Split state groups into a separate data store (#6296)

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Erik Johnston 2019-12-20 10:48:24 +00:00 committed by GitHub
parent fa780e9721
commit 75d8f26ac8
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28 changed files with 1159 additions and 1168 deletions

1
changelog.d/6245.misc Normal file
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@ -0,0 +1 @@
Split out state storage into separate data store.

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@ -51,11 +51,12 @@ from synapse.storage.data_stores.main.registration import (
from synapse.storage.data_stores.main.room import RoomBackgroundUpdateStore
from synapse.storage.data_stores.main.roommember import RoomMemberBackgroundUpdateStore
from synapse.storage.data_stores.main.search import SearchBackgroundUpdateStore
from synapse.storage.data_stores.main.state import StateBackgroundUpdateStore
from synapse.storage.data_stores.main.state import MainStateBackgroundUpdateStore
from synapse.storage.data_stores.main.stats import StatsStore
from synapse.storage.data_stores.main.user_directory import (
UserDirectoryBackgroundUpdateStore,
)
from synapse.storage.data_stores.state.bg_updates import StateBackgroundUpdateStore
from synapse.storage.database import Database, make_conn
from synapse.storage.engines import create_engine
from synapse.storage.prepare_database import prepare_database
@ -138,6 +139,7 @@ class Store(
RoomMemberBackgroundUpdateStore,
SearchBackgroundUpdateStore,
StateBackgroundUpdateStore,
MainStateBackgroundUpdateStore,
UserDirectoryBackgroundUpdateStore,
StatsStore,
):
@ -496,9 +498,7 @@ class Porter(object):
def run(self):
try:
self.sqlite_store = yield self.build_db_store(
DatabaseConnectionConfig(
"master", self.sqlite_config, data_stores=["main"]
)
DatabaseConnectionConfig("master-sqlite", self.sqlite_config)
)
# Check if all background updates are done, abort if not.

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@ -34,10 +34,12 @@ class DatabaseConnectionConfig:
module name, and `args` for the args to give to the database
connector.
data_stores: The list of data stores that should be provisioned on the
database.
database. Defaults to all data stores.
"""
def __init__(self, name: str, db_config: dict, data_stores: List[str]):
def __init__(
self, name: str, db_config: dict, data_stores: List[str] = ["main", "state"]
):
if db_config["name"] not in ("sqlite3", "psycopg2"):
raise ConfigError("Unsupported database type %r" % (db_config["name"],))
@ -62,9 +64,7 @@ class DatabaseConfig(Config):
if database_config is None:
database_config = {"name": "sqlite3", "args": {}}
self.databases = [
DatabaseConnectionConfig("master", database_config, data_stores=["main"])
]
self.databases = [DatabaseConnectionConfig("master", database_config)]
self.set_databasepath(config.get("database_path"))

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@ -15,6 +15,7 @@
import logging
from synapse.storage.data_stores.state import StateGroupDataStore
from synapse.storage.database import Database, make_conn
from synapse.storage.engines import create_engine
from synapse.storage.prepare_database import prepare_database
@ -55,6 +56,10 @@ class DataStores(object):
logger.info("Starting 'main' data store")
self.main = main_store_class(database, db_conn, hs)
if "state" in database_config.data_stores:
logger.info("Starting 'state' data store")
self.state = StateGroupDataStore(database, db_conn, hs)
db_conn.commit()
self.databases.append(database)

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@ -1757,163 +1757,6 @@ class EventsStore(
return state_groups
def purge_unreferenced_state_groups(
self, room_id: str, state_groups_to_delete
) -> defer.Deferred:
"""Deletes no longer referenced state groups and de-deltas any state
groups that reference them.
Args:
room_id: The room the state groups belong to (must all be in the
same room).
state_groups_to_delete (Collection[int]): Set of all state groups
to delete.
"""
return self.db.runInteraction(
"purge_unreferenced_state_groups",
self._purge_unreferenced_state_groups,
room_id,
state_groups_to_delete,
)
def _purge_unreferenced_state_groups(self, txn, room_id, state_groups_to_delete):
logger.info(
"[purge] found %i state groups to delete", len(state_groups_to_delete)
)
rows = self.db.simple_select_many_txn(
txn,
table="state_group_edges",
column="prev_state_group",
iterable=state_groups_to_delete,
keyvalues={},
retcols=("state_group",),
)
remaining_state_groups = set(
row["state_group"]
for row in rows
if row["state_group"] not in state_groups_to_delete
)
logger.info(
"[purge] de-delta-ing %i remaining state groups",
len(remaining_state_groups),
)
# Now we turn the state groups that reference to-be-deleted state
# groups to non delta versions.
for sg in remaining_state_groups:
logger.info("[purge] de-delta-ing remaining state group %s", sg)
curr_state = self._get_state_groups_from_groups_txn(txn, [sg])
curr_state = curr_state[sg]
self.db.simple_delete_txn(
txn, table="state_groups_state", keyvalues={"state_group": sg}
)
self.db.simple_delete_txn(
txn, table="state_group_edges", keyvalues={"state_group": sg}
)
self.db.simple_insert_many_txn(
txn,
table="state_groups_state",
values=[
{
"state_group": sg,
"room_id": room_id,
"type": key[0],
"state_key": key[1],
"event_id": state_id,
}
for key, state_id in iteritems(curr_state)
],
)
logger.info("[purge] removing redundant state groups")
txn.executemany(
"DELETE FROM state_groups_state WHERE state_group = ?",
((sg,) for sg in state_groups_to_delete),
)
txn.executemany(
"DELETE FROM state_groups WHERE id = ?",
((sg,) for sg in state_groups_to_delete),
)
@defer.inlineCallbacks
def get_previous_state_groups(self, state_groups):
"""Fetch the previous groups of the given state groups.
Args:
state_groups (Iterable[int])
Returns:
Deferred[dict[int, int]]: mapping from state group to previous
state group.
"""
rows = yield self.db.simple_select_many_batch(
table="state_group_edges",
column="prev_state_group",
iterable=state_groups,
keyvalues={},
retcols=("prev_state_group", "state_group"),
desc="get_previous_state_groups",
)
return {row["state_group"]: row["prev_state_group"] for row in rows}
def purge_room_state(self, room_id, state_groups_to_delete):
"""Deletes all record of a room from state tables
Args:
room_id (str):
state_groups_to_delete (list[int]): State groups to delete
"""
return self.db.runInteraction(
"purge_room_state",
self._purge_room_state_txn,
room_id,
state_groups_to_delete,
)
def _purge_room_state_txn(self, txn, room_id, state_groups_to_delete):
# first we have to delete the state groups states
logger.info("[purge] removing %s from state_groups_state", room_id)
self.db.simple_delete_many_txn(
txn,
table="state_groups_state",
column="state_group",
iterable=state_groups_to_delete,
keyvalues={},
)
# ... and the state group edges
logger.info("[purge] removing %s from state_group_edges", room_id)
self.db.simple_delete_many_txn(
txn,
table="state_group_edges",
column="state_group",
iterable=state_groups_to_delete,
keyvalues={},
)
# ... and the state groups
logger.info("[purge] removing %s from state_groups", room_id)
self.db.simple_delete_many_txn(
txn,
table="state_groups",
column="id",
iterable=state_groups_to_delete,
keyvalues={},
)
async def is_event_after(self, event_id1, event_id2):
"""Returns True if event_id1 is after event_id2 in the stream
"""

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@ -20,7 +20,6 @@ DROP INDEX IF EXISTS events_room_id; -- Prefix of events_room_stream
DROP INDEX IF EXISTS events_order; -- Prefix of events_order_topo_stream_room
DROP INDEX IF EXISTS events_topological_ordering; -- Prefix of events_order_topo_stream_room
DROP INDEX IF EXISTS events_stream_ordering; -- Duplicate of PRIMARY KEY
DROP INDEX IF EXISTS state_groups_id; -- Duplicate of PRIMARY KEY
DROP INDEX IF EXISTS event_to_state_groups_id; -- Duplicate of PRIMARY KEY
DROP INDEX IF EXISTS event_push_actions_room_id_event_id_user_id_profile_tag; -- Duplicate of UNIQUE CONSTRAINT

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@ -975,40 +975,6 @@ CREATE TABLE state_events (
CREATE TABLE state_group_edges (
state_group bigint NOT NULL,
prev_state_group bigint NOT NULL
);
CREATE SEQUENCE state_group_id_seq
START WITH 1
INCREMENT BY 1
NO MINVALUE
NO MAXVALUE
CACHE 1;
CREATE TABLE state_groups (
id bigint NOT NULL,
room_id text NOT NULL,
event_id text NOT NULL
);
CREATE TABLE state_groups_state (
state_group bigint NOT NULL,
room_id text NOT NULL,
type text NOT NULL,
state_key text NOT NULL,
event_id text NOT NULL
);
CREATE TABLE stats_stream_pos (
lock character(1) DEFAULT 'X'::bpchar NOT NULL,
stream_id bigint,
@ -1482,12 +1448,6 @@ ALTER TABLE ONLY state_events
ADD CONSTRAINT state_events_event_id_key UNIQUE (event_id);
ALTER TABLE ONLY state_groups
ADD CONSTRAINT state_groups_pkey PRIMARY KEY (id);
ALTER TABLE ONLY stats_stream_pos
ADD CONSTRAINT stats_stream_pos_lock_key UNIQUE (lock);
@ -1928,18 +1888,6 @@ CREATE UNIQUE INDEX room_stats_room_ts ON room_stats USING btree (room_id, ts);
CREATE INDEX state_group_edges_idx ON state_group_edges USING btree (state_group);
CREATE INDEX state_group_edges_prev_idx ON state_group_edges USING btree (prev_state_group);
CREATE INDEX state_groups_state_type_idx ON state_groups_state USING btree (state_group, type, state_key);
CREATE INDEX stream_ordering_to_exterm_idx ON stream_ordering_to_exterm USING btree (stream_ordering);

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@ -42,8 +42,6 @@ CREATE INDEX ev_edges_id ON event_edges(event_id);
CREATE INDEX ev_edges_prev_id ON event_edges(prev_event_id);
CREATE TABLE room_depth( room_id TEXT NOT NULL, min_depth INTEGER NOT NULL, UNIQUE (room_id) );
CREATE INDEX room_depth_room ON room_depth(room_id);
CREATE TABLE state_groups( id BIGINT PRIMARY KEY, room_id TEXT NOT NULL, event_id TEXT NOT NULL );
CREATE TABLE state_groups_state( state_group BIGINT NOT NULL, room_id TEXT NOT NULL, type TEXT NOT NULL, state_key TEXT NOT NULL, event_id TEXT NOT NULL );
CREATE TABLE event_to_state_groups( event_id TEXT NOT NULL, state_group BIGINT NOT NULL, UNIQUE (event_id) );
CREATE TABLE local_media_repository ( media_id TEXT, media_type TEXT, media_length INTEGER, created_ts BIGINT, upload_name TEXT, user_id TEXT, quarantined_by TEXT, url_cache TEXT, last_access_ts BIGINT, UNIQUE (media_id) );
CREATE TABLE local_media_repository_thumbnails ( media_id TEXT, thumbnail_width INTEGER, thumbnail_height INTEGER, thumbnail_type TEXT, thumbnail_method TEXT, thumbnail_length INTEGER, UNIQUE ( media_id, thumbnail_width, thumbnail_height, thumbnail_type ) );
@ -120,9 +118,6 @@ CREATE TABLE device_max_stream_id ( stream_id BIGINT NOT NULL );
CREATE TABLE public_room_list_stream ( stream_id BIGINT NOT NULL, room_id TEXT NOT NULL, visibility BOOLEAN NOT NULL , appservice_id TEXT, network_id TEXT);
CREATE INDEX public_room_list_stream_idx on public_room_list_stream( stream_id );
CREATE INDEX public_room_list_stream_rm_idx on public_room_list_stream( room_id, stream_id );
CREATE TABLE state_group_edges( state_group BIGINT NOT NULL, prev_state_group BIGINT NOT NULL );
CREATE INDEX state_group_edges_idx ON state_group_edges(state_group);
CREATE INDEX state_group_edges_prev_idx ON state_group_edges(prev_state_group);
CREATE TABLE stream_ordering_to_exterm ( stream_ordering BIGINT NOT NULL, room_id TEXT NOT NULL, event_id TEXT NOT NULL );
CREATE INDEX stream_ordering_to_exterm_idx on stream_ordering_to_exterm( stream_ordering );
CREATE INDEX stream_ordering_to_exterm_rm_idx on stream_ordering_to_exterm( room_id, stream_ordering );
@ -254,6 +249,5 @@ CREATE INDEX user_ips_last_seen_only ON user_ips (last_seen);
CREATE INDEX users_creation_ts ON users (creation_ts);
CREATE INDEX event_to_state_groups_sg_index ON event_to_state_groups (state_group);
CREATE UNIQUE INDEX device_lists_remote_cache_unique_id ON device_lists_remote_cache (user_id, device_id);
CREATE INDEX state_groups_state_type_idx ON state_groups_state(state_group, type, state_key);
CREATE UNIQUE INDEX device_lists_remote_extremeties_unique_idx ON device_lists_remote_extremeties (user_id);
CREATE UNIQUE INDEX user_ips_user_token_ip_unique_index ON user_ips (user_id, access_token, ip);

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@ -17,8 +17,7 @@ import logging
from collections import namedtuple
from typing import Iterable, Tuple
from six import iteritems, itervalues
from six.moves import range
from six import iteritems
from twisted.internet import defer
@ -29,11 +28,9 @@ from synapse.events.snapshot import EventContext
from synapse.storage._base import SQLBaseStore
from synapse.storage.data_stores.main.events_worker import EventsWorkerStore
from synapse.storage.database import Database
from synapse.storage.engines import PostgresEngine
from synapse.storage.state import StateFilter
from synapse.util.caches import get_cache_factor_for, intern_string
from synapse.util.caches import intern_string
from synapse.util.caches.descriptors import cached, cachedList
from synapse.util.caches.dictionary_cache import DictionaryCache
from synapse.util.stringutils import to_ascii
logger = logging.getLogger(__name__)
@ -55,207 +52,14 @@ class _GetStateGroupDelta(
return len(self.delta_ids) if self.delta_ids else 0
class StateGroupBackgroundUpdateStore(SQLBaseStore):
"""Defines functions related to state groups needed to run the state backgroud
updates.
"""
def _count_state_group_hops_txn(self, txn, state_group):
"""Given a state group, count how many hops there are in the tree.
This is used to ensure the delta chains don't get too long.
"""
if isinstance(self.database_engine, PostgresEngine):
sql = """
WITH RECURSIVE state(state_group) AS (
VALUES(?::bigint)
UNION ALL
SELECT prev_state_group FROM state_group_edges e, state s
WHERE s.state_group = e.state_group
)
SELECT count(*) FROM state;
"""
txn.execute(sql, (state_group,))
row = txn.fetchone()
if row and row[0]:
return row[0]
else:
return 0
else:
# We don't use WITH RECURSIVE on sqlite3 as there are distributions
# that ship with an sqlite3 version that doesn't support it (e.g. wheezy)
next_group = state_group
count = 0
while next_group:
next_group = self.db.simple_select_one_onecol_txn(
txn,
table="state_group_edges",
keyvalues={"state_group": next_group},
retcol="prev_state_group",
allow_none=True,
)
if next_group:
count += 1
return count
def _get_state_groups_from_groups_txn(
self, txn, groups, state_filter=StateFilter.all()
):
results = {group: {} for group in groups}
where_clause, where_args = state_filter.make_sql_filter_clause()
# Unless the filter clause is empty, we're going to append it after an
# existing where clause
if where_clause:
where_clause = " AND (%s)" % (where_clause,)
if isinstance(self.database_engine, PostgresEngine):
# Temporarily disable sequential scans in this transaction. This is
# a temporary hack until we can add the right indices in
txn.execute("SET LOCAL enable_seqscan=off")
# The below query walks the state_group tree so that the "state"
# table includes all state_groups in the tree. It then joins
# against `state_groups_state` to fetch the latest state.
# It assumes that previous state groups are always numerically
# lesser.
# The PARTITION is used to get the event_id in the greatest state
# group for the given type, state_key.
# This may return multiple rows per (type, state_key), but last_value
# should be the same.
sql = """
WITH RECURSIVE state(state_group) AS (
VALUES(?::bigint)
UNION ALL
SELECT prev_state_group FROM state_group_edges e, state s
WHERE s.state_group = e.state_group
)
SELECT DISTINCT type, state_key, last_value(event_id) OVER (
PARTITION BY type, state_key ORDER BY state_group ASC
ROWS BETWEEN UNBOUNDED PRECEDING AND UNBOUNDED FOLLOWING
) AS event_id FROM state_groups_state
WHERE state_group IN (
SELECT state_group FROM state
)
"""
for group in groups:
args = [group]
args.extend(where_args)
txn.execute(sql + where_clause, args)
for row in txn:
typ, state_key, event_id = row
key = (typ, state_key)
results[group][key] = event_id
else:
max_entries_returned = state_filter.max_entries_returned()
# We don't use WITH RECURSIVE on sqlite3 as there are distributions
# that ship with an sqlite3 version that doesn't support it (e.g. wheezy)
for group in groups:
next_group = group
while next_group:
# We did this before by getting the list of group ids, and
# then passing that list to sqlite to get latest event for
# each (type, state_key). However, that was terribly slow
# without the right indices (which we can't add until
# after we finish deduping state, which requires this func)
args = [next_group]
args.extend(where_args)
txn.execute(
"SELECT type, state_key, event_id FROM state_groups_state"
" WHERE state_group = ? " + where_clause,
args,
)
results[group].update(
((typ, state_key), event_id)
for typ, state_key, event_id in txn
if (typ, state_key) not in results[group]
)
# If the number of entries in the (type,state_key)->event_id dict
# matches the number of (type,state_keys) types we were searching
# for, then we must have found them all, so no need to go walk
# further down the tree... UNLESS our types filter contained
# wildcards (i.e. Nones) in which case we have to do an exhaustive
# search
if (
max_entries_returned is not None
and len(results[group]) == max_entries_returned
):
break
next_group = self.db.simple_select_one_onecol_txn(
txn,
table="state_group_edges",
keyvalues={"state_group": next_group},
retcol="prev_state_group",
allow_none=True,
)
return results
# this inherits from EventsWorkerStore because it calls self.get_events
class StateGroupWorkerStore(
EventsWorkerStore, StateGroupBackgroundUpdateStore, SQLBaseStore
):
class StateGroupWorkerStore(EventsWorkerStore, SQLBaseStore):
"""The parts of StateGroupStore that can be called from workers.
"""
STATE_GROUP_DEDUPLICATION_UPDATE_NAME = "state_group_state_deduplication"
STATE_GROUP_INDEX_UPDATE_NAME = "state_group_state_type_index"
CURRENT_STATE_INDEX_UPDATE_NAME = "current_state_members_idx"
def __init__(self, database: Database, db_conn, hs):
super(StateGroupWorkerStore, self).__init__(database, db_conn, hs)
# Originally the state store used a single DictionaryCache to cache the
# event IDs for the state types in a given state group to avoid hammering
# on the state_group* tables.
#
# The point of using a DictionaryCache is that it can cache a subset
# of the state events for a given state group (i.e. a subset of the keys for a
# given dict which is an entry in the cache for a given state group ID).
#
# However, this poses problems when performing complicated queries
# on the store - for instance: "give me all the state for this group, but
# limit members to this subset of users", as DictionaryCache's API isn't
# rich enough to say "please cache any of these fields, apart from this subset".
# This is problematic when lazy loading members, which requires this behaviour,
# as without it the cache has no choice but to speculatively load all
# state events for the group, which negates the efficiency being sought.
#
# Rather than overcomplicating DictionaryCache's API, we instead split the
# state_group_cache into two halves - one for tracking non-member events,
# and the other for tracking member_events. This means that lazy loading
# queries can be made in a cache-friendly manner by querying both caches
# separately and then merging the result. So for the example above, you
# would query the members cache for a specific subset of state keys
# (which DictionaryCache will handle efficiently and fine) and the non-members
# cache for all state (which DictionaryCache will similarly handle fine)
# and then just merge the results together.
#
# We size the non-members cache to be smaller than the members cache as the
# vast majority of state in Matrix (today) is member events.
self._state_group_cache = DictionaryCache(
"*stateGroupCache*",
# TODO: this hasn't been tuned yet
50000 * get_cache_factor_for("stateGroupCache"),
)
self._state_group_members_cache = DictionaryCache(
"*stateGroupMembersCache*",
500000 * get_cache_factor_for("stateGroupMembersCache"),
)
@defer.inlineCallbacks
def get_room_version(self, room_id):
"""Get the room_version of a given room
@ -431,229 +235,6 @@ class StateGroupWorkerStore(
return event.content.get("canonical_alias")
@cached(max_entries=10000, iterable=True)
def get_state_group_delta(self, state_group):
"""Given a state group try to return a previous group and a delta between
the old and the new.
Returns:
(prev_group, delta_ids), where both may be None.
"""
def _get_state_group_delta_txn(txn):
prev_group = self.db.simple_select_one_onecol_txn(
txn,
table="state_group_edges",
keyvalues={"state_group": state_group},
retcol="prev_state_group",
allow_none=True,
)
if not prev_group:
return _GetStateGroupDelta(None, None)
delta_ids = self.db.simple_select_list_txn(
txn,
table="state_groups_state",
keyvalues={"state_group": state_group},
retcols=("type", "state_key", "event_id"),
)
return _GetStateGroupDelta(
prev_group,
{(row["type"], row["state_key"]): row["event_id"] for row in delta_ids},
)
return self.db.runInteraction(
"get_state_group_delta", _get_state_group_delta_txn
)
@defer.inlineCallbacks
def get_state_groups_ids(self, _room_id, event_ids):
"""Get the event IDs of all the state for the state groups for the given events
Args:
_room_id (str): id of the room for these events
event_ids (iterable[str]): ids of the events
Returns:
Deferred[dict[int, dict[tuple[str, str], str]]]:
dict of state_group_id -> (dict of (type, state_key) -> event id)
"""
if not event_ids:
return {}
event_to_groups = yield self._get_state_group_for_events(event_ids)
groups = set(itervalues(event_to_groups))
group_to_state = yield self._get_state_for_groups(groups)
return group_to_state
@defer.inlineCallbacks
def get_state_ids_for_group(self, state_group):
"""Get the event IDs of all the state in the given state group
Args:
state_group (int)
Returns:
Deferred[dict]: Resolves to a map of (type, state_key) -> event_id
"""
group_to_state = yield self._get_state_for_groups((state_group,))
return group_to_state[state_group]
@defer.inlineCallbacks
def get_state_groups(self, room_id, event_ids):
""" Get the state groups for the given list of event_ids
Returns:
Deferred[dict[int, list[EventBase]]]:
dict of state_group_id -> list of state events.
"""
if not event_ids:
return {}
group_to_ids = yield self.get_state_groups_ids(room_id, event_ids)
state_event_map = yield self.get_events(
[
ev_id
for group_ids in itervalues(group_to_ids)
for ev_id in itervalues(group_ids)
],
get_prev_content=False,
)
return {
group: [
state_event_map[v]
for v in itervalues(event_id_map)
if v in state_event_map
]
for group, event_id_map in iteritems(group_to_ids)
}
@defer.inlineCallbacks
def _get_state_groups_from_groups(self, groups, state_filter):
"""Returns the state groups for a given set of groups, filtering on
types of state events.
Args:
groups(list[int]): list of state group IDs to query
state_filter (StateFilter): The state filter used to fetch state
from the database.
Returns:
Deferred[dict[int, dict[tuple[str, str], str]]]:
dict of state_group_id -> (dict of (type, state_key) -> event id)
"""
results = {}
chunks = [groups[i : i + 100] for i in range(0, len(groups), 100)]
for chunk in chunks:
res = yield self.db.runInteraction(
"_get_state_groups_from_groups",
self._get_state_groups_from_groups_txn,
chunk,
state_filter,
)
results.update(res)
return results
@defer.inlineCallbacks
def get_state_for_events(self, event_ids, state_filter=StateFilter.all()):
"""Given a list of event_ids and type tuples, return a list of state
dicts for each event.
Args:
event_ids (list[string])
state_filter (StateFilter): The state filter used to fetch state
from the database.
Returns:
deferred: A dict of (event_id) -> (type, state_key) -> [state_events]
"""
event_to_groups = yield self._get_state_group_for_events(event_ids)
groups = set(itervalues(event_to_groups))
group_to_state = yield self._get_state_for_groups(groups, state_filter)
state_event_map = yield self.get_events(
[ev_id for sd in itervalues(group_to_state) for ev_id in itervalues(sd)],
get_prev_content=False,
)
event_to_state = {
event_id: {
k: state_event_map[v]
for k, v in iteritems(group_to_state[group])
if v in state_event_map
}
for event_id, group in iteritems(event_to_groups)
}
return {event: event_to_state[event] for event in event_ids}
@defer.inlineCallbacks
def get_state_ids_for_events(self, event_ids, state_filter=StateFilter.all()):
"""
Get the state dicts corresponding to a list of events, containing the event_ids
of the state events (as opposed to the events themselves)
Args:
event_ids(list(str)): events whose state should be returned
state_filter (StateFilter): The state filter used to fetch state
from the database.
Returns:
A deferred dict from event_id -> (type, state_key) -> event_id
"""
event_to_groups = yield self._get_state_group_for_events(event_ids)
groups = set(itervalues(event_to_groups))
group_to_state = yield self._get_state_for_groups(groups, state_filter)
event_to_state = {
event_id: group_to_state[group]
for event_id, group in iteritems(event_to_groups)
}
return {event: event_to_state[event] for event in event_ids}
@defer.inlineCallbacks
def get_state_for_event(self, event_id, state_filter=StateFilter.all()):
"""
Get the state dict corresponding to a particular event
Args:
event_id(str): event whose state should be returned
state_filter (StateFilter): The state filter used to fetch state
from the database.
Returns:
A deferred dict from (type, state_key) -> state_event
"""
state_map = yield self.get_state_for_events([event_id], state_filter)
return state_map[event_id]
@defer.inlineCallbacks
def get_state_ids_for_event(self, event_id, state_filter=StateFilter.all()):
"""
Get the state dict corresponding to a particular event
Args:
event_id(str): event whose state should be returned
state_filter (StateFilter): The state filter used to fetch state
from the database.
Returns:
A deferred dict from (type, state_key) -> state_event
"""
state_map = yield self.get_state_ids_for_events([event_id], state_filter)
return state_map[event_id]
@cached(max_entries=50000)
def _get_state_group_for_event(self, event_id):
return self.db.simple_select_one_onecol(
@ -684,329 +265,6 @@ class StateGroupWorkerStore(
return {row["event_id"]: row["state_group"] for row in rows}
def _get_state_for_group_using_cache(self, cache, group, state_filter):
"""Checks if group is in cache. See `_get_state_for_groups`
Args:
cache(DictionaryCache): the state group cache to use
group(int): The state group to lookup
state_filter (StateFilter): The state filter used to fetch state
from the database.
Returns 2-tuple (`state_dict`, `got_all`).
`got_all` is a bool indicating if we successfully retrieved all
requests state from the cache, if False we need to query the DB for the
missing state.
"""
is_all, known_absent, state_dict_ids = cache.get(group)
if is_all or state_filter.is_full():
# Either we have everything or want everything, either way
# `is_all` tells us whether we've gotten everything.
return state_filter.filter_state(state_dict_ids), is_all
# tracks whether any of our requested types are missing from the cache
missing_types = False
if state_filter.has_wildcards():
# We don't know if we fetched all the state keys for the types in
# the filter that are wildcards, so we have to assume that we may
# have missed some.
missing_types = True
else:
# There aren't any wild cards, so `concrete_types()` returns the
# complete list of event types we're wanting.
for key in state_filter.concrete_types():
if key not in state_dict_ids and key not in known_absent:
missing_types = True
break
return state_filter.filter_state(state_dict_ids), not missing_types
@defer.inlineCallbacks
def _get_state_for_groups(self, groups, state_filter=StateFilter.all()):
"""Gets the state at each of a list of state groups, optionally
filtering by type/state_key
Args:
groups (iterable[int]): list of state groups for which we want
to get the state.
state_filter (StateFilter): The state filter used to fetch state
from the database.
Returns:
Deferred[dict[int, dict[tuple[str, str], str]]]:
dict of state_group_id -> (dict of (type, state_key) -> event id)
"""
member_filter, non_member_filter = state_filter.get_member_split()
# Now we look them up in the member and non-member caches
(
non_member_state,
incomplete_groups_nm,
) = yield self._get_state_for_groups_using_cache(
groups, self._state_group_cache, state_filter=non_member_filter
)
(
member_state,
incomplete_groups_m,
) = yield self._get_state_for_groups_using_cache(
groups, self._state_group_members_cache, state_filter=member_filter
)
state = dict(non_member_state)
for group in groups:
state[group].update(member_state[group])
# Now fetch any missing groups from the database
incomplete_groups = incomplete_groups_m | incomplete_groups_nm
if not incomplete_groups:
return state
cache_sequence_nm = self._state_group_cache.sequence
cache_sequence_m = self._state_group_members_cache.sequence
# Help the cache hit ratio by expanding the filter a bit
db_state_filter = state_filter.return_expanded()
group_to_state_dict = yield self._get_state_groups_from_groups(
list(incomplete_groups), state_filter=db_state_filter
)
# Now lets update the caches
self._insert_into_cache(
group_to_state_dict,
db_state_filter,
cache_seq_num_members=cache_sequence_m,
cache_seq_num_non_members=cache_sequence_nm,
)
# And finally update the result dict, by filtering out any extra
# stuff we pulled out of the database.
for group, group_state_dict in iteritems(group_to_state_dict):
# We just replace any existing entries, as we will have loaded
# everything we need from the database anyway.
state[group] = state_filter.filter_state(group_state_dict)
return state
def _get_state_for_groups_using_cache(self, groups, cache, state_filter):
"""Gets the state at each of a list of state groups, optionally
filtering by type/state_key, querying from a specific cache.
Args:
groups (iterable[int]): list of state groups for which we want
to get the state.
cache (DictionaryCache): the cache of group ids to state dicts which
we will pass through - either the normal state cache or the specific
members state cache.
state_filter (StateFilter): The state filter used to fetch state
from the database.
Returns:
tuple[dict[int, dict[tuple[str, str], str]], set[int]]: Tuple of
dict of state_group_id -> (dict of (type, state_key) -> event id)
of entries in the cache, and the state group ids either missing
from the cache or incomplete.
"""
results = {}
incomplete_groups = set()
for group in set(groups):
state_dict_ids, got_all = self._get_state_for_group_using_cache(
cache, group, state_filter
)
results[group] = state_dict_ids
if not got_all:
incomplete_groups.add(group)
return results, incomplete_groups
def _insert_into_cache(
self,
group_to_state_dict,
state_filter,
cache_seq_num_members,
cache_seq_num_non_members,
):
"""Inserts results from querying the database into the relevant cache.
Args:
group_to_state_dict (dict): The new entries pulled from database.
Map from state group to state dict
state_filter (StateFilter): The state filter used to fetch state
from the database.
cache_seq_num_members (int): Sequence number of member cache since
last lookup in cache
cache_seq_num_non_members (int): Sequence number of member cache since
last lookup in cache
"""
# We need to work out which types we've fetched from the DB for the
# member vs non-member caches. This should be as accurate as possible,
# but can be an underestimate (e.g. when we have wild cards)
member_filter, non_member_filter = state_filter.get_member_split()
if member_filter.is_full():
# We fetched all member events
member_types = None
else:
# `concrete_types()` will only return a subset when there are wild
# cards in the filter, but that's fine.
member_types = member_filter.concrete_types()
if non_member_filter.is_full():
# We fetched all non member events
non_member_types = None
else:
non_member_types = non_member_filter.concrete_types()
for group, group_state_dict in iteritems(group_to_state_dict):
state_dict_members = {}
state_dict_non_members = {}
for k, v in iteritems(group_state_dict):
if k[0] == EventTypes.Member:
state_dict_members[k] = v
else:
state_dict_non_members[k] = v
self._state_group_members_cache.update(
cache_seq_num_members,
key=group,
value=state_dict_members,
fetched_keys=member_types,
)
self._state_group_cache.update(
cache_seq_num_non_members,
key=group,
value=state_dict_non_members,
fetched_keys=non_member_types,
)
def store_state_group(
self, event_id, room_id, prev_group, delta_ids, current_state_ids
):
"""Store a new set of state, returning a newly assigned state group.
Args:
event_id (str): The event ID for which the state was calculated
room_id (str)
prev_group (int|None): A previous state group for the room, optional.
delta_ids (dict|None): The delta between state at `prev_group` and
`current_state_ids`, if `prev_group` was given. Same format as
`current_state_ids`.
current_state_ids (dict): The state to store. Map of (type, state_key)
to event_id.
Returns:
Deferred[int]: The state group ID
"""
def _store_state_group_txn(txn):
if current_state_ids is None:
# AFAIK, this can never happen
raise Exception("current_state_ids cannot be None")
state_group = self.database_engine.get_next_state_group_id(txn)
self.db.simple_insert_txn(
txn,
table="state_groups",
values={"id": state_group, "room_id": room_id, "event_id": event_id},
)
# We persist as a delta if we can, while also ensuring the chain
# of deltas isn't tooo long, as otherwise read performance degrades.
if prev_group:
is_in_db = self.db.simple_select_one_onecol_txn(
txn,
table="state_groups",
keyvalues={"id": prev_group},
retcol="id",
allow_none=True,
)
if not is_in_db:
raise Exception(
"Trying to persist state with unpersisted prev_group: %r"
% (prev_group,)
)
potential_hops = self._count_state_group_hops_txn(txn, prev_group)
if prev_group and potential_hops < MAX_STATE_DELTA_HOPS:
self.db.simple_insert_txn(
txn,
table="state_group_edges",
values={"state_group": state_group, "prev_state_group": prev_group},
)
self.db.simple_insert_many_txn(
txn,
table="state_groups_state",
values=[
{
"state_group": state_group,
"room_id": room_id,
"type": key[0],
"state_key": key[1],
"event_id": state_id,
}
for key, state_id in iteritems(delta_ids)
],
)
else:
self.db.simple_insert_many_txn(
txn,
table="state_groups_state",
values=[
{
"state_group": state_group,
"room_id": room_id,
"type": key[0],
"state_key": key[1],
"event_id": state_id,
}
for key, state_id in iteritems(current_state_ids)
],
)
# Prefill the state group caches with this group.
# It's fine to use the sequence like this as the state group map
# is immutable. (If the map wasn't immutable then this prefill could
# race with another update)
current_member_state_ids = {
s: ev
for (s, ev) in iteritems(current_state_ids)
if s[0] == EventTypes.Member
}
txn.call_after(
self._state_group_members_cache.update,
self._state_group_members_cache.sequence,
key=state_group,
value=dict(current_member_state_ids),
)
current_non_member_state_ids = {
s: ev
for (s, ev) in iteritems(current_state_ids)
if s[0] != EventTypes.Member
}
txn.call_after(
self._state_group_cache.update,
self._state_group_cache.sequence,
key=state_group,
value=dict(current_non_member_state_ids),
)
return state_group
return self.db.runInteraction("store_state_group", _store_state_group_txn)
@defer.inlineCallbacks
def get_referenced_state_groups(self, state_groups):
"""Check if the state groups are referenced by events.
@ -1031,22 +289,14 @@ class StateGroupWorkerStore(
return set(row["state_group"] for row in rows)
class StateBackgroundUpdateStore(StateGroupBackgroundUpdateStore):
class MainStateBackgroundUpdateStore(SQLBaseStore):
STATE_GROUP_DEDUPLICATION_UPDATE_NAME = "state_group_state_deduplication"
STATE_GROUP_INDEX_UPDATE_NAME = "state_group_state_type_index"
CURRENT_STATE_INDEX_UPDATE_NAME = "current_state_members_idx"
EVENT_STATE_GROUP_INDEX_UPDATE_NAME = "event_to_state_groups_sg_index"
def __init__(self, database: Database, db_conn, hs):
super(StateBackgroundUpdateStore, self).__init__(database, db_conn, hs)
self.db.updates.register_background_update_handler(
self.STATE_GROUP_DEDUPLICATION_UPDATE_NAME,
self._background_deduplicate_state,
)
self.db.updates.register_background_update_handler(
self.STATE_GROUP_INDEX_UPDATE_NAME, self._background_index_state
)
super(MainStateBackgroundUpdateStore, self).__init__(database, db_conn, hs)
self.db.updates.register_background_index_update(
self.CURRENT_STATE_INDEX_UPDATE_NAME,
index_name="current_state_events_member_index",
@ -1061,181 +311,8 @@ class StateBackgroundUpdateStore(StateGroupBackgroundUpdateStore):
columns=["state_group"],
)
@defer.inlineCallbacks
def _background_deduplicate_state(self, progress, batch_size):
"""This background update will slowly deduplicate state by reencoding
them as deltas.
"""
last_state_group = progress.get("last_state_group", 0)
rows_inserted = progress.get("rows_inserted", 0)
max_group = progress.get("max_group", None)
BATCH_SIZE_SCALE_FACTOR = 100
batch_size = max(1, int(batch_size / BATCH_SIZE_SCALE_FACTOR))
if max_group is None:
rows = yield self.db.execute(
"_background_deduplicate_state",
None,
"SELECT coalesce(max(id), 0) FROM state_groups",
)
max_group = rows[0][0]
def reindex_txn(txn):
new_last_state_group = last_state_group
for count in range(batch_size):
txn.execute(
"SELECT id, room_id FROM state_groups"
" WHERE ? < id AND id <= ?"
" ORDER BY id ASC"
" LIMIT 1",
(new_last_state_group, max_group),
)
row = txn.fetchone()
if row:
state_group, room_id = row
if not row or not state_group:
return True, count
txn.execute(
"SELECT state_group FROM state_group_edges"
" WHERE state_group = ?",
(state_group,),
)
# If we reach a point where we've already started inserting
# edges we should stop.
if txn.fetchall():
return True, count
txn.execute(
"SELECT coalesce(max(id), 0) FROM state_groups"
" WHERE id < ? AND room_id = ?",
(state_group, room_id),
)
(prev_group,) = txn.fetchone()
new_last_state_group = state_group
if prev_group:
potential_hops = self._count_state_group_hops_txn(txn, prev_group)
if potential_hops >= MAX_STATE_DELTA_HOPS:
# We want to ensure chains are at most this long,#
# otherwise read performance degrades.
continue
prev_state = self._get_state_groups_from_groups_txn(
txn, [prev_group]
)
prev_state = prev_state[prev_group]
curr_state = self._get_state_groups_from_groups_txn(
txn, [state_group]
)
curr_state = curr_state[state_group]
if not set(prev_state.keys()) - set(curr_state.keys()):
# We can only do a delta if the current has a strict super set
# of keys
delta_state = {
key: value
for key, value in iteritems(curr_state)
if prev_state.get(key, None) != value
}
self.db.simple_delete_txn(
txn,
table="state_group_edges",
keyvalues={"state_group": state_group},
)
self.db.simple_insert_txn(
txn,
table="state_group_edges",
values={
"state_group": state_group,
"prev_state_group": prev_group,
},
)
self.db.simple_delete_txn(
txn,
table="state_groups_state",
keyvalues={"state_group": state_group},
)
self.db.simple_insert_many_txn(
txn,
table="state_groups_state",
values=[
{
"state_group": state_group,
"room_id": room_id,
"type": key[0],
"state_key": key[1],
"event_id": state_id,
}
for key, state_id in iteritems(delta_state)
],
)
progress = {
"last_state_group": state_group,
"rows_inserted": rows_inserted + batch_size,
"max_group": max_group,
}
self.db.updates._background_update_progress_txn(
txn, self.STATE_GROUP_DEDUPLICATION_UPDATE_NAME, progress
)
return False, batch_size
finished, result = yield self.db.runInteraction(
self.STATE_GROUP_DEDUPLICATION_UPDATE_NAME, reindex_txn
)
if finished:
yield self.db.updates._end_background_update(
self.STATE_GROUP_DEDUPLICATION_UPDATE_NAME
)
return result * BATCH_SIZE_SCALE_FACTOR
@defer.inlineCallbacks
def _background_index_state(self, progress, batch_size):
def reindex_txn(conn):
conn.rollback()
if isinstance(self.database_engine, PostgresEngine):
# postgres insists on autocommit for the index
conn.set_session(autocommit=True)
try:
txn = conn.cursor()
txn.execute(
"CREATE INDEX CONCURRENTLY state_groups_state_type_idx"
" ON state_groups_state(state_group, type, state_key)"
)
txn.execute("DROP INDEX IF EXISTS state_groups_state_id")
finally:
conn.set_session(autocommit=False)
else:
txn = conn.cursor()
txn.execute(
"CREATE INDEX state_groups_state_type_idx"
" ON state_groups_state(state_group, type, state_key)"
)
txn.execute("DROP INDEX IF EXISTS state_groups_state_id")
yield self.db.runWithConnection(reindex_txn)
yield self.db.updates._end_background_update(self.STATE_GROUP_INDEX_UPDATE_NAME)
return 1
class StateStore(StateGroupWorkerStore, StateBackgroundUpdateStore):
class StateStore(StateGroupWorkerStore, MainStateBackgroundUpdateStore):
""" Keeps track of the state at a given event.
This is done by the concept of `state groups`. Every event is a assigned

View File

@ -0,0 +1,16 @@
# -*- coding: utf-8 -*-
# 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.
from synapse.storage.data_stores.state.store import StateGroupDataStore # noqa: F401

View File

@ -0,0 +1,374 @@
# -*- 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.
import logging
from six import iteritems
from twisted.internet import defer
from synapse.storage._base import SQLBaseStore
from synapse.storage.database import Database
from synapse.storage.engines import PostgresEngine
from synapse.storage.state import StateFilter
logger = logging.getLogger(__name__)
MAX_STATE_DELTA_HOPS = 100
class StateGroupBackgroundUpdateStore(SQLBaseStore):
"""Defines functions related to state groups needed to run the state backgroud
updates.
"""
def _count_state_group_hops_txn(self, txn, state_group):
"""Given a state group, count how many hops there are in the tree.
This is used to ensure the delta chains don't get too long.
"""
if isinstance(self.database_engine, PostgresEngine):
sql = """
WITH RECURSIVE state(state_group) AS (
VALUES(?::bigint)
UNION ALL
SELECT prev_state_group FROM state_group_edges e, state s
WHERE s.state_group = e.state_group
)
SELECT count(*) FROM state;
"""
txn.execute(sql, (state_group,))
row = txn.fetchone()
if row and row[0]:
return row[0]
else:
return 0
else:
# We don't use WITH RECURSIVE on sqlite3 as there are distributions
# that ship with an sqlite3 version that doesn't support it (e.g. wheezy)
next_group = state_group
count = 0
while next_group:
next_group = self.db.simple_select_one_onecol_txn(
txn,
table="state_group_edges",
keyvalues={"state_group": next_group},
retcol="prev_state_group",
allow_none=True,
)
if next_group:
count += 1
return count
def _get_state_groups_from_groups_txn(
self, txn, groups, state_filter=StateFilter.all()
):
results = {group: {} for group in groups}
where_clause, where_args = state_filter.make_sql_filter_clause()
# Unless the filter clause is empty, we're going to append it after an
# existing where clause
if where_clause:
where_clause = " AND (%s)" % (where_clause,)
if isinstance(self.database_engine, PostgresEngine):
# Temporarily disable sequential scans in this transaction. This is
# a temporary hack until we can add the right indices in
txn.execute("SET LOCAL enable_seqscan=off")
# The below query walks the state_group tree so that the "state"
# table includes all state_groups in the tree. It then joins
# against `state_groups_state` to fetch the latest state.
# It assumes that previous state groups are always numerically
# lesser.
# The PARTITION is used to get the event_id in the greatest state
# group for the given type, state_key.
# This may return multiple rows per (type, state_key), but last_value
# should be the same.
sql = """
WITH RECURSIVE state(state_group) AS (
VALUES(?::bigint)
UNION ALL
SELECT prev_state_group FROM state_group_edges e, state s
WHERE s.state_group = e.state_group
)
SELECT DISTINCT type, state_key, last_value(event_id) OVER (
PARTITION BY type, state_key ORDER BY state_group ASC
ROWS BETWEEN UNBOUNDED PRECEDING AND UNBOUNDED FOLLOWING
) AS event_id FROM state_groups_state
WHERE state_group IN (
SELECT state_group FROM state
)
"""
for group in groups:
args = [group]
args.extend(where_args)
txn.execute(sql + where_clause, args)
for row in txn:
typ, state_key, event_id = row
key = (typ, state_key)
results[group][key] = event_id
else:
max_entries_returned = state_filter.max_entries_returned()
# We don't use WITH RECURSIVE on sqlite3 as there are distributions
# that ship with an sqlite3 version that doesn't support it (e.g. wheezy)
for group in groups:
next_group = group
while next_group:
# We did this before by getting the list of group ids, and
# then passing that list to sqlite to get latest event for
# each (type, state_key). However, that was terribly slow
# without the right indices (which we can't add until
# after we finish deduping state, which requires this func)
args = [next_group]
args.extend(where_args)
txn.execute(
"SELECT type, state_key, event_id FROM state_groups_state"
" WHERE state_group = ? " + where_clause,
args,
)
results[group].update(
((typ, state_key), event_id)
for typ, state_key, event_id in txn
if (typ, state_key) not in results[group]
)
# If the number of entries in the (type,state_key)->event_id dict
# matches the number of (type,state_keys) types we were searching
# for, then we must have found them all, so no need to go walk
# further down the tree... UNLESS our types filter contained
# wildcards (i.e. Nones) in which case we have to do an exhaustive
# search
if (
max_entries_returned is not None
and len(results[group]) == max_entries_returned
):
break
next_group = self.db.simple_select_one_onecol_txn(
txn,
table="state_group_edges",
keyvalues={"state_group": next_group},
retcol="prev_state_group",
allow_none=True,
)
return results
class StateBackgroundUpdateStore(StateGroupBackgroundUpdateStore):
STATE_GROUP_DEDUPLICATION_UPDATE_NAME = "state_group_state_deduplication"
STATE_GROUP_INDEX_UPDATE_NAME = "state_group_state_type_index"
STATE_GROUPS_ROOM_INDEX_UPDATE_NAME = "state_groups_room_id_idx"
def __init__(self, database: Database, db_conn, hs):
super(StateBackgroundUpdateStore, self).__init__(database, db_conn, hs)
self.db.updates.register_background_update_handler(
self.STATE_GROUP_DEDUPLICATION_UPDATE_NAME,
self._background_deduplicate_state,
)
self.db.updates.register_background_update_handler(
self.STATE_GROUP_INDEX_UPDATE_NAME, self._background_index_state
)
self.db.updates.register_background_index_update(
self.STATE_GROUPS_ROOM_INDEX_UPDATE_NAME,
index_name="state_groups_room_id_idx",
table="state_groups",
columns=["room_id"],
)
@defer.inlineCallbacks
def _background_deduplicate_state(self, progress, batch_size):
"""This background update will slowly deduplicate state by reencoding
them as deltas.
"""
last_state_group = progress.get("last_state_group", 0)
rows_inserted = progress.get("rows_inserted", 0)
max_group = progress.get("max_group", None)
BATCH_SIZE_SCALE_FACTOR = 100
batch_size = max(1, int(batch_size / BATCH_SIZE_SCALE_FACTOR))
if max_group is None:
rows = yield self.db.execute(
"_background_deduplicate_state",
None,
"SELECT coalesce(max(id), 0) FROM state_groups",
)
max_group = rows[0][0]
def reindex_txn(txn):
new_last_state_group = last_state_group
for count in range(batch_size):
txn.execute(
"SELECT id, room_id FROM state_groups"
" WHERE ? < id AND id <= ?"
" ORDER BY id ASC"
" LIMIT 1",
(new_last_state_group, max_group),
)
row = txn.fetchone()
if row:
state_group, room_id = row
if not row or not state_group:
return True, count
txn.execute(
"SELECT state_group FROM state_group_edges"
" WHERE state_group = ?",
(state_group,),
)
# If we reach a point where we've already started inserting
# edges we should stop.
if txn.fetchall():
return True, count
txn.execute(
"SELECT coalesce(max(id), 0) FROM state_groups"
" WHERE id < ? AND room_id = ?",
(state_group, room_id),
)
(prev_group,) = txn.fetchone()
new_last_state_group = state_group
if prev_group:
potential_hops = self._count_state_group_hops_txn(txn, prev_group)
if potential_hops >= MAX_STATE_DELTA_HOPS:
# We want to ensure chains are at most this long,#
# otherwise read performance degrades.
continue
prev_state = self._get_state_groups_from_groups_txn(
txn, [prev_group]
)
prev_state = prev_state[prev_group]
curr_state = self._get_state_groups_from_groups_txn(
txn, [state_group]
)
curr_state = curr_state[state_group]
if not set(prev_state.keys()) - set(curr_state.keys()):
# We can only do a delta if the current has a strict super set
# of keys
delta_state = {
key: value
for key, value in iteritems(curr_state)
if prev_state.get(key, None) != value
}
self.db.simple_delete_txn(
txn,
table="state_group_edges",
keyvalues={"state_group": state_group},
)
self.db.simple_insert_txn(
txn,
table="state_group_edges",
values={
"state_group": state_group,
"prev_state_group": prev_group,
},
)
self.db.simple_delete_txn(
txn,
table="state_groups_state",
keyvalues={"state_group": state_group},
)
self.db.simple_insert_many_txn(
txn,
table="state_groups_state",
values=[
{
"state_group": state_group,
"room_id": room_id,
"type": key[0],
"state_key": key[1],
"event_id": state_id,
}
for key, state_id in iteritems(delta_state)
],
)
progress = {
"last_state_group": state_group,
"rows_inserted": rows_inserted + batch_size,
"max_group": max_group,
}
self.db.updates._background_update_progress_txn(
txn, self.STATE_GROUP_DEDUPLICATION_UPDATE_NAME, progress
)
return False, batch_size
finished, result = yield self.db.runInteraction(
self.STATE_GROUP_DEDUPLICATION_UPDATE_NAME, reindex_txn
)
if finished:
yield self.db.updates._end_background_update(
self.STATE_GROUP_DEDUPLICATION_UPDATE_NAME
)
return result * BATCH_SIZE_SCALE_FACTOR
@defer.inlineCallbacks
def _background_index_state(self, progress, batch_size):
def reindex_txn(conn):
conn.rollback()
if isinstance(self.database_engine, PostgresEngine):
# postgres insists on autocommit for the index
conn.set_session(autocommit=True)
try:
txn = conn.cursor()
txn.execute(
"CREATE INDEX CONCURRENTLY state_groups_state_type_idx"
" ON state_groups_state(state_group, type, state_key)"
)
txn.execute("DROP INDEX IF EXISTS state_groups_state_id")
finally:
conn.set_session(autocommit=False)
else:
txn = conn.cursor()
txn.execute(
"CREATE INDEX state_groups_state_type_idx"
" ON state_groups_state(state_group, type, state_key)"
)
txn.execute("DROP INDEX IF EXISTS state_groups_state_id")
yield self.db.runWithConnection(reindex_txn)
yield self.db.updates._end_background_update(self.STATE_GROUP_INDEX_UPDATE_NAME)
return 1

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@ -0,0 +1,19 @@
/* Copyright 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.
*/
-- The following indices are redundant, other indices are equivalent or
-- supersets
DROP INDEX IF EXISTS state_groups_id; -- Duplicate of PRIMARY KEY

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@ -0,0 +1,17 @@
/* 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.
*/
INSERT INTO background_updates (update_name, progress_json) VALUES
('state_groups_room_id_idx', '{}');

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@ -0,0 +1,37 @@
/* 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.
*/
CREATE TABLE state_groups (
id BIGINT PRIMARY KEY,
room_id TEXT NOT NULL,
event_id TEXT NOT NULL
);
CREATE TABLE state_groups_state (
state_group BIGINT NOT NULL,
room_id TEXT NOT NULL,
type TEXT NOT NULL,
state_key TEXT NOT NULL,
event_id TEXT NOT NULL
);
CREATE TABLE state_group_edges (
state_group BIGINT NOT NULL,
prev_state_group BIGINT NOT NULL
);
CREATE INDEX state_group_edges_idx ON state_group_edges (state_group);
CREATE INDEX state_group_edges_prev_idx ON state_group_edges (prev_state_group);
CREATE INDEX state_groups_state_type_idx ON state_groups_state (state_group, type, state_key);

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@ -0,0 +1,21 @@
/* 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.
*/
CREATE SEQUENCE state_group_id_seq
START WITH 1
INCREMENT BY 1
NO MINVALUE
NO MAXVALUE
CACHE 1;

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@ -0,0 +1,640 @@
# -*- 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.
import logging
from collections import namedtuple
from six import iteritems
from six.moves import range
from twisted.internet import defer
from synapse.api.constants import EventTypes
from synapse.storage._base import SQLBaseStore
from synapse.storage.data_stores.state.bg_updates import StateBackgroundUpdateStore
from synapse.storage.database import Database
from synapse.storage.state import StateFilter
from synapse.util.caches import get_cache_factor_for
from synapse.util.caches.descriptors import cached
from synapse.util.caches.dictionary_cache import DictionaryCache
logger = logging.getLogger(__name__)
MAX_STATE_DELTA_HOPS = 100
class _GetStateGroupDelta(
namedtuple("_GetStateGroupDelta", ("prev_group", "delta_ids"))
):
"""Return type of get_state_group_delta that implements __len__, which lets
us use the itrable flag when caching
"""
__slots__ = []
def __len__(self):
return len(self.delta_ids) if self.delta_ids else 0
class StateGroupDataStore(StateBackgroundUpdateStore, SQLBaseStore):
"""A data store for fetching/storing state groups.
"""
def __init__(self, database: Database, db_conn, hs):
super(StateGroupDataStore, self).__init__(database, db_conn, hs)
# Originally the state store used a single DictionaryCache to cache the
# event IDs for the state types in a given state group to avoid hammering
# on the state_group* tables.
#
# The point of using a DictionaryCache is that it can cache a subset
# of the state events for a given state group (i.e. a subset of the keys for a
# given dict which is an entry in the cache for a given state group ID).
#
# However, this poses problems when performing complicated queries
# on the store - for instance: "give me all the state for this group, but
# limit members to this subset of users", as DictionaryCache's API isn't
# rich enough to say "please cache any of these fields, apart from this subset".
# This is problematic when lazy loading members, which requires this behaviour,
# as without it the cache has no choice but to speculatively load all
# state events for the group, which negates the efficiency being sought.
#
# Rather than overcomplicating DictionaryCache's API, we instead split the
# state_group_cache into two halves - one for tracking non-member events,
# and the other for tracking member_events. This means that lazy loading
# queries can be made in a cache-friendly manner by querying both caches
# separately and then merging the result. So for the example above, you
# would query the members cache for a specific subset of state keys
# (which DictionaryCache will handle efficiently and fine) and the non-members
# cache for all state (which DictionaryCache will similarly handle fine)
# and then just merge the results together.
#
# We size the non-members cache to be smaller than the members cache as the
# vast majority of state in Matrix (today) is member events.
self._state_group_cache = DictionaryCache(
"*stateGroupCache*",
# TODO: this hasn't been tuned yet
50000 * get_cache_factor_for("stateGroupCache"),
)
self._state_group_members_cache = DictionaryCache(
"*stateGroupMembersCache*",
500000 * get_cache_factor_for("stateGroupMembersCache"),
)
@cached(max_entries=10000, iterable=True)
def get_state_group_delta(self, state_group):
"""Given a state group try to return a previous group and a delta between
the old and the new.
Returns:
(prev_group, delta_ids), where both may be None.
"""
def _get_state_group_delta_txn(txn):
prev_group = self.db.simple_select_one_onecol_txn(
txn,
table="state_group_edges",
keyvalues={"state_group": state_group},
retcol="prev_state_group",
allow_none=True,
)
if not prev_group:
return _GetStateGroupDelta(None, None)
delta_ids = self.db.simple_select_list_txn(
txn,
table="state_groups_state",
keyvalues={"state_group": state_group},
retcols=("type", "state_key", "event_id"),
)
return _GetStateGroupDelta(
prev_group,
{(row["type"], row["state_key"]): row["event_id"] for row in delta_ids},
)
return self.db.runInteraction(
"get_state_group_delta", _get_state_group_delta_txn
)
@defer.inlineCallbacks
def _get_state_groups_from_groups(self, groups, state_filter):
"""Returns the state groups for a given set of groups, filtering on
types of state events.
Args:
groups(list[int]): list of state group IDs to query
state_filter (StateFilter): The state filter used to fetch state
from the database.
Returns:
Deferred[dict[int, dict[tuple[str, str], str]]]:
dict of state_group_id -> (dict of (type, state_key) -> event id)
"""
results = {}
chunks = [groups[i : i + 100] for i in range(0, len(groups), 100)]
for chunk in chunks:
res = yield self.db.runInteraction(
"_get_state_groups_from_groups",
self._get_state_groups_from_groups_txn,
chunk,
state_filter,
)
results.update(res)
return results
def _get_state_for_group_using_cache(self, cache, group, state_filter):
"""Checks if group is in cache. See `_get_state_for_groups`
Args:
cache(DictionaryCache): the state group cache to use
group(int): The state group to lookup
state_filter (StateFilter): The state filter used to fetch state
from the database.
Returns 2-tuple (`state_dict`, `got_all`).
`got_all` is a bool indicating if we successfully retrieved all
requests state from the cache, if False we need to query the DB for the
missing state.
"""
is_all, known_absent, state_dict_ids = cache.get(group)
if is_all or state_filter.is_full():
# Either we have everything or want everything, either way
# `is_all` tells us whether we've gotten everything.
return state_filter.filter_state(state_dict_ids), is_all
# tracks whether any of our requested types are missing from the cache
missing_types = False
if state_filter.has_wildcards():
# We don't know if we fetched all the state keys for the types in
# the filter that are wildcards, so we have to assume that we may
# have missed some.
missing_types = True
else:
# There aren't any wild cards, so `concrete_types()` returns the
# complete list of event types we're wanting.
for key in state_filter.concrete_types():
if key not in state_dict_ids and key not in known_absent:
missing_types = True
break
return state_filter.filter_state(state_dict_ids), not missing_types
@defer.inlineCallbacks
def _get_state_for_groups(self, groups, state_filter=StateFilter.all()):
"""Gets the state at each of a list of state groups, optionally
filtering by type/state_key
Args:
groups (iterable[int]): list of state groups for which we want
to get the state.
state_filter (StateFilter): The state filter used to fetch state
from the database.
Returns:
Deferred[dict[int, dict[tuple[str, str], str]]]:
dict of state_group_id -> (dict of (type, state_key) -> event id)
"""
member_filter, non_member_filter = state_filter.get_member_split()
# Now we look them up in the member and non-member caches
(
non_member_state,
incomplete_groups_nm,
) = yield self._get_state_for_groups_using_cache(
groups, self._state_group_cache, state_filter=non_member_filter
)
(
member_state,
incomplete_groups_m,
) = yield self._get_state_for_groups_using_cache(
groups, self._state_group_members_cache, state_filter=member_filter
)
state = dict(non_member_state)
for group in groups:
state[group].update(member_state[group])
# Now fetch any missing groups from the database
incomplete_groups = incomplete_groups_m | incomplete_groups_nm
if not incomplete_groups:
return state
cache_sequence_nm = self._state_group_cache.sequence
cache_sequence_m = self._state_group_members_cache.sequence
# Help the cache hit ratio by expanding the filter a bit
db_state_filter = state_filter.return_expanded()
group_to_state_dict = yield self._get_state_groups_from_groups(
list(incomplete_groups), state_filter=db_state_filter
)
# Now lets update the caches
self._insert_into_cache(
group_to_state_dict,
db_state_filter,
cache_seq_num_members=cache_sequence_m,
cache_seq_num_non_members=cache_sequence_nm,
)
# And finally update the result dict, by filtering out any extra
# stuff we pulled out of the database.
for group, group_state_dict in iteritems(group_to_state_dict):
# We just replace any existing entries, as we will have loaded
# everything we need from the database anyway.
state[group] = state_filter.filter_state(group_state_dict)
return state
def _get_state_for_groups_using_cache(self, groups, cache, state_filter):
"""Gets the state at each of a list of state groups, optionally
filtering by type/state_key, querying from a specific cache.
Args:
groups (iterable[int]): list of state groups for which we want
to get the state.
cache (DictionaryCache): the cache of group ids to state dicts which
we will pass through - either the normal state cache or the specific
members state cache.
state_filter (StateFilter): The state filter used to fetch state
from the database.
Returns:
tuple[dict[int, dict[tuple[str, str], str]], set[int]]: Tuple of
dict of state_group_id -> (dict of (type, state_key) -> event id)
of entries in the cache, and the state group ids either missing
from the cache or incomplete.
"""
results = {}
incomplete_groups = set()
for group in set(groups):
state_dict_ids, got_all = self._get_state_for_group_using_cache(
cache, group, state_filter
)
results[group] = state_dict_ids
if not got_all:
incomplete_groups.add(group)
return results, incomplete_groups
def _insert_into_cache(
self,
group_to_state_dict,
state_filter,
cache_seq_num_members,
cache_seq_num_non_members,
):
"""Inserts results from querying the database into the relevant cache.
Args:
group_to_state_dict (dict): The new entries pulled from database.
Map from state group to state dict
state_filter (StateFilter): The state filter used to fetch state
from the database.
cache_seq_num_members (int): Sequence number of member cache since
last lookup in cache
cache_seq_num_non_members (int): Sequence number of member cache since
last lookup in cache
"""
# We need to work out which types we've fetched from the DB for the
# member vs non-member caches. This should be as accurate as possible,
# but can be an underestimate (e.g. when we have wild cards)
member_filter, non_member_filter = state_filter.get_member_split()
if member_filter.is_full():
# We fetched all member events
member_types = None
else:
# `concrete_types()` will only return a subset when there are wild
# cards in the filter, but that's fine.
member_types = member_filter.concrete_types()
if non_member_filter.is_full():
# We fetched all non member events
non_member_types = None
else:
non_member_types = non_member_filter.concrete_types()
for group, group_state_dict in iteritems(group_to_state_dict):
state_dict_members = {}
state_dict_non_members = {}
for k, v in iteritems(group_state_dict):
if k[0] == EventTypes.Member:
state_dict_members[k] = v
else:
state_dict_non_members[k] = v
self._state_group_members_cache.update(
cache_seq_num_members,
key=group,
value=state_dict_members,
fetched_keys=member_types,
)
self._state_group_cache.update(
cache_seq_num_non_members,
key=group,
value=state_dict_non_members,
fetched_keys=non_member_types,
)
def store_state_group(
self, event_id, room_id, prev_group, delta_ids, current_state_ids
):
"""Store a new set of state, returning a newly assigned state group.
Args:
event_id (str): The event ID for which the state was calculated
room_id (str)
prev_group (int|None): A previous state group for the room, optional.
delta_ids (dict|None): The delta between state at `prev_group` and
`current_state_ids`, if `prev_group` was given. Same format as
`current_state_ids`.
current_state_ids (dict): The state to store. Map of (type, state_key)
to event_id.
Returns:
Deferred[int]: The state group ID
"""
def _store_state_group_txn(txn):
if current_state_ids is None:
# AFAIK, this can never happen
raise Exception("current_state_ids cannot be None")
state_group = self.database_engine.get_next_state_group_id(txn)
self.db.simple_insert_txn(
txn,
table="state_groups",
values={"id": state_group, "room_id": room_id, "event_id": event_id},
)
# We persist as a delta if we can, while also ensuring the chain
# of deltas isn't tooo long, as otherwise read performance degrades.
if prev_group:
is_in_db = self.db.simple_select_one_onecol_txn(
txn,
table="state_groups",
keyvalues={"id": prev_group},
retcol="id",
allow_none=True,
)
if not is_in_db:
raise Exception(
"Trying to persist state with unpersisted prev_group: %r"
% (prev_group,)
)
potential_hops = self._count_state_group_hops_txn(txn, prev_group)
if prev_group and potential_hops < MAX_STATE_DELTA_HOPS:
self.db.simple_insert_txn(
txn,
table="state_group_edges",
values={"state_group": state_group, "prev_state_group": prev_group},
)
self.db.simple_insert_many_txn(
txn,
table="state_groups_state",
values=[
{
"state_group": state_group,
"room_id": room_id,
"type": key[0],
"state_key": key[1],
"event_id": state_id,
}
for key, state_id in iteritems(delta_ids)
],
)
else:
self.db.simple_insert_many_txn(
txn,
table="state_groups_state",
values=[
{
"state_group": state_group,
"room_id": room_id,
"type": key[0],
"state_key": key[1],
"event_id": state_id,
}
for key, state_id in iteritems(current_state_ids)
],
)
# Prefill the state group caches with this group.
# It's fine to use the sequence like this as the state group map
# is immutable. (If the map wasn't immutable then this prefill could
# race with another update)
current_member_state_ids = {
s: ev
for (s, ev) in iteritems(current_state_ids)
if s[0] == EventTypes.Member
}
txn.call_after(
self._state_group_members_cache.update,
self._state_group_members_cache.sequence,
key=state_group,
value=dict(current_member_state_ids),
)
current_non_member_state_ids = {
s: ev
for (s, ev) in iteritems(current_state_ids)
if s[0] != EventTypes.Member
}
txn.call_after(
self._state_group_cache.update,
self._state_group_cache.sequence,
key=state_group,
value=dict(current_non_member_state_ids),
)
return state_group
return self.db.runInteraction("store_state_group", _store_state_group_txn)
def purge_unreferenced_state_groups(
self, room_id: str, state_groups_to_delete
) -> defer.Deferred:
"""Deletes no longer referenced state groups and de-deltas any state
groups that reference them.
Args:
room_id: The room the state groups belong to (must all be in the
same room).
state_groups_to_delete (Collection[int]): Set of all state groups
to delete.
"""
return self.db.runInteraction(
"purge_unreferenced_state_groups",
self._purge_unreferenced_state_groups,
room_id,
state_groups_to_delete,
)
def _purge_unreferenced_state_groups(self, txn, room_id, state_groups_to_delete):
logger.info(
"[purge] found %i state groups to delete", len(state_groups_to_delete)
)
rows = self.db.simple_select_many_txn(
txn,
table="state_group_edges",
column="prev_state_group",
iterable=state_groups_to_delete,
keyvalues={},
retcols=("state_group",),
)
remaining_state_groups = set(
row["state_group"]
for row in rows
if row["state_group"] not in state_groups_to_delete
)
logger.info(
"[purge] de-delta-ing %i remaining state groups",
len(remaining_state_groups),
)
# Now we turn the state groups that reference to-be-deleted state
# groups to non delta versions.
for sg in remaining_state_groups:
logger.info("[purge] de-delta-ing remaining state group %s", sg)
curr_state = self._get_state_groups_from_groups_txn(txn, [sg])
curr_state = curr_state[sg]
self.db.simple_delete_txn(
txn, table="state_groups_state", keyvalues={"state_group": sg}
)
self.db.simple_delete_txn(
txn, table="state_group_edges", keyvalues={"state_group": sg}
)
self.db.simple_insert_many_txn(
txn,
table="state_groups_state",
values=[
{
"state_group": sg,
"room_id": room_id,
"type": key[0],
"state_key": key[1],
"event_id": state_id,
}
for key, state_id in iteritems(curr_state)
],
)
logger.info("[purge] removing redundant state groups")
txn.executemany(
"DELETE FROM state_groups_state WHERE state_group = ?",
((sg,) for sg in state_groups_to_delete),
)
txn.executemany(
"DELETE FROM state_groups WHERE id = ?",
((sg,) for sg in state_groups_to_delete),
)
@defer.inlineCallbacks
def get_previous_state_groups(self, state_groups):
"""Fetch the previous groups of the given state groups.
Args:
state_groups (Iterable[int])
Returns:
Deferred[dict[int, int]]: mapping from state group to previous
state group.
"""
rows = yield self.db.simple_select_many_batch(
table="state_group_edges",
column="prev_state_group",
iterable=state_groups,
keyvalues={},
retcols=("prev_state_group", "state_group"),
desc="get_previous_state_groups",
)
return {row["state_group"]: row["prev_state_group"] for row in rows}
def purge_room_state(self, room_id, state_groups_to_delete):
"""Deletes all record of a room from state tables
Args:
room_id (str):
state_groups_to_delete (list[int]): State groups to delete
"""
return self.db.runInteraction(
"purge_room_state",
self._purge_room_state_txn,
room_id,
state_groups_to_delete,
)
def _purge_room_state_txn(self, txn, room_id, state_groups_to_delete):
# first we have to delete the state groups states
logger.info("[purge] removing %s from state_groups_state", room_id)
self.db.simple_delete_many_txn(
txn,
table="state_groups_state",
column="state_group",
iterable=state_groups_to_delete,
keyvalues={},
)
# ... and the state group edges
logger.info("[purge] removing %s from state_group_edges", room_id)
self.db.simple_delete_many_txn(
txn,
table="state_group_edges",
column="state_group",
iterable=state_groups_to_delete,
keyvalues={},
)
# ... and the state groups
logger.info("[purge] removing %s from state_groups", room_id)
self.db.simple_delete_many_txn(
txn,
table="state_groups",
column="id",
iterable=state_groups_to_delete,
keyvalues={},
)

View File

@ -183,7 +183,7 @@ class EventsPersistenceStorage(object):
# so we use separate variables here even though they point to the same
# store for now.
self.main_store = stores.main
self.state_store = stores.main
self.state_store = stores.state
self._clock = hs.get_clock()
self.is_mine_id = hs.is_mine_id

View File

@ -42,7 +42,7 @@ class UpgradeDatabaseException(PrepareDatabaseException):
pass
def prepare_database(db_conn, database_engine, config, data_stores=["main"]):
def prepare_database(db_conn, database_engine, config, data_stores=["main", "state"]):
"""Prepares a database for usage. Will either create all necessary tables
or upgrade from an older schema version.

View File

@ -58,7 +58,7 @@ class PurgeEventsStorage(object):
sg_to_delete = yield self._find_unreferenced_groups(state_groups)
yield self.stores.main.purge_unreferenced_state_groups(room_id, sg_to_delete)
yield self.stores.state.purge_unreferenced_state_groups(room_id, sg_to_delete)
@defer.inlineCallbacks
def _find_unreferenced_groups(self, state_groups):
@ -102,7 +102,7 @@ class PurgeEventsStorage(object):
# groups that are referenced.
current_search -= referenced
edges = yield self.stores.main.get_previous_state_groups(current_search)
edges = yield self.stores.state.get_previous_state_groups(current_search)
prevs = set(edges.values())
# We don't bother re-handling groups we've already seen

View File

@ -342,7 +342,7 @@ class StateGroupStorage(object):
(prev_group, delta_ids)
"""
return self.stores.main.get_state_group_delta(state_group)
return self.stores.state.get_state_group_delta(state_group)
@defer.inlineCallbacks
def get_state_groups_ids(self, _room_id, event_ids):
@ -362,7 +362,7 @@ class StateGroupStorage(object):
event_to_groups = yield self.stores.main._get_state_group_for_events(event_ids)
groups = set(itervalues(event_to_groups))
group_to_state = yield self.stores.main._get_state_for_groups(groups)
group_to_state = yield self.stores.state._get_state_for_groups(groups)
return group_to_state
@ -423,7 +423,7 @@ class StateGroupStorage(object):
dict of state_group_id -> (dict of (type, state_key) -> event id)
"""
return self.stores.main._get_state_groups_from_groups(groups, state_filter)
return self.stores.state._get_state_groups_from_groups(groups, state_filter)
@defer.inlineCallbacks
def get_state_for_events(self, event_ids, state_filter=StateFilter.all()):
@ -439,7 +439,7 @@ class StateGroupStorage(object):
event_to_groups = yield self.stores.main._get_state_group_for_events(event_ids)
groups = set(itervalues(event_to_groups))
group_to_state = yield self.stores.main._get_state_for_groups(
group_to_state = yield self.stores.state._get_state_for_groups(
groups, state_filter
)
@ -476,7 +476,7 @@ class StateGroupStorage(object):
event_to_groups = yield self.stores.main._get_state_group_for_events(event_ids)
groups = set(itervalues(event_to_groups))
group_to_state = yield self.stores.main._get_state_for_groups(
group_to_state = yield self.stores.state._get_state_for_groups(
groups, state_filter
)
@ -532,7 +532,7 @@ class StateGroupStorage(object):
Deferred[dict[int, dict[tuple[str, str], str]]]:
dict of state_group_id -> (dict of (type, state_key) -> event id)
"""
return self.stores.main._get_state_for_groups(groups, state_filter)
return self.stores.state._get_state_for_groups(groups, state_filter)
def store_state_group(
self, event_id, room_id, prev_group, delta_ids, current_state_ids
@ -552,6 +552,6 @@ class StateGroupStorage(object):
Returns:
Deferred[int]: The state group ID
"""
return self.stores.main.store_state_group(
return self.stores.state.store_state_group(
event_id, room_id, prev_group, delta_ids, current_state_ids
)

View File

@ -35,7 +35,7 @@ class StateStoreTestCase(tests.unittest.TestCase):
self.store = hs.get_datastore()
self.storage = hs.get_storage()
self.state_datastore = self.store
self.state_datastore = self.storage.state.stores.state
self.event_builder_factory = hs.get_event_builder_factory()
self.event_creation_handler = hs.get_event_creation_handler()

View File

@ -231,7 +231,7 @@ def setup_test_homeserver(
"args": {"database": ":memory:", "cp_min": 1, "cp_max": 1},
}
database = DatabaseConnectionConfig("master", database_config, ["main"])
database = DatabaseConnectionConfig("master", database_config)
config.database.databases = [database]
db_engine = create_engine(database.config)