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/**
* Provides the API for server side data source access and processing from
* the Java programming language.
* This package supplements the {@code java.sql}
* package and, as of the version 1.4 release, is included in the
* Java Platform, Standard Edition (Java SE).
* It remains an essential part of the Java Platform, Enterprise Edition
* (Java EE).
* <p>
* The {@code javax.sql} package provides for the following:
* <OL>
* <LI>The {@code DataSource} interface as an alternative to the
* {@code DriverManager} for establishing a
* connection with a data source
* <LI>Connection pooling and Statement pooling
* <LI>Distributed transactions
* <LI>Rowsets
* </OL>
* Applications use the {@code DataSource} and {@code RowSet}
* APIs directly, but the connection pooling and distributed transaction
* APIs are used internally by the middle-tier infrastructure.
* <H2>Using a {@code DataSource} Object to Make a Connection</H2>
* The {@code javax.sql} package provides the preferred
* way to make a connection with a data source. The {@code DriverManager}
* class, the original mechanism, is still valid, and code using it will
* continue to run. However, the newer {@code DataSource} mechanism
* is preferred because it offers many advantages over the
* {@code DriverManager} mechanism.
* These are the main advantages of using a {@code DataSource} object to
* make a connection:
* <UL>
* <LI>Changes can be made to a data source's properties, which means
* that it is not necessary to make changes in application code when
* something about the data source or driver changes.
* <LI>Connection and Statement pooling and distributed transactions are available
* through a {@code DataSource} object that is
* implemented to work with the middle-tier infrastructure.
* Connections made through the {@code DriverManager}
* do not have connection and statement pooling or distributed transaction
* capabilities.
* </UL>
* Driver vendors provide {@code DataSource} implementations. A
* particular {@code DataSource} object represents a particular
* physical data source, and each connection the {@code DataSource} object
* creates is a connection to that physical data source.
* A logical name for the data source is registered with a naming service that
* uses the Java Naming and Directory Interface
* (JNDI) API, usually by a system administrator or someone performing the
* duties of a system administrator. An application can retrieve the
* {@code DataSource} object it wants by doing a lookup on the logical
* name that has been registered for it. The application can then use the
* {@code DataSource} object to create a connection to the physical data
* source it represents.
* A {@code DataSource} object can be implemented to work with the
* middle tier infrastructure so that the connections it produces will be
* pooled for reuse. An application that uses such a {@code DataSource}
* implementation will automatically get a connection that participates in
* connection pooling.
* A {@code DataSource} object can also be implemented to work with the
* middle tier infrastructure so that the connections it produces can be
* used for distributed transactions without any special coding.
* <H2>Connection Pooling and Statement Pooling</H2>
* Connections made via a {@code DataSource}
* object that is implemented to work with a middle tier connection pool manager
* will participate in connection pooling. This can improve performance
* dramatically because creating new connections is very expensive.
* Connection pooling allows a connection to be used and reused,
* thus cutting down substantially on the number of new connections
* that need to be created.
* Connection pooling is totally transparent. It is done automatically
* in the middle tier of a Java EE configuration, so from an application's
* viewpoint, no change in code is required. An application simply uses
* the {@code DataSource.getConnection} method to get the pooled
* connection and uses it the same way it uses any {@code Connection}
* object.
* The classes and interfaces used for connection pooling are:
* <LI>{@code ConnectionPoolDataSource}
* <LI>{@code PooledConnection}
* <LI>{@code ConnectionEvent}
* <LI>{@code ConnectionEventListener}
* <LI>{@code StatementEvent}
* <LI>{@code StatementEventListener}
* The connection pool manager, a facility in the middle tier of
* a three-tier architecture, uses these classes and interfaces
* behind the scenes. When a {@code ConnectionPoolDataSource} object
* is called on to create a {@code PooledConnection} object, the
* connection pool manager will register as a {@code ConnectionEventListener}
* object with the new {@code PooledConnection} object. When the connection
* is closed or there is an error, the connection pool manager (being a listener)
* gets a notification that includes a {@code ConnectionEvent} object.
* If the connection pool manager supports {@code Statement} pooling, for
* {@code PreparedStatements}, which can be determined by invoking the method
* {@code DatabaseMetaData.supportsStatementPooling}, the
* connection pool manager will register as a {@code StatementEventListener}
* object with the new {@code PooledConnection} object. When the
* {@code PreparedStatement} is closed or there is an error, the connection
* pool manager (being a listener)
* gets a notification that includes a {@code StatementEvent} object.
* <H2>Distributed Transactions</H2>
* As with pooled connections, connections made via a {@code DataSource}
* object that is implemented to work with the middle tier infrastructure
* may participate in distributed transactions. This gives an application
* the ability to involve data sources on multiple servers in a single
* transaction.
* The classes and interfaces used for distributed transactions are:
* <LI>{@code XADataSource}
* <LI>{@code XAConnection}
* These interfaces are used by the transaction manager; an application does
* not use them directly.
* The {@code XAConnection} interface is derived from the
* {@code PooledConnection} interface, so what applies to a pooled connection
* also applies to a connection that is part of a distributed transaction.
* A transaction manager in the middle tier handles everything transparently.
* The only change in application code is that an application cannot do anything
* that would interfere with the transaction manager's handling of the transaction.
* Specifically, an application cannot call the methods {@code Connection.commit}
* or {@code Connection.rollback}, and it cannot set the connection to be in
* auto-commit mode (that is, it cannot call
* {@code Connection.setAutoCommit(true)}).
* An application does not need to do anything special to participate in a
* distributed transaction.
* It simply creates connections to the data sources it wants to use via
* the {@code DataSource.getConnection} method, just as it normally does.
* The transaction manager manages the transaction behind the scenes. The
* {@code XADataSource} interface creates {@code XAConnection} objects, and
* each {@code XAConnection} object creates an {@code XAResource} object
* that the transaction manager uses to manage the connection.
* <H2>Rowsets</H2>
* The {@code RowSet} interface works with various other classes and
* interfaces behind the scenes. These can be grouped into three categories.
* <LI>Event Notification
* <LI>{@code RowSetListener}<br>
* A {@code RowSet} object is a JavaBeans
* component because it has properties and participates in the JavaBeans
* event notification mechanism. The {@code RowSetListener} interface
* is implemented by a component that wants to be notified about events that
* occur to a particular {@code RowSet} object. Such a component registers
* itself as a listener with a rowset via the {@code RowSet.addRowSetListener}
* method.
* When the {@code RowSet} object changes one of its rows, changes all of
* it rows, or moves its cursor, it also notifies each listener that is registered
* with it. The listener reacts by carrying out its implementation of the
* notification method called on it.
* <LI>{@code RowSetEvent}<br>
* As part of its internal notification process, a {@code RowSet} object
* creates an instance of {@code RowSetEvent} and passes it to the listener.
* The listener can use this {@code RowSetEvent} object to find out which rowset
* had the event.
* <LI>Metadata
* <LI>{@code RowSetMetaData}<br>
* This interface, derived from the
* {@code ResultSetMetaData} interface, provides information about
* the columns in a {@code RowSet} object. An application can use
* {@code RowSetMetaData} methods to find out how many columns the
* rowset contains and what kind of data each column can contain.
* The {@code RowSetMetaData} interface provides methods for
* setting the information about columns, but an application would not
* normally use these methods. When an application calls the {@code RowSet}
* method {@code execute}, the {@code RowSet} object will contain
* a new set of rows, and its {@code RowSetMetaData} object will have been
* internally updated to contain information about the new columns.
* <LI>The Reader/Writer Facility<br>
* A {@code RowSet} object that implements the {@code RowSetInternal}
* interface can call on the {@code RowSetReader} object associated with it
* to populate itself with data. It can also call on the {@code RowSetWriter}
* object associated with it to write any changes to its rows back to the
* data source from which it originally got the rows.
* A rowset that remains connected to its data source does not need to use a
* reader and writer because it can simply operate on the data source directly.
* <LI>{@code RowSetInternal}<br>
* By implementing the {@code RowSetInternal} interface, a
* {@code RowSet} object gets access to
* its internal state and is able to call on its reader and writer. A rowset
* keeps track of the values in its current rows and of the values that immediately
* preceded the current ones, referred to as the <i>original</i> values. A rowset
* also keeps track of (1) the parameters that have been set for its command and
* (2) the connection that was passed to it, if any. A rowset uses the
* {@code RowSetInternal} methods behind the scenes to get access to
* this information. An application does not normally invoke these methods directly.
* <LI>{@code RowSetReader}<br>
* A disconnected {@code RowSet} object that has implemented the
* {@code RowSetInternal} interface can call on its reader (the
* {@code RowSetReader} object associated with it) to populate it with
* data. When an application calls the {@code RowSet.execute} method,
* that method calls on the rowset's reader to do much of the work. Implementations
* can vary widely, but generally a reader makes a connection to the data source,
* reads data from the data source and populates the rowset with it, and closes
* the connection. A reader may also update the {@code RowSetMetaData} object
* for its rowset. The rowset's internal state is also updated, either by the
* reader or directly by the method {@code RowSet.execute}.
* <LI>{@code RowSetWriter}<br>
* {@code RowSetInternal} interface can call on its writer (the
* {@code RowSetWriter} object associated with it) to write changes
* back to the underlying data source. Implementations may vary widely, but
* generally, a writer will do the following:
* <LI>Make a connection to the data source
* <LI>Check to see whether there is a conflict, that is, whether
* a value that has been changed in the rowset has also been changed
* in the data source
* <LI>Write the new values to the data source if there is no conflict
* <LI>Close the connection
* The {@code RowSet} interface may be implemented in any number of
* ways, and anyone may write an implementation. Developers are encouraged
* to use their imaginations in coming up with new ways to use rowsets.
* <h2>Package Specification</h2>
* <ul>
* <li><a href="https://jcp.org/en/jsr/detail?id=221">JDBC 4.3 Specification</a>
* </ul>
* <h2>Related Documentation</h2>
* The Java Series book published by Addison-Wesley Longman provides detailed
* information about the classes and interfaces in the {@code javax.sql}
* package:
* <li>“<i>JDBC™API Tutorial and Reference, Third Edition</i>”
package javax.sql;