mirror of
https://git.anonymousland.org/anonymousland/synapse-product.git
synced 2024-12-11 13:24:19 -05:00
582 lines
21 KiB
Python
582 lines
21 KiB
Python
# -*- coding: utf-8 -*-
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# Copyright 2016 OpenMarket Ltd
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#
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# Licensed under the Apache License, Version 2.0 (the "License");
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# you may not use this file except in compliance with the License.
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# You may obtain a copy of the License at
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#
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# http://www.apache.org/licenses/LICENSE-2.0
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#
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# Unless required by applicable law or agreed to in writing, software
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# distributed under the License is distributed on an "AS IS" BASIS,
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# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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# See the License for the specific language governing permissions and
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# limitations under the License.
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import logging
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from six import iteritems
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from twisted.internet import defer
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from synapse.metrics.background_process_metrics import wrap_as_background_process
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from synapse.util.caches import CACHE_SIZE_FACTOR
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from . import background_updates
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from ._base import Cache
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logger = logging.getLogger(__name__)
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# Number of msec of granularity to store the user IP 'last seen' time. Smaller
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# times give more inserts into the database even for readonly API hits
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# 120 seconds == 2 minutes
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LAST_SEEN_GRANULARITY = 120 * 1000
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class ClientIpBackgroundUpdateStore(background_updates.BackgroundUpdateStore):
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def __init__(self, db_conn, hs):
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super(ClientIpBackgroundUpdateStore, self).__init__(db_conn, hs)
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self.register_background_index_update(
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"user_ips_device_index",
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index_name="user_ips_device_id",
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table="user_ips",
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columns=["user_id", "device_id", "last_seen"],
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)
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self.register_background_index_update(
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"user_ips_last_seen_index",
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index_name="user_ips_last_seen",
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table="user_ips",
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columns=["user_id", "last_seen"],
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)
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self.register_background_index_update(
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"user_ips_last_seen_only_index",
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index_name="user_ips_last_seen_only",
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table="user_ips",
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columns=["last_seen"],
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)
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self.register_background_update_handler(
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"user_ips_analyze", self._analyze_user_ip
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)
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self.register_background_update_handler(
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"user_ips_remove_dupes", self._remove_user_ip_dupes
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)
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# Register a unique index
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self.register_background_index_update(
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"user_ips_device_unique_index",
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index_name="user_ips_user_token_ip_unique_index",
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table="user_ips",
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columns=["user_id", "access_token", "ip"],
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unique=True,
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)
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# Drop the old non-unique index
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self.register_background_update_handler(
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"user_ips_drop_nonunique_index", self._remove_user_ip_nonunique
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)
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# Update the last seen info in devices.
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self.register_background_update_handler(
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"devices_last_seen", self._devices_last_seen_update
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)
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@defer.inlineCallbacks
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def _remove_user_ip_nonunique(self, progress, batch_size):
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def f(conn):
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txn = conn.cursor()
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txn.execute("DROP INDEX IF EXISTS user_ips_user_ip")
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txn.close()
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yield self.runWithConnection(f)
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yield self._end_background_update("user_ips_drop_nonunique_index")
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return 1
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@defer.inlineCallbacks
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def _analyze_user_ip(self, progress, batch_size):
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# Background update to analyze user_ips table before we run the
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# deduplication background update. The table may not have been analyzed
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# for ages due to the table locks.
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#
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# This will lock out the naive upserts to user_ips while it happens, but
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# the analyze should be quick (28GB table takes ~10s)
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def user_ips_analyze(txn):
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txn.execute("ANALYZE user_ips")
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yield self.runInteraction("user_ips_analyze", user_ips_analyze)
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yield self._end_background_update("user_ips_analyze")
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return 1
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@defer.inlineCallbacks
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def _remove_user_ip_dupes(self, progress, batch_size):
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# This works function works by scanning the user_ips table in batches
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# based on `last_seen`. For each row in a batch it searches the rest of
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# the table to see if there are any duplicates, if there are then they
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# are removed and replaced with a suitable row.
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# Fetch the start of the batch
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begin_last_seen = progress.get("last_seen", 0)
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def get_last_seen(txn):
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txn.execute(
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"""
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SELECT last_seen FROM user_ips
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WHERE last_seen > ?
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ORDER BY last_seen
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LIMIT 1
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OFFSET ?
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""",
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(begin_last_seen, batch_size),
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)
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row = txn.fetchone()
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if row:
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return row[0]
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else:
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return None
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# Get a last seen that has roughly `batch_size` since `begin_last_seen`
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end_last_seen = yield self.runInteraction(
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"user_ips_dups_get_last_seen", get_last_seen
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)
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# If it returns None, then we're processing the last batch
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last = end_last_seen is None
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logger.info(
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"Scanning for duplicate 'user_ips' rows in range: %s <= last_seen < %s",
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begin_last_seen,
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end_last_seen,
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)
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def remove(txn):
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# This works by looking at all entries in the given time span, and
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# then for each (user_id, access_token, ip) tuple in that range
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# checking for any duplicates in the rest of the table (via a join).
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# It then only returns entries which have duplicates, and the max
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# last_seen across all duplicates, which can the be used to delete
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# all other duplicates.
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# It is efficient due to the existence of (user_id, access_token,
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# ip) and (last_seen) indices.
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# Define the search space, which requires handling the last batch in
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# a different way
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if last:
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clause = "? <= last_seen"
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args = (begin_last_seen,)
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else:
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clause = "? <= last_seen AND last_seen < ?"
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args = (begin_last_seen, end_last_seen)
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# (Note: The DISTINCT in the inner query is important to ensure that
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# the COUNT(*) is accurate, otherwise double counting may happen due
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# to the join effectively being a cross product)
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txn.execute(
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"""
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SELECT user_id, access_token, ip,
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MAX(device_id), MAX(user_agent), MAX(last_seen),
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COUNT(*)
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FROM (
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SELECT DISTINCT user_id, access_token, ip
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FROM user_ips
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WHERE {}
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) c
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INNER JOIN user_ips USING (user_id, access_token, ip)
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GROUP BY user_id, access_token, ip
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HAVING count(*) > 1
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""".format(
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clause
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),
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args,
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)
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res = txn.fetchall()
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# We've got some duplicates
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for i in res:
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user_id, access_token, ip, device_id, user_agent, last_seen, count = i
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# We want to delete the duplicates so we end up with only a
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# single row.
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#
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# The naive way of doing this would be just to delete all rows
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# and reinsert a constructed row. However, if there are a lot of
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# duplicate rows this can cause the table to grow a lot, which
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# can be problematic in two ways:
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# 1. If user_ips is already large then this can cause the
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# table to rapidly grow, potentially filling the disk.
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# 2. Reinserting a lot of rows can confuse the table
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# statistics for postgres, causing it to not use the
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# correct indices for the query above, resulting in a full
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# table scan. This is incredibly slow for large tables and
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# can kill database performance. (This seems to mainly
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# happen for the last query where the clause is simply `? <
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# last_seen`)
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#
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# So instead we want to delete all but *one* of the duplicate
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# rows. That is hard to do reliably, so we cheat and do a two
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# step process:
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# 1. Delete all rows with a last_seen strictly less than the
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# max last_seen. This hopefully results in deleting all but
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# one row the majority of the time, but there may be
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# duplicate last_seen
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# 2. If multiple rows remain, we fall back to the naive method
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# and simply delete all rows and reinsert.
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#
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# Note that this relies on no new duplicate rows being inserted,
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# but if that is happening then this entire process is futile
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# anyway.
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# Do step 1:
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txn.execute(
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"""
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DELETE FROM user_ips
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WHERE user_id = ? AND access_token = ? AND ip = ? AND last_seen < ?
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""",
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(user_id, access_token, ip, last_seen),
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)
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if txn.rowcount == count - 1:
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# We deleted all but one of the duplicate rows, i.e. there
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# is exactly one remaining and so there is nothing left to
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# do.
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continue
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elif txn.rowcount >= count:
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raise Exception(
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"We deleted more duplicate rows from 'user_ips' than expected"
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)
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# The previous step didn't delete enough rows, so we fallback to
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# step 2:
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# Drop all the duplicates
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txn.execute(
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"""
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DELETE FROM user_ips
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WHERE user_id = ? AND access_token = ? AND ip = ?
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""",
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(user_id, access_token, ip),
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)
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# Add in one to be the last_seen
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txn.execute(
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"""
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INSERT INTO user_ips
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(user_id, access_token, ip, device_id, user_agent, last_seen)
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VALUES (?, ?, ?, ?, ?, ?)
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""",
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(user_id, access_token, ip, device_id, user_agent, last_seen),
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)
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self._background_update_progress_txn(
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txn, "user_ips_remove_dupes", {"last_seen": end_last_seen}
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)
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yield self.runInteraction("user_ips_dups_remove", remove)
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if last:
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yield self._end_background_update("user_ips_remove_dupes")
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return batch_size
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@defer.inlineCallbacks
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def _devices_last_seen_update(self, progress, batch_size):
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"""Background update to insert last seen info into devices table
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"""
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last_user_id = progress.get("last_user_id", "")
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last_device_id = progress.get("last_device_id", "")
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def _devices_last_seen_update_txn(txn):
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# This consists of two queries:
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#
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# 1. The sub-query searches for the next N devices and joins
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# against user_ips to find the max last_seen associated with
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# that device.
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# 2. The outer query then joins again against user_ips on
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# user/device/last_seen. This *should* hopefully only
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# return one row, but if it does return more than one then
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# we'll just end up updating the same device row multiple
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# times, which is fine.
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if self.database_engine.supports_tuple_comparison:
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where_clause = "(user_id, device_id) > (?, ?)"
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where_args = [last_user_id, last_device_id]
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else:
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# We explicitly do a `user_id >= ? AND (...)` here to ensure
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# that an index is used, as doing `user_id > ? OR (user_id = ? AND ...)`
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# makes it hard for query optimiser to tell that it can use the
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# index on user_id
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where_clause = "user_id >= ? AND (user_id > ? OR device_id > ?)"
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where_args = [last_user_id, last_user_id, last_device_id]
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sql = """
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SELECT
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last_seen, ip, user_agent, user_id, device_id
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FROM (
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SELECT
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user_id, device_id, MAX(u.last_seen) AS last_seen
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FROM devices
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INNER JOIN user_ips AS u USING (user_id, device_id)
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WHERE %(where_clause)s
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GROUP BY user_id, device_id
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ORDER BY user_id ASC, device_id ASC
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LIMIT ?
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) c
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INNER JOIN user_ips AS u USING (user_id, device_id, last_seen)
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""" % {
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"where_clause": where_clause
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}
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txn.execute(sql, where_args + [batch_size])
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rows = txn.fetchall()
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if not rows:
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return 0
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sql = """
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UPDATE devices
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SET last_seen = ?, ip = ?, user_agent = ?
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WHERE user_id = ? AND device_id = ?
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"""
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txn.execute_batch(sql, rows)
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_, _, _, user_id, device_id = rows[-1]
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self._background_update_progress_txn(
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txn,
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"devices_last_seen",
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{"last_user_id": user_id, "last_device_id": device_id},
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)
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return len(rows)
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updated = yield self.runInteraction(
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"_devices_last_seen_update", _devices_last_seen_update_txn
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)
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if not updated:
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yield self._end_background_update("devices_last_seen")
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return updated
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class ClientIpStore(ClientIpBackgroundUpdateStore):
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def __init__(self, db_conn, hs):
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self.client_ip_last_seen = Cache(
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name="client_ip_last_seen", keylen=4, max_entries=50000 * CACHE_SIZE_FACTOR
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)
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super(ClientIpStore, self).__init__(db_conn, hs)
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self.user_ips_max_age = hs.config.user_ips_max_age
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# (user_id, access_token, ip,) -> (user_agent, device_id, last_seen)
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self._batch_row_update = {}
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self._client_ip_looper = self._clock.looping_call(
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self._update_client_ips_batch, 5 * 1000
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)
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self.hs.get_reactor().addSystemEventTrigger(
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"before", "shutdown", self._update_client_ips_batch
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)
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if self.user_ips_max_age:
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self._clock.looping_call(self._prune_old_user_ips, 5 * 1000)
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@defer.inlineCallbacks
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def insert_client_ip(
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self, user_id, access_token, ip, user_agent, device_id, now=None
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):
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if not now:
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now = int(self._clock.time_msec())
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key = (user_id, access_token, ip)
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try:
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last_seen = self.client_ip_last_seen.get(key)
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except KeyError:
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last_seen = None
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yield self.populate_monthly_active_users(user_id)
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# Rate-limited inserts
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if last_seen is not None and (now - last_seen) < LAST_SEEN_GRANULARITY:
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return
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self.client_ip_last_seen.prefill(key, now)
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self._batch_row_update[key] = (user_agent, device_id, now)
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@wrap_as_background_process("update_client_ips")
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def _update_client_ips_batch(self):
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# If the DB pool has already terminated, don't try updating
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if not self.hs.get_db_pool().running:
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return
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to_update = self._batch_row_update
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self._batch_row_update = {}
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return self.runInteraction(
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"_update_client_ips_batch", self._update_client_ips_batch_txn, to_update
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)
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def _update_client_ips_batch_txn(self, txn, to_update):
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if "user_ips" in self._unsafe_to_upsert_tables or (
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not self.database_engine.can_native_upsert
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):
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self.database_engine.lock_table(txn, "user_ips")
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for entry in iteritems(to_update):
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(user_id, access_token, ip), (user_agent, device_id, last_seen) = entry
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try:
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self._simple_upsert_txn(
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txn,
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table="user_ips",
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keyvalues={
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"user_id": user_id,
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"access_token": access_token,
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"ip": ip,
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},
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values={
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"user_agent": user_agent,
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"device_id": device_id,
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"last_seen": last_seen,
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},
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lock=False,
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)
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# Technically an access token might not be associated with
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# a device so we need to check.
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if device_id:
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self._simple_upsert_txn(
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txn,
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table="devices",
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keyvalues={"user_id": user_id, "device_id": device_id},
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values={
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"user_agent": user_agent,
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"last_seen": last_seen,
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"ip": ip,
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},
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lock=False,
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)
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except Exception as e:
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# Failed to upsert, log and continue
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logger.error("Failed to insert client IP %r: %r", entry, e)
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@defer.inlineCallbacks
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def get_last_client_ip_by_device(self, user_id, device_id):
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"""For each device_id listed, give the user_ip it was last seen on
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Args:
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user_id (str)
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device_id (str): If None fetches all devices for the user
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Returns:
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defer.Deferred: resolves to a dict, where the keys
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are (user_id, device_id) tuples. The values are also dicts, with
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keys giving the column names
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"""
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keyvalues = {"user_id": user_id}
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if device_id is not None:
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keyvalues["device_id"] = device_id
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res = yield self._simple_select_list(
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table="devices",
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keyvalues=keyvalues,
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retcols=("user_id", "ip", "user_agent", "device_id", "last_seen"),
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)
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ret = {(d["user_id"], d["device_id"]): d for d in res}
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for key in self._batch_row_update:
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uid, access_token, ip = key
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if uid == user_id:
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user_agent, did, last_seen = self._batch_row_update[key]
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if not device_id or did == device_id:
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ret[(user_id, device_id)] = {
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"user_id": user_id,
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"access_token": access_token,
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"ip": ip,
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"user_agent": user_agent,
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"device_id": did,
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"last_seen": last_seen,
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}
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return ret
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@defer.inlineCallbacks
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def get_user_ip_and_agents(self, user):
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user_id = user.to_string()
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results = {}
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for key in self._batch_row_update:
|
|
uid, access_token, ip, = key
|
|
if uid == user_id:
|
|
user_agent, _, last_seen = self._batch_row_update[key]
|
|
results[(access_token, ip)] = (user_agent, last_seen)
|
|
|
|
rows = yield self._simple_select_list(
|
|
table="user_ips",
|
|
keyvalues={"user_id": user_id},
|
|
retcols=["access_token", "ip", "user_agent", "last_seen"],
|
|
desc="get_user_ip_and_agents",
|
|
)
|
|
|
|
results.update(
|
|
((row["access_token"], row["ip"]), (row["user_agent"], row["last_seen"]))
|
|
for row in rows
|
|
)
|
|
return list(
|
|
{
|
|
"access_token": access_token,
|
|
"ip": ip,
|
|
"user_agent": user_agent,
|
|
"last_seen": last_seen,
|
|
}
|
|
for (access_token, ip), (user_agent, last_seen) in iteritems(results)
|
|
)
|
|
|
|
@wrap_as_background_process("prune_old_user_ips")
|
|
async def _prune_old_user_ips(self):
|
|
"""Removes entries in user IPs older than the configured period.
|
|
"""
|
|
|
|
if self.user_ips_max_age is None:
|
|
# Nothing to do
|
|
return
|
|
|
|
if not await self.has_completed_background_update("devices_last_seen"):
|
|
# Only start pruning if we have finished populating the devices
|
|
# last seen info.
|
|
return
|
|
|
|
# We do a slightly funky SQL delete to ensure we don't try and delete
|
|
# too much at once (as the table may be very large from before we
|
|
# started pruning).
|
|
#
|
|
# This works by finding the max last_seen that is less than the given
|
|
# time, but has no more than N rows before it, deleting all rows with
|
|
# a lesser last_seen time. (We COALESCE so that the sub-SELECT always
|
|
# returns exactly one row).
|
|
sql = """
|
|
DELETE FROM user_ips
|
|
WHERE last_seen <= (
|
|
SELECT COALESCE(MAX(last_seen), -1)
|
|
FROM (
|
|
SELECT last_seen FROM user_ips
|
|
WHERE last_seen <= ?
|
|
ORDER BY last_seen ASC
|
|
LIMIT 5000
|
|
) AS u
|
|
)
|
|
"""
|
|
|
|
timestamp = self.clock.time_msec() - self.user_ips_max_age
|
|
|
|
def _prune_old_user_ips_txn(txn):
|
|
txn.execute(sql, (timestamp,))
|
|
|
|
await self.runInteraction("_prune_old_user_ips", _prune_old_user_ips_txn)
|