f3s: Kubernetes with FreeBSD - Part 5: WireGuard mesh network
Published at 2025-05-11T11:35:57+03:00
This is the fifth blog post about my f3s series for my self-hosting demands in my home lab. f3s? The "f" stands for FreeBSD, and the "3s" stands for k3s, the Kubernetes distribution I will use on FreeBSD-based physical machines.
I will post a new entry every month or so (there are too many other side projects for more frequent updates — I bet you can understand).
These are all the posts so far:
ChatGPT generated logo.
Let's begin...
Table of Contents
- ⇢ f3s: Kubernetes with FreeBSD - Part 5: WireGuard mesh network
- ⇢ ⇢ Introduction
- ⇢ ⇢ ⇢ Expected traffic flow
- ⇢ ⇢ Deciding on WireGuard
- ⇢ ⇢ Base configuration
- ⇢ ⇢ ⇢ FreeBSD
- ⇢ ⇢ ⇢ Rocky Linux
- ⇢ ⇢ ⇢ OpenBSD
- ⇢ ⇢ WireGuard configuration
- ⇢ ⇢ ⇢ Example `wg0.conf`
- ⇢ ⇢ ⇢ NAT traversal and keepalive
- ⇢ ⇢ ⇢ Preshared key
- ⇢ ⇢ Mesh network generator
- ⇢ ⇢ ⇢ `wireguardmeshgenerator.yaml`
- ⇢ ⇢ ⇢ `wireguardmeshgenerator.rb` overview
- ⇢ ⇢ Invoking the mesh network generator
- ⇢ ⇢ ⇢ Generating the `wg0.conf` files and keys
- ⇢ ⇢ ⇢ Installing the `wg0.conf` files
- ⇢ ⇢ ⇢ Re-generating mesh and installing the `wg0.conf` files again
- ⇢ ⇢ Happy WireGuard-ing
- ⇢ ⇢ Conclusion
Introduction
By default, traffic within my home LAN, including traffic inside a k3s cluster, is not encrypted. While it resides in the "secure" home LAN, adopting a zero-trust policy means encryption is still preferable to ensure confidentiality and security. So we decide to secure all the traffic of all f3s participating hosts by building a mesh network of all participating hosts:
Whereas `f0`, `f1`, and `f2` are the FreeBSD base hosts, `r0`, `r1`, and `r2` are the Rocky Linux Bhyve VMs, and `blowfish` and `fishfinger` are two OpenBSD systems running on the internet (as mentioned in the first blog of this series—these systems are already built; in fact, this very blog is served by those OpenBSD systems).
As we can see from the graph, it is a true full-mesh network, where every host has a VPN tunnel to every other host. The benefit is that we do not need to route traffic through intermediate hosts (significantly simplifying the routing configuration). However, the downside is that there is some overhead in configuring and managing all the tunnels.
For simplicity, we also establish VPN tunnels between `f0 <-> r0`, `f1 <-> r1`, and `f2 <-> r2`. Technically, this wouldn't be strictly required since the VMs `rN` are running on the hosts `fN`, and no network traffic is leaving the box. However, it simplifies the configuration as we don't have to account for exceptions, and we are going to automate the mesh network configuration anyway (read on).
Expected traffic flow
The traffic is expected to flow between the host groups through the mesh network as follows:
- `fN <-> rN`: The traffic between the FreeBSD hosts and the Rocky Linux VMs will be routed through the VPN tunnels for persistent storage. In a later post in this series, we will set up an NFS server on the `fN` hosts.
- `fN <-> blowfish,fishfinger`: The traffic between the FreeBSD hosts and the OpenBSD host `blowfish,fishfinger` will be routed through the VPN tunnels for management. We may want to log in via the internet to set it up remotely. The VPN tunnel will also be used for monitoring purposes.
- `rN <-> blowfish,fishfinger`: The traffic between the Rocky Linux VMs and the OpenBSD host `blowfish,fishfinger` will be routed through the VPN tunnels for usage traffic. Since k3s will be running on the `rN` hosts, the OpenBSD servers will route the traffic through `relayd` to the services running in Kubernetes.
- `fN <-> fM`: The traffic between the FreeBSD hosts may be later used for data replication for the NFS storage.
- `rN <-> rM`: The traffic between the Rocky Linux VMs will later be used by the k3s cluster itself, as every `rN` will be a Kubernetes worker node.
- `blowfish <-> fishfinger`: The traffic between the OpenBSD hosts isn't strictly required for this setup, but I set it up anyway for future use cases.
We won't cover all the details in this blog post, as we only focus on setting up the Mesh network in this blog post. Subsequent posts in this series will cover the other details.
Deciding on WireGuard
I have decided to use WireGuard as the VPN technology for this purpose.
WireGuard is a lightweight, modern, and secure VPN protocol designed for simplicity, speed, and strong cryptography. It is an excellent choice due to its minimal codebase, ease of configuration, high performance, and robust security, utilizing state-of-the-art encryption standards. WireGuard is supported on various operating systems, and its implementations are compatible with each other. Therefore, establishing WireGuard VPN tunnels between FreeBSD, Linux, and OpenBSD is seamless. This cross-platform availability makes it suitable for setups like the one described in this blog series.
We could have used Tailscale for an easy to set up and manage the WireGuard network, but the benefits of creating our own mesh network are:
- Learning about WireGuard configuration details
- Have full control over the setup
- Don't rely on an external provider like Tailscale (even if some of the components are open-source)
- Have even more fun along the way
- WireGuard is easy to configure on my target operating systems and, therefore, easier to maintain in the long run.
- There are no official Tailscale packages available for OpenBSD and FreeBSD. However, getting Tailscale running on these systems is still possible, though some tinkering would be required. Instead, we use that tinkering time to set up WireGuard tunnels ourselves.
Base configuration
In the following, we prepare the base configuration for the WireGuard mesh network. We will use a similar configuration on all participating hosts, with the exception of the host IP addresses and the private keys.
FreeBSD
On the FreeBSD hosts `f0`, `f1` and `f2`, similar as last time, first, we bring the system up to date:
paul@f0:~ % doas freebsd-update fetch paul@f0:~ % doas freebsd-update install paul@f0:~ % doas shutdown -r now .. .. paul@f0:~ % doas pkg update paul@f0:~ % doas pkg upgrade paul@f0:~ % reboot
Next, we install `wireguard-tools` and configure the WireGuard service:
paul@f0:~ % doas pkg install wireguard-tools paul@f0:~ % doas sysrc wireguard_interfaces=wg0 wireguard_interfaces: -> wg0 paul@f0:~ % doas sysrc wireguard_enable=YES wireguard_enable: -> YES paul@f0:~ % doas mkdir -p /usr/local/etc/wireguard paul@f0:~ % doas touch /usr/local/etc/wireguard/wg0.conf paul@f0:~ % doas service wireguard start paul@f0:~ % doas wg show interface: wg0 public key: L+V9o0fNYkMVKNqsX7spBzD/9oSvxM/C7ZCZX1jLO3Q= private key: (hidden) listening port: 20246
We now have the WireGuard up and running, but it is not yet in any functional configuration. We will come back to that later.
Next, we add all the participating WireGuard IPs to the `hosts` file. This is only convenience, so we don't have to manage an external DNS server for this:
paul@f0:~ % cat <As you can see, `192.168.1.0/24` is the network used in my LAN (with the `fN` and `rN` hosts) and `192.168.2.0/24` is the network used for the WireGuard mesh network. The `wg0` interface will be used for all WireGuard traffic.
Rocky Linux
We bring the Rocky Linux VMs up to date as well with the following:
[root@r0 ~] dnf update -y [root@r0 ~] rebootNext, we prepare WireGuard on them. Same as on the FreeBSD hosts, we will only prepare WireGuard without any useful configuration yet:
[root@r0 ~] dnf install -y wireguard-tools [root@r0 ~] mkdir -p /etc/wireguard [root@r0 ~] touch /etc/wireguard/wg0.conf [root@r0 ~] systemctl enable wg-quick@wg0.service [root@r0 ~] systemctl start wg-quick@wg0.service [root@r0 ~] systemctl disable firewalldWe also update the `hosts` file accordingly:
[root@r0 ~] cat <>/etc/hosts 192.168.1.130 f0 f0.lan f0.lan.buetow.org 192.168.1.131 f1 f1.lan f1.lan.buetow.org 192.168.1.132 f2 f2.lan f2.lan.buetow.org 192.168.2.130 f0.wg0 f0.wg0.wan.buetow.org 192.168.2.131 f1.wg0 f1.wg0.wan.buetow.org 192.168.2.132 f2.wg0 f2.wg0.wan.buetow.org 192.168.2.120 r0.wg0 r0.wg0.wan.buetow.org 192.168.2.121 r1.wg0 r1.wg0.wan.buetow.org 192.168.2.122 r2.wg0 r2.wg0.wan.buetow.org 192.168.2.110 blowfish.wg0 blowfish.wg0.wan.buetow.org 192.168.2.111 fishfinger.wg0 fishfinger.wg0.wan.buetow.org END Unfortunately, the SELinux policy on Rocky Linux blocks WireGuard's operation. By making the `wireguard_t` domain permissive using `semanage permissive -a wireguard_t`, SELinux will no longer enforce restrictions for WireGuard, allowing it to work as intended:
[root@r0 ~] dnf install -y policycoreutils-python-utils [root@r0 ~] semanage permissive -a wireguard_t [root@r0 ~] rebootOpenBSD
Other than the FreeBSD and Rocky Linux hosts involved, my OpenBSD hosts (`blowfish` and `fishfinger`, which are running at OpenBSD Amsterdam and Hetzner on the internet) have been running already for longer, so I can't provide you with the "from scratch" installation details here. In the following, we will only focus on the additional configuration needed to set up WireGuard:
blowfish$ doas pkg_add wireguard-tools blowfish$ doas mkdir /etc/wireguard blowfish$ doas touch /etc/wireguard/wg0.conf blowsish$ cat <Note that on `blowfish`, we configure `192.168.2.110` here in the `hostname.wg`, and on `fishfinger`, we configure `192.168.2.111`. Those are the IP addresses of the WireGuard interfaces on those hosts.
And here, we also update the `hosts` file accordingly:
blowfish$ cat <WireGuard configuration
So far, we have only started WireGuard on all participating hosts without any useful configuration. This means that no VPN tunnel has been established yet between any of the hosts.
Example `wg0.conf`
Generally speaking, a `wg0.conf` looks like this (example from `f0` host):
[Interface] # f0.wg0.wan.buetow.org Address = 192.168.2.130 PrivateKey = ************************** ListenPort = 56709 [Peer] # f1.lan.buetow.org as f1.wg0.wan.buetow.org PublicKey = ************************** PresharedKey = ************************** AllowedIPs = 192.168.2.131/32 Endpoint = 192.168.1.131:56709 # No KeepAlive configured [Peer] # f2.lan.buetow.org as f2.wg0.wan.buetow.org PublicKey = ************************** PresharedKey = ************************** AllowedIPs = 192.168.2.132/32 Endpoint = 192.168.1.132:56709 # No KeepAlive configured [Peer] # r0.lan.buetow.org as r0.wg0.wan.buetow.org PublicKey = ************************** PresharedKey = ************************** AllowedIPs = 192.168.2.120/32 Endpoint = 192.168.1.120:56709 # No KeepAlive configured [Peer] # r1.lan.buetow.org as r1.wg0.wan.buetow.org PublicKey = ************************** PresharedKey = ************************** AllowedIPs = 192.168.2.121/32 Endpoint = 192.168.1.121:56709 # No KeepAlive configured [Peer] # r2.lan.buetow.org as r2.wg0.wan.buetow.org PublicKey = ************************** PresharedKey = ************************** AllowedIPs = 192.168.2.122/32 Endpoint = 192.168.1.122:56709 # No KeepAlive configured [Peer] # blowfish.buetow.org as blowfish.wg0.wan.buetow.org PublicKey = ************************** PresharedKey = ************************** AllowedIPs = 192.168.2.110/32 Endpoint = 23.88.35.144:56709 PersistentKeepalive = 25 [Peer] # fishfinger.buetow.org as fishfinger.wg0.wan.buetow.org PublicKey = ************************** PresharedKey = ************************** AllowedIPs = 192.168.2.111/32 Endpoint = 46.23.94.99:56709 PersistentKeepalive = 25Whereas there are two main sections. One is `[Interface]`, which configures the current host (here: `f0`):
- `Address`: Local virtual IP address on the WireGuard interface.
- `PrivateKey`: Private key for this node.
- `ListenPort`: Port on which this WireGuard interface listens for incoming connections.
And in the following, there is one `[Peer]` section for every peer node on the mesh network:
- `PublicKey`: The public key of the remote peer is used to authenticate their identity.
- `PresharedKey`: An optional symmetric key is used to enhance security (used in addition to PublicKey).
- `AllowedIPs`: IPs or subnets routed through this peer (traffic is allowed to/from these IPs).
- `Endpoint`: The public IP:port combination of the remote peer for connection.
- `PersistentKeepalive`: Keeps the tunnel alive by sending periodic packets; used for NAT traversal.
NAT traversal and keepalive
As all participating hosts, except for `blowfish` and `fishfinger` (which are on the internet), are behind a NAT gateway (my home router), we need to use `PersistentKeepalive` to establish and maintain the VPN tunnel from the LAN to the internet because:
By default, WireGuard tries to be as silent as possible when not being used; it is not a chatty protocol. For the most part, it only transmits data when a peer wishes to send packets. When it's not being asked to send packets, it stops sending packets until it is asked again. In the majority of configurations, this works well. However, when a peer is behind NAT or a firewall, it might wish to be able to receive incoming packets even when it is not sending any packets. Because NAT and stateful firewalls keep track of "connections", if a peer behind NAT or a firewall wishes to receive incoming packets, he must keep the NAT/firewall mapping valid, by periodically sending keepalive packets. This is called persistent keepalives. When this option is enabled, a keepalive packet is sent to the server endpoint once every interval seconds. A sensible interval that works with a wide variety of firewalls is 25 seconds. Setting it to 0 turns the feature off, which is the default, since most users will not need this, and it makes WireGuard slightly more chatty. This feature may be specified by adding the PersistentKeepalive = field to a peer in the configuration file, or setting persistent-keepalive at the command line. If you don't need this feature, don't enable it. But if you're behind NAT or a firewall and you want to receive incoming connections long after network traffic has gone silent, this option will keep the "connection" open in the eyes of NAT.That's why you see `PersistentKeepAlive = 25` in the `blowfish` and `fishfinger` peer configurations. This means that every 25 seconds, a keep-alive signal is sent over the tunnel to maintain its connection. If the tunnel is not yet established, it will be created within 25 seconds latest.
Without this, we might never have a VPN tunnel open, as the systems in the LAN may not actively attempt to contact `blowfish` and `fishfinger` on their own. In fact, the opposite would likely occur, with the traffic flowing inward instead of outward (this is beyond the scope of this blog post but will be covered in a later post in this series!).
Preshared key
In a WireGuard configuration, the PSK (preshared key) is an optional additional layer of symmetric encryption used alongside the standard public key cryptography. It is a shared secret known to both peers that enhances security by requiring an attacker to compromise both the private keys and the PSK to decrypt communication. While optional, using a PSK is better as it strengthens the cryptographic security, mitigating risks of potential vulnerabilities in the key exchange process.
So, because it's better, we are using it.
Mesh network generator
Manually generating `wg0.conf` files for every peer in a mesh network setup is cumbersome because each peer requires its own unique public/private key pair and a preshared key for each VPN tunnel (resulting in 29 preshared keys for 8 hosts). This complexity scales almost exponentially with the number of peers as the relationships between all peers must be explicitly defined, including their unique configurations such as `AllowedIPs` and `Endpoint` and optional settings like `PersistentKeepalive`. Automating the process ensures consistency, reduces human error, saves considerable time, and allows for centralized management of configuration files.
Instead, a script can handle key generation, coordinate relationships, and generate all necessary configuration files simultaneously, making it scalable and far less error-prone.
I have written a Ruby script `wireguardmeshgenerator.rb` to do this for our purposes:
I use Fedora Linux as my main driver on my personal Laptop, so the script was developed and tested only on Fedora Linux. However, it should also work on other Linux and Unix-like systems.
To set up the mesh generator on Fedora Linux, we run the following:
> git clone https://codeberg.org/snonux/wireguardmeshgenerator > cd ./wireguardmeshgenerator > bundle install > sudo dnf install -y wireguard-toolsThis assumes that Ruby and the `bundler` gem are already installed. If not, refer to the docs of your distribution.
`wireguardmeshgenerator.yaml`
The file `wireguardmeshgenerator.yaml` configures the mesh generator script.
--- hosts: f0: os: FreeBSD ssh: user: paul conf_dir: /usr/local/etc/wireguard sudo_cmd: doas reload_cmd: service wireguard reload lan: domain: 'lan.buetow.org' ip: '192.168.1.130' wg0: domain: 'wg0.wan.buetow.org' ip: '192.168.2.130' f1: os: FreeBSD ssh: user: paul conf_dir: /usr/local/etc/wireguard sudo_cmd: doas reload_cmd: service wireguard reload lan: domain: 'lan.buetow.org' ip: '192.168.1.131' wg0: domain: 'wg0.wan.buetow.org' ip: '192.168.2.131' f2: os: FreeBSD ssh: user: paul conf_dir: /usr/local/etc/wireguard sudo_cmd: doas reload_cmd: service wireguard reload lan: domain: 'lan.buetow.org' ip: '192.168.1.132' wg0: domain: 'wg0.wan.buetow.org' ip: '192.168.2.132' r0: os: Linux ssh: user: root conf_dir: /etc/wireguard sudo_cmd: reload_cmd: systemctl reload wg-quick@wg0.service lan: domain: 'lan.buetow.org' ip: '192.168.1.120' wg0: domain: 'wg0.wan.buetow.org' ip: '192.168.2.120' r1: os: Linux ssh: user: root conf_dir: /etc/wireguard sudo_cmd: reload_cmd: systemctl reload wg-quick@wg0.service lan: domain: 'lan.buetow.org' ip: '192.168.1.121' wg0: domain: 'wg0.wan.buetow.org' ip: '192.168.2.121' r2: os: Linux ssh: user: root conf_dir: /etc/wireguard sudo_cmd: reload_cmd: systemctl reload wg-quick@wg0.service lan: domain: 'lan.buetow.org' ip: '192.168.1.122' wg0: domain: 'wg0.wan.buetow.org' ip: '192.168.2.122' blowfish: os: OpenBSD ssh: user: rex conf_dir: /etc/wireguard sudo_cmd: doas reload_cmd: sh /etc/netstart wg0 internet: domain: 'buetow.org' ip: '23.88.35.144' wg0: domain: 'wg0.wan.buetow.org' ip: '192.168.2.110' fishfinger: os: OpenBSD ssh: user: rex conf_dir: /etc/wireguard sudo_cmd: doas reload_cmd: sh /etc/netstart wg0 internet: domain: 'buetow.org' ip: '46.23.94.99' wg0: domain: 'wg0.wan.buetow.org' ip: '192.168.2.111'The file specifies details such as SSH user settings, configuration directories, sudo or reload commands, and IP/domain assignments for both internal LAN-facing interfaces and WireGuard (`wg0`) interfaces. Each host is assigned specific roles, including internal participants and publicly accessible nodes with internet-facing IPs, enabling the creation of a fully connected mesh VPN.
`wireguardmeshgenerator.rb` overview
The `wireguardmeshgenerator.rb` script consists of the following base classes:
- `KeyTool`: Manages WireGuard key generation and retrieval. It ensures the presence of public/private key pairs and preshared keys (PSKs). If keys are missing, it generates them using the `wg` tool. It provides methods to read the public/private keys and retrieve or generate a PSK for communication with a peer. The keys are stored in a temp directory on the system from where the generator is run.
- `PeerSnippet`: A `Struct` representing the configuration for a single WireGuard peer in the mesh. Based on the provided attributes and configuration, it generates the peer's WireGuard configuration, including public key, PSK, allowed IPs, endpoint, and keepalive settings.
- `WireguardConfig`: This function generates WireGuard configuration files for the specified host in the mesh network. It includes the `[Interface]` section for the host itself and the `[Peer]` sections for all other peers. It can also clean up generated files and directories and create the required directory structure for storing configuration files locally on the system from which the script is run.
- `InstallConfig`: Handles uploading, installing, and restarting the WireGuard service on remote hosts using SSH and SCP. It ensures the configuration file is uploaded to the remote machine, the necessary directories are present and correctly configured, and the WireGuard service reloads with the new configuration.
At the end (if you want to see the code for the stuff listed above, go to the Git repo and have a look), we glue it all together in this block:
begin options = { hosts: [] } OptionParser.new do |opts| opts.banner = 'Usage: wireguardmeshgenerator.rb [options]' opts.on('--generate', 'Generate Wireguard configs') do options[:generate] = true end opts.on('--install', 'Install Wireguard configs') do options[:install] = true end opts.on('--clean', 'Clean Wireguard configs') do options[:clean] = true end opts.on('--hosts=HOSTS', 'Comma separated hosts to configure') do |hosts| options[:hosts] = hosts.split(',') end end.parse! conf = YAML.load_file('wireguardmeshgenerator.yaml').freeze conf['hosts'].keys.select { options[:hosts].empty? || options[:hosts].include?(_1) } .each do |host| # Generate Wireguard configuration for the host reload! WireguardConfig.new(host, conf['hosts']).generate! if options[:generate] # Install Wireguard configuration for the host. InstallConfig.new(host, conf['hosts']).upload!.install!.reload! if options[:install] # Clean Wireguard configuration for the host. WireguardConfig.new(host, conf['hosts']).clean! if options[:clean] end rescue StandardError => e puts "Error: #{e.message}" puts e.backtrace.join("\n") exit 2 endAnd we also have a `Rakefile`:
task :generate do ruby 'wireguardmeshgenerator.rb', '--generate' end task :clean do ruby 'wireguardmeshgenerator.rb', '--clean' end task :install do ruby 'wireguardmeshgenerator.rb', '--install' end task default: :generateInvoking the mesh network generator
Generating the `wg0.conf` files and keys
To generate everything (the `wg0.conf` of all participating hosts, including all keys involved), we run the following:
> rake generate /usr/bin/ruby wireguardmeshgenerator.rb --generate Generating dist/f0/etc/wireguard/wg0.conf Generating dist/f1/etc/wireguard/wg0.conf Generating dist/f2/etc/wireguard/wg0.conf Generating dist/r0/etc/wireguard/wg0.conf Generating dist/r1/etc/wireguard/wg0.conf Generating dist/r2/etc/wireguard/wg0.conf Generating dist/blowfish/etc/wireguard/wg0.conf Generating dist/fishfinger/etc/wireguard/wg0.confIt generated all the `wg0.conf` files listed in the output, plus those keys:
> find keys/ -type f keys/f0/priv.key keys/f0/pub.key keys/psk/f0_f1.key keys/psk/f0_f2.key keys/psk/f0_r0.key keys/psk/f0_r1.key keys/psk/f0_r2.key keys/psk/blowfish_f0.key keys/psk/f0_fishfinger.key keys/psk/f1_f2.key keys/psk/f1_r0.key keys/psk/f1_r1.key keys/psk/f1_r2.key keys/psk/blowfish_f1.key keys/psk/f1_fishfinger.key keys/psk/f2_r0.key keys/psk/f2_r1.key keys/psk/f2_r2.key keys/psk/blowfish_f2.key keys/psk/f2_fishfinger.key keys/psk/r0_r1.key keys/psk/r0_r2.key keys/psk/blowfish_r0.key keys/psk/fishfinger_r0.key keys/psk/r1_r2.key keys/psk/blowfish_r1.key keys/psk/fishfinger_r1.key keys/psk/blowfish_r2.key keys/psk/fishfinger_r2.key keys/psk/blowfish_fishfinger.key keys/f1/priv.key keys/f1/pub.key keys/f2/priv.key keys/f2/pub.key keys/r0/priv.key keys/r0/pub.key keys/r1/priv.key keys/r1/pub.key keys/r2/priv.key keys/r2/pub.key keys/blowfish/priv.key keys/blowfish/pub.key keys/fishfinger/priv.key keys/fishfinger/pub.keyThose keys are embedded in the resulting `wg0.conf`, so later, we only need to install the `wg0.conf` files and not all the keys individually.
Installing the `wg0.conf` files
Uploading the `wg0.conf` files to the participating hosts and reloading WireGuard on them is then just a matter of executing (this expects, that all participating hosts are up and running):
> rake install /usr/bin/ruby wireguardmeshgenerator.rb --install Uploading dist/f0/etc/wireguard/wg0.conf to f0.lan.buetow.org:. Installing Wireguard config on f0 Uploading cmd.sh to f0.lan.buetow.org:. + [ ! -d /usr/local/etc/wireguard ] + doas chmod 700 /usr/local/etc/wireguard + doas mv -v wg0.conf /usr/local/etc/wireguard wg0.conf -> /usr/local/etc/wireguard/wg0.conf + doas chmod 644 /usr/local/etc/wireguard/wg0.conf + rm cmd.sh Reloading Wireguard on f0 Uploading cmd.sh to f0.lan.buetow.org:. + doas service wireguard reload + rm cmd.sh Uploading dist/f1/etc/wireguard/wg0.conf to f1.lan.buetow.org:. Installing Wireguard config on f1 Uploading cmd.sh to f1.lan.buetow.org:. + [ ! -d /usr/local/etc/wireguard ] + doas chmod 700 /usr/local/etc/wireguard + doas mv -v wg0.conf /usr/local/etc/wireguard wg0.conf -> /usr/local/etc/wireguard/wg0.conf + doas chmod 644 /usr/local/etc/wireguard/wg0.conf + rm cmd.sh Reloading Wireguard on f1 Uploading cmd.sh to f1.lan.buetow.org:. + doas service wireguard reload + rm cmd.sh Uploading dist/f2/etc/wireguard/wg0.conf to f2.lan.buetow.org:. Installing Wireguard config on f2 Uploading cmd.sh to f2.lan.buetow.org:. + [ ! -d /usr/local/etc/wireguard ] + doas chmod 700 /usr/local/etc/wireguard + doas mv -v wg0.conf /usr/local/etc/wireguard wg0.conf -> /usr/local/etc/wireguard/wg0.conf + doas chmod 644 /usr/local/etc/wireguard/wg0.conf + rm cmd.sh Reloading Wireguard on f2 Uploading cmd.sh to f2.lan.buetow.org:. + doas service wireguard reload + rm cmd.sh Uploading dist/r0/etc/wireguard/wg0.conf to r0.lan.buetow.org:. Installing Wireguard config on r0 Uploading cmd.sh to r0.lan.buetow.org:. + '[' '!' -d /etc/wireguard ']' + chmod 700 /etc/wireguard + mv -v wg0.conf /etc/wireguard renamed 'wg0.conf' -> '/etc/wireguard/wg0.conf' + chmod 644 /etc/wireguard/wg0.conf + rm cmd.sh Reloading Wireguard on r0 Uploading cmd.sh to r0.lan.buetow.org:. + systemctl reload wg-quick@wg0.service + rm cmd.sh Uploading dist/r1/etc/wireguard/wg0.conf to r1.lan.buetow.org:. Installing Wireguard config on r1 Uploading cmd.sh to r1.lan.buetow.org:. + '[' '!' -d /etc/wireguard ']' + chmod 700 /etc/wireguard + mv -v wg0.conf /etc/wireguard renamed 'wg0.conf' -> '/etc/wireguard/wg0.conf' + chmod 644 /etc/wireguard/wg0.conf + rm cmd.sh Reloading Wireguard on r1 Uploading cmd.sh to r1.lan.buetow.org:. + systemctl reload wg-quick@wg0.service + rm cmd.sh Uploading dist/r2/etc/wireguard/wg0.conf to r2.lan.buetow.org:. Installing Wireguard config on r2 Uploading cmd.sh to r2.lan.buetow.org:. + '[' '!' -d /etc/wireguard ']' + chmod 700 /etc/wireguard + mv -v wg0.conf /etc/wireguard renamed 'wg0.conf' -> '/etc/wireguard/wg0.conf' + chmod 644 /etc/wireguard/wg0.conf + rm cmd.sh Reloading Wireguard on r2 Uploading cmd.sh to r2.lan.buetow.org:. + systemctl reload wg-quick@wg0.service + rm cmd.sh Uploading dist/blowfish/etc/wireguard/wg0.conf to blowfish.buetow.org:. Installing Wireguard config on blowfish Uploading cmd.sh to blowfish.buetow.org:. + [ ! -d /etc/wireguard ] + doas chmod 700 /etc/wireguard + doas mv -v wg0.conf /etc/wireguard wg0.conf -> /etc/wireguard/wg0.conf + doas chmod 644 /etc/wireguard/wg0.conf + rm cmd.sh Reloading Wireguard on blowfish Uploading cmd.sh to blowfish.buetow.org:. + doas sh /etc/netstart wg0 + rm cmd.sh Uploading dist/fishfinger/etc/wireguard/wg0.conf to fishfinger.buetow.org:. Installing Wireguard config on fishfinger Uploading cmd.sh to fishfinger.buetow.org:. + [ ! -d /etc/wireguard ] + doas chmod 700 /etc/wireguard + doas mv -v wg0.conf /etc/wireguard wg0.conf -> /etc/wireguard/wg0.conf + doas chmod 644 /etc/wireguard/wg0.conf + rm cmd.sh Reloading Wireguard on fishfinger Uploading cmd.sh to fishfinger.buetow.org:. + doas sh /etc/netstart wg0 + rm cmd.shRe-generating mesh and installing the `wg0.conf` files again
The mesh network can be re-generated and re-installed as follows:
> rake clean > rake generate > rake installThat would also delete and re-generate all the keys involved.
Happy WireGuard-ing
All is set up now. E.g. on `f0`:
paul@f0:~ % doas wg show interface: wg0 public key: Jm6YItMt94++dIeOyVi1I9AhNt2qQcryxCZezoX7X2Y= private key: (hidden) listening port: 56709 peer: 8PvGZH1NohHpZPVJyjhctBX9xblsNvYBhpg68FsFcns= preshared key: (hidden) endpoint: 46.23.94.99:56709 allowed ips: 192.168.2.111/32 latest handshake: 1 minute, 46 seconds ago transfer: 124 B received, 1.75 KiB sent persistent keepalive: every 25 seconds peer: Xow+d3qVXgUMk4pcRSQ6Fe+vhYBa3VDyHX/4jrGoKns= preshared key: (hidden) endpoint: 23.88.35.144:56709 allowed ips: 192.168.2.110/32 latest handshake: 1 minute, 52 seconds ago transfer: 124 B received, 1.60 KiB sent persistent keepalive: every 25 seconds peer: s3e93XoY7dPUQgLiVO4d8x/SRCFgEew+/wP7+zwgehI= preshared key: (hidden) endpoint: 192.168.1.120:56709 allowed ips: 192.168.2.120/32 peer: 2htXdNcxzpI2FdPDJy4T4VGtm1wpMEQu1AkQHjNY6F8= preshared key: (hidden) endpoint: 192.168.1.131:56709 allowed ips: 192.168.2.131/32 peer: 0Y/H20W8YIbF7DA1sMwMacLI8WS9yG+1/QO7m2oyllg= preshared key: (hidden) endpoint: 192.168.1.122:56709 allowed ips: 192.168.2.122/32 peer: Hhy9kMPOOjChXV2RA5WeCGs+J0FE3rcNPDw/TLSn7i8= preshared key: (hidden) endpoint: 192.168.1.121:56709 allowed ips: 192.168.2.121/32 peer: SlGVsACE1wiaRoGvCR3f7AuHfRS+1jjhS+YwEJ2HvF0= preshared key: (hidden) endpoint: 192.168.1.132:56709 allowed ips: 192.168.2.132/32All the hosts are pingable as well, e.g.:
paul@f0:~ % foreach peer ( f1 f2 r0 r1 r2 blowfish fishfinger ) foreach? ping -c2 $peer.wg0 foreach? echo foreach? end PING f1.wg0 (192.168.2.131): 56 data bytes 64 bytes from 192.168.2.131: icmp_seq=0 ttl=64 time=0.334 ms 64 bytes from 192.168.2.131: icmp_seq=1 ttl=64 time=0.260 ms --- f1.wg0 ping statistics --- 2 packets transmitted, 2 packets received, 0.0% packet loss round-trip min/avg/max/stddev = 0.260/0.297/0.334/0.037 ms PING f2.wg0 (192.168.2.132): 56 data bytes 64 bytes from 192.168.2.132: icmp_seq=0 ttl=64 time=0.323 ms 64 bytes from 192.168.2.132: icmp_seq=1 ttl=64 time=0.303 ms --- f2.wg0 ping statistics --- 2 packets transmitted, 2 packets received, 0.0% packet loss round-trip min/avg/max/stddev = 0.303/0.313/0.323/0.010 ms PING r0.wg0 (192.168.2.120): 56 data bytes 64 bytes from 192.168.2.120: icmp_seq=0 ttl=64 time=0.716 ms 64 bytes from 192.168.2.120: icmp_seq=1 ttl=64 time=0.406 ms --- r0.wg0 ping statistics --- 2 packets transmitted, 2 packets received, 0.0% packet loss round-trip min/avg/max/stddev = 0.406/0.561/0.716/0.155 ms PING r1.wg0 (192.168.2.121): 56 data bytes 64 bytes from 192.168.2.121: icmp_seq=0 ttl=64 time=0.639 ms 64 bytes from 192.168.2.121: icmp_seq=1 ttl=64 time=0.629 ms --- r1.wg0 ping statistics --- 2 packets transmitted, 2 packets received, 0.0% packet loss round-trip min/avg/max/stddev = 0.629/0.634/0.639/0.005 ms PING r2.wg0 (192.168.2.122): 56 data bytes 64 bytes from 192.168.2.122: icmp_seq=0 ttl=64 time=0.569 ms 64 bytes from 192.168.2.122: icmp_seq=1 ttl=64 time=0.479 ms --- r2.wg0 ping statistics --- 2 packets transmitted, 2 packets received, 0.0% packet loss round-trip min/avg/max/stddev = 0.479/0.524/0.569/0.045 ms PING blowfish.wg0 (192.168.2.110): 56 data bytes 64 bytes from 192.168.2.110: icmp_seq=0 ttl=255 time=35.745 ms 64 bytes from 192.168.2.110: icmp_seq=1 ttl=255 time=35.481 ms --- blowfish.wg0 ping statistics --- 2 packets transmitted, 2 packets received, 0.0% packet loss round-trip min/avg/max/stddev = 35.481/35.613/35.745/0.132 ms PING fishfinger.wg0 (192.168.2.111): 56 data bytes 64 bytes from 192.168.2.111: icmp_seq=0 ttl=255 time=33.992 ms 64 bytes from 192.168.2.111: icmp_seq=1 ttl=255 time=33.751 ms --- fishfinger.wg0 ping statistics --- 2 packets transmitted, 2 packets received, 0.0% packet loss round-trip min/avg/max/stddev = 33.751/33.872/33.992/0.120 msNote that the loop above is a `tcsh` loop, the default shell used in FreeBSD. Of course, all other peers can ping their peers as well!
After the first ping, VPN tunnels now also show handshakes and the amount of data transferred through them:
paul@f0:~ % doas wg show interface: wg0 public key: Jm6YItMt94++dIeOyVi1I9AhNt2qQcryxCZezoX7X2Y= private key: (hidden) listening port: 56709 peer: 0Y/H20W8YIbF7DA1sMwMacLI8WS9yG+1/QO7m2oyllg= preshared key: (hidden) endpoint: 192.168.1.122:56709 allowed ips: 192.168.2.122/32 latest handshake: 10 seconds ago transfer: 440 B received, 532 B sent peer: Hhy9kMPOOjChXV2RA5WeCGs+J0FE3rcNPDw/TLSn7i8= preshared key: (hidden) endpoint: 192.168.1.121:56709 allowed ips: 192.168.2.121/32 latest handshake: 12 seconds ago transfer: 440 B received, 564 B sent peer: s3e93XoY7dPUQgLiVO4d8x/SRCFgEew+/wP7+zwgehI= preshared key: (hidden) endpoint: 192.168.1.120:56709 allowed ips: 192.168.2.120/32 latest handshake: 14 seconds ago transfer: 440 B received, 564 B sent peer: SlGVsACE1wiaRoGvCR3f7AuHfRS+1jjhS+YwEJ2HvF0= preshared key: (hidden) endpoint: 192.168.1.132:56709 allowed ips: 192.168.2.132/32 latest handshake: 17 seconds ago transfer: 472 B received, 564 B sent peer: Xow+d3qVXgUMk4pcRSQ6Fe+vhYBa3VDyHX/4jrGoKns= preshared key: (hidden) endpoint: 23.88.35.144:56709 allowed ips: 192.168.2.110/32 latest handshake: 55 seconds ago transfer: 472 B received, 596 B sent persistent keepalive: every 25 seconds peer: 8PvGZH1NohHpZPVJyjhctBX9xblsNvYBhpg68FsFcns= preshared key: (hidden) endpoint: 46.23.94.99:56709 allowed ips: 192.168.2.111/32 latest handshake: 55 seconds ago transfer: 472 B received, 596 B sent persistent keepalive: every 25 seconds peer: 2htXdNcxzpI2FdPDJy4T4VGtm1wpMEQu1AkQHjNY6F8= preshared key: (hidden) endpoint: 192.168.1.131:56709 allowed ips: 192.168.2.131/32Conclusion
Having a mesh network on our hosts is great for securing all the traffic between them for our future k3s setup. A self-managed WireGuard mesh network is better than Tailscale as it eliminates reliance on a third party and provides full control over the configuration. It reduces unnecessary abstraction and "magic," enabling easier debugging and ensuring full ownership of our network.
Read the next post of this series:
Other *BSD-related posts:
E-Mail your comments to `paul@nospam.buetow.org`