trait Conductors extends PatienceConfiguration
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 a
Conductor
to run threads that interact with the class, trait,
or library (the subject)
you want to test. A thread can call the Conductor
's
waitForBeat
method, which will cause the thread to block
until that beat has been reached. The Conductor
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 the thread
method on the Conductor
.
When conduct
is invoked on a Conductor
, 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, the conduct
method
will complete, either by returning normally or throwing an exception. As soon as
the conduct
method completes, the Conductor
enters its defunct phase. Once the Conductor
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 of Conductor
.
Here's an example of the use of Conductor
to test the ArrayBlockingQueue
class from java.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 the Conductor
to give them a green light to proceed.
The next call in the test is whenFinished
. This method will first call conduct
on
the Conductor
, 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.
The conduct
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 executed buf put 17
and the consumer thread has executed
waitForBeat(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., the waitForBeat(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 second put
, 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 execute buf.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 execute buf 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, the buf.take
call will return 17. The consumer thread will
execute 17 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 by whenFinished
) would have completed abruptly with an exception to indicate the test
failed. However, since both threads returned normally, conduct
will return. Because conduct
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. The whenFinished
method will then return, and
because the whenFinished
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 in ArrayBlockingQueue
such as a put
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 in ArrayBlockingQueue
such that a call to take
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 call
take
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, the Conductor
will at some point later increment the beat to 1. This will awaken the producer thread. It will return from its
waitForBeat(1)
call and execute buf 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 an ArrayBlockingQueue
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 of Conductor
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 uses java.lang.Thread
's getState
method to
decide when to advance the beat. This use goes against the advice given in the Javadoc documentation for
getState
, which says, "This method is designed for use in monitoring of the system state, not for
synchronization." In short, sometimes the return value of getState
occasionally may be inacurrate,
which in turn means that sometimes a Conductor
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.
- Source
- Conductors.scala
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- Conductors
- PatienceConfiguration
- AbstractPatienceConfiguration
- ScaledTimeSpans
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- Protected
Type Members
- final case class PatienceConfig(timeout: Span = scaled(Span(150, Millis)), interval: Span = scaled(Span(15, Millis))) extends Product with Serializable
Configuration object for asynchronous constructs, such as those provided by traits
Eventually
andWaiters
.Configuration object for asynchronous constructs, such as those provided by traits
Eventually
andWaiters
.The default values for the parameters are:
Configuration Parameter Default Value timeout
scaled(150 milliseconds)
interval
scaled(15 milliseconds)
- timeout
the maximum amount of time to wait for an asynchronous operation to complete before giving up and throwing
TestFailedException
.- interval
the amount of time to sleep between each check of the status of an asynchronous operation when polling
- Definition Classes
- AbstractPatienceConfiguration
- final class Conductor extends AnyRef
Class that facilitates the testing of classes, traits, and libraries designed to be used by multiple threads concurrently.
Class that 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
calls create 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.
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- def interval(value: Span): Interval
Returns an
Interval
configuration parameter containing the passed value, which specifies the amount of time to sleep after a retry.Returns an
Interval
configuration parameter containing the passed value, which specifies the amount of time to sleep after a retry.- Definition Classes
- PatienceConfiguration
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Implicit
PatienceConfig
value providing default configuration values.Implicit
PatienceConfig
value providing default configuration values.To change the default configuration, override or hide this
def
with another implicitPatienceConfig
containing your desired default configuration values.- Definition Classes
- PatienceConfiguration → AbstractPatienceConfiguration
- final def scaled(span: Span): Span
Scales the passed
Span
by theDouble
factor returned byspanScaleFactor
.Scales the passed
Span
by theDouble
factor returned byspanScaleFactor
.The
Span
is scaled by invoking itsscaledBy
method, thus this method has the same behavior: The value returned byspanScaleFactor
can be any positive number or zero, including a fractional number. A number greater than one will scale theSpan
up to a larger value. A fractional number will scale it down to a smaller value. A factor of 1.0 will cause the exact sameSpan
to be returned. A factor of zero will causeSpan.ZeroLength
to be returned. If overflow occurs,Span.Max
will be returned. If underflow occurs,Span.ZeroLength
will be returned.- Definition Classes
- ScaledTimeSpans
- Exceptions thrown
IllegalArgumentException
if the value returned fromspanScaleFactor
is less than zero
- def spanScaleFactor: Double
The factor by which the
scaled
method will scaleSpan
s.The factor by which the
scaled
method will scaleSpan
s.The default implementation of this method will return the span scale factor that was specified for the run, or 1.0 if no factor was specified. For example, you can specify a span scale factor when invoking ScalaTest via the command line by passing a
-F
argument toRunner
.- Definition Classes
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Returns a
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configuration parameter containing the passed value, which specifies the maximum amount to wait for an asynchronous operation to complete.Returns a
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