Do Kotlin coroutines provide any "happens-before" guarantees?

For example, is there "happens-before" guarantee between write to mutableVar and subsequent read on (potentially) other thread in this case:

suspend fun doSomething() {
    var mutableVar = 0
    withContext(Dispatchers.IO) {
        mutableVar = 1
    System.out.println("value: $mutableVar")


Maybe additional example will clarify the question better becuase it's more Kotlin-ish (except for mutability). Is this code thread-safe:

suspend fun doSomething() {
    var data = withContext(Dispatchers.IO) {
    System.out.println("value: ${data.data}")

private data class Data(var data: Int)
  • Note that when running on the JVM Kotlin uses the same memory model as Java. – Slaw Oct 23 at 9:34
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    @Slaw , I know that. However, there is a lot of magic going on under the hood. Therefore, I'd like to understand whether there are any happens-before guarantees that I get from coroutines, or it's all on me. – Vasiliy Oct 23 at 9:41
  • If anything, your second example presents an even simpler scenario: it just uses an object created within withContext, whereas the 1st example creates it first, mutates within withContext, and then reads after withContext. So the 1st example exercises more thread safety features. – Marko Topolnik Oct 23 at 11:09
  • ...and both examples exercise just the "program order" aspect of happens-before, the most trivial one. I'm speaking on the level of coroutines here, not the underlying JVM. So basically, you're asking whether or not Kotlin coroutines are so severely broken that they don't even provide program order happens-before. – Marko Topolnik Oct 23 at 11:11
  • @MarkoTopolnik, correct me if I'm wrong, but JLS only guarantees "program order happens-before" for execution on the same thread. Now, with coroutines, even though the code looks sequential, in practice there is some machinery that offloads it to different threads. I understand your point "this is such a basic guarantee that I wouldn't even waste my time checking it" (from another comment), but I asked this question to get a rigorous answer. I'm pretty sure that the examples I wrote are thread safe, but I want to understand why. – Vasiliy Oct 23 at 11:50

The code you wrote has three accesses to shared state:

var mutableVar = 0                        // access 1, init
withContext(Dispatchers.IO) {
    mutableVar = 1                        // access 2, write
System.out.println("value: $mutableVar")  // access 3, read

The three accesses are strictly sequentially ordered, with no concurrency between them, and you can rest assured that Kotlin's infrastructure takes care of establishing a happens-before edge when handing off to the IO thread pool and back to your calling coroutine.

Here's an equivalent example that may perhaps look more convincing:

launch(Dispatchers.Default) {
    var mutableVar = 0             // 1
    mutableVar = 1                 // 2
    println("value: $mutableVar")  // 3

Since delay is a suspendable function, and since we're using the Default dispatcher that is backed by a thread pool, lines 1, 2 and 3 may each execute on a different thread. Therefore your question about happen-before guarantees applies equally to this example. On the other hand, in this case it is (I would hope) completely obvious that the behavior of this code is consistent with the principles of sequential execution.

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    Thanks. It's actually the part after "rest assured" that motivated me to ask this question. Are there any links to docs that I could read? Alternatively, links to source code where this happens-before edge is established would also be of great help (join, synchronization, or any other method). – Vasiliy Oct 23 at 10:36
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    This is such a basic guarantee that I wouldn't even waste my time checking it. Under the hood it boils down to executorService.submit() and there is some typical mechanism of awaiting on the completion of the task (completing a CompletableFuture or something similar). From Kotlin coroutines' point of view there is no concurrency at all here. – Marko Topolnik Oct 23 at 10:41
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    You can think of your question as analogous to asking "does the OS guarantee a happens-before when suspending a thread and then resuming it on another core?" Threads are to coroutines what CPU cores are to threads. – Marko Topolnik Oct 23 at 10:51
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    Thanks for your explanation. However, I asked this question to understand why it works. I see your point, but, so far, it's not the rigorous answer I'm looking for. – Vasiliy Oct 23 at 11:55
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    Well... I actually don't think this thread has established that the code is sequential. It has asserted it, surely. I, too, would be interested in seeing the mechanism that guarantees that the example behaves as expected, without affecting performance. – G. Blake Meike Oct 23 at 13:59

Coroutines in Kotlin do provide happens before guarantees.

The rule is: inside a coroutine, the code prior to a suspend function call happens before the code after the suspend call.

You should think about coroutines as if they were regular threads:

Even though a coroutine in Kotlin can execute on multiple threads it is just like a thread from a standpoint of mutable state. No two actions in the same coroutine can be concurrent.

Source: https://proandroiddev.com/what-is-concurrent-access-to-mutable-state-f386e5cb8292

Getting back to the code example. Capturing vars in lambda function bodies is not the best idea, especially when lambda is a coroutine. The code prior to a lambda does not happen before the code inside.

See https://youtrack.jetbrains.com/issue/KT-15514

  • The rule is this, actually: the code prior to a suspend function call happens-before the code inside the suspend function, happens-before the code after the suspend call. This, in turn, can be generalized to "the code's program order is also the code's happens-before order". Note the absence of anything specific to suspendable functions in that statement. – Marko Topolnik Oct 23 at 18:55

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