runtime/vm/thread_registry.cc - sdk.git - Git at Google

 // Copyright (c) 2015, the Dart project authors.  Please see the AUTHORS file
 // for details. All rights reserved. Use of this source code is governed by a
 // BSD-style license that can be found in the LICENSE file.

 #include "vm/thread_registry.h"

 #include "vm/json_stream.h"
 #include "vm/lockers.h"

 namespace dart {

 ThreadRegistry::~ThreadRegistry() {
   // Go over the free thread list and delete the thread objects.
   {
     MonitorLocker ml(threads_lock());
     // At this point the active list should be empty.
     ASSERT(active_list_ == nullptr);

     // Now delete all the threads in the free list.
     while (free_list_ != nullptr) {
       Thread* thread = free_list_;
       free_list_ = thread->next_;
       delete thread;
     }
   }
 }

 Thread* ThreadRegistry::GetFreeThreadLocked(bool is_vm_isolate) {
   ASSERT(threads_lock()->IsOwnedByCurrentThread());
   Thread* thread = GetFromFreelistLocked(is_vm_isolate);
   ASSERT(thread->api_top_scope() == nullptr);
   // Now add this Thread to the active list for the isolate.
   AddToActiveListLocked(thread);
   return thread;
 }

 void ThreadRegistry::ReturnThreadLocked(Thread* thread) {
   ASSERT(threads_lock()->IsOwnedByCurrentThread());
   // Remove thread from the active list for the isolate.
   RemoveFromActiveListLocked(thread);
   ReturnToFreelistLocked(thread);
 }

 void ThreadRegistry::VisitObjectPointers(
     IsolateGroup* isolate_group_of_interest,
     ObjectPointerVisitor* visitor,
     ValidationPolicy validate_frames) {
   MonitorLocker ml(threads_lock());
   Thread* thread = active_list_;
   while (thread != nullptr) {
     if (thread->isolate_group() == isolate_group_of_interest) {
       // The mutator thread is visited by the isolate itself (see
       // [IsolateGroup::VisitStackPointers]).
       if (!thread->IsDartMutatorThread()) {
         thread->VisitObjectPointers(visitor, validate_frames);
       }
     }
     thread = thread->next_;
   }
 }

 void ThreadRegistry::ForEachThread(
     std::function<void(Thread* thread)> callback) {
   MonitorLocker ml(threads_lock());
   Thread* thread = active_list_;
   while (thread != nullptr) {
     callback(thread);
     thread = thread->next_;
   }
 }

 void ThreadRegistry::ReleaseStoreBuffers() {
   MonitorLocker ml(threads_lock());
   Thread* thread = active_list_;
   while (thread != nullptr) {
     if (!thread->BypassSafepoints()) {
       thread->ReleaseStoreBuffer();
     }
     thread = thread->next_;
   }
 }

 void ThreadRegistry::AcquireMarkingStacks() {
   MonitorLocker ml(threads_lock());
   Thread* thread = active_list_;
   while (thread != nullptr) {
     if (!thread->BypassSafepoints()) {
       thread->AcquireMarkingStacks();
     }
     thread = thread->next_;
   }
 }

 void ThreadRegistry::ReleaseMarkingStacks() {
   MonitorLocker ml(threads_lock());
   Thread* thread = active_list_;
   while (thread != nullptr) {
     if (!thread->BypassSafepoints()) {
       thread->ReleaseMarkingStacks();
       ASSERT(!thread->is_marking());
     }
     thread = thread->next_;
   }
 }

 void ThreadRegistry::FlushMarkingStacks() {
   MonitorLocker ml(threads_lock());
   Thread* thread = active_list_;
   while (thread != nullptr) {
     if (!thread->BypassSafepoints() && thread->is_marking()) {
       thread->FlushMarkingStacks();
       ASSERT(thread->is_marking());
     }
     thread = thread->next_;
   }
 }

 void ThreadRegistry::AddToActiveListLocked(Thread* thread) {
   ASSERT(thread != nullptr);
   ASSERT(threads_lock()->IsOwnedByCurrentThread());
   thread->next_ = active_list_;
   active_list_ = thread;
   active_isolates_count_.fetch_add(1);
 }

 void ThreadRegistry::RemoveFromActiveListLocked(Thread* thread) {
   ASSERT(thread != nullptr);
   ASSERT(threads_lock()->IsOwnedByCurrentThread());
   Thread* prev = nullptr;
   Thread* current = active_list_;
   while (current != nullptr) {
     if (current == thread) {
       if (prev == nullptr) {
         active_list_ = current->next_;
       } else {
         prev->next_ = current->next_;
       }
       active_isolates_count_.fetch_sub(1);
       break;
     }
     prev = current;
     current = current->next_;
   }
 }

 Thread* ThreadRegistry::GetFromFreelistLocked(bool is_vm_isolate) {
   ASSERT(threads_lock()->IsOwnedByCurrentThread());
   Thread* thread = nullptr;
   // Get thread structure from free list or create a new one.
   if (free_list_ == nullptr) {
     thread = new Thread(is_vm_isolate);
   } else {
     thread = free_list_;
     free_list_ = thread->next_;
   }
   return thread;
 }

 void ThreadRegistry::ReturnToFreelistLocked(Thread* thread) {
   ASSERT(thread != nullptr);
   ASSERT(thread->os_thread() == nullptr);
   ASSERT(thread->isolate_ == nullptr);
   ASSERT(thread->isolate_group_ == nullptr);
   ASSERT(thread->field_table_values_ == nullptr);
   ASSERT(thread->shared_field_table_values_ == nullptr);
   ASSERT(threads_lock()->IsOwnedByCurrentThread());
   // Add thread to the free list.
   thread->next_ = free_list_;
   free_list_ = thread;
 }

 }  // namespace dart
	// Copyright (c) 2015, the Dart project authors. Please see the AUTHORS file
	// for details. All rights reserved. Use of this source code is governed by a
	// BSD-style license that can be found in the LICENSE file.

	#include "vm/thread_registry.h"

	#include "vm/json_stream.h"
	#include "vm/lockers.h"

	namespace dart {

	ThreadRegistry::~ThreadRegistry() {
	// Go over the free thread list and delete the thread objects.
	{
	MonitorLocker ml(threads_lock());
	// At this point the active list should be empty.
	ASSERT(active_list_ == nullptr);

	// Now delete all the threads in the free list.
	while (free_list_ != nullptr) {
	Thread* thread = free_list_;
	free_list_ = thread->next_;
	delete thread;
	}
	}
	}

	Thread* ThreadRegistry::GetFreeThreadLocked(bool is_vm_isolate) {
	ASSERT(threads_lock()->IsOwnedByCurrentThread());
	Thread* thread = GetFromFreelistLocked(is_vm_isolate);
	ASSERT(thread->api_top_scope() == nullptr);
	// Now add this Thread to the active list for the isolate.
	AddToActiveListLocked(thread);
	return thread;
	}

	void ThreadRegistry::ReturnThreadLocked(Thread* thread) {
	ASSERT(threads_lock()->IsOwnedByCurrentThread());
	// Remove thread from the active list for the isolate.
	RemoveFromActiveListLocked(thread);
	ReturnToFreelistLocked(thread);
	}

	void ThreadRegistry::VisitObjectPointers(
	IsolateGroup* isolate_group_of_interest,
	ObjectPointerVisitor* visitor,
	ValidationPolicy validate_frames) {
	MonitorLocker ml(threads_lock());
	Thread* thread = active_list_;
	while (thread != nullptr) {
	if (thread->isolate_group() == isolate_group_of_interest) {
	// The mutator thread is visited by the isolate itself (see
	// [IsolateGroup::VisitStackPointers]).
	if (!thread->IsDartMutatorThread()) {
	thread->VisitObjectPointers(visitor, validate_frames);
	}
	}
	thread = thread->next_;
	}
	}

	void ThreadRegistry::ForEachThread(
	std::function<void(Thread* thread)> callback) {
	MonitorLocker ml(threads_lock());
	Thread* thread = active_list_;
	while (thread != nullptr) {
	callback(thread);
	thread = thread->next_;
	}
	}

	void ThreadRegistry::ReleaseStoreBuffers() {
	MonitorLocker ml(threads_lock());
	Thread* thread = active_list_;
	while (thread != nullptr) {
	if (!thread->BypassSafepoints()) {
	thread->ReleaseStoreBuffer();
	}
	thread = thread->next_;
	}
	}

	void ThreadRegistry::AcquireMarkingStacks() {
	MonitorLocker ml(threads_lock());
	Thread* thread = active_list_;
	while (thread != nullptr) {
	if (!thread->BypassSafepoints()) {
	thread->AcquireMarkingStacks();
	}
	thread = thread->next_;
	}
	}

	void ThreadRegistry::ReleaseMarkingStacks() {
	MonitorLocker ml(threads_lock());
	Thread* thread = active_list_;
	while (thread != nullptr) {
	if (!thread->BypassSafepoints()) {
	thread->ReleaseMarkingStacks();
	ASSERT(!thread->is_marking());
	}
	thread = thread->next_;
	}
	}

	void ThreadRegistry::FlushMarkingStacks() {
	MonitorLocker ml(threads_lock());
	Thread* thread = active_list_;
	while (thread != nullptr) {
	if (!thread->BypassSafepoints() && thread->is_marking()) {
	thread->FlushMarkingStacks();
	ASSERT(thread->is_marking());
	}
	thread = thread->next_;
	}
	}

	void ThreadRegistry::AddToActiveListLocked(Thread* thread) {
	ASSERT(thread != nullptr);
	ASSERT(threads_lock()->IsOwnedByCurrentThread());
	thread->next_ = active_list_;
	active_list_ = thread;
	active_isolates_count_.fetch_add(1);
	}

	void ThreadRegistry::RemoveFromActiveListLocked(Thread* thread) {
	ASSERT(thread != nullptr);
	ASSERT(threads_lock()->IsOwnedByCurrentThread());
	Thread* prev = nullptr;
	Thread* current = active_list_;
	while (current != nullptr) {
	if (current == thread) {
	if (prev == nullptr) {
	active_list_ = current->next_;
	} else {
	prev->next_ = current->next_;
	}
	active_isolates_count_.fetch_sub(1);
	break;
	}
	prev = current;
	current = current->next_;
	}
	}

	Thread* ThreadRegistry::GetFromFreelistLocked(bool is_vm_isolate) {
	ASSERT(threads_lock()->IsOwnedByCurrentThread());
	Thread* thread = nullptr;
	// Get thread structure from free list or create a new one.
	if (free_list_ == nullptr) {
	thread = new Thread(is_vm_isolate);
	} else {
	thread = free_list_;
	free_list_ = thread->next_;
	}
	return thread;
	}

	void ThreadRegistry::ReturnToFreelistLocked(Thread* thread) {
	ASSERT(thread != nullptr);
	ASSERT(thread->os_thread() == nullptr);
	ASSERT(thread->isolate_ == nullptr);
	ASSERT(thread->isolate_group_ == nullptr);
	ASSERT(thread->field_table_values_ == nullptr);
	ASSERT(thread->shared_field_table_values_ == nullptr);
	ASSERT(threads_lock()->IsOwnedByCurrentThread());
	// Add thread to the free list.
	thread->next_ = free_list_;
	free_list_ = thread;
	}

	} // namespace dart