The dm-integrity target emulates a block device that has additional per-sector tags that can be used for storing integrity information. A general problem with storing integrity tags with every sector is that writing the sector and the integrity tag must be atomic - i.e. in case of crash, either both sector and integrity tag or none of them is written. To guarantee write atomicity, the dm-integrity target uses journal, it writes sector data and integrity tags into a journal, commits the journal and then copies the data and integrity tags to their respective location. The dm-integrity target can be used with the dm-crypt target - in this situation the dm-crypt target creates the integrity data and passes them to the dm-integrity target via bio_integrity_payload attached to the bio. In this mode, the dm-crypt and dm-integrity targets provide authenticated disk encryption - if the attacker modifies the encrypted device, an I/O error is returned instead of random data. The dm-integrity target can also be used as a standalone target, in this mode it calculates and verifies the integrity tag internally. In this mode, the dm-integrity target can be used to detect silent data corruption on the disk or in the I/O path. When loading the target for the first time, the kernel driver will format the device. But it will only format the device if the superblock contains zeroes. If the superblock is neither valid nor zeroed, the dm-integrity target can't be loaded. To use the target for the first time: 1. overwrite the superblock with zeroes 2. load the dm-integrity target with one-sector size, the kernel driver will format the device 3. unload the dm-integrity target 4. read the "provided_data_sectors" value from the superblock 5. load the dm-integrity target with the the target size "provided_data_sectors" 6. if you want to use dm-integrity with dm-crypt, load the dm-crypt target with the size "provided_data_sectors" Target arguments: 1. the underlying block device 2. the number of reserved sector at the beginning of the device - the dm-integrity won't read of write these sectors 3. the size of the integrity tag (if "-" is used, the size is taken from the internal-hash algorithm) 4. mode: D - direct writes (without journal) - in this mode, journaling is not used and data sectors and integrity tags are written separately. In case of crash, it is possible that the data and integrity tag doesn't match. J - journaled writes - data and integrity tags are written to the journal and atomicity is guaranteed. In case of crash, either both data and tag or none of them are written. The journaled mode degrades write throughput twice because the data have to be written twice. 5. the number of additional arguments Additional arguments: journal-sectors:number The size of journal, this argument is used only if formatting the device. If the device is already formatted, the value from the superblock is used. interleave-sectors:number The number of interleaved sectors. This values is rounded down to a power of two. If the device is already formatted, the value from the superblock is used. buffer-sectors:number The number of sectors in one buffer. The value is rounded down to a power of two. The tag area is accessed using buffers, the buffer size is configurable. The large buffer size means that the I/O size will be larger, but there could be less I/Os issued. journal-watermark:number The journal watermark in percents. When the size of the journal exceeds this watermark, the thread that flushes the journal will be started. commit-time:number Commit time in milliseconds. When this time passes, the journal is written. The journal is also written immediatelly if the FLUSH request is received. internal-hash:algorithm(:key) (the key is optional) Use internal hash or crc. When this argument is used, the dm-integrity target won't accept integrity tags from the upper target, but it will automatically generate and verify the integrity tags. You can use a crc algorithm (such as crc32), then integrity target will protect the data against accidental corruption. You can also use a hmac algorithm (for example "hmac(sha256):0123456789abcdef"), in this mode it will provide cryptographic authentication of the data without encryption. When this argument is not used, the integrity tags are accepted from an upper layer target, such as dm-crypt. The upper layer target should check the validity of the integrity tags. journal-crypt:algorithm(:key) (the key is optional) Encrypt the journal using given algorithm to make sure that the attacker can't read the journal. You can use a block cipher here (such as "cbc(aes)") or a stream cipher (for example "chacha20", "salsa20", "ctr(aes)" or "ecb(arc4)"). The journal contains history of last writes to the block device, an attacker reading the journal could see the last sector nubmers that were written. From the sector numbers, the attacker can infer the size of files that were written. To protect against this situation, you can encrypt the journal. journal-mac:algorithm(:key) (the key is optional) Protect sector numbers in the journal from accidental or malicious modification. To protect against accidental modification, use a crc algorithm, to protect against malicious modification, use a hmac algorithm with a key. This option is not needed when using internal-hash because in this mode, the integrity of journal entries is checked when replaying the journal. Thus, modified sector number would be detected at this stage. The journal mode (D/J), buffer-sectors, journal-watermark, commit-time can be changed when reloading the target (load an inactive table and swap the tables with suspend and resume). The other arguments should not be changed when reloading the target because the layout of disk data depend on them and the reloaded target would be non-functional. The layout of the formatted block device: * reserved sectors (they are not used by this target, they can be used for storing LUKS metadata or for other purpose), the size of the reserved area is specified in the target arguments * superblock (4kiB) * magic string - identifies that the device was formatted * version * log2(interleave sectors) * integrity tag size * the number of journal sections * provided data sectors - the number of sectors that this target provides (i.e. the size of the device minus the size of all metadata and padding). The user of this target should not send bios that access data beyond the "provided data sectors" limit. * flags - a flag is set if journal-mac is used * journal The journal is divided into sections, each section contains: * metadata area (4kiB), it contains journal entries every journal entry contains: * logical sector (specifies where the data and tag should be written) * last 8 bytes of data * integrity tag (the size is specified in the superblock) every metadata sector ends with * mac (8-bytes), all the macs in 8 metadata sectors form a 64-byte value. It is used to store hmac of sector numbers in the journal section, to protect against a possibility that the attacker tampers with sector numbers in the journal. * commit id * data area (the size is variable; it depends on how many journal entries fit into the metadata area) every sector in the data area contains: * data (504 bytes of data, the last 8 bytes are stored in the journal entry) * commit id To test if the whole journal section was written correctly, every 512-byte sector of the journal ends with 8-byte commit id. If the commit id matches on all sectors in a journal section, then it is assumed that the section was written correctly. If the commit id doesn't match, the section was written partially and it should not be replayed. * one or more runs of interleaved tags and data. Each run contains: * tag area - it contains integrity tags. There is one tag for each sector in the data area * data area - it contains data sectors. The number of data sectors in one run must be a power of two. log2 of this value is stored in the superblock.