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mirror of https://github.com/funamitech/mastodon synced 2024-11-27 22:38:42 +09:00
YuruToot/lib/mastodon/snowflake.rb
Claire 4ac78e2a06
Add feature to automatically delete old toots (#16529)
* Add account statuses cleanup policy model

* Record last inspected toot to delete to speed up successive calls to statuses_to_delete

* Add service to cleanup a given account's statuses within a budget

* Add worker to go through account policies and delete old toots

* Fix last inspected status id logic

All existing statuses older or equal to last inspected status id must be
kept by the current policy. This is an invariant that must be kept so that
resuming deletion from the last inspected status remains sound.

* Add tests

* Refactor scheduler and add tests

* Add user interface

* Add support for discriminating based on boosts/favs

* Add UI support for min_reblogs and min_favs, rework UI

* Address first round of review comments

* Replace Snowflake#id_at_start with with_random parameter

* Add tests

* Add tests for StatusesCleanupController

* Rework settings page

* Adjust load-avoiding mechanisms

* Please CodeClimate
2021-08-09 23:11:50 +02:00

164 lines
5.1 KiB
Ruby

# frozen_string_literal: true
module Mastodon::Snowflake
DEFAULT_REGEX = /timestamp_id\('(?<seq_prefix>\w+)'/
class Callbacks
def self.around_create(record)
now = Time.now.utc
if record.created_at.nil? || record.created_at >= now || record.created_at == record.updated_at || record.override_timestamps
yield
else
record.id = Mastodon::Snowflake.id_at(record.created_at)
tries = 0
begin
yield
rescue ActiveRecord::RecordNotUnique
raise if tries > 100
tries += 1
record.id += rand(100)
retry
end
end
end
end
class << self
# Our ID will be composed of the following:
# 6 bytes (48 bits) of millisecond-level timestamp
# 2 bytes (16 bits) of sequence data
#
# The 'sequence data' is intended to be unique within a
# given millisecond, yet obscure the 'serial number' of
# this row.
#
# To do this, we hash the following data:
# * Table name (if provided, skipped if not)
# * Secret salt (should not be guessable)
# * Timestamp (again, millisecond-level granularity)
#
# We then take the first two bytes of that value, and add
# the lowest two bytes of the table ID sequence number
# (`table_name`_id_seq). This means that even if we insert
# two rows at the same millisecond, they will have
# distinct 'sequence data' portions.
#
# If this happens, and an attacker can see both such IDs,
# they can determine which of the two entries was inserted
# first, but not the total number of entries in the table
# (even mod 2**16).
#
# The table name is included in the hash to ensure that
# different tables derive separate sequence bases so rows
# inserted in the same millisecond in different tables do
# not reveal the table ID sequence number for one another.
#
# The secret salt is included in the hash to ensure that
# external users cannot derive the sequence base given the
# timestamp and table name, which would allow them to
# compute the table ID sequence number.
def define_timestamp_id
return if already_defined?
connection.execute(<<~SQL)
CREATE OR REPLACE FUNCTION timestamp_id(table_name text)
RETURNS bigint AS
$$
DECLARE
time_part bigint;
sequence_base bigint;
tail bigint;
BEGIN
time_part := (
-- Get the time in milliseconds
((date_part('epoch', now()) * 1000))::bigint
-- And shift it over two bytes
<< 16);
sequence_base := (
'x' ||
-- Take the first two bytes (four hex characters)
substr(
-- Of the MD5 hash of the data we documented
md5(table_name ||
'#{SecureRandom.hex(16)}' ||
time_part::text
),
1, 4
)
-- And turn it into a bigint
)::bit(16)::bigint;
-- Finally, add our sequence number to our base, and chop
-- it to the last two bytes
tail := (
(sequence_base + nextval(table_name || '_id_seq'))
& 65535);
-- Return the time part and the sequence part. OR appears
-- faster here than addition, but they're equivalent:
-- time_part has no trailing two bytes, and tail is only
-- the last two bytes.
RETURN time_part | tail;
END
$$ LANGUAGE plpgsql VOLATILE;
SQL
end
def ensure_id_sequences_exist
# Find tables using timestamp IDs.
connection.tables.each do |table|
# We're only concerned with "id" columns.
next unless (id_col = connection.columns(table).find { |col| col.name == 'id' })
# And only those that are using timestamp_id.
next unless (data = DEFAULT_REGEX.match(id_col.default_function))
seq_name = data[:seq_prefix] + '_id_seq'
# If we were on Postgres 9.5+, we could do CREATE SEQUENCE IF
# NOT EXISTS, but we can't depend on that. Instead, catch the
# possible exception and ignore it.
# Note that seq_name isn't a column name, but it's a
# relation, like a column, and follows the same quoting rules
# in Postgres.
connection.execute(<<~SQL)
DO $$
BEGIN
CREATE SEQUENCE #{connection.quote_column_name(seq_name)};
EXCEPTION WHEN duplicate_table THEN
-- Do nothing, we have the sequence already.
END
$$ LANGUAGE plpgsql;
SQL
end
end
def id_at(timestamp, with_random: true)
id = timestamp.to_i * 1000
id += rand(1000) if with_random
id = id << 16
id += rand(2**16) if with_random
id
end
private
def already_defined?
connection.execute(<<~SQL).values.first.first
SELECT EXISTS(
SELECT * FROM pg_proc WHERE proname = 'timestamp_id'
);
SQL
end
def connection
ActiveRecord::Base.connection
end
end
end