Java 8 introduces CompletableFuture, a new implementation of Future that is composable (includes a bunch of thenXxx methods). I'd like to use this exclusively, but many of the libraries I want to use return only non-composable Future instances.

Is there a way to wrap up a returned Future instances inside of a CompleteableFuture so that I can compose it?

7 Answers 7


If the library you want to use also offers a callback style method in addition to the Future style, you can provide it a handler that completes the CompletableFuture without any extra thread blocking. Like so:

    AsynchronousFileChannel open = AsynchronousFileChannel.open(Paths.get("/some/file"));
    // ... 
    CompletableFuture<ByteBuffer> completableFuture = new CompletableFuture<ByteBuffer>();
    open.read(buffer, position, null, new CompletionHandler<Integer, Void>() {
        public void completed(Integer result, Void attachment) {

        public void failed(Throwable exc, Void attachment) {

Without the callback the only other way I see solving this is to use a polling loop that puts all your Future.isDone() checks on a single thread and then invoking complete whenever a Future is gettable.

  • 1
    I am using Apache Http async library which accepts FutureCallback. It made my life easy :) Aug 22, 2017 at 19:10

There is a way, but you won't like it. The following method transforms a Future<T> into a CompletableFuture<T>:

public static <T> CompletableFuture<T> makeCompletableFuture(Future<T> future) {
  if (future.isDone())
    return transformDoneFuture(future);
  return CompletableFuture.supplyAsync(() -> {
    try {
      if (!future.isDone())
      return future.get();
    } catch (ExecutionException e) {
      throw new RuntimeException(e);
    } catch (InterruptedException e) {
      // Normally, this should never happen inside ForkJoinPool
      // Add the following statement if the future doesn't have side effects
      // future.cancel(true);
      throw new RuntimeException(e);

private static <T> CompletableFuture<T> transformDoneFuture(Future<T> future) {
  CompletableFuture<T> cf = new CompletableFuture<>();
  T result;
  try {
    result = future.get();
  } catch (Throwable ex) {
    return cf;
  return cf;

private static void awaitFutureIsDoneInForkJoinPool(Future<?> future)
    throws InterruptedException {
  ForkJoinPool.managedBlock(new ForkJoinPool.ManagedBlocker() {
    @Override public boolean block() throws InterruptedException {
      try {
      } catch (ExecutionException e) {
        throw new RuntimeException(e);
      return true;
    @Override public boolean isReleasable() {
      return future.isDone();

Obviously, the problem with this approach is, that for each Future, a thread will be blocked to wait for the result of the Future--contradicting the idea of futures. In some cases, it might be possible to do better. However, in general, there is no solution without actively wait for the result of the Future.

  • 1
    Ha, that's exactly what I wrote before thinking that there must be a better way. But, I guess not Apr 25, 2014 at 20:24
  • 15
    Hmmm... doesn't this solution eat one of the threads of the "common pool", just for waiting? Those "common pool" threads should never block... hmmmm...
    – Peti
    Dec 3, 2015 at 13:16
  • 1
    @Peti: You are right. However, the point is, if you are most likely doing something wrong, regardless whether you are using the common pool or an unbounded thread pool.
    – nosid
    Dec 4, 2015 at 0:24
  • 4
    It might not be perfect, but using CompletableFuture.supplyAsync(supplier, new SinglethreadExecutor()) would at least not block the common pool threads.
    – MikeFHay
    Jan 27, 2017 at 17:22
  • 7
    Please, just never do that
    – Laymain
    Jul 31, 2018 at 11:27

If your Future is the result of a call to an ExecutorService method (e.g. submit()), the easiest would be to use the CompletableFuture.runAsync(Runnable, Executor) method instead.


Runnbale myTask = ... ;
Future<?> future = myExecutor.submit(myTask);


Runnbale myTask = ... ;
CompletableFuture<?> future = CompletableFuture.runAsync(myTask, myExecutor);

The CompletableFuture is then created "natively".

EDIT: Pursuing comments by @SamMefford corrected by @MartinAndersson, if you want to pass a Callable, you need to call supplyAsync(), converting the Callable<T> into a Supplier<T>, e.g. with:

CompletableFuture.supplyAsync(() -> {
    try { return myCallable.call(); }
    catch (Exception ex) { throw new CompletionException(ex); } // Or return default value
}, myExecutor);

Because T Callable.call() throws Exception; throws an exception and T Supplier.get(); doesn't, you have to catch the exception so prototypes are compatible.

A note on exception handling

The get() method doesn't specify a throws, which means it should not throw a checked exception. However, unchecked exception can be used. The code in CompletableFuture shows that CompletionException is used and is unchecked (i.e. is a RuntimeException), hence the catch/throw wrapping any exception into a CompletionException.

Also, as @WeGa indicated, you can use the handle() method to deal with exceptions potentially being thrown by the result:

CompletableFuture<T> future = CompletableFuture.supplyAsync(...);
future.handle((ex,res) -> {
        if (ex != null) {
            // An exception occurred ...
        } else {
            // No exception was thrown, 'res' is valid and can be handled here
  • 1
    Or, if you're using Callable<T> rather than Runnable, instead try supplyAsync: CompletableFuture<T> future = CompletableFuture.supplyAsync(myCallable, myExecutor); Apr 28, 2020 at 22:38
  • @SamMefford thanks, I edited to include that information.
    – Matthieu
    Apr 29, 2020 at 9:46
  • supplyAsync receives a Supplier. The code will not compile if you attempt to pass in a Callable. Aug 6, 2020 at 12:26
  • @MartinAndersson that's right, thanks. I edited further to convert a Callable<T> to a Supplier<T>.
    – Matthieu
    Aug 7, 2020 at 13:16
  • 1
    You can also implement exception handling with java.util.concurrent.CompletableFuture#handle, chained right after CompletableFuture: CompletableFuture.supplyAsync(...).handle((response, throwable) -> ...)
    – WeGa
    Apr 29, 2021 at 6:33

I published a little futurity project that tries to make better than the straightforward way in the answer.

The main idea is to use the only one thread (and of course with not just a spin loop) to check all Futures states inside, which helps to avoid blocking a thread from a pool for each Future -> CompletableFuture transformation.

Usage example:

Future oldFuture = ...;
CompletableFuture profit = Futurity.shift(oldFuture);
  • This looks interesting. Is it using a timer thread ? How come this is not the accepted answer ?
    – Kira
    Mar 20, 2018 at 9:49
  • @Kira Yeah, it basically uses one timer thread to wait on all submitted futures. Mar 20, 2018 at 22:01



But, basically:

public class CompletablePromiseContext {
    private static final ScheduledExecutorService SERVICE = Executors.newSingleThreadScheduledExecutor();

    public static void schedule(Runnable r) {
        SERVICE.schedule(r, 1, TimeUnit.MILLISECONDS);

And, the CompletablePromise:

public class CompletablePromise<V> extends CompletableFuture<V> {
    private Future<V> future;

    public CompletablePromise(Future<V> future) {
        this.future = future;

    private void tryToComplete() {
        if (future.isDone()) {
            try {
            } catch (InterruptedException e) {
            } catch (ExecutionException e) {

        if (future.isCancelled()) {



public class Main {
    public static void main(String[] args) {
        final ExecutorService service = Executors.newSingleThreadExecutor();
        final Future<String> stringFuture = service.submit(() -> "success");
        final CompletableFuture<String> completableFuture = new CompletablePromise<>(stringFuture);

        completableFuture.whenComplete((result, failure) -> {
  • 1
    this is quite simple to reason about & elegant & fits most use cases. I would make the CompletablePromiseContext not-static and take param for the check interval (which is set to 1 ms here) then overload the CompletablePromise<V> constructor to be able to provide your own CompletablePromiseContext with a possibly different (longer) check interval for long-running Future<V> where you don't have to absolutely be able to run callback (or compose) immediately upon finishing, and you can also have an instance of CompletablePromiseContext to watch a set of Future (in case you have many) Apr 13, 2019 at 11:51

Let me suggest another (hopefully, better) option: https://github.com/vsilaev/java-async-await/tree/master/com.farata.lang.async.examples/src/main/java/com/farata/concurrent

Briefly, the idea is the following:

  1. Introduce CompletableTask<V> interface -- the union of the CompletionStage<V> + RunnableFuture<V>
  2. Warp ExecutorService to return CompletableTask from submit(...) methods (instead of Future<V>)
  3. Done, we have runnable AND composable Futures.

Implementation uses an alternative CompletionStage implementation (pay attention, CompletionStage rather than CompletableFuture):


J8ExecutorService exec = J8Executors.newCachedThreadPool();
CompletionStage<String> = exec
   .submit( someCallableA )
   .thenCombineAsync( exec.submit(someCallableB), (a, b) -> a + " " + b)
   .thenCombine( exec.submit(someCallableC), (ab, b) -> ab + " " + c); 
public static <T> CompletableFuture<T> fromFuture(Future<T> f) {
    return CompletableFuture.completedFuture(null).thenCompose(avoid -> {
        try {
            return CompletableFuture.completedFuture(f.get());
        } catch (InterruptedException e) {
            return CompletableFuture.failedFuture(e);
        } catch (ExecutionException e) {
            return CompletableFuture.failedFuture(e.getCause());

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