Table of Contents

1. Electron Fiddle
2. Electron Releases

Recently, I have been working on an issue in Electron, which required bisecting and finding the exact version of Electron, when the regression happened.

A quick research did not reveal any guides, but as my search was progressing, I found one interesting commit - feat: add Bisect helper.

Electron Fiddle

Fiddle is an Electron playground that allows developers to experiment with Electron APIs. It has a quick startup template, which you can change as you wish. You can save fiddle locally or as a GitHub Gist, which can be shared with anyone by just entering the Gist URL in the address bar.

Moreover, you can choose what Electron version you wish to use - from stable to nightly releases.

Electron Releases

You can run fiddle using any version of Electron you wish - either stable, beta, or nightly. One can either run fiddle with obsolete versions, which is super great when comparing behaviour between different versions.

An option to choose the version of the Electron can be found at the top-left corner of the Fiddle window.

Once pressed, you can use filter to choose any Electron version you wish.

However, you may not find beta or nightly versions in the filter. For that, go to Settings (a gear icon on the left of the filter), then Electron, and select the desired channels.

Now, you can access all the available Electron versions and try any of them on the fly.

I hope this small guide helps you to triage your Electron problems :)))

Hey there! I’m glad to finally start paying my blogging debt :) as this is something I’ve been planning to do for quite some time. To get the ball rolling, I’ve shared some bits about me in my very first blog post Olá Mundo.

In this article, I’m going to walk through what we’ve been working on since last year in the Chromium Ozone/Wayland project, on which I’ve been involved (directly or indirectly) since I’ve joined Igalia back in 2018.

Igalia is arranging the twelfth annual Web Engines Hackfest, which will be held on Monday 2nd June through Wednesday 4th June. As usual, this is a hybrid event, at Palexco in A Coruña (Galicia, Spain) as well as remotely.

Registration is now open:

• Submit your talks and breakout sessions. The deadline to submit proposals is Wednesday 30th April.
• Fill out this form if you’re attending onsite (you don’t need to do it to participate remotely). Registration closes on Sunday 18th May.
• List of early birds that have already registered

The Web Engines Hackfest is an event where folks working on various parts of the web platform gather for a few days to share knowledge and discuss a variety of topics. These topics include web standards, browser engines, JavaScript engines, and all the related technology around them. Last year, we had eight talks (watch them on YouTube) and 15 breakout sessions (read them on GitHub).

A wide range of experts with a diverse set of profiles and skills attend each year, so if you are working on the web platform, this event is a great opportunity to chat with people that are both developing the standards and working on the implementations. We’re really grateful for all the people that regularly join us for this event; you are the ones that make this event something useful and interesting for everyone! 🙏

The breakout sessions are probably the most interesting part of the event. Many different topics are discussed there, from high-level issues like how to build a new feature for the web platform, to lower-level efforts like the new WebKit SDK container. Together with the hallway discussions and impromptu meetings, the Web Engines Hackfest is an invaluable experience.

Big shout-out to Igalia for organising the Web Engines Hackfest every year since 2014, as well as the original WebKitGTK+ Hackfest starting in 2009. The event has grown and we’re now close to 100 onsite participants with representation from all major browser vendors. If your organization is interested in helping make this event possible, please contact us regarding our sponsorship options.

See you all in June!

Update on what happened in WebKit in the week from February 11 to February 18.

Cross-Port 🐱

Multimedia 🎥

Infrastructure 🏗️

Table of Contents

1. The IEEE 754 Standard and Floating-Point Imprecision
2. How the libwayland Update Exposed the Issue
3. Chromium’s Targeted Fix: RoundToNearestThousandth

Floating-point arithmetic under the IEEE 754 standard introduces subtle precision errors due to the inherent limitations of representing decimal numbers in binary form. In graphical applications like Chromium, even tiny discrepancies can manifest as rendering inconsistencies. Recent updates in libwayland’s conversion routines have uncovered such a floating-point precision issue in Chromium’s Ozone/Wayland layer—one that was previously masked by legacy conversion behavior.

The IEEE 754 Standard and Floating-Point Imprecision

The IEEE 754 standard governs how floating-point numbers are represented and manipulated in most modern computing systems. Because many decimals (for example, 0.2) cannot be exactly represented in binary being limited to 32 or 64 bits, their results are actually stored as approximations.

This limited precision means that arithmetic operations can introduce small errors. In many cases, these errors are negligible, but in precision-sensitive environments like graphical rendering, even minor inaccuracies can lead to visible artifacts.

The standard has 3 basic components:

• The Sign of Mantissa - in other words, the sign bit.
• The Biased exponent - this field is designed to encode both positive and negative values by adding a fixed bias to the actual exponent, thereby converting it into a non-negative stored form.
• The Normalised Mantissa - this component represents the significant digits of a number in scientific or floating-point notation. In normalized form, the mantissa is adjusted so that only one nonzero digit—specifically, a single “1”—appears immediately to the left of the decimal point.

Consider the number 0.2. Its binary representation is an infinitely repeating fraction:

0.2 = 0.0011 0011 0011 … (in binary)

Note that the pattern of 0011 repeats indefinitely.

If 0.2 is represented in the IEEE 754 form (32 bits), it takes the following form -

0 01111101 10011001100110011001101

As a result, the repeating nature of these binary representations leads to approximation and precision challenges when dealing with floating-point arithmetics.

0.1 + 0.2 != 0.3

How the libwayland Update Exposed the Issue

Libwayland historically provided a utility to convert integer values into a fixed-point format (wl_fixed) for use in various graphical calculations. However, it carried an unintended side effect: an implicit rounding of the result. This rounding acted as a “safety net,” smoothing over the small imprecisions that naturally occur with floating-point arithmetic.

An update to libwayland refined the conversion routine by making it more precise. The function responsible for converting floating-point values to fixed-point values — commonly used in operations like wl_fixed_to_double — no longer introduced the implicit rounding that was part of the old implementation. With this improved precision, the floating-point discrepancies, previously hidden by the rounding effect, began to surface in the Chromium Ozone/Wayland layer, causing subtle yet noticeable differences in viewport calculations.

Chromium’s Targeted Fix: RoundToNearestThousandth

To restore consistency in graphical rendering following the libwayland update, we needed to address the newly exposed precision error. In commit 6187087, the solution was to reintroduce rounding explicitly within the Ozone/Wayland layer. It was decided to implement a utility function named RoundToNearestThousandth to round the viewport source value to the nearest thousandth. This explicit rounding step effectively recreates the smoothing effect that the old implicit conversion provided, ensuring that minor floating-point errors do not result in visible inconsistencies.

By aligning the rounding behavior of the Ozone/Wayland component with that of Chromium’s cc/viz module, the fix ensures consistent and reliable rendering across the browser’s graphical stack. This deliberate approach to handling floating-point imprecision highlights the importance of explicit error management in complex software systems.

At Igalia, we believe in building open and interoperable platforms, and we’ve found that for such platforms to succeed, it is essential to combine a clear standard with an extensive test suite. We’ve worked on a number of such test suites, ranging from the official JavaScript conformance test suite test262 and web-platform-tests, which covers the rest of the web platform, to the Khronos Vulkan and OpenGL CTS. Our experience has consistently shown that the existence of a thorough test suite that is easy for implementers to run, helps significantly to get different products to interoperate in the real world.

An important way to maximize the coverage of such a test suite is to encourage implementers to share the tests they are writing as part of their implementation work. In the first place, it is helpful to share new tests – a great success story here is the web-platform-tests project, which has two-way synchronization tooling for the major browsers. This allows developers to write tests directly within their own project, which are then shared more or less automatically. However, for mature platforms, especially when the platform and implementations are older than the centralised test suite, there is often a large backlog of existing tests. We would love to see more of these tests made available.

During 2024, we looked in particular at contributing such backlog tests to test262. We identified SpiderMonkey’s non262 suite as a potential source of interesting tests for this purpose. This test suite is interesting for several reasons.

In the first place, it is part of the larger jstests suite, which also contains the upstream test262 tests (hence the name). This meant we did not expect architectural issues to crop up when upstreaming those tests. Second, as a test suite built by JavaScript engine implementers, it seemed likely to contain tests for edge cases and requirements that changed over time. It is not uncommon for several implementers to be caught out by the same issue, so such tests are more likely to find bugs in other engines as well.

During our investigation, we discovered that our friends at Bocoup had a similar idea back in 2017, and they had created a python script to transform parts of the jstests suite to work within the test262 test suite, which we gratefully reused. However, some issues quickly came to light: it had been written for Python 2, and its unit test had not been enabled in continuous integration, so it needed some work to be of use in 2024. Once that was done, we discovered that the script had been used as part of a mostly manual process to submit specifically curated tests, and it could not cope with the diversity and complexity of the whole test suite without significant up-front work to put the tests into a shape that it could deal with. We suspect that this is part of the reason that their project did not bear all that much fruit in the end, and decided that our approach needed to maximize the number of shared tests for the effort expended.

After getting the script into shape, we set to work on a batch export of the non262 test suite. In order to verify the quality of the exported tests, we ran the tests against both SpiderMonkey and V8 using the upstream tooling. This process revealed several issues—some anticipated, others more unexpected. For example, a large number of tests used helper functions that were only available in SpiderMonkey, which we either needed to provide in test262 or automatically translate to an existing helper function. Other APIs, for example those testing specific details of the garbage collection implementation, could not be reproduced at all.

Besides that, a fair number of tests relied on specifics of the SpiderMonkey implementation that were not guaranteed by the standard – such as testing exact values of the error.message property or the handling of particular bit patterns in typed arrays. Some tests also turned out not to be testing what they were meant to test or covered a previous version of the specification or a not-yet-finalized proposal. Depending on the situation, we improved the tests and added APIs to make it possible to share them, or we skipped exporting the offending tests.

We also discovered some issues in the test262-harness tool that we used to run the tests upstream, notably around tests using JavaScript modules and the [[IsHTMLDDA]] internal slot (used to specify the web compatibility requirements around document.all). Also, it turned out that the mechanism to include helper libraries into tests was not fully specified, which led to some combinations of helpers to work in some test runners but not others. We have started the process to clarify the documentation on this point.

As part of this project so far, we landed about 1600 new tests into test262 and filed 10 bugs (some covering failures in multiple tests), of which half have been fixed by the engine maintainers. Several failures also were the result of bugs that had been filed earlier but hadn’t been fixed yet. Also, Mozilla has decided to remove the exported tests from their own repository, and to use the centralised copies instead.

In terms of future work for this particular project, we’re expecting to investigate if we can share some more of the tests that are currently skipped. Separately we’re interested in looking into a fully automated two-way synchronization system; this would significantly ease the cooperation of engine developers and project maintainers on a unified test suite, though the engineering effort would be commensurate. We’ll also continue investigating if we can identify other test suites that can benefit from a similar treatment.

We would like to thank Bloomberg for sponsoring this work and the Mozilla community, in particular Dan Minor, for their indispensable help and code reviews.

Recently Node.js started to support building with clang-cl on Windows. I happened to have the chance to try it out this week and while it still needs some fixups in my case, it’s mostly working very well now. Here are some notes about this

Update on what happened in WebKit in the week from February 3 to February 11.

Cross-Port 🐱

Multimedia 🎥

Graphics 🖼️

Releases 📦️

This blog post is to announce that Igalia has gotten a grant from NLnet Foundation to work on solving cross-root ARIA issues in Shadow DOM. My colleague Alice Boxhall, which has been working on sorting out this issue since several years ago, together with support form other igalians is doing the work related to this grant.

The Problem #

Shadow DOM has some issues that prevent it to be used in some situations if you want to have an accessible application. This has been identified by the Web Components Working Group as one of the top priority issues that need to be sorted out.

Briefly speaking, there are mainly two different problems when you want to reference elements for ARIA attributes cross shadow root boundaries.

First issue is that you cannot reference things outside the Shadow DOM. Imagine you have a custom element (#customButton) which contains a native button in its Shadow DOM, and you want to associate the internal button with a label (#label) which is outside in the light DOM.

<label id="label">Label</label>
<custom-button id="customButton">
  <template shadowrootmode="open">
    <div>foo</div>
    <button aria-labelledby="label">Button</button>
    <div>bar</div>
  </template>
</custom-button>

And the second problem is that you cannot reference things inside a Shadow DOM from the outside. Imagine the opposite situation where you have a custom label (#customLabel) with a native label in its Shadow DOM that you want to reference from a button (#button) in the light DOM.

<custom-label id="customLabel">
  <template shadowrootmode="open">
    <div>foo</div>
    <label>Label</label>
    <div>bar</div>
  </template>
</custom-label>
<button id="button" aria-labelledby="customLabel">Button</button>

This is a huge issue for web components because they cannot use Shadow DOM, as they would like due to its encapsulation properties, if they want to provide an accessible experience to users. For that reason many of the web components libraries don’t use yet Shadow DOM and have to rely on workarounds or custom polyfills.

If you want to know more on the problem, Alice goes deep on the topic in her blog post How Shadow DOM and accessibility are in conflict.

Prior Art #

The Accessibility Object Model (AOM) effort was started several years ago aiming to solve several issues including the one described before, that had a wider scope and tried to solve many different things including the problems described in this blog post. At that time Alice was at Google and Alex Surkov at Mozilla, both were part of this effort. Coincidentally, they are now at Igalia, which together with Joanmarie Diggs and Valerie Young create a dream team of accessibility experts in our company.

Even when the full problem hasn’t been sorted out yet, there has been some progress with the Element Reflection feature which allows ARIA relationship attributes to be reflected as element references. Whit this users can specify them without the need to assign globally unique ID attributes to each element. This feature has been implemented in Chromium and WebKit by Igalia. So instead of doing something like:

<button id="button" aria-describedby="description">Button</button>
<div id="description">Description of the button.</div>

You could specify it like:

<button id="button">Button</button>
<div id="description">Description of the button.</div>
<script>
  button.ariaDescribedByElements = [description];
</script>

Coming back to Shadow DOM, this feature also enables authors to specify ARIA relationships pointing to things outside the Shadow DOM (the first kind of problem described in the previous section), however it doesn’t allow to reference elements inside another Shadow DOM (the second problem). Anyway let’s see an example of how this will solve the first issue:

<label id="label">Label</label>
<custom-button id="customButton"></custom-button>
<script>
  const shadowRoot = customButton.attachShadow({mode: "open"});

  const foo = document.createElement("div");
  foo.textContent = "foo";
  shadowRoot.appendChild(foo);

  const button = document.createElement("button");
  button.textContent = "Button";
  /* Here is where we reference the outer label from the button inside the Shadow DOM. */
  button.ariaLabelledByElements = [label];
  shadowRoot.appendChild(button);

  const bar = document.createElement("div");
  bar.textContent = "bar";
  shadowRoot.appendChild(bar);
</script>

Apart from Element Reflection, which only solves part of the issues, there have been other ideas about how to solve these problems. Initially Cross-root ARIA Delegation proposal by Leo Balter at Salesforce. A different one called Cross-root ARIA Reflection by Westbrook Johnson at Adobe. And finally the Reference Target for Cross-root ARIA proposal by Ben Howell at Microsoft.

Again if you want to learn more about the different nuances of the previous proposals you can revisit Alice’s blog post.

The Proposed Solution: Reference Target #

At this point this is the most promising proposal is the Reference Target one. This proposal allows the web authors to use Shadow DOM and still don’t break the accessibility of their web applications. The proposal is still in flux and it’s currently being prototyped in Chromium and WebKit. Anyway as an example this is the kind of API shape that would solve the second problem described in the initial section, where we reference a label (#actualLabel) inside the Shadow DOM from a button (#button) in the light DOM.

<custom-label id="customLabel">
  <template shadowrootmode="open"
            shadowrootreferencetarget="actualLabel">
    <div>foo</div>
    <label id="actualLabel">Label</label>
    <div>bar</div>
  </template>
</custom-label>
<button id="button" aria-labelledby="customLabel">Button</button>

The Grant #

As part of this grant we’ll work on all the process to get the Reference Target proposal ready to be shipped in the web rendering engines. Some of the tasks that will be done during this project include work in different fronts:

• Proposal: Help with the work on the proposal identifying issues, missing bits, design solutions, providing improvements, keeping it up to date as the project evolves.
• Specification: Write the specification text, discuss and review it with the appropriate working groups, improved it based on gathered feedback and implementation experience, resolve issues identified in the standards bodies.
• Implementation: Prototype implementation in WebKit to verify the proposal, upstream changes to WebKit, fix bugs on the implementation, adapt it to spec modifications.
• Testing: Analyze current WPT tests, add new ones to increase coverage, validate implementations, keep them up-to-date as things evolve.
• Outreach: Blog posts explaining the evolution of the project and participation in events with other standards folks to have the proper discussions to move the proposal and specification forward.

We’re really grateful that NLnet has trusted us to this project, and we really hope this will allow to fix an outstanding accessibility issue in the web platform that has been around for too many time already. At the same point it’s a bit sad, that the European Union through the NGI funds is the one sponsoring this project, when it will have a very important impact for several big fishes that are part of the Web Components WG.

If you want to follow the evolution of this project, I’d suggest you to follow Alice’s blog where she’ll be updating us about the progress of the different tasks.

Link in Bio

Embracing an IndieWeb thing...

Over the years, I've been there as things have come and gone on the interwebs. I had accounts on AIM, MySpace, Blogger, FaceBook, WordPress, Google Plus, Twitter, Instagram, and plenty more. On each one, I wind up with a profile where I want to link people to other places I am online - and those places don't always make it easy to do that. So, something short and memorable that you could even type if you had to is ideal - like a handle: @briankardell or @bkardell or, in the end: bkardell.com is pretty great.

Back in 2016, some folks felt the same frustration and instead created this Linktree thing. But... It's just like, a fremium thing that gives you the most basic single page website ever? Yes, and today they have 50 million users and are valued at $1.3 billion - that's a value of $26/user. I mean, I found that amazing.

But, here's the thing: After a while I realized that there's something to it. Not the business model, specifically, but the link in bio idea. The link in bio is generally not a great website on its own, but it's a page where people can pretty quickly navigate to the thing they're looking for without other noise or fluff. Which is something that a home page often isn't. So, I've learned to really appreciate them, actually.

Back in about 2020, some IndieWeb folks began thinking about, criticizing and brainstorming around it too. They began writing about Link in Bio, and why it might be useful to have your own version. There are several examples of people doing something similar.

Recently a bunch of things smashed together in my mind. First, on ShopTalk, I heard Chris and Dave talking about "slash pages" (pages right off the root domain with well known names). Second, I've been working on social media plans - getting away from some platforms and moving to others and thinking about these problems. An IndieWeb style `/links` page, that adds rel="me" links is a really nice, simple way to achieve a whole lot of things if we'd all adopt it - not the least of which is that it's an evergreen link, almost as simple as a handle, to where people can find you should you choose to leave...

So, starting with me, and Igalia, you can find our links at bkardell.com/links and igalia.com/links respectively.

Introduction

If you use SteamOS and you like to install third-party tools or modify the system-wide configuration some of your changes might be lost after an OS update. Read on for details on why this happens and what to do about it.

As you all know SteamOS uses an immutable root filesystem and users are not expected to modify it because all changes are lost after an OS update.

However this does not include configuration files: the /etc directory is not part of the root filesystem itself. Instead, it’s a writable overlay and all modifications are actually stored under /var (together with all the usual contents that go in that filesystem such as logs, cached data, etc).

/etc contains important data that is specific to that particular machine like the configuration of known network connections, the password of the main user and the SSH keys. This configuration needs to be kept after an OS update so the system can keep working as expected. However the update process also needs to make sure that other changes to /etc don’t conflict with whatever is available in the new version of the OS, and there have been issues due to some modifications unexpectedly persisting after a system update.

SteamOS 3.6 introduced a new mechanism to decide what to to keep after an OS update, and the system now keeps a list of configuration files that are allowed to be kept in the new version. The idea is that only the modifications that are known to be important for the correct operation of the system are applied, and everything else is discarded¹.

However, many users want to be able to keep additional configuration files after an OS update, either because the changes are important for them or because those files are needed for some third-party tool that they have installed. Fortunately the system provides a way to do that, and users (or developers of third-party tools) can add a configuration file to /etc/atomic-update.conf.d, listing the additional files that need to be kept.

There is an example in /etc/atomic-update.conf.d/example-additional-keep-list.conf that shows what this configuration looks like.

Developers who are targeting SteamOS can also use this same method to make sure that their configuration files survive OS updates. As an example of an actual third-party project that makes use of this mechanism you can have a look at the DeterminateSystems Nix installer:

https://github.com/DeterminateSystems/nix-installer/blob/v0.34.0/src/planner/steam_deck.rs#L273

As usual, if you encounter issues with this or any other part of the system you can check the SteamOS issue tracker. Enjoy!

1. A copy is actually kept under /etc/previous to give the user the chance to recover files if necessary, and up to five previous snapshots are kept under /var/lib/steamos-atomupd/etc_backup ︎

Maintaining a downstream of Chromium is hard, because of the speed upstream moves. and how hard it is to keep our downstream up to date.

A critical aspect is how big what we build on top of Chromium is: in other words, the size of our downstream. In this blog post I will review how to measure it, and the impact it has on the costs of maintaining a downstream.

Maintaining Chromium downstream series #

Last year, I started a series of blog posts about the challenges, the organization and the implementation details of maintaining a project that is a downstream of Chromium. This is the third blog post in the series.

The previous posts were:

• Why downstream?: why is it needed to create downstream forks of Chromium? And why using Chromium in particular?
• Update strategies: when to update? Is it better to merge or rebase? How can automation help?

Measuring the size of a downstream #

But, first… What do I mean by the size of the downstream? I am interested in a definition that can be used as a metric, something we can measure and track. A number that allows to know if the downstream is increasing or decreasing, measure if a change has impact on it.

The rough idea is: the bigger the downstream is, the more complex it is to maintain it. I will provide a few metrics that can be used for this purpose.

Delta #

The most obvious metric is the delta, the difference between upstream Chromium and the downstream. For this, and assuming the downstream uses Git, the definition I use is essentially the result of this command:

git diff --shortstat BASELINE..DOWNSTREAM

BASELINE is a commit reference that represents the pure upstream repository status our downstream is based on (our baseline). DOWNSTREAM is the commit reference we want to compare the baseline to.

As a recommendation, it is useful to maintain in our downstream repository tags or branches that represent strictly the baseline. This way we can use diff tools to represent our delta more easily.

This command is going to return 3 values:

• The number of files that have changed.
• The number of lines that were added.
• The number of lines that were removed.

We will be mostly interested in tracking the number of lines added and removed.

This definition is interesting as it gives an idea of the amount of lines of code that we need to maintain. It may not reflect the full amount to maintain, as some files are maintained out of the Chromium repository. Aggregating these with other repositories changed or added to the build could be useful.

One interesting thing with this approach is also that we can measure the delta of specific paths in the repository. I.e. if we want to measure the delta of the content/ path, it is just as easy as doing:

git diff --shortstat BASELINE..DOWNSTREAM content/

Modifying delta #

The regular delta definition we considered has a problem. All the line changes have the same weight. But, when we update our baseline, a big part of the complexity comes from the conflicts found when rebasing or merging.

So, I am introducing a new definition. Modifying delta: the changes between the baseline and the downstream that affect upstream lines. In this case, we ignore completely any file added only by the downstream, as that is not going to create conflicts.

In Git, we can use filters for that purpose:

git diff --diff-filter=CDMR --shortstat BASELINE..DOWNSTREAM

This will only account these changes:

• M: changes affecting existing files.
• R: files that were renamed.
• C: files that were copied.
• D: files that were deleted.

So, these numbers are going to more accurately represent which parts of our delta can conflict with the changes coming from upstream when we rebase or merge.

Tracking the modifying delta, and reorganizing the project to reduce it, is usually a good strategy for reducing maintenance costs.

diffstat #

An issue we have with the Git diff stats is that it represents modified lines as a block of lines removed and another of lines added.

Fortunately, we can use another tool. Diffstat, will do a best effort to identify which lines are actually modified. It can be easily installed in your distribution of choice (i.e. the package diffstat in Debian/Ubuntu/Redhat).

This behavior is enabled with the parameter -m:

git diff ...parameters... | diffstat -m

This is the kind of output that is generated. On top of the typical + and - we see the ! for the lines that have been detected to be modified.

$ git show | diffstat -m
 paint/timing/container_timing.cc        |    5 ++++!
 paint/timing/container_timing.h         |    1 +
 timing/performance_container_timing.cc  |   20 ++++++++++++++++++!!
 timing/performance_container_timing.h   |    5 +++++
 timing/performance_container_timing.idl |    1 +
 timing/window_performance.cc            |    4 ++!!
 timing/window_performance.h             |    1 +
 7 files changed, 32 insertions(+), 5 modifications(!)

Coloring is also available, with the parameter -C.

Using diffstat gives a more accurate insight of both the total delta and the modifying delta.

Tracking deltas #

Now we have the tools to provide numbers, we can track them in the time to know if our downstream is growing or shrinking.

That can be used also for measuring the impact of different strategies or changes in the downstream maintenance complexity.

Other metric ideas #

But deltas are not the only tool to measure the complexity, specially regarding the effort maintaining a downstream.

I can enumerate just a few ideas that provide insight of different problems:

• Frequency of rebase/merge conflicts per path.
• Frequency of undetected build issues.
• Frequency and complexity of the regressions, weighed by the size of the patches fixing them.

Relevant changes for tracking a downstream #

Let’s focus now on other factors, not always measurable easily, when we maintain a downstream project.

What we build on top of Chromium #

The complexity of a downstream, specially the one measured by regular delta, is impacted heavily by what is built on top of Chromium.

A full web browser is usually bigger, because it includes the required user experience, and many components that conform what we nowadays consider a browser. History, bookmarks, user profiles, secrets management…

An application runtime for hybrid applications may just have minimal wrappers for integrating a web view, but then maybe a complex set of components for easing the integration with a native toolkit or a specific programming language.

How much you build on top of Chrome?

• Browser are usually bigger pieces than runtimes.
• Hybrid application runtimes may have a big part related to toolkit or other components.

What we depend on #

For maintenance complexity, as important as what we build on top, is the set of boundaries and dependencies:

• How many upstream components are we using?
• What kind of APIs are provided?
• Are they stable or changing often?

These questions are specially relevant, as Chromium does not really provide any warranty about the stability, or even availability, of existing components.

Though, different layers provided by Chromium change less often than others. Some examples:

• The Content API provides the basics of the web platform and Chromium process model, so it is quite useful for hybrid application runtimes. It has been changing last years, in part because of the [Onion Soup refactorings] (https://mariospr.org/category/blink-onion-soup/). Though, there are always examples of how to adapt to those changes in //content/shell and //chrome.
• Chromium provides a number of reusable components at //components that may be useful for different downstreams.
• Then, for building a full web browser, it may be tempting to directly use //chrome, and modify it for the specific downstream user experience. This means a higher modifying delta. But, as the upstream Chrome browser UI may also often changes heavily, the frequency of conflicts also increases.

Wrapping up #

In this post I reviewed different ways to measure the downstream size, and how what we build impacts the complexity of maintenance.

Understanding and tracking our downstream allows to implement strategies to keep things under control. It also allows to better understand the cost of a specific feature or an implementation approach.

In the next post in this series, I will write about how the upstream Chromium community helps the downstreams.

References #

• Diffstat
• Git diff filters
• Content API
• Chromium now migrated to the new C++ Mojo types.

Update on what happened in WebKit in the week from January 27 to February 3.

Cross-Port 🐱

Web Platform 🌐

Multimedia 🎥

WebKitGTK 🖥️

Nushell is a new shell (get it?) in development since 2019. Where other shells like bash and zsh treat all data as raw text, nu instead provides a type system for all data flowing through its pipelines, with many commands inspired by functional languages to manipulate that data. The examples on their homepage and in the README.md demonstrate this well, and I recommend taking a quick look if you’re not familiar with the language.

I have been getting familiar with Nu for a few months now, and found it a lot more approachable and user-friendly than traditional shells, and particularly helpful for exploring logs.

Where to find documentation #

I won’t go over all the commands I use in detail, so if anything is ever unclear, have a look at the Command Reference. The most relevant categories for our use case are probably Strings and Filters. From inside nushell, you can also use help some_cmd or some_cmd --help, or help commands for a full table of commands that can be manipulated and searched like any other table in nu. And for debugging a pipeline, describe is a very useful command that describes the type of its input.

Set-up for analyzing GStreamer logs #

First of all, we need some custom commands to parse the raw logs into a nu table. Luckily, nushell provides a parse command for exacly this use case, and we can define this regex to use with it:

let gst_regex: ([
  '(?<time>[0-9.:]+) +'
  '(?<pid>\w+) +'
  '(?<thread>\w+) +'
  '(?<level>\w+) +'
  '(?<category>[\w-]+) +'
  '(?<file>[\w.-]+)?:'
  '(?<line>\w+):'
  '(?<function>[\w()~-]+)?:'
  '(?<object><[^>]*>)? +'
  '(?<msg>.*)$'
] | str join)

(I use a simple pipeline here to split the string over multiple lines for better readability, it just concatenates the list elements.)

Lets run a simple pipeline to get some logs to play around with:
GST_DEBUG=*:DEBUG GST_DEBUG_FILE=sample.log gst-launch-1.0 videotestsrc ! videoconvert ! autovideosink

For parsing the file, we need to be careful to remove any ansi escapes, and split the input into lines. On top of that, we will also store the result to a variable for ease of use:
let gst_log = open sample.log | ansi strip | lines | parse --regex $gst_regex

You can also define a custom command for this, which would look something like:

def "from gst logs" []: string -> table {
  $in | ansi strip | lines | parse --regex ([
    '(?<time>[0-9.:]+) +'
    '(?<pid>\w+) +'
    '(?<thread>\w+) +'
    '(?<level>\w+) +'
    '(?<category>[\w-]+) +'
    '(?<file>[\w.-]+)?:'
    '(?<line>\w+):'
    '(?<function>[\w()~-]+)?:'
    '(?<object><[^>]*>)? +'
    '(?<msg>.*)$'
  ] | str join)
}

Define it directly on the command line, or place it in your configuration files. Either way, use the command like this:
let gst_log = open sample.log | from gst logs

Some basic commands for working with the parsed data #

If you take a look at a few lines of the table, it should look something like this:
$gst_log | skip 10 | take 10

╭────┬────────────────────┬───────┬────────────┬────────┬─────────────────────┬────────────────┬───────┬──────────────────────────────┬─────────────┬───────────────────────────────────────────────╮
│  # │        time        │  pid  │   thread   │ level  │      category       │      file      │ line  │           function           │   object    │                      msg                      │
├────┼────────────────────┼───────┼────────────┼────────┼─────────────────────┼────────────────┼───────┼──────────────────────────────┼─────────────┼───────────────────────────────────────────────┤
│  0 │ 0:00:00.003607288  │ 5161  │ 0x1ceba80  │ DEBUG  │ GST_ELEMENT_PADS    │ gstelement.c   │ 315   │ gst_element_base_class_init  │             │ type GstBin : factory (nil)                   │
│  1 │ 0:00:00.003927025  │ 5161  │ 0x1ceba80  │ INFO   │ GST_INIT            │ gstcontext.c   │ 86    │ _priv_gst_context_initialize │             │ init contexts                                 │
│  2 │ 0:00:00.004117399  │ 5161  │ 0x1ceba80  │ INFO   │ GST_PLUGIN_LOADING  │ gstplugin.c    │ 328   │ _priv_gst_plugin_initialize  │             │ registering 0 static plugins                  │
│  3 │ 0:00:00.004164980  │ 5161  │ 0x1ceba80  │ DEBUG  │ GST_REGISTRY        │ gstregistry.c  │ 592   │ gst_registry_add_feature     │ <registry0> │ adding feature 0x1d08c70 (bin)                │
│  4 │ 0:00:00.004176720  │ 5161  │ 0x1ceba80  │ DEBUG  │ GST_REFCOUNTING     │ gstobject.c    │ 710   │ gst_object_set_parent        │ <bin>       │ set parent (ref and sink)                     │
│  5 │ 0:00:00.004197201  │ 5161  │ 0x1ceba80  │ DEBUG  │ GST_ELEMENT_PADS    │ gstelement.c   │ 315   │ gst_element_base_class_init  │             │ type GstPipeline : factory 0x1d09310          │
│  6 │ 0:00:00.004243022  │ 5161  │ 0x1ceba80  │ DEBUG  │ GST_REGISTRY        │ gstregistry.c  │ 592   │ gst_registry_add_feature     │ <registry0> │ adding feature 0x1d09310 (pipeline)           │
│  7 │ 0:00:00.004254252  │ 5161  │ 0x1ceba80  │ DEBUG  │ GST_REFCOUNTING     │ gstobject.c    │ 710   │ gst_object_set_parent        │ <pipeline>  │ set parent (ref and sink)                     │
│  8 │ 0:00:00.004265272  │ 5161  │ 0x1ceba80  │ INFO   │ GST_PLUGIN_LOADING  │ gstplugin.c    │ 236   │ gst_plugin_register_static   │             │ registered static plugin "staticelements"     │
│  9 │ 0:00:00.004276813  │ 5161  │ 0x1ceba80  │ DEBUG  │ GST_REGISTRY        │ gstregistry.c  │ 476   │ gst_registry_add_plugin      │ <registry0> │ adding plugin 0x1d084d0 for filename "(NULL)" │
╰────┴────────────────────┴───────┴────────────┴────────┴─────────────────────┴────────────────┴───────┴──────────────────────────────┴─────────────┴───────────────────────────────────────────────╯

skip and take do exactly what it says on the tin - removing the first N rows, and showing only the first N rows, respectively. I use them here to keep the examples short.

To ignore columns, use reject:
$gst_log | skip 10 | take 5 | reject time pid thread

╭───┬───────┬────────────────────┬───────────────┬──────┬──────────────────────────────┬─────────────┬────────────────────────────────╮
│ # │ level │      category      │     file      │ line │           function           │   object    │              msg               │
├───┼───────┼────────────────────┼───────────────┼──────┼──────────────────────────────┼─────────────┼────────────────────────────────┤
│ 0 │ DEBUG │ GST_ELEMENT_PADS   │ gstelement.c  │ 315  │ gst_element_base_class_init  │             │ type GstBin : factory (nil)    │
│ 1 │ INFO  │ GST_INIT           │ gstcontext.c  │ 86   │ _priv_gst_context_initialize │             │ init contexts                  │
│ 2 │ INFO  │ GST_PLUGIN_LOADING │ gstplugin.c   │ 328  │ _priv_gst_plugin_initialize  │             │ registering 0 static plugins   │
│ 3 │ DEBUG │ GST_REGISTRY       │ gstregistry.c │ 592  │ gst_registry_add_feature     │ <registry0> │ adding feature 0x1d08c70 (bin) │
│ 4 │ DEBUG │ GST_REFCOUNTING    │ gstobject.c   │ 710  │ gst_object_set_parent        │ <bin>       │ set parent (ref and sink)      │
╰───┴───────┴────────────────────┴───────────────┴──────┴──────────────────────────────┴─────────────┴────────────────────────────────╯

Or its counterpart, select, which is also useful for reordering columns:
$gst_log | skip 10 | take 5 | select msg category level

╭───┬────────────────────────────────┬────────────────────┬───────╮
│ # │              msg               │      category      │ level │
├───┼────────────────────────────────┼────────────────────┼───────┤
│ 0 │ type GstBin : factory (nil)    │ GST_ELEMENT_PADS   │ DEBUG │
│ 1 │ init contexts                  │ GST_INIT           │ INFO  │
│ 2 │ registering 0 static plugins   │ GST_PLUGIN_LOADING │ INFO  │
│ 3 │ adding feature 0x1d08c70 (bin) │ GST_REGISTRY       │ DEBUG │
│ 4 │ set parent (ref and sink)      │ GST_REFCOUNTING    │ DEBUG │
╰───┴────────────────────────────────┴────────────────────┴───────╯

Meanwhile, get returns a single column as a list, which can for example be used with uniq to get a list of all objects in the log:
$gst_log | get object | uniq | take 5

╭───┬──────────────╮
│ 0 │              │
│ 1 │ <registry0>  │
│ 2 │ <bin>        │
│ 3 │ <pipeline>   │
│ 4 │ <capsfilter> │
╰───┴──────────────╯

Filtering rows by different criteria works really well with where.
$gst_log | where thread in ['0x7f467c000b90' '0x232fefa0'] and category == GST_STATES | take 5

╭────┬────────────────────┬───────┬─────────────────┬────────┬─────────────┬──────────┬──────┬───────────────────────┬──────────────────┬───────────────────────────────────────────────────────────╮
│  # │        time        │  pid  │     thread      │ level  │  category   │   file   │ line │       function        │      object      │                            msg                            │
├────┼────────────────────┼───────┼─────────────────┼────────┼─────────────┼──────────┼──────┼───────────────────────┼──────────────────┼───────────────────────────────────────────────────────────┤
│  0 │ 0:00:01.318390245  │ 5158  │ 0x7f467c000b90  │ DEBUG  │ GST_STATES  │ gstbin.c │ 1957 │ bin_element_is_sink   │ <autovideosink0> │ child autovideosink0-actual-sink-xvimage is sink          │
│  1 │ 0:00:01.318523898  │ 5158  │ 0x7f467c000b90  │ DEBUG  │ GST_STATES  │ gstbin.c │ 1957 │ bin_element_is_sink   │ <pipeline0>      │ child autovideosink0 is sink                              │
│  2 │ 0:00:01.318558109  │ 5158  │ 0x7f467c000b90  │ DEBUG  │ GST_STATES  │ gstbin.c │ 1957 │ bin_element_is_sink   │ <pipeline0>      │ child videoconvert0 is not sink                           │
│  3 │ 0:00:01.318569169  │ 5158  │ 0x7f467c000b90  │ DEBUG  │ GST_STATES  │ gstbin.c │ 1957 │ bin_element_is_sink   │ <pipeline0>      │ child videotestsrc0 is not sink                           │
│  4 │ 0:00:01.338298058  │ 5158  │ 0x7f467c000b90  │ INFO   │ GST_STATES  │ gstbin.c │ 3408 │ bin_handle_async_done │ <autovideosink0> │ committing state from READY to PAUSED, old pending PAUSED │
╰────┴────────────────────┴───────┴─────────────────┴────────┴─────────────┴──────────┴──────┴───────────────────────┴──────────────────┴───────────────────────────────────────────────────────────╯

It provides special shorthands called row conditions - have a look at the reference for more examples.

Of course, get and where can also be combined:
$gst_log | get category | uniq | where $it starts-with GST | take 5

╭───┬────────────────────╮
│ 0 │ GST_REGISTRY       │
│ 1 │ GST_INIT           │
│ 2 │ GST_MEMORY         │
│ 3 │ GST_ELEMENT_PADS   │
│ 4 │ GST_PLUGIN_LOADING │
╰───┴────────────────────╯

And if you need to merge multiple logs, I recommend using sort-by time. This could look like
let gst_log = (open sample.log) + (open other.log) | from gst logs | sort-by time

Interactively exploring logs #

While there are many other useful commands, there is one more command I find incredbly useful: explore. It is essentially the nushell equivalent to less, and while it is still quite rough around the edges, I’ve been using it all the time, mostly for its interactive REPL.

First, just pipe the parsed log into explore:
$gst_log | explore

Now, using the :try command opens its REPL. Enter any pipeline at the top, and you will be able to explore its output below:

Switch between the command line and the pager using Tab, and while focused on the pager, search forwards or backwards using / and ?, or enter :help for explanations. Also have a look at the documentation on explore in the Nushell Book.

Update on what happened in WebKit in the week from January 20 to January 27.

Cross-Port 🐱

Web Platform 🌐

Multimedia 🎥

Graphics 🖼️

Releases 📦️

Recently, I fixed a macOS-specific startup performance regression in Node.js after an extensive investigation. Along the way, I learned a lot about tools for macOS and Node

Update on what happened in WebKit in the week from January 13 to January 20.

Cross-Port 🐱

JavaScriptCore 🐟

Graphics 🖼️

Landed a change that improves damage propagation in terms of animations handling.

WPE WebKit 📟

WPE Platform API 🧩

Infrastructure 🏗️

Just as 2025 is starting, we got a new Linux release in mid January, tagged as 6.13. In the spirit of holidays, Linus Torvalds even announced during 6.13-rc6 that he would be building and raffling a guitar pedal for a random kernel developer!

As usual, this release comes with a pack of exciting news done by the kernel community:

• This release has two important improvements for task scheduling: lazy preemption and proxy execution. The goal with lazy preemption is to find a better balance between throughput and response time. A secondary goal is being able to make it the preferred non-realtime scheduling policy for most cases. Tasks that really need a reschedule in a hurry will use the older TIF_NEED_RESCHED flag. A preliminary work for proxy execution was merged, which will let us avoid priority-inversion scenarios when using real time tasks with deadline scheduling, for use cases such as Android.

• New important Rust abstractions arrived, such as VFS data structures and interfaces, and also abstractions for misc devices.

• Lightweight guard pages: guard pages are used to raise a fatal signal when accessed. This feature had the drawback of having a heavy performance impact, but in this new release the flag MADV_GUARD_INSTALL was added for the madvise() syscall, offering a lightweight way to guard pages.

To know more about the community improvements, check out the summary made by Kernel Newbies.

Now let’s highlight the contributions made by Igalians for this release.

Case-insensitive support for tmpfs

Case sensitivity has been a traditional difference between Linux distros and MS Windows, with the most popular filesystems been in opposite sides: while ext4 is case sensitive, NTFS is case insensitive. This difference proved to be challenging when Windows apps, mainly games, started to be a common use case for Linux distros (thanks to Wine!). For instance, games running through Steam’s Proton would expect that the path assets/player.png and assets/PLAYER.PNG would point to be the same file, but this is not the case in ext4. To avoid doing workarounds in userspace, ext4 has support for casefolding since Linux 5.2.

Now, tmpfs joins the group of filesystems with case-insensitive support. This is particularly useful for running games inside containers, like the combination of Wine + Flatpak. In such scenarios, the container shares a subset of the host filesystem with the application, mounting it using tmpfs. To keep the filesystem consistent, with the same expectations of the host filesystem about the mounted one, if the host filesystem is case-insensitive we can do the same thing for the container filesystem too. You can read more about the use case in the patchset cover letter.

While the container frameworks implement proper support for this feature, you can play with it and try it yourself:

$ mount -t tmpfs -o casefold fs_name /mytmpfs
$ cd /mytmpfs # case-sensitive by default, we still need to enable it
$ mkdir a
$ touch a; touch A
$ ls
A  a
$ mkdir B; cd b
cd: The directory 'b' does not exist
$ # now let's create a case-insensitive dir
$ mkdir case_dir
$ chattr +F case_dir
$ cd case_dir
$ touch a; touch A
$ ls
a
$ mkdir B; cd b
$ pwd
$ /home/user/mytmpfs/case_dir/B

V3D Super Pages support

As part of Igalia’s effort for enhancing the graphics stack for Raspberry Pi, the V3D DRM driver now has support for Super Pages, improving performance and making memory usage more efficient for Raspberry Pi 4 and 5. Using Linux 6.13, the driver will enable the MMU to allocate not only the default 4KB pages, but also 64KB “Big Pages” and 1MB “Super Pages”.

To measure the difference that Super Pages made to the performance, a series of benchmarks where used, and the highlights are:

• +8.36% of FPS boost for Warzone 2100 in RPi4
• +3.62% of FPS boost for Quake 2 in RPi5
• 10% time reduction for the Mesa CI job v3dv-rpi5-vk-full:arm64
• Aether SX2 emulator is more fluid to play

You can read a detailed post about this, with all benchmark results, in Maíra’s blog post, including a super cool PlayStation 2 emulation showcase!

New transparent_hugepage_shmem= command-line parameter

Igalia contributed new kernel command-line parameters to improve the configuration of multi-size Transparent Huge Pages (mTHP) for shmem. These parameters, transparent_hugepage_shmem= and thp_shmem=, enable more flexible and fine-grained control over the allocation of huge pages when using shmem.

The transparent_hugepage_shmem= parameter allows users to set a global default huge page allocation policy for the internal shmem mount. This is particularly valuable for DRM GPU drivers. Just as CPU architectures, GPUs can also take advantage of huge pages, but this is possible only if DRM GEM objects are backed by huge pages.

Since GEM uses shmem to allocate anonymous pageable memory, having control over the default huge page allocation policy allows for the exploration of huge pages use on GPUs that rely on GEM objects backed by shmem.

In addition, the thp_shmem= parameter provides fine-grained control over the default huge page allocation policy for specific huge page sizes.

By configuring page sizes and policies of huge-page allocations for the internal shmem mount, these changes complement the V3D Super Pages feature, as we can now tailor the size of the huge pages to the needs of our GPUs.

DRM and AMDGPU improvements

As usual in Linux releases, this one collects a list of improvements made by our team in DRM and AMDGPU driver from the last cycle.

Cosmic (the desktop environment behind Pop! OS) users discovered some bugs in the AMD display driver regarding the handling of overlay planes. These issues were pre-existing and came to light with the introduction of cursor overlay mode. They were causing page faults and divide errors. We debugged the issue together with reporters and proposed a set of solutions that were ultimately accepted by AMD developers in time for this release.

In addition, we worked with AMD developers to migrate the driver-specific handling of EDID data to the DRM common code, using drm_edid opaque objects to avoid handling raw EDID data. The first phase was incorporated and allowed the inclusion of new functionality to get EDID from ACPI. However, some dependencies between the AMD the Linux-dependent and OS-agnostic components were left to be resolved in next iterations. It means that next steps will focus on removing the legacy way of handling this data.

Also in the AMD driver, we fixed one out of bounds memory write, fixed one warning on a boot regression and exposed special GPU memory pools via the fdinfo common DRM framework.

In the DRM scheduler code, we added some missing locking, removed a couple of re-lock cycles for slightly reduced command submission overheads and clarified the internal documentation.

In the common dma-fence code, we fixed one memory leak on the failure path and one significant runtime memory leak caused by incorrect merging of fences. The latter was found by the community and was manifesting itself as a system out of memory condition after a few hours of gameplay.

sched_ext

The sched_ext landed in kernel 6.12 to enable the efficient development of BPF-based custom schedulers. During the 6.13 development cycle, the sched_ext community has made efforts to harden the code to make it more reliable and clean up the BPF APIs and documentation for clarity.

Igalia has contributed to hardening the sched_ext core code. We fixed the incorrect use of the scheduler run queue lock, especially during initializing and finalizing the BPF scheduler. Also, we fixed the missing RCU lock protections when the sched_core selects a proper CPU for a task. Without these fixes, the sched_ext core, in the worst case, could crash or raise a kernel oops message.

Other Contributions & Fixes

syzkaller, a kernel fuzzer, has been an important instrument to find kernel bugs. With the help of KASAN, a memory error detector, and syzbot, numerous such bugs have been reported and fixed.

Igalians have contributed to such fixes around a lot of subsystems (like media, network, etc), helping reduce the number of open bugs.

Check the complete list of Igalia’s contributions for the 6.13 release

Authored (70)

André Almeida

• unicode: Fix utf8_load() error path
• MAINTAINERS: Add Unicode tree
• scripts/kernel-doc: Fix build time warnings
• libfs: Create the helper function generic_ci_validate_strict_name()
• ext4: Use generic_ci_validate_strict_name helper
• unicode: Export latest available UTF-8 version number
• unicode: Recreate utf8_parse_version()
• libfs: Export generic_ci_ dentry functions
• tmpfs: Add casefold lookup support
• tmpfs: Add flag FS_CASEFOLD_FL support for tmpfs dirs
• tmpfs: Expose filesystem features via sysfs
• docs: tmpfs: Add casefold options
• libfs: Fix kernel-doc warning in generic_ci_validate_strict_name
• tmpfs: Fix type for sysfs’ casefold attribute
• tmpfs: Initialize sysfs during tmpfs init

Changwoo Min

• sched_ext: Replace rq_lock() to raw_spin_rq_lock() in scx_ops_bypass()
• sched_ext: Clarify sched_ext_ops table for userland scheduler
• sched_ext: add a missing rcu_read_lock/unlock pair at scx_select_cpu_dfl()
• MAINTAINERS: add me as reviewer for sched_ext

Christian Gmeiner

• drm/v3d: Use v3d_perfmon_find()

Guilherme G. Piccoli

• Documentation: Improve crash_kexec_post_notifiers description
• wifi: rtlwifi: Drastically reduce the attempts to read efuse in case of failures

Maíra Canal

• drm/v3d: Address race-condition in MMU flush
• drm/v3d: Flush the MMU before we supply more memory to the binner
• drm/v3d: Fix return if scheduler initialization fails
• drm/gem: Create a drm_gem_object_init_with_mnt() function
• drm/v3d: Introduce gemfs
• drm/gem: Create shmem GEM object in a given mountpoint
• drm/v3d: Reduce the alignment of the node allocation
• drm/v3d: Support Big/Super Pages when writing out PTEs
• drm/v3d: Use gemfs/THP in BO creation if available
• drm/v3d: Add modparam for turning off Big/Super Pages
• drm/v3d: Expose Super Pages capability
• drm/vc4: Use vc4_perfmon_find()
• MAINTAINERS: Add Maíra to VC4 reviewers
• mm: shmem: control THP support through the kernel command line
• mm: move get_order_from_str() to internal.h
• mm: shmem: override mTHP shmem default with a kernel parameter
• mm: huge_memory: use strscpy() instead of strcpy()
• drm/v3d: Enable Performance Counters before clearing them
• drm/v3d: Ensure job pointer is set to NULL after job completion

Melissa Wen

• drm/amd/display: switch amdgpu_dm_connector to use struct drm_edid
• drm/amd/display: switch to setting physical address directly
• drm/amd/display: always call connector_update when parsing freesync_caps
• drm/amd/display: remove redundant freesync parser for DP
• drm/amd/display: add missing tracepoint event in DM atomic_commit_tail
• drm/amd/display: fix page fault due to max surface definition mismatch
• drm/amd/display: increase MAX_SURFACES to the value supported by hw
• drm/amd/display: fix divide error in DM plane scale calcs

Thadeu Lima de Souza Cascardo

• media: uvcvideo: Require entities to have a non-zero unique ID
• hfsplus: don’t query the device logical block size multiple times
• Bluetooth: btmtk: avoid UAF in btmtk_process_coredump

Tvrtko Ursulin

• drm/v3d: Appease lockdep while updating GPU stats
• drm/sched: Add locking to drm_sched_entity_modify_sched
• Documentation/gpu: Document the situation with unqualified drm-memory-
• drm/amdgpu: Drop unused fence argument from amdgpu_vmid_grab_used
• drm/amdgpu: Use drm_print_memory_stats helper from fdinfo
• drm/amdgpu: Drop impossible condition from amdgpu_job_prepare_job
• drm/amdgpu: Remove the while loop from amdgpu_job_prepare_job
• drm/sched: Optimise drm_sched_entity_push_job
• drm/sched: Stop setting current entity in FIFO mode
• drm/sched: Re-order struct drm_sched_rq members for clarity
• drm/sched: Re-group and rename the entity run-queue lock
• drm/sched: Further optimise drm_sched_entity_push_job
• drm/amd/pm: Vangogh: Fix kernel memory out of bounds write
• drm/amdgpu: Stop reporting special chip memory pools as CPU memory in fdinfo
• drm/amdgpu: Expose special on chip memory pools in fdinfo
• dma-fence: Fix reference leak on fence merge failure path
• dma-fence: Use kernel’s sort for merging fences
• workqueue: Do not warn when cancelling WQ_MEM_RECLAIM work from !WQ_MEM_RECLAIM worker

Reviewed (41)

André Almeida

• futex: Use atomic64_inc_return() in get_inode_sequence_number()
• futex: Use atomic64_try_cmpxchg_relaxed() in get_inode_sequence_number()
• mm: shmem: use signed int for version handling in casefold option

Christian Gmeiner

• drm/vc4: Use vc4_perfmon_find()
• drm/etnaviv: Request pages from DMA32 zone on addressing_limited
• drm/etnaviv: Use unsigned type to count the number of pages
• drm/etnaviv: Use ‘unsigned’ type to count the number of pages
• drm/etnaviv: Drop the <linux/pm_runtime.h> header
• drm/etnaviv: Fix missing mutex_destroy()
• drm/etnaviv: hold GPU lock across perfmon sampling
• drm/etnaviv: assert GPU lock held in perfmon pipe_*_read functions
• drm/etnaviv: unconditionally enable debug registers
• drm/etnaviv: update hardware headers from rnndb
• drm/etnaviv: take current primitive into account when checking for hung GPU
• drm/etnaviv: always allocate 4K for kernel ringbuffers
• drm/etnaviv: flush shader L1 cache after user commandstream

Iago Toral Quiroga

• drm/v3d: Address race-condition in MMU flush
• drm/v3d: Flush the MMU before we supply more memory to the binner
• drm/v3d: Fix return if scheduler initialization fails
• drm/v3d: Introduce gemfs
• drm/v3d: Reduce the alignment of the node allocation
• drm/v3d: Expose Super Pages capability
• drm/v3d: Enable Performance Counters before clearing them

Jose Maria Casanova Crespo

• drm/v3d: Ensure job pointer is set to NULL after job completion

Juan A. Suarez

• drm/vc4: Use vc4_perfmon_find()

Maíra Canal

• drm/v3d: Use v3d_perfmon_find()
• drm/vc4: Run default client setup for all variants.
• drm/vc4: Match drm_dev_enter and exit calls in vc4_hvs_lut_load
• drm/vc4: Match drm_dev_enter and exit calls in vc4_hvs_atomic_flush
• drm/vc4: Correct generation check in vc4_hvs_lut_load
• drm/vkms: Drop unnecessary call to drm_crtc_cleanup()

Tvrtko Ursulin

• drm/gem: Create a drm_gem_object_init_with_mnt() function
• drm/gem: Create shmem GEM object in a given mountpoint
• drm/v3d: Support Big/Super Pages when writing out PTEs
• drm/v3d: Use gemfs/THP in BO creation if available
• drm/v3d: Add modparam for turning off Big/Super Pages
• drm: add DRM_SET_CLIENT_NAME ioctl
• drm: use drm_file client_name in fdinfo
• drm/amdgpu: make drm-memory-* report resident memory
• dma-buf: fix dma_fence_array_signaled v4
• dma-buf: Fix __dma_buf_debugfs_list_del argument for !CONFIG_DEBUG_FS

Tested (1)

Christian Gmeiner

• drm/etnaviv: Replace the ‘&pdev->dev’ with ‘dev’

Acked (5)

Changwoo Min

• sched_ext: Rename scx_bpf_dispatch[_vtime]() to scx_bpf_dsq_insert[_vtime]()
• sched_ext: Rename scx_bpf_consume() to scx_bpf_dsq_move_to_local()
• sched_ext: Rename scx_bpf_dispatch[_vtime]_from_dsq*() -> scx_bpf_dsq_move[_vtime]*()

Maíra Canal

• MAINTAINERS: remove myself as a VKMS maintainer
• MAINTAINERS: Add myself as VKMS Maintainer

Maintainer SoB (6)

Maíra Canal

• MAINTAINERS: remove myself as a VKMS maintainer
• MAINTAINERS: Add myself as VKMS Maintainer
• drm/vkms: Add documentation
• drm/vkms: Suppress context imbalance detected by sparse warning
• drm/vkms: Add missing check for CRTC initialization
• drm/v3d: Drop allocation of object without mountpoint

2024 was another busy year for Igalia CSR. In the past 12 months, Igalia has been continuing the traditional effort on the Non-Governmental Organizations (NGOs), Reforestation, and Social Investment projects. We added a new NGO to the list and started a couple of new Social Investment projects. The CSR commission has also been looking at creating guidance on how to create and organize a cooperative based on our experience and exploring new communication channels. And we are excited about our first CSR podcast!

First CSR Podcast

In July 2024 Igalia published the first CSR podcast, thanks to Paulo Matos, Eric Meyer, and Brian Kardell!

The podcast discusses Igalia’s flat structure and why we believe that CSR is interesting for Igalia. It also covers Igalia’s approach and perspective on our social responsibilities, the projects we have, Igalia’s approach and conscience, the impact of CSR, and our vision for the future.

If interested, check out Igalia Chats: Social Responsibility At Igalia.

0.7% and NGOs

Since 2007 Igalia has been donating 0.7% of our income annually to a list of NGOs proposed by the Igalians. Working with these partners, Igalia continued the effort in a wide range of areas including development aid and humanitarian action, health, functional disabilities, ecology and animal welfare, transparency, and information, etc.

These organizations reported regularly to the commission on finance, progress, and outcomes of the dedicated projects. Most projects have been progressing nicely and steadily in 2024. Here we’d like to talk about a couple of new NGO projects we recently added.

– Degen Foundation

The Degen Foundation is a small private foundation, based in A Coruña that has been working for more than ten years on neurodegenerative diseases. The Foundation was born as Foundation “Curemos el Parkinson” in 2015 when its founder and president, Alberto Amil, was diagnosed with a particularly severe and complex version of Parkinson’s Disease.

Igalia started its collaboration with the Degen Foundation in 2023, mainly engaged in the development of the first phase of the Degen Community platform, a virtual meeting and emotional support point for patients. Studies consistently show that emotional support is as crucial as clinical support for neurodegenerative disease patients. The Degen Community platform aims to provide emotional support via a pack of tools/apps. The platform also will act as an information portal to publish relevant and up-to-date information for patients and carers. The platform has been under design and volunteers have been sourced to collaborate on content etc. The organization plans to launch the platform in 2025.

Hevya

In 2024, we introduced a new NGO, Hevya, to Igalia’s NGO list. Heyva Sor a Kurdistanê is a humanitarian aid organization established to assist people in the harsh conditions of the ongoing war in Kurdistan. The organization conducts relief efforts on fundamental needs such as food, health, shelter, and education. They have been providing continuous assistance and promoting solidarity, sacrifice, and mutual support in society since 1993. The organization has become a beacon of hope for the population in Kurdistan.

Emergency Project – Floods in Valencia

Storm DANA, which hit the Valencian territory in October 2024, has had a particular impact on Horta Sud, a region that has been devastated by the catastrophe.

The CSR Commission responded quickly to this emergency incident. After collecting the votes from Igalians, the commission decided to allocate the remaining undistributed NGO donation budget to aid Horta Sud in rebuilding their community. The first donation was made via Fundació Horta Sud and the second contribution via Cerai. Both Fundació Horta Sud and Cerai are local organizations working in the affected area and they were proposed by our colleague Jordi Mallach. We also bought a nice drawing by Mariscal, a well-known Valencian artist.

Social Investments

This year we started two new social investments: Extension of the Yoff Library project and Biomans Project. Meanwhile, after preparation was completed in 2023, UNICEF’s Casitas Infantiles project started on time.

– Casitas Infantiles (Children’s Small Houses in Cuba)

In Cuba, state educational centers only care for around 19% of children between 1 – 6 years old. Casitas Infantiles was proposed by UNICEF to Igalia to help provide children with “Children’s Small Houses”, a concept of using adapted premises in workplaces, companies, and cooperatives as shelters for children’s education. This solution has been applied over the years in several provinces. It’s approved to work well and in high demand recently. After collecting feedback/thoughts from Igalians, the CSR commission reached the decision of supporting this for a period of 24 months, targeting setting up 28 small houses to accommodate 947 children.

The project started in March 2024. We received reports in June and December detailing the 16 first small houses selected, resource acquisition and distribution, and training activities carried out for 186 educational agents and 856 parents or childminders to raise awareness of positive methods of education and parenting. Workshops and training also were carried out to raise awareness of the opening and continuity of children’s houses in key sectors.

– Extension of the Yoff Library Project

This is an extension of our Library in Yoff project.

This project progressed as planned. The construction work (Phase 5) was completed. An on-site visit in June carried out the Training action (phase 6), and Furniture and bibliography sourcing operations (phase 7). A follow-up on-site visit in November brought back some lovely videos showing how the library looks and works today and the positive feedback from the locals.

The extension project was to support completing the library with a few final bits, including kitchen extension, school furniture renovation, and computer and network equipment. It’s great to see the impact the library has on the local community.

– Biomans Project

Biomans is a circular economy project that focuses its activity on the sustainable use of residual wood for its conversion into wood biomass for heating. The goal of the project is to promote green and inclusive employment in rural Galicia for people at risk of social exclusion, mainly those with intellectual disabilities.

AMICOS Association Initiated the project and has acquired a plot of land as the premise for a factory and training unit to develop the activity. Igalia’s donation would be used for the construction of the factory.

Reforestation

Igalia started the Reforestation project in 2019. Partnering with Galnus , the Reforestation project focuses on conserving and expanding native, old-growth forests to capture, and long-term storing, carbon emissions.

Check on our blog, Igalia on Reforestation, for the projects carried out in the past few years.

In 2024, Galnus proposed ROIS III to Igalia. ROIS III is an extension of the project we are running at the Rois community land. The additional area to work in this project is around 1 hectare, adjacent to the 4 hectares we have already been working on. This would mean that we are building a new native forest of over 5 hectares. Funding for this extension work was in place in November and we shall hear more about this in 2025.

The other proposal from Galnus in 2024 was A Coruña Urban Forest project.

The concept of the urban forest project is to create an urban forest in the surroundings of “Parque de Bens. This project would become a model of public-private collaboration, encouraging the participation of other companies and public institutions in the development of environmental and social projects. It also incorporates a new model of green infrastructure, different from the usual parks and green areas, with high maintenance and low natural interest.

This is an exciting proposal. It’s different from our past and existing reforestation projects. After some discussions and feasibility studies, the commission decided to take a step forward and this proposal has now moved to the agreement handling stage.

Looking forward to 2025

With some exciting project proposals received from the Igalians for 2025, we are looking forward to another good year!

Update on what happened in WebKit in the week from December 31, 2024 to January 13, 2025.

Cross-Port 🐱

Web Platform 🌐

Multimedia 🎥

JavaScriptCore 🐟

Graphics 🖼️

WebKitGTK 🖥️

WPE WebKit 📟

2024 marked another year of exciting developments and accomplishments for Igalia's Compilers team packed with milestones, breakthroughs, and a fair share of long debugging sessions. From advancing JavaScript standards, improving LLVM RISC-V performance, to diving deep into Vulkan and FEX emulation, we did it all.

From shipping require(esm) in Node.js to porting LLVM’s libc to RISC-V, and enabling WebAssembly’s highest optimization tier in JavaScriptCore, last year was been nothing short of transformative. So, grab a coffee (or your preferred debugging beverage), and let’s take a look back at the milestones, challenges, and just plain cool stuff we've been up to last year.

JavaScript Standards #

We secured a few significant wins last year when it comes to JavaScript standards. First up, we got Import attributes (alongside JSON modules) to Stage 4. Import attributes allow customizing how modules are imported. For example, in all JavaScript environments you'll be able to natively import JSON files using

import myData from "./data" with { type: "json" };

Not far behind, the Intl.DurationFormat proposal also reached Stage 4. Intl.DurationFormat provides a built-in way to format durations (e.g., days, hours, minutes) in a locale-sensitive manner, enhancing internationalization support.

We also advanced ShadowRealm, the JavaScript API that allows you to execute code in a fresh and isolated environment, to Stage 2.7, making significant progress in resolving the questions about which web APIs should be included. We addressed open issues related to HTML integration and ensured comprehensive WPT coverage.

We didn't stop there though. We implemented MessageFormat 2.0 in ICU4C; you can read more about it in this blog post.

We also continued working on AsyncContext, an API that would let you persist state across awaits and other ways of running code asynchronously. The main blocker for Stage 2.7 is figuring out how it should interact with web APIs, and events in particular, and we have made a lot of progress in that area.

Meanwhile, the source map specification got a major update, with the publication of ECMA-426. This revamped spec, developed alongside Bloomberg, brings much-needed precision and new features like ignoreList, all aimed at improving interoperability.

We also spent time finishing Temporal, the modern date and time API for JavaScript—responding to feedback, refining the API, and reducing binary size. After clearing those hurdles, we moved forward with Test262 coverage and WebKit implementation.

Speaking of Test262, our team continued our co-stewardship of this project that ensures compatibility between JavaScript implementations across browsers and runtimes, thanks to support from the Sovereign Tech Fund. We worked on tests for everything from resizable ArrayBuffers to deferred imports, keeping JavaScript tests both thorough and up to date. To boost Test262 coverage, we successfully ported the first batch of SpiderMonkey's non-262 test suite to Test262. This initiative resulted in the addition of approximately 1,600 new tests, helping to expand and strengthen the testing framework. We would like to thank Bloomberg for supporting this work.

The decimal proposal started the year in Stage 1 and remains so, but it has gone through a number of iterative refinements after being presented at the TC39 plenary.

It’s was a productive year, and we’re excited to keep pushing these and more proposals forward.

Node.js #

In 2024, we introduced several key enhancements in Node.js.

We kicked things off by adding initial support for CPPGC-based wrapper management, which helps making the C++/JS corss-heap references visible to the garbage collector, reduces risks of memory leaks/use-after-frees, and improves garbage collection performance.

Node.js contains a significant amount of JavaScript internals, which are precompiled and preloaded into a custom V8 startup snapshot for faster startup. However, embedding these snapshots and code caches introduced reproducibility issues in Node.js executables. In 2024, We made the built-in snapshot and code cache reproducible, which is a major milestone in making the Node.js executables reproducible.

To help user applications start up faster, we also shipped support for on-disk compilation cache for user modules. Using this feature, TypeScript made their CLI start up ~2.5x faster, for example.

One of the impactful work we've done in 2024 was implementing and shipping require(esm), which is set to accelerate EcmaScript Modules (ESM) adoption in the Node.js ecosystem, as now package maintainers can ship ESM directly without having to choose between setting up dual shipping or losing reach, and it allows many frameworks/tools to load user code in ESM directly instead of doing hacky ESM -> CJS conversion , which tend to be bug-prone, or outright rejecting ESM code. Additionally, we landed module.registerHooks() to help the ecosystem migrate away from dependency of CJS loader internals and improve the state of ESM customization.

We also shipped a bunch of other smaller semver-minor features throughout 2024, such as support for embedded assets in single executable applications, crypto.hash() for more efficient one-off hashing, and v8.queryObjects() for memory leak investigation, to name a few.

Apart from project work, we also co-organized the Node.js collaboration summit in Bloomberg's London office, and worked on Node.js's Bluesky content automation for a more transparent and collaborative social media presence of the project.

You can learn more about the new module loading features from our talk at ViteConf Remote, and about require(esm) from our NodeConf EU talk.

JavaScriptCore #

In JavaScriptCore, we've ported BBQJIT, the first WebAssembly optimizing tier to 32-bits. It should be a solid improvement over the previous fast-and-reasonably-performant tier (BBQ) for most workloads. The previous incarnation of this tier generated the Air IR (the low-level); BBQJIT generates machine code more directly, which means JSC can tier-up to it faster.

We're also very close to enabling (likely this month) the highest optimizing tier (called "OMG") for WebAssembly on 32-bits. OMG generates code in the B3 IR, for which JSC implements many more optimizations. B3 then gets lowered to Air and finally to machine code. OMG can increase peak performance for many workloads, at the cost of more time spent on compilation. This has been a year-long effort by multiple people.

V8 #

In V8, we introduced a new entity called Isolate Groups to break the limit of 4Gb for pointer compression usage. It should help V8 embedders like node, deno, and others to allocate more isolate per process. We also supported multi-cage mode for the newly added sandbox feature of V8. You can read more about this in the blog post.

LLVM #

In LLVM's RISC-V backend, we added full scalable vectorization support for the BF16 vector extensions zvfbfmin and zvfbfwma. This means that code like the following C snippet:

void f(float * restrict dst, __bf16 * restrict a, __bf16 * restrict b, int n) {
  for (int i = 0; i < n; i++)
    dst[i] += ((float)a[i] * (float)b[i]);
}

Now gets efficiently vectorized into assembly like this:

	vsetvli	t4, zero, e16, m1, ta, ma
.LBB0_4:
	vl1re16.v	v8, (t3)
	vl1re16.v	v9, (t2)
	vl2re32.v	v10, (t1)
	vfwmaccbf16.vv	v10, v8, v9
	vs2r.v	v10, (t1)
	add	t3, t3, a4
	add	t2, t2, a4
	sub	t0, t0, a6
	add	t1, t1, a7
	bnez	t0, .LBB0_4

On top of that, we’ve made significant strides in overall performance last year. Here's a bar plot showing the improvements in performance from LLVM 17 last November to now.

Note: This accomplishment is the result of the combined efforts of many developers, including those at Igalia!

We also ported most of LLVM's libc to rv32 and rv64 in September (~91% of functions enabled). We presented the results at LLVM Developer's meeting 2024, you can watch the video of the talk to learn more about this.

Shader compilation (Mesa IR3) and dynamic binary translation (FEX-Emu) #

• Shader compilation: In shader compilation we've been busy improving the ir3 compiler backend for the freedreno/turnip drivers for Adreno GPUs in Mesa. Some of the highlights include:

  • Improving support for Vulkan subgroups by adding codegen for new hardware instructions and implementing clustered subgroup operations.
  • Adding support for multiple predicate registers which paved the way for supporting predication.
  • Implementing a code compression technique called repeated instructions.

• Dynamic Binary Translation

  • In 2024, Igalia had the exciting opportunity to contribute to FEX (https://fex-emu.com/), marking our first year working on the project. Last year, our primary focus was improving the x87 FPU emulation. While we worked on several pull requests with targeted optimizations, we also took on a few larger tasks that made a significant impact:

    • Introducing a new x87 stack optimization pass was one of our major contributions. You can dive deeper into the details of it in the blog post and explore the work itself in the pull request.

    • Another key feature we added was explicit mode switching between MMX and x87 modes, details can be found in the pull request.

    • We also focused on SVE optimization for x87 load/store operations. The details of this work can be found in the pull request here.

As we look ahead, we are excited to continue driving the evolution of these technologies while collaborating with our amazing partners and communities.

Back in 2023, I belatedly jumped on the bandwagon of people posting their CSS wish lists for the coming year.  This year I’m doing all that again, less belatedly! (I didn’t do it last year because I couldn’t even.  Get it?)

I started this post by looking at what I wished for a couple of years ago, and a small handful of my wishes came true:

• Subgrid support
• Nested selectors
• Color shading and blending (thanks to color-mix())
• More and better :has() use

Note that by “came true”, I mean “reached at least Baseline Newly Available”, not “reached Baseline Universal”; that latter status comes over time.  And more :has() isn’t really a feature you can track, but I do see more people sharing cool :has() tricks and techniques these days, so I’ll take that as a positive signal.

A couple more of my 2023 wishes are on the cusp of coming true:

• Element transitions, a.k.a.  view transitions
• Anchor positioning

Those are both in the process of rolling out, and look set to reach Baseline Newly Available before the year is done.  I hope.

That leaves the other half of the 2023 list, none of which has seen much movement.  So those will be the basis of this year’s list, with some new additions.

Hanging punctuation

WebKit has been the sole implementor of this very nice typographic touch for almost a decade now.  The lack of any support by Blink and Gecko is now starting to verge on feeling faintly ridiculous.

Margin and line box trimming

Trim off the leading block margin on the first child in an element, or the trailing block margin of the last child, so they don’t stick out of the element and mess with margin collapsing.  Same thing with block margins on the first and last line boxes in an element.  And then, be able to do similar things with the inline margins of elements and line boxes!  All these things could be ours.

Stroked text

We can already fake text stroking with text-shadow and paint-order, at least in SVG.  I’d love to have a text-stroke property that can be applied to HTML, SVG, and MathML text.  And XML text and any text that CSS is able to style.  It should be at least as powerful as SVG stroking, if not more so.

Expanded attr() support

This has seen some movement specification-wise, but last I checked, no implementation promises or immediate plans.  Here’s what I want to be able to do:

td {width: attr(data-size em, 1px));

<td data-size="5">…</td>

The latest Values and Units module describes this, so fingers crossed it starts to gain some momentum.

Exclusions

Yes, I still want CSS Exclusions, a lot.  They would make some layout hacks a lot less hacky, and open the door for really cool new hacks, by letting you just mark an element as creating a flow exclusions for the content of other elements.  Position an image across two columns of text and set it to exclude, and the text of those columns will flow around or past it like it was a float.  This remains one of the big missing pieces of CSS layout, in my view.  Linked flow regions is another.

Masonry layout

This one is a bit stalled because the basic approach still hasn’t been decided.  Is it part of CSS Grid or its own display type?  It’s a tough call.  There are persuasive arguments for both.  I myself keep flip-flopping on which one I prefer.

Designers want this.  Implementors want this.  In some ways, that’s what makes it so difficult to pick the final syntax and approach: because everyone wants this, everyone wants to make the exactly perfect right choices for now, for the future, and for ease of teaching new developers.  That’s very, very hard.

Grid track and gap styles

Yeah, I still want a Grid equivalent of column-rule, except more full-featured and powerful.  Ideally this would be combined with a way to select individual grid tracks, something like:

.gallery {display: grid;}
.gallery:col-track(4) {gap-rule: 2px solid red;}

…in order to just put a gap rule on that particular column.  I say that would be ideal because then I could push for a way to set the gap value for individual tracks, something like:

.gallery {gap: 1em 2em;}
.gallery:row-track(2) {gap: 2em 0.5em;}

…to change the leading and trailing gaps on just that row.

Custom media queries

This was listed as “Media query variables” in 2023.  With these, you could define a breakpoint set like so:

@custom-media --sm (inline-size <= 25rem);
@custom-media --md (25rem < inline-size <= 50rem);
@custom-media --lg (50rem < inline-size);

body {margin-inline: auto;}
@media (--sm) {body {inline-size: auto;}}
@media (--md) {body {inline-size: min(90vw, 40em);}
@media (--lg) {body {inline-size: min(90vw, 55em);}

In other words, you can use custom media queries as much as you want throughout your CSS, but change their definitions in just one place.  It’s CSS variables, but for media queries!  Let’s do it.

Unprefix all the things

Since we decided to abandon vendor prefixing in favor of feature flags, I want to see anything that’s still prefixed get unprefixed, in all browsers.  Keep the support for the prefixed versions, sure, I don’t care, just let us write the property and value names without the prefixes, please and thank you.

Grab bag

I still would like a way to indicate when a shorthand property is meant for logical rather than physical directions, a way to apply a style sheet to a single element, the ability to add or subtract values from a shorthand without having to rewrite the whole thing, and styles that cross resource boudnaries.  They’re all in the 2023 post.

Okay, that’s my list.  What’s yours?

Have something to say to all that? You can add a comment to the post, or email Eric directly.

I’ve been working on chromium input method editor integration for linux wayland at Igalia over the past several months, and I thought I’d share some insights I’ve gained along the way and some highlights from my work.

This is the first in a series of blog posts about input method editors, or IME in short. Here I will try to explain what an IME really is at a high level before diving deeper into some of the technical details of IME support in linux and chromium in upcoming posts.

Update on what happened in WebKit in the week from December 23 to December 30.

Community & Events 🤝

CSS Anchor Positioning is a novel CSS specification module that allows positioned elements to size and position themselves relative to one or more anchor elements anywhere on the web page. In simpler terms, it is a new web platform API that simplifies advanced relative-positioning scenarios such as tooltips, menus, popups, etc.

CSS Anchor Positioning in practice #

To better understand the true power it brings, let’s consider a non-trivial layout presented in Figure 1:

In the past, creating a context menu with position: fixed and positioned relative to the button required doing positioning-related calculations manually. The more complex the layout, the more complex the situation. For example, if the table in the above example was in a scrollable container, the position of the context menu would have to be updated manually on every scroll event.

With the CSS Anchor Positioning the solution to the above problem becomes trivial and requires 2 parts:

• The <button> element must be marked as an anchor element by adding anchor-name: --some-name.
• The context menu element must position itself using the anchor() function: left: anchor(--some-name right); top: anchor(--some-name bottom).

The above is enough for the web engine to understand that the context menu element’s left and top must be positioned to the anchor element’s right and bottom. With that, the web engine can carry out the job under the hood, so the result is as in Figure 2:

As the above demonstrates, even with a few simple API pieces, it’s now possible to address very complex scenarios in a very elegant fashion from the web developer’s perspective. Moreover, CSS Anchor Positioning offers even more than that. There are numerous articles with great examples such as this MDN article, this css-tricks article, or this chrome blog post, but the long story short is that both positioning and sizing elements relative to anchors are now very simple.

Implementation status across web engines #

The first draft of the specification was published in early 2023, which in the web engines field is not so long time ago. Therefore - as one can imagine - not all the major web engines support it yet. The first (and so far the only) web engine to support CSS Anchor Positioning was Chromium (see the introduction blog post) - thus the information on caniuse.com. However, despite the information visible on the WPT results page, the other web engines are currently implementing it (see the meta bug for Gecko and bug list for WebKit). The lack of progress on the WPT results page is due to the feature not being enabled by default yet in those cases.

Implementation status in WebKit #

From the commits visible publicly, one can deduce that the work on CSS Anchor Positioning in WebKit has been started by Apple early 2024. The implementation was initiated by adding a core part - support for anchor-name, position-anchor, and anchor(). Those 2 properties and function are enough to start using the feature in real-world scenarios as well as more sophisticated WPT tests.

The work on the above had been finished by the end of Q3 2024, and then - in Q4 2024 - the work significantly intensified. A parsing/computing support has been added for numerous properties and functions and moreover, a lot of new functionalities and bug fixes landed afterwards. One could expect some more things to land by the end of the year even if there’s not much time left.

Overall, the implementation is in progress and is far from being done, but can already be tested in many real-world scenarios. This can be done using custom WebKit builds (across various OSes) or using Safari Technology Preview on Mac. The precondition for testing is, however, that the runtime preference called CSSAnchorPositioning is enabled.

My contributions #

Since the CSS Anchor Positioning in WebKit is still work in progress, and since the demand for the set of features this module brings is high, I’ve been privileged to contribute a little to the implementation myself. My work so far has been focused around the parts of API that allow creating menu-like elements becoming visible on demand.

The first challenge with the above was to fix various problems related to toggling visibility status such as:

• WebProcess crash on toggling visibility status
• Layout broken

The obvious first step towards addressing the above was to isolate elegant scenarios to reproduce the above. In the process, I’ve created some test cases, and added them to WPT. With tests in place, I’ve imported them into WebKit’s source tree and proceeded with actual bug fixing. The result was the fix for the above crash, and the fix for the layout being broken. With that in place, the visibility of menu-like elements can be changed without any problems now.

The second challenge was about the missing features allowing automatic alignment to the anchor. In a nutshell, to get the alignment like in the Figure 3:

there are 2 possibilities:

• The position-area CSS property can be used: position-area: bottom center;.
• The anchor-center value of justify-self can be used: justify-self: anchor-center;.

At first, I wasn’t aware of the anchor-center and hence I’ve started initial work towards supporting position-area. Once I became aware, however, I’ve switched my focus to implementing anchor-center and left the above for Apple to continue - not to block them. Until now, both the initial and core parts of anchor-center implementation have landed. It means, the basic support is in place.

Despite anchor-center layout tests passing, I’ve already discovered some problems such as:

• The problem with default anchor resolution.
• The problem with incorrect sizing in some corner-cases.

and I anticipate more problems may appear once the testing intensifies.

To address the above, I’ll be focusing on adding extra WPT coverage along with fixing the problems one by one. The key is to make sure that at the end of the day, all the unexpected problems are covered with WPT test cases. This way, other web engines will also benefit.

The future #

With WebKit’s implementation of CSS Anchor Positioning in its current shape, the work can be very much parallel. Assuming that Apple will keep working on that at the same pace as they did for the past few months, I wouldn’t be surprised if CSS Anchor Positioning would be pretty much done by the end of 2025. If the implementation in Gecko doesn’t stall, I think one can also expect a lot of activity around testing in the WPT. With that, the quality of implementation across the web engines should improve, and eventually (perhaps in 2026?) the CSS Anchor Positioning should reach the state of full interoperability.

Update on what happened in WebKit in the week from December 16 to December 23.

Cross-Port 🐱

JavaScriptCore 🐟

Graphics 🖼️

Releases 📦️

Excited to get started on my blogging journey!

I’ve been planning to get this going for a while, and finally got around to it during the Christmas break :) .

Here’s a little bit about me…

I started working at Igalia a little over a year ago, after having decided I really wanted to work in open source software, and contributing to the chromium project was a natural choice, having worked on it previously. Igalia as a company doesn’t need any introductions in the open source community, and so I ended up here and have the privilege to be working with some amazing people, and getting to learn a lot.

2024 has been an exciting year for the Igalia’s Graphics Team. We’ve been making a lot of progress on Turnip, AMD display driver, the Raspberry Pi graphics stack, Vulkan video, and more.

Vulkan Device Generated Commands

Igalia’s Ricardo Garcia has been working hard on adding support for the new VK_EXT_device_generated_commands extension in the Vulkan Conformance Test Suite. He wrote an excellent blog post on the extension and on his work that you can read here. Ricardo also presented the extension at XDC 2024 in Montréal, which he also blogged about. Take a look and see what generating Vulkan commands directly on the GPU looks like!

Raspberry Pi Enhancements & Performance Improvements

Our very own Maíra Canal made a big contribution to improve the graphics performance of Raspberry Pi 4 & 5 devices by introducing support for “Super Pages”. She wrote an excellent and detailed blog post on what Super Pages are, how they improve performance, and comparing performance of different apps and games. You can read all the juicy details here.

She also worked on introducing CPU jobs to the Broadcom GPU kernel driver in Linux. These changes allow user space to implement jobs that get executed on the CPU in sync with the work on the GPU. She wrote a great blog post detailing what CPU jobs allow you to do and how they work that you can read here.

Christian Gmeiner on the Graphics team has also been working on adding Perfetto support to Broadcom GPUs. Perfetto is a performance tracing tool and support for it in Broadcom drivers will allow to developers to gain more insight into bottlenecks of their GPU applications. You can check out his changes to add support in the following MRs: - MR 31575 - MR 32277 - MR 31751

The Raspberry Pi team here at Igalia presented all of their work at XDC 2024 in Montréal. You can see a video below.

Linux Kernel 6.8

A number of Igalians made several contributions to the Linux 6.8 kernel release back in March of this year. Our colleague Maíra wrote a great blog post outlining these contributions that you can read here. To highlight some of these contributions:

• AMD HDR & Color Management
  • Melissa Wen has been working on improving and implementing HDR support in AMD’s display driver as well as working on color management in the Linux display stack.
• Async Flip
  • André Almeida implemented support for asynchronous page flip in the atomic DRM modesetting API.
• V3D 7.1.x Kernel Driver
  • Iago Toral contributed a number of patches upstream to get the Broadcom DRM driver working with the latest Broadcom hardware used in the Raspberry Pi 5.
• GPU stats for the Raspberry Pi 4/5
  • José María “Chema” Casanova worked on adding GPU stats support to the latest Raspberry Pi hardware.

Turnip Improvements

Dhruv Mark Collins has been very hard at work to try and bring performance parity between Qualcomm’s proprietary driver and the open source Turnip driver. Two of his big contributions to this were improving the 2D buffer to image copies on A7XX devices, and implementing unidirectional Low Resolution Z (LRZ) on A7XX devices. You can see the MR for these changes here and here.

A new member of the Igalia Graphics Team Karmjit Mahil has been working on different parts of the Turnip stack, but one notable improvement he made was to improve fmulz handling for Direct3D 9. You can check out his changes here and read more about them.

Danylo Piliaiev has been hard at work adding support for the latest generation of Adreno GPUs. This included getting support for the A750 working, and then implementing performance improvements to bring it up to parity with other Adreno GPUs in Turnip. All-together the turnip team implemented a number of Vulkan extensions and performance improvements such as:

• VK_KHR_shader_atomic_int64 - Amber
  • MR 27776
• VK_KHR_fragment_shading_rate - Danylo Piliaiev
  • MR 30905
• VK_KHR_8bit_storage - Žan Dobersek
  • MR 28254
• shaderInt8 feature - Žan Dobersek
  • MR 29875
• VK_KHR_shader_subgroup_rotate - Job Noorman
  • MR 31358
• VK_EXT_map_memory_placed - Dhruv Mark Collins
  • MR 28928
• VK_EXT_legacy_dithering - Karmjit Mahil
  • MR 30536
• VK_EXT_depth_clamp_zero_one - Danylo Piliaiev
  • MR 29387

Display Next Hackfest & Display/KMS Meet-up

Igalia hosted the 2024 version of the Display Next Hackfest. This community event is a way to get Linux display developers together to work on improving the Linux display stack. Our Melissa Wen wrote a blog post about the event and what it was like to organize it. You can read all about it here.

Just in-case you thought you couldn’t get enough Linux display stack, Melissa also helped organize a Display/KMS meet-up at XDC 2024. She wrote all about that meet-up and the progress the community made on her blog here.

AMD Display & AMDGPU

Melissa Wen has also been hard at work improving AMDGPU’s display driver. She made a number of changes including improving display debug log to include hardware color capabilities, Migrating EDID handling to EDID common code and various bug fixes such as:

• Fixing null-pointer dereference on edid reading
  • https://lore.kernel.org/amd-gfx/20240216122401.216860-1-mwen@igalia.com/
• Checking dc_link before dereferencing
  • https://lore.kernel.org/amd-gfx/20240227190828.444715-1-mwen@igalia.com/
• Using mpcc_count to log MPC state
  • https://lore.kernel.org/amd-gfx/20240412163928.118203-1-mwen@igalia.com/
• Fixing cursor offset on rotation 180
  • https://lore.kernel.org/amd-gfx/20240807075546.831208-22-chiahsuan.chung@amd.com/
• Fixes for kernel crashes since cursor overlay mode
  • https://lore.kernel.org/amd-gfx/20241217205029.39850-1-mwen@igalia.com/

Tvrtko Ursulin, a recent addition to our team, has been working on fixing issues in AMDGPU and some of the Linux kernel’s common code. For example, he worked on fixing bugs in the DRM scheduler around missing locks, optimizing the re-lock cycle on the submit path, and cleaned up the code. On AMDGPU he worked on improving memory usage reporting, fixing out of bounds writes, and micro-optimized ring emissions. For DMA fence he simplified fence merging and resolved a potential memory leak. Lastly, on workqueue he fixed false positive sanity check warnings that AMDGPU & DRM scheduler interactions were triggering. You can see the code for some of changes below: - https://lore.kernel.org/amd-gfx/20240906180639.12218-1-tursulin@igalia.com/ - https://lore.kernel.org/amd-gfx/20241008150532.23661-1-tursulin@igalia.com/ - https://lore.kernel.org/amd-gfx/20241227111938.22974-1-tursulin@igalia.com/ - https://lore.kernel.org/amd-gfx/20240813135712.82611-1-tursulin@igalia.com/ - https://lore.kernel.org/amd-gfx/20240712152855.45284-1-tursulin@igalia.com/

Vulkan & OpenGL Extensions

• GL_EXT_texture_offset_non_const
  • Ricardo was busy working on extending OpenGL by adding this extension to GLSL as well as providing an implementation for it in glslang
• VK_KHR_video_encode_av1 & VK_KHR_video_decode_av1
  • Igalia is listed as a contributor to these extensions and worked very hard to implement CTS support for the extensions.

Etnaviv Improvements

Christian Gmeiner, one of the maintainers of the Etnaviv driver for Vivante GPUs, has been hard at work this year to make a number of big improvements to Etnaviv. This includes using hwdb to detect GPU features, which he wrote about here. Another big improvement was migrating Etnaviv to use isaspec for the GPU isa description, allowing an assembler and disassembler to be generated from XML. This also allowed Etnaviv to reuse some common features in Mesa for assemblers/disassemblers and take advantage of the python code generation features others in the community have been working on. He wrote a detailed blog about it, that you can find here. On the same vein of Etnaviv infrastructure improvements, Christian has also been working on a new shader compiler, written in Rust, called “EBC”. Christian presented this new shader compiler at XDC 2024 this year. You can check out his presentation below.

On the side of new features, Christian landed a big one in Mesa 24.03 for Etnaviv: Multiple Render Target (MRT) support! This allows games and applications to render to multiple render targets (think framebuffers) in a single graphics operations. This feature is heavily used by deferred rendering techniques, and is a requirement for later versions of desktop OpenGL and OpenGL ES 3. Keep an eye on Christian’s blog to see any of his future announcements.

Lavapipe/LLVMpipe, Android & ChromeOS

I had a busy year working on improving Lavapipe/LLVMpipe platform integration. This started with adding support for DMABUF import/export, so that the display handles from Android Window system could be properly imported and mapped. Next came Android window system integration for DRI software rendering backend in EGL, and lastly but most importantly came updating the documentation in Mesa for building Android support. I wrote all about this effort here.

The latter half on the year had me working on improving lavapipe’s integration with ChromeOs, and having Lavapipe work as a host Vulkan driver for Venus. You can see some of the changes I made in virglrenderer here and crosvm here. This work is still ongoing.

What’s Next?

We’re not planning to stop our 2024 momentum, and we’re hopping for 2025 to be a great year for Igalia and the Linux graphics stack! I’m booked to present about Lavapipe at Vulkanised 2025, where Ricardo will also present about Device-Generated Commands. Maíra & Chema will be presenting together at FOSDEM 2025 about improving performance on Raspberry Pi GPUs, and Melissa will also present about kworkflow there. We’ll also be at XDC 2025, networking and presenting about all the work we are doing on the Linux graphics stack. Thanks for following our work this year, and here’s to making 2025 an even better year for Linux graphics!

As 2024 draws to a close, it’s a perfect time to reflect on the year’s accomplishments done by the Multimedia team in Igalia. In our consideration, there were three major achievements:

1. WebRTC’s support in WPE/WebKitGTK with GStreamer.
2. GES maturity improved for real-life use-cases.
3. Vulkan Video development and support in GStreamer.

WebRTC support in WPE/WebKitGTK with GStreamer #

WPE and WebKitGTK are WebKit ports maintained by Igalia, the former for embedded devices and the latter for applications with a full-featured Web integration.

WebRTC is a web API that allows real-time communication (RTC) directly between web browser and applications. Examples of these real-time communications are video conferencing, cloud gaming, live-streaming, etc.

Some WebKit ports support libwebrtc, an open-source library that implements the WebRTC specification, developed and maintained by Google. WPE and WebKitGTK originally also supports libwebrtc, but we started to use also GstWebRTC, a set of GStreamer plugins and libraries that implement WebRTC, which adapts perfectly to the multimedia implementation in both ports, also in GStreamer.

This year the fruits of this work have been unlocked by enabling Amazon Luna gaming:

https://www.youtube.com/watch?v=lyO7Hqj1jMs

And also enabling a CAD modeling, server-side rendered service, known as Zoo:

https://www.youtube.com/watch?v=CiuYjSCDsUM

WebKit Multimedia #

WebKit made significant improvements in multimedia handling, addressing various issues to enhance stability and playback quality. Key updates include preventing premature play() calls during seeking, fixing memory leaks. The management of track identifiers was also streamlined by transitioning from string-based to integer-based IDs. Additionally, GStreamer-related race conditions were resolved to prevent hangs during playback state transitions. Memory leaks in WebAudio and event listener management were addressed, along with a focus on memory usage optimizations.

The handling of media buffering and seeking was enhanced with buffering hysteresis for smoother playback. Media Source Extensions (MSE) behavior was refined to improve playback accuracy, such as supporting markEndOfStream() before appendBuffer() and simplifying playback checks. Platform-specific issues were also tackled, including AV1 and Opus support for encrypted media and better detection of audio sinks. And other improvements on multimedia performance and efficiency.

GES maturity improved for real-live use-cases #

GStreamer Editing Services (GES) is a set of GStreamer plugins and a library that allow non-linear video editing. For example, GES is what’s behind of Pitivi, the open source video editor application.

Last year, GES was deployed in web-based video editors, where the actual video processing is done server-side. These projects allowed, in great deal, the enhancement and maturity of the library and plugins.

Tella is a browser-based tool that allow to screen record and webcam, without any extra software. Finished the recording, the user can edit, in the browser, the video and publish it.

https://www.youtube.com/watch?v=uSWqWHBRDWE

Sequence is a complete, browser-based, video editor with collaborative features. GES is used in the backend to render the editing operations.

https://www.youtube.com/watch?v=bXNdDIiG9lE

Vulkan Video development and GStreamer support #

The last but not the least, this year we continue our work with the Vulkan Video ecosystem by working the task subgroup (TSG) enabling H.264/H.265 encoding, and AV1 decoding and encoding.

Early this year we delivered a talk in the Vulkanised about our work, which ranges from the Conformance Test Suite (CTS), Mesa, and GStreamer.

https://www.youtube.com/watch?v=z1HcWrmdwzI

Conclusion #

As we wrap up 2024, it’s clear that the year has been one of significant progress, driven by innovation and collaboration. Here’s to continuing the momentum and making 2025 even better!

Update on what happened in WebKit in the week from December 9 to December 16.

Cross-Port 🐱

Web Platform 🌐

Multimedia 🎥

JavaScriptCore 🐟

Graphics 🖼️

Hello, world!

Greetings from far north of Brazil! My name is Nick Diego Yamane. I’m originally from Maués, a small town that sits in the heart of the Amazon rainforest. Since 2002, I live in Manaus, from where I work remotely for Igalia, a spanish flat worker-owned consultancy specialized in core open source technologies. I’m part of its amazing Chromium team since 2018, along with other talented people spread around the world.

Update on what happened in WebKit in the week from December 3 to December 10.

Web Platform 🌐

Graphics 🖼️

An­nounc­ing a poly­fill for the TC39 dec­i­mal pro­pos­al

I’m hap­py to an­nounce that the dec­i­mal pro­pos­al—a pro­posed ex­ten­sion of JavaScript to sup­port dec­i­mal num­bers—is now avail­able as an NPM pack­age called pro­pos­al-dec­i­mal!

(Ac­tu­al­ly, it has been avail­able for some time, made avail­able not long af­ter we de­cid­ed to pur­sue IEEE 754 Dec­i­mal128 as a data mod­el for the dec­i­mal pro­pos­al rather than some al­ter­na­tives. The old pack­age was—and still is—avail­able un­der a dif­fer­ent name—dec­i­mal128—but I’ll be sun­set­ting that pack­age in fa­vor of the new one an­nounced here. If you’ve been us­ing dec­i­mal128, you can con­tin­ue to use it, but you’ll prob­a­bly want to switch to pro­pos­al-dec­i­mal.)

To use pro­pos­al-dec­i­mal in your project, in­stall the NPM pack­age. If you’re look­ing to use this code in Node.js or oth­er JS en­gines that sup­port ESM, you'll want to im­port the code like this:

im­port { Dec­i­mal128 } from 'pro­pos­al-dec­i­mal';
con­st x = new Dec­i­mal128("0.1");
// etc.

For use in a brows­er, the file dist/Dec­i­mal128.mjs con­tains the Dec­i­mal128 class and all its in­ter­nal de­pen­den­cies in a sin­gle file. Use it like this:

<script type="mod­ule">
im­port { Dec­i­mal128 } from 'path/to/Dec­i­mal128.mjs';
con­st x = new Dec­i­mal128("0.1");
// keep rock­ing dec­i­mals!
</script>

The in­ten­tion of this poly­fill is to track the spec text for the dec­i­mal pro­pos­al. I can­not rec­om­mend this pack­age for pro­duc­tion use just yet, but it is us­able and I’d love to hear any ex­pe­ri­ence re­ports you may have. We’re aim­ing to be as faith­ful as pos­si­ble to the spec, so we don’t aim to be blaz­ing­ly fast. That said, please do re­port any wild de­vi­a­tions in per­for­mance com­pared to oth­er dec­i­mal li­braries for JS as an is­sue. Any crash­es or in­cor­rect re­sults should like­wise be re­port­ed as an is­sue.

En­joy!

Suppose you have some files you want to directly commit to a branch in your current git repository, doing so without perturbing your current branch. Why would you want to do that? My current motivating use case is to commit all my draft muxup.com posts to a separate branch so I can get some tracking and backups without needing to add WIP work to the public repo. But I also use essentially the same approach to make a throw-away commit of the current repo state (including any non-staged or non-committed changes) to be pushed to a remote machine for building.

Our goal is to create a commit, so a sensible starting point is to break down what's involved. Referring to Git documentation we can break down the different object types that we need to put together a commit:

• A commit object contains metadata as well as a reference a tree object.
• A tree object is essentially a list of blob objects and other tree objects with extra metadata such as name and permissions.
• A blob object is a chunk of data (e.g. a file).

Although it's possible to build a tree object semi-manually using git hash-object to create blobs and git mktree for trees, fortunately this isn't necessary. Using a throwaway git index file allows us to rely on git to create the tree object for us after indicating the files to be included. The basic approach is:

• Identify the files you wish to commit.
• Set the GIT_INDEX_FILE environment variable to a throwaway/temporary name.
• Add the files to the temporary index (git update-index is the 'plumbing' way of doing this, but git add can work just fine as well).
• Create a tree object from the index using git write-tree.
• Create a commit object with an appropriate commit message and parent.
  • You likely want to bail out and avoid creating a commit that changes no files if it turns out the tree is unmodified vs the parent commit.
• Use git update-ref to update the branch ref to point to the new commit.
• Remove the temporary index file.

Implementation in Python

Here is how I implemented this in the site generator I use for muxup.com:

def commit_untracked() -> None:
    def exec(*args: Any, **kwargs: Any) -> tuple[str, int]:
        kwargs.setdefault("encoding", "utf-8")
        kwargs.setdefault("capture_output", True)
        kwargs.setdefault("check", True)

        result = subprocess.run(*args, **kwargs)
        return result.stdout.rstrip("\n"), result.returncode

    result, _ = exec(["git", "status", "-uall", "--porcelain", "-z"])
    untracked_files = []
    entries = result.split("\0")
    for entry in entries:
        if entry.startswith("??"):
            untracked_files.append(entry[3:])

    if len(untracked_files) == 0:
        print("No untracked files to commit.")
        return

    bak_branch = "refs/heads/bak"
    show_ref_result, returncode = exec(
        ["git", "show-ref", "--verify", bak_branch], check=False
    )
    if returncode != 0:
        print("Branch {back_branch} doesn't yet exist - it will be created")
        parent_commit = ""
        parent_commit_tree = None
        commit_message = "Initial commit of untracked files"
        extra_write_tree_args = []
    else:
        parent_commit = show_ref_result.split()[0]
        parent_commit_tree, _ = exec(["git", "rev-parse", f"{parent_commit}^{{tree}}"])
        commit_message = "Update untracked files"
        extra_write_tree_args = ["-p", parent_commit]

    # Use a temporary index in order to create a commit. Add any untracked
    # files to the index, create a tree object based on the index state, and
    # finally create a commit using that tree object.
    temp_index = pathlib.Path(".drafts.gitindex.tmp")
    atexit.register(lambda: temp_index.unlink(missing_ok=True))
    git_env = os.environ.copy()
    git_env["GIT_INDEX_FILE"] = str(temp_index)
    nul_terminated_untracked_files = "\0".join(file for file in untracked_files)
    exec(
        ["git", "update-index", "--add", "-z", "--stdin"],
        input=nul_terminated_untracked_files,
        env=git_env,
    )
    tree_sha, _ = exec(["git", "write-tree"], env=git_env)
    if tree_sha == parent_commit_tree:
        print("Untracked files are unchanged vs last commit - nothing to do.")
        return
    commit_sha, _ = exec(
        ["git", "commit-tree", tree_sha] + extra_write_tree_args,
        input=commit_message,
    )
    exec(["git", "update-ref", bak_branch, commit_sha])

    diff_stat, _ = exec(["git", "show", "--stat", "--format=", commit_sha])

    print(f"Backup branch '{bak_branch}' updated successfully.")
    print(f"Created commit {commit_sha} with the following modifications:")
    print(diff_stat)

For my particular use case, creating a commit containing only the untracked files is what I want. I'm happy to lose the ability to precisely recreate the repository state for the combination of tracked and untracked files in return for avoiding noise in the changes for the bak branch that would otherwise be present from changes to tracked files. Using paths separated by NUL via stdin is overkill here, but as it doesn't increase complexity of the code much, I've opted for the most universal approach in case I copy the logic to other projects.

• 2024-12-09: Initial publication date.

^{This is based on this previous blog post by Alicia, and I recommend taking a look - many things mentioned in it are still useful here.
Reading a symbol’s documentation in a popup}

The most straight-forward option would have been to just install another instance of my IDE inside the container. However, I use NixOS + Home Manager to manage and configure my packages declaratively, so the Ubuntu-based container environment would be a quite frustrating difference:

1. Package versions will be lagging behind, and sooner or later I will have to deal with differences with configuration, features, or bugs. For example, at time of writing, neovim is packaged in Debian 24.10 at version 0.9.5, while nixpkgs ships 0.10.2. (To be fair, Flathub and Snapcraft would be up-to-date as well, but I have my gripes with those too.)

2. Either way, I now have a new set of configurations to manage and keep in sync with their canonical versions on the host system.

3. Any other tools I don’t install in the container, I won’t have access to - for example, for running commands from inside my IDE.

Overall, this will waste time and disk space better used for other things. So, after trying out a few different approaches, a clangd wrapper script that bridges the disconnect between my host system and the container was the first satisfying solution I found.

Conveniently, this fits well with my approach of writing wrappers around wkdev scripts to expose as much functionality as possible to my host system, to avoid manually entering the container - in effect abstracting it out of sight.

Step 1: Wrapper script #

This is roughly the script I currently use. I personally prefer nushell, but I will go into details below so you can write your own version in whatever language you prefer.

The idea is to start clangd inside the container, and use socat to expose its stdin/out to the IDE over TCP. That is to avoid this podman issue I ran into if I tried using stdin.

#!/usr/bin/env -S nu --stdin

def main [
  --name (-n): string = "wkdev-sdk"
  --show-config
] {
  # picking a random port for the connection avoids colliding with itself in case an earlier instance of this script is still around
  let port = random int 2000..5000 
  let workdir = $"/host(pwd)"

  # the container SDK mounts your home directory to `/host/home/...`,
  # so as long as the WebKit checkout is somewhere within your $HOME,
  # mapping paths is as easy as just prepending `/host`
  let mappings_table = ["Source" "WebKitBuild/GTK/Debug" "WebKitBuild/GTK/Release"]
    | each {|path| {host: $"($env.WEBKIT_DIR)/($path)" container: $"/host($env.WEBKIT_DIR)/($path)"}}

  let mappings = $mappings_table
    | each {|it| $"($it.host)=($it.container)" }
    | str join ","

  let podman_args = [
    exec
    --detach
    --user
    1000:100
    $name
  ]

  let clangd_args = [
    $"--path-mappings=($mappings)"
    --header-insertion=never  # clangd has the tendency to insert unnecessary includes, so I prefer to just disable the feature.
    --limit-results=5000      # The default limit for reference search results is too low for WebKit
    --background-index
    --enable-config           # Enable reading .clangd file
    -j 8
  ]

  # Show results of above configuration when called with --show-config, particularly helpful for debugging
  if $show_config {
    {
      port: $port
      work_dir: $workdir
      mappings: $mappings_table
      podman_args: $podman_args
      clangd_args: $clangd_args
    }
  } else {
    # ensure that the container is running
    podman start $name | ignore

    # container side
    ( podman ...$podman_args /usr/bin/env $'--chdir=($workdir)' socat 
      $"tcp-l:($port),fork"
      $"exec:'clangd ($clangd_args | str join (char space))'"
    ) | ignore

    # host side
    nc localhost $port
  }
}

Step 2: IDE setup #

IDE setup is largely the same as it would usually be, aside from pointing the clangd path at our wrapper script instead. I use helix, where I just need to add a .helix/languages.toml to the WebKit checkout directory:

[language-server.clangd]
command = "/path/to/clangd_wrapper"

In VS Code, you need the clangd extension, then you can enter the absolute path to the script under File > Preferences > Settings > Extensions/clangd > Clangd: Path, ideally in the Workspace tab so the setting only applies to WebKit.

Step 3: clangd setup #

Clangd will require two things to be set up at the root of your WebKit checkout:

First, create a compile_commands.json symlink for the build you will use, for example to WebKitBuild/GTK/Debug/compile_commands.json.

Secondly, a .clangd (which is what we needed the --enable-config flag for) at the root of the WebKit checkout:

If:
	PathMatch: "(/host/home/vivienne/dev/work/metro/wk/up)?Source/.*\\.h"
	PathExclude: "(/host/home/vivienne/dev/work/metro/wk/up)?Source/ThirdParty/.*"

CompileFlags:
	Add: [-include, config.h]

I created both files manually, but as of [cmake] Auto-complete via clangd auto-setup, there seem to be new scripts to help with setting up and updating both files. (Thanks Alicia!) I haven’t tried it so far, but I recommend you take a look yourself.

Conclusion #

^{Searching for a field using the symbol picker}

Overall, I’m very satisfied with the results, so far everything is working like I expected it to. Finally having a working language server brought me the usual benefits - I mostly got rid of the manual compile-fix cycles that introduced so much friction and waiting times, and trivial mistakes and typos are much less of a headache now. But the biggest improvement, to me, is Goto definition/references and the symbol picker, making it easier to grasp how things interact. Much better than using grep over and over!

As I was fighting clangd/podman, I also came across some other options that I didn’t try, but might be interesting to look at:

1. VSCode dev containers
   Probably the most polished option, though it is exclusive to VSCode - from what I understand, the extension isn’t even available to forks for licensing reasons.

2. Distant
   Its main purpose is to act as a tool for working remotely, but I don’t see why it couldn’t be used with a container. It is still in alpha, and so far only has support in Neovim. I can’t tell how well it would play with LSP, but it might be worth a shot if you already use Neovim.

As I have spent the last 6 months starting to explore the rather precarious position we've placed web ecosystem in, with regard to how browsers are maintained and funded, I thought I'd dive into another angle: The ways that web platform features get prioritized and built.

I worked on Microsoft Edge, so I have direct experience working on a browser team. My current work is at Igalia, which is an open source consultancy that is hired by companies to work on many things across technology. My team, the web platform team, implements web platform features and APIs, and works on their specifications. Yes. You can pay for browser features to be built and for specifications to be written/updated/continued. We'll talk about both.

Browser vendors #

Browser vendors are the companies that develop, maintain and distribute a web browser. Some browser vendors are also stewards of a whole engine/browser (blink, WebKit and gecko). Google, Apple, Mozilla, Microsoft, Opera, Vivaldi, etc are all browser vendors. Google, Apple and Mozilla are engine stewards.

There are many teams that make up an entire browser team. A browser is so much more than just the web platform too. There is quite a lot of thought and design that goes into even the smallest user experience updates.

General consumer facing features, which typically have a UI component, tend to often get prioritized over more "hidden" web platform features for developers. The general consumer base is larger than the developer base. The goal is more market share (more people using your browser) which helps bring money to the browser vendor.

The web platform team works on browser features and specifications and making sure the implementation matches the spec, so you don't get different behavior in different browsers. But they're also there to enable what we'll refer to as "first party" needs.

First Party Development #

First party refers to groups within the same company as the browser vendor. Microsoft Office/Microsoft 365 is an example of a first party within Microsoft with web platform needs. Subsequently, their needs for the web will get prioritized.

Surface Duo is another example. I spent a lot of time talking about the web platform primitives and design considerations for dual screen devices. Having layout capabilities that adapted to this new form factor was incredibly important so the specification and implementing those features were also prioritized.

In my experience, first party development is typically prioritized above all else as you're enabling/enhancing another product in the company. Especially if those products are money-makers. These are also broader company strategic initiatives and very visible ways to make impact.

Come yearly review time, these things matter for compensation and bonuses. It is all deeply intertwined in company politics. These are things that make the company money and make the business case for having a browser. Bill Gates' The Internet Tidal Wave memo from 1995 even points out how access to the internet through PCs is vital for the business. Enhancing user experience and moving the web forward will be what wins consumers over.

External Companies and Third Party Development #

Another scenario is when an external, or third party, company has needs for the web platform. My experience with this while working at a browser vendor company is more limited. Third party can also mean general web developers. It was much harder to get the needs of the general web development community prioritized when first party often takes priority.

I truthfully can't remember whether it was/is possible for third parties to ask Microsoft to work on enabling certain features. I mean, of course you can ask, but I'm not sure how often an agreement would be made. With a relatively small team working on enabling web platform features, this probably wasn't/isn't a common scenario unless there's some big underlying strategic initiative that would benefit the browser and company. This type of contract could entirely have been outside my sphere of work.

The trouble with being a third party is that it's not as easy to align priorities or business cases. In fact, you might even be a competitor. Regardless, since resources are finite, it's likely that it's difficult to convince vendors to pay attention to your specific needs. At the end of the day, practically speaking, funding is required to advance features, fix bugs, etc.

Consultancies #

Guess what? Yes! You can hire experts to implement web browser features and/or give you that attention and priority! Do you need a new feature implemented or spec'd? A consultancy can help. Do you need bugs that are affecting your organization fixed? A consultancy can help.

If you have a need for a web platform feature, there are consultancies available for hire to help write and edit the specifications, work with standards groups, write web platform tests and get that feature shipped (or ready to be shipped).

I work for Igalia, and you can hire us for many things across many technologies and areas including web platform development.

In fact, we've been pivotal in moving forward a whole lot of things in the Web Platform, including features like CSS Grid, :has, container queries, MathML, classes in JavaScript, scroll snap, list-stlye-type: <string>...the list does go on and on. We work on lots of specifications and implementations for the web platform.

Instead of waiting or relying on a browser vendor to implement the features you need, which could potentially be years or even possibly never, you can hire experts like Igalia to do this work.

Why should I hire a consultancy to build web platform features? #

The most obvious answer is: It works. We've helped a lot of happy customers do amazing things.

Aside from needing features more quickly, hiring a consultancy like Igalia has advantages. We are experts in these processes and the dynamics of working in standards bodies, and our strength comes from not only our technical expertise, but our ability to navigate between the three main browser vendors with web engines to ensure feature design is agreed upon. This is a lot of work and often times it can be slow because there are only a handful of people at browser vendor companies who are responsible for reviewing patches, proposed features, design documents, etc etc.

Let's say you are a customer with a web platform need. You most likely have a backlog of work for your engineering team. There could be a few different scenarios that prevent you from internally prioritizing the web platform need: No one on the engineering team has the technical background for the type of work you need done, someone might have the technical background but not enough time to manage the entire process of spec writing, test writing and implementation, or maybe the team just doesn't have the capacity based on broader company priorities and product roadmaps.

When you hire a consultancy to do this work, then your product engineering team can spend time on the product work and roadmap while we work on the spec, implementation and coordinating among browser vendors. This stuff takes a lot of time, because it's the nature of the work, and it's our area of expertise.

Funding specific features #

There have also been instances where specific features have been funded by the community or donors, primarily driven by a want for better support and not by a business need, even though there most likely are business needs for such feature improvements out there somewhere.

The MathML work Igalia has been doing is an example of that. Igalia also ran an open prioritization experiment where the community collectively selected and funded a feature.

Sometimes there are really vital features the web needs, but for whatever reason, they're not a priority. With that being said, if anyone's interested in helping to advance and improve SVG, drop Igalia an email. We'd love to work on it.

Closing #

I have encountered many people since starting at Igalia earlier this year, who didn't know you could hire someone to build a browser feature, or work on a specification, or fix browser bugs. You can even hire us to work on improving a novel web browser engine (say hello to Servo), because you might need a web browser solution that is more lightweight than the major open source options.

Or maybe you need a browser for your Extended Reality/Virtual Reality device. With 50% of Meta Quest users spending time in the browser, it would be a missed opportunity to not offer the same on your device. This is where we come in with Wolvic. It's designed with browsing in XR in mind, and you don't have to build a browser from the ground up.

There are so many benefits to hiring someone to work on The Web in whatever way you may need. It also means the web platform can advance more quickly (in browser timescales anyway) because more people outside of browser vendors are working on things.

And that's good for the overall health of the web ecosystem.

Note: Thank you to my colleague Brian Kardell for reviewing & editing this post, which had been taking up a lot of space in my mind for a long while.

Editing text in HTML canvas has never been easy. It requires identifying which character is under the hit point in order to place a caret, and it requires computing bounds for a range of text that is selected. The existing implementations of Canvas TextMetrics made these things possible, but not without a lot of Javascript making multiple expensive calls to compute metrics for substrings. Three new additions to the TextMetrics API are intended to support editing use cases in Canvas text. They are in the standards pipeline, and implemented in Chromium-based browsers behind the ExtendedTextMetrics flag:

• getIndexFromOffset gives the location in a string corresponding to a pixel length along the string. Use it to identify where the caret is in the string, and what the bounds of a selection range are.
• getSelectionRects returns the rectangles that a browser would use to highlight a range of text. Use it to draw the selection highlight.
• getActualBoundingBox returns the bounding box for a sub-range of text within a string. Use it if you need to know whether a point lies within a substring, rather than the entire string.

To enable the flag, use --enable-blink-features=ExtendedTextMetrics when launching Chrome from a script or command line, or enable “Experimental Web Platform features” via chrome://flags/#enable-experimental-web-platform-features.

I wrote a basic web app (opens in a new tab) in order to demonstrate the use of these features. It will function in Chrome versions beyond 128.0.6587.0 (Canary at the time of writing) with the above flags set. Some functionality is available in Safari Preview, and it’s growing all the time.

The app allows the editing of a single line of text drawn in an HTML canvas. Here I’ll work through usage of the new features.

Detecting a Link Click #

In the demo, the first instance of “new Canvas Text Metrics” is considered a link back to this blog page. Canvas Text has no notion of links, and thousands of people have looked at Stack Exchange for a way to insert hyperlinks in canvas text. Part of the problem, assuming you know where the link is in the text, is determining when the link was clicked on. The TextMetrics getActualBoundingBox(start, end) method is intended to simplify the problem by returning the bounding box of a substring of the text, in this case the link.

  onStringChanged() {
    text_metrics = context.measureText(string);
    link_start_position = string.indexOf(link_text);
    if (link_start_position != -1) {
      link_end_position = link_start_position + link_text.length;
    }
  }
...
linkHit(x, y) {
    let bound_rect = undefined;
    try {
      bound_rect = text_metrics.getActualBoundingBox(link_start_position, link_end_position);
    } catch (error) {
      return false;
    }
    let relative_x = x - string_x;
    let relative_y = y - string_y;
    return relative_x >= bound_rect.left && relative_y >= bound_rect.top
        && relative_x < bound_rect.right && relative_y < bound_rect.bottom;
  }

The first function finds the link in the string and stores the start and end string offsets. When a click event happens, the second method is called to determine if the hit point was within the link area. The text metrics object is queried for the bounding box of the link’s substring. Note the call is contained within a try...catch block because an exception will be returned if the substring is invalid. The event offset is mapped into the coordinate system of the text (in this case by subtracting the text location) and the resulting point is tested against the rectangle.

In more general situations you may need to use a regular expression to find links, and keep track of a more complex transformation chain to convert event locations into the text string’s coordinate system.

Mapping a Point to a String Index #

A primary concept of any editing application is the caret location because it indicates where typed text will appear, or what will be deleted by backspace, or where an insertion will happen. Mapping a hit point in the canvas into the caret position in the text string is a fundamental editing operation. It is possible to do this with existing methods but it is expensive (you can do a binary search using the width of substrings).

The TextMetrics getIndexFromOffset(offset) method uses existing code in browsers to efficiently map a point to a string position. The underlying functionality is very similar to the document.caretPositionFromPoint(x,y) method, but modified for the canvas situation. The demo code uses it to position the caret and to identify the selection range.

  text_offset = event.offsetX - string_x;
  caret_position = text_metrics.getIndexFromOffset(text_offset);

The getIndexFromOffset function takes the horizontal offset, in pixels, measured from the origin of the text (based on the textAlign property of the canvas context). The function finds the character boundary closest to the given offset, then returns the character index to the right for left-to-right text, and to the left for right-to-left text. The offset can be negative to allow characters to the left of the origin to be mapped.

In the figure below, the top string has textDirection = "ltr" and textAlign = "center". The origin for measuring offsets is the center of the string. Green shows the offsets given, while blue shows the indexes returned. The bottom string demonstrates textDirection = "rtl" and textAlign = "start".

An offset past the beginning of the text always returns 0, and past the end returns the string length. Note that the offset is always measured left-to-right, even if the text direction is right-to-left. The “beginning” and “end” of the text string do respect the text direction, so for RTL text the beginning is on the right.

The getIndexFromOffset function may produce very counter-intuitive results when the text string has mixed bidi content, such as a latin substring within an arabic string. As the offset moves along the string the positions will not steadily increase, or decrease, but may jump around at the boundaries of a directional run. Full handling of bidi content requires incorporating bidi level information, particularly for selecting text, and is beyond the scope of this article.

Selection Rectangles #

Selected text is normally indicated by drawing a highlight over the range, but to produce such an effect in canvas requires estimating the rectangle using existing text metrics, and again making multiple queries to text metrics to obtain the left and right extents. The new TextMetrics getSelectionRects(start, end) function returns a list of browser defined selection rectangles for the given subrange of the string. There may be multiple rectangles because the browser returns one for each bidi run; you would need to draw them all to highlight the complete range. The demo assumes a single rectangle because it assumes no mixed-direction strings.

selection_rect = text_metrics.getSelectionRects(selection_range[0], selection_range[1])[0];
...
context.fillStyle = 'yellow';
context.fillRect(selection_rect.x + string_x,
                 selection_rect.y + string_y,
                 selection_rect.width,
                 selection_rect.height)

Like all the new methods, the rectangle returned is in the coordinate system of the string, as defined by the transform, textAlign and textBaseline.

Conclusion #

The new Canvas Text Metrics described here are in the process of standardization. Follow WHATWG Issue #10677 and add your feedback.

Thanks #

The implementation of Canvas Text Features was aided by Igalia S.L. funded by Bloomberg L.P.

How bi­na­ry float­ing points can let us down

If you've played Mo­nop­oly, you'll know abuot the Bank Er­ror in Your Fa­vor card in the Com­mu­ni­ty Chest. Re­mem­ber this?

A bank er­ror in your fa­vor? Sweet! But what if the bank makes an er­ror in its fa­vor? Sure­ly that's just as pos­si­ble, right?

I'm here to tell you that if you're do­ing every­day fi­nan­cial cal­cu­la­tions—noth­ing fan­cy, but in­volv­ing mon­ey that you care about—then you might need to know that us­ing bi­na­ry float­ing point num­bers, then some­thing might be go­ing wrong. Let's see how bi­na­ry float­ing-point num­bers might yield bank er­rors in your fa­vor—or the bank's.

In a won­der­ful pa­per on dec­i­mal float­ing-point num­bers, Mike Col­ishaw gives an ex­am­ple.

Here's how you can re­pro­duce that in JavaScript:

(1.05 * 0.7).to­Pre­ci­sion(2);
# 0.73

Some pro­gram­mers might not be aware of this, but many are. By point­ing this out I'm not try­ing to be a smar­ty­pants who knows some­thing you don't. For me, this ex­am­ple il­lus­trates just how com­mon this sort of er­ror might be.

For pro­gram­mers who are aware of the is­sue, one typ­i­cal ap­proache to deal­ing with it is this: Nev­er work with sub-units of a cur­ren­cy. (Some cur­ren­cies don't have this is­sue. If that's you and your prob­lem do­main, you can kick back and be glad that you don't need to en­gage in the fol­low­ing sorts of headaches.) For in­stance, when work­ing with US dol­lars of eu­ros, this ap­proach man­dates that one nev­er works with eu­ros and cents, but only with cents. In this set­ting, dol­lars ex­ist only as an ab­strac­tion on top of cents. As far as pos­si­ble, cal­cu­la­tions nev­er use floats. But if a float­ing-point num­ber threat­ens to come up, some form of round­ing is used.

An­oth­er aproach for a pro­gram­mer is to del­e­gate fi­nan­cial cal­cu­la­tions to an ex­ter­nal sys­tem, such as a re­la­tion­al data­base, that na­tive­ly sup­ports prop­er dec­i­mal cal­cu­la­tions. One dif­fi­cul­ty is that even if one del­e­gates these cal­cu­la­tions to an ex­ter­nal sys­tem, if one lets a float­ing-point val­ue flow int your pro­gram, even a val­ue that can be trust­ed, it may be­come taint­ed just by be­ing im­port­ed into a lan­guage that doesn't prop­er­ly sup­port dec­i­mals. If, for in­stance, the re­sult of a cal­cu­la­tion done in, say, Post­gres, is ex­act­ly 0.1, and that flows into your JavaScript pro­gram as a num­ber, it's pos­si­ble that you'll be deal­ing with a con­t­a­m­i­nat­ed val­ue. For in­stance:

(0.1).to­Pre­ci­sion(25)
# 0.1000000000000000055511151

This ex­am­ple, ad­mit­ted­ly, re­quires quite a lot of dec­i­mals (19!) be­fore the ugly re­al­i­ty of the sit­u­a­tion rears its head. The re­al­i­ty is that 0.1 does not, and can­not, have an ex­act rep­re­sen­ta­tion in bi­na­ry. The ear­li­er ex­am­ple with the cost of a phone call is there to raise your aware­ness of the pos­si­bil­i­ty that one doesn't need to go 19 dec­i­mal places be­fore one starts to see some weird­ness show­ing up.

There are all sorts of ex­am­ples of this. It's ex­ceed­ing­ly rare for a dec­i­mal num­ber to have an ex­act rep­re­sen­ta­tion in bi­na­ry. Of the num­bers 0.1, 0.2, …, 0.9, only 0.5 can be ex­act­ly rep­re­sent­ed in bi­na­ry.

Next time you look at a bank state­ment, or a bill where some tax is cal­cu­lat­ed, I in­vite you to ask how that was cal­cu­lat­ed. Are they us­ing dec­i­mals, or floats? Is it cor­rect?

I'm work­ing on the dec­i­mal pro­pos­al for TC39 to try to work what it might be like to add prop­er dec­i­mal num­bers to JavaScript. There are a few very in­ter­est­ing de­grees of free­dom in the de­sign space (such as the pre­cise datatype to be used to rep­re­sent these kinds of num­ber), but I'm op­ti­mistic that a rea­son­able path for­ward ex­ists, that con­sen­sus be­tween JS pro­gram­mers and JS en­gine im­ple­men­tors can be found, and even­tu­al­ly im­ple­ment­ed. If you're in­ter­est­ed in these is­sues, check out the README in the pro­pos­al and get in touch!

Get­ting start­ed with Lean 4, your next pro­gram­ming lan­guage

I had the plea­sure of learn­ing about Lean 4 with David Chris­tiansen and Joachim Bre­it­ner at their tu­to­r­i­al at BOBKonf 2024. I‘m plan­ning on do­ing a cou­ple of for­mal­iza­tions with Lean and would love to share what I learn as a to­tal new­bie, work­ing on ma­cOS.

Need­ed tools

I‘m on ma­cOS and use Home­brew ex­ten­sive­ly. My sim­ple go-to ap­proach to find­ing new soft­ware is to do brew search lean. This re­vealed lean as well as sur­face elan. Run­ning brew info lean showed me that that pack­age (at the time I write this) in­stalls Lean 3. But I know, out-of-band, that Lean 4 is what I want to work with. Run­ning brew info elan looked bet­ter, but the out­put re­minds me that (1) the in­for­ma­tion is for the elan-init pack­age, not the elan cask, and (2) elan-init con­flicts with both the elan and the afore­men­tioned lean. Yikes! This strikes me as a po­ten­tial prob­lem for the com­mu­ni­ty, be­cause I think Lean 3, though it still works, is pre­sum­ably not where new Lean de­vel­op­ment should be tak­ing place. Per­haps the Home­brew for­mu­la for Lean should be up­dat­ed called lean3, and a new lean4 pack­age should be made avail­able. I‘m not sure. The sit­u­a­tion seems less than ide­al, but in short, I have been suc­cess­ful with the elan-init pack­age.

Af­ter in­stalling elan-init, you‘ll have the elan tool avail­able in your shell. elan is the tool used for main­tain­ing dif­fer­ent ver­sions of Lean, sim­i­lar to nvm in the Node.js world or pyenv.

Set­ting up a blank pack­age

When I did the Lean 4 tu­to­r­i­al at BOB, I worked en­tire­ly with­in VS Code and cre­at­ed a new stand­alone pack­age us­ing some in-ed­i­tor func­tion­al­i­ty. At the com­mand line, I use lake init to man­u­al­ly cre­ate a new Lean pack­age. At first, I made the mis­take of run­ning this com­mand, as­sum­ing it would cre­ate a new di­rec­to­ry for me and set up any con­fig­u­ra­tion and boil­er­plate code there. I was sur­prised to find, in­stead, that lake init sets things up in the cur­rent di­rec­to­ry, in ad­di­tion to cre­at­ing a sub­di­rec­to­ry and pop­u­lat­ing it. Us­ing lake --help, I read about the lake new com­mand, which does what I had in mind. So I might sug­gest us­ing lake new rather than lake init.

What‘s in the new di­rec­to­ry? Do­ing tree foo­bar re­veals

foo­bar
├── Foo­bar
│   └── Ba­sic.lean
├── Foo­bar.lean
├── Main.lean
├── lake­file.lean
└── lean-tool­chain

Tak­ing a look there, I see four .lean files. Here‘s what they con­tain:

im­port «Foo­bar»

def main : IO Unit :=
  IO.print­ln s!"Hel­lo, {hel­lo}!"

-- This mod­ule serves as the root of the `Foo­bar` li­brary.
-- Im­port mod­ules here that should be built as part of the li­brary.
im­port «Foo­bar».Ba­sic

def hel­lo := "world"

im­port Lake
open Lake DSL

pack­age «foo­bar» where
  -- add pack­age con­fig­u­ra­tion op­tions here

lean_lib «Foo­bar» where
  -- add li­brary con­fig­u­ra­tion op­tions here

@[de­fault_tar­get]
lean_exe «foo­bar» where
  root := `Main

It looks like there‘s a lit­tle mod­ule struc­ture here, and a ref­er­ence to the iden­ti­fi­er hel­lo, de­fined in Foo­bar/Ba­sic.lean and made avail­able via Foo­bar.lean. I’m not go­ing to touch lake­file.lean for now; as a new­bie, it looks scary enough that I think I’ll just stick to things like Ba­sic.lean.

There‘s also an au­to­mat­i­cal­ly cre­at­ed .git there, not shown in the di­rec­to­ry out­put above.

Now what?

Now that you‘ve got Lean 4 in­stalled and set up a pack­age, you‘re ready to dive in to one of the of­fi­cial tu­to­ri­als. The one I‘m work­ing through is David‘s Func­tion­al Pro­gram­ming in Lean. There‘s all sorts of ad­di­tion­al things to learn, such as all the dif­fer­ent lake com­mands. En­joy!

As usual, let's start by introducing the problem. Suppose you want to produce either a Debian-derived sysroot for cross-compilation, something you can chroot into, or even a full image you can boot with QEMU or on real hardware. Debootstrap can get you started and has minimal external dependencies. If you wish to avoid using sudo, Running debootstrap under fakeroot and fakechroot works if building a rootfs for the same architecture as the current host, but it has problems out of the box for a foreign architecture. These tools are packaged and in the main repositories for at least Debian, Arch, and Fedora, so a solution that works without additional dependencies is advantageous.

I'm presenting my preferred solution / approach in the first subheading and relegating more discussion and background explanation to later on in the article, in order to cater for those who just want something they can try out without wading through lots of text.

Warning: I haven't found fakeroot to be as robust as I would like, even knowing its fundamental limitations with e.g. statically linked binaries. Specifically, a sporadically reproducible case involving installing lots of packages on riscv64 sid resulted in /usr/lib/riscv64-linux-gnu/libcbor.so.0.10.2 being given the directory bit in fakeroot's database (which I haven't yet managed to track down to the point I can file a useful bug report). I'm sharing this post because the approach may still be useful to people, especially if you rely on fakeroot for only the minimum needed to get a bootable image in qemu-system.

Not explored in this article: using newuidmap/newgidmap with appropriate /etc/subuid (see here), though note one-off setup is needed to allow your user to set sufficient UIDs.

My preferred solution

Assuming you have debootstrap and fakeroot installed (sudo pacman -S debootstrap fakeroot will suffice on Arch), and to support transparent emulation of binaries for other architectures you also have user-mode QEMU installed and set to execute via binfmt_misc (sudo pacman -S qemu-user-static qemu-user-static-binfmt on Arch) we proceed to:

• Do the first stage debootstrap under fakeroot on the host, saving the state (the uid/gid and permissions set after operations like chown/chmod) to a file, and including fakeroot in the list of packages to install for the target.
• Extract the contents of the fakeroot and libfakeroot .debs into the directory tree created by debootstrap directory (as we need to be able to use it as a pre-requisite of initiating the second-stage debootstrap which extracts and installs all the packages).
• Make use of user namespaces to chroot into the debootstrapped sysroot without needing root permissions. Then give the illusion of permissions to set arbitrary uid/gid and other permissions on files via fakeroot (loading the environment saved earlier).
• Run the second stage debootstrap.

Translated into shell commands (and later a script), you can do this by:

SYSROOT_DIR=sysroot-deb-riscv64-sid
TMP_FAKEROOT_ENV=$(mktemp)
fakeroot -s "$TMP_FAKEROOT_ENV" debootstrap \
  --variant=minbase \
  --include=fakeroot,symlinks \
  --arch=riscv64 --foreign \
  sid \
  "$SYSROOT_DIR"
mv "$TMP_FAKEROOT_ENV" "$SYSROOT_DIR/.fakeroot.env"
fakeroot -i "$SYSROOT_DIR/.fakeroot.env" -s "$SYSROOT_DIR/.fakeroot.env" sh <<EOF
ar p "$SYSROOT_DIR"/var/cache/apt/archives/libfakeroot_*.deb 'data.tar.xz' | tar xv -J -C "$SYSROOT_DIR"
ar p "$SYSROOT_DIR"/var/cache/apt/archives/fakeroot_*.deb 'data.tar.xz' | tar xv -J -C "$SYSROOT_DIR"
ln -s fakeroot-sysv "$SYSROOT_DIR/usr/bin/fakeroot"
EOF
cat <<'EOF' > "$SYSROOT_DIR/_enter"
#!/bin/sh
export PATH=/usr/sbin:$PATH
FAKEROOTDONTTRYCHOWN=1 unshare -fpr --mount-proc -R "$(dirname -- "$0")" \
  fakeroot -i .fakeroot.env -s .fakeroot.env "$@"
EOF
chmod +x "$SYSROOT_DIR/_enter"
"$SYSROOT_DIR/_enter" debootstrap/debootstrap --second-stage

You'll note this creates a helper _enter within the root of the rootfs for chrooting into it and executing fakeroot with appropriate arguments.

If you want to use this rootfs as a sysroot for cross-compiling, you'll need to convert any absolute symlinks to relative symlinks so that they resolve properly when being accessed outside of a chroot. We use the symlinks utility installed within the target filesystem for this:

"$SYSROOT_DIR/_enter" symlinks -cr .

I've written a slightly more robust and configurable encapsulation of the above logic in the form of rootless-debootstrap-wrapper which I would recommend using/adapting in preference to the above. Further code examples in the rest of this post use the rootless-debootstrap-wrapper script for convenience.

Further discussion

Depending on how you look at it, fakeroot is either a horrendous hack or a clever use of LD_PRELOAD developed at a time where there weren't lots of options for syscall interposition. As there's been so much development in that area I'd hope there are other alternatives by now, but I didn't see something that's quite so easy to use, well tested for this use case, widely packaged, and up to date.

I've avoided using fakechroot both because I couldn't get it to work reliably in the cross-architecture bootstrap scenario, and also because thinking through how it logically should work in that scenario is fairly complex. Given we're able to use user namespaces to chroot, let's save ourselves the hassle and do that. Except there was a slight hiccup in that chown was failing (running under fakeroot) when chrooted in this way. Thankfully the folks in the buildroot project had run into the same issue and their patch alerted me to the undocumented FAKEROOTDONTTRYCHOWN environment variable. As written up in that commit message, the issue is that under a user namespace with limited uid/gid mappings (in my case, just one), chown returns EINVAL which isn't masked by fakeroot unless this environment variable is set.

There has of course been previous work on rootless debootstrap, notably Johannes Schauer's blog post that takes a slightly different route (by my understanding, including communication between LD_PRELOADed fakeroot on the target and a faked running on the host). A variant of this approach is used in mmdebstrap from the same author.

Limitations

• See the warning near the top of this article about correctness issues I've encountered in some cases.
• As the file permissions info stored in fakeroot.env is keyed by the inode, you may lose important permissions information if you copy the rootfs. You should instead tar it under fakeroot, and if extracting in an unprivileged environment again then untar it under fakeroot, creating a new fakeroot.env.
• The use of unshare requires that unprivileged user namespace support is enabled. I believe this is the case in all common distributions by now, but please check your distro's guidance if not.

Litmus test across many architectures

Just to demonstrate how this working, here is how you can debootstrap all architectures supported by Debian + QEMU (except for mips, where I had issues with qemu) then run a trivial test - compiling and running a hello world:

#!/bin/sh

error() {
  printf "!!!!!!!!!! Error: %s !!!!!!!!!!\n" "$*" >&2
  exit 1
}

# TODO: mips skipped due to QEMU issues.
ARCHES="amd64 arm64 armel armhf i386 ppc64el riscv64 s390x"
mkdir -p "$HOME/debcache"

for arch in $ARCHES; do
  rootless-debootstrap-wrapper \
    --arch=$arch \
    --suite=sid \
    --cache-dir="$HOME/debcache" \
    --target-dir=debootstrap-all-test-$arch \
    --include=build-essential || error "Debootstrap failed for arch $arch"
done

for arch in $ARCHES; do
  rootfs_dir="./debootstrap-all-test-$arch"
  cat <<EOF > "$rootfs_dir/hello.c"
#include <stdio.h>
#include <sys/utsname.h>

int main() {
  struct utsname buffer;
  if (uname(&buffer) != 0) {
      perror("uname");
      return 1;
    }
  printf("Hello from %s\n", buffer.machine);
  return 0;
}
EOF
  ./debootstrap-all-test-$arch/_enter sh -c "gcc hello.c && ./a.out"
done

Executing the above script eventually gives you:

Hello from x86_64
Hello from aarch64
Hello from armv7l
Hello from armv7l
Hello from x86_64
Hello from ppc64le
Hello from riscv64
Hello from s390x

(The repeated "armv7l" is because armel and armhf differ in ABI rather than the architecture as returned by uname).

Making a RISC-V image bootable in QEMU

Here is how to use the tool to build a bootable RISC-V image. First build the rootfs:

TGT=riscv-sid-for-qemu
rootless-debootstrap-wrapper \
  --arch=riscv64 \
  --suite=sid \
  --cache-dir="$HOME/debcache" \
  --target-dir=$TGT \
  --include=linux-image-riscv64,zstd,default-dbus-system-bus || error "Debootstrap failed"
cat - <<EOF > $TGT/etc/resolv.conf
nameserver 1.1.1.1
EOF
"$TGT/_enter" sh -e <<EOF
ln -s /dev/null /etc/udev/rules.d/80-net-setup-link.rules # disable persistent network names
cat - <<INNER_EOF > /etc/systemd/network/10-eth0.network
[Match]
Name=eth0

[Network]
DHCP=yes
INNER_EOF
systemctl enable systemd-networkd
echo root:root | chpasswd
ln -sf /dev/null /etc/systemd/system/serial-getty@hvc0.service
EOF

Then produce an ext4 partition and extract the kernel and initrd:

fakeroot -i riscv-sid-for-qemu/.fakeroot.env sh <<EOF
ln -L riscv-sid-for-qemu/vmlinuz kernel
ln -L riscv-sid-for-qemu/initrd.img initrd
fallocate -l 30GiB rootfs.img
mkfs.ext4 -d riscv-sid-for-qemu rootfs.img
EOF

And boot it in qemu:

qemu-system-riscv64 \
  -machine virt \
  -cpu rv64 \
  -smp 4 \
  -m 8G \
  -device virtio-blk-device,drive=hd \
  -drive file=rootfs.img,if=none,id=hd,format=raw \
  -device virtio-net-device,netdev=net \
  -netdev user,id=net,hostfwd=tcp:127.0.0.1:10222-:22 \
  -bios /usr/share/qemu/opensbi-riscv64-generic-fw_dynamic.bin \
  -kernel kernel \
  -initrd initrd \
  -object rng-random,filename=/dev/urandom,id=rng \
  -device virtio-rng-device,rng=rng \
  -nographic \
  -append "rw noquiet root=/dev/vda console=ttyS0"

You can then log in with user root and password root. We haven't installed sshd so far, but the above command line sets up forwarding from port 10222 on the local interface to port 22 on the guest in anticipation of that.

• 2024-12-03: Initial publication date.

Update on what happened in WebKit in the week from November 23 to December 2.

Cross-Port 🐱

Web Platform 🌐

JavaScriptCore 🐟

Graphics 🖼️

Releases 📦️

Infrastructure 🏗️

Interop and Hard Problems

Let's talk about priorities, technical debt and hard problems in the Web Platform...

In many ways, browser engine projects are not that different from most other software projects. The "stewards" still have teams with managers and specializations and budgets and people out on leave, and so on. They have to prioritize and plan. And just like every other project I've ever seen, they face the same kinds of pressures and problems: There are never enough resources for everything, there are always new asks, they always accumulate tech debt, and sometimes there are really hard problems.

What is perhaps special about them is that they are trying to be more than just an isolated program: They're trying to contribute to a standard, interoperable platform. The catch, for us, is that we only reap the benefit when something makes it all the way through all of the team's independent priority gauntlets, get shipped widely, and so on.

This can be kind of painful to experience.

For example, consider the <details> element. It's literally the simplest possible interactive element. Here's how we got it:

• In June 2011, Chrome shipped <details>.
• A year later, in July 2012, Safari shipped it.
• Another year later in July 2013, Opera shipped it.
• Still another three years later, in September 2016, Firefox shipped it
• Microsoft never implemented it - we finally got the last implementation when Edge moved to Chromium in 2020.

If you're counting, that's nine years it took to reach shipping in all browsers. The newly defined "Baseline Widely Available" which indicates roughly when something should have reached as close to 100% market-share/deployment as possible would take another three... So, more or less, that happened last year.

And that's just the initial and appealing part. Then there are, of course, bugs discovered, new tests added, and ultimately feature improvements and iterations and so on. Even currently there are newly failing tests that make support for <details> ragged as we've tried to improve things like find-in-page and and add new concepts like invokers.

As time goes by, we're accumulating squares in the feature grid and new "gaps" in it faster than we're filling them. We're accumulating tech debt.

Enter Interop

Interop was originally intended as a way to pay down, that debt: Let's pick some things to prioritize together and turn all of the little red failure squares green. But prioritizing is tricky.

We'll get very roughly around 100 submissions of what we should focus on every year. But Interop is merely allowing browser makers to agree on how to focus and prioritize on some of the same things. The resources themselves are still finite. That means that prioritizing some things inevitably means not prioritizing something else.

And, there are a lot of competing pressures about what to prioritize, and why.

For example: It is super effective for developers if we can focus initial developments together. Imagine if we could have delivered <details> across the board and very high quality in 2011, or 2012.

Focusing together on a few new features has other added benefits too. People are more excited to work on it for one. We also get everyone talking about the same things at the same time, that's helpful - nobody misses the big event. It means use will grow faster, etc. It gives us something a like ECMA annual editions. So, it's a little unsurprising that last year, Interop included areas like CSS nesting, popover, relative color syntax, declarative shadow DOM.

However - at the other end of the spectrum, there are lots of things which are already very ragged. These things are damned hard to prioritize. They're all over the map. They are of obviously different, and debatable kinds of value, to sometimes very different communities. They can also incur different costs on different engines, and so on.

All of this conspires together to create some perennially hard problems. They continue to be needs, sometimes for exceedingly long times.

Perennially Hard Problems

This year, I'm making the case that we need to find a way to prioritize those perennially hard problems which, for whatever reason, we can never seem to prioritize. Perhaps every 5, 7 or 10 years we we should focus on these kinds of projects.

If you've been reading my blog or listening to our podcast, then you're already aware that MathML and SVG are probably the biggest examples of this kind of problem. Both are among the oldest web specifications, having their first versions published about the same time as HTML 4.0 and CSS 2. They were specially integrated with the HTML parser, and are integrated into the HTML Living Standard (MathML, SVG).

Yet both are historically dramatically under-funded and much of the actual work on them have been funded by volunteers and non-steward organizations! 26 years later we're still struggling to find the will to cross some important last miles.

Thus, every year, we have submissions about both for Interop.

The 2024 State of HTML survey found that <svg> was the top content pain point cited by developers, with almost double the pain attributed to “browser support”. <svg> - that is the literal <svg> element, not including the other ways SVGs can be used - is used on over 55% of HTML pages in the HTTP archive data. Only 27 of HTML's roughly 130 elements are more popular. SVG is also used heavily in embedded applications powered by Web engines.

A lot of math content is in more specific sites like arXiv and Wikipedia, which each have millions and millions of equations, or in online education or books. The HttpArchive crawl isn't the best way to measure that since it is focused mainly on public home pages where there's not likely to be a lot of math. However, even in the crawl, we still see thousands of pages do load 2 of the most popular JavaScript libraries which are bridging the gaps instead of rendering native math. This hurts performance and is unique - we don't require JavaScript to render text. We also know that numerous document editing tools like Adobe Indesign and Microsoft Word support MathML. Those are complex applications which require a lot of script already, and lacking good support means that they have to load even more.

Igalia has contributed implementations and improvements with funding from others and ourselves. Every year we have invested a bit ourselves to keep things moving forward. But it moves slowly this way. What we really need are some concerted efforts to push us across those last miles. We'd go a lot farther, a lot faster, together.

If you support the idea of some focus and push on these, please let us know - let vendors know. It might help.

Of course, it might not too. Historically, it's been difficult. What we know works is for someone outside of vendors to do the work - or fund it. Igalia will keep plugging away, but without external funding our own investments only go so far. If your organization would benefit from these, consider financially sponsoring some work. Alternatively, you can also help fund work on MathML directly.

Update on what happened in WebKit in the week from November 15 to November 22.

Cross-Port 🐱

Multimedia 🎥

WPE WebKit 📟

WPE Platform API 🧩

MiniBrowser --use-wpe-platform-api --config-file=config.ini

WPE Android ↗ 🤖

Infrastructure 🏗️

flatpak --user install \
  https://nightly.gnome.org/repo/appstream/org.gnome.Epiphany.Canary.flatpakref

XDC 2024 in Montreal was another fantastic gathering for the Linux Graphics community. It was again a great time to immerse in the world of graphics development, engage in stimulating conversations, and learn from inspiring developers.

Many Igalia colleagues and I participated in the conference again, delivering multiple talks about our work on the Linux Graphics stack and also organizing the Display/KMS meeting. This blog post is a detailed report on the Display/KMS meeting held during this XDC edition.

Short on Time?

1. Catch the lightning talk summarizing the meeting here (you can even speed up 2x):

1. For a quick written summary, scroll down to the TL;DR section.

TL;DR

This meeting took 3 hours and tackled a variety of topics related to DRM/KMS (Linux/DRM Kernel Modesetting):

• Sharing Drivers Between V4L2 and KMS: Brainstorming solutions for using a single driver for devices used in both camera capture and display pipelines.
• Real-Time Scheduling: Addressing issues with non-blocking page flips encountering sigkills under real-time scheduling.
• HDR/Color Management: Agreement on merging the current proposal, with NVIDIA implementing its special cases on VKMS and adding missing parts on top of Harry Wentland’s (AMD) changes.
• Display Mux: Collaborative design discussions focusing on compositor control and cross-sync considerations.
• Better Commit Failure Feedback: Exploring ways to equip compositors with more detailed information for failure analysis.

Bringing together Linux display developers in the XDC 2024

While I didn’t present a talk this year, I co-organized a Display/KMS meeting (with Rodrigo Siqueira of AMD) to build upon the momentum from the 2024 Linux Display Next hackfest. The meeting was attended by around 30 people in person and 4 remote participants.

Speakers: Melissa Wen (Igalia) and Rodrigo Siqueira (AMD)

Link: https://indico.freedesktop.org/event/6/contributions/383/

Topics: Similar to the hackfest, the meeting agenda was built over the first two days of the conference and mixed talks follow-up with new ideas and ongoing community efforts.

The final agenda covered five topics in the scheduled order:

1. How to share drivers between V4L2 and DRM for bridge-like components (new topic);
2. Real-time Scheduling (problems encountered after the Display Next hackfest);
3. HDR/Color Management (ofc);
4. Display Mux (from Display hackfest and XDC 2024 talk, bringing AMD and NVIDIA together);
5. (Better) Commit Failure Feedback (continuing the last minute topic of the Display Next hackfest).

Unpacking the Topics

Similar to the hackfest, the meeting agenda evolved over the conference. During the 3 hours of meeting, I coordinated the room and discussion rounds, and Rodrigo Siqueira took notes and also contacted key developers to provide a detailed report of the many topics discussed.

From his notes, let’s dive into the key discussions!

How to share drivers between V4L2 and KMS for bridge-like components.

Led by Laurent Pinchart, we delved into the challenge of creating a unified driver for hardware devices (like scalers) that are used in both camera capture pipelines and display pipelines.

• Problem Statement: How can we design a single kernel driver to handle devices that serve dual purposes in both V4L2 and DRM subsystems?
• Potential Solutions:
  1. Multiple Compatible Strings: We could assign different compatible strings to the device tree node based on its usage in either the camera or display pipeline. However, this approach might raise concerns from device tree maintainers as it could be seen as a layer violation.
  2. Separate Abstractions: A single driver could expose the device to both DRM and V4L2 through separate abstractions: drm-bridge for DRM and V4L2 subdev for video. While simple, this approach requires maintaining two different abstractions for the same underlying device.
  3. Unified Kernel Abstraction: We could create a new, unified kernel abstraction that combines the best aspects of drm-bridge and V4L2 subdev. This approach offers a more elegant solution but requires significant design effort and potential migration challenges for existing hardware.

Real-Time Scheduling Challenges

We have discussed real-time scheduling during this year Linux Display Next hackfest and, during the XDC 2024, Jonas Adahl brought up issues uncovered while progressing on this front.

• Context: Non-blocking page-flips can, on rare occasions, take a long time and, for that reason, get a sigkill if the thread doing the atomic commit is a real-time schedule.
• Action items:
  • Explore alternative backtraces during the busy wait (e.g., ftrace).
  • Investigate the maximum thread time in busy wait to reproduce issues faced by compositors. Tools like RTKit (mutter) can be used for better control (Michel Dänzer can help with this setup).

HDR/Color Management

This is a well-known topic with ongoing effort on all layers of the Linux Display stack and has been discussed online and in-person in conferences and meetings over the last years.

Here’s a breakdown of the key points raised at this meeting:

• Talk: Color operations for Linux color pipeline on AMD devices: In the previous day, Alex Hung (AMD) presented the implementation of this API on AMD display driver.
• NVIDIA Integration: While they agree with the overall proposal, NVIDIA needs to add some missing parts. Importantly, they will implement these on top of Harry Wentland’s (AMD) proposal. Their specific requirements will be implemented on VKMS (Virtual Kernel Mode Setting driver) for further discussion. This VKMS implementation can benefit compositor developers by providing insights into NVIDIA’s specific needs.
• Other vendors: There is a version of the KMS API applied on Intel color pipeline. Apart from that, other vendors appear to be comfortable with the current proposal but lacks the bandwidth to implement it right now.
• Upstream Patches: The relevant upstream patches were can be found here. [As humorously notes, this series is eagerly awaiting your “Acked-by” (approval)]
• Compositor Side: The compositor developers have also made significant progress.
  • KDE has already implemented and validated the API through an experimental implementation in Kwin.
  • Gamescope currently uses a driver-specific implementation but has a draft that utilizes the generic version. However, some work is still required to fully transition away from the driver-specific approach. AP: work on porting gamescope to KMS generic API
  • Weston has also begun exploring implementation, and we might see something from them by the end of the year.
• Kernel and Testing: The kernel API proposal is well-refined and meets the DRM subsystem requirements. Thanks to Harry Wentland effort, we already have the API attached to two hardware vendors and IGT tests, and, thanks to Xaver Hugl, a compositor implementation in place.

Finally, there was a strong sense of agreement that the current proposal for HDR/Color Management is ready to be merged. In simpler terms, everything seems to be working well on the technical side - all signs point to merging and “shipping” the DRM/KMS plane color management API!

Display Mux

During the meeting, Daniel Dadap led a brainstorming session on the design of the display mux switching sequence, in which the compositor would arm the switch via sysfs, then send a modeset to the outgoing driver, followed by a modeset to the incoming driver.

• Context:
  • During this year Linux Display Next hackfest, Mario Limonciello (AMD) introduced the topic and led a discussion on Display Mux.
  • Daniel Dadap (NVIDIA) retook this discussion with the XDC 2024 talk: Dynamic Switching of Display Muxes on Hybrid GPU Systems.
• Key Considerations:
  • HPD Handling: There was a general consensus that disabling HPD can be part of the sequence for internal panels and we don’t need to focus on it here.
  • Cross-Sync: Ensuring synchronization between the compositor and the drivers is crucial. The compositor should act as the “drm-master” to coordinate the entire sequence, but how can this be ensured?
  • Future-Proofing: The design should not assume the presence of a mux. In future scenarios, direct sharing over DP might be possible.
• Action points:
  • Sharing DP AUX: Explore the idea of sharing DP AUX and its implications.
  • Backlight: The backlight definition represents a problem in the mux switch context, so we should explore some of the current specs available for that.

Towards Better Commit Failure Feedback

In the last part of the meeting, Xaver Hugl asked for better commit failure feedback.

• Problem description: Compositors currently face challenges in collecting detailed information from the kernel about commit failures. This lack of granular data hinders their ability to understand and address the root causes of these failures.

To address this issue, we discussed several potential improvements:

• Direct Kernel Log Access: One idea is to directly load relevant kernel logs into the compositor. This would provide more detailed information about the failure and potentially aid in debugging.
• Finer-Grained Failure Reporting: We also explored the possibility of separating atomic failures into more specific categories. Not all failures are critical, and understanding the nature of the failure can help compositors take appropriate action.
• Enhanced Logging: Currently, the dmesg log doesn’t provide enough information for user-space validation. Raising the log level to capture more detailed information during failures could be a viable solution.

By implementing these improvements, we aim to equip compositors with the necessary tools to better understand and resolve commit failures, leading to a more robust and stable display system.

A Big Thank You!

Huge thanks to Rodrigo Siqueira for these detailed meeting notes. Also, Laurent Pinchart, Jonas Adahl, Daniel Dadap, Xaver Hugl, and Harry Wentland for bringing up interesting topics and leading discussions. Finally, thanks to all the participants who enriched the discussions with their experience, ideas, and inputs, especially Alex Goins, Antonino Maniscalco, Austin Shafer, Daniel Stone, Demi Obenour, Jessica Zhang, Joan Torres, Leo Li, Liviu Dudau, Mario Limonciello, Michel Dänzer, Rob Clark, Simon Ser and Teddy Li.

This collaborative effort will undoubtedly contribute to the continued development of the Linux display stack.

Stay tuned for future updates!

Update on what happened in WebKit in the week from November 8 to November 15.

Cross-Port 🐱

Infrastructure 🏗️

As many of you already know, Igalia took over the maintenance of the Servo project in January 2023. We’ve been working hard on bringing the project back to life again, and this blog post is a summary of our achievements so far.

Some history first #

You can skip this this section if you already know about the Servo project.

Servo is an experimental browser engine created by Mozilla in 2012. From the very beginning, it was developed alongside the Rust language, like a showcase for the new language that Mozilla was developing. Servo has always aimed to be a performant and secure web rendering engine, as those are also main characteristics of the Rust language.

Mozilla was the main force behind Servo’s development for many years, with some other companies like Samsung collaborating too. Some of Servo’s components, like Stylo and WebRender, were adopted and used in Firefox releases by 2017, and continue to be used there today.

In 2020, Mozilla laid off the whole Servo team, and the project moved to the Linux Foundation. Despite some initial interest in the project, by the end of 2020 there was barely any active work on the project, and 2021 and 2022 weren’t any better. At that point, many considered the Servo project to be abandoned.

2023: Igalia takes over maintenance of Servo #

Things changed in 2023, when Igalia got external funding to work on Servo and get the project moving again. We have previous experience working on Servo during the Mozilla years, and we also have a wide experience working on other web rendering engines.

To explore new markets and grow a stable community, the Servo project joined Linux Foundation Europe in September 2023, and is now one of the most active projects there. LF Europe is an umbrella organization that hosts the Servo project, and provides us with opportunities to showcase Servo at several events.

Over the last two years, Igalia has had a team of around five engineers working full-time on the Servo project. We’re taking care of the project maintenance, communication, community governance, and a large portion of development. We have also been looking for new partners and organizations that may be interested in the Servo project, and can devote resources or money towards moving it forward.

Achievements #

Two years is not a lot of time for a project like Servo, and we’re very proud of what we’ve achieved in this period. Some highlights, including work from Igalia and the wider Servo community:

• Maintenance: General project maintenance, tooling, documentation, community, and governance work. Lots of work has been put in upgrading Servo dependencies, specially the big ones (SpiderMonkey, Stylo and WebRender). There have been improvements in Servo’s CI and tooling. We now have a Servo book, the Servo community has been growing, and the Technical Steering Committee (TSC) is running periodic meetings every month.
• Communications: The project is alive again and we want the world to know it, so we’ve been doing monthly blog posts, weekly updates on social media, plus conference talks and booths at several events. The project is more popular than ever, and our GitHub stars haven’t stopped growing.
• Layout engine: Servo had two layout engines: its original one, and a newer one started around 2020, which follows specs more closely but was in very early stages. After some analysis, we decided to go with the new layout engine and start to implement features in it like floats, tables, flexbox, fonts, right-to-left, etc. We now pass 1.4 million subtests (1,401,889 at the time of publishing this blog post) in the Web Platform Tests. And of the tests we run today, our overall pass rate has gone from 40.8% in April 2023 to 62.0% (+21.2). 📈
• New platforms: Servo used to support Linux, macOS, and Windows. That’s still the case, but we’ve also added support for Android and OpenHarmony, helping us reach a wide range of mobile devices. 📱
• Embedded experiments: We’ve been working with the developers of Tauri, making Servo easier to embed and creating a first prototype of using Servo as web engine in WRY. Our community has also experimented with integrating Servo in other projects, including Blitz, Qt WebView, and Verso.
• Outreachy: Outreachy is an internship program for getting people from underrepresented groups into our industry via FOSS, and we’ve rejoined the program in 2024. Our intern in the May cohort, @eerii, brought DevTools support back to Servo.

Of course, it’s impossible to summarize all of the work that happened in so much time, with so many people working together to achieve these great results. Big thanks to everyone that has collaborated on the project! 🙏

Some numbers #

While it’s hard to list all of our achievements, we can take a look at some stats. Numbers are always tricky to draw conclusions from, but we’ve been taking a look at the number of PRs merged in Servo’s main repository since 2018, to understand how the project is faring.

• PRs: total numbers of PRs merged. We’re now doing more than we were doing in 2018-2019.
• Contributors: average number of contributors per month. We’re getting very close to the numbers of 2018-2019, it looks like a good number.
• Contributors ≥ 10: average number of contributors that have merged more than 10 PRs per month. In this case we already have bigger numbers than in 2018-2019.

As a clarification, these numbers don’t include PRs from bots (dependabot and Servo WPT Sync).

Our participation in Outreachy has also made a marked difference. During each month-long contribution period, we get a huge influx of new people contributing to the project. This year, we participated in both the May and December cohorts, and the contribution periods are very visible in our March and October 2024 stats:

Anyway overall, we think these numbers ratify that the project is back to life, and the community is growing and engaging with the project. We’re very happy about them.

Donations #

Early this year we set up the Servo Open Collective and GitHub Sponsors, where many people and organizations have since been donating to the project. We decide how to spend this money transparently in the TSC, and so far we’ve used it to cover the project’s infrastructure costs, like self-hosted runners to speed up CI times.

We’re very grateful to everyone donating money to the project, so far adding up to over $24,500 from more than 500 donors. Thank you! 🙏

About the future #

Servo has a lot of potential. Several things make it a very special project:

• Independent: Servo is managed under Linux Foundation Europe with an open governance model, which we believe is very important for the open web ecosystem as a whole.
• Performant: Servo is the only web rendering engine that uses parallel layout for web content. Though Servo is not yet faster than other web engines that are already production-ready, we’re exploring new ways to render web content that take advantage of modern CPUs with many cores.
• Secure: Servo is written in Rust, which prevents many security vulnerabilities by design, such as memory safety bugs. Other kinds of unsoundness, such as concurrency bugs, are also easier to manage in Rust.

Of course, the project has some challenges too:

• Experimental: Servo is still in an experimental phase and is not a production-ready product. We still lack several features that are important for web content.
• Competition: The dominant web rendering engines have huge teams behind them, working on making them better, faster, and more complete. Catching up with them is a really complex task.
• Funding: This is a key topic for any open source project, and Servo is no different in this regard. We need organizations from public and private sectors to join efforts with us, and grow a healthy ecosystem around the project.

To finish on a positive note, we also have some key opportunities:

• Single web apps: Servo may excel at rendering specific web apps in embedded scenarios, where the HTML and CSS features are known in advance.
• UI frameworks: UI frameworks in the Rust ecosystem could start using Servo as web engine to render their contents.
• Web engine: Servo could become the default web engine for any Rust application.
• Web browser: In the future, we could grow into being able to develop a full-featured web browser.

The future of Servo, as with many other open source projects, is still uncertain. We’ll see how things go in the coming years, but we would love to see that the Servo project can keep growing.

Servo is a huge project. To keep it alive and making progress, we need continuous funding on a bigger scale than crowdfunding can generally accomplish. If you’re interested in contributing to the project or sponsoring the development of specific functionality, please contact us at join@servo.org or igalia.com/contact.

Let’s hope we can walk this path together and keep working on Servo for many years ahead. 🤞

PS: Special thanks to my colleague Delan Azabani for proofreading and copyediting this blog post. 🙏

In October, many colleagues from Igalia participated in a TC39 meeting organized in Tokyo, Japan by Sony Interactive Entertainment to discuss proposed features for the JavaScript standard alongside delegates from various other organizations.

Let's delve together into some of the most exciting updates!

You can also read the full agenda and the meeting minutes on GitHub.

Day 1 #

Import attributes to Stage 4 #

Import attributes, (alongside JSON modules) reached Stage 4. Import attributes allow customizing how modules are imported. For example, in all JavaScript environments you'll be able to natively import JSON files using

import myData from "./data" with { type: "json" };

The proposals reached finally reached Stage 4, after a bumpy path - including being regressed from Stage 3 to Stage 2 in 2023 and needing to change their syntax.

The proposals are already supported in Chrome, Safari, and all the server-side runtimes, with Firefox soon to follow!

Iterator Helpers to stage 4! #

Although we didn't work directly on the Iterator Helpers proposal, we've been eagerly anticipating its completion. It elevates Javascript's standard library iterators up to a level of developer convenience that's comparable to Python's itertools module or the iterators in Rust. Here's a code snippet:

const result = Iterator.from(myArray)
	.filter(myPredicate)
	.take(50)
	.map(myTransformFunc)
	.reduce(mySummationFunc);

It's often convenient to think of processing code such as the above in terms of map and filter operations. But often you'd have to iterate through the array multiple times if you wrote it that way using Array's map and filter methods, which is inefficient. Conversely, if you wrote it with a for-of loop, you'd be using break, continue, and possibly state-tracking variables, which is harder to reason about. Iterator helpers give you the best of both worlds.

Normative changes to ECMA-402 #

ECMA-402 is the Internationalization API specification, the companion standard to JavaScript's ECMA-262. Our colleagues Ben Allen and Ujjwal Sharma are on the editorial board of ECMA-402 and their responsibilities often include proposing small changes. This round, we received consensus for PRs that:

• Fix a bug that caused date and time values to sometimes be rendered in the wrong numbering system for some locales.

• Correctly format currency values when rendered in scientific/engineering notations.

• Give an explicit ordering for the plural categories returned by Intl.PluralNames.resolvedOptions(). This allows for easier testing of the correctness of this method, and makes it easier for developers to discover what plural categories exist in which languages.

• Allow use of non-ISO 4217 data in CurrencyDigits AO This is a small change, but one that makes the ECMA-402 specification more closely match both extant localization needs and also web reality. Previously the specification mandated the use of a standard for determining the number of "minor units" displayed when formatting currency values -- think here the number of digits used to display cents when formatting values such as 1.25 USD. The previously mandated data source is useful for some contexts, but not others. This PR allows implementors to use whichever source of data on currency minor units is best suited for that engine -- something that implementators had already been doing.

Road to the source map standard #

TG4, a task group created one year ago within TC39, has been diligently working to standardize and enhance the source maps functionality, with the goal of ensuring a good and consistent developer experience across multiple platforms.

Thanks also to the efforts by our colleagues Nicolò Ribaudo and Asumu Takikawa, TC39 approved the first draft of the new specification (https://tc39.es/source-map/2024/), which can now advance through the Ecma publishing process to become an official standard.

JSSugar / JS0 #

JavaScript keeps evolving and adding many new features over time: this can significantly help JavaScript developers, but it comes with its own problems. Every new feature is something that browsers need to implement and optimize, and which might cause bugs and slowdowns.

Some committee members (mostly representing browsers), initiated a discussion about whether there are possible alternative approaches to evolving the language. The primary example that was presented as a potential path forward is to leverage existing deveoper tools more extensively: many developers already transpile their code, so what if we made it "official"?

We could split the language in two parts, that together compose the ECMAScript standard:

• one (JS0) would be the current language that is implemented in browsers, which is what we call today "JavaScript"
• the other (JSSugar), only implemented in tools, similar to how today we use JSX or type annotations.

The discussion is in its very early stages, and the direction it will take is uncertain. It could evolve in many ways and it's possible that TC39 could ultimately decide that actually, the way things work today is fine. There are many voices pushing in opposite directions, and everything is still on the table. Stay tuned for more developments!

Day 2 #

Decimal #

Our colleague Jesse Alama presented Decimal, showing the latest iterations on the design and data model for decimal in response to feedback in and between plenaries. The most recent version proposed an "auto-canonicalize" variant of IEEE 754 Decimal128, in which the notion of precision (or "quantum", to use the official term) of Decimal128 values would not be exposed. We received some feedback there, so decimal stays at stage 1. But stay tuned! We're going back to the drawing board and will keep iterating.

Promise.try to stage 4! #

Promise.try() is a new API that allows you to wrap a function--whether async or not--allowing it to be treated it as though it is always asynchronous. It replaces cumbersome workarounds like new Promise((resolve) => resolve(myFunction())). We didn't work on this proposal, but are nonetheless looking forward to using it!

Restricting support for sub-classing built-ins #

Sometimes TC39 makes some mistakes, designing features one way only to later realise that it should have been done differently.

One example of this is the level of support that JavaScript has for defining subclasses of built-in classes, such as

class MyUint8Array extends Uint8Array {}

const myArr = new MyUint8Array([1, 2, 3]);
myArr instanceof MyUint8Array; // true!

// also true, even if we didn't redefine .map to return a MyUint8Array
myArr.map(x => x) instanceof Uint8Array;

It often leads to vulnerabilities in JavaScript engines, and leads to many hard-to-optimize patterns that make everybody pay the cost of this language feature, even for those who don't rely on it.

After features have been shipped for years it's usually too late for TC39 to change them: our highest priority is to "not break the web", meaning that once developers start relying on something it's going to stay there forever.

The discussion focused on whether or not the use cases appeared real, conclusion was that they are for Array and Promise, but we can move forward with the conservative step of removing making only prototype methods of typed arays, Array Buffer, and Shared Array Buffer not look at their this to dynamically construct the corresponding class. The commitee will investigate further, the use cases for RegExp.

Day 3 #

Measure #

We're very excited to announce that our colleague Ben Allen presented the Measure proposal, and it has reached Stage 1. Measure proposes an API for handling general-purpose unit conversion between measurement scales and measurement systems. Measure was originally part of the localization-related Smart Units proposal, but was promoted into its own proposal in response to demand for this tool in a wide range of contexts.

Smart units #

Smart Units is a proposal to include an API for localizing measured quantities to locale-appropriate scales and measuring systems. This can be complicated by how the appropriate measuring scale for some usages varies based on the type of thing being measured; for example, many locales use a different measurement scale for the heights of people than they do for other length measurements.

Although much of the action involved in developing this proposal has shifted to the related Measure proposal, in this session we considered what units and usages should be supported.

Other Updates #

Our colleague Philip Chimento presented a short update on the progress of getting Temporal into browsers. Here's the representing the test262 conformance as of last plenary!

Good news from the AsyncContext champions, including our colleague Andreu Botella: the proposal is almost ready for Stage 2.7! All the semantics relevant to ECMAScript have been finalized, and it's now just waiting on finalizing the integration semantics with the rest of the web APIs.