1 – CACHE
NOTE You cannot issue CREATE CACHE as an independent statement. It is a clause allowed only as part of a CREATE DATABASE or IMPORT statement. You can also create a row cache using the ADD CACHE clause of the ALTER DATABASE statement. Creates a row cache that allows frequently referenced rows to remain in memory even when the associated page has been transferred back to disk. This saves in memory usage because only the more recently referenced rows are cached versus caching the entire buffer. See the ALTER DATABASE statement and the CREATE DATABASE statement for more information regarding the row cache areas.
1.1 – Environment
You can use the CREATE CACHE clause only within a CREATE DATABASE or IMPORT statement. You can use the ADD CACHE clause only within the ALTER DATABASE statement.
1.2 – Format
(B)0[m[1;4mCREATE[m[1m [1;4mCACHE[m[1m <row-cache-name> qwqwqqqqqqqqqqqqqqqqqqqqqqwqwq> [m [1m x[m [1mtq> row-cache-params1 qu[m [1mx [m [1m x[m [1mmq> row-cache-params2 qj[m [1mx [m [1mmqqqqqqqqqqqq <qqqqqqqqqqqqj[m (B)0[m[1madd-row-cache-clause = [m [1m [m [1m [m [1m [m [1mqqq> [1;4mADD[m[1m [1;4mCACHE[m[1m <row-cache-name> qwqwqqqqqqqqqqqqqqqqqqqqqqwqwq>[m [1m x tq> row-cache-params1 qu x [m [1m x mq> row-cache-params2[m [1mqj x [m [1mmqqqqqqqqqqqqq<qqqqqqqqqqqqj[m (B)0[m[1mrow-cache-params1 = [m [1m [m [1m [m [1m [m [1mqqwq> [1;4mALLOCATION[m[1m IS <n> qwqqwqqqqqqqqqqqwqqqqqqqqqqqqqqqqwq> [m [1m tq> [1;4mEXTENT[m[1m IS <n> qqqqqj tq> [1;4mBLOCK[m[1m qqu [m [1m x [m [1m x mq> [1;4mBLOCKS[m[1m qj [m [1m x [m [1m tq> [1;4mCACHE[m[1m [1;4mSIZE[m[1m IS <n> qwqqqq> [1;4mROW[m[1m qqwqqqqqqqqqqqqqqqqqqu [m [1m x mqqqq> [1;4mROWS[m[1m qj [m [1m x [m [1m [m [1mtq>[m [1;4mCHECKPOINT[m[1m qw>[m [1;4mUPDATED[m[1m [1;4mROWS[m[1m TO qw> [1;4mBACKING[m[1m [1;4mFILE[m [1mqwqu[m [1m [m [1mx[m [1mx[m [1mm>[m [1;4mDATABASE[m [1mqqqqqu[m [1mx[m [1m [m [1mx[m [1mm>[m [1;4mALL[m[1m [1;4mROWS[m[1m TO [1;4mBACKING[m[1m [1;4mFILE[m[1m qqqqqqqqqj[m [1mx[m [1m tq> [1;4mLARGE[m[1m [1;4mMEMORY[m[1m IS qqqqwqwq> [1;4mENABLED[m[1m qqwqqqqqqqqqqqqqqu[m [1m [m [1m tq> [1;4mROW[m[1m [1;4mREPLACEMENT[m[1m IS qj mq> [1;4mDISABLED[m[1m qj[m [1m x[m [1m [m [1m tq> [1;4mLOCATION[m[1m IS qq> <directory-spec> qqqqqqqqqqqqqqqqqqu[m [1m [m [1m mq> [1;4mNO[m[1m [1;4mLOCATION[m[1m qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj[m [1m [m [1m [m [1m [m (B)0[m[1mrow-cache-params2 = [m [1m [m [1mqqwq> [1;4mNUMBER[m[1m [1;4mOF[m[1m qwq> [1;4mRESERVED[m [1mqwq>[m [1;4mROWS[m[1m IS <n> qqqqqqqqqqqqqqwq>[m [1mx[m [1mmq> [1;4mSWEEP[m[1m qqqqj[m [1mx[m [1m tq> [1;4mROW[m[1m [1;4mLENGTH[m[1m IS <n> qwqqqqqqqqqqqqqwqqqqqqqqqqqqqqqqqqqqqu [m [1m x tqqqq> [1;4mBYTE[m[1m qqu [m [1m [m [1m x [m [1m x mqqqq> [1;4mBYTES[m[1m qj [m [1m [m [1m x [m [1mx[m [1mx[m [1mtq> [1;4mROW[m[1m [1;4mSNAPSHOT[m[1m IS qqwq> [1;4mENABLED[m[1m rs-opt qwqqqqqqqqqqqqqqqu[m [1mx [m [1mmq> [1;4mDISABLED[m[1m qqqqqqqqj[m [1mx[m [1mx[m [1mx[m [1m mq> [1;4mSHARED[m[1m [1;4mMEMORY[m[1m IS qqwqqqq> [1;4mSYSTEM[m[1m qqqqqqqqqqqqqqqqqqqwqqj [m [1m mqqqq> [1;4mPROCESS[m[1m qqwqqqqqqqqqqqqqwqj[m [1m [m [1m [m [1mx[m [1mx[m [1m [m [1m [m [1mmq> [1;4mRESIDENT[m[1m qj[m [1m [m (B)0[m[1mrs-opt = [m qq[1mwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqqq>[m [1mmq> ([1;4mCACHE[m[1m [1;4mSIZE[m[1m IS <n> [1;4mROWS[m[1m) qqqj[m
1.3 – Arguments
1.3.1 – ALLOCATION
Syntax options: ALLOCATION IS n BLOCK | ALLOCATION IS n BLOCKS Specifies the initial allocation of the row cache file (.rdc) to which cached rows are written. If the ALLOCATION clause is not specified, the default allocation in blocks is approximately 40 percent of the CACHE SIZE for this cache. This clause is ignored if the row cache is defined to checkpoint to the database.
1.3.2 – CACHE
Creates a row cache.
1.3.3 – CACHE_SIZE
Syntax options: CACHE SIZE IS n ROW | CACHE SIZE IS n ROWS Specifies the number of rows allocated to the row cache. As the row cache fills, rows more recently referenced are retained in the row cache while those not referenced recently are discarded. Adjusting the allocation of the row cache helps to retain important rows in memory. If not specified, the default is 1000 rows.
1.3.4 – CHECKPOINT
Syntax options: CHECKPOINT ALL ROWS TO BACKING FILE CHECKPOINT UPDATED ROWS TO BACKING FILE CHECKPOINT UPDATED ROWS TO DATABASE Specifies the source records and target for checkpoint operations for the row cache. If ALL ROWS is specified, then the records written during each checkpoint operation are both the modified and the unmodified rows in the row cache. If UPDATED ROWS is specified, then just the modified rows in the row cache are checkpointed each time. If the target of the checkpoint operation is BACKING FILE, then the row cache server (RCS) process writes the row cache entries to the backing (.rdc) files. The row cache LOCATION, ALLOCATION, and EXTENT clauses are used to create the backing files. Upon recovery from a node failure, the database recovery process is able to repopulate the row caches in memory from the rows found in the backing files. If the target is DATABASE, then the updated rows (only UPDATED ROWS is allowed) are written back to the database. The row cache LOCATION, ALLOCATION, and EXTENT clauses are ignored. Upon recovery from a node failure, the database recovery process has no data on the contents of the row cache. Therefore, it does not repopulate the row caches in memory. This CHECKPOINT clause overrides the database-level CHECKPOINT clause.
1.3.5 – EXTENT
Syntax options: EXTENT IS n BLOCK | EXTENT IS n BLOCKS Specifies the file extent size for the row cache file (.rdc). If the EXTENT clause is not specified, the default number of blocks is CACHE SIZE * 127 for this cache. This clause is ignored if the row cache is defined to checkpoint to the database.
1.3.6 – LOCATION
Syntax options: LOCATION IS directory-spec Specifies the name of the directory to which row cache information is written. The database system generates a file name (row-cache-name.rdc) automatically for each row cache at checkpoint time. Specify a device name and directory name only, enclosed within single quotation marks. By default, the location is the directory of the database root file. These .rdc files are permanent database files. This LOCATION clause overrides a previously specified location at the database level. This clause is ignored if the row cache is defined to checkpoint to the database.
1.3.7 – NO_LOCATION
Removes the location previously specified in a LOCATION IS clause for the row cache. If you specify NO LOCATION, the row cache location becomes the directory of the database root file. This clause is ignored if the row cache is defined to checkpoint to the database.
1.3.8 – NUMBER_OF_RESERVED_ROWS
Syntax options: NUMBER OF RESERVED ROWS IS n Specifies the maximum number of cache rows that each user can reserve for insertion into the cache. Processes reserve, or allocate, entries in a cache to be used when inserting rows into the cache. To improve efficiency, multiple entries are reserved at one once. Once a user's reserved list becomes depleted, Oracle Rdb attempts to reserve another group of entries. The default is 20 rows. This value is also used when searching for available slots in a row cache. The entire row cache is not searched on the initial pass. This value specifies the maximum number of rows that are searched for a free slot. If at least one free slot is found, the insert operation can proceed. If no free slots are found in this initial search, Oracle Rdb continues searching through the cache until it finds a free slot.
1.3.9 – NUMBER_OF_SWEEP_ROWS
Syntax options: NUMBER OF SWEEP ROWS IS n Specifies the number of modified rows that will be written from the row cache back to the database by the row cache server (RCS) process during a sweep operation. When the RCS is notified that a cache is "full" of modified data, the RCS starts a sweep to make space available in the cache for subsequent transactions to be able to insert rows into the cache. Oracle Corporation recommends that you initially specify the number of sweep rows to be approximately 5 percent of the total number of rows in the cache. Then monitor performance and adjust the number of sweep rows, if necessary. Allowable values must be in the range 2 through 524288. If not specified, the default is 3,000 rows.
1.3.10 – ROW_LENGTH
Syntax options: ROW LENGTH IS n BYTES Specifies the length of each row allocated to the row cache. Rows are not cached if they are too large for the row cache. area. The ROW LENGTH is an aligned longword rounded up to the next multiple of 4 bytes. The maximum row length in a row cache is 65535 bytes. When the name of the cache matches the name of an existing logical area, ADD CACHE will calculate ROW LENGTH from the size of the table row, or the size of the index node (for SORTED RANKED, or UNIQUE SORTED indices). This cache is known as a logical area cache.
1.3.11 – ROW_REPLACEMENT
Syntax options: ROW REPLACEMENT IS ENABLED | ROW REPLACEMENT IS DISABLED Specifies whether or not Oracle Rdb replaces rows in the cache. When ROW REPLACEMENT IS ENABLED, rows are replaced when the row cache becomes full. When ROW REPLACEMENT IS DISABLED, rows are not replaced when the row cache is full. The type of row replacement policy depends upon the application requirements for each cache. The default is ENABLED.
1.3.12 – ROW_SNAPSHOT_IS_DISABLED
Disables storing snapshot copies of rows within the cache.
1.3.13 – ROW_SNAPSHOT_IS_ENABLED
The ROW SNAPSHOT IS ENABLED (CACHE SIZE IS n ROWS) option enables storage of snapshot copies of rows within the cache and specifies the number of snapshot "slots" to allocate for the cache. The default for new caches, and existing caches is to have this feature disabled. If you do not specify the CACHE SIZE clause for the ROW SNAPSHOT IS ENABLED option, Oracle Rdb creates a cache that can contain up to 1000 snapshot rows.
1.3.14 – SHARED_MEMORY
Syntax options: SHARED MEMORY IS SYSTEM | SHARED MEMORY IS PROCESS Determines whether cache global sections are created in system space or process space. The default is SHARED MEMORY IS PROCESS. When you use cache global sections created in the process space, you and other users share physical memory and the OpenVMS operating system maps a row cache to a private address space for each user. As a result, all users are limited by the free virtual address range and each use a percentage of memory in overhead. If many users are accessing the database, the overhead can be high. When many users are accessing the database, consider using the SHARED MEMORY IS SYSTEM clause. This gives users more physical memory because they share the system space of memory and there is none of the overhead associated with the process space of memory.
1.3.15 – SHARED_MEMORY_IS_PROCESS_RESIDENT
The SHARED MEMORY clause determines whether database root global sections (including global buffers when enabled) or whether the cache global sections are created in system space or process space. The RESIDENT option extends the PROCESS option by making the global section memory resident.
1.4 – Examples
Example 1: Creating a row cache This example creates a database, creates a row cache, and assigns the row cache to a storage area. SQL> CREATE DATABASE FILENAME test_db cont> ROW CACHE IS ENABLED cont> CREATE CACHE test1 cont> CACHE SIZE IS 100 ROWS cont> CREATE STORAGE AREA area1 cont> CACHE USING test1; SQL> SHOW CACHE Cache Objects in database with filename test_db TEST1 SQL> SHOW CACHE test1 TEST1 Cache Size: 100 rows Row Length: 256 bytes Row Replacement: Enabled Shared Memory: Process Large Memory: Disabled Window Count: 100 Reserved Rows: 20 Sweep Rows: 3000 No Sweep Thresholds Allocation: 100 blocks Extent: 100 blocks SQL> SHOW STORAGE AREA area1 AREA1 Access is: Read write Page Format: Uniform Page Size: 2 blocks Area File: SQL_USER1:[DAY.V70]AREA1.RDA;1 Area Allocation: 402 pages Area Extent Minimum: 99 pages Area Extent Maximum: 9999 pages Area Extent Percent: 20 percent Snapshot File: SQL_USER1:[DAY.V70]AREA1.SNP;1 Snapshot Allocation: 100 pages Snapshot Extent Minimum: 99 pages Snapshot Extent Maximum: 9999 pages Snapshot Extent Percent: 20 percent Extent : Enabled Locking is Row Level Using Cache TEST1 No database objects use Storage Area AREA1 Example 2: Creating and modifying various caches 1 The cache named CUSTOMER_STATUS is created with a row length of 577 bytes with 88000 cache "slots" for storage of live database rows and 7000 slots for storage of snapshot copies of rows. This cache is also configured to be memory- resident. 2 The cache named MACHINE_FLOW_IDX_1 is created with a row length of 430 bytes with 5000 cache slots for storage of live database rows and 12000 slots for storage of snapshot copies of rows. This cache is set to disallow replacement of rows in the cache. 3 The cache named SALES_CALLS is created with a row length of 160 bytes with 3000 cache "slots" for storage of live database rows and, using the default because an explicit count was not specified, 1000 slots for storage of snapshot copies of rows. 4 The cache named CUSTOMER_ORDER does not specify "ROW SNAPSHOT IS ENABLED" so no snapshot row copies will be stored in this cache. 5 The cache named "SALES" is modified to disable storage of snapshot rows in cache. 6 The cache named "CLEARING" is modified to enable storage of snapshot rows in the cache with a snapshot cache size of 12,345 rows. SQL> ALTER DATABASE FILENAME HDB_DB 1 ADD CACHE CUSTOMER_STATUS ROW LENGTH IS 577 BYTES CACHE SIZE IS 88000 ROWS ROW SNAPSHOT IS ENABLED (CACHE SIZE IS 7000 ROWS) SHARED MEMORY IS PROCESS RESIDENT 2 ADD CACHE MACHINE_FLOW_IDX_1 ROW LENGTH IS 430 BYTES CACHE SIZE IS 5000 ROWS ROW REPLACEMENT IS DISABLED ROW SNAPSHOT IS ENABLED (CACHE SIZE IS 12000 ROWS) 3 ADD CACHE SALES_CALLS ROW LENGTH IS 160 BYTES CACHE SIZE IS 3000 ROWS ROW SNAPSHOT IS ENABLED 4 ADD CACHE CUSTOMER_ORDER ROW LENGTH IS 760 BYTES CACHE SIZE IS 9000 ROWS CHECKPOINT UPDATED ROWS TO DATABASE 5 ALTER CACHE SALES ROW SNAPSHOT IS DISABLED 6 ALTER CACHE CLEARING ROW SNAPSHOT IS ENABLED (CACHE SIZE IS 12345 ROWS); SQL> SHOW CACHE CUSTOMER_STATUS CUSTOMER_STATUS Cache Size: 88000 rows Row Length: 580 bytes Row Replacement: Enabled Shared Memory: Process Resident Large Memory: Disabled Window Count: 100 Working Set Count: 10 Reserved Rows: 20 Allocation: 100 blocks Extent: 100 blocks Snapshot in Cache: Enabled Snapshot Cache Size: 7000 rows SQL> SHOW CACHE MACHINE_FLOW_IDX_1 MACHINE_FLOW_IDX_1 Cache Size: 5000 rows Row Length: 432 bytes Row Replacement: Disabled Shared Memory: Process Large Memory: Disabled Window Count: 100 Working Set Count: 10 Reserved Rows: 20 Allocation: 100 blocks Extent: 100 blocks Snapshot in Cache: Enabled Snapshot Cache Size: 12000 rows SQL> SHOW CACHE SALES_CALLS SALES_CALLS Cache Size: 3000 rows Row Length: 160 bytes Row Replacement: Enabled Shared Memory: Process Large Memory: Disabled Window Count: 100 Working Set Count: 10 Reserved Rows: 20 Allocation: 100 blocks Extent: 100 blocks Snapshot in Cache: Enabled Snapshot Cache Size: 1000 rows SQL> SHOW CACHE CUSTOMER_ORDER CUSTOMER_ORDER Cache Size: 9000 rows Row Length: 760 bytes Row Replacement: Enabled Shared Memory: Process Large Memory: Disabled Window Count: 100 Working Set Count: 10 Reserved Rows: 20 Allocation: 100 blocks Extent: 100 blocks Row cache: checkpoint updated rows to database
2 – CATALOG
Creates a name for a group of schemas in a multischema database.
2.1 – Environment
You can use the CREATE CATALOG statement: o In interactive SQL o Embedded in host language programs to be precompiled o As part of a procedure in an SQL module o In dynamic SQL as a statement to be dynamically executed
2.2 – Format
(B)0[m[1;4mCREATE[m[1m [1;4mCATALOG[m[1m qq> <catalog-name> qk [m [1m lqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1m mqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwq> [m [1m tqqq> create-schema-statement qwj [m [1m mqwq> schema-element qwqqqqqqqqj [m [1m mqqqqqqqqq<qqqqqqqqqj [m [1m [m (B)0[m[1mcatalog-name = [m [1m [m [1mqwqqqqqq> <name-of-catalog> qqqqqqqqqqqqqqwq>[m [1m x x [m [1m mq> " q> <alias>.<name-of-catalog> q>" qj [m [1m [m (B)0[m[1mschema-element = [m [1m [m [1mqwq> create-collating-sequence-statement qwq> [m [1m tq> create-domain-statement qqqqqqqqqqqqqu [m [1mtq> create-index-statement qqqqqqqqqqqqqqu[m [1mtq> create-sequence-statement qqqqqqqqqqqu[m [1mtq> create-storage-map-statement qqqqqqqqu[m [1m tq> create-table-statement qqqqqqqqqqqqqqu [m [1m tq> create-trigger-statement qqqqqqqqqqqqu [m [1m tq> create-view-statement qqqqqqqqqqqqqqqu [m [1m mq> grant-statement qqqqqqqqqqqqqqqqqqqqqj [m [1m [m
2.3 – Arguments
2.3.1 – alias.name-of-catalog
Specifies an optional name for the attach to the database. Always qualify the catalog name with an alias if your program or your interactive SQL statements refer to more than one database. Separate the name of the catalog from the alias with a period, and enclose the qualified name within double quotation marks.
2.3.2 – catalog-name
The name of the catalog definition you want to create. Use any valid SQL name that is unique among all catalog names in the database. For more information on catalog names, see the User_ Supplied_Names HELP topic.
2.3.3 – create-schema-statement
For more information, see the CREATE SCHEMA statement.
2.3.4 – schema-element
One or more CREATE statements or a GRANT statement. For more information, see the CREATE SCHEMA statement.
2.4 – Examples
Example 1: Creating a catalog for a database using an alias This example shows how an interactive user could attach to the sample database called personnel and create a catalog in that database. (You must use the personnel sample database created with the multischema attribute for this example.) Using an alias, the user distinguishes the personnel database from other databases that may be attached later in the same session. SQL> ATTACH 'ALIAS CORPORATE FILENAME personnel - cont> MULTISCHEMA IS ON'; SQL> -- SQL> -- SQL creates a default catalog called RDB$CATALOG in SQL> -- each multischema database. SQL> -- SQL> SHOW CATALOG; Catalogs in database personnel "CORPORATE.RDB$CATALOG" SQL> -- SQL> -- The SET QUOTING RULES 'SQL99' statement allows the use of SQL> -- double quotation marks, which SQL requires when you SQL> -- qualify a catalog name with an alias. SQL> -- SQL> SET QUOTING RULES 'SQL99'; SQL> CREATE CATALOG "CORPORATE.MARKETING"; SQL> -- SQL> SHOW CATALOG; Catalogs in database personnel "CORPORATE.MARKETING" "CORPORATE.RDB$CATALOG" Example 2: Creating a catalog in the database with the default alias This example shows a CREATE CATALOG clause used in an interactive CREATE DATABASE statement. In this example, the user creates a database without specifying an alias. Because the user is not attached to any other databases, the new database becomes the default alias. SQL> CREATE DATABASE FILENAME inventory cont> MULTISCHEMA IS ON cont> CREATE CATALOG PARTS cont> CREATE SCHEMA PRINTERS AUTHORIZATION DAVIS cont> CREATE TABLE LASER EXTERNAL NAME IS DEPT_2_LASER cont> (SERIAL_NO INT, LOCATION CHAR) cont> CREATE SCHEMA TERMINALS AUTHORIZATION DAVIS cont> CREATE TABLE TERM100 EXTERNAL NAME IS DEPT_2_TERM100 cont> (SERIAL_NO INT, LOCATION CHAR); SQL> SHOW CATALOG; Catalogs in database with filename inventory PARTS RDB$CATALOG SQL> show schemas; Schemas in database with filename inventory PARTS.PRINTERS PARTS.TERMINALS RDB$SCHEMA
3 – COLLATING_SEQUENCE
Identifies a collating sequence that has been defined using the OpenVMS National Character Set (NCS) utility. Use the CREATE COLLATING SEQUENCE statement to identify collating sequences other than the database default collating sequence that you plan to use with certain domains. (The default collating sequence for a database is established by the COLLATING SEQUENCE IS clause in the CREATE SCHEMA statement; if you omit that clause at database definition time, the default sequence is ASCII.) You must enter a CREATE COLLATING SEQUENCE statement specifying a collating sequence before you enter the name of that sequence in any of the following statements: o CREATE DOMAIN . . . COLLATING SEQUENCE o DROP COLLATING SEQUENCE o ALTER DOMAIN . . . COLLATING SEQUENCE o SHOW COLLATING SEQUENCE
3.1 – Environment
You can use the CREATE COLLATING SEQUENCE statement: o In interactive SQL o Embedded in host language programs to be precompiled o As part of a procedure in an SQL module o In dynamic SQL as a statement to be dynamically executed
3.2 – Format
(B)0[m[1;4mCREATE[m[1m [1;4mCOLLATING[m[1m [1;4mSEQUENCE[m[1m <sequence-name> qqk [m [1m lqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1m mqqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqqk [m [1m mq> [1;4mSTORED[m[1m [1;4mNAME[m[1m IS <stored-name> qqqqqj x [m [1m lqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1m mqqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqk [m [1m mq> [1;4mCOMMENT[m[1m [1;4mIS[m[1m qqwq> '<string>' qqwqj x [m [1m mqqqqqq / <qqqqqqj x [m [1m lqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1m mqqqq> <ncs-name> wqqqqqqqqqqqqqqqqqqqqqqqwq> [m [1m mq> [1;4mFROM[m[1m <library-name> j [m [1m [m
3.3 – Arguments
3.3.1 – COMMENT_IS
Adds a comment about the collating sequence. SQL displays the text when it executes a SHOW COLLATING SEQUENCE statement in interactive SQL. Enclose the comment within single quotation marks (') and separate multiple lines in a comment with a slash mark (/).
3.3.2 – FROM library name
Specifies the name of an NCS library other than the default. The default NCS library is SYS$LIBRARY:NCS$LIBRARY.
3.3.3 – ncs-name
Specifies the name of a collating sequence in the default NCS library, SYS$LIBRARY:NCS$LIBRARY, or in the NCS library specified by the library-name argument. The collating sequence can be either one of the predefined NCS collating sequences or one that you defined yourself using NCS.
3.3.4 – sequence-name
Specifies the name by which the collating sequence named in the ncs-name argument is known to the schema. The ncs-name and sequence-name arguments can be the same.
3.3.5 – STORED_NAME_IS
Specifies a name that Oracle Rdb uses to access a collating sequence created in a multischema database. The stored name allows you to access multischema definitions using interfaces, such as Oracle RMU, the Oracle Rdb management utility, that do not recognize multiple schemas in one database. You cannot specify a stored name for a collating sequence in a database that does not allow multiple schemas.
3.4 – Example
Example 1: Creating a French collating sequence The following example creates a collating sequence using the predefined collating sequence FRENCH. It then shows the defined collating sequence by using the SHOW COLLATING SEQUENCE statement. SQL> CREATE COLLATING SEQUENCE FRENCH FRENCH; SQL> -- SQL> SHOW COLLATING SEQUENCE User collating sequences in schema with filename SQL$DATABASE FRENCH Example 2: Create a Spanish collating sequence specifying more than one comment SQL> CREATE COLLATING SEQUENCE SPANISH_COL cont> COMMENT IS 'first comment' / 'second comment' cont> SPANISH; SQL> SHOW COLLATING SEQUENCE SPANISH_COL; SPANISH_COL Comment: first comment second comment
4 – DATABASE
Creates database system files, metadata definitions, and user data that comprise a database. The CREATE DATABASE statement lets you specify in a single SQL statement all data and privilege definitions for a new database. (You can also add definitions to the database later.) For information about ways to ensure good performance and data consistency, see the Oracle Rdb7 Guide to Database Performance and Tuning. The many optional elements of the CREATE DATABASE statement make it very flexible. In its simplest form, the CREATE DATABASE statement creates database system files, specifies their names, and determines the physical characteristics of the database. Using the optional elements of the CREATE DATABASE statement, you can also specify: o Whether the database created with CREATE DATABASE is multifile (separate database root file and storage area data file) or single file (combined database root file and storage area data file). Multifile databases can have many storage areas for user data, all separate from the database root file created by the CREATE DATABASE statement. Multifile databases include CREATE STORAGE AREA clauses in the CREATE DATABASE statement to create multiple storage area files for enhanced performance. The presence or absence of a CREATE STORAGE AREA clause in a CREATE DATABASE statement determines whether the database is single file or multifile. To create a multifile database, you must include a CREATE STORAGE AREA clause in the CREATE DATABASE statement. To create a single-file database, do not include a CREATE STORAGE AREA clause in the CREATE DATABASE statement. o Values for various database root file parameters that override the system defaults. Database root file (.rdb) parameters describe characteristics of the database root file. Database root file parameters affect the entire database, whether it is a single-file or a multifile database. o Values for storage area parameters that override system defaults. Storage area parameters describe characteristics of the database storage area files. In a single-file database, because the storage area data file is combined with the database root file, storage area parameters apply to a single storage area and affect the entire database. In a multifile database, storage area parameters specify defaults for the main storage area, RDB$SYSTEM, and for any subsequent CREATE STORAGE AREA clauses within the CREATE DATABASE statement. o Any number of database elements. Database elements are a CREATE CATALOG statement, a CREATE STORAGE AREA clause, or a GRANT statement. The CREATE DATABASE statements that create single-file databases cannot include a CREATE STORAGE AREA clause because this is specific to multifile databases. The CREATE DATABASE statements that create multifile databases must include at least one CREATE STORAGE AREA clause. Unlike the same statements outside a CREATE DATABASE statement, database elements do not use statement terminators. The first statement terminator that SQL encounters ends the CREATE DATABASE statement. Later CREATE or GRANT statements are not within the scope of the CREATE DATABASE statement. o The database default character set and national character set. For information regarding identifier character sets, database default character sets, and national character sets, see the Character_Sets HELP topic.
4.1 – Environment
You can use the CREATE DATABASE statement: o In interactive SQL o Embedded in host language programs to be precompiled o As part of a procedure in an SQL module o In dynamic SQL as a statement to be dynamically executed
4.2 – Format
(B)0[m[1m [1;4mCREATE[m[1m [1;4mDATABASE[m[1m qwqqqqqqqqqqqqqqqqqqwk [m [1m mq> ALIAS <alias> qjx [m [1mlqqqqqqqqqqqq <qqqqqqqqqqqqqqqqqqqqqqqj [m [1mmwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqk [m [1m mwwq> root-file-params-1 qqqwwjmwwq> storage-area-params-1 qwwj x [m [1m xtq> root-file-params-2 qqqux xmq> storage-area-params-2 qjx x [m [1m xtq> root-file-params-3 qqqux mqqqqqqqqqqqqqq <qqqqqqqqqqqqj x [m [1m xmq> root-file-params-4 qqqjx x [m [1m mqqqqqqqqqqq <qqqqqqqqqqqqqqj x [m [1mlqqqqqqqqqqqqqqqqqqqqqqqqqq <qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1mmwqqqqqqqqqqqqqqqqqqqqwqqwqqqqqqqqqqqqqqqqqqqqqqqwqqqqqqqqq> [m [1m mq> character-sets qqj mwq> database-element qwj [m [1m mqqqqqqqq <qqqqqqqqqqqj [m [1m [m (B)0[m[1mroot-file-params-1 = [m [1m [m [1mqwq> [1;4mFILENAME[m[1m <db-attach-spec> qwwqqqqqqqqqqqqqqqqqqqqqqwwq>[m [1m tq> [1;4mPATHNAME[m[1m <path-name> qqqqjmq> literal-user-auth[m [1mqjx[m [1m [m [1m tq> attach-options qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu [m [1m tq> [1;4mCOLLATING[m[1m [1;4mSEQUENCE[m[1m <collation-name> qqqqqk x [m [1m x lqqqqqqqqqqqqqqqqqqq<qqqqqqqqqqqqqqqqqqqqqj x [m [1m x mwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqqqqk x [m [1m x mq> [1;4mCOMMENT[m[1m [1;4mIS[m[1m qqqwq> '<string>' qqwj x x [m [1m x mqqqqqqq / <qqqqqj x x [m [1m x lqqqqqqqqqqqqqqqqqqq<qqqqqqqqqqqqqqqqqqqqqj x [m [1m x mqq> <ncs-name> qwqqqqqqqqqqqqqqqqqqqqqqqwqqqqqqqqqqqu [m [1m x mq> [1;4mFROM[m[1m <library-name> j x [m [1m tq> [1;4mNUMBER[m[1m OF [1;4mUSERS[m[1m qqqqqqq> <number-users> qqqqqqqqqqqqu [m [1m tq> [1;4mNUMBER[m[1m OF [1;4mBUFFERS[m[1m qqqqq> <number-buffers> qqqqqqqqqqu [m [1m tq> [1;4mNUMBER[m[1m OF [1;4mCLUSTER[m[1m [1;4mNODES[m[1m qqqq> <number-nodes> qqk x [m [1mx[m [1mlqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj[m [1mx[m [1mx[m [1mmwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqqqqqqqu[m [1mx[m [1mm>[m [1m( qwq>[m [1;4mSINGLE[m [1mqqqwq> [1;4mINSTANCE[m[1m qq> ) qqj[m [1mx[m [1mx[m [1mmq>[m [1;4mMULTIPLE[m [1mqj[m [1mx[m [1m tq> [1;4mNUMBER[m[1m OF [1;4mRECOVERY[m[1m [1;4mBUFFERS[m[1m q> <number-buffers> qqqqqu [m [1m mq> [1;4mBUFFER[m[1m SIZE IS q> <buffer-blocks> qq> [1;4mBLOCKS[m[1m qqqqqqqj [m (B)0[m [1mdb-attach-spec = [m [1m [m [1mqqwqqqqqqqqqqqqqqqqwq> <file-spec> qqq> [m [1m mq> <node-spec> qj [m [1m [m (B)0[m[1mnode-spec = [m [1m [m [1mqwq> <nodename> qwqqqqqqqqqqqqqqqqqqqwqwq>[m [1m x mq> <access-string> j x [m [1m mqqqqqqqqqqqqqqqqqq :: <qqqqqqqqqqqqqqj [m (B)0[m[1maccess-string = [m [1m [m [1mqwq> " <user-name> <password> " qqwq> [m [1m mq> " <VMS-proxy-user-name> " qqqj [m [1m [m (B)0[m[1mliteral-user-auth = [m [1m [m [1mqqq> [1;4mUSER[m[1m '<username>' qwqqqqqqqqqqqqqqqqqqqqqqqqwqq> [m [1m mq> [1;4mUSING[m[1m '<password>' qj [m [1m [m (B)0[m[1mattach-options = [m [1m [m [1mqwq> [1;4mDBKEY[m[1m qwq> SCOPE IS qwq> [1;4mATTACH[m[1m qqqqqqqwqqqqqqqqqqqqqqqqqqqqqqqwq>[m [1m tq> [1;4mROWID[m[1m qj mq> [1;4mTRANSACTION[m[1m qqj x [m [1m tq> [1;4mMULTISCHEMA[m[1m IS qwq> [1;4mON[m[1m qqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu [m [1m x mq> [1;4mOFF[m[1m qj x [m [1m tq> [1;4mPRESTARTED[m[1m [1;4mTRANSACTIONS[m[1m [1;4mARE[m[1m qwq> [1;4mON[m[1m qqwqqqqqqqqqqqqqqqqqqqqqqqqu [m [1m x mq> [1;4mOFF[m[1m qj x [m [1m mqwqqqqqqqwq> [1;4mRESTRICTED[m[1m [1;4mACCESS[m[1m qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1m mq> [1;4mNO[m[1m qj [m (B)0[m[1mroot-file-params-2 = [m [1mqwq> global-buffer-params qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwq>[m [1m tq> [1;4mSNAPSHOT[m[1m IS qqqqwqqqqq> [1;4mENABLED[m[1m qwq> [1;4mIMMEDIATE[m[1m wqwqqqqqqqqqqqu[m [1m x x mq> [1;4mDEFERRED[m[1m qj x x [m [1m x mqqqqq> [1;4mDISABLED[m[1m qqqqqqqqqqqqqqqqqj x [m [1m tq> [1;4mDICTIONARY[m[1m IS qqqwqqq> [1;4mREQUIRED[m[1m qqqqqqqwqqqqqqqqqqqqqqqqqqqqqqu [m [1m x mqqq> [1;4mNOT[m[1m [1;4mREQUIRED[m[1m qqqj x [m [1m tq> [1;4mADJUSTABLE[m[1m [1;4mLOCK[m[1m [1;4mGRANULARITY[m[1m IS qwq> [1;4mENABLED[m[1m q> alg-options qwqu [m [1m x mq> [1;4mDISABLED[m[1m qqqqqqqqqqqqqqqj x [m [1m tq> [1;4mLOCK[m[1m [1;4mTIMEOUT[m[1m [1;4mINTERVAL[m[1m IS <number-seconds> SECONDS qqqqqqqqqqqqu [m [1m tq> [1;4mSEGMENTED[m[1m [1;4mSTRING[m[1m qwq> [1;4mSTORAGE[m[1m [1;4mAREA[m[1m IS <area-name> qqqqqqqqqqqqu [m [1m tq> [1;4mLIST[m[1m qqqqqqqqqqqqqu x [m [1m tq> [1;4mDEFAULT[m[1m qqqqqqqqqqj x [m [1m tq> [1;4mPROTECTION[m[1m IS qqqwqqq> [1;4mANSI[m[1m qqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu [m [1m x mqqq> [1;4mACLS[m[1m qqj x [m [1m tq> [1;4mRESERVE[m[1m <n> wq> [1;4mCACHE[m[1m [1;4mSLOTS[m[1m qqqqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu [m [1m x tq> [1;4mJOURNALS[m[1m qqqqqqqu x [m [1m x tq> [1;4mSTORAGE[m[1m [1;4mAREAS[m[1m qqu x [m [1m x[m [1mmq>[m [1;4mSEQUENCES[m[1m qqqqqqj[m [1mx[m [1m mqwq> [1;4mSET[m[1m qqqwq> [1;4mTRANSACTION[m[1m [1;4mMODES[m[1m qq> ( qwq> txn-modes qwq> ) qqqj [m [1m mq> [1;4mALTER[m[1m qj mqqqqq , <qqqqqj [m (B)0[m[1mglobal-buffer-params= [m [1m [m [1mqq> [1;4mGLOBAL[m[1m [1;4mBUFFERS[m[1m ARE qwq> [1;4mENABLED[m[1m qqwqqqqqqqqqqqqqqk [m [1m mq> [1;4mDISABLED[m[1m qj x [m [1mlqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1mtqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqqq> [m [1mm> ( qwwq> [1;4mNUMBER[m[1m IS <number-glo-buffers> qqqqww> ) j [m [1m xtq> [1;4mUSER[m[1m [1;4mLIMIT[m[1m IS <max-glo-buffers> qqqux [m [1m xtq> [1;4mPAGE[m[1m [1;4mTRANSFER[m[1m [1;4mVIA[m[1m qqwq> [1;4mDISK[m[1m qqqwqqjx [m [1m xx mq> [1;4mMEMORY[m[1m qj x [m [1mxmq> [1;4mLARGE[m[1m [1;4mMEMORY[m[1m IS qqwqq> [1;4mENABLED[m [1mqqwqqu[m [1mx[m [1mmqq>[m [1;4mDISABLED[m [1mqj[m [1mx[m [1mmqqqqqqqqqqqqqqqqqqq , <qqqqqqqqqqqqqqqqj[m [1m [m [1m [m (B)0[m[1malg-options = [m [1m [m [1mqqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqq> [m [1m mq> ( qq> [1;4mCOUNT[m[1m IS <n> qq> ) qqj [m [1m [m (B)0[m[1mtxn-modes = [m [1m [m [1mqwqwqqqqqqqwqwq> [1;4mREAD[m[1m [1;4mONLY[m[1m qqqqqqqqqqqqqqqqqwqq> [m [1m x mq> [1;4mNO[m[1m qj tq> [1;4mREAD[m[1m [1;4mWRITE[m[1m qqqqqqqqqqqqqqqqu [m [1m x tq> [1;4mBATCH[m[1m [1;4mUPDATE[m[1m qqqqqqqqqqqqqqu [m [1m x tq> [1;4mSHARED[m[1m qqqqwqqwqqqqqqqqqqwqu [m [1m x tq> [1;4mPROTECTED[m[1m qu tq> [1;4mREAD[m[1m qqu x [m [1m x mq> [1;4mEXCLUSIVE[m[1m qj mq> [1;4mWRITE[m[1m qj x [m [1m tqqqqqqqqqqqqq> [1;4mALL[m[1m qqqqqqqqqqqqqqqqqqqqqqqu [m [1m mqqqqqqqqqqqqq> [1;4mNONE[m[1m qqqqqqqqqqqqqqqqqqqqqqj [m [1m [m (B)0[m[1mroot-file-params-3 = [m [1m [m [1mqw> [1;4mCARDINALITY[m[1m [1;4mCOLLECTION[m[1m IS qqqqqqqqqqqqqqqqqqqqqqqqqww> [1;4mENABLED[m[1m qwqw[m [1m t> [1;4mCARRY[m[1m [1;4mOVER[m[1m [1;4mLOCKS[m[1m ARE qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqum> [1;4mDISABLED[m[1m j[m [1mx[m [1mt> [1;4mGALAXY[m [1;4mSUPPORT[m[1m IS qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu[m [1m [m [1mx[m [1m t> [1;4mLOCK[m[1m [1;4mPARTITIONING[m[1m [1;4mIS[m[1m qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu [m [1mx[m [1mt>[m [1;4mLOGMINER[m[1m [1;4mSUPPORT[m[1m IS qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu[m [1m [m [1mx[m [1m t> [1;4mMETADATA[m[1m [1;4mCHANGES[m[1m ARE qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu [m [1mx[m [1m t> [1;4mSTATISTICS[m[1m [1;4mCOLLECTION[m[1m IS qqqqqqqqqqqqqqqqqqqqqqqqqqu [m [1mx[m [1m t> [1;4mWORKLOAD[m[1m [1;4mCOLLECTION[m[1m IS qqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1mx[m [1m t> [1;4mSYSTEM[m[1m [1;4mINDEX[m[1m qwq> [1;4mCOMPRESSION[m[1m IS qwq> [1;4mENABLED[m[1m qqqwqqqqqwqqqqqqqqqqu[m [1mx[m [1m x[m [1mmq>[m [1;4mDISABLED[m [1mqqj[m [1mx[m [1mx[m [1mx[m [1m mq>[m [1m( qwq> system-index-options qwq> ) qqj [m [1mx[m [1mx[m [1mmqqqqqqqqqq , <qqqqqqqqqqqj[m [1m [m [1mx[m [1mt> prestarted-transaction-params qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu[m [1m t> [1;4mSECURITY[m[1m [1;4mCHECKING[m[1m IS qq> security-checking-options qqqqqqqqqqqqqqqu[m [1mt> [1;4mSYNONYMS[m[1m ARE [1;4mENABLED[m[1m qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu[m [1mm> [1;4mNOTIFY[m[1m IS qwq> [1;4mENABLED[m[1m qq> notify-options[m [1mqwqqqqqqqqqqqqqqqqqqqqqj[m [1mmq> [1;4mDISABLED[m[1m qqqqqqqqqqqqqqqqqqqqj[m (B)0[m[1msystem-index-options =[m [1mqwq> [1;4mCOMPRESSION[m[1m IS[m [1mqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwwq[m [1;4mENABLED[m[1m qwwq>[m [1mtq>[m [1;4mPREFIX[m [1;4mCARDINALITY[m [1;4mCOLLECTION[m[1m IS[m [1mqqqqqqqqqqqqqqjm>[m [1;4mDISABLED[m[1m jx[m [1mtq>[m [1;4mPREFIX[m [1;4mCARDINALITY[m [1;4mCOLLECTION[m[1m IS [1;4mENABLED[m [1;4mFULL[m [1mqqqqqqqqqqqqqqqu[m [1mmq>[m [1;4mTYPE[m [1mIS [1;4mSORTED[m [1mqqwqqqqqqqqqqqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj[m [1mmq> [1;4mRANKED[m [1mqj[m (B)0[m[1mprestarted-transaction-params = [m [1mq> [1;4mPRESTARTED[m[1m [1;4mTRANSACTIONS[m[1m ARE qwwqq>[m [1;4mENABLED[m [1mqwwqqqqqqqqqqqqqqqqqqqqqqqqqqqqww>[m [1m [m [1mxmqq> [1;4mON[m[1m qqqqqjmq>(prestart-trans-options) qjx[m [1mmqwq> [1;4mDISABLED[m[1m qqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqj[m [1m mq> [1;4mOFF[m[1m qqqqqqqj [m (B)0[m[1mprestart-trans-options =[m [1mqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwq>[m [1mtq>[m [1;4mWAIT[m[1m <n> [1;4mSECONDS[m [1;4mFOR[m [1;4mTIMEOUT[m [1mqu[m [1mtq>[m [1;4mWAIT[m[1m <n> [1;4mMINUTES[m [1;4mFOR[m [1;4mTIMEOUT[m [1mqu[m [1mmq>[m [1;4mNO[m [1;4mTIMEOUT[m [1mqqqqqqqqqqqqqqqqqqqj[m (B)0[m[1msecurity-checking-options =[m [1mqwq>[m [1;4mEXTERNAL[m[1m qwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwwq>[m [1mx [m [1mmq>[m [1m( q> [1;4mPERSONA[m [1;4mSUPPORT[m[1m IS qwq>[m [1;4mENABLED[m [1mqqw> ) qjx[m [1mx[m [1mmq>[m [1;4mDISABLED[m [1mqj[m [1mx[m [1mmq> [1;4mINTERNAL[m[1m qwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqj[m [1mmq> ( q> [1;4mACCOUNT[m [1;4mCHECK[m[1m IS qwqqq>[m [1;4mENABLED[m [1mqqw> ) j[m [1mmqqq>[m [1;4mDISABLED[m[1m qj[m (B)0[m[1mnotify-options = [m [1m [m [1mqqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqq> [m [1m mqq> ( [1;4mALERT[m[1m [1;4mOPERATOR[m[1m qwqq> operator-class qwqq ) qqj [m [1m mqqqqqqqqq + <qqqqqqqqqj [m [1m [m (B)0[m[1mroot-file-params-4 = [m [1mqwq> [1;4mASYNC[m[1m [1;4mBATCH[m[1m [1;4mWRITES[m[1m ARE w> [1;4mENABLED[m[1m q> async-bat-wr-options qwqqqwq>[m [1m x m> [1;4mDISABLED[m[1m qqqqqqqqqqqqqqqqqqqqqqqqj x[m [1m twqqqqqqqqqqqqwq> [1;4mASYNC[m[1m [1;4mPREFETCH[m[1m IS qqk x[m [1m xm> [1;4mDETECTED[m[1m qj lqqqqqqqqqqqqqqqqqqqj x[m [1m x mqwq> [1;4mENABLED[m[1m qqq> async-prefetch-options wqqqqqqu[m [1m x mq> [1;4mDISABLED[m[1m qqqqqqqqqqqqqqqqqqqqqqqqqqqj x[m [1m tq> [1;4mROW[m[1m [1;4mCACHE[m[1m IS qwq> [1;4mENABLED[m[1m qqwqwqqqqqqqqqqqqqqqqqqqqqqwqqqqqqqqqu[m [1m x mq> [1;4mDISABLED[m[1m qj mq> row-cache-options qj x[m [1m tqwqqqqqqwq> [1;4mINCREMENTAL[m[1m [1;4mBACKUP[m[1m [1;4mSCAN[m[1m [1;4mOPTIMIZATION[m[1m qqqqqqqqqqqqqqqqqu [m [1m x m> [1;4mNO[m[1m qj [m [1m x [m [1m tq> [1;4mMULTITHREAD[m[1m [1;4mAREA[m[1m [1;4mADDITIONS[m[1m qqqq> multithread-options qqqqqqqqqqu [m [1m tq> [1;4mRECOVERY[m[1m [1;4mJOURNAL[m[1m q> ( q> ruj-options q> ) qqqqqqqqqqqqqqqqqqqqqu [m [1mtq> [1;4mOPEN[m[1m IS qw> [1;4mMANUAL[m [1mqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu[m [1mx[m [1mm> [1;4mAUTOMATIC[m [1mqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwu[m [1mx[m [1mmq>([1;4mWAIT[m[1m <n> q> MINUTES q> [1;4mFOR[m[1m [1;4mCLOSE[m[1m) qjx[m [1m mq> [1;4mSHARED[m[1m [1;4mMEMORY[m[1m IS qwq> [1;4mSYSTEM[m[1m qqqqqqqqqqqqqqqqqqqwqqqqqqqqqqqqqqj [m [1m mq> [1;4mPROCESS[m[1m qwqqqqqqqqqqqqqwqqj [m [1m [m [1mmq> [1;4mRESIDENT[m[1m qj[m (B)0[m[1masynch-bat-wr-options = [m [1m [m [1mqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqq>qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwq> [m [1m m ( wwq> [1;4mCLEAN[m[1m [1;4mBUFFER[m[1m [1;4mCOUNT[m[1m IS <buffer-count> [1;4mBUFFERS[m[1m qqww> ) j [m [1m xmq> [1;4mMAXIMUM[m[1m [1;4mBUFFER[m[1m [1;4mCOUNT[m[1m IS <buffer-count> [1;4mBUFFERS[m[1m jx [m [1m mqqqqqqqqqqqqqqqqqqq , <qqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1m [m (B)0[m[1;7ma[m[1msync-prefetch-options = [m [1m [m [1mqqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqw>[m [1m mq> ( qwqwq> [1;4mDEPTH[m[1m IS <number-buffers> [1;4mBUFFERS[m[1m qqqqqwqqw> )qj [m [1m x mq> [1;4mTHRESHOLD[m[1m IS <number-buffers> [1;4mBUFFERS[m[1m qj x [m [1m mqqqqqqqqqqqqqqqqq , <qqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1m [m (B)0[m[1mrow-cache-options = [m [1m [m [1mq> ( qwwq>[m [1;4mCHECKPOINT[m[1m qwq>[m [1;4mALL[m[1m [1;4mROWS[m[1m [1;4mTO[m[1m [1;4mBACKING[m[1m [1;4mFILE[m[1m qqqqqqqqqqqwqwwq> ) qq> [m [1m [m [1mxx[m [1mtq> [1;4mTIMED[m[1m EVERY <n> SECONDS[m [1mqqqqqqqqqqqqu[m [1mxx[m [1m [m [1mxx[m [1mmq>[m [1;4mUPDATED[m[1m [1;4mROWS[m[1m [1;4mTO[m[1m qwq> [1;4mBACKING[m[1m [1;4mFILE[m [1mqwj[m [1mxx[m [1m xx [m [1m mq> [1;4mDATABASE[m[1m qqqqqj[m [1mxx[m [1mxtq> [1;4mLOCATION[m[1m IS qq> <directory-spec> qqqqqqqqqqqqqqqqqqqqqux[m [1mxtq> [1;4mNO[m[1m qqwqq> [1;4mLOCATION[m[1m qqqqqqqqwqqqqqqqqqqqqqqqqqqqqqqqqqqux[m [1mxx[m [1mmqq>[m [1;4mSWEEP[m[1m [1;4mINTERVAL[m[1m qqj[m [1mxx[m [1mxtq>[m [1;4mNUMBER[m[1m OF [1;4mSWEEP[m[1m [1;4mROWS[m[1m IS <n>[m [1mqqqqqqqqqqqqqqqqqqqqqqqqqqux[m [1mxmq>[m [1;4mSWEEP[m[1m [1;4mINTERVAL[m[1m IS <n> SECONDS[m [1mqqqqqqqqqqqqqqqqqqqqqqqqjx[m [1mmqqqqqqqqqqqqqqqqqqqqqqqqqq , <qqqqqqqqqqqqqqqqqqqqqqqqqqqqqj[m (B)0[m[1mmultithread-options = [m [1m [m [1mqqqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqq> [m [1m mq> ( qqwq> [1;4mALL[m[1m [1;4mAREAS[m[1m qqqqqqqqqqqwqq> ) qqj [m [1m mq> [1;4mLIMIT[m[1m [1;4mTO[m[1m <n> [1;4mAREAS[m[1m qqj [m [1m [m (B)0[m[1mruj-options = [m [1m [m [1mqwq> [1;4mLOCATION[m[1m IS qq> <directory-spec> qwqq> [m [1m tq> [1;4mNO[m[1m [1;4mLOCATION[m[1m qqqqqqqqqqqqqqqqqqqqqqu [m [1m mq> [1;4mBUFFER[m[1m [1;4mMEMORY[m[1m IS qwq> [1;4mLOCAL[m[1m qqqqqqu [m [1mmq> [1;4mGLOBAL[m[1m qqqqqj[m (B)0[m[1mstorage-area-params-1 = [m [1m [m [1mqqwq> [1;4mALLOCATION[m[1m IS qqq> <number-pages> qq> PAGES qqqqqwq>[m [1m tq> [1;4mCACHE[m[1m [1;4mUSING[m[1m <row-cache-name> qqqqqqqqqqqqqqqqqqqqu [m [1m tq> [1;4mNO[m[1m ROW [1;4mCACHE[m[1m qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu [m [1m tq> extent-params qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu [m [1m tq> [1;4mINTERVAL[m[1m IS qq> <number-data-pages> qqqqqqqqqqqqqu [m [1m tq> [1;4mLOCKING[m[1m IS qqwq> [1;4mROW[m[1m qqwqq> LEVEL qqqqqqqqqqqqqqqu [m [1m x mq> [1;4mPAGE[m[1m qj x [m [1m tq> [1;4mPAGE[m[1m [1;4mFORMAT[m[1m IS wq> [1;4mUNIFORM[m[1m qwqqqqqqqqqqqqqqqqqqqqu [m [1m x mq> [1;4mMIXED[m[1m qqqj x [m [1m mq> [1;4mPAGE[m[1m [1;4mSIZE[m[1m IS qqqq> <page-blocks> qq> BLOCKS qqqqqj [m [1m [m (B)0[m[1mextent-params = [m [1m [m [1mqqwq> [1;4mEXTENT[m[1m IS qwq> [1;4mENABLED[m[1m qqqqqqqqqqqqqqqqqqqwwqq> [m [1m x tq> [1;4mDISABLED[m[1m qqqqqqqqqqqqqqqqqqux [m [1m x tq> <extent-pages> qq> PAGES qqux [m [1m x mq> (extension-options) qqqqqqqjx [m [1m mqqqqqqqqqqqqqqqqqqqqq<qqqqqqqqqqqqqqqqqqqqqqqqj [m [1m [m (B)0[m[1mextension-options = [m [1m [m [1mqqq> [1;4mMINIMUM[m[1m OF <min-pages> PAGES, qqk [m [1mlqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1mmqq> [1;4mMAXIMUM[m[1m OF <max-pages> PAGES, qqk [m [1mlqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1mmqq> [1;4mPERCENT[m[1m [1;4mGROWTH[m[1m IS <growth> qqqqqqq> [m [1m [m (B)0[m[1mstorage-area-params-2 = [m [1m [m [1mqqwq> [1;4mCHECKSUM[m[1m CALCULATION IS qqqqqqqqqqqwqqwq> [1;4mENABLED[m[1m qqwqwq>[m [1m tq> [1;4mSNAPSHOT[m[1m [1;4mCHECKSUM[m[1m CALCULATION IS qqj mq> [1;4mDISABLED[m[1m qj x [m [1m tq> [1;4mSNAPSHOT[m[1m [1;4mALLOCATION[m[1m IS qq> <snp-pages> qqqq> PAGES qqqu [m [1m tq> [1;4mSNAPSHOT[m[1m [1;4mEXTENT[m[1m IS qwq> <extent-pages> qqqq> PAGES qqwu [m [1m x mq> (extension-options) qqqqqqqqqjx [m [1m tq> [1;4mSNAPSHOT[m[1m [1;4mFILENAME[m[1m qq> <file-spec> qqqqqqqqqqqqqqqqqqqqu [m [1m tq> [1;4mTHRESHOLDS[m[1m ARE ( <val1> wqqqqqqqqqqqqqqqqqqqqqqqw> ) qu [m [1m x m> ,<val2> qwqqqqqqqqqqwj x [m [1m x m> ,<val3> j x [m [1m mq[mqqqqqqqqqqqqqqqqqqqqqqqqqqqqq[1m<qqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1m [m (B)0[m[1mcharacter-sets = [m [1m [m [1m [m [1mqwqwqq> [1;4mDEFAULT[m[1m [1;4mCHARACTER[m[1m [1;4mSET[m[1m <support-char-set> qqwqwq>[m [1m x[m [1mtqq> [1;4mNATIONAL[m[1m [1;4mCHARACTER[m[1m [1;4mSET[m[1m <support-char-set> qu x [m [1m x[m [1mtqq> [1;4mIDENTIFIER[m[1m [1;4mCHARACTER[m[1m [1;4mSET[m[1m <names-char-set> qj x [m [1mx[m [1mmqq> [1;4mDISPLAY[m[1m [1;4mCHARACTER[m[1m [1;4mSET[m[1m <support-char-set> qqqqu[m [1mmqqqqqqqqqqqqqqqqqqqqqq <qqqqqqqqqqqqqqqqqqqqqqqqqqqj[m (B)0[m[1mdatabase-element = [m [1m [m [1mqwq> create-cache-clause qqqqqqqqqqqqqqqqqwqq> [m [1m tq> create-catalog-statement qqqqqqqqqqqqu [m [1m tq> create-collating-sequence-statement qu [m [1m tq> create-domain-statement qqqqqqqqqqqqqu [m [1m tq> create-function-statement qqqqqqqqqqqu [m [1m tq> create-index-statement qqqqqqqqqqqqqqu [m [1m tq> create-module-statement qqqqqqqqqqqqqu [m [1m tq> create-procedure-statement qqqqqqqqqqu [m [1mtq> create-sequence-statement qqqqqqqqqqqu[m [1m tq> create-schema-statement qqqqqqqqqqqqqu [m [1m tq> create-storage-area-clause qqqqqqqqqqu [m [1m tq> create-storage-map-statement qqqqqqqqu [m [1m tq> create-table-statement qqqqqqqqqqqqqqu [m [1m tq> create-trigger-statement qqqqqqqqqqqqu [m [1m tq> create-view-statement qqqqqqqqqqqqqqqu [m [1m mq> grant-statement qqqqqqqqqqqqqqqqqqqqqj [m
4.3 – Arguments
4.3.1 – ADJUSTABLE_LOCK_GRANULARITY
Syntax options: ADJUSTABLE LOCK GRANULARITY IS ENABLED ADJUSTABLE LOCK GRANULARITY IS DISABLED Enables or disables whether or not the database system automatically maintains as few locks as possible on database resources. The default is ENABLED and results in fewer locks against the database. However, if contention for database resources is high, the automatic adjustment of locks can become a CPU drain. Such databases can trade more restrictive locking for less CPU usage by disabling adjustable lock granularity.
4.3.2 – alias
Specifies the alias for the implicit database declaration executed by the CREATE DATABASE statement. An alias is a name for a particular attach to a database that identifies that database in subsequent SQL statements. NOTE If you attach to a database using an alias, you must use that alias in subsequent statements to qualify the names of elements in that database. If you omit the FILENAME argument from the database root file parameters, SQL also uses the alias as the file name for the database root file and creates the root file in the current default directory. (SQL generates a syntax error if you include a disk or directory specification in the alias clause.) You must specify either the FILENAME or alias argument. Schema elements in the CREATE DATABASE statement do not need to use the alias, however, they cannot specify any other alias. The alias clause is optional. The default alias in interactive SQL and in precompiled programs is RDB$DBHANDLE. In the SQL module language, the default is the alias specified in the module header. Using the default alias (either by specifying it explicitly in the ALIAS clause or omitting the ALIAS clause) declares the database as the default database. Specifying a default database means that statements outside the CREATE DATABASE statement that refer to the default database do not need to use an alias. If a default database was already declared, and you specify the default alias in the ALIAS clause (or specify any alias that was already declared), the results depend on the environment in which you issue the CREATE DATABASE statement. o In interactive SQL, you receive a prompt asking if you want to override the default database declaration. Unless you explicitly override the default declaration, the CREATE DATABASE statement fails. SQL> -- Assume a default database has been declared: SQL> -- SQL> -- Now create a database without an alias. SQL> -- SQL asks if you want to override the default: SQL> CREATE DATABASE FILENAME test; This alias has already been declared. Would you like to override this declaration (No)? NO %SQL-F-DEFDBDEC, A database has already been declared with the default alias o In embedded SQL or in the SQL module language, specifying an already-declared alias in the CREATE DATABASE statement generates an error when you precompile the program or compile the module. o In dynamic SQL, specifying an already-declared alias overrides the earlier declaration. For more information about default databases, see the User_ Supplied_Names HELP topic.
4.3.3 – ALL_AREAS
Specifies that all storage areas be created and initialized in parallel. All storage areas are created asynchronously. If you are creating a large number of storage areas, you may exceed process quotas, resulting in the database creation failing.
4.3.4 – ALLOCATION n pages
The number of database pages allocated to the database initially. SQL automatically extends the allocation to handle the loading of data and subsequent expansion. Pages are allocated in groups of 3. An ALLOCATION of 25 pages would actually provide for 27 pages. The default is 700 pages. If you are loading a large database, a large allocation helps to prevent fragmented files.
4.3.5 – ALTER_TRANSACTION_MODES
Enables the modes specified, leaving the previously defined or default modes enabled. For example, if the only transaction mode you want to disable are batch updates, use the following statement: SQL> CREATE DATABASE FILENAME mf_personnel cont> ALTER TRANSACTION MODES (NO BATCH UPDATE); If not specified, the default transaction mode is ALL.
4.3.6 – ASYNC_BATCH_WRITES
Syntax options: ASYNC BATCH WRITES ARE ENABLED | ASYNC BATCH WRITES ARE DISABLED Specifies whether asynchronous batch-writes are enabled or disabled. Asynchronous batch-writes allow a process to write batches of modified data pages to disk asynchronously (the process does not stall while waiting for the batch-write operation to complete). Asynchronous batch-writes improve the performance of update applications without the loss of data integrity. By default, batch-writes are enabled. For more information about when to use asynchronous batch-writes, see the Oracle Rdb7 Guide to Database Performance and Tuning. You can enable asynchronous batch-writes by defining the logical name RDM$BIND_ABW_ENABLED.
4.3.7 – ASYNC_PREFETCH
Syntax options: ASYNC PREFETCH IS ENABLED | ASYNC PREFETCH IS DISABLED Specifies whether or not Oracle Rdb reduces the amount of time that a process waits for pages to be read from disk by fetching pages before a process actually requests the pages. Prefetch can significantly improve performance, but it may cause excessive resource usage if it is used inappropriately. Asynchronous prefetch is enabled by default. For more information about asynchronous prefetch, see the Oracle Rdb7 Guide to Database Performance and Tuning. You can enable asynchronous prefetch by defining the logical name RDM$BIND_APF_ENABLED.
4.3.8 – BUFFER_SIZE
Specifies the number of blocks SQL allocates per buffer. You need to specify an unsigned integer greater than zero. The default buffer size is 3 times the PAGE SIZE value (6 blocks for the default PAGE SIZE of 2). The buffer size is a global parameter and the number of blocks per page (or buffer) is constrained to less than 64 blocks per page. The page size can vary by storage area for multifile databases, and the page size should be determined by the sizes of the records that will be stored in each storage area. When choosing the number of blocks per buffer, choose a number so that a round number of pages fits in the buffer. In other words, the buffer size is wholly divisible by all page sizes for all storage areas in your multifile database. For example, if you have three storage areas with page sizes of 2, 3, and 4 blocks each respectively, choosing a buffer size of 12 blocks ensures optimal buffer utilization. In contrast, choosing a buffer size of 8 wastes 2 blocks per buffer for the storage area with a page size of 3 pages. Oracle Rdb reads as many pages as fit into the buffer; in this instance it reads two 3-block pages into the buffer, leaving 2 wasted blocks.
4.3.9 – CACHE_USING
Assigns the named row cache as the default for all storage areas in the database. All rows stored in an area, whether they consist of table data, segmented string data, or special rows such as index nodes, are cached. You must create the row cache before terminating the CREATE DATABASE statement. For example: SQL> CREATE DATABASE FILENAME test_db cont> ROW CACHE IS ENABLED cont> CACHE USING test1 cont> CREATE CACHE test1 cont> CACHE SIZE IS 100 ROWS cont> CREATE STORAGE AREA area1; You can override the database default row cache by either specifying the CACHE USING clause after the CREATE STORAGE AREA clause or by later altering the database and storage area to assign a new row cache. Only one row cache is allowed for each storage area. If you do not specify the CACHE USING clause or the NO ROW CACHE clause, NO ROW CACHE is the default for the database.
4.3.10 – CARDINALITY_COLLECTION
Syntax options: CARDINALITY COLLECTION IS ENABLED CARDINALITY COLLECTION IS DISABLED Specifies whether or not the optimizer records cardinality updates in the system table. When enabled, the optimizer collects cardinalities for the table and non-unique indexes as rows are inserted or deleted from tables. The update of the cardinalities is performed at commit time, if sufficient changes have accumulated, or at disconnect time. In high update environments, it may be more convenient to disable cardinality updates. If you disable this feature, you should manually maintain the cardinalities using the RMU Analyze Cardinality command so the optimizer is given the most accurate values for estimation purposes. Cardinality collection is enabled by default.
4.3.11 – CARRY_OVER_LOCKS
Syntax options: CARRY OVER LOCKS ARE ENABLED | CARRY OVER LOCKS ARE DISABLED Enables or disables carry-over lock optimization. Carry-over locks are enabled by default. While attached to the database, a process can have some active locks (locks attached to the database) and some carry-over locks (locks requested in earlier transactions that have not been demoted). If a transaction needs a lock it has currently marked as carry-over, it can reuse the lock by changing it to an active lock. The same lock can go from active to carry-over to active multiple times without paying the cost of lock request and demotion. This substantially reduces the number of lock requests if a process accesses the same areas repeatedly. As part of the carry-over lock optimization, a NOWAIT transaction requests, acquires, and holds a NOWAIT lock. This signals other processes accessing the database that a NOWAIT transaction exists and causes Oracle Rdb to release all carry-over locks. If NOWAIT transactions are noticeably slow when executing, you can specify CARRY OVER LOCKS ARE DISABLED with the ALTER DATABASE or CREATE DATABASE statement. This feature is available as an online database modification.
4.3.12 – CHECKPOINT_TIMED
Syntax option: CHECKPOINT TIMED EVERY n SECONDS For the row-cache-options clause, specifies the frequency with which the row-cache server (RCS) process checkpoints the contents of the row caches back to disk. The RCS process does not use the checkpoint frequency options of the FAST COMMIT clause. The frequency of RCS checkpointing is important in determining how much of an .aij file must be read during a recovery operation following a node failure. It also affects the frequency with which marked records get flushed back to the database for those row caches that checkpoint to the database. The default is every 15 minutes (900 seconds).
4.3.13 – Checkpoint Rows
Syntax options: CHECKPOINT UPDATED ROWS TO BACKING FILE CHECKPOINT UPDATED ROWS TO DATABASE CHECKPOINT ALL ROWS TO BACKING FILE Specifies the default source and target during checkpoint operations for all row caches. If ALL ROWS is specified, then the source records written during each checkpoint operation are both the modified and the unmodified rows in a row cache. If UPDATED ROWS is specified, then just the modified rows in a row cache are checkpointed each time. If the target of the checkpoint operation is BACKING FILE, then the RCS process writes the source row cache entries to the backing (.rdc) files. The row cache LOCATION, ALLOCATION, and EXTENT clauses are used to create the backing files. Upon recovery from a node failure, the database recovery process is able to repopulate the row caches in memory from the rows found in the backing files. If the target is DATABASE, then updated row cache entries are written back to the database. The row cache LOCATION, ALLOCATION, and EXTENT clauses are ignored. Upon recovery from a node failure, the database recovery process has no data on the contents of the row cache. Therefore, it does not repopulate the row caches in memory. The CHECKPOINT clause of the CREATE CACHE, ADD CACHE, or ALTER CACHE clause overrides this database-level CHECKPOINT clause.
4.3.14 – CHECKSUM_CALCULATION
Syntax options: CHECKSUM CALCULATION IS ENABLED CHECKSUM CALCULATION IS DISABLED This option allows you to enable or disable calculations of page checksums when pages are read from or written to the storage area or snapshot files. The default is ENABLED. NOTE Oracle Corporation recommends that you leave checksum calculations enabled, which is the default. With current technology, it is possible that errors may occur that the checksum calculation can detect but that may not be detected by either the hardware, firmware, or software. Unexpected application results and database corruption may occur if corrupt pages exist in memory or on disk but are not detected. Oracle Corporation recommends performing checksum calculations, except in the following specific circumstances: o Your application is stable and has run without errors on the current hardware and software configuration for an extended period of time. o You have reached maximum CPU utilization in your current configuration. Actual CPU utilization by the checksum calculation depends primarily on the size of the database pages in your database. The larger the database page, the more noticeable the CPU usage by the checksum calculation may become. NOTE Oracle Corporation recommends that you carefully evaluate the trade-off between reducing CPU usage by the checksum calculation and the potential for loss of database integrity if checksum calculations are disabled. Oracle Rdb allows you to disable and, subsequently, re-enable checksum calculation without error. However, once checksum calculations have been disabled, corrupt pages may not be detected even if checksum calculations are subsequently re- enabled.
4.3.15 – CLEAN_BUFFER_COUNT
Syntax options: CLEAN BUFFER COUNT IS buffer-count BUFFERS Specifies the number of buffers to be kept available for immediate reuse. Oracle Rdb maintains the number of buffers at the end of a process' least recently used queue of buffers for replacement. The default is five buffers. The minimum value is one; the maximum value can be as large as the buffer pool size. You can override the number of clean buffers by defining the logical name RDM$BIND_CLEAN_BUF_CNT. For information about how to set the values, see the Oracle Rdb7 Guide to Database Performance and Tuning.
4.3.16 – COLLATING_SEQUENCE
Specifies a default collating sequence to be used for all CHAR and VARCHAR columns in the database. SQL uses the default collating sequence if you do not specify a collating sequence in subsequent CREATE DOMAIN statements. Collation-name is a name of your choosing; you must use this name in any COLLATING SEQUENCE clauses that refer to this collating sequence for operations on this database.
4.3.17 – COMMENT
Syntax option: COMMENT IS 'string' Adds a comment about the collating sequence. SQL displays the text when it executes a SHOW COLLATING SEQUENCE statement in interactive SQL. Enclose the comment in single quotation marks (') and separate multiple lines in a comment with a slash mark (/).
4.3.18 – COUNT IS n
Specifies the number of levels on the page lock tree used to manage locks. For example, if you specify COUNT IS 3, the fanout factor is (10, 100, 1000). Oracle Rdb locks a range of 1000 pages and adjusts downward to 100 and then to 10 and then to 1 page when necessary. If the COUNT IS clause is omitted, the default is 3. The value of n can range from 1 through 8.
4.3.19 – create-cache-clause
See the CREATE CACHE clause for more details.
4.3.20 – create-catalog-statement
See the CREATE CATALOG statement for details. If you want to specify a CREATE CATALOG statement in a CREATE DATABASE statement, you must first specify a MULTISCHEMA IS ON clause in the same CREATE DATABASE statement. The CREATE CATALOG statement is committed immediately and cannot be rolled back. Before you specify the CREATE CATALOG statement, the following conditions must be true: o The database is enabled for multischema. o No transactions are active. o The catalog alias must be the same as the database alias. For information about enabling the database for multischema, see the User_Supplied_Names HELP topic.
4.3.21 – create-collating-sequence-statement
See the CREATE COLLATING_SEQUENCE statement for details. If you want to specify a collating sequence in a CREATE DOMAIN statement embedded in a CREATE DATABASE statement, you must first specify a CREATE COLLATING SEQUENCE statement in the same CREATE DATABASE statement.
4.3.22 – create-domain-statement
See the CREATE DOMAIN statement for details. You cannot use the FROM path-name clause when embedding a CREATE DOMAIN statement in a CREATE DATABASE statement. You can, however, issue a separate CREATE DOMAIN statement following the CREATE DATABASE statement. You can also describe the domain directly in the CREATE DATABASE statement. If you want to specify a collating sequence in your embedded CREATE DOMAIN statement, you must first specify a CREATE COLLATING SEQUENCE statement in the same CREATE DATABASE statement.
4.3.23 – create-function-statement
A CREATE FUNCTION statement. See the CREATE Routine statement for details.
4.3.24 – create-index-statement
See the CREATE INDEX statement for details.
4.3.25 – create-module-statement
See the CREATE MODULE statement for details.
4.3.26 – create-procedure-statement
A CREATE PROCEDURE statement. See the CREATE Routine statement for details.
4.3.27 – create-schema-statement
See the CREATE SCHEMA statement for details. The schema you create must have the same alias as the catalog and database that contain the schema, or they must share the default alias.
4.3.28 – create-sequence-statement
See the CREATE SEQUENCE statement for details.
4.3.29 – create-storage-area-clause
See the CREATE STORAGE_AREA statement for more details.
4.3.30 – create-storage-map-statement
See the CREATE STORAGE_MAP statement for details.
4.3.31 – create-table-statement
See the CREATE TABLE statement for details. You cannot use the FROM path-name clause when embedding a CREATE TABLE statement in a CREATE DATABASE statement. You can, however, issue a separate CREATE TABLE statement following the CREATE DATABASE statement. You can also describe the table directly in the CREATE DATABASE statement. The CREATE TABLE statements in a CREATE DATABASE statement can refer to domains not yet created, provided that CREATE DOMAIN statements for the domains are in the same CREATE DATABASE statement.
4.3.32 – create-trigger-statement
See the CREATE TRIGGER statement for details.
4.3.33 – create-view-statement
See the CREATE VIEW statement for details.
4.3.34 – database-element
Database elements are a CREATE STORAGE AREA clause, any of the CREATE statements (except CREATE DOMAIN . . . FROM path-name and CREATE TABLE . . . FROM path-name), or a GRANT statement.
4.3.35 – DBKEY_SCOPE
Syntax options: DBKEY SCOPE IS ATTACH | DBKEY SCOPE IS TRANSACTION Controls when the database key of a deleted row can be used again by SQL. This setting is not a database root file parameter, but a characteristic of the implicit database attach executed by the CREATE DATABASE statement. Thus, the DBKEY SCOPE clause in a CREATE DATABASE statement takes effect only for the duration of the session of the user who entered the statement. o The default DBKEY SCOPE IS TRANSACTION means that SQL can reuse the database key of a deleted table row (to refer to a newly inserted row) as soon as the transaction that deleted the original row completes with a COMMIT statement. (If the user who deleted the original row enters a ROLLBACK statement, then the database key for that row cannot be used again by SQL.) During the connection of the user who entered the CREATE DATABASE statement, the DBKEY SCOPE IS TRANSACTION clause specifies that a database key is guaranteed to refer to the same row only within a particular transaction. o The DBKEY SCOPE IS ATTACH clause means that SQL cannot use the database key again (to refer to a newly inserted row) until all users who have attached with DBKEY SCOPE IS ATTACH have detached from the database. Also it only requires one process to attach with DBKEY SCOPE IS ATTACH to force all database users to assume this characteristic. o Oracle Corporation recommends using DBKEY SCOPE IS TRANSACTION to prevent excessive consumption of storage area space by overhead needed to support DBKEY SCOPE IS ATTACH, and to prevent performance problems when storing new rows. During the connection of the user who entered the CREATE DATABASE statement, the DBKEY SCOPE IS ATTACH clause specifies that a database key is guaranteed to refer to the same row until the user detaches from the database. For more information, see the DBKEY HELP topic.
4.3.36 – DEFAULT_CHARACTER_SET
Specifies the database default character set for this database. For a list of allowable character set names, see Supported Character Sets.
4.3.37 – DEFAULT_STORAGE_AREA
Specifies a default storage area to which all user data and unmapped indexes are stored. The DEFAULT STORAGE AREA parameter separates user data from the system data, such as system tables. RDB$SYSTEM is the default area if you do not specify a default storage area. In addition to user data, Oracle Rdb stores the following system tables in the default storage area: o RDB$INTERRELATIONS o RDB$MODULES o RDB$ROUTINES o RDB$PARAMETERS o RDB$QUERY_OUTLINES o RDB$SEQUENCES o RDB$PROFILES o RDB$GRANTED_PROFILES o RDB$TYPES o RDB$TYPE_FIELDS o RDB$WORKLOAD o RDB$OBJECT_SYNONYMS o RDB$SYNONYMS o RDB$CATALOG_SCHEMA For information on moving these system tables to other storage areas, see the Oracle Rdb Guide to Database Design and Definition. The DEFAULT STORAGE AREA parameter must reference an existing storage area. You must create the storage area using the CREATE STORAGE AREA clause in the same CREATE DATABASE statement as the DEFAULT STORAGE AREA parameter.
4.3.38 – DEPTH buffers option
Syntax option: DEPTH IS number-buffers BUFFERS Specifies the number of buffers to prefetch for a process. The default is one-quarter of the buffer pool, but not more than eight buffers. You can override the number of buffers specified in the CREATE or ALTER DATABASE statements by using the logical name RDM$BIND_APF_DEPTH. You can also specify this option with the DETECTED ASYNC PREFETCH clause.
4.3.39 – DETECTED_ASYNC_PREFETCH
Syntax options: DETECTED ASYNC PREFETCH IS ENABLED DETECTED ASYNC PREFETCH IS DISABLED Specifies whether or not Oracle Rdb reduces the amount of time that a process waits for pages to be read from disk. By using heuristics, detected asynchronous prefetch determines if an I/O pattern is sequential in behavior even if sequential I/O is not actually executing at the time. For example, when a LIST OF BYTE VARYING column is fetched, the heuristics detect that the pages being fetched are sequential and asynchronously fetches pages further in the sequence. This avoids wait times when the page is really needed. Detected asynchronous prefetch is enabled by default.
4.3.40 – DICTIONARY
Syntax options: DICTIONARY IS REQUIRED | DICTIONARY IS NOT REQUIRED Specifies whether or not definition statements issued for the database must also be stored in the repository. If you specify REQUIRED, any data definition statements issued after a DECLARE DATABASE statement that does not use the PATHNAME argument fails. If you omit the PATHNAME clause from the database root file parameters in the CREATE DATABASE statement, SQL generates an error if you also specify DICTIONARY IS REQUIRED. The default is DICTIONARY IS NOT REQUIRED.
4.3.41 – DISPLAY_CHARACTER_SET
Specifies the character set encoding and characteristics expected of text strings returned back to SQL from Oracle Rdb.
4.3.42 – EXTENT clause
Syntax options: EXTENT IS ENABLED | EXTENT IS DISABLED Enables or disables extents. Extents are enabled by default. You can encounter performance problems when creating hashed indexes in storage areas with the mixed page format if the storage area was created specifying the wrong size for the area and if extents are enabled. By disabling extents, this problem can be diagnosed early and corrected to improve performance.
4.3.43 – EXTENT pages
Syntax options: EXTENT IS extent-pages PAGES| EXTENT IS (extension-options) Specifies the number of pages of each storage area file extent. For more information, see the SNAPSHOT EXTENT argument.
4.3.44 – FILENAME file spec
The file specification associated with the database. You can omit the FILENAME clause if you specify the ALIAS clause. If you omit the FILENAME clause, the file specification uses the following defaults: o Device: the current device for the process o Directory: the current directory for the process o File name: the alias, if any was specified; otherwise omitting the FILENAME clause generates an error Use either a full file specification or a partial file specification. You can use a logical name for all or part of a file specification. If you use a simple file name, SQL creates the database in the current default directory. Because the CREATE DATABASE statement may create more than one file with different file extensions, do not specify a file extension with the file specification. The file specification may contain an OpenVMS remote node specification. Oracle Rdb must be installed on that remote node so that the CREATE DATABASE statement can be executed remotely. Note that all other file specifications in the command (storage areas, snapshot files, recovery journal location, and so on) must be specified using the logical names and device names relative to that remote node. The number and type of files created using the file specification in the FILENAME clause depend on whether you create a multifile or single-file database. o In multifile CREATE DATABASE statements (any that include CREATE STORAGE AREA clauses), SQL uses the file specification to create up to three files: - A database root file with an .rdb file extension - A storage area file, with an .rda file extension, for the main storage area, RDB$SYSTEM, (unless the CREATE DATABASE statement contains a CREATE STORAGE AREA RDB$SYSTEM clause, which overrides this file specification) - A snapshot file, with an .snp file extension, for the main storage area, RDB$SYSTEM (unless the CREATE DATABASE statement contains a CREATE STORAGE AREA RDB$SYSTEM clause, which overrides this file specification) o In single-file CREATE DATABASE statements (any that omit the CREATE STORAGE AREA clause), SQL uses the file specification to create two files: - A combined root and data file with an .rdb file extension - A snapshot file with an .snp file extension If you create a single-file database, you cannot later create additional data and snapshot files with ALTER DATABASE . . . ADD STORAGE AREA statements. If you want to change a database from a single-file to a multifile database, you must use the EXPORT and IMPORT statements.
4.3.45 – FROM library name
Specifies the name of an NCS library other than the default library. The default NCS library is SYS$LIBRARY:NCS$LIBRARY.
4.3.46 – GALAXY_SUPPORT
Syntax options: GALAXY SUPPORT IS ENABLED|GALAXY SUPPORT IS DISABLED Allows global memory to be shared in an OpenVMS Galaxy configuration. Galaxy support is disabled by default. OpenVMS Galaxy is a software architecture for the OpenVMS Alpha operating system that enables multiple instances of OpenVMS to execute cooperatively in a single computer. An instance refers to a copy of the OpenVMS Alpha operating system. As an extension of the existing OpenVMS cluster support within Oracle Rdb, Oracle Rdb provides support for databases opened on multiple instances (or nodes) within a Galaxy system to share data structures in memory. Within an Oracle Rdb Galaxy environment, all instances with an open database share: o Database root objects (for example, TSN blocks and SEQ blocks) o Global buffers (if enabled) o Row caches and Row Cache Server process (RCS) (if enabled)
4.3.47 – GLOBAL_BUFFERS
Syntax options: GLOBAL BUFFERS ARE ENABLED | GLOBAL BUFFERS ARE DISABLED Specifies that Oracle Rdb maintains one global buffer pool per VMScluster node for each database. By default, Oracle Rdb maintains a local buffer pool for each attach. For more than one attach to use the same page, each must read it from disk into its local buffer pool. A page in the global buffer pool may be read by more than one attach at the same time, although only one process reads the page from the disk into the global buffer pool. Global buffering provides improved performance because I/O is reduced and memory is better utilized. NOTE If GALAXY SUPPORT is enabled, then a single global buffer pool is shared by all Galaxy nodes.
4.3.48 – grant-statement
See the GRANT statement for details.
4.3.49 – IDENTIFIER_CHARACTER_SET
Specifies the identifier character set for user-supplied database object names, such as table names and column names. The character set must contain ASCII characters. See the Oracle Rdb SQL Reference Manual for a list of allowable character sets.
4.3.50 – INCREMENTAL_BACKUP_SCAN_OPTIMIZATION
Syntax option: INCREMENTAL BACKUP SCAN OPTIMIZATION NO INCREMENTAL BACKUP SCAN OPTIMIZATION Specifies whether Oracle Rdb checks each area's SPAM pages or each database page to find changes during incremental backup. If you specify INCREMENTAL BACKUP SCAN OPTIMIZATION, Oracle Rdb checks each area's SPAM pages and scans the SPAM interval of pages only if the SPAM transaction number (TSN) is higher than the root file backup TSN, which indicates that a page in the SPAM interval has been updated since the last full backup operation. Updates in the SPAM interval result in an extra I/O. Specify INCREMENTAL BACKUP SCAN OPTIMIZATION if your database has large SPAM intervals or infrequently occurring updates, and you want to increase the speed of incremental backups. If you specify NO INCREMENTAL BACKUP SCAN OPTIMIZATION, Oracle Rdb checks each page to find changes during incremental backup. Specify the NO INCREMENTAL BACKUP SCAN OPTIMIZATION clause if your database has frequently occurring updates, uses bulk-load operations, or does not use incremental backups, or if you want to improve run-time performance. The default is INCREMENTAL BACKUP SCAN OPTIMIZATION.
4.3.51 – INTERVAL
Specifies the number of data pages between space area management (SPAM) pages in the storage area file, and therefore the maximum number of data pages each space area management page will manage. The default, and also the minimum interval, is 216 data pages. The first page of each storage area is a space area management page. The interval you specify determines where subsequent space area management pages are to be inserted, provided there are enough data pages in the storage file to require more space area management pages. You cannot specify the INTERVAL storage area parameter for single-file databases, and you cannot specify INTERVAL unless you also explicitly specify PAGE FORMAT IS MIXED. Oracle Rdb calculates the maximum interval size based on the number of blocks per page and returns an error message if you exceed this value. For example, when the page size is 2 blocks, the maximum interval is 4008 pages. If you try to create a storage area with the interval set to 4009, Oracle Rdb returns the following error message: %RDB-E-BAD_DPB_CONTENT, invalid database parameters in the database parameter block (DPB) -RDMS-F-SPIMAX, spam interval of 4009 is more than the Rdb maximum of 4008 -RDMS-F-AREA_NAME, area NEW For more information about setting space area management parameters, see the Oracle Rdb Guide to Database Maintenance.
4.3.52 – LARGE_MEMORY
Syntax options: LARGE MEMORY IS ENABLED | LARGE MEMORY IS DISABLED Specifies whether or not large memory is used to manage the row cache. Very large memory (VLM) allows Oracle Rdb to use as much physical memory as is available. Use the LARGE MEMORY IS ENABLED clause only when both of the following are true: o You have enabled row caching. o You want to cache large amounts of data, but the cache does not fit in the virtual address space. The default is the LARGE MEMORY IS DISABLED clause.
4.3.53 – LIMIT TO n AREAS
Specifies the number of storage areas to be created in parallel. The number of areas should be smaller than the current process file open quota. The number of areas can range from between 1 and the number of storage areas being created.
4.3.54 – LIST_STORAGE_AREA
Specifies the name of the storage area to be used for table columns defined through SQL with the LIST OF BYTE VARYING data type. You can specify the LIST STORAGE AREA parameter for multifile databases only. By default, columns with the LIST OF BYTE VARYING data type are stored in the RDB$SYSTEM storage area. If you specify a different storage area in this clause, the CREATE DATABASE statement must include a CREATE STORAGE AREA clause defining that area. For information about creating multiple list storage areas for a table, see the CREATE STORAGE_AREA clause. NOTE If you plan to store lists with segments of widely varying sizes, you should specify a MIXED page format area just for list storage. (Do not assign tables and indexes to the area.) The database system looks for free space in an area when it stores each segment of a segmented string. If size varies significantly among the different segments of the lists that you plan to store, the interval and threshold values that the database system automatically sets for page format areas you specify as UNIFORM can make storing lists time- consuming. For a mixed page format area, you can customize interval and thresholds values to reduce the amount of time that the database system spends looking for free space when it stores different segments of the same segmented string. The following example shows valid syntax for the LIST STORAGE AREA clause: SQL> CREATE DATABASE FILENAME test cont> LIST STORAGE AREA IS registry_area cont> CREATE STORAGE AREA RDB$SYSTEM FILENAME maintenance_area cont> CREATE STORAGE AREA registry_area FILENAME registry_area; SQL> CREATE STORAGE MAP registry_map cont> STORE LISTS IN registry_area;
4.3.55 – literal-user-auth
Specifies the user name and password for access to databases, particularly remote database. This literal lets you explicitly provide user name and password information in the CREATE DATABASE statement.
4.3.56 – LOCATION IS directory spec
Specifies the name of the backing store directory to which row cache information is written. The database system generates a file name (row-cache-name.rdc) automatically for each row cache at checkpoint time. Specify a device name and directory name only, enclosed within single quotation marks. The file name is the row-cache-name specified when creating the row cache. By default, the location is the directory of the database root file. These .rdc files are permanent database backing store files. The LOCATION clause of the CREATE CACHE, ADD CACHE, or ALTER CACHE clause overrides this location, which is the default for the database. This clause is ignored if the row cache is defined to checkpoint to the database.
4.3.57 – LOCK_PARTITIONING
Syntax options: LOCK PARTITIONING IS ENABLED | LOCK PARTITIONING IS DISABLED Specifies whether more than one lock tree is used for the database or all lock trees for a database are mastered by one database resource tree. When partitioned lock trees are enabled for a database, locks for storage areas are separated from the database resource tree and all locks for each storage area are independently mastered on the VMScluster node that has the highest traffic for that resource. OpenVMS determines the node that is using each resource the most and moves the resource hierarchy to that node. You cannot enable lock partitioning for single-file databases. You should not enable lock partitioning for single-node systems, because all lock requests are local on single-node systems. By default, lock partitioning is disabled.
4.3.58 – LOCK_TIMEOUT_INTERVAL
Syntax option: LOCK TIMEOUT INTERVAL IS number-seconds SECONDS Specifies the number of seconds for processes to wait during a lock conflict before timing out. The number of seconds can be between 1 and 65,000 seconds. Specifying 0 is interpreted as no lock timeout interval being set. It is not interpreted as 0 seconds. The lock timeout interval is database-wide; it is used as the default as well as the upper limit for determining the timeout interval. For example, if the database definer specified LOCK TIMEOUT INTERVAL IS 25 SECONDS in the CREATE DATABASE statement, and a user of that database specified SET TRANSACTION WAIT 30 or changed the logical name RDM$BIND_LOCK_TIMEOUT_INTERVAL to 30, SQL uses the interval of 25 seconds. For more information, see the SET_TRANSACTION statement and the Oracle Rdb7 Guide to Distributed Transactions.
4.3.59 – LOCKING level
Syntax options: LOCKING IS ROW LEVEL | LOCKING IS PAGE LEVEL Specifies page-level or row-level locking as the default for the database. This clause provides an alternative to requesting locks on records. You can override the database default lock level at the storage area level. The default is ROW LEVEL, which is compatible with previous versions of Oracle Rdb. When many records are accessed in the same area and on the same page, the LOCKING IS PAGE LEVEL clause reduces the number of lock operations perfomed to process a transaction; however, this is at the expense of reduced concurrency. Transactions that benefit most with page-level locking are of short duration and also access several database records on the same page. Use the LOCKING IS ROW LEVEL clause if transactions are long in duration and lock many rows. The LOCKING IS PAGE LEVEL clause causes fewer blocking ASTs and provides better response time and utilization of system resources. However, there is a higher contention for pages and increased potential for deadlocks and long transactions may use excessive locks. Page-level locking is never applied to RDB$SYSTEM or the DEFAULT storage area, either implicitly or explicitly, because the lock protocol can stall metadata users. You cannot specify page-level locking on single-file databases.
4.3.60 – LOGMINER_SUPPORT
Syntax options: LOGMINER SUPPORT IS ENABLED|LOGMINER SUPPORT IS DISABLED Allows additional information to be written to the after-image journal file to allow the use of the RMU Unload After_Image command. See Oracle RMU Reference Manual for more details. Logminer support is disabled by default. The LOGMINER SUPPORT clause allows the continuous mode for LogMiner to be enabled and disabled. o LOGMINER SUPPORT IS ENABLED (CONTINUOUS) Enables continuous LogMiner. o LOGMINER SUPPORT IS ENABLED (NOT CONTINUOUS) Disables continuous LogMiner, but leaves LogMiner enabled. o LOGMINER SUPPORT IS DISABLED Disables LogMiner, including disabling continuous LogMiner.
4.3.61 – MAXIMUM_BUFFER_COUNT
Specifies the number of buffers a process will write asynchronously. The default is one-fifth of the buffer pool, but not more than 10 buffers. The minimum value is 2 buffers; the maximum value can be as large as the buffer pool. You can override the number of buffers to be written asynchronously by defining the logical name RDM$BIND_BATCH_MAX. For information about how to set the values, see the Oracle Rdb7 Guide to Database Performance and Tuning.
4.3.62 – MAXIMUM extent pages
Syntax option: MAXIMUM OF max-pages PAGES Specifies the maximum number of pages of each extent. The default is 9999 pages.
4.3.63 – METADATA_CHANGES
Syntax options: METADATA CHANGES ARE ENABLED | METADATA CHANGES ARE DISABLED Specifies whether or not data definition changes are allowed to the database. This attribute becomes effective at the next database attach and affects all ALTER, CREATE, and DROP statements (except ALTER DATABASE, which is needed for database tuning) and the GRANT, REVOKE, TRUNCATE TABLE, COMMENT ON and RENAME statements. For example: SQL> CREATE DATABASE FILENAME sample cont> METADATA CHANGES ARE DISABLED; SQL> CREATE TABLE t (a INTEGER); SQL> DISCONNECT ALL; SQL> ATTACH 'FILENAME sample'; SQL> CREATE TABLE s (b INTEGER); %RDB-E-NO_META_UPDATE, metadata update failed -RDMS-E-NOMETADATA, metadata operations are disabled The METADATA CHANGES ARE DISABLED clause prevents data definition changes to the database. If you specify this clause in the CREATE DATABASE statement, system index compression is implicitly enabled. The METADATA CHANGES ARE ENABLED clause allows data definition changes to the database by users granted the DBADMIN privilege. METADATA CHANGES ARE ENABLED is the default.
4.3.64 – MINIMUM extent pages
Syntax option: MINIMUM OF min-pages PAGES Specifies the minimum number of pages of each extent. The default is 99 pages.
4.3.65 – MULTISCHEMA
Syntax options: MULTISCHEMA IS ON | MULTISCHEMA IS OFF Specifies the multischema attribute for the database. You must specify the multischema attribute for your database to create multiple schemas and store them in catalogs. Each time you attach to a database created with the multischema attribute, you can specify whether you want multischema naming enabled or disabled for subsequent statements. For more information on multischema naming, see the User_Supplied_Names HELP topic. If you prefer to access a database created with the multischema attribute as though it were single-schema database, you can turn off multischema naming using the MULTISCHEMA IS OFF clause in the ATTACH or DECLARE ALIAS statement. If you have turned off the multischema attribute, you can enable it again using the MULTISCHEMA IS ON clause in the ATTACH or DECLARE ALIAS statement. You can use multischema naming only when you are attached to a database that was created with the multischema attribute. For more information, see the ATTACH statement. Multischema naming is disabled by default.
4.3.66 – MULTITHREAD_AREA_ADDITIONS
Specifies whether Oracle Rdb creates all storage areas in parallel, creates a specified number in parallel, or creates areas serially. This clause lets you determine the number of storage areas to be created in parallel, possibly saving time during the initial database creation. However, if you specify a large number of storage areas and many areas share the same device, multithreading may cause excessive disk head movement, which may result in the storage area creation taking longer than if the areas were created serially. In addition, if you specify a large number of storage areas, you may exceed process quotas, resulting in the database creation failing. This setting is not saved as a permanent database attribute. It is used only during the execution of the CREATE DATABASE, ALTER DATABASE, or IMPORT statements. If you do not specify the MULTITHREAD AREA ADDITIONS clause, the default is to create one storage area at a time. If you specify the MULTITHREAD AREA ADDITIONS clause, but do not specify an option, the default is all areas are created in parallel.
4.3.67 – NATIONAL_CHARACTER_SET
Specifies the database national character set when you create a database. For a list of allowable national character set names, see Supported Character Sets.
4.3.68 – ncs-name
The OpenVMS National Character Set (NCS) utility provides a set of predefined collating sequences and also lets you define collating sequences of your own. In the default NCS library, SYS$LIBRARY:NCS$LIBRARY, ncs-name is the name of a collating sequence or ncs-name is the name of the collating sequence in the NCS library specified by the library-name argument. (In most cases, it is simplest to make the collating sequence name the same as the ncs-name, for example, CREATE DATABASE . . . COLLATING SEQUENCE IS SPANISH SPANISH.) The COLLATING SEQUENCE clause accepts both predefined and user-defined NCS collating sequences. If you omit the COLLATING SEQUENCE clause in the CREATE DATABASE statement at database definition time, the default sequence is the DEC Multinational Character Set (MCS).
4.3.69 – NO_LOCATION
This is a subclause of other clauses and has different effects, depending upon the clause in which it is used, as follows: o In the row-cache-options clause Removes the location previously specified in a LOCATION IS clause for the row cache. If you specify NO LOCATION, the row cache location becomes the directory of the database root file. The LOCATION clause of the CREATE CACHE, ADD CACHE, or ALTER CACHE clause overrides this location, which is the default for the database. o In a CREATE CACHE, ADD CACHE, or ALTER CACHE clause (row- cache-params1 clause) Removes the location previously specified in a LOCATION IS clause for the row cache backing file. If you specify NO LOCATION, the row cache location becomes the directory of the database root file. This clause is ignored if the row cache is defined to checkpoint to the database.
4.3.70 – NO_ROW_CACHE
Specifies that the database default is not to assign a row cache to all storage areas in the database. You cannot specify the NO ROW CACHE clause if you specify the CACHE USING clause. Alter the storage area and name a row cache to override the database default. Only one row cache is allowed for each storage area. If you do not specify the CACHE USING clause or the NO ROW CACHE clause, NO ROW CACHE is the default for the database.
4.3.71 – NOTIFY
Syntax options: NOTIFY IS ENABLED | NOTIFY IS DISABLED Specifies whether system notification is enabled or disabled. When the system notification is enabled, the system is notified (using the OpenVMS OPCOM facility) in the event of events such as running out of disk space for a journal. If you specify the NOTIFY IS ENABLED clause and do not specify the ALERT OPERATOR clause, the operator classes used are CENTRAL and CLUSTER. To specify other operator classes, use the ALERT OPERATOR clause. The NOTIFY IS ENABLED clause replaces any operator classes set by the RMU Set After_Journal Notify command. The default is disabled.
4.3.72 – NUMBER global buffers
Syntax option: NUMBER IS number-glo-buffers Specifies the default number of global buffers to be used on one node when global buffers are enabled. This number appears as "global buffer count" in RMU Dump command output. Base this value on the database users' needs and the number of attachments. The default is the maximum number of attachments multiplied by 5. NOTE Do not confuse the NUMBER IS parameter with the NUMBER OF BUFFERS IS parameter. The NUMBER OF BUFFERS IS parameter determines the default number of buffers Oracle Rdb allocates to each user process that attaches to the database. The NUMBER OF BUFFERS IS parameter applies to, and has the same meaning for, both local and global buffering. The NUMBER IS parameter has meaning only within the context of global buffering. You can override the default number of user-allocated buffers by defining a value for the logical name RDM$BIND_BUFFERS. For more information, see the Oracle Rdb7 Guide to Database Performance and Tuning. Although you can change the NUMBER IS parameter on line, the change does not take effect until the next time the database is opened.
4.3.73 – NUMBER_OF_BUFFERS
Specifies the number of buffers SQL allocates for each attach to this database. This number is displayed as the "default database buffer count" in the output from the RMU Dump command. The default buffer count applies to local and global buffers. Specify an unsigned integer greater than or equal to 2 and less than or equal to 32,767. The default is 20 buffers.
4.3.74 – NUMBER_OF_CLUSTER_NODES
Syntax option: NUMBER OF CLUSTER NODES number-nodes Sets the upper limit on the maximum number of VMS cluster nodes from which users can access the shared database. The default is 16 nodes. The range is 1 to 96 nodes. The actual maximum limit is the current VMS cluster node limit set by your system administrator. The Oracle Rdb root file data structures (.rdb) are mapped to shared memory. Each such shared memory copy is known as an Rdb instance. When there is only one copy of shared memory containing root file information, several optimizations are enabled to reduce locking and root file I/O during database activity. To enable these optimizations, specify NUMBER OF CLUSTER NODES 1, or use the SINGLE INSTANCE clause. MULTIPLE INSTANCE means that the Oracle Rdb root file data structures are mapped on different system and are kept consistent through disk I/O. Such systems can not benefit from single instance optimizations. MULTIPLE INSTANCE is the default.
4.3.75 – NUMBER_OF_RECOVERY_BUFFERS
Specifies the number of buffers allocated to the automatic recovery process that Oracle Rdb initiates after a system or process failure. This recovery process uses the recovery-unit journal (.ruj) file. Specify an unsigned integer greater than or equal to 2 and less than or equal to 32,767. The default value for the NUMBER OF RECOVERY BUFFERS parameter is 20 buffers. If you have a large, multifile database and you are working on a system with a large amount of memory, specify a large number of buffers. This result is faster recovery time. However, make sure your buffer pool does not exceed the amount of memory you can allocate for the pool. if the number of buffers is too large for the amount of memory on your system, the system may be forced to perform virtual paging of the buffer pool. This can slow performance time because the operating system must perform the virtual paging of the buffer pool in addition to reading database pages. You may want to experiment to determine the optimal number of buffers for your database. Use the NUMBER OF RECOVERY BUFFERS option to increase the number of buffers allocated to the recovery process. SQL> CREATE DATABASE FILENAME personnel cont> NUMBER OF RECOVERY BUFFERS 150; This option is used only if the NUMBER OF RECOVERY BUFFERS value is larger than the NUMBER OF BUFFERS value. For more information, see the Oracle Rdb Guide to Database Maintenance.
4.3.76 – NUMBER_OF_SWEEP_ROWS
Syntax option: NUMBER OF SWEEP ROWS IS n Specifies the number of modified rows that will be written from the row cache back to the database by the row cache server (RCS) process during a sweep operation. When the RCS is notified that a cache is "full" of modified data, the RCS starts a sweep to make space available in the cache for subsequent transactions to be able to insert rows into the cache. Oracle Corporation recommends that you initially specify the number of sweep rows to be approximately 5 percent of the total number of rows in the cache. Then monitor performance and adjust the number of sweep rows, if necessary. Allowable values must be in the range 2 through 524288. If not specified, the default is 3,000 rows.
4.3.77 – NUMBER_OF_USERS
Specifies the maximum number of users allowed to access the database at one time. The default is 50 users. After the maximum is reached, the next user who tries to invoke the database receives an error message and must wait. The maximum number of users you can specify is 16368, and the minimum is 1 user. Note that "number of users" is defined as the number of active attachments to the database. Thus, if a single process runs one program but that program performs 12 attach operations, the process is responsible for 12 active users as defined by this argument.
4.3.78 – OPEN
Syntax options: OPEN IS MANUAL | OPEN IS AUTOMATIC Specifies whether or not the database must be explicitly opened before users can attach to it. The default, OPEN IS AUTOMATIC, means that any user can open a previously unopened or a closed database by attaching to it and executing a statement. The OPEN IS MANUAL option means that a privileged user must issue an explicit OPEN statement through Oracle RMU, the Oracle Rdb management utility, before other users can attach to the database. The OPEN IS MANUAL option limits access to databases. You must have the DBADM privilege to attach to the database. You receive an error message if you specify both OPEN IS AUTOMATIC and OPEN IS MANUAL options. You can modify the OPEN IS option through the ALTER DATABASE statement.
4.3.79 – PAGE_FORMAT
Syntax options: PAGE FORMAT IS UNIFORM | PAGE FORMAT IS MIXED Specifies the on-disk structure for the storage area. o The default is PAGE FORMAT IS UNIFORM and creates a storage area data file that is divided into clumps. Clump size, which is derived from buffer size, is 3 pages by default. A set of clumps forms a logical area that can contain rows from a single table only. For more information on uniform page formats, see the Oracle Rdb7 Guide to Database Performance and Tuning. Uniform page format storage areas generally give the best performance if the tables in the storage area are subject to a wide range of queries. o The PAGE FORMAT IS MIXED clause creates a storage area with a format that lets rows from more than one table reside on or near a particular page of the storage area data file. This is useful for storing related rows from different tables on the same page of the data file. For storage areas subject to repeated queries that retrieve those related rows, a mixed page format can greatly reduce I/O overhead if the mix of rows on the page is carefully controlled. However, mixed page format storage areas degrade performance if the mix of rows on the page is not suited for the queries made against the storage area. NOTE The main storage area created by the CREATE DATABASE statement, called RDB$SYSTEM, must have uniform pages. If you specify PAGE FORMAT IS MIXED as a default storage area parameter, SQL generates a warning message and overrides that default when it creates the RDB$SYSTEM storage area.
4.3.80 – PAGE_SIZE
Syntax option: PAGE SIZE IS page-blocks BLOCKS The size in blocks of each database page. Page size is allocated in 512-byte blocks. The default is 2 blocks (1024 bytes). If your largest row is larger than approximately 950 bytes, allocate more blocks per page to prevent fragmented rows. If you specify a page size larger than the buffer size, an error message is returned.
4.3.81 – PAGE_TRANSFER
Syntax options: PAGE TRANSFER VIA DISK | PAGE TRANSFER VIA MEMORY Specifies whether Oracle Rdb transfers (flushes) pages to disk or to memory. When you specify PAGE TRANSFER VIA MEMORY, processes on a single node can share and update database pages in memory without transferring the pages to disk. It is not necessary for a process to write a modified page to disk before another process accesses the page. The default is to DISK. If you specify PAGE TRANSFER VIA MEMORY, the database must have the following characteristics: o The NUMBER OF CLUSTER NODES must equal one, or SINGLE INSTANCE must be specified in the NUMBER of CLUSTER NODES clause. o GLOBAL BUFFERS must be enabled. o After-image journaling must be enabled. o FAST COMMIT must be enabled. If the database does not have these characteristics, Oracle Rdb will perform page transfers via disk. For more information about page transfers, see the Oracle Rdb7 Guide to Database Performance and Tuning.
4.3.82 – PATHNAME path name
The repository path name for the repository directory where the database definition is stored. Specify one of the following: o A full repository path name, such as CDD$TOP.SQL.DEPT3 o A relative repository path name, such as DEPT3 o A logical name that refers to a full or relative repository path name If you use a relative path name, CDD$DEFAULT must be defined as all the path name segments preceding the relative path name. For example, define CDD$DEFAULT as CDD$TOP.SQL, and then use the relative path name DEPT3. SQL> SHOW DICTIONARY The current data dictionary is CDD$TOP.SQL SQL> CREATE DATABASE ALIAS PERSONNEL PATHNAME DEPT3; There is no default path name. If you do not specify a repository path name for the database, SQL does not store database definitions in the repository. Subsequent data definitions cannot use the repository. However, Oracle Rdb recommends that you do specify a repository path name when you create a database. For more information, see the Oracle Rdb SQL Reference Manual. If you use the PATHNAME argument and your system does not have the repository, SQL ignores the argument. When you use the PATHNAME argument, the repository associates the path name with the file specification exactly as given in the CREATE DATABASE statement. If that file specification is a file name, not a logical name, you cannot alter or delete the database by specifying the path name unless the database root file is in the current, default working directory.
4.3.83 – PERCENT extent growth
Syntax option: PERCENT GROWTH IS growth Specifies the percent growth of each extent. The default is 20 percent growth.
4.3.84 – PRESTARTED_TRANSACTIONS
Syntax options: PRESTARTED TRANSACTIONS ARE ENABLED PRESTARTED TRANSACTIONS ARE DISABLED Enables or disables the prestarting of transactions. Note that the keyword ON, available in previous versions, is synonymous with ENABLED, and the OFF keyword is synonymous with the DISABLED keyword. This clause is used to establish a permanent database setting for prestarted transactions. In prior versions, this clause was only used to temporarily set the mode for prestarted transaction for the implicit attach performed by the CREATE DATABASE and IMPORT DATABASE statements. The prestart-trans-options can be one of the following clauses: o WAIT n SECONDS FOR TIMEOUT The n represents the number of seconds to wait before aborting the prestarted transaction. Timing out the prestarted transaction may prevent snapshot file growth in environments where servers stay attached to the database with long periods of inactivity. o WAIT n MINUTES FOR TIMEOUT The n represents the number of minutes to wait before aborting the prestarted transaction. o NO TIMEOUT This is the default for a prestarted transaction. Syntax options: PRESTARTED TRANSACTIONS ARE ON | PRESTARTED TRANSACTIONS ARE OFF
4.3.85 – PROTECTION
Syntax options: PROTECTION IS ANSI | PROTECTION IS ACLS Specifies whether the database root file will be invoked with ACL-style or ANSI/ISO-style privileges. If no protection clause is specified, the default is ACL-style privileges. For ACL-style databases, the access privilege set is order- dependent. When a user tries to perform an operation on a database, SQL reads the associated access privilege set, called the access control list (ACL), from top to bottom, comparing the identifier of the user with each entry. As soon as SQL finds a match, it grants the rights listed in that entry and stops the search. All identifiers that do not match a previous entry "fall through" to the entry [ *,*] (equivalent to the SQL keyword PUBLIC). The default access for PUBLIC is NONE. See the GRANT statement and the REVOKE statement for more information on ACL-style privileges. For ANSI/ISO-style databases, the access privilege set is not order-dependent. The user matches the entry in the access privilege set; gets whatever privileges have been granted on the database, table, or column; and gets the privileges defined for PUBLIC. A user without an entry in the access privilege set gets only the privileges defined for PUBLIC. There is always an access privilege entry for PUBLIC, even if that entry has no access to the database, table, or column. ANSI/ISO-style databases grant access to the creator when an object is created. Because only the creator is granted access to the newly created object, additional access must be granted explicitly. See the GRANT_ANSI statement and the REVOKE_ANSI statement for more information on ANSI/ISO-style privileges. You can change the PROTECTION IS parameter by using the IMPORT statement. See the IMPORT statement for more information.
4.3.86 – RECOVERY_JOURNAL_(BUFFER_MEMORY)
Syntax options: BUFFER MEMORY IS LOCAL BUFFER MEMORY IS GLOBAL Specifies whether RUJ buffers will be allocated in global or local memory. The RUJ buffers used by each process are normally allocated in local virtual memory. With the introduction of row caching, these buffers now can be assigned to a shared global section (global memory) on OpenVMS, so that the recovery process can process this in-memory buffer and possibly avoid a disk access. You can define this buffer memory to be global to improve row caching performance for recovery. If row caching is disabled, then buffer memory is always local.
4.3.87 – RECOVERY_JOURNAL_(LOCATION)
Syntax options: RECOVERY JOURNAL (LOCATION IS directory-spec) Specifies the location in which the recovery-unit journal (.ruj) file is written. Do not include node names, file names, or process-concealed logical names in the directory-spec. Single quotation marks are required around the directory-spec. This clause overrides the RDMS$RUJ logical name. If this clause is omitted, then NO LOCATION is assumed. Following is an example using this clause: SQL> ALTER DATABASE FILENAME SAMPLE cont> RECOVERY JOURNAL (LOCATION IS 'SQL_USER1:[DBDIR.RECOVER]') See the Oracle Rdb Guide to Database Maintenance for more information on recovery-unit journal files.
4.3.88 – RECOVERY_JOURNAL_(NO_LOCATION)
If you specify NO LOCATION, the recovery journal uses the current user's login device and the directory [RDM$RUJ]. See the Oracle Rdb Guide to Database Maintenance for more information on recovery-unit journal files.
4.3.89 – RESERVE n CACHE SLOTS
Specifies the number of row caches for which slots are reserved in the database. You can use the RESERVE CACHE SLOTS clause to reserve slots in the database root file for future use by the ADD CACHE clause of the ALTER DATABASE statement. You can only add row caches if row cache slots are available. Slots become available after a DROP CACHE clause or a RESERVE CACHE SLOTS clause of the ALTER DATABASE statement. The number of reserved slots for row caches cannot be decreased once the RESERVE clause is issued. If you reserve 10 slots and later reserve 5 slots, you have a total of 15 reserved slots for row caches If you do not specify the RESERVE CACHE SLOTS clause, the default number of row caches is one. Reserving row cache slots is an offline operation (requiring exclusive database access). See the CREATE CACHE clause for more information.
4.3.90 – RESERVE n JOURNALS
Specifies the number of journal files for which slots are reserved in the database. If your database is not a multifile database, you cannot reserve additional slots later using the ALTER DATABASE statement. You must reserve slots before you can add journal files to the database. See the ALTER DATABASE statement for more information about adding journal files and enabling the journaling feature. The following SQL statements create a multifile database and reserve 5 slots for future journal files. SQL> CREATE DATABASE FILENAME test cont> RESERVE 5 JOURNALS cont> CREATE STORAGE AREA sa_one cont> ALLOCATION IS 10 PAGES;
4.3.91 – RESERVE n SEQUENCES
Specifies the number of sequences for which slots are reserved in the database. Sequences are reserved in multiples of 32. Thus, if you specify a value less than 32 for n, 32 slots are reserved. If you specify a value of 33, 64 slots are reserved, and so on. You can use the RESERVE SEQUENCES clause to reserve slots in the database root file for future use by the CREATE SEQUENCE statement. Sequences can be created only if sequence slots are available. Slots become available after a DROP SEQUENCE statement or a RESERVE SEQUENCES clause of the ALTER DATABASE statement is executed. The number of reserved slots for sequences cannot be decreased. If you do not specify the RESERVED SEQUENCES clause, the default number of sequence slots is 32.
4.3.92 – RESERVE n STORAGE AREAS
Specifies the number of storage areas for which slots are reserved in the database. The number of slots for storage areas must be a positive number greater than zero. You can use the RESERVE STORAGE AREA clause to reserve slots in the database root file for future use by the ADD STORAGE AREA clause of the ALTER DATABASE statement. Storage areas can be added only if there are storage area slots available. Slots become available after a DROP STORAGE AREA clause or a RESERVE STORAGE AREA clause. The number of reserved slots for storage areas cannot be decreased once the RESERVE clause is issued. If you reserve 5 slots and later reserve 10 slots, you have a total of 15 reserved slots for storage areas. If you do not specify the RESERVE STORAGE AREA clause, the default number of storage areas is zero.
4.3.93 – RESTRICTED_ACCESS
Syntax option: RESTRICTED ACCESS | NO RESTRICTED ACCESS Restricts access to the database. This allows you to access the database but locks out all other users until you disconnect from the database. Setting restricted access to the database requires DBADM privileges. The default is NO RESTRICTED ACCESS.
4.3.94 – root-file-params
Parameters that control the characteristics of the database root file or characteristics stored in the database root file that apply to the entire database. You can specify these parameters for either single-file or multifile databases. Some database root file parameters specified in the CREATE DATABASE statement cannot be changed with the ALTER DATABASE statement. To change these database root file parameters, you must use the EXPORT and IMPORT statements. See the EXPORT statement and the IMPORT statement for information on exporting and importing your database.
4.3.95 – ROW_CACHE
Syntax options: ROW CACHE IS ENABLED | ROW CACHE IS DISABLED Specifies whether or not you want Oracle Rdb to enable the row caching feature. When a database is created or is converted from a previous version of Oracle Rdb without specifying row cache support, the default is ROW CACHE IS DISABLED. Enabling row cache support does not affect database operations until a row cache is created and assigned to one or more storage areas. When the row caching feature is disabled, all previously created and assigned row cache definitions remain in existence for future use when the row caching feature is enabled. The following conditions must be true in order to use row caches: o The number of cluster nodes is one o After-image journaling is enabled o Fast commit is enabled o One or more cache slots are reserved o Row caching is enabled Use the RMU Dump Header command to check if you have met the requirements for using row caches. The following command output displays a warning for every requirement that is not met: . . . Row Caches... - Active row cache count is 0 - Reserved row cache count is 1 - Sweep interval is 1 second - Default cache file directory is "" - WARNING: Maximum node count is 16 instead of 1 - WARNING: After-image journaling is disabled - WARNING: Fast commit is disabled . . .
4.3.96 – ROWID_SCOPE
Syntax options: ROWID SCOPE IS ATTACH | ROWID SCOPE IS TRANSACTION The ROWID keyword is a synonym for the DBKEY keyword. See the DBKEY_SCOPE argument for more information.
4.3.97 – SECURITY_CHECKING
Traditionally, Oracle Rdb has performed security checking using the operating system security layer (for example, the UIC and rights identifiers of the OpenVMS operating system). The access control list (ACL) information stored in the database contains a granted privilege mask and a set of users represented by a unique integer (for example, a UIC). There are two modes of security checking: 1. SECURITY CHECKING IS EXTERNAL This is the default. External security checking recognizes database users (created with the SQL CREATE USER statement) as operating system user identification codes (UICs) and roles as special rights identifiers or groups. PERSONA support is enabled or disabled as follows: o SECURITY CHECKING IS EXTERNAL (PERSONA SUPPORT IS ENABLED) Enables the full impersonation of an OpenVMS user. This means the UIC and the granted right identifiers are used to check access control list permissions. o SECURITY CHECKING IS EXTERNAL (PERSONA SUPPORT IS DISABLED) Disables the full impersonation of an OpenVMS user. Only the UIC is used to check access control list permissions. This is the default for a new database, or for a database converted from a prior version of Oracle Rdb. 2. SECURITY CHECKING IS INTERNAL In this mode, Oracle Rdb records users (username and UIC) and roles (rights identifiers) in the database. The CREATE USER and CREATE ROLE statements perform this action explicitly, and GRANT will perform this implicitly. This type of database can now be moved to another system and is only dependent on the names of the users and roles. o SECURITY CHECKING IS INTERNAL (ACCOUNT CHECK IS ENABLED) The ACCOUNT CHECK clause ensures that Oracle Rdb validates the current database user with the user name (such as defined with an SQL CREATE USER statement) stored in the database. This prevents different users with the same name from accessing the database. Therefore, this clause might prevent a breach in security. The ACCOUNT CHECK IS ENABLED clause on OpenVMS forces the user session to have the same user name and UIC as recorded in the database. o SECURITY CHECKING IS INTERNAL (ACCOUNT CHECK IS DISABLED) If you specify the ACCOUNT CHECK IS DISABLED clause, then a user with a matching UIC (also called a profile-id) is considered the same as the user even if his or her user name is different. This allows support for multiple OpenVMS users with the same UIC.
4.3.98 – SEGMENTED_STRING_STORAGE_AREA
Another name for LIST STORAGE AREA.
4.3.99 – SET_TRANSACTION_MODES
Enables only the modes specified, disabling all other previously defined modes. For example, if a database is to be used for read- only access and you want to disable all other transaction modes, use the following statement: SQL> CREATE DATABASE FILENAME mf_personnel cont> SET TRANSACTION MODES (READ ONLY); If not specified, the default transaction mode is ALL. Specifying a negated transaction mode or specifying NONE disables all transaction usage. Disabling all transaction usage would be useful when, for example, you want to perform major restructuring of the physical database. Execute the ALTER DATABASE statement to re-enable transaction modes or use Oracle RMU, the Oracle Rdb management utility.
4.3.100 – SHARED_MEMORY_IS_PROCESS_RESIDENT
The SHARED MEMORY clause determines whether database root global sections (including global buffers when enabled) or whether the cache global sections are created in system space or process space. The RESIDENT option extends the PROCESS option by making the global section memory resident.
4.3.101 – SHARED_MEMORY
Syntax options: SHARED MEMORY IS SYSTEM | SHARED MEMORY IS PROCESS Determines whether database root global sections (including global buffers when enabled) are created in system space or process space. The default is PROCESS. When you use global sections created in the process space, you and other users share physical memory and the OpenVMS operating system maps a row cache to a private address space for each user. As a result, all users are limited by the free virtual address range and each use a percentage of memory in overhead. If many users are accessing the database, the overhead can be high.
4.3.102 – SNAPSHOT_ALLOCATION
Syntax option: SNAPSHOT ALLOCATION IS snp-pages PAGES Changes the number of pages allocated for the snapshot file. The default is 100 pages. If you have disabled the snapshot file, you can set the snapshot allocation to 0 pages.
4.3.103 – SNAPSHOT_CHECKSUM_ALLOCATION
Syntax option: SNAPSHOT CHECKSUM ALLOCATION IS ENABLED SNAPSHOT CHECKSUM ALLOCATION IS DISABLED See the CHECKSUM ALLOCATION clause for details.
4.3.104 – SNAPSHOT_IS_ENABLED
Syntax options: SNAPSHOT IS ENABLED IMMEDIATE | SNAPSHOT IS ENABLED DEFERRED Specifies when read/write transactions write database changes they make to the snapshot file used by read-only transactions. The default is ENABLED IMMEDIATE and causes read/write transactions to write copies of rows they modify to the snapshot file, regardless of whether or not a read-only transaction is active. The ENABLED DEFERRED option lets read/write transactions avoid writing copies of rows they modify to the snapshot file (unless a read-only transaction is already active). Deferring snapshot writing in this manner improves the performance for the read/write transaction. However, read-only transactions that attempt to start after an active read/write transaction starts must wait for all active read/write users to complete their transactions.
4.3.105 – SNAPSHOT_EXTENT
Syntax options: SNAPSHOT EXTENT IS extent-pages SNAPSHOT EXTENT IS (extension-options) Specifies the number of pages of each snapshot or storage area file extent. The default extent for storage area files is 99 pages. Specify a number of pages for simple control over the extension. For greater control, and particularly for multivolume databases, use the MINIMUM, MAXIMUM, and PERCENT GROWTH extension options instead. If you use the MINIMUM, MAXIMUM, and PERCENT GROWTH parameters, you must enclose them in parentheses.
4.3.106 – SNAPSHOT_FILENAME
Provides a separate file specification for the storage area snapshot file. The SNAPSHOT FILENAME argument can only be used with a multifile database. In a multifile database, the file specification is used for the RDB$SYSTEM storage area snapshot file, unless the CREATE DATABASE statement contains a CREATE STORAGE AREA RDB$SYSTEM clause that contains its own SNAPSHOT FILENAME clause. Do not specify a file extension other than .snp to the snapshot file specification. Oracle Rdb will assign the extension .snp to the file specification, even if you specify an alternate extension. If you omit the SNAPSHOT FILENAME argument, the .snp file gets the same device, directory, and file name as the database root file.
4.3.107 – SNAPSHOT_IS_DISABLED
Specifies that snapshot writing is disabled. Snapshot writing is enabled by default. If you specify the SNAPSHOT IS DISABLED option, you cannot specify either of the SNAPSHOT IS ENABLED options, and you cannot back up the database on line. You can, however, continue to set snapshot options in the event that you will enable snapshots in the future. SQL warns you of a possible conflict in the setting of snapshot options while snapshots are disabled, but SQL will execute the statement.
4.3.108 – SNAPSHOT_IS_ENABLED
Syntax options: SNAPSHOT IS ENABLED IMMEDIATE | SNAPSHOT IS ENABLED DEFERRED Specifies when read/write transactions write database changes they make to the snapshot file used by read-only transactions. The default is ENABLED IMMEDIATE and causes read/write transactions to write copies of rows they modify to the snapshot file, regardless of whether or not a read-only transaction is active. The ENABLED DEFERRED option lets read/write transactions avoid writing copies of rows they modify to the snapshot file (unless a read-only transaction is already active). Deferring snapshot writing in this manner improves the performance for the read/write transaction. However, read-only transactions that attempt to start after an active read/write transaction starts must wait for all active read/write users to complete their transactions.
4.3.109 – STATISTICS_COLLECTION
Syntax options: STATISTICS COLLECTION IS ENABLED STATISTICS COLLECTION IS DISABLED Specifies whether the collection of statistics for the database is enabled or disabled. When you disable statistics for the database, statistics are not displayed for any of the processes attached to the database. Statistics are displayed using the RMU Show Statistics command. The default is STATISTICS COLLECTION IS ENABLED. You can disable statistics using the ALTER DATABASE and IMPORT statements. For more information on the RMU Show Statistics command, see the Oracle RMU Reference Manual. You can enable statistics collection by defining the logical name RDM$BIND_STATS_ENABLED. For more information about when to use statistics collection, see the Oracle Rdb7 Guide to Database Performance and Tuning.
4.3.110 – storage-area-params
Parameters that control the characteristics of database storage area files. You can specify most storage area parameters for either single-file or multifile databases, but the effect of the clauses differs. o For single-file databases, the storage area parameters specify the characteristics for the single storage area in the database. o For multifile databases, the storage area parameters specify a set of default values for any storage areas created by the CREATE DATABASE statement that do not specify their own values for the same parameters. The default values apply to the RDB$SYSTEM storage area, plus any others named in CREATE STORAGE AREA database elements. The CREATE STORAGE AREA clauses in a CREATE DATABASE statement can override these default values. The default values do not apply to any storage areas created later with the ALTER DATABASE statement.
4.3.111 – SWEEP_INTERVAL
Syntax option: SWEEP INTERVAL IS n SECONDS Specifies the interval, in seconds, between each Record Cache Server (RCS) sweep. Allowable values must be in the range from 1 second to 3600 seconds (1 hour). The default is 1. The Record Cache Server (RCS) is a detached server process automatically invoked by the monitor when row caching is active. A sweep is one full pass through all active row cache areas to write modified rows back to the database storage areas.
4.3.112 – SYSTEM_INDEX_(COMPRESSION_IS_._._._)
This clause allows the database creator choose compressed system indexes. The default is SYSTEM INDEX (COMPRESSION IS DISABLED). If enabled Oracle Rdb uses run-length compression, which compresses any sequences of two or more spaces from text data types or two or more binary zeros from non-character data types. Compressing system indexes results in reduced storage and improved I/O. Unless your applications frequently perform concurrent data definition, you should compress system indexes. Once you create a database specifying the SYSTEM INDEX (COMPRESSION IS . . . ) clause, you only can change it using the EXPORT and IMPORT statements. You cannot alter the database to change the compression mode. The clause SYSTEM INDEX COMPRESSION IS is identical to this clause and is retained for compatibility with older versions of Oracle Rdb.
4.3.113 – SYSTEM_INDEX_(PREFIX_CARDINALITY_COLLECTION_IS_._._._)
This clause allows the database creator to adjust the prefix cardinality collection for system indices. Refer to the CREATE INDEX Statement for more details on these clauses. The default is PREFIX CARDINALITY COLLECTION IS ENABLED.
4.3.114 – SYSTEM_INDEX_(TYPE_IS_._._._)
This clause allows the database creator choose between SORTED or SORTED RANKED indices for system table. The default is SORTED. SORTED RANKED indices have advantages in space usage and reduced CPU during DDL operations for those system indices with many duplicates.
4.3.115 – SYNONYMS_ARE_ENABLED
Adds the optional system table RDB$OBJECT_SYNONYMS that is used for the CREATE SYNONYM, ALTER . . . RENAME TO and RENAME statements. The default if omitted is disabled.
4.3.116 – THRESHOLD pages option
Syntax option: THRESHOLD IS number-pages PAGES This number represents the number of sequential buffer accesses that must be detected before prefetching is started. The default is four buffers. If you specify the THRESHOLD option, you must have also specified the DETECTED ASYNC PREFETCH clause. You receive an error if you attempt to specify the THRESHOLD option with the ASYNC PREFETCH clause.
4.3.117 – THRESHOLDS values
Syntax options THRESHOLDS ARE ( val1 [,val2 [,val3] ] ) Specifies one, two, or three threshold values. The threshold values represent a fullness percentage on a data page and establish four possible ranges of guaranteed free space on the data pages. When a data page reaches the percentage defined by a given threshold value, the space area management (SPAM) entry for the data page is updated to reflect the new fullness percentage and its remaining free space. The default thresholds are 70, 85, and 95 percent. If you specify only one or two values, unspecified values default to 100 percent. You cannot specify the THRESHOLDS storage area parameter for single-file databases, and you cannot specify THRESHOLDS unless you also explicitly specify PAGE FORMAT IS MIXED. To specify thresholds for uniform storage areas, use the CREATE STORAGE MAP statement. For more information about setting space area management parameters, see the Oracle Rdb Guide to Database Maintenance.
4.3.118 – USER username
Syntax option: USER 'username' A character string literal that specifies the operating system user name that the database system uses for privilege checking. This clause also sets the value of the SYSTEM_USER value expression.
4.3.119 – USER_LIMIT
Syntax option: USER LIMIT IS max-glo-buffers Specifies the maximum number of global buffers each attach allocates. Because global buffer pools are shared by all attachments, you must define an upper limit on how many global buffers a single attach can allocate. This limit prevents a user from defining the RDM$BIND_BUFFERS logical name to use all the buffers in the global buffer pool. (The behavior of RDM$BIND_ BUFFERS which depends on whether you are using local or global buffers, is explained in the Oracle Rdb7 Guide to Database Performance and Tuning.) The user limit cannot be greater than the total number of global buffers. The default is 5 buffers. The user limit appears as "maximum global buffer count per user" in RMU Dump command output. Decide the maximum number of global buffers a process can allocate per attach by dividing the total number of global buffers set by the NUMBER IS clause by the total number of attachments for which you want to guarantee access to the database. For example, if the total number of global buffers is 200 and you want to guarantee at least 10 attachments access to the database, set the maximum number of global buffers per attach to 20. In general, when you use global buffers, you should set the maximum global buffer count per user higher than the default database buffer count. For maximum performance on a VMScluster system, tune the two global buffer parameters on each node in the cluster using the RMU Open command with the Global_Buffers qualifier. Although you can change the USER LIMIT IS parameter on line, the change does not take effect until the next time the database is opened. The NUMBER IS and USER LIMIT IS parameters are the only two buffer parameters specific to global buffers. They are, therefore, in effect on a per node rather than a per process basis.
4.3.120 – USING password
Syntax option: USING 'password' A character string literal that specifies the user's password for the user name specified in the USER clause.
4.3.121 – txn-modes
Specifies the transaction modes for the database. Mode Description ALL All modes are enabled. NONE No modes are enabled. Transaction Types [NO]READ Allows read-only transactions on the database. ONLY [NO]READ Allows read/write transactions on the database. WRITE [NO] BATCH Allows batch-update transactions on the database. UPDATE This mode executes without the overhead, or security, or a recovery-unit journal file. The batch-update transaction is intended for the initial loading of a database. Oracle Rdb recommends that this mode be disabled. Reserving Modes [NO] SHARED Allows tables to be reserved for shared mode. That [READ | is, other users can work with those tables. WRITE] [NO] Allows tables to be reserved for protected mode. PROTECTED That is, other users can read from those tables. [READ | WRITE] [NO] Allows tables to be reserved for exclusive access. EXCLUSIVE That is, other users are prevented access to those [READ | tables, even in READ ONLY transactions. WRITE] ALL Allows other users to work with all tables. NONE Allows no access to tables. For detailed information about the txn-modes, see the SET_ TRANSACTION statement.
4.3.122 – WAIT option
Syntax option: WAIT n MINUTES FOR CLOSE Specifies the amount of time that Oracle Rdb waits before automatically closing a database. If anyone attaches during that wait time, the database is not closed. The default value for n is zero (0) if the WAIT clause is not specified. The value for n can range from zero (0) to 35,791,394. However, Oracle Rdb does not recommend using large values.
4.3.123 – WORKLOAD_COLLECTION
Syntax options: WORKLOAD COLLECTION IS ENABLED | WORKLOAD COLLECTION IS DISABLED Specifies whether or not the optimizer records workload information in the system table RDB$WORKLOAD. The WORKLOAD COLLECTION IS ENABLED clause creates this system table if it does not exist. If you later disable workload collection, the RDB$WORKLOAD system table is not deleted. A workload profile is a description of the interesting table and column references used by queries in a database workload. When workload collection is enabled, the optimizer collects and records these references in the RDB$WORKLOAD system table. This work load is then processed by the RMU Analyze Statistics command which records useful statistics about the work load. These workload statistics are used by the optimizer at run time to deliver more accurate access strategies. Workload collection is disabled by default.
4.4 – Examples
Example 1: Creating a single-file database This command file example creates a single-file database that contains one table, EMPLOYEES, made up of domains defined within the CREATE DATABASE statement. The EMPLOYEES table has the same definition as that in the sample personnel database. For an example that creates a multifile version of the personnel database, see the CREATE STORAGE_AREA. SQL> -- By omitting a FILENAME clause, the database root file SQL> -- takes the file name from the alias: SQL> CREATE DATABASE ALIAS personnel cont> -- cont> -- This CREATE DATABASE statement takes default cont> -- database root file and storage area parameter values. cont> -- cont> -- Create domains. cont> -- Note that database elements do not terminate with semicolons. cont> -- cont> CREATE DOMAIN ID_DOM CHAR(5) cont> -- cont> CREATE DOMAIN LAST_NAME_DOM CHAR(14) cont> -- cont> CREATE DOMAIN FIRST_NAME_DOM CHAR(10) cont> -- cont> CREATE DOMAIN MIDDLE_INITIAL_DOM CHAR(1) cont> -- cont> CREATE DOMAIN ADDRESS_DATA_1_DOM CHAR(25) cont> -- cont> CREATE DOMAIN ADDRESS_DATA_2_DOM CHAR(20) cont> -- cont> CREATE DOMAIN CITY_DOM CHAR(20) cont> -- cont> CREATE DOMAIN STATE_DOM CHAR(2) cont> -- cont> CREATE DOMAIN POSTAL_CODE_DOM CHAR(5) cont> -- cont> CREATE DOMAIN SEX_DOM CHAR(1) cont> -- cont> CREATE DOMAIN DATE_DOM DATE cont> -- cont> CREATE DOMAIN STATUS_CODE_DOM CHAR(1) cont> -- cont> -- Create a table: cont> -- cont> CREATE TABLE EMPLOYEES cont> ( cont> EMPLOYEE_ID ID_DOM cont> CONSTRAINT EMP_EMPLOYEE_ID_NOT_NULL cont> NOT NULL cont> NOT DEFERRABLE, cont> LAST_NAME LAST_NAME_DOM, cont> FIRST_NAME FIRST_NAME_DOM, cont> MIDDLE_INITIAL MIDDLE_INITIAL_DOM, cont> ADDRESS_DATA_1 ADDRESS_DATA_1_DOM, cont> ADDRESS_DATA_2 ADDRESS_DATA_2_DOM, cont> CITY CITY_DOM, cont> STATE STATE_DOM, cont> POSTAL_CODE POSTAL_CODE_DOM, cont> SEX SEX_DOM, cont> CONSTRAINT EMP_SEX_VALUES cont> CHECK ( cont> SEX IN ('M', 'F') OR SEX IS NULL cont> ) cont> NOT DEFERRABLE, cont> BIRTHDAY DATE_DOM, cont> STATUS_CODE STATUS_CODE_DOM, cont> CONSTRAINT EMP_STATUS_CODE_VALUES cont> CHECK ( cont> STATUS_CODE IN ('0', '1', '2') cont> OR STATUS_CODE IS NULL cont> ) cont> NOT DEFERRABLE cont> ) cont> -- cont> -- End CREATE DATABASE by specifying a semicolon: cont> ; Example 2: Creating a database not using the repository The following example: o Creates the database root file acct.rdb in the default working directory o Creates the snapshot file acct.snp in the default working directory o Does not store the database definition in the repository o Enables writing to the snapshot file o Sets the allocation of the snapshot file to 200 pages SQL> CREATE DATABASE ALIAS acct cont> FILENAME acct cont> SNAPSHOT IS ENABLED IMMEDIATE cont> SNAPSHOT ALLOCATION IS 200 PAGES; Example 3: Creating a database with the snapshot file disabled This statement creates a database root file and, to save disk space, disables snapshot writing and sets the initial allocation size to 1. SQL> CREATE DATABASE ALIAS PERS cont> FILENAME personnel cont> SNAPSHOT IS DISABLED cont> SNAPSHOT ALLOCATION IS 1 PAGES; Example 4: Creating a database with ANSI/ISO-style privileges This statement creates a database in which all ANSI/ISO-style privileges are granted to the creator of the database, WARRING, and no privileges are granted to the identifier [*,*], the PUBLIC identifier. SQL> CREATE DATABASE ALIAS EXAMPLE cont> FILENAME ansi_test cont> PROTECTION IS ANSI; SQL> SQL> SHOW PROTECTION ON DATABASE EXAMPLE; Protection on Alias EXAMPLE [SQL,WARRING]: With Grant Option: SELECT,INSERT,UPDATE,DELETE,SHOW,CREATE,ALTER,DROP, DBCTRL,OPERATOR,DBADM,SECURITY,DISTRIBTRAN Without Grant Option: NONE [*,*]: With Grant Option: NONE Without Grant Option: NONE Example 5: Creating a database with a German collating sequence This statement creates a database named LITERATURE and specifies a collating sequence named GERMAN (based on the GERMAN collating sequence defined in the NCS library). SQL> CREATE DATABASE FILENAME literature cont> COLLATING SEQUENCE GERMAN GERMAN; SQL> SHOW COLLATING SEQUENCE User collating sequences in schema with filename LITERATURE GERMAN Example 6: Creating a database with global buffers This statement creates a database named parts.rdb. SQL> CREATE DATABASE ALIAS PARTS FILENAME parts cont> GLOBAL BUFFERS ARE ENABLED (NUMBER IS 110, USER LIMIT IS 17); Example 7: Creating a database specifying the database default and national character sets The following SQL statements create a database specifying the database default character set of DEC_KANJI and the national character set of KANJI. Use the SHOW DATABASE statement to see the database settings. SQL> SET DIALECT 'SQL99'; SQL> CREATE DATABASE FILENAME mia_char_set cont> DEFAULT CHARACTER SET DEC_KANJI cont> NATIONAL CHARACTER SET KANJI cont> IDENTIFIER CHARACTER SET DEC_KANJI; SQL> -- SQL> SHOW CHARACTER SET; Default character set is DEC_MCS National character set is DEC_MCS Identifier character set is DEC_MCS Literal character set is DEC_MCS Display character set is UNSPECIFIED Alias RDB$DBHANDLE: Identifier character set is DEC_KANJI Default character set is DEC_KANJI National character set is KANJI See the SHOW for information on the SHOW CHARACTER SETS statement. Example 8: This example demonstrates how to: o Create a multifile database o Reserve slots for journal files, storage areas, and row caches o Restrict access to the database for the current session o Enable system index compression, row caching, and workload collection o Disable statistics and cardinality collection o Specify a default storage area o Specify ROW as the lock-level default for the database o Delay closing the database o Create and assign a row cache to a storage area o Specify the location of the recovery-unit journal file SQL> CREATE DATABASE FILENAME sample cont> SNAPSHOT IS DISABLED cont> RESERVE 10 JOURNALS cont> RESERVE 10 STORAGE AREAS cont> RESERVE 5 CACHE SLOTS cont> SYSTEM INDEX COMPRESSION IS ENABLED cont> ROW CACHE IS ENABLED cont> WORKLOAD COLLECTION IS ENABLED cont> RESTRICTED ACCESS cont> STATISTICS COLLECTION IS DISABLED cont> CARDINALITY COLLECTION IS DISABLED cont> LOCKING IS ROW LEVEL cont> DEFAULT STORAGE AREA IS area1 cont> OPEN IS AUTOMATIC (WAIT 5 MINUTES FOR CLOSE) cont> RECOVERY JOURNAL (LOCATION IS 'SQL_USER1:[DAY]') cont> CREATE CACHE cache1 cont> CACHE SIZE IS 1000 ROWS cont> ROW LENGTH IS 1000 BYTES cont> CREATE STORAGE AREA area1 cont> CACHE USING cache1; SQL> SQL> SHOW DATABASE *; Default alias: Oracle Rdb database in file sample Multischema mode is disabled Number of users: 50 Number of nodes: 16 Buffer Size (blocks/buffer): 6 Number of Buffers: 20 Number of Recovery Buffers: 20 Snapshots are Disabled Carry over locks are enabled Lock timeout interval is 0 seconds Adjustable lock granularity is enabled (count is 3) Global buffers are disabled (number is 250, user limit is 5, page transfer via disk) Journal fast commit is disabled ( checkpoint interval is 0 blocks, checkpoint timed every 0 seconds, no commit to journal optimization, transaction interval is 256 ) AIJ File Allocation: 512 AIJ File Extent: 512 Statistics Collection is DISABLED Unused Storage Areas: 10 Unused Journals: 10 System Index Compression is ENABLED Restricted Access Journal is Disabled Backup Server: Manual Log Server: Manual Overwrite: Disabled Notification: Disabled Asynchronous Prefetch is Enabled (depth is 5) Asynchronous Batch Write is Enabled (clean buffers 5, max buffers 4) Lock Partitioning is DISABLED Incremental Backup Scan Optim uses SPAM pages Shutdown Time is 60 minutes Unused Cache Slots: 5 Workload Collection is Enabled Cardinality Collection is Disabled Metadata Changes are Enabled Row Cache is Enabled (Sweep interval is 1 second, No Location) Detected Asynch Prefetch is Enabled (depth is 4, threshold is 4) Default Storage Area AREA1 Mode is Open Automatic (Wait 5 minutes for close) RUJ File Location SQL_USER1:[DAY] Database Transaction Mode(s) Enabled: ALL Dictionary Not Required ACL based protections Storage Areas in database with filename sample RDB$SYSTEM List storage area. AREA1 Default storage area. Journals in database with filename sample No Journals Found Cache Objects in database with filename sample CACHE1 SQL> SHOW CACHE cache1; CACHE1 Cache Size: 1000 rows Row Length: 1000 bytes Row Replacement: Enabled Shared Memory: Process Large Memory: Disabled Window Count: 100 Reserved Rows: 20 Sweep Rows: 3000 Reserving Slots for Sequences No Sweep Thresholds Allocation: 100 blocks Extent: 100 blocks Example 9: Reserving Slots for Sequences SQL> CREATE DATABASE FILENAME many_sequences cont> RESERVE 320 SEQUENCES; Example 10: Creating a Database with a Row Cache SQL> create database cont> filename SAMPLE cont> snapshot is disabled cont> reserve 10 journals cont> reserve 10 storage areas cont> reserve 5 cache slots cont> system index (compression is enabled, type sorted ranked) cont> row cache is enabled cont> workload collection is enabled cont> restricted access cont> default storage area is AREA1 cont> open is automatic (wait 5 minutes for close) cont> cont> create cache CACHE_AREA1 cont> shared memory is process cont> row length is 1000 bytes cont> cache size is 204 rows cont> checkpoint all rows to backing file cont> cont> create storage area AREA1 cont> page format is UNIFORM cont> cache using CACHE_AREA1 cont> ; SQL> SQL> show database * Default alias: Oracle Rdb database in file SAMPLE Multischema mode is disabled Number of users: 50 Number of nodes: 16 Buffer Size (blocks/buffer): 6 Number of Buffers: 20 Number of Recovery Buffers: 20 Snapshots are Disabled Carry over locks are enabled Lock timeout interval is 0 seconds Adjustable lock granularity is enabled (count is 3) Global buffers are disabled (number is 250, user limit is 5, page transfer via disk) Journal fast commit is disabled ( checkpoint interval is 0 blocks, checkpoint timed every 0 seconds, no commit to journal optimization, transaction interval is 256 ) AIJ File Allocation: 512 AIJ File Extent: 512 Statistics Collection is ENABLED Unused Storage Areas: 10 Unused Journals: 10 Unused Cache Slots: 5 Unused Sequences: 32 Restricted Access Journal is Disabled Backup Server: Manual Log Server: Manual Overwrite: Disabled Notification: Disabled Asynchronous Prefetch is Enabled (depth is 5) Asynchronous Batch Write is Enabled (clean buffers 5, max buffers 4) Lock Partitioning is DISABLED Incremental Backup Scan Optim uses SPAM pages Shutdown Time is 60 minutes Workload Collection is Enabled Cardinality Collection is Enabled Metadata Changes are Enabled Row Cache is Enabled Row cache: No Location Row cache: checkpoint updated rows to backing file Detected Asynch Prefetch is Enabled (depth is 4, threshold is 4) Default Storage Area AREA1 Mode is Open Automatic (Wait 5 minutes for close) No RUJ File Location recovery journal buffers are in local memory Database Transaction Mode(s) Enabled: ALL Shared Memory: Process Large Memory: Disabled Security Checking is External System Index Compression is ENABLED System Index: Type is sorted ranked Prefix cardinality collection is enabled Logminer support is disabled Galaxy support is disabled Prestarted transactions are enabled Dictionary Not Required ACL based protections Storage Areas in database with filename SAMPLE AREA1 Default storage area RDB$SYSTEM List storage area. Journals in database with filename SAMPLE No Journals Found Cache Objects in database with filename SAMPLE CACHE_AREA1
5 – DOMAIN
Creates a domain definition. A domain defines the set of values, character set, collating sequence, and formatting clause that a column in a table can have. The CREATE DOMAIN statement specifies the set of values by associating a data type with a domain name. There are two ways to specify a domain definition: o With a domain name, data type, and any combination of the following optional clauses: - Default value - Stored name - Collating sequence - Formatting clauses such as EDIT STRING or QUERY HEADER o With the FROM clause and a repository path name that refers to a field already defined in the repository When the CREATE DOMAIN statement executes, SQL adds the domain definition to the database. If you attached to the database with the PATHNAME specification, the domain definition is also added to the repository. You can refer to a domain instead of an SQL data type in the CREATE and ALTER TABLE statements, and in formal parameter declarations in functions and procedures. If the domain has to change, you need only change that one domain definition (using the ALTER DOMAIN statement) to change all the tables. This ability makes it easier to keep applications consistent. A domain can be referenced in the following locations: o CREATE, ALTER and DROP DOMAIN statements o CREATE and ALTER TABLE statements as the data type for a column o CREATE and ALTER MODULE statements as the data type of a routine parameter, or the data type of declared variable o CREATE FUNCTION statement as the data type of a function parameter or function result o CREATE PROCEDURE statement as the data type of a procedure parameter o CREATE and ALTER SYNONYM statement as the base object for a synonym o as the datatype of a CAST expression o as a data type of a DECLARE variable statement in interactive SQL o as the source in the EDIT USING clause of the SELECT and PRINT statements in interactive SQL. The EDIT STRING is inherited from that domain.
5.1 – Environment
You can use the CREATE DOMAIN statement: o In interactive SQL o Embedded in host language programs to be precompiled o As part of a procedure in an SQL module o In dynamic SQL as a statement to be dynamically executed
5.2 – Format
(B)0[m[1;4mCREATE[m[1m [1;4mDOMAIN[m[1m qk [m [1mlqqqqqqqqqqqqqqj [m [1mtq> <domain-name> wqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwk [m [1mx mq> [1;4mSTORED[m[1m [1;4mNAME[m[1m IS <stored-name> qqqjx [m [1mxlqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1mxmwq> IS data-type qwqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqqqk [m [1mx mq> AS data-type qj mqq> [1;4mDEFAULT[m[1m value-expr qqqqqj x [m [1mx lqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1mx mqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqk [m [1mx tq> [1;4mCOLLATING[m[1m [1;4mSEQUENCE[m[1m IS <collation-name> qqu x [m [1mx mq> [1;4mNO[m[1m [1;4mCOLLATING[m[1m [1;4mSEQUENCE[m[1m qqqqqqqqqqqqqqqqqqqj x [m [1mx lqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1mx mqwqqqqqqqqqqqqqqqqqqqqqqwqwqqqqqqqqqqqqqqqqqqqqqqqqwwq> [m [1mx mq> domain-constraint qj mw> sql-and-dtr-clause qwjx [m [1mx mqqqqqqqqq<qqqqqqqqqqqqj x [m [1mmq> [1;4mFROM[m[1m q> <path-name> wqqqqqqqqqqqqqqqqq>qqqqqqqqqqwqqqj [m [1m mq> [1;4mDATABASE[m[1m ALIAS <alias> qqj [m (B)0[m[1mdomain-name = [m [1m [m [1mqwqqqqqqqqqqqqqqqqqqqqqqqqqqqwq> <name-of-domain> qqq> [m [1m mqwq> <schema-name> qwq> . qj [m [1m [m [1m mq> <alias> qqqqqqqj [m [1m [m [1m [m [1m [m [1m [m (B)0[m[1mdata-type = [m [1m [m [1mqqwq> char-data-types qqqqqqqqqqqqqqqqqqqqqqqqqqqwqq> [m [1m tq> [1;4mTINYINT[m[1m qqqqqqqqqqqqqqwqqqqqwqqqqqqqqqqwqqqu [m [1m tq> [1;4mSMALLINT[m[1m qqqqqqqqqqqqqu mq> (<n>) qj x [m [1m tq> [1;4mINTEGER[m[1m qqqqqqqqqqqqqqu x [m [1m tq> [1;4mBIGINT[m[1m qqqqqqqqqqqqqqqu x [m [1m tq> [1;4mLIST[m[1m [1;4mOF[m[1m [1;4mBYTE[m[1m [1;4mVARYING[m[1m qj x [m [1m tq> [1;4mDECIMAL[m[1m qwwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqqu [m [1m tq> [1;4mNUMERIC[m[1m qjmq> ( q> <n> wqqqqqqqqqqwq> ) j x [m [1m x mq> , <n> qj x [m [1m tq> [1;4mFLOAT[m[1m qwqqqqqqqqqqwqqqqqqqqqqqqqqqqqqqqqqqqu [m [1m x mq> (<n>) qj x [m [1m tq> [1;4mREAL[m[1m qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu [m [1m tq> [1;4mDOUBLE[m[1m [1;4mPRECISION[m[1m qqqqqqqqqqqqqqqqqqqqqqqqqqu [m [1m mq> date-time-data-types qqqqqqqqqqqqqqqqqqqqqqj [m [1m [m (B)0[m[1mchar-data-types = [m [1m [m [1mqwq> [1;4mCHAR[m[1m qqqqqqqqqqqqqwwqqqqqqqqqqqqwwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqwq>[m [1m tq> [1;4mCHARACTER[m[1m qqqqqqqqumq> ( <n> ) qjmq> [1;4mCHARACTER[m[1m [1;4mSET[m[1m char[m-[1mset-name qj x [m [1mtq> [1;4mCHAR[m[1m [1;4mVARYING[m[1m qqqqqu[m [1m [m [1mx [m [1mtq> [1;4mCHARACTER[m[1m [1;4mVARYING[m[1m j[m [1mx [m [1mtq> [1;4mVARCHAR[m[1m qqw>[m [1m( <n> ) qqqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqqqqqqqqqqu [m [1mtq> [1;4mVARCHAR2[m[1m qj[m [1m mq> [1;4mCHARACTER[m[1m [1;4mSET[m[1m char-set-name qj [m [1mx[m [1m tq> [1;4mLONG[m[1m [1;4mVARCHAR[m[1m qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu [m [1m tq> [1;4mNCHAR[m[1m qqqqqqqqqqqqqqwqwqqqqqqqqqqqqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu [m [1m tq> [1;4mNATIONAL[m[1m [1;4mCHAR[m[1m qqqqqqu mq> ( <n> ) qj [m [1m [m [1mx [m [1m tq> [1;4mNATIONAL[m[1m [1;4mCHARACTER[m[1m qj [m [1m [m [1mx [m [1m tq> [1;4mNCHAR[m[1m [1;4mVARYING[m[1m qqqqqqqqqqqqqqwqwqqqqqqqqqqqqwqqqqqqqqqqqqqqqqqqqqqqqqu[m [1m tq> [1;4mNATIONAL[m[1m [1;4mCHAR[m[1m [1;4mVARYING[m[1m qqqqqqu mq> ( <n> ) qj [m [1m [m [1mx [m [1m tq> [1;4mNATIONAL[m[1m [1;4mCHARACTER[m[1m [1;4mVARYING[m[1m qj [m [1m [m [1mx [m [1mtq> [1;4mRAW[m[1m q> ( <n> ) q[mqqq[1mqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu[m [1mmq> [1;4mLONG[m[1m qwqqqqqqqqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1mmq> [1;4mRAW[m[1m qj[m (B)0[m[1mdate-time-data-types = [m [1m [m [1mqqwq> [1;4mDATE[m[1m qwqqqqqqqqqqwqqqqqqqqqqqqqqqqqwqq> [m [1m x tq> [1;4mANSI[m[1m qu x [m [1m x mq> [1;4mVMS[m[1m qqqj x [m [1m tq> [1;4mTIME[m[1m qqq> frac qqqqqqqqqqqqqqqqqqqqu [m [1m tq> [1;4mTIMESTAMP[m[1m qq> frac qqqqqqqqqqqqqqqqu [m [1m mq> [1;4mINTERVAL[m[1m qqq> interval-qualifier qqj [m [1m [m (B)0[m[1minterval-qualifier = [m [1m [m [1mqqwq> [1;4mYEAR[m[1m qqq> prec qqwqqqqqqqqqqqqqwqqqqqqqqqqqqqqqqqwq> [m [1m x mq> [1;4mTO[m[1m [1;4mMONTH[m[1m qj x [m [1m tq> [1;4mMONTH[m[1m qq> prec qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu [m [1m tq> [1;4mDAY[m[1m qqqq> prec qqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu [m [1m x mq> [1;4mTO[m[1m qwq> [1;4mHOUR[m[1m qqqqqqqqqqqqqqqu [m [1m x tq> [1;4mMINUTE[m[1m qqqqqqqqqqqqqu [m [1m x mq> [1;4mSECOND[m[1m q> frac qqqqqu [m [1m tq> [1;4mHOUR[m[1m qqq> prec qqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu [m [1m x mq> [1;4mTO[m[1m qwq> [1;4mMINUTE[m[1m qqqqqqqqqqqqqu [m [1m x mq> [1;4mSECOND[m[1m q> frac qqqqqu [m [1m tq> [1;4mMINUTE[m[1m q> prec qqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu [m [1m x mq> [1;4mTO[m[1m [1;4mSECOND[m[1m qqqqqq> frac qqqqqu [m [1m mq> [1;4mSECOND[m[1m q> seconds-prec qqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1m [m (B)0[m[1mliteral = [m [1m [m [1mqqwq> numeric-literal qqqqwqqq> [m [1m tq> string-literal qqqqqu [m [1m tq> date-time-literal qqu [m [1m mq> interval-literal qqqj [m [1m [m (B)0[m[1mdomain-constraint = [m [1m [m [1mqqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqqqq>[m [1m mq> [1;4mCHECK[m[1m ( predicate ) qwqqqqqqqqqqqqqqqqqqqqqqqqqqwj[m [1m [m [1mmq> constraint-attributes[m [1mqj[m [1m [m [1m [m (B)0[m[1msql-and-dtr-clause = [m [1m [m [1mqwq> [1;4mQUERY[m[1m [1;4mHEADER[m[1m IS qw> <quoted-string> wqqqqqqqqqqqqqqqqqqwq>[m [1m x mqqqqqq / <qqqqqqqqj x [m [1m tq> [1;4mEDIT[m[1m [1;4mSTRING[m[1m IS <quoted-string> qqqqqqqqqqqqqqqqqqqqqqqqu [m [1m x x [m [1m tq> [1;4mQUERY[m[1m [1;4mNAME[m[1m FOR qwq> DTR qqqqqqqqwq> IS <quoted-string> u [m [1m x mq> DATATRIEVE qj x [m [1m tq> [1;4mDEFAULT[m[1m [1;4mVALUE[m[1m FOR qwq> DTR qqqqqqqqwq> IS <literal> qqqu [m [1m x mq> DATATRIEVE qj x [m [1m tq> [1;4mNO[m[1m [1;4mQUERY[m[1m [1;4mHEADER[m[1m qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu [m [1m tq> [1;4mNO[m[1m [1;4mEDIT[m[1m [1;4mSTRING[m[1m qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu [m [1m tq> [1;4mNO[m[1m [1;4mQUERY[m[1m [1;4mNAME[m[1m qqqqwqq> FOR qwq> DTR qqqqqqqqwqqqqqqqqqqu [m [1m tq> [1;4mNO[m[1m [1;4mDEFAULT[m[1m [1;4mVALUE[m[1m qj mq> DATATRIEVE qj x [m [1mmq> [1;4mCOMMENT[m[1m IS qwq> <quoted-string>[m [1mqwqqqqqqqqqqqqqqqqqqqqqj[m [1m [m [1mmqqqqqq[m [1m/[m [1m<qqqqqqqqqqj[m [1m [m [1m [m [1m [m
5.3 – Arguments
5.3.1 – char-data-types
A character type. See the Data_Types HELP topic for more information on data types.
5.3.2 – character-set-name
A valid character set.
5.3.3 – COLLATING_SEQUENCE
Specifies a collating sequence for the named domain. The OpenVMS National Character Set (NCS) utility provides a set of predefined collating sequences and also lets you define collating sequences of your own. The COLLATING SEQUENCE clause accepts both predefined and user-defined NCS collating sequences. Before you use the COLLATING SEQUENCE clause in a CREATE DOMAIN statement, you must first specify the NCS collating sequence for SQL using the CREATE COLLATING SEQUENCE statement. The sequence- name argument in the COLLATING SEQUENCE clause must be the same as the sequence-name in the CREATE COLLATING SEQUENCE statement.
5.3.4 – COMMENT_IS
Adds a comment about the domain. SQL displays the text of the comment when it executes a SHOW DOMAIN statement. Enclose the comment in single quotation marks ( ') and separate multiple lines in a comment with a slash mark (/).
5.3.5 – DATABASE ALIAS alias
In the FROM path-name clause, specifies the name for an attach to a particular database. SQL adds the domain definition to the database referred to by the alias. If you do not specify an alias, SQL adds the domain definition to the default database. See the User_Supplied_Names HELP topic for more information on default databases and aliases.
5.3.6 – date-time-data-types
A data type that specifies a date, time, or interval. See the Data_Types HELP topic for more information about date-time data types.
5.3.7 – DEFAULT value-expr
Provides a default value for a domain. You can use any value expression including subqueries, conditional, character, date/time, and numeric expressions as default values. See Value Expressions for more information about value expressions. For more information about NULL, see the NULL_Keyword HELP topic. The value expressions described in Value Expressions include DBKEY and aggregate functions. However, the DEFAULT clause is not a valid location for referencing a DBKEY or an aggregate function. If you attempt to reference either, you receive a compile-time error. If you do not specify a DEFAULT for a column, it inherits the DEFAULT from the domain. If you do not specify a default for either the column or domain, SQL assigns NULL as the default value.
5.3.8 – domain-constraint
Creates a constraint for the named domain. Specify a domain constraint when you create a domain to limit which values can be stored in columns based on the domain. Domain constraints specify that columns based on the domain contain only certain data values or that data values can or cannot be null. Use the CHECK clause to specify that a value must be within a specified range or that it matches a list of values. When you specify a CHECK clause for a domain constraint, you ensure that all values stored in columns based on the domain are checked consistently.
5.3.9 – domain-name
The name of a domain you want to create. The domain name must be unique among domain names in the schema. You can qualify it with an alias or (in multischema databases only) a schema name.
5.3.10 – FROM pathname
Specifies the repository path name of a repository field definition. SQL creates the domain using the definition from this field and gives the domain the name of the field definition. Creating a domain based on a repository domain definition is useful when many applications share the same definition. Changes to the common definition can be automatically reflected in all applications that use it. You can create a domain using the FROM path-name clause only if the field definition in the repository was originally created using the repository CDO utility. For instance, you cannot create a domain using the FROM path-name clause if the definition was created in the repository as part of an SQL session. Oracle Rdb requires that the field names referenced in the VALID IF expression of the CDO utility match the name of the global field being defined or changed. NOTE Changes by other users or applications to the field definition in the repository will affect the domain definition once the database is integrated to match the repository with an INTEGRATE DATABASE . . . ALTER FILES statement. You can use the FROM path-name clause only if the database was attached specifying PATHNAME. You can specify either a full repository path name or a relative repository path name. You cannot specify formatting clauses when you use the FROM path- name form of the CREATE DOMAIN statement. You cannot use the FROM path-name clause when embedding a CREATE DOMAIN statement in a CREATE DATABASE statement.
5.3.11 – data-type
Syntax options: IS data-type AS data-type A valid SQL data type. See the Data_Types HELP topic for more information on data types.
5.3.12 – NO_COLLATING_SEQUENCE
Specifies that this domain uses the standard default collating sequence, that is, ASCII. Use the NO COLLATING SEQUENCE clause to override the collating sequence defined for the database in the CREATE DATABASE or ALTER DATABASE statement.
5.3.13 – sql-and-dtr-clause
Optional SQL and DATATRIEVE formatting clause. See the DATATRIEVE HELP topic for more information on formatting clauses.
5.3.14 – STORED_NAME_IS
Specifies a name that Oracle Rdb uses to access a domain created in a multischema database. The stored name lets you access multischema definitions using interfaces, such as Oracle RMU, the Oracle Rdb management utility, that do not recognize multiple schemas in one database. You cannot specify a stored name for a domain in a database that does not allow multiple schemas. For more information about stored names, see the User_Supplied_Names HELP topic.
5.4 – Examples
Example 1: Creating a domain for a standard EMPLOYEE_ID definition The following example creates the domain ID_DOM, which will be a standard definition of columns for the employee ID: SQL> CREATE DOMAIN ID_DOM CHAR(5) SQL> COMMENT IS cont> 'standard definition of employee id'; Example 2: Creating a domain for standard date The following example creates the domain STANDARD_DATE_DOM, which includes the edit string DD-MMM-YYYY: SQL> CREATE DOMAIN STANDARD_DATE_DOM DATE cont> EDIT STRING IS 'DD-MMM-YYYY' SQL> COMMENT IS cont> 'standard definition for complete dates'; Example 3: Creating domains with default values The following example creates two domains: ADDRESS_DATA2_DOM and WORK_STATUS_DOM. The ADDRESS_DATA2_DOM domain has a default value of NULL; the WORK_STATUS_DOM domain has a default value of 1 to signify full-time work status. SQL> CREATE DOMAIN ADDRESS_DATA2_DOM CHAR(20) cont> DEFAULT NULL; SQL> -- SQL> CREATE DOMAIN WORK_STATUS_DOM SMALLINT cont> DEFAULT 1; Example 4: Basing a domain on a repository field definition The following example illustrates using the repository as a source for the definition in a CREATE DOMAIN statement: $ SQL$ SQL> ATTACH 'PATHNAME CDD$TOP.SQL.RDB.TEST.DATE'; SQL> CREATE DOMAIN FROM DOMAIN_TEST; SQL> SHOW DOMAIN User domains in database with pathname SYS$COMMON:[CDDPLUS]SQL.RDB.TEST.DATE;1 DOMAIN_TEST BIGINT Example 5: Creating a domain with a collating sequence The following example creates a domain with the predefined NCS collating sequence SPANISH. Note that you must first execute the CREATE COLLATING SEQUENCE statement: SQL> -- SQL> CREATE COLLATING SEQUENCE SPANISH SPANISH; SQL> CREATE DOMAIN LAST_NAME_SPANISH CHAR(14) cont> COLLATING SEQUENCE IS SPANISH; SQL> -- SQL> SHOW DOMAIN LAST_NAME_SPANISH LAST_NAME_SPANISH CHAR(14) Collating sequence: SPANISH Example 6: Creating a domain using the database default character set For each of the following examples, assume the database was created specifying the database default character set as DEC_ KANJI and the national character set as KANJI. The following example creates the domain DEC_KANJI_DOM using the database default character set: SQL> SHOW CHARACTER SET; Default character set is DEC_KANJI National character set is KANJI Identifier character set is DEC_KANJI Literal character set is DEC_KANJI Alias RDB$DBHANDLE: Identifier character set is DEC_KANJI Default character set is DEC_KANJI National character set is KANJI SQL> CREATE DOMAIN DEC_KANJI_DOM CHAR(8); SQL> SHOW DOMAIN User domains in database with filename MIA_CHAR_SET DEC_KANJI_DOM CHAR(8) Because the CREATE DOMAIN statement does not specify a character set, Oracle Rdb defines the domain using the database default character set. The database default character set does not display with the SHOW DOMAIN statement. An equivalent statement to the previous CREATE DOMAIN statement is: SQL> CREATE DOMAIN DEC_KANJI_DOM CHAR(8) CHARACTER SET DEC_KANJI; Example 7: Creating a domain using the national character set The following example creates the domain KANJI_DOM using the NCHAR data type to designate use of the national character set: SQL> CREATE DOMAIN KANJI_DOM NCHAR(8); SQL> SHOW DOMAIN User domains in database with filename MIA_CHAR_SET DEC_KANJI_DOM CHAR(8) KANJI_DOM CHAR(8) KANJI 8 Characters, 16 Octets When a character set other than the default is specified, the SHOW DOMAIN statement displays the character set associated with the domain. Two statements equivalent to the previous CREATE DOMAIN statement are: SQL> CREATE DOMAIN KANJI_DOM NATIONAL CHAR(8); SQL> CREATE DOMAIN KANJI_DOM CHAR(8) CHARACTER SET KANJI; Example 8: Creating a domain constraint The following example creates a domain constraint: SQL> -- The SET DIALECT 'SQL99' statement sets the default date format SQL> -- to the ANSI/ISO SQL standard format. SQL> -- SQL> SET DIALECT 'SQL99'; SQL> -- SQL> -- The following domain ensures that any dates inserted into the database SQL> -- are later than January 1, 1900: SQL> -- SQL> CREATE DOMAIN TEST_DOM DATE cont> DEFAULT NULL cont> CHECK (VALUE > DATE'1900-01-01' OR cont> VALUE IS NULL) cont> NOT DEFERRABLE; SQL> SQL> -- The following example creates a table with one column based on the SQL> -- domain TEST_DOM: SQL> -- SQL> CREATE TABLE DOMAIN_TEST cont> (DATE_COL TEST_DOM); SQL> -- SQL> -- SQL returns an error if you attempt to insert data that does not SQL> -- conform to the domain constraint: SQL> -- SQL> INSERT INTO DOMAIN_TEST cont> VALUES (DATE'1899-01-01'); %RDB-E-NOT_VALID, validation on field DATE_COL caused operation to fail
6 – FUNCTION
Creates an external function as a schema object in an Oracle Rdb database. The CREATE FUNCTION statement is documented under the CREATE Routine. For complete information on creating an external function definition, see the CREATE Routine Help topic.
7 – INDEX
Creates an index for a table. An index allows direct access to the rows in the table to avoid sequential searching. You define an index by listing the columns in a table that make up the index. You can define more than one index for a table. The index can be made up of one column, or two or more columns. An index made up of two or more columns is called a multisegmented index. Optional arguments to the CREATE INDEX statement let you specify: o The type of index structure (hashed, sorted nonranked, or sorted ranked) o The names of a storage area or storage areas that contain the index o Physical characteristics of a sorted index structure, such as index node size and the initial fullness percentage of each node o Compression characteristics, including compressed key suffixes for text indexes and integer column compression for smallint or integer numeric columns o Compression of space characters from text data types and of binary zeros from nontext data types o Thresholds for the logical storage areas that contain the index o A comment for the index definition o Whether logging to the .ruj and .aij files is enabled or disabled for the create index operation
7.1 – Environment
You can use the CREATE INDEX statement: o In interactive SQL o Embedded in host language programs to be precompiled o As part of a procedure in an SQL module o In dynamic SQL as a statement to be dynamically executed
7.2 – Format
(B)0[m[1;4mCREATE[m[1m qwqqqqqqqqqqqwq> [1;4mINDEX[m[1m <index-name> qqqqqqqqqqqqqqqqqqk [m [1m mq> [1;4mUNIQUE[m[1m qj x [m [1mlqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1mmqqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwq> [1;4mON[m[1m <table-name> qqk [m [1m mq> [1;4mSTORED[m[1m [1;4mNAME[m[1m IS <stored-name> qqqj x [m [1mlqqqqqqqqqqqqqqqqqqqqqqqqqqqqq <qqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1mm> ( w> <column-name> qqk [m [1m x lqqqqqqqqqqqqqqj [m [1m x mqwqqqqqqqqqqqqqwwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqwq ) qk [m [1m x t> ASCENDING qut> SIZE IS <n> qqqqqqqqqqqqqqqu x x [m [1m x m> DESCENDING jm> MAPPING VALUES <l> TO <h> qj x x [m [1m mqqqqqqqqqqqqqqqqqqqqqq , <qqqqqqqqqqqqqqqqqqqqqqqqqqj x [m [1mlqqqqqqqqqqqqqqqqqqqqqqqqqqqqqq <qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1mmwqqqqqqqqqqqqqqqqwqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqqqqqqqqqqqk [m [1m mq> type-clause qj mq> index-attributes-clause qj x [m [1mlqqqqqqqqqqqqqqqqqqqqqqqqqqqqqq<qqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1mmwqqqqqqqqqqqqqqqqqqqqqqqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqq> [m [1m mq> index-store-clause qj [m [1m [m (B)0[m[1mtype-clause = [m [1m [m [1mq> [1;4mTYPE[m[1m IS w> [1;4mHASHED[m[1m wqqqqqqqqqqqqqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqw> [m [1m x t> [1;4mORDERED[m[1m qqqu x [m [1m x m> [1;4mSCATTERED[m[1m qj x [m [1m m> [1;4mSORTED[m[1m wqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqkx [m [1m m> [1;4mRANKED[m[1m qwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwj xx [m [1m m> [1;4mDUPLICATES[m[1m ARE [1;4mCOMPRESSED[m[1m qj xx [m [1m lqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqjx [m [1m mqwqqqqqqqqqqqqqqqqqqqqqqqwqqqqqqqqqqqqqqqqqqqqj [m [1m m> sorted-index-clause qj [m [1m [m (B)0[m[1msorted-index-clause = [m [1m [m [1mqqwqwq> [1;4mNODE[m[1m [1;4mSIZE[m[1m <number-bytes> qqqqqqqqqqwqwqq> [m [1m x tq> [1;4mPERCENT[m[1m [1;4mFILL[m[1m <percentage> qqqqqqqqqu x [m [1m x mq> [1;4mUSAGE[m[1m qwq> [1;4mUPDATE[m[1m qwqqqqqqqqqqqqqqqj x [m [1m x mq> [1;4mQUERY[m[1m qqj x [m [1m mqqqqqqqqqqqqqqqqqqq <qqqqqqqqqqqqqqqqqqqqqj [m [1m [m (B)0[m[1mindex-attributes-clause = [m [1m [m [1mqwqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqwq>[m [1m x tq> [1;4mENABLE[m[1m [1;4mCOMPRESSION[m[1m [m [1mrlc-attr qqqqqqqqqqqqqqqqqqqqqqqqqu x [m [1m x tq> [1;4mDISABLE[m[1m [1;4mCOMPRESSION[m[1m qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu x [m [1m x[m [1mtq> threshold-clause qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu[m [1mx[m [1m x tq> [1;4mLOGGING[m[1m qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu x [m [1m x tq> [1;4mNOLOGGING[m[1m qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu x [m [1m x tq> [1;4mCOMMENT[m[1m IS qwq> '<string>' qwqqqqqqqqqqqqqqqqqqqqqqqqqu x [m [1m x x mqqqqqqq / <qqqqj [m [1m x x [m [1mx[m [1mtq> [1;4mPREFIX[m [1;4mCARDINALITY[m [1;4mCOLLECTION[m[1m IS qwq>[m [1;4mENABLED[m [1mqqqqqqwqu[m [1mx[m [1mx[m [1mx[m [1mtq>[m [1;4mENABLED[m [1;4mFULL[m [1mqu x[m [1mx[m [1mx[m [1mx[m [1mmq>[m [1;4mDISABLED[m [1mqqqqqj[m [1mx[m [1mx[m [1mx[m [1mmq> [1;4mMAINTENANCE[m[1m IS qwq> [1;4mDISABLED[m [1mqqqqqqqqqqqqqqqqqwqqqqqqqj x[m [1mx[m [1mmq>[m [1;4mENABLED[m[1m qwqqqqqqqqqqqqqqwqj[m [1mx[m [1mx[m [1mtq>[m [1;4mDEFERRED[m [1mqqu [m [1mx[m [1mx[m [1mmq> [1;4mIMMEDIATE[m[1m qj[m [1mx[m [1mmqqqqqqqqqqqqqqqqqqqqqqqqqqqq <qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj[m (B)0[m[1mrlc-attr =[m qqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqq[1mwq[mqqqqqqqq> mqq> [1m(MINIMUM RUN LENGTH <n> ) qqj[m (B)0[m[1mindex-store-clause = [m [1m [m [1;4mSTORE[m[1m qqqqqqqqqqqqqqqqqqqqqqk [m [1mlqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1mmwq> [1;4mIN[m[1m area-spec qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqw> [m [1m mq> [1;4mUSING[m[1m q> ( qwqq> <column-name> qwq> ) qqqqqqqqqqk x [m [1m mqqqqqqq , <qqqqqqqqj x x [m [1m lqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj x [m [1m mw> [1;4mIN[m[1m area-spec qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqk x [m [1m x lqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj x [m [1m x mq> [1;4mWITH[m[1m [1;4mLIMIT[m[1m [1;4mOF[m[1m q> ( qwqq> <literal> qwq> ) qqqwqqqk x [m [1m x mqqqqqq , <qqqqqj x x x [m [1m mqqqqqqqqqqqqqqqqqqqqqqq<qqqqqqqqqqqqqqqqqqqqqqqqqqj x x [m [1mlqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj x [m [1mmwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwj [m [1m mq> [1;4mOTHERWISE[m[1m IN area-spec qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m (B)0[m[1mthreshold-clause = [m [1m [m [1mqqwq> [1;4mTHRESHOLD[m[1m qwq> IS qwq> ( qq> <val1> qq> ) qqqqqqqqqwq> [m [1m x mq> OF qj x [m [1m x x [m [1m mq> [1;4mTHRESHOLDS[m[1m qwq> ARE qwqqqqqqqqqqqk x [m [1m mq> OF qj x x [m [1m lqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj x [m [1m mq> ( qq> <val1> qwqqqqqqqqqqqqqqqqqqqqqqqqqqqwq> ) qj [m [1m mq> , <val2> qwqqqqqqqqqqqqqu [m [1m mq> , <val3> qj [m [1m [m (B)0[m[1marea-spec =[m [1m [m [1m [m [1mqq> <area-name> qwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwq> [m [1m mq> ( qwwq> threshold-clause qqqqqqqqqqqqqqqwwq> ) qj [m [1m xtq> [1;4mLOGGING[m[1m qqqqqqqqqqqqqqqqqqqqqqqqux [m [1m xtq> [1;4mNOLOGGING[m[1m qqqqqqqqqqqqqqqqqqqqqqux [m [1m xtq> [1;4mPARTITION[m[1m <name> qqqqqqqqqqqqqqqux [m [1m xmq> [1;4mCOMMENT[m[1m IS qwqq> 'string' qqqwqqjx [m [1m x mqqqqqqq / <qqqqqj x [m [1m mqqqqqqqqqqqqqqqq , qqqqqqqqqqqqqqqqqj [m
7.3 – Arguments
7.3.1 – ASCENDING
An optional keyword that causes SQL to create ascending index segments. If you omit the ASCENDING or DESCENDING keyword, ascending is the default.
7.3.2 – BUILD_ALL_PARTITIONS
This clause operates on an index in build-pending state (created using MAINTENANCE IS ENABLED DEFERRED) and builds all incomplete partitions. If the index is not in build-pending state then the statement completes successfully with a warning. No other clauses may appear in the same ALTER INDEX statement.
7.3.3 – BUILD PARTITION partition-name
This clause operates on an index in build-pending state (created using MAINTENANCE IS ENABLED DEFERRED) and builds the named partition. If the index is not in build-pending state then the statement completes successfully with a warning. No other clauses may appear in the same ALTER INDEX statement.
7.3.4 – column-name
The name of the column or columns that make up the index key. You can create a multisegmented index key by naming two or more columns, which are joined to form the index key. All the columns must be part of the same table. Separate multiple column names with commas. NOTE If column-name refers to a column defined as CHAR, VARCHAR or LONG VARCHAR data type, the size of the column must be less than or equal to 254 characters, or the SIZE IS clause must be used.
7.3.5 – COMMENT IS 'string '
Adds a comment about the storage map definition for the index. SQL displays the text of the comment when it executes a SHOW INDEXES statement. Enclose the comment in single quotation marks ( ') and separate multiple lines in a comment with a slash mark (/).
7.3.6 – DESCENDING
An optional keyword that causes SQL to create descending index segments. If you omit the ASCENDING or DESCENDING keyword, ascending is the default.
7.3.7 – DISABLE_COMPRESSION
Disables compression indexes. If compression is disabled, no form of compression is used for hashed indexes, and prefix compression or suffix compression is used for sorted indexes. Prefix compression is the compression of the first bytes of an index key that are common in consecutive index keys. Prefix compression saves space by not storing these common bytes of information. Conversely, suffix compression is the compression of the last bytes from adjacent index keys. These bytes are not necessary to guarantee uniqueness. You cannot enable index compression using the ALTER INDEX statement once you specified the DISABLE COMPRESSION clause of the CREATE INDEX statement. Index compression is disabled by default.
7.3.8 – DUPLICATES_ARE_COMPRESSED
Specifies that duplicates are compressed. If a sorted ranked index allows duplicate entries, you can store many more records in a small space when you compress duplicates, therefore, minimizing I/O and increasing performance. Oracle Rdb uses patented technology called byte-aligned bitmap compression to represent the dbkeys for the duplicate entries instead of chaining the duplicate entries together with uncompressed dbkeys. Duplicates are compressed by default if you specify RANKED without specifying the DUPLICATES ARE COMPRESSED clause. You cannot use the DUPLICATES ARE COMPRESSED clause when you create nonranked indexes or when you specify the UNIQUE keyword. See the Oracle Rdb Guide to Database Design and Definition for more information on sorted ranked B-tree indexes.
7.3.9 – ENABLE_COMPRESSION
Specifies that sorted and hashed indexes are stored in a compressed form. If compression is enabled, Oracle Rdb uses run-length compression to compress a sequence of space characters (octets) from text data types and binary zeros from nontext data types. Different character sets have different representations of the space character. Oracle Rdb compresses the representation of the space character for the character sets of the columns comprising the index values. You cannot disable index compression using the ALTER INDEX statement once you specified the ENABLE COMPRESSION clause of the CREATE INDEX statement. For more information on compressed indexes, see the Oracle Rdb Guide to Database Design and Definition.
7.3.10 – IN area name
Associates the index directly with a single storage area. All entries in the index are stored in the area you specify.
7.3.11 – index-name
The name of the index. You can use this name to refer to the index in other statements. You must qualify the index name with the authorization identifier if the schema is not the default schema. When choosing a name, specify a valid name. See the User_ Supplied_Names HELP topic for more information.
7.3.12 – index-store-clause
A storage map definition for the index. You can specify a store clause for indexes in a multifile database only. The STORE clause in a CREATE INDEX statement allows you to specify which storage area files are used to store the index entries: o All index entries can be associated with a single storage area. o Index entries can be systematically distributed, or partitioned, among several storage areas by specifying upper limits on the values for a key in a particular storage area. If you omit the storage map definition, the default is to store all the entries for an index in the main default storage area. You should define a storage area for an index that matches the storage map for the table with which it is associated. In particular, under the following conditions, the database system stores the index entry for a row on or near the same data page that contains the actual row: o The storage areas for a table have a mixed page format. o You specify an identical store clause for the index as exists in the storage map for the table. o The storage map for the table also names the index in the PLACEMENT VIA INDEX clause. Such coincidental clustering of indexes and rows can reduce I/O operations. With hashed indexes and coincidental clustering, the database system can retrieve rows for exact-match queries in one I/O operation. For sorted indexes, specifying an identical storage map reduces I/O contention on index nodes.
7.3.13 – LOGGING
Syntax options: LOGGING |NOLOGGING The LOGGING clause specifies that index nodes and hash buckets be logged when written to the database. Logging includes writing data and management records to the recovery-unit journal file (.ruj) and after-image journal files (.aij). When the NOLOGGING clause is specified then only a small number of management records are logged in the recovery-unit journal file (.ruj) and after-image journal files (.aij). See the Usage Notes below for more information. LOGGING and NOLOGGING can be specified per storage area (partition) or as a default for the CREATE INDEX statement. The LOGGING and NOLOGGING clauses are mutually exclusive; specify only one. The LOGGING clause is the default.
7.3.14 – MAINTENANCE_IS_DISABLED
An index created using this clause is not maintained. The index definition serves only as a template.
7.3.15 – MAINTENANCE_IS_ENABLED_DEFERRED
An index created using this clause does not contain index keys for the current rows in the table. Until this index is built (using ALTER INDEX . . . BUILD), the index is placed in a build- pending state. Any table with a build-pending index can not be updated using the INSERT, DELETE, or UPDATE statements.
7.3.16 – MAINTENANCE_IS_ENABLED_IMMEDIATE
This is the default behavior for CREATE INDEX.
7.3.17 – MAPPING_VALUES
l to h A compression clause for all-numeric columns that translates the column values into a compact, encoded form. You can mix mapped and unmapped columns, but the most storage space is gained by building indexes of multiple columns of data type SMALLINT or INTEGER. Oracle Rdb attempts to compress all such columns into the smallest possible space. The l (low) through h (high) specifies the range of integers as the value of the index key. The Oracle Rdb SQL Reference Manual describes addiional restrictions about this argument.
7.3.18 – MINIMUM_RUN_LENGTH
Specifies the minimum length of the sequence that Oracle Rdb should compress. You cannot alter this value once you set it. If you specify MINIMUM RUN LENGTH 2, Oracle Rdb compresses sequences of two or more spaces or of two or more binary zeros for single-octet character sets, and compresses one space or one binary zero for multi-octet character sets. As it compresses the sequences, Oracle Rdb replaces the sequence with the value of the minimum run length plus 1 byte. If many of the index values contain one space between characters in addition to trailing spaces, use a minimum run length of 2, so that you do not inadvertently expand the index beyond the 255-byte limit. If you inadvertently expand the index beyond 255 bytes during index creation, Oracle Rdb returns a warning message. The default minimum run length value is 2. Valid values for the minimum run length range from 1 to 127. Oracle Rdb determines which characters are compressed.
7.3.19 – NODE_SIZE
The size in bytes of each index node. The number and level of the resulting index nodes depend on: o This number-bytes value o The number and size of the index keys o The value specified in the PERCENT FILL or USAGE clauses If you omit the NODE SIZE clause, the default value is: o 430 bytes if the total index key size is 120 bytes or less o 860 bytes if the total index key size is more than 120 bytes The index key size is the number of bytes it takes to represent the column value in the sorted index. See the Oracle Rdb SQL Reference Manual for details on determining the valid range for a user-specified index node size.
7.3.20 – OTHERWISE IN area name
For partitioned storage maps only, specifies the storage area that is used as the overflow partition. An overflow partition is a storage area that holds any values that are higher than those specified in the last WITH LIMIT TO clause. An overflow partition holds those values that "overflow" the partitions that have specified limits.
7.3.21 – PARTITION name
Names the partition. The name can be a delimited identifier. Partition names must be unique within the index. If you do not specify this clause, Oracle Rdb generates a default name for the partition.
7.3.22 – PERCENT_FILL
Specifies the initial fullness percentage for each node in the index structure being changed. The valid range is 1 percent to 100 percent. The default is 70 percent. Both the PERCENT FILL and USAGE clauses specify how full an index node should be initially. Specify either PERCENT FILL or USAGE, but not both.
7.3.23 – PREFIX_CARDINALITY_COLLECTION_IS_DISABLED
This setting disables the cardinality collection and, instead, uses a fixed scaling algorithm which assumes a well balanced index tree.
7.3.24 – PREFIX_CARDINALITY_COLLECTION_IS_ENABLED
This is the default behavior for CREATE INDEX. The Oracle Rdb optimizer collects approximate cardinality values for the index columns to help in future query optimization. Note that no extra I/O is incurred to collect these values and, therefore, adjacent key values from other index nodes can not be checked. Hence, some inaccuracy may be seen for these indexes. In most cases, this is adequate for query optimizations.
7.3.25 – PREFIX_CARDINALITY_COLLECTION_IS_ENABLED_FULL
This setting requests that extra I/O be performed, if required, to ensure that the cardinality values reflect the key value changes of adjacent index nodes.
7.3.26 – REBUILD_ALL_PARTITIONS
This clause combines the TRUNCATE and BUILD actions into a single function. No other clauses may appear in the same ALTER INDEX statement.
7.3.27 – REBUILD PARTITION partition-name
This clause combines the TRUNCATE and BUILD actions into a single function for the named partition. No other clauses may appear in the same ALTER INDEX statement.
7.3.28 – SIZE IS n
A compression clause for text or varying text index keys that limits the number of characters used for retrieving data. The n specifies the number of characters of the key that are used in the index. NOTE Although you can create a SIZE IS index and specify the UNIQUE clause, truncating the index key values may make the key values non-unique. In this case, the index definition or insert or update statements fail.
7.3.29 – STORE IN area name
Associates the index directly with a single storage area. All entries in the index are stored in the area you specify.
7.3.30 – STORE_USING
Specifies columns whose values are used as limits for partitioning the index across multiple storage areas. You cannot name columns not specified as index key segments. If the index key is multisegmented, you can include some or all the columns that are joined to form the index key. You must specify the columns in the order in which they were specified when the index key was defined. If you only include a subset of the columns, you must include the leading segments of the multisegmented index. For example, if a CREATE INDEX statement specifies a multisegmented index based on the columns LAST_NAME, FIRST_NAME, and MIDDLE_INITIAL, then the USING clause must include the first segment LAST_NAME, or the first two segments, LAST_NAME, and FIRST_NAME, or all the segments of the index. This is true for sorted indices only. The database system uses the values of the columns specified in the STORE USING clause as a key to determine in which storage area an index entry associated with a new table row belongs. There is no restriction for hashed scattered indexes. For hashed ordered indexes, all segments listed, except the last segment can be included. Also, HASHED ORDERED indexes have further restrictions on the data type of the final column; it must be a date/time or integer numeric data type.
7.3.31 – STORED_NAME_IS
Specifies a name that Oracle Rdb uses to access an index created in a multischema database. The stored name allows you to access multischema definitions using interfaces, such as Oracle RMU, the Oracle Rdb management utility, that do not recognize multiple schemas in one database. You cannot specify a stored name for an index in a database that does not allow multiple schemas. For more information about stored names, see the User_Supplied_Names HELP topic.
7.3.32 – table-name
The name of the table that includes the index. The table must be in the same schema as the index.
7.3.33 – threshold-clause
Specifies one, two, or three default threshold values for logical areas that contain the index in storage areas with uniform page formats. By setting threshold values, you can make sure that Oracle Rdb does not overlook a page with sufficient space to store compressed data. The threshold values (val1, val2, and val3) represent a fullness percentage on a data page and establish three possible ranges of guaranteed free space on the data pages. For more information about logical area thresholds, see the CREATE STORAGE_MAP. If you use data compression, you should use logical area thresholds to obtain optimum storage performance. You cannot specify the thresholds for the storage map attribute for any area that is a mixed page format. If you have a mixed page format, set the thresholds for the storage area using the ADD STORAGE AREA or CREATE STORAGE AREA clause of the ALTER DATABASE, CREATE DATABASE, or IMPORT statements. For more information about SPAM pages, see the Oracle Rdb Guide to Database Design and Definition.
7.3.34 – TRUNCATE_ALL_PARTITIONS
This clause operates in a similar way to TRUNCATE TABLE, but just on one index. The index is automatically set to MAINTENANCE IS ENABLED DEFERRED (i.e. build-pending state) if it was currently ENABLED IMMEDIATE. Otherwise is stays in a disabled state. No other clauses may appear in the same ALTER INDEX statement.
7.3.35 – TRUNCATE PARTITION partition-name
This clause operates on just the named index partition. The index is automatically set to MAINTENANCE IS ENABLED DEFERRED (that is, build-pending state) if it was currently ENABLED IMMEDIATE. Otherwise is stays in a disabled state. No other clauses may appear in the same ALTER INDEX statement.
7.3.36 – TYPE_HASHED
Syntax options: TYPE IS HASHED ORDERED | TYPE IS HASHED SCATTERED Specifies that the index is a hashed index. If you specify HASHED, you cannot use the NODE SIZE, PERCENT FILL, or USAGE clauses. You can, however, specify if the data is ORDERED or SCATTERED. SCATTERED is the default. The TYPE IS HASHED SCATTERED clause is appropriate in situations where data is not evenly distributed across storage areas. This option places a record in a page that is chosen by applying a hashing algorithm to the index key. As a result, the record distribution pattern is not guaranteed to be even; therefore, some pages may be chosen more often than others. The TYPE IS HASHED SCATTERED clause is the default and is recommended unless your data meets the following criteria for the TYPE IS HASHED ORDERED clause: o The last column of the index key must be one of the following data types: - TINYINT - SMALLINT - INTEGER - BIGINT - DATE (both ANSI and VMS) - TIME - TIMESTAMP - INTERVAL o The index must be ascending. o The index must not be compressed or have mapping values. The TYPE IS HASHED ORDERED clause is ideal for applications where the index key values are evenly distributed across a given range. This places a record in a page derived by applying an ordered hashing algorithm to the index key. As a result, the distribution pattern is guaranteed to follow the index key distribution. In addition, if you know the range of values, you can size the storage area and pages to minimize overflows. If the index key values are not evenly distributed, use the TYPE IS HASHED SCATTERED clause. Hashed indexes must be stored in storage areas created with mixed page format, which means they are valid only in multifile databases. Hashed indexes provide fast and direct access to specific rows and are effective mainly for queries that specify an exact-match retrieval on a column or columns that are also the key to a hashed index. (For instance, SELECT EMPLOYEE_ID FROM EMPLOYEES WHERE EMPLOYEE_ID = "00126", makes effective use of a hashed index with EMPLOYEE_ID as the index key.) In a hashed indexing scheme, the index key value is converted mathematically to a relative page number in the storage area of a particular table. A hash bucket is a data structure that maintains information about an index key, and a list of internal pointers, called database keys or dbkeys, to rows that contain the particular value of the index key. To find a row using the hashed index, the database system searches the hash bucket, finds the appropriate dbkey, and then fetches the table row. Hashed indexes are most effective for random, direct access when the query supplies the entire index key on which the hashed index is defined. For these types of access, I/O operations can be significantly reduced. This is particularly useful for tables with many rows and large indexes. For example, to retrieve a row using a sorted index that is four levels deep, the database system may need to perform five I/O operations. By using hashing, the number of I/O operations is reduced to two, at most. You can define a hashed index and a sorted index for the same column. Then, depending on the type of query you use, the Oracle Rdb optimizer chooses the appropriate method of retrieval. For example, if your query contains an exact-match retrieval, the optimizer uses hashed index access. If your query contains a range retrieval, the optimizer uses the sorted index. This strategy incurs the additional overhead of maintaining two indexes, therefore, you need to consider the advantages of fast retrieval against the disadvantages of updating two indexes for every change to data. See the Oracle Rdb Guide to Database Design and Definition for a detailed discussion of the relative advantages of hashed and sorted indexes.
7.3.37 – TYPE_IS_SORTED
Specifies that the index is a sorted, nonranked (B-tree) index. If you omit the TYPE IS clause, SORTED is the default. Sorted indexes improve the performance of queries that compare values using range operators (like BETWEEN and greater than (>)). (For example, SELECT EMPLOYEE_ID FROM EMPLOYEES WHERE EMPLOYEE_ID > 200 is a query that specifies a range retrieval and makes effective use of a sorted index.) You can define a hashed index and a sorted index for the same column. Then, depending on the type of query you use, the Oracle Rdb optimizer chooses the appropriate method of retrieval. For example, if your query contains an exact-match retrieval, the optimizer may use hashed index access. If your query contains a range retrieval, the optimizer uses the sorted index. This strategy incurs the additional overhead of maintaining two indexes; however, you need to consider the advantages of fast retrieval against the disadvantages of updating two indexes for every change to data. See the Oracle Rdb Guide to Database Design and Definition for more information on the relative advantages of hashed and sorted indexes. If you specify a SORTED index, you can optionally specify NODE SIZE, PERCENT FILL, and USAGE clauses that control the characteristics of the nodes in the index.
7.3.38 – TYPE_IS_SORTED_RANKED
Specifies that the index is a sorted, ranked (B-tree) index. The ranked B-tree index allows better optimization of queries, particularly queries involving range retrievals. Oracle Rdb can make better estimates of cardinality, reducing disk I/O and lock contention. Oracle Rdb recommends using ranked sorted indexes.
7.3.39 – UNIQUE
A keyword that specifies whether or not each value of the index must be unique. If you try to store the same value twice in a column or set of columns that have an index defined as UNIQUE, SQL returns an error message the second time and does not store or modify the row that contains the value. This is true for null values as well as any other value. If you specify UNIQUE, SQL checks as it executes the CREATE INDEX statement to see if the table already contains duplicate values for the index.
7.3.40 – USAGE
Syntax options: USAGE UPDATE | USAGE QUERY Specifies a PERCENT FILL value appropriate for update- or query- intensive applications. The USAGE UPDATE clause sets the PERCENT FILL value at 70 percent. The USAGE QUERY clause sets the PERCENT FILL value at 100 percent.
7.3.41 – WITH_LIMIT_OF
Specifies the highest value for the index key that resides in a particular storage area if ASCENDING is defined. If DESCENDING is defined, the lowest value is specified for the index key that resides in a particular storage are. For multicolumn index keys, specify a literal value for each column. The number of literals in the list must be the same as the number of columns in the USING clause. Repeat this clause to partition the entries of an index among multiple storage areas. The data type of the literals must agree with the data type of the column. For character columns, enclose the literals in single quotation marks. If you are creating a multisegmented index using multisegmented keys and the STORE USING . . . WITH LIMIT clause, and if the values for the first key are all the same, then set the limit for the first key at that value. This ensures that the value of the second key determines the storage area in which each row is stored.
7.4 – Examples
Example 1: Creating a simple table index This statement names the index (EMP_EMPLOYEE_ID) and names the column to serve as the index key (EMPLOYEE_ID). The UNIQUE argument causes SQL to return an error message if a user tries to store an identification number that is already assigned. SQL> CREATE UNIQUE INDEX EMP_EMPLOYEE_ID ON EMPLOYEES cont> (EMPLOYEE_ID); Example 2: Creating an index with descending index segments This statement names the index (EMP_EMPLOYEE_ID) and names the column to serve as the descending index key (EMPLOYEE_ID DESCENDING). The DESCENDING keyword causes the keys to be sorted in descending order. If you do not specify DESCENDING or ASCENDING, SQL sorts the keys in ascending order. SQL> CREATE UNIQUE INDEX EMP_EMPLOYEE_ID ON EMPLOYEES cont> (EMPLOYEE_ID DESCENDING); Example 3: Creating a multisegmented index SQL> CREATE INDEX EMP_FULL_NAME ON EMPLOYEES cont> (LAST_NAME, cont> FIRST_NAME, cont> MIDDLE_INITIAL); This statement names three columns to be used in the index EMP_ FULL_NAME. SQL concatenates these three columns to make the multisegmented index. Example 4: Creating a compressed numeric index SQL> CREATE INDEX YEAR1_IND ON DEGREES cont> (YEAR_GIVEN ASCENDING MAPPING VALUES 1950 TO 1970); This statement creates ascending index segments for the YEAR_ GIVEN column in the DEGREES table, compressing the year values. Example 5: Creating a truncated text index SQL> CREATE INDEX COL_NAME_IND ON COLLEGES cont> (COLLEGE_NAME SIZE IS 20); This statement creates a compressed index, COL_NAME_IND, on the COLLEGES table so that the number of octets from the COLLEGE_NAME column that are used as a key cannot exceed 20 octets. Example 6: Creating an index in a uniform storage area with thresholds. SQL> ALTER DATABASE FILENAME mf_personnel cont> ADD STORAGE AREA UNIFORM1 PAGE FORMAT IS UNIFORM; SQL> ALTER DATABASE FILENAME mf_personnel cont> ADD STORAGE AREA UNIFORM2 PAGE FORMAT IS UNIFORM; SQL> ATTACH 'FILENAME mf_personnel'; SQL> CREATE UNIQUE INDEX EMP_THRESHOLDS ON EMPLOYEES (EMPLOYEE_ID) cont> TYPE IS SORTED cont> STORE USING (EMPLOYEE_ID) cont> IN RDB$SYSTEM (THRESHOLDS ARE (60,75,90)) cont> WITH LIMIT OF ('00200') cont> IN UNIFORM1 (THRESHOLD IS (65)) cont> WITH LIMIT OF ('00400') cont> OTHERWISE IN UNIFORM2 cont> (THRESHOLD OF (90)); %RDB-W-META_WARN, metadata successfully updated with the reported warning -RDMS-W-IDXCOLEXIST, an index with this column list already exists SQL> -- SQL> SHOW INDEX EMP_THRESHOLDS Indexes on table EMPLOYEES: EMP_THRESHOLDS with column EMPLOYEE_ID No Duplicates allowed Type is Sorted Key suffix compression is DISABLED Node size 430 Store clause: STORE USING (EMPLOYEE_ID) IN RDB$SYSTEM (THRESHOLDS ARE (60,75,90)) WITH LIMIT OF ('00200') IN UNIFORM1 (THRESHOLD IS (65)) WITH LIMIT OF ('00400') OTHERWISE IN UNIFORM2 (THRESHOLD OF (90)) This statement uses the STORE clause to partition the index into different uniform page format storage areas and apply thresholds. In Examples 7 and 8, the table COLOURS in the database MIA_CHAR_ SET is defined as: SQL> CREATE TABLE COLOURS cont> (ENGLISH MCS_DOM, cont> FRENCH MCS_DOM, cont> JAPANESE KANJI_DOM, cont> ROMAJI DEC_KANJI_DOM, cont> KATAKANA KATAKANA_DOM, cont> HINDI HINDI_DOM, cont> GREEK GREEK_DOM, cont> ARABIC ARABIC_DOM, cont> RUSSIAN RUSSIAN_DOM); Example 7: Creating a simple table index using the octets character length, which is the default SQL> SET CHARACTER LENGTH 'OCTETS'; SQL> CREATE INDEX COLOUR_INDEX ON COLOURS (JAPANESE SIZE IS 4) cont> TYPE IS SORTED; SQL> SHOW INDEX COLOUR_INDEX; Indexes on table COLOURS: COLOUR_INDEX with column JAPANESE size of index key is 4 octets Duplicates are allowed Type is Sorted The previous statement creates a compressed index key of 4 octets. Example 8: Creating an index using the CHARACTERS character length SQL> SET CHARACTER LENGTH 'CHARACTERS'; SQL> CREATE INDEX COLOUR_INDEX_2 ON COLOURS (JAPANESE SIZE IS 4) cont> TYPE IS SORTED; SQL> SHOW INDEX COLOUR_INDEX_2; Indexes on table COLOURS: COLOUR_INDEX_2 with column JAPANESE size of index key is 4 characters Duplicates are allowed Type is Sorted The previous statement creates a compressed index key of 4 characters. Example 9: Creating an index that enables compression The following example shows how to create an index and enable compression with a minimum run length of 2: SQL> CREATE INDEX EMP_NDX ON EMPLOYEES cont> (EMPLOYEE_ID SIZE IS 4) cont> ENABLE COMPRESSION (MINIMUM RUN LENGTH 2); SQL> SHOW INDEX EMP_NDX; Indexes on table EMPLOYEES: EMP_NDX with column EMPLOYEE_ID size of index key is 4 Duplicates are allowed Type is Sorted Compression is ENABLED (Minimum run length 2) Example 10: Using the Index Attributes Clause SQL> CREATE UNIQUE INDEX JOB_JOB_CODE cont> ON JOBS ( cont> JOB_CODE cont> ASC) cont> TYPE IS SORTED cont> THRESHOLDS ARE (75,83,90) cont> ENABLE COMPRESSION cont> NOLOGGING cont> COMMENT IS 'Used for translation of job codes'; %RDB-W-META_WARN, metadata successfully updated with the reported warning -RDMS-W-DATACMIT, unjournaled changes made; database may not be recoverable SQL> -- SQL returned this message because the NOLOGGING attribute SQL> -- was set. Example 11: Creating an Index and Displaying the Default Node Size SQL> -- Create a simple table upon which to define SQL> -- some indexes SQL> SQL> CREATE TABLE TEST_INDEX_TABLE cont> (A CHAR(70), cont> B INTEGER); SQL> SQL> -- Default value is 430 bytes SQL> SQL> CREATE UNIQUE INDEX TEST_INDEX_DEF cont> ON TEST_INDEX_TABLE (A, B) cont> TYPE IS SORTED cont> USAGE UPDATE; SQL> SQL> SHOW TABLE (INDEX) TEST_INDEX_TABLE Information for table TEST_INDEX_TABLE TEST_INDEX_DEF with column A and column B No Duplicates allowed Type is Sorted Compression is DISABLED Node size 430 Percent fill 70 Example 12: Naming Partitions SQL> -- Alter mf_personnel database to add three slots SQL> -- for storage areas and then add three storage areas. SQL> ALTER DATABASE FILENAME MF_PERSONNEL cont> RESERVE 3 STORAGE AREAS; %RDMS-W-DOFULLBCK, full database backup should be done to ensure future recovery SQL> ALTER DATABASE FILENAME MF_PERSONNEL cont> ADD STORAGE AREA WAGE_LOW; SQL> ALTER DATABASE FILENAME MF_PERSONNEL cont> ADD STORAGE AREA WAGE_MID; SQL> ALTER DATABASE FILENAME MF_PERSONNEL cont> ADD STORAGE AREA WAGE_HIGH; SQL> ATTACH 'FILENAME MF_PERSONNEL.RDB'; SQL> -- Create an index on the JOBS table and name the partitions SQL> CREATE INDEX WAGE_CLASS_IDX ON JOBS (WAGE_CLASS) cont> TYPE IS SORTED cont> STORE USING (WAGE_CLASS) cont> IN WAGE_LOW (PARTITION WAGE_LOW) WITH LIMIT OF ('1') cont> IN WAGE_MID (PARTITION WAGE_MID) WITH LIMIT OF ('3') cont> OTHERWISE IN WAGE_HIGH (PARTITION WAGE_HIGH); Example 13: Creating a Large Index Partitioned Across Many Storage Areas First, create the database definition: SQL> CREATE INDEX ... MAINTENANCE IS ENABLED DEFERRED ...; Next submit batch jobs to build each partition in parallel. For example, each batch job would execute a script similar to the following: ATTACH 'filename testdatabase'; SET FLAGS 'index_stats'; ALTER INDEX TRANSACTIONS_INDEX BUILD PARTITION PART_1; COMMIT; Finally, after the batch jobs have completed, the database administrator must make the index active for query usage by changing the maintenance mode to ENABLED IMMEDIATE. A BUILD ALL PARTITIONS clause could be added in case any step failed (possibly due to resource limitations or a failed node). SQL> SET FLAGS 'index_stats'; SQL> SET TRANSLATION READ WRITE RESERVING...FOR EXCLUSIVE WRITES; SQL> ALTER INDEX ... BUILD ALL PARTITIONS; SQL> ALTER INDEX ... MAINTENANCE IS ENABLED IMMEDIATE; SQL> COMMIT; This scheme has several advantages over issuing a CREATE INDEX statement directly: o The build actions can be run in parallel, which allows better resource usage (read and sort fewer rows), and reduced execution time for the index creation. o The partitions being processed are relatively small when compared to the full index and, therefore, smaller quantities of data will be processed. This will result in smaller .ruj files and less AIJ file space for these transactions. o Each build partition runs in a separate transaction, can easily be repeated if a step fails, and does not require repeating the entire CREATE INDEX statement. o If any steps have failed, they will also be repeated by the BUILD ALL PARTITIONS clause included in the script.
8 – MODULE
Defines a module as an object in an Oracle Rdb database. Stored with the module are its functions and procedures. A function or procedure written in SQL that resides with the data in a database is called a stored function or stored procedure. Likewise, a module stored in a database is called a stored module. A stored routine refers to either a stored procedure or stored function. You invoke a stored procedure with the CALL statement from a simple statement procedure in embedded SQL, SQL module language, or interactive SQL or with the CALL statement from within a compound statement. You invoke a stored function by specifying the function name in a value expression. SQL uses the concept of a module as its mechanism for storing, showing, deleting, and granting and revoking privileges on stored routines within a database. This means you cannot store, delete, or grant and revoke privileges on individual stored routines. Should you need to remove a stored routine, use the DROP FUNCTION routine-name CASCADE or DROP PROCEDURE routine-name CASCADE syntax. In general, SQL operates on modules, not stored routines. However, there are a few exceptions: DROP FUNCTION, DROP PROCEDURE, RENAME, SHOW FUNCTION, SHOW PROCEDURE, and CALL. The SHOW FUNCTION statement displays information about functions. The SHOW PROCEDURE statement displays individual procedures in a stored module. The CALL statement can invoke only a single stored procedure.
8.1 – Environment
You can use the CREATE MODULE statement in a simple statement procedure: o In interactive SQL o Embedded in host language programs to be precompiled o As part of a procedure in an SQL module o In dynamic SQL as a statement to be dynamically executed
8.2 – Format
(B)0[m[1;4mCREATE[m[1m [1;4mMODULE[m[1m q> <module-name> wqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqk [m [1m mq> [1;4mSTORED[m[1m [1;4mNAME[m[1m IS <stored-name> qj x [m [1mlqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqq<qqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1mmqwqqqqqqqqqqqqqqqqqqqwqqqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqqqqqqqqqqqk [m [1m mq> [1;4mLANGUAGE[m[1m [1;4mSQL[m [1mqqqj[m [1m mq> [1;4mAUTHORIZATION[m[1m <auth-id> qj x [m [1mlqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1mmwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqwqqqqqqqqqqqqqqqqqqqqwqqqqqqqqk [m [1m mq> [1;4mCOMMENT[m[1m [1;4mIS[m[1m qwq> 'string' qqqwqj mq> declare-clause qqj x [m [1m mqqqqqq / <qqqqqj x [m [1mlqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1mmqwq> routine-clause qqqwqq> [1;4mEND[m[1m [1;4mMODULE[m[1m qqq> [m [1m mqqqqqqqq <qqqqqqqqqqqj [m [1m [m (B)0[m[1mdeclare-clause = [m [1m [m [1mqqwqwq> declare-transaction-statement qqqqqqqqqqqwqwqq> [m [1m x tq> declare-local-temporary-table-statement qu x [m [1m x mq> declare-variable-statement qqqqqqqqqqqqqqj x [m [1m mqqqqqqqqqqqqqqqqqqqqqq<qqqqqqqqqqqqqqqqqqqqqqqqqj [m (B)0[m[1mroutine-clause = [m [1m [m [1mqw> [1;4mPROCEDURE[m[1m <procedure-name> wqwqqqqqqqqqqqqqqqqqqq> qqqqqqqqqqqwk [m [1m m> [1;4mFUNCTION[m[1m <function-name> qqj m> [1;4mSTORED[m[1m [1;4mNAME[m[1m IS <stored-name> qjx [m [1mlqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqq <qqqqqqqqqqqqqqqqqqqqqqqj [m [1mmqqqwqqqqqqqqqqqqqqqqqqqq> qqqqqqqqqqqqqqqqqqqqqwqqqk [m [1m mqq> ( qwqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqq ) qj x [m [1m mwq> parameter-decl[m [1mqqqqqqqqwj x [m [1m mqqqqqqqqqqq , <qqqqqqqqqqqj x [m [1mlqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1mmwqqqqqqqqqqqqqqqqqqqqqqqqqqqqwwqqqqqqqqqqqqqqqqqqqqqqwqqqqqqqqqk[m [1m m> [1;4mRETURNS[m[1m result-data-type qjm[mqqq> [1mfunction-attr qqqj[m [1m [m [1m x[m [1mlqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqq <qqqqqqqqqqqqqqqqqqqj[m [1mmwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwq> ; qwq> compound-statement qqqqqw> ; qq>[m [1mm> routine-attr [mqqqqqqqqqqqqqqqqq[1mj[m [1m [m [1mtq> compound-use-statement qu [m [1m [m [1mmq> external-body-clause qqqj[m (B)0[m[1mparameter-decl = [m [1m [m [1mqqwqqqqqqqqqqwwqqqqqqqqqqqqqqqqqqqqqwwq> data-type qqqqqwqqqk [m [1m tq> [1;4mIN[m[1m qqqqumq> <parameter-name> qjmq> <domain-name> qj x [m [1m tq> [1;4mOUT[m[1m qqqu[m [1m [m [1m [m [1m [m [1mx[m [1m [m [1m mq> [1;4mINOUT[m[1m qj[m [1m [m [1mx [m [1m [m [1mlqqqqqqqqqqqqqqqqqqqqqqqqqqqqqq<qqqqqqqqqqqqqqqqqqqqqqqqqqj[m [1mmqwqqqqqqqqqqqqqqqqqqqqqwqwqqqqqqqqqqqqqqqqqqqqqqqwqqqqqqqk[m [1mmq> mechanism-clause qj[m [1mmq> [1;4mDEFAULT[m[1m value-expr qj[m [1mx[m [1mlqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj[m [1m mqqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqqqqqqqqqqqqqqqqqqqqqqqqq> [m [1m mq> [1;4mCOMMENT[m[1m [1;4mIS[m[1m qwq> 'string' qqqwj [m [1m [m [1mmqqqqqq / <qqqqqj[m (B)0[m[1mfunction-attr =[m [1m [m [1mqwwqqqqqqqqwqwq> [1;4mVARIANT[m[1m qqqqqqqwwq> [m [1mxmq> [1;4mNOT[m[1m qj mq> [1;4mDETERMINISTIC[m[1m qjx[m [1m mqq> [1;4mLANGUAGE[m[1m [1;4mSQL[m[1m qqqqqqqqqqqqqqj[m [1m [m (B)0[m[1mroutine-attr =[m [1mqqwq> [1;4mCOMMENT[m[1m IS qqwq> 'string' qqwqwqq>[m [1mx[m [1mmqqqqqq[m [1m,[m [1m<qqqqj[m [1mx[m [1mmq> [1;4mUSAGE[m[1m IS qwq> [1;4mLOCAL[m [1mqqqwqqqqqqj[m [1mmq>[m [1;4mGLOBAL[m[1m qqj[m
8.3 – Arguments
8.3.1 – AUTHORIZATION auth id
A name that identifies the definer of a module and is used to perform privilege validation for the module. the User_Supplied_ Names HELP topic for information about using authorization identifiers.
8.3.2 – COMMENT_IS
Adds a comment about the module, routine, and parameter. SQL displays the text of the comment when it executes a SHOW MODULE, SHOW FUNCTION, or SHOW PROCEDURE statement. Enclose the comment in single quotation marks (') and separate multiple lines in a comment with a slash mark (/).
8.3.3 – compound-statement
Allows you to include more than one SQL statement in a stored routine. See the Compound_Statement HELP topic for more information.
8.3.4 – compound-use-statement
Allows you to include one SQL statement in a stored routine. See the Compound_Statement HELP topic for more information. If you are defining a stored function, the simple statement must be the RETURNS clause.
8.3.5 – data-type
A valid SQL data type. Specifying an explicit data type is an alternative to specifying a domain name. See the Data_Types HELP topic for more information on data types.
8.3.6 – decl-local-temp-table-statement
Declares a local temporary table for the module. See the DECLARE LOCAL_TEMPORARY_TABLE statement for more information.
8.3.7 – declare-transaction-statement
Declares a transaction for the module. Only one declare- transaction-statement is permitted for each module. If omitted, an implicit DECLARE TRANSACTION READ WRITE is used. See the DECLARE TRANSACTION statement for more information.
8.3.8 – declare-variable-statement
Declares a global variable for the module. See the statement DECLARE Variable for more information.
8.3.9 – DEFAULT value-expr
Specifies the default value of a parameter for a function or procedure defined with mode IN. If you omit this parameter or if the Call statement argument list or function invocation specifies the DEFAULT keyword, then the value-expr specified with this clause is used. The parameter uses NULL as the default if you do not specify a value expression explicitly.
8.3.10 – DETERMINISTIC
Syntax options: DETERMINISTIC | NOT DETERMINISTIC The clause controls the evaluation of an external function in the scope of a query: o NOT DETERMINISTIC Specifying the NOT DETERMINISTIC clause forces evaluation of corresponding functions (in scope of a single query) every time the function appears. If a function can return a different result each time it is invoked, you should use the DETERMINISTIC clause. o DETERMINISTIC Specifying the DETERMINISTIC clause can result in a single evaluation of corresponding function expressions (in scope of a single query), and the resulting value is used in all occurrences of the corresponding function expression. When you use the DETERMINISTIC clause, Oracle Rdb evaluates whether or not to invoke the function each time it is used. For example: SELECT * FROM T1 WHERE F1() > 0 AND F1() < 20; If you define the F1 function as DETERMINISTIC, the function F1() may be evaluated just once depending on the optimizer. If you define the F1 function as NOT DETERMINISTIC, the function F1() is evaluated twice. DETERMINISTIC is the default. The DETERMINISTIC or NOT DETERMINISTIC clause is not allowed on procedure definitions.
8.3.11 – domain-name
The name of a domain created in a CREATE DOMAIN statement. For more information about domains, see the CREATE DOMAIN statement.
8.3.12 – DEFAULT value-expr
Specifies the default value of a parameter for a function or procedure defined with mode IN. If you omit this parameter or if the Call statement argument list or function invocation specifies the DEFAULT keyword, then the value-expr specified with this clause is used. The parameter uses NULL as the default if you do not specify a value expression explicitly.
8.3.13 – FUNCTION function-name
A user-supplied name that you give to a function in a module. The name you specify must be unique within the database definition.
8.3.14 – IN parameter name
Specifies the parameter modes used in the procedure. The IN parameter names the parameter that is read into the routine, however is never set and cannot be written to. The IN parameter is the only mode allowed for functions. Each parameter name must be unique within the routine.
8.3.15 – INOUT parameter name
Specifies the parameter modes used in the procedure. The INOUT parameter names a parameter that inputs data (is read) as well as receives data (is set). The INOUT parameter is a parameter that is modified. Each parameter name must be unique within the procedure. You cannot use the INOUT parameter mode for stored functions.
8.3.16 – LANGUAGE_SQL
The LANGUAGE keyword and the SQL argument signify that the procedures in a module are to be invoked by SQL statements, not a host language program. With unstored procedures, the LANGUAGE keyword specifies the name of a host language; this identifies the host language in which the program calling a module's procedures is written. Beginning with Oracle Rdb Release 7.1, this clause is optional.
8.3.17 – module-name
A user-supplied name that you assign to a module. See the User_Supplied_Names HELP topic for more information on user-supplied names.
8.3.18 – OUT parameter name
Specifies the parameter modes used in the procedure. The OUT parameter names the parameter into which data is being sent. The OUT parameter is set, but never read. Each parameter name must be unique within the procedure. You cannot use the OUT parameter mode for stored functions.
8.3.19 – parameter-decl
Specifies the parameters and parameter modes used in a stored or external routine.
8.3.20 – PROCEDURE procedure-name
A user-supplied name that you give to a procedure in a module. The name you specify must be unique within the database definition.
8.3.21 – RETURNS result data type
Specifies the data type or domain of the result of the function invocation. This clause is only valid when defining a function. You can only use the RETURNS clause when defining a function.
8.3.22 – routine-clause
The definition of a stored function or stored procedure created in a module.
8.3.23 – STORED_NAME_IS
Specifies a name that Oracle Rdb uses to access a module procedure or function created in a multischema database. Or specifies a name that Oracle Rdb uses to access a procedure or a function created in a stored module.
8.3.24 – USAGE_IS
Specifies how the function or procedure can be called: o USAGE IS GLOBAL indicates that the function or procedure can be called outside the current module. This is the default. o USAGE IS LOCAL specifies that the routine is restricted to references within the module. This clause is provided for compatibility with CREATE MODULE but is not allowed for CREATE FUNCTION or CREATE PROCEDURE.
8.3.25 – VARIANT
Syntax options: VARIANT | NOT VARIANT These clauses are synonyms for the DETERMINISTIC and NOT DETERMINISTIC clauses. The DETERMINISTIC clause indicates that the same inputs to the function will generate the same output. It is the same as the NOT VARIANT clause. The NOT DETERMINISTIC clause indicates that the output of the function does not depend on the inputs. It is the same as the VARIANT clause. This clause is deprecated. Use DETERMINISTIC instead.
8.3.26 – variant-clause
Syntax options: DETERMINISTIC | NOT DETERMINISTIC The clause controls the evaluation of an external function in the scope of a query: o NOT DETERMINISTIC Specifying the NOT DETERMINISTIC clause forces evaluation of corresponding functions (in scope of a single query) every time the function appears. If a function can return a different result each time it is invoked, you should use the DETERMINISTIC clause. o DETERMINISTIC Specifying the DETERMINISTIC clause can result in a single evaluation of corresponding function expressions (in scope of a single query), and the resulting value is used in all occurrences of the corresponding function expression. When you use the DETERMINISTIC clause, Oracle Rdb evaluates whether or not to invoke the function each time it is used. For example: SELECT * FROM T1 WHERE F1() > 0 AND F1() < 20; If you define the F1 function as DETERMINISTIC, the function F1() may be evaluated just once depending on the optimizer. If you define the F1 function as NOT DETERMINISTIC, the function F1() is evaluated twice. DETERMINISTIC is the default. The DETERMINISTIC or NOT DETERMINISTIC clause is not allowed on procedure definitions.
8.4 – Examples
Example 1: Creating a stored module and stored procedure The following example shows how to create a stored module and stored procedure using interactive SQL: SQL> CREATE MODULE testmod LANGUAGE SQL cont> PROCEDURE testproc; cont> COMMIT; cont> END MODULE; SQL> SHOW MODULE testmod Module name is: TESTMOD Source: TESTMOD LANGUAGE SQL Owner is: Module ID is: 1 Example 2: Creating a stored module with SQL module language The following code fragment shows how to create a stored module as part of a procedure in a nonstored module: PROCEDURE create_them SQLCODE; CREATE MODULE my LANGUAGE SQL AUTHORIZATION smith PROCEDURE p1 ( :x CHAR(5) ); BEGIN INSERT INTO s (snum) VALUES (:x); END; PROCEDURE p2 ( :y SMALLINT ); BEGIN SELECT STATUS INTO :y FROM s LIMIT TO 1 ROW; END; PROCEDURE p3 (:x INT, :y SMALLINT ); BEGIN INSERT INTO s (snum) VALUES (:x); SELECT STATUS INTO :y FROM s WHERE snum = :x; END; PROCEDURE p4 (:x CHAR(5), :y CHAR(20) ); BEGIN INSERT INTO s (snum,sname) VALUES (:x, :y); SELECT sname INTO :y FROM s WHERE snum = :x; END; END MODULE; Example 3: Creating a stored module containing a stored routines SQL> CREATE MODULE utility_functions cont> LANGUAGE SQL cont> -- cont> -- Define a stored procedure. cont> -- cont> PROCEDURE trace_date (:dt DATE); cont> BEGIN cont> TRACE :dt; cont> END; cont> -- cont> FUNCTION mdy (IN :dt DATE) RETURNS CHAR(10) cont> COMMENT 'Returns the date in month/day/year format'; cont> BEGIN cont> IF :dt IS NULL THEN cont> RETURN '**/**/****'; cont> ELSE cont> CALL trace_date (:dt); cont> RETURN CAST(EXTRACT(MONTH FROM :dt) AS VARCHAR(2)) || '/' || cont> CAST(EXTRACT(DAY FROM :dt) AS VARCHAR(2)) || '/' || cont> CAST(EXTRACT(YEAR FROM :dt) AS VARCHAR(4)); cont> END IF; cont> END; cont> END MODULE; Example 4: Using a stored function in a SELECT statement SQL> SELECT mdy(job_end), job_end cont> FROM job_history WHERE employee_id = '00164'; JOB_END **/**/**** NULL 9/20/1981 20-Sep-1981 2 rows selected Example 5: Using declared local temporary tables in stored procedures SQL> -- The following table must exist in order to execute the following SQL> -- queries. SQL> -- SQL> CREATE TABLE payroll cont> (employee_id CHAR(5), cont> hours_worked INTEGER, cont> hourly_sal REAL, cont> week_date CHAR(10)); SQL> COMMIT; SQL> -- SQL> -- Create the module containing a declared local temporary table. SQL> -- SQL> CREATE MODULE paycheck_decl_mod cont> LANGUAGE SQL cont> DECLARE LOCAL TEMPORARY TABLE module.paycheck_decl_tab cont> (employee_id ID_DOM, cont> last_name CHAR(14) , cont> hours_worked INTEGER, cont> hourly_sal INTEGER(2), cont> weekly_pay INTEGER(2)) cont> ON COMMIT PRESERVE ROWS cont> -- cont> -- Create the procedure to insert rows. cont> -- cont> PROCEDURE paycheck_ins_decl; cont> BEGIN cont> INSERT INTO module.paycheck_decl_tab cont> (employee_id, last_name, hours_worked, hourly_sal, weekly_pay) cont> SELECT p.employee_id, e.last_name, cont> p.hours_worked, p.hourly_sal, cont> p.hours_worked * p.hourly_sal cont> FROM employees e, payroll p cont> WHERE e.employee_id = p.employee_id cont> AND p.week_date = '1995-08-01'; cont> END; cont> -- cont> -- Create the procedure to count the low hours. cont> -- cont> PROCEDURE low_hours_decl (:cnt INTEGER); cont> BEGIN cont> SELECT COUNT(*) INTO :cnt FROM module.paycheck_decl_tab cont> WHERE hours_worked < 40; cont> END; cont> END MODULE; SQL> -- SQL> -- Call the procedure to insert the rows. SQL> -- SQL> CALL paycheck_ins_decl(); SQL> -- SQL> -- Declare a variable and call the procedure to count records with SQL> -- low hours. SQL> -- SQL> DECLARE :low_hr_cnt integer; SQL> CALL low_hours_decl(:low_hr_cnt); LOW_HR_CNT 2 SQL> -- SQL> -- Because the table is a declared local temporary table, you cannot SQL> -- access it from outside the stored module that contains it. SQL> -- SQL> SELECT * FROM module.paycheck_decl_tab; %SQL-F-RELNOTDCL, Table PAYCHECK_DECL_TAB has not been declared in module or environment Example 6: Creating a stored procedure containing a simple statement SQL> CREATE MODULE a cont> LANGUAGE SQL cont> PROCEDURE new_salary_proc cont> (:id CHAR (5), cont> :new_salary INTEGER (2)); cont> UPDATE salary_history cont> SET salary_end = CURRENT_TIMESTAMP cont> WHERE employee_id = :id; cont> END MODULE; Example 7: Declaring a Global Variable to Exchange Information Between Two Routines SQL> CREATE MODULE sample cont> LANGUAGE SQL cont> DECLARE :iter_count INTEGER cont> PROCEDURE set_iter (IN :val INTEGER) cont> COMMENT IS 'Validate the iteration count and assign' cont> / 'to a global variable.'; cont> BEGIN cont> IF (:val IS NULL) OR (:val < 1) THEN cont> SIGNAL 'XXXXX'; --illegal value cont> ELSE cont> SET :iter_count =:val; cont> TRACE 'Iteration count set to ', :val; cont> END IF; cont> END; cont> FUNCTION GET_ITER () cont> RETURNS INTEGER cont> COMMENT IS 'Trace the value used and then return the' cont> / 'value from the global variable.'; cont> BEGIN cont> TRACE 'Using iteration count ', :iter_count; cont> RETURN :iter_count; cont> END; cont> END MODULE; Example 8: Using a cursor implemented by external routines This example uses multiple external routines to manage a table cursor in the external routine database environment. This management includes the OPEN, FETCH and CLOSE of a single cursor. Several domains are defined so that parameter data types can be consistently defined in the database that contain the application and also the database upon which the cursor is open. create domain SQLSTATE_T char(5); create domain STATUS_CODE char(1); create domain STATUS_NAME char(8); create domain STATUS_TYPE char(14); The external function interface is contained within a single CREATE MODULE statement. This module also contains the application in a single stored SQL procedure. create module EX language SQL -- These procedure define the interface to the external -- routines that implement the transaction and cursor operations -- procedure EX_START_READ_TXN (inout :ss sqlstate_t); external location 'TEST$SCRATCH:EX.EXE' language general general parameter style comment is 'start a READ ONLY transaction'; procedure EX_COMMIT (inout :ss sqlstate_t); external location 'TEST$SCRATCH:EX.EXE' language general general parameter style; procedure EX_OPEN_CURSOR (inout :ss sqlstate_t); external location 'TEST$SCRATCH:EX.EXE' language general general parameter style comment is 'find all rows in WORK_STATUS order by STATUS_CODE'; procedure EX_CLOSE_CURSOR (inout :ss sqlstate_t); external location 'TEST$SCRATCH:EX.EXE' language general general parameter style; procedure EX_FETCH_CURSOR (inout :ss sqlstate_t, out :s_code STATUS_CODE, out :s_code_ind integer, out :s_name STATUS_NAME, out :s_name_ind integer, out :s_type STATUS_TYPE, out :s_type_ind integer); external location 'TEST$SCRATCH:EX.EXE' language general general parameter style; -- This SQL procedures implements a simple application -- procedure WORK_STATUS comment is 'Use an external cursor to fetch all rows in the' / 'WORK_STATUS table'; begin declare :s_code STATUS_CODE; declare :s_name STATUS_NAME; declare :s_type STATUS_TYPE; declare :s_code_ind, :s_name_ind, :s_type_ind integer; declare :ss sqlstate_t; -- start a read-only transaction on the PERSONNEL database call EX_START_READ_TXN (:ss); if :ss ^= '00000' then SIGNAL :ss; end if; -- open the cursor on the work-status table call EX_OPEN_CURSOR (:ss); if :ss ^= '00000' then SIGNAL :ss; end if; -- now loop and fetch all the rows FETCH_LOOP: loop call EX_FETCH_CURSOR (:ss, :s_code, :s_code_ind, :s_name, :s_name_ind, :s_type, :s_type_ind); case :ss when '02000' then -- no more rows to fetch leave FETCH_LOOP; when '00000' then begin -- we have successfully fetched a row, so display it trace 'Status Code: ', case when :s_code_ind < 0 then 'NULL' else :s_code end; trace 'Status Name: ', case when :s_name_ind < 0 then 'NULL' else :s_name end; trace 'Status Type: ', case when :s_type_ind < 0 then 'NULL' else :s_type end; trace '***'; end; else -- signal will implicitly leave the stored procedure SIGNAL :ss; end case; end loop; -- close the cursor call EX_CLOSE_CURSOR (:ss); if :ss ^= '00000' then SIGNAL :ss; end if; -- commit the transaction call EX_COMMIT (:ss); if :ss ^= '00000' then SIGNAL :ss; end if; end; end module; The external procedures for this this example are written using the SQL module language. However, any language with embedded SQL, such as C, could have been used. module EX language GENERAL parameter colons -- EX: Sample application -- Process the WORK_STATUS table using a table cursor -- declare alias filename 'PERSONNEL' declare c cursor for select status_code, status_name, status_type from WORK_STATUS order by status_code procedure EX_START_READ_TXN (sqlstate); begin -- abort any stray transactions rollback; -- start a READ ONLY transaction set transaction read only; end; procedure EX_COMMIT (sqlstate); commit work; procedure EX_ROLLBACK (sqlstate); rollback work; procedure EX_OPEN_CURSOR (sqlstate); open c; procedure EX_CLOSE_CURSOR (sqlstate); close c; procedure EX_FETCH_CURSOR (sqlstate, :s_code STATUS_CODE, :s_code_ind integer, :s_name STATUS_NAME, :s_name_ind integer, :s_type STATUS_TYPE, :s_type_ind integer); fetch c into :s_code indicator :s_code_ind, :s_name indicator :s_name_ind, :s_type indicator :s_type_ind; procedure EX_DISCONNECT (sqlstate); disconnect default; When run the application calls the external procedures to open the cursor and fetch the rows and display them using the TRACE statement. SQL> set flags 'trace'; SQL> SQL> call WORK_STATUS (); ~Xt: Status Code: 0 ~Xt: Status Name: INACTIVE ~Xt: Status Type: RECORD EXPIRED ~Xt: *** ~Xt: Status Code: 1 ~Xt: Status Name: ACTIVE ~Xt: Status Type: FULL TIME ~Xt: *** ~Xt: Status Code: 2 ~Xt: Status Name: ACTIVE ~Xt: Status Type: PART TIME ~Xt: *** SQL> Oracle recommends that the cursors be closed, and the external routines database environment be disconnected before the calling session is disconnected. This can be achieved by using NOTIFY routines. For example, the external procedure that starts the transaction could be modified as shown below to declare a NOTIFY routine (EX_ RUNDOWN) that when called would close the cursors, rollback the transaction and disconnect from the database. procedure EX_START_READ_TXN (inout :ss sqlstate_t); external location 'TEST$SCRATCH:EX.EXE' language general general parameter style notify EX_RUNDOWN on BIND comment is 'start a READ ONLY transaction'; The BIND notification ensures that EX_RUNDOWN will be called during the DISCONNECT of the caller and allow the transaction to be rolled back and the session disconnected. ROLLBACK or COMMIT will implicitly close any open cursors, unless the cursor were defined as WITH HOLD. In this case it is important to also close that cursor. Code similar to the following (in C) could implement this rundown routine. #include <string.h> #include <stdio.h> #define RDB$K_RTX_NOTIFY_ACTV_END 2 #define SQLSTATE_LEN 5 void sql_signal (); void EX_CLOSE_CURSOR (char sqlstate [SQLSTATE_LEN]); void EX_DISCONNECT (char sqlstate [SQLSTATE_LEN]); void EX_ROLLBACK (char sqlstate [SQLSTATE_LEN]); extern void EX_RUNDOWN (int *func_code, int *u1, /* U1, U2, U3 are currently unused */ int *u2, /* and are reserved for future use */ int *u3) { char sqlstate [SQLSTATE_LEN]; if (*func_code == RDB$K_RTX_NOTIFY_ACTV_END) { /* we are running down this external routine, so * close the cursor */ EX_CLOSE_CURSOR (sqlstate); if (memcmp ("00000", sqlstate, SQLSTATE_LEN) != 0 && memcmp ("24000", sqlstate, SQLSTATE_LEN) != 0) /* we expect success or maybe 24000 (bad cursor state) */ sql_signal (); /* rollback the transaction */ EX_ROLLBACK (sqlstate); if (memcmp ("00000", sqlstate, SQLSTATE_LEN) != 0 && memcmp ("25000", sqlstate, SQLSTATE_LEN) != 0) /* we expect success or maybe 25000 (bad transaction state) */ sql_signal (); /* disconnect from the database */ EX_DISCONNECT (sqlstate); if (memcmp ("00000", sqlstate, SQLSTATE_LEN) != 0) /* we expect success or maybe 25000 (bad transaction state) */ sql_signal (); } } The application can be compiled and built using this fragment of DCL code: $ create ex.opt symbol_vector = (EX_START_READ_TXN = procedure) symbol_vector = (EX_COMMIT = procedure) symbol_vector = (EX_ROLLBACK = procedure) symbol_vector = (EX_OPEN_CURSOR = procedure) symbol_vector = (EX_CLOSE_CURSOR = procedure) symbol_vector = (EX_FETCH_CURSOR = procedure) symbol_vector = (EX_DISCONNECT = procedure) symbol_vector = (EX_RUNDOWN = procedure) psect_attr = RDB$MESSAGE_VECTOR,noshr psect_attr = RDB$DBHANDLE,noshr psect_attr = RDB$TRANSACTION_HANDLE,noshr sql$user/library $ $ cc EX_RUNDOWN $ sql$mod EX $ link/share EX,EX_RUNDOWN,EX/option
9 – OUTLINE
Creates a new query outline and stores this outline in the database. A query outline is an overall plan for how a query can be implemented and may contain directives that control the join order, join methods, index usage (or all of these) the optimizer selects when processing a query. Use of query outlines helps ensure that query performance is highly stable across releases of Oracle Rdb.
9.1 – Environment
You can use the CREATE OUTLINE statement only in interactive SQL.
9.2 – Format
(B)0[m[1;4mCREATE[m[1m [1;4mOUTLINE[m[1m <outline-name> qwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwk[m [1m [m [1mm> [1;4mSTORED[m[1m [1;4mNAME[m [1mIS[m [1m<stored-name> qjx[m [1mlqqqqqqqqqqqqqqqqqqqqqqqqq[m [1m<qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj[m [1mmwq> [1;4mFROM[m[1m qq> ( qq> <sql-query> qq> ) qqqqqqqqqqwqqqqqqqqqk[m [1m tq> on-clause qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu [m [1m [m [1mx[m [1m mq> [1;4mID[m[1m 'id-number' qqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1m [m [1mx[m [1m lqqqqqqqqqqqqqqqqqqqqqqqqqqqqqq <qqqqqqqqqqqqqqqqqqqqqqqj[m [1m mqqqqqwqqqqqqqqqqqqwwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqqk[m [1m m> [1;4mMODE[m[1m mode jt> [1;4mAS[m[1m qqqw>( q> query-list q> )qqj[m [1mx[m [1m m> [1;4mUSING[m[1m j [m [1m [m [1mx[m [1mlqqqqqqqqqqqqqqqqqqqqqqqqqqq <qqqqqqqqqqqqqqqqqqqqqqqqqqqqj[m [1mmwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqqqqqqqqqqqqqqqqqqqqqqqqqqk[m [1m m> [1;4mCOMPLIANCE[m[1m qwq> [1;4mMANDATORY[m[1m qu [m [1mx[m [1m mq> [1;4mOPTIONAL[m[1m qqj [m [1mx[m [1mlqqqqqqqqqqqqqqqqqqqqqqqqqqq <qqqqqqqqqqqqqqqqqqqqqqqqqqqqj[m [1mmwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwk[m [1m m> [1;4mEXECUTION[m[1m [1;4mOPTIONS[m[1m qq> ( qq> execution-options qq> ) qjx[m [1mlqqqqqqqqqqqqqqqqqqqqqqqqqqq <qqqqqqqqqqqqqqqqqqqqqqqqqqqqj[m [1mmwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqq>[m [1m m> [1;4mCOMMENT[m[1m IS qqwq> 'string'[m [1mqqqwj [m [1m mqqqqq / <qqqqqqj [m (B)0[m[1mon-clause =[m [1mqqq> [1;4mON[m[1m qqwq> [1;4mPROCEDURE[m[1m qwqwq>[m [1;4mID[m[1m proc-id[m [1mqqqqwqwq>[m [1mtq> [1;4mFUNCTION[m [1mqqj[m [1mmq> [1;4mNAME[m[1m <name> qqqj x[m [1mtq>[m [1;4mCOLUMN[m [1mqqqqqqwqqqqq> <name> qqqqqqj[m [1mtq>[m [1;4mCONSTRAINT[m [1mqqu[m [1m [m [1mtq>[m [1;4mTRIGGER[m [1mqqqqqu[m [1mmq>[m [1;4mVIEW[m [1mqqqqqqqqj[m (B)0[m[1mquery-list = [m [1m [m [1mqqqwq> [1;4mQUERY[m[1m (source) qqqqqqqqqqwqqqqqqqqqq> [m [1m mqqqqqqqqqqqqq<qqqqqqqqqqqqqqj [m [1m [m (B)0[m[1msource = [m [1m [m [1mqwqwqqqqqqqqqqqqqwqqwq> table-access qqqqqqqqqqqqqqwqqwqqqqqqqq> [m [1m x mq> [1;4mFLOATING[m[1m qj tq> [1;4mORDERED[m[1m qqqwqq> (source) qqu x [m [1m x tq> [1;4mUNORDERED[m[1m qj x x [m [1m x mq> subquery-list qqqqqqqqqqqqqj x [m [1m x lqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1m x tq> [1;4mJOIN[m[1m BY qwqq> [1;4mCROSS[m[1m qqqqqqwqqq TO qqqqqwqqk [m [1m x x tqq> [1;4mMATCH[m[1m qqqqqqu x x [m [1m x x mqq> [1;4mANY[m[1m METHOD qj x x [m [1m x mq> [1;4mUNION[m[1m WITH qqqqqqqqqqqqqqqqqqqqqqqqqqqqj x [m [1m mqqqqqqqqqqqqqqqqqqqqqqqq<qqqqqqqqqqqqqqqqqqqqqqj [m [1m [m (B)0[m[1mtable-access = [m [1m [m [1mqqq> <table-name> qwqqqqqqqqqqqqqqqqqqqqqqqqqwq> context qqk [m [1m mq> [1;4mMODULE[m[1m <module-name> qj x [m [1mlqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1mmq> [1;4mACCESS[m[1m qq> PATH qqqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqqq> [m [1m tqq> [1;4mANY[m[1m qqqqqqqqqqqqqqqqqqqqqqu [m [1m tqq> [1;4mSEQUENTIAL[m[1m qqqqqqqqqqqqqqqu [m [1m tqq> [1;4mDBKEY[m[1m qqqqqqqqqqqqqqqqqqqqu [m [1m tqq> [1;4mROWID[m[1m qqqqqqqqqqqqqqqqqqqqu [m [1m tqq> [1;4mNO[m[1m [1;4mINDEX[m[1m qqqqqqqqqqqqqqqqqu [m [1m mqq> [1;4mINDEX[m[1m qw> <index-name> qqwj [m [1m mqqqqqq , <qqqqqqqj [m [1m [m (B)0[m[1msubquery-list = [m [1m [m [1mqqqwq> [1;4mSUBQUERY[m[1m (source) qqqqqqqwqqqqqqqqqq> [m [1m mqqqqqqqqqqqqq<qqqqqqqqqqqqqqj [m [1m [m (B)0[m[1mexecution-options = [m [1m [m [1mqwq> [1;4mANY[m[1m qqqqqqqqwqqqqqq> [m [1m tq> [1;4mNONE[m[1m qqqqqqqu [m [1m tq> [1;4mFAST[m[1m [1;4mFIRST[m[1m qu [m [1m mq> [1;4mTOTAL[m[1m [1;4mTIME[m[1m qj [m [1m [m
9.3 – Arguments
9.3.1 – ACCESS_PATH
Syntax options: ACCESS PATH ANY ACCESS PATH SEQUENTIAL ACCESS PATH DBKEY ACCESS PATH ROWID ACCESS PATH NO INDEX See also ACCESS_PATH_INDEX. Specifies the access path to use to retrieve data from the underlying database table. The following table lists the valid access paths. Path Meaning ANY Indicates that the optimizer may choose the most appropriate method. SEQUENTIAL Indicates that sequential access should be used. DBKEY Indicates the access by database key should be used. ROWID Indicates the access by database key should be used. NO INDEX Indicates that any access path not requiring an index can be used. NOINDEX is accepted as a synonym for NO INDEX. There is no default access path. An access path must be specified for each database table specified within a query outline definition.
9.3.2 – ACCESS_PATH_INDEX
Specifies that data should be retrieved using the specified index or list of indexes. If more that one index can be used, then separate each index name with a comma. Any index name specified should indicate an existing index associated with the table with which the access method is associated.
9.3.3 – AS query list
Provides the main definition of an outline. This clause is only required when creating an outline using the ID id-number clause.
9.3.4 – COMMENT_IS
Adds a comment about the outline. SQL displays the text when it executes a SHOW OUTLINES statement in interactive SQL. Enclose the comment in single quotation marks ( ') and separate multiple lines in a comment with a slash mark (/).
9.3.5 – COMPLIANCE
Syntax options: COMPLIANCE MANDATORY | COMPLIANCE OPTIONAL Specifies the compliance level for this outline. MANDATORY indicates that all outline directives such as table order and index usage should be followed as specified. If the optimizer is unable to follow any outline directive, an exception is raised. OPTIONAL indicates that all outline directives are optional and that if they cannot be followed, no exception should be raised. If OPTIONAL is specified, the strategy chosen by the optimizer to carry out the underlying request may not match the strategy specified within the outline. Use MANDATORY when the strategy that the optimizer chooses must be followed exactly as specified from version to version of Oracle Rdb even if the optimizer finds a more efficient strategy in a future version of Oracle Rdb. The default is COMPLIANCE OPTIONAL.
9.3.6 – context
Specifies the context number for this table. Specify an unsigned integer. This number is allocated to the table by the optimizer during optimization. Context numbers are unique within queries.
9.3.7 – EXECUTION_OPTIONS
Specifies options that the optimizer should take into account during optimization. The following table lists the valid options. Option Meaning ANY Indicates that the optimizer can choose any optimization method FAST FIRST Indicates that the optimizer can use FAST FIRST optimization if and when appropriate NONE Indicates that optional optimizations should not be applied TOTAL TIME Indicates that the optimizer can use TOTAL TIME optimization if and when appropriate The default is EXECUTION OPTIONS (ANY).
9.3.8 – FLOATING
Specifies that the following data source should be considered to be floating and that the order of the data source relative to the other data sources within the same level is not fixed.
9.3.9 – FROM sql query
Enables an outline to be created directly from an SQL statement. If the AS clause is not specified, the sql-query is compiled and the resulting outline is stored. If the AS clause is specified, the sql-query provides an alternate means of specifying the ID. If the USING clause is specified, the sql-query is optimized using the designated outline as a starting point. The only statement accepted as an sql-query in the FROM clause is a SELECT statement. Do not end the sql-query with a semicolon.
9.3.10 – ID id number
Specifies the internal hash identification number of the request to which this outline should be applied. Specify a 32-byte string representing a 32-hexadecimal character identification code. The internal hash identification code is generated by the optimizer whenever query outlines are created by the Oracle Rdb optimizer during optimization. You can optionally specify the MODE clause. You are required to specify the AS clause. You cannot specify the USING clause with the ID id-number clause.
9.3.11 – JOIN_BY
Syntax options: JOIN BY CROSS JOIN BY MATCH JOIN BY ANY METHOD Specifies the method with which two data sources should be joined. The following table lists the valid methods. Method Meaning CROSS Indicates that a cross strategy should be used MATCH Indicates that a match strategy should be used ANY METHOD Indicates that the optimizer can choose any method to join the two data sources NOTE The match join strategy requires that an equivalent join column exist between the inner and outer context of the join order. If the query for which the outline is created does not have an equivalent join column, then the optimizer cannot use the match join strategy specified in the outline. There is no default join method.
9.3.12 – MODE mode
Mode is a value assigned to an outline when it is generated by the optimizer. The default mode is 0. Specify a signed integer. If you create multiple outlines for a single query, the outlines cannot have the same outline mode. When more than one outline exists for a query, you can set the RDMS$BIND_OUTLINE_MODE logical name to the value of the outline mode for the outline you want the optimizer to use. For example, if you have a query that runs during the day and at night and you created two outlines for the query, you could keep the default outline mode of 0 for the outline to be used during the day, and assign an outline mode of -1 for the outline to be used at night. By setting the RDMS$BIND_ OUTLINE_MODE logical name to -1 at night, the appropriate outline is run at the appropriate time. Valid values for modes are -2,147,483,648 to 2,147,483,647. Positive mode values are reserved for future use, so it is recommended that you specify a value between 0 and -2,147,483,648 for the mode value.
9.3.13 – MODULE module name
Associates an outline with a declared local temporary table by qualifying the table name with the name of the stored module. In order to apply the outline to the declared local temporary table, the keyword MODULE is required.
9.3.14 – ON_COLUMN
Syntax options: ON COLUMN name Generates an outline for the specified columns DEFAULT, COMPUTED BY or AUTOMATIC expression. This is a partial outline which will be used when the column is referenced. If a column has both an AUTOMATIC UPDATE AS clause and a DEFAULT expression, then only one outline is created for the AUTOMATIC clause.
9.3.15 – ON_CONSTRAINT
Syntax options: ON CONSTRAINT name Generates an outline definition for the specified constraint.
9.3.16 – ON_FUNCTION
Syntax options: ON FUNCTION ID proc-id | ON FUNCTION NAME name Generates an outline definition for the specified stored function.
9.3.17 – ON_PROCEDURE
Syntax options: ON PROCEDURE ID proc-id | ON PROCEDURE NAME name Generates an outline definition for the specified stored procedure.
9.3.18 – ON_TRIGGER
Syntax options: ON TRIGGER name Generates an outline definition for the specified trigger.
9.3.19 – ON_VIEW
Syntax options: ON VIEW name Generates an outline definition for the specified view.
9.3.20 – ORDERED
Specifies that all nonfloating data sources within the parentheses should be retrieved in the order specified. Join items in the group are placed adjacently.
9.3.21 – outline-name
The name of the new query outline. The name has a maximum length of 31 characters.
9.3.22 – QUERY
Specifies that the data sources within the parentheses belong to a separate query.
9.3.23 – SUBQUERY
Specifies that the data sources within the parentheses belong to a separate subquery.
9.3.24 – table-name
Specifies the name of a database table.
9.3.25 – UNION_WITH
Specifies the union of two data sources. Either a join or union method must be specified between all data sources with the exception of QUERY source blocks. NOTE When a join method appears immediately before an ordered or unordered group, the join method is associated with the first join item named in the group. The union strategy is only valid for queries that use the UNION operator, and all queries that specify the UNION operator must use the union strategy.
9.3.26 – UNORDERED
Specifies that all data sources within the parentheses should be considered floating and that no order is implied. Join items in the group are placed adjacently.
9.3.27 – USING query list
Specifies the outline to be used for compilation of the contents of the FROM and ON clauses. You cannot use this clause with the ID id-number clause.
9.4 – Examples
Example 1: Creating an outline named AVAILABLE_EMPLOYEES SQL> CREATE OUTLINE available_employees cont> ID '09ADFE9073AB383CAABC4567BDEF3832' MODE 0 cont> AS ( cont> QUERY ( cont> -- cont> -- Cross the employees table with departments table first. cont> -- cont> employees 0 ACCESS PATH SEQUENTIAL JOIN BY MATCH TO cont> departments 3 ACCESS PATH INDEX dept_index JOIN BY MATCH TO cont> SUBQUERY ( cont> job_fitness 2 ACCESS PATH INDEX job_fit_emp, job_fit_dept cont> JOIN BY CROSS TO cont> SKILLS 4 ACCESS PATH ANY cont> ) JOIN BY MATCH TO cont> SUBQUERY ( cont> major_proj 1 ACCESS PATH ANY JOIN BY CROSS TO cont> education 6 ACCESS PATH ANY cont> ) JOIN BY CROSS TO cont> research_projects 5 ACCESS PATH ANY UNION WITH cont> -- cont> -- Always do the union with employees table last cont> -- cont> employees 7 ACCESS PATH ANY cont> ) cont> ) cont> COMPLIANCE OPTIONAL cont> COMMENT IS 'Available employees'; Example 2: Creating an outline using the FROM clause SQL> CREATE OUTLINE degrees_for_emps_over_65 cont> FROM cont> (SELECT e.last_name, e.first_name, e.employee_id, cont> d.degree, d.year_given cont> FROM employees e, degrees d cont> WHERE e.birthday < '31-Dec-1930' cont> AND e.employee_id = d.employee_id cont> ORDER BY e.last_name) cont> USING cont> (QUERY cont> (SUBQUERY cont> (degrees 1 ACCESS PATH SEQUENTIAL cont> JOIN BY CROSS TO cont> employees 0 ACCESS PATH ANY cont> ) cont> ) cont> ) cont> COMPLIANCE OPTIONAL cont> COMMENT IS 'Outline to find employees over age 65 with college degrees'; SQL> -- SQL> SHOW OUTLINE degrees_for_emps_over_65 DEGREES_FOR_EMPS_OVER_65 Comment: Outline to find employees over age 65 with college degrees Source: -- Rdb Generated Outline : 13-NOV-1995 15:28 create outline DEGREES_FOR_EMPS_OVER_65 id 'B6923A6572B28E734D6F9E8E01598CD8' mode 0 as ( query ( subquery ( DEGREES 1 access path sequential join by cross to EMPLOYEES 0 access path index EMPLOYEES_HASH ) ) ) compliance optional ; Example 3: Creating an outline using the ON FUNCTION clause SQL> CREATE OUTLINE out1 cont> ON FUNCTION NAME function1; SQL> COMMIT; SQL> SHOW OUTLINE out1 OUT1 Source: -- Rdb Generated Outline : 2-FEB-1996 15:46 create outline OUT1 id '264A6DDADCB483AE5B2CDF629C9C8C0F' mode 0 as ( query ( subquery ( EMPLOYEES 0 access path index EMPLOYEES_HASH ) ) ) compliance optional ; Example 4: Creating an outline on a procedure that accesses a declared local temporary table (see the CREATE MODULE statement for the stored procedure and temporary table definition) SQL> CREATE OUTLINE outline1 cont> ON PROCEDURE NAME paycheck_ins_decl cont> MODE 0 cont> AS ( cont> QUERY ( cont> module.paycheck_decl_tab MODULE paycheck_decl_mod cont> 0 cont> ACCESS PATH SEQUENTIAL cont> ) cont> ) cont> COMPLIANCE OPTIONAL; SQL> SHOW OUTLINE outline1 OUTLINE1 Source: create outline OUTLINE1 mode 0 as ( query ( PAYCHECK_DECL_TAB MODULE PAYCHECK_DECL_MOD 0 access path sequential ) ) compliance optional ; Example 5: New Output from Query Outlines SQL> BEGIN cont> DECLARE :x INTEGER; cont> -- Assignment cont> SET :x = (SELECT COUNT(*) FROM TOUT_1); cont> -- Delete statement cont> DELETE FROM TOUT_1; cont> -- Update statement cont> UPDATE TOUT_1 cont> SET a = (SELECT AVG(a) FROM TOUT_2) cont> WHERE a IS NULL; cont> -- Singleton Select cont> SELECT a INTO :x cont> FROM TOUT_1 cont> WHERE a = 1; cont> -- Trace (nothing if TRACE is disabled) cont> TRACE 'The first value: ', (SELECT a FROM TOUT_1 LIMIT TO 1 ROW); cont> END; The query outline generated by Oracle Rdb appears with comments after the QUERY keyword in the outline. -- Rdb Generated Outline : 29-MAY-1997 23:17 create outline QO_C11395E6020C6FFA_00000000 id 'C11395E6020C6FFA5A183A6CCE7C1F33' mode 0 as ( query ( -- Set subquery ( TOUT_1 0 access path sequential ) ) query ( -- Delete subquery ( TOUT_1 0 access path sequential ) ) query ( -- Update subquery ( subquery ( TOUT_2 1 access path sequential ) join by cross to subquery ( TOUT_1 0 access path sequential ) ) ) query ( -- Select subquery ( TOUT_1 0 access path sequential ) ) query ( -- Trace subquery ( TOUT_1 0 access path sequential ) ) ) compliance optional ;
10 – PROCEDURE
Creates an external procedure as a schema object in an Oracle Rdb database. The CREATE PROCEDURE statement is documented under the CREATE Routine. For complete information on creating an external procedure definition, see the CREATE Routine Help topic.
11 – PROFILE
Creates a profile that extends a user definition within the database with special attributes that control transactions and resource usage. When a user attaches to the database using ATTACH, CONNECT or SET SESSION AUTHORIZATION, they will either load their assigned profile definition or inherit the default profile (if defined).
11.1 – Environment
You can use the CREATE PROFILE statement: o In interactive SQL o Embedded in host language programs o As part of a procedure in an SQL module or other compound statement o In dynamic SQL as a statement to be dynamically executed
11.2 – Format
(B)0[m[1;4mCREATE[m[1m qwqq> [1;4mPROFILE[m [1mqq> <profilename> qqqqqqqqqqqqqwqqwq>[m [1mprofile-options[m [1mqwq>[m [1m mqq>[m [1;4mDEFAULT[m[1m [1;4mPROFILE[m[1m qwqqqqqqqqqqqqqqqqqqqqwj mqqqqqqqqq<qqqqqqqqqqj[m [1m [m [1mm>[m [1;4mALIAS[m[1m aliasname [m [1mqj[m (B)0[m[1mprofile-options =[m [1mqqwq>[m [1;4mCOMMENT[m [1mIS[m [1mqwq>[m [1mchar-literal qqwqqqqqqqqqqqqqqqqqqqqw>[m [1mx[m [1mmqqqqqqq /[m [1m<qqqqqqqj[m [1mx[m [1mtq>[m [1;4mDEFAULT[m [1;4mTRANSACTION[m [1mqq>[m [1mtxn-options[m [1mqqqqqqqqqqqqqqqqu[m [1mtq> [1;4mTRANSACTION[m [1;4mMODES[m [1mqq>[m [1m(txn-modes) qqqqqqqqqqqqqqqqqqu[m [1mtq>[m [1;4mLIMIT[m [1mqwqwq>[m [1;4mROWS[m [1mlimit-value[m [1mqqqqqqqqqqqqqqqqqqqqwwu[m [1mx[m [1mx[m [1mtq>[m [1;4mTIME[m [1mlimit-value[m [1mqqqqqwqwqqqqqqqqqqqwjxx [m [1mx[m [1mx[m [1mmq>[m [1;4mCPU[m [1;4mTIME[m [1mlimit-value[m [1mqj[m [1mtq>[m [1;4mSECONDS[m[1m u[m [1mxx [m [1mx[m [1m [m [1mx[m [1mmq>[m [1;4mMINUTES[m[1m j[m [1mxx [m [1mx[m [1mmqqqqqqqqqqqqqqqqqqqq[m [1m<qqqqqqqqqqqqqqqqqqqqqjx [m [1mmq> [1;4mNO[m[1m qw> [1;4mDEFAULT[m[1m [1;4mTRANSACTION[m [1mqqwqqqqqqqqqqqqqqqqqqqqqqj [m [1m [m [1m t>[m [1;4mTRANSACTION[m[1m [1;4mMODES[m [1mqwqj[m [1m m> [1;4mLIMIT[m[1mqwq> [1;4mCPU[m[1m [1;4mTIME[m [1mqu[m [1mtq>[m [1;4mROWS[m [1mqqqu[m [1mmq>[m [1;4mTIME[m [1mqqqqj[m (B)0[m[1mlimit-value =[m [1mqqwq>[m [1mpositive-integer-literal[m [1mqwq>[m [1mtq>[m [1;4mUNLIMITED[m [1mqqqqqqqqqqqqqqqqu[m [1mmq>[m [1;4mDEFAULT[m[1m qqqqqqqqqqqqqqqqqqj[m
11.3 – Arguments
11.3.1 – ALIAS aliasname
When attached to multiple databases, the aliasname is required to direct the CREATE command to the appropriate database.
11.3.2 – COMMENT_IS
This optional clause can be used to add several lines of comment to the profile object. The comment is displayed by the SHOW PROFILES statement. Enclose the comment in single quotation marks (') and separate multiple lines in a comment with a slash mark (/).
11.3.3 – DEFAULT_PROFILE
Creates the special profile RDB$DEFAULT_PROFILE. This profile will be used by any user who is not assigned a profile using the PROFILE clause of CREATE or ALTER PROFILE.
11.3.4 – DEFAULT_TRANSACTION
DEFAULT TRANSACTION provides a default transaction for the user. By default, Oracle Rdb starts a READ WRITE transaction if none is explicitly started. Use the DECLARE TRANSACTION or START DEFAULT TRANSACTION statement to make use of this definition. You can override this clause with a DECLARE or SET TRANSACTION statement. NOTE Oracle Rdb does not permit the RESERVING or EVALUATING clauses to appear in the default transaction.
11.3.5 – LIMIT_CPU_TIME
Syntax options: LIMIT CPU TIME | NO LIMIT CPU TIME LIMIT CPU TIME sets the maximum CPU time that can be used by the query compiler. The keyword DEFAULT indicates that no value is defined by this profile and is equivalent to NO LIMIT CPU TIME. If a numeric value or the keyword UNLIMITED is specified then this value will be used even when the SET QUERY LIMIT CPU TIME statement is present in the session, or when the logical name RDMS$BIND_QG_CPU_TIMEOUT is defined. NO LIMIT CPU TIME is the default. Units can be specified as seconds or minutes.
11.3.6 – LIMIT_ROWS
Syntax options: LIMIT ROWS | NO LIMIT ROWS LIMIT ROWS sets the maximum number of rows that can be returned by a query started by the user. The keyword DEFAULT indicates that no value is defined by this profile and is equivalent to NO LIMIT ROWS. If a numeric value or the keyword UNLIMITED is specified then this value will be used even when the SET QUERY LIMIT ROWS statement is present in the session, or when the logical name RDMS$BIND_QG_REC_LIMIT is defined. NO LIMIT ROWS is the default.
11.3.7 – LIMIT_TIME
Syntax options: LIMIT TIME | NO LIMIT TIME LIMIT TIME sets the maximum elapsed time that can be used by the query compiler. The keyword DEFAULT indicates that no value is defined by this profile and is equivalent to NO LIMIT TIME. If a numeric value or the keyword UNLIMITED is specified then this value will be used even when the SET QUERY LIMIT TIME statement is present in the session, or when the logical name RDMS$BIND_QG_TIMEOUT is defined. NO LIMIT TIME is the default. Units can be specified as seconds or minutes.
11.3.8 – TRANSACTION_MODES
Syntax options: TRANSACTION MODES | NO TRANSACTION MODES TRANSACTION MODES provides the list of allowable transactions for this user. Please see the SET TRANSACTION MODES clause of the CREATE DATABASE and ALTER DATABASE statements for more details of txn-modes. The transaction modes specified may include modes disabled for all database users by CREATE, IMPORT, or ALTER DATABASE statements. However, only the subset allowed by both profile and database settings will be used. For instance, if the database specifies (READ ONLY, SHARED READ, PROTECTED READ) and the profile specifies (READ ONLY, SHARED), the session will be allowed the subset (READ ONLY, SHARED READ).
11.4 – Examples
Example 1 The following example specifies the allowed transaction modes for any user assigned this profile. SQL> CREATE PROFILE DECISION_SUPPORT cont> COMMENT IS 'limit transactions used by report writers' cont> TRANSACTION MODES (NO READ WRITE, READ ONLY); Example 2 This example shows the use of the LIMIT clauses to set boundaries for standard database users. SQL> create profile STANDARD_USER cont> limit rows 10000 cont> limit time 10 minutes cont> limit cpu time 20 seconds; SQL> show profile STANDARD_USER; STANDARD_USER Limit rows 10000 Limit time 10 minutes Limit CPU time 20 seconds SQL> alter profile STANDARD_USER cont> limit time 60 minutes;
12 – ROLE
Creates a role to which privileges and other roles can be granted. A role can be granted to a user or another role. For example, you can create a role for members of a department. When a user leaves the department, the departmental role can be revoked from that user and thus exclude that user's access to the departmental data.
12.1 – Environment
You can use the CREATE ROLE statement: o In interactive SQL o Embedded in host language programs o As part of a procedure in an SQL module or other compound statement o In dynamic SQL as a statement to be dynamically executed
12.2 – Format
(B)0[m[1;4mCREATE[m[1m [1;4mROLE[m[1m qqq> <role-name> qqqqqqqqqqqqqqqqqqqqqqk [m [1mlqqqqqqqqqqqqqqqqqqqqq<qqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1mmqqqqqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqqqqqqqqqqqk [m [1m tqq> [1;4mIDENTIFIED[m[1m [1;4mEXTERNALLY[m[1m qqqqqqu x [m [1m mqq> [1;4mNOT[m[1m [1;4mIDENTIFIED[m[1m qqqqqqqqqqqqqj x [m [1mlqqqqqqqqqqqqqqqqqqqq<qqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1mmqqqqqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqqqqqqqqqqq> [m [1m mqq> [1;4mCOMMENT[m[1m IS qqwq> 'string' qqwqj [m [1m mqqqqqq / <qqqqj [m
12.3 – Arguments
12.3.1 – COMMENT IS 'string'
Adds a comment about the role. SQL displays the text of the comment when it executes a SHOW ROLES statement. Enclose the comment in single quotation marks (') and separate multiple lines in a comment with a slash mark (/).
12.3.2 – IDENTIFIED_EXTERNALLY
The IDENTIFIED EXERNALLY clause indicates that SQL should inherit the roles defined by the facilities of the operating system, such as rights identifiers. When a session is started, any role that is defined externally is established as part of the current user's profile.
12.3.3 – NOT_IDENTIFIED
Indicates that the role is used only with the database. The database must have SECURITY CHECKING IS INTERNAL set before using this clause.
12.3.4 – role-name
A user-supplied name that you assign to the role. The special roles BATCH, DIALUP, INTERACTIVE, LOCAL, NETWORK, and REMOTE are reserved names that cannot be specified as a role-name.
12.4 – Examples
Example 1: Creating a Role SQL> ALTER DATABASE FILENAME 'mf_personnel.rdb' cont> SECURITY CHECKING IS INTERNAL; SQL> ATTACH 'FILENAME mf_personnel.rdb'; SQL> CREATE ROLE WRITER; SQL> SHOW ROLES; Roles in database with filename mf_personnel.rdb WRITER Example 2: Creating Roles and Granting Privileges to Those Roles SQL> ALTER DATABASE FILENAME mf_personnel.rdb cont> SECURITY CHECKING IS INTERNAL; SQL> -- Create a role for employees in the payroll department SQL> ATTACH 'FILENAME MF_PERSONNEL.RDB'; SQL> CREATE ROLE PAYROLL cont> COMMENT IS 'This role allows access to various tables' cont> / 'and procedures for use by the PAYROLL dept.'; SQL> -- Create another role for a subset of employees. SQL> CREATE ROLE ANNUAL_LEAVE cont> COMMENT IS 'This role is granted to PAYROLL personnel' cont> / 'who adjust the annual leave data'; SQL> -- Grant EXECUTE privilege on module and ALL privilege on table SQL> -- SALARY_HISTORY to all employees to whom the PAYROLL role has SQL> -- been granted. Grant EXECUTE privilege on module LEAVE_ADJUSTMENT SQL> -- only to those employees who have been granted both the PAYROLL SQL> -- and ANNUAL_LEAVE roles. SQL> GRANT EXECUTE ON MODULE PAYROLL_UTILITIES TO PAYROLL; SQL> GRANT ALL ON TABLE SALARY_HISTORY TO PAYROLL; SQL> GRANT EXECUTE ON MODULE LEAVE_ADJUSTMENT cont> to PAYROLL, ANNUAL_LEAVE; SQL> -- User STUART joins the personnel department. Grant him SQL> -- the PAYROLL and ANNUAL_LEAVE roles so that he can SQL> -- perform all functions in the payroll department. SQL> CREATE USER STUART cont> IDENTIFIED EXTERNALLY SQL> GRANT PAYROLL, ANNUAL_LEAVE TO STUART; SQL> -- User STUART is promoted to supervisor and thus SQL> -- no longer needs access to the objects controlled by SQL> -- the ANNUAL_LEAVE role. Revoke that role from user SQL> -- STUART. SQL> REVOKE ANNUAL_LEAVE FROM STUART; Example 3: Creating roles explictly using CREATE ROLE and implicitly using GRANT This examples demonstrates creating roles that match an OpenVMS rights identifiers. The CREATE ROLE statement is used first, and then the GRANT statement. GRANT issues a warning message to alert the database administrator of the side-effect of the GRANT statement. SQL> create database cont> filename SAMPLE cont> security checking is internal; SQL> show roles; Roles in database with filename sample No Roles found SQL> create role dba_mgr identified externally; SQL> show roles; Roles in database with filename sample DBA_MGR SQL> grant saldb_user to smith; %RDB-W-META_WARN, metadata successfully updated with the reported warning -RDMS-W-PRFCREATED, some users or roles were created SQL> show roles; Roles in database with filename sample DBA_MGR SALDB_USER SQL>
13 – Routine
Creates an external routine definition as a schema object in an Oracle Rdb database. External routine refers to both external functions and external procedures. A routine definition stores information in the database about a subprogram (a function or procedure) written in a 3GL language. The routine definition and the routine image are independent of each other, meaning one can exist without the other. However, to invoke an external routine, you need both the routine definition and routine image. SQL can invoke an external function from anywhere you can specify a value expression. External procedures are invoked using the CALL Compound_Statement.
13.1 – Environment
You can use the CREATE FUNCTION and CREATE PROCEDURE statements: o In interactive SQL o Embedded in host language programs to be precompiled o As part of a procedure in an SQL module o In dynamic SQL as a statement to be dynamically executed
13.2 – Format
(B)0[m[1;4mCREATE[m[1m qwq> [1;4mFUNCTION[m[1m qqqwq> <external-routine-name> qqqqqqqqqk [m [1m mq> [1;4mPROCEDURE[m[1m qqj x [m [1m lqqqqqqqqqqqqqqqqqqqqqqqqqqqq<qqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1m mqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqqqqqqqqqqqqqqqqqqqqqqqk [m [1m mq> [1;4mSTORED[m[1m [1;4mNAME[m[1m IS <identifier> qj x [m [1m lqqqqqqqqqqqqqqqqqqqqqqqqqqqq<qqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1m mq> ( qwqqqqqqqqqqqqqqqqqqqqqqqwq> ) qqqqqqqqqqqqqqqqqqqqqqk [m [1m mwq> parameter-list qqwqj x [m [1m mqqqqqqqq , <qqqqqqqqj x [m [1m lqqqqqqqqqqqqqqqqqqqqqqqqqqqq<qqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1m mqwqqqqqqqqqqqqqqqqqqqwqq> qqwqqqqqqqqqqqqqqqqqqwq> ; qq> qk [m [1m mq> returns-clause qj mq> [1;4mLANGUAGE[m[1m [1;4mSQL[m[1m qqj x [m [1m x [m [1m lqqqqqqqqqqqqqqqqqqqqqqqqqqqq<qqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1m mqqqq> external-body-clause qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqq> [m (B)0[m[1mparameter-list = [m [1m [m [1mqwqqqqqqqqqqwqwqqqqqqqqqqqqqqqqqqqwqwq> data-type qqqqqwqqqqqqqqqqk [m [1m tq> [1;4mIN[m[1m qqqqu m> <parameter-name> j mq> <domain-name> qj [m [1mx [m [1m tq> [1;4mOUT[m[1m qqqu [m [1mx[m [1m mq> [1;4mINOUT[m[1m qj [m [1mx[m [1mlqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj[m [1mmqwqqqqqqqqqqqqqqqqqqqqqqqqqqqwqqwqqqqqqqqqqqqqqqqqqqqqwqqqqqqqqqqk [m [1m mq> [1;4mDEFAULT[m[1m value-expr qqqqqj[m [1mmq> mechanism-clause qj x [m [1m lqqqqqqqqqqqqqqqqqqqqqqqqqqqqqq<qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1m mwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqq>[m [1m mq> [1;4mCOMMENT[m[1m [1;4mIS[m[1m qwq> 'string' qqqwqj [m [1m mqqqqqq / <qqqqqj [m (B)0[m[1mmechanism-clause = [m [1m [m [1mqqqq> [1;4mBY[m[1m qqwq> [1;4mDESCRIPTOR[m[1m qwqqq> [m [1m tq> [1;4mLENGTH[m[1m qqqqqu [m [1m tq> [1;4mREFERENCE[m[1m qqu [m [1m mq> [1;4mVALUE[m[1m qqqqqqj [m [1m [m (B)0[m[1mexternal-body-clause = [m [1m [m [1mqq> [1;4mEXTERNAL[m[1m qqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqqqqqqqqqqqqqk [m [1m mq> [1;4mNAME[m[1m <external-body-name> qj [m [1m x [m [1mlqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqq[m [1m<qqqqqqqqqqqqqqqqqqqqqqj [m [1mmwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwq> [1;4mLANGUAGE[m[1m language-name[m [1mqqk [m [1m mq> external-location-clause qj [m [1m x [m [1mlqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqq<qqqqqqqqqqqqqqqqqqqqqqqqj [m [1mmwq> [1;4mPARAMETER[m[1m [1;4mSTYLE[m[1m [1;4mGENERAL[m[1m qwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqk [m [1m mq> [1;4mGENERAL[m[1m [1;4mPARAMETER[m[1m [1;4mSTYLE[m[1m qj [m [1m x [m [1mlqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqq<qqqqqqqqqqqqqqqqqqqqqqqj [m [1mmwqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqq> [m [1mmq> external-body-clause-2 qqj[m (B)0[m[1mexternal-body-clause-2 =[m [1mqqqwqqwq> [1;4mCOMMENT[m[1m [1;4mIS[m[1m qwq> '<string> ' qwqqqqwqqwqq>[m [1m x x mqqqqqq / <qqqqqqj x x [m [1m x tq> bind-site-clause qqqqqqqqqqqqqqqqqu x [m [1m x tq> bind-scope-clause qqqqqqqqqqqqqqqqu x [m [1m x tq> notify-clause qqqqqqqqqqqqqqqqqqqqu x [m [1mx[m [1mtq>[m [1;4mCALLED[m [1;4mON[m [1;4mNULL[m [1;4mINPUT[m[1m qqqqqqqqqqqqqu[m [1mx[m [1mx[m [1mtq>[m [1;4mRETURNS[m [1;4mNULL[m [1;4mON[m [1;4mNULL[m [1;4mINPUT[m[1m qqqqqqqu[m [1mx[m [1mx[m [1mtq>[m [1;4mUSAGE[m[1m IS qwq>[m [1;4mLOCAL[m [1mqqqwqqqqqqqqqqu[m [1mx[m [1mx[m [1mx [m [1mmq>[m [1;4mGLOBAL[m[1m qqj[m [1mx[m [1mx[m [1m x mqwqqqqqqqqwqqwqqqqqqqqqqqqqqqqqqqwqqqj x [m [1m x mq> [1;4mNOT[m[1m qj tq> [1;4mVARIANT[m[1m qqqqqqqqu x [m [1m x mq> [1;4mDETERMINISTIC[m[1m qqj x [m [1m mqqqqqqqqqqqqqqqqqqqqqq <qqqqqqqqqqqqqqqqqqqj [m (B)0[m[1mexternal-location-clause = [m [1m [m [1mqqqwqq> [1;4mDEFAULT[m[1m [1;4mLOCATION[m[1m qqqqqqqqqqqqwqqqqqqqqqqqqqqqqqqqqqqqqqk[m [1m mqq> [1;4mLOCATION[m[1m '<image-location>' qj x[m [1m lqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqq<qqqqqqqqqqqqqqqqqqqqqqqqqqqqqj[m [1m mqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqq>qqqqqqqqqqqqqqqqqqqqqqqqqqwqq>[m [1m mqq> [1;4mWITH[m[1m qqwq> [1;4mALL[m[1m qqqqqwqq> [1;4mLOGICAL_NAME[m[1m [1;4mTRANSLATION[m[1m qqj [m [1m mq> [1;4mSYSTEM[m[1m qqj [m (B)0[m[1mlanguage-name = [m [1m [m [1mqqwq> [1;4mADA[m[1m qqqqqwqq> [m [1m tq> [1;4mC[m[1m qqqqqqqu [m [1m tq> [1;4mCOBOL[m[1m qqqu [m [1m tq> [1;4mFORTRAN[m[1m qu [m [1m tq> [1;4mPASCAL[m[1m qqu [m [1m mq> [1;4mGENERAL[m[1m qj [m [1m [m (B)0[m[1mbind-site-clause = [m [1m [m [1mqq> [1;4mBIND[m[1m [1;4mON[m[1m qqwqq> [1;4mCLIENT[m[1m qqwqq> [1;4mSITE[m[1m qqq> [m [1m mqq> [1;4mSERVER[m[1m qqj [m (B)0[m[1mbind-scope-clause = [m [1m [m [1mqqq> [1;4mBIND[m[1m [1;4mSCOPE[m[1m qqwq> [1;4mCONNECT[m[1m qqqqqqwqq> [m [1m mq> [1;4mTRANSACTION[m[1m qqj [m [1m [m (B)0[m[1mnotify-clause = [m [1m [m [1mq> [1;4mNOTIFY[m[1m notify-entry-name qq> [1;4mON[m[1m qwqwq> [1;4mBIND[m[1m qqqqqqqqqwqwq> [m [1m x tq> [1;4mCONNECT[m[1m qqqqqqu x [m [1m x mq> [1;4mTRANSACTION[m[1m qqj x [m [1m mqqqqqqqqq , <qqqqqqqqj [m
13.3 – Arguments
13.3.1 – bind-site-clause
Syntax options: BIND ON CLIENT SITE | BIND ON SERVER SITE Selects the execution model and environment for external routine execution. CLIENT site binding causes the external routine to be activated and executed in the OpenVMS database client (application) process. This is the default binding. This binding offers the most efficient execution characteristics, allows sharing resources such as I/O devices, and allows debugging of external routines as if they were part of the client application. However, this binding may suffer from address space limitations. Because it shares virtual memory with the database buffers, this binding is restricted to the client process system user environment, and prohibits external routine execution in cases of an application running with elevated privileges. SERVER site binding causes the external routine to be activated in a separate process from the database client and server. The process is started on the same node at the database process. This binding offers reasonable execution characteristics, a larger address space, a true session user environment, and has no restrictions regarding client process elevated privileges. However, this binding does not permit sharing resources such as I/O devices with the client (in particular, there is no connection to the client interactive terminal), and debugging of routines is generally not possible.
13.3.2 – bind-scope-clause
Syntax options: BIND SCOPE CONNECT | BIND SCOPE TRANSACTION Defines the scope during which an external routine is activated and at what point the external routine is deactivated. The default scope is CONNECT. o CONNECT An active routine is deactivated when you detach from the database (or exit without detaching). o TRANSACTION An active routine is deactivated when a transaction is terminated (COMMIT or ROLLBACK). In the event that a transaction never occurs, the scope reverts to CONNECT.
13.3.3 – COMMENT_IS
A description about the nature of the parameter or external routine. SQL displays the text of the comment when you execute a SHOW FUNCTION or SHOW PROCEDURE statement. Enclose the comment in single quotation marks (') and separate multiple lines in a comment with a slash (/).
13.3.4 – DEFAULT value-expr
Specifies the default value of a parameter for a function or procedure defined with mode IN. If you omit this parameter or if the Call statement argument list or function invocation specifies the DEFAULT keyword, then the value-expr specified with this clause is used. The parameter uses NULL as the default if you do not specify a value expression explicitly.
13.3.5 – DETERMINISTIC
Syntax options: DETERMINISTIC | NOT DETERMINISTIC The clause controls the evaluation of an external function in the scope of a query: o NOT DETERMINISTIC Specifying the NOT DETERMINISTIC clause forces evaluation of corresponding functions (in scope of a single query) every time the function appears. If a function can return a different result each time it is invoked, you should use the DETERMINISTIC clause. o DETERMINISTIC Specifying the DETERMINISTIC clause can result in a single evaluation of corresponding function expressions (in scope of a single query), and the resulting value is used in all occurrences of the corresponding function expression. When you use the DETERMINISTIC clause, Oracle Rdb evaluates whether or not to invoke the function each time it is used. For example: SELECT * FROM T1 WHERE F1() > 0 AND F1() < 20; If you define the F1 function as DETERMINISTIC, the function F1() may be evaluated just once depending on the optimizer. If you define the F1 function as NOT DETERMINISTIC, the function F1() is evaluated twice. DETERMINISTIC is the default. The DETERMINISTIC or NOT DETERMINISTIC clause is not allowed on procedure definitions.
13.3.6 – external-body-clause
Identifies key characteristics of the routine: its name, where the executable image of the routine is located, the language in which the routine is coded, and so forth.
13.3.7 – external-body-name
The name of the external routine. If you do not specify a name, SQL uses the name you specify in the external-routine-name clause. This name defines the routine entry address that is called for each invocation of the routine body. The named routine must exist in the external routine image selected by the location clause. Unquoted names are converted to uppercase characters.
13.3.8 – external-location-clause
Syntax options: DEFAULT LOCATION LOCATION 'image-location' A file specification referencing the image that contains the routine body and optional notify entry points.
13.3.9 – external-routine-name
The name of the external routine. The name must be unique among external and stored routines in the schema and can be qualified with an alias or, in a multischema database, a schema name.
13.3.10 – FUNCTION
Creates an external function definition. A function optionally accepts a list of IN parameters, always returns a value, and is referenced by name as an element of a value expression.
13.3.11 – GENERAL_PARAMETER_STYLE
This is synonymous with PARAMETER STYLE GENERAL and is deprecated.
13.3.12 – language-name
The name of the host language in which the external routine was coded. You can specify ADA, C, COBOL, FORTRAN, PASCAL, or GENERAL. The GENERAL keyword allows you to call routines written in any language.
13.3.13 – LANGUAGE_SQL
Names the language that calls the routine.
13.3.14 – mechanism-clause
Defines the passing mechanism. The following list describes the passing mechanisms. o BY DESCRIPTOR Allows passing character data with any parameter access mode to routines compiled by language compilers that implement the OpenVMS calling standard. o BY LENGTH The LENGTH passing mechanism is the same as the DESCRIPTOR passing mechanism. o BY REFERENCE Allows passing data with any parameter access mode as a reference to the actual data. This is the default passing mechanism for parameters. This is also the default passing mechanism for a function value returning character data. o BY VALUE Allows passing data with the IN parameter access mode to a routine as a value and allows functions to return a value. This is the default passing mechanism for a function value returning noncharacter data.
13.3.15 – notify-clause
Specifies the name of a second external routine called (notified) when certain external routine or database-related events occur. This name defines the routine entry address that is called, for each invocation of the notify routine. The named routine must exist in the external routine image selected by the location clause. The events of interest to the notify routine are ON BIND, ON CONNECT, and ON TRANSACTION. Multiple events can be specified. The following describes the events and scope of each event: BIND Routine activation to routine deactivation CONNECT Database attach to database disconnect TRANSACTION Start transaction to commit or roll back transaction
13.3.16 – parameter-list
The optional parameters of the external routine. For each parameter you can specify a parameter access mode (IN, OUT, and INOUT), a parameter name, a data type, and a passing mechanism (by DESCRIPTOR, LENGTH, REFERENCE, or VALUE). The parameter access mode (IN, OUT, and INOUT) is optional and specifies how the parameter is accessed (whether it is read, written, or both). IN signifies read only, OUT signifies write only, and INOUT signifies read and write. The parameter access mode defaults to IN. Only the IN parameter access mode may be specified with parameters to an external function. Any of the parameter access modes (IN, OUT, and INOUT) may be specified with parameters to an external procedure. The optional parameter name is prefixed with a colon (:). The parameter name must be unique within the external routine parameters. The data type is required and describes the type of parameter using either an SQL data type or a domain name. You cannot declare a parameter as the LIST OF BYTE VARYING data type.
13.3.17 – PARAMETER_STYLE_GENERAL
Passes arguments and returns values in a manner similar to the OpenVMS convention for passing arguments and returning function values.
13.3.18 – PROCEDURE
Creates an external procedure definition. A procedure optionally accepts a list of IN, OUT, or INOUT parameters, and is referenced by name in a CALL statement.
13.3.19 – RETURNS
Describes a function (returned) value. You can specify a data type and a passing mechanism (BY DESCRIPTOR, LENGTH, REFERENCE, or VALUE). The function value is, by definition, an OUT access mode value. The data type is required and describes the type of parameter using either an SQL data type or a domain name. You cannot declare a function value as the LIST OF BYTE VARYING data type.
13.3.20 – STORED_NAME_IS
The name that Oracle Rdb uses to access the routine when defined in a multischema database. The stored name allows you to access multischema definitions using interfaces that do not recognize multiple schemas in one database. You cannot specify a stored name for a routine in a database that does not allow multiple schemas. For more information about stored names, see Stored Names.
13.3.21 – USAGE_IS
Specifies how the function or procedure can be called: o USAGE IS GLOBAL indicates that the function or procedure can be called outside the current module. This is the default. o USAGE IS LOCAL specifies that the routine is restricted to references within the module. This clause is provided for compatibility with CREATE MODULE but is not allowed for CREATE FUNCTION or CREATE PROCEDURE.
13.3.22 – VARIANT
Syntax options: VARIANT | NOT VARIANT These clauses are synonyms for the DETERMINISTIC and NOT DETERMINISTIC clauses. The DETERMINISTIC clause indicates that the same inputs to the function will generate the same output. It is the same as the NOT VARIANT clause. The NOT DETERMINISTIC clause indicates that the output of the function does not depend on the inputs. It is the same as the VARIANT clause. This clause is deprecated. Use DETERMINISTIC instead.
13.4 – Examples
Example 1: System provided integer absolute value routine SQL> CREATE FUNCTION IABS (IN INTEGER BY REFERENCE) cont> RETURNS INTEGER BY VALUE; cont> EXTERNAL NAME MTH$JIABS cont> LOCATION 'SYS$SHARE:DPML$SHR.EXE' cont> LANGUAGE GENERAL cont> PARAMETER STYLE GENERAL cont> NOT DETERMINISTIC; SQL> -- SQL> SELECT IABS(-33) FROM JOBS LIMIT TO 1 ROW; 33 1 row selected Example 2: Using the NOT DETERMINISTIC clause, instead of the DETERMINISTIC clause The first CREATE FUNCTION statement in the following example creates a function with the DETERMINISTIC clause. The DETERMINISTIC clause indicates to Oracle Rdb that the function would return the same result no matter how many times it is called. Because the argument is a string literal (and could never change), Oracle Rdb optimizes the entire function call so that it is not called in subsequent select statements. SQL> -- Create a function with a DETERMINISTIC clause. SQL> CREATE function DO_COM (IN VARCHAR(255) BY DESCRIPTOR) cont> RETURNS INTEGER; cont> EXTERNAL NAME LIB$SPAWN cont> LOCATION 'SYS$SHARE:LIBRTL.EXE' cont> LANGUAGE GENERAL cont> PARAMETER STYLE GENERAL cont> DETERMINISTIC; SQL> -- SQL> -- Use a SELECT statement to pass a string literal to the function. SQL> -- SQL> -- Because Oracle Rdb optimizes functions with the DETERMINISTIC SQL> -- clause, and the function is passed a string literal, SQL> -- Oracle Rdb does not call the function from subsequent SQL> -- statements. SQL> -- SQL> SELECT DO_COM('WRITE SYS$OUTPUT "HELLO"'), employee_id FROM employees cont> LIMIT TO 5 ROWS; HELLO DO_COM EMPLOYEE_ID 1 00164 1 00165 1 00166 1 00167 1 00168 5 rows selected SQL> -- SQL> -- Use the NOT DETERMINISTIC clause to create the function: SQL> -- SQL> CREATE function DO_COM (IN VARCHAR(255) BY DESCRIPTOR) cont> RETURNS INTEGER; cont> EXTERNAL NAME lib$SPAWN cont> LOCATION 'SYS$SHARE:LIBRTL.EXE' cont> LANGUAGE GENERAL cont> PARAMETER STYLE GENERAL cont> NOT DETERMINISTIC; SQL> SELECT DO_COM('WRITE SYS$OUTPUT "HELLO"'), EMPLOYEE_ID FROM EMPLOYEES cont> LIMIT TO 5 ROWS; HELLO HELLO DO_COM EMPLOYEE_ID 1 00164 HELLO 1 00165 HELLO 1 00166 HELLO 1 00167 1 00168 5 rows selected Example 3: External function and external procedure definition The following example demonstrates: o An external function and an external procedure o Both CLIENT SITE and SERVER SITE binding o BIND SCOPE o A NOTIFY routine and events o SQL callback using embedded SQL and SQL module language o SQL$PRE options required when using callback o Linker options required when using callback In this example, a new column is added to the EMPLOYEES table in the MF_PERSONNEL database. External routines are used to set this column to spaces and to the SOUNDEX value corresponding to the various employee names. Transaction control at the application level (in this instance, in SQL) in conjunction with a notify routine demonstrates how the actions of the external routines can be affected by actions of the application. The space-filling is performed by an external function, CLEAR_ SOUNDEX, (written in C) containing embedded SQL, which opens another instance of the MF_PERSONNEL database and leaves it open until deactivated. The SOUNDEX name-setting is performed by an external procedure (written in FORTRAN), assisted by a notify routine (written in FORTRAN) which performs the database connection and transaction control. All the database operations are performed by SQL module language routines. The procedure also opens another instance of the MF_PERSONNEL database, which is disconnected by the notify routine when the routine is deactivated at the end of the transaction. Display statements executed by the notify routine serve to demonstrate the progress of the database operations. SQL> ATTACH 'FILENAME MF_PERSONNEL'; SQL> -- SQL> -- Add the new column SOUNDEX_NAME to the EMPLOYEES table. SQL> -- SQL> ALTER TABLE EMPLOYEES ADD SOUNDEX_NAME CHAR(4); SQL> -- SQL> -- Define the CLEAR_SOUNDEX function. SQL> -- SQL> CREATE FUNCTION CLEAR_SOUNDEX () cont> RETURNS INTEGER BY VALUE; cont> EXTERNAL NAME CLEAR_SOUNDEX cont> LOCATION 'CLEAR_SOUNDEX.EXE' cont> LANGUAGE C PARAMETER STYLE GENERAL NOT DETERMINISTIC cont> BIND ON SERVER SITE BIND SCOPE CONNECT; SQL> -- SQL> -- Define the ADD_SOUNDEX_NAME procedure. SQL> -- SQL> CREATE PROCEDURE ADD_SOUNDEX_NAME cont> (INOUT INTEGER BY REFERENCE); cont> EXTERNAL NAME ADD_SOUNDEX_NAME cont> LOCATION 'ADD_SOUNDEX.EXE' cont> LANGUAGE FORTRAN PARAMETER STYLE GENERAL cont> BIND ON CLIENT SITE BIND SCOPE TRANSACTION cont> NOTIFY ADD_SOUNDEX_NOTIFY ON BIND, TRANSACTION; SQL> -- SQL> COMMIT; SQL> DISCONNECT ALL; SQL> EXIT; Example 4: The CLEAR_SOUNDEX.SC program written in C /* Set the soundex_name column to spaces, return any error as function value */ static int state = 0; extern int clear_soundex () { exec sql include sqlca ; exec sql declare alias filename MF_PERSONNEL; if (state == 0) { exec sql attach 'filename MF_PERSONNEL'; state = 1; } exec sql set transaction read write; if (SQLCA.SQLCODE < 0) return SQLCA.SQLCODE; exec sql update employees set soundex_name = ' '; if (SQLCA.SQLCODE < 0) return SQLCA.SQLCODE; exec sql commit; if (SQLCA.SQLCODE < 0) return SQLCA.SQLCODE; return 0; } Example 5: Compiling, creating a linker options file, and linking the CLEAR_SOUNDEX program $ SQL$PRE/CC/NOLIST/SQLOPT=ROLLBACK_ON_EXIT CLEAR_SOUNDEX.SC $ CREATE CLEAR_SOUNDEX.OPT SYMBOL_VECTOR = (CLEAR_SOUNDEX=PROCEDURE) PSECT_ATTR=RDB$MESSAGE_VECTOR,NOSHR PSECT_ATTR=RDB$DBHANDLE,NOSHR PSECT_ATTR=RDB$TRANSACTION_HANDLE,NOSHR $ LINK/SHARE=CLEAR_SOUNDEX.EXE - CLEAR_SOUNDEX.OBJ, SQL$USER:/LIBRARY, - CLEAR_SOUNDEX.OPT/OPT SYMBOL_VECTOR = (CLEAR_SOUNDEX=PROCEDURE) PSECT_ATTR=RDB$MESSAGE_VECTOR,NOSHR PSECT_ATTR=RDB$DBHANDLE,NOSHR PSECT_ATTR=RDB$TRANSACTION_HANDLE,NOSHR Example 6: The ADD_SOUNDEX.FOR program written in FORTRAN C Set the soundex values, returning any error in the IN/OUT parameter SUBROUTINE ADD_SOUNDEX_NAME (ERROR) CHARACTER ID*5,LAST*14,SX_NAME*4 INTEGER ERROR ERROR = 0 ID = '00000' 10 CALL GET_NAME (ID, LAST, ERROR) IF (ERROR .NE. 0) GO TO 80 CALL MAKE_SOUNDEX_NAME (LAST, SX_NAME) CALL SET_SOUNDEX_NAME (ID, SX_NAME, ERROR) IF (ERROR .EQ. 0) GO TO 10 80 IF (ERROR .EQ. 100) ERROR = 0 90 RETURN END C Perform database connection and transaction operations for notify events SUBROUTINE ADD_SOUNDEX_NOTIFY (FUNC, RSV1, RSV2, RSV3) INTEGER FUNC, RSV1, RSV2, RSV3, SQLCODE SQLCODE = 0 GO TO (10,20,5,5,30,40,50),FUNC 5 TYPE *,'*** ADD_SOUNDEX_NOTIFY bad func ***' GO TO 90 10 TYPE *,'*** ADD_SOUNDEX_NOTIFY activate ***' CALL ATTACH_DB (SQLCODE) IF (SQLCODE .NE. 0) GO TO 80 GO TO 90 20 TYPE *,'*** ADD_SOUNDEX_NOTIFY deactivate ***' CALL DETACH_DB (SQLCODE) IF (SQLCODE .NE. 0) GO TO 80 GO TO 90 30 TYPE *,'*** ADD_SOUNDEX_NOTIFY start tran ***' CALL START_TRAN (SQLCODE) IF (SQLCODE .NE. 0) GO TO 80 GO TO 90 40 TYPE *,'*** ADD_SOUNDEX_NOTIFY commit tran ***' CALL COMMIT_TRAN (SQLCODE) IF (SQLCODE .NE. 0) GO TO 80 GO TO 90 50 TYPE *,'*** ADD_SOUNDEX_NOTIFY rollback tran ***' CALL ROLLBACK_TRAN (SQLCODE) IF (SQLCODE .NE. 0) GO TO 80 GO TO 90 80 CALL SQL_SIGNAL () 90 RETURN END C A 'substitute' SOUNDEX routine for demonstration purposes only SUBROUTINE MAKE_SOUNDEX_NAME (NAME, SOUNDEX_NAME) CHARACTER NAME*(*),SOUNDEX_NAME*4 SOUNDEX_NAME(1:1)=NAME(1:1) IV = ICHAR(NAME(1:1))+22 SOUNDEX_NAME(2:2)=CHAR(MOD(IV,10)+48) SOUNDEX_NAME(3:3)=CHAR(MOD(IV/10,10)+48) SOUNDEX_NAME(4:4)=CHAR(IV/100+48) RETURN END Example 7: The ADD_SOUNDEXM.SQLMOD module -- Support for set soundex routine MODULE ADD_SOUNDEX LANGUAGE FORTRAN PARAMETER COLONS PROCEDURE ATTACH_DB (SQLCODE); ATTACH 'FILENAME MF_PERSONNEL'; PROCEDURE DETACH_DB (SQLCODE); DISCONNECT DEFAULT; PROCEDURE START_TRAN (SQLCODE); SET TRANSACTION READ WRITE; PROCEDURE COMMIT_TRAN (SQLCODE); COMMIT; PROCEDURE ROLLBACK_TRAN (SQLCODE); ROLLBACK; PROCEDURE GET_NAME (:ID CHAR(5), :LASTNAME CHAR(14), SQLCODE); SELECT EMPLOYEE_ID, LAST_NAME INTO :ID, :LASTNAME FROM EMPLOYEES WHERE EMPLOYEE_ID > :ID LIMIT TO 1 ROW; PROCEDURE SET_SOUNDEX_NAME (:ID CHAR(5), :SX_NAME CHAR(4), SQLCODE); UPDATE EMPLOYEES SET SOUNDEX_NAME = :SX_NAME WHERE EMPLOYEE_ID = :ID; Example 8: Compiling, creating the linker options file, and linking the FORTRAN and SQL module language programs $ FORTRAN/NOLIST ADD_SOUNDEX.FOR $ SQL$MOD ADD_SOUNDEXM.SQLMOD $ CREATE ADD_SOUNDEX.OPT SYMBOL_VECTOR = (ADD_SOUNDEX_NAME=PROCEDURE) SYMBOL_VECTOR = (ADD_SOUNDEX_NOTIFY=PROCEDURE) PSECT_ATTR=RDB$MESSAGE_VECTOR,NOSHR PSECT_ATTR=RDB$DBHANDLE,NOSHR PSECT_ATTR=RDB$TRANSACTION_HANDLE,NOSHR $ LINK/SHARE=ADD_SOUNDEX.EXE - ADD_SOUNDEX.OBJ, ADD_SOUNDEXM.OBJ, SQL$USER:/LIBRARY, - ADD_SOUNDEX.OPT/OPT SYMBOL_VECTOR = ADD_SOUNDEX_NAME SYMBOL_VECTOR = ADD_SOUNDEX_NOTIFY PSECT_ATTR=RDB$MESSAGE_VECTOR,NOSHR PSECT_ATTR=RDB$DBHANDLE,NOSHR PSECT_ATTR=RDB$TRANSACTION_HANDLE,NOSHR Example 9: Using the routines with interactive SQL $ SQL SQL> ATTACH 'FILENAME MF_PERSONNEL'; SQL> -- SQL> DECLARE :ERROR INTEGER; SQL> -- SQL> SELECT EMPLOYEE_ID,SOUNDEX_NAME FROM EMPLOYEES cont> LIMIT TO 3 ROWS; EMPLOYEE_ID SOUNDEX_NAME 00165 NULL 00190 NULL 00187 NULL 3 rows selected SQL> COMMIT; SQL> -- SQL> BEGIN cont> SET :ERROR = CLEAR_SOUNDEX (); cont> END; SQL> PRINT :ERROR; ERROR 0 SQL> -- SQL> SELECT EMPLOYEE_ID,SOUNDEX_NAME FROM EMPLOYEES cont> LIMIT TO 3 ROWS; EMPLOYEE_ID SOUNDEX_NAME 00165 00190 00187 3 rows selected SQL> COMMIT; SQL> -- SQL> SET TRANSACTION READ ONLY; SQl> BEGIN cont> SET :ERROR = 0; cont> CALL ADD_SOUNDEX_NAME (:ERROR); cont> END; *** ADD_SOUNDEX_NOTIFY activate *** *** ADD_SOUNDEX_NOTIFY start tran *** SQL> PRINT :ERROR; ERROR 0 SQL> COMMIT; *** ADD_SOUNDEX_NOTIFY commit tran *** *** ADD_SOUNDEX_NOTIFY deactivate *** SQL> -- SQL> SELECT EMPLOYEE_ID,SOUNDEX_NAME FROM EMPLOYEES cont> LIMIT TO 3 ROWS; EMPLOYEE_ID SOUNDEX_NAME 00165 S501 00190 O101 00187 L890 3 rows selected SQL> COMMIT; SQL> -- SQL> BEGIN cont> SET :ERROR = CLEAR_SOUNDEX (); cont> END; SQL> PRINT :ERROR; ERROR 0 SQL> -- SQL> SET TRANSACTION READ ONLY; SQL> BEGIN cont> SET :ERROR = 0; cont> CALL ADD_SOUNDEX_NAME (:ERROR); cont> END; *** ADD_SOUNDEX_NOTIFY activate *** *** ADD_SOUNDEX_NOTIFY start tran *** SQL> PRINT :ERROR; ERROR 0 SQL> ROLLBACK; *** ADD_SOUNDEX_NOTIFY rollback tran *** *** ADD_SOUNDEX_NOTIFY deactivate *** SQL> -- SQL> SELECT EMPLOYEE_ID,SOUNDEX_NAME FROM EMPLOYEES cont> LIMIT TO 3 ROWS; EMPLOYEE_ID SOUNDEX_NAME 00165 00190 00187 3 rows selected SQL> COMMIT;
14 – SCHEMA
Creates a new schema in the current default catalog of a multischema database. NOTE Use of the CREATE SCHEMA statement to create a database is a deprecated feature. If you specify physical attributes of a database such as the root file parameters, you receive an informational message, but SQL creates the database anyway. SQL> CREATE SCHEMA FILENAME TEST SNAPSHOT IS DISABLED; %SQL-I-DEPR_FEATURE, Deprecated Feature: SCHEMA (meaning DATABASE) If you do not specify any physical attributes, you may receive an error message noting that you must enable multischema naming. SQL> CREATE SCHEMA PARTS %SQL-F-SCHCATMULTI, Schemas and catalogs may only be referenced with multischema enabled A schema is a group of definitions within a database. The CREATE SCHEMA statement lets you specify in a single SQL statement all data and privilege definitions for a new schema. You can also add definitions to the schema later. A database, in addition to schema definitions, includes database system files and user data. If you need to specify any physical database characteristics such as the database root file or storage area parameters, use the CREATE DATABASE statement. See the CREATE DATABASE statement for more information. You can specify any number of optional schema elements to the CREATE SCHEMA statement. Schema elements are any of the CREATE statements (except CREATE STORAGE AREA, CREATE DOMAIN . . . FROM path-name, and CREATE TABLE . . . FROM path-name) or a GRANT statement. These statements require statement terminators, except when they are part of a CREATE SCHEMA or CREATE DATABASE statement. When you use these statements within a CREATE SCHEMA statement, use a statement terminator on the last schema element only. The first statement terminator that SQL encounters ends the CREATE SCHEMA statement. Later CREATE or GRANT statements are not within the scope of the CREATE SCHEMA statement.
14.1 – Environment
You can use the CREATE SCHEMA statement: o In interactive SQL o Embedded in host language programs to be precompiled o As part of a procedure in an SQL module o In dynamic SQL as a statement to be dynamically executed
14.2 – Format
(B)0[m[1;4mCREATE[m[1m [1;4mSCHEMA[m[1m qwq> <schema-name> qqqqqqqqqqqqqqqqqqqqqqqqqwqk [m [1m tq> [1;4mAUTHORIZATION[m[1m <auth-id> qqqqqqqqqqqqqqqu x [m [1m mq> <schema-name> [1;4mAUTHORIZATION[m[1m <auth-id> qj x [m [1m lqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1m mqwqqqqqqqqqqqqqqqqqqqqqqqqqwqqqqqqqqqqqqqqq> [m [1m mqwqq> schema-element qqwqj [m [1m mqqqqqqqqqq<qqqqqqqqqqj [m [1m [m (B)0[m[1mschema-name = [m [1m [m [1mqqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqq[mqqqqqqqq[1mqk [m [1m tqqqqqq> <catalog-name> qqqqqqqqqqq[mqq[1mqwq>. qqqu [m [1m tq> " q> <alias>.<catalog-name> q>"[m [1mqqj [m [1mx [m [1m x lqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1m x mqqqqqqqqqqqqqq> <name-of-schema> qqqqqqwq> [m [1m mq> " q> <alias>.<name-of-schema> q>" qqqqqqj [m [1m [m (B)0[m[1mschema-element = [m [1m [m [1mqwq> create-collating-sequence-statement qwq> [m [1m tq> create-domain-statement qqqqqqqqqqqqqu [m [1mtq> create-index-statement qqqqqqqqqqqqqqu[m [1mtq> create-sequence-statement qqqqqqqqqqqu[m [1mtq> create-storage-map-statement qqqqqqqqu[m [1m tq> create-table-statement qqqqqqqqqqqqqqu [m [1m tq> create-trigger-statement qqqqqqqqqqqqu [m [1m tq> create-view-statement qqqqqqqqqqqqqqqu [m [1m mq> grant-statement qqqqqqqqqqqqqqqqqqqqqj [m [1m [m
14.3 – Arguments
14.3.1 – AUTHORIZATION auth id
If you do not specify a schema name, the authorization identifier specifies the default schema. If you want to comply with the ANSI/ISO 1989 standard, specify the AUTHORIZATION clause without the schema name. Specify both the AUTHORIZATION clause and the schema name to comply with the current ANSI/ISO SQL standard.
14.3.2 – create-collating-sequence-statement
See the CREATE COLLATING_SEQUENCE statement for details. If you want to specify a collating sequence in a CREATE DOMAIN statement embedded in a CREATE SCHEMA statement, you must first specify a CREATE COLLATING SEQUENCE statement within the same CREATE SCHEMA statement.
14.3.3 – create-domain-statement
See the CREATE DOMAIN statement for details. You cannot use the FROM path-name clause when embedding a CREATE DOMAIN statement in a CREATE SCHEMA statement. You can, however, issue a separate CREATE DOMAIN statement following the CREATE SCHEMA statement. You can also describe the domain directly within the CREATE SCHEMA statement. If you want to specify a collating sequence in your embedded CREATE DOMAIN statement, you must first specify a CREATE COLLATING SEQUENCE statement within the same CREATE SCHEMA statement.
14.3.4 – create-function-statement
See the CREATE Routine statement for details.
14.3.5 – create-index-statement
See the CREATE INDEX statement for details.
14.3.6 – create-module-statement
See the CREATE MODULE statement for details.
14.3.7 – create-procedure-statement
See the CREATE Routine statement for details.
14.3.8 – create-sequence-statement
See the CREATE SEQUENCE statement for details.
14.3.9 – create-storage-map-statement
See the CREATE STORAGE_MAP statement for details.
14.3.10 – create-table-statement
See the CREATE TABLE statement for details. You cannot use the FROM path-name clause when embedding a CREATE TABLE statement in a CREATE SCHEMA statement. You can, however, issue a separate CREATE TABLE statement following the CREATE SCHEMA statement. You can also describe the table directly within the CREATE SCHEMA statement. The CREATE TABLE statements in a CREATE SCHEMA statement can refer to domains not yet created, provided that CREATE DOMAIN statements for the domains are in the same CREATE SCHEMA statement.
14.3.11 – create-trigger-statement
See the CREATE TRIGGER statement for details.
14.3.12 – create-view-statement
See the CREATE VIEW statement for details.
14.3.13 – grant-statement
See the GRANT statement for details.
14.3.14 – schema-element
Some CREATE statements or a GRANT statement.
14.3.15 – schema-name
Specifies the name of the schema created by the CREATE SCHEMA statement. You can qualify the schema name with either a catalog name or the catalog name qualified by the alias. You must enclose the alias and catalog name in double quotation marks and separate them with a period. You must issue the SET QUOTING RULES statement before you specify the alias and catalog name pair, or SQL issues an error message about the use of double quotation marks. For information on qualifying schema names with aliases and catalog names, see the User_Supplied_Names HELP topic.
14.4 – Example
Example 1: Creating a schema within a multischema database The following interactive statements create a database that contains a schema within a catalog. You issue the CREATE SCHEMA statement alone or as part of a CREATE DATABASE statement. SQL> SET DIALECT 'SQL99'; SQL> CREATE DATABASE ALIAS PERS_ALIAS FILENAME personnel MULTISCHEMA IS ON; SQL> CREATE CATALOG "PERS_ALIAS.ADMIN"; SQL> CREATE SCHEMA "PERS_ALIAS.ADMIN".PAYROLL; SQL> SHOW SCHEMAS; Schemas in database PERS_ALIAS "PERS_ALIAS.ADMIN".PAYROLL "PERS_ALIAS.RDB$CATALOG".RDB$SCHEMA
15 – SEQUENCE
Creates a sequence. A sequence is a database object from which multiple users can generate unique integers. You can use sequences to automatically generate primary key values.
15.1 – Environment
You can use the CREATE SEQUENCE statement: o In interactive SQL o Embedded in host language programs o As part of a procedure in an SQL module or other compound statement o In dynamic SQL as a statement to be dynamically executed
15.2 – Format
(B)0[m[1;4mCREATE[m[1m [1;4mSEQUENCE[m[1m <sequence-name> qqqqqqqqqqqqqqqqqqk [m [1mlqqqqqqqqqqqqqqqqqqqq<qqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1mmqqqwqqqqqqqqqqqqqqqq>qqqqqqqqqqqqqqqqqqqqqqqqqwqqk [m [1m mqqq> [1;4mSTORED[m[1m [1;4mNAME[m[1m IS qqqq> <stored-name> qqj x [m [1mlqqqqqqqqqqqqqqqqqqqq<qqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1mmqwqqqqqqqqqqqqqqqqqq>qqqqqqqqqqqqqqqqqqqqqqqqqwqq> [m [1m mqwqwqqq> sequence-attributes qqqqqqqqwqwqqqqj [m [1m x mqqq> [1;4mSTART[m[1m [1;4mWITH[m[1m <numeric-value> qj x [m [1m mqqqqqqqqqqqqqqqqqq<qqqqqqqqqqqqqqqqqqj [m (B)0[m[1msequence-attributes = [m [1m [m [1m qqwqq> [1;4mINCREMENT[m[1m [1;4mBY[m[1m <numeric-value> qqqqqqqqqwq>[m [1m tqq> sequence-range qqqqqqqqqqqqqqqqqqqqqqqu [m [1m tqq> [1;4mCYCLE[m[1m qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu [m [1m tqq> [1;4mNOCYCLE[m[1m qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu [m [1m tqq> [1;4mCACHE[m[1m <numeric-value> qqqqqqqqqqqqqqqqu [m [1m tqq> [1;4mNOCACHE[m[1m qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu [m [1m tqq> [1;4mORDER[m[1m qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu [m [1m tqq> [1;4mNOORDER[m[1m qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu [m [1m tqq> [1;4mRANDOMIZE[m[1m qqqqqqqqqqqqqqqqqqqqqqqqqqqqu [m [1m tqq> [1;4mNORANDOMIZE[m[1m qqqqqqqqqqqqqqqqqqqqqqqqqqu [m [1mtqq> [1;4mRESTART[m[1m [1;4mWITH[m[1m qqqqqqqqqqqqqqqqqqqqqqqqqu[m [1mtqq> [1;4mWAIT[m[1m qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu[m [1mtqq> [1;4mNOWAIT[m [1mqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu[m [1mtqq> [1;4mDEFAULT[m [1;4mWAIT[m[1m qqqqqqqqqqqqqqqqqqqqqqqqqu[m [1m mqq> [1;4mCOMMENT[m[1m qwqqqqqqqwqqwq> '<string>' qwqj [m [1m mq> IS qj mqqqqqq / <qqqqqj [m (B)0[m[1msequence-range = [m [1m [m [1mqwq> [1;4mMINVALUE[m[1m qwqwqq> <numeric-value> qwqqwqq> [m [1m tq> [1;4mMAXVALUE[m[1m qj tqq> [1;4mTINYINT[m[1m [m [1mqqqqu [m [1mx [m [1m x tqq> [1;4mSMALLINT[m [1m qqqu [m [1mx [m [1m x tqq> [1;4mINTEGER[m[1m [m [1mqqqqu [m [1mx [m [1mx[m [1mmqq> [1;4mBIGINT[m[1m [m [1mqqqqqj[m [1mx[m [1mtq>[m [1;4mNOMINVALUE[m [1mqqqqqqqqqqqqqqqqqqqqqqqqqqu[m [1mmq>[m [1;4mNOMAXVALUE[m [1mqqqqqqqqqqqqqqqqqqqqqqqqqqj[m
15.3 – Arguments
15.3.1 – CACHE
Syntax options: CACHE numeric-value | NOCACHE The CACHE clause specifies how many values of the sequence Oracle Rdb should preallocate and keep in memory for faster access. The numeric value must be between 2 and 2147483647. You cannot cache more values than will fit in a given cycle of sequence numbers; thus, the maximum value allowed for the CACHE clause must be less than the value resulting from the following formula: (MAXVALUE-MINVALUE)/ABS(INCREMENT) The SET FLAGS option SEQ_CACHE can be used to override the setting of CACHE at runtime. See the SET_FLAGS statement for more details. A cache for a given sequence is populated at the first request for a number from that sequence, and whenever a value is requested when the cache is empty. If a system failure occurs, or when the cache is released any unfetched values will be discarded. The maximum number of lost values is equal to the current cache size. This may be the value specified by CACHE or by the SET FLAGS SEQ_CACHE option. The NOCACHE clause specifies that values will be allocated one at a time. This will require more I/O to the Rdb root file than using a CACHE value. By default, Oracle Rdb caches 20 sequence values.
15.3.2 – COMMENT IS 'string '
Adds a comment about the sequence. SQL displays the text of the comment when it executes a SHOW SEQUENCE statement. Enclose the comment in single quotation marks (') and separate multiple lines in a comment with a slash mark (/).
15.3.3 – CYCLE
Syntax options: CYCLE | NOCYCLE The CYCLE clause specifies that the sequence is to continue generating values after reaching either the MINVALUE or MAXVALUE. After an ascending sequence reaches the MAXVALUE, the sequence starts again from its MINVALUE. After a descending sequence reaches its MINVALUE, the sequence starts again at its MAXVALUE. The NOCYCLE clause specifies that the sequence should not continue generating values after reaching either its minimum or maximum value. An error is generated if an attempt is made to increment the sequence beyond its limits. The NOCYCLE clause is the default.
15.3.4 – INCREMENT BY numeric-value
Specifies the size of the increment and the direction (ascending or descending) of the sequence. This numeric value must be in the range -2147483648 through 2147483647, excluding 0. The absolute value must be less than the difference of MAXVALUE and MINVALUE. A negative value specifies a descending sequence; a positive value specifies an ascending sequence. By default, the numeric value is 1.
15.3.5 – MAXVALUE
Syntax options: MAXVALUE numeric-value | NOMAXVALUE The MAXVALUE clause specifies the maximum signed quadword (BIGINT) value that the sequence can generate. The numeric value must be between -9223372036854775808 and 9223372036854775808. The MAXVALUE must be equal to or greater than the value specified for the START WITH clause and greater than the value specified with the MINVALUE clause. The NOMAXVALUE clause specifies that the maximum value for an ascending sequence is 9223372036854775808 (plus the cache size) and -1 for a descending sequence. The NOMAXVALUE clause is the default.
15.3.6 – MAXVALUE integer
Syntax options: MAXVALUE TINYINT MAXVALUE SMALLINT MAXVALUE INTEGER MAXVALUE BIGINT SQL allows the keyword TINYINT, SMALLINT, INTEGER and BIGINT to follow MAXVALUE instead of a numeric value. This allows easy range setting for sequences used with these data types. The value supplied will be the largest positive value that can be assigned to this data type.
15.3.7 – MINVALUE
Syntax options: MINVALUE numeric-value | NOMINVALUE The MINVALUE clause specifies the minimum signed quadword (BIGINT) value that the sequence can generate. The numeric value must be equal to or greater than -9223372036854775808. The MINVALUE must be less than or equal to the value specified with the START WITH clause and less than the value specified with the MAXVALUE clause. The NOMINVALUE clause specifies that the minimum value for an ascending sequence is 1, and -9223372036854775808 (plus the cache size) for a descending sequence. The NOMINVALUE clause is the default.
15.3.8 – MINVALUE integer-value
Syntax options: MINVALUE TINYINT MINVALUE SMALLINT MINVALUE INTEGER MINVALUE BIGINT SQL allows the keyword TINYINT, SMALLINT, INTEGER and BIGINT to follow MINVALUE instead of a numeric value. This allows easy range setting for sequences used with these data types. The value supplied will be the smallest negative value that can be assigned to this data type.
15.3.9 – ORDER
Syntax options: ORDER | NOORDER The ORDER clause specifies that sequence numbers are guaranteed to be assigned in order for each requesting process, thus maintaining a strict history of requests. The NOORDER clause specifies that sequence numbers are not guaranteed to be generated in order of request. The NOORDER clause is the default.
15.3.10 – RANDOMIZE
Syntax options: RANDOMIZE | NORANDOMIZE The RANDOMIZE clause specifies that the sequence numbers are to be returned with a random value in the most significant bytes of the BIGINT value. This allows unique values to be generated that have a random distribution. When you specify the NORANDOMIZE clause, sequence numbers are close in value to others created at the same time. The advantage of the RANDOMIZE clause is that updates to columns of a sorted index to which these values are written occur in different locations in the index structure. This may improve concurrent access for large indexes as leaf nodes in different parts of the index can be updated independently. In contrast, the sequence numbers generated when you specify the NORANDOMIZE clause (which are likely to be close in numeric value to other sequences) result in index updates that occur in the same or nearby index nodes, which may lead to contention in one part of the sorted index. The full range of values in the BIGINT value returned for the sequence are used; therefore, the NOMAXVALUE and NOMINVALUE clauses must be specified (or defaulted to) for the sequence definition. The most significant bits of the BIGINT value are set to a randomly generated positive value. A generated distinct value is returned in the least significant 32 bits so that uniqueness is guaranteed. If you also specify the CYCLE clause, then only the least significant 32 bits are cycled. When a query is performed on the column RDB$NEXT_SEQUENCE_VALUE in the RDB$SEQUENCES table, only the generated value of the least significant bits is returned, because the most significant bits are not assigned until the NEXTVAL pseudocolumn is referenced. If you specify RANDOMIZE, you cannot also specify ORDER, MAXVALUE, or MINVALUE. The NORANDOMIZE clause is the default.
15.3.11 – sequence-name
The name of the sequence that you want to create. Use a name that is unique among all sequence, synonym, table, and view names in the database, or in the schema if you are using a multischema database. Use any valid SQL name.
15.3.12 – START WITH numeric-value
Specifies the initial numeric value to be used for the sequence. This value must be in the range specified by (or defaulted to) the other sequence attribute clauses. Valid values are in the range -9223373036854775808 to 9223372036854775807. If omitted, the START WITH value defaults to the value of MINVALUE for ascending sequences and MAXVALUE for descending sequences.
15.3.13 – STORED NAME IS stored-name
Specifies a name that Oracle Rdb uses to access a sequence created in a multischema database. The stored name allows you to access multischema definitions using interfaces, such as Oracle RMU, that do not recognize multiple schemas in one database. You cannot specify a stored name for a sequence in a database that does not allow multiple schemas.
15.3.14 – WAIT
Syntax options: WAIT | NOWAIT | DEFAULT WAIT Specifies what wait state is used when a reference to NEXTVAL is used. A reference to NEXTVAL for a sequence may require synchronization with other users of the sequence. When you specify DEFAULT WAIT, the wait state (WAIT or NOWAIT) of the current transaction is used. This may mean that no waiting is performed during a NOWAIT transaction. If you specify WAIT (the default) for the sequence, then regardless of the wait state set for the current transaction, all synchronization waits for the next value. This is the recommended setting if the application uses NOWAIT transactions. The current WAIT timeout interval defined for the transaction or database is used. If you specify NOWAIT for the sequence, then regardless of the current transaction setting, all synchronization does not wait for the next value.
15.4 – Examples
Example 1: Creating a Sequence SQL> -- This example creates a new sequence using the default SQL> -- values for NOMINVALUE, NOMAXVALUE, INCREMENT BY 1, NOCYCLE, SQL> -- and CACHE 20. The START WITH value is set to 147. SQL> -- Allyn Stuart will be assigned an EMPLOYEE_ID value of 147. SQL> -- Nick Jones will be assigned an EMPLOYEE_ID of 148. SQL> -- SQL> CREATE SEQUENCE EMPID START WITH 00147; SQL> -- Use NEXTVAL to fetch a sequence number for the primary key column. SQL> INSERT INTO EMPLOYEES cont> (EMPLOYEE_ID, LAST_NAME, FIRST_NAME) cont> VALUES (EMPID.NEXTVAL, 'STUART', 'ALLYN') cont> RETURNING EMPLOYEE_ID; EMPLOYEE_ID 147 1 row inserted SQL> -- Use CURRVAL to reuse the EMPLOYEE_ID value for the foreign key columns SQL> -- in the associated tables. SQL> INSERT INTO SALARY_HISTORY cont> (EMPLOYEE_ID, SALARY_AMOUNT,SALARY_START, SALARY_END) cont> VALUES (EMPID.CURRVAL, 35000, '6-FEB-1998', NULL) cont> RETURNING EMPLOYEE_ID; EMPLOYEE_ID 147 1 row inserted SQL> INSERT INTO JOB_HISTORY cont> (EMPLOYEE_ID, DEPARTMENT_CODE, JOB_START, JOB_END) cont> VALUES (EMPID.CURRVAL, 'ENGR', '6-FEB-1998', NULL) cont> RETURNING EMPLOYEE_ID; EMPLOYEE_ID 147 1 row inserted SQL> INSERT INTO EMPLOYEES cont> (EMPLOYEE_ID, LAST_NAME, FIRST_NAME) cont> VALUES (EMPID.NEXTVAL, 'JONES ', 'NICK ') cont> RETURNING EMPLOYEE_ID; EMPLOYEE_ID 148 1 row inserted
16 – STORAGE_AREA
NOTE You cannot issue CREATE STORAGE AREA as an independent statement. It is a clause allowed only as part of a CREATE DATABASE or IMPORT statement. You can also create a storage area using the ADD STORAGE AREA clause of the ALTER DATABASE statement. Creates additional storage areas in a multifile database. Storage areas are data and snapshot files that are associated with particular tables in a multifile database. A CREATE STORAGE AREA clause specifies the names for the storage area files and determines their physical characteristics. Subsequent CREATE STORAGE MAP statements associate the storage area with particular tables in the database.
16.1 – Environment
You can use the CREATE STORAGE AREA clause only within a CREATE DATABASE or IMPORT statement.
16.2 – Format
(B)0[m[1;4mCREATE[m[1m [1;4mSTORAGE[m[1m [1;4mAREA[m[1m qwq> <area-name> qwqwqqqqqqqqqqqqqqqqqqqqqqqqqwk [m [1m mq> [1;4mRDB$SYSTEM[m[1m qqj mq> [1;4mFILENAME[m[1m <file-spec> qjx [m [1m lqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1m mwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqwq> [m [1m mqwqwq> storage-area-params-1 qu x [m [1m x mq> storage-area-params-2 qj x [m [1m mqqqqqqqqqqqqqqq <qqqqqqqqqqqqqj [m [1m [m (B)0[m[1mstorage-area-params-1 = [m [1m [m [1mqqwq> [1;4mALLOCATION[m[1m IS qqq> <number-pages> qq> PAGES qqqqqwq>[m [1m tq> [1;4mCACHE[m[1m [1;4mUSING[m[1m <row-cache-name> qqqqqqqqqqqqqqqqqqqqu [m [1m tq> [1;4mNO[m[1m ROW [1;4mCACHE[m[1m qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu [m [1m tq> extent-params qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu [m [1m tq> [1;4mINTERVAL[m[1m IS qq> <number-data-pages> qqqqqqqqqqqqqu [m [1m tq> [1;4mLOCKING[m[1m IS qqwq> [1;4mROW[m[1m qqwqq> LEVEL qqqqqqqqqqqqqqqu [m [1m x mq> [1;4mPAGE[m[1m qj x [m [1m tq> [1;4mPAGE[m[1m [1;4mFORMAT[m[1m IS wq> [1;4mUNIFORM[m[1m qwqqqqqqqqqqqqqqqqqqqqu [m [1m x mq> [1;4mMIXED[m[1m qqqj x [m [1m mq> [1;4mPAGE[m[1m [1;4mSIZE[m[1m IS qqqq> <page-blocks> qq> BLOCKS qqqqqj [m [1m [m (B)0[m[1mextent-params = [m [1m [m [1mqqwq> [1;4mEXTENT[m[1m IS qwq> [1;4mENABLED[m[1m qqqqqqqqqqqqqqqqqqqwwqq> [m [1m x tq> [1;4mDISABLED[m[1m qqqqqqqqqqqqqqqqqqux [m [1m x tq> <extent-pages> qq> PAGES qqux [m [1m x mq> (extension-options) qqqqqqqjx [m [1m mqqqqqqqqqqqqqqqqqqqqq<qqqqqqqqqqqqqqqqqqqqqqqqj [m [1m [m (B)0[m[1mextension-options = [m [1m [m [1mqqq> [1;4mMINIMUM[m[1m OF <min-pages> PAGES, qqk [m [1mlqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1mmqq> [1;4mMAXIMUM[m[1m OF <max-pages> PAGES, qqk [m [1mlqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1mmqq> [1;4mPERCENT[m[1m [1;4mGROWTH[m[1m IS <growth> qqqqqqq> [m [1m [m (B)0[m[1mstorage-area-params-2 = [m [1m [m [1mqqwq> [1;4mCHECKSUM[m[1m CALCULATION IS qqqqqqqqqqqwqqwq> [1;4mENABLED[m[1m qqwqwq>[m [1m tq> [1;4mSNAPSHOT[m[1m [1;4mCHECKSUM[m[1m CALCULATION IS qqj mq> [1;4mDISABLED[m[1m qj x [m [1m tq> [1;4mSNAPSHOT[m[1m [1;4mALLOCATION[m[1m IS qq> <snp-pages> qqqq> PAGES qqqu [m [1m tq> [1;4mSNAPSHOT[m[1m [1;4mEXTENT[m[1m IS qwq> <extent-pages> qqqq> PAGES qqwu [m [1m x mq> (extension-options) qqqqqqqqqjx [m [1m tq> [1;4mSNAPSHOT[m[1m [1;4mFILENAME[m[1m qq> <file-spec> qqqqqqqqqqqqqqqqqqqqu [m [1m tq> [1;4mTHRESHOLDS[m[1m ARE ( <val1> wqqqqqqqqqqqqqqqqqqqqqqqw> ) qu [m [1m x m> ,<val2> qwqqqqqqqqqqwj x [m [1m x m> ,<val3> j x [m [1m mq[mqqqqqqqqqqqqqqqqqqqqqqqqqqqqq[1m<qqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1m [m
16.3 – Arguments
16.3.1 – ALLOCATION_PAGES
Syntax option: ALLOCATION IS number-pages PAGES The number of database pages initially allocated to the storage area. Rdb will automatically extend this allocation to account for internal structure pages, such as SPAM (spage management) pages. For example, an allocation of 25 will be increased to 27 as shown in this example: SQL> alter database filename MF_PERSONNEL cont> add storage area DOC_EXAMPLE cont> page format is uniform cont> allocation 25; SQL> attach 'filename MF_PERSONNEL'; SQL> show storage area DOC_EXAMPLE DOC_EXAMPLE Access is: Read write Page Format: Uniform Page Size: 2 blocks Area File: USER_DISK:[DOC.DATABASES]DOC_EXAMPLE.RDA;1 Area Allocation: 27 pages Extent: Enabled Area Extent Minimum: 99 pages Area Extent Maximum: 9999 pages Area Extent Percent: 20 percent Snapshot File: USER_DISK:[DOC.DATABASES]DOC_EXAMPLE.SNP;1 Snapshot Allocation: 100 pages Snapshot Extent Minimum: 99 pages Snapshot Extent Maximum: 9999 pages Snapshot Extent Percent: 20 percent Locking is Row Level No Cache Associated with Storage Area No database objects use Storage Area DOC_EXAMPLE
16.3.2 – CACHE USING row cache name
Assigns the named row cache to the specified storage area. All rows stored in this area, whether they consist of table data, segmented string data, or special rows such as index nodes, are cached if those rows fit in the cache. If the row cache does not exist, you must create the row cache before terminating the CREATE DATABASE statement. For example: SQL> CREATE DATABASE FILENAME test_db cont> ROW CACHE IS ENABLED cont> CREATE STORAGE AREA area1 cont> CACHE USING test1 cont> CREATE CACHE test1 cont> CACHE SIZE IS 100 ROWS cont> ROW LENGTH IS 200 BYTES; Only one row cache is allowed for each storage area. NO ROW CACHE is the default for a storage area.
16.3.3 – CHECKSUM_CALCULATION
Syntax options: CHECKSUM CALCULATION | SNAPSHOT CHECKSUM CALCULATION This option allows you to enable or disable calculations of page checksums when pages are read from or written to the storage or snapshot area files. The default is ENABLED. NOTE Oracle Corporation recommends that you leave checksum calculations enabled; which is the default. With current technology, it is possible that errors may occur that the checksum calculation can detect but that may not be detected by either the hardware, firmware, or software. Unexpected application results and database corruption may occur if corrupt pages exist in memory or on disk but are not detected. Oracle Corporation recommends performing checksum calculations, except in the following specific circumstances: o Your application is stable and has run without errors on the current hardware and software configuration for an extended period of time. o You have reached maximum CPU utilization in your current configuration. Actual CPU utilization by the checksum calculation depends primarily on the size of the database pages in your database. The larger the database page, the more noticeable the CPU usage by the checksum calculation may become. NOTE Oracle Corporation recommends that you carefully evaluate the trade-off between reducing CPU usage by the checksum calculation and the potential for loss of database integrity if checksum calculations are disabled. Oracle Rdb allows you to disable and, subsequently, re-enable checksum calculation without error. However, once checksum calculations have been disabled, corrupt pages may not be detected even if checksum calculations are subsequently re- enabled.
16.3.4 – EXTENT
Syntax options: EXTENT ENABLED | EXTENT DISABLED Enables or disables extents. Extents are ENABLED by default. You may encounter performance problems when creating hashed indexes in storage areas with the mixed page format if the storage area was created specifying the incorrect size for the area and if extents are enabled. By disabling extents, this problem can be diagnosed early and corrected to improve performance.
16.3.5 – EXTENT_IS
Syntax options: EXTENT IS extent-pages PAGES | EXTENT IS (extension-options) Specifies the number of pages of each storage area file extent. See also the description under the SNAPSHOT EXTENT argument.
16.3.6 – FILENAME file spec
Provides an explicit file specification for storage area files. The CREATE STORAGE AREA clause creates two files: a storage area file with a file extension of .rda, and a snapshot file with a file extension of .snp. If you omit the FILENAME argument, the file specification takes the following defaults: o Device: the current device for the process o Directory: the current directory for the process o File name: the name specified for the storage area Neither the file specification for the storage area nor the snapshot file may contain a node specification. The file specification is used for both the storage area and snapshot files that comprise the storage area (unless you use the SNAPSHOT FILENAME argument to specify a different file for the snapshot file). Because the CREATE STORAGE AREA clause can create two files with different file extensions, do not specify a file extension with the file specification. You may use a logical name for all or part of a file specification. One benefit of a multifile database is that its files can reside on more than one disk. If you want storage area files to reside on another disk, you must specify the FILENAME argument with a full file specification. However, you may choose to create a multifile database even if your main purpose in creating the storage area is not to distribute storage area files across more than one disk. For instance, a multifile database enables you to: o Take advantage of hashed indexes. Hashed indexes require a storage area with mixed page format and cannot be stored in the RDB$SYSTEM storage area. o Set attributes such as page size to better correspond with tables that will be stored in the storage area.
16.3.7 – INTERVAL
Syntax options: INTERVAL IS number-data-pages Specifies the number of data pages between SPAM pages in the storage area file, and thus the maximum number of data pages each SPAM page manages. The default, and also the minimum interval, is 216 data pages. The first page of each storage area is a SPAM page. The interval you specify determines where subsequent SPAM pages are to be inserted if there are enough data pages in the storage file to require more SPAM pages. You cannot specify the INTERVAL storage area parameter unless you also explicitly specify PAGE FORMAT IS MIXED. Oracle Rdb calculates the maximum INTERVAL size based on the number of blocks per page, and returns an error message if you exceed this value. For example, when the page size is 2 blocks, the maximum INTERVAL is 4008 pages. If you try to create a storage area with the INTERVAL set to 4009, Oracle Rdb returns the following error message: %RDB-E-BAD_DPB_CONTENT, invalid database parameters in the database parameter block (DPB) -RDMS-F-SPIMAX, spam interval of 4009 is more than the Rdb maximum of 4008 -RDMS-F-AREA_NAME, area NEW For more information about setting space area management parameters, see the Oracle Rdb Guide to Database Maintenance.
16.3.8 – LOCKING level
Syntax options: LOCKING IS ROW LEVEL | LOCKING IS PAGE LEVEL Specifies if locking is at the page or row level for the storage area. This clause provides an alternative to requesting locks on records. Specifying a lock level when you create a storage area overrides the database default lock level. The default is ROW LEVEL. When many records are accessed in the same area and on the same page, the LOCKING IS PAGE LEVEL clause reduces the number of lock operations performed to process a transaction; however, this is at the expense of reduced concurrency because these pages' locks are held until COMMIT/ROLLBACK. Transactions that benefit most with page-level locking are of short duration and also access several database records on the same page. However, to guarantee consistency of the data in the absence of row locking these page level locks must be held until the transaction ends with COMMIT or ROLLBACK. Use the LOCKING IS ROW LEVEL if transactions are long in duration and lock many rows. The LOCKING IS PAGE LEVEL clause causes fewer blocking ASTs and provides better response time and utilization of system resources. However, there is a higher contention for pages and increased potential for deadlocks and long transactions may use excessive locks. Page-level locking is never applied to RDB$SYSTEM or the DEFAULT storage-area, either implicitly or explicitly, because the locking protocol can stall metadata users. You cannot specify page-level locking on single-file databases.
16.3.9 – MAXIMUM_PAGES
Syntax options: MAXIMUM OF max-pages PAGES Specifies the maximum number of pages of each extent. The default is 9,999 pages.
16.3.10 – MINIMUM_PAGES
Syntax options: MINIMUM OF min-pages PAGES Specifies the minimum number of pages of each extent. The default is 99 pages.
16.3.11 – NO_ROW_CACHE
Specifies that a row cache is not assigned to the specified storage area in the database. You cannot specify the NO ROW CACHE clause if you specify the CACHE USING clause. Alter the storage area and name a row cache with the CACHE USING clause to assign a row cache to the storage area or to override the database default. Only one row cache is allowed for each storage area.
16.3.12 – PAGE_FORMAT
Syntax options: PAGE FORMAT IS UNIFORM | PAGE FORMAT IS MIXED Specifies the on-disk structure for the storage area. o The default is PAGE FORMAT IS UNIFORM. A storage area with uniform page format is a file that is divided into groups of n pages, called clumps, where n equals the buffer size divided by the page size. Both buffer size and page size are user specified values. By default, the buffer size is 6 blocks, and the page size is 1024 bytes or 2 blocks long, resulting in clumps of three pages. The PAGE FORMAT IS UNIFORM argument creates a storage area file that is divided into clumps. A set of clumps forms a logical area that can contain rows from a single table or index only. Uniform page format storage areas generally give the best performance if the tables in the storage area are likely to be subject to a wide range of queries. o The PAGE FORMAT IS MIXED argument creates a storage area with a format that allows rows from more than one table to reside on or near a particular page of the storage area file. This is useful for storing related rows from different tables on the same page of the data file. For storage areas subject to repeated queries that retrieve those related rows, a mixed page format can greatly reduce input/output overhead if the mix of rows on the page is carefully controlled. However, mixed page format storage areas degrade performance if the mix of rows on the page is not suited for the queries made against the storage area. For more information on the relative advantages and disadvantages of uniform and mixed storage areas, see the Oracle Rdb Guide to Database Maintenance.
16.3.13 – PAGE SIZE blocks
Syntax options: PAGE SIZE IS page-blocks BLOCKS The size in blocks of each data page in the storage area. Page size is allocated in 512-byte blocks. The default is 2 blocks (1024 bytes). If your largest row is larger than approximately 950 bytes, allocate more blocks per page to prevent fragmented rows. If you specify a page size larger than the buffer size, an error message is returned.
16.3.14 – PERCENT_GROWTH
Syntax options: PERCENT GROWTH IS growth Specifies the percent growth of each extent. The default is 20 percent growth.
16.3.15 – SNAPSHOT_ALLOCATION
Syntax options: SNAPSHOT ALLOCATION IS snp-pages PAGES Specifies the number of pages allocated for the snapshot file. The default is 100 pages.
16.3.16 – SNAPSHOT_EXTENT
Syntax options: SNAPSHOT EXTENT IS extent-pages | SNAPSHOT EXTENT IS (extension- options) Specifies the number of pages of each snapshot or storage area file extent. The default extent for storage area files is 100 pages. Specify a number of pages for simple control over the extension. For greater control, and particularly for multivolume databases, use the MIN, MAX, and PERCENT GROWTH extension options instead. If you use the MIN, MAX, and PERCENT GROWTH parameters, you must enclose them in parentheses.
16.3.17 – SNAPSHOT_FILENAME
Syntax options: SNAPSHOT FILENAME file-spec Provides a separate file specification for the snapshot file. The SNAPSHOT FILENAME argument can only be specified with multifile databases. This argument lets you specify a different file name, device, or directory for the snapshot file created by the CREATE STORAGE AREA clause. Do not specify a file extension other than .snp to the file specification. Oracle Rdb assigns the extension .snp to the file specification, even if you specify an alternate extension. If you omit the SNAPSHOT FILENAME argument, the snapshot file gets the same device, directory, and file name as the storage area file.
16.3.18 – STORAGE_AREA
Specifies the name of the storage area you want to create. The name cannot be the same as any other storage area definition in the database.
16.3.19 – STORAGE_AREA_RDB$SYSTEM
Specifies that you want the CREATE STORAGE AREA clause to override the default characteristics for the main storage area, RDB$SYSTEM, in a new database. The RDB$SYSTEM storage area contains database system tables and indices. If an alternate DEFAULT STORAGE AREA is not assigned then this area may also contain unmapped user tables and indices.
16.3.20 – THRESHOLDS values
Syntax options: THRESHOLDS ARE ( val1 [,val2 [,val3] ] ) Specifies one, two, or three threshold values for mixed format pages. The threshold values represent a fullness percentage on a data page and establish three possible ranges of guaranteed free space on the data pages. When a data page reaches the percentage defined by a given threshold value, the space area management (SPAM) entry for the data page is updated to reflect the new fullness percentage and its remaining free space. The default threshold values for mixed areas, if not specified, are (70,85,95), which indicates that the nominal record size should be used for SPAM threshold calculations. Oracle Rdb never stores a record on a page at the third threshold. The value you set for the highest threshold can be used to reserve space on the page for future record growth. When only val1 is specified, this is equivalent to (val1, 100, 100). When val1 and val2 are specified, this is equivalent to (val1, val2, 100). The trailing, unspecified thresholds default to 100 percent. For example, THRESHOLDS ARE (40) would appear as (40, 100, 100). You cannot specify the THRESHOLDS storage area parameter unless you also explicitly specify PAGE FORMAT IS MIXED. For more information about setting space area management parameters, see the Oracle Rdb Guide to Database Maintenance.
16.4 – Examples
Example 1: Defining a multifile database This example shows the definition of a database and storage areas for a multifile database. SQL> -- Note that there is no semicolon before SQL> -- the first CREATE STORAGE AREA clause. SQL> CREATE DATABASE ALIAS MULTIFILE_EXAMPLE cont> FILENAME 'DB_DATA01:[DB.DATA]MULTIFILE_EXAMPLE' cont> CREATE STORAGE AREA EMPID_LOW cont> FILENAME 'DB_DATA02:[DB.DATA]EMPID_LOW' cont> ALLOCATION IS 10 PAGES cont> -- Notice that the snapshot file resides on a cont> -- different disk than the storage area file. This cont> -- strategy reduces disk input/output bottlenecks: cont> SNAPSHOT FILENAME 'DB_SNAP03:[DB.SNAP]EMPID_LOW' cont> SNAPSHOT ALLOCATION IS 10 PAGES cont> -- cont> CREATE STORAGE AREA EMPID_MID cont> FILENAME 'DB_DATA04:EMPID_MID' cont> ALLOCATION IS 10 PAGES cont> SNAPSHOT FILENAME 'DB_SNAP05:[DB.SNAP]EMPID_MID' cont> SNAPSHOT ALLOCATION IS 10 PAGES cont> -- cont> CREATE STORAGE AREA EMPID_OVER cont> FILENAME 'DB_DATA06:[DB.DATA]EMPID_OVER' cont> ALLOCATION IS 10 PAGES cont> SNAPSHOT FILENAME 'DB_SNAP07:[DB.SNAP]EMPID_OVER' cont> SNAPSHOT ALLOCATION IS 10 PAGES cont> -- cont> CREATE STORAGE AREA HISTORIES cont> FILENAME 'DB_DATA02:[DB.DATA]HISTORIES' cont> ALLOCATION IS 10 PAGES cont> SNAPSHOT FILENAME 'DB_SNAP03:[DB.SNAP]HISTORIES' cont> SNAPSHOT ALLOCATION IS 10 PAGES cont> -- cont> CREATE STORAGE AREA CODES cont> FILENAME 'DB_DATA04:[DB.DATA]CODES' cont> ALLOCATION IS 10 PAGES cont> SNAPSHOT FILENAME 'DB_SNAP05:[DB.SNAP]CODES' cont> SNAPSHOT ALLOCATION IS 10 PAGES cont> -- cont> CREATE STORAGE AREA EMP_INFO cont> FILENAME 'DB_DATA08:[DB.DATA]EMP_INFO' cont> ALLOCATION IS 10 PAGES cont> SNAPSHOT FILENAME 'DB_SNAP09:[DB.SNAP]EMP_INFO' cont> SNAPSHOT ALLOCATION IS 10 PAGES cont> -- cont> -- End the CREATE DATABASE statement: cont> ; Example 2: This example shows how to set page-level and row-level locking on storage areas from both the database level and from the storage area level. SQL> CREATE DATABASE FILENAME sample cont> LOCKING IS PAGE LEVEL cont> -- cont> -- All storage areas will default to page-level locking unless cont> -- explicitly set to row-level locking. cont> -- cont> CREATE STORAGE AREA RDB$SYSTEM cont> FILENAME sample_system cont> -- cont> -- You cannot specify page-level locking on RDB$SYSTEM. RDB$SYSTEM cont> -- always defaults to row-level locking. cont> -- cont> CREATE STORAGE AREA HASH_AREA cont> FILENAME sample_hash cont> PAGE FORMAT IS MIXED cont> -- cont> -- HASH_AREA defaultS to page-level locking. cont> -- cont> CREATE STORAGE AREA DATA_AREA cont> FILENAME sample_data cont> LOCKING IS ROW LEVEL cont> -- cont> -- DATA_AREA is explicitly set to row-level locking. cont> -- cont> ; SQL> SHOW STORAGE AREAS (ATTRIBUTES) * Storage Areas in database with filename sample RDB$SYSTEM List storage area. Access is: Read write Page Format: Uniform Page Size: 2 blocks . . . Extent : Enabled Locking is Row Level HASH_AREA Access is: Read write Page Format: Mixed Page Size: 2 blocks . . . Extent : Enabled Locking is Page Level DATA_AREA Access is: Read write Page Format: Uniform Page Size: 2 blocks . . . Extent : Enabled Locking is Row Level See the SHOW statement for information on the SHOW STORAGE AREAS statement. Example 3: Creating and assigning a row cache to a storage area SQL> create database cont> filename SAMPLE_DB cont> reserve 2 cache slots cont> row cache is enabled cont> default storage area is AREA1 cont> create cache CACHE1 cont> cache size is 1000 rows cont> row length is 1000 bytes cont> create storage area AREA1 cont> cache using CACHE1 cont> ; SQL> show cache CACHE1 CACHE1 Cache Size: 1000 rows Row Length: 1000 bytes Row Replacement: Enabled Shared Memory: Process Large Memory: Disabled Window Count: 100 Working Set Count: 10 Reserved Rows: 20 Allocation: 100 blocks Extent: 100 blocks SQL> show storage area AREA1 AREA1 Access is: Read write Page Format: Uniform Page Size: 2 blocks Area File: USER_DISK:[DOC.DATABASES]AREA1.RDA;1 Area Allocation: 702 pages Extent: Enabled Area Extent Minimum: 99 pages Area Extent Maximum: 9999 pages Area Extent Percent: 20 percent Snapshot File: USER_DISK:[DOC.DATABASES]AREA1.SNP;1 Snapshot Allocation: 100 pages Snapshot Extent Minimum: 99 pages Snapshot Extent Maximum: 9999 pages Snapshot Extent Percent: 20 percent Locking is Row Level Using Cache CACHE1 Database objects using Storage Area AREA1: Usage Object Name Map / Partition ---------------- ------------------------------- ------------------------------- Default Area
17 – STORAGE_MAP
Associates a table with one or more storage areas in a multifile database. The CREATE STORAGE MAP statement specifies a storage map that controls which lists or rows of a table are stored in which storage areas. In addition to creating storage maps, the CREATE STORAGE MAP statement has options that control: o Which index the database system uses when inserting rows in the table o Whether or not the rows of the table are stored in a compressed format o Whether or not partitioning keys can be modified. o Whether the table is partitioned vertically, horizontally, or both. o Whether logging is enabled or disabled for the duration of this operation
17.1 – Environment
You can use the CREATE STORAGE MAP statement: o In interactive SQL o Embedded in host language programs to be precompiled o As part of a procedure in an SQL module o In dynamic SQL as a statement to be dynamically executed
17.2 – Format
(B)0[m[1;4mCREATE[m[1m [1;4mSTORAGE[m[1m [1;4mMAP[m[1m <map-name> qqk [m [1m lqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1m mwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqk [m [1m mq> [1;4mSTORED[m[1m [1;4mNAME[m[1m IS <stored-name> qqqj x [m [1m lqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1m t> [1;4mFOR[m[1m <table-name> wwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwwqk [m [1m x xtw> [1;4mENABLE[m[1m qw> [1;4mCOMPRESSION[m[1m qqqqqqqqqqqux x [m [1m x xxm> [1;4mDISABLE[m[1m j xx x [m [1m x xtq> [1;4mPLACEMENT[m[1m [1;4mVIA[m[1m [1;4mINDEX[m[1m <index-name> qux x [m [1m x xtq> partition-updatable-clause qqqqqqqux x [m [1m x xtq> threshold-clause qqqqqqqqqqqqqqqqqjx x [m [1m x xtq> [1;4mLOGGING[m[1m qqqqqqqqqqqqqqqqqqqqqqqqqqqu x [m [1m x xtq> [1;4mNOLOGGING[m[1m qqqqqqqqqqqqqqqqqqqqqqqqqu x [m [1m x xmq> [1;4mCOMMENT[m[1m [1;4mIS[m[1m qwq> '<string>' qqqwqqqqu x [m [1m x x mqqqqqqqq / <qqqqqj x x [m [1m x mqqqqqqqqqqqqqqqqq<qqqqqqqqqqqqqqqqqqqqqj x [m [1m x lqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1m x mqwqqqqqqqqqqqqqqqqqqqqqqwqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqq> [m [1mx[m [1mmq> partition-clause qqj[m [1mx[m [1m m> store-lists-clause qqqqqqqqqj [m (B)0[m[1mpartition-updatable-clause = [m [1m [m [1mqqq> [1;4mPARTITIONING[m[1m IS qwq> [1;4mNOT[m[1m [1;4mUPDATABLE[m[1m qwqq> [m [1m mq> [1;4mUPDATABLE[m[1m qqqqqj [m [1m [m (B)0[m[1mthreshold-clause = [m [1m [m [1mqqwq> [1;4mTHRESHOLD[m[1m qwq> IS qwq> ( qq> <val1> qq> ) qqqqqqqqqwq> [m [1m x mq> OF qj x [m [1m x x [m [1m mq> [1;4mTHRESHOLDS[m[1m qwq> ARE qwqqqqqqqqqqqk x [m [1m mq> OF qj x x [m [1m lqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj x [m [1m mq> ( qq> <val1> qwqqqqqqqqqqqqqqqqqqqqqqqqqqqwq> ) qj [m [1m mq> , <val2> qwqqqqqqqqqqqqqu [m [1m mq> , <val3> qj [m [1m [m (B)0[m[1mpartition-clause = [m [1m [m [1mqw> [1;4mSTORE[m[1m qwqqqqqqqqqqqqqqqqqqwwqqqqqqqqqqqqqqqqqqqqw> store-clause qw>[m [1m x m> columns-clause qjm> store-attributes qj x [m [1m mqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqq <qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1m [m (B)0[m[1mcolumns-clause = [m [1m [m [1mq> [1;4mCOLUMNS[m[1m qq> ( qwq> <column-name> qwq> ) qq> [m [1m mqqqqqqqq , <qqqqqqj [m [1m [m (B)0[m[1mstore-attributes = [m [1m [m [1mqqwqwqwq> [1;4mENABLE[m[1m qqwq> [1;4mCOMPRESSION[m[1m qwqwqq> [m [1m x x mq> [1;4mDISABLE[m[1m qj x x [m [1m x tq> thresholds-clause qqqqqqqqqqu x [m [1m x mq> [1;4mVERTICAL[m[1m [1;4mPARTITION[m[1m <name> qqj x [m [1m mqqqqqqqqqqqqqqq <qqqqqqqqqqqqqqqqqqj [m (B)0[m[1mstore-clause = [m [1m [m [1mqqqwq> [1;4mIN[m[1m area-spec qqqqqqqqqqqqqqqqqqqqqqqqwqq> [m [1m tq> across-clause qqqqqqqqqqqqqqqqqqqqqqqu [m [1m mq> using-clause qqqqqqqqqqqqqqqqqqqqqqqqj [m (B)0[m[1marea-spec =[m [1m [m [1m [m [1mqq> <area-name> qwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwq> [m [1m mq> ( qwwq> threshold-clause qqqqqqqqqqqqqqqwwq> ) qj [m [1m xtq> [1;4mLOGGING[m[1m qqqqqqqqqqqqqqqqqqqqqqqqux [m [1m xtq> [1;4mNOLOGGING[m[1m qqqqqqqqqqqqqqqqqqqqqqux [m [1m xtq> [1;4mPARTITION[m[1m <name> qqqqqqqqqqqqqqqux [m [1m xmq> [1;4mCOMMENT[m[1m IS qwqq> 'string' qqqwqqjx [m [1m x mqqqqqqq / <qqqqqj x [m [1m mqqqqqqqqqqqqqqqq , qqqqqqqqqqqqqqqqqj [m (B)0[m[1macross-clause = [m [1m [m [1mqqq> RANDOMLY [1;4mACROSS[m[1m qqqk [m [1m lqqqqqqqqqqqqqqqqqqqqqqj [m [1m mq> ( qw> area-spec qqwqq> ) qq>[m [1m mqqqqq , <qqqqqj [m (B)0[m[1musing-clause = [m [1m [m [1mqqq> [1;4mUSING[m[1m qqq> ( qwq> <column-name> qwq> ) qqqqqqqqqqqqqqqqqqk[m [1m mqqqqqqqq , <qqqqqqj [m [1mx[m [1mlqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj[m [1mmwq> [1;4mIN[m[1m area-spec q> [1;4mWITH[m[1m [1;4mLIMIT[m[1m [1;4mOF[m[1m qq> ( wq> <literal> qw> ) wqk[m [1m x mqqqqqq , <qqqqj[m [1mx[m [1mx[m [1m mqqqqqqqqqqqqqqqqqqqqqqqqqq<qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj[m [1mx[m [1m lqqqqqqqqqqqqqqqqqqqqqqqqqq<qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj[m [1m mwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqqqqqqqqqqqqq>[m [1m m> [1;4mOTHERWISE[m[1m IN area-spec qqqqqqqqqqqqqqqqqqqqqqqj [m (B)0[m[1mstore-lists-clause = [m [1m [m [1mqqq> [1;4mSTORE[m[1m [1;4mLISTS[m[1m qqqk [m [1m lqqqqqqqqqqqqqqqqqqj [m [1m mqwq> [1;4mIN[m[1m qwq> area-spec qqqqqqqqqqqqqqqwqqqwqqqqqqqqqqq>[m [1m x mq> ( w> area-spec q> ) qqqqwj [m [1mx[m [1m x mqqqqqq , <qqqqqqqqqqqj x [m [1m x lqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1m x mqwqqqqqqqqqqqqqqqqqqqqqqqq>qqqqqqqqqqqqqqqqqqqqqqqk [m [1m x mq> [1;4mFOR[m[1m q> ( qwq> <table-name> qqqqqqqqqwq> ) qk x [m [1m x tq> <table-name.col-name> u x x [m [1m x mqqqqqqqq , <qqqqqqqqqqqqqj x x [m [1m x lqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj x [m [1m x mqqqwqqqqqqqqqqqq>qqqqqqqqqqwqqqqqqqqqqqqu [m [1m x tq> [1;4mFILL[m[1m [1;4mRANDOMLY[m[1m qqqqqu x [m [1m x mq> [1;4mFILL[m[1m [1;4mSEQUENTIALLY[m[1m qqj x [m [1m mqqqqqqqqqqqqqqqqqqqqqqqqqqqq<qqqqqqqqqqqqqqqqqqqqqqqj [m [1m [m
17.3 – Arguments
17.3.1 – across-clause
Associates the table with two or more storage areas.
17.3.2 – COMMENT IS 'string'
Adds a comment about the storage map. SQL displays the text of the comment when it executes a SHOW STORAGE MAPS statement. Enclose the comment in single quotation marks (') and separate multiple lines in a comment with a slash mark (/).
17.3.3 – COMPRESSION option
Syntax options: ENABLE COMPRESSION | DISABLE COMPRESSION Specifies whether the rows for the partition are compressed or uncompressed when stored. You can enable or disable compression on each vertical partition. You enable compression to conserve disk space, but there is a small CPU overhead for inserting and retrieving compressed rows. If you omit this clause, the default compression is that which was specified for the storage map before the first STORE COLUMNS clause. The default is ENABLE COMPRESSION.
17.3.4 – FILL
Syntax options: FILL RANDOMLY | FILL SEQUENTIALLY Specifies whether to fill the area set randomly or sequentially. Specifying FILL RANDOMLY or FILL SEQUENTIALLY requires a FOR clause. When a storage area is filled, it is removed from the list of available areas. Oracle Rdb does not attempt to store any more lists in that area during the current database attach. Instead, Oracle Rdb starts filling the next specified area. When a set of areas is filled sequentially, Oracle Rdb stores lists in the first specified area until that area is filled. If the set of areas is filled randomly, lists are stored across multiple areas. This is the default. Random filling is intended for read/write media, which will benefit from the I/O distribution across the storage areas. The keywords FILL RANDOMLY and FILL SEQUENTIALLY can only be applied to areas contained within an area list.
17.3.5 – FOR (table name)
Specifies the table or tables to which this list storage map applies. The named table must already be defined. If you want to store lists of more than one table in the storage area, separate the names of the tables with commas. For each area, you can specify one FOR clause and list of table names.
17.3.6 – FOR (table name.col name)
Specifies the name of the table and column containing the list to which this storage map applies. Separate the table name and the column name with a period (.). The named table and column must already be defined. If you want to store multiple lists in the storage area, separate the table name and column name combinations with commas. For each area, you can specify one FOR clause and a list of column names.
17.3.7 – LOGGING
Syntax options: LOGGING | NOLOGGING The LOGGING clause specifies that rows written to the table during the current transaction (the transaction in which this table was created) be logged when written to the database. Logging includes writing data and management records to the recovery-unit journal file (.ruj) and after-image journal files (.aij). When the NOLOGGING clause is specified then only a small number of management records are logged in the recovery-unit journal file (.ruj) and after-image journal files (.aij). See the Usage Notes below for more information. LOGGING and NOLOGGING can be specified per storage area (partition) or as a default for the CREATE STORAGE MAP statement. The LOGGING and NOLOGGING clauses are mutually exclusive; specify only one. The LOGGING clause is the default.
17.3.8 – OTHERWISE_IN
For partitioned storage maps only, specifies the storage area that is used as the overflow partition. An overflow partition is a storage area that holds any values that are higher than those specified in the WITH LIMIT OF clause. An overflow partition holds those values that exceed the highest specified limits.
17.3.9 – partition-clause
Defines vertical partitioning, horizontal partitioning, or both for the specified table. Horizontal partitioning means that you divide the rows of the table among storage areas according to data values in one or more columns. Vertical partitioning means that you divide the columns of the table among storage areas. A given storage area will then contain only some of the columns of a table. You can combine both horizontal and vertical partitions in a single map. Vertical partitioning reduces disk I/O operations by placing frequently used data in one area, so that you can read and update those portions of the table in a single disk I/O operation. See the Oracle Rdb Guide to Database Design and Definition for more information regarding partitioning.
17.3.10 – PARTITION name
Names the partition. The name can be a delimited identifier if the dialect or quoting rules are set to SQL92 or SQL99. Partition names must be unique within the storage map. If you do not specify this clause, Oracle Rdb generates a default name for the partition.
17.3.11 – PARTITIONING_IS_NOT_UPDATABLE
Specifies that the value of the partitioning key cannot be modified and that the row is always stored in the storage area based on the partitioning criteria in the STORE USING clause. The partitioning key is the column or list of columns specified in the STORE USING clause. Specifying the PARTITIONING IS NOT UPDATABLE clause allows Oracle Rdb to quickly retrieve data because the partitioning criteria can be used when optimizing the query. To update columns that are partitioning keys in a NOT UPDATABLE storage map, you must delete the rows and then reinsert the rows to ensure that they are placed in the correct location. If you specify the PARTITIONING clause, you must also specify the STORE USING clause when defining a storage map. If the PARTITIONING clause is not specified, UPDATABLE is the default. See the Oracle Rdb Guide to Database Design and Definition for more information regarding partitioning.
17.3.12 – PARTITIONING_IS_UPDATABLE
Specifies that the partitioning key can be modified. The partitioning key is the column or list of columns specified in the STORE USING clause. If you modify a row in an UPDATABLE storage map, the row is not moved to a different storage area even if the new value of the partitioning key is not within the limits of original storage area. As a result, Oracle Rdb must consider all storage areas specified in the STORE USING clause when retrieving a row. If you specify the PARTITIONING clause, you must also specify the STORE USING clause when defining a storage map. If the PARTITIONING clause is not specified, UPDATABLE is the default. See the Oracle Rdb Guide to Database Design and Definition for more information regarding partitioning.
17.3.13 – PLACEMENT_VIA_INDEX
Directs the database system to store a column in a way that optimizes access to that column by the indicated path. Oracle Rdb chooses a target page for any columns being stored by rules that take into account the type of index named (sorted or hashed), the type of storage areas involved (uniform or mixed), and how indexes and tables are assigned to storage areas. For a hashed index, Oracle Rdb calculates the page containing the hashed index node that points to the column. If that page is within the same storage area in which the column will be stored, it is used as the target page for storing the column. If that page is not within the same storage area in which the column is to be stored, Oracle Rdb chooses a target page in the same relative position within the appropriate storage area (if it is a mixed storage area) or a page in a clump reserved for that table (if it is a uniform storage area). For a sorted index, Oracle Rdb finds the database key of the next lowest row to the one being stored and uses the page number in the database key as the target page.
17.3.14 – STORAGE_MAP
Specifies the name of the storage map you want to create. The name cannot be the same as any other definition in the database.
17.3.15 – store-clause
The storage map definition. The store-clause in a CREATE STORAGE MAP statement lets you specify which storage area files are used to store rows from the table. o All rows of a table can be associated with a single storage area. o Rows of a table can be randomly distributed among several storage areas. o Rows of a table can be systematically distributed, or partitioned, among several storage areas by specifying upper limits on the values for a column in a particular storage area. This is called horizontal partitioning. o Columns of a table can be partitioned among storage areas. This is called vertical partitioning. If you omit the storage map definition, the default is to store all the rows for a table in the default storage area. See the CREATE and IMPORT DATABASE statements for information on the default storage area.
17.3.16 – STORE_COLUMNS
Syntax option: STORE COLUMNS (column-name) Lists the columns which will be stored in the subsequent map. Multiple STORE COLUMNS clauses may appear in a map to spread across multiple storage areas. A column name may only appear in one STORE COLUMNS clause. A final STORE clause can appear to provide a location for all remaining unspecified columns.
17.3.17 – STORE IN area name
Associates the table directly with a single storage area. All rows in the table are stored in the area you specify.
17.3.18 – STORE_LISTS_IN
Directs the database system to store the lists from tables in a specified storage area or in a set of areas. You can create only one storage map for lists within each database. You must specify the default storage area for lists in the STORE LISTS clause. The default list storage area contains lists from system tables as well as lists not directed elsewhere by the STORE LISTS clause. You can also use the LIST STORAGE AREA clause of the CREATE DATABASE statement to specify a default storage area for lists. If you do not use the STORE LISTS clause and do not specify a list storage area in the CREATE DATABASE statement, Oracle Rdb uses the default storage area as the default list storage area. The following example directs Oracle Rdb to place all lists in the LISTS storage area unless otherwise specified in a storage map: SQL> CREATE DATABASE FILENAME mf_personnel SQL> LIST STORAGE AREA IS LISTS SQL> CREATE STORAGE AREA LISTS; The accompanying storage map statement must also specify the LISTS storage area as the default storage area. SQL> CREATE STORAGE MAP LISTS_MAP cont> STORE LISTS IN LISTS1 FOR (EMPLOYEES.RESUME) cont> IN LISTS; You can use an area set to specify that data is to be distributed across several areas. The following example shows how you can store data in three storage areas (LISTS1, LISTS2, and LISTS3) for two different columns in TABLE1. The default list storage area is LISTS1. CREATE STORAGE MAP LISTS_MAP STORE LISTS IN (LISTS1,LISTS2,LISTS3) FOR (TABLE1.COL1,TABLE1.COL2) IN LISTS1; You can store lists from different tables in the same area. The following example shows how you can store data from TABLE1, TABLE2, and TABLE3 in the LISTS storage area. The default list storage area is RDB$SYSTEM. SQL> CREATE STORAGE MAP LISTS_MAP -- to direct the list data to area LISTS cont> STORE LISTS IN LISTS FOR (TABLE1, TABLE2, TABLE3) cont> IN RDB$SYSTEM; Alternatively, you can store lists from each table in unique areas. The following example shows list data from TABLE1 being stored in the LISTS1 storage area and list data from TABLE2 being stored in the LISTS2 storage area. The default list storage area is RDB$SYSTEM. CREATE STORAGE MAP LISTS_MAP STORE LISTS IN LIST1 FOR (TABLE1) IN LIST2 FOR (TABLE2) IN RDB$SYSTEM; You can also specify that different columns from the same table go into different areas. The following example shows data from different columns in TABLE1 being stored in either LISTS1 or LISTS2. The default list storage area is RDB$SYSTEM. CREATE STORAGE MAP LISTS_MAP STORE LISTS IN LISTS1 FOR (TABLE1.COL1) IN LISTS2 FOR (TABLE1.COL2) IN RDB$SYSTEM;
17.3.19 – STORE_RANDOMLY_ACROSS
Syntax option: STORE RANDOMLY ACROSS (area-name) As rows are inserted in the table, they are distributed randomly across the storage areas named in the list. You must name at least two storage areas in this clause.
17.3.20 – STORE_USING
Syntax option: STORE USING (column-name) IN area-name The database system compares values in the columns to the values in the WITH LIMIT OF clause to determine placement of rows inserted into the table. See the Oracle Rdb SQL Reference Manual for further information. Use RMU EXTRACT to have the store using expression expanded. See Example 9.
17.3.21 – STORED_NAME
Specifies a name that Oracle Rdb uses to access a storage map created in a multischema database. The stored name allows you to access multischema definitions using interfaces that do not recognize multiple schemas in one database. You cannot specify a stored name for a storage map in a database that does not allow multiple schemas. For more information on stored names, see the User_Supplied_Names HELP topic.
17.3.22 – THRESHOLD clause
Specifies one, two, or three default threshold values for logical areas in storage areas with uniform format pages. The threshold values (val1, val2, and val3) represent a fullness percentage on a data page and establish three possible ranges of guaranteed free space on the data pages. When a data page reaches the percentage defined by a given threshold value, the space area management (SPAM) entry for the data page is updated to reflect the new fullness percentage and its remaining free space. Oracle Rdb never stores a record at the third threshold. The value you set for the highest threshold can be used to reserve space on the page for future record growth. When only val1 is specified, this is equivalent to (val1, 100, 100). When val1 and val2 are specified, this is equivalent to (val1, val2, 100). The trailing, unspecified thresholds default to 100 percent. For example, THRESHOLDS ARE (40) would appear as (40, 100, 100). If no thresholds are specified for the area, the default is (0,0,0). This causes the SPAM algorithm to set thresholds based on the nominal record length for the logical area; for example, the node size for the index or the uncompressed length of the row for a table. You cannot specify the thresholds for the storage map attribute for any area that is a mixed page format. If you have a mixed page format, set the thresholds for the storage area using the ADD STORAGE AREA or CREATE STORAGE AREA clause of the ALTER DATABASE, CREATE DATABASE, or IMPORT statements.
17.3.23 – VERTICAL PARTITION name
Names a vertical partition. The name can be a delimited identifier if the dialect or quoting rules are set to SQL92 or SQL99. Partition names must be unique within the storage map. If you do not specify this clause, Oracle Rdb generates a default name for the partition.
17.3.24 – using-clause
Specifies columns whose values are used as limits for partitioning the table horizontally across multiple storage areas.
17.3.25 – WITH_LIMIT_OF
Specifies the maximum values that the columns named in the USING clause can have when rows are initially stored in the specified storage area. Repeat this clause to partition the rows of a table among multiple storage areas. The number of literals listed must be the same as the number of columns in the USING clause. The data type of the literals must agree with the data type of the column. For character columns, enclose the literals in single quotation marks. The values in the WITH LIMIT OF clause only affect placement of rows when they are initially stored. If UPDATE statements change data in a row so that values in columns named in the USING clause exceed values specified in the WITH LIMIT OF clause, the row is not moved into a different storage area.
17.4 – Examples
Example 1: Defining storage maps for a multifile database This example shows the definition of storage maps for a multifile database. The tables named in the CREATE STORAGE MAP statements have the same definitions as those in the sample database. See the CREATE STORAGE_AREA clause for an example of a CREATE DATABASE statement with CREATE STORAGE AREA clauses that create the storage areas referred to in this example. SQL> -- Declare the database as the default: SQL> ATTACH 'FILENAME multifile_example'; SQL> -- SQL> CREATE STORAGE MAP EMPLOYEE_MAP FOR EMPLOYEES cont> STORE USING (EMPLOYEE_ID) cont> IN EMPID_LOW WITH LIMIT OF ('00200') cont> IN EMPID_MID WITH LIMIT OF ('00500') cont> OTHERWISE IN EMPID_OVER; SQL> -- SQL> CREATE STORAGE MAP RESUME_MAP cont> STORE LISTS IN EMP_INFO FOR (TABLE1, TABLE2, TABLE3) cont> IN RDB$SYSTEM; SQL> -- SQL> CREATE STORAGE MAP JOB_HISTORY_MAP FOR JOB_HISTORY cont> STORE IN HISTORIES; SQL> -- SQL> CREATE STORAGE MAP SALARY_HISTORY_MAP FOR SALARY_HISTORY cont> STORE IN HISTORIES; SQL> -- SQL> CREATE STORAGE MAP JOBS_MAP FOR JOBS cont> STORE IN CODES; SQL> -- SQL> CREATE STORAGE MAP DEPARTMENTS_MAP FOR DEPARTMENTS cont> STORE IN CODES; SQL> -- SQL> CREATE STORAGE MAP COLLEGES_MAP FOR COLLEGES cont> STORE IN CODES; SQL> -- SQL> CREATE STORAGE MAP DEGREES_MAP FOR DEGREES cont> STORE IN EMP_INFO; SQL> -- SQL> CREATE STORAGE MAP WORK_STATUS_MAP FOR WORK_STATUS cont> STORE IN HISTORIES; SQL> -- SQL> -- SQL> -COMMIT; SQL> -- Example 2: Defining storage maps that place and override thresholds on uniform storage areas SQL> CREATE DATABASE FILENAME birdlist cont> CREATE STORAGE AREA AREA1 cont> CREATE STORAGE AREA AREA2 cont> CREATE STORAGE AREA AREA3 cont> CREATE STORAGE AREA AREA4 cont> CREATE TABLE SPECIES cont> ( GENUS CHAR (30), cont> SPECIES CHAR (30), cont> COMMON_NAME CHAR (40), cont> FAMILY_NUMBER INT (3), cont> SPECIES_NUMBER INT (3) cont> ) cont> CREATE INDEX I1 ON SPECIES (FAMILY_NUMBER) cont> CREATE TABLE SIGHTING cont> ( SPECIES_NUMBER INT (3), cont> COMMON_NAME CHAR (40), cont> CITY CHAR (20), cont> STATE CHAR (20), cont> SIGHTING_DATE DATE ANSI, cont> NOTES_NUMBER INT (5)) cont> CREATE INDEX I2 ON SIGHTING (SPECIES_NUMBER) cont> CREATE TABLE FIELD_NOTES cont> ( WEATHER CHAR (30), cont> TIDE CHAR (15), cont> SPECIES_NUMBER INT (3), cont> SIGHTING_TIME TIMESTAMP(2), cont> NOTES CHAR (500), cont> NOTES_NUMBER INT (5)) cont> CREATE INDEX I3 ON FIELD_NOTES (NOTES_NUMBER) cont> ; SQL> -- SQL> -- The following CREATE STORAGE MAP statements place and SQL> -- override thresholds on uniform storage area. SQL> -- SQL> -- Note that the default threshold clause for the SQL> -- storage map is not enclosed in parentheses, but each SQL> -- threshold clause associated with a particular area is. SQL> -- SQL> CREATE STORAGE MAP M1 FOR SPECIES cont> THRESHOLDS ARE (30, 50, 80) cont> ENABLE COMPRESSION cont> PLACEMENT VIA INDEX I1 cont> STORE cont> IN AREA1 cont> (THRESHOLD (10) ); SQL> -- SQL> CREATE STORAGE MAP M2 FOR SIGHTING cont> THRESHOLD IS (40) cont> STORE cont> RANDOMLY ACROSS ( cont> AREA1 (THRESHOLD OF (10) ), cont> AREA2 (THRESHOLDS ARE (30, 50, 98) ), cont> AREA3 cont> ); SQL> -- SQL> CREATE STORAGE MAP M3 FOR FIELD_NOTES cont> THRESHOLDS OF (50,70,90) cont> STORE cont> USING (SPECIES_NUMBER, NOTES_NUMBER) cont> IN AREA1 cont> (THRESHOLDS OF (20, 80, 90) ) cont> WITH LIMIT OF (30, 88) cont> IN AREA2 cont> WITH LIMIT OF (40, 89) cont> IN AREA3 cont> WITH LIMIT OF (50, 90) cont> OTHERWISE IN AREA4 cont> (THRESHOLDS ARE (20, 30, 40)); SQL> -- SQL> SHOW STORAGE MAP *; User Storage Maps in database with filename birdlist M1 For Table: SPECIES Placement Via Index: I1 Partitioning is: UPDATABLE Store clause: STORE IN AREA1 (THRESHOLD (10) ) Partition information for storage map: Compression is: ENABLED Partition: (1) SYS_P00062 Storage Area: AREA1 M2 For Table: SIGHTING Partitioning is: UPDATABLE Store clause: STORE RANDOMLY ACROSS ( AREA1 (THRESHOLD OF (10) ), AREA2 (THRESHOLDS ARE (30, 50, 98) ), AREA3 ) Partition information for storage map: Compression is: ENABLED Partition: (1) SYS_P00063 Storage Area: AREA1 Partition: (2) SYS_P00064 Storage Area: AREA2 Partition: (3) SYS_P00065 Storage Area: AREA3 M3 For Table: FIELD_NOTES Partitioning is: UPDATABLE Store clause: STORE USING (SPECIES_NUMBER, NOTES_NUMBER) IN AREA1 (THRESHOLDS OF (20, 80, 90) ) WITH LIMIT OF (30, 88) IN AREA2 WITH LIMIT OF (40, 89) IN AREA3 WITH LIMIT OF (50, 90) OTHERWISE IN AREA4 (THRESHOLDS ARE (20, 30, 40)) Partition information for storage map: Compression is: ENABLED Partition: (1) SYS_P00066 Storage Area: AREA1 Partition: (2) SYS_P00067 Storage Area: AREA2 Partition: (3) SYS_P00068 Storage Area: AREA3 Partition: (4) SYS_P00069 Storage Area: AREA4 SQL> -- SQL> ROLLBACK; Example 3: Creating a storage map that stores lists This example creates a storage map that stores lists on specific storage areas. SQL> CREATE DATABASE FILENAME test cont> CREATE STORAGE AREA LISTS1 PAGE FORMAT IS MIXED cont> CREATE STORAGE AREA LISTS2 PAGE FORMAT IS MIXED cont> cont> CREATE TABLE EMPLOYEES cont> (EMP_ID CHAR(5), cont> RESUME LIST OF BYTE VARYING); SQL> -- SQL> CREATE STORAGE MAP LISTS_MAP cont> STORE LISTS IN cont> (LISTS1,LISTS2) FOR (EMPLOYEES.RESUME) cont> FILL SEQUENTIALLY cont> IN RDB$SYSTEM; Example 4: Creating an alternate map This example following storage map shows an alternate mapping for the EMPLOYEES table in the same MF_PERSONNEL database. SQL> create storage map EMPLOYEES_MAP cont> for EMPLOYEES cont> placement via index EMPLOYEES_HASH cont> -- store the primary information horizontally partitioned cont> -- across the areas EMPIDS_LOW, EMPIDS_MID and EMPIDS_OVER cont> -- disable compress because these columns are accessed often cont> store cont> columns (EMPLOYEE_ID, LAST_NAME, cont> FIRST_NAME, MIDDLE_INITIAL) cont> disable compression cont> using (EMPLOYEE_ID) cont> in EMPIDS_LOW cont> with limit of ('00200') cont> in EMPIDS_MID cont> with limit of ('00400') cont> otherwise in EMPIDS_OVER cont> cont> -- place all the address information in EMP_INFO cont> -- make sure these character columns are compressed cont> -- to remove the trailing spaces cont> store cont> columns (ADDRESS_DATA_1, ADDRESS_DATA_2, CITY, STATE, cont> POSTAL_CODE) cont> enable compression cont> in EMP_INFO cont> cont> -- the remaining columns get cont> -- written randomly over these areas cont> store cont> enable compression cont> randomly across (SALARY_HISTORY, JOBS); Example 5: Disabling logging and naming horizontal and vertical partitions SQL> CREATE DATABASE FILENAME birdlist cont> CREATE STORAGE AREA AREA1 cont> CREATE STORAGE AREA AREA2 cont> CREATE STORAGE AREA AREA3 cont> CREATE STORAGE AREA AREA4 cont> CREATE STORAGE AREA AREA5 cont> CREATE STORAGE AREA AREA6 cont> CREATE STORAGE AREA AREA7 cont> CREATE STORAGE AREA AREA8 cont> CREATE TABLE SPECIES cont> ( GENUS CHAR (30), cont> SPECIES CHAR (30), cont> COMMON_NAME CHAR (40), cont> FAMILY_NUMBER INT (3), cont> SPECIES_NUMBER INT (3) cont> ) cont> CREATE INDEX I1 ON SPECIES (FAMILY_NUMBER) cont> CREATE TABLE SIGHTING cont> ( SPECIES_NUMBER INT (3), cont> COMMON_NAME CHAR (40), cont> CITY CHAR (20), cont> STATE CHAR (20), cont> SIGHTING_DATE DATE ANSI, cont> NOTES_NUMBER INT (5)) cont> CREATE INDEX I2 ON SIGHTING (SPECIES_NUMBER) cont> CREATE TABLE FIELD_NOTES cont> ( WEATHER CHAR (30), cont> TIDE CHAR (15), cont> SIGHTING_TIME TIMESTAMP(2), cont> NOTES CHAR (500), cont> NOTES_NUMBER INT (5), cont> SPECIES_NUMBER INT (3)) cont> CREATE INDEX I3 ON FIELD_NOTES (NOTES_NUMBER); SQL> -- SQL> -- Note that the default threshold clause for the SQL> -- storage map is not enclosed in parentheses, but each SQL> -- threshold clause associated with a particular area is enclosed SQL> -- in parentheses. SQL> -- SQL> CREATE STORAGE MAP M1 FOR SPECIES cont> THRESHOLDS ARE (30, 50, 80) cont> ENABLE COMPRESSION cont> PLACEMENT VIA INDEX I1 cont> NOLOGGING cont> COMMENT IS 'Storage Map for Species' cont> STORE cont> IN AREA1 cont> (THRESHOLD (10), cont> PARTITION AREA1, cont> COMMENT IS 'Partition is AREA1'); SQL> -- SQL> CREATE STORAGE MAP M2 FOR SIGHTING cont> THRESHOLD IS (40) cont> STORE cont> RANDOMLY ACROSS ( cont> AREA1 (THRESHOLD OF (10), cont> PARTITION AREA1), cont> AREA2 (THRESHOLDS ARE (30, 50, 98), cont> PARTITION AREA2), cont> AREA3 (PARTITION AREA3) cont> ); SQL> -- SQL> CREATE STORAGE MAP M3 FOR FIELD_NOTES cont> THRESHOLDS OF (50,70,90) cont> STORE COLUMNS (WEATHER, TIDE, SIGHTING_TIME) cont> VERTICAL PARTITION WEATHER_TIDE_SIGHTINGTIME cont> USING (SPECIES_NUMBER, NOTES_NUMBER) cont> IN AREA1 cont> (THRESHOLDS OF (20, 80, 90) ) cont> WITH LIMIT OF (30, 88) cont> IN AREA2 cont> WITH LIMIT OF (40, 89) cont> IN AREA3 cont> WITH LIMIT OF (50, 90) cont> OTHERWISE IN AREA4 cont> (THRESHOLDS ARE (20, 30, 40)) cont> STORE COLUMNS (NOTES, NOTES_NUMBER, SPECIES_NUMBER) cont> VERTICAL PARTITION NOTES_NOTESNUM_SPECIESNUM cont> USING (SPECIES_NUMBER) cont> IN AREA5 cont> (THRESHOLDS OF (20, 80, 90) ) cont> WITH LIMIT OF (30) cont> IN AREA6 cont> WITH LIMIT OF (40) cont> IN AREA7 cont> WITH LIMIT OF (50) cont> OTHERWISE IN AREA8 cont> (THRESHOLDS ARE (20, 30, 40)); Example 6: Creating a storage map for a table containing data SQL> -- Create table, insert data, and then create a storage map. SQL> -- SQL> CREATE TABLE MAP_TEST2 (a INTEGER, b CHAR(10)); SQL> INSERT INTO MAP_TEST2 (a, b) VALUES (2, 'Second'); 1 row inserted SQL> CREATE STORAGE MAP MAP_TEST2_MAP FOR MAP_TEST2 cont> STORE IN RDB$SYSTEM; SQL> INSERT INTO MAP_TEST2 (a, b) VALUES (22, 'Second2'); 1 row inserted SQL> COMMIT; SQL> SELECT *,DBKEY FROM MAP_TEST2; A B DBKEY 2 Second 90:809:0 22 Second2 90:809:1 2 rows selected SQL> SQL> -- Now alter the storage map and SQL> -- place it in a different storage area. SQL> SQL> ALTER STORAGE MAP MAP_TEST2_MAP cont> STORE IN TEST_AREA2; SQL> COMMIT; SQL> SELECT *,DBKEY FROM MAP_TEST2; A B DBKEY 2 Second 91:11:0 22 Second2 91:11:1 2 rows selected SQL> Example 7: Invalid attempts to create a storage map SQL> -- Create table, insert data, and then SQL> -- create a storage map with invalid attributes. SQL> SQL> CREATE TABLE MAP_TEST3 (a INTEGER, b CHAR(10)); SQL> CREATE INDEX MAP_TEST3_INDEX ON MAP_TEST3 (a); SQL> INSERT INTO MAP_TEST3 (a, b) VALUES (3, 'Third'); 1 row inserted SQL> SQL> CREATE STORAGE MAP MAP_TEST3_MAP FOR MAP_TEST3 cont> STORE IN TEST_AREA1; -- Must be the default area. %RDB-E-NO_META_UPDATE, metadata update failed -RDMS-F-RELNOTEMPTY, table "MAP_TEST3" has data in it -RDMS-E-NOCMPLXMAP, can not use complex map for non-empty table SQL> SQL> CREATE STORAGE MAP MAP_TEST3_MAP for MAP_TEST3 cont> PLACEMENT VIA INDEX MAP_TEST3_INDEX -- Can't use placement. cont> STORE IN RDB$SYSTEM; %RDB-E-NO_META_UPDATE, metadata update failed -RDMS-F-RELNOTEMPTY, table "MAP_TEST3" has data in it -RDMS-E-NOCMPLXMAP, can not use complex map for non-empty table SQL> SQL> CREATE STORAGE MAP MAP_TEST3_MAP FOR MAP_TEST3 cont> DISABLE COMPRESSION -- Can't change compression. cont> STORE IN RDB$SYSTEM; %RDB-E-NO_META_UPDATE, metadata update failed -RDMS-F-RELNOTEMPTY, table "MAP_TEST3" has data in it -RDMS-E-NOCMPLXMAP, can not use complex map for non-empty table SQL> SQL> CREATE STORAGE MAP MAP_TEST3_MAP for MAP_TEST3 cont> THRESHOLDS ARE (50, 60, 70) -- Can't change thresholds. cont> STORE IN RDB$SYSTEM; %RDB-E-NO_META_UPDATE, metadata update failed -RDMS-F-RELNOTEMPTY, table "MAP_TEST3" has data in it -RDMS-E-NOCMPLXMAP, can not use complex map for non-empty table SQL> SQL> CREATE STORAGE MAP MAP_TEST3_MAP FOR MAP_TEST3 cont> STORE ACROSS (RDB$SYSTEM, TEST_AREA2);-- Can't use more than one area. %RDB-E-NO_META_UPDATE, metadata update failed -RDMS-F-RELNOTEMPTY, table "MAP_TEST3" has data in it -RDMS-E-NOCMPLXMAP, can not use complex map for non-empty table SQL> SQL> CREATE STORAGE MAP MAP_TEST3_MAP for MAP_TEST3 cont> STORE COLUMNS (a) in RDB$SYSTEM -- Can't vertically partition. cont> STORE COLUMNS (b) in TEST_AREA2; %RDB-E-NO_META_UPDATE, metadata update failed -RDMS-F-RELNOTEMPTY, table "MAP_TEST3" has data in it -RDMS-E-NOCMPLXMAP, can not use complex map for non-empty table Example 8: Using the RMU Extract command to display WITH LIMIT OF expressions The WITH LIMIT OF clauses of the STORE clause are converted to Boolean expressions that are used by Oracle Rdb to direct inserted data to the correct storage area. You can use the RMU Extract command to display these Boolean expressions. Use the Item=STORAGE_MAP and Option=FULL qualifiers as shown in the following example. $ RMU/EXTRACT- _$ /ITEM=STORAGE_MAP- _$ /OPTION=(MATCH:EMPLOYEES_MAP%,NOHEADER,FULL,FILENAME_ONLY) - _$ DB$:MF_PERSONNEL set verify; set language ENGLISH; set default date format 'SQL92'; set quoting rules 'SQL92'; set date format DATE 001, TIME 001; attach 'filename MF_PERSONNEL.RDB'; create storage map EMPLOYEES_MAP for EMPLOYEES comment is ' employees partitioned by "00200" "00400"' placement via index EMPLOYEES_HASH store using (EMPLOYEE_ID) -- Partition: -- (EMPLOYEE_ID <= '00200') in EMPIDS_LOW with limit of ('00200') -- Partition: -- (EMPLOYEE_ID <= '00400') in EMPIDS_MID with limit of ('00400') otherwise in EMPIDS_OVER; commit work; Example 9: SQL Mapping Routine This example shows the SQL mapping routine created by the CREATE STORAGE MAP statement that matches the WITH LIMIT OF clause for the storage map. SQL> create table EMPLOYEES ( cont> EMPLOYEE_ID CHAR (5), cont> LAST_NAME CHAR (14), cont> FIRST_NAME CHAR (10), cont> MIDDLE_INITIAL CHAR (1), cont> ADDRESS_DATA_1 CHAR (25), cont> ADDRESS_DATA_2 CHAR (25), cont> CITY CHAR (20), cont> STATE CHAR (2), cont> POSTAL_CODE CHAR (5), cont> SEX CHAR (1), cont> BIRTHDAY DATE VMS, cont> STATUS_CODE CHAR (1)); SQL> SQL> create storage map EMPLOYEES_MAP cont> for EMPLOYEES cont> comment is cont> ' employees partitioned by "00200" "00400"' cont> store cont> using (EMPLOYEE_ID) cont> in EMPIDS_LOW cont> with limit of ('00200') cont> in EMPIDS_MID cont> with limit of ('00400') cont> otherwise in EMPIDS_OVER; SQL> SQL> commit work; SQL> SQL> show system modules; Modules in database with filename MF_PERSONNEL RDB$STORAGE_MAPS SQL> SQL> show system functions; Functions in database with filename MF_PERSONNEL EMPLOYEES_MAP SQL> SQL> show system function EMPLOYEES_MAP; Information for function EMPLOYEES_MAP Function ID is: -2 Source: return case when (:EMPLOYEE_ID <= '00200') then 1 when (:EMPLOYEE_ID <= '00400') then 2 else 3 end case; Comment: Return value for select partition - range 1 .. 3 Module name is: RDB$STORAGE_MAPS Module ID is: -1 Number of parameters is: 1 Parameter Name Data Type Domain or Type -------------- --------- -------------- INTEGER Function result datatype Return value is passed by value EMPLOYEE_ID CHAR(5) Parameter position is 1 Parameter is IN (read) Parameter is passed by reference Example 10: Using Storage Area Attributes in a LIST Storage Map The following example shows the use of storage area attributes in a LIST storage map. The storage area attributes must immediately follow the storage area name (as in table storage maps). SQL> create database cont> filename 'DB$:MULTIMEDIA' cont> cont> create storage area PHOTO_AREA1 cont> filename 'DB$:PHOTO_AREA1' cont> page format UNIFORM cont> cont> create storage area PHOTO_AREA2 cont> filename 'DB$:PHOTO_AREA2' cont> page format UNIFORM cont> cont> create storage area TEXT_AREA cont> filename 'DB$:TEXT_AREA' cont> page format UNIFORM cont> cont> create storage area AUDIO_AREA cont> filename 'DB$:AUDIO_AREA' cont> page format UNIFORM cont> cont> create storage area DATA_AREA cont> filename 'DB$:DATA_AREA' cont> page format UNIFORM cont> ; SQL> SQL> create table EMPLOYEES cont> (name char(30), cont> dob date, cont> ident integer, cont> photograph list of byte varying (4096) as binary, cont> resume list of byte varying (132) as text, cont> review list of byte varying (80) as text, cont> voiceprint list of byte varying (4096) as binary cont> ); SQL> SQL> create storage map EMPLOYEES_MAP cont> for EMPLOYEES cont> enable compression cont> store in DATA_AREA; SQL> SQL> create storage map LISTS_MAP cont> store lists cont> in AUDIO_AREA cont> (thresholds are (89, 99, 100) cont> ,comment is 'The voice clips' cont> ,partition AUDIO_STUFF) cont> for (employees.voiceprint) cont> in TEXT_AREA cont> (thresholds is (99) cont> ,partition TEXT_DOCUMENTS) cont> for (employees.resume, employees.review) cont> in (PHOTO_AREA1 cont> (comment is 'Happy Smiling Faces?' cont> ,threshold is (99) cont> ,partition PHOTOGRAPHIC_IMAGES_1) cont> ,PHOTO_AREA2 cont> (comment is 'Happy Smiling Faces?' cont> ,threshold is (99) cont> ,partition PHOTOGRAPHIC_IMAGES_2) cont> ) cont> for (employees.photograph) cont> fill randomly cont> in RDB$SYSTEM cont> (partition SYSTEM_LARGE_OBJECTS); SQL> SQL> show storage map LISTS_MAP; LISTS_MAP For Lists Store clause: STORE lists in AUDIO_AREA (thresholds are (89, 99, 100) ,comment is 'The voice clips' ,partition AUDIO_STUFF) for (employees.voiceprint) in TEXT_AREA (thresholds is (99) ,partition TEXT_DOCUMENTS) for (employees.resume, employees.review) in (PHOTO_AREA1 (comment is 'Happy Smiling Faces?' ,threshold is (99) ,partition PHOTOGRAPHIC_IMAGES_1) ,PHOTO_AREA2 (comment is 'Happy Smiling Faces?' ,threshold is (99) ,partition PHOTOGRAPHIC_IMAGES_2) ) for (employees.photograph) fill randomly in RDB$SYSTEM (partition SYSTEM_LARGE_OBJECTS) Partition information for lists map: Vertical Partition: VRP_P000 Partition: (1) AUDIO_STUFF Fill Randomly Storage Area: AUDIO_AREA Thresholds are (89, 99, 100) Comment: The voice clips Partition: (2) TEXT_DOCUMENTS Fill Randomly Storage Area: TEXT_AREA Thresholds are (99, 100, 100) Partition: (3) PHOTOGRAPHIC_IMAGES_1 Fill Randomly Storage Area: PHOTO_AREA1 Thresholds are (99, 100, 100) Comment: Happy Smiling Faces? Partition: (3) PHOTOGRAPHIC_IMAGES_2 Storage Area: PHOTO_AREA2 Thresholds are (99, 100, 100) Comment: Happy Smiling Faces? Partition: (4) SYSTEM_LARGE_OBJECTS Fill Randomly Storage Area: RDB$SYSTEM SQL> SQL> commit;
18 – SYNONYM
Creates an alternate name or synonym for an existing database object. The object may be a domain, function, module, procedure, sequence, another synonym, table, or view. Once defined, the synonym can be used in any query or data definition language statement in place of the referenced object. However, the SHOW commands do not accept synonyms. Use the SHOW SYNONYM statement to determine if the name is a synonym.
18.1 – Environment
You can use the CREATE SYNONYM statement: o In interactive SQL o Embedded in host language programs o As part of a procedure in an SQL module or other compound statement o In dynamic SQL as a statement to be dynamically executed
18.2 – Format
(B)0[m[1;4mCREATE[m [1mqwqqqqqqqqqqqqqqqwqwqqqqqqqqqqqwqqqk[m [1m [m [1mmq> [1;4mOR[m [1;4mREPLACE[m[1m qj[m [1mmq> [1;4mPUBLIC[m[1m qj[m [1m x[m [1m [m [1mlqqqqqqqqqqqqqqqqqq <qqqqqqqqqqqqqqqqqqqqj[m [1m [m [1mmq> [1;4mSYNONYM[m [1m<synonym-name> [1;4mFOR[m[1m qwqqqqqqqqqqqqqqqqwqk[m [1mmq> object-type[m [1mqj x[m [1mlqqqqqqqqqqqqqqqqqqqqqq <qqqqqqqqqqqqqqqqqqqqqqqqqqj[m [1mmq> <object-name> qwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwq>[m [1mmq> [1;4mCOMMENT[m[1m IS[m [1mqwq> ' <quoted-string> ' qwj [m [1mmqqqqqqqqq / <qqqqqqqqqqqj[m (B)0[m[1mobject-type =[m [1mqwq> [1;4mDOMAIN[m [1mqqqqwq>[m [1mtq>[m [1;4mFUNCTION[m [1mqqu[m [1mtq>[m [1;4mMODULE[m [1mqqqqu[m [1mtq>[m [1;4mPROCEDURE[m [1mqu[m [1mtq>[m [1;4mSEQUENCE[m[1m qqu[m [1mtq>[m [1;4mSYNONYM[m[1m qqqu[m [1mtq>[m [1;4mTABLE[m [1mqqqqqu[m [1mmq>[m [1;4mVIEW[m [1mqqqqqqj[m
18.3 – Arguments
18.3.1 – COMMENT IS 'quoted-string'
This optional clause can be used to add several lines of comment to the synonym object. The comment is displayed by the SHOW SYNONYM statement.
18.3.2 – FOR object-name
The name of the database object for which the synonym is required. This name must exist for an object in the database. If the optional object type is omitted, then Oracle Rdb will search the database for an object with this name.
18.3.3 – object-type
Syntax options: DOMAIN FUNCTION MODULE PROCEDURE SEQUENCE SYNONYM TABLE VIEW These optional object types can be used when the referenced object name is not unique within the database. For instance, Oracle Rdb allows a domain and a table to both be called MONEY. Therefore, to create a synonym for the table MONEY, you must use the FOR TABLE clause so that it is uniquely identified.
18.3.4 – OR_REPLACE
Instructs SQL to replace any synonym of this name if it exists. If it does not exist, a new synonym is created. This shorthand allows replacement of an existing synonym while maintaining all the dependencies established by query and DDL usage of this synonym.
18.3.5 – PUBLIC
This optional clause is provided for compatibility with the Oracle database server. It is currently not used by Oracle Rdb. Its presence or absence may be used by future releases. Oracle Corporation recommends you use the PUBLIC keyword in applications.
18.3.6 – synonym-name
The name of the synonym you want to create. The synonym name must be unique within all domains, tables, views, functions, procedures, modules, sequences, and synonyms within the database. You may qualify it with an alias.
18.4 – Examples
Example 1: Using the Default Alias SQL> CREATE SYNONYM emps FOR employees; Example 2: Using an Explicit Alias for the Synonym SQL> CREATE SYNONYM db1.emps FOR employees; Example 3: Using an Explicit Alias for the Referenced Object SQL> CREATE SYNONYM emps FOR db1.employees; Example 4: Using the Alias Explicitly SQL> CREATE SYNONYM db1.emps FOR db1.employees; Example 5: Using the Table Type SQL> CREATE SYNONYM cash FOR table money cont> COMMENT IS 'use a different name to avoid confusion with' cont> / 'the domain MONEY'; Example 6: Using Multiple Synonyms SQL> CREATE TABLE t_employees_0001 (...); SQL> CREATE SYNONYM employees FOR t_employees_0001; SQL> CREATE SYNONYM emps FOR employees;
19 – TABLE
Creates a temporary or persistent base table definition. A table definition consists of a list of definitions of columns that make up a row in the table. Persistent base tables are tables whose metadata and data are stored in the database beyond an SQL session. The data can be shared by all users attached to the database. Temporary tables are tables whose data is automatically deleted when an SQL session or module ends. The tables only materialize when you refer to them in an SQL session and the data is local to an SQL session. You can also specify whether the data is preserved or deleted at the end of a transaction within the session; the default is to delete the data. The data in temporary tables is private to the user. There are three types of temporary tables: o Global temporary tables o Local temporary tables o Declared local temporary tables (see the DECLARE LOCAL_ TEMPORARY_TABLE for additional information) The metadata for a global temporary table is stored in the database and persists beyond the SQL session. Different SQL sessions can share the same metadata. The data stored in the table cannot be shared between SQL sessions. However, the data can be shared between modules in a single SQL session. The data does not persist beyond an SQL session. The metadata for a local temporary table is stored in the database and persists beyond the SQL session. Different SQL sessions can share the same metadata. The data stored in the table cannot be shared between different modules in a single SQL session or between SQL sessions. The data does not persist beyond an SQL session or module. Because temporary tables are used only to hold the user's data, which is not shared among users, no locks are needed and the data can be modified in a read-only transaction. See the Oracle Rdb Guide to Database Design and Definition for more information on temporary tables. Information tables are special read-only tables that can be used to retrieve database attributes that are not stored in the existing relational tables. Information tables allow interesting database information, which is currently stored in an internal format, to be displayed as a relational table. When you define a table, you can also define table constraints. A constraint specifies a condition that restricts the values that can be stored in a table. Constraints can specify that columns contain: - Only certain values - Primary key values - Unique values - Values that cannot be null There are several ways to specify a table definition in the CREATE TABLE statement: o Directly by naming the table, its columns and associated data types, default values (optional), constraint definitions (optional), and formatting clauses. You can define constraints on persistent base tables and global temporary tables only. o Indirectly by providing a path name for a repository record definition that specifies the table name, columns, and data types. o Indirectly by providing another table as a model in inheriting the columns, datatypes and NOT NULL constraints. SQL allows you to specify the default character data type or the national character data type when defining table columns.
19.1 – Environment
You can use the CREATE TABLE statement: o In interactive SQL o Embedded in host language programs to be precompiled o As part of a procedure in an SQL module o In dynamic SQL as a statement to be dynamically executed
19.2 – Format
(B)0[m [1;4mCREATE[m[1m qwqqqqqqqqqqqqqqqqqqqqqqqqqqqwq> [1;4mTABLE[m[1m qqqqqqqqk [m [1m tq> [1;4mINFORMATION[m[1m qqqqqqqqqqqqu x [m [1m tq> [1;4mGLOBAL[m[1m qwq> [1;4mTEMPORARY[m[1m qqj x [m [1m mq> [1;4mLOCAL[m[1m qqj x [m [1mlqqqqqqqqqqqqqqqqqqqqqq <qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1mmwq> [1;4mFROM[m[1m <path-name> qwqqqqqqqqqqqqqqqqqqqwqqqqqqqqqqqqqqqqqqqqqqqk[m [1mx[m [1mmq> [1;4mALIAS[m[1m <alias> qqj[m [1m [m [1mx[m [1mmq> <table-name> qwqqqqqqqqqqqqqqqq[mqqqqqq[1mqqqqqqqqqwq> table-body qu[m [1m mq>[m [1;4mSTORED[m[1m [1;4mNAME[m[1m IS[m [1mstored-name qj x [m [1m lqqqqqqqqqqqqqqqqqqqqq<qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj[m [1m mqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwq>[m [1m [m [1mmqwqq> create-table-attributes qwj[m [1mmqqqqqqqqqqqqqqq<qqqqqqqqqqqqqj[m (B)0[m[1mcreate-table-attributes =[m [1mqqqwq> [1;4mCOMMENT[m[1m IS[m [1mqqwq> 'quoted-string' qwqqqqqqwq> [m [1mx[m [1m [m [1m mqqqqqqqq / qqqqqqqqqj [m [1m x[m [1m tq> [1;4mCOMPRESSION[m[1m IS qwq> [1;4mENABLED[m[1m qqqwqqqqqqqqqu [m [1m x [m [1mmq> [1;4mDISABLED[m[1m qqj x [m [1m tq> [1;4mDISABLE[m [1mqqwq> cre-enable-disable qqqqqqqqu [m [1mtq> [1;4mENABLE[m[1m qqqj[m [1mx[m [1m tq> [1;4mLOGGING[m[1m qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu [m [1mtq> [1;4mNOLOGGING[m[1m qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu [m [1mmq>[m [1;4mON[m[1m [1;4mCOMMIT[m [1mqwq> [1;4mDELETE[m [1mqqqqwq> [1;4mROWS[m[1m qqqqqqj[m [1mmq>[m [1;4mPRESERVE[m [1mqqj[m (B)0[m[1mtable-body = [m [1m [m [1mqwq> (column-constraint-list)[m [1mqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwq>[m [1mx[m [1m [m [1mx[m [1mmq> [1;4mLIKE[m[1m <other-table-name>[m [1mqqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwj[m [1m mqq> (column-constraint-list) qj[m [1m [m (B)0[m[1mcre-enable-disable = [m [1m [m [1mqwq> [1;4mALL[m[1m [1;4mCONSTRAINTS[m[1m qqqqqqqqqqqqqqqqqqqqqwq>[m [1m tq> [1;4mCONSTRAINT[m[1m <constraint-name> qqqqqqqqu [m [1m tq> [1;4mPRIMARY[m[1m [1;4mKEY[m[1m qqqqqqqqqqqqqqqqqqqqqqqqqu [m [1m mq> [1;4mUNIQUE[m[1m ( qwq <column-name> wq> ) qqqqj [m [1m mqqqqqqq , <qqqqqj [m (B)0[m [1mcol-definition = [m [1m [m [1mqq> <column-name> qqk [m [1m lqqqqqqqqqqqqqqqj [m [1m tqqq> column-type qqqwqqqqqqqqqqqqqqqqqqqqqqqqqqwqwqqk [m [1m x [m [1m tq>[1;4mDEFAULT[m[1m [m [1m value-expr [m [1m x x x [m [1m [m [1mx[m [1mmq>column-identity qqqqqqqqj[m [1mx[m [1mx[m [1m mqqq> [1;4mCOMPUTED[m[1m [1;4mBY[m[1m value-expr qqqqqqqqqqqqqqqqqqqqqj[m [1mx[m [1m lqqqqqqqqqqqqqqqqqqqqqqqqq<qqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1mmqwqqqqqqqqqqqqqqqqqqqqwqqqqqqqqqqqqqqqqk[m [1mmq>[m [1mcol-constraint qqj[m [1mx[m [1mlqqqqqqqqqqqqqqqqqqqqqqqqqq<qqqqqqqqqqqqj[m [1m mwqqqqqqqqqqqqqqqqqqqqqqqqwqqqqqwqqqqqqqqqqqqqqqqqqqqqqqwq>[m [1m mq> comment-is-clause [m [1mqqj mq> sql-and-dtr-clause qj [m [1m [m [1m [m [1m [m (B)0[m[1mcolumn-constraint-list = [m [1m [m [1mqqwqqwq> col-definition qqqqqqqwqqqqqwq>[m [1m [m [1mx mq> table-constraint qqqqqj [m [1mx[m [1m [m [1mmqqqqqqqqqqqqqqqq[m [1m,[m [1m<qqqqqqqqqqqqqqj [m (B)0[m[1mcolumn-identity = [m [1m [m [1mqq> [1;4mIDENTITY[m[1m qqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqq> [m [1mmq ( <start-with> qqwqqqqqqqqqqqqqqqqqqqqqqwq> ) qqj[m [1m mq> , <increment-by> qqj[m [1m [m (B)0[m[1mcolumn-type= [m [1mqqwq> data-type qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqq>[m [1mtq> <domain-name> qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu[m [1mtq> references-clause [mqqq[1mqqqqqqqqqqqqqqqqqqqqqqqqu[m [1mmq> [1;4mAUTOMATIC[m[1m qqwqqqqqqqqqqqwqq> [1;4mAS[m[1m value-expr qqj[m [1mtq> [1;4mINSERT[m[1m qu[m [1mmq> [1;4mUPDATE[m[1m qj[m (B)0[m[1mdata-type = [m [1m [m [1m qwq> char-data-types qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqq> [m [1m tq> [1;4mTINYINT[m[1m qqqqqqqqqqqqqqwqqqqqwqqqqqqqqqqqqwqqqqqqqqqqqqqqqu [m [1m tq> [1;4mSMALLINT[m[1m qqqqqqqqqqqqqu mq> ( <n> ) qj x [m [1m tq> [1;4mINTEGER[m[1m qqqqqqqqqqqqqqu x [m [1m tq> [1;4mBIGINT[m[1m qqqqqqqqqqqqqqqu x [m [1m tq> [1;4mFLOAT[m[1m qqqqqqqqqqqqqqqqj x [m [1m tq> [1;4mNUMBER[m[1m qwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqqqqqqqqqqqqqu [m [1m x mq> ( qwq> <p> qwqwqqqqqqqqqqwq> ) j x [m [1m x mq> * qqqj mq> , <d> qj x [m [1m tq> [1;4mLIST[m[1m [1;4mOF[m[1m [1;4mBYTE[m[1m [1;4mVARYING[m[1m qqwqqqqqqqqqqqqwqqwqqqqqqqqqqqqqqwqqu [m [1m x mq> ( <n> ) qj tq> [1;4mAS[m[1m [1;4mBINARY[m[1m qu x [m [1m x mq> [1;4mAS[m[1m [1;4mTEXT[m[1m qqqj x [m [1m tq> [1;4mDECIMAL[m[1m qwwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqqqqqqqqqqqqqqqu [m [1m tq> [1;4mNUMERIC[m[1m qjmq> ( qq> <n> wqqqqqqqqqqwq> ) j x [m [1m x mq> , <n> qj x [m [1m tq> [1;4mREAL[m[1m qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu [m [1m tq> [1;4mDOUBLE[m[1m [1;4mPRECISION[m[1m qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu [m [1m mq> date-time-data-types qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1m [m (B)0[m[1mchar-data-types = [m [1m [m [1mqwq> [1;4mCHAR[m[1m qqqqqqqqqqqqqwwqqqqqqqqqqqqwwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqwq>[m [1m tq> [1;4mCHARACTER[m[1m qqqqqqqqumq> ( <n> ) qjmq> [1;4mCHARACTER[m[1m [1;4mSET[m[1m char[m-[1mset-name qj x [m [1mtq> [1;4mCHAR[m[1m [1;4mVARYING[m[1m qqqqqu[m [1m [m [1mx [m [1mtq> [1;4mCHARACTER[m[1m [1;4mVARYING[m[1m j[m [1mx [m [1mtq> [1;4mVARCHAR[m[1m qqw>[m [1m( <n> ) qqqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqqqqqqqqqqu [m [1mtq> [1;4mVARCHAR2[m[1m qj[m [1m mq> [1;4mCHARACTER[m[1m [1;4mSET[m[1m char-set-name qj [m [1mx[m [1m tq> [1;4mLONG[m[1m [1;4mVARCHAR[m[1m qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu [m [1m tq> [1;4mNCHAR[m[1m qqqqqqqqqqqqqqwqwqqqqqqqqqqqqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu [m [1m tq> [1;4mNATIONAL[m[1m [1;4mCHAR[m[1m qqqqqqu mq> ( <n> ) qj [m [1m [m [1mx [m [1m tq> [1;4mNATIONAL[m[1m [1;4mCHARACTER[m[1m qj [m [1m [m [1mx [m [1m tq> [1;4mNCHAR[m[1m [1;4mVARYING[m[1m qqqqqqqqqqqqqqwqwqqqqqqqqqqqqwqqqqqqqqqqqqqqqqqqqqqqqqu[m [1m tq> [1;4mNATIONAL[m[1m [1;4mCHAR[m[1m [1;4mVARYING[m[1m qqqqqqu mq> ( <n> ) qj [m [1m [m [1mx [m [1m tq> [1;4mNATIONAL[m[1m [1;4mCHARACTER[m[1m [1;4mVARYING[m[1m qj [m [1m [m [1mx [m [1mtq> [1;4mRAW[m[1m q> ( <n> ) q[mqqq[1mqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu[m [1mmq> [1;4mLONG[m[1m qwqqqqqqqqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1mmq> [1;4mRAW[m[1m qj[m (B)0[m[1mdate-time-data-types = [m [1m [m [1mqqwq> [1;4mDATE[m[1m qwqqqqqqqqqqwqqqqqqqqqqqqqqqqqwqq> [m [1m x tq> [1;4mANSI[m[1m qu x [m [1m x mq> [1;4mVMS[m[1m qqqj x [m [1m tq> [1;4mTIME[m[1m qqq> frac qqqqqqqqqqqqqqqqqqqqu [m [1m tq> [1;4mTIMESTAMP[m[1m qq> frac qqqqqqqqqqqqqqqqu [m [1m mq> [1;4mINTERVAL[m[1m qqq> interval-qualifier qqj [m [1m [m (B)0[m[1mcol-constraint= [m [1m [m [1m qqqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwk [m [1m mq> [1;4mCONSTRAINT[m[1m <constraint-name> qjx [m [1m lqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1m tq> [1;4mPRIMARY[m[1m [1;4mKEY[m[1m qqqqqqqqqqqqqqqqqk [m [1m tq> [1;4mUNIQUE[m[1m qqqqqqqqqqqqqqqqqqqqqqu [m [1m tq> [1;4mNOT[m[1m [1;4mNULL[m[1m qqqqqqqqqqqqqqqqqqqqu [m [1m tq> [1;4mNULL[m[1m qqqqqqqqqqqqqqqqqqqqqqqqu[m [1m tq> [1;4mCHECK[m[1m (predicate) qqqqqqqqqqqu [m [1m tq> references-clause qqqqqqqqqqqu [m [1m mqqqqqqqqqqqq>qqqqqqqqqqqqqqqqqqqu [m [1m lqqqqqqqqqqqqq<qqqqqqqqqqqqqqqqqqj [m [1m mqqqqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqq> [m [1m mqq> constraint-attributes qqj [m (B)0[m[1mreferences-clause = [m [1m [m [1;4mREFERENCES[m[1m <referenced-table-name> qk [m [1m lqqqqqqqqqqqqqqqqq<qqqqqqqqqqqqqqqqj [m [1m mqwqqqqqqqqqqqqqqqqqqqqq>qqqqqqqqqqqqqqqqqqqwq> [m [1m mq> ( qw> <referenced-column-name> wq> ) qj [m [1m mqqqqqqqqqqq , <qqqqqqqqqqqqj [m [1m [m (B)0[m[1msql-and-dtr-clause = [m [1m [m [1mqwq> [1;4mQUERY[m[1m [1;4mHEADER[m[1m IS qw> <quoted-string> wqqqqqqqqqqqqqqqqqqqwq> [m [1m x mqqqqqq / <qqqqqqqqj x [m [1m tq> [1;4mEDIT[m[1m [1;4mSTRING[m[1m IS <quoted-string> qqqqqqqqqqqqqqqqqqqqqqqqqu [m [1m x x [m [1m tq> [1;4mQUERY[m[1m [1;4mNAME[m[1m FOR qwq> DTR qqqqqqqqwq> IS <quoted-string> qu [m [1m x mq> DATATRIEVE qj x [m [1m mq> [1;4mDEFAULT[m[1m [1;4mVALUE[m[1m FOR qwq> DTR qqqqqqqqwq> IS literal[m [1m qqqqj [m [1m mq> DATATRIEVE qj [m [1m [m (B)0[m[1mliteral = [m [1m [m [1mqqwq> numeric-literal qqqqwqqq> [m [1m tq> string-literal qqqqqu [m [1m tq> date-time-literal qqu [m [1m tq> interval-literal qqqu [m [1m mq> dbkey-literal qqqqqqj [m (B)0[m[1mtable-constraint = [m [1m [m [1mqqqwqqqqqqqqqqqqqqqq>qqqqqqqqqqqqqqqqqqwqqqqk [m [1m mq> [1;4mCONSTRAINT[m[1m <constraint-name> qqqj x [m [1m lqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1m mqq> table-constraint-clause qqqqqqqqqqqqqqk [m [1m lqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1m mqqqwqqqqqqqqqqqqqqqqqqqqqqqqqqqwqqqqqqqqqqqqq>[m [1m mq> constraint-attributes qqj [m [1m [m (B)0[m[1mtable-constraint-clause = [m [1m [m [1mqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqq>[m [1m tq> [1;4mPRIMARY[m[1m [1;4mKEY[m[1m q> ( qwq> <column-name> qw> ) qu [m [1m x mqqqqqqq , <qqqqqqqj x [m [1m tq> [1;4mUNIQUE[m[1m q> ( qw> <column-name> wq> ) qqqqqqqu [m [1m x mqqqqqqq , <qqqqqj x [m [1m tq> [1;4mCHECK[m[1m (predicate) qqqqqqqqqqqqqqqqqqqqqqqqqu [m [1m mq> [1;4mFOREIGN[m[1m [1;4mKEY[m[1m q> ( qw> <column-name> wq> ) k x [m [1m mqqqqqqq , <qqqqqj x x [m [1m lqqqqqqqqqqqqqqqqqqqqqqq<qqqqqqqqqqqqqqqqqqj x [m [1m mq> references-clause qqqqqqqqqqqqq>qqqqqqqqqj [m [1m [m (B)0[m[1mconstraint-attributes = [m [1m [m [1mqwq> [1;4mDEFERRABLE[m[1m qqqqqqqqqqqqqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqwq> [m [1m x mq> [1;4mINITIALLY[m[1m wq> [1;4mIMMEDIATE[m[1m qqwj x [m [1m x mq> [1;4mDEFERRED[m[1m qqqj x [m [1m tq> [1;4mNOT[m[1m [1;4mDEFERRABLE[m[1m qqqqqqqqqwqqqqqqqqqqqqqqqqqqqqqqqqqwqqqqqqu [m [1m x mq> [1;4mINITIALLY[m[1m [1;4mIMMEDIATE[m[1m qqj x [m [1m tq> [1;4mINITIALLY[m[1m [1;4mIMMEDIATE[m[1m qqqqwqqqqqqqqqqqqqqqqqqqwqqqqqqqqqqqqu [m [1m x tq> [1;4mDEFERRABLE[m[1m qqqqqu x [m [1m x mq> [1;4mNOT[m[1m [1;4mDEFERRABLE[m[1m qj x [m [1m mq> [1;4mINITIALLY[m[1m [1;4mDEFERRED[m[1m qqqqqwqqqqqqqqqqqqqqqqqqqwqqqqqqqqqqqqj [m [1m mq> [1;4mDEFERRABLE[m[1m qqqqqj [m
19.3 – Arguments
19.3.1 – ALIAS alias
Specifies a name for an attach to a particular database. SQL adds the table definition to the database referred to by the alias. If you do not specify an alias, SQL adds the table definition to the default database. See the User_Supplied_Names HELP topic for more information on default databases and aliases.
19.3.2 – AUTOMATIC
Syntax options: AUTOMATIC AS value-expr AUTOMATIC INSERT AS value-expr AUTOMATIC UPDATE AS value-expr These AUTOMATIC column clauses allow you to store special information when data is inserted into a row or a row is updated. For example, you can log application-specific information to audit activity or provide essential values, such as time stamps or unique identifiers for the data. The assignment of values to these types of columns is managed by Oracle Rdb. The AUTOMATIC INSERT clause can be used to provide a complex default for the column when the row is inserted; it cannot be changed by an UPDATE statement. The AUTOMATIC UPDATE clause can be used to provide an updated value during an UPDATE statement. The unqualified AUTOMATIC clause specifies that the value expression should be applied during both INSERT and UPDATE statements. The column type is derived from the AS value-expr; using CAST allows a specific data type to be specified. However, this is not required and is rarely necessary. You can define an AUTOMATIC INSERT column to automatically receive data during an insert operation. The data is stored like any other column, but the column is read-only. Because AUTOMATIC columns are treated as read-only columns, they cannot appear in the column list for an insert operation nor be modified by an update operation. AUTOMATIC UPDATE columns can have an associated default value that will be used when the row is inserted.
19.3.3 – char-data-type
A valid SQL character data type. See the Data_Types HELP topic for more information on character data types.
19.3.4 – character-set-name
A valid character set name.
19.3.5 – CHECK predicate
Specifies a predicate that column values inserted into the table must satisfy. See the Predicates HELP topic for details on specifying predicates. Predicates in CHECK column constraints can refer directly only to the column with which they are associated.
19.3.6 – col-constraint
A constraint that applies to values stored in the associated column. SQL allows column constraints and table constraints. The five types of column constraints are PRIMARY KEY, UNIQUE, NOT NULL, CHECK, and FOREIGN KEY constraints. The FOREIGN KEY constraints are created with the REFERENCES clause. You can define a column constraint on persistent base tables and global temporary tables only.
19.3.7 – col-definition
The definition for a column in the table. SQL gives you two ways to specify column definitions: o By directly specifying a data type to associate with a column name o By naming a domain that indirectly specifies a data type to associate with a column name Either way also allows options for specifying default values, column constraints, and formatting clauses.
19.3.8 – column-name
The name of a column you want to create in the table. You need to specify a column name whether you directly specify a data type in the column definition or indirectly specify a data type by naming a domain in the column definition.
19.3.9 – COMPUTED_BY
Specifies that the value of this column is calculated from values in other columns and constant expressions. If your column definition refers to a column name within a value expression, that named column must already be defined within the same CREATE TABLE statement. See the Value_Expressions HELP topic for information on value expressions. Any column that you refer to in the definition of a computed column cannot be deleted from that table unless you first delete the computed column. SQL does not allow the following for computed columns: o UNIQUE constraints o REFERENCES clauses o PRIMARY KEY constraints o DEFAULT clause o IDENTITY clause o Default value for DATATRIEVE For example, if the FICA_RATE for an employee is 6.10 percent of the employee's starting salary and the group insurance rate is 0.7 percent, you can define FICA_RATE and GROUP_RATE columns like this: SQL> CREATE TABLE payroll_detail cont> (salary_code CHAR(1), cont> starting_salary SMALLINT(2), cont> fica_amt cont> COMPUTED BY (starting_salary * 0.061), cont> group_rate cont> COMPUTED BY (starting_salary * 0.007)); When you use this type of definition, you only have to store values in the salary_code and starting_salary columns. The FICA and group insurance deduction columns are computed automatically when the columns fica_amt or group_rate are selected.
19.3.10 – COMPRESSION_IS
Syntax options: COMPRESSION IS ENABLED | COMPRESSION IS DISABLED Specifies whether run-length compression is enabled or disabled for rows inserted into the base or temporary table. In some cases, the data inserted into a table may not compress and so incur only overhead in the row. This overhead is used by Rdb to describe the sequence of uncompressible data. Use COMPRESSION IS DISABLED to prevent Rdb from attempting the compression of such data. Any storage map which specifies the ENABLE COMPRESSION or DISABLE COMPRESSION clause will override this setting in the table. The COMPRESSION IS clause is not permitted for INFORMATION tables. The default is COMPRESSION IS ENABLED.
19.3.11 – constraint-attributes
Although the constraint attribute syntax provides 11 permutations as required by the SQL99 standard, they equate to the following three options: o INITIALLY IMMEDIATE NOT DEFERRABLE Specifies that evaluation of the constraint must take place when the INSERT, DELETE, or UPDATE statement executes. If you are using the SQL99, SQL92, MIA, ORACLE LEVEL1, or ORACLE LEVEL2 dialect, this is the default. o INITIALLY IMMEDIATE DEFERRABLE Specifies that evaluation of the constraint may be deferred (using the SET CONSTRAINT ALL statement or the SET TRANSACTION statement with the EVALUATING clause), but by default it is evaluated after the INSERT, DELETE, or UPDATE statement executes. See the SET_ALL_CONSTRAINTS statement for more information. o INITIALLY DEFERRED DEFERRABLE Specifies that evaluation of the constraint can take place at any later time. Unless otherwise specified, evaluation of the constraint takes place as the COMMIT statement executes. You can use the SET ALL CONSTRAINTS statement to have all constraints evaluated earlier. See the description of the SET ALL CONSTRAINTS statement for more information. If you are using the default SQLV40 dialect, this is the default constraint attribute. When using this dialect, Oracle Rdb displays a deprecated feature message for all constraints defined without specification of one of the constraint attributes.
19.3.12 – CONSTRAINT
Specifies a name for a column or table constraint. The name is used for a variety of purposes: o The RDB$INTEG_FAIL error message specifies the name when an INSERT, UPDATE, or DELETE statement violates the constraint. o The ALTER TABLE table-name DROP CONSTRAINT constraint-name statement specifies the name to delete a table constraint. o The SHOW TABLE statements display the names of column and table constraints. o The EVALUATING clause of the SET TRANSACTION and DECLARE TRANSACTION statements specifies constraint names. o The ENABLE and DISABLE clauses of the ALTER and CREATE TABLE statements specify constraint names. o The ALTER CONSTRAINT statement specifies constraint names. o The DROP CONSTRAINT statement The CONSTRAINT clause is optional. If you omit the constraint name, SQL creates a name. However, Oracle Rdb recommends that you always name column and table constraints. If you supply a constraint name with the CONSTRAINT clause, it must be unique in the database or in the schema if you are using a multischema database.
19.3.13 – data-type
A valid SQL data type. Specifying an explicit data type to associate with a column is an alternative to specifying a domain name. See the Data_Types HELP topic for more information on data types.
19.3.14 – date-time-data-types
A data type that specifies a date, time, or interval. See the Data_Types HELP topic for more information about date-time data types.
19.3.15 – DEFAULT value-expr
Provides a default value for a column if the row that is inserted does not include a value for that column. You can use any value expression including subqueries, conditional, character, date/time, and numeric expressions as default values. See Value Expressions for more information about value expressions. For more information about NULL, see the NULL_Keyword HELP topic. The value expressions described in Value Expressions include DBKEY and aggregate functions. However, the DEFAULT clause is not a valid location for referencing a DBKEY or an aggregate function. If you attempt to reference either, you receive a compile-time error. If you do not specify a default value, a column inherits the default value from the domain. If you do not specify a default value for either the column or domain, SQL assigns NULL as the default value.
19.3.16 – domain-name
The name of a domain created in a CREATE DOMAIN statement. SQL gives the column the data type specified in the domain. For more information on domains, see the CREATE DOMAIN statement. For most purposes, you should specify a domain instead of an explicit data type. o Domains ensure that all columns in multiple tables that serve the same purpose have the same data type. For example, several tables in the sample personnel database refer to the domain ID_DOM. o A domain lets you change the data type for all columns that refer to it in one operation by changing the domain itself with an ALTER DOMAIN statement. For example, if you want to change the data type for the column EMPLOYEE_ID from CHAR(5) to CHAR(6), you need only alter the data type for the domain ID_DOM. You do not have to alter the data type for the column EMPLOYEE_ID in the tables DEGREES, EMPLOYEES, JOB_HISTORY, or SALARY_HISTORY, nor do you have to alter the column MANAGER_ID in the DEPARTMENTS table. However, you might not want to use domains when you create tables if: o Your application must be compatible with Oracle RDBMS. o You are creating intermediate result tables that do not need the advantages of domains.
19.3.17 – enable-disable-clause
Allows you to enable or disable all constraints, specified constraints, a primary key, or a unique column name, as described in the following list. By default, table and column constraints added during a create table operation are enabled. o DISABLE ALL CONSTRAINTS All table and column constraints for this table are disabled. No error is raised if no constraints are defined on the table. o ENABLE ALL CONSTRAINTS All and column constraints for this table are enabled. No error is raised if no constraints are defined on the table. o DISABLE CONSTRAINT constraint-name The named constraint is disabled. The named constraint must be a table or column constraint for the table. o ENABLE CONSTRAINT constraint-name The named constraint is enabled. The named constraint must be a table or column constraint for the table. o DISABLE PRIMARY KEY The primary key for the table is disabled. o ENABLE PRIMARY KEY The primary key for the table is enabled. o DISABLE UNIQUE (column-name) The matching UNIQUE constraint is disabled. The columns listed must be columns in the table. o ENABLE UNIQUE (column-name) The matching UNIQUE constraint is enabled. The columns listed must be columns in the table.
19.3.18 – FOREIGN_KEY
The name of a column or columns that you want to declare as a foreign key in the table you are defining (referencing table). You cannot declare a computed column as a foreign key.
19.3.19 – FROM pathname
Specifies the repository path name of a repository record definition. SQL creates the table using the definition from this record and gives the table the name of the record definition. You can create a table using the FROM path-name clause only if the record definition in the repository was originally created using the repository Common Dictionary Operator (CDO) utility. For instance, you cannot create a table using the FROM path-name clause if the record definition was created in the repository as part of an SQL session. If the repository record contains a nested record definition, you cannot create a table based on it. Creating a table based on a repository record definition is useful when many applications share the same definition. Changes to the common definition can be automatically reflected in all applications that use it. NOTE Changes by other users or applications to the record definition in the repository affect the table definition once the database is integrated to match the repository with an INTEGRATE DATABASE . . . ALTER FILES statement. If those changes include deleting records or fields on which tables or table columns are based, any data in the dependent table or table column is lost after the next INTEGRATE DATABASE . . . ALTER FILES statement executes. You can use the FROM clause only if the database was attached specifying PATHNAME. You can specify either a full repository path name or a relative repository path name. You cannot define constraints or any other table definition clauses, such as DATATRIEVE formatting clauses, when you use the FROM path-name form of the CREATE TABLE statement. This restriction does not prevent you from using an ALTER TABLE statement to add them later. You cannot use the FROM path-name clause when embedding a CREATE TABLE statement within a CREATE DATABASE statement.
19.3.20 – IDENTITY
Specifies that the column is to be a special read-only identity column. INSERT will evaluate this column and store a unique value for each row inserted. Only one column of a table may have the IDENTITY attribute. Rdb creates a sequence with the same name as the current table. See ALTER SEQUENCE and CREATE SEQUENCE for more information.
19.3.21 – increment-by
An integer literal value that specifies the increment for the sequence created for the IDENTITY column. A negative value creates a descending sequence, and a positive value creates an ascending sequence. A value of zero is not permitted. If omitted the default is 1, that is an ascending sequence.
19.3.22 – INFORMATION
Specifies that the table definition is an information table. Information tables are reserved for use by Oracle Corporation.
19.3.23 – LIKE other-table-name
Allows a database administrator to copy the metadata for an existing table and create a new table with similar characteristics. An optional column list can be used to add extra columns and contraints to this table. The referenced table must exist in the same database as the table being created. Syntax options: LOGGING | NOLOGGING The LOGGING clause specifies that the CREATE TABLE statement should be logged in the recovery-unit journal file (.ruj) and after-image journal file (.aij). The NOLOGGING clause specifies that the CREATE TABLE statement should not be logged in the recovery-unit journal file (.ruj) and after-image journal file (.aij). The LOGGING clause is the default.
19.3.24 – NOT_NULL
Restricts values in the column to values that are not null.
19.3.25 – ON_COMMIT
Syntax options: ON COMMIT PRESERVE ROWS | ON COMMIT DELETE ROWS Specifies whether data is preserved or deleted after a COMMIT statement for global or local temporary tables only. The default, if not specified, is ON COMMIT DELETE ROWS.
19.3.26 – PRIMARY_KEY
A primary key constraint defines one or more columns whose values make a row in a table different from all others. SQL requires that values in a primary key column be unique and not null; therefore, you need not specify the UNIQUE and NOT NULL column constraints for primary key columns. You cannot specify the primary key constraint for a computed column. When used as a table constraint this clause must be followed by a list of column names. When used as a column constraint this clause applies to the named column of the table.
19.3.27 – references-clause
Specifies the name of the column or columns that are a unique key or primary key or in the referenced table. When the REFERENCES clause is used as a table constraint, the column names specified in the FOREIGN KEY clause become a foreign key for the referencing table. When used as the column type clause, specifies that the type of the column be inherited from the PRIMARY KEY or UNIQUE index referenced. Both the data type and domain are inherited.
19.3.28 – REFERENCES referenced table name
Specifies the name of the table that contains the unique key or primary key referenced by the referencing table. To declare a constraint that refers to a unique or primary key in another table, you must have the SQL REFERENCES or CREATE privileges to the referenced table.
19.3.29 – referenced-column-name
For a column constraint, the name of the column that is a unique key or primary key in the referenced table. You cannot use a computed column as a referenced column name. For a table constraint, the referenced column name is the name of the column or columns that are a unique key or primary key in the referenced table. If you omit the referenced-column-name clause, the primary key is selected by default. The number of columns and their data types must match.
19.3.30 – sql-and-dtr-clause
Optional SQL formatting clause. If you specify a formatting clause for a column that is based on a domain that also specifies a formatting clause, the formatting clause in the table definition overrides the one in the domain definition.
19.3.31 – start-with
An integer literal value that specifies the starting value for the sequence created for the IDENTITY column. If omitted the default is 1.
19.3.32 – STORED_NAME_IS
Specifies a name that Oracle Rdb uses to access a table created in a multischema database. The stored name allows you to access multischema definitions using interfaces, such as Oracle RMU, the Oracle Rdb management utility, that do not recognize multiple schemas in one database. You cannot specify a stored name for a table in a database that does not allow multiple schemas. For more details about stored names, see the User_Supplied_Names HELP topic.
19.3.33 – table-constraint
A constraint definition that applies to the whole table. SQL allows column constraints and table constraints. The four types of table constraints are PRIMARY KEY, UNIQUE, CHECK, and FOREIGN KEY constraints. A column must be defined in a table before you can specify the column in a table constraint definition. You can define a table constraint on persistent base tables and global temporary tables only.
19.3.34 – table-name
The name of the table definition you want to create. Use a name that is unique among all table, sequence, view and synonym names in the database, or in the schema if you are using a multischema database. Use any valid SQL name. (See the User_Supplied_Names HELP topic for more information on user-supplied names.)
19.3.35 – temporary_tables
Syntax options: CREATE GLOBAL TEMPORARY TABLE | CREATE LOCAL TEMPORARY TABLE Specifies that the table definition is either a global or local temporary table.
19.3.36 – UNIQUE
Specifies that values in the associated column must be unique. You can use either the UNIQUE or PRIMARY KEY keywords to define one or more columns as a unique key for a table. You cannot specify the UNIQUE constraint for a computed column or for a column defined with the LIST OF BYTE VARYING data type.
19.4 – Examples
Example 1: Creating new tables with primary and foreign keys In this example, the CREATE TABLE statement is used to create the EMPLOYEES_2, SALARY_HISTORY_2, and WORK_STATUS_2 tables in the personnel database. It specifies column definitions based on domain definitions for the entire database. The FOREIGN KEY constraint specified in the SALARY_HISTORY_2 table must match the PRIMARY KEY constraint specified in the EMPLOYEES_2 table. Note also that the CHECK constraint specified is a table constraint because it is separated by commas from the column to which it refers. In this case, a column constraint on EMPLOYEE_ID would have the same effect because it refers only to the single column EMPLOYEE_ID. Because the dialect is SQL99, the default for constraint evaluation time is NOT DEFERRABLE. SQL> -- *** Set Dialect *** SQL> -- SQL> SET DIALECT 'SQL99'; SQL> -- SQL> -- *** Create tables *** SQL> -- SQL> CREATE TABLE WORK_STATUS_2 cont> ( cont> STATUS_CODE STATUS_CODE_DOM cont> CONSTRAINT WS2_STATUS_CODE_PRIMARY cont> PRIMARY KEY, cont> STATUS_NAME STATUS_NAME_DOM, cont> STATUS_TYPE STATUS_DESC_DOM cont> ); SQL> -- SQL> CREATE TABLE EMPLOYEES_2 cont> ( cont> EMPLOYEE_ID ID_DOM cont> CONSTRAINT E2_EMPLOYEE_ID_PRIMARY cont> PRIMARY KEY, cont> LAST_NAME LAST_NAME_DOM, cont> FIRST_NAME FIRST_NAME_DOM, cont> MIDDLE_INITIAL MIDDLE_INITIAL_DOM, cont> ADDRESS_DATA_1 ADDRESS_DATA_1_DOM, cont> ADDRESS_DATA_2 ADDRESS_DATA_2_DOM, cont> CITY CITY_DOM, cont> STATE STATE_DOM, cont> POSTAL_CODE POSTAL_CODE_DOM, cont> SEX SEX_DOM cont> CONSTRAINT EMPLOYEE_SEX_VALUES cont> CHECK ( cont> SEX IN ('M', 'F') OR SEX IS NULL cont> ), cont> BIRTHDAY DATE_DOM, cont> STATUS_CODE STATUS_CODE_DOM cont> CONSTRAINT E2_STATUS_CODE_FOREIGN cont> REFERENCES WORK_STATUS_2 (STATUS_CODE), cont> CONSTRAINT EMP_STATUS_CODE_VALUES_2 cont> CHECK ( cont> STATUS_CODE IN ('0', '1', '2') cont> OR STATUS_CODE IS NULL cont> ) cont> ); SQL> -- SQL> CREATE TABLE SALARY_HISTORY_2 cont> ( cont> EMPLOYEE_ID ID_DOM cont> CONSTRAINT SH2_EMPLOYEES_ID_FOREIGN cont> REFERENCES EMPLOYEES_2 (EMPLOYEE_ID), cont> SALARY_AMOUNT SALARY_DOM, cont> SALARY_START DATE_DOM, cont> SALARY_END DATE_DOM cont> ); SQL> Example 2: Creating a table with many SQL data types The following example is an excerpt from the sample program sql_ all_datatypes created during installation of Oracle Rdb in the Samples directory. For a variety of languages, sql_all_datatypes illustrates how you declare program variables to match a variety of data types, and how you can specify those variables in SQL statements when you store and retrieve column values or null values. This example shows the CREATE TABLE statement from the sql_all_ datatypes program. EXEC SQL CREATE TABLE ALL_DATATYPES_TABLE ( CHAR_COL CHAR(10), SMALLINT_COL SMALLINT, SMALLINT_SCALED_COL SMALLINT (3), INTEGER_COL INTEGER, INTEGER_SCALED_COL INTEGER (2), QUADWORD_COL QUADWORD, QUADWORD_SCALED_COL QUADWORD (5), REAL_COL REAL, DOUBLE_PREC_COL DOUBLE PRECISION, DATE_COL DATE, VARCHAR_COL VARCHAR(40) ); Example 3: Specifying default values for columns The following example illustrates the use of default values for columns. Each salesperson enters his or her own daily sales information into the DAILY_SALES table. SQL> -- SQL> CREATE TABLE DAILY_SALES cont> -- cont> -- The column SALESPERSON is based on LAST_NAME_DOM and cont> -- the default value is the user name of the person who cont> -- enters the information: cont> (SALESPERSON LAST_NAME_DOM DEFAULT USER, cont> -- cont> -- Typical work day is 8 hours: cont> HOURS_WORKED SMALLINT DEFAULT 8, cont> HOURS_OVERTIME SMALLINT, cont> GROSS_SALES INTEGER ); SQL> -- SQL> -- Insert daily sales information accepting the SQL> -- default values for SALESPERSON and HOURS_WORKED: SQL> -- SQL> INSERT INTO DAILY_SALES cont> (HOURS_OVERTIME, GROSS_SALES ) cont> VALUES cont> (1, 2499.00); 1 row inserted SQL> SELECT * FROM DAILY_SALES; SALESPERSON HOURS_WORKED HOURS_OVERTIME GROSS_SALES KILPATRICK 8 1 2499 1 row selected Example 4: Violating a constraint indirectly with the DELETE statement Constraints prevent INSERT statements from adding rows to a table that do not satisfy conditions specified in the constraint. Constraints also prevent DELETE or UPDATE statements from deleting or changing values in a table if the deletion or change violates the constraint on another table in the database. The following example illustrates that point: SQL> -- TEST has no constraints defined for it, but it is subject to SQL> -- restrictions nonetheless because of the constraint specified SQL> -- in TEST2: SQL> CREATE TABLE TEST cont> (COL1 REAL); SQL> SQL> CREATE TABLE TEST2 cont> (COL1 REAL, cont> CHECK (COL1 IN cont> (SELECT COL1 FROM TEST)) cont> ); SQL> COMMIT; SQL> SQL> INSERT INTO TEST VALUES (1); 1 row inserted SQL> INSERT INTO TEST2 VALUES (1); 1 row inserted SQL> COMMIT; SQL> -- This DELETE statement will fail because it will cause COL1 in SQL> -- TEST2 to contain a value without the same value in COL1 of TEST: SQL> DELETE FROM TEST WHERE COL1 = 1; 1 row deleted SQL> COMMIT; %RDB-E-INTEG_FAIL, violation of constraint TEST2_CHECK1 caused operation to fail Example 5: Evaluating constraints at verb time Deferrable constraints are not evaluated until a transaction issues a COMMIT statement. You can specify that constraints be evaluated more frequently with the EVALUATING clause of the SET TRANSACTION statement. SQL> create table TEST cont> (col1 integer, cont> col2 integer cont> constraint C2 cont> unique cont> deferrable cont> ); SQL> SQL> insert into TEST (col1, col2) values (1, 2); 1 row inserted SQL> commit; SQL> SQL> /* ***> This INSERT will violate the constraint as shown by ***> the error during COMMIT ***> */ SQL> insert into TEST (col1, col2) values (1, 2); 1 row inserted SQL> commit; %RDB-E-INTEG_FAIL, violation of constraint C2 caused operation to fail -RDB-F-ON_DB, on database USER_DISK:[DOC.DATABASES]MF_PERSONNEL.RDB;1 SQL> /* ***> The COMMIT failed, so we will ROLLBACK ***> */ SQL> rollback; SQL> SQL> /* ***> You can change the evalution time using the EVALUATING ***> clause of SET TRANSACTION ***> */ SQL> set transaction read write evaluating C2 at verb time; SQL> insert into TEST (col1, col2) values (1, 2); %RDB-E-INTEG_FAIL, violation of constraint C2 caused operation to fail -RDB-F-ON_DB, on database USER_DISK:[DOC.DATABASES]MF_PERSONNEL.RDB;1 SQL> rollback;
20 – TRIGGER
Creates triggers for a specified table. A trigger defines the actions to occur before or after the table is updated (by a write operation such as an INSERT, DELETE, or UPDATE statement). The trigger is associated with a single table, takes effect at a specific time for a particular type of update, and causes one or more triggered actions to be performed. If the trigger specifies multiple actions, each action is performed in the order in which it appears within the trigger definition. With triggers, you can define useful actions such as: o Cascading deletes Deleting a row from one table causes additional rows to be deleted from other tables that are related to the first table by key values. o Cascading updates Updating a row in one table causes additional rows to be updated in other tables that are related to the first table by key values. These updates are commonly limited to the key fields themselves. o Summation updates Updating a row from one table causes a value in a row of another table to be updated by being increased or decreased. o Hidden deletes Causing rows to be deleted from a table by moving them to a parallel table that is not otherwise used by the database. NOTE Combinations of table-specific constraints and appropriately defined triggers, by themselves, are not sufficient to guarantee that database integrity is preserved when the database is updated. If integrity is to be preserved, table-specific constraints and triggers must be used in conjunction with a common set of update procedures that ensure completely reproducible and consistent retrieval and update strategies. The CREATE TRIGGER statement adds the trigger definition to the physical database. A triggered action consists of an optional predicate and some triggered statements. If specified, the predicate must evaluate to true for the triggered statements in the action to execute. Each triggered statement is executed in the order in which it appears within the triggered action clause. The triggered statement can be: o A DELETE statement o An UPDATE statement o An INSERT statement o A CALL statement o A SIGNAL statement o A TRACE statement o An ERROR statement
20.1 – Environment
You can use the CREATE TRIGGER statement: o In interactive SQL o Embedded in host language programs to be precompiled o As part of a procedure in an SQL module o In dynamic SQL as a statement to be dynamically executed
20.2 – Format
(B)0[m[1;4mCREATE[m[1m [1;4mTRIGGER[m[1m qq> <trigger-name> qqqqqqk [m [1mlqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1mmqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqk [m [1m mq> [1;4mSTORED[m[1m [1;4mNAME[m[1m IS <stored-name> qqqj x [m [1mlqqqqqqqqqqqqqqqqqq<qqqqqqqqqqqqqqqqqqqqj [m [1mmwq> [1;4mBEFORE[m[1m qwqwq> [1;4mINSERT[m[1m qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqk [m [1m mq> [1;4mAFTER[m[1m qqj tq> [1;4mDELETE[m[1m qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu x [m [1m mq> [1;4mUPDATE[m[1m qqwqqqqqqqqqqqqqqqqqqqqqqqqqqwqqj x [m [1m mqq> [1;4mOF[m[1m qw> <column-name> wj x [m [1m mqqq , <qqqqqqqqqj x [m [1mlqqqqqqqqqqqqqqqqqqqqqqqqqqqq<qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1mmq> [1;4mON[m[1m <table-name> wqqqqqqqqqqqqqqqqqqqqqqqwwq> triggered-action qw> [m [1m mq> referencing-clause qjmqqqqqqqqqq<qqqqqqqqqqj [m [1m [m (B)0[m[1mreferencing-clause = [m [1m [m [1;4mREFERENCING[m[1m qwwq> [1;4mOLD[m[1m AS qq> <old-correlation-name> qwwq> [m [1m xmq> [1;4mNEW[m[1m AS qq> <new-correlation-name> qjx [m [1m mqqqqqqqqqqqqqqqqqq<qqqqqqqqqqqqqqqqqqqqqj [m [1m [m (B)0[m[1mtriggered-action = [m [1m [m [1mqqwqqqqqqqqqqqqqqqqqqqqqwq> ( qw> triggered-statement qwq> ) qk [m [1m mq> [1;4mWHEN[m[1m (predicate) qj tqqqqqqqqqqq , <qqqqqqqqu x [m [1mmqqqqqqqqqqq[m [1m;[m [1m<qqqqqqqqj[m [1mx[m [1m lqqqqqqqqqqqqqqqqqqqqqqqqqqq<qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1m mqwqqqqqqqqqqqqqqqqqqqqqqqqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqq> [m [1m tq> [1;4mFOR[m[1m [1;4mEACH[m[1m [1;4mROW[m[1m qqqqqqqqu [m [1m mq> [1;4mFOR[m[1m [1;4mEACH[m[1m [1;4mSTATEMENT[m[1m qqj [m (B)0[m[1mtriggered-statement = [m [1m [m [1mqqwq> call-statement qqqwqq> [m [1m tq> delete-statement qu [m [1m tq> [1;4mERROR[m [1mqqqqqqqqqqqqu [m [1mtq> insert-statement qu[m [1mtq> signal-statement qu[m [1mtq> trace-statement qqu[m [1m mq> update-statement qj [m [1m [m
20.3 – Arguments
20.3.1 – call-statement
Specifies the stored procedure to invoke. You can only call procedures with IN parameters. Operations on the triggering table are not permitted due to possible side effects and recursive calls.
20.3.2 – column-name
The name of a column within the specified table to be checked for deletion, modification, or insertion. Use this argument only with UPDATE triggers.
20.3.3 – delete-statement
Specifies the row of a table that you want to delete. If you specify CURRENT OF cursor-name with the WHERE clause of the DELETE statement, you receive an error message because the cursor is not visible to the CREATE TRIGGER statement.
20.3.4 – ERROR
Provides the following message: RDMS-E-TRIG_ERROR, Trigger 'trigger_name' forced an error. A triggered ERROR statement cancels the DELETE, UPDATE, or INSERT statement that invoked the trigger.
20.3.5 – FOR_EACH
Syntax options: FOR EACH ROW | FOR EACH STATEMENT Specifies whether the triggered action is evaluated once per triggering statement, or for each row of the subject table that is affected by the triggering statement. If you specify FOR EACH STATEMENT, then the triggered action is evaluated only once, and row values are not available to the triggered action. The FOR EACH STATEMENT clause is the default.
20.3.6 – insert-statement
Specifies the new row or rows you want to add to a table.
20.3.7 – old-correlation-name
A temporary name used to refer to the row values as they existed before an UPDATE operation occurred. If you do not specify the FOR EACH ROW clause, this correlation name cannot be referred to in the triggered statement.
20.3.8 – new-correlation-name
A temporary name used to refer to the new row values to be applied by the UPDATE operation. If you do not specify the FOR EACH ROW clause, this correlation name cannot be referred to in the triggered statement.
20.3.9 – referencing-clause
Lets you specify whether you want to refer to the row values as they existed before an UPDATE operation occurred or the new row values after they are applied by the UPDATE operation. Do not use this clause with INSERT or DELETE operations. You can specify each option (OLD AS old-correlation-name or NEW AS new-correlation-name) only once in the referencing clause.
20.3.10 – signal-statement
Specifies that the signaled SQLSTATE status parameter is to be passed back to the application or SQL interface and that the current routine and all calling routines are to be terminated. This provides a more complete error mechanism than is provided by the ERROR clause.
20.3.11 – STORED_NAME_IS
Specifies a name that Oracle Rdb uses to access a trigger created in a multischema database. The stored name allows you to access multischema definitions using interfaces, such as Oracle RMU, the Oracle Rdb management utility, that do not recognize multiple schemas in one database. You cannot specify a stored name for a trigger in a database that does not allow multiple schemas. For more information on stored names, see the User_Supplied_Names HELP topic.
20.3.12 – table-name
The name of the table for which this trigger is defined.
20.3.13 – trace-statement
Allows applications to add triggers to log information when trace logging is active.
20.3.14 – triggered-action
Consists of an optional predicate, some triggered statements, and an optional frequency clause. If specified, the predicate must evaluate to true for the triggered statements in the triggered action clause to execute. Each triggered statement is executed in the order in which it appears within the triggered action clause.
20.3.15 – triggered-statement
Updates the database or generates an error message.
20.3.16 – update-statement
Specifies the row of a table that you want to modify. If you specify CURRENT OF cursor-name with the WHERE clause of the UPDATE statement, you receive an error message because the cursor is not visible to the CREATE TRIGGER statement.
20.3.17 – WHEN predicate
Describes the optional condition that must be satisfied before the associated triggered statements are executed. This predicate cannot refer to any host language variable. To avoid ambiguity between columns and external function callouts, use parentheses around the predicate in the WHEN clause.
20.4 – Examples
Example 1: Defining a cascading delete trigger The following SQL procedure shows a trigger from the sample personnel database that deletes rows in several tables before deleting a row in the EMPLOYEES table. Each associated employee row (from the tables that have foreign keys referring to the primary key in the employee row) is deleted. The employee identification number being deleted (00164) belongs to an employee who is also a manager; therefore, the MANAGER_ID column in the DEPARTMENTS table is set to null, as specified by the trigger. SQL> SET TRANSACTION READ WRITE; SQL> -- SQL> -- Display the EMPLOYEE_ID_CASCADE_DELETE trigger SQL> -- in the sample database: SQL> -- SQL> SHOW TRIGGER EMPLOYEE_ID_CASCADE_DELETE EMPLOYEE_ID_CASCADE_DELETE Source: EMPLOYEE_ID_CASCADE_DELETE BEFORE DELETE ON EMPLOYEES (DELETE FROM DEGREES D WHERE D.EMPLOYEE_ID = EMPLOYEES.EMPLOYEE_ID) FOR EACH ROW (DELETE FROM JOB_HISTORY JH WHERE JH.EMPLOYEE_ID = EMPLOYEES.EMPLOYEE_ID) FOR EACH ROW (DELETE FROM SALARY_HISTORY SH WHERE SH.EMPLOYEE_ID = EMPLOYEES.EMPLOYEE_ID) FOR EACH ROW ! Also, if an employee is terminated and that employee ! is the manager of a department, set the manager_id ! null for that department. (UPDATE DEPARTMENTS D SET D.MANAGER_ID = NULL WHERE D.MANAGER_ID = EMPLOYEES.EMPLOYEE_ID) FOR EACH ROW SQL> -- SQL> -- The EMPLOYEES table has a value of '00164' SQL> -- in the EMPLOYEE_ID column: SQL> -- SQL> SELECT * FROM EMPLOYEES E WHERE E.EMPLOYEE_ID = '00164'; EMPLOYEE_ID LAST_NAME FIRST_NAME MIDDLE_INITIAL ADDRESS_DATA_1 ADDRESS_DATA_2 CITY STATE POSTAL_CODE SEX BIRTHDAY STATUS_CODE 00164 Toliver Alvin A 146 Parnell Place Chocorua NH 03817 M 28-Mar-1947 1 1 row selected SQL> -- SQL> -- SQL> -- The DEGREES table has two values of '00164' SQL> -- in the EMPLOYEE_ID column: SQL> -- SQL> SELECT * FROM DEGREES D WHERE D.EMPLOYEE_ID = '00164'; EMPLOYEE_ID COLLEGE_CODE YEAR_GIVEN DEGREE DEGREE_FIELD 00164 PRDU 1973 MA Applied Math 00164 PRDU 1982 PhD Statistics 2 rows selected SQL> -- SQL> -- SQL> -- The JOB_HISTORY table has the value of '00164' in SQL> -- several rows in the EMPLOYEE_ID column: SQL> -- SQL> SELECT * FROM JOB_HISTORY JH WHERE JH.EMPLOYEE_ID = '00164'; EMPLOYEE_ID JOB_CODE JOB_START JOB_END DEPARTMENT_CODE SUPERVISOR_ID 00164 DMGR 21-Sep-1981 NULL MBMN 00228 00164 SPGM 5-Jul-1980 20-Sep-1981 MCBM 00164 2 rows selected SQL> -- SQL> -- SQL> -- The SALARY_HISTORY table has a value of '00164' SQL> -- in several rows in the EMPLOYEE_ID column: SQL> -- SQL> SELECT * FROM SALARY_HISTORY SH WHERE SH.EMPLOYEE_ID = '00164'; EMPLOYEE_ID SALARY_AMOUNT SALARY_START SALARY_END 00164 $26,291.00 5-Jul-1980 2-Mar-1981 00164 $51,712.00 14-Jan-1983 NULL 00164 $26,291.00 2-Mar-1981 21-Sep-1981 00164 $50,000.00 21-Sep-1981 14-Jan-1983 4 rows selected SQL> -- SQL> -- SQL> -- The DEPARTMENTS table has a value of '00164' SQL> -- in the MANAGER_ID column: SQL> -- SQL> SELECT * FROM DEPARTMENTS D WHERE D.MANAGER_ID = '00164'; DEPARTMENT_CODE DEPARTMENT_NAME MANAGER_ID BUDGET_PROJECTED BUDGET_ACTUAL MBMN Board Manufacturing North 00164 NULL NULL 1 row selected SQL> -- SQL> -- SQL> -- Test the trigger by deleting the row with a value of '00164' SQL> -- in the EMPLOYEE_ID column from the EMPLOYEES table: SQL> -- SQL> DELETE FROM EMPLOYEES E WHERE E.EMPLOYEE_ID = '00164'; 1 row deleted SQL> -- SQL> -- The row with a value of '00164' in the EMPLOYEE_ID column SQL> -- was deleted from the EMPLOYEES table: SQL> -- SQL> SELECT * FROM EMPLOYEES E WHERE E.EMPLOYEE_ID = '00164'; 0 rows selected SQL> -- SQL> -- The rows with a value of '00164' in the EMPLOYEE_ID column SQL> -- were deleted from the DEGREES table: SQL> -- SQL> SELECT * FROM DEGREES D WHERE D.EMPLOYEE_ID = '00164'; 0 rows selected SQL> -- SQL> -- The rows with a value of '00164' in the EMPLOYEE_ID SQL> -- column were deleted from the JOB_HISTORY table: SQL> -- SQL> SELECT * FROM JOB_HISTORY JH WHERE JH.EMPLOYEE_ID = '00164'; 0 rows selected SQL> -- SQL> -- The rows with a value of '00164' in the EMPLOYEE_ID SQL> -- column were deleted from the SALARY_HISTORY table: SQL> -- SQL> SELECT * FROM SALARY_HISTORY SH WHERE SH.EMPLOYEE_ID = '00164'; 0 rows selected SQL> -- SQL> -- The value of '00164' in the MANAGER_ID column was set to null SQL> -- in the DEPARTMENTS table: SQL> -- SQL> SELECT * FROM DEPARTMENTS D WHERE D.DEPARTMENT_CODE = 'MBMN'; DEPARTMENT_CODE DEPARTMENT_NAME MANAGER_ID BUDGET_PROJECTED BUDGET_ACTUAL MBMN Board Manufacturing North NULL NULL NULL 1 row selected SQL> -- SQL> ROLLBACK; Example 2: Defining a trigger that performs an update Before the STATUS_CODE column in WORK_STATUS table is updated, the STATUS_CODE_CASCADE_UPDATE trigger in the following SQL procedure updates the associated rows in the EMPLOYEES table. The REFERENCING clause specifies OLD_WORK_STATUS as the correlation name for the values in the WORK_STATUS table before the UPDATE statement executes, and NEW_WORK_STATUS as the correlation name for the values in the WORK_STATUS table after the UPDATE statement executes. SQL> -- Display the STATUS_CODE_CASCADE_UPDATE trigger in SQL> -- the sample database: SQL> -- SQL> SHOW TRIGGER STATUS_CODE_CASCADE_UPDATE STATUS_CODE_CASCADE_UPDATE Source: STATUS_CODE_CASCADE_UPDATE BEFORE UPDATE OF STATUS_CODE ON WORK_STATUS REFERENCING OLD AS OLD_WORK_STATUS NEW AS NEW_WORK_STATUS (UPDATE EMPLOYEES E SET E.STATUS_CODE = NEW_WORK_STATUS.STATUS_CODE WHERE E.STATUS_CODE = OLD_WORK_STATUS.STATUS_CODE) FOR EACH ROW SQL> -- SQL> -- Change the STATUS_CODE column with a value of 2 to a value of 3: SQL> -- SQL> UPDATE WORK_STATUS WS SET STATUS_CODE="3" WHERE STATUS_CODE="2"; 1 row updated SQL> -- SQL> -- The trigger changes any STATUS_CODE column in the EMPLOYEES table SQL> -- with a value of 2 to a value of 3. Therefore, no rows are SQL> -- selected for the first query that follows, but several are selected SQL> -- for the second query: SQL> -- SQL> SELECT * FROM EMPLOYEES E WHERE E.STATUS_CODE = "2"; 0 rows selected SQL> -- SQL> SELECT * FROM EMPLOYEES E WHERE E.STATUS_CODE = "3"; EMPLOYEE_ID LAST_NAME FIRST_NAME MIDDLE_INITIAL ADDRESS_DATA_1 ADDRESS_DATA_2 CITY STATE POSTAL_CODE SEX BIRTHDAY STATUS_CODE 00165 Smith Terry D 120 Tenby Dr. Chocorua NH 03817 M 15-May-1954 3 00178 Goldstone Neal NULL 194 Lyons Av, Colebrook NH 03576 M 25-Apr-1952 3 . . . 00358 Lapointe Jo Ann C 70 Tenby Dr. Chocorua NH 03817 F 24-Feb-1931 3 12 rows selected SQL> -- SQL> ROLLBACK; Example 3: Defining a trigger that updates a sales summary The following example defines a trigger that updates a monthly sales total after each daily sale is made. SQL> -- SQL> -- Create the table to keep track of monthly sales: SQL> CREATE TABLE MONTHLY_SALES cont> ( SALES_AMOUNT INTEGER); SQL> -- SQL> -- Create the table to keep track of sales made today: SQL> CREATE TABLE DAILY_SALES cont> ( SALES_AMOUNT INTEGER); SQL> -- SQL> -- Assume that $250.00 of sales have been made during the current month: SQL> INSERT INTO MONTHLY_SALES cont> (SALES_AMOUNT) VALUES (250); 1 row inserted SQL> -- SQL> -- After adding a new value to the SALES_AMOUNT column in SQL> -- DAILY_SALES table, SQL updates the SALES column in SQL> -- the MONTHLY_SALES table with the amount of the new sale: SQL> CREATE TRIGGER UPDATE_SALES_TOTAL_ON_NEW_SALE cont> AFTER INSERT ON DAILY_SALES cont> (UPDATE MONTHLY_SALES M cont> SET M.SALES_AMOUNT = M.SALES_AMOUNT + DAILY_SALES.SALES_AMOUNT) cont> FOR EACH ROW; SQL> -- SQL> -- The following statement records a new $5.00 sale for today: SQL> INSERT INTO DAILY_SALES cont> (SALES_AMOUNT) VALUES (5); 1 row inserted SQL> -- SQL> -- The value for the SALES_AMOUNT column of the DAILY_SALES table SQL> -- is $5.00 and the value of the SALES_AMOUNT column of the SQL> -- MONTHLY_SALES table is $255.00: SQL> SELECT * FROM DAILY_SALES; SALES_AMOUNT 5 1 row selected SQL> -- SQL> SELECT * FROM MONTHLY_SALES; SALES_AMOUNT 255 1 row selected SQL> -- SQL> -- When a new $9.00 sale is made, the values in the two rows of the SQL> -- SALES_AMOUNT column of the DAILY_SALES table are $5.00 and $9.00 SQL> -- and the value of the SALES_AMOUNT column of the MONTHLY_SALES SQL> -- table is $264.00: SQL> INSERT INTO DAILY_SALES cont> (SALES_AMOUNT) VALUES (9); 1 row inserted SQL> -- SQL> SELECT * FROM DAILY_SALES; SALES_AMOUNT 5 9 2 rows selected SQL> -- SQL> SELECT * FROM MONTHLY_SALES; SALES_AMOUNT 264 1 row selected SQL> -- SQL> ROLLBACK; SQL> -- Example 4: Defining a trigger that sets column values to null Before the STATUS_CODE column in the WORK_STATUS table is deleted, this trigger causes the associated WORK_STATUS columns in the EMPLOYEES table to be set to null. SQL> CREATE TRIGGER STATUS_CODE_ON_DELETE_SET_NULL cont> BEFORE DELETE ON WORK_STATUS cont> (UPDATE EMPLOYEES E SET E.STATUS_CODE = NULL cont> WHERE E.STATUS_CODE = WORK_STATUS.STATUS_CODE) cont> FOR EACH ROW; SQL> -- SQL> -- Delete any row in the WORK_STATUS table where the STATUS_CODE SQL> -- column has a value of 1: SQL> DELETE FROM WORK_STATUS WS WHERE WS.STATUS_CODE = "1"; 1 row deleted SQL> -- SQL> -- This trigger sets the STATUS_CODE column value to null in many SQL> -- rows in the EMPLOYEES table: SQL> SELECT * FROM EMPLOYEES E WHERE E.STATUS_CODE IS NULL; EMPLOYEE_ID LAST_NAME FIRST_NAME MIDDLE_INITIAL ADDRESS_DATA_1 ADDRESS_DATA_2 CITY STATE POSTAL_CODE SEX BIRTHDAY STATUS_CODE 00416 Ames Louie A 61 Broad st. NULL Alton NH 03809 M 13-Apr-1941 NULL 00374 Andriola Leslie Q 111 Boston Post Rd. NULL Salisbury NH 03268 M 19-Mar-1955 NULL . . . 00200 Ziemke Al F 121 Putnam Hill Rd. NULL Winnisquam NH 03289 M 27-Oct-1928 NULL 88 rows selected SQL> ROLLBACK; Example 5: Defining a trigger that prevents deletion of a row that exists in two tables Suppose that a user wants to delete only those rows in the JOB_ HISTORY table that do not also exist in the JOBS table. This is difficult to do with constraints because a row can exist in one table with a key number that does not exist in the other table. The following statement creates a trigger that causes an error when the user tries to delete a row that exists in table JOB_ HISTORY. SQL> CREATE TRIGGER DELETE_GUARD cont> BEFORE DELETE ON JOB_HISTORY cont> WHEN EXISTS (SELECT JOBS.JOB_CODE FROM JOBS cont> WHERE JOBS.JOB_CODE=JOB_HISTORY.JOB_CODE) cont> (ERROR) FOR EACH ROW; SQL> -- SQL> -- Now attempt a deletion that violates the trigger. SQL> -- SQL> DELETE FROM JOB_HISTORY WHERE JOB_CODE = 'DMGR'; %RDB-E-TRIG_INV_UPD, invalid update; encountered error condition defined for trigger -RDMS-E-TRIG_ERROR, trigger DELETE_GUARD forced an error -RDB-F-ON_DB, on database DISK1:[DEPT3.SQL]MF_PERSONNEL.RDB;1 Example 6: Defining a trigger that saves audit information SQL> -- Create new table to record changes made to SQL> -- EMPLOYEES table SQL> CREATE TABLE AUDIT_TRAIL cont> (LOG DATE VMS, cont> PERSON CHAR(31), cont> TBL_NAME CHAR(10), cont> OPER CHAR(1)); SQL> COMMIT; SQL> -- Create a trigger so that each time SQL> -- an INSERT operation is performed, SQL> -- a record is stored in the AUDIT_TRAIL table. SQL> CREATE TRIGGER EMPS_TRIGGER cont> AFTER INSERT cont> ON EMPLOYEES cont> (INSERT INTO AUDIT_TRAIL cont> VALUES (CURRENT_TIMESTAMP, cont> CURRENT_USER, 'EMPLOYEES', 'I')) cont> FOR EACH STATEMENT; SQL> -- The AUDIT_TRAIL table currently has no records. SQL> SELECT * FROM AUDIT_TRAIL; 0 rows selected SQL> -- Insert a record into EMPLOYEES SQL> INSERT INTO EMPLOYEES cont> (EMPLOYEE_ID, LAST_NAME) cont> VALUES ('00964', 'FRENCH'); 1 row inserted SQL> -- See if trigger updated the AUDIT_TRAIL table. SQL> SELECT * FROM AUDIT_TRAIL; LOG PERSON TBL_NAME OPER 17-JUN-2003 15:04:31.43 STEWART EMPLOYEES I 1 row selected Example 7: Using TRACE as a trigger action SQL> set flags 'TRACE'; SQL> create table M_TABLE (a integer, b integer); SQL> SQL> create trigger T_A cont> after insert on M_TABLE cont> (trace 'in a trigger: ' || cast(M_TABLE.a as varchar(10))) cont> for each row; SQL> SQL> insert into M_TABLE (a, b) values (1, 10); ~Xt: in a trigger: 1 1 row inserted SQL> Example 8: Using SIGNAL as a trigger action SQL> create table M_TABLE (a integer, b integer); SQL> SQL> create trigger T_A cont> after insert on M_TABLE2 cont> when (M_TABLE2.a is not null) cont> (signal '12345' ('in a trigger: ' cont> || cast(M_TABLE2.a as varchar(10)))) cont> for each row; SQL> SQL> insert into M_TABLE2 (a, b) values (1, 10); %RDB-E-SIGNAL_SQLSTATE, routine "T_A" signaled SQLSTATE "12345" -RDB-I-TEXT, in a trigger: 1 SQL> Example 9: Using CALL as a trigger action SQL> create module M_MODULE cont> language SQL cont> cont> procedure M_K (in :a int); cont> trace 'called from a trigger: ' || cast(:a as varchar(10)); cont> cont> end module; SQL> SQL> create table M_TABLE (a integer, b integer); SQL> SQL> create trigger T_A cont> after insert on M_TABLE cont> (call M_K (M_TABLE.a)) cont> for each row; SQL> SQL> insert into M_TABLE (a, b) values (1, 10); ~Xt: called from a trigger: 1 1 row inserted SQL>
21 – USER
Creates a special security profile entry to identify a database user. That user can be granted roles, which in turn provide access to database objects.
21.1 – Environment
You can use the CREATE USER statement: o In interactive SQL o Embedded in host language programs o As part of a procedure in an SQL module or other compound statement o In dynamic SQL as a statement to be dynamically executed
21.2 – Format
(B)0[m[1;4mCREATE[m[1m [1;4mUSER[m[1m qqwqqq> <username> qqqq> [1;4mIDENTIFIED[m[1m [1;4mEXTERNALLY[m[1m qqwqqqqqk [m [1m mqqq> [1;4mPUBLIC[m[1m qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj x [m [1mlqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1mmqqqqqqqqqqqqqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqqqqqqqqqqqqqqqqqqqq> [m [1m mqqq> create-user-opts qqqqqqqqqj [m (B)0[m[1mcreate-user-opts = [m [1m [m [1mqwq> [1;4mACCOUNT[m[1m qqwq>[1;4mLOCK[m[1m qqqwqqqqqqqqqqqqqqqqqqqqqwqq> [m [1m x mq>[1;4mUNLOCK[m[1m qj [m [1m x [m [1mtq> [1;4mCOMMENT[m[1m IS qwq> '<string>' qqwqqqqqqqqqqqqqu [m [1mx mqqqqqqq / <qqqqqj x [m [1m [m [1mtq> [1;4mNO[m[1m [1;4mPROFILE[m[1m qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqu[m [1mmq> [1;4mPROFILE[m[1m <profile_name> qqqqqqqqqqqqqqqqqqqqj[m [1m [m
21.3 – Arguments
21.3.1 – ACCOUNT lock-option
Syntax options: ACCOUNT LOCK | ACCOUNT UNLOCK The ACCOUNT LOCK clause disables access to the database by the user for whom the CREATE USER statement is being applied. The ACCOUNT UNLOCK clause allows that user access to the database. The ACCOUNT UNLOCK clause is the default.
21.3.2 – COMMENT IS 'string'
Adds a comment about the user. SQL displays the text of the comment when it executes a SHOW USERS statement. Enclose the comment in single quotation marks (') and separate multiple lines in a comment with a slash mark (/).
21.3.3 – IDENTIFIED_EXTERNALLY
Indicates that the user will be authenticated through the operating system.
21.3.4 – PROFILE
Syntax options: PROFILE | NOPROFILE Identifies a new profile for assignment to the user. The specified profile name must be the name of an existing profile. NOPROFILE is the default behavior and indicates that no special restrictions are applied to this user.
21.3.5 – PUBLIC
Explicitly creates a PUBLIC security profile entry in the database.
21.3.6 – username
The name of the user to add to the database. This must match the name of an existing OpenVMS username.
21.4 – Examples
Example 1: Creating a New User and Locking Her Account SQL> CREATE USER munroy IDENTIFIED EXTERNALLY cont> ACCOUNT LOCK cont> COMMENT IS 'User munroy starts job on'/ cont> 'May 1, 2003. Unlock when she starts'; Example 2: Adding a profile to a user This example creates a new profile that defines the DEFAULT transaction and then assigns a profile while creating a new user. The next time the user attaches to the database the START DEFAULT TRANSACTION statement will use the defined profile instead of the standard READ ONLY default. SQL> create profile READ_COMMITTED cont> default transaction read write isolation level read committed wait 30; SQL> show profile READ_COMMITTED READ_COMMITTED Default transaction read write wait 30 Isolation level read committed SQL> create user JAIN identified externally profile READ_COMMITTED; SQL> show user JAIN; JAIN Identified externally Account is unlocked Profile: READ_COMMITTED No roles have been granted to this user
22 – VIEW
Creates a view definition. A view is a logical structure that refers to rows stored in other tables. Data in a view is not physically stored in the database. You can include in a view definition combinations of rows and columns from other tables and view definitions in the schema. You define a view by specifying a select expression, that: o Names the criteria for selecting the tables, rows, and columns for the view o Specifies a set of columns from those tables When the CREATE VIEW statement executes, SQL adds the view definition to the physical database. If you declared the schema with the PATHNAME argument, the definition is also stored in the repository.
22.1 – Environment
You can use the CREATE VIEW statement: o In interactive SQL o Embedded in host language programs to be precompiled o As part of a procedure in an SQL module o In dynamic SQL as a statement to be dynamically executed
22.2 – Format
(B)0[m[1;4mCREATE[m[1m [1;4mVIEW[m[1m qq> <view-name> qqqqqqqqqqqqqqqqqqqqqqqqqk[m [1m lqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj[m [1m mwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqqqqqqqqqqqqqk[m [1m mq> [1;4mSTORED[m[1m [1;4mNAME[m[1m IS <stored-name> qqqj x[m [1mlqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj[m [1mmwqqqqqqqqqqqqqqqqqqqqqqqq>qqqqqqqqqqqqqqqqqqqqqqqqwqk[m [1m mq> ( qwq> <column-name> qwqqqqqqqqqqqqqqwqwq> ) qj x[m [1m x lqqqqqqqqqqqqqqqqj x x x[m [1m x mwqwqqqqqqqqqqqqqqqqqqqqqqqqwqwqj x x[m [1m x x mq> sql-and-dtr-clause qqj x x x[m [1m x mqqqqqqqqqqqqq<qqqqqqqqqqqqqqj x x[m [1m mqqqqqqqqqqqqqqqqq , <qqqqqqqqqqqqqqj x[m [1mlqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj[m [1mmq> [1;4mAS[m[1m select-expr qqqwqqqqqqqqqqqqqqqqqqqqqqqqwqq> [m [1m mq> check-option-clause qj [m [1m [m (B)0[m[1mselect-expr = [m [1m [m [1m [m [1m [m [1mqwqwq> select-clause qqqqqqqqqqqqwqwqqqqqqk[m [1m [m [1m x tq> ( select-expr ) qqqqqqqqqqqu x [m [1mx[m [1m [m [1m [m [1m x mq> [1;4mTABLE[m[1m table-ref qqqqqqqqqqj x x [m [1m [m [1m mqqqqqq select-merge-clause <qqqqqqqj [m [1m x[m [1m lqqqqqqqqqqqqqqqqqqq <qqqqqqqqqqqqqqqqqqqj[m [1m [m [1mmqwqqqqqqqqqqqqqqqqqqqqwqqwqqqqqqqqqqqqqqqqqqwqqwqqqqqqqqqqqqqqqqqqqqwq>[m [1m [m [1m mq> order-by-clause qj[m [1mmq> offset-clause qj [m [1mmq> limit-to-clause qj[m (B)0[m[1msql-and-dtr-clause = [m [1m [m [1mqwq> [1;4mQUERY[m[1m [1;4mHEADER[m[1m IS qw> <quoted-string> wqqqqqqqqqqqqqqqqqqqwq> [m [1m x mqqqqqq / <qqqqqqqqj x [m [1m tq> [1;4mEDIT[m[1m [1;4mSTRING[m[1m IS <quoted-string> qqqqqqqqqqqqqqqqqqqqqqqqqu [m [1m x x [m [1m tq> [1;4mQUERY[m[1m [1;4mNAME[m[1m FOR qwq> DTR qqqqqqqqwq> IS <quoted-string> qu [m [1m x mq> DATATRIEVE qj x [m [1m mq> [1;4mDEFAULT[m[1m [1;4mVALUE[m[1m FOR qwq> DTR qqqqqqqqwq> IS literal[m [1m qqqqj [m [1m mq> DATATRIEVE qj [m [1m [m (B)0[m[1mcheck-option-clause = [m [1m [m [1;4mWITH[m[1m [1;4mCHECK[m[1m [1;4mOPTION[m[1m qqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqq>[m [1m mq> [1;4mCONSTRAINT[m[1m <check-option-name> j [m [1m [m
22.3 – Arguments
22.3.1 – check-option-clause
A constraint that places restrictions on update operations made to a view. The check option clause ensures that any rows that are inserted or updated in a view conform to the definition of the view. Do not specify the WITH CHECK OPTION clause with views that are read-only.
22.3.2 – column-name
A list of names for the columns of the view. If you omit column names, SQL assigns the names from the columns in the source tables in the select expression. However, you must specify names for all the columns of the view in the following cases: o The select expression generates columns with duplicate names. o The select expression uses statistical functions or arithmetic expressions to create new columns that are not in the source tables.
22.3.3 – CONSTRAINT
Specify a name for the WITH CHECK OPTION constraint. If you omit the name, SQL creates a name. However, Oracle Rdb recommends that you always name constraints. If you supply a name for the WITH CHECK OPTION constraint, the name must be unique in the schema. The name for the WITH CHECK OPTION constraint is used by the INTEG_FAIL error message when an INSERT or UPDATE statement violates the constraint.
22.3.4 – select-expr
A select expression that defines which columns and rows of the specified tables SQL includes in the view. The select expression for a nonmultischema database can name only tables in the same schema as the view. A select expression for a multischema database can name a table in any schema in the database; the schema need not be in the same catalog as the view being created. See the Select_Expressions HELP topic for more information on select expressions.
22.3.5 – sql-and-dtr-clause
Optional SQL and DATATRIEVE formatting clauses. See the DATATRIEVE HELP topic for more information on formatting clauses.
22.3.6 – STORED_NAME_IS
Specifies a name that Oracle Rdb uses to access a view created in a multischema database. The stored name allows you to access multischema definitions using interfaces, such as Oracle RMU, the Oracle Rdb management utility, that do not recognize multiple schemas in one database. You cannot specify a stored name for a view in a database that does not allow multiple schemas. For more details about stored names, see the User_Supplied_Names HELP topic.
22.3.7 – view-name
Name of the view definition you want to create. When choosing a name, follow these rules: o Use a name that is unique among all view and table names in the schema. o Use any valid SQL name (see the User_Supplied_Names HELP topic for more information).
22.4 – Examples
Example 1: Defining a view based on a single table This example shows a view definition that uses three columns from a single table, EMPLOYEES. SQL> CREATE VIEW EMP_NAME cont> AS SELECT cont> FIRST_NAME, cont> MIDDLE_INITIAL, cont> LAST_NAME cont> FROM EMPLOYEES; SQL> -- SQL> -- Now display the rows from the view just created. SQL> SELECT * FROM EMP_NAME; FIRST_NAME MIDDLE_INITIAL LAST_NAME Alvin A Toliver Terry D Smith . . . Example 2: Defining a view that does not allow you to insert or update rows that do not conform to the view's definition This example shows a view definition using the WITH CHECK OPTION clause. SQL> CREATE VIEW ADMN_VIEW cont> AS SELECT * FROM JOB_HISTORY cont> WHERE DEPARTMENT_CODE = 'ADMN' cont> WITH CHECK OPTION CONSTRAINT ADMN_VIEW_CONST; SQL> -- You cannot insert a row that does not SQL> -- conform to the view definition. SQL> -- SQL> INSERT INTO ADMN_VIEW (DEPARTMENT_CODE) VALUES ('MBMN'); %RDB-E-INTEG-FAIL, violation of constraint ADMN_VIEW_CONST- caused operation to fail Example 3: Defining a view based on multiple tables You can also define a view using more than one table. SQL> CREATE VIEW CURRENT_SALARY cont> AS SELECT cont> E.LAST_NAME, cont> E.FIRST_NAME, cont> E.EMPLOYEE_ID, cont> SH.SALARY_START, cont> SH.SALARY_AMOUNT cont> FROM cont> SALARY_HISTORY SH, EMPLOYEES E cont> WHERE cont> SH.EMPLOYEE_ID = E.EMPLOYEE_ID cont> AND cont> SH.SALARY_END IS NULL ; This example defines a view from the EMPLOYEES and SALARY_HISTORY tables. It uses the select expression to: o Choose the columns derived from each table. Because no column names are specified before the select expression, the columns inherit the names from the source tables. o Join the tables and limit the view to current salaries. Example 4: Defining a view with local column names SQL> CREATE VIEW EMP_JOB cont> ( CURRENT_ID, cont> CURRENT_NAME, cont> CURRENT_JOB, cont> SUPERVISOR ) cont> AS SELECT cont> E.EMPLOYEE_ID, cont> E.LAST_NAME, cont> J.JOB_TITLE, cont> JH.SUPERVISOR_ID cont> FROM cont> EMPLOYEES E, cont> JOB_HISTORY JH, cont> JOBS J cont> WHERE cont> E.EMPLOYEE_ID = JH.EMPLOYEE_ID cont> AND cont> JH.JOB_CODE = J.JOB_CODE cont> AND cont> JH.JOB_END IS NULL ; This view definition: o Specifies local names for the columns in the view. o Joins the EMPLOYEES and JOB_HISTORY tables. This join links rows in the EMPLOYEES table to rows in the JOB_HISTORY table. o Joins the JOB_HISTORY and JOBS tables. This join lets the view contain job titles instead of job codes. o Uses the JH.JOB_END IS NULL expression. This clause specifies that only the current JOB_HISTORY rows, where the JOB_END column is null, should be included in the view. The following query uses the view defined in the previous example: EXEC SQL DECLARE X CURSOR FOR SELECT CURRENT_ID, CURRENT_NAME, CURRENT_JOB, SUPERVISOR FROM EMP_JOB END-EXEC EXEC SQL OPEN X END-EXEC PERFORM WHILE SQLCODE NOT = 0 EXEC SQL FETCH X INTO :ID, :NAME, :JOB, :SUPER END-EXEC END PERFORM EXEC SQL CLOSE X END-EXEC Example 5: Defining a view with a calculated column This example shows a view definition that derives a column through a calculation based on a column in an base table. SQL> CREATE VIEW SS_DEDUCTION cont> ( IDENT, cont> SALARY, cont> SS_AMOUNT ) cont> AS SELECT cont> E.EMPLOYEE_ID, cont> SH.SALARY_AMOUNT, cont> SH.SALARY_AMOUNT * 0.065 cont> FROM cont> SALARY_HISTORY SH, EMPLOYEES E cont> WHERE cont> SH.EMPLOYEE_ID = E.EMPLOYEE_ID cont> AND cont> SH.SALARY_END IS NULL ; Each time the view column SS_AMOUNT is selected, it computes a new value from the SALARY_AMOUNT column of the SALARY_HISTORY table. Example 6: Defining a view dependent on another view This example creates a view, DEPENDENT_VIEW, that refers to the CURRENT_JOB view in its definition to include current job information for employees in the engineering department. SQL> CREATE VIEW DEPENDENT_VIEW cont> AS SELECT * FROM CURRENT_JOB cont> WHERE DEPARTMENT_CODE = 'ENG';