Oracle® Streams Concepts and Administration 10g Release 2 (10.2) Part Number B14229-04 |
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This chapter briefly describes the basic concepts and terminology related to Oracle Streams. These concepts are described in more detail in other chapters in this book and in the Oracle Streams Replication Administrator's Guide.
This chapter contains these topics:
Oracle Streams enables information sharing. Using Oracle Streams, each unit of shared information is called a message, and you can share these messages in a stream. The stream can propagate information within a database or from one database to another. The stream routes specified information to specified destinations. The result is a feature that provides greater functionality and flexibility than traditional solutions for capturing and managing messages, and sharing the messages with other databases and applications. Streams provides the capabilities needed to build and operate distributed enterprises and applications, data warehouses, and high availability solutions. You can use all of the capabilities of Oracle Streams at the same time. If your needs change, then you can implement a new capability of Streams without sacrificing existing capabilities.
Using Oracle Streams, you control what information is put into a stream, how the stream flows or is routed from database to database, what happens to messages in the stream as they flow into each database, and how the stream terminates. By configuring specific capabilities of Streams, you can address specific requirements. Based on your specifications, Streams can capture, stage, and manage messages in the database automatically, including, but not limited to, data manipulation language (DML) changes and data definition language (DDL) changes. You can also put user-defined messages into a stream, and Streams can propagate the information to other databases or applications automatically. When messages reach a destination, Streams can consume them based on your specifications.
Figure 1-1 shows the Streams information flow.
The following sections provide an overview of what Streams can do.
A capture process can capture database events, such as changes made to tables, schemas, or an entire database. Such changes are recorded in the redo log for a database, and a capture process captures changes from the redo log and formats each captured change into a message called a logical change record (LCR). The rules used by a capture process determine which changes it captures, and these captured changes are called captured messages.
The database where changes are generated in the redo log is called the source database. A capture process can capture changes locally at the source database, or it can capture changes remotely at a downstream database. A capture process enqueues logical change records (LCRs) into a queue that is associated with it. When a capture process captures messages, it is sometimes referred to as implicit capture.
Users and applications can also enqueue messages into a queue manually. These messages are called user-enqueued messages, and they can be LCRs or messages of a user-defined type called user messages. When users and applications enqueue messages into a queue manually, it is sometimes referred to as explicit capture.
Messages are stored (or staged) in a queue. These messages can be captured messages or user-enqueued messages. A capture process enqueues messages into a ANYDATA queue. An ANYDATA
queue can stage messages of different types. Users and applications can enqueue messages into an ANYDATA
queue or into a typed queue. A typed queue can stage messages of one specific type only.
Streams propagations can propagate messages from one queue to another. These queues can be in the same database or in different databases. Rules determine which messages are propagated by a propagation.
A message is consumed when it is dequeued from a queue. An apply process can dequeue messages from a queue implicitly. A user, application, or messaging client can dequeue messages explicitly. The database where messages are consumed is called the destination database. In some configurations, the source database and the destination database can be the same.
Rules determine which messages are dequeued and processed by an apply process. An apply process can apply messages directly to database objects or pass messages to custom PL/SQL subprograms for processing.
Rules determine which messages are dequeued by a messaging client. A messaging client dequeues messages when it is invoked by an application or a user.
Other capabilities of Streams include the following:
automatic conflict detection and conflict resolution
These capabilities are discussed briefly later in this chapter and in detail later in this document and in the Oracle Streams Replication Administrator's Guide.
The following sections briefly describe some of the reasons for using Streams. In some cases, Streams components provide infrastructure for various features of Oracle.
Oracle Streams Advanced Queuing (AQ) enables user applications to enqueue messages into a queue, propagate messages to subscribing queues, notify user applications that messages are ready for consumption, and dequeue messages at the destination. A queue can be configured to stage messages of a particular type only, or a queue can be configured as an ANYDATA
queue. Messages of almost any type can be wrapped in an ANYDATA
wrapper and staged in ANYDATA
queues. AQ supports all the standard features of message queuing systems, including multiconsumer queues, publish and subscribe, content-based routing, Internet propagation, transformations, and gateways to other messaging subsystems.
You can create a queue at a database, and applications can enqueue messages into the queue explicitly. Subscribing applications or messaging clients can dequeue messages directly from this queue. If an application is remote, then a queue can be created in a remote database that subscribes to messages published in the source queue. The destination application can dequeue messages from the remote queue. Alternatively, the destination application can dequeue messages directly from the source queue using a variety of standard protocols.
See Also:
Oracle Streams Advanced Queuing User's Guide and Reference for more information about AQStreams can capture DML and DDL changes made to database objects and replicate those changes to one or more other databases. A Streams capture process captures changes made to source database objects and formats them into LCRs, which can be propagated to destination databases and then applied by Streams apply processes.
The destination databases can allow DML and DDL changes to the same database objects, and these changes might or might not be propagated to the other databases in the environment. In other words, you can configure a Streams environment with one database that propagates changes, or you can configure an environment where changes are propagated between databases bidirectionally. Also, the tables for which data is shared do not need to be identical copies at all databases. Both the structure and the contents of these tables can differ at different databases, and the information in these tables can be shared between these databases.
See Also:
Oracle Streams Replication Administrator's Guide for more information using Streams for replicationBusiness events are valuable communications between applications or organizations. An application can enqueue messages that represent events into a queue explicitly, or a Streams capture process can capture database events and encapsulate them into messages called LCRs. These captured messages can be the results of DML or DDL changes. Propagations can propagate messages in a stream through multiple queues. Finally, a user application can dequeue messages explicitly, or a Streams apply process can dequeue messages implicitly. An apply process can reenqueue these messages explicitly into the same queue or a different queue if necessary.
You can configure queues to retain explicitly-enqueued messages after consumption for a specified period of time. This capability enables you to use Advanced Queuing (AQ) as a business event management system. AQ stores all messages in the database in a transactional manner, where they can be automatically audited and tracked. You can use this audit trail to extract intelligence about the business operations.
Streams capture processes, propagations, apply processes, and messaging clients perform actions based on rules. You specify which events are captured, propagated, applied, and dequeued using rules, and a built-in rules engine evaluates events based on these rules. The ability to capture events and propagate them to relevant consumers based on rules means that you can use Streams for event notification. Messages representing events can be staged in a queue and dequeued explicitly by a messaging client or an application, and then actions can be taken based on these events, which can include an email notification, or passing the message to a wireless gateway for transmission to a cell phone or pager.
See Also:
Chapter 3, "Streams Staging and Propagation", Chapter 12, "Managing Staging and Propagation", and Oracle Streams Advanced Queuing User's Guide and Reference for more information about explicitly enqueuing and dequeuing messages
Chapter 27, "Single-Database Capture and Apply Example" for a sample environment that explicitly dequeues messages
Data warehouse loading is a special case of data replication. Some of the most critical tasks in creating and maintaining a data warehouse include refreshing existing data, and adding new data from the operational databases. Streams components can capture changes made to a production system and send those changes to a staging database or directly to a data warehouse or operational data store. Streams capture of redo data avoids unnecessary overhead on the production systems. Support for data transformations and user-defined apply procedures enables the necessary flexibility to reformat data or update warehouse-specific data fields as data is loaded. In addition, Change Data Capture uses some of the components of Streams to identify data that has changed so that this data can be loaded into a data warehouse.
See Also:
Oracle Database Data Warehousing Guide for more information about data warehousesOne solution for data protection is to create a local or remote copy of a production database. In the event of human error or a catastrophe, the copy can be used to resume processing. You can use Streams to configure flexible high availability environments.
In addition, you can use Oracle Data Guard, a data protection feature that uses some of the same infrastructure as Streams, to create and maintain a logical standby database, which is a logically equivalent standby copy of a production database. As in the case of Streams replication, a capture process captures changes in the redo log and formats these changes into LCRs. These LCRs are applied at the standby databases. The standby databases are fully open for read/write and can include specialized indexes or other database objects. Therefore, these standby databases can be queried as updates are applied.
It is important to move the updates to the remote site as soon as possible with a logical standby database. Doing so ensures that, in the event of a failure, lost transactions are minimal. By directly and synchronously writing the redo logs at the remote database, you can achieve no data loss in the event of a disaster. At the standby system, the changes are captured and directly applied to the standby database with an apply process.
See Also:
Oracle Data Guard Concepts and Administration for more information about logical standby databases
You can use the features of Oracle Streams to achieve little or no database down time during database upgrade and maintenance operations. Maintenance operations include migrating a database to a different platform, migrating a database to a different character set, modifying database schema objects to support upgrades to user-created applications, and applying an Oracle software patch.
Changes made to database objects in an Oracle database are logged in the redo log to guarantee recoverability in the event of user error or media failure. A capture process is an Oracle background process that scans the database redo log to capture DML and DDL changes made to database objects. A capture process formats these changes into messages called LCRs and enqueues them into a queue. There are two types of LCRs: row LCRs contain information about a change to a row in table resulting from a DML operation, and DDL LCRs contain information about a DDL change to a database object. Rules determine which changes are captured. Figure 1-2 shows a capture process capturing LCRs.
You can configure change capture locally at a source database or remotely at a downstream database. A local capture process runs at the source database and captures changes from the local source database redo log. The following types of configurations are possible for a downstream capture process:
A real-time downstream capture configuration means that the log writer process (LGWR) at the source database sends redo data from the online redo log to the downstream database. At the downstream database, the redo data is stored in the standby redo log, and the capture process captures changes from the standby redo log.
An archived-log downstream capture configuration means that archived redo log files from the source database are copied to the downstream database, and the capture process captures changes in these archived redo log files.
Note:
A capture process does not capture some types of DML and DDL changes, and it does not capture changes made in theSYS
, SYSTEM
, or CTXSYS
schemas.See Also:
Chapter 2, "Streams Capture Process" for more information about capture processes and for detailed information about which DML and DDL statements are captured by a capture processStreams uses queues to stage messages for propagation or consumption. Propagations send messages from one queue to another, and these queues can be in the same database or in different databases. The queue from which the messages are propagated is called the source queue, and the queue that receives the messages is called the destination queue. There can be a one-to-many, many-to-one, or many-to-many relationship between source and destination queues.
Messages that are staged in a queue can be consumed by an apply process, a messaging client, or an application. Rules determine which messages are propagated by a propagation. Figure 1-3 shows propagation from a source queue to a destination queue.
Figure 1-3 Propagation from a Source Queue to a Destination Queue
See Also:
Chapter 3, "Streams Staging and Propagation" for more information about staging and propagationStreams enables you to configure an environment in which changes are shared through directed networks. In a directed network, propagated messages pass through one or more intermediate databases before arriving at a destination database where they are consumed. The messages might or might not be consumed at an intermediate database in addition to the destination database. Using Streams, you can choose which messages are propagated to each destination database, and you can specify the route messages will traverse on their way to a destination database.
See Also:
"Directed Networks"User applications can enqueue messages into a queue explicitly. The user applications can format these user-enqueued messages as LCRs or user messages, and an apply process, a messaging client, or a user application can consume these messages. Messages that were enqueued explicitly into a queue can be propagated to another queue or explicitly dequeued from the same queue. Figure 1-4 shows explicit enqueue of messages into and dequeue of messages from the same queue.
Figure 1-4 Explicit Enqueue and Dequeue of Messages in a Single Queue
When messages are propagated between queues, messages that were enqueued explicitly into a source queue can be dequeued explicitly from a destination queue by a messaging client or user application. These messages can also be processed by an apply process. Figure 1-5 shows explicit enqueue of messages into a source queue, propagation to a destination queue, and then explicit dequeue of messages from the destination queue.
Figure 1-5 Explicit Enqueue, Propagation, and Dequeue of Messages
See Also:
"ANYDATA Queues and User Messages" for more information about explicit enqueue and dequeue of messagesAn apply process is an Oracle background process that dequeues messages from a queue and either applies each message directly to a database object or passes the message as a parameter to a user-defined procedure called an apply handler. Apply handlers include message handlers, DML handlers, DDL handler, precommit handlers, and error handlers.
Typically, an apply process applies messages to the local database where it is running, but, in a heterogeneous database environment, it can be configured to apply messages at a remote non-Oracle database. Rules determine which messages are dequeued by an apply process. Figure 1-6 shows an apply process processing LCRs and user messages.
See Also:
Chapter 4, "Streams Apply Process"A messaging client consumes user-enqueued messages when it is invoked by an application or a user. Rules determine which user-enqueued messages are dequeued by a messaging client. These user-enqueued messages can be LCRs or user messages. Figure 1-7 shows a messaging client dequeuing user-enqueued messages.
See Also:
"Messaging Clients"An apply process detects conflicts automatically when directly applying LCRs in a replication environment. A conflict is a mismatch between the old values in an LCR and the expected data in a table. Typically, a conflict results when the same row in the source database and destination database is changed at approximately the same time.
When a conflict occurs, you need a mechanism to ensure that the conflict is resolved in accordance with your business rules. Streams offers a variety of prebuilt conflict handlers. Using these prebuilt handlers, you can define a conflict resolution system for each of your databases that resolves conflicts in accordance with your business rules. If you have a unique situation that prebuilt conflict resolution handlers cannot resolve, then you can build your own conflict resolution handlers.
If a conflict is not resolved, or if a handler procedure raises an error, then all messages in the transaction that raised the error are saved in the error queue for later analysis and possible reexecution.
Streams enables you to control which information to share and where to share it using rules. A rule is specified as a condition that is similar to the condition in the WHERE
clause of a SQL query.
A rule consists of the following components:
The rule condition combines one or more expressions and conditions and returns a Boolean value, which is a value of TRUE
, FALSE
, or NULL
(unknown), based on an event.
The evaluation context defines external data that can be referenced in rule conditions. The external data can either exist as external variables, as table data, or both.
The action context is optional information associated with a rule that is interpreted by the client of the rules engine when the rule is evaluated.
You can group related rules together into rule sets. In Streams, rule sets can be positive or negative.
For example, the following rule condition can be used for a rule in Streams to specify that the schema name that owns a table must be hr
and that the table name must be departments
for the condition to evaluate to TRUE
:
:dml.get_object_owner() = 'HR' AND :dml.get_object_name() = 'DEPARTMENTS'
The :dml
variable is used in rule conditions for row LCRs. In a Streams environment, a rule with this condition can be used in the following ways:
If the rule is in a positive rule set for a capture process, then it instructs the capture process to capture row changes that result from DML changes to the hr.departments
table. If the rule is in a negative rule set for a capture process, then it instructs the capture process to discard DML changes to the hr.departments
table.
If the rule is in a positive rule set for a propagation, then it instructs the propagation to propagate LCRs that contain row changes to the hr.departments
table. If the rule is in a negative rule set for a propagation, then it instructs the propagation to discard LCRs that contain row changes to the hr.departments
table.
If the rule is in a positive rule set for an apply process, then it instructs the apply process to apply LCRs that contain row changes to the hr.departments
table. If the rule is in a negative rule set for an apply process, then it instructs the apply process to discard LCRs that contain row changes to the hr.departments
table.
If the rule is in a positive rule set for a messaging client, then it instructs the messaging client to dequeue LCRs that contain row changes to the hr.departments
table. If the rule is in a negative rule set for a messaging client, then it instructs the messaging client to discard LCRs that contain row changes to the hr.departments
table.
Streams performs tasks based on rules. These tasks include capturing messages with a capture process, propagating messages with a propagation, applying messages with an apply process, dequeuing messages with a messaging client, and discarding messages.
A rule-based transformation is any modification to a message that results when a rule in a positive rule set evaluates to TRUE
. There are two types of rule-based transformations: declarative and custom.
Declarative rule-based transformations cover a set of common transformation scenarios for row LCRs, including renaming a schema, renaming a table, adding a column, renaming a column, and deleting a column. You specify (or declare) such a transformation using a procedure in the DBMS_STREAMS_ADM
package. Streams performs declarative transformations internally, without invoking PL/SQL.
A custom rule-based transformation requires a user-defined PL/SQL function to perform the transformation. Streams invokes the PL/SQL function to perform the transformation. A custom rule-based transformation can modify either captured messages or user-enqueued messages, and these messages can be LCRs or user messages. For example, a custom rule-based transformation can change the datatype of a particular column in an LCR.
To specify a custom rule-based transformation, use the DBMS_STREAMS_ADM.SET_RULE_TRANSFORM_FUNCTION
procedure. The transformation function takes as input an ANYDATA
object containing a message and returns an ANYDATA
object containing the transformed message. For example, a transformation can use a PL/SQL function that takes as input an ANYDATA
object containing an LCR with a NUMBER
datatype for a column and returns an ANYDATA
object containing an LCR with a VARCHAR2
datatype for the same column.
Either type of rule-based transformation can occur at the following times:
During enqueue of a message by a capture process, which can be useful for formatting a message in a manner appropriate for all destination databases
During propagation of a message, which can be useful for transforming a message before it is sent to a specific remote site
During dequeue of a message by an apply process or messaging client, which can be useful for formatting a message in a manner appropriate for a specific destination database
When a transformation is performed during apply, an apply process can apply the transformed message directly or send the transformed message to an apply handler for processing. Figure 1-8 shows a rule-based transformation during apply.
Note:
A rule must be in a positive rule set for its rule-based transformation to be invoked. A rule-based transformation specified for a rule in a negative rule set is ignored by capture processes, propagations, apply processes, and messaging clients.
Throughout this document, "rule-based transformation" is used when the text applies to both declarative and custom rule-based transformations. This document distinguishes between the two types of rule-based transformations when necessary.
See Also:
Chapter 7, "Rule-Based Transformations"Every redo entry in the redo log has a tag associated with it. The datatype of the tag is RAW
. By default, when a user or application generates redo entries, the value of the tag is NULL
for each redo entry, and a NULL
tag consumes no space in the redo entry. The size limit for a tag value is 2000 bytes.
In Streams, rules can have conditions relating to tag values to control the behavior of Streams clients. For example, a tag can be used to determine whether an LCR contains a change that originated in the local database or at a different database, so that you can avoid change cycling (sending an LCR back to the database where it originated). Also, a tag can be used to specify the set of destination databases for each LCR. Tags can be used for other LCR tracking purposes as well.
You can specify Streams tags for redo entries generated by a certain session or by an apply process. These tags then become part of the LCRs captured by a capture process. Typically, tags are used in Streams replication environments, but you can use them whenever it is necessary to track database changes and LCRs.
See Also:
Oracle Streams Replication Administrator's Guide for more information about Streams tagsIn addition to information sharing between Oracle databases, Streams supports information sharing between Oracle databases and non-Oracle databases. The following sections contain an overview of this support.
See Also:
Oracle Streams Replication Administrator's Guide for more information about heterogeneous information sharing with StreamsIf an Oracle database is the source and a non-Oracle database is the destination, then the non-Oracle database destination lacks the following Streams mechanisms:
An apply process to dequeue and apply messages
To share DML changes from an Oracle source database with a non-Oracle destination database, the Oracle database functions as a proxy and carries out some of the steps that would normally be done at the destination database. That is, the messages intended for the non-Oracle destination database are dequeued in the Oracle database itself, and an apply process at the Oracle database uses Heterogeneous Services to apply the messages to the non-Oracle database across a network connection through a gateway. Figure 1-9 shows an Oracle databases sharing data with a non-Oracle database.
Figure 1-9 Oracle to Non-Oracle Heterogeneous Data Sharing
See Also:
Oracle Database Heterogeneous Connectivity Administrator's Guide for more information about Heterogeneous ServicesTo capture and propagate changes from a non-Oracle database to an Oracle database, a custom application is required. This application gets the changes made to the non-Oracle database by reading from transaction logs, using triggers, or some other method. The application must assemble and order the transactions and must convert each change into an LCR. Next, the application must enqueue the LCRs into a queue in an Oracle database by using the PL/SQL interface, where they can be processed by an apply process. Figure 1-10 shows a non-Oracle databases sharing data with an Oracle database.
Figure 1-10 Non-Oracle to Oracle Heterogeneous Data Sharing
Figure 1-11 shows how Streams might be configured to share information within a single database, while Figure 1-12 shows how Streams might be configured to share information between two different databases.
Figure 1-11 Streams Configuration in a Single Database
Figure 1-12 Streams Configuration Sharing Information Between Databases
Several tools are available for configuring, administering, and monitoring your Streams environment. Oracle-supplied PL/SQL packages are the primary configuration and management tools, and the Streams tool in Oracle Enterprise Manager provides some configuration, administration, and monitoring capabilities to help you manage your environment. Additionally, Streams data dictionary views keep you informed about your Streams environment.
The following Oracle-supplied PL/SQL packages contain procedures and functions for configuring and managing a Streams environment.
See Also:
Oracle Database PL/SQL Packages and Types Reference for more information about these packagesThe DBMS_STREAMS_ADM
package provides an administrative interface for adding and removing simple rules for capture processes, propagations, and apply processes at the table, schema, and database level. This package also enables you to add rules that control which messages a propagation propagates and which messages a messaging client dequeues. This package also contains procedures for creating queues and for managing Streams metadata, such as data dictionary information. This package also contains procedures that enable you to configure and maintain a Streams replication environment. This package is provided as an easy way to complete common tasks in a Streams environment. You can use other packages, such as the DBMS_CAPTURE_ADM
, DBMS_PROPAGATION_ADM
, DBMS_APPLY_ADM
, DBMS_RULE_ADM
, and DBMS_AQADM
packages, to complete these same tasks, as well as tasks that require additional customization.
The DBMS_CAPTURE_ADM
package provides an administrative interface for starting, stopping, and configuring a capture process. This package also provides administrative procedures that prepare database objects at the source database for instantiation at a destination database.
The DBMS_PROPAGATION_ADM
package provides an administrative interface for configuring propagation from a source queue to a destination queue.
The DBMS_APPLY_ADM
package provides an administrative interface for starting, stopping, and configuring an apply process. This package includes procedures that enable you to configure apply handlers, set enqueue destinations for messages, and specify execution directives for messages. This package also provides administrative procedures that set the instantiation SCN for objects at a destination database. This package also includes subprograms for configuring conflict detection and resolution and for managing apply errors.
The DBMS_STREAMS_MESSAGING
package provides interfaces to enqueue messages into and dequeue messages from an ANYDATA
queue.
The DBMS_RULE_ADM
package provides an administrative interface for creating and managing rules, rule sets, and rule evaluation contexts. This package also contains subprograms for managing privileges related to rules.
The DBMS_RULE
package contains the EVALUATE
procedure, which evaluates a rule set. The goal of this procedure is to produce the list of satisfied rules, based on the data. This package also contains subprograms that enable you to use iterators during rule evaluation. Instead of returning all rules that evaluate to TRUE
or MAYBE
for an evaluation, iterators can return one rule at a time.
The DBMS_STREAMS
package provides interfaces to convert ANYDATA
objects into LCR objects, to return information about Streams attributes and Streams clients, and to annotate redo entries generated by a session with a tag. This tag can affect the behavior of a capture process, a propagation, an apply process, or a messaging client whose rules include specifications for these tags in redo entries or LCRs.
The DBMS_STREAMS_TABLESPACE_ADM
package provides administrative procedures for creating and managing a tablespace repository. This package also provides administrative procedures for copying tablespaces between databases and moving tablespaces from one database to another. This package uses transportable tablespaces, Data Pump, and the DBMS_FILE_TRANSFER
package.
The DBMS_STREAMS_AUTH
package provides interfaces for granting privileges to and revoking privileges from Streams administrators.
Every database in a Streams environment has Streams data dictionary views. These views maintain administrative information about local rules, objects, capture processes, propagations, apply processes, and messaging clients. You can use these views to monitor your Streams environment.
See Also:
Oracle Streams Replication Administrator's Guide for queries that are useful in a Streams replication environment
Oracle Database Reference for more information about these data dictionary views
To help configure, administer, and monitor Streams environments, Oracle provides a Streams tool in the Oracle Enterprise Manager Console. You can also use the Streams tool to generate Streams configuration scripts, which you can then modify and run to configure your Streams environment. The Streams tool online help contains the primary documentation for this tool.
Figure 1-13 shows the top portion of the Streams page in Enterprise Manager.
Figure 1-13 Streams Page in Enterprise Manager
Figure 1-14 shows the Streams Topology, which is on the bottom portion of the Streams page in the Enterprise Manager.
See Also:
The online help for the Streams tool in the Oracle Enterprise Manager