package eval
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- sealed abstract class Coeval[+A] extends () => A with Serializable
Coeval
represents lazy computations that can execute synchronously.Coeval
represents lazy computations that can execute synchronously.Word definition and origin:
- Having the same age or date of origin; a contemporary; synchronous.
- From the Latin "coævus": com- ("equal") in combination with aevum (aevum, "age").
- The constructor of
Coeval
is the dual of an expression that evaluates to anA
.
There are three evaluation strategies:
- now or raiseError: for describing strict values, evaluated immediately
- evalOnce: expressions evaluated a single time
- eval: expressions evaluated every time the value is needed
The
Once
andAlways
are both lazy strategies whileNow
andError
are eager.Once
andAlways
are distinguished from each other only by memoization: once evaluatedOnce
will save the value to be returned immediately if it is needed again.Always
will run its computation every time.Both
Now
andError
are represented by the Eager trait, a sub-type of Coeval that can be used as a replacement for Scala's ownTry
type.Coeval
supports stack-safe lazy computation via the .map and .flatMap methods, which use an internal trampoline to avoid stack overflows. Computations done within.map
and.flatMap
are always lazy, even when applied to a Coeval.Eager instance (e.g. Coeval.Now, Coeval.Error).Evaluation Strategies
The "now" and "raiseError" builders are building
Coeval
instances out of strict values:val fa = Coeval.now(1) fa.value() // => 1 val fe = Coeval.raiseError(new RuntimeException("dummy")) fe.failed // => has RuntimeException
The "always" strategy is equivalent with a plain function:
// For didactic purposes, don't use shared vars at home :-) var i = 0 val coeval = Coeval.eval { i += 1; i } coeval.value() // => 1 coeval.value() // => 2 coeval.value() // => 3
The "once" strategy is equivalent with Scala's
lazy val
(along with thread-safe idempotency guarantees):var j = 0 val coevalOnce = Coeval.evalOnce { j += 1; j } coevalOnce.value() // => 1 coevalOnce.value() // => 1 coevalOnce.value() // => 1
Versus Task
The other option of suspending side-effects is Task. As a quick comparison:
Coeval
's execution is always immediate / synchronous, whereasTask
can describe asynchronous computationsCoeval
is not cancelable, obviously, since execution is immediate and there's nothing to cancel
Versus cats.Eval
The
Coeval
data type is very similar with cats.Eval. As a quick comparison:cats.Eval
is only for controlling laziness, but it doesn't handle side effects, hencecats.Eval
is aComonad
- Monix's
Coeval
can handle side effects as well and thus it implementsMonadError[Coeval, Throwable]
andcats.effect.Sync
, providing error-handling utilities
If you just want to delay the evaluation of a pure expression use
cats.Eval
, but if you need to suspend side effects or you need error handling capabilities, then useCoeval
. - trait CoevalLift[F[_]] extends ~>[Coeval, F]
A lawless type class that specifies conversions from
Coeval
to similar data types (i.e.A lawless type class that specifies conversions from
Coeval
to similar data types (i.e. pure, synchronous).This is nothing more than a cats.arrow.FunctionK.
- Annotations
- @implicitNotFound("""Cannot find implicit value for CoevalLift[${F}].""")
- trait CoevalLike[F[_]] extends ~>[F, Coeval]
A lawless type class that provides conversions to Coeval.
A lawless type class that provides conversions to Coeval.
Sample:
// Conversion from cats.Eval import cats.Eval val source0 = Eval.always(1 + 1) val task0 = CoevalLike[Eval].apply(source0) // Conversion from SyncIO import cats.effect.SyncIO val source1 = SyncIO(1 + 1) val task1 = CoevalLike[SyncIO].apply(source1)
This is an alternative to usage of
cats.effect.Effect
where the internals are specialized toCoeval
anyway, like for example the implementation ofmonix.reactive.Observable
. - trait Fiber[A] extends cats.effect.Fiber[Task, A]
Fiber
represents the (pure) result of a Task being started concurrently and that can be either joined or cancelled.Fiber
represents the (pure) result of a Task being started concurrently and that can be either joined or cancelled.You can think of fibers as being lightweight threads, a fiber being a concurrency primitive for doing cooperative multi-tasking.
For example a
Fiber
value is the result of evaluating Task.start:val task = Task.evalAsync(println("Hello!")) val forked: Task[Fiber[Unit]] = task.start
Usage example:
val launchMissiles = Task(println("Missiles launched!")) val runToBunker = Task(println("Run Lola run!")) for { fiber <- launchMissiles.start _ <- runToBunker.onErrorHandleWith { error => // Retreat failed, cancel launch (maybe we should // have retreated to our bunker before the launch?) fiber.cancel.flatMap(_ => Task.raiseError(error)) } aftermath <- fiber.join } yield { aftermath }
- sealed abstract class Task[+A] extends Serializable with BinCompat[A]
Task
represents a specification for a possibly lazy or asynchronous computation, which when executed will produce anA
as a result, along with possible side-effects.Task
represents a specification for a possibly lazy or asynchronous computation, which when executed will produce anA
as a result, along with possible side-effects.Compared with
Future
from Scala's standard library,Task
does not represent a running computation or a value detached from time, asTask
does not execute anything when working with its builders or operators and it does not submit any work into any thread-pool, the execution eventually taking place only afterrunAsync
is called and not before that.Note that
Task
is conservative in how it spawns logical threads. Transformations likemap
andflatMap
for example will default to being executed on the logical thread on which the asynchronous computation was started. But one shouldn't make assumptions about how things will end up executed, as ultimately it is the implementation's job to decide on the best execution model. All you are guaranteed is asynchronous execution after executingrunAsync
.Getting Started
To build a
Task
from a by-name parameters (thunks), we can use Task.apply ( alias Task.eval) or Task.evalAsync:val hello = Task("Hello ") val world = Task.evalAsync("World!")
Nothing gets executed yet, as
Task
is lazy, nothing executes until you trigger its evaluation via runAsync or runToFuture.To combine
Task
values we can use .map and .flatMap, which describe sequencing and this time it's in a very real sense because of the laziness involved:val sayHello = hello .flatMap(h => world.map(w => h + w)) .map(println)
This
Task
reference will trigger a side effect on evaluation, but not yet. To make the above print its message:import monix.execution.CancelableFuture import monix.execution.Scheduler.Implicits.global val f: CancelableFuture[Unit] = sayHello.runToFuture // => Hello World!
The returned type is a CancelableFuture which inherits from Scala's standard Future, a value that can be completed already or might be completed at some point in the future, once the running asynchronous process finishes. Such a future value can also be canceled, see below.
Laziness, Purity and Referential Transparency
The fact that
Task
is lazy whereasFuture
is not has real consequences. For example withTask
you can do this:import scala.concurrent.duration._ def retryOnFailure[A](times: Int, source: Task[A]): Task[A] = source.onErrorHandleWith { err => // No more retries left? Re-throw error: if (times <= 0) Task.raiseError(err) else { // Recursive call, yes we can! retryOnFailure(times - 1, source) // Adding 500 ms delay for good measure .delayExecution(500.millis) } }
Future
being a strict value-wannabe means that the actual value gets "memoized" (means cached), howeverTask
is basically a function that can be repeated for as many times as you want.Task
is a pure data structure that can be used to describe pure functions, the equivalent of Haskell'sIO
.Memoization
Task
can also do memoization, making it behave like a "lazy" ScalaFuture
, meaning that nothing is started yet, its side effects being evaluated on the firstrunAsync
and then the result reused on subsequent evaluations:Task(println("boo")).memoize
The difference between this and just calling
runAsync()
is thatmemoize()
still returns aTask
and the actual memoization happens on the firstrunAsync()
(with idempotency guarantees of course).But here's something else that the
Future
data type cannot do, memoizeOnSuccess:Task.eval { if (scala.util.Random.nextDouble() > 0.33) throw new RuntimeException("error!") println("moo") }.memoizeOnSuccess
This keeps repeating the computation for as long as the result is a failure and caches it only on success. Yes we can!
WARNING: as awesome as
memoize
can be, use with care because memoization can break referential transparency!Parallelism
Because of laziness, invoking Task.sequence will not work like it does for
Future.sequence
, the givenTask
values being evaluated one after another, in sequence, not in parallel. If you want parallelism, then you need to use Task.parSequence and thus be explicit about it.This is great because it gives you the possibility of fine tuning the execution. For example, say you want to execute things in parallel, but with a maximum limit of 30 tasks being executed in parallel. One way of doing that is to process your list in batches:
// Some array of tasks, you come up with something good :-) val list: Seq[Task[Int]] = Seq.tabulate(100)(Task(_)) // Split our list in chunks of 30 items per chunk, // this being the maximum parallelism allowed val chunks = list.sliding(30, 30).toSeq // Specify that each batch should process stuff in parallel val batchedTasks = chunks.map(chunk => Task.parSequence(chunk)) // Sequence the batches val allBatches = Task.sequence(batchedTasks) // Flatten the result, within the context of Task val all: Task[Seq[Int]] = allBatches.map(_.flatten)
Note that the built
Task
reference is just a specification at this point, or you can view it as a function, as nothing has executed yet, you need to call runAsync or runToFuture explicitly.Cancellation
The logic described by an
Task
task could be cancelable, depending on how theTask
gets built.CancelableFuture references can also be canceled, in case the described computation can be canceled. When describing
Task
tasks withTask.eval
nothing can be cancelled, since there's nothing about a plain function that you can cancel, but we can build cancelable tasks with Task.cancelable.import scala.concurrent.duration._ import scala.util._ val delayedHello = Task.cancelable0[Unit] { (scheduler, callback) => val task = scheduler.scheduleOnce(1.second) { println("Delayed Hello!") // Signaling successful completion callback(Success(())) } // Returning a cancel token that knows how to cancel the // scheduled computation: Task { println("Cancelling!") task.cancel() } }
The sample above prints a message with a delay, where the delay itself is scheduled with the injected
Scheduler
. TheScheduler
is in fact an implicit parameter torunAsync()
.This action can be cancelled, because it specifies cancellation logic. In case we have no cancelable logic to express, then it's OK if we returned a Cancelable.empty reference, in which case the resulting
Task
would not be cancelable.But the
Task
we just described is cancelable, for one at the edge, due torunAsync
returning Cancelable and CancelableFuture references:// Triggering execution val cf: CancelableFuture[Unit] = delayedHello.runToFuture // If we change our mind before the timespan has passed: cf.cancel()
But also cancellation is described on
Task
as a pure action, which can be used for example in race conditions:import scala.concurrent.duration._ import scala.concurrent.TimeoutException val ta = Task(1 + 1).delayExecution(4.seconds) val tb = Task.raiseError[Int](new TimeoutException) .delayExecution(4.seconds) Task.racePair(ta, tb).flatMap { case Left((a, fiberB)) => fiberB.cancel.map(_ => a) case Right((fiberA, b)) => fiberA.cancel.map(_ => b) }
The returned type in
racePair
is Fiber, which is a data type that's meant to wrap tasks linked to an active process and that can be canceled or joined.Also, given a task, we can specify actions that need to be triggered in case of cancellation, see doOnCancel:
val task = Task.eval(println("Hello!")).executeAsync task doOnCancel Task.eval { println("A cancellation attempt was made!") }
Given a task, we can also create a new task from it that atomic (non cancelable), in the sense that either all of it executes or nothing at all, via uncancelable.
Note on the ExecutionModel
Task
is conservative in how it introduces async boundaries. Transformations likemap
andflatMap
for example will default to being executed on the current call stack on which the asynchronous computation was started. But one shouldn't make assumptions about how things will end up executed, as ultimately it is the implementation's job to decide on the best execution model. All you are guaranteed (and can assume) is asynchronous execution after executingrunAsync
.Currently the default ExecutionModel specifies batched execution by default and
Task
in its evaluation respects the injectedExecutionModel
. If you want a different behavior, you need to execute theTask
reference with a different scheduler. - trait TaskApp extends AnyRef
Safe
App
type that executes a Task.Safe
App
type that executes a Task. Shutdown occurs after theTask
completes, as follows:- If completed with
ExitCode.Success
, the main method exits and shutdown is handled by the platform.- If completed with any other
ExitCode
,sys.exit
is called with the specified code.- If the
Task
raises an error, the stack trace is printed to standard error andsys.exit(1)
is called.When a shutdown is requested via a signal, the
Task
is canceled and we wait for theIO
to release any resources. The process exits with the numeric value of the signal plus 128.import cats.effect._ import cats.implicits._ import monix.eval._ object MyApp extends TaskApp { def run(args: List[String]): Task[ExitCode] = args.headOption match { case Some(name) => Task(println(s"Hello, \${name}.")).as(ExitCode.Success) case None => Task(System.err.println("Usage: MyApp name")).as(ExitCode(2)) } }
N.B. this is homologous with cats.effect.IOApp, but meant for usage with Task.
Works on top of JavaScript as well ;-)
- trait TaskLift[F[_]] extends ~>[Task, F]
A lawless type class that specifies conversions from
Task
to similar data types (i.e.A lawless type class that specifies conversions from
Task
to similar data types (i.e. pure, asynchronous, preferably cancelable).- Annotations
- @implicitNotFound("""Cannot find implicit value for TaskLift[${F}].
Building this implicit value might depend on having an implicit
s.c.ExecutionContext in scope, a Scheduler or some equivalent type.""")
- trait TaskLike[F[_]] extends ~>[F, Task]
A lawless type class that provides conversions to Task.
A lawless type class that provides conversions to Task.
Sample:
// Conversion from cats.Eval import cats.Eval val source0 = Eval.always(1 + 1) val task0 = TaskLike[Eval].apply(source0) // Conversion from Future import scala.concurrent.Future val source1 = Future.successful(1 + 1) val task1 = TaskLike[Future].apply(source1) // Conversion from IO import cats.effect.IO val source2 = IO(1 + 1) val task2 = TaskLike[IO].apply(source2)
This is an alternative to usage of
cats.effect.Effect
where the internals are specialized toTask
anyway, like for example the implementation ofmonix.reactive.Observable
.- Annotations
- @implicitNotFound("""Cannot find implicit value for TaskLike[${F}].
Building this implicit value might depend on having an implicit
s.c.ExecutionContext in scope, a Scheduler or some equivalent type.""")
- final class TaskLocal[A] extends AnyRef
A
TaskLocal
is like a ThreadLocal that is pure and with a flexible scope, being processed in the context of the Task data type.A
TaskLocal
is like a ThreadLocal that is pure and with a flexible scope, being processed in the context of the Task data type.This data type wraps monix.execution.misc.Local.
Just like a
ThreadLocal
, usage of aTaskLocal
is safe, the state of all current locals being transported over async boundaries (aka when threads get forked) by theTask
run-loop implementation, but only when theTask
reference gets executed with Task.Options.localContextPropagation set totrue
.One way to achieve this is with Task.executeWithOptions, a single call is sufficient just before
runAsync
:import monix.execution.Scheduler.Implicits.global val t = Task(42) t.executeWithOptions(_.enableLocalContextPropagation) // triggers the actual execution .runToFuture
Another possibility is to use Task.runToFutureOpt or Task.runToFutureOpt instead of
runAsync
and specify the set of options implicitly:{ implicit val options = Task.defaultOptions.enableLocalContextPropagation // Options passed implicitly val f = t.runToFutureOpt }
Full example:
import monix.eval.{Task, TaskLocal} val task: Task[Unit] = for { local <- TaskLocal(0) value1 <- local.read // value1 == 0 _ <- local.write(100) value2 <- local.read // value2 == 100 value3 <- local.bind(200)(local.read.map(_ * 2)) // value3 == 200 * 2 value4 <- local.read // value4 == 100 _ <- local.clear value5 <- local.read // value5 == 0 } yield { // Should print 0, 100, 400, 100, 0 println("value1: " + value1) println("value2: " + value2) println("value3: " + value3) println("value4: " + value4) println("value5: " + value5) } // For transporting locals over async boundaries defined by // Task, any Scheduler will do, however for transporting locals // over async boundaries managed by Future and others, you need // a `TracingScheduler` here: import monix.execution.Scheduler.Implicits.global // Needs enabling the "localContextPropagation" option // just before execution implicit val opts = Task.defaultOptions.enableLocalContextPropagation // Triggering actual execution val result = task.runToFutureOpt
Deprecated Type Members
- type MVar[A] = catnap.MVar[Task, A]
DEPRECATED — moved and made generic in monix.catnap.CircuitBreaker.
DEPRECATED — moved and made generic in monix.catnap.CircuitBreaker.
Please switch to that, because the deprecated symbols will be removed.
- Annotations
- @deprecated
- Deprecated
(Since version 3.0.0) Moved and made generic in monix.catnap.MVar
- type TaskCircuitBreaker = CircuitBreaker[Task]
DEPRECATED — moved and made generic in monix.catnap.CircuitBreaker.
DEPRECATED — moved and made generic in monix.catnap.CircuitBreaker.
Please switch to that, because the deprecated symbols will be removed.
- Annotations
- @deprecated
- Deprecated
(Since version 3.0.0) Moved and made generic in monix.catnap.CircuitBreaker
- type TaskSemaphore = Semaphore[Task]
DEPRECATED — moved and made generic in monix.catnap.Semaphore.
DEPRECATED — moved and made generic in monix.catnap.Semaphore.
Please switch to that, because the deprecated symbols will be removed.
- Annotations
- @deprecated
- Deprecated
(Since version 3.0.0) Moved and made generic in monix.catnap.Semaphore
Value Members
- object Coeval extends CoevalInstancesLevel0 with Serializable
Coeval builders.
- object CoevalLift extends CoevalLiftImplicits0 with Serializable
- object CoevalLike extends Serializable
- object Fiber
- object Task extends TaskInstancesLevel1 with Serializable
Builders for Task.
- object TaskLift extends TaskLiftImplicits0 with Serializable
- object TaskLike extends TaskLikeImplicits0 with Serializable
- object TaskLocal
Builders for TaskLocal
Deprecated Value Members
- object MVar
DEPRECATED — moved and made generic in monix.catnap.CircuitBreaker.
DEPRECATED — moved and made generic in monix.catnap.CircuitBreaker.
Please switch to that, because the deprecated symbols will be removed.
- Annotations
- @deprecated
- Deprecated
(Since version 3.0.0) Moved and made generic in monix.catnap.MVar
- object TaskCircuitBreaker
DEPRECATED — moved and made generic in monix.catnap.CircuitBreaker.
DEPRECATED — moved and made generic in monix.catnap.CircuitBreaker.
Please switch to that, because the deprecated symbols will be removed.
- Annotations
- @deprecated
- Deprecated
(Since version 3.0.0) Moved and made generic in monix.catnap.CircuitBreaker
- object TaskSemaphore
DEPRECATED — moved and made generic in monix.catnap.Semaphore.
DEPRECATED — moved and made generic in monix.catnap.Semaphore.
Please switch to that, because the deprecated symbols will be removed.
- Annotations
- @deprecated
- Deprecated
(Since version 3.0.0) Moved and made generic in monix.catnap.Semaphore
This is the API documentation for the Monix library.
Package Overview
monix.execution exposes lower level primitives for dealing with asynchronous execution:
Atomic
types, as alternative tojava.util.concurrent.atomic
monix.catnap exposes pure abstractions built on top of the Cats-Effect type classes:
monix.eval is for dealing with evaluation of results, thus exposing Task and Coeval.
monix.reactive exposes the
Observable
pattern:Observable
implementationsmonix.tail exposes Iterant for purely functional pull based streaming:
Batch
andBatchCursor
, the alternatives to Scala'sIterable
andIterator
respectively that we are using within Iterant's encodingYou can control evaluation with type you choose - be it Task, Coeval, cats.effect.IO or your own as long as you provide correct cats-effect or cats typeclass instance.