public interface Binder
Injector
. Guice provides this object to your
application's Module
implementors so they may each contribute
their own bindings and other registrations.
Guice uses an embedded domain-specific language, or EDSL, to help you
create bindings simply and readably. This approach is great for overall
usability, but it does come with a small cost: it is difficult to
learn how to use the Binding EDSL by reading
method-level javadocs. Instead, you should consult the series of
examples below. To save space, these examples omit the opening
binder
, just as you will if your module extends
AbstractModule
.
bind(ServiceImpl.class);This statement does essentially nothing; it "binds the
ServiceImpl
class to itself" and does not change Guice's default behavior. You may still
want to use this if you prefer your Module
class to serve as an
explicit manifest for the services it provides. Also, in rare cases,
Guice may be unable to validate a binding at injector creation time unless it
is given explicitly.
bind(Service.class).to(ServiceImpl.class);Specifies that a request for a
Service
instance with no binding
annotations should be treated as if it were a request for a
ServiceImpl
instance. This overrides the function of any
@ImplementedBy
or @ProvidedBy
annotations found on Service
, since Guice will have already
"moved on" to ServiceImpl
before it reaches the point when it starts
looking for these annotations.
bind(Service.class).toProvider(ServiceProvider.class);In this example,
ServiceProvider
must extend or implement
Provider<Service>
. This binding specifies that Guice should resolve
an unannotated injection request for Service
by first resolving an
instance of ServiceProvider
in the regular way, then calling
get()
on the resulting Provider instance to obtain the
Service
instance.
The Provider
you use here does not have to be a "factory"; that
is, a provider which always creates each instance it provides.
However, this is generally a good practice to follow. You can then use
Guice's concept of scopes
to guide when creation should happen
-- "letting Guice work for you".
bind(Service.class).annotatedWith(Red.class).to(ServiceImpl.class);Like the previous example, but only applies to injection requests that use the binding annotation
@Red
. If your module also includes bindings
for particular values of the @Red
annotation (see below),
then this binding will serve as a "catch-all" for any values of @Red
that have no exact match in the bindings.
bind(ServiceImpl.class).in(Singleton.class); // or, alternatively bind(ServiceImpl.class).in(Scopes.SINGLETON);Either of these statements places the
ServiceImpl
class into
singleton scope. Guice will create only one instance of ServiceImpl
and will reuse it for all injection requests of this type. Note that it is
still possible to bind another instance of ServiceImpl
if the second
binding is qualified by an annotation as in the previous example. Guice is
not overly concerned with preventing you from creating multiple
instances of your "singletons", only with enabling your application to
share only one instance if that's all you tell Guice you need.
Note: a scope specified in this way overrides any scope that
was specified with an annotation on the ServiceImpl
class.
Besides Singleton
/Scopes.SINGLETON
, there are
servlet-specific scopes available in
com.google.inject.servlet.ServletScopes
, and your Modules can
contribute their own custom scopes for use here as well.
bind(new TypeLiteral<PaymentService<CreditCard>>() {}) .to(CreditCardPaymentService.class);This admittedly odd construct is the way to bind a parameterized type. It tells Guice how to honor an injection request for an element of type
PaymentService<CreditCard>
. The class
CreditCardPaymentService
must implement the
PaymentService<CreditCard>
interface. Guice cannot currently bind or
inject a generic type, such as Set<E>
; all type parameters must be
fully specified.
bind(Service.class).toInstance(new ServiceImpl()); // or, alternatively bind(Service.class).toInstance(SomeLegacyRegistry.getService());In this example, your module itself, not Guice, takes responsibility for obtaining a
ServiceImpl
instance, then asks Guice to always use
this single instance to fulfill all Service
injection requests. When
the Injector
is created, it will automatically perform field
and method injection for this instance, but any injectable constructor on
ServiceImpl
is simply ignored. Note that using this approach results
in "eager loading" behavior that you can't control.
bindConstant().annotatedWith(ServerHost.class).to(args[0]);Sets up a constant binding. Constant injections must always be annotated. When a constant binding's value is a string, it is eligile for conversion to all primitive types, to
all enums
, and to
class literals
. Conversions for other types can be
configured using convertToTypes()
.
@Color("red") Color red; // A member variable (field) . . . red = MyModule.class.getDeclaredField("red").getAnnotation(Color.class); bind(Service.class).annotatedWith(red).to(RedService.class);If your binding annotation has parameters you can apply different bindings to different specific values of your annotation. Getting your hands on the right instance of the annotation is a bit of a pain -- one approach, shown above, is to apply a prototype annotation to a field in your module class, so that you can read this annotation instance and give it to Guice.
bind(Service.class) .annotatedWith(Names.named("blue")) .to(BlueService.class);Differentiating by names is a common enough use case that we provided a standard annotation,
@Named
. Because of
Guice's library support, binding by name is quite easier than in the
arbitrary binding annotation case we just saw. However, remember that these
names will live in a single flat namespace with all the other names used in
your application.
The above list of examples is far from exhaustive. If you can think of how the concepts of one example might coexist with the concepts from another, you can most likely weave the two together. If the two concepts make no sense with each other, you most likely won't be able to do it. In a few cases Guice will let something bogus slip by, and will then inform you of the problems at runtime, as soon as you try to create your Injector.
The other methods of Binder such as bindScope(java.lang.Class<? extends java.lang.annotation.Annotation>, org.elasticsearch.common.inject.Scope)
,
install(org.elasticsearch.common.inject.Module)
, requestStaticInjection(java.lang.Class<?>...)
,
addError(java.lang.String, java.lang.Object...)
and currentStage()
are not part of the Binding EDSL;
you can learn how to use these in the usual way, from the method
documentation.
Modifier and Type | Method and Description |
---|---|
void |
addError(Message message)
Records an error message to be presented to the user at a later time.
|
void |
addError(java.lang.String message,
java.lang.Object... arguments)
Records an error message which will be presented to the user at a later
time.
|
void |
addError(java.lang.Throwable t)
Records an exception, the full details of which will be logged, and the
message of which will be presented to the user at a later
time.
|
<T> AnnotatedBindingBuilder<T> |
bind(java.lang.Class<T> type)
See the EDSL examples at
Binder . |
<T> LinkedBindingBuilder<T> |
bind(Key<T> key)
See the EDSL examples at
Binder . |
<T> AnnotatedBindingBuilder<T> |
bind(TypeLiteral<T> typeLiteral)
See the EDSL examples at
Binder . |
AnnotatedConstantBindingBuilder |
bindConstant()
See the EDSL examples at
Binder . |
void |
bindListener(Matcher<? super TypeLiteral<?>> typeMatcher,
TypeListener listener)
Registers a listener for injectable types.
|
void |
bindScope(java.lang.Class<? extends java.lang.annotation.Annotation> annotationType,
Scope scope)
Binds a scope to an annotation.
|
void |
convertToTypes(Matcher<? super TypeLiteral<?>> typeMatcher,
TypeConverter converter)
Binds a type converter.
|
Stage |
currentStage()
Gets the current stage.
|
<T> MembersInjector<T> |
getMembersInjector(java.lang.Class<T> type)
Returns the members injector used to inject dependencies into methods and fields on instances
of the given type
T . |
<T> MembersInjector<T> |
getMembersInjector(TypeLiteral<T> typeLiteral)
Returns the members injector used to inject dependencies into methods and fields on instances
of the given type
T . |
<T> Provider<T> |
getProvider(java.lang.Class<T> type)
Returns the provider used to obtain instances for the given injection type.
|
<T> Provider<T> |
getProvider(Key<T> key)
Returns the provider used to obtain instances for the given injection key.
|
void |
install(Module module)
Uses the given module to configure more bindings.
|
PrivateBinder |
newPrivateBinder()
Creates a new private child environment for bindings and other configuration.
|
void |
requestInjection(java.lang.Object instance)
Upon successful creation, the
Injector will inject instance fields
and methods of the given object. |
<T> void |
requestInjection(TypeLiteral<T> type,
T instance)
Upon successful creation, the
Injector will inject instance fields
and methods of the given object. |
void |
requestStaticInjection(java.lang.Class<?>... types)
Upon successful creation, the
Injector will inject static fields
and methods in the given classes. |
Binder |
skipSources(java.lang.Class... classesToSkip)
Returns a binder that skips
classesToSkip when identify the
calling code. |
Binder |
withSource(java.lang.Object source)
Returns a binder that uses
source as the reference location for
configuration errors. |
void bindScope(java.lang.Class<? extends java.lang.annotation.Annotation> annotationType, Scope scope)
<T> LinkedBindingBuilder<T> bind(Key<T> key)
Binder
.<T> AnnotatedBindingBuilder<T> bind(TypeLiteral<T> typeLiteral)
Binder
.<T> AnnotatedBindingBuilder<T> bind(java.lang.Class<T> type)
Binder
.AnnotatedConstantBindingBuilder bindConstant()
Binder
.<T> void requestInjection(TypeLiteral<T> type, T instance)
Injector
will inject instance fields
and methods of the given object.type
- of instanceinstance
- for which members will be injectedvoid requestInjection(java.lang.Object instance)
Injector
will inject instance fields
and methods of the given object.instance
- for which members will be injectedvoid requestStaticInjection(java.lang.Class<?>... types)
Injector
will inject static fields
and methods in the given classes.types
- for which static members will be injectedvoid install(Module module)
Stage currentStage()
void addError(java.lang.String message, java.lang.Object... arguments)
String.format(String, Object[])
to insert the arguments into the
message.void addError(java.lang.Throwable t)
void addError(Message message)
<T> Provider<T> getProvider(Key<T> key)
Injector
has been
created. The provider will throw an IllegalStateException
if you
try to use it beforehand.<T> Provider<T> getProvider(java.lang.Class<T> type)
Injector
has been
created. The provider will throw an IllegalStateException
if you
try to use it beforehand.<T> MembersInjector<T> getMembersInjector(TypeLiteral<T> typeLiteral)
T
. The returned members injector will not be valid until the main
Injector
has been created. The members injector will throw an IllegalStateException
if you try to use it beforehand.typeLiteral
- type to get members injector for<T> MembersInjector<T> getMembersInjector(java.lang.Class<T> type)
T
. The returned members injector will not be valid until the main
Injector
has been created. The members injector will throw an IllegalStateException
if you try to use it beforehand.type
- type to get members injector forvoid convertToTypes(Matcher<? super TypeLiteral<?>> typeMatcher, TypeConverter converter)
typeMatcher
- matches types the converter can handleconverter
- converts valuesvoid bindListener(Matcher<? super TypeLiteral<?>> typeMatcher, TypeListener listener)
typeMatcher
- that matches injectable types the listener should be notified oflistener
- for injectable types matched by typeMatcherBinder withSource(java.lang.Object source)
source
as the reference location for
configuration errors. This is typically a StackTraceElement
for .java
source but it could any binding source, such as the
path to a .properties
file.source
- any object representing the source location and has a
concise toString()
valueBinder skipSources(java.lang.Class... classesToSkip)
classesToSkip
when identify the
calling code. The caller's StackTraceElement
is used to locate
the source of configuration errors.classesToSkip
- library classes that create bindings on behalf of
their clients.PrivateBinder newPrivateBinder()
PrivateModule
for details.