#Autowire vs AplicationContext way of injecting - spring-boot

#RestController
#RequestMapping("kafka")
public class KafkaController implements ApplicationContextAware {
#Autowired
KafkaConfig config;
ApplicationContext context;
#GetMapping("messages")
public void getMessages() throws InterruptedException {
System.out.println("Queue name is >>>>>>>>>>>>" + config.getQueueName());
System.out.println("<<<<<<<<<<<<<<<<<<<<<<<<<<"+ ((KafkaConfig)context.getBean("kafkaConfigBean")).getQueueName());
When I invoke the service multiple times it gives me the same queuename value in the log "Queue name is >>>>>>>>>>>>", but a different value if I get it like this : ((KafkaConfig)context.getBean("kafkaConfigBean")).getQueueName()
When I create bean I use Math.random() to produce different output.
#Bean("kafkaConfigBean")
#Scope("prototype")
public KafkaConfig createKafkaBeanConfig() {
KafkaConfig conf = new KafkaConfig();
conf.setQueueName("prototype" + String.valueOf(Math.random()));
return conf;
}
Why it's generating different value via applicationContext way but same when using #Autowired. Isn't scope "prototype" means creating new bean each time requested.
Why for each call to controller #Autowire is returning the same bean ?
Thanks

In the first case, you're defining a singleton bean of type KafkaController that contains the autowired field KafkaConfig config;. Since the bean is a singleton, it is only created once, and so the KafkaConfig field value within it is only created once. Making multiple requests using that same Controller uses that same KafkaConfig value, and so the queue name doesn't change.
In the second case, you're calling context.getBean("kafkaConfigBean") yourself explicitly, which causes Spring to create a new bean every time you call it, because you've defined that bean as being a "prototype". As designed, each time it is created, it computes a different queue name.
If you were creating multiple KafkaController objects, each of them would contain a different KafkaConfig field value, each of which having a different queue name.

Related

How to use Spring managed beans in Drool

I have a service that is managed by spring and I want to use or inject as dependency in drool rule. How can I use the service bean in the Drool rule?
#Service
public class SomeService {
public void doSomething() {}
}
dialect "mvel"
rule "something"
when
................
then
service.doSomething()
end
Pass your bean instance into working memory when you invoke them, the same as you'd pass any other data in. This way you can autowire or otherwise leverage dependency injection to get your Spring-managed singleton bean, and then use that same bean in your rules without having to new up another instance.
#Component
class RuleExecutor {
private final SomeService service; // Bean set via constructor injection
public RuleExecutor(SomeService service) {
this.service = service;
}
public void fireRules( ... ) { // assuming other data passed in via parameter
KieSession kieSession = ...;
kieSession.insert( this.service); // insert bean into the working memory
kieSession.insert( ... ); // insert other data into working memory
kieSession.fireAllRules();
}
}
In this example I used constructor injection to pass in the bean instance. We can assume that both the #Service and this #Component were picked up by the component scan.
Then you could interact with it in the rules in the same way as you'd do any other data:
dialect "mvel"
rule "something"
when
service: SomeService()
then
service.doSomething()
end
Remember that service: SomeService() matches an instance of SomeService in working memory and assigns it to the service variable for use in the rule. It does not new up a new instance.

Class not able to access bean managed by Spring

I have Spring configuration file where I am defining beans but somehow this bean is not accessible from one of the class in same package, though same beans are accessible from Controller class which was annotated as #Controller. I was thinking may be this class was not managed by Spring but that's not the case.
1) Configuration class
#Bean
public FooConsumer fooConsumer() {
return new FooConsumer();
}
#Bean
public Map<String, ProxyConsumer> appProxyConsumerMap() {
Map<String, ProxyConsumer> proxyConsumer = new HashMap<String, ProxyConsumer>();
proxyConsumer.put(FOO_APP, FooConsumer());
return proxyConsumer;
}
#Bean
public FooEventConsumer fooEventConsumer() {
return new FooEventConsumer();
}
#Bean
public Map<String, FooConsumer> fooConsumerMap(){
Map<String, FooConsumer> fooEventConsumer = new HashMap<String, FooConsumer>();
fooEventConsumer.put(FOO_EVENT, fooEventConsumer());
}
2) Controller class
#Resource
#Qualifier("appProxyConsumerMap")
Map<String, ProxyConsumer> appProxyConsumerMap;
//proxyApp comes as path variable
ProxyConsumer consumer = appProxyConsumerMap.get(proxyApp);
//invoke consumer
boolean consumed = consumer.consumeEvent(eventRequest);
//here consumer is my FooConsumer class, till now all works fine.
3) now in FooConsumer class it tries to access Map bean named fooConsumerMap to get which event to call but somehow it returns null.
#Resource
#Qualifier("fooConsumerMap")
Map<String, FooConsumer> fooConsumerMap;
FooEventConsumer consumer = fooConsumerMap.get(eventType);
//Here fooConsumerMap comes as null in this class, though it comes as object in controller class , please advise.
In your configuration file, construct your FooConsumer bean with the FooConsumerMap bean declared in the same configuration.
You can autowire other beans into a configuration file, but to pull together beans within the file you pass them as constructor arguments.
Note that if you call a Bean annotated method multiple times, you will surprisingly always get the same instance even if the method logic constructs a new instance.
Check documentation at https://docs.spring.io/spring-javaconfig/docs/1.0.0.m3/reference/html/creating-bean-definitions.html

When autowiring does a copy of the instance get returned?

If I have a bean definition with some configuration within it and I use autowire to get an instance of the same class, is it the instance of the bean definition I get returned or a new instance of the class without any configurations?
class Name {
private fName;
private lName;
constructor(string fName, string lName) {
this.fName = fName;
this.lName = lName;
}
}
#Bean
public Name getName() {
Name test = new Name(thisIsMyFirstName, thisIsMyLastName);
}
--Separate File--
#Autowired
private Name testName;
Is testName here a copy of the #Bean getName() (has thisIsMyFirstName and thisIsMyLastName set) or is it a new instance of the class Name without a first name of thisIsMyFirstName and last name of thisIsMyLastName?
By default, yes, beans are singletons.
But, the Spring framework defines a number of different scopes.
singleton
Scopes a single bean definition to a single object instance per Spring IoC container.
prototype
Scopes a single bean definition to any number of object instances.
request
Scopes a single bean definition to the lifecycle of a single HTTP request; that is each and every HTTP request will have its own instance of a bean created off the back of a single bean definition. Only valid in the context of a web-aware Spring ApplicationContext.
session
Scopes a single bean definition to the lifecycle of a HTTP Session. Only valid in the context of a web-aware Spring ApplicationContext.
global session
Scopes a single bean definition to the lifecycle of a global HTTP Session. Typically only valid when used in a portlet context. Only valid in the context of a web-aware Spring ApplicationContext.
The scope of a bean can be change using the #Scope annotation.
#Bean
#Scope("singleton") // <- singleton is the default. If no #Scope annotation is present, this is what is used.
public BeanA sharedBean() {
// This will only be called once, all subsequent calls will return from the cached reference in the ApplicationContext
return new BeanA();
}
#Bean
#Scope("prototype")
public BeanB privateBean() {
// This will be called every time the bean is injected and a new instance returned.
return new BeanB();
}
This is just another syntax
#Scope(value = ConfigurableBeanFactory.SCOPE_SINGLETON)

No qualifying bean of type [org.springframework.mail.javamail.JavaMailSender] while deploying service into PCF [duplicate]

Please explain the following about NoSuchBeanDefinitionException exception in Spring:
What does it mean?
Under what conditions will it be thrown?
How can I prevent it?
This post is designed to be a comprehensive Q&A about occurrences of NoSuchBeanDefinitionException in applications using Spring.
The javadoc of NoSuchBeanDefinitionException explains
Exception thrown when a BeanFactory is asked for a bean instance for
which it cannot find a definition. This may point to a non-existing
bean, a non-unique bean, or a manually registered singleton instance
without an associated bean definition.
A BeanFactory is basically the abstraction representing Spring's Inversion of Control container. It exposes beans internally and externally, to your application. When it cannot find or retrieve these beans, it throws a NoSuchBeanDefinitionException.
Below are simple reasons why a BeanFactory (or related classes) would not be able to find a bean and how you can make sure it does.
The bean doesn't exist, it wasn't registered
In the example below
#Configuration
public class Example {
public static void main(String[] args) throws Exception {
AnnotationConfigApplicationContext ctx = new AnnotationConfigApplicationContext(Example.class);
ctx.getBean(Foo.class);
}
}
class Foo {}
we haven't registered a bean definition for the type Foo either through a #Bean method, #Component scanning, an XML definition, or any other way. The BeanFactory managed by the AnnotationConfigApplicationContext therefore has no indication of where to get the bean requested by getBean(Foo.class). The snippet above throws
Exception in thread "main" org.springframework.beans.factory.NoSuchBeanDefinitionException:
No qualifying bean of type [com.example.Foo] is defined
Similarly, the exception could have been thrown while trying to satisfy an #Autowired dependency. For example,
#Configuration
#ComponentScan
public class Example {
public static void main(String[] args) throws Exception {
AnnotationConfigApplicationContext ctx = new AnnotationConfigApplicationContext(Example.class);
}
}
#Component
class Foo { #Autowired Bar bar; }
class Bar { }
Here, a bean definition is registered for Foo through #ComponentScan. But Spring knows nothing of Bar. It therefore fails to find a corresponding bean while trying to autowire the bar field of the Foo bean instance. It throws (nested inside a UnsatisfiedDependencyException)
Caused by: org.springframework.beans.factory.NoSuchBeanDefinitionException:
No qualifying bean of type [com.example.Bar] found for dependency [com.example.Bar]:
expected at least 1 bean which qualifies as autowire candidate for this dependency. Dependency annotations: {#org.springframework.beans.factory.annotation.Autowired(required=true)}
There are multiple ways to register bean definitions.
#Bean method in a #Configuration class or <bean> in XML configuration
#Component (and its meta-annotations, eg. #Repository) through #ComponentScan or <context:component-scan ... /> in XML
Manually through GenericApplicationContext#registerBeanDefinition
Manually through BeanDefinitionRegistryPostProcessor
...and more.
Make sure the beans you expect are properly registered.
A common error is to register beans multiple times, ie. mixing the options above for the same type. For example, I might have
#Component
public class Foo {}
and an XML configuration with
<context:component-scan base-packages="com.example" />
<bean name="eg-different-name" class="com.example.Foo />
Such a configuration would register two beans of type Foo, one with name foo and another with name eg-different-name. Make sure you're not accidentally registering more beans than you wanted. Which leads us to...
If you're using both XML and annotation-based configurations, make sure you import one from the other. XML provides
<import resource=""/>
while Java provides the #ImportResource annotation.
Expected single matching bean, but found 2 (or more)
There are times when you need multiple beans for the same type (or interface). For example, your application may use two databases, a MySQL instance and an Oracle one. In such a case, you'd have two DataSource beans to manage connections to each one. For (simplified) example, the following
#Configuration
public class Example {
public static void main(String[] args) throws Exception {
AnnotationConfigApplicationContext ctx = new AnnotationConfigApplicationContext(Example.class);
System.out.println(ctx.getBean(DataSource.class));
}
#Bean(name = "mysql")
public DataSource mysql() { return new MySQL(); }
#Bean(name = "oracle")
public DataSource oracle() { return new Oracle(); }
}
interface DataSource{}
class MySQL implements DataSource {}
class Oracle implements DataSource {}
throws
Exception in thread "main" org.springframework.beans.factory.NoUniqueBeanDefinitionException:
No qualifying bean of type [com.example.DataSource] is defined:
expected single matching bean but found 2: oracle,mysql
because both beans registered through #Bean methods satisfied the requirement of BeanFactory#getBean(Class), ie. they both implement DataSource. In this example, Spring has no mechanism to differentiate or prioritize between the two. But such mechanisms exists.
You could use #Primary (and its equivalent in XML) as described in the documentation and in this post. With this change
#Bean(name = "mysql")
#Primary
public DataSource mysql() { return new MySQL(); }
the previous snippet would not throw the exception and would instead return the mysql bean.
You can also use #Qualifier (and its equivalent in XML) to have more control over the bean selection process, as described in the documentation. While #Autowired is primarily used to autowire by type, #Qualifier lets you autowire by name. For example,
#Bean(name = "mysql")
#Qualifier(value = "main")
public DataSource mysql() { return new MySQL(); }
could now be injected as
#Qualifier("main") // or #Qualifier("mysql"), to use the bean name
private DataSource dataSource;
without issue. #Resource is also an option.
Using wrong bean name
Just as there are multiple ways to register beans, there are also multiple ways to name them.
#Bean has name
The name of this bean, or if plural, aliases for this bean. If left
unspecified the name of the bean is the name of the annotated method.
If specified, the method name is ignored.
<bean> has the id attribute to represent the unique identifier for a bean and name can be used to create one or more aliases illegal in an (XML) id.
#Component and its meta annotations have value
The value may indicate a suggestion for a logical component name, to
be turned into a Spring bean in case of an autodetected component.
If that's left unspecified, a bean name is automatically generated for the annotated type, typically the lower camel case version of the type name. For example MyClassName becomes myClassName as its bean name. Bean names are case sensitive. Also note that wrong names/capitalization typically occur in beans referred to by string like #DependsOn("my BeanName") or XML config files.
#Qualifier, as mentioned earlier, lets you add more aliases to a bean.
Make sure you use the right name when referring to a bean.
More advanced cases
Profiles
Bean definition profiles allow you to register beans conditionally. #Profile, specifically,
Indicates that a component is eligible for registration when one or
more specified profiles are active.
A profile is a named logical grouping that may be activated
programmatically via
ConfigurableEnvironment.setActiveProfiles(java.lang.String...) or
declaratively by setting the spring.profiles.active property as a JVM
system property, as an environment variable, or as a Servlet context
parameter in web.xml for web applications. Profiles may also be
activated declaratively in integration tests via the #ActiveProfiles
annotation.
Consider this examples where the spring.profiles.active property is not set.
#Configuration
#ComponentScan
public class Example {
public static void main(String[] args) throws Exception {
AnnotationConfigApplicationContext ctx = new AnnotationConfigApplicationContext(Example.class);
System.out.println(Arrays.toString(ctx.getEnvironment().getActiveProfiles()));
System.out.println(ctx.getBean(Foo.class));
}
}
#Profile(value = "StackOverflow")
#Component
class Foo {
}
This will show no active profiles and throw a NoSuchBeanDefinitionException for a Foo bean. Since the StackOverflow profile wasn't active, the bean wasn't registered.
Instead, if I initialize the ApplicationContext while registering the appropriate profile
AnnotationConfigApplicationContext ctx = new AnnotationConfigApplicationContext();
ctx.getEnvironment().setActiveProfiles("StackOverflow");
ctx.register(Example.class);
ctx.refresh();
the bean is registered and can be returned/injected.
AOP Proxies
Spring uses AOP proxies a lot to implement advanced behavior. Some examples include:
Transaction management with #Transactional
Caching with #Cacheable
Scheduling and asynchronous execution with #Async and #Scheduled
To achieve this, Spring has two options:
Use the JDK's Proxy class to create an instance of a dynamic class at runtime which only implements your bean's interfaces and delegates all method invocations to an actual bean instance.
Use CGLIB proxies to create an instance of a dynamic class at runtime which implements both interfaces and concrete types of your target bean and delegates all method invocations to an actual bean instance.
Take this example of JDK proxies (achieved through #EnableAsync's default proxyTargetClass of false)
#Configuration
#EnableAsync
public class Example {
public static void main(String[] args) throws Exception {
AnnotationConfigApplicationContext ctx = new AnnotationConfigApplicationContext(Example.class);
System.out.println(ctx.getBean(HttpClientImpl.class).getClass());
}
}
interface HttpClient {
void doGetAsync();
}
#Component
class HttpClientImpl implements HttpClient {
#Async
public void doGetAsync() {
System.out.println(Thread.currentThread());
}
}
Here, Spring attempts to find a bean of type HttpClientImpl which we expect to find because the type is clearly annotated with #Component. However, instead, we get an exception
Exception in thread "main" org.springframework.beans.factory.NoSuchBeanDefinitionException:
No qualifying bean of type [com.example.HttpClientImpl] is defined
Spring wrapped the HttpClientImpl bean and exposed it through a Proxy object that only implements HttpClient. So you could retrieve it with
ctx.getBean(HttpClient.class) // returns a dynamic class: com.example.$Proxy33
// or
#Autowired private HttpClient httpClient;
It's always recommended to program to interfaces. When you can't, you can tell Spring to use CGLIB proxies. For example, with #EnableAsync, you can set proxyTargetClass to true. Similar annotations (EnableTransactionManagement, etc.) have similar attributes. XML will also have equivalent configuration options.
ApplicationContext Hierarchies - Spring MVC
Spring lets you build ApplicationContext instances with other ApplicationContext instances as parents, using ConfigurableApplicationContext#setParent(ApplicationContext). A child context will have access to beans in the parent context, but the opposite is not true. This post goes into detail about when this is useful, particularly in Spring MVC.
In a typical Spring MVC application, you define two contexts: one for the entire application (the root) and one specifically for the DispatcherServlet (routing, handler methods, controllers). You can get more details here:
Difference between applicationContext.xml and spring-servlet.xml in Spring Framework
It's also very well explained in the official documentation, here.
A common error in Spring MVC configurations is to declare the WebMVC configuration in the root context with #EnableWebMvc annotated #Configuration classes or <mvc:annotation-driven /> in XML, but the #Controller beans in the servlet context. Since the root context cannot reach into the servlet context to find any beans, no handlers are registered and all requests fail with 404s. You won't see a NoSuchBeanDefinitionException, but the effect is the same.
Make sure your beans are registered in the appropriate context, ie. where they can be found by the beans registered for WebMVC (HandlerMapping, HandlerAdapter, ViewResolver, ExceptionResolver, etc.). The best solution is to properly isolate beans. The DispatcherServlet is responsible for routing and handling requests so all related beans should go into its context. The ContextLoaderListener, which loads the root context, should initialize any beans the rest of your application needs: services, repositories, etc.
Arrays, collections, and maps
Beans of some known types are handled in special ways by Spring. For example, if you tried to inject an array of MovieCatalog into a field
#Autowired
private MovieCatalog[] movieCatalogs;
Spring will find all beans of type MovieCatalog, wrap them in an array, and inject that array. This is described in the Spring documentation discussing #Autowired. Similar behavior applies to Set, List, and Collection injection targets.
For a Map injection target, Spring will also behave this way if the key type is String. For example, if you have
#Autowired
private Map<String, MovieCatalog> movies;
Spring will find all beans of type MovieCatalog and add them as values to a Map, where the corresponding key will be their bean name.
As described previously, if no beans of the requested type are available, Spring will throw a NoSuchBeanDefinitionException. Sometimes, however, you just want to declare a bean of these collection types like
#Bean
public List<Foo> fooList() {
return Arrays.asList(new Foo());
}
and inject them
#Autowired
private List<Foo> foos;
In this example, Spring would fail with a NoSuchBeanDefinitionException because there are no Foo beans in your context. But you didn't want a Foo bean, you wanted a List<Foo> bean. Before Spring 4.3, you'd have to use #Resource
For beans that are themselves defined as a collection/map or array
type, #Resource is a fine solution, referring to the specific
collection or array bean by unique name. That said, as of 4.3,
collection/map and array types can be matched through Spring’s
#Autowired type matching algorithm as well, as long as the element
type information is preserved in #Bean return type signatures or
collection inheritance hierarchies. In this case, qualifier values can
be used to select among same-typed collections, as outlined in the
previous paragraph.
This works for constructor, setter, and field injection.
#Resource
private List<Foo> foos;
// or since 4.3
public Example(#Autowired List<Foo> foos) {}
However, it will fail for #Bean methods, ie.
#Bean
public Bar other(List<Foo> foos) {
new Bar(foos);
}
Here, Spring ignores any #Resource or #Autowired annotating the method, because it's a #Bean method, and therefore can't apply the behavior described in the documentation. However, you can use Spring Expression Language (SpEL) to refer to beans by their name. In the example above, you could use
#Bean
public Bar other(#Value("#{fooList}") List<Foo> foos) {
new Bar(foos);
}
to refer to the bean named fooList and inject that.

Reasons for autowired beans in spring being null

I've come across a problem that at run time autowired beans in a certain class are all null. I would like an answer that will cover all possibilities on why a spring autowired bean is not initialised.
Only java config is used, no xml files at all
New keywords are only used at bean definitions
All classes and fields are annotated appropriately
Eg:
#ComponentScan(...
#Configuration
public...
#Bean
public ... myBean(){
return new ...;
}
#Service
public ...
#Autowired
private ... myBean ;
And I guess this is when I am trying to use service;
#Configuration
public ...
// Constructor
service = new Service();
// Field
private Service service;
The most likely reason is object instance is not a spring bean (the one which you want to inject something) in other words: Spring does not know the instance, and therefore does not care about it
BTW: if Spring would know/take care of that instance and would not find a matching bean, then the default result for #Autowired is an exception

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