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

 // Copyright (c) 2012, 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/isolate.h"

 #include "include/dart_api.h"
 #include "platform/assert.h"
 #include "lib/mirrors.h"
 #include "vm/compiler_stats.h"
 #include "vm/dart_api_state.h"
 #include "vm/dart_entry.h"
 #include "vm/debugger.h"
 #include "vm/debuginfo.h"
 #include "vm/heap.h"
 #include "vm/message_handler.h"
 #include "vm/object_store.h"
 #include "vm/parser.h"
 #include "vm/port.h"
 #include "vm/random.h"
 #include "vm/stack_frame.h"
 #include "vm/stub_code.h"
 #include "vm/symbols.h"
 #include "vm/thread.h"
 #include "vm/timer.h"
 #include "vm/visitor.h"

 namespace dart {

 DEFINE_FLAG(bool, report_usage_count, false,
             "Track function usage and report.");
 DEFINE_FLAG(bool, trace_isolates, false,
             "Trace isolate creation and shut down.");
 DECLARE_FLAG(bool, generate_gdb_symbols);


 class IsolateMessageHandler : public MessageHandler {
  public:
   explicit IsolateMessageHandler(Isolate* isolate);
   ~IsolateMessageHandler();

   const char* name() const;
   void MessageNotify(Message::Priority priority);
   bool HandleMessage(Message* message);

 #if defined(DEBUG)
   // Check that it is safe to access this handler.
   void CheckAccess();
 #endif
   bool IsCurrentIsolate() const;
   virtual Isolate* GetIsolate() const { return isolate_; }

  private:
   Isolate* isolate_;
 };


 IsolateMessageHandler::IsolateMessageHandler(Isolate* isolate)
     : isolate_(isolate) {
 }


 IsolateMessageHandler::~IsolateMessageHandler() {
 }

 const char* IsolateMessageHandler::name() const {
   return isolate_->name();
 }


 void IsolateMessageHandler::MessageNotify(Message::Priority priority) {
   if (priority >= Message::kOOBPriority) {
     // Handle out of band messages even if the isolate is busy.
     isolate_->ScheduleInterrupts(Isolate::kMessageInterrupt);
   }
   Dart_MessageNotifyCallback callback = isolate_->message_notify_callback();
   if (callback) {
     // Allow the embedder to handle message notification.
     (*callback)(Api::CastIsolate(isolate_));
   }
 }


 bool IsolateMessageHandler::HandleMessage(Message* message) {
   StartIsolateScope start_scope(isolate_);
   StackZone zone(isolate_);
   HandleScope handle_scope(isolate_);

   // Parse the message.
   SnapshotReader reader(message->data(), message->len(),
                         Snapshot::kMessage, Isolate::Current());
   const Object& msg_obj = Object::Handle(reader.ReadObject());
   if (!msg_obj.IsNull() && !msg_obj.IsInstance()) {
     // TODO(turnidge): We need to decide what an isolate does with
     // malformed messages.  If they (eventually) come from a remote
     // machine, then it might make sense to drop the message entirely.
     // In the case that the message originated locally, which is
     // always true for now, then this should never occur.
     UNREACHABLE();
   }

   Instance& msg = Instance::Handle();
   msg ^= msg_obj.raw();  // Can't use Instance::Cast because may be null.

   if (message->IsOOB()) {
     // For now the only OOB messages are Mirrors messages.
     HandleMirrorsMessage(isolate_, message->reply_port(), msg);
     delete message;
   } else {
     const Object& result = Object::Handle(
         DartLibraryCalls::HandleMessage(
             message->dest_port(), message->reply_port(), msg));
     delete message;
     if (result.IsError()) {
       isolate_->object_store()->set_sticky_error(Error::Cast(result));
       return false;
     }
     ASSERT(result.IsNull());
   }
   return true;
 }


 #if defined(DEBUG)
 void IsolateMessageHandler::CheckAccess() {
   ASSERT(IsCurrentIsolate());
 }
 #endif


 bool IsolateMessageHandler::IsCurrentIsolate() const {
   return (isolate_ == Isolate::Current());
 }


 #if defined(DEBUG)
 // static
 void BaseIsolate::AssertCurrent(BaseIsolate* isolate) {
   ASSERT(isolate == Isolate::Current());
 }
 #endif


 Isolate::Isolate()
     : store_buffer_block_(),
       store_buffer_(),
       message_notify_callback_(NULL),
       name_(NULL),
       main_port_(0),
       heap_(NULL),
       object_store_(NULL),
       top_context_(Context::null()),
       random_seed_(Random::kDefaultRandomSeed),
       top_exit_frame_info_(0),
       init_callback_data_(NULL),
       library_tag_handler_(NULL),
       api_state_(NULL),
       stub_code_(NULL),
       debugger_(NULL),
       long_jump_base_(NULL),
       timer_list_(),
       deopt_id_(0),
       ic_data_array_(Array::null()),
       mutex_(new Mutex()),
       stack_limit_(0),
       saved_stack_limit_(0),
       message_handler_(NULL),
       spawn_data_(NULL),
       gc_prologue_callbacks_(),
       gc_epilogue_callbacks_(),
       deopt_cpu_registers_copy_(NULL),
       deopt_xmm_registers_copy_(NULL),
       deopt_frame_copy_(NULL),
       deopt_frame_copy_size_(0),
       deferred_doubles_(NULL),
       deferred_mints_(NULL) {
 }


 Isolate::~Isolate() {
   delete [] name_;
   delete heap_;
   delete object_store_;
   delete api_state_;
   delete stub_code_;
   delete debugger_;
   delete mutex_;
   mutex_ = NULL;  // Fail fast if interrupts are scheduled on a dead isolate.
   delete message_handler_;
   message_handler_ = NULL;  // Fail fast if we send messages to a dead isolate.
 }

 void Isolate::SetCurrent(Isolate* current) {
   Thread::SetThreadLocal(isolate_key, reinterpret_cast<uword>(current));
 }


 // The single thread local key which stores all the thread local data
 // for a thread. Since an Isolate is the central repository for
 // storing all isolate specific information a single thread local key
 // is sufficient.
 ThreadLocalKey Isolate::isolate_key = Thread::kUnsetThreadLocalKey;


 void Isolate::InitOnce() {
   ASSERT(isolate_key == Thread::kUnsetThreadLocalKey);
   isolate_key = Thread::CreateThreadLocal();
   ASSERT(isolate_key != Thread::kUnsetThreadLocalKey);
   create_callback_ = NULL;
 }


 Isolate* Isolate::Init(const char* name_prefix) {
   Isolate* result = new Isolate();
   ASSERT(result != NULL);

   // TODO(5411455): For now just set the recently created isolate as
   // the current isolate.
   SetCurrent(result);

   // Setup the isolate message handler.
   MessageHandler* handler = new IsolateMessageHandler(result);
   ASSERT(handler != NULL);
   result->set_message_handler(handler);

   // Setup the Dart API state.
   ApiState* state = new ApiState();
   ASSERT(state != NULL);
   result->set_api_state(state);

   // Initialize stack top and limit in case we are running the isolate in the
   // main thread.
   // TODO(5411455): Need to figure out how to set the stack limit for the
   // main thread.
   result->SetStackLimitFromCurrentTOS(reinterpret_cast<uword>(&result));
   result->set_main_port(PortMap::CreatePort(result->message_handler()));
   result->BuildName(name_prefix);

   result->debugger_ = new Debugger();
   result->debugger_->Initialize(result);
   if (FLAG_trace_isolates) {
     if (name_prefix == NULL || strcmp(name_prefix, "vm-isolate") != 0) {
       OS::Print("[+] Starting isolate:\n"
                 "\tisolate:    %s\n", result->name());
     }
   }
   return result;
 }


 void Isolate::BuildName(const char* name_prefix) {
   ASSERT(name_ == NULL);
   if (name_prefix == NULL) {
     name_prefix = "isolate";
   }
   const char* kFormat = "%s-%lld";
   intptr_t len = OS::SNPrint(NULL, 0, kFormat, name_prefix, main_port()) + 1;
   name_ = new char[len];
   OS::SNPrint(name_, len, kFormat, name_prefix, main_port());
 }


 // TODO(5411455): Use flag to override default value and Validate the
 // stack size by querying OS.
 uword Isolate::GetSpecifiedStackSize() {
   ASSERT(Isolate::kStackSizeBuffer < Thread::GetMaxStackSize());
   uword stack_size = Thread::GetMaxStackSize() - Isolate::kStackSizeBuffer;
   return stack_size;
 }


 void Isolate::SetStackLimitFromCurrentTOS(uword stack_top_value) {
   SetStackLimit(stack_top_value - GetSpecifiedStackSize());
 }


 void Isolate::SetStackLimit(uword limit) {
   MutexLocker ml(mutex_);
   if (stack_limit_ == saved_stack_limit_) {
     // No interrupt pending, set stack_limit_ too.
     stack_limit_ = limit;
   }
   saved_stack_limit_ = limit;
 }


 void Isolate::ScheduleInterrupts(uword interrupt_bits) {
   // TODO(turnidge): Can't use MutexLocker here because MutexLocker is
   // a StackResource, which requires a current isolate.  Should
   // MutexLocker really be a StackResource?
   mutex_->Lock();
   ASSERT((interrupt_bits & ~kInterruptsMask) == 0);  // Must fit in mask.
   if (stack_limit_ == saved_stack_limit_) {
     stack_limit_ = (~static_cast<uword>(0)) & ~kInterruptsMask;
   }
   stack_limit_ |= interrupt_bits;
   mutex_->Unlock();
 }


 uword Isolate::GetAndClearInterrupts() {
   MutexLocker ml(mutex_);
   if (stack_limit_ == saved_stack_limit_) {
     return 0;  // No interrupt was requested.
   }
   uword interrupt_bits = stack_limit_ & kInterruptsMask;
   stack_limit_ = saved_stack_limit_;
   return interrupt_bits;
 }


 ICData* Isolate::GetICDataForDeoptId(intptr_t deopt_id) const {
   if (ic_data_array() == Array::null()) {
     return NULL;
   }
   const Array& array_handle = Array::Handle(ic_data_array());
   if (deopt_id >= array_handle.Length()) {
     // For computations being added in the optimizing compiler.
     return NULL;
   }
   ICData& ic_data_handle = ICData::ZoneHandle();
   ic_data_handle ^= array_handle.At(deopt_id);
   return &ic_data_handle;
 }


 static int MostUsedFunctionFirst(const Function* const* a,
                                  const Function* const* b) {
   if ((*a)->usage_counter() > (*b)->usage_counter()) {
     return -1;
   } else if ((*a)->usage_counter() < (*b)->usage_counter()) {
     return 1;
   } else {
     return 0;
   }
 }


 static void AddFunctionsFromClass(const Class& cls,
                                   GrowableArray<const Function*>* functions) {
   const Array& class_functions = Array::Handle(cls.functions());
   // Class 'dynamic' is allocated/initialized in a special way, leaving
   // the functions field NULL instead of empty.
   const int func_len = class_functions.IsNull() ? 0 : class_functions.Length();
   for (int j = 0; j < func_len; j++) {
     Function& function = Function::Handle();
     function ^= class_functions.At(j);
     if (function.usage_counter() > 0) {
       functions->Add(&function);
     }
   }
 }


 void Isolate::PrintInvokedFunctions() {
   ASSERT(this == Isolate::Current());
   StackZone zone(this);
   HandleScope handle_scope(this);
   const GrowableObjectArray& libraries =
       GrowableObjectArray::Handle(object_store()->libraries());
   Library& library = Library::Handle();
   GrowableArray<const Function*> invoked_functions;
   for (int i = 0; i < libraries.Length(); i++) {
     library ^= libraries.At(i);
     Class& cls = Class::Handle();
     ClassDictionaryIterator iter(library);
     while (iter.HasNext()) {
       cls = iter.GetNextClass();
       AddFunctionsFromClass(cls, &invoked_functions);
     }
     Array& anon_classes = Array::Handle(library.raw_ptr()->anonymous_classes_);
     for (int i = 0; i < library.raw_ptr()->num_anonymous_; i++) {
       cls ^= anon_classes.At(i);
       AddFunctionsFromClass(cls, &invoked_functions);
     }
   }
   invoked_functions.Sort(MostUsedFunctionFirst);
   for (int i = 0; i < invoked_functions.length(); i++) {
     OS::Print("%10"Pd" x %s\n",
         invoked_functions[i]->usage_counter(),
         invoked_functions[i]->ToFullyQualifiedCString());
   }
 }


 class FinalizeWeakPersistentHandlesVisitor : public HandleVisitor {
  public:
   FinalizeWeakPersistentHandlesVisitor() {
   }

   void VisitHandle(uword addr) {
     FinalizablePersistentHandle* handle =
         reinterpret_cast<FinalizablePersistentHandle*>(addr);
     FinalizablePersistentHandle::Finalize(handle);
   }

  private:
   DISALLOW_COPY_AND_ASSIGN(FinalizeWeakPersistentHandlesVisitor);
 };


 void Isolate::Shutdown() {
   ASSERT(this == Isolate::Current());
   ASSERT(top_resource() == NULL);
   ASSERT((heap_ == NULL) || heap_->Verify());

   // Clean up debugger resources. Shutting down the debugger
   // requires a handle zone. We must set up a temporary zone because
   // Isolate::Shutdown is called without a zone.
   {
     StackZone zone(this);
     HandleScope handle_scope(this);
     debugger_->Shutdown();
   }

   // Close all the ports owned by this isolate.
   PortMap::ClosePorts(message_handler());

   // Fail fast if anybody tries to post any more messsages to this isolate.
   delete message_handler();
   set_message_handler(NULL);

   // Finalize any weak persistent handles with a non-null referent.
   FinalizeWeakPersistentHandlesVisitor visitor;
   api_state()->weak_persistent_handles().VisitHandles(&visitor);

   // Dump all accumalated timer data for the isolate.
   timer_list_.ReportTimers();
   if (FLAG_report_usage_count) {
     PrintInvokedFunctions();
   }
   CompilerStats::Print();
   if (FLAG_generate_gdb_symbols) {
     DebugInfo::UnregisterAllSections();
   }
   if (FLAG_trace_isolates) {
     StackZone zone(this);
     HandleScope handle_scope(this);
     OS::Print("Number of symbols added = %"Pd"\n", Symbols::Size(this));
     OS::Print("[-] Stopping isolate:\n"
               "\tisolate:    %s\n", name());
   }
   // TODO(5411455): For now just make sure there are no current isolates
   // as we are shutting down the isolate.
   SetCurrent(NULL);
 }


 Dart_IsolateCreateCallback Isolate::create_callback_ = NULL;
 Dart_IsolateInterruptCallback Isolate::interrupt_callback_ = NULL;
 Dart_IsolateShutdownCallback Isolate::shutdown_callback_ = NULL;


 void Isolate::VisitObjectPointers(ObjectPointerVisitor* visitor,
                                   bool visit_prologue_weak_handles,
                                   bool validate_frames) {
   ASSERT(visitor != NULL);

   // Visit objects in the object store.
   object_store()->VisitObjectPointers(visitor);

   // Visit objects in the class table.
   class_table()->VisitObjectPointers(visitor);

   // Visit objects in per isolate stubs.
   StubCode::VisitObjectPointers(visitor);

   // Visit objects in zones.
   current_zone()->VisitObjectPointers(visitor);

   // Iterate over all the stack frames and visit objects on the stack.
   StackFrameIterator frames_iterator(validate_frames);
   StackFrame* frame = frames_iterator.NextFrame();
   while (frame != NULL) {
     frame->VisitObjectPointers(visitor);
     frame = frames_iterator.NextFrame();
   }

   // Visit the dart api state for all local and persistent handles.
   if (api_state() != NULL) {
     api_state()->VisitObjectPointers(visitor, visit_prologue_weak_handles);
   }

   // Visit the top context which is stored in the isolate.
   visitor->VisitPointer(reinterpret_cast<RawObject**>(&top_context_));

   // Visit the currently active IC data array.
   visitor->VisitPointer(reinterpret_cast<RawObject**>(&ic_data_array_));

   // Visit objects in the debugger.
   debugger()->VisitObjectPointers(visitor);
 }


 void Isolate::VisitWeakPersistentHandles(HandleVisitor* visitor,
                                          bool visit_prologue_weak_handles) {
   if (api_state() != NULL) {
     api_state()->VisitWeakHandles(visitor, visit_prologue_weak_handles);
   }
 }

 }  // namespace dart
	// Copyright (c) 2012, 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/isolate.h"

	#include "include/dart_api.h"
	#include "platform/assert.h"
	#include "lib/mirrors.h"
	#include "vm/compiler_stats.h"
	#include "vm/dart_api_state.h"
	#include "vm/dart_entry.h"
	#include "vm/debugger.h"
	#include "vm/debuginfo.h"
	#include "vm/heap.h"
	#include "vm/message_handler.h"
	#include "vm/object_store.h"
	#include "vm/parser.h"
	#include "vm/port.h"
	#include "vm/random.h"
	#include "vm/stack_frame.h"
	#include "vm/stub_code.h"
	#include "vm/symbols.h"
	#include "vm/thread.h"
	#include "vm/timer.h"
	#include "vm/visitor.h"

	namespace dart {

	DEFINE_FLAG(bool, report_usage_count, false,
	"Track function usage and report.");
	DEFINE_FLAG(bool, trace_isolates, false,
	"Trace isolate creation and shut down.");
	DECLARE_FLAG(bool, generate_gdb_symbols);


	class IsolateMessageHandler : public MessageHandler {
	public:
	explicit IsolateMessageHandler(Isolate* isolate);
	~IsolateMessageHandler();

	const char* name() const;
	void MessageNotify(Message::Priority priority);
	bool HandleMessage(Message* message);

	#if defined(DEBUG)
	// Check that it is safe to access this handler.
	void CheckAccess();
	#endif
	bool IsCurrentIsolate() const;
	virtual Isolate* GetIsolate() const { return isolate_; }

	private:
	Isolate* isolate_;
	};


	IsolateMessageHandler::IsolateMessageHandler(Isolate* isolate)
	: isolate_(isolate) {
	}


	IsolateMessageHandler::~IsolateMessageHandler() {
	}

	const char* IsolateMessageHandler::name() const {
	return isolate_->name();
	}


	void IsolateMessageHandler::MessageNotify(Message::Priority priority) {
	if (priority >= Message::kOOBPriority) {
	// Handle out of band messages even if the isolate is busy.
	isolate_->ScheduleInterrupts(Isolate::kMessageInterrupt);
	}
	Dart_MessageNotifyCallback callback = isolate_->message_notify_callback();
	if (callback) {
	// Allow the embedder to handle message notification.
	(*callback)(Api::CastIsolate(isolate_));
	}
	}


	bool IsolateMessageHandler::HandleMessage(Message* message) {
	StartIsolateScope start_scope(isolate_);
	StackZone zone(isolate_);
	HandleScope handle_scope(isolate_);

	// Parse the message.
	SnapshotReader reader(message->data(), message->len(),
	Snapshot::kMessage, Isolate::Current());
	const Object& msg_obj = Object::Handle(reader.ReadObject());
	if (!msg_obj.IsNull() && !msg_obj.IsInstance()) {
	// TODO(turnidge): We need to decide what an isolate does with
	// malformed messages. If they (eventually) come from a remote
	// machine, then it might make sense to drop the message entirely.
	// In the case that the message originated locally, which is
	// always true for now, then this should never occur.
	UNREACHABLE();
	}

	Instance& msg = Instance::Handle();
	msg ^= msg_obj.raw(); // Can't use Instance::Cast because may be null.

	if (message->IsOOB()) {
	// For now the only OOB messages are Mirrors messages.
	HandleMirrorsMessage(isolate_, message->reply_port(), msg);
	delete message;
	} else {
	const Object& result = Object::Handle(
	DartLibraryCalls::HandleMessage(
	message->dest_port(), message->reply_port(), msg));
	delete message;
	if (result.IsError()) {
	isolate_->object_store()->set_sticky_error(Error::Cast(result));
	return false;
	}
	ASSERT(result.IsNull());
	}
	return true;
	}


	#if defined(DEBUG)
	void IsolateMessageHandler::CheckAccess() {
	ASSERT(IsCurrentIsolate());
	}
	#endif


	bool IsolateMessageHandler::IsCurrentIsolate() const {
	return (isolate_ == Isolate::Current());
	}


	#if defined(DEBUG)
	// static
	void BaseIsolate::AssertCurrent(BaseIsolate* isolate) {
	ASSERT(isolate == Isolate::Current());
	}
	#endif


	Isolate::Isolate()
	: store_buffer_block_(),
	store_buffer_(),
	message_notify_callback_(NULL),
	name_(NULL),
	main_port_(0),
	heap_(NULL),
	object_store_(NULL),
	top_context_(Context::null()),
	random_seed_(Random::kDefaultRandomSeed),
	top_exit_frame_info_(0),
	init_callback_data_(NULL),
	library_tag_handler_(NULL),
	api_state_(NULL),
	stub_code_(NULL),
	debugger_(NULL),
	long_jump_base_(NULL),
	timer_list_(),
	deopt_id_(0),
	ic_data_array_(Array::null()),
	mutex_(new Mutex()),
	stack_limit_(0),
	saved_stack_limit_(0),
	message_handler_(NULL),
	spawn_data_(NULL),
	gc_prologue_callbacks_(),
	gc_epilogue_callbacks_(),
	deopt_cpu_registers_copy_(NULL),
	deopt_xmm_registers_copy_(NULL),
	deopt_frame_copy_(NULL),
	deopt_frame_copy_size_(0),
	deferred_doubles_(NULL),
	deferred_mints_(NULL) {
	}


	Isolate::~Isolate() {
	delete [] name_;
	delete heap_;
	delete object_store_;
	delete api_state_;
	delete stub_code_;
	delete debugger_;
	delete mutex_;
	mutex_ = NULL; // Fail fast if interrupts are scheduled on a dead isolate.
	delete message_handler_;
	message_handler_ = NULL; // Fail fast if we send messages to a dead isolate.
	}

	void Isolate::SetCurrent(Isolate* current) {
	Thread::SetThreadLocal(isolate_key, reinterpret_cast<uword>(current));
	}


	// The single thread local key which stores all the thread local data
	// for a thread. Since an Isolate is the central repository for
	// storing all isolate specific information a single thread local key
	// is sufficient.
	ThreadLocalKey Isolate::isolate_key = Thread::kUnsetThreadLocalKey;


	void Isolate::InitOnce() {
	ASSERT(isolate_key == Thread::kUnsetThreadLocalKey);
	isolate_key = Thread::CreateThreadLocal();
	ASSERT(isolate_key != Thread::kUnsetThreadLocalKey);
	create_callback_ = NULL;
	}


	Isolate* Isolate::Init(const char* name_prefix) {
	Isolate* result = new Isolate();
	ASSERT(result != NULL);

	// TODO(5411455): For now just set the recently created isolate as
	// the current isolate.
	SetCurrent(result);

	// Setup the isolate message handler.
	MessageHandler* handler = new IsolateMessageHandler(result);
	ASSERT(handler != NULL);
	result->set_message_handler(handler);

	// Setup the Dart API state.
	ApiState* state = new ApiState();
	ASSERT(state != NULL);
	result->set_api_state(state);

	// Initialize stack top and limit in case we are running the isolate in the
	// main thread.
	// TODO(5411455): Need to figure out how to set the stack limit for the
	// main thread.
	result->SetStackLimitFromCurrentTOS(reinterpret_cast<uword>(&result));
	result->set_main_port(PortMap::CreatePort(result->message_handler()));
	result->BuildName(name_prefix);

	result->debugger_ = new Debugger();
	result->debugger_->Initialize(result);
	if (FLAG_trace_isolates) {
	if (name_prefix == NULL \|\| strcmp(name_prefix, "vm-isolate") != 0) {
	OS::Print("[+] Starting isolate:\n"
	"\tisolate: %s\n", result->name());
	}
	}
	return result;
	}


	void Isolate::BuildName(const char* name_prefix) {
	ASSERT(name_ == NULL);
	if (name_prefix == NULL) {
	name_prefix = "isolate";
	}
	const char* kFormat = "%s-%lld";
	intptr_t len = OS::SNPrint(NULL, 0, kFormat, name_prefix, main_port()) + 1;
	name_ = new char[len];
	OS::SNPrint(name_, len, kFormat, name_prefix, main_port());
	}


	// TODO(5411455): Use flag to override default value and Validate the
	// stack size by querying OS.
	uword Isolate::GetSpecifiedStackSize() {
	ASSERT(Isolate::kStackSizeBuffer < Thread::GetMaxStackSize());
	uword stack_size = Thread::GetMaxStackSize() - Isolate::kStackSizeBuffer;
	return stack_size;
	}


	void Isolate::SetStackLimitFromCurrentTOS(uword stack_top_value) {
	SetStackLimit(stack_top_value - GetSpecifiedStackSize());
	}


	void Isolate::SetStackLimit(uword limit) {
	MutexLocker ml(mutex_);
	if (stack_limit_ == saved_stack_limit_) {
	// No interrupt pending, set stack_limit_ too.
	stack_limit_ = limit;
	}
	saved_stack_limit_ = limit;
	}


	void Isolate::ScheduleInterrupts(uword interrupt_bits) {
	// TODO(turnidge): Can't use MutexLocker here because MutexLocker is
	// a StackResource, which requires a current isolate. Should
	// MutexLocker really be a StackResource?
	mutex_->Lock();
	ASSERT((interrupt_bits & ~kInterruptsMask) == 0); // Must fit in mask.
	if (stack_limit_ == saved_stack_limit_) {
	stack_limit_ = (~static_cast<uword>(0)) & ~kInterruptsMask;
	}
	stack_limit_ \|= interrupt_bits;
	mutex_->Unlock();
	}


	uword Isolate::GetAndClearInterrupts() {
	MutexLocker ml(mutex_);
	if (stack_limit_ == saved_stack_limit_) {
	return 0; // No interrupt was requested.
	}
	uword interrupt_bits = stack_limit_ & kInterruptsMask;
	stack_limit_ = saved_stack_limit_;
	return interrupt_bits;
	}


	ICData* Isolate::GetICDataForDeoptId(intptr_t deopt_id) const {
	if (ic_data_array() == Array::null()) {
	return NULL;
	}
	const Array& array_handle = Array::Handle(ic_data_array());
	if (deopt_id >= array_handle.Length()) {
	// For computations being added in the optimizing compiler.
	return NULL;
	}
	ICData& ic_data_handle = ICData::ZoneHandle();
	ic_data_handle ^= array_handle.At(deopt_id);
	return &ic_data_handle;
	}


	static int MostUsedFunctionFirst(const Function* const* a,
	const Function* const* b) {
	if ((a)->usage_counter() > (b)->usage_counter()) {
	return -1;
	} else if ((a)->usage_counter() < (b)->usage_counter()) {
	return 1;
	} else {
	return 0;
	}
	}


	static void AddFunctionsFromClass(const Class& cls,
	GrowableArray<const Function> functions) {
	const Array& class_functions = Array::Handle(cls.functions());
	// Class 'dynamic' is allocated/initialized in a special way, leaving
	// the functions field NULL instead of empty.
	const int func_len = class_functions.IsNull() ? 0 : class_functions.Length();
	for (int j = 0; j < func_len; j++) {
	Function& function = Function::Handle();
	function ^= class_functions.At(j);
	if (function.usage_counter() > 0) {
	functions->Add(&function);
	}
	}
	}


	void Isolate::PrintInvokedFunctions() {
	ASSERT(this == Isolate::Current());
	StackZone zone(this);
	HandleScope handle_scope(this);
	const GrowableObjectArray& libraries =
	GrowableObjectArray::Handle(object_store()->libraries());
	Library& library = Library::Handle();
	GrowableArray<const Function*> invoked_functions;
	for (int i = 0; i < libraries.Length(); i++) {
	library ^= libraries.At(i);
	Class& cls = Class::Handle();
	ClassDictionaryIterator iter(library);
	while (iter.HasNext()) {
	cls = iter.GetNextClass();
	AddFunctionsFromClass(cls, &invoked_functions);
	}
	Array& anon_classes = Array::Handle(library.raw_ptr()->anonymous_classes_);
	for (int i = 0; i < library.raw_ptr()->num_anonymous_; i++) {
	cls ^= anon_classes.At(i);
	AddFunctionsFromClass(cls, &invoked_functions);
	}
	}
	invoked_functions.Sort(MostUsedFunctionFirst);
	for (int i = 0; i < invoked_functions.length(); i++) {
	OS::Print("%10"Pd" x %s\n",
	invoked_functions[i]->usage_counter(),
	invoked_functions[i]->ToFullyQualifiedCString());
	}
	}


	class FinalizeWeakPersistentHandlesVisitor : public HandleVisitor {
	public:
	FinalizeWeakPersistentHandlesVisitor() {
	}

	void VisitHandle(uword addr) {
	FinalizablePersistentHandle* handle =
	reinterpret_cast<FinalizablePersistentHandle*>(addr);
	FinalizablePersistentHandle::Finalize(handle);
	}

	private:
	DISALLOW_COPY_AND_ASSIGN(FinalizeWeakPersistentHandlesVisitor);
	};


	void Isolate::Shutdown() {
	ASSERT(this == Isolate::Current());
	ASSERT(top_resource() == NULL);
	ASSERT((heap_ == NULL) \|\| heap_->Verify());

	// Clean up debugger resources. Shutting down the debugger
	// requires a handle zone. We must set up a temporary zone because
	// Isolate::Shutdown is called without a zone.
	{
	StackZone zone(this);
	HandleScope handle_scope(this);
	debugger_->Shutdown();
	}

	// Close all the ports owned by this isolate.
	PortMap::ClosePorts(message_handler());

	// Fail fast if anybody tries to post any more messsages to this isolate.
	delete message_handler();
	set_message_handler(NULL);

	// Finalize any weak persistent handles with a non-null referent.
	FinalizeWeakPersistentHandlesVisitor visitor;
	api_state()->weak_persistent_handles().VisitHandles(&visitor);

	// Dump all accumalated timer data for the isolate.
	timer_list_.ReportTimers();
	if (FLAG_report_usage_count) {
	PrintInvokedFunctions();
	}
	CompilerStats::Print();
	if (FLAG_generate_gdb_symbols) {
	DebugInfo::UnregisterAllSections();
	}
	if (FLAG_trace_isolates) {
	StackZone zone(this);
	HandleScope handle_scope(this);
	OS::Print("Number of symbols added = %"Pd"\n", Symbols::Size(this));
	OS::Print("[-] Stopping isolate:\n"
	"\tisolate: %s\n", name());
	}
	// TODO(5411455): For now just make sure there are no current isolates
	// as we are shutting down the isolate.
	SetCurrent(NULL);
	}


	Dart_IsolateCreateCallback Isolate::create_callback_ = NULL;
	Dart_IsolateInterruptCallback Isolate::interrupt_callback_ = NULL;
	Dart_IsolateShutdownCallback Isolate::shutdown_callback_ = NULL;


	void Isolate::VisitObjectPointers(ObjectPointerVisitor* visitor,
	bool visit_prologue_weak_handles,
	bool validate_frames) {
	ASSERT(visitor != NULL);

	// Visit objects in the object store.
	object_store()->VisitObjectPointers(visitor);

	// Visit objects in the class table.
	class_table()->VisitObjectPointers(visitor);

	// Visit objects in per isolate stubs.
	StubCode::VisitObjectPointers(visitor);

	// Visit objects in zones.
	current_zone()->VisitObjectPointers(visitor);

	// Iterate over all the stack frames and visit objects on the stack.
	StackFrameIterator frames_iterator(validate_frames);
	StackFrame* frame = frames_iterator.NextFrame();
	while (frame != NULL) {
	frame->VisitObjectPointers(visitor);
	frame = frames_iterator.NextFrame();
	}

	// Visit the dart api state for all local and persistent handles.
	if (api_state() != NULL) {
	api_state()->VisitObjectPointers(visitor, visit_prologue_weak_handles);
	}

	// Visit the top context which is stored in the isolate.
	visitor->VisitPointer(reinterpret_cast<RawObject**>(&top_context_));

	// Visit the currently active IC data array.
	visitor->VisitPointer(reinterpret_cast<RawObject**>(&ic_data_array_));

	// Visit objects in the debugger.
	debugger()->VisitObjectPointers(visitor);
	}


	void Isolate::VisitWeakPersistentHandles(HandleVisitor* visitor,
	bool visit_prologue_weak_handles) {
	if (api_state() != NULL) {
	api_state()->VisitWeakHandles(visitor, visit_prologue_weak_handles);
	}
	}

	} // namespace dart