# # This file is licensed under the Affero General Public License (AGPL) version 3. # # Copyright 2021 The Matrix.org Foundation C.I.C. # Copyright 2014-2016 OpenMarket Ltd # Copyright (C) 2023 New Vector, Ltd # # This program is free software: you can redistribute it and/or modify # it under the terms of the GNU Affero General Public License as # published by the Free Software Foundation, either version 3 of the # License, or (at your option) any later version. # # See the GNU Affero General Public License for more details: # . # # Originally licensed under the Apache License, Version 2.0: # . # # [This file includes modifications made by New Vector Limited] # # import abc import heapq import logging import threading from types import TracebackType from typing import ( TYPE_CHECKING, AsyncContextManager, ContextManager, Dict, Generic, Iterable, List, Optional, Sequence, Set, Tuple, Type, TypeVar, Union, cast, ) import attr from sortedcontainers import SortedList, SortedSet from synapse.metrics.background_process_metrics import run_as_background_process from synapse.storage.database import ( DatabasePool, LoggingDatabaseConnection, LoggingTransaction, make_in_list_sql_clause, ) from synapse.storage.engines import PostgresEngine from synapse.storage.types import Cursor from synapse.storage.util.sequence import build_sequence_generator if TYPE_CHECKING: from synapse.notifier import ReplicationNotifier logger = logging.getLogger(__name__) T = TypeVar("T") class IdGenerator: def __init__( self, db_conn: LoggingDatabaseConnection, table: str, column: str, ): self._lock = threading.Lock() self._next_id = _load_current_id(db_conn, table, column) def get_next(self) -> int: with self._lock: self._next_id += 1 return self._next_id def _load_current_id( db_conn: LoggingDatabaseConnection, table: str, column: str, step: int = 1 ) -> int: cur = db_conn.cursor(txn_name="_load_current_id") if step == 1: cur.execute("SELECT MAX(%s) FROM %s" % (column, table)) else: cur.execute("SELECT MIN(%s) FROM %s" % (column, table)) result = cur.fetchone() assert result is not None (val,) = result cur.close() current_id = int(val) if val else step res = (max if step > 0 else min)(current_id, step) logger.info("Initialising stream generator for %s(%s): %i", table, column, res) return res class AbstractStreamIdGenerator(metaclass=abc.ABCMeta): """Generates or tracks stream IDs for a stream that may have multiple writers. Each stream ID represents a write transaction, whose completion is tracked so that the "current" stream ID of the stream can be determined. Stream IDs are monotonically increasing or decreasing integers representing write transactions. The "current" stream ID is the stream ID such that all transactions with equal or smaller stream IDs have completed. Since transactions may complete out of order, this is not the same as the stream ID of the last completed transaction. Completed transactions include both committed transactions and transactions that have been rolled back. """ @abc.abstractmethod def advance(self, instance_name: str, new_id: int) -> None: """Advance the position of the named writer to the given ID, if greater than existing entry. """ raise NotImplementedError() @abc.abstractmethod def get_current_token(self) -> int: """Returns the maximum stream id such that all stream ids less than or equal to it have been successfully persisted. Returns: The maximum stream id. """ raise NotImplementedError() @abc.abstractmethod def get_current_token_for_writer(self, instance_name: str) -> int: """Returns the position of the given writer. For streams with single writers this is equivalent to `get_current_token`. """ raise NotImplementedError() @abc.abstractmethod def get_minimal_local_current_token(self) -> int: """Tries to return a minimal current token for the local instance, i.e. for writers this would be the last successful write. If local instance is not a writer (or has written yet) then falls back to returning the normal "current token". """ @abc.abstractmethod def get_next(self) -> AsyncContextManager[int]: """ Usage: async with stream_id_gen.get_next() as stream_id: # ... persist event ... """ raise NotImplementedError() @abc.abstractmethod def get_next_mult(self, n: int) -> AsyncContextManager[Sequence[int]]: """ Usage: async with stream_id_gen.get_next(n) as stream_ids: # ... persist events ... """ raise NotImplementedError() @abc.abstractmethod def get_next_txn(self, txn: LoggingTransaction) -> int: """ Usage: stream_id_gen.get_next_txn(txn) # ... persist events ... """ raise NotImplementedError() class MultiWriterIdGenerator(AbstractStreamIdGenerator): """Generates and tracks stream IDs for a stream with multiple writers. Uses a Postgres sequence to coordinate ID assignment, but positions of other writers will only get updated when `advance` is called (by replication). Note: Only works with Postgres. Args: db_conn db stream_name: A name for the stream, for use in the `stream_positions` table. (Does not need to be the same as the replication stream name) instance_name: The name of this instance. tables: List of tables associated with the stream. Tuple of table name, column name that stores the writer's instance name, and column name that stores the stream ID. sequence_name: The name of the postgres sequence used to generate new IDs. writers: A list of known writers to use to populate current positions on startup. Can be empty if nothing uses `get_current_token` or `get_positions` (e.g. caches stream). positive: Whether the IDs are positive (true) or negative (false). When using negative IDs we go backwards from -1 to -2, -3, etc. """ def __init__( self, db_conn: LoggingDatabaseConnection, db: DatabasePool, notifier: "ReplicationNotifier", stream_name: str, instance_name: str, tables: List[Tuple[str, str, str]], sequence_name: str, writers: List[str], positive: bool = True, ) -> None: self._db = db self._notifier = notifier self._stream_name = stream_name self._instance_name = instance_name self._positive = positive self._writers = writers self._return_factor = 1 if positive else -1 # We lock as some functions may be called from DB threads. self._lock = threading.Lock() # Note: If we are a negative stream then we still store all the IDs as # positive to make life easier for us, and simply negate the IDs when we # return them. self._current_positions: Dict[str, int] = {} # Set of local IDs that we're still processing. The current position # should be less than the minimum of this set (if not empty). self._unfinished_ids: SortedSet[int] = SortedSet() # We also need to track when we've requested some new stream IDs but # they haven't yet been added to the `_unfinished_ids` set. Every time # we request a new stream ID we add the current max stream ID to the # list, and remove it once we've added the newly allocated IDs to the # `_unfinished_ids` set. This means that we *may* be allocated stream # IDs above those in the list, and so we can't advance the local current # position beyond the minimum stream ID in this list. self._in_flight_fetches: SortedList[int] = SortedList() # Set of local IDs that we've processed that are larger than the current # position, due to there being smaller unpersisted IDs. self._finished_ids: Set[int] = set() # We track the max position where we know everything before has been # persisted. This is done by a) looking at the min across all instances # and b) noting that if we have seen a run of persisted positions # without gaps (e.g. 5, 6, 7) then we can skip forward (e.g. to 7). # # Note: There is no guarantee that the IDs generated by the sequence # will be gapless; gaps can form when e.g. a transaction was rolled # back. This means that sometimes we won't be able to skip forward the # position even though everything has been persisted. However, since # gaps should be relatively rare it's still worth doing the book keeping # that allows us to skip forwards when there are gapless runs of # positions. # # We start at 1 here as a) the first generated stream ID will be 2, and # b) other parts of the code assume that stream IDs are strictly greater # than 0. self._persisted_upto_position = ( min(self._current_positions.values()) if self._current_positions else 1 ) self._known_persisted_positions: List[int] = [] # The maximum stream ID that we have seen been allocated across any writer. self._max_seen_allocated_stream_id = 1 # The maximum position of the local instance. This can be higher than # the corresponding position in `current_positions` table when there are # no active writes in progress. self._max_position_of_local_instance = self._max_seen_allocated_stream_id self._sequence_gen = build_sequence_generator( db_conn=db_conn, database_engine=db.engine, get_first_callback=lambda _: self._persisted_upto_position, sequence_name=sequence_name, # We only need to set the below if we want it to call # `check_consistency`, but we do that ourselves below so we can # leave them blank. table=None, id_column=None, stream_name=None, positive=positive, ) # We check that the table and sequence haven't diverged. for table, _, id_column in tables: self._sequence_gen.check_consistency( db_conn, table=table, id_column=id_column, stream_name=stream_name, positive=positive, ) # This goes and fills out the above state from the database. # This may read on the PostgreSQL sequence, and # SequenceGenerator.check_consistency might have fixed up the sequence, which # means the SequenceGenerator needs to be setup before we read the value from # the sequence. self._load_current_ids(db_conn, tables, sequence_name) self._max_seen_allocated_stream_id = max( self._current_positions.values(), default=1 ) # For the case where `stream_positions` is not up to date, # `_persisted_upto_position` may be higher. self._max_seen_allocated_stream_id = max( self._max_seen_allocated_stream_id, self._persisted_upto_position ) # Bump our local maximum position now that we've loaded things from the # DB. self._max_position_of_local_instance = self._max_seen_allocated_stream_id if not writers: # If there have been no explicit writers given then any instance can # write to the stream. In which case, let's pre-seed our own # position with the current minimum. self._current_positions[self._instance_name] = self._persisted_upto_position def _load_current_ids( self, db_conn: LoggingDatabaseConnection, tables: List[Tuple[str, str, str]], sequence_name: str, ) -> None: cur = db_conn.cursor(txn_name="_load_current_ids") # Load the current positions of all writers for the stream. if self._writers: # We delete any stale entries in the positions table. This is # important if we add back a writer after a long time; we want to # consider that a "new" writer, rather than using the old stale # entry here. clause, args = make_in_list_sql_clause( self._db.engine, "instance_name", self._writers, negative=True ) sql = f""" DELETE FROM stream_positions WHERE stream_name = ? AND {clause} """ cur.execute(sql, [self._stream_name] + args) sql = """ SELECT instance_name, stream_id FROM stream_positions WHERE stream_name = ? """ cur.execute(sql, (self._stream_name,)) self._current_positions = { instance: stream_id * self._return_factor for instance, stream_id in cur if instance in self._writers } # If we're a writer, we can assume we're at the end of the stream # Usually, we would get that from the stream_positions, but in some cases, # like if we rolled back Synapse, the stream_positions table might not be up to # date. If we're using Postgres for the sequences, we can just use the current # sequence value as our own position. if self._instance_name in self._writers: if isinstance(self._db.engine, PostgresEngine): cur.execute(f"SELECT last_value FROM {sequence_name}") row = cur.fetchone() assert row is not None self._current_positions[self._instance_name] = row[0] # We set the `_persisted_upto_position` to be the minimum of all current # positions. If empty we use the max stream ID from the DB table. min_stream_id = min(self._current_positions.values(), default=None) if min_stream_id is None: # We add a GREATEST here to ensure that the result is always # positive. (This can be a problem for e.g. backfill streams where # the server has never backfilled). greatest_func = ( "GREATEST" if isinstance(self._db.engine, PostgresEngine) else "MAX" ) max_stream_id = 1 for table, _, id_column in tables: sql = """ SELECT %(greatest_func)s(COALESCE(%(agg)s(%(id)s), 1), 1) FROM %(table)s """ % { "greatest_func": greatest_func, "id": id_column, "table": table, "agg": "MAX" if self._positive else "-MIN", } cur.execute(sql) result = cur.fetchone() assert result is not None (stream_id,) = result max_stream_id = max(max_stream_id, stream_id) self._persisted_upto_position = max_stream_id else: # If we have a min_stream_id then we pull out everything greater # than it from the DB so that we can prefill # `_known_persisted_positions` and get a more accurate # `_persisted_upto_position`. # # We also check if any of the later rows are from this instance, in # which case we use that for this instance's current position. This # is to handle the case where we didn't finish persisting to the # stream positions table before restart (or the stream position # table otherwise got out of date). self._persisted_upto_position = min_stream_id rows: List[Tuple[str, int]] = [] for table, instance_column, id_column in tables: sql = """ SELECT %(instance)s, %(id)s FROM %(table)s WHERE ? %(cmp)s %(id)s """ % { "id": id_column, "table": table, "instance": instance_column, "cmp": "<=" if self._positive else ">=", } cur.execute(sql, (min_stream_id * self._return_factor,)) # Cast safety: this corresponds to the types returned by the query above. rows.extend(cast(Iterable[Tuple[str, int]], cur)) # Sort by stream_id (ascending, lowest -> highest) so that we handle # rows in order for each instance because we don't want to overwrite # the current_position of an instance to a lower stream ID than # we're actually at. def sort_by_stream_id_key_func(row: Tuple[str, int]) -> int: (instance, stream_id) = row # If `stream_id` is ever `None`, we will see a `TypeError: '<' # not supported between instances of 'NoneType' and 'X'` error. return stream_id rows.sort(key=sort_by_stream_id_key_func) with self._lock: for ( instance, stream_id, ) in rows: stream_id = self._return_factor * stream_id self._add_persisted_position(stream_id) if instance == self._instance_name: self._current_positions[instance] = stream_id if self._writers: # If we have explicit writers then make sure that each instance has # a position. for writer in self._writers: self._current_positions.setdefault( writer, self._persisted_upto_position ) cur.close() def _load_next_id_txn(self, txn: Cursor) -> int: stream_ids = self._load_next_mult_id_txn(txn, 1) return stream_ids[0] def _load_next_mult_id_txn(self, txn: Cursor, n: int) -> List[int]: # We need to track that we've requested some more stream IDs, and what # the current max allocated stream ID is. This is to prevent a race # where we've been allocated stream IDs but they have not yet been added # to the `_unfinished_ids` set, allowing the current position to advance # past them. with self._lock: current_max = self._max_seen_allocated_stream_id self._in_flight_fetches.add(current_max) try: stream_ids = self._sequence_gen.get_next_mult_txn(txn, n) with self._lock: self._unfinished_ids.update(stream_ids) self._max_seen_allocated_stream_id = max( self._max_seen_allocated_stream_id, self._unfinished_ids[-1] ) finally: with self._lock: self._in_flight_fetches.remove(current_max) return stream_ids def get_next(self) -> AsyncContextManager[int]: # If we have a list of instances that are allowed to write to this # stream, make sure we're in it. if self._writers and self._instance_name not in self._writers: raise Exception("Tried to allocate stream ID on non-writer") # Cast safety: the second argument to _MultiWriterCtxManager, multiple_ids, # controls the return type. If `None` or omitted, the context manager yields # a single integer stream_id; otherwise it yields a list of stream_ids. return cast( AsyncContextManager[int], _MultiWriterCtxManager(self, self._notifier) ) def get_next_mult(self, n: int) -> AsyncContextManager[List[int]]: # If we have a list of instances that are allowed to write to this # stream, make sure we're in it. if self._writers and self._instance_name not in self._writers: raise Exception("Tried to allocate stream ID on non-writer") # Cast safety: see get_next. return cast( AsyncContextManager[List[int]], _MultiWriterCtxManager(self, self._notifier, n), ) def get_next_txn(self, txn: LoggingTransaction) -> int: """ Usage: stream_id = stream_id_gen.get_next_txn(txn) # ... persist event ... """ # If we have a list of instances that are allowed to write to this # stream, make sure we're in it. if self._writers and self._instance_name not in self._writers: raise Exception("Tried to allocate stream ID on non-writer") next_id = self._load_next_id_txn(txn) txn.call_after(self._mark_ids_as_finished, [next_id]) txn.call_on_exception(self._mark_ids_as_finished, [next_id]) txn.call_after(self._notifier.notify_replication) # Update the `stream_positions` table with newly updated stream # ID (unless self._writers is not set in which case we don't # bother, as nothing will read it). # # We only do this on the success path so that the persisted current # position points to a persisted row with the correct instance name. if self._writers: txn.call_after( run_as_background_process, "MultiWriterIdGenerator._update_table", self._db.runInteraction, "MultiWriterIdGenerator._update_table", self._update_stream_positions_table_txn, ) return self._return_factor * next_id def get_next_mult_txn(self, txn: LoggingTransaction, n: int) -> List[int]: """ Usage: stream_id = stream_id_gen.get_next_txn(txn) # ... persist event ... """ # If we have a list of instances that are allowed to write to this # stream, make sure we're in it. if self._writers and self._instance_name not in self._writers: raise Exception("Tried to allocate stream ID on non-writer") next_ids = self._load_next_mult_id_txn(txn, n) txn.call_after(self._mark_ids_as_finished, next_ids) txn.call_on_exception(self._mark_ids_as_finished, next_ids) txn.call_after(self._notifier.notify_replication) # Update the `stream_positions` table with newly updated stream # ID (unless self._writers is not set in which case we don't # bother, as nothing will read it). # # We only do this on the success path so that the persisted current # position points to a persisted row with the correct instance name. if self._writers: txn.call_after( run_as_background_process, "MultiWriterIdGenerator._update_table", self._db.runInteraction, "MultiWriterIdGenerator._update_table", self._update_stream_positions_table_txn, ) return [self._return_factor * next_id for next_id in next_ids] def _mark_ids_as_finished(self, next_ids: List[int]) -> None: """These IDs have finished being processed so we should advance the current position if possible. """ with self._lock: self._unfinished_ids.difference_update(next_ids) self._finished_ids.update(next_ids) new_cur: Optional[int] = None if self._unfinished_ids or self._in_flight_fetches: # If there are unfinished IDs then the new position will be the # largest finished ID strictly less than the minimum unfinished # ID. # The minimum unfinished ID needs to take account of both # `_unfinished_ids` and `_in_flight_fetches`. if self._unfinished_ids and self._in_flight_fetches: # `_in_flight_fetches` stores the maximum safe stream ID, so # we add one to make it equivalent to the minimum unsafe ID. min_unfinished = min( self._unfinished_ids[0], self._in_flight_fetches[0] + 1 ) elif self._in_flight_fetches: min_unfinished = self._in_flight_fetches[0] + 1 else: min_unfinished = self._unfinished_ids[0] finished = set() for s in self._finished_ids: if s < min_unfinished: if new_cur is None or new_cur < s: new_cur = s else: finished.add(s) # We clear these out since they're now all less than the new # position. self._finished_ids = finished else: # There are no unfinished IDs so the new position is simply the # largest finished one. new_cur = max(self._finished_ids) # We clear these out since they're now all less than the new # position. self._finished_ids.clear() if new_cur: curr = self._current_positions.get(self._instance_name, 0) self._current_positions[self._instance_name] = max(curr, new_cur) self._max_position_of_local_instance = max( curr, new_cur, self._max_position_of_local_instance ) # TODO Can we call this for just the last position or somehow batch # _add_persisted_position. for next_id in next_ids: self._add_persisted_position(next_id) def get_current_token(self) -> int: return self.get_persisted_upto_position() def get_current_token_for_writer(self, instance_name: str) -> int: # If we don't have an entry for the given instance name, we assume it's a # new writer. # # For new writers we assume their initial position to be the current # persisted up to position. This stops Synapse from doing a full table # scan when a new writer announces itself over replication. with self._lock: if self._instance_name == instance_name: return self._return_factor * self._max_position_of_local_instance pos = self._current_positions.get( instance_name, self._persisted_upto_position ) # We want to return the maximum "current token" that we can for a # writer, this helps ensure that streams progress as fast as # possible. pos = max(pos, self._persisted_upto_position) return self._return_factor * pos def get_minimal_local_current_token(self) -> int: with self._lock: return self._return_factor * self._current_positions.get( self._instance_name, self._persisted_upto_position ) def get_positions(self) -> Dict[str, int]: """Get a copy of the current positon map. Note that this won't necessarily include all configured writers if some writers haven't written anything yet. """ with self._lock: return { name: self._return_factor * i for name, i in self._current_positions.items() } def advance(self, instance_name: str, new_id: int) -> None: new_id *= self._return_factor with self._lock: self._current_positions[instance_name] = max( new_id, self._current_positions.get(instance_name, 0) ) self._max_seen_allocated_stream_id = max( self._max_seen_allocated_stream_id, new_id ) self._add_persisted_position(new_id) def get_persisted_upto_position(self) -> int: """Get the max position where all previous positions have been persisted. Note: In the worst case scenario this will be equal to the minimum position across writers. This means that the returned position here can lag if one writer doesn't write very often. """ with self._lock: return self._return_factor * self._persisted_upto_position def _add_persisted_position(self, new_id: int) -> None: """Record that we have persisted a position. This is used to keep the `_current_positions` up to date. """ # We require that the lock is locked by caller assert self._lock.locked() heapq.heappush(self._known_persisted_positions, new_id) # We move the current min position up if the minimum current positions # of all instances is higher (since by definition all positions less # that that have been persisted). our_current_position = self._current_positions.get(self._instance_name, 0) min_curr = min( ( token for name, token in self._current_positions.items() if name != self._instance_name ), default=our_current_position, ) if our_current_position and (self._unfinished_ids or self._in_flight_fetches): min_curr = min(min_curr, our_current_position) self._persisted_upto_position = max(min_curr, self._persisted_upto_position) # Advance our local max position. self._max_position_of_local_instance = max( self._max_position_of_local_instance, self._persisted_upto_position ) if not self._unfinished_ids and not self._in_flight_fetches: # If we don't have anything in flight, it's safe to advance to the # max seen stream ID. self._max_position_of_local_instance = max( self._max_seen_allocated_stream_id, self._max_position_of_local_instance ) # We now iterate through the seen positions, discarding those that are # less than the current min positions, and incrementing the min position # if its exactly one greater. # # This is also where we discard items from `_known_persisted_positions` # (to ensure the list doesn't infinitely grow). while self._known_persisted_positions: if self._known_persisted_positions[0] <= self._persisted_upto_position: heapq.heappop(self._known_persisted_positions) elif ( self._known_persisted_positions[0] == self._persisted_upto_position + 1 ): heapq.heappop(self._known_persisted_positions) self._persisted_upto_position += 1 else: # There was a gap in seen positions, so there is nothing more to # do. break def _update_stream_positions_table_txn(self, txn: Cursor) -> None: """Update the `stream_positions` table with newly persisted position.""" if not self._writers: return # We upsert the value, ensuring on conflict that we always increase the # value (or decrease if stream goes backwards). if isinstance(self._db.engine, PostgresEngine): agg = "GREATEST" if self._positive else "LEAST" else: agg = "MAX" if self._positive else "MIN" sql = """ INSERT INTO stream_positions (stream_name, instance_name, stream_id) VALUES (?, ?, ?) ON CONFLICT (stream_name, instance_name) DO UPDATE SET stream_id = %(agg)s(stream_positions.stream_id, EXCLUDED.stream_id) """ % { "agg": agg, } pos = self.get_current_token_for_writer(self._instance_name) txn.execute(sql, (self._stream_name, self._instance_name, pos)) @attr.s(frozen=True, auto_attribs=True) class _AsyncCtxManagerWrapper(Generic[T]): """Helper class to convert a plain context manager to an async one. This is mainly useful if you have a plain context manager but the interface requires an async one. """ inner: ContextManager[T] async def __aenter__(self) -> T: return self.inner.__enter__() async def __aexit__( self, exc_type: Optional[Type[BaseException]], exc: Optional[BaseException], tb: Optional[TracebackType], ) -> Optional[bool]: return self.inner.__exit__(exc_type, exc, tb) @attr.s(slots=True, auto_attribs=True) class _MultiWriterCtxManager: """Async context manager returned by MultiWriterIdGenerator""" id_gen: MultiWriterIdGenerator notifier: "ReplicationNotifier" multiple_ids: Optional[int] = None stream_ids: List[int] = attr.Factory(list) async def __aenter__(self) -> Union[int, List[int]]: # It's safe to run this in autocommit mode as fetching values from a # sequence ignores transaction semantics anyway. self.stream_ids = await self.id_gen._db.runInteraction( "_load_next_mult_id", self.id_gen._load_next_mult_id_txn, self.multiple_ids or 1, db_autocommit=True, ) if self.multiple_ids is None: return self.stream_ids[0] * self.id_gen._return_factor else: return [i * self.id_gen._return_factor for i in self.stream_ids] async def __aexit__( self, exc_type: Optional[Type[BaseException]], exc: Optional[BaseException], tb: Optional[TracebackType], ) -> bool: self.id_gen._mark_ids_as_finished(self.stream_ids) self.notifier.notify_replication() if exc_type is not None: return False # Update the `stream_positions` table with newly updated stream # ID (unless self._writers is not set in which case we don't # bother, as nothing will read it). # # We only do this on the success path so that the persisted current # position points to a persisted row with the correct instance name. # # We do this in autocommit mode as a) the upsert works correctly outside # transactions and b) reduces the amount of time the rows are locked # for. If we don't do this then we'll often hit serialization errors due # to the fact we default to REPEATABLE READ isolation levels. if self.id_gen._writers: await self.id_gen._db.runInteraction( "MultiWriterIdGenerator._update_table", self.id_gen._update_stream_positions_table_txn, db_autocommit=True, ) return False