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WHAT SEQUENCE OBJECTS ARE (AND ARE NOT) Louis Davidson Data Architect.

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Presentation on theme: "WHAT SEQUENCE OBJECTS ARE (AND ARE NOT) Louis Davidson Data Architect."— Presentation transcript:

1 WHAT SEQUENCE OBJECTS ARE (AND ARE NOT) Louis Davidson (louis@drsql.org) Data Architect

2 A CANDIDATE FOR THE PRIZE FOR THE WORLD’S LONGEST PRESENTATION (ON THE WORLD’S SMALLEST TOPIC) Louis Davidson (louis@drsql.org) Data Architect

3 Who is this guy? Been in IT for over 17 years Microsoft MVP For 7 Years Written five books on database design Ok, so they were all versions of the same book. They at least had slightly different titles each time Worked for Christian Broadcasting Network for nearly 15 years.

4 Sequence Objects are: Whole Number Generators Additive progression next value = current value + factor Objects They are schema owned objects. They have standard permissions (UPDATE only) Guaranteed to generate a value in order (with cycles if desired) Allows you to use them to order data

5 Sequence Objects are: Far less limited in their use as opposed to identities In a table, identity property limited to 1 column, you can have > 1 column with a default using a sequence Identity property applicable only to table column A reasonable replacement for identity generated values Far more flexible Can be added to column after creation, and removed from column anytime Column values will are updatable Tunable – knobs available to tune how values are cached

6 Sequence Objects are not: Usable exactly like identity property No way to get the last one used in scope Doesn’t automatically skip defaulted column in INSERT “Naked” insert - INSERT TABLE VALUES (1,2) The table metadata will not know about the sequence No special syntax for working with identity column in a table A direct replacement for: A numbers table ROW_NUMBER() windowing function

7 Sequence Objects are not: Available as a temporary object Subject to Transactions Allows for highly concurrent usage Every value generated is lost even if ROLLBACK Uses locks for concurrency, but not held in any isolation level beyond getting next value Exception: ALTER SEQUENCE in transaction will block Users of that sequence Other SEQUENCE creates/alters too Slower than identity generated values Performance characteristics directly tied to caching and need to persist metadata

8 v v Identity syntax and management overview

9 All parameters set at table create (or when adding an identity column using ALTER TABLE) Management tied directly to the table Get recently entered value using one of the following SCOPE_IDENTITY() – Within current execution scope @@IDENTITY – In current session IDENT_CURRENT('tablename’) – On any session (even someone else’s) To insert values manually, need: SET IDENTITY_INSERT ON …. SET IDENTITY_INSERT OFF CREATE TABLE ( int NOT NULL IDENTITY(, )

10 Identity management IDENT_INCR(' ‘) gets increment IDENT_SEED(' ') gets the original seed IDENT_CURRENT(' ') gets the current identity value across connections $IDENTITY can be used in query instead of identity column name Removing data from table DELETE leaves identity value alone TRUNCATE TABLE resets the value to the original seed DBCC CHECKIDENT to reset/fix values Cannot change the increment without dropping and recreating column

11 v v Sequence syntax and management overview

12 All parameters must be constants No variables Frustrating, but can use dynamic SQL CREATE SEQUENCE [schema_name. ] sequence_name [ AS [ built_in_integer_type | user-defined_integer_type ] ] [ START WITH ] [ INCREMENT BY ] [ { MINVALUE [ ] } | { NO MINVALUE } ] [ { MAXVALUE [ ] } | { NO MAXVALUE } ] [ CYCLE | { NO CYCLE } ] [ { CACHE [ ] } | { NO CACHE } ]

13 Datatype Bigint, Int, SmallInt, TinyInt, Numeric(N,0) Can also be an alias type that is based on one of these types Datatype by default is bigint CREATE SEQUENCE [schema_name. ] sequence_name [ AS [ built_in_integer_type | user-defined_integer_type ] ] [ START WITH ] [ INCREMENT BY ] [ { MINVALUE [ ] } | { NO MINVALUE } ] [ { MAXVALUE [ ] } | { NO MAXVALUE } ] [ CYCLE | { NO CYCLE } ] [ { CACHE [ ] } | { NO CACHE } ]

14 START WITH Tells the sequence where to start Default is to start with the minimum value for datatype (includes negative values) Note for column compression, min/max values compress less than small numbers CREATE SEQUENCE [schema_name. ] sequence_name [ AS [ built_in_integer_type | user-defined_integer_type ] ] [ START WITH ] [ INCREMENT BY ] [ { MINVALUE [ ] } | { NO MINVALUE } ] [ { MAXVALUE [ ] } | { NO MAXVALUE } ] [ CYCLE | { NO CYCLE } ] [ { CACHE [ ] } | { NO CACHE } ]

15 INCREMENT BY Tells the sequence how much to add to value to get next value Positive or negative values allowed CREATE SEQUENCE [schema_name. ] sequence_name [ AS [ built_in_integer_type | user-defined_integer_type ] ] [ START WITH ] [ INCREMENT BY ] [ { MINVALUE [ ] } | { NO MINVALUE } ] [ { MAXVALUE [ ] } | { NO MAXVALUE } ] [ CYCLE | { NO CYCLE } ] [ { CACHE [ ] } | { NO CACHE } ]

16 MINVALUE and MAXVALUE Defines lowest and highest values allowed Default values of NO MINVALUE or NO MAXVALUE is the minimum and maximum values for the datatype This is independent of the STARTWITH value, if specified. When MINVALUE or MAXVALUE is reached, how this is handled is dependent on CYCLE setting CREATE SEQUENCE [schema_name. ] sequence_name [ AS [ built_in_integer_type | user-defined_integer_type ] ] [ START WITH ] [ INCREMENT BY ] [ { MINVALUE [ ] } | { NO MINVALUE } ] [ { MAXVALUE [ ] } | { NO MAXVALUE } ] [ CYCLE | { NO CYCLE } ] [ { CACHE [ ] } | { NO CACHE } ]

17 CYCLE CYCLE indicates that when MAXVALUE (or MINVALUE for negative INCREMENT BY value) is reached, it will loop back to the min or max value, depending on the INCREMENT BY VALUE CREATE SEQUENCE [schema_name. ] sequence_name [ AS [ built_in_integer_type | user-defined_integer_type ] ] [ START WITH ] [ INCREMENT BY ] [ { MINVALUE [ ] } | { NO MINVALUE } ] [ { MAXVALUE [ ] } | { NO MAXVALUE } ] [ CYCLE | { NO CYCLE } ] [ { CACHE [ ] } | { NO CACHE } ]

18 CACHE Allows you to performance tune the number of pre- calculated values to make available Can make a large difference Default does caching, amount controlled by SQL Server One value (the next uncached value) is stored to disk, all other values persisted in ram. Value will be restored during a restore of a backup CREATE SEQUENCE [schema_name. ] sequence_name [ AS [ built_in_integer_type | user-defined_integer_type ] ] [ START WITH ] [ INCREMENT BY ] [ { MINVALUE [ ] } | { NO MINVALUE } ] [ { MAXVALUE [ ] } | { NO MAXVALUE } ] [ CYCLE | { NO CYCLE } ] [ { CACHE [ ] } | { NO CACHE } ]

19 Naming Sequences are schema bound objects Eg. Mustn't be named the same as any table, view, procedure, function, etc. in the same schema My naming standard is to name them: [ ]_[purpose]_SEQUENCE Example: For surrogate key of table "Fred“: Fred_SEQUENCE, Fred_NotKey_SEQUENCE, WholeSystemOrderingValue_SEQUENCE SELECT * FROM sys.objects WHERE type_desc = 'SEQUENCE_OBJECT' SELECT * --objects columns plus FROM sys.sequences

20 Fetching value from Sequence OBJECT NEXT VALUE FOR function Example: SELECT NEXT VALUE FOR SchemaS.Sequence FROM SchemaT.Table Evaluated once per row Limited usage … No usage in: Queries with SET operators: UNION, UNION ALL CASE Expressions Queries with ORDER BY without OVER clause on NEXT VALUE FOR call Etc. Can be used in a function call: SchemaF.FunctionName(NEXT VALUE FOR SchemaS.Sequence)

21 Pretty much the exact same syntax as the CREATE SEQUENCE statement Tons of control over settings even after object is creating ALTER SEQUENCE [schema_name. ] sequence_name [ AS [ built_in_integer_type | user-defined_integer_type ] ] [ RESTART [ WITH ] ] [ INCREMENT BY ] [ { MINVALUE [ ] } | { NO MINVALUE } ] [ { MAXVALUE [ ] } | { NO MAXVALUE } ] [ CYCLE | { NO CYCLE } ] [ { CACHE [ ] } | { NO CACHE } ]

22 RESTART lets you reset the sequence, starting at a given point. If WITH is left off, goes back to value it was started with (or last restart value) ALTER SEQUENCE [schema_name. ] sequence_name [ AS [ built_in_integer_type | user-defined_integer_type ] ] [ RESTART [ WITH ] ] [ INCREMENT BY ] [ { MINVALUE [ ] } | { NO MINVALUE } ] [ { MAXVALUE [ ] } | { NO MAXVALUE } ] [ CYCLE | { NO CYCLE } ] [ { CACHE [ ] } | { NO CACHE } ]

23 Inserting large numbers of rows You can allocate multiple rows at a time Use sp_sequence_get_range EXEC sp_sequence_get_range @sequence_name = N'Demo.SalesOrder_SEQUENCE', @range_size = Number, @range_first_value = @range_first_value OUTPUT, @range_last_value = @range_last_value OUTPUT, @sequence_increment = @sequence_increment OUTPUT; Be careful with the math.. Remember increment if trying to match singleton usage 23Track # – Session #

24 v v Typical Usage Patterns

25 Typical Usage patterns Surrogate key generation (#1 by far!) Simply instead of identity Allow client to gen their own numbers Great for data warehouse loads Hash bucket (using multiple sequences in same statement/table) Basis for generating complex identifiers Multiple tables with the same value Database wide version number Numbering “actions” (not as surrogate) Can fill gaps later before processing

26 Artificial/Surrogate Key Generation Most (not all!) usage will be to create an artificial surrogate key for a table, for performance purposes When used this way the goal should be to hide the value of the key from the user. Gaps should be ignored It is a very widely used pattern that almost every table gets a one column surrogate key. I feel it necessary to caution you that the meaning of “surrogate” is a stand in, not a replacement All tables should have some form of natural key (more or less a value that has meaning to the user)

27 Artificial Key Generation Requirement: Table of Lego Sets Always find some other key to protect against duplicate data so you don’t end up with LegoSetId Name =========== ----------- 1 M Falcon 4567 M Falcon 979796 M Falcon Scale ----------- Minifig Micro Minifig SetNumber ----------- 7965 4488 10179 ~~~~~~~~~~~ LegoSetId Name Scale SetNumber =========== ----------- ------------ ------------- 1 M Falcon Minifig 4488 4567 M Falcon Minifig 4488 979796 M Falcon Minifig 4488

28 Typical Coding Patterns Identity and sequences have slightly different usage patterns making usage slightly different With sequences if you want to know the value inserted, you generate the value manually and use it in the INSERT clause For identities, we ask afterwards

29 Identity Usage Patterns INSERT TableName (NonIdentityColumns) VALUES ('Some Value') DECLARE @NewValue int = scope_identity() INSERT RelatedTableName (TableNameId) VALUES (@NewValue)

30 Sequence Usage Pattern DECLARE @NewValue int = (NEXT VALUE FOR Seq) INSERT TableName (IdentityColumn, NonIdentityColumns) VALUES (@NewValue, 'Some Value') INSERT RelatedTableName (TableNameId) VALUES (@NewValue) 30Track # – Session #

31 Output Clause Works for both Assuming your table qualifies, can get the new values from INSERT statement directly However, there are massive limitations (http://msdn.microsoft.com/en-us/library/ms177564.aspx). The output table cannot:http://msdn.microsoft.com/en-us/library/ms177564.aspx Have enabled triggers defined on it. Have CHECK constraints or enabled rules. Participate on either side of a FOREIGN KEY constraint. 31Track # – Session # In other words, in “real” database, it is useless for normal tables.

32 v v Demos Some I will do, and more for you to play with later! What you probably have been waiting for…

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