 4096 bytes) is supported. With the
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XTS mode of operation (recommended), the logical block number within
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the file is used as the IV. With the CBC mode of operation (not
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recommended), ESSIV is used; specifically, the IV for CBC is the
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logical block number encrypted with AES-256, where the AES-256 key is
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the SHA-256 hash of the inode's data encryption key.
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For filenames, the full filename is encrypted at once. Because of the
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requirements to retain support for efficient directory lookups and
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filenames of up to 255 bytes, a constant initialization vector (IV) is
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used. However, each encrypted directory uses a unique key, which
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limits IV reuse to within a single directory. Note that IV reuse in
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the context of CTS-CBC encryption means that when the original
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filenames share a common prefix at least as long as the cipher block
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size (16 bytes for AES), the corresponding encrypted filenames will
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also share a common prefix. This is undesirable; it may be fixed in
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the future by switching to an encryption mode that is a strong
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pseudorandom permutation on arbitrary-length messages, e.g. the HEH
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(Hash-Encrypt-Hash) mode.
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Since filenames are encrypted with the CTS-CBC mode of operation, the
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plaintext and ciphertext filenames need not be multiples of the AES
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block size, i.e. 16 bytes. However, the minimum size that can be
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encrypted is 16 bytes, so shorter filenames are NUL-padded to 16 bytes
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before being encrypted. In addition, to reduce leakage of filename
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lengths via their ciphertexts, all filenames are NUL-padded to the
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next 4, 8, 16, or 32-byte boundary (configurable). 32 is recommended
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since this provides the best confidentiality, at the cost of making
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directory entries consume slightly more space. Note that since NUL
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(``\0``) is not otherwise a valid character in filenames, the padding
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will never produce duplicate plaintexts.
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Symbolic link targets are considered a type of filename and are
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encrypted in the same way as filenames in directory entries. Each
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symlink also uses a unique key; hence, the hardcoded IV is not a
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problem for symlinks.
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User API
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========
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Setting an encryption policy
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----------------------------
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The FS_IOC_SET_ENCRYPTION_POLICY ioctl sets an encryption policy on an
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empty directory or verifies that a directory or regular file already
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has the specified encryption policy. It takes in a pointer to a
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:c:type:`struct fscrypt_policy`, defined as follows::
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#define FS_KEY_DESCRIPTOR_SIZE 8
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struct fscrypt_policy {
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__u8 version;
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__u8 contents_encryption_mode;
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__u8 filenames_encryption_mode;
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__u8 flags;
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__u8 master_key_descriptor[FS_KEY_DESCRIPTOR_SIZE];
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};
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This structure must be initialized as follows:
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- ``version`` must be 0.
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- ``contents_encryption_mode`` and ``filenames_encryption_mode`` must
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be set to constants from ``<linux/fs.h>`` which identify the
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encryption modes to use. If unsure, use
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FS_ENCRYPTION_MODE_AES_256_XTS (1) for ``contents_encryption_mode``
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and FS_ENCRYPTION_MODE_AES_256_CTS (4) for
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``filenames_encryption_mode``.
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- ``flags`` must be set to a value from ``<linux/fs.h>`` which
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identifies the amount of NUL-padding to use when encrypting
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filenames. If unsure, use FS_POLICY_FLAGS_PAD_32 (0x3).
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- ``master_key_descriptor`` specifies how to find the master key in
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the keyring; see `Adding keys`_. It is up to userspace to choose a
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unique ``master_key_descriptor`` for each master key. The e4crypt
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and fscrypt tools use the first 8 bytes of
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``SHA-512(SHA-512(master_key))``, but this particular scheme is not
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required. Also, the master key need not be in the keyring yet when
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FS_IOC_SET_ENCRYPTION_POLICY is executed. However, it must be added
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before any files can be created in the encrypted directory.
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If the file is not yet encrypted, then FS_IOC_SET_ENCRYPTION_POLICY
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verifies that the file is an empty directory. If so, the specified
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encryption policy is assigned to the directory, turning it into an
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encrypted directory. After that, and after providing the
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corresponding master key as described in `Adding keys`_, all regular
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files, directories (recursively), and symlinks created in the
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directory will be encrypted, inheriting the same encryption policy.
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The filenames in the directory's entries will be encrypted as well.
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Alternatively, if the file is already encrypted, then
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FS_IOC_SET_ENCRYPTION_POLICY validates that the specified encryption
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policy exactly matches the actual one. If they match, then the ioctl
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returns 0. Otherwise, it fails with EEXIST. This works on both
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regular files and directories, including nonempty directories.
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Note that the ext4 filesystem does not allow the root directory to be
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encrypted, even if it is empty. Users who want to encrypt an entire
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filesystem with one key should consider using dm-crypt instead.
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FS_IOC_SET_ENCRYPTION_POLICY can fail with the following errors:
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- ``EACCES``: the file is not owned by the process's uid, nor does the
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process have the CAP_FOWNER capability in a namespace with the file
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owner's uid mapped
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- ``EEXIST``: the file is already encrypted with an encryption policy
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different from the one specified
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- ``EINVAL``: an invalid encryption policy was specified (invalid
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version, mode(s), or flags)
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- ``ENOTDIR``: the file is unencrypted and is a regular file, not a
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directory
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- ``ENOTEMPTY``: the file is unencrypted and is a nonempty directory
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- ``ENOTTY``: this type of filesystem does not implement encryption
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- ``EOPNOTSUPP``: the kernel was not configured with encryption
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support for this filesystem, or the filesystem superblock has not
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had encryption enabled on it. (For example, to use encryption on an
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ext4 filesystem, CONFIG_EXT4_ENCRYPTION must be enabled in the
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kernel config, and the superblock must have had the "encrypt"
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feature flag enabled using ``tune2fs -O encrypt`` or ``mkfs.ext4 -O
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encrypt``.)
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- ``EPERM``: this directory may not be encrypted, e.g. because it is
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the root directory of an ext4 filesystem
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- ``EROFS``: the filesystem is readonly
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Getting an encryption policy
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----------------------------
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The FS_IOC_GET_ENCRYPTION_POLICY ioctl retrieves the :c:type:`struct
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fscrypt_policy`, if any, for a directory or regular file. See above
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for the struct definition. No additional permissions are required
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beyond the ability to open the file.
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FS_IOC_GET_ENCRYPTION_POLICY can fail with the following errors:
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- ``EINVAL``: the file is encrypted, but it uses an unrecognized
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encryption context format
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- ``ENODATA``: the file is not encrypted
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- ``ENOTTY``: this type of filesystem does not implement encryption
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- ``EOPNOTSUPP``: the kernel was not configured with encryption
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support for this filesystem
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Note: if you only need to know whether a file is encrypted or not, on
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most filesystems it is also possible to use the FS_IOC_GETFLAGS ioctl
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and check for FS_ENCRYPT_FL, or to use the statx() system call and
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check for STATX_ATTR_ENCRYPTED in stx_attributes.
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Getting the per-filesystem salt
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-------------------------------
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Some filesystems, such as ext4 and F2FS, also support the deprecated
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ioctl FS_IOC_GET_ENCRYPTION_PWSALT. This ioctl retrieves a randomly
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generated 16-byte value stored in the filesystem superblock. This
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value is intended to used as a salt when deriving an encryption key
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from a passphrase or other low-entropy user credential.
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FS_IOC_GET_ENCRYPTION_PWSALT is deprecated. Instead, prefer to
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generate and manage any needed salt(s) in userspace.
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Adding keys
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-----------
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To provide a master key, userspace must add it to an appropriate
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keyring using the add_key() system call (see:
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``Documentation/security/keys/core.rst``). The key type must be
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"logon"; keys of this type are kept in kernel memory and cannot be
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read back by userspace. The key description must be "fscrypt:"
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followed by the 16-character lower case hex representation of the
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``master_key_descriptor`` that was set in the encryption policy. The
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key payload must conform to the following structure::
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#define FS_MAX_KEY_SIZE 64
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struct fscrypt_key {
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u32 mode;
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u8 raw[FS_MAX_KEY_SIZE];
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u32 size;
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};
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``mode`` is ignored; just set it to 0. The actual key is provided in
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``raw`` with ``size`` indicating its size in bytes. That is, the
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bytes ``raw[0..size-1]`` (inclusive) are the actual key.
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The key description prefix "fscrypt:" may alternatively be replaced
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with a filesystem-specific prefix such as "ext4:". However, the
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filesystem-specific prefixes are deprecated and should not be used in
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new programs.
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There are several different types of keyrings in which encryption keys
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may be placed, such as a session keyring, a user session keyring, or a
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user keyring. Each key must be placed in a keyring that is "attached"
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to all processes that might need to access files encrypted with it, in
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the sense that request_key() will find the key. Generally, if only
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processes belonging to a specific user need to access a given
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encrypted directory and no session keyring has been installed, then
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that directory's key should be placed in that user's user session
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keyring or user keyring. Otherwise, a session keyring should be
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installed if needed, and the key should be linked into that session
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keyring, or in a keyring linked into that session keyring.
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Note: introducing the complex visibility semantics of keyrings here
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was arguably a mistake --- especially given that by design, after any
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process successfully opens an encrypted file (thereby setting up the
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per-file key), possessing the keyring key is not actually required for
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any process to read/write the file until its in-memory inode is
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evicted. In the future there probably should be a way to provide keys
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directly to the filesystem instead, which would make the intended
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semantics clearer.
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Access semantics
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================
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With the key
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------------
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With the encryption key, encrypted regular files, directories, and
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symlinks behave very similarly to their unencrypted counterparts ---
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after all, the encryption is intended to be transparent. However,
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astute users may notice some differences in behavior:
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- Unencrypted files, or files encrypted with a different encryption
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policy (i.e. different key, modes, or flags), cannot be renamed or
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linked into an encrypted directory; see `Encryption policy
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enforcement`_. Attempts to do so will fail with EPERM. However,
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encrypted files can be renamed within an encrypted directory, or
|
|
into an unencrypted directory.
|
|
|
|
- Direct I/O is not supported on encrypted files. Attempts to use
|
|
direct I/O on such files will fall back to buffered I/O.
|
|
|
|
- The fallocate operations FALLOC_FL_COLLAPSE_RANGE,
|
|
FALLOC_FL_INSERT_RANGE, and FALLOC_FL_ZERO_RANGE are not supported
|
|
on encrypted files and will fail with EOPNOTSUPP.
|
|
|
|
- Online defragmentation of encrypted files is not supported. The
|
|
EXT4_IOC_MOVE_EXT and F2FS_IOC_MOVE_RANGE ioctls will fail with
|
|
EOPNOTSUPP.
|
|
|
|
- The ext4 filesystem does not support data journaling with encrypted
|
|
regular files. It will fall back to ordered data mode instead.
|
|
|
|
- DAX (Direct Access) is not supported on encrypted files.
|
|
|
|
- The st_size of an encrypted symlink will not necessarily give the
|
|
length of the symlink target as required by POSIX. It will actually
|
|
give the length of the ciphertext, which will be slightly longer
|
|
than the plaintext due to NUL-padding and an extra 2-byte overhead.
|
|
|
|
- The maximum length of an encrypted symlink is 2 bytes shorter than
|
|
the maximum length of an unencrypted symlink. For example, on an
|
|
EXT4 filesystem with a 4K block size, unencrypted symlinks can be up
|
|
to 4095 bytes long, while encrypted symlinks can only be up to 4093
|
|
bytes long (both lengths excluding the terminating null).
|
|
|
|
Note that mmap *is* supported. This is possible because the pagecache
|
|
for an encrypted file contains the plaintext, not the ciphertext.
|
|
|
|
Without the key
|
|
---------------
|
|
|
|
Some filesystem operations may be performed on encrypted regular
|
|
files, directories, and symlinks even before their encryption key has
|
|
been provided:
|
|
|
|
- File metadata may be read, e.g. using stat().
|
|
|
|
- Directories may be listed, in which case the filenames will be
|
|
listed in an encoded form derived from their ciphertext. The
|
|
current encoding algorithm is described in `Filename hashing and
|
|
encoding`_. The algorithm is subject to change, but it is
|
|
guaranteed that the presented filenames will be no longer than
|
|
NAME_MAX bytes, will not contain the ``/`` or ``\0`` characters, and
|
|
will uniquely identify directory entries.
|
|
|
|
The ``.`` and ``..`` directory entries are special. They are always
|
|
present and are not encrypted or encoded.
|
|
|
|
- Files may be deleted. That is, nondirectory files may be deleted
|
|
with unlink() as usual, and empty directories may be deleted with
|
|
rmdir() as usual. Therefore, ``rm`` and ``rm -r`` will work as
|
|
expected.
|
|
|
|
- Symlink targets may be read and followed, but they will be presented
|
|
in encrypted form, similar to filenames in directories. Hence, they
|
|
are unlikely to point to anywhere useful.
|
|
|
|
Without the key, regular files cannot be opened or truncated.
|
|
Attempts to do so will fail with ENOKEY. This implies that any
|
|
regular file operations that require a file descriptor, such as
|
|
read(), write(), mmap(), fallocate(), and ioctl(), are also forbidden.
|
|
|
|
Also without the key, files of any type (including directories) cannot
|
|
be created or linked into an encrypted directory, nor can a name in an
|
|
encrypted directory be the source or target of a rename, nor can an
|
|
O_TMPFILE temporary file be created in an encrypted directory. All
|
|
such operations will fail with ENOKEY.
|
|
|
|
It is not currently possible to backup and restore encrypted files
|
|
without the encryption key. This would require special APIs which
|
|
have not yet been implemented.
|
|
|
|
Encryption policy enforcement
|
|
=============================
|
|
|
|
After an encryption policy has been set on a directory, all regular
|
|
files, directories, and symbolic links created in that directory
|
|
(recursively) will inherit that encryption policy. Special files ---
|
|
that is, named pipes, device nodes, and UNIX domain sockets --- will
|
|
not be encrypted.
|
|
|
|
Except for those special files, it is forbidden to have unencrypted
|
|
files, or files encrypted with a different encryption policy, in an
|
|
encrypted directory tree. Attempts to link or rename such a file into
|
|
an encrypted directory will fail with EPERM. This is also enforced
|
|
during ->lookup() to provide limited protection against offline
|
|
attacks that try to disable or downgrade encryption in known locations
|
|
where applications may later write sensitive data. It is recommended
|
|
that systems implementing a form of "verified boot" take advantage of
|
|
this by validating all top-level encryption policies prior to access.
|
|
|
|
Implementation details
|
|
======================
|
|
|
|
Encryption context
|
|
------------------
|
|
|
|
An encryption policy is represented on-disk by a :c:type:`struct
|
|
fscrypt_context`. It is up to individual filesystems to decide where
|
|
to store it, but normally it would be stored in a hidden extended
|
|
attribute. It should *not* be exposed by the xattr-related system
|
|
calls such as getxattr() and setxattr() because of the special
|
|
semantics of the encryption xattr. (In particular, there would be
|
|
much confusion if an encryption policy were to be added to or removed
|
|
from anything other than an empty directory.) The struct is defined
|
|
as follows::
|
|
|
|
#define FS_KEY_DESCRIPTOR_SIZE 8
|
|
#define FS_KEY_DERIVATION_NONCE_SIZE 16
|
|
|
|
struct fscrypt_context {
|
|
u8 format;
|
|
u8 contents_encryption_mode;
|
|
u8 filenames_encryption_mode;
|
|
u8 flags;
|
|
u8 master_key_descriptor[FS_KEY_DESCRIPTOR_SIZE];
|
|
u8 nonce[FS_KEY_DERIVATION_NONCE_SIZE];
|
|
};
|
|
|
|
Note that :c:type:`struct fscrypt_context` contains the same
|
|
information as :c:type:`struct fscrypt_policy` (see `Setting an
|
|
encryption policy`_), except that :c:type:`struct fscrypt_context`
|
|
also contains a nonce. The nonce is randomly generated by the kernel
|
|
and is used to derive the inode's encryption key as described in
|
|
`Per-file keys`_.
|
|
|
|
Data path changes
|
|
-----------------
|
|
|
|
For the read path (->readpage()) of regular files, filesystems can
|
|
read the ciphertext into the page cache and decrypt it in-place. The
|
|
page lock must be held until decryption has finished, to prevent the
|
|
page from becoming visible to userspace prematurely.
|
|
|
|
For the write path (->writepage()) of regular files, filesystems
|
|
cannot encrypt data in-place in the page cache, since the cached
|
|
plaintext must be preserved. Instead, filesystems must encrypt into a
|
|
temporary buffer or "bounce page", then write out the temporary
|
|
buffer. Some filesystems, such as UBIFS, already use temporary
|
|
buffers regardless of encryption. Other filesystems, such as ext4 and
|
|
F2FS, have to allocate bounce pages specially for encryption.
|
|
|
|
Filename hashing and encoding
|
|
-----------------------------
|
|
|
|
Modern filesystems accelerate directory lookups by using indexed
|
|
directories. An indexed directory is organized as a tree keyed by
|
|
filename hashes. When a ->lookup() is requested, the filesystem
|
|
normally hashes the filename being looked up so that it can quickly
|
|
find the corresponding directory entry, if any.
|
|
|
|
With encryption, lookups must be supported and efficient both with and
|
|
without the encryption key. Clearly, it would not work to hash the
|
|
plaintext filenames, since the plaintext filenames are unavailable
|
|
without the key. (Hashing the plaintext filenames would also make it
|
|
impossible for the filesystem's fsck tool to optimize encrypted
|
|
directories.) Instead, filesystems hash the ciphertext filenames,
|
|
i.e. the bytes actually stored on-disk in the directory entries. When
|
|
asked to do a ->lookup() with the key, the filesystem just encrypts
|
|
the user-supplied name to get the ciphertext.
|
|
|
|
Lookups without the key are more complicated. The raw ciphertext may
|
|
contain the ``\0`` and ``/`` characters, which are illegal in
|
|
filenames. Therefore, readdir() must base64-encode the ciphertext for
|
|
presentation. For most filenames, this works fine; on ->lookup(), the
|
|
filesystem just base64-decodes the user-supplied name to get back to
|
|
the raw ciphertext.
|
|
|
|
However, for very long filenames, base64 encoding would cause the
|
|
filename length to exceed NAME_MAX. To prevent this, readdir()
|
|
actually presents long filenames in an abbreviated form which encodes
|
|
a strong "hash" of the ciphertext filename, along with the optional
|
|
filesystem-specific hash(es) needed for directory lookups. This
|
|
allows the filesystem to still, with a high degree of confidence, map
|
|
the filename given in ->lookup() back to a particular directory entry
|
|
that was previously listed by readdir(). See :c:type:`struct
|
|
fscrypt_digested_name` in the source for more details.
|
|
|
|
Note that the precise way that filenames are presented to userspace
|
|
without the key is subject to change in the future. It is only meant
|
|
as a way to temporarily present valid filenames so that commands like
|
|
``rm -r`` work as expected on encrypted directories.
|