OpenSSH is a set of network connectivity tools used to access remote machines securely. It can be used as a direct replacement for rlogin, rsh, rcp, and telnet. Additionally, TCP/IP connections can be tunneled/forwarded securely through SSH. OpenSSH encrypts all traffic to effectively eliminate eavesdropping, connection hijacking, and other network-level attacks.
OpenSSH is maintained by the OpenBSD project, and is based upon SSH v1.2.12 with all the recent bug fixes and updates. It is compatible with both SSH protocols 1 and 2.
Normally, when using telnet(1) or rlogin(1), data is sent over the network in a clear, un-encrypted form. Network sniffers anywhere in between the client and server can steal your user/password information or data transferred in your session. OpenSSH offers a variety of authentication and encryption methods to prevent this from happening.
The sshd is an option presented during a Standard install of FreeBSD. To see if sshd is enabled, check the rc.conf file for:
# /etc/rc.d/sshd start
# ssh email@example.com Host key not found from the list of known hosts. Are you sure you want to continue connecting (yes/no)? yes Host 'example.com' added to the list of known hosts. firstname.lastname@example.org's password: *******
The login will continue just as it would have if a session was created using rlogin or telnet. SSH utilizes a key fingerprint system for verifying the authenticity of the server when the client connects. The user is prompted to enter yes only when connecting for the first time. Future attempts to login are all verified against the saved fingerprint key. The SSH client will alert you if the saved fingerprint differs from the received fingerprint on future login attempts. The fingerprints are saved in ~/.ssh/known_hosts, or ~/.ssh/known_hosts2 for SSH v2 fingerprints.
By default, recent versions of the OpenSSH servers
only accept SSH v2 connections. The client will use version 2 if possible and
will fall back to version 1. The client can also be forced to use one or the other
by passing it the
for version 1 or version 2, respectively. The version 1 compatibility is
maintained in the client for backwards compatibility with older versions.
# scp email@example.com:/COPYRIGHT COPYRIGHT firstname.lastname@example.org's password: ******* COPYRIGHT 100% |*****************************| 4735 00:00 #
Since the fingerprint was already saved for this host in the previous example, it is verified when using scp(1) here.
The arguments passed to scp(1) are similar to
cp(1), with the file
or files in the first argument, and the destination in the second. Since the file is
fetched over the network, through SSH, one or more of the file arguments takes
on the form
The system-wide configuration files for both the OpenSSH daemon and client reside within the /etc/ssh directory.
ssh_config configures the client settings, while sshd_config configures the daemon.
sshd_program (/usr/sbin/sshd by default), and
sshd_flags rc.conf options can
provide more levels of configuration.
Instead of using passwords, ssh-keygen(1) can be used to generate DSA or RSA keys to authenticate a user:
% ssh-keygen -t dsa Generating public/private dsa key pair. Enter file in which to save the key (/home/user/.ssh/id_dsa): Created directory '/home/user/.ssh'. Enter passphrase (empty for no passphrase): Enter same passphrase again: Your identification has been saved in /home/user/.ssh/id_dsa. Your public key has been saved in /home/user/.ssh/id_dsa.pub. The key fingerprint is: bb:48:db:f2:93:57:80:b6:aa:bc:f5:d5:ba:8f:79:17 email@example.com
ssh-keygen(1) will create a public and private key pair for use in authentication. The private key is stored in ~/.ssh/id_dsa or ~/.ssh/id_rsa, whereas the public key is stored in ~/.ssh/id_dsa.pub or ~/.ssh/id_rsa.pub, respectively for DSA and RSA key types. The public key must be placed in the ~/.ssh/authorized_keys file of the remote machine for both RSA or DSA keys in order for the setup to work.
This will allow connection to the remote machine based upon SSH keys instead of passwords.
If a passphrase is used in ssh-keygen(1), the user will be prompted for a password each time in order to use the private key. ssh-agent(1) can alleviate the strain of repeatedly entering long passphrases, and is explored in the Section 15.10.7 section below.
Warning: The various options and files can be different according to the OpenSSH version you have on your system; to avoid problems you should consult the ssh-keygen(1) manual page.
The ssh-agent(1) utility will handle the authentication using the private key(s) that are loaded into it. ssh-agent(1) should be used to launch another application. At the most basic level, it could spawn a shell or at a more advanced level, a window manager.
To use ssh-agent(1) in a shell, first it will need to be spawned with a shell as an argument. Secondly, the identity needs to be added by running ssh-add(1) and providing it the passphrase for the private key. Once these steps have been completed the user will be able to ssh(1) to any host that has the corresponding public key installed. For example:
% ssh-agent csh % ssh-add Enter passphrase for /home/user/.ssh/id_dsa: Identity added: /home/user/.ssh/id_dsa (/home/user/.ssh/id_dsa) %
To use ssh-agent(1) in X11, a call to ssh-agent(1) will need to be placed in ~/.xinitrc. This will provide the ssh-agent(1) services to all programs launched in X11. An example ~/.xinitrc file might look like this:
exec ssh-agent startxfce4
This would launch ssh-agent(1), which would in turn launch XFCE, every time X11 starts. Then once that is done and X11 has been restarted so that the changes can take effect, simply run ssh-add(1) to load all of your SSH keys.
OpenSSH has the ability to create a tunnel to encapsulate another protocol in an encrypted session.
The following command tells ssh(1) to create a tunnel for telnet:
% ssh -2 -N -f -L 5023:localhost:23 firstname.lastname@example.org %
The ssh command is used with the following options:
Forces ssh to use version 2 of the protocol. (Do not use if you are working with older SSH servers)
Indicates no command, or tunnel only. If omitted, ssh would initiate a normal session.
Forces ssh to run in the background.
Indicates a local tunnel in localport:remotehost:remoteport fashion.
The remote SSH server.
An SSH tunnel works by creating a listen socket on localhost on the specified port. It then forwards any connection received on the local host/port via the SSH connection to the specified remote host and port.
In the example, port 5023 on localhost is being forwarded to port 23 on localhost of the remote machine. Since 23 is telnet, this would create a secure telnet session through an SSH tunnel.
This can be used to wrap any number of insecure TCP protocols such as SMTP, POP3, FTP, etc.
Example 15-1. Using SSH to Create a Secure Tunnel for SMTP
% ssh -2 -N -f -L 5025:localhost:25 email@example.com firstname.lastname@example.org's password: ***** % telnet localhost 5025 Trying 127.0.0.1... Connected to localhost. Escape character is '^]'. 220 mailserver.example.com ESMTP
This can be used in conjunction with an ssh-keygen(1) and additional user accounts to create a more seamless/hassle-free SSH tunneling environment. Keys can be used in place of typing a password, and the tunnels can be run as a separate user.
At work, there is an SSH server that accepts connections from the outside. On the same office network resides a mail server running a POP3 server. The network, or network path between your home and office may or may not be completely trustable. Because of this, you need to check your e-mail in a secure manner. The solution is to create an SSH connection to your office's SSH server, and tunnel through to the mail server.
% ssh -2 -N -f -L 2110:mail.example.com:110 email@example.com firstname.lastname@example.org's password: ******
When the tunnel is up and running, you can point your mail client to send POP3 requests to localhost port 2110. A connection here will be forwarded securely across the tunnel to mail.example.com.
Some network administrators impose extremely draconian firewall rules, filtering not only incoming connections, but outgoing connections. You may be only given access to contact remote machines on ports 22 and 80 for SSH and web surfing.
You may wish to access another (perhaps non-work related) service, such as an Ogg Vorbis server to stream music. If this Ogg Vorbis server is streaming on some other port than 22 or 80, you will not be able to access it.
The solution is to create an SSH connection to a machine outside of your network's firewall, and use it to tunnel to the Ogg Vorbis server.
% ssh -2 -N -f -L 8888:music.example.com:8000 email@example.com firstname.lastname@example.org's password: *******
Your streaming client can now be pointed to localhost port 8888, which will be forwarded over to music.example.com port 8000, successfully evading the firewall.
It is often a good idea to limit which users can log in and from where. The AllowUsers option is a good way to accomplish this. For example, to only allow the root user to log in from 192.168.1.32, something like this would be appropriate in the /etc/ssh/sshd_config file:
To allow the user admin to log in from anywhere, just list the username by itself:
Multiple users should be listed on the same line, like so:
AllowUsers email@example.com admin
Note: It is important that you list each user that needs to log in to this machine; otherwise they will be locked out.
After making changes to /etc/ssh/sshd_config you must tell sshd(8) to reload its config files, by running:
# /etc/rc.d/sshd reload