Georgia Street View imagery is now available on Google Maps.
Street View opens a new window into Georgia
Georgia Street View imagery is now available on Google Maps.
Georgia Street View imagery is now available on Google Maps.
Google Workspace Weekly Recap – June 19, 2026
New discoverable space setting in Google Chat
Previously, spaces were either private (invite-only) or open (anyone in the organization can find and join). Discoverable spaces provide a new option between the two: they appear when users browse for spaces within their organization, but the conversation history and messages remain private until an owner or manager approves a user's request to join. | Learn more.
Carrier Link for Google Voice
Carrier Link allows Workspace customers to easily add phone numbers and calling plans from a certified local carrier, leveraging a pre-configured multi-tenant implementation of SIP Link. | Learn more.
AI note-taking is now available in Google Voice
This powerful new feature records and transcribes calls, summarizes key points, and organizes action items, which are sent via Gmail and stored in the Voice app. | Learn more.
Gemini in Chrome expands to more languages and regions, including Latin America, Africa, and the Middle East
Many of Chrome's latest AI features are rolling out to users in Latin America, Africa, the Middle East, and more. | Learn more.
Control whether your users can have temporary chats and delete conversations in the Gemini app
We’re introducing two new administrator controls for the Gemini app (gemini.google.com) that allow end users to manage their own chat activity. Admins can now configure whether users can use temporary chats and delete their conversation history. | Learn more.
Create longer Veo videos and generate multiple at once in Google Vids
These updates provide all Vids users with the ability to create longer videos with consistent characters and generate multiple videos in parallel, enabling you to bring your vision to life faster than ever before. | Learn more.
Enhanced AI avatar features and capabilities in Google Vids
We’re excited to announce expanded language support, a new collection of avatar defaults, and the ability to direct your custom avatars to take action in any generated video. | Learn more.
Custom event colors in Google Calendar
Going forward, users are offered an expanded color palette so they can personalize events and visually organize their calendar with ease, giving each user access to up to 200 custom colors for individual events via both the native web and mobile apps as well as the Calendar API. | Learn more.
Make Gemini more helpful and relevant to your teaching goals with the Google Classroom app in Gemini
Educators have shared that AI is especially helpful when it understands the context of their teaching environment, from tailoring resources toward student needs or building on their existing materials. To support this, Gemini will be able to collaborate with your Google Classroom, using context from your classes to inform its outputs or help complete tasks. | Learn more.
Improved management of secondary calendars via the Calendar API
We’re introducing two enhancements to the Calendar API that make it easier for admins to programmatically manage secondary calendars within their organization: a transfer API and a filter for secondary calendars owned by your organization. | Learn more.
Google Meet now available on Android Auto
We’re bringing the power of Google Meet to your vehicle's display with our new integration for Android Auto. This update makes it easy to safely stay connected and handle important meetings hands-free from behind the wheel. | Learn more.
Expanded language support for building and editing spreadsheets with Gemini
We’re now expanding support for these features to 28 additional languages, enabling users who speak Spanish, Portuguese, Japanese, Korean, Italian, French, German, Chinese Simplified, Dutch, Hebrew, Polish, Turkish, Czech, Indonesian, Malay, Swedish, Danish, Norwegian, Arabic, Finnish, Vietnamese, Ukrainian, Greek, Thai, Romanian, Russian, Catalan, and Hungarian to collaborate natively with Gemini in their preferred language. | Learn more.
The announcements above were published on the Workspace Updates blog over the last week. Please refer to the original blog posts for complete details.
Source: Google Workspace Updates
How A2A is Building a World of Collaborative Agents
Celebrating the first anniversary of the Agent-to-Agent (A2A) protocol, this blog post highlights how the framework enables autonomous AI agents to securely collaborate and hand off tasks without the rigidity of traditional APIs. By delegating complex workflows to specialized peer agents, A2A prevents context pollution, ensures data privacy, and simplifies application design through modularity. To demonstrate this ecosystem in action, the post spotlights FoldRun—an agentic interface for life sciences that orchestrates complex protein structure predictions—alongside diverse A2A use cases spanning commerce, data streaming, DevOps, and telecommunications.
Source: Google Developers Blog
In-place pod restarts: Boosting efficiency and workload reliability in Kubernetes v1.35
Operational efficiency and system resilience are critical when running scaled platforms. Yet, in Kubernetes, recovering from software crashes remains a headache because you couldn't trigger a clean restart of a Pod's containers without recreating the entire Pod object, leading to some amount of resource waste.
To address this, Restart All Containers on Container Exits graduated to beta and is enabled by default in Kubernetes v1.36. Developed in close collaboration with the CNCF community, this capability represents Google's commitment to investing in the success of foundation-led open source projects. By sharing best practices from running large distributed systems internally, we are helping build a more resilient and efficient ecosystem. Letting containers restart while keeping the Pod's runtime identity provides a built-in way to perform in-place Pod recovery, boosting application reliability and saving resource costs.
The Problem: The High Cost of Pod Re-creation
Historically, Kubernetes managed failures using pod level restart policies. While sufficient for simple services, modern multi-container Pods often have complex dependencies. When a failure requires a full environment reset, your only option was deleting and recreating the entire Pod.
This introduces massive control plane churn, causing latency and pressure on the etcd backend during large failures:
- Initialization Dependencies: If a main container corrupts a local environment, for example, single-use secrets that must be re-requested, restarting just that container is insufficient; the setup must run again.
- Watcher Interoperability: If a watcher sidecar detects a fatal error, it must trigger a full recreate of the entire pod and its infrastructure, including the sandbox.
- Stale States: If a database sidecar proxy restarts, the main application can get stuck attempting to use stale, broken connections.
- Resource Race Conditions: When a large job finds a proper set of nodes, recreating Pods can lead to other pending Pods taking over those resources. In-place restarts eliminate this race condition risk.
Previously, resolving these failures required destroying the entire Pod. For large batch or AI/ML workloads, where thousands of Pods might fail simultaneously, this can lead to "Thundering Herd" scheduling requests, delaying recovery and wasting expensive GPU/TPU compute time.
Introducing In-Place Restarts: The RestartAllContainers Action
Kubernetes v1.35 introduces the RestartAllContainers action, enabled by the RestartAllContainersOnContainerExits feature gate, which graduated to beta in 1.36 alongside its dependencies ContainerRestartRules and NodeDeclaredFeatures. This lets a container's exit behavior trigger a fast, in-place restart of the entire Pod on its existing node.
The Kubelet halts all containers while keeping the Pod sandbox intact, preserving critical infrastructure:
- Network Identity: Keeps the same IP, network namespace, and UID, completely bypassing IP reassignment.
- Hardware and Devices: Keeps GPUs/TPUs bound, eliminating scheduling and re-allocation delays.
- Storage Mounts: Volumes, including
emptyDirand PVCs, remain fully mounted; their content is not cleared during restarts.
Once terminated, the Kubelet re-runs init containers (including sidecars, which are part of the init sequence) in order, guaranteeing a clean setup in a known-good environment.
A Native Pod Specification Example
You can implement this under the container's restartPolicyRules field. Here is a quick example of how a watcher sidecar can trigger an in-place restart of the entire Pod by exiting with code 88:
YAML
Note: Image names and paths in the YAML below are for illustrative purposes.
apiVersion: v1
kind: Pod
metadata:
name: ml-worker-pod
spec:
restartPolicy: Never
initContainers:
- name: setup-environment
image: registry.k8s.io/ml-tools/setup-worker:v1.0
- name: watcher-sidecar
image: registry.k8s.io/ml-tools/watcher:v1.0
restartPolicy: Always
restartPolicyRules:
- action: RestartAllContainers
exitCodes:
operator: In
values: [88]
containers:
- name: main-application
image: registry.k8s.io/ml-tools/training-app:v1.0The Operational Impact of In-Place Restarts
For organizations running distributed workloads, RestartAllContainers provides serious operational advantages:
- No Control Plane Overhead: By preserving identity, clusters avoid scheduling latency and DNS propagation. This was a key factor for JobSet using this feature to reduce recovery from minutes to seconds.
- Node Locality Preservation: Since the Pod stays anchored to the same node, restarted containers can instantly access local, warm storage caches.
- Maximized Hardware Efficiency: In distributed AI training, losing a single node halts the entire job. Keeping accelerators like GPUs/TPUs bound lets workloads resume training significantly faster, directly reducing compute costs.
Observability and SRE Best Practices
To support monitoring, Kubernetes v1.35 introduces the AllContainersRestarting Pod condition. Set to True during restarts, it alerts SREs and autoscalers, preventing false-positive alerts, while container restart counts increment to let Prometheus easily track recovery events.
To use in-place restarts successfully, shift your mental model to "persistent sandboxes" and follow three best practices:
- Ensure Reentrancy: Kubelet only guarantees "at least once" execution for init containers. Reentrancy is now a standard requirement, so your code must be fully idempotent.
- Plan for Termination Handling: Graceful termination (
preStophooks) is not supported for in-place restarts. SIGKILL is almost immediate, so applications must handle sudden exits gracefully. - Prepare External Tooling: CD and observability tools should expect re-running init containers without interpreting them as new deployments.
What's Next?
This beta capability is a major step toward fluid workload management and serves as a building block for advanced community features like JobSet in-place restarts (KEP-467).
Our work on KEP-5532 reflects our commitment to transparent open source governance. Developed collaboratively within SIG Node, this feature shows how we hold ourselves to high citizenship standards; making our design, goals, and intentions transparent while building shared best practices that benefit everyone. We encourage you to experiment with Kubernetes v1.35 and share your feedback with the community!
Learn More
- Read the Kubernetes Pod Lifecycle Documentation.
- Explore KEP-5532: Restart All Containers on Container Exits.
- Review theKubernetes v1.35: Restart All Containers Blog Post.
- Join the SIG Node Community on Slack (#sig-node).