Update on what happened in WebKit in the week from February 2 to February 9.
The main event this week was FOSDEM (pun intended), which included
presentations related to WebKit; but also we got a batch of stable
and development releases, asynchronous scrolling work, OpenGL
logging, cleanups, and improving the inspector for the WPE work.
Cross-Port 🐱
Graphics 🖼️
While asynchronous scrolling for mouse wheel events was already supported,
scrollbar layers were still being painted on the main thread. This has been
changed to paint scrollbars on the
scrolling thread instead, which avoids scrollbars to “lag” behind scrolled
content.
Fixed flickering caused by the
combination of damage tracking and asynchronous scrolling for mouse wheel
events.
Figuring out the exact location inside WebKit that triggered an OpenGL issue
may still be challenging with this aid, and therefore a backtrace will be
appended in case of errors to help
pinpoint the source, when the log channel is enabled at the “debug” level with
GLContext=debug.
Configuring the build with USE_SKIA=OFF to make WebKit use the
Cairo graphics library is no longer
supported. Using
Skia has been the default since late
2024,
and after two full years the 2.54.0 release (due in September 2026)
will be the first one where the choice is no longer possible.
WebKitGTK 🖥️
The “on demand” hardware acceleration policy has been rarely used lately, and
thus support for it has been removed.
Note that this affects only the GTK port when built with GTK 3—the option never
existed when using GTK 4.
Existing GTK 3 applications that use
WEBKIT_HARDWARE_ACCELERATION_POLICY_ON_DEMAND will continue to work and do
not need rebuilding: they will be promoted to use the “always enabled” policy
starting with WebKitGTK 2.54.0 (due in September 2026).
WPE WebKit 📟
The Web Inspector has received
support for saving data to local
files, allowing things such as saving page resources or exporting the network
session to a HAR archive.
Note that using the Web Inspector locally is supported when using the
WPEPlatform API, and the keyboard shortcut Ctrl+Shift+I may be used to bring it up.
Releases 📦️
WebKitGTK
2.50.5 and
WPE WebKit 2.50.5 have
been released. These are stable maintenance releases that improves stability,
correct bugs, and fixes small rendering issues.
The second release candidates for the upcoming stable branch, WebKitGTK
2.51.91 and
WPE WebKit 2.51.91,
have been published as well. Those using those to preview the upcoming 2.52.x
series are encouraged to provide bug reports in
Bugzilla for any issue they may experience.
Community & Events 🤝
We have published a blog
post
on our work implementing the
Temporal proposal in JavaScriptCore,
WebKit's JavaScript engine.
This year's edition of FOSDEM took place in
Brussels between January 31st and February 1st, and featured a number of
sessions related to WebKitGTK and WPE:
Update on what happened in WebKit in the week from January 26 to February 2.
A calm week for sure! The highlight this week is the fix for scrolling not starting when the main thread is blocked.
Cross-Port 🐱
Graphics 🖼️
Fixed the problem of wheel event async scrolling doesn't start while the main thread is blocked. This should make WebKit feel more responsive even on heavier websites.
Update on what happened in WebKit in the week from January 19 to January 26.
The main event this week has been the creation of the branch for the upcoming stable series, accompanied by the first release candidate before 2.52.0. But there's more: the WPE port gains hyphenation support and the ability to notify of graphics buffer changes; both ports get graphics fixes and a couple of new Web features, and WPE-Android also gets a new stable release.
Cross-Port 🐱
Implemented support for the :open
pseudo-class on dialog and details elements. This is currently behind the
OpenPseudoClass feature flag.
Implemented the source property for
ToggleEvent. This can be used to run code dependent on the triggering element
in response to a popover or dialog toggle.
Graphics 🖼️
Fixed the rendering glitches with
wheel event asynchronous scrolling, which occurred when the page was scrolled
to areas not covered by tiles while the main thread was blocked.
WPE WebKit 📟
Support for
hyphenation
has been added to WPE. This requires
libhyphen and can be disabled at build-time with the USE_LIBHYPHEN=OFF
CMake option.
WPE Platform API 🧩
New, modern platform API that supersedes usage of libwpe and WPE backends.
WPEPlatform gained support to notify
changes in the configuration of graphics buffers allocated to render the
contents of a web view, either by handling the WPEView::buffers-changed
signal or by overriding the WPEViewClass.buffers_changed virtual function.
This feature is mainly useful for platform implementations which may need to
perform additional setup in advance, before updated web view contents are
provided in the buffers configured by WebKit.
Releases 📦️
WPE-Android 0.3.0
has been released, and prebuilt packages are available at the Maven Central
repository.
The main change in this this version is the update to WPE WebKit 2.50.4, which
is the most recent stable release.
A new branch has been
created for the
upcoming 2.52.x stable release series of the GTK and WPE WebKit ports. The
first release candidates from this branch, WebKitGTK
2.51.90 and
WPE WebKit 2.51.90 are
now available. Testing and issue reports in Bugzilla
are welcome to help with stabilization before the first stable release, which
is planned for mid-March.
Now that 2025 is over, it’s time to look back and feel proud of the path we’ve walked. Last year has been really exciting in terms of contributions to GStreamer and WebKit for the Igalia Multimedia team.
With more than 459 contributions along the year, we’ve been one of the top contributors to the GStreamer project, in areas like Vulkan Video, GstValidate, VA, GStreamer Editing Services, WebRTC or H.266 support.
Igalia’s contributions to the GStreamer project
In Vulkan Video we’ve worked on the VP9 video decoder, and cooperated with other contributors to push the AV1 decoder as well. There’s now an H.264 base class for video encoding that is designed to support general hardware-accelerated processing.
GStreaming Editing Services, the framework to build video editing applications, has gained time remapping support, which now allows to include fast/slow motion effects in the videos. Video transformations (scaling, cropping, rounded corners, etc) are now hardware-accelerated thanks to the addition of new Skia-based GStreamer elements and integration with OpenGL. Buffer pool tuning and pipeline improvements have helped to optimize memory usage and performance, enabling the edition of 4K video at 60 frames per second. Much of this work to improve and ensure quality in GStreamer Editing Services has also brought improvements in the GstValidate testing framework, which will be useful for other parts of GStreamer.
Regarding H.266 (VVC), full playback support (with decoders such as vvdec and avdec_h266, demuxers and muxers for Matroska, MP4 and TS, and parsers for the vvc1 and vvi1 formats) is now available in GStreamer 1.26 thanks to Igalia’s work. This allows user applications such as the WebKitGTK web browser to leverage the hardware accelerated decoding provided by VAAPI to play H.266 video using GStreamer.
Igalia has also been one of the top contributors to GStreamer Rust, with 43 contributions. Most of the commits there have been related to Vulkan Video.
Igalia’s contributions to the GStreamer Rust project
In addition to GStreamer, the team also has a strong presence in WebKit, where we leverage our GStreamer knowledge to implement many features of the web engine related to multimedia. From the 1739 contributions to the WebKit project done last year by Igalia, the Multimedia team has made 323 of them. Nearly one third of those have been related to generic multimedia playback, and the rest have been on areas such as WebRTC, MediaStream, MSE, WebAudio, a new Quirks system to provide adaptations for specific hardware multimedia platforms at runtime, WebCodecs or MediaRecorder.
Igalia Multimedia Team’s contributions to different areas of the WebKit project
We’re happy about what we’ve achieved along the year and look forward to maintaining this success and bringing even more exciting features and contributions in 2026.
Update on what happened in WebKit in the week from December 26 to January 19.
We're back! The first periodical of 2026 brings you performance optimizations, improvements to the memory footprint calculation, new APIs, the removal of the legacy Qt5 WPE backend, and as always, progress on JSC's Temporal implementation.
Cross-Port 🐱
The memory footprint calculation mechanism has been unified across GTK, JSC, and WPE ports. Therefore, the expensive /proc/self/smaps is not used anymore and the WPE uses /proc/self/statm with extra cache now to prevent frequent file reading.
Added a new webkit_context_menu_get_position() function to the API that allows obtaining the pointer coordinates, relative to the web view origin, at the moment when a context menu was triggered.
Additionally, behaviour of context menus has been made more consistent between the GTK and WPE ports, and handling of GAction objects attached to menu items has been rewritten and improved with the goal of better supporting context menus in the WPE port.
JavaScriptCore 🐟
The built-in JavaScript/ECMAScript engine for WebKit, also known as JSC or SquirrelFish.
In JavaScriptCore's implementation of Temporal, fixed a bug in Temporal.PlainTime.from that read options in the wrong order, which caused a test262 test to fail.
In JavaScriptCore's implementation of Temporal, fixed several bugs in PlainYearMonth methods and enabled all PlainYearMonth tests that don't depend on the Intl object. This completes the implementation of Temporal PlainYearMonth objects in JSC.
Graphics 🖼️
In WebKit's Skia graphics backend, fixed GrDirectContext management for GPU resources. Operations on GPU-backed resources must use the context that created them, not the current thread's context. The fix stores GrDirectContext at creation time for NativeImage and uses surface->recordingContext()->asDirectContext() for SkSurface, correcting multiple call sites that previously used the shared display's context incorrectly.
Damage propagation has been added to the recently-added, non-composited mode in WPE.
In WebKit's Skia graphics backend for GTK/WPE, added canvas 2D operation recording for GPU-accelerated rendering. Instead of executing drawing commands immediately, operations are recorded into an SkPicture and replayed in batch when the canvas contents are needed, reducing GPU state change overhead for workloads with many small drawing operations, improving the MotionMark Canvas Lines performance on embedded devices with low-end tiled GPUs.
WPE WebKit 📟
Due to Qt5 not receiving maintenance since mid-2025, the WPE Qt5 binding that used the legacy libwpe API has been removed from the tree. The Qt6 binding remains part of the source tree, which is a better alternative that allows using supported Qt versions, and is built atop the new WPEPlatform API, making it a future-proof option. The WPE Qt API may be enabled when configuring the build with CMake, using the ENABLE_WPE_QT_API option.
WPE Platform API 🧩
New, modern platform API that supersedes usage of libwpe and WPE backends.
The WPEScreenSyncObserver class has been improved to support multiple callbacks. Instead of a single callback set with wpe_screen_sync_observer_set_callback(), clients of the API can now use wpe_screen_sync_observer_add_callback() and wpe_screen_sync_observer_remove_callback(). The observer will be paused automatically when there are no callbacks attached to it.
Update on what happened in WebKit in the week from December 16 to December 25.
Right during the holiday season 🎄, the last WIP installment of the year comes packed with new releases, a couple of functions added to the public API, cleanups, better timer handling, and improvements to MathML and WebXR support.
Cross-Port 🐱
Landed support for font-size: math. Now
math-depth
can automatically control the font size inside of <math> blocks, making
scripts and nested content smaller to improve readability and presentation.
webkit_context_menu_item_get_gaction_target() to obtain the GVariant
associated with a context menu item created from a GAction.
webkit_context_menu_item_get_title() may be used to obtain
the title of a context menu item.
Improved timers, by making some of
them use the timerfd API. This reduces
timer “lateness”—the amount of time elapsed between the configured trigger
time, and the effective one—, which in turn improves the perceived smoothness
of animations thanks to steadier frame delivery timings. Systems where the
timerfd_create and timerfd_settime functions are not available will
continue working as before.
On the WebXR front, support was added
for XR_TRACKABLE_TYPE_DEPTH_ANDROID through the XR_ANDROID_trackables
extension, which allows reporting depth information for elements that take part
in hit testing.
Graphics 🖼️
Landed a change that implements
non-composited page rendering in the WPE port. This new mode is disabled by
default, and may be activated by disabling the AcceleratedCompositing runtime
preference. In such case, the frames are rendered using a simplified code path
that does not involve the internal WebKit compositor. Therefore it may offer a
better performance in some specific cases on constrained embedded devices.
Since version 2.10.2, the FreeType library can be built
with direct support for loading fonts in the
WOFF2 format. Until now, the WPE and GTK WebKit
ports used libwoff2 in an intermediate step
to convert those fonts on-the-fly before handing them to FreeType for
rendering. The CMake build system will now detect when FreeType supports WOFF2
directly and skip the conversion step.
This way, in systems which provide a suitable version of FreeType, libwoff2
will no longer be needed.
WPE WebKit 📟
WPE Platform API 🧩
New, modern platform API that supersedes usage of libwpe and WPE backends.
The legacy libwpe-based API can now be disabled at build
time, by toggling the
ENABLE_WPE_LEGACY_API CMake option. This allows removal of uneeded code when
an application is exclusively using the new WPEPlatform API.
Adaptation of WPE WebKit targeting the Android operating system.
AHardwareBuffer
is now supported as backing for
accelerated graphics surfaces that can be shared across processes. This is the
last piece of the puzzle to use WPEPlatform on Android without involving
expensive operations to copy rendered frames back-and-forth between GPU and
system memory.
Releases 📦️
WebKitGTK
2.50.4 and
WPE WebKit 2.50.4 have
been released. These stable releases include a number of important patches for
security issues, and we urge users and distributors to update to this release
if they have not yet done it. An accompanying security advisory,
WSA-2025-0010, has been published
(GTK,
WPE).
This article is a continuation of the series on WPE performance considerations. While the previous article touched upon fairly low-level aspects of the DOM tree overhead,
this one focuses on more high-level problems related to managing the application’s workload over time. Similarly to before, the considerations and conclusions made in this blog post are strongly related to web applications
in the context of embedded devices, and hence the techniques presented should be used with extra care (and benchmarking) if one would like to apply those on desktop-class devices.
Typical web applications on embedded devices have their workloads distributed over time in various ways. In practice, however, the workload distributions can usually be fitted into one of the following categories:
Idle applications with occasional updates - the applications that present static content and are updated at very low intervals. As an example, one can think of some static dashboard that presents static content and switches
the page every, say, 60 seconds - such as e.g. a static departures/arrivals dashboard on the airport.
Idle applications with frequent updates - the applications that present static content yet are updated frequently (or are presenting some dynamic content, such as animations occasionally). In that case, one can imagine a similar
airport departures/arrivals dashboard, yet with the animated page scrolling happening quite frequently.
Active applications with occasional updates - the applications that present some dynamic content (animations, multimedia, etc.), yet with major updates happening very rarely. An example one can think of in this case is an application
playing video along with presenting some metadata about it, and switching between other videos every few minutes.
Active applications with frequent updates - the applications that present some dynamic content and change the surroundings quite often. In this case, one can think of a stock market dashboard continuously animating the charts
and updating the presented real-time statistics very frequently.
Such workloads can be well demonstrated on charts plotting the browser’s CPU usage over time:
As long as the peak workload (due to updates) is small, no negative effects are perceived by the end user. However, when the peak workload is significant, some negative effects may start getting noticeable.
In case of applications from groups (1) and (2) mentioned above, a significant peak workload may not be a problem at all. As long as there are no continuous visual changes and no interaction is allowed during updates, the end-user
is unable to notice that the browser was not responsive or missed some frames for some period of time. In such cases, the application designer does not need to worry much about the workload.
In other cases, especially the ones involving applications from groups (3) and (4) mentioned above, the significant peak workload may lead to visual stuttering, as any processing making the browser busy for longer than 16.6 milliseconds
will lead to lost frames. In such cases, the workload has to be managed in a way that the peaks are reduced either by optimizing them or distributing them over time.
The first step to addressing the peak workload is usually optimization. Modern web platform gives a full variety of tools to optimize all the stages of web application processing done by the browser. The usual process of optimization is a
2-step cycle starting with measuring the bottlenecks and followed by fixing them. In the process, the usual improvements involve:
using CSS containment,
using shadow DOM,
promoting certain parts of the DOM to layers and manipulating them with transforms,
parallelizing the work with workers/worklets,
using the visibility CSS property to separate painting from layout,
optimizing the application itself (JavaScript code, the structure of the DOM, the architecture of the application),
Unfortunately, in practice, it’s not uncommon that even very well optimized applications still have too much of a peak workload for the constrained embedded devices they’re used on. In such cases, the last resort solution is
pre-rendering. As long as it’s possible from the application business-logic perspective, having at least some web page content pre-rendered is very helpful in situations when workload has to be managed, as pre-rendering
allows the web application designer to choose the precise moment when the content should actually be rendered and how it should be done. With that, it’s possible to establish a proper trade-off between reduction in peak workload and
the amount of extra memory used for storing the pre-rendered contents.
Nowadays, the web platform provides at lest a few widely-adapted APIs that provide means for the application to perform various kinds of pre-rendering. Also, due to the ways the browsers are implemented, some APIs can be purposely misused
to provide pre-rendering techniques not necessarily supported by the specification. However, in the pursuit of good trade-offs, all the possibilities should be taken into account.
Before jumping into particular pre-rendering techniques, it’s necessary to emphasize that the pre-rendering term used in this article refers to the actual rendering being done earlier than it’s visually presented. In that
sense, the resource is rasterized to some intermediate form when desired and then just composited by the browser engine’s compositor later.
The most basic (and limited at the same time) pre-rendering technique is one that involves rendering offline i.e. before the browser even starts. In that case, the first limitation is that the content to be rendered must be known
beforehand. If that’s the case, the rendering can be done in any way, and the result may be captured as e.g. raster or vector image (depending on the desired trade-off). However, the other problem is that such a rendering is usually out of
the given web application scope and thus requires extra effort. Moreover, depending on the situation, the amount of extra memory used, the longer web application startup (due to loading the pre-rendered resources), and the processing
power required to composite a given resource, it may not always be trivial to obtain the desired gains.
The first group of actual pre-rendering techniques happening during web application runtime is related to Canvas and
OffscreenCavas. Those APIs are really useful as they offer great flexibility in terms of usage and are usually very performant.
However, in this case, the natural downside is the lack of support for rendering the DOM inside the canvas. Moreover, canvas has a very limited support for painting text — unlike the DOM, where
CSS has a significant amount of features related to it. Interestingly, there’s an ongoing proposal called HTML-in-Canvas that could resolve those limitations
to some degree. In fact, Blink has a functioning prototype of it already. However, it may take a while before the spec is mature and widely adopted by other browser engines.
When it comes to actual usage of canvas APIs for pre-rendering, the possibilities are numerous, and there are even more of them when combined with processing using workers.
The most popular ones are as follows:
rendering to an invisible canvas and showing it later,
rendering to a canvas detached from the DOM and attaching it later,
rendering to an invisible/detached canvas and producing an image out of it to be shown later,
rendering to an offscreen canvas and producing an image out of it to be shown later.
When combined with workers, some of the above techniques may be used in the worker threads with the rendered artifacts transferred to the main for presentation purposes. In that case, one must be careful with
the transfer itself, as some objects may get serialized, which is very costly. To avoid that, it’s recommended to use transferable objects
and always perform a proper benchmarking to make sure the transfer is not involving serialization in the particular case.
While the use of canvas APIs is usually very straightforward, one must be aware of two extra caveats.
First of all, in the case of many techniques mentioned above, there is no guarantee that the browser will perform actual rasterization at the given point in time. To ensure the rasterization is triggered, it’s usually
necessary to enforce it using e.g. a dummy readback (getImageData()).
Finally, one should be aware that the usage of canvas comes with some overhead. Therefore, creating many canvases or creating them often, may lead to performance problems that could outweigh the gains from the
pre-rendering itself.
The second group of pre-rendering techniques happening during web application runtime is limited to the DOM rendering and comes out of a combination of purposeful spec misuse and tricking the browser engine into making it rasterizing
on demand. As one can imagine, this group of techniques is very much browser-engine-specific. Therefore, it should always be backed by proper benchmarking of all the use cases on the target browsers and target hardware.
In principle, all the techniques of this kind consist of 3 parts:
Enforcing the content to be pre-rendered being placed on a separate layer backed by an actual buffer internally in the browser,
Tricking the browser’s compositor into thinking that the layer needs to be rasterized right away,
Ensuring the layer won’t be composited eventually.
When all the elements are combined together, the browser engine will allocate an internal buffer (e.g. texture) to back the given DOM fragment, it will process that fragment (style recalc, layout), and rasterize it right away. It will do so
as it will not have enough information to allow delaying the rasterization of the layer (as e.g. in case of display: none). Then, when the compositing time comes, the layer will turn out to be invisible in practice
due to e.g. being occluded, clipped, etc. This way, the rasterization will happen right away, but the results will remain invisible until a later time when the layer is made visible.
In practice, the following approaches can be used to trigger the above behavior:
for (1), the CSS properties such as will-change: transform, z-index, position: fixed, overflow: hidden etc. can be used depending on the browser engine,
for (2) and (3), the CSS properties such as opacity: 0, overflow: hidden, contain: strict etc. can be utilized, again, depending on the browser engine.
The scrolling trick
While the above CSS properties allow for various combinations, in case of WPE WebKit in the context of embedded devices (tested on NXP i.MX8M Plus), the combination that has proven to yield the best performance benefits turns
out to be a simple approach involving overflow: hidden and scrolling. The example of such an approach is explained below.
With the number of idle frames (if) set to 59, the idea is that the application does nothing significant for the 59 frames, and then every 60th frame it updates all the numbers in the table.
As one can imagine, on constrained embedded devices, such an approach leads to a very heavy workload during every 60th frame and hence to lost frames and unstable application’s FPS.
As long as the numbers are available earlier than every 60th frame, the above application is a perfect example where pre-rendering could be used to reduce the peak workload.
To simulate that, the 3 variants of the approach involving the scrolling trick were prepared for comparison with the above:
In the above demos, the idea is that each cell with a number becomes a scrollable container with 2 numbers actually — one above the other. In that case, because overflow: hidden is set, only one of the numbers is visible while the
other is hidden — depending on the current scrolling:
With such a setup, it’s possible to update the invisible numbers during idle frames without the user noticing. Due to how WPE WebKit accelerates the scrolling, changing the invisible
numbers, in practice, triggers the layout and rendering right away. Moreover, the actual rasterization to the buffer backing the scrollable container happens immediately (depending on the tiling settings), and hence the high cost of layout
and text rasterization can be distributed. When the time comes, and all the numbers need to be updated, the scrollable containers can be just scrolled, which in that case turns out to be ~2 times faster than updating all the numbers in place.
While the first sysprof trace shows very little processing during 11 idle frames and a big chunk of processing (21 ms) every 12th frame, the second sysprof trace shows how the distribution of load looks. In
that case, the amount of work during 11 idle frames is much bigger (yet manageable), but at the same time, the formerly big chunk of processing every 12th frame is reduced almost 2 times (to 11 ms). Therefore, the overall
frame rate in the application is much better.
Results
Despite the above improvement speaking for itself, it’s worth summarizing the improvement with the benchmarking results of the above demos obtained from the NXP i.MX8M Plus and presenting the application’s average
frames per second (FPS):
Clearly, the positive impact of pre-rendering can be substantial depending on the conditions. In practice, when the rendered DOM fragment is more complex, the trick such as above can yield even better results.
However, due to how tiling works, the effect can be minimized if the content to be pre-rendered spans multiple tiles. In that case, the browser may defer rasterization until the tiles are actually needed. Therefore,
the above needs to be used with care and always with proper benchmarking.
As demonstrated in the above sections, when it comes to pre-rendering the contents to distribute the web application workload over time, the web platform gives both the official APIs to do it, as well as unofficial
means through purposeful misuse of APIs and exploitation of browser engine implementations. While this article hasn’t covered all the possibilities available, the above should serve as a good initial read with some easy-to-try
solutions that may yield surprisingly good results. However, as some of the ideas mentioned above are very much browser-engine-specific, they should be used with extra care and with the limitations (lack of portability)
in mind.
As the web platform constantly evolves, the pool of pre-rendering techniques and tricks should keep evolving as well. Also, as more and more web applications are used on embedded devices, more pressure should be
put on the specification, which should yield more APIs targeting the low-end devices in the future. With that in mind, it’s recommended for the readers to stay up-to-date with the latest specification and
perhaps even to get involved if some interesting use cases would be worth introducing new APIs.
Update on what happened in WebKit in the week from December 8 to December 15.
In this end-of-year special have a new GMallocString helper that makes
management of malloc-based strings more efficient, development releases,
and a handful of advancements on JSC's implementation of Temporal, in
particular the PlainYearMonth class.
Cross-Port 🐱
Added GMallocString class to WTF to adopt UTF8 C strings and make them WebKit first class citizens efficiently (no copies). Applied in GStreamer code together with other improvements by using CStringView. Fixed other twobugs about string management.
JavaScriptCore 🐟
The built-in JavaScript/ECMAScript engine for WebKit, also known as JSC or SquirrelFish.
Development releases of WebKitGTK 2.51.3
and WPE WebKit 2.51.3
are now available. These include a number of API additions and new features,
and are intended to allow interested parties to test those in advance, prior
to the next stable release series. As usual, bug reports are
welcome in Bugzilla.
Update on what happened in WebKit in the week from December 1 to December 8.
In this edition of the periodical we have further advancements on
the Temporal implementation, support for Vivante super-tiled format,
and an adaptation of the DMA-BUF formats code to the Android port.
Cross-Port 🐱
JavaScriptCore 🐟
The built-in JavaScript/ECMAScript engine for WebKit, also known as JSC or SquirrelFish.
Implemented the toString, toJSON, and toLocaleString methods for PlainYearMonth objects in JavaScriptCore's implementation of Temporal.
Graphics 🖼️
BitmapTexture and TextureMapperwere prepared to handle textures where the logical size (e.g. 100×100) differs from the allocated size (e.g. 128×128) due to alignment requirements. This allowed to add support for using memory-mapped GPU buffers in the Vivante super-tiled format available on i.MX platforms. Set WEBKIT_SKIA_USE_VIVANTE_SUPER_TILED_TILE_TEXTURES=1 to activate at runtime.
WPE WebKit 📟
WPE Platform API 🧩
New, modern platform API that supersedes usage of libwpe and WPE backends.
The WPEBufferDMABufFormats class has been renamed to WPEBufferFormats, as it can be used in situations where mechanisms other than DMA-BUF may be used for buffer sharing—on Android targets AHardwareBuffer is used instead, for example. The naming change involved also WPEBufferFormatsBuilder (renamed from WPEBufferDMABufFormatsBuilder), and methods and signals in other classes that use these types. Other than the renames, there is no change in functionality.
Some years ago I had mentioned some command line tools I used to analyze and find useful information on GStreamer logs. I’ve been using them consistently along all these years, but some weeks ago I thought about unifying them in a single tool that could provide more flexibility in the mid term, and also as an excuse to unrust my Rust knowledge a bit. That’s how I wrote Meow, a tool to make cat speak (that is, to provide meaningful information).
The idea is that you can cat a file through meow and apply the filters, like this:
which means “select those lines that contain appsinknewsample (with case insensitive matching), but don’t contain V0 nor video (that is, by exclusion, only that contain audio, probably because we’ve analyzed both and realized that we should focus on audio for our specific problem), highlight the different thread ids, only show those lines with timestamp lower than 21.46 sec, and change strings like Source/WebCore/platform/graphics/gstreamer/mse/AppendPipeline.cpp to become just AppendPipeline.cpp“, to get an output as shown in this terminal screenshot:
Cool, isn’t it? After all, I’m convinced that the answer to any GStreamer bug is always hidden in the logs (or will be, as soon as I add “just a couple of log lines more, bro” ).
Currently, meow supports this set of manipulation commands:
Word filter and highlighting by regular expression (fc:REGEX, or just REGEX): Every expression will highlight its matched words in a different color.
Filtering without highlighting (fn:REGEX): Same as fc:, but without highlighting the matched string. This is useful for those times when you want to match lines that have two expressions (E1, E2) but the highlighting would pollute the line too much. In those case you can use a regex such as E1.*E2 and then highlight the subexpressions manually later with an h: rule.
Negative filter (n:REGEX): Selects only the lines that don’t match the regex filter. No highlighting.
Highlight with no filter (h:REGEX): Doesn’t discard any line, just highlights the specified regex.
Substitution (s:/REGEX/REPLACE): Replaces one pattern for another. Any other delimiter character can be used instead of /, it that’s more convenient to the user (for instance, using # when dealing with expressions to manipulate paths).
Time filter (ft:TIME-TIME): Assuming the lines start with a GStreamer log timestamp, this filter selects only the lines between the target start and end time. Any of the time arguments (or both) can be omitted, but the - delimiter must be present. Specifying multiple time filters will generate matches that fit on any of the time ranges, but overlapping ranges can trigger undefined behaviour.
Highlight threads (ht:): Assuming a GStreamer log, where the thread id appears as the third word in the line, highlights each thread in a different color.
The REGEX pattern is a regular expression. All the matches are case insensitive. When used for substitutions, capture groups can be defined as (?CAPTURE_NAMEREGEX).
The REPLACEment string is the text that the REGEX will be replaced by when doing substitutions. Text captured by a named capture group can be referred to by ${CAPTURE_NAME}.
The TIME pattern can be any sequence of numbers, : or . . Typically, it will be a GStreamer timestamp (eg: 0:01:10.881123150), but it can actually be any other numerical sequence. Times are compared lexicographically, so it’s important that all of them have the same string length.
The filtering algorithm has a custom set of priorities for operations, so that they get executed in an intuitive order. For instance, a sequence of filter matching expressions (fc:, fn:) will have the same priority (that is, any of them will let a text line pass if it matches, not forbidding any of the lines already allowed by sibling expressions), while a negative filter will only be applied on the results left by the sequence of filters before it. Substitutions will be applied at their specific position (not before or after), and will therefore modify the line in a way that can alter the matching of subsequent filters. In general, the user doesn’t have to worry about any of this, because the rules are designed to generate the result that you would expect.
Now some practical examples:
Example 1: Select lines with the word “one”, or the word “orange”, or a number, highlighting each pattern in a different color except the number, which will have no color:
$ cat file.txt | meow one fc:orange 'fn:[0-9][0-9]*' 000 one small orange 005 one big orange
Example 2: Assuming a pictures filename listing, select filenames not ending in “jpg” nor in “jpeg”, and rename the filename to “.bak”, preserving the extension at the end:
Example 3: Only print the log lines with times between 0:00:24.787450146 and 0:00:24.790741865 or those at 0:00:30.492576587 or after, and highlight every thread in a different color:
This is only the begining. I have great ideas for this new tool (as time allows), such as support for parenthesis (so the expressions can be grouped), or call stack indentation on logs generated by tracers, in a similar way to what Alicia’s gst-log-indent-tracers tool does. I might also predefine some common expressions to use in regular expressions, such as the ones to match paths (so that the user doesn’t have to think about them and reinvent the wheel every time). Anyway, these are only ideas. Only time and hyperfocus slots will tell…
Update on what happened in WebKit in the week from November 24 to December 1.
The main highlights for this week are the completion of `PlainMonthDay`
in Temporal, moving networking access for GstWebRTC to the WebProcess,
and Xbox Cloud Gaming now working in the GTK and WPE ports.
Cross-Port 🐱
Multimedia 🎥
GStreamer-based multimedia support for WebKit, including (but not limited to)
playback, capture, WebAudio, WebCodecs, and WebRTC.
Support for remote inbound RTP statistics was improved in
303671@main, we now properly report
framesPerSecond and totalDecodeTime metrics, those fields are used in the
Xbox Cloud Gaming service to show live stats about the connection and video
decoder performance in an overlay.
The GstWebRTC backend now relies on
librice for its
ICE.
The Sans-IO architecture of librice allows us to keep the WebProcess sandboxed
and to route WebRTC-related UDP and (eventually) TCP packets using the
NetworkProcess. This work landed in
303623@main. The GNOME SDK should
also soon ship
librice.
Support for seeking in looping videos was fixed in
303539@main.
JavaScriptCore 🐟
The built-in JavaScript/ECMAScript engine for WebKit, also known as JSC or SquirrelFish.
Implemented the valueOf and
toPlainDate for PlainMonthDay objects.
This completes the implementation of
TemporalPlainMonthDay objects in JSC!
WebKitGTK 🖥️
The GTK port has gained support for
interpreting touch input as pointer
events. This
matches the behaviour of other browsers by following the corresponding
specifications.
WPE WebKit 📟
Fixed an issue that prevented
WPE from processing further input events after receiving a secondary mouse
button press.
Fixed an issue that caused right
mouse button clicks to prevent processing of further pointer events.
WPE Platform API 🧩
New, modern platform API that supersedes usage of libwpe and WPE backends.
We landed a patch to add a new signal
in WPEDisplay to notify when the connection to the native display has been lost.
Note that this work removed the support for building against
Enchant 1.x, and only version 2 will be
supported. The first stable release to require Enchant 2.x will be 2.52.0 due
in March 2026. Major Linux and BSD distributions have included Enchant 2
packages for years, and therefore this change is not expected to cause any
trouble. The Enchant library is used by the GTK port for spell checking.
Community & Events 🤝
We have published an
article detailing our
work making MathML
interoperable across browser engines! It has live demonstrations and feature
tables with our progress on WebKit support.
We have published new blogs post highlighting the most important changes in
both WPE WebKit
and WebKitGTK 2.50.
Enjoy!
This fall, the WPE WebKit team has released the 2.50 series of the Web engine after six months of hard work. Let’s have a deeper look at some of the most interesting changes in this release series!
Improved rendering performance
For this series, the threaded rendering implementation has been switched to use the Skia API. What has changed is the way we record the painting commands for each layer. Previously we used WebCore’s built-in mechanism (DisplayList) which is not thread-safe, and led to obscure rendering issues in release builds and/or sporadic assertions in debug builds when replaying the display lists in threads other than the main one. The DisplayList usage was replaced with SkPictureRecorder, Skia’s built-in facility, that provides similar functionality but in a thread-safe manner. Using the Skia API, we can leverage multithreading in a reliable way to replay recorded drawing commands in different worker threads, improving rendering performance.
An experimental hybrid rendering mode has also been added. In this mode, WPE WebKit will attempt to use GPU worker threads for rendering but, if these are busy, CPU worker threads will be used whenever possible. This rendering mode is still under investigation, as it is unclear whether the improvements are substantial enough to justify the extra complexity.
Damage propagation to the system compositor, which was added during the 2.48 cycle but remained disabled by default, has now been enabled. The system compositor may now leverage the damage information for further optimization.
Vertical writing-mode rendering has also received improvements for this release series.
Changes in Multimedia support
When available in the system, WebKit can now leverage the XDG desktop portal for accessing capture devices (like cameras) so that no specific sandbox exception is required. This provides secure access to capture devices in browser applications that use WPE WebKit.
Managed Media Source support has been enabled. This potentially improves multimedia playback, for example in mobile devices, by allowing the user agent to react to changes in memory and CPU availability.
Transcoding is now using the GStreamer built-in uritranscodebin element instead of GstTranscoder, which improves stability of the media recording that needs transcoding.
SVT-AV1 encoder support has been added to the media backend.
WebXR support
The WebXR implementation had been stagnating since it was first introduced, and had a number of shortcomings. This was removed in favor of a new implementation, also built using OpenXR, that better adapts to the multiprocess architecture of WebKit.
This feature is considered experimental in 2.50, and while it is complete enough to load and display a number of immersive experiences, a number of improvements and optional features continue to be actively developed. Therefore, WebXR support needs to be enabled at build time with the ENABLE_WEBXR=ON CMake option.
Android support
Support for Android targets has been greatly improved. It is now possible to build WPE WebKit without the need for additional patches when using the libwpe-based WPEBackend-android. This was achieved by incorporating changes that make WebKit use more appropriate defaults (like disabling MediaSession) or using platform-specific features (like ASharedMemory and AHardwareBuffer) when targeting Android.
The WebKit logging system has gained support to use the Android logd service. This is particularly useful for both WebKit and application developers, allowing to configure logging channels at runtime in any WPE WebKit build. For example, the following commands may be used before launching an application to debug WebGL setup and multimedia playback errors:
There is an ongoing effort to enable the WPEPlatform API on Android, and while it builds now, rendering is not yet working.
Web Platform support
As usual, changes in this area are extensive as WebKit constantly adopts, improves, and supports new Web Platform features. However, some interesting additions in this release cycle include:
Work continues on the new WPEPlatform API, which is still shipped as a preview feature in the 2.50 and needs to be explicitly enabled at build time with the ENABLE_WPE_PLATFORM=ON CMake option. The API may still change and applications developed using WPEPlatform are likely to need changes with future WPE WebKit releases; but not for long: the current goal is to have it ready and enabled by default for the upcoming 2.52 series.
One of the main changes is that WPEPlatform now gets built into libWPEWebKit. The rationale for this change is avoiding shipping two copies of shared code from the Web Template Framework (WTF), which saves both disk and memory space usage. The wpe-platform-2.0 pkg-config module is still shipped, which allows application developers to know whether WPEPlatform support has been built into WPE WebKit.
The abstract base class WPEScreenSyncObserver has been introduced, and allows platform implementations to notify on display synchronization, allowing WebKit to better pace rendering.
WPEPlatform has gained support for controllers like gamepads and joysticks through the new WPEGamepadManager and WPEGamepad classes. When building with the ENABLE_MANETTE=ON CMake option a built-in implementation based on libmanette is used by default, if a custom one is not specified.
WPEPlatform now includes a new WPEBufferAndroid class, used to represent graphics buffers backed by AHardwareBuffer. These buffers support being imported into an EGLImage using wpe_buffer_import_to_egl_image().
As part of the work to improve Android support, the buffer rendering and release fences have been moved from WPEBufferDMABuf to the base class, WPEBuffer. This is leveraged by WPEBufferAndroid, and should be helpful if more buffer types are introduced in the future.
Other additions include clipboard support, Interaction Media Features, and an accessibility implementation using ATK.
What’s new for WebKit developers?
WebKit now supports sending tracing marks and counters to Sysprof. Marks indicate when certain events occur and their duration; while counters track variables over time. Together, these allow developers to find performance bottlenecks and monitor internal WebKit performance metrics like frame rates, memory usage, and more. This integration enables developers to analyze the performance of applications, including data for WebKit alongside system-level metrics, in a unified view. For more details see this article, which also details how Sysprof was improved to handle the massive amounts of data produced by WebKit.
Finally, GCC 12.2 is now the minimum required version to build WPE WebKit. Increasing the minimum compiler version allows us to remove obsolete code and focus on improving code quality, while taking advantage of new C++ and compiler features.
Looking forward to 2.52
The 2.52 release series will bring even more improvements, and we expect it to be released during the spring of 2026. Until then!
Update on what happened in WebKit in the week from November 17 to November 24.
In this week's rendition, the WebView snapshot API was enabled on the WPE
port, further progress on the Temporal and Trusted Types implementations,
and the release of WebKitGTK and WPE WebKit 2.50.2.
Cross-Port 🐱
A WebKitImage-based implementation of WebView snapshot landed this week, enabling this feature on WPE when it was previously only available in GTK. This means you can now use webkit_web_view_get_snapshot (and webkit_web_view_get_snapshot_finish) to get a WebKitImage-representation of your screenshot.
WebKitImage implements the GLoadableIcon interface (as well as GIcon's), so you can get a PNG-encoded image using g_loadable_icon_load.
Remove incorrect early return in Trusted Types DOM attribute handling to align with spec changes.
JavaScriptCore 🐟
The built-in JavaScript/ECMAScript engine for WebKit, also known as JSC or SquirrelFish.
In JavaScriptCore's implementation of Temporal, implemented the with method for PlainMonthDay objects.
In JavaScriptCore's implementation of Temporal, implemented the from and equals methods for PlainMonthDay objects.
These stable releases include a number of patches for security issues, and as such a new security advisory, WSA-2025-0008, has been issued (GTK, WPE).
It is recommend to apply an additional patch that fixes building with the JavaScriptCore “CLoop” interpreter is enabled, which is typicall for architectures where JIT compilation is unsupported. Releases after 2.50.2 will include it and manual patching will no longer be needed.
Update on what happened in WebKit in the week from November 10 to November 17.
This week's update is composed of a new CStringView internal API, more
MathML progress with the implementation of the "scriptlevel" attribute,
the removal of the Flatpak-based SDK, and the maintanance update of
WPEBackend-fdo.
Cross-Port 🐱
Implement the MathML scriptlevel attribute using math-depth.
Finished implementing CStringView, which is a wrapper around UTF8 C strings. It allows you to recover the string without making any copies and perform string operations safely by taking into account the encoding at compile time.
Releases 📦️
WPEBackend-fdo 1.16.1 has been released. This is a maintenance update which adds compatibility with newer Mesa versions.
Infrastructure 🏗️
Most of the Flatpak-based SDK was removed. Developers are warmly encouraged to use the new SDK for their contributions to the Linux ports, this SDK has been successfully deployed on EWS and post-commits bots.
Update on what happened in WebKit in the week from November 3 to November 10.
This week brought a hodgepodge of fixes in Temporal and multimedia,
a small addition to the public API in preparation for future work,
plus advances in WebExtensions, WebXR, and Android support.
Cross-Port 🐱
The platform-independent part of the WebXR Hit Test Module has been implemented. The rest, including the FakeXRDevice mock implementation used for testing will be done later.
On the WebExtensions front, parts of the WebExtensionCallbackHandler code have been rewritten to use more C++ constructs and helper functions, in preparation to share more code among the different WebKit ports.
A new WebKitImage utility class
landed this week. This image
abstraction is one of the steps towards delivering a new improved API for page
favicons, and it is also expected to
be useful for the WebExtensions work, and to enable the webkit_web_view_get_snapshot()
API for the WPE port.
Multimedia 🎥
GStreamer-based multimedia support for WebKit, including (but not limited to) playback, capture, WebAudio, WebCodecs, and WebRTC.
Videos with BT2100-PQ colorspace are now tone-mapped to
SDR in WebKit's compositor, ensuring
colours do not appear washed out.
Adaptation of WPE WebKit targeting the Android operating system.
One of the last pieces needed to have the WPEPlatform API working on Android
has been merged: a custom platform
EGL display implementation, and enabling the default display as fallback.
Community & Events 🤝
The dates for the next Web Engines Hackfest
have been announced: it will take place from Monday, June 15th to Wednesday,
June 17th. As it has been the case in the last years, it will be possible to
attend both on-site, and remotely for those who cannot to travel to A Coruña.
The video recording for Adrian Pérez's “WPE Android 🤖 State of the Bot” talk from this year's edition of the WebKit Contributors' Meeting has been published. This was an update on what the Igalia WebKit team has been done during the last year to improve WPE WebKit on Android, and what is coming up next.
Update on what happened in WebKit in the week from October 27 to November 3.
A calmer week this time! This week we have the GTK and WPE ports implementing
the RunLoopObserver infrastructure, which enables more sophisticated scheduling
in WebKit Linux ports, as well as more information in webkit://gpu. On the Trusted
Types front, the timing of check was changed to align with spec changes.
Cross-Port 🐱
Implemented the RunLoopObserver
infrastructure for GTK and WPE ports, a critical piece of technology previously
exclusive to Apple ports that enables sophisticated scheduling features like
OpportunisticTaskScheduler for optimal garbage collection timing.
The implementation refactored the GLib run loop to notify clients about
activity-state transitions (BeforeWaiting, Entry, Exit, AfterWaiting),
then moved from timer-based to
observer-based layer flushing for more
precise control over rendering updates. Finally support was added to support
cross-thread scheduling of RunLoopObservers, allowing the ThreadedCompositor
to use them, enabling deterministic
composition notifications across thread boundaries.
Changed timing of Trusted Types
checks within DOM attribute handling to align with spec changes.
Graphics 🖼️
The webkit://gpu page now showsmoreinformation like the list of
preferred buffer formats, the list of supported buffer formats, threaded
rendering information, number of MSAA samples, view size, and toplevel state.
It is also now possible to make the
page autorefresh every the given amount of seconds by passing a
?refresh=<seconds> parameter in the URL.
Update on what happened in WebKit in the week from October 21 to October 28.
This week has again seen a spike in activity related to WebXR and graphics
performance improvements. Additionally, we got in some MathML additions, a
fix for hue interpolation, a fix for WebDriver screenshots, development
releases, and a blog post about memory profiling.
Cross-Port 🐱
Support for WebXR Layers has seen the
very firstchanges
needed to have them working on WebKit.
This is expected to take time to complete, but should bring improvements in
performance, rendering quality, latency, and power consumption down the road.
Work has started on the WebXR Hit Test
Module, which will allow WebXR
experiences to check for real world surfaces. The JavaScript API bindings were
added, followed by an initial XRRay
implementation. More work is needed to
actually provide data from device sensors.
Now that the WebXR implementation used for the GTK and WPE ports is closer to
the Cocoa ones, it was possible to unify the
code used to handle opaque buffers.
Implemented the text-transform: math-auto CSS property, which replaces the legacy mathvariant system and is
used to make identifiers italic in MathML Core.
Implemented the math-depth CSS
extension from MathML Core.
Graphics 🖼️
The hue interpolation
method
for gradients has been fixed. This is
expected to be part of the upcoming 2.50.2 stable release.
Paths that contain a single arc, oval, or line have been changed to use a
specialized code path, resulting in
improved performance.
WebGL content rendering will be handled by a new isolated process (dubbed “GPU
Process”) by default. This is the
first step towards moving more graphics processing out of the process that
handles processing Web content (the “Web Process”), which will result in
increased resilience against buggy graphics drivers and certain kinds of
malicious content.
The internal webkit://gpu page has been
improved to also display information
about the graphics configuration used in the rendering process.
WPE WebKit 📟
WPE Platform API 🧩
New, modern platform API that supersedes usage of libwpe and WPE backends.
The new WPE Platform, when using Skia (the default), now takes WebDriver
screenshots in the UI Process, using
the final assembled frame that was sent to the system compositor. This fixes
the issues of some operations like 3D CSS animations that were not correctly
captured in screenshots.
Releases 📦️
The first development releases for the current development cycle have been
published: WebKitGTK
2.51.1 and
WPE WebKit 2.51.1. These
are intended to let third parties test upcoming features and improvements and
as such bug reports for those are particularly welcome in
Bugzilla. We are particularly interested in reports
related to WebGL, now that it is handled in an isolated process.
Community & Events 🤝
Paweł Lampe has published a blog post that discusses GTK/WPE WebKit memory profiling using industry-standard tools and a built-in "Malloc Heap Breakdown" WebKit feature.
One of the main constraints that embedded platforms impose on the browsers is a very limited memory. Combined with the fact that embedded web applications tend to run actively for days, weeks, or even longer,
it’s not hard to imagine how important the proper memory management within the browser engine is in such use cases. In fact, WebKit and WPE in particular receive numerous memory-related fixes and improvements every year.
Before making any changes, however, the areas to fix/improve need to be narrowed down first. Like any C++ application, WebKit memory can be profiled using a variety of industry-standard tools. Although such well-known
tools are really useful in the majority of use cases, they have their limits that manifest themselves when applied on production-grade embedded systems in conjunction with long-running web applications.
In such cases, a very useful tool is a debug-only feature of WebKit itself called malloc heap breakdown, which this article describes.
Massif is a heap profiler that comes as part of the Valgrind suite. As its documentation states:
It measures how much heap memory your program uses. This includes both the useful space, and the extra bytes allocated for book-keeping and alignment purposes. It can also measure the size of your program’s stack(s),
although it does not do so by default.
Using Massif with WebKit is very straightforward and boils down to a single command:
The Malloc=1 environment variable set above is necessary to instruct WebKit to enable debug heaps that use the system malloc allocator.
Given some results are generated, the memory usage over time can be visualized using massif-visualizer utility. An example of such a visualization is presented in the image below:
While Massif has been widely adopted and used for many years now, from the very beginning, it suffered from a few significant downsides.
First of all, the way Massif instruments the profiled application introduces significant overhead that may slow down the application up to 2 orders of magnitude. In some cases, such overhead makes it simply unusable.
The other important problem is that Massif is snapshot-based, and hence, the level of detail is not ideal.
Heaptrack is a modern heap profiler developed as part of KDE. The below is its description from the git repository:
Heaptrack traces all memory allocations and annotates these events with stack traces. Dedicated analysis tools then allow you to interpret the heap memory profile to:
find hotspots that need to be optimized to reduce the memory footprint of your application
find memory leaks, i.e. locations that allocate memory which is never deallocated
find allocation hotspots, i.e. code locations that trigger a lot of memory allocation calls
find temporary allocations, which are allocations that are directly followed by their deallocation
At first glance, Heaptrack resembles Massif. However, a closer look at the architecture and features shows that it’s much more than the latter. While it’s fair to say it’s a bit similar, in fact, it is a
significant progression.
Usage of Heaptrack to profile WebKit is also very simple. At the moment of writing, the most suitable way to use it is to attach to a certain running WebKit process using the following command:
heaptrack -p <PID>
while the WebKit needs to be run with system malloc, just like in Massif case:
If profiling of e.g. web content process startup is essential, it’s then recommended also to use WEBKIT2_PAUSE_WEB_PROCESS_ON_LAUNCH=1, which adds 30s delay to the process startup.
When the profiling session is done, the analysis of the recordings is done using:
heaptrack --analyze <RECORDING>
The utility opened with the above, shows various things, such as the memory consumption over time:
flame graphs of memory allocations with respect to certain functions in the code:
etc.
As Heaptrack records every allocation and deallocation, the data it gathers is very precise and full of details, especially when accompanied by stack traces arranged into flame graphs. Also, as Heaptrack
does instrumentation differently than e.g. Massif, it’s usually much faster in the sense that it slows down the profiled application only up to 1 order of magnitude.
Although the memory profilers such as above are really great for everyday use, their limitations on embedded platforms are:
they significantly slow down the profiled application — especially on low-end devices,
they effectively cannot be run for a longer period of time such as days or weeks, due to memory consumption,
they are not always provided in the images — and hence require additional setup,
they may not be buildable out of the box on certain architectures — thus requiring extra patching.
While the above limitations are not always a problem, usually at least one of them is. What’s worse, usually at least one of the limitations turns into a blocking problem. For example, if the target device is very short on memory,
it may be basically impossible to run anything extra beyond the browser. Another example could be a situation where the application slowdown due to the profiler usage, leads to different application behavior, such as a problem
that originally reproduced 100% of the time, does not reproduce anymore etc.
Profiling the memory of WebKit while addressing the above problems points towards a solution that does not involve any extra tools, i.e. instrumenting WebKit itself. Normally, adding such an instrumentation to the C++ application
means a lot of work. Fortunately, in the case of WebKit, all that work is already done and can be easily enabled by using the Malloc heap breakdown.
In a nutshell, Malloc heap breakdown is a debug-only feature that enables memory allocation tracking within WebKit itself. Since it’s built into WebKit, it’s very lightweight and very easy to build, as it’s just about setting
the ENABLE_MALLOC_HEAP_BREAKDOWN build option. Internally, when the feature is enabled, WebKit switches to using debug heaps that use system malloc along with the malloc zone API
to mark objects of certain classes as belonging to different heap zones and thus allowing one to track the allocation sizes of such zones.
As the malloc zone API is specific to BSD-like OSes, the actual implementations (and usages) in WebKit have to be considered separately for Apple and non-Apple ports.
Malloc heap breakdown was originally designed only with Apple ports in mind, with the reason being twofold:
The malloc zone API is provided virtually by all platforms that Apple ports integrate with.
MacOS platforms provide a great utility called footprint that allows one to inspect per-zone memory statistics for a given process.
Given the above, usage of malloc heap breakdown with Apple ports is very smooth and as simple as building WebKit with the ENABLE_MALLOC_HEAP_BREAKDOWN build option and running on macOS while using the footprint utility:
Footprint is a macOS specific tool that allows the developer to check memory usage across regions.
Since all of the non-Apple WebKit ports are mostly being built and run on non-BSD-like systems, it’s safe to assume the malloc zone API is not offered to such ports by the system itself.
Because of the above, for many years, malloc heap breakdown was only available for Apple ports.
The idea behind the integration for non-Apple ports is to provide a simple WebKit-internal library that provides a fake <malloc/malloc.h> header along with simple implementation that provides malloc_zone_*() function implementations
as proxy calls to malloc(), calloc(), realloc() etc. along with a tracking mechanism that keeps references to memory chunks. Such an approach gathers all the information needed to be reported later on.
At the moment of writing, the above allows 2 methods of reporting the memory usage statistics periodically:
By default, when WebKit is built with ENABLE_MALLOC_HEAP_BREAKDOWN, the heap breakdown is printed to the standard output every few seconds for each process. That can be tweaked by setting WEBKIT_MALLOC_HEAP_BREAKDOWN_LOG_INTERVAL=<SECONDS>
environment variable.
The results have a structure similar to the one below:
Given the allocation statistics per-zone, it’s easy to narrow down the unusual usage patterns manually. The example of a successful investigation is presented in the image below:
Moreover, the data presented can be processed either manually or using scripts to create memory usage charts that span as long as the application lifetime so e.g. hours (20+ like below), days, or even longer:
Periodic reporting to sysprof
The other reporting mechanism currently supported is reporting periodically to sysprof as counters. In short, sysprof is a modern system-wide profiling tool
that already integrates with WebKit very well when it comes to non-Apple ports.
The condition for malloc heap breakdown reporting to sysprof is that the WebKit browser needs to be profiled e.g. using:
sysprof-cli -f -- <BROWSER_COMMAND>
and the sysprof has to be in the latest version possible.
With the above, the memory usage statistics can then be inspected using the sysprof utility and look like in the image below:
In the case of sysprof, memory statistics in that case are just a minor addition to other powerful features that were well described in this blog post from Georges.
While malloc heap breakdown is very useful in some use cases — especially on embedded systems — there are a few problems with it.
First of all, compilation with -DENABLE_MALLOC_HEAP_BREAKDOWN=ON is not guarded by any continuous integration bots; therefore, the compilation issues are expected on the latest WebKit main. Fortunately, fixing the problems
is usually straightforward. For a reference on what may be causing compilation problems usually, one should refer to 299555@main, which contains a full variety of fixes.
The second problem is that malloc heap breakdown uses WebKit’s debug heaps, and hence the memory usage patterns may be different just because system malloc is used.
The third, and final problem, is that malloc heap breakdown integration for non-Apple ports introduces some overhead as the allocations need to lock/unlock the mutex, and as statistics are stored in the memory as well.
Although malloc heap breakdown can be considered fairly constrained, in the case of non-Apple ports, it gives some additional possibilities that are worth mentioning.
Because on non-Apple ports, the custom library is used to track allocations (as mentioned at the beginning of the Malloc heap breakdown on non-Apple ports section), it’s very easy
to add more sophisticated tracking/debugging/reporting capabilities. The only file that requires changes in such a case is:
Source/WTF/wtf/malloc_heap_breakdown/main.cpp.
Some examples of custom modifications include:
adding different reporting mechanisms — e.g. writing to a file, or to some other tool,
reporting memory usage with more details — e.g. reporting the per-memory-chunk statistics,
dumping raw memory bytes — e.g. when some allocations are suspicious.
altering memory in-place — e.g. to simulate memory corruption.
While the presented malloc heap breakdown mechanism is a rather poor approximation of what industry standard tools offer, the main benefit of it is that it’s built into WebKit, and that in some rare use-cases (especially on
embedded platforms), it’s the only way to perform any reasonable profiling.
In general, as a rule of thumb, it’s not recommended to use malloc heap breakdown unless all other methods have failed. In that sense, it should be considered a last resort approach. With that in mind, malloc heap breakdown
can be seen as a nice mechanism complementing other tools in the toolbox.
Update on what happened in WebKit in the week from October 13 to October 20.
This week was calmer than previous week but we still had some
meaningful updates. We had a Selenium update, improvements to
how tile sizes are calculated, and a new Igalian in the list
of WebKit committer!
Cross-Port 🐱
Selenium's relative locators are now supported after commit 301445@main. Before, finding elements with locate_with(By.TAG_NAME, "input").above({By.ID: "password"}) could lead to "Unsupported locator strategy" errors.
Graphics 🖼️
A patch landed to compute the layers tile size, using a different strategy depending on whether GPU rendering is enabled, which improved the performance for both GPU and CPU rendering modes.
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