Contextos e Injeção de Dependência
Quarkus DI solution (also called ArC) is based on the Jakarta Contexts and Dependency Injection 4.1 specification. It implements the CDI Lite specification, with selected improvements on top, and passes the CDI Lite TCK. It does not implement CDI Full. See also the list of supported features and limitations. Most of the existing CDI code should work just fine but there are some small differences which follow from the Quarkus architecture and goals.
If you’re new to CDI we recommend you to read the Introduction to CDI first. |
The CDI integration guide has more detail on common CDI-related integration use cases, and example code for solutions. |
1. Bean Discovery
Bean discovery in CDI is a complex process which involves legacy deployment structures and accessibility requirements of the underlying module architecture.
However, Quarkus is using a simplified bean discovery.
There is only single bean archive with the bean discovery mode annotated
and no visibility boundaries.
The bean archive is synthesized from:
-
the application classes,
-
dependencies that contain a
beans.xml
descriptor (content is ignored), -
dependencies that contain a Jandex index -
META-INF/jandex.idx
, -
dependencies referenced by
quarkus.index-dependency
inapplication.properties
, -
and Quarkus integration code.
Bean classes that don’t have a bean defining annotation are not discovered.
This behavior is defined by CDI.
But producer methods and fields and observer methods are discovered even if the declaring class is not annotated with a bean defining annotation (this behavior is different to what is defined in CDI).
In fact, the declaring bean classes are considered annotated with @Dependent
.
Quarkus extensions may declare additional discovery rules. For example, @Scheduled business methods are registered even if the declaring class is not annotated with a bean defining annotation.
|
1.1. How to Generate a Jandex Index
A dependency with a Jandex index is automatically scanned for beans. To generate the index just add the following plugin to your build file:
If you can’t modify the dependency, you can still index it by adding quarkus.index-dependency
entries to your application.properties
:
quarkus.index-dependency.<name>.group-id=
quarkus.index-dependency.<name>.artifact-id=(this one is optional)
quarkus.index-dependency.<name>.classifier=(this one is optional)
If no artifact-id is specified then all dependencies with the specified group-id are indexed.
|
For example, the following entries ensure that the org.acme:acme-api
dependency is indexed:
quarkus.index-dependency.acme.group-id=org.acme (1)
quarkus.index-dependency.acme.artifact-id=acme-api (2)
1 | Value is a group id for a dependency identified by name acme . |
2 | Value is an artifact id for a dependency identified by name acme . |
1.2. How To Exclude Types and Dependencies from Discovery
It may happen that some beans from third-party libraries do not work correctly in Quarkus.
A typical example is a bean injecting a portable extension.
In such case, it’s possible to exclude types and dependencies from the bean discovery.
The quarkus.arc.exclude-types
property accepts a list of string values that are used to match classes that should be excluded.
Value |
Descrição |
|
Match the fully qualified name of the class |
|
Match classes with package |
|
Match classes where the package starts with |
|
Match the simple name of the class |
quarkus.arc.exclude-types=org.acme.Foo,org.acme.*,Bar (1)(2)(3)
1 | Exclude the type org.acme.Foo . |
2 | Exclude all types from the org.acme package. |
3 | Exclude all types whose simple name is Bar |
It is also possible to exclude a dependency artifact that would be otherwise scanned for beans.
For example, because it contains a beans.xml
descriptor.
quarkus.arc.exclude-dependency.acme.group-id=org.acme (1)
quarkus.arc.exclude-dependency.acme.artifact-id=acme-services (2)
1 | Value is a group id for a dependency identified by name acme . |
2 | Value is an artifact id for a dependency identified by name acme . |
2. Native Executables and Private Members
Quarkus is using GraalVM to build a native executable. One of the limitations of GraalVM is the usage of Reflection. Reflective operations are supported but all relevant members must be registered for reflection explicitly. Those registrations result in a bigger native executable.
And if Quarkus DI needs to access a private member it has to use reflection. That’s why Quarkus users are encouraged not to use private members in their beans. This involves injection fields, constructors and initializers, observer methods, producer methods and fields, disposers and interceptor methods.
How to avoid using private members? You can use package-private modifiers:
@ApplicationScoped
public class CounterBean {
@Inject
CounterService counterService; (1)
void onMessage(@Observes Event msg) { (2)
}
}
1 | A package-private injection field. |
2 | A package-private observer method. |
Or constructor injection:
@ApplicationScoped
public class CounterBean {
private CounterService service;
CounterBean(CounterService service) { (1)
this.service = service;
}
}
1 | A package-private constructor injection. @Inject is optional in this particular case. |
3. Supported Features and Limitations
The CDI Lite specification is fully supported. The following features from CDI Full are also supported:
-
Decorators
-
Decoration of built-in beans, such as
Event
, is not supported
-
-
BeanManager
-
In addition to the
BeanContainer
methods, the following methods are supported:getInjectableReference()
,resolveDecorators()
-
-
@SessionScoped
-
Only with the Undertow extension; see here for details
-
The method invokers implementation supports asynchronous methods.
The following methods are considered asynchronous and @Dependent
instances are only destroyed when the asynchronous action completes:
-
methods that declare a return type of
CompletionStage
,Uni
, orMulti
These additional features are not covered by the CDI Lite TCK. |
4. Non-standard Features
4.1. Eager Instantiation of Beans
4.1.1. Lazy By Default
By default, CDI beans are created lazily, when needed. What exactly "needed" means depends on the scope of a bean.
-
A normal scoped bean (
@ApplicationScoped
,@RequestScoped
, etc.) is needed when a method is invoked upon an injected instance (contextual reference per the specification).In other words, injecting a normal scoped bean will not suffice because a client proxy is injected instead of a contextual instance of the bean.
-
A bean with a pseudo-scope (
@Dependent
and@Singleton
) is created when injected.
@Singleton // => pseudo-scope
class AmazingService {
String ping() {
return "amazing";
}
}
@ApplicationScoped // => normal scope
class CoolService {
String ping() {
return "cool";
}
}
@Path("/ping")
public class PingResource {
@Inject
AmazingService s1; (1)
@Inject
CoolService s2; (2)
@GET
public String ping() {
return s1.ping() + s2.ping(); (3)
}
}
1 | Injection triggers the instantiation of AmazingService . |
2 | Injection itself does not result in the instantiation of CoolService . A client proxy is injected. |
3 | The first invocation upon the injected proxy triggers the instantiation of CoolService . |
4.1.2. Startup Event
However, if you really need to instantiate a bean eagerly you can:
-
Declare an observer of the
StartupEvent
- the scope of the bean does not matter in this case:@ApplicationScoped class CoolService { void startup(@Observes StartupEvent event) { (1) } }
1 A CoolService
is created during startup to service the observer method invocation. -
Use the bean in an observer of the
StartupEvent
- normal scoped beans must be used as described in Lazy By Default:@Dependent class MyBeanStarter { void startup(@Observes StartupEvent event, AmazingService amazing, CoolService cool) { (1) cool.toString(); (2) } }
1 The AmazingService
is created during injection.2 The CoolService
is a normal scoped bean, so we have to invoke a method upon the injected proxy to force the instantiation. -
Annotate the bean with
@io.quarkus.runtime.Startup
as described in Startup annotation:@Startup (1) @ApplicationScoped public class EagerAppBean { private final String name; EagerAppBean(NameGenerator generator) { (2) this.name = generator.createName(); } }
1 For each bean annotated with @Startup
a synthetic observer ofStartupEvent
is generated. The default priority is used.2 The bean constructor is called when the application starts and the resulting contextual instance is stored in the application context.
Quarkus users are encouraged to always prefer the @Observes StartupEvent to @Initialized(ApplicationScoped.class) as explained in the Application Initialization and Termination guide.
|
4.2. Request Context Lifecycle
The request context is also active:
-
during notification of a synchronous observer method.
The request context is destroyed:
-
after the observer notification completes for an event, if it was not already active when the notification started.
An event with qualifier @Initialized(RequestScoped.class) is fired when the request context is initialized for an observer notification. Moreover, the events with qualifiers @BeforeDestroyed(RequestScoped.class) and @Destroyed(RequestScoped.class) are fired when the request context is destroyed.
|
4.2.1. How to Enable Trace Logging for Request Context Activation
You can set the TRACE
level for the logger io.quarkus.arc.requestContext
and try to analyze the log output afterwards.
application.properties
quarkus.log.category."io.quarkus.arc.requestContext".min-level=TRACE (1)
quarkus.log.category."io.quarkus.arc.requestContext".level=TRACE
1 | Também é necessário ajustar o nível mínimo de log para a categoria relevante. |
4.3. Qualified Injected Fields
In CDI, if you declare a field injection point you need to use @Inject
and optionally a set of qualifiers.
@Inject
@ConfigProperty(name = "cool")
String coolProperty;
In Quarkus, you can skip the @Inject
annotation completely if the injected field declares at least one qualifier.
@ConfigProperty(name = "cool")
String coolProperty;
With the notable exception of one special case discussed below, @Inject is still required for constructor and method injection.
|
4.4. Simplified Constructor Injection
In CDI, a normal scoped bean must always declare a no-args constructor (this constructor is normally generated by the compiler unless you declare any other constructor). However, this requirement complicates constructor injection - you need to provide a dummy no-args constructor to make things work in CDI.
@ApplicationScoped
public class MyCoolService {
private SimpleProcessor processor;
MyCoolService() { // dummy constructor needed
}
@Inject // constructor injection
MyCoolService(SimpleProcessor processor) {
this.processor = processor;
}
}
There is no need to declare dummy constructors for normal scoped bean in Quarkus - they are generated automatically.
Also, if there’s only one constructor there is no need for @Inject
.
@ApplicationScoped
public class MyCoolService {
private SimpleProcessor processor;
MyCoolService(SimpleProcessor processor) {
this.processor = processor;
}
}
We don’t generate a no-args constructor automatically if a bean class extends a class that does not declare a no-args constructor. |
4.5. Removing Unused Beans
The container attempts to remove all unused beans, interceptors and decorators during build by default.
This optimization helps to minimize the amount of generated classes, thus conserving memory.
However, Quarkus can’t detect the programmatic lookup performed via the CDI.current()
static method.
Therefore, it is possible that a removal results in a false positive error, i.e. a bean is removed although it’s actually used.
In such cases, you’ll notice a big warning in the log.
Users and extension authors have several options how to eliminate false positives.
The optimization can be disabled by setting quarkus.arc.remove-unused-beans
to none
or false
.
Quarkus also provides a middle ground where application beans are never removed whether or not they are unused, while the optimization proceeds normally for non application classes.
To use this mode, set quarkus.arc.remove-unused-beans
to fwk
or framework
.
4.5.1. What’s Removed?
Quarkus first identifies so-called unremovable beans that form the roots in the dependency tree.
A good example is a Jakarta REST resource class or a bean which declares a @Scheduled
method.
An unremovable bean:
-
is excluded from removal, or
-
has a name designated via
@Named
, or -
declares an observer method.
An unused bean:
-
is not unremovable, and
-
is not eligible for injection to any injection point in the dependency tree of unremovable beans, and
-
does not declare any producer which is eligible for injection to any injection point in the dependency tree, and
-
is not eligible for injection into any
jakarta.enterprise.inject.Instance
orjakarta.inject.Provider
injection point, and -
is not eligible for injection into any
@Inject @All List<>
injection point.
Unused interceptors and decorators are not associated with any bean.
When using the dev mode (running
|
4.5.2. How To Eliminate False Positives
Users can instruct the container to not remove any of their specific beans (even if they satisfy all the rules specified above) by annotating them with @io.quarkus.arc.Unremovable
.
This annotation can be declared on a class, a producer method or field.
Since this is not always possible, there is an option to achieve the same via application.properties
.
The quarkus.arc.unremovable-types
property accepts a list of string values that are used to match beans based on their name or package.
Value |
Descrição |
|
Match the fully qualified name of the bean class |
|
Match beans where the package of the bean class is |
|
Match beans where the package of the bean class starts with |
|
Match the simple name of the bean class |
quarkus.arc.unremovable-types=org.acme.Foo,org.acme.*,Bar
Furthermore, extensions can eliminate false positives by producing an UnremovableBeanBuildItem
.
4.6. Default Beans
Quarkus adds a capability that CDI currently does not support which is to conditionally declare a bean if no other bean with equal types and qualifiers was declared by any available means (bean class, producer, synthetic bean, …)
This is done using the @io.quarkus.arc.DefaultBean
annotation and is best explained with an example.
Say there is a Quarkus extension that among other things declares a few CDI beans like the following code does:
@Dependent
public class TracerConfiguration {
@Produces
public Tracer tracer(Reporter reporter, Configuration configuration) {
return new Tracer(reporter, configuration);
}
@Produces
@DefaultBean
public Configuration configuration() {
// create a Configuration
}
@Produces
@DefaultBean
public Reporter reporter(){
// create a Reporter
}
}
The idea is that the extension autoconfigures things for the user, eliminating a lot of boilerplate - we can just @Inject
a Tracer
wherever it is needed.
Now imagine that in our application we would like to utilize the configured Tracer
, but we need to customize it a little, for example by providing a custom Reporter
.
The only thing that would be needed in our application would be something like the following:
@Dependent
public class CustomTracerConfiguration {
@Produces
public Reporter reporter(){
// create a custom Reporter
}
}
@DefaultBean
allows extensions (or any other code for that matter) to provide defaults while backing off if beans of that type are supplied in any
way Quarkus supports.
Default beans can optionally declare @jakarta.annotation.Priority
.
If there is no priority defined, @Priority(0)
is assumed.
Priority value is used for bean ordering and during typesafe resolution to disambiguate multiple matching default beans.
@Dependent
public class CustomizedDefaultConfiguration {
@Produces
@DefaultBean
@Priority(100)
public Configuration customizedConfiguration(){
// create a customized default Configuration
// this will have priority over previously defined default bean
}
}
4.7. Enabling Beans for Quarkus Build Profile
Quarkus adds a capability that CDI currently does not support which is to conditionally enable a bean when a Quarkus build time profile is enabled,
via the @io.quarkus.arc.profile.IfBuildProfile
and @io.quarkus.arc.profile.UnlessBuildProfile
annotations.
When used in conjunction with @io.quarkus.arc.DefaultBean
, these annotations allow for the creation of different bean configurations for different build profiles.
Imagine for instance that an application contains a bean named Tracer
, which needs to do nothing when in tests or in dev mode, but works in its normal capacity for the production artifact.
An elegant way to create such beans is the following:
@Dependent
public class TracerConfiguration {
@Produces
@IfBuildProfile("prod")
public Tracer realTracer(Reporter reporter, Configuration configuration) {
return new RealTracer(reporter, configuration);
}
@Produces
@DefaultBean
public Tracer noopTracer() {
return new NoopTracer();
}
}
If instead, it is required that the Tracer
bean also works in dev mode and only default to doing nothing for tests, then @UnlessBuildProfile
would be ideal. The code would look like:
@Dependent
public class TracerConfiguration {
@Produces
@UnlessBuildProfile("test") // this will be enabled for both prod and dev build time profiles
public Tracer realTracer(Reporter reporter, Configuration configuration) {
return new RealTracer(reporter, configuration);
}
@Produces
@DefaultBean
public Tracer noopTracer() {
return new NoopTracer();
}
}
The runtime profile has absolutely no effect on the bean resolution using @IfBuildProfile and @UnlessBuildProfile .
|
It is also possible to use @IfBuildProfile and @UnlessBuildProfile on stereotypes.
|
4.8. Enabling Beans for Quarkus Build Properties
Quarkus adds a capability that CDI currently does not support which is to conditionally enable a bean when a Quarkus build time property has/has not a specific value,
via the @io.quarkus.arc.properties.IfBuildProperty
and @io.quarkus.arc.properties.UnlessBuildProperty
annotations.
When used in conjunction with @io.quarkus.arc.DefaultBean
, this annotation allow for the creation of different bean configurations for different build properties.
The scenario we mentioned above with Tracer
could also be implemented in the following way:
@Dependent
public class TracerConfiguration {
@Produces
@IfBuildProperty(name = "some.tracer.enabled", stringValue = "true")
public Tracer realTracer(Reporter reporter, Configuration configuration) {
return new RealTracer(reporter, configuration);
}
@Produces
@DefaultBean
public Tracer noopTracer() {
return new NoopTracer();
}
}
@IfBuildProperty and @UnlessBuildProperty are repeatable annotations, i.e. a bean will only be enabled if all the conditions defined by these annotations are satisfied.
|
If instead, it is required that the RealTracer
bean is only used if the some.tracer.enabled
property is not false
, then @UnlessBuildProperty
would be ideal. The code would look like:
@Dependent
public class TracerConfiguration {
@Produces
@UnlessBuildProperty(name = "some.tracer.enabled", stringValue = "false")
public Tracer realTracer(Reporter reporter, Configuration configuration) {
return new RealTracer(reporter, configuration);
}
@Produces
@DefaultBean
public Tracer noopTracer() {
return new NoopTracer();
}
}
Properties set at runtime have absolutely no effect on the bean resolution using @IfBuildProperty .
|
It is also possible to use @IfBuildProperty and @UnlessBuildProperty on stereotypes.
|
4.9. Declaring Selected Alternatives
In CDI, an alternative bean may be selected either globally for an application by means of @Priority
, or for a bean archive using a beans.xml
descriptor.
Quarkus has a simplified bean discovery and the content of beans.xml
is ignored.
However, it is also possible to select alternatives for an application using the unified configuration.
The quarkus.arc.selected-alternatives
property accepts a list of string values that are used to match alternative beans.
If any value matches then the priority of Integer#MAX_VALUE
is used for the relevant bean.
The priority declared via @Priority
or inherited from a stereotype is overridden.
Value |
Descrição |
|
Match the fully qualified name of the bean class or the bean class of the bean that declares the producer |
|
Match beans where the package of the bean class is |
|
Match beans where the package of the bean class starts with |
|
Match the simple name of the bean class or the bean class of the bean that declares the producer |
quarkus.arc.selected-alternatives=org.acme.Foo,org.acme.*,Bar
4.10. Simplified Producer Method Declaration
In CDI, a producer method must be always annotated with @Produces
.
class Producers {
@Inject
@ConfigProperty(name = "cool")
String coolProperty;
@Produces
@ApplicationScoped
MyService produceService() {
return new MyService(coolProperty);
}
}
In Quarkus, you can skip the @Produces
annotation completely if the producer method is annotated with a scope annotation, a stereotype or a qualifier.
class Producers {
@ConfigProperty(name = "cool")
String coolProperty;
@ApplicationScoped
MyService produceService() {
return new MyService(coolProperty);
}
}
4.11. Interception of Static Methods
The Interceptors specification is clear that around-invoke methods must not be declared static. However, this restriction was driven mostly by technical limitations. And since Quarkus is a build-time oriented stack that allows for additional class transformations, those limitations don’t apply anymore. It’s possible to annotate a non-private static method with an interceptor binding:
class Services {
@Logged (1)
static BigDecimal computePrice(long amount) { (2)
BigDecimal price;
// Perform computations...
return price;
}
}
1 | Logged is an interceptor binding. |
2 | Each method invocation is intercepted if there is an interceptor associated with Logged . |
4.11.1. Limitações
-
Only method-level bindings are considered for backward compatibility reasons (otherwise static methods of bean classes that declare class-level bindings would be suddenly intercepted)
-
Private static methods are never intercepted
-
InvocationContext#getTarget()
returnsnull
for obvious reasons; therefore not all existing interceptors may behave correctly when intercepting static methodsInterceptors can use InvocationContext.getMethod()
to detect static methods and adjust the behavior accordingly.
4.12. Ability to handle 'final' classes and methods
In normal CDI, classes that are marked as final
and / or have final
methods are not eligible for proxy creation,
which in turn means that interceptors and normal scoped beans don’t work properly.
This situation is very common when trying to use CDI with alternative JVM languages like Kotlin where classes and methods are final
by default.
Quarkus however, can overcome these limitations when quarkus.arc.transform-unproxyable-classes
is set to true
(which is the default value).
4.13. Container-managed Concurrency
There is no standard concurrency control mechanism for CDI beans.
Nevertheless, a bean instance can be shared and accessed concurrently from multiple threads.
In that case it should be thread-safe.
You can use standard Java constructs (volatile
, synchronized
, ReadWriteLock
, etc.) or let the container control the concurrent access.
Quarkus provides @io.quarkus.arc.Lock
and a built-in interceptor for this interceptor binding.
Each interceptor instance associated with a contextual instance of an intercepted bean holds a separate ReadWriteLock
with non-fair ordering policy.
io.quarkus.arc.Lock is a regular interceptor binding and as such can be used for any bean with any scope. However, it is especially useful for "shared" scopes, e.g. @Singleton and @ApplicationScoped .
|
import io.quarkus.arc.Lock;
@Lock (1)
@ApplicationScoped
class SharedService {
void addAmount(BigDecimal amount) {
// ...changes some internal state of the bean
}
@Lock(value = Lock.Type.READ, time = 1, unit = TimeUnit.SECONDS) (2) (3)
BigDecimal getAmount() {
// ...it is safe to read the value concurrently
}
}
1 | @Lock (which maps to @Lock(Lock.Type.WRITE) ) declared on the class instructs the container to lock the bean instance for any invocation of any business method, i.e. the client has "exclusive access" and no concurrent invocations will be allowed. |
2 | @Lock(Lock.Type.READ) overrides the value specified at class level. It means that any number of clients can invoke the method concurrently, unless the bean instance is locked by @Lock(Lock.Type.WRITE) . |
3 | You can also specify the "wait time". If it’s not possible to acquire the lock in the given time a LockException is thrown. |
4.14. Repeatable interceptor bindings
Quarkus has limited support for @Repeatable
interceptor binding annotations.
When binding an interceptor to a component, you can declare multiple @Repeatable
annotations on methods.
Repeatable interceptor bindings declared on classes and stereotypes are not supported, because there are some open questions around interactions with the Interceptors specification.
This might be added in the future.
As an example, suppose we have an interceptor that clears a cache.
The corresponding interceptor binding would be called @CacheInvalidateAll
and would be declared as @Repeatable
.
If we wanted to clear two caches at the same time, we would add @CacheInvalidateAll
twice:
@ApplicationScoped
class CachingService {
@CacheInvalidateAll(cacheName = "foo")
@CacheInvalidateAll(cacheName = "bar")
void heavyComputation() {
// ...
// some computation that updates a lot of data
// and requires 2 caches to be invalidated
// ...
}
}
This is how interceptors are used. What about creating an interceptor?
When declaring interceptor bindings of an interceptor, you can add multiple @Repeatable
annotations to the interceptor class as usual.
This is useless when the annotation members are @Nonbinding
, as would be the case for the @Cached
annotation, but is important otherwise.
For example, suppose we have an interceptor that can automatically log method invocations to certain targets.
The interceptor binding annotation @Logged
would have a member called target
, which specifies where to store the log.
Our implementation could be restricted to console logging and file logging:
@Interceptor
@Logged(target = "console")
@Logged(target = "file")
class NaiveLoggingInterceptor {
// ...
}
Other interceptors could be provided to log method invocations to different targets.
4.15. Caching the Result of Programmatic Lookup
In certain situations, it is practical to obtain a bean instance programmatically via an injected jakarta.enterprise.inject.Instance
and Instance.get()
.
However, according to the specification the get()
method must identify the matching bean and obtain a contextual reference.
As a consequence, a new instance of a @Dependent
bean is returned from each invocation of get()
.
Moreover, this instance is a dependent object of the injected Instance
.
This behavior is well-defined, but it may lead to unexpected errors and memory leaks.
Therefore, Quarkus comes with the io.quarkus.arc.WithCaching
annotation.
An injected Instance
annotated with this annotation will cache the result of the Instance#get()
operation.
The result is computed on the first call and the same value is returned for all subsequent calls, even for @Dependent
beans.
class Producer {
AtomicLong nextLong = new AtomicLong();
AtomicInteger nextInt = new AtomicInteger();
@Dependent
@Produces
Integer produceInt() {
return nextInt.incrementAndGet();
}
@Dependent
@Produces
Long produceLong() {
return nextLong.incrementAndGet();
}
}
class Consumer {
@Inject
Instance<Long> longInstance;
@Inject
@WithCaching
Instance<Integer> intInstance;
// this method should always return true
// Producer#produceInt() is only called once
boolean pingInt() {
return intInstance.get().equals(intInstance.get());
}
// this method should always return false
// Producer#produceLong() is called twice per each pingLong() invocation
boolean pingLong() {
return longInstance.get().equals(longInstance.get());
}
}
It is also possible to clear the cached value via io.quarkus.arc.InjectableInstance.clearCache() . In this case, you’ll need to inject the Quarkus-specific io.quarkus.arc.InjectableInstance instead of jakarta.enterprise.inject.Instance .
|
4.16. Declaratively Choose Beans That Can Be Obtained by Programmatic Lookup
It is sometimes useful to narrow down the set of beans that can be obtained by programmatic lookup via jakarta.enterprise.inject.Instance
.
Typically, a user needs to choose the appropriate implementation of an interface based on a runtime configuration property.
Imagine that we have two beans implementing the interface org.acme.Service
.
You can’t inject the org.acme.Service
directly unless your implementations declare a CDI qualifier.
However, you can inject the Instance<Service>
instead, then iterate over all implementations and choose the correct one manually.
Alternatively, you can use the @LookupIfProperty
and @LookupUnlessProperty
annotations.
@LookupIfProperty
indicates that a bean should only be obtained if a runtime configuration property matches the provided value.
@LookupUnlessProperty
, on the other hand, indicates that a bean should only be obtained if a runtime configuration property does not match the provided value.
@LookupIfProperty
Example interface Service {
String name();
}
@LookupIfProperty(name = "service.foo.enabled", stringValue = "true")
@ApplicationScoped
class ServiceFoo implements Service {
public String name() {
return "foo";
}
}
@ApplicationScoped
class ServiceBar implements Service {
public String name() {
return "bar";
}
}
@ApplicationScoped
class Client {
@Inject
Instance<Service> service;
void printServiceName() {
// This will print "bar" if the property "service.foo.enabled" is NOT set to "true"
// If "service.foo.enabled" is set to "true" then service.get() would result in an AmbiguousResolutionException
System.out.println(service.get().name());
}
}
4.17. Sorting beans obtained with programmatic lookup
If there is more than one bean that matches the required type and qualifiers and is eligible for injection, it is possible to iterate (or stream) available bean instances.
Beans returned by both stream and iterator methods are sorted by priority as defined by io.quarkus.arc.InjectableBean#getPriority()
. Higher priority goes first.
If no priority is explicitly declared, 0 is assumed.
interface Service {
}
@Priority(100)
@ApplicationScoped
class FirstService implements Service {
}
@Priority(10)
@ApplicationScoped
class SecondService implements Service {
}
@ApplicationScoped
class ThirdService implements Service {
}
@ApplicationScoped
class Client {
@Inject
Instance<Service> serviceInstance;
void printServiceName() {
if(service.isAmbiguous()){
for (Service service : serviceInstance) {
// FirstService, SecondService, ThirdService
}
}
}
}
4.18. Injecting Multiple Bean Instances Intuitively
In CDI, it’s possible to inject multiple bean instances (aka contextual references) via the jakarta.enterprise.inject.Instance
which implements java.lang.Iterable
.
However, it’s not exactly intuitive.
Therefore, a new way was introduced in Quarkus - you can inject a java.util.List
annotated with the io.quarkus.arc.All
qualifier.
The type of elements in the list is used as the required type when performing the lookup.
@ApplicationScoped
public class Processor {
@Inject
@All
List<Service> services; (1) (2)
}
1 | The injected instance is an immutable list of the contextual references of the disambiguated beans. |
2 | For this injection point the required type is Service and no additional qualifiers are declared. |
The list is sorted by priority as defined by io.quarkus.arc.InjectableBean#getPriority() . Higher priority goes first. In general, the @jakarta.annotation.Priority annotation can be used to assign the priority to a class bean, producer method or producer field.
|
If an injection point declares no other qualifier than @All
then @Any
is used, i.e. the behavior is equivalent to @Inject @Any Instance<Service>
.
You can also inject a list of bean instances wrapped in io.quarkus.arc.InstanceHandle
.
This can be useful if you need to inspect the related bean metadata.
@ApplicationScoped
public class Processor {
@Inject
@All
List<InstanceHandle<Service>> services;
public void doSomething() {
for (InstanceHandle<Service> handle : services) {
if (handle.getBean().getScope().equals(Dependent.class)) {
handle.get().process();
break;
}
}
}
}
Neither a type variable nor a wildcard is a legal type parameter for an @All List<> injection point, i.e. @Inject @All List<?> all is not supported and results in a deployment error.
|
It is also possible to obtain the list of all bean instance handles programmatically via the Arc.container().listAll() methods.
|
4.19. Ignoring Class-Level Interceptor Bindings for Methods and Constructors
If a managed bean declares interceptor binding annotations on the class level, the corresponding @AroundInvoke
interceptors will apply to all business methods.
Similarly, the corresponding @AroundConstruct
interceptors will apply to the bean constructor.
For example, suppose we have a logging interceptor with the @Logged
binding annotation and a tracing interceptor with the @Traced
binding annotation:
@ApplicationScoped
@Logged
public class MyService {
public void doSomething() {
...
}
@Traced
public void doSomethingElse() {
...
}
}
In this example, both doSomething
and doSomethingElse
will be intercepted by the hypothetical logging interceptor.
Additionally, the doSomethingElse
method will be intercepted by the hypothetical tracing interceptor.
Now, if that @Traced
interceptor also performed all the necessary logging, we’d like to skip the @Logged
interceptor for this method, but keep it for all other methods.
To achieve that, you can annotate the method with @NoClassInterceptors
:
@Traced
@NoClassInterceptors
public void doSomethingElse() {
...
}
The @NoClassInterceptors
annotation may be put on methods and constructors and means that all class-level interceptors are ignored for these methods and constructors.
In other words, if a method/constructor is annotated @NoClassInterceptors
, then the only interceptors that will apply to this method/constructor are interceptors declared directly on the method/constructor.
This annotation affects only business method interceptors (@AroundInvoke
) and constructor lifecycle callback interceptors (@AroundConstruct
).
4.20. Exceptions Thrown By An Asynchronous Observer Method
If an exception is thrown by an asynchronous observer then the CompletionStage
returned by the fireAsync()
method completes exceptionally so that the event producer may react appropriately.
However, if the event producer does not care then the exception is ignored silently.
Therefore, Quarkus logs an error message by default.
It is also possible to implement a custom AsyncObserverExceptionHandler
.
A bean that implements this interface should be @jakarta.inject.Singleton
or @jakarta.enterprise.context.ApplicationScoped
.
NoopAsyncObserverExceptionHandler
@Singleton
public class NoopAsyncObserverExceptionHandler implements AsyncObserverExceptionHandler {
void handle(Throwable throwable, ObserverMethod<?> observerMethod, EventContext<?> eventContext) {
// do nothing
}
}
4.21. Intercepted self-invocation
Quarkus supports what is known as intercepted self-invocation or just self-interception - a scenario where CDI bean invokes its own intercepted method from within another method while triggering any associated interceptors. This is a non-standard feature as CDI specification doesn’t define whether self-interception should work or not.
Suppose we have a CDI bean with two methods, one of which has the @Transactional
interceptor binding associated with it:
@ApplicationScoped
public class MyService {
@Transactional (1)
void doSomething() {
// some application logic
}
void doSomethingElse() {
doSomething();(2)
}
}
1 | One or more interceptor bindings; @Transactional is just an example. |
2 | Non-intercepted method invoking another method from the same bean that has associated binding(s); this will trigger interception. |
In the above example, any code calling the doSomething()
method triggers interception - in this case, the method becomes transactional.
This is regardless of whether the invocation originated directly from the MyService
bean (such as MyService#doSomethingElse
) or from some other bean.
4.22. Intercepting Producer Methods and Synthetic Beans
By default, interception is only supported for managed beans (also known as class-based beans).
To support interception of producer methods and synthetic beans, the CDI specification includes an InterceptionFactory
, which is a runtime oriented concept and therefore cannot be supported in Quarkus.
Instead, Quarkus has its own API: InterceptionProxy
and @BindingsSource
.
The InterceptionProxy
is very similar to InterceptionFactory
: it creates a proxy that applies @AroundInvoke
interceptors before forwarding the method call to the target instance.
The @BindingsSource
annotation allows setting interceptor bindings in case the intercepted class is external and cannot be changed.
import io.quarkus.arc.InterceptionProxy;
@ApplicationScoped
class MyProducer {
@Produces
MyClass produce(InterceptionProxy<MyClass> proxy) { (1)
return proxy.create(new MyClass()); (2)
}
}
1 | Declares an injection point of type InterceptionProxy<MyClass> .
This means that at build time, a subclass of MyClass is generated that does the interception and forwarding.
Note that the type argument must be identical to the return type of the producer method. |
2 | Creates an instance of the interception proxy for the given instance of MyClass .
The method calls will be forwarded to this target instance after all interceptors run. |
In this example, interceptor bindings are read from the MyClass
class.
Note that InterceptionProxy only supports @AroundInvoke interceptors declared on interceptor classes.
Other kinds of interception, as well as @AroundInvoke interceptors declared on the target class and its superclasses, are not supported.
|
The intercepted class should be proxyable and therefore should not be final
, should not have non-private final
methods, and should have a non-private zero-parameter constructor.
If it isn’t, a bytecode transformation will attempt to fix it if enabled, but note that adding a zero-parameter constructor is not always possible.
It is often the case that the produced classes come from external libraries and don’t contain interceptor binding annotations at all.
To support such cases, the @BindingsSource
annotation may be declared on the InterceptionProxy
parameter:
import io.quarkus.arc.BindingsSource;
import io.quarkus.arc.InterceptionProxy;
abstract class MyClassBindings { (1)
@MyInterceptorBinding
abstract String doSomething();
}
@ApplicationScoped
class MyProducer {
@Produces
MyClass produce(@BindingsSource(MyClassBindings.class) InterceptionProxy<MyClass> proxy) { (2)
return proxy.create(new MyClass());
}
}
1 | A class that mirrors the MyClass structure and contains interceptor bindings. |
2 | The @BindingsSource annotation says that interceptor bindings for MyClass should be read from MyClassBindings . |
The concept of bindings source is a build-time friendly equivalent of InterceptionFactory.configure()
.
Producer method interception and synthetic bean interception only works for instance methods. Interception of Static Methods is not supported for producer methods and synthetic beans. |
4.22.1. Declaring @BindingsSource
The @BindingsSource
annotation specifies a class that mirrors the structure of the intercepted class.
Interceptor bindings are then read from that class and treated as if they were declared on the intercepted class.
Specifically: class-level interceptor bindings declared on the bindings source class are treated as class-level bindings of the intercepted class.
Method-level interceptor bindings declared on the bindings source class are treated as method-level bindings of a method with the same name, return type, parameter types and static
flag of the intercepted class.
It is common to make the bindings source class and methods abstract
so that you don’t have to write method bodies:
abstract class MyClassBindings {
@MyInterceptorBinding
abstract String doSomething();
}
Since this class is never instantiated and its method are never invoked, this is okay, but it’s also possible to create a non-abstract
class:
class MyClassBindings {
@MyInterceptorBinding
String doSomething() {
return null; (1)
}
}
1 | The method body does not matter. |
Note that for generic classes, the type variable names must also be identical. For example, for the following class:
class MyClass<T> {
T doSomething() {
...
}
void doSomethingElse(T param) {
...
}
}
the bindings source class must also use T
as the name of the type variable:
abstract class MyClassBindings<T> {
@MyInterceptorBinding
abstract T doSomething();
}
You don’t need to declare methods that are not annotated simply because they exist on the intercepted class. If you want to add method-level bindings to a subset of methods, you only have to declare the methods that are supposed to have an interceptor binding. If you only want to add class-level bindings, you don’t have to declare any methods at all.
These annotations can be present on a bindings source class:
-
interceptor bindings: on the class and on the methods
-
stereotypes: on the class
-
@NoClassInterceptors
: on the methods
Any other annotation present on a bindings source class is ignored.
4.22.2. Synthetic Beans
Using InterceptionProxy
in synthetic beans is similar.
First, you have to declare that your synthetic bean injects the InterceptionProxy
:
public void register(RegistrationContext context) {
context.configure(MyClass.class)
.types(MyClass.class)
.injectInterceptionProxy() (1)
.creator(MyClassCreator.class)
.done();
}
1 | Once again, this means that at build time, a subclass of MyClass is generated that does the interception and forwarding. |
Second, you have to obtain the InterceptionProxy
from the SyntheticCreationalContext
in the BeanCreator
and use it:
public MyClass create(SyntheticCreationalContext<MyClass> context) {
InterceptionProxy<MyClass> proxy = context.getInterceptionProxy(); (1)
return proxy.create(new MyClass());
}
1 | Obtains the InterceptionProxy for MyClass , as declared above.
It would also be possible to use the getInjectedReference() method, passing a TypeLiteral , but getInterceptionProxy() is easier. |
There’s also an equivalent of @BindingsSource
.
The injectInterceptionProxy()
method has an overload with a parameter:
public void register(RegistrationContext context) {
context.configure(MyClass.class)
.types(MyClass.class)
.injectInterceptionProxy(MyClassBindings.class) (1)
.creator(MyClassCreator.class)
.done();
}
1 | The argument is the bindings source class. |
4.23. Instance.Handle.close()
Behavior
Per the CDI specification, the Instance.Handle.close()
method always delegates to destroy()
.
In ArC, this is only true in the Strict Mode.
In the default mode, the close()
method only delegates to destroy()
when the bean is @Dependent
(or when the instance handle does not represent a CDI contextual object).
When the instance handle represents a bean of any other scope, the close()
method does nothing; the bean is left as is and will be destroyed whenever its context is destroyed.
This is to make the following code behave as one would naively expect:
Instance<T> instance = ...;
try (Instance.Handle<T> handle : instance.getHandle()) {
T value = handle.get();
... use value ...
}
The @Dependent
beans are destroyed immediately, while other beans are not destroyed at all.
This is important when multiple beans of different scopes might be returned by the Instance
.
5. Pitfalls with Reactive Programming
CDI is a purely synchronous framework. Its notion of asynchrony is very limited and based solely on thread pools and thread offloading. Therefore, there is a number of pitfalls when using CDI together with reactive programming.
5.1. Detecting When Blocking Is Allowed
The io.quarkus.runtime.BlockingOperationControl#isBlockingAllowed()
method can be used to detect whether blocking is allowed on the current thread.
When it is not, and you need to perform a blocking operation, you have to offload it to another thread.
The easiest way is to use the Vertx.executeBlocking()
method:
import io.quarkus.runtime.BlockingOperationControl;
@ApplicationScoped
public class MyBean {
@Inject
Vertx vertx;
@PostConstruct
void init() {
if (BlockingOperationControl.isBlockingAllowed()) {
somethingThatBlocks();
} else {
vertx.executeBlocking(() -> {
somethingThatBlocks();
return null;
});
}
}
void somethingThatBlocks() {
// use the file system or JDBC, call a REST service, etc.
Thread.sleep(5000);
}
}
5.2. Asynchronous Observers
CDI asynchronous observers (@ObservesAsync
) are not aware of reactive programming and are not meant to be used as part of reactive pipelines.
The observer methods are meant to be synchronous, they are just offloaded to a thread pool.
The Event.fireAsync()
method returns a CompletionStage
that completes when all observers are notified.
If all observers were notified successfully, the CompletionStage
completes with the event payload.
If some observers have thrown an exception, the CompletionStage
completes exceptionally with a CompletionException
.
The return type of the observer does not matter. The return value of the observer is ignored.
You may declare an observer method that has a return type of CompletionStage<>
or Uni<>
, but neither the return type nor the actual return value affect the result of Event.fireAsync()
.
Further, if the observer declares a return type of Uni<>
, the returned Uni
will not be subscribed to, so it is quite possible that part of the observer logic will not even execute.
Therefore, it is recommended that observer methods, both synchronous and asynchronous, are always declared void
.
6. Build Time Extensions
Quarkus incorporates build-time optimizations in order to provide instant startup and low memory footprint. The downside of this approach is that CDI Portable Extensions cannot be supported. Nevertheless, most of the functionality can be achieved using Quarkus extensions. See the integration guide for more information.
7. Dev mode
In dev mode, two special endpoints are registered automatically to provide some basic debug info in the JSON format:
-
HTTP GET
/q/arc
- returns the summary; number of beans, config properties, etc. -
HTTP GET
/q/arc/beans
- returns the list of all beans-
You can use query params to filter the output:
-
scope
- include beans with scope that ends with the given value, i.e.http://localhost:8080/q/arc/beans?scope=ApplicationScoped
-
beanClass
- include beans with bean class that starts with the given value, i.e.http://localhost:8080/q/arc/beans?beanClass=org.acme.Foo
-
kind
- include beans of the specified kind (CLASS
,PRODUCER_FIELD
,PRODUCER_METHOD
,INTERCEPTOR
orSYNTHETIC
), i.e.http://localhost:8080/q/arc/beans?kind=PRODUCER_METHOD
-
-
-
HTTP GET
/q/arc/removed-beans
- returns the list of unused beans removed during build -
HTTP GET
/q/arc/observers
- returns the list of all observer methods
These endpoints are only available in dev mode, i.e. when you run your application via mvn quarkus:dev (or ./gradlew quarkusDev ).
|
8. Strict Mode
By default, ArC does not perform all validations required by the CDI specification. It also improves CDI usability in many ways, some of them being directly against the specification.
To pass the CDI Lite TCK, ArC also has a strict mode. This mode enables additional validations and disables certain improvements that conflict with the specification.
To enable the strict mode, use the following configuration:
quarkus.arc.strict-compatibility=true
Some other features affect specification compatibility as well:
To get a behavior closer to the specification, these features should be disabled.
Applications are recommended to use the default, non-strict mode, which makes CDI more convenient to use. The "strictness" of the strict mode (the set of additional validations and the set of disabled improvements on top of the CDI specification) may change over time.
9. ArC Configuration Reference
Propriedade de Configuração Fixa no Momento da Compilação - Todas as outras propriedades de configuração podem ser sobrepostas em tempo de execução.
Configuration property |
Tipo |
Padrão |
||
---|---|---|---|---|
An unused bean:
Environment variable: Show more |
string |
|
||
If set to true Environment variable: Show more |
boolean |
|
||
If set to true, the bytecode of unproxyable beans will be transformed. This ensures that a proxy/subclass can be created properly. If the value is set to false, then an exception is thrown at build time indicating that a subclass/proxy could not be created. Quarkus performs the following transformations when this setting is enabled:
Environment variable: Show more |
boolean |
|
||
If set to true, the bytecode of private fields that are injection points will be transformed to package private. This ensures that field injection can be performed completely reflection-free. If the value is set to false, then a reflection fallback is used to perform the injection. Environment variable: Show more |
boolean |
|
||
If set to true (the default), the build fails if a private method that is neither an observer nor a producer, is annotated with an interceptor binding. An example of this is the use of Environment variable: Show more |
boolean |
|
||
The list of selected alternatives for an application. An element value can be:
Environment variable: Show more |
list of string |
|||
If set to true then Environment variable: Show more |
boolean |
|
||
The list of types that should be excluded from discovery. An element value can be:
Environment variable: Show more |
list of string |
|||
List of types that should be considered unremovable regardless of whether they are directly used or not. This is a configuration option equivalent to using An element value can be:
Environment variable: Show more |
list of string |
|||
Tipo |
Padrão |
|||
The maven groupId of the artifact. Environment variable: Show more |
string |
required |
||
The maven artifactId of the artifact (optional). Environment variable: Show more |
string |
|||
The maven classifier of the artifact (optional). Environment variable: Show more |
string |
|||
If set to true then the container attempts to detect "unused removed beans" false positives during programmatic lookup at runtime. You can disable this feature to conserve some memory when running your application in production. Environment variable: Show more |
boolean |
|
||
If set to true then the container attempts to detect wrong usages of annotations and eventually fails the build to prevent unexpected behavior of a Quarkus application. A typical example is Environment variable: Show more |
boolean |
|
||
If set to The strict mode is mainly introduced to allow passing the CDI Lite TCK. Applications are recommended to use the default, non-strict mode, which makes CDI more convenient to use. The "strictness" of the strict mode (the set of additional validations and the set of disabled improvements on top of the CDI specification) may change over time. Note that Environment variable: Show more |
boolean |
|
||
If set to true then the container monitors business method invocations and fired events during the development mode.
Environment variable: Show more |
boolean |
|
||
If set to true then the dependency graphs are generated and available in the Dev UI. Environment variable: Show more |
boolean |
|
||
If set to true then disable Environment variable: Show more |
boolean |
|
||
The list of packages that will not be checked for split package issues. A package string representation can be:
Environment variable: Show more |
list of string |
|||
If set to true and the SmallRye Context Propagation extension is present then the CDI contexts will be propagated by means of the MicroProfile Context Propagation API. Specifically, a Environment variable: Show more |
boolean |
|