jason810496 commented on code in PR #68136: URL: https://github.com/apache/airflow/pull/68136#discussion_r3371161513
########## airflow-core/docs/core-concepts/resumable-tasks.rst: ########## @@ -0,0 +1,187 @@ + .. 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. + +.. _concepts-resumable-tasks: + +Resumable Tasks +=============== + +.. versionadded:: 3.3.0 + +Many data engineering workflows involve submitting work to an external system and waiting for it +to complete. A Spark job, a BigQuery query, a Kubernetes batch pod, an EMR step: these are all +tasks where the real work happens outside Airflow, and the operator's job is mostly to submit, +poll, and collect the result. + +These tasks share a common failure mode. In classic operator cases, the worker slot is held for the +entire polling duration, and if the worker process is restarted or the host is preempted, the task +retries from scratch, losing all the progress made. Depending on the operator, that means the external +job is submitted again, creating a duplicate run in context of the external system. + +Airflow recommends three approaches for handling long-running external work. Understanding the trade-offs +between them helps you choose the right one for your situation. + +.. _concepts-resumable-tasks-deferrable: + +Deferrable Operators +-------------------- + +A deferrable operator pauses itself at the point where it would otherwise start polling, hands +the polling work to the Triggerer component, and releases its worker slot. When the external +condition is met, the Triggerer wakes the task and the worker resumes from where the operator +left off. + +This is the most resource-efficient option. A single Triggerer process can concurrently watch +thousands of conditions, so the rest of the worker pool stays free for other tasks. + +The trade-offs are: + +* A Triggerer component must be running. Deployments that do not include a Triggerer cannot use this pattern. +* Writing a custom deferrable operator requires implementing a dedicated ``Trigger`` class in + addition to the operator itself. +* The polling logic runs inside the Triggerer's async event loop. Blocking calls inside a + Trigger stall the entire Triggerer process. + +If a deferrable operator already exists for your use case, or your team is comfortable +implementing one, this is the recommended path considering its resource efficiency. + +For more details, see :doc:`../authoring-and-scheduling/deferring`. + +.. _concepts-resumable-tasks-resumable: + +Resumable Tasks +--------------- + +A resumable task uses the task state store to persist a checkpoint before +it would otherwise lose progress. On retry, the task reads that checkpoint and continues from +where it left off rather than starting over. + +The worker slot is held for the full duration of the task, the same as a standard synchronous +operator. The benefit is crash safety and continuity, not resource efficiency. + +Resumable tasks are useful when: + +* No deferrable operator exists for your external system and writing one is not practical. +* You want crash recovery without operating a Triggerer. +* The task processes work incrementally (for example, reading files from a list or paginating + through API results) and should be able to resume from its last completed batch. + +**General pattern** + +The task reads a checkpoint from ``task_store`` at the start, does some work, writes an updated +checkpoint, and either continues or finishes. On the next run (whether due to a retry after a +crash or a deliberate reschedule), it reads the checkpoint again and picks up from there. + +.. code-block:: python + + from airflow.sdk import dag, task + + + @dag(schedule=None) + def process_files_dag(): + + @task(retries=5) + def process_files(context=None): + task_store = context["task_store"] + files = ["a.csv", "b.csv", "c.csv", "d.csv"] + + last_processed = task_store.get("last_processed") + start_index = 0 + if last_processed is not None: + start_index = files.index(last_processed) + 1 + + for file in files[start_index:]: + # ... process the file ... + task_store.set("last_processed", file) + + process_files() + + + process_files_dag() + +This pattern works without any additional work, relying only on ``context``. The state store is just +a key-value store scoped to the task instance, and what you checkpoint is up to you. + +**Resumable operators for external jobs** + +When the task submits a job to an external system and then polls for completion, there is an +additional problem: on retry, the task would submit a second job even though the first one may +still be running. Instead of having to handle this manually, the :class:`~airflow.sdk.ResumableJobMixin` +solves this by persisting the external job identifier before polling starts, and reconnecting to the +existing job on retry instead of submitting a new one. + +For more details and a working example, see :class:`~airflow.sdk.ResumableJobMixin`. + +.. _concepts-resumable-tasks-async: + +Asynchronous Tasks +------------------ + +.. note:: + + Async task support applies to Python tasks only: ``@task`` decorated ``async def`` functions + and class-based operators that subclass ``BaseAsyncOperator``. It is not available for + other operator types. + +Python tasks support ``async``/``await`` syntax. When the decorated callable is an async +function, Airflow runs it inside an event loop, which lets you fan out many concurrent I/O +operations (HTTP requests, database queries, file reads) within a single task execution without +blocking the event loop while waiting for each one. + +The worker slot is held for the full duration of the task. Async tasks are not designed for +long external waits or crash recovery; they are designed for high-throughput I/O work that +completes within a single execution. Review Comment: No problem and not blocking at all, or just having an issue to keep track of would be sufficient for now. -- This is an automated message from the Apache Git Service. To respond to the message, please log on to GitHub and use the URL above to go to the specific comment. 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