Starts a transaction and specifies its characteristics. A transaction is a group of statements whose changes can be made permanent or undone only as a unit. A transaction ends with a COMMIT or ROLLBACK statement. If you end the transaction with the COMMIT statement, all the changes made to the database by the statements are made permanent. If you end the transaction with the ROLLBACK statement, the statements do not take effect. You must end the transaction with a COMMIT or ROLLBACK statement before starting or declaring another transaction. If you try to start or declare a transaction while another one is active, SQL generates an error message. Besides the SET TRANSACTION statement, you can specify the characteristics of a transaction in one of two other ways: o If you specify the DECLARE TRANSACTION statement, the declarations in the statement take effect when SQL starts a new transaction that is not started by the SET TRANSACTION statement. SQL starts a new transaction with the first executable data manipulation or data definition statement following the DECLARE TRANSACTION, COMMIT, or ROLLBACK statement. o If you omit both the DECLARE and SET TRANSACTION statements, SQL automatically starts a transaction (using the read/write option) with the first executable data manipulation or data definition statement following a COMMIT or ROLLBACK statement. Thus, you can retrieve and update data without declaring or setting a transaction explicitly. See the Oracle Rdb SQL Reference Manual for examples of when you would want to use the DECLARE TRANSACTION statement instead of the SET TRANSACTION statement. You can specify many options with the SET TRANSACTION statement, including: o Transaction mode (READ ONLY/READ WRITE) o Lock specification clause (RESERVING options) o Horizontal partition specification (RESERVING options) o Wait mode (WAIT/NOWAIT) o Isolation level o Constraint evaluation specification clause o Multiple sets of all the preceding options for each database involved in the transaction (ON . . . AND ON) The Arguments section explains these options in more detail.
1 – Environment
You can use the SET TRANSACTION 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 – Format
(B)0[m[1;4mSET[m[1m [1;4mTRANSACTION[m[1m qqwqqqqqqqqqqqqqqqwq> [m [1m tq> tx-options qu [m [1m mq> db-txns qqqqj [m (B)0[m[1mtx-options = [m [1m [m [1mqqwqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqwq> [m [1mx tq>[m [1;4mNAME[m[1m 'quoted-string' qqqqqqqqqqqqqqqqu[m [1mx[m [1mx[m [1mtq> [1;4mEVALUATING[m[1m qwq evaluating-clause qqwqu[m [1mx[m [1mx[m [1mx [m [1mmqqqqqqq> , <qqqqqqqqqqj[m [1mx[m [1mx[m [1m x[m [1mtq>[m [1;4mRESERVING[m[1m qqwq> reserving-clause qqwqu x [m [1mx[m [1mx[m [1m [m [1mmqqqqqqqq[m [1m, <qqqqqqqqqqj[m [1mx[m [1mx[m [1mx tq>[m [1misolation-level qqqqqqqqqqqqqqqqqqqqqu[m [1mx[m [1mx[m [1mtq> transaction-mode[m [1mqqqqqqqqqqqqqqqqqqqqu[m [1mx[m [1mx[m [1mmq>[m [1mwait-option[m [1mqqqqqqqqqqqqqqqqqqqqqqqqqj[m [1mx[m [1mmqqqqqqqqqqqqqqqqwqqqqqqqwqqqqqqqqqqqqqqqqqqqj[m [1mmqq[m [1m, <qj[m (B)0[m[1mtransaction-mode =[m [1mqqwq>[m [1;4mREAD[m [1;4mONLY[m [1mqqqqwq>[m [1mtq>[m [1;4mREAD[m [1;4mWRITE[m[1m qqqu[m [1mmq> [1;4mBATCH[m[1m [1;4mUPDATE[m[1m qj[m (B)0[m[1mwait-option =[m q[1mqwq> [1;4mWAIT[m[1m qwqqqqqqqqqqqqqqqqqqqqqwqwq>[m [1mx[m [1mmq> <timeout-value>[m [1mqqj[m [1mx[m [1mmq> [1;4mNOWAIT[m[1m qqqqqqqqqqqqqqqqqqqqqqqj[m (B)0[m[1misolation-level =[m [1mqqq> [1;4mISOLATION[m [1;4mLEVEL[m[1m qqwq>[m [1;4mREAD[m [1;4mCOMMITTED[m [1mqqqqwqq>[m [1mtq>[m [1;4mREPEATABLE[m [1;4mREAD[m [1mqqqu[m [1mmq>[m [1;4mSERIALIZABLE[m[1m qqqqqqj[m (B)0[m[1mevaluating-clause = [m [1m [m [1mqwqqqqqqqqqqqqqwq> <constraint-name> q> [1;4mAT[m[1m qwq> [1;4mVERB[m[1m [1;4mTIME[m[1m qqqwqq> [m [1m mq> <alias.> qj mq> [1;4mCOMMIT[m[1m [1;4mTIME[m[1m qj [m [1m [m (B)0[m[1mreserving-clause = [m [1m [m [1mqwqwq> <view-name> qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqwqk [m [1m x mq> <table-name> qwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqj x x [m [1m x mq> [1;4mPARTITION[m[1m qq> ( qwq> <part-num> qwq> ) qj x x [m [1m x mqqqqqq , <qqqqqj x x [m [1m mqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqq , <qqqqqqqqqqqqqqqqqqqqqqqqqqqqj x [m [1m lqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1m mq> [1;4mFOR[m[1m qwqqqqqqqqqqqqqqwqqwq> [1;4mREAD[m[1m qqqqqqqqqqqqwqqqqqqqqqqqqqqqqqqqqq> [m [1m tq> [1;4mEXCLUSIVE[m[1m qu tq> [1;4mWRITE[m[1m qqqqqqqqqqqu [m [1m tq> [1;4mPROTECTED[m[1m qu mq> [1;4mDATA[m[1m [1;4mDEFINITION[m[1m qj [m [1m mq> [1;4mSHARED[m[1m qqqqj [m [1m [m (B)0[m[1mdb-txns = [m [1m [m [1mqqwqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqwqq>[m [1m mwq> [1;4mON[m[1m qwq> <alias> qwq> [1;4mUSING[m[1m qq> ( wq> tx-options qqwq> ) qwj [m [1m x mqqqq , <qqqqj mq> [1;4mDEFAULTS[m[1m qqqqj x [m [1m mqqqqqqqqqqqqqqqqqqqqqqqqqq [1;4mAND[m[1m <qqqqqqqqqqqqqqqqqqqqqqqqqqqqj [m [1m [m
3 – Arguments
3.1 – alias
Specifies the alias for a constraint.
3.2 – BATCH_UPDATE
Specifies the batch-update mode to reduce overhead in large- load operations. To speed update operations, Oracle Rdb does not write to snapshot or recovery-unit journal files in a batch- update transaction. For more information about batch-update transactions, see the Oracle Rdb Guide to SQL Programming and the Oracle Rdb SQL Reference Manual. CAUTION Before you begin a batch-update transaction in your programs, you should create a backup copy of the database using the RMU Backup command. If an error occurs in your program that would normally result in a rollback of the transaction, Oracle Rdb marks the database as corrupt. To recover from a corrupt database, you must create the database again from the backup copy of the database. After correcting the error condition, you can restart the program from the beginning. You should back up the database after completing a batch-update transaction as well.
3.3 – constraint-name
Specifies the name of a constraint.
3.4 – db-txns
Specifies different transaction options. When you attach to more than one database and want to specify different transaction options for each database, use this clause.
3.5 – evaluating-clause
Specifies the point at which the named constraint or constraints are evaluated. If you specify VERB TIME, they are evaluated when the data manipulation statement is issued. If you specify COMMIT TIME, the constraint evaluation is based on the setting of the SET ALL CONSTRAINTS statement. For read-only transactions, this clause is allowed but is ignored.
3.6 – FOR share modes
Syntax options: FOR EXCLUSIVE FOR PROTECTED FOR SHARED Specifies the SQL share modes. The keyword you choose determines which operations you allow others to perform on the tables you are reserving. While you can specify an EXCLUSIVE or PROTECTED share mode when declaring a read-only transaction, SQL ignores these entries and specifies SHARED mode. The default is SHARED. For more information, see the Oracle Rdb SQL Reference Manual.
3.7 – ISOLATION_LEVEL
Syntax options: ISOLATION LEVEL READ COMMITTED ISOLATION LEVEL REPEATABLE READ ISOLATION LEVEL SERIALIZABLE Defines the degree to which database operations in an SQL transaction are affected by database operations in concurrently executing transactions. It determines the extent to which the database protects the consistency of your data. Oracle Rdb supports isolation levels READ COMMITTED, REPEATABLE READ, and SERIALIZABLE. When you use SQL with Oracle Rdb databases, by default, SQL executes a transaction at isolation level SERIALIZABLE. The higher the isolation level, the more isolated a transaction is from other currently executing transactions. Isolation levels determine the type of phenomena that are allowed to occur during the execution of concurrent transactions. Two phenomena define SQL isolation levels for a transaction: o Nonrepeatable read Allows the return of different results within a single transaction when an SQL operation reads the same row in a table twice. Nonrepeatable reads can occur when another transaction modifies and commits a change to the row between transaction reads. o Phantom Allows the return of different results within a single transaction when an SQL operation retrieves a range of data values (or similar data existence check) twice. Phantoms can occur if another transaction inserted a new record and committed the insertion between executions of the range retrieval. Each isolation level differs in the phenomena it allows. The following table shows the phenomena permitted for the isolation levels that you can explicitly specify with the SET TRANSACTION statement. Table 1-8 Phenomena Permitted at Each Isolation Level Nonrepeatable Isolation Reads Phantoms Level Allowed? Allowed? READ Yes Yes COMMITTED REPEATABLE No Yes READ SERIALIZABLE No No For read-only transactions, which always execute at isolation level SERIALIZABLE if snapshots are enabled, the database system guarantees that you will not see changes made by another user before you issue a COMMIT statement. See the Oracle Rdb Guide to SQL Programming for further information about specifying isolation levels in transactions.
3.8 – NAME transaction-name
Supplies a title for the transaction. This information is displayed by the SET FLAGS TRANSACTION keyword.
3.9 – ON
Syntax options: ON alias | AND ON alias Specifies the alias for a database for which you want to specify transaction options. An alias is a name for a particular attach to a database. Use the ON clause when you attach to more than one database and want to specify different transaction options for each database. (If you omit the ON clause, the single set of transaction options in the SET TRANSACTION statement applies to all attached databases.) You can include multiple sets of transaction options, one for each database, in multiple ON clauses separated with the AND keyword.
3.10 – PARTITION (part-num)
PARTITION When used with the RESERVING clause specifies a list of numeric partition numbers so that only a subset of the tables partitions are reserved. For example, an application could submit several processing jobs that each reserved a separate partition of the table for EXCLUSIVE access. The default, if this clause is omitted, is to reserve all partitions. An error is reported if the application references a partition if the table that was not reserved.
3.11 – part-num
The numeric identifier for the partition. Partition are numbered from 1. The CREATE INDEX statement allocates these values and records them in the RDB$STORAGE_MAP_AREAS table in the column RDB$ORDINAL_POSITION.
3.12 – reserved_lock_types
Syntax options: READ WRITE DATA DEFINITION Specifies the lock type. These keywords declare what you intend to do with the tables you are reserving. Use READ when you only want to read data from the tables. This is the default for read-only transactions. Use WRITE when you want to insert, update, or delete data in the tables. This is the default for read/write transactions. You cannot specify WRITE for read-only transactions. Use DATA DEFINITION when you want to create or alter metadata at the same time as other users on the same table. This clause can be used only in read/write transactions.
3.13 – READ_ONLY
Retrieves a snapshot of the database at the moment the read-only transaction starts. Other users can update rows in the table you are using, but your transaction retrieves the rows as they existed at the time the transaction started. You cannot update, insert, or delete rows, or execute data definition statements in a read-only transaction with the exception of declaring a local temporary table or modifying data in a created or declared temporary table. Read-only transactions are implicitly isolation level serializable. Because a read-only transaction uses the snapshot (.snp) version of the database, any changes that other users make and commit during the transaction are invisible to you. Using a read-only transaction lets you read data without incurring the overhead of row locking. (You do incur overhead for keeping a snapshot of the tables you specify in the RESERVING clause, but this overhead is less than that of a comparable read/write transaction.) Because of the limited nature of read-only transactions, they are subject to several restrictions.
3.14 – READ_WRITE
Signals that you want to use the lock mechanisms of SQL for consistency in data retrieval and update. Read/write is the default transaction. Use the read/write transaction mode when you need to: o Insert, update, or delete data o Retrieve data that is guaranteed to be correct at the moment of retrieval o Use SQL data definition statements When you are reading a row in a read/write transaction, no other user can update that row. Under some circumstances, SQL may lock rows that you are not explicitly reading. o If your query is scanning a table without using an index, SQL locks all the rows in the record stream to maintain isolation level serializable. o If your query uses indexes, SQL may lock part of an index, which has the effect of locking several rows.
3.15 – RESERVING
Syntax options: RESERVING table-name RESERVING view-name Lists the tables to be locked during the transaction. Include all the persistent base tables your transaction will access. You cannot reserve created or declared temporary tables. If you use the RESERVING clause to specify tables, you can access only the tables you have reserved. However, specifying a view in a RESERVING clause is the same as specifying the base tables on which the view is based.
3.16 – timeout-value
Specifies the number of seconds for a given transaction to wait for other transactions to complete. This interval is only valid for the transaction specified in the SET TRANSACTION statement. Subsequent transactions return to the database default timeout interval. A timeout value of 0 specifies NOWAIT. When starting a transaction, there are three different values that are used to determine the lock timeout interval for that transaction. Those values are: 1. The value specified in the SET TRANSACTION statement 2. The value stored in the database as specified in CREATE or ALTER DATABASE 3. The value of the logical name RDM$BIND_LOCK_TIMEOUT_INTERVAL The timeout interval for a transaction is the smaller of the value specified in the SET TRANSACTION statement and the value specified in CREATE DATABASE. However, if the logical name RDM$BIND_LOCK_TIMEOUT_INTERVAL is defined, the value of this logical name overrides the value specified in CREATE DATABASE.
3.17 – USING
Syntax options: USING (tx-options) USING DEFAULTS Specifies the transaction options you want for the database referred to by the alias in the preceding ON clause. You can explicitly specify the transaction, wait mode, and isolation level option, or you can use the DEFAULTS keyword. Using DEFAULTS is equivalent to specifying READ WRITE WAIT. For more information on DEFAULTS, see the Oracle Rdb SQL Reference Manual.
3.18 – WAIT
Syntax options: WAIT |NOWAIT Determines what your transaction does when it encounters a locked row. The default is WAIT. o If you specify WAIT, the transaction waits for other transactions to complete and then proceeds. If you prefer, you can specify that the transaction proceeds after a certain time interval instead of waiting for other transactions to complete. You can specify the timeout interval value after the WAIT keyword. The timeout interval value is expressed in seconds. o If you specify NOWAIT, your transaction returns an error message when it encounters a locked row.
4 – Examples
Example 1: Starting a read-only transaction SQL> SET TRANSACTION READ ONLY; This statement lets you read data from the database but not insert or update data. When you retrieve data, you see the database records as they existed at the time SQL started the transaction. You do not see any updates to the database made after that time. Example 2: Reserving specific tables with the SET TRANSACTION statement The following statement lets you specify the intended action for each table in the transaction: SQL> ATTACH 'FILENAME mf_personnel'; SQL> SET TRANSACTION READ WRITE RESERVING cont> EMPLOYEES FOR PROTECTED WRITE, cont> JOBS, SALARY_HISTORY FOR SHARED READ; Assume that this transaction updates the EMPLOYEES table based on values found in two other tables: JOBS and SALARY_HISTORY. o The transaction must update the EMPLOYEES table, so EMPLOYEES is readied for protected write access. o The program will only read values from the JOBS and SALARY_ HISTORY tables, so there is no need for write access or protected write access. However, you do intend to update records in the transaction, so a read-only transaction is not appropriate. Example 3: Specifying multiple databases in a SET TRANSACTION statement You can access multiple databases from within the same transaction. This example explains how you can benefit from this feature. Read-only transactions use a snapshot version of the data, and therefore you might encounter older values in the data your application retrieves. because another transaction using a read/write transaction might be updating a table. The snapshot file represents a before-image of the database rows that the other program is updating. If you require The very latest data, you should specify read/write access for both databases, and permit other users to read one of the databases by including the shared read mode. In this way, you maintain data consistency during updates, while permitting concurrent data retrieval from the database that your program reads. However, any read/write transaction you set offers reduced concurrent access when compared to read-only access. For that reason, use read/write transactions only when necessary. Before you can use the multiple database feature of the SET TRANSACTION statement, you must issue a DECLARE ALIAS statement that specifies each database you intend to access. The DECLARE ALIAS statement must include an alias. For example, the following DECLARE ALIAS statements identify two databases required by an update application: EXEC SQL DECLARE DB1 ALIAS FOR FILENAME PERSONNEL; END EXEC EXEC SQL DECLARE DB2 ALIAS FOR FILENAME benefits; END EXEC Because the program needs to only read the EMPLOYEES table of the PERSONNEL database but needs to change values in two tables (TUITION and STATUS) in the BENEFITS database, the update program might contain the following SET TRANSACTION statement: EXEC SQL SET TRANSACTION ON DB1 USING ( READ ONLY RESERVING DB1.EMPLOYEES FOR SHARED READ ) AND ON DB2 USING ( READ WRITE RESERVING DB2.TUITION FOR SHARED WRITE DB2.STATUS FOR SHARED WRITE ) END EXEC Example 4: Specifying a multischema database in a SET TRANSACTION statement If one of the databases you access is a multischema database, you must specify it using a delimited identifier. The following example shows how to access the single-schema personnel database and the multischema corporate_data database. The table EMPLOYEES is located within the schema PERSONNEL in the catalog ADMINISTRATION within the CORPORATE_DATA database. SQL> ATTACH 'ALIAS CORP FILENAME corporate_data'; SQL> ATTACH 'ALIAS PERS FILENAME personnel'; SQL> SET QUOTING RULES 'SQL92'; SQL> SET CATALOG '"CORP.ADMINISTRATION"'; SQL> SET SCHEMA '"CORP.ADMINISTRATION".PERSONNEL'; SQL> -- SQL> SET TRANSACTION ON CORP USING (READ ONLY cont> RESERVING "CORP.EMPLOYEES" FOR SHARED READ) cont> AND ON PERS USING (READ WRITE RESERVING cont> PERS.EMPLOYEES FOR SHARED WRITE); Example 5: Specifying evaluation at verb time in a SET TRANSACTION statement The following example shows an insert into the DEGREES table of a newly acquired degree for EMPLOYEE_ID 00164. The new degree, MME, is evaluated and, because it is not one of the acceptable degree codes, an error message is returned immediately. SQL> ATTACH 'FILENAME personnel'; SQL> SET TRANSACTION READ WRITE cont> EVALUATING DEGREES_FOREIGN1 AT VERB TIME, cont> DEGREES_FOREIGN2 AT VERB TIME, cont> DEG_DEGREE_VALUES AT VERB TIME cont> RESERVING DEGREES FOR PROTECTED WRITE, cont> COLLEGES, EMPLOYEES FOR SHARED READ; SQL> SHOW TRANSACTION Transaction information: Statement constraint evaluation is off On the default alias Transaction characteristics: Read Write Evaluating constraint DEGREES_FOREIGN1 at verb time Evaluating constraint DEGREES_FOREIGN2 at verb time Evaluating constraint DEG_DEGREE_VALUES at verb time Reserving table DEGREES for protected write Reserving table COLLEGES for shared read Reserving table EMPLOYEES for shared read Transaction information returned by base system: a read-write transaction is in progress - updates have not been performed - transaction sequence number (TSN) is 153 - snapshot space for TSNs less than 153 can be reclaimed - session ID number is 21 SQL> INSERT INTO DEGREES cont> (EMPLOYEE_ID, COLLEGE_CODE, YEAR_GIVEN, cont> DEGREE, DEGREE_FIELD) cont> VALUES cont> ('00164', 'PRDU', 1992, cont> 'MME', 'Mech Enging'); %RDB-E-INTEG_FAIL, violation of constraint DEG_DEGREE_VALUES caused operation to fail -RDB-F-ON_DB, on database DISK1:[JONES.PERSONNEL]PERSONNEL.RDB;1 SQL> ROLLBACK; Example 6: Explicitly setting isolation levels in a transaction This statement lets you read data from and write data to the database. It also sets the transaction to run at isolation level READ COMMITTED, not at the higher default isolation level SERIALIZABLE. SQL> SET TRANSACTION READ WRITE ISOLATION LEVEL REPEATABLE READ; Example 7: Creating index concurrently The following example shows how to reserve the table for shared data definition and how to create an index: SQL> SET TRANSACTION READ WRITE cont> RESERVING EMPLOYEES FOR SHARED DATA DEFINITION; SQL> -- SQL> CREATE INDEX EMP_LAST_NAME1 ON EMPLOYEES (LAST_NAME); SQL> -- SQL> -- Commit the transaction immediately. SQL> -- SQL> COMMIT; Example 8: Reserving a Partition SQL> -- This example locks only the second partition of SQL> -- the EMPLOYEES table in exclusive write mode. SQL> -- The advantage of this is that the process can insert, SQL> -- update, or delete from this partition without writing SQL> -- to the snapshot (.snp) file, and in general, uses fewer SQL> -- resources for operations on the partition. SQL> SET TRANSACTION READ WRITE cont> RESERVING EMPLOYEES PARTITION (2) FOR EXCLUSIVE WRITE; Example 9: Interaction between RESERVING clause and column DEFAULT values This example examines the interaction between the RESERVING clause and DEFAULT values that reference tables (either directly and indirectly). The RESERVING clause of SET TRANSACTION limits the transaction to just those tables listed for the transaction. Tables directly referenced by constraints, triggers, COMPUTED BY columns, AUTOMATIC columns and DEFAULT values are implicitly reserved for SHARED READ. However, if these definitions reference the table indirectly via a stored function then that table is not considered for automatic reservation. This example uses DEFAULT value to contrast three different mechanisms and their interactions with the RESERVING clause. The same technique could be applied to other definitions such as triggers and constraints. The DEFAULT value is derived from a secondary table (DEFAULTS) that holds one value for each valid user of the database. The DEFAULT is retrieved based on the value of CURRENT_USER. In the three tables below the value is either directly fetched (SAMPLE_ TABLE2), or via a stored function (SAMPLE_TABLE1, and SAMPLE_ TABLE3). The SQL function GET_DEFAULT3 includes a LOCK TABLE statement to ensure that the table is correctly reserved. Oracle recommends this approach since it relieves the programmer from knowing which tables might be required when coding a RESERVING clause for a transaction. SQL> set dialect 'sql99'; SQL> SQL> create table DEFAULTS cont> (user_id rdb$object_name primary key, cont> valid_number integer); SQL> insert into DEFAULTS values ('SMITH', 100); 1 row inserted SQL> SQL> create module UTL1 cont> function GET_DEFAULT1 () cont> returns integer cont> not deterministic; cont> return (select valid_number from DEFAULTS cont> where user_id = CURRENT_USER); cont> end module; SQL> SQL> create table SAMPLE_TABLE1 cont> (id integer identity, cont> quantity integer cont> default GET_DEFAULT1 () cont> ); SQL> SQL> create table SAMPLE_TABLE2 cont> (id integer identity, cont> quantity integer cont> default (select valid_number from DEFAULTS cont> where user_id = CURRENT_USER) cont> ); SQL> SQL> create module UTL3 cont> function GET_DEFAULT3 () cont> returns integer cont> not deterministic; cont> begin cont> lock table DEFAULTS for shared read mode; cont> return (select valid_number from DEFAULTS cont> where user_id = CURRENT_USER); cont> end; cont> end module; SQL> SQL> create table SAMPLE_TABLE3 cont> (id integer identity, cont> quantity integer cont> default GET_DEFAULT3 () cont> ); SQL> SQL> commit; The following transactions succeed or fail as explained in the example. SQL> /* ***> Fails because the module references a table that is not reserved ***> */ SQL> set transaction read write cont> reserving SAMPLE_TABLE1 for shared write; SQL> insert into SAMPLE_TABLE1 default values; %RDB-E-UNRES_REL, relation DEFAULTS in specified request is not a relation reserved in specified transaction SQL> rollback; SQL> SQL> /* ***> Succeeds because direct access to the table from the DEFAULT ***> is implicitly added to the reserving list as SHARED READ ***> */ SQL> set transaction read write cont> reserving SAMPLE_TABLE2 for shared write; SQL> insert into SAMPLE_TABLE2 default values; 1 row inserted SQL> rollback; SQL> SQL> /* ***> Succeeds because the routine adds the table to the reserved ***> table list using LOCK TABLE. ***> */ SQL> set transaction read write cont> reserving SAMPLE_TABLE3 for shared write; SQL> insert into SAMPLE_TABLE3 default values; 1 row inserted SQL> rollback; SQL>