Chunking secrets for RAG Pipeline

If you’ve started exploring how to build AI applications with Large Language Models (LLMs), you’ve probably come across the term RAG — Retrieval-Augmented Generation. It sounds fancy, but here’s the simple idea:

LLMs (like GPT) are powerful, but they don’t “know” your private data. To give them accurate answers, you connect them to an external knowledge source (for example, a vector database) where your documents live. Before generating an answer, the system retrieves the most relevant information from that database.

This retrieval step is critical, and its quality directly affects your application’s performance. Many beginners focus on choosing the “right” vector database or embedding model. But one often-overlooked step is how you prepare your data before putting it into the database.

That’s where chunking comes in.

Think of chunking like cutting a long book into smaller sections. Instead of feeding an entire 500-page novel into your system, you break it into smaller pieces (called chunks) that are easier for an AI model to handle.

Why do this? Because LLMs have a context window — a limit on how much text they can “see” at once. If your input is too long, the model can miss important details. Chunking solves this by giving the model smaller, focused pieces that it can actually use to generate accurate answers.

Chunking isn’t just a convenience — it’s often the make-or-break factor in how well your RAG system works. Even the best retriever or database can fail if your data chunks are poorly prepared. Lets see why  as shown below 

1. Helping Retrieval

   • If a chunk is too large, it might mix multiple topics. This creates a fuzzy “average” representation that doesn’t clearly capture any single idea.

   • If a chunk is small and focused, the system creates precise embeddings that make retrieval much more accurate.

    Small, topic-focused chunks = better search results.

2. Helping Generation

   • Once the right chunks are retrieved, they go into the LLM. If they’re too small, they may not provide enough context (like reading one sentence from the middle of a paper).

   • If they’re too big, the model struggles with “attention dilution” — it has trouble focusing on the relevant part, especially in the middle of a long chunk.

    The goal is to find a sweet spot: chunks that are big enough to carry meaning but small enough to stay precise.

Benefits:

When you get chunking right, everything improves:

• Better Retrieval: The system quickly finds the most relevant passages.

• Better Context: The LLM has just enough information to answer clearly.

• Fewer Hallucinations: The model is grounded in real, factual data.

• Efficiency & Cost Savings: Smaller, smarter chunks reduce token usage and speed up responses.

---

Retrieval-Augmented Generation (RAG) is an AI technique that enhances the accuracy of responses by combining the power of search and generation. Instead of relying solely on the general knowledge of a language model, RAG systems retrieve relevant information from external data sources and use it to generate personalized, context-aware answers.

Improves factual accuracy by grounding responses in real data

Reduces hallucinations from LLMs

Supports personalization using your own documents or datasets

While RAG is powerful, building a functional system can be complex:

• Choosing the right models
• Structuring and indexing your data
• Designing the retrieval and generation pipeline

Tools like LangChain and LlamaIndex help prototype RAG systems, but they often require technical expertise. LangChain is an open-source framework for building applications powered by language models. It helps developers connect LLMs with external tools, memory, and data sources.

Let’s walk through the Retrieval-Augmented Generation (RAG) flow using your example question: “What is LangChain?”

RAG Flow Explained with Example

Step 1: User Asks a Question

You ask:
“What is LangChain?”

This question is passed to the RAG system.

Step 2: Retrieve Relevant Information

Instead of relying only on the language model’s internal memory, the system first retrieves documents from a vector database or knowledge base. These documents are semantically similar to your question.

For example, it might retrieve:

• LangChain documentation
• Blog posts about LangChain
• GitHub README files

Step 3: Generate a Response

The retrieved documents are then passed to a language model (like GPT or Claude). The model reads this context and generates a response based on both:

• Your original question
• The retrieved documents

Step 4: Final Answer

The system combines the retrieved knowledge and the model’s reasoning to produce a grounded, accurate answer:

“LangChain is an open-source framework for building applications powered by language models. It helps developers connect LLMs with external tools, memory, and data sources.”

Why This Is Better Than Just Using an LLM

• More accurate: Uses real, up-to-date data
• Less hallucination: Doesn’t guess when unsure
• Customizable: You can control what data is retrieved

--------------------------------

Chunking Strategies

There’s no one-size-fits-all approach, but here are two common strategies:

1. Pre-Chunking (Most Common)

• Documents are broken into chunks before being stored in the vector database.

• Pros: Fast retrieval, since everything is ready in advance.

• Cons: You must decide chunk size upfront, and you might chunk documents that never get used.

2. Post-Chunking (More Advanced)

• Entire documents are stored as embeddings, and chunking happens at query time, but only for the documents that are retrieved.

• Pros: Dynamic and flexible, chunks can be tailored to the query.

• Cons: Slower the first time you query a document, since chunking happens on the fly. (Caching helps over time.)

Chunking may sound like a small preprocessing step, but in practice, it’s one of the most critical factors in building high-performing RAG applications.

Think of it as context engineering: preparing your data so that your AI assistant always has the right amount of context to give the best possible answer.

If you’re just starting out, experiment with different chunk sizes and boundaries. Test whether your chunks “stand alone” and still make sense. Over time, you’ll find the balance that gives you the sweet spot between accuracy, efficiency, and reliability.

Designing Multi-Agent AI Systems for Developers and Enterprises

The rise of Agentic AI has opened up exciting possibilities beyond what a single large language model (LLM) can do. While an LLM can generate text or answer questions, it often struggles with coordination, memory, and execution of multi-step workflows. This is where multi-agent systems and orchestration frameworks come in.

Multi-Agent AI Systems are advanced frameworks where multiple AI agents work together—often autonomously—to solve complex tasks that would be difficult for a single agent to handle alone.

 Key Characteristics of Multi-Agent AI Systems

1. Distributed Intelligence
   Each agent has a specialized role (e.g., data retrieval, analysis, decision-making), contributing its expertise to the overall task.

2. Collaboration & Coordination
   Agents communicate and coordinate their actions, often using shared memory or messaging protocols to stay aligned.

3. Autonomy
   Agents operate independently, making decisions based on their goals, context, and available tools.

4. Tool Usage
   Agents can call external APIs, run code, or interact with databases to extend their capabilities.

5. Scalability
   These systems can be scaled horizontally by adding more agents to handle larger or more complex workflows.

 Two of the most talked-about approaches in this space today are CrewAI and IBM Watsonx Orchestrator. At first glance, both seem to manage multi-agent AI workflows—but their design philosophy, architecture, and use cases differ significantly.

CrewAI: CrewAI is designed like a virtual AI team, where each agent has a specific role and collaborates to complete complex tasks. It’s ideal for developers building modular, open-source agentic systems with flexibility in tool and model selection.

A Virtual AI Team for Developers

Think of CrewAI as building your own AI-powered virtual team. Each agent has a role, goal, and tools—just like a real-world team member. For example:

• A Research Agent might gather background data.

• A Reasoning Agent could analyze findings.

• A Writer Agent might prepare a final report.

These agents don’t work in isolation—they collaborate. The framework allows developers to design modular agentic systems, where agents exchange information, adapt to context, and make decisions collectively.

Key traits of CrewAI:

• Developer-focused: Open-source and flexible, ideal for POCs and innovation.

• Agent-centric design: You define roles, tools, and workflows.

• Plug-and-play: Works with different models and APIs, not locked into a vendor ecosystem.

• Best suited for: Startups, researchers, and developers experimenting with agent workflows.

Watsonx Orchestrator: 

Watson Orchestrator, on the other hand, is built for enterprise-grade orchestration, offering robust security, scalability, and integration with IBM’s cloud ecosystem. It follows a manager-worker architecture, where a central orchestrator dynamically routes tasks to specialized agents based on context.

Enterprise-Grade AI Workflow Management

On the other side of the spectrum is Watsonx Orchestrator, part of IBM’s Watsonx AI suite. It’s built not just to run AI agents, but to integrate AI into enterprise workflows.

Instead of thinking in terms of a “virtual team,” think of Watsonx Orchestrator as a manager-worker model:

• The orchestrator acts like a manager, dynamically assigning tasks.

• Specialized agents (workers) handle tasks such as RPA actions, LLM queries, or API calls.

• The orchestrator ensures compliance, scalability, and security—things enterprises care deeply about.

Key traits of Watsonx Orchestrator:

• Enterprise-first: Built for governance, compliance, and auditability.

• Manager-worker design: Central orchestrator routes tasks to the right worker agents.

• Deep integrations: Works seamlessly with IBM’s Watsonx.ai, Watsonx.data, cloud APIs, and ITSM tools.

• Best suited for: Enterprises automating business processes (e.g., IT ticketing, HR workflows, incident response).

  

In the Watsonx Orchestrator side of the diagram:

• Task A, Task B, Task C are not agents.

• They are steps in a workflow (things that need to be executed).

• Each task could call an agent, a script, an API, or a business system depending on what the workflow designer configured.

Example: Security Incident Workflow

• Trigger → A suspicious login attempt is detected.

• Task A → Verify if the login came from a trusted location (via API).

• Decision → If trusted, continue → If not trusted, branch out.

• Task B → Send MFA request (multi-factor authentication).

• Task C → Log incident in database + alert security team.

• Approval → Security lead approves final action.

Here, each task could internally use an AI agent (e.g., an anomaly detection agent), but in Orchestrator, they are modeled as workflow blocks rather than peer agents.

Conclusion: 

• CrewAI → Agents themselves are the actors (like teammates).

• Watsonx Orchestrator → Tasks are workflow steps; the orchestrator may call an agent (or a script/system) to complete a task.

 where  Tasks A/B/C are workflow steps, not standalone agents.

Design Philosophy: Team vs Manager

The core difference can be boiled down to philosophy:

• CrewAI is like building a team of AI colleagues that collaborate directly with each other. You design the playbook and give them the tools.

• Watsonx Orchestrator is like having a manager who assigns work to employees. It’s structured, secure, and optimized for reliability at scale.

While both platforms support multi-agent orchestration, CrewAI is more developer-friendly and open, whereas Watson Orchestrator is optimized for enterprise environments with built-in governance, scalability, and integration capabilities. They can even be used together—CrewAI for agent logic and Watson Orchestrator for deployment and workflow management.

AgentOps and Langfuse: Observability in the Age of Autonomous AI Agents

An AI agent is a system designed to autonomously perform tasks by planning its actions and using external tools when needed. These agents are powered by Large Language Models (LLMs), which help them understand user inputs, reason through problems step-by-step, and decide when to take action or call external services.

Trust by Design: The Architecture Behind Safe AI Agents

As AI agents become more powerful and autonomous, it’s critical to understand how they behave, make decisions, and interact with users. Tools like Langfuse, LangGraph, Llama Agents, Dify, Flowise, and Langflow are helping developers build smarter agents—but how do you monitor and debug them effectively? That’s where LLM observability platforms come in. Without observability, it’s like flying blind—you won’t know why your agent failed or how to improve it.

Introduction: Why Observability Matters in LLM-Driven Systems

LLMs and autonomous agents are increasingly used in production systems. Their non-deterministic behavior, multi-step reasoning, and external tool usage make debugging and monitoring complex. Observability platforms like AgentOps and Langfuse aim to bring transparency and control to these systems.

AgentOps :

AgentOps (Agent Operations) is an emerging discipline focused on managing the lifecycle of autonomous AI agents. It draws inspiration from DevOps and MLOps but adapts to the unique challenges of agentic systems:

Key Concepts:

1. Lifecycle Management: From development to deployment and monitoring.
2. Session Tracing: Replay agent runs to understand decisions and tool usage.
3. Multi-Agent Orchestration: Supports frameworks like LangChain, AutoGen, and CrewAI.
4. OpenTelemetry Integration: Enables standardized instrumentation and analytics.
5. Governance & Compliance: Helps align agent behavior with ethical and regulatory standards -https://www.ibm.com/think/topics/agentops

Use Case Example: 

• An AI agent handling customer support
• Monitor emails
• Query a knowledge base
• Create support tickets autonomously
• AgentOps helps trace each step, monitor latency, and optimize cost across LLM providers.

CASE 1: Debugging and Edge Case Detection

AI agents often perform multi-step reasoning. A small error in one step can cause the entire task to fail. Langfuse helps you:

- Trace intermediate steps

- Identify failure points

- Add edge cases to test datasets

- Benchmark new versions before deployment

CASE 2: Balancing Accuracy and Cost

LLMs are probabilistic—they can hallucinate or produce inconsistent results. To improve accuracy, agents may call the model multiple times or use external APIs. This increases cost.

- Track how many calls are made

- Monitor token usage and API costs

- Optimize for both **accuracy and efficiency**

CASE 3: Understanding User Interactions

Langfuse captures how users interact with your AI system, helping you:

- Analyze user feedback

- Score responses over time

- Break down metrics by user, session, geography, or model version

This is essential for improving user experience and tailoring responses.

 Langfuse:

Langfuse (GitHub) is an open-source LLM engineering platform that helps teams collaboratively debug, analyze, and iterate on their LLM applications via tracing, prompt management and evaluations.

Langfuse is an open-source observability platform purpose-built for LLM applications. It provides deep tracing and analytics for every interaction between your app and LLMs. Langfuse integrates with popular frameworks like LangChain, LlamaIndex, and OpenAI, and supports both prompt-level and session-level tracing.

Core Features:

1. Trace Everything: Inputs, outputs, retries, latencies, costs, and errors.
2. Multi-Modal & Multi-Model Support: Works with text, images, audio, and major LLM providers.
3. Framework Agnostic: Integrates with LangChain, OpenAI, LlamaIndex, etc.
4. Advanced Analytics: Token usage, cost tracking, agent graphs, and session metadata[2](https://langfuse.com/docs/observability/overview).

Why Langfuse?

1. Open source and incrementally adoptable
2. Built for production-grade LLM workflows
3. Enables debugging, cost optimization, and compliance tracking

AgentOps vs Langfuse:

While Langfuse focuses on observability, AgentOps is a broader concept that includes:

1. Lifecycle management of AI agents
2. Multi-agent orchestration
3. Governance and compliance
4. OpenTelemetry integration

Best Practices for LLM Observability

1. Traceability: Capture every step in the LLM pipeline.
2. Cost & Latency Monitoring: Identify expensive or slow prompts.
3. Error Analysis: Detect hallucinations and edge-case failures.
4. Compliance & Governance: Maintain audit trails for regulated environments.
5. Continuous Evaluation: Use evals and scoring to benchmark performance (https://www.tredence.com/blog/llm-observability).

How to Integrate above Tools in Your Workflow

1. Use Langfuse to trace LLM-based agents and log failures into Elastic/Kibana dashboards.
2. Apply AgentOps for multi-agent orchestration and lifecycle monitoring.
3. Create automated test cases to validate agent behavior across sessions.
4. Open defects in Bugzilla based on trace anomalies and integrate with Jira for task tracking.

Conclusion: 

As AI agents become more autonomous and complex, observability is essential for building trust and ensuring reliability at scale. Platforms like Langfuse and AgentOps complement each other by offering deep tracing, real-time monitoring, and lifecycle management for agentic workflows. By integrating these tools into **automated testing and governance pipelines, teams can proactively detect issues, optimize performance, and maintain high standards of quality and compliance in production environments.

Automating Incident Investigations with LangGraph and OpenAI GPT

Incident investigations are time-consuming and often happen during off-hours. I built an AI agent that automates this process—When incidents happen at 2 AM, engineers lose sleep digging through Slack alerts, Prometheus metrics, and Splunk logs. What if an AI agent could do the heavy lifting—triage, investigate, and summarize the root cause.  LangGraph makes it simple to design agent workflows as nodes and flows, while GPT provides the reasoning power. LangGraph is a powerful framework built on top of LangChain that allows you to create stateful, multi-step agents using a graph-based architecture. Unlike traditional chains, LangGraph lets you define nodes(functions or agents) and edges (transitions) to model complex workflows so that it  helps you orchestrate multi-step agent workflows. Think of it like drawing a flowchart for your AI agent  where each box is a node (task) and the arrows represent the logic flow.

• Node = step in your agent (e.g., "fetch metrics")
• Edge = connection (e.g., "if anomaly detected → analyze logs")

Here’s the problem we’re solving:

1. Alerts come in via Slack
2. We need to query Prometheus (metrics) + Splunk (logs)
3. Generate an investigation report
4. Share root cause insights automatically

Step 1: Define the Flow (Nodes)

We design our agent as a graph of nodes:

1. Slack Listener Node → listens for alerts in real-time

2. Prometheus Query Node → fetches system metrics

3. Splunk Query Node → retrieves log entries

4. LLM Analysis Node (GPT-4o) → correlates signals

5. Summary & Report Node → generates incident summary

6. Slack Notifier Node → posts root cause back to Slack

Step 2: How the Flow Works

• When a Slack alert is received → trigger the workflow

• Prometheus Node and Splunk Node run in parallel (fetching metrics & logs)

• LLM Node takes this raw data and performs correlation reasoning

• Report Node structures it into a human-readable summary

• Finally, Slack Node posts results back to the team

  +----------------+
  | Slack Alerts   |
  +----------------+
          ↓
  +----------------+        +------------------+
  | Slack Listener | ----→  | Prometheus Query |
  +----------------+        +------------------+
          ↓                        ↓
          └─────────────→ +------------------+
                          | Splunk Query     |
                          +------------------+
                                  ↓
                          +------------------+
                          | GPT-4o Analysis  |
                          +------------------+
                                  ↓
                          +------------------+
                          | Report Generator |
                          +------------------+
                                  ↓
                          +------------------+
                          | Slack Notifier   |
                          +------------------+

Step 3:  LangGraph Code (POC 1)

Here’s a simplified version for beginners:

from langgraph.graph import StateGraph, END
from langchain_openai import ChatOpenAI

# 1. Define LLM
llm = ChatOpenAI(model="gpt-4o")

# 2. State definition
class AgentState(dict):
    pass

# 3. Nodes (functions)
def slack_listener(state: AgentState):
    state["alert"] = "High CPU usage on server-123"
    return state

def query_prometheus(state: AgentState):
    state["metrics"] = "CPU 95% for last 10 min"
    return state

def query_splunk(state: AgentState):
    state["logs"] = "Error: Timeout connecting to DB"
    return state

def analyze_with_llm(state: AgentState):
    response = llm.predict(f"""
        Alert: {state['alert']}
        Metrics: {state['metrics']}
        Logs: {state['logs']}
        Please find likely root cause and suggest action.
    """)
    state["analysis"] = response
    return state

def slack_notifier(state: AgentState):
    print("Incident Report to Slack:")
    print(state["analysis"])
    return state

# 4. Build Graph
workflow = StateGraph(AgentState)
workflow.add_node("slack_listener", slack_listener)
workflow.add_node("query_prometheus", query_prometheus)
workflow.add_node("query_splunk", query_splunk)
workflow.add_node("analyze_with_llm", analyze_with_llm)
workflow.add_node("slack_notifier", slack_notifier)

# 5. Define edges (flow)
workflow.set_entry_point("slack_listener")
workflow.add_edge("slack_listener", "query_prometheus")
workflow.add_edge("slack_listener", "query_splunk")
workflow.add_edge("query_prometheus", "analyze_with_llm")
workflow.add_edge("query_splunk", "analyze_with_llm")
workflow.add_edge("analyze_with_llm", "slack_notifier")
workflow.add_edge("slack_notifier", END)

# 6. Compile & run
agent = workflow.compile()
agent.invoke({})

------------

This POC shows how simple it is to build your own AI agent using LangGraph:
Just define nodes as functions
Connect them with edges
Let GPT handle the reasoning
From here, you can expand:
Add ticket creation in Jira
Add automated remediation scripts
Scale to multi-agent workflows

Install dependencies:

pip install -r requirements.txt

pip install langgraph openai slack_sdk prometheus-api-client splunk-sdk

---------------------------------------------------

You can  design the flow  bit differently  as shown in this Building the LangGraph 

Each node is a LangGraph function or GPT-4o-powered agent. The transitions are based on the success/failure of each step.

--------------------------

Define nodes: Each node is a Python function. Example: Query Prometheus

----------

def query_prometheus(alert_data):

    from prometheus_api_client import PrometheusConnect

    prom = PrometheusConnect(url=os.getenv("PROMETHEUS_URL"), disable_ssl=True)

    metric_data = prom.get_current_metric_value(metric_name="cpu_usage")

    return {"metrics": metric_data}

------------

 Build the Graph

------------

from langgraph.graph import StateGraph

graph = StateGraph()

graph.add_node("parse_alert", parse_alert)

graph.add_node("query_prometheus", query_prometheus)

graph.add_node("query_splunk", query_splunk)

graph.add_node("analyze", analyze_data)

graph.add_node("summarize", summarize_root_cause)

graph.add_node("post_slack", post_to_slack)

graph.set_entry_point("parse_alert")

graph.add_edge("parse_alert", "query_prometheus")

graph.add_edge("parse_alert", "query_splunk")

graph.add_edge("query_prometheus", "analyze")

graph.add_edge("query_splunk", "analyze")

graph.add_edge("analyze", "summarize")

graph.add_edge("summarize", "post_slack")

agent = graph.compile()

--------------------------------------------------

Running the Agent

agent.invoke({"alert": slack_alert_data})

-----------------------------------------------------

POC 2: Security Breach Detection Agent with LangGraph + GPT

Security teams spend countless hours scanning logs for suspicious login attempts—failed SSH connections, brute force attacks, or abnormal geolocation logins. How  AI agent could detect login anomalies, analyze logs, and automatically alert on Slack with root cause insights. Let’s build that with LangGraph + OpenAI GPT-4o.

---

Use Case Overview

• Problem: Multiple suspicious logins are detected on a server, but admins often get overwhelmed by raw log alerts.

• Solution: Create an AI Agent flow to:

  1. Monitor server logs for abnormal login attempts

  2. Correlate failed login data (IPs, frequency, geolocation)

  3. Ask GPT to determine if it’s a brute force attack, unusual login, or benign

  4. Generate a clear summary with root cause analysis

  5. Send the summary to Slack Security Channel

---

Agent Flow (Nodes)

1. Log Monitor Node → listens to /var/log/auth.log or SIEM events

2. Anomaly Detector Node → extracts suspicious login attempts (e.g., >5 failed SSH logins from same IP)

3. GeoIP Lookup Node → enriches IP with geolocation info

4. LLM Analysis Node (GPT-4o) → determines likelihood of attack and explains root cause

5. Slack Notifier Node → sends human-readable incident report to security team

---

How the Flow Works

• Input: System log entries (/var/log/auth.log)

• Processing: Detect multiple failed login attempts, enrich data with GeoIP lookup

• Reasoning: LLM correlates and explains possible root cause (e.g., brute-force attempt from overseas IP)

• Output: Slack notification with analysis & recommended action

LangGraph Implementation

from langgraph.graph import StateGraph, END
from langchain_openai import ChatOpenAI
import random

# Define LLM
llm = ChatOpenAI(model="gpt-4o")

# Agent State
class AgentState(dict):
    pass

# 1. Log Monitor Node
def log_monitor(state: AgentState):
    # Example logs (in real case, parse /var/log/auth.log)
    state["logs"] = [
        "Failed password for root from 203.0.113.25 port 54321 ssh2",
        "Failed password for root from 203.0.113.25 port 54322 ssh2",
        "Failed password for root from 203.0.113.25 port 54323 ssh2",
        "Failed password for root from 203.0.113.25 port 54324 ssh2",
        "Failed password for root from 203.0.113.25 port 54325 ssh2",
    ]
    return state

# 2. Anomaly Detector Node
def detect_anomaly(state: AgentState):
    failed_attempts = len(state["logs"])
    if failed_attempts > 3:
        state["suspicious_ip"] = "203.0.113.25"
        state["anomaly"] = f"Detected {failed_attempts} failed logins from {state['suspicious_ip']}"
    else:
        state["anomaly"] = "No anomaly detected"
    return state

# 3. GeoIP Lookup Node (simulated)
def geoip_lookup(state: AgentState):
    # Fake GeoIP lookup for example
    geo_info = {"ip": state.get("suspicious_ip", "N/A"), "country": "Russia", "asn": "AS12345"}
    state["geoip"] = geo_info
    return state

# 4. LLM Analysis Node
def analyze_with_llm(state: AgentState):
    prompt = f"""
    Security Alert:
    Logs: {state['logs']}
    Anomaly: {state['anomaly']}
    GeoIP Info: {state['geoip']}
    
    Please analyze the root cause.
    Is this a brute force attack, suspicious login, or benign activity?
    Suggest next action.
    """
    response = llm.predict(prompt)
    state["analysis"] = response
    return state

# 5. Slack Notifier Node
def slack_notifier(state: AgentState):
    print(" Security Incident Report to Slack:")
    print(state["analysis"])
    return state

# Build Workflow
workflow = StateGraph(AgentState)
workflow.add_node("log_monitor", log_monitor)
workflow.add_node("detect_anomaly", detect_anomaly)
workflow.add_node("geoip_lookup", geoip_lookup)
workflow.add_node("analyze_with_llm", analyze_with_llm)
workflow.add_node("slack_notifier", slack_notifier)

# Define Flow
workflow.set_entry_point("log_monitor")
workflow.add_edge("log_monitor", "detect_anomaly")
workflow.add_edge("detect_anomaly", "geoip_lookup")
workflow.add_edge("geoip_lookup", "analyze_with_llm")
workflow.add_edge("analyze_with_llm", "slack_notifier")
workflow.add_edge("slack_notifier", END)

# Run Workflow
app = workflow.compile()
app.invoke({})

Block Diagram

+------------------+        +-------------------+
| Auth Logs (/var) | -----> | Log Monitor Node  |
+------------------+        +-------------------+
                                  ↓
                          +-------------------+
                          | Anomaly Detector  |
                          +-------------------+
                                  ↓
                          +-------------------+
                          | GeoIP Lookup Node |
                          +-------------------+
                                  ↓
                          +-------------------+
                          | GPT Analysis Node |
                          +-------------------+
                                  ↓
                          +-------------------+
                          | Slack Notifier    |
                          +-------------------+

Benefits

• Detects brute force attacks in real time
• Provides context (IP, country, ASN, frequency)
• Generates human-readable summary for faster decision-making
• Alerts team on Slack in seconds

With just a few nodes and flows in LangGraph, you’ve created a security incident investigation assistant—a perfect POC for security teams.

LangGraph makes it easy to build modular, scalable, and intelligent agents that mirror real-world workflows. Combined with GPT-4o’s reasoning power, you can automate even complex tasks like incident investigations.

OpenShift Virtualization with KVM on IBM Servers

Introduction

OpenShift Virtualization, built on the upstream KubeVirt project, enables the seamless integration of virtual machines (VMs) into Kubernetes-native environments. It allows organizations to run containerized and traditional VM-based workloads side by side, using the same OpenShift platform. This is especially powerful on IBM infrastructure, including IBM Power, IBM Z, and LinuxONE systems, where enterprise-grade virtualization is a key requirement.

source

OpenShift Virtualization allows you to run VMs inside a Kubernetes cluster. It uses KVM (Kernel-based Virtual Machine) as the hypervisor and wraps VM processes inside Kubernetes Pods. The process is orchestrated using several components like virt-controller, virt-handler, and virt-launcher.

Step 1: Create VM

• A user or automation tool submits a VirtualMachine (VM) object to the OpenShift API server.
• This is a Custom Resource Definition (CRD) that describes the desired VM configuration (CPU, memory, disk, etc.).

Step 2: Create VMI

• The virt-controller watches for new VM objects.
• It creates a VirtualMachineInstance (VMI) object, which represents the actual running VM.
• This VMI is also a CRD and is used to track the VM’s runtime state.

Step 3: Create virt-launcher Pod

• The virt-controller instructs Kubernetes to create a Pod called virt-launcher.
• This Pod is responsible for running the VM process.
• It contains the libvirtd and qemu-kvm binaries needed to start the VM.

Step 4: Signal to Start VM

• On the node where the Pod is scheduled, the virt-handler (a DaemonSet running on every node) receives a signal.
• It prepares the environment and communicates with libvirt inside the virt-launcher Pod.

Step 5: Start VM

• Inside the virt-launcher Pod, libvirtd uses qemu-kvm to start the VM.
• The VM runs as a process on the host node, isolated inside the Pod.
• Other containers (like container 1 and container 2) may run alongside the VM for networking or monitoring.

Component :                   Role:

API Server	Receives VM definitions
virt-controller	Creates VMI and virt-launcher Pod
virt-handler	Manages VM lifecycle on each node
virt-launcher Pod	Runs the VM using libvirt and qemu
libvirtd + qemu-kvm	Actual VM execution
KVM kernel module	Hypervisor that runs the VM

Where the VM Actually Runs

• The VM runs inside the virt-launcher Pod, but it’s not a container.
• It’s a process managed by libvirt and qemu, using the KVM hypervisor on the host Linux kernel.

Key Terminologies and Components

• VirtualMachine (VM) CRD: Defines the VM object.
• VirtualMachineInstance (VMI) CRD: Represents a running VM instance.
• virt-controller: Running on master node -Watches for new VMIs and creates corresponding pods.
• virt-handler: Runs as a DaemonSet on each worker node, manages VM lifecycle.
• virt-launcher Pod: Encapsulates the VM process using libvirt and qemu-kvm.
• libvirtd: Embedded in virt-launcher, interfaces with KVM for VM operations.
• CDI (Containerized Data Importer): Handles disk image imports into PVCs.
• Multus CNI: Enables multiple network interfaces for VMs.
• HyperConverged CR: Central configuration point for OpenShift Virtualization.

VM Lifecycle Flow

1. User defines a VMI via YAML or GUI.
2. virt-controller creates a pod for the VM.
3. virt-handler on the target node configures the VM using libvirt.
4. virt-launcher runs the VM inside the pod.
5. KVM executes the VM as a process on the host.

Networking in OpenShift Virtualization

OpenShift uses Multus to attach VMs to multiple networks. This is crucial for legacy workloads that require direct Layer 2 access or static IPs.

• VMs can bypass SDN and connect directly to external networks.
• SR-IOV, MACVLAN, and bridge interfaces are supported.
• nmstate operator helps configure physical NICs on worker nodes.

Storage Integration

VM disks are managed using Kubernetes-native storage constructs:

• PersistentVolumeClaims (PVCs) and StorageClasses.
• CDI allows importing disk images via annotations.
• Integration with OpenShift Data Foundation (Ceph) enables RWX and block storage.

Example PVC with CDI:

apiVersion: v1
kind: PersistentVolumeClaim
metadata:
  name: fedora-disk0
  annotations:
    cdi.kubevirt.io/storage.import.endpoint: "http://10.0.0.1/images/Fedora.qcow2"
spec:
  storageClassName: ocs-gold
  accessModes:
    - ReadWriteOnce
  resources:
    requests:
      storage: 20Gi

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IBM Server Support

OpenShift Virtualization is supported on IBM infrastructure including:

• IBM Power Virtual Server
• IBM Z and LinuxONE
• IBM x86 platforms

Deployment Highlights

• Uses RHEL KVM as the hypervisor.
• VMs are configured with static IPs using macvtap bridges.
• OpenShift clusters run on RHEL CoreOS nodes.
• Supports live migration, high availability, and secure networking.

Operator Lifecycle and Control Plane

OpenShift Virtualization is managed via several operators:

• virt-operator: Deploys and upgrades virtualization components.
• cdi-operator: Manages disk imports.
• ssp-operator: Handles VM templates and validation.
• tekton-tasks-operator: Enables VM creation via pipelines.
• cluster-network-addons-operator: Manages extended networking.
• hostpath-provisioner-operator: Provides CSI-based storage provisioning.

Each operator creates resources like DaemonSets, ConfigMaps, and CRDs to manage the virtualization lifecycle.

Best Practices for VM Workloads

• Use security-hardened images.
• Monitor resource usage with Prometheus/Grafana.
• Apply affinity/anti-affinity rules for VM placement.
• Enable live migration for high availability.
• Use templates for consistent VM provisioning.

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KubeVirt :  is a tool that lets you run virtual machines (VMs) inside a Kubernetes cluster. This means you can manage both containers and VMs using the same platform.

KubeVirt is designed using a service-oriented architecture, which means different parts of the system handle different tasks. It also follows a choreography pattern, meaning each component knows its role and works independently without needing a central controller to tell it what to do.

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1. User Request
   A user (or automation tool) sends a request to create a VM using the KubeVirt Virtualization API.

2. API Talks to Kubernetes
   The Virtualization API communicates with the Kubernetes API Server to schedule the VM.

3. Kubernetes Handles the Basics
   Kubernetes takes care of:

   • Scheduling: Deciding which node the VM should run on.
   • Networking: Connecting the VM to the network.
   • Storage: Attaching disks or volumes to the VM.

4. KubeVirt Adds Virtualization
   While Kubernetes handles the infrastructure, KubeVirt provides the virtualization layer. It uses components like:

   • virt-controller: Watches for VM requests and creates VM instances.
   • virt-handler: Manages VM lifecycle on each node.
   • virt-launcher: Runs the actual VM inside a pod.
   • virt-api: Exposes the virtualization API.

• Kubernetes = handles scheduling, networking, and storage.
• KubeVirt = adds the ability to run VMs
• NOTE: Together, they let you run containers and VMs side-by-side in a cloud-native way.

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Note basic terminology/names if you are a beginner :

 Containers → Pods → ReplicaSets

1. Container

A container is a lightweight, standalone executable package that includes everything needed to run an application (code, runtime, libraries). Examples: Nginx container, Python app container.

2. Pod

A Pod wraps one or more containers. A pod with a single container running a web server . A pod with two containers -one running the app and another running helper process(like logging or monitoring) 

All containers in a Pod share:The same network IP. The same storage volumes.The same lifecycle

Most Pods contain just one container, but you can have multiple if they need to work closely together.

3. ReplicaSet

A ReplicaSet ensures that a specified number of identical Pods are running at all times.

If a Pod crashes or is deleted, the ReplicaSet creates a new one to maintain the desired count.

It’s usually managed by a Deployment, which adds features like rolling updates.

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Conclusion

OpenShift Virtualization bridges the gap between traditional VMs and cloud-native containers. On IBM servers, it offers a robust, scalable, and secure platform for hybrid workloads. With KVM as the backbone and Kubernetes as the orchestrator, enterprises can modernize without abandoning legacy applications.

Software Architecture Patterns Explained with Real-World Examples

Every project has its own unique flavor, and selecting the right architecture is like choosing the perfect tool for the job. Whether you're building a web app, a distributed system, or a real-time platform, the architecture you choose will shape how your system performs, scales, and evolves.

Let’s break down four popular software architecture patterns in simple, real-world terms—with examples to bring them to life:

             Choosing the Right Software Architecture: A Practical Guide

1️⃣ MVC (Model–View–Controller)

MVC stands for Model–View–Controller, a widely used software design pattern that separates an application into three interconnected components. This separation helps manage complexity, improve scalability, and make code easier to maintain and test.

A time-tested pattern that cleanly separates concerns:

• Model: Manages the data and business logic.
• View: Handles the user interface and presentation.
• Controller: Processes user input and coordinates between the model and view.

Best suited for: Web applications where UI and logic need to evolve independently. MVC promotes modularity and makes it easier to maintain and scale.

Examples:

• Django (Python): A popular web framework that follows MVC principles for building scalable web apps.
• Ruby on Rails: Uses MVC to separate business logic from presentation, making development faster and cleaner.

2️⃣ Microservices Architecture

Microservices divide an application into small, independent services that communicate via APIs. Each service is responsible for a specific business capability and can be developed, deployed, and scaled independently.

Benefits:

• Flexibility in technology choices
• Faster deployment cycles
• Easier fault isolation

Watch out for: Increased complexity in orchestration, monitoring, and inter-service communication.

Examples:

• Netflix: Uses microservices to handle everything from user profiles to streaming services, allowing independent scaling.
• Amazon: Each business function (e.g., payments, recommendations, inventory) is a separate microservice.

3️⃣ Monolithic Architecture

Everything is bundled into a single, unified codebase. It’s straightforward to build and test in the early stages, making it ideal for small teams or MVPs.

Pros:

• Simple development and deployment
• Easier debugging

Cons:

• Difficult to scale
• Risk of tight coupling and slower release cycles as the codebase grows

Examples:

• WordPress: A classic monolithic CMS where all components are tightly integrated.
• Early versions of LinkedIn: Started as a monolithic app before migrating to microservices.

4️⃣ Event-Driven Architecture

This pattern revolves around events—changes in state or user actions—that trigger responses across services. Components are loosely coupled and communicate through event brokers.

Ideal for:

• Real-time systems
• E-commerce platforms
• IoT applications

Advantages:

• High scalability
• Asynchronous processing
• Decoupled services

Examples:

• Uber: Uses event-driven architecture to handle real-time ride requests, driver updates, and location tracking.
• Spotify: Processes user actions like song plays and playlist updates using event streams for analytics and recommendations.

Final Thoughts

Each architecture comes with its own strengths and trade-offs. The key is to understand your project’s requirements—performance, scalability, team size, and future growth—and choose the architecture that aligns best.