home / skills / wshobson / agents / python-background-jobs
This skill helps you implement Python background jobs and task queues, enabling asynchronous processing, idempotency, and reliable decoupled workflows.
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---
name: python-background-jobs
description: Python background job patterns including task queues, workers, and event-driven architecture. Use when implementing async task processing, job queues, long-running operations, or decoupling work from request/response cycles.
---
# Python Background Jobs & Task Queues
Decouple long-running or unreliable work from request/response cycles. Return immediately to the user while background workers handle the heavy lifting asynchronously.
## When to Use This Skill
- Processing tasks that take longer than a few seconds
- Sending emails, notifications, or webhooks
- Generating reports or exporting data
- Processing uploads or media transformations
- Integrating with unreliable external services
- Building event-driven architectures
## Core Concepts
### 1. Task Queue Pattern
API accepts request, enqueues a job, returns immediately with a job ID. Workers process jobs asynchronously.
### 2. Idempotency
Tasks may be retried on failure. Design for safe re-execution.
### 3. Job State Machine
Jobs transition through states: pending → running → succeeded/failed.
### 4. At-Least-Once Delivery
Most queues guarantee at-least-once delivery. Your code must handle duplicates.
## Quick Start
This skill uses Celery for examples, a widely adopted task queue. Alternatives like RQ, Dramatiq, and cloud-native solutions (AWS SQS, GCP Tasks) are equally valid choices.
```python
from celery import Celery
app = Celery("tasks", broker="redis://localhost:6379")
@app.task
def send_email(to: str, subject: str, body: str) -> None:
# This runs in a background worker
email_client.send(to, subject, body)
# In your API handler
send_email.delay("[email protected]", "Welcome!", "Thanks for signing up")
```
## Fundamental Patterns
### Pattern 1: Return Job ID Immediately
For operations exceeding a few seconds, return a job ID and process asynchronously.
```python
from uuid import uuid4
from dataclasses import dataclass
from enum import Enum
from datetime import datetime
class JobStatus(Enum):
PENDING = "pending"
RUNNING = "running"
SUCCEEDED = "succeeded"
FAILED = "failed"
@dataclass
class Job:
id: str
status: JobStatus
created_at: datetime
started_at: datetime | None = None
completed_at: datetime | None = None
result: dict | None = None
error: str | None = None
# API endpoint
async def start_export(request: ExportRequest) -> JobResponse:
"""Start export job and return job ID."""
job_id = str(uuid4())
# Persist job record
await jobs_repo.create(Job(
id=job_id,
status=JobStatus.PENDING,
created_at=datetime.utcnow(),
))
# Enqueue task for background processing
await task_queue.enqueue(
"export_data",
job_id=job_id,
params=request.model_dump(),
)
# Return immediately with job ID
return JobResponse(
job_id=job_id,
status="pending",
poll_url=f"/jobs/{job_id}",
)
```
### Pattern 2: Celery Task Configuration
Configure Celery tasks with proper retry and timeout settings.
```python
from celery import Celery
app = Celery("tasks", broker="redis://localhost:6379")
# Global configuration
app.conf.update(
task_time_limit=3600, # Hard limit: 1 hour
task_soft_time_limit=3000, # Soft limit: 50 minutes
task_acks_late=True, # Acknowledge after completion
task_reject_on_worker_lost=True,
worker_prefetch_multiplier=1, # Don't prefetch too many tasks
)
@app.task(
bind=True,
max_retries=3,
default_retry_delay=60,
autoretry_for=(ConnectionError, TimeoutError),
)
def process_payment(self, payment_id: str) -> dict:
"""Process payment with automatic retry on transient errors."""
try:
result = payment_gateway.charge(payment_id)
return {"status": "success", "transaction_id": result.id}
except PaymentDeclinedError as e:
# Don't retry permanent failures
return {"status": "declined", "reason": str(e)}
except TransientError as e:
# Retry with exponential backoff
raise self.retry(exc=e, countdown=2 ** self.request.retries * 60)
```
### Pattern 3: Make Tasks Idempotent
Workers may retry on crash or timeout. Design for safe re-execution.
```python
@app.task(bind=True)
def process_order(self, order_id: str) -> None:
"""Process order idempotently."""
order = orders_repo.get(order_id)
# Already processed? Return early
if order.status == OrderStatus.COMPLETED:
logger.info("Order already processed", order_id=order_id)
return
# Already in progress? Check if we should continue
if order.status == OrderStatus.PROCESSING:
# Use idempotency key to avoid double-charging
pass
# Process with idempotency key
result = payment_provider.charge(
amount=order.total,
idempotency_key=f"order-{order_id}", # Critical!
)
orders_repo.update(order_id, status=OrderStatus.COMPLETED)
```
**Idempotency Strategies:**
1. **Check-before-write**: Verify state before action
2. **Idempotency keys**: Use unique tokens with external services
3. **Upsert patterns**: `INSERT ... ON CONFLICT UPDATE`
4. **Deduplication window**: Track processed IDs for N hours
### Pattern 4: Job State Management
Persist job state transitions for visibility and debugging.
```python
class JobRepository:
"""Repository for managing job state."""
async def create(self, job: Job) -> Job:
"""Create new job record."""
await self._db.execute(
"""INSERT INTO jobs (id, status, created_at)
VALUES ($1, $2, $3)""",
job.id, job.status.value, job.created_at,
)
return job
async def update_status(
self,
job_id: str,
status: JobStatus,
**fields,
) -> None:
"""Update job status with timestamp."""
updates = {"status": status.value, **fields}
if status == JobStatus.RUNNING:
updates["started_at"] = datetime.utcnow()
elif status in (JobStatus.SUCCEEDED, JobStatus.FAILED):
updates["completed_at"] = datetime.utcnow()
await self._db.execute(
"UPDATE jobs SET status = $1, ... WHERE id = $2",
updates, job_id,
)
logger.info(
"Job status updated",
job_id=job_id,
status=status.value,
)
```
## Advanced Patterns
### Pattern 5: Dead Letter Queue
Handle permanently failed tasks for manual inspection.
```python
@app.task(bind=True, max_retries=3)
def process_webhook(self, webhook_id: str, payload: dict) -> None:
"""Process webhook with DLQ for failures."""
try:
result = send_webhook(payload)
if not result.success:
raise WebhookFailedError(result.error)
except Exception as e:
if self.request.retries >= self.max_retries:
# Move to dead letter queue for manual inspection
dead_letter_queue.send({
"task": "process_webhook",
"webhook_id": webhook_id,
"payload": payload,
"error": str(e),
"attempts": self.request.retries + 1,
"failed_at": datetime.utcnow().isoformat(),
})
logger.error(
"Webhook moved to DLQ after max retries",
webhook_id=webhook_id,
error=str(e),
)
return
# Exponential backoff retry
raise self.retry(exc=e, countdown=2 ** self.request.retries * 60)
```
### Pattern 6: Status Polling Endpoint
Provide an endpoint for clients to check job status.
```python
from fastapi import FastAPI, HTTPException
app = FastAPI()
@app.get("/jobs/{job_id}")
async def get_job_status(job_id: str) -> JobStatusResponse:
"""Get current status of a background job."""
job = await jobs_repo.get(job_id)
if job is None:
raise HTTPException(404, f"Job {job_id} not found")
return JobStatusResponse(
job_id=job.id,
status=job.status.value,
created_at=job.created_at,
started_at=job.started_at,
completed_at=job.completed_at,
result=job.result if job.status == JobStatus.SUCCEEDED else None,
error=job.error if job.status == JobStatus.FAILED else None,
# Helpful for clients
is_terminal=job.status in (JobStatus.SUCCEEDED, JobStatus.FAILED),
)
```
### Pattern 7: Task Chaining and Workflows
Compose complex workflows from simple tasks.
```python
from celery import chain, group, chord
# Simple chain: A → B → C
workflow = chain(
extract_data.s(source_id),
transform_data.s(),
load_data.s(destination_id),
)
# Parallel execution: A, B, C all at once
parallel = group(
send_email.s(user_email),
send_sms.s(user_phone),
update_analytics.s(event_data),
)
# Chord: Run tasks in parallel, then a callback
# Process all items, then send completion notification
workflow = chord(
[process_item.s(item_id) for item_id in item_ids],
send_completion_notification.s(batch_id),
)
workflow.apply_async()
```
### Pattern 8: Alternative Task Queues
Choose the right tool for your needs.
**RQ (Redis Queue)**: Simple, Redis-based
```python
from rq import Queue
from redis import Redis
queue = Queue(connection=Redis())
job = queue.enqueue(send_email, "[email protected]", "Subject", "Body")
```
**Dramatiq**: Modern Celery alternative
```python
import dramatiq
from dramatiq.brokers.redis import RedisBroker
dramatiq.set_broker(RedisBroker())
@dramatiq.actor
def send_email(to: str, subject: str, body: str) -> None:
email_client.send(to, subject, body)
```
**Cloud-native options:**
- AWS SQS + Lambda
- Google Cloud Tasks
- Azure Functions
## Best Practices Summary
1. **Return immediately** - Don't block requests for long operations
2. **Persist job state** - Enable status polling and debugging
3. **Make tasks idempotent** - Safe to retry on any failure
4. **Use idempotency keys** - For external service calls
5. **Set timeouts** - Both soft and hard limits
6. **Implement DLQ** - Capture permanently failed tasks
7. **Log transitions** - Track job state changes
8. **Retry appropriately** - Exponential backoff for transient errors
9. **Don't retry permanent failures** - Validation errors, invalid credentials
10. **Monitor queue depth** - Alert on backlog growth
This skill explains Python background job patterns for task queues, workers, and event-driven architectures. It shows practical patterns for decoupling long-running work from request/response cycles, making tasks idempotent, and tracking job state. Examples use Celery but note alternatives like RQ, Dramatiq, and cloud-native queues.
The skill describes how an API enqueues jobs and returns a job ID immediately while background workers process tasks asynchronously. It covers job state management, retries with exponential backoff, dead letter queues, and task chaining to build complex workflows. Configuration examples illustrate timeouts, acknowledgement behavior, and retry policies to make processing robust and observable.
Which task queue should I pick for a new project?
Start with Celery for feature richness or RQ/Dramatiq for simpler setups; choose cloud-native queues when you need managed infrastructure (SQS, Cloud Tasks). Match the tool to scale, operational complexity, and language/runtime constraints.
How do I avoid double-processing after worker crashes?
Make operations idempotent, use idempotency keys when calling external services, persist job state, and check state before performing destructive actions. Configure late acknowledgements and small prefetch sizes to reduce duplicates.