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Add a batching queue implementation. (#10017)

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Erik Johnston 2021-05-21 11:20:51 +01:00 committed by GitHub
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Add a batching queue implementation.

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# Copyright 2021 The Matrix.org Foundation C.I.C.
#
# 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 logging
from typing import (
Awaitable,
Callable,
Dict,
Generic,
Hashable,
List,
Set,
Tuple,
TypeVar,
)
from twisted.internet import defer
from synapse.logging.context import PreserveLoggingContext, make_deferred_yieldable
from synapse.metrics import LaterGauge
from synapse.metrics.background_process_metrics import run_as_background_process
from synapse.util import Clock
logger = logging.getLogger(__name__)
V = TypeVar("V")
R = TypeVar("R")
class BatchingQueue(Generic[V, R]):
"""A queue that batches up work, calling the provided processing function
with all pending work (for a given key).
The provided processing function will only be called once at a time for each
key. It will be called the next reactor tick after `add_to_queue` has been
called, and will keep being called until the queue has been drained (for the
given key).
Note that the return value of `add_to_queue` will be the return value of the
processing function that processed the given item. This means that the
returned value will likely include data for other items that were in the
batch.
"""
def __init__(
self,
name: str,
clock: Clock,
process_batch_callback: Callable[[List[V]], Awaitable[R]],
):
self._name = name
self._clock = clock
# The set of keys currently being processed.
self._processing_keys = set() # type: Set[Hashable]
# The currently pending batch of values by key, with a Deferred to call
# with the result of the corresponding `_process_batch_callback` call.
self._next_values = {} # type: Dict[Hashable, List[Tuple[V, defer.Deferred]]]
# The function to call with batches of values.
self._process_batch_callback = process_batch_callback
LaterGauge(
"synapse_util_batching_queue_number_queued",
"The number of items waiting in the queue across all keys",
labels=("name",),
caller=lambda: sum(len(v) for v in self._next_values.values()),
)
LaterGauge(
"synapse_util_batching_queue_number_of_keys",
"The number of distinct keys that have items queued",
labels=("name",),
caller=lambda: len(self._next_values),
)
async def add_to_queue(self, value: V, key: Hashable = ()) -> R:
"""Adds the value to the queue with the given key, returning the result
of the processing function for the batch that included the given value.
The optional `key` argument allows sharding the queue by some key. The
queues will then be processed in parallel, i.e. the process batch
function will be called in parallel with batched values from a single
key.
"""
# First we create a defer and add it and the value to the list of
# pending items.
d = defer.Deferred()
self._next_values.setdefault(key, []).append((value, d))
# If we're not currently processing the key fire off a background
# process to start processing.
if key not in self._processing_keys:
run_as_background_process(self._name, self._process_queue, key)
return await make_deferred_yieldable(d)
async def _process_queue(self, key: Hashable) -> None:
"""A background task to repeatedly pull things off the queue for the
given key and call the `self._process_batch_callback` with the values.
"""
try:
if key in self._processing_keys:
return
self._processing_keys.add(key)
while True:
# We purposefully wait a reactor tick to allow us to batch
# together requests that we're about to receive. A common
# pattern is to call `add_to_queue` multiple times at once, and
# deferring to the next reactor tick allows us to batch all of
# those up.
await self._clock.sleep(0)
next_values = self._next_values.pop(key, [])
if not next_values:
# We've exhausted the queue.
break
try:
values = [value for value, _ in next_values]
results = await self._process_batch_callback(values)
for _, deferred in next_values:
with PreserveLoggingContext():
deferred.callback(results)
except Exception as e:
for _, deferred in next_values:
if deferred.called:
continue
with PreserveLoggingContext():
deferred.errback(e)
finally:
self._processing_keys.discard(key)

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# Copyright 2021 The Matrix.org Foundation C.I.C.
#
# 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.
from twisted.internet import defer
from synapse.logging.context import make_deferred_yieldable
from synapse.util.batching_queue import BatchingQueue
from tests.server import get_clock
from tests.unittest import TestCase
class BatchingQueueTestCase(TestCase):
def setUp(self):
self.clock, hs_clock = get_clock()
self._pending_calls = []
self.queue = BatchingQueue("test_queue", hs_clock, self._process_queue)
async def _process_queue(self, values):
d = defer.Deferred()
self._pending_calls.append((values, d))
return await make_deferred_yieldable(d)
def test_simple(self):
"""Tests the basic case of calling `add_to_queue` once and having
`_process_queue` return.
"""
self.assertFalse(self._pending_calls)
queue_d = defer.ensureDeferred(self.queue.add_to_queue("foo"))
# The queue should wait a reactor tick before calling the processing
# function.
self.assertFalse(self._pending_calls)
self.assertFalse(queue_d.called)
# We should see a call to `_process_queue` after a reactor tick.
self.clock.pump([0])
self.assertEqual(len(self._pending_calls), 1)
self.assertEqual(self._pending_calls[0][0], ["foo"])
self.assertFalse(queue_d.called)
# Return value of the `_process_queue` should be propagated back.
self._pending_calls.pop()[1].callback("bar")
self.assertEqual(self.successResultOf(queue_d), "bar")
def test_batching(self):
"""Test that multiple calls at the same time get batched up into one
call to `_process_queue`.
"""
self.assertFalse(self._pending_calls)
queue_d1 = defer.ensureDeferred(self.queue.add_to_queue("foo1"))
queue_d2 = defer.ensureDeferred(self.queue.add_to_queue("foo2"))
self.clock.pump([0])
# We should see only *one* call to `_process_queue`
self.assertEqual(len(self._pending_calls), 1)
self.assertEqual(self._pending_calls[0][0], ["foo1", "foo2"])
self.assertFalse(queue_d1.called)
self.assertFalse(queue_d2.called)
# Return value of the `_process_queue` should be propagated back to both.
self._pending_calls.pop()[1].callback("bar")
self.assertEqual(self.successResultOf(queue_d1), "bar")
self.assertEqual(self.successResultOf(queue_d2), "bar")
def test_queuing(self):
"""Test that we queue up requests while a `_process_queue` is being
called.
"""
self.assertFalse(self._pending_calls)
queue_d1 = defer.ensureDeferred(self.queue.add_to_queue("foo1"))
self.clock.pump([0])
queue_d2 = defer.ensureDeferred(self.queue.add_to_queue("foo2"))
# We should see only *one* call to `_process_queue`
self.assertEqual(len(self._pending_calls), 1)
self.assertEqual(self._pending_calls[0][0], ["foo1"])
self.assertFalse(queue_d1.called)
self.assertFalse(queue_d2.called)
# Return value of the `_process_queue` should be propagated back to the
# first.
self._pending_calls.pop()[1].callback("bar1")
self.assertEqual(self.successResultOf(queue_d1), "bar1")
self.assertFalse(queue_d2.called)
# We should now see a second call to `_process_queue`
self.clock.pump([0])
self.assertEqual(len(self._pending_calls), 1)
self.assertEqual(self._pending_calls[0][0], ["foo2"])
self.assertFalse(queue_d2.called)
# Return value of the `_process_queue` should be propagated back to the
# second.
self._pending_calls.pop()[1].callback("bar2")
self.assertEqual(self.successResultOf(queue_d2), "bar2")
def test_different_keys(self):
"""Test that calls to different keys get processed in parallel."""
self.assertFalse(self._pending_calls)
queue_d1 = defer.ensureDeferred(self.queue.add_to_queue("foo1", key=1))
self.clock.pump([0])
queue_d2 = defer.ensureDeferred(self.queue.add_to_queue("foo2", key=2))
self.clock.pump([0])
# We queue up another item with key=2 to check that we will keep taking
# things off the queue.
queue_d3 = defer.ensureDeferred(self.queue.add_to_queue("foo3", key=2))
# We should see two calls to `_process_queue`
self.assertEqual(len(self._pending_calls), 2)
self.assertEqual(self._pending_calls[0][0], ["foo1"])
self.assertEqual(self._pending_calls[1][0], ["foo2"])
self.assertFalse(queue_d1.called)
self.assertFalse(queue_d2.called)
self.assertFalse(queue_d3.called)
# Return value of the `_process_queue` should be propagated back to the
# first.
self._pending_calls.pop(0)[1].callback("bar1")
self.assertEqual(self.successResultOf(queue_d1), "bar1")
self.assertFalse(queue_d2.called)
self.assertFalse(queue_d3.called)
# Return value of the `_process_queue` should be propagated back to the
# second.
self._pending_calls.pop()[1].callback("bar2")
self.assertEqual(self.successResultOf(queue_d2), "bar2")
self.assertFalse(queue_d3.called)
# We should now see a call `_pending_calls` for `foo3`
self.clock.pump([0])
self.assertEqual(len(self._pending_calls), 1)
self.assertEqual(self._pending_calls[0][0], ["foo3"])
self.assertFalse(queue_d3.called)
# Return value of the `_process_queue` should be propagated back to the
# third deferred.
self._pending_calls.pop()[1].callback("bar4")
self.assertEqual(self.successResultOf(queue_d3), "bar4")