Voici comment mettre en place rapidement un environnement de développement avec MySQL, PostgreSQL, MongoDB, Redis et Kafka à l'aide de Docker Compose, avec des images bitnami , les variables d'environnement et les outils d'interface utilisateur pour chaque base de données. Nous allons suivre le processus étape par étape :
Préconfiguré et optimisé : Les images Bitnami sont préconfigurées avec les meilleures pratiques, ce qui les rend plus faciles à configurer et à optimiser pour les cas d'utilisation courants.
Sécurité : Bitnami met régulièrement à jour ses images pour corriger les vulnérabilités, offrant ainsi une option plus sécurisée par rapport à certaines images gérées par la communauté qui peuvent ne pas être mises à jour aussi fréquemment.
Cohérence entre les environnements : Bitnami garantit que ses images fonctionnent de manière cohérente dans différents environnements, ce qui en fait un bon choix pour les configurations de test, de développement et de production.
Facilité d'utilisation : Ils incluent souvent des scripts et des valeurs par défaut qui simplifient les déploiements, réduisant ainsi le besoin de configuration et d'installation manuelles.
Documentation et assistance : Bitnami fournit une documentation détaillée et parfois une assistance via sa société mère, VMware, ce qui peut être utile pour le dépannage et l'utilisation en entreprise.
Une autre note d'importation concerne les licences, cela peut varier, mais le logiciel bitnami est généralement gratuit, ses conteneurs et packages sont basés sur des logiciels open source et utilisent des licences comme MIT, Apache 2.0 ou GPL... Lire la suite À propos des licences pour les sources ouvertes
Créez la structure de projet suivante :
dev-environment/ ├── components # for mounting container volumes ├── scripts/ │ ├── pgadmin │ │ ├──servers.json # for pgadmin automatically load postgreDB │ ├── create-topics.sh # for creating kafka topics │ ├── mongo-init.sh # init script for mongodb │ ├── mysql-init.sql # init script for mysql │ ├── postgres-init.sql # init script for postgre ├── .env ├── docker-compose.yml
Créez un fichier .env avec le contenu suivant :
# MySQL Configuration MYSQL_PORT=23306 MYSQL_USERNAME=dev-user MYSQL_PASSWORD=dev-password MYSQL_DATABASE=dev_database # PostgreSQL Configuration POSTGRES_PORT=25432 POSTGRES_USERNAME=dev-user POSTGRES_PASSWORD=dev-password POSTGRES_DATABASE=dev_database # MongoDB Configuration MONGO_PORT=27017 MONGO_USERNAME=dev-user MONGO_PASSWORD=dev-password MONGO_DATABASE=dev_database # Redis Configuration REDIS_PORT=26379 REDIS_PASSWORD=dev-password # Kafka Configuration KAFKA_PORT=29092 KAFKA_USERNAME=dev-user KAFKA_PASSWORD=dev-password # UI Tools Configuration PHPMYADMIN_PORT=280 PGADMIN_PORT=281 MONGOEXPRESS_PORT=28081 REDIS_COMMANDER_PORT=28082 KAFKA_UI_PORT=28080 # Data Directory for Volumes DATA_DIR=./
Créez le fichier docker-compose.yml :
version: '3.8' services: dev-mysql: image: bitnami/mysql:latest # This container_name can be used for internal connections between containers (running on the same docker virtual network) container_name: dev-mysql ports: # This mapping means that requests sent to the ${MYSQL_PORT} on the host machine will be forwarded to port 3306 in the dev-mysql container. This setup allows users to access the MySQL database from outside the container, such as from a local machine or another service. - '${MYSQL_PORT}:3306' environment: # Setup environment variables for container - MYSQL_ROOT_PASSWORD=${MYSQL_PASSWORD} - MYSQL_USER=${MYSQL_USERNAME} - MYSQL_PASSWORD=${MYSQL_PASSWORD} - MYSQL_DATABASE=${MYSQL_DATABASE} volumes: # Syncs msyql data from inside container to host machine, to keep them accross container restarts - '${DATA_DIR}/components/mysql/data:/bitnami/mysql/data' # Add custom script to init db - './scripts/mysql-init.sql:/docker-entrypoint-initdb.d/init.sql' phpmyadmin: image: phpmyadmin/phpmyadmin:latest container_name: dev-phpmyadmin # The depends_on option in Docker specifies that a container should be started only after the specified dependent container (e.g., dev-mysql) has been started (but not ensuring that it is ready) depends_on: - dev-mysql ports: - '${PHPMYADMIN_PORT}:80' environment: - PMA_HOST=dev-mysql # use internal port for internal connections, not exposed port ${MYSQL_PORT} - PMA_PORT=3306 - PMA_USER=${MYSQL_USERNAME} - PMA_PASSWORD=${MYSQL_PASSWORD} #======= dev-postgresql: image: bitnami/postgresql:latest container_name: dev-postgresql ports: - '${POSTGRES_PORT}:5432' environment: - POSTGRESQL_USERNAME=${POSTGRES_USERNAME} - POSTGRESQL_PASSWORD=${POSTGRES_PASSWORD} - POSTGRESQL_DATABASE=${POSTGRES_DATABASE} volumes: # This setup will ensure that PostgreSQL data from inside container is synced to host machine, enabling persistence across container restarts. - '${DATA_DIR}/components/postgresql/data:/bitnami/postgresql/data' # Most relational databases support a special docker-entrypoint-initdb.d folder. This folder is used to initialise the database automatically when the container is first created. # We can put .sql or .sh scripts there, and Docker will automatically, here ./scripts/postgres-init.sql from host machine be automatically copied to the Docker container during the build and then run it - ./scripts/postgres-init.sql:/docker-entrypoint-initdb.d/init.sql:ro pgadmin: image: dpage/pgadmin4:latest container_name: dev-pgadmin depends_on: - dev-postgresql ports: - '${PGADMIN_PORT}:80' # user: root used to ensure that the container has full administrative privileges, # necessary when performing actions that require elevated permissions, such as mounting volumes (properly read or write to the mounted volumes), executing certain entrypoint commands, or accessing specific directories from host machine user: root environment: # PGADMIN_DEFAULT_EMAIL and PGADMIN_DEFAULT_PASSWORD - Sets the default credentials for the pgAdmin user - PGADMIN_DEFAULT_EMAIL=admin@dev.com - PGADMIN_DEFAULT_PASSWORD=${POSTGRES_PASSWORD} # PGADMIN_CONFIG_SERVER_MODE - determines whether pgAdmin runs in server mode (multi-user) or desktop mode (single-user). We’re setting it to false, so we won’t be prompted for login credentials - PGADMIN_CONFIG_SERVER_MODE=False # PGADMIN_CONFIG_MASTER_PASSWORD_REQUIRED - controls whether a master password is required to access saved server definitions and other sensitive information - PGADMIN_CONFIG_MASTER_PASSWORD_REQUIRED=False volumes: # This setup will ensure that PGAdmin data from inside container is synced to host machine, enabling persistence across container restarts. - '${DATA_DIR}/components/pgadmin:/var/lib/pgadmin' # This setup to make PGAdmin automatically detect and connect to PostgreSQL when it starts (following the config being set in servers.json) - ./scripts/pgadmin/servers.json:/pgadmin4/servers.json:ro #======= dev-mongodb: image: bitnami/mongodb:latest container_name: dev-mongodb ports: - '${MONGO_PORT}:27017' environment: - MONGO_INITDB_ROOT_USERNAME=${MONGO_USERNAME} - MONGO_INITDB_ROOT_PASSWORD=${MONGO_PASSWORD} - MONGO_INITDB_DATABASE=${MONGO_DATABASE} - MONGODB_ROOT_USER=${MONGO_USERNAME} - MONGODB_ROOT_PASSWORD=${MONGO_PASSWORD} - MONGODB_DATABASE=${MONGO_DATABASE} volumes: - '${DATA_DIR}/components/mongodb/data:/bitnami/mongodb' # This line maps ./scripts/mongo-init.sh from host machine to /docker-entrypoint-initdb.d/mongo-init.sh inside container with 'ro' mode (read only mode) which means container can't modify the mounted file - ./scripts/mongo-init.sh:/docker-entrypoint-initdb.d/mongo-init.sh:ro # - ./scripts/mongo-init.sh:/bitnami/scripts/mongo-init.sh:ro mongo-express: image: mongo-express:latest container_name: dev-mongoexpress depends_on: - dev-mongodb ports: - '${MONGOEXPRESS_PORT}:8081' environment: - ME_CONFIG_MONGODB_ENABLE_ADMIN=true - ME_CONFIG_MONGODB_ADMINUSERNAME=${MONGO_USERNAME} - ME_CONFIG_MONGODB_ADMINPASSWORD=${MONGO_PASSWORD} # - ME_CONFIG_MONGODB_SERVER=dev-mongodb # - ME_CONFIG_MONGODB_PORT=${MONGO_PORT} - ME_CONFIG_MONGODB_URL=mongodb://${MONGO_USERNAME}:${MONGO_PASSWORD}@dev-mongodb:${MONGO_PORT}/${MONGO_DATABASE}?authSource=admin&ssl=false&directConnection=true restart: unless-stopped # 'restart: unless-stopped' restarts a container automatically unless it is explicitly stopped by the user. # some others: 1. 'no': (Default option if not specified) meaning the container won't automatically restart if it stops or crashes. # 2. 'always': The container will restart regardless of the reason it stopped, including if Docker is restarted. # 3. 'on-failure': The container will restart only if it exits with a non-zero status indicating an error. (and won't restart if it stops when completing as short running task and return 0 status). #======= dev-redis: image: bitnami/redis:latest container_name: dev-redis ports: - '${REDIS_PORT}:6379' environment: - REDIS_PASSWORD=${REDIS_PASSWORD} volumes: - '${DATA_DIR}/components/redis:/bitnami/redis' networks: - dev-network redis-commander: image: rediscommander/redis-commander:latest container_name: dev-redis-commander depends_on: - dev-redis ports: - '${REDIS_COMMANDER_PORT}:8081' environment: - REDIS_HOST=dev-redis # While exposed port ${REDIS_PORT} being bind to host network, redis-commander still using internal port 6379 (being use internally inside docker virtual network) to connect to redis - REDIS_PORT=6379 - REDIS_PASSWORD=${REDIS_PASSWORD} networks: - dev-network # This networks setup is optional, in case not being set, both redis-commader and redis will both be assigned to default docker network (usually named bridge) and still being able to connect each other #======= dev-kafka: image: 'bitnami/kafka:latest' container_name: dev-kafka ports: - '${KAFKA_PORT}:9094' environment: # Sets the timezone for the container to "Asia/Shanghai". This ensures that logs and timestamps inside the Kafka container align with the Shanghai timezone. - TZ=Asia/Shanghai # KAFKA_CFG_NODE_ID=0: Identifies the Kafka node with ID 0. This is crucial for multi-node Kafka clusters to distinguish each node uniquely. - KAFKA_CFG_NODE_ID=0 # KAFKA_CFG_PROCESS_ROLES=controller,broker: Specifies the roles the Kafka node will perform, in this case, both as a controller (managing cluster metadata) and a broker (handling messages). - KAFKA_CFG_PROCESS_ROLES=controller,broker # KAFKA_CFG_CONTROLLER_QUORUM_VOTERS=0@<your_host>:9093: Defines the quorum voters for the Kafka controllers. It indicates that node 0 (the current node) acts as a voter for controller decisions and will be accessible at 9093 on <your_host>. - KAFKA_CFG_CONTROLLER_QUORUM_VOTERS=0@<your_host>:9093 # The following lists different listeners for Kafka. Each listener binds a protocol to a specific port: # PLAINTEXT for client connections (:9092). CONTROLLER for internal controller communication (:9093). EXTERNAL for external client access (:9094).SASL_PLAINTEXT for SASL-authenticated clients (:9095). - KAFKA_CFG_LISTENERS=PLAINTEXT://:9092,CONTROLLER://:9093,EXTERNAL://:9094,SASL_PLAINTEXT://:9095 # KAFKA_CFG_ADVERTISED_LISTENERS specifies how clients should connect to Kafka externally: # PLAINTEXT at dev-kafka:9092 for internal communication. EXTERNAL at 127.0.0.1:${KAFKA_PORT} (host access). SASL_PLAINTEXT for SASL connections (kafka:9095). - KAFKA_CFG_ADVERTISED_LISTENERS=PLAINTEXT://dev-kafka:9092,EXTERNAL://127.0.0.1:${KAFKA_PORT},SASL_PLAINTEXT://kafka:9095 # The following maps security protocols to each listener. For example, CONTROLLER uses PLAINTEXT, and EXTERNAL uses SASL_PLAINTEXT. - KAFKA_CFG_LISTENER_SECURITY_PROTOCOL_MAP=CONTROLLER:PLAINTEXT,EXTERNAL:SASL_PLAINTEXT,PLAINTEXT:PLAINTEXT,SASL_PLAINTEXT:SASL_PLAINTEXT # Indicates that the CONTROLLER role should use the CONTROLLER listener for communications. - KAFKA_CFG_CONTROLLER_LISTENER_NAMES=CONTROLLER # Specifies users with relevant passwords that can connect to Kafka using SASL authentication - KAFKA_CLIENT_USERS=${KAFKA_USERNAME} - KAFKA_CLIENT_PASSWORDS=${KAFKA_PASSWORD} volumes: - '${DATA_DIR}/components/kafka/data:/bitnami/kafka/data' # Maps a local file create-topics.sh from the ./scripts directory to the path /opt/bitnami/kafka/create_topic.sh inside the Kafka container # This script can be used to automatically create Kafka topics when the container starts - ./scripts/create-topics.sh:/opt/bitnami/kafka/create_topic.sh:ro # Following command starts the Kafka server in the background using /opt/bitnami/scripts/kafka/run.sh. then sleep 5 to ensure that the Kafka server is fully up and running. # Executes the create_topic.sh script, which is used to create Kafka topics. Uses 'wait' to keep the script running until all background processes (like the Kafka server) finish, command: > bash -c " /opt/bitnami/scripts/kafka/run.sh & sleep 5; /opt/bitnami/kafka/create_topic.sh; wait " kafka-ui: image: provectuslabs/kafka-ui:latest container_name: dev-kafka-ui ports: - '${KAFKA_UI_PORT}:8080' environment: # Sets the name of the Kafka cluster displayed in the UI as "local." - KAFKA_CLUSTERS_0_NAME=local # Specifies the address (dev-kafka:9092) for the Kafka broker that the UI should connect to. - KAFKA_CLUSTERS_0_BOOTSTRAPSERVERS=dev-kafka:9092 # Uses the provided ${KAFKA_USERNAME} for SASL (Simple Authentication and Security Layer) authentication with the Kafka cluster. - KAFKA_CLUSTERS_0_SASL_USER=${KAFKA_USERNAME} # Uses the ${KAFKA_PASSWORD} for authentication with the Kafka broker. - KAFKA_CLUSTERS_0_SASL_PASSWORD=${KAFKA_PASSWORD} # Sets the SASL mechanism as 'PLAIN', which is a simple username-password-based authentication method. - KAFKA_CLUSTERS_0_SASL_MECHANISM=PLAIN # Configures the communication protocol as SASL_PLAINTEXT, which means it uses SASL for authentication without encryption over plaintext communication. - KAFKA_CLUSTERS_0_SECURITY_PROTOCOL=SASL_PLAINTEXT depends_on: - dev-kafka networks: dev-network: driver: bridge
Créez les scripts nécessaires dans le dossier scripts.
pgadmin/servers.json :
{ "Servers": { "1": { "Name": "Local PostgreSQL", "Group": "Servers", "Host": "dev-postgresql", "Port": 5432, "MaintenanceDB": "dev_database", "Username": "dev-user", "Password": "dev-password", "SSLMode": "prefer", "Favorite": true } } }
create-topics.sh :
# Wait for Kafka to be ready until /opt/bitnami/kafka/bin/kafka-topics.sh --list --bootstrap-server localhost:9092; do echo "Waiting for Kafka to be ready..." sleep 2 done # Create topics /opt/bitnami/kafka/bin/kafka-topics.sh --create --bootstrap-server localhost:9092 --replication-factor 1 --partitions 8 --topic latestMsgToRedis /opt/bitnami/kafka/bin/kafka-topics.sh --create --bootstrap-server localhost:9092 --replication-factor 1 --partitions 8 --topic msgToPush /opt/bitnami/kafka/bin/kafka-topics.sh --create --bootstrap-server localhost:9092 --replication-factor 1 --partitions 8 --topic offlineMsgToMongoMysql echo "Topics created."
mongo-init.sh :
# mongosh --: Launches the MongoDB shell, connecting to the default MongoDB instance. # "$MONGO_INITDB_DATABASE": Specifies the database to connect to (using the value from the environment variable). # <<EOF: Indicates the start of a multi-line input block. Everything between <<EOF and EOF is treated as MongoDB shell commands to be executed. # db.getSiblingDB('admin'): Switches to the admin database, which is the default administrative database in MongoDB. It allows you to perform administrative tasks like user creation, where the user dev-user will be created. # db.auth('$MONGO_INITDB_ROOT_USERNAME', '$MONGO_INITDB_ROOT_PASSWORD') (commented out): This line, if executed, would authenticate the user with the given credentials against the "admin" database. It’s necessary if the following operations require authentication. # The user dev-user is created in the admin database with the specified username and password. # { role: 'root', db: 'admin' }: Allows full access to the admin database. # { role: 'readWrite', db: '$MONGO_INITDB_DATABASE' }: Grants read and write permissions specifically for dev_database. mongosh -- "$MONGO_INITDB_DATABASE" <<EOF db = db.getSiblingDB('admin') db.auth('$MONGO_INITDB_ROOT_USERNAME', '$MONGO_INITDB_ROOT_PASSWORD') db.createUser({ user: "$MONGODB_ROOT_USER", pwd: "$MONGODB_ROOT_PASSWORD", roles: [ { role: 'root', db: 'admin' }, { role: 'root', db: '$MONGO_INITDB_DATABASE' } ] }) db = db.getSiblingDB('$MONGO_INITDB_DATABASE'); db.createCollection('users'); db.users.insertMany([ { username: 'user1', email: 'user1@example.com' }, { username: 'user2', email: 'user2@example.com' } ]); EOF
mysql-init.sql :
-- CREATE TABLE IF NOT EXISTS test (id SERIAL PRIMARY KEY, name VARCHAR(50)); BEGIN; -- structure setup CREATE TABLE users ( id SERIAL PRIMARY KEY, username VARCHAR(50) NOT NULL, email VARCHAR(100) NOT NULL ); -- data setup INSERT INTO users (username, email) VALUES ('user1', 'user1@example.com'); INSERT INTO users (username, email) VALUES ('user2', 'user2@example.com'); COMMIT;
postgres-init.sql :
-- CREATE TABLE IF NOT EXISTS test (id SERIAL PRIMARY KEY, name VARCHAR(50)); BEGIN; -- structure setup CREATE TABLE users ( id SERIAL PRIMARY KEY, username VARCHAR(50) NOT NULL, email VARCHAR(100) NOT NULL ); -- data setup INSERT INTO users (username, email) VALUES ('user1', 'user1@example.com'); INSERT INTO users (username, email) VALUES ('user2', 'user2@example.com'); COMMIT;
Dans votre terminal, accédez au dossier dev-environment et exécutez :
dev-environment/ ├── components # for mounting container volumes ├── scripts/ │ ├── pgadmin │ │ ├──servers.json # for pgadmin automatically load postgreDB │ ├── create-topics.sh # for creating kafka topics │ ├── mongo-init.sh # init script for mongodb │ ├── mysql-init.sql # init script for mysql │ ├── postgres-init.sql # init script for postgre ├── .env ├── docker-compose.yml
Cette commande démarrera tous les services, chacun avec sa propre configuration de conteneur, de port et d'environnement telle que définie.
Chaque outil d'interface utilisateur est déjà configuré pour se connecter à son conteneur de base de données respectif.
Tout d'abord, nous devons charger toutes les variables d'environnement du fichier .env vers la session CLI de travail en cours. Pour ce faire, nous pouvons utiliser la commande suivante :
# MySQL Configuration MYSQL_PORT=23306 MYSQL_USERNAME=dev-user MYSQL_PASSWORD=dev-password MYSQL_DATABASE=dev_database # PostgreSQL Configuration POSTGRES_PORT=25432 POSTGRES_USERNAME=dev-user POSTGRES_PASSWORD=dev-password POSTGRES_DATABASE=dev_database # MongoDB Configuration MONGO_PORT=27017 MONGO_USERNAME=dev-user MONGO_PASSWORD=dev-password MONGO_DATABASE=dev_database # Redis Configuration REDIS_PORT=26379 REDIS_PASSWORD=dev-password # Kafka Configuration KAFKA_PORT=29092 KAFKA_USERNAME=dev-user KAFKA_PASSWORD=dev-password # UI Tools Configuration PHPMYADMIN_PORT=280 PGADMIN_PORT=281 MONGOEXPRESS_PORT=28081 REDIS_COMMANDER_PORT=28082 KAFKA_UI_PORT=28080 # Data Directory for Volumes DATA_DIR=./
Accéder à la CLI MySQL
version: '3.8' services: dev-mysql: image: bitnami/mysql:latest # This container_name can be used for internal connections between containers (running on the same docker virtual network) container_name: dev-mysql ports: # This mapping means that requests sent to the ${MYSQL_PORT} on the host machine will be forwarded to port 3306 in the dev-mysql container. This setup allows users to access the MySQL database from outside the container, such as from a local machine or another service. - '${MYSQL_PORT}:3306' environment: # Setup environment variables for container - MYSQL_ROOT_PASSWORD=${MYSQL_PASSWORD} - MYSQL_USER=${MYSQL_USERNAME} - MYSQL_PASSWORD=${MYSQL_PASSWORD} - MYSQL_DATABASE=${MYSQL_DATABASE} volumes: # Syncs msyql data from inside container to host machine, to keep them accross container restarts - '${DATA_DIR}/components/mysql/data:/bitnami/mysql/data' # Add custom script to init db - './scripts/mysql-init.sql:/docker-entrypoint-initdb.d/init.sql' phpmyadmin: image: phpmyadmin/phpmyadmin:latest container_name: dev-phpmyadmin # The depends_on option in Docker specifies that a container should be started only after the specified dependent container (e.g., dev-mysql) has been started (but not ensuring that it is ready) depends_on: - dev-mysql ports: - '${PHPMYADMIN_PORT}:80' environment: - PMA_HOST=dev-mysql # use internal port for internal connections, not exposed port ${MYSQL_PORT} - PMA_PORT=3306 - PMA_USER=${MYSQL_USERNAME} - PMA_PASSWORD=${MYSQL_PASSWORD} #======= dev-postgresql: image: bitnami/postgresql:latest container_name: dev-postgresql ports: - '${POSTGRES_PORT}:5432' environment: - POSTGRESQL_USERNAME=${POSTGRES_USERNAME} - POSTGRESQL_PASSWORD=${POSTGRES_PASSWORD} - POSTGRESQL_DATABASE=${POSTGRES_DATABASE} volumes: # This setup will ensure that PostgreSQL data from inside container is synced to host machine, enabling persistence across container restarts. - '${DATA_DIR}/components/postgresql/data:/bitnami/postgresql/data' # Most relational databases support a special docker-entrypoint-initdb.d folder. This folder is used to initialise the database automatically when the container is first created. # We can put .sql or .sh scripts there, and Docker will automatically, here ./scripts/postgres-init.sql from host machine be automatically copied to the Docker container during the build and then run it - ./scripts/postgres-init.sql:/docker-entrypoint-initdb.d/init.sql:ro pgadmin: image: dpage/pgadmin4:latest container_name: dev-pgadmin depends_on: - dev-postgresql ports: - '${PGADMIN_PORT}:80' # user: root used to ensure that the container has full administrative privileges, # necessary when performing actions that require elevated permissions, such as mounting volumes (properly read or write to the mounted volumes), executing certain entrypoint commands, or accessing specific directories from host machine user: root environment: # PGADMIN_DEFAULT_EMAIL and PGADMIN_DEFAULT_PASSWORD - Sets the default credentials for the pgAdmin user - PGADMIN_DEFAULT_EMAIL=admin@dev.com - PGADMIN_DEFAULT_PASSWORD=${POSTGRES_PASSWORD} # PGADMIN_CONFIG_SERVER_MODE - determines whether pgAdmin runs in server mode (multi-user) or desktop mode (single-user). We’re setting it to false, so we won’t be prompted for login credentials - PGADMIN_CONFIG_SERVER_MODE=False # PGADMIN_CONFIG_MASTER_PASSWORD_REQUIRED - controls whether a master password is required to access saved server definitions and other sensitive information - PGADMIN_CONFIG_MASTER_PASSWORD_REQUIRED=False volumes: # This setup will ensure that PGAdmin data from inside container is synced to host machine, enabling persistence across container restarts. - '${DATA_DIR}/components/pgadmin:/var/lib/pgadmin' # This setup to make PGAdmin automatically detect and connect to PostgreSQL when it starts (following the config being set in servers.json) - ./scripts/pgadmin/servers.json:/pgadmin4/servers.json:ro #======= dev-mongodb: image: bitnami/mongodb:latest container_name: dev-mongodb ports: - '${MONGO_PORT}:27017' environment: - MONGO_INITDB_ROOT_USERNAME=${MONGO_USERNAME} - MONGO_INITDB_ROOT_PASSWORD=${MONGO_PASSWORD} - MONGO_INITDB_DATABASE=${MONGO_DATABASE} - MONGODB_ROOT_USER=${MONGO_USERNAME} - MONGODB_ROOT_PASSWORD=${MONGO_PASSWORD} - MONGODB_DATABASE=${MONGO_DATABASE} volumes: - '${DATA_DIR}/components/mongodb/data:/bitnami/mongodb' # This line maps ./scripts/mongo-init.sh from host machine to /docker-entrypoint-initdb.d/mongo-init.sh inside container with 'ro' mode (read only mode) which means container can't modify the mounted file - ./scripts/mongo-init.sh:/docker-entrypoint-initdb.d/mongo-init.sh:ro # - ./scripts/mongo-init.sh:/bitnami/scripts/mongo-init.sh:ro mongo-express: image: mongo-express:latest container_name: dev-mongoexpress depends_on: - dev-mongodb ports: - '${MONGOEXPRESS_PORT}:8081' environment: - ME_CONFIG_MONGODB_ENABLE_ADMIN=true - ME_CONFIG_MONGODB_ADMINUSERNAME=${MONGO_USERNAME} - ME_CONFIG_MONGODB_ADMINPASSWORD=${MONGO_PASSWORD} # - ME_CONFIG_MONGODB_SERVER=dev-mongodb # - ME_CONFIG_MONGODB_PORT=${MONGO_PORT} - ME_CONFIG_MONGODB_URL=mongodb://${MONGO_USERNAME}:${MONGO_PASSWORD}@dev-mongodb:${MONGO_PORT}/${MONGO_DATABASE}?authSource=admin&ssl=false&directConnection=true restart: unless-stopped # 'restart: unless-stopped' restarts a container automatically unless it is explicitly stopped by the user. # some others: 1. 'no': (Default option if not specified) meaning the container won't automatically restart if it stops or crashes. # 2. 'always': The container will restart regardless of the reason it stopped, including if Docker is restarted. # 3. 'on-failure': The container will restart only if it exits with a non-zero status indicating an error. (and won't restart if it stops when completing as short running task and return 0 status). #======= dev-redis: image: bitnami/redis:latest container_name: dev-redis ports: - '${REDIS_PORT}:6379' environment: - REDIS_PASSWORD=${REDIS_PASSWORD} volumes: - '${DATA_DIR}/components/redis:/bitnami/redis' networks: - dev-network redis-commander: image: rediscommander/redis-commander:latest container_name: dev-redis-commander depends_on: - dev-redis ports: - '${REDIS_COMMANDER_PORT}:8081' environment: - REDIS_HOST=dev-redis # While exposed port ${REDIS_PORT} being bind to host network, redis-commander still using internal port 6379 (being use internally inside docker virtual network) to connect to redis - REDIS_PORT=6379 - REDIS_PASSWORD=${REDIS_PASSWORD} networks: - dev-network # This networks setup is optional, in case not being set, both redis-commader and redis will both be assigned to default docker network (usually named bridge) and still being able to connect each other #======= dev-kafka: image: 'bitnami/kafka:latest' container_name: dev-kafka ports: - '${KAFKA_PORT}:9094' environment: # Sets the timezone for the container to "Asia/Shanghai". This ensures that logs and timestamps inside the Kafka container align with the Shanghai timezone. - TZ=Asia/Shanghai # KAFKA_CFG_NODE_ID=0: Identifies the Kafka node with ID 0. This is crucial for multi-node Kafka clusters to distinguish each node uniquely. - KAFKA_CFG_NODE_ID=0 # KAFKA_CFG_PROCESS_ROLES=controller,broker: Specifies the roles the Kafka node will perform, in this case, both as a controller (managing cluster metadata) and a broker (handling messages). - KAFKA_CFG_PROCESS_ROLES=controller,broker # KAFKA_CFG_CONTROLLER_QUORUM_VOTERS=0@<your_host>:9093: Defines the quorum voters for the Kafka controllers. It indicates that node 0 (the current node) acts as a voter for controller decisions and will be accessible at 9093 on <your_host>. - KAFKA_CFG_CONTROLLER_QUORUM_VOTERS=0@<your_host>:9093 # The following lists different listeners for Kafka. Each listener binds a protocol to a specific port: # PLAINTEXT for client connections (:9092). CONTROLLER for internal controller communication (:9093). EXTERNAL for external client access (:9094).SASL_PLAINTEXT for SASL-authenticated clients (:9095). - KAFKA_CFG_LISTENERS=PLAINTEXT://:9092,CONTROLLER://:9093,EXTERNAL://:9094,SASL_PLAINTEXT://:9095 # KAFKA_CFG_ADVERTISED_LISTENERS specifies how clients should connect to Kafka externally: # PLAINTEXT at dev-kafka:9092 for internal communication. EXTERNAL at 127.0.0.1:${KAFKA_PORT} (host access). SASL_PLAINTEXT for SASL connections (kafka:9095). - KAFKA_CFG_ADVERTISED_LISTENERS=PLAINTEXT://dev-kafka:9092,EXTERNAL://127.0.0.1:${KAFKA_PORT},SASL_PLAINTEXT://kafka:9095 # The following maps security protocols to each listener. For example, CONTROLLER uses PLAINTEXT, and EXTERNAL uses SASL_PLAINTEXT. - KAFKA_CFG_LISTENER_SECURITY_PROTOCOL_MAP=CONTROLLER:PLAINTEXT,EXTERNAL:SASL_PLAINTEXT,PLAINTEXT:PLAINTEXT,SASL_PLAINTEXT:SASL_PLAINTEXT # Indicates that the CONTROLLER role should use the CONTROLLER listener for communications. - KAFKA_CFG_CONTROLLER_LISTENER_NAMES=CONTROLLER # Specifies users with relevant passwords that can connect to Kafka using SASL authentication - KAFKA_CLIENT_USERS=${KAFKA_USERNAME} - KAFKA_CLIENT_PASSWORDS=${KAFKA_PASSWORD} volumes: - '${DATA_DIR}/components/kafka/data:/bitnami/kafka/data' # Maps a local file create-topics.sh from the ./scripts directory to the path /opt/bitnami/kafka/create_topic.sh inside the Kafka container # This script can be used to automatically create Kafka topics when the container starts - ./scripts/create-topics.sh:/opt/bitnami/kafka/create_topic.sh:ro # Following command starts the Kafka server in the background using /opt/bitnami/scripts/kafka/run.sh. then sleep 5 to ensure that the Kafka server is fully up and running. # Executes the create_topic.sh script, which is used to create Kafka topics. Uses 'wait' to keep the script running until all background processes (like the Kafka server) finish, command: > bash -c " /opt/bitnami/scripts/kafka/run.sh & sleep 5; /opt/bitnami/kafka/create_topic.sh; wait " kafka-ui: image: provectuslabs/kafka-ui:latest container_name: dev-kafka-ui ports: - '${KAFKA_UI_PORT}:8080' environment: # Sets the name of the Kafka cluster displayed in the UI as "local." - KAFKA_CLUSTERS_0_NAME=local # Specifies the address (dev-kafka:9092) for the Kafka broker that the UI should connect to. - KAFKA_CLUSTERS_0_BOOTSTRAPSERVERS=dev-kafka:9092 # Uses the provided ${KAFKA_USERNAME} for SASL (Simple Authentication and Security Layer) authentication with the Kafka cluster. - KAFKA_CLUSTERS_0_SASL_USER=${KAFKA_USERNAME} # Uses the ${KAFKA_PASSWORD} for authentication with the Kafka broker. - KAFKA_CLUSTERS_0_SASL_PASSWORD=${KAFKA_PASSWORD} # Sets the SASL mechanism as 'PLAIN', which is a simple username-password-based authentication method. - KAFKA_CLUSTERS_0_SASL_MECHANISM=PLAIN # Configures the communication protocol as SASL_PLAINTEXT, which means it uses SASL for authentication without encryption over plaintext communication. - KAFKA_CLUSTERS_0_SECURITY_PROTOCOL=SASL_PLAINTEXT depends_on: - dev-kafka networks: dev-network: driver: bridge
Accéder à la CLI PostgreSQL
{ "Servers": { "1": { "Name": "Local PostgreSQL", "Group": "Servers", "Host": "dev-postgresql", "Port": 5432, "MaintenanceDB": "dev_database", "Username": "dev-user", "Password": "dev-password", "SSLMode": "prefer", "Favorite": true } } }
Accéder à la CLI MongoDB
# Wait for Kafka to be ready until /opt/bitnami/kafka/bin/kafka-topics.sh --list --bootstrap-server localhost:9092; do echo "Waiting for Kafka to be ready..." sleep 2 done # Create topics /opt/bitnami/kafka/bin/kafka-topics.sh --create --bootstrap-server localhost:9092 --replication-factor 1 --partitions 8 --topic latestMsgToRedis /opt/bitnami/kafka/bin/kafka-topics.sh --create --bootstrap-server localhost:9092 --replication-factor 1 --partitions 8 --topic msgToPush /opt/bitnami/kafka/bin/kafka-topics.sh --create --bootstrap-server localhost:9092 --replication-factor 1 --partitions 8 --topic offlineMsgToMongoMysql echo "Topics created."
Accéder à Redis CLI
# mongosh --: Launches the MongoDB shell, connecting to the default MongoDB instance. # "$MONGO_INITDB_DATABASE": Specifies the database to connect to (using the value from the environment variable). # <<EOF: Indicates the start of a multi-line input block. Everything between <<EOF and EOF is treated as MongoDB shell commands to be executed. # db.getSiblingDB('admin'): Switches to the admin database, which is the default administrative database in MongoDB. It allows you to perform administrative tasks like user creation, where the user dev-user will be created. # db.auth('$MONGO_INITDB_ROOT_USERNAME', '$MONGO_INITDB_ROOT_PASSWORD') (commented out): This line, if executed, would authenticate the user with the given credentials against the "admin" database. It’s necessary if the following operations require authentication. # The user dev-user is created in the admin database with the specified username and password. # { role: 'root', db: 'admin' }: Allows full access to the admin database. # { role: 'readWrite', db: '$MONGO_INITDB_DATABASE' }: Grants read and write permissions specifically for dev_database. mongosh -- "$MONGO_INITDB_DATABASE" <<EOF db = db.getSiblingDB('admin') db.auth('$MONGO_INITDB_ROOT_USERNAME', '$MONGO_INITDB_ROOT_PASSWORD') db.createUser({ user: "$MONGODB_ROOT_USER", pwd: "$MONGODB_ROOT_PASSWORD", roles: [ { role: 'root', db: 'admin' }, { role: 'root', db: '$MONGO_INITDB_DATABASE' } ] }) db = db.getSiblingDB('$MONGO_INITDB_DATABASE'); db.createCollection('users'); db.users.insertMany([ { username: 'user1', email: 'user1@example.com' }, { username: 'user2', email: 'user2@example.com' } ]); EOF
Accéder à la CLI Kafka
-- CREATE TABLE IF NOT EXISTS test (id SERIAL PRIMARY KEY, name VARCHAR(50)); BEGIN; -- structure setup CREATE TABLE users ( id SERIAL PRIMARY KEY, username VARCHAR(50) NOT NULL, email VARCHAR(100) NOT NULL ); -- data setup INSERT INTO users (username, email) VALUES ('user1', 'user1@example.com'); INSERT INTO users (username, email) VALUES ('user2', 'user2@example.com'); COMMIT;
Cette configuration utilise Docker Compose avec des variables d'environnement, des images Bitnami et des mappages de volumes pour créer un environnement de développement reproductible. En utilisant docker-compose up -d, vous pouvez rapidement démarrer ou détruire l'ensemble de l'environnement avec docker-compose down, le rendant ainsi adapté au développement et aux tests locaux.
Ce qui précède est le contenu détaillé de. pour plus d'informations, suivez d'autres articles connexes sur le site Web de PHP en chinois!