I do not understand why Scala's Future is harder to use and has less functionality than Twitters, while the first has been created after the second. So, here are questions about scala.concurrent.Future:
Why does Future.onComplete return Unit instead of Future? Composable methods are much more convenient.
Why does Scala's Future not support cancellation?
Future.onComplete returns a unit, so the invocations cannot be chained. According to the scala docs, "note that this design is intentional, to avoid suggesting that chained invocations may imply an ordering on the execution of the registered callbacks (callbacks registered on the same future are unordered)."
To compose the future, use combinators like flatMap, andThen, and filter, which all return a Future.
Check out http://docs.scala-lang.org/overviews/core/futures.html#functional-composition-and-for-comprehensions for more details
I think cancellation is quite nuanced. See this discussion for more details: How to cancel Future in Scala?
Related
I am trying to get my head around Scala's promise and future constructs.
I've been reading Futures and Promises in Scala Documentation and am a bit confused as I've got a feeling that the concepts of promises and futures are mixed up.
In my understanding a promise is a container that we could populate
value in a later point. And future is some sort of an asynchronous
operation that would complete in a different execution path.
In Scala we can obtain a result using the attached callbacks to future.
Where I'm lost is how promise has a future?
I have read about these concepts in Clojure too, assuming that promise and future have some generic common concept, but it seems like I was wrong.
A promise p completes the future returned by p.future. This future is
specific to the promise p. Depending on the implementation, it may be
the case that p.future eq p.
val p = promise[T]
val f = p.future
You can think of futures and promises as two different sides of a pipe.
On the promise side, data is pushed in, and on the future side, data can be pulled out.
And future is some sort of an asynchronous operation that would complete in a different execution path.
Actually, a future is a placeholder object for a value that may be become available at some point in time, asynchronously. It is not the asynchronous computation itself.
The fact that there is a future constructor called future that returns such a placeholder object and spawns an asynchronous computation that completes this placeholder object does not mean that the asynchronous computation is called a future. There are also other future constructors/factory methods.
But the point I do not get is how promise has a future?
To divide promises and futures into 2 separate interfaces was a design decision. You could have these two under the same interface Future, but that would then allow clients of futures to complete them instead of the intended completer of the future. This would cause unexpected errors, as there could be any number of contending completers.
E.g. for the asynchronous computation spawned by the future construct, it would no longer be clear whether it has to complete the promise, or if the client will do it.
Futures and promises are intended to constrain the flow of data in the program.
The idea is to have a future client that subscribes to the data to act on it once the data arrives.
The role of the promise client is to provide that data.
Mixing these two roles can lead to programs that are harder to understand or reason about.
You might also ask why the Promise trait does not extend Future. This is another design decision to discourage programmers from blindly passing Promises to clients where they should upcast the Promise to Future (this upcast is prone to be left out, whereas having to explicitly call future on the promise ensures you call it every time). In other words, by returning a promise you are giving the right to complete it to somebody else, and by returning the future you are giving the right to subscribe to it.
EDIT:
If you would like to learn more about futures, Chapter 4 in the Learning Concurrent Programming in Scala book describes them in detail. Disclaimer: I'm the author of the book.
The difference between the two is that futures are usually centered around the computation while promises are centered around data.
It seems your understanding matches this, but let me explain what I mean:
In both scala and clojure futures are (unless returned by some other function/method) created with some computation:
// scala
future { do_something() }
;; clojure
(future (do-something))
In both cases the "return-value" of the future can only be read (without blocking) only after the computation has terminated. When this is the case is typically outside the control of the programmer, as the computation gets executed in some thread (pool) in the background.
In contrast in both cases promises are an initially empty container, which can later be filled (exactly once):
// scala
val p = promise[Int]
...
p success 10 // or failure Exception()
;; clojure
(def p (promise))
(deliver p 10)
Once this is the case it can be read.
Reading the futures and promises is done through deref in clojure (and realized? can be used to check if deref will block). In scala reading is done through the methods provided by the Future trait. In order to read the result of a promise we thus have to obtain an object implementing Future, this is done by p.future. Now if the trait Future is implemented by a Promise, then p.future can return this and the two are equal. This is purely a implementation choice and does not change the concepts. So you were not wrong!
In any case Futures are mostly dealt with using callbacks.
At this point it might be worthwhile to reconsider the initial characterization of the two concepts:
Futures represent a computation that will produce a result at some point. Let's look at one possible implementation: We run the code in some thread(pool) and once its done, we arrange use the return value to fulfill a promise. So reading the result of the future is reading a promise; This is clojure's way of thinking (not necessarily of implementation).
On the other hand a promise represents a value that will be filled at some point. When it gets filled this means that some computation produced a result. So in a way this is like a future completing, so we should consume the value in the same way, using callbacks; This is scala's way of thinking.
Note that under the hood Future is implemented in terms of Promise and this Promise is completed with the body you passed to your Future:
def apply[T](body: =>T): Future[T] = impl.Future(body) //here I have omitted the implicit ExecutorContext
impl.Future is an implementation of Future trait:
def apply[T](body: =>T)(implicit executor: ExecutionContext): scala.concurrent.Future[T] =
{
val runnable = new PromiseCompletingRunnable(body)
executor.prepare.execute(runnable)
runnable.promise.future
}
Where PromiseCompletingRunnable looks like this:
class PromiseCompletingRunnable[T](body: => T) extends Runnable {
val promise = new Promise.DefaultPromise[T]()
override def run() = {
promise complete {
try Success(body) catch { case NonFatal(e) => Failure(e) }
}
} }
So you see even though they are seperate concepts that you can make use of independently in reality you can't get Future without using Promise.
I'm working on a scala code where a 3rd party library returns a Future[Boolean] object while I need to consume this future object in my scala code which is fully written in a synchronous manner.
Currently, I'm doing Await.result on 3rd party lib operation to ensure it returns just boolean. Is there a better way to handle this, my scala code needs a boolean value for further operation?
As Luis noted in the comments, in general there's no alternative to Awaiting on the Future.
That said, you may have some choice about where to Await.
For instance, if you have code like
val result = Await.result(someFuture, Duration.Inf)
f(result)
It may be more useful to run f in Future land with
Await.result(someFuture.map(f), Duration.Inf)
If f happens to block, then it may be worth either wrapping f in blocking or explicitly using an ExecutionContext which will handle a lot of its threads being blocked (e.g. one that can have more threads than cores) for the map.
In general, you'll want to move Awaits to the outermost edge of your code as you can, even shifting edges if you can.
I have been struggling into understanding of monad.
And, I concluded monad is box of values in which operates some specific task.
so, Can I say Future and Promise are also kind of monad?
Not sure about Promise but Future is considered monadic.
https://www.precog.com/blog/Precog-Copointed-The-Abstract-Future/
I'm trying to understand the idea and purpose behind scalaz concurrent package, primarily Future and Task classes, but when using them in some application, it's now far from simple sequential analog, whereas scala.concurrent.Future, works more then better. Can any one share with his experience on writing concurrent/asynchronous application with scalaz, basically how to use it's async method correctly? As i understand from the sources async doesn't use a separate thread like the call to standard future, or fork/apply methods from scalaz works, so why it is called async then? Does it mean that in order to get real concurrency with scalaz i always have to call fork(now(...)) or apply?
I'm not a scalaz expert, but I'll try to help you a little bit. Let me try answer your questions one by one:
1) Can any one share with his experience on writing concurrent/asynchronous application with scalaz, basically how to use it's async method correctly?
Let's first take a look at async signature:
def async[A](listen: (A => Unit) => Unit): Future[A]
This could be a bit cryptic at first, so as always it's good idea to look at tests to understands possible use cases. In https://github.com/scalaz/scalaz/blob/scalaz-seven/tests/src/test/scala/scalaz/concurrent/FutureTest.scala
you can find the following code:
"when constructed from Future.async" ! prop{(n: Int) =>
def callback(call: Int => Unit): Unit = call(n)
Future.async(callback).run must_==
}
As we know from signature Future.async just construct new Future using function of signature (A => Unit) => Unit. What this really means is that Future.async takes as parameter function which for given callback makes all required computations and pass the result to that callback.
What is important to note it that Future.async does not run any computations on itself, it only prepare structure to run them later.
2) As i understand from the sources async doesn't use a separate thread like the call to standard future, or fork/apply methods from scalaz works, so why it is called async then?
You are correct. Only fork and apply seems to be running anything using threads, which is easy to notice looking at the signatures which contains implicit pool: ExecutorService. I cannot speak for the authors here, but I guess async is related to the callback. It means that rather than blocking on Future to get it result at the end you will use asynchronous callback.
3) Does it mean that in order to get real concurrency with scalaz i always have to call fork(now(...)) or apply?
From what I can say, yes. Just notice that when you are creating Future using syntax Future(x) you are using apply method here, so this is kind of default behavior (which is fine).
If you want to better understand design of Scalaz Futures I can recommend you reading "Functional Programming in Scala". I believe this book is written by main Scalaz contributors and chapter 7 discusses designing API for purely functional parallelism library. It's not exactly the same as Scalaz Future, but you can see many similarities.
You can also read wonderful Timothy Perrett blog post about Scalaz Task and Future which covers many not so obvious details.
async is used to adapt an async, callback-based API as a Future. It's called async because it's expected that it will be used with something that runs asynchronously, perhaps calling the callback from another thread somewhere further down the line. This is "real" concurrency, provided the API you're calling really uses it asynchronously (e.g. I use Future.async with the async parts of the AWS SDK like AmazonSimpleDBAsyncClient).
If you want "real" concurrency from the scalaz Task API directly you need to use things like fork or gatherUnordered, as many of the APIs default towards being safe/deterministic and restartable, with concurrency only when explicitly requested.
When composing Tasks with map and flatMap you can get a performance win by not using fork, see:
http://blog.higher-order.com/blog/2015/06/18/easy-performance-wins-with-scalaz/
I am trying to get my head around Scala's promise and future constructs.
I've been reading Futures and Promises in Scala Documentation and am a bit confused as I've got a feeling that the concepts of promises and futures are mixed up.
In my understanding a promise is a container that we could populate
value in a later point. And future is some sort of an asynchronous
operation that would complete in a different execution path.
In Scala we can obtain a result using the attached callbacks to future.
Where I'm lost is how promise has a future?
I have read about these concepts in Clojure too, assuming that promise and future have some generic common concept, but it seems like I was wrong.
A promise p completes the future returned by p.future. This future is
specific to the promise p. Depending on the implementation, it may be
the case that p.future eq p.
val p = promise[T]
val f = p.future
You can think of futures and promises as two different sides of a pipe.
On the promise side, data is pushed in, and on the future side, data can be pulled out.
And future is some sort of an asynchronous operation that would complete in a different execution path.
Actually, a future is a placeholder object for a value that may be become available at some point in time, asynchronously. It is not the asynchronous computation itself.
The fact that there is a future constructor called future that returns such a placeholder object and spawns an asynchronous computation that completes this placeholder object does not mean that the asynchronous computation is called a future. There are also other future constructors/factory methods.
But the point I do not get is how promise has a future?
To divide promises and futures into 2 separate interfaces was a design decision. You could have these two under the same interface Future, but that would then allow clients of futures to complete them instead of the intended completer of the future. This would cause unexpected errors, as there could be any number of contending completers.
E.g. for the asynchronous computation spawned by the future construct, it would no longer be clear whether it has to complete the promise, or if the client will do it.
Futures and promises are intended to constrain the flow of data in the program.
The idea is to have a future client that subscribes to the data to act on it once the data arrives.
The role of the promise client is to provide that data.
Mixing these two roles can lead to programs that are harder to understand or reason about.
You might also ask why the Promise trait does not extend Future. This is another design decision to discourage programmers from blindly passing Promises to clients where they should upcast the Promise to Future (this upcast is prone to be left out, whereas having to explicitly call future on the promise ensures you call it every time). In other words, by returning a promise you are giving the right to complete it to somebody else, and by returning the future you are giving the right to subscribe to it.
EDIT:
If you would like to learn more about futures, Chapter 4 in the Learning Concurrent Programming in Scala book describes them in detail. Disclaimer: I'm the author of the book.
The difference between the two is that futures are usually centered around the computation while promises are centered around data.
It seems your understanding matches this, but let me explain what I mean:
In both scala and clojure futures are (unless returned by some other function/method) created with some computation:
// scala
future { do_something() }
;; clojure
(future (do-something))
In both cases the "return-value" of the future can only be read (without blocking) only after the computation has terminated. When this is the case is typically outside the control of the programmer, as the computation gets executed in some thread (pool) in the background.
In contrast in both cases promises are an initially empty container, which can later be filled (exactly once):
// scala
val p = promise[Int]
...
p success 10 // or failure Exception()
;; clojure
(def p (promise))
(deliver p 10)
Once this is the case it can be read.
Reading the futures and promises is done through deref in clojure (and realized? can be used to check if deref will block). In scala reading is done through the methods provided by the Future trait. In order to read the result of a promise we thus have to obtain an object implementing Future, this is done by p.future. Now if the trait Future is implemented by a Promise, then p.future can return this and the two are equal. This is purely a implementation choice and does not change the concepts. So you were not wrong!
In any case Futures are mostly dealt with using callbacks.
At this point it might be worthwhile to reconsider the initial characterization of the two concepts:
Futures represent a computation that will produce a result at some point. Let's look at one possible implementation: We run the code in some thread(pool) and once its done, we arrange use the return value to fulfill a promise. So reading the result of the future is reading a promise; This is clojure's way of thinking (not necessarily of implementation).
On the other hand a promise represents a value that will be filled at some point. When it gets filled this means that some computation produced a result. So in a way this is like a future completing, so we should consume the value in the same way, using callbacks; This is scala's way of thinking.
Note that under the hood Future is implemented in terms of Promise and this Promise is completed with the body you passed to your Future:
def apply[T](body: =>T): Future[T] = impl.Future(body) //here I have omitted the implicit ExecutorContext
impl.Future is an implementation of Future trait:
def apply[T](body: =>T)(implicit executor: ExecutionContext): scala.concurrent.Future[T] =
{
val runnable = new PromiseCompletingRunnable(body)
executor.prepare.execute(runnable)
runnable.promise.future
}
Where PromiseCompletingRunnable looks like this:
class PromiseCompletingRunnable[T](body: => T) extends Runnable {
val promise = new Promise.DefaultPromise[T]()
override def run() = {
promise complete {
try Success(body) catch { case NonFatal(e) => Failure(e) }
}
} }
So you see even though they are seperate concepts that you can make use of independently in reality you can't get Future without using Promise.