sshd
—
secure shell daemon
sshd |
[-diqQ46 ] [-b
bits] [-f
config_file] [-g
login_grace_time] [-h
host_key_file] [-k
key_gen_time] [-p
port] [-V
client_protocol_id] |
sshd
(Secure Shell Daemon) is the daemon program for
ssh(1). Together these programs replace rlogin and rsh, and
provide secure encrypted communications between two untrusted hosts over an
insecure network. The programs are intended to be as easy to install and use
as possible.
sshd
is the daemon that listens for
connections from clients. It is normally started at boot from
/etc/rc. It forks a new daemon for each incoming
connection. The forked daemons handle key exchange, encryption,
authentication, command execution, and data exchange. This implementation of
sshd
supports both SSH protocol version 1 and 2
simultaneously. sshd
works as follows.
Each host has a host-specific RSA key (normally 1024 bits) used to identify the
host. Additionally, when the daemon starts, it generates a server RSA key
(normally 768 bits). This key is normally regenerated every hour if it has
been used, and is never stored on disk.
Whenever a client connects the daemon responds with its public
host and server keys. The client compares the RSA host key against its own
database to verify that it has not changed. The client then generates a 256
bit random number. It encrypts this random number using both the host key
and the server key, and sends the encrypted number to the server. Both sides
then use this random number as a session key which is used to encrypt all
further communications in the session. The rest of the session is encrypted
using a conventional cipher, currently Blowfish or 3DES, with 3DES being
used by default. The client selects the encryption algorithm to use from
those offered by the server.
Next, the server and the client enter an authentication dialog.
The client tries to authenticate itself using
.rhosts authentication,
.rhosts authentication combined with RSA host
authentication, RSA challenge-response authentication, or password based
authentication.
Rhosts authentication is normally disabled because it is
fundamentally insecure, but can be enabled in the server configuration file
if desired. System security is not improved unless
rshd(8), rlogind(8),
rexecd(8), and rexd(8) are disabled
(thus completely disabling rlogin(1) and
rsh(1) into the machine).
Version 2 works similar: Each host has a host-specific DSA key used to identify
the host. However, when the daemon starts, it does not generate a server key.
Forward security is provided through a Diffie-Hellman key agreement. This key
agreement results in a shared session key. The rest of the session is
encrypted using a symmetric cipher, currently Blowfish, 3DES or CAST128 in CBC
mode or Arcfour. The client selects the encryption algorithm to use from those
offered by the server. Additionally, session integrity is provided through a
cryptographic message authentication code (hmac-sha1 or hmac-md5).
Protocol version 2 provides a public key based user authentication
method (DSAAuthentication) and conventional password authentication.
If the client successfully authenticates itself, a dialog for preparing the
session is entered. At this time the client may request things like allocating
a pseudo-tty, forwarding X11 connections, forwarding TCP/IP connections, or
forwarding the authentication agent connection over the secure channel.
Finally, the client either requests a shell or execution of a
command. The sides then enter session mode. In this mode, either side may
send data at any time, and such data is forwarded to/from the shell or
command on the server side, and the user terminal in the client side.
When the user program terminates and all forwarded X11 and other
connections have been closed, the server sends command exit status to the
client, and both sides exit.
sshd
can be configured using command-line
options or a configuration file. Command-line options override values
specified in the configuration file.
sshd
rereads its configuration file when
it receives a hangup signal, SIGHUP
.
The options are as follows:
-b
bits
- Specifies the number of bits in the server key (default 768).
-d
- Debug mode. The server sends verbose debug output to the system log, and
does not put itself in the background. The server also will not fork and
will only process one connection. This option is only intended for
debugging for the server.
-f
configuration_file
- Specifies the name of the configuration file. The default is
/etc/sshd_config.
sshd
refuses to start if there is no configuration file.
-g
login_grace_time
- Gives the grace time for clients to authenticate themselves (default 300
seconds). If the client fails to authenticate the user within this many
seconds, the server disconnects and exits. A value of zero indicates no
limit.
-h
host_key_file
- Specifies the file from which the RSA host key is read (default
/etc/ssh_host_key). This option must be given if
sshd
is not run as root (as the normal host file
is normally not readable by anyone but root).
-i
- Specifies that
sshd
is being run from inetd.
sshd
is normally not run from inetd because it
needs to generate the server key before it can respond to the client, and
this may take tens of seconds. Clients would have to wait too long if the
key was regenerated every time. However, with small key sizes (e.g., 512)
using sshd
from inetd may be feasible.
-k
key_gen_time
- Specifies how often the server key is regenerated (default 3600 seconds,
or one hour). The motivation for regenerating the key fairly often is that
the key is not stored anywhere, and after about an hour, it becomes
impossible to recover the key for decrypting intercepted communications
even if the machine is cracked into or physically seized. A value of zero
indicates that the key will never be regenerated.
-p
port
- Specifies the port on which the server listens for connections (default
22).
-q
- Quiet mode. Nothing is sent to the system log. Normally the beginning,
authentication, and termination of each connection is logged.
-Q
- Do not print an error message if RSA support is missing.
-V
client_protocol_id
- SSH2 compatibility mode. When this option is specified
sshd
assumes the client has sent the supplied
version string and skips the Protocol Version Identification
Exchange.
-4
- Forces
sshd
to use IPv4 addresses only.
-6
- Forces
sshd
to use IPv6 addresses only.
sshd
reads configuration data from
/etc/sshd_config (or the file specified with
-f
on the command line). The file contains
keyword-value pairs, one per line. Lines starting with
‘#
’ and empty lines are interpreted as
comments.
The following keywords are possible.
AFSTokenPassing
- Specifies whether an AFS token may be forwarded to the server. Default is
“yes”.
AllowGroups
- This keyword can be followed by a number of group names, separated by
spaces. If specified, login is allowed only for users whose primary group
matches one of the patterns. ‘
*
’ and
‘
’? can be used as wildcards in the
patterns. Only group names are valid, a numerical group ID isn't
recognized. By default login is allowed regardless of the primary
group.
AllowUsers
- This keyword can be followed by a number of user names, separated by
spaces. If specified, login is allowed only for users names that match one
of the patterns. ‘
*
’ and
‘
’? can be used as wildcards in the
patterns. Only user names are valid, a numerical user ID isn't recognized.
By default login is allowed regardless of the user name.
Ciphers
- Specifies the ciphers allowed for protocol version 2. Multiple ciphers
must be comma-separated. The default is
“3des-cbc,blowfish-cbc,arcfour,cast128-cbc”.
CheckMail
- Specifies whether
sshd
should check for new mail
for interactive logins. The default is “no”.
DenyGroups
- This keyword can be followed by a number of group names, separated by
spaces. Users whose primary group matches one of the patterns aren't
allowed to log in. ‘
*
’ and
‘
’? can be used as wildcards in the
patterns. Only group names are valid, a numerical group ID isn't
recognized. By default login is allowed regardless of the primary
group.
DenyUsers
- This keyword can be followed by a number of user names, separated by
spaces. Login is disallowed for user names that match one of the patterns.
‘
*
’ and
‘
’? can be used as wildcards in the
patterns. Only user names are valid, a numerical user ID isn't recognized.
By default login is allowed regardless of the user name.
DSAAuthentication
- Specifies whether DSA authentication is allowed. The default is
“yes”. Note that this option applies to protocol version 2
only.
GatewayPorts
- Specifies whether remote hosts are allowed to connect to ports forwarded
for the client. The argument must be “yes” or
“no”. The default is “no”.
HostDsaKey
- Specifies the file containing the private DSA host key (default
/etc/ssh_host_dsa_key) used by SSH protocol 2.0.
Note that
sshd
disables protocol 2.0 if this file
is group/world-accessible.
HostKey
- Specifies the file containing the private RSA host key (default
/etc/ssh_host_key) used by SSH protocols 1.3 and
1.5. Note that
sshd
disables protocols 1.3 and 1.5
if this file is group/world-accessible.
IgnoreRhosts
- Specifies that .rhosts and
.shosts files will not be used in authentication.
/etc/hosts.equiv and
/etc/shosts.equiv are still used. The default is
“yes”.
IgnoreUserKnownHosts
- Specifies whether
sshd
should ignore the user's
$HOME/.ssh/known_hosts during
RhostsRSAAuthentication
. The default is
“no”.
KeepAlive
- Specifies whether the system should send keepalive messages to the other
side. If they are sent, death of the connection or crash of one of the
machines will be properly noticed. However, this means that connections
will die if the route is down temporarily, and some people find it
annoying. On the other hand, if keepalives are not sent, sessions may hang
indefinitely on the server, leaving “ghost” users and
consuming server resources.
The default is “yes” (to send keepalives), and
the server will notice if the network goes down or the client host
reboots. This avoids infinitely hanging sessions.
To disable keepalives, the value should be set to
“no” in both the server and the client configuration
files.
KerberosAuthentication
- Specifies whether Kerberos authentication is allowed. This can be in the
form of a Kerberos ticket, or if
PasswordAuthentication
is yes, the password
provided by the user will be validated through the Kerberos KDC. Default
is “yes”.
KerberosOrLocalPasswd
- If set then if password authentication through Kerberos fails then the
password will be validated via any additional local mechanism such as
/etc/passwd or SecurID. Default is
“yes”.
KerberosTgtPassing
- Specifies whether a Kerberos TGT may be forwarded to the server. Default
is “no”, as this only works when the Kerberos KDC is
actually an AFS kaserver.
KerberosTicketCleanup
- Specifies whether to automatically destroy the user's ticket cache file on
logout. Default is “yes”.
KeyRegenerationInterval
- The server key is automatically regenerated after this many seconds (if it
has been used). The purpose of regeneration is to prevent decrypting
captured sessions by later breaking into the machine and stealing the
keys. The key is never stored anywhere. If the value is 0, the key is
never regenerated. The default is 3600 (seconds).
ListenAddress
- Specifies what local address
sshd
should listen
on. The default is to listen to all local addresses. Multiple options of
this type are permitted. Additionally, the Ports
options must precede this option.
LoginGraceTime
- The server disconnects after this time if the user has not successfully
logged in. If the value is 0, there is no time limit. The default is 600
(seconds).
LogLevel
- Gives the verbosity level that is used when logging messages from
sshd
. The possible values are: QUIET, FATAL,
ERROR, INFO, VERBOSE and DEBUG. The default is INFO. Logging with level
DEBUG violates the privacy of users and is not recommended.
PasswordAuthentication
- Specifies whether password authentication is allowed. The default is
“yes”. Note that this option applies to both protocol
version 1 and 2.
PermitEmptyPasswords
- When password authentication is allowed, it specifies whether the server
allows login to accounts with empty password strings. The default is
“no”.
PermitRootLogin
- Specifies whether the root can log in using ssh(1). The
argument must be “yes”, “without-password” or
“no”. The default is “yes”. If this options is
set to “without-password” only password authentication is
disabled for root.
Root login with RSA authentication when the
command option has been specified will be allowed
regardless of the value of this setting (which may be useful for taking
remote backups even if root login is normally not allowed).
PidFile
- Specifies the file that contains the process identifier of the
sshd
daemon. The default is
/var/run/sshd.pid.
Port
- Specifies the port number that
sshd
listens on.
The default is 22. Multiple options of this type are permitted.
PrintMotd
- Specifies whether
sshd
should print
/etc/motd when a user logs in interactively. (On
some systems it is also printed by the shell,
/etc/profile, or equivalent.) The default is
“yes”.
Protocol
- Specifies the protocol versions
sshd
should
support. The possible values are “1” and “2”.
Multiple versions must be comma-separated. The default is
“1”.
RandomSeed
- Obsolete. Random number generation uses other techniques.
RhostsAuthentication
- Specifies whether authentication using rhosts or /etc/hosts.equiv files is
sufficient. Normally, this method should not be permitted because it is
insecure.
RhostsRSAAuthentication
should be used
instead, because it performs RSA-based host authentication in addition to
normal rhosts or /etc/hosts.equiv authentication. The default is
“no”.
RhostsRSAAuthentication
- Specifies whether rhosts or /etc/hosts.equiv authentication together with
successful RSA host authentication is allowed. The default is
“no”.
RSAAuthentication
- Specifies whether pure RSA authentication is allowed. The default is
“yes”. Note that this option applies to protocol version 1
only.
ServerKeyBits
- Defines the number of bits in the server key. The minimum value is 512,
and the default is 768.
SkeyAuthentication
- Specifies whether skey(1) authentication is allowed. The
default is “yes”. Note that s/key authentication is enabled
only if
PasswordAuthentication
is allowed,
too.
StrictModes
- Specifies whether
sshd
should check file modes and
ownership of the user's files and home directory before accepting login.
This is normally desirable because novices sometimes accidentally leave
their directory or files world-writable. The default is
“yes”.
SyslogFacility
- Gives the facility code that is used when logging messages from
sshd
. The possible values are: DAEMON, USER, AUTH,
LOCAL0, LOCAL1, LOCAL2, LOCAL3, LOCAL4, LOCAL5, LOCAL6, LOCAL7. The
default is AUTH.
UseLogin
- Specifies whether login(1) is used for interactive login
sessions. Note that login(1) is not never for remote
command execution. The default is “no”.
X11DisplayOffset
- Specifies the first display number available for
sshd
's X11 forwarding. This prevents
sshd
from interfering with real X11 servers. The
default is 10.
X11Forwarding
- Specifies whether X11 forwarding is permitted. The default is
“no”. Note that disabling X11 forwarding does not improve
security in any way, as users can always install their own
forwarders.
XAuthLocation
- Specifies the location of the xauth(1) program. The
default is /usr/X11R6/bin/xauth.
When a user successfully logs in, sshd
does the
following:
- If the login is on a tty, and no command has been specified, prints last
login time and /etc/motd (unless prevented in the
configuration file or by $HOME/.hushlogin; see the
FILES section).
- If the login is on a tty, records login time.
- Checks /etc/nologin; if it exists, prints contents
and quits (unless root).
- Changes to run with normal user privileges.
- Sets up basic environment.
- Reads $HOME/.ssh/environment if it exists.
- Changes to user's home directory.
- If $HOME/.ssh/rc exists, runs it; else if
/etc/sshrc exists, runs it; otherwise runs xauth.
The “rc” files are given the X11 authentication protocol and
cookie in standard input.
- Runs user's shell or command.
The $HOME/.ssh/authorized_keys file lists the RSA keys
that are permitted for RSA authentication in SSH protocols 1.3 and 1.5
Similarly, the $HOME/.ssh/authorized_keys2 file lists
the DSA keys that are permitted for DSA authentication in SSH protocol 2.0.
Each line of the file contains one key (empty lines and lines starting with a
‘#
’ are ignored as comments). Each line
consists of the following fields, separated by spaces: options, bits,
exponent, modulus, comment. The options field is optional; its presence is
determined by whether the line starts with a number or not (the option field
never starts with a number). The bits, exponent, modulus and comment fields
give the RSA key; the comment field is not used for anything (but may be
convenient for the user to identify the key).
Note that lines in this file are usually several hundred bytes
long (because of the size of the RSA key modulus). You don't want to type
them in; instead, copy the identity.pub file and
edit it.
The options (if present) consists of comma-separated option
specifications. No spaces are permitted, except within double quotes. The
following option specifications are supported:
from="pattern-list"
- Specifies that in addition to RSA authentication, the canonical name of
the remote host must be present in the comma-separated list of patterns
(‘
*
’ and
‘
’? serve as wildcards). The list
may also contain patterns negated by prefixing them with
‘
’!; if the canonical host name
matches a negated pattern, the key is not accepted. The purpose of this
option is to optionally increase security: RSA authentication by itself
does not trust the network or name servers or anything (but the key);
however, if somebody somehow steals the key, the key permits an intruder
to log in from anywhere in the world. This additional option makes using a
stolen key more difficult (name servers and/or routers would have to be
compromised in addition to just the key).
command="command"
- Specifies that the command is executed whenever this key is used for
authentication. The command supplied by the user (if any) is ignored. The
command is run on a pty if the connection requests a pty; otherwise it is
run without a tty. A quote may be included in the command by quoting it
with a backslash. This option might be useful to restrict certain RSA keys
to perform just a specific operation. An example might be a key that
permits remote backups but nothing else. Note that the client may specify
TCP/IP and/or X11 forwarding unless they are explicitly prohibited.
environment="NAME=value"
- Specifies that the string is to be added to the environment when logging
in using this key. Environment variables set this way override other
default environment values. Multiple options of this type are
permitted.
no-port-forwarding
- Forbids TCP/IP forwarding when this key is used for authentication. Any
port forward requests by the client will return an error. This might be
used, e.g., in connection with the
command
option.
no-X11-forwarding
- Forbids X11 forwarding when this key is used for authentication. Any X11
forward requests by the client will return an error.
no-agent-forwarding
- Forbids authentication agent forwarding when this key is used for
authentication.
no-pty
- Prevents tty allocation (a request to allocate a pty will fail).
1024 33 12121...312314325 ylo@foo.bar
from="*.niksula.hut.fi,!pc.niksula.hut.fi" 1024 35
23...2334 ylo@niksula
command="dump /home",no-pty,no-port-forwarding 1024 33
23...2323 backup.hut.fi
The /etc/ssh_known_hosts,
/etc/ssh_known_hosts2,
$HOME/.ssh/known_hosts, and
$HOME/.ssh/known_hosts2 files contain host public keys
for all known hosts. The global file should be prepared by the administrator
(optional), and the per-user file is maintained automatically: whenever the
user connects an unknown host its key is added to the per-user file.
Each line in these files contains the following fields: hostnames,
bits, exponent, modulus, comment. The fields are separated by spaces.
Hostnames is a comma-separated list of patterns ('*' and '?' act
as wildcards); each pattern in turn is matched against the canonical host
name (when authenticating a client) or against the user-supplied name (when
authenticating a server). A pattern may also be preceded by
‘
’! to indicate negation: if the host
name matches a negated pattern, it is not accepted (by that line) even if it
matched another pattern on the line.
Bits, exponent, and modulus are taken directly from the RSA host
key; they can be obtained, e.g., from
/etc/ssh_host_key.pub. The optional comment field
continues to the end of the line, and is not used.
Lines starting with ‘#
’ and
empty lines are ignored as comments.
When performing host authentication, authentication is accepted if
any matching line has the proper key. It is thus permissible (but not
recommended) to have several lines or different host keys for the same
names. This will inevitably happen when short forms of host names from
different domains are put in the file. It is possible that the files contain
conflicting information; authentication is accepted if valid information can
be found from either file.
Note that the lines in these files are typically hundreds of
characters long, and you definitely don't want to type in the host keys by
hand. Rather, generate them by a script or by taking
/etc/ssh_host_key.pub and adding the host names at
the front.
closenet,closenet.hut.fi,...,130.233.208.41 1024 37 159...93 closenet.hut.fi
- /etc/sshd_config
- Contains configuration data for
sshd
. This file
should be writable by root only, but it is recommended (though not
necessary) that it be world-readable.
- /etc/ssh_host_key
- Contains the private part of the host key. This file should only be owned
by root, readable only by root, and not accessible to others. Note that
sshd
does not start if this file is
group/world-accessible.
- /etc/ssh_host_key.pub
- Contains the public part of the host key. This file should be
world-readable but writable only by root. Its contents should match the
private part. This file is not really used for anything; it is only
provided for the convenience of the user so its contents can be copied to
known hosts files. These two files are created using
ssh-keygen(1).
- /var/run/sshd.pid
- Contains the process ID of the
sshd
listening for
connections (if there are several daemons running concurrently for
different ports, this contains the pid of the one started last). The
contents of this file are not sensitive; it can be world-readable.
- $HOME/.ssh/authorized_keys
- Lists the RSA keys that can be used to log into the user's account. This
file must be readable by root (which may on some machines imply it being
world-readable if the user's home directory resides on an NFS volume). It
is recommended that it not be accessible by others. The format of this
file is described above. Users will place the contents of their
identity.pub files into this file, as described in
ssh-keygen(1).
- $HOME/.ssh/authorized_keys2
- Lists the DSA keys that can be used to log into the user's account. This
file must be readable by root (which may on some machines imply it being
world-readable if the user's home directory resides on an NFS volume). It
is recommended that it not be accessible by others. The format of this
file is described above. Users will place the contents of their
id_dsa.pub files into this file, as described in
ssh-keygen(1).
- /etc/ssh_known_hosts and
$HOME/.ssh/known_hosts
- These files are consulted when using rhosts with RSA host authentication
to check the public key of the host. The key must be listed in one of
these files to be accepted. The client uses the same files to verify that
the remote host is the one we intended to connect. These files should be
writable only by root/the owner.
/etc/ssh_known_hosts should be world-readable, and
$HOME/.ssh/known_hosts can but need not be
world-readable.
- /etc/nologin
- If this file exists,
sshd
refuses to let anyone
except root log in. The contents of the file are displayed to anyone
trying to log in, and non-root connections are refused. The file should be
world-readable.
- /etc/hosts.allow, /etc/hosts.deny
- If compiled with LIBWRAP support, tcp-wrappers access
controls may be defined here as described in
hosts_access(5).
- $HOME/.rhosts
- This file contains host-username pairs, separated by a space, one per
line. The given user on the corresponding host is permitted to log in
without password. The same file is used by rlogind and rshd. The file must
be writable only by the user; it is recommended that it not be accessible
by others.
If is also possible to use netgroups in the file. Either host
or user name may be of the form +@groupname to specify all hosts or all
users in the group.
- $HOME/.shosts
- For ssh, this file is exactly the same as for
.rhosts. However, this file is not used by rlogin
and rshd, so using this permits access using SSH only.
/etc/hosts.equiv This file is used during
.rhosts authentication. In the simplest form, this
file contains host names, one per line. Users on those hosts are permitted
to log in without a password, provided they have the same user name on
both machines. The host name may also be followed by a user name; such
users are permitted to log in as any user on this
machine (except root). Additionally, the syntax “+@group”
can be used to specify netgroups. Negated entries start with
‘
-
’.
If the client host/user is successfully matched in this file,
login is automatically permitted provided the client and server user
names are the same. Additionally, successful RSA host authentication is
normally required. This file must be writable only by root; it is
recommended that it be world-readable.
Warning: It is almost never a good idea to use
user names in hosts.equiv. Beware that it
really means that the named user(s) can log in as
anybody, which includes bin, daemon, adm, and other
accounts that own critical binaries and directories. Using a user name
practically grants the user root access. The only valid use for user
names that I can think of is in negative entries.
Note that this warning also applies to rsh/rlogin.
- /etc/shosts.equiv
- This is processed exactly as /etc/hosts.equiv.
However, this file may be useful in environments that want to run both
rsh/rlogin and ssh.
- $HOME/.ssh/environment
- This file is read into the environment at login (if it exists). It can
only contain empty lines, comment lines (that start with
‘
#
’), and assignment lines of the
form name=value. The file should be writable only by the user; it need not
be readable by anyone else.
- $HOME/.ssh/rc
- If this file exists, it is run with /bin/sh after reading the environment
files but before starting the user's shell or command. If X11 spoofing is
in use, this will receive the "proto cookie" pair in standard
input (and
DISPLAY
in environment). This must call
xauth(1) in that case.
The primary purpose of this file is to run any initialization
routines which may be needed before the user's home directory becomes
accessible; AFS is a particular example of such an environment.
This file will probably contain some initialization code
followed by something similar to: "if read proto cookie; then echo
add $DISPLAY $proto $cookie | xauth -q -; fi".
If this file does not exist,
/etc/sshrc is run, and if that does not exist
either, xauth is used to store the cookie.
This file should be writable only by the user, and need not be
readable by anyone else.
- /etc/sshrc
- Like $HOME/.ssh/rc. This can be used to specify
machine-specific login-time initializations globally. This file should be
writable only by root, and should be world-readable.
OpenSSH is a derivative of the original (free) ssh 1.2.12 release by Tatu
Ylonen, but with bugs removed and newer features re-added. Rapidly after the
1.2.12 release, newer versions of the original ssh bore successively more
restrictive licenses, and thus demand for a free version was born.
This version of OpenSSH
- has all components of a restrictive nature (i.e., patents) directly
removed from the source code; any licensed or patented components are
chosen from external libraries.
- has been updated to support SSH protocol 1.5 and 2, making it compatible
with all other SSH clients and servers.
- contains added support for kerberos(8) authentication
and ticket passing.
- supports one-time password authentication with
skey(1).
OpenSSH has been created by Aaron Campbell, Bob Beck, Markus
Friedl, Niels Provos, Theo de Raadt, and Dug Song.
The support for SSH protocol 2 was written by Markus Friedl.