There are certain common kinds of properties, that, though we can implement them manually every time we need them, would be very nice to implement once and for all, and put into a library. Examples include:
To cover these (and other) cases, Kotlin supports delegated properties:
class Example { var p: String by Delegate() }
The syntax is: val/var <property name>: <Type> by <expression>
. The expression after by is the delegate, because get()
(and set()
) corresponding to the property will be delegated to its getValue()
and setValue()
methods. Property delegates don’t have to implement any interface, but they have to provide a getValue()
function (and setValue()
— for vars). For example:
class Delegate { operator fun getValue(thisRef: Any?, property: KProperty<*>): String { return "$thisRef, thank you for delegating '${property.name}' to me!" } operator fun setValue(thisRef: Any?, property: KProperty<*>, value: String) { println("$value has been assigned to '${property.name}' in $thisRef.") } }
When we read from p
that delegates to an instance of Delegate
, the getValue()
function from Delegate
is called, so that its first parameter is the object we read p
from and the second parameter holds a description of p
itself (e.g. you can take its name). For example:
val e = Example() println(e.p)
This prints:
Example@33a17727, thank you for delegating ‘p’ to me!
Similarly, when we assign to p
, the setValue()
function is called. The first two parameters are the same, and the third holds the value being assigned:
e.p = "NEW"
This prints
NEW has been assigned to ‘p’ in Example@33a17727.
The specification of the requirements to the delegated object can be found below.
Note that since Kotlin 1.1 you can declare a delegated property inside a function or code block, it shouldn't necessarily be a member of a class. Below you can find the example.
The Kotlin standard library provides factory methods for several useful kinds of delegates.
lazy()
is a function that takes a lambda and returns an instance of Lazy<T>
which can serve as a delegate for implementing a lazy property: the first call to get()
executes the lambda passed to lazy()
and remembers the result, subsequent calls to get()
simply return the remembered result.
val lazyValue: String by lazy { println("computed!") "Hello" } fun main() { println(lazyValue) println(lazyValue) }
By default, the evaluation of lazy properties is synchronized: the value is computed only in one thread, and all threads will see the same value. If the synchronization of initialization delegate is not required, so that multiple threads can execute it simultaneously, pass LazyThreadSafetyMode.PUBLICATION
as a parameter to the lazy()
function. And if you're sure that the initialization will always happen on a single thread, you can use LazyThreadSafetyMode.NONE
mode, which doesn't incur any thread-safety guarantees and the related overhead.
Delegates.observable()
takes two arguments: the initial value and a handler for modifications. The handler gets called every time we assign to the property (after the assignment has been performed). It has three parameters: a property being assigned to, the old value and the new one:
import kotlin.properties.Delegates class User { var name: String by Delegates.observable("<no name>") { prop, old, new -> println("$old -> $new") } } fun main() { val user = User() user.name = "first" user.name = "second" }
If you want to be able to intercept an assignment and "veto" it, use vetoable()
instead of observable()
. The handler passed to the vetoable
is called before the assignment of a new property value has been performed.
One common use case is storing the values of properties in a map. This comes up often in applications like parsing JSON or doing other “dynamic” things. In this case, you can use the map instance itself as the delegate for a delegated property.
class User(val map: Map<String, Any?>) { val name: String by map val age: Int by map }
In this example, the constructor takes a map:
val user = User(mapOf( "name" to "John Doe", "age" to 25 ))
Delegated properties take values from this map (by the string keys –– names of properties):
class User(val map: Map<String, Any?>) { val name: String by map val age: Int by map } fun main() { val user = User(mapOf( "name" to "John Doe", "age" to 25 )) //sampleStart println(user.name) // Prints "John Doe" println(user.age) // Prints 25 //sampleEnd }
This works also for var’s properties if you use a MutableMap
instead of read-only Map
:
class MutableUser(val map: MutableMap<String, Any?>) { var name: String by map var age: Int by map }
You can declare local variables as delegated properties. For instance, you can make a local variable lazy:
fun example(computeFoo: () -> Foo) { val memoizedFoo by lazy(computeFoo) if (someCondition && memoizedFoo.isValid()) { memoizedFoo.doSomething() } }
The memoizedFoo
variable will be computed on the first access only. If someCondition
fails, the variable won't be computed at all.
Here we summarize requirements to delegate objects.
For a read-only property (i.e. a val), a delegate has to provide a function named getValue
that takes the following parameters:
thisRef
— must be the same or a supertype of the property owner (for extension properties — the type being extended);property
— must be of type KProperty<*>
or its supertype.this function must return the same type as property (or its subtype).
For a mutable property (a var), a delegate has to additionally provide a function named setValue
that takes the following parameters:
thisRef
— same as for getValue()
;property
— same as for getValue()
;new value
— must be of the same type as the property or its subtype.getValue()
and/or setValue()
functions may be provided either as member functions of the delegate class or extension functions. The latter is handy when you need to delegate property to an object which doesn't originally provide these functions. Both of the functions need to be marked with the operator
keyword.
The delegate class may implement one of the interfaces ReadOnlyProperty
and ReadWriteProperty
containing the required operator
methods. These interfaces are declared in the Kotlin standard library:
interface ReadOnlyProperty<in R, out T> { operator fun getValue(thisRef: R, property: KProperty<*>): T } interface ReadWriteProperty<in R, T> { operator fun getValue(thisRef: R, property: KProperty<*>): T operator fun setValue(thisRef: R, property: KProperty<*>, value: T) }
Under the hood for every delegated property the Kotlin compiler generates an auxiliary property and delegates to it. For instance, for the property prop
the hidden property prop$delegate
is generated, and the code of the accessors simply delegates to this additional property:
class C { var prop: Type by MyDelegate() } // this code is generated by the compiler instead: class C { private val prop$delegate = MyDelegate() var prop: Type get() = prop$delegate.getValue(this, this::prop) set(value: Type) = prop$delegate.setValue(this, this::prop, value) }
The Kotlin compiler provides all the necessary information about prop
in the arguments: the first argument this
refers to an instance of the outer class C
and this::prop
is a reflection object of the KProperty
type describing prop
itself.
Note that the syntax this::prop
to refer a bound callable reference in the code directly is available only since Kotlin 1.1.
By defining the provideDelegate
operator you can extend the logic of creating the object to which the property implementation is delegated. If the object used on the right hand side of by
defines provideDelegate
as a member or extension function, that function will be called to create the property delegate instance.
One of the possible use cases of provideDelegate
is to check property consistency when the property is created, not only in its getter or setter.
For example, if you want to check the property name before binding, you can write something like this:
class ResourceDelegate<T> : ReadOnlyProperty<MyUI, T> { override fun getValue(thisRef: MyUI, property: KProperty<*>): T { ... } } class ResourceLoader<T>(id: ResourceID<T>) { operator fun provideDelegate( thisRef: MyUI, prop: KProperty<*> ): ReadOnlyProperty<MyUI, T> { checkProperty(thisRef, prop.name) // create delegate return ResourceDelegate() } private fun checkProperty(thisRef: MyUI, name: String) { ... } } class MyUI { fun <T> bindResource(id: ResourceID<T>): ResourceLoader<T> { ... } val image by bindResource(ResourceID.image_id) val text by bindResource(ResourceID.text_id) }
The parameters of provideDelegate
are the same as for getValue
:
thisRef
— must be the same or a supertype of the property owner (for extension properties — the type being extended);property
— must be of type KProperty<*>
or its supertype.The provideDelegate
method is called for each property during the creation of the MyUI
instance, and it performs the necessary validation right away.
Without this ability to intercept the binding between the property and its delegate, to achieve the same functionality you'd have to pass the property name explicitly, which isn't very convenient:
// Checking the property name without "provideDelegate" functionality class MyUI { val image by bindResource(ResourceID.image_id, "image") val text by bindResource(ResourceID.text_id, "text") } fun <T> MyUI.bindResource( id: ResourceID<T>, propertyName: String ): ReadOnlyProperty<MyUI, T> { checkProperty(this, propertyName) // create delegate }
In the generated code, the provideDelegate
method is called to initialize the auxiliary prop$delegate
property. Compare the generated code for the property declaration val prop: Type by MyDelegate()
with the generated code above (when the provideDelegate
method is not present):
class C { var prop: Type by MyDelegate() } // this code is generated by the compiler // when the 'provideDelegate' function is available: class C { // calling "provideDelegate" to create the additional "delegate" property private val prop$delegate = MyDelegate().provideDelegate(this, this::prop) var prop: Type get() = prop$delegate.getValue(this, this::prop) set(value: Type) = prop$delegate.setValue(this, this::prop, value) }
Note that the provideDelegate
method affects only the creation of the auxiliary property and doesn't affect the code generated for getter or setter.
© 2010–2019 JetBrains s.r.o.
Licensed under the Apache License, Version 2.0.
https://kotlinlang.org/docs/reference/delegated-properties.html