/cloud-native-monitoring-app

Cloud Native app on K8S to monitor system resources using python

Primary LanguageHTML

Cloud Native Resource Monitoring Python App on K8s!

Things you will Learn 🤯

  1. Python and How to create Monitoring Application in Python using Flask and psutil
  2. How to run a Python App locally.
  3. Learn Docker and How to containerize a Python application
    1. Creating Dockerfile
    2. Building DockerImage
    3. Running Docker Container
    4. Docker Commands
  4. Create ECR repository using Python Boto3 and pushing Docker Image to ECR
  5. Learn Kubernetes and Create EKS cluster and Nodegroups
  6. Create Kubernetes Deployments and Services using Python!

# **Youtube Video for step by step Demonstration!**
https://youtu.be/kBWCsHEcWnc

## **Prerequisites** !

(Things to have before starting the projects)

- [x]  AWS Account.
- [x]  Programmatic access and AWS configured with CLI.
- [x]  Python3 Installed.
- [x]  Docker and Kubectl installed.
- [x]  Code editor (Vscode)

# ✨Let’s Start the Project ✨

## **Part 1: Deploying the Flask application locally**

### **Step 1: Clone the code**

Clone the code from the repository:

$ git clone <repository_url>


### **Step 2: Install dependencies**

The application uses the **`psutil`** and **`Flask`, Plotly, boto3** libraries. Install them using pip:

pip3 install -r requirements.txt


### **Step 3: Run the application**

To run the application, navigate to the root directory of the project and execute the following command:

$ python3 app.py


This will start the Flask server on **`localhost:5000`**. Navigate to [http://localhost:5000/](http://localhost:5000/) on your browser to access the application.

## **Part 2: Dockerizing the Flask application**

### **Step 1: Create a Dockerfile**

Create a **`Dockerfile`** in the root directory of the project with the following contents:

Use the official Python image as the base image

FROM python:3.9-slim-buster

Set the working directory in the container

WORKDIR /app

Copy the requirements file to the working directory

COPY requirements.txt .

RUN pip3 install --no-cache-dir -r requirements.txt

Copy the application code to the working directory

COPY . .

Set the environment variables for the Flask app

ENV FLASK_RUN_HOST=0.0.0.0

Expose the port on which the Flask app will run

EXPOSE 5000

Start the Flask app when the container is run

CMD ["flask", "run"]


### **Step 2: Build the Docker image**

To build the Docker image, execute the following command:

$ docker build -t <image_name> .


### **Step 3: Run the Docker container**

To run the Docker container, execute the following command:

$ docker run -p 5000:5000 <image_name>


This will start the Flask server in a Docker container on **`localhost:5000`**. Navigate to [http://localhost:5000/](http://localhost:5000/) on your browser to access the application.

## **Part 3: Pushing the Docker image to ECR**

### **Step 1: Create an ECR repository**

Create an ECR repository using Python:

import boto3

Create an ECR client

ecr_client = boto3.client('ecr')

Create a new ECR repository

repository_name = 'my-ecr-repo' response = ecr_client.create_repository(repositoryName=repository_name)

Print the repository URI

repository_uri = response['repository']['repositoryUri'] print(repository_uri)


### **Step 2: Push the Docker image to ECR**

Push the Docker image to ECR using the push commands on the console:

$ docker push <ecr_repo_uri>:


## **Part 4: Creating an EKS cluster and deploying the app using Python**

### **Step 1: Create an EKS cluster**

Create an EKS cluster and add node group

### **Step 2: Create a node group**

Create a node group in the EKS cluster.

### **Step 3: Create deployment and service**

```jsx
from kubernetes import client, config

# Load Kubernetes configuration
config.load_kube_config()

# Create a Kubernetes API client
api_client = client.ApiClient()

# Define the deployment
deployment = client.V1Deployment(
    metadata=client.V1ObjectMeta(name="my-flask-app"),
    spec=client.V1DeploymentSpec(
        replicas=1,
        selector=client.V1LabelSelector(
            match_labels={"app": "my-flask-app"}
        ),
        template=client.V1PodTemplateSpec(
            metadata=client.V1ObjectMeta(
                labels={"app": "my-flask-app"}
            ),
            spec=client.V1PodSpec(
                containers=[
                    client.V1Container(
                        name="my-flask-container",
                        image="568373317874.dkr.ecr.us-east-1.amazonaws.com/my-cloud-native-repo:latest",
                        ports=[client.V1ContainerPort(container_port=5000)]
                    )
                ]
            )
        )
    )
)

# Create the deployment
api_instance = client.AppsV1Api(api_client)
api_instance.create_namespaced_deployment(
    namespace="default",
    body=deployment
)

# Define the service
service = client.V1Service(
    metadata=client.V1ObjectMeta(name="my-flask-service"),
    spec=client.V1ServiceSpec(
        selector={"app": "my-flask-app"},
        ports=[client.V1ServicePort(port=5000)]
    )
)

# Create the service
api_instance = client.CoreV1Api(api_client)
api_instance.create_namespaced_service(
    namespace="default",
    body=service
)

make sure to edit the name of the image on line 25 with your image Uri.

  • Once you run this file by running “python3 eks.py” deployment and service will be created.
  • Check by running following commands:
kubectl get deployment -n default (check deployments)
kubectl get service -n default (check service)
kubectl get pods -n default (to check the pods)

Once your pod is up and running, run the port-forward to expose the service

kubectl port-forward service/<service_name> 5000:5000