synapse-product/synapse/storage/databases/main/stream.py

1089 lines
38 KiB
Python

# -*- coding: utf-8 -*-
# Copyright 2014-2016 OpenMarket Ltd
# Copyright 2017 Vector Creations Ltd
# Copyright 2018-2019 New Vector Ltd
# Copyright 2019 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.
""" This module is responsible for getting events from the DB for pagination
and event streaming.
The order it returns events in depend on whether we are streaming forwards or
are paginating backwards. We do this because we want to handle out of order
messages nicely, while still returning them in the correct order when we
paginate bacwards.
This is implemented by keeping two ordering columns: stream_ordering and
topological_ordering. Stream ordering is basically insertion/received order
(except for events from backfill requests). The topological_ordering is a
weak ordering of events based on the pdu graph.
This means that we have to have two different types of tokens, depending on
what sort order was used:
- stream tokens are of the form: "s%d", which maps directly to the column
- topological tokems: "t%d-%d", where the integers map to the topological
and stream ordering columns respectively.
"""
import abc
import logging
from collections import namedtuple
from typing import Dict, Iterable, List, Optional, Tuple
from twisted.internet import defer
from synapse.api.filtering import Filter
from synapse.events import EventBase
from synapse.logging.context import make_deferred_yieldable, run_in_background
from synapse.storage._base import SQLBaseStore
from synapse.storage.database import DatabasePool, make_in_list_sql_clause
from synapse.storage.databases.main.events_worker import EventsWorkerStore
from synapse.storage.engines import BaseDatabaseEngine, PostgresEngine
from synapse.types import RoomStreamToken
from synapse.util.caches.stream_change_cache import StreamChangeCache
logger = logging.getLogger(__name__)
MAX_STREAM_SIZE = 1000
_STREAM_TOKEN = "stream"
_TOPOLOGICAL_TOKEN = "topological"
# Used as return values for pagination APIs
_EventDictReturn = namedtuple(
"_EventDictReturn", ("event_id", "topological_ordering", "stream_ordering")
)
def generate_pagination_where_clause(
direction: str,
column_names: Tuple[str, str],
from_token: Optional[Tuple[int, int]],
to_token: Optional[Tuple[int, int]],
engine: BaseDatabaseEngine,
) -> str:
"""Creates an SQL expression to bound the columns by the pagination
tokens.
For example creates an SQL expression like:
(6, 7) >= (topological_ordering, stream_ordering)
AND (5, 3) < (topological_ordering, stream_ordering)
would be generated for dir=b, from_token=(6, 7) and to_token=(5, 3).
Note that tokens are considered to be after the row they are in, e.g. if
a row A has a token T, then we consider A to be before T. This convention
is important when figuring out inequalities for the generated SQL, and
produces the following result:
- If paginating forwards then we exclude any rows matching the from
token, but include those that match the to token.
- If paginating backwards then we include any rows matching the from
token, but include those that match the to token.
Args:
direction: Whether we're paginating backwards("b") or forwards ("f").
column_names: The column names to bound. Must *not* be user defined as
these get inserted directly into the SQL statement without escapes.
from_token: The start point for the pagination. This is an exclusive
minimum bound if direction is "f", and an inclusive maximum bound if
direction is "b".
to_token: The endpoint point for the pagination. This is an inclusive
maximum bound if direction is "f", and an exclusive minimum bound if
direction is "b".
engine: The database engine to generate the clauses for
Returns:
The sql expression
"""
assert direction in ("b", "f")
where_clause = []
if from_token:
where_clause.append(
_make_generic_sql_bound(
bound=">=" if direction == "b" else "<",
column_names=column_names,
values=from_token,
engine=engine,
)
)
if to_token:
where_clause.append(
_make_generic_sql_bound(
bound="<" if direction == "b" else ">=",
column_names=column_names,
values=to_token,
engine=engine,
)
)
return " AND ".join(where_clause)
def _make_generic_sql_bound(
bound: str,
column_names: Tuple[str, str],
values: Tuple[Optional[int], int],
engine: BaseDatabaseEngine,
) -> str:
"""Create an SQL expression that bounds the given column names by the
values, e.g. create the equivalent of `(1, 2) < (col1, col2)`.
Only works with two columns.
Older versions of SQLite don't support that syntax so we have to expand it
out manually.
Args:
bound: The comparison operator to use. One of ">", "<", ">=",
"<=", where the values are on the left and columns on the right.
names: The column names. Must *not* be user defined
as these get inserted directly into the SQL statement without
escapes.
values: The values to bound the columns by. If
the first value is None then only creates a bound on the second
column.
engine: The database engine to generate the SQL for
Returns:
The SQL statement
"""
assert bound in (">", "<", ">=", "<=")
name1, name2 = column_names
val1, val2 = values
if val1 is None:
val2 = int(val2)
return "(%d %s %s)" % (val2, bound, name2)
val1 = int(val1)
val2 = int(val2)
if isinstance(engine, PostgresEngine):
# Postgres doesn't optimise ``(x < a) OR (x=a AND y<b)`` as well
# as it optimises ``(x,y) < (a,b)`` on multicolumn indexes. So we
# use the later form when running against postgres.
return "((%d,%d) %s (%s,%s))" % (val1, val2, bound, name1, name2)
# We want to generate queries of e.g. the form:
#
# (val1 < name1 OR (val1 = name1 AND val2 <= name2))
#
# which is equivalent to (val1, val2) < (name1, name2)
return """(
{val1:d} {strict_bound} {name1}
OR ({val1:d} = {name1} AND {val2:d} {bound} {name2})
)""".format(
name1=name1,
val1=val1,
name2=name2,
val2=val2,
strict_bound=bound[0], # The first bound must always be strict equality here
bound=bound,
)
def filter_to_clause(event_filter: Filter) -> Tuple[str, List[str]]:
# NB: This may create SQL clauses that don't optimise well (and we don't
# have indices on all possible clauses). E.g. it may create
# "room_id == X AND room_id != X", which postgres doesn't optimise.
if not event_filter:
return "", []
clauses = []
args = []
if event_filter.types:
clauses.append("(%s)" % " OR ".join("type = ?" for _ in event_filter.types))
args.extend(event_filter.types)
for typ in event_filter.not_types:
clauses.append("type != ?")
args.append(typ)
if event_filter.senders:
clauses.append("(%s)" % " OR ".join("sender = ?" for _ in event_filter.senders))
args.extend(event_filter.senders)
for sender in event_filter.not_senders:
clauses.append("sender != ?")
args.append(sender)
if event_filter.rooms:
clauses.append("(%s)" % " OR ".join("room_id = ?" for _ in event_filter.rooms))
args.extend(event_filter.rooms)
for room_id in event_filter.not_rooms:
clauses.append("room_id != ?")
args.append(room_id)
if event_filter.contains_url:
clauses.append("contains_url = ?")
args.append(event_filter.contains_url)
# We're only applying the "labels" filter on the database query, because applying the
# "not_labels" filter via a SQL query is non-trivial. Instead, we let
# event_filter.check_fields apply it, which is not as efficient but makes the
# implementation simpler.
if event_filter.labels:
clauses.append("(%s)" % " OR ".join("label = ?" for _ in event_filter.labels))
args.extend(event_filter.labels)
return " AND ".join(clauses), args
class StreamWorkerStore(EventsWorkerStore, SQLBaseStore):
"""This is an abstract base class where subclasses must implement
`get_room_max_stream_ordering` and `get_room_min_stream_ordering`
which can be called in the initializer.
"""
__metaclass__ = abc.ABCMeta
def __init__(self, database: DatabasePool, db_conn, hs):
super(StreamWorkerStore, self).__init__(database, db_conn, hs)
self._instance_name = hs.get_instance_name()
self._send_federation = hs.should_send_federation()
self._federation_shard_config = hs.config.worker.federation_shard_config
# If we're a process that sends federation we may need to reset the
# `federation_stream_position` table to match the current sharding
# config. We don't do this now as otherwise two processes could conflict
# during startup which would cause one to die.
self._need_to_reset_federation_stream_positions = self._send_federation
events_max = self.get_room_max_stream_ordering()
event_cache_prefill, min_event_val = self.db_pool.get_cache_dict(
db_conn,
"events",
entity_column="room_id",
stream_column="stream_ordering",
max_value=events_max,
)
self._events_stream_cache = StreamChangeCache(
"EventsRoomStreamChangeCache",
min_event_val,
prefilled_cache=event_cache_prefill,
)
self._membership_stream_cache = StreamChangeCache(
"MembershipStreamChangeCache", events_max
)
self._stream_order_on_start = self.get_room_max_stream_ordering()
@abc.abstractmethod
def get_room_max_stream_ordering(self):
raise NotImplementedError()
@abc.abstractmethod
def get_room_min_stream_ordering(self):
raise NotImplementedError()
async def get_room_events_stream_for_rooms(
self,
room_ids: Iterable[str],
from_key: str,
to_key: str,
limit: int = 0,
order: str = "DESC",
) -> Dict[str, Tuple[List[EventBase], str]]:
"""Get new room events in stream ordering since `from_key`.
Args:
room_ids
from_key: Token from which no events are returned before
to_key: Token from which no events are returned after. (This
is typically the current stream token)
limit: Maximum number of events to return
order: Either "DESC" or "ASC". Determines which events are
returned when the result is limited. If "DESC" then the most
recent `limit` events are returned, otherwise returns the
oldest `limit` events.
Returns:
A map from room id to a tuple containing:
- list of recent events in the room
- stream ordering key for the start of the chunk of events returned.
"""
from_id = RoomStreamToken.parse_stream_token(from_key).stream
room_ids = self._events_stream_cache.get_entities_changed(room_ids, from_id)
if not room_ids:
return {}
results = {}
room_ids = list(room_ids)
for rm_ids in (room_ids[i : i + 20] for i in range(0, len(room_ids), 20)):
res = await make_deferred_yieldable(
defer.gatherResults(
[
run_in_background(
self.get_room_events_stream_for_room,
room_id,
from_key,
to_key,
limit,
order=order,
)
for room_id in rm_ids
],
consumeErrors=True,
)
)
results.update(dict(zip(rm_ids, res)))
return results
def get_rooms_that_changed(self, room_ids, from_key):
"""Given a list of rooms and a token, return rooms where there may have
been changes.
Args:
room_ids (list)
from_key (str): The room_key portion of a StreamToken
"""
from_key = RoomStreamToken.parse_stream_token(from_key).stream
return {
room_id
for room_id in room_ids
if self._events_stream_cache.has_entity_changed(room_id, from_key)
}
async def get_room_events_stream_for_room(
self,
room_id: str,
from_key: str,
to_key: str,
limit: int = 0,
order: str = "DESC",
) -> Tuple[List[EventBase], str]:
"""Get new room events in stream ordering since `from_key`.
Args:
room_id
from_key: Token from which no events are returned before
to_key: Token from which no events are returned after. (This
is typically the current stream token)
limit: Maximum number of events to return
order: Either "DESC" or "ASC". Determines which events are
returned when the result is limited. If "DESC" then the most
recent `limit` events are returned, otherwise returns the
oldest `limit` events.
Returns:
The list of events (in ascending order) and the token from the start
of the chunk of events returned.
"""
if from_key == to_key:
return [], from_key
from_id = RoomStreamToken.parse_stream_token(from_key).stream
to_id = RoomStreamToken.parse_stream_token(to_key).stream
has_changed = self._events_stream_cache.has_entity_changed(room_id, from_id)
if not has_changed:
return [], from_key
def f(txn):
sql = (
"SELECT event_id, stream_ordering FROM events WHERE"
" room_id = ?"
" AND not outlier"
" AND stream_ordering > ? AND stream_ordering <= ?"
" ORDER BY stream_ordering %s LIMIT ?"
) % (order,)
txn.execute(sql, (room_id, from_id, to_id, limit))
rows = [_EventDictReturn(row[0], None, row[1]) for row in txn]
return rows
rows = await self.db_pool.runInteraction("get_room_events_stream_for_room", f)
ret = await self.get_events_as_list(
[r.event_id for r in rows], get_prev_content=True
)
self._set_before_and_after(ret, rows, topo_order=from_id is None)
if order.lower() == "desc":
ret.reverse()
if rows:
key = "s%d" % min(r.stream_ordering for r in rows)
else:
# Assume we didn't get anything because there was nothing to
# get.
key = from_key
return ret, key
async def get_membership_changes_for_user(self, user_id, from_key, to_key):
from_id = RoomStreamToken.parse_stream_token(from_key).stream
to_id = RoomStreamToken.parse_stream_token(to_key).stream
if from_key == to_key:
return []
if from_id:
has_changed = self._membership_stream_cache.has_entity_changed(
user_id, int(from_id)
)
if not has_changed:
return []
def f(txn):
sql = (
"SELECT m.event_id, stream_ordering FROM events AS e,"
" room_memberships AS m"
" WHERE e.event_id = m.event_id"
" AND m.user_id = ?"
" AND e.stream_ordering > ? AND e.stream_ordering <= ?"
" ORDER BY e.stream_ordering ASC"
)
txn.execute(sql, (user_id, from_id, to_id))
rows = [_EventDictReturn(row[0], None, row[1]) for row in txn]
return rows
rows = await self.db_pool.runInteraction("get_membership_changes_for_user", f)
ret = await self.get_events_as_list(
[r.event_id for r in rows], get_prev_content=True
)
self._set_before_and_after(ret, rows, topo_order=False)
return ret
async def get_recent_events_for_room(
self, room_id: str, limit: int, end_token: str
) -> Tuple[List[EventBase], str]:
"""Get the most recent events in the room in topological ordering.
Args:
room_id
limit
end_token: The stream token representing now.
Returns:
A list of events and a token pointing to the start of the returned
events. The events returned are in ascending order.
"""
rows, token = await self.get_recent_event_ids_for_room(
room_id, limit, end_token
)
events = await self.get_events_as_list(
[r.event_id for r in rows], get_prev_content=True
)
self._set_before_and_after(events, rows)
return (events, token)
async def get_recent_event_ids_for_room(
self, room_id: str, limit: int, end_token: str
) -> Tuple[List[_EventDictReturn], str]:
"""Get the most recent events in the room in topological ordering.
Args:
room_id
limit
end_token: The stream token representing now.
Returns:
A list of _EventDictReturn and a token pointing to the start of the
returned events. The events returned are in ascending order.
"""
# Allow a zero limit here, and no-op.
if limit == 0:
return [], end_token
end_token = RoomStreamToken.parse(end_token)
rows, token = await self.db_pool.runInteraction(
"get_recent_event_ids_for_room",
self._paginate_room_events_txn,
room_id,
from_token=end_token,
limit=limit,
)
# We want to return the results in ascending order.
rows.reverse()
return rows, token
def get_room_event_before_stream_ordering(self, room_id: str, stream_ordering: int):
"""Gets details of the first event in a room at or before a stream ordering
Args:
room_id:
stream_ordering:
Returns:
Deferred[(int, int, str)]:
(stream ordering, topological ordering, event_id)
"""
def _f(txn):
sql = (
"SELECT stream_ordering, topological_ordering, event_id"
" FROM events"
" WHERE room_id = ? AND stream_ordering <= ?"
" AND NOT outlier"
" ORDER BY stream_ordering DESC"
" LIMIT 1"
)
txn.execute(sql, (room_id, stream_ordering))
return txn.fetchone()
return self.db_pool.runInteraction("get_room_event_before_stream_ordering", _f)
async def get_room_events_max_id(self, room_id: Optional[str] = None) -> str:
"""Returns the current token for rooms stream.
By default, it returns the current global stream token. Specifying a
`room_id` causes it to return the current room specific topological
token.
"""
token = self.get_room_max_stream_ordering()
if room_id is None:
return "s%d" % (token,)
else:
topo = await self.db_pool.runInteraction(
"_get_max_topological_txn", self._get_max_topological_txn, room_id
)
return "t%d-%d" % (topo, token)
async def get_stream_id_for_event(self, event_id: str) -> int:
"""The stream ID for an event
Args:
event_id: The id of the event to look up a stream token for.
Raises:
StoreError if the event wasn't in the database.
Returns:
A stream ID.
"""
return await self.db_pool.simple_select_one_onecol(
table="events", keyvalues={"event_id": event_id}, retcol="stream_ordering"
)
async def get_stream_token_for_event(self, event_id: str) -> str:
"""The stream token for an event
Args:
event_id: The id of the event to look up a stream token for.
Raises:
StoreError if the event wasn't in the database.
Returns:
A "s%d" stream token.
"""
stream_id = await self.get_stream_id_for_event(event_id)
return "s%d" % (stream_id,)
async def get_topological_token_for_event(self, event_id: str) -> str:
"""The stream token for an event
Args:
event_id: The id of the event to look up a stream token for.
Raises:
StoreError if the event wasn't in the database.
Returns:
A "t%d-%d" topological token.
"""
row = await self.db_pool.simple_select_one(
table="events",
keyvalues={"event_id": event_id},
retcols=("stream_ordering", "topological_ordering"),
desc="get_topological_token_for_event",
)
return "t%d-%d" % (row["topological_ordering"], row["stream_ordering"])
async def get_max_topological_token(self, room_id: str, stream_key: int) -> int:
"""Get the max topological token in a room before the given stream
ordering.
Args:
room_id
stream_key
Returns:
The maximum topological token.
"""
sql = (
"SELECT coalesce(max(topological_ordering), 0) FROM events"
" WHERE room_id = ? AND stream_ordering < ?"
)
row = await self.db_pool.execute(
"get_max_topological_token", None, sql, room_id, stream_key
)
return row[0][0] if row else 0
def _get_max_topological_txn(self, txn, room_id):
txn.execute(
"SELECT MAX(topological_ordering) FROM events WHERE room_id = ?",
(room_id,),
)
rows = txn.fetchall()
return rows[0][0] if rows else 0
@staticmethod
def _set_before_and_after(
events: List[EventBase], rows: List[_EventDictReturn], topo_order: bool = True
):
"""Inserts ordering information to events' internal metadata from
the DB rows.
Args:
events
rows
topo_order: Whether the events were ordered topologically or by stream
ordering. If true then all rows should have a non null
topological_ordering.
"""
for event, row in zip(events, rows):
stream = row.stream_ordering
if topo_order and row.topological_ordering:
topo = row.topological_ordering
else:
topo = None
internal = event.internal_metadata
internal.before = str(RoomStreamToken(topo, stream - 1))
internal.after = str(RoomStreamToken(topo, stream))
internal.order = (int(topo) if topo else 0, int(stream))
async def get_events_around(
self,
room_id: str,
event_id: str,
before_limit: int,
after_limit: int,
event_filter: Optional[Filter] = None,
) -> dict:
"""Retrieve events and pagination tokens around a given event in a
room.
"""
results = await self.db_pool.runInteraction(
"get_events_around",
self._get_events_around_txn,
room_id,
event_id,
before_limit,
after_limit,
event_filter,
)
events_before = await self.get_events_as_list(
list(results["before"]["event_ids"]), get_prev_content=True
)
events_after = await self.get_events_as_list(
list(results["after"]["event_ids"]), get_prev_content=True
)
return {
"events_before": events_before,
"events_after": events_after,
"start": results["before"]["token"],
"end": results["after"]["token"],
}
def _get_events_around_txn(
self,
txn,
room_id: str,
event_id: str,
before_limit: int,
after_limit: int,
event_filter: Optional[Filter],
) -> dict:
"""Retrieves event_ids and pagination tokens around a given event in a
room.
Args:
room_id
event_id
before_limit
after_limit
event_filter
Returns:
dict
"""
results = self.db_pool.simple_select_one_txn(
txn,
"events",
keyvalues={"event_id": event_id, "room_id": room_id},
retcols=["stream_ordering", "topological_ordering"],
)
# Paginating backwards includes the event at the token, but paginating
# forward doesn't.
before_token = RoomStreamToken(
results["topological_ordering"] - 1, results["stream_ordering"]
)
after_token = RoomStreamToken(
results["topological_ordering"], results["stream_ordering"]
)
rows, start_token = self._paginate_room_events_txn(
txn,
room_id,
before_token,
direction="b",
limit=before_limit,
event_filter=event_filter,
)
events_before = [r.event_id for r in rows]
rows, end_token = self._paginate_room_events_txn(
txn,
room_id,
after_token,
direction="f",
limit=after_limit,
event_filter=event_filter,
)
events_after = [r.event_id for r in rows]
return {
"before": {"event_ids": events_before, "token": start_token},
"after": {"event_ids": events_after, "token": end_token},
}
async def get_all_new_events_stream(
self, from_id: int, current_id: int, limit: int
) -> Tuple[int, List[EventBase]]:
"""Get all new events
Returns all events with from_id < stream_ordering <= current_id.
Args:
from_id: the stream_ordering of the last event we processed
current_id: the stream_ordering of the most recently processed event
limit: the maximum number of events to return
Returns:
A tuple of (next_id, events), where `next_id` is the next value to
pass as `from_id` (it will either be the stream_ordering of the
last returned event, or, if fewer than `limit` events were found,
the `current_id`).
"""
def get_all_new_events_stream_txn(txn):
sql = (
"SELECT e.stream_ordering, e.event_id"
" FROM events AS e"
" WHERE"
" ? < e.stream_ordering AND e.stream_ordering <= ?"
" ORDER BY e.stream_ordering ASC"
" LIMIT ?"
)
txn.execute(sql, (from_id, current_id, limit))
rows = txn.fetchall()
upper_bound = current_id
if len(rows) == limit:
upper_bound = rows[-1][0]
return upper_bound, [row[1] for row in rows]
upper_bound, event_ids = await self.db_pool.runInteraction(
"get_all_new_events_stream", get_all_new_events_stream_txn
)
events = await self.get_events_as_list(event_ids)
return upper_bound, events
async def get_federation_out_pos(self, typ: str) -> int:
if self._need_to_reset_federation_stream_positions:
await self.db_pool.runInteraction(
"_reset_federation_positions_txn", self._reset_federation_positions_txn
)
self._need_to_reset_federation_stream_positions = False
return await self.db_pool.simple_select_one_onecol(
table="federation_stream_position",
retcol="stream_id",
keyvalues={"type": typ, "instance_name": self._instance_name},
desc="get_federation_out_pos",
)
async def update_federation_out_pos(self, typ: str, stream_id: int) -> None:
if self._need_to_reset_federation_stream_positions:
await self.db_pool.runInteraction(
"_reset_federation_positions_txn", self._reset_federation_positions_txn
)
self._need_to_reset_federation_stream_positions = False
await self.db_pool.simple_update_one(
table="federation_stream_position",
keyvalues={"type": typ, "instance_name": self._instance_name},
updatevalues={"stream_id": stream_id},
desc="update_federation_out_pos",
)
def _reset_federation_positions_txn(self, txn) -> None:
"""Fiddles with the `federation_stream_position` table to make it match
the configured federation sender instances during start up.
"""
# The federation sender instances may have changed, so we need to
# massage the `federation_stream_position` table to have a row per type
# per instance sending federation. If there is a mismatch we update the
# table with the correct rows using the *minimum* stream ID seen. This
# may result in resending of events/EDUs to remote servers, but that is
# preferable to dropping them.
if not self._send_federation:
return
# Pull out the configured instances. If we don't have a shard config then
# we assume that we're the only instance sending.
configured_instances = self._federation_shard_config.instances
if not configured_instances:
configured_instances = [self._instance_name]
elif self._instance_name not in configured_instances:
return
instances_in_table = self.db_pool.simple_select_onecol_txn(
txn,
table="federation_stream_position",
keyvalues={},
retcol="instance_name",
)
if set(instances_in_table) == set(configured_instances):
# Nothing to do
return
sql = """
SELECT type, MIN(stream_id) FROM federation_stream_position
GROUP BY type
"""
txn.execute(sql)
min_positions = dict(txn) # Map from type -> min position
# Ensure we do actually have some values here
assert set(min_positions) == {"federation", "events"}
sql = """
DELETE FROM federation_stream_position
WHERE NOT (%s)
"""
clause, args = make_in_list_sql_clause(
txn.database_engine, "instance_name", configured_instances
)
txn.execute(sql % (clause,), args)
for typ, stream_id in min_positions.items():
self.db_pool.simple_upsert_txn(
txn,
table="federation_stream_position",
keyvalues={"type": typ, "instance_name": self._instance_name},
values={"stream_id": stream_id},
)
def has_room_changed_since(self, room_id: str, stream_id: int) -> bool:
return self._events_stream_cache.has_entity_changed(room_id, stream_id)
def _paginate_room_events_txn(
self,
txn,
room_id: str,
from_token: RoomStreamToken,
to_token: Optional[RoomStreamToken] = None,
direction: str = "b",
limit: int = -1,
event_filter: Optional[Filter] = None,
) -> Tuple[List[_EventDictReturn], str]:
"""Returns list of events before or after a given token.
Args:
txn
room_id
from_token: The token used to stream from
to_token: A token which if given limits the results to only those before
direction: Either 'b' or 'f' to indicate whether we are paginating
forwards or backwards from `from_key`.
limit: The maximum number of events to return.
event_filter: If provided filters the events to
those that match the filter.
Returns:
A list of _EventDictReturn and a token that points to the end of the
result set. If no events are returned then the end of the stream has
been reached (i.e. there are no events between `from_token` and
`to_token`), or `limit` is zero.
"""
assert int(limit) >= 0
# Tokens really represent positions between elements, but we use
# the convention of pointing to the event before the gap. Hence
# we have a bit of asymmetry when it comes to equalities.
args = [False, room_id]
if direction == "b":
order = "DESC"
else:
order = "ASC"
bounds = generate_pagination_where_clause(
direction=direction,
column_names=("topological_ordering", "stream_ordering"),
from_token=from_token,
to_token=to_token,
engine=self.database_engine,
)
filter_clause, filter_args = filter_to_clause(event_filter)
if filter_clause:
bounds += " AND " + filter_clause
args.extend(filter_args)
args.append(int(limit))
select_keywords = "SELECT"
join_clause = ""
if event_filter and event_filter.labels:
# If we're not filtering on a label, then joining on event_labels will
# return as many row for a single event as the number of labels it has. To
# avoid this, only join if we're filtering on at least one label.
join_clause = """
LEFT JOIN event_labels
USING (event_id, room_id, topological_ordering)
"""
if len(event_filter.labels) > 1:
# Using DISTINCT in this SELECT query is quite expensive, because it
# requires the engine to sort on the entire (not limited) result set,
# i.e. the entire events table. We only need to use it when we're
# filtering on more than two labels, because that's the only scenario
# in which we can possibly to get multiple times the same event ID in
# the results.
select_keywords += "DISTINCT"
sql = """
%(select_keywords)s event_id, topological_ordering, stream_ordering
FROM events
%(join_clause)s
WHERE outlier = ? AND room_id = ? AND %(bounds)s
ORDER BY topological_ordering %(order)s,
stream_ordering %(order)s LIMIT ?
""" % {
"select_keywords": select_keywords,
"join_clause": join_clause,
"bounds": bounds,
"order": order,
}
txn.execute(sql, args)
rows = [_EventDictReturn(row[0], row[1], row[2]) for row in txn]
if rows:
topo = rows[-1].topological_ordering
toke = rows[-1].stream_ordering
if direction == "b":
# Tokens are positions between events.
# This token points *after* the last event in the chunk.
# We need it to point to the event before it in the chunk
# when we are going backwards so we subtract one from the
# stream part.
toke -= 1
next_token = RoomStreamToken(topo, toke)
else:
# TODO (erikj): We should work out what to do here instead.
next_token = to_token if to_token else from_token
return rows, str(next_token)
async def paginate_room_events(
self,
room_id: str,
from_key: str,
to_key: Optional[str] = None,
direction: str = "b",
limit: int = -1,
event_filter: Optional[Filter] = None,
) -> Tuple[List[EventBase], str]:
"""Returns list of events before or after a given token.
Args:
room_id
from_key: The token used to stream from
to_key: A token which if given limits the results to only those before
direction: Either 'b' or 'f' to indicate whether we are paginating
forwards or backwards from `from_key`.
limit: The maximum number of events to return.
event_filter: If provided filters the events to those that match the filter.
Returns:
The results as a list of events and a token that points to the end
of the result set. If no events are returned then the end of the
stream has been reached (i.e. there are no events between `from_key`
and `to_key`).
"""
from_key = RoomStreamToken.parse(from_key)
if to_key:
to_key = RoomStreamToken.parse(to_key)
rows, token = await self.db_pool.runInteraction(
"paginate_room_events",
self._paginate_room_events_txn,
room_id,
from_key,
to_key,
direction,
limit,
event_filter,
)
events = await self.get_events_as_list(
[r.event_id for r in rows], get_prev_content=True
)
self._set_before_and_after(events, rows)
return (events, token)
class StreamStore(StreamWorkerStore):
def get_room_max_stream_ordering(self) -> int:
return self._stream_id_gen.get_current_token()
def get_room_min_stream_ordering(self) -> int:
return self._backfill_id_gen.get_current_token()