d5026c2074
Also add infrastructure to also generate the supported hardware page when building the docs locally
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324 lines
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Tutorial
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########
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Liminix is very configurable, which can make it initially quite
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daunting - especially if you're learning Nix or Linux or networking
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concepts at the same time. In this section we build some "worked
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example" Liminix images to introduce the concepts. If you follow the
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examples exactly, they should work. If you change things as you go
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along, they may work differently or not at all, but the experience
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should be educational either way.
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Requirements
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************
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You will need a reasonably powerful computer running Nix. Target
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devices for Liminix are unlikely to have the CPU power and disk space
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to be able to build it in situ, so the build process is based around
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"cross-compilation" from another computer. The build machine can be
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any reasonably powerful desktop/laptop/server PC running NixOS.
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Standalone Nixpkgs installations on other Linux distributions - or on
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MacOS, or even in a Docker container - also ought to work but are
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untested.
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Running in Qemu
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***************
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You can try out Liminix without even having a router to play with.
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Clone the Liminix git repository and change into its directory
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.. code-block:: console
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git clone https://gti.telent.net/dan/liminix
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cd liminix
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Now build Liminix
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.. code-block:: console
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nix-build -I liminix-config=./examples/hello-from-qemu.nix \
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--arg device "import ./devices/qemu" -A outputs.default
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In this command ``liminix-config`` points to the desired software
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configuration (e.g. services, users, filesystem, secrets) and
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``device`` describes the hardware (or emulated hardware) to run it on.
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``outputs.default`` tells Liminix that we want the default image
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output for flashing to the device: for the Qemu "hardware" it's an
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alias for ``outputs.vmbuild``, which creates a directory containing a
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root filesystem image and a kernel.
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.. tip:: The first time you run this it may take several hours,
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because it builds all of the dependencies including a full
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MIPS gcc and library toolchain. Once those intermediate build
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products are in the nix store, subsequent builds will be much
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faster - practically instant, if nothing has changed.
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Now you can try it:
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.. code-block:: console
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./result/run.sh
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This starts the Qemu emulator with a bunch of useful options, to run
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the Liminix configuration you just built. It connects the emulated
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device's serial console and the `QEMU monitor
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<https://www.qemu.org/docs/master/system/monitor.html>`_ to
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stdin/stdout.
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You should now see Linux boot messages and after a few seconds be
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presented with a root shell prompt. You can run commands to look at
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the filesystem, see what processes are running, view log messages (in
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:file:/run/uncaught-logs.current), etc. To kill the emulator, press ^P
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(Control P) then c to enter the "QEMU Monitor", then type ``quit`` at
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the ``(qemu)`` prompt.
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To see that it's running network services we need to connect to its
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emulated network. Start the machine again, if you had stopped it, and
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open up a second terminal on your build machine. We're going to run
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another virtual machine attached to the virtual network, which will
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request an IP address from our Liminix system and give you a shell you
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can run ssh from.
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We use `System Rescue <https://www.system-rescue.org/>`_ in tty
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mode (no graphical output) for this example, but if you have some
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other favourite Linux Live CD ISO - or, for that matter, any other OS
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image that QEMU can boot - adjust the command to suit.
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Download the System Rescue ISO:
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.. code-block:: console
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curl https://fastly-cdn.system-rescue.org/releases/10.01/systemrescue-10.01-amd64.iso -O
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and run it
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.. code-block:: console
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nix-shell -p qemu --run " \
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qemu-system-x86_64 \
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-echr 16 \
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-m 1024 \
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-cdrom systemrescue-10.01-amd64.iso \
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-netdev socket,mcast=230.0.0.1:1235,localaddr=127.0.0.1,id=lan \
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-device virtio-net,disable-legacy=on,disable-modern=off,netdev=lan,mac=ba:ad:3d:ea:21:01 \
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-display none -serial mon:stdio"
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System Rescue displays a boot menu at which you should select the
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"serial console" option, then after a few moments it boots to a root
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prompt. You can now try things out:
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* run :command:`ip a` and see that it's been allocated an IP address in the range 10.3.0.0/16.
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* run :command:`ping 10.3.0.1` to see that the Liminix VM responds
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* run :command:`ssh root@10.3.0.1` to try logging into it.
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Congratulations! You have installed your first Liminix system - albeit
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it has no practical use and it's not even real. The next step is to try
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running it on hardware.
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Installing on hardware
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**********************
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For the next example, we're going to install onto an actual hardware
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device. These steps have been tested using a GL.iNet GL-MT300A, which
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has been chosen for the purpose because it's cheap and easy to
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unbrick if necessary.
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.. warning:: There is always a risk of rendering your device
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unbootable by flashing it with an image that doesn't
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work. The GL-MT300A has a builtin "debrick" procedure in
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the boot monitor and is also comparatively simple to
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attach serial cables to (soldering not required), so it
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is lower-risk than some devices. Using some other
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Liminix-supported MIPS hardware device also *ought* to
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work here, but you accept the slightly greater bricking
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risk if it doesn't.
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See :doc:`hardware` for device support status.
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You may want to read and inwardly digest the Develoment Manual section
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:ref:`serial` when you start working with Liminix on real hardware. You
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won't *need* serial access for this example, assuming it works, but it
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allows you
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to see the boot monitor and kernel messages, and to login directly to
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the device if for some reason it doesn't bring its network up.
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Now we can build Liminix. Although we could use the same example
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configuration as we did for Qemu, you might not want to plug a DHCP
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server into your working LAN because it will compete with the real
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DHCP service. So we're going to use a different configuration with a
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DHCP client: this is :file:`examples/hello-from-mt300.nix`
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It's instructive to compare the two configurations:
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.. code-block:: console
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diff -u examples/hello-from-qemu.nix examples/hello-from-mt300.nix
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You'll see a new ``boot.tftp`` stanza which you can ignore,
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``services.dns`` has been removed, and the static IP address allocation
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has been replaced by a ``dhcp.client`` service.
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.. code-block:: console
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nix-build -I liminix-config=./examples/hello-from-mt300.nix \
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--arg device "import ./devices/gl-mt300a" -A outputs.default
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.. tip:: The first time you run this it may take several hours.
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Again? Yes, even if you ran the previous example. Qemu is
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set up as a big-endian system whereas the MediaTek SoC
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on this device is little-endian - so it requires building
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all of the dependencies including an entirely different
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MIPS gcc and library toolchain to the other one.
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This time in :file:`result/` you will see a bunch of files. Most of
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them you can ignore for the moment, but :file:`result/firmware.bin` is
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the firmware image you can flash.
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Flashing
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========
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Again, there are a number of different ways you could do this: using
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TFTP with a serial cable, through the stock firmware's web UI, or
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using the `vendor's "debrick" process
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<https://docs.gl-inet.com/router/en/3/tutorials/debrick/>`_. The last
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of these options has a lot to recommend it for a first attempt:
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* it works no matter what firmware is currently installed
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* it doesn't require plugging a router into the same network as your
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build system and potentially messing up your actual upstream
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* no need to open the device and add cables
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You can read detailed instructions on the vendor site, but the short version is:
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1. turn the device off
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2. connect it by ethernet cable to a computer
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3. configure the computer to have static ip address 192.168.1.10
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4. while holding down the Reset button, turn the device on
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5. after about five seconds you can release the Reset button
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6. visit http://192.168.1.1/ using a web browser on the connected computer
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7. click on "Browse" and choose :file:`result/firmware.bin`
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8. click on "Update firmware"
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9. wait a minute or so while it updates.
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There's no feedback from the web interface when the flashing is
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finished, but what should happen is that the router reboots and
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starts running Liminix. Now you need to figure out what address it got
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from DHCP - e.g. by checking the DHCP server logs, or maybe by pinging
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``hello.lan`` or something. Once you've found it on the
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network you can ping it and ssh to it just like you did the Qemu
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example, but this time for real.
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.. warning:: Do not leave the default root password in place on any
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device exposed to the internet! Although it has no
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writable storage and no default route, a motivated attacker
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with some imagination could probably still do something
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awful using it.
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Congratulations Part II! You have installed your first Liminix system on actual hardware - albeit that it *still* has no practical use.
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Exercise for the reader: change the default password by editing
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:file:`examples/hello-from-mt300.nix`, and then create and upload a
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new image that has it set to something less hopeless.
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Routing
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*******
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The third example :file:`examples/demo.nix` is a fully-functional home
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"WiFi router" - although you will have to edit it a bit before it will
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actually work for you. Copy :file:`examples/demo.nix` to
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:file:`my-router.nix` (or other name of your choice) and open it in
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your favourite text editor. Everywhere that the text :code:`EDIT`
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appears is either a place you probably want to change or a place you
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almost certainly need to change.
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There's a lot going on in this configuration:
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* it provides a wireless access point using the :code:`hostapd`
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service: in this stanza you can change the ssid, the channel,
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the passphrase etc.
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* the wireless lan and wired lan are bridged together with the
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:code:`bridge` service, so that your wired and wireless clients appear
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to be on the same network.
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.. tip:: If you were using a hardware device that provides both 2.4GHz
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and 5GHz wifi, you'd probably find that it has two wireless
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devices (often called wlan0 and wlan1). In Liminix we handle
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this by running two :code:`hostapd` services, and adding
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both of them to the network bridge along with the wired lan.
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(You can see an example in :file:`examples/rotuer.nix`)
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* we use the combination DNS and DHCP daemon provided by the
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:code:`dnsmasq` service, which you can configure
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* the upstream network is "PPP over Ethernet", provided by the
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:code:`pppoe` service. Assuming that your ISP uses this standard,
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they will have provided you with a PPP username and password
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(sometimes this will be listed as "PAP" or "CHAP") which you can edit
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into the configuration
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* this example supports the new [#ipv6]_ Internet Protocol v6
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as well as traditional IPv4. Configuring IPv6 seems to
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vary from one ISP to the next: this example expects them
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to be providing IP address allocation and "prefix delegation"
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using DHCP6.
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Build it using the same method as the previous example
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.. code-block:: console
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nix-build -I liminix-config=./my-router.nix \
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--arg device "import ./devices/gl-mt300a" -A outputs.default
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and then you can flash it to the device.
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Bonus: in-place updates
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=======================
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This configuration uses a writable filesystem (see the line
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:code:`rootfsType = "jffs2"`), which means that once you've flashed it
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for the first time, you can make further updates over SSH onto the
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running router. To try this, make a small change (I'd suggest changing
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the hostname) and then run
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.. code-block:: console
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nix-shell --run "liminix-rebuild root@address-of-the-device -I liminix-config=./my-router.nix --arg device "import ./devices/gl-ar750""
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(This requires the device to be network-accessible from your build
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machine, which for a test/demo system might involve a second network
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device in your build system - USB ethernet adapters are cheap - or
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a bit of messing around unplugging cables.)
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For more information about :code:`liminix-rebuild`, see the manual section :ref:`admin:Rebuilding the system`.
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Final thoughts
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**************
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* These are demonstration configs for pedagogical purposes. If you'd
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like to see some more realistic uses of Liminix,
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:file:`examples/rotuer,arhcive,extneder.nix` are based on some
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actual real hosts in my home network.
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* The technique used here for flashing was chosen mostly because it
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doesn't need much infrastructure/tooling, but it is a bit of a faff
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(requires physical access, vendor specific). There are slicker ways
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to do it that need a bit more setup - we'll talk about that later as
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well.
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.. rubric:: Footnotes
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.. [#ipv6] `RFC1883 Internet Protocol, Version 6 <https://datatracker.ietf.org/doc/html/rfc1883>`_ was published in 1995, so only "new" when Bill Clinton was US President
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