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SecureBox Pro
Secure shell application, terminal screens and auxiliary commands for Android OS
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Documents </>
Manual pages "User Commands (1)" </>
SSH(1) |
General Commands Manual |
SSH(1) |
ssh — Secure shell
client (remote login program)
ssh |
[-46AaCdfgKkMNnqsTtVvXxYy ]
[-B bind_interface]
[-b bind_address]
[-c cipher_spec]
[-D
[bind_address:]port]
[-E log_file]
[-e escape_char]
[-F configfile]
[-G engine_configfile]
[-I pkcs11]
[-i identity_file]
[-J destination]
[-L address]
[-l login_name]
[-m mac_spec]
[-O ctl_cmd]
[-o option]
[-P tag]
[-p port]
[-R address]
[-S ctl_path]
[-W
host:port]
[-w
local_tun[:remote_tun]]
destination [command
[argument ...]] |
ssh (SSH client) is a program for logging
into a remote machine and for executing commands on a remote machine. It is
intended to provide secure encrypted communications between two untrusted
hosts over an insecure network. X11 connections, arbitrary TCP ports and
UNIX-domain sockets can also be forwarded over the
secure channel.
ssh connects and logs into the specified
destination, which may be specified as either
[user@]hostname or a URI of the form
ssh://[user@]hostname[:port]. The user must prove
their identity to the remote machine using one of several methods (see
below).
If a command is specified, it will be
executed on the remote host instead of a login shell. A complete command
line may be specified as command, or it may have
additional arguments. If supplied, the arguments will be appended to the
command, separated by spaces, before it is sent to the server to be
executed.
The options are as follows:
-4
- Forces
ssh to use IPv4 addresses only.
-6
- Forces
ssh to use IPv6 addresses only.
-A
- Enables forwarding of connections from an authentication agent such as
ssh-agent(1). This can also be specified on a per-host
basis in a configuration file.
Agent forwarding should be enabled with caution. Users with
the ability to bypass file permissions on the remote host (for the
agent's UNIX-domain socket) can access the local
agent through the forwarded connection. An attacker cannot obtain key
material from the agent, however they can perform operations on the keys
that enable them to authenticate using the identities loaded into the
agent. Using the -c flag of
ssh-add(1) can reduce (but not eliminate) the risk. A
safer alternative may be to use a jump host (see
-J ).
-a
- Disables forwarding of the authentication agent connection.
-
-B
bind_interface
- Bind to the address of bind_interface before
attempting to connect to the destination host. This is only useful on
systems with more than one address.
-
-b
bind_address
- Use bind_address on the local machine as the source
address of the connection. Only useful on systems with more than one
address.
-C
- Requests compression of all data (including stdin, stdout, stderr, and
data for forwarded X11, TCP and UNIX-domain
connections). The compression algorithm is the same used by
gzip(1). Compression is desirable on modem lines and
other slow connections, but will only slow down things on fast networks.
The default value can be set on a host-by-host basis in the configuration
files. See the
Compression keyword in
ssh_config(5) for more information.
-
-c
cipher_spec
- Selects the cipher specification for encrypting the session.
cipher_spec is a comma-separated list of ciphers
listed in order of preference. See the
Ciphers
keyword in ssh_config(5) for more information.
-
-D
[bind_address:]port
- Specifies a local “dynamic” application-level port
forwarding. This works by allocating a socket to listen to
port on the local side, optionally bound to the
specified bind_address. Whenever a connection is
made to this port, the connection is forwarded over the secure channel,
and the application protocol is then used to determine where to connect to
from the remote machine. Currently the SOCKS4 and SOCKS5 protocols are
supported, and
ssh will act as a SOCKS server.
Only root can forward privileged ports. Dynamic port forwardings can also
be specified in the configuration file.
IPv6 addresses can be specified by enclosing the address in
square brackets. Only the superuser can forward privileged ports. By
default, the local port is bound in accordance with the
GatewayPorts setting. However, an explicit
bind_address may be used to bind the connection to
a specific address. The bind_address of
“localhost” indicates that the listening port be bound for
local use only, while an empty address or ‘*’ indicates
that the port should be available from all interfaces.
-d
- Causes
ssh to print its configuration after
evaluating Host and Match
blocks and exit.
-
-E
log_file
- Append debug logs to log_file instead of standard
error.
-
-e
escape_char
- Sets the escape character for sessions with a pty (default:
‘
~ ’). The escape character is only
recognized at the beginning of a line. The escape character followed by a
dot (‘. ’) closes the connection;
followed by control-Z suspends the connection; and followed by itself
sends the escape character once. Setting the character to
“none” disables any escapes and makes the session fully
transparent.
-
-F
configfile
- Specifies an alternative per-user configuration file. If a configuration
file is given on the command line, the system-wide configuration file
([APPDATA]/etc/ssh_config) will be ignored. The
default for the per-user configuration file is
~/.ssh/config. If set to “none”, no
configuration files will be read.
-f
- Requests
ssh to go to background just before
command execution. This is useful if ssh is going
to ask for passwords or passphrases, but the user wants it in the
background. This implies -n . The recommended way
to start X11 programs at a remote site is with something like
ssh -f host xterm .
If the ExitOnForwardFailure
configuration option is set to “yes”, then a client
started with -f will wait for all remote port
forwards to be successfully established before placing itself in the
background. Refer to the description of
ForkAfterAuthentication in
ssh_config(5) for details.
-
-G
engine_configfile
- Specifies an alternative per-user file for post initialization of
openssl(1) engines. The default per-user configuration
file is ~/.ssh/engine.
-g
- Allows remote hosts to connect to local forwarded ports. If used on a
multiplexed connection, then this option must be specified on the master
process.
-
-I
pkcs11
- Specify the PKCS#11 shared library
ssh should use
to communicate with a PKCS#11 token providing the user's private EC or RSA
key and X.509 certificate.
-
-i
identity_file
- Selects a file from which the identity (private key) for public key
authentication is read. You can also specify a public key file to use the
corresponding private key that is loaded in ssh-agent(1)
when the private key file is not present locally. The default is
~/.ssh/id_rsa,
~/.ssh/id_ecdsa, and
~/.ssh/id_ed25519. Identity files may also be
specified on a per-host basis in the configuration file. It is possible to
have multiple
-i options (and multiple identities
specified in configuration files).
Option is equal to configuration option
IdentityFile - see
ssh_config(5) for more details. This mean than could
be used prefixes “engine:” or “store:” to
load identifies using engine or store functionality provided by
cryptographic library.
For RSA, ECDSA, or Ed25519 identity file may contain X.509
certificate that match key. In addition file may contain extra X.509
certificates. Extra certificates along with certificates from X.509
store are used to build chain of certificates leading to a trusted
certificate authority if required by public key algorithm format.
If no OpenSSH custom certificates have been explicitly
specified by the CertificateFile directive,
ssh will also try to load OpenSSH custom
certificate information from the filename obtained by appending
-cert.pub to identity filenames.
-
-J
destination
- Connect to the target host by first making an
ssh
connection to the jump host described by destination
and then establishing a TCP forwarding to the ultimate destination from
there. Multiple jump hops may be specified separated by comma characters.
IPv6 addresses can be specified by enclosing the address in square
brackets. This is a shortcut to specify a
ProxyJump configuration directive. Note that
configuration directives supplied on the command-line generally apply to
the destination host and not any specified jump hosts. Use
~/.ssh/config to specify configuration for jump
hosts.
-K
- Enables GSSAPI-based authentication and forwarding (delegation) of GSSAPI
credentials to the server.
-k
- Disables forwarding (delegation) of GSSAPI credentials to the server.
-
-L
[bind_address:]port:host:hostport
-
-
-L
[bind_address:]port:remote_socket
-
-
-L
local_socket:host:hostport
-
-
-L
local_socket:remote_socket
- Specifies that connections to the given TCP port or Unix socket on the
local (client) host are to be forwarded to the given host and port, or
Unix socket, on the remote side. This works by allocating a socket to
listen to either a TCP port on the local side,
optionally bound to the specified bind_address, or
to a Unix socket. Whenever a connection is made to the local port or
socket, the connection is forwarded over the secure channel, and a
connection is made to either host port
hostport, or the Unix socket
remote_socket, from the remote machine.
Port forwardings can also be specified in the configuration
file. Only the superuser can forward privileged ports. IPv6 addresses
can be specified by enclosing the address in square brackets.
By default, the local port is bound in accordance with the
GatewayPorts setting. However, an explicit
bind_address may be used to bind the connection to
a specific address. The bind_address of
“localhost” indicates that the listening port be bound for
local use only, while an empty address or ‘*’ indicates
that the port should be available from all interfaces.
-
-l
login_name
- Specifies the user to log in as on the remote machine. This also may be
specified on a per-host basis in the configuration file.
-M
- Places the
ssh client into “master”
mode for connection sharing. Multiple -M options
places ssh into “master” mode but
with confirmation required using ssh-askpass(1) before
each operation that changes the multiplexing state (e.g. opening a new
session). Refer to the description of
ControlMaster in ssh_config(5)
for details.
-
-m
mac_spec
- A comma-separated list of MAC (message authentication code) algorithms,
specified in order of preference. See the
MACs
keyword in ssh_config(5) for more information.
-N
- Do not execute a remote command. This is useful for just forwarding ports.
Refer to the description of
SessionType in
ssh_config(5) for details.
-n
- Redirects stdin from /dev/null (actually, prevents
reading from stdin). This must be used when
ssh is
run in the background. A common trick is to use this to run X11 programs
on a remote machine. For example, ssh -n
shadows.cs.hut.fi emacs & will start an emacs on
shadows.cs.hut.fi, and the X11 connection will be automatically forwarded
over an encrypted channel. The ssh program will be
put in the background. (This does not work if ssh
needs to ask for a password or passphrase; see also the
-f option.) Refer to the description of
StdinNull in ssh_config(5) for
details.
-
-O
ctl_cmd
- Control an active connection multiplexing master process. When the
-O option is specified, the
ctl_cmd argument is interpreted and passed to the
master process. Valid commands are: “check” (check that the
master process is running), “forward” (request forwardings
without command execution), “cancel” (cancel forwardings),
“proxy” (connect to a running multiplexing master in proxy
mode), “exit” (request the master to exit), and
“stop” (request the master to stop accepting further
multiplexing requests).
-
-o
option
- Can be used to give options in the format used in the configuration file.
This is useful for specifying options for which there is no separate
command-line flag. For full details of the options and their possible
values, see ssh_config(5).
-
-P
tag
- Specify a tag name that may be used to select configuration in
ssh_config(5). Refer to the
Tag
and Match keywords in
ssh_config(5) for more information.
-
-p
port
- Port to connect to on the remote host. This can be specified on a per-host
basis in the configuration file.
-
-Q
query_option
- Queries for the algorithms supported by one of the following features:
cipher (supported symmetric ciphers),
cipher-auth (supported symmetric ciphers that
support authenticated encryption), help (supported
query terms for use with the
-Q flag),
mac (supported message integrity codes),
compression (compression algorithms),
kex (key exchange algorithms),
key (key types), key-alg
(public key algorithms), key-ca-sign (compatibility
option), key-cert (OpenSSH custom certificate key
types), key-plain (non-certificate key types),
protocol-version (supported SSH protocol versions),
and sig (compatibility option). This option must be
specified last as other options may impact list of supported algorithms.
-q
- Quiet mode. Causes most warning and diagnostic messages to be suppressed.
-
-R
[bind_address:]port:host:hostport
-
-
-R
[bind_address:]port:local_socket
-
-
-R
remote_socket:host:hostport
-
-
-R
remote_socket:local_socket
-
-
-R
[bind_address:]port
- Specifies that connections to the given TCP port or Unix socket on the
remote (server) host are to be forwarded to the local side.
This works by allocating a socket to listen to either a TCP
port or to a Unix socket on the remote side.
Whenever a connection is made to this port or Unix socket, the
connection is forwarded over the secure channel, and a connection is
made from the local machine to either an explicit destination specified
by host port hostport, or
local_socket, or, if no explicit destination was
specified, ssh will act as a SOCKS 4/5 proxy and
forward connections to the destinations requested by the remote SOCKS
client.
Port forwardings can also be specified in the configuration
file. Privileged ports can be forwarded only when logging in as root on
the remote machine. IPv6 addresses can be specified by enclosing the
address in square brackets.
By default, TCP listening sockets on the server will be bound
to the loopback interface only. This may be overridden by specifying a
bind_address. An empty
bind_address, or the address
‘* ’, indicates that the remote
socket should listen on all interfaces. Specifying a remote
bind_address will only succeed if the server's
GatewayPorts option is enabled (see
sshd_config(5)).
If the port argument is
‘0 ’, the listen port will be
dynamically allocated on the server and reported to the client at run
time. When used together with -O forward , the
allocated port will be printed to the standard output.
-
-S
ctl_path
- Specifies the location of a control socket for connection sharing, or the
string “none” to disable connection sharing. Refer to the
description of
ControlPath and
ControlMaster in ssh_config(5)
for details.
-s
- May be used to request invocation of a subsystem on the remote system.
Subsystems facilitate the use of SSH as a secure transport for other
applications (e.g. sftp(1)). The subsystem is specified
as the remote command. Refer to the description of
SessionType in ssh_config(5) for
details.
-T
- Disable pseudo-terminal allocation.
-t
- Force pseudo-terminal allocation. This can be used to execute arbitrary
screen-based programs on a remote machine, which can be very useful, e.g.
when implementing menu services. Multiple
-t
options force tty allocation, even if ssh has no
local tty.
-V
- Display the version number and exit.
-v
- Verbose mode. Causes
ssh to print debugging
messages about its progress. This is helpful in debugging connection,
authentication, and configuration problems. Multiple
-v options increase the verbosity. The maximum is
4.
-
-W
host:port
- Requests that standard input and output on the client be forwarded to
host on port over the secure
channel. Implies
-N , -T ,
ExitOnForwardFailure and
ClearAllForwardings , though these can be
overridden in the configuration file or using -o
command line options.
-
-w
local_tun[:remote_tun]
- Requests tunnel device forwarding with the specified
tun(4) devices between the client
(local_tun) and the server
(remote_tun).
The devices may be specified by numerical ID or the keyword
“any”, which uses the next available tunnel device. If
remote_tun is not specified, it defaults to
“any”. See also the Tunnel and
TunnelDevice directives in
ssh_config(5).
If the Tunnel directive is unset, it
will be set to the default tunnel mode, which is
“point-to-point”. If a different
Tunnel forwarding mode it desired, then it
should be specified before -w .
-X
- Enables X11 forwarding. This can also be specified on a per-host basis in
a configuration file.
X11 forwarding should be enabled with caution. Users with the
ability to bypass file permissions on the remote host (for the user's X
authorization database) can access the local X11 display through the
forwarded connection. An attacker may then be able to perform activities
such as keystroke monitoring.
For this reason, X11 forwarding is subjected to X11 SECURITY
extension restrictions by default. Refer to the
ssh -Y option and the
ForwardX11Trusted directive in
ssh_config(5) for more information.
-x
- Disables X11 forwarding.
-Y
- Enables trusted X11 forwarding. Trusted X11 forwardings are not subjected
to the X11 SECURITY extension controls.
-y
- Send log information using the syslog(3) system module.
By default this information is sent to stderr.
ssh may additionally obtain configuration
data from a per-user configuration file and a system-wide configuration
file. The file format and configuration options are described in
ssh_config(5).
The SecSH client supports SSH protocol 2.
The methods available for authentication are: GSSAPI-based
authentication, host-based authentication, public key authentication,
keyboard-interactive authentication, and password authentication.
Authentication methods are tried in the order specified above, though
PreferredAuthentications can be used to change the
default order.
Host-based authentication works as follows: If the
machine the user logs in from is listed in
/etc/hosts.equiv or
[APPDATA]/etc/shosts.equiv on the remote machine,
the user is non-root and the user names are the same on both sides, or if
the files ~/.rhosts or
~/.shosts exist in the user's home directory on the
remote machine and contain a line containing the name of the client machine
and the name of the user on that machine, the user is considered for login.
Additionally, the server
must be able to
verify the client's host key or X.509 certificate (see the description of
[APPDATA]/etc/ssh_known_hosts and
~/.ssh/known_hosts, below) for login to be
permitted. This authentication method closes security holes due to IP
spoofing, DNS spoofing, and routing spoofing. [Note to the administrator:
/etc/hosts.equiv, ~/.rhosts,
and the rlogin/rsh protocol in general, are inherently insecure and should
be disabled if security is desired.]
Public key authentication works as follows: The scheme is based on
public-key cryptography or infrastructure (PKI), using cryptosystems where
encryption and decryption are done using separate keys, and it is unfeasible
to derive the decryption key from the encryption key. The idea is that each
user creates a public/private key pair for authentication purposes. The
server knows the public key or X.509 certificate, and only the user knows
the private key. ssh implements public key
authentication protocol automatically, using one of the ECDSA, Ed25519, or
RSA key algorithms, or X.509 certificates.
The file ~/.ssh/authorized_keys lists the
public keys or X.509 certificates that are permitted for logging in. When
the user logs in, the ssh program tells the server
which key pair or X.509 certificate it would like to use for authentication.
The client proves that it has access to the private key and the server
checks that the corresponding public key or X.509 certificate is authorized
to accept the account.
The server may inform the client of errors that prevented public
key authentication from succeeding after authentication completes using a
different method. These may be viewed by increasing the
LogLevel to DEBUG or higher
(e.g. by using the -v flag).
The user creates their key pair by running
ssh-keygen(1). This stores the private key in
~/.ssh/id_ecdsa (ECDSA),
~/.ssh/id_ed25519 (Ed25519), or
~/.ssh/id_rsa (RSA) and stores the public key in
~/.ssh/id_ecdsa.pub (ECDSA),
~/.ssh/id_ed25519.pub (Ed25519), or
~/.ssh/id_rsa.pub (RSA) in the user's home
directory. For RSA, ECDSA, or Ed25519 identity files may contain private
key, X.509 certificate that match it and extra X.509 certificates. In this
case *.pub file must contain certificate that match key. The user should
then copy the public key or X.509 certificate to
~/.ssh/authorized_keys in their home directory on
the remote machine. In case with X.509 certificates user can use “new
style” : instead to add content of file to authorized_keys user can
write certificate “Distinguished Name” - see
sshd(8) manual page. The
authorized_keys file corresponds to the conventional
~/.rhosts file, and has one key or X.509 certificate
per line, though the lines can be very long. After this, the user can log in
without giving the password.
A variation on public key authentication is available in the form
of OpenSSH custom certificate authentication: instead of a set of
public/private keys, signed certificates are used. This has the advantage
that a single trusted OpenSSH custom certification authority can be used in
place of many public/private keys. See the CERTIFICATES section of
ssh-keygen(1) for more information.
The most convenient way to use public key or certificate
authentication may be with an authentication agent. See
ssh-agent(1) and (optionally) the
AddKeysToAgent directive in
ssh_config(5) for more information.
Keyboard-interactive authentication works as follows: The server
sends an arbitrary "challenge" text and prompts for a response,
possibly multiple times. Examples of keyboard-interactive authentication
include BSD Authentication (see
login.conf(5)) and PAM (some
non-OpenBSD systems).
Finally, if other authentication methods fail,
ssh prompts the user for a password. The password is
sent to the remote host for checking; however, since all communications are
encrypted, the password cannot be seen by someone listening on the
network.
ssh automatically maintains and checks a
database containing identification for all hosts it has ever been used with.
Host keys are stored in ~/.ssh/known_hosts in the
user's home directory. Additionally, the file
[APPDATA]/etc/ssh_known_hosts is automatically
checked for known hosts. If host key is a X.509 certificate line may contain
certificate “Distinguished Name” instead base64 encoded
representation. Any new hosts are automatically added to the user's file. If
a host's identification ever changes, ssh warns
about this and disables password authentication to prevent server spoofing
or man-in-the-middle attacks, which could otherwise be used to circumvent
the encryption. The StrictHostKeyChecking option can
be used to control logins to machines whose host key is not known or has
changed.
When the user's identity has been accepted by the server, the
server either executes the given command in a non-interactive session or, if
no command has been specified, logs into the machine and gives the user a
normal shell as an interactive session. All communication with the remote
command or shell will be automatically encrypted.
If an interactive session is requested,
ssh by default will only request a pseudo-terminal
(pty) for interactive sessions when the client has one. The flags
-T and -t can be used to
override this behaviour.
If a pseudo-terminal has been allocated, the user may use the
escape characters noted below.
If no pseudo-terminal has been allocated, the session is
transparent and can be used to reliably transfer binary data. On most
systems, setting the escape character to “none” will also make
the session transparent even if a tty is used.
The session terminates when the command or shell on the remote
machine exits and all X11 and TCP connections have been closed.
When a pseudo-terminal has been requested,
ssh supports a number of functions through the use
of an escape character.
A single tilde character can be sent as ~~
or by following the tilde by a character other than those described below.
The escape character must always follow a newline to be interpreted as
special. The escape character can be changed in configuration files using
the EscapeChar configuration directive or on the
command line by the -e option.
The supported escapes (assuming the default
‘~ ’) are:
~.
- Disconnect.
~^Z
- Background
ssh .
~#
- List forwarded connections.
~&
- Background
ssh at logout when waiting for
forwarded connection / X11 sessions to terminate.
~?
- Display a list of escape characters.
~B
- Send a BREAK to the remote system (only useful if the peer supports
it).
~C
- Open command line. Currently this allows the addition of port forwardings
using the
-L , -R and
-D options (see above). It also allows the
cancellation of existing port-forwardings with
-KL [bind_address:]port
for local,
-KR [bind_address:]port
for remote and
-KD [bind_address:]port
for dynamic port-forwardings.
! command allows the user to
execute a local command if the PermitLocalCommand
option is enabled in ssh_config(5). Basic help is
available, using the -h option.
~R
- Request rekeying of the connection (only useful if the peer supports
it).
~V
- Decrease the verbosity (
LogLevel ) when errors are
being written to stderr.
~v
- Increase the verbosity (
LogLevel ) when errors are
being written to stderr.
Forwarding of arbitrary TCP connections over a secure channel can
be specified either on the command line or in a configuration file. One
possible application of TCP forwarding is a secure connection to a mail
server; another is going through firewalls.
In the example below, we look at encrypting communication for an
IRC client, even though the IRC server it connects to does not directly
support encrypted communication. This works as follows: the user connects to
the remote host using ssh , specifying the ports to
be used to forward the connection. After that it is possible to start the
program locally, and ssh will encrypt and forward
the connection to the remote server.
The following example tunnels an IRC session from the client to an
IRC server at “server.example.com”, joining channel
“#users”, nickname “pinky”, using the standard
IRC port, 6667:
$ ssh -f -L 6667:localhost:6667 server.example.com sleep 10
$ irc -c '#users' pinky IRC/127.0.0.1
The -f option backgrounds
ssh and the remote command “sleep 10”
is specified to allow an amount of time (10 seconds, in the example) to
start the program which is going to use the tunnel. If no connections are
made within the time specified, ssh will exit.
If the ForwardX11 variable is set to
“yes” (or see the description of the
-X , -x , and
-Y options above) and the user is using X11 (the
DISPLAY environment variable is set), the connection
to the X11 display is automatically forwarded to the remote side in such a
way that any X11 programs started from the shell (or command) will go
through the encrypted channel, and the connection to the real X server will
be made from the local machine. The user should not manually set
DISPLAY . Forwarding of X11 connections can be
configured on the command line or in configuration files.
The DISPLAY value set by
ssh will point to the server machine, but with a
display number greater than zero. This is normal, and happens because
ssh creates a “proxy” X server on the
server machine for forwarding the connections over the encrypted
channel.
ssh will also automatically set up
Xauthority data on the server machine. For this purpose, it will generate a
random authorization cookie, store it in Xauthority on the server, and
verify that any forwarded connections carry this cookie and replace it by
the real cookie when the connection is opened. The real authentication
cookie is never sent to the server machine (and no cookies are sent in the
plain).
If the ForwardAgent variable is set to
“yes” (or see the description of the
-A and -a options above) and
the user is using an authentication agent, the connection to the agent is
automatically forwarded to the remote side.
When connecting to a server for the first time, a fingerprint of
the server's public key is presented to the user (unless the option
StrictHostKeyChecking has been disabled).
Fingerprints can be determined using ssh-keygen(1):
$ ssh-keygen -l -f
[APPDATA]/etc/ssh_host_rsa_key
If the fingerprint is already known, it can be matched and the key
can be accepted or rejected. If only legacy (MD5) fingerprints for the
server are available, the ssh-keygen(1)
-E option may be used to downgrade the fingerprint
algorithm to match.
Because of the difficulty of comparing host keys just
by looking at fingerprint strings, there is also support to compare host
keys visually, using
random art. By
setting the VisualHostKey option to
“yes”, a small ASCII graphic gets displayed on every login to
a server, no matter if the session itself is interactive or not. By learning
the pattern a known server produces, a user can easily find out that the
host key has changed when a completely different pattern is displayed.
Because these patterns are not unambiguous however, a pattern that looks
similar to the pattern remembered only gives a good probability that the
host key is the same, not guaranteed proof.
To get a listing of the fingerprints along with their random art
for all known hosts, the following command line can be used:
$ ssh-keygen -lv -f
~/.ssh/known_hosts
If the fingerprint is unknown, an alternative method of
verification is available: SSH fingerprints or X.509 certificates verified
by DNS. An additional resource record (RR), SSHFP or CERT, is added to a
zonefile and the connecting client is able to match the fingerprint or X.509
certificate with that of the key presented.
In this example, we are connecting a client to a server,
“host.example.com”. The SSHFP or CERT resource records should
first be added to the zonefile for host.example.com:
$ ssh-keygen -r host.example.com.
The output lines will have to be added to the zonefile. To check
that the zone is answering fingerprint queries:
$ dig -t SSHFP
host.example.com
To check that the zone is answering X.509 certificate queries:
$ dig -t CERT
host.example.com
Finally the client connects:
$ ssh -o "VerifyHostKeyDNS ask" host.example.com
[...]
Matching host key fingerprint found in DNS.
Are you sure you want to continue connecting (yes/no)?
When host key is a X.509 certificate “Distinguished
Name” is displayed after fingerprint. Note that host X.509
certificate always is verifified and validated.
See the VerifyHostKeyDNS option in
ssh_config(5) for more information.
ssh contains support for Virtual Private
Network (VPN) tunnelling using the tun(4) network
pseudo-device, allowing two networks to be joined securely. The
sshd_config(5) configuration option
PermitTunnel controls whether the server supports
this, and at what level (layer 2 or 3 traffic).
The following example would connect client network 10.0.50.0/24
with remote network 10.0.99.0/24 using a point-to-point connection from
10.1.1.1 to 10.1.1.2, provided that the SSH server running on the gateway to
the remote network, at 192.168.1.15, allows it.
On the client:
# ssh -f -w 0:1 192.168.1.15 true
# ifconfig tun0 10.1.1.1 10.1.1.2 netmask 255.255.255.252
# route add 10.0.99.0/24 10.1.1.2
On the server:
# ifconfig tun1 10.1.1.2 10.1.1.1 netmask 255.255.255.252
# route add 10.0.50.0/24 10.1.1.1
Client access may be more finely tuned via the
/root/.ssh/authorized_keys file (see below) and the
PermitRootLogin server option. The following entry
would permit connections on tun(4) device 1 from user
“jane” and on tun device 2 from user “john”, if
PermitRootLogin is set to
“forced-commands-only”:
tunnel="1",command="sh /etc/netstart tun1" ssh-rsa ... jane
tunnel="2",command="sh /etc/netstart tun2" ssh-rsa ... john
Since an SSH-based setup entails a fair amount of overhead, it may
be more suited to temporary setups, such as for wireless VPNs. More
permanent VPNs are better provided by tools such as
ipsecctl(8) and isakmpd(8).
SSH_ASKPASS
- If
ssh needs a passphrase, it will read the
passphrase from the current terminal if it was run from a terminal. If
ssh does not have a terminal associated with it
but DISPLAY and SSH_ASKPASS are set, it will
execute the program specified by SSH_ASKPASS that
may open a X11 window to read the passphrase. For keys from
“engine” or “store”
SSH_ASKPASS is preferred over associated terminal.
Note if SSH_ASKPASS is not set will be executed
program ssh-askpass located in
“libexec” directory. This is particularly useful when
calling ssh from a
.xsession or related script.
Remark: On Android DISPLAY is
ignored.
SSH_ASKPASS_REQUIRE
- Allows further control over the use of an askpass program. If this
variable is set to “never” then
ssh
will never attempt to use one. If it is set to “prefer”,
then ssh will prefer to use the askpass program
instead of the TTY when requesting passwords. Finally, if the variable is
set to “force”, then the askpass program will be used for
all passphrase input regardless of whether DISPLAY
is set.
SSH_AUTH_SOCK
- Identifies the path of a UNIX-domain socket used
to communicate with the agent.
SSH_ENGINE_CONF
- Overrides default location of engine configuration file.
sshd(8) will normally set the following
environment variables:
DISPLAY
- The
DISPLAY variable indicates the location of the
X11 server. It is automatically set by ssh to
point to a value of the form “hostname:n”, where
“hostname” indicates the host where the shell runs, and
‘n’ is an integer ≥ 1. ssh
uses this special value to forward X11 connections over the secure
channel. The user should normally not set DISPLAY
explicitly, as that will render the X11 connection insecure (and will
require the user to manually copy any required authorization
cookies).
HOME
- Set to the path of the user's home directory.
LOGNAME
- Synonym for
USER ; set for compatibility with
systems that use this variable.
MAIL
- Set to the path of the user's mailbox.
PATH
- Set to the default
PATH , as specified when
compiling ssh .
SSH_AUTH_SOCK
- Identifies the path of a UNIX-domain socket used
to communicate with the forwarded agent.
SSH_CONNECTION
- Identifies the client and server ends of the connection. The variable
contains four space-separated values: client IP address, client port
number, server IP address, and server port number.
SSH_ORIGINAL_COMMAND
- This variable contains the original command line if a forced command is
executed. It can be used to extract the original arguments.
SSH_TTY
- This is set to the name of the tty (path to the device) associated with
the current shell or command. If the current session has no tty, this
variable is not set.
SSH_TUNNEL
- Optionally set by sshd(8) to contain the interface names
assigned if tunnel forwarding was requested by the client.
SSH_USER_AUTH
- Optionally set by sshd(8), this variable may contain a
pathname to a file that lists the authentication methods successfully used
when the session was established, including any public keys that were
used.
TZ
- This variable is set to indicate the present time zone if it was set when
the daemon was started (i.e. the daemon passes the value on to new
connections).
USER
- Set to the name of the user logging in.
Additionally, sshd(8) reads
~/.ssh/environment, and adds lines of the format
“VARNAME=value” to the environment if the file exists and
users are allowed to change their environment. For more information, see the
PermitUserEnvironment option in
sshd_config(5).
- ~/.rhosts
- This file is used for host-based authentication (see above). On some
machines this file may need to be world-readable if the user's home
directory is on an NFS partition, because sshd(8) reads
it as root. Additionally, this file must be owned by the user, and must
not have write permissions for anyone else. The recommended permission for
most machines is read/write for the user, and not accessible by others.
- ~/.shosts
- This file is used in exactly the same way as
.rhosts, but allows host-based authentication
without permitting login with rlogin/rsh.
- ~/.ssh/
- This directory is the default location for all user-specific configuration
and authentication information. There is no general requirement to keep
the entire contents of this directory secret, but the recommended
permissions are read/write/execute for the user, and not accessible by
others.
- ~/.ssh/authorized_keys
- Lists the public keys (ECDSA, Ed25519, RSA) or X.509 certificates that can
be used for logging in as this user. The format of this file is described
in the sshd(8) manual page. This file is not highly
sensitive, but the recommended permissions are read/write for the user,
and not accessible by others.
- ~/.ssh/ca/ca-bundle.crt
-
- ~/.ssh/ca/ca-bundle.crl
- Part of user “X.509 store”. Same as systemwide files below.
- ~/.ssh/ca/crt
-
- ~/.ssh/ca/crl
- Part of user “X.509 store”. Same as systemwide directories
below.
- ~/.ssh/config
- This is the per-user configuration file. The file format and configuration
options are described in ssh_config(5). Because of the
potential for abuse, this file must have strict permissions: read/write
for the user, and not writable by others.
- ~/.ssh/environment
- Contains additional definitions for environment variables; see
ENVIRONMENT, above.
- ~/.ssh/id_ecdsa
-
- ~/.ssh/id_ed25519
-
- ~/.ssh/id_rsa
- Contains the private key for authentication. These files contain sensitive
data and should be readable by the user but not accessible by others
(read/write/execute).
ssh will simply ignore a
private key file if it is accessible by others. It is possible to specify
a passphrase when generating the key which will be used to encrypt the
sensitive part of this file using 256-bit AES.
For RSA, ECDSA, or Ed25519 identity file (private key) may
contain X.509 certificate that match key. In addition file may contain
extra X.509 certificates. Extra certificates along with certificates
from X.509 store are used to build chain of certificates leading to a
trusted certificate authority if required by public key algorithm
format.
- ~/.ssh/id_ecdsa.pub
-
- ~/.ssh/id_ed25519.pub
-
- ~/.ssh/id_rsa.pub
- Contains the public key for authentication. Note if an identity contain
private key and X.509 certificate, file must contain that certificate.
These files are not sensitive and can (but need not) be readable by
anyone.
- ~/.ssh/known_hosts
- Contains a list of host keys or X.509 certificates for all hosts the user
has logged into that are not already in the systemwide list of known host
keys. See sshd(8) for further details of the format of
this file.
- ~/.ssh/rc
- Commands in this file are executed by
ssh when the
user logs in, just before the user's shell (or command) is started. See
the sshd(8) manual page for more information.
- /etc/hosts.equiv
- This file is for host-based authentication (see above). It should only be
writable by root.
- [APPDATA]/etc/shosts.equiv
- This file is used in exactly the same way as
hosts.equiv, but allows host-based authentication
without permitting login with rlogin/rsh.
- [APPDATA]/etc/ca/ca-bundle.crt
-
- [APPDATA]/etc/ca/ca-bundle.crl
- Part of systemwide “X.509 store”. The first file contain
multiple certificates and the second “Certificate Revocation
List” (CRLs) of X.509 certificate signers in PEM format
concatenated together. Used in verification and validation of server host
certificate.
- [APPDATA]/etc/ca/crt
-
- [APPDATA]/etc/ca/crl
- Part of systemwide “X.509 store”. “Hash dirs”
with certificates, the first directory or CLRs, the second of certificate
signers. Each certificate should be stored in separate file with name
[HASH].[NUMBER] or [HASH].r[NUMBER] for the CRL, where [HASH] is
certificate or CRL hash value and [NUMBER] is an integer starting from
zero. Used in verification and validation of server host certificate.
- [APPDATA]/etc/ssh_config
- Systemwide configuration file. The file format and configuration options
are described in ssh_config(5).
- [APPDATA]/etc/ssh_host_ecdsa_key
-
- [APPDATA]/etc/ssh_host_ed25519_key
-
- [APPDATA]/etc/ssh_host_rsa_key
- These files contain the private parts of the host keys and are used for
host-based authentication. For RSA, ECDSA, or Ed25519 keys files may
contain X.509 certificate that match it. In addition file may contain
extra X.509 certificates. Extra certificates along with certificates from
X.509 store are used to build chain of certificates leading to a trusted
certificate authority if required by host-based key algorithm format. If a
X.509 certificate is used as host key for hostbased authentication that
certificate must have client purpose too or server configuration must
permit connection without client purpose. For allowed client certificate
purposes see ssh_config(5).
- [APPDATA]/etc/ssh_known_hosts
- Systemwide list of known host keys or X.509 certificates. This file should
be prepared by the system administrator to contain the public host keys or
X.509 certificates of all machines in the organization. It should be
world-readable. See sshd(8) for further details of the
format of this file.
- [APPDATA]/etc/sshrc
- Commands in this file are executed by
ssh when the
user logs in, just before the user's shell (or command) is started. See
the sshd(8) manual page for more information.
ssh exits with the exit status of the
remote command or with 255 if an error occurred.
scp(1), sftp(1),
ssh-add(1), ssh-agent(1),
ssh-askpass(1), ssh-keygen(1),
ssh-keyscan(1), tun(4),
ssh_config(5), ssh-keysign(8),
sshd(8)
- T. Ylonen, T.
Kivinen, M. Saarinen, T.
Rinne, and S. Lehtinen,
SSH Transport Layer Protocol,
31 January 2002,
draft-ietf-secsh-transport-12.txt.
- S. Lehtinen and
C. Lonvick, The Secure Shell
(SSH) Protocol Assigned Numbers, RFC 4250,
January 2006.
- T. Ylonen and
C. Lonvick, The Secure Shell
(SSH) Protocol Architecture, RFC 4251,
January 2006.
- T. Ylonen and
C. Lonvick, The Secure Shell
(SSH) Authentication Protocol, RFC 4252,
January 2006.
- T. Ylonen and
C. Lonvick, The Secure Shell
(SSH) Transport Layer Protocol, RFC 4253,
January 2006.
- T. Ylonen and
C. Lonvick, The Secure Shell
(SSH) Connection Protocol, RFC 4254,
January 2006.
- J. Schlyter and
W. Griffin, Using DNS to
Securely Publish Secure Shell (SSH) Key Fingerprints,
RFC 4255, January
2006.
- F. Cusack and
M. Forssen, Generic Message
Exchange Authentication for the Secure Shell Protocol (SSH),
RFC 4256, January
2006.
- J. Galbraith and
P. Remaker, The Secure Shell
(SSH) Session Channel Break Extension, RFC
4335, January 2006.
- M. Bellare, T.
Kohno, and C. Namprempre,
The Secure Shell (SSH) Transport Layer Encryption
Modes, RFC 4344, January
2006.
- B. Harris,
Improved Arcfour Modes for the Secure Shell (SSH)
Transport Layer Protocol, RFC 4345,
January 2006.
- M. Friedl, N.
Provos, and W. Simpson,
Diffie-Hellman Group Exchange for the Secure Shell (SSH)
Transport Layer Protocol, RFC 4419,
March 2006.
- J. Galbraith and
R. Thayer, The Secure Shell
(SSH) Public Key File Format, RFC 4716,
November 2006.
- D. Stebila and
J. Green, Elliptic Curve
Algorithm Integration in the Secure Shell Transport Layer,
RFC 5656, December
2009.
- A. Perrig and
D. Song, Hash Visualization: a
New Technique to improve Real-World Security,
1999, International Workshop on
Cryptographic Techniques and E-Commerce (CrypTEC '99).
- K. Igoe and D.
Stebila, X.509v3 Certificates for Secure Shell
Authentication, RFC 6187,
March 2011.
- S. Josefsson and
I. Liusvaara, Edwards-Curve
Digital Signature Algorithm (EdDSA), RFC
8032, January 2017.
- D. Bider,
Extension Negotiation in the Secure Shell (SSH)
Protocol, RFC 8308,
March 2018.
- D. Bider, Use
of RSA Keys with SHA-256 and SHA-512 in the Secure Shell (SSH)
Protocol, RFC 8332,
March 2018.
- A. Adamantiadis,
S. Josefsson, and M.
Baushke, Secure Shell (SSH) Key Exchange Method
Using Curve25519 and Curve448, RFC 8731,
February 2020.
- B. Harris and
L. Velvindron, Ed25519 and
Ed448 Public Key Algorithms for the Secure Shell (SSH) Protocol,
RFC 8709, February
2020.
PKIX-SSH is a derivative of the original and free ssh 1.2.12
release by Tatu Ylonen. Aaron Campbell, Bob Beck, Markus Friedl, Niels
Provos, Theo de Raadt and Dug Song removed many bugs, re-added newer
features and created OpenSSH. Markus Friedl contributed the support for SSH
protocol versions 1.5 and 2.0. Roumen Petrov contributed support for X.509
certificates.
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Copyright © 2018-2024 |
, Roumen Petrov |
Авторско право 2018-2024 |
, Румен Петров |
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