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Package javax.sql

为Java ^TM编程语言提供服务器端数据源访问和处理API。

See: 描述

接口摘要

接口	描述
CommonDataSource	接口，定义它们之间的共同的方法 DataSource ， XADataSource和 ConnectionPoolDataSource 。
ConnectionEventListener	注册通知由 PooledConnection对象生成的事件的对象。
ConnectionPoolDataSource	一个工厂为 PooledConnection对象。
DataSource	一个连接到这个 DataSource对象所代表的物理数据源的工厂。
PooledConnection	提供连接池管理钩子的对象。
RowSet	该接口为JavaBeans组件模型的JDBC API添加了支持。
RowSetInternal	一个 RowSet对象实现的接口，以便向 RowSetReader或 RowSetWriter对象呈现自身。
RowSetListener	一个接口，必须由一个组件实现，该组件希望在 RowSet对象的生命中发生重大事件时被通知。
RowSetMetaData	一个对象，其中包含有关 RowSet对象中的列的 RowSet 。
RowSetReader	断开连接的 RowSet对象调用的工具将自己填充数据行。
RowSetWriter	一个实现 RowSetWriter接口的对象，称为 写入器 。
StatementEventListener	注册在“声明”池中的PreparedStatements上发生的事件的通知对象。
XAConnection	为分布式事务提供支持的对象。
XADataSource	一个用于 XAConnection使用的XAConnection对象的工厂。

类摘要

类	描述
ConnectionEvent	一个 Event对象，提供有关连接相关事件源的信息。
RowSetEvent	Event对象在 Event对象发生事件时 RowSet对象。
StatementEvent	A StatementEvent发送到所有 StatementEventListener的用户注册了 PooledConnection 。

Package javax.sql Description

Provides the API for server side data source access and processing from the Java ^TM programming language. This package supplements the java.sql package and, as of the version 1.4 release, is included in the Java Platform, Standard Edition (Java SE ^TM). It remains an essential part of the Java Platform, Enterprise Edition (Java EE ^TM).

The javax.sql package provides for the following:

1. The DataSource interface as an alternative to the DriverManager for establishing a connection with a data source
2. Connection pooling and Statement pooling
3. Distributed transactions
4. Rowsets

Applications use the DataSource and RowSet APIs directly, but the connection pooling and distributed transaction APIs are used internally by the middle-tier infrastructure.

Using a DataSource Object to Make a Connection

The javax.sql package provides the preferred way to make a connection with a data source. The DriverManager class, the original mechanism, is still valid, and code using it will continue to run. However, the newer DataSource mechanism is preferred because it offers many advantages over the DriverManager mechanism.

These are the main advantages of using a DataSource object to make a connection:

• 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.
• Connection and Statement pooling and distributed transactions are available through a DataSource object that is implemented to work with the middle-tier infrastructure. Connections made through the DriverManager do not have connection and statement pooling or distributed transaction capabilities.

Driver vendors provide DataSource implementations. A particular DataSource object represents a particular physical data source, and each connection the 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^TM (JNDI) API, usually by a system administrator or someone performing the duties of a system administrator. An application can retrieve the DataSource object it wants by doing a lookup on the logical name that has been registered for it. The application can then use the DataSource object to create a connection to the physical data source it represents.

A 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 DataSource implementation will automatically get a connection that participates in connection pooling. A 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.

Connection Pooling and Statement Pooling

Connections made via a 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 DataSource.getConnection method to get the pooled connection and uses it the same way it uses any Connection object.

The classes and interfaces used for connection pooling are:

• ConnectionPoolDataSource
• PooledConnection
• ConnectionEvent
• ConnectionEventListener
• StatementEvent
• 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 ConnectionPoolDataSource object is called on to create a PooledConnection object, the connection pool manager will register as a ConnectionEventListener object with the new 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 ConnectionEvent object.

If the connection pool manager supports Statement pooling, for PreparedStatements, which can be determined by invoking the method DatabaseMetaData.supportsStatementPooling, the connection pool manager will register as a StatementEventListener object with the new PooledConnection object. When the PreparedStatement is closed or there is an error, the connection pool manager (being a listener) gets a notification that includes a StatementEvent object.

Distributed Transactions

As with pooled connections, connections made via a 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:

• XADataSource
• XAConnection

These interfaces are used by the transaction manager; an application does not use them directly.

The XAConnection interface is derived from the 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 Connection.commit or Connection.rollback, and it cannot set the connection to be in auto-commit mode (that is, it cannot call 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 DataSource.getConnection method, just as it normally does. The transaction manager manages the transaction behind the scenes. The XADataSource interface creates XAConnection objects, and each XAConnection object creates an XAResource object that the transaction manager uses to manage the connection.

Rowsets

The RowSet interface works with various other classes and interfaces behind the scenes. These can be grouped into three categories.

1. Event Notification
   • RowSetListener
     A RowSet object is a JavaBeans^TM component because it has properties and participates in the JavaBeans event notification mechanism. The RowSetListener interface is implemented by a component that wants to be notified about events that occur to a particular RowSet object. Such a component registers itself as a listener with a rowset via the RowSet.addRowSetListener method.

     When the 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.

   • RowSetEvent
     As part of its internal notification process, a RowSet object creates an instance of RowSetEvent and passes it to the listener. The listener can use this RowSetEvent object to find out which rowset had the event.

2. Metadata
   • RowSetMetaData
     This interface, derived from the ResultSetMetaData interface, provides information about the columns in a RowSet object. An application can use RowSetMetaData methods to find out how many columns the rowset contains and what kind of data each column can contain.

     The RowSetMetaData interface provides methods for setting the information about columns, but an application would not normally use these methods. When an application calls the RowSet method execute, the RowSet object will contain a new set of rows, and its RowSetMetaData object will have been internally updated to contain information about the new columns.

3. The Reader/Writer Facility
   A RowSet object that implements the RowSetInternal interface can call on the RowSetReader object associated with it to populate itself with data. It can also call on the 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.
   • RowSetInternal
     By implementing the RowSetInternal interface, a 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 original 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 RowSetInternal methods behind the scenes to get access to this information. An application does not normally invoke these methods directly.

   • RowSetReader
     A disconnected RowSet object that has implemented the RowSetInternal interface can call on its reader (the RowSetReader object associated with it) to populate it with data. When an application calls the 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 RowSetMetaData object for its rowset. The rowset's internal state is also updated, either by the reader or directly by the method RowSet.execute.
   • RowSetWriter
     A disconnected RowSet object that has implemented the RowSetInternal interface can call on its writer (the 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:
     • Make a connection to the data source
     • 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
     • Write the new values to the data source if there is no conflict
     • Close the connection

The 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.

IMPORTANT NOTE: Code that uses API marked "Since 1.6" must be run using a JDBC technology driver that implements the JDBC 4.0 API. You must check your driver documentation to be sure that it implements the particular features you want to use.

Package Specification

• Specification of the JDBC 4.0 API

Related Documentation

The Java Series book published by Addison-Wesley Longman provides detailed information about the classes and interfaces in the javax.sql package:

• JDBC^TM API Tutorial and Reference, Third Edition:

从以下版本开始：

1.4