The Practical DeveloperModify

2025-11-11 00:22:16

Over the past few months, I’ve been working on one of the most exciting and challenging cloud migration projects of my career, a large-scale transformation initiative between xyz (a global technology consulting firm) and abc (a major telecommunications company).

The goal of this project is simple but powerful: to move dozens of critical enterprise applications from on-premises data centers into a secure, scalable, and automated AWS environment without disrupting existing business operations. This is part of a broader modernization program that will allow abc to run its workloads faster, more securely, and more efficiently in the cloud.

What We’re Doing

The migration involves a mix of rehosting, redeploying, and refactoring applications using AWS native tools, Terraform for Infrastructure as Code (IaC), and automated CI/CD pipelines.

Our scope includes:

• Designing and deploying AWS environments for multiple business units.

• Setting up VPCs, subnets, IAM roles, security groups, load balancers, and monitoring tools.

• Implementing cross-account role assumption for secure access and governance.

• Coordinating closely with both the cloud engineering and application teams to ensure smooth transitions.

As of now, we’re working through a pipeline of over 30 applications scheduled for migration to AWS. Several have already been successfully redeployed and tested in non-production and production environments.

My Role

As a Cloud Engineer on this project, my role cuts across technical execution, documentation, and coordination. I’ve been directly involved in:

• Designing AWS architectures for multiple applications; defining network layout, IAM roles, and access controls.

• Collaborating on Terraform automation, including maintaining GitHub repositories and building modular scripts for consistent infrastructure deployment.

• Managing environment readiness, which includes server provisioning, IAM access configuration, and validating connectivity between on-prem databases and cloud servers.

• Supporting MGN setup, ensuring source servers are correctly configured for migration replication.

• Contributing to migration design documents, including the logical architecture, deployment models, dependencies, and database connections.

• Coordinating with the application and security teams to manage firewall requests, DNS cutovers, and access provisioning.

What I’ve Achieved So Far

• Successfully supported the AWS environment setup for multiple application migrations.

• Created and refined design documentation that clearly outlines migration strategy, deployment processes, and technical architecture.

• Validated IAM roles and cross-account access, ensuring secure provisioning in multi-account AWS setups.

• Helped establish a Terraform-based deployment workflow, integrating version control and infrastructure automation.

• Worked closely with the project leads to align AWS provisioning with organizational compliance standards.

• Gained practical experience in AWS MGN (Migration Hub), Terraform automation, and enterprise migration governance.

Where We Are Now

Our team has completed the foundation setup AWS accounts, networking, IAM, and automation frameworks are now in place. We’re currently focused on:

• Accelerating AWS application deployments through Terraform automation.
• Coordinating with database and app owners for production cutovers.
• Streamlining server provisioning and post-deployment checks.
• Ensuring security compliance and monitoring with AWS CloudWatch and Config.

What Makes This Experience Stand Out

This project is more than just moving workloads to AWS; it’s a complete cloud enablement initiative. I’ve learned the value of collaboration between cloud engineers, app owners, database administrators, and project managers, all working toward a shared goal of modernization.

Every day comes with new learning: understanding enterprise migration frameworks, managing IAM at scale, troubleshooting deployment issues, and optimizing Terraform code for real-world production environments.

My Reflection

This experience has strengthened my skills not only as a Cloud Engineer but as a problem solver and collaborator. From designing secure AWS architectures to supporting production rollouts, I’ve seen firsthand how cloud migration works at scale the challenges, the coordination, and the satisfaction that comes when an application successfully goes live in the cloud.

We’re still moving forward, with many more applications to migrate in the coming weeks. And as we continue to build, automate, and refine, I’m proud to be part of a team that’s shaping the future of cloud transformation for one of the biggest enterprises in the industry.

2025-11-11 00:18:17

It is great to come back to sharing my thoughts on the next line of action I want for my career. At this moment, I want to go all in with data engineering with focus on mastery.

Data is critical in this modern time as it has always been. Some social media platforms like LinkedIn and Instagram have made it explicity known that they will be using your data for training if you are comfortable with it.

In this data challenge series, I will be going from the basics to the complex to grasp the full concept of what it is to be a data engineer right from ingesting, storing, cleaning, and processing the data.

Who are Data Engineers?

From the brief intro above, data engineers are integral part of the company for maintaining systems that ingest data from both internal or external sources like databases and APIs, store this data for further processing, clean, and process them after going through a series of transformation steps.

How Spark works

To use Spark, you first need to have a Spark cluster. A cluster is a collection of computers running Spark software.

For a Spark application, the cluster consists of two components:

• driver: this orchestrates the data processing
• executors: this process the data itself

Installing Spark

brew install apache-spark

# after installation, run:
pyspark

# install jupyter notebook in the virtual env
pip install jupyter

# configure pyspark to use the jupyter notebook when we start it
# define these two environment variables
export PYSPARK_DRIVER_PYTHON='jupyter'
export PYSPARK_DRIVER_PYTHON_OPTS='lab'

# run or start the development server in the venv
pyspark

Practical demo

For you to become better, you must practice. This demo will use the data processing framework, Apache Spark to start the development server in Jupyter Notebook in a virtual environment.

This documentation is a good starting guide to writing efficient Spark applications and its functionality.

Now, let's create a SparkSession by reading an actual data from a CSV. To follow along, download a sample data from this website.

from pyspark.sql import SparkSession

spark = SparkSession \
        .builder \
        .appName('Read inside airbnb data') \
        .getOrCreate()

listings = spark.read.csv('data/listings.csv.gz',
                          header=True,
                          inferSchema=True,
                          sep=',',
                          quote='"',
                          escape='"',
                          multiLine=True,
                          mode='PERMISSIVE'
                         )

listings.printSchema()

for list in listings.schema:
    print(list)

description = listings.select(listings.description)

description.show(20, truncate=False)

When not to work with Apache Spark

• when working on small amount of data
• processing data in real-time (it is better to use data streaming)

Where to find out more about this journey

The public repo is available here:

https://github.com/Terieyenike/data-engineering

If you want to connect and reach out, I am active on LinkedIn:

https://linkedin.com/in/terieyenike

2025-11-11 00:07:04

Music Monday: Outside of Your Bubble

Any song you've had on repeat lately?

Drop a YouTube, SoundCloud, Bandcamp or Spotify {% embed %} in the comments. Let's discover something new beyond what the algorithms are feeding us.

Any genre is welcome! Music taste is subjective, and there's no "good" or "bad" here. Share what you love and include why if you feel like it.

2025-11-11 00:05:00

Introduction

So, you've decided to dive into the world of Home Assistant! Congratulations. You're on the path to building a truly private, powerful, and customized smart home that isn't locked into a single corporate ecosystem. But as you stand at the starting line, the sheer number of choices can feel overwhelming. What computer should you run it on? What are Zigbee and Z-Wave? Which smart devices should you even buy first?

Don't worry. As a home improvement expert, I know that the best projects start with a solid plan and the right materials. This guide will be your blueprint. We'll cut through the noise and walk you through selecting the perfect core hardware and your first few game-changing smart devices.

Core Principles for a Stable Smart Home

Before we even think about shopping, let's establish some foundational rules. Think of this as your safety check before a big project. Following these principles will save you immense frustration down the road.

• Prioritize Local Control: Many cheap Wi-Fi devices rely on cloud servers, meaning they stop working if the internet goes down or the company shuts its doors. We'll focus on protocols like Zigbee and Z-Wave, which create their own reliable network inside your home. This ensures your automations are fast, private, and dependable.
• Check for Compatibility FIRST: This is the golden rule. Before you click "buy" on any device, check the official Home Assistant integrations list. A quick search can tell you if a device is fully supported, partially supported, or not supported at all. This simple step prevents buying expensive paperweights.
• Start Small, Think Big: It's tempting to automate your entire house at once. Resist the urge. Start with one or two rooms and a handful of devices. Learn the system, understand how automations work, and then expand. Your future self will thank you.
• Your Network is Your Foundation: Your smart home is only as stable as your home network. An old, unreliable Wi-Fi router will cause endless headaches with device dropouts and slow responses. Ensure you have a modern, solid router before you begin.

Your Smart Home Shopping List: Hardware & Devices

Every great smart home needs a brain and senses. First, we'll choose the "brain" (the computer that runs Home Assistant), then we'll pick the "senses" (your first few devices).

Part 1: The "Brain" - Home Assistant Hardware

This is the central computer that will run the Home Assistant software 24/7.

• The Official Choice (Easiest): Home Assistant Green
  • What it is: A plug-and-play box designed and sold by the creators of Home Assistant.
  • Pros: The simplest way to start. It's optimized for Home Assistant and just works.
  • Cons: Less powerful than a mini PC, so it may struggle if you later add dozens of cameras or complex processing.
• The Classic Starter: Raspberry Pi 4 or 5
  • What it is: A tiny, credit-card-sized computer beloved by hobbyists.
  • Pros: Inexpensive, low power consumption, and a huge community for support.
  • Cons: Can be slow, and running off an SD card can lead to failure over time (an SSD upgrade is highly recommended).
• The Power User Option: Mini PC (NUC-style)
  • What it is: A small, powerful computer from brands like Intel, Beelink, or Minisforum.
  • Pros: Very powerful and reliable. Can easily handle a large number of devices, cameras, and even other home server applications. Uses a fast, durable SSD.
  • Cons: The most expensive option.
• The Recycled Option: An Old Laptop or Desktop
  • What it is: That old computer collecting dust in your closet.
  • Pros: It's free! A great way to test the waters without spending money.
  • Cons: Can be bulky, noisy, and consume a lot of electricity compared to the other options.

Part 2: The "Senses" - Your First Devices & Connectors

• Connectivity Hardware: A Zigbee/Z-Wave USB Stick
  • This is non-negotiable for a local-control setup. This USB "dongle" plugs into your Home Assistant hardware and allows it to communicate with Zigbee or Z-Wave devices.
  • Recommended: A Sonoff Zigbee 3.0 USB Dongle Plus or a SkyConnect from the Home Assistant team are excellent, affordable starting points for Zigbee.
• Smart Lighting: 1-2 Zigbee Bulbs
  • This is the classic "hello, world" of smart homes. Brands like Philips Hue or IKEA TRÅDFRI are great. Seeing a light turn on automatically is an instant reward.
• Sensors: A Motion and a Door/Window Sensor
  • These are the true building blocks of automation. A simple motion sensor and a contact sensor (for a door or window) unlock countless possibilities. Look for brands like Aqara or Sonoff.
• Smart Plugs: 1-2 Zigbee or Z-Wave Plugs
  • These are magical. They can make almost any "dumb" device with a physical on/off switch smart. Think lamps, fans, or even your coffee maker.

Pre-Purchase Planning: Asking the Right Questions

Before you add anything to your cart, take five minutes to answer these questions.

1. What is the first problem I want to solve? Don't just "buy smart stuff." Have a goal. Is it to have the hallway light turn on automatically at night? Or get an alert if the garage door is left open? Your first goal will determine your first purchase.
2. What is my budget? A Raspberry Pi and a few Zigbee sensors can get you started for under $150. A mini PC and more devices will be more. Decide on a budget and stick to it.
3. How technically confident am I? If you want the easiest path, buy a Home Assistant Green. If you enjoy tinkering, a Raspberry Pi or Mini PC is a fantastic project.

Step-by-Step Guide to Choosing Your Gear

1. Step 1: Choose Your Home Assistant Host. Based on your budget and confidence level from the planning step, select your hardware. For 90% of beginners, the choice is between the Home Assistant Green (for simplicity) and a Raspberry Pi 4/5 (for a budget-friendly project).
2. Step 2: Pick Your Wireless Protocol & Dongle. For beginners, Zigbee is the way to go. It has a wider variety of affordable devices. Purchase a well-regarded Zigbee USB dongle, like the Sonoff model mentioned above. This is the key that unlocks a world of local-control devices.
3. Step 3: Select Your "Starter Pack." Don't buy a dozen of anything. Start with this trio:
   • One smart plug: To learn how to control simple appliances.
   • One motion sensor: To trigger your first automation.
   • One door/window contact sensor: To learn about states (open/closed) and notifications.
4. Step 4: Verify Compatibility! This is your final check. Take the model numbers of the three devices you picked and search for them on the Home Assistant integrations website. Ensure they are listed as working with ZHA (Zigbee Home Automation) or Zigbee2MQTT, the two main ways Home Assistant handles Zigbee.

Bringing It All Together & Next Steps

Once your packages arrive, the real fun begins. The process generally involves:

1. Installing the Home Assistant operating system on your chosen hardware.
2. Plugging in your Zigbee USB stick.
3. Setting up the Zigbee integration within Home Assistant.
4. Powering on your new smart devices and "pairing" them. Home Assistant will discover them, and they will appear on your dashboard.

Your first project? Create a simple automation. A great one is: "When motion is detected in the living room AND it's after sunset, turn on the lamp's smart plug." Accomplishing this first task is a hugely satisfying moment.

From there, the sky's the limit. You can expand with climate sensors, smart thermostats, leak detectors, energy monitoring, and so much more.

Conclusion

Jumping into Home Assistant is one of the most rewarding home improvement projects you can undertake. By starting with a solid hardware host, committing to local-control protocols like Zigbee, and choosing a few simple sensors and plugs, you set yourself up for success. You're not just buying gadgets; you're building a home that is smarter, more efficient, and truly yours. Welcome to the community

2025-11-11 00:04:28

Last week, I ran into one of those tricky production bugs where everything looked fine, but Azure Front Door kept throwing a 504 Gateway Timeout.
And the real cause? A simple missing HTTP method. 😅

⚙️ My Setup

I had a typical production setup:

• FastAPI app running on port 8000 as a background process (managed via systemd, so it auto-starts on reboot)
• Nginx working as a reverse proxy, handling all HTTP/HTTPS traffic
• Everything deployed behind Azure Front Door

So the flow looked like this:

Frontend → Azure Front Door → Nginx → FastAPI (port 8000)

When I tested everything manually:

curl http://localhost:8000/health

✅ returned “healthy”
✅ app responded instantly
✅ SSL working fine via Nginx
✅ no errors in systemd logs

Still, Front Door said:

“No healthy backends available.”

And my frontend just sat there… until it failed with a 504 Gateway Timeout. 😩

🧠 The Clue I Almost Missed

While checking my logs, I noticed this repeating line every 30 seconds:

INFO: 127.0.0.1:44438 "HEAD /health HTTP/1.0" 405 Method Not Allowed

That was the “aha!” moment.
Azure Front Door wasn’t using GET at all — it was sending a HEAD /health request.

🧩 What Was Happening

Here’s what Front Door was doing under the hood:

Every 30 seconds:
Front Door → HEAD /health → backend VM

But my FastAPI code looked like this:

@app.get("/health")
async def health():
    return {"status": "healthy"}

So my app said:

“I don’t accept that method.” → 405 Method Not Allowed ❌

Front Door took that as:

“Backend is unhealthy.”

And started marking every VM as unhealthy.

💥 The Domino Effect

HEAD /health → 405 ❌ → Backend unhealthy
All backends unhealthy → No route to send traffic
Front Door → Waits → Times out after 60s
Frontend → 504 Gateway Timeout

Meanwhile, when I ran a GET manually, everything looked healthy.
That’s what made this bug so sneaky.

🩹 The One-Line Fix

I updated my FastAPI route to accept both GET and HEAD:

from fastapi import FastAPI, Response

app = FastAPI()

@app.api_route("/health", methods=["GET", "HEAD"], include_in_schema=False)
async def health():
    return Response(content="healthy", status_code=200)

Now both checks pass:

curl http://localhost:8000/health     # GET → healthy ✅
curl -I http://localhost:8000/health  # HEAD → 200 OK ✅

And Azure Front Door is happy again 💙

🔍 Why HEAD Is Used

HEAD is like a lightweight GET it only retrieves headers, no body.
It’s faster and cheaper to run for hundreds of backend checks.

That’s why all major load balancers (Azure Front Door, AWS ALB, GCP LB, Nginx) prefer using it for health probes.

🧠 TL;DR

✨ Simple Analogy

Front Door: "Knock knock, are you alive?" (HEAD)
FastAPI: "I only reply to phone calls (GET)" → 405
Front Door: "Okay, unhealthy then."

After the fix:

Front Door: "Knock knock?"
FastAPI: "Yep, alive and ready!" → 200 OK
Front Door: "Perfect, routing traffic now."

💭 Final Thought

This one was a great reminder
sometimes, your system isn’t broken… it’s just misunderstanding the protocol.

A tiny missing method caused a full 504 outage.
But with one line of code, everything started flowing smoothly again. 🚀

2025-11-11 00:02:13

TL;DR

CinemaSins rips into Thunderbolts (a.k.a. The New Avengers) in true “Everything Wrong With” style, ticking off plot holes, janky CGI and character missteps—all in under 20 minutes—yet can’t help admitting the movie’s got a weird charm. Is it perfect? Far from it. Is it kinda fun? Totally.

For more sin-counting madness, head to their website, hop on Discord or Reddit, follow them on social, fill out their polls and even support the team on Patreon for extra behind-the-scenes treats.

Watch on YouTube