90
  1. This code compiles with a warning (insignificant performance impact):

    inline fun test(noinline f: () -> Unit) {
        thread(block = f)
    }
    
  2. This code does not compile (illegal usage of inline-parameter):

    inline fun test(crossinline f: () -> Unit) {
        thread(block = f)
    }
    
  3. This code compiles with a warning (insignificant performance impact):

    inline fun test(noinline f: () -> Unit) {
        thread { f() }
    }
    
  4. This code compiles with no warning or error:

    inline fun test(crossinline f: () -> Unit) {
        thread { f() }
    }
    

Here are my questions:

  • How come (2) does not compile but (4) does?
  • What exactly is the difference between noinline and crossinline?
  • If (3) does not generates a no performance improvements, why would (4) do?

4 Answers 4

52

From the inline functions reference:

Note that some inline functions may call the lambdas passed to them as parameters not directly from the function body, but from another execution context, such as a local object or a nested function. In such cases, non-local control flow is also not allowed in the lambdas. To indicate that, the lambda parameter needs to be marked with the crossinline modifier

Hence, example 2. doesn't compile, since crossinline enforces only local control flow, and the expression block = f violates that. Example 1 compiles, since noinline doesn't require such behavior (obviously, since it's an ordinary function parameter).

Examples 1 and 3 do not generate any performance improvements, since the only lambda parameter is marked noinline, rendering the inline modifier of the function useless and redundant - the compiler would like to inline something, but everything that could be has been marked not to be inlined.

Consider two functions, A and B

A

inline fun test(noinline f: () -> Unit) {
    thread { f() }
}

B

fun test(f: () -> Unit) {
    thread { f() }
}

Function A behaves like function B in the sense that the parameter f will not be inlined (the B function doesn't inline the body of test whereas in the A function, the body: thread { f() } still gets inlined).

Now, this is not true in the example 4, since the crossinline f: () -> Unit parameter can be inlined, it just cannot violate the aforementioned non-local control flow rule (like assigning new value to a global variable). And if it can be inlined, the compiler assumes performance improvements and does not warn like in the example 3.

7
  • 6
    inline fun test(noinline f) will inline the body of the function test, but will not inline f. So the snippets above are not identical. Please correct that
    – voddan
    Aug 8, 2016 at 13:01
  • @voddan you're right, I forgot to mention that and it was misleading, thanks! Aug 8, 2016 at 13:09
  • 2
    If I understand this right: crossinline will inline the lambda where it's called (but prevent non-local control flow) while noinline will not inline it at all (and therefore encapsulate the lambda into a Function object). Aug 9, 2016 at 8:09
  • 1
    @SalomonBRYS yes, although the crossinline will also result in inlining the body of the method itself, not only the passed lambda. Aug 20, 2016 at 12:45
  • 3
    @LaiYu-Hsuan in the expression block = f, the block variable is not local to the test function, it exists outside of the method's scope, hence 'non-local control flow'. Frankly it just means 'accesses non-local values' here. May 7, 2017 at 22:30
30

Let me try to explain this by example: I'll go through each of your examples and describe what it orders the compiler to do. First, here's some code that uses your function:

fun main(args: Array<String>) {
    test { 
        println("start")
        println("stop")
    }
}

Now let's go through your variants. I'll call the functions from your examples test1..test4 and I'll show in pseudocode what the above main function would compile into.

1. noinline, block = f

test1() compiles with a warning (insignificant performance impact)

inline fun test1(noinline f: () -> Unit) {
    thread(block = f)
}

fun compiledMain1() {
    val myBlock = {
        println("start")
        println("stop")
    }
    thread(block = myBlock)
}

First, note that in compiledMain1 there's no evidence of inline fun test1 even existing. Inline functions aren't really "called": it's as if the code of test1 was written inside main(). On the other hand, the noinline lambda parameter behaves same as without inlining: you create a lambda object and pass it to the thread function.

2. crossinline, block = f

test2() does not compile (illegal usage of inline-parameter)

inline fun test2(crossinline f: () -> Unit) {
    thread(block = f)
}

fun compiledMain2() {
    thread(block =
        println("start")
        println("stop")
    )
}

I hope I managed to conjure what happens here: you requested to copy-paste the code of the block into a place that expects a value. It's just syntactic garbage. Reason: with or without crossinline you request that the block be copy-pasted into the place where it's used. This modifier just restricts what you can write inside the block (no returns etc.)

3. noinline, { f() }

test3() compiles with a warning (insignificant performance impact)

inline fun test3(noinline f: () -> Unit) {
    thread { f() }
}

fun compiledMain3() {
    val myBlock = {
        println("start")
        println("stop")
    }
    thread { myBlock() }
}

We're back to noinline here so things are straightforward again. You create a regular lambda object myBlock, then you create another regular lambda object that delegates to it: { myBlock() }, then you pass this to thread().

4. crossinline, { f() }

test4() compiles with no warning or error

inline fun test4(crossinline f: () -> Unit) {
    thread { f() }
}

fun compiledMain4() {
    thread {
        println("start")
        println("stop")
    }
}

Finally this example demonstrates what crossinline is for. The code of test4 is inlined into main, the code of the block is inlined into the place where it's used. But, since it's used inside the definition of a regular lambda object, it can't contain non-local control flow.

About the Performance Impact

The Kotlin team wants you to use the inlining feature sensibly. With inlining the size of the compiled code can explode dramatically and even hit the JVM limits of up to 64K bytecode instructions per method. The main use case is higher-order functions that avoid the cost of creating an actual lambda object, only to discard it right after a single function call which happens right away.

Whenever you declare an inline fun without any inline lambdas, inlining itself has lost its purpose. The compiler warns you about it.

0
12

Q1: How come (2) does not compile but (4) does?

From their doc:

Inlinable lambdas can only be called inside the inline functions or passed as inlinable arguments...

Answer:

The method thread(...) is not an inline method so you won't be able to pass f as an argument.

Q2: What exactly is the difference between noinline and crossinline?

Answer:

noinline will prevent the inlining of lambdas. This becomes useful when you have multiple lambda arguments and you want only some of the lambdas passed to an inline function to be inlined.

crossinline is used to mark lambdas that mustn't allow non-local returns, especially when such lambda is passed to another execution context. In other words, you won't be able to do a use a return in such lambdas. Using your example:

inline fun test(crossinline f: () -> Unit) {
    thread { f() }
}

//another method in the class
fun foo() {

    test{ 

       //Error! return is not allowed here.
       return
    }

}

Q3: If (3) does not generates a no performance improvements, why would (4) do?

Answer:

That is because the only lambda you have in (3) has been marked with noinline which means you'll have the overhead cost of creating the Function object to house the body of your lamda. For (4) the lambda is still inlined (performance improvement) only that it won't allow non-local returns.

2

To the first and second question

How come (2) does not compile but (4) does?.. difference between noinline and crossinline

2. inline fun test(crossinline f: () -> Unit) {
    thread(block = f)
}

4. inline fun test(crossinline f: () -> Unit) {
    thread { f() }
}

Both cases have inline modifier instructing to inline both the function test and its argument lambda f. From kotlin reference:

The inline modifier affects both the function itself and the lambdas passed to it: all of those will be inlined into the call site.

So the compiler is instructed to place the code (inline) instead of constructing and invoking a function object for f. crossinline modifier is only for inlined things: it just says that the passed lambda (in f parameter) should not have non-local returns (which "normal" inlined lambdas may have). crossinline can be thought of as something like this (instruction to the compiler ): “ do inline but there is a restriction that it is crossing the invoker context and so make sure the lambda does not have non-local returns.

On a side note, thread seems like a conceptually illustrative example for crossinline because obviously returning from some code (passed in f) later on a different thread cannot possibly affect the return from test, which continues to execute on the caller thread independently from what it spawned (f goes on to execute independently)..

In case #4, there is a lambda (curly braces) invoking f(). In case #2, f is passed directly as an argument to thread

So in #4, call f() can be inlined and the compiler can guarantee there is no non-local return. To elaborate, the compiler would replace f() with its definition and that code is then “wrapped” inside the enclosing lambda, in other words, { //code for f() } is sort of another (wrapper) lambda and it itself is further passed as a function object reference (to thread).

In case #2, the compiler error simply says it cannot inline f because it is being passed as a reference into an “unknown” (non-inlined) place. crossinline becomes out of place and irrelevant in this case because it could be applied only if f were inlined.

To sum up, case 2 and 4 are not the same by comparing to the example from the kotlin reference (see "Higher-Order Functions and Lambdas"): below invocations are equivalent, where curly braces (lambda expression) "replace" the wrapper function toBeSynchronized

//want to pass `sharedResource.operation()` to lock body
fun <T> lock(lock: Lock, body: () -> T): T {...}
//pass a function
fun toBeSynchronized() = sharedResource.operation()
val result = lock(lock, ::toBeSynchronized) 
//or pass a lambda expression
val result = lock(lock, { sharedResource.operation() })

Case #2 and #4 in the question are not equivalent because there is no "wrapper" invoking f in #2

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