Can I get strongly typed value from an Object, something like this:
Object obj;
final fooOrBar = obj as (flag ? Foo : Bar); // Error
fooOrBar should be either of type Foo or Bar but this gives me an error.
Note:
I don't want to do things like:
if (flag) {
final foo = obj as Foo;
} else {
final bar = obj as Bar;
}
You cannot do what you are asking for.
A variable has one type, determined at compile-time.
Since flag is not known at compile-time, it cannot affect the type of the variable fooOrBar.
You also cannot abstract over types like that. The thing after as must be a single type.
You can do
var fooOrBar = flag ? obj as Foo : obj as Bar;
but the static type of fooOrBar will likely be Object anyway, or at least some common supertype of Foo and Bar. Then you might as well just cast directly to that: var castObj = obj as CommonSupertypeOfFooAndBar;.
You can use helper functions:
Foo asFoo(Object o) => o as Foo;
Bar asBar(Object o) => o as Bar;
//...
var fooOrBar = (flag ? asFoo : asBar)(obj);
Again, the type won't be Foo or Bar, but some supertype of both.
If you actually care about the type of fooOrBar being either precisely Foo or precisely Bar, you need two different variables.
for (var foo in bar) print(foo);
for (final foo in bar) print(foo);
Is there any difference in performance between these two? Or is the only difference "avoiding accidental reassignments"?
Edit:
prefer_final_locals mentions compiler performing optimizations when final is used. Will it apply here? dart2js output matches for the 2 snippets above. Not sure about dart2native.
The only difference is that you can reassign the foo value if you use var.
for (var foo in bar) {
foo = foo + 5;
print(foo);
}
doing so using final would not work
for (final foo in bar) {
foo = foo + 5; //Error: The variable foo can be set only once
print(foo);
}
From Dart Style Guide:
DON'T use final for local variables.
var is shorter, and final does not change the meaning of the code.
https://dart-lang.github.io/linter/lints/unnecessary_final.html
class X extends Y {
X(int a, int b) : super(a,b);
}
Can someone give me an explanation about the syntax meaning of the colon :?
This feature in Dart is called "initializer list".
It allows you to initialize fields of your class, make assertions and call the super constructor.
This means that it is not the same as the constructor body. As I said, you can only initialize variables and only access static members. You cannot call any (non-static) methods.
The benefit is that you can also initialize final variables, which you cannot do in the constructor body. You also have access to all parameters that are passed to the constructor, which you do not have when initializing the parameters directly in the parentheses.
Additionally, you can use class fields on the left-hand of an assignment with the same name as a parameter on the right-hand side that refers to a parameter. Dart will automatically use the class field on the left-hand side.
Here is an example:
class X {
final int number;
X(number) : number = number ?? 0;
}
The code above assigns the parameter named number to the final field this.number if it is non-null and otherwise it assigns 0. This means that the left-hand number of the assignment actually refers to this.number. Now, you can even make an assertion that will never fail (and is redundant because of that, but I want to explain how everything works together):
class X {
final int number;
X(number): number = number ?? 0, assert(number != null);
}
Learn more.
It's ok to access non static member in initializer list.
class Point {
num x, y;
Point(this.x, this.y);
Point.origin(): this.x = 10, this.y = 10;
}
main() {
Point p = Point.origin();
print(p.x); // 10
}
If I have a nullable type Xyz?, I want to reference it or convert it to a non-nullable type Xyz. What is the idiomatic way of doing so in Kotlin?
For example, this code is in error:
val something: Xyz? = createPossiblyNullXyz()
something.foo() // Error: "Only safe (?.) or non-null asserted (!!.) calls are allowed on a nullable receiver of type Xyz?"
But if I check null first it is allowed, why?
val something: Xyz? = createPossiblyNullXyz()
if (something != null) {
something.foo()
}
How do I change or treat a value as not null without requiring the if check, assuming I know for sure it is truly never null? For example, here I am retrieving a value from a map that I can guarantee exists and the result of get() is not null. But I have an error:
val map = mapOf("a" to 65,"b" to 66,"c" to 67)
val something = map.get("a")
something.toLong() // Error: "Only safe (?.) or non-null asserted (!!.) calls are allowed on a nullable receiver of type Int?"
The method get() thinks it is possible that the item is missing and returns type Int?. Therefore, what is the best way to force the type of the value to be not nullable?
Note: this question is intentionally written and answered by the author (Self-Answered Questions), so that the idiomatic answers to commonly asked Kotlin topics are present in SO. Also to clarify some really old answers written for alphas of Kotlin that are not accurate for current-day Kotlin.
First, you should read all about Null Safety in Kotlin which covers the cases thoroughly.
In Kotlin, you cannot access a nullable value without being sure it is not null (Checking for null in conditions), or asserting that it is surely not null using the !! sure operator, accessing it with a ?. Safe Call, or lastly giving something that is possibly null a default value using the ?: Elvis Operator.
For your 1st case in your question you have options depending on the intent of the code you would use one of these, and all are idiomatic but have different results:
val something: Xyz? = createPossiblyNullXyz()
// access it as non-null asserting that with a sure call
val result1 = something!!.foo()
// access it only if it is not null using safe operator,
// returning null otherwise
val result2 = something?.foo()
// access it only if it is not null using safe operator,
// otherwise a default value using the elvis operator
val result3 = something?.foo() ?: differentValue
// null check it with `if` expression and then use the value,
// similar to result3 but for more complex cases harder to do in one expression
val result4 = if (something != null) {
something.foo()
} else {
...
differentValue
}
// null check it with `if` statement doing a different action
if (something != null) {
something.foo()
} else {
someOtherAction()
}
For the "Why does it work when null checked" read the background information below on smart casts.
For your 2nd case in your question in the question with Map, if you as a developer are sure of the result never being null, use !! sure operator as an assertion:
val map = mapOf("a" to 65,"b" to 66,"c" to 67)
val something = map.get("a")!!
something.toLong() // now valid
or in another case, when the map COULD return a null but you can provide a default value, then Map itself has a getOrElse method:
val map = mapOf("a" to 65,"b" to 66,"c" to 67)
val something = map.getOrElse("z") { 0 } // provide default value in lambda
something.toLong() // now valid
Background Information:
Note: in the examples below I am using explicit types to make the behavior clear. With type inference, normally the types can be omitted for local variables and private members.
More about the !! sure operator
The !! operator asserts that the value is not null or throws an NPE. This should be used in cases where the developer is guaranteeing that the value will never be null. Think of it as an assert followed by a smart cast.
val possibleXyz: Xyz? = ...
// assert it is not null, but if it is throw an exception:
val surelyXyz: Xyz = possibleXyz!!
// same thing but access members after the assertion is made:
possibleXyz!!.foo()
read more: !! Sure Operator
More about null Checking and Smart Casts
If you protect access to a nullable type with a null check, the compiler will smart cast the value within the body of the statement to be non-nullable. There are some complicated flows where this cannot happen, but for common cases works fine.
val possibleXyz: Xyz? = ...
if (possibleXyz != null) {
// allowed to reference members:
possiblyXyz.foo()
// or also assign as non-nullable type:
val surelyXyz: Xyz = possibleXyz
}
Or if you do a is check for a non-nullable type:
if (possibleXyz is Xyz) {
// allowed to reference members:
possiblyXyz.foo()
}
And the same for 'when' expressions that also safe cast:
when (possibleXyz) {
null -> doSomething()
else -> possibleXyz.foo()
}
// or
when (possibleXyz) {
is Xyz -> possibleXyz.foo()
is Alpha -> possibleXyz.dominate()
is Fish -> possibleXyz.swim()
}
Some things do not allow the null check to smart cast for the later use of the variable. The example above uses a local variable that in no way could have mutated in the flow of the application, whether val or var this variable had no opportunity to mutate into a null. But, in other cases where the compiler cannot guarantee the flow analysis, this would be an error:
var nullableInt: Int? = ...
public fun foo() {
if (nullableInt != null) {
// Error: "Smart cast to 'kotlin.Int' is impossible, because 'nullableInt' is a mutable property that could have been changed by this time"
val nonNullableInt: Int = nullableInt
}
}
The lifecycle of the variable nullableInt is not completely visible and may be assigned from other threads, the null check cannot be smart cast into a non-nullable value. See the "Safe Calls" topic below for a workaround.
Another case that cannot be trusted by a smart cast to not mutate is a val property on an object that has a custom getter. In this case, the compiler has no visibility into what mutates the value and therefore you will get an error message:
class MyThing {
val possibleXyz: Xyz?
get() { ... }
}
// now when referencing this class...
val thing = MyThing()
if (thing.possibleXyz != null) {
// error: "Kotlin: Smart cast to 'kotlin.Int' is impossible, because 'p.x' is a property that has open or custom getter"
thing.possiblyXyz.foo()
}
read more: Checking for null in conditions
More about the ?. Safe Call operator
The safe call operator returns null if the value to the left is null, otherwise continues to evaluate the expression to the right.
val possibleXyz: Xyz? = makeMeSomethingButMaybeNullable()
// "answer" will be null if any step of the chain is null
val answer = possibleXyz?.foo()?.goo()?.boo()
Another example where you want to iterate a list but only if not null and not empty, again the safe call operator comes in handy:
val things: List? = makeMeAListOrDont()
things?.forEach {
// this loops only if not null (due to safe call) nor empty (0 items loop 0 times):
}
In one of the examples above we had a case where we did an if check but have the chance another thread mutated the value and therefore no smart cast. We can change this sample to use the safe call operator along with the let function to solve this:
var possibleXyz: Xyz? = 1
public fun foo() {
possibleXyz?.let { value ->
// only called if not null, and the value is captured by the lambda
val surelyXyz: Xyz = value
}
}
read more: Safe Calls
More about the ?: Elvis Operator
The Elvis operator allows you to provide an alternative value when an expression to the left of the operator is null:
val surelyXyz: Xyz = makeXyzOrNull() ?: DefaultXyz()
It has some creative uses as well, for example throw an exception when something is null:
val currentUser = session.user ?: throw Http401Error("Unauthorized")
or to return early from a function:
fun foo(key: String): Int {
val startingCode: String = codes.findKey(key) ?: return 0
// ...
return endingValue
}
read more: Elvis Operator
Null Operators with Related Functions
Kotlin stdlib has a series of functions that work really nicely with the operators mentioned above. For example:
// use ?.let() to change a not null value, and ?: to provide a default
val something = possibleNull?.let { it.transform() } ?: defaultSomething
// use ?.apply() to operate further on a value that is not null
possibleNull?.apply {
func1()
func2()
}
// use .takeIf or .takeUnless to turn a value null if it meets a predicate
val something = name.takeIf { it.isNotBlank() } ?: defaultName
val something = name.takeUnless { it.isBlank() } ?: defaultName
Related Topics
In Kotlin, most applications try to avoid null values, but it isn't always possible. And sometimes null makes perfect sense. Some guidelines to think about:
in some cases, it warrants different return types that include the status of the method call and the result if successful. Libraries like Result give you a success or failure result type that can also branch your code. And the Promises library for Kotlin called Kovenant does the same in the form of promises.
for collections as return types always return an empty collection instead of a null, unless you need a third state of "not present". Kotlin has helper functions such as emptyList() or emptySet() to create these empty values.
when using methods which return a nullable value for which you have a default or alternative, use the Elvis operator to provide a default value. In the case of a Map use the getOrElse() which allows a default value to be generated instead of Map method get() which returns a nullable value. Same for getOrPut()
when overriding methods from Java where Kotlin isn't sure about the nullability of the Java code, you can always drop the ? nullability from your override if you are sure what the signature and functionality should be. Therefore your overridden method is more null safe. Same for implementing Java interfaces in Kotlin, change the nullability to be what you know is valid.
look at functions that can help already, such as for String?.isNullOrEmpty() and String?.isNullOrBlank() which can operate on a nullable value safely and do what you expect. In fact, you can add your own extensions to fill in any gaps in the standard library.
assertion functions like checkNotNull() and requireNotNull() in the standard library.
helper functions like filterNotNull() which remove nulls from collections, or listOfNotNull() for returning a zero or single item list from a possibly null value.
there is a Safe (nullable) cast operator as well that allows a cast to non-nullable type return null if not possible. But I do not have a valid use case for this that isn't solved by the other methods mentioned above.
The previous answer is a hard act to follow, but here's one quick and easy way:
val something: Xyz = createPossiblyNullXyz() ?: throw RuntimeError("no it shouldn't be null")
something.foo()
If it really is never null, the exception won't happen, but if it ever is you'll see what went wrong.
I want to add that now it exists Konad library that addresses more complex situations for nullable composition. Here it follows an example usage:
val foo: Int? = 1
val bar: String? = "2"
val baz: Float? = 3.0f
fun useThem(x: Int, y: String, z: Float): Int = x + y.toInt() + z.toInt()
val result: Int? = ::useThem.curry()
.on(foo.maybe)
.on(bar.maybe)
.on(baz.maybe)
.nullable
if you want to keep it nullable, or
val result: Result<Int> = ::useThem.curry()
.on(foo.ifNull("Foo should not be null"))
.on(bar.ifNull("Bar should not be null"))
.on(baz.ifNull("Baz should not be null"))
.result
if you want to accumulate errors. See maybe section
Accepted answer contains the complete detail, here I am adding the summary
How to call functions on a variable of nullable type
val str: String? = "HELLO"
// 1. Safe call (?), makes sure you don't get NPE
val lowerCaseStr = str?.toLowerCase() // same as str == null ? null : str.toLowerCase()
// 2. non-null asserted call (!!), only use if you are sure that value is non-null
val upperCaseStr = str!!.toUpperCase() // same as str.toUpperCase() in java, NPE if str is null
How to convert nullable type variable to non-nullable type
Given that you are 100% sure that nullable variable contains non-null value
// use non-null assertion, will cause NPE if str is null
val nonNullableStr = str!! // type of nonNullableStr is String(non-nullable)
Why safe(?) or non-null(!!) assertion not required inside null check if block
if the compiler can guarantee that the variable won't change between the check and the usage then it knows that variable can't possibly be null, so you can do
if(str != null){
val upperCaseStr = str.toUpperCase() // str can't possibly be null, no need of ? or !!
}
I need clarity on how objects are declared and assigned a definition in F#.
What's happening in this code?
let service = {
new IService with
member this.Translate(_) = raise error }
My guess is we're creating an object that will implement some interface on the fly even though there is no actual class that's backing this object. Hence, we're removing the ceremony involved with creating an object by not having to declare a separate class to use it. In this case, we're minimizing the ceremony involved for implementing a mock object that could be used within a unit test.
Is my understanding accurate?
I tried to research my question and found the specification for F# 3.0 (Section - 6.3.8 Object Expressions)
6.3.8 Object Expressions An expression of the following form is an object expression: { new ty0 args-expropt object-members interface
ty1 object-members1 … interface tyn object-membersn } In the case
of the interface declarations, the object-members are optional and are
considered empty if absent. Each set of object-members has the form:
with member-defns endopt Lexical filtering inserts simulated $end
tokens when lightweight syntax is used. Each member of an object
expression members can use the keyword member, override, or default.
The keyword member can be used even when overriding a member or
implementing an interface.
For example:
let obj1 =
{ new System.Collections.Generic.IComparer<int> with
member x.Compare(a,b) = compare (a % 7) (b % 7) }
You can get a pretty good picture of what is happening behind the scenes if you look at the generated IL using a decompiler like ILSpy. For the example involving IComparer, it generates a hidden class, which implements the interface:
internal sealed class obj1#2 : IComparer<int> {
public obj1#2() : this() { }
int IComparer<int>.System-Collections-Generic-IComparer(int x, int y) {
int num = x % 7;
int num2 = y % 7;
if (num < num2) { return -1; }
return (num > num2) ? 1 : 0;
}
}
Inside the body of the method, it then creates a new instance:
IComparer<int> obj1 = new obj1#2();