OpenVPN configuration examples

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Introduction

OpenVPN is an open-source software application that implements virtual private network (VPN) techniques for creating secure point-to-point or site-to-site connections in routed or bridged configurations and remote access facilities.

This article contains various OpenVPN configuration examples that require more in-depth explanations to achieve a successful configuration. All of the examples given concern two or more RUT routers. For more basic explanations on the OpenVPN WebUI section, visit our VPN manual page.

OpenVPN configuration type

Before configuring anything you should first know what type of OpenVPN connection suits your needs the best. The key things to be considered here are the type of connection (TUN (tunnel) or TAP (bridged)), the data transfer protocol (User Datagram Protocol (UDP) or Transmission Control Protocol (TCP)), and the authentication type (TLS or Static key). Here is a short overview of the differences:

  • Type
    • TUN (tunnel) - simulates a network layer device and it operates with layer 3 packets like IP packets. TUN is used for routing and connecting multiple clients to a single server.
    • TAP (bridged) - simulates a link layer device and it operates with layer 2 packets like Ethernet frames. TAP is used for creating a network bridge between two Ethernet segments in different locations.
  • Protocol
    • UDP - is used by apps to deliver a faster stream of information by doing away with error-checking.
    • TCP - a suite of protocols used by devices to communicate over the Internet and most local networks. It provides apps a way to deliver (and receive) an ordered and error-checked stream of information packets over the network.
  • Authentication
    • TLS - uses SSL/TLS + certificates for authentication and key exchange.
    • Static key - uses a pre-shared Static key. Can only be used between two peers.

Overviews of most of these types and variations are provided in this article. Concerning TCP vs UDP, we will be using UDP for all examples. Choosing between TCP and UDP doesn't affect the rest of the configuration, so you can still follow the given examples no matter which protocol you are using. Simply choose the one that suits your purposes.

TLS Authentication

This section provides a guide on how to configure a successful OpenVPN connection between an OpenVPN Client and Server, using the TLS Authentication method on RUTxxx routers.

Generating TLS certificates/keys


A connection that uses TLS requires multiple certificates and keys for authentication:

  • OpenVPN server
    • The root certificate file (Certificate Authority)
    • Server certificate
    • Server key
    • Diffie Hellman Parameters
  • OpenVPN client
    • The root certificate file (Certificate Authority)
    • Client certificate
    • Client key

Before you continue you'll have to obtain the necessary certificates and keys. When you use a third-party OpenVPN service, they should provide you with their certificates and even configuration files.

If you're creating your server, you'll have to generate these files yourself. To get detailed instructions on how to generate TLS certificates and keys check out our article on the topic of Windows TLS certificate generation.

Configuration


Now we can start configuring OpenVPN Server and Client instances. For this example we will be creating a TUN (Tunnel) type connection that uses the UDP protocol for data transfer and TLS for Authentication. We will be using two RUT routers: RUT1 (Server; LAN IP: 192.168.1.1; WAN (Public static) IP: 213.226.191.61) and RUT2 (Client; LAN IP: 192.168.2.1); that will be connected into virtual network (with the virtual address: 10.0.0.0):

To sum up, just make sure the Server and the Clients use the same parameters (same authentication, same port, same protocol, etc.). Another important aspect is the Virtual network IP address (10.0.0.0 in this case). The Server and the connected Clients will be given IP addresses that belong to this network. If you're creating an exceptionally large network, you might want to change the Virtual network netmask.

From the Client side, make sure to enter the correct Remote host/IP address (213.226.191.61 in this case). This is the Server's Public IP address, not the virtual IP address.

Static key Authentication

This section provides a guide on how to configure a successful OpenVPN connection between an OpenVPN Client and Server, using the Static key Authentication method on RUT routers.

Creating a Static key


A Static key connection uses a pre-shared for authentication between a Server and one Client. You can generate a Static key within the router itself or with a PC that uses a Linux-based OS.

Within the router


In order to generate a Static key within the router connect to the device via the Command Line Interface (CLI) or SSH (the default username is root, the password is your router's admin password, admin01 by default). CLI can be found in the router's WebUI, under Services. To connect to the router via SSH, use the Terminal app (type ssh [email protected]; replace 192.168.1.1 with your router's LAN IP address) if you're using a Linux-based OS. Or download PuTTY, a free SSH and telnet client, if you're using Windows.

When you have connected to the router, relocate to the directory (for example, cd /etc/easy-rsa/keys/) where you want to store your Static key and use this command:

# openvpn --genkey --secret static.key

The newly generated Static key will appear in the same directory where you issued the command above.

Extracting the key

If you are using a Linux-based OS, extracting files from the router is simple. Just go to the directory on your PC where you want to relocate the files, right click anywhere and choose the Open in Terminal option. In the Terminal command line use the Secure Copy (scp) command to copy the files from the router. The full command should look something like this:

$ scp [email protected]:/etc/easy-rsa/keys/static.key ./

The [email protected]:/etc/easy-rsa/keys/static.key specifies the path to where the Static key is located (replace the IP address with your router's LAN IP); the ./ denotes that you want to copy the contents to the directory you are in at the moment.

If you are using Windows, you can copy files from the router using WinSCP, an Open source freeware SFTP, SCP, and FTP client for Windows OS. Use the same login information with WinSCP as with CLI or SSH. Once you've connected to the router with WinSCP, copying the files should be simple enough: just relocate to the directory where you generated the key, select the Static key file and drag it to a directory on your PC where you would like to store it.

Please note: You must select SCP as File Protocol in WinSCP Session settings.

On a Linux PC


To generate a Static key on a Linux PC, go to the directory where you want the key to appear, right-click anywhere in that directory, and chose the option Open in Terminal. In the Terminal window execute this command:

$ openvpn --genkey --secret static.key

The newly generated key should then appear in the directory you were in.

Configuration


When you have a Static key, you can start configuring OpenVPN Server and Client instances. For this example we will be creating a TUN (Tunnel) type connection that uses the UDP protocol for data transfer and Static key for Authentication. We will be using two RUT routers: RUT1 (Server; LAN IP: 192.168.1.1; WAN (Public static) IP: 213.226.191.61) and RUT2 (Client; LAN IP: 192.168.2.1); the two routers will be connected via OpenVPN; the Server's Virtual IP address will be 10.0.0.1; the Client's - 10.0.0.2:

To sum up, just make sure the Server and the Clients use the same parameters (same authentication, same port, same protocol, etc.). Other important aspects are the Local tunnel endpoint IP and the Remote tunnel endpoint IP. Take note these two particular parameter values are reversed for the individual Client and the Server configurations since these values represent opposite things depending on the instance's perspective.

From the Client side, make sure to enter the correct Remote host/IP address (213.226.191.61 in this case). This is the Server's Public IP address, not the virtual IP address.

TAP (bridged) OpenVPN

This section provides a guide on how to configure a successful OpenVPN TAP (bridged) connection between an OpenVPN Client and Server on RUT routers.

Configuration


TAP is used for creating a network bridge between Ethernet segments in different locations. For this example we will be creating a TAP (bridged) type connection that uses the UDP protocol for data transfer and TLS for Authentication. We will be using two RUT routers: RUT1 (Server; LAN IP: 192.168.1.1; WAN (Public static) IP: 213.226.191.61) and RUT2 (Client; LAN IP: 192.168.1.2); the two routers will be connected via OpenVPN.

To sum up, just make sure the Server and the Clients use the same parameters (same authentication, same port, same protocol, etc.). Since the OpenVPN interface that comes up is bridged with the LAN interface, make sure the routers are in the same subnet (192.168.1.0 in this case). While making sure of that, don't forget that the routers can't have the same IP address, just the same subnet (for example, if both routers have the LAN IP 192.168.1.1, the connection won't work; if one has, for example, 192.168.1.1 and the other 192.168.1.100, then the connection will work).

For this example, we used TLS Authentication. If you want to use a different Authentication method, refer to the relevant section of this article. The authentication configuration will not be different because of the chosen OpenVPN type (TUN or TAP).

From the Client side, make sure to enter the correct Remote host/IP address (213.226.191.61 in this case). This is the Server's Public IP address, not the LAN IP address.

Testing an OpenVPN connection

The most important thing after configuration is making sure that the newly established connection works. You can check the status of an OpenVPN connection on the Status → Network → OpenVPN page:

Server side

Client side

Another method of testing pinging the other instance's virtual or private IP address. You can send ping packets via CLI, SSH, or from the System → Administration → Troubleshoot → Diagnostics section of the router's WebUI:

Ping the Server's virtual/private IP address from the Client or vice versa. If the ping packets are transmitted successfully, congratulations, your OpenVPN connection is working.

Additional configuration

This section will provide examples of some additional OpenVPN-related configurations like how to reach another OpenVPN instance's private LAN or how to use an OpenVPN instance as a Proxy.

Reaching a device's LAN network


You may want your OpenVPN Clients to be able to reach devices that are in the Server device's private network (LAN) or vice versa. This section will provide directions on how to do that.

Server from Client


To reach another OpenVPN instance's LAN network, you have to have a route to that network with the Virtual remote endpoint as the gateway. You can add Static routes via the command line, but these routes are removed automatically when the router reboots or when the connection goes down even if only for a moment. To solve this, you add permanent static routes via the router's WebUI in the Network → Routing → Static Routes page. But this method is also not foolproof since it means that if an address ever changes, you would have to also modify the static route on all related devices.


Another method of reaching the OpenVPN Server's private network from the Client is specifying the network in the OpenVPN Client's configuration. To do so, open the Client's configuration window and fill in these two fields:

As you can see, the two fields in question are Remote network IP address and Remote network IP netmask. The values placed in these fields specify the Server's LAN address and having them filled will automatically add the necessary route into the routing table when the OpenVPN connection goes up. However, if your OpenVPN Server has multiple Clients, you would need to do this for all of them. If that is the case, use this next method.


Even another method is pushing the necessary routes via the OpenVPN Server. This method is the most foolproof because it will generate a route to the Server's private network for all connecting Clients. Therefore, in case of configuration changes you would only have to edit one field in the Server's configuration instead of having to edit all of the Clients' configurations.

To accomplish this, go to OpenVPN Server's configuration window and locate the Push option field. Let's say that the Server's LAN IP address is 192.168.1.1. In this case use the line route 192.168.1.0 255.255.255.0

Modify the information so that it reflects your own configuration. Do not specify the gateway, because the command will not work. The correct gateway will be assigned automatically.

Clients from Server


Reaching OpenVPN Clients' private networks from the Server is a bit trickier than the opposite, because in order to do so the Server has to be aware of the different specific addresses and Common Names of specific Clients.

To accomplish this, we can use the TLS Clients function. TLS Clients is a way to more specifically differentiate Clients by their Common Name (CN) found in the client certificate file. It can be used to assign specific VPN addresses to specific Clients and bind them to their LAN addresses so that other devices in the Client‘s LAN can be reached from the Server.

In other words, TLS Clients binds Common Names (found in Client certificates) to Clients' private networks. If the certificate hasn't been tampered with in any after generation, the Common name should be the same as the file name (without the file type extension). For example, a certificate called client1.crt will likely have the Common Name of client1. But just to be sure you can open the certificate and check:

Once you know the Common Names and LAN IP Addresses of your OpenVPN Clients, you can create TLS Clients instances for each of them: