Uniformly refer to a file system as "file system".

Approved by:	re
This commit is contained in:
ru 2002-12-12 17:26:04 +00:00
parent 719bf11717
commit 041d1287e8
173 changed files with 769 additions and 769 deletions

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@ -82,8 +82,8 @@
.Ar ...
.Sh DESCRIPTION
.Nm Amd
is a daemon that automatically mounts filesystems whenever a file or directory
within that filesystem is accessed. Filesystems are automatically unmounted
is a daemon that automatically mounts file systems whenever a file or directory
within that file system is accessed. File systems are automatically unmounted
when they appear to be quiescent.
.Pp
.Nm Amd
@ -97,7 +97,7 @@ are handled by
which uses the map defined by
.Ar mapname
to determine how to resolve the lookup. Generally, this will be a host name,
some filesystem information and some mount options for the given filesystem.
some file system information and some mount options for the given file system.
.Pp
In the first form depicted above,
.Nm amd
@ -171,7 +171,7 @@ to standard output where it can be saved into a file.
.It Fl r
Restart existing mounts.
.Nm Amd
will scan the mount file table to determine which filesystems
will scan the mount file table to determine which file systems
are currently mounted. Whenever one of these would have
been auto-mounted,
.Nm amd
@ -197,7 +197,7 @@ Version. Displays version and configuration information on standard error.
.It Fl w Ar interval
Specify an
.Ar interval ,
in seconds, between attempts to dismount filesystems that have exceeded their
in seconds, between attempts to dismount file systems that have exceeded their
cached times. The default is 2 minutes.
.It Fl x Ar options
Specify run-time logging options. The options are a comma separated list
@ -286,7 +286,7 @@ will not be processed.
.Sh FILES
.Bl -tag -width /axx
.It Pa /.amd_mnt
directory under which filesystems are dynamically mounted
directory under which file systems are dynamically mounted
.It Pa /etc/amd.conf
default configuration file
.El
@ -295,7 +295,7 @@ Some care may be required when creating a mount map.
.Pp
Symbolic links on an
.Tn NFS
filesystem can be incredibly inefficient.
file system can be incredibly inefficient.
In most implementations of
.Tn NFS ,
their interpolations are not cached by

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@ -66,14 +66,14 @@ program.
Communication is by
.Tn RPC .
Three modes of operation are supported by the current protocol.
By default a list of mount points and auto-mounted filesystems
By default a list of mount points and auto-mounted file systems
is output.
An alternative host can be specified using the
.Fl h
option.
.Pp
If directory names are given, as output by default,
then per-filesystem information is displayed.
then per file system information is displayed.
.Sh OPTIONS
.Bl -tag -width Ds
.It Fl f
@ -97,8 +97,8 @@ refresh
open file handle on the log file, so that it can be rotated and compressed via
daily cron jobs.
.It Fl m
Request the automounter to provide a list of mounted filesystems,
including the number of references to each filesystem and any error
Request the automounter to provide a list of mounted file systems,
including the number of references to each file system and any error
which occurred while mounting.
.It Fl p
Return the process ID of the remote or locally running
@ -112,9 +112,9 @@ script.
.It Fl s
Request the automounter to provide system-wide mount statistics.
.It Fl u
Request the automounter to unmount the named filesystems
Request the automounter to unmount the named file systems
instead of providing information about them. Unmounts are requested,
not forced. They merely cause the mounted filesystem to timeout,
not forced. They merely cause the mounted file system to timeout,
which will be picked up by
.Nm amd Ns \'s
main scheduler thus causing the normal timeout action to be taken.

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@ -83,9 +83,9 @@ found. The remote mount table is not changed.
.It Fl A
Issues a command to the remote mountd declaring that
.Em all
of its filesystems have been unmounted. This should be used with caution, as
of its file systems have been unmounted. This should be used with caution, as
it removes all remote mount entries pertaining to the local system, whether or
not any filesystems are still mounted locally.
not any file systems are still mounted locally.
.It Fl v
Be quiet. Suppresses error messages due to timeouts and
.Dq Program not Registered ,
@ -135,7 +135,7 @@ and verifying the resulting path).
Symbolic links on the server will cause the path in the remote entry to differ
from the one in
.Pa /etc/mtab .
To catch those cases, a filesystem is also deemed mounted if its
To catch those cases, a file system is also deemed mounted if its
.Em local
mount point is identical to the remote entry.
I.e., on a SunOS diskless client,

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@ -41,7 +41,7 @@
.Os
.Sh NAME
.Nm fsinfo
.Nd co-ordinate site-wide filesystem information
.Nd co-ordinate site-wide file system information
.Sh SYNOPSIS
.Nm
.Op Fl qv
@ -124,7 +124,7 @@ For each machine defined in the configuration files, a
file is created with the file name determined by prefixing this
.Ar fstabs_prefix
string with the name of the machine. These files contain entries
for filesystems and partitions to mount at boot time.
for file systems and partitions to mount at boot time.
.It Fl h Ar hostname
Defines the hostname of the destination machine to process for.
If this is not specified, it defaults to the local machine name,

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@ -70,7 +70,7 @@
.Op linkname Op subdir
.Sh DESCRIPTION
.Nm
is a daemon which implements a filesystem containing a symbolic link to
is a daemon which implements a file system containing a symbolic link to
subdirectory within a user's home directory, depending on the user
which accessed that link. It was primarily designed to redirect
incoming mail to users' home directories, so that it can read from

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@ -662,7 +662,7 @@ will attempt to unmount all file systems which it knows about. Normally
leaves all
(esp.\&)
.Tn NFS
mounted filesystems intact. Note that
mounted file systems intact. Note that
.Nm amd
does not know about file systems mounted before it starts up, unless the
.Ar restart_mounts

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@ -228,7 +228,7 @@ Begin at
in the archive.
.It Fl l
.It Fl -one-file-system
Stay in local filesystem when creating an archive (do not cross mount
Stay in local file system when creating an archive (do not cross mount
points).
.It Fl L Ar number
.It Fl -tape-length Ar number

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@ -37,7 +37,7 @@
.Os
.Sh NAME
.Nm getvfsbyname
.Nd get information about a filesystem
.Nd get information about a file system
.Sh LIBRARY
.Lb libc
.Sh SYNOPSIS
@ -49,9 +49,9 @@
The
.Fn getvfsbyname
function provides access to information about a
filesystem module that is configured in the kernel.
file system module that is configured in the kernel.
If successful,
the requested filesystem
the requested file system
.Fa xvfsconf
is returned in the location pointed to by
.Fa vfc .
@ -61,11 +61,11 @@ are defined as follows:
.Pp
.Bl -tag -compact -width vfc_refcount
.It vfc_name
the name of the filesystem
the name of the file system
.It vfc_typenum
the filesystem type number assigned by the kernel
the file system type number assigned by the kernel
.It vfc_refcount
the number of active mount points using the filesystem
the number of active mount points using the file system
.It vfc_flags
flag bits, as described below
.El
@ -98,7 +98,7 @@ pointer contains an invalid address.
.It Bq Er ENOENT
The
.Fa name
specifies a filesystem that is unknown or not configured in the kernel.
specifies a file system that is unknown or not configured in the kernel.
.El
.Sh SEE ALSO
.Xr mount 2 ,

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@ -11,7 +11,7 @@
.Nm endvfsent ,
.Nm vfsisloadable ,
.Nm vfsload
.Nd manage virtual filesystem modules
.Nd manage virtual file system modules
.Sh LIBRARY
.Lb libc
.Sh SYNOPSIS
@ -31,21 +31,21 @@
The
.Fn getvfsent
function provides convenient access to a list of installed virtual
filesystem modules managed by the kernel. It steps through the
list of filesystems one at a time. A null pointer is returned when
file system modules managed by the kernel. It steps through the
list of file systems one at a time. A null pointer is returned when
no more data is available. The fields in a
.Dq Li struct ovfsconf
are as follows:
.Pp
.Bl -tag -compact -width vfc_refcount
.It vfc_name
the name of the filesystem
the name of the file system
.It vfc_index
the filesystem type number assigned by the kernel and used in calls to
the file system type number assigned by the kernel and used in calls to
.Xr mount 2
.It vfc_refcount
the number of references to this filesystem
(usually the number of mounts, but one greater for filesystems which
the number of references to this file system
(usually the number of mounts, but one greater for file systems which
cannot be unloaded or which are statically linked into the kernel)
.It vfc_flags
flag bits
@ -72,7 +72,7 @@ The
.Fn setvfsent
and
.Fn endvfsent
functions are used to control caching of the filesystem list, which is
functions are used to control caching of the file system list, which is
obtained in toto from the kernel via
.Xr sysctl 3 .
If the
@ -107,9 +107,9 @@ to succeed.
.Pp
The
.Fn vfsload
function attempts to load a kernel module implementing filesystem
function attempts to load a kernel module implementing file system
.Fa name .
It returns zero if the filesystem module was successfully located and
It returns zero if the file system module was successfully located and
loaded, or non-zero otherwise. It should only be called in the
following circumstances:
.Bl -enum
@ -172,7 +172,7 @@ may be set to one of the values documented for
.Xr mount 8
.Sh AUTHORS
.An -nosplit
The loadable filesystem support was written by
The loadable file system support was written by
.An Garrett A. Wollman ,
based on generic loadable kernel module support by
.An Terry Lambert .

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@ -34,7 +34,7 @@
.Sh NAME
.Nm statvfs ,
.Nm fstatvfs
.Nd retrieve filesystem information
.Nd retrieve file system information
.Sh LIBRARY
.Lb libc
.Sh SYNOPSIS
@ -51,17 +51,17 @@ and
functions fill the structure pointed to by
.Fa buf
with garbage.
This garbage will occasionally bear resemblance to filesystem
This garbage will occasionally bear resemblance to file system
statistics, but portable applications must not depend on this.
Applications must pass a pathname or file descriptor which refers to a
file on the filesystem in which they are interested.
file on the file system in which they are interested.
.Pp
The
.Vt statvfs
structure contains the following members:
.Bl -tag -offset indent -width ".Va f_namemax"
.It Va f_namemax
The maximum length in bytes of a file name on this filesystem.
The maximum length in bytes of a file name on this file system.
Applications should use
.Xr pathconf 3
instead.
@ -69,19 +69,19 @@ instead.
Not meaningful in this implementation.
.It Va f_frsize
The size in bytes of the minimum unit of allocation on this
filesystem.
file system.
(This corresponds to the
.Va f_bsize
member of
.Vt "struct statfs" . )
.It Va f_bsize
The preferred length of I/O requests for files on this filesystem.
The preferred length of I/O requests for files on this file system.
(Corresponds to the
.Va f_iosize
member of
.Vt "struct statfs" . )
.It Va f_flag
Flags describing mount options for this filesystem; see below.
Flags describing mount options for this file system; see below.
.El
.Pp
In addition, there are three members of type
@ -108,14 +108,14 @@ There are two flags defined for the
member:
.Bl -tag -offset indent -width ".Dv ST_NOSUID"
.It Dv ST_RDONLY
The filesystem is mounted read-only.
The file system is mounted read-only.
.It Dv ST_NOSUID
The semantics of the
.Dv S_ISUID
and
.Dv S_ISGID
file mode bits
are not supported by, or are disabled on, this filesystem.
are not supported by, or are disabled on, this file system.
.El
.Sh IMPLEMENTATION NOTES
The
@ -152,7 +152,7 @@ and
functions may also fail for the following reason:
.Bl -tag -width Er
.It Bq Er EOVERFLOW
One or more of the filesystem statistics has a value which cannot be
One or more of the file system statistics has a value which cannot be
represented by the data types used in
.Vt "struct statvfs" .
.El
@ -169,7 +169,7 @@ functions conform to
As standardized, portable applications cannot depend on these functions
returning any valid information at all.
This implementation attempts to provide as much useful information as
is provided by the underlying filesystem, subject to the limitations
is provided by the underlying file system, subject to the limitations
of the specified data types.
.Sh HISTORY
The

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@ -188,7 +188,7 @@ listed here, and described in separate sections below.
.Bl -column CTLXMACHDEPXXX "Next level namesXXXXXX" -offset indent
.It Sy "Name Next level names Description"
.It "CTL\_DEBUG sys/sysctl.h Debugging"
.It "CTL\_VFS sys/mount.h Filesystem"
.It "CTL\_VFS sys/mount.h File system"
.It "CTL\_HW sys/sysctl.h Generic CPU, I/O"
.It "CTL\_KERN sys/sysctl.h High kernel limits"
.It "CTL\_MACHDEP sys/sysctl.h Machine dependent"
@ -251,21 +251,21 @@ struct ctldebug debug5 = { "dospecialcheck", &dospecialcheck };
.Ed
.Ss CTL_VFS
A distinguished second level name, VFS_GENERIC,
is used to get general information about all filesystems.
is used to get general information about all file systems.
One of its third level identifiers is VFS_MAXTYPENUM
that gives the highest valid filesystem type number.
that gives the highest valid file system type number.
Its other third level identifier is VFS_CONF that
returns configuration information about the filesystem
returns configuration information about the file system
type given as a fourth level identifier (see
.Xr getvfsbyname 3
as an example of its use).
The remaining second level identifiers are the
filesystem type number returned by a
file system type number returned by a
.Xr statfs 2
call or from VFS_CONF.
The third level identifiers available for each filesystem
The third level identifiers available for each file system
are given in the header file that defines the mount
argument structure for that filesystem.
argument structure for that file system.
.Ss CTL_HW
The string and integer information available for the CTL_HW level
is detailed below.

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@ -52,7 +52,7 @@ the
function undoes the aforementioned operation,
and converts a human-readable string representing a namespace to a
namespace identifier.
Although a filesystem may implement arbitrary namespaces,
Although a file system may implement arbitrary namespaces,
these functions only support the
.Dv EXTATTR_NAMESPACE_USER
.Pq Dq user

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@ -1426,7 +1426,7 @@ which may be
.Dv RPC_ANYSOCK ,
in which case a new socket is created.
.Fa *path
is a variable-length filesystem pathname of
is a variable-length file system pathname of
at most 104 characters.
This file is
.Em not

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@ -473,7 +473,7 @@ and
functions conform to
.St -isoC .
.Sh HISTORY
The present allocation implementation started out as a filesystem for a
The present allocation implementation started out as a file system for a
drum attached to a 20bit binary challenged computer which was built
with discrete germanium transistors.
It has since graduated to

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@ -112,7 +112,7 @@ The
VM system totally ignores the sticky bit
.Pq Dv ISVTX
for executables.
On UFS-based filesystems (FFS, LFS) the sticky
On UFS-based file systems (FFS, LFS) the sticky
bit may only be set upon directories.
.Pp
If mode
@ -127,7 +127,7 @@ For more details of the properties of the sticky bit, see
.Xr sticky 8 .
.Pp
If mode ISUID (set UID) is set on a directory,
and the MNT_SUIDDIR option was used in the mount of the filesystem,
and the MNT_SUIDDIR option was used in the mount of the file system,
then the owner of any new files and sub-directories
created within this directory are set
to be the same as the owner of that directory.
@ -145,7 +145,7 @@ It provides security holes for shell users and as
such should not be used on shell machines, especially on home directories.
This option requires the SUIDDIR
option in the kernel to work.
Only UFS filesystems support this option.
Only UFS file systems support this option.
For more details of the suiddir mount option, see
.Xr mount 8 .
.Pp

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@ -139,7 +139,7 @@ the namespace in which the extended attribute resides; see
the name of the extended attribute
.El
.Pp
Named extended attribute semantics vary by filesystem implementing the call.
Named extended attribute semantics vary by file system implementing the call.
Not all operations may be supported for a particular attribute.
Additionally, the format of the data in
.Fa data
@ -174,7 +174,7 @@ is set to indicate the error.
.Rv -std extattr_delete_file
.Sh ERRORS
The following errors may be returned by the system calls themselves.
Additionally, the filesystem implementing the call may return any
Additionally, the file system implementing the call may return any
other errors it desires.
.Bl -tag -width Er
.It Bq Er EFAULT

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@ -38,7 +38,7 @@
.Sh NAME
.Nm getdirentries ,
.Nm getdents
.Nd "get directory entries in a filesystem independent format"
.Nd "get directory entries in a file system independent format"
.Sh LIBRARY
.Lb libc
.Sh SYNOPSIS
@ -58,7 +58,7 @@ referenced by the file descriptor
.Fa fd
into the buffer pointed to by
.Fa buf ,
in a filesystem independent format.
in a file system independent format.
Up to
.Fa nbytes
of data will be transferred.
@ -68,7 +68,7 @@ argument must be greater than or equal to the
block size associated with the file,
see
.Xr stat 2 .
Some filesystems may not support these functions
Some file systems may not support these functions
with buffers smaller than this size.
.Pp
The data in the buffer is a series of
@ -85,7 +85,7 @@ char d_name[MAXNAMELEN + 1]; /* see below */
The
.Fa d_fileno
entry is a number which is unique for each
distinct file in the filesystem.
distinct file in the file system.
Files that are linked by hard links (see
.Xr link 2 )
have the same

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@ -37,7 +37,7 @@
.Os
.Sh NAME
.Nm getfsstat
.Nd get list of all mounted filesystems
.Nd get list of all mounted file systems
.Sh LIBRARY
.Lb libc
.Sh SYNOPSIS
@ -48,7 +48,7 @@
.Fn getfsstat "struct statfs *buf" "long bufsize" "int flags"
.Sh DESCRIPTION
.Fn Getfsstat
returns information about all mounted filesystems.
returns information about all mounted file systems.
.Fa Buf
is a pointer to
.Xr statfs
@ -73,53 +73,53 @@ struct statfs {
long f_files; /* total file nodes in file system */
long f_ffree; /* free file nodes in fs */
fsid_t f_fsid; /* file system id */
uid_t f_owner; /* user that mounted the filesystem */
int f_type; /* type of filesystem (see below) */
uid_t f_owner; /* user that mounted the file system */
int f_type; /* type of file system (see below) */
int f_flags; /* copy of mount flags */
long f_spare[2]; /* spare for later */
char f_fstypename[MFSNAMELEN];/* fs type name */
char f_mntonname[MNAMELEN];/* directory on which mounted */
char f_mntfromname[MNAMELEN];/* mounted filesystem */
char f_mntfromname[MNAMELEN];/* mounted file system */
};
.Ed
.Pp
The flags that may be returned include:
.Bl -tag -width MNT_ASYNCHRONOUS
.It Dv MNT_RDONLY
The filesystem is mounted read-only;
The file system is mounted read-only;
Even the super-user may not write on it.
.It Dv MNT_NOEXEC
Files may not be executed from the filesystem.
Files may not be executed from the file system.
.It Dv MNT_NOSUID
Setuid and setgid bits on files are not honored when they are executed.
.It Dv MNT_NODEV
Special files in the filesystem may not be opened.
Special files in the file system may not be opened.
.It Dv MNT_SYNCHRONOUS
All I/O to the filesystem is done synchronously.
All I/O to the file system is done synchronously.
.It Dv MNT_ASYNCHRONOUS
No filesystem I/O is done synchronously.
No file system I/O is done synchronously.
.It Dv MNT_LOCAL
The filesystem resides locally.
The file system resides locally.
.It Dv MNT_QUOTA
The filesystem has quotas enabled on it.
The file system has quotas enabled on it.
.It Dv MNT_ROOTFS
Identifies the root filesystem.
Identifies the root file system.
.It Dv MNT_EXRDONLY
The filesystem is exported read-only.
The file system is exported read-only.
.It Dv MNT_EXPORTED
The filesystem is exported for both reading and writing.
The file system is exported for both reading and writing.
.It Dv MNT_DEFEXPORTED
The filesystem is exported for both reading and writing to any Internet host.
The file system is exported for both reading and writing to any Internet host.
.It Dv MNT_EXPORTANON
The filesystem maps all remote accesses to the anonymous user.
The file system maps all remote accesses to the anonymous user.
.It Dv MNT_EXKERB
The filesystem is exported with Kerberos uid mapping.
The file system is exported with Kerberos uid mapping.
.El
.Pp
Fields that are undefined for a particular filesystem are set to -1.
Fields that are undefined for a particular file system are set to -1.
The buffer is filled with an array of
.Fa fsstat
structures, one for each mounted filesystem
structures, one for each mounted file system
up to the size specified by
.Fa bufsize .
.Pp
@ -127,7 +127,7 @@ If
.Fa buf
is given as NULL,
.Fn getfsstat
returns just the number of mounted filesystems.
returns just the number of mounted file systems.
.Pp
Normally
.Fa flags
@ -139,10 +139,10 @@ is set to
.Dv MNT_NOWAIT ,
.Fn getfsstat
will return the information it has available without requesting
an update from each filesystem.
an update from each file system.
Thus, some of the information will be out of date, but
.Fn getfsstat
will not block waiting for information from a filesystem that is
will not block waiting for information from a file system that is
unable to respond.
.Sh RETURN VALUES
Upon successful completion, the number of
@ -161,7 +161,7 @@ points to an invalid address.
.It Bq Er EIO
An
.Tn I/O
error occurred while reading from or writing to the filesystem.
error occurred while reading from or writing to the file system.
.El
.Sh SEE ALSO
.Xr statfs 2 ,

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@ -394,7 +394,7 @@ was exhausted.
.It Er 70 ESTALE Em "Stale NFS file handle" .
An attempt was made to access an open file (on an
.Tn NFS
filesystem)
file system)
which is now unavailable as referenced by the file descriptor.
This may indicate the file was deleted on the
.Tn NFS
@ -432,11 +432,11 @@ the wrong format.
.It Er 80 EAUTH Em "Authentication error" .
Attempted to use an invalid authentication ticket to mount a
.Tn NFS
filesystem.
file system.
.It Er 81 ENEEDAUTH Em "Need authenticator" .
An authentication ticket must be obtained before the given
.Tn NFS
filesystem may be mounted.
file system may be mounted.
.It Er 82 EIDRM Em "Identifier removed" .
An IPC identifier was removed while the current process was waiting on it.
.It Er 83 ENOMSG Em "No message of desired type" .

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@ -164,5 +164,5 @@ function call appeared in
The
.Fn link
system call traditionally allows the super-user to link directories which
corrupts the filesystem coherency. This implementation no longer permits
corrupts the file system coherency. This implementation no longer permits
it.

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@ -104,8 +104,8 @@ modified again.
.It Dv MADV_NOSYNC
Request that the system not flush the data associated with this map to
physical backing store unless it needs to. Typically this prevents the
filesystem update daemon from gratuitously writing pages dirtied
by the VM system to physical disk. Note that VM/filesystem coherency is
file system update daemon from gratuitously writing pages dirtied
by the VM system to physical disk. Note that VM/file system coherency is
always maintained, this feature simply ensures that the mapped data is
only flush when it needs to be, usually by the system pager.
.Pp

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@ -45,7 +45,7 @@
.Ft int
.Fn mknod "const char *path" "mode_t mode" "dev_t dev"
.Sh DESCRIPTION
The filesystem node
The file system node
.Fa path
is created with the file type and access permissions specified in
.Fa mode .

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@ -145,7 +145,7 @@ this option any VM pages you dirty may be flushed to disk every so often
(every 30-60 seconds usually) which can create performance problems if you
do not need that to occur (such as when you are using shared file-backed
mmap regions for IPC purposes).
Note that VM/filesystem coherency is
Note that VM/file system coherency is
maintained whether you use
.Dv MAP_NOSYNC
or not.
@ -197,9 +197,9 @@ The
.Xr msync 2
system call is obsolete since
.Bx
implements a coherent filesystem buffer cache.
implements a coherent file system buffer cache.
However, it may be
used to associate dirty VM pages with filesystem buffers and thus cause
used to associate dirty VM pages with file system buffers and thus cause
them to be flushed to physical media sooner rather then later.
.It Dv MAP_PRIVATE
Modifications are private.
@ -346,8 +346,8 @@ this gives
.Fx
a maximum of 8TB filesizes.
It is actually bugs in
the filesystem code that causes the limit to be further restricted to
the file system code that causes the limit to be further restricted to
1TB (loss of precision when doing blockno calculations).
.Pp
Another reason for the 2GB limit is that filesystem metadata can
Another reason for the 2GB limit is that file system metadata can
reside at negative offsets.

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@ -38,7 +38,7 @@
.Sh NAME
.Nm mount ,
.Nm unmount
.Nd mount or dismount a filesystem
.Nd mount or dismount a file system
.Sh LIBRARY
.Lb libc
.Sh SYNOPSIS
@ -52,12 +52,12 @@
The
.Fn mount
function grafts
a filesystem object onto the system file tree
a file system object onto the system file tree
at the point
.Ar dir .
The argument
.Ar data
describes the filesystem object to be mounted.
describes the file system object to be mounted.
The argument
.Ar type
tells the kernel how to interpret
@ -65,41 +65,41 @@ tells the kernel how to interpret
(See
.Ar type
below).
The contents of the filesystem
The contents of the file system
become available through the new mount point
.Ar dir .
Any files in
.Ar dir
at the time
of a successful mount are swept under the carpet so to speak, and
are unavailable until the filesystem is unmounted.
are unavailable until the file system is unmounted.
.Pp
The following
.Ar flags
may be specified to
suppress default semantics which affect filesystem access.
suppress default semantics which affect file system access.
.Bl -tag -width MNT_SYNCHRONOUS
.It Dv MNT_RDONLY
The filesystem should be treated as read-only;
The file system should be treated as read-only;
Even the super-user may not write on it.
Specifying MNT_UPDATE without this option will upgrade
a read-only filesystem to read/write.
a read-only file system to read/write.
.It Dv MNT_NOEXEC
Do not allow files to be executed from the filesystem.
Do not allow files to be executed from the file system.
.It Dv MNT_NOSUID
Do not honor setuid or setgid bits on files when executing them.
.It Dv MNT_NOATIME
Disable update of file access times.
.It Dv MNT_NODEV
Do not interpret special files on the filesystem.
Do not interpret special files on the file system.
.It Dv MNT_SUIDDIR
Directories with the SUID bit set chown new files to their own owner.
.It Dv MNT_SYNCHRONOUS
All I/O to the filesystem should be done synchronously.
All I/O to the file system should be done synchronously.
.It Dv MNT_ASYNC
All I/O to the filesystem should be done asynchronously.
All I/O to the file system should be done asynchronously.
.It Dv MNT_FORCE
Force a read-write mount even if the filesystem appears to be unclean.
Force a read-write mount even if the file system appears to be unclean.
Dangerous.
.It Dv MNT_NOCLUSTERR
Disable read clustering.
@ -110,41 +110,41 @@ Disable write clustering.
The flag
.Dv MNT_UPDATE
indicates that the mount command is being applied
to an already mounted filesystem.
to an already mounted file system.
This allows the mount flags to be changed without requiring
that the filesystem be unmounted and remounted.
Some filesystems may not allow all flags to be changed.
that the file system be unmounted and remounted.
Some file systems may not allow all flags to be changed.
For example,
many filesystems will not allow a change from read-write to read-only.
many file systems will not allow a change from read-write to read-only.
.Pp
The flag
.Dv MNT_RELOAD
causes the vfs subsystem to update its data structures pertaining to
the specified already mounted filesystem.
the specified already mounted file system.
.Pp
The
.Fa type
argument names the filesystem.
The types of filesystems known to the system can be obtained with
argument names the file system.
The types of file systems known to the system can be obtained with
.Xr lsvfs 1 .
.Pp
.Fa Data
is a pointer to a structure that contains the type
specific arguments to mount.
The format for these argument structures is described in the
manual page for each filesystem.
By convention filesystem manual pages are named
by prefixing ``mount_'' to the name of the filesystem as returned by
manual page for each file system.
By convention file system manual pages are named
by prefixing ``mount_'' to the name of the file system as returned by
.Xr lsvfs 1 .
Thus the
.Nm NFS
filesystem is described by the
file system is described by the
.Xr mount_nfs 8
manual page.
.Pp
The
.Fn unmount
function call disassociates the filesystem from the specified
function call disassociates the file system from the specified
mount point
.Fa dir .
.Pp
@ -152,12 +152,12 @@ The
.Fa flags
argument may specify
.Dv MNT_FORCE
to specify that the filesystem should be forcibly unmounted or made read-only
to specify that the file system should be forcibly unmounted or made read-only
(if MNT_UPDATE and MNT_RDONLY are also specified)
even if files are still active.
Active special devices continue to work,
but any further accesses to any other active files result in errors
even if the filesystem is later remounted.
even if the file system is later remounted.
.Pp
The
.Dv MNT_SUIDDIR
@ -203,7 +203,7 @@ points outside the process's allocated address space.
.Pp
The following errors can occur for a
.Em ufs
filesystem mount:
file system mount:
.Bl -tag -width Er
.It Bq Er ENODEV
A component of ufs_args
@ -223,11 +223,11 @@ is already mounted.
.It Bq Er EMFILE
No space remains in the mount table.
.It Bq Er EINVAL
The super block for the filesystem had a bad magic
The super block for the file system had a bad magic
number or an out of range block size.
.It Bq Er ENOMEM
Not enough memory was available to read the cylinder
group information for the filesystem.
group information for the file system.
.It Bq Er EIO
An I/O error occurred while reading the super block or
cylinder group information.
@ -238,7 +238,7 @@ points outside the process's allocated address space.
.Pp
The following errors can occur for a
.Em nfs
filesystem mount:
file system mount:
.Bl -tag -width Er
.It Bq Er ETIMEDOUT
.Em Nfs
@ -265,9 +265,9 @@ Too many symbolic links were encountered in translating the pathname.
The requested directory is not in the mount table.
.It Bq Er EBUSY
A process is holding a reference to a file located
on the filesystem.
on the file system.
.It Bq Er EIO
An I/O error occurred while writing cached filesystem information.
An I/O error occurred while writing cached file system information.
.It Bq Er EFAULT
.Fa Dir
points outside the process's allocated address space.
@ -275,7 +275,7 @@ points outside the process's allocated address space.
.Pp
A
.Em ufs
mount can also fail if the maximum number of filesystems are currently
mount can also fail if the maximum number of file systems are currently
mounted.
.Sh SEE ALSO
.Xr lsvfs 1 ,

View File

@ -48,7 +48,7 @@
The
.Fn msync
system call
writes any modified pages back to the filesystem and updates
writes any modified pages back to the file system and updates
the file modification time.
If
.Fa len

View File

@ -151,7 +151,7 @@ for an exclusive lock.
If creating a file with
.Dv O_CREAT ,
the request for the lock will never fail
(provided that the underlying filesystem supports locking).
(provided that the underlying file system supports locking).
.Pp
.Dv O_DIRECT
may be used to minimize or eliminate the cache effects of reading and writing.
@ -243,7 +243,7 @@ operation was interrupted by a signal.
.Dv O_SHLOCK
or
.Dv O_EXLOCK
is specified but the underlying filesystem does not support locking.
is specified but the underlying file system does not support locking.
.It Bq Er EWOULDBLOCK
.Dv O_NONBLOCK
and one of

View File

@ -40,7 +40,7 @@
.Os
.Sh NAME
.Nm quotactl
.Nd manipulate filesystem quotas
.Nd manipulate file system quotas
.Sh LIBRARY
.Lb libc
.Sh SYNOPSIS
@ -52,7 +52,7 @@
The
.Fn quotactl
call enables, disables and
manipulates filesystem quotas.
manipulates file system quotas.
A quota control command
given by
.Fa cmd
@ -71,7 +71,7 @@ is discussed below with each command.
.Pp
Currently quotas are supported only for the
.Dq ufs
filesystem.
file system.
For
.Dq ufs ,
a command is composed of a primary command (see below)
@ -84,7 +84,7 @@ The
specific commands are:
.Bl -tag -width Q_QUOTAOFFxx
.It Dv Q_QUOTAON
Enable disk quotas for the filesystem specified by
Enable disk quotas for the file system specified by
.Fa path .
The command type specifies the type of the quotas being enabled.
The
@ -99,7 +99,7 @@ The
argument is unused.
Only the super-user may turn quotas on.
.It Dv Q_QUOTAOFF
Disable disk quotas for the filesystem specified by
Disable disk quotas for the file system specified by
.Fa path .
The command type specifies the type of the quotas being disabled.
The
@ -170,7 +170,7 @@ In
.Dv Q_GETQUOTA
and
.Dv Q_SETQUOTA ,
quotas are not currently enabled for this filesystem.
quotas are not currently enabled for this file system.
.It Bq Er EACCES
In
.Dv Q_QUOTAON ,
@ -189,7 +189,7 @@ Too many symbolic links were encountered in translating a pathname.
.It Bq Er EROFS
In
.Dv Q_QUOTAON ,
the quota file resides on a read-only filesystem.
the quota file resides on a read-only file system.
.It Bq Er EIO
An
.Tn I/O

View File

@ -51,7 +51,7 @@
.Fn Statfs
returns information about a mounted file system.
.Fa Path
is the path name of any file within the mounted filesystem.
is the path name of any file within the mounted file system.
.Fa Buf
is a pointer to a
.Fn statfs
@ -75,8 +75,8 @@ long f_bavail; /* free blocks avail to non-superuser */
long f_files; /* total file nodes in file system */
long f_ffree; /* free file nodes in fs */
fsid_t f_fsid; /* file system id */
uid_t f_owner; /* user that mounted the filesystem */
int f_type; /* type of filesystem */
uid_t f_owner; /* user that mounted the file system */
int f_type; /* type of file system */
int f_flags; /* copy of mount flags */
long f_syncwrites; /* count of sync writes since mount */
long f_asyncwrites; /* count of async writes since mount */
@ -84,40 +84,40 @@ char f_fstypename[MFSNAMELEN];/* fs type name */
char f_mntonname[MNAMELEN]; /* mount point */
long f_syncreads; /* count of sync reads since mount */
long f_asyncreads; /* count of async reads since mount */
char f_mntfromname[MNAMELEN]; /* mounted filesystem */
char f_mntfromname[MNAMELEN]; /* mounted file system */
};
.Ed
The flags that may be returned include:
.Bl -tag -width MNT_SYNCHRONOUS
.It Dv MNT_RDONLY
The filesystem is mounted read-only;
The file system is mounted read-only;
Even the super-user may not write on it.
.It Dv MNT_NOEXEC
Files may not be executed from the filesystem.
Files may not be executed from the file system.
.It Dv MNT_NOSUID
Setuid and setgid bits on files are not honored when they are executed.
.It Dv MNT_NODEV
Special files in the filesystem may not be opened.
Special files in the file system may not be opened.
.It Dv MNT_SYNCHRONOUS
All I/O to the filesystem is done synchronously.
All I/O to the file system is done synchronously.
.It Dv MNT_ASYNC
No filesystem I/O is done synchronously.
No file system I/O is done synchronously.
.It Dv MNT_LOCAL
The filesystem resides locally.
The file system resides locally.
.It Dv MNT_QUOTA
The filesystem has quotas enabled on it.
The file system has quotas enabled on it.
.It Dv MNT_ROOTFS
Identifies the root filesystem.
Identifies the root file system.
.It Dv MNT_EXRDONLY
The filesystem is exported read-only.
The file system is exported read-only.
.It Dv MNT_EXPORTED
The filesystem is exported for both reading and writing.
The file system is exported for both reading and writing.
.It Dv MNT_DEFEXPORTED
The filesystem is exported for both reading and writing to any Internet host.
The file system is exported for both reading and writing to any Internet host.
.It Dv MNT_EXPORTANON
The filesystem maps all remote accesses to the anonymous user.
The file system maps all remote accesses to the anonymous user.
.It Dv MNT_EXKERB
The filesystem is exported with Kerberos uid mapping.
The file system is exported with Kerberos uid mapping.
.El
.Pp
Fields that are undefined for a particular file system are set to -1.

View File

@ -37,7 +37,7 @@
.Os
.Sh NAME
.Nm sync
.Nd "schedule filesystem updates"
.Nd "schedule file system updates"
.Sh LIBRARY
.Lb libc
.Sh SYNOPSIS

View File

@ -51,15 +51,15 @@ The
function attempts to recover the deleted file named by
.Fa path .
Currently, this works only when the named object
is a whiteout in a union filesystem.
is a whiteout in a union file system.
The system call removes the whiteout causing
any objects in a lower layer of the
union stack to become visible once more.
.Pp
Eventually, the
.Fn undelete
functionality may be expanded to other filesystems able to recover
deleted files such as the log-structured filesystem.
functionality may be expanded to other file systems able to recover
deleted files such as the log-structured file system.
.Sh RETURN VALUES
.Rv -std undelete
.Sh ERRORS

View File

@ -114,5 +114,5 @@ function call appeared in
The
.Fn unlink
system call traditionally allows the super-user to unlink directories which
can damage the filesystem integrity. This implementation no longer permits
can damage the file system integrity. This implementation no longer permits
it.

View File

@ -75,7 +75,7 @@ is
it is assumed to point to an array of two timeval structures.
The access time is set to the value of the first element, and the
modification time is set to the value of the second element.
For filesystems that support file birth (creation) times (such as
For file systems that support file birth (creation) times (such as
.Dv UFS2 ) ,
the birth time will be set to the value of the second element
if the second element is older than the currently set birth time.

View File

@ -357,7 +357,7 @@ Similar to the behaviour as specified in
except that file creation is not supported, so the mode parameter is not
required. The
.Fa flags
argument may be one of O_RDONLY, O_WRONLY and O_RDWR (although no filesystems
argument may be one of O_RDONLY, O_WRONLY and O_RDWR (although no file systems
currently support writing).
.It Xo
.Ft int
@ -378,7 +378,7 @@ Close all open files.
.Fn write "int fd" "void *buf" "size_t len"
.Xc
.Pp
(No filesystems currently support writing.)
(No file systems currently support writing.)
.It Xo
.Ft off_t
.Fn lseek "int fd" "off_t offset" "int whence"
@ -403,9 +403,9 @@ functions only fill out the following fields in the
.Fa sb
structure: st_mode,st_nlink,st_uid,st_gid,st_size. The
.Nm tftp
filesystem cannot provide meaningful values for this call, and the
file system cannot provide meaningful values for this call, and the
.Nm cd9660
filesystem always reports files having uid/gid of zero.
file system always reports files having uid/gid of zero.
.El
.Sh PAGER
.Nm
@ -466,7 +466,7 @@ The following resources are consumed by
The stack must be established before
.Nm
functions can be invoked. Stack requirements vary depending on the functions
and filesystems used by the consumer and the support layer functions detailed
and file systems used by the consumer and the support layer functions detailed
below.
.Pp
The heap must be established before calling
@ -567,36 +567,36 @@ Signal a fatal and unrecoverable error condition. The
arguments are as for
.Fn printf .
.El
.Sh INTERNAL FILESYSTEMS
Internal filesystems are enabled by the consumer exporting the array
.Sh INTERNAL FILE SYSTEMS
Internal file systems are enabled by the consumer exporting the array
.Vt struct fs_ops *file_system[] ,
which should be initialised with pointers
to
.Vt struct fs_ops
structures. The following filesystem handlers are supplied by
structures. The following file system handlers are supplied by
.Nm ,
the consumer may supply other filesystems of their own:
the consumer may supply other file systems of their own:
.Bl -hang -width ".Va cd9660_fsops"
.It Va ufs_fsops
The
.Bx
UFS.
.It Va ext2fs_fsops
Linux ext2fs filesystem.
Linux ext2fs file system.
.It Va tftp_fsops
File access via TFTP.
.It Va nfs_fsops
File access via NFS.
.It Va cd9660_fsops
ISO 9660 (CD-ROM) filesystem.
ISO 9660 (CD-ROM) file system.
.It Va zipfs_fsops
Stacked filesystem supporting gzipped files.
When trying the zipfs filesystem,
Stacked file system supporting gzipped files.
When trying the zipfs file system,
.Nm
appends
.Li .gz
to the end of the filename, and then tries to locate the file using the other
filesystems. Placement of this filesystem in the
file systems. Placement of this file system in the
.Va file_system[]
array determines whether gzipped files will be opened in preference to non-gzipped
files. It is only possible to seek a gzipped file forwards, and

View File

@ -42,11 +42,11 @@ The
.Nm
utility is a
.Xr rpc 3
server which returns quotas for a user of a local filesystem
server which returns quotas for a user of a local file system
which is NFS-mounted onto a remote machine.
The
.Xr quota 1
utility uses the results to display user quotas for remote filesystems.
utility uses the results to display user quotas for remote file systems.
The
.Nm
utility is normally invoked by

View File

@ -87,7 +87,7 @@ routine is called. Thus,
can complete the link-editing process before the dynamic program calls upon
services of any dynamic library.
.Pp
To quickly locate the required shared objects in the filesystem,
To quickly locate the required shared objects in the file system,
.Nm
may use a
.Dq hints
@ -204,7 +204,7 @@ are recognized and have their usual meaning.
.\" .It Ev LD_NOSTD_PATH
.\" When set, do not include a set of built-in standard directory paths for
.\" searching. This might be useful when running on a system with a completely
.\" non-standard filesystem layout.
.\" non-standard file system layout.
.El
.Pp
.Sh FILES

View File

@ -67,7 +67,7 @@ After the dynamic linker has finished loading,
relocating, and initializing the program and its required shared
objects, it transfers control to the entry point of the program.
.Pp
To locate the required shared objects in the filesystem,
To locate the required shared objects in the file system,
.Nm
may use a
.Dq hints

View File

@ -243,7 +243,7 @@ The
flag allows you to specify an alternate path should you wish to
store your
.Tn NIS
maps in a different part of the filesystem. The
maps in a different part of the file system. The
.Tn NIS
server,
.Xr ypserv 8 ,

View File

@ -287,7 +287,7 @@ static char *dktypenames[] = {
#endif
/*
* Filesystem type and version.
* File system type and version.
* Used to interpret other file system-specific
* per-partition information.
*/

View File

@ -287,7 +287,7 @@ static char *dktypenames[] = {
#endif
/*
* Filesystem type and version.
* File system type and version.
* Used to interpret other file system-specific
* per-partition information.
*/

View File

@ -197,10 +197,10 @@ was compiled.)
.It Fl L
This option is to notify
.Nm
that it is dumping a live filesystem.
that it is dumping a live file system.
To obtain a consistent dump image,
.Nm
takes a snapshot of the filesystem and
takes a snapshot of the file system and
then does a dump of the snapshot.
The snapshot is removed when the dump is complete.
.It Fl n

View File

@ -88,7 +88,7 @@ that are mounted
or
.Dq ro
and that have non-zero pass number are checked.
Filesystems with pass number 1 (normally just the root file system)
File systems with pass number 1 (normally just the root file system)
are always checked one at a time.
.Pp
If not in preen mode, the remaining entries are checked in order of

View File

@ -53,7 +53,7 @@ The specified disk partitions and/or file systems are checked.
In "preen" mode the clean flag of each file system's superblock is examined
and only those file systems that
are not marked clean are checked.
Filesystems are marked clean when they are unmounted,
File systems are marked clean when they are unmounted,
when they have been mounted read-only, or when
.Nm
runs on them successfully.

View File

@ -58,7 +58,7 @@ Before starting
.Nm
the disk must be labeled to a bigger size using
.Xr disklabel 8 .
If you wish to grow a filesystem beyond the boundary of
If you wish to grow a file system beyond the boundary of
the slice it resides in, you must re-size the slice using
.Xr fdisk 8
before running

View File

@ -230,7 +230,7 @@ is that vnode arguments must be manually mapped.
UCLA Technical Report CSD-910056,
.Em "Stackable Layers: an Architecture for File System Development" .
.Sh BUGS
THIS FILESYSTEM TYPE IS NOT YET FULLY SUPPORTED (READ: IT DOESN'T WORK)
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.
.Pp

View File

@ -125,7 +125,7 @@ sophisticated.
.Xr mount 8 ,
.Xr mount_nullfs 8
.Sh BUGS
THIS FILESYSTEM TYPE IS NOT YET FULLY SUPPORTED (READ: IT DOESN'T WORK)
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.
.Pp

View File

@ -182,7 +182,7 @@ accessible via
.Xr mount 8 ,
.Xr mount_nullfs 8
.Sh BUGS
THIS FILESYSTEM TYPE IS NOT YET FULLY SUPPORTED (READ: IT DOESN'T WORK)
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.
.Pp

View File

@ -146,7 +146,7 @@ as a hot spare for the device
Make the RAID set auto-configurable. The RAID set will be
automatically configured at boot
.Ar before
the root filesystem is
the root file system is
mounted. Note that all components of the set must be of type RAID in the
disklabel.
.It Fl A Ic no Ar dev
@ -195,7 +195,7 @@ the selected device. This
be done for
.Ar all
RAID sets before the RAID device is labeled and before
filesystems are created on the RAID device.
file systems are created on the RAID device.
.It Fl I Ar serial_number Ar dev
Initialize the component labels on each component of the device.
.Ar serial_number
@ -394,7 +394,7 @@ for a more complete configuration file example.
.Sh EXAMPLES
It is highly recommended that before using the RAID driver for real
filesystems that the system administrator(s) become quite familiar
file systems that the system administrator(s) become quite familiar
with the use of
.Nm ,
and that they understand how the component reconstruction process
@ -622,7 +622,7 @@ it is then safe to perform
.Xr newfs 8 ,
or
.Xr fsck 8
on the device or its filesystems, and then to mount the filesystems
on the device or its file systems, and then to mount the file systems
for use.
.Pp
Under certain circumstances (e.g. the additional component has not
@ -680,7 +680,7 @@ raidctl -P raid0
is used. Note that re-writing the parity can be done while
other operations on the RAID set are taking place (e.g. while doing a
.Xr fsck 8
on a filesystem on the RAID set). However: for maximum effectiveness
on a file system on the RAID set). However: for maximum effectiveness
of the RAID set, the parity should be known to be correct before any
data on the set is modified.
.Pp
@ -734,7 +734,7 @@ are the component lines which read
and the
.Sq Parity status
line which indicates that the parity is up-to-date. Note that if
there are filesystems open on the RAID set, the individual components
there are file systems open on the RAID set, the individual components
will not be
.Sq clean
but the set as a whole can still be clean.
@ -995,19 +995,19 @@ raidctl -A no raid0
.Ed
.Pp
RAID sets which are auto-configurable will be configured before the
root filesystem is mounted. These RAID sets are thus available for
use as a root filesystem, or for any other filesystem. A primary
root file system is mounted. These RAID sets are thus available for
use as a root file system, or for any other file system. A primary
advantage of using the auto-configuration is that RAID components
become more independent of the disks they reside on. For example,
SCSI ID's can change, but auto-configured sets will always be
configured correctly, even if the SCSI ID's of the component disks
have become scrambled.
.Pp
Having a system's root filesystem (/) on a RAID set is also allowed,
Having a system's root file system (/) on a RAID set is also allowed,
with the
.Sq a
partition of such a RAID set being used for /.
To use raid0a as the root filesystem, simply use:
To use raid0a as the root file system, simply use:
.Bd -unfilled -offset indent
raidctl -A root raid0
.Ed
@ -1019,9 +1019,9 @@ arguments.
Note that kernels can only be directly read from RAID 1 components on
alpha and pmax architectures. On those architectures, the
.Dv FS_RAID
filesystem is recognized by the bootblocks, and will properly load the
file system is recognized by the bootblocks, and will properly load the
kernel directly from a RAID 1 component. For other architectures, or
to support the root filesystem on other RAID sets, some other
to support the root file system on other RAID sets, some other
mechanism must be used to get a kernel booting. For example, a small
partition containing only the secondary boot-blocks and an alternate
kernel (or two) could be used. Once a kernel is booting however, and
@ -1039,7 +1039,7 @@ NetBSD installation.
.It
wd1a - also contains a complete, bootable, basic NetBSD installation.
.It
wd0e and wd1e - a RAID 1 set, raid0, used for the root filesystem.
wd0e and wd1e - a RAID 1 set, raid0, used for the root file system.
.It
wd0f and wd1f - a RAID 1 set, raid1, which will be used only for
swap space.
@ -1051,7 +1051,7 @@ wd0h and wd0h - a RAID 1 set, raid3, if desired.
.El
.Pp
RAID sets raid0, raid1, and raid2 are all marked as
auto-configurable. raid0 is marked as being a root filesystem.
auto-configurable. raid0 is marked as being a root file system.
When new kernels are installed, the kernel is not only copied to /,
but also to wd0a and wd1a. The kernel on wd0a is required, since that
is the kernel the system boots from. The kernel on wd1a is also
@ -1059,9 +1059,9 @@ required, since that will be the kernel used should wd0 fail. The
important point here is to have redundant copies of the kernel
available, in the event that one of the drives fail.
.Pp
There is no requirement that the root filesystem be on the same disk
There is no requirement that the root file system be on the same disk
as the kernel. For example, obtaining the kernel from wd0a, and using
da0s1e and da1s1e for raid0, and the root filesystem, is fine. It
da0s1e and da1s1e for raid0, and the root file system, is fine. It
.Ar is
critical, however, that there be multiple kernels available, in the
event of media failure.
@ -1110,7 +1110,7 @@ Distribution of components among controllers
.It
IO bandwidth
.It
Filesystem access patterns
File system access patterns
.It
CPU speed
.El
@ -1155,7 +1155,7 @@ problem in the real world, it may be useful to ensure that stripe
sizes are small enough that a
.Sq large IO
from the system will use exactly one large stripe write. As is seen
later, there are some filesystem dependencies which may come into play
later, there are some file system dependencies which may come into play
here as well.
.Pp
Since the size of a
@ -1167,13 +1167,13 @@ data per stripe is 64 blocks (32K) or 128 blocks (64K). Again,
empirical measurement will provide the best indicators of which
values will yeild better performance.
.Pp
The parameters used for the filesystem are also critical to good
The parameters used for the file system are also critical to good
performance. For
.Xr newfs 8 ,
for example, increasing the block size to 32K or 64K may improve
performance dramatically. As well, changing the cylinders-per-group
parameter from 16 to 32 or higher is often not only necessary for
larger filesystems, but may also have positive performance
larger file systems, but may also have positive performance
implications.
.Pp
.Ss Summary
@ -1225,13 +1225,13 @@ disklabel -R -r raid0 /tmp/label
.Ed
.Pp
.It
Create the filesystem:
Create the file system:
.Bd -unfilled -offset indent
newfs /dev/rraid0e
.Ed
.Pp
.It
Mount the filesystem:
Mount the file system:
.Bd -unfilled -offset indent
mount /dev/raid0e /mnt
.Ed
@ -1251,7 +1251,7 @@ the /etc/rc scripts.
Certain RAID levels (1, 4, 5, 6, and others) can protect against some
data loss due to component failure. However the loss of two
components of a RAID 4 or 5 system, or the loss of a single component
of a RAID 0 system will result in the entire filesystem being lost.
of a RAID 0 system will result in the entire file system being lost.
RAID is
.Ar NOT
a substitute for good backup practices.

View File

@ -120,6 +120,6 @@ code is implemented in the
It is not the most throughly tested code.
It is also my first attempt to write in Forth.
.Pp
Finally, it does some evil things like writing to the filesystem before it
Finally, it does some evil things like writing to the file system before it
has been checked.
If it scrambles your filesystem, do not blame me.
If it scrambles your file system, do not blame me.

View File

@ -104,7 +104,7 @@ The remote system returned something that was
during a protocol exchange.
.It Sy EX_NOPERM Pq 77
You did not have sufficient permission to perform the operation. This
is not intended for filesystem problems, which should use
is not intended for file system problems, which should use
.Sy EX_NOINPUT
or
.Sy EX_CANTCREAT ,

View File

@ -175,7 +175,7 @@ Note that a one-disk
.Nm
is not the same as the original partition.
In particular, this means
if you have a filesystem on a two-disk mirrored
if you have a file system on a two-disk mirrored
.Nm
and one of the disks fail, you cannot mount and use the remaining
partition as itself; you have to configure it as a one-disk
@ -188,7 +188,7 @@ then restoring the partition.
If just one (or more) of the disks in a
.Nm
fails, the entire
filesystem will be lost unless you are mirroring the disks.
file system will be lost unless you are mirroring the disks.
.Pp
If one of the disks in a mirror is lost, you should still
be able to back up your data.

View File

@ -67,7 +67,7 @@ partitioning scheme,
.Xr disklabel 5 ,
which is used to subdivide the
.Fx
slices into areas for individual filesystems and swap spaces.
slices into areas for individual file systems and swap spaces.
For more information, see
.Xr fdisk 8
and
@ -105,7 +105,7 @@ and allows the device to reorganize writes to increase efficiency and
performance. This performance gain comes at a price. Should the device
lose power while its cache contains uncommitted write operations, these
writes will be lost. The effect of a loss of write transactions on
a filesystem is non-deterministic and can cause corruption. Most
a file system is non-deterministic and can cause corruption. Most
devices age write transactions to limit vulnerability to a few transactions
recently reported as complete, but it is none-the-less recommended that
systems with write cache enabled devices reside on an Uninterruptible

View File

@ -225,7 +225,7 @@ some kind of structure or identifying byte sequences.
.Pp
Certain file formats like ELF contain multiple distinct sections, and it
would be possible to locate things just right in such a way that a device
contains a partition with a filesystem with a large executable,
contains a partition with a file system with a large executable,
.Pq Dq "a backup copy of my kernel"
where a non-loaded ELF section is laid out
consecutively on the device and thereby could be used to contain a

View File

@ -236,7 +236,7 @@ to be instantiated between a consumer and a provider attached to
each other and to remove it again.
.Pp
To understand the utility of this, imagine a provider with
being mounted as a filesystem.
being mounted as a file system.
Between the DEVFS geoms consumer and its provider we insert
a mirror module which configures itself with one mirror
copy and consequently is transparent to the I/O requests
@ -244,7 +244,7 @@ on the path.
We can now configure yet a mirror copy on the mirror geom,
request a synchronization, and finally drop the first mirror
copy.
We have now in essence moved a mounted filesystem from one
We have now in essence moved a mounted file system from one
disk to another while it was being used.
At this point the mirror geom can be deleted from the path
again, it has served its purpose.

View File

@ -71,7 +71,7 @@ sometimes also called
.Em special files .
They are usually located under the directory
.Pa /dev
in the filesystem hierarchy
in the file system hierarchy
(see also
.Xr hier 7 ) .
.Pp
@ -106,7 +106,7 @@ and
as the file type identification in the output of
.Ql ls -l .
Buffered devices are being accessed through the buffer cache of the
operating system, and they are solely intended to layer a filesystem
operating system, and they are solely intended to layer a file system
on top of them. They are normally implemented for disks and disk-like
devices only and, for historical reasons, for tape devices.
.Pp
@ -121,7 +121,7 @@ denotes the raw device for the first SCSI disk, while
is the corresponding device node for the buffered device.
.Pp
Unbuffered devices should be used for all actions that are not related
to filesystem operations, even if the device in question is a disk
to file system operations, even if the device in question is a disk
device. This includes making backups of entire disk partitions, or
to
.Em raw

View File

@ -52,7 +52,7 @@ unloading.
The
.Fx
system makes extensive use of loadable kernel modules, and provides loadable
versions of most filesystems, the
versions of most file systems, the
.Tn NFS
client and server, all the screen-savers, and the
.Tn iBCS2

View File

@ -61,7 +61,7 @@ or
.Dq low
security level, attached to it,
and these labels of integrity will be managed with a system cognizant
of IPC (signals, debugging, sockets, pipes), path-based filesystem
of IPC (signals, debugging, sockets, pipes), path-based file system
labels, virtual memory objects, and privileged system calls.
A process (or set of vmspace-sharing processes) will initially inherit
the integrity level of its parent, which, at the point of
@ -84,8 +84,8 @@ operation performed after it has been initialized.
Pre-existing jail or chroot environments may not necessarily work
completely.
.Nm Ns 's
filesystem should correctly respect the caching behavior of any of the
system's filesystems, and so work for any
file system should correctly respect the caching behavior of any of the
system's file systems, and so work for any
.Dq normal
or
.Dq synthetic
@ -99,7 +99,7 @@ See
.Pa /sys/security/lomac/policy_plm.h
for specific information on exactly how
.Nm
has been compiled to control access to the filesystem.
has been compiled to control access to the file system.
.Sh COMPATIBILITY
Some programs, for example
.Xr syslogd 8 ,

View File

@ -113,7 +113,7 @@ or loaded as a module.
.It Pa /compat/linux
minimal Linux run-time environment
.It Pa /compat/linux/proc
limited Linux process filesystem
limited Linux process file system
.El
.Sh SEE ALSO
.Xr brandelf 1 ,

View File

@ -113,7 +113,7 @@ or loaded as a module.
.It Pa /compat/linux
minimal Linux run-time environment
.It Pa /compat/linux/proc
limited Linux process filesystem
limited Linux process file system
.El
.Sh SEE ALSO
.Xr brandelf 1 ,

View File

@ -132,7 +132,7 @@ accesses
.Bx
partition on the disc.
Normally, there is only
one filesystem on a CD-ROM disc.
one file system on a CD-ROM disc.
.It Pa /dev/(r)mcd0c
accesses raw device.
.El

View File

@ -52,7 +52,7 @@ accesses
.Bx
partition on the disc.
Normally, there is only
one filesystem on a CDROM disc.
one file system on a CDROM disc.
.It Pa /dev/[r]scd0c
accesses the raw device.
.El

View File

@ -44,7 +44,7 @@ For backwards compatibility the type
is also recognized.
If the kernel is created with option
.Dv MD_ROOT
the first preloaded image found will become the root filesystem.
the first preloaded image found will become the root file system.
.It Cm vnode
A regular file is used as backing store.
This allows for mounting ISO images without the tedious

View File

@ -136,21 +136,21 @@ will configure normally.
Component labels are also used to support the auto-detection and
auto-configuration of RAID sets. A RAID set can be flagged as
auto-configurable, in which case it will be configured automatically
during the kernel boot process. RAID filesystems which are
automatically configured are also eligible to be the root filesystem.
during the kernel boot process. RAID file systems which are
automatically configured are also eligible to be the root file system.
There is currently only limited support (alpha and pmax architectures)
for booting a kernel directly from a RAID 1 set, and no support for
booting from any other RAID sets. To use a RAID set as the root
filesystem, a kernel is usually obtained from a small non-RAID
file system, a kernel is usually obtained from a small non-RAID
partition, after which any auto-configuring RAID set can be used for the
root filesystem. See
root file system. See
.Xr raidctl 8
for more information on auto-configuration of RAID sets.
.Pp
The driver supports
.Sq hot spares ,
disks which are on-line, but are not
actively used in an existing filesystem. Should a disk fail, the
actively used in an existing file system. Should a disk fail, the
driver is capable of reconstructing the failed disk onto a hot spare
or back onto a replacement drive.
If the components are hot swapable, the failed disk can then be
@ -185,10 +185,10 @@ before doing a
.Xr fsck 8
or a
.Xr newfs 8 ,
filesystem integrity and parity integrity can be ensured. It bears
file system integrity and parity integrity can be ensured. It bears
repeating again that parity recomputation is
.Ar required
before any filesystems are created or used on the RAID device. If the
before any file systems are created or used on the RAID device. If the
parity is not correct, then missing data cannot be correctly recovered.
.Pp
RAID levels may be combined in a hierarchical fashion. For example, a RAID 0
@ -259,7 +259,7 @@ result in data loss.
Certain RAID levels (1, 4, 5, 6, and others) can protect against some
data loss due to component failure. However the loss of two
components of a RAID 4 or 5 system, or the loss of a single component
of a RAID 0 system, will result in the entire filesystems on that RAID
of a RAID 0 system, will result in the entire file systems on that RAID
device being lost.
RAID is
.Ar NOT

View File

@ -29,14 +29,14 @@
.Os
.Sh NAME
.Nm syncer
.Nd filesystem synchronizer kernel process
.Nd file system synchronizer kernel process
.Sh SYNOPSIS
.Nm
.Sh DESCRIPTION
The
.Nm
kernel process helps protect the integrity of disk volumes
by flushing volatile cached filesystem data to disk.
by flushing volatile cached file system data to disk.
.Pp
The kernel places all
.Xr vnode 9 Ns 's
@ -87,5 +87,5 @@ process first appeared in
It is possible on some systems that a
.Xr sync 2
occurring simultaneously with a crash may cause
filesystem damage. See
file system damage. See
.Xr fsck 8 .

View File

@ -98,11 +98,11 @@ Write a disklabel to the Zip drive (see
.Nm vpo
for the
.Nm disktab
entry), creates the filesystem and mounts the new filesystem on /mnt.
entry), creates the file system and mounts the new file system on /mnt.
.Pp
.Dl newfs_msdos /dev/da0
.Pp
Create a new FAT type filesystem.
Create a new FAT type file system.
.Sh SEE ALSO
.Xr ohci 4 ,
.Xr uhci 4 ,

View File

@ -56,10 +56,10 @@ family supports the
and
.Dv SOCK_DGRAM
socket types and uses
filesystem pathnames for addressing.
file system pathnames for addressing.
.Sh ADDRESSING
.Ux Ns -domain
addresses are variable-length filesystem pathnames of
addresses are variable-length file system pathnames of
at most 104 characters.
The include file
.Aq Pa sys/un.h
@ -76,7 +76,7 @@ Binding a name to a
.Ux Ns -domain
socket with
.Xr bind 2
causes a socket file to be created in the filesystem.
causes a socket file to be created in the file system.
This file is
.Em not
removed when the socket is closed \(em
@ -93,7 +93,7 @@ All addresses are absolute- or relative-pathnames
of other
.Ux Ns -domain
sockets.
Normal filesystem access-control mechanisms are also
Normal file system access-control mechanisms are also
applied when referencing pathnames; e.g., the destination
of a
.Xr connect 2

View File

@ -85,10 +85,10 @@ By attaching an
additional plex and subsequently detaching one of the older plexes, data can be
moved on-line without compromising access.
.It
An additional plex can be used to obtain a consistent dump of a filesystem.
An additional plex can be used to obtain a consistent dump of a file system.
By
attaching an additional plex and detaching at a specific time, the detached plex
becomes an accurate snapshot of the filesystem at the time of detachment.
becomes an accurate snapshot of the file system at the time of detachment.
.\" Make sure to flush!
.El
.It
@ -163,7 +163,7 @@ devices.
offers automatic startup.
Unlike
.Ux
filesystems,
file systems,
.Nm
volumes contain all the configuration information needed to ensure that they are
started correctly when the subsystem is enabled.
@ -385,7 +385,7 @@ flag to
.Xr newfs 8 .
For example, if you have a volume
.Pa concat ,
use the following command to create a UFS filesystem on it:
use the following command to create a UFS file system on it:
.Pp
.Dl "newfs -v /dev/vinum/concat"
.Sh OBJECT NAMING

View File

@ -51,11 +51,11 @@ transferring data.
.Pp
DOS and
.Fx
filesystems are supported.
When mounting a DOS filesystem or
file systems are supported.
When mounting a DOS file system or
formating a
.Fx
filesystem, check the slice of the disk with the
file system, check the slice of the disk with the
.Xr fdisk 8
utility.
.Pp

View File

@ -43,18 +43,18 @@
.Os
.Sh NAME
.Nm devfs
.Nd device filesystem
.Nd device file system
.Sh SYNOPSIS
devfs /dev devfs rw 0 0
.Sh DESCRIPTION
The device filesystem, or
The device file system, or
.Nm ,
provides access to kernel's device
namespace in the global filesystem namespace.
namespace in the global file system namespace.
The conventional mount point is
.Pa /dev .
.Pp
The filesystem includes several directories, links, symbolic links
The file system includes several directories, links, symbolic links
and devices, some of which can also be written. In a chroot'ed
environment,
.Nm
@ -73,7 +73,7 @@ mount point.
.Sh HISTORY
The
.Nm
filesystem first appeared in
file system first appeared in
.Fx 2.0 .
The
.Nm

View File

@ -54,7 +54,7 @@ Directory entries may contain other directories
as well as plain files; such nested directories are referred to as
subdirectories.
A hierarchy of directories and files is formed in this manner
and is called a filesystem (or referred to as a filesystem tree).
and is called a file system (or referred to as a file system tree).
.\" An entry in this tree,
.\" nested or not nested,
.\" is a pathname.
@ -72,7 +72,7 @@ the system root directory
has no parent and dot-dot points to itself like dot.
.Pp
File system nodes are ordinary directory files on which has
been grafted a filesystem object, such as a physical disk or a
been grafted a file system object, such as a physical disk or a
partitioned area of such a disk.
(See
.Xr mount 2
@ -152,7 +152,7 @@ struct dirent {
.Sh BUGS
The usage of the member d_type of struct dirent is unportable as it is
.Fx Ns -specific .
It also may fail on certain filesystems, for example the cd9660 filesystem.
It also may fail on certain file systems, for example the cd9660 file system.
.Sh HISTORY
A
.Nm

View File

@ -118,7 +118,7 @@ default
.It "\&ph num Size of partition `h' in sectors"
.It "\&ta str Partition type of partition `a'"
.Pf ( Bx 4.2
filesystem, swap, etc)
file system, swap, etc)
.It "\&tb str Partition type of partition `b'"
.It "\&tc str Partition type of partition `c'"
.It "\&td str Partition type of partition `d'"

View File

@ -43,18 +43,18 @@
.Os
.Sh NAME
.Nm fdescfs
.Nd file-descriptor filesystem
.Nd file-descriptor file system
.Sh SYNOPSIS
fdescfs /dev/fd fdescfs rw 0 0
.Sh DESCRIPTION
The file-descriptor filesystem, or
The file-descriptor file system, or
.Nm ,
provides access to the per-process file descriptor
namespace in the global filesystem namespace.
namespace in the global file system namespace.
The conventional mount point is
.Pa /dev/fd .
.Pp
The filesystem's contents
The file system's contents
appear as a list of numbered files
which correspond to the open files of the process reading the
directory.
@ -95,7 +95,7 @@ are ignored.
.Sh HISTORY
The
.Nm
filesystem first appeared in
file system first appeared in
.Bx 4.4 .
The
.Nm

View File

@ -38,7 +38,7 @@
.Sh NAME
.Nm fs ,
.Nm inode
.Nd format of filesystem volume
.Nd format of file system volume
.Sh SYNOPSIS
.In sys/param.h
.In ufs/ffs/fs.h
@ -54,10 +54,10 @@ and
.Aq Pa inode.h
declare several structures, defined variables and macros
which are used to create and manage the underlying format of
filesystem objects on random access devices (disks).
file system objects on random access devices (disks).
.Pp
The block size and number of blocks which
comprise a filesystem are parameters of the filesystem.
comprise a file system are parameters of the file system.
Sectors beginning at
.Dv BBLOCK
and continuing for
@ -66,7 +66,7 @@ are used
for a disklabel and for some hardware primary
and secondary bootstrapping programs.
.Pp
The actual filesystem begins at sector
The actual file system begins at sector
.Dv SBLOCK
with the
.Em super-block
@ -77,10 +77,10 @@ from the file
.Aq Pa ufs/ffs/fs.h :
.Bd -literal
/*
* Super block for an FFS filesystem.
* Super block for an FFS file system.
*/
struct fs {
int32_t fs_firstfield; /* historic filesystem linked list, */
int32_t fs_firstfield; /* historic file system linked list, */
int32_t fs_unused_1; /* used for incore super blocks */
ufs_daddr_t fs_sblkno; /* addr of super-block in filesys */
ufs_daddr_t fs_cblkno; /* offset of cyl-block in filesys */
@ -123,7 +123,7 @@ struct fs {
int32_t fs_interleave; /* hardware sector interleave */
int32_t fs_trackskew; /* sector 0 skew, per track */
/* fs_id takes the space of the unused fs_headswitch and fs_trkseek fields */
int32_t fs_id[2]; /* unique filesystem id*/
int32_t fs_id[2]; /* unique file system id*/
/* sizes determined by number of cylinder groups and their sizes */
ufs_daddr_t fs_csaddr; /* blk addr of cyl grp summary area */
int32_t fs_cssize; /* size of cyl grp summary area */
@ -133,7 +133,7 @@ struct fs {
int32_t fs_nsect; /* sectors per track */
int32_t fs_spc; /* sectors per cylinder */
/* this comes from the disk driver partitioning */
int32_t fs_ncyl; /* cylinders in filesystem */
int32_t fs_ncyl; /* cylinders in file system */
/* these fields can be computed from the others */
int32_t fs_cpg; /* cylinders per group */
int32_t fs_ipg; /* inodes per group */
@ -142,7 +142,7 @@ struct fs {
struct csum fs_cstotal;/* cylinder summary information */
/* these fields are cleared at mount time */
int8_t fs_fmod; /* super block modified flag */
int8_t fs_clean; /* filesystem is clean flag */
int8_t fs_clean; /* file system is clean flag */
int8_t fs_ronly; /* mounted read-only flag */
int8_t fs_flags; /* currently unused flag */
u_char fs_fsmnt[MAXMNTLEN]; /* name mounted on */
@ -170,9 +170,9 @@ struct fs {
};
/*
* Filesystem identification
* File system identification
*/
#define FS_MAGIC 0x011954 /* the fast filesystem magic number */
#define FS_MAGIC 0x011954 /* the fast file system magic number */
#define FS_OKAY 0x7c269d38 /* superblock checksum */
#define FS_42INODEFMT -1 /* 4.2BSD inode format */
#define FS_44INODEFMT 2 /* 4.4BSD inode format */
@ -189,14 +189,14 @@ struct fs {
#define FS_DYNAMICPOSTBLFMT 1 /* dynamic rotational table format */
.Ed
.Pp
Each disk drive contains some number of filesystems.
A filesystem consists of a number of cylinder groups.
Each disk drive contains some number of file systems.
A file system consists of a number of cylinder groups.
Each cylinder group has inodes and data.
.Pp
A filesystem is described by its super-block, which in turn
A file system is described by its super-block, which in turn
describes the cylinder groups. The super-block is critical
data and is replicated in each cylinder group to protect against
catastrophic loss. This is done at filesystem creation
catastrophic loss. This is done at file system creation
time and the critical
super-block data does not change, so the copies need not be
referenced further unless disaster strikes.
@ -216,17 +216,17 @@ unit.
Large files consist of exclusively large data blocks. To avoid
undue wasted disk space, the last data block of a small file is
allocated as only as many fragments of a large block as are
necessary. The filesystem format retains only a single pointer
necessary. The file system format retains only a single pointer
to such a fragment, which is a piece of a single large block that
has been divided. The size of such a fragment is determinable from
information in the inode, using the
.Fn blksize fs ip lbn
macro.
.Pp
The filesystem records space availability at the fragment level;
The file system records space availability at the fragment level;
to determine block availability, aligned fragments are examined.
.Pp
The root inode is the root of the filesystem.
The root inode is the root of the file system.
Inode 0 can't be used for normal purposes and
historically bad blocks were linked to inode 1,
thus the root inode is 2 (inode 1 is no longer used for
@ -235,7 +235,7 @@ assumption, so we are stuck with it).
.Pp
The
.Fa fs_minfree
element gives the minimum acceptable percentage of filesystem
element gives the minimum acceptable percentage of file system
blocks that may be free.
If the freelist drops below this level
only the super-user may continue to allocate blocks.
@ -244,7 +244,7 @@ The
element
may be set to 0 if no reserve of free blocks is deemed necessary,
however severe performance degradations will be observed if the
filesystem is run at greater than 90% full; thus the default
file system is run at greater than 90% full; thus the default
value of
.Fa fs_minfree
is 10%.
@ -256,15 +256,15 @@ of the block size.
.Pp
The element
.Fa fs_optim
specifies whether the filesystem should try to minimize the time spent
specifies whether the file system should try to minimize the time spent
allocating blocks, or if it should attempt to minimize the space
fragmentation on the disk.
If the value of fs_minfree (see above) is less than 10%,
then the filesystem defaults to optimizing for space to avoid
then the file system defaults to optimizing for space to avoid
running out of full sized blocks.
If the value of minfree is greater than or equal to 10%,
fragmentation is unlikely to be problematical, and
the filesystem defaults to optimizing for time.
the file system defaults to optimizing for time.
.Pp
.Em Cylinder group related limits :
Each cylinder keeps track of the availability of blocks at different
@ -284,7 +284,7 @@ the default value for
.Fa fs_rotdelay
is 2ms.
.Pp
Each filesystem has a statically allocated number of inodes.
Each file system has a statically allocated number of inodes.
An inode is allocated for each
.Dv NBPI
bytes of disk space.
@ -306,12 +306,12 @@ must keep its size within
Note that super-blocks are never more than size
.Dv SBSIZE .
.Pp
The path name on which the filesystem is mounted is maintained in
The path name on which the file system is mounted is maintained in
.Fa fs_fsmnt .
.Dv MAXMNTLEN
defines the amount of space allocated in
the super-block for this name.
The limit on the amount of summary information per filesystem
The limit on the amount of summary information per file system
is defined by
.Dv MAXCSBUFS .
For a 4096 byte block size, it is currently parameterized for a
@ -333,14 +333,14 @@ the
macro to work.
.Pp
The
.Em "Super-block for a filesystem" :
.Em "Super-block for a file system" :
The size of the rotational layout tables
is limited by the fact that the super-block is of size
.Dv SBSIZE .
The size of these tables is
.Em inversely
proportional to the block
size of the filesystem.
size of the file system.
The size of the tables is
increased when sector sizes are not powers of two,
as this increases the number of cylinders
@ -361,7 +361,7 @@ The
.Em Inode :
The inode is the focus of all file activity in the
.Ux
filesystem.
file system.
There is a unique inode allocated
for each active file,
each current directory, each mounted-on file,
@ -372,6 +372,6 @@ For further information, see the include file
.Sh HISTORY
A super-block structure named filsys appeared in
.At v6 .
The filesystem described in this manual appeared
The file system described in this manual appeared
in
.Bx 4.2 .

View File

@ -37,7 +37,7 @@
.Os
.Sh NAME
.Nm fstab
.Nd static information about the filesystems
.Nd static information about the file systems
.Sh SYNOPSIS
.In fstab.h
.Sh DESCRIPTION
@ -49,7 +49,7 @@ systems.
is only read by programs, and not written;
it is the duty of the system administrator to properly create
and maintain this file.
Each filesystem is described on a separate line;
Each file system is described on a separate line;
fields on each line are separated by tabs or spaces.
The order of records in
.Nm
@ -65,8 +65,8 @@ doing their thing.
The first field,
.Pq Fa fs_spec ,
describes the block special device or
remote filesystem to be mounted.
For filesystems of type
remote file system to be mounted.
For file systems of type
.Em ufs ,
the special file name is the block special file name,
and not the character special file name.
@ -76,46 +76,46 @@ last ``/'' in the special file name.
.Pp
The second field,
.Pq Fa fs_file ,
describes the mount point for the filesystem.
describes the mount point for the file system.
For swap partitions, this field should be specified as ``none''.
.Pp
The third field,
.Pq Fa fs_vfstype ,
describes the type of the filesystem.
The system can support various filesystem types.
Only the root, /usr, and /tmp filesystems need be statically
describes the type of the file system.
The system can support various file system types.
Only the root, /usr, and /tmp file systems need be statically
compiled into the kernel;
everything else will be automatically loaded at mount
time. (Exception: the UFS family - FFS and LFS cannot
currently be demand-loaded.) Some people still prefer to statically
compile other filesystems as well.
compile other file systems as well.
.Pp
The fourth field,
.Pq Fa fs_mntops ,
describes the mount options associated with the filesystem.
describes the mount options associated with the file system.
It is formatted as a comma separated list of options.
It contains at least the type of mount (see
.Fa fs_type
below) plus any additional options
appropriate to the filesystem type. See the options flag
appropriate to the file system type. See the options flag
.Pq Fl o
in the
.Xr mount 8
page and the filesystem specific page, such as
page and the file system specific page, such as
.Xr mount_nfs 8 ,
for additional options that may be specified.
.Pp
If the options ``userquota'' and/or ``groupquota'' are specified,
the filesystem is automatically processed by the
the file system is automatically processed by the
.Xr quotacheck 8
command, and user and/or group disk quotas are enabled with
.Xr quotaon 8 .
By default,
filesystem quotas are maintained in files named
file system quotas are maintained in files named
.Pa quota.user
and
.Pa quota.group
which are located at the root of the associated filesystem.
which are located at the root of the associated file system.
These defaults may be overridden by putting an equal sign
and an alternative absolute pathname following the quota option.
Thus, if the user quota file for
@ -127,9 +127,9 @@ this location can be specified as:
userquota=/var/quotas/tmp.user
.Ed
.Pp
If the option ``noauto'' is specified, the filesystem will not be automatically
If the option ``noauto'' is specified, the file system will not be automatically
mounted at system startup.
Note that, for network filesystems
Note that, for network file systems
of third party types
(i.e. types supported by additional software
not included in the base system)
@ -139,7 +139,7 @@ the
.Xr rc.conf 5
variable must be used to extend the
.Xr rc 8
startup script's list of network filesystem types.
startup script's list of network file system types.
.Pp
The type of the mount is extracted from the
.Fa fs_mntops
@ -150,7 +150,7 @@ field (it is not deleted from the
field).
If
.Fa fs_type
is ``rw'' or ``ro'' then the filesystem whose name is given in the
is ``rw'' or ``ro'' then the file system whose name is given in the
.Fa fs_file
field is normally mounted read-write or read-only on the
specified special file.
@ -172,31 +172,31 @@ This is useful to show disk partitions which are currently unused.
.Pp
The fifth field,
.Pq Fa fs_freq ,
is used for these filesystems by the
is used for these file systems by the
.Xr dump 8
command to determine which filesystems need to be dumped.
command to determine which file systems need to be dumped.
If the fifth field is not present, a value of zero is returned and
.Nm dump
will assume that the filesystem does not need to be dumped.
will assume that the file system does not need to be dumped.
.Pp
The sixth field,
.Pq Fa fs_passno ,
is used by the
.Xr fsck 8
program to determine the order in which filesystem checks are done
program to determine the order in which file system checks are done
at reboot time.
The root filesystem should be specified with a
The root file system should be specified with a
.Fa fs_passno
of 1, and other filesystems should have a
of 1, and other file systems should have a
.Fa fs_passno
of 2.
Filesystems within a drive will be checked sequentially,
but filesystems on different drives will be checked at the
File systems within a drive will be checked sequentially,
but file systems on different drives will be checked at the
same time to utilize parallelism available in the hardware.
If the sixth field is not present or is zero,
a value of zero is returned and
.Xr fsck 8
will assume that the filesystem does not need to be checked.
will assume that the file system does not need to be checked.
.Bd -literal
#define FSTAB_RW "rw" /* read/write device */
#define FSTAB_RQ "rq" /* read/write with quotas */
@ -206,7 +206,7 @@ will assume that the filesystem does not need to be checked.
struct fstab {
char *fs_spec; /* block special device name */
char *fs_file; /* filesystem path prefix */
char *fs_file; /* file system path prefix */
char *fs_vfstype; /* File system type, ufs, nfs */
char *fs_mntops; /* Mount options ala -o */
char *fs_type; /* FSTAB_* from fs_mntops */

View File

@ -530,7 +530,7 @@ structures define the layout of the library hints, normally found in
which is used by
.Nm ld.so
to quickly locate the shared object images in the
filesystem.
file system.
The organization of the hints file is not unlike that of an
.Dq a.out
object file, in that it contains a header determining the offset and size

View File

@ -7,15 +7,15 @@
.Os
.Sh NAME
.Nm linprocfs
.Nd Linux process filesystem
.Nd Linux process file system
.Sh SYNOPSIS
.Bd -literal
linproc /compat/linux/proc linprocfs rw 0 0
.Ed
.Sh DESCRIPTION
The Linux process filesystem, or
The Linux process file system, or
.Nm ,
emulates a subset of Linux' process filesystem and is required for
emulates a subset of Linux' process file system and is required for
the complete operation of some Linux binaries.
.Pp
The

View File

@ -449,14 +449,14 @@ the previous day's values.
.Pq Vt bool
Set to
.Dq YES
to check for changes mounted filesystems to the previous day's values.
to check for changes mounted file systems to the previous day's values.
.It Va daily_status_security_noamd
.Pq Vt bool
Set to
.Dq YES
if you want to ignore
.Xr amd 8
mounts when comparing against yesterdays filesystem mounts in the
mounts when comparing against yesterdays file system mounts in the
.Va daily_status_security_chkmounts_enable
check.
.It Va daily_status_security_chkuid0_enable

View File

@ -7,15 +7,15 @@
.Os
.Sh NAME
.Nm procfs
.Nd process filesystem
.Nd process file system
.Sh SYNOPSIS
.Bd -literal
proc /proc procfs rw 0 0
.Ed
.Sh DESCRIPTION
The process filesystem, or
The process file system, or
.Nm ,
implements a view of the system process table inside the filesystem.
implements a view of the system process table inside the file system.
It is normally mounted on
.Pa /proc ,
and is required for the complete operation of programs such as

View File

@ -28,13 +28,13 @@
.Os
.Sh NAME
.Nm quota.user , quota.group
.Nd per-filesystem quota database
.Nd per file system quota database
.Sh DESCRIPTION
Each filesystem with active quotas should contain a
Each file system with active quotas should contain a
.Pa quota.user
and
.Pa quota.group
file in the filesystem root.
file in the file system root.
These files are created by
.Xr quotacheck 8 ,
and should be edited with

View File

@ -726,7 +726,7 @@ If set to
will be run with the
.Fl y
flag if the initial preen
of the filesystems fails.
of the file systems fails.
.It Va background_fsck
.Pq Vt bool
If set to
@ -739,19 +739,19 @@ in the background where possible.
If set to something other than
.Dq Li NO
(the default),
this variable extends the list of filesystem types
this variable extends the list of file system types
for which automatic mounting at startup by
.Xr rc 8
should be delayed until the network is initialized.
It should contain
a whitespace-separated list of network filesystem descriptor pairs,
each consisting of a filesystem type as passed to
a whitespace-separated list of network file system descriptor pairs,
each consisting of a file system type as passed to
.Xr mount 8
and a human-readable, one-word description,
joined with a colon
.Pq Ql \&: .
Extending the default list in this way is only necessary
when third party filesystem types are used.
when third party file system types are used.
.It Va syslogd_enable
.Pq Vt bool
If set to

View File

@ -35,7 +35,7 @@
.Os
.Sh NAME
.Nm ffs
.Nd Berkeley fast filesystem
.Nd Berkeley fast file system
.Sh SYNOPSIS
In the kernel configuration file:
.Cd "options FFS"
@ -53,21 +53,21 @@ In
/dev/disk0a /mnt ufs rw 1 1
.Ed
.Sh DESCRIPTION
The Berkeley fast filesystem
provides facilities to store filesystem data onto a disk device.
The Berkeley fast file system
provides facilities to store file system data onto a disk device.
.Nm
has been optimized over the years
for speed and reliability
and is the default
.Fx
filesystem.
file system.
.Ss Quotas
.Bl -tag -width 2n
.It Cd "options QUOTA"
This option allows system administrators
to set limits on disk usage
on a per-user basis.
Quotas can be used only on filesystems
Quotas can be used only on file systems
mounted with the
.Cm quota
option;
@ -82,11 +82,11 @@ and
The soft updates feature tracks writes to the disk
and enforces metadata update dependencies
(e.g., updating free block maps)
to ensure that the filesystem remains consistent.
to ensure that the file system remains consistent.
.Pp
To enable soft updates on an
.Em unmounted
filesystem, use the following command:
file system, use the following command:
.Pp
.D1 Nm tunefs Fl n Cm enable Ar fs
.Pp
@ -108,7 +108,7 @@ on networks including
and
.Tn "Apple Macintosh"
computers,
this option allows files on filesystems
this option allows files on file systems
mounted with the
.Cm suiddir
option
@ -127,7 +127,7 @@ This option requires the presence of the
option, and it is recommended that
.Dv UFS_EXTATTR_AUTOSTART
is included as well,
so that ACLs are enabled atomically upon mounting the filesystem.
so that ACLs are enabled atomically upon mounting the file system.
.El
.Pp
In order to enable support for ACLs,
@ -139,11 +139,11 @@ which holds the access ACL,
and
.Pa posix1e.acl_default ,
which holds the default ACL for directories.
If you are using filesystem extended attributes,
If you are using file system extended attributes,
the following commands may be used to
allocate space for and create the necessary EA backing files
for ACLs in the root of each filesystem.
In these examples, the root filesystem is used;
for ACLs in the root of each file system.
In these examples, the root file system is used;
see
.Sx "Extended Attributes"
for more details.
@ -154,7 +154,7 @@ extattrctl initattr -p / 388 posix1e.acl_access
extattrctl initattr -p / 388 posix1e.acl_default
.Ed
.Pp
On the next mount of the root filesystem,
On the next mount of the root file system,
the attributes will be automatically started
(if
.Dv UFS_EXTATTR_AUTOSTART
@ -179,9 +179,9 @@ If this option is defined,
.Nm
will search for a
.Pa .attribute
subdirectory of the filesystem root during the mount operation.
subdirectory of the file system root during the mount operation.
If found, extended attribute support will be
automatically started for that filesystem.
automatically started for that file system.
.El
.Pp
The following
@ -191,7 +191,7 @@ MIBs are defined for use with
.Bl -hang -width ".Va vfs.ffs.doreallocblk"
.It Va vfs.ffs.doasyncfree
Asynchronously write out modified i-node and indirect blocks
upon reallocating filesystem blocks to be contiguous.
upon reallocating file system blocks to be contiguous.
(Default: 1.)
.It Va vfs.ffs.doreallocblks
Enable support for the rearrangement of blocks

View File

@ -37,12 +37,12 @@
.Os
.Sh NAME
.Nm hier
.Nd layout of filesystems
.Nd layout of file systems
.Sh DESCRIPTION
A sketch of the filesystem hierarchy.
A sketch of the file system hierarchy.
.Bl -tag -width "/stand/"
.It Pa /
root directory of the filesystem
root directory of the file system
.It Pa /bin/
user utilities fundamental to both single-user and multi-user environments
.It Pa /boot/
@ -143,7 +143,7 @@ OpenSSL configuration files
empty directory commonly used by
system administrators as a temporary mount point
.It Pa /proc/
process filesystem;
process file system;
see
.Xr procfs 5 ,
.Xr mount_procfs 8
@ -208,28 +208,28 @@ WaveLAN driver
.It Pa fs/
.Bl -tag -width "kerberosIV/" -compact
.It Pa fdescfs/
per-process file descriptors filesystem
per-process file descriptors file system
.It Pa fifofs/
.St -p1003.1
FIFOs filesystem
FIFOs file system
.It Pa msdosfs/
MS-DOS filesystem
MS-DOS file system
.It Pa ntfs/
NTFS filesystem
NTFS file system
.It Pa nullfs/
loopback filesystem
loopback file system
.It Pa nwfs/
NetWare filesystem
NetWare file system
.It Pa portalfs/
portal filesystem
portal file system
.It Pa procfs/
process filesystem
process file system
.It Pa smbfs/
SMB/CIFS filesystem
SMB/CIFS file system
.It Pa umapfs/
alternate uid/gid mappings filesystem
alternate uid/gid mappings file system
.It Pa unionfs
union filesystem
union file system
.El
.It Pa g++/
GNU C++ include files
@ -242,7 +242,7 @@ ISC utility library libisc include files
.It Pa isofs/
.Bl -tag -width "kerberosIV/" -compact
.It Pa cd9660/
iso9660 filesystem
iso9660 file system
.El
.It Pa kerberosIV/
C include files for kerberos authentication package;
@ -327,9 +327,9 @@ system C include files (kernel data structures)
C include files for UFS (The U-word File System)
.Bl -tag -width "kerberosIV/" -compact
.It Pa ffs/
Fast filesystem
Fast file system
.It Pa ufs/
UFS filesystem
UFS file system
.El
.It Pa vm/
virtual memory;
@ -719,7 +719,7 @@ system messages database;
see
.Xr msgs 1
.It Pa quotas/
filesystem quota information files
file system quota information files
.It Pa run/
system information files describing various info about
system since it was booted
@ -779,7 +779,7 @@ the NIS maps
.Sh NOTES
This manual page documents the default
.Fx
filesystem layout, but
file system layout, but
the actual hierarchy on a given system is defined at the system
administrator's discretion.
A well-maintained installation will include a customized version of

View File

@ -79,7 +79,7 @@ Uses
.Dq Li "make installworld"
to install a clean system into a
.Xr chroot 8
environment on the filesystem.
environment on the file system.
Checks out the specified version of the source code and then rebuilds
the entire system in the clean environment with
.Dq Li "make world" .
@ -153,7 +153,7 @@ Sets up a suitable area to build CD-ROM images in
.It Cm iso.1
Builds two ISO images (installation and
.Dq live
filesystem) from the CD-ROM release area
file system) from the CD-ROM release area
(disabled by default, see
.Va MAKE_ISOS
below).
@ -189,7 +189,7 @@ environment for the entire release build.
.\" XXX: "we don't know how much space you'll need, but make sure you have
.\" XXX: at least 3 GB to be safe" (I know i'm still hardcoding a number,
.\" XXX: but at least it looks less like a decree and more like an estimate.
This filesystem should have at least 2.3 gigabytes of free space on the
This file system should have at least 2.3 gigabytes of free space on the
i386 architecture.
.It Va CVSROOT
The location of the
@ -440,7 +440,7 @@ used a manual checklist, compiled by
.An Rod Grimes ,
to produce a release.
Apart from being incomplete, the list put a lot of specific demands on
available filesystems and was quite torturous to execute.
available file systems and was quite torturous to execute.
.Pp
As part of the
.Fx 2.0

View File

@ -122,7 +122,7 @@ Securing user accounts
.It
Securing the password file
.It
Securing the kernel core, raw devices, and filesystems
Securing the kernel core, raw devices, and file systems
.It
Quick detection of inappropriate changes made to the system
.It
@ -319,7 +319,7 @@ the password file
(see
.Sq Checking file integrity
below).
.Sh SECURING THE KERNEL CORE, RAW DEVICES, AND FILESYSTEMS
.Sh SECURING THE KERNEL CORE, RAW DEVICES, AND FILE SYSTEMS
If an attacker breaks root he can do just about anything, but there
are certain conveniences. For example, most modern kernels have a
packet sniffing device driver built in. Under
@ -384,7 +384,7 @@ limited-access box significant access to the other machines in the business,
usually either by doing a read-only NFS export of the other machines to the
limited-access box, or by setting up ssh keypairs to allow the limit-access
box to ssh to the other machines. Except for its network traffic, NFS is
the least visible method - allowing you to monitor the filesystems on each
the least visible method - allowing you to monitor the file systems on each
client box virtually undetected. If your
limited-access server is connected to the client boxes through a switch,
the NFS method is often the better choice. If your limited-access server

View File

@ -15,13 +15,13 @@ When using
.Xr disklabel 8
or
.Xr sysinstall 8
to lay out your filesystems on a hard disk it is important to remember
to lay out your file systems on a hard disk it is important to remember
that hard drives can transfer data much more quickly from outer tracks
than they can from inner tracks.
To take advantage of this you should
try to pack your smaller filesystems and swap closer to the outer tracks,
follow with the larger filesystems, and end with the largest filesystems.
It is also important to size system standard filesystems such that you
try to pack your smaller file systems and swap closer to the outer tracks,
follow with the larger file systems, and end with the largest file systems.
It is also important to size system standard file systems such that you
will not be forced to resize them later as you scale the machine up.
I usually create, in order, a 128M root, 1G swap, 128M
.Pa /var ,
@ -85,7 +85,7 @@ Also note that sysinstall will create a
.Pa /tmp
directory.
Dedicating a partition for temporary file storage is important for
two reasons: first, it reduces the possibility of filesystem corruption
two reasons: first, it reduces the possibility of file system corruption
in a crash, and second it reduces the chance of a runaway process that
fills up
.Oo Pa /var Oc Ns Pa /tmp
@ -155,7 +155,7 @@ Then I do not have to worry about undersizing things!
Well, there are several reasons this is not a good idea.
First,
each partition has different operational characteristics and separating them
allows the filesystem to tune itself to those characteristics.
allows the file system to tune itself to those characteristics.
For example,
the root and
.Pa /usr
@ -198,8 +198,8 @@ and
.Em cylinders/group .
.Pp
.Fx
performs best when using 8K or 16K filesystem block sizes.
The default filesystem block size is 16K,
performs best when using 8K or 16K file system block sizes.
The default file system block size is 16K,
which provides best performance for most applications,
with the exception of those that perform random access on large files
(such as database server software).
@ -211,9 +211,9 @@ can cause fragmentation of the buffer cache and
lead to lower performance.
.Pp
The defaults may be unsuitable
for a filesystem that requires a very large number of i-nodes
for a file system that requires a very large number of i-nodes
or is intended to hold a large number of very small files.
Such a filesystem should be created with an 8K or 4K block size.
Such a file system should be created with an 8K or 4K block size.
This also requires you to specify a smaller
fragment size.
We recommend always using a fragment size that is 1/8
@ -229,12 +229,12 @@ as database files, you can increase the
ratio which reduces the number of i-nodes (maximum number of files and
directories that can be created) for that partition.
Decreasing the number
of i-nodes in a filesystem can greatly reduce
of i-nodes in a file system can greatly reduce
.Xr fsck 8
recovery times after a crash.
Do not use this option
unless you are actually storing large files on the partition, because if you
overcompensate you can wind up with a filesystem that has lots of free
overcompensate you can wind up with a file system that has lots of free
space remaining but cannot accommodate any more files.
Using 32768, 65536, or 262144 bytes/i-node is recommended.
You can go higher but
@ -245,13 +245,13 @@ For example,
.Dq Li "newfs -i 32768 ..." .
.Pp
.Xr tunefs 8
may be used to further tune a filesystem.
may be used to further tune a file system.
This command can be run in
single-user mode without having to reformat the filesystem.
single-user mode without having to reformat the file system.
However, this is possibly the most abused program in the system.
Many people attempt to
increase available filesystem space by setting the min-free percentage to 0.
This can lead to severe filesystem fragmentation and we do not recommend
increase available file system space by setting the min-free percentage to 0.
This can lead to severe file system fragmentation and we do not recommend
that you do this.
Really the only
.Xr tunefs 8
@ -267,27 +267,27 @@ option to
.Xr newfs 8 ,
and
.Xr sysinstall 8
will typically enable softupdates automatically for non-root filesystems).
will typically enable softupdates automatically for non-root file systems).
Softupdates drastically improves meta-data performance, mainly file
creation and deletion.
We recommend enabling softupdates on most filesystems; however, there
We recommend enabling softupdates on most file systems; however, there
are two limitations to softupdates that you should be aware of when
determining whether to use it on a filesystem.
First, softupdates guarantees filesystem consistency in the
determining whether to use it on a file system.
First, softupdates guarantees file system consistency in the
case of a crash but could very easily be several seconds (even a minute!\&)
behind on pending write to the physical disk.
If you crash you may lose more work
than otherwise.
Secondly, softupdates delays the freeing of filesystem
Secondly, softupdates delays the freeing of file system
blocks.
If you have a filesystem (such as the root filesystem) which is
If you have a file system (such as the root file system) which is
close to full, doing a major update of it, e.g.\&
.Dq Li "make installworld" ,
can run it out of space and cause the update to fail.
For this reason, softupdates will not be enabled on the root filesystem
For this reason, softupdates will not be enabled on the root file system
during a typical install.
There is no loss of performance since the root
filesystem is rarely written to.
file system is rarely written to.
.Pp
A number of run-time
.Xr mount 8
@ -301,7 +301,7 @@ useful
option is called
.Cm noatime .
.Ux
filesystems normally update the last-accessed time of a file or
file systems normally update the last-accessed time of a file or
directory whenever it is accessed.
This operation is handled in
.Fx
@ -318,7 +318,7 @@ However, you should not gratuitously turn off atime
updates everywhere.
For example, the
.Pa /var
filesystem customarily
file system customarily
holds mailboxes, and atime (in combination with mtime) is used to
determine whether a mailbox has new mail.
You might as well leave
@ -335,13 +335,13 @@ use the atime field for reporting.
In larger systems you can stripe partitions from several drives together
to create a much larger overall partition.
Striping can also improve
the performance of a filesystem by splitting I/O operations across two
the performance of a file system by splitting I/O operations across two
or more disks.
The
.Xr vinum 8
and
.Xr ccdconfig 8
utilities may be used to create simple striped filesystems.
utilities may be used to create simple striped file systems.
Generally
speaking, striping smaller partitions such as the root and
.Pa /var/tmp ,
@ -354,7 +354,7 @@ typically
or custom partitions used to hold databases and web pages.
Choosing the proper stripe size is also
important.
Filesystems tend to store meta-data on power-of-2 boundaries
File systems tend to store meta-data on power-of-2 boundaries
and you usually want to reduce seeking rather than increase seeking.
This
means you want to use a large off-center stripe size such as 1152 sectors
@ -400,7 +400,7 @@ sysctl defaults to 1 (on).
This parameter controls how directories are cached
by the system.
Most directories are small and use but a single fragment
(typically 1K) in the filesystem and even less (typically 512 bytes) in
(typically 1K) in the file system and even less (typically 512 bytes) in
the buffer cache.
However, when operating in the default mode the buffer
cache will only cache a fixed number of directories even if you have a huge
@ -422,7 +422,7 @@ wasted memory but you should experiment to find out.
The
.Va vfs.write_behind
sysctl defaults to 1 (on).
This tells the filesystem to issue media
This tells the file system to issue media
writes as full clusters are collected, which typically occurs when writing
large sequential files.
The idea is to avoid saturating the buffer
@ -749,7 +749,7 @@ More and more programs are using the
system call to transmit files over the network.
The
.Va kern.ipc.nsfbufs
sysctl controls the number of filesystem buffers
sysctl controls the number of file system buffers
.Xr sendfile 2
is allowed to use to perform its work.
This parameter nominally scales
@ -818,7 +818,7 @@ With IDE write caching turned
on, IDE hard drives will not only write data to disk out of order, they
will sometimes delay some of the blocks indefinitely under heavy disk
load.
A crash or power failure can result in serious filesystem
A crash or power failure can result in serious file system
corruption.
So our default was changed to be safe.
Unfortunately, the

View File

@ -58,7 +58,7 @@ and then invokes an automatic reboot procedure as
described in
.Xr reboot 8 .
Unless some unexpected inconsistency is encountered in the state
of the filesystems due to hardware or software failure, the system
of the file systems due to hardware or software failure, the system
will then resume multi-user operations.
.Pp
The system has a large number of internal consistency checks; if one
@ -78,12 +78,12 @@ error produced the message in some unexpected way.
.Pp
.Bl -diag -compact
.It "cannot mount root"
This panic message results from a failure to mount the root filesystem
This panic message results from a failure to mount the root file system
during the bootstrap process.
Either the root filesystem has been corrupted,
or the system is attempting to use the wrong device as root filesystem.
Either the root file system has been corrupted,
or the system is attempting to use the wrong device as root file system.
Usually, an alternate copy of the system binary or an alternate root
filesystem can be used to bring up the system to investigate.
file system can be used to bring up the system to investigate.
Most often
this is done by the use of the boot floppy you used to install the system,
and then using the
@ -95,7 +95,7 @@ This is not a panic message, as reboots are likely to be futile.
Late in the bootstrap procedure, the system was unable to locate
and execute the initialization process,
.Xr init 8 .
The root filesystem is incorrect or has been corrupted, or the mode
The root file system is incorrect or has been corrupted, or the mode
or type of
.Pa /sbin/init
forbids execution or is totally missing.
@ -108,11 +108,11 @@ forbids execution or is totally missing.
.It "blkfree: freeing free frag"
.It "ifree: freeing free inode"
These panic messages are among those that may be produced
when filesystem inconsistencies are detected.
The problem generally results from a failure to repair damaged filesystems
when file system inconsistencies are detected.
The problem generally results from a failure to repair damaged file systems
after a crash, hardware failures, or other condition that should not
normally occur.
A filesystem check will normally correct the problem.
A file system check will normally correct the problem.
.Pp
.It "timeout table full"
This really should not be a panic, but until the data structure

View File

@ -38,7 +38,7 @@ The ability to boot a machine over the network is useful for
or
.Em dataless
machines, or as a temporary measure while repairing or
re-installing filesystems on a local disk.
re-installing file systems on a local disk.
This file provides a general description of the interactions between
a client and its server when a client is booting over the network.
.Sh OPERATION
@ -80,7 +80,7 @@ loaded using TFTP or NFS.
.Pp
In phase 3, the kernel uses again DHCP or BOOTP to acquire
configuration information, and proceeds to mount the
root filesystem and start operation.
root file system and start operation.
Some specific actions performed during the startup
of a diskless system are listed in
.Pa /etc/rc.diskless1
@ -155,7 +155,7 @@ The files and subdirectories within
.Pa /conf/default/etc
are used to bootstrap the diskless environment's
.Pa /etc
memory filesystem.
memory file system.
Be sure and copy the entirety of
.Pa /etc ,
and not just overrides.
@ -208,7 +208,7 @@ local startup files will not be used.
.Pp
While an
.Xr md 4 Ns -backed
filesystem is mounted on
file system is mounted on
.Pa /var
by the startup scripts,
some sites may want to disable the saving of entropy by setting
@ -248,7 +248,7 @@ This manpage is probably incomplete.
sometimes requires to write onto
the root partition, so the startup scripts create and mount
.Xr md 4 Ns -backed
filesystems on some locations (e.g.\&
file systems on some locations (e.g.\&
.Pa /etc
and
.Pa /var ) ,

View File

@ -41,9 +41,9 @@
.Sh DESCRIPTION
This section contains information related to system operation
and maintenance.
It describes commands used to create new filesystems,
It describes commands used to create new file systems,
.Xr newfs 8 ,
verify the integrity of the filesystems,
verify the integrity of the file systems,
.Xr fsck 8 ,
control disk usage,
.Xr edquota 8 ,

View File

@ -30,15 +30,15 @@ in the server, it can be extremely useful to developers to
test their code without having to reinstall the system.
.Pp
The boot media (typically a floppy disk) contains a boot loader and a
compressed kernel which includes a memory filesystem.
compressed kernel which includes a memory file system.
Depending on the media, it might also contain a number of
additional files, which can be updated at run time, and are
used to override/update those in the memory filesystem.
used to override/update those in the memory file system.
.Pp
The system loads the kernel in the normal way, uncompresses
the memory filesystem and mounts it as root.
the memory file system and mounts it as root.
It then updates the memory
filesystem with files from the boot media (if present),
file system with files from the boot media (if present),
and executes a specialized version of
.Pa /etc/rc .
The boot media (floppy, etc.) is
@ -96,8 +96,8 @@ commands to be executed and waiting for user
input before executing each of them.
Useful for debugging.
.It Fl -all_in_mfs
Put the entire contents of the filesystem in the
memory filesystem image which is contained in the
Put the entire contents of the file system in the
memory file system image which is contained in the
kernel.
This is the default behaviour, and is
extremely useful as the kernel itself can be loaded,
@ -233,7 +233,7 @@ option:
options MD_ROOT_SIZE=4200 # same as def_sz
.Ed
.Pp
This informs the script of the size of the memory filesystem and
This informs the script of the size of the memory file system and
provides a few other details on how to build the image.
.It Pa crunch.conf
.Xr crunchgen 1
@ -317,7 +317,7 @@ because only the files that are actually loaded from the image
contribute to the memory usage.
.It Va import_files
Contains a list of files to be imported in the floppy tree.
Absolute names refer to the standard filesystem, relative
Absolute names refer to the standard file system, relative
names refer to the root of the source tree being used
(i.e.\&
.Va SRC_PATH/.. ) .
@ -494,7 +494,7 @@ ethernet.
.Pp
After booting,
.Nm
loads the root filesystem from the memory filesystem, starts
loads the root file system from the memory file system, starts
.Pa /sbin/init ,
and passes control to a first startup script,
.Pa /etc/rc .
@ -504,7 +504,7 @@ and
.Pa /root
directories with the default files, then tries to identify the boot
device (floppy, hard disk partition) and possibly override the contents
of the root filesystem with files read from the boot device.
of the root file system with files read from the boot device.
This allows you to store local configuration on the same media.
After this phase the boot device is no longer used, unless the
user specifically does it.

View File

@ -379,7 +379,7 @@ the script does not do anything.
The
.Nm rc.early
script is run very early in the startup process, immediately before the
filesystem check.
file system check.
The
.Nm rc.early
script is deprecated.

View File

@ -33,11 +33,11 @@
.Dt VFS 9
.Sh NAME
.Nm VFS
.Nd kernel interface to filesystems
.Nd kernel interface to file systems
.Sh DESCRIPTION
Calls used to set or query filesystems for settings or information.
Calls used to set or query file systems for settings or information.
.Pp
Filesystems that don't implement a VFS operation should use the appropriate
File systems that don't implement a VFS operation should use the appropriate
.Fa vfs_std
function from
.Pa src/sys/kern/vfs_default.c

View File

@ -29,7 +29,7 @@
.Dt VFS_CHECKEXP 9
.Sh NAME
.Nm VFS_CHECKEXP
.Nd check if a filesystem is exported to a client
.Nd check if a file system is exported to a client
.Sh SYNOPSIS
.In sys/param.h
.In sys/mount.h
@ -51,21 +51,21 @@ Return parameter for the export flags for this client.
Return parameter for the anonymous credentials for this client.
.El
.Pp
This should be called on a filesystem's mount structure to determine if it
This should be called on a file system's mount structure to determine if it
is exported to a client whose address is contained in
.Fa nam .
.Pp
It is generally called before
.Xr VFS_FHTOVP 9
to validate that a client has access to the filesystem.
to validate that a client has access to the file system.
.Pp
The filesystem should call
The file system should call
.Xr vfs_export_lookup 9
with the address of an appropriate
.Dv netexport
structure and the address of the client,
.Fa nam ,
to verify that the client can access this filesystem.
to verify that the client can access this file system.
.Sh RETURN VALUES
The export flags and anonymous credentials specific to the client (returned
by

View File

@ -46,19 +46,19 @@ This is used by the NFS server to turn an NFS filehandle into a vnode.
Its arguments are:
.Bl -tag -width vpp
.It Ar mp
The filesystem.
The file system.
.It Ar fhp
The filehandle to convert.
.It Ar vpp
Return parameter for the new locked vnode.
.El
.Pp
The contents of the filehandle are defined by the filesystem and are
The contents of the filehandle are defined by the file system and are
not examined by any other part of the system. It should contain
enough information to uniquely identify a file within the filesystem
as well as noticing when a file has been removed and the filesystem
enough information to uniquely identify a file within the file system
as well as noticing when a file has been removed and the file system
resources have been reused for a new file. For instance, UFS
filesystem stores the inode number and inode generation counter in its
file system stores the inode number and inode generation counter in its
filehandle.
.Pp
A call to this function should generally be preceded by a call to

View File

@ -33,7 +33,7 @@
.Dt VFS_INIT 9
.Sh NAME
.Nm VFS_INIT
.Nd initialize a filesystem
.Nd initialize a file system
.Sh SYNOPSIS
.In sys/param.h
.In sys/mount.h
@ -41,10 +41,10 @@
.Ft int
.Fn VFS_INIT
.Sh DESCRIPTION
This function is called once to allow a filesystem to initialize any
This function is called once to allow a file system to initialize any
global data structures that it might have. It is either called when
the operating system boots or, for dynamically loaded filesystems,
when the kernel module containing the filesystem is loaded.
the operating system boots or, for dynamically loaded file systems,
when the kernel module containing the file system is loaded.
.Sh SEE ALSO
.Xr VFS 9 ,
.Xr vnode 9

View File

@ -33,7 +33,7 @@
.Dt VFS_MOUNT 9
.Sh NAME
.Nm VFS_MOUNT
.Nd mount a filesystem
.Nd mount a file system
.Sh SYNOPSIS
.In sys/param.h
.In sys/mount.h
@ -41,44 +41,44 @@
.Ft int
.Fn VFS_MOUNT "struct mount *mp" "char *path" "caddr_t data" "struct nameidata *ndp" "struct thread *td"
.Sh DESCRIPTION
Mount a filesystem into the system's namespace.
Mount a file system into the system's namespace.
.Pp
Its arguments are:
.Bl -tag -width data
.It Ar mp
Structure representing the filesystem.
Structure representing the file system.
.It Ar path
Pathname where the filesystem is being mounted.
Pathname where the file system is being mounted.
.It Ar data
Filesystem specific data. This should be read into the kernel using
File system specific data. This should be read into the kernel using
.Xr copyin 9 .
.It Ar ndp
Contains the result of a
.Xr namei 9
call on the pathname of the mountpoint.
.It Ar td
Thread which is mounting the filesystem.
Thread which is mounting the file system.
.El
.Pp
This is called both to mount new filesystems and to change the
attributes of an existing filesystem. If the
This is called both to mount new file systems and to change the
attributes of an existing file system. If the
.Dv MNT_UPDATE
flag is set in
.Fa mp->mnt_flag
then the filesystem should update its internal state from the value of
then the file system should update its internal state from the value of
.Fa mp->mnt_flag .
This can be used, for instance, to convert a read-only filesystem to
This can be used, for instance, to convert a read-only file system to
read-write.
It is also used by
.Xr mountd 8
to update the NFS export information for the filesystem.
to update the NFS export information for the file system.
.Pp
If the
.Dv MNT_UPDATE
flag is not specified, then this is a newly mounted filesystem. The
filesystem code should allocate and initialize
flag is not specified, then this is a newly mounted file system. The
file system code should allocate and initialize
any private data needed to represent
the filesystem (it can use the
the file system (it can use the
.Fa mp->mnt_data
field to store this information).
.Sh SEE ALSO

View File

@ -33,7 +33,7 @@
.Dt VFS_QUOTACTL 9
.Sh NAME
.Nm VFS_QUOTACTL
.Nd manipulate filesystem quotas
.Nd manipulate file system quotas
.Sh SYNOPSIS
.In sys/param.h
.In sys/mount.h
@ -41,7 +41,7 @@
.Ft int
.Fn VFS_QUOTACTL "struct mount *mp" "int cmds" "uid_t uid" "caddr_t arg" "struct thread *td"
.Sh DESCRIPTION
Implement filesystem quotas. See
Implement file system quotas. See
.Xr quotactl 2
for a description of the arguments.
.Sh SEE ALSO

View File

@ -33,7 +33,7 @@
.Dt VFS_ROOT 9
.Sh NAME
.Nm VFS_ROOT
.Nd return the root vnode of a filesystem
.Nd return the root vnode of a file system
.Sh SYNOPSIS
.In sys/param.h
.In sys/mount.h
@ -41,12 +41,12 @@
.Ft int
.Fn VFS_ROOT "struct mount *mp" "struct vnode **vpp"
.Sh DESCRIPTION
Return a locked vnode for the root directory of the filesystem.
Return a locked vnode for the root directory of the file system.
.Pp
Its arguments are:
.Bl -tag -width vpp
.It Ar mp
The filesystem.
The file system.
.It Ar vpp
Return parameter for the root vnode.
.El

View File

@ -31,7 +31,7 @@
.Os
.Sh NAME
.Nm VFS_SET
.Nd set up loadable filesystem
.Nd set up loadable file system
.Vt vfsconf
.Sh SYNOPSIS
.In sys/param.h

View File

@ -33,7 +33,7 @@
.Dt VFS_START 9
.Sh NAME
.Nm VFS_START
.Nd make a filesystem operational
.Nd make a file system operational
.Sh SYNOPSIS
.In sys/param.h
.In sys/mount.h
@ -43,15 +43,15 @@
.Sh DESCRIPTION
This is called after
.Xr VFS_MOUNT 9
and before the first access to the filesystem.
and before the first access to the file system.
Its arguments are:
.Bl -tag -width flags
.It Ar mp
The filesystem.
The file system.
.It Ar flags
??
.It Ar td
Thread which is starting the filesystem.
Thread which is starting the file system.
.El
.Sh SEE ALSO
.Xr VFS 9 ,

View File

@ -33,7 +33,7 @@
.Dt VFS_STATFS 9
.Sh NAME
.Nm VFS_STATFS
.Nd return filesystem status
.Nd return file system status
.Sh SYNOPSIS
.In sys/param.h
.In sys/mount.h
@ -41,17 +41,17 @@
.Ft int
.Fn VFS_STATFS "struct mount *mp" "struct statfs *sbp" "struct thread *td"
.Sh DESCRIPTION
This call returns various pieces of information about the filesystem,
This call returns various pieces of information about the file system,
including recommended I/O sizes, free space, free inodes, etc.
.Pp
Its arguments are:
.Bl -tag -width sbp
.It Ar mp
The filesystem.
The file system.
.It Ar sbp
Return parameter for the filesystem's status.
Return parameter for the file system's status.
.It Ar td
The thread which is querying the filesystem.
The thread which is querying the file system.
.El
.Sh SEE ALSO
.Xr VFS 9 ,

View File

@ -41,12 +41,12 @@
.Ft int
.Fn VFS_SYNC "struct mount *mp" "int waitfor" "struct ucred *cred" "struct thread *td"
.Sh DESCRIPTION
This writes out all unwritten data in a filesystem.
This writes out all unwritten data in a file system.
.Pp
Its arguments are:
.Bl -tag -width waitfor
.It Ar mp
The filesystem.
The file system.
.It Ar waitfor
Whether the function should wait for I/O to complete.
Possible values are:
@ -56,7 +56,7 @@ synchronously wait for I/O to complete
.It Dv MNT_NOWAIT
start all I/O, but do not wait for it
.It Dv MNT_LAZY
push data not written by filesystem syncer
push data not written by file system syncer
.El
.It Ar cred
The caller's credentials.
@ -66,7 +66,7 @@ The calling thread.
.Pp
This would normally call
.Xr VOP_FSYNC 9
for all the vnodes in the filesystem.
for all the vnodes in the file system.
.Sh SEE ALSO
.Xr fsync 2 ,
.Xr sync 2 ,

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