// Copyright 2015 the V8 project authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#ifndef V8_ISOLATE_INL_H_
#define V8_ISOLATE_INL_H_
#include "src/isolate.h"
#include "src/objects-inl.h"
namespace v8 {
namespace internal {
bool Isolate::FromWritableHeapObject(HeapObject* obj, Isolate** isolate) {
i::MemoryChunk* chunk = i::MemoryChunk::FromHeapObject(obj);
if (chunk->owner()->identity() == i::RO_SPACE) {
*isolate = nullptr;
return false;
}
*isolate = chunk->heap()->isolate();
return true;
}
void Isolate::set_context(Context* context) {
DCHECK(context == nullptr || context->IsContext());
thread_local_top_.context_ = context;
}
Handle<NativeContext> Isolate::native_context() {
return handle(context()->native_context(), this);
}
NativeContext* Isolate::raw_native_context() {
return context()->native_context();
}
Object* Isolate::pending_exception() {
DCHECK(has_pending_exception());
DCHECK(!thread_local_top_.pending_exception_->IsException(this));
return thread_local_top_.pending_exception_;
}
void Isolate::set_pending_exception(Object* exception_obj) {
DCHECK(!exception_obj->IsException(this));
thread_local_top_.pending_exception_ = exception_obj;
}
void Isolate::clear_pending_exception() {
DCHECK(!thread_local_top_.pending_exception_->IsException(this));
thread_local_top_.pending_exception_ = ReadOnlyRoots(this).the_hole_value();
}
bool Isolate::has_pending_exception() {
DCHECK(!thread_local_top_.pending_exception_->IsException(this));
return !thread_local_top_.pending_exception_->IsTheHole(this);
}
Object* Isolate::get_wasm_caught_exception() {
return thread_local_top_.wasm_caught_exception_;
}
void Isolate::set_wasm_caught_exception(Object* exception) {
thread_local_top_.wasm_caught_exception_ = exception;
}
void Isolate::clear_wasm_caught_exception() {
thread_local_top_.wasm_caught_exception_ = nullptr;
}
void Isolate::clear_pending_message() {
thread_local_top_.pending_message_obj_ = ReadOnlyRoots(this).the_hole_value();
}
Object* Isolate::scheduled_exception() {
DCHECK(has_scheduled_exception());
DCHECK(!thread_local_top_.scheduled_exception_->IsException(this));
return thread_local_top_.scheduled_exception_;
}
bool Isolate::has_scheduled_exception() {
DCHECK(!thread_local_top_.scheduled_exception_->IsException(this));
return thread_local_top_.scheduled_exception_ !=
ReadOnlyRoots(this).the_hole_value();
}
void Isolate::clear_scheduled_exception() {
DCHECK(!thread_local_top_.scheduled_exception_->IsException(this));
thread_local_top_.scheduled_exception_ = ReadOnlyRoots(this).the_hole_value();
}
bool Isolate::is_catchable_by_javascript(Object* exception) {
return exception != ReadOnlyRoots(heap()).termination_exception();
}
void Isolate::FireBeforeCallEnteredCallback() {
for (auto& callback : before_call_entered_callbacks_) {
callback(reinterpret_cast<v8::Isolate*>(this));
}
}
void Isolate::FireMicrotasksCompletedCallback() {
std::vector<MicrotasksCompletedCallback> callbacks(
microtasks_completed_callbacks_);
for (auto& callback : callbacks) {
callback(reinterpret_cast<v8::Isolate*>(this));
}
}
Handle<JSGlobalObject> Isolate::global_object() {
return handle(context()->global_object(), this);
}
Handle<JSObject> Isolate::global_proxy() {
return handle(context()->global_proxy(), this);
}
Isolate::ExceptionScope::ExceptionScope(Isolate* isolate)
: isolate_(isolate),
pending_exception_(isolate_->pending_exception(), isolate_) {}
Isolate::ExceptionScope::~ExceptionScope() {
isolate_->set_pending_exception(*pending_exception_);
}
#define NATIVE_CONTEXT_FIELD_ACCESSOR(index, type, name) \
Handle<type> Isolate::name() { \
return Handle<type>(raw_native_context()->name(), this); \
} \
bool Isolate::is_##name(type* value) { \
return raw_native_context()->is_##name(value); \
}
NATIVE_CONTEXT_FIELDS(NATIVE_CONTEXT_FIELD_ACCESSOR)
#undef NATIVE_CONTEXT_FIELD_ACCESSOR
bool Isolate::IsArrayConstructorIntact() {
Cell* array_constructor_cell = heap()->array_constructor_protector();
return array_constructor_cell->value() == Smi::FromInt(kProtectorValid);
}
bool Isolate::IsArraySpeciesLookupChainIntact() {
// Note: It would be nice to have debug checks to make sure that the
// species protector is accurate, but this would be hard to do for most of
// what the protector stands for:
// - You'd need to traverse the heap to check that no Array instance has
// a constructor property
// - To check that Array[Symbol.species] == Array, JS code has to execute,
// but JS cannot be invoked in callstack overflow situations
// All that could be checked reliably is that
// Array.prototype.constructor == Array. Given that limitation, no check is
// done here. In place, there are mjsunit tests harmony/array-species* which
// ensure that behavior is correct in various invalid protector cases.
PropertyCell* species_cell = heap()->array_species_protector();
return species_cell->value()->IsSmi() &&
Smi::ToInt(species_cell->value()) == kProtectorValid;
}
bool Isolate::IsTypedArraySpeciesLookupChainIntact() {
PropertyCell* species_cell = heap()->typed_array_species_protector();
return species_cell->value()->IsSmi() &&
Smi::ToInt(species_cell->value()) == kProtectorValid;
}
bool Isolate::IsPromiseSpeciesLookupChainIntact() {
PropertyCell* species_cell = heap()->promise_species_protector();
return species_cell->value()->IsSmi() &&
Smi::ToInt(species_cell->value()) == kProtectorValid;
}
bool Isolate::IsStringLengthOverflowIntact() {
Cell* string_length_cell = heap()->string_length_protector();
return string_length_cell->value() == Smi::FromInt(kProtectorValid);
}
bool Isolate::IsArrayBufferNeuteringIntact() {
PropertyCell* buffer_neutering = heap()->array_buffer_neutering_protector();
return buffer_neutering->value() == Smi::FromInt(kProtectorValid);
}
bool Isolate::IsArrayIteratorLookupChainIntact() {
PropertyCell* array_iterator_cell = heap()->array_iterator_protector();
return array_iterator_cell->value() == Smi::FromInt(kProtectorValid);
}
} // namespace internal
} // namespace v8
#endif // V8_ISOLATE_INL_H_