Google's "golang.org/x/crypto/ssh" library offers a fantastic full implementation of the ssh client and server protocols. However this library is minimalistic by design, cumbersome to figure out how to use with RSA keys, and needs additional code to support tunneling and receiving connections as an sshd.
sshego bridges this usability gap,
providing a drop-in Go library
to secure your tcp connections. In
places sshego can be used in preference to
a virtual-private-network (VPN), for both
convenience and speed. Moreover the SSH
protocol's man-in-the-middle attack protection is
better than a VPN in almost all cases.
For strong security, our embedded sshd offers three-factor auth (3FA). The three security factors are: a passphrase ("what you know"); a 6-digit Google authenticator code (TOTP/RFC 6238; "what you have": your phone); and the use of PKI in the form of 4096-bit RSA keys.
To promote strong passphrases, we follow the inspiration of https://xkcd.com/936/, and offer a user- friendly 3-word starting prompt (the user completes the sentence) to spark the user's imagination in creating a strong and memorizable passphrase. Passphrases of up to 100 characters are supported.
Although not for the super-security conscious, if desired and configured, passphrases can automatically be backed up to email (via the Mailgun email service).
On new account creation with gosshtun -adduser yourlogin,
we will attempt to pop-up the QR-code on your
local desktop for quick Google Authenticator setup
on your phone.
sshego is a golang (Go) library for ssh
tunneling (secure port forwarding). It also offers an
embeddable 3-factor authentication sshd server,
which can be useful for securing reverse forwards.
This means you can easily create an ssh-based vpn with 3-factor authentication requrirements: the embedded sshd requires passphrase, RSA keys, and a TOTP Google Authenticator one-time password.
In addition to the libary, gosshtun is also
a command line utility (see the cmd/ subdir) that
demonstrates use of the library and may prove
useful on its own.
The intent of having a Go library is so that it can be used to secure (via SSH tunnel) any other traffic that your Go application would normally have to do over cleartext TCP.
While you could always run a tunnel as a separate process, by running the tunnel in process with your application, you know the tunnel is running when the process is running. It's just simpler to administer; only one thing to start instead of two.
Also this is much simpler, and much faster, than using a virtual private network (VPN). For a speed comparison, consider [1] where SSH is seen to be at least 2x faster than OpenVPN.
[1] https://serverfault.com/questions/653211/ssh-tunneling-is-faster-than-openvpn-could-it-be
In its principal use, sshego is the equivalent
to using the ssh client and giving -L and/or -R.
It acts like an ssh client without a remote shell; it simply
tunnels other TCP connections securely. There are
also options to run an embedded SSHD. This can
be useful for securing reverse forwards, if allowed.
For example,
gosshtun -listen 127.0.0.1:89 -sshd jumpy:55 -remote 10.0.1.5:80 -user alice -key ~/.ssh/id_rsa_nopw
is equivalent to
ssh -N -L 89:10.0.1.5:80 alice@jumpy -port 55
with the addendum that gosshtun requires the use of passwordless
private -key file, and will never prompt you for a password at the keyboard.
This makes it ideal for embedding inside your application to
secure your (e.g. mysql, postgres, other cleartext) traffic. As
many connections as you need will be multiplexed over the
same ssh tunnel.
If you don't trust the other users on the host where your process is running, you can also use sshego to (a) secure a direct TCP connection (see DialConfig.Dial() and the example in cli_test.go; https://github.com/glycerine/sshego/blob/master/cli_test.go#L72); or (b) forward via a file-system secured unix-domain sockets.
The first option (a) would disallow any other process (even under the same user) from multiplexing your original connection, and the second (b) would disallow any other user from accessing your tunnel, so long as you use the file-system permissions to make the unix-domain socket path inaccessible to others.
In either case, note that keys are by default stored on disk under the user's $HOME/.ssh folder, so as usual that folder should not be readable by others. Using a direct connection as in (a) in no way prevents you from starting another process (from the same executable or another) that reads the same keys and starts its own direct tcp connection.
gosshtun and sshego will check the sshd server's host key. We prevent MITM attacks
by only allowing new servers if -new (a.k.a. SshegoConfig.AddIfNotKnown == true) is given.
When running the standalone gosshtun to test
a foward, you should give -new only once at setup time.
Then the lack of -new protects you on subsequent runs,
because the server's host key must match what we were
given the very first time.
Usage of gosshtun:
-cfg string
path to our config file
-esshd string
(optional) start an in-process embedded sshd (server),
binding this host:port, with both RSA key and 2FA
checking; useful for securing -revfwd connections.
-esshd-host-db string
(only matters if -esshd is also given) path
to database holding sshd persistent state
such as our host key, registered 2FA secrets, etc.
(default "$HOME/.ssh/.sshego.sshd.db")
-key string
private key for sshd login (default "$HOME/.ssh/id_rsa_nopw")
-known-hosts string
path to gosshtun's own known-hosts file (default
"$HOME/.ssh/.sshego.cli.known.hosts")
-listen string
(forward tunnel) We listen on this host:port locally,
securely tunnel that traffic to sshd, then send it
cleartext to -remote. The forward tunnel is active
if and only if -listen is given. If host starts with
a '/' then we treat it as the path to a unix-domain
socket to listen on, and the port can be omitted.
-new
allow connecting to a new sshd host key, and store it
for future reference. Otherwise prevent MITM attacks by
rejecting unknown hosts.
-quiet
if -quiet is given, we don't log to stdout as each
connection is made. The default is false; we log
each tunneled connection.
-remote string
(forward tunnel) After traversing the secured forward
tunnel, -listen traffic flows in cleartext from the
sshd to this host:port. The foward tunnel is active
only if -listen is given too. If host starts with a
'/' then we treat it as the path to a unix-domain
socket to forward to, and the port can be omitted.
-revfwd string
(reverse tunnel) The gosshtun application will receive
securely tunneled connections from -revlisten on the
sshd side, and cleartext forward them to this host:port.
For security, it is recommended that this be 127.0.0.1:22,
so that the sshd service on your gosshtun host
authenticates all remotely initiated traffic.
See also the -esshd option which can be used to
secure the -revfwd connection as well.
The reverse tunnel is active only if -revlisten is given
too. (default "127.0.0.1:22")
-revlisten string
(reverse tunnel) The sshd will listen on this host:port,
securely tunnel those connections to the gosshtun application,
whence they will cleartext connect to the -revfwd address.
The reverse tunnel is active if and only if -revlisten is given.
-sshd string
The remote sshd host:port that we establish a secure tunnel to;
our public key must have been already deployed there.
-user string
username for sshd login (default is $USER)
-v verbose debug mode
-write-config string
(optional) write our config to this path before doing
connections
go get github.com/glycerine/sshego/...
$ gosshtun -listen localhost:8888 -sshd 10.0.1.68:22 -remote 127.0.0.1:80
means the following two network hops will happen, when a local browser connects to localhost:8888
`gosshtun` `sshd`
local browser ----> localhost:8888 --(a)--> 10.0.1.68:22 --(b)--> 127.0.0.1:80
`host A` `host A` `host B` `host B`
where (a) takes place inside the previously established ssh tunnel.
Connection (b) takes place over basic, un-adorned, un-encrypted TCP/IP. Of
course you could always run gosshtun again on the remote host to
secure the additional hop as well, but typically -remote is aimed at the 127.0.0.1,
which will be internal to the remote host itself and so needs no encryption.
The -user flag should be used if your local $USER is different from that on the sshd host.
See github.com/glycerine/sshego/cmd/gosshtun/main.go for the source code. This
also serves as an example of how to use the library.
~/.ssh/.sshego.known.hosts.json.snappy
a) install your passwordless ssh-private key in ~/.ssh/id_rsa_nopw or use -key to say where it is.
b) add the corresponding public key to the user's .ssh/authorized_keys file on the sshd host.
a) see demo.env for an example
b) run gosshtun -write-config - to generate a sample config file to stdout
c) comments are allowed; lines must start with #, comments continue until end-of-line
d) fields recognized (see gosshtun -write-config - for a full list)
#
# config file for sshego:
#
SSHD_ADDR="1.2.3.4:22"
FWD_LISTEN_ADDR="127.0.0.1:8888"
FWD_REMOTE_ADDR="127.0.0.1:22"
REV_LISTEN_ADDR=""
REV_REMOTE_ADDR=""
SSHD_LOGIN_USERNAME="$USER"
SSH_PRIVATE_KEY_PATH="$HOME/.ssh/id_rsa_nopw"
SSH_KNOWN_HOSTS_PATH="$HOME/.ssh/.sshego.known.hosts"
#
# optional in-process sshd
#
EMBEDDED_SSHD_HOST_DB_PATH="$HOME/.ssh/.sshego.sshd.db"
EMBEDDED_SSHD_LISTEN_ADDR="127.0.0.1:2022"
d) special environment reads
-
The SSHD_LOGIN_USERNAME will subsitute $USER from the environment, if present.
-
The *PATH keys will substitute $HOME from the environment, if present.
See the LICENSE file.
Jason E. Aten, Ph.D.