commit | c81b6e51903e18bf73bf0c8dde15b1aedcbd78f9 | [log] [tgz] |
---|---|---|
author | Jan Kundrát <jan.kundrat@cesnet.cz> | Tue Nov 14 11:45:00 2023 +0100 |
committer | Jan Kundrát <jan.kundrat@cesnet.cz> | Tue Nov 14 11:45:00 2023 +0100 |
tree | a2118b798e0bd29888e6704ee28526dad7bbee68 | |
parent | ca697b9bbc767370b85d6c8e023600b8e684be72 [diff] |
docs: RAUC updates handle config upgrades just fine Since the introduction of migrations, it's expected that all updates will work just fine. Downgrades might be problematic for obvious reasons, so let's at least hint at that in the docs without going into too many details (it's a landing page with README, not a complete troubleshooting guide). Change-Id: I5efc44abea846a1dd43f016bfdf9554068e7c86a
This repository contains CzechLight-specific bits for Buildroot. Buildroot is a tool which produces system images for flashing to embedded devices. They have a nice documentation which explains everything that one might need.
The system architecture is described in another document. This is a quick build HOWTO.
Everything is in Gerrit. One should not need to clone anything from anywhere else. The build will download source tarballs of various open source components, though.
By default, each change of this repo uploaded to Gerrit causes the CI system to produce a firmware update. On Gerrit, the change will get a comment from Zuul with a link to the CI log server. Next to the logs, a file named artifacts/update.raucb
can be used for updating devices.
Behind the scenes, the system uses Zuul with a configuration tracked in git.
Here's how to reproduce the build on a developer's workstation:
git clone ssh://$YOUR_LOGIN@cesnet.cz@gerrit.cesnet.cz:29418/CzechLight/br2-external czechlight pushd czechlight git submodule update --init --recursive popd mkdir build-clearfog cd build-clearfog ../czechlight/dev-setup-git.sh make czechlight_clearfog_defconfig make -j8
A full rebuild takes about half an hour on a modern laptop.
WARNING: Buildroot is fragile. It is not safe to perform incremental builds after changing an "important" setting. Please check their manual for details.
Apart from the traditional way of re-flashing the SD card or the eMMC from scratch, it's also possible to use RAUC to update. This method preserves the U-Boot version and the U-Boot's environment. Apart from that, everything starting with the kernel and the DTB file and including the root FS is updated. Configuration stored in /cfg
is brought along and preserved as well.
To install an update:
# build node make rsync -avP images/update.raucb somewhere.example.org:path/to/web/root # target, perhaps via an USB console or over SSH rauc install http://somewhere.example.org/update.raucb reboot
Once the updated FW slot boots, the configuration in /cfg
will be automatically upgraded ("migrated") to the newest layout. A downgrade to an incompatible OS version might therefore fail during the next reboot. Completely removing all data in the newly updated slot's cfg
partition will restore functionality, but it is effectively a factory reset.
On a regular Clearfog Base with an eMMC, one has to bootstrap the device first. If recovering a totally bricked board (or one that is fresh from factory), use the kwboot
command to upload the initial, new enough U-Boot via the console. Ensure that the jumpers are set to 0 1 0 0 1
(default for eMMC boot is 0 0 1 1 1
), and then use U-Boot's kwboot
tool:
./host/bin/kwboot -b ./u-boot-spl.kwb -t -p /dev/ttyUSB0
Prepare a USB flash disk with a raw bootable image, images/usb-flash.img
. Use a tool such as dd
to overwrite the raw block device, do not copy the image file. Once in U-Boot, plug the USB flash disk and execute:
usb start; fatload usb 0:1 00800000 boot.scr; source 00800000
The system will boot and flash the eMMC from the USB drive. Once the status LED starts blinking in yellow, data are being transferred to the eMMC. The light changes to solid yellow in later phases of the flashing process. Once everything is done, the status LED shows a solid white light and the system reboots automatically.
Turn off power, remove the USB flash, re-jumper the board (0 0 1 1 1
), power-cycle, and configure MAC addresses at the U-Boot prompt. The MAC addresses are found on the label at the front panel.
=> setenv eth1addr 00:11:17:01:XX:XX => setenv eth2addr 00:11:17:01:XX:YY => setenv eth3addr 00:11:17:01:XX:ZZ
Also set up the system type:
Model | czechlight variable value |
---|---|
ROADM Line Degree | sdn-roadm-line-g2 |
WSS Add/Drop | sdn-roadm-add-drop-g2 |
Hi-resolution Add/Drop | sdn-roadm-hires-add-drop-g2 |
Coherent Add/Drop | sdn-roadm-coherent-a-d-g2 |
Inline EDFA Amplifier | sdn-inline-g2 |
Some prototypes have deprecated PCBs (blue). On these, skip the -g2
suffix. All red PCBs are -g2
.
=> setenv czechlight sdn-roadm-line-g2 => saveenv Saving Environment to MMC... Writing to redundant MMC(0)... OK => boot
Once the system boots (which currently requires a reboot for some unknown reason -- fsck, perhaps?), configure hostname, plug in the network cable, and update SW:
# hostnamectl set-hostname line-XYZSERIALNO # cp /etc/hostname /cfg/etc/ # rauc install http://somewhere.example.org/update.raucb # reboot
Obtain a reasonable Linux distro image for BBB and flash it to a µSD card. Unlock eMMC boot partitions (echo 0 > /sys/class/block/mmcblk1boot0/force_ro; echo 0 > /sys/class/block/mmcblk1boot1/force_ro
). Clean the eMMC data (blkdiscard /dev/mmcblk1
). Flash the content of images/emmc.img
to device's /dev/mmcblk1
. Flash what fits into /dev/mmcblk1boot0
and /dev/mmcblk1boot1
. Fetching the image over web (python3 -m http.server
and wget http://...:8000/emmc.img -O - | dd of=/dev/mmcblk1 conv=sparse
) works well.