What is Late Chunking

What it does: Processes the entire document through the transformer before chunking the token embeddings (not the text).

The problem it solves: Traditional chunking loses long-distance context. Late chunking preserves full document context in each chunk’s embedding.

Conceptual example:

def late_chunk(text: str, chunk_size=512) -> list:

    """Embed full document BEFORE chunking"""

  

    # Step 1: Embed entire document (8192 tokens max)

    full_doc_token_embeddings = transformer_embed(text)  # Token-level

  

    # Step 2: Define chunk boundaries

    tokens = tokenize(text)

    chunk_boundaries = range(0, len(tokens), chunk_size)

  

    # Step 3: Pool token embeddings for each chunk

    chunks_with_embeddings = []

    for start in chunk_boundaries:

        end = start + chunk_size

        chunk_text = detokenize(tokens[start:end])

  

        # Mean pool token embeddings (preserves full doc context!)

        chunk_embedding = mean_pool(full_doc_token_embeddings[start:end])

        chunks_with_embeddings.append((chunk_text, chunk_embedding))

  

    return chunks_with_embeddings

Late chunking in the context of embeddings for GenAI (Generative AI) is a strategy used when processing large documents or datasets for vector embeddings, particularly in RAG (Retrieval-Augmented Generation) workflows.

Here’s a clear breakdown:

Definition

Late chunking means delaying the splitting of content into smaller pieces (chunks) until after embedding generation has started or the content has been initially processed.

Instead of splitting a large document into chunks before generating embeddings (which is early chunking), the model or system first generates embeddings for larger units (like full documents or sections) and then splits or processes them further later in the pipeline if needed.

Why use Late Chunking?

Preserves context

Early chunking may break semantic context by splitting sentences or paragraphs arbitrarily.

Late chunking allows embeddings to capture larger context, improving similarity searches.

Efficient processing

You can generate embeddings for larger units first and only create smaller chunks if retrieval or indexing requires it, reducing unnecessary computations.

Dynamic retrieval granularity

Allows flexible adjustment of chunk size later depending on how the embeddings will be queried or used in the application.

Comparison to Early Chunking

Feature Early Chunking Late Chunking

When text is split Before embedding After embedding or during retrieval

Context retention Lower (may lose semantic links across chunks) Higher (larger context retained)

Processing efficiency May generate more embeddings unnecessarily Can reduce embedding count

Use case Simple search or small documents Large documents, long context GenAI applications

💡 Example Scenario:

A book with 1000 pages is to be used in a RAG application.

Early chunking: Split into 2-page chunks first → 500 embeddings.

Late chunking: Generate embeddings for each chapter first → 20 embeddings, then split chapters into smaller chunks later only if needed.

This approach balances context preservation and computational efficiency.

What is an example of Graphiti with Neo4J

from graphiti_core import Graphiti

from graphiti_core.nodes import EpisodeType

# Initialize Graphiti (connects to Neo4j)

graphiti = Graphiti("neo4j://localhost:7687", "neo4j", "password")

async def ingest_document(text: str, source: str):

    """Ingest into knowledge graph"""

    # Graphiti automatically extracts entities and relationships

    await graphiti.add_episode(

        name=source,

        episode_body=text,

        source=EpisodeType.text,

        source_description=f"Document: {source}"

    )

async def search_knowledge_graph(query: str) -> str:

    """Hybrid search: semantic + keyword + graph"""

    # Graphiti combines:

    # - Semantic similarity (embeddings)

    # - BM25 keyword search

    # - Graph structure traversal

    # - Temporal context

  

    results = await graphiti.search(query=query, num_results=5)

  

    # Format graph results

    formatted = []

    for result in results:

        formatted.append(

            f"Entity: {result.node.name}\n"

            f"Type: {result.node.type}\n"

            f"Relationships: {result.relationships}"

        )

  

    return "\n---\n".join(formatted)

A Cross Encoder Example

 from sentence_transformers import CrossEncoder

# Initialize once
reranker = CrossEncoder('cross-encoder/ms-marco-MiniLM-L-6-v2')
async def search_with_reranking(query: str, limit: int = 5) -> list:
# Stage 1: Fast vector retrieval (get 4x candidates)
candidate_limit = min(limit * 4, 20)
query_embedding = await embedder.embed_query(query)

candidates = await db.query(
"SELECT content, metadata FROM chunks ORDER BY embedding $1 LIMIT $2",
query_embedding, candidate_limit
)

# Stage 2: Re-rank with cross-encoder
pairs = [[query, row['content']] for row in candidates]
scores = reranker.predict(pairs)

# Sort by reranker scores and return top N
reranked = sorted(
zip(candidates, scores),
key=lambda x: x[1],
reverse=True
)[:limit]

return [doc for doc, score in reranked]

How AWS Config, AWS Inspector, AWS Audit Manager and AWS Artifact work togther ?

 Excellent question — these four AWS services (Audit Manager, Config, Inspector, and Artifact) all relate to security, compliance, and governance, but they serve very different purposes within that ecosystem.

Let’s break them down in a clear, structured way 👇

---

🧩 High-Level Summary

Service	Primary Purpose	Type
AWS Audit Manager	Continuously collects evidence and automates audit reporting for compliance frameworks	Compliance reporting tool
AWS Config	Tracks configuration changes and checks AWS resources against compliance rules	Configuration monitoring tool
Amazon Inspector	Scans workloads for vulnerabilities and security issues	Security assessment tool
AWS Artifact	Provides on-demand access to AWS compliance reports and agreements	Compliance documentation portal

---

🧠 1. AWS Audit Manager

🔹 Purpose:

Helps you audit your AWS environment automatically to simplify compliance with frameworks like ISO 27001, GDPR, PCI-DSS, SOC 2, etc.

⚙️ How It Works:

• Continuously collects evidence (data points) from AWS services (like Config, CloudTrail, IAM).

• Maps them to control sets defined by compliance frameworks.

• Generates audit-ready reports automatically.

📋 Key Features:

• Prebuilt compliance frameworks and control mappings.

• Automated evidence collection (no manual screenshots or data gathering).

• Integration with AWS Organizations (multi-account audits).

• Custom frameworks for internal governance.

🧭 Best For:

• Compliance teams or auditors.

• Organizations preparing for certifications or audits.

🧩 Example:

“Show me all evidence that IAM users require MFA.”
Audit Manager automatically gathers this proof over time.

---

⚙️ 2. AWS Config

🔹 Purpose:

Tracks and records configuration changes of AWS resources to ensure they remain compliant with desired settings or internal policies.

⚙️ How It Works:

• Continuously records resource configurations (EC2, IAM, S3, VPC, etc.).

• Allows you to define Config Rules (managed or custom using Lambda).

• Detects non-compliant resources and triggers alerts or remediation.

📋 Key Features:

• Real-time configuration tracking and history.

• Compliance evaluation against internal or AWS standards.

• Integration with CloudTrail and Security Hub.

🧭 Best For:

• DevOps, security, and compliance teams wanting configuration drift detection.

• Maintaining continuous resource compliance posture.

🧩 Example:

“Alert me if any S3 bucket becomes public.”
AWS Config continuously monitors and flags such violations.

---

🛡️ 3. Amazon Inspector

🔹 Purpose:

An automated vulnerability management service that scans workloads for security issues.

⚙️ How It Works:

• Automatically discovers EC2 instances, container images (ECR), and Lambda functions.

• Continuously scans for:

  • CVEs (Common Vulnerabilities and Exposures)

  • Misconfigurations

  • Software package vulnerabilities

• Prioritizes findings by severity (CVSS score, exploitability).

📋 Key Features:

• Continuous vulnerability scanning.

• Agentless scanning for EC2 and container images.

• Integration with AWS Security Hub, EventBridge, and Inspector dashboard.

• Automatic remediation support.

🧭 Best For:

• Security operations and compliance monitoring.

• Continuous vulnerability assessment of compute resources.

🧩 Example:

“Detect and alert if any EC2 instance has a vulnerable OpenSSL version.”

---

📄 4. AWS Artifact

🔹 Purpose:

A self-service portal that provides AWS compliance reports, certifications, and agreements (e.g., SOC, ISO, PCI, GDPR).

⚙️ How It Works:

• You access it from the AWS Console (no setup required).

• Download third-party audit reports of AWS infrastructure.

• Accept compliance agreements (e.g., Business Associate Addendum (BAA) for HIPAA).

📋 Key Features:

• Central access to AWS’s own compliance evidence.

• No cost; just authentication required.

• Up-to-date compliance documentation and certifications.

🧭 Best For:

• Compliance and legal teams.

• Customers needing AWS compliance proof for audits.

🧩 Example:

“I need AWS’s SOC 2 Type II report to show my auditor.”
You download it directly from AWS Artifact.

---

⚖️ 5. Key Differences

Feature	AWS Audit Manager	AWS Config	Amazon Inspector	AWS Artifact
Purpose	Automate collection of audit evidence	Monitor resource configurations	Detect vulnerabilities	Provide AWS compliance reports
Focus Area	Compliance automation	Configuration compliance	Security posture & CVE detection	External compliance documentation
Scope	Organization-level audits	Resource-level state	Instance, container, Lambda-level scanning	AWS infrastructure compliance
Customization	Custom frameworks	Custom Config rules	Custom scan targets	None (read-only portal)
Output	Audit reports, control evidence	Compliance dashboard	Vulnerability findings	Downloadable reports (PDF)
Integration with Others	Uses Config, CloudTrail, IAM data	Feeds data to Audit Manager, Security Hub	Integrates with Security Hub	Standalone portal
User Role	Auditors & compliance officers	DevOps/SecOps	Security engineers	Compliance/legal staff

---

🧩 6. How They Work Together

Here’s how they complement each other in a real compliance workflow:

1. AWS Config → Monitors your resource configurations.

2. Amazon Inspector → Scans for vulnerabilities in EC2, ECR, Lambda.

3. AWS Audit Manager → Collects evidence from Config, Inspector, IAM, etc., and maps it to compliance controls (e.g., SOC 2).

4. AWS Artifact → Provides the official AWS compliance documentation to share with auditors.

📊 Example Flow:

Config detects non-compliant S3 → Inspector detects a vulnerability → Audit Manager collects both as audit evidence → Artifact provides AWS’s ISO report for your compliance pack.

---

🧠 Simple Analogy

Service	Analogy
Audit Manager	Your automated audit assistant (collects compliance evidence)
Config	Your compliance monitor (tracks changes and deviations)
Inspector	Your security scanner (finds vulnerabilities)
Artifact	Your compliance library (stores AWS certifications and reports)

---

Would you like me to add a diagram showing how these four services connect in a compliance architecture (e.g., flow from Config → Inspector → Audit Manager → Artifact)? It visually clarifies their interaction.

goroutine 5 - Using github.com/Jeffail/tunny (Third-party Library)

 package main

import (

"fmt"

"time"

"github.com/Jeffail/tunny"

)

func main() {

const numTasks = 50

// Create pool with 10 workers

pool := tunny.NewFunc(10, func(payload interface{}) interface{} {

taskID := payload.(int)

// Simulate work

time.Sleep(time.Millisecond * time.Duration(100+taskID*10))

return fmt.Sprintf("Task %d completed", taskID)

})

defer pool.Close()

// Submit tasks

results := make([]interface{}, numTasks)

for i := 1; i <= numTasks; i++ {

go func(taskID int) {

results[taskID-1] = pool.Process(taskID)

}(i)

}

// Wait for tasks (simple wait for demo)

time.Sleep(3 * time.Second)

// Count completed tasks

completed := 0

for _, result := range results {

if result != nil {

completed++

fmt.Println(result.(string))

}

}

fmt.Printf("\nSummary: %d out of %d tasks completed\n", completed, numTasks)

}

goroutine 4 - ErrGroup with Context and Worker Pool

 package main

import (

"context"

"fmt"

"golang.org/x/sync/errgroup"

"sync"

"time"

)

func workerPool(ctx context.Context, numWorkers, numTasks int) ([]string, error) {

taskChan := make(chan int, numTasks)

resultChan := make(chan string, numTasks)

// Create worker pool

g, ctx := errgroup.WithContext(ctx)

g.SetLimit(numWorkers)

// Start workers

for i := 0; i < numWorkers; i++ {

g.Go(func() error {

for {

select {

case <-ctx.Done():

return ctx.Err()

case taskID, ok := <-taskChan:

if !ok {

return nil

}

// Process task

time.Sleep(time.Millisecond * time.Duration(100+taskID*10))

resultChan <- fmt.Sprintf("Processed task %d", taskID)

}

}

})

}

// Feed tasks

go func() {

for i := 1; i <= numTasks; i++ {

taskChan <- i

}

close(taskChan)

}()

// Collect results

var results []string

var wg sync.WaitGroup

wg.Add(1)

go func() {

defer wg.Done()

for result := range resultChan {

results = append(results, result)

}

}()

// Wait for completion

if err := g.Wait(); err != nil {

return nil, err

}

close(resultChan)

wg.Wait()

return results, nil

}

func main() {

ctx := context.Background()

results, err := workerPool(ctx, 10, 50)

if err != nil {

fmt.Printf("Error: %v\n", err)

return

}

fmt.Printf("Summary: Completed %d tasks\n", len(results))

}

goroutine - 3 - Buffered Channel as Semaphore (Classic Go Pattern)

 package main

import (

"fmt"

"sync"

"time"

)

func processTask(taskID int, sem chan struct{}, results chan<- string) {

defer func() { <-sem }() // Release the semaphore

// Simulate work

time.Sleep(time.Millisecond * time.Duration(100+taskID*10))

results <- fmt.Sprintf("Task %d completed", taskID)

}

func main() {

const totalTasks = 50

const maxConcurrency = 10

sem := make(chan struct{}, maxConcurrency)

results := make(chan string, totalTasks)

var wg sync.WaitGroup

// Launch tasks

for i := 1; i <= totalTasks; i++ {

wg.Add(1)

go func(taskID int) {

defer wg.Done()

sem <- struct{}{} // Acquire semaphore

processTask(taskID, sem, results)

}(i)

}

// Wait for all tasks

go func() {

wg.Wait()

close(results)

}()

// Collect results

var completed []string

for result := range results {

completed = append(completed, result)

fmt.Println(result)

}

fmt.Printf("\nSummary: Completed %d tasks with max %d concurrent workers\n", 

len(completed), maxConcurrency)

}