A Scala DSL to enable a direct style of coding when composing Future
s.
As of scala-async 1.0, Scala 2.12.12+ or 2.13.3+ are required.
libraryDependencies += "org.scala-lang.modules" %% "scala-async" % "1.0.1"
libraryDependencies += "org.scala-lang" % "scala-reflect" % scalaVersion.value % Provided
For Maven projects add the following to your (make sure to use the correct Scala version suffix to match your project’s Scala binary version):
<dependency>
<groupId>org.scala-lang.modules</groupId>
<artifactId>scala-async_2.13</artifactId>
<version>1.0.1</version>
</dependency>
<dependency>
<groupId>org.scala-lang</groupId>
<artifactId>scala-reflect</artifactId>
<version>2.13.8</version>
<scope>provided</scope>
</dependency>
Add the -Xasync
to the Scala compiler options.
scalacOptions += "-Xasync"
<project>
...
<plugin>
<groupId>net.alchim31.maven</groupId>
<artifactId>scala-maven-plugin</artifactId>
<version>4.4.0</version>
<configuration>
<args>
<arg>-Xasync</arg>
</args>
</configuration>
</plugin>
...
</project>
import scala.concurrent.ExecutionContext.Implicits.global
import scala.async.Async.{async, await}
val future = async {
val f1: Future[Boolean] = async { ...; true }
val f2 = async { ...; 42 }
if (await(f1)) await(f2) else 0
}
async
marks a block of asynchronous code. Such a block usually contains
one or more await
calls, which marks a point at which the computation
will be suspended until the awaited Future
is complete.
By default, async
blocks operate on scala.concurrent.{Future, Promise}
.
The system can be adapted to alternative implementations of the
Future
pattern.
Consider the following example:
def slowCalcFuture: Future[Int] = ... // 01
def combined: Future[Int] = async { // 02
await(slowCalcFuture) + await(slowCalcFuture) // 03
}
val x: Int = Await.result(combined, 10.seconds) // 05
Line 1 defines an asynchronous method: it returns a Future
.
Line 2 begins an async
block. During compilation,
the contents of this block will be analyzed to identify
the await
calls, and transformed into non-blocking
code.
Control flow will immediately pass to line 5, as the
computation in the async
block is not executed
on the caller's thread.
Line 3 begins by triggering slowCalcFuture
, and then
suspending until it has been calculated. Only after it
has finished, we trigger it again, and suspend again.
Finally, we add the results and complete combined
, which
in turn will release line 5 (unless it had already timed out).
It is important to note that while lines 1-4 are non-blocking, they are not parallel. If we wanted to parallelize the two computations, we could rearrange the code as follows:
def combined: Future[Int] = async {
val future1 = slowCalcFuture
val future2 = slowCalcFuture
await(future1) + await(future2)
}
The await
cannot be nested under a local method, object, class or lambda:
async {
List(1).foreach { x => await(f(x) } // invalid
}
This implementation restriction may be lifted in future versions.
This computation could also be expressed by directly using the higher-order functions of Futures:
def slowCalcFuture: Future[Int] = ...
val future1 = slowCalcFuture
val future2 = slowCalcFuture
def combined: Future[Int] = for {
r1 <- future1
r2 <- future2
} yield r1 + r2
The async
approach has two advantages over the use of
map
and flatMap
:
- The code more directly reflects the programmer's intent,
and does not require us to name the results
r1
andr2
. This advantage is even more pronounced when we mix control structures inasync
blocks. async
blocks are compiled to a single anonymous class, as opposed to a separate anonymous class for each closure required at each generator (<-
) in the for-comprehension. This reduces the size of generated code, and can avoid boxing of intermediate results.