src/hotspot/share/gc/shared/workgroup.cpp - platform/libcore - Git at Google

 /*
  * Copyright (c) 2001, 2018, Oracle and/or its affiliates. All rights reserved.
  * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
  *
  * This code is free software; you can redistribute it and/or modify it
  * under the terms of the GNU General Public License version 2 only, as
  * published by the Free Software Foundation.
  *
  * This code 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 General Public License
  * version 2 for more details (a copy is included in the LICENSE file that
  * accompanied this code).
  *
  * You should have received a copy of the GNU General Public License version
  * 2 along with this work; if not, write to the Free Software Foundation,
  * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
  *
  * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
  * or visit www.oracle.com if you need additional information or have any
  * questions.
  *
  */

 #include "precompiled.hpp"
 #include "gc/shared/gcId.hpp"
 #include "gc/shared/workgroup.hpp"
 #include "gc/shared/workerManager.hpp"
 #include "memory/allocation.hpp"
 #include "memory/allocation.inline.hpp"
 #include "memory/iterator.hpp"
 #include "runtime/atomic.hpp"
 #include "runtime/os.hpp"
 #include "runtime/semaphore.hpp"
 #include "runtime/thread.inline.hpp"

 // Definitions of WorkGang methods.

 // The current implementation will exit if the allocation
 // of any worker fails.
 void  AbstractWorkGang::initialize_workers() {
   log_develop_trace(gc, workgang)("Constructing work gang %s with %u threads", name(), total_workers());
   _workers = NEW_C_HEAP_ARRAY(AbstractGangWorker*, total_workers(), mtInternal);
   if (_workers == NULL) {
     vm_exit_out_of_memory(0, OOM_MALLOC_ERROR, "Cannot create GangWorker array.");
   }

   add_workers(true);
 }


 AbstractGangWorker* AbstractWorkGang::install_worker(uint worker_id) {
   AbstractGangWorker* new_worker = allocate_worker(worker_id);
   set_thread(worker_id, new_worker);
   return new_worker;
 }

 void AbstractWorkGang::add_workers(bool initializing) {
   add_workers(_active_workers, initializing);
 }

 void AbstractWorkGang::add_workers(uint active_workers, bool initializing) {

   os::ThreadType worker_type;
   if (are_ConcurrentGC_threads()) {
     worker_type = os::cgc_thread;
   } else {
     worker_type = os::pgc_thread;
   }
   uint previous_created_workers = _created_workers;

   _created_workers = WorkerManager::add_workers(this,
                                                 active_workers,
                                                 _total_workers,
                                                 _created_workers,
                                                 worker_type,
                                                 initializing);
   _active_workers = MIN2(_created_workers, _active_workers);

   WorkerManager::log_worker_creation(this, previous_created_workers, _active_workers, _created_workers, initializing);
 }

 AbstractGangWorker* AbstractWorkGang::worker(uint i) const {
   // Array index bounds checking.
   AbstractGangWorker* result = NULL;
   assert(_workers != NULL, "No workers for indexing");
   assert(i < total_workers(), "Worker index out of bounds");
   result = _workers[i];
   assert(result != NULL, "Indexing to null worker");
   return result;
 }

 void AbstractWorkGang::print_worker_threads_on(outputStream* st) const {
   uint workers = created_workers();
   for (uint i = 0; i < workers; i++) {
     worker(i)->print_on(st);
     st->cr();
   }
 }

 void AbstractWorkGang::threads_do(ThreadClosure* tc) const {
   assert(tc != NULL, "Null ThreadClosure");
   uint workers = created_workers();
   for (uint i = 0; i < workers; i++) {
     tc->do_thread(worker(i));
   }
 }

 // WorkGang dispatcher implemented with semaphores.
 //
 // Semaphores don't require the worker threads to re-claim the lock when they wake up.
 // This helps lowering the latency when starting and stopping the worker threads.
 class SemaphoreGangTaskDispatcher : public GangTaskDispatcher {
   // The task currently being dispatched to the GangWorkers.
   AbstractGangTask* _task;

   volatile uint _started;
   volatile uint _not_finished;

   // Semaphore used to start the GangWorkers.
   Semaphore* _start_semaphore;
   // Semaphore used to notify the coordinator that all workers are done.
   Semaphore* _end_semaphore;

 public:
   SemaphoreGangTaskDispatcher() :
       _task(NULL),
       _started(0),
       _not_finished(0),
       _start_semaphore(new Semaphore()),
       _end_semaphore(new Semaphore())
 { }

   ~SemaphoreGangTaskDispatcher() {
     delete _start_semaphore;
     delete _end_semaphore;
   }

   void coordinator_execute_on_workers(AbstractGangTask* task, uint num_workers) {
     // No workers are allowed to read the state variables until they have been signaled.
     _task         = task;
     _not_finished = num_workers;

     // Dispatch 'num_workers' number of tasks.
     _start_semaphore->signal(num_workers);

     // Wait for the last worker to signal the coordinator.
     _end_semaphore->wait();

     // No workers are allowed to read the state variables after the coordinator has been signaled.
     assert(_not_finished == 0, "%d not finished workers?", _not_finished);
     _task    = NULL;
     _started = 0;

   }

   WorkData worker_wait_for_task() {
     // Wait for the coordinator to dispatch a task.
     _start_semaphore->wait();

     uint num_started = Atomic::add(1u, &_started);

     // Subtract one to get a zero-indexed worker id.
     uint worker_id = num_started - 1;

     return WorkData(_task, worker_id);
   }

   void worker_done_with_task() {
     // Mark that the worker is done with the task.
     // The worker is not allowed to read the state variables after this line.
     uint not_finished = Atomic::sub(1u, &_not_finished);

     // The last worker signals to the coordinator that all work is completed.
     if (not_finished == 0) {
       _end_semaphore->signal();
     }
   }
 };

 class MutexGangTaskDispatcher : public GangTaskDispatcher {
   AbstractGangTask* _task;

   volatile uint _started;
   volatile uint _finished;
   volatile uint _num_workers;

   Monitor* _monitor;

  public:
   MutexGangTaskDispatcher()
       : _task(NULL),
         _monitor(new Monitor(Monitor::leaf, "WorkGang dispatcher lock", false, Monitor::_safepoint_check_never)),
         _started(0),
         _finished(0),
         _num_workers(0) {}

   ~MutexGangTaskDispatcher() {
     delete _monitor;
   }

   void coordinator_execute_on_workers(AbstractGangTask* task, uint num_workers) {
     MutexLockerEx ml(_monitor, Mutex::_no_safepoint_check_flag);

     _task        = task;
     _num_workers = num_workers;

     // Tell the workers to get to work.
     _monitor->notify_all();

     // Wait for them to finish.
     while (_finished < _num_workers) {
       _monitor->wait(/* no_safepoint_check */ true);
     }

     _task        = NULL;
     _num_workers = 0;
     _started     = 0;
     _finished    = 0;
   }

   WorkData worker_wait_for_task() {
     MonitorLockerEx ml(_monitor, Mutex::_no_safepoint_check_flag);

     while (_num_workers == 0 || _started == _num_workers) {
       _monitor->wait(/* no_safepoint_check */ true);
     }

     _started++;

     // Subtract one to get a zero-indexed worker id.
     uint worker_id = _started - 1;

     return WorkData(_task, worker_id);
   }

   void worker_done_with_task() {
     MonitorLockerEx ml(_monitor, Mutex::_no_safepoint_check_flag);

     _finished++;

     if (_finished == _num_workers) {
       // This will wake up all workers and not only the coordinator.
       _monitor->notify_all();
     }
   }
 };

 static GangTaskDispatcher* create_dispatcher() {
   if (UseSemaphoreGCThreadsSynchronization) {
     return new SemaphoreGangTaskDispatcher();
   }

   return new MutexGangTaskDispatcher();
 }

 WorkGang::WorkGang(const char* name,
                    uint  workers,
                    bool  are_GC_task_threads,
                    bool  are_ConcurrentGC_threads) :
     AbstractWorkGang(name, workers, are_GC_task_threads, are_ConcurrentGC_threads),
     _dispatcher(create_dispatcher())
 { }

 WorkGang::~WorkGang() {
   delete _dispatcher;
 }

 AbstractGangWorker* WorkGang::allocate_worker(uint worker_id) {
   return new GangWorker(this, worker_id);
 }

 void WorkGang::run_task(AbstractGangTask* task) {
   run_task(task, active_workers());
 }

 void WorkGang::run_task(AbstractGangTask* task, uint num_workers) {
   guarantee(num_workers <= total_workers(),
             "Trying to execute task %s with %u workers which is more than the amount of total workers %u.",
             task->name(), num_workers, total_workers());
   guarantee(num_workers > 0, "Trying to execute task %s with zero workers", task->name());
   uint old_num_workers = _active_workers;
   update_active_workers(num_workers);
   _dispatcher->coordinator_execute_on_workers(task, num_workers);
   update_active_workers(old_num_workers);
 }

 AbstractGangWorker::AbstractGangWorker(AbstractWorkGang* gang, uint id) {
   _gang = gang;
   set_id(id);
   set_name("%s#%d", gang->name(), id);
 }

 void AbstractGangWorker::run() {
   initialize();
   loop();
 }

 void AbstractGangWorker::initialize() {
   this->initialize_named_thread();
   assert(_gang != NULL, "No gang to run in");
   os::set_priority(this, NearMaxPriority);
   log_develop_trace(gc, workgang)("Running gang worker for gang %s id %u", gang()->name(), id());
   // The VM thread should not execute here because MutexLocker's are used
   // as (opposed to MutexLockerEx's).
   assert(!Thread::current()->is_VM_thread(), "VM thread should not be part"
          " of a work gang");
 }

 bool AbstractGangWorker::is_GC_task_thread() const {
   return gang()->are_GC_task_threads();
 }

 bool AbstractGangWorker::is_ConcurrentGC_thread() const {
   return gang()->are_ConcurrentGC_threads();
 }

 void AbstractGangWorker::print_on(outputStream* st) const {
   st->print("\"%s\" ", name());
   Thread::print_on(st);
   st->cr();
 }

 WorkData GangWorker::wait_for_task() {
   return gang()->dispatcher()->worker_wait_for_task();
 }

 void GangWorker::signal_task_done() {
   gang()->dispatcher()->worker_done_with_task();
 }

 void GangWorker::run_task(WorkData data) {
   GCIdMark gc_id_mark(data._task->gc_id());
   log_develop_trace(gc, workgang)("Running work gang: %s task: %s worker: %u", name(), data._task->name(), data._worker_id);

   data._task->work(data._worker_id);

   log_develop_trace(gc, workgang)("Finished work gang: %s task: %s worker: %u thread: " PTR_FORMAT,
                                   name(), data._task->name(), data._worker_id, p2i(Thread::current()));
 }

 void GangWorker::loop() {
   while (true) {
     WorkData data = wait_for_task();

     run_task(data);

     signal_task_done();
   }
 }

 // *** WorkGangBarrierSync

 WorkGangBarrierSync::WorkGangBarrierSync()
   : _monitor(Mutex::safepoint, "work gang barrier sync", true,
              Monitor::_safepoint_check_never),
     _n_workers(0), _n_completed(0), _should_reset(false), _aborted(false) {
 }

 WorkGangBarrierSync::WorkGangBarrierSync(uint n_workers, const char* name)
   : _monitor(Mutex::safepoint, name, true, Monitor::_safepoint_check_never),
     _n_workers(n_workers), _n_completed(0), _should_reset(false), _aborted(false) {
 }

 void WorkGangBarrierSync::set_n_workers(uint n_workers) {
   _n_workers    = n_workers;
   _n_completed  = 0;
   _should_reset = false;
   _aborted      = false;
 }

 bool WorkGangBarrierSync::enter() {
   MutexLockerEx x(monitor(), Mutex::_no_safepoint_check_flag);
   if (should_reset()) {
     // The should_reset() was set and we are the first worker to enter
     // the sync barrier. We will zero the n_completed() count which
     // effectively resets the barrier.
     zero_completed();
     set_should_reset(false);
   }
   inc_completed();
   if (n_completed() == n_workers()) {
     // At this point we would like to reset the barrier to be ready in
     // case it is used again. However, we cannot set n_completed() to
     // 0, even after the notify_all(), given that some other workers
     // might still be waiting for n_completed() to become ==
     // n_workers(). So, if we set n_completed() to 0, those workers
     // will get stuck (as they will wake up, see that n_completed() !=
     // n_workers() and go back to sleep). Instead, we raise the
     // should_reset() flag and the barrier will be reset the first
     // time a worker enters it again.
     set_should_reset(true);
     monitor()->notify_all();
   } else {
     while (n_completed() != n_workers() && !aborted()) {
       monitor()->wait(/* no_safepoint_check */ true);
     }
   }
   return !aborted();
 }

 void WorkGangBarrierSync::abort() {
   MutexLockerEx x(monitor(), Mutex::_no_safepoint_check_flag);
   set_aborted();
   monitor()->notify_all();
 }

 // SubTasksDone functions.

 SubTasksDone::SubTasksDone(uint n) :
   _n_tasks(n), _tasks(NULL) {
   _tasks = NEW_C_HEAP_ARRAY(uint, n, mtInternal);
   guarantee(_tasks != NULL, "alloc failure");
   clear();
 }

 bool SubTasksDone::valid() {
   return _tasks != NULL;
 }

 void SubTasksDone::clear() {
   for (uint i = 0; i < _n_tasks; i++) {
     _tasks[i] = 0;
   }
   _threads_completed = 0;
 #ifdef ASSERT
   _claimed = 0;
 #endif
 }

 bool SubTasksDone::is_task_claimed(uint t) {
   assert(t < _n_tasks, "bad task id.");
   uint old = _tasks[t];
   if (old == 0) {
     old = Atomic::cmpxchg(1u, &_tasks[t], 0u);
   }
   bool res = old != 0;
 #ifdef ASSERT
   if (!res) {
     assert(_claimed < _n_tasks, "Too many tasks claimed; missing clear?");
     Atomic::inc(&_claimed);
   }
 #endif
   return res;
 }

 void SubTasksDone::all_tasks_completed(uint n_threads) {
   uint observed = _threads_completed;
   uint old;
   do {
     old = observed;
     observed = Atomic::cmpxchg(old+1, &_threads_completed, old);
   } while (observed != old);
   // If this was the last thread checking in, clear the tasks.
   uint adjusted_thread_count = (n_threads == 0 ? 1 : n_threads);
   if (observed + 1 == adjusted_thread_count) {
     clear();
   }
 }


 SubTasksDone::~SubTasksDone() {
   if (_tasks != NULL) FREE_C_HEAP_ARRAY(jint, _tasks);
 }

 // *** SequentialSubTasksDone

 void SequentialSubTasksDone::clear() {
   _n_tasks   = _n_claimed   = 0;
   _n_threads = _n_completed = 0;
 }

 bool SequentialSubTasksDone::valid() {
   return _n_threads > 0;
 }

 bool SequentialSubTasksDone::is_task_claimed(uint& t) {
   t = _n_claimed;
   while (t < _n_tasks) {
     uint res = Atomic::cmpxchg(t+1, &_n_claimed, t);
     if (res == t) {
       return false;
     }
     t = res;
   }
   return true;
 }

 bool SequentialSubTasksDone::all_tasks_completed() {
   uint complete = _n_completed;
   while (true) {
     uint res = Atomic::cmpxchg(complete+1, &_n_completed, complete);
     if (res == complete) {
       break;
     }
     complete = res;
   }
   if (complete+1 == _n_threads) {
     clear();
     return true;
   }
   return false;
 }
	/*
	* Copyright (c) 2001, 2018, Oracle and/or its affiliates. All rights reserved.
	* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
	*
	* This code is free software; you can redistribute it and/or modify it
	* under the terms of the GNU General Public License version 2 only, as
	* published by the Free Software Foundation.
	*
	* This code 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 General Public License
	* version 2 for more details (a copy is included in the LICENSE file that
	* accompanied this code).
	*
	* You should have received a copy of the GNU General Public License version
	* 2 along with this work; if not, write to the Free Software Foundation,
	* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
	*
	* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
	* or visit www.oracle.com if you need additional information or have any
	* questions.
	*
	*/

	#include "precompiled.hpp"
	#include "gc/shared/gcId.hpp"
	#include "gc/shared/workgroup.hpp"
	#include "gc/shared/workerManager.hpp"
	#include "memory/allocation.hpp"
	#include "memory/allocation.inline.hpp"
	#include "memory/iterator.hpp"
	#include "runtime/atomic.hpp"
	#include "runtime/os.hpp"
	#include "runtime/semaphore.hpp"
	#include "runtime/thread.inline.hpp"

	// Definitions of WorkGang methods.

	// The current implementation will exit if the allocation
	// of any worker fails.
	void AbstractWorkGang::initialize_workers() {
	log_develop_trace(gc, workgang)("Constructing work gang %s with %u threads", name(), total_workers());
	_workers = NEW_C_HEAP_ARRAY(AbstractGangWorker*, total_workers(), mtInternal);
	if (_workers == NULL) {
	vm_exit_out_of_memory(0, OOM_MALLOC_ERROR, "Cannot create GangWorker array.");
	}

	add_workers(true);
	}


	AbstractGangWorker* AbstractWorkGang::install_worker(uint worker_id) {
	AbstractGangWorker* new_worker = allocate_worker(worker_id);
	set_thread(worker_id, new_worker);
	return new_worker;
	}

	void AbstractWorkGang::add_workers(bool initializing) {
	add_workers(_active_workers, initializing);
	}

	void AbstractWorkGang::add_workers(uint active_workers, bool initializing) {

	os::ThreadType worker_type;
	if (are_ConcurrentGC_threads()) {
	worker_type = os::cgc_thread;
	} else {
	worker_type = os::pgc_thread;
	}
	uint previous_created_workers = _created_workers;

	_created_workers = WorkerManager::add_workers(this,
	active_workers,
	_total_workers,
	_created_workers,
	worker_type,
	initializing);
	_active_workers = MIN2(_created_workers, _active_workers);

	WorkerManager::log_worker_creation(this, previous_created_workers, _active_workers, _created_workers, initializing);
	}

	AbstractGangWorker* AbstractWorkGang::worker(uint i) const {
	// Array index bounds checking.
	AbstractGangWorker* result = NULL;
	assert(_workers != NULL, "No workers for indexing");
	assert(i < total_workers(), "Worker index out of bounds");
	result = _workers[i];
	assert(result != NULL, "Indexing to null worker");
	return result;
	}

	void AbstractWorkGang::print_worker_threads_on(outputStream* st) const {
	uint workers = created_workers();
	for (uint i = 0; i < workers; i++) {
	worker(i)->print_on(st);
	st->cr();
	}
	}

	void AbstractWorkGang::threads_do(ThreadClosure* tc) const {
	assert(tc != NULL, "Null ThreadClosure");
	uint workers = created_workers();
	for (uint i = 0; i < workers; i++) {
	tc->do_thread(worker(i));
	}
	}

	// WorkGang dispatcher implemented with semaphores.
	//
	// Semaphores don't require the worker threads to re-claim the lock when they wake up.
	// This helps lowering the latency when starting and stopping the worker threads.
	class SemaphoreGangTaskDispatcher : public GangTaskDispatcher {
	// The task currently being dispatched to the GangWorkers.
	AbstractGangTask* _task;

	volatile uint _started;
	volatile uint _not_finished;

	// Semaphore used to start the GangWorkers.
	Semaphore* _start_semaphore;
	// Semaphore used to notify the coordinator that all workers are done.
	Semaphore* _end_semaphore;

	public:
	SemaphoreGangTaskDispatcher() :
	_task(NULL),
	_started(0),
	_not_finished(0),
	_start_semaphore(new Semaphore()),
	_end_semaphore(new Semaphore())
	{ }

	~SemaphoreGangTaskDispatcher() {
	delete _start_semaphore;
	delete _end_semaphore;
	}

	void coordinator_execute_on_workers(AbstractGangTask* task, uint num_workers) {
	// No workers are allowed to read the state variables until they have been signaled.
	_task = task;
	_not_finished = num_workers;

	// Dispatch 'num_workers' number of tasks.
	_start_semaphore->signal(num_workers);

	// Wait for the last worker to signal the coordinator.
	_end_semaphore->wait();

	// No workers are allowed to read the state variables after the coordinator has been signaled.
	assert(_not_finished == 0, "%d not finished workers?", _not_finished);
	_task = NULL;
	_started = 0;

	}

	WorkData worker_wait_for_task() {
	// Wait for the coordinator to dispatch a task.
	_start_semaphore->wait();

	uint num_started = Atomic::add(1u, &_started);

	// Subtract one to get a zero-indexed worker id.
	uint worker_id = num_started - 1;

	return WorkData(_task, worker_id);
	}

	void worker_done_with_task() {
	// Mark that the worker is done with the task.
	// The worker is not allowed to read the state variables after this line.
	uint not_finished = Atomic::sub(1u, &_not_finished);

	// The last worker signals to the coordinator that all work is completed.
	if (not_finished == 0) {
	_end_semaphore->signal();
	}
	}
	};

	class MutexGangTaskDispatcher : public GangTaskDispatcher {
	AbstractGangTask* _task;

	volatile uint _started;
	volatile uint _finished;
	volatile uint _num_workers;

	Monitor* _monitor;

	public:
	MutexGangTaskDispatcher()
	: _task(NULL),
	_monitor(new Monitor(Monitor::leaf, "WorkGang dispatcher lock", false, Monitor::_safepoint_check_never)),
	_started(0),
	_finished(0),
	_num_workers(0) {}

	~MutexGangTaskDispatcher() {
	delete _monitor;
	}

	void coordinator_execute_on_workers(AbstractGangTask* task, uint num_workers) {
	MutexLockerEx ml(_monitor, Mutex::_no_safepoint_check_flag);

	_task = task;
	_num_workers = num_workers;

	// Tell the workers to get to work.
	_monitor->notify_all();

	// Wait for them to finish.
	while (_finished < _num_workers) {
	_monitor->wait(/* no_safepoint_check */ true);
	}

	_task = NULL;
	_num_workers = 0;
	_started = 0;
	_finished = 0;
	}

	WorkData worker_wait_for_task() {
	MonitorLockerEx ml(_monitor, Mutex::_no_safepoint_check_flag);

	while (_num_workers == 0 \|\| _started == _num_workers) {
	_monitor->wait(/* no_safepoint_check */ true);
	}

	_started++;

	// Subtract one to get a zero-indexed worker id.
	uint worker_id = _started - 1;

	return WorkData(_task, worker_id);
	}

	void worker_done_with_task() {
	MonitorLockerEx ml(_monitor, Mutex::_no_safepoint_check_flag);

	_finished++;

	if (_finished == _num_workers) {
	// This will wake up all workers and not only the coordinator.
	_monitor->notify_all();
	}
	}
	};

	static GangTaskDispatcher* create_dispatcher() {
	if (UseSemaphoreGCThreadsSynchronization) {
	return new SemaphoreGangTaskDispatcher();
	}

	return new MutexGangTaskDispatcher();
	}

	WorkGang::WorkGang(const char* name,
	uint workers,
	bool are_GC_task_threads,
	bool are_ConcurrentGC_threads) :
	AbstractWorkGang(name, workers, are_GC_task_threads, are_ConcurrentGC_threads),
	_dispatcher(create_dispatcher())
	{ }

	WorkGang::~WorkGang() {
	delete _dispatcher;
	}

	AbstractGangWorker* WorkGang::allocate_worker(uint worker_id) {
	return new GangWorker(this, worker_id);
	}

	void WorkGang::run_task(AbstractGangTask* task) {
	run_task(task, active_workers());
	}

	void WorkGang::run_task(AbstractGangTask* task, uint num_workers) {
	guarantee(num_workers <= total_workers(),
	"Trying to execute task %s with %u workers which is more than the amount of total workers %u.",
	task->name(), num_workers, total_workers());
	guarantee(num_workers > 0, "Trying to execute task %s with zero workers", task->name());
	uint old_num_workers = _active_workers;
	update_active_workers(num_workers);
	_dispatcher->coordinator_execute_on_workers(task, num_workers);
	update_active_workers(old_num_workers);
	}

	AbstractGangWorker::AbstractGangWorker(AbstractWorkGang* gang, uint id) {
	_gang = gang;
	set_id(id);
	set_name("%s#%d", gang->name(), id);
	}

	void AbstractGangWorker::run() {
	initialize();
	loop();
	}

	void AbstractGangWorker::initialize() {
	this->initialize_named_thread();
	assert(_gang != NULL, "No gang to run in");
	os::set_priority(this, NearMaxPriority);
	log_develop_trace(gc, workgang)("Running gang worker for gang %s id %u", gang()->name(), id());
	// The VM thread should not execute here because MutexLocker's are used
	// as (opposed to MutexLockerEx's).
	assert(!Thread::current()->is_VM_thread(), "VM thread should not be part"
	" of a work gang");
	}

	bool AbstractGangWorker::is_GC_task_thread() const {
	return gang()->are_GC_task_threads();
	}

	bool AbstractGangWorker::is_ConcurrentGC_thread() const {
	return gang()->are_ConcurrentGC_threads();
	}

	void AbstractGangWorker::print_on(outputStream* st) const {
	st->print("\"%s\" ", name());
	Thread::print_on(st);
	st->cr();
	}

	WorkData GangWorker::wait_for_task() {
	return gang()->dispatcher()->worker_wait_for_task();
	}

	void GangWorker::signal_task_done() {
	gang()->dispatcher()->worker_done_with_task();
	}

	void GangWorker::run_task(WorkData data) {
	GCIdMark gc_id_mark(data._task->gc_id());
	log_develop_trace(gc, workgang)("Running work gang: %s task: %s worker: %u", name(), data._task->name(), data._worker_id);

	data._task->work(data._worker_id);

	log_develop_trace(gc, workgang)("Finished work gang: %s task: %s worker: %u thread: " PTR_FORMAT,
	name(), data._task->name(), data._worker_id, p2i(Thread::current()));
	}

	void GangWorker::loop() {
	while (true) {
	WorkData data = wait_for_task();

	run_task(data);

	signal_task_done();
	}
	}

	// *** WorkGangBarrierSync

	WorkGangBarrierSync::WorkGangBarrierSync()
	: _monitor(Mutex::safepoint, "work gang barrier sync", true,
	Monitor::_safepoint_check_never),
	_n_workers(0), _n_completed(0), _should_reset(false), _aborted(false) {
	}

	WorkGangBarrierSync::WorkGangBarrierSync(uint n_workers, const char* name)
	: _monitor(Mutex::safepoint, name, true, Monitor::_safepoint_check_never),
	_n_workers(n_workers), _n_completed(0), _should_reset(false), _aborted(false) {
	}

	void WorkGangBarrierSync::set_n_workers(uint n_workers) {
	_n_workers = n_workers;
	_n_completed = 0;
	_should_reset = false;
	_aborted = false;
	}

	bool WorkGangBarrierSync::enter() {
	MutexLockerEx x(monitor(), Mutex::_no_safepoint_check_flag);
	if (should_reset()) {
	// The should_reset() was set and we are the first worker to enter
	// the sync barrier. We will zero the n_completed() count which
	// effectively resets the barrier.
	zero_completed();
	set_should_reset(false);
	}
	inc_completed();
	if (n_completed() == n_workers()) {
	// At this point we would like to reset the barrier to be ready in
	// case it is used again. However, we cannot set n_completed() to
	// 0, even after the notify_all(), given that some other workers
	// might still be waiting for n_completed() to become ==
	// n_workers(). So, if we set n_completed() to 0, those workers
	// will get stuck (as they will wake up, see that n_completed() !=
	// n_workers() and go back to sleep). Instead, we raise the
	// should_reset() flag and the barrier will be reset the first
	// time a worker enters it again.
	set_should_reset(true);
	monitor()->notify_all();
	} else {
	while (n_completed() != n_workers() && !aborted()) {
	monitor()->wait(/* no_safepoint_check */ true);
	}
	}
	return !aborted();
	}

	void WorkGangBarrierSync::abort() {
	MutexLockerEx x(monitor(), Mutex::_no_safepoint_check_flag);
	set_aborted();
	monitor()->notify_all();
	}

	// SubTasksDone functions.

	SubTasksDone::SubTasksDone(uint n) :
	_n_tasks(n), _tasks(NULL) {
	_tasks = NEW_C_HEAP_ARRAY(uint, n, mtInternal);
	guarantee(_tasks != NULL, "alloc failure");
	clear();
	}

	bool SubTasksDone::valid() {
	return _tasks != NULL;
	}

	void SubTasksDone::clear() {
	for (uint i = 0; i < _n_tasks; i++) {
	_tasks[i] = 0;
	}
	_threads_completed = 0;
	#ifdef ASSERT
	_claimed = 0;
	#endif
	}

	bool SubTasksDone::is_task_claimed(uint t) {
	assert(t < _n_tasks, "bad task id.");
	uint old = _tasks[t];
	if (old == 0) {
	old = Atomic::cmpxchg(1u, &_tasks[t], 0u);
	}
	bool res = old != 0;
	#ifdef ASSERT
	if (!res) {
	assert(_claimed < _n_tasks, "Too many tasks claimed; missing clear?");
	Atomic::inc(&_claimed);
	}
	#endif
	return res;
	}

	void SubTasksDone::all_tasks_completed(uint n_threads) {
	uint observed = _threads_completed;
	uint old;
	do {
	old = observed;
	observed = Atomic::cmpxchg(old+1, &_threads_completed, old);
	} while (observed != old);
	// If this was the last thread checking in, clear the tasks.
	uint adjusted_thread_count = (n_threads == 0 ? 1 : n_threads);
	if (observed + 1 == adjusted_thread_count) {
	clear();
	}
	}


	SubTasksDone::~SubTasksDone() {
	if (_tasks != NULL) FREE_C_HEAP_ARRAY(jint, _tasks);
	}

	// *** SequentialSubTasksDone

	void SequentialSubTasksDone::clear() {
	_n_tasks = _n_claimed = 0;
	_n_threads = _n_completed = 0;
	}

	bool SequentialSubTasksDone::valid() {
	return _n_threads > 0;
	}

	bool SequentialSubTasksDone::is_task_claimed(uint& t) {
	t = _n_claimed;
	while (t < _n_tasks) {
	uint res = Atomic::cmpxchg(t+1, &_n_claimed, t);
	if (res == t) {
	return false;
	}
	t = res;
	}
	return true;
	}

	bool SequentialSubTasksDone::all_tasks_completed() {
	uint complete = _n_completed;
	while (true) {
	uint res = Atomic::cmpxchg(complete+1, &_n_completed, complete);
	if (res == complete) {
	break;
	}
	complete = res;
	}
	if (complete+1 == _n_threads) {
	clear();
	return true;
	}
	return false;
	}