Alpine for the Orange Pi Zero
Running in RAM, using an SD card only for initial loading of the filesystem and configuration storage.
Pre-built files, ready to go, can be found in builds/
. There is also a Makefile which allows easy customization and building using either files in configs/
or defconfigs as a base to work from.
The built kernel images are intentionally quite minimal, and no modules are included other than for the WiFi, to keep the size down. The default build is intended to be a base to build from, it should be everything necessary to run all the hardware on the Orange Pi Zero, but nothing else. Any other builds in this repo will generally be the bare minimum for a particular application of mine. You'll probably need to build your own kernel to suit your application and/or support any devices you might attach, unless your application happens to be quite similar to something I've already built for.
U-Boot 2020.04-rc5_opizero
# uname -r
5.6.0-rc4_opizero_default-g6a8c531e7
# cat /etc/alpine-release
3.11.3
This is a work in progress. Not everything necessarily functions, not everything will necessarily be made to function. (Although if you want to make something function that doesn't feel free to fork and pull request.)
The script scripts/write_sd.sh
will automatically configure an SD card with a bootable Alpine from a build folder (it expects to see apks/
, boot/
and u-boot-sunxi-with-spl.bin
). If no <path>
argument is specified it default to the directory it was run from. Be careful about specifying the correct device because the script will happily rewrite the partition table of any device you point it at.
Usage: sudo ./write_sd.sh <device> <path>
Example: sudo ./write_sd.sh /dev/sda builds/default/
The script scripts/copy_sd.sh
will copy kernel files to an already-prepared SD card (with U-Boot already written and the apks/
folder already present), useful for testing new builds without losing Alpine configuration that is already done. As with the write_sd.sh
script, it wants to be executed inside a build folder or with the path of a build folder specified as the <path>
argument.
Usage: sudo ./copy_sd.sh <device> <path>
Example: sudo ./copy_sd.sh /dev/sda builds/default/
A manual approach is safer, with less risk of accidentally aiming dd
and fdisk
at the wrong device.
- zero the start of the SD card
dd if=/dev/zero of=<device> bs=1M count=1
- write u-boot
dd if=u-boot-sunxi-with-spl.bin of=<device> bs=1024 seek=8
- create a FAT32 partition with fdisk (although u-boot will handle other partition types if you prefer)
fdisk <device>
n
# add newp
# primary partition1
# numbered 12048
# from sector 2048<enter>
# to the last sectort
# of typec
# W95 FAT32 (LBA)a
# make it bootablew
# save changesq
# exit fdisk
- format and label partition
mkfs.vfat -n ALPINE <partition>
- create folder (if necessary) and mount the SD card
mkdir <mount_path>
sudo mount <partition> <mount_path>
- copy
apks
andboot
foldercp -r apks <mount_path>
cp -r boot <mount_path>
- unmount the SD card and remove the folder (if desired)
sudo umount <partition>
rm -rf <mount_path>
- eject the SD card before removing it
eject <device>
There's a basic Autoconf script and a Makefile to build any or all required files from source. To build with the default configuration all that's required is:
./configure
make install
This has been tested on Ubuntu Bionic, however, it should function just fine on other distros. The prerequisites for building can be installed with apt-get
on distros that use it:
sudo apt-get -y --no-install-recommends --fix-missing install \
gcc-arm-linux-gnueabihf gcc automake make bison flex swig python-dev musl \
u-boot-tools dosfstools device-tree-compiler \
git wget pv
At the moment this doesn't actually configure any part of the build process, it just checks the build environment for required dependencies and warns if any are missing. It doesn't strictly need to be run, missing dependencies will become evident during the build process itself, it's just for convenience.
The Makefile will fetch all necessary source files and build whatever needs to be built. make help
will give a list of options, make info
will show build parameters (which can be changed by editing variables defined at the top of the Makefile). To build a complete set of files, ready to go onto an SD card, all you need to do is type make install
and everything else should sort itself out.
Menuconfig will pop up for the builds of U-Boot and the linux kernel but the build process is otherwise non-interactive. Completed build files will output into files/
, builds of individual components (e.g. make uboot
, make linux
) will output into the respective source folders.
It wouldn't be hard to adapt the Makefile to work with other devices, it's just a matter of providing appropriate config files and device trees.
At the moment the Alpine filesystem that loads is taken directly from the generic ARM distro and not modified.
The default login is root
with no password.
Initial configuration on first boot can be done with alpine-setup
. It's a good idea to apk add haveged
and start it as a service as part of the initial setup (especially if you're using the WiFi with WPS, but several services will load faster with more entropy available), once repos are configured. As we're running in RAM any config changes will need to be committed to the SD card with lbu ci
or they'll be lost on reboot.
At some point I plan to customize the OS a bit more, integrating a rootfs builder that allows package selection into the build process in one way or another.
DT overlays can be applied at boot using the boot/bootEnv.txt
file (which will be in /media/mmcblk0p1/
from within the booted OS). The environment variable overlays
should be set to a space separated string of overlays to load. The overlay DTBO files themselves will be in boot/dtbs/overlays
and prefixed with sun8i-h2-plus-
.
The overlays created during the build process have generally not been individually tested, they're just pulled directly from the relevant Armbian repo and renamed. The main device tree file is (currently) built from the linux-sunxi kernel source, however, so there may be some incompatibilities.
Preferentially, make install
(via make overlays
) will build overlays from configs/overlays
. Any *.dts
files in this folder will be used if they exist, regardless of any files with matching names existing in the source.
The comments in the sections below apply to the default build (builds/default
, configs/kernel.default.config
).
Any other configs/*.config
files that may be present are works in progress and should be assumed to be entirely non-functional.
Seems to function just fine.
The xradio WiFi is generally functional, although there will be many "missed interrupt" warnings in the log and some (presumably) associated packet loss. This seems to be caused by an issue in the hardware and/or the driver and is not exclusive to this build.
It can be started with wpa_supplicant
directly from the command line, or as a service via OpenRC, adding the following to /etc/conf.d/wpa_supplicant
:
wpa_supplicant_args="-B -i wlan0 -c /etc/wpa_supplicant/wpa_supplicant.conf"
Starting wpa_supplicant at the boot runlevel will cause the boot process to pause for an annoying length of time as it tries to configure the WiFi, due to a lack on entropy at boot. Having haveged running before starting wpa_supplicant dramatically improves this, the easiest way to achieve this is to start haveged as a boot service and wpa_supplicant as a default service:
apk add haveged
rc-update add haveged boot
rc-update add wpa_supplicant default
In theory it should be possible to make haveged start before wpa_supplicant on the same runlevel by adding appropriate before/after/use/want parameters to the depends() block in the /etc/init.d/
files, but this isn't working for me at the moment and I've so far not put the effort in to figure out why.
The UART TX/RX/GND pins, next to the ethernet connector, work as advertised, allowing monitoring of the boot process and providing serial console access as you'd expect.
Make sure you're using a 3.3V serial adapter, the board won't like 5V RS-232 (and if you try +/-15V old-school RS-232 set up a video camera first because I'm curious which components will let the magic smoke out first).
The serial console runs at 115,200 baud (8N1).
The USB 2.0 port detects and can read/write USB flash drives, I've not yet tested it beyond that.
Untested. dmesg
will have a few complaints about various bits and pieces of hardware.
It's not been a priority for me so far to plug things into the pin headers to see what happens, or to investigate these issues more generally. My intended application for the OPiZero only requires ethernet and a functional UART, although ideally I will get around to looking at other aspects at some point.
- build a better initramfs with Alpine rootfs build tools, rather than cut and paste from the generic ARM release
- build a more complete kernel with a variety of modules for common hardware included so we have a device that has working header/GPIO pins and a USB port all sorts of things can be attached to
- see what an absolute minimal build looks like in terms of functionality, and how much of a size reduction it provides
- with a bit of luck, fit the whole thing on a 128Mb/16MB SPI NOR
- try not to get distracted and/or lose interest and actually implement the above