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Performance Tuning

Performance Tuning. Next, we focus on lock-based concurrency control, and look at optimising lock contention. The key is to combine the theory of concurrency control with practical DBMS knowledge Goal: maximise DBMS throughput (not the response time of any single transaction). Lock Tuning (I).

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Performance Tuning

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  1. Performance Tuning • Next, we focus on lock-based concurrency control, and look at optimising lock contention. • The key is to combine the theory of concurrency control with practical DBMS knowledge • Goal: maximise DBMS throughput (not the response time of any single transaction)

  2. Lock Tuning (I) • Use special system facilities for long reads • Create a version for reading purposes -- multiversion read consistency • Snapshot Isolation • Eliminate locking when it is unnecessary • Single transaction: bulk loading • Read only transaction: statistical analysis

  3. Lock Tuning (II) • Take advantages of transactional context to chop transactions into small pieces • Atomicity is only guaranteed on the small pieces! • Longer transactions more locks, longer wait (blocking others longer time) • Weaken isolation guarantees when the application allows it • SQL allows 4 level of consistency options

  4. Lock Tuning (III) • Select the appropriate locking granularity • Table, record, field… • Do DDL statements when not busy • Catalog is accessed by all transactions • Avoid updates when system is busy • Think about partitioning • Use multiple physical disks, insertion points

  5. Lock Tuning (IV) • Circumventing hot spots • Partitioning • Delay the access till late stage of processing • Use special database operations • Tune the deadlock intervals • How long to time-out a transaction? • …

  6. Understand Your DBMS • Each DBMS product may have different default locking behaviours • Example: SQL Server and Sybase • Write locks are held to the end of a transaction • Read locks are released immediately after use • Not 2PL!

  7. Understand Your Applications • What is the requirement for your transaction? • What will be the transactions that will run in parallel to your transaction? • Where is the start and the end of your transaction?

  8. Understand Your Run-Time Environment • What are the concurrent transactions? • What are their priorities? • How your system has performed so far?

  9. Each transaction executes against the version of the data items that was committed when the transaction started: No locks for read Costs space (old copy of data must be kept) Almost serialisable level: T1: x:=y T2: y:= x Initially x=3 and y =17 Serial execution: x,y=17 or x,y=3 Snapshot isolation: x=17, y=3 if both transactions start at the same time. R(Y) returns 1 R(Z) returns 0 R(X) returns 0 T1 W(Y:=1) T2 W(X:=2, Z:=3) T3 TIME X=Y=Z=0 Snapshot Isolation

  10. Isolation • Correctness vs. Performance • Number of locks held by each transaction • Kind of locks • Length of time a transaction holds locks • Life is full of compromises • High performance, at the cost of allowing some bad things happening • Application programmer and DBA should make a decision • An informed decision!

  11. SQL Isolation Levels • Degree 0: • Allow dirty read and lost update/nonrepeatable reads • Write-locks released immediately after writing, and no read locks • Degree 1 (read uncommitted) • Degree 2 (read committed) • Degree 3 (serialisable)

  12. Isolation Levels • Read Uncommitted (No lost update) • Write-locks held for the duration of the transactions • No read-locks • Read Committed (No dirty retrieval) • Read-locks released immediately after the read operation. • SQL Server default option • Repeatable Read (no unrepeatable reads for read/write ) • Two phase locking • Serialisable (read/write/insert/delete model) • Table locking or index locking to avoid phantoms

  13. Value of Serializability: Data Settings: accounts( number, branchnum, balance); create clustered index c on accounts(number); • 100000 rows • Cold buffer; same buffer size on all systems. • Row level locking • Isolation level (SERIALIZABLE or READ COMMITTED) • SQL Server 7, DB2 v7.1 and Oracle 8i on Windows 2000 • Dual Xeon (550MHz,512Kb), 1Gb RAM, Internal RAID controller from Adaptec (80Mb), 4x18Gb drives (10000RPM), Windows 2000.

  14. Value of Serializability: Transactions Concurrent Transactions: • T1: summation query [1 thread] select sum(balance) from accounts; • T2: swap balance between two account numbers (in order of scan to avoid deadlocks) [N threads] valX:=select balance from accounts where number=X;valY:=select balance from accounts where number=Y;update accounts set balance=valX where number=Y;update accounts set balance=valY where number=X;

  15. With SQL Server and DB2 the scan returns incorrect answers if the read committed isolation level is used (default setting) Value of Serializability: Results

  16. Because the update conflicts with the scan, correct answers are obtained at the cost of decreased concurrency and thus decreased throughput. Cost of Serializability

  17. Logical Bottleneck: Sequential Key Generation • Consider an application that reuires a sequential number to act as a key in a table, e.g. invoice numbers for bills. • Ad hoc approach: a separate table holding the last invoice number. Fetch and update that number on each insert transaction. • Counter approach: use facility such as Sequence (Oracle)/Identity(MSSQL).

  18. Counter Facility: Data Settings: • default isolation level: READ COMMITTED; Empty tables • Dual Xeon (550MHz,512Kb), 1Gb RAM, Internal RAID controller from Adaptec (80Mb), 4x18Gb drives (10000RPM), Windows 2000. accounts( number, branchnum, balance); create clustered index c on accounts(number); counter ( nextkey ); insert into counter values (1);

  19. Counter Facility: Transactions No Concurrent Transactions: • System [100 000 inserts, N threads] • SQL Server 7 (uses Identity column) insert into accounts values (94496,2789); • Oracle 8i insert into accounts values (seq.nextval,94496,2789); • Ad-hoc [100 000 inserts, N threads]begin transactionNextKey:=select nextkey from counter; update counter set nextkey = NextKey+1;commit transactionbegin transaction insert into accounts values(NextKey,?,?);commit transaction

  20. System generated counter (system) much better than a counter managed as an attribute value within a table (ad hoc). Avoid Bottlenecks: Counters

  21. Insertion Points: Transactions No Concurrent Transactions: • Sequential [100 000 inserts, N threads] Insertions into account table with clustered index on ssnum Data is sorted on ssnum Single insertion point • Non Sequential [100 000 inserts, N threads] Insertions into account table with clustered index on ssnum Data is not sorted (uniform distribution) 100 000 insertion points • Hashing Key [100 000 inserts, N threads] Insertions into account table with extra attribute att with clustered index on (ssnum, att) Extra attribute att contains hash key (1021 possible values) 1021 insertion points

  22. Page locking: single insertion point is a source of contention (sequential key with clustered index, or heap) Row locking: No contention between successive insertions. DB2 v7.1 and Oracle 8i do not support page locking. Insertion Points

  23. Summary • In today’s lecture, we have covered • A review of concurrency control in DBMS • How to optimise lock contention • Concurrency control levels, their implications to the applications and their overheads in different systems

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