Tag Archives: Open source

Introducing Open Source DAW Plugin for Eclipsa Audio

Eclipsa Audio logo

Eclipsa Audio is the brand name for a new, open-source 3D spatial audio technology. It's built upon the Immersive Audio Model and Formats (IAMF) specification, developed as a collaborative effort from the Alliance for Open Media (AOMedia). IAMF technology is available under a royalty free license from AOMedia.

An open source Eclipsa Audio plugin is now available for Digital Audio Workstations (DAWs) and Non-Linear Editing (NLE) software :

IAMF: A New Era for Immersive Audio

IAMF is a new open-source audio container specification poised to revolutionize how we experience sound. Developed by AOMedia, with significant contributions from industry, including Google and Samsung, IAMF aims to deliver truly immersive, three-dimensional audio across a wide array of applications, platforms, and devices.

At its core, IAMF is designed to deliver a realistic and engaging 3D soundscape. IAMF allows audio to be anywhere in space, including above, below, and behind the listener, creating a vivid three dimensional sphere of sound. This creates a more lifelike "3D audio" experience.

IAMF is designed as a versatile and open-source audio container format with several key technical characteristics to enable immersive and interactive audio experiences:

  • Codec-Agnostic Container: IAMF itself is not a codec but a container format. This means it can carry audio data compressed by various existing and future codecs, such as Opus, PCM, AAC, and FLAC.
  • Support for Multiple Audio Types: IAMF can handle different types of audio presentations, also called Audio Elements in the IAMF specification:
    • Channel-based audio: Such as 5.1.2 and 7.1.4, according to the Rec. ITU-R BS.2051-3
    • Scene-based audio: Full ambisonics spherical soundfield
  • 3D Spatial Audio Rendering: Open source based rendering to loudspeakers and binaurally for headphones.
  • Metadata for Rendering and Customization: IAMF includes Mix Presentation metadata that specifies how to render, process and mix one or more Audio Elements:
    • Creators can make user selectable Mix Presentations, for example enabling users to adjust dialog channel volume.
  • Open Source Reference Software: AOMedia provides various open-source tools for developers:
  • Integration with Standard Media Containers: IAMF is designed to be integrated into common media container formats like MP4 (ISO-BMFF) for delivery with video content.

The IAMF specification includes a definition for profiles which determine how many audio elements and audio channels a corresponding IAMF file can include. The table below summarizes the profile requirements for the current IAMF specifications.

Feature IAMF v1.0 IAMF v1.1
Profile Simple Base Base Enhanced
Audio codec Opus, AAC, FLAC, PCM Opus, AAC, FLAC, PCM Opus, AAC, FLAC, PCM
Max # of Audio Elements 1 2 28
Max # of audio channels 16 18 28

Eclipsa Audio support in YouTube

Since January 2025, YouTube now accepts files with Eclipsa Audio (IAMF v1.0) and consumers can now play the content on a growing range of compatible devices, including Samsung's 2025 TV and soundbar lineup.

Eclipsa Audio playback in a YouTube TV app can be verified with two different ways (see the screenshot below):

  • "Eclipsa Audio" should be visible in the Settings menu
  • "Stats for nerds" view should show the "iamf.001.001.Opus" string in the Codecs section

YouTube TV player user interface with settings

Here's an example of Eclipsa Audio content on YouTube. The actual audio track in this video consists of 3rd order ambisonics and stereo, thus it includes two audio elements and in total 18 channels of audio. Ambient sounds are all in the 3rd order ambisonics track (16 channels) and narrative parts in the stereo track (2 channels). YouTube uses the Opus open source codec for compressing the audio channel data.

Eclipsa Audio Plugins for Sound Design

The Eclipsa Audio plugin consists of two parts:

  • Eclipsa Audio renderer plugin: central hub for monitoring, configuration and export
  • Eclipsa Audio element plugin: connects your audio elements (channels) to the renderer plugin, with optional basic panning functionality

First release of the Eclipsa Audio plugin is available for Avid Pro Tools with macOS support. While downloading the plugin binaries from www.eclipsaapp.com, you can sign up to receive updates on the upcoming new releases.

The Eclipsa Audio Renderer Plugin manages the overall 3D audio mix, enabling you to configure speaker setups, monitor your mix, and export the final mix in the IAMF format. Additionally, it's used to create audio elements and configure mix presentations, both of which are required for playback.

Eclipsa Audio Renderer plugin user interface

The Eclipsa Audio Renderer Plugin provides comprehensive export options to ensure your 3D audio mix is correctly formatted and optimized for immersive playback systems. Once the final mix is ready for export, you can also select a video track to be muxed with the IAMF audio track. The final MP4 file after export is ready to be uploaded to YouTube.

Eclipsa Audio Renderer export options user interface

The Eclipsa Audio Element plugin should be added on every track you want to spatialize. This setup ensures each sound source is routed to the correct audio element and fully integrated into the 3D mix. To reduce the number of panners needed, Pro Tools' buses can also be used to route multiple tracks through an Audio Element plugin instance before routing the audio to the Eclipsa Audio Renderer Plugin. Pro Tools includes a great selection of built-in panning tools so it is recommended to use these tools for the actual sound mixing and use the pass-through option in the Audio Element plugin.

Next Steps

The Eclipsa Audio plugins continue to evolve. As an open source project, we invite developers to join and contribute.

By Jani Huoponen, Felicia Lim, Jan Skoglund - Open Media Audio Team

Introducing New Open Source Documentation Resources

shapes representing pie charts, a circuit board, and text edited with red markings

Today we're introducing two new open source documentation resources for open source software maintainers, a Docs Advisor guide and a set of Documentation Project Archetypes. These tools are intended to help maintainers make effective use of limited resources when it comes to planning and executing open source documentation work.

The Docs Advisor is a guide intended to demystify documentation work, including help picking a documentation approach, understanding your audience and available resources, and how to write, revise, evaluate, and maintain your documentation.

Documentation Project Archetypes are a set of thirteen project field guides. Each archetype represents a different type of documentation project, the problems it can solve, and how to bring the right collaborators together on the project to create great docs.

Origin story

More than 130 open source projects wrote 200+ case studies and project reports as a part of their participation in the Google Season of Docs program from 2019 to 2024. These case studies and project reports represent a variety of documentation projects from a wide range of open source groups. In these wrap-ups, project maintainers and technical writers describe how they approached their documentation projects, capturing many successes and more than a few challenges.

These reports are a treasure trove of lessons learned–but it's unrealistic to expect time-crunched open source maintainers to read through them all. So we got in touch with Daniel Beck and Erin Kissane to chat about ways to help organize and summarize some of these lessons learned.

These conversations turned into the Docs Advisor guide (‘like having an experienced technical writer hanging over your shoulder') and the thirteen Documentation Project Archetypes.

Our goal with these resources was to turn all of the hard-won experience of the Google Season of Docs participants into explicit documentation advice and guidance for open source maintainers.

More about the Docs Advisor

The Docs Advisor guide is intended to demystify the work of good documentation. It collects practices and processes from within technical writing and docs communities and from user experience, information architecture, and content strategy.

  • In Part 1, you'll pick an overall approach that suits the needs of your project.
  • In Part 2, you'll learn enough about your community and their needs to ensure that your hard work will be helping real people.
  • In Part 3, you'll assess your existing resources and pull together everything you need to move quickly and confidently through the work of creating and revising your docs.
  • In Part 4, you'll get to work writing and revising your docs and set yourself to successfully evaluate your work and maintain it.

The Docs Advisor guide also includes a docs plan template to help you accomplish your docs plan work, including:

  • What approach will you take to your documentation work, as a whole?
  • What risks do you need to mitigate?
  • Are there any documents to make or steps to perform to increase your chances of success?

The Docs Advisor incorporates guidance from interviews with open source maintainers and technical writers as well as from the Google Season of Docs case studies, and integrates the Documentation Project Archetypes into the recommendations for maintainers planning docs work.

More about the Archetypes

Documentation Project Archetypes are meant to help you recognize common types of documentation work (whether you're writing a new user guide or replatforming your docs site), the situations in which they apply, and organize yourself to bring the work to completion.

The archetypes cover the following areas:

  • Planning and evaluating your docs: Experiment and analysis archetypes support future docs work, by learning more about your existing docs, your audience, and your capacity to deliver meaningful change.
  • Producing new docs: Creation archetypes make new docs that directly help your audience complete tasks and achieve their goals.
  • Revising and transforming existing docs: Revision archetypes modify existing docs, to improve quality, reduce maintenance costs, and reach wider audiences.
  • Equipping yourself with docs tools and process: Tool and process archetypes adopt new tools or practices that help you make more, better, or higher quality docs.

All of the archetypes are available on GitHub.

The Edit: a secretary bird holding a red pencil and a doc showing copy marked up for editing The Audit: an otter holding an abacus and a red pie-shaped wedge against a background of pie charts and line charts The Factory: robot arms holding a red angled block against a backdrop of abstract circuitry in green and black

Doc tools in the wild

We are excited to share these tools and are looking forward to seeing how they are used and evolve.

Daniel demoed the concept and first completed archetype, The Migration, at FOSDEM 2025 in his talk Patterns for maintainer and tech writer collaboration. He also talked about the work on the API Resilience Podcast episode "Patterns in Documentation."

We hope to get valuable feedback during a proposed Doc Archetypes session at Open Source Summit Europe 2025 (acceptance pending).

We are also excited to be developing some Doc Archetype illustration cards with Heather Cummings — a few previews are already live on The Edit, The Audit, and The Factory.

If you have questions or suggestions, please raise an issue in the Open Docs repo.

By Elena Spitzer & Erin McKean, Google Open Source Programs Office

Transforming Kubernetes and GKE into the leading platform for AI/ML

The world is rapidly embracing the power of AI/ML, from training cutting-edge foundation models to deploying intelligent applications at scale. As these workloads become more sophisticated and demanding, the infrastructure required to support them must evolve. Kubernetes has emerged as the standard for container orchestration, but AI/ML introduces unique challenges that push traditional infrastructure to its limits.

AI training jobs often require massive scale, needing to coordinate thousands of specialized hardware like GPUs and TPUs. Reliability is critical, as failures can be costly for long running, large-scale training jobs. Efficient resource sharing across teams and workloads is essential given the expense of accelerators. Furthermore, deploying and scaling AI models for inference demands low latency and faster startup times for large container images and models.

At Google, we are deeply invested in the AI/ML revolution. This is why we are doubling down on our commitment to advancing Kubernetes as the foundational open standard for these workloads. Our strategy centers on evolving the core Kubernetes platform to meet the needs of the "next trillion core hours," specifically focusing on batch and AI/ML. We then bring these advancements, alongside enterprise-grade management and optimizations, to users through Google Kubernetes Engine (GKE).

Here's how we are transforming Kubernetes and GKE:

Redefining Kubernetes' relationship with specialized hardware

Kubernetes was initially designed for more uniform CPU compute. The surge of AI/ML brought new requirements for seamless integration and efficient management of expensive, sparse, and diverse accelerators. To support these new demands, Google has been a key investor in upstream Kubernetes to offer robust support for a diverse portfolio of the latest accelerators, including multiple generations of TPUs and a wide range of NVIDIA GPUs.

A core Kubernetes enhancement driven by Google and the community to better support AI/ML workloads is Dynamic Resource Allocation (DRA). This framework, developed in the heart of Kubernetes, provides a more flexible and extensible way for workloads to request and consume specialized hardware resources beyond traditional CPU and memory, which is crucial for efficiently managing accelerators. Building on such foundational open-source capabilities, GKE can then offer features like Custom Compute Classes, which improve the obtainability of these resources through intelligent fallback priorities across different capacity types like reservations, on-demand, and Spot instances. Google's active contributions to advanced resource management and scheduling capabilities within the Kubernetes community ensure that the platform evolves to meet the sophisticated demands of AI/ML, making efficient use of these specialized hardware resources more broadly accessible.

Unlocking scale and reliability

AI/ML workloads demand unprecedented scale and have new failure modes compared to traditional applications. GKE is built to handle this, supporting up to 65,000 nodes in a single cluster. We've demonstrated the ability to run the largest publicly announced training jobs, coordinating 50,000 TPU chips with near-ideal scaling efficiency.

Critically, we are enhancing core Kubernetes capabilities to support the scale and reliability needed for AI/ML. For instance, to better manage distributed AI workloads like serving large models split across multiple hosts, Google has been instrumental in developing features like JobSet (emerging from earlier concepts like LeaderWorkerSet) within the Kubernetes community (SIG Apps). This provides robust orchestration for co-scheduled, interdependent groups of Pods. We are also actively working upstream to improve Kubernetes reliability and stability through initiatives like Production Readiness Reviews, promoting safer upgrade paths, and enhancing etcd stability for the benefit of all Kubernetes users.

Optimizing Kubernetes performance for efficient inference

Low-latency and cost-efficient inference is critical for AI applications. For serving, the GKE Inference Gateway routes requests based on model server metrics like KVCache utilization and pending queue length, reducing serving costs by up to 30% and tail latency by 60% compared to traditional load balancing. We've even achieved vLLM fungibility across TPUs and GPUs, allowing users to serve the same model on either accelerator without incremental effort.

To address slow startup times for large AI/ML container images (often 20GB+), GKE offers rapid scale-out features. Secondary boot disks allow preloading container images and data, resulting in up to 29x faster container mounting time. GCS FUSE enables streaming data directly from Cloud Storage, leading to faster model load times. Furthermore, GKE Inference Quickstart provides data-driven, optimized Kubernetes deployment configurations, saving extensive benchmarking effort and enabling up to 30% lower cost, 60% lower tail latency, and 40% higher throughput.

Simplifying the Kubernetes experience and enhancing observability for AI/ML

We understand that data scientists and ML researchers may not be Kubernetes experts. Google aims to simplify the setup and management of AI-optimized Kubernetes clusters. This includes contributions to Kubernetes usability efforts and SIG-Usability. Managed offerings like GKE provide multiple paths to set up AI-optimized environments, from default configurations to customizable blueprints. Offerings like GKE Autopilot further abstract away infrastructure management, aiming for the ease of use that benefits all users.
Ensuring visibility into AI/ML workloads is paramount. Google actively supports and contributes to the integration of standard open-source observability tools within the Kubernetes ecosystem, such as Prometheus, Grafana, and OpenTelemetry. Building on this open foundation, GKE then provides enhanced, out-of-the-box observability integrated with popular AI frameworks & tools, including specific insights into workload startup latency and end-to-end tracing.

Looking ahead: continued investment in Open Source Kubernetes for AI/ML

The transformation continues. Our roadmap includes exciting developments in upstream Kubernetes for easily deploying and managing large-scale clusters, support for new GPU & TPU generations integrated through open-source mechanisms, and continued community-driven innovations in fast startup, reliability, and ease of use for AI/ML workloads.

Google is committed to making Kubernetes the premier open-source platform for AI/ML, pushing the boundaries of scale, performance, and efficiency while maintaining stability and ease of use. By driving innovation in core Kubernetes and building powerful, deeply integrated capabilities in our managed offering, GKE, we are empowering organizations to accelerate their AI/ML initiatives and unlock the next generation of intelligent applications built on an open foundation.

Come explore the possibilities with Kubernetes and GKE for your AI/ML workloads!

By Francisco Cabrera & Federico Bongiovanni, GCP Google Kubernetes Engine

Androidify: Building powerful AI-driven experiences with Jetpack Compose, Gemini and CameraX

Posted by Rebecca Franks – Developer Relations Engineer

The Android bot is a beloved mascot for Android users and developers, with previous versions of the bot builder being very popular - we decided that this year we’d rebuild the bot maker from the ground up, using the latest technology backed by Gemini. Today we are releasing a new open source app, Androidify, for learning how to build powerful AI driven experiences on Android using the latest technologies such as Jetpack Compose, Gemini through Firebase, CameraX, and Navigation 3.

a moving image of various droid bots dancing individually

Androidify app demo

Here’s an example of the app running on the device, showcasing converting a photo to an Android bot that represents my likeness:

moving image showing the conversion of an image of a woman in a pink dress holding na umbrella into a 3D image of a droid bot wearing a pink dress holding an umbrella

Under the hood

The app combines a variety of different Google technologies, such as:

    • Gemini API - through Firebase AI Logic SDK, for accessing the underlying Imagen and Gemini models.
    • Jetpack Compose - for building the UI with delightful animations and making the app adapt to different screen sizes.
    • Navigation 3 - the latest navigation library for building up Navigation graphs with Compose.
    • CameraX Compose and Media3 Compose - for building up a custom camera with custom UI controls (rear camera support, zoom support, tap-to-focus) and playing the promotional video.

This sample app is currently using a standard Imagen model, but we've been working on a fine-tuned model that's trained specifically on all of the pieces that make the Android bot cute and fun; we'll share that version later this year. In the meantime, don't be surprised if the sample app puts out some interesting looking examples!

How does the Androidify app work?

The app leverages our best practices for Architecture, Testing, and UI to showcase a real world, modern AI application on device.

Flow chart describing Androidify app flow
Androidify app flow chart detailing how the app works with AI

AI in Androidify with Gemini and ML Kit

The Androidify app uses the Gemini models in a multitude of ways to enrich the app experience, all powered by the Firebase AI Logic SDK. The app uses Gemini 2.5 Flash and Imagen 3 under the hood:

    • Image validation: We ensure that the captured image contains sufficient information, such as a clearly focused person, and assessing for safety. This feature uses the multi-modal capabilities of Gemini API, by giving it a prompt and image at the same time:

val response = generativeModel.generateContent(
   content {
       text(prompt)
       image(image)
   },
)

    • Text prompt validation: If the user opts for text input instead of image, we use Gemini 2.5 Flash to ensure the text contains a sufficiently descriptive prompt to generate a bot.

    • Image captioning: Once we’re sure the image has enough information, we use Gemini 2.5 Flash to perform image captioning., We ask Gemini to be as descriptive as possible,focusing on the clothing and its colors.

    • “Help me write” feature: Similar to an “I’m feeling lucky” type feature, “Help me write” uses Gemini 2.5 Flash to create a random description of the clothing and hairstyle of a bot.

    • Image generation from the generated prompt: As the final step, Imagen generates the image, providing the prompt and the selected skin tone of the bot.

The app also uses the ML Kit pose detection to detect a person in the viewfinder and enable the capture button when a person is detected, as well as adding fun indicators around the content to indicate detection.

Explore more detailed information about AI usage in Androidify.

Jetpack Compose

The user interface of Androidify is built using Jetpack Compose, the modern UI toolkit that simplifies and accelerates UI development on Android.

Delightful details with the UI

The app uses Material 3 Expressive, the latest alpha release that makes your apps more premium, desirable, and engaging. It provides delightful bits of UI out-of-the-box, like new shapes, componentry, and using the MotionScheme variables wherever a motion spec is needed.

MaterialShapes are used in various locations. These are a preset list of shapes that allow for easy morphing between each other—for example, the cute cookie shape for the camera capture button:


Androidify app UI showing camera button
Camera button with a MaterialShapes.Cookie9Sided shape

Beyond using the standard Material components, Androidify also features custom composables and delightful transitions tailored to the specific needs of the app:

    • There are plenty of shared element transitions across the app—for example, a morphing shape shared element transition is performed between the “take a photo” button and the camera surface.

      moving example of expressive button shapes in slow motion

    • Custom enter transitions for the ResultsScreen with the usage of marquee modifiers.

      animated marquee example

    • Fun color splash animation as a transition between screens.

      moving image of a blue color splash transition between Androidify demo screens

    • Animating gradient buttons for the AI-powered actions.

      animated gradient button for AI powered actions example

To learn more about the unique details of the UI, read Androidify: Building delightful UIs with Compose

Adapting to different devices

Androidify is designed to look great and function seamlessly across candy bar phones, foldables, and tablets. The general goal of developing adaptive apps is to avoid reimplementing the same app multiple times on each form factor by extracting out reusable composables, and leveraging APIs like WindowSizeClass to determine what kind of layout to display.

a collage of different adaptive layouts for the Androidify app across small and large screens
Various adaptive layouts in the app

For Androidify, we only needed to leverage the width window size class. Combining this with different layout mechanisms, we were able to reuse or extend the composables to cater to the multitude of different device sizes and capabilities.

    • Responsive layouts: The CreationScreen demonstrates adaptive design. It uses helper functions like isAtLeastMedium() to detect window size categories and adjust its layout accordingly. On larger windows, the image/prompt area and color picker might sit side-by-side in a Row, while on smaller windows, the color picker is accessed via a ModalBottomSheet. This pattern, called “supporting pane”, highlights the supporting dependencies between the main content and the color picker.

    • Foldable support: The app actively checks for foldable device features. The camera screen uses WindowInfoTracker to get FoldingFeature information to adapt to different features by optimizing the layout for tabletop posture.

    • Rear display: Support for devices with multiple displays is included via the RearCameraUseCase, allowing for the device camera preview to be shown on the external screen when the device is unfolded (so the main content is usually displayed on the internal screen).

Using window size classes, coupled with creating a custom @LargeScreensPreview annotation, helps achieve unique and useful UIs across the spectrum of device sizes and window sizes.

CameraX and Media3 Compose

To allow users to base their bots on photos, Androidify integrates CameraX, the Jetpack library that makes camera app development easier.

The app uses a custom CameraLayout composable that supports the layout of the typical composables that a camera preview screen would include— for example, zoom buttons, a capture button, and a flip camera button. This layout adapts to different device sizes and more advanced use cases, like the tabletop mode and rear-camera display. For the actual rendering of the camera preview, it uses the new CameraXViewfinder that is part of the camerax-compose artifact.

CameraLayout in Compose
CameraLayout composable that takes care of different device configurations, such as table top mode

CameraLayout in Compose
CameraLayout composable that takes care of different device configurations, such as table top mode

The app also integrates with Media3 APIs to load an instructional video for showing how to get the best bot from a prompt or image. Using the new media3-ui-compose artifact, we can easily add a VideoPlayer into the app:

@Composable
private fun VideoPlayer(modifier: Modifier = Modifier) {
    val context = LocalContext.current
    var player by remember { mutableStateOf<Player?>(null) }
    LifecycleStartEffect(Unit) {
        player = ExoPlayer.Builder(context).build().apply {
            setMediaItem(MediaItem.fromUri(Constants.PROMO_VIDEO))
            repeatMode = Player.REPEAT_MODE_ONE
            prepare()
        }
        onStopOrDispose {
            player?.release()
            player = null
        }
    }
    Box(
        modifier
            .background(MaterialTheme.colorScheme.surfaceContainerLowest),
    ) {
        player?.let { currentPlayer ->
            PlayerSurface(currentPlayer, surfaceType = SURFACE_TYPE_TEXTURE_VIEW)
        }
    }
}

Using the new onLayoutRectChanged modifier, we also listen for whether the composable is completely visible or not, and play or pause the video based on this information:

var videoFullyOnScreen by remember { mutableStateOf(false) }     

LaunchedEffect(videoFullyOnScreen) {
     if (videoFullyOnScreen) currentPlayer.play() else currentPlayer.pause()
} 

// We add this onto the player composable to determine if the video composable is visible, and mutate the videoFullyOnScreen variable, that then toggles the player state. 
Modifier.onVisibilityChanged(
                containerWidth = LocalView.current.width,
                containerHeight = LocalView.current.height,
) { fullyVisible -> videoFullyOnScreen = fullyVisible }

// A simple version of visibility changed detection
fun Modifier.onVisibilityChanged(
    containerWidth: Int,
    containerHeight: Int,
    onChanged: (visible: Boolean) -> Unit,
) = this then Modifier.onLayoutRectChanged(100, 0) { layoutBounds ->
    onChanged(
        layoutBounds.boundsInRoot.top > 0 &&
            layoutBounds.boundsInRoot.bottom < containerHeight &&
            layoutBounds.boundsInRoot.left > 0 &&
            layoutBounds.boundsInRoot.right < containerWidth,
    )
}

Additionally, using rememberPlayPauseButtonState, we add on a layer on top of the player to offer a play/pause button on the video itself:

val playPauseButtonState = rememberPlayPauseButtonState(currentPlayer)
            OutlinedIconButton(
                onClick = playPauseButtonState::onClick,
                enabled = playPauseButtonState.isEnabled,
            ) {
                val icon =
                    if (playPauseButtonState.showPlay) R.drawable.play else R.drawable.pause
                val contentDescription =
                    if (playPauseButtonState.showPlay) R.string.play else R.string.pause
                Icon(
                    painterResource(icon),
                    stringResource(contentDescription),
                )
            }

Check out the code for more details on how CameraX and Media3 were used in Androidify.

Navigation 3

Screen transitions are handled using the new Jetpack Navigation 3 library androidx.navigation3. The MainNavigation composable defines the different destinations (Home, Camera, Creation, About) and displays the content associated with each destination using NavDisplay. You get full control over your back stack, and navigating to and from destinations is as simple as adding and removing items from a list.

@Composable
fun MainNavigation() {
   val backStack = rememberMutableStateListOf<NavigationRoute>(Home)
   NavDisplay(
       backStack = backStack,
       onBack = { backStack.removeLastOrNull() },
       entryProvider = entryProvider {
           entry<Home> { entry ->
               HomeScreen(
                   onAboutClicked = {
                       backStack.add(About)
                   },
               )
           }
           entry<Camera> {
               CameraPreviewScreen(
                   onImageCaptured = { uri ->
                       backStack.add(Create(uri.toString()))
                   },
               )
           }
           // etc
       },
   )
}

Notably, Navigation 3 exposes a new composition local, LocalNavAnimatedContentScope, to easily integrate your shared element transitions without needing to keep track of the scope yourself. By default, Navigation 3 also integrates with predictive back, providing delightful back experiences when navigating between screens, as seen in this prior shared element transition:

CameraLayout in Compose

Learn more about Jetpack Navigation 3, currently in alpha.

Learn more

By combining the declarative power of Jetpack Compose, the camera capabilities of CameraX, the intelligent features of Gemini, and thoughtful adaptive design, Androidify is a personalized avatar creation experience that feels right at home on any Android device. You can find the full code sample at github.com/android/androidify where you can see the app in action and be inspired to build your own AI-powered app experiences.

Explore this announcement and all Google I/O 2025 updates on io.google starting May 22.


Androidify: Building delightful UIs with Compose

Posted by Rebecca Franks - Developer Relations Engineer

Androidify is a new sample app we built using the latest best practices for mobile apps. Previously, we covered all the different features of the app, from Gemini integration and CameraX functionality to adaptive layouts. In this post, we dive into the Jetpack Compose usage throughout the app, building upon our base knowledge of Compose to add delightful and expressive touches along the way!

Material 3 Expressive

Material 3 Expressive is an expansion of the Material 3 design system. It’s a set of new features, updated components, and design tactics for creating emotionally impactful UX.


It’s been released as part of the alpha version of the Material 3 artifact (androidx.compose.material3:material3:1.4.0-alpha10) and contains a wide range of new components you can use within your apps to build more personalized and delightful experiences. Learn more about Material 3 Expressive's component and theme updates for more engaging and user-friendly products.

Material Expressive Component updates
Material Expressive Component updates

In addition to the new component updates, Material 3 Expressive introduces a new motion physics system that's encompassed in the Material theme.

In Androidify, we’ve utilized Material 3 Expressive in a few different ways across the app. For example, we’ve explicitly opted-in to the new MaterialExpressiveTheme and chosen MotionScheme.expressive() (this is the default when using expressive) to add a bit of playfulness to the app:

@Composable
fun AndroidifyTheme(
   content: @Composable () -> Unit,
) {
   val colorScheme = LightColorScheme


   MaterialExpressiveTheme(
       colorScheme = colorScheme,
       typography = Typography,
       shapes = shapes,
       motionScheme = MotionScheme.expressive(),
       content = {
           SharedTransitionLayout {
               CompositionLocalProvider(LocalSharedTransitionScope provides this) {
                   content()
               }
           }
       },
   )
}

Some of the new componentry is used throughout the app, including the HorizontalFloatingToolbar for the Prompt type selection:

moving example of expressive button shapes in slow motion

The app also uses MaterialShapes in various locations, which are a preset list of shapes that allow for easy morphing between each other. For example, check out the cute cookie shape for the camera capture button:

Material Expressive Component updates
Camera button with a MaterialShapes.Cookie9Sided shape

Animations

Wherever possible, the app leverages the Material 3 Expressive MotionScheme to obtain a themed motion token, creating a consistent motion feeling throughout the app. For example, the scale animation on the camera button press is powered by defaultSpatialSpec(), a specification used for animations that move something across a screen (such as x,y or rotation, scale animations):

val interactionSource = remember { MutableInteractionSource() }
val animationSpec = MaterialTheme.motionScheme.defaultSpatialSpec<Float>()
Spacer(
   modifier
       .indication(interactionSource, ScaleIndicationNodeFactory(animationSpec))
       .clip(MaterialShapes.Cookie9Sided.toShape())
       .size(size)
       .drawWithCache {
           //.. etc
       },
)

Camera button scale interaction
Camera button scale interaction

Shared element animations

The app uses shared element transitions between different screen states. Last year, we showcased how you can create shared elements in Jetpack Compose, and we’ve extended this in the Androidify sample to create a fun example. It combines the new Material 3 Expressive MaterialShapes, and performs a transition with a morphing shape animation:

moving example of expressive button shapes in slow motion

To do this, we created a custom Modifier that takes in the target and resting shapes for the sharedBounds transition:

@Composable
fun Modifier.sharedBoundsRevealWithShapeMorph(
   sharedContentState: 
SharedTransitionScope.SharedContentState,
   sharedTransitionScope: SharedTransitionScope = 
LocalSharedTransitionScope.current,
   animatedVisibilityScope: AnimatedVisibilityScope = 
LocalNavAnimatedContentScope.current,
   boundsTransform: BoundsTransform = 
MaterialTheme.motionScheme.sharedElementTransitionSpec,
   resizeMode: SharedTransitionScope.ResizeMode = 
SharedTransitionScope.ResizeMode.RemeasureToBounds,
   restingShape: RoundedPolygon = RoundedPolygon.rectangle().normalized(),
   targetShape: RoundedPolygon = RoundedPolygon.circle().normalized(),
)

Then, we apply a custom OverlayClip to provide the morphing shape, by tying into the AnimatedVisibilityScope provided by the LocalNavAnimatedContentScope:

val animatedProgress =
   animatedVisibilityScope.transition.animateFloat(targetValueByState = targetValueByState)


val morph = remember {
   Morph(restingShape, targetShape)
}
val morphClip = MorphOverlayClip(morph, { animatedProgress.value })


return this@sharedBoundsRevealWithShapeMorph
   .sharedBounds(
       sharedContentState = sharedContentState,
       animatedVisibilityScope = animatedVisibilityScope,
       boundsTransform = boundsTransform,
       resizeMode = resizeMode,
       clipInOverlayDuringTransition = morphClip,
       renderInOverlayDuringTransition = renderInOverlayDuringTransition,
   )

View the full code snippet for this Modifer on GitHub.

Autosize text

With the latest release of Jetpack Compose 1.8, we added the ability to create text composables that automatically adjust the font size to fit the container’s available size with the new autoSize parameter:

BasicText(text,
style = MaterialTheme.typography.titleLarge,
autoSize = TextAutoSize.StepBased(maxFontSize = 220.sp),
)

This is used front and center for the “Customize your own Android Bot” text:

Text reads Customize your own Android Bot with an inline moving image
“Customize your own Android Bot” text with inline GIF

This text composable is interesting because it needed to have the fun dancing Android bot in the middle of the text. To do this, we use InlineContent, which allows us to append a composable in the middle of the text composable itself:

@Composable
private fun DancingBotHeadlineText(modifier: Modifier = Modifier) {
   Box(modifier = modifier) {
       val animatedBot = "animatedBot"
       val text = buildAnnotatedString {
           append(stringResource(R.string.customize))
           // Attach "animatedBot" annotation on the placeholder
           appendInlineContent(animatedBot)
           append(stringResource(R.string.android_bot))
       }
       var placeHolderSize by remember {
           mutableStateOf(220.sp)
       }
       val inlineContent = mapOf(
           Pair(
               animatedBot,
               InlineTextContent(
                   Placeholder(
                       width = placeHolderSize,
                       height = placeHolderSize,
                       placeholderVerticalAlign = PlaceholderVerticalAlign.TextCenter,
                   ),
               ) {
                   DancingBot(
                       modifier = Modifier
                           .padding(top = 32.dp)
                           .fillMaxSize(),
                   )
               },
           ),
       )
       BasicText(
           text,
           modifier = Modifier
               .align(Alignment.Center)
               .padding(bottom = 64.dp, start = 16.dp, end = 16.dp),
           style = MaterialTheme.typography.titleLarge,
           autoSize = TextAutoSize.StepBased(maxFontSize = 220.sp),
           maxLines = 6,
           onTextLayout = { result ->
               placeHolderSize = result.layoutInput.style.fontSize * 3.5f
           },
           inlineContent = inlineContent,
       )
   }
}

Composable visibility with onLayoutRectChanged

With Compose 1.8, a new modifier, Modifier.onLayoutRectChanged, was added. This modifier is a more performant version of onGloballyPositioned, and includes features such as debouncing and throttling to make it performant inside lazy layouts.

In Androidify, we’ve used this modifier for the color splash animation. It determines the position where the transition should start from, as we attach it to the “Let’s Go” button:

var buttonBounds by remember {
   mutableStateOf<RelativeLayoutBounds?>(null)
}
var showColorSplash by remember {
   mutableStateOf(false)
}
Box(modifier = Modifier.fillMaxSize()) {
   PrimaryButton(
       buttonText = "Let's Go",
       modifier = Modifier
           .align(Alignment.BottomCenter)
           .onLayoutRectChanged(
               callback = { bounds ->
                   buttonBounds = bounds
               },
           ),
       onClick = {
           showColorSplash = true
       },
   )
}

We use these bounds as an indication of where to start the color splash animation from.

moving image of a blue color splash transition between Androidify demo screens

Learn more delightful details

From fun marquee animations on the results screen, to animated gradient buttons for the AI-powered actions, to the path drawing animation for the loading screen, this app has many delightful touches for you to experience and learn from.

animated marquee example

animated gradient button for AI powered actions example

animated loading screen example

Check out the full codebase at github.com/android/androidify and learn more about the latest in Compose from using Material 3 Expressive, the new modifiers, auto-sizing text and of course a couple of delightful interactions!

Explore this announcement and all Google I/O 2025 updates on io.google starting May 22.

Announcing LMEval: An Open Source Framework for Cross-Model Evaluation

Announcing LMEval: An Open Source Framework for Cross-Model Evaluation

Authors: Elie Bursztein - Distinguished Research Scientist & David Tao - Software Engineer, Applied Security and Safety Research

Simplifying Cross-Provider Model Benchmarking

At InCyber Forum Europe in April, we open sourced LMEval, a large model evaluation framework, to help others accurately and efficiently compare how models from various providers perform across benchmark datasets. This announcement coincided with a joint talk with Giskard about our collaboration to increase trust in model safety and security. Giskard uses LMeval to run the Phare benchmark that independently evaluates popular models' security and safety.

Results from the Phare benchmark that leverages LMEval for evaluation
Example of LMEval running on a multimodal benchmark across two models.

Rapid Changes in the Landscape of Large Models

New Large Language Models (LLMs) are released constantly, often promising improvements and new features. To keep up with this fast-paced lifecycle, developers, researchers, and organizations must quickly and reliably evaluate if those newer models are better suited for their specific applications. So far, rapid model evaluation has proven difficult, as it requires tools that allow scalable, accurate, easy-to-use, cross-provider benchmarking.

Introducing LMEval: Simplifying Cross-Provider Model Benchmarking

To address this challenge, we are excited to introduce LMEval (Large Model Evaluator), an open source framework that Google developed to streamline the evaluation of LLMs across diverse benchmark datasets and model providers. LMEval is designed from the ground up to be accurate, multimodal, and easy-to-use. Its key features include:

  • Multi-Provider Compatibility: Evaluating models shouldn't require wrestling with different APIs for each provider. LMEval leverages the LiteLLM framework to offer out-of-the-box compatibility with major model providers including Google, OpenAI, Anthropic, Ollama, and Hugging Face. You can define your benchmark once and run it consistently across various models with minimal code changes.
  • Incremental & Efficient Evaluation: Re-running an entire benchmark suite every time a new model or version is released is slow, inefficient and costly. LMEval's intelligent evaluation engine plans and executes evaluations incrementally. It runs only the necessary evaluations for new models, prompts, or questions, saving significant time and compute resources. Its multi-threaded engine further accelerates this process.
  • Multimodal & Multi-Metric Support: Modern foundation models go beyond text. LMEval is designed for multimodal evaluation, supporting benchmarks that include text, images and code. Adding new modalities is straightforward. Furthermore, it supports various scoring metrics to support a wide range of benchmark formats from boolean questions, to multi-choices, to free form generation. Additionally, LMEval provides support for safety/punting detection.
  • Scalable & Secure Storage: To store benchmark results in a secure and efficient manner, LMEval utilizes a self-encrypting SQLite database. This approach protects benchmark data and results from inadvertent crawling/indexing while they stay easily accessible through LMEval.

Getting Started with LMEval

Creating and running evaluations with LMEval is designed to be intuitive. Here's a simplified example demonstrating how to evaluate two Gemini model versions on a benchmark:

Example of LMEval running on a multimodal benchmark across two models.
Results from the Phare benchmark that leverages LMEval for evaluation

The LMEval GitHub repository includes example notebooks to help you get started.

Visualizing Results with LMEvalboard

Understanding benchmark results requires more than just summary statistics. To help with this, LMEval includes LMEvalboard, a companion dashboard tool that offers an interactive visualization of how models stack up against each other. LMEvalboard provides valuable insights into model strengths and weaknesses, complementing traditional raw evaluation data.

LMEvalboard UI allows to quickly analyze how models compares on a given benchmark
LMEvalboard UI allows to quickly analyze how models compares on a given benchmark

LMEvalboard allows you to:

  • View Overall Performance: Quickly compare all models' accuracy across the entire benchmark.
  • Analyze a Single Model: Dive deep into a specific model's performance characteristics across different categories using radar charts and drill down on specific examples of failures
  • Perform Head-to-Head Comparisons: Directly compare two models, visualizing their performance differences across categories and examine specific questions where they disagree.

Try LMEval Today!

We invite you to explore LMEval, use it for your own evaluations, and contribute to its development by heading to the LMEval GitHub repository: https://github.com/google/lmeval

Acknowledgements

LMEval would not have been possible without the help of many people, including: Luca Invernizzi, Lenin Simicich, Marianna Tishchenko, Amanda Walker, and many other Googlers.

Kubernetes 1.33 is available on GKE!

Kubernetes 1.33 is now available in the Google Kubernetes Engine (GKE) Rapid Channel! For more information about the content of Kubernetes 1.33, read the official Kubernetes 1.33 Release Notes and the specific GKE 1.33 Release Notes.

Enhancements in 1.33:

In-place Pod Resizing

Workloads can be scaled horizontally by updating the Pod replica count, or vertically by updating the resources required in the Pods container(s). Before this enhancement, container resources defined in a Pod's spec were immutable, and updating any of these details within a Pod template would trigger Pod replacement impacting service's reliability.

In-place Pod Resizing (IPPR, Public Preview) allows you to change the CPU and memory requests and limits assigned to containers within a running Pod through the new /resize pod subresource, often without requiring a container restart decreasing service's disruptions.

This opens up various possibilities for vertical scale-up of stateful processes without any downtime, seamless scale-down when the traffic is low, and even allocating larger resources during startup, which can then be reduced once the initial setup is complete.

Review Resize CPU and Memory Resources assigned to Containers for detailed guidance on using the new API.

DRA

Kubernetes Dynamic Resource Allocation (DRA), currently in beta as of v1.33, offers a more flexible API for requesting devices than Device Plugin. (Instructions for opt-in beta features in GKE)

Recent updates include the promotion of driver-owned resource claim status to beta. New alpha features introduced are partitionable devices, device taints and tolerations for managing device availability, prioritized device lists for versatile workload allocation, and enhanced admin access controls. Preparations for general availability include a new v1beta2 API to improve user experience and simplify future feature integration, alongside improved RBAC rules and support for seamless driver upgrades. DRA is anticipated to reach general availability in Kubernetes v1.34.

containerd 2.0

With GKE 1.33, we are excited to introduce support for containerd 2.0. This marks the first major version update for the underlying container runtime used by GKE. Adopting this version ensures that GKE continues to leverage the latest advancements and security enhancements from the upstream containerd community.

It's important to note that as a major version update, containerd 2.0 introduces many new features and enhancements while also deprecating others. To ensure a smooth transition and maintain compatibility for your workloads, we strongly encourage you to review your Cloud Recommendations. These recommendations will help identify any workloads that may be affected by these changes. Please see "Migrate nodes to containerd 2" for detailed guidance on making your workloads forward-compatible.

Multiple Service CIDRs

This enhancement introduced a new implementation of allocation logic for Service IPs. The updated IP address allocator logic uses two newly stable API objects: ServiceCIDR and IPAddress. Now generally available, these APIs allow cluster administrators to dynamically increase the number of IP addresses available for Services by creating new ServiceCIDR objects.

Highlight of Googlers' contributions in 1.33 cycle:

Coordinated Leader Election

The Coordinated Leader Election feature progressed to beta, introducing significant enhancements in how a lease-candidate's availability is determined for an election. Specifically, the ping-acknowledgement checking process has been optimized to be fully concurrent instead of the previous sequential approach ensuring faster and more efficient detection of unresponsive candidates, which is essential for promptly identifying truly available lease candidates and maintaining the reliability of the leader election process.

Compatibility Versions

New CLI flags were added to apiserver as options for adjusting API enablement wrt an apiserver's emulated version. --emulation-forward-compatible is an option to implicitly enable all APIs which are introduced after the emulation version and have higher priority than APIs of the same group resource enabled at the emulation version.
--runtime-config-emulation-forward-compatible is an option to explicit enable specific APIs introduced after the emulation version through the runtime-config

zPages

ComponentStatusz and ComponentFlagz alpha features are now available to be turned on for all control plane components.
Components now expose two new HTTP endpoints, /statusz and /flagz, providing enhanced visibility into their internal state. /statusz details the component's uptime, golang, binary and emulation versions info, while /flagz reveals the command-line arguments used at startup.

Streaming List Responses

To improve cluster stability when handling large datasets, streaming encoding for List responses was introduced as a new Beta feature. Previously, serializing entire List responses into a single memory block could strain kube-apiserver memory. The new streaming encoder processes and transmits each item in a list individually, preventing large memory allocations. This significantly reduces memory spikes, improves API server reliability, and enhances overall cluster performance, especially for clusters with large resources, all while maintaining backward compatibility and requiring no client-side changes.

Snapshottable API server cache

Further enhancing API server performance and stability, a new Alpha feature introduces snapshotting to the watchcache. This allows serving LIST requests for historical or paginated data directly from its in-memory cache. Previously, these types of requests would query etcd directly, requiring to pipe the data through multiple encoding, decoding, and validation stages. This process often led to increased memory pressure, unpredictable performance, and potential stability issues, especially with large resources. By leveraging efficient B-tree based snapshotting within the watchcache, this enhancement significantly reduces direct etcd load and minimizes memory allocations on the API server. This results in more predictable performance, increased API server reliability, and better overall resource utilization, while incorporating mechanisms to ensure data consistency between the cache and etcd.

Declarative Validation

Kubernetes thrives on its large, vibrant community of contributors. We're constantly looking for ways to help make it easier to maintain and contribute to this project. For years, one area that posed challenges was how the Kubernetes API itself was validated: using hand-written Go code. This traditional method has proven to be difficult to authors, challenging to review and cumbersome to document, impacting overall maintainability and the contributor experience. To address these pain points, the declarative validation project was initiated.
In 1.33, the foundational infrastructure was established to transition Kubernetes API validation from handwritten Go code to a declarative model using IDL tags. This release introduced the validation-gen code generator, designed to parse these IDL tags and produce Go validation functions.

Ordered Namespace Deletion

The current namespace deletion process is semi-random, which may lead to security gaps or unintended behavior, such as Pods persisting after the deletion of their associated NetworkPolicies. By implementing an opinionated deletion mechanism, the Pods will be deleted before other resources with respect to logical and security dependencies. This design enhances the security and reliability of Kubernetes by mitigating risks arising from the non-deterministic deletion order.

Acknowledgements

As always, we want to thank all the Googlers that provide their time, passion, talent and leadership to keep making Kubernetes the best container orchestration platform. We would like to mention especially Googlers who helped drive the contributions mentioned in this blog: Tim Allclair, Natasha Sarkar, Vivek Bansal, Anish Shah, Dawn Chen, Tim Hockin, John Belamaric, Morten Torkildsen, Yu Liao,Cici Huang, Samuel Karp, Chris Henzie, Luiz Oliveira, Piotr Betkier, Alex Curtis, Jonah Peretz, Brad Hoekstra, Yuhan Yao, Ray Wainman, Richa Banker, Marek Siarkowicz, Siyuan Zhang, Jeffrey Ying, Henry Wu, Yuchen Zhou, Jordan Liggitt, Benjamin Elder, Antonio Ojea, Yongrui Lin, Joe Betz, Aaron Prindle and the Googlers who helped bring 1.33 to GKE!

- Benjamin Elder & Sen Lu, Google Kubernetes Engine

GSoC 2025: We have our Contributors!

Google Summer of Code logo. A simplistic sun made of 2 orange square on top of each other, one rotated. In the middle is the XML opening and closing brackets in white

Congratulations to the 1272 Contributors from 68 countries accepted for GSoC 2025! Our 185 Mentoring Orgs have been very busy this past month - reviewing 23,559 proposals, having countless discussions with applicants, and finally, completing the rigorous selection process to find the right Contributors for their community.

Here are some highlights of the 2025 GSoC applicants:

  • 15,240 applicants from 130 countries submitting 23,559 proposals
  • Over 2,350 mentors and organization administrators
  • 66.3% of applicants have no prior open source experience

Now that the 2025 GSoC Contributors have been announced, the Organizations and Contributors will be spending 3 weeks together in the Community Bonding period. This time is a very important part of the GSoC program. Designed to get new contributors quickly up to speed, Mentors will use the next three weeks to introduce GSoC Contributors to their community, helping them understand the codebase and norms of their project, adjusting deliverables for the project and understanding the impact and reach of their summer project.

Contributors will begin writing code for Organizations on June 2nd - the official beginning of a totally new adventure! We're absolutely delighted to kick off another year alongside our amazing community.

A huge thanks to all the enthusiastic applicants who participated and, of course, to our phenomenal volunteer Mentors and Organization Administrators. Your weeks of thoughtful proposal reviews and proactive engagement with participants have been invaluable in introducing them to the world of open source.

And congratulations once again to our 2025 GSoC Contributors! Our goal is that GSoC serves as the catalyst for Contributors to become long term participants (and maybe even maintainers!) of open source communities of every shape and size. Now is their chance to dive in and learn more about open source and connect with these amazing communities.


Stephanie Taylor, Mary Radomile and Lucila Ortiz, Google Open Source

Get ready for Google I/O: Program lineup revealed

The Google I/O agenda is live. We're excited to share Google’s biggest announcements across AI, Android, Web, and Cloud May 20-21. Tune in to learn how we’re making development easier so you can build faster.

We'll kick things off with the Google Keynote at 10:00 AM PT on May 20th, followed by the Developer Keynote at 1:30 PM PT. This year, we're livestreaming two days of sessions directly from Mountain View, bringing more of the I/O experience to you, wherever you are.

Here’s a sneak peek of what we’ll cover:

    • AI advancements: Learn how Gemini models enable you to build new applications and unlock new levels of productivity. Explore the flexibility offered by options like our Gemma open models and on-device capabilities.
    • Build excellent apps, across devices with Android: Crafting exceptional app experiences across devices is now even easier with Android. Dive into sessions focused on building intelligent apps with Google AI and boosting your productivity, alongside creating adaptive user experiences and leveraging the power of Google Play.
    • Powerful web, made easier: Exciting new features continue to accelerate web development, helping you to build richer, more reliable web experiences. We’ll share the latest innovations in web UI, Baseline progress, new multimodal built-in AI APIs using Gemini Nano, and how AI in DevTools streamline building innovative web experiences.

Plan your I/O

Join us online for livestreams May 20-21, followed by on-demand sessions and codelabs on May 22. Register today and explore the full program for sessions like these:

We're excited to share what's next and see what you build!

By the Google I/O team

Get ready for Google I/O: Program lineup revealed

The Google I/O agenda is live. We're excited to share Google’s biggest announcements across AI, Android, Web, and Cloud May 20-21. Tune in to learn how we’re making development easier so you can build faster.

We'll kick things off with the Google Keynote at 10:00 AM PT on May 20th, followed by the Developer Keynote at 1:30 PM PT. This year, we're livestreaming two days of sessions directly from Mountain View, bringing more of the I/O experience to you, wherever you are.

Here’s a sneak peek of what we’ll cover:

    • AI advancements: Learn how Gemini models enable you to build new applications and unlock new levels of productivity. Explore the flexibility offered by options like our Gemma open models and on-device capabilities.
    • Build excellent apps, across devices with Android: Crafting exceptional app experiences across devices is now even easier with Android. Dive into sessions focused on building intelligent apps with Google AI and boosting your productivity, alongside creating adaptive user experiences and leveraging the power of Google Play.
    • Powerful web, made easier: Exciting new features continue to accelerate web development, helping you to build richer, more reliable web experiences. We’ll share the latest innovations in web UI, Baseline progress, new multimodal built-in AI APIs using Gemini Nano, and how AI in DevTools streamline building innovative web experiences.

Plan your I/O

Join us online for livestreams May 20-21, followed by on-demand sessions and codelabs on May 22. Register today and explore the full program for sessions like these:

We're excited to share what's next and see what you build!

By the Google I/O team