Speed up chain cover calculation (#9176)

pull/9199/head
Erik Johnston 2021-01-21 17:00:12 +00:00 committed by GitHub
parent 12ec55bfaa
commit 758ed5f1bc
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3 changed files with 161 additions and 55 deletions

1
changelog.d/9176.misc Normal file
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@ -0,0 +1 @@
Speed up chain cover calculation when persisting a batch of state events at once.

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@ -473,8 +473,9 @@ class PersistEventsStore:
txn, self.db_pool, event_to_room_id, event_to_types, event_to_auth_chain,
)
@staticmethod
@classmethod
def _add_chain_cover_index(
cls,
txn,
db_pool: DatabasePool,
event_to_room_id: Dict[str, str],
@ -614,60 +615,17 @@ class PersistEventsStore:
if not events_to_calc_chain_id_for:
return
# We now calculate the chain IDs/sequence numbers for the events. We
# do this by looking at the chain ID and sequence number of any auth
# event with the same type/state_key and incrementing the sequence
# number by one. If there was no match or the chain ID/sequence
# number is already taken we generate a new chain.
#
# We need to do this in a topologically sorted order as we want to
# generate chain IDs/sequence numbers of an event's auth events
# before the event itself.
chains_tuples_allocated = set() # type: Set[Tuple[int, int]]
new_chain_tuples = {} # type: Dict[str, Tuple[int, int]]
for event_id in sorted_topologically(
events_to_calc_chain_id_for, event_to_auth_chain
):
existing_chain_id = None
for auth_id in event_to_auth_chain.get(event_id, []):
if event_to_types.get(event_id) == event_to_types.get(auth_id):
existing_chain_id = chain_map[auth_id]
break
new_chain_tuple = None
if existing_chain_id:
# We found a chain ID/sequence number candidate, check its
# not already taken.
proposed_new_id = existing_chain_id[0]
proposed_new_seq = existing_chain_id[1] + 1
if (proposed_new_id, proposed_new_seq) not in chains_tuples_allocated:
already_allocated = db_pool.simple_select_one_onecol_txn(
txn,
table="event_auth_chains",
keyvalues={
"chain_id": proposed_new_id,
"sequence_number": proposed_new_seq,
},
retcol="event_id",
allow_none=True,
)
if already_allocated:
# Mark it as already allocated so we don't need to hit
# the DB again.
chains_tuples_allocated.add((proposed_new_id, proposed_new_seq))
else:
new_chain_tuple = (
proposed_new_id,
proposed_new_seq,
)
if not new_chain_tuple:
new_chain_tuple = (db_pool.event_chain_id_gen.get_next_id_txn(txn), 1)
chains_tuples_allocated.add(new_chain_tuple)
chain_map[event_id] = new_chain_tuple
new_chain_tuples[event_id] = new_chain_tuple
# Allocate chain ID/sequence numbers to each new event.
new_chain_tuples = cls._allocate_chain_ids(
txn,
db_pool,
event_to_room_id,
event_to_types,
event_to_auth_chain,
events_to_calc_chain_id_for,
chain_map,
)
chain_map.update(new_chain_tuples)
db_pool.simple_insert_many_txn(
txn,
@ -794,6 +752,137 @@ class PersistEventsStore:
],
)
@staticmethod
def _allocate_chain_ids(
txn,
db_pool: DatabasePool,
event_to_room_id: Dict[str, str],
event_to_types: Dict[str, Tuple[str, str]],
event_to_auth_chain: Dict[str, List[str]],
events_to_calc_chain_id_for: Set[str],
chain_map: Dict[str, Tuple[int, int]],
) -> Dict[str, Tuple[int, int]]:
"""Allocates, but does not persist, chain ID/sequence numbers for the
events in `events_to_calc_chain_id_for`. (c.f. _add_chain_cover_index
for info on args)
"""
# We now calculate the chain IDs/sequence numbers for the events. We do
# this by looking at the chain ID and sequence number of any auth event
# with the same type/state_key and incrementing the sequence number by
# one. If there was no match or the chain ID/sequence number is already
# taken we generate a new chain.
#
# We try to reduce the number of times that we hit the database by
# batching up calls, to make this more efficient when persisting large
# numbers of state events (e.g. during joins).
#
# We do this by:
# 1. Calculating for each event which auth event will be used to
# inherit the chain ID, i.e. converting the auth chain graph to a
# tree that we can allocate chains on. We also keep track of which
# existing chain IDs have been referenced.
# 2. Fetching the max allocated sequence number for each referenced
# existing chain ID, generating a map from chain ID to the max
# allocated sequence number.
# 3. Iterating over the tree and allocating a chain ID/seq no. to the
# new event, by incrementing the sequence number from the
# referenced event's chain ID/seq no. and checking that the
# incremented sequence number hasn't already been allocated (by
# looking in the map generated in the previous step). We generate a
# new chain if the sequence number has already been allocated.
#
existing_chains = set() # type: Set[int]
tree = [] # type: List[Tuple[str, Optional[str]]]
# We need to do this in a topologically sorted order as we want to
# generate chain IDs/sequence numbers of an event's auth events before
# the event itself.
for event_id in sorted_topologically(
events_to_calc_chain_id_for, event_to_auth_chain
):
for auth_id in event_to_auth_chain.get(event_id, []):
if event_to_types.get(event_id) == event_to_types.get(auth_id):
existing_chain_id = chain_map.get(auth_id)
if existing_chain_id:
existing_chains.add(existing_chain_id[0])
tree.append((event_id, auth_id))
break
else:
tree.append((event_id, None))
# Fetch the current max sequence number for each existing referenced chain.
sql = """
SELECT chain_id, MAX(sequence_number) FROM event_auth_chains
WHERE %s
GROUP BY chain_id
"""
clause, args = make_in_list_sql_clause(
db_pool.engine, "chain_id", existing_chains
)
txn.execute(sql % (clause,), args)
chain_to_max_seq_no = {row[0]: row[1] for row in txn} # type: Dict[Any, int]
# Allocate the new events chain ID/sequence numbers.
#
# To reduce the number of calls to the database we don't allocate a
# chain ID number in the loop, instead we use a temporary `object()` for
# each new chain ID. Once we've done the loop we generate the necessary
# number of new chain IDs in one call, replacing all temporary
# objects with real allocated chain IDs.
unallocated_chain_ids = set() # type: Set[object]
new_chain_tuples = {} # type: Dict[str, Tuple[Any, int]]
for event_id, auth_event_id in tree:
# If we reference an auth_event_id we fetch the allocated chain ID,
# either from the existing `chain_map` or the newly generated
# `new_chain_tuples` map.
existing_chain_id = None
if auth_event_id:
existing_chain_id = new_chain_tuples.get(auth_event_id)
if not existing_chain_id:
existing_chain_id = chain_map[auth_event_id]
new_chain_tuple = None # type: Optional[Tuple[Any, int]]
if existing_chain_id:
# We found a chain ID/sequence number candidate, check its
# not already taken.
proposed_new_id = existing_chain_id[0]
proposed_new_seq = existing_chain_id[1] + 1
if chain_to_max_seq_no[proposed_new_id] < proposed_new_seq:
new_chain_tuple = (
proposed_new_id,
proposed_new_seq,
)
# If we need to start a new chain we allocate a temporary chain ID.
if not new_chain_tuple:
new_chain_tuple = (object(), 1)
unallocated_chain_ids.add(new_chain_tuple[0])
new_chain_tuples[event_id] = new_chain_tuple
chain_to_max_seq_no[new_chain_tuple[0]] = new_chain_tuple[1]
# Generate new chain IDs for all unallocated chain IDs.
newly_allocated_chain_ids = db_pool.event_chain_id_gen.get_next_mult_txn(
txn, len(unallocated_chain_ids)
)
# Map from potentially temporary chain ID to real chain ID
chain_id_to_allocated_map = dict(
zip(unallocated_chain_ids, newly_allocated_chain_ids)
) # type: Dict[Any, int]
chain_id_to_allocated_map.update((c, c) for c in existing_chains)
return {
event_id: (chain_id_to_allocated_map[chain_id], seq)
for event_id, (chain_id, seq) in new_chain_tuples.items()
}
def _persist_transaction_ids_txn(
self,
txn: LoggingTransaction,

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@ -69,6 +69,11 @@ class SequenceGenerator(metaclass=abc.ABCMeta):
"""Gets the next ID in the sequence"""
...
@abc.abstractmethod
def get_next_mult_txn(self, txn: Cursor, n: int) -> List[int]:
"""Get the next `n` IDs in the sequence"""
...
@abc.abstractmethod
def check_consistency(
self,
@ -219,6 +224,17 @@ class LocalSequenceGenerator(SequenceGenerator):
self._current_max_id += 1
return self._current_max_id
def get_next_mult_txn(self, txn: Cursor, n: int) -> List[int]:
with self._lock:
if self._current_max_id is None:
assert self._callback is not None
self._current_max_id = self._callback(txn)
self._callback = None
first_id = self._current_max_id + 1
self._current_max_id += n
return [first_id + i for i in range(n)]
def check_consistency(
self,
db_conn: Connection,