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NAME

       mount_namespaces - overview of Linux mount namespaces

DESCRIPTION

       For an overview of namespaces, see namespaces(7).

       Mount  namespaces  provide  isolation of the list of mount points seen by the processes in
       each namespace instance.  Thus, the processes in each of  the  mount  namespace  instances
       will see distinct single-directory hierarchies.

       The    views    provided    by    the   /proc/[pid]/mounts,   /proc/[pid]/mountinfo,   and
       /proc/[pid]/mountstats files (all described in proc(5)) correspond to the mount  namespace
       in which the process with the PID [pid] resides.  (All of the processes that reside in the
       same mount namespace will see the same view in these files.)

       A new mount namespace is created using either clone(2) or unshare(2) with the  CLONE_NEWNS
       flag.   When  a  new  mount  namespace  is created, its mount point list is initialized as
       follows:

       *  If the namespace is created using  clone(2),  the  mount  point  list  of  the  child's
          namespace is a copy of the mount point list in the parent's namespace.

       *  If the namespace is created using unshare(2), the mount point list of the new namespace
          is a copy of the mount point list in the caller's previous mount namespace.

       Subsequent modifications to the mount point list (mount(2) and umount(2)) in either  mount
       namespace  will  not  (by default) affect the mount point list seen in the other namespace
       (but see the following discussion of shared subtrees).

   Restrictions on mount namespaces
       Note the following points with respect to mount namespaces:

       *  Each mount namespace has an owner user namespace.  As explained above, when a new mount
          namespace  is created, its mount point list is initialized as a copy of the mount point
          list of another mount namespace.  If the new namespace and the namespace from which the
          mount  point list was copied are owned by different user namespaces, then the new mount
          namespace is considered less privileged.

       *  When creating a less privileged mount namespace, shared mounts  are  reduced  to  slave
          mounts.   (Shared  and  slave  mounts are discussed below.)  This ensures that mappings
          performed in less privileged mount namespaces will not  propagate  to  more  privileged
          mount namespaces.

       *  Mounts  that  come  as a single unit from more privileged mount are locked together and
          may not be separated in a less privileged mount namespace.  (The unshare(2) CLONE_NEWNS
          operation brings across all of the mounts from the original mount namespace as a single
          unit, and recursive mounts that propagate  between  mount  namespaces  propagate  as  a
          single unit.)

       *  The  mount(2) flags MS_RDONLY, MS_NOSUID, MS_NOEXEC, and the "atime" flags (MS_NOATIME,
          MS_NODIRATIME,  MS_RELATIME)  settings  become  locked  when  propagated  from  a  more
          privileged  to  a  less  privileged mount namespace, and may not be changed in the less
          privileged mount namespace.

       *  A file or directory that is a mount point in one namespace that is not a mount point in
          another  namespace,  may  be  renamed,  unlinked,  or  removed  (rmdir(2)) in the mount
          namespace in which it is not a mount point (subject to the  usual  permission  checks).
          Consequently,  the  mount  point is removed in the mount namespace where it was a mount
          point.

          Previously (before Linux 3.18), attempting to unlink,  rename,  or  remove  a  file  or
          directory  that  was a mount point in another mount namespace would result in the error
          EBUSY.  That behavior had  technical  problems  of  enforcement  (e.g.,  for  NFS)  and
          permitted  denial-of-service  attacks against more privileged users.  (i.e., preventing
          individual files from being updated by bind mounting on top of them).

SHARED SUBTREES

       After the implementation of mount namespaces was completed,  experience  showed  that  the
       isolation that they provided was, in some cases, too great.  For example, in order to make
       a newly loaded optical disk available in all  mount  namespaces,  a  mount  operation  was
       required in each namespace.  For this use case, and others, the shared subtree feature was
       introduced in Linux 2.6.15.  This feature allows for automatic, controlled propagation  of
       mount  and unmount events between namespaces (or, more precisely, between the members of a
       peer group that are propagating events to one another).

       Each mount point is marked (via mount(2)) as  having  one  of  the  following  propagation
       types:

       MS_SHARED
              This  mount  point  shares  events with members of a peer group.  Mount and unmount
              events immediately under this mount point will propagate to the other mount  points
              that  are members of the peer group.  Propagation here means that the same mount or
              unmount will automatically occur under all of the other mount points  in  the  peer
              group.   Conversely,  mount  and  unmount  events  that take place under peer mount
              points will propagate to this mount point.

       MS_PRIVATE
              This mount point is private; it does not have a  peer  group.   Mount  and  unmount
              events do not propagate into or out of this mount point.

       MS_SLAVE
              Mount  and  unmount  events  propagate into this mount point from a (master) shared
              peer group.  Mount and unmount events under this mount point do  not  propagate  to
              any peer.

              Note  that  a  mount point can be the slave of another peer group while at the same
              time sharing mount and unmount events with a peer group of which it  is  a  member.
              (More precisely, one peer group can be the slave of another peer group.)

       MS_UNBINDABLE
              This  is  like  a  private mount, and in addition this mount can't be bind mounted.
              Attempts to bind mount this mount (mount(2) with the MS_BIND flag) will fail.

              When a recursive bind mount  (mount(2)  with  the  MS_BIND  and  MS_REC  flags)  is
              performed  on  a  directory  subtree,  any  bind  mounts  within  the  subtree  are
              automatically pruned (i.e.,  not  replicated)  when  replicating  that  subtree  to
              produce the target subtree.

       For a discussion of the propagation type assigned to a new mount, see NOTES.

       The  propagation  type  is  a  per-mount-point setting; some mount points may be marked as
       shared (with each shared mount point being a member  of  a  distinct  peer  group),  while
       others are private (or slaved or unbindable).

       Note  that  a  mount's  propagation  type  determines whether mounts and unmounts of mount
       points immediately under the mount point are propagated.  Thus, the propagation type  does
       not  affect  propagation  of events for grandchildren and further removed descendant mount
       points.  What happens if the  mount  point  itself  is  unmounted  is  determined  by  the
       propagation type that is in effect for the parent of the mount point.

       Members are added to a peer group when a mount point is marked as shared and either:

       *  the mount point is replicated during the creation of a new mount namespace; or

       *  a new bind mount is created from the mount point.

       In  both  of  these  cases, the new mount point joins the peer group of which the existing
       mount point is a member.

       A new peer group is also created when a child mount point is  created  under  an  existing
       mount  point  that  is  marked as shared.  In this case, the new child mount point is also
       marked as shared and the resulting peer group consists of all the mount  points  that  are
       replicated under the peers of parent mount.

       A  mount  ceases  to  be  a  member  of  a  peer group when either the mount is explicitly
       unmounted, or when the mount is implicitly unmounted because a mount namespace is  removed
       (because it has no more member processes).

       The  propagation  type  of the mount points in a mount namespace can be discovered via the
       "optional fields" exposed in /proc/[pid]/mountinfo.  (See  proc(5)  for  details  of  this
       file.)  The following tags can appear in the optional fields for a record in that file:

       shared:X
              This  mount  point is shared in peer group X.  Each peer group has a unique ID that
              is automatically generated by the kernel, and all mount points  in  the  same  peer
              group  will  show  the same ID.  (These IDs are assigned starting from the value 1,
              and may be recycled when a peer group ceases to have any members.)

       master:X
              This mount is a slave to shared peer group X.

       propagate_from:X (since Linux 2.6.26)
              This mount is a slave and receives propagation from shared peer group X.  This  tag
              will  always  appear  in  conjunction  with a master:X tag.  Here, X is the closest
              dominant peer group under the process's root directory.   If  X  is  the  immediate
              master  of  the  mount,  or if there is no dominant peer group under the same root,
              then only the master:X field is present and not the  propagate_from:X  field.   For
              further details, see below.

       unbindable
              This is an unbindable mount.

       If none of the above tags is present, then this is a private mount.

   MS_SHARED and MS_PRIVATE example
       Suppose  that  on  a  terminal  in the initial mount namespace, we mark one mount point as
       shared and another as private, and then view the mounts in /proc/self/mountinfo:

           sh1# mount --make-shared /mntS
           sh1# mount --make-private /mntP
           sh1# cat /proc/self/mountinfo | grep '/mnt' | sed 's/ - .*//'
           77 61 8:17 / /mntS rw,relatime shared:1
           83 61 8:15 / /mntP rw,relatime

       From the /proc/self/mountinfo output, we see that /mntS is a shared mount in peer group 1,
       and that /mntP has no optional tags, indicating that it is a private mount.  The first two
       fields in each record in this file are the unique ID for this mount, and the mount  ID  of
       the  parent mount.  We can further inspect this file to see that the parent mount point of
       /mntS and /mntP is the root directory, /, which is mounted as private:

           sh1# cat /proc/self/mountinfo | awk '$1 == 61' | sed 's/ - .*//'
           61 0 8:2 / / rw,relatime

       On a second terminal, we create a new mount namespace where we  run  a  second  shell  and
       inspect the mounts:

           $ PS1='sh2# ' sudo unshare -m --propagation unchanged sh
           sh2# cat /proc/self/mountinfo | grep '/mnt' | sed 's/ - .*//'
           222 145 8:17 / /mntS rw,relatime shared:1
           225 145 8:15 / /mntP rw,relatime

       The  new  mount  namespace  received a copy of the initial mount namespace's mount points.
       These new mount points maintain the same propagation types, but  have  unique  mount  IDs.
       (The --propagation unchanged option prevents unshare(1) from marking all mounts as private
       when creating a new mount namespace, which it does by default.)

       In the second terminal, we then create submounts under each of /mntS and /mntP and inspect
       the set-up:

           sh2# mkdir /mntS/a
           sh2# mount /dev/sdb6 /mntS/a
           sh2# mkdir /mntP/b
           sh2# mount /dev/sdb7 /mntP/b
           sh2# cat /proc/self/mountinfo | grep '/mnt' | sed 's/ - .*//'
           222 145 8:17 / /mntS rw,relatime shared:1
           225 145 8:15 / /mntP rw,relatime
           178 222 8:22 / /mntS/a rw,relatime shared:2
           230 225 8:23 / /mntP/b rw,relatime

       From the above, it can be seen that /mntS/a was created as shared (inheriting this setting
       from its parent mount) and /mntP/b was created as a private mount.

       Returning to the first terminal and inspecting the set-up,  we  see  that  the  new  mount
       created  under  the  shared mount point /mntS propagated to its peer mount (in the initial
       mount namespace), but the new mount created under the private mount point  /mntP  did  not
       propagate:

           sh1# cat /proc/self/mountinfo | grep '/mnt' | sed 's/ - .*//'
           77 61 8:17 / /mntS rw,relatime shared:1
           83 61 8:15 / /mntP rw,relatime
           179 77 8:22 / /mntS/a rw,relatime shared:2

   MS_SLAVE example
       Making a mount point a slave allows it to receive propagated mount and unmount events from
       a master shared peer group, while preventing it from propagating events  to  that  master.
       This  is  useful if we want to (say) receive a mount event when an optical disk is mounted
       in the master shared peer group (in another mount namespace), but want  to  prevent  mount
       and unmount events under the slave mount from having side effects in other namespaces.

       We  can  demonstrate  the effect of slaving by first marking two mount points as shared in
       the initial mount namespace:

           sh1# mount --make-shared /mntX
           sh1# mount --make-shared /mntY
           sh1# cat /proc/self/mountinfo | grep '/mnt' | sed 's/ - .*//'
           132 83 8:23 / /mntX rw,relatime shared:1
           133 83 8:22 / /mntY rw,relatime shared:2

       On a second terminal, we create a new mount namespace and inspect the mount points:

           sh2# unshare -m --propagation unchanged sh
           sh2# cat /proc/self/mountinfo | grep '/mnt' | sed 's/ - .*//'
           168 167 8:23 / /mntX rw,relatime shared:1
           169 167 8:22 / /mntY rw,relatime shared:2

       In the new mount namespace, we then mark one of the mount points as a slave:

           sh2# mount --make-slave /mntY
           sh2# cat /proc/self/mountinfo | grep '/mnt' | sed 's/ - .*//'
           168 167 8:23 / /mntX rw,relatime shared:1
           169 167 8:22 / /mntY rw,relatime master:2

       From the above output, we  see  that  /mntY  is  now  a  slave  mount  that  is  receiving
       propagation events from the shared peer group with the ID 2.

       Continuing in the new namespace, we create submounts under each of /mntX and /mntY:

           sh2# mkdir /mntX/a
           sh2# mount /dev/sda3 /mntX/a
           sh2# mkdir /mntY/b
           sh2# mount /dev/sda5 /mntY/b

       When  we  inspect  the  state  of the mount points in the new mount namespace, we see that
       /mntX/a was created as a new shared mount (inheriting the "shared" setting from its parent
       mount) and /mntY/b was created as a private mount:

           sh2# cat /proc/self/mountinfo | grep '/mnt' | sed 's/ - .*//'
           168 167 8:23 / /mntX rw,relatime shared:1
           169 167 8:22 / /mntY rw,relatime master:2
           173 168 8:3 / /mntX/a rw,relatime shared:3
           175 169 8:5 / /mntY/b rw,relatime

       Returning  to  the  first terminal (in the initial mount namespace), we see that the mount
       /mntX/a propagated to the  peer  (the  shared  /mntX),  but  the  mount  /mntY/b  was  not
       propagated:

           sh1# cat /proc/self/mountinfo | grep '/mnt' | sed 's/ - .*//'
           132 83 8:23 / /mntX rw,relatime shared:1
           133 83 8:22 / /mntY rw,relatime shared:2
           174 132 8:3 / /mntX/a rw,relatime shared:3

       Now we create a new mount point under /mntY in the first shell:

           sh1# mkdir /mntY/c
           sh1# mount /dev/sda1 /mntY/c
           sh1# cat /proc/self/mountinfo | grep '/mnt' | sed 's/ - .*//'
           132 83 8:23 / /mntX rw,relatime shared:1
           133 83 8:22 / /mntY rw,relatime shared:2
           174 132 8:3 / /mntX/a rw,relatime shared:3
           178 133 8:1 / /mntY/c rw,relatime shared:4

       When  we  examine the mount points in the second mount namespace, we see that in this case
       the new mount has been propagated to the slave mount point, and  that  the  new  mount  is
       itself a slave mount (to peer group 4):

           sh2# cat /proc/self/mountinfo | grep '/mnt' | sed 's/ - .*//'
           168 167 8:23 / /mntX rw,relatime shared:1
           169 167 8:22 / /mntY rw,relatime master:2
           173 168 8:3 / /mntX/a rw,relatime shared:3
           175 169 8:5 / /mntY/b rw,relatime
           179 169 8:1 / /mntY/c rw,relatime master:4

   MS_UNBINDABLE example
       One  of  the primary purposes of unbindable mounts is to avoid the "mount point explosion"
       problem when repeatedly performing bind mounts of a higher-level subtree at a  lower-level
       mount point.  The problem is illustrated by the following shell session.

       Suppose we have a system with the following mount points:

           # mount | awk '{print $1, $2, $3}'
           /dev/sda1 on /
           /dev/sdb6 on /mntX
           /dev/sdb7 on /mntY

       Suppose  furthermore  that  we  wish  to  recursively  bind mount the root directory under
       several users' home directories.  We do this for the first user,  and  inspect  the  mount
       points:

           # mount --rbind / /home/cecilia/
           # mount | awk '{print $1, $2, $3}'
           /dev/sda1 on /
           /dev/sdb6 on /mntX
           /dev/sdb7 on /mntY
           /dev/sda1 on /home/cecilia
           /dev/sdb6 on /home/cecilia/mntX
           /dev/sdb7 on /home/cecilia/mntY

       When we repeat this operation for the second user, we start to see the explosion problem:

           # mount --rbind / /home/henry
           # mount | awk '{print $1, $2, $3}'
           /dev/sda1 on /
           /dev/sdb6 on /mntX
           /dev/sdb7 on /mntY
           /dev/sda1 on /home/cecilia
           /dev/sdb6 on /home/cecilia/mntX
           /dev/sdb7 on /home/cecilia/mntY
           /dev/sda1 on /home/henry
           /dev/sdb6 on /home/henry/mntX
           /dev/sdb7 on /home/henry/mntY
           /dev/sda1 on /home/henry/home/cecilia
           /dev/sdb6 on /home/henry/home/cecilia/mntX
           /dev/sdb7 on /home/henry/home/cecilia/mntY

       Under /home/henry, we have not only recursively added the /mntX and /mntY mounts, but also
       the recursive mounts of those directories under /home/cecilia that  were  created  in  the
       previous  step.   Upon  repeating  the  step for a third user, it becomes obvious that the
       explosion is exponential in nature:

           # mount --rbind / /home/otto
           # mount | awk '{print $1, $2, $3}'
           /dev/sda1 on /
           /dev/sdb6 on /mntX
           /dev/sdb7 on /mntY
           /dev/sda1 on /home/cecilia
           /dev/sdb6 on /home/cecilia/mntX
           /dev/sdb7 on /home/cecilia/mntY
           /dev/sda1 on /home/henry
           /dev/sdb6 on /home/henry/mntX
           /dev/sdb7 on /home/henry/mntY
           /dev/sda1 on /home/henry/home/cecilia
           /dev/sdb6 on /home/henry/home/cecilia/mntX
           /dev/sdb7 on /home/henry/home/cecilia/mntY
           /dev/sda1 on /home/otto
           /dev/sdb6 on /home/otto/mntX
           /dev/sdb7 on /home/otto/mntY
           /dev/sda1 on /home/otto/home/cecilia
           /dev/sdb6 on /home/otto/home/cecilia/mntX
           /dev/sdb7 on /home/otto/home/cecilia/mntY
           /dev/sda1 on /home/otto/home/henry
           /dev/sdb6 on /home/otto/home/henry/mntX
           /dev/sdb7 on /home/otto/home/henry/mntY
           /dev/sda1 on /home/otto/home/henry/home/cecilia
           /dev/sdb6 on /home/otto/home/henry/home/cecilia/mntX
           /dev/sdb7 on /home/otto/home/henry/home/cecilia/mntY

       The mount explosion problem in the above scenario can be avoided by making each of the new
       mounts  unbindable.   The  effect  of  doing  this  is  that  recursive mounts of the root
       directory will not replicate the unbindable mounts.  We make such a mount  for  the  first
       user:

           # mount --rbind --make-unbindable / /home/cecilia

       Before going further, we show that unbindable mounts are indeed unbindable:

           # mkdir /mntZ
           # mount --bind /home/cecilia /mntZ
           mount: wrong fs type, bad option, bad superblock on /home/cecilia,
                  missing codepage or helper program, or other error

                  In some cases useful info is found in syslog - try
                  dmesg | tail or so.

       Now we create unbindable recursive bind mounts for the other two users:

           # mount --rbind --make-unbindable / /home/henry
           # mount --rbind --make-unbindable / /home/otto

       Upon  examining  the  list  of  mount  points, we see there has been no explosion of mount
       points, because the unbindable mounts were not replicated under each user's directory:

           # mount | awk '{print $1, $2, $3}'
           /dev/sda1 on /
           /dev/sdb6 on /mntX
           /dev/sdb7 on /mntY
           /dev/sda1 on /home/cecilia
           /dev/sdb6 on /home/cecilia/mntX
           /dev/sdb7 on /home/cecilia/mntY
           /dev/sda1 on /home/henry
           /dev/sdb6 on /home/henry/mntX
           /dev/sdb7 on /home/henry/mntY
           /dev/sda1 on /home/otto
           /dev/sdb6 on /home/otto/mntX
           /dev/sdb7 on /home/otto/mntY

   Propagation type transitions
       The following table shows the effect that applying a new  propagation  type  (i.e.,  mount
       --make-xxxx)  has  on the existing propagation type of a mount point.  The rows correspond
       to existing propagation types, and the columns are  the  new  propagation  settings.   For
       reasons of space, "private" is abbreviated as "priv" and "unbindable" as "unbind".

                     make-shared   make-slave      make-priv  make-unbind
       shared        shared        slave/priv [1]  priv       unbind
       slave         slave+shared  slave [2]       priv       unbind
       slave+shared  slave+shared  slave           priv       unbind
       private       shared        priv [2]        priv       unbind
       unbindable    shared        unbind [2]      priv       unbind

       Note the following details to the table:

       [1] If a shared mount is the only mount in its peer group, making it a slave automatically
           makes it private.

       [2] Slaving a nonshared mount has no effect on the mount.

   Bind (MS_BIND) semantics
       Suppose that the following command is performed:

           mount --bind A/a B/b

       Here, A is the source mount point, B is the destination mount point, a is  a  subdirectory
       path  under  the mount point A, and b is a subdirectory path under the mount point B.  The
       propagation type of the resulting mount, B/b, depends on  the  propagation  types  of  the
       mount points A and B, and is summarized in the following table.

                                    source(A)
                            shared  private    slave         unbind
       ───────────────────────────────────────────────────────────────
       dest(B)  shared    | shared  shared     slave+shared  invalid
                nonshared | shared  private    slave         invalid

       Note that a recursive bind of a subtree follows the same semantics as for a bind operation
       on each mount in the subtree.  (Unbindable mounts are automatically pruned at  the  target
       mount point.)

       For  further details, see Documentation/filesystems/sharedsubtree.txt in the kernel source
       tree.

   Move (MS_MOVE) semantics
       Suppose that the following command is performed:

           mount --move A B/b

       Here, A is the source mount  point,  B  is  the  destination  mount  point,  and  b  is  a
       subdirectory  path  under the mount point B.  The propagation type of the resulting mount,
       B/b, depends on the propagation types of the mount points A and B, and  is  summarized  in
       the following table.

                                    source(A)
                            shared  private    slave         unbind
       ──────────────────────────────────────────────────────────────────
       dest(B)  shared    | shared  shared     slave+shared  invalid
                nonshared | shared  private    slave         unbindable

       Note: moving a mount that resides under a shared mount is invalid.

       For  further details, see Documentation/filesystems/sharedsubtree.txt in the kernel source
       tree.

   Mount semantics
       Suppose that we use the following command to create a mount point:

           mount device B/b

       Here, B is the destination mount point, and b is a subdirectory path under the mount point
       B.  The propagation type of the resulting mount, B/b, follows the same rules as for a bind
       mount, where the propagation type of the source mount is considered always to be private.

   Unmount semantics
       Suppose that we use the following command to tear down a mount point:

           unmount A

       Here, A is a mount point on B/b, where B is the parent mount and b is a subdirectory  path
       under  the  mount  point B.  If B is shared, then all most-recently-mounted mounts at b on
       mounts that receive propagation from mount B and do not  have  submounts  under  them  are
       unmounted.

   The /proc/[pid]/mountinfo propagate_from tag
       The propagate_from:X tag is shown in the optional fields of a /proc/[pid]/mountinfo record
       in cases where a process can't see a slave's immediate master (i.e., the pathname  of  the
       master  is  not  reachable from the filesystem root directory) and so cannot determine the
       chain of propagation between the mounts it can see.

       In the following example, we first create a two-link master-slave chain between the mounts
       /mnt, /tmp/etc, and /mnt/tmp/etc.  Then the chroot(1) command is used to make the /tmp/etc
       mount point unreachable from the root directory, creating a situation where the master  of
       /mnt/tmp/etc is not reachable from the (new) root directory of the process.

       First,  we  bind mount the root directory onto /mnt and then bind mount /proc at /mnt/proc
       so that after the later chroot(1) the proc(5) filesystem remains visible  at  the  correct
       location in the chroot-ed environment.

           # mkdir -p /mnt/proc
           # mount --bind / /mnt
           # mount --bind /proc /mnt/proc

       Next, we ensure that the /mnt mount is a shared mount in a new peer group (with no peers):

           # mount --make-private /mnt  # Isolate from any previous peer group
           # mount --make-shared /mnt
           # cat /proc/self/mountinfo | grep '/mnt' | sed 's/ - .*//'
           239 61 8:2 / /mnt ... shared:102
           248 239 0:4 / /mnt/proc ... shared:5

       Next, we bind mount /mnt/etc onto /tmp/etc:

           # mkdir -p /tmp/etc
           # mount --bind /mnt/etc /tmp/etc
           # cat /proc/self/mountinfo | egrep '/mnt|/tmp/' | sed 's/ - .*//'
           239 61 8:2 / /mnt ... shared:102
           248 239 0:4 / /mnt/proc ... shared:5
           267 40 8:2 /etc /tmp/etc ... shared:102

       Initially,  these  two  mount  points  are  in  the  same peer group, but we then make the
       /tmp/etc a slave of /mnt/etc, and then make /tmp/etc  shared  as  well,  so  that  it  can
       propagate events to the next slave in the chain:

           # mount --make-slave /tmp/etc
           # mount --make-shared /tmp/etc
           # cat /proc/self/mountinfo | egrep '/mnt|/tmp/' | sed 's/ - .*//'
           239 61 8:2 / /mnt ... shared:102
           248 239 0:4 / /mnt/proc ... shared:5
           267 40 8:2 /etc /tmp/etc ... shared:105 master:102

       Then  we bind mount /tmp/etc onto /mnt/tmp/etc.  Again, the two mount points are initially
       in the same peer group, but we then make /mnt/tmp/etc a slave of /tmp/etc:

           # mkdir -p /mnt/tmp/etc
           # mount --bind /tmp/etc /mnt/tmp/etc
           # mount --make-slave /mnt/tmp/etc
           # cat /proc/self/mountinfo | egrep '/mnt|/tmp/' | sed 's/ - .*//'
           239 61 8:2 / /mnt ... shared:102
           248 239 0:4 / /mnt/proc ... shared:5
           267 40 8:2 /etc /tmp/etc ... shared:105 master:102
           273 239 8:2 /etc /mnt/tmp/etc ... master:105

       From the above, we see that /mnt is the master of the slave /tmp/etc, which in turn is the
       master of the slave /mnt/tmp/etc.

       We  then  chroot(1) to the /mnt directory, which renders the mount with ID 267 unreachable
       from the (new) root directory:

           # chroot /mnt

       When we examine the state of the mounts inside  the  chroot-ed  environment,  we  see  the
       following:

           # cat /proc/self/mountinfo | sed 's/ - .*//'
           239 61 8:2 / / ... shared:102
           248 239 0:4 / /proc ... shared:5
           273 239 8:2 /etc /tmp/etc ... master:105 propagate_from:102

       Above,  we  see  that the mount with ID 273 is a slave whose master is the peer group 105.
       The mount point for that master is unreachable, and so a propagate_from tag is  displayed,
       indicating  that the closest dominant peer group (i.e., the nearest reachable mount in the
       slave chain) is the peer group with the ID 102 (corresponding  to  the  /mnt  mount  point
       before the chroot(1) was performed.

VERSIONS

       Mount namespaces first appeared in Linux 2.4.19.

CONFORMING TO

       Namespaces are a Linux-specific feature.

NOTES

       The  propagation type assigned to a new mount point depends on the propagation type of the
       parent mount.  If the mount point has a parent (i.e., it is a non-root  mount  point)  and
       the  propagation  type  of  the  parent is MS_SHARED, then the propagation type of the new
       mount is also MS_SHARED.  Otherwise, the propagation type of the new mount is MS_PRIVATE.

       Notwithstanding the fact that the default propagation type for new mount points is in many
       cases  MS_PRIVATE,  MS_SHARED  is  typically  more  useful.   For  this reason, systemd(1)
       automatically remounts all mount points as MS_SHARED on system  startup.   Thus,  on  most
       modern systems, the default propagation type is in practice MS_SHARED.

       Since,  when  one  uses  unshare(1)  to  create a mount namespace, the goal is commonly to
       provide full isolation of the mount points in the new namespace, unshare(1)  (since  util-
       linux version 2.27) in turn reverses the step performed by systemd(1), by making all mount
       points private in the new namespace.  That is, unshare(1) performs the equivalent  of  the
       following in the new mount namespace:

           mount --make-rprivate /

       To prevent this, one can use the --propagation unchanged option to unshare(1).

       An  application  that  creates a new mount namespace directly using clone(2) or unshare(2)
       may desire to prevent propagation of mount events to other mount namespaces (as is done by
       unshare(1)).  This can be done by changing the propagation type of mount points in the new
       namespace to either MS_SLAVE or MS_PRIVATE.  using a call such as the following:

                  mount(NULL, "/", MS_SLAVE | MS_REC, NULL);

       For a discussion of propagation types when  moving  mounts  (MS_MOVE)  and  creating  bind
       mounts (MS_BIND), see Documentation/filesystems/sharedsubtree.txt.

EXAMPLE

       See pivot_root(2).

SEE ALSO

       unshare(1),  clone(2),  mount(2), pivot_root(2), setns(2), umount(2), unshare(2), proc(5),
       namespaces(7), user_namespaces(7), findmnt(8), pivot_root(8)

       Documentation/filesystems/sharedsubtree.txt in the kernel source tree.

COLOPHON

       This page is part of release 5.05 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/.