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Am-utils (4.4BSD Automounter Utilities) User Manual
For version 6.2a3, 27 November 2006
Erez Zadok
(Originally by Jan-Simon Pendry and Nick Williams)
Copyright © 1997-2006 Erez Zadok
Copyright © 1989 Jan-Simon Pendry
Copyright © 1989 Imperial College of Science, Technology & Medicine
Copyright © 1989 The Regents of the University of California.
All Rights Reserved.
Permission to copy this document, or any portion of it, as necessary for use of this software is granted provided this copyright notice and statement of permission are included.
Am-utils is the 4.4BSD Automounter Tool Suite, which includes the Amd automounter, the Amq query and control program, the Hlfsd daemon, and other tools. This Info file describes how to use and understand the tools within Am-utils.
License | Explains the terms and conditions for using and distributing Am-utils. | |
Source Distribution | How to get the latest Am-utils distribution. | |
Getting Additional Information | How to get additional information. | |
Introduction | An introduction to Automounting concepts. | |
History | History of am-utils' development. | |
1. Overview | An overview of Amd. | |
2. Supported Platforms | Machines and Systems supported by Amd. | |
3. Mount Maps | Details of mount maps. | |
4. Amd Command Line Options | All the Amd command line options explained. | |
5. Filesystem Types | The different mount types supported by Amd. | |
6. Amd Configuration File | The amd.conf file syntax and meaning. | |
7. Run-time Administration | How to start, stop and control Amd. | |
8. FSinfo | The FSinfo filesystem management tool. | |
9. Hlfsd | The Home-Link Filesystem server. | |
10. Assorted Tools | Other tools which come with am-utils. | |
11. Examples | Some examples showing how Amd might be used. | |
12. Internals | Implementation details. | |
Acknowledgments & Trademarks | Legal Notes. | |
Indexes | ||
---|---|---|
Index | An item for each concept. |
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Am-utils is not in the public domain; it is copyrighted and there are restrictions on its distribution.
Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met:
"This product includes software developed by the University of California, Berkeley and its contributors, as well as the Trustees of Columbia University." |
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.
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The Am-utils home page is located in
http://www.am-utils.org/ |
You can get the latest distribution version of Am-utils from
ftp://ftp.am-utils.org/pub/am-utils/am-utils.tar.gz |
Additional alpha, beta, and release distributions are available in
ftp://ftp.am-utils.org/pub/am-utils/. |
Revision 5.2 was part of the 4.3BSD Reno distribution.
Revision 5.3bsdnet, a late alpha version of 5.3, was part of the BSD network version 2 distribution
Revision 6.0 was made independently by Erez Zadok at the Computer Science Department of Columbia University, as part of his PhD thesis work. Am-utils (especially version 6.1) continues to be developed and maintained at the Computer Science Department of Stony Brook University, as a service to the user community.
See section History, for more details.
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Before reporting a bug, see if it is a known one in the bugs file.
If you find a problem and hopefully you can reproduce it, please describe it in detail and submit a bug report via Bugzilla. Alternatively, you can send your bug report to the "am-utils" list (see http://www.am-utils.org/ under "Mailing Lists") quoting the details of the release and your configuration. These details can be obtained by running the command `amd -v'. It would greatly help if you could provide a reproducible procedure for detecting the bug you are reporting.
Providing working patches is highly encouraged. Every patch incorporated, however small, will get its author an honorable mention in the authors file.
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There are several mailing lists for people interested in keeping up-to-date with developments.
To subscribe, visit http://www.am-utils.org/ under "Mailing Lists." After subscribing, you can post a message to this list. To avoid as much spam as possible, only subscribers to this list may post to it.
Subscribers of `am-utils' are most helpful if they have the time and resources to test new and development versions of amd, on as many different platforms as possible. They should also be prepared to learn and use the GNU Autoconf, Automake, and Libtool packages, as needed; and of course, become familiar with the complex code in the am-utils package. In other words, subscribers on this list should hopefully be able to contribute meaningfully to the development of amd.
Note that this `am-utils' list used to be called `amd-dev' before January 1st, 2004. Please use the new name, `am-utils'.
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Erez Zadok wrote a book, titled Linux NFS and Automounter Administration, ISBN 0-7821-2739-8, (Sybex, 2001). The book is full of details and examples that go beyond what this manual has. The book also covers NFS in great detail. Although the book is geared toward Linux users, it is general enough for any Unix administrator and contains specific sections for non-Linux systems.
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An automounter maintains a cache of mounted filesystems. Filesystems are mounted on demand when they are first referenced, and unmounted after a period of inactivity.
Amd may be used as a replacement for Sun's automounter. The choice of which filesystem to mount can be controlled dynamically with selectors. Selectors allow decisions of the form "hostname is this," or "architecture is not that." Selectors may be combined arbitrarily. Amd also supports a variety of filesystem types, including NFS, UFS and the novel program filesystem. The combination of selectors and multiple filesystem types allows identical configuration files to be used on all machines thus reducing the administrative overhead.
Amd ensures that it will not hang if a remote server goes down. Moreover, Amd can determine when a remote server has become inaccessible and then mount replacement filesystems as and when they become available.
Amd contains no proprietary source code and has been ported to numerous flavors of Unix.
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The Amd package has been without an official maintainer since 1992. Several people have stepped in to maintain it unofficially. Most notable were the `upl' (Unofficial Patch Level) releases of Amd, created by me (Erez Zadok), and available from ftp://ftp.am-utils.org/pub/amd/. The last such unofficial release was `upl102'.
Through the process of patching and aging, it was becoming more and more apparent that Amd was in much need of revitalizing. Maintaining Amd had become a difficult task. I took it upon myself to cleanup the code, so that it would be easier to port to new platforms, add new features, keep up with the many new feature requests, and deal with the never ending stream of bug reports.
I have been working on such a release of Amd on and off since January of 1996. The new suite of tools is currently named "am-utils" (AutoMounter Utilities), in line with GNU naming conventions, befitting the contents of the package. In October of 1996 I had received enough offers to help me with this task that I decided to make a mailing list for this group of people. Around the same time, Amd had become a necessary part of my PhD thesis work, resulting in more work performed on am-utils.
Am-utils version 6.0 was numbered with a major new release number to
distinguish it from the last official release of Amd (5.x). Many
new features have been added such as a GNU configure
system, NFS
Version 3, a run-time configuration file (`amd.conf'), many new ports,
more scripts and programs, as well as numerous bug fixes. Another
reason for the new major release number was to alert users of am-utils
that user-visible interfaces may have changed. In order to make Amd
work well for the next 10 years, and be easier to maintain, it was
necessary to remove old or unused features, change various syntax files,
etc. However, great care was taken to ensure the maximum possible
backwards compatibility.
Am-utils version 6.1 has autofs support for Linux and Solaris 2.5+ as
the major new feature, in addition to several other minor new
features. The autofs support is completely transparent to the
end-user, aside from the fact that /bin/pwd
now always returns
the correct amd-ified path. The administrator can easily switch
between NFS and autofs mounts by changing one parameter in
amd.conf
. Autofs support and maintenance was developed in
conjunction with Ion Badulescu.
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Amd maintains a cache of mounted filesystems. Filesystems are demand-mounted when they are first referenced, and unmounted after a period of inactivity. Amd may be used as a replacement for Sun's automount(8) program. It contains no proprietary source code and has been ported to numerous flavors of Unix. See section Supported Platforms.
Amd was designed as the basis for experimenting with filesystem layout and management. Although Amd has many direct applications it is loaded with additional features which have little practical use. At some point the infrequently used components may be removed to streamline the production system.
Amd supports the notion of replicated filesystems by evaluating each member of a list of possible filesystem locations one by one. Amd checks that each cached mapping remains valid. Should a mapping be lost - such as happens when a fileserver goes down - Amd automatically selects a replacement should one be available.
1.1 Fundamentals | ||
1.2 Filesystems and Volumes | ||
1.3 Volume Naming | ||
1.4 Volume Binding | ||
1.5 Operational Principles | ||
1.6 Mounting a Volume | ||
1.7 Automatic Unmounting | ||
1.8 Keep-alives | ||
1.9 Non-blocking Operation |
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The fundamental concept behind Amd is the ability to separate the name used to refer to a file from the name used to refer to its physical storage location. This allows the same files to be accessed with the same name regardless of where in the network the name is used. This is very different from placing `/n/hostname' in front of the pathname since that includes location dependent information which may change if files are moved to another machine.
By placing the required mappings in a centrally administered database, filesystems can be re-organized without requiring changes to configuration files, shell scripts and so on.
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Amd views the world as a set of fileservers, each containing one or more filesystems where each filesystem contains one or more volumes. Here the term volume is used to refer to a coherent set of files such as a user's home directory or a TeX distribution.
In order to access the contents of a volume, Amd must be told in which filesystem the volume resides and which host owns the filesystem. By default the host is assumed to be local and the volume is assumed to be the entire filesystem. If a filesystem contains more than one volume, then a sublink is used to refer to the sub-directory within the filesystem where the volume can be found.
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Volume names are defined to be unique across the entire network. A volume name is the pathname to the volume's root as known by the users of that volume. Since this name uniquely identifies the volume contents, all volumes can be named and accessed from each host, subject to administrative controls.
Volumes may be replicated or duplicated. Replicated volumes contain identical copies of the same data and reside at two or more locations in the network. Each of the replicated volumes can be used interchangeably. Duplicated volumes each have the same name but contain different, though functionally identical, data. For example, `/vol/tex' might be the name of a TeX distribution which varied for each machine architecture.
Amd provides facilities to take advantage of both replicated and duplicated volumes. Configuration options allow a single set of configuration data to be shared across an entire network by taking advantage of replicated and duplicated volumes.
Amd can take advantage of replacement volumes by mounting them as required should an active fileserver become unavailable.
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Unix implements a namespace of hierarchically mounted filesystems. Two forms of binding between names and files are provided. A hard link completes the binding when the name is added to the filesystem. A soft link delays the binding until the name is accessed. An automounter adds a further form in which the binding of name to filesystem is delayed until the name is accessed.
The target volume, in its general form, is a tuple (host, filesystem, sublink) which can be used to name the physical location of any volume in the network.
When a target is referenced, Amd ignores the sublink element and determines whether the required filesystem is already mounted. This is done by computing the local mount point for the filesystem and checking for an existing filesystem mounted at the same place. If such a filesystem already exists then it is assumed to be functionally identical to the target filesystem. By default there is a one-to-one mapping between the pair (host, filesystem) and the local mount point so this assumption is valid.
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Amd operates by introducing new mount points into the namespace. These are called automount points. The kernel sees these automount points as NFS filesystems being served by Amd. Having attached itself to the namespace, Amd is now able to control the view the rest of the system has of those mount points. RPC calls are received from the kernel one at a time.
When a lookup call is received Amd checks whether the name is already known. If it is not, the required volume is mounted. A symbolic link pointing to the volume root is then returned. Once the symbolic link is returned, the kernel will send all other requests direct to the mounted filesystem.
If a volume is not yet mounted, Amd consults a configuration mount-map corresponding to the automount point. Amd then makes a runtime decision on what and where to mount a filesystem based on the information obtained from the map.
Amd does not implement all the NFS requests; only those relevant to name binding such as lookup, readlink and readdir. Some other calls are also implemented but most simply return an error code; for example mkdir always returns "read-only filesystem".
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Each automount point has a corresponding mount map. The mount map contains a list of key-value pairs. The key is the name of the volume to be mounted. The value is a list of locations describing where the filesystem is stored in the network. In the source for the map the value would look like
location1 location2 … locationN |
Amd examines each location in turn. Each location may contain selectors which control whether Amd can use that location. For example, the location may be restricted to use by certain hosts. Those locations which cannot be used are ignored.
Amd attempts to mount the filesystem described by each remaining location until a mount succeeds or Amd can no longer proceed. The latter can occur in three ways:
Once a volume has been mounted, Amd establishes a volume mapping which is used to satisfy subsequent requests.
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To avoid an ever increasing number of filesystem mounts, Amd removes
volume mappings which have not been used recently. A time-to-live
interval is associated with each mapping and when that expires the
mapping is removed. When the last reference to a filesystem is removed,
that filesystem is unmounted. If the unmount fails, for example the
filesystem is still busy, the mapping is re-instated and its
time-to-live interval is extended. The global default for this grace
period is controlled by the -w
command-line option (see section -w) or the amd.conf parameter `dismount_interval'
(see section dismount_interval Parameter). It is also possible to set this
value on a per-mount basis (see section opts).
Filesystems can be forcefully timed out using the Amq command. See section Run-time Administration. Note that on new enough systems that support forced unmounts, such as Linux, Amd can try to use the umount2(2) system call to force the unmount, if the regular umount(2) system call failed in a way that indicates that the mount point is hung or stale. See section forced_unmounts Parameter.
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Use of some filesystem types requires the presence of a server on another machine. If a machine crashes then it is of no concern to processes on that machine that the filesystem is unavailable. However, to processes on a remote host using that machine as a fileserver this event is important. This situation is most widely recognized when an NFS server crashes and the behavior observed on client machines is that more and more processes hang. In order to provide the possibility of recovery, Amd implements a keep-alive interval timer for some filesystem types. Currently only NFS makes use of this service.
The basis of the NFS keep-alive implementation is the observation that most sites maintain replicated copies of common system data such as manual pages, most or all programs, system source code and so on. If one of those servers goes down it would be reasonable to mount one of the others as a replacement.
The first part of the process is to keep track of which fileservers are
up and which are down. Amd does this by sending RPC requests to the
servers' NFS NullProc
and checking whether a reply is returned.
While the server state is uncertain the requests are re-transmitted at
three second intervals and if no reply is received after four attempts
the server is marked down. If a reply is received the fileserver is
marked up and stays in that state for 30 seconds at which time another
NFS ping is sent. This interval is configurable and can even be
turned off using the ping option. See section opts Option.
Once a fileserver is marked down, requests continue to be sent every 30 seconds in order to determine when the fileserver comes back up. During this time any reference through Amd to the filesystems on that server fail with the error "Operation would block". If a replacement volume is available then it will be mounted, otherwise the error is returned to the user.
Although this action does not protect user files, which are unique on the network, or processes which do not access files via Amd or already have open files on the hung filesystem, it can prevent most new processes from hanging.
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Since there is only one instance of Amd for each automount point, and usually only one instance on each machine, it is important that it is always available to service kernel calls. Amd goes to great lengths to ensure that it does not block in a system call. As a last resort Amd will fork before it attempts a system call that may block indefinitely, such as mounting an NFS filesystem. Other tasks such as obtaining filehandle information for an NFS filesystem, are done using a purpose built non-blocking RPC library which is integrated with Amd's task scheduler. This library is also used to implement NFS keep-alives (see section Keep-alives).
Whenever a mount is deferred or backgrounded, Amd must wait for it to complete before replying to the kernel. However, this would cause Amd to block waiting for a reply to be constructed. Rather than do this, Amd simply drops the call under the assumption that the kernel RPC mechanism will automatically retry the request.
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Am-utils has been ported to a wide variety of machines and operating systems. Am-utils's code works for little-endian and big-endian machines, as well as 32 bit and 64 bit architectures. Furthermore, when Am-utils ports to an Operating System on one architecture, it is generally readily portable to the same Operating System on all platforms on which it is available.
See the `INSTALL' in the distribution for more specific details on building and/or configuring for some systems.
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Amd has no built-in knowledge of machines or filesystems. External mount-maps are used to provide the required information. Specifically, Amd needs to know when and under what conditions it should mount filesystems.
The map entry corresponding to the requested name contains a list of possible locations from which to resolve the request. Each location specifies filesystem type, information required by that filesystem (for example the block special device in the case of UFS), and some information describing where to mount the filesystem (see section fs Option). A location may also contain selectors (see section Selectors).
3.1 Map Types | ||
3.2 How keys are looked up | ||
3.3 Location Format |
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A mount-map provides the run-time configuration information to Amd. Maps can be implemented in many ways. Some of the forms supported by Amd are regular files, ndbm databases, NIS maps, the Hesiod name server, and even the password file.
A mount-map name is a sequence of characters. When an automount point is created a handle on the mount-map is obtained. For each map type configured, Amd attempts to reference the map of the appropriate type. If a map is found, Amd notes the type for future use and deletes the reference, for example closing any open file descriptors. The available maps are configured when Amd is built and can be displayed by running the command `amd -v'.
When using an Amd configuration file (see section Amd Configuration File) and the keyword `map_type' (see section map_type Parameter), you may force the map used to any type.
By default, Amd caches data in a mode dependent on the type of map. This is the same as specifying `cache:=mapdefault' and selects a suitable default cache mode depending on the map type. The individual defaults are described below. The cache option can be specified on automount points to alter the caching behavior (see section Automount Filesystem (`auto')).
The following map types have been implemented, though some are not available on all machines. Run the command `amd -v' to obtain a list of map types configured on your machine.
3.1.1 File maps | ||
3.1.2 ndbm maps | ||
3.1.3 NIS maps | ||
3.1.4 NIS+ maps | ||
3.1.5 Hesiod maps | ||
3.1.6 Password maps | ||
3.1.7 Union maps | ||
3.1.8 LDAP maps | ||
3.1.9 Executable maps |
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When Amd searches a file for a map entry it does a simple scan of the file and supports both comments and continuation lines.
Continuation lines are indicated by a backslash character (`\') as the last character of a line in the file. The backslash, newline character and any leading white space on the following line are discarded. A maximum line length of 2047 characters is enforced after continuation lines are read but before comments are stripped. Each line must end with a newline character; that is newlines are terminators, not separators. The following examples illustrate this:
key valA valB; \ valC |
specifies three locations, and is identical to
key valA valB; valC |
However,
key valA valB;\ valC |
specifies only two locations, and is identical to
key valA valB;valC |
After a complete line has been read from the file, including continuations, Amd determines whether there is a comment on the line. A comment begins with a hash ("`#'") character and continues to the end of the line. There is no way to escape or change the comment lead-in character.
Note that continuation lines and comment support only apply to
file maps, or ndbm maps built with the mk-amd-map
program.
When caching is enabled, file maps have a default cache mode of
all
(see section Automount Filesystem (`auto')).
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An ndbm map may be used as a fast access form of a file map. The program,
mk-amd-map
, converts a normal map file into an ndbm database.
This program supports the same continuation and comment conventions that
are provided for file maps. Note that ndbm format files may not
be sharable across machine architectures. The notion of speed generally
only applies to large maps; a small map, less than a single disk block,
is almost certainly better implemented as a file map.
ndbm maps have a default cache mode of `all' (see section Automount Filesystem (`auto')).
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When using NIS (formerly YP), an Amd map is implemented directly by the underlying NIS map. Comments and continuation lines are not supported in the automounter and must be stripped when constructing the NIS server's database.
NIS maps have a default cache mode of all
(see section Automount Filesystem (`auto')).
The following rule illustrates what could be added to your NIS `Makefile', in this case causing the `amd.home' map to be rebuilt:
$(YPTSDIR)/amd.home.time: $(ETCDIR)/amd.home -@sed -e "s/#.*$$//" -e "/^$$/d" $(ETCDIR)/amd.home | \ awk '{ \ for (i = 1; i <= NF; i++) \ if (i == NF) { \ if (substr($$i, length($$i), 1) == "\\") \ printf("%s", substr($$i, 1, length($$i) - 1)); \ else \ printf("%s\n", $$i); \ } \ else \ printf("%s ", $$i); \ }' | \ $(MAKEDBM) - $(YPDBDIR)/amd.home; \ touch $(YPTSDIR)/amd.home.time; \ echo "updated amd.home"; \ if [ ! $(NOPUSH) ]; then \ $(YPPUSH) amd.home; \ echo "pushed amd.home"; \ else \ : ; \ fi |
Here $(YPTSDIR)
contains the time stamp files, and
$(YPDBDIR)
contains the dbm format NIS files.
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NIS+ maps do not support cache mode `all' and, when caching is enabled, have a default cache mode of `inc'.
XXX: FILL IN WITH AN EXAMPLE.
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When the map name begins with the string `hesiod.' lookups are made
using the Hesiod name server. The string following the dot is
used as a name qualifier and is prepended with the key being located.
The entire string is then resolved in the automount
context, or
the amd.conf parameter `hesiod_base' (see section hesiod_base Parameter). For example, if the key is `jsp' and map name is
`hesiod.homes' then Hesiod is asked to resolve
`jsp.homes.automount'.
Hesiod maps do not support cache mode `all' and, when caching is enabled, have a default cache mode of `inc' (see section Automount Filesystem (`auto')).
The following is an example of a Hesiod map entry:
jsp.homes.automount HS TXT "rfs:=/home/charm;rhost:=charm;sublink:=jsp" njw.homes.automount HS TXT "rfs:=/home/dylan/dk2;rhost:=dylan;sublink:=njw" |
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The password map support is unlike the four previous map types. When the map name is the string `/etc/passwd' Amd can lookup a user name in the password file and re-arrange the home directory field to produce a usable map entry.
Amd assumes the home directory has the format
`/anydir/dom1/../domN/login'.
It breaks this string into a map entry where ${rfs}
has the
value `/anydir/domN', ${rhost}
has the value
`domN.....dom1', and ${sublink}
has the
value login.
Thus if the password file entry was
/home/achilles/jsp |
the map entry used by Amd would be
rfs:=/home/achilles;rhost:=achilles;sublink:=jsp |
Similarly, if the password file entry was
/home/cc/sugar/mjh |
the map entry used by Amd would be
rfs:=/home/sugar;rhost:=sugar.cc;sublink:=mhj |
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The union map support is provided specifically for use with the union filesystem, see section Union Filesystem (`union').
It is identified by the string `union:' which is followed by a colon separated list of directories. The directories are read in order, and the names of all entries are recorded in the map cache. Later directories take precedence over earlier ones. The union filesystem type then uses the map cache to determine the union of the names in all the directories.
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LDAP (Lightweight Directory Access Protocol) maps do not support cache mode `all' and, when caching is enabled, have a default cache mode of `inc'.
For example, an Amd map `amd.home' that looks as follows:
/defaults opts:=rw,intr;type:=link zing -rhost:=shekel \ host==shekel \ host!=shekel;type:=nfs |
when converted to LDAP (see section amd2ldif), will result in the following LDAP database:
$ amd2ldif amd.home CUCS < amd.home dn: cn=amdmap timestamp, CUCS cn : amdmap timestamp objectClass : amdmapTimestamp amdmapTimestamp: 873071363 dn: cn=amdmap amd.home[/defaults], CUCS cn : amdmap amd.home[/defaults] objectClass : amdmap amdmapName : amd.home amdmapKey : /defaults amdmapValue : opts:=rw,intr;type:=link dn: cn=amdmap amd.home[], CUCS cn : amdmap amd.home[] objectClass : amdmap amdmapName : amd.home amdmapKey : amdmapValue : dn: cn=amdmap amd.home[zing], CUCS cn : amdmap amd.home[zing] objectClass : amdmap amdmapName : amd.home amdmapKey : zing amdmapValue : -rhost:=shekel host==shekel host!=shekel;type:=nfs |
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An executable map is a dynamic map in which the keys and values for the maps are generated on the fly by a program or script. The program is expected to take a single parameter argument which is the key to lookup. If the key is found, the program should print on stdout the key-value pair that were found; if the key was not found, nothing should be printed out. Below is an sample of such a map script:
#!/bin/sh # executable map example case "$1" in "/defaults" ) echo "/defaults type:=nfs;rfs:=filer" ;; "a" ) echo "a type:=nfs;fs:=/tmp" ;; "b" ) echo "b type:=link;fs:=/usr/local" ;; * ) # no match, echo nothing ;; esac |
See section exec_map_timeout Parameter.
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The key is located in the map whose type was determined when the automount point was first created. In general the key is a pathname component. In some circumstances this may be modified by variable expansion (see section Variable Expansion) and prefixing. If the automount point has a prefix, specified by the pref option, then that is prepended to the search key before the map is searched.
If the map cache is a `regexp' cache then the key is treated as an egrep-style regular expression, otherwise a normal string comparison is made.
If the key cannot be found then a wildcard match is attempted. Amd repeatedly strips the basename from the key, appends `/*' and attempts a lookup. Finally, Amd attempts to locate the special key `*'.
For example, the following sequence would be checked if `home/dylan/dk2' was being located:
home/dylan/dk2 home/dylan/* home/* * |
At any point when a wildcard is found, Amd proceeds as if an exact match had been found and the value field is then used to resolve the mount request, otherwise an error code is propagated back to the kernel. (see section Filesystem Types).
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The value field from the lookup provides the information required to mount a filesystem. The information is parsed according to the syntax shown below.
location-list: location-selection location-list white-space || white-space location-selection location-selection: location location-selection white-space location location: location-info -location-info - location-info: sel-or-opt location-info;sel-or-opt ; sel-or-opt: selection opt-ass selection: selector==value selector!=value opt-ass: option:=value white-space: space tab |
Note that unquoted whitespace is not allowed in a location description. White space is only allowed, and is mandatory, where shown with non-terminal white-space.
A location-selection is a list of possible volumes with which to satisfy the request. Each location-selection is tried sequentially, until either one succeeds or all fail. This, by the way, is different from the historically documented behavior, which claimed (falsely, at least for last 3 years) that Amd would attempt to mount all location-selections in parallel and the first one to succeed would be used.
location-selections are optionally separated by the `||' operator. The effect of this operator is to prevent use of location-selections to its right if any of the location-selections on its left were selected, whether or not any of them were successfully mounted (see section Selectors).
The location-selection, and singleton location-list, `type:=ufs;dev:=/dev/xd1g' would inform Amd to mount a UFS filesystem from the block special device `/dev/xd1g'.
The sel-or-opt component is either the name of an option required by a specific filesystem, or it is the name of a built-in, predefined selector such as the architecture type. The value may be quoted with double quotes `"', for example `type:="ufs";dev:="/dev/xd1g"'. These quotes are stripped when the value is parsed and there is no way to get a double quote into a value field. Double quotes are used to get white space into a value field, which is needed for the program filesystem (see section Program Filesystem (`program')).
3.3.1 Map Defaults | ||
3.3.2 Variable Expansion | ||
3.3.3 Selectors | ||
3.3.4 Map Options |
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A location beginning with a dash `-' is used to specify default values for subsequent locations. Any previously specified defaults in the location-list are discarded. The default string can be empty in which case no defaults apply.
The location `-fs:=/mnt;opts:=ro' would set the local mount point to `/mnt' and cause mounts to be read-only by default. Defaults specified this way are appended to, and so override, any global map defaults given with `/defaults').
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To allow generic location specifications Amd does variable expansion
on each location and also on some of the option strings. Any option or
selector appearing in the form $var
is replaced by the
current value of that option or selector. For example, if the value of
${key}
was `bin', ${autodir}
was `/a' and
${fs}
was `${autodir}/local/${key}' then
after expansion ${fs}
would have the value `/a/local/bin'.
Any environment variable can be accessed in a similar way.
Two pathname operators are available when expanding a variable. If the
variable name begins with `/' then only the last component of the
pathname is substituted. For example, if ${path}
was
`/foo/bar' then ${/path}
would be expanded to `bar'.
Similarly, if the variable name ends with `/' then all but the last
component of the pathname is substituted. In the previous example,
${path/}
would be expanded to `/foo'.
Two domain name operators are also provided. If the variable name
begins with `.' then only the domain part of the name is
substituted. For example, if ${rhost}
was
`swan.doc.ic.ac.uk' then ${.rhost}
would be expanded to
`doc.ic.ac.uk'. Similarly, if the variable name ends with `.'
then only the host component is substituted. In the previous example,
${rhost.}
would be expanded to `swan'.
Variable expansion is a two phase process. Before a location is parsed,
all references to selectors, eg ${path}
, are expanded. The
location is then parsed, selections are evaluated and option assignments
recorded. If there were no selections or they all succeeded the
location is used and the values of the following options are expanded in
the order given: sublink, rfs, fs, opts,
remopts, mount and unmount.
Note that expansion of option values is done after all assignments have been completed and not in a purely left to right order as is done by the shell. This generally has the desired effect but care must be taken if one of the options references another, in which case the ordering can become significant.
There are two special cases concerning variable expansion:
${key}
would be
`vax.bin'.
${rhost}
is expanded and normalized before the
other options are expanded. The normalization process strips any local
sub-domain components. For example, if ${domain}
was
`Berkeley.EDU' and ${rhost}
was initially
`snow.Berkeley.EDU', after the normalization it would simply be
`snow'. Hostname normalization is currently done in a
case-dependent manner.
@c======================================================================
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Selectors are used to control the use of a location. It is possible to share a mount map between many machines in such a way that filesystem location, architecture and operating system differences are hidden from the users. A selector of the form `arch==sun3;os==sunos4' would only apply on Sun-3s running SunOS 4.x.
Selectors can be negated by using `!=' instead of `=='. For example to select a location on all non-Vax machines the selector `arch!=vax' would be used.
Selectors are evaluated left to right. If a selector fails then that location is ignored. Thus the selectors form a conjunction and the locations form a disjunction. If all the locations are ignored or otherwise fail then Amd uses the error filesystem (see section Error Filesystem (`error')). This is equivalent to having a location `type:=error' at the end of each mount-map entry.
The default value of many of the selectors listed here can be overridden by an Amd command line switch or in an Amd configuration file. See section Amd Configuration File.
The following selectors are currently implemented.
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The machine architecture which was automatically determined at compile
time. The architecture type can be displayed by running the command
`amd -v'. You can override this value also using the -A
command line option. See section Supported Platforms.
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The default directory under which to mount filesystems. This may be
changed by the -a
command line option. See section fs Option.
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The machine's byte ordering. This is either `little', indicating little-endian, or `big', indicating big-endian. One possible use is to share `rwho' databases (see section `rwho' servers). Another is to share ndbm databases, however this use can be considered a courageous juggling act.
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This is provided as a hook for the name of the local cluster. This can
be used to decide which servers to use for copies of replicated
filesystems. ${cluster}
defaults to the value of
${domain}
unless a different value is set with the -C
command line option.
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The local domain name as specified by the -d
command line option.
See section host Selector Variable.
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This is a special variable, whose sole purpose is to produce a literal dollar sign in the value of another variable. For example, if you have a remote file system whose name is `/disk$s', you can mount it by setting the remote file system variable as follows:
rfs:=/disk${dollar}s |
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The local hostname as determined by gethostname(2). If no domain
name was specified on the command line and the hostname contains a
period `.' then the string before the period is used as the host
name, and the string after the period is assigned to ${domain}
.
For example, if the hostname is `styx.doc.ic.ac.uk' then
host
would be `styx' and domain
would be
`doc.ic.ac.uk'. hostd
would be
`styx.doc.ic.ac.uk'.
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This resolves to the ${host}
and ${domain}
concatenated with a `.' inserted between them if required. If
${domain}
is an empty string then ${host}
and
${hostd}
will be identical.
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This is provided as a hook for the kernel architecture. This is used on
SunOS 4 and SunOS 5, for example, to distinguish between different
`/usr/kvm' volumes. ${karch}
defaults to the "machine"
value gotten from uname(2). If the uname(2) system call is not
available, the value of ${karch}
defaults to that of
${arch}
. Finally, a different value can be set with the -k
command line option.
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The operating system. Like the machine architecture, this is automatically determined at compile time. The operating system name can be displayed by running the command `amd -v'. See section Supported Platforms.
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The operating system version. Like the machine architecture, this is automatically determined at compile time. The operating system name can be displayed by running the command `amd -v'. See section Supported Platforms.
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The full name of the operating system, including its version. This value is automatically determined at compile time. The full operating system name and version can be displayed by running the command `amd -v'. See section Supported Platforms.
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The name of the vendor of the operating system. This value is automatically determined at compile time. The name of the vendor can be displayed by running the command `amd -v'. See section Supported Platforms.
<HR>
The following selectors are also provided. Unlike the other selectors,
they vary for each lookup. Note that when the name from the kernel is
expanded prior to a map lookup, these selectors are all defined as empty
strings.
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The name being resolved. For example, if `/home' is an automount
point, then accessing `/home/foo' would set ${key}
to the
string `foo'. The key is prefixed by the pref option set in
the parent mount point. The default prefix is an empty string. If the
prefix was `blah/' then ${key}
would be set to
`blah/foo'.
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The name of the mount map being used.
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This selector is identical to the `in_network' selector function, see in_network Selector Function. It will match either the name or number of any network interface on which this host is connected to. The names and numbers of all attached interfaces are available from the output of `amd -v'.
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This selector is identical to the `in_network' selector function, see in_network Selector Function. It will match either the name or number of any network interface on which this host is connected to. The names and numbers of all attached interfaces are available from the output of `amd -v'.
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The full pathname of the name being resolved. For example `/home/foo' in the example above.
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This selector is identical to the `in_network' selector function, see in_network Selector Function. It will match either the name or number of any network interface on which this host is connected to. The names and numbers of all attached interfaces are available from the output of `amd -v'.
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This selector provides the numeric effective user ID (UID) of the user which last accessed an automounted path name. This simple example shows how floppy mounting can be assigned only to machine owners:
floppy -type:=pcfs \ uid==2301;host==shekel;dev:=/dev/floppy \ uid==6712;host==titan;dev=/dev/fd0 \ uid==0;dev:=/dev/fd0c \ type:=error |
The example allows two machine owners to mount floppies on their designated workstations, allows the root user to mount on any host, and otherwise forces an error.
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This selector provides the numeric effective group ID (GID) of the user which last accessed an automounted path name.
<HR>
The following boolean functions are selectors which take an argument
ARG. They return a value of true or false, and thus do not need to
be compared with a value. Each of these may be negated by prepending
`!' to their name.
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If the file listed by ARG exists (via lstat(2)), this function evaluates to true. Otherwise it evaluates to false.
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Always evaluates to false. ARG is ignored.
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The argument ARG of this selector is a netgroup name followed
optionally by a comma and a host name. If the host name is not
specified, it defaults to ${host}
. If the host name (short
name) is a member of the netgroup, this selector evaluates to true.
Otherwise it evaluates to false.
For example, suppose you have a netgroup `ppp-hosts', and for reasons of performance, these have a local `/home' partition, while all other clients on the faster network can access a shared home directory. A common map to use for both might look like the following:
home/* netgrp(ppp-hosts);type:=link;fs:=/local/${key} \ !netgrp(ppp-hosts);type:=nfs;rhost:=serv1;rfs:=/remote/${key} |
A more complex example that takes advantage of the two argument netgrp mount selector is given in the following scenario. Suppose one wants to mount the local scratch space from a each host under `scratch/<hostname>' and some hosts have their scratch space in a different path than others. Hosts in the netgroup `apple-hosts' have their scratch space in the `/apple' path, where hosts in the netgroup `cherry-hosts' have their scratch space in the `/cherry' path. For hosts that are neither in the `apple-hosts' or `cherry-hosts' netgroups we want to make a symlink pointing to nowhere but provide a descriptive error message in the link destination:
scratch/* netgrp(apple-hosts,${/key});type:=nfs;rhost:=${/key};\ rfs:="/apple" \ netgrp(cherry-hosts,${/key});type:=nfs;rhost:=${/key};\ rfs:="/cherry" \ type:=link;rfs:="no local partition for ${/key}" |
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The argument ARG of this selector is a netgroup name followed
optionally by a comma and a host name. If the host name is not
specified, it defaults to ${hostd}
. If the host name
(fully-qualified name) is a member of the netgroup, this selector
evaluates to true. Otherwise it evaluates to false.
The `netgrpd' function uses fully-qualified host names to match netgroup names, while the `netgrp' function (see section netgrp Selector Function) uses short host names.
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This selector matches against any network name or number with an optional netmask. First, if the current host has any network interface that is locally attached to the network specified in ARG (either via name or number), this selector evaluates to true.
Second, `in_network' supports a network/netmask syntax such as `128.59.16.0/255.255.255.0', `128.59.16.0/24', `128.59.16.0/0xffffff00', or `128.59.16.0/'. Using the last form, Amd will match the specified network number against the default netmasks of each of the locally attached interfaces.
If the selector does not match, it evaluates to false.
For example, suppose you have two servers that have an exportable `/opt' that smaller clients can NFS mount. The two servers are say, `serv1' on network `foo-net.site.com' and `serv2' on network `123.4.5.0'. You can write a map to be used by all clients that will attempt to mount the closest one as follows:
opt in_network(foo-net.site.com);rhost:=serv1;rfs:=/opt \ in_network(123.4.5.0);rhost:=serv2;rfs:=/opt \ rhost:=fallback-server |
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Always evaluates to true. ARG is ignored.
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This function compares ARG against the current hostname, similarly to the host Selector Variable. However, this function will also match if ARG is a CNAME (DNS Canonical Name, or alias) for the current host's name.
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Options are parsed concurrently with selectors. The difference is that when an option is seen the string following the `:=' is recorded for later use. As a minimum the type option must be specified. Each filesystem type has other options which must also be specified. See section Filesystem Types, for details on the filesystem specific options.
Superfluous option specifications are ignored and are not reported as errors.
The following options apply to more than one filesystem type.
3.3.4.1 addopts Option | ||
3.3.4.2 delay Option | ||
3.3.4.3 fs Option | ||
3.3.4.4 opts Option | ||
3.3.4.5 remopts Option | ||
3.3.4.6 sublink Option | ||
3.3.4.7 type Option |
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This option adds additional options to default options normally specified in the `/defaults' entry or the defaults of the key entry being processed (see section opts Option). Normally when you specify `opts' in both the `/defaults' and the map entry, the latter overrides the former completely. But with `addopts' it will append the options and override any conflicting ones.
`addopts' also overrides the value of the `remopts' option (see section remopts Option), which unless specified defaults to the value of `opts'.
Options which start with `no' will override those with the same name that do not start with `no' and vice verse. Special handling is given to inverted options such as `soft' and `hard', `bg' and `fg', `ro' and `rw', etc.
For example, if the default options specified were
opts:=rw,nosuid,intr,rsize=1024,wsize=1024,quota,posix |
and the ones specified in a map entry were
addopts:=grpid,suid,ro,rsize=2048,quota,nointr |
then the actual options used would be
wsize=1024,posix,grpid,suid,ro,rsize=2048,quota,nointr |
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The delay, in seconds, before an attempt will be made to mount from the current location. Auxiliary data, such as network address, file handles and so on are computed regardless of this value.
A delay can be used to implement the notion of primary and secondary file servers. The secondary servers would have a delay of a few seconds, thus giving the primary servers a chance to respond first.
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The local mount point. The semantics of this option vary between filesystems.
For NFS and UFS filesystems the value of ${fs}
is used as the
local mount point. For other filesystem types it has other meanings
which are described in the section describing the respective filesystem
type. It is important that this string uniquely identifies the
filesystem being mounted. To satisfy this requirement, it should
contain the name of the host on which the filesystem is resident and the
pathname of the filesystem on the local or remote host.
The reason for requiring the hostname is clear if replicated filesystems are considered. If a fileserver goes down and a replacement filesystem is mounted then the local mount point must be different from that of the filesystem which is hung. Some encoding of the filesystem name is required if more than one filesystem is to be mounted from any given host.
If the hostname is first in the path then all mounts from a particular host will be gathered below a single directory. If that server goes down then the hung mount points are less likely to be accidentally referenced, for example when getcwd(3) traverses the namespace to find the pathname of the current directory.
The `fs' option defaults to
${autodir}/${rhost}${rfs}
. In addition,
`rhost' defaults to the local host name (${host}
) and
`rfs' defaults to the value of ${path}
, which is the full
path of the requested file; `/home/foo' in the example above
(see section Selectors). ${autodir}
defaults to `/a' but may
be changed with the -a
command line option. Sun's automounter
defaults to `/tmp_mnt'. Note that there is no `/' between
the ${rhost}
and ${rfs}
since ${rfs}
begins
with a `/'.
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The options to pass to the mount system call. A leading `-' is silently ignored. The mount options supported generally correspond to those used by mount(8) and are listed below. Some additional pseudo-options are interpreted by Amd and are also listed.
Unless specifically overridden, each of the system default mount options
applies. Any options not recognized are ignored. If no options list is
supplied the string `rw,defaults' is used and all the system
default mount options apply. Options which are not applicable for a
particular operating system are silently ignored. For example, only 4.4BSD
is known to implement the compress
and spongy
options.
acdirmax=n
Set the maximum directory attribute cache timeout to n.
acdirmin=n
Set the minimum directory attribute cache timeout to n.
acregmax=n
Set the maximum file attribute cache timeout to n.
acregmin=n
Set the minimum file attribute cache timeout to n.
actimeo=n
Set the overall attribute cache timeout to n.
auto
ignore
Ignore this mount by df(1).
cache
Allow data to be cached from a remote server for this mount.
compress
Use NFS compression protocol.
defperm
Ignore the permission mode bits, and default file permissions to 0555, UID 0, and GID 0. Useful for CD-ROMs formatted as ISO-9660.
dev
Allow local special devices on this filesystem.
dirmask=n
For PCFS mounts, specify the maximum file permissions for directories in the file system. See the `mask' option's description for more details. The mask value of n can be specified in decimal, octal, or hexadecimal.
dumbtimr
Turn off the dynamic retransmit timeout estimator. This may be useful for UDP mounts that exhibit high retry rates, since it is possible that the dynamically estimated timeout interval is too short.
extatt
Enable extended attributes in ISO-9660 file systems.
fsid
Set ID of filesystem.
gens
Enable generations in ISO-9660 file systems. Generations allow you to see all versions of a given file.
group=n
For PCFS mounts, set the group of the files in the file system to n (which can either be a group name or a GID number). The default group is the group of the directory on which the file system is being mounted.
grpid
Use BSD directory group-id semantics.
int
intr
Allow keyboard interrupts on hard mounts.
lock
Use the NFS locking protocol (default)
longname
For PCFS mounts, force Win95 long names.
mask=n
For PCFS mounts, specify the maximum file permissions for files in the file system. For example, a mask of 755 specifies that, by default, the owner should have read, write, and execute permissions for files, but others should only have read and execute permissions. Only the nine low-order bits of mask are used. The default mask is taken from the directory on which the file system is being mounted. The mask value of n can be specified in decimal, octal, or hexadecimal.
multi
Perform multi-component lookup on files.
maxgroups
Set the maximum number of groups to allow for this mount.
nfsv3
Use NFS Version 3 for this mount.
noac
Turn off the attribute cache.
noauto
This option is used by the mount command in `/etc/fstab' or `/etc/vfstab' and means not to mount this file system when mount -a is used.
nocache
Do not allow data to be cached from a remote server for this mount.
noconn
Don't make a connection on datagram transports.
nocto
No close-to-open consistency.
nodefperm
Do not ignore the permission mode bits. Useful for CD-ROMS formatted as ISO-9660.
nodev
nodevs
Don't allow local special devices on this filesystem.
noexec
Don't allow program execution.
noint
Do not allow keyboard interrupts for this mount
nolock
Do not use the NFS locking protocol
nomnttab
This option is used internally to tell Amd that a Solaris 8 system using mntfs is in use.
norrip
Turn off using of the Rock Ridge Interchange Protocol (RRIP) extensions to ISO-9660.
nosub
Disallow mounts beneath this mount.
nosuid
Don't allow set-uid or set-gid executables on this filesystem.
noversion
Strip the extension `;#' from the version string of files recorded on an ISO-9660 CD-ROM.
nowin95
For PCFS mounts, completely ignore Win95 entries.
optionstr
Under Solaris 8, provide the kernel a string of options to parse and show as part of the special in-kernel mount file system.
overlay
Overlay this mount on top of an existing mount, if any.
pgthresh=n
Set the paging threshold to n kilobytes.
port=n
Set the NFS port to n.
posix
Turn on POSIX static pathconf for mounts.
private
Use local locking instead of the NLM protocol, useful for IRIX 6 only.
proplist
Support property lists (ACLs) for this mount, useful primarily for Tru64 UNIX.
proto=s
Use transport protocol s for NFS (can be "tcp"
or "udp"
).
quota
Enable quota checking on this mount.
rdonly
ro
Mount this filesystem readonly.
resvport
Use a reserved port (smaller than 1024) for remote NFS mounts. Most systems assume that, but some allow for mounts to occur on non-reserved ports. This causes problems when such a system tries to NFS mount one that requires reserved ports. It is recommended that this option always be on.
retrans=n
The number of NFS retransmits made before a user error is generated by a `soft' mounted filesystem, and before a `hard' mounted filesystem reports `NFS server yoyo not responding still trying'.
retry
Set the NFS retry counter.
rrip
Uses the Rock Ridge Interchange Protocol (RRIP) extensions to ISO-9660.
rsize=n
The NFS read packet size. You may need to set this if you are using NFS/UDP through a gateway or a slow link.
rw
Allow reads and writes on this filesystem.
shortname
For PCFS mounts, force old DOS short names only.
soft
Give up after retrans retransmissions.
spongy
Like `soft' for status requests, and `hard' for data transfers.
suid
Allow set-uid programs on this mount.
symttl
Turn off the symbolic link cache time-to-live.
sync
Perform synchronous filesystem operations on this mount.
tcp
Use TCP/IP instead of UDP/IP, ignored if the NFS implementation does not support TCP/IP mounts.
timeo=n
The NFS timeout, in tenth-seconds, before a request is retransmitted.
user=n
For PCFS mounts, set the owner of the files in the file system to n (which can either be a user name or a UID number). The default owner is the owner of the directory on which the file system is being mounted.
vers=n
Use NFS protocol version number n (can be 2 or 3).
wsize=n
The NFS write packet size. You may need to set this if you are using NFS/UDP through a gateway or a slow link.
The following options are implemented by Amd, rather than being passed to the kernel.
nounmount
Configures the mount so that its time-to-live will never expire. This is the default for non-network based filesystem types (such as mounting local disks, floppies, and CD-ROMs). See also the related unmount option.
ping=n
The interval, in seconds, between keep-alive pings. When four consecutive pings have failed the mount point is marked as hung. This interval defaults to 30 seconds; if the ping interval is set to zero, Amd will use the default 30-second interval. If the interval is set to -1 (or any other negative value), no pings are sent and the host is assumed to be always up, which can cause unmounts to hang See the softlookup option for a better alternative. Turning pings off can be useful in NFS-HA (High-Availability) sites where the NFS service rarely goes down. Setting the ping value to a large value can reduce the amount of NFS_NULL chatter on your network considerably, especially in large sites.
Note that if you have multiple Amd entries using the same file server, and each entry sets a different value of N, then each time Amd mounts a new entry, the ping value will be re-evaluated (and updated, turned off, or turned back on as needed). Finally, note that NFS_NULL pings are sent for both UDP and TCP mounts, because even a hung TCP mount can cause user processes to hang.
public
Use WebNFS multi-component lookup on the public file handle instead of the mount protocol to obtain NFS file handles, as documented in the WebNFS Client Specification, RFC 2054. This means that Amd will not attempt to contact the remote portmapper or remote mountd daemon, and will only connect to the well-known NFS port 2049 or the port specified with the port mount option, thus making it easier to use NFS through a firewall.
retry=n
The number of times to retry the mount system call.
softlookup
Configures Amd's behavior with respect to already-mounted shares from NFS fileservers that are unreachable. If softlookup is specified, trying to access such a share will result in an error (EIO, which is changed from the ENOENT 6.0 used to return). If it is not specified, a regular symlink is provided and the access will probably hang in the NFS filesystem.
The default behavior depends on whether the mount is 'soft' or 'hard'; softlookup can be used to change this default. This is changed from 6.0 which always behaved as if softlookup was specified.
unmount
Configures the mount so that its time-to-live will indeed expire (and thus may be automatically unmounted). This is also the default for network-based filesystem types (e.g., NFS). This option is useful for removable local media such as CD-ROMs, USB drives, etc. so they can expire when not in use, and get unmounted (such drives can get work out when they keep spinning). See also the related nounmount option.
utimeout=n
The interval, in seconds, that looked up and mounted map entries are
cached. After that period of time, Amd will attempt to unmount
the entries. If, however, the unmount fails (with EBUSY), then
Amd will extend the mount's time-to-live by the utimeout value
before the next unmount attempt is made. In fact the interval is
extended before the unmount is attempted, to avoid thrashing. The
default value is 120 seconds (two minutes) or as set by the -w
command line option.
xlatecookie
Translate directory cookies between 32-long and 64-long lengths.
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This option has the same use as ${opts}
but applies only when
the remote host is on a non-local network. For example, when using NFS
across a gateway it is often necessary to use smaller values for the
data read and write sizes. This can simply be done by specifying the
small values in remopts. When a non-local host is accessed, the
smaller sizes will automatically be used.
Amd determines whether a host is local by examining the network interface configuration at startup. Any interface changes made after Amd has been started will not be noticed. The likely effect will be that a host may incorrectly be declared non-local.
Unless otherwise set, the value of ${remopts}
is the same as
the value of ${opts}
.
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The subdirectory within the mounted filesystem to which the reference should point. This can be used to prevent duplicate mounts in cases where multiple directories in the same mounted filesystem are used.
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The filesystem type to be used. See section Filesystem Types, for a full description of each type.
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Many of Amd's parameters can be set from the command line. The command line is also used to specify automount points and maps.
The general format of a command line is
amd [options] [{ directory map-name [-map-options] } ...] |
For each directory and map-name given or specified in the `amd.conf' file, Amd establishes an automount point. The map-options may be any sequence of options or selectors--see section Location Format. The map-options apply only to Amd's mount point.
`type:=toplvl;cache:=mapdefault;fs:=${map}' is the default value for the map options. Default options for a map are read from a special entry in the map whose key is the string `/defaults'. When default options are given they are prepended to any options specified in the mount-map locations as explained in Map Defaults.
The options are any combination of those listed below.
Once the command line has been parsed, the automount points are mounted. The mount points are created if they do not already exist, in which case they will be removed when Amd exits. Finally, Amd disassociates itself from its controlling terminal and forks into the background.
Note: Even if Amd has been built with `-DDEBUG' (via
configure --enable-debug
), it will still background itself and
disassociate itself from the controlling terminal. To use a debugger it
is necessary to specify `-D daemon' on the command line.
However, even with all of this, mounts and unmounts are performed in the
background, and Amd will always fork before doing them. Therefore,
debugging what happens closely during un/mounts is more challenging.
All of Amd's command options (save -F
and -T
)
can be specified in the `amd.conf' file. See section Amd Configuration File. If Amd is invoked without any command line options, it will
default to using the configuration file `/etc/amd.conf', if one
exists.
4.1 -a directory | Automount directory. | |
4.2 -c cache-interval | Cache timeout interval. | |
4.3 -d domain | Domain name. | |
4.4 -k kernel-architecture | Kernel architecture. | |
4.5 -l log-option | Log file. | |
4.6 -n | Hostname normalization. | |
4.7 -o op-sys-ver | Operating system version. | |
4.8 -p | Output process id. | |
4.9 -r | Restart existing mounts. | |
4.10 -t timeout.retransmit | Kernel RPC timeout. | |
4.11 -v | Version information. | |
4.12 -w wait-timeout | Wait interval after failed unmount. | |
4.13 -x opts | Log options. | |
4.14 -y NIS-domain | NIS domain. | |
4.15 -A architecture | Operating system Architecture. | |
4.16 -C cluster-name | Cluster name. | |
4.17 -D opts | Debug flags. | |
4.18 -F conf-file | Amd configuration file. | |
4.19 -H | Show brief help. | |
4.20 -O op-sys-name | Operating system name. | |
4.21 -S | Lock executable pages in memory. | |
4.22 -T tag | Set tag for configuration file. |
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-a
directory Specifies the default mount directory. This option changes the variable
${autodir}
which otherwise defaults to `/a'. For example,
some sites prefer `/amd' or `/n'.
amd -a /amd ... |
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-c
cache-interval Selects the period, in seconds, for which a name is cached by Amd. If no reference is made to the volume in this period, Amd discards the volume name to filesystem mapping.
Once the last reference to a filesystem has been removed, Amd attempts to unmount the filesystem. If the unmount fails the interval is extended by a further period as specified by the `-w' command line option or by the `utimeout' mount option.
The default cache-interval is 300 seconds (five minutes).
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-d
domain Specifies the host's domain. This sets the internal variable
${domain}
and affects the ${hostd}
variable.
If this option is not specified and the hostname already contains the
local domain then that is used, otherwise the default value of
${domain}
is `unknown.domain'.
For example, if the local domain was `doc.ic.ac.uk', Amd could be started as follows:
amd -d doc.ic.ac.uk ... |
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-k
kernel-architecture Specifies the kernel architecture of the system. This is usually the
output of `uname -m' (the "machine" value gotten from
uname(2)). If the uname(2) system call is not available, the
value of ${karch}
defaults to that of ${arch}
.
The only effect of this option is to set the variable ${karch}
.
This option would be used as follows:
amd -k `arch -k` ... |
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-l
log-option Selects the form of logging to be made. Several special log-options are recognized.
Any other string is taken as a filename to use for logging. Log messages are appended to the file if it already exists, otherwise a new file is created. The file is opened once and then held open, rather than being re-opened for each message.
Normally, when long-running daemons hold an open file descriptor on a
log file, it is impossible to "rotate" the log file and compress older
logs on a daily basis. The daemon needs to be told to discard (via
close(2)) its file handle, and re-open the log file. This is done
using amq -l
log-option. See section Amq -l
option.
If the `syslog' option is specified but the system does not support syslog or if the named file cannot be opened or created, Amd will use standard error. Error messages generated before Amd has finished parsing the command line are printed on standard error.
Since Amd tends to generate a lot of logging information (especially if debugging was turned on), and due to it being an important program running on the system, it is usually best to log to a separate disk file. In that case Amd would be started as follows:
amd -l /var/log/amd ... |
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-n
Normalizes the remote hostname before using it. Normalization is done
by replacing the value of ${rhost}
with the (generally fully
qualified) primary name returned by a hostname lookup.
This option should be used if several names are used to refer to a single host in a mount map.
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-o
op-sys-ver Overrides the compiled-in version number of the operating system, with op-sys-ver. Useful when the built-in version is not desired for backward compatibility reasons. For example, if the built-in version is `2.5.1', you can override it to `5.5.1', and use older maps that were written with the latter in mind.
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-p
Causes Amd's process id to be printed on standard output. This can be redirected to a suitable file for use with kill:
amd -p > /var/run/amd.pid ... |
This option only has an affect if Amd is running in daemon mode.
If Amd is started with the -D daemon
debug flag, this
option is ignored.
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-r
Tells Amd to restart existing mounts (see section Inheritance Filesystem (`inherit')).
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-t
timeout.retransmit Specifies the RPC timeout interval and the retransmit counter used by the kernel to communicate to Amd. These are used to set the `timeo' and `retrans' mount options, respectively. The default timeout is 0.8 seconds, and the default number of retransmissions is 11.
Amd relies on the kernel RPC retransmit mechanism to trigger mount retries. The values of these parameters change the overall retry interval. Too long an interval gives poor interactive response; too short an interval causes excessive retries.
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-v
Print version information on standard error and then exit. The output is of the form:
Copyright (c) 1997-1999 Erez Zadok Copyright (c) 1990 Jan-Simon Pendry Copyright (c) 1990 Imperial College of Science, Technology & Medicine Copyright (c) 1990 The Regents of the University of California. am-utils version 6.0a15 (build 61). Built by ezk@example.com on date Wed Oct 22 15:21:03 EDT 1997. cpu=sparc (big-endian), arch=sun4, karch=sun4u. full_os=solaris2.5.1, os=sos5, osver=5.5.1, vendor=sun. Map support for: root, passwd, union, nisplus, nis, ndbm, file, error. AMFS: nfs, link, nfsx, nfsl, host, linkx, program, union, inherit, ufs, lofs, hsfs, pcfs, auto, direct, toplvl, error. FS: autofs, cachefs, cdfs, lofs, nfs, nfs3, pcfs, tfs, tmpfs, ufs. Network 1: wire="mcl-lab-net.cs.columbia.edu" (netnumber=128.59.13). Network 2: wire="14-net.cs.columbia.edu" (netnumber=128.59.14). Network 3: wire="old-net.cs.columbia.edu" (netnumber=128.59.16). |
The information includes the version number, number of times Amd was
compiled on the local system, release date and name of the release.
Following come the cpu type, byte ordering, and the architecture and
kernel architecture as ${arch}
and ${karch}
,
respectively. The next line lists the operating system full name, short
name, version, and vendor. These four values correspond to the
variables ${full_os}
, ${os}
, ${osver}
, and
${vendor}
, respectively. See section Supported Platforms.
Then come a list of map types supported, filesystems internally
supported by Amd (AMFS), and generic filesystems available (FS).
Finally all known networks (if any) of this host are listed by name
and number. They are available via the variables
${wire}
or ${network}
, and
${netnumber}
(see section Selectors) or the `in_network'
selector function (see section in_network Selector Function).
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-w
wait-timeout Selects the interval in seconds between unmount attempts after the initial time-to-live has expired.
This defaults to 120 seconds (two minutes).
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-x
opts Specifies the type and verbosity of log messages. opts is a comma separated list selected from the following options:
fatal
Fatal errors (cannot be turned off)
error
Non-fatal errors (cannot be turned off)
user
Non-fatal user errors
warn
Recoverable errors
warning
Alias for warn
info
Information messages
map
Mount map usage
stats
Additional statistics
all
All of the above
defaults
An alias for "fatal,error,user,warning,info".
Initially a set of default logging flags is enabled. This is as if
`-x defaults'
or
`-x fatal,error,user,warning,info'
had been selected. The command line is
parsed and logging is controlled by the -x
option. The very first
set of logging flags is saved and can not be subsequently disabled using
Amq. This default set of options is useful for general production
use.
The `info' messages include details of what is mounted and unmounted and when filesystems have timed out. If you want to have the default set of messages without the `info' messages then you simply need `-x noinfo'. The messages given by `user' relate to errors in the mount maps, so these are useful when new maps are installed. The following table lists the syslog priorities used for each of the message types.
fatal
`LOG_CRIT'
error
`LOG_ERR'
user
`LOG_WARNING'
warning
`LOG_WARNING'
info
`LOG_INFO'
debug
`LOG_DEBUG'
map
`LOG_DEBUG'
stats
`LOG_INFO'
The options can be prefixed by the string `no' to indicate that this option should be turned off. For example, to obtain all but `info' messages the option `-x all,noinfo' would be used.
If Amd was built with debugging enabled the debug
option is
automatically enabled regardless of the command line options.
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-y
NIS-domain Selects an alternate NIS domain. This is useful for debugging and cross-domain shared mounting. If this flag is specified, Amd immediately attempts to bind to a server for this domain.
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-A
architecture Specifies the OS architecture of the system.
The only effect of this option is to set the variable ${arch}
.
This option would be used as follows:
amd -A i386 ... |
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-C
cluster-name Specifies the name of the cluster of which the local machine is a member.
The only effect is to set the variable ${cluster}
.
The cluster-name is will usually obtained by running another command which uses
a database to map the local hostname into a cluster name.
${cluster}
can then be used as a selector to restrict mounting of
replicated data.
If this option is not given, ${cluster}
has the same value as ${domain}
.
This would be used as follows:
amd -C `clustername` ... |
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-D
opts Controls the verbosity and coverage of the debugging trace; opts
is a comma separated list of debugging options. The -D
option is
only available if Amd was compiled with `-DDEBUG', or
configured with configure --enable-debug
. The memory debugging
facilities (`mem') are only available if Amd was compiled with
`-DDEBUG_MEM' (in addition to `-DDEBUG'), or configured with
configure --enable-debug=mem
.
The most common options to use are `-D trace' and `-D test' (which turns on all the useful debug options). As usual, every option can be prefixed with `no' to turn it off.
all
all options (excluding hrtime and mtab)
defaults
"sensible" default options (all-excluding hrtime, mtab, and xdrtrace)
test
full debug options plus mtab,nodaemon,nofork,noamq
amq
register Amd with the RPC portmapper, for Amq
daemon
enter daemon mode
fork
fork child worker (hlfsd only)
full
program trace
hrtime
print high resolution time stamps (only if syslog(3) is not used)
info
info service specific debugging (hesiod, nis, etc.) In the case of hesiod maps, turns on the hesiod RES_DEBUG internal debugging option.
mem
trace memory allocations. Needs to be explicitly enabled at compile time with -enable-debug=mem.
mtab
use local mount-table file (defaults to `/tmp/mtab', see section debug_mtab_file Parameter)
readdir
show readdir progress
str
debug string munging
trace
trace RPC protocol and NFS mount arguments
xdrtrace
trace XDR routines
You may also refer to the program source for a more detailed explanation of the available options.
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-F
conf-file Specify an Amd configuration file conf-file to use. For a description of the format and syntax, see section Amd Configuration File. This configuration file is used to specify any options in lieu of typing many of them on the command line. The `amd.conf' file includes directives for every command line option Amd has, and many more that are only available via the configuration file facility. The configuration file specified by this option is processed after all other options had been processed, regardless of the actual location of this option on the command line.
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-H
Print a brief help and usage string.
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-O
op-sys-name Overrides the compiled-in name of the operating system, with op-sys-name. Useful when the built-in name is not desired for backward compatibility reasons. For example, if the build in name is `sunos5', you can override it to the old name `sos5', and use older maps which were written with the latter in mind.
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-S
Do not lock the running executable pages of Amd into memory.
To improve Amd's performance, systems that support the plock(3)
or mlockall(2)
call lock the Amd process into memory. This way there is less
chance the operating system will schedule, page out, and swap the
Amd process as needed. This tends to improve Amd's performance,
at the cost of reserving the memory used by the Amd process (making
it unavailable for other processes). If this behavior is not desired,
use the -S
option.
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-T
tag Specify a tag to use with `amd.conf'. All map entries tagged with tag will be processed. Map entries that are not tagged are always processed. Map entries that are tagged with a tag other than tag will not be processed.
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To mount a volume, Amd must be told the type of filesystem to be used. Each filesystem type typically requires additional information such as the fileserver name for NFS.
From the point of view of Amd, a filesystem is anything that can resolve an incoming name lookup. An important feature is support for multiple filesystem types. Some of these filesystems are implemented in the local kernel and some on remote fileservers, whilst the others are implemented internally by Amd.
The two common filesystem types are UFS and NFS. Four other user accessible filesystems (`link', `program', `auto' and `direct') are also implemented internally by Amd and these are described below. There are two additional filesystem types internal to Amd which are not directly accessible to the user (`inherit' and `error'). Their use is described since they may still have an effect visible to the user.
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The nfs (`type:=nfs') filesystem type provides access to Sun's NFS.
The following options must be specified:
rhost
the remote fileserver. This must be an entry in the hosts database. IP
addresses are not accepted. The default value is taken
from the local host name (${host}
) if no other value is
specified.
rfs
the remote filesystem.
If no value is specified for this option, an internal default of
${path}
is used.
NFS mounts require a two stage process. First, the file handle of the remote file system must be obtained from the server. Then a mount system call must be done on the local system. Amd keeps a cache of file handles for remote file systems. The cache entries have a lifetime of a few minutes.
If a required file handle is not in the cache, Amd sends a request to the remote server to obtain it.
Historically, this documentation has maintained that Amd will try all the locations in parallel and use the first one which responds with a valid file handle. This has not been the case for quite some time, however. Instead, Amd will go through each location, one by one, and will only skip to the next one if the previous one either fails or times out.
An NFS entry might be:
jsp host!=charm;type:=nfs;rhost:=charm;rfs:=/home/charm;sublink:=jsp |
The mount system call and any unmount attempts are always done in a new task to avoid the possibility of blocking Amd.
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The host (`type:=host') filesystem allows access to the entire export tree of an NFS server. The implementation is layered above the `nfs' implementation so keep-alives work in the same way. The only option which needs to be specified is `rhost' which is the name of the fileserver to mount.
The `host' filesystem type works by querying the mount daemon on the given fileserver to obtain its export list. Amd then obtains filehandles for each of the exported filesystems. Any errors at this stage cause that particular filesystem to be ignored. Finally each filesystem is mounted. Again, errors are logged but ignored. One common reason for mounts to fail is that the mount point does not exist. Although Amd attempts to automatically create the mount point, it may be on a remote filesystem to which Amd does not have write permission.
When an attempt to unmount a `host' filesystem mount fails, Amd remounts any filesystems which had successfully been unmounted. To do this Amd queries the mount daemon again and obtains a fresh copy of the export list. Amd then tries to mount any exported filesystems which are not currently mounted.
Sun's automounter provides a special `-hosts' map. To achieve the same effect with Amd requires two steps. First a mount map must be created as follows:
* type:=host;rhost:=${key};fs:=${autodir}/${rhost}/root |
and then start Amd with the following command
amd /net net.map |
where `net.map' is the name of map described above. Note that the
value of ${fs}
is overridden in the map. This is done to avoid
a clash between the mount tree and any other filesystem already mounted
from the same fileserver.
If different mount options are needed for different hosts then additional entries can be added to the map, for example
host2 opts:=ro,nosuid,soft |
would soft mount `host2' read-only.
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The nfsx (`type:=nfsx') filesystem allows a group of filesystems to be mounted from a single NFS server. The implementation is layered above the `nfs' implementation so keep-alives work in the same way.
WARNING: `nfsx' is meant to be a "last resort" kind of solution. It is racy and poorly supported. The authors highly recommend that other solutions be considered before relying on it.
The options are the same as for the `nfs' filesystem with one difference for `rfs', as explained below.
The following options should be specified:
rhost
the remote fileserver. The default value is taken from the local
host name (${host}
) if no other value is specified.
rfs
is a list of filesystems to mount, and must be specified. The list is in the form of a comma separated strings.
For example:
pub type:=nfsx;rhost:=gould;\ rfs:=/public,/,graphics,usenet;fs:=${autodir}/${rhost}/root |
The first string defines the root of the tree, and is applied as a prefix to the remaining members of the list which define the individual filesystems. The first string is not used as a filesystem name. A serial operation is used to determine the local mount points to ensure a consistent layout of a tree of mounts.
Here, the three filesystems, `/public', `/public/graphics' and `/public/usenet', would be mounted.
A local mount point, ${fs}
, must be specified. The
default local mount point will not work correctly in the general case.
A suggestion is to use `fs:=${autodir}/${rhost}/root'.
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The ufs (`type:=ufs') filesystem type provides access to the system's standard disk filesystem--usually a derivative of the Berkeley Fast Filesystem.
The following option must be specified:
dev
the block special device to be mounted.
A UFS entry might be:
jsp host==charm;type:=ufs;dev:=/dev/sd0d;sublink:=jsp |
UFS is the default Unix disk-based file system, which Am-utils picks up during the autoconfiguration phase. Some systems have more than one type, such as IRIX, that comes with EFS (Extent File System) and XFS (Extended File System). In those cases, you may explicitly set the file system type, by using entries such:
ez1 type:=efs;dev:=/dev/xd0a ez2 type:=xfs;dev:=/dev/sd3c |
The UFS/XFS/EFS filesystems are never timed out by default, i.e. they will never be unmounted by Amd. If automatic unmounting is desired, the "unmount" option should be added to the mount options for the entry.
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The cachefs (`type:=cachefs') filesystem caches files from one location onto another, presumably providing faster access. It is particularly useful to cache from a larger and remote (slower) NFS partition to a smaller and local (faster) UFS directory.
The following options must be specified:
cachedir
the directory where the cache is stored.
rfs
the path name to the "back file system" to be cached from.
fs
the "front file system" mount point to the cached files, where Amd will set a symbolic link pointing to.
A CacheFS entry for, say, the `/import' Amd mount point, might be:
copt type:=cachefs;cachedir:=/cache;rfs:=/import/opt;fs:=/n/import/copt |
Access to the pathname `/import/copt' will follow a symbolic link to `/n/import/copt'. The latter is the mount point for a caching file system, that caches from `/import/opt' to `/cache'.
The cachefs filesystem is never timed out by default, i.e. it will never be unmounted by Amd. If automatic unmounting is desired, the "unmount" option should be added to the mount options for the entry.
Caveats:
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The cdfs (`type:=cdfs') filesystem mounts a CD-ROM with an ISO9660 format filesystem on it.
The following option must be specified:
dev
the block special device to be mounted.
Some operating systems will fail to mount read-only CDs unless the `ro' option is specified. A cdfs entry might be:
cdfs os==sunos4;type:=cdfs;dev:=/dev/sr0 \ os==sunos5;addopts:=ro;type:=cdfs;dev:=/dev/dsk/c0t6d0s2 |
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The lofs (`type:=lofs') filesystem is also called the loopback filesystem. It mounts a local directory on another, thus providing mount-time binding to another location (unlike symbolic links).
The loopback filesystem is particularly useful within the context of a chroot-ed directory (via chroot(2)), to provide access to directories otherwise inaccessible.
The following option must be specified:
rfs
the pathname to be mounted on top of ${fs}
.
Usually, the FTP server runs in a chroot-ed environment, for security reasons. In this example, lofs is used to provide a subdirectory within a user's home directory, also available for public ftp.
lofs type:=lofs;rfs:=/home/ezk/myftpdir;fs:=/usr/ftp/pub/ezk |
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The mfs (`type:=mfs') filesystem is available in 4.4BSD, Linux, and other systems. It creates a filesystem in a portion of the system's memory, thus providing very fast file (volatile) access.
XXX: THIS FILESYSTEM IS NOT IMPLEMENTED YET!
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The nullfs (`type:=nullfs') filesystem is available from 4.4BSD, and is very similar to the loopback filesystem, lofs.
XXX: THIS FILESYSTEM IS NOT IMPLEMENTED YET!
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The pcfs (`type:=pcfs') filesystem mounts a floppy previously formatted for the MS-DOS format.
The following option must be specified:
dev
the block special device to be mounted.
A pcfs entry might be:
pcfs os==sunos4;type:=pcfs;dev:=/dev/fd0 \ os==sunos5;type:=pcfs;dev:=/dev/diskette |
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The tfs (`type:=tfs') filesystem is an older version of the 4.4BSD unionfs.
XXX: THIS FILESYSTEM IS NOT IMPLEMENTED YET!
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The tmpfs (`type:=tmpfs') filesystem shares memory between a the swap device and the rest of the system. It is generally used to provide a fast access `/tmp' directory, one that uses memory that is otherwise unused. This filesystem is available in SunOS 4.x and 5.x.
XXX: THIS FILESYSTEM IS NOT IMPLEMENTED YET!
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The umapfs (`type:=umapfs') filesystem maps User IDs of file ownership, and is available from 4.4BSD.
XXX: THIS FILESYSTEM IS NOT IMPLEMENTED YET!
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The program (`type:=program') filesystem type allows a program to be run whenever a mount or unmount is required. This allows easy addition of support for other filesystem types, such as MIT's Remote Virtual Disk (RVD) which has a programmatic interface via the commands `rvdmount' and `rvdunmount'.
Both of the following options must be specified:
mount
the program which will perform the mount.
unmount
umount
the program which will perform the unmount. For convenience, you may
use either `unmount' or `umount' but not both. If neither
is defined, Amd will default to `umount ${fs}' (the actual
unmount program pathname will be automatically determined at the time
GNU configure
runs.)
The exit code from these two programs is interpreted as a Unix error code. As usual, exit code zero indicates success. To execute the program, Amd splits the string on whitespace to create an array of substrings. Single quotes `'' can be used to quote whitespace if that is required in an argument. There is no way to escape or change the single quote character.
To run e.g. the program `rvdmount' with a host name and filesystem as arguments, it would be specified by `fs:=${autodir}${path};type:=program;mount:="/etc/rvdmount rvdmount fserver ${fs}";unmount:="/etc/rdvumount rvdumount ${fs}"'.
The first element in the array is taken as the pathname of the program
to execute. The other members of the array form the argument vector
to be passed to the program, including argument zero. The array
is exactly the same as the array passed to the execv() system call
(man execv for details). The split string must have at least two
elements. The programs are directly executed by Amd, not via a
shell. Therefore, if a script is to be used as a mount/umount
program, it must begin with a #!
interpreter specification.
Often, this program mount type is used for Samba mounts, where you need a double slash in pathnames. However, Amd normalizes sequences of slashes into one slash. Therefore, you must use an escaped slash, preceded by an escaped backslash. So to get a double slash in the mount command, you need the eight character sequence `\\\/\\\/' in your map. For example:
`mount="/sbin/mount mount -r -t smbfs -o-N,-Ihostname \\\/\\\/guest@venus/mp3"'
If a filesystem type is to be heavily used, it may be worthwhile adding a new filesystem type into Amd, but for most uses the program filesystem should suffice.
When the program is run, standard input and standard error are inherited
from the current values used by Amd. Standard output is a
duplicate of standard error. The value specified with the -l
command line option has no effect on standard error.
Amd guarantees that the mountpoint will be created before calling the mount program, and that it will be removed after the umount program returns success.
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Each filesystem type creates a symbolic link to point from the volume name to the physical mount point. The `link' filesystem does the same without any other side effects. This allows any part of the machines name space to be accessed via Amd.
One common use for the symlink filesystem is `/homes' which can be made to contain an entry for each user which points to their (auto-mounted) home directory. Although this may seem rather expensive, it provides a great deal of administrative flexibility.
The following option must be defined:
fs
The value of fs option specifies the destination of the link, as
modified by the sublink option. If sublink is non-null, it
is appended to ${fs}
/
and the resulting string is used
as the target.
The `link' filesystem can be thought of as identical to the `ufs' filesystem but without actually mounting anything.
An example entry might be:
jsp host==charm;type:=link;fs:=/home/charm;sublink:=jsp |
which would return a symbolic link pointing to `/home/charm/jsp'.
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The linkx (`type:=linkx') filesystem type is identical to `link' with the exception that the target of the link must exist. Existence is checked with the lstat(2) system call.
The `linkx' filesystem type is particularly useful for wildcard map entries. In this case, a list of possible targets can be given and Amd will choose the first one which exists on the local machine.
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The nfsl (`type:=nfsl') filesystem type is a combination of two others:
`link' and `nfs'. If the local host name is equal to the
value of ${rhost}
and the target pathname listed in
${fs}
exists, `nfsl' will behave exactly as
`type:=link', and refer to the target as a symbolic link. If the
local host name is not equal to the value of ${rhost}
, or if
the target of the link does not exist, Amd will treat it as
`type:=nfs', and will mount a remote pathname for it.
The `nfsl' filesystem type is particularly useful as a shorthand for the more cumbersome and yet one of the most popular Amd entries. For example, you can simplify all map entries that look like:
zing -fs:=/n/shekel/u/zing \ host!=shekel;type:=nfs;rhost:=shekel;rfs:=${fs} \ host==shekel;type:=link |
or
zing -fs:=/n/shekel/u/zing \ exists(${fs});type:=link \ !exists(${fs});type:=nfs;rhost:=shekel;rfs:=${fs} |
into a shorter form
zing type:=nfsl;fs:=/n/shekel/u/zing;rhost:=shekel;rfs:=${fs} |
Not just does it make the maps smaller and simpler, but it avoids possible mistakes that often happen when forgetting to set up the two entries (one for `type:=nfs' and the other for `type:=link') necessary to perform transparent mounts of existing or remote mounts.
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The auto (`type:=auto') filesystem type creates a new automount point below an existing automount point. Top-level automount points appear as system mount points. An automount mount point can also appear as a sub-directory of an existing automount point. This allows some additional structure to be added, for example to mimic the mount tree of another machine.
The following options may be specified:
cache
specifies whether the data in this mount-map should be cached. The default value is `none', in which case no caching is done in order to conserve memory.
However, better performance and reliability can be obtained by caching some or all of a mount-map.
If the cache option specifies `all', the entire map is enumerated when the mount point is created.
If the cache option specifies `inc', caching is done incrementally as and when data is required. Some map types do not support cache mode `all', in which case `inc' is used whenever `all' is requested.
Caching can be entirely disabled by using cache mode `none'.
If the cache option specifies `regexp' then the entire map will be enumerated and each key will be treated as an egrep-style regular expression. The order in which a cached map is searched does not correspond to the ordering in the source map so the regular expressions should be mutually exclusive to avoid confusion.
Each mount map type has a default cache type, usually `inc', which can be selected by specifying `mapdefault'.
The cache mode for a mount map can only be selected on the command line. Starting Amd with the command:
amd /homes hesiod.homes -cache:=inc |
will cause `/homes' to be automounted using the Hesiod name server with local incremental caching of all successfully resolved names.
All cached data is forgotten whenever Amd receives a `SIGHUP' signal and, if cache `all' mode was selected, the cache will be reloaded. This can be used to inform Amd that a map has been updated. In addition, whenever a cache lookup fails and Amd needs to examine a map, the map's modify time is examined. If the cache is out of date with respect to the map then it is flushed as if a `SIGHUP' had been received.
An additional option (`sync') may be specified to force Amd to check the map's modify time whenever a cached entry is being used. For example, an incremental, synchronized cache would be created by the following command:
amd /homes hesiod.homes -cache:=inc,sync |
fs
specifies the name of the mount map to use for the new mount point.
Arguably this should have been specified with the ${rfs}
option but
we are now stuck with it due to historical accident.
pref
alters the name that is looked up in the mount map. If
${pref}
, the prefix, is non-null then it is prepended
to the name requested by the kernel before the map is
searched. The default prefix is the prefix of the parent map (if any)
with name of the auto node appended to it. That means if you want no
prefix you must say so in the map: `pref:=null'.
opts
Normally, `auto' style maps are not browsable even if you turn on directory browsability (see section browsable_dirs Parameter). To enable browsing entries in `auto' maps, specify `opts:=browsable' or `opts:=fullybrowsable' in the description of this map.
The server `dylan.doc.ic.ac.uk' has two user disks: `/dev/dsk/2s0' and `/dev/dsk/5s0'. These are accessed as `/home/dylan/dk2' and `/home/dylan/dk5' respectively. Since `/home' is already an automount point, this naming is achieved with the following map entries:
dylan type:=auto;fs:=${map};pref:=${key}/ dylan/dk2 type:=ufs;dev:=/dev/dsk/2s0 dylan/dk5 type:=ufs;dev:=/dev/dsk/5s0 |
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The direct (`type:=direct') filesystem is almost identical to the automount filesystem. Instead of appearing to be a directory of mount points, it appears as a symbolic link to a mounted filesystem. The mount is done at the time the link is accessed. See section Automount Filesystem (`auto'), for a list of required options.
Direct automount points are created by specifying the `direct' filesystem type on the command line:
amd ... /usr/man auto.direct -type:=direct |
where `auto.direct' would contain an entry such as:
usr/man -type:=nfs;rfs:=/usr/man \ rhost:=man-server1 rhost:=man-server2 |
In this example, `man-server1' and `man-server2' are file servers which export copies of the manual pages. Note that the key which is looked up is the name of the automount point without the leading `/'.
Note that the implementation of the traditional direct filesystem is essentially a hack (pretending that the root of an NFS filesystem is a symlink) and many modern operating systems get very unhappy about it. For example, Linux kernel 2.4+ completely disallows it, and Solaris 2.8 fails to unmount it when Amd shuts down. Therefore, the use of the traditional direct filesystem is strongly discouraged; it is only semi-supported, at best.
The autofs implementations that permit direct mounts are fully supported, however. That currently includes all versions of Solaris. Linux autofs does NOT support direct mounts at all.
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The union (`type:=union') filesystem type allows the contents of several directories to be merged and made visible in a single directory. This can be used to overcome one of the major limitations of the Unix mount mechanism which only allows complete directories to be mounted.
For example, supposing `/tmp' and `/var/tmp' were to be merged into a new directory called `/mtmp', with files in `/var/tmp' taking precedence. The following command could be used to achieve this effect:
amd ... /mtmp union:/tmp:/var/tmp -type:=union |
Currently, the unioned directories must not be automounted. That would cause a deadlock. This seriously limits the current usefulness of this filesystem type and the problem will be addressed in a future release of Amd.
Files created in the union directory are actually created in the last named directory. This is done by creating a wildcard entry which points to the correct directory. The wildcard entry is visible if the union directory is listed, so allowing you to see which directory has priority.
The files visible in the union directory are computed at the time Amd is started, and are not kept up-to-date with respect to the underlying directories. Similarly, if a link is removed, for example with the `rm' command, it will be lost forever.
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The error (`type:=error') filesystem type is used internally as a catch-all in the case where none of the other filesystems was selected, or some other error occurred. Lookups and mounts always fail with "No such file or directory". All other operations trivially succeed.
The error filesystem is not directly accessible.
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The toplvl (`type:=toplvl') filesystems is derived from the `auto' filesystem and is used to mount the top-level automount nodes. Requests of this type are automatically generated from the command line arguments.
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The root (`type:=root') filesystem type acts as an internal placeholder onto which Amd can pin `toplvl' mounts. Only one node of this type need ever exist and one is created automatically during startup. The effect of having more than one root node is undefined.
The root filesystem is not directly accessible.
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The inheritance (`type:=inherit') filesystem is not directly
accessible. Instead, internal mount nodes of this type are
automatically generated when Amd is started with the -r
option.
At this time the system mount table is scanned to locate any filesystems
which are already mounted. If any reference to these filesystems is
made through Amd then instead of attempting to mount it, Amd
simulates the mount and inherits the filesystem. This allows a
new version of Amd to be installed on a live system simply by
killing the old daemon with `SIGTERM' and starting the new one.
This filesystem type is not generally visible externally, but it is possible that the output from `amq -m' may list `inherit' as the filesystem type. This happens when an inherit operation cannot be completed for some reason, usually because a fileserver is down.
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The `amd.conf' file is the configuration file for Amd, as part of the am-utils suite. This file contains runtime configuration information for the Amd automounter program.
6.1 File Format | ||
6.2 The Global Section | ||
6.3 Regular Map Sections | ||
6.4 Common Parameters | ||
6.5 Global Parameters | ||
6.6 Regular Map Parameters | ||
6.7 amd.conf Examples |
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The `amd.conf' file consists of sections and parameters. A section begins with the name of the section in square brackets `[]' and continues until the next section begins or the end of the file is reached. Sections contain parameters of the form `name = value'.
The file is line-based -- that is, each newline-terminated line represents either a comment, a section name or a parameter. No line-continuation syntax is available.
Section names, parameter names and their values are case sensitive.
Only the first equals sign in a parameter is significant. Whitespace before or after the first equals sign is discarded. Leading, trailing and internal whitespace in section and parameter names is irrelevant. Leading and trailing whitespace in a parameter value is discarded. Internal whitespace within a parameter value is not allowed, unless the whole parameter value is quoted with double quotes as in `name = "some value"'.
Any line beginning with a pound sign `#' is ignored, as are lines containing only whitespace.
The values following the equals sign in parameters are all either a string (no quotes needed if string does not include spaces) or a boolean, which may be given as `yes'/`no'. Case is significant in all values. Some items such as cache timeouts are numeric.
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The global section must be specified as `[global]'. Parameters in this section either apply to Amd as a whole, or to all other regular map sections which follow. There should be only one global section defined in one configuration file.
It is highly recommended that this section be specified first in the configuration file. If it is not, then regular map sections which precede it will not use global values defined later.
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Parameters in regular (non-global) sections apply to a single map entry. For example, if the map section `[/homes]' is defined, then all parameters following it will be applied to the `/homes' Amd-managed mount point.
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These parameters can be specified either in the global or a map-specific section. Entries specified in a map-specific section override the default value or one defined in the global section. If such a common parameter is specified only in the global section, it is applicable to all regular map sections that follow.
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(type=string, default=`yes').
When set to `yes', Amd's autofs code will use lofs-type
(loopback) mounts for type:=link
mounts, as well as several
other cases that require local references. This has the advantage
that Amd does not use a secondary mount point and users do not see
external pathnames (the infamous /bin/pwd
problem, where it
reports a different path than the user chdir'ed into). One of the
disadvantages of using this option is that the autofs code is
relatively new and the in-place mounts have not been throughly tested.
If this option is set to `no', then Amd's autofs code will use symlinks instead of lofs-type mounts for local references. This has the advantage of using simpler (more stable) code, but at the expense of negating one of autofs's big advantages: the hiding of Amd's internal paths. Note that symlinks are not supported in all autofs implementations, especially those derived from Solaris Autofs v1. Also, on Solaris 2.6 and newer, autofs symlinks are not cached, resulting in repeated up-call requests to Amd.
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(type=string, default=`no'). If `yes', then Amd's top-level mount points will be browsable to readdir(3) calls. This means you could run for example ls(1) and see what keys are available to mount in that directory. Not all entries are made visible to readdir(3): the `/defaults' entry, wildcard entries, and those with a `/' in them are not included. If you specify `full' to this option, all but the `/defaults' entry will be visible. Note that if you run a command which will attempt to stat(2) the entries, such as often done by `ls -l' or `ls -F', Amd will attempt to mount every entry in that map. This is often called a "mount storm".
Note that mount storms are mostly avoided by using autofs mounts (`mount_type = autofs').
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(type=string, default to empty). This option sets a string to be used
as the map's /defaults
entry, overriding any /defaults
specified in the map. This allows local users to override a given
map's defaults without modifying maps globally (which is impossible in
sites where the maps are managed by a different administrative group).
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(type=string, default no options). This option is the same as specifying map options on the command line to Amd, such as `cache:=all'.
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(type=string, default search all map types). If specified, Amd will initialize the map only for the type given. This is useful to avoid the default map search type used by Amd which takes longer and can have undesired side-effects such as initializing NIS even if not used. Possible values are
plain files
Hesiod name service from MIT
Lightweight Directory Access Protocol
(New) dbm style hash files
Network Information Services (version 2)
Network Information Services Plus (version 3)
local password files
union maps
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(type=string, default=`nfs'). All Amd mount types default to NFS. That is, Amd is an NFS server on the map mount points, for the local host it is running on. If `autofs' is specified, Amd will be an autofs server for those mount points.
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(type=string, default no search path). This provides a (colon-delimited) search path for file maps. Using a search path, sites can allow for local map customizations and overrides, and can distributed maps in several locations as needed.
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(type=boolean, default=`no'). If `yes', then the `/defaults' entry of maps will search for and process any selectors before setting defaults for all other keys in that map. Useful when you want to set different options for a complete map based on some parameters. For example, you may want to better the NFS performance over slow slip-based networks as follows:
/defaults \ wire==slip-net;opts:=intr,rsize=1024,wsize=1024 \ wire!=slip-net;opts:=intr,rsize=8192,wsize=8192 |
Deprecated form: selectors_on_default.
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(type=boolean, default=`no'). If `yes', then Amd will parse the map according to the Sun Automount syntax.
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The following parameters are applicable to the `[global]' section only.
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(type=string, default to compiled in value). Same as the -A
option to Amd. Allows you to override the value of the arch
Amd variable.
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(type=numeric, default=0). Specify in seconds (or units of 0.1 seconds, depending on the OS), what is the (kernel-side) NFS attribute cache timeout for Amd's own automount points. A value of 0 is supposed to turn off attribute caching, meaning that Amd will be consulted via a kernel-RPC each time someone stat()'s the mount point (which could be abused as a denial-of-service attack).
WARNING: Amd depends on being able to turn off the NFS attribute cache of the client OS. If it cannot be turned off, then users may get ESTALE errors or symlinks that point to the wrong places. This is more likely under heavy use of Amd, for example if your system is experiencing frequent map changes or frequent mounts/unmounts. Therefore, under normal circumstances, this parameter should remain set to 0, to ensure that the attribute cache is indeed off.
Unfortunately, some kernels (e.g., certain BSDs) don't have a way to
turn off the NFS attribute cache. Setting this parameter to 0 is
supposed to turn off attribute caching entirely, but unfortunately it
does not; instead, the attribute cache is set to some internal
hard-coded default (usually anywhere from 5-30 seconds). If you
suspect that your OS doesn't have a reliable way of turning off the
attribute cache, then it is better to set this parameter to the
smallest possible non-zero value (set `auto_attrcache=1' in your
amd.conf
). This will not eliminate the problem, but reduce the
risk window somewhat. The best solutions are (1) to use Amd in
Autofs mode, if it's supported in your OS, and (2) talk to your OS
vendor to support a true `noac' flag. See the
README.attrcache
document for more details.
If you are able to turn off the attribute cache on your OS, alas, Amd's performance may degrade (when not using Autofs) because every traversal of an automounter-controlled pathname will result in a lookup request from the kernel to Amd. Under heavy loads, for example when using recursive tools like `find', `rdist', or `rsync', this performance degradation can be noticeable. There are two possible solutions that some administrators have chosen to improve performance:
amd.conf
:
[global] auto_attrcache = 1 dismount_interval = 3600 |
This has the benefit of using the kernel's attribute cache and thus improving performance. The disadvantage with this option is that the window of vulnerability is not eliminated entirely: it is only made smaller.
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(type=string, default=`/a'). Same as the -a
option to Amd.
This sets the private directory where Amd will create
sub-directories for its real mount points.
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(type=numeric, default=300). Same as the -c
option to Amd.
Sets the duration in seconds that looked-up or mounted map entries
remain in the cache.
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(type=string, default no cluster). Same as the -C
option to
Amd. Specifies the alternate HP-UX cluster to use.
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(type=string, default="/tmp/mtab"). Path to mtab file that is used by Amd to store a list of mounted file systems during debug-mtab mode. This option only applies to systems that store mtab information on disk.
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(type=string, default no debug options). Same as the -D
option
to Amd. Specify any debugging options for Amd. Works only if
am-utils was configured for debugging using the --enable-debug
option. The additional `mem' option can be turned on via
--enable-debug=mem
. Otherwise debugging options are ignored.
Options are comma delimited, and can be preceded by the string
`no' to negate their meaning. You can get the list of supported
debugging and logging options by running amd -H
. Possible
values those listed for the -D option. See section -D
opts.
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(type=numeric, default=120). Same as the -w
option to
Amd. Specify in seconds, the time between attempts to dismount file
systems that have exceeded their cached times.
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(type=boolean, default=`yes'). If `yes', then the domain
name part referred to by ${rhost}
is stripped off. This is
useful to keep logs and smaller. If `no', then the domain name
part is left changed. This is useful when using multiple domains with
the same maps (as you may have hosts whose domain-stripped name is
identical).
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(type=numeric, default=10). The timeout in seconds that Amd will wait for an executable map program before an answer is returned from that program (or script). This value should be set to as small as possible while still allowing normal replies to be returned before the timer expires, because during the time that the executable map program is queried, Amd is essentially waiting and is thus not responding to any other queries. See section Executable maps.
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(type=boolean, default=`no'). Sometimes, mount points are hung due to unrecoverable conditions, such as when NFS servers migrate, change their IP address, are down permanently, or due to hardware failures, and more. In this case, attempting to unmount an existing mount point, or even just to stat(2) it, results in one of three fatal errors: EIO, ESTALE, or EBUSY. At that point, Amd can do little to recover that hung point (in fact, the OS cannot automatically recover either). For that reason, some OSs support special kinds of forced unmounts, which must be used very carefully: they will force an unmount immediately (or lazily on Linux), which could result in application data loss. However, that may be the only way to recover the entire host (without rebooting). Once a hung mount point is forced out, Amd can then re-mount a replacement one (if available), bringing a mostly-hung system back to operation and avoiding a potentially costly reboot.
If the `forced_unmounts' option is set to `yes', and the
client OS supports forced or lazy unmounts, then Amd will attempt
to use them if it gets any of the three serious error conditions
listed above. Note that Amd will force the unmount of mount
points that returned EBUSY only for `type:=toplvl' mounts
(see section Top-level Filesystem (`toplvl')): that is, Amd's own mount points.
This is useful to recover from a previously hung Amd, and to
ensure that an existing Amd can shutdown cleanly even if some
processes are keeping its mount points busy (i.e., when a user's shell
process uses cd
to set its CWD to Amd's own mount point).
If this option is set to `no' (the default), then Amd will not attempt this special recovery procedure.
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(type=string, default to compiled in value). The full name of the operating system, along with its version. Allows you to override the compiled-in full name and version of the operating system. Useful when the compiled-in name is not desired. For example, the full operating system name on linux comes up as `linux', but you can override it to `linux-2.2.5'.
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(type=string, default=`no'). If `yes', Amd will perform RPC authentication using fully-qualified host names. This is necessary for some systems, and especially when performing cross-domain mounting. For this function to work, the Amd variable `${hostd}' is used, requiring that `${domain}' not be null.
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(type=string, default=`automount'). Specify the base name for hesiod maps.
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(type=string, default to karch of the system). Same as the -k
option to Amd. Allows you to override the kernel-architecture of
your system. Useful for example on Sun (Sparc) machines, where you can
build one Amd binary, and run it on multiple machines, yet you want
each one to get the correct karch variable set (for example, sun4c,
sun4m, sun4u, etc.) Note that if not specified, Amd will use
uname(2) to figure out the kernel architecture of the machine.
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(type=string, default not set). Specify the base name for LDAP. This often includes LDAP-specific values such as country and organization.
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(type=numeric, default=131072). Specify the maximum memory Amd should use to cache LDAP entries.
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(type=numeric, default=0). Specify the number of seconds to keep entries in the cache.
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(type=string, default not set). Specify the LDAP host and port values.
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(type=numeric, default=2). Specify the LDAP protocol version to use. With a value of 3 will use LDAPv3 protocol.
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(type=string, default no sub-domain). Same as the -d
option
to Amd. Specify the local domain name. If this option is not given
the domain name is determined from the hostname, by removing the first
component of the fully-qualified host name.
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(type=string, default to localhost or 127.0.0.1). Specify the name or IP address for Amd to use when connecting the sockets for the local NFS server and the RPC server. This defaults to 127.0.0.1 or whatever the host reports as its local address. This parameter is useful on hosts with multiple addresses where you want to force Amd to connect to a specific address.
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(type=string, default=`stderr'). Same as the -l
option to
Amd. Specify a file name to log Amd events to.
If the string `/dev/stderr' is specified,
Amd will send its events to the standard error file descriptor.
If the string `syslog' is given, Amd will record its events with the system logger syslogd(8). If your system supports syslog facilities, then the default facility used is `LOG_DAEMON'.
When using syslog, if you wish to change the facility, append its name to the option name, delimited by a single colon. For example, if it is the string `syslog:local7' then Amd will log messages via syslog(3) using the `LOG_LOCAL7' facility. If the facility name specified is not recognized, Amd will default to `LOG_DAEMON'. Note: while you can use any syslog facility available on your system, it is generally a bad idea to use those reserved for other services such as `kern', `lpr', `cron', etc.
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(type=string, default="defaults"). Same as the -x
option to Amd. Specify any logging options for Amd. Options
are comma delimited, and can be preceded by the string `no' to
negate their meaning. The `debug' logging option is only available
if am-utils was configured with --enable-debug
. You can get the
list of supported debugging options by running amd -H
. Possible
values are:
all messages
an alias for "fatal,error,user,warning,info"
debug messages
non-fatal system errors (cannot be turned off)
fatal errors (cannot be turned off)
information
map errors
additional statistical information
non-fatal user errors
warnings
warnings
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(type=numeric, default=3600). The number of seconds that Amd will wait before it checks to see if any maps have changed at their source (NIS servers, LDAP servers, files, etc.). Amd will reload only those maps that have changed.
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(type=string, default=`no'). Normally Amd accepts local NFS packets only from 127.0.0.1. If this parameter is set to `yes', then amd will accept local NFS packets from any local interface; this is useful on hosts that may have multiple interfaces where the system is forced to send all outgoing packets (even those bound to the same host) via an address other than 127.0.0.1.
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(type=string, default=`no'). Normally Amd will refuse requests coming from unprivileged ports (i.e., ports >= 1024 on Unix systems), so that only privileged users and the kernel can send NFS requests to it. However, some kernels (certain versions of Darwin, MacOS X, and Linux) have bugs that cause them to use unprivileged ports in certain situations, which causes Amd to stop dead in its tracks. This parameter allows Amd to operate normally even on such systems, at the expense of a slight decrease in the security of its operations. If you see messages like "ignoring request from foo:1234, port not reserved" in your Amd log, try enabling this parameter and give it another go.
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(type=string, default to trying version tcp then udp). By default,
Amd tries tcp
and then udp
. This option forces the
overall NFS protocol used to TCP or UDP. It overrides what is in the
Amd maps, and is useful when Amd is compiled with TCP support
in NFSv2/NFSv3 that may not be stable. With this option you can turn
off the complete usage of TCP for NFS dynamically (without having to
recompile Amd), and use UDP only, until such time as TCP support
is desired again.
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(type=numeric, default=11). Same as the retransmit part of the
-t
timeout.retransmit option to Amd. Specifies the
number of NFS retransmissions that the kernel will use to communicate
with Amd using either UDP or TCP mounts. See section -t
timeout.retransmit.
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(type=numeric, default=11). Same as the nfs_retransmit_counter parameter, but applied globally only to UDP mounts. See section nfs_retransmit_counter Parameter.
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(type=numeric, default=11). Same as the nfs_retransmit_counter parameter, but applied globally only to TCP mounts. See section nfs_retransmit_counter Parameter.
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(type=numeric, default=11). Same as the nfs_retransmit_counter parameter, applied only for Amd's top-level UDP mounts. On some systems it is useful to set this differently than the OS default, so as to better tune Amd's responsiveness under heavy scheduler loads. See section nfs_retransmit_counter Parameter.
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(type=numeric, default=8). Same as the timeout part of the
-t
timeout.retransmit option to Amd. Specifies the NFS
timeout interval, in tenths of seconds, between NFS/RPC retries
(for UDP or TCP). This is the value that the kernel will use to
communicate with Amd. See section -t
timeout.retransmit.
Amd relies on the kernel RPC retransmit mechanism to trigger mount retries. The values of the nfs_retransmit_counter and the nfs_retry_interval parameters change the overall retry interval. Too long an interval gives poor interactive response; too short an interval causes excessive retries.
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(type=numeric, default=8). Same as the nfs_retry_interval parameter, but applied globally only to UDP mounts. See section nfs_retry_interval Parameter.
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(type=numeric, default=8). Same as the nfs_retry_interval parameter, but applied globally only to TCP mounts. See section nfs_retry_interval Parameter.
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(type=numeric, default=8). Same as the nfs_retry_interval parameter, applied only for Amd's top-level UDP mounts. On some systems it is useful to set this differently than the OS default, so as to better tune Amd's responsiveness under heavy scheduler loads. See section nfs_retry_interval Parameter.
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(type=numeric, default to trying version 3 then 2). By default, Amd tries version 3 and then version 2. This option forces the overall NFS protocol used to version 3 or 2. It overrides what is in the Amd maps, and is useful when Amd is compiled with NFSv3 support that may not be stable. With this option you can turn off the complete usage of NFSv3 dynamically (without having to recompile Amd), and use NFSv2 only, until such time as NFSv3 support is desired again.
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(type=string, default to local NIS domain name). Same as the
-y
option to Amd. Specify an alternative NIS domain from
which to fetch the NIS maps. The default is the system domain name.
This option is ignored if NIS support is not available.
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(type=boolean, default=`no'). Same as the -n
option to Amd.
If `yes', then the name referred to by ${rhost}
is normalized
relative to the host database before being used. The effect is to
translate aliases into "official" names.
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(type=boolean, default=`yes'). If `yes' then amd will
condense all multiple /
(slash) characters into one and remove
all trailing slashes. If `no', then amd will not touch strings
that may contain repeated or trailing slashes. The latter is
sometimes useful with SMB mounts, which often require multiple slash
characters in pathnames.
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(type=string, default to compiled in value). Same as the -O
option to Amd. Allows you to override the compiled-in name of the
operating system. Useful when the built-in name is not desired for
backward compatibility reasons. For example, if the built-in name is
`sunos5', you can override it to `sos5', and use older maps
which were written with the latter in mind.
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(type=string, default to compiled in value). Same as the -o
option to Amd. Allows you to override the compiled-in version
number of the operating system. Useful when the built-in version is not
desired for backward compatibility reasons. For example, if the build
in version is `2.5.1', you can override it to `5.5.1', and use
older maps that were written with the latter in mind.
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(type=string, default=`/dev/stdout'). Specify a file to store the process
ID of the running daemon into. If not specified, Amd will print its
process id onto the standard output. Useful for killing Amd after
it had run. Note that the PID of a running Amd can also be
retrieved via Amq (see section Amq -p
option).
This file is used only if the `print_pid' option is on (see section print_pid Parameter).
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(type=boolean, default=`yes'). Same as the -S
option to Amd.
If `yes', lock the running executable pages of Amd into memory.
To improve Amd's performance, systems that support the plock(3)
or mlockall(2)
call can lock the Amd process into memory. This way there is less
chance the operating system will schedule, page out, and swap the
Amd process as needed. This improves Amd's performance, at the
cost of reserving the memory used by the Amd process (making it
unavailable for other processes).
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(type=numeric, default=300019). Specify an alternate Port-mapper RPC
program number, other than the official number. This is useful when
running multiple Amd processes. For example, you can run another
Amd in "test" mode, without affecting the primary Amd process
in any way. For safety reasons, the alternate program numbers that can
be specified must be in the range 300019-300029, inclusive. Amq has
an option -P
which can be used to specify an alternate program
number of an Amd to contact. In this way, amq can fully control any
number of Amd processes running on the same host.
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(type=numeric, default=0). Specify an alternate Port-mapper RPC port number for Amd's Amq service. This is used for both UDP and TCP. Setting this value to 0 (or not defining it) will cause Amd to select an arbitrary port number. Setting the Amq RPC service port to a specific number is useful in firewalled or NAT'ed environments, where you need to know which port Amd will listen on.
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(type=boolean, default=`no'). Same as the -p
option to Amd.
If `yes', Amd will print its process ID upon starting.
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(type=boolean, default=`no'). Same as the -v
option to Amd,
but the version prints and Amd continues to run. If `yes', Amd
will print its version information string, which includes some
configuration and compilation values.
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(type=boolean, default=`no'). Same as the -r
option to Amd.
If `yes' Amd will scan the mount table to determine which file
systems are currently mounted. Whenever one of these would have been
auto-mounted, Amd inherits it.
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(type=boolean), default=`no'). If `yes', then all maps which are browsable will also show the number of entries (keys) they have when df(1) runs. (This is accomplished by returning non-zero values to the statfs(2) system call).
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(type=boolean), default=`no'). If `yes', then Amd will truncate the log file (if it's a regular file) on startup. This could be useful when conducting extensive testing on Amd maps (or Amd itself) and you don't want to see log data from a previous run in the same file.
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(type=boolean, default=`no'). If `yes', then Amd will attempt to unmount all file systems which it knows about. Normally it leaves all (esp. NFS) mounted file systems intact. Note that Amd does not know about file systems mounted before it starts up, unless the `restart_mounts' option is used (see section restart_mounts Parameter).
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(type=boolean), default=`yes'). If `yes', then amd will use
the tcpwrappers (tcpd/librwap) library (if available) to control
access to Amd via the /etc/hosts.allow
and
/etc/hosts.deny
files. Amd will verify that the host
running Amq is authorized to connect. The amd
service name
must used in the /etc/hosts.allow
and /etc/hosts.deny
files. For example, to allow only localhost to connect to Amd,
add this line to /etc/hosts.allow
:
amd: localhost |
and this line to /etc/hosts.deny
:
amd: ALL |
Consult the man pages for hosts_access(5) for more information on using the tcpwrappers access-control library.
Note that in particular, you should not configure your hosts.allow
file to spawn a command for Amd: that will cause Amd to not be able
to waitpid
on the child process ID of any background un/mount that
Amd issued, resulting in a confused Amd that does not know what
happened to those background un/mount requests.
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(type=string, default to compiled in value). The name of the vendor of the operating system. Overrides the compiled-in vendor name. Useful when the compiled-in name is not desired. For example, most Intel based systems set the vendor name to `unknown', but you can set it to `redhat'.
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The following parameters are applicable only to regular map sections.
6.6.1 map_name Parameter | ||
6.6.2 tag Parameter |
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(type=string, must be specified). Name of the map where the keys are located.
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(type=string, default no tag). Each map entry in the configuration file
can be tagged. If no tag is specified, that map section will always be
processed by Amd. If it is specified, then Amd will process the map
if the -T
option was given to Amd, and the value given to that
command-line option matches that in the map section.
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The following is the actual amd.conf
file I used at the
Computer Science Department of Columbia University.
# GLOBAL OPTIONS SECTION [ global ] normalize_hostnames = no print_pid = no #pid_file = /var/run/amd.pid restart_mounts = yes #unmount_on_exit = yes auto_dir = /n log_file = /var/log/amd log_options = all #debug_options = defaults plock = no selectors_in_defaults = yes # config.guess picks up "sunos5" and I don't want to edit my maps yet os = sos5 # if you print_version after setting up "os", it will show it. print_version = no map_type = file search_path = /etc/amdmaps:/usr/lib/amd:/usr/local/AMD/lib browsable_dirs = yes fully_qualified_hosts = no # DEFINE AN AMD MOUNT POINT [ /u ] map_name = amd.u [ /proj ] map_name = amd.proj [ /src ] map_name = amd.src [ /misc ] map_name = amd.misc [ /import ] map_name = amd.import [ /tftpboot/.amd ] tag = tftpboot map_name = amd.tftpboot |
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7.1 Starting Amd | ||
7.2 Stopping Amd | ||
7.3 Restarting Amd | ||
7.4 Controlling Amd |
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Amd is best started from `/etc/rc.local' on BSD systems, or from the appropriate start-level script in `/etc/init.d' on System V systems.
if [ -f /usr/local/sbin/ctl-amd ]; then /usr/local/sbin/ctl-amd start; (echo -n ' amd') > /dev/console fi |
The shell script, `ctl-amd' is used to start, stop, or restart Amd. It is a relatively generic script. All options you want to set should not be made in this script, but rather updated in the `amd.conf' file. See section Amd Configuration File.
If you do not wish to use an Amd configuration file, you may start Amd manually. For example, getting the map entries via NIS:
amd -r -l /var/log/amd `ypcat -k auto.master` |
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Amd stops in response to two signals.
causes the top-level automount points to be unmounted and then Amd
to exit. Any automounted filesystems are left mounted. They can be
recovered by restarting Amd with the -r
command line option.
causes Amd to attempt to unmount any filesystems which it has automounted, in addition to the actions of `SIGTERM'. This signal is primarily used for debugging.
Actions taken for other signals are undefined.
The easiest and safest way to stop Amd, without having to find its process ID by hand, is to use the `ctl-amd' script, as with:
ctl-amd stop |
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Before Amd can be started, it is vital to ensure that no other Amd processes are managing any of the mount points, and that the previous process(es) have terminated cleanly. When a terminating signal is set to Amd, the automounter does not terminate right then. Rather, it starts by unmounting all of its managed mount mounts in the background, and then terminates. It usually takes a few seconds for this process to happen, but it can take an arbitrarily longer time. If two or more Amd processes attempt to manage the same mount point, it usually will result in a system lockup.
The easiest and safest way to restart Amd, without having to find its process ID by hand, sending it the `SIGTERM' signal, waiting for Amd to die cleanly, and verifying so, is to use the `ctl-amd' script, as with:
ctl-amd restart |
The script will locate the process ID of Amd, kill it, and wait for it to die cleanly before starting a new instance of the automounter. `ctl-amd' will wait for a total of 30 seconds for Amd to die, and will check once every 5 seconds if it had.
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It is sometimes desirable or necessary to exercise external control over some of Amd's internal state. To support this requirement, Amd implements an RPC interface which is used by the Amq program. A variety of information is available.
Amq generally applies an operation, specified by a single letter option, to a list of mount points. The default operation is to obtain statistics about each mount point. This is similar to the output shown above but includes information about the number and type of accesses to each mount point.
7.4.1 Amq default information | Default command behavior. | |
7.4.2 Amq -f option | Flushing the map cache. | |
7.4.3 Amq -h option | Controlling a non-local host. | |
7.4.4 Amq -H option | Print help message. | |
7.4.5 Amq -l option | Controlling the log file. | |
7.4.6 Amq -m option | Obtaining mount statistics. | |
7.4.7 Amq -p option | Getting Amd's process ID. | |
7.4.8 Amq -P option | Contacting alternate Amd processes. | |
7.4.9 Amq -s option | Obtaining global statistics. | |
7.4.10 Amq -T option | Use TCP transport. | |
7.4.11 Amq -U option | Use UDP transport. | |
7.4.12 Amq -u option | Forcing volumes to time out. | |
7.4.13 Amq -v option | Version information. | |
7.4.14 Amq -w option | Print Amd current working directory. | |
7.4.15 Other Amq options | Three other special options. |
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With no arguments, Amq obtains a brief list of all existing mounts created by Amd. This is different from the list displayed by df(1) since the latter only includes system mount points.
The output from this option includes the following information:
For example:
/ root "root" sky:(pid75) /homes toplvl /usr/local/etc/amd.homes /homes /home toplvl /usr/local/etc/amd.home /home /homes/jsp nfs charm:/home/charm /a/charm/home/charm/jsp /homes/phjk nfs toytown:/home/toytown /a/toytown/home/toytown/ai/phjk |
If an argument is given then statistics for that volume name will be output. For example:
What Uid Getattr Lookup RdDir RdLnk Statfs Mounted@ /homes 0 1196 512 22 0 30 90/09/14 12:32:55 /homes/jsp 0 0 0 0 1180 0 90/10/13 12:56:58 |
What
the volume name.
Uid
ignored.
Getattr
the count of NFS getattr requests on this node. This should only be non-zero for directory nodes.
Lookup
the count of NFS lookup requests on this node. This should only be non-zero for directory nodes.
RdDir
the count of NFS readdir requests on this node. This should only be non-zero for directory nodes.
RdLnk
the count of NFS readlink requests on this node. This should be zero for directory nodes.
Statfs
the count of NFS statfs requests on this node. This should only be non-zero for top-level automount points.
Mounted@
the date and time the volume name was first referenced.
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-f
option The -f
option causes Amd to flush the internal mount map cache.
This is useful for example in Hesiod maps since Amd will not
automatically notice when they have been updated. The map cache can
also be synchronized with the map source by using the `sync' option
(see section Automount Filesystem (`auto')).
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-h
option By default the local host is used. In an HP-UX cluster the root server
is used since that is the only place in the cluster where Amd will
be running. To query Amd on another host the -h
option should
be used.
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-H
option Print a brief help and usage string.
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-l
option Tell Amd to use log_file as the log file name. For security reasons, this must be the same log file which Amd used when started. This option is therefore only useful to refresh Amd's open file handle on the log file, so that it can be rotated and compressed via daily cron jobs.
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-m
option The -m
option displays similar information about mounted
filesystems, rather than automount points. The output includes the
following information:
For example:
"root" truth:(pid602) root 1 localhost is up hesiod.home /home toplvl 1 localhost is up hesiod.vol /vol toplvl 1 localhost is up hesiod.homes /homes toplvl 1 localhost is up amy:/home/amy /a/amy/home/amy nfs 5 amy is up swan:/home/swan /a/swan/home/swan nfs 0 swan is up (Permission denied) ex:/home/ex /a/ex/home/ex nfs 0 ex is down |
When the reference count is zero the filesystem is not mounted but the mount point and server information is still being maintained by Amd.
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-p
option Return the process ID of the remote or locally running Amd. Useful when you need to send a signal to the local Amd process, and would rather not have to search through the process table. This option is used in the `ctl-amd' script.
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-P
option Contact an alternate running Amd that had registered itself on a different RPC program_number and apply all other operations to that instance of the automounter. This is useful when you run multiple copies of Amd, and need to manage each one separately. If not specified, Amq will use the default program number for Amd, 300019. For security reasons, the only alternate program numbers Amd can use range from 300019 to 300029, inclusive.
For example, to kill an alternate running Amd:
kill `amq -p -P 300020` |
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-s
option The -s
option displays global statistics. If any other options are specified
or any filesystems named then this option is ignored. For example:
requests stale mount mount unmount deferred fhandles ok failed failed 1054 1 487 290 7017 |
are those for which an immediate reply could not be constructed. For example, this would happen if a background mount was required.
counts the number of times the kernel passes a stale filehandle to Amd. Large numbers indicate problems.
counts the number of automounts which were successful.
counts the number of automounts which failed.
counts the number of times a filesystem could not be unmounted. Very large numbers here indicate that the time between unmount attempts should be increased.
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-T
option The -T
option causes the Amq to contact Amd using the TCP
transport only (connection oriented). Normally, Amq will use TCP
first, and if that failed, will try UDP.
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-U
option The -U
option causes the Amq to contact Amd using the UDP
transport only (connectionless). Normally, Amq will use TCP first,
and if that failed, will try UDP.
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-u
option The -u
option causes the time-to-live interval of the named mount
points to be expired, thus causing an unmount attempt. This is the only
safe way to unmount an automounted filesystem. It is not possible to
unmount a filesystem which has been mounted with the `nounmount'
flag.
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-v
option The -v
option displays the version of Amd in a similar way to
Amd's -v
option.
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-w
option The -w
option translates a full pathname as returned by
getpwd(3) into a short Amd pathname that goes through its mount
points. This option requires that Amd is running.
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Two other operations are implemented. These modify the state of Amd
as a whole, rather than any particular filesystem. The -x
and
-D
options have exactly the same effect as Amd's corresponding
command line options.
When Amd receives the -x
flag, it disallows turning off the
`fatal' or `error' flags. Both are on by default. They are
mandatory so that Amd could report important errors, including
errors relating to turning flags on/off.
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XXX: this chapter should be reviewed by someone knowledgeable with fsinfo.
8.1 FSinfo overview | Introduction to FSinfo. | |
8.2 Using FSinfo | Basic concepts. | |
8.3 FSinfo grammar | Language syntax, semantics and examples. | |
8.4 FSinfo host definitions | Defining a new host. | |
8.5 FSinfo host attributes | Definable host attributes. | |
8.6 FSinfo filesystems | Defining locally attached filesystems. | |
8.7 FSinfo static mounts | Defining additional static mounts. | |
8.8 Defining an Amd Mount Map in FSinfo | ||
8.9 FSinfo Command Line Options | ||
8.10 Errors produced by FSinfo |
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FSinfo is a filesystem management tool. It has been designed to work with Amd to help system administrators keep track of the ever increasing filesystem namespace under their control.
The purpose of FSinfo is to generate all the important standard filesystem data files from a single set of input data. Starting with a single data source guarantees that all the generated files are self-consistent. One of the possible output data formats is a set of Amd maps which can be used among the set of hosts described in the input data.
FSinfo implements a declarative language. This language is specifically designed for describing filesystem namespace and physical layouts. The basic declaration defines a mounted filesystem including its device name, mount point, and all the volumes and access permissions. FSinfo reads this information and builds an internal map of the entire network of hosts. Using this map, many different data formats can be produced including `/etc/fstab', `/etc/exports', Amd mount maps and `/etc/bootparams'.
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The basic strategy when using FSinfo is to gather all the information about all disks on all machines into one set of declarations. For each machine being managed, the following data is required:
The following information can also be entered into the same configuration files so that all data can be kept in one place.
To generate Amd mount maps, the automount tree must also be defined (see section Defining an Amd Mount Map in FSinfo). This will have been designed at the time the volume names were allocated. Some volume names will not be automounted, so FSinfo needs an explicit list of which volumes should be automounted.
Hostnames are required at several places in the FSinfo language. It is important to stick to either fully qualified names or unqualified names. Using a mixture of the two will inevitably result in confusion.
Sometimes volumes need to be referenced which are not defined in the set of hosts being managed with FSinfo. The required action is to add a dummy set of definitions for the host and volume names required. Since the files generated for those particular hosts will not be used on them, the exact values used is not critical.
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FSinfo has a relatively simple grammar. Distinct syntactic constructs exist for each of the different types of data, though they share a common flavor. Several conventions are used in the grammar fragments below.
The notation, list(xxx), indicates a list of zero or more xxx's. The notation, opt(xxx), indicates zero or one xxx. Items in double quotes, eg "host", represent input tokens. Items in angle brackets, eg <hostname>, represent strings in the input. Strings need not be in double quotes, except to differentiate them from reserved words. Quoted strings may include the usual set of C "\" escape sequences with one exception: a backslash-newline-whitespace sequence is squashed into a single space character. To defeat this feature, put a further backslash at the start of the second line.
At the outermost level of the grammar, the input consists of a sequence of host and automount declarations. These declarations are all parsed before they are analyzed. This means they can appear in any order and cyclic host references are possible.
fsinfo : list(fsinfo_attr) ; fsinfo_attr : host | automount ; |
8.4 FSinfo host definitions | ||
8.8 Defining an Amd Mount Map in FSinfo |
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A host declaration consists of three parts: a set of machine attribute data, a list of filesystems physically attached to the machine, and a list of additional statically mounted filesystems.
host : "host" host_data list(filesystem) list(mount) ; |
Each host must be declared in this way exactly once. Such things as the hardware address, the architecture and operating system types and the cluster name are all specified within the host data.
All the disks the machine has should then be described in the list of filesystems. When describing disks, you can specify what volname the disk/partition should have and all such entries are built up into a dictionary which can then be used for building the automounter maps.
The list of mounts specifies all the filesystems that should be statically mounted on the machine.
8.5 FSinfo host attributes | ||
8.6 FSinfo filesystems | ||
8.7 FSinfo static mounts |
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The host data, host_data, always includes the hostname. In addition, several other host attributes can be given.
host_data : <hostname> | "{" list(host_attrs) "}" <hostname> ; host_attrs : host_attr "=" <string> | netif ; host_attr : "config" | "arch" | "os" | "cluster" ; |
The hostname is, typically, the fully qualified hostname of the machine.
Examples:
host dylan.doc.ic.ac.uk host { os = hpux arch = hp300 } dougal.doc.ic.ac.uk |
The options that can be given as host attributes are shown below.
8.5.1 netif Option | FSinfo host netif. | |
8.5.2 config Option | FSinfo host config. | |
8.5.3 arch Option | FSinfo host arch. | |
8.5.4 os Option | FSinfo host os. | |
8.5.5 cluster Option | FSinfo host cluster. |
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This defines the set of network interfaces configured on the machine. The interface attributes collected by FSinfo are the IP address, subnet mask and hardware address. Multiple interfaces may be defined for hosts with several interfaces by an entry for each interface. The values given are sanity checked, but are currently unused for anything else.
netif : "netif" <string> "{" list(netif_attrs) "}" ; netif_attrs : netif_attr "=" <string> ; netif_attr : "inaddr" | "netmask" | "hwaddr" ; |
Examples:
netif ie0 { inaddr = 129.31.81.37 netmask = 0xfffffe00 hwaddr = "08:00:20:01:a6:a5" } netif ec0 { } |
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This option allows you to specify configuration variables for the startup scripts (`rc' scripts). A simple string should immediately follow the keyword.
Example:
config "NFS_SERVER=true" config "ZEPHYR=true" |
This option is currently unsupported.
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This defines the architecture of the machine. For example:
arch = hp300 |
This is intended to be of use when building architecture specific mountmaps, however, the option is currently unsupported.
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This defines the operating system type of the host. For example:
os = hpux |
This information is used when creating the `fstab' files, for example in choosing which format to use for the `fstab' entries within the file.
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This is used for specifying in which cluster the machine belongs. For example:
cluster = "theory" |
The cluster is intended to be used when generating the automount maps, although it is currently unsupported.
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The list of physically attached filesystems follows the machine attributes. These should define all the filesystems available from this machine, whether exported or not. In addition to the device name, filesystems have several attributes, such as filesystem type, mount options, and `fsck' pass number which are needed to generate `fstab' entries.
filesystem : "fs" <device> "{" list(fs_data) "}" ; fs_data : fs_data_attr "=" <string> | mount ; fs_data_attr : "fstype" | "opts" | "passno" | "freq" | "dumpset" | "log" ; |
Here, <device> is the device name of the disk (for example, `/dev/dsk/2s0'). The device name is used for building the mount maps and for the `fstab' file. The attributes that can be specified are shown in the following section.
The FSinfo configuration file for dylan.doc.ic.ac.uk
is listed below.
host dylan.doc.ic.ac.uk fs /dev/dsk/0s0 { fstype = swap } fs /dev/dsk/0s0 { fstype = hfs opts = rw,noquota,grpid passno = 0; freq = 1; mount / { } } fs /dev/dsk/1s0 { fstype = hfs opts = defaults passno = 1; freq = 1; mount /usr { local { exportfs "dougal eden dylan zebedee brian" volname /nfs/hp300/local } } } fs /dev/dsk/2s0 { fstype = hfs opts = defaults passno = 1; freq = 1; mount default { exportfs "toytown_clients hangers_on" volname /home/dylan/dk2 } } fs /dev/dsk/3s0 { fstype = hfs opts = defaults passno = 1; freq = 1; mount default { exportfs "toytown_clients hangers_on" volname /home/dylan/dk3 } } fs /dev/dsk/5s0 { fstype = hfs opts = defaults passno = 1; freq = 1; mount default { exportfs "toytown_clients hangers_on" volname /home/dylan/dk5 } } |
8.6.1 fstype Option | FSinfo filesystems fstype. | |
8.6.2 opts Option | FSinfo filesystems opts. | |
8.6.3 passno Option | FSinfo filesystems passno. | |
8.6.4 freq Option | FSinfo filesystems freq. | |
8.6.5 mount Option | FSinfo filesystems mount. | |
8.6.6 dumpset Option | FSinfo filesystems dumpset. | |
8.6.7 log Option | FSinfo filesystems log. |
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This specifies the type of filesystem being declared and will be placed
into the `fstab' file as is. The value of this option will be
handed to mount
as the filesystem type--it should have such
values as 4.2
, nfs
or swap
. The value is not
examined for correctness.
There is one special case. If the filesystem type is specified as `export' then the filesystem information will not be added to the host's `fstab' information, but it will still be visible on the network. This is useful for defining hosts which contain referenced volumes but which are not under full control of FSinfo.
Example:
fstype = swap |
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This defines any options that should be given to mount(8) in the `fstab' file. For example:
opts = rw,nosuid,grpid |
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This defines the fsck(8) pass number in which to check the filesystem. This value will be placed into the `fstab' file.
Example:
passno = 1 |
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This defines the interval (in days) between dumps. The value is placed as is into the `fstab' file.
Example:
freq = 3 |
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This defines the mountpoint at which to place the filesystem. If the
mountpoint of the filesystem is specified as default
, then the
filesystem will be mounted in the automounter's tree under its volume
name and the mount will automatically be inherited by the automounter.
Following the mountpoint, namespace information for the filesystem may
be described. The options that can be given here are exportfs
,
volname
and sel
.
The format is:
mount : "mount" vol_tree ; vol_tree : list(vol_tree_attr) ; vol_tree_attr : <string> "{" list(vol_tree_info) vol_tree "}" ; vol_tree_info : "exportfs" <export-data> | "volname" <volname> | "sel" <selector-list> ; |
Example:
mount default { exportfs "dylan dougal florence zebedee" volname /vol/andrew } |
In the above example, the filesystem currently being declared will have
an entry placed into the `exports' file allowing the filesystem to
be exported to the machines dylan
, dougal
, florence
and zebedee
. The volume name by which the filesystem will be
referred to remotely, is `/vol/andrew'. By declaring the
mountpoint to be default
, the filesystem will be mounted on the
local machine in the automounter tree, where Amd will automatically
inherit the mount as `/vol/andrew'.
a string defining which machines the filesystem may be exported to. This is copied, as is, into the `exports' file--no sanity checking is performed on this string.
a string which declares the remote name by which to reference the filesystem. The string is entered into a dictionary and allows you to refer to this filesystem in other places by this volume name.
a string which is placed into the automounter maps as a selector for the filesystem.
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This provides support for Imperial College's local file backup tools and is not documented further here.
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Specifies the log device for the current filesystem. This is ignored if not required by the particular filesystem type.
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Each host may also have a number of statically mounted filesystems. For
example, the host may be a diskless workstation in which case it will
have no fs
declarations. In this case the mount
declaration is used to determine from where its filesystems will be
mounted. In addition to being added to the `fstab' file, this
information can also be used to generate a suitable `bootparams'
file.
mount : "mount" <volname> list(localinfo) ; localinfo : localinfo_attr <string> ; localinfo_attr : "as" | "from" | "fstype" | "opts" ; |
The filesystem specified to be mounted will be searched for in the dictionary of volume names built when scanning the list of hosts' definitions.
The attributes have the following semantics:
mount the filesystem from the machine with the hostname of machine.
mount the filesystem locally as the name given, in case this is different from the advertised volume name of the filesystem.
native mount(8) options.
type of filesystem to be mounted.
An example:
mount /export/exec/hp300/local as /usr/local |
If the mountpoint specified is either `/' or `swap', the machine will be considered to be booting off the net and this will be noted for use in generating a `bootparams' file for the host which owns the filesystems.
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The maps used by Amd can be constructed from FSinfo by defining all the automount trees. FSinfo takes all the definitions found and builds one map for each top level tree.
The automount tree is usually defined last. A single automount
configuration will usually apply to an entire management domain. One
automount
declaration is needed for each Amd automount point.
FSinfo determines whether the automount point is direct
(see section Direct Automount Filesystem (`direct')) or indirect
(see section Top-level Filesystem (`toplvl')). Direct automount points are
distinguished by the fact that there is no underlying
automount_tree.
automount : "automount" opt(auto_opts) automount_tree ; auto_opts : "opts" <mount-options> ; automount_tree : list(automount_attr) ; automount_attr : <string> "=" <volname> | <string> "->" <symlink> | <string> "{" automount_tree "}" ; |
If <mount-options> is given, then it is the string to be placed in
the maps for Amd for the opts
option.
A map is typically a tree of filesystems, for example `home' normally contains a tree of filesystems representing other machines in the network.
A map can either be given as a name representing an already defined volume name, or it can be a tree. A tree is represented by placing braces after the name. For example, to define a tree `/vol', the following map would be defined:
automount /vol { } |
Within a tree, the only items that can appear are more maps. For example:
automount /vol { andrew { } X11 { } } |
In this case, FSinfo will look for volumes named `/vol/andrew' and `/vol/X11' and a map entry will be generated for each. If the volumes are defined more than once, then FSinfo will generate a series of alternate entries for them in the maps.
Instead of a tree, either a link (name ->
destination) or a reference can be specified (name =
destination). A link creates a symbolic link to the string
specified, without further processing the entry. A reference will
examine the destination filesystem and optimize the reference. For
example, to create an entry for njw
in the `/homes' map,
either of the two forms can be used:
automount /homes { njw -> /home/dylan/njw } |
or
automount /homes { njw = /home/dylan/njw } |
In the first example, when `/homes/njw' is referenced from Amd, a link will be created leading to `/home/dylan/njw' and the automounter will be referenced a second time to resolve this filename. The map entry would be:
njw type:=link;fs:=/home/dylan/njw |
In the second example, the destination directory is analyzed and found to be in the filesystem `/home/dylan' which has previously been defined in the maps. Hence the map entry will look like:
njw rhost:=dylan;rfs:=/home/dylan;sublink:=njw |
Creating only one symbolic link, and one access to Amd.
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FSinfo is started from the command line by using the command:
fsinfo [options] files ... |
The input to FSinfo is a single set of definitions of machines and automount maps. If multiple files are given on the command-line, then the files are concatenated together to form the input source. The files are passed individually through the C pre-processor before being parsed.
Several options define a prefix for the name of an output file. If the prefix is not specified no output of that type is produced. The suffix used will correspond either to the hostname to which a file belongs, or to the type of output if only one file is produced. Dumpsets and the `bootparams' file are in the latter class. To put the output into a subdirectory simply put a `/' at the end of the prefix, making sure that the directory has already been made before running Fsinfo.
8.9.1 -a autodir | Amd automount directory: | |
8.9.2 -b bootparams | Prefix for bootparams files. | |
8.9.3 -d dumpsets | Prefix for dumpset data files. | |
8.9.4 -e exportfs | Prefix for exports files. | |
8.9.5 -f fstab | Prefix for fstab files. | |
8.9.6 -h hostname | Local hostname. | |
8.9.7 -m mount-maps | Prefix for automount maps. | |
8.9.8 -q | Ultra quiet mode. | |
8.9.9 -v | Verbose mode. | |
8.9.11 -I directory | Define new #include directory. | |
8.9.10 -D name[=defn] | Define macro. | |
8.9.12 -U name | Undefine macro. |
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-a
autodir Specifies the directory name in which to place the automounter's mountpoints. This defaults to `/a'. Some sites have the autodir set to be `/amd', and this would be achieved by:
fsinfo -a /amd ... |
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-b
bootparams This specifies the prefix for the `bootparams' filename. If it is not given, then the file will not be generated. The `bootparams' file will be constructed for the destination machine and will be placed into a file named `bootparams' and prefixed by this string. The file generated contains a list of entries describing each diskless client that can boot from the destination machine.
As an example, to create a `bootparams' file in the directory `generic', the following would be used:
fsinfo -b generic/ ... |
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-d
dumpsets This specifies the prefix for the `dumpsets' file. If it is not specified, then the file will not be generated. The file will be for the destination machine and will be placed into a filename `dumpsets', prefixed by this string. The `dumpsets' file is for use by Imperial College's local backup system.
For example, to create a `dumpsets' file in the directory `generic', then you would use the following:
fsinfo -d generic/ ... |
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-e
exportfs Defines the prefix for the `exports' files. If it is not given, then the file will not be generated. For each machine defined in the configuration files as having disks, an `exports' file is constructed and given a filename determined by the name of the machine, prefixed with this string. If a machine is defined as diskless, then no `exports' file will be created for it. The files contain entries for directories on the machine that may be exported to clients.
Example: To create the `exports' files for each diskfull machine and place them into the directory `exports':
fsinfo -e exports/ ... |
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-f
fstab This defines the prefix for the `fstab' files. The files will only be created if this prefix is defined. For each machine defined in the configuration files, a `fstab' file is created with the filename determined by prefixing this string with the name of the machine. These files contain entries for filesystems and partitions to mount at boot time.
Example, to create the files in the directory `fstabs':
fsinfo -f fstabs/ ... |
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-h
hostname Defines the hostname of the destination machine to process for. If this is not specified, it defaults to the local machine name, as returned by gethostname(2).
Example:
fsinfo -h dylan.doc.ic.ac.uk ... |
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-m
mount-maps Defines the prefix for the automounter files. The maps will only be produced if this prefix is defined. The mount maps suitable for the network defined by the configuration files will be placed into files with names calculated by prefixing this string to the name of each map.
For example, to create the automounter maps and place them in the directory `automaps':
fsinfo -m automaps/ ... |
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-q
Selects quiet mode. FSinfo suppress the "running commentary" and only outputs any error messages which are generated.
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-v
Selects verbose mode. When this is activated, the program will display more messages, and display all the information discovered when performing the semantic analysis phase. Each verbose message is output to `stdout' on a line starting with a `#' character.
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-D
name[=defn] Defines a symbol name for the preprocessor when reading the
configuration files. Equivalent to #define
directive.
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-I
directory This option is passed into the preprocessor for the configuration files. It specifies directories in which to find include files
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-U
name Removes any initial definition of the symbol name. Inverse of the
-D
option.
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The following table documents the errors and warnings which FSinfo may produce.
Occurs if an unescaped newline is found in a quoted string.
If several filesystems are declared as having the same volume name, they will be considered replicated filesystems. To mount a replicated filesystem statically, a specific host will need to be named, to say which particular copy to try and mount, else this error will result.
Occurs if any errors are encountered when opening an output file.
If a volume is replicated and an attempt is made to mount the filesystem statically without specifying a local mountpoint, FSinfo cannot calculate a mountpoint, as the desired pathname would be ambiguous.
Produced if the `exportfs' option is used multiple times within the same branch of a filesystem definition. For example, if you attempt to set the `exportfs' data at different levels of the mountpoint directory tree.
Occurs if device has its `fstype' declared to be `swap' or `export' and the `dump' option is set to a value greater than zero. Swap devices should not be dumped.
If a host has more than one definition.
A comment was unterminated before the end of one of the configuration files.
If a file specified on the command line as containing configuration data could not be opened.
Occurs when a volume name is declared for a file system, but the string specifying what machines the filesystem can be exported to is missing.
Occurs when multiple definitions are given for one of the attributes of a host's filesystem.
If duplicate definitions are given for any of the fields with a host definition.
Occurs if the mount option for a host's filesystem specifies multiple trees at which to place the mountpoint.
Occurs if the `mount' option is not specified for a host's filesystem.
Occurs when a filesystem is missing a required field. field-name could be one of `fstype', `opts', `passno' or `mount'.
Occurs if a mountpoint is given for a filesystem whose type is declared to be `swap'.
If the Internet address of an interface is incorrectly specified. An Internet address definition is handled to inet_addr(3N) to see if it can cope. If not, then this message will be displayed.
If the netmask cannot be decoded as though it were a hexadecimal number, then this message will be displayed. It will typically be caused by incorrect characters in the netmask value.
Occurs when a static mount has multiple definitions of the same field.
Occurs when the field-name is defined more than once during the definition of a filesystems mountpoint.
Occurs if you attempt to define an attribute of an interface more than once.
Occurs if a machine has mount declarations for either the root partition or the swap area, but not both. You cannot define a machine to only partially boot via the network.
If there are no static mounts, nor local disk mounts specified for a machine, this message will be displayed.
Occurs when a filesystem is defined to be mounted on `default', but no volume name is given for the file system, then the mountpoint cannot be determined.
Occurs when a pathname with multiple directory elements is specified as the name for an automounter tree. A tree should only have one name at each level.
Occurs if device has its `fstype' declared to be `swap' or `export' and the fsck(8) pass number is set. Swap devices should not be fsck'd. See section fstype Option.
Within the filesystem specification for a host, if an element directory of the mountpoint begins with a `/' and it is not the start of the tree.
`default' is a keyword used to specify if a mountpoint should be automatically calculated by FSinfo. If you attempt to specify a directory name as this, it will use the filename of `default' but will produce this warning.
Occurs if an unknown escape sequence is found inside a string. Within a string, you can give the standard C escape sequences for strings, such as newlines and tab characters.
If an unknown keyword is found while reading the definition of a host's filesystem mount option.
Occurs if an unrecognized keyword is used when defining a host's filesystems.
Occurs if an unrecognized keyword is used when defining a host.
Occurs if an unrecognized keyword is found while parsing the list of static mounts.
Occurs if volume is used in a definition of an automount map but the volume name has not been declared during the host filesystem definitions.
Occurs if an attempt is made to mount or reference a volume name which has not been declared during the host filesystem definitions.
Occurs if you attempt to mount the volume volume from a machine which has not declared itself to have such a filesystem available.
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Hlfsd is a daemon which implements a filesystem 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 be read from anywhere. It was designed and implemented by Erez Zadok and Alexander Dupuy, at the Computer Science Department of Columbia University. A paper on Hlfsd was presented at the Usenix LISA VII conference in 1993.
Hlfsd operates by mounting itself as an NFS server for the directory containing linkname, which defaults to `/hlfs/home'. Lookups within that directory are handled by Hlfsd, which uses the password map to determine how to resolve the lookup. The directory will be created if it doesn't already exist. The symbolic link will be to the accessing user's home directory, with subdir appended to it. If not specified, subdir defaults to `.hlfsdir'. This directory will also be created if it does not already exist.
A `SIGTERM' sent to Hlfsd will cause it to shutdown. A `SIGHUP' will flush the internal caches, and reload the password map. It will also close and reopen the log file, to enable the original log file to be removed or rotated. A `SIGUSR1' will cause it to dump its internal table of user IDs and home directories to the file `/tmp/hlfsddump'.
9.1 Introduction to Hlfsd | ||
9.2 Background to Mail Delivery | ||
9.3 Using Hlfsd |
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Electronic mail has become one of the major applications for many computer networks, and use of this service is expected to increase over time, as networks proliferate and become faster. Providing a convenient environment for users to read, compose, and send electronic mail has become a requirement for systems administrators (SAs).
Widely used methods for handling mail usually require users to be logged into a designated "home" machine, where their mailbox files reside. Only on that one machine can they read newly arrived mail. Since users have to be logged into that system to read their mail, they often find it convenient to run all of their other processes on that system as well, including memory and CPU-intensive jobs. For example, in our department, we have allocated and configured several multi-processor servers to handle such demanding CPU/memory applications, but these were underutilized, in large part due to the inconvenience of not being able to read mail on those machines. (No home directories were located on these designated CPU-servers, since we did not want NFS service for users' home directories to have to compete with CPU-intensive jobs. At the same time, we discouraged users from running demanding applications on their home machines.)
Many different solutions have been proposed to allow users to read their mail on any host. However, all of these solutions fail in one or more of several ways:
We have designed a simple filesystem, called the Home-Link File System, to provide the ability to deliver mail to users' home directories, without modification to mail-related applications. We have endeavored to make it as stable as possible. Of great importance to us was to make sure the HLFS daemon, `hlfsd' , would not hang under any circumstances, and would take the next-best action when faced with problems. Compared to alternative methods, Hlfsd is a stable, more general solution, and easier to install/use. In fact, in some ways, we have even managed to improve the reliability and security of mail service.
Our server implements a small filesystem containing a symbolic link to a subdirectory of the invoking user's home directory, and named symbolic links to users' mailbox files.
The Hlfsd server finds out the uid of the process that is accessing its mount point, and resolves the pathname component `home' as a symbolic link to a subdirectory within the home directory given by the uid's entry in the password file. If the gid of the process that attempts to access a mailbox file is a special one (called HLFS_GID), then the server maps the name of the next pathname component directly to the user's mailbox. This is necessary so that access to a mailbox file by users other than the owner can succeed. The server has safety features in case of failures such as hung filesystems or home directory filesystems that are inaccessible or full.
On most of our machines, mail gets delivered to the directory `/var/spool/mail'. Many programs, including UAs, depend on that path. Hlfsd creates a directory `/mail', and mounts itself on top of that directory. Hlfsd implements the path name component called `home', pointing to a subdirectory of the user's home directory. We have made `/var/spool/mail' a symbolic link to `/mail/home', so that accessing `/var/spool/mail' actually causes access to a subdirectory within a user's home directory.
The following table shows an example of how resolving the pathname `/var/mail/NAME' to `/users/ezk/.mailspool/NAME' proceeds.
Resolving Component | Pathname left to resolve | Value if symbolic link |
/ | var/mail/NAME | |
var/ | mail/NAME | |
mail@ | /mail/home/NAME | mail@ -> /mail/home |
/ | mail/home/NAME | |
mail/ | home/NAME | |
home@ | NAME | home@ -> /users/ezk/.mailspool |
/ | users/ezk/.mailspool/NAME | |
users/ | ezk/.mailspool/NAME | |
ezk/ | .mailspool/NAME | |
.mailspool/ | NAME | |
NAME |
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This section provides an in-depth discussion of why available methods for delivering mail to home directories are not as good as the one used by Hlfsd.
9.2.1 Single-Host Mail Spool Directory | ||
9.2.2 Centralized Mail Spool Directory | ||
9.2.3 Distributed Mail Spool Service | ||
9.2.4 Why Deliver Into the Home Directory? |
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The most common method for mail delivery is for mail to be appended to a mailbox file in a standard spool directory on the designated "mail home" machine of the user. The greatest advantage of this method is that it is the default method most vendors provide with their systems, thus very little (if any) configuration is required on the SA's part. All they need to set up are mail aliases directing mail to the host on which the user's mailbox file is assigned. (Otherwise, mail is delivered locally, and users find mailboxes on many machines.)
As users become more sophisticated, and aided by windowing systems, they find themselves logging in on multiple hosts at once, performing several tasks concurrently. They ask to be able to read their mail on any host on the network, not just the one designated as their "mail home".
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A popular method for providing mail readability from any host is to have all mail delivered to a mail spool directory on a designated "mail-server" which is exported via NFS to all of the hosts on the network. Configuring such a system is relatively easy. On most systems, the bulk of the work is a one-time addition to one or two configuration files in `/etc'. The file-server's spool directory is then hard-mounted across every machine on the local network. In small environments with only a handful of hosts this can be an acceptable solution. In our department, with a couple of hundred active hosts and thousands of mail messages processed daily, this was deemed completely unacceptable, as it introduced several types of problems:
As more and more machines get added to the network, more mail traffic has to go over NFS to and from the mail-server. Users like to run mail-watchers, and read their mail often. The stress on the shared infrastructure increases with every user and host added; loads on the mail server would most certainly be high since all mail delivery goes through that one machine.(1) This leads to lower reliability and performance. To reduce the number of concurrent connections between clients and the server host, some SAs have resorted to automounting the mail-spool directory. But this solution only makes things worse: since users often run mail watchers, and many popular applications such as `trn', `emacs', `csh' or `ksh' check periodically for new mail, the automounted directory would be effectively permanently mounted. If it gets unmounted automatically by the automounter program, it is most likely to get mounted shortly afterwards, consuming more I/O resources by the constant cycle of mount and umount calls.
The mail-server host and its network connectivity must be very reliable. Worse, since the spool directory has to be hard-mounted,(2) many processes which access the spool directory (various shells, `login', `emacs', etc.) would be hung as long as connectivity to the mail-server is severed. To improve reliability, SAs may choose to backup the mail-server's spool partition several times a day. This may make things worse since reading or delivering mail while backups are in progress may cause backups to be inconsistent; more backups consume more backup-media resources, and increase the load on the mail-server host.
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Despite the existence of a few systems that support delivery to users' home directories, mail delivery to home directories hasn't caught on. We believe the main reason is that there are too many programs that "know" where mailbox files reside. Besides the obvious (the delivery program `/bin/mail' and mail readers like `/usr/ucb/Mail', `mush', `mm', etc.), other programs that know mailbox location are login, from, almost every shell, `xbiff', `xmailbox', and even some programs not directly related to mail, such as `emacs' and `trn'. Although some of these programs can be configured to look in different directories with the use of environment variables and other resources, many of them cannot. The overall porting work is significant.
Other methods that have yet to catch on require the use of a special mail-reading server, such as IMAP or POP. The main disadvantage of these systems is that UAs need to be modified to use these services -- a long and involved task. That is why they are not popular at this time.
Several other ideas have been proposed and even used in various environments. None of them is robust. They are mostly very specialized, inflexible, and do not extend to the general case. Some of the ideas are plain bad, potentially leading to lost or corrupt mail:
Using an automounter such as Amd to provide a set of symbolic links from the normal spool directory to user home directories is not sufficient. UAs rename, unlink, and recreate the mailbox as a regular file, therefore it must be a real file, not a symbolic link. Furthermore, it must reside in a real directory which is writable by the UAs and MTAs. This method may also require populating `/var/spool/mail' with symbolic links and making sure they are updated. Making Amd manage that directory directly fails, since many various lock files need to be managed as well. Also, Amd does not provide all of the NFS operations which are required to write mail such as write, create, remove, and unlink.
$MAIL
Setting this variable to an automounted directory pointing to the user's
mail spool host only solves the problem for those programs which know
and use $MAIL
. Many programs don't, therefore this solution is partial
and of limited flexibility. Also, it requires the SAs or the users to
set it themselves -- an added level of inconvenience and possible
failures.
Using a different mail delivery agent could be the solution. One such
example is `hdmail'. However, `hdmail' still requires
modifying all UAs, the MTA's configuration, installing new daemons, and
changing login scripts. This makes the system less upgradable or
compatible with others, and adds one more complicated system for SAs to
deal with. It is not a complete solution because it still requires each
user have their $MAIL
variable setup correctly, and that every program
use this variable.
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There are several major reasons why SAs might want to deliver mail directly into the users' home directories:
Many mail readers need to move mail from the spool directory to the user's home directory. It speeds up this operation if the two are on the same filesystem. If for some reason the user's home directory is inaccessible, it isn't that useful to be able to read mail, since there is no place to move it to. In some cases, trying to move mail to a non-existent or hung filesystem may result in mail loss.
Having all mail spool directories spread among the many more filesystems minimizes the chances that complete environments will grind to a halt when a single server is down. It does increase the chance that there will be someone who is not able to read their mail when a machine is down, but that is usually preferred to having no one be able to read their mail because a centralized mail server is down. The problem of losing some mail due to the (presumably) higher chances that a user's machine is down is minimized in HLFS.
Delivering mail to users' home directories has another advantage -- enhanced security and privacy. Since a shared system mail spool directory has to be world-readable and searchable, any user can see whether other users have mail, when they last received new mail, or when they last read their mail. Programs such as `finger' display this information, which some consider an infringement of privacy. While it is possible to disable this feature of `finger' so that remote users cannot see a mailbox file's status, this doesn't prevent local users from getting the information. Furthermore, there are more programs which make use of this information. In shared environments, disabling such programs has to be done on a system-wide basis, but with mail delivered to users' home directories, users less concerned with privacy who do want to let others know when they last received or read mail can easily do so using file protection bits.
In summary, delivering mail to home directories provides users the functionality sought, and also avoids most of the problems just discussed.
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9.3.1 Controlling Hlfsd | ||
9.3.2 Hlfsd Options | ||
9.3.3 Hlfsd Files |
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Much the same way Amd is controlled by `ctl-amd', so does Hlfsd get controlled by the `ctl-hlfsd' script:
Start a new Hlfsd.
Stop a running Hlfsd.
Stop a running Hlfsd, wait for 10 seconds, and then start a new one. It is hoped that within 10 seconds, the previously running Hlfsd terminate properly; otherwise, starting a second one could cause system lockup.
For example, on our systems, we start Hlfsd within `ctl-hlfsd' as follows on Solaris 2 systems:
hlfsd -a /var/alt_mail -x all -l /var/log/hlfsd /mail/home .mailspool |
The directory `/var/alt_mail' is a directory in the root partition where alternate mail will be delivered into, when it cannot be delivered into the user's home directory.
Normal mail gets delivered into `/var/mail', but on our systems,
that is a symbolic link to `/mail/home'. `/mail' is managed
by Hlfsd, which creates a dynamic symlink named `home',
pointing to the subdirectory `.mailspool' within the
accessing user's home directory. This results in mail which normally
should go to `/var/mail/$USER
', to go to
`$HOME
/.mailspool/$USER
'.
Hlfsd does not create the `/var/mail' symlink. This needs to be created (manually) once on each host, by the system administrators, as follows:
mv /var/mail /var/alt_mail ln -s /mail/home /var/mail |
Hlfsd also responds to the following signals:
A `SIGHUP' signal sent to Hlfsd will force it to reload the password map immediately.
A `SIGUSR1' signal sent to Hlfsd will cause it to dump its internal password map to the file `/usr/tmp/hlfsd.dump.XXXXXX', where `XXXXXX' will be replaced by a random string generated by mktemp(3) or (the more secure) mkstemp(3).
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Alternate directory. The name of the directory to which the symbolic link returned by Hlfsd will point, if it cannot access the home directory of the user. This defaults to `/var/hlfs'. This directory will be created if it doesn't exist. It is expected that either users will read these files, or the system administrators will run a script to resend this "lost mail" to its owner.
Caching interval. Hlfsd will cache the validity of home directories for this interval, in seconds. Entries which have been verified within the last cache-interval seconds will not be verified again, since the operation could be expensive, and the entries are most likely still valid. After the interval has expired, Hlfsd will re-verify the validity of the user's home directory, and reset the cache time-counter. The default value for cache-interval is 300 seconds (5 minutes).
Force fast startup. This option tells Hlfsd to skip startup-time consistency checks such as existence of mount directory, alternate spool directory, symlink to be hidden under the mount directory, their permissions and validity.
Set the special group HLFS_GID to group. Programs such as `/usr/ucb/from' or `/usr/sbin/in.comsat', which access the mailboxes of other users, must be setgid `HLFS_GID' to work properly. The default group is `hlfs'. If no group is provided, and there is no group `hlfs', this feature is disabled.
Help. Print a brief help message, and exit.
Map-reloading interval. Each reload-interval seconds, Hlfsd will reload the password map. Hlfsd needs the password map for the UIDs and home directory pathnames. Hlfsd schedules a `SIGALRM' to reload the password maps. A `SIGHUP' sent to Hlfsd will force it to reload the maps immediately. The default value for reload-interval is 900 seconds (15 minutes.)
Specify a log file to which Hlfsd will record events. If logfile is the string `syslog' then the log messages will be sent to the system log daemon by syslog(3), using the `LOG_DAEMON' facility. This is also the default.
No verify. Hlfsd will not verify the validity of the symbolic link
it will be returning, or that the user's home directory contains
sufficient disk-space for spooling. This can speed up Hlfsd at the
cost of possibly returning symbolic links to home directories which are
not currently accessible or are full. By default, Hlfsd validates
the symbolic-link in the background. The -n
option overrides the
meaning of the -c
option, since no caching is necessary.
Mount options which Hlfsd will use to mount itself on top of dirname. By default, mount-options is set to `ro'. If the system supports symbolic-link caching, default options are set to `ro,nocache'.
Print PID. Outputs the process-id of Hlfsd to standard output where it can be saved into a file.
Version. Displays version information to standard error.
Specify run-time logging options. The options are a comma separated list chosen from: `fatal', `error', `user', `warn', `info', `map', `stats', `all'.
Force Hlfsd to run on systems that cannot turn off the NFS attribute-cache. Use of this option on those systems is discouraged, as it may result in loss or misdelivery of mail. The option is ignored on systems that can turn off the attribute-cache.
Select from a variety of debugging options. Prefixing an option with the string `no' reverses the effect of that option. Options are cumulative. The most useful option is `all'. Since this option is only used for debugging other options are not documented here. A fuller description is available in the program source.
Read the user-name, user-id, and home directory information from the file password-file. Normally, Hlfsd will use getpwent(3) to read the password database. This option allows you to override the default database, and is useful if you want to map users' mail files to a directory other than their home directory. Only the username, uid, and home-directory fields of the file password-file are read and checked. All other fields are ignored. The file password-file must otherwise be compliant with Unix Version 7 colon-delimited format passwd(4).
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The following files are used by Hlfsd:
directory under which Hlfsd mounts itself and manages the symbolic link `home'.
default sub-directory in the user's home directory, to which the `home' symbolic link returned by Hlfsd points.
directory to which `home' symbolic link returned by Hlfsd points if it is unable to verify the that user's home directory is accessible.
file to which Hlfsd will dump its internal password map when it receives the `SIGUSR1' signal. `XXXXXX' will be replaced by a random string generated by mktemp(3) or (the more secure) mkstemp(3).
For discussion on other files used by Hlfsd, see See section lostaltmail, and lostaltmail.conf-sample.
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The following are additional utilities and scripts included with am-utils, and get installed.
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A shell script unmounts a floppy or CD-ROM that is automounted, and then attempts to eject the removable device.
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A sample Amd configuration file. See section Amd Configuration File.
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A script to convert Amd maps to LDAP input files. Use it as follows:
amd2ldif mapname base < amd.mapfile > mapfile.ldif |
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A script to convert Amd maps to Sun Automounter maps. Use it as follows
amd2sun < amd.mapfile > auto_mapfile |
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A script to convert old Sun Automounter maps to Amd maps.
Say you have the Sun automount file auto.foo, with these two lines:
home earth:/home moon -ro,intr server:/proj/images |
Running
automount2amd auto.foo > amd.foo |
will produce the Amd map amd.foo with this content:
# generated by automount2amd on Sat Aug 14 17:59:32 US/Eastern 1999 /defaults \\ type:=nfs;opts:=rw,grpid,nosuid,utimeout=600 home \ host==earth;type:=link;fs:=/home \\ rhost:=earth;rfs:=/home moon \ -addopts:=ro,intr \\ host==server;type:=link;fs:=/proj/images \\ rhost:=server;rfs:=/proj/images |
This perl script will use the following /default entry
type:=nfs;opts:=rw,grpid,nosuid,utimeout=600 |
If you wish to override that, define the $DEFAULTS environment variable, or modify the script.
If you wish to generate Amd maps using the hostd (see section hostd Selector Variable) Amd map syntax, then define the environment variable $DOMAIN or modify the script.
Note that automount2amd does not understand the syntax in newer Sun Automount maps, those used with autofs.
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A script to start, stop, or restart Amd. Use it as follows:
Start a new Amd process.
Stop the running Amd.
Stop the running Amd (if any), safely wait for it to terminate, and then start a new process -- only if the previous one died cleanly.
See section Run-time Administration, for more details.
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A script for controlling Hlfsd, much the same way `ctl-amd' controls Amd. Use it as follows:
Start a new Hlfsd process.
Stop the running Hlfsd.
Stop the running Hlfsd (if any), wait for 10 seconds for it to terminate, and then start a new process -- only if the previous one died cleanly.
See section Hlfsd, for more details.
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A script to expand email addresses into their full name. It is generally useful when using with the `lostaltmail' script, but is a useful tools otherwise.
$ expn -v ezk@example.com ezk@example.com -> ezk@shekel.example.com ezk@shekel.example.com -> Erez Zadok <"| /usr/local/mh/lib/slocal -user ezk || exit 75> Erez Zadok <\ezk> Erez Zadok </u/zing/ezk/.mailspool/backup> |
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Am-utils changed some of the syntax and default values of some variables. For example, the default value for `${os}' for Solaris 2.x (aka SunOS 5.x) systems used to be `sos5', it is now more automatically generated from `config.guess' and its value is `sunos5'.
This script converts older Amd maps to new ones. Use it as follows:
fix-amd-map < old.map > new.map |
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`fixmount' is a variant of showmount(8) that can delete bogus mount entries in remote mountd(8) daemons. This is useful to cleanup otherwise ever-accumulating "junk". Use it for example:
fixmount -r host |
See the online manual page for `fixmount' for more details of its usage.
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A script to invalidate `/etc/rmtab' entries for hosts named. Also restart mountd for changes to take effect. Use it for example:
fixrmtab host1 host2 ... |
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A script used with Hlfsd to resend any "lost" mail. Hlfsd redirects mail which cannot be written into the user's home directory to an alternate directory. This is useful to continue delivering mail, even if the user's file system was unavailable, full, or over quota. But, the mail which gets delivered to the alternate directory needs to be resent to its respective users. This is what the `lostaltmail' script does.
Use it as follows:
lostaltmail |
This script needs a configuration file `lostaltmail.conf' set up with the right parameters to properly work. See section Hlfsd, for more details.
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This is a text file with configuration parameters needed for the `lostaltmail' script. The script includes comments explaining each of the configuration variables. See it for more information. Also see section Hlfsd for general information.
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This program converts a normal Amd map file into an ndbm database with the same prefix as the named file. Use it as follows:
mk-amd-map mapname |
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Pawd is used to print the current working directory, adjusted to reflect proper paths that can be reused to go through the automounter for the shortest possible path. In particular, the path printed back does not include any of Amd's local mount points. Using them is unsafe, because Amd may unmount managed file systems from the mount points, and thus including them in paths may not always find the files within.
Without any arguments, Pawd will print the automounter adjusted current working directory. With any number of arguments, it will print the adjusted path of each one of the arguments.
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This script is similar to ctl-amd (see section ctl-amd) but is intended for Red Hat Linux systems. You can safely copy redhat-ctl-amd onto `/etc/rc.d/init.d/amd'. The script supplied by Am-utils is usually better than the one provided by Red Hat, because the Red Hat script does not correctly kill Amd processes: it is too quick to kill the wrong processes, leaving stale or hung mount points behind.
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A script to wait for Amd to start on a particular host before performing an arbitrary command. The command is executed repeatedly, with 1 second intervals in between. You may interrupt the script using `^C' (or whatever keyboard sequence your terminal's `intr' function is bound to).
Examples:
When Amd is up on host `saturn', get the process ID of that running Amd.
Remote login to host `pluto' when Amd is up on that host. It is generally necessary to wait for Amd to properly start and initialize on a remote host before logging in to it, because otherwise user home directories may not be accessible across the network.
A short-hand version of the previous command, since the most useful reason for this script is to login to a remote host. I use it very often when testing out new versions of Amd, and need to reboot hung hosts.
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This script is used internally by `ctl-amd' when used to restart Amd. It waits for Amd to terminate. If it detected that Amd terminated cleanly, this script will return an exist status of zero. Otherwise, it will return a non-zero exit status.
The script tests for Amd's existence once every 5 seconds, six times, for a total of 30 seconds. It will return a zero exist status as soon as it detects that Amd dies.
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A simple program to test if some of the most basic networking functions in am-util's library `libamu' work. It also tests the combination of NFS protocol and version number that are supported from the current host, to a remote one.
For example, in this test a machine which only supports NFS Version 2 is contacting a remote host that can support the same version, but using both UDP and TCP. If no host name is specified, `wire-test' will try `localhost'.
$ wire-test moisil Network name is "mcl-lab-net.cs.columbia.edu" Network number is "128.59.13" Network name is "old-net.cs.columbia.edu" Network number is "128.59.16" My IP address is 0x7f000001. NFS Version and protocol tests to host "moisil"... testing vers=2, proto="udp" -> found version 2. testing vers=3, proto="udp" -> failed! testing vers=2, proto="tcp" -> found version 2. testing vers=3, proto="tcp" -> failed! |
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With more than one fileserver, the directories most frequently cross-mounted are those containing user home directories. A common convention used at Imperial College is to mount the user disks under /home/machine.
Typically, the `/etc/fstab' file contained a long list of entries such as:
machine:/home/machine /home/machine nfs ... |
for each fileserver on the network.
There are numerous problems with this system. The mount list can become quite large and some of the machines may be down when a system is booted. When a new fileserver is installed, `/etc/fstab' must be updated on every machine, the mount directory created and the filesystem mounted.
In many environments most people use the same few workstations, but it is convenient to go to a colleague's machine and access your own files. When a server goes down, it can cause a process on a client machine to hang. By minimizing the mounted filesystems to only include those actively being used, there is less chance that a filesystem will be mounted when a server goes down.
The following is a short extract from a map taken from a research fileserver at Imperial College.
Note the entry for `localhost' which is used for users such as the operator (`opr') who have a home directory on most machine as `/home/localhost/opr'.
/defaults opts:=rw,intr,grpid,nosuid charm host!=${key};type:=nfs;rhost:=${key};rfs:=/home/${key} \ host==${key};type:=ufs;dev:=/dev/xd0g # ... # localhost type:=link;fs:=${host} ... # # dylan has two user disks so have a # top directory in which to mount them. # dylan type:=auto;fs:=${map};pref:=${key}/ # dylan/dk2 host!=dylan;type:=nfs;rhost:=dylan;rfs:=/home/${key} \ host==dylan;type:=ufs;dev:=/dev/dsk/2s0 # dylan/dk5 host!=dylan;type:=nfs;rhost:=dylan;rfs:=/home/${key} \ host==dylan;type:=ufs;dev:=/dev/dsk/5s0 ... # toytown host!=${key};type:=nfs;rhost:=${key};rfs:=/home/${key} \ host==${key};type:=ufs;dev:=/dev/xy1g ... # zebedee host!=${key};type:=nfs;rhost:=${key};rfs:=/home/${key} \ host==${key};type:=ufs;dev:=/dev/dsk/1s0 # # Just for access... # gould type:=auto;fs:=${map};pref:=${key}/ gould/staff host!=gould;type:=nfs;rhost:=gould;rfs:=/home/${key} # gummo host!=${key};type:=nfs;rhost:=${key};rfs:=/home/${key} ... |
This map is shared by most of the machines listed so on those systems any of the user disks is accessible via a consistent name. Amd is started with the following command
amd /home amd.home |
Note that when mounting a remote filesystem, the automounted mount point is referenced, so that the filesystem will be mounted if it is not yet (at the time the remote `mountd' obtains the file handle).
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One convention for home directories is to locate them in `/homes' so user `jsp''s home directory is `/homes/jsp'. With more than a single fileserver it is convenient to spread user files across several machines. All that is required is a mount-map which converts login names to an automounted directory.
Such a map might be started by the command:
amd /homes amd.homes |
where the map `amd.homes' contained the entries:
/defaults type:=link # All the entries are of type:=link jsp fs:=/home/charm/jsp njw fs:=/home/dylan/dk5/njw ... phjk fs:=/home/toytown/ai/phjk sjv fs:=/home/ganymede/sjv |
Whenever a login name is accessed in `/homes' a symbolic link appears pointing to the real location of that user's home directory. In this example, `/homes/jsp' would appear to be a symbolic link pointing to `/home/charm/jsp'. Of course, `/home' would also be an automount point.
This system causes an extra level of symbolic links to be used. Although that turns out to be relatively inexpensive, an alternative is to directly mount the required filesystems in the `/homes' map. The required map is simple, but long, and its creation is best automated. The entry for `jsp' could be:
jsp -sublink:=${key};rfs:=/home/charm \ host==charm;type:=ufs;dev:=/dev/xd0g \ host!=charm;type:=nfs;rhost:=charm |
This map can become quite big if it contains a large number of entries. By combining two other features of Amd it can be greatly simplified.
First the UFS partitions should be mounted under the control of `/etc/fstab', taking care that they are mounted in the same place that Amd would have automounted them. In most cases this would be something like `/a/host/home/host' and `/etc/fstab' on host `charm' would have a line:
/dev/xy0g /a/charm/home/charm 4.2 rw,nosuid,grpid 1 5 |
The map can then be changed to:
/defaults type:=nfs;sublink:=${key};opts:=rw,intr,nosuid,grpid jsp rhost:=charm;rfs:=/home/charm njw rhost:=dylan;rfs:=/home/dylan/dk5 ... phjk rhost:=toytown;rfs:=/home/toytown;sublink:=ai/${key} sjv rhost:=ganymede;rfs:=/home/ganymede |
This map operates as usual on a remote machine (ie ${host}
not equal to ${rhost}
). On the machine where the filesystem is
stored (ie ${host}
equal to ${rhost}
), Amd
will construct a local filesystem mount point which corresponds to the
name of the locally mounted UFS partition. If Amd is started with
the -r
option then instead of attempting an NFS mount, Amd will
simply inherit the UFS mount (see section Inheritance Filesystem (`inherit')). If
-r
is not used then a loopback NFS mount will be made. This type of
mount is known to cause a deadlock on many systems.
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Often a filesystem will be shared by machines of different architectures. Separate trees can be maintained for the executable images for each architecture, but it may be more convenient to have a shared tree, with distinct subdirectories.
A shared tree might have the following structure on the fileserver (called `fserver' in the example):
local/tex local/tex/fonts local/tex/lib local/tex/bin local/tex/bin/sun3 local/tex/bin/sun4 local/tex/bin/hp9000 ... |
In this example, the subdirectories of `local/tex/bin' should be hidden when accessed via the automount point (conventionally `/vol'). A mount-map for `/vol' to achieve this would look like:
/defaults sublink:=${/key};rhost:=fserver;type:=link tex type:=auto;fs:=${map};pref:=${key}/ tex/fonts host!=fserver;type:=nfs;rfs:=/vol/tex \ host==fserver;fs:=/usr/local/tex tex/lib host!=fserver;type:=nfs;rfs:=/vol/tex \ host==fserver;fs:=/usr/local/tex tex/bin -sublink:=${/key}/${arch} \ host!=fserver;type:=nfs;rfs:=/vol/tex \ host:=fserver;fs:=/usr/local/tex |
When `/vol/tex/bin' is referenced, the current machine architecture
is automatically appended to the path by the ${sublink}
variable. This means that users can have `/vol/tex/bin' in their
`PATH' without concern for architecture dependencies.
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By using the wildcard facility, Amd can overlay an existing directory with additional entries. The system files are usually mounted under `/usr'. If instead, Amd is mounted on `/usr', additional names can be overlayed to augment or replace names in the "master" `/usr'. A map to do this would have the form:
local type:=auto;fs:=local-map share type:=auto;fs:=share-map * -type:=nfs;rfs:=/export/exec/${arch};sublink:="${key}" \ rhost:=fserv1 rhost:=fserv2 rhost:=fserv3 |
Note that the assignment to ${sublink}
is surrounded by double
quotes to prevent the incoming key from causing the map to be
misinterpreted. This map has the effect of directing any access to
`/usr/local' or `/usr/share' to another automount point.
In this example, it is assumed that the `/usr' files are replicated on three fileservers: `fserv1', `fserv2' and `fserv3'. For any references other than to `local' and `share' one of the servers is used and a symbolic link to ${autodir}/${rhost}/export/exec/${arch}/whatever is returned once an appropriate filesystem has been mounted.
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The `/usr/spool/rwho' directory is a good candidate for automounting. For efficiency reasons it is best to capture the rwho data on a small number of machines and then mount that information onto a large number of clients. The data written into the rwho files is byte order dependent so only servers with the correct byte ordering can be used by a client:
/defaults type:=nfs usr/spool/rwho -byte==little;rfs:=/usr/spool/rwho \ rhost:=vaxA rhost:=vaxB \ || -rfs:=/usr/spool/rwho \ rhost:=sun4 rhost:=hp300 |
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`/vol' is used as a catch-all for volumes which do not have other conventional names.
Below is part of the `/vol' map for the domain `doc.ic.ac.uk'. The `r+d' tree is used for new or experimental software that needs to be available everywhere without installing it on all the fileservers. Users wishing to try out the new software then simply include `/vol/r+d/{bin,ucb}' in their path.
The main tree resides on one host `gould.doc.ic.ac.uk', which has different `bin', `etc', `lib' and `ucb' sub-directories for each machine architecture. For example, `/vol/r+d/bin' for a Sun-4 would be stored in the sub-directory `bin/sun4' of the filesystem `/usr/r+d'. When it was accessed a symbolic link pointing to `/a/gould/usr/r+d/bin/sun4' would be returned.
/defaults type:=nfs;opts:=rw,grpid,nosuid,intr,soft wp -opts:=rw,grpid,nosuid;rhost:=charm \ host==charm;type:=link;fs:=/usr/local/wp \ host!=charm;type:=nfs;rfs:=/vol/wp ... # src -opts:=rw,grpid,nosuid;rhost:=charm \ host==charm;type:=link;fs:=/usr/src \ host!=charm;type:=nfs;rfs:=/vol/src # r+d type:=auto;fs:=${map};pref:=r+d/ # per architecture bin,etc,lib&ucb... r+d/bin rhost:=gould.doc.ic.ac.uk;rfs:=/usr/r+d;sublink:=${/key}/${arch} r+d/etc rhost:=gould.doc.ic.ac.uk;rfs:=/usr/r+d;sublink:=${/key}/${arch} r+d/include rhost:=gould.doc.ic.ac.uk;rfs:=/usr/r+d;sublink:=${/key} r+d/lib rhost:=gould.doc.ic.ac.uk;rfs:=/usr/r+d;sublink:=${/key}/${arch} r+d/man rhost:=gould.doc.ic.ac.uk;rfs:=/usr/r+d;sublink:=${/key} r+d/src rhost:=gould.doc.ic.ac.uk;rfs:=/usr/r+d;sublink:=${/key} r+d/ucb rhost:=gould.doc.ic.ac.uk;rfs:=/usr/r+d;sublink:=${/key}/${arch} # hades pictures pictures -opts:=rw,grpid,nosuid;rhost:=thpfs \ host==thpfs;type:=link;fs:=/nbsd/pictures \ host!=thpfs;type:=nfs;rfs:=/nbsd;sublink:=pictures # hades tools hades -opts:=rw,grpid,nosuid;rhost:=thpfs \ host==thpfs;type:=link;fs:=/nbsd/hades \ host!=thpfs;type:=nfs;rfs:=/nbsd;sublink:=hades # bsd tools for hp. bsd -opts:=rw,grpid,nosuid;arch==hp9000;rhost:=thpfs \ host==thpfs;type:=link;fs:=/nbsd/bsd \ host!=thpfs;type:=nfs;rfs:=/nbsd;sublink:=bsd |
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It is sometimes useful to have different defaults for a given map. To achieve this, the `/defaults' entry must be able to process normal selectors. This feature is turned on by setting `selectors_in_defaults = yes' in the `amd.conf' file. See section selectors_in_defaults Parameter.
In this example, I set different default NFS mount options for hosts which are running over a slower network link. By setting a smaller size for the NFS read and write buffer sizes, you can greatly improve remote file service performance.
/defaults \ wire==slip-net;opts:=rw,intr,rsize=1024,wsize=1024,timeo=20,retrans=10 \ wire!=slip-net;opts:=rw,intr |
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In this complex example, we attempt to run an Amd process inside a chroot-ed environment. `tftpd' (Trivial FTP) is used to trivially retrieve files used to boot X-Terminals, Network Printers, Network routers, diskless workstations, and other such devices. For security reasons, `tftpd' (and also `ftpd') processes are run using the chroot(2) system call. This provides an environment for these processes, where access to any files outside the directory where the chroot-ed process runs is denied.
For example, if you start `tftpd' on your system with
chroot /tftpboot /usr/sbin/tftpd |
then the `tftpd' process will not be able to access any files outside `/tftpboot'. This ensures that no one can retrieve files such as `/etc/passwd' and run password crackers on it.
Since the TFTP service works by broadcast, it is necessary to have at least one TFTP server running on each subnet. If you have lots of files that you need to make available for `tftp', and many subnets, it could take significant amounts of disk space on each host serving them.
A solution we implemented at Columbia University was to have every host run `tftpd', but have those servers retrieve the boot files from two replicated servers. Those replicated servers have special partitions dedicated to the many network boot files.
We start Amd as follows:
amd /tftpboot/.amd amd.tftpboot |
That is, Amd is serving the directory `/tftpboot/.amd'. The `tftp' server runs inside `/tftpboot' and is chroot-ed in that directory too. The `amd.tftpboot' map looks like:
# # Amd /tftpboot directory -> host map # /defaults opts:=nosuid,ro,intr,soft;fs:=/tftpboot/import;type:=nfs tp host==lol;rfs:=/n/lol/import/tftpboot;type:=lofs \ host==ober;rfs:=/n/ober/misc/win/tftpboot;type:=lofs \ rhost:=ober;rfs:=/n/ober/misc/win/tftpboot \ rhost:=lol;rfs:=/n/lol/import/tftpboot |
To help understand this example, I list a few of the file entries that are created inside `/tftpboot':
$ ls -la /tftpboot dr-xr-xr-x 2 root 512 Aug 30 23:11 .amd drwxrwsr-x 12 root 512 Aug 30 08:00 import lrwxrwxrwx 1 root 33 Feb 27 1997 adminpr.cfg -> ./.amd/tp/hplj/adminpr.cfg lrwxrwxrwx 1 root 22 Dec 5 1996 tekxp -> ./.amd/tp/xterms/tekxp lrwxrwxrwx 1 root 1 Dec 5 1996 tftpboot -> . |
Here is an explanation of each of the entries listed above:
.amd
This is the Amd mount point. Note that you do not need to run a separate Amd process for the TFTP service. The chroot(2) system call only protects against file access, but the same process can still serve files and directories inside and outside the chroot-ed environment, because Amd itself was not run in chroot-ed mode.
import
This is the mount point where Amd will mount the directories containing the boot files. The map is designed so that remote directories will be NFS mounted (even if they are already mounted elsewhere), and local directories are loopback mounted (since they are not accessible outside the chroot-ed `/tftpboot' directory).
adminpr.cfg
tekxp
Two manually created symbolic links to directories inside the Amd-managed directory. The crossing of the component `tp' will cause Amd to automount one of the remote replicas. Once crossed, access to files inside proceeds as usual. The `adminpr.cfg' is a configuration file for an HP Laser-Jet 4si printer, and the `tekxp' is a directory for Tektronix X-Terminal boot files.
tftpboot
This innocent looking symlink is important. Usually, when devices boot via the TFTP service, they perform the `get file' command to retrieve file. However, some devices assume that `tftpd' does not run in a chroot-ed environment, but rather "unprotected", and thus use a full pathname for files to retrieve, as in `get /tftpboot/file'. This symlink effectively strips out the leading `/tftpboot/'.
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Note that there are more error and logging messages possible than are listed here. Most of them are self-explanatory. Refer to the program sources for more details on the rest.
12.1 Log Messages |
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In the following sections a brief explanation is given of some of the
log messages made by Amd. Where the message is in `typewriter'
font, it corresponds exactly to the message produced by Amd. Words
in italic are replaced by an appropriate string. Variables,
${var}
, indicate that the value of the appropriate variable is
output.
Log messages are either sent directly to a file, or logged via the syslog(3) mechanism. See section log_file Parameter. In either case, entries in the file are of the form:
date-string hostname amd[pid] message |
12.1.1 Fatal errors | ||
12.1.2 Info messages |
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Amd attempts to deal with unusual events. Whenever it is not possible to deal with such an error, Amd will log an appropriate message and, if it cannot possibly continue, will either exit or abort. These messages are selected by `-x fatal' on the command line. When syslog(3) is being used, they are logged with level `LOG_FATAL'. Even if Amd continues to operate it is likely to remain in a precarious state and should be restarted at the earliest opportunity.
The prototype mount point created during a filesystem restart did not contain a reference to the restarted filesystem. This error "should never happen".
A specific NIS domain was requested on the command line, but no server for that domain is available on the local net.
When Amd starts it determines its own IP address. If this lookup fails then Amd cannot continue. The hostname it looks up is that obtained returned by gethostname(2) system call.
Amd creates its own file handles for the automount points. When it mounts itself as a server, it must pass these file handles to the local kernel. If the filehandle is not obtainable the mount point is ignored. This error "should never happen".
To prevent embarrassment, Amd makes sure it has appropriate system
privileges. This amounts to having an euid of 0. The check is made
after argument processing complete to give non-root users a chance to
access the -v
option.
No automount points were given on the command line and so there is no work to do.
While attempting to malloc some memory, the memory space available to Amd was exhausted. This is an unrecoverable error.
While attempting to realloc some memory, the memory space available to Amd was exhausted. This is an unrecoverable error.
Either the NFS or AMQ endpoint could not be created.
The gethostname(2) system call failed during startup.
The gethostname(2) system call returned a zero length host name. This can happen if Amd is started in single user mode just after booting the system.
An internal error occurred while restarting a pre-mounted filesystem. This error "should never happen".
An error occurred while Amd was mounting itself.
Somehow the main NFS server loop failed. This error "should never happen".
The incoming arguments to the AMQ server could not be free'ed.
The incoming arguments to the NFS server could not be free'ed.
The AMQ server could not be registered with the local portmapper or the internal RPC dispatcher.
The NFS server could not be registered with the internal RPC dispatcher.
XXX: This section needs to be updated
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Amd generates information messages to record state changes. These messages are selected by `-x info' on the command line. When syslog(3) is being used, they are logged with level `LOG_INFO'.
The messages listed below can be generated and are in a format suitable for simple statistical analysis. mount-info is the string that is displayed by Amq in its mount information column and placed in the system mount table.
An automount point has been timed out by the Amq command.
No access to the automount point has been made within the timeout period.
The mount daemon refused to return a file handle for the requested filesystem.
The mount daemon gave some other error for the requested filesystem.
Amd is about to exit with the given exit status.
The named map has been modified and the internal cache is being re-synchronized.
An automount point has timed out, but the corresponding file server is known to be down. This message is only produced once for each mount point for which the server is down.
An NFS file server that was previously up is now down.
An NFS file server that was previously down is now up.
A new NFS file server has been referenced and is known to be down.
A new NFS file server has been referenced and is known to be up.
Attempts to mount a filesystem for the given automount point have failed to complete within 30 seconds.
A new file system has been mounted.
Amd is using a pre-mounted filesystem to satisfy a mount request.
A file system has been unmounted.
A file system of which only a sub-directory was in use has been unmounted.
A pre-mounted file system has been noted.
XXX: This section needs to be updated
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Many thanks to the Am-Utils Users mailing list through the months developing am-utils. These members have contributed to the discussions, ideas, code and documentation, and subjected their systems to alpha quality code. Special thanks go to those authors who have submitted patches, and especially to the maintainers:
Thanks to the Formal Methods Group at Imperial College for suffering patiently while Amd was being developed on their machines.
Thanks to the many people who have helped with the development of Amd, especially Piete Brooks at the Cambridge University Computing Lab for many hours of testing, experimentation and discussion.
Thanks to the older Amd Workers mailing list (now defunct) members for many suggestions and bug reports to Amd.
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Jump to: | !
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A B C D E F G H I K L M N O P Q R S T U V W X Y |
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Jump to: | !
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A B C D E F G H I K L M N O P Q R S T U V W X Y |
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Delivery via NFS-mounted filesystems may require usage of `rpc.lockd' and `rpc.statd' to provide distributed file-locking, both of which are widely regarded as unstable and unreliable. Furthermore, this will degrade performance, as local processes as well as remote `nfsd' processes are kept busy.
No SA in their right minds would soft-mount read/write partitions -- the chances for data loss are too great.
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-a
directory-c
cache-interval-d
domain-k
kernel-architecture-l
log-option-n
-o
op-sys-ver-p
-r
-t
timeout.retransmit-v
-w
wait-timeout-x
opts-y
NIS-domain-A
architecture-C
cluster-name-D
opts-F
conf-file-H
-O
op-sys-name-S
-T
tag-f
option-h
option-H
option-l
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option-p
option-P
option-s
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option-u
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