The Spring Framework supports integration with Hibernate, Java Persistence API (JPA), Java Data Objects (JDO) and iBATIS SQL Maps for resource management, data access object (DAO) implementations, and transaction strategies. For example, for Hibernate there is first-class support with several convenient IoC features that address many typical Hibernate integration issues. You can configure all of the supported features for O/R (object relational) mapping tools through Dependency Injection. They can participate in Spring's resource and transaction management, and they comply with Spring's generic transaction and DAO exception hierarchies. The recommended integration style is to code DAOs against plain Hibernate, JPA, and JDO APIs. The older style of using Spring's DAO templates is no longer recommended; however, coverage of this style can be found in the Section A.1, “Classic ORM usage” in the appendices.
Spring adds significant enhancements to the ORM layer of your choice when you create data access applications. You can leverage as much of the integration support as you wish, and you should compare this integration effort with the cost and risk of building a similar infrastructure in-house. You can use much of the ORM support as you would a library, regardless of technology, because everything is designed as a set of reusable JavaBeans. ORM in a Spring IoC container facilitates configuration and deployment. Thus most examples in this section show configuration inside a Spring container.
Benefits of using the Spring Framework to create your ORM DAOs include:
Easier testing. Spring's IoC approach makes
it easy to swap the implementations and configuration locations of
Hibernate SessionFactory
instances,
JDBC DataSource
instances, transaction
managers, and mapped object implementations (if needed). This in turn makes it
much easier to test each piece of persistence-related code in
isolation.
Common data access exceptions. Spring can wrap exceptions from your ORM tool, converting them from proprietary (potentially checked) exceptions to a common runtime DataAccessException hierarchy. This feature allows you to handle most persistence exceptions, which are non-recoverable, only in the appropriate layers, without annoying boilerplate catches, throws, and exception declarations. You can still trap and handle exceptions as necessary. Remember that JDBC exceptions (including DB-specific dialects) are also converted to the same hierarchy, meaning that you can perform some operations with JDBC within a consistent programming model.
General resource management. Spring
application contexts can handle the location and configuration of
Hibernate SessionFactory
instances, JPA
EntityManagerFactory
instances, JDBC
DataSource
instances, iBATIS SQL Maps
configuration objects, and other related resources. This makes these
values easy to manage and change. Spring offers efficient, easy, and
safe handling of persistence resources. For example, related code that
uses Hibernate generally needs to use the same Hibernate
Session
to ensure efficiency and proper
transaction handling. Spring makes it easy to create and bind a
Session
to the current thread
transparently, by
exposing a current Session
through the
Hibernate SessionFactory
. Thus Spring
solves many chronic problems of typical Hibernate usage, for any local
or JTA transaction environment.
Integrated transaction management. You can
wrap your ORM code with a declarative, aspect-oriented programming
(AOP) style method interceptor either through the
@Transactional
annotation or by
explicitly configuring the transaction AOP advice in an XML
configuration file. In both cases, transaction semantics and exception
handling (rollback, and so on) are handled for you. As discussed
below, in Resource and transaction
management, you can also swap various transaction managers,
without affecting your ORM-related code. For example, you can swap
between local transactions and JTA, with the same full services (such
as declarative transactions) available in both scenarios.
Additionally, JDBC-related code can fully integrate transactionally
with the code you use to do ORM. This is useful for data access that
is not suitable for ORM, such as batch processing and BLOB streaming,
which still need to
share common transactions with ORM operations.
TODO: provide links to current samples
This section highlights considerations that apply to all ORM technologies. The Section 15.3, “Hibernate” section provides more details and also show these features and configurations in a concrete context.
The major goal of Spring's ORM integration is clear application layering, with any data access and transaction technology, and for loose coupling of application objects. No more business service dependencies on the data access or transaction strategy, no more hard-coded resource lookups, no more hard-to-replace singletons, no more custom service registries. One simple and consistent approach to wiring up application objects, keeping them as reusable and free from container dependencies as possible. All the individual data access features are usable on their own but integrate nicely with Spring's application context concept, providing XML-based configuration and cross-referencing of plain JavaBean instances that need not be Spring-aware. In a typical Spring application, many important objects are JavaBeans: data access templates, data access objects, transaction managers, business services that use the data access objects and transaction managers, web view resolvers, web controllers that use the business services,and so on.
Typical business applications are cluttered with repetitive resource management code. Many projects try to invent their own solutions, sometimes sacrificing proper handling of failures for programming convenience. Spring advocates simple solutions for proper resource handling, namely IoC through templating in the case of JDBC and applying AOP interceptors for the ORM technologies.
The infrastructure provides proper resource handling and
appropriate conversion of specific API exceptions to an unchecked
infrastructure exception hierarchy. Spring
introduces a DAO exception hierarchy, applicable to any data access
strategy. For direct JDBC, the JdbcTemplate
class
mentioned in a previous section provides connection handling and proper
conversion of SQLException
to the
DataAccessException
hierarchy, including
translation of database-specific SQL error codes to meaningful exception
classes. For ORM technologies, see the next section for how to get the
same exception translation benefits.
When it comes to transaction management, the
JdbcTemplate
class hooks in to the Spring
transaction support and supports both JTA and JDBC transactions, through
respective Spring transaction managers. For the supported ORM
technologies Spring offers Hibernate, JPA and JDO support through the
Hibernate, JPA, and JDO transaction managers as well as JTA support. For
details on transaction support, see the Chapter 12, Transaction Management
chapter.
When you use Hibernate, JPA, or JDO in a DAO, you must decide how
to handle the persistence technology's native exception classes. The DAO
throws a subclass of a HibernateException
,
PersistenceException
or
JDOException
depending on the technology.
These exceptions are all run-time exceptions and do not have to be
declared or caught. You may also have to deal with
IllegalArgumentException
and
IllegalStateException
. This means that callers
can only treat exceptions as generally fatal, unless they want to depend
on the persistence technology's own exception structure. Catching
specific causes such as an optimistic locking failure is not possible
without tying the caller to the implementation strategy. This trade off
might be acceptable to applications that are strongly ORM-based and/or
do not need any special exception treatment. However, Spring enables
exception translation to be applied transparently through the
@Repository
annotation:
@Repository public class ProductDaoImpl implements ProductDao { // class body here... }
<beans> <!-- Exception translation bean post processor --> <bean class="org.springframework.dao.annotation.PersistenceExceptionTranslationPostProcessor"/> <bean id="myProductDao" class="product.ProductDaoImpl"/> </beans>
The postprocessor automatically looks for all exception
translators (implementations of the
PersistenceExceptionTranslator
interface)
and advises all beans marked with the
@Repository
annotation so that the
discovered translators can intercept and apply the appropriate
translation on the thrown exceptions.
In summary: you can implement DAOs based on the plain persistence technology's API and annotations, while still benefiting from Spring-managed transactions, dependency injection, and transparent exception conversion (if desired) to Spring's custom exception hierarchies.
We will start with a coverage of Hibernate 3 in a Spring environment, using it to demonstrate the approach that Spring takes towards integrating O/R mappers. This section will cover many issues in detail and show different variations of DAO implementations and transaction demarcation. Most of these patterns can be directly translated to all other supported ORM tools. The following sections in this chapter will then cover the other ORM technologies, showing briefer examples there.
Note | |
---|---|
As of Spring 3.0, Spring requires Hibernate 3.2 or later. |
To avoid tying application objects to hard-coded resource lookups,
you can define resources such as a JDBC
DataSource
or a Hibernate
SessionFactory
as beans in the Spring
container. Application objects that need to access resources receive
references to such predefined instances through bean references, as
illustrated in the DAO definition in the next section.
The following excerpt from an XML application context definition
shows how to set up a JDBC DataSource
and a
Hibernate SessionFactory
on top of
it:
<beans> <bean id="myDataSource" class="org.apache.commons.dbcp.BasicDataSource" destroy-method="close"> <property name="driverClassName" value="org.hsqldb.jdbcDriver"/> <property name="url" value="jdbc:hsqldb:hsql://localhost:9001"/> <property name="username" value="sa"/> <property name="password" value=""/> </bean> <bean id="mySessionFactory" class="org.springframework.orm.hibernate3.LocalSessionFactoryBean"> <property name="dataSource" ref="myDataSource"/> <property name="mappingResources"> <list> <value>product.hbm.xml</value> </list> </property> <property name="hibernateProperties"> <value> hibernate.dialect=org.hibernate.dialect.HSQLDialect </value> </property> </bean> </beans>
Switching from a local Jakarta Commons DBCP
BasicDataSource
to a JNDI-located
DataSource
(usually managed by an
application server) is just a matter of configuration:
<beans> <jee:jndi-lookup id="myDataSource" jndi-name="java:comp/env/jdbc/myds"/> </beans>
You can also access a JNDI-located
SessionFactory
, using Spring's
JndiObjectFactoryBean
/
<jee:jndi-lookup>
to retrieve and expose it.
However, that is typically not common outside of an EJB context.
Hibernate 3 has a feature called contextual sessions, wherein
Hibernate itself manages one current
Session
per transaction. This is roughly
equivalent to Spring's synchronization of one Hibernate
Session
per transaction. A corresponding
DAO implementation resembles the following example, based on the plain
Hibernate API:
public class ProductDaoImpl implements ProductDao { private SessionFactory sessionFactory; public void setSessionFactory(SessionFactory sessionFactory) { this.sessionFactory = sessionFactory; } public Collection loadProductsByCategory(String category) { return this.sessionFactory.getCurrentSession() .createQuery("from test.Product product where product.category=?") .setParameter(0, category) .list(); } }
This style is similar to that of the Hibernate reference
documentation and examples, except for holding the
SessionFactory
in an instance variable.
We strongly recommend such an instance-based setup over the old-school
static
HibernateUtil
class
from Hibernate's CaveatEmptor sample application. (In general, do not
keep any resources in static
variables unless
absolutely necessary.)
The above DAO follows the dependency injection pattern: it fits
nicely into a Spring IoC container, just as it would if coded against
Spring's HibernateTemplate
. Of course, such a DAO
can also be set up in plain Java (for example, in unit tests). Simply
instantiate it and call setSessionFactory(..)
with the desired factory reference. As a Spring bean definition, the DAO
would resemble the following:
<beans> <bean id="myProductDao" class="product.ProductDaoImpl"> <property name="sessionFactory" ref="mySessionFactory"/> </bean> </beans>
The main advantage of this DAO style is that it depends on Hibernate API only; no import of any Spring class is required. This is of course appealing from a non-invasiveness perspective, and will no doubt feel more natural to Hibernate developers.
However, the DAO throws plain
HibernateException
(which is unchecked, so does
not have to be declared or caught), which means that callers can only
treat exceptions as generally fatal - unless they want to depend on
Hibernate's own exception hierarchy. Catching specific causes such as an
optimistic locking failure is not possible without tying the caller to
the implementation strategy. This trade off might be acceptable to
applications that are strongly Hibernate-based and/or do not need any
special exception treatment.
Fortunately, Spring's
LocalSessionFactoryBean
supports Hibernate's
SessionFactory.getCurrentSession()
method for
any Spring transaction strategy, returning the current Spring-managed
transactional Session
even with
HibernateTransactionManager
. Of course, the
standard behavior of that method remains the return of the current
Session
associated with the ongoing JTA
transaction, if any. This behavior applies regardless of whether you are
using Spring's JtaTransactionManager
, EJB
container managed transactions (CMTs), or JTA.
In summary: you can implement DAOs based on the plain Hibernate 3 API, while still being able to participate in Spring-managed transactions.
We recommend that you use Spring's declarative transaction support, which enables you to replace explicit transaction demarcation API calls in your Java code with an AOP transaction interceptor. This transaction interceptor can be configured in a Spring container using either Java annotations or XML.This declarative transaction capability allows you to keep business services free of repetitive transaction demarcation code and to focus on adding business logic, which is the real value of your application.
Note | |
---|---|
Prior to continuing, you are strongly encouraged to read Section 12.5, “Declarative transaction management” if you have not done so. |
Furthermore, transaction semantics like propagation behavior and isolation level can be changed in a configuration file and do not affect the business service implementations.
The following example shows how you can configure an AOP transaction interceptor, using XML, for a simple service class:
<?xml version="1.0" encoding="UTF-8"?> <beans xmlns="http://www.springframework.org/schema/beans" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" xmlns:aop="http://www.springframework.org/schema/aop" xmlns:tx="http://www.springframework.org/schema/tx" xsi:schemaLocation=" http://www.springframework.org/schema/beans http://www.springframework.org/schema/beans/spring-beans.xsd http://www.springframework.org/schema/tx http://www.springframework.org/schema/tx/spring-tx.xsd http://www.springframework.org/schema/aop http://www.springframework.org/schema/aop/spring-aop.xsd"> <!-- SessionFactory, DataSource, etc. omitted --> <bean id="transactionManager" class="org.springframework.orm.hibernate3.HibernateTransactionManager"> <property name="sessionFactory" ref="sessionFactory"/> </bean> <aop:config> <aop:pointcut id="productServiceMethods" expression="execution(* product.ProductService.*(..))"/> <aop:advisor advice-ref="txAdvice" pointcut-ref="productServiceMethods"/> </aop:config> <tx:advice id="txAdvice" transaction-manager="myTxManager"> <tx:attributes> <tx:method name="increasePrice*" propagation="REQUIRED"/> <tx:method name="someOtherBusinessMethod" propagation="REQUIRES_NEW"/> <tx:method name="*" propagation="SUPPORTS" read-only="true"/> </tx:attributes> </tx:advice> <bean id="myProductService" class="product.SimpleProductService"> <property name="productDao" ref="myProductDao"/> </bean> </beans>
This is the service class that is advised:
public class ProductServiceImpl implements ProductService { private ProductDao productDao; public void setProductDao(ProductDao productDao) { this.productDao = productDao; } // notice the absence of transaction demarcation code in this method // Spring's declarative transaction infrastructure will be demarcating // transactions on your behalf public void increasePriceOfAllProductsInCategory(final String category) { List productsToChange = this.productDao.loadProductsByCategory(category); // ... } }
We also show an attribute-support based configuration, in the following example. You annotate the service layer with @Transactional annotations and instruct the Spring container to find these annotations and provide transactional semantics for these annotated methods.
public class ProductServiceImpl implements ProductService { private ProductDao productDao; public void setProductDao(ProductDao productDao) { this.productDao = productDao; } @Transactional public void increasePriceOfAllProductsInCategory(final String category) { List productsToChange = this.productDao.loadProductsByCategory(category); // ... } @Transactional(readOnly = true) public List<Product> findAllProducts() { return this.productDao.findAllProducts(); } }
As you can see from the following configuration example, the configuration is much simplified, compared to the XML example above, while still providing the same functionality driven by the annotations in the service layer code. All you need to provide is the TransactionManager implementation and a "<tx:annotation-driven/>" entry.
<?xml version="1.0" encoding="UTF-8"?> <beans xmlns="http://www.springframework.org/schema/beans" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" xmlns:aop="http://www.springframework.org/schema/aop" xmlns:tx="http://www.springframework.org/schema/tx" xsi:schemaLocation=" http://www.springframework.org/schema/beans http://www.springframework.org/schema/beans/spring-beans.xsd http://www.springframework.org/schema/tx http://www.springframework.org/schema/tx/spring-tx.xsd http://www.springframework.org/schema/aop http://www.springframework.org/schema/aop/spring-aop.xsd"> <!-- SessionFactory, DataSource, etc. omitted --> <bean id="transactionManager" class="org.springframework.orm.hibernate3.HibernateTransactionManager"> <property name="sessionFactory" ref="sessionFactory"/> </bean> <tx:annotation-driven/> <bean id="myProductService" class="product.SimpleProductService"> <property name="productDao" ref="myProductDao"/> </bean> </beans>
You can demarcate transactions in a higher level of the
application, on top of such lower-level data access services spanning
any number of operations. Nor do restrictions exist on the
implementation of the surrounding business service; it just needs a
Spring PlatformTransactionManager
. Again, the
latter can come from anywhere, but preferably as a bean reference
through a setTransactionManager(..)
method,
just as the productDAO
should be set by a
setProductDao(..)
method. The following
snippets show a transaction manager and a business service definition in
a Spring application context, and an example for a business method
implementation:
<beans> <bean id="myTxManager" class="org.springframework.orm.hibernate3.HibernateTransactionManager"> <property name="sessionFactory" ref="mySessionFactory"/> </bean> <bean id="myProductService" class="product.ProductServiceImpl"> <property name="transactionManager" ref="myTxManager"/> <property name="productDao" ref="myProductDao"/> </bean> </beans>
public class ProductServiceImpl implements ProductService { private TransactionTemplate transactionTemplate; private ProductDao productDao; public void setTransactionManager(PlatformTransactionManager transactionManager) { this.transactionTemplate = new TransactionTemplate(transactionManager); } public void setProductDao(ProductDao productDao) { this.productDao = productDao; } public void increasePriceOfAllProductsInCategory(final String category) { this.transactionTemplate.execute(new TransactionCallbackWithoutResult() { public void doInTransactionWithoutResult(TransactionStatus status) { List productsToChange = this.productDao.loadProductsByCategory(category); // do the price increase... } } ); } }
Spring's TransactionInterceptor
allows any
checked application exception to be thrown with the callback code, while
TransactionTemplate
is restricted to unchecked
exceptions within the callback.
TransactionTemplate
triggers a rollback in case
of an unchecked application exception, or if the transaction is marked
rollback-only by the application (via
TransactionStatus
).
TransactionInterceptor
behaves the same way by
default but allows configurable rollback policies per method.
Both TransactionTemplate
and
TransactionInterceptor
delegate the actual
transaction handling to a
PlatformTransactionManager
instance, which can be
a HibernateTransactionManager
(for a single
Hibernate SessionFactory
, using a
ThreadLocal
Session
under the hood) or a
JtaTransactionManager
(delegating to the JTA
subsystem of the container) for Hibernate applications. You can even use
a custom PlatformTransactionManager
implementation. Switching from native Hibernate transaction management
to JTA, such as when facing distributed transaction requirements for
certain deployments of your application, is just a matter of
configuration. Simply replace the Hibernate transaction manager with
Spring's JTA transaction implementation. Both transaction demarcation
and data access code will work without changes, because they just use
the generic transaction management APIs.
For distributed transactions across multiple Hibernate session
factories, simply combine JtaTransactionManager
as a transaction strategy with multiple
LocalSessionFactoryBean
definitions. Each DAO
then gets one specific SessionFactory
reference passed into its corresponding bean property. If all underlying
JDBC data sources are transactional container ones, a business service
can demarcate transactions across any number of DAOs and any number of
session factories without special regard, as long as it is using
JtaTransactionManager
as the strategy.
<beans> <jee:jndi-lookup id="dataSource1" jndi-name="java:comp/env/jdbc/myds1"/> <jee:jndi-lookup id="dataSource2" jndi-name="java:comp/env/jdbc/myds2"/> <bean id="mySessionFactory1" class="org.springframework.orm.hibernate3.LocalSessionFactoryBean"> <property name="dataSource" ref="myDataSource1"/> <property name="mappingResources"> <list> <value>product.hbm.xml</value> </list> </property> <property name="hibernateProperties"> <value> hibernate.dialect=org.hibernate.dialect.MySQLDialect hibernate.show_sql=true </value> </property> </bean> <bean id="mySessionFactory2" class="org.springframework.orm.hibernate3.LocalSessionFactoryBean"> <property name="dataSource" ref="myDataSource2"/> <property name="mappingResources"> <list> <value>inventory.hbm.xml</value> </list> </property> <property name="hibernateProperties"> <value> hibernate.dialect=org.hibernate.dialect.OracleDialect </value> </property> </bean> <bean id="myTxManager" class="org.springframework.transaction.jta.JtaTransactionManager"/> <bean id="myProductDao" class="product.ProductDaoImpl"> <property name="sessionFactory" ref="mySessionFactory1"/> </bean> <bean id="myInventoryDao" class="product.InventoryDaoImpl"> <property name="sessionFactory" ref="mySessionFactory2"/> </bean> <bean id="myProductService" class="product.ProductServiceImpl"> <property name="productDao" ref="myProductDao"/> <property name="inventoryDao" ref="myInventoryDao"/> </bean> <aop:config> <aop:pointcut id="productServiceMethods" expression="execution(* product.ProductService.*(..))"/> <aop:advisor advice-ref="txAdvice" pointcut-ref="productServiceMethods"/> </aop:config> <tx:advice id="txAdvice" transaction-manager="myTxManager"> <tx:attributes> <tx:method name="increasePrice*" propagation="REQUIRED"/> <tx:method name="someOtherBusinessMethod" propagation="REQUIRES_NEW"/> <tx:method name="*" propagation="SUPPORTS" read-only="true"/> </tx:attributes> </tx:advice> </beans>
Both HibernateTransactionManager
and
JtaTransactionManager
allow for proper JVM-level
cache handling with Hibernate, without container-specific transaction
manager lookup or a JCA connector (if you are not using EJB to initiate
transactions).
HibernateTransactionManager
can export the
Hibernate JDBC Connection
to plain JDBC
access code, for a specific DataSource
.
This capability allows for high-level transaction demarcation with mixed
Hibernate and JDBC data access completely without JTA, if you are
accessing only one database.
HibernateTransactionManager
automatically exposes
the Hibernate transaction as a JDBC transaction if you have set up the
passed-in SessionFactory
with a
DataSource
through the
dataSource
property of the
LocalSessionFactoryBean
class. Alternatively, you
can specify explicitly the DataSource
for
which the transactions are supposed to be exposed through the
dataSource
property of the
HibernateTransactionManager
class.
You can switch between a container-managed JNDI
SessionFactory
and a
locally defined one, without having to change a single line of
application code. Whether to keep resource definitions in the container
or locally within the application is mainly a matter of the transaction
strategy that you use. Compared to a Spring-defined local
SessionFactory
, a manually registered
JNDI SessionFactory
does not provide any
benefits. Deploying a SessionFactory
through Hibernate's JCA connector provides the added value of
participating in the Java EE server's management infrastructure, but
does not add actual value beyond that.
Spring's transaction support is not bound to a container.
Configured with any strategy other than JTA, transaction support also
works in a stand-alone or test environment. Especially in the typical
case of single-database transactions, Spring's single-resource local
transaction support is
a lightweight and powerful alternative to JTA. When you use local EJB
stateless session beans to drive transactions, you depend both on an EJB
container and JTA, even if you access only a single database, and only
use stateless session beans to provide declarative transactions through
container-managed transactions. Also,
direct use of JTA programmatically requires a Java EE environment as
well. JTA does not involve only container dependencies in terms of JTA
itself and of JNDI DataSource
instances.
For non-Spring, JTA-driven Hibernate transactions, you have to use the
Hibernate JCA connector, or extra Hibernate transaction code with the
TransactionManagerLookup
configured for
proper JVM-level caching.
Spring-driven transactions can work as well with a locally defined
Hibernate SessionFactory
as they do with
a local JDBC DataSource
if they are
accessing a single database. Thus you only have to use Spring's JTA
transaction strategy when you have distributed transaction requirements.
A JCA connector requires container-specific deployment steps, and
obviously JCA support in the first place. This configuration requires
more work than deploying a simple web application with local resource
definitions and Spring-driven transactions. Also, you often need the
Enterprise Edition of your container if you are using, for example,
WebLogic Express, which does not provide JCA. A Spring application with
local resources and transactions spanning one single database works in
any Java EE web container (without JTA, JCA, or EJB) such as Tomcat,
Resin, or even plain Jetty. Additionally, you can easily reuse such a
middle tier in desktop applications or test suites.
All things considered, if you do not use EJBs, stick with local
SessionFactory
setup and Spring's
HibernateTransactionManager
or
JtaTransactionManager
. You get all of the
benefits, including proper transactional JVM-level caching and
distributed transactions, without the inconvenience of container
deployment. JNDI registration of a Hibernate
SessionFactory
through the JCA connector
only adds value when used in conjunction with EJBs.
In some JTA environments with very strict
XADataSource
implementations -- currently
only some WebLogic Server and WebSphere versions -- when Hibernate is
configured without regard to the JTA
PlatformTransactionManager
object for
that environment, it is possible for spurious warning or exceptions to
show up in the application server log. These warnings or exceptions
indicate that the connection being accessed is no longer valid, or JDBC
access is no longer valid, possibly because the transaction is no longer
active. As an example, here is an actual exception from WebLogic:
java.sql.SQLException: The transaction is no longer active - status: 'Committed'. No further JDBC access is allowed within this transaction.
You resolve this warning by simply making Hibernate aware of the
JTA PlatformTransactionManager
instance,
to which it will synchronize (along with Spring). You have two options
for doing this:
If in your application context you are already directly
obtaining the JTA
PlatformTransactionManager
object
(presumably from JNDI through
JndiObjectFactoryBean
or <jee:jndi-lookup>
)
and feeding it, for example, to Spring's
JtaTransactionManager
, then the easiest way
is to specify a reference to the bean defining this JTA
PlatformTransactionManager
instance as
the value of the jtaTransactionManager property
for LocalSessionFactoryBean.
Spring then makes
the object available to Hibernate.
More likely you do not already have the JTA
PlatformTransactionManager
instance,
because Spring's JtaTransactionManager
can
find it itself. Thus
you need to configure Hibernate to look up JTA
PlatformTransactionManager
directly.
You do this by configuring an application server- specific
TransactionManagerLookup
class in the Hibernate
configuration, as described in the Hibernate manual.
The remainder of this section describes the sequence of events
that occur with and without Hibernate's awareness of the JTA
PlatformTransactionManager
.
When Hibernate is not configured with any awareness of the JTA
PlatformTransactionManager
, the following
events occur when a JTA transaction commits:
The JTA transaction commits.
Spring's JtaTransactionManager
is
synchronized to the JTA transaction, so it is called back through an
afterCompletion callback by the JTA transaction
manager.
Among other activities, this synchronization can
trigger a callback by Spring to Hibernate, through Hibernate's
afterTransactionCompletion
callback (used
to clear the Hibernate cache), followed by an explicit
close()
call on the Hibernate Session, which
causes Hibernate to attempt to close()
the JDBC
Connection.
In some environments, this
Connection.close()
call then triggers the
warning or error, as the application server no longer considers the
Connection
usable at all, because the
transaction has already been committed.
When Hibernate is configured with awareness of the JTA
PlatformTransactionManager
, the following
events occur when a JTA transaction commits:
the JTA transaction is ready to commit.
Spring's JtaTransactionManager
is
synchronized to the JTA transaction, so the transaction is called
back through a beforeCompletion callback by the
JTA transaction manager.
Spring is aware that Hibernate itself is synchronized to the
JTA transaction, and behaves differently than in the previous
scenario. Assuming the Hibernate
Session
needs to be closed at all,
Spring will close it now.
The JTA transaction commits.
Hibernate is synchronized to the JTA transaction, so the transaction is called back through an afterCompletion callback by the JTA transaction manager, and can properly clear its cache.
Spring supports the standard JDO 2.0 and 2.1 APIs as data access
strategy, following the same style as the Hibernate support. The
corresponding integration classes reside in the
org.springframework.orm.jdo
package.
Spring provides a
LocalPersistenceManagerFactoryBean
class that
allows you to define a local JDO
PersistenceManagerFactory
within a Spring
application context:
<beans> <bean id="myPmf" class="org.springframework.orm.jdo.LocalPersistenceManagerFactoryBean"> <property name="configLocation" value="classpath:kodo.properties"/> </bean> </beans>
Alternatively, you can set up a
PersistenceManagerFactory
through direct
instantiation of a
PersistenceManagerFactory
implementation
class. A JDO PersistenceManagerFactory
implementation class follows the JavaBeans pattern, just like a JDBC
DataSource
implementation class, which is
a natural fit for a configuration that uses Spring. This setup style
usually supports a Spring-defined JDBC
DataSource
, passed into the
connectionFactory
property. For example, for the
open source JDO implementation DataNucleus (formerly JPOX) (http://www.datanucleus.org/),
this is the XML configuration of the
PersistenceManagerFactory
implementation:
<beans> <bean id="dataSource" class="org.apache.commons.dbcp.BasicDataSource" destroy-method="close"> <property name="driverClassName" value="${jdbc.driverClassName}"/> <property name="url" value="${jdbc.url}"/> <property name="username" value="${jdbc.username}"/> <property name="password" value="${jdbc.password}"/> </bean> <bean id="myPmf" class="org.datanucleus.jdo.JDOPersistenceManagerFactory" destroy-method="close"> <property name="connectionFactory" ref="dataSource"/> <property name="nontransactionalRead" value="true"/> </bean> </beans>
You can also set up JDO
PersistenceManagerFactory
in the JNDI
environment of a Java EE application server, usually through the JCA
connector provided by the particular JDO implementation. Spring's
standard JndiObjectFactoryBean
or
<jee:jndi-lookup>
can be used to
retrieve and expose such a
PersistenceManagerFactory
. However,
outside an EJB context, no real benefit exists in holding the
PersistenceManagerFactory
in JNDI: only
choose such a setup for a good reason. See Section 15.3.6, “Comparing container-managed and locally defined resources” for a discussion; the arguments
there apply to JDO as well.
DAOs can also be written directly against plain JDO API, without
any Spring dependencies, by using an injected
PersistenceManagerFactory
. The following
is an example of a corresponding DAO implementation:
public class ProductDaoImpl implements ProductDao { private PersistenceManagerFactory persistenceManagerFactory; public void setPersistenceManagerFactory(PersistenceManagerFactory pmf) { this.persistenceManagerFactory = pmf; } public Collection loadProductsByCategory(String category) { PersistenceManager pm = this.persistenceManagerFactory.getPersistenceManager(); try { Query query = pm.newQuery(Product.class, "category = pCategory"); query.declareParameters("String pCategory"); return query.execute(category); } finally { pm.close(); } } }
Because the above DAO follows the dependency injection pattern, it
fits nicely into a Spring container, just as it would if coded against
Spring's JdoTemplate
:
<beans> <bean id="myProductDao" class="product.ProductDaoImpl"> <property name="persistenceManagerFactory" ref="myPmf"/> </bean> </beans>
The main problem with such DAOs is that they always get a new
PersistenceManager
from the factory. To
access a Spring-managed transactional
PersistenceManager
, define a
TransactionAwarePersistenceManagerFactoryProxy
(as included in Spring) in front of your target
PersistenceManagerFactory
, then passing a
reference to that proxy into your DAOs as in the following example:
<beans> <bean id="myPmfProxy" class="org.springframework.orm.jdo.TransactionAwarePersistenceManagerFactoryProxy"> <property name="targetPersistenceManagerFactory" ref="myPmf"/> </bean> <bean id="myProductDao" class="product.ProductDaoImpl"> <property name="persistenceManagerFactory" ref="myPmfProxy"/> </bean> </beans>
Your data access code will receive a transactional
PersistenceManager
(if any) from the
PersistenceManagerFactory.getPersistenceManager()
method that it calls. The latter method call goes through the proxy,
which first checks for a current transactional
PersistenceManager
before getting a new
one from the factory. Any close()
calls on the
PersistenceManager
are ignored in case of
a transactional
PersistenceManager
.
If your data access code always runs within an active transaction
(or at least within active transaction synchronization), it is safe to
omit the PersistenceManager.close()
call and
thus the entire finally
block, which you might do to
keep your DAO implementations concise:
public class ProductDaoImpl implements ProductDao { private PersistenceManagerFactory persistenceManagerFactory; public void setPersistenceManagerFactory(PersistenceManagerFactory pmf) { this.persistenceManagerFactory = pmf; } public Collection loadProductsByCategory(String category) { PersistenceManager pm = this.persistenceManagerFactory.getPersistenceManager(); Query query = pm.newQuery(Product.class, "category = pCategory"); query.declareParameters("String pCategory"); return query.execute(category); } }
With such DAOs that rely on active transactions, it is recommended
that you enforce active transactions through turning off
TransactionAwarePersistenceManagerFactoryProxy
's
allowCreate
flag:
<beans> <bean id="myPmfProxy" class="org.springframework.orm.jdo.TransactionAwarePersistenceManagerFactoryProxy"> <property name="targetPersistenceManagerFactory" ref="myPmf"/> <property name="allowCreate" value="false"/> </bean> <bean id="myProductDao" class="product.ProductDaoImpl"> <property name="persistenceManagerFactory" ref="myPmfProxy"/> </bean> </beans>
The main advantage of this DAO style is that it depends on JDO API only; no import of any Spring class is required. This is of course appealing from a non-invasiveness perspective, and might feel more natural to JDO developers.
However, the DAO throws plain
JDOException
(which is unchecked, so does
not have to be declared or caught), which means that callers can only
treat exceptions as fatal, unless you want to depend on JDO's own
exception structure. Catching specific causes such as an optimistic
locking failure is not possible without tying the caller to the
implementation strategy. This trade off might be acceptable to
applications that are strongly JDO-based and/or do not need any special
exception treatment.
In summary, you can DAOs based on the plain JDO API, and they can
still participate in Spring-managed transactions. This strategy might
appeal to you if you are already familiar with JDO. However, such DAOs
throw plain JDOException
, and you would
have to convert explicitly to Spring's
DataAccessException
(if desired).
Note | |
---|---|
You are strongly encouraged to read Section 12.5, “Declarative transaction management” if you have not done so, to get a more detailed coverage of Spring's declarative transaction support. |
To execute service operations within transactions, you can use Spring's common declarative transaction facilities. For example:
<?xml version="1.0" encoding="UTF-8"?> <beans xmlns="http://www.springframework.org/schema/beans" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" xmlns:aop="http://www.springframework.org/schema/aop" xmlns:tx="http://www.springframework.org/schema/tx" xsi:schemaLocation=" http://www.springframework.org/schema/beans http://www.springframework.org/schema/beans/spring-beans.xsd http://www.springframework.org/schema/tx http://www.springframework.org/schema/tx/spring-tx.xsd http://www.springframework.org/schema/aop http://www.springframework.org/schema/aop/spring-aop.xsd"> <bean id="myTxManager" class="org.springframework.orm.jdo.JdoTransactionManager"> <property name="persistenceManagerFactory" ref="myPmf"/> </bean> <bean id="myProductService" class="product.ProductServiceImpl"> <property name="productDao" ref="myProductDao"/> </bean> <tx:advice id="txAdvice" transaction-manager="txManager"> <tx:attributes> <tx:method name="increasePrice*" propagation="REQUIRED"/> <tx:method name="someOtherBusinessMethod" propagation="REQUIRES_NEW"/> <tx:method name="*" propagation="SUPPORTS" read-only="true"/> </tx:attributes> </tx:advice> <aop:config> <aop:pointcut id="productServiceMethods" expression="execution(* product.ProductService.*(..))"/> <aop:advisor advice-ref="txAdvice" pointcut-ref="productServiceMethods"/> </aop:config> </beans>
JDO requires an active transaction to modify a persistent object.
The non-transactional flush concept does not exist in JDO, in contrast
to Hibernate. For this reason, you need to set up the chosen JDO
implementation for a specific environment. Specifically, you need to set
it up explicitly for JTA synchronization, to detect an active JTA
transaction itself. This is not necessary for local transactions as
performed by Spring's JdoTransactionManager
, but
it is necessary to participate in JTA transactions, whether driven by
Spring's JtaTransactionManager
or by EJB CMT and
plain JTA.
JdoTransactionManager
is capable of
exposing a JDO transaction to JDBC access code that accesses the same
JDBC DataSource
, provided that the
registered JdoDialect
supports retrieval of the
underlying JDBC Connection
. This is the
case for JDBC-based JDO 2.0 implementations by default.
As an advanced feature, both JdoTemplate
and JdoTransactionManager
support a custom
JdoDialect
that can be passed into the
jdoDialect
bean property. In this scenario, the DAOs will
not receive a PersistenceManagerFactory
reference but rather a full JdoTemplate
instance
(for example, passed into the jdoTemplate
property of JdoDaoSupport
). Using a
JdoDialect
implementation, you can enable
advanced features supported by Spring, usually in a vendor-specific
manner:
Applying specific transaction semantics such as custom isolation level or transaction timeout
Retrieving the transactional JDBC
Connection
for exposure to JDBC-based
DAOs
Applying query timeouts, which are automatically calculated from Spring-managed transaction timeouts
Eagerly flushing a
PersistenceManager,
to make
transactional changes visible to JDBC-based data access code
Advanced translation of JDOExceptions
to
Spring DataAccessExceptions
See the JdoDialect
Javadoc for more details
on its operations and how to use them within Spring's JDO
support.
The Spring JPA, available under the
org.springframework.orm.jpa
package, offers
comprehensive support for the Java
Persistence API in a similar manner to the integration with
Hibernate or JDO, while being aware of the underlying implementation in
order to provide additional features.
The Spring JPA support offers three ways of setting up the JPA
EntityManagerFactory
that will be used by
the application to obtain an entity manager.
Note | |
---|---|
Only use this option in simple deployment environments such as stand-alone applications and integration tests. |
The LocalEntityManagerFactoryBean
creates
an EntityManagerFactory
suitable for
simple deployment environments where the application uses only JPA for
data access. The factory bean uses the JPA
PersistenceProvider
autodetection
mechanism (according to JPA's Java SE bootstrapping) and, in most
cases, requires you to specify only the persistence unit name:
<beans> <bean id="myEmf" class="org.springframework.orm.jpa.LocalEntityManagerFactoryBean"> <property name="persistenceUnitName" value="myPersistenceUnit"/> </bean> </beans>
This form of JPA deployment is the simplest and the most
limited. You cannot refer to
an existing JDBC DataSource
bean
definition and no support for global transactions exists. Furthermore,
weaving (byte-code transformation) of persistent classes is
provider-specific, often requiring a specific JVM agent to specified
on startup. This option is sufficient only for stand-alone
applications and test environments, for which the JPA specification is
designed.
Note | |
---|---|
Use this option when deploying to a Java EE 5 server. Check your server's documentation on how to deploy a custom JPA provider into your server, allowing for a different provider than the server's default. |
Obtaining an EntityManagerFactory
from JNDI (for example in a Java EE 5 environment), is simply a matter
of changing the XML configuration:
<beans> <jee:jndi-lookup id="myEmf" jndi-name="persistence/myPersistenceUnit"/> </beans>
This action assumes standard Java EE 5 bootstrapping: the Java
EE server autodetects persistence units (in effect,
META-INF/persistence.xml
files in application jars)
and persistence-unit-ref
entries in the Java EE
deployment descriptor (for example, web.xml
) and
defines environment naming context locations for those persistence
units.
In such a scenario, the entire persistence unit deployment,
including the weaving (byte-code transformation) of persistent
classes, is up to the Java EE server. The JDBC
DataSource
is defined through a JNDI
location in the META-INF/persistence.xml
file;
EntityManager transactions are integrated with the server's JTA
subsystem. Spring merely uses the obtained
EntityManagerFactory
, passing it on to
application objects through dependency injection, and managing
transactions for the persistence unit,
typically through JtaTransactionManager
.
If multiple persistence units are used in the same application,
the bean names of such JNDI-retrieved persistence units should match
the persistence unit names that the application uses to refer to them,
for example, in @PersistenceUnit
and
@PersistenceContext
annotations.
Note | |
---|---|
Use this option for full JPA capabilities in a Spring-based application environment. This includes web containers such as Tomcat as well as stand-alone applications and integration tests with sophisticated persistence requirements. |
The
LocalContainerEntityManagerFactoryBean
gives
full control over EntityManagerFactory
configuration and is appropriate for environments where fine-grained
customization is required. The
LocalContainerEntityManagerFactoryBean
creates
a PersistenceUnitInfo
instance based
on the persistence.xml
file, the supplied
dataSourceLookup
strategy, and the specified
loadTimeWeaver
. It is thus possible to work with
custom data sources outside of JNDI and to control the weaving
process. The following example shows a typical bean definition for a
LocalContainerEntityManagerFactoryBean
:
<beans> <bean id="myEmf" class="org.springframework.orm.jpa.LocalContainerEntityManagerFactoryBean"> <property name="dataSource" ref="someDataSource"/> <property name="loadTimeWeaver"> <bean class="org.springframework.instrument.classloading.InstrumentationLoadTimeWeaver"/> </property> </bean> </beans>
The following example shows a typical
persistence.xml
file:
<persistence xmlns="http://java.sun.com/xml/ns/persistence" version="1.0"> <persistence-unit name="myUnit" transaction-type="RESOURCE_LOCAL"> <mapping-file>META-INF/orm.xml</mapping-file> <exclude-unlisted-classes/> </persistence-unit> </persistence>
Note | |
---|---|
The |
Using the
LocalContainerEntityManagerFactoryBean
is the
most powerful JPA setup option, allowing for flexible local
configuration within the application. It supports links to an existing
JDBC DataSource
, supports both local
and global transactions, and so on. However, it also imposes
requirements on the runtime environment, such as the availability of
a weaving-capable class loader if the persistence provider demands
byte-code transformation.
This option may conflict with the built-in JPA capabilities of a
Java EE 5 server. In a full Java EE 5 environment, consider obtaining
your EntityManagerFactory
from JNDI.
Alternatively, specify a custom
persistenceXmlLocation
on your
LocalContainerEntityManagerFactoryBean
definition, for example, META-INF/my-persistence.xml, and only include
a descriptor with that name in your application jar files. Because the
Java EE 5 server only looks for default
META-INF/persistence.xml
files, it ignores such
custom persistence units and hence avoid conflicts with a
Spring-driven JPA setup upfront. (This applies to Resin 3.1, for
example.)
The LoadTimeWeaver
interface is a
Spring-provided class that allows JPA
ClassTransformer
instances to be
plugged in a specific manner, depending whether the environment is a
web container or application server.
Hooking ClassTransformers
through a Java 5 agent
typically is not efficient. The agents work against the
entire virtual machine and inspect
every class that is loaded, which is usually
undesirable in a production server environment.
Spring provides a number of
LoadTimeWeaver
implementations for
various environments, allowing
ClassTransformer
instances to be
applied only per class loader and not per
VM.
Refer to the section called “Spring configuration” in the AOP chapter for more insight regarding the
LoadTimeWeaver
implementations and their setup, either generic or customized to
various platforms (such as Tomcat, WebLogic, OC4J, GlassFish, Resin and JBoss).
As described in the aforementioned section, you can configure a context-wide LoadTimeWeaver
using the @EnableLoadTimeWeaving
annotation of context:load-time-weaver
XML element.
Such a global weaver is picked up by all JPA LocalContainerEntityManagerFactoryBeans
automatically. This is the preferred way of setting up a load-time weaver, delivering autodetection of the platform
(WebLogic, OC4J, GlassFish, Tomcat, Resin, JBoss or VM agent) and automatic propagation of the weaver to all weaver-aware beans:
<context:load-time-weaver/> <bean id="emf" class="org.springframework.orm.jpa.LocalContainerEntityManagerFactoryBean"> ... </bean>
However, if needed, one can manually specify a dedicated weaver through the loadTimeWeaver
property:
<bean id="emf" class="org.springframework.orm.jpa.LocalContainerEntityManagerFactoryBean"> <property name="loadTimeWeaver"> <bean class="org.springframework.instrument.classloading.ReflectiveLoadTimeWeaver"/> </property> </bean>
No matter how the LTW is configured, using this technique, JPA applications relying on instrumentation can run in the target platform (ex: Tomcat) without needing an agent. This is important especially when the hosting applications rely on different JPA implementations because the JPA transformers are applied only at class loader level and thus are isolated from each other.
For applications that rely on multiple persistence units
locations, stored in various JARS in the classpath, for example,
Spring offers the
PersistenceUnitManager
to act as a
central repository and to avoid the persistence units discovery
process, which can be expensive. The default implementation allows
multiple locations to be specified that are parsed and later retrieved
through the persistence unit name. (By default, the classpath is
searched for META-INF/persistence.xml
files.)
<bean id="pum" class="org.springframework.orm.jpa.persistenceunit.DefaultPersistenceUnitManager"> <property name="persistenceXmlLocations"> <list> <value>org/springframework/orm/jpa/domain/persistence-multi.xml</value> <value>classpath:/my/package/**/custom-persistence.xml</value> <value>classpath*:META-INF/persistence.xml</value> </list> </property> <property name="dataSources"> <map> <entry key="localDataSource" value-ref="local-db"/> <entry key="remoteDataSource" value-ref="remote-db"/> </map> </property> <!-- if no datasource is specified, use this one --> <property name="defaultDataSource" ref="remoteDataSource"/> </bean> <bean id="emf" class="org.springframework.orm.jpa.LocalContainerEntityManagerFactoryBean"> <property name="persistenceUnitManager" ref="pum"/> <property name="persistenceUnitName" value="myCustomUnit"/> </bean>
The default implementation allows customization of the
PersistenceUnitInfo
instances,
before they are fed to the JPA provider, declaratively through its
properties,
which affect all hosted units, or
programmatically, through the
PersistenceUnitPostProcessor
, which
allows persistence unit selection. If no
PersistenceUnitManager
is specified,
one is created and used internally by
LocalContainerEntityManagerFactoryBean
.
Note | |
---|---|
Although |
It is possible to write code against the plain JPA without any
Spring dependencies, by using an injected
EntityManagerFactory
or
EntityManager
. Spring can understand
@PersistenceUnit
and
@PersistenceContext
annotations both at
field and method level if a
PersistenceAnnotationBeanPostProcessor
is
enabled. A plain JPA DAO implementation using the
@PersistenceUnit
annotation might
look like this:
public class ProductDaoImpl implements ProductDao { private EntityManagerFactory emf; @PersistenceUnit public void setEntityManagerFactory(EntityManagerFactory emf) { this.emf = emf; } public Collection loadProductsByCategory(String category) { EntityManager em = this.emf.createEntityManager(); try { Query query = em.createQuery("from Product as p where p.category = ?1"); query.setParameter(1, category); return query.getResultList(); } finally { if (em != null) { em.close(); } } } }
The DAO above has no dependency on Spring and still fits nicely
into a Spring application context. Moreover, the DAO takes advantage of
annotations to require the injection of the default
EntityManagerFactory
:
<beans> <!-- bean post-processor for JPA annotations --> <bean class="org.springframework.orm.jpa.support.PersistenceAnnotationBeanPostProcessor"/> <bean id="myProductDao" class="product.ProductDaoImpl"/> </beans>
As an alternative to defining a
PersistenceAnnotationBeanPostProcessor
explicitly, consider using the Spring
context:annotation-config
XML element in your
application context configuration. Doing so automatically registers all
Spring standard post-processors for annotation-based configuration,
including CommonAnnotationBeanPostProcessor
and
so on.
<beans> <!-- post-processors for all standard config annotations --> <context:annotation-config/> <bean id="myProductDao" class="product.ProductDaoImpl"/> </beans>
The main problem with such a DAO is that it always creates a new
EntityManager
through the factory. You
can avoid this by requesting a transactional
EntityManager
(also called "shared
EntityManager" because it is a shared, thread-safe proxy for the actual
transactional EntityManager) to be injected instead of the
factory:
public class ProductDaoImpl implements ProductDao { @PersistenceContext private EntityManager em; public Collection loadProductsByCategory(String category) { Query query = em.createQuery("from Product as p where p.category = :category"); query.setParameter("category", category); return query.getResultList(); } }
The @PersistenceContext
annotation has an
optional attribute type
, which defaults to
PersistenceContextType.TRANSACTION
. This default is
what you need to receive a shared EntityManager proxy. The alternative,
PersistenceContextType.EXTENDED
, is a completely
different affair: This results in a so-called extended EntityManager,
which is not thread-safe and hence must not be used
in a concurrently accessed component such as a Spring-managed singleton
bean. Extended EntityManagers are only supposed to be used in stateful
components that, for example, reside in a session, with the lifecycle of
the EntityManager not tied to a current transaction but rather being
completely up to the application.
The injected EntityManager
is
Spring-managed (aware of the ongoing transaction). It is important to
note that even though the new DAO implementation uses method level
injection of an EntityManager
instead of
an EntityManagerFactory
, no change is
required in the application context XML due to annotation usage.
The main advantage of this DAO style is that it only depends on Java Persistence API; no import of any Spring class is required. Moreover, as the JPA annotations are understood, the injections are applied automatically by the Spring container. This is appealing from a non-invasiveness perspective, and might feel more natural to JPA developers.
Note | |
---|---|
You are strongly encouraged to read Section 12.5, “Declarative transaction management” if you have not done so, to get a more detailed coverage of Spring's declarative transaction support. |
To execute service operations within transactions, you can use Spring's common declarative transaction facilities. For example:
<?xml version="1.0" encoding="UTF-8"?> <beans xmlns="http://www.springframework.org/schema/beans" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" xmlns:aop="http://www.springframework.org/schema/aop" xmlns:tx="http://www.springframework.org/schema/tx" xsi:schemaLocation=" http://www.springframework.org/schema/beans http://www.springframework.org/schema/beans/spring-beans.xsd http://www.springframework.org/schema/tx http://www.springframework.org/schema/tx/spring-tx.xsd http://www.springframework.org/schema/aop http://www.springframework.org/schema/aop/spring-aop.xsd"> <bean id="myTxManager" class="org.springframework.orm.jpa.JpaTransactionManager"> <property name="entityManagerFactory" ref="myEmf"/> </bean> <bean id="myProductService" class="product.ProductServiceImpl"> <property name="productDao" ref="myProductDao"/> </bean> <aop:config> <aop:pointcut id="productServiceMethods" expression="execution(* product.ProductService.*(..))"/> <aop:advisor advice-ref="txAdvice" pointcut-ref="productServiceMethods"/> </aop:config> <tx:advice id="txAdvice" transaction-manager="myTxManager"> <tx:attributes> <tx:method name="increasePrice*" propagation="REQUIRED"/> <tx:method name="someOtherBusinessMethod" propagation="REQUIRES_NEW"/> <tx:method name="*" propagation="SUPPORTS" read-only="true"/> </tx:attributes> </tx:advice> </beans>
Spring JPA allows a configured
JpaTransactionManager
to expose a JPA transaction
to JDBC access code that accesses the same JDBC
DataSource
, provided that the registered
JpaDialect
supports retrieval of the
underlying JDBC Connection
. Out of the
box, Spring provides dialects for the Toplink, Hibernate and OpenJPA JPA
implementations. See the next section for details on the
JpaDialect
mechanism.
As an advanced feature JpaTemplate
,
JpaTransactionManager
and subclasses of
AbstractEntityManagerFactoryBean
support a custom
JpaDialect
, to be passed into the
jpaDialect bean property. In such a scenario, the
DAOs do not receive an
EntityManagerFactory
reference but rather
a full JpaTemplate
instance (for example,
passed
into the jpaTemplate property of
JpaDaoSupport
). A JpaDialect
implementation can enable some advanced features supported by Spring,
usually in a vendor-specific manner:
Applying specific transaction semantics such as custom isolation level or transaction timeout)
Retrieving the transactional JDBC
Connection
for exposure to JDBC-based
DAOs)
Advanced translation of
PersistenceExceptions
to Spring
DataAccessExceptions
This is particularly valuable for special transaction semantics
and for advanced translation of exception. The default implementation
used (DefaultJpaDialect
) does not provide any
special capabilities and if the above features are required, you have to
specify the appropriate dialect.
See the JpaDialect
Javadoc for more
details of its operations and how they are used within Spring's JPA
support.
The iBATIS support in the Spring Framework much resembles the JDBC support in that it supports the same template style programming, and as with JDBC and other ORM technologies, the iBATIS support works with Spring's exception hierarchy and lets you enjoy Spring's IoC features.
Transaction management can be handled through Spring's standard
facilities. No special transaction strategies are necessary for iBATIS,
because no special transactional resource involved other than a JDBC
Connection
. Hence, Spring's standard JDBC
DataSourceTransactionManager
or
JtaTransactionManager
are perfectly
sufficient.
Note | |
---|---|
Spring supports iBATIS 2.x. The iBATIS 1.x support classes are no longer provided. |
Using iBATIS SQL Maps involves creating SqlMap configuration files
containing statements and result maps. Spring takes care of loading
those using the SqlMapClientFactoryBean
. For the
examples we will be using the following Account
class:
public class Account { private String name; private String email; public String getName() { return this.name; } public void setName(String name) { this.name = name; } public String getEmail() { return this.email; } public void setEmail(String email) { this.email = email; } }
To map this Account
class with iBATIS 2.x we
need to create the following SQL map
Account.xml
:
<sqlMap namespace="Account"> <resultMap id="result" class="examples.Account"> <result property="name" column="NAME" columnIndex="1"/> <result property="email" column="EMAIL" columnIndex="2"/> </resultMap> <select id="getAccountByEmail" resultMap="result"> select ACCOUNT.NAME, ACCOUNT.EMAIL from ACCOUNT where ACCOUNT.EMAIL = #value# </select> <insert id="insertAccount"> insert into ACCOUNT (NAME, EMAIL) values (#name#, #email#) </insert> </sqlMap>
The configuration file for iBATIS 2 looks like this:
<sqlMapConfig> <sqlMap resource="example/Account.xml"/> </sqlMapConfig>
Remember that iBATIS loads resources from the class path, so be
sure to add theAccount.xml
file to the class
path.
We can use the SqlMapClientFactoryBean
in
the Spring container. Note that with iBATIS SQL Maps 2.x, the JDBC
DataSource
is usually specified on the
SqlMapClientFactoryBean
, which enables lazy
loading. This is the configuration needed for these bean
definitions:
<beans> <bean id="dataSource" class="org.apache.commons.dbcp.BasicDataSource" destroy-method="close"> <property name="driverClassName" value="${jdbc.driverClassName}"/> <property name="url" value="${jdbc.url}"/> <property name="username" value="${jdbc.username}"/> <property name="password" value="${jdbc.password}"/> </bean> <bean id="sqlMapClient" class="org.springframework.orm.ibatis.SqlMapClientFactoryBean"> <property name="configLocation" value="WEB-INF/sqlmap-config.xml"/> <property name="dataSource" ref="dataSource"/> </bean> </beans>
The SqlMapClientDaoSupport
class offers a
supporting class similar to the SqlMapDaoSupport
.
We extend it to implement our DAO:
public class SqlMapAccountDao extends SqlMapClientDaoSupport implements AccountDao { public Account getAccount(String email) throws DataAccessException { return (Account) getSqlMapClientTemplate().queryForObject("getAccountByEmail", email); } public void insertAccount(Account account) throws DataAccessException { getSqlMapClientTemplate().update("insertAccount", account); } }
In the DAO, we use the pre-configured
SqlMapClientTemplate
to execute the queries,
after setting up the SqlMapAccountDao
in the
application context and wiring it with our
SqlMapClient
instance:
<beans> <bean id="accountDao" class="example.SqlMapAccountDao"> <property name="sqlMapClient" ref="sqlMapClient"/> </bean> </beans>
An SqlMapTemplate
instance can also be
created manually, passing in the SqlMapClient
as
constructor argument. The SqlMapClientDaoSupport
base
class simply preinitializes a
SqlMapClientTemplate
instance for us.
The SqlMapClientTemplate
offers a generic
execute
method, taking a custom
SqlMapClientCallback
implementation as argument. This
can, for example, be used for batching:
public class SqlMapAccountDao extends SqlMapClientDaoSupport implements AccountDao { public void insertAccount(Account account) throws DataAccessException { getSqlMapClientTemplate().execute(new SqlMapClientCallback() { public Object doInSqlMapClient(SqlMapExecutor executor) throws SQLException { executor.startBatch(); executor.update("insertAccount", account); executor.update("insertAddress", account.getAddress()); executor.executeBatch(); } }); } }
In general, any combination of operations offered by the native
SqlMapExecutor
API can be used in such a callback.
Any thrown SQLException
is converted automatically to
Spring's generic DataAccessException
hierarchy.
DAOs can also be written against plain iBATIS API, without any
Spring dependencies, directly using an injected
SqlMapClient
. The following example shows a
corresponding DAO implementation:
public class SqlMapAccountDao implements AccountDao { private SqlMapClient sqlMapClient; public void setSqlMapClient(SqlMapClient sqlMapClient) { this.sqlMapClient = sqlMapClient; } public Account getAccount(String email) { try { return (Account) this.sqlMapClient.queryForObject("getAccountByEmail", email); } catch (SQLException ex) { throw new MyDaoException(ex); } } public void insertAccount(Account account) throws DataAccessException { try { this.sqlMapClient.update("insertAccount", account); } catch (SQLException ex) { throw new MyDaoException(ex); } } }
In this scenario, you need to handle the
SQLException
thrown by the iBATIS API in a custom
fashion, usually by wrapping it in your own application-specific DAO
exception. Wiring in the application context would still look like it
does in the example for the
SqlMapClientDaoSupport
,
due to the fact that the plain iBATIS-based DAO still follows the
dependency injection pattern:
<beans> <bean id="accountDao" class="example.SqlMapAccountDao"> <property name="sqlMapClient" ref="sqlMapClient"/> </bean> </beans>