The so-called phantom problem occurs
within a transaction when the same query produces different sets
of rows at different times. For example, if a
SELECT
is executed twice, but
returns a row the second time that was not returned the first
time, the row is a “phantom” row.
Suppose that there is an index on the id
column of the child
table and that you want
to read and lock all rows from the table having an identifier
value larger than 100, with the intention of updating some
column in the selected rows later:
SELECT * FROM child WHERE id > 100 FOR UPDATE;
The query scans the index starting from the first record where
id
is bigger than 100. Let the table contain
rows having id
values of 90 and 102. If the
locks set on the index records in the scanned range do not lock
out inserts made in the gaps (in this case, the gap between 90
and 102), another session can insert a new row into the table
with an id
of 101. If you were to execute the
same SELECT
within the same
transaction, you would see a new row with an
id
of 101 (a “phantom”) in the
result set returned by the query. If we regard a set of rows as
a data item, the new phantom child would violate the isolation
principle of transactions that a transaction should be able to
run so that the data it has read does not change during the
transaction.
To prevent phantoms, InnoDB
uses an algorithm
called next-key locking that combines
index-row locking with gap locking. InnoDB
performs row-level locking in such a way that when it searches
or scans a table index, it sets shared or exclusive locks on the
index records it encounters. Thus, the row-level locks are
actually index-record locks. In addition, a next-key lock on an
index record also affects the “gap” before that
index record. That is, a next-key lock is an index-record lock
plus a gap lock on the gap preceding the index record. If one
session has a shared or exclusive lock on record
R
in an index, another session cannot insert
a new index record in the gap immediately before
R
in the index order.
When InnoDB
scans an index, it can also lock
the gap after the last record in the index. Just that happens in
the preceding example: To prevent any insert into the table
where id
would be bigger than 100, the locks
set by InnoDB
include a lock on the gap
following id
value 102.
You can use next-key locking to implement a uniqueness check in your application: If you read your data in share mode and do not see a duplicate for a row you are going to insert, then you can safely insert your row and know that the next-key lock set on the successor of your row during the read prevents anyone meanwhile inserting a duplicate for your row. Thus, the next-key locking allows you to “lock” the nonexistence of something in your table.
Gap locking can be disabled as discussed in
Section 13.2.8.4, “InnoDB
Record, Gap, and Next-Key Locks”. This may cause
phantom problems because other sessions can insert new rows into
the gaps when gap locking is disabled.
User Comments
Note that if you use SELECT FOR UPDATE to perform a uniqueness check before an insert, you will get a deadlock for every race condition unless you enable the innodb_locks_unsafe_for_binlog option. A deadlock-free method to check uniqueness is to blindly insert a row into a table with a unique index using INSERT IGNORE, then to check the affected row count.
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