package concurrent
Classes, traits, and objects related to testing asynchronous and multi-threaded behavior.
This package is released as part of the scalatest-core
module.
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- trait AbstractPatienceConfiguration extends ScaledTimeSpans
Trait that defines an abstract
patienceConfig
method that is implemented inPatienceConfiguration
and can be overriden in stackable modification traits such asIntegrationPatience
.Trait that defines an abstract
patienceConfig
method that is implemented inPatienceConfiguration
and can be overriden in stackable modification traits such asIntegrationPatience
.The main purpose of
AbstractPatienceConfiguration
is to differentiate corePatienceConfiguration
traits, such asEventually
andWaiters
, from stackable modification traits forPatienceConfiguration
s such asIntegrationPatience
. Because these stackable traits extendAbstractPatienceConfiguration
instead ofSuite
, you can't simply mix in a stackable trait:class ExampleSpec extends FunSpec with IntegrationPatience // Won't compile
The previous code is undesirable because
IntegrationPatience
would have no affect on the class. Instead, you need to mix in a corePatienceConfiguration
trait and mix the stackableIntegrationPatience
trait into that, like this:class ExampleSpec extends FunSpec with Eventually with IntegrationPatience // Compiles fine
The previous code is better because
IntegrationPatience
does have an effect: it modifies the behavior ofEventually
. - trait AsyncCancelAfterFailure extends AsyncTestSuiteMixin
Trait that when mixed into a
AsyncTestSuite
cancels any remaining tests in thatAsyncTestSuite
instance after a test fails.Trait that when mixed into a
AsyncTestSuite
cancels any remaining tests in thatAsyncTestSuite
instance after a test fails.The intended use case for this trait is if you have a suite of long-running tests that are related such that if one fails, you aren't interested in running the others, you can use this trait to simply cancel any remaining tests, so you need not wait long for them to complete.
- trait AsyncTimeLimitedTests extends AsyncTestSuiteMixin with TimeLimits
Trait that when mixed into an asynchronous suite class establishes a time limit for its tests.
Trait that when mixed into an asynchronous suite class establishes a time limit for its tests.
This trait overrides
withFixture
, wrapping asuper.withFixture(test)
call in afailAfter
invocation, specifying a timeout obtained by invokingtimeLimit
:failAfter(timeLimit) { super.withFixture(test) }
Note that the
failAfter
method executes the body of the by-name passed to it using the same thread that invokedfailAfter
. This means that the calling ofwithFixture
method will be run using the same thread, but the test body may be run using a different thread, depending on theexecutionContext
set at theAsyncTestSuite
level.The
timeLimit
field is abstract in this trait. Thus you must specify a time limit when you use it. For example, the following code specifies that each test must complete within 200 milliseconds:import org.scalatest.AsyncFunSpec import org.scalatest.concurrent.AsyncTimeLimitedTests import org.scalatest.time.SpanSugar._
class ExampleSpec extends AsyncFunSpec with AsyncTimeLimitedTests {
// Note: You may need to either write 200.millis or (200 millis), or // place a semicolon or blank line after plain old 200 millis, to // avoid the semicolon inference problems of postfix operator notation. val timeLimit = 200 millis
describe("An asynchronous time-limited test") { it("should succeed if it completes within the time limit") { Thread.sleep(100) succeed } it("should fail if it is taking too darn long") { Thread.sleep(300) succeed } } }If you run the above
ExampleSpec
, the second test will fail with the error message:The test did not complete within the specified 200 millisecond time limit.
Different from
TimeLimitedTests
,AsyncTimeLimitedTests
does not supportInterruptor
for now. - trait ConductorFixture extends TestSuiteMixin with Conductors
Trait that can pass a new
Conductor
fixture into tests.Trait that can pass a new
Conductor
fixture into tests.Here's an example of the use of this trait to test the
ArrayBlockingQueue
class fromjava.util.concurrent
:import org.scalatest.funsuite import org.scalatest.concurrent.ConductorFixture import org.scalatest.matchers.Matchers import java.util.concurrent.ArrayBlockingQueue
class ArrayBlockingQueueSuite extends FixtureFunSuite with ConductorFixture with Matchers {
test("calling put on a full queue blocks the producer thread") { conductor => import conductor._
val buf = new ArrayBlockingQueue[Int](1)
thread("producer") { buf put 42 buf put 17 beat should be (1) }
thread("consumer") { waitForBeat(1) buf.take should be (42) buf.take should be (17) }
whenFinished { buf should be ('empty) } }
test("calling take on an empty queue blocks the consumer thread") { conductor => import conductor._
val buf = new ArrayBlockingQueue[Int](1)
thread("producer") { waitForBeat(1) buf put 42 buf put 17 }
thread("consumer") { buf.take should be (42) buf.take should be (17) beat should be (1) }
whenFinished { buf should be ('empty) } } }For an explanation of how these tests work, see the documentation for
Conductors
. - trait ConductorMethods extends TestSuiteMixin with Conductors
Trait that provides each test with access to a new
Conductor
via methods.Trait that provides each test with access to a new
Conductor
via methods.Here's an example of the use of this trait to test the
ArrayBlockingQueue
concurrency abstraction fromjava.util.concurrent
:import org.scalatest.FunSuite import org.scalatest.concurrent.ConductorMethods import org.scalatest.matchers.Matchers import java.util.concurrent.ArrayBlockingQueue
class ArrayBlockingQueueSuite extends FunSuite with ConductorMethods with Matchers {
test("calling put on a full queue blocks the producer thread") {
val buf = new ArrayBlockingQueue[Int](1)
thread("producer") { buf put 42 buf put 17 beat should be (1) }
thread("consumer") { waitForBeat(1) buf.take should be (42) buf.take should be (17) }
whenFinished { buf should be ('empty) } }
test("calling take on an empty queue blocks the consumer thread") {
val buf = new ArrayBlockingQueue[Int](1)
thread("producer") { waitForBeat(1) buf put 42 buf put 17 }
thread("consumer") { buf.take should be (42) buf.take should be (17) beat should be (1) }
whenFinished { buf should be ('empty) } } }For an explanation of how these tests work, see the documentation for
Conductors
. - trait Conductors extends PatienceConfiguration
Trait whose
Conductor
member facilitates the testing of classes, traits, and libraries designed to be used by multiple threads concurrently.Trait whose
Conductor
member facilitates the testing of classes, traits, and libraries designed to be used by multiple threads concurrently.A
Conductor
conducts a multi-threaded scenario by maintaining a clock of "beats." Beats are numbered starting with 0. You can ask aConductor
to run threads that interact with the class, trait, or library (the subject) you want to test. A thread can call theConductor
'swaitForBeat
method, which will cause the thread to block until that beat has been reached. TheConductor
will advance the beat only when all threads participating in the test are blocked. By tying the timing of thread activities to specific beats, you can write tests for concurrent systems that have deterministic interleavings of threads.A
Conductor
object has a three-phase lifecycle. It begins its life in the setup phase. During this phase, you can start threads by invoking thethread
method on theConductor
. Whenconduct
is invoked on aConductor
, it enters the conducting phase. During this phase it conducts the one multi-threaded scenario it was designed to conduct. After all participating threads have exited, either by returning normally or throwing an exception, theconduct
method will complete, either by returning normally or throwing an exception. As soon as theconduct
method completes, theConductor
enters its defunct phase. Once theConductor
has conducted a multi-threaded scenario, it is defunct and can't be reused. To run the same test again, you'll need to create a new instance ofConductor
.Here's an example of the use of
Conductor
to test theArrayBlockingQueue
class fromjava.util.concurrent
:import org.scalatest.fixture.FunSuite import org.scalatest.matchers.Matchers import java.util.concurrent.ArrayBlockingQueue import org.scalatest.concurrent.Conductors
class ArrayBlockingQueueSuite extends FunSuite with Matchers with Conductors {
test("calling put on a full queue blocks the producer thread") {
val conductor = new Conductor import conductor._
val buf = new ArrayBlockingQueue[Int](1)
thread("producer") { buf put 42 buf put 17 beat should be (1) }
thread("consumer") { waitForBeat(1) buf.take should be (42) buf.take should be (17) }
whenFinished { buf should be ('empty) } } }When the test shown is run, it will create one thread named producer and another named consumer. The producer thread will eventually execute the code passed as a by-name parameter to
thread("producer")
:buf put 42 buf put 17 beat should be (1)
Similarly, the consumer thread will eventually execute the code passed as a by-name parameter to
thread("consumer")
:waitForBeat(1) buf.take should be (42) buf.take should be (17)
The
thread
creates the threads and starts them, but they will not immediately execute the by-name parameter passed to them. They will first block, waiting for theConductor
to give them a green light to proceed.The next call in the test is
whenFinished
. This method will first callconduct
on theConductor
, which will wait until all threads that were created (in this case, producer and consumer) are at the "starting line", i.e., they have all started and are blocked, waiting on the green light. Theconduct
method will then give these threads the green light and they will all start executing their blocks concurrently.When the threads are given the green light, the beat is 0. The first thing the producer thread does is put 42 in into the queue. As the queue is empty at this point, this succeeds. The producer thread next attempts to put a 17 into the queue, but because the queue has size 1, this can't succeed until the consumer thread has read the 42 from the queue. This hasn't happened yet, so producer blocks. Meanwhile, the consumer thread's first act is to call
waitForBeat(1)
. Because the beat starts out at 0, this call will block the consumer thread. As a result, once the producer thread has executedbuf put 17
and the consumer thread has executedwaitForBeat(1)
, both threads will be blocked.The
Conductor
maintains a clock that wakes up periodically and checks to see if all threads participating in the multi-threaded scenario (in this case, producer and consumer) are blocked. If so, it increments the beat. Thus sometime later the beat will be incremented, from 0 to 1. Because consumer was waiting for beat 1, it will wake up (i.e., thewaitForBeat(1)
call will return) and execute the next line of code in its block,buf.take should be (42)
. This will succeed, because the producer thread had previously (during beat 0) put 42 into the queue. This act will also make producer runnable again, because it was blocked on the secondput
, which was waiting for another thread to read that 42.Now both threads are unblocked and able to execute their next statement. The order is non-deterministic, and can even be simultaneous if running on multiple cores. If the
consumer
thread happens to executebuf.take should be (17)
first, it will block (buf.take
will not return), because the queue is at that point empty. At some point later, the producer thread will executebuf put 17
, which will unblock the consumer thread. Again both threads will be runnable and the order non-deterministic and possibly simulataneous. The producer thread may charge ahead and run its next statement,beat should be (1)
. This will succeed because the beat is indeed 1 at this point. As this is the last statement in the producer's block, the producer thread will exit normally (it won't throw an exception). At some point later the consumer thread will be allowed to complete its last statement, thebuf.take
call will return 17. The consumer thread will execute17 should be (17)
. This will succeed and as this was the last statement in its block, the consumer will return normally.If either the producer or consumer thread had completed abruptbly with an exception, the
conduct
method (which was called bywhenFinished
) would have completed abruptly with an exception to indicate the test failed. However, since both threads returned normally,conduct
will return. Becauseconduct
doesn't throw an exception,whenFinished
will execute the block of code passed as a by-name parameter to it:buf should be ('empty)
. This will succeed, because the queue is indeed empty at this point. ThewhenFinished
method will then return, and because thewhenFinished
call was the last statement in the test and it didn't throw an exception, the test completes successfully.This test tests
ArrayBlockingQueue
, to make sure it works as expected. If there were a bug inArrayBlockingQueue
such as aput
called on a full queue didn't block, but instead overwrote the previous value, this test would detect it. However, if there were a bug inArrayBlockingQueue
such that a call totake
called on an empty queue never blocked and always returned 0, this test might not detect it. The reason is that whether the consumer thread will ever calltake
on an empty queue during this test is non-deterministic. It depends on how the threads get scheduled during beat 1. What is deterministic in this test, because the consumer thread blocks during beat 0, is that the producer thread will definitely attempt to write to a full queue. To make sure the other scenario is tested, you'd need a different test:test("calling take on an empty queue blocks the consumer thread") {
val conductor = new Conductor import conductor._
val buf = new ArrayBlockingQueue[Int](1)
thread("producer") { waitForBeat(1) buf put 42 buf put 17 }
thread("consumer") { buf.take should be (42) buf.take should be (17) beat should be (1) }
whenFinished { buf should be ('empty) } }In this test, the producer thread will block, waiting for beat 1. The consumer thread will invoke
buf.take
as its first act. This will block, because the queue is empty. Because both threads are blocked, theConductor
will at some point later increment the beat to 1. This will awaken the producer thread. It will return from itswaitForBeat(1)
call and executebuf put 42
. This will unblock the consumer thread, which will take the 42, and so on.The problem that
Conductor
is designed to address is the difficulty, caused by the non-deterministic nature of thread scheduling, of testing classes, traits, and libraries that are intended to be used by multiple threads. If you just create a test in which one thread reads from anArrayBlockingQueue
and another writes to it, you can't be sure that you have tested all possible interleavings of threads, no matter how many times you run the test. The purpose ofConductor
is to enable you to write tests with deterministic interleavings of threads. If you write one test for each possible interleaving of threads, then you can be sure you have all the scenarios tested. The two tests shown here, for example, ensure that both the scenario in which a producer thread tries to write to a full queue and the scenario in which a consumer thread tries to take from an empty queue are tested.Class
Conductor
was inspired by the MultithreadedTC project, created by Bill Pugh and Nat Ayewah of the University of Maryland.Although useful, bear in mind that a
Conductor
's results are not guaranteed to be accurate 100% of the time. The reason is that it usesjava.lang.Thread
'sgetState
method to decide when to advance the beat. This use goes against the advice given in the Javadoc documentation forgetState
, which says, "This method is designed for use in monitoring of the system state, not for synchronization." In short, sometimes the return value ofgetState
occasionally may be inacurrate, which in turn means that sometimes aConductor
could decide to advance the beat too early. In practice,Conductor
has proven to be very helpful when developing thread safe classes. It is also useful in for regression tests, but you may have to tolerate occasional false negatives. - trait Eventually extends PatienceConfiguration
Trait that provides the
eventually
construct, which periodically retries executing a passed by-name parameter, until it either succeeds or the configured timeout has been surpassed.Trait that provides the
eventually
construct, which periodically retries executing a passed by-name parameter, until it either succeeds or the configured timeout has been surpassed.The by-name parameter "succeeds" if it returns a result. It "fails" if it throws any exception that would normally cause a test to fail. (These are any exceptions except
TestPendingException
andError
s listed in the Treatment ofjava.lang.Error
s section of the documentation of traitSuite
.)For example, the following invocation of
eventually
would succeed (not throw an exception):val xs = 1 to 125 val it = xs.iterator eventually { it.next should be (3) }
However, because the default timeout is 150 milliseconds, the following invocation of
eventually
would ultimately produce aTestFailedDueToTimeoutException
:val xs = 1 to 125 val it = xs.iterator eventually { Thread.sleep(50); it.next should be (110) }
Assuming the default configuration parameters, a
timeout
of 150 milliseconds and aninterval
of 15 milliseconds, were passed implicitly toeventually
, the detail message of the thrownTestFailedDueToTimeoutException
would look like:The code passed to eventually never returned normally. Attempted 2 times over 166.682 milliseconds. Last failure message: 2 was not equal to 110.
The cause of the thrown
TestFailedDueToTimeoutException
will be the exception most recently thrown by the block of code passed to eventually. (In the previous example, the cause would be theTestFailedException
with the detail message2 was not equal to 100
.)Configuration of
eventually
The
eventually
methods of this trait can be flexibly configured. The two configuration parameters foreventually
along with their default values and meanings are described in the following table:Configuration Parameter Default Value Meaning timeout
scaled(150 milliseconds)
the maximum amount of time to allow unsuccessful attempts before giving up and throwing TestFailedDueToTimeoutException
interval
scaled(15 milliseconds)
the amount of time to sleep between each attempt The default values of both timeout and interval are passed to the
scaled
method, inherited fromScaledTimeSpans
, so that the defaults can be scaled up or down together with other scaled time spans. See the documentation for traitScaledTimeSpans
for more information.The
eventually
methods of traitEventually
each take aPatienceConfig
object as an implicit parameter. This object provides values for the two configuration parameters. (These configuration parameters are called "patience" because they determine how patient tests will be with asynchronous operations: how long they will tolerate failures before giving up and how long they will wait before checking again after a failure.) TraitEventually
provides an implicitval
namedpatienceConfig
with each configuration parameter set to its default value. If you want to set one or more configuration parameters to a different value for all invocations ofeventually
in a suite you can override this val (or hide it, for example, if you are importing the members of theEventually
companion object rather than mixing in the trait). For example, if you always want the defaulttimeout
to be 2 seconds and the defaultinterval
to be 5 milliseconds, you can overridepatienceConfig
, like this:implicit override val patienceConfig = PatienceConfig(timeout = scaled(Span(2, Seconds)), interval = scaled(Span(5, Millis)))
Or, hide it by declaring a variable of the same name in whatever scope you want the changed values to be in effect:
implicit val patienceConfig = PatienceConfig(timeout = scaled(Span(2, Seconds)), interval = scaled(Span(5, Millis)))
Passing your new default values to
scaled
is optional, but a good idea because it allows them to be easily scaled if run on a slower or faster system.In addition to taking a
PatienceConfig
object as an implicit parameter, theeventually
methods of traitEventually
include overloaded forms that take one or twoPatienceConfigParam
objects that you can use to override the values provided by the implicitPatienceConfig
for a singleeventually
invocation. For example, if you want to settimeout
to 5 seconds for just one particulareventually
invocation, you can do so like this:eventually (timeout(Span(5, Seconds))) { Thread.sleep(10); it.next should be (110) }
This invocation of
eventually
will use 5 seconds for thetimeout
and whatever value is specified by the implicitly passedPatienceConfig
object for theinterval
configuration parameter. If you want to set both configuration parameters in this way, just list them separated by commas:eventually (timeout(Span(5, Seconds)), interval(Span(5, Millis))) { it.next should be (110) }
You can also import or mix in the members of
SpanSugar
if you want a more concise DSL for expressing time spans:eventually (timeout(5 seconds), interval(5 millis)) { it.next should be (110) }
Note that ScalaTest will not scale any time span that is not explicitly passed to
scaled
to make the meaning of the code as obvious as possible. Thus if you ask for "timeout(5 seconds)
" you will get exactly that: a timeout of five seconds. If you want such explicitly given values to be scaled, you must pass them toscale
explicitly like this:eventually (timeout(scaled(5 seconds))) { it.next should be (110) }
The previous code says more clearly that the timeout will be five seconds, unless scaled higher or lower by the
scaled
method.Simple backoff algorithm
The
eventually
methods employ a very simple backoff algorithm to try and maximize the speed of tests. If an asynchronous operation completes quickly, a smaller interval will yield a faster test. But if an asynchronous operation takes a while, a small interval will keep the CPU busy repeatedly checking and rechecking a not-ready operation, to some extent taking CPU cycles away from other processes that could proceed. To strike the right balance between these design tradeoffs, theeventually
methods will check more frequently during the initial interval.Rather than sleeping an entire interval if the initial attempt fails,
eventually
will only sleep 1/10 of the configured interval. It will continue sleeping only 1/10 of the configured interval until the configured interval has passed, after which it sleeps the configured interval between attempts. Here's an example in which the timeout is set equal to the interval:val xs = 1 to 125 val it = xs.iterator eventually(timeout(100 milliseconds), interval(100 milliseconds)) { it.next should be (110) }
Even though this call to
eventually
will time out after only one interval, approximately, the error message will likely report that more than one (and less than ten) attempts were made:The code passed to eventually never returned normally. Attempted 6 times over 100.485 milliseconds. Last failure message: 6 was not equal to 110.
Note that if the initial attempt takes longer than the configured interval to complete,
eventually
will never sleep for a 1/10 interval. You can observe this behavior in the second example above in which the first statement in the block of code passed toeventually
wasThread.sleep(50)
.Usage note:
Eventually
intended primarily for integration testingAlthough the default timeouts of trait
Eventually
are tuned for unit testing, the use ofEventually
in unit tests is a choice you should question. Usually during unit testing you'll want to mock out subsystems that would requireEventually
, such as network services with varying and unpredictable response times. This will allow your unit tests to run as fast as possible while still testing the focused bits of behavior they are designed to test.Nevertheless, because sometimes it will make sense to use
Eventually
in unit tests (and because it is destined to happen anyway even when it isn't the best choice),Eventually
by default uses timeouts tuned for unit tests: Calls toeventually
are more likely to succeed on fast development machines, and if a call does time out, it will do so quickly so the unit tests can move on.When you are using
Eventually
for integration testing, therefore, the default timeout and interval may be too small. A good way to override them is by mixing in traitIntegrationPatience
or a similar trait of your own making. Here's an example:class ExampleSpec extends FeatureSpec with Eventually with IntegrationPatience { // Your integration tests here... }
Trait
IntegrationPatience
increases the default timeout from 150 milliseconds to 15 seconds, the default interval from 15 milliseconds to 150 milliseconds. If need be, you can do fine tuning of the timeout and interval by specifying a time span scale factor when you run your tests. - trait Futures extends PatienceConfiguration
Trait that facilitates testing with futures.
Trait that facilitates testing with futures.
This trait defines a
FutureConcept
trait that can be used to implicitly wrap different kinds of futures, thereby providing a uniform testing API for futures. The three ways this trait enables you to test futures are:1. Invoking
isReadyWithin
, to assert that a future is ready within a a specified time period. Here's an example:assert(result.isReadyWithin(100 millis))
2. Invoking
futureValue
, to obtain a futures result within a specified or implicit time period, like this:assert(result.futureValue === 7)
// Or, if you expect the future to fail: assert(result.failed.futureValue.isInstanceOf[ArithmeticException])3. Passing the future to
whenReady
, and performing assertions on the result value passed to the given function, as in:whenReady(result) { s => s should be ("hello") }
The
whenReady
construct periodically inspects the passed future, until it is either ready or the configured timeout has been surpassed. If the future becomes ready before the timeout,whenReady
passes the future's value to the specified function.To make
whenReady
more broadly applicable, the type of future it accepts is aFutureConcept[T]
, whereT
is the type of value promised by the future. Passing a future towhenReady
requires an implicit conversion from the type of future you wish to pass (the modeled type) toFutureConcept[T]
. SubtraitJavaFutures
provides an implicit conversion fromjava.util.concurrent.Future[T]
toFutureConcept[T]
.For example, the following invocation of
whenReady
would succeed (not throw an exception):import org.scalatest._ import Matchers._ import concurrent.Futures._ import java.util.concurrent._
val exec = Executors.newSingleThreadExecutor val task = new Callable[String] { def call() = { Thread.sleep(50); "hi" } } whenReady(exec.submit(task)) { s => s should be ("hi") }However, because the default timeout is 150 milliseconds, the following invocation of
whenReady
would ultimately produce aTestFailedException
:val task = new Callable[String] { def call() = { Thread.sleep(500); "hi" } } whenReady(exec.submit(task)) { s => s should be ("hi") }
Assuming the default configuration parameters, a
timeout
of 150 milliseconds and aninterval
of 15 milliseconds, were passed implicitly towhenReady
, the detail message of the thrownTestFailedException
would look like:The future passed to whenReady was never ready, so whenReady timed out. Queried 95 times, sleeping 10 milliseconds between each query.
Configuration of
whenReady
The
whenReady
methods of this trait can be flexibly configured. The two configuration parameters forwhenReady
along with their default values and meanings are described in the following table:Configuration Parameter Default Value Meaning timeout scaled(150 milliseconds) the maximum amount of time to allow unsuccessful queries before giving up and throwing TestFailedException
interval scaled(15 milliseconds) the amount of time to sleep between each query The default values of both timeout and interval are passed to the
scaled
method, inherited fromScaledTimeSpans
, so that the defaults can be scaled up or down together with other scaled time spans. See the documentation for traitScaledTimeSpans
for more information.The
whenReady
methods of traitFutures
each take aPatienceConfig
object as an implicit parameter. This object provides values for the two configuration parameters. TraitFutures
provides an implicitval
nameddefaultPatience
with each configuration parameter set to its default value. If you want to set one or more configuration parameters to a different value for all invocations ofwhenReady
in a suite you can override this val (or hide it, for example, if you are importing the members of theFutures
companion object rather than mixing in the trait). For example, if you always want the defaulttimeout
to be 2 seconds and the defaultinterval
to be 5 milliseconds, you can overridedefaultPatience
, like this:implicit override val defaultPatience = PatienceConfig(timeout = Span(2, Seconds), interval = Span(5, Millis))
Or, hide it by declaring a variable of the same name in whatever scope you want the changed values to be in effect:
implicit val defaultPatience = PatienceConfig(timeout = Span(2, Seconds), interval = Span(5, Millis))
In addition to taking a
PatienceConfig
object as an implicit parameter, thewhenReady
methods of traitFutures
include overloaded forms that take one or twoPatienceConfigParam
objects that you can use to override the values provided by the implicitPatienceConfig
for a singlewhenReady
invocation. For example, if you want to settimeout
to 6 seconds for just one particularwhenReady
invocation, you can do so like this:whenReady (exec.submit(task), timeout(Span(6, Seconds))) { s => s should be ("hi") }
This invocation of
eventually
will use 6000 fortimeout
and whatever value is specified by the implicitly passedPatienceConfig
object for theinterval
configuration parameter. If you want to set both configuration parameters in this way, just list them separated by commas:whenReady (exec.submit(task), timeout(Span(6, Seconds)), interval(Span(500, Millis))) { s => s should be ("hi") }
You can also import or mix in the members of
SpanSugar
if you want a more concise DSL for expressing time spans:whenReady (exec.submit(task), timeout(6 seconds), interval(500 millis)) { s => s should be ("hi") }
Note: The
whenReady
construct was in part inspired by thewhenDelivered
matcher of the BlueEyes project, a lightweight, asynchronous web framework for Scala. - trait IntegrationPatience extends AbstractPatienceConfiguration
Stackable modification trait for
PatienceConfiguration
that provides default timeout and interval values appropriate for integration testing.Stackable modification trait for
PatienceConfiguration
that provides default timeout and interval values appropriate for integration testing.The default values for the parameters are:
Configuration Parameter Default Value timeout
scaled(15 seconds)
interval
scaled(150 milliseconds)
The default values of both timeout and interval are passed to the
scaled
method, inherited fromScaledTimeSpans
, so that the defaults can be scaled up or down together with other scaled time spans. See the documentation for traitScaledTimeSpans
for more information.Mix this trait into any class that uses
PatienceConfiguration
(such as classes that mix inEventually
orWaiters
) to get timeouts tuned towards integration testing, like this:class ExampleSpec extends FeatureSpec with Eventually with IntegrationPatience { // ... }
- trait JavaFutures extends Futures
Provides an implicit conversion from
java.util.concurrent.Future[T]
toFutureConcept[T]
.Provides an implicit conversion from
java.util.concurrent.Future[T]
toFutureConcept[T]
.This trait enables you to invoke the methods defined on
FutureConcept
on a JavaFuture
, as well as to pass a Java future to thewhenReady
methods of supertraitFutures
. See the documentation for supertraitFutures
for the details on the syntax this trait provides for testing with Java futures. - trait PatienceConfiguration extends AbstractPatienceConfiguration
Trait providing methods and classes used to configure timeouts and, where relevant, the interval between retries.
Trait providing methods and classes used to configure timeouts and, where relevant, the interval between retries.
This trait is called
PatienceConfiguration
because it allows configuration of two values related to patience: The timeout specifies how much time asynchronous operations will be given to succeed before giving up. The interval specifies how much time to wait between checks to determine success when polling.The default values for timeout and interval provided by trait
PatienceConfiguration
are tuned for unit testing, where running tests as fast as possible is a high priority and subsystems requiring asynchronous operations are therefore often replaced by mocks. This table shows the default values:Configuration Parameter Default Value timeout
scaled(150 milliseconds)
interval
scaled(15 milliseconds)
Values more appropriate to integration testing, where asynchronous operations tend to take longer because the tests are run against the actual subsytems (not mocks), can be obtained by mixing in trait
IntegrationPatience
.The default values of both timeout and interval are passed to the
scaled
method, inherited fromScaledTimeSpans
, so that the defaults can be scaled up or down together with other scaled time spans. See the documentation for traitScaledTimeSpans
for more information.Timeouts are used by the
eventually
methods of traitEventually
and theawait
method of classWaiter
, a member of traitWaiters
. Intervals are used by theeventually
methods. - trait ScalaFutures extends Futures
Provides an implicit conversion from
scala.concurrent.Future[T]
toFutureConcept[T]
.Provides an implicit conversion from
scala.concurrent.Future[T]
toFutureConcept[T]
.This trait enables you to invoke the methods defined on
FutureConcept
on a ScalaFuture
, as well as to pass a Scala future to thewhenReady
methods of supertraitFutures
. The three ways this trait enables you to test futures are:1. Invoking
isReadyWithin
, to assert that a future is ready within a a specified time period. Here's an example:assert(result.isReadyWithin(100 millis))
2. Invoking
futureValue
, to obtain a futures result within a specified or implicit time period, like this:assert(result.futureValue === 7)
// Or, if you expect the future to fail: assert(result.failed.futureValue.isInstanceOf[ArithmeticException])3. Passing the future to
whenReady
, and performing assertions on the result value passed to the given function, as in:whenReady(result) { s => s should be ("hello") }
The
whenReady
construct periodically inspects the passed future, until it is either ready or the configured timeout has been surpassed. If the future becomes ready before the timeout,whenReady
passes the future's value to the specified function.To make
whenReady
more broadly applicable, the type of future it accepts is aFutureConcept[T]
, whereT
is the type of value promised by the future. Passing a future towhenReady
requires an implicit conversion from the type of future you wish to pass (the modeled type) toFutureConcept[T]
. SubtraitJavaFutures
provides an implicit conversion fromjava.util.concurrent.Future[T]
toFutureConcept[T]
.For example, the following invocation of
whenReady
would succeed (not throw an exception):import org.scalatest._ import Matchers._ import concurrent.Futures._ import java.util.concurrent._
val exec = Executors.newSingleThreadExecutor val task = new Callable[String] { def call() = { Thread.sleep(50); "hi" } } whenReady(exec.submit(task)) { s => s should be ("hi") }However, because the default timeout is 150 milliseconds, the following invocation of
whenReady
would ultimately produce aTestFailedException
:val task = new Callable[String] { def call() = { Thread.sleep(500); "hi" } } whenReady(exec.submit(task)) { s => s should be ("hi") }
Assuming the default configuration parameters, a
timeout
of 150 milliseconds and aninterval
of 15 milliseconds, were passed implicitly towhenReady
, the detail message of the thrownTestFailedException
would look like:The future passed to whenReady was never ready, so whenReady timed out. Queried 95 times, sleeping 10 milliseconds between each query.
Configuration of
whenReady
The
whenReady
methods of this trait can be flexibly configured. The two configuration parameters forwhenReady
along with their default values and meanings are described in the following table:Configuration Parameter Default Value Meaning timeout scaled(150 milliseconds) the maximum amount of time to allow unsuccessful queries before giving up and throwing TestFailedException
interval scaled(15 milliseconds) the amount of time to sleep between each query The default values of both timeout and interval are passed to the
scaled
method, inherited fromScaledTimeSpans
, so that the defaults can be scaled up or down together with other scaled time spans. See the documentation for traitScaledTimeSpans
for more information.The
whenReady
methods of traitFutures
each take aPatienceConfig
object as an implicit parameter. This object provides values for the two configuration parameters. TraitFutures
provides an implicitval
nameddefaultPatience
with each configuration parameter set to its default value. If you want to set one or more configuration parameters to a different value for all invocations ofwhenReady
in a suite you can override this val (or hide it, for example, if you are importing the members of theFutures
companion object rather than mixing in the trait). For example, if you always want the defaulttimeout
to be 2 seconds and the defaultinterval
to be 5 milliseconds, you can overridedefaultPatience
, like this:implicit override val defaultPatience = PatienceConfig(timeout = Span(2, Seconds), interval = Span(5, Millis))
Or, hide it by declaring a variable of the same name in whatever scope you want the changed values to be in effect:
implicit val defaultPatience = PatienceConfig(timeout = Span(2, Seconds), interval = Span(5, Millis))
In addition to taking a
PatienceConfig
object as an implicit parameter, thewhenReady
methods of traitFutures
include overloaded forms that take one or twoPatienceConfigParam
objects that you can use to override the values provided by the implicitPatienceConfig
for a singlewhenReady
invocation. For example, if you want to settimeout
to 6 seconds for just one particularwhenReady
invocation, you can do so like this:whenReady (exec.submit(task), timeout(Span(6, Seconds))) { s => s should be ("hi") }
This invocation of
eventually
will use 6000 fortimeout
and whatever value is specified by the implicitly passedPatienceConfig
object for theinterval
configuration parameter. If you want to set both configuration parameters in this way, just list them separated by commas:whenReady (exec.submit(task), timeout(Span(6, Seconds)), interval(Span(500, Millis))) { s => s should be ("hi") }
You can also import or mix in the members of
SpanSugar
if you want a more concise DSL for expressing time spans:whenReady (exec.submit(task), timeout(6 seconds), interval(500 millis)) { s => s should be ("hi") }
Note: The
whenReady
construct was in part inspired by thewhenDelivered
matcher of the BlueEyes project, a lightweight, asynchronous web framework for Scala. - trait ScaledTimeSpans extends AnyRef
Trait providing a
scaled
method that can be used to scale timeSpan
s used during the testing of asynchronous operations.Trait providing a
scaled
method that can be used to scale timeSpan
s used during the testing of asynchronous operations.The
scaled
method allows tests of asynchronous operations to be tuned according to need. For example,Span
s can be scaled larger when running tests on slower continuous integration servers or smaller when running on faster development machines.The
Double
factor by which to scale theSpan
s passed toscaled
is obtained from thespanScaleFactor
method, also declared in this trait. By default this method returns 1.0, but can be configured to return a different value by passing a-F
argument toRunner
(or an equivalent mechanism in an ant, sbt, or Maven build file).The default timeouts and intervals defined for traits
Eventually
andWaiters
invokescaled
, so those defaults will be scaled automatically. Other than such defaults, however, to get aSpan
to scale you'll need to explicitly pass it toscaled
. For example, here's how you would scale aSpan
you supply to thefailAfter
method from traitTimeouts
:failAfter(scaled(150 millis)) { // ... }
The reason
Span
s are not scaled automatically in the general case is to make code obvious. If a reader seesfailAfter(1 second)
, it will mean exactly that: fail after one second. And if aSpan
will be scaled, the reader will clearly see that as well:failAfter(scaled(1 second))
.Overriding
spanScaleFactor
You can override the
spanScaleFactor
method to configure the factor by a different means. For example, to configure the factor from Akka TestKit's test time factor you might create a trait like this:import org.scalatest.concurrent.ScaledTimeSpans import akka.actor.ActorSystem import akka.testkit.TestKitExtension
trait AkkaSpanScaleFactor extends ScaledTimeSpans { override def spanScaleFactor: Double = TestKitExtension.get(ActorSystem()).TestTimeFactor }This trait overrides
spanScaleFactor
so that it takes its scale factor from Akka'sapplication.conf
file. You could then scaleSpan
s tenfold in Akka's configuration file like this:akka { test { timefactor = 10.0 } }
Armed with this trait and configuration file, you can simply mix trait
AkkaSpanScaleFactor
into any test class whoseSpan
s you want to scale, like this:class MySpec extends FunSpec with Eventually with AkkaSpanScaleFactor { // .. }
- class SelectorSignaler extends Signaler
Strategy for signaling an operation in which
wakeup
is called on thejava.nio.channels.Selector
passed to the constructor.Strategy for signaling an operation in which
wakeup
is called on thejava.nio.channels.Selector
passed to the constructor.This class can be used for configuration when using traits
TimeLimits
andTimeLimitedTests
. - trait Signaler extends AnyRef
Strategy for signaling an operation after a timeout expires.
Strategy for signaling an operation after a timeout expires.
An instance of this trait is used for configuration when using traits
TimeLimits
andTimeLimitedTests
. - class SocketSignaler extends Signaler
Strategy for signaling an operation in which
close
is called on thejava.net.Socket
passed to the constructor.Strategy for signaling an operation in which
close
is called on thejava.net.Socket
passed to the constructor.This class can be used for configuration when using traits
TimeLimits
andTimeLimitedTests
. - trait TimeLimitedTests extends TestSuiteMixin
Trait that when mixed into a suite class establishes a time limit for its tests.
Trait that when mixed into a suite class establishes a time limit for its tests.
Unfortunately this trait experienced a potentially breaking change in 3.0: previously this trait declared a
defaultTestInterruptor
val
of typeInterruptor
, in 3.0 that was renamed todefaultTestSignaler
and given typeSignaler
. The reason is that the defaultInterruptor
,ThreadInterruptor
, did not make sense on Scala.js—in fact, the entire notion of interruption did not make sense on Scala.js.Signaler
's default isDoNotSignal
, which is a better default on Scala.js, and works fine as a default on the JVM.Timeouts
was left the same in 3.0, so existing code using it would continue to work as before, but after a deprecation periodTimeouts
will be supplanted byTimeLimits
, which usesSignaler
.TimeLimitedTests
now usesTimeLimits
instead ofTimeouts
, so if you overrode the defaultInterruptor
before, you'll need to change it to the equivalentSignaler
. And if you were depending on the default being aThreadInterruptor
, you'll need to overridedefaultTestSignaler
and set it toThreadSignaler
.This trait overrides
withFixture
, wrapping asuper.withFixture(test)
call in afailAfter
invocation, specifying a time limit obtained by invokingtimeLimit
and aSignaler
by invokingdefaultTestSignaler
:failAfter(timeLimit) { super.withFixture(test) } (defaultTestSignaler)
Note that the
failAfter
method executes the body of the by-name passed to it using the same thread that invokedfailAfter
. This means that the same thread will run thewithFixture
method as well as each test, so no extra synchronization is required. A second thread is used to run a timer, and if the timeout expires, that second thread will attempt to signal the main test thread via thedefaultTestSignaler
.The
timeLimit
field is abstract in this trait. Thus you must specify a time limit when you use it. For example, the following code specifies that each test must complete within 200 milliseconds:import org.scalatest.FunSpec import org.scalatest.concurrent.TimeLimitedTests import org.scalatest.time.SpanSugar._
class ExampleSpec extends FunSpec with TimeLimitedTests {
// Note: You may need to either write 200.millis or (200 millis), or // place a semicolon or blank line after plain old 200 millis, to // avoid the semicolon inference problems of postfix operator notation. val timeLimit = 200 millis
describe("A time-limited test") { it("should succeed if it completes within the time limit") { Thread.sleep(100) } it("should fail if it is taking too darn long") { Thread.sleep(300) } } }If you run the above
ExampleSpec
, the second test will fail with the error message:The test did not complete within the specified 200 millisecond time limit.
The
failAfter
method uses anSignaler
to attempt to signal the main test thread if the timeout expires. The defaultSignaler
returned by thedefaultTestSignaler
method is aDoNotSignal
, which does not signal the main test thread to stop. If you wish to change this signaling strategy, overridedefaultTestSignaler
to return a differentSignaler
. For example, here's how you'd change the default toThreadSignaler
, which will interrupt the main test thread when time is up:import org.scalatest.FunSpec import org.scalatest.concurrent.{ThreadSignaler, TimeLimitedTests} import org.scalatest.time.SpanSugar._
class ExampleSignalerSpec extends FunSpec with TimeLimitedTests {
val timeLimit = 200 millis
override val defaultTestSignaler = ThreadSignaler
describe("A time-limited test") { it("should succeed if it completes within the time limit") { Thread.sleep(100) } it("should fail if it is taking too darn long") { Thread.sleep(300) } } }Like the previous incarnation of
ExampleSuite
, the second test will fail with an error message that indicates a timeout expired. But whereas in the previous case, theThread.sleep
would be interrupted after 200 milliseconds, in this case it is never interrupted. In the previous case, the failed test requires a little over 200 milliseconds to run. In this case, because thesleep(300)
is never interrupted, the failed test requires a little over 300 milliseconds to run. - trait TimeLimits extends AnyRef
Trait that provides
failAfter
andcancelAfter
methods, which allow you to specify a time limit for an operation passed as a by-name parameter, as well as a way to signal it if the operation exceeds its time limit.Trait that provides
failAfter
andcancelAfter
methods, which allow you to specify a time limit for an operation passed as a by-name parameter, as well as a way to signal it if the operation exceeds its time limit.The time limit is passed as the first parameter, as a
Span
. The operation is passed as the second parameter. ASignaler
, a strategy for interrupting the operation, is passed as an implicit third parameter. Here's a simple example of its use:failAfter(Span(100, Millis)) { Thread.sleep(200) }
The above code will eventually produce a
TestFailedDueToTimeoutException
with a message that indicates a time limit has been exceeded:The code passed to failAfter did not complete within 100 milliseconds.
If you use
cancelAfter
in place offailAfter
, aTestCanceledException
will be thrown instead, also with a message that indicates a time limit has been exceeded:The code passed to cancelAfter did not complete within 100 milliseconds.
If you prefer you can mix in or import the members of
SpanSugar
and place a units value after the integer timeout. Here are some examples:import org.scalatest.time.SpanSugar._
failAfter(100 millis) { Thread.sleep(200) }
failAfter(1 second) { Thread.sleep(2000) }The code passed via the by-name parameter to
failAfter
orcancelAfter
will be executed by the thread that invokedfailAfter
orcancelAfter
, so that no synchronization is necessary to access variables declared outside the by-name.var result = -1 // No need to make this volatile failAfter(100 millis) { result = accessNetService() } result should be (99)
The
failAfter
orcancelAfter
method will create a timer that runs on a different thread than the thread that invokedfailAfter
orcancelAfter
, so that it can detect when the time limit has been exceeded and attempt to signal the main thread. Because different operations can require different signaling strategies, thefailAfter
andcancelAfter
methods accept an implicit third parameter of typeSignaler
that is responsible for signaling the main thread.Configuring
failAfter
orcancelAfter
with aSignaler
The
Signaler
companion object declares an implicitval
of typeSignaler
that returns aDoNotSignal
. This serves as the default signaling strategy. If you wish to use a different strategy, you can declare an implicitval
that establishes a differentSignaler
as the policy. Here's an example in which the default signaling strategy is changed toThreadSignaler
, which does not attempt to interrupt the main thread in any way:override val signaler: Signaler = ThreadSignaler failAfter(100 millis) { Thread.sleep(500) }
As with the default
Signaler
, the above code will eventually produce aTestFailedDueToTimeoutException
with a message that indicates a timeout expired. However, instead of throwing the exception after approximately 500 milliseconds, it will throw it after approximately 100 milliseconds.This illustrates an important feature of
failAfter
andcancelAfter
: it will throw aTestFailedDueToTimeoutException
(orTestCanceledException
in case ofcancelAfter
) if the code passed as the by-name parameter takes longer than the specified timeout to execute, even if it is allowed to run to completion beyond the specified timeout and returns normally.ScalaTest provides the following
Signaler
implementations:Signaler
implementationUsage DoNotSignal The default signaler, does not attempt to interrupt the main test thread in any way ThreadSignaler Invokes interrupt
on the main test thread. This will set the interrupted status for the main test thread and, if the main thread is blocked, will in some cases cause the main thread to complete abruptly with anInterruptedException
.SelectorSignaler Invokes wakeup
on the passedjava.nio.channels.Selector
, which will cause the main thread, if blocked inSelector.select
, to complete abruptly with aClosedSelectorException
.SocketSignaler Invokes close
on thejava.io.Socket
, which will cause the main thread, if blocked in a read or write of anjava.io.InputStream
orjava.io.OutputStream
that uses theSocket
, to complete abruptly with aSocketException
.You may wish to create your own
Signaler
in some situations. For example, if your operation is performing a loop and can check a volatile flag each pass through the loop, you could write aSignaler
that sets that flag so that the next time around, the loop would exit. - trait Waiters extends PatienceConfiguration
Trait that facilitates performing assertions outside the main test thread, such as assertions in callback methods that are invoked asynchronously.
Trait that facilitates performing assertions outside the main test thread, such as assertions in callback methods that are invoked asynchronously.
Trait
Waiters
provides aWaiter
class that you can use to orchestrate the inter-thread communication required to perform assertions outside the main test thread, and a means to configure it.To use
Waiter
, create an instance of it in the main test thread:val w = new Waiter // Do this in the main test thread
At some point later, call
await
on the waiter:w.await() // Call await() from the main test thread
The
await
call will block until it either receives a report of a failed assertion from a different thread, at which point it will complete abruptly with the same exception, or until it is dismissed by a different thread (or threads), at which point it will return normally. You can optionally specify a timeout and/or a number of dismissals to wait for. Here's an example:import org.scalatest.time.SpanSugar._
w.await(timeout(300 millis), dismissals(2))The default value for
timeout
, provided via an implicitPatienceConfig
parameter, is 150 milliseconds. The default value fordismissals
is 1. Theawait
method will block until either it is dismissed a sufficient number of times by other threads or an assertion fails in another thread. Thus if you just want to perform assertions in just one other thread, only that thread will be performing a dismissal, so you can use the default value of 1 fordismissals
.Waiter
contains four overloaded forms ofawait
, two of which take an implicitPatienceConfig
parameter. To change the default timeout configuration, override or hide (if you imported the members ofWaiters
companion object instead of mixing in the trait)patienceConfig
with a new one that returns your desired configuration.To dismiss a waiter, you just invoke
dismiss
on it:w.dismiss() // Call this from one or more other threads
You may want to put
dismiss
invocations in a finally clause to ensure they happen even if an exception is thrown. Otherwise if a dismissal is missed because of a thrown exception, anawait
call will wait until it times out.Note that if a
Waiter
receives more than the expected number of dismissals, it will not report this as an error: i.e., receiving greater than the number of expected dismissals without any failed assertion will simply cause the the test to complete, not to fail. The only way aWaiter
will cause a test to fail is if one of the asynchronous assertions to which it is applied fails.Finally, to perform an assertion in a different thread, you just apply the
Waiter
to the assertion code. Here are some examples:w { assert(1 + 1 === 3) } // Can use assertions w { 1 + 1 should equal (3) } // Or matchers w { "hi".charAt(-1) } // Any exceptions will be forwarded to await
Here's a complete example:
import org.scalatest._ import concurrent.Waiters import scala.actors.Actor
class ExampleSuite extends FunSuite with Matchers with Waiters {
case class Message(text: String)
class Publisher extends Actor {
@volatile private var handle: Message => Unit = { (msg) => }
def registerHandler(f: Message => Unit) { handle = f }
def act() { var done = false while (!done) { react { case msg: Message => handle(msg) case "Exit" => done = true } } } }
test("example one") {
val publisher = new Publisher val message = new Message("hi") val w = new Waiter
publisher.start()
publisher.registerHandler { msg => w { msg should equal (message) } w.dismiss() }
publisher ! message w.await() publisher ! "Exit" } }
Value Members
- object DoNotSignal extends Signaler
Signaling strategy in which nothing is done to try and signal or interrupt an operation.
Signaling strategy in which nothing is done to try and signal or interrupt an operation.
This object can be used for configuration when using traits
TimeLimits
andTimeLimitedTests
. - object Eventually extends Eventually
Companion object that facilitates the importing of
Eventually
members as an alternative to mixing in the trait.Companion object that facilitates the importing of
Eventually
members as an alternative to mixing in the trait. One use case is to importEventually
's members so you can use them in the Scala interpreter:$ scala -cp scalatest-1.8.jar Welcome to Scala version 2.9.1.final (Java HotSpot(TM) 64-Bit Server VM, Java 1.6.0_29). Type in expressions to have them evaluated. Type :help for more information. scala> import org.scalatest._ import org.scalatest._ scala> import Matchers._ import Matchers._ scala> import concurrent.Eventually._ import concurrent.Eventually._ scala> val xs = 1 to 125 xs: scala.collection.immutable.Range.Inclusive = Range(1, 2, 3, 4, 5, 6, 7, 8, 9, 10, ..., 125) scala> val it = xs.iterator it: Iterator[Int] = non-empty iterator scala> eventually { it.next should be (3) } scala> eventually { Thread.sleep(999); it.next should be (3) } org.scalatest.TestFailedException: The code passed to eventually never returned normally. Attempted 2 times, sleeping 10 milliseconds between each attempt. at org.scalatest.Eventually$class.tryTryAgain$1(Eventually.scala:313) at org.scalatest.Eventually$class.eventually(Eventually.scala:322) ...
- object PatienceConfiguration
- object ScalaFutures extends ScalaFutures
Companion object that facilitates the importing of
ScalaFutures
members as an alternative to mixing in the trait.Companion object that facilitates the importing of
ScalaFutures
members as an alternative to mixing in the trait. One use case is to importScalaFutures
's members so you can use them in the Scala interpreter. - object SelectorSignaler
Companion object that provides a factory method for a
SelectorSignaler
. - object Signaler
Companion object that provides a factory method for a
Singlaer
defined in terms of a function from a function of typeThread
to Unit. - object SocketSignaler
Companion object that provides a factory method for a
SocketSignaler
. - object ThreadSignaler extends Signaler
Strategy for signaling an operation in which
interrupt
is called on theThread
passed toapply
.Strategy for signaling an operation in which
interrupt
is called on theThread
passed toapply
.This object can be used for configuration when using traits
TimeLimits
andTimeLimitedTests
. - object TimeLimits extends TimeLimits
Companion object that facilitates the importing of
Timeouts
members as an alternative to mixing in the trait.Companion object that facilitates the importing of
Timeouts
members as an alternative to mixing in the trait. One use case is to importTimeouts
's members so you can use them in the Scala interpreter. - object Waiters extends Waiters
Companion object that facilitates the importing of
Waiters
members as an alternative to mixing in the trait.Companion object that facilitates the importing of
Waiters
members as an alternative to mixing in the trait. One use case is to importWaiters
's members so you can use them in the Scala interpreter.