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Add a lesson on configuring Zebra and STATIC
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* [Introduction to Route 0](introduction-to-route-0.md)
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* [Introduction to Route 0](introduction-to-route-0.md)
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* [IP Addresses and Subnets](ip-addresses-and-subnets.md)
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* [IP Addresses and Subnets](ip-addresses-and-subnets.md)
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* [Configuring Zebra and STATIC](configuring-zebra-and-static.md)
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lessons/configuring-zebra-and-static.md
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lessons/configuring-zebra-and-static.md
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# Configuring Zebra and STATIC
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The difference between the `plain` and `basic` scenarios is that the latter
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configures interface addresses and default routes on hosts. In [another
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lesson](ip-addresses-and-subnet.md) we used basic Linux commands to build a
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`basic` network on top of a `plain` scenario. However, `route0` does not
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implement the `basic` scenario using Linux shell commands. Instead, it uses
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the FRR daemons [Zebra](http://docs.frrouting.org/en/latest/zebra.html) and
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[STATIC](http://docs.frrouting.org/en/latest/static.html).
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This lesson goes over how to configure Zebra and STATIC to achieve the
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connectivity of a `basic` scenario on the [`one_rtr`
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topology](../topology/one_rtr). This is a good way to introduce the basic
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usage and configuration of FRR.
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If you are only interested in networking concepts and are not interested
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learning how to configure FRR daemons you may skip this lesson.
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Before you continue with the lesson you may find it useful to read the brief
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section on [system architecture on the FRR
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website](http://docs.frrouting.org/en/latest/overview.html#system-architecture).
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## Starting the daemons
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Before we start the network we need to actually create a basic configuration
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file that sets the passwords and also raises the loopback interface which we
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will use to connect to the daemons.
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Create a `route0.conf` file in the root of the project directory with the
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following content
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```
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hostname route0
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password route0
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enable password route0
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interface lo
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no shutdown
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```
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Now let's start with an empty network
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```
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sudo python route0.py --topology one_rtr --scenario plain
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```
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First thing we need to do is launch the daemons. The two daemons we will use
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are `zebra` and `staticd`. Since all the FRR protocols rely on `zebra` to talk
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to the Linux kernel it must always be started first. There is also a minor
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complication due to the fact that these daemons weren't designed to run
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multiple instances on a single machine. The daemons may not work as expected
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if you don't start all the daemons on one node before moving to the next one.
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To start `<daemon>` on `<node>` we can run the following command in the Mininet
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prompt
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```
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<node> /usr/lib/frr/<daemon> -f route0.conf -d -i $(tempfile).pid
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```
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Now start the daemons on all the nodes. Remember that `zebra` must always be
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first and start all the daemons on each node before moving to the next one.
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Note that since we won't be installing any static routes on `R1` it doesn't
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need `staticd`. You can ignore the message about no kernel support for
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MPLS-TE.
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## Using Zebra to assign IP addresses
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Before we begin, verify that no IP addresses have been assigned on `h1_1` using
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the `ip addr` command. The `lo` interface will have `127.0.0.1/8` assigned to
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it, but that IP address is only valid locally and cannot be used for routing.
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We need it to connect to the FRR daemons.
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Interface IP addresses are assigned using `zebra` so we will first connect to
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the `zebra` daemon on `h1_1`. To do so we will connect using telnet
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```
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noecho h1_1 telnet localhost zebra
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```
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`noecho` is just a quirk of the Mininet CLI. If you don't prefix your command
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with `noecho`, you will be seeing double.
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You can also connect to the daemon from a separate terminal (the experience is
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slightly better as you avoid the Mininet CLI quirks). In that case, navigate
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to the Route 0 directory and run
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```
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sudo python attach.py --node h1_1 --daemon zebra
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```
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The password to all the daemons is `route0` just as we set it in the `conf`
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file we just created.
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Before we start, it is useful to note that if you are ever lost in the FRR
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shell, simply press `?` which will list all the commands you can run in the
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current context.
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The process of assigning an IP address through the `zebra` shell is rather
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tedious, but this is because router configuration is a difficult problem. The
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daemon shells follow a configuration model that seems more convoluted than the
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basic Linux commands, but that will make sense when configuring much more
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complex protocols.
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We will go over assigning the IP address for the `h1_1` interface together so
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make sure you have connected to the `zebra` daemon on that node.
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First we must turn on privileged mode by running (password is `route0` as
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usual)
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```
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enable
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```
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Next we enter configuration mode
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```
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configure terminal
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```
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If you press `?` you will notice that there are lots of things we can configure
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at this point. We are only interested in configuring a specific interface so
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we select it. Note that the terminal has very clever auto-completion
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capabilities so try hitting `<tab>` after typing just a few letters.
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```
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interface h1_1-eth1
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```
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Finally, we are at a point where we can add an IP address
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```
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ip address 10.1.0.1/24
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```
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Now let's exit the `zebra` shell. Run `exit` as many times as you need until
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you're back in the Mininet prompt if you connected from Mininet (careful not to
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exit Mininet or you will have to redo all of this!) or your default shell if
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you connected from a different terminal using `attach.py`. If you now run
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`h1_1 ip addr` you will see the IP address on the interface!
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The `zebra` shell is used for more than just configuration. It can also give
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you a lot of information about the system's state. Connect to the `zebra`
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daemon on `h1_1` once again. This time we will inspect the `show` command.
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Try running the following commands in the shell and inspect their output
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```
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show interface
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show interface h1_1-eth1
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show ip route
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```
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As you can see we can get a lot of nicely formatted state information this
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way. We haven't seen anything we can't find out using basic Linux commands,
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but that's because we haven't done anything complicated yet. Feel free to
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explore the `zebra` daemon more by pressing `?` whenever you can.
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When you finish exploring the daemon, assign all the other IP addresses as
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shown in the [topology](../topology/one_rtr).
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Verify what you've done by pinging the IP addresses on `h1_1` and `h1_2` from
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`R1`.
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## Using STATIC to create static routes
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In order to complete the network we need to create default routes on the
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hosts. The hosts have only one outgoing link so it makes sense they have a
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rule which says to send all traffic over this link.
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If you try to connect to `staticd` from Mininet using the same method as for
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`zebra` it will fail. This is because Linux doesn't know the port number of
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`staticd` (presumably as it's a newer daemon). Therefore, if you want to
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connect from the Mininet prompt you need to use the port number, `2616`,
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explicitly
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```
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noecho h1_1 telnet localhost 2616
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```
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Note that if you use the `attach.py` script from a separate terminal window,
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you can still just use the name `staticd`.
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Connect to the `staticd` daemon on `h1_1`, enable privileged mode, and enter
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the configuration terminal. Once in the configuration terminal we can create
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the default route. Can you figure out the right command using `?`?. Hint: do
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not use the `via` word.
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The full command to install a default route on `h1_1` is
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```
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ip route 0.0.0.0/0 10.1.0.254
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```
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which is very similar to the Linux command you would run for the same effect.
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If you exit the daemon's shell you can now check that your route installed
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correctly using `ip route`. Repeat the process for `h1_2`.
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When you finish you can verify that everything is correctly set up by checking
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whether `h1_1` can ping the interface IP address on `h1_2` and vice versa.
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If the ping succeeds, congratulations on configuring your first network using
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the FRR daemons!
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## Configuring the protocols using configuration files
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The manual configuration process was rather tedious which is why configuration
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files exist. When you start the network in the `basic` scenario using
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`route0.py` it simply reads in a bunch of configuration files. The ones it
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reads on for `one_rtr` can be found in the
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[`staticd`](../topology/one_rtr/staticd) and
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[`zebra`](../topology/one_rtr/zebra) directories in its [topology
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directory](../topology/one_rtr). Have a look at them and see how similar they
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are to the commands we have just run to configure the network.
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## Conclusion
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In this lesson you learned how to configure a `basic` scenario on the `one_rtr`
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network. You learned how to connect to the FRR daemons, how use them for
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configuration and displaying routing state. You also tried exploring the
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different options available in the shell using `?`. All these skills will be
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useful when configuring actual routing protocols in later lessons.
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