In this text I will explain what is the I2P network and how to provide a service over I2P on OpenBSD and how to use to connect to an I2P service from NixOS.
This acronym stands for Invisible Internet Project and is a network over the network (Internet). It is quite an old project from 2003 and is considered stable and reliable. The idea of I2P is to build a network of relays (people running an i2p daemon) to make tunnels from a client to a server, but a single TCP session (or UDP) between a client and a server could use many tunnels of n hops across relays. Basically, when you start your I2P service, the program will get some information about the relays available and prepare many tunnels in advance that will be used to reach a destination when you connect.
Some benefits from I2P network:
It is possible to host a website on I2P (by exposing your web server port), it is called an eepsite and can be accessed using the SOCKs proxy provided by your I2P daemon. I never played with them though but this is a thing and you may be interested into looking more in depth.
I2P project and I2P implementation (java) page
i2pd project (a recent C++ implementation that I use for this tutorial)
Obviously, many people would question why not using Tor which seems similar. While I2P can seem very close to Tor hidden services, the implementation is really different. Tor is designed to reach the outside while I2P is meant to build a reliable and anonymous network. When started, Tor creates a path of relays named a Circuit that will remain static for an approximate duration of 12 hours, everything you do over Tor will pass through this circuit (usually 3 relays), on the other hand I2P creates many tunnels all the time with a very low lifespan. Small difference, I2P can relay UDP protocol while Tor only supports TCP.
Tor is very widespread and using a tor hidden service for hosting a private website (if you don't have a public IP or a domain name for example) would be better to reach an audience, I2P is not very well known and that's partially why I'm writing this. It is a fantastic piece of software and only require more users.
Relays in I2P doesn't have any weight and can be seen as a huge P2P network while Tor network is built using scores (consensus) of relaying servers depending of their throughput and availability. Fastest and most reliable relays will be elected as "Guard server" which are entry points to the Tor network.
I've been running a test over 10 hours to compare bandwidth usage of I2P and Tor to keep a tunnel / hidden service available (they have not been used). Please note that relaying/transit were desactivated so it's only the uploaded data in order to keep the service working.
Tor was a lot more bandwidth efficient than I2P for the same task: keeping the network access (tor or i2p) alive.
There are three components in an I2P usage.
- a computer running an I2P daemon configured with tunnels servers (to expose a TCP/UDP port from this machine, not necessarily from localhost though)
- a computer running an I2P daemon configured with tunnel client (with information that match the server tunnel)
- computers running I2P and allowing relay, they will receive data from other I2P daemons and pass the encrypted packets. They are the core of the network.
In this text we will use an OpenBSD system to share its localhost ssh access over I2P and a NixOS client to reach the OpenBSD ssh port.
The setup is quite simple, we will use i2pd and not the i2p java program.
pkg_add i2pd # read /usr/local/share/doc/pkg-readmes/i2pd for open files limits cat <<EOF > /etc/i2pd/tunnels.conf [SSH] type = server port = 22 host = 127.0.0.1 keys = ssh.dat EOF rcctl enable i2pd rcctl start i2pd
You can edit the file /etc/i2pd/i2pd.conf to uncomment the line "notransit = true" if you don't want to relay. I would encourage people to contribute to the network by relaying packets but this would require some explanations about a nice tuning to limit the bandwidth correctly. If you disable transit, you won't participate into the network but I2P won't use any CPU and virtually no data if your tunnel is in use.
Visit http://localhost:7070/ for the admin interface and check the menu "I2P Tunnels", you should see a line "SSH => " with a long address ending by .i2p with :22 added to it. This is the address of your tunnel on I2P, we will need it (without the :22) to configure the client.
As usual, on NixOS we will only configure the /etc/nixos/configuration.nix file to declare the service and its configuration.
We will name the tunnel "ssh-solene" and use the destination seen on the administration interface on the OpenBSD server and expose that port to 127.0.0.1:2222 on our NixOS box.
services.i2pd.enable = true;
services.i2pd.notransit = true;
services.i2pd.outTunnels = {
ssh-solene = {
enable = true;
name = "ssh";
destination = "gajcbkoosoztqklad7kosh226tlt5wr2srr2tm4zbcadulxw2o5a.b32.i2p";
address = "127.0.0.1";
port = 2222;
};
};
Now you can use "nixos-rebuild switch" as root to apply changes.
Note that the equivalent NixOS configuration for any other OS would look like that for any I2P setup in the file "tunnel.conf" (on OpenBSD it would be in /etc/i2pd/tunnels.conf).
[ssh-solene] type = client address = 127.0.0.1 # optional, default is 127.0.0.1 port = 2222 destination = gajcbkoosoztqklad7kosh226tlt5wr2srr2tm4zbcadulxw2o5a.b32.i2p
From the NixOS client you should be able to run "ssh -p 2222 localhost" and get access to the OpenBSD ssh server.
Both systems have a http://localhost:7070/ interface because it's a default setting that is not bad (except if you have multiple people who can access the box).
I2P is a nice way to share services on a reliable and privacy friendly network, it may not be fast but shouldn't drop you when you need it. Because it can easily bypass NAT or dynamic IP it's perfectly fine for a remote system you need to access when you can use NAT or VPN.