How to work with SnowflakeOperator XCOM JSON result? - python

I'm triggering the snowflake SP from Airflow using SnowflakeOperator, and want to build logic on top of the SP return code.
For example, for testing purposes, I have two steps with a simple CALL of two different procedures (let's say sp1 and sp2) - one that will fail and another one that will succeed.
When triggering the DAG in Airflow, they are working as expected and I can see the log for each of them, with the return message of its snowflake SP inside the DAG logs in a JSON format (two columns - P_RETURN_MSG and P_STATUS and its value). They aren't terminated in a SQL, but exception handled inside of SP and different return message printed for failed and succeeded.
For now, I have a problem that even if the SP failed (P_STATUS = -3) the DAG step still succeeds. So I want to work with the SPs return message to build some logic if P_STATUS = -3 then raise AirflowException() to fail my step manually.
To sum up: is there a way to work with SnowflakeOperator return message that is printed in the logs under the lines Statement execution info - {...}? If so, how to?
UPD:
From this answer I'm able to pull the last XCOM return value of my SnowflakeOperator and can see the correct log by debugging (with PythonOperaotr(t3), BashOperator(t4), or even when inserting it in a SQL parameter of the same SnowflakeOperator task).
But still can't manage to raise exceptions with my IF, it still succeeds. I can fail the next task by PythonOperator (t1), but how to fail the same task call_statement_1 with the SnowflakeOperator if the XCOM returns -3? Attaching pseudo code that I use:
...
dag = DAG(...)
insert_dag_run_op = TemplatePostgresOperator(...)
s3_to_snowflake = SnowflakeOperator(...)
def task_to_fail():
raise AirflowException("Test error msg")
def xcom_func(**kwargs):
context = kwargs
print('{{ task_instance.xcom_pull() }}')
t1 = PythonOperator( # Triggers the exception
task_id='python_fail',
python_callable=task_to_fail,
provide_context=True,
dag=dag
)
t3 = PythonOperator( # Prints correct xcom return value
task_id='python_xcom',
python_callable=xcom_func,
provide_context=True,
dag=dag
)
t4 = BashOperator( # Prints correct xcom return value
task_id='bash_xcom',
bash_command='echo {{ task_instance.xcom_pull() }}',
dag=dag)
def call(task_id, sql, params, snowflake_conn_id, warehouse, database, role, dag):
call_statement = SnowflakeOperator(task_id=task_id,
sql=sql,
params=params,
snowflake_conn_id=snowflake_conn_id,
warehouse=warehouse,
database=database,
role=role,
dag=dag
)
if "{{ task_instance.xcom_pull() }}".find("-3.0") != -1 : # Find/In - not working
#if "None" in "{{ task_instance.xcom_pull() }}": # None - not working
task_to_fail()
else:
return call_statement
call_statement_1 = call(...)
update_dag_run_op = TemplatePostgresOperator(...)
insert_dag_run_op >> s3_to_snowflake >> call_statement_1 >> t1 >> t3 >> t4 >> update_dag_run_op

Related

Airflow 1.10.15 dynamic task creation

I'm trying to create a DAG that will spawn N-tasks depending on the result of the previous task. The problem is that I cannot use the value returned from the previous task (in XCom) outside of Operator
Is there a way to make this work?
with DAG(
"spawn_dag",
start_date=datetime(2022, 1, 1)
) as dag:
# Calculates the number of tasks based on some previous task run
count_number_of_tasks = PythonOperator(
task_id='count_number_of_tasks',
python_callable=count_tasks_function,
dag=dag,
xcom_push=True,
provide_context=True
)
# Generates tasks and chains them
def dynamic_spawn_func(parent_dag_name, child_dag_name, start_date, args, **kwargs):
subdag = DAG(
dag_id=f"{parent_dag_name}.{child_dag_name}",
default_args=args,
start_date=start_date,
schedule_interval=None
)
# Here is the problem, the following variable cannot be used in a loop to spawn tasks
number_of_tasks = kwargs['ti'].xcom_pull(dag_id='spawn_dag', task_ids='count_number_of_tasks')
# This is where that variable is used
for j in range(number_of_tasks):
task = PythonOperator(
task_id='processor_' + str(j),
python_callable=some_func,
op_kwargs={"val": j},
dag=subdag,
provide_context=True)
task_2 = PythonOperator(
task_id='wait_for_processor_' + str(j),
python_callable=some_func,
op_kwargs={"val": j},
dag=subdag,
provide_context=True)
task >> task_2
return subdag
dynamic_spawn_op = SubDagOperator(
task_id='dynamic_spawn',
subdag=dynamic_spawn_func("spawn_dag", "dynamic_spawn", dag.start_date, args=default_args),
dag=dag,
provide_context=True
)
generate >> count_number_of_tasks >> dynamic_spawn_op
No. Migrate to Airflow 2.3+. Airlfow 1.10 is End of Life for 2 years now and you are shooting yourself in the foot by not upgrading. Not only you lack new features (like Dynamic Task Mapping) but also you make yourself super-vulnerable to potential security problems (there were 10s of CVEs fixed since 1.10) but also you put yourself in this position:
https://xkcd.com/979/
because you are one of the last peoople in the world who run Airflow 1.10.
Not upgrading at this stage is just very wrong decision because not upgrading costs you a LOT more than migration cost. Multiple times more.

conditionally_trigger for TriggerDagRunOperator

I have 2 DAGs: dag_a and dag_b (dag_a -> dag_b)
After dag_a is executed, TriggerDagRunOperator is called, which starts dag_b. The problem is, when dag_b is off (paused), dag_a's TriggerDagRunOperator creates scheduled runs in dag_b that queue up for as long as dag_a is running. After turning dag_b back ON, the execution of tasks from the queue begins.
I'm trying to find a solution for TriggerDagRunOperator, namely a conditionally_trigger function that would skip the execution of the TriggerDagRunOperator task if dag_b is paused (OFF). How can i do this?
You can use ShortCircuitOperator to execute/skip the downstream dag_b. Then, use the Airflow Rest API (or shell/CLI) to figure out whether dag_b is paused or not.
dag_a = TriggerDagRunOperator(
trigger_dag_id='dag_a',
...
)
pause_check = ShortCircuitOperator(
task_id='pause_check',
python_callable=is_dag_paused,
op_kwargs={
'dag_id': 'dag_b'
}
)
dag_b = TriggerDagRunOperator(
trigger_dag_id='dag_b',
...
)
dag_a >> pause_check >> dag_b
and is_dag_paused function can be like this. (here I use Rest API.)
def is_dag_paused(**kwargs):
import requests
from requests.auth import HTTPBasicAuth
dag_id = kwargs['dag_id']
res = requests.get(f'http://{airflow_host}/api/v1/dags/{dag_id}/details',
auth=HTTPBasicAuth('username', 'pasword')) # The auth method could be different for you.
if res.status_code == 200:
rjson = res.json()
# if you return True, the downstream tasks will be executed
# if False, it will be skipped
return not rjson['is_paused']
else:
print('Error: ', res)
exit(1)
import airflow.settings
from airflow.models import DagModel
def check_status_dag(*op_args):
session = airflow.settings.Session()
qry = session.query(DagModel).filter(DagModel.dag_id == op_args[0])
if not qry.value(DagModel.is_paused):
return op_args[1]
else: return op_args[2]
Where check_status_dag is the method of making a choice decision for executing a further branch, op_args[0] is the dag_id of the dag being checked for pause status, op_args[1] and op_args[2] are the names of the tasks in accordance with the logic of the BranchPythonOperator
start = DummyOperator(
task_id = 'start',
dag=dag
)
check_dag_B = BranchPythonOperator(
task_id = "check_dag_B",
python_callable = check_status_dag,
op_args = ['dag_B','trigger_dag_B','skip_trigger_dag_B'],
trigger_rule = 'all_done',
dag = dag
)
trigger_dag_B = TriggerDagRunOperator(
task_id = 'trigger_dag_B',
trigger_dag_id = 'dag_B',
dag = dag
)
skip_trigger_dag_B = DummyOperator(
task_id = 'skip_trigger_dag_B',
dag = dag
)
finish = DummyOperator(
task_id = 'finish',
trigger_rule = 'all_done',
dag=dag
)
start >> check_dag_B >> [trigger_dag_B, skip_trigger_dag_B] >> finish#or continue working

ti is not defined while pulling xcom variable in S3ToRedshiftOperator

I am using S3ToRedshiftOperator to load csv file into Redshift database. Kindly help to pass xcom variable to S3ToRedshiftOperator. How can we push xcom without using custom function?
Error:
NameError: name 'ti' is not defined
Using below code:
from airflow.operators.s3_to_redshift_operator import S3ToRedshiftOperator
def export_db_fn(**kwargs):
session = settings.Session()
outkey = S3_KEY.format(MWAA_ENV_NAME, name[6:])
print(outkey)
s3_client.put_object(Bucket=S3_BUCKET, Key=outkey, Body=f.getvalue())
ti.xcom_push(key='FILE_PATH', value=outkey)
return "OK"
with DAG(dag_id="export_info", schedule_interval=None, catchup=False, start_date=days_ago(1)) as dag:
export_info = PythonOperator(
task_id="export_info",
python_callable=export_db_fn,
provide_context=True
)
transfer_s3_to_redshift = S3ToRedshiftOperator(
s3_bucket=S3_BUCKET,
s3_key="{{ti.xcom_pull(key='FILE_PATH', task_ids='export_info')}}",
schema="dw_stage",
table=REDSHIFT_TABLE,
copy_options=['csv',"IGNOREHEADER 1"],
redshift_conn_id='redshift',
autocommit=True,
task_id='transfer_s3_to_redshift',
)
start >> export_info >> transfer_s3_to_redshift >> end
The error message tells the problem.
ti is not defined.
When you set provide_context=True, Airflow makes Context available for you in the python callable. One of the attributes is ti (see source code). So you need to extract it from kwargs or set it in the function signature.
Your code should be:
def export_db_fn(**kwargs):
...
ti = kwargs['ti']
ti.xcom_push(key='FILE_PATH', value=outkey)
...
Or if you want to use ti directly then:
def export_db_fn(ti, **kwargs):
...
ti.xcom_push(key='FILE_PATH', value=outkey)
...
Note: In Airflow >= 2.0 there is no need to set provide_context=True

How do I trigger a backfill with TriggerDagRunOperator?

I have a requirement where I need the dag triggered by TriggerDagRunOperator to execute a backfill and not just for the same execution date.
The TriggerDagOperator is set as follows:
trigger1 = TriggerDagRunOperator(
task_id = 'trigger1',
trigger_dag_id = 'target_dag',
conf = {'message': 'Starting target 1'},
reset_dag_run = True,
wait_for_completion = True
)
Target dag is basically:
starting_date = datetime.strptime("2021-11-15", "%Y-%m-%d")
with DAG("target_dag", default_args=default_args, schedule_interval='#daily', max_active_runs=10) as dag:
start = DummyOperator(
task_id = 'start'
)
t1 = PythonOperator(
task_id = "t1",
provide_context=True,
python_callable=t1
)
finish = DummyOperator(
task_id = 'finish'
)
start >> t1 >> finish
target_dag is only executing for today's date and not backfilling.
How do I force it to backfill regardless of past dag runs? I'm using airflow 2.0
this might be late now, but I have come up with 2 different solutions.
The first one (and probably the better) would be as follows:
from airflow.operators.latest_only_operator import LatestOnlyOperator
t1 = LatestOnlyOperator(task_id="ensure_backfill_complete")
I was stuck on a similar conundrum, and this suddenly popped in my head.
The 2nd one is basically wrapping the operator in a loop within a python function, which is honestly terrible.
and it seems to work.

Proper way to create dynamic workflows in Airflow

Problem
Is there any way in Airflow to create a workflow such that the number of tasks B.* is unknown until completion of Task A? I have looked at subdags but it looks like it can only work with a static set of tasks that have to be determined at Dag creation.
Would dag triggers work? And if so could you please provide an example.
I have an issue where it is impossible to know the number of task B's that will be needed to calculate Task C until Task A has been completed. Each Task B.* will take several hours to compute and cannot be combined.
|---> Task B.1 --|
|---> Task B.2 --|
Task A ------|---> Task B.3 --|-----> Task C
| .... |
|---> Task B.N --|
Idea #1
I don't like this solution because I have to create a blocking ExternalTaskSensor and all the Task B.* will take between 2-24 hours to complete. So I do not consider this a viable solution. Surely there is an easier way? Or was Airflow not designed for this?
Dag 1
Task A -> TriggerDagRunOperator(Dag 2) -> ExternalTaskSensor(Dag 2, Task Dummy B) -> Task C
Dag 2 (Dynamically created DAG though python_callable in TriggerDagrunOperator)
|-- Task B.1 --|
|-- Task B.2 --|
Task Dummy A --|-- Task B.3 --|-----> Task Dummy B
| .... |
|-- Task B.N --|
Edit 1:
As of now this question still does not have a great answer. I have been contacted by several people looking for a solution.
Here is how I did it with a similar request without any subdags:
First create a method that returns whatever values you want
def values_function():
return values
Next create method that will generate the jobs dynamically:
def group(number, **kwargs):
#load the values if needed in the command you plan to execute
dyn_value = "{{ task_instance.xcom_pull(task_ids='push_func') }}"
return BashOperator(
task_id='JOB_NAME_{}'.format(number),
bash_command='script.sh {} {}'.format(dyn_value, number),
dag=dag)
And then combine them:
push_func = PythonOperator(
task_id='push_func',
provide_context=True,
python_callable=values_function,
dag=dag)
complete = DummyOperator(
task_id='All_jobs_completed',
dag=dag)
for i in values_function():
push_func >> group(i) >> complete
Yes this is possible I've created an example DAG that demonstrates this.
import airflow
from airflow.operators.python_operator import PythonOperator
import os
from airflow.models import Variable
import logging
from airflow import configuration as conf
from airflow.models import DagBag, TaskInstance
from airflow import DAG, settings
from airflow.operators.bash_operator import BashOperator
main_dag_id = 'DynamicWorkflow2'
args = {
'owner': 'airflow',
'start_date': airflow.utils.dates.days_ago(2),
'provide_context': True
}
dag = DAG(
main_dag_id,
schedule_interval="#once",
default_args=args)
def start(*args, **kwargs):
value = Variable.get("DynamicWorkflow_Group1")
logging.info("Current DynamicWorkflow_Group1 value is " + str(value))
def resetTasksStatus(task_id, execution_date):
logging.info("Resetting: " + task_id + " " + execution_date)
dag_folder = conf.get('core', 'DAGS_FOLDER')
dagbag = DagBag(dag_folder)
check_dag = dagbag.dags[main_dag_id]
session = settings.Session()
my_task = check_dag.get_task(task_id)
ti = TaskInstance(my_task, execution_date)
state = ti.current_state()
logging.info("Current state of " + task_id + " is " + str(state))
ti.set_state(None, session)
state = ti.current_state()
logging.info("Updated state of " + task_id + " is " + str(state))
def bridge1(*args, **kwargs):
# You can set this value dynamically e.g., from a database or a calculation
dynamicValue = 2
variableValue = Variable.get("DynamicWorkflow_Group2")
logging.info("Current DynamicWorkflow_Group2 value is " + str(variableValue))
logging.info("Setting the Airflow Variable DynamicWorkflow_Group2 to " + str(dynamicValue))
os.system('airflow variables --set DynamicWorkflow_Group2 ' + str(dynamicValue))
variableValue = Variable.get("DynamicWorkflow_Group2")
logging.info("Current DynamicWorkflow_Group2 value is " + str(variableValue))
# Below code prevents this bug: https://issues.apache.org/jira/browse/AIRFLOW-1460
for i in range(dynamicValue):
resetTasksStatus('secondGroup_' + str(i), str(kwargs['execution_date']))
def bridge2(*args, **kwargs):
# You can set this value dynamically e.g., from a database or a calculation
dynamicValue = 3
variableValue = Variable.get("DynamicWorkflow_Group3")
logging.info("Current DynamicWorkflow_Group3 value is " + str(variableValue))
logging.info("Setting the Airflow Variable DynamicWorkflow_Group3 to " + str(dynamicValue))
os.system('airflow variables --set DynamicWorkflow_Group3 ' + str(dynamicValue))
variableValue = Variable.get("DynamicWorkflow_Group3")
logging.info("Current DynamicWorkflow_Group3 value is " + str(variableValue))
# Below code prevents this bug: https://issues.apache.org/jira/browse/AIRFLOW-1460
for i in range(dynamicValue):
resetTasksStatus('thirdGroup_' + str(i), str(kwargs['execution_date']))
def end(*args, **kwargs):
logging.info("Ending")
def doSomeWork(name, index, *args, **kwargs):
# Do whatever work you need to do
# Here I will just create a new file
os.system('touch /home/ec2-user/airflow/' + str(name) + str(index) + '.txt')
starting_task = PythonOperator(
task_id='start',
dag=dag,
provide_context=True,
python_callable=start,
op_args=[])
# Used to connect the stream in the event that the range is zero
bridge1_task = PythonOperator(
task_id='bridge1',
dag=dag,
provide_context=True,
python_callable=bridge1,
op_args=[])
DynamicWorkflow_Group1 = Variable.get("DynamicWorkflow_Group1")
logging.info("The current DynamicWorkflow_Group1 value is " + str(DynamicWorkflow_Group1))
for index in range(int(DynamicWorkflow_Group1)):
dynamicTask = PythonOperator(
task_id='firstGroup_' + str(index),
dag=dag,
provide_context=True,
python_callable=doSomeWork,
op_args=['firstGroup', index])
starting_task.set_downstream(dynamicTask)
dynamicTask.set_downstream(bridge1_task)
# Used to connect the stream in the event that the range is zero
bridge2_task = PythonOperator(
task_id='bridge2',
dag=dag,
provide_context=True,
python_callable=bridge2,
op_args=[])
DynamicWorkflow_Group2 = Variable.get("DynamicWorkflow_Group2")
logging.info("The current DynamicWorkflow value is " + str(DynamicWorkflow_Group2))
for index in range(int(DynamicWorkflow_Group2)):
dynamicTask = PythonOperator(
task_id='secondGroup_' + str(index),
dag=dag,
provide_context=True,
python_callable=doSomeWork,
op_args=['secondGroup', index])
bridge1_task.set_downstream(dynamicTask)
dynamicTask.set_downstream(bridge2_task)
ending_task = PythonOperator(
task_id='end',
dag=dag,
provide_context=True,
python_callable=end,
op_args=[])
DynamicWorkflow_Group3 = Variable.get("DynamicWorkflow_Group3")
logging.info("The current DynamicWorkflow value is " + str(DynamicWorkflow_Group3))
for index in range(int(DynamicWorkflow_Group3)):
# You can make this logic anything you'd like
# I chose to use the PythonOperator for all tasks
# except the last task will use the BashOperator
if index < (int(DynamicWorkflow_Group3) - 1):
dynamicTask = PythonOperator(
task_id='thirdGroup_' + str(index),
dag=dag,
provide_context=True,
python_callable=doSomeWork,
op_args=['thirdGroup', index])
else:
dynamicTask = BashOperator(
task_id='thirdGroup_' + str(index),
bash_command='touch /home/ec2-user/airflow/thirdGroup_' + str(index) + '.txt',
dag=dag)
bridge2_task.set_downstream(dynamicTask)
dynamicTask.set_downstream(ending_task)
# If you do not connect these then in the event that your range is ever zero you will have a disconnection between your stream
# and your tasks will run simultaneously instead of in your desired stream order.
starting_task.set_downstream(bridge1_task)
bridge1_task.set_downstream(bridge2_task)
bridge2_task.set_downstream(ending_task)
Before you run the DAG create these three Airflow Variables
airflow variables --set DynamicWorkflow_Group1 1
airflow variables --set DynamicWorkflow_Group2 0
airflow variables --set DynamicWorkflow_Group3 0
You'll see that the DAG goes from this
To this after it's ran
You can see more information on this DAG in my article on creating Dynamic Workflows On Airflow.
I have figured out a way to create workflows based on the result of previous tasks.
Basically what you want to do is have two subdags with the following:
Xcom push a list (or what ever you need to create the dynamic workflow later) in the subdag that gets executed first (see test1.py def return_list())
Pass the main dag object as a parameter to your second subdag
Now if you have the main dag object, you can use it to get a list of its task instances. From that list of task instances, you can filter out a task of the current run by using parent_dag.get_task_instances(settings.Session, start_date=parent_dag.get_active_runs()[-1])[-1]), one could probably add more filters here.
With that task instance, you can use xcom pull to get the value you need by specifying the dag_id to the one of the first subdag: dag_id='%s.%s' % (parent_dag_name, 'test1')
Use the list/value to create your tasks dynamically
Now I have tested this in my local airflow installation and it works fine. I don't know if the xcom pull part will have any problems if there is more than one instance of the dag running at the same time, but then you'd probably either use a unique key or something like that to uniquely identify the xcom value you want.
One could probably optimize the 3. step to be 100% sure to get a specific task of the current main dag, but for my use this performs well enough, I think one only needs one task_instance object to use xcom_pull.
Also I clean the xcoms for the first subdag before every execution, just to make sure that I don't accidentally get any wrong value.
I'm pretty bad at explaining, so I hope the following code will make everything clear:
test1.py
from airflow.models import DAG
import logging
from airflow.operators.python_operator import PythonOperator
from airflow.operators.postgres_operator import PostgresOperator
log = logging.getLogger(__name__)
def test1(parent_dag_name, start_date, schedule_interval):
dag = DAG(
'%s.test1' % parent_dag_name,
schedule_interval=schedule_interval,
start_date=start_date,
)
def return_list():
return ['test1', 'test2']
list_extract_folder = PythonOperator(
task_id='list',
dag=dag,
python_callable=return_list
)
clean_xcoms = PostgresOperator(
task_id='clean_xcoms',
postgres_conn_id='airflow_db',
sql="delete from xcom where dag_id='{{ dag.dag_id }}'",
dag=dag)
clean_xcoms >> list_extract_folder
return dag
test2.py
from airflow.models import DAG, settings
import logging
from airflow.operators.dummy_operator import DummyOperator
log = logging.getLogger(__name__)
def test2(parent_dag_name, start_date, schedule_interval, parent_dag=None):
dag = DAG(
'%s.test2' % parent_dag_name,
schedule_interval=schedule_interval,
start_date=start_date
)
if len(parent_dag.get_active_runs()) > 0:
test_list = parent_dag.get_task_instances(settings.Session, start_date=parent_dag.get_active_runs()[-1])[-1].xcom_pull(
dag_id='%s.%s' % (parent_dag_name, 'test1'),
task_ids='list')
if test_list:
for i in test_list:
test = DummyOperator(
task_id=i,
dag=dag
)
return dag
and the main workflow:
test.py
from datetime import datetime
from airflow import DAG
from airflow.operators.subdag_operator import SubDagOperator
from subdags.test1 import test1
from subdags.test2 import test2
DAG_NAME = 'test-dag'
dag = DAG(DAG_NAME,
description='Test workflow',
catchup=False,
schedule_interval='0 0 * * *',
start_date=datetime(2018, 8, 24))
test1 = SubDagOperator(
subdag=test1(DAG_NAME,
dag.start_date,
dag.schedule_interval),
task_id='test1',
dag=dag
)
test2 = SubDagOperator(
subdag=test2(DAG_NAME,
dag.start_date,
dag.schedule_interval,
parent_dag=dag),
task_id='test2',
dag=dag
)
test1 >> test2
What I think your are looking for is creating DAG dynamically
I encountered this type of situation few days ago after some search I found this blog.
Dynamic Task Generation
start = DummyOperator(
task_id='start',
dag=dag
)
end = DummyOperator(
task_id='end',
dag=dag)
def createDynamicETL(task_id, callableFunction, args):
task = PythonOperator(
task_id = task_id,
provide_context=True,
#Eval is used since the callableFunction var is of type string
#while the python_callable argument for PythonOperators only receives objects of type callable not strings.
python_callable = eval(callableFunction),
op_kwargs = args,
xcom_push = True,
dag = dag,
)
return task
Setting the DAG workflow
with open('/usr/local/airflow/dags/config_files/dynamicDagConfigFile.yaml') as f:
# Use safe_load instead to load the YAML file
configFile = yaml.safe_load(f)
# Extract table names and fields to be processed
tables = configFile['tables']
# In this loop tasks are created for each table defined in the YAML file
for table in tables:
for table, fieldName in table.items():
# In our example, first step in the workflow for each table is to get SQL data from db.
# Remember task id is provided in order to exchange data among tasks generated in dynamic way.
get_sql_data_task = createDynamicETL('{}-getSQLData'.format(table),
'getSQLData',
{'host': 'host', 'user': 'user', 'port': 'port', 'password': 'pass',
'dbname': configFile['dbname']})
# Second step is upload data to s3
upload_to_s3_task = createDynamicETL('{}-uploadDataToS3'.format(table),
'uploadDataToS3',
{'previous_task_id': '{}-getSQLData'.format(table),
'bucket_name': configFile['bucket_name'],
'prefix': configFile['prefix']})
# This is where the magic lies. The idea is that
# once tasks are generated they should linked with the
# dummy operators generated in the start and end tasks.
# Then you are done!
start >> get_sql_data_task
get_sql_data_task >> upload_to_s3_task
upload_to_s3_task >> end
This is how our DAG looks like after putting the code together
import yaml
import airflow
from airflow import DAG
from datetime import datetime, timedelta, time
from airflow.operators.python_operator import PythonOperator
from airflow.operators.dummy_operator import DummyOperator
start = DummyOperator(
task_id='start',
dag=dag
)
def createDynamicETL(task_id, callableFunction, args):
task = PythonOperator(
task_id=task_id,
provide_context=True,
# Eval is used since the callableFunction var is of type string
# while the python_callable argument for PythonOperators only receives objects of type callable not strings.
python_callable=eval(callableFunction),
op_kwargs=args,
xcom_push=True,
dag=dag,
)
return task
end = DummyOperator(
task_id='end',
dag=dag)
with open('/usr/local/airflow/dags/config_files/dynamicDagConfigFile.yaml') as f:
# use safe_load instead to load the YAML file
configFile = yaml.safe_load(f)
# Extract table names and fields to be processed
tables = configFile['tables']
# In this loop tasks are created for each table defined in the YAML file
for table in tables:
for table, fieldName in table.items():
# In our example, first step in the workflow for each table is to get SQL data from db.
# Remember task id is provided in order to exchange data among tasks generated in dynamic way.
get_sql_data_task = createDynamicETL('{}-getSQLData'.format(table),
'getSQLData',
{'host': 'host', 'user': 'user', 'port': 'port', 'password': 'pass',
'dbname': configFile['dbname']})
# Second step is upload data to s3
upload_to_s3_task = createDynamicETL('{}-uploadDataToS3'.format(table),
'uploadDataToS3',
{'previous_task_id': '{}-getSQLData'.format(table),
'bucket_name': configFile['bucket_name'],
'prefix': configFile['prefix']})
# This is where the magic lies. The idea is that
# once tasks are generated they should linked with the
# dummy operators generated in the start and end tasks.
# Then you are done!
start >> get_sql_data_task
get_sql_data_task >> upload_to_s3_task
upload_to_s3_task >> end
It was very help full
hope It will also help some one else
Only for v2.3 and above:
This feature is achieved using Dynamic Task Mapping, only for Airflow versions 2.3 and higher
More documentation and example here:
Official Dynamic Task Mapping documentation
Tutorial from Astronomer
Airflow v2.4 has added additional improvements
Example:
#task
def make_list():
# This can also be from an API call, checking a database, -- almost anything you like, as long as the
# resulting list/dictionary can be stored in the current XCom backend.
return [1, 2, {"a": "b"}, "str"]
#task
def consumer(arg):
print(list(arg))
with DAG(dag_id="dynamic-map", start_date=datetime(2022, 4, 2)) as dag:
consumer.expand(arg=make_list())
example 2:
from airflow import XComArg
task = MyOperator(task_id="source")
downstream = MyOperator2.partial(task_id="consumer").expand(input=XComArg(task))
The graph view and tree view are also updated:
Relevant issues here:
https://github.com/apache/airflow/projects/12
OA: "Is there any way in Airflow to create a workflow such that the number of tasks B.* is unknown until completion of Task A?"
Short answer is no. Airflow will build the DAG flow before starting to running it.
That said we came to a simple conclusion, that is we don't have such needing.
When you want to parallelize some work you should evaluate the resources you have available and not the number of items to process.
We did it like this: we dynamically generate a fixed number of tasks, say 10, that will split the job. For example if we need to process 100 files each task will process 10 of them. I will post the code later today.
Update
Here is the code, sorry for the delay.
from datetime import datetime, timedelta
import airflow
from airflow.operators.dummy_operator import DummyOperator
args = {
'owner': 'airflow',
'depends_on_past': False,
'start_date': datetime(2018, 1, 8),
'email': ['myemail#gmail.com'],
'email_on_failure': True,
'email_on_retry': True,
'retries': 1,
'retry_delay': timedelta(seconds=5)
}
dag = airflow.DAG(
'parallel_tasks_v1',
schedule_interval="#daily",
catchup=False,
default_args=args)
# You can read this from variables
parallel_tasks_total_number = 10
start_task = DummyOperator(
task_id='start_task',
dag=dag
)
# Creates the tasks dynamically.
# Each one will elaborate one chunk of data.
def create_dynamic_task(current_task_number):
return DummyOperator(
provide_context=True,
task_id='parallel_task_' + str(current_task_number),
python_callable=parallelTask,
# your task will take as input the total number and the current number to elaborate a chunk of total elements
op_args=[current_task_number, int(parallel_tasks_total_number)],
dag=dag)
end = DummyOperator(
task_id='end',
dag=dag)
for page in range(int(parallel_tasks_total_number)):
created_task = create_dynamic_task(page)
start_task >> created_task
created_task >> end
Code explanation:
Here we have a single start task and a single end task (both dummy).
Then from the start task with the for loop we create 10 tasks with the same python callable. The tasks are created in the function create_dynamic_task.
To each python callable we pass as arguments the total number of parallel tasks and the current task index.
Suppose you have 1000 items to elaborate: the first task will receive in input that it should elaborate the first chunk out of 10 chunks. It will divide the 1000 items into 10 chunks and elaborate the first one.
The jobs graph is not generated at run time. Rather the graph is built when it is picked up by Airflow from your dags folder. Therefore it isn't really going to be possible to have a different graph for the job every time it runs. You can configure a job to build a graph based on a query at load time. That graph will remain the same for every run after that, which is probably not very useful.
You can design a graph which executes different tasks on every run based on query results by using a Branch Operator.
What I've done is to pre-configure a set of tasks and then take the query results and distribute them across the tasks. This is probably better anyhow because if your query returns a lot of results, you probably don't want to flood the scheduler with a lot of concurrent tasks anyhow. To be even safer, I also used a pool to ensure my concurrency doesn't get out of hand with an unexpectedly large query.
"""
- This is an idea for how to invoke multiple tasks based on the query results
"""
import logging
from datetime import datetime
from airflow import DAG
from airflow.hooks.postgres_hook import PostgresHook
from airflow.operators.mysql_operator import MySqlOperator
from airflow.operators.python_operator import PythonOperator, BranchPythonOperator
from include.run_celery_task import runCeleryTask
########################################################################
default_args = {
'owner': 'airflow',
'catchup': False,
'depends_on_past': False,
'start_date': datetime(2019, 7, 2, 19, 50, 00),
'email': ['rotten#stackoverflow'],
'email_on_failure': True,
'email_on_retry': False,
'retries': 0,
'max_active_runs': 1
}
dag = DAG('dynamic_tasks_example', default_args=default_args, schedule_interval=None)
totalBuckets = 5
get_orders_query = """
select
o.id,
o.customer
from
orders o
where
o.created_at >= current_timestamp at time zone 'UTC' - '2 days'::interval
and
o.is_test = false
and
o.is_processed = false
"""
###########################################################################################################
# Generate a set of tasks so we can parallelize the results
def createOrderProcessingTask(bucket_number):
return PythonOperator(
task_id=f'order_processing_task_{bucket_number}',
python_callable=runOrderProcessing,
pool='order_processing_pool',
op_kwargs={'task_bucket': f'order_processing_task_{bucket_number}'},
provide_context=True,
dag=dag
)
# Fetch the order arguments from xcom and doStuff() to them
def runOrderProcessing(task_bucket, **context):
orderList = context['ti'].xcom_pull(task_ids='get_open_orders', key=task_bucket)
if orderList is not None:
for order in orderList:
logging.info(f"Processing Order with Order ID {order[order_id]}, customer ID {order[customer_id]}")
doStuff(**op_kwargs)
# Discover the orders we need to run and group them into buckets for processing
def getOpenOrders(**context):
myDatabaseHook = PostgresHook(postgres_conn_id='my_database_conn_id')
# initialize the task list buckets
tasks = {}
for task_number in range(0, totalBuckets):
tasks[f'order_processing_task_{task_number}'] = []
# populate the task list buckets
# distribute them evenly across the set of buckets
resultCounter = 0
for record in myDatabaseHook.get_records(get_orders_query):
resultCounter += 1
bucket = (resultCounter % totalBuckets)
tasks[f'order_processing_task_{bucket}'].append({'order_id': str(record[0]), 'customer_id': str(record[1])})
# push the order lists into xcom
for task in tasks:
if len(tasks[task]) > 0:
logging.info(f'Task {task} has {len(tasks[task])} orders.')
context['ti'].xcom_push(key=task, value=tasks[task])
else:
# if we didn't have enough tasks for every bucket
# don't bother running that task - remove it from the list
logging.info(f"Task {task} doesn't have any orders.")
del(tasks[task])
return list(tasks.keys())
###################################################################################################
# this just makes sure that there aren't any dangling xcom values in the database from a crashed dag
clean_xcoms = MySqlOperator(
task_id='clean_xcoms',
mysql_conn_id='airflow_db',
sql="delete from xcom where dag_id='{{ dag.dag_id }}'",
dag=dag)
# Ideally we'd use BranchPythonOperator() here instead of PythonOperator so that if our
# query returns fewer results than we have buckets, we don't try to run them all.
# Unfortunately I couldn't get BranchPythonOperator to take a list of results like the
# documentation says it should (Airflow 1.10.2). So we call all the bucket tasks for now.
get_orders_task = PythonOperator(
task_id='get_orders',
python_callable=getOpenOrders,
provide_context=True,
dag=dag
)
get_orders_task.set_upstream(clean_xcoms)
# set up the parallel tasks -- these are configured at compile time, not at run time:
for bucketNumber in range(0, totalBuckets):
taskBucket = createOrderProcessingTask(bucketNumber)
taskBucket.set_upstream(get_orders_task)
###################################################################################################
A great answer
Too much? Anyway.
A lot of the other answers are a bit square-peg-round-hole. Adding complicated new operators, abusing built in variables, or somewhat failing to answer the question. I wasn't particularly happy with any of them, as they either hide their behaviour when viewed through the web UI, are prone to breaking, or require a lot of custom code (that's also prone to breaking).
This solution uses built in functionality, requires no new operators and limited aditional code, the DAGs are visible through the UI without any tricks, and follows airflow best practice (see idempotency).
The solution to this problem is fairly complicated, so I've split it into several parts. These are:
How to safely trigger a dynamic number of tasks
How to wait for all of these tasks to finish then call a final task
How to integrate this into your task pipeline
Limitations (nothing is perfect)
Can a task trigger a dynamic number of other tasks?
Yes. Sortof. Without needing to write any new operators, it's possible to have a DAG trigger a dynamic number of other DAGs, using only builtin operators. This can then be expanded to have a DAG depend on a dynamic number of other DAGs (see waiting for tasks to finish). This is similar to flinz's solution, but more robust and with much less custom code.
This is done using a BranchPythonOperator that selectively triggers 2 other TriggerDagRunOperators. One of these recursively re-calls the current DAG, the other calls an external dag, the target function.
An example config that can be used to trigger the dag is given at the top of recursive_dag.py.
print_conf.py (an example DAG to trigger)
from datetime import timedelta
from airflow import DAG
from airflow.operators.python import PythonOperator
from airflow.utils.dates import days_ago
def print_output(dag_run):
dag_conf = dag_run.conf
if 'output' in dag_conf:
output = dag_conf['output']
else:
output = 'no output found'
print(output)
default_args = {
'owner': 'airflow',
'depends_on_past': False,
'retries': 0,
'retry_delay': timedelta(minutes=5),
}
with DAG(
'print_output',
start_date=days_ago(2),
tags=['my_test'],
default_args=default_args,
description='A simple test DAG',
schedule_interval=None
) as dag:
print_output = PythonOperator(
task_id='print_output_task',
python_callable=print_output
)
recursive_dag.py (Where the magic happens)
"""
DAG that can be used to trigger multiple other dags.
For example, trigger with the following config:
{
"task_list": ["print_output","print_output"],
"conf_list": [
{
"output": "Hello"
},
{
"output": "world!"
}
]
}
"""
from datetime import timedelta
import json
from airflow import DAG
from airflow.operators.python import BranchPythonOperator
from airflow.operators.trigger_dagrun import TriggerDagRunOperator
from airflow.utils.dates import days_ago
default_args = {
'owner': 'airflow',
'depends_on_past': False,
'retries': 0,
'retry_delay': timedelta(minutes=5),
}
dag_id = 'branch_recursive'
branch_id = 'branch_operator'
repeat_task_id = 'repeat_dag_operator'
repeat_task_conf = repeat_task_id + '_conf'
next_task_id = 'next_dag_operator'
next_task_conf = next_task_id + '_conf'
def choose_branch(task_instance, dag_run):
dag_conf = dag_run.conf
task_list = dag_conf['task_list']
next_task = task_list[0]
later_tasks = task_list[1:]
conf_list = dag_conf['conf_list']
# dump to string because value is stringified into
# template string, is then parsed.
next_conf = json.dumps(conf_list[0])
later_confs = conf_list[1:]
task_instance.xcom_push(key=next_task_id, value=next_task)
task_instance.xcom_push(key=next_task_conf, value=next_conf)
if later_tasks:
repeat_conf = json.dumps({
'task_list': later_tasks,
'conf_list': later_confs
})
task_instance.xcom_push(key=repeat_task_conf, value=repeat_conf)
return [next_task_id, repeat_task_id]
return next_task_id
def add_braces(in_string):
return '{{' + in_string + '}}'
def make_templated_pull(key):
pull = f'ti.xcom_pull(key=\'{key}\', task_ids=\'{branch_id}\')'
return add_braces(pull)
with DAG(
dag_id,
start_date=days_ago(2),
tags=['my_test'],
default_args=default_args,
description='A simple test DAG',
schedule_interval=None
) as dag:
branch = BranchPythonOperator(
task_id=branch_id,
python_callable=choose_branch
)
trigger_next = TriggerDagRunOperator(
task_id=next_task_id,
trigger_dag_id=make_templated_pull(next_task_id),
conf=make_templated_pull(next_task_conf)
)
trigger_repeat = TriggerDagRunOperator(
task_id=repeat_task_id,
trigger_dag_id=dag_id,
conf=make_templated_pull(repeat_task_conf)
)
branch >> [trigger_next, trigger_repeat]
This solution has the advantage of using very limited custom code. flinz's solution can fail part way through, resulting in some scheduled tasks and others not. Then on retry, DAGS may either be scheduled to run twice, or fail on the first dag resulting in partially complete work done by a failed task. This approach will tell you which DAGs have failed to trigger, and retry only the DAGs that failed to trigger. Therefore this approach is idempotent, the other isn't.
Can a DAG depend on a dynamic number of other DAGS?
Yes, but... This can be easily done if tasks don't run in parallel. Running in parallel is more complicated.
To run in sequence, the important changes are using wait_for_completion=True in trigger_next, use a python operator to setup the xcom values before "trigger_next", and adding a branch operator that either enables or disables the repeat task, then having a linear dependence
setup_xcom >> trigger_next >> branch >> trigger_repeat
To run in parallel, you can similarily recursively chain several ExternalTaskSensors that use templated external_dag_id values, and the timestamps associated with the triggered dag runs. To get the triggered dag timestamp, you can trigger a dag using the timestamp of the triggering dag. Then these sensors one by one wait for all of the created DAGs to complete, then trigger a final DAG. Code below, this time I've added a random sleep to the print output DAG, so that the wait dags actually do some waiting.
Note: recurse_wait_dag.py now defines 2 dags, both need to be enabled for this all to work.
An example config that can be used to trigger the dag is given at the top of recurse_wait_dag.py
print_conf.py (modified to add a random sleep)
"""
Simple dag that prints the output in DAG config
Used to demo TriggerDagRunOperator (see recursive_dag.py)
"""
from datetime import timedelta
from time import sleep
from random import randint
from airflow import DAG
from airflow.operators.python import PythonOperator
from airflow.utils.dates import days_ago
def print_output(dag_run):
sleep_time = randint(15,30)
print(f'sleeping for time: {sleep_time}')
sleep(sleep_time)
dag_conf = dag_run.conf
if 'output' in dag_conf:
output = dag_conf['output']
else:
output = 'no output found'
print(output)
default_args = {
'owner': 'airflow',
'depends_on_past': False,
'retries': 0,
'retry_delay': timedelta(minutes=5),
}
with DAG(
'print_output',
start_date=days_ago(2),
tags=['my_test'],
default_args=default_args,
description='A simple test DAG',
schedule_interval=None
) as dag:
print_output = PythonOperator(
task_id='print_output_task',
python_callable=print_output
)
recurse_wait_dag.py (where even more magic happens)
"""
DAG that can be used to trigger multiple other dags,
waits for all dags to execute, then triggers a final dag.
For example, trigger the DAG 'recurse_then_wait' with the following config:
{
"final_task": "print_output",
"task_list": ["print_output","print_output"],
"conf_list": [
{
"output": "Hello"
},
{
"output": "world!"
}
]
}
"""
from datetime import timedelta
import json
from airflow import DAG
from airflow.operators.python import BranchPythonOperator, PythonOperator
from airflow.operators.trigger_dagrun import TriggerDagRunOperator
from airflow.utils.dates import days_ago
from airflow.sensors.external_task import ExternalTaskSensor
from airflow.utils import timezone
from common import make_templated_pull
default_args = {
'owner': 'airflow',
'depends_on_past': False,
'retries': 0,
'retry_delay': timedelta(minutes=5),
}
def to_conf(id):
return f'{id}_conf'
def to_execution_date(id):
return f'{id}_execution_date'
def to_ts(id):
return f'{id}_ts'
recurse_dag_id = 'recurse_then_wait'
branch_id = 'recursive_branch'
repeat_task_id = 'repeat_dag_operator'
repeat_task_conf = to_conf(repeat_task_id)
next_task_id = 'next_dag_operator'
next_task_conf = to_conf(next_task_id)
next_task_execution_date = to_execution_date(next_task_id)
end_task_id = 'end_task'
end_task_conf = to_conf(end_task_id)
wait_dag_id = 'wait_after_recurse'
choose_wait_id = 'choose_wait'
next_wait_id = 'next_wait'
next_wait_ts = to_ts(next_wait_id)
def choose_branch(task_instance, dag_run, ts):
dag_conf = dag_run.conf
task_list = dag_conf['task_list']
next_task = task_list[0]
# can't have multiple dag runs of same DAG with same timestamp
assert next_task != recurse_dag_id
later_tasks = task_list[1:]
conf_list = dag_conf['conf_list']
next_conf = json.dumps(conf_list[0])
later_confs = conf_list[1:]
triggered_tasks = dag_conf.get('triggered_tasks', []) + [(next_task, ts)]
task_instance.xcom_push(key=next_task_id, value=next_task)
task_instance.xcom_push(key=next_task_conf, value=next_conf)
task_instance.xcom_push(key=next_task_execution_date, value=ts)
if later_tasks:
repeat_conf = json.dumps({
'task_list': later_tasks,
'conf_list': later_confs,
'triggered_tasks': triggered_tasks,
'final_task': dag_conf['final_task']
})
task_instance.xcom_push(key=repeat_task_conf, value=repeat_conf)
return [next_task_id, repeat_task_id]
end_conf = json.dumps({
'tasks_to_wait': triggered_tasks,
'final_task': dag_conf['final_task']
})
task_instance.xcom_push(key=end_task_conf, value=end_conf)
return [next_task_id, end_task_id]
def choose_wait_target(task_instance, dag_run):
dag_conf = dag_run.conf
tasks_to_wait = dag_conf['tasks_to_wait']
next_task, next_ts = tasks_to_wait[0]
later_tasks = tasks_to_wait[1:]
task_instance.xcom_push(key=next_wait_id, value=next_task)
task_instance.xcom_push(key=next_wait_ts, value=next_ts)
if later_tasks:
repeat_conf = json.dumps({
'tasks_to_wait': later_tasks,
'final_task': dag_conf['final_task']
})
task_instance.xcom_push(key=repeat_task_conf, value=repeat_conf)
def execution_date_fn(_, task_instance):
date_str = task_instance.xcom_pull(key=next_wait_ts, task_ids=choose_wait_id)
return timezone.parse(date_str)
def choose_wait_branch(task_instance, dag_run):
dag_conf = dag_run.conf
tasks_to_wait = dag_conf['tasks_to_wait']
if len(tasks_to_wait) == 1:
return end_task_id
return repeat_task_id
with DAG(
recurse_dag_id,
start_date=days_ago(2),
tags=['my_test'],
default_args=default_args,
description='A simple test DAG',
schedule_interval=None
) as recursive_dag:
branch = BranchPythonOperator(
task_id=branch_id,
python_callable=choose_branch
)
trigger_next = TriggerDagRunOperator(
task_id=next_task_id,
trigger_dag_id=make_templated_pull(next_task_id, branch_id),
execution_date=make_templated_pull(next_task_execution_date, branch_id),
conf=make_templated_pull(next_task_conf, branch_id)
)
trigger_repeat = TriggerDagRunOperator(
task_id=repeat_task_id,
trigger_dag_id=recurse_dag_id,
conf=make_templated_pull(repeat_task_conf, branch_id)
)
trigger_end = TriggerDagRunOperator(
task_id=end_task_id,
trigger_dag_id=wait_dag_id,
conf=make_templated_pull(end_task_conf, branch_id)
)
branch >> [trigger_next, trigger_repeat, trigger_end]
with DAG(
wait_dag_id,
start_date=days_ago(2),
tags=['my_test'],
default_args=default_args,
description='A simple test DAG',
schedule_interval=None
) as wait_dag:
py_operator = PythonOperator(
task_id=choose_wait_id,
python_callable=choose_wait_target
)
sensor = ExternalTaskSensor(
task_id='do_wait',
external_dag_id=make_templated_pull(next_wait_id, choose_wait_id),
execution_date_fn=execution_date_fn
)
branch = BranchPythonOperator(
task_id=branch_id,
python_callable=choose_wait_branch
)
trigger_repeat = TriggerDagRunOperator(
task_id=repeat_task_id,
trigger_dag_id=wait_dag_id,
conf=make_templated_pull(repeat_task_conf, choose_wait_id)
)
trigger_end = TriggerDagRunOperator(
task_id=end_task_id,
trigger_dag_id='{{ dag_run.conf[\'final_task\'] }}'
)
py_operator >> sensor >> branch >> [trigger_repeat, trigger_end]
Integrating with your code
That's great, but you want to actually use this. So, what do you need to do? The question includes an example trying to do the following:
|---> Task B.1 --|
|---> Task B.2 --|
Task A ------|---> Task B.3 --|-----> Task C
| .... |
|---> Task B.N --|
To achieve the question goal (example implementation below), you need to separate Tasks A, B and C into their own DAG. Then, in DAG A add a new operator at the end that triggers the above DAG 'recurse_then_wait'. Pass into this dag a config that includes the config needed for each B DAG, as well as the B dag id (this can be easily changed to use different dags, go nuts). Then include the name of DAG C, the final DAG, to be run at the end. This config should look like this:
{
"final_task": "C_DAG",
"task_list": ["B_DAG","B_DAG"],
"conf_list": [
{
"b_number": 1,
"more_stuff": "goes_here"
},
{
"b_number": 2,
"foo": "bar"
}
]
}
When implemented it should look something like this:
trigger_recurse.py
from datetime import timedelta
import json
from airflow import DAG
from airflow.operators.python import PythonOperator
from airflow.operators.trigger_dagrun import TriggerDagRunOperator
from airflow.utils.dates import days_ago
from recurse_wait_dag import recurse_dag_id
def add_braces(in_string):
return '{{' + in_string + '}}'
def make_templated_pull(key, task_id):
pull = f'ti.xcom_pull(key=\'{key}\', task_ids=\'{task_id}\')'
return add_braces(pull)
default_args = {
'owner': 'airflow',
'depends_on_past': False,
'retries': 0,
'retry_delay': timedelta(minutes=5),
}
setup_trigger_conf_id = 'setup_trigger_conf'
trigger_conf_key = 'trigger_conf'
def setup_trigger_conf(task_instance):
trigger_conf = {
'final_task': 'print_output',
'task_list': ['print_output','print_output'],
'conf_list': [
{
'output': 'Hello'
},
{
'output': 'world!'
}
]
}
print('Triggering the following tasks')
for task, conf in zip(trigger_conf['task_list'], trigger_conf['conf_list']):
print(f' task: {task} with config {json.dumps(conf)}')
print(f'then waiting for completion before triggering {trigger_conf["final_task"]}')
task_instance.xcom_push(key=trigger_conf_key, value=json.dumps(trigger_conf))
with DAG(
'trigger_recurse_example',
start_date=days_ago(2),
tags=['my_test'],
default_args=default_args,
description='A simple test DAG',
schedule_interval=None
) as dag:
py_operator = PythonOperator(
task_id=setup_trigger_conf_id,
python_callable=setup_trigger_conf
)
trigger_operator = TriggerDagRunOperator(
task_id='trigger_call_and_wait',
trigger_dag_id=recurse_dag_id,
conf=make_templated_pull(trigger_conf_key, setup_trigger_conf_id)
)
py_operator >> trigger_operator
All of this ends up looking something like the below, with vertical and horizontal lines to show where a DAG triggers another DAG:
A
|
Recurse - B.1
|
Recurse - B.2
|
...
|
Recurse - B.N
|
Wait for B.1
|
Wait for B.2
|
...
|
Wait for B.N
|
C
Limitations
Tasks are no longer visible on a single graph. This is probably the biggest problem with this approach. By adding tags to all associated DAGs, the DAGs can at least be viewed together. However relating multiple parallel runs of DAG B to runs of DAG A is messy. However, as a single DAG run shows its input conf, this means that each DAG B run doesn't depend on DAG A, only on it's input config. Therefore this relation can be at least partially ignored.
Tasks can no longer communicate using xcom. The B tasks can receive input from task A via DAG config, however task C can't get output from the B tasks. The results of all the B tasks should be put into a known location then read by task C.
The config argument to 'recurse_and_wait' could maybe be improved to combine task_list and conf_list, but this solves the problem as stated.
There's no config for the final DAG. That should be trivial to solve.
I think I have found a nicer solution to this at https://github.com/mastak/airflow_multi_dagrun, which uses simple enqueuing of DagRuns by triggering multiple dagruns, similar to TriggerDagRuns. Most of the credits go to https://github.com/mastak, although I had to patch some details to make it work with the most recent airflow.
The solution uses a custom operator that triggers several DagRuns:
from airflow import settings
from airflow.models import DagBag
from airflow.operators.dagrun_operator import DagRunOrder, TriggerDagRunOperator
from airflow.utils.decorators import apply_defaults
from airflow.utils.state import State
from airflow.utils import timezone
class TriggerMultiDagRunOperator(TriggerDagRunOperator):
CREATED_DAGRUN_KEY = 'created_dagrun_key'
#apply_defaults
def __init__(self, op_args=None, op_kwargs=None,
*args, **kwargs):
super(TriggerMultiDagRunOperator, self).__init__(*args, **kwargs)
self.op_args = op_args or []
self.op_kwargs = op_kwargs or {}
def execute(self, context):
context.update(self.op_kwargs)
session = settings.Session()
created_dr_ids = []
for dro in self.python_callable(*self.op_args, **context):
if not dro:
break
if not isinstance(dro, DagRunOrder):
dro = DagRunOrder(payload=dro)
now = timezone.utcnow()
if dro.run_id is None:
dro.run_id = 'trig__' + now.isoformat()
dbag = DagBag(settings.DAGS_FOLDER)
trigger_dag = dbag.get_dag(self.trigger_dag_id)
dr = trigger_dag.create_dagrun(
run_id=dro.run_id,
execution_date=now,
state=State.RUNNING,
conf=dro.payload,
external_trigger=True,
)
created_dr_ids.append(dr.id)
self.log.info("Created DagRun %s, %s", dr, now)
if created_dr_ids:
session.commit()
context['ti'].xcom_push(self.CREATED_DAGRUN_KEY, created_dr_ids)
else:
self.log.info("No DagRun created")
session.close()
You can then submit several dagruns from the callable function in your PythonOperator, for example:
from airflow.operators.dagrun_operator import DagRunOrder
from airflow.models import DAG
from airflow.operators import TriggerMultiDagRunOperator
from airflow.utils.dates import days_ago
def generate_dag_run(**kwargs):
for i in range(10):
order = DagRunOrder(payload={'my_variable': i})
yield order
args = {
'start_date': days_ago(1),
'owner': 'airflow',
}
dag = DAG(
dag_id='simple_trigger',
max_active_runs=1,
schedule_interval='#hourly',
default_args=args,
)
gen_target_dag_run = TriggerMultiDagRunOperator(
task_id='gen_target_dag_run',
dag=dag,
trigger_dag_id='common_target',
python_callable=generate_dag_run
)
I created a fork with the code at https://github.com/flinz/airflow_multi_dagrun
Do not understand what the problem is?
Here is a standard example.
Now if in function subdag replace for i in range(5): with for i in range(random.randint(0, 10)): then everything will work.
Now imagine that operator 'start' puts the data in a file, and instead of a random value, the function will read this data. Then operator 'start' will affect the number of tasks.
The problem will only be in the display in the UI since when entering the subdag, the number of tasks will be equal to the last read from the file/database/XCom at the moment.
Which automatically gives a restriction on several launches of one dag at one time.
Paradigm Shift
Based on all the answers here, it seems to me that the best approach is not to think of the dynamic "work list" generating code as an initial task, but rather as a pre-DAG definition computation.
This, of course, assumes that there is a single initial computation to be made only once and at the beginning each DAG run (as OP describes). This approach would not work if some halfway task must re-define the DAG, a pattern that airflow doesn't seem to be built for. However, consider chaining controller/target DAGs (see below).
Code sample:
from airflow.decorators import dag, task
from airflow.operators.dummy import DummyOperator
from airflow.providers.postgres.hooks.postgres import PostgresHook
from airflow.utils.dates import days_ago
DEFAULT_ARGS = {"owner": "airflow"}
def get_list_of_things(connection_id):
list_all_the_things_sql = """
SELECT * FROM things
"""
pg_hook = PostgresHook(postgres_conn_id=connection_id)
connection = pg_hook.get_conn()
cursor = connection.cursor()
cursor.execute(list_all_the_things_sql) # NOTE: this will execute to build the DAG, so if you grock the code, expect the DAG not to load, unless you have a valid postgres DB with a table named "things" and with things in it.
res = cursor.fetchall()
return res
#dag(default_args=DEFAULT_ARGS, schedule_interval="#once", start_date=days_ago(2), dag_id='test_joey_dag')
def dynamicly_generated_dag():
connection_id = "ProdDB"
#task
def do_a_thing(row):
print(row)
return row
start = DummyOperator(task_id='start')
end = DummyOperator(task_id='end')
data_list = get_list_of_things(connection_id)
for row in data_list:
start >> do_a_thing(row) >> end
dag = dynamicly_generated_dag()
If the get_list_of_things() computation is long, then perhaps it would be prudent to pre-compute it and trigger this DAG externally with a controller/target pattern:
trigger_controller_dag
trigger_target_dag
Depending on the context, this could be implemented in an asynchronous batch workers style. "Dynamic tasks" can be treated as list of work items to be done and split into asynchronous messages published into external message broker queue for worker nodes to pick up.
One tasks generates "work" dynamically and publishes all items (we don't know in advance how many and even which exactly) into a topic/queue.
Workers consume "work tasks" from the queue. Either directly if implemented using external to Airflow technology, or as as Airflow Sensor task (maybe in a separate DAG). When they finish processing their task, the Airflow Sensor gets triggered and the execution flow continues.
To restore the flow for individual work items, think about using EIP Claim Check pattern.
though question was asked 5 years back, but it's relevant today for many tasks.
I had the same requirement and i couldn't find the proper way to create dynamic tasks based on output of previous task, requirement in my case was:-
Create dynamic number of tasks based on previous tasks
These tasks had to be executed on remote GCP dataproc server using dataproc operators and not using PythonOperator which executes on airflow server.
Wrote approach i took briefly here. Give it a read if you have the same requirement and let me know if there are other ways too. Hope it helps.
You can do something like this for dynamically creating Postgres tasks for example:
for filename in some_files:
try:
f = open(f'{filename}')
query = f.read()
dynamic_task = PostgresOperator(
task_id=f"run_{filename}",
postgres_conn_id="some_connection",
sql=query
)
task_start >> dynamic_task >> task_end
finally:
f.close()
For versions under v2.3, you can do a sequential approach like this:
Use a python_operator. within that function, you can call another operator using the execute command, which isn't clearly documented..
Notes:
this will run sequentially (not exactly what OP is looking for but still useful in many cases)
the UI in the graph/treeview won't show all the items processed in the loop. sometimes not a big deal if you have enough logging in the loop.
the below example uses a triggerdagrunoperator for parent/child dag scenario but you can use a different operator.
def dynamic_executions(
df_data = pd.read_sql('select * from mytable', my_engine)
for row in df_data.itertuples():
trigger = TriggerDagRunOperator(
task_id="test1",
trigger_dag_id="my_child_dag",
conf={"message": row.column1},
execution_date=exec_date
)
-- key piece here, call execute
trigger.execute(kwcontext)
dynamic_executions= PythonOperator(
task_id='dynamic_executions',
python_callable=dynamic_executions,
)
I found this Medium post which is very similar to this question. However it is full of typos, and does not work when I tried implementing it.
My answer to the above is as follows:
If you are creating tasks dynamically you must do so by iterating over something which is not created by an upstream task, or can be defined independently of that task. I learned that you can't pass execution dates or other airflow variables to something outside of a template (e.g., a task) as many others have pointed out before. See also this post.

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