294 lines
13 KiB
Perl
294 lines
13 KiB
Perl
|
.\" Copyright (c) 1986, 1993
|
||
|
.\" The Regents of the University of California. All rights reserved.
|
||
|
.\"
|
||
|
.\" Redistribution and use in source and binary forms, with or without
|
||
|
.\" modification, are permitted provided that the following conditions
|
||
|
.\" are met:
|
||
|
.\" 1. Redistributions of source code must retain the above copyright
|
||
|
.\" notice, this list of conditions and the following disclaimer.
|
||
|
.\" 2. Redistributions in binary form must reproduce the above copyright
|
||
|
.\" notice, this list of conditions and the following disclaimer in the
|
||
|
.\" documentation and/or other materials provided with the distribution.
|
||
|
.\" 3. All advertising materials mentioning features or use of this software
|
||
|
.\" must display the following acknowledgement:
|
||
|
.\" This product includes software developed by the University of
|
||
|
.\" California, Berkeley and its contributors.
|
||
|
.\" 4. Neither the name of the University nor the names of its contributors
|
||
|
.\" may be used to endorse or promote products derived from this software
|
||
|
.\" without specific prior written permission.
|
||
|
.\"
|
||
|
.\" THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
|
||
|
.\" ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
|
||
|
.\" IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
|
||
|
.\" ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
|
||
|
.\" FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
|
||
|
.\" DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
|
||
|
.\" OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
|
||
|
.\" HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
|
||
|
.\" LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
|
||
|
.\" OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
|
||
|
.\" SUCH DAMAGE.
|
||
|
.\"
|
||
|
.\" @(#)5.t 8.1 (Berkeley) 6/8/93
|
||
|
.\"
|
||
|
.ds RH Functional enhancements
|
||
|
.NH
|
||
|
File system functional enhancements
|
||
|
.PP
|
||
|
The performance enhancements to the
|
||
|
UNIX file system did not require
|
||
|
any changes to the semantics or
|
||
|
data structures visible to application programs.
|
||
|
However, several changes had been generally desired for some
|
||
|
time but had not been introduced because they would require users to
|
||
|
dump and restore all their file systems.
|
||
|
Since the new file system already
|
||
|
required all existing file systems to
|
||
|
be dumped and restored,
|
||
|
these functional enhancements were introduced at this time.
|
||
|
.NH 2
|
||
|
Long file names
|
||
|
.PP
|
||
|
File names can now be of nearly arbitrary length.
|
||
|
Only programs that read directories are affected by this change.
|
||
|
To promote portability to UNIX systems that
|
||
|
are not running the new file system, a set of directory
|
||
|
access routines have been introduced to provide a consistent
|
||
|
interface to directories on both old and new systems.
|
||
|
.PP
|
||
|
Directories are allocated in 512 byte units called chunks.
|
||
|
This size is chosen so that each allocation can be transferred
|
||
|
to disk in a single operation.
|
||
|
Chunks are broken up into variable length records termed
|
||
|
directory entries. A directory entry
|
||
|
contains the information necessary to map the name of a
|
||
|
file to its associated inode.
|
||
|
No directory entry is allowed to span multiple chunks.
|
||
|
The first three fields of a directory entry are fixed length
|
||
|
and contain: an inode number, the size of the entry, and the length
|
||
|
of the file name contained in the entry.
|
||
|
The remainder of an entry is variable length and contains
|
||
|
a null terminated file name, padded to a 4 byte boundary.
|
||
|
The maximum length of a file name in a directory is
|
||
|
currently 255 characters.
|
||
|
.PP
|
||
|
Available space in a directory is recorded by having
|
||
|
one or more entries accumulate the free space in their
|
||
|
entry size fields. This results in directory entries
|
||
|
that are larger than required to hold the
|
||
|
entry name plus fixed length fields. Space allocated
|
||
|
to a directory should always be completely accounted for
|
||
|
by totaling up the sizes of its entries.
|
||
|
When an entry is deleted from a directory,
|
||
|
its space is returned to a previous entry
|
||
|
in the same directory chunk by increasing the size of the
|
||
|
previous entry by the size of the deleted entry.
|
||
|
If the first entry of a directory chunk is free, then
|
||
|
the entry's inode number is set to zero to indicate
|
||
|
that it is unallocated.
|
||
|
.NH 2
|
||
|
File locking
|
||
|
.PP
|
||
|
The old file system had no provision for locking files.
|
||
|
Processes that needed to synchronize the updates of a
|
||
|
file had to use a separate ``lock'' file.
|
||
|
A process would try to create a ``lock'' file.
|
||
|
If the creation succeeded, then the process
|
||
|
could proceed with its update;
|
||
|
if the creation failed, then the process would wait and try again.
|
||
|
This mechanism had three drawbacks.
|
||
|
Processes consumed CPU time by looping over attempts to create locks.
|
||
|
Locks left lying around because of system crashes had
|
||
|
to be manually removed (normally in a system startup command script).
|
||
|
Finally, processes running as system administrator
|
||
|
are always permitted to create files,
|
||
|
so were forced to use a different mechanism.
|
||
|
While it is possible to get around all these problems,
|
||
|
the solutions are not straight forward,
|
||
|
so a mechanism for locking files has been added.
|
||
|
.PP
|
||
|
The most general schemes allow multiple processes
|
||
|
to concurrently update a file.
|
||
|
Several of these techniques are discussed in [Peterson83].
|
||
|
A simpler technique is to serialize access to a file with locks.
|
||
|
To attain reasonable efficiency,
|
||
|
certain applications require the ability to lock pieces of a file.
|
||
|
Locking down to the byte level has been implemented in the
|
||
|
Onyx file system by [Bass81].
|
||
|
However, for the standard system applications,
|
||
|
a mechanism that locks at the granularity of a file is sufficient.
|
||
|
.PP
|
||
|
Locking schemes fall into two classes,
|
||
|
those using hard locks and those using advisory locks.
|
||
|
The primary difference between advisory locks and hard locks is the
|
||
|
extent of enforcement.
|
||
|
A hard lock is always enforced when a program tries to
|
||
|
access a file;
|
||
|
an advisory lock is only applied when it is requested by a program.
|
||
|
Thus advisory locks are only effective when all programs accessing
|
||
|
a file use the locking scheme.
|
||
|
With hard locks there must be some override
|
||
|
policy implemented in the kernel.
|
||
|
With advisory locks the policy is left to the user programs.
|
||
|
In the UNIX system, programs with system administrator
|
||
|
privilege are allowed override any protection scheme.
|
||
|
Because many of the programs that need to use locks must
|
||
|
also run as the system administrator,
|
||
|
we chose to implement advisory locks rather than
|
||
|
create an additional protection scheme that was inconsistent
|
||
|
with the UNIX philosophy or could
|
||
|
not be used by system administration programs.
|
||
|
.PP
|
||
|
The file locking facilities allow cooperating programs to apply
|
||
|
advisory
|
||
|
.I shared
|
||
|
or
|
||
|
.I exclusive
|
||
|
locks on files.
|
||
|
Only one process may have an exclusive
|
||
|
lock on a file while multiple shared locks may be present.
|
||
|
Both shared and exclusive locks cannot be present on
|
||
|
a file at the same time.
|
||
|
If any lock is requested when
|
||
|
another process holds an exclusive lock,
|
||
|
or an exclusive lock is requested when another process holds any lock,
|
||
|
the lock request will block until the lock can be obtained.
|
||
|
Because shared and exclusive locks are advisory only,
|
||
|
even if a process has obtained a lock on a file,
|
||
|
another process may access the file.
|
||
|
.PP
|
||
|
Locks are applied or removed only on open files.
|
||
|
This means that locks can be manipulated without
|
||
|
needing to close and reopen a file.
|
||
|
This is useful, for example, when a process wishes
|
||
|
to apply a shared lock, read some information
|
||
|
and determine whether an update is required, then
|
||
|
apply an exclusive lock and update the file.
|
||
|
.PP
|
||
|
A request for a lock will cause a process to block if the lock
|
||
|
can not be immediately obtained.
|
||
|
In certain instances this is unsatisfactory.
|
||
|
For example, a process that
|
||
|
wants only to check if a lock is present would require a separate
|
||
|
mechanism to find out this information.
|
||
|
Consequently, a process may specify that its locking
|
||
|
request should return with an error if a lock can not be immediately
|
||
|
obtained.
|
||
|
Being able to conditionally request a lock
|
||
|
is useful to ``daemon'' processes
|
||
|
that wish to service a spooling area.
|
||
|
If the first instance of the
|
||
|
daemon locks the directory where spooling takes place,
|
||
|
later daemon processes can
|
||
|
easily check to see if an active daemon exists.
|
||
|
Since locks exist only while the locking processes exist,
|
||
|
lock files can never be left active after
|
||
|
the processes exit or if the system crashes.
|
||
|
.PP
|
||
|
Almost no deadlock detection is attempted.
|
||
|
The only deadlock detection done by the system is that the file
|
||
|
to which a lock is applied must not already have a
|
||
|
lock of the same type (i.e. the second of two successive calls
|
||
|
to apply a lock of the same type will fail).
|
||
|
.NH 2
|
||
|
Symbolic links
|
||
|
.PP
|
||
|
The traditional UNIX file system allows multiple
|
||
|
directory entries in the same file system
|
||
|
to reference a single file. Each directory entry
|
||
|
``links'' a file's name to an inode and its contents.
|
||
|
The link concept is fundamental;
|
||
|
inodes do not reside in directories, but exist separately and
|
||
|
are referenced by links.
|
||
|
When all the links to an inode are removed,
|
||
|
the inode is deallocated.
|
||
|
This style of referencing an inode does
|
||
|
not allow references across physical file
|
||
|
systems, nor does it support inter-machine linkage.
|
||
|
To avoid these limitations
|
||
|
.I "symbolic links"
|
||
|
similar to the scheme used by Multics [Feiertag71] have been added.
|
||
|
.PP
|
||
|
A symbolic link is implemented as a file that contains a pathname.
|
||
|
When the system encounters a symbolic link while
|
||
|
interpreting a component of a pathname,
|
||
|
the contents of the symbolic link is prepended to the rest
|
||
|
of the pathname, and this name is interpreted to yield the
|
||
|
resulting pathname.
|
||
|
In UNIX, pathnames are specified relative to the root
|
||
|
of the file system hierarchy, or relative to a process's
|
||
|
current working directory. Pathnames specified relative
|
||
|
to the root are called absolute pathnames. Pathnames
|
||
|
specified relative to the current working directory are
|
||
|
termed relative pathnames.
|
||
|
If a symbolic link contains an absolute pathname,
|
||
|
the absolute pathname is used,
|
||
|
otherwise the contents of the symbolic link is evaluated
|
||
|
relative to the location of the link in the file hierarchy.
|
||
|
.PP
|
||
|
Normally programs do not want to be aware that there is a
|
||
|
symbolic link in a pathname that they are using.
|
||
|
However certain system utilities
|
||
|
must be able to detect and manipulate symbolic links.
|
||
|
Three new system calls provide the ability to detect, read, and write
|
||
|
symbolic links; seven system utilities required changes
|
||
|
to use these calls.
|
||
|
.PP
|
||
|
In future Berkeley software distributions
|
||
|
it may be possible to reference file systems located on
|
||
|
remote machines using pathnames. When this occurs,
|
||
|
it will be possible to create symbolic links that span machines.
|
||
|
.NH 2
|
||
|
Rename
|
||
|
.PP
|
||
|
Programs that create a new version of an existing
|
||
|
file typically create the
|
||
|
new version as a temporary file and then rename the temporary file
|
||
|
with the name of the target file.
|
||
|
In the old UNIX file system renaming required three calls to the system.
|
||
|
If a program were interrupted or the system crashed between these calls,
|
||
|
the target file could be left with only its temporary name.
|
||
|
To eliminate this possibility the \fIrename\fP system call
|
||
|
has been added. The rename call does the rename operation
|
||
|
in a fashion that guarantees the existence of the target name.
|
||
|
.PP
|
||
|
Rename works both on data files and directories.
|
||
|
When renaming directories,
|
||
|
the system must do special validation checks to insure
|
||
|
that the directory tree structure is not corrupted by the creation
|
||
|
of loops or inaccessible directories.
|
||
|
Such corruption would occur if a parent directory were moved
|
||
|
into one of its descendants.
|
||
|
The validation check requires tracing the descendents of the target
|
||
|
directory to insure that it does not include the directory being moved.
|
||
|
.NH 2
|
||
|
Quotas
|
||
|
.PP
|
||
|
The UNIX system has traditionally attempted to share all available
|
||
|
resources to the greatest extent possible.
|
||
|
Thus any single user can allocate all the available space
|
||
|
in the file system.
|
||
|
In certain environments this is unacceptable.
|
||
|
Consequently, a quota mechanism has been added for restricting the
|
||
|
amount of file system resources that a user can obtain.
|
||
|
The quota mechanism sets limits on both the number of inodes
|
||
|
and the number of disk blocks that a user may allocate.
|
||
|
A separate quota can be set for each user on each file system.
|
||
|
Resources are given both a hard and a soft limit.
|
||
|
When a program exceeds a soft limit,
|
||
|
a warning is printed on the users terminal;
|
||
|
the offending program is not terminated
|
||
|
unless it exceeds its hard limit.
|
||
|
The idea is that users should stay below their soft limit between
|
||
|
login sessions,
|
||
|
but they may use more resources while they are actively working.
|
||
|
To encourage this behavior,
|
||
|
users are warned when logging in if they are over
|
||
|
any of their soft limits.
|
||
|
If users fails to correct the problem for too many login sessions,
|
||
|
they are eventually reprimanded by having their soft limit
|
||
|
enforced as their hard limit.
|
||
|
.ds RH Acknowledgements
|
||
|
.sp 2
|
||
|
.ne 1i
|