=============== Workers Guide =============== Starting the worker =================== Starting celeryd in the foreground:: $ celeryd --loglevel=INFO You probably want to use a daemonization tool to start and stop ``celeryd`` in the background, see :doc:`../cookbook/daemonizing` for help using some of the most popular solutions. For a full list of available command line options see :mod:`~celery.bin.celeryd`. You can also start multiple celeryd's on the same machine, but if you do so be sure to give a unique name to each individual worker by specifying the ``-hostname`` argument:: $ celeryd --loglevel=INFO --concurrency=10 -n worker1.example.com $ celeryd --loglevel=INFO --concurrency=10 -n worker2.example.com $ celeryd --loglevel=INFO --concurrency=10 -n worker3.example.com Stopping the worker =================== Shutdown should be accomplished using the ``TERM`` signal (although ``INT`` also works). When shutdown is initiated the worker will finish any tasks it's currently executing before it terminates, so if these tasks are important you should wait for it to finish before doing anything drastic (like sending the ``KILL`` signal). If the worker won't shutdown after considerate time, you probably have hanging tasks, in this case it's safe to use the ``KILL`` signal but be aware that currently executing tasks will be lost (unless the tasks have the :attr:`~celery.task.base.Task.acks_late` option set). Also, since the ``KILL`` signal can't be catched by processes the worker will not be able to reap its children, so make sure you do it manually. This command usually does the trick:: $ ps auxww | grep celeryd | awk '{print $2}' | xargs kill -KILL Restarting the worker ===================== Other than stopping then starting the worker to restart, you can also restart the worker using the ``HUP`` signal:: $ kill -HUP $pid The worker will then replace itself using the same arguments as it was started with. Concurrency =========== Multiprocessing is used to perform concurrent execution of tasks. The number of worker processes can be changed using the ``--concurrency`` argument, and defaults to the number of CPUs in the system. More worker processes are usually better, but there's a cut-off point where adding more processes affects performance in negative ways. There is even some evidence to support that having multiple celeryd's running, may perform better than having a single worker. For example 3 celeryd's with 10 worker processes each, but you need to experiment to find the values that works best for you, as this varies based on application, work load, task runtimes and other factors. Time limits =========== A single task can potentially run forever, if you have lots of tasks waiting for some event that will never happen you will block the worker from processing new tasks indefinitely. The best way to defend against this scenario happening is enabling time limits. The time limit (``--time-limit``) is the maximum number of seconds a task may run before the process executing it is terminated and replaced by a new process. You can also enable a soft time limit (``--soft-time-limit``), this raises an exception that the task can catch to clean up before the hard time limit kills it: .. code-block:: python from celery.decorators import task from celery.exceptions import SoftTimeLimitExceeded @task() def mytask(): try: do_work() except SoftTimeLimitExceeded: clean_up_in_a_hurry() Time limits can also be set using the ``CELERYD_TASK_TIME_LIMIT`` / ``CELERYD_SOFT_TASK_TIME_LIMIT`` settings. **NOTE** Time limits does not currently work on Windows. Max tasks per child setting =========================== With this option you can configure the maximum number of tasks a worker can execute before it's replaced by a new process. This is useful if you have memory leaks you have no control over, for example closed source C extensions. The option can be set using the ``--maxtasksperchild`` argument to ``celeryd`` or using the ``CELERYD_MAX_TASKS_PER_CHILD`` setting. Remote control ============== Workers have the ability to be remote controlled using a broadcast message queue. The commands can be directed to all, or a specific list of workers. Commands can also have replies, the client can then wait for and collect those replies, but since there's no central authority to know how many workers are available in the cluster, there is also no way to estimate how many workers may send a reply, therefore the client has a configurable timeout - the deadline in seconds for replies to arrive in. This timeout defaults to one second. If the worker didn't reply within the deadline, it doesn't necessarily mean the worker didn't reply, or worse is dead, but may just be caused by network latency or the worker being slow at processing commands, so adjust the timeout accordingly. In addition to timeouts, the client can specify the maximum number of replies to wait for. If a destination is specified this limit is set to the number of destinations. The :func:`~celery.task.control.broadcast` function. ---------------------------------------------------- This is the client function used to send commands to the workers. Some remote control commands also have higher-level interfaces using :func:`~celery.task.control.broadcast` in the background, like :func:`~celery.task.control.rate_limit` and :func:`~celery.task.control.ping`. Sending the ``rate_limit`` command and keyword arguments:: >>> from celery.task.control import broadcast >>> broadcast("rate_limit", arguments={"task_name": "myapp.mytask", ... "rate_limit": "200/m"}) This will send the command asynchronously, without waiting for a reply. To request a reply you have to use the ``reply`` argument:: >>> broadcast("rate_limit", {"task_name": "myapp.mytask", ... "rate_limit": "200/m"}, reply=True) [{'worker1.example.com': 'New rate limit set successfully'}, {'worker2.example.com': 'New rate limit set successfully'}, {'worker3.example.com': 'New rate limit set successfully'}] Using the ``destination`` argument you can specify a list of workers to receive the command:: >>> broadcast >>> broadcast("rate_limit", {"task_name": "myapp.mytask", ... "rate_limit": "200/m"}, reply=True, ... destination=["worker1.example.com"]) [{'worker1.example.com': 'New rate limit set successfully'}] Of course, using the higher-level interface to set rate limits is much more convenient, but there are commands that can only be requested using :func:`~celery.task.control.broadcast`. Rate limits ----------- Example changing the rate limit for the ``myapp.mytask`` task to accept 200 tasks a minute on all servers: >>> from celery.task.control import rate_limit >>> rate_limit("myapp.mytask", "200/m") Example changing the rate limit on a single host by specifying the destination hostname:: >>> rate_limit("myapp.mytask", "200/m", ... destination=["worker1.example.com"]) **NOTE** This won't affect workers with the ``CELERY_DISABLE_RATE_LIMITS`` setting on. To re-enable rate limits you have to restart the worker. Remote shutdown --------------- This command will gracefully shut down the worker from remote. >>> broadcast("shutdown") # shutdown all workers >>> broadcast("shutdown, destination="worker1.example.com") Ping ---- This command requests a ping from alive workers. The workers reply with the string 'pong', and that's just about it. It will use the default one second limit for replies unless you specify a custom ``timeout``. >>> from celery.task.control import ping >>> ping() [{'worker1.example.com': 'pong'}, {'worker2.example.com': 'pong'}, {'worker3.example.com': 'pong'}] :func:`~celery.task.control.ping` also supports the ``destination`` argument, so you can specify which workers to ping:: >>> ping(['worker2.example.com', 'worker3.example.com']) [{'worker2.example.com': 'pong'}, {'worker3.example.com': 'pong'}] Enable/disable events --------------------- You can enable/disable events by using the ``enable_events``, ``disable_events`` commands. This is useful to temporarily monitor a worker using celeryev/celerymon. >>> broadcast("enable_events") >>> broadcast("disable_events") Writing your own remote control commands ---------------------------------------- Remote control commands are registered in the control panel and they take a single argument: the current :class:`~celery.worker.control.ControlDispatch` instance. From there you have access to the active :class:`celery.worker.listener.CarrotListener` if needed. Here's an example control command that restarts the broker connection: .. code-block:: python from celery.worker.control import Panel @Panel.register def reset_connection(panel): panel.logger.critical("Connection reset by remote control.") panel.listener.reset_connection() return {"ok": "connection reset"} These can be added to task modules, or you can keep them in their own module then import them using the ``CELERY_IMPORTS`` setting:: CELERY_IMPORTS = ("myapp.worker.control", ) Debugging ========= Dump of registered tasks ------------------------ You can get a list of tasks registered in the worker using the ``dump_tasks`` remote control command:: >>> broadcast("dump_tasks", reply=True) [{'worker1.example.com': ['celery.delete_expired_task_meta', 'celery.execute_remote', 'celery.map_async', 'celery.ping', 'celery.task.http.HttpDispatchTask', 'tasks.add', 'tasks.sleeptask']}] Dump of scheduled (ETA) tasks ----------------------------- You can get a list of tasks waiting to be scheduled by using the ``dump_schedule`` remote control command. >>> broadcast("dump_schedule", reply=True) [{'worker1.example.com': ['0. 2010-06-07 09:07:52 pri0 ', '1. 2010-06-07 09:07:53 pri0 ', The outputted fields are (in order): position, eta, priority, request. Note that these are tasks with an eta/countdown argument, not periodic tasks. Dump of reserved tasks ---------------------- Reserved tasks are tasks that has been received by the broker and is waiting for immediate execution. You can get a list of these using the ``dump_reserved`` remote control command. >>> broadcast("dump_reserved", reply=True) [{'worker1.example.com': ['']}]