tenacity/wait.py - third_party/github.com/jd/tenacity - Git at Google

 # Copyright 2016–2021 Julien Danjou
 # Copyright 2016 Joshua Harlow
 # Copyright 2013-2014 Ray Holder
 #
 # Licensed under the Apache License, Version 2.0 (the "License");
 # you may not use this file except in compliance with the License.
 # You may obtain a copy of the License at
 #
 # http://www.apache.org/licenses/LICENSE-2.0
 #
 # Unless required by applicable law or agreed to in writing, software
 # distributed under the License is distributed on an "AS IS" BASIS,
 # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 # See the License for the specific language governing permissions and
 # limitations under the License.

 import abc
 import random
 import typing

 from tenacity import _utils

 if typing.TYPE_CHECKING:
     from tenacity import RetryCallState


 class wait_base(abc.ABC):
     """Abstract base class for wait strategies."""

     @abc.abstractmethod
     def __call__(self, retry_state: "RetryCallState") -> float:
         pass

     def __add__(self, other: "wait_base") -> "wait_combine":
         return wait_combine(self, other)

     def __radd__(self, other: "wait_base") -> typing.Union["wait_combine", "wait_base"]:
         # make it possible to use multiple waits with the built-in sum function
         if other == 0:
             return self
         return self.__add__(other)


 class wait_fixed(wait_base):
     """Wait strategy that waits a fixed amount of time between each retry."""

     def __init__(self, wait: _utils.time_unit_type) -> None:
         self.wait_fixed = _utils.to_seconds(wait)

     def __call__(self, retry_state: "RetryCallState") -> float:
         return self.wait_fixed


 class wait_none(wait_fixed):
     """Wait strategy that doesn't wait at all before retrying."""

     def __init__(self) -> None:
         super().__init__(0)


 class wait_random(wait_base):
     """Wait strategy that waits a random amount of time between min/max."""

     def __init__(self, min: _utils.time_unit_type = 0, max: _utils.time_unit_type = 1) -> None:  # noqa
         self.wait_random_min = _utils.to_seconds(min)
         self.wait_random_max = _utils.to_seconds(max)

     def __call__(self, retry_state: "RetryCallState") -> float:
         return self.wait_random_min + (random.random() * (self.wait_random_max - self.wait_random_min))


 class wait_combine(wait_base):
     """Combine several waiting strategies."""

     def __init__(self, *strategies: wait_base) -> None:
         self.wait_funcs = strategies

     def __call__(self, retry_state: "RetryCallState") -> float:
         return sum(x(retry_state=retry_state) for x in self.wait_funcs)


 class wait_chain(wait_base):
     """Chain two or more waiting strategies.

     If all strategies are exhausted, the very last strategy is used
     thereafter.

     For example::

         @retry(wait=wait_chain(*[wait_fixed(1) for i in range(3)] +
                                [wait_fixed(2) for j in range(5)] +
                                [wait_fixed(5) for k in range(4)))
         def wait_chained():
             print("Wait 1s for 3 attempts, 2s for 5 attempts and 5s
                    thereafter.")
     """

     def __init__(self, *strategies: wait_base) -> None:
         self.strategies = strategies

     def __call__(self, retry_state: "RetryCallState") -> float:
         wait_func_no = min(max(retry_state.attempt_number, 1), len(self.strategies))
         wait_func = self.strategies[wait_func_no - 1]
         return wait_func(retry_state=retry_state)


 class wait_incrementing(wait_base):
     """Wait an incremental amount of time after each attempt.

     Starting at a starting value and incrementing by a value for each attempt
     (and restricting the upper limit to some maximum value).
     """

     def __init__(
         self,
         start: _utils.time_unit_type = 0,
         increment: _utils.time_unit_type = 100,
         max: _utils.time_unit_type = _utils.MAX_WAIT,  # noqa
     ) -> None:
         self.start = _utils.to_seconds(start)
         self.increment = _utils.to_seconds(increment)
         self.max = _utils.to_seconds(max)

     def __call__(self, retry_state: "RetryCallState") -> float:
         result = self.start + (self.increment * (retry_state.attempt_number - 1))
         return max(0, min(result, self.max))


 class wait_exponential(wait_base):
     """Wait strategy that applies exponential backoff.

     It allows for a customized multiplier and an ability to restrict the
     upper and lower limits to some maximum and minimum value.

     The intervals are fixed (i.e. there is no jitter), so this strategy is
     suitable for balancing retries against latency when a required resource is
     unavailable for an unknown duration, but *not* suitable for resolving
     contention between multiple processes for a shared resource. Use
     wait_random_exponential for the latter case.
     """

     def __init__(
         self,
         multiplier: typing.Union[int, float] = 1,
         max: _utils.time_unit_type = _utils.MAX_WAIT,  # noqa
         exp_base: typing.Union[int, float] = 2,
         min: _utils.time_unit_type = 0,  # noqa
     ) -> None:
         self.multiplier = multiplier
         self.min = _utils.to_seconds(min)
         self.max = _utils.to_seconds(max)
         self.exp_base = exp_base

     def __call__(self, retry_state: "RetryCallState") -> float:
         try:
             exp = self.exp_base ** (retry_state.attempt_number - 1)
             result = self.multiplier * exp
         except OverflowError:
             return self.max
         return max(max(0, self.min), min(result, self.max))


 class wait_random_exponential(wait_exponential):
     """Random wait with exponentially widening window.

     An exponential backoff strategy used to mediate contention between multiple
     uncoordinated processes for a shared resource in distributed systems. This
     is the sense in which "exponential backoff" is meant in e.g. Ethernet
     networking, and corresponds to the "Full Jitter" algorithm described in
     this blog post:

     https://aws.amazon.com/blogs/architecture/exponential-backoff-and-jitter/

     Each retry occurs at a random time in a geometrically expanding interval.
     It allows for a custom multiplier and an ability to restrict the upper
     limit of the random interval to some maximum value.

     Example::

         wait_random_exponential(multiplier=0.5,  # initial window 0.5s
                                 max=60)          # max 60s timeout

     When waiting for an unavailable resource to become available again, as
     opposed to trying to resolve contention for a shared resource, the
     wait_exponential strategy (which uses a fixed interval) may be preferable.

     """

     def __call__(self, retry_state: "RetryCallState") -> float:
         high = super().__call__(retry_state=retry_state)
         return random.uniform(0, high)


 class wait_exponential_jitter(wait_base):
     """Wait strategy that applies exponential backoff and jitter.

     It allows for a customized initial wait, maximum wait and jitter.

     This implements the strategy described here:
     https://cloud.google.com/storage/docs/retry-strategy

     The wait time is min(initial * (2**n + random.uniform(0, jitter)), maximum)
     where n is the retry count.
     """

     def __init__(
         self,
         initial: float = 1,
         max: float = _utils.MAX_WAIT,  # noqa
         exp_base: float = 2,
         jitter: float = 1,
     ) -> None:
         self.initial = initial
         self.max = max
         self.exp_base = exp_base
         self.jitter = jitter

     def __call__(self, retry_state: "RetryCallState") -> float:
         jitter = random.uniform(0, self.jitter)
         try:
             exp = self.exp_base ** (retry_state.attempt_number - 1)
             result = self.initial * exp + jitter
         except OverflowError:
             result = self.max
         return max(0, min(result, self.max))
	# Copyright 2016–2021 Julien Danjou
	# Copyright 2016 Joshua Harlow
	# Copyright 2013-2014 Ray Holder
	#
	# Licensed under the Apache License, Version 2.0 (the "License");
	# you may not use this file except in compliance with the License.
	# You may obtain a copy of the License at
	#
	# http://www.apache.org/licenses/LICENSE-2.0
	#
	# Unless required by applicable law or agreed to in writing, software
	# distributed under the License is distributed on an "AS IS" BASIS,
	# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	# See the License for the specific language governing permissions and
	# limitations under the License.

	import abc
	import random
	import typing

	from tenacity import _utils

	if typing.TYPE_CHECKING:
	from tenacity import RetryCallState


	class wait_base(abc.ABC):
	"""Abstract base class for wait strategies."""

	@abc.abstractmethod
	def __call__(self, retry_state: "RetryCallState") -> float:
	pass

	def __add__(self, other: "wait_base") -> "wait_combine":
	return wait_combine(self, other)

	def __radd__(self, other: "wait_base") -> typing.Union["wait_combine", "wait_base"]:
	# make it possible to use multiple waits with the built-in sum function
	if other == 0:
	return self
	return self.__add__(other)


	class wait_fixed(wait_base):
	"""Wait strategy that waits a fixed amount of time between each retry."""

	def __init__(self, wait: _utils.time_unit_type) -> None:
	self.wait_fixed = _utils.to_seconds(wait)

	def __call__(self, retry_state: "RetryCallState") -> float:
	return self.wait_fixed


	class wait_none(wait_fixed):
	"""Wait strategy that doesn't wait at all before retrying."""

	def __init__(self) -> None:
	super().__init__(0)


	class wait_random(wait_base):
	"""Wait strategy that waits a random amount of time between min/max."""

	def __init__(self, min: _utils.time_unit_type = 0, max: _utils.time_unit_type = 1) -> None: # noqa
	self.wait_random_min = _utils.to_seconds(min)
	self.wait_random_max = _utils.to_seconds(max)

	def __call__(self, retry_state: "RetryCallState") -> float:
	return self.wait_random_min + (random.random() * (self.wait_random_max - self.wait_random_min))


	class wait_combine(wait_base):
	"""Combine several waiting strategies."""

	def __init__(self, *strategies: wait_base) -> None:
	self.wait_funcs = strategies

	def __call__(self, retry_state: "RetryCallState") -> float:
	return sum(x(retry_state=retry_state) for x in self.wait_funcs)


	class wait_chain(wait_base):
	"""Chain two or more waiting strategies.

	If all strategies are exhausted, the very last strategy is used
	thereafter.

	For example::

	@retry(wait=wait_chain(*[wait_fixed(1) for i in range(3)] +
	[wait_fixed(2) for j in range(5)] +
	[wait_fixed(5) for k in range(4)))
	def wait_chained():
	print("Wait 1s for 3 attempts, 2s for 5 attempts and 5s
	thereafter.")
	"""

	def __init__(self, *strategies: wait_base) -> None:
	self.strategies = strategies

	def __call__(self, retry_state: "RetryCallState") -> float:
	wait_func_no = min(max(retry_state.attempt_number, 1), len(self.strategies))
	wait_func = self.strategies[wait_func_no - 1]
	return wait_func(retry_state=retry_state)


	class wait_incrementing(wait_base):
	"""Wait an incremental amount of time after each attempt.

	Starting at a starting value and incrementing by a value for each attempt
	(and restricting the upper limit to some maximum value).
	"""

	def __init__(
	self,
	start: _utils.time_unit_type = 0,
	increment: _utils.time_unit_type = 100,
	max: _utils.time_unit_type = _utils.MAX_WAIT, # noqa
	) -> None:
	self.start = _utils.to_seconds(start)
	self.increment = _utils.to_seconds(increment)
	self.max = _utils.to_seconds(max)

	def __call__(self, retry_state: "RetryCallState") -> float:
	result = self.start + (self.increment * (retry_state.attempt_number - 1))
	return max(0, min(result, self.max))


	class wait_exponential(wait_base):
	"""Wait strategy that applies exponential backoff.

	It allows for a customized multiplier and an ability to restrict the
	upper and lower limits to some maximum and minimum value.

	The intervals are fixed (i.e. there is no jitter), so this strategy is
	suitable for balancing retries against latency when a required resource is
	unavailable for an unknown duration, but not suitable for resolving
	contention between multiple processes for a shared resource. Use
	wait_random_exponential for the latter case.
	"""

	def __init__(
	self,
	multiplier: typing.Union[int, float] = 1,
	max: _utils.time_unit_type = _utils.MAX_WAIT, # noqa
	exp_base: typing.Union[int, float] = 2,
	min: _utils.time_unit_type = 0, # noqa
	) -> None:
	self.multiplier = multiplier
	self.min = _utils.to_seconds(min)
	self.max = _utils.to_seconds(max)
	self.exp_base = exp_base

	def __call__(self, retry_state: "RetryCallState") -> float:
	try:
	exp = self.exp_base ** (retry_state.attempt_number - 1)
	result = self.multiplier * exp
	except OverflowError:
	return self.max
	return max(max(0, self.min), min(result, self.max))


	class wait_random_exponential(wait_exponential):
	"""Random wait with exponentially widening window.

	An exponential backoff strategy used to mediate contention between multiple
	uncoordinated processes for a shared resource in distributed systems. This
	is the sense in which "exponential backoff" is meant in e.g. Ethernet
	networking, and corresponds to the "Full Jitter" algorithm described in
	this blog post:

	https://aws.amazon.com/blogs/architecture/exponential-backoff-and-jitter/

	Each retry occurs at a random time in a geometrically expanding interval.
	It allows for a custom multiplier and an ability to restrict the upper
	limit of the random interval to some maximum value.

	Example::

	wait_random_exponential(multiplier=0.5, # initial window 0.5s
	max=60) # max 60s timeout

	When waiting for an unavailable resource to become available again, as
	opposed to trying to resolve contention for a shared resource, the
	wait_exponential strategy (which uses a fixed interval) may be preferable.

	"""

	def __call__(self, retry_state: "RetryCallState") -> float:
	high = super().__call__(retry_state=retry_state)
	return random.uniform(0, high)


	class wait_exponential_jitter(wait_base):
	"""Wait strategy that applies exponential backoff and jitter.

	It allows for a customized initial wait, maximum wait and jitter.

	This implements the strategy described here:
	https://cloud.google.com/storage/docs/retry-strategy

	The wait time is min(initial * (2**n + random.uniform(0, jitter)), maximum)
	where n is the retry count.
	"""

	def __init__(
	self,
	initial: float = 1,
	max: float = _utils.MAX_WAIT, # noqa
	exp_base: float = 2,
	jitter: float = 1,
	) -> None:
	self.initial = initial
	self.max = max
	self.exp_base = exp_base
	self.jitter = jitter

	def __call__(self, retry_state: "RetryCallState") -> float:
	jitter = random.uniform(0, self.jitter)
	try:
	exp = self.exp_base ** (retry_state.attempt_number - 1)
	result = self.initial * exp + jitter
	except OverflowError:
	result = self.max
	return max(0, min(result, self.max))