A synchronization aid that allows a set of threads to all wait for each other to reach a common barrier point. CyclicBarriers are useful in programs involving a fixed sized party of threads that must occasionally wait for each other. The barrier is called cyclic because it can be re-used after the waiting threads are released.
A CyclicBarrier supports an optional Runnable command that is run once per barrier point, after the last thread in the party arrives, but before any threads are released. This barrier action is useful for updating shared-state before any of the parties continue.
Sample usage: Here is an example of using a barrier in a parallel decomposition design:
class Solver { final int N; final float[][] data; final CyclicBarrier barrier;
class Worker implements Runnable { int myRow; Worker(int row) { myRow = row; } public void run() { while (!done()) { processRow(myRow);
try {
barrier.await();
} catch (InterruptedException ex) {
return;
} catch (BrokenBarrierException ex) {
return;
}
}
}
}
public Solver(float[][] matrix) { data = matrix; N = matrix.length; Runnable barrierAction = new Runnable() { public void run() { mergeRows(...); }}; barrier = new CyclicBarrier(N, barrierAction);
List<Thread> threads = new ArrayList<Thread>(N);
for (int i = 0; i < N; i++) {
Thread thread = new Thread(new Worker(i));
threads.add(thread);
thread.start();
}
// wait until done
for (Thread thread : threads)
thread.join();
} }
Here, each worker thread processes a row of the matrix then waits at the barrier until all rows have been processed. When all rows are processed the supplied Runnable barrier action is executed and merges the rows. If the merger determines that a solution has been found then done() will return true and each worker will terminate.
If the barrier action does not rely on the parties being suspended when it is executed, then any of the threads in the party could execute that action when it is released. To facilitate this, each invocation of await() returns the arrival index of that thread at the barrier. You can then choose which thread should execute the barrier action, for example:
if (barrier.await() == 0) { // log the completion of this iteration }
The CyclicBarrier uses an all-or-none breakage model for failed synchronization attempts: If a thread leaves a barrier point prematurely because of interruption, failure, or timeout, all other threads waiting at that barrier point will also leave abnormally via BrokenBarrierException (or InterruptedException if they too were interrupted at about the same time).
Memory consistency effects: Actions in a thread prior to calling await() happen-before actions that are part of the barrier action, which in turn happen-before actions following a successful return from the corresponding await() in other threads.
A synchronization aid that allows a set of threads to all wait for each other to reach a common barrier point. CyclicBarriers are useful in programs involving a fixed sized party of threads that must occasionally wait for each other. The barrier is called cyclic because it can be re-used after the waiting threads are released. A CyclicBarrier supports an optional Runnable command that is run once per barrier point, after the last thread in the party arrives, but before any threads are released. This barrier action is useful for updating shared-state before any of the parties continue. Sample usage: Here is an example of using a barrier in a parallel decomposition design: class Solver { final int N; final float[][] data; final CyclicBarrier barrier; class Worker implements Runnable { int myRow; Worker(int row) { myRow = row; } public void run() { while (!done()) { processRow(myRow); try { barrier.await(); } catch (InterruptedException ex) { return; } catch (BrokenBarrierException ex) { return; } } } } public Solver(float[][] matrix) { data = matrix; N = matrix.length; Runnable barrierAction = new Runnable() { public void run() { mergeRows(...); }}; barrier = new CyclicBarrier(N, barrierAction); List<Thread> threads = new ArrayList<Thread>(N); for (int i = 0; i < N; i++) { Thread thread = new Thread(new Worker(i)); threads.add(thread); thread.start(); } // wait until done for (Thread thread : threads) thread.join(); } } Here, each worker thread processes a row of the matrix then waits at the barrier until all rows have been processed. When all rows are processed the supplied Runnable barrier action is executed and merges the rows. If the merger determines that a solution has been found then done() will return true and each worker will terminate. If the barrier action does not rely on the parties being suspended when it is executed, then any of the threads in the party could execute that action when it is released. To facilitate this, each invocation of await() returns the arrival index of that thread at the barrier. You can then choose which thread should execute the barrier action, for example: if (barrier.await() == 0) { // log the completion of this iteration } The CyclicBarrier uses an all-or-none breakage model for failed synchronization attempts: If a thread leaves a barrier point prematurely because of interruption, failure, or timeout, all other threads waiting at that barrier point will also leave abnormally via BrokenBarrierException (or InterruptedException if they too were interrupted at about the same time). Memory consistency effects: Actions in a thread prior to calling await() happen-before actions that are part of the barrier action, which in turn happen-before actions following a successful return from the corresponding await() in other threads.
(->cyclic-barrier parties)
(->cyclic-barrier parties barrier-action)
Constructor.
Creates a new CyclicBarrier that will trip when the given number of parties (threads) are waiting upon it, and which will execute the given barrier action when the barrier is tripped, performed by the last thread entering the barrier.
parties - the number of threads that must invoke await() before the barrier is tripped - int
barrier-action - the command to execute when the barrier is tripped, or null if there is no action - java.lang.Runnable
throws: java.lang.IllegalArgumentException - if parties is less than 1
Constructor. Creates a new CyclicBarrier that will trip when the given number of parties (threads) are waiting upon it, and which will execute the given barrier action when the barrier is tripped, performed by the last thread entering the barrier. parties - the number of threads that must invoke await() before the barrier is tripped - `int` barrier-action - the command to execute when the barrier is tripped, or null if there is no action - `java.lang.Runnable` throws: java.lang.IllegalArgumentException - if parties is less than 1
(await this)
(await this timeout unit)
Waits until all parties have invoked await on this barrier, or the specified waiting time elapses.
If the current thread is not the last to arrive then it is disabled for thread scheduling purposes and lies dormant until one of the following things happens:
The last thread arrives; or The specified timeout elapses; or Some other thread interrupts the current thread; or Some other thread interrupts one of the other waiting threads; or Some other thread times out while waiting for barrier; or Some other thread invokes reset() on this barrier.
If the current thread:
has its interrupted status set on entry to this method; or is interrupted while waiting
then InterruptedException is thrown and the current thread's interrupted status is cleared.
If the specified waiting time elapses then TimeoutException is thrown. If the time is less than or equal to zero, the method will not wait at all.
If the barrier is reset() while any thread is waiting, or if the barrier is broken when await is invoked, or while any thread is waiting, then BrokenBarrierException is thrown.
If any thread is interrupted while waiting, then all other waiting threads will throw BrokenBarrierException and the barrier is placed in the broken state.
If the current thread is the last thread to arrive, and a non-null barrier action was supplied in the constructor, then the current thread runs the action before allowing the other threads to continue. If an exception occurs during the barrier action then that exception will be propagated in the current thread and the barrier is placed in the broken state.
timeout - the time to wait for the barrier - long
unit - the time unit of the timeout parameter - java.util.concurrent.TimeUnit
returns: the arrival index of the current thread, where index
getParties() - 1 indicates the first
to arrive and zero indicates the last to arrive - int
throws: java.lang.InterruptedException - if the current thread was interrupted while waiting
Waits until all parties have invoked await on this barrier, or the specified waiting time elapses. If the current thread is not the last to arrive then it is disabled for thread scheduling purposes and lies dormant until one of the following things happens: The last thread arrives; or The specified timeout elapses; or Some other thread interrupts the current thread; or Some other thread interrupts one of the other waiting threads; or Some other thread times out while waiting for barrier; or Some other thread invokes reset() on this barrier. If the current thread: has its interrupted status set on entry to this method; or is interrupted while waiting then InterruptedException is thrown and the current thread's interrupted status is cleared. If the specified waiting time elapses then TimeoutException is thrown. If the time is less than or equal to zero, the method will not wait at all. If the barrier is reset() while any thread is waiting, or if the barrier is broken when await is invoked, or while any thread is waiting, then BrokenBarrierException is thrown. If any thread is interrupted while waiting, then all other waiting threads will throw BrokenBarrierException and the barrier is placed in the broken state. If the current thread is the last thread to arrive, and a non-null barrier action was supplied in the constructor, then the current thread runs the action before allowing the other threads to continue. If an exception occurs during the barrier action then that exception will be propagated in the current thread and the barrier is placed in the broken state. timeout - the time to wait for the barrier - `long` unit - the time unit of the timeout parameter - `java.util.concurrent.TimeUnit` returns: the arrival index of the current thread, where index getParties() - 1 indicates the first to arrive and zero indicates the last to arrive - `int` throws: java.lang.InterruptedException - if the current thread was interrupted while waiting
(broken? this)
Queries if this barrier is in a broken state.
returns: true if one or more parties broke out of this
barrier due to interruption or timeout since
construction or the last reset, or a barrier action
failed due to an exception; false otherwise. - boolean
Queries if this barrier is in a broken state. returns: true if one or more parties broke out of this barrier due to interruption or timeout since construction or the last reset, or a barrier action failed due to an exception; false otherwise. - `boolean`
(get-number-waiting this)
Returns the number of parties currently waiting at the barrier. This method is primarily useful for debugging and assertions.
returns: the number of parties currently blocked in await() - int
Returns the number of parties currently waiting at the barrier. This method is primarily useful for debugging and assertions. returns: the number of parties currently blocked in await() - `int`
(get-parties this)
Returns the number of parties required to trip this barrier.
returns: the number of parties required to trip this barrier - int
Returns the number of parties required to trip this barrier. returns: the number of parties required to trip this barrier - `int`
(reset this)
Resets the barrier to its initial state. If any parties are currently waiting at the barrier, they will return with a BrokenBarrierException. Note that resets after a breakage has occurred for other reasons can be complicated to carry out; threads need to re-synchronize in some other way, and choose one to perform the reset. It may be preferable to instead create a new barrier for subsequent use.
Resets the barrier to its initial state. If any parties are currently waiting at the barrier, they will return with a BrokenBarrierException. Note that resets after a breakage has occurred for other reasons can be complicated to carry out; threads need to re-synchronize in some other way, and choose one to perform the reset. It may be preferable to instead create a new barrier for subsequent use.
cljdoc is a website building & hosting documentation for Clojure/Script libraries
× close