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author | Hyman Huang <yong.huang@smartx.com> | 2024-01-30 13:37:19 +0800 |
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committer | Daniel P. Berrangé <berrange@redhat.com> | 2024-02-09 12:50:33 +0000 |
commit | 9ad5c4e7ee513019e75ea8ece0d1da6ecce540e6 (patch) | |
tree | 24b5b2a4bbe6af94d280961b052ac0278548dd3d /disas/nanomips.c | |
parent | 003f15369de4e290a4d2e58292d96c5a506e4ee6 (diff) |
crypto: Support LUKS volume with detached header
By enhancing the LUKS driver, it is possible to implement
the LUKS volume with a detached header.
Normally a LUKS volume has a layout:
disk: | header | key material | disk payload data |
With a detached LUKS header, you need 2 disks so getting:
disk1: | header | key material |
disk2: | disk payload data |
There are a variety of benefits to doing this:
* Secrecy - the disk2 cannot be identified as containing LUKS
volume since there's no header
* Control - if access to the disk1 is restricted, then even
if someone has access to disk2 they can't unlock
it. Might be useful if you have disks on NFS but
want to restrict which host can launch a VM
instance from it, by dynamically providing access
to the header to a designated host
* Flexibility - your application data volume may be a given
size and it is inconvenient to resize it to
add encryption.You can store the LUKS header
separately and use the existing storage
volume for payload
* Recovery - corruption of a bit in the header may make the
entire payload inaccessible. It might be
convenient to take backups of the header. If
your primary disk header becomes corrupt, you
can unlock the data still by pointing to the
backup detached header
Take the raw-format image as an example to introduce the usage
of the LUKS volume with a detached header:
1. prepare detached LUKS header images
$ dd if=/dev/zero of=test-header.img bs=1M count=32
$ dd if=/dev/zero of=test-payload.img bs=1M count=1000
$ cryptsetup luksFormat --header test-header.img test-payload.img
> --force-password --type luks1
2. block-add a protocol blockdev node of payload image
$ virsh qemu-monitor-command vm '{"execute":"blockdev-add",
> "arguments":{"node-name":"libvirt-1-storage", "driver":"file",
> "filename":"test-payload.img"}}'
3. block-add a protocol blockdev node of LUKS header as above.
$ virsh qemu-monitor-command vm '{"execute":"blockdev-add",
> "arguments":{"node-name":"libvirt-2-storage", "driver":"file",
> "filename": "test-header.img" }}'
4. object-add the secret for decrypting the cipher stored in
LUKS header above
$ virsh qemu-monitor-command vm '{"execute":"object-add",
> "arguments":{"qom-type":"secret", "id":
> "libvirt-2-storage-secret0", "data":"abc123"}}'
5. block-add the raw-drived blockdev format node
$ virsh qemu-monitor-command vm '{"execute":"blockdev-add",
> "arguments":{"node-name":"libvirt-1-format", "driver":"raw",
> "file":"libvirt-1-storage"}}'
6. block-add the luks-drived blockdev to link the raw disk
with the LUKS header by specifying the field "header"
$ virsh qemu-monitor-command vm '{"execute":"blockdev-add",
> "arguments":{"node-name":"libvirt-2-format", "driver":"luks",
> "file":"libvirt-1-format", "header":"libvirt-2-storage",
> "key-secret":"libvirt-2-format-secret0"}}'
7. hot-plug the virtio-blk device finally
$ virsh qemu-monitor-command vm '{"execute":"device_add",
> "arguments": {"num-queues":"1", "driver":"virtio-blk-pci",
> "drive": "libvirt-2-format", "id":"virtio-disk2"}}'
Starting a VM with a LUKS volume with detached header is
somewhat similar to hot-plug in that both maintaining the
same json command while the starting VM changes the
"blockdev-add/device_add" parameters to "blockdev/device".
Signed-off-by: Hyman Huang <yong.huang@smartx.com>
Reviewed-by: Daniel P. Berrangé <berrange@redhat.com>
Signed-off-by: Daniel P. Berrangé <berrange@redhat.com>
Diffstat (limited to 'disas/nanomips.c')
0 files changed, 0 insertions, 0 deletions