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Signed-off-by: Ján Tomko <jtomko@redhat.com> Reviewed-by: Erik Skultety <eskultet@redhat.com> Reviewed-by: Neal Gompa <ngompa13@gmail.com>
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=======================
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Secure Usage of Libvirt
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=======================
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.. contents::
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This page details information that application developers and
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administrators of libvirt should be aware of when working with libvirt,
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that may have a bearing on security of the system.
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Disk image handling
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===================
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Disk image format probing
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-------------------------
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Historically there have been multiple flaws in QEMU and most projects
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using QEMU, related to handling of disk formats. The problems occur when
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a guest is given a virtual disk backed by raw disk format on the host.
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If the management application on the host tries to auto-detect / probe
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the disk format, it is vulnerable to a malicious guest which can write a
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qcow2 file header into its raw disk. If the management application
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subsequently probes the disk, it will see it as a 'qcow2' disk instead
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of a 'raw' disk. Since 'qcow2' disks can have a copy on write backing
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file, such flaw can be leveraged to read arbitrary files on the host.
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The same type of flaw may occur if the management application allows
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users to upload pre-created raw images.
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**Recommendation:** never attempt to automatically detect the format of
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a disk image based on file contents which are accessible to / originate
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from an untrusted source.
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Disk image backing files
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------------------------
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If a management application allows users to upload pre-created disk
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images in non-raw formats, it can be tricked into giving the user access
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to arbitrary host files via the copy-on-write backing file feature. This
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is because the qcow2 disk format header contains a filename field which
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can point to any location. It can also point to network protocols such
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as NBD, HTTP, GlusterFS, RBD and more. This could allow for compromise
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of almost arbitrary data accessible on the LAN/WAN.
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**Recommendation:** always validate that a disk image originating from
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an untrusted source has no backing file set. If a backing file is seen,
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reject the image.
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Disk image size validation
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--------------------------
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If an application allows users to upload pre-created disk images in
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non-raw formats, it is essential to validate the logical disk image
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size, rather than the physical disk image size. Non-raw disk images have
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a grow-on-demand capability, so a user can provide a qcow2 image that
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may be only 1 MB in size, but is configured to grow to many TB in size.
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**Recommendation:** if receiving a non-raw disk image from an untrusted
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source, validate the logical image size stored in the disk image
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metadata against some finite limit.
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Disk image data access
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----------------------
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If an untrusted disk image is ever mounted on the host OS by a
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management application or administrator, this opens an avenue of attack
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with which to potentially compromise the host kernel. Filesystem drivers
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in OS kernels are often very complex code and thus may have bugs lurking
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in them. With Linux, there are a large number of filesystem drivers,
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many of which attract little security analysis attention. Linux will
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helpfully probe filesystem formats if not told to use an explicit
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format, allowing an attacker the ability to target specific weak
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filesystem drivers. Even commonly used and widely audited filesystems
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such as ``ext4`` have had `bugs lurking in
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them <https://lwn.net/Articles/538898/>`__ undetected for years at a
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time.
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**Recommendation:** if there is a need to access the content of a disk
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image, use a single-use throwaway virtual machine to access the data.
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Never mount disk images on the host OS. Ideally make use of the
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`libguestfs <https://libguestfs.org>`__ tools and APIs for accessing
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disks
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Guest migration network
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=======================
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Most hypervisors with support for guest migration between hosts make use
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of one (or more) network connections. Typically the source host will
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connect to some port on the target host to initiate the migration. There
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may be separate connections for co-ordinating the migration,
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transferring memory state and transferring storage. If the network over
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which migration takes place is accessible the guest, or client
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applications, there is potential for data leakage via packet
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snooping/capture. It is also possible for a malicious guest or client to
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make attempts to connect to the target host to trigger bogus migration
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operations, or at least inflict a denial of service attack.
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**Recommendations:** there are several things to consider when
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performing migration
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- Use a specific address for establishing the migration connection
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which is accessible only to the virtualization hosts themselves, not
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libvirt clients or virtual guests. Most hypervisors allow the
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management application to provide the IP address of the target host
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as a way to determine which network migration takes place on. This is
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effectively the connect() socket address for the source host.
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- Use a specific address for listening for incoming migration
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connections which is accessible only to the virtualization hosts
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themselves, not libvirt clients or virtual guests. Most hypervisors
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allow the management application to configure the IP address on which
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the target host listens. This is the bind() socket address for the
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target host.
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- Use an encrypted migration protocol. Some hypervisors have support
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for encrypting the migration memory/storage data. In other cases it
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can be tunnelled over the libvirtd RPC protocol connections.
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Storage encryption
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==================
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Virtual disk images will typically contain confidential data belonging
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to the owner of the virtual machine. It is desirable to protect this
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against data center administrators as much as possible. For example, a
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rogue storage administrator may attempt to access disk contents directly
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from a storage host, or a network administrator/attack may attempt to
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snoop on data packets relating to storage access. Use of disk encryption
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on the virtualization host can ensure that only the virtualization host
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administrator can see the plain text contents of disk images.
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**Recommendation:** make use of storage encryption to protect non-local
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storage from attack by rogue network / storage administrators or
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external attackers. This is particularly important if the storage
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protocol itself does not offer any kind of encryption capabilities.
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