blob: f7caee18d3618160072aaa28a06b2e501260afde [file] [log] [blame]
// Copyright (c) 2013, 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 "include/dart_native_api.h"
#include "platform/assert.h"
#include "platform/json.h"
#include "vm/class_finalizer.h"
#include "vm/code_observers.h"
#include "vm/compiler.h"
#include "vm/compiler_stats.h"
#include "vm/coverage.h"
#include "vm/dart_api_message.h"
#include "vm/dart_api_state.h"
#include "vm/dart_entry.h"
#include "vm/debugger.h"
#include "vm/deopt_instructions.h"
#include "vm/heap.h"
#include "vm/lockers.h"
#include "vm/log.h"
#include "vm/message_handler.h"
#include "vm/object_id_ring.h"
#include "vm/object_store.h"
#include "vm/object.h"
#include "vm/os_thread.h"
#include "vm/port.h"
#include "vm/profiler.h"
#include "vm/reusable_handles.h"
#include "vm/service.h"
#include "vm/service_event.h"
#include "vm/service_isolate.h"
#include "vm/simulator.h"
#include "vm/stack_frame.h"
#include "vm/store_buffer.h"
#include "vm/stub_code.h"
#include "vm/symbols.h"
#include "vm/tags.h"
#include "vm/thread_interrupter.h"
#include "vm/thread_registry.h"
#include "vm/timeline.h"
#include "vm/timeline_analysis.h"
#include "vm/timer.h"
#include "vm/visitor.h"
namespace dart {
DECLARE_FLAG(bool, print_metrics);
DECLARE_FLAG(bool, timing);
DECLARE_FLAG(bool, trace_service);
DEFINE_FLAG(bool, trace_isolates, false,
"Trace isolate creation and shut down.");
DEFINE_FLAG(bool, pause_isolates_on_start, false,
"Pause isolates before starting.");
DEFINE_FLAG(bool, pause_isolates_on_exit, false,
"Pause isolates exiting.");
DEFINE_FLAG(bool, break_at_isolate_spawn, false,
"Insert a one-time breakpoint at the entrypoint for all spawned "
"isolates");
DEFINE_FLAG(int, new_gen_semi_max_size, (kWordSize <= 4) ? 16 : 32,
"Max size of new gen semi space in MB");
DEFINE_FLAG(int, old_gen_heap_size, 0,
"Max size of old gen heap size in MB, or 0 for unlimited,"
"e.g: --old_gen_heap_size=1024 allows up to 1024MB old gen heap");
DEFINE_FLAG(int, external_max_size, (kWordSize <= 4) ? 512 : 1024,
"Max total size of external allocations in MB, or 0 for unlimited,"
"e.g: --external_max_size=1024 allows up to 1024MB of externals");
// TODO(iposva): Make these isolate specific flags inaccessible using the
// regular FLAG_xyz pattern.
// These flags are per-isolate and only influence the defaults.
DEFINE_FLAG(bool, enable_asserts, false, "Enable assert statements.");
DEFINE_FLAG(bool, enable_type_checks, false, "Enable type checks.");
DEFINE_FLAG(bool, error_on_bad_override, false,
"Report error for bad overrides.");
DEFINE_FLAG(bool, error_on_bad_type, false,
"Report error for malformed types.");
static void CheckedModeHandler(bool value) {
FLAG_enable_asserts = value;
FLAG_enable_type_checks = value;
}
// --enable-checked-mode and --checked both enable checked mode which is
// equivalent to setting --enable-asserts and --enable-type-checks.
DEFINE_FLAG_HANDLER(CheckedModeHandler,
enable_checked_mode,
"Enable checked mode.");
DEFINE_FLAG_HANDLER(CheckedModeHandler,
checked,
"Enable checked mode.");
// Quick access to the locally defined thread() and isolate() methods.
#define T (thread())
#define I (isolate())
#if defined(DEBUG)
// Helper class to ensure that a live origin_id is never reused
// and assigned to an isolate.
class VerifyOriginId : public IsolateVisitor {
public:
explicit VerifyOriginId(Dart_Port id) : id_(id) {}
void VisitIsolate(Isolate* isolate) {
ASSERT(isolate->origin_id() != id_);
}
private:
Dart_Port id_;
DISALLOW_COPY_AND_ASSIGN(VerifyOriginId);
};
#endif
static uint8_t* allocator(uint8_t* ptr, intptr_t old_size, intptr_t new_size) {
void* new_ptr = realloc(reinterpret_cast<void*>(ptr), new_size);
return reinterpret_cast<uint8_t*>(new_ptr);
}
static void SerializeObject(const Instance& obj,
uint8_t** obj_data,
intptr_t* obj_len,
bool allow_any_object) {
MessageWriter writer(obj_data, &allocator, allow_any_object);
writer.WriteMessage(obj);
*obj_len = writer.BytesWritten();
}
void Isolate::RegisterClass(const Class& cls) {
class_table()->Register(cls);
}
void Isolate::RegisterClassAt(intptr_t index, const Class& cls) {
class_table()->RegisterAt(index, cls);
}
void Isolate::ValidateClassTable() {
class_table()->Validate();
}
void Isolate::SendInternalLibMessage(LibMsgId msg_id, uint64_t capability) {
const Array& msg = Array::Handle(Array::New(3));
Object& element = Object::Handle();
element = Smi::New(Message::kIsolateLibOOBMsg);
msg.SetAt(0, element);
element = Smi::New(msg_id);
msg.SetAt(1, element);
element = Capability::New(capability);
msg.SetAt(2, element);
uint8_t* data = NULL;
MessageWriter writer(&data, &allocator, false);
writer.WriteMessage(msg);
PortMap::PostMessage(new Message(main_port(),
data, writer.BytesWritten(),
Message::kOOBPriority));
}
class IsolateMessageHandler : public MessageHandler {
public:
explicit IsolateMessageHandler(Isolate* isolate);
~IsolateMessageHandler();
const char* name() const;
void MessageNotify(Message::Priority priority);
MessageStatus HandleMessage(Message* message);
void NotifyPauseOnStart();
void NotifyPauseOnExit();
#if defined(DEBUG)
// Check that it is safe to access this handler.
void CheckAccess();
#endif
bool IsCurrentIsolate() const;
virtual Isolate* isolate() const { return isolate_; }
private:
// A result of false indicates that the isolate should terminate the
// processing of further events.
RawError* HandleLibMessage(const Array& message);
MessageStatus ProcessUnhandledException(const Error& result);
Isolate* isolate_;
};
IsolateMessageHandler::IsolateMessageHandler(Isolate* isolate)
: isolate_(isolate) {
}
IsolateMessageHandler::~IsolateMessageHandler() {
}
const char* IsolateMessageHandler::name() const {
return isolate_->name();
}
// Isolate library OOB messages are fixed sized arrays which have the
// following format:
// [ OOB dispatch, Isolate library dispatch, <message specific data> ]
RawError* IsolateMessageHandler::HandleLibMessage(const Array& message) {
if (message.Length() < 2) return Error::null();
Zone* zone = I->current_zone();
const Object& type = Object::Handle(zone, message.At(1));
if (!type.IsSmi()) return Error::null();
const intptr_t msg_type = Smi::Cast(type).Value();
switch (msg_type) {
case Isolate::kPauseMsg: {
// [ OOB, kPauseMsg, pause capability, resume capability ]
if (message.Length() != 4) return Error::null();
Object& obj = Object::Handle(zone, message.At(2));
if (!I->VerifyPauseCapability(obj)) return Error::null();
obj = message.At(3);
if (!obj.IsCapability()) return Error::null();
if (I->AddResumeCapability(Capability::Cast(obj))) {
increment_paused();
}
break;
}
case Isolate::kResumeMsg: {
// [ OOB, kResumeMsg, pause capability, resume capability ]
if (message.Length() != 4) return Error::null();
Object& obj = Object::Handle(zone, message.At(2));
if (!I->VerifyPauseCapability(obj)) return Error::null();
obj = message.At(3);
if (!obj.IsCapability()) return Error::null();
if (I->RemoveResumeCapability(Capability::Cast(obj))) {
decrement_paused();
}
break;
}
case Isolate::kPingMsg: {
// [ OOB, kPingMsg, responsePort, priority, response ]
if (message.Length() != 5) return Error::null();
const Object& obj2 = Object::Handle(zone, message.At(2));
if (!obj2.IsSendPort()) return Error::null();
const SendPort& send_port = SendPort::Cast(obj2);
const Object& obj3 = Object::Handle(zone, message.At(3));
if (!obj3.IsSmi()) return Error::null();
const intptr_t priority = Smi::Cast(obj3).Value();
const Object& obj4 = Object::Handle(zone, message.At(4));
if (!obj4.IsInstance() && !obj4.IsNull()) return Error::null();
const Instance& response =
obj4.IsNull() ? Instance::null_instance() : Instance::Cast(obj4);
if (priority == Isolate::kImmediateAction) {
uint8_t* data = NULL;
intptr_t len = 0;
SerializeObject(response, &data, &len, false);
PortMap::PostMessage(new Message(send_port.Id(),
data, len,
Message::kNormalPriority));
} else {
ASSERT((priority == Isolate::kBeforeNextEventAction) ||
(priority == Isolate::kAsEventAction));
// Update the message so that it will be handled immediately when it
// is picked up from the message queue the next time.
message.SetAt(0, Smi::Handle(zone,
Smi::New(Message::kDelayedIsolateLibOOBMsg)));
message.SetAt(3, Smi::Handle(zone,
Smi::New(Isolate::kImmediateAction)));
uint8_t* data = NULL;
intptr_t len = 0;
SerializeObject(message, &data, &len, false);
this->PostMessage(
new Message(Message::kIllegalPort,
data, len,
Message::kNormalPriority),
priority == Isolate::kBeforeNextEventAction /* at_head */);
}
break;
}
case Isolate::kKillMsg:
case Isolate::kInternalKillMsg:
case Isolate::kVMRestartMsg: {
// [ OOB, kKillMsg, terminate capability, priority ]
if (message.Length() != 4) return Error::null();
Object& obj = Object::Handle(zone, message.At(3));
if (!obj.IsSmi()) return Error::null();
const intptr_t priority = Smi::Cast(obj).Value();
if (priority == Isolate::kImmediateAction) {
obj = message.At(2);
if (I->VerifyTerminateCapability(obj)) {
// We will kill the current isolate by returning an UnwindError.
if (msg_type == Isolate::kKillMsg) {
const String& msg = String::Handle(String::New(
"isolate terminated by Isolate.kill"));
const UnwindError& error =
UnwindError::Handle(UnwindError::New(msg));
error.set_is_user_initiated(true);
return error.raw();
} else if (msg_type == Isolate::kInternalKillMsg) {
const String& msg = String::Handle(String::New(
"isolate terminated by vm"));
return UnwindError::New(msg);
} else if (msg_type == Isolate::kVMRestartMsg) {
// If this is the main isolate, this request to restart
// will be caught and handled in the embedder. Otherwise
// this unwind error will cause the isolate to exit.
const String& msg = String::Handle(String::New(
"isolate terminated for vm restart"));
const UnwindError& error =
UnwindError::Handle(UnwindError::New(msg));
error.set_is_vm_restart(true);
return error.raw();
} else {
UNREACHABLE();
}
} else {
return Error::null();
}
} else {
ASSERT((priority == Isolate::kBeforeNextEventAction) ||
(priority == Isolate::kAsEventAction));
// Update the message so that it will be handled immediately when it
// is picked up from the message queue the next time.
message.SetAt(0, Smi::Handle(zone,
Smi::New(Message::kDelayedIsolateLibOOBMsg)));
message.SetAt(3, Smi::Handle(zone,
Smi::New(Isolate::kImmediateAction)));
uint8_t* data = NULL;
intptr_t len = 0;
SerializeObject(message, &data, &len, false);
this->PostMessage(
new Message(Message::kIllegalPort,
data, len,
Message::kNormalPriority),
priority == Isolate::kBeforeNextEventAction /* at_head */);
}
break;
}
case Isolate::kInterruptMsg: {
// [ OOB, kInterruptMsg, pause capability ]
if (message.Length() != 3) return Error::null();
Object& obj = Object::Handle(zone, message.At(2));
if (!I->VerifyPauseCapability(obj)) return Error::null();
// If we are already paused, don't pause again.
if (I->debugger()->PauseEvent() == NULL) {
return I->debugger()->SignalIsolateInterrupted();
}
break;
}
case Isolate::kAddExitMsg:
case Isolate::kDelExitMsg:
case Isolate::kAddErrorMsg:
case Isolate::kDelErrorMsg: {
// [ OOB, msg, listener port ]
if (message.Length() < 3) return Error::null();
const Object& obj = Object::Handle(zone, message.At(2));
if (!obj.IsSendPort()) return Error::null();
const SendPort& listener = SendPort::Cast(obj);
switch (msg_type) {
case Isolate::kAddExitMsg: {
if (message.Length() != 4) return Error::null();
// [ OOB, msg, listener port, response object ]
const Object& response = Object::Handle(zone, message.At(3));
if (!response.IsInstance() && !response.IsNull()) {
return Error::null();
}
I->AddExitListener(listener,
response.IsNull() ? Instance::null_instance()
: Instance::Cast(response));
break;
}
case Isolate::kDelExitMsg:
if (message.Length() != 3) return Error::null();
I->RemoveExitListener(listener);
break;
case Isolate::kAddErrorMsg:
if (message.Length() != 3) return Error::null();
I->AddErrorListener(listener);
break;
case Isolate::kDelErrorMsg:
if (message.Length() != 3) return Error::null();
I->RemoveErrorListener(listener);
break;
default:
UNREACHABLE();
}
break;
}
case Isolate::kErrorFatalMsg: {
// [ OOB, kErrorFatalMsg, terminate capability, val ]
if (message.Length() != 4) return Error::null();
// Check that the terminate capability has been passed correctly.
Object& obj = Object::Handle(zone, message.At(2));
if (!I->VerifyTerminateCapability(obj)) return Error::null();
// Get the value to be set.
obj = message.At(3);
if (!obj.IsBool()) return Error::null();
I->SetErrorsFatal(Bool::Cast(obj).value());
break;
}
#if defined(DEBUG)
// Malformed OOB messages are silently ignored in release builds.
default:
UNREACHABLE();
break;
#endif // defined(DEBUG)
}
return Error::null();
}
void IsolateMessageHandler::MessageNotify(Message::Priority priority) {
if (priority >= Message::kOOBPriority) {
// Handle out of band messages even if the isolate is busy.
I->ScheduleInterrupts(Isolate::kMessageInterrupt);
}
Dart_MessageNotifyCallback callback = I->message_notify_callback();
if (callback) {
// Allow the embedder to handle message notification.
(*callback)(Api::CastIsolate(I));
}
}
MessageHandler::MessageStatus IsolateMessageHandler::HandleMessage(
Message* message) {
ASSERT(IsCurrentIsolate());
Thread* thread = Thread::Current();
StackZone stack_zone(thread);
Zone* zone = stack_zone.GetZone();
HandleScope handle_scope(thread);
TimelineDurationScope tds(thread, I->GetIsolateStream(), "HandleMessage");
tds.SetNumArguments(1);
tds.CopyArgument(0, "isolateName", I->name());
// If the message is in band we lookup the handler to dispatch to. If the
// receive port was closed, we drop the message without deserializing it.
// Illegal port is a special case for artificially enqueued isolate library
// messages which are handled in C++ code below.
Object& msg_handler = Object::Handle(zone);
if (!message->IsOOB() && (message->dest_port() != Message::kIllegalPort)) {
msg_handler = DartLibraryCalls::LookupHandler(message->dest_port());
if (msg_handler.IsError()) {
delete message;
return ProcessUnhandledException(Error::Cast(msg_handler));
}
if (msg_handler.IsNull()) {
// If the port has been closed then the message will be dropped at this
// point. Make sure to post to the delivery failure port in that case.
if (message->RedirectToDeliveryFailurePort()) {
PortMap::PostMessage(message);
} else {
delete message;
}
return kOK;
}
}
// Parse the message.
MessageSnapshotReader reader(message->data(), message->len(), thread);
const Object& msg_obj = Object::Handle(zone, reader.ReadObject());
if (msg_obj.IsError()) {
// An error occurred while reading the message.
delete message;
return ProcessUnhandledException(Error::Cast(msg_obj));
}
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(zone);
msg ^= msg_obj.raw(); // Can't use Instance::Cast because may be null.
MessageStatus status = kOK;
if (message->IsOOB()) {
// OOB messages are expected to be fixed length arrays where the first
// element is a Smi describing the OOB destination. Messages that do not
// confirm to this layout are silently ignored.
if (msg.IsArray()) {
const Array& oob_msg = Array::Cast(msg);
if (oob_msg.Length() > 0) {
const Object& oob_tag = Object::Handle(zone, oob_msg.At(0));
if (oob_tag.IsSmi()) {
switch (Smi::Cast(oob_tag).Value()) {
case Message::kServiceOOBMsg: {
Service::HandleIsolateMessage(I, oob_msg);
break;
}
case Message::kIsolateLibOOBMsg: {
const Error& error = Error::Handle(HandleLibMessage(oob_msg));
if (!error.IsNull()) {
status = ProcessUnhandledException(error);
}
break;
}
#if defined(DEBUG)
// Malformed OOB messages are silently ignored in release builds.
default: {
UNREACHABLE();
break;
}
#endif // defined(DEBUG)
}
}
}
}
} else if (message->dest_port() == Message::kIllegalPort) {
// Check whether this is a delayed OOB message which needed handling as
// part of the regular message dispatch. All other messages are dropped on
// the floor.
if (msg.IsArray()) {
const Array& msg_arr = Array::Cast(msg);
if (msg_arr.Length() > 0) {
const Object& oob_tag = Object::Handle(zone, msg_arr.At(0));
if (oob_tag.IsSmi() &&
(Smi::Cast(oob_tag).Value() == Message::kDelayedIsolateLibOOBMsg)) {
const Error& error = Error::Handle(HandleLibMessage(msg_arr));
if (!error.IsNull()) {
status = ProcessUnhandledException(error);
}
}
}
}
} else {
const Object& result = Object::Handle(zone,
DartLibraryCalls::HandleMessage(msg_handler, msg));
if (result.IsError()) {
status = ProcessUnhandledException(Error::Cast(result));
} else {
ASSERT(result.IsNull());
}
}
delete message;
if (status == kOK) {
const Object& result =
Object::Handle(zone, I->InvokePendingServiceExtensionCalls());
if (result.IsError()) {
status = ProcessUnhandledException(Error::Cast(result));
} else {
ASSERT(result.IsNull());
}
}
return status;
}
void IsolateMessageHandler::NotifyPauseOnStart() {
if (Service::debug_stream.enabled()) {
StartIsolateScope start_isolate(I);
StackZone zone(T);
HandleScope handle_scope(T);
ServiceEvent pause_event(I, ServiceEvent::kPauseStart);
Service::HandleEvent(&pause_event);
} else if (FLAG_trace_service) {
OS::Print("vm-service: Dropping event of type PauseStart (%s)\n",
I->name());
}
}
void IsolateMessageHandler::NotifyPauseOnExit() {
if (Service::debug_stream.enabled()) {
StartIsolateScope start_isolate(I);
StackZone zone(T);
HandleScope handle_scope(T);
ServiceEvent pause_event(I, ServiceEvent::kPauseExit);
Service::HandleEvent(&pause_event);
} else if (FLAG_trace_service) {
OS::Print("vm-service: Dropping event of type PauseExit (%s)\n",
I->name());
}
}
#if defined(DEBUG)
void IsolateMessageHandler::CheckAccess() {
ASSERT(IsCurrentIsolate());
}
#endif
bool IsolateMessageHandler::IsCurrentIsolate() const {
return (I == Isolate::Current());
}
static MessageHandler::MessageStatus StoreError(Isolate* isolate,
const Error& error) {
isolate->object_store()->set_sticky_error(error);
if (error.IsUnwindError()) {
const UnwindError& unwind = UnwindError::Cast(error);
if (!unwind.is_user_initiated()) {
if (unwind.is_vm_restart()) {
return MessageHandler::kRestart;
} else {
return MessageHandler::kShutdown;
}
}
}
return MessageHandler::kError;
}
MessageHandler::MessageStatus IsolateMessageHandler::ProcessUnhandledException(
const Error& result) {
// Notify the debugger about specific unhandled exceptions which are withheld
// when being thrown.
if (result.IsUnhandledException()) {
const UnhandledException& error = UnhandledException::Cast(result);
RawInstance* exception = error.exception();
if ((exception == I->object_store()->out_of_memory()) ||
(exception == I->object_store()->stack_overflow())) {
// We didn't notify the debugger when the stack was full. Do it now.
I->debugger()->SignalExceptionThrown(Instance::Handle(exception));
}
}
// Invoke the isolate's unhandled exception callback if there is one.
if (Isolate::UnhandledExceptionCallback() != NULL) {
Dart_EnterScope();
Dart_Handle error = Api::NewHandle(I, result.raw());
(Isolate::UnhandledExceptionCallback())(error);
Dart_ExitScope();
}
// Generate the error and stacktrace strings for the error message.
String& exc_str = String::Handle(I->current_zone());
String& stacktrace_str = String::Handle(I->current_zone());
if (result.IsUnhandledException()) {
Zone* zone = I->current_zone();
const UnhandledException& uhe = UnhandledException::Cast(result);
const Instance& exception = Instance::Handle(zone, uhe.exception());
Object& tmp = Object::Handle(zone);
tmp = DartLibraryCalls::ToString(exception);
if (!tmp.IsString()) {
tmp = String::New(exception.ToCString());
}
exc_str ^= tmp.raw();
const Instance& stacktrace = Instance::Handle(zone, uhe.stacktrace());
tmp = DartLibraryCalls::ToString(stacktrace);
if (!tmp.IsString()) {
tmp = String::New(stacktrace.ToCString());
}
stacktrace_str ^= tmp.raw();;
} else {
exc_str = String::New(result.ToErrorCString());
}
if (result.IsUnwindError()) {
// When unwinding we don't notify error listeners and we ignore
// whether errors are fatal for the current isolate.
return StoreError(I, result);
} else {
bool has_listener = I->NotifyErrorListeners(exc_str, stacktrace_str);
if (I->ErrorsFatal()) {
if (has_listener) {
I->object_store()->clear_sticky_error();
} else {
I->object_store()->set_sticky_error(result);
}
return kError;
}
}
return kOK;
}
Isolate::Flags::Flags()
: type_checks_(FLAG_enable_type_checks),
asserts_(FLAG_enable_asserts),
error_on_bad_type_(FLAG_error_on_bad_type),
error_on_bad_override_(FLAG_error_on_bad_override) {}
void Isolate::Flags::CopyFrom(const Flags& orig) {
type_checks_ = orig.type_checks();
asserts_ = orig.asserts();
error_on_bad_type_ = orig.error_on_bad_type();
error_on_bad_override_ = orig.error_on_bad_override();
}
void Isolate::Flags::CopyFrom(const Dart_IsolateFlags& api_flags) {
type_checks_ = api_flags.enable_type_checks;
asserts_ = api_flags.enable_asserts;
// Leave others at defaults.
}
void Isolate::Flags::CopyTo(Dart_IsolateFlags* api_flags) const {
api_flags->version = DART_FLAGS_CURRENT_VERSION;
api_flags->enable_type_checks = type_checks();
api_flags->enable_asserts = asserts();
}
#if defined(DEBUG)
// static
void BaseIsolate::AssertCurrent(BaseIsolate* isolate) {
ASSERT(isolate == Isolate::Current());
}
void BaseIsolate::AssertCurrentThreadIsMutator() const {
ASSERT(Isolate::Current() == this);
ASSERT(Isolate::Current()->MutatorThreadIsCurrentThread());
}
#endif // defined(DEBUG)
#if defined(DEBUG)
#define REUSABLE_HANDLE_SCOPE_INIT(object) \
reusable_##object##_handle_scope_active_(false),
#else
#define REUSABLE_HANDLE_SCOPE_INIT(object)
#endif // defined(DEBUG)
#define REUSABLE_HANDLE_INITIALIZERS(object) \
object##_handle_(NULL),
Isolate::Isolate(const Dart_IsolateFlags& api_flags)
: stack_limit_(0),
store_buffer_(new StoreBuffer()),
heap_(NULL),
vm_tag_(0),
user_tag_(0),
current_tag_(UserTag::null()),
default_tag_(UserTag::null()),
class_table_(),
single_step_(false),
thread_registry_(new ThreadRegistry()),
message_notify_callback_(NULL),
name_(NULL),
debugger_name_(NULL),
start_time_(OS::GetCurrentTimeMicros()),
main_port_(0),
origin_id_(0),
pause_capability_(0),
terminate_capability_(0),
errors_fatal_(true),
object_store_(NULL),
top_exit_frame_info_(0),
init_callback_data_(NULL),
environment_callback_(NULL),
library_tag_handler_(NULL),
api_state_(NULL),
debugger_(NULL),
resume_request_(false),
last_resume_timestamp_(OS::GetCurrentTimeMillis()),
has_compiled_code_(false),
flags_(),
random_(),
simulator_(NULL),
mutex_(new Mutex()),
saved_stack_limit_(0),
stack_base_(0),
stack_overflow_flags_(0),
stack_overflow_count_(0),
message_handler_(NULL),
spawn_state_(NULL),
is_runnable_(false),
gc_prologue_callback_(NULL),
gc_epilogue_callback_(NULL),
defer_finalization_count_(0),
deopt_context_(NULL),
background_compiler_(NULL),
compiler_stats_(NULL),
is_service_isolate_(false),
stacktrace_(NULL),
stack_frame_index_(-1),
last_allocationprofile_accumulator_reset_timestamp_(0),
last_allocationprofile_gc_timestamp_(0),
object_id_ring_(NULL),
trace_buffer_(NULL),
profiler_data_(NULL),
tag_table_(GrowableObjectArray::null()),
collected_closures_(GrowableObjectArray::null()),
deoptimized_code_array_(GrowableObjectArray::null()),
background_compilation_queue_(GrowableObjectArray::null()),
pending_service_extension_calls_(GrowableObjectArray::null()),
registered_service_extension_handlers_(GrowableObjectArray::null()),
metrics_list_head_(NULL),
compilation_allowed_(true),
next_(NULL),
pause_loop_monitor_(NULL) {
flags_.CopyFrom(api_flags);
Thread::Current()->set_vm_tag(VMTag::kEmbedderTagId);
set_user_tag(UserTags::kDefaultUserTag);
}
#undef REUSABLE_HANDLE_SCOPE_INIT
#undef REUSABLE_HANDLE_INITIALIZERS
Isolate::~Isolate() {
free(name_);
free(debugger_name_);
delete store_buffer_;
delete heap_;
delete object_store_;
delete api_state_;
delete debugger_;
#if defined(USING_SIMULATOR)
delete simulator_;
#endif
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.
ASSERT(deopt_context_ == NULL); // No deopt in progress when isolate deleted.
delete spawn_state_;
delete object_id_ring_;
object_id_ring_ = NULL;
delete pause_loop_monitor_;
pause_loop_monitor_ = NULL;
if (compiler_stats_ != NULL) {
delete compiler_stats_;
compiler_stats_ = NULL;
}
delete thread_registry_;
}
#if defined(DEBUG)
bool Isolate::IsIsolateOf(Thread* thread) {
return this == thread->isolate();
}
#endif // DEBUG
void Isolate::InitOnce() {
create_callback_ = NULL;
isolates_list_monitor_ = new Monitor();
ASSERT(isolates_list_monitor_ != NULL);
EnableIsolateCreation();
}
Isolate* Isolate::Init(const char* name_prefix,
const Dart_IsolateFlags& api_flags,
bool is_vm_isolate) {
Isolate* result = new Isolate(api_flags);
ASSERT(result != NULL);
// Initialize metrics.
#define ISOLATE_METRIC_INIT(type, variable, name, unit) \
result->metric_##variable##_.Init(result, name, NULL, Metric::unit);
ISOLATE_METRIC_LIST(ISOLATE_METRIC_INIT);
#undef ISOLATE_METRIC_INIT
// Initialize Timeline streams.
#define ISOLATE_TIMELINE_STREAM_INIT(name, enabled_by_default) \
result->stream_##name##_.Init(#name, \
Timeline::EnableStreamByDefault(#name) || \
enabled_by_default, \
Timeline::Stream##name##EnabledFlag());
ISOLATE_TIMELINE_STREAM_LIST(ISOLATE_TIMELINE_STREAM_INIT);
#undef ISOLATE_TIMELINE_STREAM_INIT
Heap::Init(result,
is_vm_isolate
? 0 // New gen size 0; VM isolate should only allocate in old.
: FLAG_new_gen_semi_max_size * MBInWords,
FLAG_old_gen_heap_size * MBInWords,
FLAG_external_max_size * MBInWords);
// TODO(5411455): For now just set the recently created isolate as
// the current isolate.
Thread::EnterIsolate(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 limit (wait until later for the VM isolate, since the
// needed GetStackPointer stub has not yet been generated in that case).
if (!is_vm_isolate) {
result->InitializeStackLimit();
}
result->set_main_port(PortMap::CreatePort(result->message_handler()));
#if defined(DEBUG)
// Verify that we are never reusing a live origin id.
VerifyOriginId id_verifier(result->main_port());
Isolate::VisitIsolates(&id_verifier);
#endif
result->set_origin_id(result->main_port());
result->set_pause_capability(result->random()->NextUInt64());
result->set_terminate_capability(result->random()->NextUInt64());
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());
}
}
result->compiler_stats_ = new CompilerStats(result);
if (FLAG_compiler_benchmark) {
result->compiler_stats_->EnableBenchmark();
}
ObjectIdRing::Init(result);
// Add to isolate list. Shutdown and delete the isolate on failure.
if (!AddIsolateToList(result)) {
result->LowLevelShutdown();
Thread::ExitIsolate();
delete result;
return NULL;
}
return result;
}
void Isolate::InitializeStackLimit() {
SetStackLimitFromStackBase(Isolate::GetCurrentStackPointer());
}
/* static */
uword Isolate::GetCurrentStackPointer() {
// Since AddressSanitizer's detect_stack_use_after_return instruments the
// C++ code to give out fake stack addresses, we call a stub in that case.
uword (*func)() = reinterpret_cast<uword (*)()>(
StubCode::GetStackPointer_entry()->EntryPoint());
// But for performance (and to support simulators), we normally use a local.
#if defined(__has_feature)
#if __has_feature(address_sanitizer)
uword current_sp = func();
return current_sp;
#else
uword stack_allocated_local_address = reinterpret_cast<uword>(&func);
return stack_allocated_local_address;
#endif
#else
uword stack_allocated_local_address = reinterpret_cast<uword>(&func);
return stack_allocated_local_address;
#endif
}
void Isolate::SetupInstructionsSnapshotPage(
const uint8_t* instructions_snapshot_buffer) {
InstructionsSnapshot snapshot(instructions_snapshot_buffer);
#if defined(DEBUG)
if (FLAG_trace_isolates) {
OS::Print("Precompiled instructions are at [0x%" Px ", 0x%" Px ")\n",
reinterpret_cast<uword>(snapshot.instructions_start()),
reinterpret_cast<uword>(snapshot.instructions_start()) +
snapshot.instructions_size());
}
#endif
heap_->SetupInstructionsSnapshotPage(snapshot.instructions_start(),
snapshot.instructions_size());
}
void Isolate::set_debugger_name(const char* name) {
free(debugger_name_);
debugger_name_ = strdup(name);
}
void Isolate::BuildName(const char* name_prefix) {
ASSERT(name_ == NULL);
if (name_prefix == NULL) {
name_prefix = "isolate";
}
set_debugger_name(name_prefix);
if (ServiceIsolate::NameEquals(name_prefix)) {
name_ = strdup(name_prefix);
return;
}
name_ = OS::SCreate(NULL, "%s-%" Pd64 "", 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 < OSThread::GetMaxStackSize());
uword stack_size = OSThread::GetMaxStackSize() - Isolate::kStackSizeBuffer;
return stack_size;
}
void Isolate::SetStackLimitFromStackBase(uword stack_base) {
// Set stack base.
stack_base_ = stack_base;
// Set stack limit.
#if defined(USING_SIMULATOR)
// Ignore passed-in native stack top and use Simulator stack top.
Simulator* sim = Simulator::Current(); // May allocate a simulator.
ASSERT(simulator() == sim); // This isolate's simulator is the current one.
stack_base = sim->StackTop();
// The overflow area is accounted for by the simulator.
#endif
SetStackLimit(stack_base - GetSpecifiedStackSize());
}
void Isolate::SetStackLimit(uword limit) {
// The isolate setting the stack limit is not necessarily the isolate which
// the stack limit is being set on.
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::ClearStackLimit() {
SetStackLimit(~static_cast<uword>(0));
stack_base_ = 0;
}
bool Isolate::GetProfilerStackBounds(uword* lower, uword* upper) const {
uword stack_upper = stack_base_;
if (stack_upper == 0) {
return false;
}
uword stack_lower = stack_upper - GetSpecifiedStackSize();
*lower = stack_lower;
*upper = stack_upper;
return true;
}
void Isolate::ScheduleInterrupts(uword interrupt_bits) {
MutexLocker ml(mutex_);
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;
}
void Isolate::DoneLoading() {
GrowableObjectArray& libs = GrowableObjectArray::Handle(current_zone(),
object_store()->libraries());
Library& lib = Library::Handle(current_zone());
intptr_t num_libs = libs.Length();
for (intptr_t i = 0; i < num_libs; i++) {
lib ^= libs.At(i);
// If this library was loaded with Dart_LoadLibrary, it was marked
// as 'load in progres'. Set the status to 'loaded'.
if (lib.LoadInProgress()) {
lib.SetLoaded();
}
}
}
bool Isolate::MakeRunnable() {
ASSERT(Isolate::Current() == NULL);
MutexLocker ml(mutex_);
// Check if we are in a valid state to make the isolate runnable.
if (is_runnable() == true) {
return false; // Already runnable.
}
// Set the isolate as runnable and if we are being spawned schedule
// isolate on thread pool for execution.
ASSERT(object_store()->root_library() != Library::null());
set_is_runnable(true);
if (!ServiceIsolate::IsServiceIsolate(this)) {
message_handler()->set_pause_on_start(FLAG_pause_isolates_on_start);
message_handler()->set_pause_on_exit(FLAG_pause_isolates_on_exit);
}
IsolateSpawnState* state = spawn_state();
if (state != NULL) {
ASSERT(this == state->isolate());
Run();
}
TimelineStream* stream = GetIsolateStream();
ASSERT(stream != NULL);
TimelineEvent* event = stream->StartEvent();
if (event != NULL) {
event->Instant("Runnable");
event->Complete();
}
if (Service::isolate_stream.enabled()) {
ServiceEvent runnableEvent(this, ServiceEvent::kIsolateRunnable);
Service::HandleEvent(&runnableEvent);
}
return true;
}
bool Isolate::VerifyPauseCapability(const Object& capability) const {
return !capability.IsNull() &&
capability.IsCapability() &&
(pause_capability() == Capability::Cast(capability).Id());
}
bool Isolate::VerifyTerminateCapability(const Object& capability) const {
return !capability.IsNull() &&
capability.IsCapability() &&
(terminate_capability() == Capability::Cast(capability).Id());
}
bool Isolate::AddResumeCapability(const Capability& capability) {
// Ensure a limit for the number of resume capabilities remembered.
static const intptr_t kMaxResumeCapabilities = kSmiMax / (6 * kWordSize);
const GrowableObjectArray& caps = GrowableObjectArray::Handle(
current_zone(), object_store()->resume_capabilities());
Capability& current = Capability::Handle(current_zone());
intptr_t insertion_index = -1;
for (intptr_t i = 0; i < caps.Length(); i++) {
current ^= caps.At(i);
if (current.IsNull()) {
if (insertion_index < 0) {
insertion_index = i;
}
} else if (current.Id() == capability.Id()) {
return false;
}
}
if (insertion_index < 0) {
if (caps.Length() >= kMaxResumeCapabilities) {
// Cannot grow the array of resume capabilities beyond its max. Additional
// pause requests are ignored. In practice will never happen as we will
// run out of memory beforehand.
return false;
}
caps.Add(capability);
} else {
caps.SetAt(insertion_index, capability);
}
return true;
}
bool Isolate::RemoveResumeCapability(const Capability& capability) {
const GrowableObjectArray& caps = GrowableObjectArray::Handle(
current_zone(), object_store()->resume_capabilities());
Capability& current = Capability::Handle(current_zone());
for (intptr_t i = 0; i < caps.Length(); i++) {
current ^= caps.At(i);
if (!current.IsNull() && (current.Id() == capability.Id())) {
// Remove the matching capability from the list.
current = Capability::null();
caps.SetAt(i, current);
return true;
}
}
return false;
}
// TODO(iposva): Remove duplicated code and start using some hash based
// structure instead of these linear lookups.
void Isolate::AddExitListener(const SendPort& listener,
const Instance& response) {
// Ensure a limit for the number of listeners remembered.
static const intptr_t kMaxListeners = kSmiMax / (12 * kWordSize);
const GrowableObjectArray& listeners = GrowableObjectArray::Handle(
current_zone(), object_store()->exit_listeners());
SendPort& current = SendPort::Handle(current_zone());
intptr_t insertion_index = -1;
for (intptr_t i = 0; i < listeners.Length(); i += 2) {
current ^= listeners.At(i);
if (current.IsNull()) {
if (insertion_index < 0) {
insertion_index = i;
}
} else if (current.Id() == listener.Id()) {
listeners.SetAt(i + 1, response);
return;
}
}
if (insertion_index < 0) {
if (listeners.Length() >= kMaxListeners) {
// Cannot grow the array of listeners beyond its max. Additional
// listeners are ignored. In practice will never happen as we will
// run out of memory beforehand.
return;
}
listeners.Add(listener);
listeners.Add(response);
} else {
listeners.SetAt(insertion_index, listener);
listeners.SetAt(insertion_index + 1, response);
}
}
void Isolate::RemoveExitListener(const SendPort& listener) {
const GrowableObjectArray& listeners = GrowableObjectArray::Handle(
current_zone(), object_store()->exit_listeners());
SendPort& current = SendPort::Handle(current_zone());
for (intptr_t i = 0; i < listeners.Length(); i += 2) {
current ^= listeners.At(i);
if (!current.IsNull() && (current.Id() == listener.Id())) {
// Remove the matching listener from the list.
current = SendPort::null();
listeners.SetAt(i, current);
listeners.SetAt(i + 1, Object::null_instance());
return;
}
}
}
void Isolate::NotifyExitListeners() {
const GrowableObjectArray& listeners = GrowableObjectArray::Handle(
current_zone(), this->object_store()->exit_listeners());
if (listeners.IsNull()) return;
SendPort& listener = SendPort::Handle(current_zone());
Instance& response = Instance::Handle(current_zone());
for (intptr_t i = 0; i < listeners.Length(); i += 2) {
listener ^= listeners.At(i);
if (!listener.IsNull()) {
Dart_Port port_id = listener.Id();
uint8_t* data = NULL;
intptr_t len = 0;
response ^= listeners.At(i + 1);
SerializeObject(response, &data, &len, false);
Message* msg = new Message(port_id, data, len, Message::kNormalPriority);
PortMap::PostMessage(msg);
}
}
}
void Isolate::AddErrorListener(const SendPort& listener) {
// Ensure a limit for the number of listeners remembered.
static const intptr_t kMaxListeners = kSmiMax / (6 * kWordSize);
const GrowableObjectArray& listeners = GrowableObjectArray::Handle(
current_zone(), object_store()->error_listeners());
SendPort& current = SendPort::Handle(current_zone());
intptr_t insertion_index = -1;
for (intptr_t i = 0; i < listeners.Length(); i++) {
current ^= listeners.At(i);
if (current.IsNull()) {
if (insertion_index < 0) {
insertion_index = i;
}
} else if (current.Id() == listener.Id()) {
return;
}
}
if (insertion_index < 0) {
if (listeners.Length() >= kMaxListeners) {
// Cannot grow the array of listeners beyond its max. Additional
// listeners are ignored. In practice will never happen as we will
// run out of memory beforehand.
return;
}
listeners.Add(listener);
} else {
listeners.SetAt(insertion_index, listener);
}
}
void Isolate::RemoveErrorListener(const SendPort& listener) {
const GrowableObjectArray& listeners = GrowableObjectArray::Handle(
current_zone(), object_store()->error_listeners());
SendPort& current = SendPort::Handle(current_zone());
for (intptr_t i = 0; i < listeners.Length(); i++) {
current ^= listeners.At(i);
if (!current.IsNull() && (current.Id() == listener.Id())) {
// Remove the matching listener from the list.
current = SendPort::null();
listeners.SetAt(i, current);
return;
}
}
}
bool Isolate::NotifyErrorListeners(const String& msg,
const String& stacktrace) {
const GrowableObjectArray& listeners = GrowableObjectArray::Handle(
current_zone(), this->object_store()->error_listeners());
if (listeners.IsNull()) return false;
const Array& arr = Array::Handle(current_zone(), Array::New(2));
arr.SetAt(0, msg);
arr.SetAt(1, stacktrace);
SendPort& listener = SendPort::Handle(current_zone());
for (intptr_t i = 0; i < listeners.Length(); i++) {
listener ^= listeners.At(i);
if (!listener.IsNull()) {
Dart_Port port_id = listener.Id();
uint8_t* data = NULL;
intptr_t len = 0;
SerializeObject(arr, &data, &len, false);
Message* msg = new Message(port_id, data, len, Message::kNormalPriority);
PortMap::PostMessage(msg);
}
}
return listeners.Length() > 0;
}
static MessageHandler::MessageStatus RunIsolate(uword parameter) {
Isolate* isolate = reinterpret_cast<Isolate*>(parameter);
IsolateSpawnState* state = NULL;
Thread* thread = Thread::Current();
{
// TODO(turnidge): Is this locking required here at all anymore?
MutexLocker ml(isolate->mutex());
state = isolate->spawn_state();
}
{
StartIsolateScope start_scope(isolate);
ASSERT(thread->isolate() == isolate);
StackZone zone(thread);
HandleScope handle_scope(thread);
// If particular values were requested for this newly spawned isolate, then
// they are set here before the isolate starts executing user code.
isolate->SetErrorsFatal(state->errors_are_fatal());
if (state->on_exit_port() != ILLEGAL_PORT) {
const SendPort& listener =
SendPort::Handle(SendPort::New(state->on_exit_port()));
isolate->AddExitListener(listener, Instance::null_instance());
}
if (state->on_error_port() != ILLEGAL_PORT) {
const SendPort& listener =
SendPort::Handle(SendPort::New(state->on_error_port()));
isolate->AddErrorListener(listener);
}
// Switch back to spawning isolate.
if (!ClassFinalizer::ProcessPendingClasses()) {
// Error is in sticky error already.
#if defined(DEBUG)
const Error& error =
Error::Handle(isolate->object_store()->sticky_error());
ASSERT(!error.IsUnwindError());
#endif
return MessageHandler::kError;
}
Object& result = Object::Handle();
result = state->ResolveFunction();
bool is_spawn_uri = state->is_spawn_uri();
if (result.IsError()) {
return StoreError(isolate, Error::Cast(result));
}
ASSERT(result.IsFunction());
Function& func = Function::Handle(thread->zone());
func ^= result.raw();
// TODO(turnidge): Currently we need a way to force a one-time
// breakpoint for all spawned isolates to support isolate
// debugging. Remove this once the vmservice becomes the standard
// way to debug. Set the breakpoint on the static function instead
// of its implicit closure function because that latter is merely
// a dispatcher that is marked as undebuggable.
if (FLAG_break_at_isolate_spawn) {
isolate->debugger()->OneTimeBreakAtEntry(func);
}
func = func.ImplicitClosureFunction();
const Array& capabilities = Array::Handle(Array::New(2));
Capability& capability = Capability::Handle();
capability = Capability::New(isolate->pause_capability());
capabilities.SetAt(0, capability);
// Check whether this isolate should be started in paused state.
if (state->paused()) {
bool added = isolate->AddResumeCapability(capability);
ASSERT(added); // There should be no pending resume capabilities.
isolate->message_handler()->increment_paused();
}
capability = Capability::New(isolate->terminate_capability());
capabilities.SetAt(1, capability);
// Instead of directly invoking the entry point we call '_startIsolate' with
// the entry point as argument.
// Since this function ("RunIsolate") is used for both Isolate.spawn and
// Isolate.spawnUri we also send a boolean flag as argument so that the
// "_startIsolate" function can act corresponding to how the isolate was
// created.
const Array& args = Array::Handle(Array::New(7));
args.SetAt(0, SendPort::Handle(SendPort::New(state->parent_port())));
args.SetAt(1, Instance::Handle(func.ImplicitStaticClosure()));
args.SetAt(2, Instance::Handle(state->BuildArgs(thread)));
args.SetAt(3, Instance::Handle(state->BuildMessage(thread)));
args.SetAt(4, is_spawn_uri ? Bool::True() : Bool::False());
args.SetAt(5, ReceivePort::Handle(
ReceivePort::New(isolate->main_port(), true /* control port */)));
args.SetAt(6, capabilities);
const Library& lib = Library::Handle(Library::IsolateLibrary());
const String& entry_name = String::Handle(String::New("_startIsolate"));
const Function& entry_point =
Function::Handle(lib.LookupLocalFunction(entry_name));
ASSERT(entry_point.IsFunction() && !entry_point.IsNull());
result = DartEntry::InvokeFunction(entry_point, args);
if (result.IsError()) {
return StoreError(isolate, Error::Cast(result));
}
}
return MessageHandler::kOK;
}
static void ShutdownIsolate(uword parameter) {
Isolate* isolate = reinterpret_cast<Isolate*>(parameter);
{
// Print the error if there is one. This may execute dart code to
// print the exception object, so we need to use a StartIsolateScope.
Thread* thread = Thread::Current();
StartIsolateScope start_scope(isolate);
ASSERT(thread->isolate() == isolate);
StackZone zone(thread);
HandleScope handle_scope(thread);
const Error& error = Error::Handle(isolate->object_store()->sticky_error());
if (!error.IsNull() && !error.IsUnwindError()) {
OS::PrintErr("in ShutdownIsolate: %s\n", error.ToErrorCString());
}
Dart::RunShutdownCallback();
}
{
// Shut the isolate down.
SwitchIsolateScope switch_scope(isolate);
Dart::ShutdownIsolate();
}
}
void Isolate::Run() {
message_handler()->Run(Dart::thread_pool(),
RunIsolate,
ShutdownIsolate,
reinterpret_cast<uword>(this));
}
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;
}
RawError* Isolate::HandleInterrupts() {
uword interrupt_bits = GetAndClearInterrupts();
if ((interrupt_bits & kVMInterrupt) != 0) {
thread_registry()->CheckSafepoint();
if (store_buffer()->Overflowed()) {
if (FLAG_verbose_gc) {
OS::PrintErr("Scavenge scheduled by store buffer overflow.\n");
}
heap()->CollectGarbage(Heap::kNew);
}
}
if ((interrupt_bits & kMessageInterrupt) != 0) {
MessageHandler::MessageStatus status =
message_handler()->HandleOOBMessages();
if (status != MessageHandler::kOK) {
// False result from HandleOOBMessages signals that the isolate should
// be terminating.
if (FLAG_trace_isolates) {
OS::Print("[!] Terminating isolate due to OOB message:\n"
"\tisolate: %s\n", name());
}
const Error& error = Error::Handle(object_store()->sticky_error());
ASSERT(!error.IsNull() && error.IsUnwindError());
object_store()->clear_sticky_error();
return error.raw();
}
}
return Error::null();
}
uword Isolate::GetAndClearStackOverflowFlags() {
uword stack_overflow_flags = stack_overflow_flags_;
stack_overflow_flags_ = 0;
return stack_overflow_flags;
}
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());
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,
ClassDictionaryIterator::kIteratePrivate);
while (iter.HasNext()) {
cls = iter.GetNextClass();
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() : HandleVisitor(Thread::Current()) {
}
void VisitHandle(uword addr) {
FinalizablePersistentHandle* handle =
reinterpret_cast<FinalizablePersistentHandle*>(addr);
handle->UpdateUnreachable(thread()->isolate());
}
private:
DISALLOW_COPY_AND_ASSIGN(FinalizeWeakPersistentHandlesVisitor);
};
void Isolate::LowLevelShutdown() {
// Ensure we have a zone and handle scope so that we can call VM functions,
// but we no longer allocate new heap objects.
Thread* thread = Thread::Current();
StackZone stack_zone(thread);
HandleScope handle_scope(thread);
NoSafepointScope no_safepoint_scope;
// Notify exit listeners that this isolate is shutting down.
if (object_store() != NULL) {
const Error& error = Error::Handle(object_store()->sticky_error());
if (error.IsNull() ||
!error.IsUnwindError() ||
UnwindError::Cast(error).is_user_initiated()) {
NotifyExitListeners();
}
}
// Clean up debugger resources.
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);
// Before analyzing the isolate's timeline blocks- reclaim all cached blocks.
ReclaimTimelineBlocks();
// Dump all timing data for the isolate.
if (FLAG_timing) {
TimelinePauseTrace tpt;
tpt.Print();
}
// Finalize any weak persistent handles with a non-null referent.
FinalizeWeakPersistentHandlesVisitor visitor;
api_state()->weak_persistent_handles().VisitHandles(&visitor);
api_state()->prologue_weak_persistent_handles().VisitHandles(&visitor);
if (FLAG_trace_isolates) {
heap()->PrintSizes();
MegamorphicCacheTable::PrintSizes(this);
Symbols::DumpStats();
OS::Print("[-] Stopping isolate:\n"
"\tisolate: %s\n", name());
}
if (FLAG_print_metrics) {
LogBlock lb;
THR_Print("Printing metrics for %s\n", name());
#define ISOLATE_METRIC_PRINT(type, variable, name, unit) \
THR_Print("%s\n", metric_##variable##_.ToString());
ISOLATE_METRIC_LIST(ISOLATE_METRIC_PRINT);
#undef ISOLATE_METRIC_PRINT
THR_Print("\n");
}
}
void Isolate::Shutdown() {
ASSERT(this == Isolate::Current());
ASSERT(top_resource() == NULL);
#if defined(DEBUG)
if (heap_ != NULL) {
// The VM isolate keeps all objects marked.
heap_->Verify(this == Dart::vm_isolate() ? kRequireMarked : kForbidMarked);
}
#endif // DEBUG
Thread* thread = Thread::Current();
// First, perform higher-level cleanup that may need to allocate.
{
// Ensure we have a zone and handle scope so that we can call VM functions.
StackZone stack_zone(thread);
HandleScope handle_scope(thread);
// Write out the coverage data if collection has been enabled.
if ((this != Dart::vm_isolate()) &&
!ServiceIsolate::IsServiceIsolateDescendant(this)) {
CodeCoverage::Write(thread);
}
// Write compiler stats data if enabled.
if (FLAG_compiler_stats
&& !ServiceIsolate::IsServiceIsolateDescendant(this)
&& (this != Dart::vm_isolate())) {
OS::Print("%s", compiler_stats()->PrintToZone());
}
}
// Remove this isolate from the list *before* we start tearing it down, to
// avoid exposing it in a state of decay.
RemoveIsolateFromList(this);
if (heap_ != NULL) {
// Wait for any concurrent GC tasks to finish before shutting down.
// TODO(koda): Support faster sweeper shutdown (e.g., after current page).
PageSpace* old_space = heap_->old_space();
MonitorLocker ml(old_space->tasks_lock());
while (old_space->tasks() > 0) {
ml.Wait();
}
}
// Then, proceed with low-level teardown.
LowLevelShutdown();
#if defined(DEBUG)
// No concurrent sweeper tasks should be running at this point.
if (heap_ != NULL) {
PageSpace* old_space = heap_->old_space();
MonitorLocker ml(old_space->tasks_lock());
ASSERT(old_space->tasks() == 0);
}
#endif
BackgroundCompiler::Stop(background_compiler_);
// TODO(5411455): For now just make sure there are no current isolates
// as we are shutting down the isolate.
Thread::ExitIsolate();
// All threads should have exited by now.
thread_registry()->CheckNotScheduled(this);
Profiler::ShutdownProfilingForIsolate(this);
}
void Isolate::ReclaimTimelineBlocks() {
TimelineEventRecorder* recorder = Timeline::recorder();
if (recorder == NULL) {
return;
}
thread_registry_->ReclaimTimelineBlocks();
}
Dart_IsolateCreateCallback Isolate::create_callback_ = NULL;
Dart_IsolateInterruptCallback Isolate::interrupt_callback_ = NULL;
Dart_IsolateUnhandledExceptionCallback
Isolate::unhandled_exception_callback_ = NULL;
Dart_IsolateShutdownCallback Isolate::shutdown_callback_ = NULL;
Dart_FileOpenCallback Isolate::file_open_callback_ = NULL;
Dart_FileReadCallback Isolate::file_read_callback_ = NULL;
Dart_FileWriteCallback Isolate::file_write_callback_ = NULL;
Dart_FileCloseCallback Isolate::file_close_callback_ = NULL;
Dart_EntropySource Isolate::entropy_source_callback_ = NULL;
Monitor* Isolate::isolates_list_monitor_ = NULL;
Isolate* Isolate::isolates_list_head_ = NULL;
bool Isolate::creation_enabled_ = false;
void Isolate::IterateObjectPointers(ObjectPointerVisitor* visitor,
bool visit_prologue_weak_handles,
bool validate_frames) {
HeapIterationScope heap_iteration_scope;
VisitObjectPointers(visitor, visit_prologue_weak_handles, validate_frames);
}
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 the dart api state for all local and persistent handles.
if (api_state() != NULL) {
api_state()->VisitObjectPointers(visitor, visit_prologue_weak_handles);
}
// Visit the current tag which is stored in the isolate.
visitor->VisitPointer(reinterpret_cast<RawObject**>(&current_tag_));
// Visit the default tag which is stored in the isolate.
visitor->VisitPointer(reinterpret_cast<RawObject**>(&default_tag_));
// Visit the tag table which is stored in the isolate.
visitor->VisitPointer(reinterpret_cast<RawObject**>(&tag_table_));
// Visit array of closures pending precompilation.
visitor->VisitPointer(reinterpret_cast<RawObject**>(&collected_closures_));
visitor->VisitPointer(reinterpret_cast<RawObject**>(
&background_compilation_queue_));
// Visit the deoptimized code array which is stored in the isolate.
visitor->VisitPointer(
reinterpret_cast<RawObject**>(&deoptimized_code_array_));
// Visit the pending service extension calls.
visitor->VisitPointer(
reinterpret_cast<RawObject**>(&pending_service_extension_calls_));
// Visit the registered service extension handlers.
visitor->VisitPointer(
reinterpret_cast<RawObject**>(&registered_service_extension_handlers_));
// Visit objects in the debugger.
debugger()->VisitObjectPointers(visitor);
// Visit objects that are being used for deoptimization.
if (deopt_context() != NULL) {
deopt_context()->VisitObjectPointers(visitor);
}
// Visit objects in thread registry (e.g., Dart stack, handles in zones).
thread_registry()->VisitObjectPointers(visitor, validate_frames);
}
void Isolate::VisitWeakPersistentHandles(HandleVisitor* visitor,
bool visit_prologue_weak_handles) {
if (api_state() != NULL) {
api_state()->VisitWeakHandles(visitor, visit_prologue_weak_handles);
}
}
void Isolate::VisitPrologueWeakPersistentHandles(HandleVisitor* visitor) {
if (api_state() != NULL) {
api_state()->VisitPrologueWeakHandles(visitor);
}
}
static const char* ExceptionPauseInfoToServiceEnum(Dart_ExceptionPauseInfo pi) {
switch (pi) {
case kPauseOnAllExceptions:
return "All";
case kNoPauseOnExceptions:
return "None";
case kPauseOnUnhandledExceptions:
return "Unhandled";
default:
UNIMPLEMENTED();
return NULL;
}
}
void Isolate::PrintJSON(JSONStream* stream, bool ref) {
JSONObject jsobj(stream);
jsobj.AddProperty("type", (ref ? "@Isolate" : "Isolate"));
jsobj.AddFixedServiceId("isolates/%" Pd "",
static_cast<intptr_t>(main_port()));
jsobj.AddProperty("name", debugger_name());
jsobj.AddPropertyF("number", "%" Pd "",
static_cast<intptr_t>(main_port()));
if (ref) {
return;
}
jsobj.AddPropertyF("_originNumber", "%" Pd "",
static_cast<intptr_t>(origin_id()));
int64_t start_time_millis = start_time() / kMicrosecondsPerMillisecond;
jsobj.AddPropertyTimeMillis("startTime", start_time_millis);
{
JSONObject jsheap(&jsobj, "_heaps");
heap()->PrintToJSONObject(Heap::kNew, &jsheap);
heap()->PrintToJSONObject(Heap::kOld, &jsheap);
}
jsobj.AddProperty("livePorts", message_handler()->live_ports());
jsobj.AddProperty("pauseOnExit", message_handler()->pause_on_exit());
if (message_handler()->paused_on_start()) {
ASSERT(debugger()->PauseEvent() == NULL);
ServiceEvent pause_event(this, ServiceEvent::kPauseStart);
jsobj.AddProperty("pauseEvent", &pause_event);
} else if (message_handler()->paused_on_exit()) {
ASSERT(debugger()->PauseEvent() == NULL);
ServiceEvent pause_event(this, ServiceEvent::kPauseExit);
jsobj.AddProperty("pauseEvent", &pause_event);
} else if (debugger()->PauseEvent() != NULL && !resume_request_) {
ServiceEvent pause_event(debugger()->PauseEvent());
jsobj.AddProperty("pauseEvent", &pause_event);
} else {
ServiceEvent pause_event(this, ServiceEvent::kResume);
// TODO(turnidge): Don't compute a full stack trace.
DebuggerStackTrace* stack = debugger()->StackTrace();
if (stack->Length() > 0) {
pause_event.set_top_frame(stack->FrameAt(0));
}
jsobj.AddProperty("pauseEvent", &pause_event);
}
jsobj.AddProperty("exceptionPauseMode",
ExceptionPauseInfoToServiceEnum(debugger()->GetExceptionPauseInfo()));
const Library& lib =
Library::Handle(object_store()->root_library());
if (!lib.IsNull()) {
jsobj.AddProperty("rootLib", lib);
}
{
JSONObject tagCounters(&jsobj, "_tagCounters");
vm_tag_counters()->PrintToJSONObject(&tagCounters);
}
if (object_store()->sticky_error() != Object::null()) {
Error& error = Error::Handle(current_zone(),
object_store()->sticky_error());
ASSERT(!error.IsNull());
jsobj.AddProperty("error", error, false);
}
{
const GrowableObjectArray& libs =
GrowableObjectArray::Handle(object_store()->libraries());
intptr_t num_libs = libs.Length();
Library& lib = Library::Handle();
JSONArray lib_array(&jsobj, "libraries");
for (intptr_t i = 0; i < num_libs; i++) {
lib ^= libs.At(i);
ASSERT(!lib.IsNull());
lib_array.AddValue(lib);
}
}
{
JSONArray breakpoints(&jsobj, "breakpoints");
debugger()->PrintBreakpointsToJSONArray(&breakpoints);
}
{
JSONObject jssettings(&jsobj, "_debuggerSettings");
debugger()->PrintSettingsToJSONObject(&jssettings);
}
}
intptr_t Isolate::ProfileInterrupt() {
// Other threads might be modifying these fields. Save them in locals so that
// we can at least trust the NULL check.
IsolateProfilerData* prof_data = profiler_data();
if (prof_data == NULL) {
// Profiler not setup for isolate.
return 0;
}
if (prof_data->blocked()) {
// Profiler blocked for this isolate.
return 0;
}
Debugger* debug = debugger();
if ((debug != NULL) && debug->IsPaused()) {
// Paused at breakpoint. Don't tick.
return 0;
}
MessageHandler* msg_handler = message_handler();
if ((msg_handler != NULL) &&
(msg_handler->paused_on_start() ||
msg_handler->paused_on_exit())) {
// Paused at start / exit . Don't tick.
return 0;
}
// Make sure that the isolate's mutator thread does not change behind our
// backs. Otherwise we find the entry in the registry and end up reading
// the field again. Only by that time it has been reset to NULL because the
// thread was in process of exiting the isolate.
Thread* mutator = mutator_thread_;
if (mutator == NULL) {
// No active mutator.
ProfileIdle();
return 1;
}
// TODO(johnmccutchan): Sample all threads, not just the mutator thread.
// TODO(johnmccutchan): Keep a global list of threads and use that
// instead of Isolate.
ThreadRegistry::EntryIterator it(thread_registry());
while (it.HasNext()) {
const ThreadRegistry::Entry& entry = it.Next();
if (entry.thread == mutator) {
ThreadInterrupter::InterruptThread(mutator);
break;
}
}
return 1;
}
void Isolate::ProfileIdle() {
// Currently we are only sampling the mutator thread.
vm_tag_counters_.Increment(VMTag::kIdleTagId);
}
void Isolate::set_tag_table(const GrowableObjectArray& value) {
tag_table_ = value.raw();
}
void Isolate::set_current_tag(const UserTag& tag) {
uword user_tag = tag.tag();
ASSERT(user_tag < kUwordMax);
set_user_tag(user_tag);
current_tag_ = tag.raw();
}
void Isolate::set_default_tag(const UserTag& tag) {
default_tag_ = tag.raw();
}
void Isolate::set_collected_closures(const GrowableObjectArray& value) {
collected_closures_ = value.raw();
}
void Isolate::set_deoptimized_code_array(const GrowableObjectArray& value) {
deoptimized_code_array_ = value.raw();
}
void Isolate::set_background_compilation_queue(
const GrowableObjectArray& value) {
background_compilation_queue_ = value.raw();
}
void Isolate::TrackDeoptimizedCode(const Code& code) {
ASSERT(!code.IsNull());
const GrowableObjectArray& deoptimized_code =
GrowableObjectArray::Handle(deoptimized_code_array());
if (deoptimized_code.IsNull()) {
// Not tracking deoptimized code.
return;
}
// TODO(johnmccutchan): Scan this array and the isolate's profile before
// old space GC and remove the keep_code flag.
deoptimized_code.Add(code);
}
void Isolate::set_pending_service_extension_calls(
const GrowableObjectArray& value) {
pending_service_extension_calls_ = value.raw();
}
void Isolate::set_registered_service_extension_handlers(
const GrowableObjectArray& value) {
registered_service_extension_handlers_ = value.raw();
}
RawObject* Isolate::InvokePendingServiceExtensionCalls() {
GrowableObjectArray& calls =
GrowableObjectArray::Handle(GetAndClearPendingServiceExtensionCalls());
if (calls.IsNull()) {
return Object::null();
}
// Grab run function.
const Library& developer_lib = Library::Handle(Library::DeveloperLibrary());
ASSERT(!developer_lib.IsNull());
const Function& run_extension = Function::Handle(
developer_lib.LookupLocalFunction(Symbols::_runExtension()));
ASSERT(!run_extension.IsNull());
const Array& arguments =
Array::Handle(Array::New(kPendingEntrySize, Heap::kNew));
Object& result = Object::Handle();
String& method_name = String::Handle();
Instance& closure = Instance::Handle();
Array& parameter_keys = Array::Handle();
Array& parameter_values = Array::Handle();
Instance& reply_port = Instance::Handle();
Instance& id = Instance::Handle();
for (intptr_t i = 0; i < calls.Length(); i += kPendingEntrySize) {
// Grab arguments for call.
closure ^= calls.At(i + kPendingHandlerIndex);
ASSERT(!closure.IsNull());
arguments.SetAt(kPendingHandlerIndex, closure);
method_name ^= calls.At(i + kPendingMethodNameIndex);
ASSERT(!method_name.IsNull());
arguments.SetAt(kPendingMethodNameIndex, method_name);
parameter_keys ^= calls.At(i + kPendingKeysIndex);
ASSERT(!parameter_keys.IsNull());
arguments.SetAt(kPendingKeysIndex, parameter_keys);
parameter_values ^= calls.At(i + kPendingValuesIndex);
ASSERT(!parameter_values.IsNull());
arguments.SetAt(kPendingValuesIndex, parameter_values);
reply_port ^= calls.At(i + kPendingReplyPortIndex);
ASSERT(!reply_port.IsNull());
arguments.SetAt(kPendingReplyPortIndex, reply_port);
id ^= calls.At(i + kPendingIdIndex);
arguments.SetAt(kPendingIdIndex, id);
result = DartEntry::InvokeFunction(run_extension, arguments);
if (result.IsError()) {
if (result.IsUnwindError()) {
// Propagate the unwind error. Remaining service extension calls
// are dropped.
return result.raw();
} else {
// Send error back over the protocol.
Service::PostError(method_name,
parameter_keys,
parameter_values,
reply_port,
id,
Error::Cast(result));
}
}
result = DartLibraryCalls::DrainMicrotaskQueue();
if (result.IsError()) {
return result.raw();
}
}
return Object::null();
}
RawGrowableObjectArray* Isolate::GetAndClearPendingServiceExtensionCalls() {
RawGrowableObjectArray* r = pending_service_extension_calls_;
pending_service_extension_calls_ = GrowableObjectArray::null();
return r;
}
void Isolate::AppendServiceExtensionCall(const Instance& closure,
const String& method_name,
const Array& parameter_keys,
const Array& parameter_values,
const Instance& reply_port,
const Instance& id) {
GrowableObjectArray& calls =
GrowableObjectArray::Handle(pending_service_extension_calls());
if (calls.IsNull()) {
calls ^= GrowableObjectArray::New();
ASSERT(!calls.IsNull());
set_pending_service_extension_calls(calls);
}
ASSERT(kPendingHandlerIndex == 0);
calls.Add(closure);
ASSERT(kPendingMethodNameIndex == 1);
calls.Add(method_name);
ASSERT(kPendingKeysIndex == 2);
calls.Add(parameter_keys);
ASSERT(kPendingValuesIndex == 3);
calls.Add(parameter_values);
ASSERT(kPendingReplyPortIndex == 4);
calls.Add(reply_port);
ASSERT(kPendingIdIndex == 5);
calls.Add(id);
}
// This function is written in C++ and not Dart because we must do this
// operation atomically in the face of random OOB messages. Do not port
// to Dart code unless you can ensure that the operations will can be
// done atomically.
void Isolate::RegisterServiceExtensionHandler(const String& name,
const Instance& closure) {
GrowableObjectArray& handlers =
GrowableObjectArray::Handle(registered_service_extension_handlers());
if (handlers.IsNull()) {
handlers ^= GrowableObjectArray::New(Heap::kOld);
set_registered_service_extension_handlers(handlers);
}
#if defined(DEBUG)
{
// Sanity check.
const Instance& existing_handler =
Instance::Handle(LookupServiceExtensionHandler(name));
ASSERT(existing_handler.IsNull());
}
#endif
ASSERT(kRegisteredNameIndex == 0);
handlers.Add(name, Heap::kOld);
ASSERT(kRegisteredHandlerIndex == 1);
handlers.Add(closure, Heap::kOld);
}
// This function is written in C++ and not Dart because we must do this
// operation atomically in the face of random OOB messages. Do not port
// to Dart code unless you can ensure that the operations will can be
// done atomically.
RawInstance* Isolate::LookupServiceExtensionHandler(const String& name) {
const GrowableObjectArray& handlers =
GrowableObjectArray::Handle(registered_service_extension_handlers());
if (handlers.IsNull()) {
return Instance::null();
}
String& handler_name = String::Handle();
for (intptr_t i = 0; i < handlers.Length(); i += kRegisteredEntrySize) {
handler_name ^= handlers.At(i + kRegisteredNameIndex);
ASSERT(!handler_name.IsNull());
if (handler_name.Equals(name)) {
return Instance::RawCast(handlers.At(i + kRegisteredHandlerIndex));
}
}
return Instance::null();
}
void Isolate::WakePauseEventHandler(Dart_Isolate isolate) {
Isolate* iso = reinterpret_cast<Isolate*>(isolate);
MonitorLocker ml(iso->pause_loop_monitor_);
ml.Notify();
}
void Isolate::PauseEventHandler() {
// We are stealing a pause event (like a breakpoint) from the
// embedder. We don't know what kind of thread we are on -- it
// could be from our thread pool or it could be a thread from the
// embedder. Sit on the current thread handling service events
// until we are told to resume.
if (pause_loop_monitor_ == NULL) {
pause_loop_monitor_ = new Monitor();
}
Dart_EnterScope();
MonitorLocker ml(pause_loop_monitor_);
Dart_MessageNotifyCallback saved_notify_callback =
message_notify_callback();
set_message_notify_callback(Isolate::WakePauseEventHandler);
bool resume = false;
while (true) {
// Handle all available vm service messages, up to a resume
// request.
while (!resume && Dart_HasServiceMessages()) {
pause_loop_monitor_->Exit();
resume = Dart_HandleServiceMessages();
pause_loop_monitor_->Enter();
}
if (resume) {
break;
}
// Wait for more service messages.
Monitor::WaitResult res = ml.Wait();
ASSERT(res == Monitor::kNotified);
}
set_message_notify_callback(saved_notify_callback);
Dart_ExitScope();
}
void Isolate::VisitIsolates(IsolateVisitor* visitor) {
if (visitor == NULL) {
return;
}
MonitorLocker ml(isolates_list_monitor_);
Isolate* current = isolates_list_head_;
while (current) {
visitor->VisitIsolate(current);
current = current->next_;
}
}
intptr_t Isolate::IsolateListLength() {
MonitorLocker ml(isolates_list_monitor_);
intptr_t count = 0;
Isolate* current = isolates_list_head_;
while (current != NULL) {
count++;
current = current->next_;
}
return count;
}
bool Isolate::AddIsolateToList(Isolate* isolate) {
MonitorLocker ml(isolates_list_monitor_);
if (!creation_enabled_) {
return false;
}
ASSERT(isolate != NULL);
ASSERT(isolate->next_ == NULL);
isolate->next_ = isolates_list_head_;
isolates_list_head_ = isolate;
return true;
}
void Isolate::RemoveIsolateFromList(Isolate* isolate) {
MonitorLocker ml(isolates_list_monitor_);
ASSERT(isolate != NULL);
if (isolate == isolates_list_head_) {
isolates_list_head_ = isolate->next_;
if (!creation_enabled_) {
ml.Notify();
}
return;
}
Isolate* previous = NULL;
Isolate* current = isolates_list_head_;
while (current) {
if (current == isolate) {
ASSERT(previous != NULL);
previous->next_ = current->next_;
if (!creation_enabled_) {
ml.Notify();
}
return;
}
previous = current;
current = current->next_;
}
// If we are shutting down the VM, the isolate may not be in the list.
ASSERT(!creation_enabled_);
}
void Isolate::DisableIsolateCreation() {
MonitorLocker ml(isolates_list_monitor_);
creation_enabled_ = false;
}
void Isolate::EnableIsolateCreation() {
MonitorLocker ml(isolates_list_monitor_);
creation_enabled_ = true;
}
void Isolate::KillLocked(LibMsgId msg_id) {
Dart_CObject kill_msg;
Dart_CObject* list_values[4];
kill_msg.type = Dart_CObject_kArray;
kill_msg.value.as_array.length = 4;
kill_msg.value.as_array.values = list_values;
Dart_CObject oob;
oob.type = Dart_CObject_kInt32;
oob.value.as_int32 = Message::kIsolateLibOOBMsg;
list_values[0] = &oob;
Dart_CObject msg_type;
msg_type.type = Dart_CObject_kInt32;
msg_type.value.as_int32 = msg_id;
list_values[1] = &msg_type;
Dart_CObject cap;
cap.type = Dart_CObject_kCapability;
cap.value.as_capability.id = terminate_capability();
list_values[2] = &cap;
Dart_CObject imm;
imm.type = Dart_CObject_kInt32;
imm.value.as_int32 = Isolate::kImmediateAction;
list_values[3] = &imm;
{
uint8_t* buffer = NULL;
ApiMessageWriter writer(&buffer, allocator);
bool success = writer.WriteCMessage(&kill_msg);
ASSERT(success);
// Post the message at the given port.
success = PortMap::PostMessage(new Message(main_port(),
buffer,
writer.BytesWritten(),
Message::kOOBPriority));
ASSERT(success);
}
}
class IsolateKillerVisitor : public IsolateVisitor {
public:
explicit IsolateKillerVisitor(Isolate::LibMsgId msg_id)
: target_(NULL), msg_id_(msg_id) {}
IsolateKillerVisitor(Isolate* isolate, Isolate::LibMsgId msg_id)
: target_(isolate), msg_id_(msg_id) {
ASSERT(isolate != Dart::vm_isolate());
}
virtual ~IsolateKillerVisitor() {}
void VisitIsolate(Isolate* isolate) {
ASSERT(isolate != NULL);
if (ShouldKill(isolate)) {
isolate->KillLocked(msg_id_);
}
}
private:
bool ShouldKill(Isolate* isolate) {
// If a target_ is specified, then only kill the target_.
// Otherwise, don't kill the service isolate or vm isolate.
return (((target_ != NULL) && (isolate == target_)) ||
((target_ == NULL) &&
!ServiceIsolate::IsServiceIsolateDescendant(isolate) &&
(isolate != Dart::vm_isolate())));
}
Isolate* target_;
Isolate::LibMsgId msg_id_;
};
void Isolate::KillAllIsolates(LibMsgId msg_id) {
IsolateKillerVisitor visitor(msg_id);
VisitIsolates(&visitor);
}
void Isolate::KillIfExists(Isolate* isolate, LibMsgId msg_id) {
IsolateKillerVisitor visitor(isolate, msg_id);
VisitIsolates(&visitor);
}
static RawInstance* DeserializeObject(Thread* thread,
uint8_t* obj_data,
intptr_t obj_len) {
if (obj_data == NULL) {
return Instance::null();
}
MessageSnapshotReader reader(obj_data, obj_len, thread);
Zone* zone = thread->zone();
const Object& obj = Object::Handle(zone, reader.ReadObject());
ASSERT(!obj.IsError());
Instance& instance = Instance::Handle(zone);
instance ^= obj.raw(); // Can't use Instance::Cast because may be null.
return instance.raw();
}
static const char* NewConstChar(const char* chars) {
size_t len = strlen(chars);
char* mem = new char[len + 1];
memmove(mem, chars, len + 1);
return mem;
}
IsolateSpawnState::IsolateSpawnState(Dart_Port parent_port,
const Function& func,
const Instance& message,
bool paused,
bool errors_are_fatal,
Dart_Port on_exit_port,
Dart_Port on_error_port)
: isolate_(NULL),
parent_port_(parent_port),
on_exit_port_(on_exit_port),
on_error_port_(on_error_port),
script_url_(NULL),
package_root_(NULL),
package_map_(NULL),
library_url_(NULL),
class_name_(NULL),
function_name_(NULL),
serialized_args_(NULL),
serialized_args_len_(0),
serialized_message_(NULL),
serialized_message_len_(0),
isolate_flags_(),
paused_(paused),
errors_are_fatal_(errors_are_fatal) {
const Class& cls = Class::Handle(func.Owner());
const Library& lib = Library::Handle(cls.library());
const String& lib_url = String::Handle(lib.url());
library_url_ = NewConstChar(lib_url.ToCString());
const String& func_name = String::Handle(func.name());
function_name_ = NewConstChar(func_name.ToCString());
if (!cls.IsTopLevel()) {
const String& class_name = String::Handle(cls.Name());
class_name_ = NewConstChar(class_name.ToCString());
}
bool can_send_any_object = true;
SerializeObject(message,
&serialized_message_,
&serialized_message_len_,
can_send_any_object);
// Inherit flags from spawning isolate.
isolate_flags()->CopyFrom(Isolate::Current()->flags());
}
IsolateSpawnState::IsolateSpawnState(Dart_Port parent_port,
const char* script_url,
const char* package_root,
const char** package_map,
const Instance& args,
const Instance& message,
bool paused,
bool errors_are_fatal,
Dart_Port on_exit_port,
Dart_Port on_error_port)
: isolate_(NULL),
parent_port_(parent_port),
on_exit_port_(on_exit_port),
on_error_port_(on_error_port),
script_url_(script_url),
package_root_(package_root),
package_map_(package_map),
library_url_(NULL),
class_name_(NULL),
function_name_(NULL),
serialized_args_(NULL),
serialized_args_len_(0),
serialized_message_(NULL),
serialized_message_len_(0),
isolate_flags_(),
paused_(paused),
errors_are_fatal_(errors_are_fatal) {
function_name_ = NewConstChar("main");
bool can_send_any_object = false;
SerializeObject(args,
&serialized_args_,
&serialized_args_len_,
can_send_any_object);
SerializeObject(message,
&serialized_message_,
&serialized_message_len_,
can_send_any_object);
// By default inherit flags from spawning isolate. These can be overridden
// from the calling code.
isolate_flags()->CopyFrom(Isolate::Current()->flags());
}
IsolateSpawnState::~IsolateSpawnState() {
delete[] script_url_;
delete[] package_root_;
for (int i = 0; package_map_ != NULL; i++) {
if (package_map_[i] != NULL) {
delete[] package_map_[i];
} else {
delete[] package_map_;
package_map_ = NULL;
}
}
delete[] library_url_;
delete[] class_name_;
delete[] function_name_;
free(serialized_args_);
free(serialized_message_);
}
RawObject* IsolateSpawnState::ResolveFunction() {
const String& func_name = String::Handle(String::New(function_name()));
if (library_url() == NULL) {
// Handle spawnUri lookup rules.
// Check whether the root library defines a main function.
const Library& lib = Library::Handle(I->object_store()->root_library());
Function& func = Function::Handle(lib.LookupLocalFunction(func_name));
if (func.IsNull()) {
// Check whether main is reexported from the root library.
const Object& obj = Object::Handle(lib.LookupReExport(func_name));
if (obj.IsFunction()) {
func ^= obj.raw();
}
}
if (func.IsNull()) {
const String& msg = String::Handle(String::NewFormatted(
"Unable to resolve function '%s' in script '%s'.",
function_name(), script_url()));
return LanguageError::New(msg);
}
return func.raw();
}
ASSERT(script_url() == NULL);
// Resolve the library.
const String& lib_url = String::Handle(String::New(library_url()));
const Library& lib = Library::Handle(Library::LookupLibrary(lib_url));
if (lib.IsNull() || lib.IsError()) {
const String& msg = String::Handle(String::NewFormatted(
"Unable to find library '%s'.", library_url()));
return LanguageError::New(msg);
}
// Resolve the function.
if (class_name() == NULL) {
const Function& func = Function::Handle(lib.LookupLocalFunction(func_name));
if (func.IsNull()) {
const String& msg = String::Handle(String::NewFormatted(
"Unable to resolve function '%s' in library '%s'.",
function_name(), library_url()));
return LanguageError::New(msg);
}
return func.raw();
}
const String& cls_name = String::Handle(String::New(class_name()));
const Class& cls = Class::Handle(lib.LookupLocalClass(cls_name));
if (cls.IsNull()) {
const String& msg = String::Handle(String::NewFormatted(
"Unable to resolve class '%s' in library '%s'.",
class_name(),
(library_url() != NULL ? library_url() : script_url())));
return LanguageError::New(msg);
}
const Function& func =
Function::Handle(cls.LookupStaticFunctionAllowPrivate(func_name));
if (func.IsNull()) {
const String& msg = String::Handle(String::NewFormatted(
"Unable to resolve static method '%s.%s' in library '%s'.",
class_name(), function_name(),
(library_url() != NULL ? library_url() : script_url())));
return LanguageError::New(msg);
}
return func.raw();
}
RawInstance* IsolateSpawnState::BuildArgs(Thread* thread) {
return DeserializeObject(thread, serialized_args_, serialized_args_len_);
}
RawInstance* IsolateSpawnState::BuildMessage(Thread* thread) {
return DeserializeObject(thread,
serialized_message_, serialized_message_len_);
}
void IsolateSpawnState::Cleanup() {
SwitchIsolateScope switch_scope(I);
Dart::ShutdownIsolate();
}
} // namespace dart