4  Configuration in SSH

4 Configuration in SSH

The OTP SSH app can be configurated by a large amount of Options. This chapter will not go into details of what each of the options does. It will however describe and define different ways by which they could be entered.

Options for hardening are described in the Hardening SSH chapter. How the options for algorithm configuration interact are described in the Configuring algorithms in SSH chapter.

There are from OTP-23.0 two main ways to set an option:

  • Like before, in the Options parameter in the Erlang code in a call to for example ssh:daemon/3 or ssh:connect/3 or any of their variants. Example:
    ssh:connect(22, [{user,"foo"}])
  • In OTP Configuration Parameters:

    • In the erl command line:
      erl -ssh user \"foo\"
    • In the ssh.app file, in the env part
      {application, ssh,
       [{description, "SSH-2 for Erlang/OTP"},
        {vsn, "4.9"},
        {modules, [ssh,
              ...
      	     ssh_xfer]},
        {registered, []},
        {applications, [kernel, stdlib, crypto, public_key]},
        {env, [{user, "bar"]}, % <<<<<<<<<<<<<<<<<<<<<<<<<<<<<< HERE
        {mod, {ssh_app, []}},
             ...       
    • In a .config file:
      erl -config ex1
      where ex1.config contains:
      [
      {ssh, [{user, "foo"}]}
      ].

    If the option is intended only for a server or for a client, it may be set in this way:

    [
    {ssh, [{server_options,[{user, "foo"}]},
           {client_options,[{user, "bar"}]}
    ].

    A server (daemon) will use the user name foo, and a client will use the name bar.

If an option is set in more than one way, what happens?

There is an ordering, which is:

If the same option is set at two different levels, the one at the highest level is used.

The only exception is the modify_algorithms common option. They are all applied in ascending level order on the set of algorithms. So a modify_algorithms on level zero is applied before one of level one and so on.

If there is an preferred_algorithms option on some level the whole set is replaced by that in that option and all modify_algorithms are applied in level ordering.

The reason for applying all modify_algorithms in level order, is to enable the user to add an algorithm that has been removed from the default set without code changes, only by adding an option in a config file. This can be used to interoperate with legacy systems that still uses algorithms no longer considered secure enough to be supported by default.

There is a separate chapter about how preferred_algorithms and modify_algorithms co-operate. How the different configuration levels affect them, is described here in this section.

The ssh:start/0 function

If the application SSH is not started, the command ssh:default_algorithms/0 delivers the list of default (hardcoded) algorithms with respect to the support in the current cryptolib.

If the application SSH is started, the command ssh:default_algorithms/0 delvers the list of algorithms after application of level 0 and level 1 configurations.

Here is an example. The config-file has the following contents:

$ cat ex2.config
[
 {ssh, [{preferred_algorithms, [{cipher, ['aes192-ctr']},
       			        {public_key, ['ssh-rsa']},
                                {kex, ['ecdh-sha2-nistp384']},
                                {mac, ['hmac-sha1']}]}]}
].

Erlang is started with ex2.config as configuration and we check the default set of algorithms before starting ssh:

$ erl -config ex2
Erlang/OTP 23 [RELEASE CANDIDATE 1] [erts-10.6.4] [source-96a0823109] [64-bit] [smp:4:4] [ds:4:4:10] [async-threads:1] [hipe]

Eshell V10.6.4  (abort with ^G)
1> ssh:default_algorithms().
[{kex,['ecdh-sha2-nistp384','ecdh-sha2-nistp521',
       'ecdh-sha2-nistp256','diffie-hellman-group-exchange-sha256',
       'diffie-hellman-group16-sha512',
       'diffie-hellman-group18-sha512',
       'diffie-hellman-group14-sha256','curve25519-sha256',
       '[email protected]','curve448-sha512',
       'diffie-hellman-group14-sha1',
       'diffie-hellman-group-exchange-sha1']},
 {public_key,['ecdsa-sha2-nistp384','ecdsa-sha2-nistp521',
              'ecdsa-sha2-nistp256','ssh-ed25519','ssh-ed448','ssh-rsa',
              'rsa-sha2-256','rsa-sha2-512','ssh-dss']},
 {cipher,[{client2server,['[email protected]',
                          '[email protected]','aes256-ctr','aes192-ctr',
                          '[email protected]','aes128-ctr','aes256-cbc',
                          'aes192-cbc','aes128-cbc','3des-cbc']},
          {server2client,['[email protected]',
                          '[email protected]','aes256-ctr','aes192-ctr',
                          '[email protected]','aes128-ctr','aes256-cbc',
                          'aes192-cbc','aes128-cbc','3des-cbc']}]},
 {mac,[{client2server,['hmac-sha2-256','hmac-sha2-512',
                       'hmac-sha1']},
       {server2client,['hmac-sha2-256','hmac-sha2-512',
                       'hmac-sha1']}]},
 {compression,[{client2server,[none,'[email protected]',zlib]},
               {server2client,[none,'[email protected]',zlib]}]}]

Note that the algorithms in the file ex2.config is not yet applied. They will be when we start ssh:

2> ssh:start().
ok
3> ssh:default_algorithms().
[{kex,['ecdh-sha2-nistp384']},
 {public_key,['ssh-rsa']},
 {cipher,[{client2server,['aes192-ctr']},
          {server2client,['aes192-ctr']}]},
 {mac,[{client2server,['hmac-sha1']},
       {server2client,['hmac-sha1']}]},
 {compression,[{client2server,[none,'[email protected]',zlib]},
               {server2client,[none,'[email protected]',zlib]}]}]
4> 

We see that the algorithm set is changed to the one in the ex2.config. Since compression is not specified in the file, the hard-coded default is still used for that entry.

Establishing a connection (ssh:connect et al) or starting a daemon (ssh:daemon)

Both when the client establishes a connection with ssh:connect or other functions, or a daemon is started with ssh:daemon, the option lists in the function calls are also used.

If a client is started (ssh:connect et al), the environment variable client_options is used. Similarly for a daemon the server_options variable is handled.

If any preferred_algorithms is present, the one with the highest level is used, that is, the Option list parameter has the highest priority. Then the modify_algorithms on all levels in order starting with level 0 are applied.

We continue the example above by connecting to a server and modifying the kex algorithm set. We remove the only one ('ecdh-sha2-nistp384') and add '[email protected]' by appending it to the now empty list:

4> {ok,C} = ssh:connect(loopback, 22,
                        [{modify_algorithms,
                                 [{rm,
                                     [ {kex,['ecdh-sha2-nistp384']} ]
				  },
                                  {append,
			             [ {kex,['[email protected]']} ]
				  }
				 ]
	                 }
                        ]).
{ok,>0.118.0>}

We check which algoritms are negotiated by the client and the server, and note that the (only) kex algorithm '[email protected]' was selected:

5> ssh:connection_info(C, algorithms).
{algorithms,[{kex,'[email protected]'},
             {hkey,'ssh-rsa'},
             {send_mac,'hmac-sha1'},
             {recv_mac,'hmac-sha1'},
             {encrypt,'aes192-ctr'},
             {decrypt,'aes192-ctr'},
             {compress,none},
             {decompress,none},
             {send_ext_info,false},
             {recv_ext_info,true}]}
Example of modify_algorithms handling

We will now check if the modify_algorithms on a lower level is applied to a preferred_algorithms on a higher level. We will do that by enabling the ssh-dss algorithm that is supported, but not in the default set.

The config file ex3.config has the contents:

[
 {ssh, [{modify_algorithms,
         [ {prepend, [{public_key, ['ssh-dss']}]} ]
        }]}
].

A newly started erlang shell shows that no 'ssh-dss' is present in the public_key entry:

1> proplists:get_value(public_key, ssh:default_algorithms()).
['ecdsa-sha2-nistp384','ecdsa-sha2-nistp521',
 'ecdsa-sha2-nistp256','ssh-ed25519','ssh-ed448',
 'rsa-sha2-256','rsa-sha2-512','ssh-rsa']
2> 

A call to ssh:connect/3 removes all algorithms but one of each type:

2> ssh:start().
ok
3> {ok,C} = ssh:connect(loopback, 22,
                        [{preferred_algorithms,
                         [{public_key, ['ecdsa-sha2-nistp256']},
			  {kex, ['ecdh-sha2-nistp256']},
		          {cipher, ['[email protected]']},
			  {mac, ['hmac-sha2-256']},
			  {compression, [none]}
			  ]}
			 ]).
{ok,<0.101.0>}
4> ssh:connection_info(C,algorithms).
{algorithms,[{kex,'ecdh-sha2-nistp256'},
             {hkey,'ssh-dss'},
             {send_mac,'[email protected]'},
             {recv_mac,'[email protected]'},
             {encrypt,'[email protected]'},
             {decrypt,'[email protected]'},
             {compress,none},
             {decompress,none},
             {send_ext_info,false},
             {recv_ext_info,true}]}
5>

But 'ssh-dss' is selected although the call inserted only 'ecdsa-sha2-nistp256' as acceptable.

This example showed that we could augment the set of algorithms with a config-file without the need to change the actual call.

For demonstration purposes we used prepend instead of append. This forces the negotiation to select ssh-dss since the the full list of public key algorithms was ['ssh-dss','ecdsa-sha2-nistp256']. Normally it is safer to append a non-default algorithm.