By Ralf Schlatterbeck
This is a project to connect to a Checkpoint SSL-VPN from a Linux client. The current version of checkpoint SNX (SSL Network Extender) for Linux no longer supports a command-line mode. The supported version involves a Browser with Java and is heavily dependent on the correct Java version and other configuration options in the Browser. Moreover it seems to only work with the Mozilla browsers (Firefox) not with others like Chrome. Last not least Java and the Browser like to die frequently.
The current Checkpoint solution still depends on a command-line utility
called snx that needs root privileges and is installed either via
automatic download (and install) from Java or by hand. The web-page for
the SSL-VPN usually supports download of the correct snx-version for
that endpoint for manual installation.
In the new solution the snx binary is called with the undocumented
-Z Option. In that mode it does not do the password negotiation
(which is done via the browser) but is only used for setting up the VPN
connection.
This project is an attempt to duplicate the Browser-based login with a
standalone program (in python) to get rid of all the Java version and
Browser intergration headache. We still rely on the snx binary by
Checkpoint which is called with the undocumented -Z option.
So far this is working for me with a Checkpoint SSL that uses username and password authentication and in addition a one-time password transmitted via SMS to the telephone of the person trying to connect. If you're using certificate-based login or other methods, this will probably not work for you out-of-the-box but you may want to help me make it work.
Install via pip is the preferred way (replace pip with pip3
if you want to install for python3):
pip install snxvpn
The following dependencies are needed but should be picked up
automagically if you install via pip:
- Beautiful Soup version 4 (
python-bs4Debian package) - pycrypto (
python-cryptoDebian package)
After installation you should be able to run snxconnect --help to
find out about options. At least a host, and username must be given,
either on the command-line via options or in a config file (see below).
The snxconnect program will currently create two files in the
current working directory where the program is started:
snxanswer: The not-yet-reverse-engineered answer of Checkpoint'ssnxprogram to the caller, only created if the--debugoption is given$HOME/.snxcookies: The cookies from the remote end in the format known from the perl LWP library (available in python as LWPCookieJar), this is only created if the--save-cookiesoption is given. The default cookie filename can be changed with the--cookiefileoption.
If a cookie file is found, snxconnect tries to reconnect without
asking for a password. This can be used if the connection has died
prematurely before the connection time ran out. And, yes, it might be a
security risk to save cookies to disk, so you have to explicitly enable
this feature by setting save-cookies true in the config file or
giving the --save-cookies option. Note that the cookies of course
only have a limited lifetime and your connection isn't very secure if
you cannot be sure of the files on your disk. Moreover all users of the
current machine can access the VPN connection anyway.
When you run Checkpoints snx for the first time with snxconnect it
creates an X-Windows popup that lets you confirm the server fingerprint.
I've not seen this popup with the Java framework (but Java died several
times during my first experiments which is one of the reasons I wrote
snxvpn, so that might be the reason I hadn't seen the popup
before). You have to confirm this popup. The server fingerprint is
stored into a file with extension .db in /etc/snx.
For configuration, snxconnect accepts a config file
$HOME/.snxvpnrc. The options there are the command-line long options
(obtained with --help) where a '-' is replaced with '_'. For
compatibility with .snxrc, the keyword server is an alias for
host. You can see which options were picked up from the config-file
by specifying --help, where defaults are displayed, the defaults
from the config-file are displayed. Command-line options take precedence
over config-file entries.
In addition a .netrc file is supported that can contain username and
password by host name. Note that storing long-term login credentials on
disk is a security risk. See the manual page for netrc for further
details.
To install from source (from a git checkout) you need my
sfreleasetools from Sourceforge. This adds the necessary Makefile
includes to create the snxvpnversion.py from the git tag containing
the latest version number. You can either install sfreleasetools in a
sibling directory of snxvpn called releasetools or set the
environment variable RELEASETOOLS pointing to your cloned version.
You also need the rst2html command provided by docutils, on
Debian Linux you can obtain it by installing the python-docutils
package.
Once this is installed, call make without arguments. This will
create the snxvpnversion.py which is used by the setup.py
script.
Once the snxvpnversion.py has been created, the snxvpn package can
be installed with normal:
python setup.py install --prefix=/usr/local
From many posts on various mailinglists and forums, it is clear that
installing snx isn't straightforward. You need some non-standard
libraries installed that snx needs to function. Moreover snx is
a binary for the i386 architecture, not a modern 64-bit AMD/Intel
architecture. I can only give hints for Debian installation here but the
general steps will apply to other distributions, too.
Obtaining the snx binary in the first place can usually be achieved by
connecting via web-browser to the SSL-VPN site via the browser, log in
and (in my installation here at least) look in the Settings (in german
Einstellungen) menu for an entry native application settings or
similar (german "Native Anwendungseinstellungen bearbeiten"). In this
menu I do have links for manual download of snx for Linux and
Mac-OS.
First of all if you're on a 64-bit architecture (called amd-64 at
least by Debian) you need to enable multi-architecture support with:
dpkg --add-architecture i386 apt-get update
Then you need to install some packages that contain libraries needed by
snx, notably:
libstdc++5:i386libxcb1:i386libaudit1:i386libgcc1:i386libxau6:i386libxdmcp6:i386
To check if you have all necessary libraries, you can run ldd on the
snx binary (with sudo to root):
sudo ldd /usr/bin/snx
This should list a library file for each line and should not report any missing libraries.
This section discusses some of the internals of how the snx program
is called by the Java framework and snxconnect.
The Login process via the browser is a standard login page with lots of Javascript and redirects. Passwords are sent in encrypted form to the VPN gateway. The encryption uses a 2048 bit RSA key and pads the password with random data before encryption (this is good). During login the browser (or this program) picks up a lot of cookies and can access necessary login information via Javascript. This information includes:
- RSA public key for the password encryption
- Username to be passed to
snx - A one-time password (different from the one received via telephone) to
be passed to
snx - Host name for TLS connection
- Port for TLS connection
- A server fingerprint
All these (except the RSA key) are passed to the snx program for
establishing the connection. The connection might use PPP internally as
some of the error messages (which are sent as part of the i18n info in
Javascript and map the error codes of snx to human-readable
messages) suggest.
If you call snx with the undocumented -Z option by hand, it
will terminate immediately. It obviously has other checks in place if it
is called "correctly". To call snx correctly with this option,
snx expects that standard input, output and error are UNIX pipes.
Only if something goes wrong and snx dies with an error-message,
these pipes are ever used. After startup, snx checks the existence
of a logfile and creates it if it doesn't exist or is not locked by
another snx process. Then it creates some other lockfiles in
/etc/snx/tmp and then immediately forks a child process and lets the
parent process terminate. This forking and terminating sends the child
process to the background. The first step the child process does is
close the file-descriptors for standard input, output, and error.
After this, snx opens and listens on a TCP socket on port 7776 on
the local machine. I haven't found options for telling snx to use
another port. The calling application (e.g., snxconnect or the
original Java framework) is expected to pass the connection information
detailed above in an undocumented binary format. After that snx
establishes a VPN connection and reports back with another blob of
binary information on the same socket. The socket must then be kept open
by the calling application, otherwise snx terminates. It may well be
that snx accepts further commands on that socket, e.g., for renewing
the authentication after the VPN timeout has expired. We log the binary
data received on that socket to the file snxanswer if debugging is
enabled.