MOUNT_UNIONFS(8) BSD System Manager's Manual MOUNT_UNIONFS(8)
mount_unionfs -- mount union file systems
mount_unionfs [-b] [-o options] directory uniondir
The mount_unionfs utility attaches directory above uniondir in such a way that the contents of both directory trees remain visible. By
default, directory becomes the upper layer and uniondir becomes the lower layer.
The options are as follows:
-b Deprecated. Use -o below instead.
-o Options are specified with the -o flag followed by an option. The following options are available:
below Inverts the default position, so that directory becomes the lower layer and uniondir becomes the upper layer. However,
uniondir remains the mount point.
Specifies the way to create a file or a directory in the upper layer automatically when needed. The traditional mode uses
the same way as the old unionfs for backward compatibility, and transparent duplicates the file and directory mode bits and
the ownership in the lower layer to the created file in the upper layer. For behavior of the masquerade mode, see MASQUERADE
Specifies whether whiteouts should always be made in the upper layer when removing a file or directory or only when it
already exists in the lower layer.
Specifies directory mode bits in octal for masquerade mode.
Specifies file mode bits in octal for masquerade mode.
Specifies group for masquerade mode.
Specifies user for masquerade mode.
To enforce file system security, the user mounting a file system must be superuser or else have write permission on the mounted-on directory.
In addition, the vfs.usermount sysctl(8) variable must be set to 1 to permit file system mounting by ordinary users. However, note that
transparent and masquerade modes require vfs.usermount to be set to 0 because this functionality can only be used by superusers.
Filenames are looked up in the upper layer and then in the lower layer. If a directory is found in the lower layer, and there is no entry in
the upper layer, then a shadow directory will be created in the upper layer. The ownership and the mode bits are set depending on the
copymode option. In traditional mode, it will be owned by the user who originally did the union mount, with mode 0777 (``rwxrwxrwx'') modi-
fied by the umask in effect at that time.
If a file exists in the upper layer then there is no way to access a file with the same name in the lower layer. If necessary, a combination
of loopback and union mounts can be made which will still allow the lower files to be accessed by a different pathname.
Except in the case of a directory, access to an object is granted via the normal file system access checks. For directories, the current
user must have access to both the upper and lower directories (should they both exist).
Requests to create or modify objects in uniondir are passed to the upper layer with the exception of a few special cases. An attempt to open
for writing a file which exists in the lower layer causes a copy of the entire file to be made to the upper layer, and then for the upper
layer copy to be opened. Similarly, an attempt to truncate a lower layer file to zero length causes an empty file to be created in the upper
layer. Any other operation which would ultimately require modification to the lower layer fails with EROFS.
The union file system manipulates the namespace, rather than individual file systems. The union operation applies recursively down the
directory tree now rooted at uniondir. Thus any file systems which are mounted under uniondir will take part in the union operation. This
differs from the union option to mount(8) which only applies the union operation to the mount point itself, and then only for lookups.
When a file (or a directory) is created in the upper layer, the masquerade mode sets it the fixed access mode bits given in ufile (for files)
or udir (for directories) option and the owner given in udir and gid options, instead of ones in the lower layer. Note that in the
masquerade mode and when owner of the file or directory matches one specified in uid option, only mode bits for the owner will be modified.
More specifically, the file mode bits in the upper layer will be (mode in the lower layer) OR (mode given in ufile AND 0700), and the owner-
ship will be the same as one in the lower layer.
The default values for ufile, udir, uid, and gid are as follow:
o If none of ufile and udir were specified, access mode bits in the mount point will be used.
o If none of uid and gid were specified, ownership in the mount point will be used.
o If one of udir or ufile is not specified, the value of the other option will be used.
o If one of uid or gid is not specified, the value of the other option will be used.
mount -t cd9660 -o ro /dev/cd0 /usr/src
mount -t unionfs -o noatime /var/obj /usr/src
mount the CD-ROM drive /dev/cd0 on /usr/src and then attaches /var/obj on top. For most purposes the effect of this is to make the source
tree appear writable even though it is stored on a CD-ROM. The -o noatime option is useful to avoid unnecessary copying from the lower to
the upper layer.
mount -t cd9660 -o ro /dev/cd0 /usr/src
chown 2020 /usr/src
mount -t unionfs -o noatime -o copymode=masquerade -o uid=builder
-o udir=755 -o ufile=644 /var/obj /usr/src
also mount the CD-ROM drive /dev/cd0 on /usr/src and then attaches /var/obj on top. Furthermore, the owner of all files and directories in
/usr/src is a regular user with UID 2020 when seen from the upper layer. Note that for the access mode bits, ones in the lower layer (on the
CD-ROM, in this example) are still used without change. Thus, write privilege to the upper layer can be controlled independently from access
mode bits and ownership in the lower layer. If a user does not have read privilege from the lower layer, one cannot still read even when the
upper layer is mounted by using masquerade mode.
mount -t unionfs -o noatime -o below /sys $HOME/sys
attaches the system source tree below the sys directory in the user's home directory. This allows individual users to make private changes
to the source, and build new kernels, without those changes becoming visible to other users. Note that the files in the lower layer remain
accessible via /sys.
intro(2), mount(2), unmount(2), fstab(5), mount(8), mount_nullfs(8)
The mount_unionfs utility first appeared in 4.4BSD.
The -r option for hiding the lower layer completely was removed in FreeBSD 7.0 because this is identical to using mount_nullfs(8).
In FreeBSD 7.0, Masanori OZAWA <email@example.com> reimplemented handling of locking, whiteout, and file mode bits, and Hiroki Sato
<hrs@FreeBSD.org> wrote about the changes in this manual page.
THIS FILE SYSTEM TYPE IS NOT YET FULLY SUPPORTED (READ: IT DOESN'T WORK) AND USING IT MAY, IN FACT, DESTROY DATA ON YOUR SYSTEM. USE AT YOUR
OWN RISK. BEWARE OF DOG. SLIPPERY WHEN WET. BATTERIES NOT INCLUDED.
This code also needs an owner in order to be less dangerous - serious hackers can apply by sending mail to <freebsd-fs@FreeBSD.org> and
announcing their intent to take it over.
Without whiteout support from the file system backing the upper layer, there is no way that delete and rename operations on lower layer
objects can be done. EOPNOTSUPP is returned for this kind of operations as generated by VOP_WHITEOUT() along with any others which would
make modifications to the lower layer, such as chmod(1).
Running find(1) over a union tree has the side-effect of creating a tree of shadow directories in the upper layer.
The current implementation does not support copying extended attributes for acl(9), mac(9), or so on to the upper layer. Note that this may
be a security issue.
A shadow directory, which is one automatically created in the upper layer when it exists in the lower layer and does not exist in the upper
layer, is always created with the superuser privilege. However, a file copied from the lower layer in the same way is created by the user
who accessed it. Because of this, if the user is not the superuser, even in transparent mode the access mode bits in the copied file in the
upper layer will not always be the same as ones in the lower layer. This behavior should be fixed.
November 30, 2006 BSD