Skip Headers
Oracle® Streams Concepts and Administration
10g Release 2 (10.2)

Part Number B14229-02
Go to Documentation Home
Home
Go to Book List
Book List
Go to Table of Contents
Contents
Go to Index
Index
Go to Master Index
Master Index
Go to Feedback page
Contact Us

Go to previous page
Previous
Go to next page
Next
View PDF

12 Managing Staging and Propagation

This chapter provides instructions for managing ANYDATA queues, propagations, and messaging environments.

This chapter contains these topics:

Each task described in this chapter should be completed by a Streams administrator that has been granted the appropriate privileges, unless specified otherwise.

See Also:

Managing ANYDATA Queues

An ANYDATA queue stages messages whose payloads are of ANYDATA type. Therefore, an ANYDATA queue can stage a message with a payload of nearly any type, if the payload is wrapped in an ANYDATA wrapper. Each Streams capture process, apply process, and messaging client is associated with one ANYDATA queue, and each Streams propagation is associated with one ANYDATA source queue and one ANYDATA destination queue.

This section contains instructions for completing the following tasks related to ANYDATA queues:

Creating an ANYDATA Queue

The easiest way to create an ANYDATA queue is to use the SET_UP_QUEUE procedure in the DBMS_STREAMS_ADM package. This procedure enables you to specify the following settings for the ANYDATA queue it creates:

  • The queue table for the queue

  • A storage clause for the queue table

  • The queue name

  • A queue user that will be configured as a secure queue user of the queue and granted ENQUEUE and DEQUEUE privileges on the queue

  • A comment for the queue

If the specified queue table does not exist, then it is created. If the specified queue table exists, then the existing queue table is used for the new queue. If you do not specify any queue table when you create the queue, then, by default, streams_queue_table is specified.

You can use a single procedure, the SET_UP_QUEUE procedure in the DBMS_STREAMS_ADM package, to create an ANYDATA queue and the queue table used by the queue. For SET_UP_QUEUE to create a new queue table, the specified queue table must not exist.

For example, run the following procedure to create an ANYDATA queue with the SET_UP_QUEUE procedure:

BEGIN
  DBMS_STREAMS_ADM.SET_UP_QUEUE(
    queue_table => 'strmadmin.streams_queue_table',
    queue_name  => 'strmadmin.streams_queue',
    queue_user  => 'hr');
END;
/

Running this procedure performs the following actions:

  • Creates a queue table named streams_queue_table. The queue table is created only if it does not already exist. Queues based on the queue table stage messages of ANYDATA type. Queue table names can be a maximum of 24 bytes.

  • Creates a queue named streams_queue. The queue is created only if it does not already exist. Queue names can be a maximum of 24 bytes.

  • Specifies that the streams_queue queue is based on the strmadmin.streams_queue_table queue table.

  • Configures the hr user as a secure queue user of the queue, and grants this user ENQUEUE and DEQUEUE privileges on the queue.

  • Starts the queue.

Default settings are used for the parameters that are not explicitly set in the SET_UP_QUEUE procedure.

When the SET_UP_QUEUE procedure creates a queue table, the following DBMS_AQADM.CREATE_QUEUE_TABLE parameter settings are specified:

  • If the database is Oracle Database 10g Release 2 or later, the sort_list setting is commit_time. If the database is a release prior to Oracle Database 10g Release 2, the sort_list setting is enq_time.

  • The multiple_consumers setting is true.

  • The message_grouping setting is transactional.

  • The secure setting is true.

The other parameters in the CREATE_QUEUE_TABLE procedure are set to their default values.

You can use the CREATE_QUEUE_TABLE procedure in the DBMS_AQADM package to create a queue table of ANYDATA type with different properties than the default properties specified by the SET_UP_QUEUE procedure in the DBMS_STREAMS_ADM package. After you create the queue table with the CREATE_QUEUE_TABLE procedure, you can create a queue that uses the queue table. To do so, specify the queue table in the queue_table parameter of the SET_UP_QUEUE procedure.

Similarly, you can use the CREATE_QUEUE procedure in the DBMS_AQADM package to create a queue instead of SET_UP_QUEUE. Use CREATE_QUEUE if you require custom settings for the queue. For example, use CREATE_QUEUE to specify a custom retry delay or retention time. If you use CREATE_QUEUE, then you must start the queue manually.

Note:

A message cannot be enqueued into a queue unless a subscriber who can dequeue the message is configured.

Enabling a User to Perform Operations on a Secure Queue

For a user to perform queue operations, such as enqueue and dequeue, on a secure queue, the user must be configured as a secure queue user of the queue. If you use the SET_UP_QUEUE procedure in the DBMS_STREAMS_ADM package to create the secure queue, then the queue owner and the user specified by the queue_user parameter are configured as secure users of the queue automatically. If you want to enable other users to perform operations on the queue, then you can configure these users in one of the following ways:

  • Run SET_UP_QUEUE and specify a queue_user. Queue creation is skipped if the queue already exists, but a new queue user is configured if one is specified.

  • Associate the user with an AQ agent manually.

The following example illustrates associating a user with an AQ agent manually. Suppose you want to enable the oe user to perform queue operations on the streams_queue created in "Creating an ANYDATA Queue". The following steps configure the oe user as a secure queue user of streams_queue:

  1. Connect as an administrative user who can create AQ agents and alter users.

  2. Create an agent:

    EXEC DBMS_AQADM.CREATE_AQ_AGENT(agent_name => 'streams_queue_agent');
    
    
  3. If the user must be able to dequeue messages from queue, then make the agent a subscriber of the secure queue:

    DECLARE
      subscriber SYS.AQ$_AGENT;
    BEGIN
      subscriber :=  SYS.AQ$_AGENT('streams_queue_agent', NULL, NULL);  
      DBMS_AQADM.ADD_SUBSCRIBER(
        queue_name          =>  'strmadmin.streams_queue',
        subscriber          =>  subscriber,
        rule                =>  NULL,
        transformation      =>  NULL);
    END;
    /
    
    
  4. Associate the user with the agent:

    BEGIN
      DBMS_AQADM.ENABLE_DB_ACCESS(
        agent_name  => 'streams_queue_agent',
        db_username => 'oe');
    END;
    /
    
    
  5. Grant the user EXECUTE privilege on the DBMS_STREAMS_MESSAGING package or the DBMS_AQ package, if the user is not already granted these privileges:

    GRANT EXECUTE ON DBMS_STREAMS_MESSAGING TO oe;
    
    GRANT EXECUTE ON DBMS_AQ TO oe;
    
    

When these steps are complete, the oe user is a secure user of the streams_queue queue and can perform operations on the queue. You still must grant the user specific privileges to perform queue operations, such as enqueue and dequeue privileges.

See Also:

Disabling a User from Performing Operations on a Secure Queue

You might want to disable a user from performing queue operations on a secure queue for the following reasons:

  • You dropped a capture process, but you did not drop the queue that was used by the capture process, and you do not want the user who was the capture user to be able to perform operations on the remaining secure queue.

  • You dropped an apply process, but you did not drop the queue that was used by the apply process, and you do not want the user who was the apply user to be able to perform operations on the remaining secure queue.

  • You used the ALTER_APPLY procedure in the DBMS_APPLY_ADM package to change the apply_user for an apply process, and you do not want the old apply_user to be able to perform operations on the apply process queue.

  • You enabled a user to perform operations on a secure queue by completing the steps described in Enabling a User to Perform Operations on a Secure Queue, but you no longer want this user to be able to perform operations on the secure queue.

To disable a secure queue user, you can revoke ENQUEUE and DEQUEUE privilege on the queue from the user, or you can run the DISABLE_DB_ACCESS procedure in the DBMS_AQADM package. For example, suppose you want to disable the oe user from performing queue operations on the streams_queue created in "Creating an ANYDATA Queue".

Attention:

If an AQ agent is used for multiple secure queues, then running DISABLE_DB_ACCESS for the agent prevents the user associated with the agent from performing operations on all of these queues.
  1. Run the following procedure to disable the oe user from performing queue operations on the secure queue streams_queue:

    BEGIN
      DBMS_AQADM.DISABLE_DB_ACCESS(
        agent_name  => 'streams_queue_agent',
        db_username => 'oe');
    END;
    /
    
    
  2. If the agent is no longer needed, you can drop the agent:

    BEGIN
      DBMS_AQADM.DROP_AQ_AGENT(
        agent_name  => 'streams_queue_agent');
    END;
    /
    
    
  3. Revoke privileges on the queue from the user, if the user no longer needs these privileges.

    BEGIN
      DBMS_AQADM.REVOKE_QUEUE_PRIVILEGE (
       privilege   => 'ALL',
       queue_name  => 'strmadmin.streams_queue',
       grantee     => 'oe');
    END;
    /
    
    

    See Also:

Removing an ANYDATA Queue

You use the REMOVE_QUEUE procedure in the DBMS_STREAMS_ADM package to remove an existing ANYDATA queue. When you run the REMOVE_QUEUE procedure, it waits until any existing messages in the queue are consumed. Next, it stops the queue, which means that no further enqueues into the queue or dequeues from the queue are allowed. When the queue is stopped, it drops the queue.

You can also drop the queue table for the queue if it is empty and is not used by another queue. To do so, specify true, the default, for the drop_unused_queue_table parameter.

In addition, you can drop any Streams clients that use the queue by setting the cascade parameter to true. By default, the cascade parameter is set to false.

For example, to remove an ANYDATA queue named streams_queue in the strmadmin schema and drop its empty queue table, run the following procedure:

BEGIN
  DBMS_STREAMS_ADM.REMOVE_QUEUE(
    queue_name              => 'strmadmin.streams_queue',
    cascade                 => false,
    drop_unused_queue_table => true);
END;
/

In this case, because the cascade parameter is set to false, this procedure drops the streams_queue only if no Streams clients use the queue. If the cascade parameter is set to false and any Streams client uses the queue, then an error is raised.

Managing Streams Propagations and Propagation Jobs

A propagation propagates messages from a Streams source queue to a Streams destination queue. This section provides instructions for completing the following tasks:

In addition, you can use the features of Oracle Advanced Queuing (AQ) to manage Streams propagations.

See Also:

Creating a Propagation Between Two ANYDATA Queues

You can use any of the following procedures to create a propagation between two ANYDATA queues:

Each of these procedures in the DBMS_STREAMS_ADM package creates a propagation with the specified name if it does not already exist, creates either a positive rule set or negative rule set for the propagation if the propagation does not have such a rule set, and can add table rules, schema rules, or global rules to the rule set. The CREATE_PROPAGATION procedure creates a propagation, but does not create a rule set or rules for the propagation. However, the CREATE_PROPAGATION procedure enables you to specify an existing rule set to associate with the propagation, either as a positive or a negative rule set. All propagations are started automatically upon creation.

The following tasks must be completed before you create a propagation:

Example of Creating a Propagation Using DBMS_STREAMS_ADM

The following example runs the ADD_TABLE_PROPAGATION_RULES procedure in the DBMS_STREAMS_ADM package to create a propagation:

BEGIN
  DBMS_STREAMS_ADM.ADD_TABLE_PROPAGATION_RULES(
    table_name              => 'hr.departments',
    streams_name            => 'strm01_propagation',
    source_queue_name       => 'strmadmin.strm_a_queue',
    destination_queue_name  => 'strmadmin.strm_b_queue@dbs2.net',
    include_dml             => true,
    include_ddl             => true,
    include_tagged_lcr      => false,
    source_database         => 'dbs1.net',
    inclusion_rule          => true,
    queue_to_queue          => true);
END;
/

Running this procedure performs the following actions:

  • Creates a propagation named strm01_propagation. The propagation is created only if it does not already exist.

  • Specifies that the propagation propagates LCRs from strm_a_queue in the current database to strm_b_queue in the dbs2.net database.

  • Specifies that the propagation uses the dbs2.net database link to propagate the LCRs, because the destination_queue_name parameter contains @dbs2.net.

  • Creates a positive rule set and associates it with the propagation because the inclusion_rule parameter is set to true. The rule set uses the evaluation context SYS.STREAMS$_EVALUATION_CONTEXT. The rule set name is system generated.

  • Creates two rules. One rule evaluates to TRUE for row LCRs that contain the results of DML changes to the hr.departments table. The other rule evaluates to TRUE for DDL LCRs that contain DDL changes to the hr.departments table. The rule names are system generated.

  • Adds the two rules to the positive rule set associated with the propagation. The rules are added to the positive rule set because the inclusion_rule parameter is set to true.

  • Specifies that the propagation propagates an LCR only if it has a NULL tag, because the include_tagged_lcr parameter is set to false. This behavior is accomplished through the system-created rules for the propagation.

  • Specifies that the source database for the LCRs being propagated is dbs1.net, which might or might not be the current database. This propagation does not propagate LCRs in the source queue that have a different source database.

  • Creates a propagation job for the queue-to-queue propagation.

Note:

To use queue-to-queue propagation, the compatibility level must be 10.2.0 or higher for each database that contains a queue involved in the propagation.

Example of Creating a Propagation Using DBMS_PROPAGATION_ADM

The following example runs the CREATE_PROPAGATION procedure in the DBMS_PROPAGATION_ADM package to create a propagation:

BEGIN
  DBMS_PROPAGATION_ADM.CREATE_PROPAGATION(
    propagation_name   => 'strm02_propagation',
    source_queue       => 'strmadmin.strm03_queue',
    destination_queue  => 'strmadmin.strm04_queue',
    destination_dblink => 'dbs2.net',
    rule_set_name      => 'strmadmin.strm01_rule_set',
    queue_to_queue     => true);
END;
/

Running this procedure performs the following actions:

  • Creates a propagation named strm02_propagation. A propagation with the same name must not exist.

  • Specifies that the propagation propagates messages from strm03_queue in the current database to strm04_queue in the dbs2.net database. Depending on the rules in the rule sets for the propagation, the propagated messages can be captured messages or user-enqueued messages, or both.

  • Specifies that the propagation uses the dbs2.net database link to propagate the messages.

  • Associates the propagation with an existing rule set named strm01_rule_set. This rule set is the positive rule set for the propagation.

  • Creates a propagation job for the queue-to-queue propagation.

Note:

To use queue-to-queue propagation, the compatibility level must be 10.2.0 or higher for each database that contains a queue involved in the propagation.

Starting a Propagation

You run the START_PROPAGATION procedure in the DBMS_PROPAGATION_ADM package to start an existing propagation. For example, the following procedure starts a propagation named strm01_propagation:

BEGIN
  DBMS_PROPAGATION_ADM.START_PROPAGATION(
    propagation_name => 'strm01_propagation');
END;
/

Stopping a Propagation

You run the STOP_PROPAGATION procedure in the DBMS_PROPAGATION_ADM package to stop an existing propagation. For example, the following procedure stops a propagation named strm01_propagation:

BEGIN
  DBMS_PROPAGATION_ADM.STOP_PROPAGATION(
    propagation_name => 'strm01_propagation',
    force            => false);
END;
/

To clear the statistics for the propagation when it is stopped, set the force parameter to true. If there is a problem with a propagation, then stopping the propagation with the force parameter set to true and restarting the propagation might correct the problem. If the force parameter is set to false, then the statistics for the propagation are not cleared.

Altering the Schedule of a Propagation Job

To alter the schedule of an existing propagation job, use the ALTER_PROPAGATION_SCHEDULE procedure in the DBMS_AQADM package. The following sections contain examples that alter the schedule of a propagation job for a queue-to-queue propagation and for a queue-to-dblink propagation. These examples set the propagation job to propagate messages every 15 minutes (900 seconds), with each propagation lasting 300 seconds, and a 25-second wait before new messages in a completely propagated queue are propagated.

See Also:

Altering the Schedule of a Propagation Job for a Queue-to-Queue Propagation

To alter the schedule of a propagation job for a queue-to-queue propagation that propagates messages from the strmadmin.strm_a_queue source queue to the strmadmin.strm_b_queue destination queue using the dbs2.net database link, run the following procedure:

BEGIN
  DBMS_AQADM.ALTER_PROPAGATION_SCHEDULE(
   queue_name        => 'strmadmin.strm_a_queue',
   destination       => 'dbs2.net',
   duration          => 300,
   next_time         => 'SYSDATE + 900/86400',
   latency           => 25,
   destination_queue => 'strmadmin.strm_b_queue'); 
END;
/

Because each queue-to-queue propagation has its own propagation job, this procedure alters only the schedule of the propagation that propagates messages between the two queues specified. The destination_queue parameter must specify the name of the destination queue to alter the propagation schedule of a queue-to-queue propagation.

Altering the Schedule of a Propagation Job for a Queue-to-Dblink Propagation

To alter the schedule of a propagation job for a queue-to-dblink propagation that propagates messages from the strmadmin.streams_queue source queue using the dbs3.net database link, run the following procedure:

BEGIN
  DBMS_AQADM.ALTER_PROPAGATION_SCHEDULE(
   queue_name  => 'strmadmin.streams_queue',
   destination => 'dbs3.net',
   duration    => 300,
   next_time   => 'SYSDATE + 900/86400',
   latency     => 25); 
END;
/

Because the propagation is a queue-to-dblink propagation, the destination_queue parameter is not specified. Completing this task affects all queue-to-dblink propagations that propagate messages from the source queue to all destination queues that use the dbs3.net database link.

Specifying the Rule Set for a Propagation

You can specify one positive rule set and one negative rule set for a propagation. The propagation propagates a message if it evaluates to TRUE for at least one rule in the positive rule set and discards a change if it evaluates to TRUE for at least one rule in the negative rule set. The negative rule set is evaluated before the positive rule set.

Specifying a Positive Rule Set for a Propagation

You specify an existing rule set as the positive rule set for an existing propagation using the rule_set_name parameter in the ALTER_PROPAGATION procedure. This procedure is in the DBMS_PROPAGATION_ADM package.

For example, the following procedure sets the positive rule set for a propagation named strm01_propagation to strm02_rule_set.

BEGIN
  DBMS_PROPAGATION_ADM.ALTER_PROPAGATION(
    propagation_name  => 'strm01_propagation',
    rule_set_name     => 'strmadmin.strm02_rule_set');
END;
/

Specifying a Negative Rule Set for a Propagation

You specify an existing rule set as the negative rule set for an existing propagation using the negative_rule_set_name parameter in the ALTER_PROPAGATION procedure. This procedure is in the DBMS_PROPAGATION_ADM package.

For example, the following procedure sets the negative rule set for a propagation named strm01_propagation to strm03_rule_set.

BEGIN
  DBMS_PROPAGATION_ADM.ALTER_PROPAGATION(
    propagation_name        => 'strm01_propagation',
    negative_rule_set_name  => 'strmadmin.strm03_rule_set');
END;
/

Adding Rules to the Rule Set for a Propagation

To add rules to the rule set of a propagation, you can run one of the following procedures:

Excluding the ADD_SUBSET_PROPAGATION_RULES procedure, these procedures can add rules to the positive rule set or negative rule set for a propagation. The ADD_SUBSET_PROPAGATION_RULES procedure can add rules only to the positive rule set for a propagation.

Adding Rules to the Positive Rule Set for a Propagation

The following example runs the ADD_TABLE_PROPAGATION_RULES procedure in the DBMS_STREAMS_ADM package to add rules to the positive rule set of an existing propagation named strm01_propagation:

BEGIN
  DBMS_STREAMS_ADM.ADD_TABLE_PROPAGATION_RULES(
    table_name              => 'hr.locations',
    streams_name            => 'strm01_propagation',
    source_queue_name       => 'strmadmin.strm_a_queue',
    destination_queue_name  => 'strmadmin.strm_b_queue@dbs2.net',
    include_dml             => true,
    include_ddl             => true,
    source_database         => 'dbs1.net',
    inclusion_rule          => true);
END;
/

Running this procedure performs the following actions:

  • Creates two rules. One rule evaluates to TRUE for row LCRs that contain the results of DML changes to the hr.locations table. The other rule evaluates to TRUE for DDL LCRs that contain DDL changes to the hr.locations table. The rule names are system generated.

  • Specifies that both rules evaluate to TRUE only for LCRs whose changes originated at the dbs1.net source database.

  • Adds the two rules to the positive rule set associated with the propagation because the inclusion_rule parameter is set to true.

Adding Rules to the Negative Rule Set for a Propagation

The following example runs the ADD_TABLE_PROPAGATION_RULES procedure in the DBMS_STREAMS_ADM package to add rules to the negative rule set of an existing propagation named strm01_propagation:

BEGIN
  DBMS_STREAMS_ADM.ADD_TABLE_PROPAGATION_RULES(
    table_name              => 'hr.departments',
    streams_name            => 'strm01_propagation',
    source_queue_name       => 'strmadmin.strm_a_queue',
    destination_queue_name  => 'strmadmin.strm_b_queue@dbs2.net',
    include_dml             => true,
    include_ddl             => true,
    source_database         => 'dbs1.net',
    inclusion_rule          => false);
END;
/

Running this procedure performs the following actions:

  • Creates two rules. One rule evaluates to TRUE for row LCRs that contain the results of DML changes to the hr.departments table, and the other rule evaluates to TRUE for DDL LCRs that contain DDL changes to the hr.departments table. The rule names are system generated.

  • Specifies that both rules evaluate to TRUE only for LCRs whose changes originated at the dbs1.net source database.

  • Adds the two rules to the negative rule set associated with the propagation because the inclusion_rule parameter is set to false.

Removing a Rule from the Rule Set for a Propagation

You remove a rule from the rule set for an existing propagation by running the REMOVE_RULE procedure in the DBMS_STREAMS_ADM package. For example, the following procedure removes a rule named departments3 from the positive rule set of a propagation named strm01_propagation.

BEGIN
  DBMS_STREAMS_ADM.REMOVE_RULE(
    rule_name        => 'departments3',
    streams_type     => 'propagation',
    streams_name     => 'strm01_propagation',
    drop_unused_rule => true,
    inclusion_rule   => true);
END;
/

In this example, the drop_unused_rule parameter in the REMOVE_RULE procedure is set to true, which is the default setting. Therefore, if the rule being removed is not in any other rule set, then it will be dropped from the database. If the drop_unused_rule parameter is set to false, then the rule is removed from the rule set, but it is not dropped from the database even if it is not in any other rule set.

If the inclusion_rule parameter is set to false, then the REMOVE_RULE procedure removes the rule from the negative rule set for the propagation, not the positive rule set.

To remove all of the rules in the rule set for the propagation, then specify NULL for the rule_name parameter when you run the REMOVE_RULE procedure.

Removing a Rule Set for a Propagation

You specify that you want to remove a rule set from a propagation using the ALTER_PROPAGATION procedure in the DBMS_PROPAGATION_ADM package. This procedure can remove the positive rule set, negative rule set, or both. Specify true for the remove_rule_set parameter to remove the positive rule set for the propagation. Specify true for the remove_negative_rule_set parameter to remove the negative rule set for the propagation.

For example, the following procedure removes both the positive and the negative rule set from a propagation named strm01_propagation.

BEGIN
  DBMS_PROPAGATION_ADM.ALTER_PROPAGATION(
    propagation_name         => 'strm01_propagation',
    remove_rule_set          => true,
    remove_negative_rule_set => true);
END;
/

Note:

If a propagation does not have a positive or negative rule set, then the propagation propagates all messages in the source queue to the destination queue.

Dropping a Propagation

You run the DROP_PROPAGATION procedure in the DBMS_PROPAGATION_ADM package to drop an existing propagation. For example, the following procedure drops a propagation named strm01_propagation:

BEGIN
  DBMS_PROPAGATION_ADM.DROP_PROPAGATION(
    propagation_name      => 'strm01_propagation',
    drop_unused_rule_sets => true);
END;
/

Because the drop_unused_rule_sets parameter is set to true, this procedure also drops any rule sets used by the propagation strm01_propagation, unless a rule set is used by another Streams client. If the drop_unused_rule_sets parameter is set to true, then both the positive rule set and negative rule set for the propagation might be dropped. If this procedure drops a rule set, then it also drops any rules in the rule set that are not in another rule set.

Note:

When you drop a propagation, the propagation job used by the propagation is dropped automatically, if no other propagations are using the propagation job.

Managing a Streams Messaging Environment

Streams enables messaging with queues of type ANYDATA. These queues stage user messages whose payloads are of ANYDATA type, and an ANYDATA payload can be a wrapper for payloads of different datatypes.

This section provides instructions for completing the following tasks:

Wrapping User Message Payloads in an ANYDATA Wrapper and Enqueuing Them

You can wrap almost any type of payload in an ANYDATA payload. The following sections provide examples of enqueuing messages into, and dequeuing messages from, an ANYDATA queue.

The following steps illustrate how to wrap payloads of various types in an ANYDATA payload.

  1. Connect as an administrative user who can create users, grant privileges, create tablespaces, and alter users at the dbs1.net database.

  2. Grant EXECUTE privilege on the DBMS_AQ package to the oe user so that this user can run the ENQUEUE and DEQUEUE procedures in that package:

    GRANT EXECUTE ON DBMS_AQ TO oe;
    
    
  3. Connect as the Streams administrator, as in the following example:

    CONNECT strmadmin/strmadminpw@dbs1.net
    
    
  4. Create an ANYDATA queue if one does not already exist.

    BEGIN
      DBMS_STREAMS_ADM.SET_UP_QUEUE(
        queue_table  => 'oe_q_table_any',
        queue_name   => 'oe_q_any',
        queue_user   => 'oe');
    END;
    /
    
    

    The oe user is configured automatically as a secure queue user of the oe_q_any queue and is given ENQUEUE and DEQUEUE privileges on the queue. In addition, an AQ agent named oe is configured and is associated with the oe user. However, a message cannot be enqueued into a queue unless a subscriber who can dequeue the message is configured.

  5. Add a subscriber for oe_q_any queue. This subscriber will perform explicit dequeues of messages.

    DECLARE
      subscriber SYS.AQ$_AGENT;
    BEGIN
      subscriber :=  SYS.AQ$_AGENT('OE', NULL, NULL);  
      SYS.DBMS_AQADM.ADD_SUBSCRIBER(
        queue_name  =>  'strmadmin.oe_q_any',
        subscriber  =>  subscriber);
    END;
    /
    
    
  6. Connect as the oe user.

    CONNECT oe/oe@dbs1.net
    
    
  7. Create a procedure that takes as an input parameter an object of ANYDATA type and enqueues a message containing the payload into an existing ANYDATA queue.

    CREATE OR REPLACE PROCEDURE oe.enq_proc (payload ANYDATA) 
    IS
      enqopt     DBMS_AQ.ENQUEUE_OPTIONS_T;
      mprop      DBMS_AQ.MESSAGE_PROPERTIES_T;
      enq_msgid  RAW(16);
    BEGIN
      mprop.SENDER_ID := SYS.AQ$_AGENT('OE', NULL, NULL); 
      DBMS_AQ.ENQUEUE(
        queue_name          =>  'strmadmin.oe_q_any',
        enqueue_options     =>  enqopt,
        message_properties  =>  mprop,
        payload             =>  payload,
        msgid               =>  enq_msgid);
    END;
    /
    
    
  8. Run the procedure you created in Step 7 by specifying the appropriate Convertdata_type function. The following commands enqueue messages of various types.

    VARCHAR2 type:

    EXEC oe.enq_proc(ANYDATA.ConvertVarchar2('Chemicals - SW'));
    COMMIT;
    
    

    NUMBER type:

    EXEC oe.enq_proc(ANYDATA.ConvertNumber('16'));
    COMMIT;
    
    

    User-defined type:

    BEGIN
      oe.enq_proc(ANYDATA.ConvertObject(oe.cust_address_typ(
        '1646 Brazil Blvd','361168','Chennai','Tam', 'IN')));
    END;
    /
    COMMIT;
    
    

    See Also:

    "Viewing the Contents of User-Enqueued Messages in a Queue" for information about viewing the contents of these enqueued messages

Dequeuing a Payload that Is Wrapped in an ANYDATA Payload

The following steps illustrate how to dequeue a payload wrapped in an ANYDATA payload. This example assumes that you have completed the steps in "Wrapping User Message Payloads in an ANYDATA Wrapper and Enqueuing Them".

To dequeue messages, you must know the consumer of the messages. To find the consumer for the messages in a queue, connect as the owner of the queue and query the AQ$queue_table_name, where queue_table_name is the name of the queue table. For example, to find the consumers of the messages in the oe_q_any queue, run the following query:

CONNECT strmadmin/strmadminpw@dbs1.net

SELECT MSG_ID, MSG_STATE, CONSUMER_NAME FROM AQ$OE_Q_TABLE_ANY;

  1. Connect as the oe user:

    CONNECT oe/oe@dbs1.net
    
    
  2. Create a procedure that takes as an input the consumer of the messages you want to dequeue. The following example procedure dequeues messages of oe.cust_address_typ and prints the contents of the messages.

    CREATE OR REPLACE PROCEDURE oe.get_cust_address (
    consumer IN VARCHAR2) AS
      address         OE.CUST_ADDRESS_TYP;
      deq_address     ANYDATA; 
      msgid           RAW(16); 
      deqopt          DBMS_AQ.DEQUEUE_OPTIONS_T; 
      mprop           DBMS_AQ.MESSAGE_PROPERTIES_T;
      new_addresses   BOOLEAN := true;
      next_trans      EXCEPTION;
      no_messages     EXCEPTION; 
      pragma exception_init (next_trans, -25235);
      pragma exception_init (no_messages, -25228);
      num_var         pls_integer;
    BEGIN
         deqopt.consumer_name := consumer;
         deqopt.wait := 1;
         WHILE (new_addresses) LOOP
         BEGIN
          DBMS_AQ.DEQUEUE( 
             queue_name          =>  'strmadmin.oe_q_any',
             dequeue_options     =>  deqopt,
             message_properties  =>  mprop,
             payload             =>  deq_address,
             msgid               =>  msgid);
          deqopt.navigation := DBMS_AQ.NEXT;
          DBMS_OUTPUT.PUT_LINE('****');
          IF (deq_address.GetTypeName() = 'OE.CUST_ADDRESS_TYP') THEN
              DBMS_OUTPUT.PUT_LINE('Message TYPE is: ' ||  
                                    deq_address.GetTypeName()); 
              num_var := deq_address.GetObject(address);    
              DBMS_OUTPUT.PUT_LINE(' **** CUSTOMER ADDRESS **** ');
              DBMS_OUTPUT.PUT_LINE(address.street_address);
              DBMS_OUTPUT.PUT_LINE(address.postal_code);
              DBMS_OUTPUT.PUT_LINE(address.city);
              DBMS_OUTPUT.PUT_LINE(address.state_province);
              DBMS_OUTPUT.PUT_LINE(address.country_id);
          ELSE
             DBMS_OUTPUT.PUT_LINE('Message TYPE is: ' ||    
                                   deq_address.GetTypeName()); 
          END IF;  
        COMMIT;   
        EXCEPTION
          WHEN next_trans THEN
          deqopt.navigation := DBMS_AQ.NEXT_TRANSACTION;
          WHEN no_messages THEN
            new_addresses := false;
            DBMS_OUTPUT.PUT_LINE('No more messages');
         END;
      END LOOP; 
    END;
    /
    
    
  3. Run the procedure you created in Step 1 and specify the consumer of the messages you want to dequeue, as in the following example:

    SET SERVEROUTPUT ON SIZE 100000
    EXEC oe.get_cust_address('OE');
    

Configuring a Messaging Client and Message Notification

This section contains instructions for configuring the following elements in a database:

  • An enqueue procedure that enqueues messages into an ANYDATA queue at a database. In this example, the enqueue procedure uses a trigger to enqueue a message every time a row is inserted into the oe.orders table.

  • A messaging client that can dequeue user-enqueued messages based on rules. In this example, the messaging client uses a rule so that it dequeues only messages that involve the oe.orders table. The messaging client uses the DEQUEUE procedure in the DBMS_STREAMS_MESSAGING to dequeue one message at a time and display the order number for the order.

  • Message notification for the messaging client. In this example, a notification is sent to an email address when a message is enqueued into the queue used by the messaging client. The message can be dequeued by the messaging client because the message satisfies the rule sets of the messaging client.

You can query the DBA_STREAMS_MESSAGE_CONSUMERS data dictionary view for information about existing messaging clients and notifications.

Complete the following steps to configure a messaging client and message notification:

  1. Connect as an administrative user who can grant privileges and execute subprograms in supplied packages.

  2. Set the host name used to send the email, the mail port, and the email account that sends email messages for email notifications using the DBMS_AQELM package. The following example sets the mail host name to smtp.mycompany.com, the mail port to 25, and the email account to Mary.Smith@mycompany.com:

    BEGIN
      DBMS_AQELM.SET_MAILHOST('smtp.mycompany.com') ;
      DBMS_AQELM.SET_MAILPORT(25) ;
      DBMS_AQELM.SET_SENDFROM('Mary.Smith@mycompany.com');
    END;
    /
    
    

    You can use procedures in the DBMS_AQELM package to determine the current mail host, mail port, and send from settings for a database. For example, to determine the current mail host for a database, use the DBMS_AQELM.GET_MAILHOST procedure.

  3. Grant the necessary privileges to the users who will create the messaging client, enqueue and dequeue messages, and specify message notifications. In this example, the oe user performs all of these tasks.

    GRANT EXECUTE ON DBMS_AQ TO oe;
    GRANT EXECUTE ON DBMS_STREAMS_ADM TO oe;
    GRANT EXECUTE ON DBMS_STREAMS_MESSAGING TO oe;
    
    BEGIN 
      DBMS_RULE_ADM.GRANT_SYSTEM_PRIVILEGE(
        privilege    => DBMS_RULE_ADM.CREATE_RULE_SET_OBJ, 
        grantee      => 'oe', 
        grant_option => false);
    END;
    /
    
    BEGIN 
      DBMS_RULE_ADM.GRANT_SYSTEM_PRIVILEGE(
        privilege    => DBMS_RULE_ADM.CREATE_RULE_OBJ, 
        grantee      => 'oe', 
        grant_option => false);
    END;
    /
    
    BEGIN 
      DBMS_RULE_ADM.GRANT_SYSTEM_PRIVILEGE(
        privilege    => DBMS_RULE_ADM.CREATE_EVALUATION_CONTEXT_OBJ, 
        grantee      => 'oe', 
        grant_option => false);
    END;
    /
    
    
  4. Connect as the oe user:

    CONNECT oe/oe
    
    
  5. Create an ANYDATA queue using SET_UP_QUEUE, as in the following example:

    BEGIN
      DBMS_STREAMS_ADM.SET_UP_QUEUE(
        queue_table  => 'oe.notification_queue_table',
        queue_name   => 'oe.notification_queue');
    END;
    /
    
    
  6. Create the types for the user-enqueued messages, as in the following example:

    CREATE TYPE oe.user_msg AS OBJECT(
      object_name    VARCHAR2(30),
      object_owner   VARCHAR2(30),
      message        VARCHAR2(50));
    /
    
    
  7. Create a trigger that enqueues a message into the queue whenever an order is inserted into the oe.orders table, as in the following example:

    CREATE OR REPLACE TRIGGER oe.order_insert AFTER INSERT
    ON oe.orders FOR EACH ROW
    DECLARE
      msg            oe.user_msg;
      str            VARCHAR2(2000);
    BEGIN
      str := 'New Order - ' || :NEW.ORDER_ID || ' Order ID';
      msg  := oe.user_msg(
                 object_name   => 'ORDERS',
                 object_owner  => 'OE',
                 message       => str);
      DBMS_STREAMS_MESSAGING.ENQUEUE (
        queue_name   => 'oe.notification_queue',
        payload      => ANYDATA.CONVERTOBJECT(msg));
    END;
    /
    
    
  8. Create the messaging client that will dequeue messages from the queue and the rule used by the messaging client to determine which messages to dequeue, as in the following example:

    BEGIN
      DBMS_STREAMS_ADM.ADD_MESSAGE_RULE (
        message_type   => 'oe.user_msg',
        rule_condition => ' :msg.OBJECT_OWNER = ''OE'' AND  ' ||
                          ' :msg.OBJECT_NAME = ''ORDERS'' ',
        streams_type   => 'dequeue',
        streams_name   => 'oe',
        queue_name     => 'oe.notification_queue');
    END;
    /
    
    
  9. Set the message notification to send email upon enqueue of messages that can be dequeued by the messaging client, as in the following example:

    BEGIN
      DBMS_STREAMS_ADM.SET_MESSAGE_NOTIFICATION (
        streams_name         => 'oe',
        notification_action  => 'Mary.Smith@mycompany.com',
        notification_type    => 'MAIL',
        include_notification => true,
        queue_name           => 'oe.notification_queue');
    END;
    /
    
    
  10. Create a PL/SQL procedure that dequeues messages using the messaging client, as in the following example:

    CREATE OR REPLACE PROCEDURE oe.deq_notification(consumer IN VARCHAR2) AS
      msg            ANYDATA;
      user_msg       oe.user_msg;
      num_var        PLS_INTEGER;
      more_messages  BOOLEAN := true;
      navigation     VARCHAR2(30);
    BEGIN
      navigation := 'FIRST MESSAGE';
      WHILE (more_messages) LOOP
        BEGIN
          DBMS_STREAMS_MESSAGING.DEQUEUE(
            queue_name   => 'oe.notification_queue',
            streams_name => consumer,
            payload      => msg,
            navigation   => navigation,
            wait         => DBMS_STREAMS_MESSAGING.NO_WAIT);
          IF msg.GETTYPENAME() = 'OE.USER_MSG' THEN
            num_var := msg.GETOBJECT(user_msg);
            DBMS_OUTPUT.PUT_LINE(user_msg.object_name);
            DBMS_OUTPUT.PUT_LINE(user_msg.object_owner);
            DBMS_OUTPUT.PUT_LINE(user_msg.message);
          END IF;
          navigation := 'NEXT MESSAGE';
          COMMIT;
        EXCEPTION WHEN SYS.DBMS_STREAMS_MESSAGING.ENDOFCURTRANS THEN
                    navigation := 'NEXT TRANSACTION';
                  WHEN DBMS_STREAMS_MESSAGING.NOMOREMSGS THEN
                    more_messages := false;
                    DBMS_OUTPUT.PUT_LINE('No more messages.');
                  WHEN OTHERS THEN
                    RAISE;  
        END;
      END LOOP;
    END;
    /
    
    
  11. Insert rows into the oe.orders table, as in the following example:

    INSERT INTO oe.orders VALUES(2521, 'direct', 144, 0, 922.57, 159, NULL);
    INSERT INTO oe.orders VALUES(2522, 'direct', 116, 0, 1608.29, 153, NULL);
    COMMIT;
    INSERT INTO oe.orders VALUES(2523, 'direct', 116, 0, 227.55, 155, NULL);
    COMMIT;
    
    

Message notification sends a message to the email address specified in Step 9 for each message that was enqueued. Each notification is an AQXmlNotification, which includes of the following:

  • notification_options, which includes the following:

    • destination - The destination queue from which the message was dequeued

    • consumer_name - The name of the messaging client that dequeued the message

  • message_set - The set of message properties

The following example shows the AQXmlNotification format sent in an email notification:

<?xml version="1.0" encoding="UTF-8"?>
<Envelope xmlns="http://ns.oracle.com/AQ/schemas/envelope">
    <Body>
        <AQXmlNotification xmlns="http://ns.oracle.com/AQ/schemas/access">
            <notification_options>
                <destination>OE.NOTIFICATION_QUEUE</destination>
                <consumer_name>OE</consumer_name>
            </notification_options>
            <message_set>
                <message>
                    <message_header>
                        <message_id>CB510DDB19454731E034080020AE3E0A</message_id>
                        <expiration>-1</expiration>
                        <delay>0</delay>
                        <priority>1</priority>
                        <delivery_count>0</delivery_count>
                        <sender_id>
                            <agent_name>OE</agent_name>
                            <protocol>0</protocol>
                        </sender_id>
                        <message_state>0</message_state>
                    </message_header>
                </message>
            </message_set>
        </AQXmlNotification>
    </Body>
</Envelope>

You can dequeue the messages enqueued in this example by running the oe.deq_notification procedure:

SET SERVEROUTPUT ON SIZE 100000
EXEC oe.deq_notification('OE');

See Also: