mirror of
https://github.com/ceph/ceph
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51d8c526f0
Signed-off-by: Ilya Dryomov <idryomov@gmail.com>
247 lines
10 KiB
ReStructuredText
247 lines
10 KiB
ReStructuredText
======================
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Image Encryption
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======================
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.. index:: Ceph Block Device; encryption
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Starting with the Pacific release, image-level encryption can be handled
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internally by RBD clients. This means you can set a secret key that will be
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used to encrypt a specific RBD image. This page describes the scope of the
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RBD encryption feature.
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.. note::
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The ``krbd`` kernel module does not support encryption at this time.
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.. note::
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External tools (e.g. dm-crypt, QEMU) can be used as well to encrypt
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an RBD image, and the feature set and limitation set for that use may be
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different than described here.
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Encryption Format
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=================
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By default, RBD images are not encrypted. To encrypt an RBD image, it needs to
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be formatted to one of the supported encryption formats. The format operation
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persists encryption metadata to the image. The encryption metadata usually
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includes information such as the encryption format and version, cipher
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algorithm and mode specification, as well as information used to secure the
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encryption key. The encryption key itself is protected by a user-kept secret
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(usually a passphrase), which is never persisted. The basic encryption format
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operation will require specifying the encryption format and a secret.
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Some of the encryption metadata may be stored as part of the image data,
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typically an encryption header will be written to the beginning of the raw
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image data. This means that the effective image size of the encrypted image may
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be lower than the raw image size. See the `Supported Formats`_ section for more
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details.
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.. note::
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Unless explicitly (re-)formatted, clones of an encrypted image are
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inherently encrypted using the same format and secret.
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.. note::
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Clones of an encrypted image are always encrypted.
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Re-formatting to plaintext is not supported.
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.. note::
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Any data written to the image prior to its format may become unreadable,
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though it may still occupy storage resources.
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.. note::
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Images with the `journal feature`_ enabled cannot be formatted and encrypted
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by RBD clients.
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Encryption Load
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=================
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Formatting an image is a necessary pre-requisite for enabling encryption.
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However, formatted images will still be treated as raw unencrypted images by
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all of the RBD APIs. In particular, an encrypted RBD image can be opened
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by the same APIs as any other image, and raw unencrypted data can be
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read / written. Such raw IOs may risk the integrity of the encryption format,
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for example by overriding encryption metadata located at the beginning of the
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image.
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In order to safely perform encrypted IO on the formatted image, an additional
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*encryption load* operation should be applied after opening the image. The
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encryption load operation requires supplying the encryption format and a secret
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for unlocking the encryption key for the image itself and each of its explicitly
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formatted ancestor images. Following a successful encryption load operation,
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all IOs for the opened image will be encrypted / decrypted. For a cloned
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image, this includes IOs for ancestor images as well. The encryption keys will
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be stored in-memory by the RBD client until the image is closed.
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.. note::
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Once encryption has been loaded, no other encryption load / format
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operations can be applied to the context of the opened image.
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.. note::
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Once encryption has been loaded, API calls for retrieving the image size
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and the parent overlap using the opened image context will return the
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effective image size and the effective parent overlap respectively.
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.. note::
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Once encryption has been loaded, API calls for resizing the image will
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interpret the specified target size as effective image size.
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.. note::
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If a clone of an encrypted image is explicitly formatted, the operation of
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flattening the cloned image ceases to be transparent since the parent data
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must be re-encrypted according to the cloned image format as it is copied
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from the parent snapshot. If encryption is not loaded before the flatten
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operation is issued, any parent data that was previously accessible in the
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cloned image may become unreadable.
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.. note::
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If a clone of an encrypted image is explicitly formatted, the operation of
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shrinking the cloned image ceases to be transparent since in some cases
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(e.g. if the cloned image has snapshots or if the cloned image is being
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shrunk to a size that is not aligned with the object size) it involves
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copying some data from the parent snapshot, similar to flattening. If
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encryption is not loaded before the shrink operation is issued, any parent
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data that was previously accessible in the cloned image may become
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unreadable.
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.. note::
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Encryption load can be automatically applied when mounting RBD images as
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block devices via `rbd-nbd`_.
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Supported Formats
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=================
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LUKS
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~~~~~~~
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Both LUKS1 and LUKS2 are supported. The data layout is fully compliant with the
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LUKS specification. Thus, images formatted by RBD can be loaded using external
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LUKS-supporting tools such as dm-crypt or QEMU. Furthermore, existing LUKS
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data, created outside of RBD, can be imported (by copying the raw LUKS data
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into the image) and loaded by RBD encryption.
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.. note::
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The LUKS formats are supported on Linux-based systems only.
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.. note::
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Currently, only AES-128 and AES-256 encryption algorithms are supported.
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Additionally, xts-plain64 is currently the only supported encryption mode.
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To use the LUKS format, start by formatting the image:
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.. prompt:: bash $
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rbd encryption format [--cipher-alg {aes-128|aes-256}] {image-spec} {luks1|luks2} {passphrase-file}
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The encryption format operation generates a LUKS header and writes it to the
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beginning of the image. The header is appended with a single keyslot holding a
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randomly-generated encryption key, and is protected by the passphrase read from
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`passphrase-file`.
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.. note::
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In older versions, if the content of `passphrase-file` ended with a newline
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character, it was stripped off.
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By default, AES-256 in xts-plain64 mode (which is the current recommended mode,
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and the usual default for other tools) will be used. The format operation
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allows selecting AES-128 as well. Adding / removing passphrases is currently
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not supported by RBD, but can be applied to the raw RBD data using compatible
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tools such as cryptsetup.
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The LUKS header size can vary (up to 136MiB in LUKS2), but is usually up to
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16MiB, depending on the version of `libcryptsetup` installed. For optimal
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performance, the encryption format will set the data offset to be aligned with
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the image stripe period size. For example, expect a minimum overhead of 8MiB if
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using an image configured with an 8MiB object size and a minimum overhead of
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12MiB if using an image configured with a 4MiB object size and `stripe count`_
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of 3.
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In LUKS1, sectors, which are the minimal encryption units, are fixed at 512
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bytes. LUKS2 supports larger sectors, and for better performance we set
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the default sector size to the maximum of 4KiB. Writes which are either smaller
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than a sector, or are not aligned to a sector start, will trigger a guarded
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read-modify-write chain on the client, with a considerable latency penalty.
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A batch of such unaligned writes can lead to IO races which will further
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deteriorate performance. Thus it is advisable to avoid using RBD encryption
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in cases where incoming writes cannot be guaranteed to be sector-aligned.
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To map a LUKS-formatted image run:
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.. prompt:: bash #
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rbd device map -t nbd -o encryption-passphrase-file={passphrase-file} {image-spec}
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Note that for security reasons, both the encryption format and encryption load
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operations are CPU-intensive, and may take a few seconds to complete. For the
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encryption operations of actual image IO, assuming AES-NI is enabled,
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a relative small microseconds latency should be added, as well as a small
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increase in CPU utilization.
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Examples
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========
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Create a LUKS2-formatted image with the effective size of 50GiB:
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.. prompt:: bash $
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rbd create --size 50G mypool/myimage
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rbd encryption format mypool/myimage luks2 passphrase.bin
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rbd resize --size 50G --encryption-passphrase-file passphrase.bin mypool/myimage
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``rbd resize`` command at the end grows the image to compensate for the
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overhead associated with the LUKS2 header.
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Given a LUKS2-formatted image, create a LUKS2-formatted clone with the
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same effective size:
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.. prompt:: bash $
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rbd snap create mypool/myimage@snap
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rbd snap protect mypool/myimage@snap
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rbd clone mypool/myimage@snap mypool/myclone
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rbd encryption format mypool/myclone luks2 clone-passphrase.bin
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Given a LUKS2-formatted image with the effective size of 50GiB, create
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a LUKS1-formatted clone with the same effective size:
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.. prompt:: bash $
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rbd snap create mypool/myimage@snap
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rbd snap protect mypool/myimage@snap
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rbd clone mypool/myimage@snap mypool/myclone
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rbd encryption format mypool/myclone luks1 clone-passphrase.bin
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rbd resize --size 50G --allow-shrink --encryption-passphrase-file clone-passphrase.bin --encryption-passphrase-file passphrase.bin mypool/myclone
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Since LUKS1 header is usually smaller than LUKS2 header, ``rbd resize``
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command at the end shrinks the cloned image to get rid of unneeded
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space allowance.
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Given a LUKS1-formatted image with the effective size of 50GiB, create
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a LUKS2-formatted clone with the same effective size:
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.. prompt:: bash $
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rbd resize --size 51G mypool/myimage
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rbd snap create mypool/myimage@snap
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rbd snap protect mypool/myimage@snap
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rbd clone mypool/myimage@snap mypool/myclone
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rbd encryption format mypool/myclone luks2 clone-passphrase.bin
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rbd resize --size 50G --allow-shrink --encryption-passphrase-file passphrase.bin mypool/myimage
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rbd resize --size 50G --allow-shrink --encryption-passphrase-file clone-passphrase.bin --encryption-passphrase-file passphrase.bin mypool/myclone
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Since LUKS2 header is usually bigger than LUKS1 header, ``rbd resize``
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command at the beginning temporarily grows the parent image to reserve
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some extra space in the parent snapshot and consequently the cloned
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image. This is necessary to make all parent data accessible in the
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cloned image. ``rbd resize`` commands at the end shrink the parent
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image back to its original size (this does not impact the parent
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snapshot) and also the cloned image to get rid of unused reserved
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space.
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The same applies to creating a formatted clone of an unformatted
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(plaintext) image since an unformatted image does not have a header at
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all.
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.. _journal feature: ../rbd-mirroring/#enable-image-journaling-feature
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.. _Supported Formats: #supported-formats
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.. _rbd-nbd: ../../man/8/rbd-nbd
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.. _stripe count: ../../man/8/rbd/#striping
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