next-steps.rst 22 KB

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  1. .. _next-steps:
  2. ============
  3. Next Steps
  4. ============
  5. The :ref:`first-steps` guide is intentionally minimal. In this guide
  6. I will demonstrate what Celery offers in more detail, including
  7. how to add Celery support for your application and library.
  8. This document does not document all of Celery's features and
  9. best practices, so it's recommended that you also read the
  10. :ref:`User Guide <guide>`
  11. .. contents::
  12. :local:
  13. :depth: 1
  14. Using Celery in your Application
  15. ================================
  16. .. _project-layout:
  17. Our Project
  18. -----------
  19. Project layout::
  20. proj/__init__.py
  21. /celery.py
  22. /tasks.py
  23. :file:`proj/celery.py`
  24. ~~~~~~~~~~~~~~~~~~~~~~
  25. .. literalinclude:: ../../examples/next-steps/proj/celery.py
  26. :language: python
  27. In this module you created our :class:`@Celery` instance (sometimes
  28. referred to as the *app*). To use Celery within your project
  29. you simply import this instance.
  30. - The ``broker`` argument specifies the URL of the broker to use.
  31. See :ref:`celerytut-broker` for more information.
  32. - The ``backend`` argument specifies the result backend to use,
  33. It's used to keep track of task state and results.
  34. While results are disabled by default I use the RPC result backend here
  35. because I demonstrate how retrieving results work later, you may want to use
  36. a different backend for your application. They all have different
  37. strengths and weaknesses. If you don't need results it's better
  38. to disable them. Results can also be disabled for individual tasks
  39. by setting the ``@task(ignore_result=True)`` option.
  40. See :ref:`celerytut-keeping-results` for more information.
  41. - The ``include`` argument is a list of modules to import when
  42. the worker starts. You need to add our tasks module here so
  43. that the worker is able to find our tasks.
  44. :file:`proj/tasks.py`
  45. ~~~~~~~~~~~~~~~~~~~~~
  46. .. literalinclude:: ../../examples/next-steps/proj/tasks.py
  47. :language: python
  48. Starting the worker
  49. -------------------
  50. The :program:`celery` program can be used to start the worker (you need to run the worker in the directory above proj):
  51. .. code-block:: console
  52. $ celery -A proj worker -l info
  53. When the worker starts you should see a banner and some messages::
  54. -------------- celery@halcyon.local v4.0 (0today8)
  55. ---- **** -----
  56. --- * *** * -- [Configuration]
  57. -- * - **** --- . broker: amqp://guest@localhost:5672//
  58. - ** ---------- . app: __main__:0x1012d8590
  59. - ** ---------- . concurrency: 8 (processes)
  60. - ** ---------- . events: OFF (enable -E to monitor this worker)
  61. - ** ----------
  62. - *** --- * --- [Queues]
  63. -- ******* ---- . celery: exchange:celery(direct) binding:celery
  64. --- ***** -----
  65. [2012-06-08 16:23:51,078: WARNING/MainProcess] celery@halcyon.local has started.
  66. -- The *broker* is the URL you specified in the broker argument in our ``celery``
  67. module, you can also specify a different broker on the command-line by using
  68. the :option:`-b <celery -b>` option.
  69. -- *Concurrency* is the number of prefork worker process used
  70. to process your tasks concurrently, when all of these are busy doing work
  71. new tasks will have to wait for one of the tasks to finish before
  72. it can be processed.
  73. The default concurrency number is the number of CPU's on that machine
  74. (including cores), you can specify a custom number using
  75. the :option:`celery worker -c` option.
  76. There is no recommended value, as the optimal number depends on a number of
  77. factors, but if your tasks are mostly I/O-bound then you can try to increase
  78. it, experimentation has shown that adding more than twice the number
  79. of CPU's is rarely effective, and likely to degrade performance
  80. instead.
  81. Including the default prefork pool, Celery also supports using
  82. Eventlet, Gevent, and running in a single thread (see :ref:`concurrency`).
  83. -- *Events* is an option that when enabled causes Celery to send
  84. monitoring messages (events) for actions occurring in the worker.
  85. These can be used by monitor programs like ``celery events``,
  86. and Flower - the real-time Celery monitor, which you can read about in
  87. the :ref:`Monitoring and Management guide <guide-monitoring>`.
  88. -- *Queues* is the list of queues that the worker will consume
  89. tasks from. The worker can be told to consume from several queues
  90. at once, and this is used to route messages to specific workers
  91. as a means for Quality of Service, separation of concerns,
  92. and prioritization, all described in the :ref:`Routing Guide
  93. <guide-routing>`.
  94. You can get a complete list of command-line arguments
  95. by passing in the :option:`--help <celery --help>` flag:
  96. .. code-block:: console
  97. $ celery worker --help
  98. These options are described in more detailed in the :ref:`Workers Guide <guide-workers>`.
  99. Stopping the worker
  100. ~~~~~~~~~~~~~~~~~~~
  101. To stop the worker simply hit :kbd:`Control-c`. A list of signals supported
  102. by the worker is detailed in the :ref:`Workers Guide <guide-workers>`.
  103. In the background
  104. ~~~~~~~~~~~~~~~~~
  105. In production you will want to run the worker in the background, this is
  106. described in detail in the :ref:`daemonization tutorial <daemonizing>`.
  107. The daemonization scripts uses the :program:`celery multi` command to
  108. start one or more workers in the background:
  109. .. code-block:: console
  110. $ celery multi start w1 -A proj -l info
  111. celery multi v4.0.0 (0today8)
  112. > Starting nodes...
  113. > w1.halcyon.local: OK
  114. You can restart it too:
  115. .. code-block:: console
  116. $ celery multi restart w1 -A proj -l info
  117. celery multi v4.0.0 (0today8)
  118. > Stopping nodes...
  119. > w1.halcyon.local: TERM -> 64024
  120. > Waiting for 1 node.....
  121. > w1.halcyon.local: OK
  122. > Restarting node w1.halcyon.local: OK
  123. celery multi v4.0.0 (0today8)
  124. > Stopping nodes...
  125. > w1.halcyon.local: TERM -> 64052
  126. or stop it:
  127. .. code-block:: console
  128. $ celery multi stop w1 -A proj -l info
  129. The ``stop`` command is asynchronous so it will not wait for the
  130. worker to shutdown. You will probably want to use the ``stopwait`` command
  131. instead which will ensure all currently executing tasks is completed:
  132. .. code-block:: console
  133. $ celery multi stopwait w1 -A proj -l info
  134. .. note::
  135. :program:`celery multi` doesn't store information about workers
  136. so you need to use the same command-line arguments when
  137. restarting. Only the same pidfile and logfile arguments must be
  138. used when stopping.
  139. By default it will create pid and log files in the current directory,
  140. to protect against multiple workers launching on top of each other
  141. you are encouraged to put these in a dedicated directory:
  142. .. code-block:: console
  143. $ mkdir -p /var/run/celery
  144. $ mkdir -p /var/log/celery
  145. $ celery multi start w1 -A proj -l info --pidfile=/var/run/celery/%n.pid \
  146. --logfile=/var/log/celery/%n%I.log
  147. With the multi command you can start multiple workers, and there is a powerful
  148. command-line syntax to specify arguments for different workers too,
  149. e.g:
  150. .. code-block:: console
  151. $ celery multi start 10 -A proj -l info -Q:1-3 images,video -Q:4,5 data \
  152. -Q default -L:4,5 debug
  153. For more examples see the :mod:`~celery.bin.multi` module in the API
  154. reference.
  155. .. _app-argument:
  156. About the :option:`--app <celery --app>` argument
  157. ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
  158. The :option:`--app <celery --app>` argument specifies the Celery app instance
  159. to use, it must be in the form of ``module.path:attribute``
  160. But it also supports a shortcut form If only a package name is specified,
  161. where it'll try to search for the app instance, in the following order:
  162. With :option:`--app=proj <celery --app>`:
  163. 1) an attribute named ``proj.app``, or
  164. 2) an attribute named ``proj.celery``, or
  165. 3) any attribute in the module ``proj`` where the value is a Celery
  166. application, or
  167. If none of these are found it'll try a submodule named ``proj.celery``:
  168. 4) an attribute named ``proj.celery.app``, or
  169. 5) an attribute named ``proj.celery.celery``, or
  170. 6) Any attribute in the module ``proj.celery`` where the value is a Celery
  171. application.
  172. This scheme mimics the practices used in the documentation,
  173. i.e. ``proj:app`` for a single contained module, and ``proj.celery:app``
  174. for larger projects.
  175. .. _calling-tasks:
  176. Calling Tasks
  177. =============
  178. You can call a task using the :meth:`delay` method:
  179. .. code-block:: pycon
  180. >>> add.delay(2, 2)
  181. This method is actually a star-argument shortcut to another method called
  182. :meth:`apply_async`:
  183. .. code-block:: pycon
  184. >>> add.apply_async((2, 2))
  185. The latter enables you to specify execution options like the time to run
  186. (countdown), the queue it should be sent to and so on:
  187. .. code-block:: pycon
  188. >>> add.apply_async((2, 2), queue='lopri', countdown=10)
  189. In the above example the task will be sent to a queue named ``lopri`` and the
  190. task will execute, at the earliest, 10 seconds after the message was sent.
  191. Applying the task directly will execute the task in the current process,
  192. so that no message is sent:
  193. .. code-block:: pycon
  194. >>> add(2, 2)
  195. 4
  196. These three methods - :meth:`delay`, :meth:`apply_async`, and applying
  197. (``__call__``), represents the Celery calling API, which are also used for
  198. signatures.
  199. A more detailed overview of the Calling API can be found in the
  200. :ref:`Calling User Guide <guide-calling>`.
  201. Every task invocation will be given a unique identifier (an UUID), this
  202. is the task id.
  203. The ``delay`` and ``apply_async`` methods return an :class:`~@AsyncResult`
  204. instance, which can be used to keep track of the tasks execution state.
  205. But for this you need to enable a :ref:`result backend <task-result-backends>` so that
  206. the state can be stored somewhere.
  207. Results are disabled by default because of the fact that there is no result
  208. backend that suits every application, so to choose one you need to consider
  209. the drawbacks of each individual backend. For many tasks
  210. keeping the return value isn't even very useful, so it's a sensible default to
  211. have. Also note that result backends are not used for monitoring tasks and workers,
  212. for that Celery uses dedicated event messages (see :ref:`guide-monitoring`).
  213. If you have a result backend configured you can retrieve the return
  214. value of a task:
  215. .. code-block:: pycon
  216. >>> res = add.delay(2, 2)
  217. >>> res.get(timeout=1)
  218. 4
  219. You can find the task's id by looking at the :attr:`id` attribute:
  220. .. code-block:: pycon
  221. >>> res.id
  222. d6b3aea2-fb9b-4ebc-8da4-848818db9114
  223. You can also inspect the exception and traceback if the task raised an
  224. exception, in fact ``result.get()`` will propagate any errors by default:
  225. .. code-block:: pycon
  226. >>> res = add.delay(2)
  227. >>> res.get(timeout=1)
  228. .. code-block:: pytb
  229. Traceback (most recent call last):
  230. File "<stdin>", line 1, in <module>
  231. File "/opt/devel/celery/celery/result.py", line 113, in get
  232. interval=interval)
  233. File "/opt/devel/celery/celery/backends/rpc.py", line 138, in wait_for
  234. raise meta['result']
  235. TypeError: add() takes exactly 2 arguments (1 given)
  236. If you don't wish for the errors to propagate then you can disable that
  237. by passing the ``propagate`` argument:
  238. .. code-block:: pycon
  239. >>> res.get(propagate=False)
  240. TypeError('add() takes exactly 2 arguments (1 given)',)
  241. In this case it will return the exception instance raised instead,
  242. and so to check whether the task succeeded or failed you will have to
  243. use the corresponding methods on the result instance::
  244. >>> res.failed()
  245. True
  246. >>> res.successful()
  247. False
  248. So how does it know if the task has failed or not? It can find out by looking
  249. at the tasks *state*:
  250. .. code-block:: pycon
  251. >>> res.state
  252. 'FAILURE'
  253. A task can only be in a single state, but it can progress through several
  254. states. The stages of a typical task can be::
  255. PENDING -> STARTED -> SUCCESS
  256. The started state is a special state that is only recorded if the
  257. :setting:`task_track_started` setting is enabled, or if the
  258. ``@task(track_started=True)`` option is set for the task.
  259. The pending state is actually not a recorded state, but rather
  260. the default state for any task id that is unknown, which you can see
  261. from this example:
  262. .. code-block:: pycon
  263. >>> from proj.celery import app
  264. >>> res = app.AsyncResult('this-id-does-not-exist')
  265. >>> res.state
  266. 'PENDING'
  267. If the task is retried the stages can become even more complex,
  268. e.g, for a task that is retried two times the stages would be::
  269. PENDING -> STARTED -> RETRY -> STARTED -> RETRY -> STARTED -> SUCCESS
  270. To read more about task states you should see the :ref:`task-states` section
  271. in the tasks user guide.
  272. Calling tasks is described in detail in the
  273. :ref:`Calling Guide <guide-calling>`.
  274. .. _designing-workflows:
  275. *Canvas*: Designing Work-flows
  276. ==============================
  277. You just learned how to call a task using the tasks ``delay`` method,
  278. and this is often all you need, but sometimes you may want to pass the
  279. signature of a task invocation to another process or as an argument to another
  280. function, for this Celery uses something called *signatures*.
  281. A signature wraps the arguments and execution options of a single task
  282. invocation in a way such that it can be passed to functions or even serialized
  283. and sent across the wire.
  284. You can create a signature for the ``add`` task using the arguments ``(2, 2)``,
  285. and a countdown of 10 seconds like this:
  286. .. code-block:: pycon
  287. >>> add.signature((2, 2), countdown=10)
  288. tasks.add(2, 2)
  289. There is also a shortcut using star arguments:
  290. .. code-block:: pycon
  291. >>> add.s(2, 2)
  292. tasks.add(2, 2)
  293. And there's that calling API again…
  294. -----------------------------------
  295. Signature instances also supports the calling API, which means that they
  296. have the ``delay`` and ``apply_async`` methods.
  297. But there is a difference in that the signature may already have
  298. an argument signature specified. The ``add`` task takes two arguments,
  299. so a signature specifying two arguments would make a complete signature:
  300. .. code-block:: pycon
  301. >>> s1 = add.s(2, 2)
  302. >>> res = s1.delay()
  303. >>> res.get()
  304. 4
  305. But, you can also make incomplete signatures to create what we call
  306. *partials*:
  307. .. code-block:: pycon
  308. # incomplete partial: add(?, 2)
  309. >>> s2 = add.s(2)
  310. ``s2`` is now a partial signature that needs another argument to be complete,
  311. and this can be resolved when calling the signature:
  312. .. code-block:: pycon
  313. # resolves the partial: add(8, 2)
  314. >>> res = s2.delay(8)
  315. >>> res.get()
  316. 10
  317. Here you added the argument 8, which was prepended to the existing argument 2
  318. forming a complete signature of ``add(8, 2)``.
  319. Keyword arguments can also be added later, these are then merged with any
  320. existing keyword arguments, but with new arguments taking precedence:
  321. .. code-block:: pycon
  322. >>> s3 = add.s(2, 2, debug=True)
  323. >>> s3.delay(debug=False) # debug is now False.
  324. As stated signatures supports the calling API, which means that:
  325. - ``sig.apply_async(args=(), kwargs={}, **options)``
  326. Calls the signature with optional partial arguments and partial
  327. keyword arguments. Also supports partial execution options.
  328. - ``sig.delay(*args, **kwargs)``
  329. Star argument version of ``apply_async``. Any arguments will be prepended
  330. to the arguments in the signature, and keyword arguments is merged with any
  331. existing keys.
  332. So this all seems very useful, but what can you actually do with these?
  333. To get to that I must introduce the canvas primitives…
  334. The Primitives
  335. --------------
  336. .. topic:: \
  337. .. hlist::
  338. :columns: 2
  339. - :ref:`group <canvas-group>`
  340. - :ref:`chain <canvas-chain>`
  341. - :ref:`chord <canvas-chord>`
  342. - :ref:`map <canvas-map>`
  343. - :ref:`starmap <canvas-map>`
  344. - :ref:`chunks <canvas-chunks>`
  345. These primitives are signature objects themselves, so they can be combined
  346. in any number of ways to compose complex work-flows.
  347. .. note::
  348. These examples retrieve results, so to try them out you need
  349. to configure a result backend. The example project
  350. above already does that (see the backend argument to :class:`~celery.Celery`).
  351. Let's look at some examples:
  352. Groups
  353. ~~~~~~
  354. A :class:`~celery.group` calls a list of tasks in parallel,
  355. and it returns a special result instance that lets you inspect the results
  356. as a group, and retrieve the return values in order.
  357. .. code-block:: pycon
  358. >>> from celery import group
  359. >>> from proj.tasks import add
  360. >>> group(add.s(i, i) for i in xrange(10))().get()
  361. [0, 2, 4, 6, 8, 10, 12, 14, 16, 18]
  362. - Partial group
  363. .. code-block:: pycon
  364. >>> g = group(add.s(i) for i in xrange(10))
  365. >>> g(10).get()
  366. [10, 11, 12, 13, 14, 15, 16, 17, 18, 19]
  367. Chains
  368. ~~~~~~
  369. Tasks can be linked together so that after one task returns the other
  370. is called:
  371. .. code-block:: pycon
  372. >>> from celery import chain
  373. >>> from proj.tasks import add, mul
  374. # (4 + 4) * 8
  375. >>> chain(add.s(4, 4) | mul.s(8))().get()
  376. 64
  377. or a partial chain:
  378. .. code-block:: pycon
  379. >>> # (? + 4) * 8
  380. >>> g = chain(add.s(4) | mul.s(8))
  381. >>> g(4).get()
  382. 64
  383. Chains can also be written like this:
  384. .. code-block:: pycon
  385. >>> (add.s(4, 4) | mul.s(8))().get()
  386. 64
  387. Chords
  388. ~~~~~~
  389. A chord is a group with a callback:
  390. .. code-block:: pycon
  391. >>> from celery import chord
  392. >>> from proj.tasks import add, xsum
  393. >>> chord((add.s(i, i) for i in xrange(10)), xsum.s())().get()
  394. 90
  395. A group chained to another task will be automatically converted
  396. to a chord:
  397. .. code-block:: pycon
  398. >>> (group(add.s(i, i) for i in xrange(10)) | xsum.s())().get()
  399. 90
  400. Since these primitives are all of the signature type they
  401. can be combined almost however you want, e.g::
  402. >>> upload_document.s(file) | group(apply_filter.s() for filter in filters)
  403. Be sure to read more about work-flows in the :ref:`Canvas <guide-canvas>` user
  404. guide.
  405. Routing
  406. =======
  407. Celery supports all of the routing facilities provided by AMQP,
  408. but it also supports simple routing where messages are sent to named queues.
  409. The :setting:`task_routes` setting enables you to route tasks by name
  410. and keep everything centralized in one location:
  411. .. code-block:: python
  412. app.conf.update(
  413. task_routes = {
  414. 'proj.tasks.add': {'queue': 'hipri'},
  415. },
  416. )
  417. You can also specify the queue at runtime
  418. with the ``queue`` argument to ``apply_async``:
  419. .. code-block:: pycon
  420. >>> from proj.tasks import add
  421. >>> add.apply_async((2, 2), queue='hipri')
  422. You can then make a worker consume from this queue by
  423. specifying the :option:`celery worker -Q` option:
  424. .. code-block:: console
  425. $ celery -A proj worker -Q hipri
  426. You may specify multiple queues by using a comma separated list,
  427. for example you can make the worker consume from both the default
  428. queue, and the ``hipri`` queue, where
  429. the default queue is named ``celery`` for historical reasons:
  430. .. code-block:: console
  431. $ celery -A proj worker -Q hipri,celery
  432. The order of the queues doesn't matter as the worker will
  433. give equal weight to the queues.
  434. To learn more about routing, including taking use of the full
  435. power of AMQP routing, see the :ref:`Routing Guide <guide-routing>`.
  436. Remote Control
  437. ==============
  438. If you're using RabbitMQ (AMQP) or Qpid as a broker then
  439. you can control and inspect the worker at runtime.
  440. For example you can see what tasks the worker is currently working on:
  441. .. code-block:: console
  442. $ celery -A proj inspect active
  443. This is implemented by using broadcast messaging, so all remote
  444. control commands are received by every worker in the cluster.
  445. You can also specify one or more workers to act on the request
  446. using the :option:`--destination <celery inspect --destination>` option,
  447. which is a comma separated list of worker host names:
  448. .. code-block:: console
  449. $ celery -A proj inspect active --destination=celery@example.com
  450. If a destination is not provided then every worker will act and reply
  451. to the request.
  452. The :program:`celery inspect` command contains commands that
  453. does not change anything in the worker, it only replies information
  454. and statistics about what is going on inside the worker.
  455. For a list of inspect commands you can execute:
  456. .. code-block:: console
  457. $ celery -A proj inspect --help
  458. Then there is the :program:`celery control` command, which contains
  459. commands that actually changes things in the worker at runtime:
  460. .. code-block:: console
  461. $ celery -A proj control --help
  462. For example you can force workers to enable event messages (used
  463. for monitoring tasks and workers):
  464. .. code-block:: console
  465. $ celery -A proj control enable_events
  466. When events are enabled you can then start the event dumper
  467. to see what the workers are doing:
  468. .. code-block:: console
  469. $ celery -A proj events --dump
  470. or you can start the curses interface:
  471. .. code-block:: console
  472. $ celery -A proj events
  473. when you're finished monitoring you can disable events again:
  474. .. code-block:: console
  475. $ celery -A proj control disable_events
  476. The :program:`celery status` command also uses remote control commands
  477. and shows a list of online workers in the cluster:
  478. .. code-block:: console
  479. $ celery -A proj status
  480. You can read more about the :program:`celery` command and monitoring
  481. in the :ref:`Monitoring Guide <guide-monitoring>`.
  482. Timezone
  483. ========
  484. All times and dates, internally and in messages uses the UTC timezone.
  485. When the worker receives a message, for example with a countdown set it
  486. converts that UTC time to local time. If you wish to use
  487. a different timezone than the system timezone then you must
  488. configure that using the :setting:`timezone` setting:
  489. .. code-block:: python
  490. app.conf.timezone = 'Europe/London'
  491. Optimization
  492. ============
  493. The default configuration is not optimized for throughput by default,
  494. it tries to walk the middle way between many short tasks and fewer long
  495. tasks, a compromise between throughput and fair scheduling.
  496. If you have strict fair scheduling requirements, or want to optimize
  497. for throughput then you should read the :ref:`Optimizing Guide
  498. <guide-optimizing>`.
  499. If you're using RabbitMQ then you should install the :pypi:`librabbitmq`
  500. module, which is an AMQP client implemented in C:
  501. .. code-block:: console
  502. $ pip install librabbitmq
  503. What to do now?
  504. ===============
  505. Now that you have read this document you should continue
  506. to the :ref:`User Guide <guide>`.
  507. There's also an :ref:`API reference <apiref>` if you are so inclined.