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dart / sdk.git / b3c12d4e3ac489a01892279f9a660d36941862f8 / . / runtime / vm / dart.cc
blob: c0039667349ba4880b73cbb1a6b8e49ed32363a4 [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/dart.h"
#include "vm/become.h"
#include "vm/clustered_snapshot.h"
#include "vm/code_observers.h"
#include "vm/cpu.h"
#include "vm/dart_api_state.h"
#include "vm/dart_entry.h"
#include "vm/debugger.h"
#include "vm/flags.h"
#include "vm/freelist.h"
#include "vm/handles.h"
#include "vm/heap.h"
#include "vm/isolate.h"
#include "vm/kernel_isolate.h"
#include "vm/malloc_hooks.h"
#include "vm/message_handler.h"
#include "vm/metrics.h"
#include "vm/object.h"
#include "vm/object_id_ring.h"
#include "vm/object_store.h"
#include "vm/port.h"
#include "vm/profiler.h"
#include "vm/service_isolate.h"
#include "vm/simulator.h"
#include "vm/snapshot.h"
#include "vm/store_buffer.h"
#include "vm/stub_code.h"
#include "vm/symbols.h"
#include "vm/thread_interrupter.h"
#include "vm/thread_pool.h"
#include "vm/timeline.h"
#include "vm/virtual_memory.h"
#include "vm/zone.h"
namespace dart {
DECLARE_FLAG(bool, print_class_table);
DECLARE_FLAG(bool, trace_time_all);
DEFINE_FLAG(bool, keep_code, false, "Keep deoptimized code for profiling.");
DEFINE_FLAG(bool, trace_shutdown, false, "Trace VM shutdown on stderr");
Isolate* Dart::vm_isolate_ = NULL;
int64_t Dart::start_time_micros_ = 0;
ThreadPool* Dart::thread_pool_ = NULL;
DebugInfo* Dart::pprof_symbol_generator_ = NULL;
ReadOnlyHandles* Dart::predefined_handles_ = NULL;
Snapshot::Kind Dart::vm_snapshot_kind_ = Snapshot::kInvalid;
const uint8_t* Dart::vm_snapshot_instructions_ = NULL;
Dart_ThreadExitCallback Dart::thread_exit_callback_ = NULL;
Dart_FileOpenCallback Dart::file_open_callback_ = NULL;
Dart_FileReadCallback Dart::file_read_callback_ = NULL;
Dart_FileWriteCallback Dart::file_write_callback_ = NULL;
Dart_FileCloseCallback Dart::file_close_callback_ = NULL;
Dart_EntropySource Dart::entropy_source_callback_ = NULL;
// Structure for managing read-only global handles allocation used for
// creating global read-only handles that are pre created and initialized
// for use across all isolates. Having these global pre created handles
// stored in the vm isolate ensures that we don't constantly create and
// destroy handles for read-only objects referred in the VM code
// (e.g: symbols, null object, empty array etc.)
// The ReadOnlyHandles C++ Wrapper around VMHandles which is a ValueObject is
// to ensure that the handles area is not trashed by automatic running of C++
// static destructors when 'exit()" is called by any isolate. There might be
// other isolates running at the same time and trashing the handles area will
// have unintended consequences.
class ReadOnlyHandles {
public:
ReadOnlyHandles() {}
private:
VMHandles handles_;
LocalHandles api_handles_;
friend class Dart;
DISALLOW_COPY_AND_ASSIGN(ReadOnlyHandles);
};
static void CheckOffsets() {
#define CHECK_OFFSET(expr, offset) \
if ((expr) != (offset)) { \
FATAL2("%s == %" Pd, #expr, (expr)); \
}
#if defined(TARGET_ARCH_ARM)
// These offsets are embedded in precompiled instructions. We need simarm
// (compiler) and arm (runtime) to agree.
CHECK_OFFSET(Thread::stack_limit_offset(), 4);
CHECK_OFFSET(Thread::object_null_offset(), 48);
CHECK_OFFSET(SingleTargetCache::upper_limit_offset(), 14);
CHECK_OFFSET(Isolate::object_store_offset(), 28);
NOT_IN_PRODUCT(CHECK_OFFSET(sizeof(ClassHeapStats), 168));
#endif
#if defined(TARGET_ARCH_ARM64)
// These offsets are embedded in precompiled instructions. We need simarm64
// (compiler) and arm64 (runtime) to agree.
CHECK_OFFSET(Thread::stack_limit_offset(), 8);
CHECK_OFFSET(Thread::object_null_offset(), 96);
CHECK_OFFSET(SingleTargetCache::upper_limit_offset(), 26);
CHECK_OFFSET(Isolate::object_store_offset(), 56);
NOT_IN_PRODUCT(CHECK_OFFSET(sizeof(ClassHeapStats), 288));
#endif
#undef CHECK_OFFSET
}
char* Dart::InitOnce(const uint8_t* vm_isolate_snapshot,
const uint8_t* instructions_snapshot,
Dart_IsolateCreateCallback create,
Dart_IsolateShutdownCallback shutdown,
Dart_IsolateCleanupCallback cleanup,
Dart_ThreadExitCallback thread_exit,
Dart_FileOpenCallback file_open,
Dart_FileReadCallback file_read,
Dart_FileWriteCallback file_write,
Dart_FileCloseCallback file_close,
Dart_EntropySource entropy_source,
Dart_GetVMServiceAssetsArchive get_service_assets,
bool start_kernel_isolate) {
CheckOffsets();
// TODO(iposva): Fix race condition here.
if (vm_isolate_ != NULL || !Flags::Initialized()) {
return strdup("VM already initialized or flags not initialized.");
}
#if defined(DEBUG)
// Turn on verify_gc_contains if any of the other GC verification flag
// is turned on.
if (FLAG_verify_before_gc || FLAG_verify_after_gc ||
FLAG_verify_on_transition) {
FLAG_verify_gc_contains = true;
}
#endif
set_thread_exit_callback(thread_exit);
SetFileCallbacks(file_open, file_read, file_write, file_close);
set_entropy_source_callback(entropy_source);
OS::InitOnce();
start_time_micros_ = OS::GetCurrentMonotonicMicros();
VirtualMemory::InitOnce();
OSThread::InitOnce();
if (FLAG_support_timeline) {
Timeline::InitOnce();
}
NOT_IN_PRODUCT(
TimelineDurationScope tds(Timeline::GetVMStream(), "Dart::InitOnce"));
Isolate::InitOnce();
IdleNotifier::InitOnce();
PortMap::InitOnce();
FreeListElement::InitOnce();
ForwardingCorpse::InitOnce();
Api::InitOnce();
NativeSymbolResolver::InitOnce();
NOT_IN_PRODUCT(CodeObservers::InitOnce());
NOT_IN_PRODUCT(Profiler::InitOnce());
SemiSpace::InitOnce();
NOT_IN_PRODUCT(Metric::InitOnce());
StoreBuffer::InitOnce();
MarkingStack::InitOnce();
#if defined(USING_SIMULATOR)
Simulator::InitOnce();
#endif
// Create the read-only handles area.
ASSERT(predefined_handles_ == NULL);
predefined_handles_ = new ReadOnlyHandles();
// Create the VM isolate and finish the VM initialization.
ASSERT(thread_pool_ == NULL);
thread_pool_ = new ThreadPool();
{
ASSERT(vm_isolate_ == NULL);
ASSERT(Flags::Initialized());
const bool is_vm_isolate = true;
// Setup default flags for the VM isolate.
Dart_IsolateFlags api_flags;
Isolate::FlagsInitialize(&api_flags);
vm_isolate_ = Isolate::Init("vm-isolate", api_flags, is_vm_isolate);
// Verify assumptions about executing in the VM isolate.
ASSERT(vm_isolate_ == Isolate::Current());
ASSERT(vm_isolate_ == Thread::Current()->isolate());
Thread* T = Thread::Current();
ASSERT(T != NULL);
StackZone zone(T);
HandleScope handle_scope(T);
Object::InitNull(vm_isolate_);
ObjectStore::Init(vm_isolate_);
TargetCPUFeatures::InitOnce();
Object::InitOnce(vm_isolate_);
ArgumentsDescriptor::InitOnce();
ICData::InitOnce();
if (vm_isolate_snapshot != NULL) {
NOT_IN_PRODUCT(TimelineDurationScope tds(Timeline::GetVMStream(),
"VMIsolateSnapshot"));
const Snapshot* snapshot = Snapshot::SetupFromBuffer(vm_isolate_snapshot);
if (snapshot == NULL) {
return strdup("Invalid vm isolate snapshot seen");
}
vm_snapshot_kind_ = snapshot->kind();
if (Snapshot::IncludesCode(vm_snapshot_kind_)) {
if (vm_snapshot_kind_ == Snapshot::kFullAOT) {
#if defined(DART_PRECOMPILED_RUNTIME)
vm_isolate_->set_compilation_allowed(false);
#else
return strdup("JIT runtime cannot run a precompiled snapshot");
#endif
}
if (instructions_snapshot == NULL) {
return strdup("Missing instructions snapshot");
}
} else if (Snapshot::IsFull(vm_snapshot_kind_)) {
#if defined(DART_PRECOMPILED_RUNTIME)
return strdup("Precompiled runtime requires a precompiled snapshot");
#else
StubCode::InitOnce();
// MallocHooks can't be initialized until StubCode has been since stack
// trace generation relies on stub methods that are generated in
// StubCode::InitOnce().
// TODO(bkonyi) Split initialization for stack trace collection from the
// initialization for the actual malloc hooks to increase accuracy of
// memory consumption statistics.
MallocHooks::InitOnce();
#endif
} else {
return strdup("Invalid vm isolate snapshot seen");
}
FullSnapshotReader reader(snapshot, instructions_snapshot, T);
const Error& error = Error::Handle(reader.ReadVMSnapshot());
if (!error.IsNull()) {
// Must copy before leaving the zone.
return strdup(error.ToErrorCString());
}
#if !defined(PRODUCT)
if (tds.enabled()) {
tds.SetNumArguments(2);
tds.FormatArgument(0, "snapshotSize", "%" Pd, snapshot->length());
tds.FormatArgument(
1, "heapSize", "%" Pd64,
vm_isolate_->heap()->UsedInWords(Heap::kOld) * kWordSize);
}
#endif // !defined(PRODUCT)
if (FLAG_trace_isolates) {
OS::Print("Size of vm isolate snapshot = %" Pd "\n",
snapshot->length());
vm_isolate_->heap()->PrintSizes();
MegamorphicCacheTable::PrintSizes(vm_isolate_);
intptr_t size;
intptr_t capacity;
Symbols::GetStats(vm_isolate_, &size, &capacity);
OS::Print("VM Isolate: Number of symbols : %" Pd "\n", size);
OS::Print("VM Isolate: Symbol table capacity : %" Pd "\n", capacity);
}
} else {
#if defined(DART_PRECOMPILED_RUNTIME)
return strdup("Precompiled runtime requires a precompiled snapshot");
#elif !defined(DART_NO_SNAPSHOT)
return strdup("Missing vm isolate snapshot");
#else
vm_snapshot_kind_ = Snapshot::kNone;
StubCode::InitOnce();
// MallocHooks can't be initialized until StubCode has been since stack
// trace generation relies on stub methods that are generated in
// StubCode::InitOnce().
// TODO(bkonyi) Split initialization for stack trace collection from the
// initialization for the actual malloc hooks to increase accuracy of
// memory consumption statistics.
MallocHooks::InitOnce();
Symbols::InitOnce(vm_isolate_);
#endif
}
// We need to initialize the constants here for the vm isolate thread due to
// bootstrapping issues.
T->InitVMConstants();
Scanner::InitOnce();
#if defined(TARGET_ARCH_IA32) || defined(TARGET_ARCH_X64)
// Dart VM requires at least SSE2.
if (!TargetCPUFeatures::sse2_supported()) {
return strdup("SSE2 is required.");
}
#endif
{
NOT_IN_PRODUCT(TimelineDurationScope tds(Timeline::GetVMStream(),
"FinalizeVMIsolate"));
Object::FinalizeVMIsolate(vm_isolate_);
}
#if defined(DEBUG)
vm_isolate_->heap()->Verify(kRequireMarked);
#endif
}
// Allocate the "persistent" scoped handles for the predefined API
// values (such as Dart_True, Dart_False and Dart_Null).
Api::InitHandles();
Thread::ExitIsolate(); // Unregister the VM isolate from this thread.
Isolate::SetCreateCallback(create);
Isolate::SetShutdownCallback(shutdown);
Isolate::SetCleanupCallback(cleanup);
if (FLAG_support_service) {
Service::SetGetServiceAssetsCallback(get_service_assets);
}
ServiceIsolate::Run();
#ifndef DART_PRECOMPILED_RUNTIME
if (start_kernel_isolate) {
KernelIsolate::Run();
}
#endif // DART_PRECOMPILED_RUNTIME
return NULL;
}
// This waits until only the VM isolate and the service isolate remains in the
// list, i.e. list length == 2.
void Dart::WaitForApplicationIsolateShutdown() {
ASSERT(!Isolate::creation_enabled_);
MonitorLocker ml(Isolate::isolates_list_monitor_);
while ((Isolate::isolates_list_head_ != NULL) &&
(Isolate::isolates_list_head_->next_ != NULL) &&
(Isolate::isolates_list_head_->next_->next_ != NULL)) {
ml.Wait();
}
ASSERT(
((Isolate::isolates_list_head_ == Dart::vm_isolate()) &&
ServiceIsolate::IsServiceIsolate(Isolate::isolates_list_head_->next_)) ||
((Isolate::isolates_list_head_->next_ == Dart::vm_isolate()) &&
ServiceIsolate::IsServiceIsolate(Isolate::isolates_list_head_)));
}
// This waits until only the VM isolate remains in the list.
void Dart::WaitForIsolateShutdown() {
ASSERT(!Isolate::creation_enabled_);
MonitorLocker ml(Isolate::isolates_list_monitor_);
while ((Isolate::isolates_list_head_ != NULL) &&
(Isolate::isolates_list_head_->next_ != NULL)) {
ml.Wait();
}
ASSERT(Isolate::isolates_list_head_ == Dart::vm_isolate());
}
const char* Dart::Cleanup() {
ASSERT(Isolate::Current() == NULL);
if (vm_isolate_ == NULL) {
return "VM already terminated.";
}
if (FLAG_trace_shutdown) {
OS::PrintErr("[+%" Pd64 "ms] SHUTDOWN: Starting shutdown\n",
UptimeMillis());
}
#if !defined(PRODUCT)
if (FLAG_trace_shutdown) {
OS::PrintErr("[+%" Pd64 "ms] SHUTDOWN: Shutting down profiling\n",
UptimeMillis());
}
Profiler::Shutdown();
#endif // !defined(PRODUCT)
NativeSymbolResolver::ShutdownOnce();
{
// Set the VM isolate as current isolate when shutting down
// Metrics so that we can use a StackZone.
if (FLAG_trace_shutdown) {
OS::PrintErr("[+%" Pd64 "ms] SHUTDOWN: Entering vm isolate\n",
UptimeMillis());
}
bool result = Thread::EnterIsolate(vm_isolate_);
ASSERT(result);
NOT_IN_PRODUCT(Metric::Cleanup());
Thread::ExitIsolate();
}
// Disable the creation of new isolates.
if (FLAG_trace_shutdown) {
OS::PrintErr("[+%" Pd64 "ms] SHUTDOWN: Disabling isolate creation\n",
UptimeMillis());
}
Isolate::DisableIsolateCreation();
// Send the OOB Kill message to all remaining application isolates.
if (FLAG_trace_shutdown) {
OS::PrintErr("[+%" Pd64 "ms] SHUTDOWN: Killing all app isolates\n",
UptimeMillis());
}
Isolate::KillAllIsolates(Isolate::kInternalKillMsg);
// Wait for all isolates, but the service and the vm isolate to shut down.
// Only do that if there is a service isolate running.
if (ServiceIsolate::IsRunning()) {
if (FLAG_trace_shutdown) {
OS::PrintErr("[+%" Pd64 "ms] SHUTDOWN: Shutting down app isolates\n",
UptimeMillis());
}
WaitForApplicationIsolateShutdown();
}
// Shutdown the service isolate.
if (FLAG_trace_shutdown) {
OS::PrintErr("[+%" Pd64 "ms] SHUTDOWN: Shutting down service isolate\n",
UptimeMillis());
}
ServiceIsolate::Shutdown();
// Wait for the remaining isolate (service isolate) to shutdown
// before shutting down the thread pool.
if (FLAG_trace_shutdown) {
OS::PrintErr("[+%" Pd64 "ms] SHUTDOWN: Waiting for isolate shutdown\n",
UptimeMillis());
}
WaitForIsolateShutdown();
IdleNotifier::Stop();
// Shutdown the thread pool. On return, all thread pool threads have exited.
if (FLAG_trace_shutdown) {
OS::PrintErr("[+%" Pd64 "ms] SHUTDOWN: Deleting thread pool\n",
UptimeMillis());
}
delete thread_pool_;
thread_pool_ = NULL;
// Disable creation of any new OSThread structures which means no more new
// threads can do an EnterIsolate. This must come after isolate shutdown
// because new threads may need to be spawned to shutdown the isolates.
// This must come after deletion of the thread pool to avoid a race in which
// a thread spawned by the thread pool does not exit through the thread
// pool, messing up its bookkeeping.
if (FLAG_trace_shutdown) {
OS::PrintErr("[+%" Pd64 "ms] SHUTDOWN: Disabling OS Thread creation\n",
UptimeMillis());
}
OSThread::DisableOSThreadCreation();
// Set the VM isolate as current isolate.
if (FLAG_trace_shutdown) {
OS::PrintErr("[+%" Pd64 "ms] SHUTDOWN: Cleaning up vm isolate\n",
UptimeMillis());
}
bool result = Thread::EnterIsolate(vm_isolate_);
ASSERT(result);
ShutdownIsolate();
vm_isolate_ = NULL;
ASSERT(Isolate::IsolateListLength() == 0);
IdleNotifier::Cleanup();
TargetCPUFeatures::Cleanup();
StoreBuffer::ShutDown();
// Delete the current thread's TLS and set it's TLS to null.
// If it is the last thread then the destructor would call
// OSThread::Cleanup.
OSThread* os_thread = OSThread::Current();
OSThread::SetCurrent(NULL);
delete os_thread;
if (FLAG_trace_shutdown) {
OS::PrintErr("[+%" Pd64 "ms] SHUTDOWN: Deleted os_thread\n",
UptimeMillis());
}
if (FLAG_trace_shutdown) {
OS::PrintErr("[+%" Pd64 "ms] SHUTDOWN: Deleting code observers\n",
UptimeMillis());
}
NOT_IN_PRODUCT(CodeObservers::DeleteAll());
if (FLAG_support_timeline) {
if (FLAG_trace_shutdown) {
OS::PrintErr("[+%" Pd64 "ms] SHUTDOWN: Shutting down timeline\n",
UptimeMillis());
}
Timeline::Shutdown();
}
if (FLAG_trace_shutdown) {
OS::PrintErr("[+%" Pd64 "ms] SHUTDOWN: Done\n", UptimeMillis());
}
MallocHooks::TearDown();
return NULL;
}
Isolate* Dart::CreateIsolate(const char* name_prefix,
const Dart_IsolateFlags& api_flags) {
// Create a new isolate.
Isolate* isolate = Isolate::Init(name_prefix, api_flags);
return isolate;
}
static bool IsSnapshotCompatible(Snapshot::Kind vm_kind,
Snapshot::Kind isolate_kind) {
if (vm_kind == isolate_kind) return true;
if (vm_kind == Snapshot::kFull && isolate_kind == Snapshot::kFullJIT)
return true;
return Snapshot::IsFull(isolate_kind);
}
RawError* Dart::InitializeIsolate(const uint8_t* snapshot_data,
const uint8_t* snapshot_instructions,
intptr_t snapshot_length,
kernel::Program* kernel_program,
void* data) {
// Initialize the new isolate.
Thread* T = Thread::Current();
Isolate* I = T->isolate();
NOT_IN_PRODUCT(TimelineDurationScope tds(T, Timeline::GetIsolateStream(),
"InitializeIsolate");
tds.SetNumArguments(1);
tds.CopyArgument(0, "isolateName", I->name());)
ASSERT(I != NULL);
StackZone zone(T);
HandleScope handle_scope(T);
{
NOT_IN_PRODUCT(TimelineDurationScope tds(T, Timeline::GetIsolateStream(),
"ObjectStore::Init"));
ObjectStore::Init(I);
}
Error& error = Error::Handle(T->zone());
error = Object::Init(I, kernel_program);
if (!error.IsNull()) {
return error.raw();
}
if ((snapshot_data != NULL) && kernel_program == NULL) {
// Read the snapshot and setup the initial state.
NOT_IN_PRODUCT(TimelineDurationScope tds(T, Timeline::GetIsolateStream(),
"IsolateSnapshotReader"));
// TODO(turnidge): Remove once length is not part of the snapshot.
const Snapshot* snapshot = Snapshot::SetupFromBuffer(snapshot_data);
if (snapshot == NULL) {
const String& message = String::Handle(String::New("Invalid snapshot"));
return ApiError::New(message);
}
if (!IsSnapshotCompatible(vm_snapshot_kind_, snapshot->kind())) {
const String& message = String::Handle(String::NewFormatted(
"Incompatible snapshot kinds: vm '%s', isolate '%s'",
Snapshot::KindToCString(vm_snapshot_kind_),
Snapshot::KindToCString(snapshot->kind())));
return ApiError::New(message);
}
if (FLAG_trace_isolates) {
OS::Print("Size of isolate snapshot = %" Pd "\n", snapshot->length());
}
FullSnapshotReader reader(snapshot, snapshot_instructions, T);
const Error& error = Error::Handle(reader.ReadIsolateSnapshot());
if (!error.IsNull()) {
return error.raw();
}
#if !defined(PRODUCT)
if (tds.enabled()) {
tds.SetNumArguments(2);
tds.FormatArgument(0, "snapshotSize", "%" Pd, snapshot->length());
tds.FormatArgument(1, "heapSize", "%" Pd64,
I->heap()->UsedInWords(Heap::kOld) * kWordSize);
}
#endif // !defined(PRODUCT)
if (FLAG_trace_isolates) {
I->heap()->PrintSizes();
MegamorphicCacheTable::PrintSizes(I);
}
} else {
if ((vm_snapshot_kind_ != Snapshot::kNone) && kernel_program == NULL) {
const String& message =
String::Handle(String::New("Missing isolate snapshot"));
return ApiError::New(message);
}
}
Object::VerifyBuiltinVtables();
DEBUG_ONLY(I->heap()->Verify(kForbidMarked));
#if defined(DART_PRECOMPILED_RUNTIME)
// AOT: The megamorphic miss function and code come from the snapshot.
ASSERT(I->object_store()->megamorphic_miss_code() != Code::null());
#else
// JIT: The megamorphic miss function and code come from the snapshot in JIT
// app snapshot, otherwise create them.
if (I->object_store()->megamorphic_miss_code() == Code::null()) {
MegamorphicCacheTable::InitMissHandler(I);
}
#endif // defined(DART_PRECOMPILED_RUNTIME)
const Code& miss_code =
Code::Handle(I->object_store()->megamorphic_miss_code());
I->set_ic_miss_code(miss_code);
if ((snapshot_data == NULL) || (kernel_program != NULL)) {
const Error& error = Error::Handle(I->object_store()->PreallocateObjects());
if (!error.IsNull()) {
return error.raw();
}
}
I->heap()->InitGrowthControl();
I->set_init_callback_data(data);
Api::SetupAcquiredError(I);
if (FLAG_print_class_table) {
I->class_table()->Print();
}
bool is_kernel_isolate = false;
USE(is_kernel_isolate);
#ifndef DART_PRECOMPILED_RUNTIME
KernelIsolate::InitCallback(I);
is_kernel_isolate = KernelIsolate::IsKernelIsolate(I);
#endif
ServiceIsolate::MaybeMakeServiceIsolate(I);
#if !defined(PRODUCT)
if (!ServiceIsolate::IsServiceIsolate(I) && !is_kernel_isolate) {
I->message_handler()->set_should_pause_on_start(
FLAG_pause_isolates_on_start);
I->message_handler()->set_should_pause_on_exit(FLAG_pause_isolates_on_exit);
}
#endif // !defined(PRODUCT)
ServiceIsolate::SendIsolateStartupMessage();
#if !defined(PRODUCT)
I->debugger()->NotifyIsolateCreated();
#endif
// Create tag table.
I->set_tag_table(GrowableObjectArray::Handle(GrowableObjectArray::New()));
// Set up default UserTag.
const UserTag& default_tag = UserTag::Handle(UserTag::DefaultTag());
I->set_current_tag(default_tag);
if (FLAG_keep_code) {
I->set_deoptimized_code_array(
GrowableObjectArray::Handle(GrowableObjectArray::New()));
}
return Error::null();
}
const char* Dart::FeaturesString(Isolate* isolate,
bool is_vm_isolate,
Snapshot::Kind kind) {
TextBuffer buffer(64);
// Different fields are included for DEBUG/RELEASE/PRODUCT.
#if defined(DEBUG)
buffer.AddString("debug");
#elif defined(PRODUCT)
buffer.AddString("product");
#else
buffer.AddString("release");
#endif
#define ADD_FLAG(name, isolate_flag, flag) \
do { \
const bool name = (isolate != NULL) ? isolate->name() : flag; \
buffer.AddString(name ? (" " #name) : (" no-" #name)); \
} while (0);
// We don't write the strong flag into the features list for the VM isolate
// snapshot as the implementation is in an intermediate state where the VM
// isolate is always initialized from a vm_snapshot generated in non strong
// mode.
if (!is_vm_isolate) {
ADD_FLAG(strong, strong, FLAG_strong);
}
if (Snapshot::IncludesCode(kind)) {
// Checked mode affects deopt ids.
ADD_FLAG(type_checks, enable_type_checks, FLAG_enable_type_checks);
ADD_FLAG(asserts, enable_asserts, FLAG_enable_asserts);
ADD_FLAG(error_on_bad_type, enable_error_on_bad_type,
FLAG_error_on_bad_type);
ADD_FLAG(error_on_bad_override, enable_error_on_bad_override,
FLAG_error_on_bad_override);
if (kind == Snapshot::kFullJIT) {
ADD_FLAG(use_field_guards, use_field_guards, FLAG_use_field_guards);
ADD_FLAG(use_osr, use_osr, FLAG_use_osr);
}
// Generated code must match the host architecture and ABI.
#if defined(TARGET_ARCH_ARM)
#if defined(TARGET_OS_MACOS) || defined(TARGET_OS_MACOS_IOS)
buffer.AddString(" arm-ios");
#else
buffer.AddString(" arm-eabi");
#endif
buffer.AddString(TargetCPUFeatures::hardfp_supported() ? " hardfp"
: " softfp");
#elif defined(TARGET_ARCH_ARM64)
buffer.AddString(" arm64");
#elif defined(TARGET_ARCH_IA32)
buffer.AddString(" ia32");
#elif defined(TARGET_ARCH_X64)
#if defined(_WIN64)
buffer.AddString(" x64-win");
#else
buffer.AddString(" x64-sysv");
#endif
#elif defined(TARGET_ARCH_DBC)
buffer.AddString(" dbc");
#elif defined(TARGET_ARCH_DBC64)
buffer.AddString(" dbc64");
#endif
}
if (FLAG_precompiled_mode && FLAG_dwarf_stack_traces) {
buffer.AddString(" dwarf-stack-traces");
}
#undef ADD_FLAG
return buffer.Steal();
}
void Dart::RunShutdownCallback() {
Isolate* isolate = Isolate::Current();
void* callback_data = isolate->init_callback_data();
Dart_IsolateShutdownCallback callback = Isolate::ShutdownCallback();
if (callback != NULL) {
(callback)(callback_data);
}
}
void Dart::ShutdownIsolate(Isolate* isolate) {
ASSERT(Isolate::Current() == NULL);
// We need to enter the isolate in order to shut it down.
bool result = Thread::EnterIsolate(isolate);
ASSERT(result);
ShutdownIsolate();
// Since the isolate is shutdown and deleted, there is no need to
// exit the isolate here.
ASSERT(Isolate::Current() == NULL);
}
void Dart::ShutdownIsolate() {
Isolate* isolate = Isolate::Current();
isolate->Shutdown();
delete isolate;
}
int64_t Dart::UptimeMicros() {
return OS::GetCurrentMonotonicMicros() - Dart::start_time_micros_;
}
uword Dart::AllocateReadOnlyHandle() {
ASSERT(Isolate::Current() == Dart::vm_isolate());
ASSERT(predefined_handles_ != NULL);
return predefined_handles_->handles_.AllocateScopedHandle();
}
LocalHandle* Dart::AllocateReadOnlyApiHandle() {
ASSERT(Isolate::Current() == Dart::vm_isolate());
ASSERT(predefined_handles_ != NULL);
return predefined_handles_->api_handles_.AllocateHandle();
}
bool Dart::IsReadOnlyHandle(uword address) {
ASSERT(predefined_handles_ != NULL);
return predefined_handles_->handles_.IsValidScopedHandle(address);
}
bool Dart::IsReadOnlyApiHandle(Dart_Handle handle) {
ASSERT(predefined_handles_ != NULL);
return predefined_handles_->api_handles_.IsValidHandle(handle);
}
} // namespace dart