JDBC-based transaction management leverages the JDBC defined methods java.sql.Connection.commit() and java.sql.Connection.rollback() (JDBC does not define an explicit method of beginning a transaction). In Hibernate, this approach is represented by the org.hibernate.engine.transaction.internal.jdbc.JdbcTransactionFactory class.

JTA-based transaction approach which leverages the javax.transaction.UserTransaction interface as obtained from org.hibernate.engine.transaction.jta.platform.spi.JtaPlatform API. This approach is represented by the org.hibernate.engine.transaction.internal.jta.JtaTransactionFactory class.

Another JTA-based transaction approach which leverages the JTA javax.transaction.TransactionManager interface as obtained from org.hibernate.engine.transaction.jta.platform.spi.JtaPlatform API. This approach is represented by the org.hibernate.engine.transaction.internal.jta.CMTTransactionFactory class. In an actual JEE CMT environment, access to the javax.transaction.UserTransaction is restricted.

Its is also possible to plug in a custom transaction approach by implementing the org.hibernate.engine.transaction.spi.TransactionFactory contract. The default service initiator has built-in support for understanding custom transaction approaches via the hibernate.transaction.factory_class which can name either:

During development of 4.0, most of these classes named here were moved to new packages. To help facilitate upgrading, Hibernate will also recognize the legacy names here for a short period of time.

This is an anti-pattern of opening and closing a Session for each database call in a single thread. It is also an anti-pattern in terms of database transactions. Group your database calls into a planned sequence. In the same way, do not auto-commit after every SQL statement in your application. Hibernate disables, or expects the application server to disable, auto-commit mode immediately. Database transactions are never optional. All communication with a database must be encapsulated by a transaction. Avoid auto-commit behavior for reading data, because many small transactions are unlikely to perform better than one clearly-defined unit of work, and are more difficult to maintain and extend.

This is the most common transaction pattern. The term request here relates to the concept of a system that reacts to a series of requests from a client/user. Web applications are a prime example of this type of system, though certainly not the only one. At the beginning of handling such a request, the application opens a Hibernate Session, starts a transaction, performs all data related work, ends the transaction and closes the Session. The crux of the pattern is the one-to-one relationship between the transaction and the Session.

Within this pattern there is a common technique of defining a current session to simplify the need of passing this Session around to all the application components that may need access to it. Hibernate provides support for this technique through the getCurrentSession method of the SessionFactory. The concept of a "current" session has to have a scope that defines the bounds in which the notion of "current" is valid. This is purpose of the org.hibernate.context.spi.CurrentSessionContext contract. There are 2 reliable defining scopes:

The session-per-request pattern is not the only valid way of designing units of work. Many business processes require a whole series of interactions with the user that are interleaved with database accesses. In web and enterprise applications, it is not acceptable for a database transaction to span a user interaction. Consider the following example:

Even though we have multiple databases access here, from the point of view of the user, this series of steps represents a single unit of work. There are many ways to implement this in your application.

A first naive implementation might keep the Session and database transaction open while the user is editing, using database-level locks to prevent other users from modifying the same data and to guarantee isolation and atomicity. This is an anti-pattern, because lock contention is a bottleneck which will prevent scalability in the future.

Several database transactions are used to implement the conversation. In this case, maintaining isolation of business processes becomes the partial responsibility of the application tier. A single conversation usually spans several database transactions. These multiple database accesses can only be atomic as a whole if only one of these database transactions (typically the last one) stores the updated data. All others only read data. A common way to receive this data is through a wizard-style dialog spanning several request/response cycles. Hibernate includes some features which make this easy to implement.

Session-per-request-with-detached-objects and session-per-conversation each have advantages and disadvantages.

Discussion coming soon..