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Variable value is still null even after assigning a value inside the listener block [duplicate]

(Disclaimer: There are a ton of questions which arise from people asking about data being null/incorrect when using asynchronous operations through requests such as facebook,firebase, etc. My intention for this question was to provide a simple answer for that problem to everyone starting out with asynchronous operations in android)
I'm trying to get data from one of my operations, when I debug it using breakpoints or logs, the values are there, but when I run it they are always null, how can I solve this ?
Firebase
firebaseFirestore.collection("some collection").get()
.addOnSuccessListener(new OnSuccessListener<QuerySnapshot>() {
#Override
public void onSuccess(QuerySnapshot documentSnapshots) {
//I want to return these values I receive here...
});
//...and use the returned value here.
Facebook
GraphRequest request = GraphRequest.newGraphPathRequest(
accessToken,
"some path",
new GraphRequest.Callback() {
#Override
public void onCompleted(GraphResponse response) {
//I want to return these values I receive here...
}
});
request.executeAsync();
//...and use the returned value here.
Kotlin coroutine
var result: SomeResultType? = null
someScope.launch {
result = someSuspendFunctionToRetrieveSomething()
//I want to return the value I received here...
}
Log.d("result", result.toString()) //...but it is still null here.
Etc.

What is a Synchronous/Asynchronous operation ?
Well, Synchronous waits until the task has completed. Your code executes "top-down" in this situation.
Asynchronous completes a task in the background and can notify you when it is complete.
If you want to return the values from an async operation through a method/function, you can define your own callbacks in your method/function to use these values as they are returned from these operations.
Here's how for Java
Start off by defining an interface :
interface Callback {
void myResponseCallback(YourReturnType result);//whatever your return type is: string, integer, etc.
}
next, change your method signature to be like this :
public void foo(final Callback callback) { // make your method, which was previously returning something, return void, and add in the new callback interface.
next up, wherever you previously wanted to use those values, add this line :
callback.myResponseCallback(yourResponseObject);
as an example :
#Override
public void onSuccess(QuerySnapshot documentSnapshots) {
// create your object you want to return here
String bar = document.get("something").toString();
callback.myResponseCallback(bar);
})
now, where you were previously calling your method called foo:
foo(new Callback() {
#Override
public void myResponseCallback(YourReturnType result) {
//here, this result parameter that comes through is your api call result to use, so use this result right here to do any operation you previously wanted to do.
}
});
}
How do you do this for Kotlin ?
(as a basic example where you only care for a single result)
start off by changing your method signature to something like this:
fun foo(callback:(YourReturnType) -> Unit) {
.....
then, inside your asynchronous operation's result :
firestore.collection("something")
.document("document").get()
.addOnSuccessListener {
val bar = it.get("something").toString()
callback(bar)
}
then, where you would have previously called your method called foo, you now do this :
foo() { result->
// here, this result parameter that comes through is
// whatever you passed to the callback in the code aboce,
// so use this result right here to do any operation
// you previously wanted to do.
}
// Be aware that code outside the callback here will run
// BEFORE the code above, and cannot rely on any data that may
// be set inside the callback.
if your foo method previously took in parameters :
fun foo(value:SomeType, callback:(YourType) -> Unit)
you simply change it to :
foo(yourValueHere) { result ->
// here, this result parameter that comes through is
// whatever you passed to the callback in the code aboce,
// so use this result right here to do any operation
// you previously wanted to do.
}
these solutions show how you can create a method/function to return values from async operations you've performed through the use of callbacks.
However, it is important to understand that, should you not be interested in creating a method/function for these:
#Override
public void onSuccess(SomeApiObjectType someApiResult) {
// here, this `onSuccess` callback provided by the api
// already has the data you're looking for (in this example,
// that data would be `someApiResult`).
// you can simply add all your relevant code which would
// be using this result inside this block here, this will
// include any manipulation of data, populating adapters, etc.
// this is the only place where you will have access to the
// data returned by the api call, assuming your api follows
// this pattern
})

There's a particular pattern of this nature I've seen repeatedly, and I think an explanation of what's happening would help. The pattern is a function/method that calls an API, assigning the result to a variable in the callback, and returns that variable.
The following function/method always returns null, even if the result from the API is not null.
Kotlin
fun foo(): String? {
var myReturnValue: String? = null
someApi.addOnSuccessListener { result ->
myReturnValue = result.value
}.execute()
return myReturnValue
}
Kotlin coroutine
fun foo(): String? {
var myReturnValue: String? = null
lifecycleScope.launch {
myReturnValue = someApiSuspendFunction()
}
return myReturnValue
}
Java 8
private String fooValue = null;
private String foo() {
someApi.addOnSuccessListener(result -> fooValue = result.getValue())
.execute();
return fooValue;
}
Java 7
private String fooValue = null;
private String foo() {
someApi.addOnSuccessListener(new OnSuccessListener<String>() {
public void onSuccess(Result<String> result) {
fooValue = result.getValue();
}
}).execute();
return fooValue;
}
The reason is that when you pass a callback or listener to an API function, that callback code will only be run some time in the future, when the API is done with its work. By passing the callback to the API function, you are queuing up work, but the current function (foo() in this case) returns immediately before that work begins and before that callback code is run.
Or in the case of the coroutine example above, the launched coroutine is very unlikely to complete before the function that started it.
Your function that calls the API cannot return the result that is returned in the callback (unless it's a Kotlin coroutine suspend function). The solution, explained in the other answer, is to make your own function take a callback parameter and not return anything.
Alternatively, if you're working with coroutines, you can make your function suspend instead of launching a separate coroutine. When you have suspend functions, somewhere in your code you must launch a coroutine and handle the results within the coroutine. Typically, you would launch a coroutine in a lifecycle function like onCreate(), or in a UI callback like in an OnClickListener.

Other answer explains how to consume APIs based on callbacks by exposing a similar callbacks-based API in the outer function. However, recently Kotlin coroutines become more and more popular, especially on Android and while using them, callbacks are generally discouraged for such purposes. Kotlin approach is to use suspend functions instead. Therefore, if our application uses coroutines already, I suggest not propagating callbacks APIs from 3rd party libraries to the rest of our code, but converting them to suspend functions.
Converting callbacks to suspend
Let's assume we have this callback API:
interface Service {
fun getData(callback: Callback<String>)
}
interface Callback<in T> {
fun onSuccess(value: T)
fun onFailure(throwable: Throwable)
}
We can convert it to suspend function using suspendCoroutine():
private val service: Service
suspend fun getData(): String {
return suspendCoroutine { cont ->
service.getData(object : Callback<String> {
override fun onSuccess(value: String) {
cont.resume(value)
}
override fun onFailure(throwable: Throwable) {
cont.resumeWithException(throwable)
}
})
}
}
This way getData() can return the data directly and synchronously, so other suspend functions can use it very easily:
suspend fun otherFunction() {
val data = getData()
println(data)
}
Note that we don't have to use withContext(Dispatchers.IO) { ... } here. We can even invoke getData() from the main thread as long as we are inside the coroutine context (e.g. inside Dispatchers.Main) - main thread won't be blocked.
Cancellations
If the callback service supports cancelling of background tasks then it is best to cancel when the calling coroutine is itself cancelled. Let's add a cancelling feature to our callback API:
interface Service {
fun getData(callback: Callback<String>): Task
}
interface Task {
fun cancel();
}
Now, Service.getData() returns Task that we can use to cancel the operation. We can consume it almost the same as previously, but with small changes:
suspend fun getData(): String {
return suspendCancellableCoroutine { cont ->
val task = service.getData(object : Callback<String> {
...
})
cont.invokeOnCancellation {
task.cancel()
}
}
}
We only need to switch from suspendCoroutine() to suspendCancellableCoroutine() and add invokeOnCancellation() block.
Example using Retrofit
interface GitHubService {
#GET("users/{user}/repos")
fun listRepos(#Path("user") user: String): Call<List<Repo>>
}
suspend fun listRepos(user: String): List<Repo> {
val retrofit = Retrofit.Builder()
.baseUrl("https://api.github.com/")
.build()
val service = retrofit.create<GitHubService>()
return suspendCancellableCoroutine { cont ->
val call = service.listRepos(user)
call.enqueue(object : Callback<List<Repo>> {
override fun onResponse(call: Call<List<Repo>>, response: Response<List<Repo>>) {
if (response.isSuccessful) {
cont.resume(response.body()!!)
} else {
// just an example
cont.resumeWithException(Exception("Received error response: ${response.message()}"))
}
}
override fun onFailure(call: Call<List<Repo>>, t: Throwable) {
cont.resumeWithException(t)
}
})
cont.invokeOnCancellation {
call.cancel()
}
}
}
Native support
Before we start converting callbacks to suspend functions, it is worth checking whether the library that we use does support suspend functions already: natively or with some extension. Many popular libraries like Retrofit or Firebase support coroutines and suspend functions. Usually, they either provide/handle suspend functions directly or they provide suspendable waiting on top of their asynchronous task/call/etc. object. Such waiting is very often named await().
For example, Retrofit supports suspend functions directly since 2.6.0:
interface GitHubService {
#GET("users/{user}/repos")
suspend fun listRepos(#Path("user") user: String): List<Repo>
}
Note that we not only added suspend, but also we no longer return Call, but the result directly. Now, we can use it without all this enqueue() boilerplate:
val repos = service.listRepos(user)

TL;DR The code you pass to these APIs (e.g. in the onSuccessListener) is a callback, and it runs asynchronously (not in the order it is written in your file). It runs at some point later in the future to "call back" into your code. Without using a coroutine to suspend the program, you cannot "return" data retrieved in a callback from a function.
What is a callback?
A callback is a piece of code you pass to some third party library that it will run later when some event happens (e.g. when it gets data from a server). It is important to remember that the callback is not run in the order you wrote it - it may be run much later in the future, could run multiple times, or may never run at all. The example callback below will run Point A, start the server fetching process, run Point C, exit the function, then some time in the distant future may run Point B when the data is retrieved. The printout at Point C will always be empty.
fun getResult() {
// Point A
var r = ""
doc.get().addOnSuccessListener { result ->
// The code inside the {} here is the "callback"
// Point B - handle result
r = result // don't do this!
}
// Point C - r="" still here, point B hasn't run yet
println(r)
}
How do I get the data from the callback then?
Make your own interface/callback
Making your own custom interface/callback can sometimes make things cleaner looking but it doesn't really help with the core question of how to use the data outside the callback - it just moves the aysnc call to another location. It can help if the primary API call is somewhere else (e.g. in another class).
// you made your own callback to use in the
// async API
fun getResultImpl(callback: (String)->Unit) {
doc.get().addOnSuccessListener { result ->
callback(result)
}
}
// but if you use it like this, you still have
// the EXACT same problem as before - the printout
// will always be empty
fun getResult() {
var r = ""
getResultImpl { result ->
// this part is STILL an async callback,
// and runs later in the future
r = result
}
println(r) // always empty here
}
// you still have to do things INSIDE the callback,
// you could move getResultImpl to another class now,
// but still have the same potential pitfalls as before
fun getResult() {
getResultImpl { result ->
println(result)
}
}
Some examples of how to properly use a custom callback: example 1, example 2, example 3
Make the callback a suspend function
Another option is to turn the async method into a suspend function using coroutines so it can wait for the callback to complete. This lets you write linear-looking functions again.
suspend fun getResult() {
val result = suspendCoroutine { cont ->
doc.get().addOnSuccessListener { result ->
cont.resume(result)
}
}
// the first line will suspend the coroutine and wait
// until the async method returns a result. If the
// callback could be called multiple times this may not
// be the best pattern to use
println(result)
}
Re-arrange your program into smaller functions
Instead of writing monolithic linear functions, break the work up into several functions and call them from within the callbacks. You should not try to modify local variables within the callback and return or use them after the callback (e.g. Point C). You have to move away from the idea of returning data from a function when it comes from an async API - without a coroutine this generally isn't possible.
For example, you could handle the async data in a separate method (a "processing method") and do as little as possible in the callback itself other than call the processing method with the received result. This helps avoid a lot of the common errors with async APIs where you attempt to modify local variables declared outside the callback scope or try to return things modified from within the callback. When you call getResult it starts the process of getting the data. When that process is complete (some time in the future) the callback calls showResult to show it.
fun getResult() {
doc.get().addOnSuccessListener { result ->
showResult(result)
}
// don't try to show or return the result here!
}
fun showResult(result: String) {
println(result)
}
Example
As a concrete example here is a minimal ViewModel showing how one could include an async API into a program flow to fetch data, process it, and display it in an Activity or Fragment. This is written in Kotlin but is equally applicable to Java.
class MainViewModel : ViewModel() {
private val textLiveData = MutableLiveData<String>()
val text: LiveData<String>
get() = textLiveData
fun fetchData() {
// Use a coroutine here to make a dummy async call,
// this is where you could call Firestore or other API
// Note that this method does not _return_ the requested data!
viewModelScope.launch {
delay(3000)
// pretend this is a slow network call, this part
// won't run until 3000 ms later
val t = Calendar.getInstance().time
processData(t.toString())
}
// anything out here will run immediately, it will not
// wait for the "slow" code above to run first
}
private fun processData(d: String) {
// Once you get the data you may want to modify it before displaying it.
val p = "The time is $d"
textLiveData.postValue(p)
}
}
A real API call in fetchData() might look something more like this
fun fetchData() {
firestoreDB.collection("data")
.document("mydoc")
.get()
.addOnCompleteListener { task ->
if (task.isSuccessful) {
val data = task.result.data
processData(data["time"])
}
else {
textLiveData.postValue("ERROR")
}
}
}
The Activity or Fragment that goes along with this doesn't need to know anything about these calls, it just passes actions in by calling methods on the ViewModel and observes the LiveData to update its views when new data is available. It cannot assume that the data is available immediately after a call to fetchData(), but with this pattern it doesn't need to.
The view layer can also do things like show and hide a progress bar while the data is being loaded so the user knows it's working in the background.
class MainActivity : AppCompatActivity() {
override fun onCreate(savedInstanceState: Bundle?) {
super.onCreate(savedInstanceState)
val binding = ActivityMainBinding.inflate(layoutInflater)
setContentView(binding.root)
val model: MainViewModel by viewModels()
// Observe the LiveData and when it changes, update the
// state of the Views
model.text.observe(this) { processedData ->
binding.text.text = processedData
binding.progress.visibility = View.GONE
}
// When the user clicks the button, pass that action to the
// ViewModel by calling "fetchData()"
binding.getText.setOnClickListener {
binding.progress.visibility = View.VISIBLE
model.fetchData()
}
binding.progress.visibility = View.GONE
}
}
The ViewModel is not strictly necessary for this type of async workflow - here is an example of how to do the same thing in the activity
class MainActivity : AppCompatActivity() {
private lateinit var binding: ActivityMainBinding
override fun onCreate(savedInstanceState: Bundle?) {
super.onCreate(savedInstanceState)
binding = ActivityMainBinding.inflate(layoutInflater)
setContentView(binding.root)
// When the user clicks the button, trigger the async
// data call
binding.getText.setOnClickListener {
binding.progress.visibility = View.VISIBLE
fetchData()
}
binding.progress.visibility = View.GONE
}
private fun fetchData() {
lifecycleScope.launch {
delay(3000)
val t = Calendar.getInstance().time
processData(t.toString())
}
}
private fun processData(d: String) {
binding.progress.visibility = View.GONE
val p = "The time is $d"
binding.text.text = p
}
}
(and, for completeness, the activity XML)
<?xml version="1.0" encoding="utf-8"?>
<androidx.constraintlayout.widget.ConstraintLayout xmlns:android="http://schemas.android.com/apk/res/android"
xmlns:app="http://schemas.android.com/apk/res-auto"
xmlns:tools="http://schemas.android.com/tools"
android:layout_width="match_parent"
android:layout_height="match_parent"
tools:context=".MainActivity">
<TextView
android:id="#+id/text"
android:layout_margin="16dp"
android:layout_width="wrap_content"
android:layout_height="wrap_content"
app:layout_constraintLeft_toLeftOf="parent"
app:layout_constraintRight_toRightOf="parent"
app:layout_constraintTop_toTopOf="parent"/>
<Button
android:id="#+id/get_text"
android:layout_width="wrap_content"
android:layout_height="wrap_content"
android:layout_margin="16dp"
android:text="Get Text"
app:layout_constraintLeft_toLeftOf="parent"
app:layout_constraintRight_toRightOf="parent"
app:layout_constraintTop_toBottomOf="#+id/text"
/>
<ProgressBar
android:id="#+id/progress"
android:layout_width="match_parent"
android:layout_height="wrap_content"
android:padding="48dp"
app:layout_constraintLeft_toLeftOf="parent"
app:layout_constraintRight_toRightOf="parent"
app:layout_constraintTop_toBottomOf="#+id/get_text"
/>
</androidx.constraintlayout.widget.ConstraintLayout>

Design pattern to best implement batch api requests that happen transparently to the calling layer

I have a batch processor that I want to refactor to be expressed a 1-to-1 fashion based on input to increase readability, and for further optimization later on. The issue is that there is a service that should be called in batches to reduce HTTP overhead, so mixing the 1-to-1 code with the batch code is a bit tricky, and we may not want to call the service with every input. Results can be sent out eagerly one-by-one, but order must be maintained, so something like a flow doesn't seem to work.
So, ideally the batch processor would look something like this:
class Processor<A, B> {
val service: Service<A, B>
val scope: CoroutineScope
fun processBatch(input: List<A>) {
input.map {
Pair(it, scope.async { service.call(it) })
}.map {
(a, b) ->
runBlocking { b.await().let { /** handle result, do something with a if result is null, etc **/ } }
}
}
}
The desire is to perform all of the service logic in such a way that it is executing in the background, automatically splitting the inputs for the service into batches, executing them asynchronously, and somehow mapping the result of the batch call into the suspended call.
Here is a hacky implementation:
class Service<A, B> {
val inputContainer: MutableList<A>
val outputs: MutableList<B>
val runCalled = AtomicBoolean(false)
val batchSize: Int
suspended fun call(input: A): B? {
// some prefiltering logic that returns a null early
val index = inputContainer.size
inputContainer.add(a) // add to overall list for later batching
return suspend {
run()
outputs[index]
}
}
fun run() {
val batchOutputs = mutableListOf<Deferred<List<B?>>>()
if (!runCalled.getAndSet(true)) {
inputs.chunked(batchSize).forEach {
batchOutputs.add(scope.async { batchCall(it) })
}
runBlocking {
batchOutputs.map {
val res = result.await()
outputs.addAll(res)
}
}
}
}
suspended fun batchCall(input: List<A>): List<B?> {
// batch API call, etc
}
}
Something like this could work but there are several concerns:
All API calls go out at once. Ideally this would be batching and executing in the background while other inputs are being scheduled, but this is not .
Processing of the service result for the first input cannot resume until all results have been returned. Ideally we could process the result if the service call has returned, while other results continue to be performed in the background.
Containers of intermediate results seem hacky and prone to bugs. Cleanup logic is also needed, which introduces more hacky bits into the rest of the code
I can think of several optimizations to the address 1 and 2, but I imagine concerns related to 3 would be worse. This seems like a fairly common call pattern and I would expect there to be a library or much simpler design pattern to accomplish this, but I haven't been able to find anything. Any guidance is appreciated.

You're on the right track by using Deferred. The solution I would use is:
When the caller makes a request, create a CompletableDeferred
Using a channel, pass this CompletableDeferred to the service for later completion
Have the caller suspend until the service completes the CompletableDeferred
It might look something like this:
val requestChannel = Channel<Pair<Request, CompletableDeferred<Result>>()
suspend fun doRequest(request: Request): Result {
val result = CompletableDeferred<Result>()
requestChannel.send(Pair(request, result))
return result.await()
}
fun run() = scope.launch {
while(isActive) {
val (requests, deferreds) = getBatch(batchSize).unzip()
val results = batchCall(requests)
(results zip deferreds).forEach { (result, deferred) ->
deferred.complete(result)
}
}
}
suspend fun getBatch(batchSize: Int) = buildList {
repeat(batchSize) {
add(requestChannel.receive())
}
}

How to wait for a flow to complete emitting the values

I have a function "getUser" in my Repository which emits an object representing a user based on the provided id.
flow function
fun getUser(id: String) = callbackFlow {
val collectionReference: CollectionReference =
FirebaseFirestore.getInstance().collection(COLLECTION_USERS)
val query: Query = collectionReference.whereEqualTo(ID, id)
query.get().addOnSuccessListener {
val lst = it.toObjects(User::class.java)
if (lst.isEmpty())
offer(null)
else
offer(it.toObjects(User::class.java)[0])
}
awaitClose()
}
I need these values in another class. I loop over a list of ids and I add the collected user to a new list. How can I wait for the list to be completed when I collect the values, before calling return?
collector function
private fun computeAttendeesList(reminder: Reminder): ArrayList<User> {
val attendeesList = arrayListOf<User>()
for (friend in reminder.usersToShare) {
repoScope.launch {
Repository.getUser(friend).collect {
it?.let { user ->
if (!attendeesList.contains(user))
attendeesList.add(user)
}
}
}
}
return attendeesList
}
I do not want to use live data since this is not a UI-related class.

There are multiple problems to address in this code:
getUser() is meant to return a single User, but it currently returns a Flow<User>
which will never end, and never return more than one user.
the way the list of users is constructed from multiple concurrent query is not thread safe (because multiple launches are executed on the multi-threaded IO dispatcher, and they all update the same unsafe list directly)
the actual use case is to get a list of users from Firebase, but many queries for a single ID are used instead of a single query
Solution to #1
Let's tackle #1 first. Here is a version of getUser() that suspends for a single User instead of returning a Flow:
suspend fun getUser(id: String): User {
val collectionReference = FirebaseFirestore.getInstance().collection(COLLECTION_USERS)
val query = collectionReference.whereEqualTo(ID, id)
return query.get().await().let { it.toObjects(User::class.java) }.firstOrNull()
}
// use the kotlinx-coroutines-play-services library instead
private suspend fun <T> Task<T>.await(): T {
return suspendCancellableCoroutine { cont ->
addOnCompleteListener {
val e = exception
if (e == null) {
#Suppress("UNCHECKED_CAST")
if (isCanceled) cont.cancel() else cont.resume(result as T)
} else {
cont.resumeWithException(e)
}
}
}
}
It turns out that this await() function was already written (in a better way) and it's available in the kotlinx-coroutines-play-services library, so you don't need to actually write it yourself.
Solution to #2
If we could not rewrite the whole thing according to #3, we could deal with problem #2 this way:
private suspend fun computeAttendeesList(reminder: Reminder): List<User> {
return reminder.usersToShare
.map { friendId ->
repoScope.async { Repository.getUser(friendId) }
}
.map { it.await() }
.toList()
}
Solution to #3
Instead, we could directly query Firebase for the whole list:
suspend fun getUsers(ids: List<String>): List<User> {
val collectionReference = FirebaseFirestore.getInstance().collection(COLLECTION_USERS)
val query = collectionReference.whereIn(ID, ids)
return query.get().await().let { it.toObjects(User::class.java) }
}
And then consume it in a very basic way:
private suspend fun computeAttendeesList(reminder: Reminder): List<User> {
return Repository.getUsers(reminder.usersToShare)
}
Alternatively, you could make this function blocking (remove suspend) and wrap your call in runBlocking (if you really need to block the current thread).
Note that this solution didn't enforce any dispatcher, so if you want a particular scope or dispatcher, you can wrap one of the suspend function calls with withContext.

await inside await or how to get parent scope? Kotlin

I have a fucntion:
suspend fun getChats() {
val chatList = mutableListOf<Chat>()
getMyChats { chats ->
chats.forEach {
it.getDetail().await()
}
}.await()
}
But compiler show Suspension functions can be called only within coroutine body for await() which inside of forEach loop. How can I avoid this problem or how can I pass parent scope for it?
**getMyChats() receives a callback

According to you, the getMyChats doesn't support taking suspendable block (lambda).
So you can wrap it with a suspendCancellableCoroutine.
suspend fun getMyChatsSuspend(): List<Chat> = suspendCancellableCoroutine { cont ->
getMyChats { cont.resume(it) }
}
Now use your function like this:
suspend fun getChats() {
...
val chats = getMyChatsSuspend()
val chatDetails = chats.map{ chat.getDetail() }
val chatDetailsAwait = awaitAll( *chatDetails.toTypedArray() )
}
Obviously just chain the calls instead of creating multiple variables if you want
If you want everything to be done in single line you can do:
val resolvedDetails = getMyChatsSuspend().map{ chat.getDetail() }.let { awaitAll(*it.toTypedArray()) }

You have to isolate the getMyChats function like #Animesh Sahu said, but that last call to await() looks very suspicious so I'll rewrite it.
I'll also assume that await is not necessarily on a Deferred<T>.
suspend fun getChats() {
val chatList = mutableListOf<Chat>()
val result = CompletableDeferred<List<Chat>>()
getMyChats { result.complete(it) }.await()
val chats = result.await()
chats.forEach {
it.getDetail().await()
}
}
If you provide the function signatures of the functions involved I might be able give you a nicer solution.
Although without looking at anything else, I can tell you that the getMyChats function needs a refactor.

How to execute a program with Kotlin and Arrow

I'm trying to learn a bit of Functional Programming using Kotlin and Arrow and in this way I've already read some blogposts like the following one: https://jorgecastillo.dev/kotlin-fp-1-monad-stack, which is good, I've understand the main idea, but when creating a program, I can't figure out how to run it.
Let me be more explicit:
I have the following piece of code:
typealias EitherIO<A, B> = EitherT<ForIO, A, B>
sealed class UserError(
val message: String,
val status: Int
) {
object AuthenticationError : UserError(HttpStatus.UNAUTHORIZED.reasonPhrase, HttpStatus.UNAUTHORIZED.value())
object UserNotFound : UserError(HttpStatus.NOT_FOUND.reasonPhrase, HttpStatus.NOT_FOUND.value())
object InternalServerError : UserError(HttpStatus.INTERNAL_SERVER_ERROR.reasonPhrase, HttpStatus.INTERNAL_SERVER_ERROR.value())
}
#Component
class UserAdapter(
private val myAccountClient: MyAccountClient
) {
#Lazy
#Inject
lateinit var subscriberRepository: SubscriberRepository
fun getDomainUser(ssoId: Long): EitherIO<UserError, User?> {
val io = IO.fx {
val userResource = getUserResourcesBySsoId(ssoId, myAccountClient).bind()
userResource.fold(
{ error -> Either.Left(error) },
{ success ->
Either.right(composeDomainUserWithSubscribers(success, getSubscribersForUserResource(success, subscriberRepository).bind()))
})
}
return EitherIO(io)
}
fun composeDomainUserWithSubscribers(userResource: UserResource, subscribers: Option<Subscribers>): User? {
return subscribers.map { userResource.toDomainUser(it) }.orNull()
}
}
private fun getSubscribersForUserResource(userResource: UserResource, subscriberRepository: SubscriberRepository): IO<Option<Subscribers>> {
return IO {
val msisdnList = userResource.getMsisdnList()
Option.invoke(subscriberRepository.findAllByMsisdnInAndDeletedIsFalse(msisdnList).associateBy(Subscriber::msisdn))
}
}
private fun getUserResourcesBySsoId(ssoId: Long, myAccountClient: MyAccountClient): IO<Either<UserError, UserResource>> {
return IO {
val response = myAccountClient.getUserBySsoId(ssoId)
if (response.isSuccessful) {
val userResource = JacksonUtils.fromJsonToObject(response.body()?.string()!!, UserResource::class.java)
Either.Right(userResource)
} else {
when (response.code()) {
401 -> Either.Left(UserError.AuthenticationError)
404 -> Either.Left(UserError.UserNotFound)
else -> Either.Left(UserError.InternalServerError)
}
}
}.handleError { Either.Left(UserError.InternalServerError) }
}
which, as you can see is accumulating some results into an IO monad. I should run this program using unsafeRunSync() from arrow, but on javadoc it's stated the following: **NOTE** this function is intended for testing, it should never appear in your mainline production code!.
I should mention that I know about unsafeRunAsync, but in my case I want to be synchronous.
Thanks!

Instead of running unsafeRunSync, you should favor unsafeRunAsync.
If you have myFun(): IO<A> and want to run this, then you call myFun().unsafeRunAsync(cb) where cb: (Either<Throwable, A>) -> Unit.
For instance, if your function returns IO<List<Int>> then you can call
myFun().unsafeRunAsync { /* it (Either<Throwable, List<Int>>) -> */
it.fold(
{ Log.e("Foo", "Error! $it") },
{ println(it) })
}
This will run the program contained in the IO asynchronously and pass the result safely to the callback, which will log an error if the IO threw, and otherwise it will print the list of integers.
You should avoid unsafeRunSync for a number of reasons, discussed here. It's blocking, it can cause crashes, it can cause deadlocks, and it can halt your application.
If you really want to run your IO as a blocking computation, then you can precede this with attempt() to have your IO<A> become an IO<Either<Throwable, A>> similar to the unsafeRunAsync callback parameter. At least then you won't crash.
But unsafeRunAsync is preferred. Also, make sure your callback passed to unsafeRunAsync won't throw any errors, at it's assumed it won't. Docs.