In Kotlin, you can perform type checks to check the type of an object at runtime. Type casts enable you to convert objects to a different type.
To learn specifically about generics type checks and casts, for example
List<T>
,Map<K,V>
, see Generics type checks and casts.
{type="tip"}
To perform a runtime check that identifies whether an object conforms to a given type, use the is
operator or its negated form !is
:
if (obj is String) {
print(obj.length)
}
if (obj !is String) { // Same as !(obj is String)
print("Not a String")
} else {
print(obj.length)
}
In most cases, you don't need to use explicit cast operators because the compiler automatically casts objects for you. This is called smart-casting. The compiler tracks the type checks and explicit casts for immutable values and inserts implicit (safe) casts automatically when necessary:
fun demo(x: Any) {
if (x is String) {
print(x.length) // x is automatically cast to String
}
}
The compiler is even smart enough to know that a cast is safe if a negative check leads to a return:
if (x !is String) return
print(x.length) // x is automatically cast to String
Smart casts work not only for if
conditional expressions but also for when
expressions
and while
loops:
when (x) {
is Int -> print(x + 1)
is String -> print(x.length + 1)
is IntArray -> print(x.sum())
}
If you declare a variable of Boolean
type before using it in your if
, when
, or while
condition, then any
information collected by the compiler about the variable will be accessible in the corresponding block for
smart-casting.
This can be useful when you want to do things like extract boolean conditions into variables. Then, you can give the variable a meaningful name, which will improve your code readability and make it possible to reuse the variable later in your code. For example:
class Cat {
fun purr() {
println("Purr purr")
}
}
fun petAnimal(animal: Any) {
val isCat = animal is Cat
if (isCat) {
// The compiler can access information about
// isCat, so it knows that animal was smart-cast
// to the type Cat.
// Therefore, the purr() function can be called.
animal.purr()
}
}
fun main(){
val kitty = Cat()
petAnimal(kitty)
// Purr purr
}
{kotlin-runnable="true" kotlin-min-compiler-version="2.0" id="kotlin-smart-casts-local-variables" validate="false"}
The compiler can perform smart casts on the right-hand side of &&
or ||
operators if there is a type check (regular or negative) on the left-hand side:
// x is automatically cast to String on the right-hand side of `||`
if (x !is String || x.length == 0) return
// x is automatically cast to String on the right-hand side of `&&`
if (x is String && x.length > 0) {
print(x.length) // x is automatically cast to String
}
If you combine type checks for objects with an or
operator (||
), a smart cast is made to their closest common supertype:
interface Status {
fun signal() {}
}
interface Ok : Status
interface Postponed : Status
interface Declined : Status
fun signalCheck(signalStatus: Any) {
if (signalStatus is Postponed || signalStatus is Declined) {
// signalStatus is smart-cast to a common supertype Status
signalStatus.signal()
}
}
The common supertype is an approximation of a union type. Union types are not currently supported in Kotlin.
{type="note"}
The compiler can smart-cast variables captured within lambda functions that are passed to inline functions.
Inline functions are treated as having an implicit callsInPlace
contract. This means that any lambda functions passed to an inline function are called in place. Since lambda functions
are called in place, the compiler knows that a lambda function can't leak references to any variables contained within
its function body.
The compiler uses this knowledge, along with other analyses to decide whether it's safe to smart-cast any of the captured variables. For example:
interface Processor {
fun process()
}
inline fun inlineAction(f: () -> Unit) = f()
fun nextProcessor(): Processor? = null
fun runProcessor(): Processor? {
var processor: Processor? = null
inlineAction {
// The compiler knows that processor is a local variable and inlineAction()
// is an inline function, so references to processor can't be leaked.
// Therefore, it's safe to smart-cast processor.
// If processor isn't null, processor is smart-cast
if (processor != null) {
// The compiler knows that processor isn't null, so no safe call
// is needed
processor.process()
}
processor = nextProcessor()
}
return processor
}
Smart cast information is passed on to catch
and finally
blocks. This change makes your code safer
as the compiler tracks whether your object has a nullable type. For example:
//sampleStart
fun testString() {
var stringInput: String? = null
// stringInput is smart-cast to String type
stringInput = ""
try {
// The compiler knows that stringInput isn't null
println(stringInput.length)
// 0
// The compiler rejects previous smart cast information for
// stringInput. Now stringInput has the String? type.
stringInput = null
// Trigger an exception
if (2 > 1) throw Exception()
stringInput = ""
} catch (exception: Exception) {
// The compiler knows stringInput can be null
// so stringInput stays nullable.
println(stringInput?.length)
// null
}
}
//sampleEnd
fun main() {
testString()
}
{kotlin-runnable="true" kotlin-min-compiler-version="2.0" id="kotlin-smart-casts-exception-handling"}
Note that smart casts work only when the compiler can guarantee that the variable won't change between the check and its usage.
{type="warning"}
Smart casts can be used in the following conditions:
val local variables
|
Always, except local delegated properties. |
val properties
|
If the property is private , internal , or if the check is performed in the same module where the property is declared. Smart casts can't be used on open properties or properties that have custom getters.
|
var local variables
|
If the variable is not modified between the check and its usage, is not captured in a lambda that modifies it, and is not a local delegated property. |
var properties
|
Never, because the variable can be modified at any time by other code. |
To explicitly cast an object to a non-nullable type, use the unsafe cast operator as
:
val x: String = y as String
If the cast isn't possible, the compiler throws an exception. This is why it's called unsafe.
In the previous example, if y
is null
, the code above also throws an exception. This is because null
can't be cast
to String
, as String
isn't nullable. To make the example work for possible null values, use a nullable
type on the right-hand side of the cast:
val x: String? = y as String?
To avoid exceptions, use the safe cast operator as?
, which returns null
on failure.
val x: String? = y as? String
Note that despite the fact that the right-hand side of as?
is a non-nullable type String
, the result of the cast is nullable.