Skip to content

celery-capillary/capillary

Folders and files

NameName
Last commit message
Last commit date

Latest commit

 

History

52 Commits
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Repository files navigation

.. currentmodule:: capillary

Capillary

Status:Alpha (API feedback is welcome, API could break compatibility)
Generated:|today|
Version:|release|
License:BSD 3 Clause
Authors:Domen Kožar and Aaron McMillin

Introduction

:mod:`capillary` is a small integration package for the :mod:`celery` Distributed Task Queue with an aim of designing workflows (Canvas) in a declarative manner using Python decorators.

The main reason why :mod:`capillary` exists is to get rid of manual tracking how celery tasks depend on each other.

:mod:`capillary` executes in two phases:

  1. Scans for all Celery tasks in defined Python packages
  2. Executes tasks based on metadata passed to :func:`@pipeline` decorators

:mod:`capillary` uses:

  • :mod:`venusian` to discover Celery tasks using deferred decorators
  • :mod:`networkx` to handle the graph operations for tracking dependencies between tasks in the workflow

User Guide

Simple Example

Below is the first steps with Celery tutorial expanded with :mod:`capillary` integration.

The tasks.py module contains the steps of the pipeline. Steps are marked with the @pipeline decorator, which has optional parameters to indicate that this step must be executed after some other step or that the step has certain tags to allow groups of tasks to be executed together.

from capillary import pipeline

@pipeline()
def foo(celery_task):
    return 'simple task flow'

@pipeline(after='foo')
def bar(celery_task, l):
    return l.upper()

The myapp.py module then creates a :class:`PipelineConfigurator` instance which will assemble the declared steps:

from celery import Celery
from capillary import PipelineConfigurator

import tasks

app = Celery('tasks', broker='redis://', backend='redis://')
pc = PipelineConfigurator(app)
pc.scan(tasks)

Start the worker with

$ celery worker -A myapp -D

and execute the pipeline in a Python shell:

>>> from myapp import pc
>>> asyncresult = pc.run()
>>> asyncresult.get()
SIMPLE TASK FLOW

This example will be used throughout the user guide as a base.

Note

This example assumes the Redis broker is running with default settings, but any Celery broker will do.

backend is defined only for retrieving the result using .get(), it is otherwise not required.

Core concept: Handling input and output parameters

Celery uses a concept called partials (sometimes also known as Currying) to create function signatures.

:mod:`capillary` reuses these concepts to execute tasks. A value returned from task foo is passed into task bar.

It is possible to pass extra parameters to specific tasks as described in :ref:`extra-parameters`.

Core concept: Tagging pipelines

By default :meth:`PipelineConfigurator.run` will execute all scanned tasks without tags in topological order.

If tags=['foobar'] is passed to :func:`@pipeline`, the task will be run when `tagged_as=['foobar'] is passed to :meth:`PipelineConfigurator.run`.

See :ref:`predefined_defaults` for information on how to reduce boilerplate and group pipelines per tag.

Aborting the Pipeline

If a step needs to stop the current pipeline (meaning no further tasks are processed in the pipeline), just raise :exc:`capillary.AbortPipeline` anywhere in your pipeline tasks.

Passing extra parameters to a specific task

Some :func:`@pipeline` elements might require extra arguments that are only known when :meth:`PipelineConfigurator.run` is called.

>>> @pipeline(
...     required_kwarg_names=['param'],
... )
... def foobar(celery_task, param=None):
...     print param
...     return 'simple task flow'

When :meth:`PipelineConfigurator.run` is called, it will need param passed inside required_kwargs; otherwise :exc:`MissingArgument` will be thrown.

Applying multiple :func:`@pipeline` decorators

The most typical use case where two :func:`@pipeline` decorators are useful is when you'd like to reuse a function for two different pipelines each differently tagged.

@pipeline(
    after=['first', 'second'],
    tags=['some_pipeline'],
)
@pipeline(
    after=['third'],
    tags=['other_pipeline'],
)
def foobar(celery_task):
    return 'simple task flow'

Executing ConfigurePipeline.run(tagged_as=['some_pipeline']) would run the foobar function as a task after first and second tasks were done.

However executing ConfigurePipeline.run(tagged_as=['other_pipeline']) would run the foobar function after third task was done.

Note

If both tags are used (e.g. ConfigurePipeline.run(tagged_as=['some_pipeline', 'other_pipeline'])) then ordering of tags specified matters and the latter will override a former.

if you specify a different name parameter for each, they will be both executed.

Create pipelines based on predefined defaults

Often :func:`@pipeline` definitions will repeat arguments through your application. :func:`make_pipeline_from_defaults` allows you to create customized predefined defaults for a pipeline. This example makes a foobar_pipeline decorator that will apply the same tag to each step:

>>> from capillary import make_pipeline_from_defaults
>>> foobar_pipeline = make_pipeline_from_defaults(
>>>     tags=["foobar"]
>>> )

Then use @foobar_pipeline just as one would use :func:`@pipeline` while all your definitions will have foobar as a tag.

Note

Passing tags to @foobar_pipeline will override ["foobar"] value.

Printing the task tree

To actually see what kind of canvas will be executed call :meth:`ConfigurePipeline.prettyprint` with the same arguments as :meth:`ConfigurePipeline.run`

>>> pc.prettyprint(args=[], kwargs={})
tasks.foo() | tasks.bar()

The very last task in the pipeline

Using a constant :class:`capillary.ALL` it's possible to declare a task as the last one in the pipeline

>>> from capillary import ALL, pipeline
>>> @pipeline(
...   after=ALL,
... )
... def last(celery_task, obj):
...    print('ALL DONE!')
...    return obj

Note

Multiple tasks with after=ALL steps will be run in :class:`celery.group` as the last part of the pipeline.

The following is a quick summary of what happens inside :meth:`~PipelineConfigurator.run()`:

  • task tree is generated using dependency information
  • Celery signatures are created
  • task tree is reduced into a chain using topological sort
  • tasks is executed using :meth:`celery.app.Task.apply_async`

Note

Currently the task tree is reduced into a linear chained list of tasks, but in future different "runners" could be implemented.

Unit Testing

Functions marked as :func:`@pipeline` elements are still just simple untouched functions, until :meth:`PipelineConfigurator.scan()` is called. If function code doesn't depend on the first argument of celery_task, just pass None as the value.

To unit test our two pipeline elements from :ref:`simple-example`:

class PipelineTestCase(unittest.TestCase):

    def test_bar(self):
        self.assertEquals(bar(None, 'test'), 'TEST')

    def test_foo(self):
        self.assertEquals(foo(None), 'simple task flow')

Development

To run tests install py.test and run it:

$ py.test tests/

Features to be considered

  • Using a lot of tasks with large objects passed as arguments can be quite storage intensive. One alternative would be to generate signatures on-the-fly if Celery permits that.

API Reference

.. automodule:: capillary
    :members:
    :exclude-members: PipelineConfigurator
.. autoclass:: capillary.PipelineConfigurator
    :members: run, prettyprint, scan

About

No description, website, or topics provided.

Resources

License

Stars

Watchers

Forks

Releases

No releases published

Packages

No packages published

Languages