boundary-layer
is a tool for building Airflow DAGs from human-friendly, structured, maintainable yaml configuration. It includes first-class support for various usability enhancements that are not built into Airflow itself:
- Managed resources created and destroyed by Airflow within a DAG: for example, ephemeral DAG-scoped hadoop clusters on Dataproc
- Type checking and automatic preprocessing on all arguments to all operators, based on flexible schemas
- Automatic imports of required classes
- Distinct
before
andafter
operator groups, to make it easier to manage actions taken at the beginning or end of workflows - DAG pruning, for extracting or eliminating sections of the graph while maintaining dependency relationships
boundary-layer
also performs various checks to find errors that would only be made visible upon deployment to an Airflow instance, such as cycles in the DAG, duplicate task names, etc.
boundary-layer
is used heavily on the Etsy Data Platform. Every DAG on our platform is defined by a boundary-layer
configuration instead of in raw python, which greatly reduces the barrier to entry for our data scientists and engineers to develop DAGs, while ensuring that best practices are always observed in the generated python code. boundary-layer
is the core of our fully self-service deployment process, in which DAGs are tested by our CI tools and errors are surfaced prior to allowing DAGs to be merged and deployed to our Airflow instances.
In addition, our migration from Oozie to Airflow relied heavily on boundary-layer
's included conversion tool.
boundary-layer
is pluggable, supporting custom configuration and extensions via plugins that are installed using pip
. The core package does not contain any etsy-specific customizations; instead, those are all defined in an internally-distributed etsy plugin package.
For more information, see our article on Etsy's Code as Craft blog.
boundary-layer
requires that each operator have a configuration file to define its schema, the python class it corresponds to, etc. These configuration files are stored in the boundary-layer-default-plugin. We currently include configurations for a number of common Airflow operators (sufficient to support our needs at Etsy, plus a few more), but we know that we are missing quite a few operators that may be needed to satisfy common Airflow use cases. We are committed to continuing to add support for more operators, and we also commit to supporting a quick turn-around time for any contributed pull requests that only add support for additional operators. So please, submit a pull request if something is missing, or at least drop an issue to let us know.
Furthermore, due to some differences in the operators and sensors between Airflow release versions, there may be incompatibilities between boundary-layer
and some Airflow versions. All of our operators are known to work with Airflow release versions 1.9 and 1.10 (although our schemas validate against the operator arguments for 1.10, which is a superset of those for 1.9 --- there could be some parameters that we allow but that 1.9 will not properly use).
boundary-layer
is distributed via PyPI and can be installed using pip.
pip install boundary-layer --upgrade
We recommend installing into a virtual environment, but that's up to you.
You should now be able to run boundary-layer
and view its help message:
$ boundary-layer --help
If the installation was successful, you should see output like:
usage: boundary-layer [-h] {build-dag,prune-dag,parse-oozie} ...
positional arguments:
{build-dag,prune-dag,parse-oozie}
optional arguments:
-h, --help show this help message and exit
boundary-layer
is distributed via PyPI. We rely on an automated Github Actions build to publish updates. The build runs every time a tag is pushed to the repository. We have a script that automates the creation of these tags, making sure that they are versioned correctly and created for the intended commits.
The recommended process for publishing a relatively minor boundary layer update is to simply run
./release.py
which will bump the patch version.
For bigger changes, you can bump the minor (or major) versions, or you can force a specific version string, via one of the following commands:
./release.py --bump minor
./release.py --bump major
./release.py --force-version a.b.c
There are a few other options supported by the release.py
command, as described by the usage string:
╰$ ./release.py --help
usage: release.py [-h]
[--bump {major,minor,patch} | --force-version FORCE_VERSION]
[--git-remote-name GIT_REMOTE_NAME]
[--remote-branch-name REMOTE_BRANCH_NAME]
optional arguments:
-h, --help show this help message and exit
--bump {major,minor,patch}
Select the portion of the version string to bump.
default: `patch`
--force-version FORCE_VERSION
Force the new version to this value. Must be a valid
semver.
--git-remote-name GIT_REMOTE_NAME
Name of the git remote from which to release. default:
`origin`
--remote-branch-name REMOTE_BRANCH_NAME
Name of the remote branch to use as the basis for the
release. default: `master`
The primary feature of boundary-layer is its ability to build python DAGs from simple, structured YAML files.
Below is a simple boundary-layer yaml config, used for running a Hadoop job on Google Cloud Dataproc:
name: my_dag
dag_args:
schedule_interval: '@daily'
resources:
- name: dataproc-cluster
type: dataproc_cluster
properties:
cluster_name: my-cluster-{{ execution_date.strftime('%s') }}
num_workers: 10
region: us-central1
default_task_args:
owner: etsy-data-platform
project_id: my-project-id
retries: 2
start_date: '2018-10-31'
dataproc_hadoop_jars:
- gs://my-bucket/my/path/to/my.jar
before:
- name: data-sensor
type: gcs_object_sensor
properties:
bucket: my-bucket
object: my/object
operators:
- name: my-job
type: dataproc_hadoop
requires_resources:
- dataproc-cluster
properties:
main_class: com.etsy.my.job.ClassName
dataproc_hadoop_properties:
mapreduce.map.output.compress: 'true'
arguments: [ '--date', '{{ ds }}' ]
A few interesting features:
- The
resources
section of the configuration defines a transientDataProc
cluster resource that is required by the hadoop job.boundary-layer
will automatically insert the operators to create and delete this cluster, as well as the dependencies between the jobs and the cluster, when the DAG is created. - The
before
section of the configuration defines sensors that will be inserted byboundary-layer
as prerequisites for all downstream operations in the DAG, including the creation of the transient DataProc cluster.
To convert the above YAML config into a python DAG, save it to a file (for convenience, this DAG is already stored in the examples directory) and run
$ boundary-layer build-dag readme_example.yaml > readme_example.py
and, if all goes well, this will write a valid Airflow DAG into the file readme_example.py
. You should open this file up and look at its contents, to get a feel for what boundary-layer is doing. In particular, after some comments at the top of the file, you should see something like this:
import os
from airflow import DAG
import datetime
from airflow.operators.dummy_operator import DummyOperator
from airflow.contrib.sensors.gcs_sensor import GoogleCloudStorageObjectSensor
from airflow.contrib.operators.dataproc_operator import DataprocClusterDeleteOperator, DataProcHadoopOperator, DataprocClusterCreateOperator
DEFAULT_TASK_ARGS = {
'owner': 'etsy-data-platform',
'retries': 2,
'project_id': 'my-project-id',
'start_date': '2018-10-31',
'dataproc_hadoop_jars': ['gs://my-bucket/my/path/to/my.jar'],
}
dag = DAG(
schedule_interval = '@daily',
catchup = True,
max_active_runs = 1,
dag_id = 'my_dag',
default_args = DEFAULT_TASK_ARGS,
)
data_sensor = GoogleCloudStorageObjectSensor(
dag = (dag),
task_id = 'data_sensor',
object = 'my/object',
bucket = 'my-bucket',
start_date = (datetime.datetime(2018, 10, 31, 0, 0)),
)
dataproc_cluster_create = DataprocClusterCreateOperator(
dag = (dag),
task_id = 'dataproc_cluster_create',
num_workers = 10,
region = 'us-central1',
cluster_name = "my-cluster-{{ execution_date.strftime('%s') }}",
start_date = (datetime.datetime(2018, 10, 31, 0, 0)),
)
dataproc_cluster_create.set_upstream(data_sensor)
my_job = DataProcHadoopOperator(
dag = (dag),
task_id = 'my_job',
dataproc_hadoop_properties = { 'mapreduce.map.output.compress': 'true' },
region = 'us-central1',
start_date = (datetime.datetime(2018, 10, 31, 0, 0)),
cluster_name = "my-cluster-{{ execution_date.strftime('%s') }}",
arguments = ['--date','{{ ds }}'],
main_class = 'com.etsy.my.job.ClassName',
)
my_job.set_upstream(dataproc_cluster_create)
dataproc_cluster_destroy_sentinel = DummyOperator(
dag = (dag),
start_date = (datetime.datetime(2018, 10, 31, 0, 0)),
task_id = 'dataproc_cluster_destroy_sentinel',
)
dataproc_cluster_destroy_sentinel.set_upstream(my_job)
dataproc_cluster_destroy = DataprocClusterDeleteOperator(
dag = (dag),
task_id = 'dataproc_cluster_destroy',
trigger_rule = 'all_done',
region = 'us-central1',
cluster_name = "my-cluster-{{ execution_date.strftime('%s') }}",
priority_weight = 50,
start_date = (datetime.datetime(2018, 10, 31, 0, 0)),
)
dataproc_cluster_destroy.set_upstream(my_job)
This python DAG is now ready for ingestion directly into a running Airflow instance, following whatever procedure is appropriate for your Airflow deployments.
A few things to note:
boundary-layer
converted thestart_date
parameter from a string to a pythondatetime
object. This is an example of the boundary-layer argument-preprocessor feature, which allows config parameters to be specified as user-friendly strings and converted to the necessary python data structures automatically.boundary-layer
added asentinel
node in parallel with the cluster-destroy node, which serves as an indicator to Airflow itself regarding the ultimate outcome of the Dag Run. Airflow determines the Dag Run status from the leaf nodes of the DAG, and normally the cluster-destroy node will always execute (irrespective of upstream failures) and will likely succeed. This would cause DAGs with failures in critical nodes to be marked as successes, if not for the sentinel node. The sentinel node will only trigger if all of its upstream dependencies succeed --- otherwise it will be marked asupstream-failed
, which induces a failure state for the Dag Run.
In addition to allowing us to define Airflow workflows using YAML configurations, boundary-layer
also provides a module for converting Oozie XML configuration files into boundary-layer
YAML configurations, which can then be used to create Airflow DAGs.
Admittedly, boundary-layer
's Oozie support is currently limited: it is only capable of building DAGs that submit their Hadoop jobs to Dataproc (it does not support stand-alone Hadoop clusters, for example), and it does not support Oozie coordinators. We are open to working on improved Oozie support if there is community demand for it, and of course, we are open to community contributions toward this goal.
The following command will translate an example Oozie workflow to a boundary-layer DAG that will execute on a 64-node Dataproc cluster in GCP's us-east1
region, for the GCP project my-project-id
:
boundary-layer parse-oozie example \
--local-workflow-base-path test/data/oozie-workflows/ \
--cluster-project-id my-project-id \
--cluster-region us-east1 \
--cluster-num-workers 64