What happened was, I was hanging out in an online chatter channel when a little birdy named Bruce chirped about OpenAI’s Whisper and how he was using it to transcribe audio.  And I thought, Hey, I have audio that needs to be transcribed.  Brucie Bird also mentioned it would output text, SRT, and WebVTT formats, and I thought, Hey, I have videos I’ll need to upload with transcription to YouTube!  And then he said you could run it from the command line, and I thought, Hey, I have a command line!

So off I went to install it and try it out, and immediately ran smack into some hurdles I thought I’d document here in case someone else has similar problems.  All of this took place on my M2 MacBook Pro, though I believe most of the below should be relevant to anyone trying to do this at the command line.

The first thing I did was what the GitHub repository’s README recommended, which is:

$ pip install -U openai-whisper

That failed because I didn’t have pip installed.  Okay, fair enough.  I figured out how to install that, setting up an alias of python for python3 along the way, and then tried again.  This time, the install started and then bombed out:

Collecting openai-whisper
  Using cached openai-whisper-20230314.tar.gz (792 kB)
  Installing build dependencies ...  done
  Getting requirements to build wheel ...  done
  Preparing metadata (pyproject.toml) ...  done
Collecting numba
  Using cached numba-0.56.4.tar.gz (2.4 MB)
  Preparing metadata (setup.py) ...  error
  error: subprocess-exited-with-error

…followed by some stack trace stuff, none of which was really useful until ten or so lines down, where I found:

RuntimeError: Cannot install on Python version 3.11.2; only versions >=3.7,<3.11 are supported.

In other words, the version of Python I have installed is too modern to run AI.  What a world.

I DuckDucked around a bit and hit upon pyenv, which is I guess a way of installing and running older versions of Python without having to overwrite whatever version(s) you already have.  I’ll skip over the error part of my trial-and-error process and give you the commands that made it all work:

$ brew install pyenv

$ pyenv install 3.10

$ PATH="~/.pyenv/shims:${PATH}"

$ pyenv local 3.10

$ pip install -U openai-whisper

That got Whisper to install.  It didn’t take very long.

At that point, I wondered what I’d have to configure to transcribe something, and the answer turned out to be precisely zilch.  Once the install was done, I dropped into the directory containing my MP4 video, and typed this:

$ whisper wpe-mse-eme-v2.mp4

Here’s what I got back.  I’ve marked the very few errors.

[00:00.000 --> 00:07.000]  In this video, we'll show you several demos showcasing multi-media capabilities in WPE WebKit,
[00:07.000 --> 00:11.000]  the official port of the WebKit engine for embedded devices.
[00:11.000 --> 00:18.000]  Each of these demos are running on the low-powered Raspberry Pi 3 seen in the lower right-hand side of the screen here.
[00:18.000 --> 00:25.000]  Infotainment systems and media players often need to consume digital rights-managed videos.
[00:25.000 --> 00:32.000]  They tell me, is Michael coming out?  Affirmative, Mike's coming out.
[00:32.000 --> 00:45.000]  Here you can see just that, smooth streaming playback using encrypted media extensions, or EME, with PlayReady 4.
[00:45.000 --> 00:52.000]  Media source extensions, or MSE, are used by many players for greater control over playback.
[00:52.000 --> 01:00.000]  YouTube TV has a whole conformance test suite for this, which WPE has been passing since 2021.
[01:00.000 --> 01:09.000]  The loan exceptions here are those tests requiring hardware support not available on the Raspberry Pi 4, but available for other platforms.
[01:09.000 --> 01:16.000]  YouTube TV has a conformance test for EME, which WPE WebKit passes with flying colors.
[01:22.000 --> 01:40.000]  Music
[01:40.000 --> 01:45.000]  Finally, perhaps most impressively, we can put all these things together.
[01:45.000 --> 01:56.000]  Here is the dash.js player using MSE, running in a page, and using Widevine DRM to decrypt and play rights-managed video with EME all fluidly.
[01:56.000 --> 02:04.000]  Music
[02:04.000 --> 02:09.000]  Remember, all of this is being played back on the same low-powered Raspberry Pi 3.
[02:27.000 --> 02:34.000]  For more about WPE WebKit, please visit WPE WebKit.com.
[02:34.000 --> 02:42.000]  For more information about EGALIA, or to find out how we can help with your embedded device needs, please visit us at EGALIA.com.  

I am, frankly, astonished.  This has no business being as accurate as it is, for all kinds of reasons.  There’s a lot of jargon and very specific terminology in there, and Whisper nailed pretty much every last bit of it, first time in, no special configuration, nothing.  I didn’t even bump up the model size from the default of small.  I felt a little like that Froyo guy in the animated Hunchback of Notre Dame meme yelling about sorcery or whatever.

True, the output isn’t absolutely perfect.  Let’s review the glitches in reverse order.  The last two errors, turning “Igalia” into “EGALIA”, seems fair enough given I didn’t specify that there would be languages other than English involved.  I routinely have to spell it for my fellow Americans, so no reason to think a codebase could do any better.

The space inserted into “WPEWebKit” (which happens throughout) is similarly understandable.  I’m impressed it understood “WebKit” at all, never mind that it was properly capitalized and not-spaced.

The place where it says Music and I marked it as an error: This is essentially an echoing countdown and then a white-noise roar from rocket engines.  There’s a “music today is just noise” joke in here somewhere, but I’m too hip to find it.

Whisper turning “lone” into “loan” doesn’t particularly faze me, given the difficulty of handling soundalike words.  Hell, just yesterday, I was scribing a conference call and mistakenly recorded “gamut” as “gamma”, and those aren’t even technically homophones.  They just sound like they are.

Rounding out the glitch tour, “Hey” got turned into “They”, which (given the audio quality of that particular part of the video) is still pretty good.

There is one other error I couldn’t mark because there’s nothing to mark, but if you scrutinize the timeline, you’ll see a gap from 02:09.000 and 02:27.000.  In there, a short clip from a movie plays, and there’s a brief dialogue between two characters in not-very-Dutch-accented English there.  It’s definitely louder and more clear than the 00:25.000 –> 00:32.000 bit, so I’m not sure why Whisper just skipped over it.  Manually transcribing that part isn’t a big deal, but it’s odd to see it perform so flawlessly on every other piece of speech and then drop this completely on the floor.

Before posting, I decided to give Whisper another go, this time on a different video:

$ whisper wpe-gamepad-support-v3.mp4

This was the result, with the one actual error marked:

[00:00.000 --> 00:13.760]  In this video, we demonstrate WPE WebKit's support for the W3C's GamePad API.
[00:13.760 --> 00:20.080]  Here we're running WPE WebKit on a Raspberry Pi 4, but any device that will run WPE WebKit
[00:20.080 --> 00:22.960]  can benefit from this support.
[00:22.960 --> 00:28.560]  The GamePad API provides a JavaScript interface that makes it possible for developers to access
[00:28.560 --> 00:35.600]  and respond to signals from GamePads and other game controllers in a simple, consistent way.
[00:35.600 --> 00:40.320]  Having connected a standard Xbox controller, we boot up the Raspberry Pi with a customized
[00:40.320 --> 00:43.040]  build route image.
[00:43.040 --> 00:48.560]  Once the device is booted, we run cog, which is a small, single window launcher made specifically
[00:48.560 --> 00:51.080]  for WPE WebKit.
[00:51.080 --> 00:57.360]  The window cog creates can be full screen, which is what we're doing here.
[00:57.360 --> 01:01.800]  The game is loaded from a website that hosts a version of the classic video arcade game
[01:01.800 --> 01:05.480]  Asteroids.
[01:05.480 --> 01:11.240]  Once the game has loaded, the Xbox controller is used to start the game and control the spaceship.
[01:11.240 --> 01:17.040]  All the GamePad inputs are handled by the JavaScript GamePad API.
[01:17.040 --> 01:22.560]  This GamePad support is now possible thanks to work done by Igalia in 2022 and is available
[01:22.560 --> 01:27.160]  to anyone who uses WPE WebKit on their embedded device.
[01:27.160 --> 01:32.000]  For more about WPE WebKit, please visit wpewebkit.com.
[01:32.000 --> 01:35.840]  For more information about Igalia, or to find out how we can help with your embedded device
[01:35.840 --> 01:39.000]  needs, please visit us at Igalia.com.  

That should have been “buildroot”.  Again, an entirely reasonable error.  I’ve made at least an order of magnitude more typos writing this post than Whisper has in transcribing these videos.  And this time, it got the spelling of Igalia correct.  I didn’t make any changes between the two runs.  It just… figured it out.

I don’t have a lot to say about this other than, wow.  Just WOW.  This is some real Clarke’s Third Law stuff right here, and the technovertigo is Marianas deep.

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

Table of Contents

1. How the tool is used

In previous posts, “Graphics Flight Recorder - unknown but handy tool to debug GPU hangs” and “Debugging Unrecoverable GPU Hangs”, I demonstrated a few tricks of how to identify the location of GPU fault.

But what’s the next step once you’ve roughly pinpointed the issue? What if the problem is only sporadically reproducible and the only way to ensure consistent results is by replaying a trace of raw GPU commands? How can you precisely determine the cause and find a proper fix?

Sometimes, you may have an inkling of what’s causing the problem, then and you can simply modify the driver’s code to see if it resolves the issue. However, there are instances where the root cause remains elusive or you only want to change a specific value without affecting the same register before and after it.

The optimal approach in these situations is to directly modify the commands sent to the GPU. The ability to arbitrarily edit the command stream was always an obvious idea and has crossed my mind numerous times (and not only mine – proprietary driver developers seem to employ similar techniques). Finally, the stars aligned: my frustration with a recent bug, the kernel’s new support for user-space-defined GPU addresses for buffer objects, the tool I wrote to replay command stream traces not so long ago, and the realization that implementing a command stream editor was not as complicated as initially thought.

The end result is a tool for Adreno GPUs (with msm kernel driver) to decompile, edit, and compile back command streams: “freedreno,turnip: Add tooling to edit command streams and use them in ‘replay’”.

The primary advantage of this command stream editing tool lies the ability to rapidly iterate over hypotheses. Another highly valuable feature (which I have plans for) would be the automatic bisection of the command stream, which would be particularly beneficial in instances where only the bug reporter has the necessary hardware to reproduce the issue at hand.

How the tool is used

# Decompile one command stream from the trace
./rddecompiler -s 0 gpu_trace.rd > generate_rd.c

# Compile the executable which would output the command stream
meson setup . build
ninja -C build

# Override the command stream with the commands from the generator
./replay gpu_trace.rd --override=0 --generator=./build/generate_rd

Reading dEQP-VK.renderpass.suballocation.formats.r5g6b5_unorm_pack16.clear.clear.rd...
gpuid: 660
Uploading iova 0x100000000 size = 0x82000
Uploading iova 0x100089000 size = 0x4000
cmdstream 0: 207 dwords
generating cmdstream './generate_rd --vastart=21441282048 --vasize=33554432 gpu_trace.rd'
Uploading iova 0x4fff00000 size = 0x1d4
override cmdstream: 117 dwords
skipped cmdstream 1: 248 dwords
skipped cmdstream 2: 223 dwords

The decompiled code isn’t pretty:

/* pkt4: GRAS_SC_SCREEN_SCISSOR[0].TL = { X = 0 | Y = 0 } */
pkt4(cs, REG_A6XX_GRAS_SC_SCREEN_SCISSOR_TL(0), (2), 0);
/* pkt4: GRAS_SC_SCREEN_SCISSOR[0].BR = { X = 32767 | Y = 32767 } */
pkt(cs, 2147450879);
/* pkt4: VFD_INDEX_OFFSET = 0 */
pkt4(cs, REG_A6XX_VFD_INDEX_OFFSET, (2), 0);
/* pkt4: VFD_INSTANCE_START_OFFSET = 0 */
pkt(cs, 0);
/* pkt4: SP_FS_OUTPUT[0].REG = { REGID = r0.x } */
pkt4(cs, REG_A6XX_SP_FS_OUTPUT_REG(0), (1), 0);
/* pkt4: SP_TP_RAS_MSAA_CNTL = { SAMPLES = MSAA_FOUR } */
pkt4(cs, REG_A6XX_SP_TP_RAS_MSAA_CNTL, (2), 2);
/* pkt4: SP_TP_DEST_MSAA_CNTL = { SAMPLES = MSAA_FOUR } */
pkt(cs, 2);
/* pkt4: GRAS_RAS_MSAA_CNTL = { SAMPLES = MSAA_FOUR } */
pkt4(cs, REG_A6XX_GRAS_RAS_MSAA_CNTL, (2), 2);

Shader assembly is editable:

const char *source = R"(
  shps #l37
  getone #l37
  cov.u32f32 r1.w, c504.z
  cov.u32f32 r2.x, c504.w
  cov.u32f32 r1.y, c504.x
  ....
  end
)";
upload_shader(&ctx, 0x100200d80, source);
emit_shader_iova(&ctx, cs, 0x100200d80);

However, not everything is currently editable, such as descriptors. Despite this limitations, the existing functionality is sufficient for the majority of cases.

LLVM 16.0.0 was just released today, and as I did for LLVM 15, I wanted to highlight some of the RISC-V specific changes and improvements. This is very much a tour of a chosen subset of additions rather than an attempt to be exhaustive. If you're interested in RISC-V, you may also want to check out my recent attempt to enumerate the commercially available RISC-V SoCs and if you want to find out what's going on in LLVM as a whole on a week-by-week basis, then I've got the perfect newsletter for you.

In case you're not familiar with LLVM's release schedule, it's worth noting that there are two major LLVM releases a year (i.e. one roughly every 6 months) and these are timed releases as opposed to being cut when a pre-agreed set of feature targets have been met. We're very fortunate to benefit from an active and growing set of contributors working on RISC-V support in LLVM projects, who are responsible for the work I describe below - thank you! I coordinate biweekly sync-up calls for RISC-V LLVM contributors, so if you're working in this area please consider dropping in.

Documentation

LLVM 16 is the first release featuring a user guide for the RISC-V target (16.0.0 version, current HEAD. This fills a long-standing gap in our documentation, whereby it was difficult to tell at a glance the expected level of support for the various RISC-V instruction set extensions (standard, vendor-specific, and experimental extensions of either type) in a given LLVM release. We've tried to keep it concise but informative, and add a brief note to describe any known limitations that end users should know about. Thanks again to Philip Reames for kicking this off, and the reviewers and contributors for ensuring it's kept up to date.

Vectorization

LLVM 16 was a big release for vectorisation. As well as a long-running strand of work making incremental improvements (e.g. better cost modelling) and fixes, scalable vectorization was enabled by default. This allows LLVM's loop vectorizer to use scalable vectors when profitable. Follow-on work enabled support for loop vectorization using fixed length vectors and disabled vectorization of epilogue loops. See the talk optimizing code for scalable vector architectures (slides) by Sander de Smalen for more information about scalable vectorization in LLVM and introduction to the RISC-V vector extension by Roger Ferrer Ibáñez for an overview of the vector extension and some of its codegen challenges.

The RISC-V vector intrinsics supported by Clang have changed (to match e.g. this and this) during the 16.x development process in a backwards incompatible way, as the RISC-V Vector Extension Intrinsics specification evolves towards a v1.0. In retrospect, it would have been better to keep the intrinsics behind an experimental flag when the vector codegen and MC layer (assembler/disassembler) support became stable, and this is something we'll be more careful of for future extensions. The good news is that thanks to Yueh-Ting Chen, headers are available that provide the old-style intrinsics mapped to the new version.

Support for new instruction set extensions

I refer to 'experimental' support many times below. See the documentation on experimental extensions within RISC-V LLVM for guidance on what that means. One point to highlight is that the extensions remain experimental until they are ratified, which is why some extensions on the list below are 'experimental' despite the fact the LLVM support needed is trivial. On to the list of newly added instruction set extensions:

• Experimental support for the Zca, Zcf, and Zcd instruction set extensions. These are all 16-bit instructions and are being defined as part of the output of the RISC-V code size reduction working group.
  • Zca is just a subset of the standard 'C' compressed instruction set extension but without floating point loads/stores.
  • Zcf is also a subset of the standard 'C' compressed instruction set extension, including just the single precision floating point loads and stores (c.flw, c.flwsp, c.fsw, c.fswsp).
  • Zcd, as you might have guessed, just includes the double precision floating point loads and stores from the standard 'C' compressed instruction set extension (c.fld, c.fldsp, c.fsd, c.fsdsp).
• Experimental assembler/disassembler support for the Zihintntl instruction set extension. This provides a small set of instructions that can be used to hint that the memory accesses of the following instruction exhibits poor temporal locality.
• Experimental assembler/disassembler support for the Zawrs instruction set extension, providing a pair of instructions meant for use in a polling loop allowing a core to enter a low-power state and wait on a store to a memory location.
• Experimental support for the Ztso extension, which for now just means setting the appropriate ELF header flag. If a core implements Ztso, it implements the Total Store Ordering memory consistency model. Future releases will provide alternate lowerings of atomics operations that take advantage of this.
• Code generation support for the Zfhmin extension (load/store, conversion, and GPR/FPR move support for 16-bit floating point values).
• Codegen and assembler/disassembler support for the XVentanaCondOps vendor extension, which provides conditional arithmetic and move/select operations.
• Codegen and assembler/disassembler support for the XTHeadVdot vendor extension, which implements vector integer four 8-bit multiple and 32-bit add.

LLDB

LLDB has started to become usable for RISC-V in this period due to work by contributor 'Emmer'. As they summarise here, LLDB should be usable for debugging RV64 programs locally but support is lacking for remote debug (e.g. via the gdb server protocol). During the LLVM 16 development window, LLDB gained support for software single stepping on RISC-V, support in EmulateInstructionRISCV for RV{32,64}I, as well as extensions A and M, C, RV32F and RV64F, and D.

Short forward branch optimisation

Another improvement that's fun to look more closely at is support for "short forward branch optimisation" for the SiFive 7 series cores. What does this mean? Well, let's start by looking at the problem it's trying to solve. The base RISC-V ISA doesn't include conditional moves or predicated instructions, which can be a downside if your code features unpredictable short forward branches (with the ensuing cost in terms of branch mispredictions and bloating branch predictor state). The ISA spec includes commentary on this decision (page 23), noting some disadvantages of adding such instructions to the specification and noting microarchitectural techniques exist to convert short forward branches into predicated code internally. In the case of the SiFive 7 series, this is achieved using macro-op fusion where a branch over a single ALU instruction is fused and executed as a single conditional instruction.

In the LLVM 16 cycle, compiler optimisations targeting this microarchitectural feature were enabled for conditional move style sequences (i.e. branch over a register move) as well as for other ALU operations. The job of the compiler here is of course to emit a sequence compatible with the micro-architectural optimisation when possible and profitable. I'm not aware of other RISC-V designs implementing a similar optimisation - although there are developments in terms of instructions to support such operations directly in the ISA which would avoid the need for such microarchitectural tricks. See XVentanaCondOps, XTheadCondMov, the previously proposed but now abandoned Zbt extension (part of the earlier bitmanip spec) and more recently the proposed Zicond (integer conditional operations) standard extension.

Atomics

It's perhaps not surprising that code generation for atomics can be tricky to understand, and the LLVM documentation on atomics codegen and libcalls is actually one of the best references on the topic I've found. A particularly important note in that document is that if a backend supports any inline lock-free atomic operations at a given size, all operations of that size must be supported in a lock-free manner. If targeting a RISC-V CPU without the atomics extension, all atomics operations would usually be lowered to __atomic_* libcalls. But if we know a bit more about the target, it's possible to do better - for instance, a single-core microcontroller could implement an atomic operation in a lock-free manner by disabling interrupts (and conventionally, lock-free implementations of atomics are provided through __sync_* libcalls). This kind of setup is exactly what the +forced-atomics feature enables, where atomic load/store can be lowered to a load/store with appropriate fences (as is supported in the base ISA) while other atomic operations generate a __sync_* libcall.

There's also been a very minor improvement for targets with native atomics support (the 'A' instruction set extension) that I may as well mention while on the topic. As you might know, atomic operations such as compare and swap that are lowered to an instruction sequence involving lr.{w,d} (load reserved) and sc.{w,d} (store conditional). There are very specific rules about these instruction sequences that must be met to align with the architectural forward progress guarantee (section 8.3, page 51), which is why we expand to a fixed instruction sequence at a very late stage in compilation (see original RFC). This means the sequence of instructions implementing the atomic operation are opaque to LLVM's optimisation passes and are treated as a single unit. The obvious disadvantage of avoiding LLVM's optimisations is that sometimes there are optimisations that would be helpful and wouldn't break that forward-progress guarantee. One that came up in real-world code was the lack of branch folding, which would have simplified a branch in the expanded cmpxchg sequence that just targets another branch with the same condition (by just folding in the eventual target). With some relatively simple logic, this suboptimal codegen is resolved.

; Before                 => After
.loop:                   => .loop
  lr.w.aqrl a3, (a0)     => lr.w.aqrl a3, (a0)
  bne a3, a1, .afterloop => bne a3, a1, .loop
  sc.w.aqrl a4, a2, (a0) => sc.w.aqrl a4, a2, (a0)
  bnez a4, .loop         => bnez a4, .loop
.aferloop:               =>
  bne a3, a1, .loop      =>
  ret                    => ret

Assorted optimisations

As you can imagine, there's been a lot of incremental minor improvements over the past ~6 months. I unfortunately only have space (and patience) to highight a few of them.

A new pre-regalloc pseudo instruction expansion pass was added in order to allow optimising the global address access instruction sequences such as those found in the medany code model (and was later broadened further). This results in improvements such as the following (note: this transformation was already supported for the medlow code model):

; Before                            => After
.Lpcrel_hi1:                        => .Lpcrel_hi1
auipc a0, %pcrel_hi1(ga)            => auipc a0, %pcrel_hi1(ga+4)
addi a0, a0, %pcrel_lo(.Lpcrel_hi1) =>
lw a0, 4(a0)                        => lw a0, %pcrel_lo(.Lpcrel_hi1)(a0)

A missing target hook (isUsedByReturnOnly) had been preventing tail calling libcalls in some cases. This was fixed, and later support was added for generating an inlined sequence of instructions for some of the floating point libcalls.

The RISC-V compressed instruction set extension defines a number of 16-bit encodings that map to a 32-bit longer form (with restrictions on addressable registers in the compressed form of course). The conversion 32-bit instructions 16-bit forms when possible happens at a very late stage, after instruction selection. But of course over time, we've introduced more tuning to influence codegen decisions in cases where a choice can be made to produce an instruction that can be compressed, rather than one that can't. A recent addition to this was the RISCVStripWSuffix pass, which for RV64 targets will convert addw and slliw to add or slli respectively when it can be determined that all the users of its result only use the lower 32 bits. This is a minor code size saving, as slliw has no matching compressed instruction and c.addw can address a more restricted set of registers than c.add.

Other

At the risk of repeating myself, this has been a selective tour of some additions I thought it would be fun to write about. Apologies if I've missed your favourite new feature or improvement - the LLVM release notes will include some things I haven't had space for here. Thanks again for everyone who has been contributing to make the RISC-V in LLVM even better.

If you have a RISC-V project you think me and my colleagues and at Igalia may be able to help with, then do get in touch regarding our services.

• 2023-03-19: Clarified that Zawrs and Zihintntl support just involves the MC layer (assembler/disassembler).
• 2023-03-18: Initial publication date.

Last year I wrote a series of blog posts (1, 2, 3) about stack walk profiling Chromium using Windows native tools around ETW.

A fast recap: ETW support for stack walking in V8 allows to show V8 JIT generated code in the Windows Performance Analyzer. This is a powerful tool to analyze work loads where Javascript execution time is significant.

In this blog post, I will cover the usage of this very same tool, but to analyze NodeJS execution.

Enabling stack walk JIT information in NodeJS

In an ideal situation, V8 engines would always generate stack walk information when Windows is profiling. This is something we will want to consider in the future, as we prove enabling it has no cost if we are not in a tracing session.

Meanwhile, we need to set the V8 flag --enable-etw-stack-walking somehow. This will install hooks that, when a profiling session starts, will emit the JIT generated code addresses, and the information about the source code associated to them.

For a command line execution of NodeJS runtime, it is as simple as passing the command line flag:

node --enable-etw-stack-walking

This will work enabling ETW stack walking for that specific NodeJS session… Good, but not very useful.

Enabling ETW stack walking for a session

What’s the problem here? Usually, NodeJS is invoked indirectly through other tools (based or not in NodeJS). Some examples are Yarn, NPM, or even some Windows scripts or link files.

We could tune all the existing launching scripts to pass --enable-etw-stack-walking to the NodeJS runtime when it is called. But that is not much convenient.

There is a better way though, just using NODE_OPTIONS environment variable. This way, stack walking support can be enabled for all NodeJS calls in a shell session, or even system wide.

Bad news and good news

Some bad news: NodeJS was refusing --enable-etw-stack-walking in NODE_OPTIONS. There is a filter for which V8 options it accepts (mostly for security purposes), and ETW support was not considered.

Good news? I implemented a fix adding the flag to the list accepted by NODE_OPTIONS. It has been landed already, and it is available from NodeJS 19.6.0. Unfortunately, if you are using an older version, then you may need to backport the patch.

Using it: linting TypeScript

To explain how this can be used, I will analyse ESLint on a known workload: TypeScript. For simplicity, we are using the lint task provided by TypeScript.

This example assumes the usage of Git Bash.

First, clone TypeScript from GitHub, and go to the cloned copy:

git clone https://github.com/microsoft/TypeScript.git
cd TypeScript

Then, install hereby and the dependencies of TypeScript:

npm install -g hereby
npm ci

Now, we are ready to profile the lint task. First, set NODE_OPTIONS:

export NODE_OPTIONS="--enable-etw-stack-walking"

Then, launch UIForETW. This tool simplifies capturing traces, and will provide good defaults for Javascript ETW analysis. It provides a very useful keyboard shortcut, <Ctrl>+<Win>+R, to start and then stop a recording.

Switch to Git Bash terminal and do this sequence:

• Write (without pressing <Enter>): hereby lint
• Press <Ctrl>+<Win>+R to start recording. Wait 3-4 seconds as recording does not start immediately.
• Press <Enter>. ESLint will traverse all the TypeScript code.
• Press again <Ctrl>+<Win>+R to stop recording.

After a few seconds UIForETW will automatically open the trace in Windows Performance Analyzer. Thanks to settings NODE_OPTIONS all the child processes of the parent node.exe execution also have stack walk information.

Randomascii inclusive (stack) analysis

Focusing on node.exe instances, in Randomascii inclusive (stack) view, we can see where time is spent for each of the node.exe processes. If I take the bigger one (that is the longest of the benchmarks I executed), I get some nice insights.

The worker threads take 40% of the CPU processing. What is happening there? I basically see JIT compilation and garbage collection concurrent marking. V8 offloads that work, so there is a benefit from a multicore machine.

Most of the work happens in the main thread, as expected. And most of the time is spent parsing and applying the lint rules (half for each).

If we go deeper in the rules processing, we can see which rules are more expensive.

Memory allocation

In total commit view, we can observe the memory usage pattern of the process running ESLint. For most of the seconds of the workload, allocation grows steadily (to over 2GB of RAM). Then there is a first garbage collection, and a bit later, the process finishes and all the memory is deallocated.

More findings

At first sight, I observe we are creating the rules objects for all the execution of ESLint. What does it mean? Could we run faster reusing those? I can also observe that a big part of the time in main thread leads to leaves doing garbage collection.

This is a good start! You can see how ETW can give you insights of what is happening and how much time it takes. And even correlate that to memory usage, File I/O, etc.

Builtins fix

Using NodeJS, as is today, will still show many missing lines in the stack. I did those tests, and could do a useful analysis, because I applied a very recent patch I landed in V8.

Before the fix, we would have this sequence:

• Enable ETW recording
• Run several NodeJS tests.
• Each of the tests creates one or more JS contexts.
• That context then sends to ETW the information of any code compiled with JIT.

But there was a problem: any JS context has already a lot of pre-compiled code associated: builtins and V8 snapshot code. Those were missing from the ETW traces captured.

The fix, as said, has been already landed to V8, and hopefully will be available soon in future NodeJS releases.

Wrapping up

There is more work to do:

• WASM is still not supported.
• Ideally, we would want to have --enable-etw-stack-walking set by default, as the impact while not tracing is minimal.

In any case, after these new fixes, capturing ETW stack walks of code executed by NodeJS runtime is a bit easier. I hope this gives some joy to your performance research.

One last thing! My work for these fixes is possible thanks to the sponsorship from Igalia and Bloomberg.

We, Igalia’s multimedia team, would like to share with you our list of achievements along the past 2022.

WebKit Multimedia

WebRTC

Phil already wrote a first blog post, of a series, on this regard: WebRTC in WebKitGTK and WPE, status updates, part I. Please, be sure to give it a glance, it has nice videos.

Long story short, last year we started to support Media Capture and Streams in WebKitGTK and WPE using GStreamer, either for input devices (camera and microphone), desktop sharing, webaudio, and web canvas. But this is just the first step. We are currently working on RTCPeerConnection, also using GStreamer, to share all these captured streams with other web peers. Meanwhile, we’ll wait for the second episode of Phil’s series

MediaRecorder

We worked in an initial implementation of MediaRecorder with GStreamer (1.20 or superior). The specification goes about allowing a web browser to record a selected stream. For example, a voice-memo or video application which could encode and upload a capture of your microphone / camera.

Gamepad

While WebKitGTK already has Gamepad support, WPE lacked it. We did the implementation last year, and there’s a blog post about it: Gamepad in WPEWebkit, with video showing a demo of it.

Capture encoded video streams from webcams

Some webcams only provide high resolution frames encoded in H.264 or so. In order to support these resolutions with those webcams we added the support for negotiate of those formats and decode them internally to handle the streams. Though we are just at the beginning of more efficient support.

Flatpak SDK maintenance

A lot of effort went to maintain the Flatpak SDK for WebKit. It is a set of runtimes that allows to have a reproducible build of WebKit, independently of the used Linux distribution. Nowadays the Flatpak SDK is used in Webkit’s EWS, and by many developers.

Among all the features added during the year we can highlight added Rust support, a full integrity check before upgrading, and offer a way to override dependencies as local projects.

MSE/EME enhancements

As every year, massive work was done in WebKit ports using GStreamer for Media Source Extensions and Encrypted Media Extensions, improving user experience with different streaming services in the Web, such as Odysee, Amazon, DAZN, etc.

In the case of encrypted media, GStreamer-based WebKit ports provide the stubs to communicate with an external Content Decryption Module (CDM). If you’re willing to support this in your platform, you can reach us.

Also we worked in a video demo showing how MSE/EME works in a Raspberry Pi 3 using WPE:

WebAudio demo

We also spent time recording video demos, such as this one, showing WebAudio using WPE on a desktop computer.

GStreamer

We managed to merge a lot of bug fixes in GStreamer, which in many cases can be harder to solve rather than implementing new features, though former are more interesting to tell, such as those related with making Rust the main developing language for GStreamer besides C.

Rust bindings and GStreamer elements for Vonage Video API / OpenTok

OpenTok is the legacy name of Vonage Video API, and is a PaaS (Platform As a Service) to ease the development and deployment of WebRTC services and applications.

We published our work in Github of Rust bindings both for the Client SDK for Linux and the Server SDK using REST API, along with a GStreamer plugin to publish and subscribe to video and audio streams.

GstWebRTCSrc

In the beginning there was webrtcbin, an element that implements the majority of W3C RTCPeerConnection API. It’s so flexible and powerful that it’s rather hard to use for the most common cases. Then appeared webrtcsink, a wrapper of webrtcbin, written in Rust, which receives GStreamer streams which will be offered and streamed to web peers. Later on, we developed webrtcsrc, the webrtcsink counterpart: an element which source pads push streams from web peers, such as another browser, and forward those Web streams as GStreamer ones in a pipeline. Both webrtcsink and webrtcsrc are written in Rust.

Behavior-Driven Development test framework for GStreamer

Behavior-Driven Development is gaining relevance with tools like Cucumber for Java and its domain specific language, Gherkin to define software behaviors. Rustaceans have picked up these ideas and developed cucumber-rs. The logical consequence was obvious: Why not GStreamer?

Last year we tinkered with GStreamer-Cucumber, a BDD to define behavior tests for GStreamer pipelines.

GstValidate Rust bindings

There have been some discussion if BDD is the best way to test GStreamer pipelines, and there’s GstValidate, and also, last year, we added its Rust bindings.

GStreamer Editing Services

Though not everything was Rust. We work hard on GStreamer’s nuts and bolts.

Last year, we gathered the team to hack GStreamer Editing Services, particularly to explore adding OpenGL and DMABuf support, such as downloading or uploading a texture before processing, and selecting a proper filter to avoid those transfers.

GstVA and GStreamer-VAAPI

We helped in the maintenance of GStreamer-VAAPI and the development of its near replacement: GstVA, adding new elements such as the H.264 encoder, the compositor and the JPEG decoder. Along with participation on the debate and code reviewing of negotiating DMABuf streams in the pipeline.

Vulkan decoder and parser library for CTS

You might have heard about Vulkan has now integrated in its API video decoding, while encoding is currently work-in-progress. We devoted time on helping Khronos with the Vulkan Video Conformance Tests (CTS), particularly with a parser based on GStreamer and developing a H.264 decoder in GStreamer using Vulkan Video API.

You can check the presentation we did last Vulkanised.

WPE Android Experiment

In a joint adventure with Igalia’s Webkit team we did some experiments to port WPE to Android. This is just an internal proof of concept so far, but we are looking forward to see how this will evolve in the future, and what new possibilities this might open up.

If you have any questions about WebKit, GStreamer, Linux video stack, compilers, etc., please contact us.

I use Home Assistant (HA) to control my WiFi-enabled thermostat, which in turn is walled off from the Internet. So no matter how "smart" my thermostat wants to be, it's forced to live in isolation and follow orders from HA. For the past year, I've been trying out crude methods for detecting when humans are home, or not, so that the HVAC can be set accordingly. The last attempt required using the "ping" integration in HA. You basically provide a list of IPs, add users that are associated with the IP / device tracker for it, then you can conditionally run automation based on the status of those things.

This has worked pretty well, however there are some pain points that have been really digging at me:

1. Setting this up requires using static DHCP for devices on the network that I want to associate with someone being home, like a cell phone. This is tricky since some phones use random MACs, and it's cumbersome to add new people to the "who could be home?" list.

2. If people come over, I don't want the HVAC to shut off if the regular inhabitants leave. E.g. if my partner and I have to leave the house, and my mother-in-law stays at home, I'll get in trouble if the heat shuts off because HA thinks everyone is gone. Don't ask me how I know.

3. Setting this all up requires basically configuring HA to track inhabitants and guests in my home. Even though I've gone through great lengths to try to prevent HA from sending any data externally, I still don't like that this data is being stored anywhere. I actually don't care if my partner or some particular guest is home and I'm not, it's easy enough to ask if I suddenly do. But seeing that someone is home is fine. I've heard that some folks use the "cloud" to manage HA and its data. Ouch.

So I present my latest attempt to alleviate those 3 things as much as possible:

• Monitor IP ranges and detect if any devices in those ranges are "online" (responding to ping)
• Use DHCP to "put" devices that humans carry or use when they are home into the appropriate monitored IP range
• HA can use this to determine if any humans are connected (or not), and thus at home (or not)
• Guests who are on WiFi are counted as "home" by HA without me having to do anything more than just give them the guest WiFi password (which I would have done previously anyways).
• HA doesn't have any information about specific users and their home/not home status. And it doesn't care if devices use a consistent MAC or not.

All three pain points above are addressed... although maybe not 100% solved in every situation. But it still seems like an improvement.

At the heart of this is a script that runs ping in parallel on an arbitrary number of IP addresses given to it. I'm sure it could be improved... Like, I doubt this would turn out well if the list gets too large. And the run time of the script can be kinda long if there are no devices and it ends up retrying the max number of times. The retry is there because I've seen that some devices might not respond to ping immediately (they were sleeping, or had a WiFi reconnect event at the wrong time, etc...) So if you have any ideas, let me know!

#!/bin/bash
#
# Pings the given addresses and prints "up" if any of
# them respond to the ping, else it prints "down". A
# non-zero return value is an error.
# A simple backoff delay is used between attempts to
# ping the group when none of them responded to the
# last attempt.

function pings(){
    local PIDS=()
    local STATUS=()
    local IP=( "$@" )

    for ip in "${IP[@]}"; do
        ping  -c1 -W1 "$ip" &>/dev/null &
        PIDS+=($!)
    done

    i=0
    for p in "${PIDS[@]}"; do
        wait "${p}"
        STATUS[i]=$?
        ((i+=1))
    done

    for s in "${STATUS[@]}"; do
        if [[ $s -eq 0 ]]; then
            return 0
        fi
    done

    return 1
}

if [ -z "$1" ]; then
    echo "Parameter required!!"
    exit 1
fi

ADDRS=( "$@" )
try_interval=1  # starting interval, before backoff
tries=0
max_tries=4

while ! pings "${ADDRS[@]}"; do
    if [[ $tries -ge $max_tries ]]; then
        echo down
        exit 0
    fi

    sleep "$try_interval"
    ((tries+=1))
    ((try_interval*=2))
done

echo up
exit 0

This script should be saved in some directory that HA can access. Next, we need to actually run the script in a way that HA can consume the output directly and use it. A binary sensor seemed like the best choice:

binary_sensor:
  - platform: command_line
    name: 'network_users'
    device_class: presence
    scan_interval: 30 # seconds
    command_timeout: 30 # seconds
    command: 'bash -c "tools/mass_ping.sh 192.168.20.{100..150} 192.168.40.37"'
    payload_on: 'up'
    payload_off: 'down'

The parameters to that script can be ranges that the shell can expand, so you don't have to list out every IP. Triggering every 30 seconds may be too often, I may back that off later to be a minute or more... so I'll run this for a bit to see if I start to form any opinions about changing it.

Next we need to create a "device tracker" so that this can be associated with some "user" in HA for presence detection. I used device_tracker.see in a scheduled automation to add and update a device tracker thing in HA specifically for network users:

- alias: Update presence tracking sensors
  description: This is done periodically so that device trackers for each sensor have
    updated values after HA startup / config reload
  trigger:
  - platform: time_pattern
    minutes: /1
  condition: []
  action:
  - parallel:
    - service: device_tracker.see
      data:
        dev_id: network_users
        location_name: '{{ "home" if is_state("binary_sensor.network_users", "on")
          else "not_home" }}'
      alias: Update Network Users Tracker Status
    alias: Update device trackers
    
    # .... other binary sensors used for determining presence can be listed here too!
  mode: single

I set this automation to fire every 1 minute, so that the current status is "known" to HA soon after it starts up, or config is reloaded. Maybe 1 minute is "too often", but it's just reading a value from the HA database, so, meh. Basically, I've learned that triggering automations based on state changes is flaky, and it's often more reliable to trigger some automations on a schedule and then check entity states in the condition or action.

Lastly, there needs to be a "person" in HA to associate this device tracker with. I created a generic "person" and associated the tracker with it. This can be done through Settings->People->Add Person. I called the fake person I made for this "Pamela", but the name doesn't matter.

The presence status of this person can now be used in automation and/or dashboard cards:

Home Assistant Card showing that someone is connected to the network, and HVAC is enabled by automation

Now, this obviously isn't perfect... One of the issues is that this can lead to the HVAC being left on if someone forgets a phone at home, for example. But that could have happened over the last year with the old implementation, and I've found that 1) it's rare, and 2) the savings from having a "smarter" HVAC outweighs the handful of situations where it's being wasteful. Also, this could be circumvented if some smart guest assigns a static IP outside any expected range I pass to the script above. But if they do that, then the joke is on them since they'll just slowly freeze as the HVAC is shut off because HA thinks no one is home. I do have some other presence detection things that help out too (like IR motion detectors), that can help a little though.

With all of that, HA can tell if someone is home if they're connected to a network, and have an IP from DHCP (or otherwise) that's being monitored. And HA is completely oblivious to any specific people. Again, that's mostly just a personal concern and probably not very existential for my setup, but maybe this will be helpful for folks who do use some external thing for managing HA data, and are concerned about how location status for household members is handled.

Igalia started the Reforestation project in 2019. As one of the company’s Corporate Social Responsibility (CSR) efforts, the Reforestation project focuses on conserving and expanding native, old growth forests to capture, and long-term storing, carbon emissions. Partnering with Galnus, we have been working on reforestation of a 10.993 hectares area with 11,000 trees, which absorbs 66 tons of carbon dioxide each year.

Phase I – Rois

The first land where the project started was framed in the woods of the communal land of “San Miguel de Costa” in Rois. Rois is a municipality of northwestern Spain in the province of A Coruña in the autonomous community of Galicia. Environment in this land was highly altered by human action and the predominance of eucalyptus plantations left few examples of native forest.

After the agreement for land transfer signed on the 29th June 2019, the project started with creating maps and technical plans for the areas affected. Purposes of these plans are not only to build a cartographic base for management and accomplishment of the works but also to designate accurately these zones as “Reserved Areas” in future management plans.

Work carried out

• Clear and crush remaining eucalyptus and other exotic plants

Eucalyptus is an exotic and invasive species. It spread widely and had a negative impact on the environmental situation of this habitat. This work is to clear the existing growth and eliminate the regrowths of eucalyptus and other exotic plants before the start of planting work. In Q1 2020, 100% of exotic trees were cut as part of the Atlantic forest sponsorship. After that the focus was moved to eliminating the sprouts of eucalyptus grown from the seeds present in the soil in early years. Sprout and seeds elimination continues throughout the duration of the project.

• Acquire trees, shrubs and all other materials needed.

To improve forest structure and increase biodiversity for the affected area, the following native trees and shrubs were chosen and purchased in Q3 2019 –
– 1000 downy birch (Betula pubescens)
– 650 common oak (Quercus robur)
– 350 wild cherry (Prunus avium)
– 150 common holly (Ilex aquifolium)

A lot of other materials such as tree protectors, stakes etc. were also acquired at the time time.

• Planting

Planting started in Q4 2019, downy birches (Betula pubescens) and some common oaks (Quercus robur) were the first batch planted. This planting campaign continued in 2020 on the arrival of the rest of the trees.

• Care during the first year

The first year after planting is key to the future development and success of the project.

In Q1 2020, 100% of planted trees were already sprouting and alive. At this stage 100% of the restoration area has already been planted with at least 65% of the trees.

The first summer after planting is vital for the trees and shrubs to settle. During the first summer, trees adapt and take root in their new location. If they survive, their chances of developing correctly will increase exponentially and the following years they will be able to focus all their energy on their growth. The beginning of the summer 2020 was difficult due to hot and dry weather. However, the tree mortality rate remains within the expected range.

In Q4 2020, most of the planted trees are well-established and ready for spring sprouting. By Q1 2021 many of them have reached over 2 meters high.

The trees and shrubs settled happily after the first year of growth. This is the photo taken in Spring 2020

And see how they had grown in a year’s time –

• Wildlife studies

With plants sprouting all around the forest, insects, reptiles and birds start thriving too. The development of the ecosystem will provide for better results in future inventories and wildlife studies. In summer 2020 the wildlife studies started and first inventory was completed. In winter 2020 wildlife nest boxes were in the manufacturing process and some bat boxes were installed in Spring 2021.

• Improving biodiversity

In addition to ensuring the introduction of a wide variety of tree species to reforestation areas, the project has also put effort on enhancing biodiversity in existing forest areas. For example, One of the areas targeted by the project is one hectare of young secondary forest made up mainly of oaks (Quercus robur). In this forest we have been planting understory species such as holly (Ilex aquifolium), laurel (Laurus nobilis) or Atlantic pear (Pyrus cordata) to increase biodiversity and improve the structure and complexity of the forest.

Phase II – Eume and Rois

Phase II of the reforestation project set sail in winter 2020. While the Rois project had moved to a steady stage with most trees and shrubs planted and settled through the first year’s growth, this phase is to expand restoration of new forest area in Rois and to start a new project in “Fragas do Eume” natural park.

• Rois

In order to explain the progress in the Rois expansion project, the maps below distinguish three areas in different stages of development.
– Phase 1 (Green) – The green area is completely planted with native trees and free of eucalyptus sprouts.
– Phase 2 (Yellow) – Acacias have been eliminated in this area. The work to control this species and also the eucalyptus trees will continue.
– Phase 3 (Red) – The entire area is covered with dense plantations of eucalyptus and acacia. Work is in the preparation stage.

The following maps represent the progresses made between Spring to Fall in 2021.

Spring 2021:

Fall 2021:

• Eume

Unlike the Rois project, habitats in “Fragas do Eume” natural park are some of the largest and best preserved examples in the world of coastal Atlantic rainforest, where much of its biodiversity and original structure is still preserved. Unfortunately, most of these forests are young secondary forests under numerous threats such as the presence of eucalyptus and other invasive species.

Our project represents one of the largest actions in recent years for the elimination and control of exotic species and the restoration of native forest in the area, increasing native forest surface area, reconnecting fragmented forest patches and improving the landscape in the “Fragas do Eume Natural Park”.

In order to explain the progress in the Eume project, it also distinguishes three areas in different stages of development.

Phase 1 (Green) – All the environmental restoration works have been completed. Only maintenance tasks remain for the next few years.
phase 2 (Yellow) – This area is in the process of control and elimination of eucalyptus to start the restoration of native vegetation with native trees plantation works.
Phase 3 (Red) – Waiting for the loggers to cut the big eucalyptus trees in this area, in order to start the work associated with the project.

The following maps represent the progresses made between Spring to Fall in 2021.

Spring 2021:

Fall 2021:

Esmelle

In 2021 Igalia started working on a 0.538-hectare land owned by the Esmelle Valley Association. This land is borded by a road and a forest track on each side, and the Esmelle stream flows across it. This once mighty stream and its tributary springs are currently used to provide drinking water to the houses in the surrounding area. Unfortunately, in summer time, the flow of the stream could reduce drastically due to dry weather and exhausting uses. In addition, this area also suffers invasion of numerous eucalyptus trees and other exotic species. Recovering and restoring a good example of the Atlantic Forest will bring great benefit to this enormously altered and humanized case.

After work preparation and planning, major work were carried out in 2022 including –
– Elimination and control of eucalyptus and its sprouts.
– Clearing and ground preparation
– Tree seedling, plantation and protections (placement of tree stakes and protectors etc.)
– Maintenance and replacement of dead trees

This work will continue in the next two years. Main focus will be on reinforcement and enrichment of the plantation based on the availability of tree seedlings of certain species, and finishing all the remaining maintenance work.

What’s next?

Igalia sees Reforestation as a long term effort. While maintaining and developing the current projects, Igalia doesn’t stop looking for new candidates. In Q4 2022, Igalia started preparing a new Reforestation project – Galnus: O Courel.

This is the first time that Igalia considered developing an environmental compensation project in one of the most rural and least densely populated areas of Galicia. Igalia believes that the environmental, social and economic characteristics associated with this area, offers an opportunity to carry out
environmental restoration projects. If it goes as planned, major work will happen in the next two years. Something to look forward to!

Impacts

The Reforestation project is making contributions to our environment, and it has gone further. Here we’d like to share a picture of a 7-year-old boy’s work. This young student is from the community owning the Rois forest. He took advantage of a school newspaper project to communicate about our work in Rois forest.

Isn’t it a joy to see Iglaia’s Reforestation project is making impacts on our children, and our future?

As a kernel developer, everyday I need to compile and install custom kernels, and any improvement in this workflow means to be more productive. While installing my fresh compiled modules, I noticed that it would be stuck in amdgpu compression for some time:

XZ      /usr/lib/modules/6.2.0-tonyk/kernel/drivers/gpu/drm/amd/amdgpu/amdgpu.ko.xz

XZ format

My target machine is the Steam Deck, that uses .xz for compressing the modules. Giving that we want gamers to be able to install as many games as possible, the OS shouldn’t waste much disk space. amdgpu, when compiled with debug symbols can use a good hunk of space. Here’s the comparison of disk size of the module uncompressed, and then with .zst and .xz compression:

360M amdgpu.ko
61M  amdgpu.ko.zst
38M  amdgpu.ko.xz

This more compact module comes with a cost: more CPU time for compression.

Multithread compression

When I opened htop, I saw that only a lonely thread was doing the hard work to compress amdgpu, even that compression is a task easily parallelizable. I then hacked scripts/Makefile.modinst so XZ would use as many threads as possible, with the option -T0. In my main build machine, modules_install was running 4 times faster!

# before the patch
$ time make modules_install -j16
Executed in  100.08 secs

# after the patch
$ time make  modules_install -j16
Executed in   28.60 secs

Then, I submitted a patch to make this default for everyone: [PATCH] kbuild: modinst: Enable multithread xz compression

However, as Masahiro Yamada noticed, we shouldn’t be spawning numerous threads in the build system without the user request. Until today we specify manually how many threads we should run with make -jX.

Hopefully, Nathan Chancellor suggested that the same results can be achieved using XZ_OPT=-T0, so we still can benefit from this without the patch. I experimented with different -TX and -jY values, but in my notebook the most efficient values were X = Y = nproc. You can check some results bellow:

$ make modules_install
174.83 secs

$ make modules_install -j8
100.55 secs

$ make modules_install XZ_OPT=-T0
81.51 secs

$ make modules_install -j8 XZ_OPT=-T0
53.22 sec

The RISC-V instruction set architecture has seen huge excitement and growth in recent years (10B cores estimated to have shipped as of Dec 2022) and I've been keeping very busy with RISC-V related work at Igalia. I thought it would be fun to look beyond the cores I've been working with and to enumerate the SoCs that are available for direct purchase or in development boards that feature RISC-V cores programmable by the end user. I'm certain to be missing some SoCs or have some mistakes or missing information - any corrections very gratefully received at asb@muxup.com or @asbradbury. I'm focusing almost exclusively on the RISC-V aspects of each SoC - i.e. don't expect a detailed listing of other on-chip peripherals or accelerators.

A few thoughts

• It was absolutely astonishing how difficult it was to get basic information about the RISC-V specification implemented by many of these SoCs. In a number of cases, just a description of a "RV32 core at xxMHz" with further detective work being needed to find any information at all about even the standard instruction set extensions supported.
• The way I've focused on the details of individual cores does a bit of a disservice to those SoCs with compute clusters or interesting cache hierarchies. If I were to do this again (or if I revisit this in the future), I'd look to rectify that. There a whole bunch of other micro-architectural details it would be interesting to detail too.
  • I've picked up CoreMark numbers where available, but of course that's a very limited metric to compare cores. It's also not always clear which compiler was used, which extensions were targeted and so on. Plus when the figure is taken from an IP core product page, the numbers may refer to a newer version of the IP. Where there are multiple numbers floating about I've listed them all.
• There's a lot of chips here - but although I've likely missed some, not so many that it's impossible to enumerate. RISC-V is growing rapidly, so perhaps this will change in the next year or two.
• A large proportion of the SoC designs listed are based on proprietary core designs. The exceptions are the collection of SoCs based on the T-Head cores, the SiFive E31 and Kendryte K210 (Rocket-derived) and the GreenWaves GAP8/GAP9 (PULP-derived). As a long-term proponent of open source silicon I'd hope to see this change over time. Once a company has moved from a proprietary ISA to an open standard (RISC-V), there's a much easier transition path to switch from a proprietary IP core to one that's open source.

64-bit Linux-capable application processors

• StarFive JH7110
  • Core design:
    • 4 x RV64GC_Zba_Zbb SiFive U74 application cores, 1 x RV64IMAC SiFive S7 (this?) monitor core, and 1 x RV32IMFC SiFive E24 (ref, ref).
    • The U74 is a dual-issue in-order pipeline with 8 stages.
  • Key stats:
    • 1.5 GHz, fabbed on TSMC 28nm (ref).
    • StarFive report a CoreMark/MHz of 5.09.
  • Development board:
    • Available in the VisionFive 2 and Pine64 Star64 development boards.
• T-Head C910 ICE
  • Core design:
    • 2 x RV64GC T-Head C910 application cores and an additional T-Head C910 RV64GCV core (i.e., with the vector extension).
    • The C910 is a 3-issue out-of-order pipeline with 12 stages.
  • Key stats:
    • 1.2 GHz, fabbed on a 28nm process (ref).
  • Development board:
    • Available in the RVB-ICE.
• Allwinner D1-H (datasheet, user manual)
  • Core design:
    • 1 x RV64GC T-Head C906 application core. Additionally supports the unratified, v0.7.1 RISC-V vector specification (ref).
    • Single-issue in-order pipeline with 5 stages.
    • Verilog for the core is on GitHub under the Apache License (see discussion on what is included).
    • At least early versions of the chip incorrectly trapped on fence.tso. It's unclear if this has been fixed in later revisions.
  • Key stats:
    • 1GHz, taped out on a 22nm process node.
    • Reportedly 3.8 CoreMark/MHz.
  • Development board:
    • Available in a number of development boards (e.g. Allwinner Nezha, SiPeed Lichee RV, and more).
• StarFive JH7100
  • Core design:
    • 2 x RV64GC SiFive U74 application cores and 1 x RV32IMAFC SiFive E24.
    • The U74 is a dual-issue in-order pipeline with 8 stages.
  • Key stats:
    • 1.2GHz (as listed on StarFive's page but articles about the V1 board claimed 1.5GHz), presumably fabbed on TSMC 28nm (the JH7110 is).
    • The current U74 product page claims 5.75 CoreMark/MHz (previous reports suggested 4.9 CoreMark/MHz).
  • Development board:
    • Available on the VisionFive V1 development board.
• Kendryte K210 (datasheet)
  • Core design:
    • 2 x RV64GC application cores (reportedly implementations of the open-source Rocket core design).
    • If it's correct the K210 uses Rocket, it's a single-issue in-order pipeline with 5 stages.
    • Has a non-standard (older version of the privileged spec?) MMU (ref, so the nommu Linux port is typically used.
  • Key stats:
    • 400MHz, fabbed on TSMC 28nm.
  • Development board:
    • Available in development boards from SiPeed.
• MicroChip PolarFire SoC MPFSxxxT
  • Core design:
    • 4 x RV64GC SiFive U54 application cores, 1 x RV64IMAC SiFive E51 (now renamed to S51) monitor core.
    • The U54 is a single-issue, in-order pipeline with 5 stages.
  • Key stats:
    • 667 MHz (ref), fabbed on a 28nm node (ref).
    • Microchip report 3.125 CoreMark/MHz.
  • Development board:
    • Available in the 'Icicle' development board.
• SiFive FU740
  • Core design:
    • 4 x RV64GC SFive U74 application cores, 1 x RV64IMAC SiFive S71 monitor core.
    • It's hard to find details for the S71 core, the FU740 manual refers to it as an S7 while the HiFive Unmatched refers to it as the S71 - but neither have a page on SiFive's site. I'm told that the S71 has the same pipeline as the S76, just no support for the F and D extensions.
    • The U74 is a dual-issue in-order pipeline with 8 stages.
  • Key stats:
    • 1.2 GHz, fabbed on TSMC 28nm (ref).
    • The current U74 product page claims 5.75 CoreMark/MHz (previous reports suggested 4.9 CoreMark/MHz).
  • Development board:
    • Was available on the now-discontinued HiFive Unmatched development board.
• SiFive FU540
  • Core design:
    • 4 x RV64GC SiFive U54 application cores, 1 x RV64IMAC SiFive E51 (now renamed to S51) monitor core.
    • The U54 is a single-issue, in-order pipeline with 5 stages.
  • Key stats:
    • 1.5GHz, fabbed on TSMC 28nm (ref).
    • The current U54 product page claims 3.16 CoreMark/MHz but it was 2.75 in 2017.
  • Development board:
    • Was available on the now-discontinued HiFive Unleashed development board.
• Bouffalo Lab BL808
  • Core design:
    • 1 x RV64IMAFCV T-Head C906 application core, 1 x RV32IMAFCP T-Head E907, 1 x RV32E?? T-Head E902 (ref).
    • See notes elsewhere for more info on these T-Head core designs.
  • Key stats:
    • The C906 runs at 480 MHz, the E907 at 320 MHz and the E902 at 150 MHz.
  • Development board:
    • Available in the Ox64 from Pine64.
• Renesas RZ/Five
  • Core design:
    • 1 x RV64GC Andes AX45MP application core with additional Andes extensions (draft of the 'P' packed SIMD spec, Andes 'V5' extensions).
    • Unfortunately has a hardware bug where virtual addresses in a certain range are always treated as physical addresses.
    • Dual issue, in-order pipeline with 8 stages.
  • Key stats:
    • 1.0 GHz, 5.63 CoreMark/MHz (ref).
  • Development board:
    • Evaluation kit available.
• Kendryte K510
  • Core design:
    • 2 x RV64GC application cores and 1 x RV64GC core with DSP extensions. The Andes AX25MP appears to be used (ref).
  • Key stats:
    • 800 MHz.
  • Development board:
    • K510 CRB-KIT developer kit is available.
• (Upcoming) Intel-SiFive Horse Creek SoC
  • Core design:
    • 4 x "RV64GBC" SiFive P550 application cores (docs not yet available, but an overview is here). As the 'B' extension was broken up into smaller sub-extensions, this is perhaps RV64GC_Zba_Zbb like the SiFive U74.
    • 13 stage, 3 issue, out-of-order pipeline.
    • As the bit manipulation extension was split into a range of sub-extensions it's unclear exactly which of the 'B' family extensions will be supported.
  • Key stats:
    • 2.2 GHz, fabbed on Intel's '4' process node (ref).
  • Development board:
    • Will be available in the HiFive Pro P550 development board.
• (Upcoming) T-Head TH1520 (announcement)
  • Core design:
    • 4 x RV64GC T-Head C910 application cores, 1 x RV64GC T-Head C906, 1 x RV32IMC T-Head E902.
    • The C910 is a 3-issue out-of-order pipeline with 12 stages, the C906 is single-issue in-order with 5 stages, and the E902 is single-issue in-order with 2 stages.
    • Verilog for the cores is up on GitHub under the Apache license: C910, C906, E902. See discussion on what is included).
  • Key stats:
    • 2.4 GHz, fabbed on a 12nm process (ref).
  • Development board:
    • Will be available on the SiPeed Lichee Pi 4A.

Embedded / specialised SoCs (mostly 32-bit)

• SiFive FE310
  • Core design:
    • 1 x RV32IMAC SiFive E31 core.
    • Single-issue, in-order pipeline with 5 stages.
    • Derived from the open source Rocket core design (ref).
  • Key stats:
    • 320 MHz (ref), fabbed on TSMC 180nm (ref),
    • 2.73 CoreMark/MHz in the FE310-G002 datasheet, 3.17 CoreMark/MHz on the E31 product page.
  • Development board:
    • Available in development boards such as the HiFive 1 Rev B.
• GigaDevice GD32VF103 series
  • Core design:
    • 1 x RV32IMAC Nuclei Bumblebee N200 ("jointly developed by Nuclei System Technology and Andes Technology.")
    • No support for PMP (Physical Memory Protection), includes the 'ECLIC' interrupt controller derived from the CLIC design.
    • Single-issue, in-order pipeline with 2 stages.
  • Key stats:
    • 108 MHz. 360 CoreMark (ref), implying 3.33 CoreMark/MHz.
  • Development board:
    • Available in development boards such as the Sipeed Longan Nano.
• GreenWaves GAP8
  • Core design:
    • Fabric Controller (FC) core and compute cluster of 8 cores based on PULP. Implements RV32IMC with alongside additional custom extensions.
  • Key stats:
    • 175 MHz Fabric Controller, 250 MHz cluster. Fabbed on TSMC's 55nm process (ref).
    • 22.65 GOPS at 4.24mW/GOP (ref).
    • Shipped 150,000 units, composed of roughly 80% open source and 20% proprietary IP (ref).
  • Development board:
    • Available in the GAPuino.
• GreenWaves GAP9
  • Core design:
    • Fabric Controller (FC) and compute cluster of 9 cores. Extends the RV32IMC (plus extensions) GAP8 core design with additional custom extensions (ref).
  • Key stats:
    • 400 MHz Fabric Controller and computer cluster. Fabbed on Global Foundries 22nm FDX process (ref).
    • 150.8 GOPS at 0.33mW/GOP (ref).
  • Development board:
    • GAP9 evaluation kit listed on Greenwaves store but you must email to receive access to order it.
• Renesas RH850/U2B
  • Core design:
    • Features an NSITEXE DR1000C RISC-V parallel coprocessor, comprised of RV32I scalar processor units, a control core unit, and a vector processing unit based on the RISC-V vector extension.
  • Key stats:
    • 400 MHz. Fabbed on a 28nm process.
  • Development board:
    • None I can find.
• Renesas R9A02G020
  • Core design:
    • 1 x RV32IMC AndesCore N22 (additionally supporting the Andes 'Performance' and 'CoDense' instruction set extensions).
    • Single-issue in-order with a 2-stage pipeline.
  • Key stats:
    • 32 MHz.
  • Development board:
    • The R9A02G020-EVK motor control kit is available.
• Analog Devices MAX78000
  • Core design:
    • Features an RV32 RISC-V coprocessor of unknown (to me!) design and unknown ISA naming string.
  • Key stats:
    • 60 MHz (for the RISC-V co-processor), fabbed on a TSMC 40nm process (ref).
  • Development board:
    • MAX78000EVKIT and MAX78000FTHR.
• Espressif ESP32-C3 / ESP8685
  • Core design:
    • 1 x RV32IMC core of unknown design, single issue in-order 4-stage pipeline (ref).
  • Key stats:
    • 160 MHz, fabbed on a TSMC 40nm process (ref).
    • 2.55 CoreMark/MHz.
  • Development board:
    • Available in a number of formats including the ESP32-C3-DevKitM-1 and the M5Stack M5Stamp C3.
• Espressif ESP32-C2 / ESP8684
  • Core design:
    • 1 x RV32IMC core of unknown design, single issue in-order 4-stage pipeline (ref).
  • Key stats:
    • 160 MHz, fabbed on a TSMC 40nm process.
    • 2.55 CoreMark/MHz.
    • Die photo available in this article.
  • Development board:
    • Available in the ESP8684-DevKitM-1-H4.
• Espressif ESP32-C6
  • Core design:
    • 1 x RV32IMAC core of unknown design (four stage pipeline) and 1 x RV32IMAC core of unknown design (two stage pipeline) for low power operation (ref).
  • Key stats:
    • 160 MHz high performance (HP) core with 2.76 CoreMark/MHz, 20 MHz low power (LP) core.
  • Development board:
    • Available in the ESP32-C6-DevKitC-1-N8.
• HiSilicon Hi3861
  • Core design:
    • 1 x RV32IM core of unknown design, supporting additional non-standard compressed instruction set extensions (ref).
  • Key stats:
    • 160 MHz.
  • Development board:
    • A low-cost board is available advertising support for Harmony OS.
• Bouffalo Lab BL616/BL618
  • Core design:
    • 1 x RV32GC core of unknown design, also with support for the unratified 'P' packed SIMD extension (ref).
  • Key stats:
    • 320 MHz.
  • Development board:
    • Available in the Sipeed M0S module.
• Bouffalo Lab BL602/BL604
  • Core design:
    • 1 x RV32IMAFC SiFive E24 core (ref).
    • 3-stage pipeline.
  • Key stats:
    • 192 MHz, 3.1 CoreMark/MHz (ref).
  • Development board:
    • Available in the very low cost Pinecone evaluation board.
  • Other:
    • The BL702 appears to have the same core, so I haven't listed it separately.
• Bluetrum AB5301A
  • Core design:
    • 1 x RV32 core of uknown design and unknown ISA naming string (CNX Software tried and failed to get clarification.
  • Key stats:
    • 125 MHz.
  • Development board:
    • Available in the AB32VG1 development board.
• WCH CH583/CH582/CH581
  • Core design:
    • 1 x RV32IMAC QingKe V4a core, which also supports a "hardware prologue/epilogue" extension.
    • Single issue in-order pipeline with 2 stages.
    • Unlike the other QingKe V4 series core designs, the V4a doesn't support the custom 'extended instruction' (XW) instruction set extension.
  • Key stats:
    • 20MHz.
  • Development board:
    • An evaluation board is available.
• WCH CH32V307
  • Core design:
    • 1 x RV32IMAFC QingKe V4f core.
  • Key stats:
    • 144 MHz.
  • Development board:
    • An evaluation board is available.
• WVH CH32V208
  • Core design:
    • 1 x RV32IMAC QingKe V4c core with custom instruction set extensions ('XW' for sign-extended byte and half word operations).
  • Key info:
    • 144 MHz.
  • Development board:
    • Available here.
  • Other:
    • The CH32V203 is also available but I haven't listed it separately as it's not clear how the QingKe V4b core in that chip differs to the V4c in this one.
• WCH CH569 / WCH CH573 / WCH CH32V103
  • Core design:
    • 1 x RV32IMAC QinqKe V3a core.
  • Key stats:
    • 120 MHz (CH569), 20 MHz (CH573), 80 MHz (CH32V103).
  • Development board:
    • Evaluation boards available, e.g. this one for the CH32V103.
• WCH CH32V003
  • Core design:
    • 1 x RV32EC QingKe V2A with custom instruction set extensions ('XW' for sign-extended byte and half word operations).
  • Key stats:
    • 48 MHz.
    • Notably announced as costing less than 10 cents.
  • Development board:
    • Various boards available.
• PicoCom PC802
  • Core design:
    • Two clusters of 16 RV32IMAC Andes N25F cores (ref).
    • Single issue, in order pipeline with 5 stages.
    • Also see the 2021 RISC-V summit talk for more insight on the architecture.
  • Key stats:
    • Fabbed on TSMC 12nm process (ref).
  • Development board:
    • Several boards are available.
• CSM32RV20
  • Core design:
    • 1 x RV32IMAC core of unknown design.
  • Key stats:
    • 2.6 CoreMark/MHz.
  • Development board:
    • The product page suggests two boards are available.

Bonus: Other SoCs that don't match the above criteria or where there's insufficient info

• The Espressif ESP32-P4 was announced, featuring a dual-core 400MHz RISC-V CPU with "an AI instructions extension". I look forward to incorporating it into the list above when more information is available.
• I won't try to enumerate every use of RISC-V in chips that aren't programmable by end users or where development boards aren't available, but it's worth noting the use of RISC-V Google's Titan M2
• In January 2022 Intel Mobileye announced the EyeQ Ultra featuring 12 RISC-V cores (of unknown design), but there hasn't been any news since.

• 2023-03-19: Add note on silicon bug in the Renesas RZ/Five.
• 2023-03-12: Clarified details of several SiFive cores and made the listing of SoCs using cores derived from open source RTL exhaustive.
• 2023-03-04:
  • Added in the CSM32RV20 and some extra Bouffalo Lab and WCH chips (thanks to Reddit user 1r0n_m6n).
  • Confirmed likely core design in the K510 (thanks to Reddit user zephray_wenting).
  • Further Espressif information and new ESP32-C2 entry contributed by Ivan Grokhotkov.
  • Clarified cores in the JH7110 and JH7100 (thanks to Conor Dooley for the tip).
  • Added T-Head C910-ICE (thanks to a tip via email).
• 2023-03-03:
  • Added note about CoreMark scores.
  • Added the Renesas R9A02G020 (thanks to Giancarlo Parodi for the tip!).
  • Various typo fixes.
  • Add link to PicoCom RISC-V Summit talk and clarify the ISA extensions supported by the PC802 Andes N25F clusters.
• 2023-03-03: Initial publication date.

As part of my training at Igalia I’ve been attempting to write a new backend for Freedreno that targets the proprietary “KGSL” kernel mode driver. For those unaware there are two “main” kernel mode drivers on Qualcomm SOCs for the GPU, there is the “MSM”, and “KGSL”. “MSM” is DRM compliant, and Freedreno already able to run on this driver. “KGSL” is the proprietary KMD that Qualcomm’s proprietary userspace driver targets. Now why would you want to run freedreno against KGSL, when MSM exists? Well there are a few ones, first MSM only really works on an up-streamed kernel, so if you have to run a down-streamed kernel you can continue using the version of KGSL that the manufacturer shipped with your device. Second this allows you to run both the proprietary adreno driver and the open source freedreno driver on the same device just by swapping libraries, which can be very nice for quickly testing something against both drivers.

When “DRM” isn’t just “DRM”

When working on a new backend, one of the critical things to do is to make use of as much “common code” as possible. This has a number of benefits, least of all reducing the amount of code you have to write. It also allows reduces the number of bugs that will likely exist as you are relying on well tested code, and it ensures that the backend is mostly likely going to continue to work with new driver updates.

When I started the work for a new backend I looked inside mesa’s src/freedreno/drm folder. This has the current backend code for Freedreno, and its already modularized to support multiple backends. It currently has support for the above mentioned MSM kernel mode driver as well as virtio (a backend that allows Freedreno to be used from within in a virtualized environment). From the name of this path, you would think that the code in this module would only work with kernel mode drivers that implement DRM, but actually there is only a handful of places in this module where DRM support is assumed. This made it a good starting point to introduce the KGSL backend and piggy back off the common code.

For example the drm module has a lot of code to deal with the management of synchronization primitives, buffer objects, and command submit lists. All managed at a abstraction above “DRM” and to re-implement this code would be a bad idea.

How to get Android to behave

One of this big struggles with getting the KGSL backend working was figuring out how I could get Android to load mesa instead of Qualcomm blob driver that is shipped with the device image. Thankfully a good chunk of this work has already been figured out when the Turnip developers (Turnip is the open source Vulkan implementation for Adreno GPUs) figured out how to get Turnip running on android with KGSL. Thankfully one of my coworkers Danylo is one of those Turnip developers, and he gave me a lot of guidance on getting Android setup. One thing to watch out for is the outdated instructions here. These instructions almost work, but require some modifications. First if you’re using a more modern version of the Android NDK, the compiler has been replaced with LLVM/Clang, so you need to change which compiler is being used. Second flags like system in the cross compiler script incorrectly set the system as linux instead of android. I had success using the below cross compiler script. Take note that the compiler paths need to be updated to match where you extracted the android NDK on your system.

[binaries]
ar = '/home/lfryzek/Documents/projects/igalia/freedreno/android-ndk-r25b-linux/android-ndk-r25b/toolchains/llvm/prebuilt/linux-x86_64/bin/llvm-ar'
c = ['ccache', '/home/lfryzek/Documents/projects/igalia/freedreno/android-ndk-r25b-linux/android-ndk-r25b/toolchains/llvm/prebuilt/linux-x86_64/bin/aarch64-linux-android29-clang']
cpp = ['ccache', '/home/lfryzek/Documents/projects/igalia/freedreno/android-ndk-r25b-linux/android-ndk-r25b/toolchains/llvm/prebuilt/linux-x86_64/bin/aarch64-linux-android29-clang++', '-fno-exceptions', '-fno-unwind-tables', '-fno-asynchronous-unwind-tables', '-static-libstdc++']
c_ld = 'lld'
cpp_ld = 'lld'
strip = '/home/lfryzek/Documents/projects/igalia/freedreno/android-ndk-r25b-linux/android-ndk-r25b/toolchains/llvm/prebuilt/linux-x86_64/bin/llvm-strip'
# Android doesn't come with a pkg-config, but we need one for Meson to be happy not
# finding all the optional deps it looks for.  Use system pkg-config pointing at a
# directory we get to populate with any .pc files we want to add for Android
pkgconfig = ['env', 'PKG_CONFIG_LIBDIR=/home/lfryzek/Documents/projects/igalia/freedreno/android-ndk-r25b-linux/android-ndk-r25b/pkgconfig:/home/lfryzek/Documents/projects/igalia/freedreno/install-android/lib/pkgconfig', '/usr/bin/pkg-config']

[host_machine]
system = 'android'
cpu_family = 'arm'
cpu = 'armv8'
endian = 'little'

Another thing I had to figure out with Android, that was different with these instructions, was how I would get Android to load mesa versions of mesa libraries. That’s when my colleague Mark pointed out to me that Android is open source and I could just check the source code myself. Sure enough you have find the OpenGL driver loader in Android’s source code. From this code we can that Android will try to load a few different files based on some settings, and in my case it would try to load 3 different shaded libraries in the /vendor/lib64/egl folder, libEGL_adreno.so ,libGLESv1_CM_adreno.so, and libGLESv2.so. I could just replace these libraries with the version built from mesa and voilà, you’re now loading a custom driver! This realization that I could just “read the code” was very powerful in debugging some more android specific issues I ran into, like dealing with gralloc.

Something cool that the opensource Freedreno & Turnip driver developers figured out was getting android to run test OpenGL applications from the adb shell without building android APKs. If you check out the freedreno repo, they have an ndk-build.sh script that can build tests in the tests-* folder. The nice benefit of this is that it provides an easy way to run simple test cases without worrying about the android window system integration. Another nifty feature about this repo is the libwrap tool that lets trace the commands being submitted to the GPU.

What even is Gralloc?

Gralloc is the graphics memory allocated in Android, and the OS will use it to allocate the surface for “windows”. This means that the memory we want to render the display to is managed by gralloc and not our KGSL backend. This means we have to get all the information about this surface from gralloc, and if you look in src/egl/driver/dri2/platform_android.c you will see existing code for handing gralloc. You would think “Hey there is no work for me here then”, but you would be wrong. The handle gralloc provides is hardware specific, and the code in platform_android.c assumes a DRM gralloc implementation. Thankfully the turnip developers had already gone through this struggle and if you look in src/freedreno/vulkan/tu_android.c you can see they have implemented a separate path when a Qualcomm msm implementation of gralloc is detected. I could copy this detection logic and add a separate path to platform_android.c.

Working with the Freedreno community

When working on any project (open-source or otherwise), it’s nice to know that you aren’t working alone. Thankfully the #freedreno channel on irc.oftc.net is very active and full of helpful people to answer any questions you may have. While working on the backend, one area I wasn’t really sure how to address was the synchronization code for buffer objects. The backend exposed a function called cpu_prep, This function was just there to call the DRM implementation of cpu_prep on the buffer object. I wasn’t exactly sure how to implement this functionality with KGSL since it doesn’t use DRM buffer objects.

I ended up reaching out to the IRC channel and Rob Clark on the channel explained to me that he was actually working on moving a lot of the code for cpu_prep into common code so that a non-drm driver (like the KGSL backend I was working on) would just need to implement that operation as NOP (no operation).

Dealing with bugs & reverse engineering the blob

I encountered a few different bugs when implementing the KGSL backend, but most of them consisted of me calling KGSL wrong, or handing synchronization incorrectly. Thankfully since Turnip is already running on KGSL, I could just more carefully compare my code to what Turnip is doing and figure out my logical mistake.

Some of the bugs I encountered required the backend interface in Freedreno to be modified to expose per a new per driver implementation of that backend function, instead of just using a common implementation. For example the existing function to map a buffer object into userspace assumed that the same fd for the device could be used for the buffer object in the mmap call. This worked fine for any buffer objects we created through KGSL but would not work for buffer objects created from gralloc (remember the above section on surface memory for windows comming from gralloc). To resolve this issue I exposed a new per backend implementation of “map” where I could take a different path if the buffer object came from gralloc.

While testing the KGSL backend I did encounter a new bug that seems to effect both my new KGSL backend and the Turnip KGSL backend. The bug is an iommu fault that occurs when the surface allocated by gralloc does not have a height that is aligned to 4. The blitting engine on a6xx GPUs copies in 16x4 chunks, so if the height is not aligned by 4 the GPU will try to write to pixels that exists outside the allocated memory. This issue only happens with KGSL backends since we import memory from gralloc, and gralloc allocates exactly enough memory for the surface, with no alignment on the height. If running on any other platform, the fdl (Freedreno Layout) code would be called to compute the minimum required size for a surface which would take into account the alignment requirement for the height. The blob driver Qualcomm didn’t seem to have this problem, even though its getting the exact same buffer from gralloc. So it must be doing something different to handle the none aligned height.

Because this issue relied on gralloc, the application needed to running as an Android APK to get a surface from gralloc. The best way to fix this issue would be to figure out what the blob driver is doing and try to replicate this behavior in Freedreno (assuming it isn’t doing something silly like switch to sysmem rendering). Unfortunately it didn’t look like the libwrap library worked to trace an APK.

The libwrap library relied on a linux feature known as LD_PRELOAD to load libwrap.so when the application starts and replace the system functions like open and ioctl with their own implementation that traces what is being submitted to the KGSL kernel mode driver. Thankfully android exposes this LD_PRELOAD mechanism through its “wrap” interface where you create a propety called wrap.<app-name> with a value LD_PRELOAD=<path to libwrap.so>. Android will then load your library like would be done in a normal linux shell. If you tried to do this with libwrap though you find very quickly that you would get corrupted traces. When android launches your APK, it doesn’t only launch your application, there are different threads for different android system related functions and some of them can also use OpenGL. The libwrap library is not designed to handle multiple threads using KGSL at the same time. After discovering this issue I created a MR that would store the tracing file handles as TLS (thread local storage) preventing the clobbering of the trace file, and also allowing you to view the traces generated by different threads separately from each other.

With this is in hand one could begin investing what the blob driver is doing to handle this unaligned surfaces.

What’s next?

Well the next obvious thing to fix is the aligned height issue which is still open. I’ve also worked on upstreaming my changes with this WIP MR.

SuperTuxKart Vulkan vs OpenGL

The latest SuperTuxKart release comes with an experimental Vulkan renderer and I was eager to check it out on my Raspbery Pi 4 and see how well it worked.

The short story is that while I have only tested a few tracks it seems to perform really well overall. In my tests, even with a debug build of Mesa I saw the FPS ranging from 60 to 110 depending on the track. I think the game might be able to produce more than 110 fps actually, since various tracks were able to reach exactly 110 fps I think the limiting factor here was the display.

I was then naturally interested in comparing this to the GL renderer and I was a bit surprised to see that, with the same settings, the GL renderer would be somewhere in the 8-20 fps range for the same tracks. The game was clearly hitting a very bad path in the GL driver so I had to fix that before I could make a fair comparison between both.

A perf session quickly pointed me to the issue: Mesa has code to transparently translate vertex attribute formats that are not natively supported to a supported format. While this is great for compatibility it is obviously going to be very slow. In particular, SuperTuxKart uses rgba16f and rg16f with some vertex buffers and Mesa was silently translating these to 32-bit counterparts because the GL driver was not advertising support for the 16-bit variants. The hardware does support 16-bit floating point vertex attributes though, so this was very easy to fix.

The Vulkan driver was exposing support for this already, which explains the dramatic difference in performance between both drivers. Indeed, with that change SuperTuxKart now plays smooth on OpenGL too, with framerates always above 30 fps and up to 110 fps depending on the track. We should probably have an option in Mesa to make this kind of under-the-hood compatibility translations more obvious to users so we can catch silly issues like this more easily.

With that said, even if GL is now a lot better, Vulkan is still ahead by quite a lot, producing 35-50% better framerate than OpenGL depending on the track, at least for the tracks that don’t hit the 110 fps mark, which as I said above, looks like it is a display maximum, at least with my setup.

Zink

During my presentation at XDC last year I mentioned Zink wasn’t supported on Raspberry Pi 4 any more due to feature requirements we could not fulfill.

In the past, Zink used to abort when it detected unsupported features, but it seems this policy has been changed and now it simply drops a warning and points to the possibility of incorrect rendering as a result.

Also, I have been talking to zmike about one of the features we could not support natively: scalarBlockLayout. Particularly, the issue with this is that we can’t make it work with vectors in all cases and the only alternative for us would be to scalarize everything through a lowering, which would probably have a performance impact. However, zmike confirmed that Zink is already doing this, so in practice we would not see vector load/stores from Zink, in which case it should work fine .

So with all that in mind, I did give Zink a go and indeed, I get the warning that we don’t support scalar block layouts (and some other feature I don’t remember now) but otherwise it mostly works. It is not as stable as the native driver and some things that work with the native driver don’t work with Zink at present, some examples I saw include the WebGL Aquarium demo in Chromium or SuperTuxKart.

As far as performance goes, it has been a huge leap from when I tested it maybe 2 years ago. With VkQuake3‘s OpenGL renderer performance with Zink used to be ~40% of the native OpenGL driver, but is now on par with it, even if not a tiny bit better, so kudos to zmike and all the other contributors to Zink for all the work they put into this over the last 2 years, it really shows.

With all that said, I didn’t do too much testing with Zink myself so if anyone here decides to give it a more thorough go, please let me know how it went in the comments.

I tend to keep quite a lot of notes on the development related (sometimes at work, sometimes not) I do on a week-by-week basis, and thought it might be fun to write up the parts that were public. This may or may not be of wider interest, but it aims to be a useful aide-mémoire for my purposes at least. Weeks with few entries might be due to focusing on downstream work (or perhaps just a less productive week - I am only human!).

Week of 13th March 2023

• Most importantly, added some more footer images for this site from the Quick Draw dataset. Thanks to my son (Archie, 5) for the assistance.
• Reviewed submissions for EuroLLVM (I'm on the program committee).
• Added note to the commercially available RISC-V silicon post about a hardware bug in the Renesas RZ/Five.
• Finished writing and published what's new for RISC-V in LLVM 16 article and took part in some of the discussions in the HN and Reddit threads (it's on lobste.rs too, but that didn't generate any comments).
• Investigated an issue where inline asm with the m constraint was generating worse code on LLVM vs GCC, finding that LLVM conservatively lowers this to a single register, while GCC treats m as reg+imm, relying on users indicating A when using a memory operand with an instruction that can't take an immediate offset. Worked with a colleague who posted D146245 to fix this.
• Set agenda for and ran the biweekly RISC-V LLVM contributor sync call as usual.
• Bisected reported LLVM bug #61412, which as it happens was fixed that evening by D145474 being committed. We hope to backport this to 16.0.1.
• Did some digging on a regression (compiler crash) for -Oz, bisecting it to the commit that enabled machine copy propagation by default. I found the issue was due to machine copy propagation running after the machine outliner, and incorrectly determining that some register writes in outlined functions were not live-out. I posted and landed D146037 to fix this by running machine copy propagation earlier in the pipeline, though a more principled fix would be desirable.
• Filed a PR against the riscv-isa-manual to disambiguate the use of the term "reserved" for HINT instructions. I've also been looking at the proposed bfloat16 extension recently and filed an issue to clarify if Zfbfinxmin will be defined (as all the other floating point extensions so far have an *inx twin.
• Almost finished work to resolve issues related to overzealous error checking on RISC-V ISA naming strings (with llvm-objdump and related tools being the final piece).
  • Landed D145879 and D145882 to expand RISCVISAInfo test coverage and fix an issue that surfaced through that.
  • Posted a pair of patches that makes llvm-objdump and related tools tolerant of unrecognised versions of ISA extensions. D146070 resolves this for the base ISA in a minimally invasive way, while D146114 solves this for other extensions, moving the parsing logic to using the parseNormalizedArchString function I introduced to fix a similar issue in LLD. This built on some directly committed work to expand testing.
• The usual assortment of upstream LLVM reviews.
• LLVM Weekly #480.

Week of 6th March 2023

• Had a really useful meeting with a breakout group from the RISC-V LLVM sync-up calls about the long-standing issues related to ISA extension versioning, error handling for this, and other related issues.
  • Related to this, posted D145879 and D145882 to flesh out testing of RISCVISAInfo::parseArchString ahead of further improvements, and to start to fix identified issues.
• Incorporated more clarifications submitted to me about the commercially available RISC-V SoCs post, particularly around SiFive cores.
• Shared some thoughts on attracting more people to the LLVM Foundation strategic planning sessions.
• Posted and committed an LLVM patch to migrate the RISC-V backend to using shared MCELFStreamer code for attribute emission. The initial implementation was largely derived from Arm's version of the same feature but a later refactoring managed to move this logic to common code, which we can now reuse.
• Some small tasks related to the RISC-V LLVM build-bot: trying to find a path forwards for a simple patch to enable RISC-V support in libcxx, and clarifying how often the staging buildmaster configuration is updated.
• Posted a docs patch to clarify Clang's -fexceptions in follow-up to discussion in issue 61216.
• Did some final preparations for the LLVM 16.0.0 release - committing some cleaned up release notes.
• A variety of upstream LLVM reviews, and left some thoughts on using sub-modules for RVV intrinsics tests.
• LLVM Weekly #479.

Week of 27th February 2023

• Completed (to the point I was happy to publish at least) my attempt to enumerate the commercially available RISC-V SoCs. I'm very grateful to have received a whole range of suggested additions and clarifications over the weekend, which have all been incorporated.
• Ran the usual biweekly RISC-V LLVM sync-up call. Topics included outstanding issues for LLVM 16.x (no major issues now my backport request to fix and LLD regression was merged), an overview off _Float16 ABI lowering fixes, GP relaxation in LLD, my recent RISC-V buildbot, and some vectorisation related issues.
• Investigated and largely resolved a issues related to ABI lowering of _Float16 for RISC-V. Primarily, we weren't handling the cases where a GPR+FPR or a pair of FPRs are used to pass small structs including _Float16.
  • Part of this work involved rebasing my previous patches to refactor our RISC-V ABI lowering tests in Clang. Now that a version of my improvements to update_cc_test_check.py --function-signature (required for the refactor) landed as part of D144963, this can hopefully be completed.
  • Committed a number of simple test improvements related to half floats. e.g. 570995e, 81979c3, 34b412d.
  • Posted D145070 to add proper coverage for _Float16 ABI lowering, and D145074 to fix it. Also D145071 to set the HasLegalHalfType property, but the semantics of that are less clear.
  • Posted a strawman psABI patch for __bf16, needed for the RISC-V bfloat16 extension.
• Attended the Cambridge RISC-V Meetup.
• After seeing the Helix editor discussed on lobste.rs, retried my previously shared large Markdown file test case. Unfortunately it's still unusably slow to edit, seemingly due to a tree-sitter related issue.
• Cleaned up the static site generator used for this site a bit. e.g. now my fixes (#157, #158, #159) for the traverse() helper in mistletoe where merged upstream, I removed my downstream version.
• The usual mix of upstream LLVM reviews.
• Had a day off for my birthday.
• Publicly shared this week log for the first time.
• LLVM Weekly #478.

Week of 20th February 2023

• Iterated on D144353 (aiming to fix LLD regression related to merging RISC-V attributes) based on review feedback and committed it.
  • Created an issue to track this as a regression, aiming for a backport into 16.0.0, and requested that backport.
  • Also some related discussion in ClangBuiltLinux issues #1777 and #1808.
• Committed my llvm-zorg patch to add the qemu-user based RISC-V builder, after finalising provisioning the machine to run it. The builder is live on the LLVM staging buildmaster as clang-rv64gc-qemu-user-single-stage.
  • Worked to resolve remaining test failures and stability issues. One recurrent issue was an assert in ___pthread_mutex_lock when executing ccache. Setting inode_cache=false in the local ccache config seems to avoid this.
  • Posted a couple of patches - D144464 and D144465 to tweak the LLVM docs on setting up a builder, based on my experience doing so.
• Chased for reviews and clarification about pre-commit test requirements for my libcxx RISC-V test fix patch, D134158.
• Committed a couple of further test updates for Wasm in LLVM ahead of some upcoming patches. 771261f 1ae8597.
• Left some quick notes on the LLVM RFC shepherds proposal.
• A variety of upstream LLVM reviews, and received a useful clarification on the RISC-V psABI and the ratification lifecycle.
• LLVM Weekly #477.

Week of 13th February 2023

• After a fair bit of investigation and thinking about reported compatibility issues between GNU and LLVM tools (particularly binutils ld and lld) due to RISC-V extension versioning, posted an RFC outlining the major issues and a proposed fix for what I consider to be a regression in lld.
  • Landed a few LLVM patches cleaning up tests related to this. 8b50048 574d0c2, d05e1e9.
  • Posted D144353, a proposed fix for the LLD regression due to overzealous checking of extensions/versions when merging RISC-V attributes.
• Organised agenda for and ran the bi-weekly RISC-V LLVM contributor call. Key discussion items were the extension versioning related compatibility issue mentioned below and support for emulated TLS (where I'd left some comments the previous week).
• Updated my patch (D143172) to register and configure a RISC-V qemu-user based builder with LLVM's staging buildmaster, based on review feedback.
• A variety of upstream LLVM reviews. Also landed D143407, marking Zawrs as non-experimental.
• LLVM Weekly #476.

Week of 6th February 2023

• Left feedback on the proposed RISC-V psABI patch clarifying treatment of empty structs or unions in the FP calling convention. This is a follow-up to the issue I filed on this issue (where I have D142327 queued up for LLVM to fix our incorrect handling).
• Responded to a question on LLVM's Discourse about zicsr and zifencei support in LLVM. As noted, the issue is that we haven't moved RV32I/RV64I 2.1 yet which split out Zicsr and Zifencei. Unfortunately this is a backwards-incompatible change so requires some care.
• Worked with a colleague trying to reproduce an assertion failure in his committed patch adding support for WebAssembly externref in Clang that appeared only on an MSan buildbot. The sanitizers project guidance is useful for this, but I ended up rolling a slightly hacky script as I stepped through each part of the multi-stage build and test sequence.
• Left my thoughts on a proposed RISC-V preprocessor define to specify support and for and performance of misaligned loads/stores. I like the idea of the define, but prefer sticking to the Zicclsm terminology introduced in the RISC-V profiles.
• Posted patch D143507 to mark RISC-V Zawrs as non-experimental, after confirming there were no relevant changes between the implemented 1.0-rc3 spec and the ratified version.
• A series of WebAssembly GC type related patches remains a work in progress downstream, but I landed a couple of related minor test cleanups. 604c9a0, 3a80dc2.
• Many upstream RISC-V LLVM reviews.
• LLVM Weekly #475.

• 2023-03-20: Added notes for the week of 13th March 2023.
• 2023-03-13: Added notes for the week of 6th March 2023.
• 2023-03-06: Added notes for the week of 27th February 2023.
• 2023-02-27: Added in a forgotten note about trivial buildbot doc improvements.
• 2023-02-27: Initial publication date.

I’ve heard it said there are two kinds of tech power users: the ones who constantly update to stay on the bleeding edge, and the ones who update only when absolutely forced to do so.  I’m in the latter camp.  If a program, setup, or piece of hardware works for me, I stick by it like it’s the last raft off a sinking island.

And so it has been for my early 2013 MacBook Pro, which has served me incredibly well across all those years and many continents, but was sliding into the software update chasm: some applications, and for that matter its operating system, could no longer be run on its hardware.  Oh and also, the top row of letter keys was becoming unresponsive, in particular the E-R-T sequence.  Which I kind of need if I’m going to be writing English text, never mind reloading pages and opening new browser tabs.

Stepping Up

So on Monday, I dropped by the Apple Store and picked up a custom-built early 2023 MacBook Pro: M2 Max with 38 GPU cores, 64GB RAM, and 2TB SSD.  (Thus quadrupling the active memory and nearly trebling the storage capacity of its predecessor.)  I went with that balance, or perhaps imbalance, because I intend to have this machine last me another ten years, and in that time, RAM is more likely to be in demand than SSD.  If I’m wrong about that, I can always plug in an external SSD.  Many thanks to the many people in my Mastodon herd who nudged me in that direction.

I chose the 14” model over the 16”, so it is a wee bit smaller than my old 15” workhorse.  The thing that surprises me is the new machine looks boxier, somehow.  Probably it’s that the corners of the case are not nearly as rounded as the 2013 model, and I think the thickness ratio of display to body is closer to 1:1 than before.  It isn’t a problem or anything, it’s just a thing that I notice.  I’ll probably forget about it soon enough.

Some things I find mildly-to-moderately annoying:

• DragThing doesn’t work any more.  It had stopped being updated before the 64-bit revolution, never mind the shift to Apple silicon, so this was expected, but wow do I miss it.  Like a stick-shift driver uselessly stomping the floorboards and blindly grasping air while driving an automatic car, I still flip the mouse pointer toward the right edge of the screen, where I kept my DragThing dock, before remembering it’s gone.  I’ve looked at alternatives, but none of them seem like they’re meant as straight up replacements, so I’ve yet to commit to one.  Maybe some day I’ll ask Daniel to teach me Swift to I can build my own. (Because I definitely need more demands on my time.)
• The twisty arrows in the Finder to open and close folders don’t have enough visual weight.  Really, the overall UI feels like a movie’s toy representation of an operating system, not an actual operating system.  I mean, the visual presentation of the OS looks like something I would create, and brother, that is not a compliment.
• The Finder’s menu bar has no visually distinct background.  What the hell.  No, seriously, what the hell?  The Notch I’m actually okay with, but removing the distinction between the active area of the menu bar and the inert rest of the desktop seems… ill-advised.  Do not like.  HARK, A FIX: Cory Birdsong pointed me to “System Settings… > Accessibility > Display > Reduce Transparency”, which fixes this, over on Mastodon.  Thanks, Cory!
• I’m not used to the system default font(s) yet, which I imagine will come with time, but still catches me here and there.
• The alert and other systems sounds are different, and I don’t like them.  Sosumi.

Oh, and it’s weird to me that the Apple logo on the back of the display doesn’t glow.  Not annoying, just weird.

Otherwise, I’m happy with it so far.  Great display, great battery life, and the keyboard works!

Getting Migratory

The 2013 MBP was backed up nightly to a 1TB Samsung SSD, so that was how I managed the migration: plugged the SSD into the new MBP and let Migration Assistant do its thing.  This got me 90% of the way there, really.  The remaining 10% is what I’ll talk about in a bit, in case anyone else finds themselves in a similar situation.

The only major hardware hurdle I hit was that my Dell U2713HM monitor, also of mid-2010s vintage, seems to limit HDMI signals to 1920×1080 despite supposedly supporting HDMI 1.4, which caught me by surprise.  When connected to a machine via DisplayPort, even my 2013 MBP, the Dell will go up to 2560×1440.  The new MBP only has one HDMI port and three USB-C ports.  Fortunately, the USB-C ports can be used as DisplayPorts, so I acquired a DisplayPort–to–USB-C cable and that fixed the situation right up.

Yes, I could upgrade to a monitor that supports USB-C directly, but the Dell is a good size for my work environment, it still looks pretty good, and did I mention I’m the cling-tightly-to-what-works kind of user?

Otherwise, in the hardware space, I’ll have to figure out how I want to manage connecting all the USB-A devices I have (podcasting microphone, wireless headset, desktop speaker, secondary HD camera, etc., etc.) to the USB-C ports.  I expected that to be the case, just as I expected some applications would no longer work.  I expect an adapter cable or two will be necessary, at least for a while.

Trouble Brewing

I said earlier that Migration Assistant got me 90% of the way to being switched over.  Were I someone who doesn’t install stuff via the Terminal, I suspect it would have been 100% successful, but I’m not, so it wasn’t.  As with the cables, I anticipated this would happen.  What I didn’t expect was that covering that last 10% would take me only an hour or so of actual work, most of it spent waiting on downloads and installs.

First, the serious and quite unexpected problem: my version of Homebrew used an old installation prefix, one that could break newer packages.  So, I needed to migrate Homebrew itself from /usr/local to /opt/homebrew.  Some searching around indicated that the best way to do this was uninstall Homebrew entirely, then install it fresh.

Okay, except that would also remove everything I’d installed with Homebrew.  Which was maybe not as much as some of y’all, but it was still a fair number of fairly essential packages.  When I ran brew list, I got over a hundred packages, of which most were dependencies.  What I found through further searching was that brew leaves returns a list of the packages I’d installed, without their dependencies.  Here’s what I got:

automake
bash
bison
chruby
ckan
cmake
composer
ffmpeg
gh
git
git-lfs
httpd
imagemagick
libksba
lynx
minetest
minimal-racket
pandoc
php
php@7.2
python@3.10
ruby
ruby-install
wget
yarn

That felt a lot more manageable.  After a bit more research, boiled down to its essentials, the New Brew Shuffle I came up with was:

$ brew leaves > brewlist.txt

$ /bin/bash -c "$(curl -fsSL https://raw.githubusercontent.com/Homebrew/install/HEAD/uninstall.sh)"

$ xcode-select --install

$ /bin/bash -c "$(curl -fsSL https://raw.githubusercontent.com/Homebrew/install/HEAD/install.sh)"

$ xargs brew install < brewlist.txt

The above does elide a few things.  In step two, the Homebrew uninstall script identified a bunch of directories that it couldn’t remove, and would have to be deleted manually.  I saved all that to a text file (thanks to Warp’s “Copy output” feature) for later study, and pressed onward.  I probably also had to sudo some of those steps; I no longer remember.

In addition to all the above, I elected to delete a few of the packages in brewlist.txt before I fed it back to brew install in the last step — things like ckan, left over from my Kerbal Space Program days  —  and to remove the version dependencies for PHP and Python.  Overall, the process was pretty smooth.  I just had to sit there and watch Homrebrew chew through all the installs, including all the dependencies.

Cleanup

Once all the reinstalls from the last step had finished, I was left with a few things to clean up.  For example, Python didn’t seem to have installed.  Eventually I realized it had actually installed as python3 instead of just plain python, so that was mostly fine and I’m sure there’s a way to alias one to the other that I might get around to looking up one day.

Ruby also didn’t seem to reinstall cleanly: there was a library it was looking for that complained about the chip architecture, and attempts to overcome that spawned even more errors, and none of them were decipherable to me or my searches.  Multiple attempts at uninstalling and then reinstalling Ruby through a variety of means, some with Homebrew, some other ways, either got me the same indecipherable erros or a whole new set of indecipherable errors.  In the end, I just uninstalled Ruby, as I don’t actually use it for anything I’m aware of, and the default Ruby that comes with macOS is still there.  If I run into some script I need for work that requires something more, I’ll revisit this, probably with many muttered imprecations.

Finally, httpd wasn’t working as intended.  I could launch it with brew services httpd start, but the resulting server was pointing to a page that just said “It works!”, and not bringing up any of my local hosts.  Eventually, I found where Homebrew had stuffed httpd and its various files, and then replaced its configuration files with my old configuration files.  Then I went through the cycle of typing sudo apachectl start, addressing the errors it threw over directories or PHP installs or whatever by editing httpd.conf, and then trying again.

After only three or four rounds of that, everything was up and running as intended  —  and as a bonus, I was able to mark httpd as a Login item in the Finder’s System Settings, so it will automatically come back up whenever I reboot!  Which my old machine wouldn’t do, for some reason I never got around to figuring out.

Now I just need to decide what to call this thing.  The old MBP was “CoCo”, as in the TRS-80 Color Computer, meant as a wry commentary on the feel of the keyboard and a callback to the first home computer I ever used.  That joke still works, but I’m thinking the new machine will be “C64” in honor of the first actually powerful home computer I ever used and its 64 kilobytes of RAM.  There’s a pleasing echo between that and the 64 gigabytes of RAM I now have at my literal fingertips, four decades later.

Now that I’m up to date on hardware and operating system, I’d be interested to hear what y’all recommend for good quality-of-life improvement applications or configuration changes.  Link me up!

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

First of all, you should go on the gobject-introspection website and read the page on how to write bindable API. What I’m going to write here is going to build upon what’s already documented, or will update the best practices, so if you maintain a GObject/C library, or you’re writing one, you must be familiar with the basics of gobject-introspection. It’s 2023: it’s already too bad we’re still writing C libraries, we should at the very least be responsible about it.

A specific note for people maintaining an existing GObject/C library with an API designed before the mainstream establishment of gobject-introspection (basically, anything written prior to 2011): you should really consider writing all new types and entry points with gobject-introspection in mind, and you should also consider phasing out older API and replacing it piecemeal with a bindable one. You should have done this 10 years ago, and I can already hear the objections, but: too bad. Just because you made an effort 10 years ago it doesn’t mean things are frozen in time, and you don’t get to fix things. Maintenance means constantly tending to your code, and that doubly applies if you’re exposing an API to other people.

Let’s take the “how to write bindable API” recommendations, and elaborate them a bit.

Structures with custom memory management

The recommendation is to use GBoxed as a way to specify a copy and a free function, in order to clearly define the memory management semantics of a type.

The important caveat is that boxed types are necessary for:

• opaque types that can only be heap allocated
• using a type as a GObject property
• using a type as an argument or return value for a GObject signal

You don’t need a boxed type for the following cases:

• your type is an argument or return value for a method, function, or virtual function
• your type can be placed on the stack, or can be allocated with malloc()/free()

Additionally, starting with gobject-introspection 1.76, you can specify the copy and free function of a type without necessarily registering a boxed type, which leaves boxed types for the thing they were created: signals and properties.

Addendum: object types

Boxed types should only ever be used for plain old data types; if you need inheritance, then the strong recommendation is to use GObject. You can use GTypeInstance, but only if you know what you’re doing; for more information on that, see my old blog post about typed instances.

Functionality only accessible through a C macro

This ought to be fairly uncontroversial. C pre-processor symbols don’t exist at the ABI level, and gobject-introspection is a mechanism to describe a C ABI. Never, ever expose API only through C macros; those are for C developers. C macros can be used to create convenience wrappers, but remember that anything they call must be public API, and that other people will need to re-implement the convenience wrappers themselves, so don’t overdo it. C developers deserve some convenience, but not at the expense of everyone else.

Addendum: inline functions

Static inline functions are also not part of the introspectable ABI of a library, because they cannot be used with dlsym(); you can provide inlined functions for performance reasons, but remember to always provide their non-inlined equivalent.

Direct C structure access for objects

Again, another fairly uncontroversial rule. You shouldn’t be putting anything into an instance structure, as it makes your API harder to future-proof, and direct access cannot do things like change notification, or memoization.

Always provide accessor functions.

va_list

Variadic argument functions are mainly C convenience. Yes, some languages can support them, but it’s a bad idea to have this kind of API exposed as the only way to do things.

Any variadic argument function should have two additional variants:

• a vector based version, using C arrays (zero terminated, or with an explicit length)
• a va_list version, to be used when creating wrappers with variadic arguments themselves

The va_list variant is kind of optional, since not many people go around writing variadic argument C wrappers, these days, but at the end of the day you might be going to write an internal function that takes a va_list anyway, so it’s not particularly strange to expose it as part of your public API.

The vector-based variant, on the other hand, is fundamental.

Incidentally, if you’re using variadic arguments as a way to collect similarly typed values, e.g.:

// void
// some_object_method (SomeObject *self,
//                     ...) G_GNUC_NULL_TERMINATED

some_object_method (obj, "foo", "bar", "baz", NULL);

there’s very little difference to using a vector and C99’s compound literals:

// void
// some_object_method (SomeObject *self,
//                     const char *args[])

some_object_method (obj, (const char *[]) {
                      "foo",
                      "bar",
                      "baz",
                      NULL,
                    });

Except that now the compiler will be able to do some basic type check and scream at you if you’re doing something egregiously bad.

Compound literals and designated initialisers also help when dealing with key/value pairs:

typedef struct {
  int column;
  union {
    const char *v_str;
    int v_int;
  } value;
} ColumnValue;

enum {
  COLUMN_NAME,
  COLUMN_AGE,
  N_COLUMNS
};

// void
// some_object_method (SomeObject *self,
//                     size_t n_columns,
//                     const ColumnValue values[])

some_object_method (obj, 2,
  (ColumnValue []) {
    { .column = COLUMN_NAME, .data = { .v_str = "Emmanuele" } },
    { .column = COLUMN_AGE, .data = { .v_int = 42 } },
  });

So you should seriously reconsider the amount of variadic arguments convenience functions you expose.

Multiple out parameters

Using a structured type with a out direction is a good recommendation as a way to both limit the amount of out arguments and provide some future-proofing for your API. It’s easy to expand an opaque pointer type with accessors, whereas adding more out arguments requires an ABI break.

Addendum: inout arguments

Don’t use in-out arguments. Just don’t.

Pass an in argument to the callable for its input, and take an out argument or a return value for the output.

Memory management and ownership of inout arguments is incredibly hard to capture with static annotations; it mainly works for scalar values, so:

void
some_object_update_matrix (SomeObject *self,
                           double *xx,
                           double *yy,
                           double *xy,
                           double *yx)

can work with xx, yy, xy, yx as inout arguments, because there’s no ownership transfer; but as soon as you start throwing things in like pointers to structures, or vectors of string, you open yourself to questions like:

• who allocates the argument when it goes in?
• who is responsible for freeing the argument when it comes out?
• what happens if the function frees the argument in the in direction and then re-allocates the out?
• what happens if the function uses a different allocator than the one used by the caller?
• what happens if the function has to allocate more memory?
• what happens if the function modifies the argument and frees memory?

Even if gobject-introspection nailed down the rules, they could not be enforced, or validated, and could lead to leaks or, worse, crashes.

So, once again: don’t use inout arguments. If your API already exposes inout arguments, especially for non-scalar types, consider deprecations and adding new entry points.

Addendum: GValue

Sadly, GValue is one of the most notable cases of inout abuse. The oldest parts of the GNOME stack use GValue in a way that requires inout annotations because they expect the caller to:

• initialise a GValue with the desired type
• pass the address of the value
• let the function fill the value

The caller is then left with calling g_value_unset() in order to free the resources associated with a GValue. This means that you’re passing an initialised value to a callable, the callable will do something to it (which may or may not even entail re-allocating the value) and then you’re going to get it back at the same address.

It would be a lot easier if the API left the job of initialising the GValue to the callee; then functions could annotate the GValue argument with out and caller-allocates=1. This would leave the ownership to the caller, and remove a whole lot of uncertainty.

Various new (comparatively speaking) API allow the caller to pass an unitialised GValue, and will leave initialisation to the callee, which is how it should be, but this kind of change isn’t always possible in a backward compatible way.

Arrays

You can use three types of C arrays in your API:

• zero-terminated arrays, which are the easiest to use, especially for pointers and strings
• fixed-size arrays
• arrays with length arguments

Addendum: strings and byte arrays

A const char* argument for C strings with a length argument is not an array:

/**
 * some_object_load_data:
 * @self: ...
 * @str: the data to load
 * @len: length of @str in bytes, or -1
 *
 * ...
 */
void
some_object_load_data (SomeObject *self,
                       const char *str,
                       ssize_t len)

Never annotate the str argument with array length=len. Ideally, this kind of function should not exist in the first place. You should always use const char* for NUL-terminated strings, possibly UTF-8 encoded; if you allow embedded NUL characters then use a bytes array:

/**
 * some_object_load_data:
 * @self: ...
 * @data: (array length=len) (element-type uint8): the data to load
 * @len: the length of the data in bytes
 *
 * ...
 */
void
some_object_load_data (SomeObject *self,
                       const unsigned char *data,
                       size_t len)

Instead of unsigned char you can also use uint8_t, just to drive the point home.

Yes, it’s slightly nicer to have a single entry point for strings and byte arrays, but that’s just a C convenience: decent languages will have a proper string type, which always comes with a length; and string types are not binary data.

Addendum: GArray, GPtrArray, GByteArray

Whatever you do, however low you feel on the day, whatever particular tragedy befell your family at some point, please: never use GLib array types in your API. Nothing good will ever come of it, and you’ll just spend your days regretting this choice.

Yes: gobject-introspection transparently converts between GLib array types and C types, to the point of allowing you to annotate the contents of the array. The problem is that that information is static, and only exists at the introspection level. There’s nothing that prevents you from putting other random data into a GPtrArray, as long as it’s pointer-sized. There’s nothing that prevents a version of a library from saying that you own the data inside a GArray, and have the next version assign a clear function to the array to avoid leaking it all over the place on error conditions, or when using g_autoptr.

Adding support for GLib array types in the introspection was a well-intentioned mistake that worked in very specific cases—for instance, in a library that is private to an application. Any well-behaved, well-designed general purpose library should not expose this kind of API to its consumers.

You should use GArray, GPtrArray, and GByteArray internally; they are good types, and remove a lot of the pain of dealing with C arrays. Those types should never be exposed at the API boundary: always convert them to C arrays, or wrap them into your own data types, with proper argument validation and ownership rules.

Addendum: GHashTable

What’s worse than a type that contains data with unclear ownership rules decided at run time? A type that contains twice the amount of data with unclear ownership rules decided at run time.

Just like the GLib array types, hash tables should be used but never directly exposed to consumers of an API.

Addendum: GList, GSList, GQueue

See above, re: pain and misery. On top of that, linked lists are a terrible data type that people should rarely, if ever, use in the first place.

Callbacks

Your callbacks should always be in the form of a simple callable with a data argument:

typedef void (* SomeCallback) (SomeObject *obj,
                               gpointer data);

Any function that takes a callback should also take a “user data” argument that will be passed as is to the callback:

// scope: call; the callback data is valid until the
// function returns
void
some_object_do_stuff_immediately (SomeObject *self,
                                  SomeCallback callback,
                                  gpointer data);

// scope: notify; the callback data is valid until the
// notify function gets called
void
some_object_do_stuff_with_a_delay (SomeObject *self,
                                   SomeCallback callback,
                                   gpointer data,
                                   GDestroyNotify notify);

// scope: async; the callback data is valid until the async
// callback is called
void
some_object_do_stuff_but_async (SomeObject *self,
                                GCancellable *cancellable,
                                GAsyncReadyCallback callback,
                                gpointer data);

// not pictured here: scope forever; the data is valid fori
// the entirety of the process lifetime

If your function takes more than one callback argument, you should make sure that it also takes a different user data for each callback, and that the lifetime of the callbacks are well defined. The alternative is to use GClosure instead of a simple C function pointer—but that comes at a cost of GValue marshalling, so the recommendation is to stick with one callback per function.

Addendum: the closure annotation

It seems that many people are unclear about the closure annotation.

Whenever you’re describing a function that takes a callback, you should always annotate the callback argument with the argument that contains the user data using the (closure argument) annotation, e.g.

/**
 * some_object_do_stuff_immediately:
 * @self: ...
 * @callback: (scope call) (closure data): the callback
 * @data: the data to be passed to the @callback
 *
 * ...
 */

You should not annotate the data argument with a unary (closure).

The unary (closure) is meant to be used when annotating the callback type:

/**
 * SomeCallback:
 * @self: ...
 * @data: (closure): ...
 *
 * ...
 */
typedef void (* SomeCallback) (SomeObject *self,
                               gpointer data);

Yes, it’s confusing, I know.

Sadly, the introspection parser isn’t very clear about this, but in the future it will emit a warning if it finds a unary closure on anything that isn’t a callback type.

Ideally, you don’t really need to annotate anything when you call your argument user_data, but it does not hurt to be explicit.

A cleaned up version of this blog post will go up on the gobject-introspection website, and we should really have a proper set of best API design practices on the Developer Documentation website by now; nevertheless, I do hope people will actually follow these recommendations at some point, and that they will be prepared for new recommendations in the future. Only dead and unmaintained projects don’t change, after all, and I expect the GNOME stack to last a bit longer than the 25 years it already spans today.

Some time ago we at Igalia embarked on the journey to ship a GStreamer-powered WebRTC backend. This is a long journey, it is not over, but we made some progress. This post is the first of a series providing some insights of the challenges we are facing and the plans for the next release cycle(s).

Most web-engines nowadays bundle a version of LibWebRTC, it is indeed a pragmatic approach. WebRTC is a huge spec, spanning across many protocols, RFCs and codecs. LibWebRTC is in fact a multimedia framework on its own, and it’s a very big code-base. I still remember the suprised face of Emilio at the 2022 WebEngines conference when I told him we had unusual plans regarding WebRTC support in GStreamer WebKit ports. There are several reasons for this plan, explained in the WPE FAQ. We worked on a LibWebRTC backend for the WebKit GStreamer ports, my colleague Thibault Saunier blogged about it but unfortunately this backend has remained disabled by default and not shipped in the tarballs, for the reasons explained in the WPE FAQ.

The GStreamer project nowadays provides a library and a plugin allowing applications to interact with third-party WebRTC actors. This is in my opinion a paradigm shift, because it enables new ways of interoperability between the so-called Web and traditional native applications. Since the GstWebRTC announcement back in late 2017 I’ve been experimenting with the idea of shipping an alternative to LibWebRTC in WebKitGTK and WPE. The initial GstWebRTC WebKit backend was merged upstream on March 18, 2022.

As you might already know, before any audio/video call, your browser might ask permission to access your webcam/microphone and even during the call you can now share your screen. From the WebKitGTK/WPE perspective the procedure is the same of course. Let’s dive in.

WebCam/Microphone capture

Back in 2018 for the LibWebRTC backend, Thibault added support for GStreamer-powered media capture to WebKit, meaning that capture devices such as microphones and webcams would be accessible from WebKit applications using the getUserMedia spec. Under the hood, a GStreamer source element is created, using the GstDevice API. This implementation is now re-used for the GstWebRTC backend, it works fine, still has room for improvements but that’s a topic for a follow-up post.

A MediaStream can be rendered in a <audio> or <video> element, through a custom GStreamer source element that we also provide in WebKit, this is all internally wired up so that the following JS code will trigger the WebView in natively capturing and rendering a WebCam device using GStreamer:

<html>
  <head>
    <script>
    navigator.mediaDevices.getUserMedia({video: true, audio: false }).then((mediaStream) => {
        const video = document.querySelector('video');
        video.srcObject = mediaStream;
        video.onloadedmetadata = () => {
            video.play();
        };
    });
    </script>
  </head>
  <body>
    <video/>
  </body>
</html>

When this WebPage is rendered and after the user has granted access to capture devices, the GStreamer backends will create not one, but two pipelines.

flowchart LR
    pipewiresrc-->videoscale-->videoconvert-->videorate-->valve-->appsink

flowchart LR
    subgraph mediastreamsrc
    appsrc-->srcghost[src]
    end
    subgraph playbin3
       subgraph decodebin3
       end
       subgraph webkitglsink
       end
       decodebin3-->webkitglsink
    end
    srcghost-->decodebin3

The first pipeline routes video frames from the capture device using pipewiresrc to an appsink. From the appsink our capturer leveraging the Observer design pattern notifies its observers. In this case there is only one observer which is a GStreamer source element internal to WebKit called mediastreamsrc. The playback pipeline shown above is heavily simplified, in reality more elements are involved, but what matters most is that thanks to the flexibility of Gstreamer, we can leverage the existing MediaPlayer backend that we at Igalia have been maintaining for more than 10 years, to render MediaStreams. All we needed was a custom source element, the rest of our MediaPlayer didn’t need much changes to support this use-case.

One notable change we did since the initial implementation though is that for us a MediaStream can be either raw, encoded or even encapsulated in a RTP payload. So depending on which component is going to render the MediaStream, we have enough flexibility to allow zero-copy, in most scenarios. In the example above, typically the stream will be raw from source to renderer. However, some webcams can provide encoded streams. WPE and WebKitGTK will be able to internally leverage these and in some cases allow for direct streaming from hardware device to outgoing PeerConnection without third-party encoding.

Desktop capture

There is another JS API, allowing to capture from your screen or a window, called getDisplayMedia, and yes, we also support it! Thanks to these recent years ground-breaking progress of the Linux Desktop such as PipeWire and xdg-desktop-portal we can now stream your favorite desktop environment over WebRTC. Under the hood when the WebView is granted access to the desktop capture through the portal, our backend creates a pipewiresrc GStreamer element, configured to source from the file descriptor provided by the portal, and we have a healthy raw video stream.

Here’s a demo:

WebAudio capture

What more, yes you can also create a MediaStream from a WebAudio node. On the backend side, the GStreamerMediaStreamAudioSource fills GstBuffers from the audio bus channels and notifies third-parties internally observing the MediaStream, such as outgoing media sources, or simply an <audio> element that was configured to source from the given MediaStream. I have no demo for this, you’ll have to take my word.

Canvas capture

But wait there is more. Did I hear canvas? Yes we can feed your favorite <canvas> to a MediaStream. The JS API is called captureStream, its code is actually cross-platform but defers to the HTMLCanvasElement::toVideoFrame() method which has a GStreamer implementation. The code is not the most optimal yet though due to shortcomings of our current graphics pipeline implementation. Here is a demo of Canvas to WebRTC running in the WebKitGTK MiniBrowser:

Wrap-up

So we’ve got MediaStream support covered. This is only one part of the puzzle though. We are facing challenges now on the PeerConnection implementation. MediaStreams are cool but it’s even better when you can share them with your friends on the fancy A/V conferencing websites, but we’re not entirely ready for this yet in WebKitGTK and WPE. For this reason, WebRTC is not yet enabled by default in the upcoming WebKitGTK and WPE 2.40 releases. We’re just not there yet. In the next part of these series I’ll tackle the PeerConnection backend on which we’re working hard on these days, both in WebKit and in GStreamer.

Happy hacking and as always, all my gratitude goes to my fellow Igalia comrades for allowing me to keep working on these domains and to Metrological for funding some of this work. Is your organization or company interested in leveraging modern WebRTC APIs from WebKitGTK and/or WPE? If so please get in touch with us in order to help us speed-up the implementation work.

A developer's nightmare: a day dominated by meetings.

Now, this isn't at all what my typical day at Igalia is like... In fact, while it does still happen (out of necessity), it's rare here. And I find that quite amazing when compared to my time at a previous employer. Anyways, because of past experiences at a previous employer, I've always been on this mission to remove or reduce my need to attend meetings, as much as possible. Mainly because I often think I have better things I could be using my time for at the exact day/time of each meeting 😅. It's not really a secret that meetings are expensive. In case it's not clear yet: I don't like to have a lot of meetings! ¹

Aaanyways, this happened to me recently², my day was dominated by a series of meetings. And it got me thinking about how this could be improved. I'm pretty sure that none of the meetings could have been canceled, or that I could have skipped any of them. So what else could be done if the meeting must go on and I am required to be there?

Two possible things come to mind: 1) reduce the meeting time, 2) improve the "quality"³ of the topics/material covered. Those two things aren't always directly related, you can obviously have a 1 hour meeting that covers exactly 1 topic in excruciating detail, or you could have a 30 minute meeting that covers 10 topics poorly. But if you can effectively cover (for example) 5 topics on average in a 1 hour meeting and you only have 2 topics on the agenda, your meeting time is probably going to be shorter. Wow! Or if you can cover 5 topics in that a full 1 hour meeting and it's "engaging" and all that (i.e. high "quality"), then I'm probably going to feel like my time was well spent there. Or if I look at the topics ahead of time then I might feel a little more comfortable skipping the meeting if I had to, or if my attendance is optional.

I think that sounds nice... So how could you do that consistently, or at least more consistently? I guess the meeting organizer could follow something like this before every meeting:

1. Do some pre-screening of topics

2. and pick ones that are most relevant / unresolved.

3. Of those, pick the ones that have the most info available at meeting time, so they're ready (or as close to being so) to discuss "live" in a meeting.

4. Then, allow any time-sensitive topics to preempt any/all topics on the agenda, if necessary.

If I'm the organizer, I don't want to do all of that by myself. I am probably not knowledgeable in every possible topic that might come up, and it might be hard for me to determine if a topic is "ready" enough to spend meeting time on. And it's even harder to gently, and regularly, push other people into helping along with some process like that.

I was looking over the list of topics in an upcoming postmarketOS core team meeting, and realized that we might have accidentally⁴ stumbled on a neat way to achieve something kinda like the above process, but more naturally:

The postmarketOS core team maintains a collection of topics for future team meetings in a shared notes thing, and any participant can propose topics, ask questions about a topic, etc for some number of days/weeks beforehand. That's it.

As a result, sometimes topics are:

• added, because there's almost always something new to talk about on the team
• dropped from the list, because (for example) an issue or decision was resolved "offline" and it's not necessary to discuss in a meeting
• modified, with clarifications or new information being added to support the topic's discussion in a meeting

On the day of the meeting, we quickly run through all of the proposed topics to set the agenda, moving any that aren't "ready" to some future meeting. Then we start going through the agenda. It's probably obvious but if some time-sensitive topic came in then we'd usually agree to discuss it regardless of what we had already planned.

In a way, we're "crowdsourcing"⁵ this pre-meeting work to all the participants, who probably want to use their time during the meeting effectively, or not have the meeting if it's not necessary. So, in theory at least, they might be motivated to help make that happen. And it's neat that all of this can happen before the meeting, completely asynchronously between everyone.

There's definitely a lot more to actually running an effective meeting beyond having a "good agenda". Our meetings still go off-topic at times. But I feel that this is some improvement, when we all have an opportunity to help shape the topics/agenda this way. I'll try to spend a little more time ahead of postmarketOS team meetings thinking about the proposed topics and asking questions, or proposing my own topics. Because it can happen asynchronously, I can do this whenever I feel like it. And if there's a chance it helps reduce the overall meeting time or it results in a more effective meeting, why not?

¹ Do you?

² To be fair, I didn't feel like any of the meetings I attended were poorly run or were a waste of time, but sometimes it's fun to think about how things could be improved further. Ya, I have a weird definition of "fun".

³ By "quality", I mean that topics are well-researched and presented by someone knowledgeable on the subject, folks are at least a little aware of what the topic is, and time was spent trying to anticipate questions that others might have. And so on. This is hard to achieve.

⁴ Or someone much smarter than me did this intentionally, for the same reasons, and I'm just now realizing it. If they did then ssshhhhhhh let me have my moment.

⁵ Ugghhhh.....

ResizeObserver related objects

<div id="target"></div>
<script>
{
  var ro = new ResizeObserver( entries => {});
  ro.observe(document.getElementById('target'));
} // end of the scope
</script>

• ro: a JSResizeObserver which is a js wrapper of ResizeObserver,
• callback: JSResizeObserverCallback,
• entries: JSResizeObserverEntry,
• and observe() would create a ResizeObservation,
• then document and the target.

Keep JSResizeObserver alive

Visit Children – When JavaScriptCore’s garbage collection visits some JS wrapper during the marking phase, visit another JS wrapper or JS object that needs to be kept alive.
Reachable from Opaque Roots – Tell JavaScriptCore’s garbage collection that a JS wrapper is reachable from an opaque root which was added to the set of opaque roots during marking phase.

ResizeObservation

Keep `JSCallbackDataWeak* m_data` in `JSResizeObserverCallback` alive

void JSCallbackDataWeak::visitJSFunction(Visitor& visitor)
{
    visitor.append(m_callback);
}

JSResizeObserverEntry

void JSResizeObserverEntry::visitAdditionalChildren(Visitor& visitor)
{
    addWebCoreOpaqueRoot(visitor, wrapped().target());
    addWebCoreOpaqueRoot(visitor, wrapped().contentRect());
}

class ResizeObserverEntry : public RefCounted<ResizeObserverEntry>

[1] https://github.com/WebKit/WebKit/blob/main/Introduction.md#js-wrapper-lifecycle-management

Some weeks ago, Igalia announced publicly that we will host X.Org Developers Conference 2023 (XDC 2023) in A Coruña, Spain. If you remember, we also organized XDC 2018 in this beautiful city in the northwest of Spain (I hope you enjoyed it!)

Since the announcement, I can now confirm that the conference will be in the awesome facilities of Palexco conference center, at the city center of A Coruña, Spain, from 17th to 19th of October 2023.

We are going to setup soon the website, and prepare everything to open the Call For Papers in the coming weeks. Stay tuned!

XDC 2023 is a three-day conference full of talks and workshops related to the open-source graphics stack: from Wayland to X11, from DRM/KMS to Mesa drivers, toolkits, libraries… you name it! This is the go-to conference if you are involved in the development of any part of the open-source graphics stack. Don’t miss it!

A Few Good Lies

On Wolvic’s new UA string in 1.3, things working, and frustrating intertwined problems.

Ok, let’s play a game… Imagine that you look at your server logs and see this UA string. Which browser sent it to you?

Mozilla/5.0 (Linux; Android 10; Quest 2) AppleWebKit/537.36 (KHTML, like Gecko) OculusBrowser/24.2.0.0.16.408393304 SamsungBrowser/4.0 Chrome/106.0.5249.79 VR Safari/537.36
  

I won’t blame you if you don’t immediately recognize the browser that sends that string by default (it’s the OculusBrowser). It’s already a giant set of lies and there’s no intuitive way to decide which one to believe.

But... Maybe you should believe none of them! Wolvic, for example, will send that string sometimes. And sometimes the OculusBrowser will send some other string. Eek.

Okay, maybe that was just a particularly complicated example. How about this one:

Mozilla/5.0 (Android 10; Mobile VR; rv:81.0) Gecko/81.0 Firefox/81.0
  

Ah, Firefox for Android? Sort of! Firefox Reality used to send that. Yes, it was for AOS-based devices, but not really for your Pixel phone’s Android.

Alright, alright — this one should be easy given the last one, right? Look how similar it is…

Mozilla/5.0 (Android 10; Mobile VR; rv:105.0) Gecko/105.0 Firefox/105.0
  

That is… Wolvic.

At least by default. Anything where one of those numbers was over ‘81’ was probably Wolvic. At least before this week’s release.

Starting with this release, Wolvic will normally send:

Mozilla/5.0 (Android 10; Mobile VR; rv:105.0) Gecko/105.0 Firefox/105.0 Wolvic/1.3
  

Ah finally - the text “Wolvic” appears in the string! But also, still, some lies. And then, of course, sometimes we’ll have to tell a completely different lie.

But... I mean...WHO CARES, right!?

You might imagine that nobody cares about the UA stirng, but you would be very wrong. Everybody seems to care about it, somehow.

The lies we need to tell ourselves

It’s not just about an app that suddenly starts refusing to service HTTPS requests, except to tell them to use a different browser (maybe, for example, the one they just so happen to make).

It’s all kinds of things that people try to reason about that ultimately somehow involves the UA string — and it affects so much.

Maybe, for example, you use some CMS or tool that lets you think in simpler terms: Is it “mobile” or is it a “tablet” or is it a “desktop”? Cool, but how does it know, and by what definition? Does that definition hold forever?

Or maybe you use a library which tries to make it simple to give all different devices as good an experience as they can. Again, there is some kind of attempt at categorizing in order to determine the ‘best’ experience — and it often involves (just a little maybe!) the UA string. And again, does that hold up forever?

Even if this works perfectly with every device in the whole world (it probably doesn’t!), as soon as something changes, or doesn’t neatly fit those definitions anymore, this is probably going to give users a pretty bad result.

And guess what? We’re all users! You can imagine how it might be frustrating if you are, for example, a user of some new device or browser. Like, hypothetically, one who has bought an XR device, running an immersive operating system, and browsing the web in a broswer built for that, and the cool immersive experience link someone sent you is giving you the non-immersive experience instead. The site thinks your totally capable browser just isn’t.

That kind of shit happens, a lot, and when it happens in popular libraries or CMSes or whatever, it can affect thousands of sites.

In fact, that’s a thing that happened with Wolvic. A lot.

You know who users get mad at when that happens? Not the site, nor the library. They get mad at the browser. When that happens, browsers will start lying to your site because that makes the user happy, and stops their hate. At the end of the day, making users happy is their job.

And this isn't a new thing. My colleague Eric Meyer wrote a great post about something similar from 2002, and we did a whole Igalia chats episode about all of this.

"Making users happy is their job" is tricky though, right? Because in our case, the site or CMS or library maker probably introduced something there because they cared about users. They wanted to make sure that some browser that falls through the logic cracks gets at least the basic mobile experience or something. Which is great, until it sucks.

Ugh.

Even if you aren’t looking at the UA string functionally somehow, you probably still care about it for functional reasons, if you think about it.

Let’s just take a for example: Should you care about how your site looks on these XR headsets? Is it worth doing something specially interesting on those? How do you decide what is worth your energy? Probably by asking “how many users of that are there?” in general, and more specifically “how many users are using that to visit my website?”

In both cases, you’re probably relying on the UA string. Either by looking through your own server logs and trying to see, or else by looking at market share numbers, which are literally a summary of other people’s server logs.

But, it’s possible you have 1000 people all visiting your site with Wolvic or the OculusBrowser right now, and you see none of that in your logs, because the browser makers have already figured out that we have to lie about what they are.

So, this is an especially frustrating thing for new browsers and new classes of devices.

Say, for example, you’re building a new browser. Maybe you have a logo that looks like a Wolf. Hypothetically. And you’re trying to fund a handful of developers to implement features which will serve the needs of your users.

The main way that a browser can pull in some income to pay said developers, historically, is by signing a default/integrated a search deal with a search engine. However, this presents something of a chicken and egg problem. To be a worthwhile deal, the search engine wants to know what kind of market share you have — in other words, how many users? And, well, they’re certainly not going to trust your private data on this. Metrics based on the UA string are the most obvious and public ones, but as a new browser you have to lie about what you are so that your users can, you know, use websites.

Sooooo… Cool, cool, cool, cool.

I wish none of this was the way it was, but I also don’t know how to fix it except to say “we really need to talk about the funding model”.

So, please be careful. Try not to make it worse.

Use Wolvic if you can.

Test with it if you can.

Please definitely report bugs, but also please be patient with us if you’re a user, we’re fighting systemic problems sometimes.

Maybe toss some money at our collective efforts if you can and help instigate the kind of change we need… or, if not, maybe just tell someone about it.

Thanks.

This was my first time attending FOSDEM, and it was a really neat conference! I saw a few talks, though not as many as I had originally planned, because I decided to try and prioritize meeting people and hanging out with them over going to talks that I could watch online. So I ended up mostly attending talks with others I knew, as a workaround 😅

I don't have a many friends, so getting to see some for the first time in person was amazing. And I hopefully made some new ones too!

It was a fairly long trip for a 2 day conference, ~20 hours of travel to there, and ~24hrs of travel home. I added a couple of extra days afterwards to stick around Brussels and hang out with some friends, which was totally the right decision.

I'm looking forward to seeing folks again, and encourage others who are fortunate enough to have a chance to attend conferences/meet-ups to go, or consider doing it!

My talk

Here's a talk I did, my first one in a looong time. Link to description

Photos

most of the postmarketOS team in front of the Linux Mobile stand

group of mobile devices on the Linux Mobile stand (photo by: A-wai)

recording postmarketOS podcast in person for the first time

aftermath of reaching #avocadosnumber (photo by: Caleb)

Belgium waffles are something else... mmmmmmm

scene from a 1 day 'pmOS hackathon'

labne w/ poached egg, starting a long layover

view of St Helens as I'm coming home

Dave asked people to share their CSS wish lists for 2023, and even though it’s well into the second month of the year, I’m going to sprint wild-eyed out of the brush along the road, grab the hitch on the back of the departing bandwagon, and try to claw my way aboard. At first I thought I had maybe four or five things to put on my list, but as I worked on it, I kept thinking of one more thing and one more thing until eventually I had a list of (checks notes) sixt — no, SEVENTEEN?!?!?  What the hell.

There’s going to be some overlap with the things being worked on for Interop 2023, and I’m sure there will be overlap with other peoples’ lists.  Regardless, here we go.

Subgrid

Back in the day, I asserted Grid should wait for subgrid.  I was probably wrong about that, but I wasn’t wrong about the usefulness of and need for subgrid.  Nearly every time I implement a design, I trip over the lack of widespread support.

I have a blog post in my head about how I hacked around this problem for wpewebkit.org by applying the same grid column template to nested containers, and how I could make it marginally more efficient with variables.  I keep not writing it, because it would show the approach and improvement and then mostly be about the limitations, flaws, and annoyances this approach embodies.  The whole idea just depresses me, and I would probably become impolitic.

So instead I’ll just say that I hope those browser engines that have yet to catch up with subgrid support will do so in 2023.

Masonry layout

Grid layout is great, and you can use it to create a masonry-style layout, but having a real masonry layout mechanism would be better, particularly if you can set it on a per-axis basis.  What I mean is, you could define a bunch of fixed (or flexible) columns and then say the rows use masonry layout.  It’s not something I’m likely to use myself, but I always think the more layout possibilities there are, the better.

Grid track styles

For someone who doesn’t do a ton of layout, I find myself wanting to style grid lines a surprising amount.  I just want to do something like:

display: grid;
gap: 1em;
grid-rules-columns: 1px dotted red;

…although it would be much better to be able to style separators for a specific grid track, or even an individual grid cell, as well as be able to apply it to an entire grid all at once.

No, I don’t know exactly how this should work.  I’m an idea guy!  But that’s what I want.  I want to be able to define what separator lines look like between grid tracks, centered on the grid lines.

Anchored positioning

I’ve wanted this in one form or another almost since CSS2 was published.  The general idea is, you can position an element in relation to the edges of another element that isn’t a containing block.  I wrote about this a bit in my post on connector lines for wpewebkit.org, but another place it would have come in handy was with the footnotes on The Effects of Nuclear Weapons.

See, I wanted those to actually be sidenotes, Tufteee-styleee.  Right now, in order to make sidenotes, you have to stick the footnote into the text, right where its footnote reference appears  —  or, at a minimum, right after the element containing the footnote reference.  Neither was acceptable to me, because it would dork up the source text.

What I wanted to be able to do was collect all the footnotes as endnotes at the end of the markup (which we did) and then absolutely position each to sit next to the element that referenced them, or have it pop up there on click, tap, hover, whatever.  Anchored positioning would make that not just possible, but fairly easy to do.

Exclusions

Following on anchored positioning, I’d love to have CSS Exclusions finally come to browsers.  Exclusions are a way to mark an element to have other content avoid it.  You know how floats move out of the normal flow, but normal-flow text avoids overlapping them?  That’s an exclusion.  Now imagine being able to position an element by other means, whether grid layout or absolute positioning or whatever, and then say “have the content of other elements flow around it”.  Exclusions!  See this article by Rob Weychert for a more in-depth explanation of a common use case.

Element transitions

The web is cool and all, but you know how futuristic interfaces in movies have pieces of the interface sliding and zooming and popping out and all that stuff?  Element transitions.  You can already try them out in Chrome Canary, Batman, and I’d love to see them across the board.  Even more, I’d love some gentle, easy-to-follow tutorials on how to make them work, because even in their single-page form, I found the coding requirements basically impossible to work out.  Make them all-CSS, and explain them like I’m a newb, and I’m in.

Nested Selectors

A lot of people I know are still hanging on to preprocessors solely because they permit nested selectors, like:

main {
	padding: 1em;
	background: #F1F1F0;
	
	h2 {
		border-block-end: 1px solid gray;
	}
	p {
		text-indent: 2em;
	}
}

The CSS Working Group has been wrestling with this for quite some time now, because it turns out the CSS parsing rules make it hard to just add this, there are a lot of questions about how this should interact with pseudo-classes like :is(), there are serious concerns about doing this in a way that will be maximally future-compatible, and also there has been a whole lot of argument over whether it’s okay to clash with Sass syntax or not.

So it’s a difficult thing to make happen in native CSS, and the debates are both wide-ranging and slow, but it’s on my (and probably nearly everyone else’s) wish list.  You can try it out in Safari Technology Preview as I write this, so here’s hoping for accelerating adoption!

More and better :has()

Okay, since I’m talking about selectors already, I’ll throw in universal, full-featured, more optimized support for :has().  One browser doesn’t support compound selectors, for example.  I’ve also thought that maybe some combinators would be nice, like making a:has(> b) can be made equal to a < b.

But I also wish for people to basically go crazy with :has().  There’s SO MUCH THERE.  There are so many things we can do with it, and I don’t think we’ve touched even a tiny fraction of the possibility space.

More attr()

I’ve wanted attr() to be more widely accepted in CSS values since, well, I can’t remember.  A long time.  I want to be able to do something like:

p[data-size] {width: attr(data-width, rem);}

<p data-size="27">…</p>

Okay, not a great example, but it conveys the idea.  I also talked about this in my post about aligning table columns. I realize adding this would probably lead to someone creating a framework called Headgust where all the styling is jammed into a million data-*attributes and the whole of the framework’s CSS is nothing but property: attr() declarations for every single CSS property known to man, but we shouldn’t let that stop us.

Variables in media queries

Basically I want to be able to do this:

:root {--mobile: 35em;}

@media (min-width: var(--mobile)) {
	/* non-mobile styles go here */
}

That’s it.  This was made possible in container queries, I believe, so maybe it can spread to media (and feature?) queries.  I sure hope so!

Logical modifiers

You can do this:

p {margin-block: 1em; margin-inline: 1rem;}

But you can’t do this:

p {margin: logical 1em 1rem;}

I want to be able to do that.  We should all want to be able to do that, however it’s made possible.

Additive values

You know how you can set a bunch of values with a comma-separated list, but if you want to override just one of them, you have to do the whole thing over?  I want to be able to add another thing to the list without having to do the whole thing over.  So rather than adding a value like this:

background-clip: content, content, border, padding; /* needed to add padding */

…I want to be able to do something like:

background-clip: add(padding);

No, I don’t know how to figure out where in the list it should be added.  I don’t know a lot of things.  I just know I want to be able to do this.  And also to remove values from a list in a similar way, since I’m pony-wishing.

Color shading and blending

Preprocessors already allow you to say you want the color of an element to be 30% lighter than it would otherwise be.  Or darker.  Or blend two colors together.  Native CSS should have the same power.  It’s being worked on.  Let’s get it done, browsers.

Hanging punctuation

Safari has supported hanging-punctuation forever (where “forever”, in this case, means since 2016) and it’s long past time for other browsers to get with the program.  This should be universally supported.

Cross-boundary styles

I want to be able to apply styles from my external (or even embedded) CSS to a resource like an external SVG.  I realize this sets up all kinds of security and privacy concerns.  I still want to be able to do it.  Every time I have to embed an entire inline SVG into a template just so I can change the fill color of a logo based on its page context, I grit my teeth just that little bit harder.  It tasks me.

Scoped styling (including imports)

The Mirror Universe version of the previous wish is that I want to be able to say a bit of CSS, or an entire style sheet (embedded or external), only applies to a certain DOM node and all its descendants. “But you can do that with descendant selectors!” Not always.  For that matter, I’d love to be able to just say:

<div style="@import(styles.css);">

…and have that apply to that <div> and its descendants, as if it were an <iframe>, while not being an <iframe> so styles from the document could also apply to it.  Crazy?  Don’t care.  Still want it.

Linked flow regions(?)

SPECIAL BONUS TENTATIVE WISH: I didn’t particularly like how CSS Regions were structured, but I really liked the general idea.  It would be really great to be able to link elements together, and allow the content to flow between them in a “smooth” manner.  Even to allow the content from the second region to flow back into the first, if there’s room for it and nothing prevents it.  I admit, this is really a “try to recreate Aldus PageMaker in CSS” thing for me, but the idea still appeals to me, and I’d love to see it come to CSS some day.

So there you go.  I’d love to hear what you’d like to see added to CSS, either in the comments below or in posts of your own.

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

Superb Howl

We are rapidly approaching Sunday, Feburary 12th, or in America "Super Bowl Sunday". There's something interesting about the Super Bowl that I wish we could emulate there for the Web.

Chances are pretty good that even if you don't care at all about American football or watch broadcast TV, you're still going to wind up hearing about the Super Bowl. Or, at least, the commercials.

In fact, there's a pretty good chance you'll even see them. They'll be written about by media and talked about on social media. The Super Bowl is the only event that I know of that is like that. The commercials aren't just an annoyance. In fact, it is the only one I know of where where a segment of the audience is tuning in for the commercials. They want to see them live, as they air. The commercials are part of the event.

That is... unique

Maybe the web needs that.

Wait, don't run away! Please!! Let me explain!!

Check this out...

Most people I show this to don't realize what they're seeing, but this is the "What's New" page. Whever Firefox updates it can launch a "What's new?" page, and it can put whatever it wants on there. This isn't really about what's new in this release of Firefox at all - it is a full page advertisement! This particular advertisement is for a product that Mozilla acquired called Pocket, but I believe it was also a place where they highlighted the partnership with the Going Red movie. That's pretty interesting and like a lot of things Mozilla has done, pretty innovative. I guess now we'll see if like a lot of other Mozilla things, they were just a little too early or got a few details wrong.

It requires Firefox to sell that space, and, I'm pretty sure they're not selling it successfully right now. Maybe they never tried. Maybe they've stopped trying. But, what's very interesting to me is that while their numbers have been declining for years, even right now "Firefox users" is more than twice the audience that the Super Bowl will next week.

Wow.

That could be a valuable ad spot, right? And not just for Firefox — it’s valuable in just about every browser. For example, Brave’s user numbers are right now getting close to half the audience of the Super Bowl.

In fact, even Brave's numbers are, at this point, approaching about half the audience of the Super Bowl.

Maybe this approach could be compelling for them too? Imagine if they did a thing like Firefox.. Oh wait..

Yeah, look at that. Brave also recognizes this is valuable, though they are offering something similar, but a little different, more repeatable - the whole start backdrop.

That's a pretty interesting idea which one could argue is just a better version of something that came before. Opera, I think, was the first one to introduce a start page with "speed dial". That's sort of like "default bookmarks on the start page" and for both Vivaldi or Opera their funding sources can include default bookmarks.

Microsoft, I think has had some of their own product stuff in their start page at various times. Google's browser, unsuprisingly places Search almost alone on the new tab page, despite the fact that the wonderbar will also search with Google. Search is their main money making business, after all. There is still, however, an drawer you can open which will link you to all of the other Google properties too.

Changing ideas

As I wrote in The NASCAR Model we need better ways to fund browser development and to incentivize direct investement, and for better or worse, that is way more practical if we can find a way to involve marketing budgets... Or just charging users somehow (they're charged now, they just don't realize it).

So, all of those ideas above are kind of interesting attempts to do just that.

In Wolvic we also have an environment around us, and we've effectively put up ads for Wolvic in those so far...

But, the same thing holds there: There's no real reason we couldn't put some small amount of marking in the environment there. There's no reason that one there couldn't be a billboard there for a new Star Wars show or Avengers movie...

(psst... Disney, call me).

Somehow, I feel like they're all worth exploring - or at least worth discussing as we figure out how to collectively come to grips with the fact that ultimately we need to find new funding models for browsers (and their underlying engines). You can also consider adding some sponsorship via the collective, right now, and read more about that.

I'd love to hear your thoughts on any of this. Could we really somehow convince marketing dollars to be spent on this? What would it take? Is there a way, like the Super Bowl, we can design create "just the right thing" where it's very valuable and not something users loathe. How could we get ads worthy of the opportunity and not turn into another vector for attention stealing? That's difficult. There are, of course, way more questions than answers - but if you'd like to talk or share your thoughts, hit me up. Especially if you are in Disney's marketing department, for example.

This year I started a new job working with Igalia’s Graphics Team. For those of you who don’t know Igalia they are a “worker-owned, employee-run cooperative model consultancy focused on open source software”.

As a new member of the team, I thought it would be a great idea to summarize the incredible amount of work the team completed in 2022. If you’re interested keep reading!

Vulkan 1.2 Conformance on RPi 4

One of the big milestones for the team in 2022 was achieving Vulkan 1.2 conformance on the Raspberry Pi 4. The folks over at the Raspberry Pi company wrote a nice article about the achievement. Igalia has been partnering with the Raspberry Pi company to bring build and improve the graphics driver on all versions of the Raspberry Pi.

The Vulkan 1.2 spec ratification came with a few extensions that were promoted to Core. This means a conformant Vulkan 1.2 driver needs to implement those extensions. Alejandro Piñeiro wrote this interesting blog post that talks about some of those extensions.

Vulkan 1.2 also came with a number of optional extensions such as VK_KHR_pipeline_executable_properties. My colleague Iago Toral wrote an excellent blog post on how we implemented that extension on the Raspberry Pi 4 and what benefits it provides for debugging.

Vulkan 1.3 support on Turnip

Igalia has been heavily supporting the Open-Source Turnip Vulkan driver for Qualcomm Adreno GPUs, and in 2022 we helped it achieve Vulkan 1.3 conformance. Danylo Piliaiev on the graphics team here at Igalia, wrote a great blog post on this achievement! One of the biggest challenges for the Turnip driver is that it is a completely reverse-engineered driver that has been built without access to any hardware documentation or reference driver code.

With Vulkan 1.3 conformance has also come the ability to run more commercial games on Adreno GPUs through the use of the DirectX translation layers. If you would like to see more of this check out this post from Danylo where he talks about getting “The Witcher 3”, “The Talos Principle”, and “OMD2” running on the A660 GPU. Outside of Vulkan 1.3 support he also talks about some of the extensions that were implemented to allow “Zink” (the OpenGL over Vulkan driver) to run Turnip, and bring OpenGL 4.6 support to Adreno GPUs.

Vulkan Extensions

Several developers on the Graphics Team made several key contributions to Vulkan Extensions and the Vulkan conformance test suite (CTS). My colleague Ricardo Garcia made an excellent blog post about those contributions. Below I’ve listed what Igalia did for each of the extensions:

• VK_EXT_image_2d_view_of_3d
  • We reviewed the spec and are listed as contributors to this extension
• VK_EXT_shader_module_identifier
  • We reviewed the spec, contributed to it, and created tests for this extension
• VK_EXT_attachment_feedback_loop_layout
  • We reviewed, created tests and contributed to this extension
• VK_EXT_mesh_shader
  • We contributed to the spec and created tests for this extension
• VK_EXT_mutable_descriptor_type
  • We reviewed the spec and created tests for this extension
• VK_EXT_extended_dynamic_state3
  • We wrote tests and reviewed the spec for this extension

AMDGPU kernel driver contributions

Our resident “Not an AMD expert” Melissa Wen made several contributions to the AMDGPU driver. Those contributions include connecting parts of the pixel blending and post blending code in AMD’s DC module to DRM and fixing a bug related to how panel orientation is set when a display is connected. She also had a presentation at XDC 2022, where she talks about techniques you can use to understand and debug AMDGPU, even when there aren’t hardware docs available.

André Almeida also completed and submitted work on enabled logging features for the new GFXOFF hardware feature in AMD GPUs. He also created a userspace application (which you can find here), that lets you interact with this feature through the debugfs interface. Additionally, he submitted a patch for async page flips (which he also talked about in his XDC 2022 presentation) which is still yet to be merged.

Modesetting without Glamor on RPi

Christopher Michael joined the Graphics Team in 2022 and along with Chema Casanova made some key contributions to enabling hardware acceleration and mode setting on the Raspberry Pi without the use of Glamor which allows making more video memory available to graphics applications running on a Raspberry Pi.

The older generation Raspberry Pis (1-3) only have a maximum of 256MB of memory available for video memory, and using Glamor will consume part of that video memory. Christopher wrote an excellent blog post on this work. Both him and Chema also had a joint presentation at XDC 2022 going into more detail on this work.

Linux Format Magazine Column

Our very own Samuel Iglesias had a column published in Linux Format Magazine. It’s a short column about reaching Vulkan 1.1 conformance for v3dv & Turnip Vulkan drivers, and how Open-Source GPU drivers can go from a “hobby project” to the defacto driver for the platform. Check it out on page 7 of issue #288!

XDC 2022

X.Org Developers Conference is one of the big conferences for us here at the Graphics Team. Last year at XDC 2022 our Team presented 5 talks in Minneapolis, Minnesota. XDC 2022 took place towards the end of the year in October, so it provides some good context on how the team closed out the year. If you didn’t attend or missed their presentation, here’s a breakdown:

“Replacing the geometry pipeline with mesh shaders” (Ricardo García)

Ricardo presents what exactly mesh shaders are in Vulkan. He made many contributions to this extension including writing 1000s of CTS tests for this extension with a blog post on his presentation that should check out!

“Status of Vulkan on Raspberry Pi” (Iago Toral)

Iago goes into detail about the current status of the Raspberry Pi Vulkan driver. He talks about achieving Vulkan 1.2 conformance, as well as some of the challenges the team had to solve due to hardware limitations of the Broadcom GPU.

“Enable hardware acceleration for GL applications without Glamor on Xorg modesetting driver” (Jose María Casanova, Christopher Michael)

Chema and Christopher talk about the challenges they had to solve to enable hardware acceleration on the Raspberry Pi without Glamor.

“I’m not an AMD expert, but…” (Melissa Wen)

In this non-technical presentation, Melissa talks about techniques developers can use to understand and debug drivers without access to hardware documentation.

“Async page flip in atomic API” (André Almeida)

André talks about the work that has been done to enable asynchronous page flipping in DRM’s atomic API with an introduction to the topic by explaining about what exactly is asynchronous page flip, and why you would want it.

FOSDEM 2022

Another important conference for us is FOSDEM, and last year we presented 3 of the 5 talks in the graphics dev room. FOSDEM took place in early February 2022, these talks provide some good context of where the team started in 2022.

The status of Turnip driver development (Hyunjun Ko)

Hyunjun presented the current state of the Turnip driver, also talking about the difficulties of developing a driver for a platform without hardware documentation. He talks about how Turnip developers reverse engineer the behaviour of the hardware, and then implement that in an open-source driver. He also made a companion blog post to checkout along with his presentation.

v3dv: Status Update for Open Source Vulkan Driver for Raspberry Pi 4 (Alejandro Piñeiro)

Igalia has been presenting the status of the v3dv driver since December 2019 and in this presentation, Alejandro talks about the status of the v3dv driver in early 2022. He talks about achieving conformance, the extensions that had to be implemented, and the future plans of the v3dv driver.

Fun with border colors in Vulkan (Ricardo Garcia)

Ricardo presents about the work he did on the VK_EXT_border_color_swizzle extension in Vulkan. He talks about the specific contributions he did and how the extension fits in with sampling color operations in Vulkan.

GSoC & Igalia CE

Last year Melissa & André co-mentored contributors working on introducing KUnit tests to the AMD display driver. This project was hosted as a “Google Summer of Code” (GSoC) project from the X.Org Foundation. If you’re interested in seeing their work Tales da Aparecida, Maíra Canal, Magali Lemes, and Isabella Basso presented their work at the Linux Plumbers Conference 2022 and across two talks at XDC 2022. Here you can see their first presentation and here you can see their second second presentation.

André & Melissa also mentored two “Igalia Coding Experience” (CE) projects, one related to IGT GPU test tools on the VKMS kernel driver, and the other for IGT GPU test tools on the V3D kernel driver. If you’re interested in reading up on some of that work, Maíra Canal wrote about her experience being part of the Igalia CE.

Ella Stanforth was also part of the Igalia Coding Experience, being mentored by Iago & Alejandro. They worked on the VK_KHR_sampler_ycbcr_conversion extension for the v3dv driver. Alejandro talks about their work in his blog post here.

What’s Next?

The graphics team is looking forward to having a jam-packed 2023 with just as many if not more contributions to the Open-Source graphics stack! I’m super excited to be part of the team, and hope to see my name in our 2023 recap post!

Also, you might have heard that Igalia will be hosting XDC 2023 in the beautiful city of A Coruña! We hope to see you there where there will be many presentations from all the great people working on the Open-Source graphics stack, and most importantly where you can dream in the Atlantic!

There are lots of powerful IDEs which are broadly used by developers. Vim is a text editor, but it can be turned into a good IDE with awesome plugins and a little bit of configuration.

Many people already prefer using Vim to develop software because of its lightness and availability. I am one of them, and always use Vim to develop Chromium. However, someone would think that it’s hard to get Vim to reach the same performance as other IDEs, since Chromium is a very huge project.

For those potential users, this post introduces some tips for using Vim as an IDE when developing Chromium.

The context of this document is for Linux users who are used to using Vim.

Code Formatting

I strongly recommend using vim-codefmt for code formatting. It supports most file types in Chromium including GN (See GN docs) and autoformatting. However, I don’t like to use autoformatting and just bind :FormatLines to ctrl-I for formating a selected visual block.

1 
map <C-I> :FormatLines<CR> 

Another option is using clang-format in depot_tools by clang-format.vim in tools/vim. Please check about tools/vim at the following section.

tools/vim

You can easily find a bunch of Vim files in tools/vim. I create a .vimrc file locally in a working directory and load only what I need.

1 2 3 4 5 6 7 
let chtool_path=getcwd().'/tools' filetype off let &rtp.=','.chtool_path.'/vim/mojom' exec 'source' chtool_path.'/vim/filetypes.vim' exec 'source' chtool_path.'/vim/ninja-build.vim' filetype plugin indent on 

Chromium provides vimscript files for syntax highliting and file detection of Mojom, which is the IDL for Mojo interfaces (IPC) among Chromium services. And ninja-build.vim allows you compile a file with ctrl-O or build the specific target with :CrBuild command. See each Vim files for details.

Running Tests

tools/autotest.py is very useful when you run tests of Chromium. As the description of the script, autotest.py finds the appropriate test suits and builds it, then runs it. ! is an option for running autotest.py inside Vim, but sometimes it’s a hassle to type all parameters. What about to write simple commands (or functions) with scripts under tools/vim?

This is an example script for running a test for the current line. Some codes are copied from ninja-build.vim and imported from ninja-output.py.

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 
pythonx << endpython import os, vim def path_to_build_dir(): # Codes from tools/vim/ninja-build.vim. chrome_root = os.path.dirname(vim.current.buffer.name) fingerprints = ['chrome', 'net', 'v8', 'build', 'skia'] while chrome_root and not all( [os.path.isdir(os.path.join(chrome_root , fp)) for fp in fingerprints]): chrome_root = os.path.dirname(chrome_root) sys.path.append(os.path.join(chrome_root, 'tools', 'vim')) # Import GetNinjaOutputDirectory from tools/vim/ninja_output.py. from ninja_output import GetNinjaOutputDirectory return GetNinjaOutputDirectory(chrome_root) def run_test_for_line(linenumb): run_cmd = ' '.join(['!tools/autotest.py', '-C', path_to_build_dir(), '%', '--line', linenumb] ) vim.command(run_cmd) endpython fun! RunTestForCurrentLine() let l:current_line = shellescape(line('.')) pythonx run_test_for_line(vim.eval('l:current_line')) endfun map <C-T> :call RunTestForCurrentLine()<CR> 

Place the cursor on what we want to test and ctrl-t … Here you go.

YouCompleteMe

tools/vim has an example configuration for YouCompleteMe (a code completion engine for Vim). See tools/vim/chromium.ycm_extra_conf.py.

1 2 
let g:ycm_extra_conf_globlist = ['../.ycm_extra_conf.py'] let g:ycm_goto_buffer_command = 'split-or-existing-window' 

As you already know, YouCompleteMe requires clangd. Very fortunately, Chromium already supports clangd and remote index server to get daily index snapshots.

Do not skip documents about using Clangd to build chromium and chromium remote index server.

Here are short demos for completion suggestions,

and code jumping(:YcmCompleter GoTo, :YcmCompleter GoToReferences) during Chromium development.

Commenter

A good developer writes good comments, so being a good commenter makes you a good developer (joke). In my humble opinion, NERD commenter will make you a good developer (joke again). You can get all details from the docs of NERD commenter, and Chromium needs only an additional option for mojom.

1 
let g:NERDCustomDelimiters = { 'mojom': {'left': '//'} } 

File Navigation

Chromium is really huge, so we benefit from efficient file navigation tools. There are lots of awesome fuzzy finder plugins for this purpose and I have been using command-t for a long time. But command-t requires a Vim executable with ruby/lua support or Neovim. If you need a simpler yet still powerful navigator, fzf.vim is an altenative great option.

Since Chromium a git project, search commands based by git ls-files will provide results very quickly. Use the option let g:CommandTFileScanner = 'git' for command-t, and use the command :GFiles for fzf.vim.

In case you can’t depend on git ls-files based commands, please make sure your plugin use rg or fd which are the fastest command line search tools. For example, fzf.vim has an option FZF_DEFAULT_COMMAND and the following suggestion in the manual: export FZF_DEFAULT_COMMAND='fd --type f'.

Conclusion

Thanks for reading and I hope this blog post can be some help to your development enviroment for Chromium. Any comment for sharing some other cool tips always be welcomed, so that we can make our Vim more productive. (Right, this is the real purpose of this blog post.)

…. I will be back someday with debugging Chromium in Vim.

Back in March of 2021, as part of my maintenance work on Chrome/Chromium accessibility at Igalia, I inadvertently started a long, deep dive into the accessible name calculation code, that had me intermittently busy since then.

This is the third and last post in the series. We started with an introduction to the problem, and followed by describing how we fixed things in Chromium. In this post, we will describe some problems we detected in the accessible name computation spec, and the process to address them.

This post extends what was recently presented in a lightning talk at BlinkOn 17, in November 2022:

Hidden content and aria-labelledby

Authors may know they can use aria-labelledby to name a node after another, hidden node. The attribute aria-describedby works analogously for descriptions, but in this post we will refer to names for simplicity.

This is a simple example, where the produced name for the input is “foo”:

<input aria-labelledby="label">
<div id="label" class="hidden">foo</div>

This is because the spec says, in step 2B:

• if computing a name, and the current node has an aria-labelledby attribute that contains at least one valid IDREF, and the current node is not already part of an aria-labelledby traversal, process its IDREFs in the order they occur:
• or, if computing a description, and the current node has an aria-describedby attribute that contains at least one valid IDREF, and the current node is not already part of an aria-describedby traversal, process its IDREFs in the order they occur:
  i. Set the accumulated text to the empty string.
  ii. For each IDREF:
   
  a. Set the current node to the node referenced by the IDREF.
  b. Compute the text alternative of the current node beginning with step 2. Set the result to that text alternative.
  c. Append the result, with a space, to the accumulated text.
   
  iii. Return the accumulated text.

When processing each IDREF per 2B.ii.b, it will stumble upon this condition in 2A:

If the current node is hidden and is not directly referenced by aria-labelledby or aria-describedby, nor directly referenced by a native host language text alternative element (e.g. label in HTML) or attribute, return the empty string. 

So, a hidden node referenced by aria-labelledby or aria-describedby will not return the empty string. Instead, it will go on with the subsequent steps in the procedure.

Unfortunately, the spec did not provide clear answers to some corner cases: what happens if there are elements that are explicitly hidden inside the first hidden node? What about nodes that aren’t directly referenced? How deep are we expected to go inside a hidden tree to calculate its name? And what about aria-hidden nodes?

Consider another example:

  <input id="test" aria-labelledby="t1">
  <div id="t1" style="visibility:hidden">
    <span aria-hidden="true">a</span>
    <span style="visibility:hidden">b</span>
    <span>c</span>
    d
  </div>

Given the markup above, WebKit generated the name “d”, Firefox said “abcd” and Chrome said “bcd”. In absence of clear answers, user agent behaviors differ.

There was an ongoing discussion in Github regarding this topic, where I shared my findings and concerns. Some conclusions that came out from it:

• It appears that the original intention of the spec was allowing the naming of nodes from hidden subtrees, if done explicitly, and to include only those children that were not explicitly hidden.
• It’s really hard to implement a check for explicitly hidden nodes inside a hidden subtree. For optimization purposes, that information is simplified away in early stages of stylesheet processing, and it wouldn’t be practical to recover or keep it.
• Given the current state of affairs and how long the current behavior has been in place, changing it radically would cause confusion among authors, backwards compatibility problems, etc.

The agreement was to change the spec to match the actual behavior in browsers, and clarify the points where implementations differed. But, before that…

A dead end: the innerText proposal

An approach we discussed which looked promising was to use the innerText property for the specific case of producing a name from a hidden subtree. The spec would say something like: “if node is hidden and it’s the target of an aria-labelledby relation, return the innerText property”.

It’s easy to explain, and saves user agents the trouble of implementing the traversal. It went as far as to have a proposed wording and I coded a prototype for Chromium.

Unfortunately, innerText has a peculiar behavior with regard to hidden content: it will return empty if the node was hidden with the visibility:hidden rule.

The relevant spec says:

The innerText and outerText getter steps are:
 
1. If this is not being rendered or if the user agent is a non-CSS user agent, then return this’s descendant text content.

Where:

An element is being rendered if it has any associated CSS layout boxes, SVG layout boxes, or some equivalent in other styling languages.

An element with visibility:hidden has an associated layout box, hence it’s considered “rendered” and follows the steps 2 and beyond:

1. Let results be a new empty list.
    
2. For each child node node of this:
   i. Let current be the list resulting in running the rendered text collection steps with node. Each item in results will either be a string or a positive integer (a required line break count).

Where “rendered text collection steps” says:

1. Let items be the result of running the rendered text collection steps with each child node of node in tree order, and then concatenating the results to a single list.
    
2. If node’s computed value of ‘visibility’ is not ‘visible’, then return items.

The value of visibility is hidden, hence it returns items, which is empty because we had just started.

This behavior makes using innerText too big of a change to be acceptable for backwards compatibility reasons.

Clarifying the spec: behavior on naming after hidden subtrees

In the face of the challenges and preconditions described above, we agreed that the spec would document what most browsers are already doing in this case, which means exposing the entire, hidden subtree, down to the bottom. There was one detail that diverged: what about nodes with aria-hidden="true"? Firefox included them in the name, but Chrome and WebKit didn’t.

Letting authors use aria-hidden to really omit a node in a hidden subtree appeared to be a nice feature to have, so we first tried to codify that behavior into words. Unfortunately, the result became too convoluted: it added new steps, it created differences in what “hidden” means… We decided not to submit this proposal, but you can still take a look at it if you’re curious.

Instead, the proposal we submitted does not add or change many words in the spec text. The new text is:

“If the current node is hidden and is not part of an aria-labelledby or aria-describedby traversal, where the node directly referenced by that relation was hidden […], return the empty string.”

Instead, it adds a lot of clarifications and examples. Although it includes guidelines on what’s considered hidden, it does not make differences in the specific rules used to hide; as a result, aria-hidden nodes are expected to be included in the name when naming after a hidden subtree. 

Updating Chromium to match the spec: aria-hidden in hidden subtrees

We finally settled on including aria-hidden nodes when calculating a name or a description after a hidden subtree, via the aria-labelledby and aria-describedby relations. Firefox already behaved like this but Chromium did not. It appeared to be an easy change, like removing only one condition somewhere in the code… The reality is never like that, though.

The change landed successfully, but it’s much more than removing a condition: we found out the removal had side effects in other parts of the code. Additionally, we had some corrections in Chromium to prevent authors to use aria-hidden on focusable elements, but they weren’t explicit in the code; our change codifies them and adds tests. All this was addressed in the patch and, in general, I think we left things in a better shape than they were.

A recap

In the process to fix a couple of bugs about accessible name computation in Chrome, we detected undocumented cases in the spec and TODOs in the implementation. To address all of it, we ended up rewriting the traversal code, discussing and updating the spec and adding even more tests to document corner cases.

Many people were involved in the process, not only Googlers but also people from other browser vendors, independent agents, and members of the ARIA working group. I’d like to thank them all for their hard work building and maintaining accessibility on the Web.

But there is still a lot to do! There are some known bugs, and most likely some unknown ones. Some discussions around the spec still remain open and could require changes in browser behavior. Contributions are welcome!

Thanks for reading, and happy hacking!

WebGPU Introduction

WebGPU CTS

Contribution

1. Set up the CTS developing environment.
2. Add to or edit the test plan in the CTS project site.
3. Implement the test.
4. Upload the test and request a review.

Organization

Example

• desc: Describes what it tests and summarize how it tests that functionality.
• params: Defines parameters with a list of objects to be tested. Each such instance of the test is a “case”
• fn: Implementation body of the test.

Parameterization

Contributors

The next steps

References

Chromium 109 (released January 10, 2023) has dropped support for xdg_shell_unstable_v6, one of Wayland shell protocols.

For years, the Chromium’s Wayland backend was aware of two versions of the XDG shell interface. There were two parallel implementations of the client part, similar like twins. In certain parts, the only difference was names of functions. Wayland has a naming convention that requires these names to start with the name of the interface they work with, so where one implementation would call xdg_toplevel_resize(), the other one would call zxdg_toplevel_v6_resize().

The shell is a now standard Wayland protocol extension that describes semantics for the “windows”. It does so by assigning “roles” to the Wayland surfaces, and by providing means to set relative positions of these surfaces. That altogether makes it possible to build tree-like hierarchies of windows, which is absolutely necessary to render a window that has a menu with submenus.

The XDG shell protocol was introduced in Wayland protocols a long time ago. The definition file mentions 2008, but I was unable to track its history back that far. The Git repository where these files are hosted these days was created in October 2015, and the earlier history is not preserved. (Maybe the older repository still exists somewhere?)

Back in 2015, the XDG shell interface was termed “unstable”. Wayland waives backwards compatibility for unstable stuff, and requires the versions to be explicitly mentioned in the names of protocols and their definition files. Following that rule, the XDG shell protocol was named xdg_shell_unstable_v5. Soon after the initial migration of the project, the version 6 was introduced, named xdg_shell_unstable_v6. Since then, there are two manifests in the unstable section, xdg-shell-unstable-v5.xml and xdg-shell-unstable-v6.xml. I assume versions prior to 5 were dropped at the migration.

This may be confusing, so let me clarify. Wayland defines several entities to describe stuff. A protocol is a grouping entity: it is the root element of the XML file where it is defined. A protocol may contain a number of interfaces that describe behaviour of objects. The real objects and calls are bound to interfaces, but the header files are generated for the protocol as a whole, so even if the client uses only one interface, it will import the whole protocol.

The XDG shell allows the application to, quoting its description, “create desktop-style surfaces”. A number of desktop environments implemented support for the unstable protocol, providing feedback and proposing improvements. In 2017, the shell protocol was declared stable, and got a new name: xdg_shell. The shell interface was renamed from zxdg_shell_v6 to xdg_wm_base. Since then, the clients had to choose between two protocols, or to support both.

For the stable stuff, the convention is simpler and easier to follow: the changes are assumed to be backwards compatible, so names of interfaces and protocols are fixed and no longer change. The version tracking is built into the protocol definition and uses the self-explanatory version and since attributes. The client can import one protocol and decide at run time which calls are possible and which are not depending on the version exposed by the compositor.

The stable version continued to evolve. Eventually, the unstable version became redundant, and in 2022 major Wayland compositors started to drop support for it. By November in the past year we realised that the code that implemented the unstable shell protocol in Chromium was no longer used by real clients. Of 30 thousand recorded uses of the Wayland backend, only 3 (yeah, just three) used the unstable interface. The time had come to get rid of the legacy, which was more than one thousand lines of code.

Some bits of the support for alternative shell interfaces is preserved, though. A special factory class named ui::ShellObjectFactory is used to hide the implementation details of the shell objects. Before getting rid of the unstable shell implementation, the primary use of the factory was to select the XDG shell interface supported by the host. However, it also made it possible to integrate easily with the alternative shells. For that purpose, mainly for the downstream projects, the factory will remain.

Once upon a time…

10 years ago I landed my first WebKit patch 🎂:

Bug 107275 - [GTK] Implement LayoutTestController::addUserScript

That was my first patch to a web engine related project, and also my first professional C++ patch. My previous work at Igalia was around web applications development with PHP and Java. At that time, 2013, Igalia had been already involved on web rendering engines for several years, and the work around web applications was fading out inside the company, so moving to the other side of the platform looked like a good idea. 10 years have passed and lots of great things have happened.

Since that first patch many more have come mostly in Chromium/Blink and WebKit; but also in WPT, CSS, HTML and other specs; and just a few, sadly, in Gecko (I’d love to find the opportunity to contribute there more at some point). I’ve became committer and reviewer in both Chromium and WebKit projects. I’m also member of the CSS Working Group (though not very active lately) and Blink API owner.

During these years I have had the chance to attend several events, spoke at a few conferences, got some interviews. I’ve been also helping to organize the Web Engines Hackfest since 2014 and a CSSWG face-to-face meeting at Igalia headquarters in A Coruña in January 2020 (I have so great memories of the last dinner).

These years have allowed me to meet lots of wonderful people from which I’ve learnt, and still learn every day, many things. I have the pleasure to work with amazing folks on a daily basis in the open. Every new feature or project in which I have to work, it’s again a new learning experience, and that’s something I really like about this kind of work.

In this period I’ve seen Igalia grow a lot in the web platform community, to the point that these days we’re the top world consultancy on the web platform, with an important position in several projects and standards bodies. We’re getting fairly well know in this ecosystem, and we’re very proud about having achieved that.

Looking back, I’m so grateful for the opportunity given by Igalia. Thanks to the amazing colleagues and the community and how they have helped me to contribute work on the different projects. Also thanks to the different customers that have allowed me to work upstream and develop my career around web browsers. 🙏 These days the source code I write (together with many others) is being used daily by millions of people, that’s totally unbelievable if you stop for a minute to think about it.

Looking forward to the next decade of involvement in the web platform. See you all on the web! 🚀

A lightning guide for building WPE WebKit with buildroot

This tutorial will be for getting “up and running” with WPE WebKit using a Raspberry Pi 3 using a laptop/desktop with Linux Fedora installed. WPE WebKit has many benefits; you may read here about why WPE WebKit is a great choice for embedded devices. WPE WebKit has minimal dependencies and it displays high-quality animations, WebGL and videos on embedded devices.

WebPlatformForEmbedded is our focus; for this tutorial, we’ll be building WPE WebKit with buildroot to build our image, so, make sure to clone the buildroot repository.

You will need:

Raspberry pi 3 items:

• A raspberry pi 3.
• A microSD card for the pi. (I usually choose 32GB microSD cards).
• An external monitor, extra mouse, and extra keyboard for our rpi3, separately from the laptop.
• An HDMI cable to connect the rpi3 to its own external monitor.

Laptop items:

• Linux laptop/desktop.
  • This tutorial will be based on Fedora, but you can use Debian or any distro of your choice.
• You also need a way to interface the microSD card with your laptop. You can get an SD Adapter for laptops that have an SD Card adapter slot, or you can use an external SD Card adapter interface for your computer.
  • This tutorial will be based on having a laptop with an SD card slot, and hence an SD Card Adapter will work just fine.

Items for laptop to communicate with rpi3:

• An ethernet cable to connect the rpi3 to your laptop.
• You need some way to get ethernet into your laptop. This is either in the form of an ethernet port on your laptop (not likely), or an adapter of some sort (likely a USB adapter).

Steps: High level overview

This is a high level overview of the steps we will be taking.

1. Partition the blank SD card.
2. In the buildroot repository, make <desired_config>.
3. Run the buildroot menuconfig with make menuconfig to set up .config file.
4. Run make to build sdcard.img in buildroot/output dir; change .config settings as needed.
5. Write sdcard.img file to the SD card.
6. Connect the rpi3 to its own external monitor, and its own mouse and keyboard.
7. Connect the rpi3 to the laptop using ethernet cable.
8. Put the SD card into the rpi3.
9. Setup a shared ethernet connection between the laptop and rpi to get the IP address of rpi.
10. ssh into the rpi and start WPE WebKit.

Steps: Detailed overview/sequence

1. Partition the blank SD card using fdisk. Create a boot partition and a root partition.

• Note: this is only needed in case the output image format is root.tar. If it’s sdcard.img, then that is dumped directly to the sdcard, that image is already partitioned internally.
• If you’re unfamiliar with fdisk, this is a good tutorial.

2. In the buildroot repository root directory, make the desired config.

• Make sure to clone the buildroot repository.
• Since things change a lot over time, it’s important to note the specific buildroot commit this tutorial was built on, and that this tutorial was built on January 12th, 2023. It is recommended to build from that commit for consistency to ensure that the tutorial works for you.
• We are building the cog 2.28 wpe with buildroot. See the build options from the buildroot repository.
• Run make list-defconfigs to get a list of configurations.
• Copy raspberrypi3_wpe_2_28_cog_defconfig and run it: make raspberrypi3_wpe_2_28_cog_defconfig.
• You will quickly get output which indicates that a .config file has been written in the root directory of the buildroot repository.

3. Run the buildroot menuconfig with make menuconfig to set up .config file.

• Run make menuconfig. You’ll see options here for configuration. Go slowly and be careful.
• Change these settings. Help menus are available for menuconfig, you’ll see them displayed on the screen.

4. Run make to build sdcard.img in buildroot/output dir; change .config settings as needed.

• Run make. Then get a coffee as the build and cross-compilation will take awhile.

• In reality, you may encounter some errors along the way, as cross-compilation can be an intricate matter. This tutorial will guide you through those potential errors.
• When you encounter errors, you’ll follow a “loop” of sorts:

  Run make -> encounter errors -> manually edit .config file -> -> remove buildroot/output dir -> run make again until sdcard.img is built successfully.

• If you encounter CMake errors, such as fatal error: stdlib.h: No such file or directory, compilation terminated, and you have a relatively new version of CMake on your system, the reason for the error may be that buildroot is using your local CMake instead of the one specified in the buildroot configuration.
  • We will fix this error by setting in .config file: BR2_FORCE_HOST_BUILD=y. Then remove buildroot/output dir, and run make again.
• If you encounter error such as path/to/buildroot/output/host/lib/gcc/arm-buildroot-linux-gnueabihf/9.2.0/plugin/include/builtins.h:23:10: fatal error: mpc.h: No such file or directory:
• then we can fix this error by changing Makefile in ./output/build/linux-rpi-5.10.y/scripts/gcc-plugins/Makefile, by adding -I path/to/buildroot/output/host/include in plugin_cxxflags stanza. Then, as usual, remove buildroot/output dir, and run make again.

5. Write sdcard.img file to the SD card.

• At this point after the make process, we should have sdcard.img file in buildroot/output/images directory.
• Write this file to the SD card.
• Consider using Etcher to do so.

6. Connect the rpi3 to its own external monitor, and its own mouse and keyboard.

• We’ll have separate monitor, mouse and keyboard all connected to the raspberry pi so that we can use it independently from the laptop.

7. Connect the rpi3 to the laptop using ethernet cable.

8. Put the SD card into the rpi3.

9. Setup a shared ethernet connection between the laptop and rpi to get the IP address of rpi.

In general, one of the main problems for connecting via ssh to the Raspberry Pi is to know the IP address of the device. This is very simple with Raspbian OS; simply turn on the raspberry pi and edit configurations to enable ssh, often over wifi.

This is where the ethernet capabilities of the raspberry pi come in.

Goal: To find syslog message DHCPACK acknowledgement and assignment of the IP address after setting up shared connection between raspberry pi and the laptop.

Throughout this process, continually look at logs. Eventually we will see a message DHCPACK which will likely be preceded by several DHCP handshake related messages such as DHCP DISCOVER, REQUEST etc. The DHCPACK message will contain the IP address of the ethernet device, and we will then be able to ssh into it.

• 1. Tail the syslogs of the laptop. On Debian distributions, this is often /var/log/syslog. Since we are using Fedora, we’ll be using systemd's journald with the journactl command:
     • sudo journalctl -f
     • Keep this open in a terminal window.
     • You can also come up with a better solution like grepping logs, if you like, or piping output of stdout elsewhere.
• 1. In a second terminal window, open up the NetworkManager.
     • Become familiar with existing devices prior to powering on the raspberry pi, by running nmcli.
• 1. Power on the raspberry pi. Watch your system logs.
     • Syslogs will detail the raspberry pi’s name.
• 1. Look for that name in NetworkManager nmcli device.
     • Using NetworkManager nmcli, set up shared connection for the ethernet device.
     • Setting up a shared connection is as simple as nmcli connection add type ethernet ifname $ETHERNET_DEVICE_NAME ipv4.method shared con-name local
     • This is a good tutorial for setting up a shared connection with NetworkManager.
• 1. Once the connection is shared, syslogs will show a DHCPACK message acknowledging the ethernet device and its IP address. (You may need to power cycle the rpi to see this message, but it will happen).

10. ssh into the rpi and start WPE WebKit.

• Now that we have the IP address of the raspberry pi, we can ssh into it from the laptop: ssh root@<RPI3_IP_ADDRESS>. (The default password is ‘root’. You can also add your user public key to /root/.ssh/authorized_keys on the pi. You can simplify this process by creating an overlay/root/.ssh/authorized_keys on your computer and by specifying the path to the overlay directory in the BR2_ROOTFS_OVERLAY config variable. That will copy everything in the overlay dir to the image.)
• After that, export these env variables WPE_BCMRPI_TOUCH=1 and WPE_BCMRPI_CURSOR=1 to enable keyboard and mouse control.
  • Why: Recall that generally WPE WebKit is for embedded devices, such as kioks, or set top boxes requiring control with a remote control or similar device or touch interaction. We are exporting these environment variables so that we can “test” WPE WebKit with our separate mouse and keyboard for our raspberry pi without the need for a touch screen or special hardware targets, or a Wayland compositor such as weston. If this piques your curiosity, please see the WPE WebKit FAQ on Wayland.
• Start WPE WebKit with cog: cog "http://www.igalia.com/"
• A browser will launch in the external monitor connected to the raspberry pi 3, and we can control the browser with the raspberry pi’s mouse and keyboard!

That’s all for now. Feel free to reach out in the support channels for WPE on Matrix.

WPE’s Frequently Asked Questions

• https://wpewebkit.org/about/faq.html

Spurred by a toot in reply to a goofy dev joke I made, I’ve set up a dirty-rough Dark Mode handler for meyerweb:

@media (prefers-color-scheme: dark) {
	html body {filter: invert(1);}
	/* the following really should be managed by a cascade layer */
	html img, 
	html img.book.cover, 
	html img.book.cover.big, 
	html #archipelago a:hover img {filter: invert(1);}
	html #thoughts figure.standalone img {
	  box-shadow: 0.25em 0.25em 0.67em #FFF8;
	}
}

It’s the work of about five minutes’ thought and typing, so I suspect it’s teetering on the edge of Minimum Viable Product, but I’m not sure which side of that line it lands on.

Other than restructuring things so that I can use Cascade Layers to handle the Light and Dark Mode styling, what am I missing or overlooking?  <video> elements, I suppose, but anything else jump out at you as in need of correction?  Let me know!

(P.S. “Use only classes, never IDs” is not something that needs to be corrected.  Yes, I know why people think that, and this situation seems to be an argument in favor of that view, but I have a different view and will not be converting IDs to classes.  Thanks in advance for your forbearance.)

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

We haven’t posted updates to the work done on the V3DV driver since
we announced the driver becoming Vulkan 1.2 Conformant

But after reaching that milestone, we’ve been very busy working on more improvements, so let’s summarize the work done since then.

Moved more functionality to the GPU

Our implementation for Events and Occlusion Queries were both mostly CPU based. We have refactored both features with a new GPU-side implementation based on the use of compute shaders.

In addition to be more “the Vulkan way”, has additional benefits. For example, for the case of the events, we no longer need to stall on the CPU when we need to handle GPU-side event commnds, and allowed to re-enable sync_fd import/export.

VK_KHR_sampler_ycbcr_conversion

We have just landed a real implementation for this extension, based on the work of Ella Stanforth as part of her Igalia Coding Experience with us. This was a really complex work, as this feature added support for multi-plane formats, and needed to modify various parts of the driver. A big kudos to Ella for getting this tricky feature going. Also thanks to Jason Ekstrand, as he worked on a common Mesa framework for ycbcr support.

Support for new extensions

Since 1.2 got announced the following extension got exposed:

• VK_EXT_texel_buffer_alignment
• VK_KHR_maintenance4
• VK_KHR_zero_initialize_workgroup_memory
• VK_KHR_synchronization2
• VK_KHR_workgroup_memory_explicit_layout
• VK_EXT_tooling_info (0 tools exposed though)
• VK_EXT_border_color_swizzle
• VK_EXT_shader_module_identifier
• VK_EXT_depth_clip_control
• VK_EXT_attachment_feeback_loop_layout
• VK_EXT_memory_budget
• VK_EXT_primitive_topology_list_restart
• VK_EXT_load_store_op_none
• VK_EXT_image_robustness
• VK_EXT_pipeline_robustness
• VK_KHR_shader_integer_dot_product

Some miscellanea

In addition to those, we also worked on the following:

• Implemented heuristic to decide to enable double-buffer mode, that could help to improve performance on some cases. It still needs to be enabled through the V3D_DEBUG environment variable.

• Getting v3dv and v3d using the same shader optimization method, that would allow to reuse more code between the OpenGL and Vulkan driver.

• Getting the driver working with the fossilize-db tools

• Bugfixing, mostly related to bugs identified through new Khronos CTS releases

Relationship between FrameTreeNode and RenderFrameHost in MPArch

Navigation changes to support multiple pages in WebContents

Navigation changes to support multiple pages in WebContents

Reference FrameTreeNode from RenderFrameHost

  // - Owning FrameTreeNode for main RenderFrameHosts in kActive, kPrerender,
  //   kSpeculative or kPendingCommit lifecycle states.
  // - Null for main RenderFrameHosts in kPendingDeletion lifecycle state.
  // - Null for main RenderFrameHosts stored in BFCache.
  // - Owning FrameTreeNode for subframes (which stays the same for the entire
  //   lifetime of a subframe RenderFrameHostImpl).

//content/browser/renderer_host/render_frame_host_impl.h

It’s been 8 years since the last time I wrote a videogame just for personal fun. As it’s now become a tradition, I took advantage of the extra focused personal time I usually have on the Christmas season and gave a try to Processing to do my own “advent of code”. It’s a programming environment based on Java that offers a similar visual, canvas-based experience to the one I enjoyed as a child in 8 bit computers. I certainly found coding there to be a pleasant and fun experience.

So, what I coded is called Cat’s Panic, my own version of a known arcade game with a similar name. In this version, the player has to unveil the outline of a hidden cute cat on each stage.

The player uses the arrow keys to control a cursor that can freely move inside a border line. When pressing space, the cursor can start an excursion to try to cover a new area of the image to be unveiled. If any of the enemies touches the excursion path, the player loses a life. The excursion can be canceled at any time by releasing the space key. Enemies can be killed by trapping them in a released area. A stage is completed when 85% of the outline is unveiled.

Although this game is released under GPLv2, I don’t recommend anybody to look at its source code. It breaks all principles of good software design, it’s messy, ugly, and it’s only purpose was to make the developing process entertaining for me. You’ve been warned.

I’m open to contributions in the way of new cat pictures that add more stages to the already existing ones, though.

You can get the source code in the GitHub repository and a binary release for Linux here (with all the Java dependencies, which weight a lot).

Meow, enjoy!

2022 was a good year for the Web Platform team in Igalia in a lot of ways. We worked on some really interesting Web technologies, and explored some really interesting new ways of funding them. We hired some great new people, and attended and spoke at some great events. And we did some of our meetings in person!

Projects

Open Prioritization Projects

In 2020 Igalia launched the Open Prioritization experiment. It is an experiment in crowd-funding prioritization of new feature implementations for web browsers.

• :focus-visible in WebKit

Our first Open-Priotization experiment to choose a project to crowdfund launched with 6 possible candidates representing work in every browser engine, across many areas of the platform and at various stages of completeness. According to the pledges that different projects got, :focus-visible in WebKit stood out and became the winner. Rego worked on this feature in 2021 and he had been reporting regularly about his progress. :focus-visible was finally enabled by default in WebKit and shipped in Safari 15.4.

Bear in mind that Apple Did Not Crowdfund :focus-visible in Safari. Eric made it very clear in his blog that, “the addition of :focus-visible to WebKit was lead by the community, done by Igalia, and contributed to WebKit without any involvement from Apple except in the sense of their reviewing patches and accepting the contributions”.

• Enter: Wolvic

In February 2022, Igalia announced Wolvic, a new browser project with an initial focus of picking up where Firefox Reality leaves off. Brian published Enter: Wolvic explaining what WebXR could bring and Igalia’s initial focus with Wolvic. As an open collective project, Wolvic Collective is seeking more partners and collective funding to further explore the potential and capability of WebXR technology. To understand in details about this project, please follow Brian’s talk on Wolvic’s vision.

The igalians involved in the Wolvic project have put a lot of effort on updating and nurturing the Firefox Reality codebase. Follow the commits by Sergio (@svillar), Felipe(@felipeerias) and Edu (@elima) from Web Platform team at Wolvic Github codebase.

• MathML

As part of the Open Prioritization effort, it’s exciting that MathML is going to be shipped in in Chrome 109. MathML collective is also part of our open collective effort. The plan is to have MathML-Core support in other browsers for browser interoperability. The MathML-Core support is level 1 for this project. We have envisioned more work to follow and will move to Level 2 after that. Your supports would make a lot of difference to move this forward.

Other Collaborative Projects

Most projects happening in the team are collaborative efforts with our clients and other parties in the Open Source community.

• :has()

The :has() pseudo class is a selector that specifies an element which has at least one element that matches the relative selector passed as an argument. Byungwoo (@byungwoo_bw on Twitter) started the prototyping work since 2021 and It’s shipped in Chromium 105 this year.

CSS :has() pseudo-class is a very exciting feature. Igalians have been talking about it since its initial stage of filing an intent to prototype. Byungwoo presented implementation and performance details in Blinkon 16. And you can find a recent blog on examples of using it by Eric. In addition, Byungwoo had a talk on Updates since has was enabled in Chrome.

• CSS highlight pseudos

Since 2021, Delan has been working on spelling and grammar features in Chromium. She has been writing a series on development of this work ( Chromium spelling and grammar features and Chromium spelling and grammar, part 2). As the project progresses, Delan produced her third part of the series on CSS highlight pseudos.

• Custom Handlers component for Chrome

Igalia has been working on improving the integration of the IPFS protocol in the main browsers. Javier has been blogging on his work including New Custom Handlers component for Chrome to introduce some architectural changes in Chrome to move the Custom Handlers logic into a new component, and Discovering Chrome’s pre-defined
Custom Handlers to discuss feasible solutions.

• Automated accessibility testing

The Web Platform team has been engaging in various aspects of accessiblity work in Browser, from web standard to solutions. The Automated accessibility testing by Alex is a reflection of our knowledge on testing.

• WPT Python 3 Migration

In 2020, Igalia was involved in the Python 3 migration work for the web-platform-tests (WPT) project. The WPT Python 3 Migration Post walks through challenges, approaches and some implementations for this migration work.

As always, there are a lot of other Web technology topics Igalians are working on. We recommend you to follow Brian’s blog and Eric’s blog for updates.

Conferences & Events

The Web Platform team were able to attend some conferences and Events on-site this year after the Covid-19 Pandemic. Here are some highlights.

• Igalia Summit and Web Engines Hackfest

With employees distributed in over 20 countries globally and most are working remotely, Igalia holds summits every year to give the employees opportunities to meet face-to-face. The summit normally runs in a period of a week with Hackfest, code camps, team building and recreational activities etc..

As it is a great opportunity to bring together people working on the different browsers and related standards to discuss ideas and plans, during the summit week Igalia normally hosts Web Engines Hackfest to invite members from all parts of the Web Platform community. This year’s Hackfest was a success with over 70 people attendees during 2 days involving lots of discussions and conversations around different features. Rego noted down his personal highlights for the event. Frédéric also published the status Update on OpenType MATH fonts.

The summit is a great event for Igalians gathering together. For a new joiner, it’s a great first summit. And for an experienced Igalian, there are a lot to take away too.

• Blinkon 17

Blinkon 17 in November was a hybrid event hosted in the San Francisco Bay area as well as via the Internet. Igalia had a strong presence in the event with 7 Lightning Talks and three breakout talks. From the Web Platform team, Delan presented her work on Faster Style & Paint for CSS Highlights and Frédéric updated the status on MathML in his talk Shipping MathML in Chrome 109 in breakout sessions. Andreu’s lightning talk on Specifying Line-clamp is very interesting. And you might find the live session on History of the Web by Brian and Eric fascinating to follow.

• TPAC

TPAC this year is a hybrid event and rego was happy that he managed to travel away to TPAC 2022 after pandemic and meet so many people in real life again.

Hiring

Igalia has been hiring actively . Web Platform team is no exception. In his blog of Igalia Web Platform team is hiring , Rego explains how Igalia’s cooperative flat structure works and what you could expect working in Igalia. Web Platform team is a very friendly and hard-working team. The team’s blogs probably only show a small part of work happening in the team. If you’d like to know more, contact us. And even better if you are interested in joining the team, check on rego’s blog about how to apply.

We were all super excited that Alice Boxhall (@sundress on Twitter) joined the team in November 2022. Alice represented Igalia as a candidate for the W3C TAG election. Brian tells you in his blog Alice 2023 why we thought that Alice could be a good addition to the W3C TAG. Although the final result didn’t go our way, our support for Alice continues for the future :-).

Looking forward to 2023

With some exciting work planned for 2023, we are looking forward to another productive year ahead!

This is the third part of my “Turnips in the wild” blog post series where I describe how I found and fixed graphical issues in the Mesa Turnip Vulkan driver for Adreno GPUs. If you missed the first two parts, you can find them here:

• Turnips in the wild (Part 1)
• Turnips in the wild (Part 2)

Table of Contents

1. Psychonauts 2
   1. Step 1 - Toggling driver options
   2. Step 2 - Finding the Draw Call and staring at it intensively
   3. Step 3 - Bisecting the shader until nothing is left
   4. Step 4 - Going deeper
      1. Loading varyings
      2. Packing varyings
      3. Interpolating varyings
2. Injustice 2
3. Monster Hunter: World

Psychonauts 2

A few months ago it was reported that “Psychonauts 2” has rendering artifacts in the main menu. Though only recently I got my hands on it.

Step 1 - Toggling driver options

Forcing direct rendering, forcing tiled rendering, disabling UBWC compression, forcing synchronizations everywhere, and so on, nothing helped or changed the outcome.

Step 2 - Finding the Draw Call and staring at it intensively

When looking around the draw call, everything looks good, but a single input image:

Ughhh, it seems like this image comes from the previous frame, that’s bad. Inter-frame issues are hard to debug since there is no tooling to inspect two frames together…

* Looks around nervously *

Ok, let’s forget about it, maybe it doesn’t matter. Then next step would be looking at the pixel values in the corrupted region:

Now, let’s see whether RenderDoc’s built-in shader debugger would give us the same value as GPU or not.

(Or not)

After looking at the similar pixel on the RADV, RenderDoc seems right. So the issue is somewhere in how driver compiled the shader.

Step 3 - Bisecting the shader until nothing is left

A good start is to print the shader values with debugPrintfEXT, much nicer than looking at color values. Adding the debugPrintfEXT aaaand, the issue goes away, great, not like I wanted to debug it or anything.

Adding a printf changes the shader which affects the compilation process, so the changed result is not unexpected, though it’s much better when it works. So now we are stuck with observing pixel colors.

Bisecting a shader isn’t hard, especially if there is a reference GPU, with the same capture opened, to compare the changes. You delete pieces of the shader until results are the same, when you get the same results you take one step back and start removing other expressions, repeat until nothing could be removed.

float _258 = 1.0 / gl_FragCoord.w;
vec4 _273 = vec4(_222, _222, _222, 1.0) * _258;
vec4 _280 = View.View_SVPositionToTranslatedWorld * vec4(gl_FragCoord.xyz, 1.0);
vec3 _284 = _280.xyz / vec3(_280.w);
vec3 _287 = _284 - View.View_PreViewTranslation;
vec3 _289 = normalize(-_284);
vec2 _303 = vec2(in_var_TEXCOORD0[0].x, in_var_TEXCOORD0[0].y) * Material.Material_ScalarExpressions[0].x;
vec4 _309 = texture(sampler2D(Material_Texture2D_0, Material_Texture2D_0Sampler), _303, View.View_MaterialTextureMipBias);
vec2 _312 = (_309.xy * vec2(2.0)) - vec2(1.0);
vec3 _331 = normalize(mat3(in_var_TEXCOORD10_centroid.xyz, cross(in_var_TEXCOORD11_centroid.xyz, in_var_TEXCOORD10_centroid.xyz) * in_var_TEXCOORD11_centroid.w, in_var_TEXCOORD11_centroid.xyz) * normalize((vec4(_312, sqrt(clamp(1.0 - dot(_312, _312), 0.0, 1.0)), 1.0).xyz * View.View_NormalOverrideParameter.w) + View.View_NormalOverrideParameter.xyz)) * ((View.View_CullingSign * View_PrimitiveSceneData._m0[(in_var_PRIMITIVE_ID * 37u) + 4u].w) * float(gl_FrontFacing ? (-1) : 1));


vec2 _405 = in_var_TEXCOORD4.xy * vec2(1.0, 0.5);
vec4 _412 = texture(sampler2D(LightmapResourceCluster_LightMapTexture, LightmapResourceCluster_LightMapSampler), _405 + vec2(0.0, 0.5));
uint _418 = in_var_LIGHTMAP_ID; // <<<<<<-
float _447 = _331.y;


vec3 _531 = (((max(0.0, dot((_412 * View_LightmapSceneData_1._m0[_418 + 5u]), vec4(_447, _331.zx, 1.0))))) * View.View_IndirectLightingColorScale);

bool _1313 = TranslucentBasePass.TranslucentBasePass_Shared_Fog_ApplyVolumetricFog > 0.0;
vec4 _1364;

vec4 _1322 = View.View_WorldToClip * vec4(_287, 1.0);
float _1323 = _1322.w;
vec4 _1352;
if (_1313)
{
    _1352 = textureLod(sampler3D(TranslucentBasePass_Shared_Fog_IntegratedLightScattering, View_SharedBilinearClampedSampler), vec3(((_1322.xy / vec2(_1323)).xy * vec2(0.5, -0.5)) + vec2(0.5), (log2((_1323 * View.View_VolumetricFogGridZParams.x) + View.View_VolumetricFogGridZParams.y) * View.View_VolumetricFogGridZParams.z) * View.View_VolumetricFogInvGridSize.z), 0.0);
}
else
{
    _1352 = vec4(0.0, 0.0, 0.0, 1.0);
}
_1364 = vec4(_1352.xyz + (in_var_TEXCOORD7.xyz * _1352.w), _1352.w * in_var_TEXCOORD7.w);

out_var_SV_Target0 = vec4(_531.x, _1364.w, 0, 1);

After that it became harder to reduce the code.

vec2 _303 = vec2(in_var_TEXCOORD0[0].x, in_var_TEXCOORD0[0].y);
vec4 _309 = texture(sampler2D(Material_Texture2D_0, Material_Texture2D_0Sampler), _303, View.View_MaterialTextureMipBias);
vec3 _331 = normalize(mat3(in_var_TEXCOORD10_centroid.xyz, in_var_TEXCOORD11_centroid.www, in_var_TEXCOORD11_centroid.xyz) * normalize((vec4(_309.xy, 1.0, 1.0).xyz))) * ((View_PrimitiveSceneData._m0[(in_var_PRIMITIVE_ID)].w) );

vec4 _412 = texture(sampler2D(LightmapResourceCluster_LightMapTexture, LightmapResourceCluster_LightMapSampler), in_var_TEXCOORD4.xy);
uint _418 = in_var_LIGHTMAP_ID; // <<<<<<-

vec3 _531 = (((dot((_412 * View_LightmapSceneData_1._m0[_418 + 5u]), vec4(_331.x, 1,1, 1.0)))) * View.View_IndirectLightingColorScale);

vec4 _1352 = textureLod(sampler3D(TranslucentBasePass_Shared_Fog_IntegratedLightScattering, View_SharedBilinearClampedSampler), vec3(vec2(0.5), View.View_VolumetricFogInvGridSize.z), 0.0);

out_var_SV_Target0 = vec4(_531.x, in_var_TEXCOORD7.w, 0, 1);

And finally, the end result:

vec3 a = in_var_TEXCOORD10_centroid.xyz + in_var_TEXCOORD11_centroid.xyz;
float b = a.x + a.y + a.z + in_var_TEXCOORD11_centroid.w + in_var_TEXCOORD0[0].x + in_var_TEXCOORD0[0].y + in_var_PRIMITIVE_ID.x;
float c = b + in_var_TEXCOORD4.x + in_var_TEXCOORD4.y + in_var_LIGHTMAP_ID;

out_var_SV_Target0 = vec4(c, in_var_TEXCOORD7.w, 0, 1);

Nothing left but loading of varyings and the simplest operations on them in order to prevent their elimination by the compiler.

in_var_TEXCOORD7.w values are several orders of magnitude different from the expected ones and if any varying is removed the issue goes away. Seems like an issue with loading of varyings.

I created a simple standalone reproducer in vkrunner to isolate this case and make my life easier, but the same fragment shader passed without any trouble. This should have pointed me to undefined behavior somewhere.

Step 4 - Going deeper

Anyway, one major difference is the vertex shader, changing it does “fix” the issue. Though changing it resulted in the changes in varyings layout, without changing the layout the issue is present. Thus the vertex shader is an unlikely culprit here.

Let’s take a look at the fragment shader assembly:

bary.f r0.z, 0, r0.x
bary.f r0.w, 3, r0.x
bary.f r1.x, 1, r0.x
bary.f r1.z, 4, r0.x
bary.f r1.y, 2, r0.x
bary.f r1.w, 5, r0.x
bary.f r2.x, 6, r0.x
bary.f r2.y, 7, r0.x
flat.b r2.z, 11, 16
bary.f r2.w, 8, r0.x
bary.f r3.x, 9, r0.x
flat.b r3.y, 12, 17
bary.f r3.z, 10, r0.x
bary.f (ei)r1.x, 16, r0.x
....

Loading varyings

bary.f loads interpolated varying, flat.b loads it without interpolation. bary.f (ei)r1.x, 16, r0.x is what loads the problematic varying, though it doesn’t look suspicious at all. Looking through the state which defines how varyings are passed between VS and FS also doesn’t yield anything useful.

Ok, but what does second operand of flat.b r2.z, 11, 16 means (the command format is flat.b dst, src1, src2). The first one is location from where varying is loaded, and looking through the Turnip’s code the second one should be equal to the first otherwise “some bad things may happen”. Forced the sources to be equal - nothing changed… What have I expected? Since the standalone reproducer with the same assembly works fine.

The same description which promised bad things to happen also said that using 2 immediate sources for flat.b isn’t really expected. Let’s revert the change and get something like flat.b r2.z, 11, r0.x, nothing is changed, again.

Packing varyings

What else happens with these varyings? They are being packed! To remove their unused components, so let’s stop packing them. Aha! Now it works correctly!

Looking several times through the code, nothing is wrong. Changing the order of varyings helps, aligning them helps, aligning only flat varyings also helps. But code is entirely correct.

Though one thing changes, during the shuffling of varyings order I noticed that the resulting misrendering changed, so likely it’s not the order, but the location which is cursed.

Interpolating varyings

What’s left? How varyings interpolation is specified. The code emits interpolations only for used varyings, but looking closer the “used varyings” part isn’t that obviously defined. Emitting the whole interpolation state fixes the issue!

The culprit is found, stale data is being read of varying interpolation. The resulting fix could be found in tu: Fix varyings interpolation reading stale values + cosmetic changes

Injustice 2

Another corruption in the main menu.

How it should look:

The draw call inputs and state look good enough. So it’s time to bisect the shader.

Here is the output of the reduced shader on Turnip:

Enabling the display of NaNs and Infs shows that there are NaNs in the output on Turnip (NaNs have green color here):

While the correct rendering on RADV is:

Carefully reducing the shader further resulted in the following fragment which reproduces the issue:

r12 = uintBitsToFloat(uvec4(texelFetch(t34, _1195 + 0).x, texelFetch(t34, _1195 + 1).x, texelFetch(t34, _1195 + 2).x, texelFetch(t34, _1195 + 3).x));
....
vec4 _1268 = r12;
_1268.w = uintBitsToFloat(floatBitsToUint(r12.w) & 65535u);
_1275.w = unpackHalf2x16(floatBitsToUint(r12.w)).x;

On Turnip this _1275.w is NaN, while on RADV it is a proper number. Looking at assembly, the calculation of _1275.w from the above is translated into:

isaml.base0 (u16)(x)hr2.z, r0.w, r0.y, s#0, t#12
(sy)cov.f16f32 r1.z, hr2.z

In GLSL there is a read of uint32, stripping it of the high 16 bits, then converting the lower 16 bits to a half float.

In assembly the “read and strip the high 16 bits” part is done in a single command isaml, where the stripping is done via (u16) conversion.

At this point I wrote a simple reproducer to speed up iteration on the issue:

result = uint(unpackHalf2x16(texelFetch(t34, 0).x & 65535u).x);

After testing different values I confirmed that (u16) conversion doesn’t strip higher 16 bits, but clamps the value to 16 bit unsigned integer. Running the reproducer on the proprietary driver shown that it doesn’t fold u32 -> u16 conversion into isaml.

Knowing that the fix is easy: ir3: Do 16b tex dst folding only for floats

Monster Hunter: World

Main menu, again =) Before we even got here two other issues were fixed before, including the one which seems like an HW bug which proprietary driver is not aware of.

In this case of misrendering the culprit is a compute shader.

How it should look:

Compute shader are generally easier to deal with since much less state is involved.

None of debug options helped and shader printf didn’t work at that time for some reason. So I decided to look at the shader assembly trying to spot something funny.

ldl.u32 r6.w, l[r6.z-4016], 1
ldl.u32 r7.x, l[r6.z-4012], 1
ldl.u32 r7.y, l[r6.z-4032], 1
ldl.u32 r7.z, l[r6.z-4028], 1
ldl.u32 r0.z, l[r6.z-4024], 1
ldl.u32 r2.z, l[r6.z-4020], 1

Negative offsets into shared memory are not suspicious at all. Were they always there? How does it look right before being passed into our backend compiler?

vec1 32 ssa_206 = intrinsic load_shared (ssa_138) (base=4176, align_mul=4, align_offset=0)
vec1 32 ssa_207 = intrinsic load_shared (ssa_138) (base=4180, align_mul=4, align_offset=0)
vec1 32 ssa_208 = intrinsic load_shared (ssa_138) (base=4160, align_mul=4, align_offset=0)
vec1 32 ssa_209 = intrinsic load_shared (ssa_138) (base=4164, align_mul=4, align_offset=0)
vec1 32 ssa_210 = intrinsic load_shared (ssa_138) (base=4168, align_mul=4, align_offset=0)
vec1 32 ssa_211 = intrinsic load_shared (ssa_138) (base=4172, align_mul=4, align_offset=0)
vec1 32 ssa_212 = intrinsic load_shared (ssa_138) (base=4192, align_mul=4, align_offset=0)

Nope, no negative offsets, just a number of offsets close to 4096. Looks like offsets got wrapped around!

Looking at ldl definition it has 13 bits for the offset:

<pattern pos="0"           >1</pattern>
<field   low="1"  high="13" name="OFF" type="offset"/>    <--- This is the offset field
<field   low="14" high="21" name="SRC" type="#reg-gpr"/>
<pattern pos="22"          >x</pattern>
<pattern pos="23"          >1</pattern>

With offset type being a signed integer (so the one bit is for the sign). Which leaves us with 12 bits, meaning the upper bound of 4095. Case closed!

I know that there is a upper bound set on offset during optimizations, but where and how it is set?

The upper bound is set via nir_opt_offsets_options::shared_max and is equal to (1 << 13) - 1, which we saw is incorrect. Who set it?

Subject: [PATCH] ir3: Limit the maximum imm offset in nir_opt_offset for
 shared vars

STL/LDL have 13 bits to store imm offset.

Fixes crash in CS compilation in Monster Hunter World.

Fixes: b024102d7c2959451bfef323432beaa4dca4dd88
("freedreno/ir3: Use nir_opt_offset for removing constant adds for shared vars.")

Signed-off-by: Danylo Piliaiev
Part-of: <https://gitlab.freedesktop.org/mesa/mesa/-/merge_requests/14968>
---
 src/freedreno/ir3/ir3_nir.c | 2 +-
 1 file changed, 1 insertion(+), 1 deletion(-)

@@ -124,7 +124,7 @@ ir3_optimize_loop(struct ir3_compiler *compiler, nir_shader *s)
           */
          .uniform_max = (1 << 9) - 1,

-         .shared_max = ~0,
+         .shared_max = (1 << 13) - 1,

Weeeell, totally unexpected, it was me! Fixing the same game, maybe even the same shader…

Let’s set the shared_max to a correct value . . . . . Nothing changed, not even the assembly. The same incorrect offset is still there.

After a bit of wandering around the optimization pass, it was found that in one case the upper bound is not enforced correctly. Fixing it fixed the rendering.

The final changes were:

• ir3: Reduce the maximum allowed imm offset for shared var load/store
• nir/nir_opt_offsets: Prevent offsets going above max

The NASCAR Model

Let's talk about interesting solutions to problems and how we can (today) begin to change things...

Over the past two years I’ve gone into a whole lot about the web ecosystem, and in particular the economics of it. I’ve made the case that the model we’ve built and grown for the last 20 years is ultimately fatally flawed. It is fundamentally dependent on a very few organizations. It is already inadequate and showing signs of strain.

I've been making a case for a while now that we need to re-think how we look at and fund web engines.

It seems really easy at some level, right? Just diversify the investment that is sponsoring work on engines. Every tech company in the world benefits from these projects, and lots of them make money hand over fist - giving back should be easy? But yeah, it's (currently) not and this should suprise no one. It isn't the norm, and companies don't like to spend money that they don't have to. Neither do we. We don't (currently) want to buy a browser or pay to use the open source project if we can avoid it, it's not the norm we're used to.

I was in the middle of trying to write something up on all of this just before the holidays (which got strange for me). I wanted to explain one such opportunity that we're building now, attempting to bend the arc of things in a healthier way. Before I could get back to post something, I saw Zach Leatherman post a thing on Mastodon:

the nascar car advertising model but for t-shirts on speakers at tech conferences

In reply, Chris Coyier shared screenshot of him wearing a F1 jacket that's full of logos like Red Bull, Tezos and Oracle.

To which I replied...

This, but for browser funding

While it sounds funny, and it obviously needs more words to explain it, I'm kind of serious.

It makes sense to look at history and try to learn from what worked (or didn't) elsewhere. It's interesting how many things seem to have followed a trend of getting a single original backer and ultimately diversifying. Lots of early TV shows had individual sponsors - soaps like Lux and cigarette companies like Winston, for example were, for decades even, lucrative single sources of funding.

While it's not what Zach was saying, it's interesting that for over 30 years, the NASCAR Cup Series was called the Winston Cup, until that became a problem. In 2004 it became the Nextel Cup, until it became the Sprint Cup, and then the Monster Energy Cup. Finally, in 2020 it just became the NASCAR Cup Series with a tiered sponsoship model and diverse sponsors.

You know, just like a lot of tech events.

Have a look at this page for AWS summit in DC sponsors for example. Or check out the video in this page for Salesforce's Dreamforce Sponsors. These pages are basically the NASCAR model. They are similarly tiered: you get different things for different levels of sponsorship. And those, I think, learn some things from what work for sports teams too. Here in Pittsbugh, for example, you'll see and hear ads that say "Proud Partner of the Pittsburgh Steelers". It costs money to be able to say that, and one of the things you get for that money is the ability to use the team's logo in your ad.

Spot the difference

A single event sponsorship can range from several thousand to literally millions of dollars. So, why do we get hundreds of tech companies to invest in sponsoring lots of events, or even putting their name on an actual NASCAR jacket (or car), but very few invest in web browsers?

I think the answer is pretty simple: Different departments and budgets.

Funding (from non-vendors) that goes into the browser engines today is coming from engineering departments of downstream products like Microsoft Edge or ad blocking extensions or the PlayStation 5. That's great, but engineering departments are constantly too tight already. Engineering is about efficiency, right? Do more with less.

Those sponsorships, on the other hand, are often marketing dollars (just like default search). Entirely different budgets/intents.

But, if you think about it, shouldn't those companies get some NASCAR-style credit for their browser support? Don't you think it's worth mentioning that Bloomberg Tech was really key to making CSS Grid Happen? Or that EyeO was really key to making :has() happen? Isn't that a kind of marketing? Don't we kind of need both kinds of investment?

Hey, there it is!

I haven't had much of a chance to talk about this yet, but have a look at this...

In February 2022, in a joint announcement with Mozilla, Igalia announced we'd be taking over stewardship of the project "Firefox Reality" which would now be called "Wolvic" with the tagline "Join the Pack". That's not just a cute slogan, it's kind of the whole idea. Rather than a singularly badass wolf, we need a pack.

We're trying some really interesting ideas with Wolvic to reimagine how we can fund the development of the browser, upstream work, and manage priorities. I talked about our plans in a small 'launch' event recently which you can watch if you like, but a brief summary is:

1. We're partnering with some device manufacturers directly at several different levels. On some (Lynx R1, Huawei Lens, HTC Vive) we will be the default browser and they will commit to some funding, and we'll work with them closely.
2. We're exploring other ideas with a new Wolvic collective. There are a lot of details there explaining all this, but just like other sponsorships, you get different things. One of those is being on a Sponsors page which will be in the browser itself too. Another is that you can help us figure out priorities.

I would encourage you to have a look at the collective page. Share it with your engineering department. Share it with your marketing department.

Or, just help be a part of sparking the change and contribute yourself. I think this isn't the worst idea - many of us (myself included) owe our entire careers to the web - your mileage and personal comfort levels may vary of course, but it doesn't feel wrong for me to throw a cup of coffee's worth of funding back to it every month.

I hope you'll help us explore these ideas, either through some funding, or just sharing the idea and encouraging organizations to participate (or all of the above).

Suppose that you have to hack a GStreamer element which requires a library that is not (yet) packaged by your distribution, nor wrapped as a Meson’s subproject. How do you do?

In our case, we needed the latest version of

• Vulkan-Headers
• Vulkan-Loader
• Vulkan-Tools

Which are interrelated CMake projects.

For these cases, GStreamer’s uninstalled development scripts can use a special directory: gstreamer/prefix. As the README.md says:

NOTE: In the development environment, a fully usable prefix is also configured in gstreamer/prefix where you can install any extra dependency/project.

This means that gstenv.py script (the responsible of setting up the uninstalled development environment) will add

• gstreamer/prefix/bin in PATH for executable files.
• gstreamer/prefix/lib and gstreamer/prefix/share/gstreamer-1.0 in GST_PLUGIN_PATH, for out-of-tree elements.
• gstreamer/prefix/lib in GI_TYPELIB_PATH for GObject Introspection metadata.
• gstreamer/prefix/lib/pkgconfig in PKG_CONFIG_PATH for third party dependencies (our case!)
• gstreamer/prefix/etc/xdg for XDG_CONFIG_DIRS for XDG compliant configuration files.
• gstreamer/prefix/lib and gstreamer/prefix/lib64 in LD_LIBRARY_PATH for third party libraries.

Therefore, the general idea, is to compile those third party libraries with their installation prefix as gstreamer/prefix.

In our case, Vulkan repositories are interrelated so they need to be compiled in certain order. Also, we decided, for self-containment, to clone them in gstreamer/subprojects.

Vulkan-Headers

$ cd ~/gst/gstreamer/subprojects
$ git clone git@github.com:KhronosGroup/Vulkan-Headers.git
$ cd Vulkan-Headers
$ mkdir build
$ cd build
$ cmake -GNinja -DCMAKE_BUILD_TYPE=Debug -DCMAKE_INSTALL_PREFIX=/home/vjaquez/gst/gstreamer/prefix ..
$ cmake --build . --install

Vulkan-Loader

$ cd ~/gst/gstreamer/subprojects
$ git clone git@github.com:KhronosGroup/Vulkan-Loader.git
$ cd Vulkan-Loader
$ mkdir build
$ cd build
$ cmake  -DCMAKE_BUILD_TYPE=Debug -DVULKAN_HEADERS_INSTALL_DIR=/home/vjaquez/gst/gstreamer/prefix DCMAKE_INSTALL_PREFIX=/home/vjaquez/gst/gstreamer/prefix ..
$ cmake --build . --install

Vulkan-Tools

$ cd ~/gst/gstreamer/subprojects
$ git clone git@github.com:KhronosGroup/Vulkan-Tools.git
$ cd Vulkan-Tools
$ mkdir build
$ cd build
$ cmake  -DCMAKE_BUILD_TYPE=Debug -DVULKAN_HEADERS_INSTALL_DIR=/home/vjaquez/gst/gstreamer/prefix DCMAKE_INSTALL_PREFIX=/home/vjaquez/gst/gstreamer/prefix ..
$ cmake --build . --install

Right now we have the Vulkan headers and the Vulkan loader pkg-config file in place. And we should be able to compile GStreamer. Right?

Not exactly, because gstenv.py only sets the environment variables for the development environment, not for GStreamer compilation. But the solution is simple, because we have all set in the proper order: just to set PKG_CONFIG_PATH when executing meson setup:

$ PKG_CONFIG_PATH=/home/vjaquez/gst/gstreamer/prefix/lib/pkgconfig meson setup --buildtype=debug build

Surreal Holiday

Hello, yes, I had a heart attack.

In the middle of the night last Tuesday (technically Wednesday morning), I had a heart attack. Ambulance, EKGs - you get the idea. In the end they placed two stents in my heart and I spent two days in the ICU, one more in the general hospital before being sent home Friday afternoon.

Mainly I just wanted to say...

• Sorry if I haven't replied somewhere
• That's why
• Thanks for the concern if you were worried
• I'm gonna be ok
• I am mostly ok now. I just happen to also have planned holidays, so it's been a good spot to disconnect for a bit.
• Yes, I quit smoking (8 days cold and counting).
• ... The whole thing was just... very weird

Surreal

In my experience - our brains are actually not very good at imagining the big "smack you in the face" things like this. When they happen I'm often like "Oh wow!... That was nothing like I imagined it would be."

Yes, I have imagined many of the bits here many times (I have an anxiety disoder) and this wasn't an exception. Literally no aspect of what unfolded was anything like I imagined it would be.

Short of literally sitting and imagining bad scenarios: I'm sure you think you have some idea of what a heart attack would feel like. Like, vaguely, at least. But... maybe you don't? Maybe it is very diffrent from that? It certainly was for me.

I guess the natural question is "different how?" and the answer is "yes".

Different like zuchini and cucumber, maybe? Superficially similar, but much different. If you bit into something thinking it contained lots of cucumber and that turned out to be zucchini (or vice versa) you would say "Oh wow!... That was nothing like I imagined it would be."

Anyway... I've been sitting here for way too long trying to think of how to explain all of the ways in which none of this was what I expected or how surreal it all felt, but honestly, I think I can't.

I spent a lot of time thinking about my family. Would they be ok, even if I wasnt? Pretty shitty for them to have this happen at Christmas. It was the middle of the night, most of them wouldn't find out for a while still probably. What would they be finding out?

I don't know, it was just many layers of strange, really.

One especially surreal moment I'd like to write down: As the doctors who were getting ready to put a stint in my heart were chatting, one of them said something like...

Man, can you imagine? So sad. Just before 50. He was looking great just yesterday, and then you just die. So sad.

Here's the thing: They weren't talking about me and I knew it. But, lying there on the table, not so short of 50 myself, at that moment... It totally could have... It still might, you know? They hadn't gone in yet. Did they just not think of that?

What they were talking about was the fact that Franco Harris had just died the same morning. It was just a few days shy of the 50th anniversay of The Immaculate Reception, a rematch game and so many events planned around it and him.

You don't really have to know about any of this, I guess - except that Franco's impact in Pittsburgh was huge and began just before I was born. My grandparents were part of the large Italian community that loved the Steelers - "Franco's Italian Army". I have a lot of memories of shared moments with family around the Steelers - ultimately because of all of this. I always felt a kind of connection with him. It was very strange to think that we we both seemed pretty great just yesterday, and now here we were.

Anyways.... It was weird.

Happily for my family, I made it through and I'm doing great.

I was home for the game too, which I was able to watch with my son. It was great - and happily for Pittsburgh, we won.

I’ve just committed my first :has() selector to production CSS and want to share it, so I will!  But first, a little context that will feel familiar to nerds like me who post snippets of computer code to the Web, and have markup with this kind of tree structure (not raw source; we’d never allow this much formatting whitespace inside a <pre>):

<pre>
	<code>
		{{content goes here}}
	</code>
</pre>

It’s nicely semantic, indicating that the contents of the <pre> are in fact code of some kind, as opposed to just plain preformatted text like, say, output from a shell script or npm job, which isn’t code and thus should, perhaps, be styled in a distinct way.

Given cases like that, you’ve probably written rules that go a little something like this:

pre > code {
	display: block;
	background: #f1f1f1;
	padding: 1.33em;
	border-radius: 0.33em;
}

Which says: if a <code> element is the child of a <pre> element, then turn the <code> into a block box and give it some background color, padding, etc.

It works out fine, but it always feels a little fragile.  What if there are already <pre> styles that throw off the intended effect on code blocks?  Do we get into specificity wars between those rules and the code-block rules?  Find other ways to figure out what should be adjusted in which cases?  Those are probably manageable problems, but it would be better not to have them.

It’s also, when you step back for a moment, a little weird.  The <pre> is already a block box and the container for the code; why aren’t we styling that?  Because unless you wrote some scripting, whether server-side or client-side, to add a class to the <pre> in scenarios like this, there wasn’t a way to address it directly based on its structural contents.

There is now:

pre:has(> code) {
	background: #f1f1f1;
	padding: 1.33em;
	border-radius: 0.33em;
}

Now I’m styling any <pre> that has a <code> as a child, which is why I took out the display: block.  I don’t need it any more!

But suppose you have a framework or ancient script or something that inserts classed <span> elements between the <pre> and the <code>, like this:

<pre>
	<span class="pref">
		<code>
			{{content goes here}}
		</code>
	</span>
</pre>

First of all, ew, address the root problem here if at all possible.  But if that isn’t possible for whatever reason, you can still style the <pre> based on the presence of a <code> by removing the child combinator from the selector.  In other words:

pre:has(code) {
	background: #f1f1f1;
	padding: 1.33em;
	border-radius: 0.33em;
}

Now I’m styling any <pre> that has a <code> as a descendant  —  child, grandchild, great-great-great-great grandchild, whatever.

Which is not only more robust, it’s a lot more future-proof: even if some hot new front-end framework that sticks in <span> elements or something gets added to the site next year, this style will just keep chugging along, styling <pre> elements that contain <code> elements until long after that hot new framework has cooled to ash and been chucked into the bit-bucket.

There is one thing to keep in mind here, as pointed out by Emmanuel over on Mastodon: if you have a scenario where <pre> elements can contain child text nodes in addition to <code> blocks, the <pre> will still be styled in its entirely.  Consider:

<pre>
	{{some text is here}}
	<code>
		{{content goes here}}
	</code>
	{{or text is here}}
</pre>

pre:has(> code) and pre:has(code) will still match the <pre> element here, which means all of the text (both inside and outside the <code> elements)  will sit inside the light-gray box with the rounded corners.  If that’s fine for your use case, great!  If not, then don’t use :has() in this scenario, and stick with the pre > code {…} or pre code {…} approach of yore.  That will style just the <code> elements instead of the whole <pre>, as in the example at the beginning of this article.

As I write this, the code hasn’t gone into production on wpewebkit.org yet, but I think it will within the next week or two, and will be my first wide-production use of :has().  I feel like it’s a great way to close out 2022 and kick off 2023, because I am that kind of nerd.  If you are too, I hope you enjoyed this quick dive into the world of :has().

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

This is the last blog post of the series. In first post I presented some concepts of call stack profiling, and why it is useful. In second post I reviewed Event Tracing for Windows, the native tool for the purpose, and how it can be used to trace Chromium.

This last post will review the work done in 2022 to improve the support in V8 of call stack profiling in Windows.

I worked on several of the fixes this year. This work has been sponsored by Bloomberg and Igalia.

This work was presented as a lightning talk in BlinkOn 17.

Some bad news to start… and a fix

In March I started working on the report that Windows event traces where not properly resolving the Javascript symbols.

After some bisecting I found this was a regression introduced by this commit, that changed the --js-flags handling to a later stage. This happened to be after V8 initialization, so the code that would enable instrumentation would not consider the flag.

The fix I implemented moved flags processing to happen right before platform initialization, so instrumentation worked again.

Simplified method names

Another fix I worked was to improve the methods name generation. Windows tracing would show a quite redundant description of each level, and that was making analysis more difficult.

Before my work, the entries would look like this:

string-tagcloud.js!LazyCompile:~makeTagCloud- string-tagcloud.js:231-232:22 0x0

After my change, now it looks like this:

string-tagcloud.js!makeTagCloud-231:22 0x0

The fix adds a specific implementation for ETW. Instead of reusing the method name that is also used for Perf, it has a specific implementation for function that takes into account what ETW backend exports already, to avoid redundancy. It also takes advantage of the existing method DebugNameCStr to retrieve inferred method names in case there is no name available.

Problem with Javascript code compiled before tracing

The way V8 ETW worked was that, when tracing was ongoing and a new function was compiled in JIT, it would emit information to ETW.

This implied a big problem. If a function was compiled by V8 before tracing started, then ETW would not properly resolve the function names so, when analyzing the traces, it would not be possible to know which function was called at any of the samples.

The solution is conceptually simple. When tracing starts, V8 traverse the living Javascript contexts and emit all the symbols. This adds noise to the tracing, as it is an expensive process. But, as it happens at the start of the tracing, it is very easy to isolate in the captured trace.

And a performance fix

I also fixed a huge performance penalty when tracing code from snapshots, caused by calculating all the time the end line numbers of code instead of caching it.

Initialization improvements

Paolo Severini improved the initialization code, so the initialization of an ETW session was lighter, and also tracing would be started or stopped correctly.

Benchmarking ETW overhead

After all these changes I did some benchmarking with and without ETW. The goal was knowing if it would be good to enable by default ETW support in V8, not requiring to pass any JS flag.

With Sunspider in a Windows 64 bits build:

Other benchmarks I tried gave similar numbers.

So far, in 64 bits architecture I could not detect any overhead of enabling ETW support when recording is not happening, and the cost when it is enabled is very low.

Though, when combined with interpreted frames native stack, the overhead is close to 10%. This was expected as explained here.

So, good news so far. We still need to benchmark 32 bit architecture to see if the impact is similar.

Try it!

The work described in this post is available in V8 10.9.0. I hope you enjoy the improvements, and specially hope these tools help in the investigation of performance issues around Javascript, in NodeJS, Google Chrome or Microsoft Edge.

What next?

There is still a lot of things to do, and I hope I can continue working on improvements for V8 ETW support next year:

• First, finishing the benchmarks, and considering to enable ETW instrumentation by default in V8 and derivatives.
• Add full support for WASM.
• Bugfixing, as we still see segments missing in certain benchnarmks.
• Create specific events for when the JIT information of already compiled symbols is sent to ETW, to make it easier to differenciate from the code compiled while recording a trace.

If you want to track the work, keep an eye on V8 issue 11043.

The end

This is the last post in the series.

Thanks to Bloomberg and Igalia for sponsoring my work in ETW Chromium integration improvements!

Its has been a while since I reported my tinkering with the Vulkan Video provisional extension. Now the specification will have its final release soonish, and also there has been more engagement within the open source communities, such as the work-in-progress FFMpeg implementation by Lynne (please, please, read that post), and the also work-in-progress Mesa 3D drivers both for AMD and Intel by Dave Airlie! Along with the well known NVIDIA beta drivers for Vulkan.

From our side, we have been trying to provide an open source alternative to the video parser used by the Conformance Test Suite and the NVIDIA
vk_video_samples, using GStreamer: GstVkVideoParser, which intends to be a drop-in replacement of the current proprietary parser library.

Along the way, we have sketched the Vulkan Video support in
gfxreconstruct, for getting traces of the API usage. Sadly, its kind of bit-rotten right now, even more because the specification has changed since then.

Regarding the H.264 decoder for GStreamer, we just restarted its hacking. The merge request was moved to monorepo, but for the sake of the well needed complete re-write, we changed the branch to this one (vkh264dec). We needed to re-write it because, besides the specification updates, we have learned many things along the journey, such as the out-of-band parameters update, Vulkan’s recommendation for memory pre-allocation as much as possible, the DPB/references handling, the debate about buffer vs. slice uploading, and other friction points that Lynne has spotted for future early adopters.

The way to compile it is grab the branch and compile as usually GStreamer is compiled with meson:

meson setup builddir -Dgst-plugins-bad:vulkan-video=enabled --buildtype=debug
ninja C builddir

And run simple pipelines such as

gst-launch-1.0 filesrc location=INPUT ! parsebin ! vulkanh264dec ! fakesink -v

Our objective is to have a functional demo for the next Vulkanised in
February. We are very ambitious, we want it to work in Linux, Windows and in many GPU as possible. Wish us luck. And happy December festivities!

Some time ago, I published user styles to visually highlight images on Twitter that didn’t have alt text  —  this was in the time before the “ALT” badge and the much improved accessibility features Twitter deployed in the pre-Musk era.

With the mass Mastodon migration currently underway in the circles I frequent, I spend more time there, and I missed the quick visual indication of images having alt text, as well as my de-emphasis styles for those images that don’t have useful alt text.  So I put the two together and wrote a new user stylesheet, which I apply via the Stylus browser extension.  If you’d like to also use it, please do so!

/* ==UserStyle==
@name           mastodon.social - 12/14/2022, 9:37:56 AM
@namespace      github.com/openstyles/stylus
@version        1.0.0
@description    Styles images posted on mastodon.social based on whether or not they have alt text.
@author         @Meyerweb@mastodon.social, https://meyerweb.com/
==/UserStyle== */

@-moz-document regexp(".*\.social.*") {
	.media-gallery__item-thumbnail img:not([alt]) {
		filter: grayscale(1) contrast(0.5);
	}
	.media-gallery__item-thumbnail img:not([alt]):hover {
		filter: none;
	}
	.media-gallery__item-thumbnail:has(img[alt]) {
		position: relative;
	}
	.media-gallery__item-thumbnail:has(img[alt])::after {
		content: "ALT";
		position: absolute;
		bottom: 0;
		right: 0;
		border-radius: 5px 0 0 0;
		border: 1px solid #FFF3;
		color: #FFFD;
		background: #000A;
		border-width: 1px 0 0 1px;
		padding-block: 0.5em 0.4em;
		padding-inline: 0.7em 0.8em;
		font: bold 90% sans-serif;
	}
}

Because most of my (admittedly limited and sporadic) Mastodon time is spent on mastodon.social, the styles I wrote are attuned to mastodon.social’s markup.  I set things up so these styles should be applied to any *.social site, but only those who use the same markup mastodon.social uses will get the benefits.  pinafore.social, for example, has different markup (I think they’re using Svelte).

You can always adapt the selectors to fit the markup of whatever Mastodon instance you use, if you’re so inclined.  Please feel free to share your changes in the comments, or in posts of your own.  And with any luck, this will be a temporary solution before Mastodon adds these sorts of things natively, just as Twitter eventually did.

Addendum: It was rightly pointed out to me that Firefox does not, as of this writing, support :has() by default.  If you want to use this in Firefox, as I do, set the layout.css.has-selector.enabled flag in about:config to true.

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

Mike Cowlishaw’s FAQ on dec­i­mal arith­metic

If you’re in­ter­est­ed in dec­i­mal arith­metic in com­put­ers, you’ve got to check out Mike Cowlishaw’s FAQ on the sub­ject. There’s a ton of in­sight to be had there. If you like the kind of writ­ing that makes you feel smarter as you read it, this one is worth your time.

For con­text: Cowlishaw is the ed­i­tor of the 2008 edi­tion of the IEEE 754 stan­dard, up­dat­ing the 1985 and 1987 stan­dards. The words thus car­ry a lot of au­thor­i­ty, and it would be quite un­wise to ig­nore Mike in these mat­ters.

If you pre­fer sim­i­lar in­for­ma­tion in ar­ti­cle form, take a look at Mike’s Dec­i­mal Float­ing-Point: Al­go­rism for Com­put­ers. (Note the de­light­ful use of al­go­rism. Yes, it’s a word.)

The FAQ fo­cused main­ly on float­ing-point dec­i­mal arith­metic, not ar­bi­trary-pre­ci­sion dec­i­mal arith­metic (which is what one might im­me­di­ate­ly think of when the one hears dec­i­mal arith­metic). Ar­bi­trary-pre­ci­sion dec­i­mal arith­metic is whole oth­er ball of wax. In that set­ting, we’re talk­ing about se­quences of dec­i­mal dig­its whose length can­not be spec­i­fied in ad­vance. Pro­pos­als such as dec­i­mal128 are about a fixed bit width—128 bits—which al­lows for a lot of pre­ci­sion, but not ar­bi­trary pre­ci­sion.

One cru­cial in­sight I take away from Mike’s FAQ—a real mis­un­der­stand­ing on my part which is a bit em­bar­rass­ing to ad­mit—is that dec­i­mal128 is not just a 128-bit ver­sion of the same old bi­na­ry float­ing-point arith­metic we all know about (and might find bro­ken). It’s not as though adding more bits meets the de­mands of those who want high-pre­ci­sion arith­metic. No! Al­though dec­i­mal128 is a fixed-width en­cod­ing (128 bits), the un­der­ly­ing en­cod­ing is dec­i­mal, not bi­na­ry. That is, dec­i­mal128 isn’t just bi­na­ry float­ing-point with ex­tra juice. Just adding bits won’t un­break bust­ed float­ing-point arith­metic; some new ideas are need­ed. And dec­i­mal128 is a way for­ward. It is a new (well, rel­a­tive­ly new) for­mat that ad­dress­es all sorts of use cas­es that mo­ti­vate dec­i­mal arith­metic, in­clud­ing needs in busi­ness, fi­nance, ac­count­ing, and any­thing that uses hu­man dec­i­mal num­bers. What prob­a­bly led to my con­fu­sion is think­ing that the ad­jec­tive float­ing-point, re­gard­less of what it mod­i­fies, must be some kind of vari­a­tion of bi­na­ry float­ing-point arith­metic.

Okay, I can’t believe I have to do this again.

This time, let’s leave the Hellsite out of it, and let’s try to be nuanced from the start. I’d like to avoid getting grief online.

The current state of the Python bindings for GObject-based libraries is making it really hard to recommend using Python as a language for developing GTK and GNOME applications.

PyGObject is currently undermaintained, even after the heroic efforts of Christoph Reiter to keep the fires burning through the long night. The Python community needs more people to work on the bindings, if we want Python to be a first class citizen of the ecosystem.

There’s a lot to do, and not nearly enough people left to do it.

Case study: typed instances

Yes, thou shall use GObject should be the law of the land; but there are legitimate reasons to use typed instances, and GTK 4 has a few of them:

• GtkExpression
• GskRenderNode
• GdkEvent

At this very moment, it is impossible to use the types above from Python. PyGObject will literally error out if you try to do so. There are technical reasons why that was a reasonable choice 15+ years ago, but most language bindings written since then can handle typed instances just fine. In fact, PyGObject does handle them, since GParamSpec is a GTypeInstance; of course, that’s because PyGObject has some ad hoc code for them.

Dealing with events and render nodes is not so important in GTK4; but not having access to the expressions API makes writing list widgets incredibly more complicated, requiring to set up everything through UI definition files and never modifying the objects programmatically.

Case study: constructing and disposing

While most of the API in PyGObject is built through introspection, the base wrapper for the GObject class is still very much written in CPython. This requires, among other things, wiring the class’s virtual functions manually, and figuring out the interactions between Python, GObject, and the type system wrappers. This means Python types that inherit from GObject don’t have automatic access to the GObjectClass.constructed and GObjectClass.dispose virtual functions. Normally, this would not be an issue, but modern GObject-based libraries have started to depend on being able to control construction and destruction sequences.

For instance, it is necessary for any type that inherits from GtkWidget to ensure that all its child widgets are disposed manually. While that was possible through the “destroy” signal in GTK3, in GTK4 the signal was removed and everything should go through the GObjectClass.dispose virtual function. Since PyGObject does not allow overriding or implementing that virtual function, your Python class cannot inherit from GtkWidget, but must inherit from ancillary classes like GtkBox or AdwBin. That’s even more relevant for the disposal of resources created through the composite template API. Theoretically, using Gtk.Template would take care of this, but since we cannot plug the Python code into the underlying CPython, we’re stuck.

Case study: documentation, examples, and tutorials

While I have been trying to write Python examples for the GNOME developers documentation, I cannot write everything by myself. Plus, I can’t convince Google to only link to what I write. The result is that searching for “Python” and “GNOME” or “GTK” will inevitably lead people to the GTK3 tutorials and references.

The fragmentation of the documentation is also an issue. The PyGObject website is off to readthedocs.org, which is understandable for a Python projects; then we have the GTK3 tutorial, which hasn’t been updated in a while, and for which there are no plans to have a GTK 4 version.

Additionally, the Python API reference is currently stuck on GTK3, with Python references for GTK4 and friends off on the side.

It would be great to unify the reference sites, and possibly have them under the GNOME infrastructure; but at this point, I’d settle for having a single place to find everything, like GJS did.

What can you do?

Pick up PyGObject. Learn how it works, and how the GObject and CPython API interact.

Write Python overrides to ensure that API like GTK and GIO are nice to use with idiomatic Python.

Write tests for PyGObject.

Write documentation.

Port existing tutorials, examples, and demos to GTK4.

Help Christoph out when it comes to triaging issues, and reviewing merge requests.

Join GNOME Python on Matrix, or the #gnome-python channel on Libera.

Ask questions and provide answers on Discourse.

What happens if nobody does anything?

Right now, we’re in maintenance mode. Things work because of inertia, and because nobody is really pushing the bindings outside of their existing functionality.

Let’s be positive, for a change, and assume that people will show up. They did for Vala when I ranted about it five years ago after a particularly frustrating week dealing with constant build failures in GNOME, so maybe the magic will happen again.

If people do not show up, though, what will likely happen is that Python will just fall on the wayside inside GNOME. Python developers won’t use GTK to write GUI applications; existing Python applications targeting GNOME will either wither and die, or get ported to other languages. The Python bindings themselves may stop working with newer versions of Python, which will inevitably lead downstream distributors to jettison the bindings themselves.

We have been through this dance with the C# bindings and Mono, and the GNOME and Mono communities are all the poorer for it, so I’d like to avoid losing another community of talented developers. History does not need to repeat itself.

Like many of you, I’ve been checking out Mastodon and finding more and more things I like.  Including the use of XFN (XHTML Friends Network) semantics to verify ownership of sites you link from your profile’s metadata!  What that means is, you can add up to four links in your profile, and if you have an XFN-compliant link on that URL pointing to your Mastodon profile, it will show up as verified as actually being your site.

Okay, that probably also comes off a little confusing.  Let me walk through the process.

First, go to your home Mastodon server and edit your profile.  On servers like mastodon.social, there should be an “Edit profile” link under your user avatar.

I saw the same thing on another Mastodon server where I have an account, so it seems to be common to Mastodon in general.  I can’t know what every Mastodon server does, though, so you might have to root around to find how you edit your profile.  (Similarly, I can’t be sure that everything will be exactly as I depict it below, but hopefully it will be at least reasonably close.)

Under “Appearance” in the profile editing screen, which I believe is the default profile editing page, there should be a section called “Profile metadata”.  You’ll probably have to scroll a bit to reach it.  You can add up to four labels with content, and a very common label is “Web” or “Homepage” with the URL of your personal server.  They don’t all have to be links to sites; you could add your favorite color or relationship preference(s) or whatever

But look, over there next to the table, there’s a “Verification” section, with a little bit of explanation and a field containing some markup you can copy, but it’s cut off before the end of the markup.  Here’s what mine looks like in full:

<a rel="me" href="https://mastodon.social/@Meyerweb">Mastodon</a>

If I take this markup and add it to any URL I list in my metadata, then that entry in my metadata table will get special treatment, because it will mean I’ve verified it.

The important part is the rel="me", which establishes a shared identity.  Here’s how it’s (partially) described by XFN 1.1:

A link to yourself at a different URL. Exclusive of all other XFN values. Required symmetric.

I admit, that’s written in terse spec-speak, so let’s see how this works out in practice.

First, let’s look at the markup in my Mastodon profile’s page.  Any link to another site in the table of profile metadata has a me value in the rel attribute, like so:

<a href="https://meyerweb.com/" rel="nofollow noopener noreferrer me">

That means I’ve claimed via Mastodon that meyerweb.com is me at another URL.

But that’s not enough, because I could point at the home page of, say, Wikipedia as if it were mine.  That’s why XFN requires the relationship to be symmetric, which is to say, there needs to be a rel="me" annotated link on each end.  (On both ends.  However you want to say that.)

So on the page being pointed to, which in my case is https://meyerweb.com/, I need to include a link back to my Mastodon profile page, and that link also has to have rel="me".  That’s the markup Mastodon provided for me to copy, which we saw before and I’ll repeat here:

<a rel="me" href="https://mastodon.social/@Meyerweb">Mastodon</a>

Again, the important part is that the href points to my Mastodon profile page, and there’s a rel attribute containing me.  It can contain other things, like noreferrer, but needs to have me for the verfiication to work.  Note that the content of the link element doesn’t have to be the text “Mastodon”.  In my case, I’m using a Mastodon logo, with the markup looking like this:

<a rel="me" href="https://mastodon.social/@Meyerweb">
 	<img src="/pix/icons/mastodon.svg" alt="Mastodon">
</a>

With that in place, there’s a “me” link pointing to a page that contains a “me” link.  That’s a symmetric relationship, as XFN requires, and it verifies that the two pages have a shared owner.  Who is me!

Thus, if you go to my Mastodon profile page, in the table of my profile metadata, the entry for my homepage is specially styled to indicate it’s been verified as actually belonging to me.

And that’s how it works.

Next question: how can I verify my GitHub page?  At the moment, I’d have to put my Mastodon profile page’s URL into the one open field for URLs in GitHub profiles, because GitHub also does the rel="me" thing for its profile links.  But if I do that, I’d have to remove the link to my homepage, which I don’t want to do.

Until GitHub either provides a dedicated Mastodon profile field the way it provides a dedicated Twitter profile field, or else allows people to add multiple URLs to their profiles the way Mastodon does, I won’t be able to verify my GitHub page on Mastodon.  Not a huge deal for me, personally, but in general it would be nice to see GitHub become more flexible in this area.  Very smart people are also asking for this, so hopefully that will happen soon(ish).

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

In last blog post, I introduced call stack profiling, why it is useful, and how a system wide support can be useful. This new blog post will talk about Windows native call stack tracing, and how it is integrated in Chromium.

Event Tracing for Windows (ETW)

Event Tracing for Windows, usually also named with the acronym ETW, is a Windows kernel based tool that allows to log kernel and application events to a file.

A good description of its architecture is available at Microsoft Learn: About Event Tracing.

Essentially, it is an efficient event capturing tool, in some ways similar to LTTng. Its events recording stage is as lightweight as possible to avoid processing of collected data impacting the results as much as possible, reducing the observer effect.

The main participants are:
– Providers: kernel components (including device drivers) or applications that emit log events.
– Controllers: tools that control when a recording session starts and stops, which providers to record, and what each provider is expected to log. Controllers also decide where to dump the recorded data (typically a file).
– Consumers: tools that can read and analyze the recorded data, and combine with system information (i.e. debugging information). Consumers will usually get the data from previously recorded files, but it is also possible to consume tracing information in real time.

What about call stack profiling? ETW supports call stack sampling, allowing to capture call stacks when certain events happen, and associates the call stack to that event. Bruce Dawson has written a fantastic blog post about the topic.

Chromium call stack profiling in Windows

Chromium provides support for call stack profiling. This is done at different levels of the stack:
– It allows to build with frame pointers, so CPU profile samplers can properly capture the full call stack.
– v8 can generate symbol information for for JIT-compiled code. This is supported for ETW (and also for Linux Perf).

Compilation

In any platform compilation will usually benefit from compiling with the GN flag enable_profiling=true. This will enable frame pointers support. In Windows, it will also enable generation of function information for code generated by V8.

Also, symbol_level=1 should be added at least, so the compilation stage function names are available.

Chrome startup

To enable generation of V8 profiling information in Windows, these flags should be passed to chrome on launch:

chrome --js-flags="--enable-etw-stack-walking --interpreted-frames-native-stack"

--enable-etw-stack-walking will emit information of the functions compiled by V8 JIT engine, so they can be recorded while sampling the stack.

--interpreted-frames-native-stack will show the frames of interpreted code in the native stack, so external profilers as ETW can properly show those in the profiling samples.

Recording

Then, a session of the workload to analyze can be captured with Windows Performance Recorder.

An alternate tool with specific Chromium support, UIForETW can be used too. Main advantage is that it allows to select specific Chromium tracer categories, that will be emitted in the same trace. Its author, Bruce Dawson, has explained very well how to use it.

Analysis

For analysis, the tool Windows Performance Analyzer (WPA) can be used. Both UIForETW and Windows Performance Recorder will offer opening the obtained trace at the end of the capture for analysis.

Before starting analysis, in WPA, add the paths where the .PDB files with debugging information are available.

Then, select Computation/CPU Usage (Sampled):

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From the available charts, we are interested in the ones providing stackwalk information:

Next

In the last post of this series, I will present the work done in 2022 to improve V8 support for Windows ETW.