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- """
- celery.datastructures
- =====================
- Custom data structures.
- :copyright: (c) 2009 - 2010 by Ask Solem.
- :license: BSD, see LICENSE for more details.
- """
- from __future__ import generators
- import time
- import traceback
- from itertools import chain
- from Queue import Queue, Empty as QueueEmpty
- from celery.utils.compat import OrderedDict
- class AttributeDictMixin(object):
- """Adds attribute access to mappings.
- `d.key -> d[key]`
- """
- def __getattr__(self, key):
- """`d.key -> d[key]`"""
- try:
- return self[key]
- except KeyError:
- raise AttributeError("'%s' object has no attribute '%s'" % (
- self.__class__.__name__, key))
- def __setattr__(self, key, value):
- """`d[key] = value -> d.key = value`"""
- self[key] = value
- class AttributeDict(dict, AttributeDictMixin):
- """Dict subclass with attribute access."""
- pass
- class DictAttribute(object):
- """Dict interface to attributes.
- `obj[k] -> obj.k`
- """
- def __init__(self, obj):
- self.obj = obj
- def get(self, key, default=None):
- try:
- return self[key]
- except KeyError:
- return default
- def setdefault(self, key, default):
- try:
- return self[key]
- except KeyError:
- self[key] = default
- return default
- def __getitem__(self, key):
- try:
- return getattr(self.obj, key)
- except AttributeError:
- raise KeyError(key)
- def __setitem__(self, key, value):
- setattr(self.obj, key, value)
- def __contains__(self, key):
- return hasattr(self.obj, key)
- def iteritems(self):
- return vars(self.obj).iteritems()
- class ConfigurationView(AttributeDictMixin):
- changes = None
- defaults = None
- def __init__(self, changes, defaults):
- self.__dict__["changes"] = changes
- self.__dict__["defaults"] = defaults
- self.__dict__["_order"] = [changes] + defaults
- def __getitem__(self, key):
- for d in self.__dict__["_order"]:
- try:
- return d[key]
- except KeyError:
- pass
- raise KeyError(key)
- def __setitem__(self, key, value):
- self.__dict__["changes"][key] = value
- def get(self, key, default=None):
- try:
- return self[key]
- except KeyError:
- return default
- def setdefault(self, key, default):
- try:
- return self[key]
- except KeyError:
- self[key] = default
- return default
- def update(self, *args, **kwargs):
- return self.__dict__["changes"].update(*args, **kwargs)
- def __contains__(self, key):
- for d in self.__dict__["_order"]:
- if key in d:
- return True
- return False
- def __repr__(self):
- return repr(dict(iter(self)))
- def __iter__(self):
- # defaults must be first in the stream, so values in
- # in changes takes precedence.
- return chain(*[d.iteritems()
- for d in reversed(self.__dict__["_order"])])
- def iteritems(self):
- return iter(self)
- def items(self):
- return tuple(self.iteritems())
- class ExceptionInfo(object):
- """Exception wrapping an exception and its traceback.
- :param exc_info: The exception info tuple as returned by
- :func:`sys.exc_info`.
- """
- #: The original exception.
- exception = None
- #: A traceback form the point when :attr:`exception` was raised.
- traceback = None
- def __init__(self, exc_info):
- _, exception, _ = exc_info
- self.exception = exception
- self.traceback = ''.join(traceback.format_exception(*exc_info))
- def __str__(self):
- return self.traceback
- def __repr__(self):
- return "<ExceptionInfo: %r>" % (self.exception, )
- def consume_queue(queue):
- """Iterator yielding all immediately available items in a
- :class:`Queue.Queue`.
- The iterator stops as soon as the queue raises :exc:`Queue.Empty`.
- *Examples*
- >>> q = Queue()
- >>> map(q.put, range(4))
- >>> list(consume_queue(q))
- [0, 1, 2, 3]
- >>> list(consume_queue(q))
- []
- """
- while 1:
- try:
- yield queue.get_nowait()
- except QueueEmpty:
- break
- class SharedCounter(object):
- """Thread-safe counter.
- Please note that the final value is not synchronized, this means
- that you should not update the value by using a previous value, the only
- reliable operations are increment and decrement.
- Example::
- >>> max_clients = SharedCounter(initial_value=10)
- # Thread one
- >>> max_clients += 1 # OK (safe)
- # Thread two
- >>> max_clients -= 3 # OK (safe)
- # Main thread
- >>> if client >= int(max_clients): # Max clients now at 8
- ... wait()
- >>> max_client = max_clients + 10 # NOT OK (unsafe)
- """
- def __init__(self, initial_value):
- self._value = initial_value
- self._modify_queue = Queue()
- def increment(self, n=1):
- """Increment value."""
- self += n
- return int(self)
- def decrement(self, n=1):
- """Decrement value."""
- self -= n
- return int(self)
- def _update_value(self):
- self._value += sum(consume_queue(self._modify_queue))
- return self._value
- def __iadd__(self, y):
- """`self += y`"""
- self._modify_queue.put(y * +1)
- return self
- def __isub__(self, y):
- """`self -= y`"""
- self._modify_queue.put(y * -1)
- return self
- def __int__(self):
- """`int(self) -> int`"""
- return self._update_value()
- def __repr__(self):
- return repr(int(self))
- class LimitedSet(object):
- """Kind-of Set with limitations.
- Good for when you need to test for membership (`a in set`),
- but the list might become to big, so you want to limit it so it doesn't
- consume too much resources.
- :keyword maxlen: Maximum number of members before we start
- deleting expired members.
- :keyword expires: Time in seconds, before a membership expires.
- """
- def __init__(self, maxlen=None, expires=None):
- self.maxlen = maxlen
- self.expires = expires
- self._data = {}
- def add(self, value):
- """Add a new member."""
- self._expire_item()
- self._data[value] = time.time()
- def clear(self):
- """Remove all members"""
- self._data.clear()
- def pop_value(self, value):
- """Remove membership by finding value."""
- self._data.pop(value, None)
- def _expire_item(self):
- """Hunt down and remove an expired item."""
- while 1:
- if self.maxlen and len(self) >= self.maxlen:
- value, when = self.first
- if not self.expires or time.time() > when + self.expires:
- try:
- self.pop_value(value)
- except TypeError: # pragma: no cover
- continue
- break
- def __contains__(self, value):
- return value in self._data
- def update(self, other):
- if isinstance(other, self.__class__):
- self._data.update(other._data)
- else:
- self._data.update(other)
- def as_dict(self):
- return self._data
- def __iter__(self):
- return iter(self._data.keys())
- def __len__(self):
- return len(self._data.keys())
- def __repr__(self):
- return "LimitedSet([%s])" % (repr(self._data.keys()))
- @property
- def chronologically(self):
- return sorted(self._data.items(), key=lambda (value, when): when)
- @property
- def first(self):
- """Get the oldest member."""
- return self.chronologically[0]
- class LocalCache(OrderedDict):
- """Dictionary with a finite number of keys.
- Older items expires first.
- """
- def __init__(self, limit=None):
- super(LocalCache, self).__init__()
- self.limit = limit
- def __setitem__(self, key, value):
- while len(self) >= self.limit:
- self.popitem(last=False)
- super(LocalCache, self).__setitem__(key, value)
- class TokenBucket(object):
- """Token Bucket Algorithm.
- See http://en.wikipedia.org/wiki/Token_Bucket
- Most of this code was stolen from an entry in the ASPN Python Cookbook:
- http://code.activestate.com/recipes/511490/
- .. admonition:: Thread safety
- This implementation may not be thread safe.
- """
- #: The rate in tokens/second that the bucket will be refilled
- fill_rate = None
- #: Maximum number of tokensin the bucket.
- capacity = 1
- #: Timestamp of the last time a token was taken out of the bucket.
- timestamp = None
- def __init__(self, fill_rate, capacity=1):
- self.capacity = float(capacity)
- self._tokens = capacity
- self.fill_rate = float(fill_rate)
- self.timestamp = time.time()
- def can_consume(self, tokens=1):
- """Returns :const:`True` if `tokens` number of tokens can be consumed
- from the bucket."""
- if tokens <= self._get_tokens():
- self._tokens -= tokens
- return True
- return False
- def expected_time(self, tokens=1):
- """Returns the expected time in seconds when a new token should be
- available.
- .. admonition:: Warning
- This consumes a token from the bucket.
- """
- _tokens = self._get_tokens()
- tokens = max(tokens, _tokens)
- return (tokens - _tokens) / self.fill_rate
- def _get_tokens(self):
- if self._tokens < self.capacity:
- now = time.time()
- delta = self.fill_rate * (now - self.timestamp)
- self._tokens = min(self.capacity, self._tokens + delta)
- self.timestamp = now
- return self._tokens
|
