docs-archive/1.10.6/_sources/tutorial.rst.txt - airflow-site - Git at Google

  .. Licensed to the Apache Software Foundation (ASF) under one
     or more contributor license agreements.  See the NOTICE file
     distributed with this work for additional information
     regarding copyright ownership.  The ASF licenses this file
     to you under the Apache License, Version 2.0 (the
     "License"); you may not use this file except in compliance
     with the License.  You may obtain a copy of the License at

  ..   http://www.apache.org/licenses/LICENSE-2.0

  .. Unless required by applicable law or agreed to in writing,
     software distributed under the License is distributed on an
     "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY
     KIND, either express or implied.  See the License for the
     specific language governing permissions and limitations
     under the License.


 Tutorial
 ================

 This tutorial walks you through some of the fundamental Airflow concepts,
 objects, and their usage while writing your first pipeline.

 Example Pipeline definition
 ---------------------------

 Here is an example of a basic pipeline definition. Do not worry if this looks
 complicated, a line by line explanation follows below.

 .. code:: python

     """
     Code that goes along with the Airflow tutorial located at:
     https://github.com/apache/airflow/blob/master/airflow/example_dags/tutorial.py
     """
     from airflow import DAG
     from airflow.operators.bash_operator import BashOperator
     from datetime import datetime, timedelta


     default_args = {
         'owner': 'Airflow',
         'depends_on_past': False,
         'start_date': datetime(2015, 6, 1),
         'email': ['airflow@example.com'],
         'email_on_failure': False,
         'email_on_retry': False,
         'retries': 1,
         'retry_delay': timedelta(minutes=5),
         # 'queue': 'bash_queue',
         # 'pool': 'backfill',
         # 'priority_weight': 10,
         # 'end_date': datetime(2016, 1, 1),
     }

     dag = DAG('tutorial', default_args=default_args, schedule_interval=timedelta(days=1))

     # t1, t2 and t3 are examples of tasks created by instantiating operators
     t1 = BashOperator(
         task_id='print_date',
         bash_command='date',
         dag=dag)

     t2 = BashOperator(
         task_id='sleep',
         bash_command='sleep 5',
         retries=3,
         dag=dag)

     templated_command = """
         {% for i in range(5) %}
             echo "{{ ds }}"
             echo "{{ macros.ds_add(ds, 7)}}"
             echo "{{ params.my_param }}"
         {% endfor %}
     """

     t3 = BashOperator(
         task_id='templated',
         bash_command=templated_command,
         params={'my_param': 'Parameter I passed in'},
         dag=dag)

     t2.set_upstream(t1)
     t3.set_upstream(t1)


 It's a DAG definition file
 --------------------------

 One thing to wrap your head around (it may not be very intuitive for everyone
 at first) is that this Airflow Python script is really
 just a configuration file specifying the DAG's structure as code.
 The actual tasks defined here will run in a different context from
 the context of this script. Different tasks run on different workers
 at different points in time, which means that this script cannot be used
 to cross communicate between tasks. Note that for this
 purpose we have a more advanced feature called ``XCom``.

 People sometimes think of the DAG definition file as a place where they
 can do some actual data processing - that is not the case at all!
 The script's purpose is to define a DAG object. It needs to evaluate
 quickly (seconds, not minutes) since the scheduler will execute it
 periodically to reflect the changes if any.


 Importing Modules
 -----------------

 An Airflow pipeline is just a Python script that happens to define an
 Airflow DAG object. Let's start by importing the libraries we will need.

 .. code:: python

     # The DAG object; we'll need this to instantiate a DAG
     from airflow import DAG

     # Operators; we need this to operate!
     from airflow.operators.bash_operator import BashOperator

 Default Arguments
 -----------------
 We're about to create a DAG and some tasks, and we have the choice to
 explicitly pass a set of arguments to each task's constructor
 (which would become redundant), or (better!) we can define a dictionary
 of default parameters that we can use when creating tasks.

 .. code:: python

     from datetime import datetime, timedelta

     default_args = {
         'owner': 'Airflow',
         'depends_on_past': False,
         'start_date': datetime(2015, 6, 1),
         'email': ['airflow@example.com'],
         'email_on_failure': False,
         'email_on_retry': False,
         'retries': 1,
         'retry_delay': timedelta(minutes=5),
         # 'queue': 'bash_queue',
         # 'pool': 'backfill',
         # 'priority_weight': 10,
         # 'end_date': datetime(2016, 1, 1),
     }

 For more information about the BaseOperator's parameters and what they do,
 refer to the :py:class:`airflow.models.BaseOperator` documentation.

 Also, note that you could easily define different sets of arguments that
 would serve different purposes. An example of that would be to have
 different settings between a production and development environment.


 Instantiate a DAG
 -----------------

 We'll need a DAG object to nest our tasks into. Here we pass a string
 that defines the ``dag_id``, which serves as a unique identifier for your DAG.
 We also pass the default argument dictionary that we just defined and
 define a ``schedule_interval`` of 1 day for the DAG.

 .. code:: python

     dag = DAG(
         'tutorial', default_args=default_args, schedule_interval=timedelta(days=1))

 Tasks
 -----
 Tasks are generated when instantiating operator objects. An object
 instantiated from an operator is called a constructor. The first argument
 ``task_id`` acts as a unique identifier for the task.

 .. code:: python

     t1 = BashOperator(
         task_id='print_date',
         bash_command='date',
         dag=dag)

     t2 = BashOperator(
         task_id='sleep',
         bash_command='sleep 5',
         retries=3,
         dag=dag)

 Notice how we pass a mix of operator specific arguments (``bash_command``) and
 an argument common to all operators (``retries``) inherited
 from BaseOperator to the operator's constructor. This is simpler than
 passing every argument for every constructor call. Also, notice that in
 the second task we override the ``retries`` parameter with ``3``.

 The precedence rules for a task are as follows:

 1.  Explicitly passed arguments
 2.  Values that exist in the ``default_args`` dictionary
 3.  The operator's default value, if one exists

 A task must include or inherit the arguments ``task_id`` and ``owner``,
 otherwise Airflow will raise an exception.

 Templating with Jinja
 ---------------------
 Airflow leverages the power of
 `Jinja Templating <http://jinja.pocoo.org/docs/dev/>`_  and provides
 the pipeline author
 with a set of built-in parameters and macros. Airflow also provides
 hooks for the pipeline author to define their own parameters, macros and
 templates.

 This tutorial barely scratches the surface of what you can do with
 templating in Airflow, but the goal of this section is to let you know
 this feature exists, get you familiar with double curly brackets, and
 point to the most common template variable: ``{{ ds }}`` (today's "date
 stamp").

 .. code:: python

     templated_command = """
         {% for i in range(5) %}
             echo "{{ ds }}"
             echo "{{ macros.ds_add(ds, 7) }}"
             echo "{{ params.my_param }}"
         {% endfor %}
     """

     t3 = BashOperator(
         task_id='templated',
         bash_command=templated_command,
         params={'my_param': 'Parameter I passed in'},
         dag=dag)

 Notice that the ``templated_command`` contains code logic in ``{% %}`` blocks,
 references parameters like ``{{ ds }}``, calls a function as in
 ``{{ macros.ds_add(ds, 7)}}``, and references a user-defined parameter
 in ``{{ params.my_param }}``.

 The ``params`` hook in ``BaseOperator`` allows you to pass a dictionary of
 parameters and/or objects to your templates. Please take the time
 to understand how the parameter ``my_param`` makes it through to the template.

 Files can also be passed to the ``bash_command`` argument, like
 ``bash_command='templated_command.sh'``, where the file location is relative to
 the directory containing the pipeline file (``tutorial.py`` in this case). This
 may be desirable for many reasons, like separating your script's logic and
 pipeline code, allowing for proper code highlighting in files composed in
 different languages, and general flexibility in structuring pipelines. It is
 also possible to define your ``template_searchpath`` as pointing to any folder
 locations in the DAG constructor call.

 Using that same DAG constructor call, it is possible to define
 ``user_defined_macros`` which allow you to specify your own variables.
 For example, passing ``dict(foo='bar')`` to this argument allows you
 to use ``{{ foo }}`` in your templates. Moreover, specifying
 ``user_defined_filters`` allow you to register you own filters. For example,
 passing ``dict(hello=lambda name: 'Hello %s' % name)`` to this argument allows
 you to use ``{{ 'world' | hello }}`` in your templates. For more information
 regarding custom filters have a look at the
 `Jinja Documentation <http://jinja.pocoo.org/docs/dev/api/#writing-filters>`_

 For more information on the variables and macros that can be referenced
 in templates, make sure to read through the :doc:`macros`

 Setting up Dependencies
 -----------------------
 We have tasks ``t1``, ``t2`` and ``t3`` that do not depend on each other. Here's a few ways
 you can define dependencies between them:

 .. code:: python

     t1.set_downstream(t2)

     # This means that t2 will depend on t1
     # running successfully to run.
     # It is equivalent to:
     t2.set_upstream(t1)

     # The bit shift operator can also be
     # used to chain operations:
     t1 >> t2

     # And the upstream dependency with the
     # bit shift operator:
     t2 << t1

     # Chaining multiple dependencies becomes
     # concise with the bit shift operator:
     t1 >> t2 >> t3

     # A list of tasks can also be set as
     # dependencies. These operations
     # all have the same effect:
     t1.set_downstream([t2, t3])
     t1 >> [t2, t3]
     [t2, t3] << t1

 Note that when executing your script, Airflow will raise exceptions when
 it finds cycles in your DAG or when a dependency is referenced more
 than once.

 Recap
 -----
 Alright, so we have a pretty basic DAG. At this point your code should look
 something like this:

 .. code:: python

     """
     Code that goes along with the Airflow tutorial located at:
     https://github.com/apache/airflow/blob/master/airflow/example_dags/tutorial.py
     """
     from airflow import DAG
     from airflow.operators.bash_operator import BashOperator
     from datetime import datetime, timedelta


     default_args = {
         'owner': 'Airflow',
         'depends_on_past': False,
         'start_date': datetime(2015, 6, 1),
         'email': ['airflow@example.com'],
         'email_on_failure': False,
         'email_on_retry': False,
         'retries': 1,
         'retry_delay': timedelta(minutes=5),
         # 'queue': 'bash_queue',
         # 'pool': 'backfill',
         # 'priority_weight': 10,
         # 'end_date': datetime(2016, 1, 1),
     }

     dag = DAG(
         'tutorial', default_args=default_args, schedule_interval=timedelta(days=1))

     # t1, t2 and t3 are examples of tasks created by instantiating operators
     t1 = BashOperator(
         task_id='print_date',
         bash_command='date',
         dag=dag)

     t2 = BashOperator(
         task_id='sleep',
         bash_command='sleep 5',
         retries=3,
         dag=dag)

     templated_command = """
         {% for i in range(5) %}
             echo "{{ ds }}"
             echo "{{ macros.ds_add(ds, 7)}}"
             echo "{{ params.my_param }}"
         {% endfor %}
     """

     t3 = BashOperator(
         task_id='templated',
         bash_command=templated_command,
         params={'my_param': 'Parameter I passed in'},
         dag=dag)

     t2.set_upstream(t1)
     t3.set_upstream(t1)

 Testing
 --------

 Running the Script
 ''''''''''''''''''

 Time to run some tests. First, let's make sure the pipeline
 is parsed successfully.

 Let's assume we're saving the code from the previous step in
 ``tutorial.py`` in the DAGs folder referenced in your ``airflow.cfg``.
 The default location for your DAGs is ``~/airflow/dags``.

 .. code-block:: bash

     python ~/airflow/dags/tutorial.py

 If the script does not raise an exception it means that you haven't done
 anything horribly wrong, and that your Airflow environment is somewhat
 sound.

 Command Line Metadata Validation
 '''''''''''''''''''''''''''''''''
 Let's run a few commands to validate this script further.

 .. code-block:: bash

     # print the list of active DAGs
     airflow list_dags

     # prints the list of tasks the "tutorial" dag_id
     airflow list_tasks tutorial

     # prints the hierarchy of tasks in the tutorial DAG
     airflow list_tasks tutorial --tree


 Testing
 '''''''
 Let's test by running the actual task instances on a specific date. The
 date specified in this context is an ``execution_date``, which simulates the
 scheduler running your task or dag at a specific date + time:

 .. code-block:: bash

     # command layout: command subcommand dag_id task_id date

     # testing print_date
     airflow test tutorial print_date 2015-06-01

     # testing sleep
     airflow test tutorial sleep 2015-06-01

 Now remember what we did with templating earlier? See how this template
 gets rendered and executed by running this command:

 .. code-block:: bash

     # testing templated
     airflow test tutorial templated 2015-06-01

 This should result in displaying a verbose log of events and ultimately
 running your bash command and printing the result.

 Note that the ``airflow test`` command runs task instances locally, outputs
 their log to stdout (on screen), doesn't bother with dependencies, and
 doesn't communicate state (running, success, failed, ...) to the database.
 It simply allows testing a single task instance.

 Backfill
 ''''''''
 Everything looks like it's running fine so let's run a backfill.
 ``backfill`` will respect your dependencies, emit logs into files and talk to
 the database to record status. If you do have a webserver up, you'll be able
 to track the progress. ``airflow webserver`` will start a web server if you
 are interested in tracking the progress visually as your backfill progresses.

 Note that if you use ``depends_on_past=True``, individual task instances
 will depend on the success of the preceding task instance, except for the
 start_date specified itself, for which this dependency is disregarded.

 The date range in this context is a ``start_date`` and optionally an ``end_date``,
 which are used to populate the run schedule with task instances from this dag.

 .. code-block:: bash

     # optional, start a web server in debug mode in the background
     # airflow webserver --debug &

     # start your backfill on a date range
     airflow backfill tutorial -s 2015-06-01 -e 2015-06-07

 What's Next?
 -------------
 That's it, you've written, tested and backfilled your very first Airflow
 pipeline. Merging your code into a code repository that has a master scheduler
 running against it should get it to get triggered and run every day.

 Here's a few things you might want to do next:

 * Take an in-depth tour of the UI - click all the things!
 * Keep reading the docs! Especially the sections on:

     * Command line interface
     * Operators
     * Macros

 * Write your first pipeline!
	.. Licensed to the Apache Software Foundation (ASF) under one
	or more contributor license agreements. See the NOTICE file
	distributed with this work for additional information
	regarding copyright ownership. The ASF licenses this file
	to you under the Apache License, Version 2.0 (the
	"License"); you may not use this file except in compliance
	with the License. You may obtain a copy of the License at

	.. http://www.apache.org/licenses/LICENSE-2.0

	.. Unless required by applicable law or agreed to in writing,
	software distributed under the License is distributed on an
	"AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY
	KIND, either express or implied. See the License for the
	specific language governing permissions and limitations
	under the License.




	Tutorial
	================

	This tutorial walks you through some of the fundamental Airflow concepts,
	objects, and their usage while writing your first pipeline.

	Example Pipeline definition
	---------------------------

	Here is an example of a basic pipeline definition. Do not worry if this looks
	complicated, a line by line explanation follows below.

	.. code:: python

	"""
	Code that goes along with the Airflow tutorial located at:
	https://github.com/apache/airflow/blob/master/airflow/example_dags/tutorial.py
	"""
	from airflow import DAG
	from airflow.operators.bash_operator import BashOperator
	from datetime import datetime, timedelta


	default_args = {
	'owner': 'Airflow',
	'depends_on_past': False,
	'start_date': datetime(2015, 6, 1),
	'email': ['airflow@example.com'],
	'email_on_failure': False,
	'email_on_retry': False,
	'retries': 1,
	'retry_delay': timedelta(minutes=5),
	# 'queue': 'bash_queue',
	# 'pool': 'backfill',
	# 'priority_weight': 10,
	# 'end_date': datetime(2016, 1, 1),
	}

	dag = DAG('tutorial', default_args=default_args, schedule_interval=timedelta(days=1))

	# t1, t2 and t3 are examples of tasks created by instantiating operators
	t1 = BashOperator(
	task_id='print_date',
	bash_command='date',
	dag=dag)

	t2 = BashOperator(
	task_id='sleep',
	bash_command='sleep 5',
	retries=3,
	dag=dag)

	templated_command = """
	{% for i in range(5) %}
	echo "{{ ds }}"
	echo "{{ macros.ds_add(ds, 7)}}"
	echo "{{ params.my_param }}"
	{% endfor %}
	"""

	t3 = BashOperator(
	task_id='templated',
	bash_command=templated_command,
	params={'my_param': 'Parameter I passed in'},
	dag=dag)

	t2.set_upstream(t1)
	t3.set_upstream(t1)


	It's a DAG definition file
	--------------------------

	One thing to wrap your head around (it may not be very intuitive for everyone
	at first) is that this Airflow Python script is really
	just a configuration file specifying the DAG's structure as code.
	The actual tasks defined here will run in a different context from
	the context of this script. Different tasks run on different workers
	at different points in time, which means that this script cannot be used
	to cross communicate between tasks. Note that for this
	purpose we have a more advanced feature called ``XCom``.

	People sometimes think of the DAG definition file as a place where they
	can do some actual data processing - that is not the case at all!
	The script's purpose is to define a DAG object. It needs to evaluate
	quickly (seconds, not minutes) since the scheduler will execute it
	periodically to reflect the changes if any.


	Importing Modules
	-----------------

	An Airflow pipeline is just a Python script that happens to define an
	Airflow DAG object. Let's start by importing the libraries we will need.

	.. code:: python

	# The DAG object; we'll need this to instantiate a DAG
	from airflow import DAG

	# Operators; we need this to operate!
	from airflow.operators.bash_operator import BashOperator

	Default Arguments
	-----------------
	We're about to create a DAG and some tasks, and we have the choice to
	explicitly pass a set of arguments to each task's constructor
	(which would become redundant), or (better!) we can define a dictionary
	of default parameters that we can use when creating tasks.

	.. code:: python

	from datetime import datetime, timedelta

	default_args = {
	'owner': 'Airflow',
	'depends_on_past': False,
	'start_date': datetime(2015, 6, 1),
	'email': ['airflow@example.com'],
	'email_on_failure': False,
	'email_on_retry': False,
	'retries': 1,
	'retry_delay': timedelta(minutes=5),
	# 'queue': 'bash_queue',
	# 'pool': 'backfill',
	# 'priority_weight': 10,
	# 'end_date': datetime(2016, 1, 1),
	}

	For more information about the BaseOperator's parameters and what they do,
	refer to the :py:class:`airflow.models.BaseOperator` documentation.

	Also, note that you could easily define different sets of arguments that
	would serve different purposes. An example of that would be to have
	different settings between a production and development environment.


	Instantiate a DAG
	-----------------

	We'll need a DAG object to nest our tasks into. Here we pass a string
	that defines the ``dag_id``, which serves as a unique identifier for your DAG.
	We also pass the default argument dictionary that we just defined and
	define a ``schedule_interval`` of 1 day for the DAG.

	.. code:: python

	dag = DAG(
	'tutorial', default_args=default_args, schedule_interval=timedelta(days=1))

	Tasks
	-----
	Tasks are generated when instantiating operator objects. An object
	instantiated from an operator is called a constructor. The first argument
	``task_id`` acts as a unique identifier for the task.

	.. code:: python

	t1 = BashOperator(
	task_id='print_date',
	bash_command='date',
	dag=dag)

	t2 = BashOperator(
	task_id='sleep',
	bash_command='sleep 5',
	retries=3,
	dag=dag)

	Notice how we pass a mix of operator specific arguments (``bash_command``) and
	an argument common to all operators (``retries``) inherited
	from BaseOperator to the operator's constructor. This is simpler than
	passing every argument for every constructor call. Also, notice that in
	the second task we override the ``retries`` parameter with ``3``.

	The precedence rules for a task are as follows:

	1. Explicitly passed arguments
	2. Values that exist in the ``default_args`` dictionary
	3. The operator's default value, if one exists

	A task must include or inherit the arguments ``task_id`` and ``owner``,
	otherwise Airflow will raise an exception.

	Templating with Jinja
	---------------------
	Airflow leverages the power of
	`Jinja Templating <http://jinja.pocoo.org/docs/dev/>`_ and provides
	the pipeline author
	with a set of built-in parameters and macros. Airflow also provides
	hooks for the pipeline author to define their own parameters, macros and
	templates.

	This tutorial barely scratches the surface of what you can do with
	templating in Airflow, but the goal of this section is to let you know
	this feature exists, get you familiar with double curly brackets, and
	point to the most common template variable: ``{{ ds }}`` (today's "date
	stamp").

	.. code:: python

	templated_command = """
	{% for i in range(5) %}
	echo "{{ ds }}"
	echo "{{ macros.ds_add(ds, 7) }}"
	echo "{{ params.my_param }}"
	{% endfor %}
	"""

	t3 = BashOperator(
	task_id='templated',
	bash_command=templated_command,
	params={'my_param': 'Parameter I passed in'},
	dag=dag)

	Notice that the ``templated_command`` contains code logic in ``{% %}`` blocks,
	references parameters like ``{{ ds }}``, calls a function as in
	``{{ macros.ds_add(ds, 7)}}``, and references a user-defined parameter
	in ``{{ params.my_param }}``.

	The ``params`` hook in ``BaseOperator`` allows you to pass a dictionary of
	parameters and/or objects to your templates. Please take the time
	to understand how the parameter ``my_param`` makes it through to the template.

	Files can also be passed to the ``bash_command`` argument, like
	``bash_command='templated_command.sh'``, where the file location is relative to
	the directory containing the pipeline file (``tutorial.py`` in this case). This
	may be desirable for many reasons, like separating your script's logic and
	pipeline code, allowing for proper code highlighting in files composed in
	different languages, and general flexibility in structuring pipelines. It is
	also possible to define your ``template_searchpath`` as pointing to any folder
	locations in the DAG constructor call.

	Using that same DAG constructor call, it is possible to define
	``user_defined_macros`` which allow you to specify your own variables.
	For example, passing ``dict(foo='bar')`` to this argument allows you
	to use ``{{ foo }}`` in your templates. Moreover, specifying
	``user_defined_filters`` allow you to register you own filters. For example,
	passing ``dict(hello=lambda name: 'Hello %s' % name)`` to this argument allows
	you to use ``{{ 'world' \| hello }}`` in your templates. For more information
	regarding custom filters have a look at the
	`Jinja Documentation <http://jinja.pocoo.org/docs/dev/api/#writing-filters>`_

	For more information on the variables and macros that can be referenced
	in templates, make sure to read through the :doc:`macros`

	Setting up Dependencies
	-----------------------
	We have tasks ``t1``, ``t2`` and ``t3`` that do not depend on each other. Here's a few ways
	you can define dependencies between them:

	.. code:: python

	t1.set_downstream(t2)

	# This means that t2 will depend on t1
	# running successfully to run.
	# It is equivalent to:
	t2.set_upstream(t1)

	# The bit shift operator can also be
	# used to chain operations:
	t1 >> t2

	# And the upstream dependency with the
	# bit shift operator:
	t2 << t1

	# Chaining multiple dependencies becomes
	# concise with the bit shift operator:
	t1 >> t2 >> t3

	# A list of tasks can also be set as
	# dependencies. These operations
	# all have the same effect:
	t1.set_downstream([t2, t3])
	t1 >> [t2, t3]
	[t2, t3] << t1

	Note that when executing your script, Airflow will raise exceptions when
	it finds cycles in your DAG or when a dependency is referenced more
	than once.

	Recap
	-----
	Alright, so we have a pretty basic DAG. At this point your code should look
	something like this:

	.. code:: python

	"""
	Code that goes along with the Airflow tutorial located at:
	https://github.com/apache/airflow/blob/master/airflow/example_dags/tutorial.py
	"""
	from airflow import DAG
	from airflow.operators.bash_operator import BashOperator
	from datetime import datetime, timedelta


	default_args = {
	'owner': 'Airflow',
	'depends_on_past': False,
	'start_date': datetime(2015, 6, 1),
	'email': ['airflow@example.com'],
	'email_on_failure': False,
	'email_on_retry': False,
	'retries': 1,
	'retry_delay': timedelta(minutes=5),
	# 'queue': 'bash_queue',
	# 'pool': 'backfill',
	# 'priority_weight': 10,
	# 'end_date': datetime(2016, 1, 1),
	}

	dag = DAG(
	'tutorial', default_args=default_args, schedule_interval=timedelta(days=1))

	# t1, t2 and t3 are examples of tasks created by instantiating operators
	t1 = BashOperator(
	task_id='print_date',
	bash_command='date',
	dag=dag)

	t2 = BashOperator(
	task_id='sleep',
	bash_command='sleep 5',
	retries=3,
	dag=dag)

	templated_command = """
	{% for i in range(5) %}
	echo "{{ ds }}"
	echo "{{ macros.ds_add(ds, 7)}}"
	echo "{{ params.my_param }}"
	{% endfor %}
	"""

	t3 = BashOperator(
	task_id='templated',
	bash_command=templated_command,
	params={'my_param': 'Parameter I passed in'},
	dag=dag)

	t2.set_upstream(t1)
	t3.set_upstream(t1)

	Testing
	--------

	Running the Script
	''''''''''''''''''

	Time to run some tests. First, let's make sure the pipeline
	is parsed successfully.

	Let's assume we're saving the code from the previous step in
	``tutorial.py`` in the DAGs folder referenced in your ``airflow.cfg``.
	The default location for your DAGs is ``~/airflow/dags``.

	.. code-block:: bash

	python ~/airflow/dags/tutorial.py

	If the script does not raise an exception it means that you haven't done
	anything horribly wrong, and that your Airflow environment is somewhat
	sound.

	Command Line Metadata Validation
	'''''''''''''''''''''''''''''''''
	Let's run a few commands to validate this script further.

	.. code-block:: bash

	# print the list of active DAGs
	airflow list_dags

	# prints the list of tasks the "tutorial" dag_id
	airflow list_tasks tutorial

	# prints the hierarchy of tasks in the tutorial DAG
	airflow list_tasks tutorial --tree


	Testing
	'''''''
	Let's test by running the actual task instances on a specific date. The
	date specified in this context is an ``execution_date``, which simulates the
	scheduler running your task or dag at a specific date + time:

	.. code-block:: bash

	# command layout: command subcommand dag_id task_id date

	# testing print_date
	airflow test tutorial print_date 2015-06-01

	# testing sleep
	airflow test tutorial sleep 2015-06-01

	Now remember what we did with templating earlier? See how this template
	gets rendered and executed by running this command:

	.. code-block:: bash

	# testing templated
	airflow test tutorial templated 2015-06-01

	This should result in displaying a verbose log of events and ultimately
	running your bash command and printing the result.

	Note that the ``airflow test`` command runs task instances locally, outputs
	their log to stdout (on screen), doesn't bother with dependencies, and
	doesn't communicate state (running, success, failed, ...) to the database.
	It simply allows testing a single task instance.

	Backfill
	''''''''
	Everything looks like it's running fine so let's run a backfill.
	``backfill`` will respect your dependencies, emit logs into files and talk to
	the database to record status. If you do have a webserver up, you'll be able
	to track the progress. ``airflow webserver`` will start a web server if you
	are interested in tracking the progress visually as your backfill progresses.

	Note that if you use ``depends_on_past=True``, individual task instances
	will depend on the success of the preceding task instance, except for the
	start_date specified itself, for which this dependency is disregarded.

	The date range in this context is a ``start_date`` and optionally an ``end_date``,
	which are used to populate the run schedule with task instances from this dag.

	.. code-block:: bash

	# optional, start a web server in debug mode in the background
	# airflow webserver --debug &

	# start your backfill on a date range
	airflow backfill tutorial -s 2015-06-01 -e 2015-06-07

	What's Next?
	-------------
	That's it, you've written, tested and backfilled your very first Airflow
	pipeline. Merging your code into a code repository that has a master scheduler
	running against it should get it to get triggered and run every day.

	Here's a few things you might want to do next:

	* Take an in-depth tour of the UI - click all the things!
	* Keep reading the docs! Especially the sections on:

	* Command line interface
	* Operators
	* Macros

	* Write your first pipeline!