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KEYRINGS(7)		   Linux Programmer's Manual		   KEYRINGS(7)



NAME
       keyrings - in-kernel key management and retention facility

DESCRIPTION
       The Linux key-management facility is primarily a way for various kernel
       components to retain  or	 cache	security  data,	 authentication	 keys,
       encryption keys, and other data in the kernel.

       System  call  interfaces	 are  provided so that user-space programs can
       manage those objects and also use the facility for their own  purposes;
       see add_key(2), request_key(2), and keyctl(2).

       A library and some user-space utilities are provided to allow access to
       the facility.  See  keyctl(1),  keyctl(3),  and	keyutils(7)  for  more
       information.

   Keys
       A key has the following attributes:

       Serial number (ID)
	      This is a unique integer handle by which a key is referred to in
	      system calls.   The  serial  number  is  sometimes  synonymously
	      referred	as  the	 key ID.  Programmatically, key serial numbers
	      are represented using the type key_serial_t.

       Type   A key's type defines what sort of data can be held in  the  key,
	      how  the proposed content of the key will be parsed, and how the
	      payload will be used.

	      There are a number of general-purpose types available, plus some
	      specialist types defined by specific kernel components.

       Description (name)
	      The  key	description  is a printable string that is used as the
	      search term for the key (in conjunction with the	key  type)  as
	      well as a display name.  During searches, the description may be
	      partially matched or exactly matched.

       Payload (data)
	      The payload is the actual content of a key.  This is usually set
	      when  a  key  is	created,  but it is possible for the kernel to
	      upcall to user space to finish the instantiation	of  a  key  if
	      that  key	 wasn't	 already  known	 to  the  kernel  when	it was
	      requested.  For further details, see request_key(2).

	      A key's payload can be read and updated if the key type supports
	      it and if suitable permission is granted to the caller.

       Access rights
	      Much  as	files  do,  each  key has an owning user ID, an owning
	      group ID, and a security label.  Each key also has a set of per-
	      missions, though there are more than for a normal UNIX file, and
	      there is an  additional  category--possessor--beyond  the	 usual
	      user, group, and other (see Possession, below).

	      Note  that keys are quota controlled, since they require unswap-
	      pable kernel memory.  The owning user ID specifies  whose	 quota
	      is to be debited.

       Expiration time
	      Each  key	 can  have  an expiration time set.  When that time is
	      reached, the key is marked as being expired and accesses	to  it
	      fail  with  the  error EKEYEXPIRED.  If not deleted, updated, or
	      replaced, then, after a set amount of time, an  expired  key  is
	      automatically  removed  (garbage collected) along with all links
	      to it, and attempts to access the key will fail with  the	 error
	      ENOKEY.

       Reference count
	      Each  key	 has  a	 reference  count.   Keys  are	referenced  by
	      keyrings, by currently active users, and by a process's  creden-
	      tials.  When the reference count reaches zero, the key is sched-
	      uled for garbage collection.

   Key types
       The kernel provides several basic types of key:

       "keyring"
	      Keyrings are special keys which store a set of  links  to	 other
	      keys  (including other keyrings), analogous to a directory hold-
	      ing links to files.  The main purpose of a keyring is to prevent
	      other  keys  from being garbage collected because nothing refers
	      to them.

	      Keyrings with descriptions (names)  that	begin  with  a	period
	      ('.') are reserved to the implementation.

       "user" This  is	a  general-purpose key type.  The key is kept entirely
	      within kernel memory.  The payload may be read  and  updated  by
	      user-space applications.

	      The payload for keys of this type is a blob of arbitrary data of
	      up to 32,767 bytes.

	      The description may be any valid string, though it is  preferred
	      that  it	start  with  a colon-delimited prefix representing the
	      service  to  which  the  key  is	of  interest   (for   instance
	      "afs:mykey").

       "logon" (since Linux 3.3)
	      This key type is essentially the same as "user", but it does not
	      provide reading (i.e.,  the  keyctl(2)  KEYCTL_READ  operation),
	      meaning  that  the key payload is never visible from user space.
	      This is suitable for storing username-password pairs that should
	      not be readable from user space.

       "big_key" (since Linux 3.13)
	      This key type is similar to the "user" key type, but it may hold
	      a payload of up to 1 MiB in size.	 This key type is  useful  for
	      purposes such as holding Kerberos ticket caches.

	      The  payload  data  may  be stored in a tmpfs filesystem, rather
	      than in kernel memory, if the data size exceeds the overhead  of
	      storing  the  data  in  the  filesystem.	(Storing the data in a
	      filesystem requires filesystem structures to be allocated in the
	      kernel.	The  size  of  these  structures  determines  the size
	      threshold above which the tmpfs storage method is used.)	 Since
	      Linux  4.8,  the payload data is encrypted when stored in tmpfs,
	      thereby preventing it from being written unencrypted  into  swap
	      space.

       There  are  more	 specialized key types available also, but they aren't
       discussed here because they aren't intended for normal user-space use.

       Key type names that begin with a	 period	 ('.')	are  reserved  to  the
       implementation.

   Keyrings
       As  previously  mentioned, keyrings are a special type of key that con-
       tain links to other keys (which may include other keyrings).  Keys  may
       be linked to by multiple keyrings.  Keyrings may be considered as anal-
       ogous to UNIX directories where each directory contains a set  of  hard
       links to files.

       Various operations (system calls) may be applied only to keyrings:

       Adding A	 key  may  be  added  to a keyring by system calls that create
	      keys.  This prevents the new key from being immediately  deleted
	      when the system call releases its last reference to the key.

       Linking
	      A	 link  may  be	added  to  a keyring pointing to a key that is
	      already known, provided this does not create a  self-referential
	      cycle.

       Unlinking
	      A	 link  may be removed from a keyring.  When the last link to a
	      key is removed, that key will be scheduled for deletion  by  the
	      garbage collector.

       Clearing
	      All the links may be removed from a keyring.

       Searching
	      A	 keyring  may  be  considered the root of a tree or subtree in
	      which keyrings form the branches and  non-keyrings  the  leaves.
	      This  tree  may be searched for a key matching a particular type
	      and description.

       See    keyctl_clear(3),	  keyctl_link(3),    keyctl_search(3),	   and
       keyctl_unlink(3) for more information.

   Anchoring keys
       To prevent a key from being garbage collected, it must anchored to keep
       its reference count elevated when it is not in active use by  the  ker-
       nel.

       Keyrings	 are  used to anchor other keys: each link is a reference on a
       key.  Note that keyrings themselves are just keys and are also  subject
       to  the	same  anchoring requirement to prevent them being garbage col-
       lected.

       The kernel makes available a number of anchor keyrings.	Note that some
       of these keyrings will be created only when first accessed.

       Process keyrings
	      Process  credentials themselves reference keyrings with specific
	      semantics.  These keyrings are pinned as long as the set of cre-
	      dentials exists, which is usually as long as the process exists.

	      There  are  three	 keyrings  with	 different inheritance/sharing
	      rules: the session-keyring(7) (inherited and shared by all child
	      processes),  the	process-keyring(7) (shared by all threads in a
	      process) and the thread-keyring(7)  (specific  to	 a  particular
	      thread).

	      As  an  alternative to using the actual keyring IDs, in calls to
	      add_key(2), keyctl(2), and request_key(2), the  special  keyring
	      values  KEY_SPEC_SESSION_KEYRING,	 KEY_SPEC_PROCESS_KEYRING, and
	      KEY_SPEC_THREAD_KEYRING can be used to refer to the caller's own
	      instances of these keyrings.

       User keyrings
	      Each  UID	 known	to  the	 kernel has a record that contains two
	      keyrings: the user-keyring(7) and	 the  user-session-keyring(7).
	      These exist for as long as the UID record in the kernel exists.

	      As  an  alternative to using the actual keyring IDs, in calls to
	      add_key(2), keyctl(2), and request_key(2), the  special  keyring
	      values  KEY_SPEC_USER_KEYRING  and KEY_SPEC_USER_SESSION_KEYRING
	      can be used to refer to the  caller's  own  instances  of	 these
	      keyrings.

	      A link to the user keyring is placed in a new session keyring by
	      pam_keyinit(8) when a new login session is initiated.

       Persistent keyrings
	      There is a persistent-keyring(7) available to each UID known  to
	      the  system.   It	 may persist beyond the life of the UID record
	      previously mentioned, but has an expiration time set  such  that
	      it is automatically cleaned up after a set time.	The persistent
	      keyring permits, for example, cron(8) scripts to use credentials
	      that are left in the persistent keyring after the user logs out.

	      Note that the expiration time of the persistent keyring is reset
	      every time the persistent key is requested.

       Special keyrings
	      There are special keyrings owned by the kernel that  can	anchor
	      keys  for	 special  purposes.   An example of this is the system
	      keyring used for holding encryption keys	for  module  signature
	      verification.

	      These  special keyrings  are usually closed to direct alteration
	      by user space.

       An originally planned "group keyring", for storing keys associated with
       each GID known to the kernel, is not so far implemented, is unlikely to
       be implemented.	Nevertheless, the constant KEY_SPEC_GROUP_KEYRING  has
       been defined for this keyring.

   Possession
       The  concept  of	 possession is important to understanding the keyrings
       security model.	Whether a thread possesses a key is determined by  the
       following rules:

       (1) Any	key  or	 keyring  that does not grant search permission to the
	   caller is ignored in all the following rules.

       (2) A thread possesses its session-keyring(7), process-keyring(7),  and
	   thread-keyring(7)  directly	because those keyrings are referred to
	   by its credentials.

       (3) If a keyring is possessed, then any key it links to	is  also  pos-
	   sessed.

       (4) If  any  key	 a keyring links to is itself a keyring, then rule (3)
	   applies recursively.

       (5) If a process is upcalled from the kernel to instantiate a key  (see
	   request_key(2)), then it also possesses the requester's keyrings as
	   in rule (1) as if it were the requester.

       Note that possession is not a fundamental property of a key,  but  must
       rather be calculated each time the key is needed.

       Possession  is  designed	 to allow set-user-ID programs run from, say a
       user's shell to access the user's keys.	Granting  permissions  to  the
       key  possessor while denying them to the key owner and group allows the
       prevention of access to keys on the basis of UID and GID matches.

       When it creates the session keyring, pam_keyinit(8) adds a link to  the
       user-keyring(7),	 thus making the user keyring and anything it contains
       possessed by default.

   Access rights
       Each key has the following security-related attributes:

       *  The owning user ID

       *  The ID of a group that is permitted to access the key

       *  A security label

       *  A permissions mask

       The permissions mask contains four sets of  rights.   The  first	 three
       sets  are  mutually exclusive.  One and only one will be in force for a
       particular access check.	 In order of descending priority, these	 three
       sets are:

       user   The  set	specifies  the	rights	granted	 if  the key's user ID
	      matches the caller's filesystem user ID.

       group  The set specifies the rights granted if the user ID didn't match
	      and  the	key's  group ID matches the caller's filesystem GID or
	      one of the caller's supplementary group IDs.

       other  The set specifies the rights granted if neither the  key's  user
	      ID nor group ID matched.

       The fourth set of rights is:

       possessor
	      The  set	specifies the rights granted if a key is determined to
	      be possessed by the caller.

       The complete set of rights for a key is the union of whichever  of  the
       first  three  sets is applicable plus the fourth set if the key is pos-
       sessed.

       The set of rights that may be granted in each of the four masks	is  as
       follows:

       view   The  attributes of the key may be read.  This includes the type,
	      description, and access rights (excluding the security label).

       read   For a key: the payload of the key may be read.  For  a  keyring:
	      the list of serial numbers (keys) to which the keyring has links
	      may be read.

       write  The payload of the key  may  be  updated	and  the  key  may  be
	      revoked.	 For  a keyring, links may be added to or removed from
	      the keyring, and the keyring  may	 be  cleared  completely  (all
	      links are removed),

       search For a key (or a keyring): the key may be found by a search.  For
	      a keyring: keys and keyrings that are linked to by  the  keyring
	      may be searched.

       link   Links may be created from keyrings to the key.  The initial link
	      to a key that is established when the  key  is  created  doesn't
	      require this permission.

       setattr
	      The  ownership  details  and  security  label  of the key may be
	      changed, the key's expiration time may be set, and the  key  may
	      be revoked.

       In  addition  to	 access rights, any active Linux Security Module (LSM)
       may prevent access to a key if its policy so dictates.  A  key  may  be
       given  a	 security  label  or other attribute by the LSM; this label is
       retrievable via keyctl_get_security(3).

       See   keyctl_chown(3),	keyctl_describe(3),    keyctl_get_security(3),
       keyctl_setperm(3), and selinux(8) for more information.

   Searching for keys
       One  of	the  key  features of the Linux key-management facility is the
       ability to find a key that a process is retaining.  The	request_key(2)
       system  call is the primary point of access for user-space applications
       to find a key.  (Internally, the kernel has something similar available
       for use by internal components that make use of keys.)

       The search algorithm works as follows:

       (1) The	process	 keyrings  are	searched  in  the following order: the
	   thread thread-keyring(7) if it exists, the process-keyring(7) if it
	   exists,  and then either the session-keyring(7) if it exists or the
	   user-session-keyring(7) if that exists.

       (2) If the caller was a process that was invoked by the	request_key(2)
	   upcall  mechanism,  then  the  keyrings  of	the original caller of
	   request_key(2) will be searched as well.

       (3) The search of a  keyring  tree  is  in  breadth-first  order:  each
	   keyring  is	searched first for a match, then the keyrings referred
	   to by that keyring are searched.

       (4) If a matching key is found that is valid, then  the	search	termi-
	   nates and that key is returned.

       (5) If  a  matching key is found that has an error state attached, that
	   error state is noted and the search continues.

       (6) If no valid matching key is found, then the first noted error state
	   is returned; otherwise, an ENOKEY error is returned.

       It  is  also  possible to search a specific keyring, in which case only
       steps (3) to (6) apply.

       See request_key(2) and keyctl_search(3) for more information.

   On-demand key creation
       If a key cannot be found, request_key(2) will, if given a  callout_info
       argument, create a new key and then upcall to user space to instantiate
       the key.	 This allows keys to be created on an as-needed basis.

       Typically, this will involve the kernel creating	 a  new	 process  that
       executes the request-key(8) program, which will then execute the appro-
       priate handler based on its configuration.

       The handler is passed a special authorization key that  allows  it  and
       only  it	 to  instantiate  the  new  key.   This is also used to permit
       searches	 performed  by	the  handler  program  to  also	  search   the
       requester's keyrings.

       See  request_key(2), keyctl_assume_authority(3), keyctl_instantiate(3),
       keyctl_negate(3),  keyctl_reject(3),   request-key(8),	and   request-
       key.conf(5) for more information.

   /proc files
       The  kernel  provides various /proc files that expose information about
       keys or define limits on key usage.

       /proc/keys (since Linux 2.6.10)
	      This file exposes a list of  the	keys  for  which  the  reading
	      thread  has view permission, providing various information about
	      each key.	 The thread need not possess the key for it to be vis-
	      ible in this file.

	      The  only	 keys  included	 in the list are those that grant view
	      permission to the reading process (regardless of whether or  not
	      it  possesses  them).   LSM security checks are still performed,
	      and may filter out further keys that the process is  not	autho-
	      rized to view.

	      An example of the data that one might see in this file (with the
	      columns numbered for easy reference below) is the following:

  (1)	  (2)	  (3)(4)    (5)	    (6)	  (7)	(8)	   (9)
009a2028 I--Q---   1 perm 3f010000  1000  1000 user	krb_ccache:primary: 12
1806c4ba I--Q---   1 perm 3f010000  1000  1000 keyring	_pid: 2
25d3a08f I--Q---   1 perm 1f3f0000  1000 65534 keyring	_uid_ses.1000: 1
28576bd8 I--Q---   3 perm 3f010000  1000  1000 keyring	_krb: 1
2c546d21 I--Q--- 190 perm 3f030000  1000  1000 keyring	_ses: 2
30a4e0be I------   4   2d 1f030000  1000 65534 keyring	_persistent.1000: 1
32100fab I--Q---   4 perm 1f3f0000  1000 65534 keyring	_uid.1000: 2
32a387ea I--Q---   1 perm 3f010000  1000  1000 keyring	_pid: 2
3ce56aea I--Q---   5 perm 3f030000  1000  1000 keyring	_ses: 1

	      The fields shown in each line of this file are as follows:

	      ID (1) The ID (serial number) of the key, expressed in hexadeci-
		     mal.

	      Flags (2)
		     A set of flags describing the state of the key:

		     I	 The key has been instantiated.

		     R	 The key has been revoked.

		     D	 The key is dead (i.e., the key type has been unregis-
			 tered).  (A key may be briefly in this	 state	during
			 garbage collection.)

		     Q	 The key contributes to the user's quota.

		     U	 The  key is under construction via a callback to user
			 space; see request-key(2).

		     N	 The key is negatively instantiated.

		     i	 The key has been invalidated.

	      Usage (3)
		     This is a count of the number of kernel credential struc-
		     tures that are pinning the key (approximately: the number
		     of threads and open file references that  refer  to  this
		     key).

	      Timeout (4)
		     The  amount  of time until the key will expire, expressed
		     in human-readable form (weeks, days, hours, minutes,  and
		     seconds).	 The  string  perm  here means that the key is
		     permanent (no timeout).  The string expd means  that  the
		     key  has  already	expired,  but has not yet been garbage
		     collected.

	      Permissions (5)
		     The key permissions, expressed as four hexadecimal	 bytes
		     containing,  from	left  to  right,  the possessor, user,
		     group, and other permissions.  Within each byte, the per-
		     mission bits are as follows:

			  0x01	 view
			  Ox02	 read
			  0x04	 write
			  0x08	 search
			  0x10	 link
			  0x20	 setattr

	      UID (6)
		     The user ID of the key owner.

	      GID (7)
		     The  group	 ID  of the key.  The value -1 here means that
		     the key has no group ID; this can occur in	 certain  cir-
		     cumstances for keys created by the kernel.

	      Type (8)
		     The key type (user, keyring, etc.)

	      Description (9)
		     The key description (name).  This field contains descrip-
		     tive information about the key.  For most key  types,  it
		     has the form

			  name[: extra-info]

		     The  name	subfield is the key's description (name).  The
		     optional extra-info field provides some further  informa-
		     tion  about  the  key.  The information that appears here
		     depends on the key type, as follows:

		     "user" and "logon"
			 The size in bytes of the key  payload	(expressed  in
			 decimal).

		     "keyring"
			 The  number  of  keys	linked	to the keyring, or the
			 string empty if there	are  no	 keys  linked  to  the
			 keyring.

		     "big_key"
			 The  payload  size  in	 bytes, followed either by the
			 string [file], if the key payload exceeds the thresh-
			 old that means that the payload is stored in a (swap-
			 pable) tmpfs(5) filesystem, or otherwise  the	string
			 [buff],  indicating  that  the key is small enough to
			 reside in kernel memory.

		     For the ".request_key_auth" key type (authorization  key;
		     see  request_key(2)),  the description field has the form
		     shown in the following example:

			 key:c9a9b19 pid:28880 ci:10

		     The three subfields are as follows:

		     key  The hexadecimal ID of the key being instantiated  in
			  the requesting program.

		     pid  The PID of the requesting program.

		     ci	  The  length  of  the	callout	 data  with  which the
			  requested key	 should	 be  instantiated  (i.e.,  the
			  length of the payload associated with the authoriza-
			  tion key).

       /proc/key-users (since Linux 2.6.10)
	      This file lists various information for each user ID that has at
	      least  one  key  on the system.  An example of the data that one
	      might see in this file is the following:

		     0:	   10 9/9 2/1000000 22/25000000
		    42:	    9 9/9 8/200 106/20000
		  1000:	   11 11/11 10/200 271/20000

	      The fields shown in each line are as follows:

	      uid    The user ID.

	      usage  This is a kernel-internal	usage  count  for  the	kernel
		     structure used to record key users.

	      nkeys/nikeys
		     The  total number of keys owned by the user, and the num-
		     ber of those keys that have been instantiated.

	      qnkeys/maxkeys
		     The number of keys owned by the  user,  and  the  maximum
		     number of keys that the user may own.

	      qnbytes/maxbytes
		     The  number  of  bytes  consumed  in payloads of the keys
		     owned by this user, and the upper limit on the number  of
		     bytes in key payloads for that user.

       /proc/sys/kernel/keys/gc_delay (since Linux 2.6.32)
	      The value in this file specifies the interval, in seconds, after
	      which revoked and expired keys will be garbage  collected.   The
	      purpose  of having such an interval is so that there is a window
	      of time where user space can see an error (respectively  EKEYRE-
	      VOKED and EKEYEXPIRED) that indicates what happened to the key.

	      The default value in this file is 300 (i.e., 5 minutes).

       /proc/sys/kernel/keys/persistent_keyring_expiry (since Linux 3.13)
	      This  file defines an interval, in seconds, to which the persis-
	      tent keyring's expiration timer is reset each time  the  keyring
	      is  accessed  (via  keyctl_get_persistent(3)  or	the  keyctl(2)
	      KEYCTL_GET_PERSISTENT operation.)

	      The default value in this file is 259200 (i.e., 3 days).

       The following files (which are writable by  privileged  processes)  are
       used  to	 enforce  quotas  on the number of keys and number of bytes of
       data that can be stored in key payloads:

       /proc/sys/kernel/keys/maxbytes (since Linux 2.6.26)
	      This is the maximum number of bytes of data that a nonroot  user
	      can hold in the payloads of the keys owned by the user.

	      The default value in this file is 20,000.

       /proc/sys/kernel/keys/maxkeys (since Linux 2.6.26)
	      This is the maximum number of keys that a nonroot user may own.

	      The default value in this file is 200.

       /proc/sys/kernel/keys/root_maxbytes (since Linux 2.6.26)
	      This  is	the maximum number of bytes of data that the root user
	      (UID 0 in the root user namespace) can hold in the  payloads  of
	      the keys owned by root.

	      The  default  value  in  this  file is 25,000,000 (20,000 before
	      Linux 3.17).

       /proc/sys/kernel/keys/root_maxkeys (since Linux 2.6.26)
	      This is the maximum number of keys that the root user (UID 0  in
	      the root user namespace) may own.

	      The  default  value  in this file is 1,000,000 (200 before Linux
	      3.17).

       With respect to keyrings, note that each link in a keyring  consumes  4
       bytes of the keyring payload.

   Users
       The Linux key-management facility has a number of users and usages, but
       is not limited to those that already exist.

       In-kernel users of this facility include:

       Network filesystems - DNS
	      The kernel uses the upcall mechanism provided  by	 the  keys  to
	      upcall  to  user	space  to do DNS lookups and then to cache the
	      results.

       AF_RXRPC and kAFS - Authentication
	      The AF_RXRPC network protocol and the in-kernel  AFS  filesystem
	      use  keys	 to store the ticket needed to do secured or encrypted
	      traffic.	These are then looked  up  by  network	operations  on
	      AF_RXRPC and filesystem operations on kAFS.

       NFS - User ID mapping
	      The  NFS	filesystem uses keys to store mappings of foreign user
	      IDs to local user IDs.

       CIFS - Password
	      The CIFS filesystem uses keys to store passwords	for  accessing
	      remote shares.

       Module verification
	      The  kernel  build process can be made to cryptographically sign
	      modules.	That signature	is  then  checked  when	 a  module  is
	      loaded.

       User-space users of this facility include:

       Kerberos key storage
	      The  MIT	Kerberos  5  facility  (libkrb5) can use keys to store
	      authentication tokens which can  be  made	 to  be	 automatically
	      cleaned  up  a set time after the user last uses them, but until
	      then permits them to hang around after the user has  logged  out
	      so that cron(8) scripts can use them.

SEE ALSO
       keyctl(1), add_key(2), keyctl(2), request_key(2), keyctl(3),
       keyutils(7), persistent-keyring(7), process-keyring(7),
       session-keyring(7), thread-keyring(7), user-keyring(7),
       user-session-keyring(7), pam_keyinit(8), request-key(8)

COLOPHON
       This page is part of release 4.10 of the Linux man-pages project.  A
       description of the project, information about reporting bugs, and the
       latest version of this page, can be found at
       https://www.kernel.org/doc/man-pages/.



Linux				  2017-03-13			   KEYRINGS(7)