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SQL Anywhere 11.0.1 (Français) » SQL Anywhere Server - SQL Usage » Creating Databases » Using transactions and isolation levels » Isolation levels and consistency

 

Snapshot isolation

Blocks and deadlocks can occur when users are reading and writing the same data simultaneously. Snapshot isolation is designed to improve concurrency and consistency by maintaining different versions of data. When you use snapshot isolation in a transaction, the database server returns a committed version of the data in response to any read requests. It does this without acquiring read locks, and prevents interference with users who are writing data.

A snapshot is a set of data that has been committed in the database. When using snapshot isolation, all queries within a transaction use the same set of data. No locks are acquired on database tables, which allows other transactions to access and modify the data without blocking. SQL Anywhere supports three snapshot isolation levels that let you control when a snapshot is taken:

  • snapshot   Use a snapshot of committed data from the time when the first row is read, inserted, updated, or deleted by the transaction.

  • statement-snapshot   Use a snapshot of committed data from the time when the first row is read by the statement. Each statement within the transaction sees a snapshot of data from a different time.

  • readonly-statement-snapshot   For read-only statements, use a snapshot of committed data from the time when the first row is read. Each read-only statement within the transaction sees a snapshot of data from a different time. For insert, update, and delete statements, use the isolation level specified by the updatable_statement_isolation option (can be one of 0 (the default), 1, 2, or 3).

You also have the option of specifying when the snapshot starts for a transaction by using the BEGIN SNAPSHOT statement. See BEGIN SNAPSHOT statement.

Snapshot isolation is often useful, such as:

  • Applications that perform many reads and few updates   Snapshot transactions acquire write locks only for statements that modify the database. If a transaction is performing mainly read operations, then the snapshot transaction does not acquire read locks that could interfere with other users' transactions.

  • Applications that perform long-running transactions while other users need to access data   Snapshot transactions do not acquire read locks, which makes data available to other users for reading and updating while the snapshot transaction takes place.

  • Applications that must read a consistent set of data from the database   Because a snapshot shows a committed set of data from a specific point in time, you can use snapshot isolation to see consistent data that does not change throughout the transaction, even if other users are making changes to the data while your transaction is running.

Snapshot isolation only affects base tables and global temporary tables that are shared by all users. A read operation on any other table type never sees an old version of the data, and never initiates a snapshot. The only time where an update to another table type initiates a snapshot is if the isolation_level option is set to snapshot, and the update initiates a transaction.

The following statements cannot be executed when there are cursors opened with the WITH HOLD clause that use either statement or transaction snapshots:

When opening cursors with the WITH HOLD clause, a snapshot of all rows committed at the snapshot start time is visible. Also visible are all modifications completed by the current connection since the start of the transaction within which the cursor was opened.

TRUNCATE TABLE is allowed only when a fast truncation is not performed because in this case, individual DELETEs are then recorded in the transaction log. See TRUNCATE statement.

In addition, if any of these statements are performed from a non-snapshot transaction, then snapshot transactions that are already in progress that subsequently try to use the table return an error indicating that the schema has changed.

Materialized view matching avoids using a view if it was refreshed after the start of the snapshot for a transaction.

Snapshot isolation levels are supported in all programming interfaces. You can set the isolation level using the SET OPTION statement. For information about using snapshot isolation, see:

Row versions

When snapshot isolation is enabled for a database, each time a row is updated, the database server adds a copy of the original row to the version stored in the temporary file. The original row version entries are stored until all the active snapshot transactions complete that might need access to the original row values. A transaction using snapshot isolation sees only committed values, so if the update to a row was not committed or rolled back before a snapshot transaction began, the snapshot transaction needs to be able to access the original row value. This allows transactions using snapshot isolation to view data without placing any locks on the underlying tables.

The VersionStorePages database property returns the number of pages in the temporary file that are currently being used for the version store. To obtain this value, execute the following query:

SELECT DB_PROPERTY ( 'VersionStorePages' );

Old row version entries are removed when they are no longer needed. Old versions of BLOBs are stored in the original table, not the temporary file, until they are no longer required, and index entries for old row versions are stored in the original index until they are not required.

You can retrieve the amount of free space in the temporary file using the sa_disk_free_space system procedure. See sa_disk_free_space system procedure.

If a trigger is fired that updates row values, the original values of those rows are also stored in the temporary file.

Designing your application to use shorter transactions and shorter snapshots reduces temporary file space requirements.

If you are concerned about temporary file growth, you can set up a GrowTemp system event that specifies the actions to take when the temporary file reaches a specific size. See Understanding system events.

Understanding snapshot transactions

Snapshot transactions acquire write locks on updates, but read locks are never acquired for a transaction or statement that uses a snapshot. As a result, readers never block writers and writers never block readers, but writers can block writers if they attempt to update the same rows.

Note that for the purposes of snapshot isolation, a transaction does not begin with a BEGIN TRANSACTION statement. Rather, it begins with the first read, insert, update, or delete within the transaction, depending on the snapshot isolation level being used for the transaction. The following example shows when a transaction begins for snapshot isolation:

SET OPTION PUBLIC.allow_snapshot_isolation = 'On';
         SET TEMPORARY OPTION isolation_level = 'snapshot';
   SELECT * FROM Products; --transaction begins and the statement only 
                           --sees changes that are already committed
   INSERT INTO Products 
         SELECT ID + 30, Name, Description,
         'Extra large', Color, 50, UnitPrice, NULL
         FROM Products
         WHERE Name = 'Tee Shirt';
COMMIT; --transaction ends

Enabling snapshot isolation
Snapshot isolation example
Update conflicts and snapshot isolation