io.logspace.agent.shaded.mchange.v2.async.ThreadPerTaskAsynchronousRunner Maven / Gradle / Ivy
/*
* Distributed as part of c3p0 v.0.9.1.1
*
* Copyright (C) 2005 Machinery For Change, Inc.
*
* Author: Steve Waldman
*
* This library is free software; you can redistribute it and/or modify
* it under the terms of the GNU Lesser General Public License version 2.1, as
* published by the Free Software Foundation.
*
* This software is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public License
* along with this software; see the file LICENSE. If not, write to the
* Free Software Foundation, Inc., 59 Temple Place, Suite 330,
* Boston, MA 02111-1307, USA.
*/
package io.logspace.agent.shaded.mchange.v2.async;
import java.util.*;
import io.logspace.agent.shaded.mchange.v2.log.*;
import io.logspace.agent.shaded.mchange.v2.util.ResourceClosedException;
public class ThreadPerTaskAsynchronousRunner implements AsynchronousRunner
{
final static int PRESUME_DEADLOCKED_MULTIPLE = 3; //after three times the interrupt period, we presume deadlock
final static MLogger logger = MLog.getLogger( ThreadPerTaskAsynchronousRunner.class );
//MT: unchanged post-ctor
final int max_task_threads;
final long interrupt_task_delay;
//MT: protected by this' lock
LinkedList queue = new LinkedList();
ArrayList running = new ArrayList(); //as a Collection -- duplicate-accepting-ness is important, order is not
ArrayList deadlockSnapshot = null;
boolean still_open = true;
//MT: thread-safe and not reassigned post-ctor
Thread dispatchThread = new DispatchThread();
Timer interruptAndDeadlockTimer;
public ThreadPerTaskAsynchronousRunner(int max_task_threads)
{ this( max_task_threads, 0); }
public ThreadPerTaskAsynchronousRunner(int max_task_threads, long interrupt_task_delay)
{
this.max_task_threads = max_task_threads;
this.interrupt_task_delay = interrupt_task_delay;
if ( hasIdTimer() )
{
interruptAndDeadlockTimer = new Timer( true );
TimerTask deadlockChecker = new TimerTask()
{
public void run()
{ checkForDeadlock(); }
};
long delay = interrupt_task_delay * PRESUME_DEADLOCKED_MULTIPLE;
interruptAndDeadlockTimer.schedule(deadlockChecker, delay, delay);
}
dispatchThread.start();
}
private boolean hasIdTimer()
{ return (interrupt_task_delay > 0); }
public synchronized void postRunnable(Runnable r)
{
if ( still_open )
{
queue.add( r );
this.notifyAll();
}
else
throw new ResourceClosedException("Attempted to use a ThreadPerTaskAsynchronousRunner in a closed or broken state.");
}
public void close()
{ close( true ); }
public synchronized void close( boolean skip_remaining_tasks )
{
if ( still_open )
{
this.still_open = false;
if (skip_remaining_tasks)
{
queue.clear();
for (Iterator ii = running.iterator(); ii.hasNext(); )
((Thread) ii.next()).interrupt();
closeThreadResources();
}
}
}
public synchronized int getRunningCount()
{ return running.size(); }
public synchronized Collection getRunningTasks()
{ return (Collection) running.clone(); }
public synchronized int getWaitingCount()
{ return queue.size(); }
public synchronized Collection getWaitingTasks()
{ return (Collection) queue.clone(); }
public synchronized boolean isClosed()
{ return !still_open; }
public synchronized boolean isDoneAndGone()
{ return (!dispatchThread.isAlive() && running.isEmpty() && interruptAndDeadlockTimer == null); }
private synchronized void acknowledgeComplete(TaskThread tt)
{
if (! tt.isCompleted())
{
running.remove( tt );
tt.markCompleted();
ThreadPerTaskAsynchronousRunner.this.notifyAll();
if (! still_open && queue.isEmpty() && running.isEmpty())
closeThreadResources();
}
}
private synchronized void checkForDeadlock()
{
if (deadlockSnapshot == null)
{
if (running.size() == max_task_threads)
deadlockSnapshot = (ArrayList) running.clone();
}
else if (running.size() < max_task_threads)
deadlockSnapshot = null;
else if (deadlockSnapshot.equals( running )) //deadlock!
{
if (logger.isLoggable(MLevel.WARNING))
{
StringBuffer warningMsg = new StringBuffer(1024);
warningMsg.append("APPARENT DEADLOCK! (");
warningMsg.append( this );
warningMsg.append(") Deadlocked threads (unresponsive to interrupt()) are being set aside as hopeless and up to ");
warningMsg.append( max_task_threads );
warningMsg.append(" may now be spawned for new tasks. If tasks continue to deadlock, you may run out of memory. Deadlocked task list: ");
for (int i = 0, len = deadlockSnapshot.size(); i < len; ++i)
{
if (i != 0) warningMsg.append(", ");
warningMsg.append( ((TaskThread) deadlockSnapshot.get(i)).getTask() );
}
logger.log(MLevel.WARNING, warningMsg.toString());
}
// note "complete" here means from the perspective of the async runner, as complete
// as it will ever be, since the task is presumed hopelessly hung
for (int i = 0, len = deadlockSnapshot.size(); i < len; ++i)
acknowledgeComplete( (TaskThread) deadlockSnapshot.get(i) );
deadlockSnapshot = null;
}
else
deadlockSnapshot = (ArrayList) running.clone();
}
private void closeThreadResources()
{
if (interruptAndDeadlockTimer != null)
{
interruptAndDeadlockTimer.cancel();
interruptAndDeadlockTimer = null;
}
dispatchThread.interrupt();
}
class DispatchThread extends Thread
{
DispatchThread()
{ super( "Dispatch-Thread-for-" + ThreadPerTaskAsynchronousRunner.this ); }
public void run()
{
synchronized (ThreadPerTaskAsynchronousRunner.this)
{
try
{
while (true)
{
while (queue.isEmpty() || running.size() == max_task_threads)
ThreadPerTaskAsynchronousRunner.this.wait();
Runnable next = (Runnable) queue.remove(0);
TaskThread doer = new TaskThread( next );
doer.start();
running.add( doer );
}
}
catch (InterruptedException e)
{
if (still_open) //we're not closed...
{
if ( logger.isLoggable( MLevel.WARNING ) )
logger.log( MLevel.WARNING, this.getName() + " unexpectedly interrupted! Shutting down!" );
close( false );
}
}
}
}
}
class TaskThread extends Thread
{
//MT: post-ctor constant
Runnable r;
//MT: protected by this' lock
boolean completed = false;
TaskThread( Runnable r )
{
super( "Task-Thread-for-" + ThreadPerTaskAsynchronousRunner.this );
this.r = r;
}
Runnable getTask()
{ return r; }
synchronized void markCompleted()
{ completed = true; }
synchronized boolean isCompleted()
{ return completed; }
public void run()
{
try
{
if (hasIdTimer())
{
TimerTask interruptTask = new TimerTask()
{
public void run()
{ TaskThread.this.interrupt(); }
};
interruptAndDeadlockTimer.schedule( interruptTask , interrupt_task_delay );
}
r.run();
}
finally
{ acknowledgeComplete( this ); }
}
}
}