diff --git a/doc/developer.rst b/doc/developer.rst deleted file mode 100644 index d781914..0000000 --- a/doc/developer.rst +++ /dev/null @@ -1,336 +0,0 @@ -Developer Manual -################ - -As a developer working on Liminix, or implementing a service or -module, you probably want to test your changes more conveniently -than by building and flashing a new image every time. This manual -documents various affordances for iteration and experiments. - -In general, packages and tools that run on the "build" machine are -available in the ``buildEnv`` derivation and can most easily -be added to your environment by running :command:`nix-shell` - - - -Emulated devices -**************** - -Liminix has a ``qemu`` device, which generates images suitable for -running on your build machine using the free `QEMU machine emulator `_. -This is useful for developing userland without needing to keep -flashing or messing with U-Boot: it also enables testing against -emulated network peers using `QEMU socket networking `_, -which may be preferable to letting Liminix loose on your actual LAN. -To build it, - -.. code-block:: console - - nix-build -I liminix-config=path/to/your/configuration.nix --arg device "import ./devices/qemu" -A outputs.default - -In a ``buildEnv`` nix-shell, you can use the :command:`mips-vm` command -to run Qemu with appropriate options. It connects the Liminix -serial console and the `QEMU monitor `_ to stdin/stdout. Use ^P (not ^A) to switch to the monitor. - -.. code-block:: console - - nix-shell --run "mips-vm result/vmlinux result/squashfs" - -If you run with ``--background /path/to/some/directory`` as the first -parameter, it will fork into the background and open Unix sockets in -that directory for console and monitor. Use :command:`connect-vm` -(also in the ``buildEnv`` environment) to connect to either of these -sockets, and ^O to disconnect. - -Networking -========== - -VMs can network with each other using QEMU -socket networking. We observe these conventions, so that we can run -multiple emulated instances and have them wired up to each other in -the right way: - -* multicast 230.0.0.1:1234 : access (interconnect between router and "isp") -* multicast 230.0.0.1:1235 : lan -* multicast 230.0.0.1:1236 : world (the internet) - -A VM started with :command:`mips-vm` is connected to "lan" and "access", and -the emulated border network gateway (see below) runs PPPoE and is -connected to "access" and "world". - -Border Network Gateway ----------------------- - -In pkgs/routeros there is a derivation to install and configure -`Mikrotik RouterOS `_ as a PPPoE access -concentrator connected to the ``access`` and ``world`` networks, so that -Liminix PPPoE client support can be tested without actual hardware. - -This is made available as the :command:`routeros` command in -``buildEnv``, so you can do something like:: - - mkdir ros-sockets - nix-shell - nix-shell$ routeros ros-sockets - nix-shell$ connect-vm ./ros-sockets/console - -to start it and connect to it. Note that by default it runs in the -background. It is connected to "access" and "world" virtual networks -and runs a PPPoE service on "access" - so a Liminix VM with a -PPPOE client can connect to it and thus reach the virtual internet. -[ check, but pretty sure this is not the actual internet ] - -`Liminix does not provide RouterOS licences and it is your own -responsibility if you use this to ensure you're compliant with the -terms of Mikrotik's licencing. It may be supplemented or replaced in -time with configurations for RP-PPPoE and/or Accel PPP.` - -Hardware devices -**************** - -How you get your image onto hardware will vary according to the -device, but is likely to involve taking it apart to add wires to -serial console pads/headers, then using U-Boot to fetch images over -TFTP. The OpenWrt documentation has a `good explanation `_ of what you may expect to find on -the device. - -There is a rudimentary TFTP server bundled with the system which runs -from the command line, has an allowlist for client connections, and -follows symlinks, so you can have your device download images direct -from the :file:`./result` directory without exposing :file:`/nix/store/` to the -internet or mucking about copying files to :file:`/tftproot`. If the -permitted device is to be given the IP address 192.168.8.251 you might -do something like this: - -.. code-block:: console - - nix-shell --run "tufted -a 192.168.8.251 result" - -Now add the device and server IP addresses to your configuration: - -.. code-block:: nix - - boot.tftp = { - serverip = "192.168.8.111"; - ipaddr = "192.168.8.251"; - }; - -and then build the derivation for ``outputs.default`` or -``outputs.flashimage`` (for which it will be an alias on any device -where this is applicable). You should find it has created - -* :file:`result/firmware.bin` which is the file you are going to flash -* :file:`result/flash.scr` which is a set of instructions to U-Boot to - download the image and write it to flash after erasing the appropriate - flash partition. - -.. NOTE:: - - TTL serial connections typically have no form of flow control and - so don't always like having massive chunks of text pasted into - them - and U-Boot may drop characters while it's busy. So don't - necessarily expect to copy-paste the whole of :file:`boot.scr` into - a terminal emulator and have it work just like that. You may need - to paste each line one at a time, or even retype it. - - -For a faster edit-compile-test cycle, you can build a TFTP-bootable -image instead of flashing. In your device configuration add - -.. code-block:: nix - - imports = [ - ./modules/tftpboot.nix - ]; - -and then build ``outputs.tftpboot``. This creates a file in -``result/`` called ``boot.scr``, which you can copy and paste into -U-Boot to transfer the kernel and filesystem over TFTP and boot the -kernel from RAM. - - -Networking -========== - -You probably don't want to be testing a device that might serve DHCP, -DNS and routing protocols on the same LAN as you (or your colleagues, -employees, or family) are using for anything else, because it will -interfere. You also might want to test the device against an -"upstream" connection without having to unplug your regular home -router from the internet so you can borrow the cable/fibre/DSL. - -``bordervm`` is included for this purpose. You will need - -* a Linux machine with a spare (PCI or USB) ethernet device which you can dedicate to Liminix - -* an L2TP service such as https://www.aa.net.uk/broadband/l2tp-service/ - -You need to "hide" the Ethernet device from the host - for PCI this -means configuring it for VFIO passthru; for USB you need to unload the -module(s) it uses. I have this segment in configuration.nix which you -may be able to adapt: - -.. code-block:: nix - - boot = { - kernelParams = [ "intel_iommu=on" ]; - kernelModules = [ - "kvm-intel" "vfio_virqfd" "vfio_pci" "vfio_iommu_type1" "vfio" - ]; - - postBootCommands = '' - # modprobe -i vfio-pci - # echo vfio-pci > /sys/bus/pci/devices/0000:01:00.0/driver_override - ''; - blacklistedKernelModules = [ - "r8153_ecm" "cdc_ether" - ]; - }; - services.udev.extraRules = '' - SUBSYSTEM=="usb", ATTRS{idVendor}=="0bda", ATTRS{idProduct}=="8153", OWNER="dan" - ''; - -Then -you can execute :command:`run-border-vm` in a ``buildEnv`` shell, -which starts up QEMU using the NixOS configuration in -:file:`bordervm-configuration.nix`. - -In this VM - -* your Liminix checkout is mounted under :file:`/home/liminix/liminix` - -* TFTP is listening on the ethernet device and serving - :file:`/home/liminix/liminix`. The server IP address is 10.0.0.1 - -* a PPPOE-L2TP relay is running on the same ethernet card. When the - connected Liminix device makes PPPoE requests, the relay spawns - L2TPv2 Access Concentrator sessions to your specified L2TP LNS. - Note that authentication is expected at the PPP layer not the L2TP - layer, so the PAP/CHAP credentials provided by your L2TP service can - be configured into your test device - bordervm doesn't need to know - about them. - -To configure bordervm, you need a file called :file:`bordervm.conf.nix` -which you can create by copying and appropriately editing :file:`bordervm.conf-example.nix` - -.. note:: - - If you make changes to the bordervm configuration after executing - :command:`run-border-vm`, you need to remove the :file:`border.qcow2` disk - image file otherwise the changes won't get picked up. - - -Running tests -************* - -You can run all of the tests by evaluating :file:`ci.nix`, which is the -input I use in Hydra. Note that it expects Nixpkgs stable `and` unstable -as inputs, because it builds the qemu device against both. - -.. code-block:: console - - nix-build --argstr liminix `pwd` --arg nixpkgs "" \ - --argstr unstable `pwd`/../unstable-nixpkgs/ ci.nix - -To run a single named test, use the ``-A`` flag. For example, ``-A pppoe`` - - - - -Troubleshooting -*************** - -Diagnosing unexpectedly large images -==================================== - -Sometimes you can add a package and it causes the image size to balloon -because it has dependencies on other things you didn't know about. Build the -``outputs.manifest`` attribute, which is a JSON representation of the -filesystem, and you can run :command:`nix-store --query` on it. - -.. code-block:: console - - nix-build -I liminix-config=path/to/your/configuration.nix \ - --arg device "import ./devices/qemu" -A outputs.manifest \ - -o manifest - nix-store -q --tree manifest - - -Contributing -************ - -Contributions are welcome, though in these early days there may be a -bit of back and forth involved before patches are merged: -Please get in touch somehow `before` you invest a lot of time into a -code contribution I haven't asked for. Just so I know it's expected -and you're not wasting time doing something I won't accept or have -already started on. - - -Nix language style -================== - -This section describes some Nix language style points that we -attempt to adhere to in this repo. - -* favour ``callPackage`` over raw ``import`` for calling derivations - or any function that may generate one - any code that might need - ``pkgs`` or parts of it. - -* prefer ``let inherit (quark) up down strange charm`` over - ``with quark``, in any context where the scope is more than a single - expression or there is more than one reference to ``up``, ``down`` - etc. ``with pkgs; [ foo bar baz]`` is OK, - ``with lib; stdenv.mkDerivation { ... }`` is usually not. - -* ```` is defined only when running tests, so don't refer to it - in "application" code - -* the parameters to a derivation are sorted alphabetically, except for - ``lib``, ``stdenv`` and maybe other non-package "special cases" - -* indentation is whatever emacs nix-mode says it is. - -* where a ``let`` form defines multiple names, put a newline after the - token ``let``, and indent each name two characters - -* to decide whether some code should be a package or a module? - Packages are self-contained - they live in ``/nix/store/eeeeeee-name`` - and don't directly change system behaviour by their presence or - absense. modules can add to - ``/etc`` or ``/bin`` or other global state, create services, all that - side-effecty stuff. Generally it should be a package unless it - can't be. - - - -Copyright -========= - -The Nix code in Liminix is MIT-licenced (same as Nixpkgs), but the -code it combines from other places (e.g. Linux, OpenWrt) may have a -variety of licences. I have no intention of asking for copyright -assignment: just like when submitting to the Linux kernel you retain -the copyright on the code you contribute. - - -Code of Conduct -=============== - -Please govern yourself in Liminix project venues according to the -`Code of Conduct `_ - - -Where to send patches -===================== - - -Liminix' primary repo is https://gti.telent.net/dan/liminix but you -can't send code there directly because it doesn't have open registrations. - -* There's a `mirror on Github `_ for - convenience and visibility: you can open PRs against that - -* or, you can send me your patch by email using `git send-email `_ - -* or in the future, some day, we will have federated Gitea using - ActivityPub. diff --git a/doc/etc.rst b/doc/etc.rst deleted file mode 100644 index 3c5c70b..0000000 --- a/doc/etc.rst +++ /dev/null @@ -1,51 +0,0 @@ -The Future -########## - -What about NixWRT? - -This is an in-progress rewrite of NixWRT, incorporating Lessons -Learned. That said, as of today it is not yet at feature parity. - -Liminix will eventually provide these differentiators over NixWRT: - -* a writable filesystem so that software updates or reconfiguration - (e.g. changing passwords) don't require taking the device offline to - reflash it. - -* more flexible service management with dependencies, to allow - configurations such as "route through PPPoE if it is healthy, with - fallback to LTE" - -* a spec for valid configuration options (a la NixOS module options) - to that we can detect errors at evaluation time instead of producing - a bad image. - -* a network-based mechanism for secrets management so that changes can - be pushed from a central location to several Liminix devices at once - -* send device metrics and logs to a monitoring/alerting/o11y - infrastructure - -Today though, it does approximately none of these things and certainly -not on real hardware. - - -Articles of interest -#################### - -* `Build Safety of Software in 28 Popular Home Routers `_: "of the access - points and routers we reviewed, not a single one took full - advantage of the basic application armoring features provided by - the operating system. Indeed, only one or two models even came - close, and no brand did well consistently across all models tested" - -* `A PPPoE Implementation for Linux `_: - "Many DSL service providers use PPPoE for residential broadband - Internet access. This paper briefly describes the PPPoE protocol, - presents strategies for implementing it under Linux and describes in - detail a user-space implementation of a PPPoE client." - -* `PPP IPV6CP vs DHCPv6 at AAISP `_ - - -* `Creating a Home IPv6 Network (James Bottomley) `_ diff --git a/doc/index.rst b/doc/index.rst index 8ab4c64..1b11bdd 100644 --- a/doc/index.rst +++ b/doc/index.rst @@ -5,10 +5,7 @@ Liminix :maxdepth: 3 :caption: Contents: - intro - user - developer - etc + new Indices and tables diff --git a/doc/new.rst b/doc/new.rst new file mode 100644 index 0000000..1b095b5 --- /dev/null +++ b/doc/new.rst @@ -0,0 +1,114 @@ +Getting Started +############### + +Liminix is very configurable, which can make it initially daunting +especially if you're learning Nix or Linux or networking concepts at +the same time. In this section we build some "worked example" Liminix +images to introduce the concepts. If you follow the examples exactly, +they should work. If you change things as you go along, they may work +differently or not at all, but the experience should be educational +either way. + + +.. warning:: The first example we will look at runs under emulation, + so there is no danger of bricking your hardware + device. For the second example you may (if you have + appropriate hardware and choose to do so) flash the + configuration onto an actual router. There is always a + risk of rendering the device unbootable when you do this, + and various ways to recover depending on what went wrong. + We'll write more about that at the appropriate point + + +Requirements +************ + +You will need a reasonably powerful computer running Nix. Devices +that run Liminix are unlikely tohave the CPU power and disk space to +be able to build it in situ, so the build process is based around +"cross-compilation" from another computer. The build machine can be +any reasonably powerful desktop/laptop/server PC running NixOS. +Standalone Nixpkgs installations on other Linux distribuions or MacOS +also ought to work (but I haven't tested that configuration) + + +Running in Qemu +*************** + +Clone the Liminix git repository and change into its directory + + +.. code-block:: console + + git clone https://gti.telent.net/dan/liminix + cd liminix + +Now build Liminix + +.. code-block:: console + + nix-build -I liminix-config=./examples/hellonet.nix \ + --arg device "import ./devices/qemu" -A outputs.default + +In this command ``liminix-config`` points to the configuration for the +device (services, users, filesystem, secrets) and ``device`` is the +file for your hardware device definition. ``outputs.default`` tells +Liminix to build the appropriate image output appropriate to +flash to the hardware device: for the qemu "hardware" it's an alias +for ``outputs.vmbuild``, which creates a directory containing a root +filesystem image and a kernel. + +.. tip:: The first time you run this it may take several hours, + because it builds all of the dependencies including a full + MIPS gcc and library toolchain. Once those intermediate build + products are in the nix store, subsequent builds will be much + faster - practically instant, if nothing has changed. + +Now you can try it: + +.. code-block:: console + + nix-shell --run "mips-vm ./result/vmlinux ./result/rootfs" + +This starts the Qemu emulator to run the Liminix configuration you +just built. It connects the Liminix serial console and the `QEMU +monitor `_ to +stdin/stdout. Use ^P (not ^A) to switch to the monitor. + +You should now see Linux boot messages and after a few seconds be +presented with a login prompt. You can login on the console as +``root`` (no password) and poke around to see what processes are +running. Run ``shutdown`` to shut it down cleanly, or press ^P then +type ``exit`` at the monitor to stop it suddenly. + +To see that it running an ssh service we need to connect to its +emulated network. Start the machine again, if you had stopped it, +and open up a second terminal on your build machine. We're going to +run another virtual machine attached to the virtual network, which will +request an IP address from our Liminix system and give you a shell +you can run ssh from. + + + + +- using modules + + - link to module reference + +- creating custom services + + - longrun or oneshot + - dependencies + - outputs + +- creating your own modules + +- hacking on Liminix itself + +- contributing + +- external links and resources + +- module reference + +- hardware device reference diff --git a/doc/user.rst b/doc/user.rst deleted file mode 100644 index 5d37db4..0000000 --- a/doc/user.rst +++ /dev/null @@ -1,347 +0,0 @@ -User Manual -########### - -This manual is an early work in progress, not least because Liminix is -not yet really ready for users who are not also developers. Your -feedback to improve it is very welcome. - -Installation -************ - -The Liminix installation process is not quite like installing NixOS on -a real computer, but some NixOS experience will nevertheless be -helpful in understanding it. The steps are as follows: - -* Decide whether you want the device to be updatable in-place (there - are advantages and disadvantages), or if you are happy to generate - and flash a new image whenever changes are required. - -* Create a :file:`configuration.nix` describing the system you want - -* Build an image - -* Flash it to the device - -Supported devices -================= - -For a list of devices that Liminix (present or previous versions) -has run on, refer to `devices/ in the source repo `_. For devices that _currently_ build, -cross-reference it with `the CI status `_. Everything that builds is (usually) expected -to run, so if you end up with an image that builds but doesn't -boot, please report it as a bug. - -As of June 2023 the device list is a little thin. Adding devices based -on the Atheros or Mediatek (Ralink) platform should be quite -straightforward if you have some C/Linux kernel experience and are -prepared to open it up and attach serial wires: please refer to the -Developer Manual. - - -Choosing a flavour (read-only or updatable) -=========================================== - -Liminix installations come in two "flavours"- read-only or in-place -updatable: - -* a read-only installation can't be updated once it is flashed to your - device, and so must be reinstalled in its entirety every time you - want to change it. It uses the ``squashfs`` filesystem which has - very good compression ratios and so you can pack quite a lot of - useful stuff onto your device. This is good if you don't expect - to change it often. - -* an updatable installation has a writable filesystem so that you can - update configuration, upgrade packages and install new packages over - the network after installation. This uses the `jffs2 - `_ filesystem: - although it does compress the data, the need to support writes means - that it can't pack quite as small as squashfs, so you will not have - as much space to play with. - -Updatability caveats -~~~~~~~~~~~~~~~~~~~~ - -At the time of writing this manual the read-only squashfs support is -much more mature. Consider also that it may not be possible to perform -"larger" updates in-place even if you do opt for updatability. If you -have (for example) an 11MB system on a 16MB device, you won't be able -to do an in-place update of something fundamental like the C library -(libc), as this will temporarily require 22MB to install all the -packages needing the new library before the packages using the old -library can be removed. A writable system will be more useful for -smaller updates such as installing a new package (perhaps you -temporarily need tcpdump to diagnose a network problem) or for -changing configuration files. - -Note also that the kernel is not part of the filesystem so cannot be -updated this way. Kernel changes require a full reflash. - - - -Creating configuration.nix -========================== - - -You need to create a :file:`configuration.nix` that describes your -device and the services that you want to run on it. The best way to -get started is by reading one of the examples such as -:file:`examples/rotuer.nix` and modifying it to your needs. - -:file:`configuration.nix` conventionally describes the packages, services, -user accounts etc of the device. It does not describe the hardware -itself, which is specified separately in the build command (as you -will see below). - -Most of the functionality of a Liminix system is driven by *services* -which are declared by *modules*: thus, to add for example an NTP service -you first add :file:`modules/ntp` to your ``imports`` list, then -you create a service by calling :code:`config.system.service.ntp.build { .... }` -with the appropriate service-dependent configuration parameters. - -.. code-block:: nix - - let svc = config.system.service; - in { - # ... - imports = [ - ./modules/ntp - # .... - ]; - config.services.ntp = svc.ntp.build { - pools = { "pool.ntp.org" = ["iburst"]; }; - makestep = { threshold = 1.0; limit = 3; }; - }; - -A :ref:`full list of module options ` is provided -later in this manual. - -You *most likely* want to include the ``standard`` module unless you -have a quite unusual use case for a very minimal system, in which case -you will understand what it does and what happens if you leave it out. - -.. code-block:: nix - - imports = [ - ./modules/standard.nix - ] - configuration.rootfsType = "jffs2"; # or "squashfs" - - - -Building -======== - -Build Liminix using the :file:`default.nix` in the project toplevel -directory, passing it arguments for configuration and hardware. For -example: - -.. code-block:: console - - nix-build -I liminix-config=./tests/smoke/configuration.nix \ - --arg device "import ./devices/qemu" -A outputs.default - -In this command ```` points to your -:file:`configuration.nix`, ``device`` is the file for your hardware device -definition, and ``outputs.default`` will generate some kind of -Liminix image output appropriate to that device. - -For the qemu device in this example, ``outputs.default`` is an alias -for ``outputs.vmbuild``, which creates a directory containing a -squashfs root image and a kernel. You can use the :command:`mips-vm` command to -run this. - -For the currently supported hardware devices, ``outputs.default`` -creates a directory containing a file called ``firmware.bin``. This -is a raw image file that can be written directly to the firmware flash -partition. - - -Flashing -======== - - -Flashing from the boot monitor -~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ - -If you are prepared to open the device and have a TTL serial adaptor -of some kind to connect it to, you can probably flash it using U-Boot. -This is quite hardware-specific, and sometimes involves soldering: -please refer to the Developer Manual. - - -Flashing from an existing Liminix system with :command:`flashcp` -~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ - -The flash procedure from an existing Liminix-system is two-step. -First we reboot the device (using "kexec") into an "ephemeral" -RAM-based version of the new configuration, then when we're happy it -works we can flash the image - and if it doesn't work we can reboot -the device again and it will boot from the old image. - - - -Building the RAM-based image -............................ - -To create the ephemeral image, build ``outputs.kexecboot`` instead of -``outputs.default``. This generates a directory containing the root -filesystem image and kernel, along with an executable called `kexec` -and a `boot.sh` script that runs it with appropriate arguments. - -For example - -.. code-block:: console - - nix-build --show-trace -I liminix-config=./examples/arhcive.nix \ - --arg device "import ./devices/gl-ar750" - -A outputs.kexecboot && \ - (tar chf - result | ssh root@the-device tar -C /run -xvf -) - -and then login to the device and run - -.. code-block:: console - - cd /run/result - sh ./boot.sh . - - -This will load the new kernel and map the root filesystem into a RAM -disk, then start executing the new kernel. *This is effectively a -reboot - be sure to close all open files and finish anything else -you were doing first.* - -If the new system crashes or is rebooted, then the device will revert -to the old configuration it finds in flash. - - -Building the second (permanent) image -..................................... - -While running in the kexecboot system, you can copy the permanent -image to the device with :command:`ssh` - -.. code-block:: console - - build-machine$ tar chf - result/firmware.bin | \ - ssh root@the-device tar -C /run -xvf - - -Next you need to connect to the device and locate the "firmware" -partition, which you can do with a combination of :command:`dmesg` -output and the contents of :file:`/proc/mtd` - -.. code-block:: console - - <5>[ 0.469841] Creating 4 MTD partitions on "spi0.0": - <5>[ 0.474837] 0x000000000000-0x000000040000 : "u-boot" - <5>[ 0.480796] 0x000000040000-0x000000050000 : "u-boot-env" - <5>[ 0.487056] 0x000000050000-0x000000060000 : "art" - <5>[ 0.492753] 0x000000060000-0x000001000000 : "firmware" - - # cat /proc/mtd - dev: size erasesize name - mtd0: 00040000 00001000 "u-boot" - mtd1: 00010000 00001000 "u-boot-env" - mtd2: 00010000 00001000 "art" - mtd3: 00fa0000 00001000 "firmware" - mtd4: 002a0000 00001000 "kernel" - mtd5: 00d00000 00001000 "rootfs" - -Now run (in this example) - -.. code-block:: console - - flashcp -v firmware.bin /dev/mtd3 - - -"I know my new image is good, can I skip the intemediate step?" -``````````````````````````````````````````````````````````````` - -In addition to giving you a chance to see if the new image works, this -two-step process ensures that you're not copying the new image over -the top of the active root filesystem. It might work, or it might -crash in surprising ways. - - - -Flashing from OpenWrt (not currently advised!) -~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ - -.. CAUTION:: At your own risk! This will (at least in some - circumstances) lead to bricking the device: we think this - flash method is currently incompatible with use of a - writeable (jffs2) filesystem. - -If your device is running OpenWrt then it probably has the -:command:`mtd` command installed. After transferring the image onto the -device using e.g. :command:`ssh`, you can run it as follows: - -.. code-block:: console - - mtd -r write /tmp/firmware.bin firmware - -For more information, please see the `OpenWrt manual `_ which may also contain (hardware-dependent) instructions on how to flash an image using the vendor firmware - perhaps even from a web interface. - - -Updating an installed system (JFFS2) -************************************ - -Adding packages -=============== - - -If your device is running a JFFS2 root filesystem, you can build -extra packages for it on your build system and copy them to the -device: any package in Nixpkgs or in the Liminix overlay is available -with the ``pkgs`` prefix: - -.. code-block:: console - - nix-build -I liminix-config=./my-configuration.nix \ - --arg device "import ./devices/mydevice" -A pkgs.tcpdump - - nix-shell -p min-copy-closure root@the-device result/ - -Note that this only copies the package to the device: it doesn't update -any profile to add it to ``$PATH`` - - -Rebuilding the system -===================== - -:command:`liminix-rebuild` is the Liminix analogue of :command:`nixos-rebuild`, although its operation is a bit different because it expects to run on a build machine and then copy to the host device. Run it with the same ``liminix-config`` and ``device`` parameters as you would run :command:`nix-build`, and it will build any new/changed packages and then copy them to the device using SSH. For example: - -.. code-block:: console - - liminix-rebuild root@the-device -I liminix-config=./examples/rotuer.nix --arg device "import ./devices/gl-ar750" - -This will - -* build anything that needs building -* copy new or changed packages to the device -* reboot the device - -It doesn't delete old packages automatically: to do that run -:command:`min-collect-garbage`, which will delete any packages not in -the current system closure. Note that Liminix does not have the NixOS -concept of environments or generations, and there is no way back from -this except for building the previous configuration again. - - - -Caveats -~~~~~~~ - -* it needs there to be enough free space on the device for all the new - packages in addition to all the packages already on it - which may be - a problem if a lot of things have changed (e.g. a new version of - nixpkgs). - -* it cannot upgrade the kernel, only userland - -Configuration options -********************* - -.. _module-options: - -.. include:: modules.rst diff --git a/examples/hellonet.nix b/examples/hellonet.nix new file mode 100644 index 0000000..b5373d7 --- /dev/null +++ b/examples/hellonet.nix @@ -0,0 +1,50 @@ +{ config, pkgs, lib, ... } : +let + inherit (pkgs) serviceFns; + svc = config.system.service; + +in rec { + imports = [ + ../modules/network + ../modules/dnsmasq + ../modules/ntp + ../modules/ssh + ]; + hostname = "hellonet"; + + services.int = svc.network.address.build { + interface = config.hardware.networkInterfaces.lan; + family = "inet"; address ="10.3.0.1"; prefixLength = 16; + }; + + services.ntp = svc.ntp.build { + pools = { "pool.ntp.org" = ["iburst"]; }; + makestep = { threshold = 1.0; limit = 3; }; + }; + + services.sshd = svc.ssh.build { }; + + users.root = { + passwd = ""; + }; + + services.dns = + let interface = services.int; + in svc.dnsmasq.build { + inherit interface; + ranges = [ + "10.3.0.10,10.3.0.240" + # ra-stateless: sends router advertisements with the O and A + # bits set, and provides a stateless DHCP service. The client + # will use a SLAAC address, and use DHCP for other + # configuration information. + "::,constructor:$(output ${interface} ifname),ra-stateless" + ]; + + domain = "example.org"; + }; + + defaultProfile.packages = with pkgs; [ + figlet + ]; +}