305 lines
10 KiB
ReStructuredText
305 lines
10 KiB
ReStructuredText
User Manual
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###########
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This manual is an early work in progress, not least because Liminix is
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not yet really ready for users who are not also developers. Your
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feedback to improve it is very welcome.
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Installation
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************
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The Liminix installation process is not quite like installing NixOS on
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a real computer, but some NixOS experience will nevertheless be
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helpful in understanding it. The steps are as follows:
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* Decide whether you want the device to be updatable in-place (there
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are advantages and disadvantages), or if you are happy to generate
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and flash a new image whenever changes are required.
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* Create a :file:`configuration.nix` describing the system you want
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* Build an image
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* Flash it to the device
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Choosing a flavour (read-only or updatable)
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===========================================
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Liminix installations come in two "flavours"- read-only or in-place
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updatable:
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* a read-only installation can't be updated once it is flashed to your
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device, and so must be reinstalled in its entirety every time you
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want to change it. It uses the ``squashfs`` filesystem which has
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very good compression ratios and so you can pack quite a lot of
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useful stuff onto your device. This is good if you don't expect
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to change it often.
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* an updatable installation has a writable filesystem so that you can
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update configuration, upgrade packages and install new packages over
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the network after installation. This uses the `jffs2
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<http://www.linux-mtd.infradead.org/doc/jffs2.html>`_ filesystem:
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although it does compress the data, the need to support writes means
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that it can't pack quite as small as squashfs, so you will not have
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as much space to play with.
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Updatability caveats
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~~~~~~~~~~~~~~~~~~~~
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At the time of writing this manual the read-only squashfs support is
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much more mature. Consider also that it may not be possible to perform
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"larger" updates in-place even if you do opt for updatability. If you
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have (for example) an 11MB system on a 16MB device, you won't be able
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to do an in-place update of something fundamental like the C library
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(libc), as this will temporarily require 22MB to install all the
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packages needing the new library before the packages using the old
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library can be removed. A writable system will be more useful for
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smaller updates such as installing a new package (perhaps you
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temporarily need tcpdump to diagnose a network problem) or for
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changing configuration files.
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Note also that the kernel is not part of the filesystem so cannot be
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updated this way. Kernel changes require a full reflash.
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Creating configuration.nix
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==========================
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You need to create a :file:`configuration.nix` that describes your device
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and the services that you want to run on it. Start by copying
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:file:`vanilla-configuration.nix` and adjusting it, or look in the `examples`
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directory for some pre-written configurations.
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:file:`configuration.nix` conventionally describes the packages, services,
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user accounts etc of the device. It does not describe the hardware
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itself, which is specified separately in the build command (as you
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will see below).
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Your configuration may include modules: it probably *should*
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include the ``standard`` module unless you understand what it
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does and what happens if you leave it out.
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.. code-block:: nix
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imports = [
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./modules/standard.nix
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]
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configuration.rootfsType = "jffs2"; # or "squashfs"
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Building
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========
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Build Liminix using the :file:`default.nix` in the project toplevel
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directory, passing it arguments for configuration and hardware. For
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example:
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.. code-block:: console
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nix-build -I liminix-config=./tests/smoke/configuration.nix \
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--arg device "import ./devices/qemu" -A outputs.default
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In this command ``<liminix-config>`` points to your
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:file:`configuration.nix`, ``device`` is the file for your hardware device
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definition, and ``outputs.default`` will generate some kind of
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Liminix image output appropriate to that device.
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For the qemu device in this example, ``outputs.default`` is an alias
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for ``outputs.vmbuild``, which creates a directory containing a
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squashfs root image and a kernel. You can use the :command:`mips-vm` command to
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run this.
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For the currently supported hardware devices, ``outputs.default``
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creates a directory containing a file called ``firmware.bin``. This
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is a raw image file that can be written directly to the firmware flash
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partition.
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Flashing
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========
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Flashing from OpenWrt (untested)
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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If your device is running OpenWrt then it probably has the
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:command:`mtd` command installed and you can use it as follows:
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.. code-block:: console
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mtd -r write /tmp/firmware_image.bin firmware
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For more information, please see the `OpenWrt manual <https://openwrt.org/docs/guide-user/installation/sysupgrade.cli>`_ which may also contain (hardware-dependent) instructions on how to flash an image using the vendor firmware - perhaps even from a web interface.
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Flashing from the boot monitor
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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If you are prepared to open the device and have a TTL serial adaptor
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of some kind to connect it to, you can probably flash it using U-Boot.
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This is quite hardware-specific, and sometimes involves soldering:
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please refer to the Developer Manual.
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Flashing from an existing Liminix system with :command:`flashcp`
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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The flash procedure from an existing Liminix-system is two-step.
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First we reboot the device (using "kexec") into an "ephemeral"
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RAM-based version of the new configuration, then when we're happy it
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works we can flash the image - and if it doesn't work we can reboot
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the device again and it will boot from the old image.
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Building the RAM-based image
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............................
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To create the ephemeral image, build ``outputs.kexecboot`` instead of
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``outputs.default``. This generates a directory containing the root
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filesystem image and kernel, along with an executable called `kexec`
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and a `boot.sh` script that runs it with appropriate arguments.
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For example
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.. code-block:: console
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nix-build --show-trace -I liminix-config=./examples/arhcive.nix \
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--arg device "import ./devices/gl-ar750"
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-A outputs.kexecboot && \
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(tar chf - result | ssh root@the-device tar -C /run -xvf -)
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and then login to the device and run
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.. code-block:: console
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cd /run/result
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sh ./boot.sh .
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This will load the new kernel and map the root filesystem into a RAM
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disk, then start executing the new kernel. *This is effectively a
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reboot - be sure to close all open files and finish anything else
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you were doing first.*
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If the new system crashes or is rebooted, then the device will revert
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to the old configuration it finds in flash.
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Building the second (permanent) image
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.....................................
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While running in the kexecboot system, you can copy the permanent
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image to the device with :command:`ssh`
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.. code-block:: console
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build-machine$ tar chf - result/firmware.bin | \
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ssh root@the-device tar -C /run -xvf -
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Next you need to connect to the device and locate the "firmware"
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partition, which you can do with a combination of :command:`dmesg`
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output and the contents of :file:`/proc/mtd`
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.. code-block:: console
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<5>[ 0.469841] Creating 4 MTD partitions on "spi0.0":
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<5>[ 0.474837] 0x000000000000-0x000000040000 : "u-boot"
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<5>[ 0.480796] 0x000000040000-0x000000050000 : "u-boot-env"
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<5>[ 0.487056] 0x000000050000-0x000000060000 : "art"
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<5>[ 0.492753] 0x000000060000-0x000001000000 : "firmware"
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# cat /proc/mtd
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dev: size erasesize name
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mtd0: 00040000 00001000 "u-boot"
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mtd1: 00010000 00001000 "u-boot-env"
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mtd2: 00010000 00001000 "art"
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mtd3: 00fa0000 00001000 "firmware"
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mtd4: 002a0000 00001000 "kernel"
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mtd5: 00d00000 00001000 "rootfs"
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Now run (in this example)
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.. code-block:: console
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flashcp -v firmware.bin /dev/mtd3
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"I know my new image is good, can I skip the intemediate step?"
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```````````````````````````````````````````````````````````````
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In addition to giving you a chance to see if the new image works, this
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two-step process ensures that you're not copying the new image over
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the top of the active root filesystem. It might work, or it might
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crash in surprising ways.
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Updating an installed system (JFFS2)
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************************************
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Adding packages
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===============
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If your device is running a JFFS2 root filesystem, you can build
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extra packages for it on your build system and copy them to the
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device: any package in Nixpkgs or in the Liminix overlay is available
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with the ``pkgs`` prefix:
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.. code-block:: console
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nix-build -I liminix-config=./my-configuration.nix \
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--arg device "import ./devices/mydevice" -A pkgs.tcpdump
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nix-shell -p min-copy-closure root@the-device result/
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Note that this only copies the package to the device: it doesn't update
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any profile to add it to ``$PATH``
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Rebuilding the system
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=====================
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: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:
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.. code-block:: console
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liminix-rebuild root@the-device -I liminix-config=./examples/rotuer.nix --arg device "import ./devices/gl-ar750"
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This will
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* build anything that needs building
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* copy new or changed packages to the device
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* reboot the device
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It doesn't delete old packages automatically: to do that run
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:command:`min-collect-garbage`, which will delete any packages not in
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the current system closure. Note that Liminix does not have the NixOS
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concept of environments or generations, and there is no way back from
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this except for building the previous configuration again.
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Caveats
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~~~~~~~
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* it needs there to be enough free space on the device for all the new
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packages in addition to all the packages already on it - which may be
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a problem if a lot of things have changed (e.g. a new version of
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nixpkgs).
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* it cannot upgrade the kernel, only userland
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Configuration Options
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*********************
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Module docs will go here. This part of the doc should be autogenerated.
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