This document describes the current stable version of Celery (5.2). For development docs, go here.

Source code for celery.bootsteps

"""A directed acyclic graph of reusable components."""

from collections import deque
from threading import Event

from kombu.common import ignore_errors
from kombu.utils.encoding import bytes_to_str
from kombu.utils.imports import symbol_by_name

from .utils.graph import DependencyGraph, GraphFormatter
from .utils.imports import instantiate, qualname
from .utils.log import get_logger

try:
    from greenlet import GreenletExit
except ImportError:  # pragma: no cover
    IGNORE_ERRORS = ()
else:
    IGNORE_ERRORS = (GreenletExit,)

__all__ = ('Blueprint', 'Step', 'StartStopStep', 'ConsumerStep')

#: States
RUN = 0x1
CLOSE = 0x2
TERMINATE = 0x3

logger = get_logger(__name__)


def _pre(ns, fmt):
    return f'| {ns.alias}: {fmt}'


def _label(s):
    return s.name.rsplit('.', 1)[-1]


class StepFormatter(GraphFormatter):
    """Graph formatter for :class:`Blueprint`."""

    blueprint_prefix = '⧉'
    conditional_prefix = '∘'
    blueprint_scheme = {
        'shape': 'parallelogram',
        'color': 'slategray4',
        'fillcolor': 'slategray3',
    }

    def label(self, step):
        return step and '{}{}'.format(
            self._get_prefix(step),
            bytes_to_str(
                (step.label or _label(step)).encode('utf-8', 'ignore')),
        )

    def _get_prefix(self, step):
        if step.last:
            return self.blueprint_prefix
        if step.conditional:
            return self.conditional_prefix
        return ''

    def node(self, obj, **attrs):
        scheme = self.blueprint_scheme if obj.last else self.node_scheme
        return self.draw_node(obj, scheme, attrs)

    def edge(self, a, b, **attrs):
        if a.last:
            attrs.update(arrowhead='none', color='darkseagreen3')
        return self.draw_edge(a, b, self.edge_scheme, attrs)


[docs]class Blueprint: """Blueprint containing bootsteps that can be applied to objects. Arguments: steps Sequence[Union[str, Step]]: List of steps. name (str): Set explicit name for this blueprint. on_start (Callable): Optional callback applied after blueprint start. on_close (Callable): Optional callback applied before blueprint close. on_stopped (Callable): Optional callback applied after blueprint stopped. """ GraphFormatter = StepFormatter name = None state = None started = 0 default_steps = set() state_to_name = { 0: 'initializing', RUN: 'running', CLOSE: 'closing', TERMINATE: 'terminating', } def __init__(self, steps=None, name=None, on_start=None, on_close=None, on_stopped=None): self.name = name or self.name or qualname(type(self)) self.types = set(steps or []) | set(self.default_steps) self.on_start = on_start self.on_close = on_close self.on_stopped = on_stopped self.shutdown_complete = Event() self.steps = {}
[docs] def start(self, parent): self.state = RUN if self.on_start: self.on_start() for i, step in enumerate(s for s in parent.steps if s is not None): self._debug('Starting %s', step.alias) self.started = i + 1 step.start(parent) logger.debug('^-- substep ok')
[docs] def human_state(self): return self.state_to_name[self.state or 0]
[docs] def info(self, parent): info = {} for step in parent.steps: info.update(step.info(parent) or {}) return info
[docs] def close(self, parent): if self.on_close: self.on_close() self.send_all(parent, 'close', 'closing', reverse=False)
[docs] def restart(self, parent, method='stop', description='restarting', propagate=False): self.send_all(parent, method, description, propagate=propagate)
[docs] def send_all(self, parent, method, description=None, reverse=True, propagate=True, args=()): description = description or method.replace('_', ' ') steps = reversed(parent.steps) if reverse else parent.steps for step in steps: if step: fun = getattr(step, method, None) if fun is not None: self._debug('%s %s...', description.capitalize(), step.alias) try: fun(parent, *args) except Exception as exc: # pylint: disable=broad-except if propagate: raise logger.exception( 'Error on %s %s: %r', description, step.alias, exc)
[docs] def stop(self, parent, close=True, terminate=False): what = 'terminating' if terminate else 'stopping' if self.state in (CLOSE, TERMINATE): return if self.state != RUN or self.started != len(parent.steps): # Not fully started, can safely exit. self.state = TERMINATE self.shutdown_complete.set() return self.close(parent) self.state = CLOSE self.restart( parent, 'terminate' if terminate else 'stop', description=what, propagate=False, ) if self.on_stopped: self.on_stopped() self.state = TERMINATE self.shutdown_complete.set()
[docs] def join(self, timeout=None): try: # Will only get here if running green, # makes sure all greenthreads have exited. self.shutdown_complete.wait(timeout=timeout) except IGNORE_ERRORS: pass
[docs] def apply(self, parent, **kwargs): """Apply the steps in this blueprint to an object. This will apply the ``__init__`` and ``include`` methods of each step, with the object as argument:: step = Step(obj) ... step.include(obj) For :class:`StartStopStep` the services created will also be added to the objects ``steps`` attribute. """ self._debug('Preparing bootsteps.') order = self.order = [] steps = self.steps = self.claim_steps() self._debug('Building graph...') for S in self._finalize_steps(steps): step = S(parent, **kwargs) steps[step.name] = step order.append(step) self._debug('New boot order: {%s}', ', '.join(s.alias for s in self.order)) for step in order: step.include(parent) return self
[docs] def connect_with(self, other): self.graph.adjacent.update(other.graph.adjacent) self.graph.add_edge(type(other.order[0]), type(self.order[-1]))
def __getitem__(self, name): return self.steps[name] def _find_last(self): return next((C for C in self.steps.values() if C.last), None) def _firstpass(self, steps): for step in steps.values(): step.requires = [symbol_by_name(dep) for dep in step.requires] stream = deque(step.requires for step in steps.values()) while stream: for node in stream.popleft(): node = symbol_by_name(node) if node.name not in self.steps: steps[node.name] = node stream.append(node.requires) def _finalize_steps(self, steps): last = self._find_last() self._firstpass(steps) it = ((C, C.requires) for C in steps.values()) G = self.graph = DependencyGraph( it, formatter=self.GraphFormatter(root=last), ) if last: for obj in G: if obj != last: G.add_edge(last, obj) try: return G.topsort() except KeyError as exc: raise KeyError('unknown bootstep: %s' % exc)
[docs] def claim_steps(self): return dict(self.load_step(step) for step in self.types)
[docs] def load_step(self, step): step = symbol_by_name(step) return step.name, step
def _debug(self, msg, *args): return logger.debug(_pre(self, msg), *args) @property def alias(self): return _label(self)
class StepType(type): """Meta-class for steps.""" name = None requires = None def __new__(cls, name, bases, attrs): module = attrs.get('__module__') qname = f'{module}.{name}' if module else name attrs.update( __qualname__=qname, name=attrs.get('name') or qname, ) return super().__new__(cls, name, bases, attrs) def __str__(cls): return cls.name def __repr__(cls): return 'step:{0.name}{{{0.requires!r}}}'.format(cls)
[docs]class Step(metaclass=StepType): """A Bootstep. The :meth:`__init__` method is called when the step is bound to a parent object, and can as such be used to initialize attributes in the parent object at parent instantiation-time. """ #: Optional step name, will use ``qualname`` if not specified. name = None #: Optional short name used for graph outputs and in logs. label = None #: Set this to true if the step is enabled based on some condition. conditional = False #: List of other steps that that must be started before this step. #: Note that all dependencies must be in the same blueprint. requires = () #: This flag is reserved for the workers Consumer, #: since it is required to always be started last. #: There can only be one object marked last #: in every blueprint. last = False #: This provides the default for :meth:`include_if`. enabled = True def __init__(self, parent, **kwargs): pass
[docs] def include_if(self, parent): """Return true if bootstep should be included. You can define this as an optional predicate that decides whether this step should be created. """ return self.enabled
[docs] def instantiate(self, name, *args, **kwargs): return instantiate(name, *args, **kwargs)
def _should_include(self, parent): if self.include_if(parent): return True, self.create(parent) return False, None
[docs] def include(self, parent): return self._should_include(parent)[0]
[docs] def create(self, parent): """Create the step."""
def __repr__(self): return f'<step: {self.alias}>' @property def alias(self): return self.label or _label(self)
[docs] def info(self, obj): pass
[docs]class StartStopStep(Step): """Bootstep that must be started and stopped in order.""" #: Optional obj created by the :meth:`create` method. #: This is used by :class:`StartStopStep` to keep the #: original service object. obj = None
[docs] def start(self, parent): if self.obj: return self.obj.start()
[docs] def stop(self, parent): if self.obj: return self.obj.stop()
[docs] def close(self, parent): pass
[docs] def terminate(self, parent): if self.obj: return getattr(self.obj, 'terminate', self.obj.stop)()
[docs] def include(self, parent): inc, ret = self._should_include(parent) if inc: self.obj = ret parent.steps.append(self) return inc
[docs]class ConsumerStep(StartStopStep): """Bootstep that starts a message consumer.""" requires = ('celery.worker.consumer:Connection',) consumers = None
[docs] def get_consumers(self, channel): raise NotImplementedError('missing get_consumers')
[docs] def start(self, c): channel = c.connection.channel() self.consumers = self.get_consumers(channel) for consumer in self.consumers or []: consumer.consume()
[docs] def stop(self, c): self._close(c, True)
[docs] def shutdown(self, c): self._close(c, False)
def _close(self, c, cancel_consumers=True): channels = set() for consumer in self.consumers or []: if cancel_consumers: ignore_errors(c.connection, consumer.cancel) if consumer.channel: channels.add(consumer.channel) for channel in channels: ignore_errors(c.connection, channel.close)