What is this double pipe operator in Kotlin? - kotlin

I found this code in a Kotlin library and I couldn't find any information on it.
open fun <Type : ScreenType> addScreen(type: Class<Type>, screen: Type) {
!screens.containsKey(type) || throw GdxRuntimeException("Screen already
registered to type: $type.")
screens.put(type, screen)
}
I don't understand the middle part. What is that strange "OR" operator doing there?

In Kotlin, throwing an Exception evaluates as an expression that returns Nothing. Nothing is treated like a sub-type of anything else, so that first line of code is basically an expression of type Boolean || Nothing, which can be simplified to just Boolean. Kotlin also allows a line of code to simply be an expression (many other languages like Java do not), so you can simply put this line of code to evaluate the two parts of the expression sequentially, and the throw will be skipped (short-circuited) if the first part of the expression is true.
While writing code like this in Kotlin is possible, it is certainly not idiomatic. In my opinion, it is unclear for readability. The equivalent behavior can be achieved with code that very clearly shows its intent:
if (screens.containsKey(type)) {
throw GdxRuntimeException("Screen already registered to type: $type.")
}

The expression uses short-circuiting property of the OR operator. The right-hand side is only evaluated if the left-hand side is false. That way it's just another way to write conditional code.

Related

Kotlin checkNotNull vs requireNotNull

As I learn new components in Kotlin, I came accross requireNotNull and checkNotNull but the only difference I've found is that requireNotNull can throw an IllegalArgumentException while checkNotNull can throw an IllegalStateException. Is this the only reason why there are two methods, or I'm missing some under-the-hood implementation detail?
The exception types are the only practical difference, as far as the compiler is concerned — but there's a big difference in intent, for anyone reading the code:
• require…() functions are for checking parameters, to confirm that a function's input fulfils its contract. So you'd normally call them first thing in a function. (Of course, Kotlin's non-nullable types mean that you wouldn't need to call requireNotNull() for a single parameter; but you might need to check a more complex condition on a combination of parameters or their sub-objects.) That's why they throw IllegalArgumentException: it's checking that the arguments are legal.
• check…() functions are for checking the relevant properties, to confirm that the object or whatever is in a valid state for this function to be called now. (Again, any properties that were never null would be typed accordingly, so checkNotNull() is more appropriate for cases where a property, combination, and/or sub-property can be null, but this function mustn't be called when they are.) So they throw IllegalStateException: they're checking that the object's current state allows the function to be called.
In both cases, you could of course write a standard if check (as you would in Java). Or you could use the Elvis operator ?: to do the check the first time the possibly-null value is used. But these functions give you an alternative that's in a more declarative form: you'd normally put them at the top of the function, where they spell out what the function's contract is, in a way that's obvious to anyone glancing at the code.
As a linked answer points out, there are also assert…() functions, which again have more of a semantic difference than a practical one. Those are for detecting programming errors away from the boundary of a function call: for confirming invariants and other conditions, and for all the checks in unit tests and other automated tests.
(Assertions have another important difference: they can be enabled and disabled from the command-line. Though in my experience, that's not a very good thing. If a check is important, it should always be run: be mandatory; if not, then it should be removed, or at least moved to automated tests, once the code is debugged.)
It is a semantic difference and hence it throws different exceptions. RequireNotNull is used to check input values, typically at the beginning of a method, while checkNotNull is used anywhere to check the current state.
If you're looking for differences in implementation, the best place to go would be the source code. In this case it seems like there are no differences aside from the different exception thrown, the source for both methods is otherwise identical.
checkNotNull
[...]
if (value == null) {
val message = lazyMessage()
throw IllegalStateException(message.toString())
} else {
return value
}
requireNotNull
[...]
if (value == null) {
val message = lazyMessage()
throw IllegalArgumentException(message.toString())
} else {
return value
}
Therefore the difference is purely semantic. The answer from #gidds details some good scenarios for using them both.

Kotlin expression fun vs normal fun - differences

Let's assume that I have two functions which do the same stuff.
First one:
fun doSomething() = someObject.getSomeData()
Second one:
fun doSomething(): SomeData {
return someObject.getSomeData()
}
Are there any technical differences between expression functions and standard function in Kotlin excluding the way how they look?
Is compiled output the same?
Are there any advantages using one instead another?
As #Sơn Phan says, they both compile to exactly the same bytecode.
So the differences are simply about conciseness.  The expression form omits the braces and return; it also lets you omit the return type (using type inference as needed).  As the question illustrates, the expression form can be shorter — and when all else is equal, shorter tends to be easier to read and understand.
So whether the expression form is appropriate is usually a matter of style rather than correctness.  For example, this function could be on one line:
fun String.toPositiveIntegers() = split(",").mapNotNull{ it.toIntOrNull() }.filter{ it >= 0 }
But it's a bit long, and probably better to split it.  You could keep the expression form:
fun String.toPositiveIntegers()
= split(",")
.mapNotNull{ it.toIntOrNull() }
.filter{ it >= 0 }
Or use a traditional function form:
fun String.toPositiveIntegers(): List<Int> {
return split(",")
.mapNotNull{ it.toIntOrNull() }
.filter{ it >= 0 }
}
(I tend to prefer the former, but there are arguments both ways.)
Similarly, I rather like using it when the body is a simple lambda, e.g.:
fun createMyObject() = MyObject.apply {
someConfig(someField)
someOtherConfig()
}
…but I expect some folk wouldn't.
One gotcha when using the expression form is the type inference.  Generally speaking, in Kotlin it's good to let the compiler figure out the type when it can; but for function return values, that's not always such a good idea.  For example:
fun myFun(): String = someProperty.someFunction()
will give a compilation error if the someFunction() is ever changed to return something other than a String — even a nullable String?.  However:
fun myFun() = someProperty.someFunction()
…would NOT give a compilation error; it would silently change the function's return type.  That can mask bugs, or make them harder to find.  (It's not a very common problem, but I've hit it myself.)  So you might consider specifying the return type, even though you don't need to, whenever there's a risk of it changing.
One particular case of this is when calling a Java function which doesn't have an annotation specifying its nullability.  Kotlin will treat the result as a ‘platform type’ (which means it can't tell whether it's nullable); returning such a platform type is rarely a good idea, and IntelliJ has a warning suggesting that you specify the return type explicitly.
1. Compiled output
Yes the compiled output will be completely the same
2. Advantage
You usually use expression function when the body of a function is only one line of expression to make it a oneliner function. Its advantage mainly about making the code more concise. Imagine instead of all the brackets and return, you only need a = to make things done.

What is the difference between not-null checks in Kotlin?

There are some ways to fulfill a null-checking in Kotlin:
1.
if(myVar != null) {
foo(myVar)
}
2.
myVar?.let {
foo(it)
}
3.
myVar?.run {
foo(this)
}
What are the difference between these ways?
Are there any reasons (performance, best practice, code style etc.) why I should prefer on way over the other?
!! is to tell the compiler that I am sure the value of the variable is not null, and if it is null throw a null pointer exception (NPE) where as ?. is to tell the compiler that I am not sure if the value of the variable is null or not, if it is null do not throw any null pointer.
Another way of using a nullable property is safe call operator ?.
This calls the method if the property is not null or returns null if that property is null without throwing an NPE (null pointer exception).
nullableVariable?.someMethodCall()
All three code are behave same null check in operation-wise.
?. is used for chain operations.
bob?.department?.head?.name // if any of the properties in it is null it returns null
To perform a chain operation only for non-null values, you can use the safe call operator together with let
myVar?.let {
foo(it)
}
the above code is good for code style and performance
more details refer Null Safety
The ways 2 and 3 are more idiomatic for Kotlin. Both functions are quite similar. There is little difference with argument passing.
For example, we have a nullable variable:
var canBeNull: String? = null
When you working with T.run you work with extension function calling and you pass this in the closure.
canBeNull?.run {
println(length) // `this` could be omitted
}
When you call T.let you can use it like lambda argument it.
canBeNull?.let {
myString -> println(myString.length) // You could convert `it` to some other name
}
A good article about Kotlin standard functions.
All three are roughly equivalent.
The if case is more like most other languages, and so many developers may find it easier to read.
However, one difference is that the if case will read the value of myVar twice: once for the check, and again when passing it to foo(). That makes a difference, because if myVar is a property (i.e. something that could potentially be changed by another thread), then the compiler will warn that it could have been set to null after the check. If that's a problem (e.g. because foo() expects a non-null parameter), then you'll need to use one of the other cases.
For that reason, the let case has become fairly common practice in Kotlin. (The run case does just about the same thing, but for some reason isn't as popular for this sort of thing. I don't know why.)
Another way around it is to assign myVar to a temporary value, test that, and then use that. That's also more like other languages, but it's more verbose; many people prefer the conciseness of the let case — especially when myVar is actually a complicated expression.
The examples in your question don't show the true reason to decide.
First of all, since you're not using the return value of foo, you should use neither let nor run. Your choice is between also and apply.
Second, since you already have the result you want to null-check in a variable, the difference fades. This is a better motivating example:
complexCall(calculateArg1(), calculateArg2())?.also {
results.add(it)
}
as opposed to
val result = complexCall(calculateArg1(), calculateArg2())
if (result != null) {
results.add(result)
}
The second example declares an identifier, result, which is now available to the rest of the lexical scope, even though you're done with it in just one line.
The first example, on the other hand, keeps everything self-contained and when you go on reading the rest of the code, you are 100% confident that you don't have to keep in mind the meaning of result.
Kotlin have new features with NullPoint-Exception as Compare to Java.
Basically When we do Coding in Java , then we have to Check with !! in every Flied.
But in Kotlin, it is Easy way to Implement First
as Like,
Suppose, in Kotlin
var response:Json?=Null
response:Json?.let {
this part will handle automatic if response is Not Null....then this Block start Executing }?.run {
This is Nullable But, where we Can put Warring } So, I am Suggest you Guys to Start Work in Kotlin with this Features Provided by Kotlin.
(Flied)?.let { Not Null Value Comes Under }?.run{ Null Value Code }
This will Handle to NullPoint Exception or Protect You App for Crash
What you want to achieve
What you want to achieve is that the Kotlin compiler does a smart cast on the variable you are working with.
In all of your three examples, the compiler can do that.
Example:
if(myVar != null) {
foo(myVar) // smart cast: the compiler knows, that myVar can never be null here
}
The choice
Which one of the options to use, is really a matter of style. What you should not do is mix it up to often. Use one and stick to it.
You don't need to worry about performance since let and run are inlined (see inline function). This means that their code (body) is copied to the call site at compile time so there is no runtime overhead.

When working with Java libraries in Kotlin, is it more idiomatic to use ? or !! on method return values?

I'm new to Kotlin and there's a common pattern that I'm not sure how to deal with most correctly. Take this code, for example, which doesn't compile:
git_repo?.add().addFilepattern()
add() is a call in the JGit library which is purely Java, so its return type is AddCommand!.
I have two options:
git_repo?.add()!!.addFilepattern("test.txt")
and
git_repo?.add()?.addFilepattern("test.txt")
Both work fine and given that
I don't know the intricacies of the library implementation,
the documentation of the JGit library doesn't specify whether add() can return null, and
within this context I'd typically expect add() to not return a null
Which version is more idiomatically correct to write in Kotlin? It seems that this would be a fairly common issue to deal with since basically every non-Kotlin library would introduce this issue.
I would use the ?. safe operator and then put your own exception at the end after an ?: Elvis operator. This way you get a message that is meaningful. Using just !! isn't a very helpful message to someone down the road who has no idea what the intricacies were either.
val cmd = gitRepo.add()?.addFilepattern("test.txt") ?: throw IllegalStateException("assert: gitRepo.add() returned an unexpected null")
cmd.doSomething() // never is null guaranteed
If the value is every null you will have a custom error.
assert: gitRepo.add() returned an unexpected null
And after this line, you will not have to null check because the result of the expression is guaranteed never to be null.
If you inspect the code of the other library and ensure it would never ever be null no matter what, then a !! is appropriate. But if not sure, do one better with the custom message.
Note I dropped the first ?. from your example because I'm assuming git_repo itself is not nullable. Plus I renamed it not to have an underscore which isn't normal Kotlin naming convention.
If you are sure that git_repo will always return a value!! is fine in that case.
It is ugly but !! will always be there when you use Java libraries, and you can't avoid it.
The only reason i would use git_repo?.add()?.addFilepattern("test.txt"), would be if you are returning a value, and you want the value to be nullable so that your calling method can handle the nullable.
fun nullableMethod(): string? {
return git_repo?.add()?.addFilepattern("test.txt")
}
fun callingMethod() {
if(this.nullableMethod() != null) {
}
//Else
}
If you are guaranteed it is never going to null, use !!

Usage of CompletableFuture's exceptionally method in Kotlin

I'm trying to handle CompletableFuture exceptions in Kotlin, but I'm not able to figure out how to supply the appropriate parameters. So, for example, I have:
CompletableFuture.runAsync { "sr" }
.exceptionally{e -> {}}
but then the compiler complains Cannot infer type parameter T.
How do I fix this?
Quite a tricky case which becomes tricky because of some Kotlin magic :)
The direct solution to your problem would be the following code:
CompletableFuture.runAsync {"sr"}
.exceptionally({e -> null})
The detailed explanation goes here:
The runAsync method accepts a Runnable which means after execution it will return Void. The function passed to exceptionally method must match the generic parameter of the CompletableFuture so in this particular case, you need to help a compiler by returning null explicitly.
So the following will compile without problems:
CompletableFuture.runAsync {"sr"}
.exceptionally({null})
CompletableFuture.runAsync {}
.exceptionally({null})
In the first case, the "sr" String will simply be ignored and not returned since the runAsync accepts a Runnable.
You probably wanted to do something like:
CompletableFuture.supplyAsync {"sr"}
.exceptionally({"sr_exceptional"})
or:
CompletableFuture.supplyAsync {"sr"}
.exceptionally({e -> "sr_exceptional"})