nfsd (7)
Leading comments
nfsd(7) - The nfsd filesystem Copyright (C) 2003 Neil Brown <neilb@cse.unsw.edu.au> Licensed for public use under the terms of the FSF General Public License (GPL) version 2.
NAME
nfsd - special filesystem for controlling Linux NFS serverSYNPOSIS
mount -t nfsd nfsd /proc/fs/nfsdDESCRIPTION
The nfsd filesystem is a special filesystem which provides access to the Linux NFS server. The filesystem consists of a single directory which contains a number of files. These files are actually gateways into the NFS server. Writing to them can affect the server. Reading from them can provide information about the server. This file system is only available in Linux 2.6 and later series kernels (and in the later parts of the 2.5 development series leading up to 2.6). This man page does not apply to 2.4 and earlier. As well as this filesystem, there are a collection of files in the procfs filesystem (normally mounted at /proc) which are used to control the NFS server. This manual page describes all of these files. The exportfs and mountd programs (part of the nfs-utils package) expect to find this filesystem mounted at /proc/fs/nfsd or /proc/fs/nfs. If it is not mounted, they will fall-back on 2.4 style functionality. This involves accessing the NFS server via a systemcall. This systemcall is scheduled to be removed after the 2.6 kernel series.DETAILS
The three files in the nfsd filesystem are:- exports
-
This file contains a list of filesystems that are currently exported
and clients that each filesystem is exported to, together with a list
of export options for that client/filesystem pair. This is similar
to the
/proc/fs/nfs/exports
file in 2.4.
One difference is that a client doesn't necessarily correspond to just
one host. It can respond to a large collection of hosts that are
being treated identically.
Each line of the file contains a path name, a client name, and a number of options in parentheses. Any space, tab, newline or back-slash character in the path name or client name will be replaced by a backslash followed by the octal ASCII code for that character.
- threads
-
This file represents the number of
nfsd
thread currently running. Reading it will show the number of
threads. Writing an ASCII decimal number will cause the number of
threads to be changed (increased or decreased as necessary) to achieve
that number.
- filehandle
-
This is a somewhat unusual file in that what is read from it depends
on what was just written to it. It provides a transactional interface
where a program can open the file, write a request, and read a
response. If two separate programs open, write, and read at the same
time, their requests will not be mixed up.
The request written to filehandle should be a client name, a path name, and a number of bytes. This should be followed by a newline, with white-space separating the fields, and octal quoting of special characters.
On writing this, the program will be able to read back a filehandle for that path as exported to the given client. The filehandle's length will be at most the number of bytes given.
The filehandle will be represented in hex with a leading '\x'.
The directory
/proc/net/rpc
in the
procfs
filesystem contains a number of files and directories.
The files contain statistics that can be display using the
nfsstat
program.
The directories contain information about various caches that the NFS
server maintains to keep track of access permissions that different
clients have for different filesystems.
The caches are:
- auth.domain
-
This cache maps the name of a client (or domain) to an internal data
structure. The only access that is possible is to flush the cache.
- auth.unix.ip
-
This cache contains a mapping from IP address to the name of the
authentication domain that the ipaddress should be treated as part of.
- nfsd.export
-
This cache contains a mapping from directory and domain to export
options.
- nfsd.fh
-
This cache contains a mapping from domain and a filesystem identifier
to a directory. The filesystem identifier is stored in the
filehandles and consists of a number indicating the type of identifier
and a number of hex bytes indicating the content of the identifier.
Each directory representing a cache can hold from 1 to 3 files. They are:
- flush
-
When a number of seconds since epoch (1 Jan 1970) is written to this
file, all entries in the cache that were last updated before that file
become invalidated and will be flushed out. Writing 1 will flush
everything. This is the only file that will always be present.
- content
-
This file, if present, contains a textual representation of ever entry
in the cache, one per line. If an entry is still in the cache
(because it is actively being used) but has expired or is otherwise
invalid, it will be presented as a comment (with a leading hash
character).
- channel
-
This file, if present, acts a channel for request from the kernel-based
nfs server to be passed to a user-space program for handling.
When the kernel needs some information which isn't in the cache, it makes a line appear in the channel file giving the key for the information. A user-space program should read this, find the answer, and write a line containing the key, an expiry time, and the content. For example the kernel might make
nfsd 127.0.0.1
appear in the auth.unix.ip/content file. The user-space program might then write
nfsd 127.0.0.1 1057206953 localhost
to indicate that 127.0.0.1 should map to localhost, at least for now.
If the program uses select(2) or poll(2) to discover if it can read from the channel then it will never see and end-of-file but when all requests have been answered, it will block until another request appears.
In the
/proc
filesystem there are 4 files that can be used to enabled extra tracing
of nfsd and related code. They are:
/proc/sys/sunrpc/nfs_debug
/proc/sys/sunrpc/nfsd_debug
/proc/sys/sunrpc/nlm_debug
/proc/sys/sunrpc/rpc_debug
They control tracing for the NFS client, the NFS server, the Network
Lock Manager (lockd) and the underlying RPC layer respectively.
Decimal numbers can be read from or written to these files. Each
number represents a bit-pattern where bits that are set cause certain
classes of tracing to be enabled. Consult the kernel header files to
find out what number correspond to what tracing.