4.4 BSD Automounter Reference Manual |
The 4.4 BSD Automounter
Reference Manual
Jan-Simon Pendry
and
Nick Williams
Last updated March 1991
Documentation for software revision 5.3 Alpha
Copyright (C) 1989 Jan-Simon Pendry
Copyright (C) 1989 Imperial College of Science, Technology & Medicine
Copyright (C) 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.
This manual documents the use of the 4.4 BSD automounter---Amd. This is primarily a reference manual. Unfortunately, no tutorial exists.
This manual comes in two forms: the published form and the Info form. The Info form is for on-line perusal with the INFO program which is distributed along with GNU Emacs. Both forms contain substantially the same text and are generated from a common source file, which is distributed with the Amd source.
Amd is not in the public domain; it is copyrighted and there are restrictions on its distribution.
Redistribution and use in source and binary forms are permitted provided that: (1) source distributions retain this entire copyright notice and comment, and (2) distributions including binaries display the following acknowledgement: "This product includes software developed by The University of California, Berkeley and its Contributors" in the documentation or other materials provided with the distribution and in all advertising materials mentioning features or use of this software. neither the name of the University nor the names of its Contributors may be used to endorse or promote products derived from this software without specific prior written permission.
THIS SOFTWARE IS PROVIDED "AS IS" AND WITHOUT ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, WITHOUT LIMITATION, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE.
If you have access to the Internet, you can get the latest distribution version of Amd from host `usc.edu' using anonymous FTP. Move to the directory `/pub/amd' on that host and fetch the file `amd.tar.Z'.
If you are in the UK, you can get the latest distribution version of Amd from the UKnet info-server. Start by sending email to `info-server@doc.ic.ac.uk'.
Sites on the UK JANET network can get the latest distribution by using anonymous NIFTP to fetch the file `<AMD>amd.tar.Z' from host `uk.ac.imperial.doc.src'.
Revision 5.2 was part of the 4.3 BSD Reno distribution.
Revision 5.3bsdnet, a late alpha version of 5.3, was part of the BSD network version 2 distribution
Send all bug reports to `jsp@doc.ic.ac.uk' quoting the details of the release and your configuration. These can be obtained by running the command `amd -v'.
There is a mailing list for people interested in keeping uptodate with developments. To subscribe, send a note to `amd-workers-request@acl.lanl.gov'.
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 so 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 flavours of Unix.
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 flavours of Unix. See section Supported Operating Systems.
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.
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-organised without requiring changes to configuration files, shell scripts and so on.
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.
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.
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.
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".
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.
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
wait-timeout). It is also possible to set this value on a per-mount
basis (see section opts Option).
Filesystems can be forcefully timed out using the Amq command. See section Run-time Administration.
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 recognised when an NFS server crashes and the behaviour 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.
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.
By default, fileserver state is not maintained for NFS/TCP mounts. The remote fileserver is always assumed to be up.
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.
Amd has been ported to a wide variety of machines and operating systems. The table below lists those platforms supported by the current release.
The following operating systems are currently supported by Amd. Amd's conventional name for each system is given.
acis43
aix3
aux
bsd44
concentrix
convex
dgux
fpx4
hcx
hlh42
hpux
irix
next
pyrOSx
riscix
sos3
sos4
u2_2
u3_0
u4_0
umax43
utek
xinu43
linux
alliant
arm
aviion
encore
fps500
hp9000
hp9k8
ibm032
ibm6000
iris4d
macII
mips
multimax
orion105
sun3
sun4
tahoe
vax
linux
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).
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 a 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 configure when Amd is built and can be displayed by running the command `amd -v'.
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 behaviour (see section Automount Filesystem (`type:=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.
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 (`type:=auto')).
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 do not support cache mode `all' and, when caching is enabled, have a default cache mode of `inc' (see section Automount Filesystem (`type:=auto')).
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 do not support cache mode all
and, when caching is
enabled, have a default cache mode of inc
(see section Automount Filesystem (`type:=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.
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. 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 (`type:=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"
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:=jsp
The union map support is provided specifically for use with the union filesystem, see section Union Filesystem (`type:=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.
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).
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. location-selections are 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 (`type:=program')).
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').
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
then 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.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==sos4' would only apply on Sun-3s running SunOS 4.x.
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 (`type:=error')). This is equivalent to having a location `type:=error' at the end of each mount-map entry.
The selectors currently implemented are:
${cluster}
defaults to the value of
${domain}
unless a different value is set with the "-C"
command line option.
${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'.
${host}
and ${domain}
concatenated with a
`.' inserted between them if required. If ${domain}
is an empty string then ${host}
and ${hostd}
will be
identical.
${karch}
defaults to the value of ${arch}
unless a different value is set with the "-k" command line option.
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.
${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'.
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.
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.
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.
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 getwd(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 `/'.
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 recognised 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 4.4
BSD is known to implement the compress
and spongy
options.
compress
grpid
intr
noconn
nocto
nodevs
nosuid
quota
retrans=n
ro
rsize=n
soft
spongy
tcp
timeo=n
wsize=n
The following options are implemented by Amd, rather than being passed to the kernel.
nounmount
ping=n
retry=n
utimeout=n
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 ${rem}
is the same as the
value of ${opts}
.
The subdirectory within the mounted filesystem to which the reference should point. This can be used to prevent duplicate mounts in cases where multiple directories in the same mounted filesystem are used.
The filesystem type to be used. See section Filesystem Types, for a full description of each type.
Many of Amd's parameters can be set from the command line. The command line is also used to specify automount points and maps.
The general format of a command line is
amd [options] { directory map-name [-map-options] } ...
For each directory and map-name given, Amd establishes an automount point. The map-options may be any sequence of options or selectors---see section Location Format. The map-options apply only to Amd's mount point.
`type:=toplvl;cache:=mapdefault;fs:=${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. See section Map Defaults, for more details.
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' it will still background itself and disassociate itself from the controlling terminal. To use a debugger it is necessary to specify `-D nodaemon' on the command line.
-a
directory
Specifies the default mount directory. This option changes the variable
${autodir}
which otherwise defaults to `/a'. For example,
some sites prefer `/amd'.
amd -a /amd ...
-c
cache-intervalSelects 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).
-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 ...
-k
kernel-architecture
Specifies the kernel architecture of the system. This is usually the
output of `arch -k' and its only effect is to set the variable
${karch}
. If this option is not given, ${karch}
has
the same value as ${arch}
.
This would be used as follows:
amd -k `arch -k` ...
-l
log-optionSelects the form of logging to be made. Two special log-options are recognised.
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.
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.
Using `syslog' is usually best, in which case Amd would be started as follows:
amd -l syslog ...
-n
Normalises the remote hostname before using it. Normalisation is done
by replacing the value of ${rhost}
with the 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.
-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 nodaemon
debug flag, this
option is ignored.
-r
Tells Amd to restart existing mounts (see section Inheritance Filesystem).
-t
timeout.retransmitSpecifies the RPC timeout and retransmit intervals used by the kernel to communicate to Amd. These are used to set the `timeo' and `retrans' mount options.
Amd relies on the kernel RPC retransmit mechanism to trigger mount retries. The value of this parameter changes the retry interval. Too long an interval gives poor interactive response, too short an interval causes excessive retries.
-v
Print version information on standard error and then exit. The output is of the form:
amd 5.2.1.11 of 91/03/17 18:04:05 5.3Alpha11 #0: Sun Mar 17 18:07:28 GMT 1991 Built by pendry@vangogh.Berkeley.EDU for a hp300 running bsd44 (big-endian). Map support for: root, passwd, union, file, error. FS: ufs, nfs, nfsx, host, link, program, union, auto, direct, toplvl, error. Primary network is 128.32.130.0.
The information includes the version number, release date and name of
the release. The architecture (see section Supported Machine Architectures),
operating system (see section Supported Operating Systems)
and byte ordering are also printed as they appear in the ${os}
,
${arch}
and ${byte}
variables.
-w
wait-timeoutSelects the interval in seconds between unmount attempts after the initial time-to-live has expired.
This defaults to 120 seconds (two minutes).
-x
optsSpecifies the type and verbosity of log messages. opts is a comma separated list selected from the following options:
fatal
error
user
warn
warning
warn
info
map
stats
all
Initially a set of default logging flags is enabled. This is as if `-x all,nomap,nostats' 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
error
user
warning
info
debug
map
stats
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.
-y
NIS-domainSelects 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.
-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` ...
-D
optsControls 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'. The memory debugging facilities are only available if Amd was compiled with `-DDEBUG_MEM' (in addition to `-DDEBUG').
The most common options to use are `-D trace' and `-D test' (which turns on all the useful debug options). See the program source for a more detailed explanation of the available options.
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.
The nfs filesystem type provides access to Sun's NFS.
The following options must be specified:
rhost
${host}
) if no other value is
specified.
rfs
${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. Amd does not wait for a response; it notes that one of the locations needs retrying, but continues with any remaining locations. When the file handle becomes available, and assuming none of the other locations was successfully mounted, Amd will retry the mount. This mechanism allows several NFS filesystems to be mounted in parallel. The first one which responds with a valid file handle will be used.
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.
The 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 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:
/defaults type:=host;fs:=${autodir}/${rhost}/root;rhost:=${key} * opts:=rw,nosuid,grpid
and then start Amd with the following command
amd /n 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.
The 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.
The options are the same as for the `nfs' filesystem with one difference.
The following options must be specified:
rhost
${host}
) if no other value is specified.
rfs
For example:
pub type:=nfsx;rhost:=gould;\ rfs:=/public,/,graphics,usenet;fs:=${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 parallel 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'.
The 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
A UFS entry might be:
jsp host==charm;type:=ufs;dev:=/dev/xd0g;sublink:=jsp
The 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'.
The following options must be specified:
mount
unmount
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 quote character.
To run the program `rvdmount' with a host name and filesystem as arguments would be specified by `mount:="/etc/rvdmount rvdmount fserver ${path}"'.
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. This means
that the split string must have at least two elements. The program is
directly executed by Amd, not via a shell. This means that scripts
must begin with a #!
interpreter specification.
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.
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
${fs}
/
and the resulting string is used
as the target.
The `link' filesystem can be though 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'.
The `linkx' filesystem type is identical to `link' with the exception that the target of the link must exist. Existence is checked with the `lstat' system call.
The `linkx' filesystem type is particularly useful for wildcard map entries. In this case, a list of possible targets can be give and Amd will choose the first one which exists on the local machine.
The 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
amd /homes hesiod.homes -cache:=incwill cause `/homes' to be automounted using the Hesiod name server with local incremental caching of all succesfully 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, synchronised cache would be created by the following command:
amd /homes hesiod.homes -cache:=inc,sync
fs
${rfs}
option but
we are now stuck with it due to historical accident.
pref
${pref}
, the prefix, is non-null then it is prepended to
the name requested by the kernel before the map is searched.
The server `dylan.doc.ic.ac.uk' has two user disks: `/dev/dsk/2s0' and `/dev/dsk/5s0'. These are accessed as `/home/dylan/dk2' and `/home/dylan/dk5' respectively. Since `/home' is already an automount point, this naming is achieved with the following map entries:
dylan type:=auto;fs:=${map};pref:=${key}/ dylan/dk2 type:=ufs;dev:=/dev/dsk/2s0 dylan/dk5 type:=ufs;dev:=/dev/dsk/5s0
The 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 (`type:=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 `/'.
The 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 uptodate with respect to the underlying directories. Similarly, if a link is removed, for example with the `rm' command, it will be lost forever.
The 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.
The 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 and can also be passed in by using the "-M" option of the Amq command.
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 creating a second root node is undefined.
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.
Amd is best started from `/etc/rc.local':
if [ -f /etc/amd.start ]; then sh /etc/amd.start; (echo -n ' amd') >/dev/console fi
The shell script, `amd.start', contains:
#!/bin/sh - PATH=/etc:/bin:/usr/bin:/usr/ucb:$PATH export PATH # # Either name of logfile or "syslog" # LOGFILE=syslog #LOGFILE=/var/log/amd # # Figure out whether domain name is in host name # If the hostname is just the machine name then # pass in the name of the local domain so that the # hostnames in the map are domain stripped correctly. # case `hostname` in *.*) dmn= ;; *) dmn='-d doc.ic.ac.uk' esac # # Zap earlier log file # case "$LOGFILE" in */*) mv "$LOGFILE" "$LOGFILE"- > "$LOGFILE" ;; syslog) : nothing ;; esac cd /usr/sbin # # -r restart # -d dmn local domain # -w wait wait between unmount attempts # -l log logfile or "syslog" # eval ./amd -r $dmn -w 240 -l "$LOGFILE" \ /homes amd.homes -cache:=inc \ /home amd.home -cache:=inc \ /vol amd.vol -cache:=inc \ /n amd.net -cache:=inc
If the list of automount points and maps is contained in a file or NIS map it is easily incorporated onto the command line:
... eval ./amd -r $dmn -w 240 -l "$LOGFILE" `ypcat -k auto.master`
Amd stops in response to two signals.
Actions taken for other signals are undefined.
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.
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
Uid
Getattr
Lookup
RdDir
RdLnk
Statfs
Mounted@
The "-f" option causes Amd to flush the internal mount map cache. This is useful for Hesiod maps since Amd will not automatically notice when they have been updated. The map cache can also be synchronised with the map source by using the `sync' option (see section Automount Filesystem (`type:=auto')).
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.
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.
The "-M" option passes a new map entry to Amd and waits for it to be evaluated, possibly causing a mount. For example, the following command would cause `/home/toytown' on host `toytown' to be mounted locally on `/mnt/toytown'.
amq -M '/mnt/toytown type:=nfs;rfs:=/home/toytown;rhost:=toytown;fs:=${key}'
Amd applies some simple security checks before allowing this operation. The check tests whether the incoming request is from a privileged UDP port on the local machine. "Permission denied" is returned if the check fails.
A future release of Amd will include code to allow the mount(8) command to mount automount points:
mount -t amd /vol hesiod.vol
This will then allow Amd to be controlled from the standard system filesystem mount list.
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
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.
The "-v" option displays the version of Amd in a similar way to Amd's "-v" option.
Three other operations are implemented. These modify the state of Amd as a whole, rather than any particular filesystem. The "-l", "-x" and "-D" options have exactly the same effect as Amd's corresponding command line options. The "-l" option is rejected by Amd in the current version for obvious security reasons. When Amd receives a "-x"flag it limits the log options being modified to those which were not enabled at startup. This prevents a user turning off any logging option which was specified at startup, though any which have been turned off since then can still be turned off. The "-D" option has a similar behaviour.
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 amongst 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'.
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.
FSinfo has a relatively simple grammar. Distinct syntactic constructs exist for each of the different types of data, though they share a common flavour. 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 ;
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.
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.
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 { }
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.
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.
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.
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.
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 } }
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
This defines any options that should be given to mount(8) in the `fstab' file. For example:
opts = rw,nosuid,grpid
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
This defines the interval (in days) between dumps. The value is placed as is into the `fstab' file.
Example:
freq = 3
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'.
This provides support for Imperial College's local file backup tools and is not documented further here.
Specifies the log device for the current filesystem. This is ignored if not required by the particular filesystem type.
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:
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.
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 (`type:=direct')) or indirect
(see section Top-level Filesystem (`type:=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 optimise 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 analysed 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.
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'.
-a
autodirSpecifies 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 ...
-b
bootparamsThis 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/ ...
-d
dumpsetsThis 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/ ...
-e
exportfsDefines 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 diskful machine and place them into the directory `exports':
fsinfo -e exports/ ...
-f
fstabThis 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/ ...
-h
hostnameDefines 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 ...
-m
mount-mapsDefines 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/ ...
-q
Selects quiet mode. FSinfo suppress the "running commentary" and only outputs any error messages which are generated.
-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.
-D
name[=defn]
Defines a symbol name for the preprocessor when reading the
configuration files. Equivalent to #define
directive.
-I
directoryThis option is passed into the preprocessor for the configuration files. It specifies directories in which to find include files
-U
name
Removes any initial definition of the symbol name. Inverse of the
-D
option.
The following table documents the errors and warnings which FSinfo may produce.
fstype
, opts
, passno
or
mount
.
swap
.
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 minimising 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).
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 ${rhost}
), Amd
will construct a local filesystem mount point which corresponds to the
name of the locally mounted UFS partition. If Amd is started with
the "-r" option then instead of attempting an NFS mount, Amd will
simply inherit the UFS mount (see section Inheritance Filesystem). If
"-r" is not used then a loopback NFS mount will be made. This type of
mount is known to cause a deadlock on many systems.
Often a filesystem will be shared by machines of different architectures. Separate trees can be maintained for the executable images for each architecture, but it may be more convenient to have a shared tree, with distinct subdirectories.
A shared tree might have the following structure on the fileserver (called `fserver' in the example):
local/tex local/tex/fonts local/tex/lib local/tex/bin local/tex/bin/sun3 local/tex/bin/sun4 local/tex/bin/hp9000 ...
In this example, the subdirectories of `local/tex/bin' should be hidden when accessed via the automount point (conventionally `/vol'). A mount-map for `/vol' to achieve this would look like:
/defaults sublink:=${/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 ${sublink}
variable. This means that users can have `/vol/tex/bin' in their
`PATH' without concern for architecture dependencies.
By using the wildcard facility, Amd can overlay an existing directory with additional entries. The system files are usually mounted under `/usr'. If instead Amd is mounted on `/usr', additional names can be overlayed to augment or replace names in the "master" `/usr'. A map to do this would have the form:
local type:=auto;fs:=local-map share type:=auto;fs:=share-map * -type:=nfs;rfs:=/export/exec/${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/${arch}/whatever is returned once an appropriate filesystem has been mounted.
The `/usr/spool/rwho' directory is a good candidate for automounting. For efficiency reasons it is best to capture the rwho data on a small number of machines and then mount that information onto a large number of clients. The data written into the rwho files is byte order dependent so only servers with the correct byte ordering can be used by a client:
/defaults type:=nfs usr/spool/rwho -byte==little;rfs:=/usr/spool/rwho \ rhost:=vaxA rhost:=vaxB \ || -rfs:=/usr/spool/rwho \ rhost:=sun4 rhost:=hp300
`/vol' is used as a catch-all for volumes which do not have other conventional names.
Below is part of the `/vol' map for the domain `doc.ic.ac.uk'. The `r+d' tree is used for new or experimental software that needs to be available everywhere without installing it on all the fileservers. Users wishing to try out the new software then simply include `/vol/r+d/{bin,ucb}' in their path.
The main tree resides on one host `gould.doc.ic.ac.uk', which has different `bin', `etc', `lib' and `ucb' sub-directories for each machine architecture. For example, `/vol/r+d/bin' for a Sun-4 would be stored in the sub-directory `bin/sun4' of the filesystem `/usr/r+d'. When it was accessed a symbolic link pointing to `/a/gould/usr/r+d/bin/sun4' would be returned.
/defaults type:=nfs;opts:=rw,grpid,nosuid,intr,soft wp -opts:=rw,grpid,nosuid;rhost:=charm \ host==charm;type:=link;fs:=/usr/local/wp \ host!=charm;type:=nfs;rfs:=/vol/wp ... # src -opts:=rw,grpid,nosuid;rhost:=charm \ host==charm;type:=link;fs:=/usr/src \ host!=charm;type:=nfs;rfs:=/vol/src # r+d type:=auto;fs:=${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
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 direct to a file, or logged via the syslog(3) mechanism. Messages are logged with facility `LOG_DAEMON' when using syslog(3). In either case, entries in the file are of the form:
date-string hostname amd[pid] message
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.
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.
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.
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