runtime/vm/heap/safepoint.h - sdk.git - Git at Google

 // Copyright (c) 2016, 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.

 #ifndef RUNTIME_VM_HEAP_SAFEPOINT_H_
 #define RUNTIME_VM_HEAP_SAFEPOINT_H_

 #include "vm/globals.h"
 #include "vm/isolate.h"
 #include "vm/lockers.h"
 #include "vm/thread.h"
 #include "vm/thread_registry.h"
 #include "vm/thread_stack_resource.h"

 namespace dart {

 // A stack based scope that can be used to perform an operation after getting
 // all threads to a safepoint. At the end of the operation all the threads are
 // resumed.
 class SafepointOperationScope : public ThreadStackResource {
  protected:
   SafepointOperationScope(Thread* T, SafepointLevel level);
   ~SafepointOperationScope();

  private:
   SafepointLevel level_;

   DISALLOW_COPY_AND_ASSIGN(SafepointOperationScope);
 };

 // Gets all mutators to a safepoint where GC is allowed.
 class GcSafepointOperationScope : public SafepointOperationScope {
  public:
   explicit GcSafepointOperationScope(Thread* T)
       : SafepointOperationScope(T, SafepointLevel::kGC) {}
   ~GcSafepointOperationScope() {}

  private:
   DISALLOW_COPY_AND_ASSIGN(GcSafepointOperationScope);
 };

 // Gets all mutators to a safepoint where GC and Deopt is allowed.
 class DeoptSafepointOperationScope : public SafepointOperationScope {
  public:
   explicit DeoptSafepointOperationScope(Thread* T)
       : SafepointOperationScope(T, SafepointLevel::kGCAndDeopt) {}
   ~DeoptSafepointOperationScope() {}

  private:
   DISALLOW_COPY_AND_ASSIGN(DeoptSafepointOperationScope);
 };

 // Gets all mutators to a safepoint where GC, Deopt and Reload is allowed.
 class ReloadSafepointOperationScope : public SafepointOperationScope {
  public:
   explicit ReloadSafepointOperationScope(Thread* T)
       : SafepointOperationScope(T, SafepointLevel::kGCAndDeoptAndReload) {}
   ~ReloadSafepointOperationScope() {}

  private:
   DISALLOW_COPY_AND_ASSIGN(ReloadSafepointOperationScope);
 };

 // A stack based scope that can be used to perform an operation after getting
 // all threads to a safepoint. At the end of the operation all the threads are
 // resumed. Allocations in the scope will force heap growth.
 class ForceGrowthSafepointOperationScope : public ThreadStackResource {
  public:
   ForceGrowthSafepointOperationScope(Thread* T, SafepointLevel level);
   ~ForceGrowthSafepointOperationScope();

  private:
   SafepointLevel level_;
   bool current_growth_controller_state_;

   DISALLOW_COPY_AND_ASSIGN(ForceGrowthSafepointOperationScope);
 };

 // Implements handling of safepoint operations for all threads in an
 // IsolateGroup.
 class SafepointHandler {
  public:
   explicit SafepointHandler(IsolateGroup* I);
   ~SafepointHandler();

   void EnterSafepointUsingLock(Thread* T);
   void ExitSafepointUsingLock(Thread* T);
   void BlockForSafepoint(Thread* T);

   // The innermost safepoint operation this thread owns
   //
   // Returns `SafepointLevel::kNone` if the current thread doesn't own any
   // safepoint. Otherwise returns the innermost safepoint level of the current
   // thread.
   //
   // * Will return SafepointLevel::kDeoptAndGC for
   //
   //   DeoptSafepointOperationScope sp;
   //
   // * Will return SafepointLevel::kGC for
   //
   //   DeoptSafepointOperationScope sp1;
   //   GcSafepointOperationScope sp2;
   //
   SafepointLevel InnermostSafepointOperation(
       const Thread* current_thread) const;

   bool AnySafepointInProgressLocked() {
     for (intptr_t level = 0; level < SafepointLevel::kNumLevels; ++level) {
       if (handlers_[level]->SafepointInProgress()) {
         return true;
       }
     }
     return false;
   }

  private:
   class LevelHandler {
    public:
     LevelHandler(IsolateGroup* isolate_group, SafepointLevel level)
         : isolate_group_(isolate_group), level_(level) {}

     bool SafepointInProgress() const {
       ASSERT(threads_lock()->IsOwnedByCurrentThread());
       ASSERT((operation_count_ > 0) == (owner_ != nullptr));
       return ((operation_count_ > 0) && (owner_ != nullptr));
     }
     void SetSafepointInProgress(Thread* T) {
       ASSERT(threads_lock()->IsOwnedByCurrentThread());
       ASSERT(owner_ == nullptr);
       ASSERT(operation_count_ == 0);
       operation_count_ = 1;
       owner_ = T;
     }
     void ResetSafepointInProgress(Thread* T) {
       ASSERT(threads_lock()->IsOwnedByCurrentThread());
       ASSERT(owner_ == T);
       ASSERT(operation_count_ == 1);
       ASSERT(num_threads_not_parked_ == 0);
       operation_count_ = 0;
       owner_ = nullptr;
     }
     void NotifyWeAreParked(Thread* T);

     IsolateGroup* isolate_group() const { return isolate_group_; }
     Monitor* threads_lock() const {
       return isolate_group_->thread_registry()->threads_lock();
     }

    private:
     friend class SafepointHandler;

     // Helper methods for [SafepointThreads]
     void NotifyThreadsToGetToSafepointLevel(
         Thread* T,
         MallocGrowableArray<Dart_Port>* oob_isolates);
     void WaitUntilThreadsReachedSafepointLevel();

     // Helper methods for [ResumeThreads]
     void NotifyThreadsToContinue(Thread* T);

     IsolateGroup* isolate_group_;
     SafepointLevel level_;

     // Monitor used by thread initiating a safepoint operation to track threads
     // not at a safepoint and wait for these threads to reach a safepoint.
     Monitor parked_lock_;

     // If a safepoint operation is currently in progress, this field contains
     // the thread that initiated the safepoint operation, otherwise it is
     // nullptr.
     std::atomic<Thread*> owner_ = nullptr;

     // The number of nested safepoint operations currently held.
     std::atomic<int32_t> operation_count_ = 0;

     // Count the number of threads the currently in-progress safepoint operation
     // is waiting for to check-in.
     int32_t num_threads_not_parked_ = 0;
   };

   void SafepointThreads(Thread* T, SafepointLevel level);
   void ResumeThreads(Thread* T, SafepointLevel level);

   // Helper methods for [SafepointThreads]
   void AssertWeOwnLowerLevelSafepoints(Thread* T, SafepointLevel level);
   void AssertWeDoNotOwnLowerLevelSafepoints(Thread* T, SafepointLevel level);
   void AcquireLowerLevelSafepoints(Thread* T, SafepointLevel level);

   // Helper methods for [ResumeThreads]
   void ReleaseLowerLevelSafepoints(Thread* T, SafepointLevel level);

   void EnterSafepointLocked(Thread* T, MonitorLocker* tl, SafepointLevel level);
   void ExitSafepointLocked(Thread* T, MonitorLocker* tl, SafepointLevel level);

   IsolateGroup* isolate_group() const { return isolate_group_; }
   Monitor* threads_lock() const {
     return isolate_group_->thread_registry()->threads_lock();
   }

   IsolateGroup* isolate_group_;

   LevelHandler* handlers_[SafepointLevel::kNumLevels];

   friend class Isolate;
   friend class IsolateGroup;
   friend class SafepointOperationScope;
   friend class ForceGrowthSafepointOperationScope;
   friend class HeapIterationScope;
 };

 /*
  * Set of StackResource classes to track thread execution state transitions:
  *
  * kThreadInGenerated transitioning to
  *   ==> kThreadInVM:
  *       - set_execution_state(kThreadInVM).
  *       - block if safepoint is requested.
  *   ==> kThreadInNative:
  *       - set_execution_state(kThreadInNative).
  *       - EnterSafepoint().
  *   ==> kThreadInBlockedState:
  *       - Invalid transition
  *
  * kThreadInVM transitioning to
  *   ==> kThreadInGenerated
  *       - set_execution_state(kThreadInGenerated).
  *   ==> kThreadInNative
  *       - set_execution_state(kThreadInNative).
  *       - EnterSafepoint.
  *   ==> kThreadInBlockedState
  *       - set_execution_state(kThreadInBlockedState).
  *       - EnterSafepoint.
  *
  * kThreadInNative transitioning to
  *   ==> kThreadInGenerated
  *       - ExitSafepoint.
  *       - set_execution_state(kThreadInGenerated).
  *   ==> kThreadInVM
  *       - ExitSafepoint.
  *       - set_execution_state(kThreadInVM).
  *   ==> kThreadInBlocked
  *       - Invalid transition.
  *
  * kThreadInBlocked transitioning to
  *   ==> kThreadInVM
  *       - ExitSafepoint.
  *       - set_execution_state(kThreadInVM).
  *   ==> kThreadInNative
  *       - Invalid transition.
  *   ==> kThreadInGenerated
  *       - Invalid transition.
  */
 class TransitionSafepointState : public ThreadStackResource {
  public:
   explicit TransitionSafepointState(Thread* T) : ThreadStackResource(T) {}
   ~TransitionSafepointState() {}

   SafepointHandler* handler() const {
     ASSERT(thread()->isolate() != nullptr);
     ASSERT(thread()->isolate()->safepoint_handler() != nullptr);
     return thread()->isolate()->safepoint_handler();
   }

  private:
   DISALLOW_COPY_AND_ASSIGN(TransitionSafepointState);
 };

 // TransitionGeneratedToVM is used to transition the safepoint state of a
 // thread from "running generated code" to "running vm code" and ensures
 // that the state is reverted back to "running generated code" when
 // exiting the scope/frame.
 class TransitionGeneratedToVM : public TransitionSafepointState {
  public:
   explicit TransitionGeneratedToVM(Thread* T) : TransitionSafepointState(T) {
     ASSERT(T == Thread::Current());
     ASSERT(T->execution_state() == Thread::kThreadInGenerated);
     T->set_execution_state(Thread::kThreadInVM);
     // Fast check to see if a safepoint is requested or not.
     // We do the more expensive operation of blocking the thread
     // only if a safepoint is requested.
     if (T->IsSafepointRequested()) {
       T->BlockForSafepoint();
     }
   }

   ~TransitionGeneratedToVM() {
     ASSERT(thread()->execution_state() == Thread::kThreadInVM);
     thread()->set_execution_state(Thread::kThreadInGenerated);
   }

  private:
   DISALLOW_COPY_AND_ASSIGN(TransitionGeneratedToVM);
 };

 // TransitionGeneratedToNative is used to transition the safepoint state of a
 // thread from "running generated code" to "running native code" and ensures
 // that the state is reverted back to "running generated code" when
 // exiting the scope/frame.
 class TransitionGeneratedToNative : public TransitionSafepointState {
  public:
   explicit TransitionGeneratedToNative(Thread* T)
       : TransitionSafepointState(T) {
     // Native code is considered to be at a safepoint and so we mark it
     // accordingly.
     ASSERT(T->execution_state() == Thread::kThreadInGenerated);
     T->set_execution_state(Thread::kThreadInNative);
     T->EnterSafepoint();
   }

   ~TransitionGeneratedToNative() {
     // We are returning to generated code and so we are not at a safepoint
     // anymore.
     ASSERT(thread()->execution_state() == Thread::kThreadInNative);
     thread()->ExitSafepoint();
     thread()->set_execution_state(Thread::kThreadInGenerated);
   }

  private:
   DISALLOW_COPY_AND_ASSIGN(TransitionGeneratedToNative);
 };

 // TransitionVMToBlocked is used to transition the safepoint state of a
 // thread from "running vm code" to "blocked on a monitor" and ensures
 // that the state is reverted back to "running vm code" when
 // exiting the scope/frame.
 class TransitionVMToBlocked : public TransitionSafepointState {
  public:
   explicit TransitionVMToBlocked(Thread* T) : TransitionSafepointState(T) {
     ASSERT(T->CanAcquireSafepointLocks());
     // A thread blocked on a monitor is considered to be at a safepoint.
     ASSERT(T->execution_state() == Thread::kThreadInVM);
     T->set_execution_state(Thread::kThreadInBlockedState);
     T->EnterSafepoint();
   }

   ~TransitionVMToBlocked() {
     // We are returning to vm code and so we are not at a safepoint anymore.
     ASSERT(thread()->execution_state() == Thread::kThreadInBlockedState);
     thread()->ExitSafepoint();
     thread()->set_execution_state(Thread::kThreadInVM);
   }

  private:
   DISALLOW_COPY_AND_ASSIGN(TransitionVMToBlocked);
 };

 // TransitionVMToNative is used to transition the safepoint state of a
 // thread from "running vm code" to "running native code" and ensures
 // that the state is reverted back to "running vm code" when
 // exiting the scope/frame.
 class TransitionVMToNative : public TransitionSafepointState {
  public:
   explicit TransitionVMToNative(Thread* T) : TransitionSafepointState(T) {
     // A thread running native code is considered to be at a safepoint.
     ASSERT(T->execution_state() == Thread::kThreadInVM);
     T->set_execution_state(Thread::kThreadInNative);
     T->EnterSafepoint();
   }

   ~TransitionVMToNative() {
     // We are returning to vm code and so we are not at a safepoint anymore.
     ASSERT(thread()->execution_state() == Thread::kThreadInNative);
     thread()->ExitSafepoint();
     thread()->set_execution_state(Thread::kThreadInVM);
   }

  private:
   DISALLOW_COPY_AND_ASSIGN(TransitionVMToNative);
 };

 // TransitionVMToGenerated is used to transition the safepoint state of a
 // thread from "running vm code" to "running generated code" and ensures
 // that the state is reverted back to "running vm code" when
 // exiting the scope/frame.
 class TransitionVMToGenerated : public TransitionSafepointState {
  public:
   explicit TransitionVMToGenerated(Thread* T) : TransitionSafepointState(T) {
     ASSERT(T == Thread::Current());
     ASSERT(T->execution_state() == Thread::kThreadInVM);
     T->set_execution_state(Thread::kThreadInGenerated);
   }

   ~TransitionVMToGenerated() {
     ASSERT(thread()->execution_state() == Thread::kThreadInGenerated);
     thread()->set_execution_state(Thread::kThreadInVM);
     // Fast check to see if a safepoint is requested or not.
     if (thread()->IsSafepointRequested()) {
       thread()->BlockForSafepoint();
     }
   }

  private:
   DISALLOW_COPY_AND_ASSIGN(TransitionVMToGenerated);
 };

 // TransitionNativeToVM is used to transition the safepoint state of a
 // thread from "running native code" to "running vm code" and ensures
 // that the state is reverted back to "running native code" when
 // exiting the scope/frame.
 class TransitionNativeToVM : public TransitionSafepointState {
  public:
   explicit TransitionNativeToVM(Thread* T) : TransitionSafepointState(T) {
     // We are about to execute vm code and so we are not at a safepoint anymore.
     ASSERT(T->execution_state() == Thread::kThreadInNative);
     if (T->no_callback_scope_depth() == 0) {
       T->ExitSafepoint();
     }
     T->set_execution_state(Thread::kThreadInVM);
   }

   ~TransitionNativeToVM() {
     // We are returning to native code and so we are at a safepoint.
     ASSERT(thread()->execution_state() == Thread::kThreadInVM);
     thread()->set_execution_state(Thread::kThreadInNative);
     if (thread()->no_callback_scope_depth() == 0) {
       thread()->EnterSafepoint();
     }
   }

  private:
   DISALLOW_COPY_AND_ASSIGN(TransitionNativeToVM);
 };

 // TransitionToGenerated is used to transition the safepoint state of a
 // thread from "running vm code" or "running native code" to
 // "running generated code" and ensures that the state is reverted back
 // to "running vm code" or "running native code" when exiting the
 // scope/frame.
 class TransitionToGenerated : public TransitionSafepointState {
  public:
   explicit TransitionToGenerated(Thread* T)
       : TransitionSafepointState(T), execution_state_(T->execution_state()) {
     ASSERT(T == Thread::Current());
     ASSERT((execution_state_ == Thread::kThreadInVM) ||
            (execution_state_ == Thread::kThreadInNative));
     if (execution_state_ == Thread::kThreadInNative) {
       T->ExitSafepoint();
     }
     T->set_execution_state(Thread::kThreadInGenerated);
   }

   ~TransitionToGenerated() {
     ASSERT(thread()->execution_state() == Thread::kThreadInGenerated);
     if (execution_state_ == Thread::kThreadInNative) {
       thread()->set_execution_state(Thread::kThreadInNative);
       thread()->EnterSafepoint();
     } else {
       ASSERT(execution_state_ == Thread::kThreadInVM);
       thread()->set_execution_state(Thread::kThreadInVM);
     }
   }

  private:
   uint32_t execution_state_;
   DISALLOW_COPY_AND_ASSIGN(TransitionToGenerated);
 };

 // TransitionToVM is used to transition the safepoint state of a
 // thread from "running native code" to "running vm code"
 // and ensures that the state is reverted back to "running native code"
 // when exiting the scope/frame.
 // This transition helper is mainly used in the error path of the
 // Dart API implementations where we sometimes do not have an explicit
 // transition set up.
 class TransitionToVM : public TransitionSafepointState {
  public:
   explicit TransitionToVM(Thread* T)
       : TransitionSafepointState(T), execution_state_(T->execution_state()) {
     ASSERT(T == Thread::Current());
     ASSERT((execution_state_ == Thread::kThreadInVM) ||
            (execution_state_ == Thread::kThreadInNative));
     if (execution_state_ == Thread::kThreadInNative) {
       T->ExitSafepoint();
       T->set_execution_state(Thread::kThreadInVM);
     }
     ASSERT(T->execution_state() == Thread::kThreadInVM);
   }

   ~TransitionToVM() {
     ASSERT(thread()->execution_state() == Thread::kThreadInVM);
     if (execution_state_ == Thread::kThreadInNative) {
       thread()->set_execution_state(Thread::kThreadInNative);
       thread()->EnterSafepoint();
     }
   }

  private:
   uint32_t execution_state_;
   DISALLOW_COPY_AND_ASSIGN(TransitionToVM);
 };

 // TransitionToNative is used to transition the safepoint state of a
 // thread from "running VM code" to "running native code"
 // and ensures that the state is reverted back to the initial state
 // when exiting the scope/frame.
 class TransitionToNative : public TransitionSafepointState {
  public:
   explicit TransitionToNative(Thread* T)
       : TransitionSafepointState(T), execution_state_(T->execution_state()) {
     ASSERT(T == Thread::Current());
     ASSERT((execution_state_ == Thread::kThreadInVM) ||
            (execution_state_ == Thread::kThreadInNative));
     if (execution_state_ == Thread::kThreadInVM) {
       T->set_execution_state(Thread::kThreadInNative);
       T->EnterSafepoint();
     }
     ASSERT(T->execution_state() == Thread::kThreadInNative);
   }

   ~TransitionToNative() {
     ASSERT(thread()->execution_state() == Thread::kThreadInNative);
     if (execution_state_ == Thread::kThreadInVM) {
       thread()->ExitSafepoint();
       thread()->set_execution_state(Thread::kThreadInVM);
     }
   }

  private:
   uint32_t execution_state_;
   DISALLOW_COPY_AND_ASSIGN(TransitionToNative);
 };

 }  // namespace dart

 #endif  // RUNTIME_VM_HEAP_SAFEPOINT_H_
	// Copyright (c) 2016, 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.

	#ifndef RUNTIME_VM_HEAP_SAFEPOINT_H_
	#define RUNTIME_VM_HEAP_SAFEPOINT_H_

	#include "vm/globals.h"
	#include "vm/isolate.h"
	#include "vm/lockers.h"
	#include "vm/thread.h"
	#include "vm/thread_registry.h"
	#include "vm/thread_stack_resource.h"

	namespace dart {

	// A stack based scope that can be used to perform an operation after getting
	// all threads to a safepoint. At the end of the operation all the threads are
	// resumed.
	class SafepointOperationScope : public ThreadStackResource {
	protected:
	SafepointOperationScope(Thread* T, SafepointLevel level);
	~SafepointOperationScope();

	private:
	SafepointLevel level_;

	DISALLOW_COPY_AND_ASSIGN(SafepointOperationScope);
	};

	// Gets all mutators to a safepoint where GC is allowed.
	class GcSafepointOperationScope : public SafepointOperationScope {
	public:
	explicit GcSafepointOperationScope(Thread* T)
	: SafepointOperationScope(T, SafepointLevel::kGC) {}
	~GcSafepointOperationScope() {}

	private:
	DISALLOW_COPY_AND_ASSIGN(GcSafepointOperationScope);
	};

	// Gets all mutators to a safepoint where GC and Deopt is allowed.
	class DeoptSafepointOperationScope : public SafepointOperationScope {
	public:
	explicit DeoptSafepointOperationScope(Thread* T)
	: SafepointOperationScope(T, SafepointLevel::kGCAndDeopt) {}
	~DeoptSafepointOperationScope() {}

	private:
	DISALLOW_COPY_AND_ASSIGN(DeoptSafepointOperationScope);
	};

	// Gets all mutators to a safepoint where GC, Deopt and Reload is allowed.
	class ReloadSafepointOperationScope : public SafepointOperationScope {
	public:
	explicit ReloadSafepointOperationScope(Thread* T)
	: SafepointOperationScope(T, SafepointLevel::kGCAndDeoptAndReload) {}
	~ReloadSafepointOperationScope() {}

	private:
	DISALLOW_COPY_AND_ASSIGN(ReloadSafepointOperationScope);
	};

	// A stack based scope that can be used to perform an operation after getting
	// all threads to a safepoint. At the end of the operation all the threads are
	// resumed. Allocations in the scope will force heap growth.
	class ForceGrowthSafepointOperationScope : public ThreadStackResource {
	public:
	ForceGrowthSafepointOperationScope(Thread* T, SafepointLevel level);
	~ForceGrowthSafepointOperationScope();

	private:
	SafepointLevel level_;
	bool current_growth_controller_state_;

	DISALLOW_COPY_AND_ASSIGN(ForceGrowthSafepointOperationScope);
	};

	// Implements handling of safepoint operations for all threads in an
	// IsolateGroup.
	class SafepointHandler {
	public:
	explicit SafepointHandler(IsolateGroup* I);
	~SafepointHandler();

	void EnterSafepointUsingLock(Thread* T);
	void ExitSafepointUsingLock(Thread* T);
	void BlockForSafepoint(Thread* T);

	// The innermost safepoint operation this thread owns
	//
	// Returns `SafepointLevel::kNone` if the current thread doesn't own any
	// safepoint. Otherwise returns the innermost safepoint level of the current
	// thread.
	//
	// * Will return SafepointLevel::kDeoptAndGC for
	//
	// DeoptSafepointOperationScope sp;
	//
	// * Will return SafepointLevel::kGC for
	//
	// DeoptSafepointOperationScope sp1;
	// GcSafepointOperationScope sp2;
	//
	SafepointLevel InnermostSafepointOperation(
	const Thread* current_thread) const;

	bool AnySafepointInProgressLocked() {
	for (intptr_t level = 0; level < SafepointLevel::kNumLevels; ++level) {
	if (handlers_[level]->SafepointInProgress()) {
	return true;
	}
	}
	return false;
	}

	private:
	class LevelHandler {
	public:
	LevelHandler(IsolateGroup* isolate_group, SafepointLevel level)
	: isolate_group_(isolate_group), level_(level) {}

	bool SafepointInProgress() const {
	ASSERT(threads_lock()->IsOwnedByCurrentThread());
	ASSERT((operation_count_ > 0) == (owner_ != nullptr));
	return ((operation_count_ > 0) && (owner_ != nullptr));
	}
	void SetSafepointInProgress(Thread* T) {
	ASSERT(threads_lock()->IsOwnedByCurrentThread());
	ASSERT(owner_ == nullptr);
	ASSERT(operation_count_ == 0);
	operation_count_ = 1;
	owner_ = T;
	}
	void ResetSafepointInProgress(Thread* T) {
	ASSERT(threads_lock()->IsOwnedByCurrentThread());
	ASSERT(owner_ == T);
	ASSERT(operation_count_ == 1);
	ASSERT(num_threads_not_parked_ == 0);
	operation_count_ = 0;
	owner_ = nullptr;
	}
	void NotifyWeAreParked(Thread* T);

	IsolateGroup* isolate_group() const { return isolate_group_; }
	Monitor* threads_lock() const {
	return isolate_group_->thread_registry()->threads_lock();
	}

	private:
	friend class SafepointHandler;

	// Helper methods for [SafepointThreads]
	void NotifyThreadsToGetToSafepointLevel(
	Thread* T,
	MallocGrowableArray<Dart_Port>* oob_isolates);
	void WaitUntilThreadsReachedSafepointLevel();

	// Helper methods for [ResumeThreads]
	void NotifyThreadsToContinue(Thread* T);

	IsolateGroup* isolate_group_;
	SafepointLevel level_;

	// Monitor used by thread initiating a safepoint operation to track threads
	// not at a safepoint and wait for these threads to reach a safepoint.
	Monitor parked_lock_;

	// If a safepoint operation is currently in progress, this field contains
	// the thread that initiated the safepoint operation, otherwise it is
	// nullptr.
	std::atomic<Thread*> owner_ = nullptr;

	// The number of nested safepoint operations currently held.
	std::atomic<int32_t> operation_count_ = 0;

	// Count the number of threads the currently in-progress safepoint operation
	// is waiting for to check-in.
	int32_t num_threads_not_parked_ = 0;
	};

	void SafepointThreads(Thread* T, SafepointLevel level);
	void ResumeThreads(Thread* T, SafepointLevel level);

	// Helper methods for [SafepointThreads]
	void AssertWeOwnLowerLevelSafepoints(Thread* T, SafepointLevel level);
	void AssertWeDoNotOwnLowerLevelSafepoints(Thread* T, SafepointLevel level);
	void AcquireLowerLevelSafepoints(Thread* T, SafepointLevel level);

	// Helper methods for [ResumeThreads]
	void ReleaseLowerLevelSafepoints(Thread* T, SafepointLevel level);

	void EnterSafepointLocked(Thread* T, MonitorLocker* tl, SafepointLevel level);
	void ExitSafepointLocked(Thread* T, MonitorLocker* tl, SafepointLevel level);

	IsolateGroup* isolate_group() const { return isolate_group_; }
	Monitor* threads_lock() const {
	return isolate_group_->thread_registry()->threads_lock();
	}

	IsolateGroup* isolate_group_;

	LevelHandler* handlers_[SafepointLevel::kNumLevels];

	friend class Isolate;
	friend class IsolateGroup;
	friend class SafepointOperationScope;
	friend class ForceGrowthSafepointOperationScope;
	friend class HeapIterationScope;
	};

	/*
	* Set of StackResource classes to track thread execution state transitions:
	*
	* kThreadInGenerated transitioning to
	* ==> kThreadInVM:
	* - set_execution_state(kThreadInVM).
	* - block if safepoint is requested.
	* ==> kThreadInNative:
	* - set_execution_state(kThreadInNative).
	* - EnterSafepoint().
	* ==> kThreadInBlockedState:
	* - Invalid transition
	*
	* kThreadInVM transitioning to
	* ==> kThreadInGenerated
	* - set_execution_state(kThreadInGenerated).
	* ==> kThreadInNative
	* - set_execution_state(kThreadInNative).
	* - EnterSafepoint.
	* ==> kThreadInBlockedState
	* - set_execution_state(kThreadInBlockedState).
	* - EnterSafepoint.
	*
	* kThreadInNative transitioning to
	* ==> kThreadInGenerated
	* - ExitSafepoint.
	* - set_execution_state(kThreadInGenerated).
	* ==> kThreadInVM
	* - ExitSafepoint.
	* - set_execution_state(kThreadInVM).
	* ==> kThreadInBlocked
	* - Invalid transition.
	*
	* kThreadInBlocked transitioning to
	* ==> kThreadInVM
	* - ExitSafepoint.
	* - set_execution_state(kThreadInVM).
	* ==> kThreadInNative
	* - Invalid transition.
	* ==> kThreadInGenerated
	* - Invalid transition.
	*/
	class TransitionSafepointState : public ThreadStackResource {
	public:
	explicit TransitionSafepointState(Thread* T) : ThreadStackResource(T) {}
	~TransitionSafepointState() {}

	SafepointHandler* handler() const {
	ASSERT(thread()->isolate() != nullptr);
	ASSERT(thread()->isolate()->safepoint_handler() != nullptr);
	return thread()->isolate()->safepoint_handler();
	}

	private:
	DISALLOW_COPY_AND_ASSIGN(TransitionSafepointState);
	};

	// TransitionGeneratedToVM is used to transition the safepoint state of a
	// thread from "running generated code" to "running vm code" and ensures
	// that the state is reverted back to "running generated code" when
	// exiting the scope/frame.
	class TransitionGeneratedToVM : public TransitionSafepointState {
	public:
	explicit TransitionGeneratedToVM(Thread* T) : TransitionSafepointState(T) {
	ASSERT(T == Thread::Current());
	ASSERT(T->execution_state() == Thread::kThreadInGenerated);
	T->set_execution_state(Thread::kThreadInVM);
	// Fast check to see if a safepoint is requested or not.
	// We do the more expensive operation of blocking the thread
	// only if a safepoint is requested.
	if (T->IsSafepointRequested()) {
	T->BlockForSafepoint();
	}
	}

	~TransitionGeneratedToVM() {
	ASSERT(thread()->execution_state() == Thread::kThreadInVM);
	thread()->set_execution_state(Thread::kThreadInGenerated);
	}

	private:
	DISALLOW_COPY_AND_ASSIGN(TransitionGeneratedToVM);
	};

	// TransitionGeneratedToNative is used to transition the safepoint state of a
	// thread from "running generated code" to "running native code" and ensures
	// that the state is reverted back to "running generated code" when
	// exiting the scope/frame.
	class TransitionGeneratedToNative : public TransitionSafepointState {
	public:
	explicit TransitionGeneratedToNative(Thread* T)
	: TransitionSafepointState(T) {
	// Native code is considered to be at a safepoint and so we mark it
	// accordingly.
	ASSERT(T->execution_state() == Thread::kThreadInGenerated);
	T->set_execution_state(Thread::kThreadInNative);
	T->EnterSafepoint();
	}

	~TransitionGeneratedToNative() {
	// We are returning to generated code and so we are not at a safepoint
	// anymore.
	ASSERT(thread()->execution_state() == Thread::kThreadInNative);
	thread()->ExitSafepoint();
	thread()->set_execution_state(Thread::kThreadInGenerated);
	}

	private:
	DISALLOW_COPY_AND_ASSIGN(TransitionGeneratedToNative);
	};

	// TransitionVMToBlocked is used to transition the safepoint state of a
	// thread from "running vm code" to "blocked on a monitor" and ensures
	// that the state is reverted back to "running vm code" when
	// exiting the scope/frame.
	class TransitionVMToBlocked : public TransitionSafepointState {
	public:
	explicit TransitionVMToBlocked(Thread* T) : TransitionSafepointState(T) {
	ASSERT(T->CanAcquireSafepointLocks());
	// A thread blocked on a monitor is considered to be at a safepoint.
	ASSERT(T->execution_state() == Thread::kThreadInVM);
	T->set_execution_state(Thread::kThreadInBlockedState);
	T->EnterSafepoint();
	}

	~TransitionVMToBlocked() {
	// We are returning to vm code and so we are not at a safepoint anymore.
	ASSERT(thread()->execution_state() == Thread::kThreadInBlockedState);
	thread()->ExitSafepoint();
	thread()->set_execution_state(Thread::kThreadInVM);
	}

	private:
	DISALLOW_COPY_AND_ASSIGN(TransitionVMToBlocked);
	};

	// TransitionVMToNative is used to transition the safepoint state of a
	// thread from "running vm code" to "running native code" and ensures
	// that the state is reverted back to "running vm code" when
	// exiting the scope/frame.
	class TransitionVMToNative : public TransitionSafepointState {
	public:
	explicit TransitionVMToNative(Thread* T) : TransitionSafepointState(T) {
	// A thread running native code is considered to be at a safepoint.
	ASSERT(T->execution_state() == Thread::kThreadInVM);
	T->set_execution_state(Thread::kThreadInNative);
	T->EnterSafepoint();
	}

	~TransitionVMToNative() {
	// We are returning to vm code and so we are not at a safepoint anymore.
	ASSERT(thread()->execution_state() == Thread::kThreadInNative);
	thread()->ExitSafepoint();
	thread()->set_execution_state(Thread::kThreadInVM);
	}

	private:
	DISALLOW_COPY_AND_ASSIGN(TransitionVMToNative);
	};

	// TransitionVMToGenerated is used to transition the safepoint state of a
	// thread from "running vm code" to "running generated code" and ensures
	// that the state is reverted back to "running vm code" when
	// exiting the scope/frame.
	class TransitionVMToGenerated : public TransitionSafepointState {
	public:
	explicit TransitionVMToGenerated(Thread* T) : TransitionSafepointState(T) {
	ASSERT(T == Thread::Current());
	ASSERT(T->execution_state() == Thread::kThreadInVM);
	T->set_execution_state(Thread::kThreadInGenerated);
	}

	~TransitionVMToGenerated() {
	ASSERT(thread()->execution_state() == Thread::kThreadInGenerated);
	thread()->set_execution_state(Thread::kThreadInVM);
	// Fast check to see if a safepoint is requested or not.
	if (thread()->IsSafepointRequested()) {
	thread()->BlockForSafepoint();
	}
	}

	private:
	DISALLOW_COPY_AND_ASSIGN(TransitionVMToGenerated);
	};

	// TransitionNativeToVM is used to transition the safepoint state of a
	// thread from "running native code" to "running vm code" and ensures
	// that the state is reverted back to "running native code" when
	// exiting the scope/frame.
	class TransitionNativeToVM : public TransitionSafepointState {
	public:
	explicit TransitionNativeToVM(Thread* T) : TransitionSafepointState(T) {
	// We are about to execute vm code and so we are not at a safepoint anymore.
	ASSERT(T->execution_state() == Thread::kThreadInNative);
	if (T->no_callback_scope_depth() == 0) {
	T->ExitSafepoint();
	}
	T->set_execution_state(Thread::kThreadInVM);
	}

	~TransitionNativeToVM() {
	// We are returning to native code and so we are at a safepoint.
	ASSERT(thread()->execution_state() == Thread::kThreadInVM);
	thread()->set_execution_state(Thread::kThreadInNative);
	if (thread()->no_callback_scope_depth() == 0) {
	thread()->EnterSafepoint();
	}
	}

	private:
	DISALLOW_COPY_AND_ASSIGN(TransitionNativeToVM);
	};

	// TransitionToGenerated is used to transition the safepoint state of a
	// thread from "running vm code" or "running native code" to
	// "running generated code" and ensures that the state is reverted back
	// to "running vm code" or "running native code" when exiting the
	// scope/frame.
	class TransitionToGenerated : public TransitionSafepointState {
	public:
	explicit TransitionToGenerated(Thread* T)
	: TransitionSafepointState(T), execution_state_(T->execution_state()) {
	ASSERT(T == Thread::Current());
	ASSERT((execution_state_ == Thread::kThreadInVM) \|\|
	(execution_state_ == Thread::kThreadInNative));
	if (execution_state_ == Thread::kThreadInNative) {
	T->ExitSafepoint();
	}
	T->set_execution_state(Thread::kThreadInGenerated);
	}

	~TransitionToGenerated() {
	ASSERT(thread()->execution_state() == Thread::kThreadInGenerated);
	if (execution_state_ == Thread::kThreadInNative) {
	thread()->set_execution_state(Thread::kThreadInNative);
	thread()->EnterSafepoint();
	} else {
	ASSERT(execution_state_ == Thread::kThreadInVM);
	thread()->set_execution_state(Thread::kThreadInVM);
	}
	}

	private:
	uint32_t execution_state_;
	DISALLOW_COPY_AND_ASSIGN(TransitionToGenerated);
	};

	// TransitionToVM is used to transition the safepoint state of a
	// thread from "running native code" to "running vm code"
	// and ensures that the state is reverted back to "running native code"
	// when exiting the scope/frame.
	// This transition helper is mainly used in the error path of the
	// Dart API implementations where we sometimes do not have an explicit
	// transition set up.
	class TransitionToVM : public TransitionSafepointState {
	public:
	explicit TransitionToVM(Thread* T)
	: TransitionSafepointState(T), execution_state_(T->execution_state()) {
	ASSERT(T == Thread::Current());
	ASSERT((execution_state_ == Thread::kThreadInVM) \|\|
	(execution_state_ == Thread::kThreadInNative));
	if (execution_state_ == Thread::kThreadInNative) {
	T->ExitSafepoint();
	T->set_execution_state(Thread::kThreadInVM);
	}
	ASSERT(T->execution_state() == Thread::kThreadInVM);
	}

	~TransitionToVM() {
	ASSERT(thread()->execution_state() == Thread::kThreadInVM);
	if (execution_state_ == Thread::kThreadInNative) {
	thread()->set_execution_state(Thread::kThreadInNative);
	thread()->EnterSafepoint();
	}
	}

	private:
	uint32_t execution_state_;
	DISALLOW_COPY_AND_ASSIGN(TransitionToVM);
	};

	// TransitionToNative is used to transition the safepoint state of a
	// thread from "running VM code" to "running native code"
	// and ensures that the state is reverted back to the initial state
	// when exiting the scope/frame.
	class TransitionToNative : public TransitionSafepointState {
	public:
	explicit TransitionToNative(Thread* T)
	: TransitionSafepointState(T), execution_state_(T->execution_state()) {
	ASSERT(T == Thread::Current());
	ASSERT((execution_state_ == Thread::kThreadInVM) \|\|
	(execution_state_ == Thread::kThreadInNative));
	if (execution_state_ == Thread::kThreadInVM) {
	T->set_execution_state(Thread::kThreadInNative);
	T->EnterSafepoint();
	}
	ASSERT(T->execution_state() == Thread::kThreadInNative);
	}

	~TransitionToNative() {
	ASSERT(thread()->execution_state() == Thread::kThreadInNative);
	if (execution_state_ == Thread::kThreadInVM) {
	thread()->ExitSafepoint();
	thread()->set_execution_state(Thread::kThreadInVM);
	}
	}

	private:
	uint32_t execution_state_;
	DISALLOW_COPY_AND_ASSIGN(TransitionToNative);
	};

	} // namespace dart

	#endif // RUNTIME_VM_HEAP_SAFEPOINT_H_