For a project recently it was necessary to collect video frames of multiple streams during a specific interval, and in the future also audio, to pass it through an inference framework for extracting additional metadata from the media and attaching it to the frames.

While GStreamer has gained quite a bit of infrastructure in the past years for machine learning use-cases in the analytics library, there was nothing for this specific use-case yet.

As part of solving this, I proposed as design for a generic interface that allows combining and batching multiple streams into a single one by using empty buffers with a GstMeta that contains the buffers of the original streams, and caps that include the caps of the original streams and allow format negotiation in the pipeline to work as usual.

While this covers my specific use case of combining multiple streams, it should be generic enough to also handle other cases that came up during the discussions.

In addition I wrote two new elements, analyticscombiner and analyticssplitter, that make use of this new API for combining and batching multiple streams in a generic, media-agnostic way over specific time intervals, and later splitting it out again into the original streams. The combiner can be configured to collect all media in the time interval, or only the first or last.

Conceptually the combiner element is similar to NVIDIA's DeepStream nvstreammux element, and in the future it should be possible to write a translation layer between the GStreamer analytics library and DeepStream.

The basic idea for the usage of these elements is to have a pipeline like

-- stream 1 --\                                                                  / -- stream 1 with metadata --
               -- analyticscombiner -- inference elements -- analyticssplitter --
-- stream 2 --/                                                                  \ -- stream 2 with metadata --
   ........                                                                           ......................
-- stream N -/                                                                     \- stream N with metadata --

The inference elements would only add additional metadata to each of the buffers, which can then be made use of further downstream in the pipeline for operations like overlays or blurring specific areas of the frames.

In the future there are likely going to be more batching elements for specific stream types, operating on multiple or a single stream, or making use of completely different batching strategies.

Special thanks also to Olivier and Daniel who provided very useful feedback during the review of the two merge requests.

The GStreamer team is pleased to announce another bug fix release in the new stable 1.26 release series of your favourite cross-platform multimedia framework!

This release only contains bugfixes as well as a number of security fixes and important playback fixes, and it should be safe to update from 1.26.x.

Highlighted bugfixes:

• Various security fixes and playback fixes
• Security fix for the H.266 video parser
• Fix regression for WAV files with acid chunks
• Fix high memory consumption caused by a text handling regression in uridecodebin3 and playbin3
• Fix panic on late GOP in fragmented MP4 muxer
• Closed caption conversion, rendering and muxing improvements
• Decklink video sink preroll frame rendering and clock drift handling fixes
• MPEG-TS demuxing and muxing fixes
• MP4 muxer fixes for creating very large files with faststart support
• New thread-sharing 1:N inter source and sink elements, and a ts-rtpdtmfsrc
• New speech synthesis element around ElevenLabs API
• RTP H.265 depayloader fixes and improvements, as well as TWCC and GCC congestion control fixes
• Seeking improvements in DASH client for streams with gaps
• WebRTC sink and source fixes and enhancements, including to LiveKit and WHIP signallers
• The macOS osxvideosink now posts navigation messages
• QtQML6GL video sink input event handling improvements
• Overhaul detection of hardware-accelerated video codecs on Android
• Video4Linux capture source fixes and support for BT.2100 PQ and 1:4:5:3 colorimetry
• Vulkan buffer upload and memory handling regression fixes
• Python bindings: fix various regressions introduced in 1.26.2
• cerbero: fix text relocation issues on 32-bit Android and fix broken VisualStudio VC templates
• packages: ship pbtypes plugin and update openssl to 3.5.0 LTS
• Various bug fixes, build fixes, memory leak fixes, and other stability and reliability improvements

See the GStreamer 1.26.3 release notes for more details.

Binaries for Android, iOS, Mac OS X and Windows will be available shortly.

With GStreamer 1.26, a new D3D12 backend GstD3D12 public library was introduced in gst-plugins-bad.

Now, with the new gstreamer-d3d12 rust crate, Rust can finally access the Windows-native GPU feature written in GStreamer in a safe and idiomatic way.

What You Get with GStreamer D3D12 Support in Rust

• Pass D3D12 textures created by your Rust application directly into GStreamer pipelines without data copying
• Likewise, GStreamer-generated GPU resources (such as frames decoded by D3D12 decoders) can be accessed directly in your Rust app
• GstD3D12 base GStreamer element can be written in Rust

Beyond Pipelines: General D3D12 Utility Layer

GstD3D12 is not limited to multimedia pipelines. It also acts as a convenient D3D12 runtime utility, providing:

• GPU resource pooling such as command allocator and descriptor heap, to reduce overhead and improve reuse
• Abstractions for creating and recycling GPU textures with consistent lifetime tracking
• Command queue and fence management helpers, greatly simplifying GPU/CPU sync
• A foundation for building custom GPU workflows in Rust, with or without the full GStreamer pipeline

The GStreamer team is pleased to announce another bug fix release in the new old stable 1.24 release series of your favourite cross-platform multimedia framework!

This release only contains bugfixes as well as a number of security fixes and important playback fixes, and it should be safe to update from 1.24.x.

Please note that the 1.24 old-stable series is no longer actively maintained and has been superseded by the GStreamer 1.26 stable series now.

Highlighted bugfixes:

• Various security fixes and playback fixes
• MP4 demuxer atom parsing improvements and security fixes
• H.265 decoder base class and caption inserter SPS/PPS handling fixes
• Subtitle parser security fixes
• Subtitle rendering and seeking fixes
• Closed caption fixes
• Matroska rotation tag support and v4 muxing support
• Ogg seeking improvements in streaming mode
• Windows plugin loading fixes
• MIDI parser improvements for tempo changes
• Video time code support for 119.88 fps and drop-frames-related conversion fixes
• GStreamer editing services fixes for sources with non-1:1 aspect ratios
• RTP session handling and RTSP server fixes
• Thread-safety improvements for the Media Source Extension (MSE) library
• macOS video capture improvements for external devices
• Python bindings: Fix compatibility with PyGObject >= 3.52.0
• cerbero: bootstrapping fixes on Windows, improved support for RHEL, and openh264 recipe update
• Various bug fixes, build fixes, memory leak fixes, and other stability and reliability improvements

See the GStreamer 1.24.13 release notes for more details.

Binaries for Android, iOS, Mac OS X and Windows will be available shortly.

The GStreamer team is pleased to announce another bug fix release in the new stable 1.26 release series of your favourite cross-platform multimedia framework!

This release only contains bugfixes as well as a number of security fixes and important playback fixes, and it should be safe to update from 1.26.x.

Highlighted bugfixes:

• Various security fixes and playback fixes
• aggregator base class fixes to not produce buffers too early in live mode
• AWS translate element improvements
• D3D12 video decoder workarounds for crashes on NVIDIA cards on resolution changes
• dav1d AV1-decoder performance improvements
• fmp4mux: tfdt and composition time offset fixes, plus AC-3 / EAC-3 audio support
• GStreamer editing services fixes for sources with non-1:1 aspect ratios
• MIDI parser improvements for tempo changes
• MP4 demuxer atom parsing improvements and security fixes
• New skia-based video compositor element
• Subtitle parser security fixes
• Subtitle rendering and seeking fixes
• Playbin3 and uridecodebin3 stability fixes
• GstPlay stream selection improvements
• WAV playback regression fix
• GTK4 paintable sink colorimetry support and other improvements
• WebRTC: allow webrtcsrc to wait for a webrtcsink producer to initiate the connection
• WebRTC: new Janus Video Room WebRTC source element
• vah264enc profile decision making logic fixes
• Python bindings gained support for handling mini object writability (buffers, caps, etc.)
• Various bug fixes, build fixes, memory leak fixes, and other stability and reliability improvements

See the GStreamer 1.26.2 release notes for more details.

Binaries for Android, iOS, Mac OS X and Windows will be available shortly.

The release of GStreamer 1.26, last March, delivered new features, optimization and improvements. Igalia played its role as long standing contributor, with 382 commits (194 merge requests) from a total of 2666 of commits merged in this release.This blog post takes a closer look on those contributions.

gst-devtools #

This module contains development and validation tools.

gst-dot-viewer #

gst-dot-viewer is a new web tool for real-time pipeline visualization. Our colleague, Thibault, wrote a blog post about its usage.

validate #

GstValidate is a tool to check if elements are behaving as expected.

• Added support for HTTP Testing.
• Scenario fixes such as reset pipelines on expected errors to avoid inconsistent states, improved error logging, and async action handling to prevent busy loops.

gst-editing-services #

GStreamer Editing Services is a library to simplify the creation of multimedia editing applications.

• Enabled reverse playback, by adding a reverse property to nlesource for seamless backward clip playback.
• Added internal tests for Non-Linear Engine elements.

gst-libav #

GStreamer Libav plug-in contains a set of many popular decoders and encoders using FFmpeg.

• As part of the effort to support VVC/H.266 in GStreamer FFmpeg VVC/H.266 decoder was exposed.
• Optimized framerate renegotiation in avviddec without decoder resets.
• Mapped GST_VIDEO_FORMAT_GRAY10_LE16 format to FFmpeg’s equivalent.

gstreamer #

Core library.

• Added a tracer for gst-dots-viewer.
• Log tracers improvements such as, replaced integer codes with readable strings, to track pad’s sticky events, and simplify parameters handling, etc.
• On pads, don’t push sticky events in response to a FLUSH_STOP event.
• On queue element, fixed missing notify signals for level changes.
• Pipeline parser now logs bus error messages during pipeline construction.
• Fixed gst_util_ceil_log2 utility function.

gst-plugins-base #

GStreamer Base Plugins is a well-groomed and well-maintained collection of plugins. It also contains helper libraries and base classes useful for writing elements.

• audiorate: respect tolerance property to avoid unnecessary sample adjustments for minor gaps.
• audioconvert: support reordering of unpositioned input channels.
• videoconvertscale: improve aspect ratio handling.
• glcolorconvert: added I422_10XX, I422_12XX, Y444_10XX, and Y444_16XX color formats, and fixed caps negotiation for DMABuf.
• glvideomixer: handle mouse events.
• pbutils: added VVC/H.266 codec support
• encodebasebin: parser fixes.
• oggdemux: fixed seek to the end of files.
• rtp: fixed precision for UNIX timestamp.
• sdp: enhanced debugging messages.
• parsebin: improved caps negotiation.
• decodebin3: added missing locks to prevent race conditions.
• streamsynchronizer: improved documentation.

gst-plugins-good #

GStreamer Good Plugins is a set of plugins considered to have good quality code, correct functionality, and uses LGPL/LGPL+compatible licenses.

• hlsdemux2: handle empty segments at the beginning of a stream.
• qtmux and matroska: add support for VVC/H.266.
• matroskademux:support seek with stop in push mode.
• rtp: several fixes.
• osxaudio: fixes.
• videoflip: support Y444_16LE and Y444_16BE color formats.
• vpx: enhance error and warning messages.

gst-plugins-bad #

GStreamer Bad Plug+ins is a set of plugins that aren’t up to par compared to the rest. They might be close to being good quality, but they’re missing something, be it a good code review, some documentation, a set of tests, etc.

• dashsink: a lot of improvements and cleanups, such as unit tests, state and event management.
• h266parse: enabled vvc1 and vvi1 stream formats, improved code data parsing and negotiatios, along with cleanups and fixes.
• mpegtsmux and tsdemux: added support for VVC/H.266 codec.
• vulkan:
  • Added compatibility for timeline semaphores and barriers.
  • Initial support of multiple GPU and dynamic element registering.
  • Vulkan image buffer pool improvements.
  • vulkanh264dec: support interlaced streams.
  • vulkanencoding: rate control and quality level adjustments, update SPS/PPS, support layered DPBs.
• webrtcbin:
  • Resolved duplicate payload types in SDP offers with RTX and multiple codecs.
  • Transceivers are now created earlier during negotiation to avoid linkage issues.
  • Allow session level in setup attribute in SDP answer.
• wpevideosrc:
  • code cleanups
  • cached SHM buffers are cleared after caps renegotiation.
  • handle latency queries and post progress messages on bus.
• srtdec: fixes
• jpegparse: handle avi1 tag for progressive images
• va: improve encoders configuration when properties change in run+time, specially rate control.

As part of the GStreamer Hackfest in Nice, France I had some time to go through some outstanding GStreamer issues. One such issue that has been on my mind was this GStreamer OpenGL Wayland issue.

Now, the issue is that OpenGL is an old API and did not have some of the platform extensions it does today. As a result, most windowing system APIs allow creating an output surface (or a window) but never showing it. This also works just fine when you are creating an OpenGL context but not actually rendering anything to the screen and this approach is what is used by all of the other major OpenGL platforms (Windows, macOS, X11, etc) supported by GStreamer.

When wayland initially arrived, this was not the case. A wayland surface could be the back buffer (an OpenGL term for rendering to a surface) but could not be hidden. This is very different from how other windowing APIs worked at the time. As a result, the initial implementation using Wayland within GStreamer OpenGL used some heuristics for determining when a wayland surface would be created and used that basically boiled down to, if there is no shared OpenGL context, then create a window.

This heuristic obviously breaks in multiple different ways, the two most obvious being:

1. gltestsrc ! gldownload ! some-non-gl-sink - there should be no surface used here.
2. gltestsrc ! glimagesink gltestsrc ! glimagesink - there should be two output surfaces used here.

The good news is that issue is now fixed by adding some API that glimagesink can use to notify that it would like an output surface. This has been implemented in this merge request and will be part of GStreamer 1.28.

We’re happy to have released gst-dots-viewer, a new development tool that makes it easier to visualize and debug GStreamer pipelines. This tool,  included in GStreamer 1.26, provides a web-based interface for viewing pipeline graphs in real-time as your application runs and allows to easily request all pipelines to be dumped at any time.

What is gst-dots-viewer?

gst-dots-viewer is a server application that monitors a directory for .dot files generated by GStreamer’s pipeline visualization system and displays them in your web browser. It automatically updates the visualization whenever new .dot files are created, making it simpler to debug complex applications and understand the evolution of the pipelines at runtime.

Key Features

• Real-time Updates: Watch your pipelines evolve as your application runs
• Interactive Visualization:
  • Click nodes to highlight pipeline elements
  • Use Shift-Ctrl-scroll or w/s keys to zoom
  • Drag-scroll support for easy navigation
• Easily deployable in cloud based environments

How to Use It

1. Start the viewer server:

   gst-dots-viewer
   

2. Open your browser at http://localhost:3000
3. Enable the dots tracer in your GStreamer application:

   GST_TRACERS=dots your-gstreamer-application
   

The web page will automatically update whenever new pipeline are dumped, and you will be able to dump all pipelines from the web page.

New Dots Tracer

As part of this release, we’ve also introduced a new dots tracer that replaces the previous manual approach to specify where to dump pipelines. The tracer can be activated simply by setting the GST_TRACERS=dots environment variable.

Interactive Pipeline Dumps

The dots tracer integrates with the pipeline-snapshot tracer to provide real-time pipeline visualization control. Through a WebSocket connection, the web interface allows you to trigger pipeline dumps. This means you can dump pipelines exactly when you need them during debugging or development, from your browser.

Future Improvements

We plan on adding more feature and  have this list of possibilities:

• Additional interactive features in the web interface
• Enhanced visualization options
• Integration with more GStreamer tracers to provide comprehensive debugging information. For example, we could integrate the newly released memory-tracer and queue-level tracers so to plot graphs about memory usage at any time.

This could transform gst-dots-viewer into a more complete debugging and monitoring dashboard for GStreamer applications.

Demo

The GStreamer team is pleased to announce another bug fix release in the new stable 1.26 release series of your favourite cross-platform multimedia framework!

This release only contains bugfixes and security fixes, and it should be safe to update from 1.26.0.

Highlighted bugfixes:

• awstranslate and speechmatics plugin improvements
• decodebin3 fixes and urisourcebin/playbin3 stability improvements
• Closed captions: CEA-708 generation and muxing fixes, and H.264/H.265 caption extractor fixes
• dav1d AV1 decoder: RGB support, plus colorimetry, renegotiation and buffer pool handling fixes
• Fix regression when rendering VP9 with alpha
• H.265 decoder base class and caption inserter SPS/PPS handling fixes
• hlssink3 and hlsmultivariantsink feature enhancements
• Matroska v4 support in muxer, seeking fixes in demuxer
• macOS: framerate guessing for cameras or capture devices where the OS reports silly framerates
• MP4 demuxer uncompressed video handling improvements and sample table handling fixes
• oggdemux: seeking improvements in streaming mode
• unixfdsrc: fix gst_memory_resize warnings
• Plugin loader fixes, especially for Windows
• QML6 GL source renegotiation fixes
• RTP and RTSP stability fixes
• Thread-safety improvements for the Media Source Extension (MSE) library
• v4l2videodec: fix A/V sync issues after decoding errors
• Various improvements and fixes for the fragmented and non-fragmented MP4 muxers
• Video encoder base class segment and buffer timestamp handling fixes
• Video time code support for 119.88 fps and drop-frames-related conversion fixes
• WebRTC: Retransmission entry creation fixes and better audio level header extension compatibility
• YUV4MPEG encoder improvments
• dots-viewer: make work locally without network access
• gst-python: fix compatibility with PyGObject >= 3.52.0
• Cerbero: recipe updates, compatibility fixes for Python < 3.10; Windows Android cross-build improvements
• Various bug fixes, build fixes, memory leak fixes, and other stability and reliability improvements

See the GStreamer 1.26.1 release notes for more details.

Binaries for Android, iOS, Mac OS X and Windows will be available shortly.

We are excited about the Fedora Workstation 42 released today. Having worked on some great features for it.

Fedora Workstation 42 HDR edition
I would say that the main feature that landed was HDR or High Dynamic Range. It is a feature we spent years on with many team members involved and a lot of collaboration with various members of the wider community.

GNOME Settings menu showing HDR settings

HDR setup in Ori and Will of the Wisps

One area that should benefit from HDR support are games. In the screenshot about you see the game Ori and the Will of the Wisps which is known for great HDR support. Valve will need to update to a Wine version for Proton that supports Wayland natively though before this just works, at the moment you can get it working using gamescope, but hopefully soon it will just work under both Mutter and Kwin.

Also a special shoutout to the MPV community for quickly jumping on this and releasing a HDR capable video player recently.

MPV video player playing HDR content

Of course getting Fedora Workstation 42 to out with these features is just the beginning, with the baseline support it now is really the time when application maintainers have a real chance of starting to make use of these features, so I would expect various content creative applications for instance to start having support over the next year.

For the desktop itself there are also open questions we need to decide on like:

• Format to use for HDR screenshots
• Better backlight and brightness handling
• Better offloading
• HDR screen recording video format
• How to handle HDR webcams (seems a lot of them are not really capable of producing HDR output).
• Version of the binary NVIDIA driver released supporting the VK_EXT_hdr_metadata and VK_COLOR_SPACE_HDR10_ST2084_EXT Vulkan extension on Linux
• A million smaller issues we will need to iron out

Accessibility
Our accessibility team has been hard at work trying to ensure we have a great accessibility story in Fedora Workstation 42. Our accessibility team with Lukas Tyrychtr and Bohdan Milar has been working hard together with others to ensure that Fedora Workstation 42 has the best accessibility support you can get on Linux. One major effort that landed was the new keyboard monitoring interface which is critical for making Orca work well under Wayland. This was a collaboration of between Lukas Tyrychtr, Matthias Clasen and Carlos Garnacho on our team. If you are interested in Accessibility, as a user or a developer or both then make sure to join in by reaching out to the Accessibility Working group

PipeWire
PipeWire also keeps going strong with continuous improvements and bugfixes. Thanks to the great work by Jan Grulich the support for PipeWire in Firefox and Chrome is now working great, including for camera handling. It is an area where we want to do an even better job though, so Wim Taymans is currently looking at improving video handling to ensure we are using the best possible video stream the camera can provide and handle conversion between formats transparently. He is currently testing it out using a ffmpeg software backend, but the end goal is to have it all hardware accelerated through directly using Vulkan.

Another feature Wim Taymans added recently is MIDI2 support. This is the next generation of MIDI with only a limited set of hardware currently supporting it, but on the other hand it feels good that we are now able to be ahead of the curve instead of years behind thanks to the solid foundation we built with Pipewire.

Wayland
For a long time the team has been focused on making sure Wayland has all the critical pieces and was functionality wise on the same level as X11. For instance we spent a lot of time and effort on ensuring proper remote desktop support. That work all landed in the previous Fedora release which means that over the last 6 Months the team has had more time to look at things like various proposed Wayland protocols and get them supported in GNOME. Thanks to that we helped ensure the Cursor Shape Protocol and Toplevel Drag protocols got landed in time for this release. We are already looking and what to help land for the next release, so expect a continued acceleration in Wayland protocol adoption going forward.

First steps into AI
So an effort we been plugging away at recently is starting to bring AI tooling to Open Source desktop applications. Our first effort in this regard is Granite.code. Granite.code is a extension for Visual Studio Code that sets up a local AI engine on your system to help with various tasks including code generation and chat inside Visual Studio Code. So what is special about this effort is that it relies on downloading and running a copy of the open source AI Granite LLM model to your system instead on relying on it being run in a cloud instance somewhere. That means you can use Granite.code without having to share your data and work with someone else. Granite.code is still very early stage and it requires a NVIDIA or AMD GPU with over 8GB of video ram to use under Linux. (It also runs under Windows and MacOS X). It is still in a pre-release stage, we are waiting for the Granite 3.3 model update to enable some major features for us before we make the first formal release, but for those willing to help us test you can search for Granite in the Visual Studio Code extension marketplace and install it.
We are hoping though that this will just the starting point where our work can get picked up and used by other IDEs out there too and also we are thinking about how we can offer AI features in other parts of the desktop too.

Granite.code running on Linux

The GStreamer project is thrilled to announce that there will be a spring hackfest on Friday-Sunday 16-18 May 2025 in Nice, France.

For more details and latest updates check out the announcement on Discourse.

We will announce any further updates on Discourse, but you can also follow us on Bluesky and on on Mastodon.

We hope to see you in Nice!

Please spread the word!

Recently, GStreamer development story integrated the usage of pre-commit. pre-commit is a Git hook script that chain different linters, checkers, validators, formatters, etc., that are executed at git commit. This script is in Python. And there’s other GStreamer utility in Python: hotdoc

The challenge is that Debian doesn’t allow to install Python packages through pip, they have to be installed as Debian packages or inside virtual environments, such as venv.

So, instead of activating a virtual environment when I work in GStreamer, let’s just use direnv to activate it automatically.

Here’s a screencast of what I did to setup a Python virtual environment, within direnv, and installing pre-commit, hotdoc and gst-indent-1.0.

UPDATE: Tim told me that wit pipx we can do the same without the venv hassle.

https://mastodon.social/@tp_muller@fosstodon.org/114150178786863565

The GStreamer team is excited to announce a new major feature release of your favourite cross-platform multimedia framework!

As always, this release is again packed with new features, bug fixes and many other improvements.

The 1.26 release series adds new features on top of the previous 1.24 series and is part of the API and ABI-stable 1.x release series of the GStreamer multimedia framework.

Highlights:

• H.266 Versatile Video Coding (VVC) codec support
• Low Complexity Enhancement Video Coding (LCEVC) support
• Closed captions: H.264/H.265 extractor/inserter, cea708overlay, cea708mux, tttocea708 and more
• New hlscmafsink, hlssink3, and hlsmultivariantsink; HLS/DASH client and dashsink improvements
• New AWS and Speechmatics transcription, translation and TTS services elements, plus translationbin
• Splitmux lazy loading and dynamic fragment addition support
• Matroska: H.266 video and rotation tag support, defined latency muxing
• MPEG-TS: support for H.266, JPEG XS, AV1, VP9 codecs and SMPTE ST-2038 and ID3 meta; mpegtslivesrc
• ISO MP4: support for H.266, Hap, Lagarith lossless codecs; raw video support; rotation tags
• SMPTE 2038 ancillary data streams support
• JPEG XS image codec support
• Analytics: New TensorMeta; N-to-N relationships; Mtd to carry segmentation masks
• ONVIF metadata extractor and conversion to/from relation metas
• New originalbuffer element that can restore buffers again after transformation steps for analytics
• Improved Python bindings for analytics API
• Lots of Vulkan integration and Vulkan Video decoder/encoder improvements
• OpenGL integration improvements, esp. in glcolorconvert, gldownload, glupload
• Qt5/Qt6 QML GL sinks now support direct DMABuf import from hardware decoders
• CUDA: New compositor, Jetson NVMM memory support, stream-ordered allocator
• NVCODEC AV1 video encoder element, and nvdsdewarp
• New Direct3D12 integration support library
• New d3d12swapchainsink and d3d12deinterlace elements and D3D12 sink/source for zero-copy IPC
• Decklink HDR support (PQ + HLG) and frame scheduling enhancements
• AJA capture source clock handling and signal loss recovery improvements
• RTP and RTSP: New rtpbin sync modes, client-side MIKEY support in rtspsrc
• New Rust rtpbin2, rtprecv, rtpsend, and many new Rust RTP payloaders and depayloaders
• webrtcbin support for basic rollbacks and other improvements
• webrtcsink: support for more encoders, SDP munging, and a built-in web/signalling server
• webrtcsrc/sink: support for uncompressed audio/video and NTP & PTP clock signalling and synchronization
• rtmp2: server authentication improvements incl. Limelight CDN (llnw) authentication
• New Microsoft WebView2 based web browser source element
• The GTK3 plugin has gained support for OpenGL/WGL on Windows
• Many GTK4 paintable sink improvements
• GstPlay: id-based stream selection and message API improvements
• Real-time pipeline visualization in a browser using a new dots tracer and viewer
• New tracers for tracking memory usage, pad push timings, and buffer flow as pcap files
• VA hardware-acclerated H.266/VVC decoder, VP8 and JPEG encoders, VP9/VP8 alpha decodebins
• Video4Linux2 elements support DMA_DRM caps negotiation now
• V4L2 stateless decoders implement inter-frame resolution changes for AV1 and VP9
• Editing services: support for reverse playback and audio channel reordering
• New QUIC-based elements for working with raw QUIC streams, RTP-over-QUIC (RoQ) and WebTransport
• Apple AAC audio encoder and multi-channel support for the Apple audio decoders
• cerbero: Python bindings and introspection support; improved Windows installer based on WiX5
• Lots of new plugins, features, performance improvements and bug fixes

For more details check out the GStreamer 1.26 release notes.

Binaries for Android, iOS, macOS and Windows will be provided in due course.

You can download release tarballs directly here: gstreamer, gst-plugins-base, gst-plugins-good, gst-plugins-ugly, gst-plugins-bad, gst-libav, gst-rtsp-server, gst-python, gst-editing-services, gst-devtools, gstreamer-vaapi, gstreamer-sharp, gstreamer-docs.

UK calling

Long time no see this beautiful grey sky, roast beef on sunday and large but full packed pub when there is a football or a rugby game (The rose team has been lucky this year, grrr).

It was a delightful journey in the UK starting with my family visiting London including a lot (yes a lot…) of sightviews in a very short amount of time. But we managed to fit everything in. We saw the changing of the guards, the Thames river tide on a boat, Harry Potter gift shops and the beautiful Arsenal stadium with its legendary pitch, one of the best of England.

It was our last attraction in London and now it was time for my family to go to Standsted back home and me to Cambridge and its legendary university.

To start the journey in Cambridge, first I got some rest on Monday in the hotel to face the hail of information I will get during the conference. This year, Vulkanised took place on Arm’s campus, who kindly hosted the event, providing everything we needed to feel at home and comfortable.

The first day, we started with an introduction from Ralph Potter, the Vulkan Working Group Chair at Khronos, who introduced the new 1.4 release and all the extensions coming along including “Vulkan Video”. Then we could start this conference with my favorite topic, decoding video content with Vulkan Video. And the game was on! There was a presentation every 30 minutes including a neat one from my colleague at Igalia Ricardo Garcia about Device-Generated Commands in Vulkan and a break every 3 presentations. It took a lot of mental energy to keep up with all the topics as each presentation was more interesting than the last. During the break, we had time to relax with good coffee, delicious cookies, and nice conversations.

The first day ended up with a tooling demonstrations from LunarG, helping us all to understand and tame the Vulkan beast. The beast is ours now!

As I was not in the best shape due to a bug I caught on Sunday, I decided to play it safe and went to the hotel just after a nice indian meal. I had to prepare myself for the next day, where I would present “Vulkan Video is Open: Application Showcase”.

Vulkan Video is Open: Application showcase !

First Srinath Kumarapuram from Nvidia gave a presentation about the new extensions made available during 2024 by the Vulkan Video TSG. It started with a brief timeline of the video extensions from the initial h26x decoding to the latest VP9 decode coming this year including the 2024 extensions such as the AV1 codec. Then he presented more specific extensions such as VK_KHR_video_encode_quantization_map, VK_KHR_video_maintenance2 released during 2024 and coming in 2025, VK_KHR_video_encode_intra_refresh. He mentioned that the Vulkan toolbox now completely supports Vulkan Video, including the Validation Layers, Vulkan Profiles, vulkaninfo or GFXReconstruct.

After some deserved applause for a neat presentation, it was my time to be on stage.

During this presentation I focused on the Open source ecosystem around Vulkan Video. Indeed Vulkan Video ships with a sample app which is totally open along with the regular Conformance Test Suite. But that’s not all! Two major frameworks now ship with Vulkan Video support: GStreamer and FFmpeg.

Before this, I started by talking about Mesa, the open graphics library. This library which is totally open provides drivers which support Vulkan Video extensions and allow applications to run Vulkan Video decode or encode. The 3 major chip vendors are now supported. It started in 2022 with RADV, a userspace driver that implements the Vulkan API on most modern AMD GPUs. This driver supports all the vulkan video extensions except the lastest ones such as VK_KHR_video_encode_quantization_map or VK_KHR_video_maintenance2 but this they should be implemented sometime in 2025. Intel GPUs are now supported with the ANV driver, this driver also supports the common video extensions such as h264/5 and AV1 codec. The last driver to gain support was at the end of 2024 where several of the Vulkan Video extensions were introduced to NVK, a Vulkan driver for NVIDIA GPUs. This driver is still experimental but it’s possible to decode H264 and H265 content as well as its proprietary version. This completes the offering of the main GPUs on the market.

Then I moved to the applications including GStreamer, FFmpeg and Vulkan-Video-Samples. In addition to the extensions supported in 2025, we talked mainly about the decode conformance using Fluster. To compare all the implementations, including the driver, the version and the framework, a spreadsheet can be found here. In this spreadsheet we summarize the 3 supported codecs (H264, H265 and AV1) with their associated test suites and compare their implemententations using Vulkan Video (or not, see results for VAAPI with GStreamer). GStreamer, my favorite playground, can now decode H264 and H265 since 1.24 and recently got the support for AV1 but the merge request is still under review. It supports more than 80% of the H264 test vectors for the JVT-AVC_V1 and 85% of the H265 test vectors in JCT-VC-HEVC_V1. FFMpeg is offering better figures passing 90% of the tests. It supports all the avaliable codecs including all of the encoders as well. And finally Vulkan-Video-Samples is the app that you want to use to support all codecs for both encode and decode, but its currently missing support for mesa drivers when it comes to use Fluster decode tests..

Vulkanised on the 3rd day

During the 3rd day, we had interesting talks as well demonstrating the power of Vulkan, from Blender, a free and open-source 3D computer graphics software tool switching progressively to Vulkan, to the implementation of 3D a game engine using Rust, or compute shaders in Astronomy. My other colleague at Igalia, Lucas Fryzek, also had a presentation on Mesa with Lavapipe: a Mesa’s Software Renderer for Vulkan which allows you to have a hardware free implementation of Vulkan and to validate extensions in a simpler way. Finally, we finished this prolific and dense conference with Android and its close collaboration with Vulkan.

If you are interested in 3D graphics, I encourage you to attend future Vulkanised editions, which are full of passionate people. And if you can not attend you can still watch the presentation online.

If you are interested in the Vulkan Video presentation I gave, you can catch up the video here:

Or follow our Igalia live blog post on Vulkan Video:

https://blogs.igalia.com/vjaquez/vulkan-video-status/

As usual, if you would like to learn more about Vulkan, GStreamer or any other open multimedia framework, please feel free to contact us!

The GStreamer team is excited to announce the first release candidate for the upcoming stable 1.26.0 feature release.

This 1.25.90 pre-release is for testing and development purposes in the lead-up to the stable 1.26 series which is now frozen for commits and scheduled for release very soon.

Depending on how things go there might be more release candidates in the next couple of days, but in any case we're aiming to get 1.26.0 out as soon as possible.

Binaries for Android, iOS, Mac OS X and Windows will be made available shortly at the usual location.

Release tarballs can be downloaded directly here:

• gstreamer-1.25.90.tar.xz
• gst-plugins-base-1.25.90.tar.xz
• gst-plugins-good-1.25.90.tar.xz
• gst-plugins-ugly-1.25.90.tar.xz
• gst-plugins-bad-1.25.90.tar.xz
• gst-libav-1.25.90.tar.xz
• gst-rtsp-server-1.25.90.tar.xz
• gst-python-1.25.90.tar.xz
• gst-editing-services-1.25.90.tar.xz
• gst-devtools-1.25.90.tar.xz,
• gstreamer-vaapi-1.25.90.tar.xz
• gst-omx-1.25.90.tar.xz
• gstreamer-docs-1.25.90.tar.xz

As always, please give it a spin and let us know of any issues you run into by filing an issue in GitLab.

The GStreamer team is pleased to announce another release of liborc, the Optimized Inner Loop Runtime Compiler, which is used for SIMD acceleration in GStreamer plugins such as audioconvert, audiomixer, compositor, videoscale, and videoconvert, to name just a few.

This is a bug-fix release.

Highlights:

• orccodemem: Don't modify the process umask, which caused race conditions with other threads
• Require glibc >= 2.07
• x86: various SSE and MMX fixes
• avx: Fix sqrtps encoding causing an illegal instruction crash
• Hide internal symbols from ABI and do not install internal headers
• Rename backend to target, including `orc-backend` meson option and `ORC_BACKEND` environment variable
• Testsuite, tools: Disambiguate OrcProgram naming conventions
• Build: Fix `_clear_cache` call for Clang and error out on implicit function declarations
• opcodes: Use MIN instead of CLAMP for known unsigned values to fix compiler warnings
• ci improvements: Upload the generated .S and .bin and include Windows artifacts
• Spelling fix in debug log message

Direct tarball download: orc-0.4.41.tar.xz.

The GStreamer team is pleased to announce another development release in the unstable 1.25 release series.

The unstable 1.25 release series is for testing and development purposes in the lead-up to the stable 1.26 series which is scheduled for release ASAP. Any newly-added API can still change until that point.

This development release is primarily for developers and early adopters.

The plan is to get 1.26 out of the door as quickly as possible, and with this release a feature freeze is now in effect.

Binaries for Android, iOS, Mac OS X and Windows will be made available shortly at the usual location.

Release tarballs can be downloaded directly here:

• gstreamer-1.25.50.tar.xz
• gst-plugins-base-1.25.50.tar.xz
• gst-plugins-good-1.25.50.tar.xz
• gst-plugins-ugly-1.25.50.tar.xz
• gst-plugins-bad-1.25.50.tar.xz
• gst-libav-1.25.50.tar.xz
• gst-rtsp-server-1.25.50.tar.xz
• gst-python-1.25.50.tar.xz
• gst-editing-services-1.25.50.tar.xz
• gst-devtools-1.25.50.tar.xz,
• gstreamer-vaapi-1.25.50.tar.xz
• gstreamer-docs-1.25.50.tar.xz

As always, please give it a spin and let us know of any issues you run into by filing an issue in GitLab.

So a we are a little bit into the new year I hope everybody had a great break and a good start of 2025. Personally I had a blast having gotten the kids an air hockey table as a Yuletide present :). Anyway, wanted to put this blog post together talking about what we are looking at for the new year and to let you all know that we are hiring.

Artificial Intelligence
One big item on our list for the year is looking at ways Fedora Workstation can make use of artificial intelligence. Thanks to IBMs Granite effort we know have an AI engine that is available under proper open source licensing terms and which can be extended for many different usecases. Also the IBM Granite team has an aggressive plan for releasing updated versions of Granite, incorporating new features of special interest to developers, like making Granite a great engine to power IDEs and similar tools. We been brainstorming various ideas in the team for how we can make use of AI to provide improved or new features to users of GNOME and Fedora Workstation. This includes making sure Fedora Workstation users have access to great tools like RamaLama, that we make sure setting up accelerated AI inside Toolbx is simple, that we offer a good Code Assistant based on Granite and that we come up with other cool integration points.

Wayland
The Wayland community had some challenges last year with frustrations boiling over a few times due to new protocol development taking a long time. Some of it was simply the challenge of finding enough people across multiple projects having the time to follow up and help review while other parts are genuine disagreements of what kind of things should be Wayland protocols or not. That said I think that problem has been somewhat resolved with a general understanding now that we have the ‘ext’ namespace for a reason, to allow people to have a space to review and make protocols without an expectation that they will be universally implemented. This allows for protocols of interest only to a subset of the community going into ‘ext’ and thus allowing protocols that might not be of interest to GNOME and KDE for instance to still have a place to live.

The other more practical problem is that of having people available to help review protocols or providing reference implementations. In a space like Wayland where you need multiple people from multiple different projects it can be hard at times to get enough people involved at any given time to move things forward, as different projects have different priorities and of course the developers involved might be busy elsewhere. One thing we have done to try to help out there is to set up a small internal team, lead by Jonas Ådahl, to discuss in-progress Wayland protocols and assign people the responsibility to follow up on those protocols we have an interest in. This has been helpful both as a way for us to develop internal consensus on the best way forward, but also I think our contribution upstream has become more efficient due to this.

All that said I also believe Wayland protocols will fade a bit into the background going forward. We are currently at the last stage of a community ‘ramp up’ on Wayland and thus there is a lot of focus on it, but once we are over that phase we will probably see what we saw with X.org extensions over time, that for the most time new extensions are so niche that 95% of the community don’t pay attention or care. There will always be some new technology creating the need for important new protocols, but those are likely to come along a relatively slow cadence.

High Dynamic Range

HDR support in GNOME Control Center

As for concrete Wayland protocols the single biggest thing for us for a long while now has of course been the HDR support for Linux. And it was great to see the HDR protocol get merged just before the holidays. I also want to give a shout out to Xaver Hugl from the KWin project. As we where working to ramp up HDR support in both GNOME Shell and GTK+ we ended up working with Xaver and using Kwin for testing especially the GTK+ implementation. Xaver was very friendly and collaborative and I think HDR support in both GNOME and KDE is more solid thanks to that collaboration, so thank you Xaver!

Talking about concrete progress on HDR support Jonas Adahl submitted merge requests for HDR UI controls for GNOME Control Center. This means you will be able to configure the use of HDR on your system in the next Fedora Workstation release.

PipeWire
I been sharing a lot of cool PipeWire news here in the last couple of years, but things might slow down a little as we go forward just because all the major features are basically working well now. The PulseAudio support is working well and we get very few bug reports now against it. The reports we are getting from the pro-audio community is that PipeWire works just as well or better as JACK for most people in terms of for instance latency, and when we do see issues with pro-audio it tends to be more often caused by driver issues triggered by PipeWire trying to use the device in ways that JACK didn’t. We been resolving those by adding more and more options to hardcode certain options in PipeWire, so that just as with JACK you can force PipeWire to not try things the driver has problems with. Of course fixing the drivers would be the best outcome, but for some of these pro-audio cards they are so niche that it is hard to find developers who wants to work on them or who has hardware to test with.

We are still maturing the video support although even that is getting very solid now. The screen capture support is considered fully mature, but the camera support is still a bit of a work in progress, partially because we are going to a generational change the camera landscape with UVC cameras being supplanted by MIPI cameras. Resolving that generational change isn’t just on PipeWire of course, but it does make the a more volatile landscape to mature something in. Of course an advantage here is that applications using PipeWire can easily switch between V4L2 UVC cameras and libcamera MIPI cameras, thus helping users have a smooth experience through this transition period.
But even with the challenges posed by this we are moving rapidly forward with Firefox PipeWire camera support being on by default in Fedora now, Chrome coming along quickly and OBS Studio having PipeWire support for some time already. And last but not least SDL3 is now out with PipeWire camera support.

MIPI camera support
Hans de Goede, Milan Zamazal and Kate Hsuan keeps working on making sure MIPI cameras work under Linux. MIPI cameras are a step forward in terms of technical capabilities, but at the moment a bit of a step backward in terms of open source as a lot of vendors believe they have ‘secret sauce’ in the MIPI camera stacks. Our works focuses mostly on getting the Intel MIPI stack fully working under Linux with the Lattice MIPI aggregator being the biggest hurdle currently for some laptops. Luckily Alan Stern, the USB kernel maintainer, is looking at this now as he got the hardware himself.

Flatpak
Some major improvements to the Flatpak stack has happened recently with the USB portal merged upstream. The USB portal came out of the Sovereign fund funding for GNOME and it gives us a more secure way to give sandboxed applications access to you USB devcices. In a somewhat related note we are still working on making system daemons installable through Flatpak, with the usecase being applications that has a system daemon to communicate with a specific piece of hardware for example (usually through USB). Christian Hergert got this on his todo list, but we are at the moment waiting for Lennart Poettering to merge some pre-requisite work into systemd that we want to base this on.

Accessibility
We are putting in a lot of effort towards accessibility these days. This includes working on portals and Wayland extensions to help facilitate accessibility, working on the ORCA screen reader and its dependencies to ensure it works great under Wayland. Working on GTK4 to ensure we got top notch accessibility support in the toolkit and more.

GNOME Software
Last year Milan Crha landed the support for signing the NVIDIA driver for use on secure boot. The main feature Milan he is looking at now is getting support for DNF5 into GNOME Software. Doing this will resolve one of the longest standing annoyances we had, which is that the dnf command line and GNOME Software would maintain two separate package caches. Once the DNF5 transition is done that should be a thing of the past and thus less risk of disk space being wasted on an extra set of cached packages.

Firefox
Martin Stransky and Jan Horak has been working hard at making Firefox ready for the future, with a lot of work going into making sure it supports the portals needed to function as a flatpak and by bringing HDR support to Firefox. In fact Martin just got his HDR patches for Firefox merged this week. So with the PipeWire camera support, Flatpak support and HDR support in place, Firefox will be ready for the future.

We are hiring! looking for 2 talented developers to join the Red Hat desktop team
We are hiring! So we got 2 job openings on the Red Hat desktop team! So if you are interested in joining us in pushing the boundaries of desktop linux forward please take a look and apply. For these 2 positions we are open to remote workers across the globe and while the job adds list specific seniorities we are somewhat flexible on that front too for the right candidate. So be sure to check out the two job listings and get your application in! If you ever wanted to work fulltime on GNOME and related technologies this is your chance.

The GStreamer team is pleased to announce another bug fix release in the new stable 1.24 release series of your favourite cross-platform multimedia framework!

This release only contains bugfixes and it should be safe to update from 1.24.x.

Highlighted bugfixes:

• d3d12: Fix shaders failing to compile with newer dxc versions
• decklinkvideosink: Fix handling of caps framerate in auto mode; also a decklinkaudiosink fix
• devicemonitor: Fix potential crash macOS when a device is unplugged
• gst-libav: Fix crash in audio encoders like avenc_ac3 if input data has insufficient alignment
• gst-libav: Fix build against FFmpeg 4.2 as in Ubuntu 20.04
• gst-editing-services: Fix Python library name fetching on Windows
• netclientclock: Don't store failed internal clocks in the cache, so applications can re-try later
• oggdemux: Seeking and duration fixes
• osxaudiosrc: Fixes for failing init/no output on recent iOS versions
• qtdemux: Use mvhd transform matrix and support for flipping
• rtpvp9pay: Fix profile parsing
• splitmuxsrc: Fix use with decodebin3 which would occasionally fail with an assertion when seeking
• tsdemux: Fix backwards PTS wraparound detection with ignore-pcr=true
• video-overlay-composition: Declare the video/size/orientation tags for the meta and implement scale transformations
• vtdec: Fix seeks occasionally hanging on macOS due to a race condition when draining
• webrtc: Fix duplicate payload types with RTX and multiple video codecs
• win32-pluginloader: Make sure not to create any windows when inspecting plugins
• wpe: Various fixes for re-negotiation, latency reporting, progress messages on startup
• x264enc: Add missing data to AvcDecoderConfigurationRecord in codec_data for high profile variants
• cerbero: Support using ccache with cmake if enabled
• Various bug fixes, build fixes, memory leak fixes, and other stability and reliability improvements

See the GStreamer 1.24.12 release notes for more details.

Binaries for Android, iOS, Mac OS X and Windows will be available shortly.

The GStreamer team is pleased to announce the first development release in the unstable 1.25 release series.

The unstable 1.25 release series is for testing and development purposes in the lead-up to the stable 1.26 series which is scheduled for release ASAP. Any newly-added API can still change until that point.

This development release is primarily for developers and early adopters.

The plan is to get 1.26 out of the door as quickly as possible.

Binaries for Android, iOS, Mac OS X and Windows will be made available shortly at the usual location.

Release tarballs can be downloaded directly here:

• gstreamer-1.25.1.tar.xz
• gst-plugins-base-1.25.1.tar.xz
• gst-plugins-good-1.25.1.tar.xz
• gst-plugins-ugly-1.25.1.tar.xz
• gst-plugins-bad-1.25.1.tar.xz
• gst-libav-1.25.1.tar.xz
• gst-rtsp-server-1.25.1.tar.xz
• gst-python-1.25.1.tar.xz
• gst-editing-services-1.25.1.tar.xz
• gst-devtools-1.25.1.tar.xz,
• gstreamer-vaapi-1.25.1.tar.xz
• gstreamer-docs-1.25.1.tar.xz

As always, please give it a spin and let us know of any issues you run into by filing an issue in GitLab.

The GStreamer team is pleased to announce another bug fix release in the new stable 1.24 release series of your favourite cross-platform multimedia framework!

This release only contains bugfixes and it should be safe to update from 1.24.x.

Highlighted bugfixes:

• playback: Fix SSA/ASS subtitles with embedded fonts
• decklink: add missing video modes and fix 8K video modes
• matroskamux: spec compliance fixes for audio-only files
• onnx: disable onnxruntime telemetry
• qtdemux: Fix base offset update when doing segment seeks
• srtpdec: Fix a use-after-free issue
• (uri)decodebin3: Fix stream change scenarios, possible deadlock on shutdown
• video: fix missing alpha flag in AV12 format description
• avcodecmap: Add some more channel position mappings
• cerbero bootstrap fixes for Windows 11
• Various bug fixes, build fixes, memory leak fixes, and other stability and reliability improvements

See the GStreamer 1.24.11 release notes for more details.

Binaries for Android, iOS, Mac OS X and Windows will be available shortly.

JPEG XS is a visually lossless, low-latency, intra-only video codec for video production workflows, standardised in ISO/IEC 21122.

A few months ago we added support for JPEG XS encoding and decoding in GStreamer, alongside MPEG-TS container support.

This initially covered progressive scan only though.

Unfortunately interlaced scan, which harks back to the days when TVs had cathode ray tube displays, is still quite common, especially in the broadcasting industry, so it was only a matter of time until support for that would be needed as well.

Long story short, GStreamer can now (with this pending Merge Request) also encode and decode interlaced video into/from JPEG XS.

When putting JPEG XS into MPEG-TS, the individual fields are actually coded separately, so there are two JPEG XS code streams per frame. Inside GStreamer pipelines interlaced raw video can be carried in multiple ways, but the most common one is an "interleaved" image, where the two fields are interleaved row by row, and this is also what capture cards such as AJA or Decklink Blackmagic produce in GStreamer.

When encoding interlaced video in this representation, we need to go twice over each frame and feed every second row of pixels to the underlying SVT JPEG XS encoder which itself is not aware of the interlaced nature of the video content. We do this by specifying double the usual stride as rowstride. This works fine, but unearthed some minor issues with the size checks on the codec side, for which we filed a pull request.

Please give it a spin, and let us know if you have any questions or are interested in additional container mappings such as MP4 or MXF, or RTP payloaders / depayloaders.

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

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

WebRTC support in WPE/WebKitGTK with GStreamer #

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

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

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

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

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

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

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

WebKit Multimedia #

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

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

GES maturity improved for real-live use-cases #

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

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

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

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

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

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

Vulkan Video development and GStreamer support #

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

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

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

Conclusion #

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

Some time ago, Edward and I wrote a new element that allows clocking a GStreamer pipeline from an MPEG-TS stream, for example received via SRT.

This new element, mpegtslivesrc, wraps around any existing live source element, e.g. udpsrc or srtsrc, and provides a GStreamer clock that approximates the sender's clock. By making use of this clock as pipeline clock, it is possible to run the whole pipeline at the same speed as the sender is producing the stream and without having to implement any kind of clock drift mechanism like skewing or resampling. Without this it is necessary currently to adjust the timestamps of media coming out of GStreamer's tsdemux element, which is problematic if accurate timestamps are necessary or the stream should be stored to a file, e.g. a 25fps stream wouldn't have exactly 40ms inter-frame timestamp differences anymore.

The clock is approximated by making use of the in-stream MPEG-TS PCR, which basically gives the sender's clock time at specific points inside the stream, and correlating that together with the local receive times via a linear regression to calculate the relative rate between the sender's clock and the local system clock.

Usage of the element is as simple as

$ gst-launch-1.0 mpegtslivesrc source='srtsrc location=srt://1.2.3.4:5678?latency=150&mode=caller' ! tsdemux skew-corrections=false ! ...
$ gst-launch-1.0 mpegtslivesrc source='udpsrc address=1.2.3.4 port=5678' ! tsdemux skew-corrections=false ! ...

Addition 2025-06-28: If you're using an older (< 1.28) version of GStreamer, you'll have to use the ignore-pcr=true property on tsdemux instead. skew-corrections=false was only added recently and allows for more reliable handling of MPEG-TS timestamp discontinuities.

A similar approach for clocking is implemented in the AJA source element and the NDI source element when the clocked timestamp mode is configured.

The GStreamer team is pleased to announce another bug fix release in the new stable 1.24 release series of your favourite cross-platform multimedia framework!

This release only contains bugfixes and security fixes.

It should be safe to update from 1.24.x, and we would recommend you update at your earliest convenience.

Highlighted bugfixes:

• More than 40 security fixes across a wide range of elements following an audit by the GitHub Security Lab, including the MP4, Matroska, Ogg and WAV demuxers, subtitle parsers, image decoders, audio decoders and the id3v2 tag parser
• avviddec: Fix regression that could trigger assertions about width/height mismatches
• appsink and appsrc fixes
• closed caption handling fixes
• decodebin3 and urisourcebin fixes
• glupload: dmabuf: Fix emulated tiled import
• level: fix LevelMeta values outside of the stated range
• mpegtsmux, flvmux: fix potential busy looping with high cpu usage in live mode
• pipeline dot file graph generation improvements
• qt(6): fix criticals with multiple qml(6)gl{src,sink}
• rtspsrc: Optionally timestamp RTP packets with their receive times in TCP/HTTP mode to enable clock drift handling
• splitmuxsrc: reduce number of file descriptors used
• systemclock: locking order fixes
• v4l2: fix possible v4l2videodec deadlock on shutdown; 8-bit bayer format fixes
• x265: Fix build with libx265 version >= 4.1 after masteringDisplayColorVolume API change
• macOS: fix rendering artifacts in retina displays, plus ptp clock fixes
• cargo: Default to thin lto for the release profile (for faster builds with lower memory requirements)
• Various bug fixes, build fixes, memory leak fixes, and other stability and reliability improvements
• Translation updates

See the GStreamer 1.24.10 release notes for more details.

Binaries for Android, iOS, Mac OS X and Windows will be available shortly.

Thanks to the newly added atenc element, you can now use Apple's well-known AAC encoder directly in GStreamer!

gst-launch-1.0 -e audiotestsrc ! audio/x-raw,channels=2,rate=48000 ! atenc ! mp4mux ! filesink location=output.m4a

It supports all the usual rate control modes (CBR/LTA/VBR/CVBR), as well as settings relevant for each of them (target bitrate for CBR, perceived quality for VBR).

For now you can encode AAC-LC with up to 7.1 channels. Support for more AAC profiles and different output formats will be added in the future.

If you need decoding too, atdec is there to help and has supported AAC alongside a few other formats for a long time now.

The GStreamer team is pleased to announce another bug fix release in the new stable 1.24 release series of your favourite cross-platform multimedia framework!

This release only contains bugfixes and a security fix and it should be safe to update from 1.24.x.

Highlighted bugfixes:

• gst-rtsp-server security fix
• GstAggregator start time selection and latency query fixes for force-live mode
• audioconvert: fix dynamic handling of mix matrix, and accept custom upstream event for setting one
• encodebin: fix parser selection for encoders that support multiple codecs
• flvmux improvments for pipelines where timestamps don't start at 0
• glcontext: egl: Unrestrict the support base DRM formats
• kms: Add IMX-DCSS auto-detection in sink and fix stride with planar formats in allocator
• macOS main application event loop fixes
• mpegtsdemux: Handle PTS/DTS wraparound with ignore-pcr=true
• playbin3, decodebin3, parsebin, urisourcebin: fix races, and improve stability and stream-collection handling
• rtpmanager: fix early RTCP SR generation for sparse streams like metadata
• qml6glsrc: Reduce capture delay
• qtdemux: fix parsing of rotation matrix with 180 degree rotation
• rtpav1depay: added wait-for-keyframe and request-keyframe properties
• srt: make work with newer libsrt versions and don't re-connect on authentication failure
• v4l2 fixes and improvement
• webrtcsink, webrtcbin and whepsrc fixes
• cerbero: fix Python 3.13 compatibility, g-i with newer setuptools, bootstrap on Arch Linux; iOS build fixes
• Ship qroverlay plugin in binary packages
• Various bug fixes, memory leak fixes, and other stability and reliability improvements

See the GStreamer 1.24.9 release notes for more details.

Binaries for Android, iOS, Mac OS X and Windows will be available shortly.

If you've ever seen a news or sports channel playing without sound in the background of a hotel lobby, bar, or airport, you've probably seen closed captions in action.

These TV-style captions are alphabet/character-based, with some very basic commands to control the positioning and layout of the text on the screen.

They are very low bitrate and were transmitted in the invisible part of TV images during the vertical blanking interval (VBI) back in those good old analogue days ("line 21 captions").

Nowadays they are usually carried as part of the MPEG-2 or H.264/H.265 video bitstream, unlike say text subtitles in a Matroska file which will be its own separate stream in the container.

In GStreamer closed captions can be carried in different ways: Either implicitly as part of a video bitstream, or explicitly as part of a video bitstream with video caption metas on the buffers passing through the pipeline. Captions can also travel through a pipeline stand-alone in form of one of multiple raw caption bitstream formats.

To make handling these different options easier for applications there are elements that can extract captions from the video bitstream into metas, and split off captions from metas into their own stand-alone stream, and to do the reverse and combine and reinject them again.

SMPTE 2038 Ancillary Data

SMPTE 2038 (pdf) is a generic system to put VBI-style ancillary data into an MPEG-TS container. This could include all kinds of metadata such as scoreboard data or game clocks, and of course also closed captions, in this case in form of a distinct stream completely separate from any video bitstream.

We've recently added support for SMPTE 2038 ancillary data in GStreamer. This comes in form of a number of new elements in the GStreamer Rust closedcaption plugin and mappings for it in the MPEG-TS muxer and demuxer.

The new elements are:

• st2038ancdemux: splits SMPTE ST-2038 ancillary metadata (as received from tsdemux) into separate streams per DID/SDID and line/horizontal_offset. Will add a sometimes pad with details for each ancillary stream. Also has an always source pad that just outputs all ancillary streams for easy forwarding or remuxing, in case none of the ancillary streams need to be modified or dropped.

• st2038ancmux: muxes SMPTE ST-2038 ancillary metadata streams into a single stream for muxing into MPEG-TS with mpegtsmux. Combines ancillary data on the same line if needed, as is required for MPEG-TS muxing. Can accept individual ancillary metadata streams as inputs and/or the combined stream from st2038ancdemux.

  If the video framerate is known, it can be signalled to the ancillary data muxer via the output caps by adding a capsfilter behind it, with e.g. meta/x-st-2038,framerate=30/1.

  This allows the muxer to bundle all packets belonging to the same frame (with the same timestamp), but that is not required. In case there are multiple streams with the same DID/SDID that have an ST-2038 packet for the same frame, it will prioritise the one from more recently created request pads over those from earlier created request pads (which might contain a combined stream for example if that's fed first).

• st2038anctocc: extracts closed captions (CEA-608 and/or CEA-708) from SMPTE ST-2038 ancillary metadata streams and outputs them on the respective sometimes source pad (src_cea608 or src_cea708). The data is output as a closed caption stream with caps closedcaption/x-cea-608,format=s334-1a or closedcaption/x-cea-708,format=cdp for further processing by other GStreamer closed caption processing elements.

• cctost2038anc: takes closed captions (CEA-608 and/or CEA-708) as produced by other GStreamer closed caption processing elements and converts them into SMPTE ST-2038 ancillary data that can be fed to st2038ancmux and then to mpegtsmux for splicing/muxing into an MPEG-TS container. The line-number and horizontal-offset properties should be set to the desired line number and horizontal offset.

Please give it a spin and let us know how it goes!

    The new usb_set_wireless_status() driver API function can be used by drivers of USB devices to export whether the wireless device associated with that USB dongle is turned on or not.

    To quote the commit message:

This will be used by user-space OS components to determine whether the
battery-powered part of the device is wirelessly connected or not,
allowing, for example:
- upower to hide the battery for devices where the device is turned off
  but the receiver plugged in, rather than showing 0%, or other values
  that could be confusing to users
- Pipewire to hide a headset from the list of possible inputs or outputs
  or route audio appropriately if the headset is suddenly turned off, or
  turned on
- libinput to determine whether a keyboard or mouse is present when its
  receiver is plugged in.

This is not an attribute that is meant to replace protocol specific
APIs [...] but solely for wireless devices with
an ad-hoc “lose it and your device is e-waste” receiver dongle.
 

    Currently, the only 2 drivers to use this are the ones for the Logitech G935 headset, and the Steelseries Arctis 1 headset. Adding support for other Logitech headsets would be possible if they export battery information (the protocols are usually well documented), support for more Steelseries headsets should be feasible if the protocol has already been reverse-engineered.

    As far as consumers for this sysfs attribute, I filed a bug against Pipewire (link) to use it to not consider the receiver dongle as good as unplugged if the headset is turned off, which would avoid audio being sent to headsets that won't hear it.

    UPower supports this feature since version 1.90.1 (although it had a bug that makes 1.90.2 the first viable release to include it), and batteries will appear and disappear when the device is turned on/off.

A turned-on headset

Early this month I spent a couple weeks in Montreal, visiting the city, but mostly to attend the GStreamer Conference and the following hackfest, which happened to be co-located with the XDC Conference. It was my first time in Canada and I utterly enjoyed it. Thanks to all those from the GStreamer community that organized and attended the event.

For now you can replay the whole streams of both days of conference, but soon the split videos for each talk will be published:

GStreamer Conference 2024 - Day 1, Room 1 - October 7, 2024

https://www.youtube.com/watch?v=KLUL1D53VQI

GStreamer Conference 2024 - Day 1, Room 2 - October 7, 2024

https://www.youtube.com/watch?v=DH64D_6gc80

GStreamer Conference 2024 - Day 2, Room 2 - October 8, 2024

https://www.youtube.com/watch?v=jt6KyV757Dk

GStreamer Conference 2024 - Day 2, Room 1 - October 8, 2024

https://www.youtube.com/watch?v=W4Pjtg0DfIo

And a couple pictures of igalians :)

The <video> element implementation in WebKit does its job by using a multiplatform player that relies on a platform-specific implementation. In the specific case of glib platforms, which base their multimedia on GStreamer, that’s MediaPlayerPrivateGStreamer.

The player private can have 3 buffering modes:

• On-disk buffering: This is the typical mode on desktop systems, but is frequently disabled on purpose on embedded devices to avoid wearing out their flash storage memories. All the video content is downloaded to disk, and the buffering percentage refers to the total size of the video. A GstDownloader element is present in the pipeline in this case. Buffering level monitoring is done by polling the pipeline every second, using the fillTimerFired() method.
• In-memory buffering: This is the typical mode on embedded systems and on desktop systems in case of streamed (live) content. The video is downloaded progressively and only the part of it ahead of the current playback time is buffered. A GstQueue2 element is present in the pipeline in this case. Buffering level monitoring is done by listening to GST_MESSAGE_BUFFERING bus messages and using the buffering level stored on them. This is the case that motivates the refactoring described in this blog post, what we actually wanted to correct in Broadcom platforms, and what motivated the addition of hysteresis working on all the platforms.
• Local files: Files, MediaStream sources and other special origins of video don’t do buffering at all (no GstDownloadBuffering nor GstQueue2 element is present on the pipeline). They work like the on-disk buffering mode in the sense that fillTimerFired() is used, but the reported level is relative, much like in the streaming case. In the initial version of the refactoring I was unaware of this third case, and only realized about it when tests triggered the assert that I added to ensure that the on-disk buffering method was working in GST_BUFFERING_DOWNLOAD mode.

The current implementation (actually, its wpe-2.38 version) was showing some buffering problems on some Broadcom platforms when doing in-memory buffering. The buffering levels monitored by MediaPlayerPrivateGStreamer weren’t accurate because the Nexus multimedia subsystem used on Broadcom platforms was doing its own internal buffering. Data wasn’t being accumulated in the GstQueue2 element of playbin, because BrcmAudFilter/BrcmVidFilter was accepting all the buffers that the queue could provide. Because of that, the player private buffering logic was erratic, leading to many transitions between “buffer completely empty” and “buffer completely full”. This, it turn, caused many transitions between the HaveEnoughData, HaveFutureData and HaveCurrentData readyStates in the player, leading to frequent pauses and unpauses on Broadcom platforms.

So, one of the first thing I tried to solve this issue was to ask the Nexus PlayPump (the subsystem in charge of internal buffering in Nexus) about its internal levels, and add that to the levels reported by GstQueue2. There’s also a GstMultiqueue in the pipeline that can hold a significant amount of buffers, so I also asked it for its level. Still, the buffering level unstability was too high, so I added a moving average implementation to try to smooth it.

All these tweaks only make sense on Broadcom platforms, so they were guarded by ifdefs in a first version of the patch. Later, I migrated those dirty ifdefs to the new quirks abstraction added by Phil. A challenge of this migration was that I needed to store some attributes that were considered part of MediaPlayerPrivateGStreamer before. They still had to be somehow linked to the player private but only accessible by the platform specific code of the quirks. A special HashMap attribute stores those quirks attributes in an opaque way, so that only the specific quirk they belong to knows how to interpret them (using downcasting). I tried to use move semantics when storing the data, but was bitten by object slicing when trying to move instances of the superclass. In the end, moving the responsibility of creating the unique_ptr that stored the concrete subclass to the caller did the trick.

Even with all those changes, undesirable swings in the buffering level kept happening, and when doing a careful analysis of the causes I noticed that the monitoring of the buffering level was being done from different places (in different moments) and sometimes the level was regarded as “enough” and the moment right after, as “insufficient”. This was because the buffering level threshold was one single value. That’s something that a hysteresis mechanism (with low and high watermarks) can solve. So, a logical level change to “full” would only happen when the level goes above the high watermark, and a logical level change to “low” when it goes under the low watermark level.

For the threshold change detection to work, we need to know the previous buffering level. There’s a problem, though: the current code checked the levels from several scattered places, so only one of those places (the first one that detected the threshold crossing at a given moment) would properly react. The other places would miss the detection and operate improperly, because the “previous buffering level value” had been overwritten with the new one when the evaluation had been done before. To solve this, I centralized the detection in a single place “per cycle” (in updateBufferingStatus()), and then used the detection conclusions from updateStates().

So, with all this in mind, I refactored the buffering logic as https://commits.webkit.org/284072@main, so now WebKit GStreamer has a buffering code much more robust than before. The unstabilities observed in Broadcom devices were gone and I could, at last, close Issue 1309.

The GStreamer Conference team is pleased to announce that the full conference schedule including talk abstracts and speaker biographies is now available for this year's lineup of talks and speakers, covering again an exciting range of topics!

The GStreamer Conference 2024 will take place on 7-8 October 2024 in Montréal, Canada, followed by a hackfest.

Details about the conference, hackfest and how to register can be found on the conference website.

This year's topics and speakers:

• GStreamer State of the Union
  Tim-Philipp Müller, Centricular
• HLS master playlist management made easy
  Sanchayan Maity, Asymptotic
• What's going on in my pipelines?
  Guillaume Desmottes
• GStreamer Nervous System for AI Brain : Introducing Python Analytics
  Aaron Boxer, Collabora
• New developments with the WebRTC crate
  Mathieu Duponchelle, Centricular
• Real-Time Network Audio with GStreamer on Windows
  Taruntej Kanakamalla, Asymptotic
• GStreamer & Rust: What has happened over the last 5 years
  Sebastian Dröge, Centricular
• It’s time for some clock rate matching
  Arun Raghavan, Asymptotic
• Embedded audio policies made easy with WirePlumber
  George Kiagiadakis, Collabora
• GStreamer Vulkan Video: 2024 edition
  Stéphane Cerveau, Igalia; Victor Manuel Jáquez Leal, Igalia
• librice: a sans-IO ICE networking library
  Matthew Waters, Centricular
• Open Standards for Media including ST 2110 and IPMX
  Dan Maloney, Matrox Video
• State of QUIC in GStreamer
  Sanchayan Maity, Asymptotic
• Gst.WASM Launched
  Jorge Zapata, Fluendo
• A New RTSP Source Element Written in Rust
  Nirbheek Chauhan, Centricular
• GStreamer NVIDIA memory in Jetson: looking for an efficient way to process video frames when handling raw CUDA kernels
  Diego Nieto Munoz, Fluendo
• From GL to your Encoder, Zero-Copy Made Possible
  Nicolas Dufresne, Collabora
• unixfd: Zero-copy multi-process pipeline
  Xavier Claessens, Netflix
• GStreamer Meets GPAC: Enhancing GStreamer's Capabilities through GPAC Integration
  Deniz Ugur, Motion Spell
• Update on Encrypted Media Extensions in GStreamer
  Jordan Yelloz, Collabora
• Which plugin should I use on Windows?
  Seungha Yang, Centricular
• GstWebRTC / WebKit state of the union
  Philippe Normand, Igalia; Carlos Bentzen, Igalia
• How we rewrote GStreamer in Elixir - 8 years later
  Mateusz Front, Software Mansion
• Video Editing with GStreamer: an update
  Thibault Saunier, Igalia
• GStreamer RTP sessions in Rust
  Matthew Waters, Centricular
• AI-assisted video encoding with AMD Alveo MA35D
  Jakub Adam, Collabora
• TV channel in the cloud with GStreamer
  Jurijs Satcs, Veset.tv
• Tea. Earl Grey. Hot. Automated Air-Ground Communication with GStreamer
  Aaron Boxer, Collabora
• Real time volumetric video streaming
  Sudarshan Bisht, Nokia
• Gst-Analytics: Advancements in Machine Learning and Analytics Pipeline
  Daniel Morin, Collabora
• Experiences during the development of point cloud encoding for real-time 3D video streaming using GStreamer
  Jozsef Szabo, Nokia
• HDR in GTK
  Matthias Clasen, RedHat
• macOS and iOS Support: Recent History and Near Future
  Nirbheek Chauhan, Centricular
• AMD's Video Processing Engine
  Harry Wentland, AMD
• Windows Graphics Stack Improvements – Direct3D12
  Seungha Yang, Centricular
• Raven AI Engine: a framework to develop AI computer vision GStreamer elements
  Andoni Morales Alastruey, Fluendo
• Learnings of building a scaleable webrtc media pipeline in rust using gstreamer
  Ramyak Mehra, Dyte
• LiveKit Support for GStreamer WebRTC Elements
  Jordan Yelloz, Collabora
• Perfect Harmony: How we synchronized Audio and Video from Multiple Sources using GStreamer for Seamless Real-Time Streaming
  Tokunbo Quaye, IPS; Michael Yackavage, IPS
• Developing and debugging on Windows, Fluendo experience.
  Rubén Gonzalez, Fluendo; Diego Nieto Munoz, Fluendo
• Playback support, 2024 update
  Edward Hervey, Centricular
• Streamlining Video Presentation and Recording with GStreamer-Based Processing
  Tomasz Mikołajczyk
• GStreamer and display clock synchronization
  Jochen Henneberg, Centricular
• Scenic and GStreamer on stage : collaborative theater adventures at the Society for Arts and Technology
  Olivier Gauthier, Society for Arts and Technology
• GStreamer and VR
  Jan Schmidt, Centricular

Lightning Talks:

• GQuark in GStreamer structures — What nonsense!
  Sebastian Dröge, Centricular
• Integration testing video with Test Containers by example
  Johannes Nel, Genius Sports
• Silhouette, the ML/PipeWire-powered virtual camera device app
  George Kiagiadakis, Collabora
• Last year's updates in Fluster
  Rubén Gonzalez, Fluendo
• A new GStreamer plugin to leverage the skia 2D drawing library
  Thibault Saunier, Igalia
• New RTP payloaders & depayloaders in Rust
  Sebastian Dröge, Centricular
• How easy it is to write a video sink plugin
  ramyak mehra, Dyte
• Closed Captions: Additional Things GStreamer Can Do
  Matthew Waters, Centricular
• Is an H264 encoder base class for hardware accelerated API possible?
  Victor Manuel Jáquez Leal, Igalia
• Effects of a GStreamer version upgrade on Yocto-based application
  Michael Yackavage, IPS
• GstVA updates
  Victor Manuel Jáquez Leal, Igalia
• GStreamer plugin updates on webOS as a platform
  Seungwook Cha, LG Electronics
• An update on GStreamer validate
  Thibault Saunier, Igalia
• Fluendo and Cerbero, testing challenges
  Jorge Zapata, Fluendo
• Yet another V4L2 update
  Nicolas Dufresne, Collabora
• A new Windows web browser source plugin - webview2
  Seungha Yang, Centricular
• Seeking Perfection: Challenges and Solution attempts in Implementing HLS Stream Seeking with RTP Synchronization Using GStreamer
  Tokunbo Quaye, IPS
• ...and more to come
• Submit your lightning talk now!

Many thanks to our amazing sponsors ‒ Platinum sponsors Collabora, Igalia, and Pexip, Gold sponsors Centricular, La Société des Arts Technologiques, Axis Communications, and Genius Sports, and Silver sponsors Laerdal Labs, asymptotic, Cablecast, and Fluendo, without whom the conference would not be possible in this form.

We hope to see you all in Montréal! Don't forget to register as soon as possible if you're planning on joining us, so we can order enough food and drinks!

Up until recently, when using hlscmafsink, if you wanted to move to a new playlist you had to stop the pipeline, modify the relevant properties and then go to PLAYING again.

This was problematic when working with live sources because some data was being lost between the state changes. Not anymore!

A new-playlist signal has been added, which lets you switch output to a new location on the fly, without having any gaps between the content in each playlist.

Simply change the relevant properties first and then emit the signal:

hlscmafsink.set_property("playlist-location", new_playlist_location);
hlscmafsink.set_property("init-location", new_init_location);
hlscmafsink.set_property("location", new_segment_location);
hlscmafsink.emit_by_name::<()>("new-playlist", &[]);

This can be useful if you're capturing a live source and want to switch to a different folder every couple of hours, for example.

What is JPEG XS?

JPEG XS is a visually lossless, low-latency, intra-only video codec for video production workflows, standardised in ISO/IEC 21122.

It's wavelet based, with low computational overhead and a latency measured in scanlines, and it is designed to allow easy implementation in software, GPU or FPGAs.

Multi-generation robustness means repeated decoding and encoding will not introduce unpleasant coding artefacts or noticeably degrade image quality, which makes it suitable for video production workflows.

It is often deployed in lieu of existing raw video workflows, where it allows sending multiple streams over links designed to carry a single raw video transport.

JPEG XS encoding / decoding in GStreamer

GStreamer now gained basic support for this codec.

Encoding and decoding is supported via the Open Source Intel Scalable Video Technology JPEG XS library, but third-party GStreamer plugins that provide GPU accelerated encoding and decoding exist as well.

MPEG-TS container mapping

Support was also added for carriage inside MPEG-TS which should enable a wide range of streaming applications including those based on the Video Services Forum (VSF)'s Technical Recommendation TR-07.

JPEG XS caps in GStreamer

It actually took us a few iterations to come up with GStreamer caps that we were somewhat happy with for starters.

Our starting point was what the SVT encoder/decoder output/consume, and our initial target was MPEG-TS container format support.

We checked various specifications to see how JPEG XS is mapped there and how it could work, in particular:

• ISO/IEC 21122-3 (Part 3: Transport and container formats)
• MPEG-TS JPEG XS mapping and VSF TR-07 - Transport of JPEG XS Video in MPEG-2 Transport Stream over IP
• RFC 9134: RTP Payload Format for ISO/IEC 21122 (JPEG XS)
• SMPTE ST 2124:2020 (Mapping JPEG XS Codestreams into the MXF)
• MP4 mapping

and we think the current mapping will work for all of those cases.

Basically each mapping wants some extra headers in addition to the codestream data, for the out-of-band signalling required to make sense of the image data. Originally we thought about putting some form of codec_data header into the caps, but it wouldn't really have made anything easier, and would just have duplicated 99% of the info that's in the video caps already anyway.

The current caps mapping is based on ISO/IEC 21122-3, Annex D, with additional metadata in the caps, which should hopefully work just fine for RTP, MP4, MXF and other mappings in future.

Please give it a spin, and let us know if you have any questions or are interested in additional container mappings such as MP4 or MXF, or RTP payloaders / depayloaders.

The GStreamer team is pleased to announce another bug fix release in the new stable 1.24 release series of your favourite cross-platform multimedia framework!

This release only contains bugfixes and it should be safe to update from 1.24.x.

Highlighted bugfixes:

• decodebin3: collection handling fixes
• encodebin: Fix pad removal (and smart rendering in gst-editing-services)
• glimagesink: Fix cannot resize viewport when video size changed in caps
• matroskamux, webmmux: fix firefox compatibility issue with Opus audio streams
• mpegtsmux: Wait for data on all pads before deciding on a best pad unless timing out
• splitmuxsink: Override LATENCY query to pretend to downstream that we're not live
• video: QoS event handling improvements
• voamrwbenc: fix list of bitrates
• vtenc: Restart encoding session when certain errors are detected
• wayland: Fix ABI break in WL context type name
• webrtcbin: Prevent crash when attempting to set answer on invalid SDP
• cerbero: ship vp8/vp9 software encoders again, which went missing in 1.24.7; ship transcode plugin
• Various bug fixes, memory leak fixes, and other stability and reliability improvements

See the GStreamer 1.24.8 release notes for more details.

Binaries for Android, iOS, Mac OS X and Windows will be available shortly.

The GStreamer team is pleased to announce another release of liborc, the Optimized Inner Loop Runtime Compiler, which is used for SIMD acceleration in GStreamer plugins such as audioconvert, audiomixer, compositor, videoscale, and videoconvert, to name just a few.

This is a bug-fix release, with some minor follow-ups to the security fixes of the previous release.

Highlights:

• Security: Minor follow-up fixes for CVE-2024-40897
• Fix include header use from C++
• orccodemem: Assorted memory mapping fixes
• powerpc: fix div255w which still used the inexact substitution
• powerpc: Disable VSX and ISA 2.07 for Apple targets
• powerpc: Allow detection of ppc64 in Mac OS
• x86: work around old GCC versions (pre 9.0) having broken xgetbv implementationsv
• x86: consider MSYS2/Cygwin as Windows for ABI purposes only
• x86: handle unnatural and misaligned array pointers
• x86: Fix non-C11 typedefs
• x86: try fixing AVX detection again by adding check for XSAVE
• Some compatibility fixes for Musl
• meson: Fix detecting XSAVE on older AppleClangv
• Check return values of malloc() and realloc()

Direct tarball download: orc-0.4.40.tar.xz.

When using hlssink3 and hlscmafsink elements, it's now possible to track new fragments being added by listening for the hls-segment-added message:

Got message #67 from element "hlscmafsink0" (element): hls-segment-added, location=(string)segment00000.m4s, running-time=(guint64)0, duration=(guint64)3000000000;
Got message #71 from element "hlscmafsink0" (element): hls-segment-added, location=(string)segment00001.m4s, running-time=(guint64)3000000000, duration=(guint64)3000000000;
Got message #74 from element "hlscmafsink0" (element): hls-segment-added, location=(string)segment00002.m4s, running-time=(guint64)6000000000, duration=(guint64)3000000000;

This is similar to how you would listen for splitmuxsink-fragment-closed when using the older hlssink2.

webrtcsink already supported instantiating a data channel for the sole purpose of carrying navigation events from the consumer to the producer, it can also now create a generic control data channel through which the consumer can send JSON requests in the form:

{
    "id": identifier used in the response message,
    "mid": optional media identifier the request applies to,
    "request": {
        "type": currently "navigationEvent" and "customUpstreamEvent" are supported,
        "type-specific-field": ...
    }
}

The producer will reply with such messages:

{
  "id": identifier of the request,
  "error": optional error message, successful if not set
}

The example frontend was also updated with a text area for sending any arbitrary request.

The use case for this work was to make it possible for a consumer to control the mix matrix used for the audio stream, with such a pipeline running on the producer side:

gst-launch-1.0 audiotestsrc ! audioconvert ! webrtcsink enable-control-data-channel=true

As audioconvert now supports setting a mix matrix through a custom upstream event, the consumer can simply input the following text in the request field of the frontend to reverse the channels of a stereo audio stream:

{
  "type": "customUpstreamEvent",
  "structureName": "GstRequestAudioMixMatrix",
  "structure": {
    "matrix": [[0.0, 1.0], [1.0, 0.0]]
  }
}

The GStreamer team is pleased to announce another bug fix release in the new stable 1.24 release series of your favourite cross-platform multimedia framework!

This release only contains bugfixes and it should be safe to update from 1.24.x.

Highlighted bugfixes:

• Fix APE and Musepack audio file and GIF playback with FFmpeg 7.0
• playbin3: Fix potential deadlock with multiple playbin3s with glimagesink used in parallel
• qt6: various qmlgl6src and qmlgl6sink fixes and improvements
• rtspsrc: expose property to force usage of non-compliant setup URLs for RTSP servers where the automatic fallback doesn't work
• urisourcebin: gapless playback and program switching fixes
• v4l2: various fixes
• va: Fix potential deadlock with multiple va elements used in parallel
• meson: option to disable gst-full for static-library build configurations that do not need this
• cerbero: libvpx updated to 1.14.1; map 2022Server to Windows11; disable rust variant on Linux if binutils is too old
• Various bug fixes, memory leak fixes, and other stability and reliability improvements

See the GStreamer 1.24.7 release notes for more details.

Binaries for Android, iOS, Mac OS X and Windows will be available shortly.

GStreamer's VideoToolbox encoder recently gained support for encoding HEVC/H.265 videos containing an alpha channel.

A separate vtenc_h265a element has been added for this purpose. Assuming you're on macOS, you can use it like this:

gst-launch-1.0 -e videotestsrc ! alpha alpha=0.5 ! videoconvert ! vtenc_h265a ! mp4mux ! filesink location=alpha.mp4

Click here to see an example in action! It should work fine on macOS and iOS, in both Chrome and Safari. On other platforms it might not be displayed at all - compatibility is unfortunately still quite limited.

If your browser supports this format correctly, you will see a moving GStreamer logo on a constantly changing background - something like this. That background is entirely separate from the video and is generated using CSS.

The default signaller for webrtcsink can now produce an answer when the consumer sends the offer first.

To test this with the example, you can simply follow the usual steps but also paste the following text in the text area before clicking on the producer name:

{
  "offerToReceiveAudio": 1,
  "offerToReceiveVideo": 1
}

I implemented this in order to test multiopus support with webrtcsink, as it seems to work better when munging the SDP offered by chrome.

webrtcsink can now run both the default signalling server and a web server for static content.

gst-launch-1.0 ! videotestsrc webrtcsink name=ws run-signalling-server=true run-web-server=true

This comes in very handy for testing purposes, but could also prove useful in production.

A couple of weeks ago I implemented support for static HDR10 metadata in the decklinkvideosink and decklinkvideosrc elements for Blackmagic video capture and playout devices. The culmination of this work is available from MR 7124 - decklink: add support for HDR output and input

This adds support for both PQ and HLG HDR alongside some improvements in colorimetry negotiation. Static HDR metadata in GStreamer is conveyed through caps.

The first part of this is the 'colorimetry' field in video/x-raw caps. decklinkvideosink and decklinkvideosrc now support the colorimetry values 'bt601', 'bt709', 'bt2020', 'bt2100-hlg', and 'bt2100-pq' for any resolution. Previously the colorimetry used was fixed based on the resolution of the video frames being sent or received. With some glue code, the colorimetry is now retrieved from the Decklink API and the Decklink API can ask us for the colorimetry of the submitted video frame. Arbitrary colorimetry support is not supported on all Decklink devices and we fallback to the previous fixed list based on frame resolution when not supported.

Support for HDR metadata is a separate feature flag in the Decklink API and may or may not be present independent of Decklink's arbitrary colour space support. If the Decklink device does not support HDR metadata, then the colorimetry values 'bt2100-hlg', and 'bt2100-pq' are not supported.

In the case of HLG, all that is necessary is to provide information that the HLG gamma transfer function is being used. Nothing else is required.

In the case of PQ HDR, in addition to providing Decklink with the correct gamma transfer function, Decklink also needs some other metadata conveyed in the caps in the form of the 'mastering-display-info' and 'light-content-level' fields. With some support from GstVideoMasteringDisplayInfo, and GstVideoContentLightLevel the relevant information signalled to Decklink and can be retrieved from each individual video frame.

About the GStreamer Conference

The GStreamer Conference 2024 GStreamer Conference will take place on Monday-Tuesday 7-8 October 2024 in Montréal, Québec, Canada.

It is a conference for developers, community members, decision-makers, industry partners, researchers, students and anyone else interested in the GStreamer multimedia framework or Open Source and cross-platform multimedia.

There will also be a hackfest just after the conference.

You can find more details about the conference on the GStreamer Conference 2024 web site.

Call for Presentations is open

The call for presentations is now open for talk proposals and lightning talks. Please submit your talk now!

Talks can be on almost anything multimedia related, ranging from talks about applications to challenges in the lower levels in the stack or hardware.

We want to hear from you, what you are working on, what you are using GStreamer for, what difficulties you have encountered and how you solved them, what your plans are, what you like, what you dislike, how to improve things!

Please submit all proposals through the GStreamer Conference 2024 Talk Submission Portal.

The GStreamer team is pleased to announce another bug fix release in the new stable 1.24 release series of your favourite cross-platform multimedia framework!

This release only contains bugfixes and security fixes and it should be safe to update from 1.24.x.

Highlighted bugfixes:

• Fix compatibility with FFmpeg 7.0
• qmlglsink: Fix failure to display content on recent Android devices
• adaptivedemux: Fix handling of closed caption streams
• cuda: Fix runtime compiler loading with old CUDA tookit
• decodebin3 stream selection handling fixes
• d3d11compositor, d3d12compositor: Fix transparent background mode with YUV output
• d3d12converter: Make gamma remap work as intended
• h264decoder: Update output frame duration for interlaced video when second field frame is discarded
• macOS audio device provider now listens to audio devices being added/removed at runtime
• Rust plugins: audioloudnorm, s3hlssink, gtk4paintablesink, livesync and webrtcsink fixes
• videoaggregator: preserve features in non-alpha caps for subclasses with non-system memory sink caps
• vtenc: Fix redistribute latency spam
• v4l2: fixes for complex video formats
• va: Fix strides when importing DMABUFs, dmabuf handle leaks, and blocklist unmaintained Intel i965 driver for encoding
• waylandsink: Fix surface cropping for rotated streams
• webrtcdsp: Enable multi_channel processing to fix handling of stereo streams
• Various bug fixes, memory leak fixes, and other stability and reliability improvements

See the GStreamer 1.24.6 release notes for more details.

Binaries for Android, iOS, Mac OS X and Windows will be available shortly.

The GStreamer team is pleased to announce another release of liborc, the Optimized Inner Loop Runtime Compiler, which is used for SIMD acceleration in GStreamer plugins such as audioconvert, audiomixer, compositor, videoscale, and videoconvert, to name just a few.

This is a minor bug-fix release, and also includes a security fix.

Highlights:

• Security: Fix error message printing buffer overflow leading to possible code execution in orcc with specific input files (CVE-2024-40897). This only affects developers and CI environments using orcc, not users of liborc.
• div255w: fix off-by-one error in the implementations
• x86: only run AVX detection if xgetbv is available
• x86: fix AVX detection by implementing the check recommended by Intel
• Only enable JIT compilation on Apple arm64 if running on macOS, fixes crashes on iOS
• Fix potential crash in emulation mode if logging is enabled
• Handle undefined TARGET_OS_OSX correctly
• orconce: Fix typo in GCC __sync-based implementation
• orconce: Fix usage of __STDC_NO_ATOMICS__
• Fix build with MSVC 17.10 + C11
• Support stack unwinding on Windows
• Major opcode and instruction set code clean-ups and refactoring
• Refactor allocation and chunk initialization of code regions
• Fall back to emulation on Linux if JIT support is not available, e.g. because of SELinux sandboxing or noexec mounting)

Direct tarball download: orc-0.4.39.tar.xz.

As usual this release follows the latest gtk-rs 0.20 release and the corresponding API changes.

This release features relatively few changes and mostly contains the addition of some convenience APIs, the addition of bindings for some minor APIs, addition of bindings for new GStreamer 1.26 APIs, and various optimizations.

The new release also brings a lot of bugfixes, most of which were already part of the bugfix releases of the previous release series.

Details can be found in the release notes for gstreamer-rs.

The code and documentation for the bindings is available on the freedesktop.org GitLab

• GStreamer Rust Bindings (documentation)

The new 0.13 version of the GStreamer Rust plugins features many improvements to the existing plugins as well as various new plugins. A majority of the changes were already backported to the 0.12 release series and its bugfix releases, which is part of the GStreamer 1.24 binaries.

A full list of available plugins can be seen in the repository's README.md.

Details for this release can be found in the release notes for gst-plugins-rs.

If you find any bugs, notice any missing features or other issues please report them in GitLab for the bindings or the plugins.

In GStreamer 1.20 times I fixed the handling of RTSP control URIs in GStreamer's RTSP source element by making use of GstUri for joining URIs and resolving relative URIs instead of using a wrong, custom implementation of those basic URI operations (see RFC 2396).

This was in response to a bug report which was caused by a regression in 1.18 when fixing that custom implementation some years before. Now that this is handled according to the standards, one would expect that the topic is finally solved.

Unfortunately that was not the case. As it turns out, various RTSP servers are not actually implementing the URI operations for constructing the control URI but instead do simple string concatenation. This works fine for simple cases but once path separators or query parameters are involved this is not sufficient. The fact that both VLC and ffmpeg on the client-side also only do string concatenation unfortunately does not help this situation either as these servers will work fine in VLC and ffmpeg but not in GStreamer, so it initially appears like a GStreamer bug.

To work around these cases automatically, a workaround with a couple of follow-up fixes 1 2 3 4 was implemented. This workaround is available since 1.20.4.

Unfortunately this was also not enough as various servers don't just implement the URI RFC wrong, but also don't implement the RTSP RFC correctly and don't return any kind of meaningful errors but, for example, simply close the connection.

To solve this once and for all, Mathieu now added a new property to rtspsrc that forces it to directly use string concatenation and not attempt proper URI operations first.

$ gst-launch-1.0 rtspsrc location=rtsp://1.2.3.4/test force-non-compliant-url=true ! ...

This property is available since 1.24.7 and should make it possible to use such misbehaving and non-compliant servers.

If GStreamer's rtspsrc fails on an RTSP stream that is handled just fine by VLC and ffmpeg, give this a try.

The GStreamer team is pleased to announce another bug fix release in the new stable 1.24 release series of your favourite cross-platform multimedia framework!

This release only contains bugfixes and security fixes and it should be safe to update from 1.24.x.

Highlighted bugfixes:

• webrtcsink: Support for AV1 via nvav1enc, av1enc or rav1enc encoders
• AV1 RTP payloader/depayloader fixes to work correctly with Chrome and Pion WebRTC
• av1parse, av1dec error handling/robustness improvements
• av1enc: Handle force-keyunit events properly for WebRTC
• decodebin3: selection and collection handling improvements
• hlsdemux2: Various fixes for discontinuities, variant switching, playlist updates
• qml6glsink: fix RGB format support
• rtspsrc: more control URL handling fixes
• v4l2src: Interpret V4L2 report of sync loss as video signal loss
• d3d12 encoder, memory and videosink fixes
• vtdec: more robust error handling, fix regression
• ndi: support for NDI SDK v6
• Various bug fixes, memory leak fixes, and other stability and reliability improvements

See the GStreamer 1.24.5 release notes for more details.

Binaries for Android, iOS, Mac OS X and Windows will be available shortly.

There are times when you feel your making no progress and there are other times when things feel like they are landing in quick succession. Luckily this definitely is the second when a lot of our long term efforts are finally coming over the finish line. As many of you probably know our priorities tend to be driven by a combination of what our RHEL Workstation customers need, what our hardware partners are doing and what is needed for Fedora Workstation to succeed. We also try to be good upstream partners and do patch reviews and participate where we can in working on upstream standards, especially those of course of concern to our RHEL Workstation and Server users. So when all those things align we are at our most productive and that seems to be what is happening now. Everything below is features in flight that will at the latest land in Fedora Workstation 41.

Artificial Intelligence

IBM Granite LLM models usher in a new era of open source AI.

And it is not just Granite, we are ensuring other other major AI projects will work with Fedora too, like Meta’s popular Llama LLM. And a big step for that is how Tom Rix has been working on bringing in AMD accelerated support (ROCm) for PyTorch to Fedora. PyTorch is an optimized tensor library for deep learning using GPUs and CPUs. The long term goal is that you should be able to just install PyTorch on Fedora and have it work hardware accelerated with any of the 3 major GPU vendors chipsets.

NVIDIA in Fedora

So the clear market leader at the moment for powering AI workloads in NVIDIA so I am also happy to let you know about two updates we are working on that will make you life better on Fedora when using NVIDIA GPUs, be that for graphics or for compute or Artificial Intelligence. So for the longest time we have had easy install of the NVIDIA driver through GNOME Software in Fedora Workstation, unfortunately this setup never dealt with what is now the default usecase, which is using it with a system that has secure boot enabled. So the driver install was dropped from GNOME Software in our most recent release as the only way for people to get it working was through using mokutils on the command line, but the UI didn’t tell you that. Well we of course realize that sending people back to the command line to get this driver installed is highly unfortunate so Milan Crha has been working together with Alan Day and Jakub Steiner to come up with a streamlined user experience in GNOME Software to let you install the binary NVIDIA driver and provide you with an integrated graphical user interface help to sign the kernel module for use with secure boot. This is a bit different than what we for instance are doing in RHEL, where we are working with NVIDIA to provide pre-signed kernel modules, but that is a lot harder to do in Fedora due to the rapidly updating kernel versions and which most Fedora users appreciate as a big plus. So instead what we are for opting in Fedora is as I said to make it simple for you to self-sign the kernel module for use with secure boot. We are currently looking at when we can make this feature available, but no later than Fedora Workstation 41 for sure.

Toolbx getting top notch NVIDIA integration

Container Toolbx enables developers quick and easy access to their favorite development platforms

We are also hoping the packaging fixes to subscription manager will land soon as that will make using RHEL containers on Fedora a lot smoother. While this feature basically already works as outlined here we do hope to make it even more streamlined going forward.

Open Source NVIDIA support
Of course being Red Hat we haven’t forgotten about open source here, you probably heard about Nova our new Rust based upstream kernel driver for NVIDIA hardware which will provided optimized support for the hardware supported by NVIDIAs firmware (basically all newer ones) and accelerate Vulkan through the NVK module and provide OpenGL through Zink. That effort is still quite early days, but there is some really cool developments happening around Nova that I am not at liberty to share yet, but I hope to be able to talk about those soon.

High Dynamic Range (HDR)
Jonas Ådahl after completing the remote access work for GNOME under Wayland has moved his focus to help land the HDR support in mutter and GNOME Shell. He recently finished rebasing his HDR patches onto a wip merge request from
Georges Stavracas which ported gnome-shell to using paint nodes,

So the HDR enablement in mutter and GNOME shell is now a set of 3 patches.

• First the paint nodes port
• then the base HDR plumbing patch
• then the patch to allow SDR and HDR content to run side by side

With this the work is mostly done, what is left is avoiding over exposure of the cursor, and inhibiting direct scanout.

We also hope to help finalize the upstream Wayland specs soon so that everyone can implement this and know the protocols are stable and final.

DRM leasing – VR Headsets

The most common usecase for DRM leasing is VR headsets, but it is also a useful feature for things like video walls. José Expósito is working on finalizing a patch for it using the Wayland protocol adopted by KDE and others. We where somewhat hesitant to go down this route as we felt a portal would have been a better approach, especially as a lot of our experienced X.org developers are worried that Wayland is in the process of replicating one of the core issues with X through the unmanageable plethora of Wayland protocols that is being pushed. That said, the DRM leasing stuff was not a hill worth dying on here, getting this feature out to our users in a way they could quickly use was more critical, so DRM leasing will land soon through this merge request.

Explicit sync
Another effort that we have put a lot of effort into together with our colleagues at NVIDIA is landing support for what is called explicit sync into the Linux kernel and the graphics drivers.The linux graphics stack was up to this point using something called implicit sync, but the NVIDIA drivers did not work well with that and thus people where experiencing ‘blinking’ applications under Wayland. So we worked with NVIDIA and have landed the basic support in the kernel and in GNOME and thus once the 555 release of the NVIDIA driver is out we hope the ‘blinking’ issues are fully resolved for your display. There has been some online discussion about potential performance gains from this change too, across all graphics drivers, but the reality of this is somewhat uncertain or at least it is still unclear if there will be real world measurable gains from adding explicit sync. I heard knowledgeable people argue both sides with some saying there should be visible performance gains while others say the potential gains will be so specific that unless you write a test to benchmark it explicitly you will not be able to detect a difference. But what is beyond doubt is that this will make using the NVIDIA stack with Wayland a lot better a that is a worthwhile goal in itself. The one item we are still working on is integrating the PipeWire support for explicit sync into our stack, because without it you might have the same flickering issues with PipeWire streams on top of the NVIDIA driver that you have up to now seen on your screen. So for instance if you are using PipeWire for screen capture it might look fine on screen with the fixes already merged, but the captured video has flickering. Wim Taymans landed some initial support in PipeWire already so now Michel Dänzer is working on implementing the needed bits for PipeWire in mutter. At the same time Wim is working on ensuring we have a testing client available to verify the compositor support. Once everything has landed in mutter and we been able to verify that it works with the sample client we will need to add support to client applications interacting with PipeWire, like Firefox, Chrome, OBS Studio and GNOME-remote-desktop.

Two weeks ago the GStreamer Spring Hackfest took place in Thessaloniki, Greece. I had a great time. I hacked a bit on VA, Vulkan and my toy, planet-rs, but mostly I ate delicious Greek food ☻. A big thanks to our hosts: Vivia, Jordan and Sebastian!

And now, writing this supposed small note, I recalled that I have in my to-do list an item to write a comment about GstVulkanOperation, an addition to GstVulkan API which helps with the synchronization of operations on frames, in order to enable Vulkan Video.

Originally, GstVulkan API didn’t provide almost any synchronization operation, beside fences, and that appeared to be enough for elements, since they do simple Vulkan operations. Nonetheless, as soon as we enabled VK_VALIDATION_FEATURE_ENABLE_SYNCHRONIZATION_VALIDATION_EXT feature, which reports resource access conflicts due to missing or incorrect synchronization operations between action [*], a sea of hazard operation warnings drowned us [*].

Hazard operations are a sequence of read/write commands in a memory area, such as an image, that might be re-ordered, or racy even.

Why are those hazard operations reported by the Vulkan Validation Layer, if the programmer pushes the commands to execute in queue in order? Why is explicit synchronization required? Because, as the great blog post from Hans-Kristian Arntzen, Yet another blog explaining Vulkan synchronization, (make sure you read it!) states:

[…] all commands in a queue execute out of order. Reordering may happen across command buffers and even vkQueueSubmits

In order to explain how synchronization is done in Vulkan, allow me to yank a couple definitions stated by the specification:

Commands are instructions that are recorded in a device’s queue. There are four types of commands: action, state, synchronization and indirection. Synchronization commands impose ordering constraints on action commands, by introducing explicit execution and memory dependencies.

Operation is an arbitrary amount of commands recorded in a device’s queue.

Since the driver can reorder commands (perhaps for better performance, dunno), we need to send explicit synchronization commands to the device’s queue to enforce a specific sequence of action commands.

Nevertheless, Vulkan doesn’t offer fine-grained dependencies between individual operations. Instead, dependencies are expressed as a relation of two elements, where each element is composed by the intersection of scope and operation. A scope is a concept in the specification that, in practical terms, can be either pipeline stage (for execution dependencies), or both pipeline stage and memory access type (for memory dependencies).

First let’s review execution dependencies through pipeline stages:

Every command submitted to a device’s queue goes through a sequence of steps known as pipeline stages. This sequence of steps is one of the very few implicit ordering guarantees that Vulkan has. Draw calls, copy commands, compute dispatches, all go through certain sequential stages, which amount of stages to cover depends on the specific command and the current command buffer state.

In order to visualize an abstract execution dependency let’s imagine two compute operations and the first must happen before the second.

Operation 1
Sync command
Operation 2

1. The programmer has to specify the Sync command in terms of two scopes (Scope 1 and Scope 2), in this execution dependency case, two pipeline stages.
2. The driver generates an intersection between commands in Operation 1 and Scope 1 defined as Scoped operation 1. The intersection contains all the commands in Operation 1 that go through up to the pipeline stage defined in Scope 1. The same is done with Operation 2 and Scope 2 generating Scoped operation 2.
3. Finally, we got an execution dependency that guarantees that Scoped operation 1 happens before Scoped operation 2.

Now let’s talk about memory dependencies:

First we need to understand the concepts of memory availability and visibility. Their formal definition in Vulkan are a bit hard to grasp since they come from the Vulkan memory model, which is intended to abstract all the ways of how hardware access memory. Perhaps we could say that availability is the operation that assures the existence of the required memory; while visibility is the operation that assures it’s possible to read/write the data in that memory area.

Memory dependencies are limited the Operation 1 that be done before memory availability and Operation 2 that have to be done after its visibility.

But again, there’s no fine-grained way to declare that memory dependency. Instead, there are memory access types, which are functions used by descriptor types, or functions for pipeline stage to access memory, and they are used as access scopes.

All in all, if a synchronization command defining a memory dependency between two operations, it’s composed by the intersection of between each command and a pipeline stage, intersected with the memory access type associated with the memory processed by those commands.

Now that the concepts are more or less explained we could see those concepts expressed in code. The synchronization command for execution and memory dependencies is defined by VkDependencyInfoKHR. And it contains a set of barrier arrays, for memory, buffers and images. Barriers express the relation of dependency between two operations. For example, Image barriers use VkImageMemoryBarrier2 which contain the mask for source pipeline stage (to define Scoped operation 1), and the mask for the destination pipeline stage (to define Scoped operation 2); the mask for source memory access type and the mask for the destination memory access to define access scopes; and also layout transformation declaration.

A Vulkan synchronization example from Vulkan Documentation wiki:

vkCmdDraw(...);

... // First render pass teardown etc.

VkImageMemoryBarrier2KHR imageMemoryBarrier = {
  ...
  .srcStageMask = VK_PIPELINE_STAGE_2_FRAGMENT_SHADER_BIT_KHR,
  .dstStageMask = VK_PIPELINE_STAGE_2_COLOR_ATTACHMENT_OUTPUT_BIT_KHR,
  .dstAccessMask = VK_ACCESS_2_COLOR_ATTACHMENT_WRITE_BIT_KHR,
  .oldLayout = VK_IMAGE_LAYOUT_READ_ONLY_OPTIMAL,
  .newLayout = VK_IMAGE_LAYOUT_ATTACHMENT_OPTIMAL
  /* .image and .subresourceRange should identify image subresource accessed */};

VkDependencyInfoKHR dependencyInfo = {
    ...
    1,                      // imageMemoryBarrierCount
    &imageMemoryBarrier,    // pImageMemoryBarriers
    ...
}

vkCmdPipelineBarrier2KHR(commandBuffer, &dependencyInfo);

... // Second render pass setup etc.

vkCmdDraw(...);

First draw samples a texture in the fragment shader. Second draw writes to that texture as a color attachment.

This is a Write-After-Read (WAR) hazard, which you would usually only need an execution dependency for - meaning you wouldn’t need to supply any memory barriers. In this case you still need a memory barrier to do a layout transition though, but you don’t need any access types in the src access mask. The layout transition itself is considered a write operation though, so you do need the destination access mask to be correct - or there would be a Write-After-Write (WAW) hazard between the layout transition and the color attachment write.

Other explicit synchronization mechanisms, along with barriers, are semaphores and fences. Semaphores are a synchronization primitive that can be used to insert a dependency between operations without notifying the host; while fences are a synchronization primitive that can be used to insert a dependency from a queue to the host. Semaphores and fences are expressed in the VkSubmitInfo2KHR structure.

As a preliminary conclusion, synchronization in Vulkan is hard and a helper API would be very helpful. Inspired by FFmpeg work done by Lynne, I added GstVulkanOperation object helper to GStreamer Vulkan API.

GstVulkanOperation object helper aims to represent an operation in the sense of the Vulkan specification mentioned before. It owns a command buffer as public member where external commands can be pushed to the associated device’s queue.

It has a set of methods:

• gst_vulkan_operation_begin wraps vkBeginCommandBuffer.
• gst_vulkan_operation_end wraps both vkEndCommandBuffer and either vkQueueSubmit or vkQueueSubmit2 (the object internally handle both depending on the driver support).
• gst_vulkan_operation_wait wraps vkWaitForFences.

Internally, GstVulkanOperation contains two arrays:

1. The array of dependency frames, which are the set of frames, each representing an operation, which will hold dependency relationships with other dependency frames.

   gst_vulkan_operation_add_dependency_frame appends frames to this array.

   When calling gst_vulkan_operation_end the frame’s barrier state for each frame in the array is updated.

   Also, each dependency frame creates a timeline semaphore, which will be signaled when a command, associated with the frame, is executed in the device’s queue.

2. The array of barriers, which contains a list of synchronization commands. gst_vulkan_operation_add_frame_barrier fills and appends a VkImageMemoryBarrier2KHR associated with a frame, which can be in the array of dependency frames.

Here’s a generic view of video decoding example:

gst_vulkan_operation_begin (priv->exec, ...);

cmd_buf = priv->exec->cmd_buf->cmd;

gst_vulkan_operation_add_dependency_frame (exec, out,
    VK_PIPELINE_STAGE_2_VIDEO_DECODE_BIT_KHR,
    VK_PIPELINE_STAGE_2_VIDEO_DECODE_BIT_KHR);

/* assume a engine where out frames can be used for DPB frames, */
/* so a barrier for layout transition is required */
gst_vulkan_operation_add_frame_barrier (exec, out,
    VK_PIPELINE_STAGE_2_ALL_COMMANDS_BIT,
    VK_ACCESS_2_VIDEO_DECODE_WRITE_BIT_KHR,
    VK_IMAGE_LAYOUT_VIDEO_DECODE_DPB_KHR, NULL);

for (i = 0; i < dpb_size; i++) {
  gst_vulkan_operation_add_dependency_frame (exec, dpb_frame,
      VK_PIPELINE_STAGE_2_VIDEO_DECODE_BIT_KHR,
      VK_PIPELINE_STAGE_2_VIDEO_DECODE_BIT_KHR);
}

barriers = gst_vulkan_operation_retrieve_image_barriers (exec);
vkCmdPipelineBarrier2 (cmd_buf, &(VkDependencyInfo) {
    ...
    .pImageMemoryBarriers = barriers->data,
    .imageMemoryBarrierCount = barriers->len,
});
g_array_unref (barriers);

vkCmdBeginVideoCodingKHR (cmd_buf, &decode_start);
vkCmdDecodeVideoKHR (cmd_buf, &decode_info);
vkCmdEndVideoCodingKHR (cmd_buf, &decode_end);

gst_vulkan_operation_end (exec, ...);

Here, just one memory barrier is required for memory layout transition, but semaphores are required to signal when an output frame and its DPB frames are processed, and later, the output frame can be used as a DPB frame. Otherwise, the output frame might not be fully reconstructed with it’s used as DPB for the next output frame, generating only noise.

And that’s all. Thank you.

The GStreamer team is pleased to announce another bug fix release in the new stable 1.24 release series of your favourite cross-platform multimedia framework!

This release only contains bugfixes and security fixes and it should be safe to update from 1.24.x.

Highlighted bugfixes:

• audioconvert: support more than 64 audio channels
• avvidec: fix dropped frames when doing multi-threaded decoding of I-frame codecs such as DV Video
• mpegtsmux: Correctly time out in live pipelines, esp. for sparse streams like KLV and DVB subtitles
• vtdec deadlock fixes on shutdown and format/resolution changes (as might happen with e.g. HLS/DASH)
• fmp4mux, isomp4mux: Add support for adding AV1 header OBUs into the MP4 headers, and add language from tags
• gtk4paintablesink improvements: fullscreen mode and gst-play-1.0 support
• webrtcsink: add support for insecure TLS and improve error handling and VP9 handling
• vah264enc, vah265enc: timestamp handling fixes; generate IDR frames on force-keyunit-requests, not I frames
• v4l2codecs: decoder: Reorder caps to prefer `DMA_DRM` ones, fixes issues with playbin3
• Visualizer plugins fixes
• Avoid using private APIs on iOS
• various bug fixes, memory leak fixes, and other stability and reliability improvements

See the GStreamer 1.24.4 release notes for more details.

Binaries for Android, iOS, Mac OS X and Windows will be available shortly.

Last weeks were a bit hectic. First, with a couple friends we biked the southwest of the Netherlands for almost a week. The next week, the last one, I attended the 2024 Display Next Hackfest

https://mastodon.social/@igalia@floss.social/112438486139416587

This week was Igalia’s Assembly meetings, and next week, along with other colleagues, I’ll be in Thessaloniki for the GStreamer Spring Hackfest

https://mastodon.social/@gstreamer@floss.social/112473279155437759

I’m happy to meet again friends from the GStreamer community and talk and move things forward related with Vulkan, VA-API, KMS, video codecs, etc.

The GStreamer project is thrilled to announce that this year's GStreamer Conference will take place on Monday-Tuesday 7-8 October 2024 in Montréal, Québec, Canada, followed by a hackfest.

You can find more details about the conference on the GStreamer Conference 2024 web site.

A call for papers will be sent out in due course.

Registration will open at a later time, in late June / early July.

We will announce those and any further updates on the gstreamer-announce mailing list, the website, on Twitter. and on Mastodon.

Talk slots will be available in varying durations from 20 minutes up to 45 minutes. Whatever you're doing or planning to do with GStreamer, we'd like to hear from you!

We also plan to have sessions with short lightning talks / demos / showcase talks for those who just want to show what they've been working on or do a mini-talk instead of a full-length talk. Lightning talk slots will be allocated on a first-come-first-serve basis, so make sure to reserve your slot if you plan on giving a lightning talk.

A GStreamer hackfest will take place right after the conference, on 9-10 October 2024.

We hope to see you in Montréal!

Please spread the word!