Futures
Futures were introduced in Java 5 (2004). They're basically placeholders for a result of an operation that hasn't finished yet. Once the operation finishes, the Future will contain that result. For example, an operation can be a Runnable or Callable instance that is submitted to an ExecutorService. The submitter of the operation can use the Future object to check whether the operation isDone(), or wait for it to finish using the blocking get() method.
Example:
/**
* A task that sleeps for a second, then returns 1
**/
public static class MyCallable implements Callable<Integer> {
@Override
public Integer call() throws Exception {
Thread.sleep(1000);
return 1;
}
}
public static void main(String[] args) throws Exception{
ExecutorService exec = Executors.newSingleThreadExecutor();
Future<Integer> f = exec.submit(new MyCallable());
System.out.println(f.isDone()); //False
System.out.println(f.get()); //Waits until the task is done, then prints 1
}
CompletableFutures
CompletableFutures were introduced in Java 8 (2014). They are in fact an evolution of regular Futures, inspired by Google's Listenable Futures, part of the Guava library. They are Futures that also allow you to string tasks together in a chain. You can use them to tell some worker thread to "go do some task X, and when you're done, go do this other thing using the result of X". Using CompletableFutures, you can do something with the result of the operation without actually blocking a thread to wait for the result. Here's a simple example:
/**
* A supplier that sleeps for a second, and then returns one
**/
public static class MySupplier implements Supplier<Integer> {
@Override
public Integer get() {
try {
Thread.sleep(1000);
} catch (InterruptedException e) {
//Do nothing
}
return 1;
}
}
/**
* A (pure) function that adds one to a given Integer
**/
public static class PlusOne implements Function<Integer, Integer> {
@Override
public Integer apply(Integer x) {
return x + 1;
}
}
public static void main(String[] args) throws Exception {
ExecutorService exec = Executors.newSingleThreadExecutor();
CompletableFuture<Integer> f = CompletableFuture.supplyAsync(new MySupplier(), exec);
System.out.println(f.isDone()); // False
CompletableFuture<Integer> f2 = f.thenApply(new PlusOne());
System.out.println(f2.get()); // Waits until the "calculation" is done, then prints 2
}
RxJava
RxJava is whole library for reactive programming created at Netflix. At a glance, it will appear to be similar to Java 8's streams. It is, except it's much more powerful.
Similarly to Futures, RxJava can be used to string together a bunch of synchronous or asynchronous actions to create a processing pipeline. Unlike Futures, which are single-use, RxJava works on streams of zero or more items. Including never-ending streams with an infinite number of items. It's also much more flexible and powerful thanks to an unbelievably rich set of operators.
Unlike Java 8's streams, RxJava also has a backpressure mechanism, which allows it to handle cases in which different parts of your processing pipeline operate in different threads, at different rates.
The downside of RxJava is that despite the solid documentation, it is a challenging library to learn due to the paradigm shift involved. Rx code can also be a nightmare to debug, especially if multiple threads are involved, and even worse - if backpressure is needed.
Bonus: Java 9 Reactive Streams
Java 9's Reactive Streams aka Flow API are a set of Interfaces implemented by various reactive streams libraries such as RxJava 2, Akka Streams, and Vertx. They allow these reactive libraries to interconnect, while preserving the all important back-pressure.