In one of our previous blog posts, we described the process you should take when Installing and Configuring Apache Airflow. In this post, we will describe how to setup an Apache Airflow Cluster to run across multiple nodes. This will provide you with more computing power and higher availability for your Apache Airflow instance.

Airflow Daemons

A running instance of Airflow has a number of Daemons that work together to provide the full functionality of Airflow. The daemons include the Web Server, Scheduler, Worker, Kerberos Ticket Renewer, Flower and others. Bellow are the primary ones you will need to have running for a production quality Apache Airflow Cluster.

Web Server

A daemon which accepts HTTP requests and allows you to interact with Airflow via a Python Flask Web Application. It provides the ability to pause, unpause DAGs, manually trigger DAGs, view running DAGs, restart failed DAGs and much more.

The Web Server Daemon starts up gunicorn workers to handle requests in parallel. You can scale up the number of gunicorn workers on a single machine to handle more load by updating the ‘workers’ configuration in the {AIRFLOW_HOME}/airflow.cfg file.

Example

workers = 4

Startup Command:

$ airflow webserver

Scheduler

A daemon which periodically polls to determine if any registered DAG and/or Task Instances needs to triggered based off its schedule.

Startup Command:

$ airflow scheduler

Executors/Workers

A daemon that handles starting up and managing 1 to many CeleryD processes to execute the desired tasks of a particular DAG.

This daemon only needs to be running when you set the ‘executor ‘ config in the {AIRFLOW_HOME}/airflow.cfg file to ‘CeleryExecutor’. It is recommended to do so for Production.

Example:

executor = CeleryExecutor

Startup Command:

$ airflow worker

How do the Daemons work together?

One thing to note about the Airflow Daemons is that they don’t register with each other or even need to know about each other. Each of them handle their own assigned task and when all of them are running, everything works as you would expect.

The Scheduler periodically polls to see if any DAGs that are registered in the MetaStore need to be executed. If a particular DAG needs to be triggered (based off the DAGs Schedule), then the Scheduler Daemon creates a DagRun instance in the MetaStore and starts to trigger the individual tasks in the DAG. The scheduler will do this by pushing messages into the Queueing Service. Each message contains information about the Task it is executing including the DAG Id, Task Id and what function needs to be performed. In the case where the Task is a BashOperator with some bash code, the message will contain this bash code. A user might also interact with the Web Server and manually trigger DAGs to be ran. When a user does this, a DagRun will be created and the scheduler will start to trigger individual Tasks in the DAG in the same way that was mentioned in #1. The celeryd processes controlled by the Worker daemon, will pull from the Queueing Service on regular intervals to see if there are any tasks that need to be executed. When one of the celeryd processes pulls a Task message, it updates the Task instance in the MetaStore to a Running state and tries to execute the code provided. If it succeeds then it updates the state as succeeded but if the code fails while being executed then it updates the Task as failed.

Single Node Airflow Setup

A simple instance of Apache Airflow involves putting all the services on a single node like the bellow diagram depicts.

Multi-Node (Cluster) Airflow Setup

A more formal setup for Apache Airflow is to distribute the daemons across multiple machines as a cluster.

Benefits

Higher Availability

If one of the worker nodes were to go down or be purposely taken offline, the cluster would still be operational and tasks would still be executed.

Distributed Processing

If you have a workflow with several memory intensive tasks, then the tasks will be better distributed to allow for higher utilizaiton of data across the cluster and provide faster execution of the tasks.

Scaling Workers

Horizontally

You can scale the cluster horizontally and distribute the processing by adding more executor nodes to the cluster and allowing those new nodes to take load off the existing nodes. Since workers don’t need to register with any central authority to start processing tasks, the machine can be turned on and off without any downtime to the cluster.

Vertically

You can scale the cluster vertically by increasing the number of celeryd daemons running on each node. This can be done by increasing the value in the ‘celeryd_concurrency’ config in the {AIRFLOW_HOME}/airflow.cfg file.

Example:

celeryd_concurrency = 30

You may need to increase the size of the instances in order to support a larger number of celeryd processes. This will depend on the memory and cpu intensity of the tasks you’re running on the cluster.

Scaling Master Nodes

You can also add more Master Nodes to your cluster to scale out the services that are running on the Master Nodes. This will mainly allow you to scale out the Web Server Daemon incase there are too many HTTP requests coming for one machine to handle or if you want to provide Higher Availability for that service.

One thing to note is that there can only be one Scheduler instance running at a time. If you have multiple Schedulers running, there is a possibility that multiple instances of a single task will be scheduled. This could cause some major problems with your Workflow and cause duplicate data to show up in the final table if you were running some sort of ETL process.

If you would like, the Scheduler daemon may also be setup to run on its own dedicated Master Node.

Apache Airflow Cluster Setup Steps

Pre-Requisites

The following nodes are available with the given host names: master1 Will have the role(s): Web Server, Scheduler master2 Will have the role(s): Web Server worker1 Will have the role(s): Worker worker2 Will have the role(s): Worker

A Queuing Service is Running. (RabbitMQ, AWS SQS, etc) You can install RabbitMQ by following these instructions: Installing RabbitMQ If you’re using RabbitMQ, it is recommended that it is also setup to be a cluster for High Availability. Setup a Load Balancer to proxy requests to the RabbitMQ instances.



Steps

Install Apache Airflow on ALL machines that will have a role in the Airflow You can follow the instructions on our previous blog post: Installing and Configuring Apache Airflow. Apply Airflow Configuration changes to all ALL machines. Apply changes to the {AIRFLOW_HOME}/airflow.cfg file. Change the Executor to CeleryExecutor

executor = CeleryExecutor Point SQL Alchemy to the MetaStore

sql_alchemy_conn = mysql://{USERNAME}:{PASSWORD}@{MYSQL_HOST}:3306/airflow Set the Broker URL If you’re using RabbitMQ:

broker_url = amqp://guest:guest@{RABBITMQ_HOST}:5672/ If you’re using AWS SQS:

broker_url = sqs://{ACCESS_KEY_ID}:{SECRET_KEY}@ #Note: You will also need to install boto: $ pip install -U boto Point Celery to the MetaStore

celery_result_backend = db+mysql://{USERNAME}:{PASSWORD}@{MYSQL_HOST}:3306/airflow Deploy your DAGs/Workflows on master1 and master2 (and any future master nodes you might add) On master1, initialize the Airflow Database (if not already done after updating the sql_alchemy_conn configuration) airflow initdb On master1, startup the required role(s) Startup Web Server $ airflow webserver

Startup Scheduler $ airflow scheduler On master2, startup the required role(s) Startup Web Server $ airflow webserver On worker1 and worker2, startup the required role(s) Startup Worker $ airflow worker Create a Load Balancer to balance requests going to the Web Servers If you’re in AWS you can do this with the EC2 Load Balancer Sample Configurations: Port Forwarding Port 8080 (HTTP) → Port 8080 (HTTP) Health Check Protocol: HTTP Ping Port: 8080 Ping Path: / Success Code: 200,302

If you’re not on AWS you can use something like haproxy to proxy/balance requests to the Web Servers Sample Configurations:

global log 127.0.0.1 local2 chroot /var/lib/haproxy pidfile /var/run/haproxy.pid maxconn 4000 user haproxy group haproxy daemon # turn on stats unix socket # stats socket /var/lib/haproxy/stats defaults mode tcp log global option tcplog option tcpka retries 3 timeout connect 5s timeout client 1h timeout server 1h # port forwarding from 8080 to the airflow webserver on 8080 listen impala bind 0.0.0.0:8080 balance roundrobin server airflow_webserver_1 host1:8080 check server airflow_webserver_2 host2:8080 check # This sets up the admin page for HA Proxy at port 1936. listen stats :1936 mode http stats enable stats uri / stats hide-version stats refresh 30s

You’re done!

Additional Documentation

Documentation: https://airflow.incubator.apache.org/

Install Documentation: https://airflow.incubator.apache.org/installation.html

GitHub Repo: https://github.com/apache/incubator-airflow