Comprehensive transaction support is among the most compelling reasons to use the Spring Framework. The Spring Framework provides a consistent abstraction for transaction management that delivers the following benefits:
Consistent programming model across different transaction APIs such as Java Transaction API (JTA), JDBC, Hibernate, Java Persistence API (JPA), and Java Data Objects (JDO).
Support for declarative transaction management.
Simpler API for programmatic transaction management than complex transaction APIs such as JTA.
Excellent integration with Spring's data access abstractions.
The following sections describe the Spring Framework's transaction value-adds and technologies. (The chapter also includes discussions of best practices, application server integration, and solutions to common problems.)
Advantages of the Spring Framework's transaction support model describes why you would use the Spring Framework's transaction abstraction instead of EJB Container-Managed Transactions (CMT) or choosing to drive local transactions through a proprietary API such as Hibernate.
Understanding the Spring
Framework transaction abstraction outlines the core classes and
describes how to configure and obtain
DataSource
instances from a variety of
sources.
Synchronizing resources with transactions describes how the application code ensures that resources are created, reused, and cleaned up properly.
Declarative transaction management describes support for declarative transaction management.
Programmatic transaction management covers support for programmatic (that is, explicitly coded) transaction management.
Traditionally, Java EE developers have had two choices for transaction management: global or local transactions, both of which have profound limitations. Global and local transaction management is reviewed in the next two sections, followed by a discussion of how the Spring Framework's transaction management support addresses the limitations of the global and local transaction models.
Global transactions enable you to work with multiple transactional
resources, typically relational databases and message queues. The
application server manages global transactions through the JTA, which is
a cumbersome API to use (partly due to its exception model).
Furthermore, a JTA UserTransaction
normally needs to be sourced from JNDI, meaning that you
also need to use JNDI in order to use JTA.
Obviously the use of global transactions would limit any potential reuse
of application code, as JTA is normally only available in an application
server environment.
Previously, the preferred way to use global transactions was via EJB CMT (Container Managed Transaction): CMT is a form of declarative transaction management (as distinguished from programmatic transaction management). EJB CMT removes the need for transaction-related JNDI lookups, although of course the use of EJB itself necessitates the use of JNDI. It removes most but not all of the need to write Java code to control transactions. The significant downside is that CMT is tied to JTA and an application server environment. Also, it is only available if one chooses to implement business logic in EJBs, or at least behind a transactional EJB facade. The negatives of EJB in general are so great that this is not an attractive proposition, especially in the face of compelling alternatives for declarative transaction management.
Local transactions are resource-specific, such as a transaction associated with a JDBC connection. Local transactions may be easier to use, but have significant disadvantages: they cannot work across multiple transactional resources. For example, code that manages transactions using a JDBC connection cannot run within a global JTA transaction. Because the application server is not involved in transaction management, it cannot help ensure correctness across multiple resources. (It is worth noting that most applications use a single transaction resource.) Another downside is that local transactions are invasive to the programming model.
Spring resolves the disadvantages of global and local transactions. It enables application developers to use a consistent programming model in any environment. You write your code once, and it can benefit from different transaction management strategies in different environments. The Spring Framework provides both declarative and programmatic transaction management. Most users prefer declarative transaction management, which is recommended in most cases.
With programmatic transaction management, developers work with the Spring Framework transaction abstraction, which can run over any underlying transaction infrastructure. With the preferred declarative model, developers typically write little or no code related to transaction management, and hence do not depend on the Spring Framework transaction API, or any other transaction API.
The key to the Spring transaction abstraction is the notion of a
transaction strategy. A transaction strategy is
defined by the
org.springframework.transaction.PlatformTransactionManager
interface:
public interface PlatformTransactionManager { TransactionStatus getTransaction(TransactionDefinition definition) throws TransactionException; void commit(TransactionStatus status) throws TransactionException; void rollback(TransactionStatus status) throws TransactionException; }
This is primarily a service provider interface (SPI), although it
can be used programmatically from your
application code. Because
PlatformTransactionManager
is an
interface, it can be easily mocked or stubbed as
necessary. It is not tied to a lookup strategy such as JNDI.
PlatformTransactionManager
implementations
are defined like any other object (or bean) in the Spring Framework IoC
container. This benefit alone makes Spring Framework transactions a
worthwhile abstraction even when you work with JTA. Transactional code can
be tested much more easily than if it used JTA directly.
Again in keeping with Spring's philosophy, the
TransactionException
that can be thrown by
any of the PlatformTransactionManager
interface's methods is unchecked (that is, it extends
the java.lang.RuntimeException
class).
Transaction infrastructure failures are almost invariably fatal. In rare
cases where application code can actually recover from a transaction
failure, the application developer can still choose to catch and handle
TransactionException
. The salient point is
that developers are not forced to do so.
The getTransaction(..)
method returns a
TransactionStatus
object, depending on a
TransactionDefinition
parameter. The
returned TransactionStatus
might represent
a new transaction, or can represent an existing transaction if a matching
transaction exists in the current call stack. The implication in this
latter case is that, as with Java EE transaction contexts, a
TransactionStatus
is associated with a
thread of execution.
The TransactionDefinition
interface
specifies:
Isolation: The degree to which this transaction is isolated from the work of other transactions. For example, can this transaction see uncommitted writes from other transactions?
Propagation: Typically, all code executed within a transaction scope will run in that transaction. However, you have the option of specifying the behavior in the event that a transactional method is executed when a transaction context already exists. For example, code can continue running in the existing transaction (the common case); or the existing transaction can be suspended and a new transaction created. Spring offers all of the transaction propagation options familiar from EJB CMT. To read about the semantics of transaction propagation in Spring, see Section 10.5.7, “Transaction propagation”.
Timeout: How long this transaction runs before timing out and being rolled back automatically by the underlying transaction infrastructure.
Read-only status: A read-only transaction can be used when your code reads but does not modify data. Read-only transactions can be a useful optimization in some cases, such as when you are using Hibernate.
These settings reflect standard transactional concepts. If necessary, refer to resources that discuss transaction isolation levels and other core transaction concepts. Understanding these concepts is essential to using the Spring Framework or any transaction management solution.
The TransactionStatus
interface
provides a simple way for transactional code to control transaction
execution and query transaction status. The concepts should be familiar,
as they are common to all transaction APIs:
public interface TransactionStatus extends SavepointManager { boolean isNewTransaction(); boolean hasSavepoint(); void setRollbackOnly(); boolean isRollbackOnly(); void flush(); boolean isCompleted(); }
Regardless of whether you opt for declarative or programmatic
transaction management in Spring, defining the correct
PlatformTransactionManager
implementation
is absolutely essential. You typically define this implementation through
dependency injection.
PlatformTransactionManager
implementations normally require knowledge of the environment in which
they work: JDBC, JTA, Hibernate, and so on. The following examples show
how you can define a local
PlatformTransactionManager
implementation.
(This example works with plain JDBC.)
You define a JDBC DataSource
<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>
The related The
PlatformTransactionManager
bean definition will then have
a reference to the DataSource
definition.
It will look like this:
<bean id="txManager" class="org.springframework.jdbc.datasource.DataSourceTransactionManager"> <property name="dataSource" ref="dataSource"/> </bean>
If you use JTA in a Java EE container then you use a container
DataSource
, obtained through JNDI, in
conjunction with Spring's JtaTransactionManager
.
This is what the JTA and JNDI lookup version would look like:
<?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:jee="http://www.springframework.org/schema/jee" xsi:schemaLocation=" http://www.springframework.org/schema/beans http://www.springframework.org/schema/beans/spring-beans-3.0.xsd http://www.springframework.org/schema/jee http://www.springframework.org/schema/jee/spring-jee-3.0.xsd"> <jee:jndi-lookup id="dataSource" jndi-name="jdbc/jpetstore"/> <bean id="txManager" class="org.springframework.transaction.jta.JtaTransactionManager" /> <!-- other <bean/> definitions here --> </beans>
The JtaTransactionManager
does not need to
know about the DataSource
, or any other
specific resources, because it uses the container's global transaction
management infrastructure.
Note | |
---|---|
The above definition of the |
You can also use Hibernate local transactions easily, as shown in
the following examples. In this case, you need to define a Hibernate
LocalSessionFactoryBean
, which your application
code will use to obtain Hibernate Session
instances.
The DataSource
bean definition will
be similar to the local JDBC example shown previously and thus is not
shown in the following example.
Note | |
---|---|
If the |
The txManager
bean in this case is of the
HibernateTransactionManager
type. In the same way
as the DataSourceTransactionManager
needs a
reference to the DataSource
, the
HibernateTransactionManager
needs a reference to
the SessionFactory
.
<bean id="sessionFactory" class="org.springframework.orm.hibernate3.LocalSessionFactoryBean"> <property name="dataSource" ref="dataSource" /> <property name="mappingResources"> <list> <value>org/springframework/samples/petclinic/hibernate/petclinic.hbm.xml</value> </list> </property> <property name="hibernateProperties"> <value> hibernate.dialect=${hibernate.dialect} </value> </property> </bean> <bean id="txManager" class="org.springframework.orm.hibernate3.HibernateTransactionManager"> <property name="sessionFactory" ref="sessionFactory" /> </bean>
If you are using Hibernate and Java EE container-managed JTA
transactions, then you should simply use the same
JtaTransactionManager
as in the previous JTA
example for JDBC.
<bean id="txManager" class="org.springframework.transaction.jta.JtaTransactionManager"/>
Note | |
---|---|
If you use JTA , then your transaction manager definition will look the same regardless of what data access technology you use, be it JDBC, Hibernate JPA or any other supported technology. This is due to the fact that JTA transactions are global transactions, which can enlist any transactional resource. |
In all these cases, application code does not need to change. You can change how transactions are managed merely by changing configuration, even if that change means moving from local to global transactions or vice versa.
It should now be clear how you create different transaction
managers, and how they are linked to related resources that need to be
synchronized to transactions (for example
DataSourceTransactionManager
to a JDBC
DataSource
,
HibernateTransactionManager
to a Hibernate
SessionFactory
, and so forth). This section
describes how the application code, directly or indirectly using a
persistence API such as JDBC, Hibernate, or JDO, ensures that these
resources are created, reused, and cleaned up properly. The section also
discusses how transaction synchronization is triggered (optionally)
through the relevant
PlatformTransactionManager
.
The preferred approach is to use Spring's highest level template
based persistence integration APIs or to use native ORM APIs with
transaction- aware factory beans or proxies for managing the native
resource factories. These transaction-aware solutions internally handle
resource creation and reuse, cleanup, optional transaction
synchronization of the resources, and exception mapping. Thus user data
access code does not have to address these tasks, but can be focused
purely on non-boilerplate persistence logic. Generally, you use the
native ORM API or take a template approach for JDBC
access by using the JdbcTemplate
. These solutions
are detailed in subsequent chapters of this reference documentation.
Classes such as DataSourceUtils
(for JDBC),
EntityManagerFactoryUtils
(for JPA),
SessionFactoryUtils
(for Hibernate),
PersistenceManagerFactoryUtils
(for JDO), and so
on exist at a lower level. When you want the application code to deal
directly with the resource types of the native persistence APIs, you use
these classes to ensure that proper Spring Framework-managed instances
are obtained, transactions are (optionally) synchronized, and exceptions
that occur in the process are properly mapped to a consistent
API.
For example, in the case of JDBC, instead of the traditional JDBC
approach of calling the getConnection()
method on the
DataSource
, you instead use Spring's
org.springframework.jdbc.datasource.DataSourceUtils
class as follows:
Connection conn = DataSourceUtils.getConnection(dataSource);
If an existing transaction already has a connection synchronized
(linked) to it, that instance is returned. Otherwise, the method call
triggers the creation of a new connection, which is (optionally)
synchronized to any existing transaction, and made available for
subsequent reuse in that same transaction. As mentioned, any
SQLException
is wrapped in a Spring
Framework
CannotGetJdbcConnectionException
, one of
the Spring Framework's hierarchy of unchecked DataAccessExceptions. This
approach gives you more information than can be obtained easily from the
SQLException
, and ensures portability
across databases, even across different persistence technologies.
This approach also works without Spring transaction management (transaction synchronization is optional), so you can use it whether or not you are using Spring for transaction management.
Of course, once you have used Spring's JDBC support, JPA support
or Hibernate support, you will generally prefer not to use
DataSourceUtils
or the other helper classes,
because you will be much happier working through the Spring abstraction
than directly with the relevant APIs. For example, if you use the Spring
JdbcTemplate
or jdbc.object
package to simplify your use of JDBC, correct connection retrieval
occurs behind the scenes and you won't need to write any special
code.
At the very lowest level exists the
TransactionAwareDataSourceProxy
class. This is a
proxy for a target DataSource
, which
wraps the target DataSource
to add
awareness of Spring-managed transactions. In this respect, it is similar
to a transactional JNDI DataSource
as
provided by a Java EE server.
It should almost never be necessary or desirable to use this
class, except when existing code must be called and passed a standard
JDBC DataSource
interface implementation.
In that case, it is possible that this code is usable, but participating
in Spring managed transactions. It is preferable to write your new code
by using the higher level abstractions mentioned above.
Note | |
---|---|
Most Spring Framework users choose declarative transaction management. This option has the least impact on application code, and hence is most consistent with the ideals of a non-invasive lightweight container. |
The Spring Framework's declarative transaction management is made possible with Spring aspect-oriented programming (AOP), although, as the transactional aspects code comes with the Spring Framework distribution and may be used in a boilerplate fashion, AOP concepts do not generally have to be understood to make effective use of this code.
The Spring Framework's declarative transaction management is similar
to EJB CMT in that you can specify transaction behavior (or lack of it)
down to individual method level. It is possible to make a
setRollbackOnly()
call within a transaction
context if necessary. The differences between the two types of transaction
management are:
Unlike EJB CMT, which is tied to JTA, the Spring Framework's declarative transaction management works in any environment. It can work with JTA transactions or local transactions using JDBC, JPA, Hibernate or JDO by simply adjusting the configuration files.
You can apply the Spring Framework declarative transaction management to any class, not merely special classes such as EJBs.
The Spring Framework offers declarative rollback rules, a feature with no EJB equivalent. Both programmatic and declarative support for rollback rules is provided.
The Spring Framework enables you to customize transactional
behavior, by using AOP. For example, you can insert custom behavior in
the case of transaction rollback. You can also add arbitrary advice,
along with the transactional advice. With EJB CMT, cannot influence
the container's transaction management except with
setRollbackOnly()
.
The Spring Framework does not support propagation of transaction contexts across remote calls, as do high-end application servers. If you need this feature, we recommend that you use EJB. However, consider carefully before using such a feature, because normally, one does not want transactions to span remote calls.
The concept of rollback rules is important: they enable you to
specify which exceptions (and throwables) should
cause automatic rollback. You specify this declaratively, in
configuration, not in Java code. So, although you can still call
setRollbackOnly()
on the
TransactionStatus
object to roll back the
current transaction back, most often you can specify a rule that
MyApplicationException
must always result
in rollback. The significant advantage to this option is that business
objects do not depend on the transaction infrastructure. For example, they
typically do not need to import Spring transaction APIs or other Spring
APIs.
Although EJB container default behavior automatically rolls back the
transaction on a system exception (usually a runtime
exception), EJB CMT does not roll back the transaction automatically on an
application exception (that is, a checked exception
other than java.rmi.RemoteException
). While
the Spring default behavior for declarative transaction management follows
EJB convention (roll back is automatic only on unchecked exceptions), it
is often useful to customize this behavior.
It is not sufficient to tell you simply to annotate your classes
with the @Transactional
annotation, add
the line (<tx:annotation-driven/>
) to your
configuration, and then expect you to understand how it all works. This
section explains the inner workings of the Spring Framework's
declarative transaction infrastructure in the event of
transaction-related issues.
The most important concepts to grasp with regard to the Spring
Framework's declarative transaction support are that this support is
enabled via AOP
proxies, and that the transactional advice is driven
by metadata (currently XML- or annotation-based).
The combination of AOP with transactional metadata yields an AOP proxy
that uses a TransactionInterceptor
in conjunction
with an appropriate PlatformTransactionManager
implementation to drive transactions around method
invocations.
Note | |
---|---|
Spring AOP is covered in Chapter 7, Aspect Oriented Programming with Spring. |
Conceptually, calling a method on a transactional proxy looks like this...
Consider the following interface, and its attendant
implementation. This example uses the rote Foo
and Bar
tropes so that you can concentrate on the
transaction usage without focusing on the domain model. For the purposes
of this example, the fact that the
DefaultFooService
class throws
UnsupportedOperationException
instances
in the body of each implemented method is good; it allows you to see
transactions created and then rolled back in response to the
UnsupportedOperationException
instance.
// the service interface that we want to make transactional package x.y.service; public interface FooService { Foo getFoo(String fooName); Foo getFoo(String fooName, String barName); void insertFoo(Foo foo); void updateFoo(Foo foo); }
// an implementation of the above interface package x.y.service; public class DefaultFooService implements FooService { public Foo getFoo(String fooName) { throw new UnsupportedOperationException(); } public Foo getFoo(String fooName, String barName) { throw new UnsupportedOperationException(); } public void insertFoo(Foo foo) { throw new UnsupportedOperationException(); } public void updateFoo(Foo foo) { throw new UnsupportedOperationException(); } }
Assume that the first two methods of the
FooService
interface,
getFoo(String)
and getFoo(String, String),
must execute in the context of a transaction with read-only
semantics, and that the other methods,insertFoo(Foo)
and updateFoo(Foo),
must execute in the context of a
transaction with read-write semantics. The following configuration is
explained in detail in the next few paragraphs.
<!-- from the file 'context.xml' --> <?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-3.0.xsd http://www.springframework.org/schema/tx http://www.springframework.org/schema/tx/spring-tx-3.0.xsd http://www.springframework.org/schema/aop http://www.springframework.org/schema/aop/spring-aop-3.0.xsd"> <!-- this is the service object that we want to make transactional --> <bean id="fooService" class="x.y.service.DefaultFooService"/> <!-- the transactional advice (what 'happens'; see the <aop:advisor/> bean below) --> <tx:advice id="txAdvice" transaction-manager="txManager"> <!-- the transactional semantics... --> <tx:attributes> <!-- all methods starting with 'get' are read-only --> <tx:method name="get*" read-only="true"/> <!-- other methods use the default transaction settings (see below) --> <tx:method name="*"/> </tx:attributes> </tx:advice> <!-- ensure that the above transactional advice runs for any execution of an operation defined by the FooService interface --> <aop:config> <aop:pointcut id="fooServiceOperation" expression="execution(* x.y.service.FooService.*(..))"/> <aop:advisor advice-ref="txAdvice" pointcut-ref="fooServiceOperation"/> </aop:config> <!-- don't forget the DataSource --> <bean id="dataSource" class="org.apache.commons.dbcp.BasicDataSource" destroy-method="close"> <property name="driverClassName" value="oracle.jdbc.driver.OracleDriver"/> <property name="url" value="jdbc:oracle:thin:@rj-t42:1521:elvis"/> <property name="username" value="scott"/> <property name="password" value="tiger"/> </bean> <!-- similarly, don't forget the PlatformTransactionManager --> <bean id="txManager" class="org.springframework.jdbc.datasource.DataSourceTransactionManager"> <property name="dataSource" ref="dataSource"/> </bean> <!-- other <bean/> definitions here --> </beans>
Examine the preceding configuration. You want to make a service
object, the fooService
bean, transactional. The
transaction semantics to apply are encapsulated in the
<tx:advice/>
definition. The
<tx:advice/>
definition reads as
“... all methods on starting with
'get'
are to execute in the context of a read-only
transaction, and all other methods are to execute with the default
transaction semantics”. The
transaction-manager
attribute of the
<tx:advice/>
tag is set to the name of the
PlatformTransactionManager
bean that is
going to drive the transactions, in this case, the
txManager
bean.
Tip | |
---|---|
You can omit the |
The <aop:config/>
definition ensures that
the transactional advice defined by the txAdvice
bean
executes at the appropriate points in the program. First you define a
pointcut that matches the execution of any operation defined in the
FooService
interface
(fooServiceOperation
). Then you associate the
pointcut with the txAdvice
using an advisor. The
result indicates that at the execution of a
fooServiceOperation
, the advice defined by
txAdvice
will be run.
The expression defined within the
<aop:pointcut/>
element is an AspectJ pointcut
expression; see Chapter 7, Aspect Oriented Programming with Spring for more details on pointcut
expressions in Spring 2.0.
A common requirement is to make an entire service layer transactional. The best way to do this is simply to change the pointcut expression to match any operation in your service layer. For example:
<aop:config> <aop:pointcut id="fooServiceMethods" expression="execution(* x.y.service.*.*(..))"/> <aop:advisor advice-ref="txAdvice" pointcut-ref="fooServiceMethods"/> </aop:config>
Note | |
---|---|
In this example it is assumed that all your service
interfaces are defined in the |
Now that we've analyzed the configuration, you may be asking yourself, “Okay... but what does all this configuration actually do?”.
The above configuration will be used to create a transactional
proxy around the object that is created from the
fooService
bean definition. The
proxy will be configured with the transactional advice, so that when an
appropriate method is invoked on the proxy, a
transaction is started, suspended, marked as read-only, and so on,
depending on the transaction configuration associated with that method.
Consider the following program that test drives the above
configuration:
public final class Boot { public static void main(final String[] args) throws Exception { ApplicationContext ctx = new ClassPathXmlApplicationContext("context.xml", Boot.class); FooService fooService = (FooService) ctx.getBean("fooService"); fooService.insertFoo (new Foo()); } }
The output from running the preceding program will resemble the following. (The Log4J output and the stack trace from the UnsupportedOperationException thrown by the insertFoo(..) method of the DefaultFooService class have been truncated for clarity.)
<!-- the Spring container is starting up... --> [AspectJInvocationContextExposingAdvisorAutoProxyCreator] - Creating implicit proxy for bean 'fooService' with 0 common interceptors and 1 specific interceptors <!-- the DefaultFooService is actually proxied --> [JdkDynamicAopProxy] - Creating JDK dynamic proxy for [x.y.service.DefaultFooService] <!-- ... the insertFoo(..) method is now being invoked on the proxy --> [TransactionInterceptor] - Getting transaction for x.y.service.FooService.insertFoo <!-- the transactional advice kicks in here... --> [DataSourceTransactionManager] - Creating new transaction with name [x.y.service.FooService.insertFoo] [DataSourceTransactionManager] - Acquired Connection [org.apache.commons.dbcp.PoolableConnection@a53de4] for JDBC transaction <!-- the insertFoo(..) method from DefaultFooService throws an exception... --> [RuleBasedTransactionAttribute] - Applying rules to determine whether transaction should rollback on java.lang.UnsupportedOperationException [TransactionInterceptor] - Invoking rollback for transaction on x.y.service.FooService.insertFoo due to throwable [java.lang.UnsupportedOperationException] <!-- and the transaction is rolled back (by default, RuntimeException instances cause rollback) --> [DataSourceTransactionManager] - Rolling back JDBC transaction on Connection [org.apache.commons.dbcp.PoolableConnection@a53de4] [DataSourceTransactionManager] - Releasing JDBC Connection after transaction [DataSourceUtils] - Returning JDBC Connection to DataSource Exception in thread "main" java.lang.UnsupportedOperationException at x.y.service.DefaultFooService.insertFoo(DefaultFooService.java:14) <!-- AOP infrastructure stack trace elements removed for clarity --> at $Proxy0.insertFoo(Unknown Source) at Boot.main(Boot.java:11)
The previous section outlined the basics of how to specify transactional settings for classes, typically service layer classes, declaratively in your application. This section describes how you can control the rollback of transactions in a simple declarative fashion.
The recommended way to indicate to the Spring Framework's
transaction infrastructure that a transaction's work is to be rolled
back is to throw an Exception
from code
that is currently executing in the context of a transaction. The Spring
Framework's transaction infrastructure code will catch any unhandled
Exception
as it bubbles up the call
stack, and make a determination whether to mark the transaction for
rollback.
In its default configuration, the Spring Framework's transaction
infrastructure code only marks a transaction for
rollback in the case of runtime, unchecked exceptions; that is, when the
thrown exception is an instance or subclass of
RuntimeException
.
(Error
s will also - by default - result
in a rollback). Checked exceptions that are thrown from a transactional
method do not result in rollback in the default
configuration.
You can configure exactly which
Exception
types mark a transaction for
rollback, including checked exceptions. The following XML snippet
demonstrates how you configure rollback for a checked,
application-specific Exception
type.
<tx:advice id="txAdvice" transaction-manager="txManager"> <tx:attributes> <tx:method name="get*" read-only="true" rollback-for="NoProductInStockException"/> <tx:method name="*"/> </tx:attributes> </tx:advice>
You can also specify 'no rollback rules', if you do
not want a transaction rolled back when an
exception is thrown. The following example tells the Spring Framework's
transaction infrastructure to commit the attendant transaction even in
the face of an unhandled
InstrumentNotFoundException
.
<tx:advice id="txAdvice"> <tx:attributes> <tx:method name="updateStock" no-rollback-for="InstrumentNotFoundException"/> <tx:method name="*"/> </tx:attributes> </tx:advice>
When the Spring Framework's transaction infrastructure catches an
exception and is consults configured rollback rules to determine whether
to mark the transaction for rollback, the strongest
matching rule wins. So in the case of the following configuration, any
exception other than an
InstrumentNotFoundException
results in a
rollback of the attendant transaction.
<tx:advice id="txAdvice"> <tx:attributes> <tx:method name="*" rollback-for="Throwable" no-rollback-for="InstrumentNotFoundException"/> </tx:attributes> </tx:advice>
You can also indicate a required rollback programmatically. Although very simple, this process is quite invasive, and tightly couples your code to the Spring Framework's transaction infrastructure:
public void resolvePosition() { try { // some business logic... } catch (NoProductInStockException ex) { // trigger rollback programmatically TransactionAspectSupport.currentTransactionStatus().setRollbackOnly(); } }
You are strongly encouraged to use the declarative approach to rollback if at all possible. Programmatic rollback is available should you absolutely need it, but its usage flies in the face of achieving a clean POJO-based architecture.
Consider the scenario where you have a number of service layer
objects, and you want to apply a totally different
transactional configuration to each of them. You do this by defining
distinct <aop:advisor/>
elements with differing
pointcut
and advice-ref
attribute
values.
As a point of comparison, first assume that all of your service
layer classes are defined in a root x.y.service
package. To make all beans that are instances of classes defined in that
package (or in subpackages) and that have names ending in
Service
have the default transactional configuration,
you would write the following:
<?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-3.0.xsd http://www.springframework.org/schema/tx http://www.springframework.org/schema/tx/spring-tx-3.0.xsd http://www.springframework.org/schema/aop http://www.springframework.org/schema/aop/spring-aop-3.0.xsd"> <aop:config> <aop:pointcut id="serviceOperation" expression="execution(* x.y.service..*Service.*(..))"/> <aop:advisor pointcut-ref="serviceOperation" advice-ref="txAdvice"/> </aop:config> <!-- these two beans will be transactional... --> <bean id="fooService" class="x.y.service.DefaultFooService"/> <bean id="barService" class="x.y.service.extras.SimpleBarService"/> <!-- ... and these two beans won't --> <bean id="anotherService" class="org.xyz.SomeService"/> <!-- (not in the right package) --> <bean id="barManager" class="x.y.service.SimpleBarManager"/> <!-- (doesn't end in 'Service') --> <tx:advice id="txAdvice"> <tx:attributes> <tx:method name="get*" read-only="true"/> <tx:method name="*"/> </tx:attributes> </tx:advice> <!-- other transaction infrastructure beans such as a PlatformTransactionManager omitted... --> </beans>
The following example shows how to configure two distinct beans with totally different transactional settings.
<?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-3.0.xsd http://www.springframework.org/schema/tx http://www.springframework.org/schema/tx/spring-tx-3.0.xsd http://www.springframework.org/schema/aop http://www.springframework.org/schema/aop/spring-aop-3.0.xsd"> <aop:config> <aop:pointcut id="defaultServiceOperation" expression="execution(* x.y.service.*Service.*(..))"/> <aop:pointcut id="noTxServiceOperation" expression="execution(* x.y.service.ddl.DefaultDdlManager.*(..))"/> <aop:advisor pointcut-ref="defaultServiceOperation" advice-ref="defaultTxAdvice"/> <aop:advisor pointcut-ref="noTxServiceOperation" advice-ref="noTxAdvice"/> </aop:config> <!-- this bean will be transactional (see the 'defaultServiceOperation' pointcut) --> <bean id="fooService" class="x.y.service.DefaultFooService"/> <!-- this bean will also be transactional, but with totally different transactional settings --> <bean id="anotherFooService" class="x.y.service.ddl.DefaultDdlManager"/> <tx:advice id="defaultTxAdvice"> <tx:attributes> <tx:method name="get*" read-only="true"/> <tx:method name="*"/> </tx:attributes> </tx:advice> <tx:advice id="noTxAdvice"> <tx:attributes> <tx:method name="*" propagation="NEVER"/> </tx:attributes> </tx:advice> <!-- other transaction infrastructure beans such as a PlatformTransactionManager omitted... --> </beans>
This section summarizes the various transactional settings that
can be specified using the <tx:advice/>
tag.
The default <tx:advice/>
settings are:
Propagation setting is
REQUIRED.
Isolation level is DEFAULT.
Transaction is read/write.
Transaction timeout defaults to the default timeout of the underlying transaction system, or none if timeouts are not supported.
Any RuntimeException
triggers
rollback, and any checked Exception
does not.
You can change these default settings; the various attributes of
the <tx:method/>
tags that are nested within
<tx:advice/>
and
<tx:attributes/>
tags are summarized
below:
Table 10.1. <tx:method/>
settings
Attribute | Required? | Default | Description |
---|---|---|---|
name | Yes | Method name(s) with which the transaction
attributes are to be associated. The wildcard (*) character
can be used to associate the same transaction attribute
settings with a number of methods; for example,
| |
propagation | No | REQUIRED | Transaction propagation behavior. |
isolation | No | DEFAULT | Transaction isolation level. |
timeout | No | -1 | Transaction timeout value (in seconds). |
read-only | No | false | Is this transaction read-only? |
rollback-for | No |
| |
no-rollback-for | No |
|
In addition to the XML-based declarative approach to transaction configuration, you can use an annotation-based approach. Declaring transaction semantics directly in the Java source code puts the declarations much closer to the affected code. There is not much danger of undue coupling, because code that is meant to be used transactionally is almost always deployed that way anyway.
The ease-of-use afforded by the use of the
@Transactional
annotation is best
illustrated with an example, which is explained in the text that
follows. Consider the following class definition:
// the service class that we want to make transactional @Transactional public class DefaultFooService implements FooService { Foo getFoo(String fooName); Foo getFoo(String fooName, String barName); void insertFoo(Foo foo); void updateFoo(Foo foo); }
When the above POJO is defined as a bean in a Spring IoC container, the bean instance can be made transactional by adding merely one line of XML configuration:
<!-- from the file 'context.xml' --> <?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-3.0.xsd http://www.springframework.org/schema/tx http://www.springframework.org/schema/tx/spring-tx-3.0.xsd http://www.springframework.org/schema/aop http://www.springframework.org/schema/aop/spring-aop-3.0.xsd"> <!-- this is the service object that we want to make transactional --> <bean id="fooService" class="x.y.service.DefaultFooService"/> <!-- enable the configuration of transactional behavior based on annotations --> <tx:annotation-driven transaction-manager="txManager"/> <!-- a PlatformTransactionManager is still required --> <bean id="txManager" class="org.springframework.jdbc.datasource.DataSourceTransactionManager"> <!-- (this dependency is defined somewhere else) --> <property name="dataSource" ref="dataSource"/> </bean> <!-- other <bean/> definitions here --> </beans>
Tip | |
---|---|
You can omit the |
You can place the @Transactional
annotation before an interface definition, a method on an interface, a
class definition, or a public method on a class.
However, the mere presence of the
@Transactional
annotation is not enough
to activate the transactional behavior. The
@Transactional
annotation is simply
metadata that can be consumed by some runtime infrastructure that is
@Transactional
-aware and that can use the
metadata to configure the appropriate beans with transactional behavior.
In the preceding example, the
<tx:annotation-driven/>
element
switches on the transactional behavior.
Tip | |
---|---|
Spring recommends that you only annotate concrete classes (and
methods of concrete classes) with the
|
Note | |
---|---|
In proxy mode (which is the default), only external method calls
coming in through the proxy are intercepted. This means that
self-invocation, in effect, a method within the target object calling
another method of the target object, will not lead to an actual
transaction at runtime even if the invoked method is marked with
|
Consider the use of AspectJ mode (see mode attribute in table
below) if you expect self-invocations to be wrapped with transactions as
well. In
this case, there will not be a proxy in the first place; instead, the
target class will be weaved (that is, its byte code will be modified) in
order to turn @Transactional
into runtime
behavior on any kind of method.
Table 10.2. <tx:annotation-driven/>
settings
Attribute | Default | Description |
---|---|---|
transaction-manager | transactionManager | Name of transaction manager to use. Only required
if the name of the transaction manager is not
|
mode | proxy | The default mode "proxy" processes annotated beans to be proxied using Spring's AOP framework (following proxy semantics, as discussed above, applying to method calls coming in through the proxy only). The alternative mode "aspectj" instead weaves the affected classes with Spring's AspectJ transaction aspect, modifying the target class byte code to apply to any kind of method call. AspectJ weaving requires spring-aspects.jar in the classpath as well as load-time weaving (or compile-time weaving) enabled. (See Section 7.8.4.5, “Spring configuration” for details on how to set up load-time weaving.) |
proxy-target-class | false | Applies to proxy mode only. Controls what type of
transactional proxies are created for classes annotated with
the |
order | Ordered.LOWEST_PRECEDENCE | Defines the order of the transaction advice that
is applied to beans annotated with
|
Note | |
---|---|
The |
Note | |
---|---|
|
The most derived location takes precedence when evaluating the
transactional settings for a method. In
the case of the following example, the
DefaultFooService
class is annotated at the class
level with the settings for a read-only transaction, but the
@Transactional
annotation on the
updateFoo(Foo)
method in the same class takes
precedence over the transactional settings defined at the class
level.
@Transactional(readOnly = true) public class DefaultFooService implements FooService { public Foo getFoo(String fooName) { // do something } // these settings have precedence for this method @Transactional(readOnly = false, propagation = Propagation.REQUIRES_NEW) public void updateFoo(Foo foo) { // do something } }
The @Transactional
annotation is
metadata that specifies that an interface, class, or method must have
transactional semantics; for example, “start a brand
new read-only transaction when this method is invoked, suspending any
existing transaction”. The default
@Transactional
settings are as
follows:
Propagation setting is
PROPAGATION_REQUIRED.
Isolation level is
ISOLATION_DEFAULT.
Transaction is read/write.
Transaction timeout defaults to the default timeout of the underlying transaction system, or to none if timeouts are not supported.
Any RuntimeException
triggers
rollback, and any checked Exception
does not.
These default settings can be changed; the various properties of
the @Transactional
annotation are
summarized in the following table:
Table 10.3. @Transactional
properties
Property | Type | Description |
---|---|---|
value | String | Optional qualifier specifying the transaction manager to be used. |
propagation | enum: Propagation | Optional propagation setting. |
isolation | enum: Isolation | Optional isolation level. |
readOnly | boolean | Read/write vs. read-only transaction |
timeout | int (in seconds granularity) | Transaction timeout. |
rollbackFor | Array of Class objects, which
must be derived from
Throwable. | Optional array of exception classes that must cause rollback. |
rollbackForClassname | Array of class names. Classes must be derived from
Throwable. | Optional array of names of exception classes that must cause rollback. |
noRollbackFor | Array of Class objects, which
must be derived from
Throwable. | Optional array of exception classes that must not cause rollback. |
noRollbackForClassname | Array of String class names,
which must be derived from
Throwable. | Optional array of names of exception classes that must not cause rollback. |
Currently you cannot have explicit control over the name of a
transaction, where 'name' means the transaction name that will be
shown in a transaction monitor, if applicable (for example, WebLogic's
transaction monitor), and in logging output. For declarative
transactions, the transaction name is always the fully-qualified class
name + "." + method
name of the transactionally-advised class. For example, if the
handlePayment(..)
method of the
BusinessService
class started a transaction,
the name of the transaction would be:
com.foo.BusinessService.handlePayment
.
Most Spring applications only need a single transaction manager, but there may be situations
where you want multiple independent transaction managers in a single application.
The value attribute of the @Transactional
annotation can
be used to optionally specify the identity of the PlatformTransactionManager
to be used. This can either be the bean name or the qualifier value of the transaction manager bean.
For example, using the qualifier notation, the following Java code
public class TransactionalService { @Transactional("order") public void setSomething(String name) { ... } @Transactional("account") public void doSomething() { ... } }
could be combined with the following transaction manager bean declarations in the application context.
<tx:annotation-driven/> <bean id="transactionManager1" class="org.springframework.jdbc.DataSourceTransactionManager"> ... <qualifier value="order"/> </bean> <bean id="transactionManager2" class="org.springframework.jdbc.DataSourceTransactionManager"> ... <qualifier value="account"/> </bean>
In this case, the two methods on TransactionalService
will run under separate
transaction managers, differentiated by the "order" and "account" qualifiers.
The default <tx:annotation-driven>
target bean name transactionManager
will
still be used if no specifically qualified PlatformTransactionManager bean is found.
If you find you are repeatedly using the same attributes with @Transactional
on many different methods, then Spring's meta-annotation support allows you to define custom shortcut
annotations for your specific use cases. For example, defining the following annotations
@Target({ElementType.METHOD, ElementType.TYPE}) @Retention(RetentionPolicy.RUNTIME) @Transactional("order") public @interface OrderTx { } @Target({ElementType.METHOD, ElementType.TYPE}) @Retention(RetentionPolicy.RUNTIME) @Transactional("account") public @interface AccountTx { }
allows us to write the example from the previous section as
public class TransactionalService { @OrderTx public void setSomething(String name) { ... } @AccountTx public void doSomething() { ... } }
Here we have used the syntax to define the transaction manager qualifier, but could also have included propagation behavior, rollback rules, timeouts etc.
This section describes some semantics of transaction propagation in Spring. Please note that this section is not an introduction to transaction propagation proper; rather it details some of the semantics regarding transaction propagation in Spring.
In Spring-managed transactions, be aware of the difference between physical and logical transactions, and how the propagation setting applies to this difference.
When the propagation setting is
PROPAGATION_REQUIRED
, a
logical transaction scope is created for each
method that to which the setting is applied. Each such logical
transaction scope can determine rollback-only status individually,
with an outer transaction scope being logically independent from the
inner transaction scope. Of course, in case of standard
PROPAGATION_REQUIRED
behavior, all these scopes
will be mapped to the same physical transaction. So a rollback-only
marker set in the inner transaction scope does affect the outer
transaction's chance to actually commit (as you would expect it
to).
However, in the case where an inner transaction scope sets the
rollback-only marker, the outer transaction has not decided on the
rollback itself, and so the rollback (silently triggered by the inner
transaction scope) is unexpected. A corresponding
UnexpectedRollbackException
is thrown at that
point. This is expected behavior so that the
caller of a transaction can never be misled to assume that a commit
was performed when it really was not. So if an inner transaction (of
which the outer caller is not aware) silently marks a transaction as
rollback-only, the outer caller still calls commit. The outer caller
needs to receive an UnexpectedRollbackException
to indicate clearly that a rollback was performed instead.
PROPAGATION_REQUIRES_NEW
, in contrast to
PROPAGATION_REQUIRED, uses a
completely independent transaction for each
affected transaction scope. In that case, the underlying physical
transactions are different and hence can commit or roll back
independently, with an outer transaction not affected by an inner
transaction's rollback status.
PROPAGATION_NESTED
uses a
single physical transaction with multiple
savepoints that it can roll back to. Such partial rollbacks allow an
inner transaction scope to trigger a rollback for its
scope, with the outer transaction being able to continue
the physical transaction despite some operations having been rolled
back. This setting is typically mapped onto JDBC savepoints, so will
only work with JDBC resource transactions. See Spring's
DataSourceTransactionManager
.
Suppose you want to execute both
transactional and some basic profiling advice. How
do you effect this in the context of
<tx:annotation-driven/>
?
When you invoke the updateFoo(Foo)
method, you want to see the following actions:
Configured profiling aspect starts up.
Transactional advice executes.
Method on the advised object executes.
Transaction commits.
Profiling aspect reports exact duration of the whole transactional method invocation.
Note | |
---|---|
This chapter is not concerned with explaining AOP in any great detail (except as it applies to transactions). See Chapter 7, Aspect Oriented Programming with Spring for detailed coverage of the following AOP configuration and AOP in general. |
Here is the code for a simple profiling aspect discussed above.
The
ordering of advice is controlled through the
Ordered
interface. For full details on
advice ordering, see Section 7.2.4.7, “Advice ordering”.
package x.y; import org.aspectj.lang.ProceedingJoinPoint; import org.springframework.util.StopWatch; import org.springframework.core.Ordered; public class SimpleProfiler implements Ordered { private int order; // allows us to control the ordering of advice public int getOrder() { return this.order; } public void setOrder(int order) { this.order = order; } // this method is the around advice public Object profile(ProceedingJoinPoint call) throws Throwable { Object returnValue; StopWatch clock = new StopWatch(getClass().getName()); try { clock.start(call.toShortString()); returnValue = call.proceed(); } finally { clock.stop(); System.out.println(clock.prettyPrint()); } return returnValue; } }
<?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-3.0.xsd http://www.springframework.org/schema/tx http://www.springframework.org/schema/tx/spring-tx-3.0.xsd http://www.springframework.org/schema/aop http://www.springframework.org/schema/aop/spring-aop-3.0.xsd"> <bean id="fooService" class="x.y.service.DefaultFooService"/> <!-- this is the aspect --> <bean id="profiler" class="x.y.SimpleProfiler"> <!-- execute before the transactional advice (hence the lower order number) --> <property name="order" value="1"/> </bean> <tx:annotation-driven transaction-manager="txManager" order="200"/> <aop:config> <!-- this advice will execute around the transactional advice --> <aop:aspect id="profilingAspect" ref="profiler"> <aop:pointcut id="serviceMethodWithReturnValue" expression="execution(!void x.y..*Service.*(..))"/> <aop:around method="profile" pointcut-ref="serviceMethodWithReturnValue"/> </aop:aspect> </aop:config> <bean id="dataSource" class="org.apache.commons.dbcp.BasicDataSource" destroy-method="close"> <property name="driverClassName" value="oracle.jdbc.driver.OracleDriver"/> <property name="url" value="jdbc:oracle:thin:@rj-t42:1521:elvis"/> <property name="username" value="scott"/> <property name="password" value="tiger"/> </bean> <bean id="txManager" class="org.springframework.jdbc.datasource.DataSourceTransactionManager"> <property name="dataSource" ref="dataSource"/> </bean> </beans>
The result of the above configuration is a
fooService
bean that has profiling and transactional
aspects applied to it in the desired order. You
configure any number of additional aspects in similar fashion.
The following example effects the same setup as above, but uses the purely XML declarative approach.
<?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-3.0.xsd http://www.springframework.org/schema/tx http://www.springframework.org/schema/tx/spring-tx-3.0.xsd http://www.springframework.org/schema/aop http://www.springframework.org/schema/aop/spring-aop-3.0.xsd"> <bean id="fooService" class="x.y.service.DefaultFooService"/> <!-- the profiling advice --> <bean id="profiler" class="x.y.SimpleProfiler"> <!-- execute before the transactional advice (hence the lower order number) --> <property name="order" value="1"/> </bean> <aop:config> <aop:pointcut id="entryPointMethod" expression="execution(* x.y..*Service.*(..))"/> <!-- will execute after the profiling advice (c.f. the order attribute) --> <aop:advisor advice-ref="txAdvice" pointcut-ref="entryPointMethod" order="2"/> <!-- order value is higher than the profiling aspect --> <aop:aspect id="profilingAspect" ref="profiler"> <aop:pointcut id="serviceMethodWithReturnValue" expression="execution(!void x.y..*Service.*(..))"/> <aop:around method="profile" pointcut-ref="serviceMethodWithReturnValue"/> </aop:aspect> </aop:config> <tx:advice id="txAdvice" transaction-manager="txManager"> <tx:attributes> <tx:method name="get*" read-only="true"/> <tx:method name="*"/> </tx:attributes> </tx:advice> <!-- other <bean/> definitions such as a DataSource and a PlatformTransactionManager here --> </beans>
The result of the above configuration will be a
fooService
bean that has profiling and transactional
aspects applied to it in that order. If you want
the profiling advice to execute after the
transactional advice on the way in, and before the
transactional advice on the way out, then you simply swap the value of
the profiling aspect bean's order
property so that it
is higher than the transactional advice's order value.
You configure additional aspects in similar fashion.
It is also possible to use the Spring Framework's
@Transactional
support outside of a
Spring container by means of an AspectJ aspect. To do so, you first
annotate your classes (and optionally your classes' methods) with the
@Transactional
annotation, and then you
link (weave) your application with the
org.springframework.transaction.aspectj.AnnotationTransactionAspect
defined in the spring-aspects.jar
file. The aspect must
also be configured with a transaction manager. You can of course use the
Spring Framework's IoC container to take care of dependency-injecting
the aspect. The simplest way to configure the transaction management
aspect is to use the <tx:annotation-driven/>
element and specify the mode
attribute to
asepctj
as described in Section 10.5.6, “Using @Transactional”. Because we're focusing
here on applications running outside of a Spring container, we'll show
you how to do it programmatically.
Note | |
---|---|
Prior to continuing, you may want to read Section 10.5.6, “Using @Transactional” and Chapter 7, Aspect Oriented Programming with Spring respectively. |
// construct an appropriate transaction manager DataSourceTransactionManager txManager = new DataSourceTransactionManager(getDataSource()); // configure the AnnotationTransactionAspect to use it; this must be done before executing any transactional methods AnnotationTransactionAspect.aspectOf().setTransactionManager(txManager);
Note | |
---|---|
When using this aspect, you must annotate the implementation class (and/or methods within that class), not the interface (if any) that the class implements. AspectJ follows Java's rule that annotations on interfaces are not inherited. |
The @Transactional
annotation on a
class specifies the default transaction semantics for the execution of
any method in the class.
The @Transactional
annotation on a
method within the class overrides the default transaction semantics
given by the class annotation (if present). Any method may be annotated,
regardless of visibility.
To weave your applications with the
AnnotationTransactionAspect
you must either build
your application with AspectJ (see the AspectJ
Development Guide) or use load-time weaving. See Section 7.8.4, “Load-time weaving with AspectJ in the Spring Framework” for a discussion of load-time weaving with
AspectJ.
The Spring Framework provides two means of programmatic transaction management:
Using the TransactionTemplate
.
Using a
PlatformTransactionManager
implementation directly.
The Spring team generally recommends the
TransactionTemplate
for programmatic transaction
management. The second approach is similar to using the JTA
UserTransaction
API, although exception
handling is less cumbersome.
The TransactionTemplate
adopts the same
approach as other Spring templates such as the
JdbcTemplate
. It uses a callback approach, to
free application code from having to do the boilerplate acquisition and
release of transactional resources, and results in code that is
intention driven, in that the code that is written focuses solely on
what the developer wants to do.
Note | |
---|---|
As you will see in the examples that follow, using the
|
Application code that must execute in a transactional context, and
that will use the TransactionTemplate
explicitly,
looks like the following. You, as an application developer, write a
TransactionCallback
implementation
(typically expressed as an anonymous inner class) that contains the code
that you need to execute in the context of a transaction. You then pass
an instance of your custom
TransactionCallback
to the
execute(..)
method exposed on the
TransactionTemplate
.
public class SimpleService implements Service { // single TransactionTemplate shared amongst all methods in this instance private final TransactionTemplate transactionTemplate; // use constructor-injection to supply the PlatformTransactionManager public SimpleService(PlatformTransactionManager transactionManager) { Assert.notNull(transactionManager, "The 'transactionManager' argument must not be null."); this.transactionTemplate = new TransactionTemplate(transactionManager); } public Object someServiceMethod() { return transactionTemplate.execute(new TransactionCallback() { // the code in this method executes in a transactional context public Object doInTransaction(TransactionStatus status) { updateOperation1(); return resultOfUpdateOperation2(); } }); } }
If there is no return value, use the convenient
TransactionCallbackWithoutResult
class with an
anonymous class as follows:
transactionTemplate.execute(new TransactionCallbackWithoutResult() { protected void doInTransactionWithoutResult(TransactionStatus status) { updateOperation1(); updateOperation2(); } });
Code within the callback can roll the transaction back by calling
the setRollbackOnly()
method on the supplied
TransactionStatus
object:
transactionTemplate.execute(new TransactionCallbackWithoutResult() { protected void doInTransactionWithoutResult(TransactionStatus status) { try { updateOperation1(); updateOperation2(); } catch (SomeBusinessExeption ex) { status.setRollbackOnly(); } } });
You can specify transaction settings such as the propagation
mode, the isolation level, the timeout, and so forth on the
TransactionTemplate
either programmatically or
in configuration. TransactionTemplate
instances
by default have the default
transactional settings. The following example shows the
programmatic customization of the transactional settings for a
specific TransactionTemplate:
public class SimpleService implements Service { private final TransactionTemplate transactionTemplate; public SimpleService(PlatformTransactionManager transactionManager) { Assert.notNull(transactionManager, "The 'transactionManager' argument must not be null."); this.transactionTemplate = new TransactionTemplate(transactionManager); // the transaction settings can be set here explicitly if so desired this.transactionTemplate.setIsolationLevel(TransactionDefinition.ISOLATION_READ_UNCOMMITTED); this.transactionTemplate.setTimeout(30); // 30 seconds // and so forth... } }
The following example defines a
TransactionTemplate
with some custom
transactional settings, using Spring XML configuration. The
sharedTransactionTemplate
can then be injected into
as many services as are required.
<bean id="sharedTransactionTemplate" class="org.springframework.transaction.support.TransactionTemplate"> <property name="isolationLevelName" value="ISOLATION_READ_UNCOMMITTED"/> <property name="timeout" value="30"/> </bean>"
Finally, instances of the
TransactionTemplate
class are threadsafe, in that
instances do not maintain any conversational state.
TransactionTemplate
instances
do however maintain configuration state, so while a
number of classes may share a single instance of a
TransactionTemplate
, if a class needs to use a
TransactionTemplate
with different settings (for
example, a different isolation level), then you need to create two
distinct TransactionTemplate
instances.
You can also use the
org.springframework.transaction.PlatformTransactionManager
directly to manage your transaction. Simply pass the implementation of
the PlatformTransactionManager
you are
using to your bean through a bean reference. Then, using the
TransactionDefinition
and
TransactionStatus
objects you can
initiate transactions, roll back, and commit.
DefaultTransactionDefinition def = new DefaultTransactionDefinition(); // explicitly setting the transaction name is something that can only be done programmatically def.setName("SomeTxName"); def.setPropagationBehavior(TransactionDefinition.PROPAGATION_REQUIRED); TransactionStatus status = txManager.getTransaction(def); try { // execute your business logic here } catch (MyException ex) { txManager.rollback(status); throw ex; } txManager.commit(status);
Programmatic transaction management is usually a good idea only if
you have a small number of transactional operations. For example, if you
have a web application that require transactions only for certain update
operations, you may not want to set up transactional proxies using Spring
or any other technology. In this case, using the
TransactionTemplate
may be a
good approach. Being able to set the transaction name explicitly is also
something that can only be done using the programmatic approach to
transaction management.
On the other hand, if your application has numerous transactional operations, declarative transaction management is usually worthwhile. It keeps transaction management out of business logic, and is not difficult to configure. When using the Spring Framework, rather than EJB CMT, the configuration cost of declarative transaction management is greatly reduced.
Spring's transaction abstraction generally is application server
agnostic. Additionally, Spring's
JtaTransactionManager
class, which can optionally
perform a JNDI lookup for the JTA
UserTransaction
and
TransactionManager
objects, autodetects the
location for the latter object, which varies by application server. Having
access to the JTA TransactionManager
allows
for enhanced transaction semantics, in particular supporting transaction
suspension. See the JtaTransactionManager
Javadocs
for details.
Spring's JtaTransactionManager
is the
standard choice to run on Java EE application servers, and is known to
work on all common servers. Advanced functionality such as transaction
suspension works on many servers as well -- including GlassFish, JBoss,
Geronimo, and Oracle OC4J -- without any special configuration required.
However, for fully supported transaction suspension and further advanced
integration, Spring ships special adapters for IBM WebSphere, BEA WebLogic
Server, and Oracle OC4J. These adapters iare discussed in the following
sections.
For standard scenarios, including WebLogic Server,
WebSphere and OC4J, consider using the convenient
<tx:jta-transaction-manager/>
configuration
element. When configured, this element automatically detects
the underlying server and chooses the best transaction manager available
for the platform. This means that you won't have to configure
server-specific adapter classes (as discussed in the following sections)
explicitly; rather, they are chosen automatically, with the standard
JtaTransactionManager
as default fallback.
On WebSphere 6.1.0.9 and above, the recommended Spring JTA
transaction manager to use is
WebSphereUowTransactionManager
. This special
adapter leverages IBM's UOWManager
API,
which is available in WebSphere Application Server 6.0.2.19 and later
and 6.1.0.9 and later. With this adapter, Spring-driven transaction
suspension (suspend/resume as initiated by
PROPAGATION_REQUIRES_NEW
) is officially supported by
IBM!
On WebLogic Server 9.0 or above, you typically would use the
WebLogicJtaTransactionManager
instead of the
stock JtaTransactionManager
class. This special
WebLogic-specific subclass of the normal
JtaTransactionManager
supports the full power of
Spring's transaction definitions in a WebLogic-managed transaction
environment, beyond standard JTA semantics: Features include transaction
names, per-transaction isolation levels, and proper resuming of
transactions in all cases.
Spring ships a special adapter class for OC4J 10.1.3 or later
called OC4JJtaTransactionManager
. This class is
analogous to the WebLogicJtaTransactionManager
class discussed in the previous section, providing similar value-adds on
OC4J: transaction names and per-transaction isolation levels.
The full JTA functionality, including transaction suspension,
works fine with Spring's JtaTransactionManager
on
OC4J as well. The special
OC4JJtaTransactionManager
adapter simply provides
value-adds beyond standard JTA.
Use the correct
PlatformTransactionManager
implementation
based on your choice of transactional technologies and requirements.
Used properly, the Spring Framework merely provides a straightforward
and portable abstraction. If you are using global transactions, you
must use the
org.springframework.transaction.jta.JtaTransactionManager
class (or an application
server-specific subclass of it) for all your transactional
operations. Otherwise the transaction infrastructure attempts to perform
local transactions on resources such as container
DataSource
instances. Such local
transactions do not make sense, and a good application server treats
them as errors.
For more information about the Spring Framework's transaction support:
Distributed transactions in Spring, with and without XA is a JavaWorld presentation in which SpringSource's David Syer guides you through seven patterns for distributed transactions in Spring applications, three of them with XA and four without.
Java Transaction Design Strategies is a book available from InfoQ that provides a well-paced introduction to transactions in Java. It also includes side-by-side examples of how to configure and use transactions with both the Spring Framework and EJB3.