deploying-airflow

作成者: astronomer

AirflowのDAGやプロジェクトをデプロイします。ユーザーがコードのデプロイ、DAGのプッシュ、CI/CDの設定、本番環境へのデプロイ、またはデプロイ戦略について質問した場合に使用します…

npx skills add https://github.com/astronomer/agents --skill deploying-airflow

Deploying Airflow

This skill covers deploying Airflow DAGs and projects to production, whether using Astro (Astronomer's managed platform) or open-source Airflow on Docker Compose or Kubernetes.

Choosing a path: Astro is a good fit for managed operations and faster CI/CD. For open-source, use Docker Compose for dev and the Helm chart for production.


Astro (Astronomer)

Astro provides CLI commands and GitHub integration for deploying Airflow projects.

Deploy Commands

CommandWhat It Does
astro deployFull project deploy — builds Docker image and deploys DAGs
astro deploy --dagsDAG-only deploy — pushes only DAG files (fast, no image build)
astro deploy --imageImage-only deploy — pushes only the Docker image (for multi-repo CI/CD)
astro deploy --dbtdbt project deploy — deploys a dbt project to run alongside Airflow

Full Project Deploy

Builds a Docker image from your Astro project and deploys everything (DAGs, plugins, requirements, packages):

astro deploy

Use this when you've changed requirements.txt, Dockerfile, packages.txt, plugins, or any non-DAG file.

DAG-Only Deploy

Pushes only files in the dags/ directory without rebuilding the Docker image:

astro deploy --dags

This is significantly faster than a full deploy since it skips the image build. Use this when you've only changed DAG files and haven't modified dependencies or configuration.

Image-Only Deploy

Pushes only the Docker image without updating DAGs:

astro deploy --image

This is useful in multi-repo setups where DAGs are deployed separately from the image, or in CI/CD pipelines that manage image and DAG deploys independently.

dbt Project Deploy

Deploys a dbt project to run with Cosmos on an Astro deployment:

astro deploy --dbt

GitHub Integration

Astro supports branch-to-deployment mapping for automated deploys:

  • Map branches to specific deployments (e.g., main -> production, develop -> staging)
  • Pushes to mapped branches trigger automatic deploys
  • Supports DAG-only deploys on merge for faster iteration

Configure this in the Astro UI under Deployment Settings > CI/CD.

CI/CD Patterns

Common CI/CD strategies on Astro:

  1. DAG-only on feature branches: Use astro deploy --dags for fast iteration during development
  2. Full deploy on main: Use astro deploy on merge to main for production releases
  3. Separate image and DAG pipelines: Use --image and --dags in separate CI jobs for independent release cycles

Deploy Queue

When multiple deploys are triggered in quick succession, Astro processes them sequentially in a deploy queue. Each deploy completes before the next one starts.

Reference


Open-Source: Docker Compose

Deploy Airflow using the official Docker Compose setup. This is recommended for learning and exploration — for production, use Kubernetes with the Helm chart (see below).

Prerequisites

  • Docker and Docker Compose v2.14.0+
  • The official apache/airflow Docker image

Quick Start

Download the official Airflow 3 Docker Compose file:

curl -LfO 'https://airflow.apache.org/docs/apache-airflow/stable/docker-compose.yaml'

This sets up the full Airflow 3 architecture:

ServicePurpose
airflow-apiserverREST API and UI (port 8080)
airflow-schedulerSchedules DAG runs
airflow-dag-processorParses and processes DAG files
airflow-workerExecutes tasks (CeleryExecutor)
airflow-triggererHandles deferrable/async tasks
postgresMetadata database
redisCelery message broker

Minimal Setup

For a simpler setup with LocalExecutor (no Celery/Redis), create a docker-compose.yaml:

x-airflow-common: &airflow-common
  image: apache/airflow:3  # Use the latest Airflow 3.x release
  environment: &airflow-common-env
    AIRFLOW__CORE__EXECUTOR: LocalExecutor
    AIRFLOW__DATABASE__SQL_ALCHEMY_CONN: postgresql+psycopg2://airflow:airflow@postgres/airflow
    AIRFLOW__CORE__LOAD_EXAMPLES: 'false'
    AIRFLOW__CORE__DAGS_FOLDER: /opt/airflow/dags
  volumes:
    - ./dags:/opt/airflow/dags
    - ./logs:/opt/airflow/logs
    - ./plugins:/opt/airflow/plugins
  depends_on:
    postgres:
      condition: service_healthy

services:
  postgres:
    image: postgres:16
    environment:
      POSTGRES_USER: airflow
      POSTGRES_PASSWORD: airflow
      POSTGRES_DB: airflow
    volumes:
      - postgres-db-volume:/var/lib/postgresql/data
    healthcheck:
      test: ["CMD", "pg_isready", "-U", "airflow"]
      interval: 10s
      retries: 5
      start_period: 5s

  airflow-init:
    <<: *airflow-common
    entrypoint: /bin/bash
    command:
      - -c
      - |
        airflow db migrate
        airflow users create \
          --username admin \
          --firstname Admin \
          --lastname User \
          --role Admin \
          --email [email protected] \
          --password admin
    depends_on:
      postgres:
        condition: service_healthy

  airflow-apiserver:
    <<: *airflow-common
    command: airflow api-server
    ports:
      - "8080:8080"
    healthcheck:
      test: ["CMD", "curl", "--fail", "http://localhost:8080/health"]
      interval: 30s
      timeout: 10s
      retries: 5
      start_period: 30s

  airflow-scheduler:
    <<: *airflow-common
    command: airflow scheduler

  airflow-dag-processor:
    <<: *airflow-common
    command: airflow dag-processor

  airflow-triggerer:
    <<: *airflow-common
    command: airflow triggerer

volumes:
  postgres-db-volume:

Airflow 3 architecture note: The webserver has been replaced by the API server (airflow api-server), and the DAG processor now runs as a standalone process separate from the scheduler.

Common Operations

# Start all services
docker compose up -d

# Stop all services
docker compose down

# View logs
docker compose logs -f airflow-scheduler

# Restart after requirements change
docker compose down && docker compose up -d --build

# Run a one-off Airflow CLI command
docker compose exec airflow-apiserver airflow dags list

Installing Python Packages

Add packages to requirements.txt and rebuild:

# Add to requirements.txt, then:
docker compose down
docker compose up -d --build

Or use a custom Dockerfile:

FROM apache/airflow:3  # Pin to a specific version (e.g., 3.1.7) for reproducibility
COPY requirements.txt .
RUN pip install --no-cache-dir -r requirements.txt

Update docker-compose.yaml to build from the Dockerfile:

x-airflow-common: &airflow-common
  build:
    context: .
    dockerfile: Dockerfile
  # ... rest of config

Environment Variables

Configure Airflow settings via environment variables in docker-compose.yaml:

environment:
  # Core settings
  AIRFLOW__CORE__EXECUTOR: LocalExecutor
  AIRFLOW__CORE__PARALLELISM: 32
  AIRFLOW__CORE__MAX_ACTIVE_TASKS_PER_DAG: 16

  # Email
  AIRFLOW__EMAIL__EMAIL_BACKEND: airflow.utils.email.send_email_smtp
  AIRFLOW__SMTP__SMTP_HOST: smtp.example.com

  # Connections (as URI)
  AIRFLOW_CONN_MY_DB: postgresql://user:pass@host:5432/db

Open-Source: Kubernetes (Helm Chart)

Deploy Airflow on Kubernetes using the official Apache Airflow Helm chart.

Prerequisites

  • A Kubernetes cluster
  • kubectl configured
  • helm installed

Installation

# Add the Airflow Helm repo
helm repo add apache-airflow https://airflow.apache.org
helm repo update

# Install with default values
helm install airflow apache-airflow/airflow \
  --namespace airflow \
  --create-namespace

# Install with custom values
helm install airflow apache-airflow/airflow \
  --namespace airflow \
  --create-namespace \
  -f values.yaml

Key values.yaml Configuration

# Executor type
executor: KubernetesExecutor  # or CeleryExecutor, LocalExecutor

# Airflow image (pin to your desired version)
defaultAirflowRepository: apache/airflow
defaultAirflowTag: "3"  # Or pin: "3.1.7"

# Git-sync for DAGs (recommended for production)
dags:
  gitSync:
    enabled: true
    repo: https://github.com/your-org/your-dags.git
    branch: main
    subPath: dags
    wait: 60  # seconds between syncs

# API server (replaces webserver in Airflow 3)
apiServer:
  resources:
    requests:
      cpu: "250m"
      memory: "512Mi"
    limits:
      cpu: "500m"
      memory: "1Gi"
  replicas: 1

# Scheduler
scheduler:
  resources:
    requests:
      cpu: "500m"
      memory: "1Gi"
    limits:
      cpu: "1000m"
      memory: "2Gi"

# Standalone DAG processor
dagProcessor:
  enabled: true
  resources:
    requests:
      cpu: "250m"
      memory: "512Mi"
    limits:
      cpu: "500m"
      memory: "1Gi"

# Triggerer (for deferrable tasks)
triggerer:
  resources:
    requests:
      cpu: "250m"
      memory: "512Mi"
    limits:
      cpu: "500m"
      memory: "1Gi"

# Worker resources (CeleryExecutor only)
workers:
  resources:
    requests:
      cpu: "500m"
      memory: "1Gi"
    limits:
      cpu: "2000m"
      memory: "4Gi"
  replicas: 2

# Log persistence
logs:
  persistence:
    enabled: true
    size: 10Gi

# PostgreSQL (built-in)
postgresql:
  enabled: true

# Or use an external database
# postgresql:
#   enabled: false
# data:
#   metadataConnection:
#     user: airflow
#     pass: airflow
#     host: your-rds-host.amazonaws.com
#     port: 5432
#     db: airflow

Upgrading

# Upgrade with new values
helm upgrade airflow apache-airflow/airflow \
  --namespace airflow \
  -f values.yaml

# Upgrade to a new Airflow version
helm upgrade airflow apache-airflow/airflow \
  --namespace airflow \
  --set defaultAirflowTag="<version>"

DAG Deployment Strategies on Kubernetes

  1. Git-sync (recommended): DAGs are synced from a Git repository automatically
  2. Persistent Volume: Mount a shared PV containing DAGs
  3. Baked into image: Include DAGs in a custom Docker image

Useful Commands

# Check pod status
kubectl get pods -n airflow

# View scheduler logs
kubectl logs -f deployment/airflow-scheduler -n airflow

# Port-forward the API server
kubectl port-forward svc/airflow-apiserver 8080:8080 -n airflow

# Run a one-off CLI command
kubectl exec -it deployment/airflow-scheduler -n airflow -- airflow dags list

Related Skills

  • setting-up-astro-project: For initializing a new Astro project
  • managing-astro-local-env: For local development with astro dev
  • authoring-dags: For writing DAGs before deployment
  • testing-dags: For testing DAGs before deployment

astronomerのその他のスキル

airflow
astronomer
Apache AirflowのDAG、実行、タスク、システム設定をクエリ、管理、トラブルシューティングします。DAG検査、実行管理、タスクログ、設定クエリ、REST API直接アクセスを含む30以上のコマンドをサポート。複数のAirflowインスタンスを永続的な設定で管理し、ローカルおよびAstroデプロイメントを自動検出。DAG実行を同期的(完了待機)または非同期的にトリガーし、障害を診断、再試行のために実行をクリア、リトライ/マップインデックスフィルタリング付きでタスクログにアクセス。出力...
official
airflow-hitl
astronomer
人間による承認ゲート、フォーム入力、およびAirflow DAG内での分岐を、遅延可能オペレーターを使用して実現。4種類のオペレーター:承認/却下の判断を行うApprovalOperator、フォームによる複数選択肢の選択を行うHITLOperator、人間主導のタスクルーティングを行うHITLBranchOperator、フォームデータ収集を行うHITLEntryOperator。すべてのオペレーターは遅延可能であり、Airflow UIのRequired ActionsタブまたはREST APIを介して人間の応答を待つ間、ワーカースロットを解放します。カスタム...を含むオプション機能をサポート。
official
airflow-plugins
astronomer
Airflow 3.1+のプラグインを構築し、FastAPIアプリ、カスタムUIページ、Reactコンポーネント、ミドルウェア、マクロ、オペレーターリンクをAirflow UIに直接埋め込みます。使用…
official
analyzing-data
astronomer
データウェアハウスにクエリを実行し、キャッシュされたパターンと概念マッピングを使用してビジネス上の質問に回答します。繰り返し発生する質問タイプのパターン検索とキャッシュをサポートし、結果を記録して将来のクエリを改善します。概念からテーブルへのマッピングキャッシュと、INFORMATION_SCHEMAまたはコードベースのgrepによるテーブルスキーマ検出を含みます。分析用にPolarsまたはPandas DataFrameを返すrun_sql()およびrun_sql_pandas()カーネル関数を提供します。概念、パターン、テーブルキャッシュを管理するCLIコマンド、さらに...
official
annotating-task-lineage
astronomer
Airflowタスクにデータ系列を注釈付けし、インレットとアウトレットを使用します。OpenLineage Datasetオブジェクト、Airflow Assets、Airflow Datasetsをサポートし、データベース、データウェアハウス、クラウドストレージ間での入出力を定義します。オペレーターに組み込みのOpenLineage抽出機能がない場合のフォールバックとして使用し、カスタム抽出機能とOpenLineageメソッドが優先される4段階の優先順位システムに従います。Snowflake、BigQuery、S3、PostgreSQL向けのデータセット命名ヘルパーを含み、一貫性を確保します。
official
authoring-dags
astronomer
Apache Airflow DAGを作成するためのガイド付きワークフローで、検証とテストの統合を備えています。構造化された6フェーズのアプローチ:環境と既存のパターンを発見し、DAG構造を計画し、ベストプラクティスに従って実装し、af CLIコマンドで検証し、ユーザーの同意を得てテストし、修正を繰り返します。発見用のCLIコマンド(af config connections、af config providers、af dags list)と検証用のCLIコマンド(af dags errors、af dags get、af dags explore)は、DAGに関する即時フィードバックを提供します。
official
blueprint
astronomer
Pydanticバリデーションを使用して再利用可能なAirflowタスクグループテンプレートを定義し、YAMLからDAGを構成します。ブループリントテンプレートの作成時や、DAGの構成時に使用します。
official
checking-freshness
astronomer
テーブルのタイムスタンプと更新パターンを陳腐化スケールに照らして確認し、データの鮮度を検証します。一般的なETL命名パターン(_loaded_at、_updated_at、created_atなど)を使用してタイムスタンプカラムを特定し、その最大値をクエリして経過時間を判定します。データを4つの鮮度ステータスに分類します:Fresh(4時間未満)、Stale(4~24時間)、Very Stale(24時間超)、またはUnknown(タイムスタンプなし)。最近の日数における最終更新時刻と行数トレンドを確認するためのSQLテンプレートを提供します...
official