anonymousland-synapse/synapse/federation/send_queue.py
2017-04-10 12:44:43 +01:00

532 lines
16 KiB
Python

# -*- coding: utf-8 -*-
# Copyright 2014-2016 OpenMarket Ltd
#
# 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.
"""A federation sender that forwards things to be sent across replication to
a worker process.
It assumes there is a single worker process feeding off of it.
Each row in the replication stream consists of a type and some json, where the
types indicate whether they are presence, or edus, etc.
Ephemeral or non-event data are queued up in-memory. When the worker requests
updates since a particular point, all in-memory data since before that point is
dropped. We also expire things in the queue after 5 minutes, to ensure that a
dead worker doesn't cause the queues to grow limitlessly.
Events are replicated via a separate events stream.
"""
from .units import Edu
from synapse.storage.presence import UserPresenceState
from synapse.util.metrics import Measure
import synapse.metrics
from blist import sorteddict
from collections import namedtuple
import logging
logger = logging.getLogger(__name__)
metrics = synapse.metrics.get_metrics_for(__name__)
class FederationRemoteSendQueue(object):
"""A drop in replacement for TransactionQueue"""
def __init__(self, hs):
self.server_name = hs.hostname
self.clock = hs.get_clock()
self.notifier = hs.get_notifier()
self.presence_map = {}
self.presence_changed = sorteddict()
self.keyed_edu = {}
self.keyed_edu_changed = sorteddict()
self.edus = sorteddict()
self.failures = sorteddict()
self.device_messages = sorteddict()
self.pos = 1
self.pos_time = sorteddict()
# EVERYTHING IS SAD. In particular, python only makes new scopes when
# we make a new function, so we need to make a new function so the inner
# lambda binds to the queue rather than to the name of the queue which
# changes. ARGH.
def register(name, queue):
metrics.register_callback(
queue_name + "_size",
lambda: len(queue),
)
for queue_name in [
"presence_map", "presence_changed", "keyed_edu", "keyed_edu_changed",
"edus", "failures", "device_messages", "pos_time",
]:
register(queue_name, getattr(self, queue_name))
self.clock.looping_call(self._clear_queue, 30 * 1000)
def _next_pos(self):
pos = self.pos
self.pos += 1
self.pos_time[self.clock.time_msec()] = pos
return pos
def _clear_queue(self):
"""Clear the queues for anything older than N minutes"""
FIVE_MINUTES_AGO = 5 * 60 * 1000
now = self.clock.time_msec()
keys = self.pos_time.keys()
time = keys.bisect_left(now - FIVE_MINUTES_AGO)
if not keys[:time]:
return
position_to_delete = max(keys[:time])
for key in keys[:time]:
del self.pos_time[key]
self._clear_queue_before_pos(position_to_delete)
def _clear_queue_before_pos(self, position_to_delete):
"""Clear all the queues from before a given position"""
with Measure(self.clock, "send_queue._clear"):
# Delete things out of presence maps
keys = self.presence_changed.keys()
i = keys.bisect_left(position_to_delete)
for key in keys[:i]:
del self.presence_changed[key]
user_ids = set(
user_id for uids in self.presence_changed.values() for _, user_id in uids
)
to_del = [
user_id for user_id in self.presence_map if user_id not in user_ids
]
for user_id in to_del:
del self.presence_map[user_id]
# Delete things out of keyed edus
keys = self.keyed_edu_changed.keys()
i = keys.bisect_left(position_to_delete)
for key in keys[:i]:
del self.keyed_edu_changed[key]
live_keys = set()
for edu_key in self.keyed_edu_changed.values():
live_keys.add(edu_key)
to_del = [edu_key for edu_key in self.keyed_edu if edu_key not in live_keys]
for edu_key in to_del:
del self.keyed_edu[edu_key]
# Delete things out of edu map
keys = self.edus.keys()
i = keys.bisect_left(position_to_delete)
for key in keys[:i]:
del self.edus[key]
# Delete things out of failure map
keys = self.failures.keys()
i = keys.bisect_left(position_to_delete)
for key in keys[:i]:
del self.failures[key]
# Delete things out of device map
keys = self.device_messages.keys()
i = keys.bisect_left(position_to_delete)
for key in keys[:i]:
del self.device_messages[key]
def notify_new_events(self, current_id):
"""As per TransactionQueue"""
# We don't need to replicate this as it gets sent down a different
# stream.
pass
def send_edu(self, destination, edu_type, content, key=None):
"""As per TransactionQueue"""
pos = self._next_pos()
edu = Edu(
origin=self.server_name,
destination=destination,
edu_type=edu_type,
content=content,
)
if key:
assert isinstance(key, tuple)
self.keyed_edu[(destination, key)] = edu
self.keyed_edu_changed[pos] = (destination, key)
else:
self.edus[pos] = edu
self.notifier.on_new_replication_data()
def send_presence(self, destination, states):
"""As per TransactionQueue"""
pos = self._next_pos()
self.presence_map.update({
state.user_id: state
for state in states
})
self.presence_changed[pos] = [
(destination, state.user_id) for state in states
]
self.notifier.on_new_replication_data()
def send_failure(self, failure, destination):
"""As per TransactionQueue"""
pos = self._next_pos()
self.failures[pos] = (destination, str(failure))
self.notifier.on_new_replication_data()
def send_device_messages(self, destination):
"""As per TransactionQueue"""
pos = self._next_pos()
self.device_messages[pos] = destination
self.notifier.on_new_replication_data()
def get_current_token(self):
return self.pos - 1
def federation_ack(self, token):
self._clear_queue_before_pos(token)
def get_replication_rows(self, from_token, to_token, limit, federation_ack=None):
"""Get rows to be sent over federation between the two tokens
Args:
from_token (int)
to_token(int)
limit (int)
federation_ack (int): Optional. The position where the worker is
explicitly acknowledged it has handled. Allows us to drop
data from before that point
"""
# TODO: Handle limit.
# To handle restarts where we wrap around
if from_token > self.pos:
from_token = -1
# list of tuple(int, BaseFederationRow), where the first is the position
# of the federation stream.
rows = []
# There should be only one reader, so lets delete everything its
# acknowledged its seen.
if federation_ack:
self._clear_queue_before_pos(federation_ack)
# Fetch changed presence
keys = self.presence_changed.keys()
i = keys.bisect_right(from_token)
j = keys.bisect_right(to_token) + 1
dest_user_ids = set(
(pos, dest_user_id)
for pos in keys[i:j]
for dest_user_id in self.presence_changed[pos]
)
for (key, (dest, user_id)) in dest_user_ids:
rows.append((key, PresenceRow(
destination=dest,
state=self.presence_map[user_id],
)))
# Fetch changes keyed edus
keys = self.keyed_edu_changed.keys()
i = keys.bisect_right(from_token)
j = keys.bisect_right(to_token) + 1
keyed_edus = set((k, self.keyed_edu_changed[k]) for k in keys[i:j])
for (pos, (destination, edu_key)) in keyed_edus:
rows.append((pos, KeyedEduRow(
key=edu_key,
edu=self.keyed_edu[(destination, edu_key)],
)))
# Fetch changed edus
keys = self.edus.keys()
i = keys.bisect_right(from_token)
j = keys.bisect_right(to_token) + 1
edus = set((k, self.edus[k]) for k in keys[i:j])
for (pos, edu) in edus:
rows.append((pos, EduRow(edu)))
# Fetch changed failures
keys = self.failures.keys()
i = keys.bisect_right(from_token)
j = keys.bisect_right(to_token) + 1
failures = set((k, self.failures[k]) for k in keys[i:j])
for (pos, (destination, failure)) in failures:
rows.append((pos, FailureRow(
destination=destination,
failure=failure,
)))
# Fetch changed device messages
keys = self.device_messages.keys()
i = keys.bisect_right(from_token)
j = keys.bisect_right(to_token) + 1
device_messages = set((k, self.device_messages[k]) for k in keys[i:j])
for (pos, destination) in device_messages:
rows.append((pos, DeviceRow(
destination=destination,
)))
# Sort rows based on pos
rows.sort()
return [(pos, row.TypeId, row.to_data()) for pos, row in rows]
class BaseFederationRow(object):
"""Base class for rows to be sent in the federation stream.
Specifies how to identify, serialize and deserialize the different types.
"""
TypeId = None # Unique string that ids the type. Must be overriden in sub classes.
@staticmethod
def from_data(data):
"""Parse the data from the federation stream into a row.
Args:
data: The value of ``data`` from FederationStreamRow.data, type
depends on the type of stream
"""
raise NotImplementedError()
def to_data(self):
"""Serialize this row to be sent over the federation stream.
Returns:
The value to be sent in FederationStreamRow.data. The type depends
on the type of stream.
"""
raise NotImplementedError()
def add_to_buffer(self, buff):
"""Add this row to the appropriate field in the buffer ready for this
to be sent over federation.
We use a buffer so that we can batch up events that have come in at
the same time and send them all at once.
Args:
buff (BufferedToSend)
"""
raise NotImplementedError()
class PresenceRow(BaseFederationRow, namedtuple("PresenceRow", (
"destination", # str
"state", # UserPresenceState
))):
TypeId = "p"
@staticmethod
def from_data(data):
return PresenceRow(
destination=data["destination"],
state=UserPresenceState.from_dict(data["state"])
)
def to_data(self):
return {
"destination": self.destination,
"state": self.state.as_dict()
}
def add_to_buffer(self, buff):
buff.presence.setdefault(self.destination, []).append(self.state)
class KeyedEduRow(BaseFederationRow, namedtuple("KeyedEduRow", (
"key", # tuple(str) - the edu key passed to send_edu
"edu", # Edu
))):
TypeId = "k"
@staticmethod
def from_data(data):
return KeyedEduRow(
key=tuple(data["key"]),
edu=Edu(**data["edu"]),
)
def to_data(self):
return {
"key": self.key,
"edu": self.edu.get_internal_dict(),
}
def add_to_buffer(self, buff):
buff.keyed_edus.setdefault(
self.edu.destination, {}
)[self.key] = self.edu
class EduRow(BaseFederationRow, namedtuple("EduRow", (
"edu", # Edu
))):
TypeId = "e"
@staticmethod
def from_data(data):
return EduRow(Edu(**data))
def to_data(self):
return self.edu.get_internal_dict()
def add_to_buffer(self, buff):
buff.edus.setdefault(self.edu.destination, []).append(self.edu)
class FailureRow(BaseFederationRow, namedtuple("FailureRow", (
"destination", # str
"failure",
))):
TypeId = "f"
@staticmethod
def from_data(data):
return FailureRow(
destination=data["destination"],
failure=data["failure"],
)
def to_data(self):
return {
"destination": self.destination,
"failure": self.failure,
}
def add_to_buffer(self, buff):
buff.failures.setdefault(self.destination, []).append(self.failure)
class DeviceRow(BaseFederationRow, namedtuple("DeviceRow", (
"destination", # str
))):
TypeId = "d"
@staticmethod
def from_data(data):
return DeviceRow(destination=data["destination"])
def to_data(self):
return {"destination": self.destination}
def add_to_buffer(self, buff):
buff.device_destinations.add(self.destination)
TypeToRow = {
Row.TypeId: Row
for Row in (
PresenceRow,
KeyedEduRow,
EduRow,
FailureRow,
DeviceRow,
)
}
ParsedFederationStreamData = namedtuple("ParsedFederationStreamData", (
"presence", # dict of destination -> [UserPresenceState]
"keyed_edus", # dict of destination -> { key -> Edu }
"edus", # dict of destination -> [Edu]
"failures", # dict of destination -> [failures]
"device_destinations", # set of destinations
))
def process_rows_for_federation(transaction_queue, rows):
"""Parse a list of rows from the federation stream and put them in the
transaction queue ready for sending to the relevant homeservers.
Args:
transaction_queue (TransactionQueue)
rows (list(synapse.replication.tcp.streams.FederationStreamRow))
"""
# The federation stream contains a bunch of different types of
# rows that need to be handled differently. We parse the rows, put
# them into the appropriate collection and then send them off.
buff = ParsedFederationStreamData(
presence={},
keyed_edus={},
edus={},
failures={},
device_destinations=set(),
)
# Parse the rows in the stream and add to the buffer
for row in rows:
if row.type not in TypeToRow:
logger.error("Unrecognized federation row type %r", row.type)
continue
RowType = TypeToRow[row.type]
parsed_row = RowType.from_data(row.data)
parsed_row.add_to_buffer(buff)
for destination, states in buff.presence.iteritems():
transaction_queue.send_presence(destination, states)
for destination, edu_map in buff.keyed_edus.iteritems():
for key, edu in edu_map.items():
transaction_queue.send_edu(
edu.destination, edu.edu_type, edu.content, key=key,
)
for destination, edu_list in buff.edus.iteritems():
for edu in edu_list:
transaction_queue.send_edu(
edu.destination, edu.edu_type, edu.content, key=None,
)
for destination, failure_list in buff.failures.iteritems():
for failure in failure_list:
transaction_queue.send_failure(destination, failure)
for destination in buff.device_destinations:
transaction_queue.send_device_messages(destination)