/* * libcryptsetup - cryptsetup library * * Copyright (C) 2004 Jana Saout * Copyright (C) 2004-2007 Clemens Fruhwirth * Copyright (C) 2009-2022 Red Hat, Inc. All rights reserved. * Copyright (C) 2009-2022 Milan Broz * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version 2 * of the License, or (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. */ /** * @file libcryptsetup.h * @brief Public cryptsetup API * * For more verbose examples of LUKS related use cases, * please read @ref index "examples". */ #ifndef _LIBCRYPTSETUP_H #define _LIBCRYPTSETUP_H #ifdef __cplusplus extern "C" { #endif #include #include /** * @defgroup crypt-init Cryptsetup device context initialization * Set of functions for creating and destroying @e crypt_device context * @addtogroup crypt-init * @{ */ struct crypt_device; /* crypt device handle */ /** * Initialize crypt device handle and check if the provided device exists. * * @param cd Returns pointer to crypt device handle * @param device Path to the backing device. * If @e device is not a block device but a path to some file, * the function will try to create a loopdevice and attach * the file to the loopdevice with AUTOCLEAR flag set. * If @e device is @e NULL function it will initialize dm backend only. * * @return @e 0 on success or negative errno value otherwise. * * @note Note that logging is not initialized here, possible messages use * default log function. */ int crypt_init(struct crypt_device **cd, const char *device); /** * Initialize crypt device handle with optional data device and check * if devices exist. * * @param cd Returns pointer to crypt device handle * @param device Path to the backing device or detached header. * @param data_device Path to the data device or @e NULL. * * @return @e 0 on success or negative errno value otherwise. * * @note Note that logging is not initialized here, possible messages use * default log function. */ int crypt_init_data_device(struct crypt_device **cd, const char *device, const char *data_device); /** * Initialize crypt device handle from provided active device name, * and, optionally, from separate metadata (header) device * and check if provided device exists. * * @return @e 0 on success or negative errno value otherwise. * * @param cd returns crypt device handle for active device * @param name name of active crypt device * @param header_device optional device containing on-disk header * (@e NULL if it the same as underlying device on there is no on-disk header) * * @post In case @e device points to active LUKS device but header load fails, * context device type is set to @e NULL and @e 0 is returned as if it were successful. * Context with @e NULL device type can only be deactivated by crypt_deactivate * * @note @link crypt_init_by_name @endlink is equivalent to calling * crypt_init_by_name_and_header(cd, name, NULL); */ int crypt_init_by_name_and_header(struct crypt_device **cd, const char *name, const char *header_device); /** * This is equivalent to call * @ref crypt_init_by_name_and_header "crypt_init_by_name_and_header(cd, name, NULL)" * * @sa crypt_init_by_name_and_header */ int crypt_init_by_name(struct crypt_device **cd, const char *name); /** * Release crypt device context and used memory. * * @param cd crypt device handle */ void crypt_free(struct crypt_device *cd); /** * Set confirmation callback (yes/no). * * If code need confirmation (like resetting uuid or restoring LUKS header from file) * this function is called. If not defined, everything is confirmed. * * Callback function @e confirm should return @e 0 if operation is declined, * other values mean accepted. * * @param cd crypt device handle * @param confirm user defined confirm callback reference; use * @p msg for message for user to confirm and * @p usrptr for identification in callback * @param usrptr provided identification in callback * * @note Current version of cryptsetup API requires confirmation for UUID change and * LUKS header restore only. */ void crypt_set_confirm_callback(struct crypt_device *cd, int (*confirm)(const char *msg, void *usrptr), void *usrptr); /** * Set data device * For LUKS it is encrypted data device when LUKS header is separated. * For VERITY it is data device when hash device is separated. * * @param cd crypt device handle * @param device path to device * * @returns 0 on success or negative errno value otherwise. */ int crypt_set_data_device(struct crypt_device *cd, const char *device); /** * Set data device offset in 512-byte sectors. * Used for LUKS. * This function is replacement for data alignment fields in LUKS param struct. * If set to 0 (default), old behaviour is preserved. * This value is reset on @link crypt_load @endlink. * * @param cd crypt device handle * @param data_offset data offset in bytes * * @returns 0 on success or negative errno value otherwise. * * @note Data offset must be aligned to multiple of 8 (alignment to 4096-byte sectors) * and must be big enough to accommodate the whole LUKS header with all keyslots. * @note Data offset is enforced by this function, device topology * information is no longer used after calling this function. */ int crypt_set_data_offset(struct crypt_device *cd, uint64_t data_offset); /** @} */ /** * @defgroup crypt-log Cryptsetup logging * Set of functions and defines used in cryptsetup for * logging purposes * @addtogroup crypt-log * @{ */ /** normal log level */ #define CRYPT_LOG_NORMAL 0 /** error log level */ #define CRYPT_LOG_ERROR 1 /** verbose log level */ #define CRYPT_LOG_VERBOSE 2 /** debug log level - always on stdout */ #define CRYPT_LOG_DEBUG -1 /** debug log level - additional JSON output (for LUKS2) */ #define CRYPT_LOG_DEBUG_JSON -2 /** * Set log function. * * @param cd crypt device handle (can be @e NULL to set default log function) * @param log user defined log function reference; use * @p level for log level, * @p msg for message, and * @p usrptr for identification in callback * @param usrptr provided identification in callback */ void crypt_set_log_callback(struct crypt_device *cd, void (*log)(int level, const char *msg, void *usrptr), void *usrptr); /** * Defines log function or use the default one otherwise. * * @see crypt_set_log_callback * * @param cd crypt device handle * @param level log level * @param msg log message */ void crypt_log(struct crypt_device *cd, int level, const char *msg); /** * Log function with variable arguments. * * @param cd crypt device handle * @param level log level * @param format formatted log message */ void crypt_logf(struct crypt_device *cd, int level, const char *format, ...); /** @} */ /** * @defgroup crypt-set Cryptsetup settings (RNG, PBKDF, locking) * @addtogroup crypt-set * @{ */ /** CRYPT_RNG_URANDOM - use /dev/urandom */ #define CRYPT_RNG_URANDOM 0 /** CRYPT_RNG_RANDOM - use /dev/random (waits if no entropy in system) */ #define CRYPT_RNG_RANDOM 1 /** * Set which RNG (random number generator) is used for generating long term key * * @param cd crypt device handle * @param rng_type kernel random number generator to use * */ void crypt_set_rng_type(struct crypt_device *cd, int rng_type); /** * Get which RNG (random number generator) is used for generating long term key. * * @param cd crypt device handle * @return RNG type on success or negative errno value otherwise. * */ int crypt_get_rng_type(struct crypt_device *cd); /** * PBKDF parameters. */ struct crypt_pbkdf_type { const char *type; /**< PBKDF algorithm */ const char *hash; /**< Hash algorithm */ uint32_t time_ms; /**< Requested time cost [milliseconds] */ uint32_t iterations; /**< Iterations, 0 or benchmarked value. */ uint32_t max_memory_kb; /**< Requested or benchmarked memory cost [kilobytes] */ uint32_t parallel_threads;/**< Requested parallel cost [threads] */ uint32_t flags; /**< CRYPT_PBKDF* flags */ }; /** Iteration time set by crypt_set_iteration_time(), for compatibility only. */ #define CRYPT_PBKDF_ITER_TIME_SET (UINT32_C(1) << 0) /** Never run benchmarks, use pre-set value or defaults. */ #define CRYPT_PBKDF_NO_BENCHMARK (UINT32_C(1) << 1) /** PBKDF2 according to RFC2898, LUKS1 legacy */ #define CRYPT_KDF_PBKDF2 "pbkdf2" /** Argon2i according to RFC */ #define CRYPT_KDF_ARGON2I "argon2i" /** Argon2id according to RFC */ #define CRYPT_KDF_ARGON2ID "argon2id" /** * Set default PBKDF (Password-Based Key Derivation Algorithm) for next keyslot * about to get created with any crypt_keyslot_add_*() call. * * @param cd crypt device handle * @param pbkdf PBKDF parameters * * @return 0 on success or negative errno value otherwise. * * @note For LUKS1, only PBKDF2 is supported, other settings will be rejected. * @note For non-LUKS context types the call succeeds, but PBKDF is not used. */ int crypt_set_pbkdf_type(struct crypt_device *cd, const struct crypt_pbkdf_type *pbkdf); /** * Get PBKDF (Password-Based Key Derivation Algorithm) parameters. * * @param pbkdf_type type of PBKDF * * @return struct on success or NULL value otherwise. * */ const struct crypt_pbkdf_type *crypt_get_pbkdf_type_params(const char *pbkdf_type); /** * Get default PBKDF (Password-Based Key Derivation Algorithm) settings for keyslots. * Works only with LUKS device handles (both versions). * * @param type type of device (see @link crypt-type @endlink) * * @return struct on success or NULL value otherwise. * */ const struct crypt_pbkdf_type *crypt_get_pbkdf_default(const char *type); /** * Get current PBKDF (Password-Based Key Derivation Algorithm) settings for keyslots. * Works only with LUKS device handles (both versions). * * @param cd crypt device handle * * @return struct on success or NULL value otherwise. * */ const struct crypt_pbkdf_type *crypt_get_pbkdf_type(struct crypt_device *cd); /** * Set how long should cryptsetup iterate in PBKDF2 function. * Default value heads towards the iterations which takes around 1 second. * \b Deprecated, only for backward compatibility. * Use @link crypt_set_pbkdf_type @endlink. * * @param cd crypt device handle * @param iteration_time_ms the time in ms * * @note If the time value is not acceptable for active PBKDF, value is quietly ignored. */ void crypt_set_iteration_time(struct crypt_device *cd, uint64_t iteration_time_ms); /** * Helper to lock/unlock memory to avoid swap sensitive data to disk. * * @param cd crypt device handle, can be @e NULL * @param lock 0 to unlock otherwise lock memory * * @returns Value indicating whether the memory is locked (function can be called multiple times). * * @note Only root can do this. * @note It locks/unlocks all process memory, not only crypt context. */ int crypt_memory_lock(struct crypt_device *cd, int lock); /** * Set global lock protection for on-disk metadata (file-based locking). * * @param cd crypt device handle, can be @e NULL * @param enable 0 to disable locking otherwise enable it (default) * * @returns @e 0 on success or negative errno value otherwise. * * @note Locking applied only for some metadata formats (LUKS2). * @note The switch is global on the library level. * In current version locking can be only switched off and cannot be switched on later. */ int crypt_metadata_locking(struct crypt_device *cd, int enable); /** * Set metadata header area sizes. This applies only to LUKS2. * These values limit amount of metadata anf number of supportable keyslots. * * @param cd crypt device handle, can be @e NULL * @param metadata_size size in bytes of JSON area + 4k binary header * @param keyslots_size size in bytes of binary keyslots area * * @returns @e 0 on success or negative errno value otherwise. * * @note The metadata area is stored twice and both copies contain 4k binary header. * Only 16,32,64,128,256,512,1024,2048 and 4096 kB value is allowed (see LUKS2 specification). * @note Keyslots area size must be multiple of 4k with maximum 128MB. */ int crypt_set_metadata_size(struct crypt_device *cd, uint64_t metadata_size, uint64_t keyslots_size); /** * Get metadata header area sizes. This applies only to LUKS2. * These values limit amount of metadata anf number of supportable keyslots. * * @param cd crypt device handle * @param metadata_size size in bytes of JSON area + 4k binary header * @param keyslots_size size in bytes of binary keyslots area * * @returns @e 0 on success or negative errno value otherwise. */ int crypt_get_metadata_size(struct crypt_device *cd, uint64_t *metadata_size, uint64_t *keyslots_size); /** @} */ /** * @defgroup crypt-type Cryptsetup on-disk format types * Set of functions, \#defines and structs related * to on-disk format types * @addtogroup crypt-type * @{ */ /** plain crypt device, no on-disk header */ #define CRYPT_PLAIN "PLAIN" /** LUKS version 1 header on-disk */ #define CRYPT_LUKS1 "LUKS1" /** LUKS version 2 header on-disk */ #define CRYPT_LUKS2 "LUKS2" /** loop-AES compatibility mode */ #define CRYPT_LOOPAES "LOOPAES" /** dm-verity mode */ #define CRYPT_VERITY "VERITY" /** TCRYPT (TrueCrypt-compatible and VeraCrypt-compatible) mode */ #define CRYPT_TCRYPT "TCRYPT" /** INTEGRITY dm-integrity device */ #define CRYPT_INTEGRITY "INTEGRITY" /** BITLK (BitLocker-compatible mode) */ #define CRYPT_BITLK "BITLK" /** LUKS any version */ #define CRYPT_LUKS NULL /** * Get device type * * @param cd crypt device handle * @return string according to device type or @e NULL if not known. */ const char *crypt_get_type(struct crypt_device *cd); /** * Get device default LUKS type * * @return string according to device type (CRYPT_LUKS1 or CRYPT_LUKS2). */ const char *crypt_get_default_type(void); /** * * Structure used as parameter for PLAIN device type. * * @see crypt_format */ struct crypt_params_plain { const char *hash; /**< password hash function */ uint64_t offset; /**< offset in sectors */ uint64_t skip; /**< IV offset / initialization sector */ uint64_t size; /**< size of mapped device or @e 0 for autodetection */ uint32_t sector_size; /**< sector size in bytes (@e 0 means 512 for compatibility) */ }; /** * Structure used as parameter for LUKS device type. * * @see crypt_format, crypt_load * * @note during crypt_format @e data_device attribute determines * if the LUKS header is separated from encrypted payload device * */ struct crypt_params_luks1 { const char *hash; /**< hash used in LUKS header */ size_t data_alignment; /**< data area alignment in 512B sectors, data offset is multiple of this */ const char *data_device; /**< detached encrypted data device or @e NULL */ }; /** * * Structure used as parameter for loop-AES device type. * * @see crypt_format * */ struct crypt_params_loopaes { const char *hash; /**< key hash function */ uint64_t offset; /**< offset in sectors */ uint64_t skip; /**< IV offset / initialization sector */ }; /** * * Structure used as parameter for dm-verity device type. * * @see crypt_format, crypt_load * */ struct crypt_params_verity { const char *hash_name; /**< hash function */ const char *data_device; /**< data_device (CRYPT_VERITY_CREATE_HASH) */ const char *hash_device; /**< hash_device (output only) */ const char *fec_device; /**< fec_device (output only) */ const char *salt; /**< salt */ uint32_t salt_size; /**< salt size (in bytes) */ uint32_t hash_type; /**< in-kernel hashing type */ uint32_t data_block_size; /**< data block size (in bytes) */ uint32_t hash_block_size; /**< hash block size (in bytes) */ uint64_t data_size; /**< data area size (in data blocks) */ uint64_t hash_area_offset; /**< hash/header offset (in bytes) */ uint64_t fec_area_offset; /**< FEC/header offset (in bytes) */ uint32_t fec_roots; /**< Reed-Solomon FEC roots */ uint32_t flags; /**< CRYPT_VERITY* flags */ }; /** No on-disk header (only hashes) */ #define CRYPT_VERITY_NO_HEADER (UINT32_C(1) << 0) /** Verity hash in userspace before activation */ #define CRYPT_VERITY_CHECK_HASH (UINT32_C(1) << 1) /** Create hash - format hash device */ #define CRYPT_VERITY_CREATE_HASH (UINT32_C(1) << 2) /** Root hash signature required for activation */ #define CRYPT_VERITY_ROOT_HASH_SIGNATURE (UINT32_C(1) << 3) /** * * Structure used as parameter for TCRYPT device type. * * @see crypt_load * */ struct crypt_params_tcrypt { const char *passphrase; /**< passphrase to unlock header (input only) */ size_t passphrase_size; /**< passphrase size (input only, max length is 64) */ const char **keyfiles; /**< keyfile paths to unlock header (input only) */ unsigned int keyfiles_count;/**< keyfiles count (input only) */ const char *hash_name; /**< hash function for PBKDF */ const char *cipher; /**< cipher chain c1[-c2[-c3]] */ const char *mode; /**< cipher block mode */ size_t key_size; /**< key size in bytes (the whole chain) */ uint32_t flags; /**< CRYPT_TCRYPT* flags */ uint32_t veracrypt_pim; /**< VeraCrypt Personal Iteration Multiplier */ }; /** Include legacy modes when scanning for header */ #define CRYPT_TCRYPT_LEGACY_MODES (UINT32_C(1) << 0) /** Try to load hidden header (describing hidden device) */ #define CRYPT_TCRYPT_HIDDEN_HEADER (UINT32_C(1) << 1) /** Try to load backup header */ #define CRYPT_TCRYPT_BACKUP_HEADER (UINT32_C(1) << 2) /** Device contains encrypted system (with boot loader) */ #define CRYPT_TCRYPT_SYSTEM_HEADER (UINT32_C(1) << 3) /** Include VeraCrypt modes when scanning for header, * all other TCRYPT flags applies as well. * VeraCrypt device is reported as TCRYPT type. */ #define CRYPT_TCRYPT_VERA_MODES (UINT32_C(1) << 4) /** * * Structure used as parameter for dm-integrity device type. * * @see crypt_format, crypt_load * * @note In bitmap tracking mode, the journal is implicitly disabled. * As an ugly workaround for compatibility, journal_watermark is overloaded * to mean 512-bytes sectors-per-bit and journal_commit_time means bitmap flush time. * All other journal parameters are not applied in the bitmap mode. */ struct crypt_params_integrity { uint64_t journal_size; /**< size of journal in bytes */ unsigned int journal_watermark; /**< journal flush watermark in percents; in bitmap mode sectors-per-bit */ unsigned int journal_commit_time; /**< journal commit time (or bitmap flush time) in ms */ uint32_t interleave_sectors; /**< number of interleave sectors (power of two) */ uint32_t tag_size; /**< tag size per-sector in bytes */ uint32_t sector_size; /**< sector size in bytes */ uint32_t buffer_sectors; /**< number of sectors in one buffer */ const char *integrity; /**< integrity algorithm, NULL for LUKS2 */ uint32_t integrity_key_size; /**< integrity key size in bytes, info only, 0 for LUKS2 */ const char *journal_integrity; /**< journal integrity algorithm */ const char *journal_integrity_key; /**< journal integrity key, only for crypt_load */ uint32_t journal_integrity_key_size; /**< journal integrity key size in bytes, only for crypt_load */ const char *journal_crypt; /**< journal encryption algorithm */ const char *journal_crypt_key; /**< journal crypt key, only for crypt_load */ uint32_t journal_crypt_key_size; /**< journal crypt key size in bytes, only for crypt_load */ }; /** * Structure used as parameter for LUKS2 device type. * * @see crypt_format, crypt_load * * @note during crypt_format @e data_device attribute determines * if the LUKS2 header is separated from encrypted payload device * */ struct crypt_params_luks2 { const struct crypt_pbkdf_type *pbkdf; /**< PBKDF (and hash) parameters or @e NULL*/ const char *integrity; /**< integrity algorithm or @e NULL */ const struct crypt_params_integrity *integrity_params; /**< Data integrity parameters or @e NULL*/ size_t data_alignment; /**< data area alignment in 512B sectors, data offset is multiple of this */ const char *data_device; /**< detached encrypted data device or @e NULL */ uint32_t sector_size; /**< encryption sector size, 0 triggers auto-detection for optimal encryption sector size */ const char *label; /**< header label or @e NULL*/ const char *subsystem; /**< header subsystem label or @e NULL*/ }; /** @} */ /** * @defgroup crypt-actions Cryptsetup device context actions * Set of functions for formatting and manipulating with specific crypt_type * @addtogroup crypt-actions * @{ */ /** * Create (format) new crypt device (and possible header on-disk) but do not activate it. * * @pre @e cd contains initialized and not formatted device context (device type must @b not be set) * * @param cd crypt device handle * @param type type of device (optional params struct must be of this type) * @param cipher (e.g. "aes") * @param cipher_mode including IV specification (e.g. "xts-plain") * @param uuid requested UUID or @e NULL if it should be generated * @param volume_key pre-generated volume key or @e NULL if it should be generated (only for LUKS) * @param volume_key_size size of volume key in bytes. * @param params crypt type specific parameters (see @link crypt-type @endlink) * * @returns @e 0 on success or negative errno value otherwise. * * @note Note that crypt_format does not create LUKS keyslot (any version). To create keyslot * call any crypt_keyslot_add_* function. * @note For VERITY @link crypt-type @endlink, only uuid parameter is used, other parameters * are ignored and verity specific attributes are set through mandatory params option. */ int crypt_format(struct crypt_device *cd, const char *type, const char *cipher, const char *cipher_mode, const char *uuid, const char *volume_key, size_t volume_key_size, void *params); /** * Set format compatibility flags. * * @param cd crypt device handle * @param flags CRYPT_COMPATIBILITY_* flags */ void crypt_set_compatibility(struct crypt_device *cd, uint32_t flags); /** * Get compatibility flags. * * @param cd crypt device handle * * @returns compatibility flags */ uint32_t crypt_get_compatibility(struct crypt_device *cd); /** dm-integrity device uses less effective (legacy) padding (old kernels) */ #define CRYPT_COMPAT_LEGACY_INTEGRITY_PADDING (UINT32_C(1) << 0) /** dm-integrity device does not protect superblock with HMAC (old kernels) */ #define CRYPT_COMPAT_LEGACY_INTEGRITY_HMAC (UINT32_C(1) << 1) /** dm-integrity allow recalculating of volumes with HMAC keys (old kernels) */ #define CRYPT_COMPAT_LEGACY_INTEGRITY_RECALC (UINT32_C(1) << 2) /** * Convert to new type for already existing device. * * @param cd crypt device handle * @param type type of device (optional params struct must be of this type) * @param params crypt type specific parameters (see @link crypt-type @endlink) * * @returns 0 on success or negative errno value otherwise. * * @note Currently, only LUKS1->LUKS2 and LUKS2->LUKS1 conversions are supported. * Not all LUKS2 devices may be converted back to LUKS1. To make such a conversion * possible all active LUKS2 keyslots must be in LUKS1 compatible mode (i.e. pbkdf * type must be PBKDF2) and device cannot be formatted with any authenticated * encryption mode. * * @note Device must be offline for conversion. UUID change is not possible for active * devices. */ int crypt_convert(struct crypt_device *cd, const char *type, void *params); /** * Set new UUID for already existing device. * * @param cd crypt device handle * @param uuid requested UUID or @e NULL if it should be generated * * @returns 0 on success or negative errno value otherwise. * * @note Currently, only LUKS device type are supported */ int crypt_set_uuid(struct crypt_device *cd, const char *uuid); /** * Set new labels (label and subsystem) for already existing device. * * @param cd crypt device handle * @param label requested label or @e NULL * @param subsystem requested subsystem label or @e NULL * * @returns 0 on success or negative errno value otherwise. * * @note Currently, only LUKS2 device type is supported */ int crypt_set_label(struct crypt_device *cd, const char *label, const char *subsystem); /** * Get the label of an existing device. * * @param cd crypt device handle * * @return label, or @e NULL otherwise */ const char *crypt_get_label(struct crypt_device *cd); /** * Get the subsystem of an existing device. * * @param cd crypt device handle * * @return subsystem, or @e NULL otherwise */ const char *crypt_get_subsystem(struct crypt_device *cd); /** * Enable or disable loading of volume keys via kernel keyring. When set to * 'enabled' library loads key in kernel keyring first and pass the key * description to dm-crypt instead of binary key copy. If set to 'disabled' * library fallbacks to old method of loading volume key directly in * dm-crypt target. * * @param cd crypt device handle, can be @e NULL * @param enable 0 to disable loading of volume keys via kernel keyring * (classical method) otherwise enable it (default) * * @returns @e 0 on success or negative errno value otherwise. * * @note Currently loading of volume keys via kernel keyring is supported * (and enabled by default) only for LUKS2 devices. * @note The switch is global on the library level. */ int crypt_volume_key_keyring(struct crypt_device *cd, int enable); /** * Load crypt device parameters from on-disk header. * * @param cd crypt device handle * @param requested_type @link crypt-type @endlink or @e NULL for all known * @param params crypt type specific parameters (see @link crypt-type @endlink) * * @returns 0 on success or negative errno value otherwise. * * @post In case LUKS header is read successfully but payload device is too small * error is returned and device type in context is set to @e NULL * * @note Note that load works only for device types with on-disk metadata. * @note Function does not print visible error message if metadata is not present. * */ int crypt_load(struct crypt_device *cd, const char *requested_type, void *params); /** * Try to repair crypt device LUKS on-disk header if invalid. * * @param cd crypt device handle * @param requested_type @link crypt-type @endlink or @e NULL for all known * @param params crypt type specific parameters (see @link crypt-type @endlink) * * @returns 0 on success or negative errno value otherwise. * * @note For LUKS2 device crypt_repair bypass blkid checks and * perform auto-recovery even though there're third party device * signatures found by blkid probes. Currently the crypt_repair on LUKS2 * works only if exactly one header checksum does not match or exactly * one header is missing. */ int crypt_repair(struct crypt_device *cd, const char *requested_type, void *params); /** * Resize crypt device. * * @param cd - crypt device handle * @param name - name of device to resize * @param new_size - new device size in sectors or @e 0 to use all of the underlying device size * * @return @e 0 on success or negative errno value otherwise. * * @note Most notably it returns -EPERM when device was activated with volume key * in kernel keyring and current device handle (context) doesn't have verified key * loaded in kernel. To load volume key for already active device use any of * @link crypt_activate_by_passphrase @endlink, @link crypt_activate_by_keyfile @endlink, * @link crypt_activate_by_keyfile_offset @endlink, @link crypt_activate_by_volume_key @endlink, * @link crypt_activate_by_keyring @endlink or @link crypt_activate_by_token @endlink with flag * @e CRYPT_ACTIVATE_KEYRING_KEY raised and @e name parameter set to @e NULL. */ int crypt_resize(struct crypt_device *cd, const char *name, uint64_t new_size); /** * Suspend crypt device. * * @param cd crypt device handle, can be @e NULL * @param name name of device to suspend * * @return 0 on success or negative errno value otherwise. * * @note Only LUKS device type is supported * */ int crypt_suspend(struct crypt_device *cd, const char *name); /** * Resume crypt device using passphrase. * * * @param cd crypt device handle * @param name name of device to resume * @param keyslot requested keyslot or CRYPT_ANY_SLOT * @param passphrase passphrase used to unlock volume key * @param passphrase_size size of @e passphrase (binary data) * * @return unlocked key slot number or negative errno otherwise. * * @note Only LUKS device type is supported */ int crypt_resume_by_passphrase(struct crypt_device *cd, const char *name, int keyslot, const char *passphrase, size_t passphrase_size); /** * Resume crypt device using key file. * * @param cd crypt device handle * @param name name of device to resume * @param keyslot requested keyslot or CRYPT_ANY_SLOT * @param keyfile key file used to unlock volume key * @param keyfile_size number of bytes to read from keyfile, 0 is unlimited * @param keyfile_offset number of bytes to skip at start of keyfile * * @return unlocked key slot number or negative errno otherwise. */ int crypt_resume_by_keyfile_device_offset(struct crypt_device *cd, const char *name, int keyslot, const char *keyfile, size_t keyfile_size, uint64_t keyfile_offset); /** * Backward compatible crypt_resume_by_keyfile_device_offset() (with size_t offset). */ int crypt_resume_by_keyfile_offset(struct crypt_device *cd, const char *name, int keyslot, const char *keyfile, size_t keyfile_size, size_t keyfile_offset); /** * Backward compatible crypt_resume_by_keyfile_device_offset() (without offset). */ int crypt_resume_by_keyfile(struct crypt_device *cd, const char *name, int keyslot, const char *keyfile, size_t keyfile_size); /** * Resume crypt device using provided volume key. * * @param cd crypt device handle * @param name name of device to resume * @param volume_key provided volume key * @param volume_key_size size of volume_key * * @return @e 0 on success or negative errno value otherwise. */ int crypt_resume_by_volume_key(struct crypt_device *cd, const char *name, const char *volume_key, size_t volume_key_size); /** * Resume crypt device using LUKS2 token. * * @param cd LUKS2 crypt device handle * @param name name of device to resume * @param type restrict type of token, if @e NULL all types are allowed * @param pin passphrase (or PIN) to unlock token (may be binary data) * @param pin_size size of @e pin * @param usrptr provided identification in callback * * @return unlocked key slot number or negative errno otherwise. * * @note EPERM errno means token provided passphrase successfully, but * passphrase did not unlock any keyslot associated with the token. * * @note ENOENT errno means no token (or subsequently assigned keyslot) was * eligible to resume LUKS2 device. * * @note ENOANO errno means that token is PIN protected and was either missing * (NULL) or wrong. * * @note Negative EAGAIN errno means token handler requires additional hardware * not present in the system to unlock keyslot. * * @note with @param token set to CRYPT_ANY_TOKEN libcryptsetup runs best effort loop * to resume device using any available token. It may happen that various token handlers * return different error codes. At the end loop returns error codes in the following * order (from the most significant to the least) any negative errno except those * listed below, non negative token id (success), -ENOANO, -EAGAIN, -EPERM, -ENOENT. */ int crypt_resume_by_token_pin(struct crypt_device *cd, const char *name, const char *type, int token, const char *pin, size_t pin_size, void *usrptr); /** @} */ /** * @defgroup crypt-keyslot LUKS keyslots * @addtogroup crypt-keyslot * @{ */ /** iterate through all keyslots and find first one that fits */ #define CRYPT_ANY_SLOT -1 /** * Add key slot using provided passphrase. * * @pre @e cd contains initialized and formatted LUKS device context * * @param cd crypt device handle * @param keyslot requested keyslot or @e CRYPT_ANY_SLOT * @param passphrase passphrase used to unlock volume key * @param passphrase_size size of passphrase (binary data) * @param new_passphrase passphrase for new keyslot * @param new_passphrase_size size of @e new_passphrase (binary data) * * @return allocated key slot number or negative errno otherwise. */ int crypt_keyslot_add_by_passphrase(struct crypt_device *cd, int keyslot, const char *passphrase, size_t passphrase_size, const char *new_passphrase, size_t new_passphrase_size); /** * Change defined key slot using provided passphrase. * * @pre @e cd contains initialized and formatted LUKS device context * * @param cd crypt device handle * @param keyslot_old old keyslot or @e CRYPT_ANY_SLOT * @param keyslot_new new keyslot (can be the same as old) * @param passphrase passphrase used to unlock volume key * @param passphrase_size size of passphrase (binary data) * @param new_passphrase passphrase for new keyslot * @param new_passphrase_size size of @e new_passphrase (binary data) * * @return allocated key slot number or negative errno otherwise. */ int crypt_keyslot_change_by_passphrase(struct crypt_device *cd, int keyslot_old, int keyslot_new, const char *passphrase, size_t passphrase_size, const char *new_passphrase, size_t new_passphrase_size); /** * Add key slot using provided key file path. * * @pre @e cd contains initialized and formatted LUKS device context * * @param cd crypt device handle * @param keyslot requested keyslot or @e CRYPT_ANY_SLOT * @param keyfile key file used to unlock volume key * @param keyfile_size number of bytes to read from keyfile, @e 0 is unlimited * @param keyfile_offset number of bytes to skip at start of keyfile * @param new_keyfile keyfile for new keyslot * @param new_keyfile_size number of bytes to read from @e new_keyfile, @e 0 is unlimited * @param new_keyfile_offset number of bytes to skip at start of new_keyfile * * @return allocated key slot number or negative errno otherwise. */ int crypt_keyslot_add_by_keyfile_device_offset(struct crypt_device *cd, int keyslot, const char *keyfile, size_t keyfile_size, uint64_t keyfile_offset, const char *new_keyfile, size_t new_keyfile_size, uint64_t new_keyfile_offset); /** * Backward compatible crypt_keyslot_add_by_keyfile_device_offset() (with size_t offset). */ int crypt_keyslot_add_by_keyfile_offset(struct crypt_device *cd, int keyslot, const char *keyfile, size_t keyfile_size, size_t keyfile_offset, const char *new_keyfile, size_t new_keyfile_size, size_t new_keyfile_offset); /** * Backward compatible crypt_keyslot_add_by_keyfile_device_offset() (without offset). */ int crypt_keyslot_add_by_keyfile(struct crypt_device *cd, int keyslot, const char *keyfile, size_t keyfile_size, const char *new_keyfile, size_t new_keyfile_size); /** * Add key slot using provided volume key. * * @pre @e cd contains initialized and formatted LUKS device context * * @param cd crypt device handle * @param keyslot requested keyslot or CRYPT_ANY_SLOT * @param volume_key provided volume key or @e NULL if used after crypt_format * @param volume_key_size size of volume_key * @param passphrase passphrase for new keyslot * @param passphrase_size size of passphrase * * @return allocated key slot number or negative errno otherwise. */ int crypt_keyslot_add_by_volume_key(struct crypt_device *cd, int keyslot, const char *volume_key, size_t volume_key_size, const char *passphrase, size_t passphrase_size); /** create keyslot with volume key not associated with current dm-crypt segment */ #define CRYPT_VOLUME_KEY_NO_SEGMENT (UINT32_C(1) << 0) /** create keyslot with new volume key and assign it to current dm-crypt segment */ #define CRYPT_VOLUME_KEY_SET (UINT32_C(1) << 1) /** Assign key to first matching digest before creating new digest */ #define CRYPT_VOLUME_KEY_DIGEST_REUSE (UINT32_C(1) << 2) /** * Add key slot using provided key. * * @pre @e cd contains initialized and formatted LUKS2 device context * * @param cd crypt device handle * @param keyslot requested keyslot or CRYPT_ANY_SLOT * @param volume_key provided volume key or @e NULL (see note below) * @param volume_key_size size of volume_key * @param passphrase passphrase for new keyslot * @param passphrase_size size of passphrase * @param flags key flags to set * * @return allocated key slot number or negative errno otherwise. * * @note in case volume_key is @e NULL following first matching rule will apply: * @li if cd is device handle used in crypt_format() by current process, the volume * key generated (or passed) in crypt_format() will be stored in keyslot. * @li if CRYPT_VOLUME_KEY_NO_SEGMENT flag is raised the new volume_key will be * generated and stored in keyslot. The keyslot will become unbound (unusable to * dm-crypt device activation). * @li fails with -EINVAL otherwise * * @warning CRYPT_VOLUME_KEY_SET flag force updates volume key. It is @b not @b reencryption! * By doing so you will most probably destroy your ciphertext data device. It's supposed * to be used only in wrapped keys scheme for key refresh process where real (inner) volume * key stays untouched. It may be involed on active @e keyslot which makes the (previously * unbound) keyslot new regular keyslot. */ int crypt_keyslot_add_by_key(struct crypt_device *cd, int keyslot, const char *volume_key, size_t volume_key_size, const char *passphrase, size_t passphrase_size, uint32_t flags); /** * Destroy (and disable) key slot. * * @pre @e cd contains initialized and formatted LUKS device context * * @param cd crypt device handle * @param keyslot requested key slot to destroy * * @return @e 0 on success or negative errno value otherwise. * * @note Note that there is no passphrase verification used. */ int crypt_keyslot_destroy(struct crypt_device *cd, int keyslot); /** @} */ /** * @defgroup crypt-aflags Device runtime attributes * Activation flags * @addtogroup crypt-aflags * @{ */ /** device is read only */ #define CRYPT_ACTIVATE_READONLY (UINT32_C(1) << 0) /** only reported for device without uuid */ #define CRYPT_ACTIVATE_NO_UUID (UINT32_C(1) << 1) /** activate even if cannot grant exclusive access (DANGEROUS) */ #define CRYPT_ACTIVATE_SHARED (UINT32_C(1) << 2) /** enable discards aka TRIM */ #define CRYPT_ACTIVATE_ALLOW_DISCARDS (UINT32_C(1) << 3) /** skip global udev rules in activation ("private device"), input only */ #define CRYPT_ACTIVATE_PRIVATE (UINT32_C(1) << 4) /** corruption detected (verity), output only */ #define CRYPT_ACTIVATE_CORRUPTED (UINT32_C(1) << 5) /** use same_cpu_crypt option for dm-crypt */ #define CRYPT_ACTIVATE_SAME_CPU_CRYPT (UINT32_C(1) << 6) /** use submit_from_crypt_cpus for dm-crypt */ #define CRYPT_ACTIVATE_SUBMIT_FROM_CRYPT_CPUS (UINT32_C(1) << 7) /** dm-verity: ignore_corruption flag - ignore corruption, log it only */ #define CRYPT_ACTIVATE_IGNORE_CORRUPTION (UINT32_C(1) << 8) /** dm-verity: restart_on_corruption flag - restart kernel on corruption */ #define CRYPT_ACTIVATE_RESTART_ON_CORRUPTION (UINT32_C(1) << 9) /** dm-verity: ignore_zero_blocks - do not verify zero blocks */ #define CRYPT_ACTIVATE_IGNORE_ZERO_BLOCKS (UINT32_C(1) << 10) /** key loaded in kernel keyring instead directly in dm-crypt */ #define CRYPT_ACTIVATE_KEYRING_KEY (UINT32_C(1) << 11) /** dm-integrity: direct writes, do not use journal */ #define CRYPT_ACTIVATE_NO_JOURNAL (UINT32_C(1) << 12) /** dm-integrity: recovery mode - no journal, no integrity checks */ #define CRYPT_ACTIVATE_RECOVERY (UINT32_C(1) << 13) /** ignore persistently stored flags */ #define CRYPT_ACTIVATE_IGNORE_PERSISTENT (UINT32_C(1) << 14) /** dm-verity: check_at_most_once - check data blocks only the first time */ #define CRYPT_ACTIVATE_CHECK_AT_MOST_ONCE (UINT32_C(1) << 15) /** allow activation check including unbound keyslots (keyslots without segments) */ #define CRYPT_ACTIVATE_ALLOW_UNBOUND_KEY (UINT32_C(1) << 16) /** dm-integrity: activate automatic recalculation */ #define CRYPT_ACTIVATE_RECALCULATE (UINT32_C(1) << 17) /** reactivate existing and update flags, input only */ #define CRYPT_ACTIVATE_REFRESH (UINT32_C(1) << 18) /** Use global lock to serialize memory hard KDF on activation (OOM workaround) */ #define CRYPT_ACTIVATE_SERIALIZE_MEMORY_HARD_PBKDF (UINT32_C(1) << 19) /** dm-integrity: direct writes, use bitmap to track dirty sectors */ #define CRYPT_ACTIVATE_NO_JOURNAL_BITMAP (UINT32_C(1) << 20) /** device is suspended (key should be wiped from memory), output only */ #define CRYPT_ACTIVATE_SUSPENDED (UINT32_C(1) << 21) /** use IV sector counted in sector_size instead of default 512 bytes sectors */ #define CRYPT_ACTIVATE_IV_LARGE_SECTORS (UINT32_C(1) << 22) /** dm-verity: panic_on_corruption flag - panic kernel on corruption */ #define CRYPT_ACTIVATE_PANIC_ON_CORRUPTION (UINT32_C(1) << 23) /** dm-crypt: bypass internal workqueue and process read requests synchronously. */ #define CRYPT_ACTIVATE_NO_READ_WORKQUEUE (UINT32_C(1) << 24) /** dm-crypt: bypass internal workqueue and process write requests synchronously. */ #define CRYPT_ACTIVATE_NO_WRITE_WORKQUEUE (UINT32_C(1) << 25) /** dm-integrity: reset automatic recalculation */ #define CRYPT_ACTIVATE_RECALCULATE_RESET (UINT32_C(1) << 26) /** * Active device runtime attributes */ struct crypt_active_device { uint64_t offset; /**< offset in sectors */ uint64_t iv_offset; /**< IV initialization sector */ uint64_t size; /**< active device size */ uint32_t flags; /**< activation flags */ }; /** * Receive runtime attributes of active crypt device. * * @param cd crypt device handle (can be @e NULL) * @param name name of active device * @param cad preallocated active device attributes to fill * * @return @e 0 on success or negative errno value otherwise * */ int crypt_get_active_device(struct crypt_device *cd, const char *name, struct crypt_active_device *cad); /** * Get detected number of integrity failures. * * @param cd crypt device handle (can be @e NULL) * @param name name of active device * * @return number of integrity failures or @e 0 otherwise * */ uint64_t crypt_get_active_integrity_failures(struct crypt_device *cd, const char *name); /** @} */ /** * @defgroup crypt-pflags LUKS2 Device persistent flags and requirements * @addtogroup crypt-pflags * @{ */ /** * LUKS2 header requirements */ /** Unfinished offline reencryption */ #define CRYPT_REQUIREMENT_OFFLINE_REENCRYPT (UINT32_C(1) << 0) /** Online reencryption in-progress */ #define CRYPT_REQUIREMENT_ONLINE_REENCRYPT (UINT32_C(1) << 1) /** unknown requirement in header (output only) */ #define CRYPT_REQUIREMENT_UNKNOWN (UINT32_C(1) << 31) /** * Persistent flags type */ typedef enum { CRYPT_FLAGS_ACTIVATION, /**< activation flags, @see aflags */ CRYPT_FLAGS_REQUIREMENTS /**< requirements flags */ } crypt_flags_type; /** * Set persistent flags. * * @param cd crypt device handle (can be @e NULL) * @param type type to set (CRYPT_FLAGS_ACTIVATION or CRYPT_FLAGS_REQUIREMENTS) * @param flags flags to set * * @return @e 0 on success or negative errno value otherwise * * @note Valid only for LUKS2. * * @note Not all activation flags can be stored. Only ALLOW_DISCARD, * SAME_CPU_CRYPT, SUBMIT_FROM_CRYPT_CPU and NO_JOURNAL can be * stored persistently. * * @note Only requirements flags recognised by current library may be set. * CRYPT_REQUIREMENT_UNKNOWN is illegal (output only) in set operation. */ int crypt_persistent_flags_set(struct crypt_device *cd, crypt_flags_type type, uint32_t flags); /** * Get persistent flags stored in header. * * @param cd crypt device handle (can be @e NULL) * @param type flags type to retrieve (CRYPT_FLAGS_ACTIVATION or CRYPT_FLAGS_REQUIREMENTS) * @param flags reference to output variable * * @return @e 0 on success or negative errno value otherwise */ int crypt_persistent_flags_get(struct crypt_device *cd, crypt_flags_type type, uint32_t *flags); /** @} */ /** * @defgroup crypt-activation Device activation * @addtogroup crypt-activation * @{ */ /** * Activate device or check passphrase. * * @param cd crypt device handle * @param name name of device to create, if @e NULL only check passphrase * @param keyslot requested keyslot to check or @e CRYPT_ANY_SLOT * @param passphrase passphrase used to unlock volume key * @param passphrase_size size of @e passphrase * @param flags activation flags * * @return unlocked key slot number or negative errno otherwise. */ int crypt_activate_by_passphrase(struct crypt_device *cd, const char *name, int keyslot, const char *passphrase, size_t passphrase_size, uint32_t flags); /** * Activate device or check using key file. * * @param cd crypt device handle * @param name name of device to create, if @e NULL only check keyfile * @param keyslot requested keyslot to check or CRYPT_ANY_SLOT * @param keyfile key file used to unlock volume key * @param keyfile_size number of bytes to read from keyfile, 0 is unlimited * @param keyfile_offset number of bytes to skip at start of keyfile * @param flags activation flags * * @return unlocked key slot number or negative errno otherwise. */ int crypt_activate_by_keyfile_device_offset(struct crypt_device *cd, const char *name, int keyslot, const char *keyfile, size_t keyfile_size, uint64_t keyfile_offset, uint32_t flags); /** * Backward compatible crypt_activate_by_keyfile_device_offset() (with size_t offset). */ int crypt_activate_by_keyfile_offset(struct crypt_device *cd, const char *name, int keyslot, const char *keyfile, size_t keyfile_size, size_t keyfile_offset, uint32_t flags); /** * Backward compatible crypt_activate_by_keyfile_device_offset() (without offset). */ int crypt_activate_by_keyfile(struct crypt_device *cd, const char *name, int keyslot, const char *keyfile, size_t keyfile_size, uint32_t flags); /** * Activate device using provided volume key. * * @param cd crypt device handle * @param name name of device to create, if @e NULL only check volume key * @param volume_key provided volume key (or @e NULL to use internal) * @param volume_key_size size of volume_key * @param flags activation flags * * @return @e 0 on success or negative errno value otherwise. * * @note If @e NULL is used for volume_key, device has to be initialized * by previous operation (like @ref crypt_format * or @ref crypt_init_by_name) * @note For VERITY the volume key means root hash required for activation. * Because kernel dm-verity is always read only, you have to provide * CRYPT_ACTIVATE_READONLY flag always. * @note For TCRYPT the volume key should be always NULL * the key from decrypted header is used instead. */ int crypt_activate_by_volume_key(struct crypt_device *cd, const char *name, const char *volume_key, size_t volume_key_size, uint32_t flags); /** * Activate VERITY device using provided key and optional signature). * * @param cd crypt device handle * @param name name of device to create * @param volume_key provided volume key * @param volume_key_size size of volume_key * @param signature buffer with signature for the key * @param signature_size bsize of signature buffer * @param flags activation flags * * @return @e 0 on success or negative errno value otherwise. * * @note For VERITY the volume key means root hash required for activation. * Because kernel dm-verity is always read only, you have to provide * CRYPT_ACTIVATE_READONLY flag always. */ int crypt_activate_by_signed_key(struct crypt_device *cd, const char *name, const char *volume_key, size_t volume_key_size, const char *signature, size_t signature_size, uint32_t flags); /** * Activate device using passphrase stored in kernel keyring. * * @param cd crypt device handle * @param name name of device to create, if @e NULL only check passphrase in keyring * @param key_description kernel keyring key description library should look * for passphrase in * @param keyslot requested keyslot to check or CRYPT_ANY_SLOT * @param flags activation flags * * @return @e unlocked keyslot number on success or negative errno value otherwise. * * @note Keyslot passphrase must be stored in 'user' key type * and the key has to be reachable for process context * on behalf of which this function is called. */ int crypt_activate_by_keyring(struct crypt_device *cd, const char *name, const char *key_description, int keyslot, uint32_t flags); /** lazy deactivation - remove once last user releases it */ #define CRYPT_DEACTIVATE_DEFERRED (UINT32_C(1) << 0) /** force deactivation - if the device is busy, it is replaced by error device */ #define CRYPT_DEACTIVATE_FORCE (UINT32_C(1) << 1) /** if set, remove lazy deactivation */ #define CRYPT_DEACTIVATE_DEFERRED_CANCEL (UINT32_C(1) << 2) /** * Deactivate crypt device. This function tries to remove active device-mapper * mapping from kernel. Also, sensitive data like the volume key are removed from * memory * * @param cd crypt device handle, can be @e NULL * @param name name of device to deactivate * @param flags deactivation flags * * @return @e 0 on success or negative errno value otherwise. * */ int crypt_deactivate_by_name(struct crypt_device *cd, const char *name, uint32_t flags); /** * Deactivate crypt device. See @ref crypt_deactivate_by_name with empty @e flags. */ int crypt_deactivate(struct crypt_device *cd, const char *name); /** @} */ /** * @defgroup crypt-key Volume Key manipulation * @addtogroup crypt-key * @{ */ /** * Get volume key from crypt device. * * @param cd crypt device handle * @param keyslot use this keyslot or @e CRYPT_ANY_SLOT * @param volume_key buffer for volume key * @param volume_key_size on input, size of buffer @e volume_key, * on output size of @e volume_key * @param passphrase passphrase used to unlock volume key * @param passphrase_size size of @e passphrase * * @return unlocked key slot number or negative errno otherwise. * * @note For TCRYPT cipher chain is the volume key concatenated * for all ciphers in chain. * @note For VERITY the volume key means root hash used for activation. */ int crypt_volume_key_get(struct crypt_device *cd, int keyslot, char *volume_key, size_t *volume_key_size, const char *passphrase, size_t passphrase_size); /** * Verify that provided volume key is valid for crypt device. * * @param cd crypt device handle * @param volume_key provided volume key * @param volume_key_size size of @e volume_key * * @return @e 0 on success or negative errno value otherwise. * * @note Negative EPERM return value means that passed volume_key * did not pass digest verification routine (not a valid volume * key). */ int crypt_volume_key_verify(struct crypt_device *cd, const char *volume_key, size_t volume_key_size); /** @} */ /** * @defgroup crypt-devstat Crypt and Verity device status * @addtogroup crypt-devstat * @{ */ /** * Device status */ typedef enum { CRYPT_INVALID, /**< device mapping is invalid in this context */ CRYPT_INACTIVE, /**< no such mapped device */ CRYPT_ACTIVE, /**< device is active */ CRYPT_BUSY /**< device is active and has open count > 0 */ } crypt_status_info; /** * Get status info about device name. * * @param cd crypt device handle, can be @e NULL * @param name crypt device name * * @return value defined by crypt_status_info. * */ crypt_status_info crypt_status(struct crypt_device *cd, const char *name); /** * Dump text-formatted information about crypt or verity device to log output. * * @param cd crypt device handle * * @return @e 0 on success or negative errno value otherwise. */ int crypt_dump(struct crypt_device *cd); /** * Dump JSON-formatted information about LUKS2 device * * @param cd crypt device handle (only LUKS2 format supported) * @param json buffer with JSON, if NULL use log callback for output * @param flags dump flags (reserved) * * @return @e 0 on success or negative errno value otherwise. */ int crypt_dump_json(struct crypt_device *cd, const char **json, uint32_t flags); /** * Get cipher used in device. * * @param cd crypt device handle * * @return used cipher, e.g. "aes" or @e NULL otherwise * */ const char *crypt_get_cipher(struct crypt_device *cd); /** * Get cipher mode used in device. * * @param cd crypt device handle * * @return used cipher mode e.g. "xts-plain" or @e otherwise * */ const char *crypt_get_cipher_mode(struct crypt_device *cd); /** * Get device UUID. * * @param cd crypt device handle * * @return device UUID or @e NULL if not set * */ const char *crypt_get_uuid(struct crypt_device *cd); /** * Get path to underlying device. * * @param cd crypt device handle * * @return path to underlying device name * */ const char *crypt_get_device_name(struct crypt_device *cd); /** * Get path to detached metadata device or @e NULL if it is not detached. * * @param cd crypt device handle * * @return path to underlying device name * */ const char *crypt_get_metadata_device_name(struct crypt_device *cd); /** * Get device offset in 512-bytes sectors where real data starts (on underlying device). * * @param cd crypt device handle * * @return device offset in sectors * */ uint64_t crypt_get_data_offset(struct crypt_device *cd); /** * Get IV offset in 512-bytes sectors (skip). * * @param cd crypt device handle * * @return IV offset * */ uint64_t crypt_get_iv_offset(struct crypt_device *cd); /** * Get size (in bytes) of volume key for crypt device. * * @param cd crypt device handle * * @return volume key size * * @note For LUKS2, this function can be used only if there is at least * one keyslot assigned to data segment. */ int crypt_get_volume_key_size(struct crypt_device *cd); /** * Get size (in bytes) of encryption sector for crypt device. * * @param cd crypt device handle * * @return sector size * */ int crypt_get_sector_size(struct crypt_device *cd); /** * Check if initialized LUKS context uses detached header * (LUKS header located on a different device than data.) * * @param cd crypt device handle * * @return @e 1 if detached header is used, @e 0 if not * or negative errno value otherwise. * * @note This is a runtime attribute, it does not say * if a LUKS device requires detached header. * This function works only with LUKS devices. */ int crypt_header_is_detached(struct crypt_device *cd); /** * Get device parameters for VERITY device. * * @param cd crypt device handle * @param vp verity device info * * @e 0 on success or negative errno value otherwise. * */ int crypt_get_verity_info(struct crypt_device *cd, struct crypt_params_verity *vp); /** * Get device parameters for INTEGRITY device. * * @param cd crypt device handle * @param ip verity device info * * @e 0 on success or negative errno value otherwise. * */ int crypt_get_integrity_info(struct crypt_device *cd, struct crypt_params_integrity *ip); /** @} */ /** * @defgroup crypt-benchmark Benchmarking * Benchmarking of algorithms * @addtogroup crypt-benchmark * @{ */ /** * Informational benchmark for ciphers. * * @param cd crypt device handle * @param cipher (e.g. "aes") * @param cipher_mode (e.g. "xts"), IV generator is ignored * @param volume_key_size size of volume key in bytes * @param iv_size size of IV in bytes * @param buffer_size size of encryption buffer in bytes used in test * @param encryption_mbs measured encryption speed in MiB/s * @param decryption_mbs measured decryption speed in MiB/s * * @return @e 0 on success or negative errno value otherwise. * * @note If encryption_buffer_size is too small and encryption time * cannot be properly measured, -ERANGE is returned. */ int crypt_benchmark(struct crypt_device *cd, const char *cipher, const char *cipher_mode, size_t volume_key_size, size_t iv_size, size_t buffer_size, double *encryption_mbs, double *decryption_mbs); /** * Informational benchmark for PBKDF. * * @param cd crypt device handle * @param pbkdf PBKDF parameters * @param password password for benchmark * @param password_size size of password * @param salt salt for benchmark * @param salt_size size of salt * @param volume_key_size output volume key size * @param progress callback function * @param usrptr provided identification in callback * * @return @e 0 on success or negative errno value otherwise. */ int crypt_benchmark_pbkdf(struct crypt_device *cd, struct crypt_pbkdf_type *pbkdf, const char *password, size_t password_size, const char *salt, size_t salt_size, size_t volume_key_size, int (*progress)(uint32_t time_ms, void *usrptr), void *usrptr); /** @} */ /** * @addtogroup crypt-keyslot * @{ */ /** * Crypt keyslot info */ typedef enum { CRYPT_SLOT_INVALID, /**< invalid keyslot */ CRYPT_SLOT_INACTIVE, /**< keyslot is inactive (free) */ CRYPT_SLOT_ACTIVE, /**< keyslot is active (used) */ CRYPT_SLOT_ACTIVE_LAST,/**< keylost is active (used) * and last used at the same time */ CRYPT_SLOT_UNBOUND /**< keyslot is active and not bound * to any crypt segment (LUKS2 only) */ } crypt_keyslot_info; /** * Get information about particular key slot. * * @param cd crypt device handle * @param keyslot requested keyslot to check or CRYPT_ANY_SLOT * * @return value defined by crypt_keyslot_info * */ crypt_keyslot_info crypt_keyslot_status(struct crypt_device *cd, int keyslot); /** * Crypt keyslot priority */ typedef enum { CRYPT_SLOT_PRIORITY_INVALID =-1, /**< no such slot */ CRYPT_SLOT_PRIORITY_IGNORE = 0, /**< CRYPT_ANY_SLOT will ignore it for open */ CRYPT_SLOT_PRIORITY_NORMAL = 1, /**< default priority, tried after preferred */ CRYPT_SLOT_PRIORITY_PREFER = 2, /**< will try to open first */ } crypt_keyslot_priority; /** * Get keyslot priority (LUKS2) * * @param cd crypt device handle * @param keyslot keyslot number * * @return value defined by crypt_keyslot_priority */ crypt_keyslot_priority crypt_keyslot_get_priority(struct crypt_device *cd, int keyslot); /** * Set keyslot priority (LUKS2) * * @param cd crypt device handle * @param keyslot keyslot number * @param priority priority defined in crypt_keyslot_priority * * @return @e 0 on success or negative errno value otherwise. */ int crypt_keyslot_set_priority(struct crypt_device *cd, int keyslot, crypt_keyslot_priority priority); /** * Get number of keyslots supported for device type. * * @param type crypt device type * * @return slot count or negative errno otherwise if device * doesn't not support keyslots. */ int crypt_keyslot_max(const char *type); /** * Get keyslot area pointers (relative to metadata device). * * @param cd crypt device handle * @param keyslot keyslot number * @param offset offset on metadata device (in bytes) * @param length length of keyslot area (in bytes) * * @return @e 0 on success or negative errno value otherwise. * */ int crypt_keyslot_area(struct crypt_device *cd, int keyslot, uint64_t *offset, uint64_t *length); /** * Get size (in bytes) of stored key in particular keyslot. * Use for LUKS2 unbound keyslots, for other keyslots it is the same as @ref crypt_get_volume_key_size * * @param cd crypt device handle * @param keyslot keyslot number * * @return volume key size or negative errno value otherwise. * */ int crypt_keyslot_get_key_size(struct crypt_device *cd, int keyslot); /** * Get cipher and key size for keyslot encryption. * Use for LUKS2 keyslot to set different encryption type than for data encryption. * Parameters will be used for next keyslot operations. * * @param cd crypt device handle * @param keyslot keyslot number of CRYPT_ANY_SLOT for default * @param key_size encryption key size (in bytes) * * @return cipher specification on success or @e NULL. * * @note This is the encryption of keyslot itself, not the data encryption algorithm! */ const char *crypt_keyslot_get_encryption(struct crypt_device *cd, int keyslot, size_t *key_size); /** * Get PBKDF parameters for keyslot. * * @param cd crypt device handle * @param keyslot keyslot number * @param pbkdf struct with returned PBKDF parameters * * @return @e 0 on success or negative errno value otherwise. */ int crypt_keyslot_get_pbkdf(struct crypt_device *cd, int keyslot, struct crypt_pbkdf_type *pbkdf); /** * Set encryption for keyslot. * Use for LUKS2 keyslot to set different encryption type than for data encryption. * Parameters will be used for next keyslot operations that create or change a keyslot. * * @param cd crypt device handle * @param cipher (e.g. "aes-xts-plain64") * @param key_size encryption key size (in bytes) * * @return @e 0 on success or negative errno value otherwise. * * @note To reset to default keyslot encryption (the same as for data) * set cipher to NULL and key size to 0. */ int crypt_keyslot_set_encryption(struct crypt_device *cd, const char *cipher, size_t key_size); /** * Get directory where mapped crypt devices are created * * @return the directory path */ const char *crypt_get_dir(void); /** @} */ /** * @defgroup crypt-backup Device metadata backup * @addtogroup crypt-backup * @{ */ /** * Backup header and keyslots to file. * * @param cd crypt device handle * @param requested_type @link crypt-type @endlink or @e NULL for all known * @param backup_file file to backup header to * * @return @e 0 on success or negative errno value otherwise. * */ int crypt_header_backup(struct crypt_device *cd, const char *requested_type, const char *backup_file); /** * Restore header and keyslots from backup file. * * @param cd crypt device handle * @param requested_type @link crypt-type @endlink or @e NULL for all known * @param backup_file file to restore header from * * @return @e 0 on success or negative errno value otherwise. * */ int crypt_header_restore(struct crypt_device *cd, const char *requested_type, const char *backup_file); /** @} */ /** * @defgroup crypt-dbg Library debug level * Set library debug level * @addtogroup crypt-dbg * @{ */ /** Debug all */ #define CRYPT_DEBUG_ALL -1 /** Debug all with additional JSON dump (for LUKS2) */ #define CRYPT_DEBUG_JSON -2 /** Debug none */ #define CRYPT_DEBUG_NONE 0 /** * Set the debug level for library * * @param level debug level * */ void crypt_set_debug_level(int level); /** @} */ /** * @defgroup crypt-keyfile Function to read keyfile * @addtogroup crypt-keyfile * @{ */ /** * Read keyfile * * @param cd crypt device handle * @param keyfile keyfile to read * @param key buffer for key * @param key_size_read size of read key * @param keyfile_offset key offset in keyfile * @param key_size exact key length to read from file or 0 * @param flags keyfile read flags * * @return @e 0 on success or negative errno value otherwise. * * @note If key_size is set to zero we read internal max length * and actual size read is returned via key_size_read parameter. */ int crypt_keyfile_device_read(struct crypt_device *cd, const char *keyfile, char **key, size_t *key_size_read, uint64_t keyfile_offset, size_t key_size, uint32_t flags); /** * Backward compatible crypt_keyfile_device_read() (with size_t offset). */ int crypt_keyfile_read(struct crypt_device *cd, const char *keyfile, char **key, size_t *key_size_read, size_t keyfile_offset, size_t key_size, uint32_t flags); /** Read key only to the first end of line (\\n). */ #define CRYPT_KEYFILE_STOP_EOL (UINT32_C(1) << 0) /** @} */ /** * @defgroup crypt-wipe Function to wipe device * @addtogroup crypt-wipe * @{ */ /** * Wipe pattern */ typedef enum { CRYPT_WIPE_ZERO, /**< Fill with zeroes */ CRYPT_WIPE_RANDOM, /**< Use RNG to fill data */ CRYPT_WIPE_ENCRYPTED_ZERO, /**< Obsolete, same as CRYPT_WIPE_RANDOM */ CRYPT_WIPE_SPECIAL, /**< Compatibility only, do not use (Gutmann method) */ } crypt_wipe_pattern; /** * Wipe/Fill (part of) a device with the selected pattern. * * @param cd crypt device handle * @param dev_path path to device to wipe or @e NULL if data device should be used * @param pattern selected wipe pattern * @param offset offset on device (in bytes) * @param length length of area to be wiped (in bytes) * @param wipe_block_size used block for wiping (one step) (in bytes) * @param flags wipe flags * @param progress callback function called after each @e wipe_block_size or @e NULL * @param usrptr provided identification in callback * * @return @e 0 on success or negative errno value otherwise. * * @note A @e progress callback can interrupt wipe process by returning non-zero code. * * @note If the error values is -EIO or -EINTR, some part of the device could * be overwritten. Other error codes (-EINVAL, -ENOMEM) means that no IO was performed. */ int crypt_wipe(struct crypt_device *cd, const char *dev_path, /* if null, use data device */ crypt_wipe_pattern pattern, uint64_t offset, uint64_t length, size_t wipe_block_size, uint32_t flags, int (*progress)(uint64_t size, uint64_t offset, void *usrptr), void *usrptr ); /** Use direct-io */ #define CRYPT_WIPE_NO_DIRECT_IO (UINT32_C(1) << 0) /** @} */ /** * @defgroup crypt-tokens LUKS2 token wrapper access * * Utilities for handling tokens LUKS2 * Token is a device or a method how to read password for particular keyslot * automatically. It can be chunk of data stored on hardware token or * just a metadata how to generate the password. * * @addtogroup crypt-tokens * @{ */ /** * Get number of tokens supported for device type. * * @param type crypt device type * * @return token count or negative errno otherwise if device * doesn't not support tokens. * * @note Real number of supported tokens for a particular device depends * on usable metadata area size. */ int crypt_token_max(const char *type); /** Iterate through all tokens */ #define CRYPT_ANY_TOKEN -1 /** * Get content of a token definition in JSON format. * * @param cd crypt device handle * @param token token id * @param json buffer with JSON * * @return allocated token id or negative errno otherwise. */ int crypt_token_json_get(struct crypt_device *cd, int token, const char **json); /** * Store content of a token definition in JSON format. * * @param cd crypt device handle * @param token token id or @e CRYPT_ANY_TOKEN to allocate new one * @param json buffer with JSON or @e NULL to remove token * * @return allocated token id or negative errno otherwise. * * @note The buffer must be in proper JSON format and must contain at least * string "type" with slot type and an array of string names "keyslots". * Keyslots array contains assignments to particular slots and can be empty. */ int crypt_token_json_set(struct crypt_device *cd, int token, const char *json); /** * Token info */ typedef enum { CRYPT_TOKEN_INVALID, /**< token is invalid */ CRYPT_TOKEN_INACTIVE, /**< token is empty (free) */ CRYPT_TOKEN_INTERNAL, /**< active internal token with driver */ CRYPT_TOKEN_INTERNAL_UNKNOWN, /**< active internal token (reserved name) with missing token driver */ CRYPT_TOKEN_EXTERNAL, /**< active external (user defined) token with driver */ CRYPT_TOKEN_EXTERNAL_UNKNOWN, /**< active external (user defined) token with missing token driver */ } crypt_token_info; /** * Get info for specific token. * * @param cd crypt device handle * @param token existing token id * @param type pointer for returned type string * * @return token status info. For any returned status (besides CRYPT_TOKEN_INVALID * and CRYPT_TOKEN_INACTIVE) and if type parameter is not NULL it will * contain address of type string. * * @note if required, create a copy of string referenced in *type before calling next * libcryptsetup API function. The reference may become invalid. */ crypt_token_info crypt_token_status(struct crypt_device *cd, int token, const char **type); /** * LUKS2 keyring token parameters. * * @see crypt_token_builtin_set * */ struct crypt_token_params_luks2_keyring { const char *key_description; /**< Reference in keyring */ }; /** * Create a new luks2 keyring token. * * @param cd crypt device handle * @param token token id or @e CRYPT_ANY_TOKEN to allocate new one * @param params luks2 keyring token params * * @return allocated token id or negative errno otherwise. * */ int crypt_token_luks2_keyring_set(struct crypt_device *cd, int token, const struct crypt_token_params_luks2_keyring *params); /** * Get LUKS2 keyring token params * * @param cd crypt device handle * @param token existing luks2 keyring token id * @param params returned luks2 keyring token params * * @return allocated token id or negative errno otherwise. * * @note do not call free() on params members. Members are valid only * until next libcryptsetup function is called. */ int crypt_token_luks2_keyring_get(struct crypt_device *cd, int token, struct crypt_token_params_luks2_keyring *params); /** * Assign a token to particular keyslot. * (There can be more keyslots assigned to one token id.) * * @param cd crypt device handle * @param token token id * @param keyslot keyslot to be assigned to token (CRYPT_ANY SLOT * assigns all active keyslots to token) * * @return allocated token id or negative errno otherwise. */ int crypt_token_assign_keyslot(struct crypt_device *cd, int token, int keyslot); /** * Unassign a token from particular keyslot. * (There can be more keyslots assigned to one token id.) * * @param cd crypt device handle * @param token token id * @param keyslot keyslot to be unassigned from token (CRYPT_ANY SLOT * unassigns all active keyslots from token) * * @return allocated token id or negative errno otherwise. */ int crypt_token_unassign_keyslot(struct crypt_device *cd, int token, int keyslot); /** * Get info about token assignment to particular keyslot. * * @param cd crypt device handle * @param token token id * @param keyslot keyslot * * @return 0 on success (token exists and is assigned to the keyslot), * -ENOENT if token is not assigned to a keyslot (token, keyslot * or both may be inactive) or other negative errno otherwise. */ int crypt_token_is_assigned(struct crypt_device *cd, int token, int keyslot); /** * Token handler open function prototype. * This function retrieves password from a token and return allocated buffer * containing this password. This buffer has to be deallocated by calling * free() function and content should be wiped before deallocation. * * @param cd crypt device handle * @param token token id * @param buffer returned allocated buffer with password * @param buffer_len length of the buffer * @param usrptr user data in @link crypt_activate_by_token @endlink * * @return 0 on success (token passed LUKS2 keyslot passphrase in buffer) or * negative errno otherwise. * * @note Negative ENOANO errno means that token is PIN protected and caller should * use @link crypt_activate_by_token_pin @endlink with PIN provided. * * @note Negative EAGAIN errno means token handler requires additional hardware * not present in the system. */ typedef int (*crypt_token_open_func) ( struct crypt_device *cd, int token, char **buffer, size_t *buffer_len, void *usrptr); /** * Token handler open with passphrase/PIN function prototype. * This function retrieves password from a token and return allocated buffer * containing this password. This buffer has to be deallocated by calling * free() function and content should be wiped before deallocation. * * @param cd crypt device handle * @param token token id * @param pin passphrase (or PIN) to unlock token (may be binary data) * @param pin_size size of @e pin * @param buffer returned allocated buffer with password * @param buffer_len length of the buffer * @param usrptr user data in @link crypt_activate_by_token @endlink * * @return 0 on success (token passed LUKS2 keyslot passphrase in buffer) or * negative errno otherwise. * * @note Negative ENOANO errno means that token is PIN protected and PIN was * missing or wrong. * * @note Negative EAGAIN errno means token handler requires additional hardware * not present in the system. */ typedef int (*crypt_token_open_pin_func) ( struct crypt_device *cd, int token, const char *pin, size_t pin_size, char **buffer, size_t *buffer_len, void *usrptr); /** * Token handler buffer free function prototype. * This function is used by library to free the buffer with keyslot * passphrase when it's no longer needed. If not defined the library * overwrites buffer with zeroes and call free(). * * @param buffer the buffer with keyslot passphrase * @param buffer_len the buffer length */ typedef void (*crypt_token_buffer_free_func) (void *buffer, size_t buffer_len); /** * Token handler validate function prototype. * This function validates JSON representation of user defined token for additional data * specific for its token type. If defined in the handler, it's called * during @link crypt_activate_by_token @endlink. It may also be called during * @link crypt_token_json_set @endlink when appropriate token handler was registered before * with @link crypt_token_register @endlink. * * @param cd crypt device handle * @param json buffer with JSON */ typedef int (*crypt_token_validate_func) (struct crypt_device *cd, const char *json); /** * Token handler dump function prototype. * This function is supposed to print token implementation specific details. It gets * called during @link crypt_dump @endlink if token handler was registered before. * * @param cd crypt device handle * @param json buffer with token JSON * * @note dump implementations are advised to use @link crypt_log @endlink function * to dump token details. */ typedef void (*crypt_token_dump_func) (struct crypt_device *cd, const char *json); /** * Token handler version function prototype. * This function is supposed to return pointer to version string information. * * @note The returned string is advised to contain only version. * For example '1.0.0' or 'v1.2.3.4'. * */ typedef const char * (*crypt_token_version_func) (void); /** * Token handler */ typedef struct { const char *name; /**< token handler name */ crypt_token_open_func open; /**< token handler open function */ crypt_token_buffer_free_func buffer_free; /**< token handler buffer_free function (optional) */ crypt_token_validate_func validate; /**< token handler validate function (optional) */ crypt_token_dump_func dump; /**< token handler dump function (optional) */ } crypt_token_handler; /** * Register token handler * * @param handler token handler to register * * @return @e 0 on success or negative errno value otherwise. */ int crypt_token_register(const crypt_token_handler *handler); /** * Report configured path where library searches for external token handlers * * @return @e absolute path when external tokens are enabled or @e NULL otherwise. */ const char *crypt_token_external_path(void); /** * Disable external token handlers (plugins) support * If disabled, it cannot be enabled again. */ void crypt_token_external_disable(void); /** ABI version for external token in libcryptsetup-token-[name].so */ #define CRYPT_TOKEN_ABI_VERSION1 "CRYPTSETUP_TOKEN_1.0" /** open by token - ABI exported symbol for external token (mandatory) */ #define CRYPT_TOKEN_ABI_OPEN "cryptsetup_token_open" /** open by token with PIN - ABI exported symbol for external token */ #define CRYPT_TOKEN_ABI_OPEN_PIN "cryptsetup_token_open_pin" /** deallocate callback - ABI exported symbol for external token */ #define CRYPT_TOKEN_ABI_BUFFER_FREE "cryptsetup_token_buffer_free" /** validate token metadata - ABI exported symbol for external token */ #define CRYPT_TOKEN_ABI_VALIDATE "cryptsetup_token_validate" /** dump token metadata - ABI exported symbol for external token */ #define CRYPT_TOKEN_ABI_DUMP "cryptsetup_token_dump" /** token version - ABI exported symbol for external token */ #define CRYPT_TOKEN_ABI_VERSION "cryptsetup_token_version" /** * Activate device or check key using a token. * * @param cd crypt device handle * @param name name of device to create, if @e NULL only check token * @param token requested token to check or CRYPT_ANY_TOKEN to check all * @param usrptr provided identification in callback * @param flags activation flags * * @return unlocked key slot number or negative errno otherwise. * * @note EPERM errno means token provided passphrase successfully, but * passphrase did not unlock any keyslot associated with the token. * * @note ENOENT errno means no token (or subsequently assigned keyslot) was * eligible to unlock device. * * @note ENOANO errno means that token is PIN protected and you should call * @link crypt_activate_by_token_pin @endlink with PIN * * @note Negative EAGAIN errno means token handler requires additional hardware * not present in the system. * * @note with @e token set to CRYPT_ANY_TOKEN libcryptsetup runs best effort loop * to unlock device using any available token. It may happen that various token handlers * return different error codes. At the end loop returns error codes in the following * order (from the most significant to the least) any negative errno except those * listed below, non negative token id (success), -ENOANO, -EAGAIN, -EPERM, -ENOENT. */ int crypt_activate_by_token(struct crypt_device *cd, const char *name, int token, void *usrptr, uint32_t flags); /** * Activate device or check key using a token with PIN. * * @param cd crypt device handle * @param name name of device to create, if @e NULL only check token * @param type restrict type of token, if @e NULL all types are allowed * @param token requested token to check or CRYPT_ANY_TOKEN to check all * @param pin passphrase (or PIN) to unlock token (may be binary data) * @param pin_size size of @e pin * @param usrptr provided identification in callback * @param flags activation flags * * @return unlocked key slot number or negative errno otherwise. * * @note EPERM errno means token provided passphrase successfully, but * passphrase did not unlock any keyslot associated with the token. * * @note ENOENT errno means no token (or subsequently assigned keyslot) was * eligible to unlock device. * * @note ENOANO errno means that token is PIN protected and was either missing * (NULL) or wrong. * * @note Negative EAGAIN errno means token handler requires additional hardware * not present in the system. * * @note with @e token set to CRYPT_ANY_TOKEN libcryptsetup runs best effort loop * to unlock device using any available token. It may happen that various token handlers * return different error codes. At the end loop returns error codes in the following * order (from the most significant to the least) any negative errno except those * listed below, non negative token id (success), -ENOANO, -EAGAIN, -EPERM, -ENOENT. */ int crypt_activate_by_token_pin(struct crypt_device *cd, const char *name, const char *type, int token, const char *pin, size_t pin_size, void *usrptr, uint32_t flags); /** @} */ /** * @defgroup crypt-reencryption LUKS2 volume reencryption support * * Set of functions to handling LUKS2 volume reencryption * * @addtogroup crypt-reencryption * @{ */ /** Initialize reencryption metadata but do not run reencryption yet. (in) */ #define CRYPT_REENCRYPT_INITIALIZE_ONLY (UINT32_C(1) << 0) /** Move the first segment, used only with datashift resilience mode * and subvariants. (in/out) */ #define CRYPT_REENCRYPT_MOVE_FIRST_SEGMENT (UINT32_C(1) << 1) /** Resume already initialized reencryption only. (in) */ #define CRYPT_REENCRYPT_RESUME_ONLY (UINT32_C(1) << 2) /** Run reencryption recovery only. (in) */ #define CRYPT_REENCRYPT_RECOVERY (UINT32_C(1) << 3) /** Reencryption requires metadata protection. (in/out) */ #define CRYPT_REENCRYPT_REPAIR_NEEDED (UINT32_C(1) << 4) /** * Reencryption direction */ typedef enum { CRYPT_REENCRYPT_FORWARD = 0, /**< forward direction */ CRYPT_REENCRYPT_BACKWARD /**< backward direction */ } crypt_reencrypt_direction_info; /** * Reencryption mode */ typedef enum { CRYPT_REENCRYPT_REENCRYPT = 0, /**< Reencryption mode */ CRYPT_REENCRYPT_ENCRYPT, /**< Encryption mode */ CRYPT_REENCRYPT_DECRYPT, /**< Decryption mode */ } crypt_reencrypt_mode_info; /** * LUKS2 reencryption options. */ struct crypt_params_reencrypt { crypt_reencrypt_mode_info mode; /**< Reencryption mode, immutable after first init. */ crypt_reencrypt_direction_info direction; /**< Reencryption direction, immutable after first init. */ const char *resilience; /**< Resilience mode: "none", "checksum", "journal", "datashift", "datashift-checksum" or "datashift-journal". "datashift" mode is immutable, "datashift-" subvariant can be only changed to other "datashift-" subvariant */ const char *hash; /**< Used hash for "checksum" resilience type, ignored otherwise. */ uint64_t data_shift; /**< Used in "datashift" mode (and subvariants), must be non-zero, immutable after first init. */ uint64_t max_hotzone_size; /**< Maximum hotzone size (may be lowered by library). For "datashift-" subvariants it is used to set size of moved segment (decryption only). */ uint64_t device_size; /**< Reencrypt only initial part of the data device. */ const struct crypt_params_luks2 *luks2; /**< LUKS2 parameters for the final reencryption volume.*/ uint32_t flags; /**< Reencryption flags. */ }; /** * Initialize reencryption metadata using passphrase. * * This function initializes on-disk metadata to include all reencryption segments, * according to the provided options. * If metadata already contains ongoing reencryption metadata, it loads these parameters * (in this situation all parameters except @e name and @e passphrase can be omitted). * * @param cd crypt device handle * @param name name of active device or @e NULL for offline reencryption * @param passphrase passphrase used to unlock volume key * @param passphrase_size size of @e passphrase (binary data) * @param keyslot_old keyslot to unlock existing device or CRYPT_ANY_SLOT * @param keyslot_new existing (unbound) reencryption keyslot; must be set except for decryption * @param cipher cipher specification (e.g. "aes") * @param cipher_mode cipher mode and IV (e.g. "xts-plain64") * @param params reencryption parameters @link crypt_params_reencrypt @endlink. * * @return reencryption key slot number or negative errno otherwise. */ int crypt_reencrypt_init_by_passphrase(struct crypt_device *cd, const char *name, const char *passphrase, size_t passphrase_size, int keyslot_old, int keyslot_new, const char *cipher, const char *cipher_mode, const struct crypt_params_reencrypt *params); /** * Initialize reencryption metadata using passphrase in keyring. * * This function initializes on-disk metadata to include all reencryption segments, * according to the provided options. * If metadata already contains ongoing reencryption metadata, it loads these parameters * (in this situation all parameters except @e name and @e key_description can be omitted). * * @param cd crypt device handle * @param name name of active device or @e NULL for offline reencryption * @param key_description passphrase (key) identification in keyring * @param keyslot_old keyslot to unlock existing device or CRYPT_ANY_SLOT * @param keyslot_new existing (unbound) reencryption keyslot; must be set except for decryption * @param cipher cipher specification (e.g. "aes") * @param cipher_mode cipher mode and IV (e.g. "xts-plain64") * @param params reencryption parameters @link crypt_params_reencrypt @endlink. * * @return reencryption key slot number or negative errno otherwise. */ int crypt_reencrypt_init_by_keyring(struct crypt_device *cd, const char *name, const char *key_description, int keyslot_old, int keyslot_new, const char *cipher, const char *cipher_mode, const struct crypt_params_reencrypt *params); /** * Legacy data reencryption function. * * @param cd crypt device handle * @param progress is a callback function reporting device \b size, * current \b offset of reencryption and provided \b usrptr identification * * @return @e 0 on success or negative errno value otherwise. * * @deprecated Use @link crypt_reencrypt_run @endlink instead. */ int crypt_reencrypt(struct crypt_device *cd, int (*progress)(uint64_t size, uint64_t offset, void *usrptr)) __attribute__((deprecated)); /** * Run data reencryption. * * @param cd crypt device handle * @param progress is a callback function reporting device \b size, * current \b offset of reencryption and provided \b usrptr identification * @param usrptr progress specific data * * @return @e 0 on success or negative errno value otherwise. */ int crypt_reencrypt_run(struct crypt_device *cd, int (*progress)(uint64_t size, uint64_t offset, void *usrptr), void *usrptr); /** * Reencryption status info */ typedef enum { CRYPT_REENCRYPT_NONE = 0, /**< No reencryption in progress */ CRYPT_REENCRYPT_CLEAN, /**< Ongoing reencryption in a clean state. */ CRYPT_REENCRYPT_CRASH, /**< Aborted reencryption that need internal recovery. */ CRYPT_REENCRYPT_INVALID /**< Invalid state. */ } crypt_reencrypt_info; /** * LUKS2 reencryption status. * * @param cd crypt device handle * @param params reencryption parameters * * @return reencryption status info and parameters. */ crypt_reencrypt_info crypt_reencrypt_status(struct crypt_device *cd, struct crypt_params_reencrypt *params); /** @} */ /** * @defgroup crypt-memory Safe memory helpers functions * @addtogroup crypt-memory * @{ */ /** * Allocate safe memory (content is safely wiped on deallocation). * * @param size size of memory in bytes * * @return pointer to allocated memory or @e NULL. */ void *crypt_safe_alloc(size_t size); /** * Release safe memory, content is safely wiped. * The pointer must be allocated with @link crypt_safe_alloc @endlink * * @param data pointer to memory to be deallocated */ void crypt_safe_free(void *data); /** * Reallocate safe memory (content is copied and safely wiped on deallocation). * * @param data pointer to memory to be deallocated * @param size new size of memory in bytes * * @return pointer to allocated memory or @e NULL. */ void *crypt_safe_realloc(void *data, size_t size); /** * Safe clear memory area (compile should not compile this call out). * * @param data pointer to memory to be cleared * @param size size of memory in bytes */ void crypt_safe_memzero(void *data, size_t size); /** @} */ #ifdef __cplusplus } #endif #endif /* _LIBCRYPTSETUP_H */