Categories
Machine Learning

End-to-End Metaflow ML Flow

from metaflow import FlowSpec, step, card
from sklearn.datasets import load_iris
from sklearn.model_selection import train_test_split
from sklearn.ensemble import RandomForestClassifier
from datetime import datetime

class MLFlow(FlowSpec):

    @card
    @step
    def start(self):
        """
        Load dataset and split it.
        """
        self.timestamp = datetime.utcnow()
        iris = load_iris()
        X, y = iris.data, iris.target
        self.X_train, self.X_test, self.y_train, self.y_test = train_test_split(X, y, test_size=0.2)
        self.next(self.train_model)

    @card
    @step
    def train_model(self):
        """
        Train a RandomForest model.
        """
        self.timestamp = datetime.utcnow()
        self.model = RandomForestClassifier()
        self.model.fit(self.X_train, self.y_train)
        self.next(self.evaluate_model)

    @card
    @step
    def evaluate_model(self):
        """
        Evaluate the model.
        """
        self.timestamp = datetime.utcnow()
        self.score = self.model.score(self.X_test, self.y_test)
        self.next(self.end)

    @step
    def end(self):
        """
        End the flow.
        """
        print("Flow is complete.")

if __name__ == '__main__':
    MLFlow()

python <your_script_name>.py run

Scale, Resource allocate and save the model

from metaflow import FlowSpec, step, card, resources, Parameter, S3
from sklearn.datasets import load_iris
from sklearn.model_selection import train_test_split
from sklearn.ensemble import RandomForestClassifier
from sklearn.preprocessing import StandardScaler
from datetime import datetime
import pickle

class MLFlow(FlowSpec):

    # Parameter for scaling
    scale = Parameter('scale', default=True)

    @card
    @step
    def start(self):
        self.timestamp = datetime.utcnow()
        iris = load_iris()
        X, y = iris.data, iris.target
        self.X_train, self.X_test, self.y_train, self.y_test = train_test_split(X, y, test_size=0.2)
        self.next(self.preprocess)

    @card
    @step
    def preprocess(self):
        self.timestamp = datetime.utcnow()
        if self.scale:
            scaler = StandardScaler()
            self.X_train = scaler.fit_transform(self.X_train)
            self.X_test = scaler.transform(self.X_test)
        self.next(self.train_model)

    @resources(memory=4000, cpu=2)
    @card
    @step
    def train_model(self):
        self.timestamp = datetime.utcnow()
        self.model = RandomForestClassifier()
        self.model.fit(self.X_train, self.y_train)
        self.next(self.evaluate_model)

    @card
    @step
    def evaluate_model(self):
        self.timestamp = datetime.utcnow()
        self.score = self.model.score(self.X_test, self.y_test)
        self.next(self.save_model)

    @resources(memory=4000, cpu=2)
    @card
    @step
    def save_model(self):
        self.timestamp = datetime.utcnow()
        with S3(run=self) as s3:
            with s3.open("s3://my-bucket/my-model.pkl", "wb") as f:
                pickle.dump(self.model, f)
        self.next(self.end)

    @step
    def end(self):
        print("Flow is complete.")

if __name__ == '__main__':
    MLFlow()

python <your_script_name>.py run --scale=True

requirements.txt

metaflow
scikit-learn
boto3

Dashboard

python3 <your_script_name>.py card view start
Categories
Kubernetes

Migrating GCP GKE to AWS EKS

Create Google Cloud Build Trigger (GCP)

  1. First, make sure you’ve installed and initialized the gcloud CLI tool.
  2. Create a build trigger:
gcloud builds triggers create github \
  --repo-name=<YOUR_GITHUB_REPO_NAME> \
  --repo-owner=<YOUR_GITHUB_USERNAME> \
  --branch-pattern="^master$" \
  --build-config=<PATH_TO_YOUR_CLoudbuild.yaml>

Replace placeholders like <YOUR_GITHUB_REPO_NAME>, <YOUR_GITHUB_USERNAME>, and <PATH_TO_YOUR_CLOUDBUILD.yaml> with your specific values.

Create AWS CodeBuild Project

  1. Install and configure the aws CLI tool.
  2. Create a CodeBuild project using a JSON build specification:
aws codebuild create-project \
    --name <PROJECT_NAME> \
    --source "type=GITHUB,location=https://github.com/<GITHUB_USERNAME>/<GITHUB_REPO>.git" \
    --artifacts "type=S3,location=<S3_BUCKET_NAME>" \
    --environment "type=LINUX_CONTAINER,computeType=BUILD_GENERAL1_SMALL,image=aws/codebuild/standard:5.0" \
    --service-role <IAM_ROLE_ARN> \
    --buildspec <PATH_TO_YOUR_buildspec.yml>

Replace placeholders like <PROJECT_NAME>, <GITHUB_USERNAME>, <GITHUB_REPO>, <S3_BUCKET_NAME>, <IAM_ROLE_ARN>, and <PATH_TO_YOUR_buildspec.yml> with your specific values.

Run these commands in your terminal to create the respective build setups.

Dockerfile for GCP (Utilizes Google Storage)

# Using base image
FROM python:3.8

# Set environment variables for GCP
ENV GOOGLE_APPLICATION_CREDENTIALS=/path/to/credentials.json

# Install gsutil
RUN apt-get update && apt-get install -y google-cloud-sdk

# Copy files and use gsutil
COPY . .
RUN gsutil cp gs://<your-gcp-bucket>/some-file /some-directory/

Dockerfile for AWS (Utilizes S3)

# Using base image
FROM python:3.8

# Set environment variables for AWS
ENV AWS_ACCESS_KEY_ID=<your-access-key>
ENV AWS_SECRET_ACCESS_KEY=<your-secret-key>

# Install AWS CLI
RUN apt-get update && apt-get install -y awscli

# Copy files and use AWS S3 commands
COPY . .
RUN aws s3 cp s3://<your-aws-bucket>/some-file /some-directory/

Helm Chart Deployment Example for GCP with GCR Image

Here’s a short Helm chart for deploying a Kubernetes Deployment that uses an image from Google Container Registry (GCR).

# gcp-deployment.yaml
apiVersion: apps/v1
kind: Deployment
metadata:
  name: gcp-deployment
spec:
  replicas: 1
  selector:
    matchLabels:
      app: gcp-app
  template:
    metadata:
      labels:
        app: gcp-app
    spec:
      containers:
      - name: gcp-container
        image: gcr.io/<PROJECT_ID>/<IMAGE_NAME>:<TAG>

Helm Chart Deployment Example for AWS with ECR Image

Here’s a short Helm chart for deploying a Kubernetes Deployment that uses an image from Amazon Elastic Container Registry (ECR).

# aws-deployment.yaml
apiVersion: apps/v1
kind: Deployment
metadata:
  name: aws-deployment
spec:
  replicas: 1
  selector:
    matchLabels:
      app: aws-app
  template:
    metadata:
      labels:
        app: aws-app
    spec:
      containers:
      - name: aws-container
        image: <ACCOUNT_ID>.dkr.ecr.<REGION>.amazonaws.com/<REPO_NAME>:<TAG>

Replace placeholders like <PROJECT_ID>, <IMAGE_NAME>, <TAG>, <ACCOUNT_ID>, <REGION>, and <REPO_NAME> with your specific values.

To deploy these, you’d typically run helm install or helm upgrade with these files as input.

Helm Chart for Ingress in GCP

Manual SSL

apiVersion: networking.k8s.io/v1
kind: Ingress
metadata:
  name: my-ingress
  annotations:
    kubernetes.io/ingress.global-static-ip-name: "your-static-ip"
    kubernetes.io/ingress.class: "gce"
spec:
  tls:
  - secretName: ssl-cert
  backend:
    service:
      name: my-service
      port:
        number: 80

Auto Managed SSL

apiVersion: networking.gke.io/v1
kind: ManagedCertificate
metadata:
  name: managed-cert
spec:
  domains:
    - example.com
    - dev.example.com
apiVersion: networking.k8s.io/v1
kind: Ingress
metadata:
  name: my-ingress
  annotations:
    kubernetes.io/ingress.global-static-ip-name: "your-static-ip"
    kubernetes.io/ingress.class: "gce"
    networking.gke.io/managed-certificates: managed-cert
spec:
  backend:
    service:
      name: my-service
      port:
        number: 80

Helm Chart for Ingress in AWS

apiVersion: networking.k8s.io/v1
kind: Ingress
metadata:
  name: my-ingress
  annotations:
    kubernetes.io/ingress.class: "alb"
    alb.ingress.kubernetes.io/scheme: internet-facing
    alb.ingress.kubernetes.io/target-type: ip
    alb.ingress.kubernetes.io/certificate-arn: "your-aws-certificate-arn"
spec:
  tls:
  - hosts:
    - "your.domain.com"
    secretName: aws-cert
  rules:
    ...

Helm Chart with Standard Storage in GCP

apiVersion: v1
kind: PersistentVolumeClaim
metadata:
  name: my-pvc
spec:
  storageClassName: standard
  accessModes:
    - ReadWriteOnce
  resources:
    requests:
      storage: 10Gi

Code for Creating and Assigning Storage in AWS (PV and PVC)

aws ec2 create-volume \
  --availability-zone us-west-2a \
  --size 20 \
  --volume-type gp2

# Assign the volume id to a variable
VOLUME_ID="vol-XXXXXXXXXXXXXXXXX"
apiVersion: v1
kind: PersistentVolume
metadata:
  name: my-aws-pv
spec:
  capacity:
    storage: 20Gi
  volumeID: ${VOLUME_ID}
  storageClassName: gp2
  accessModes:
    - ReadWriteOnce

---

apiVersion: v1
kind: PersistentVolumeClaim
metadata:
  name: my-aws-pvc
spec:
  storageClassName: gp2
  accessModes:
    - ReadWriteOnce
  resources:
    requests:
      storage: 20Gi

Terraform code to assign GCP Global Load Balancer IP address to A Record

provider "google" {
  credentials = file("<PATH_TO_YOUR_SERVICE_ACCOUNT_JSON>")
  project     = "<PROJECT_ID>"
  region      = "us-central1"
}

resource "google_dns_managed_zone" "my_zone" {
  name     = "my-zone"
  dns_name = "example.com."
}

resource "google_dns_record_set" "my_a_record" {
  name         = "sub.example.com."
  type         = "A"
  ttl          = 300
  managed_zone = google_dns_managed_zone.my_zone.name
  rrdatas      = [google_compute_global_address.my_global_address.address]
}

resource "google_compute_global_address" "my_global_address" {
  name = "my-global-address"
}

Replace <PATH_TO_YOUR_SERVICE_ACCOUNT_JSON> with the path to your Google Cloud service account JSON file, and <PROJECT_ID> with your Google Cloud Project ID.

Terraform code to assign AWS Route53 to Load Balancer (A Record)

provider "aws" {
  region = "us-west-2"
}

resource "aws_route53_zone" "my_zone" {
  name = "example.com."
}

resource "aws_route53_record" "my_a_record" {
  zone_id = aws_route53_zone.my_zone.zone_id
  name    = "sub.example.com"
  type    = "A"

  alias {
    name                   = aws_lb.my_lb.dns_name
    zone_id                = aws_lb.my_lb.zone_id
    evaluate_target_health = false
  }
}

resource "aws_lb" "my_lb" {
  name               = "my-lb"
  internal           = false
  load_balancer_type = "application"
  security_groups    = [aws_security_group.my_group.id]
  subnets            = [aws_subnet.my_subnet.id]
  enable_deletion_protection = false
}

AWS Terraform Code for ALB and EKS with Subnets

provider "aws" {
  region = "us-west-2"
}

# Define VPC
resource "aws_vpc" "my_vpc" {
  cidr_block = "10.0.0.0/16"
}

# Create two public subnets
resource "aws_subnet" "my_subnet1" {
  vpc_id     = aws_vpc.my_vpc.id
  cidr_block = "10.0.1.0/24"
  map_public_ip_on_launch = true  # Public Subnet
}

resource "aws_subnet" "my_subnet2" {
  vpc_id     = aws_vpc.my_vpc.id
  cidr_block = "10.0.2.0/24"
  map_public_ip_on_launch = true  # Public Subnet
}

# ALB tied to public subnets
resource "aws_lb" "my_lb" {
  name               = "my-lb"
  internal           = false
  load_balancer_type = "application"
  subnets            = [aws_subnet.my_subnet1.id, aws_subnet.my_subnet2.id]
  enable_deletion_protection = false
}

# EKS Cluster
resource "aws_eks_cluster" "this" {
  name     = "my-cluster"
  role_arn = aws_iam_role.eks_cluster.arn

  vpc_config {
    subnet_ids = [aws_subnet.my_subnet1.id, aws_subnet.my_subnet2.id]
  }
}

resource "aws_iam_role" "eks_cluster" {
  name = "eks-cluster"

  assume_role_policy = jsonencode({
    Version = "2012-10-17",
    Statement = [
      {
        Action = "sts:AssumeRole",
        Effect = "Allow",
        Principal = {
          Service = "eks.amazonaws.com"
        }
      }
    ]
  })
}

GCP Terraform Code for Global Load Balancer and GKE with Subnets

provider "google" {
  credentials = file("<PATH_TO_YOUR_SERVICE_ACCOUNT_JSON>")
  project     = "<PROJECT_ID>"
  region      = "us-central1"
}

# Create VPC
resource "google_compute_network" "my_network" {
  name = "my-network"
}

# Create public subnet
resource "google_compute_subnetwork" "my_public_subnet" {
  name          = "my-public-subnet"
  ip_cidr_range = "10.0.1.0/24"
  network       = google_compute_network.my_network.self_link
  region        = "us-central1"  # Public Subnet
}

# Create Global HTTP Load Balancer components
resource "google_compute_global_forwarding_rule" "global_forwarding_rule" {
  name       = "my-global-lb-forwarding-rule"
  target     = google_compute_target_http_proxy.default.self_link
  port_range = "80"
  ip_address = google_compute_global_address.default.address
}

resource "google_compute_global_address" "default" {
  name = "my-global-ip"
}

resource "google_compute_target_http_proxy" "default" {
  name  = "my-http-proxy"
  url_map = google_compute_url_map.default.self_link
}

resource "google_compute_url_map" "default" {
  name        = "my-url-map"
  default_service = google_compute_backend_service.default.self_link
}

resource "google_compute_backend_service" "default" {
  name        = "my-backend-service"
  port_name   = "http"
  protocol    = "HTTP"
  timeout_sec = 10

  backend {
    group = google_compute_instance_group_manager.default.instance_group
  }
}

resource "google_compute_instance_group_manager" "default" {
  name = "my-instance-group"
  base_instance_name = "my-instance"
  instance_template = google_compute_instance_template.default.self_link
  zone = "us-central1-a"
}

resource "google_compute_instance_template" "default" {
  name_prefix  = "my-instance-template-"
  machine_type = "g1-small"
  tags         = ["http-server"]

  network_interface {
    network = google_compute_network.my_network.name
  }
}

# GKE Cluster
resource "google_container_cluster" "primary" {
  name     = "my-gke-cluster"
  location = "us-central1"
  network    = google_compute_network.my_network.name
  subnetwork = google_compute_subnetwork.my_public_subnet.name  # Public Subnet

  initial_node_count = 3
}

Public and Private Subnets in Load Balancers

  • AWS: You can associate both public and private subnets with an ALB. However, the ALB itself is either internal or internet-facing, not both. You would typically use an internet-facing ALB with public subnets and an internal ALB with private subnets.
  • GCP: Google Cloud Load Balancers operate differently than AWS ALBs. The Global Load Balancer doesn’t directly associate with subnets; rather, it directs traffic to instance groups, which can be in different regions and subnets. You can have backend services in both public and private subnets.
Categories
Automation

Jumpcutter and Auto-Editor Commands

Jumpcutter

# Clone repository
git clone https://github.com/carykh/jumpcutter.git

# Move into directory
cd jumpcutter

# Install Requirements
pip install -r requirements.txt

# Basic Usage
python jumpcutter.py --input_file <input_video_file>

# Specify silence speed
python jumpcutter.py --input_file <input_video_file> --silent_speed 1

# Specify sounded speed
python jumpcutter.py --input_file <input_video_file> --sounded_speed 1.2

# Debug (No specific debug flag)
python jumpcutter.py --input_file <input_video_file> --frame_margin 1

To find the value for <input_video_file>:

ls *.mp4  # Lists all mp4 files in the current directory

Auto-Editor

# Install auto-editor
pip install auto-editor

# Basic Usage
auto-editor <input_video_file>

# Specify output format
auto-editor <input_video_file> --format mp4

# Change speed factor
auto-editor <input_video_file> --fast_speed 1.5

# Specify audio language
auto-editor <input_video_file> --audio_language eng

# Debug
auto-editor <input_video_file> --debug

To find the value for <input_video_file>:

ls *.mp4  # Lists all mp4 files in the current directory

Commands for Debugging

# For auto-editor
auto-editor <input_video_file> --debug

# For jumpcutter (No specific debug flag)
python jumpcutter.py --input_file <input_video_file> --frame_margin 1

Replace <input_video_file> with your video file name.

Categories
Kubernetes

Adding MySQL Dashboards to Grafana using Helm

mysql-exporter-values.yaml

mysql:
  db: ""
  host: "172.1.0.6"
  pass: "IjTdP4ri79"
  port: 3306
  protocol: ""
  user: "root"

serviceMonitor:
  # enabled should be set to true to enable prometheus-operator discovery of this service
  enabled: true
  additionalLabels:
    release: grafana

Install Kube-Prometheus-Stack on Cluster

  1. Add Prometheus Helm Repo
    bash helm repo add prometheus-community https://prometheus-community.github.io/helm-charts
  2. Update Helm Repo
    bash helm repo update
  3. Create Namespace ‘metrics’
    bash kubectl create ns metrics
  4. Set Current Context to ‘metrics’ Namespace
    bash kubectl config set-context --current --namespace=metrics
  5. Deploy Grafana & Kube-Prometheus-Stack
    bash helm upgrade --install grafana prometheus-community/kube-prometheus-stack

Install Prometheus MySQL Exporter

  1. Add Prometheus Helm Repo (if not added)
    bash helm repo add prometheus-community https://prometheus-community.github.io/helm-charts
  2. Update Helm Repo
    bash helm repo update
  3. Deploy MySQL Exporter
    bash helm upgrade --install mysql-exporter prometheus-community/prometheus-mysql-exporter -f mysql-exporter-values.yaml

Install Prometheus MySQL Exporter Dashboard

  1. Grafana Dashboard IDs for MySQL Monitoring
    • 14057
    • 7362

Combined Code Block

# Add Prometheus Helm Repo and Update
helm repo add prometheus-community https://prometheus-community.github.io/helm-charts
helm repo update

# Create Namespace 'metrics' and Set Context
kubectl create ns metrics
kubectl config set-context --current --namespace=metrics

# Deploy Grafana & Kube-Prometheus-Stack
helm upgrade --install grafana prometheus-community/kube-prometheus-stack

# Deploy MySQL Exporter
helm upgrade --install mysql-exporter prometheus-community/prometheus-mysql-exporter -f mysql-exporter-values.yaml
Categories
Kubernetes

Enable HTTPS on AWS ALB with Kubernetes

Step-01: Register a Domain in Route53 (if not exists)

  1. AWS Management Console -> Services -> Route53 -> Registered Domains
  2. Click on “Register Domain”
  3. Enter domain: example.com -> Click “Check”
  4. “Add to cart” -> “Continue”
  5. Fill Contact Details -> “Continue”
  6. Enable “Automatic Renewal”
  7. Accept Terms -> “Complete Order”

Step-02: Create SSL Certificate in Certificate Manager

  1. Services -> Certificate Manager -> “Create a Certificate”
  2. “Request a Certificate” -> Choose “Request a public certificate”
  3. Add domain: *.example.com
  4. Select “DNS Validation” -> “Confirm & Request”
  5. “Create record in Route 53”
  6. Wait 5-10 mins -> Check Validation Status

Step-03: Update Ingress Manifest with SSL Annotations

07-ALB-Ingress-SSL.yml

# SSL Annotations
alb.ingress.kubernetes.io/listen-ports: '[{"HTTPS":443}, {"HTTP":80}]'
alb.ingress.kubernetes.io/certificate-arn: <YOUR_CERTIFICATE_ARN>

To get <YOUR_CERTIFICATE_ARN>, run: aws acm list-certificates --query 'CertificateSummaryList[*].CertificateArn' --output text

Step-04: Deploy Manifests and Test

  1. Deploy
kubectl apply -f kube-manifests/
  1. Verify
  • Load Balancer: 80 & 443
  • Target Groups: Health checks
  • kubectl get ingress

Step-05: Add DNS in Route53

  1. Services -> Route 53 -> Hosted Zones -> Click example.com
  2. “Create a Record Set”
  3. Name: ssldemo.example.com
  4. Alias: Yes
  5. Alias Target: <ALB_DNS_Name>
  6. “Create”

To get <ALB_DNS_Name>, run: kubectl get svc -n <namespace> -o=jsonpath='{.items[?(@.metadata.annotations."service\.beta\.kubernetes\.io/aws-load-balancer-dns-name")].metadata.annotations."service\.beta\.kubernetes\.io/aws-load-balancer-dns-name"}'

Step-06: Access Application

  • HTTP URLs: http://ssldemo.example.com/<your_app_endpoints>
  • HTTPS URLs: https://ssldemo.example.com/<your_app_endpoints>

Debug Commands (If needed)

aws route53 list-hosted-zones
aws acm list-certificates
kubectl get svc
kubectl get ingress

Combined One Block Code

aws acm list-certificates --query 'CertificateSummaryList[*].CertificateArn' --output text
kubectl apply -f kube-manifests/
kubectl get svc -n <namespace> -o=jsonpath='{.items[?(@.metadata.annotations."service\.beta\.kubernetes\.io/aws-load-balancer-dns-name")].metadata.annotations."service\.beta\.kubernetes\.io/aws-load-balancer-dns-name"}'
aws route53 list-hosted-zones
aws acm list-certificates
kubectl get svc
kubectl get ingress
Categories
Kubernetes

Install SSL in an EKS Cluster Using cert-manager

Steps to Install SSL in an EKS Cluster Using cert-manager and aws-pca-issuer

Prerequisites

  • AWS CLI, eksctl, kubectl, and Helm must be installed.

1. Create IAM Policy File

Create a file named pca-iam-policy.json and save the IAM policy inside it.

echo '{
  "Version": "2012-10-17",
  "Statement": [
    {
      "Sid": "awspcaissuer",
      "Action": [
        "acm-pca:DescribeCertificateAuthority",
        "acm-pca:GetCertificate",
        "acm-pca:IssueCertificate"
      ],
      "Effect": "Allow",
      "Resource": "arn:aws:acm-pca:<region>:<account_id>:certificate-authority/<resource_id>"
    }
  ]
}' > pca-iam-policy.json

2. Create IAM Policy

Run the following AWS CLI command.

aws iam create-policy \
    --policy-name AWSPCAIssuerIAMPolicy \
    --policy-document file://pca-iam-policy.json

Note down the returned policy ARN.

3. Create IAM Role and ServiceAccount

Replace <AWS_ACCOUNT_ID> with your AWS account ID.

eksctl create iamserviceaccount \
--cluster=nlb-lab \
--namespace=aws-pca-issuer \
--name=aws-pca-issuer \
--attach-policy-arn=arn:aws:iam::<AWS_ACCOUNT_ID>:policy/AWSPCAIssuerIAMPolicy \
--override-existing-serviceaccounts \
--approve

4. Install cert-manager and aws-pca-issuer

helm repo add awspca https://cert-manager.github.io/aws-privateca-issuer
helm install aws-pca-issuer awspca/aws-privateca-issuer -n aws-pca-issuer --set serviceAccount.create=false --set serviceAccount.name=aws-pca-issuer

5. Verify Installation

kubectl get pods --namespace aws-pca-issuer

6. Create ClusterIssuer

Replace placeholders and create cluster-issuer.yaml.

apiVersion: awspca.cert-manager.io/v1beta1
kind: AWSPCAClusterIssuer
metadata:
  name: demo-test-root-ca
spec:
  arn: arn:aws:acm-pca:<region>:<account-id>:certificate-authority/<resource_id>
  region: <region>
kubectl apply -f cluster-issuer.yaml

7. Create Certificate

Replace domain name and create nlb-lab-tls.yaml.

kind: Certificate
apiVersion: cert-manager.io/v1
metadata:
  name: nlb-lab-tls-cert
spec:
  commonName: www.nlb-lab.com
  dnsNames:
    - www.nlb-lab.com
    - nlb-lab.com
  duration: 2160h0m0s
  issuerRef:
    group: awspca.cert-manager.io
    kind: AWSPCAClusterIssuer
    name: demo-test-root-ca
  renewBefore: 360h0m0s
  secretName: nlb-tls-app-secret
  usages:
    - server auth
    - client auth
  privateKey:
    algorithm: "RSA"
    size: 2048
kubectl apply -f nlb-lab-tls.yaml

8. Verify Certificate

kubectl get certificate

Combined Code Block

#!/bin/bash

# Define variables
REGION="<region>"
ACCOUNT_ID="<account_id>"
RESOURCE_ID="<resource_id>"

# Create IAM policy
cat <<EOF > pca-iam-policy.json
{
  "Version": "2012-10-17",
  "Statement": [
    {
      "Sid": "awspcaissuer",
      "Action": [
        "acm-pca:DescribeCertificateAuthority",
        "acm-pca:GetCertificate",
        "acm-pca:IssueCertificate"
      ],
      "Effect": "Allow",
      "Resource": "arn:aws:acm-pca:$REGION:$ACCOUNT_ID:certificate-authority/$RESOURCE_ID"
    }
  ]
}
EOF

# Create IAM Policy
aws iam create-policy \
    --policy-name AWSPCAIssuerIAMPolicy \
    --policy-document file://pca-iam-policy.json

# Create IAM Role and ServiceAccount
eksctl create iamserviceaccount \
--cluster=nlb-lab \
--namespace=aws-pca-issuer \
--name=aws-pca-issuer \
--attach-policy-arn=arn:aws:iam::$ACCOUNT_ID:policy/AWSPCAIssuerIAMPolicy \
--override-existing-serviceaccounts \
--approve

# Install cert-manager and aws-pca-issuer
helm repo add awspca https://cert-manager.github.io/aws-privateca-issuer
helm install aws-pca-issuer awspca/aws-privateca-issuer -n aws-pca-issuer --set serviceAccount.create=false --set serviceAccount.name=aws-pca-issuer

# Verify Installation
kubectl get pods --namespace aws-pca-issuer

# Create ClusterIssuer
kubectl apply -f cluster-issuer.yaml

# Create Certificate
kubectl apply -f nlb-lab-tls.yaml

# Verify Certificate
kubectl get certificate

Replace placeholders like <region>, <account_id>, and <resource_id> with actual values. Use AWS CLI commands or refer to your AWS console to find these.

Categories
Apache

No code signing authority for module

Problem Summary:

You can’t load the PHP module in Apache on macOS because it’s not signed.

Steps to Fix:

1. Install codesign Tool:

xcode-select --install

2. Create Certificate Authority & Code Signing Certificate

  • Open “Keychain Access” (CMD+Space -> type “Keychain Access”).
  • Follow instructions in these articles to create certificates:
  • Article 1
  • Article 2
  • Article 3

3. Sign PHP Module

Replace <common_name> with your common name.

common_name="<common_name>"
codesign --sign "$common_name" --force --keychain ~/Library/Keychains/login.keychain-db /usr/local/opt/php/lib/httpd/modules/libphp.so

4. Verify Signing

codesign -dv --verbose=4 "/usr/local/opt/php/lib/httpd/modules/libphp.so"

5. Update Apache Config

Replace <authority> with the Authority from step 4.

authority="<authority>"
sed -i '' "s|LoadModule php_module.*|LoadModule php_module /usr/local/opt/php/lib/httpd/modules/libphp.so \"$authority\"|" /etc/apache2/httpd.conf

6. Restart Apache Server

apachectl restart

7. Debugging

Check Apache config and logs.

apachectl configtest
cat /var/log/apache2/error_log

Combined Code Block:

# Step 1
xcode-select --install
# Step 3
common_name="<common_name>"
codesign --sign "$common_name" --force --keychain ~/Library/Keychains/login.keychain-db /usr/local/opt/php/lib/httpd/modules/libphp.so
# Step 4
codesign -dv --verbose=4 "/usr/local/opt/php/lib/httpd/modules/libphp.so"
# Step 5
authority="<authority>"
sed -i '' "s|LoadModule php_module.*|LoadModule php_module /usr/local/opt/php/lib/httpd/modules/libphp.so \"$authority\"|" /etc/apache2/httpd.conf
# Step 6
apachectl restart
# Step 7
apachectl configtest
cat /var/log/apache2/error_log
Categories
Kubernetes

ClusterRoleBinding vs RoleBinding: A Comparison

ClusterRoleBindingRoleBinding
ScopeApplies to the entire cluster. It’s like a pass for the whole city.Applies to a specific namespace (like a building within the city).
PermissionsGrants permissions across all namespaces. Users can perform certain actions in every part of the cluster.Grants permissions within a specific namespace. Users can perform certain actions only within a designated part of the cluster.
Use CaseUsed when you need to give someone permissions that apply to the whole cluster.Used when you want to limit someone’s permissions to a specific namespace within the cluster.
Categories
Kubernetes

Kubernetes Dashboard Timeout Issue fix

{
  "kind": "Status",
  "apiVersion": "v1",
  "metadata": {},
  "status": "Failure",
  "message": "error trying to reach service: dial tcp 172.7.3.82:8443: i/o timeout",
  "reason": "ServiceUnavailable",
  "code": 503
}

Here’s a concise guide to solve the common Kubernetes service unavailability issue:

StepsCommands/Actions
1. Forward the Pod PortUse your terminal to input:
kubectl port-forward -n kubernetes-dashboard service/kubernetes-dashboard 8080:443
2. Access the DashboardOpen Firefox and visit:
https://localhost:8080
Accept the security risk prompt.
3. Log InGenerate a token by executing the necessary commands depending on your specific setup. Copy and paste this token into the login form field.

Remember: This method involves a security risk due to the self-signed certificate, use it as a quick workaround knowing the implications.

Generate token

echo "
apiVersion: v1
kind: ServiceAccount
metadata:
  name: admin-user
  namespace: kubernetes-dashboard
---
apiVersion: rbac.authorization.k8s.io/v1
kind: ClusterRoleBinding
metadata:
  name: admin-user
roleRef:
  apiGroup: rbac.authorization.k8s.io
  kind: ClusterRole
  name: cluster-admin
subjects:
- kind: ServiceAccount
  name: admin-user
  namespace: kubernetes-dashboard
" | kubectl apply -f - && echo "
apiVersion: v1
kind: Secret
metadata:
  name: admin-user
  namespace: kubernetes-dashboard
  annotations:
    kubernetes.io/service-account.name: \"admin-user\"
type: kubernetes.io/service-account-token
" | kubectl apply -f - && kubectl get secret admin-user -n kubernetes-dashboard -o jsonpath={".data.token"} | base64 -d
Categories
Kubernetes

Comparing StatefulSets and Deployments: Elasticsearch, MySQL, and MongoDB

Here’s a comparison of using StatefulSets and Deployments for Elasticsearch, MySQL, and MongoDB, along with the reasoning for each:

AspectStatefulSet (Elasticsearch)Deployment (MySQL, MongoDB)
ScalingVertically or Horizontally scaled based on cluster requirementsHorizontally scaled using replication or sharding
Stable Network IdentityRequires stable network identity for proper cluster formationNo need for stable network identity for clustering
Persistent Data StorageRequires persistent data storage for each nodeRequires persistent data storage for each replica/shard
Scaling ControlOrdered scaling for controlled cluster reconfigurationIndependent scaling of replicas or shards
Rolling UpdatesOrdered rolling updates for minimal downtime during upgradesRolling updates for minimal downtime during upgrades
High AvailabilityAchieved through node replication and data shardingAchieved through replication and clustering
Pod HostnamePods have stable and unique hostnames for cluster membershipPods can have dynamically assigned names
Use CaseUsed for search, indexing, and data analysisUsed for relational database management (MySQL) and NoSQL
Communication between PodsPods communicate using stable hostnamesPods can communicate through Kubernetes Services
ComplexityMore complex setup and maintenance due to stateful natureSimpler setup and maintenance due to stateless nature

Reasoning for StatefulSet (Elasticsearch):

  • Elasticsearch relies on stable network identities for proper cluster formation. StatefulSets provide stable, unique hostnames for each pod, which is crucial for forming and maintaining the cluster.
  • Persistent data storage is essential for Elasticsearch to ensure data availability and prevent data loss. StatefulSets allow the use of PersistentVolumeClaims (PVCs) for persistent storage.
  • Elasticsearch clusters are typically vertically or horizontally scaled based on the requirements. StatefulSets provide ordered scaling, ensuring controlled reconfiguration during scaling.

Reasoning for Deployment (MySQL, MongoDB):

  • MySQL and MongoDB can achieve high availability and horizontal scalability through replication and sharding mechanisms, respectively. These mechanisms do not depend on stable network identities.
  • Both databases can be horizontally scaled by adding more read replicas (MySQL) or sharded nodes (MongoDB), which can be independently deployed using Deployments.
  • Rolling updates are crucial for minimal downtime during upgrades or changes to the database. Deployments support rolling updates, ensuring continuous availability.

In summary, using StatefulSets is more suitable for Elasticsearch due to its stateful nature and the need for stable network identities and persistent storage. Deployments are preferred for MySQL and MongoDB due to their stateless nature and ability to achieve high availability and horizontal scalability through replication and sharding. The choice depends on the specific requirements and characteristics of each database system.