Mini Shell
"""In-memory representation of cluster state.
This module implements a data-structure used to keep
track of the state of a cluster of workers and the tasks
it is working on (by consuming events).
For every event consumed the state is updated,
so the state represents the state of the cluster
at the time of the last event.
Snapshots (:mod:`celery.events.snapshot`) can be used to
take "pictures" of this state at regular intervals
to for example, store that in a database.
"""
import bisect
import sys
import threading
from collections import defaultdict
from collections.abc import Callable
from datetime import datetime
from decimal import Decimal
from itertools import islice
from operator import itemgetter
from time import time
from typing import Mapping, Optional # noqa
from weakref import WeakSet, ref
from kombu.clocks import timetuple
from kombu.utils.objects import cached_property
from celery import states
from celery.utils.functional import LRUCache, memoize, pass1
from celery.utils.log import get_logger
__all__ = ('Worker', 'Task', 'State', 'heartbeat_expires')
# pylint: disable=redefined-outer-name
# We cache globals and attribute lookups, so disable this warning.
# pylint: disable=too-many-function-args
# For some reason pylint thinks ._event is a method, when it's a property.
#: Set if running PyPy
PYPY = hasattr(sys, 'pypy_version_info')
#: The window (in percentage) is added to the workers heartbeat
#: frequency. If the time between updates exceeds this window,
#: then the worker is considered to be offline.
HEARTBEAT_EXPIRE_WINDOW = 200
#: Max drift between event timestamp and time of event received
#: before we alert that clocks may be unsynchronized.
HEARTBEAT_DRIFT_MAX = 16
DRIFT_WARNING = (
"Substantial drift from %s may mean clocks are out of sync. Current drift is "
"%s seconds. [orig: %s recv: %s]"
)
logger = get_logger(__name__)
warn = logger.warning
R_STATE = '<State: events={0.event_count} tasks={0.task_count}>'
R_WORKER = '<Worker: {0.hostname} ({0.status_string} clock:{0.clock})'
R_TASK = '<Task: {0.name}({0.uuid}) {0.state} clock:{0.clock}>'
#: Mapping of task event names to task state.
TASK_EVENT_TO_STATE = {
'sent': states.PENDING,
'received': states.RECEIVED,
'started': states.STARTED,
'failed': states.FAILURE,
'retried': states.RETRY,
'succeeded': states.SUCCESS,
'revoked': states.REVOKED,
'rejected': states.REJECTED,
}
class CallableDefaultdict(defaultdict):
""":class:`~collections.defaultdict` with configurable __call__.
We use this for backwards compatibility in State.tasks_by_type
etc, which used to be a method but is now an index instead.
So you can do::
>>> add_tasks = state.tasks_by_type['proj.tasks.add']
while still supporting the method call::
>>> add_tasks = list(state.tasks_by_type(
... 'proj.tasks.add', reverse=True))
"""
def __init__(self, fun, *args, **kwargs):
self.fun = fun
super().__init__(*args, **kwargs)
def __call__(self, *args, **kwargs):
return self.fun(*args, **kwargs)
Callable.register(CallableDefaultdict)
@memoize(maxsize=1000, keyfun=lambda a, _: a[0])
def _warn_drift(hostname, drift, local_received, timestamp):
# we use memoize here so the warning is only logged once per hostname
warn(DRIFT_WARNING, hostname, drift,
datetime.fromtimestamp(local_received),
datetime.fromtimestamp(timestamp))
def heartbeat_expires(timestamp, freq=60,
expire_window=HEARTBEAT_EXPIRE_WINDOW,
Decimal=Decimal, float=float, isinstance=isinstance):
"""Return time when heartbeat expires."""
# some json implementations returns decimal.Decimal objects,
# which aren't compatible with float.
freq = float(freq) if isinstance(freq, Decimal) else freq
if isinstance(timestamp, Decimal):
timestamp = float(timestamp)
return timestamp + (freq * (expire_window / 1e2))
def _depickle_task(cls, fields):
return cls(**fields)
def with_unique_field(attr):
def _decorate_cls(cls):
def __eq__(this, other):
if isinstance(other, this.__class__):
return getattr(this, attr) == getattr(other, attr)
return NotImplemented
cls.__eq__ = __eq__
def __hash__(this):
return hash(getattr(this, attr))
cls.__hash__ = __hash__
return cls
return _decorate_cls
@with_unique_field('hostname')
class Worker:
"""Worker State."""
heartbeat_max = 4
expire_window = HEARTBEAT_EXPIRE_WINDOW
_fields = ('hostname', 'pid', 'freq', 'heartbeats', 'clock',
'active', 'processed', 'loadavg', 'sw_ident',
'sw_ver', 'sw_sys')
if not PYPY: # pragma: no cover
__slots__ = _fields + ('event', '__dict__', '__weakref__')
def __init__(self, hostname=None, pid=None, freq=60,
heartbeats=None, clock=0, active=None, processed=None,
loadavg=None, sw_ident=None, sw_ver=None, sw_sys=None):
self.hostname = hostname
self.pid = pid
self.freq = freq
self.heartbeats = [] if heartbeats is None else heartbeats
self.clock = clock or 0
self.active = active
self.processed = processed
self.loadavg = loadavg
self.sw_ident = sw_ident
self.sw_ver = sw_ver
self.sw_sys = sw_sys
self.event = self._create_event_handler()
def __reduce__(self):
return self.__class__, (self.hostname, self.pid, self.freq,
self.heartbeats, self.clock, self.active,
self.processed, self.loadavg, self.sw_ident,
self.sw_ver, self.sw_sys)
def _create_event_handler(self):
_set = object.__setattr__
hbmax = self.heartbeat_max
heartbeats = self.heartbeats
hb_pop = self.heartbeats.pop
hb_append = self.heartbeats.append
def event(type_, timestamp=None,
local_received=None, fields=None,
max_drift=HEARTBEAT_DRIFT_MAX, abs=abs, int=int,
insort=bisect.insort, len=len):
fields = fields or {}
for k, v in fields.items():
_set(self, k, v)
if type_ == 'offline':
heartbeats[:] = []
else:
if not local_received or not timestamp:
return
drift = abs(int(local_received) - int(timestamp))
if drift > max_drift:
_warn_drift(self.hostname, drift,
local_received, timestamp)
if local_received: # pragma: no cover
hearts = len(heartbeats)
if hearts > hbmax - 1:
hb_pop(0)
if hearts and local_received > heartbeats[-1]:
hb_append(local_received)
else:
insort(heartbeats, local_received)
return event
def update(self, f, **kw):
d = dict(f, **kw) if kw else f
for k, v in d.items():
setattr(self, k, v)
def __repr__(self):
return R_WORKER.format(self)
@property
def status_string(self):
return 'ONLINE' if self.alive else 'OFFLINE'
@property
def heartbeat_expires(self):
return heartbeat_expires(self.heartbeats[-1],
self.freq, self.expire_window)
@property
def alive(self, nowfun=time):
return bool(self.heartbeats and nowfun() < self.heartbeat_expires)
@property
def id(self):
return '{0.hostname}.{0.pid}'.format(self)
@with_unique_field('uuid')
class Task:
"""Task State."""
name = received = sent = started = succeeded = failed = retried = \
revoked = rejected = args = kwargs = eta = expires = retries = \
worker = result = exception = timestamp = runtime = traceback = \
exchange = routing_key = root_id = parent_id = client = None
state = states.PENDING
clock = 0
_fields = (
'uuid', 'name', 'state', 'received', 'sent', 'started', 'rejected',
'succeeded', 'failed', 'retried', 'revoked', 'args', 'kwargs',
'eta', 'expires', 'retries', 'worker', 'result', 'exception',
'timestamp', 'runtime', 'traceback', 'exchange', 'routing_key',
'clock', 'client', 'root', 'root_id', 'parent', 'parent_id',
'children',
)
if not PYPY: # pragma: no cover
__slots__ = ('__dict__', '__weakref__')
#: How to merge out of order events.
#: Disorder is detected by logical ordering (e.g., :event:`task-received`
#: must've happened before a :event:`task-failed` event).
#:
#: A merge rule consists of a state and a list of fields to keep from
#: that state. ``(RECEIVED, ('name', 'args')``, means the name and args
#: fields are always taken from the RECEIVED state, and any values for
#: these fields received before or after is simply ignored.
merge_rules = {
states.RECEIVED: (
'name', 'args', 'kwargs', 'parent_id',
'root_id', 'retries', 'eta', 'expires',
),
}
#: meth:`info` displays these fields by default.
_info_fields = (
'args', 'kwargs', 'retries', 'result', 'eta', 'runtime',
'expires', 'exception', 'exchange', 'routing_key',
'root_id', 'parent_id',
)
def __init__(self, uuid=None, cluster_state=None, children=None, **kwargs):
self.uuid = uuid
self.cluster_state = cluster_state
if self.cluster_state is not None:
self.children = WeakSet(
self.cluster_state.tasks.get(task_id)
for task_id in children or ()
if task_id in self.cluster_state.tasks
)
else:
self.children = WeakSet()
self._serializer_handlers = {
'children': self._serializable_children,
'root': self._serializable_root,
'parent': self._serializable_parent,
}
if kwargs:
self.__dict__.update(kwargs)
def event(self, type_, timestamp=None, local_received=None, fields=None,
precedence=states.precedence, setattr=setattr,
task_event_to_state=TASK_EVENT_TO_STATE.get, RETRY=states.RETRY):
fields = fields or {}
# using .get is faster than catching KeyError in this case.
state = task_event_to_state(type_)
if state is not None:
# sets, for example, self.succeeded to the timestamp.
setattr(self, type_, timestamp)
else:
state = type_.upper() # custom state
# note that precedence here is reversed
# see implementation in celery.states.state.__lt__
if state != RETRY and self.state != RETRY and \
precedence(state) > precedence(self.state):
# this state logically happens-before the current state, so merge.
keep = self.merge_rules.get(state)
if keep is not None:
fields = {
k: v for k, v in fields.items() if k in keep
}
else:
fields.update(state=state, timestamp=timestamp)
# update current state with info from this event.
self.__dict__.update(fields)
def info(self, fields=None, extra=None):
"""Information about this task suitable for on-screen display."""
extra = [] if not extra else extra
fields = self._info_fields if fields is None else fields
def _keys():
for key in list(fields) + list(extra):
value = getattr(self, key, None)
if value is not None:
yield key, value
return dict(_keys())
def __repr__(self):
return R_TASK.format(self)
def as_dict(self):
get = object.__getattribute__
handler = self._serializer_handlers.get
return {
k: handler(k, pass1)(get(self, k)) for k in self._fields
}
def _serializable_children(self, value):
return [task.id for task in self.children]
def _serializable_root(self, value):
return self.root_id
def _serializable_parent(self, value):
return self.parent_id
def __reduce__(self):
return _depickle_task, (self.__class__, self.as_dict())
@property
def id(self):
return self.uuid
@property
def origin(self):
return self.client if self.worker is None else self.worker.id
@property
def ready(self):
return self.state in states.READY_STATES
@cached_property
def parent(self):
# issue github.com/mher/flower/issues/648
try:
return self.parent_id and self.cluster_state.tasks.data[self.parent_id]
except KeyError:
return None
@cached_property
def root(self):
# issue github.com/mher/flower/issues/648
try:
return self.root_id and self.cluster_state.tasks.data[self.root_id]
except KeyError:
return None
class State:
"""Records clusters state."""
Worker = Worker
Task = Task
event_count = 0
task_count = 0
heap_multiplier = 4
def __init__(self, callback=None,
workers=None, tasks=None, taskheap=None,
max_workers_in_memory=5000, max_tasks_in_memory=10000,
on_node_join=None, on_node_leave=None,
tasks_by_type=None, tasks_by_worker=None):
self.event_callback = callback
self.workers = (LRUCache(max_workers_in_memory)
if workers is None else workers)
self.tasks = (LRUCache(max_tasks_in_memory)
if tasks is None else tasks)
self._taskheap = [] if taskheap is None else taskheap
self.max_workers_in_memory = max_workers_in_memory
self.max_tasks_in_memory = max_tasks_in_memory
self.on_node_join = on_node_join
self.on_node_leave = on_node_leave
self._mutex = threading.Lock()
self.handlers = {}
self._seen_types = set()
self._tasks_to_resolve = {}
self.rebuild_taskheap()
self.tasks_by_type = CallableDefaultdict(
self._tasks_by_type, WeakSet) # type: Mapping[str, WeakSet[Task]]
self.tasks_by_type.update(
_deserialize_Task_WeakSet_Mapping(tasks_by_type, self.tasks))
self.tasks_by_worker = CallableDefaultdict(
self._tasks_by_worker, WeakSet) # type: Mapping[str, WeakSet[Task]]
self.tasks_by_worker.update(
_deserialize_Task_WeakSet_Mapping(tasks_by_worker, self.tasks))
@cached_property
def _event(self):
return self._create_dispatcher()
def freeze_while(self, fun, *args, **kwargs):
clear_after = kwargs.pop('clear_after', False)
with self._mutex:
try:
return fun(*args, **kwargs)
finally:
if clear_after:
self._clear()
def clear_tasks(self, ready=True):
with self._mutex:
return self._clear_tasks(ready)
def _clear_tasks(self, ready: bool = True):
if ready:
in_progress = {
uuid: task for uuid, task in self.itertasks()
if task.state not in states.READY_STATES
}
self.tasks.clear()
self.tasks.update(in_progress)
else:
self.tasks.clear()
self._taskheap[:] = []
def _clear(self, ready=True):
self.workers.clear()
self._clear_tasks(ready)
self.event_count = 0
self.task_count = 0
def clear(self, ready: bool = True):
with self._mutex:
return self._clear(ready)
def get_or_create_worker(self, hostname, **kwargs):
"""Get or create worker by hostname.
Returns:
Tuple: of ``(worker, was_created)`` pairs.
"""
try:
worker = self.workers[hostname]
if kwargs:
worker.update(kwargs)
return worker, False
except KeyError:
worker = self.workers[hostname] = self.Worker(
hostname, **kwargs)
return worker, True
def get_or_create_task(self, uuid):
"""Get or create task by uuid."""
try:
return self.tasks[uuid], False
except KeyError:
task = self.tasks[uuid] = self.Task(uuid, cluster_state=self)
return task, True
def event(self, event):
with self._mutex:
return self._event(event)
def task_event(self, type_, fields):
"""Deprecated, use :meth:`event`."""
return self._event(dict(fields, type='-'.join(['task', type_])))[0]
def worker_event(self, type_, fields):
"""Deprecated, use :meth:`event`."""
return self._event(dict(fields, type='-'.join(['worker', type_])))[0]
def _create_dispatcher(self):
# pylint: disable=too-many-statements
# This code is highly optimized, but not for reusability.
get_handler = self.handlers.__getitem__
event_callback = self.event_callback
wfields = itemgetter('hostname', 'timestamp', 'local_received')
tfields = itemgetter('uuid', 'hostname', 'timestamp',
'local_received', 'clock')
taskheap = self._taskheap
th_append = taskheap.append
th_pop = taskheap.pop
# Removing events from task heap is an O(n) operation,
# so easier to just account for the common number of events
# for each task (PENDING->RECEIVED->STARTED->final)
#: an O(n) operation
max_events_in_heap = self.max_tasks_in_memory * self.heap_multiplier
add_type = self._seen_types.add
on_node_join, on_node_leave = self.on_node_join, self.on_node_leave
tasks, Task = self.tasks, self.Task
workers, Worker = self.workers, self.Worker
# avoid updating LRU entry at getitem
get_worker, get_task = workers.data.__getitem__, tasks.data.__getitem__
get_task_by_type_set = self.tasks_by_type.__getitem__
get_task_by_worker_set = self.tasks_by_worker.__getitem__
def _event(event,
timetuple=timetuple, KeyError=KeyError,
insort=bisect.insort, created=True):
self.event_count += 1
if event_callback:
event_callback(self, event)
group, _, subject = event['type'].partition('-')
try:
handler = get_handler(group)
except KeyError:
pass
else:
return handler(subject, event), subject
if group == 'worker':
try:
hostname, timestamp, local_received = wfields(event)
except KeyError:
pass
else:
is_offline = subject == 'offline'
try:
worker, created = get_worker(hostname), False
except KeyError:
if is_offline:
worker, created = Worker(hostname), False
else:
worker = workers[hostname] = Worker(hostname)
worker.event(subject, timestamp, local_received, event)
if on_node_join and (created or subject == 'online'):
on_node_join(worker)
if on_node_leave and is_offline:
on_node_leave(worker)
workers.pop(hostname, None)
return (worker, created), subject
elif group == 'task':
(uuid, hostname, timestamp,
local_received, clock) = tfields(event)
# task-sent event is sent by client, not worker
is_client_event = subject == 'sent'
try:
task, task_created = get_task(uuid), False
except KeyError:
task = tasks[uuid] = Task(uuid, cluster_state=self)
task_created = True
if is_client_event:
task.client = hostname
else:
try:
worker = get_worker(hostname)
except KeyError:
worker = workers[hostname] = Worker(hostname)
task.worker = worker
if worker is not None and local_received:
worker.event(None, local_received, timestamp)
origin = hostname if is_client_event else worker.id
# remove oldest event if exceeding the limit.
heaps = len(taskheap)
if heaps + 1 > max_events_in_heap:
th_pop(0)
# most events will be dated later than the previous.
timetup = timetuple(clock, timestamp, origin, ref(task))
if heaps and timetup > taskheap[-1]:
th_append(timetup)
else:
insort(taskheap, timetup)
if subject == 'received':
self.task_count += 1
task.event(subject, timestamp, local_received, event)
task_name = task.name
if task_name is not None:
add_type(task_name)
if task_created: # add to tasks_by_type index
get_task_by_type_set(task_name).add(task)
get_task_by_worker_set(hostname).add(task)
if task.parent_id:
try:
parent_task = self.tasks[task.parent_id]
except KeyError:
self._add_pending_task_child(task)
else:
parent_task.children.add(task)
try:
_children = self._tasks_to_resolve.pop(uuid)
except KeyError:
pass
else:
task.children.update(_children)
return (task, task_created), subject
return _event
def _add_pending_task_child(self, task):
try:
ch = self._tasks_to_resolve[task.parent_id]
except KeyError:
ch = self._tasks_to_resolve[task.parent_id] = WeakSet()
ch.add(task)
def rebuild_taskheap(self, timetuple=timetuple):
heap = self._taskheap[:] = [
timetuple(t.clock, t.timestamp, t.origin, ref(t))
for t in self.tasks.values()
]
heap.sort()
def itertasks(self, limit: Optional[int] = None):
for index, row in enumerate(self.tasks.items()):
yield row
if limit and index + 1 >= limit:
break
def tasks_by_time(self, limit=None, reverse: bool = True):
"""Generator yielding tasks ordered by time.
Yields:
Tuples of ``(uuid, Task)``.
"""
_heap = self._taskheap
if reverse:
_heap = reversed(_heap)
seen = set()
for evtup in islice(_heap, 0, limit):
task = evtup[3]()
if task is not None:
uuid = task.uuid
if uuid not in seen:
yield uuid, task
seen.add(uuid)
tasks_by_timestamp = tasks_by_time
def _tasks_by_type(self, name, limit=None, reverse=True):
"""Get all tasks by type.
This is slower than accessing :attr:`tasks_by_type`,
but will be ordered by time.
Returns:
Generator: giving ``(uuid, Task)`` pairs.
"""
return islice(
((uuid, task) for uuid, task in self.tasks_by_time(reverse=reverse)
if task.name == name),
0, limit,
)
def _tasks_by_worker(self, hostname, limit=None, reverse=True):
"""Get all tasks by worker.
Slower than accessing :attr:`tasks_by_worker`, but ordered by time.
"""
return islice(
((uuid, task) for uuid, task in self.tasks_by_time(reverse=reverse)
if task.worker.hostname == hostname),
0, limit,
)
def task_types(self):
"""Return a list of all seen task types."""
return sorted(self._seen_types)
def alive_workers(self):
"""Return a list of (seemingly) alive workers."""
return (w for w in self.workers.values() if w.alive)
def __repr__(self):
return R_STATE.format(self)
def __reduce__(self):
return self.__class__, (
self.event_callback, self.workers, self.tasks, None,
self.max_workers_in_memory, self.max_tasks_in_memory,
self.on_node_join, self.on_node_leave,
_serialize_Task_WeakSet_Mapping(self.tasks_by_type),
_serialize_Task_WeakSet_Mapping(self.tasks_by_worker),
)
def _serialize_Task_WeakSet_Mapping(mapping):
return {name: [t.id for t in tasks] for name, tasks in mapping.items()}
def _deserialize_Task_WeakSet_Mapping(mapping, tasks):
mapping = mapping or {}
return {name: WeakSet(tasks[i] for i in ids if i in tasks)
for name, ids in mapping.items()}
Zerion Mini Shell 1.0