docs/tools/virtiofsd.rst - third_party/qemu - Git at Google

 QEMU virtio-fs shared file system daemon
 ========================================

 Synopsis
 --------

 **virtiofsd** [*OPTIONS*]

 Description
 -----------

 Share a host directory tree with a guest through a virtio-fs device.  This
 program is a vhost-user backend that implements the virtio-fs device.  Each
 virtio-fs device instance requires its own virtiofsd process.

 This program is designed to work with QEMU's ``--device vhost-user-fs-pci``
 but should work with any virtual machine monitor (VMM) that supports
 vhost-user.  See the Examples section below.

 This program must be run as the root user.  The program drops privileges where
 possible during startup although it must be able to create and access files
 with any uid/gid:

 * The ability to invoke syscalls is limited using seccomp(2).
 * Linux capabilities(7) are dropped.

 In "namespace" sandbox mode the program switches into a new file system
 namespace and invokes pivot_root(2) to make the shared directory tree its root.
 A new pid and net namespace is also created to isolate the process.

 In "chroot" sandbox mode the program invokes chroot(2) to make the shared
 directory tree its root. This mode is intended for container environments where
 the container runtime has already set up the namespaces and the program does
 not have permission to create namespaces itself.

 Both sandbox modes prevent "file system escapes" due to symlinks and other file
 system objects that might lead to files outside the shared directory.

 Options
 -------

 .. program:: virtiofsd

 .. option:: -h, --help

   Print help.

 .. option:: -V, --version

   Print version.

 .. option:: -d

   Enable debug output.

 .. option:: --syslog

   Print log messages to syslog instead of stderr.

 .. option:: -o OPTION

   * debug -
     Enable debug output.

   * flock|no_flock -
     Enable/disable flock.  The default is ``no_flock``.

   * modcaps=CAPLIST
     Modify the list of capabilities allowed; CAPLIST is a colon separated
     list of capabilities, each preceded by either + or -, e.g.
     ''+sys_admin:-chown''.

   * log_level=LEVEL -
     Print only log messages matching LEVEL or more severe.  LEVEL is one of
     ``err``, ``warn``, ``info``, or ``debug``.  The default is ``info``.

   * posix_lock|no_posix_lock -
     Enable/disable remote POSIX locks.  The default is ``no_posix_lock``.

   * readdirplus|no_readdirplus -
     Enable/disable readdirplus.  The default is ``readdirplus``.

   * sandbox=namespace|chroot -
     Sandbox mode:
     - namespace: Create mount, pid, and net namespaces and pivot_root(2) into
     the shared directory.
     - chroot: chroot(2) into shared directory (use in containers).
     The default is "namespace".

   * source=PATH -
     Share host directory tree located at PATH.  This option is required.

   * timeout=TIMEOUT -
     I/O timeout in seconds.  The default depends on cache= option.

   * writeback|no_writeback -
     Enable/disable writeback cache. The cache allows the FUSE client to buffer
     and merge write requests.  The default is ``no_writeback``.

   * xattr|no_xattr -
     Enable/disable extended attributes (xattr) on files and directories.  The
     default is ``no_xattr``.

   * posix_acl|no_posix_acl -
     Enable/disable posix acl support.  Posix ACLs are disabled by default.

   * security_label|no_security_label -
     Enable/disable security label support. Security labels are disabled by
     default. This will allow client to send a MAC label of file during
     file creation. Typically this is expected to be SELinux security
     label. Server will try to set that label on newly created file
     atomically wherever possible.

 .. option:: --socket-path=PATH

   Listen on vhost-user UNIX domain socket at PATH.

 .. option:: --socket-group=GROUP

   Set the vhost-user UNIX domain socket gid to GROUP.

 .. option:: --fd=FDNUM

   Accept connections from vhost-user UNIX domain socket file descriptor FDNUM.
   The file descriptor must already be listening for connections.

 .. option:: --thread-pool-size=NUM

   Restrict the number of worker threads per request queue to NUM.  The default
   is 64.

 .. option:: --cache=none|auto|always

   Select the desired trade-off between coherency and performance.  ``none``
   forbids the FUSE client from caching to achieve best coherency at the cost of
   performance.  ``auto`` acts similar to NFS with a 1 second metadata cache
   timeout.  ``always`` sets a long cache lifetime at the expense of coherency.
   The default is ``auto``.

 Extended attribute (xattr) mapping
 ----------------------------------

 By default the name of xattr's used by the client are passed through to the server
 file system.  This can be a problem where either those xattr names are used
 by something on the server (e.g. selinux client/server confusion) or if the
 ``virtiofsd`` is running in a container with restricted privileges where it
 cannot access some attributes.

 Mapping syntax
 ~~~~~~~~~~~~~~

 A mapping of xattr names can be made using -o xattrmap=mapping where the ``mapping``
 string consists of a series of rules.

 The first matching rule terminates the mapping.
 The set of rules must include a terminating rule to match any remaining attributes
 at the end.

 Each rule consists of a number of fields separated with a separator that is the
 first non-white space character in the rule.  This separator must then be used
 for the whole rule.
 White space may be added before and after each rule.

 Using ':' as the separator a rule is of the form:

 ``:type:scope:key:prepend:``

 **scope** is:

 - 'client' - match 'key' against a xattr name from the client for
              setxattr/getxattr/removexattr
 - 'server' - match 'prepend' against a xattr name from the server
              for listxattr
 - 'all' - can be used to make a single rule where both the server
           and client matches are triggered.

 **type** is one of:

 - 'prefix' - is designed to prepend and strip a prefix;  the modified
   attributes then being passed on to the client/server.

 - 'ok' - Causes the rule set to be terminated when a match is found
   while allowing matching xattr's through unchanged.
   It is intended both as a way of explicitly terminating
   the list of rules, and to allow some xattr's to skip following rules.

 - 'bad' - If a client tries to use a name matching 'key' it's
   denied using EPERM; when the server passes an attribute
   name matching 'prepend' it's hidden.  In many ways it's use is very like
   'ok' as either an explicit terminator or for special handling of certain
   patterns.

 - 'unsupported' - If a client tries to use a name matching 'key' it's
   denied using ENOTSUP; when the server passes an attribute
   name matching 'prepend' it's hidden.  In many ways it's use is very like
   'ok' as either an explicit terminator or for special handling of certain
   patterns.

 **key** is a string tested as a prefix on an attribute name originating
 on the client.  It maybe empty in which case a 'client' rule
 will always match on client names.

 **prepend** is a string tested as a prefix on an attribute name originating
 on the server, and used as a new prefix.  It may be empty
 in which case a 'server' rule will always match on all names from
 the server.

 e.g.:

   ``:prefix:client:trusted.:user.virtiofs.:``

   will match 'trusted.' attributes in client calls and prefix them before
   passing them to the server.

   ``:prefix:server::user.virtiofs.:``

   will strip 'user.virtiofs.' from all server replies.

   ``:prefix:all:trusted.:user.virtiofs.:``

   combines the previous two cases into a single rule.

   ``:ok:client:user.::``

   will allow get/set xattr for 'user.' xattr's and ignore
   following rules.

   ``:ok:server::security.:``

   will pass 'securty.' xattr's in listxattr from the server
   and ignore following rules.

   ``:ok:all:::``

   will terminate the rule search passing any remaining attributes
   in both directions.

   ``:bad:server::security.:``

   would hide 'security.' xattr's in listxattr from the server.

 A simpler 'map' type provides a shorter syntax for the common case:

 ``:map:key:prepend:``

 The 'map' type adds a number of separate rules to add **prepend** as a prefix
 to the matched **key** (or all attributes if **key** is empty).
 There may be at most one 'map' rule and it must be the last rule in the set.

 Note: When the 'security.capability' xattr is remapped, the daemon has to do
 extra work to remove it during many operations, which the host kernel normally
 does itself.

 Security considerations
 ~~~~~~~~~~~~~~~~~~~~~~~

 Operating systems typically partition the xattr namespace using
 well defined name prefixes. Each partition may have different
 access controls applied. For example, on Linux there are multiple
 partitions

  * ``system.*`` - access varies depending on attribute & filesystem
  * ``security.*`` - only processes with CAP_SYS_ADMIN
  * ``trusted.*`` - only processes with CAP_SYS_ADMIN
  * ``user.*`` - any process granted by file permissions / ownership

 While other OS such as FreeBSD have different name prefixes
 and access control rules.

 When remapping attributes on the host, it is important to
 ensure that the remapping does not allow a guest user to
 evade the guest access control rules.

 Consider if ``trusted.*`` from the guest was remapped to
 ``user.virtiofs.trusted*`` in the host. An unprivileged
 user in a Linux guest has the ability to write to xattrs
 under ``user.*``. Thus the user can evade the access
 control restriction on ``trusted.*`` by instead writing
 to ``user.virtiofs.trusted.*``.

 As noted above, the partitions used and access controls
 applied, will vary across guest OS, so it is not wise to
 try to predict what the guest OS will use.

 The simplest way to avoid an insecure configuration is
 to remap all xattrs at once, to a given fixed prefix.
 This is shown in example (1) below.

 If selectively mapping only a subset of xattr prefixes,
 then rules must be added to explicitly block direct
 access to the target of the remapping. This is shown
 in example (2) below.

 Mapping examples
 ~~~~~~~~~~~~~~~~

 1) Prefix all attributes with 'user.virtiofs.'

 ::

  -o xattrmap=":prefix:all::user.virtiofs.::bad:all:::"


 This uses two rules, using : as the field separator;
 the first rule prefixes and strips 'user.virtiofs.',
 the second rule hides any non-prefixed attributes that
 the host set.

 This is equivalent to the 'map' rule:

 ::

  -o xattrmap=":map::user.virtiofs.:"

 2) Prefix 'trusted.' attributes, allow others through

 ::

    "/prefix/all/trusted./user.virtiofs./
     /bad/server//trusted./
     /bad/client/user.virtiofs.//
     /ok/all///"


 Here there are four rules, using / as the field
 separator, and also demonstrating that new lines can
 be included between rules.
 The first rule is the prefixing of 'trusted.' and
 stripping of 'user.virtiofs.'.
 The second rule hides unprefixed 'trusted.' attributes
 on the host.
 The third rule stops a guest from explicitly setting
 the 'user.virtiofs.' path directly to prevent access
 control bypass on the target of the earlier prefix
 remapping.
 Finally, the fourth rule lets all remaining attributes
 through.

 This is equivalent to the 'map' rule:

 ::

  -o xattrmap="/map/trusted./user.virtiofs./"

 3) Hide 'security.' attributes, and allow everything else

 ::

     "/bad/all/security./security./
      /ok/all///'

 The first rule combines what could be separate client and server
 rules into a single 'all' rule, matching 'security.' in either
 client arguments or lists returned from the host.  This stops
 the client seeing any 'security.' attributes on the server and
 stops it setting any.

 SELinux support
 ---------------
 One can enable support for SELinux by running virtiofsd with option
 "-o security_label". But this will try to save guest's security context
 in xattr security.selinux on host and it might fail if host's SELinux
 policy does not permit virtiofsd to do this operation.

 Hence, it is preferred to remap guest's "security.selinux" xattr to say
 "trusted.virtiofs.security.selinux" on host.

 "-o xattrmap=:map:security.selinux:trusted.virtiofs.:"

 This will make sure that guest and host's SELinux xattrs on same file
 remain separate and not interfere with each other. And will allow both
 host and guest to implement their own separate SELinux policies.

 Setting trusted xattr on host requires CAP_SYS_ADMIN. So one will need
 add this capability to daemon.

 "-o modcaps=+sys_admin"

 Giving CAP_SYS_ADMIN increases the risk on system. Now virtiofsd is more
 powerful and if gets compromised, it can do lot of damage to host system.
 So keep this trade-off in my mind while making a decision.

 Examples
 --------

 Export ``/var/lib/fs/vm001/`` on vhost-user UNIX domain socket
 ``/var/run/vm001-vhost-fs.sock``:

 .. parsed-literal::

   host# virtiofsd --socket-path=/var/run/vm001-vhost-fs.sock -o source=/var/lib/fs/vm001
   host# |qemu_system| \\
         -chardev socket,id=char0,path=/var/run/vm001-vhost-fs.sock \\
         -device vhost-user-fs-pci,chardev=char0,tag=myfs \\
         -object memory-backend-memfd,id=mem,size=4G,share=on \\
         -numa node,memdev=mem \\
         ...
   guest# mount -t virtiofs myfs /mnt
	QEMU virtio-fs shared file system daemon
	========================================

	Synopsis
	--------

	virtiofsd [OPTIONS]

	Description
	-----------

	Share a host directory tree with a guest through a virtio-fs device. This
	program is a vhost-user backend that implements the virtio-fs device. Each
	virtio-fs device instance requires its own virtiofsd process.

	This program is designed to work with QEMU's ``--device vhost-user-fs-pci``
	but should work with any virtual machine monitor (VMM) that supports
	vhost-user. See the Examples section below.

	This program must be run as the root user. The program drops privileges where
	possible during startup although it must be able to create and access files
	with any uid/gid:

	* The ability to invoke syscalls is limited using seccomp(2).
	* Linux capabilities(7) are dropped.

	In "namespace" sandbox mode the program switches into a new file system
	namespace and invokes pivot_root(2) to make the shared directory tree its root.
	A new pid and net namespace is also created to isolate the process.

	In "chroot" sandbox mode the program invokes chroot(2) to make the shared
	directory tree its root. This mode is intended for container environments where
	the container runtime has already set up the namespaces and the program does
	not have permission to create namespaces itself.

	Both sandbox modes prevent "file system escapes" due to symlinks and other file
	system objects that might lead to files outside the shared directory.

	Options
	-------

	.. program:: virtiofsd

	.. option:: -h, --help

	Print help.

	.. option:: -V, --version

	Print version.

	.. option:: -d

	Enable debug output.

	.. option:: --syslog

	Print log messages to syslog instead of stderr.

	.. option:: -o OPTION

	* debug -
	Enable debug output.

	* flock\|no_flock -
	Enable/disable flock. The default is ``no_flock``.

	* modcaps=CAPLIST
	Modify the list of capabilities allowed; CAPLIST is a colon separated
	list of capabilities, each preceded by either + or -, e.g.
	''+sys_admin:-chown''.

	* log_level=LEVEL -
	Print only log messages matching LEVEL or more severe. LEVEL is one of
	``err``, ``warn``, ``info``, or ``debug``. The default is ``info``.

	* posix_lock\|no_posix_lock -
	Enable/disable remote POSIX locks. The default is ``no_posix_lock``.

	* readdirplus\|no_readdirplus -
	Enable/disable readdirplus. The default is ``readdirplus``.

	* sandbox=namespace\|chroot -
	Sandbox mode:
	- namespace: Create mount, pid, and net namespaces and pivot_root(2) into
	the shared directory.
	- chroot: chroot(2) into shared directory (use in containers).
	The default is "namespace".

	* source=PATH -
	Share host directory tree located at PATH. This option is required.

	* timeout=TIMEOUT -
	I/O timeout in seconds. The default depends on cache= option.

	* writeback\|no_writeback -
	Enable/disable writeback cache. The cache allows the FUSE client to buffer
	and merge write requests. The default is ``no_writeback``.

	* xattr\|no_xattr -
	Enable/disable extended attributes (xattr) on files and directories. The
	default is ``no_xattr``.

	* posix_acl\|no_posix_acl -
	Enable/disable posix acl support. Posix ACLs are disabled by default.

	* security_label\|no_security_label -
	Enable/disable security label support. Security labels are disabled by
	default. This will allow client to send a MAC label of file during
	file creation. Typically this is expected to be SELinux security
	label. Server will try to set that label on newly created file
	atomically wherever possible.

	.. option:: --socket-path=PATH

	Listen on vhost-user UNIX domain socket at PATH.

	.. option:: --socket-group=GROUP

	Set the vhost-user UNIX domain socket gid to GROUP.

	.. option:: --fd=FDNUM

	Accept connections from vhost-user UNIX domain socket file descriptor FDNUM.
	The file descriptor must already be listening for connections.

	.. option:: --thread-pool-size=NUM

	Restrict the number of worker threads per request queue to NUM. The default
	is 64.

	.. option:: --cache=none\|auto\|always

	Select the desired trade-off between coherency and performance. ``none``
	forbids the FUSE client from caching to achieve best coherency at the cost of
	performance. ``auto`` acts similar to NFS with a 1 second metadata cache
	timeout. ``always`` sets a long cache lifetime at the expense of coherency.
	The default is ``auto``.

	Extended attribute (xattr) mapping
	----------------------------------

	By default the name of xattr's used by the client are passed through to the server
	file system. This can be a problem where either those xattr names are used
	by something on the server (e.g. selinux client/server confusion) or if the
	``virtiofsd`` is running in a container with restricted privileges where it
	cannot access some attributes.

	Mapping syntax
	~~~~~~~~~~~~~~

	A mapping of xattr names can be made using -o xattrmap=mapping where the ``mapping``
	string consists of a series of rules.

	The first matching rule terminates the mapping.
	The set of rules must include a terminating rule to match any remaining attributes
	at the end.

	Each rule consists of a number of fields separated with a separator that is the
	first non-white space character in the rule. This separator must then be used
	for the whole rule.
	White space may be added before and after each rule.

	Using ':' as the separator a rule is of the form:

	``:type:scope:key:prepend:``

	scope is:

	- 'client' - match 'key' against a xattr name from the client for
	setxattr/getxattr/removexattr
	- 'server' - match 'prepend' against a xattr name from the server
	for listxattr
	- 'all' - can be used to make a single rule where both the server
	and client matches are triggered.

	type is one of:

	- 'prefix' - is designed to prepend and strip a prefix; the modified
	attributes then being passed on to the client/server.

	- 'ok' - Causes the rule set to be terminated when a match is found
	while allowing matching xattr's through unchanged.
	It is intended both as a way of explicitly terminating
	the list of rules, and to allow some xattr's to skip following rules.

	- 'bad' - If a client tries to use a name matching 'key' it's
	denied using EPERM; when the server passes an attribute
	name matching 'prepend' it's hidden. In many ways it's use is very like
	'ok' as either an explicit terminator or for special handling of certain
	patterns.

	- 'unsupported' - If a client tries to use a name matching 'key' it's
	denied using ENOTSUP; when the server passes an attribute
	name matching 'prepend' it's hidden. In many ways it's use is very like
	'ok' as either an explicit terminator or for special handling of certain
	patterns.

	key is a string tested as a prefix on an attribute name originating
	on the client. It maybe empty in which case a 'client' rule
	will always match on client names.

	prepend is a string tested as a prefix on an attribute name originating
	on the server, and used as a new prefix. It may be empty
	in which case a 'server' rule will always match on all names from
	the server.

	e.g.:

	``:prefix:client:trusted.:user.virtiofs.:``

	will match 'trusted.' attributes in client calls and prefix them before
	passing them to the server.

	``:prefix:server::user.virtiofs.:``

	will strip 'user.virtiofs.' from all server replies.

	``:prefix:all:trusted.:user.virtiofs.:``

	combines the previous two cases into a single rule.

	``:ok:client:user.::``

	will allow get/set xattr for 'user.' xattr's and ignore
	following rules.

	``:ok:server::security.:``

	will pass 'securty.' xattr's in listxattr from the server
	and ignore following rules.

	``:ok:all:::``

	will terminate the rule search passing any remaining attributes
	in both directions.

	``:bad:server::security.:``

	would hide 'security.' xattr's in listxattr from the server.

	A simpler 'map' type provides a shorter syntax for the common case:

	``:map:key:prepend:``

	The 'map' type adds a number of separate rules to add prepend as a prefix
	to the matched key (or all attributes if key is empty).
	There may be at most one 'map' rule and it must be the last rule in the set.

	Note: When the 'security.capability' xattr is remapped, the daemon has to do
	extra work to remove it during many operations, which the host kernel normally
	does itself.

	Security considerations
	~~~~~~~~~~~~~~~~~~~~~~~

	Operating systems typically partition the xattr namespace using
	well defined name prefixes. Each partition may have different
	access controls applied. For example, on Linux there are multiple
	partitions

	* ``system.*`` - access varies depending on attribute & filesystem
	* ``security.*`` - only processes with CAP_SYS_ADMIN
	* ``trusted.*`` - only processes with CAP_SYS_ADMIN
	* ``user.*`` - any process granted by file permissions / ownership

	While other OS such as FreeBSD have different name prefixes
	and access control rules.

	When remapping attributes on the host, it is important to
	ensure that the remapping does not allow a guest user to
	evade the guest access control rules.

	Consider if ``trusted.*`` from the guest was remapped to
	``user.virtiofs.trusted*`` in the host. An unprivileged
	user in a Linux guest has the ability to write to xattrs
	under ``user.*``. Thus the user can evade the access
	control restriction on ``trusted.*`` by instead writing
	to ``user.virtiofs.trusted.*``.

	As noted above, the partitions used and access controls
	applied, will vary across guest OS, so it is not wise to
	try to predict what the guest OS will use.

	The simplest way to avoid an insecure configuration is
	to remap all xattrs at once, to a given fixed prefix.
	This is shown in example (1) below.

	If selectively mapping only a subset of xattr prefixes,
	then rules must be added to explicitly block direct
	access to the target of the remapping. This is shown
	in example (2) below.

	Mapping examples
	~~~~~~~~~~~~~~~~

	1) Prefix all attributes with 'user.virtiofs.'

	::

	-o xattrmap=":prefix:all::user.virtiofs.::bad:all:::"


	This uses two rules, using : as the field separator;
	the first rule prefixes and strips 'user.virtiofs.',
	the second rule hides any non-prefixed attributes that
	the host set.

	This is equivalent to the 'map' rule:

	::

	-o xattrmap=":map::user.virtiofs.:"

	2) Prefix 'trusted.' attributes, allow others through

	::

	"/prefix/all/trusted./user.virtiofs./
	/bad/server//trusted./
	/bad/client/user.virtiofs.//
	/ok/all///"


	Here there are four rules, using / as the field
	separator, and also demonstrating that new lines can
	be included between rules.
	The first rule is the prefixing of 'trusted.' and
	stripping of 'user.virtiofs.'.
	The second rule hides unprefixed 'trusted.' attributes
	on the host.
	The third rule stops a guest from explicitly setting
	the 'user.virtiofs.' path directly to prevent access
	control bypass on the target of the earlier prefix
	remapping.
	Finally, the fourth rule lets all remaining attributes
	through.

	This is equivalent to the 'map' rule:

	::

	-o xattrmap="/map/trusted./user.virtiofs./"

	3) Hide 'security.' attributes, and allow everything else

	::

	"/bad/all/security./security./
	/ok/all///'

	The first rule combines what could be separate client and server
	rules into a single 'all' rule, matching 'security.' in either
	client arguments or lists returned from the host. This stops
	the client seeing any 'security.' attributes on the server and
	stops it setting any.

	SELinux support
	---------------
	One can enable support for SELinux by running virtiofsd with option
	"-o security_label". But this will try to save guest's security context
	in xattr security.selinux on host and it might fail if host's SELinux
	policy does not permit virtiofsd to do this operation.

	Hence, it is preferred to remap guest's "security.selinux" xattr to say
	"trusted.virtiofs.security.selinux" on host.

	"-o xattrmap=:map:security.selinux:trusted.virtiofs.:"

	This will make sure that guest and host's SELinux xattrs on same file
	remain separate and not interfere with each other. And will allow both
	host and guest to implement their own separate SELinux policies.

	Setting trusted xattr on host requires CAP_SYS_ADMIN. So one will need
	add this capability to daemon.

	"-o modcaps=+sys_admin"

	Giving CAP_SYS_ADMIN increases the risk on system. Now virtiofsd is more
	powerful and if gets compromised, it can do lot of damage to host system.
	So keep this trade-off in my mind while making a decision.

	Examples
	--------

	Export ``/var/lib/fs/vm001/`` on vhost-user UNIX domain socket
	``/var/run/vm001-vhost-fs.sock``:

	.. parsed-literal::

	host# virtiofsd --socket-path=/var/run/vm001-vhost-fs.sock -o source=/var/lib/fs/vm001
	host# \|qemu_system\| \\
	-chardev socket,id=char0,path=/var/run/vm001-vhost-fs.sock \\
	-device vhost-user-fs-pci,chardev=char0,tag=myfs \\
	-object memory-backend-memfd,id=mem,size=4G,share=on \\
	-numa node,memdev=mem \\
	...
	guest# mount -t virtiofs myfs /mnt