Description

I would like to contribute to mcp-server-uyuni, the MCP server for Uyuni / Multi-Linux Manager) exposing additional features as tools. There is lots of relevant features to be found throughout the API, for example:

System operations and infos
System groups
Maintenance windows
Ansible
Reporting
...

At the end of the week I managed to enable basic system group operations:

List all system groups visible to the user
Create new system groups
List systems assigned to a group
Add and remove systems from groups

Goals

Set up test environment locally with the MCP server and client + a recent MLM server [DONE]
Identify features and use cases offering a benefit with limited effort required for enablement [DONE]
Create a PR to the repo [DONE]

Resources

Join this project Leave this project

Looking for hackers with the skills:

mcpserver ai uyuni mcp agenticai

This project is part of:

Hack Week 25

Activity

about 2 months ago: j_renner added keyword "mcp" to this project.

about 2 months ago: j_renner added keyword "agenticai" to this project.

about 2 months ago: j_renner started this project.

2 months ago: j_renner added keyword "mcpserver" to this project.

2 months ago: j_renner added keyword "ai" to this project.

2 months ago: j_renner added keyword "uyuni" to this project.

2 months ago: j_renner originated this project.

Comments

Be the first to comment!

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Description

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[x] Basic MCP API setup
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Resources

Gemini CLI setup:

~/.gemini/settings.json:

SUSE Observability MCP server by drutigliano

Description

The idea is to implement the SUSE Observability Model Context Protocol (MCP) Server as a specialized, middle-tier API designed to translate the complex, high-cardinality observability data from StackState (topology, metrics, and events) into highly structured, contextually rich, and LLM-ready snippets.

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Hackweek STEP

Create a functional MCP endpoint exposing one (or more) tool(s) to answer queries like "What is the health of service X?") by fetching, normalizing, and returning live StackState data in an LLM-ready format.

Scope

Implement read-only MCP server that can:
- Connect to a live SUSE Observability instance and authenticate (with API token)
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Deliverables

MCP Server v0.1 A running Golang MCP server with at least one tool.
A README.md and a test script (e.g., curl commands or a simple notebook) showing how an AI agent would call the endpoint and the resulting JSON payload.

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Resources

https://www.honeycomb.io/blog/its-the-end-of-observability-as-we-know-it-and-i-feel-fine
https://www.datadoghq.com/blog/datadog-remote-mcp-server
https://modelcontextprotocol.io/specification/2025-06-18/index
https://modelcontextprotocol.io/docs/develop/build-server

Basic implementation

https://github.com/drutigliano19/suse-observability-mcp-server

Results

Successfully developed and delivered a fully functional SUSE Observability MCP Server that bridges language models with SUSE Observability's operational data. This project demonstrates how AI agents can perform intelligent troubleshooting and root cause analysis using structured access to real-time infrastructure data.

Example execution

ai

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Description

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Goals

Familiarize myself with MCPs
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https://hackweek.opensuse.org/25/projects/suse-edge-image-builder-json-schema
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Liz - Prompt autocomplete by ftorchia

Description

Liz is the Rancher AI assistant for cluster operations.

Goals

We want to help users when sending new messages to Liz, by adding an autocomplete feature to complete their requests based on the context.

Example:

User prompt: "Can you show me the list of p"
Autocomplete suggestion: "Can you show me the list of p...od in local cluster?"

Example:

User prompt: "Show me the logs of #rancher-"
Chat console: It shows a drop-down widget, next to the # character, with the list of available pod names starting with "rancher-".

Technical Overview

The AI agent should expose a new ws/autocomplete endpoint to proxy autocomplete messages to the LLM.
The UI extension should be able to display prompt suggestions and allow users to apply the autocomplete to the Prompt via keyboard shortcuts.

Resources

GitHub repository

The Agentic Rancher Experiment: Do Androids Dream of Electric Cattle? by moio

Rancher is a beast of a codebase. Let's investigate if the new 2025 generation of GitHub Autonomous Coding Agents and Copilot Workspaces can actually tame it.

The Plan

Create a sandbox GitHub Organization, clone in key Rancher repositories, and let the AI loose to see if it can handle real-world enterprise OSS maintenance - or if it just hallucinates new breeds of Kubernetes resources!

Specifically, throw "Agentic Coders" some typical tasks in a complex, long-lived open-source project, such as:

❥ The Grunt Work: generate missing GoDocs, unit tests, and refactorings. Rebase PRs.

❥ The Complex Stuff: fix actual (historical) bugs and feature requests to see if they can traverse the complexity without (too much) human hand-holding.

❥ Hunting Down Gaps: find areas lacking in docs, areas of improvement in code, dependency bumps, and so on.

If time allows, also experiment with Model Context Protocol (MCP) to give agents context on our specific build pipelines and CI/CD logs.

Why?

We know AI can write "Hello World." and also moderately complex programs from a green field. But can it rebase a 3-month-old PR with conflicts in rancher/rancher? I want to find the breaking point of current AI agents to determine if and how they can help us to reduce our technical debt, work faster and better. At the same time, find out about pitfalls and shortcomings.

The CONCLUSION!!!

A State of the Union document was compiled to summarize lessons learned this week. For more gory details, just read on the diary below!

MCP Trace Suite by r1chard-lyu

Description

This project plans to create an MCP Trace Suite, a system that consolidates commonly used Linux debugging tools such as bpftrace, perf, and ftrace.

The suite is implemented as an MCP Server. This architecture allows an AI agent to leverage the server to diagnose Linux issues and perform targeted system debugging by remotely executing and retrieving tracing data from these powerful tools.

Repo: https://github.com/r1chard-lyu/systracesuite
Demo: Slides

Goals

Build an MCP Server that can integrate various Linux debugging and tracing tools, including bpftrace, perf, ftrace, strace, and others, with support for future expansion of additional tools.
Perform testing by intentionally creating bugs or issues that impact system performance, allowing an AI agent to analyze the root cause and identify the underlying problem.

Resources

Gemini CLI: https://geminicli.com/
eBPF: https://ebpf.io/
bpftrace: https://github.com/bpftrace/bpftrace/
perf: https://perfwiki.github.io/main/
ftrace: https://github.com/r1chard-lyu/tracium/

Uyuni Health-check Grafana AI Troubleshooter by ygutierrez

Description

This project explores the feasibility of using the open-source Grafana LLM plugin to enhance the Uyuni Health-check tool with LLM capabilities. The idea is to integrate a chat-based "AI Troubleshooter" directly into existing dashboards, allowing users to ask natural-language questions about errors, anomalies, or performance issues.

Goals

Investigate if and how the grafana-llm-app plug-in can be used within the Uyuni Health-check tool.
Investigate if this plug-in can be used to query LLMs for troubleshooting scenarios.
Evaluate support for local LLMs and external APIs through the plugin.
Evaluate if and how the Uyuni MCP server could be integrated as another source of information.

Resources

Grafana LMM plug-in

Uyuni Health-check

uyuni

Enhance setup wizard for Uyuni by PSuarezHernandez

Description

This project wants to enhance the intial setup on Uyuni after its installation, so it's easier for a user to start using with it.

Uyuni currently uses "uyuni-tools" (mgradm) as the installation entrypoint, to trigger the installation of Uyuni in the given host, but does not really perform an initial setup, for instance:

user creation
adding products / channels
generating bootstrap repos
create activation keys
...

Goals

Provide initial setup wizard as part of mgradm uyuni installation

Resources

Flaky Tests AI Finder for Uyuni and MLM Test Suites by oscar-barrios

Description

Our current Grafana dashboards provide a great overview of test suite health, including a panel for "Top failed tests." However, identifying which of these failures are due to legitimate bugs versus intermittent "flaky tests" is a manual, time-consuming process. These flaky tests erode trust in our test suites and slow down development.

This project aims to build a simple but powerful Python script that automates flaky test detection. The script will directly query our Prometheus instance for the historical data of each failed test, using the jenkins_build_test_case_failure_age metric. It will then format this data and send it to the Gemini API with a carefully crafted prompt, asking it to identify which tests show a flaky pattern.

The final output will be a clean JSON list of the most probable flaky tests, which can then be used to populate a new "Top Flaky Tests" panel in our existing Grafana test suite dashboard.

Goals

By the end of Hack Week, we aim to have a single, working Python script that:

Connects to Prometheus and executes a query to fetch detailed test failure history.
Processes the raw data into a format suitable for the Gemini API.
Successfully calls the Gemini API with the data and a clear prompt.
Parses the AI's response to extract a simple list of flaky tests.
Saves the list to a JSON file that can be displayed in Grafana.
New panel in our Dashboard listing the Flaky tests

Resources

Jenkins Prometheus Exporter: https://github.com/uyuni-project/jenkins-exporter/
Data Source: Our internal Prometheus server.
Key Metric: jenkins_build_test_case_failure_age{jobname, buildid, suite, case, status, failedsince}.
Existing Query for Reference: count by (suite) (max_over_time(jenkins_build_test_case_failure_age{status=~"FAILED|REGRESSION", jobname="$jobname"}[$__range])).
AI Model: The Google Gemini API.
Example about how to interact with Gemini API: https://github.com/srbarrios/FailTale/
Visualization: Our internal Grafana Dashboard.
Internal IaC: https://gitlab.suse.de/galaxy/infrastructure/-/tree/master/srv/salt/monitoring

Outcome

Uyuni read-only replica by cbosdonnat

Description

For now, there is no possible HA setup for Uyuni. The idea is to explore setting up a read-only shadow instance of an Uyuni and make it as useful as possible.

Possible things to look at:

live sync of the database, probably using the WAL. Some of the tables may have to be skipped or some features disabled on the RO instance (taskomatic, PXT sessions…)
Can we use a load balancer that routes read-only queries to either instance and the other to the RW one? For example, packages or PXE data can be served by both, the API GET requests too. The rest would be RW.

Goals

Prepare a document explaining how to do it.
PR with the needed code changes to support it

Set Uyuni to manage edge clusters at scale by RDiasMateus

Description

Prepare a Poc on how to use MLM to manage edge clusters. Those cluster are normally equal across each location, and we have a large number of them.

The goal is to produce a set of sets/best practices/scripts to help users manage this kind of setup.

Goals

step 1: Manual set-up

Goal: Have a running application in k3s and be able to update it using System Update Controler (SUC)

Deploy Micro 6.2 machine
Deploy k3s - single node
- https://docs.k3s.io/quick-start
Build/find a simple web application (static page)
- Build/find a helmchart to deploy the application
Deploy the application on the k3s cluster
Install App updates through helm update
Install OS updates using MLM

step 2: Automate day 1

Goal: Trigger the application deployment and update from MLM

Salt states For application (with static data)
- Deploy the application helmchart, if not present
- install app updates through helmchart parameters
Link it to GIT
- Define how to link the state to the machines (based in some pillar data? Using configuration channels by importing the state? Naming convention?)
- Use git update to trigger helmchart app update
Recurrent state applying configuration channel?

step 3: Multi-node cluster

Goal: Use SUC to update a multi-node cluster.

Create a multi-node cluster
Deploy application
- call the helm update/install only on control plane?
Install App updates through helm update
Prepare a SUC for OS update (k3s also? How?)
- https://github.com/rancher/system-upgrade-controller
- https://documentation.suse.com/cloudnative/k3s/latest/en/upgrades/automated.html
- Update/deploy the SUC?
- Update/deploy the SUC CRD with the update procedure

Set Up an Ephemeral Uyuni Instance by mbussolotto

Description

To test, check, and verify the latest changes in the master branch, we want to easily set up an ephemeral environment.

Goals

Create an ephemeral environment manually
Create an ephemeral environment automatically

Resources
https://github.com/uyuni-project/uyuni
https://www.uyuni-project.org/uyuni-docs/en/uyuni/index.html

mcp

SUSE Observability MCP server by drutigliano

Description

Goals

Grounding AI Responses: Ensure that all AI diagnoses, root cause analyses, and action recommendations are strictly based on verifiable, real-time data retrieved from the SUSE Observability StackState platform.
Simplifying Data Access: Abstract the complexity of StackState's native APIs (e.g., Time Travel, 4T Data Model) into simple, semantic functions that can be easily invoked by LLM tool-calling mechanisms.
Data Normalization: Convert complex, technical identifiers (like component URNs, raw metric names, and proprietary health states) into standardized, natural language terms that an LLM can easily reason over.
Enabling Automated Remediation: Define clear, action-oriented MCP endpoints (e.g., execute_runbook) that allow the AI agent to initiate automated operational workflows (e.g., restarts, scaling) after a diagnosis, closing the loop on observability.

Hackweek STEP

Create a functional MCP endpoint exposing one (or more) tool(s) to answer queries like "What is the health of service X?") by fetching, normalizing, and returning live StackState data in an LLM-ready format.

Scope

Implement read-only MCP server that can:
- Connect to a live SUSE Observability instance and authenticate (with API token)
- Use tools to fetch data for a specific component URN (e.g., current health state, metrics, possibly topology neighbors, ...).
- Normalize response fields (e.g., URN to "Service Name," health state DEVIATING to "Unhealthy", raw metrics).
- Return the data as a structured JSON payload compliant with the MCP specification.

Deliverables

MCP Server v0.1 A running Golang MCP server with at least one tool.
A README.md and a test script (e.g., curl commands or a simple notebook) showing how an AI agent would call the endpoint and the resulting JSON payload.

Resources

https://www.honeycomb.io/blog/its-the-end-of-observability-as-we-know-it-and-i-feel-fine
https://www.datadoghq.com/blog/datadog-remote-mcp-server
https://modelcontextprotocol.io/specification/2025-06-18/index
https://modelcontextprotocol.io/docs/develop/build-server

Basic implementation

https://github.com/drutigliano19/suse-observability-mcp-server

Results

Example execution

Try to use AI and MCP for ACPI table analysis by joeyli

Description

Try to use AI and MCP if they can help with ACPI table analysis.

Goals

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Resources

Any resources about AI and MCP.

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Description

This project plans to create an MCP Trace Suite, a system that consolidates commonly used Linux debugging tools such as bpftrace, perf, and ftrace.

Repo: https://github.com/r1chard-lyu/systracesuite
Demo: Slides

Goals

Build an MCP Server that can integrate various Linux debugging and tracing tools, including bpftrace, perf, ftrace, strace, and others, with support for future expansion of additional tools.
Perform testing by intentionally creating bugs or issues that impact system performance, allowing an AI agent to analyze the root cause and identify the underlying problem.

Resources

Gemini CLI: https://geminicli.com/
eBPF: https://ebpf.io/
bpftrace: https://github.com/bpftrace/bpftrace/
perf: https://perfwiki.github.io/main/
ftrace: https://github.com/r1chard-lyu/tracium/

Docs Navigator MCP: SUSE Edition by mackenzie.techdocs

Description

Docs Navigator MCP: SUSE Edition is an AI-powered documentation navigator that makes finding information across SUSE, Rancher, K3s, and RKE2 documentation effortless. Built as a Model Context Protocol (MCP) server, it enables semantic search, intelligent Q&A, and documentation summarization using 100% open-source AI models (no API keys required!). The project also allows you to bring your own keys from Anthropic and Open AI for parallel processing.

Goals

[ X ] Build functional MCP server with documentation tools
[ X ] Implement semantic search with vector embeddings
[ X ] Create user-friendly web interface
[ X ] Optimize indexing performance (parallel processing)
[ X ] Add SUSE branding and polish UX
[ X ] Stretch Goal: Add more documentation sources
[ X ] Stretch Goal: Implement document change detection for auto-updates

Coming Soon!

Community Feedback: Test with real users and gather improvement suggestions

Resources

Repository: Docs Navigator MCP: SUSE Edition GitHub
UI Demo: Live UI Demo of Docs Navigator MCP: SUSE Edition

Bugzilla goes AI - Phase 1 by nwalter

Description

Goals

To reduce employee time spent on Bugzilla by implementing an AI tool that triages and summarizes bug reports, providing actionable recommendations to the team via Web Interface.

Project Charter

Bugzilla goes AI Phase 1

Description

Project Achievements during Hackweek

In this file you can read about what we achieved during Hackweek.

Project Achievements

agenticai

The Agentic Rancher Experiment: Do Androids Dream of Electric Cattle? by moio

Rancher is a beast of a codebase. Let's investigate if the new 2025 generation of GitHub Autonomous Coding Agents and Copilot Workspaces can actually tame it.

The Plan

Specifically, throw "Agentic Coders" some typical tasks in a complex, long-lived open-source project, such as:

❥ The Grunt Work: generate missing GoDocs, unit tests, and refactorings. Rebase PRs.

❥ The Complex Stuff: fix actual (historical) bugs and feature requests to see if they can traverse the complexity without (too much) human hand-holding.

❥ Hunting Down Gaps: find areas lacking in docs, areas of improvement in code, dependency bumps, and so on.

If time allows, also experiment with Model Context Protocol (MCP) to give agents context on our specific build pipelines and CI/CD logs.

Why?

The CONCLUSION!!!

A State of the Union document was compiled to summarize lessons learned this week. For more gory details, just read on the diary below!

SUSE Observability MCP server by drutigliano

Description

Goals

Grounding AI Responses: Ensure that all AI diagnoses, root cause analyses, and action recommendations are strictly based on verifiable, real-time data retrieved from the SUSE Observability StackState platform.
Simplifying Data Access: Abstract the complexity of StackState's native APIs (e.g., Time Travel, 4T Data Model) into simple, semantic functions that can be easily invoked by LLM tool-calling mechanisms.
Data Normalization: Convert complex, technical identifiers (like component URNs, raw metric names, and proprietary health states) into standardized, natural language terms that an LLM can easily reason over.
Enabling Automated Remediation: Define clear, action-oriented MCP endpoints (e.g., execute_runbook) that allow the AI agent to initiate automated operational workflows (e.g., restarts, scaling) after a diagnosis, closing the loop on observability.

Hackweek STEP

Create a functional MCP endpoint exposing one (or more) tool(s) to answer queries like "What is the health of service X?") by fetching, normalizing, and returning live StackState data in an LLM-ready format.

Scope

Implement read-only MCP server that can:
- Connect to a live SUSE Observability instance and authenticate (with API token)
- Use tools to fetch data for a specific component URN (e.g., current health state, metrics, possibly topology neighbors, ...).
- Normalize response fields (e.g., URN to "Service Name," health state DEVIATING to "Unhealthy", raw metrics).
- Return the data as a structured JSON payload compliant with the MCP specification.

Deliverables

MCP Server v0.1 A running Golang MCP server with at least one tool.
A README.md and a test script (e.g., curl commands or a simple notebook) showing how an AI agent would call the endpoint and the resulting JSON payload.

Resources

https://www.honeycomb.io/blog/its-the-end-of-observability-as-we-know-it-and-i-feel-fine
https://www.datadoghq.com/blog/datadog-remote-mcp-server
https://modelcontextprotocol.io/specification/2025-06-18/index
https://modelcontextprotocol.io/docs/develop/build-server

Basic implementation

https://github.com/drutigliano19/suse-observability-mcp-server