// Copyright 2012 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. #include "src/elements.h" #include "src/arguments.h" #include "src/conversions.h" #include "src/factory.h" #include "src/isolate-inl.h" #include "src/messages.h" #include "src/objects-inl.h" #include "src/utils.h" // Each concrete ElementsAccessor can handle exactly one ElementsKind, // several abstract ElementsAccessor classes are used to allow sharing // common code. // // Inheritance hierarchy: // - ElementsAccessorBase (abstract) // - FastElementsAccessor (abstract) // - FastSmiOrObjectElementsAccessor // - FastPackedSmiElementsAccessor // - FastHoleySmiElementsAccessor // - FastPackedObjectElementsAccessor // - FastHoleyObjectElementsAccessor // - FastDoubleElementsAccessor // - FastPackedDoubleElementsAccessor // - FastHoleyDoubleElementsAccessor // - TypedElementsAccessor: template, with instantiations: // - FixedUint8ElementsAccessor // - FixedInt8ElementsAccessor // - FixedUint16ElementsAccessor // - FixedInt16ElementsAccessor // - FixedUint32ElementsAccessor // - FixedInt32ElementsAccessor // - FixedFloat32ElementsAccessor // - FixedFloat64ElementsAccessor // - FixedUint8ClampedElementsAccessor // - DictionaryElementsAccessor // - SloppyArgumentsElementsAccessor // - FastSloppyArgumentsElementsAccessor // - SlowSloppyArgumentsElementsAccessor // - StringWrapperElementsAccessor // - FastStringWrapperElementsAccessor // - SlowStringWrapperElementsAccessor namespace v8 { namespace internal { namespace { static const int kPackedSizeNotKnown = -1; enum Where { AT_START, AT_END }; // First argument in list is the accessor class, the second argument is the // accessor ElementsKind, and the third is the backing store class. Use the // fast element handler for smi-only arrays. The implementation is currently // identical. Note that the order must match that of the ElementsKind enum for // the |accessor_array[]| below to work. #define ELEMENTS_LIST(V) \ V(FastPackedSmiElementsAccessor, FAST_SMI_ELEMENTS, FixedArray) \ V(FastHoleySmiElementsAccessor, FAST_HOLEY_SMI_ELEMENTS, FixedArray) \ V(FastPackedObjectElementsAccessor, FAST_ELEMENTS, FixedArray) \ V(FastHoleyObjectElementsAccessor, FAST_HOLEY_ELEMENTS, FixedArray) \ V(FastPackedDoubleElementsAccessor, FAST_DOUBLE_ELEMENTS, FixedDoubleArray) \ V(FastHoleyDoubleElementsAccessor, FAST_HOLEY_DOUBLE_ELEMENTS, \ FixedDoubleArray) \ V(DictionaryElementsAccessor, DICTIONARY_ELEMENTS, SeededNumberDictionary) \ V(FastSloppyArgumentsElementsAccessor, FAST_SLOPPY_ARGUMENTS_ELEMENTS, \ FixedArray) \ V(SlowSloppyArgumentsElementsAccessor, SLOW_SLOPPY_ARGUMENTS_ELEMENTS, \ FixedArray) \ V(FastStringWrapperElementsAccessor, FAST_STRING_WRAPPER_ELEMENTS, \ FixedArray) \ V(SlowStringWrapperElementsAccessor, SLOW_STRING_WRAPPER_ELEMENTS, \ FixedArray) \ V(FixedUint8ElementsAccessor, UINT8_ELEMENTS, FixedUint8Array) \ V(FixedInt8ElementsAccessor, INT8_ELEMENTS, FixedInt8Array) \ V(FixedUint16ElementsAccessor, UINT16_ELEMENTS, FixedUint16Array) \ V(FixedInt16ElementsAccessor, INT16_ELEMENTS, FixedInt16Array) \ V(FixedUint32ElementsAccessor, UINT32_ELEMENTS, FixedUint32Array) \ V(FixedInt32ElementsAccessor, INT32_ELEMENTS, FixedInt32Array) \ V(FixedFloat32ElementsAccessor, FLOAT32_ELEMENTS, FixedFloat32Array) \ V(FixedFloat64ElementsAccessor, FLOAT64_ELEMENTS, FixedFloat64Array) \ V(FixedUint8ClampedElementsAccessor, UINT8_CLAMPED_ELEMENTS, \ FixedUint8ClampedArray) template class ElementsKindTraits { public: typedef FixedArrayBase BackingStore; }; #define ELEMENTS_TRAITS(Class, KindParam, Store) \ template<> class ElementsKindTraits { \ public: /* NOLINT */ \ static const ElementsKind Kind = KindParam; \ typedef Store BackingStore; \ }; ELEMENTS_LIST(ELEMENTS_TRAITS) #undef ELEMENTS_TRAITS MUST_USE_RESULT MaybeHandle ThrowArrayLengthRangeError(Isolate* isolate) { THROW_NEW_ERROR(isolate, NewRangeError(MessageTemplate::kInvalidArrayLength), Object); } void CopyObjectToObjectElements(FixedArrayBase* from_base, ElementsKind from_kind, uint32_t from_start, FixedArrayBase* to_base, ElementsKind to_kind, uint32_t to_start, int raw_copy_size) { DCHECK(to_base->map() != from_base->GetIsolate()->heap()->fixed_cow_array_map()); DisallowHeapAllocation no_allocation; int copy_size = raw_copy_size; if (raw_copy_size < 0) { DCHECK(raw_copy_size == ElementsAccessor::kCopyToEnd || raw_copy_size == ElementsAccessor::kCopyToEndAndInitializeToHole); copy_size = Min(from_base->length() - from_start, to_base->length() - to_start); if (raw_copy_size == ElementsAccessor::kCopyToEndAndInitializeToHole) { int start = to_start + copy_size; int length = to_base->length() - start; if (length > 0) { Heap* heap = from_base->GetHeap(); MemsetPointer(FixedArray::cast(to_base)->data_start() + start, heap->the_hole_value(), length); } } } DCHECK((copy_size + static_cast(to_start)) <= to_base->length() && (copy_size + static_cast(from_start)) <= from_base->length()); if (copy_size == 0) return; FixedArray* from = FixedArray::cast(from_base); FixedArray* to = FixedArray::cast(to_base); DCHECK(IsFastSmiOrObjectElementsKind(from_kind)); DCHECK(IsFastSmiOrObjectElementsKind(to_kind)); WriteBarrierMode write_barrier_mode = (IsFastObjectElementsKind(from_kind) && IsFastObjectElementsKind(to_kind)) ? UPDATE_WRITE_BARRIER : SKIP_WRITE_BARRIER; for (int i = 0; i < copy_size; i++) { Object* value = from->get(from_start + i); to->set(to_start + i, value, write_barrier_mode); } } static void CopyDictionaryToObjectElements( FixedArrayBase* from_base, uint32_t from_start, FixedArrayBase* to_base, ElementsKind to_kind, uint32_t to_start, int raw_copy_size) { DisallowHeapAllocation no_allocation; SeededNumberDictionary* from = SeededNumberDictionary::cast(from_base); int copy_size = raw_copy_size; if (raw_copy_size < 0) { DCHECK(raw_copy_size == ElementsAccessor::kCopyToEnd || raw_copy_size == ElementsAccessor::kCopyToEndAndInitializeToHole); copy_size = from->max_number_key() + 1 - from_start; if (raw_copy_size == ElementsAccessor::kCopyToEndAndInitializeToHole) { int start = to_start + copy_size; int length = to_base->length() - start; if (length > 0) { Heap* heap = from->GetHeap(); MemsetPointer(FixedArray::cast(to_base)->data_start() + start, heap->the_hole_value(), length); } } } DCHECK(to_base != from_base); DCHECK(IsFastSmiOrObjectElementsKind(to_kind)); if (copy_size == 0) return; FixedArray* to = FixedArray::cast(to_base); uint32_t to_length = to->length(); if (to_start + copy_size > to_length) { copy_size = to_length - to_start; } WriteBarrierMode write_barrier_mode = IsFastObjectElementsKind(to_kind) ? UPDATE_WRITE_BARRIER : SKIP_WRITE_BARRIER; Isolate* isolate = from->GetIsolate(); for (int i = 0; i < copy_size; i++) { int entry = from->FindEntry(isolate, i + from_start); if (entry != SeededNumberDictionary::kNotFound) { Object* value = from->ValueAt(entry); DCHECK(!value->IsTheHole(isolate)); to->set(i + to_start, value, write_barrier_mode); } else { to->set_the_hole(isolate, i + to_start); } } } // NOTE: this method violates the handlified function signature convention: // raw pointer parameters in the function that allocates. // See ElementsAccessorBase::CopyElements() for details. static void CopyDoubleToObjectElements(FixedArrayBase* from_base, uint32_t from_start, FixedArrayBase* to_base, uint32_t to_start, int raw_copy_size) { int copy_size = raw_copy_size; if (raw_copy_size < 0) { DisallowHeapAllocation no_allocation; DCHECK(raw_copy_size == ElementsAccessor::kCopyToEnd || raw_copy_size == ElementsAccessor::kCopyToEndAndInitializeToHole); copy_size = Min(from_base->length() - from_start, to_base->length() - to_start); if (raw_copy_size == ElementsAccessor::kCopyToEndAndInitializeToHole) { // Also initialize the area that will be copied over since HeapNumber // allocation below can cause an incremental marking step, requiring all // existing heap objects to be propertly initialized. int start = to_start; int length = to_base->length() - start; if (length > 0) { Heap* heap = from_base->GetHeap(); MemsetPointer(FixedArray::cast(to_base)->data_start() + start, heap->the_hole_value(), length); } } } DCHECK((copy_size + static_cast(to_start)) <= to_base->length() && (copy_size + static_cast(from_start)) <= from_base->length()); if (copy_size == 0) return; // From here on, the code below could actually allocate. Therefore the raw // values are wrapped into handles. Isolate* isolate = from_base->GetIsolate(); Handle from(FixedDoubleArray::cast(from_base), isolate); Handle to(FixedArray::cast(to_base), isolate); // Use an outer loop to not waste too much time on creating HandleScopes. // On the other hand we might overflow a single handle scope depending on // the copy_size. int offset = 0; while (offset < copy_size) { HandleScope scope(isolate); offset += 100; for (int i = offset - 100; i < offset && i < copy_size; ++i) { Handle value = FixedDoubleArray::get(*from, i + from_start, isolate); to->set(i + to_start, *value, UPDATE_WRITE_BARRIER); } } } static void CopyDoubleToDoubleElements(FixedArrayBase* from_base, uint32_t from_start, FixedArrayBase* to_base, uint32_t to_start, int raw_copy_size) { DisallowHeapAllocation no_allocation; int copy_size = raw_copy_size; if (raw_copy_size < 0) { DCHECK(raw_copy_size == ElementsAccessor::kCopyToEnd || raw_copy_size == ElementsAccessor::kCopyToEndAndInitializeToHole); copy_size = Min(from_base->length() - from_start, to_base->length() - to_start); if (raw_copy_size == ElementsAccessor::kCopyToEndAndInitializeToHole) { for (int i = to_start + copy_size; i < to_base->length(); ++i) { FixedDoubleArray::cast(to_base)->set_the_hole(i); } } } DCHECK((copy_size + static_cast(to_start)) <= to_base->length() && (copy_size + static_cast(from_start)) <= from_base->length()); if (copy_size == 0) return; FixedDoubleArray* from = FixedDoubleArray::cast(from_base); FixedDoubleArray* to = FixedDoubleArray::cast(to_base); Address to_address = to->address() + FixedDoubleArray::kHeaderSize; Address from_address = from->address() + FixedDoubleArray::kHeaderSize; to_address += kDoubleSize * to_start; from_address += kDoubleSize * from_start; int words_per_double = (kDoubleSize / kPointerSize); CopyWords(reinterpret_cast(to_address), reinterpret_cast(from_address), static_cast(words_per_double * copy_size)); } static void CopySmiToDoubleElements(FixedArrayBase* from_base, uint32_t from_start, FixedArrayBase* to_base, uint32_t to_start, int raw_copy_size) { DisallowHeapAllocation no_allocation; int copy_size = raw_copy_size; if (raw_copy_size < 0) { DCHECK(raw_copy_size == ElementsAccessor::kCopyToEnd || raw_copy_size == ElementsAccessor::kCopyToEndAndInitializeToHole); copy_size = from_base->length() - from_start; if (raw_copy_size == ElementsAccessor::kCopyToEndAndInitializeToHole) { for (int i = to_start + copy_size; i < to_base->length(); ++i) { FixedDoubleArray::cast(to_base)->set_the_hole(i); } } } DCHECK((copy_size + static_cast(to_start)) <= to_base->length() && (copy_size + static_cast(from_start)) <= from_base->length()); if (copy_size == 0) return; FixedArray* from = FixedArray::cast(from_base); FixedDoubleArray* to = FixedDoubleArray::cast(to_base); Object* the_hole = from->GetHeap()->the_hole_value(); for (uint32_t from_end = from_start + static_cast(copy_size); from_start < from_end; from_start++, to_start++) { Object* hole_or_smi = from->get(from_start); if (hole_or_smi == the_hole) { to->set_the_hole(to_start); } else { to->set(to_start, Smi::cast(hole_or_smi)->value()); } } } static void CopyPackedSmiToDoubleElements(FixedArrayBase* from_base, uint32_t from_start, FixedArrayBase* to_base, uint32_t to_start, int packed_size, int raw_copy_size) { DisallowHeapAllocation no_allocation; int copy_size = raw_copy_size; uint32_t to_end; if (raw_copy_size < 0) { DCHECK(raw_copy_size == ElementsAccessor::kCopyToEnd || raw_copy_size == ElementsAccessor::kCopyToEndAndInitializeToHole); copy_size = packed_size - from_start; if (raw_copy_size == ElementsAccessor::kCopyToEndAndInitializeToHole) { to_end = to_base->length(); for (uint32_t i = to_start + copy_size; i < to_end; ++i) { FixedDoubleArray::cast(to_base)->set_the_hole(i); } } else { to_end = to_start + static_cast(copy_size); } } else { to_end = to_start + static_cast(copy_size); } DCHECK(static_cast(to_end) <= to_base->length()); DCHECK(packed_size >= 0 && packed_size <= copy_size); DCHECK((copy_size + static_cast(to_start)) <= to_base->length() && (copy_size + static_cast(from_start)) <= from_base->length()); if (copy_size == 0) return; FixedArray* from = FixedArray::cast(from_base); FixedDoubleArray* to = FixedDoubleArray::cast(to_base); for (uint32_t from_end = from_start + static_cast(packed_size); from_start < from_end; from_start++, to_start++) { Object* smi = from->get(from_start); DCHECK(!smi->IsTheHole(from->GetIsolate())); to->set(to_start, Smi::cast(smi)->value()); } } static void CopyObjectToDoubleElements(FixedArrayBase* from_base, uint32_t from_start, FixedArrayBase* to_base, uint32_t to_start, int raw_copy_size) { DisallowHeapAllocation no_allocation; int copy_size = raw_copy_size; if (raw_copy_size < 0) { DCHECK(raw_copy_size == ElementsAccessor::kCopyToEnd || raw_copy_size == ElementsAccessor::kCopyToEndAndInitializeToHole); copy_size = from_base->length() - from_start; if (raw_copy_size == ElementsAccessor::kCopyToEndAndInitializeToHole) { for (int i = to_start + copy_size; i < to_base->length(); ++i) { FixedDoubleArray::cast(to_base)->set_the_hole(i); } } } DCHECK((copy_size + static_cast(to_start)) <= to_base->length() && (copy_size + static_cast(from_start)) <= from_base->length()); if (copy_size == 0) return; FixedArray* from = FixedArray::cast(from_base); FixedDoubleArray* to = FixedDoubleArray::cast(to_base); Object* the_hole = from->GetHeap()->the_hole_value(); for (uint32_t from_end = from_start + copy_size; from_start < from_end; from_start++, to_start++) { Object* hole_or_object = from->get(from_start); if (hole_or_object == the_hole) { to->set_the_hole(to_start); } else { to->set(to_start, hole_or_object->Number()); } } } static void CopyDictionaryToDoubleElements(FixedArrayBase* from_base, uint32_t from_start, FixedArrayBase* to_base, uint32_t to_start, int raw_copy_size) { DisallowHeapAllocation no_allocation; SeededNumberDictionary* from = SeededNumberDictionary::cast(from_base); int copy_size = raw_copy_size; if (copy_size < 0) { DCHECK(copy_size == ElementsAccessor::kCopyToEnd || copy_size == ElementsAccessor::kCopyToEndAndInitializeToHole); copy_size = from->max_number_key() + 1 - from_start; if (raw_copy_size == ElementsAccessor::kCopyToEndAndInitializeToHole) { for (int i = to_start + copy_size; i < to_base->length(); ++i) { FixedDoubleArray::cast(to_base)->set_the_hole(i); } } } if (copy_size == 0) return; FixedDoubleArray* to = FixedDoubleArray::cast(to_base); uint32_t to_length = to->length(); if (to_start + copy_size > to_length) { copy_size = to_length - to_start; } Isolate* isolate = from->GetIsolate(); for (int i = 0; i < copy_size; i++) { int entry = from->FindEntry(isolate, i + from_start); if (entry != SeededNumberDictionary::kNotFound) { to->set(i + to_start, from->ValueAt(entry)->Number()); } else { to->set_the_hole(i + to_start); } } } static void TraceTopFrame(Isolate* isolate) { StackFrameIterator it(isolate); if (it.done()) { PrintF("unknown location (no JavaScript frames present)"); return; } StackFrame* raw_frame = it.frame(); if (raw_frame->is_internal()) { Code* apply_builtin = isolate->builtins()->builtin(Builtins::kFunctionPrototypeApply); if (raw_frame->unchecked_code() == apply_builtin) { PrintF("apply from "); it.Advance(); raw_frame = it.frame(); } } JavaScriptFrame::PrintTop(isolate, stdout, false, true); } static void SortIndices( Handle indices, uint32_t sort_size, WriteBarrierMode write_barrier_mode = UPDATE_WRITE_BARRIER) { struct { bool operator()(Object* a, Object* b) { if (a->IsSmi() || !a->IsUndefined(HeapObject::cast(a)->GetIsolate())) { if (!b->IsSmi() && b->IsUndefined(HeapObject::cast(b)->GetIsolate())) { return true; } return a->Number() < b->Number(); } return !b->IsSmi() && b->IsUndefined(HeapObject::cast(b)->GetIsolate()); } } cmp; Object** start = reinterpret_cast(indices->GetFirstElementAddress()); std::sort(start, start + sort_size, cmp); if (write_barrier_mode != SKIP_WRITE_BARRIER) { FIXED_ARRAY_ELEMENTS_WRITE_BARRIER(indices->GetIsolate()->heap(), *indices, 0, sort_size); } } static Maybe IncludesValueSlowPath(Isolate* isolate, Handle receiver, Handle value, uint32_t start_from, uint32_t length) { bool search_for_hole = value->IsUndefined(isolate); for (uint32_t k = start_from; k < length; ++k) { LookupIterator it(isolate, receiver, k); if (!it.IsFound()) { if (search_for_hole) return Just(true); continue; } Handle element_k; ASSIGN_RETURN_ON_EXCEPTION_VALUE(isolate, element_k, Object::GetProperty(&it), Nothing()); if (value->SameValueZero(*element_k)) return Just(true); } return Just(false); } static Maybe IndexOfValueSlowPath(Isolate* isolate, Handle receiver, Handle value, uint32_t start_from, uint32_t length) { for (uint32_t k = start_from; k < length; ++k) { LookupIterator it(isolate, receiver, k); if (!it.IsFound()) { continue; } Handle element_k; ASSIGN_RETURN_ON_EXCEPTION_VALUE( isolate, element_k, Object::GetProperty(&it), Nothing()); if (value->StrictEquals(*element_k)) return Just(k); } return Just(-1); } // The InternalElementsAccessor is a helper class to expose otherwise protected // methods to its subclasses. Namely, we don't want to publicly expose methods // that take an entry (instead of an index) as an argument. class InternalElementsAccessor : public ElementsAccessor { public: explicit InternalElementsAccessor(const char* name) : ElementsAccessor(name) {} virtual uint32_t GetEntryForIndex(Isolate* isolate, JSObject* holder, FixedArrayBase* backing_store, uint32_t index) = 0; virtual PropertyDetails GetDetails(JSObject* holder, uint32_t entry) = 0; }; // Base class for element handler implementations. Contains the // the common logic for objects with different ElementsKinds. // Subclasses must specialize method for which the element // implementation differs from the base class implementation. // // This class is intended to be used in the following way: // // class SomeElementsAccessor : // public ElementsAccessorBase { // ... // } // // This is an example of the Curiously Recurring Template Pattern (see // http://en.wikipedia.org/wiki/Curiously_recurring_template_pattern). We use // CRTP to guarantee aggressive compile time optimizations (i.e. inlining and // specialization of SomeElementsAccessor methods). template class ElementsAccessorBase : public InternalElementsAccessor { public: explicit ElementsAccessorBase(const char* name) : InternalElementsAccessor(name) {} typedef ElementsTraitsParam ElementsTraits; typedef typename ElementsTraitsParam::BackingStore BackingStore; static ElementsKind kind() { return ElementsTraits::Kind; } static void ValidateContents(Handle holder, int length) { } static void ValidateImpl(Handle holder) { Handle fixed_array_base(holder->elements()); if (!fixed_array_base->IsHeapObject()) return; // Arrays that have been shifted in place can't be verified. if (fixed_array_base->IsFiller()) return; int length = 0; if (holder->IsJSArray()) { Object* length_obj = Handle::cast(holder)->length(); if (length_obj->IsSmi()) { length = Smi::cast(length_obj)->value(); } } else { length = fixed_array_base->length(); } Subclass::ValidateContents(holder, length); } void Validate(Handle holder) final { DisallowHeapAllocation no_gc; Subclass::ValidateImpl(holder); } static bool IsPackedImpl(Handle holder, Handle backing_store, uint32_t start, uint32_t end) { if (IsFastPackedElementsKind(kind())) return true; Isolate* isolate = backing_store->GetIsolate(); for (uint32_t i = start; i < end; i++) { if (!Subclass::HasElementImpl(isolate, holder, i, backing_store, ALL_PROPERTIES)) { return false; } } return true; } static void TryTransitionResultArrayToPacked(Handle array) { if (!IsHoleyElementsKind(kind())) return; int length = Smi::cast(array->length())->value(); Handle backing_store(array->elements()); if (!Subclass::IsPackedImpl(array, backing_store, 0, length)) { return; } ElementsKind packed_kind = GetPackedElementsKind(kind()); Handle new_map = JSObject::GetElementsTransitionMap(array, packed_kind); JSObject::MigrateToMap(array, new_map); if (FLAG_trace_elements_transitions) { JSObject::PrintElementsTransition(stdout, array, kind(), backing_store, packed_kind, backing_store); } } bool HasElement(Handle holder, uint32_t index, Handle backing_store, PropertyFilter filter) final { return Subclass::HasElementImpl(holder->GetIsolate(), holder, index, backing_store, filter); } static bool HasElementImpl(Isolate* isolate, Handle holder, uint32_t index, Handle backing_store, PropertyFilter filter = ALL_PROPERTIES) { return Subclass::GetEntryForIndexImpl(isolate, *holder, *backing_store, index, filter) != kMaxUInt32; } bool HasAccessors(JSObject* holder) final { return Subclass::HasAccessorsImpl(holder, holder->elements()); } static bool HasAccessorsImpl(JSObject* holder, FixedArrayBase* backing_store) { return false; } Handle Get(Handle holder, uint32_t entry) final { return Subclass::GetInternalImpl(holder, entry); } static Handle GetInternalImpl(Handle holder, uint32_t entry) { return Subclass::GetImpl(holder->GetIsolate(), holder->elements(), entry); } static Handle GetImpl(Isolate* isolate, FixedArrayBase* backing_store, uint32_t entry) { uint32_t index = GetIndexForEntryImpl(backing_store, entry); return handle(BackingStore::cast(backing_store)->get(index), isolate); } void Set(Handle holder, uint32_t entry, Object* value) final { Subclass::SetImpl(holder, entry, value); } void Reconfigure(Handle object, Handle store, uint32_t entry, Handle value, PropertyAttributes attributes) final { Subclass::ReconfigureImpl(object, store, entry, value, attributes); } static void ReconfigureImpl(Handle object, Handle store, uint32_t entry, Handle value, PropertyAttributes attributes) { UNREACHABLE(); } void Add(Handle object, uint32_t index, Handle value, PropertyAttributes attributes, uint32_t new_capacity) final { Subclass::AddImpl(object, index, value, attributes, new_capacity); } static void AddImpl(Handle object, uint32_t index, Handle value, PropertyAttributes attributes, uint32_t new_capacity) { UNREACHABLE(); } uint32_t Push(Handle receiver, Arguments* args, uint32_t push_size) final { return Subclass::PushImpl(receiver, args, push_size); } static uint32_t PushImpl(Handle receiver, Arguments* args, uint32_t push_sized) { UNREACHABLE(); return 0; } uint32_t Unshift(Handle receiver, Arguments* args, uint32_t unshift_size) final { return Subclass::UnshiftImpl(receiver, args, unshift_size); } static uint32_t UnshiftImpl(Handle receiver, Arguments* args, uint32_t unshift_size) { UNREACHABLE(); return 0; } Handle Slice(Handle receiver, uint32_t start, uint32_t end) final { return Subclass::SliceImpl(receiver, start, end); } static Handle SliceImpl(Handle receiver, uint32_t start, uint32_t end) { UNREACHABLE(); return Handle(); } Handle Splice(Handle receiver, uint32_t start, uint32_t delete_count, Arguments* args, uint32_t add_count) final { return Subclass::SpliceImpl(receiver, start, delete_count, args, add_count); } static Handle SpliceImpl(Handle receiver, uint32_t start, uint32_t delete_count, Arguments* args, uint32_t add_count) { UNREACHABLE(); return Handle(); } Handle Pop(Handle receiver) final { return Subclass::PopImpl(receiver); } static Handle PopImpl(Handle receiver) { UNREACHABLE(); return Handle(); } Handle Shift(Handle receiver) final { return Subclass::ShiftImpl(receiver); } static Handle ShiftImpl(Handle receiver) { UNREACHABLE(); return Handle(); } void SetLength(Handle array, uint32_t length) final { Subclass::SetLengthImpl(array->GetIsolate(), array, length, handle(array->elements())); } static void SetLengthImpl(Isolate* isolate, Handle array, uint32_t length, Handle backing_store) { DCHECK(!array->SetLengthWouldNormalize(length)); DCHECK(IsFastElementsKind(array->GetElementsKind())); uint32_t old_length = 0; CHECK(array->length()->ToArrayIndex(&old_length)); if (old_length < length) { ElementsKind kind = array->GetElementsKind(); if (!IsFastHoleyElementsKind(kind)) { kind = GetHoleyElementsKind(kind); JSObject::TransitionElementsKind(array, kind); } } // Check whether the backing store should be shrunk. uint32_t capacity = backing_store->length(); old_length = Min(old_length, capacity); if (length == 0) { array->initialize_elements(); } else if (length <= capacity) { if (IsFastSmiOrObjectElementsKind(kind())) { JSObject::EnsureWritableFastElements(array); if (array->elements() != *backing_store) { backing_store = handle(array->elements(), isolate); } } if (2 * length <= capacity) { // If more than half the elements won't be used, trim the array. isolate->heap()->RightTrimFixedArray(*backing_store, capacity - length); } else { // Otherwise, fill the unused tail with holes. BackingStore::cast(*backing_store)->FillWithHoles(length, old_length); } } else { // Check whether the backing store should be expanded. capacity = Max(length, JSObject::NewElementsCapacity(capacity)); Subclass::GrowCapacityAndConvertImpl(array, capacity); } array->set_length(Smi::FromInt(length)); JSObject::ValidateElements(array); } uint32_t NumberOfElements(JSObject* receiver) final { return Subclass::NumberOfElementsImpl(receiver, receiver->elements()); } static uint32_t NumberOfElementsImpl(JSObject* receiver, FixedArrayBase* backing_store) { UNREACHABLE(); } static uint32_t GetMaxIndex(JSObject* receiver, FixedArrayBase* elements) { if (receiver->IsJSArray()) { DCHECK(JSArray::cast(receiver)->length()->IsSmi()); return static_cast( Smi::cast(JSArray::cast(receiver)->length())->value()); } return Subclass::GetCapacityImpl(receiver, elements); } static uint32_t GetMaxNumberOfEntries(JSObject* receiver, FixedArrayBase* elements) { return Subclass::GetMaxIndex(receiver, elements); } static Handle ConvertElementsWithCapacity( Handle object, Handle old_elements, ElementsKind from_kind, uint32_t capacity) { return ConvertElementsWithCapacity( object, old_elements, from_kind, capacity, 0, 0, ElementsAccessor::kCopyToEndAndInitializeToHole); } static Handle ConvertElementsWithCapacity( Handle object, Handle old_elements, ElementsKind from_kind, uint32_t capacity, int copy_size) { return ConvertElementsWithCapacity(object, old_elements, from_kind, capacity, 0, 0, copy_size); } static Handle ConvertElementsWithCapacity( Handle object, Handle old_elements, ElementsKind from_kind, uint32_t capacity, uint32_t src_index, uint32_t dst_index, int copy_size) { Isolate* isolate = object->GetIsolate(); Handle new_elements; if (IsFastDoubleElementsKind(kind())) { new_elements = isolate->factory()->NewFixedDoubleArray(capacity); } else { new_elements = isolate->factory()->NewUninitializedFixedArray(capacity); } int packed_size = kPackedSizeNotKnown; if (IsFastPackedElementsKind(from_kind) && object->IsJSArray()) { packed_size = Smi::cast(JSArray::cast(*object)->length())->value(); } Subclass::CopyElementsImpl(*old_elements, src_index, *new_elements, from_kind, dst_index, packed_size, copy_size); return new_elements; } static void TransitionElementsKindImpl(Handle object, Handle to_map) { Handle from_map = handle(object->map()); ElementsKind from_kind = from_map->elements_kind(); ElementsKind to_kind = to_map->elements_kind(); if (IsFastHoleyElementsKind(from_kind)) { to_kind = GetHoleyElementsKind(to_kind); } if (from_kind != to_kind) { // This method should never be called for any other case. DCHECK(IsFastElementsKind(from_kind)); DCHECK(IsFastElementsKind(to_kind)); DCHECK_NE(TERMINAL_FAST_ELEMENTS_KIND, from_kind); Handle from_elements(object->elements()); if (object->elements() == object->GetHeap()->empty_fixed_array() || IsFastDoubleElementsKind(from_kind) == IsFastDoubleElementsKind(to_kind)) { // No change is needed to the elements() buffer, the transition // only requires a map change. JSObject::MigrateToMap(object, to_map); } else { DCHECK((IsFastSmiElementsKind(from_kind) && IsFastDoubleElementsKind(to_kind)) || (IsFastDoubleElementsKind(from_kind) && IsFastObjectElementsKind(to_kind))); uint32_t capacity = static_cast(object->elements()->length()); Handle elements = ConvertElementsWithCapacity( object, from_elements, from_kind, capacity); JSObject::SetMapAndElements(object, to_map, elements); } if (FLAG_trace_elements_transitions) { JSObject::PrintElementsTransition(stdout, object, from_kind, from_elements, to_kind, handle(object->elements())); } } } static void GrowCapacityAndConvertImpl(Handle object, uint32_t capacity) { ElementsKind from_kind = object->GetElementsKind(); if (IsFastSmiOrObjectElementsKind(from_kind)) { // Array optimizations rely on the prototype lookups of Array objects // always returning undefined. If there is a store to the initial // prototype object, make sure all of these optimizations are invalidated. object->GetIsolate()->UpdateArrayProtectorOnSetLength(object); } Handle old_elements(object->elements()); // This method should only be called if there's a reason to update the // elements. DCHECK(IsFastDoubleElementsKind(from_kind) != IsFastDoubleElementsKind(kind()) || IsDictionaryElementsKind(from_kind) || static_cast(old_elements->length()) < capacity); Subclass::BasicGrowCapacityAndConvertImpl(object, old_elements, from_kind, kind(), capacity); } static void BasicGrowCapacityAndConvertImpl( Handle object, Handle old_elements, ElementsKind from_kind, ElementsKind to_kind, uint32_t capacity) { Handle elements = ConvertElementsWithCapacity(object, old_elements, from_kind, capacity); if (IsHoleyElementsKind(from_kind)) to_kind = GetHoleyElementsKind(to_kind); Handle new_map = JSObject::GetElementsTransitionMap(object, to_kind); JSObject::SetMapAndElements(object, new_map, elements); // Transition through the allocation site as well if present. JSObject::UpdateAllocationSite(object, to_kind); if (FLAG_trace_elements_transitions) { JSObject::PrintElementsTransition(stdout, object, from_kind, old_elements, to_kind, elements); } } void TransitionElementsKind(Handle object, Handle map) final { Subclass::TransitionElementsKindImpl(object, map); } void GrowCapacityAndConvert(Handle object, uint32_t capacity) final { Subclass::GrowCapacityAndConvertImpl(object, capacity); } bool GrowCapacity(Handle object, uint32_t index) final { // This function is intended to be called from optimized code. We don't // want to trigger lazy deopts there, so refuse to handle cases that would. if (object->map()->is_prototype_map() || object->WouldConvertToSlowElements(index)) { return false; } Handle old_elements(object->elements()); uint32_t new_capacity = JSObject::NewElementsCapacity(index + 1); DCHECK(static_cast(old_elements->length()) < new_capacity); Handle elements = ConvertElementsWithCapacity(object, old_elements, kind(), new_capacity); DCHECK_EQ(object->GetElementsKind(), kind()); // Transition through the allocation site as well if present. if (JSObject::UpdateAllocationSite( object, kind())) { return false; } object->set_elements(*elements); return true; } void Delete(Handle obj, uint32_t entry) final { Subclass::DeleteImpl(obj, entry); } static void CopyElementsImpl(FixedArrayBase* from, uint32_t from_start, FixedArrayBase* to, ElementsKind from_kind, uint32_t to_start, int packed_size, int copy_size) { UNREACHABLE(); } void CopyElements(JSObject* from_holder, uint32_t from_start, ElementsKind from_kind, Handle to, uint32_t to_start, int copy_size) final { int packed_size = kPackedSizeNotKnown; bool is_packed = IsFastPackedElementsKind(from_kind) && from_holder->IsJSArray(); if (is_packed) { packed_size = Smi::cast(JSArray::cast(from_holder)->length())->value(); if (copy_size >= 0 && packed_size > copy_size) { packed_size = copy_size; } } FixedArrayBase* from = from_holder->elements(); // NOTE: the Subclass::CopyElementsImpl() methods // violate the handlified function signature convention: // raw pointer parameters in the function that allocates. This is done // intentionally to avoid ArrayConcat() builtin performance degradation. // // Details: The idea is that allocations actually happen only in case of // copying from object with fast double elements to object with object // elements. In all the other cases there are no allocations performed and // handle creation causes noticeable performance degradation of the builtin. Subclass::CopyElementsImpl(from, from_start, *to, from_kind, to_start, packed_size, copy_size); } void CopyElements(Handle source, ElementsKind source_kind, Handle destination, int size) { Subclass::CopyElementsImpl(*source, 0, *destination, source_kind, 0, kPackedSizeNotKnown, size); } Handle Normalize(Handle object) final { return Subclass::NormalizeImpl(object, handle(object->elements())); } static Handle NormalizeImpl( Handle object, Handle elements) { UNREACHABLE(); return Handle(); } Maybe CollectValuesOrEntries(Isolate* isolate, Handle object, Handle values_or_entries, bool get_entries, int* nof_items, PropertyFilter filter) { return Subclass::CollectValuesOrEntriesImpl( isolate, object, values_or_entries, get_entries, nof_items, filter); } static Maybe CollectValuesOrEntriesImpl( Isolate* isolate, Handle object, Handle values_or_entries, bool get_entries, int* nof_items, PropertyFilter filter) { DCHECK_EQ(*nof_items, 0); KeyAccumulator accumulator(isolate, KeyCollectionMode::kOwnOnly, ALL_PROPERTIES); Subclass::CollectElementIndicesImpl( object, handle(object->elements(), isolate), &accumulator); Handle keys = accumulator.GetKeys(); int count = 0; int i = 0; Handle original_map(object->map(), isolate); for (; i < keys->length(); ++i) { Handle key(keys->get(i), isolate); uint32_t index; if (!key->ToUint32(&index)) continue; DCHECK_EQ(object->map(), *original_map); uint32_t entry = Subclass::GetEntryForIndexImpl( isolate, *object, object->elements(), index, filter); if (entry == kMaxUInt32) continue; PropertyDetails details = Subclass::GetDetailsImpl(*object, entry); Handle value; if (details.kind() == kData) { value = Subclass::GetImpl(isolate, object->elements(), entry); } else { // This might modify the elements and/or change the elements kind. LookupIterator it(isolate, object, index, LookupIterator::OWN); ASSIGN_RETURN_ON_EXCEPTION_VALUE( isolate, value, Object::GetProperty(&it), Nothing()); } if (get_entries) value = MakeEntryPair(isolate, index, value); values_or_entries->set(count++, *value); if (object->map() != *original_map) break; } // Slow path caused by changes in elements kind during iteration. for (; i < keys->length(); i++) { Handle key(keys->get(i), isolate); uint32_t index; if (!key->ToUint32(&index)) continue; if (filter & ONLY_ENUMERABLE) { InternalElementsAccessor* accessor = reinterpret_cast( object->GetElementsAccessor()); uint32_t entry = accessor->GetEntryForIndex(isolate, *object, object->elements(), index); if (entry == kMaxUInt32) continue; PropertyDetails details = accessor->GetDetails(*object, entry); if (!details.IsEnumerable()) continue; } Handle value; LookupIterator it(isolate, object, index, LookupIterator::OWN); ASSIGN_RETURN_ON_EXCEPTION_VALUE(isolate, value, Object::GetProperty(&it), Nothing()); if (get_entries) value = MakeEntryPair(isolate, index, value); values_or_entries->set(count++, *value); } *nof_items = count; return Just(true); } void CollectElementIndices(Handle object, Handle backing_store, KeyAccumulator* keys) final { if (keys->filter() & ONLY_ALL_CAN_READ) return; Subclass::CollectElementIndicesImpl(object, backing_store, keys); } static void CollectElementIndicesImpl(Handle object, Handle backing_store, KeyAccumulator* keys) { DCHECK_NE(DICTIONARY_ELEMENTS, kind()); // Non-dictionary elements can't have all-can-read accessors. uint32_t length = Subclass::GetMaxIndex(*object, *backing_store); PropertyFilter filter = keys->filter(); Isolate* isolate = keys->isolate(); Factory* factory = isolate->factory(); for (uint32_t i = 0; i < length; i++) { if (Subclass::HasElementImpl(isolate, object, i, backing_store, filter)) { keys->AddKey(factory->NewNumberFromUint(i)); } } } static Handle DirectCollectElementIndicesImpl( Isolate* isolate, Handle object, Handle backing_store, GetKeysConversion convert, PropertyFilter filter, Handle list, uint32_t* nof_indices, uint32_t insertion_index = 0) { uint32_t length = Subclass::GetMaxIndex(*object, *backing_store); for (uint32_t i = 0; i < length; i++) { if (Subclass::HasElementImpl(isolate, object, i, backing_store, filter)) { if (convert == GetKeysConversion::kConvertToString) { Handle index_string = isolate->factory()->Uint32ToString(i); list->set(insertion_index, *index_string); } else { list->set(insertion_index, Smi::FromInt(i), SKIP_WRITE_BARRIER); } insertion_index++; } } *nof_indices = insertion_index; return list; } MaybeHandle PrependElementIndices( Handle object, Handle backing_store, Handle keys, GetKeysConversion convert, PropertyFilter filter) final { return Subclass::PrependElementIndicesImpl(object, backing_store, keys, convert, filter); } static MaybeHandle PrependElementIndicesImpl( Handle object, Handle backing_store, Handle keys, GetKeysConversion convert, PropertyFilter filter) { Isolate* isolate = object->GetIsolate(); uint32_t nof_property_keys = keys->length(); uint32_t initial_list_length = Subclass::GetMaxNumberOfEntries(*object, *backing_store); initial_list_length += nof_property_keys; if (initial_list_length > FixedArray::kMaxLength || initial_list_length < nof_property_keys) { return isolate->Throw(isolate->factory()->NewRangeError( MessageTemplate::kInvalidArrayLength)); } // Collect the element indices into a new list. MaybeHandle raw_array = isolate->factory()->TryNewFixedArray(initial_list_length); Handle combined_keys; // If we have a holey backing store try to precisely estimate the backing // store size as a last emergency measure if we cannot allocate the big // array. if (!raw_array.ToHandle(&combined_keys)) { if (IsHoleyElementsKind(kind())) { // If we overestimate the result list size we might end up in the // large-object space which doesn't free memory on shrinking the list. // Hence we try to estimate the final size for holey backing stores more // precisely here. initial_list_length = Subclass::NumberOfElementsImpl(*object, *backing_store); initial_list_length += nof_property_keys; } combined_keys = isolate->factory()->NewFixedArray(initial_list_length); } uint32_t nof_indices = 0; bool needs_sorting = IsDictionaryElementsKind(kind()) || IsSloppyArgumentsElements(kind()); combined_keys = Subclass::DirectCollectElementIndicesImpl( isolate, object, backing_store, needs_sorting ? GetKeysConversion::kKeepNumbers : convert, filter, combined_keys, &nof_indices); if (needs_sorting) { SortIndices(combined_keys, nof_indices); // Indices from dictionary elements should only be converted after // sorting. if (convert == GetKeysConversion::kConvertToString) { for (uint32_t i = 0; i < nof_indices; i++) { Handle index_string = isolate->factory()->Uint32ToString( combined_keys->get(i)->Number()); combined_keys->set(i, *index_string); } } } // Copy over the passed-in property keys. CopyObjectToObjectElements(*keys, FAST_ELEMENTS, 0, *combined_keys, FAST_ELEMENTS, nof_indices, nof_property_keys); // For holey elements and arguments we might have to shrink the collected // keys since the estimates might be off. if (IsHoleyElementsKind(kind()) || IsSloppyArgumentsElements(kind())) { // Shrink combined_keys to the final size. int final_size = nof_indices + nof_property_keys; DCHECK_LE(final_size, combined_keys->length()); combined_keys->Shrink(final_size); } return combined_keys; } void AddElementsToKeyAccumulator(Handle receiver, KeyAccumulator* accumulator, AddKeyConversion convert) final { Subclass::AddElementsToKeyAccumulatorImpl(receiver, accumulator, convert); } static uint32_t GetCapacityImpl(JSObject* holder, FixedArrayBase* backing_store) { return backing_store->length(); } uint32_t GetCapacity(JSObject* holder, FixedArrayBase* backing_store) final { return Subclass::GetCapacityImpl(holder, backing_store); } static Maybe IncludesValueImpl(Isolate* isolate, Handle receiver, Handle value, uint32_t start_from, uint32_t length) { return IncludesValueSlowPath(isolate, receiver, value, start_from, length); } Maybe IncludesValue(Isolate* isolate, Handle receiver, Handle value, uint32_t start_from, uint32_t length) final { return Subclass::IncludesValueImpl(isolate, receiver, value, start_from, length); } static Maybe IndexOfValueImpl(Isolate* isolate, Handle receiver, Handle value, uint32_t start_from, uint32_t length) { return IndexOfValueSlowPath(isolate, receiver, value, start_from, length); } Maybe IndexOfValue(Isolate* isolate, Handle receiver, Handle value, uint32_t start_from, uint32_t length) final { return Subclass::IndexOfValueImpl(isolate, receiver, value, start_from, length); } static uint32_t GetIndexForEntryImpl(FixedArrayBase* backing_store, uint32_t entry) { return entry; } static uint32_t GetEntryForIndexImpl(Isolate* isolate, JSObject* holder, FixedArrayBase* backing_store, uint32_t index, PropertyFilter filter) { uint32_t length = Subclass::GetMaxIndex(holder, backing_store); if (IsHoleyElementsKind(kind())) { return index < length && !BackingStore::cast(backing_store) ->is_the_hole(isolate, index) ? index : kMaxUInt32; } else { return index < length ? index : kMaxUInt32; } } uint32_t GetEntryForIndex(Isolate* isolate, JSObject* holder, FixedArrayBase* backing_store, uint32_t index) final { return Subclass::GetEntryForIndexImpl(isolate, holder, backing_store, index, ALL_PROPERTIES); } static PropertyDetails GetDetailsImpl(FixedArrayBase* backing_store, uint32_t entry) { return PropertyDetails(kData, NONE, 0, PropertyCellType::kNoCell); } static PropertyDetails GetDetailsImpl(JSObject* holder, uint32_t entry) { return PropertyDetails(kData, NONE, 0, PropertyCellType::kNoCell); } PropertyDetails GetDetails(JSObject* holder, uint32_t entry) final { return Subclass::GetDetailsImpl(holder, entry); } Handle CreateListFromArray(Isolate* isolate, Handle array) final { return Subclass::CreateListFromArrayImpl(isolate, array); }; static Handle CreateListFromArrayImpl(Isolate* isolate, Handle array) { UNREACHABLE(); return Handle(); } private: DISALLOW_COPY_AND_ASSIGN(ElementsAccessorBase); }; class DictionaryElementsAccessor : public ElementsAccessorBase > { public: explicit DictionaryElementsAccessor(const char* name) : ElementsAccessorBase >(name) {} static uint32_t GetMaxIndex(JSObject* receiver, FixedArrayBase* elements) { // We cannot properly estimate this for dictionaries. UNREACHABLE(); } static uint32_t GetMaxNumberOfEntries(JSObject* receiver, FixedArrayBase* backing_store) { return NumberOfElementsImpl(receiver, backing_store); } static uint32_t NumberOfElementsImpl(JSObject* receiver, FixedArrayBase* backing_store) { SeededNumberDictionary* dict = SeededNumberDictionary::cast(backing_store); return dict->NumberOfElements(); } static void SetLengthImpl(Isolate* isolate, Handle array, uint32_t length, Handle backing_store) { Handle dict = Handle::cast(backing_store); int capacity = dict->Capacity(); uint32_t old_length = 0; CHECK(array->length()->ToArrayLength(&old_length)); if (length < old_length) { if (dict->requires_slow_elements()) { // Find last non-deletable element in range of elements to be // deleted and adjust range accordingly. for (int entry = 0; entry < capacity; entry++) { DisallowHeapAllocation no_gc; Object* index = dict->KeyAt(entry); if (index->IsNumber()) { uint32_t number = static_cast(index->Number()); if (length <= number && number < old_length) { PropertyDetails details = dict->DetailsAt(entry); if (!details.IsConfigurable()) length = number + 1; } } } } if (length == 0) { // Flush the backing store. JSObject::ResetElements(array); } else { DisallowHeapAllocation no_gc; // Remove elements that should be deleted. int removed_entries = 0; Handle the_hole_value = isolate->factory()->the_hole_value(); for (int entry = 0; entry < capacity; entry++) { Object* index = dict->KeyAt(entry); if (index->IsNumber()) { uint32_t number = static_cast(index->Number()); if (length <= number && number < old_length) { dict->SetEntry(entry, the_hole_value, the_hole_value); removed_entries++; } } } // Update the number of elements. dict->ElementsRemoved(removed_entries); } } Handle length_obj = isolate->factory()->NewNumberFromUint(length); array->set_length(*length_obj); } static void CopyElementsImpl(FixedArrayBase* from, uint32_t from_start, FixedArrayBase* to, ElementsKind from_kind, uint32_t to_start, int packed_size, int copy_size) { UNREACHABLE(); } static void DeleteImpl(Handle obj, uint32_t entry) { // TODO(verwaest): Remove reliance on index in Shrink. Handle dict( SeededNumberDictionary::cast(obj->elements())); uint32_t index = GetIndexForEntryImpl(*dict, entry); Handle result = SeededNumberDictionary::DeleteProperty(dict, entry); USE(result); DCHECK(result->IsTrue(dict->GetIsolate())); Handle new_elements = SeededNumberDictionary::Shrink(dict, index); obj->set_elements(*new_elements); } static bool HasAccessorsImpl(JSObject* holder, FixedArrayBase* backing_store) { DisallowHeapAllocation no_gc; SeededNumberDictionary* dict = SeededNumberDictionary::cast(backing_store); if (!dict->requires_slow_elements()) return false; int capacity = dict->Capacity(); Isolate* isolate = dict->GetIsolate(); for (int i = 0; i < capacity; i++) { Object* key = dict->KeyAt(i); if (!dict->IsKey(isolate, key)) continue; DCHECK(!dict->IsDeleted(i)); PropertyDetails details = dict->DetailsAt(i); if (details.kind() == kAccessor) return true; } return false; } static Object* GetRaw(FixedArrayBase* store, uint32_t entry) { SeededNumberDictionary* backing_store = SeededNumberDictionary::cast(store); return backing_store->ValueAt(entry); } static Handle GetImpl(Isolate* isolate, FixedArrayBase* backing_store, uint32_t entry) { return handle(GetRaw(backing_store, entry), isolate); } static inline void SetImpl(Handle holder, uint32_t entry, Object* value) { SetImpl(holder->elements(), entry, value); } static inline void SetImpl(FixedArrayBase* backing_store, uint32_t entry, Object* value) { SeededNumberDictionary::cast(backing_store)->ValueAtPut(entry, value); } static void ReconfigureImpl(Handle object, Handle store, uint32_t entry, Handle value, PropertyAttributes attributes) { SeededNumberDictionary* dictionary = SeededNumberDictionary::cast(*store); if (attributes != NONE) object->RequireSlowElements(dictionary); dictionary->ValueAtPut(entry, *value); PropertyDetails details = dictionary->DetailsAt(entry); details = PropertyDetails(kData, attributes, details.dictionary_index(), PropertyCellType::kNoCell); dictionary->DetailsAtPut(entry, details); } static void AddImpl(Handle object, uint32_t index, Handle value, PropertyAttributes attributes, uint32_t new_capacity) { PropertyDetails details(kData, attributes, 0, PropertyCellType::kNoCell); Handle dictionary = object->HasFastElements() || object->HasFastStringWrapperElements() ? JSObject::NormalizeElements(object) : handle(SeededNumberDictionary::cast(object->elements())); Handle new_dictionary = SeededNumberDictionary::AddNumberEntry(dictionary, index, value, details, object); if (attributes != NONE) object->RequireSlowElements(*new_dictionary); if (dictionary.is_identical_to(new_dictionary)) return; object->set_elements(*new_dictionary); } static bool HasEntryImpl(Isolate* isolate, FixedArrayBase* store, uint32_t entry) { DisallowHeapAllocation no_gc; SeededNumberDictionary* dict = SeededNumberDictionary::cast(store); Object* index = dict->KeyAt(entry); return !index->IsTheHole(isolate); } static uint32_t GetIndexForEntryImpl(FixedArrayBase* store, uint32_t entry) { DisallowHeapAllocation no_gc; SeededNumberDictionary* dict = SeededNumberDictionary::cast(store); uint32_t result = 0; CHECK(dict->KeyAt(entry)->ToArrayIndex(&result)); return result; } static uint32_t GetEntryForIndexImpl(Isolate* isolate, JSObject* holder, FixedArrayBase* store, uint32_t index, PropertyFilter filter) { DisallowHeapAllocation no_gc; SeededNumberDictionary* dictionary = SeededNumberDictionary::cast(store); int entry = dictionary->FindEntry(isolate, index); if (entry == SeededNumberDictionary::kNotFound) return kMaxUInt32; if (filter != ALL_PROPERTIES) { PropertyDetails details = dictionary->DetailsAt(entry); PropertyAttributes attr = details.attributes(); if ((attr & filter) != 0) return kMaxUInt32; } return static_cast(entry); } static PropertyDetails GetDetailsImpl(JSObject* holder, uint32_t entry) { return GetDetailsImpl(holder->elements(), entry); } static PropertyDetails GetDetailsImpl(FixedArrayBase* backing_store, uint32_t entry) { return SeededNumberDictionary::cast(backing_store)->DetailsAt(entry); } static uint32_t FilterKey(Handle dictionary, int entry, Object* raw_key, PropertyFilter filter) { DCHECK(!dictionary->IsDeleted(entry)); DCHECK(raw_key->IsNumber()); DCHECK_LE(raw_key->Number(), kMaxUInt32); PropertyDetails details = dictionary->DetailsAt(entry); PropertyAttributes attr = details.attributes(); if ((attr & filter) != 0) return kMaxUInt32; return static_cast(raw_key->Number()); } static uint32_t GetKeyForEntryImpl(Isolate* isolate, Handle dictionary, int entry, PropertyFilter filter) { DisallowHeapAllocation no_gc; Object* raw_key = dictionary->KeyAt(entry); if (!dictionary->IsKey(isolate, raw_key)) return kMaxUInt32; return FilterKey(dictionary, entry, raw_key, filter); } static void CollectElementIndicesImpl(Handle object, Handle backing_store, KeyAccumulator* keys) { if (keys->filter() & SKIP_STRINGS) return; Isolate* isolate = keys->isolate(); Handle dictionary = Handle::cast(backing_store); int capacity = dictionary->Capacity(); Handle elements = isolate->factory()->NewFixedArray( GetMaxNumberOfEntries(*object, *backing_store)); int insertion_index = 0; PropertyFilter filter = keys->filter(); for (int i = 0; i < capacity; i++) { Object* raw_key = dictionary->KeyAt(i); if (!dictionary->IsKey(isolate, raw_key)) continue; uint32_t key = FilterKey(dictionary, i, raw_key, filter); if (key == kMaxUInt32) { keys->AddShadowingKey(raw_key); continue; } elements->set(insertion_index, raw_key); insertion_index++; } SortIndices(elements, insertion_index); for (int i = 0; i < insertion_index; i++) { keys->AddKey(elements->get(i)); } } static Handle DirectCollectElementIndicesImpl( Isolate* isolate, Handle object, Handle backing_store, GetKeysConversion convert, PropertyFilter filter, Handle list, uint32_t* nof_indices, uint32_t insertion_index = 0) { if (filter & SKIP_STRINGS) return list; if (filter & ONLY_ALL_CAN_READ) return list; Handle dictionary = Handle::cast(backing_store); uint32_t capacity = dictionary->Capacity(); for (uint32_t i = 0; i < capacity; i++) { uint32_t key = GetKeyForEntryImpl(isolate, dictionary, i, filter); if (key == kMaxUInt32) continue; Handle index = isolate->factory()->NewNumberFromUint(key); list->set(insertion_index, *index); insertion_index++; } *nof_indices = insertion_index; return list; } static void AddElementsToKeyAccumulatorImpl(Handle receiver, KeyAccumulator* accumulator, AddKeyConversion convert) { Isolate* isolate = accumulator->isolate(); Handle undefined = isolate->factory()->undefined_value(); Handle the_hole = isolate->factory()->the_hole_value(); Handle dictionary( SeededNumberDictionary::cast(receiver->elements()), isolate); int capacity = dictionary->Capacity(); for (int i = 0; i < capacity; i++) { Object* k = dictionary->KeyAt(i); if (k == *undefined) continue; if (k == *the_hole) continue; if (dictionary->IsDeleted(i)) continue; Object* value = dictionary->ValueAt(i); DCHECK(!value->IsTheHole(isolate)); DCHECK(!value->IsAccessorPair()); DCHECK(!value->IsAccessorInfo()); accumulator->AddKey(value, convert); } } static bool IncludesValueFastPath(Isolate* isolate, Handle receiver, Handle value, uint32_t start_from, uint32_t length, Maybe* result) { DisallowHeapAllocation no_gc; SeededNumberDictionary* dictionary = SeededNumberDictionary::cast(receiver->elements()); int capacity = dictionary->Capacity(); Object* the_hole = isolate->heap()->the_hole_value(); Object* undefined = isolate->heap()->undefined_value(); // Scan for accessor properties. If accessors are present, then elements // must be accessed in order via the slow path. bool found = false; for (int i = 0; i < capacity; ++i) { Object* k = dictionary->KeyAt(i); if (k == the_hole) continue; if (k == undefined) continue; uint32_t index; if (!k->ToArrayIndex(&index) || index < start_from || index >= length) { continue; } if (dictionary->DetailsAt(i).kind() == kAccessor) { // Restart from beginning in slow path, otherwise we may observably // access getters out of order return false; } else if (!found) { Object* element_k = dictionary->ValueAt(i); if (value->SameValueZero(element_k)) found = true; } } *result = Just(found); return true; } static Maybe IncludesValueImpl(Isolate* isolate, Handle receiver, Handle value, uint32_t start_from, uint32_t length) { DCHECK(JSObject::PrototypeHasNoElements(isolate, *receiver)); bool search_for_hole = value->IsUndefined(isolate); if (!search_for_hole) { Maybe result = Nothing(); if (DictionaryElementsAccessor::IncludesValueFastPath( isolate, receiver, value, start_from, length, &result)) { return result; } } Handle original_map(receiver->map(), isolate); Handle dictionary( SeededNumberDictionary::cast(receiver->elements()), isolate); // Iterate through entire range, as accessing elements out of order is // observable for (uint32_t k = start_from; k < length; ++k) { DCHECK_EQ(receiver->map(), *original_map); int entry = dictionary->FindEntry(isolate, k); if (entry == SeededNumberDictionary::kNotFound) { if (search_for_hole) return Just(true); continue; } PropertyDetails details = GetDetailsImpl(*dictionary, entry); switch (details.kind()) { case kData: { Object* element_k = dictionary->ValueAt(entry); if (value->SameValueZero(element_k)) return Just(true); break; } case kAccessor: { LookupIterator it(isolate, receiver, k, LookupIterator::OWN_SKIP_INTERCEPTOR); DCHECK(it.IsFound()); DCHECK_EQ(it.state(), LookupIterator::ACCESSOR); Handle element_k; ASSIGN_RETURN_ON_EXCEPTION_VALUE( isolate, element_k, JSObject::GetPropertyWithAccessor(&it), Nothing()); if (value->SameValueZero(*element_k)) return Just(true); // Bailout to slow path if elements on prototype changed if (!JSObject::PrototypeHasNoElements(isolate, *receiver)) { return IncludesValueSlowPath(isolate, receiver, value, k + 1, length); } // Continue if elements unchanged if (*dictionary == receiver->elements()) continue; // Otherwise, bailout or update elements if (receiver->GetElementsKind() != DICTIONARY_ELEMENTS) { if (receiver->map()->GetInitialElements() == receiver->elements()) { // If switched to initial elements, return true if searching for // undefined, and false otherwise. return Just(search_for_hole); } // Otherwise, switch to slow path. return IncludesValueSlowPath(isolate, receiver, value, k + 1, length); } dictionary = handle( SeededNumberDictionary::cast(receiver->elements()), isolate); break; } } } return Just(false); } static Maybe IndexOfValueImpl(Isolate* isolate, Handle receiver, Handle value, uint32_t start_from, uint32_t length) { DCHECK(JSObject::PrototypeHasNoElements(isolate, *receiver)); Handle original_map(receiver->map(), isolate); Handle dictionary( SeededNumberDictionary::cast(receiver->elements()), isolate); // Iterate through entire range, as accessing elements out of order is // observable. for (uint32_t k = start_from; k < length; ++k) { DCHECK_EQ(receiver->map(), *original_map); int entry = dictionary->FindEntry(isolate, k); if (entry == SeededNumberDictionary::kNotFound) { continue; } PropertyDetails details = GetDetailsImpl(*dictionary, entry); switch (details.kind()) { case kData: { Object* element_k = dictionary->ValueAt(entry); if (value->StrictEquals(element_k)) { return Just(k); } break; } case kAccessor: { LookupIterator it(isolate, receiver, k, LookupIterator::OWN_SKIP_INTERCEPTOR); DCHECK(it.IsFound()); DCHECK_EQ(it.state(), LookupIterator::ACCESSOR); Handle element_k; ASSIGN_RETURN_ON_EXCEPTION_VALUE( isolate, element_k, JSObject::GetPropertyWithAccessor(&it), Nothing()); if (value->StrictEquals(*element_k)) return Just(k); // Bailout to slow path if elements on prototype changed. if (!JSObject::PrototypeHasNoElements(isolate, *receiver)) { return IndexOfValueSlowPath(isolate, receiver, value, k + 1, length); } // Continue if elements unchanged. if (*dictionary == receiver->elements()) continue; // Otherwise, bailout or update elements. if (receiver->GetElementsKind() != DICTIONARY_ELEMENTS) { // Otherwise, switch to slow path. return IndexOfValueSlowPath(isolate, receiver, value, k + 1, length); } dictionary = handle( SeededNumberDictionary::cast(receiver->elements()), isolate); break; } } } return Just(-1); } }; // Super class for all fast element arrays. template class FastElementsAccessor : public ElementsAccessorBase { public: explicit FastElementsAccessor(const char* name) : ElementsAccessorBase(name) {} typedef typename KindTraits::BackingStore BackingStore; static Handle NormalizeImpl( Handle object, Handle store) { Isolate* isolate = store->GetIsolate(); ElementsKind kind = Subclass::kind(); // Ensure that notifications fire if the array or object prototypes are // normalizing. if (IsFastSmiOrObjectElementsKind(kind)) { isolate->UpdateArrayProtectorOnNormalizeElements(object); } int capacity = object->GetFastElementsUsage(); Handle dictionary = SeededNumberDictionary::New(isolate, capacity); PropertyDetails details = PropertyDetails::Empty(); int j = 0; for (int i = 0; j < capacity; i++) { if (IsHoleyElementsKind(kind)) { if (BackingStore::cast(*store)->is_the_hole(isolate, i)) continue; } Handle value = Subclass::GetImpl(isolate, *store, i); dictionary = SeededNumberDictionary::AddNumberEntry(dictionary, i, value, details, object); j++; } return dictionary; } static void DeleteAtEnd(Handle obj, Handle backing_store, uint32_t entry) { uint32_t length = static_cast(backing_store->length()); Isolate* isolate = obj->GetIsolate(); for (; entry > 0; entry--) { if (!backing_store->is_the_hole(isolate, entry - 1)) break; } if (entry == 0) { FixedArray* empty = isolate->heap()->empty_fixed_array(); // Dynamically ask for the elements kind here since we manually redirect // the operations for argument backing stores. if (obj->GetElementsKind() == FAST_SLOPPY_ARGUMENTS_ELEMENTS) { FixedArray::cast(obj->elements())->set(1, empty); } else { obj->set_elements(empty); } return; } isolate->heap()->RightTrimFixedArray(*backing_store, length - entry); } static void DeleteCommon(Handle obj, uint32_t entry, Handle store) { DCHECK(obj->HasFastSmiOrObjectElements() || obj->HasFastDoubleElements() || obj->HasFastArgumentsElements() || obj->HasFastStringWrapperElements()); Handle backing_store = Handle::cast(store); if (!obj->IsJSArray() && entry == static_cast(store->length()) - 1) { DeleteAtEnd(obj, backing_store, entry); return; } Isolate* isolate = obj->GetIsolate(); backing_store->set_the_hole(isolate, entry); // TODO(verwaest): Move this out of elements.cc. // If an old space backing store is larger than a certain size and // has too few used values, normalize it. // To avoid doing the check on every delete we require at least // one adjacent hole to the value being deleted. const int kMinLengthForSparsenessCheck = 64; if (backing_store->length() < kMinLengthForSparsenessCheck) return; if (backing_store->GetHeap()->InNewSpace(*backing_store)) return; uint32_t length = 0; if (obj->IsJSArray()) { JSArray::cast(*obj)->length()->ToArrayLength(&length); } else { length = static_cast(store->length()); } if ((entry > 0 && backing_store->is_the_hole(isolate, entry - 1)) || (entry + 1 < length && backing_store->is_the_hole(isolate, entry + 1))) { if (!obj->IsJSArray()) { uint32_t i; for (i = entry + 1; i < length; i++) { if (!backing_store->is_the_hole(isolate, i)) break; } if (i == length) { DeleteAtEnd(obj, backing_store, entry); return; } } int num_used = 0; for (int i = 0; i < backing_store->length(); ++i) { if (!backing_store->is_the_hole(isolate, i)) { ++num_used; // Bail out if a number dictionary wouldn't be able to save at least // 75% space. if (4 * SeededNumberDictionary::ComputeCapacity(num_used) * SeededNumberDictionary::kEntrySize > backing_store->length()) { return; } } } JSObject::NormalizeElements(obj); } } static void ReconfigureImpl(Handle object, Handle store, uint32_t entry, Handle value, PropertyAttributes attributes) { Handle dictionary = JSObject::NormalizeElements(object); entry = dictionary->FindEntry(entry); DictionaryElementsAccessor::ReconfigureImpl(object, dictionary, entry, value, attributes); } static void AddImpl(Handle object, uint32_t index, Handle value, PropertyAttributes attributes, uint32_t new_capacity) { DCHECK_EQ(NONE, attributes); ElementsKind from_kind = object->GetElementsKind(); ElementsKind to_kind = Subclass::kind(); if (IsDictionaryElementsKind(from_kind) || IsFastDoubleElementsKind(from_kind) != IsFastDoubleElementsKind(to_kind) || Subclass::GetCapacityImpl(*object, object->elements()) != new_capacity) { Subclass::GrowCapacityAndConvertImpl(object, new_capacity); } else { if (IsFastElementsKind(from_kind) && from_kind != to_kind) { JSObject::TransitionElementsKind(object, to_kind); } if (IsFastSmiOrObjectElementsKind(from_kind)) { DCHECK(IsFastSmiOrObjectElementsKind(to_kind)); JSObject::EnsureWritableFastElements(object); } } Subclass::SetImpl(object, index, *value); } static void DeleteImpl(Handle obj, uint32_t entry) { ElementsKind kind = KindTraits::Kind; if (IsFastPackedElementsKind(kind)) { JSObject::TransitionElementsKind(obj, GetHoleyElementsKind(kind)); } if (IsFastSmiOrObjectElementsKind(KindTraits::Kind)) { JSObject::EnsureWritableFastElements(obj); } DeleteCommon(obj, entry, handle(obj->elements())); } static bool HasEntryImpl(Isolate* isolate, FixedArrayBase* backing_store, uint32_t entry) { return !BackingStore::cast(backing_store)->is_the_hole(isolate, entry); } static uint32_t NumberOfElementsImpl(JSObject* receiver, FixedArrayBase* backing_store) { uint32_t max_index = Subclass::GetMaxIndex(receiver, backing_store); if (IsFastPackedElementsKind(Subclass::kind())) return max_index; Isolate* isolate = receiver->GetIsolate(); uint32_t count = 0; for (uint32_t i = 0; i < max_index; i++) { if (Subclass::HasEntryImpl(isolate, backing_store, i)) count++; } return count; } static void AddElementsToKeyAccumulatorImpl(Handle receiver, KeyAccumulator* accumulator, AddKeyConversion convert) { Isolate* isolate = accumulator->isolate(); Handle elements(receiver->elements(), isolate); uint32_t length = Subclass::GetMaxNumberOfEntries(*receiver, *elements); for (uint32_t i = 0; i < length; i++) { if (IsFastPackedElementsKind(KindTraits::Kind) || HasEntryImpl(isolate, *elements, i)) { accumulator->AddKey(Subclass::GetImpl(isolate, *elements, i), convert); } } } static void ValidateContents(Handle holder, int length) { #if DEBUG Isolate* isolate = holder->GetIsolate(); Heap* heap = isolate->heap(); HandleScope scope(isolate); Handle elements(holder->elements(), isolate); Map* map = elements->map(); if (IsFastSmiOrObjectElementsKind(KindTraits::Kind)) { DCHECK_NE(map, heap->fixed_double_array_map()); } else if (IsFastDoubleElementsKind(KindTraits::Kind)) { DCHECK_NE(map, heap->fixed_cow_array_map()); if (map == heap->fixed_array_map()) DCHECK_EQ(0, length); } else { UNREACHABLE(); } if (length == 0) return; // nothing to do! #if ENABLE_SLOW_DCHECKS DisallowHeapAllocation no_gc; Handle backing_store = Handle::cast(elements); if (IsFastSmiElementsKind(KindTraits::Kind)) { for (int i = 0; i < length; i++) { DCHECK(BackingStore::get(*backing_store, i, isolate)->IsSmi() || (IsFastHoleyElementsKind(KindTraits::Kind) && backing_store->is_the_hole(isolate, i))); } } else if (KindTraits::Kind == FAST_ELEMENTS || KindTraits::Kind == FAST_DOUBLE_ELEMENTS) { for (int i = 0; i < length; i++) { DCHECK(!backing_store->is_the_hole(isolate, i)); } } else { DCHECK(IsFastHoleyElementsKind(KindTraits::Kind)); } #endif #endif } static Handle PopImpl(Handle receiver) { return Subclass::RemoveElement(receiver, AT_END); } static Handle ShiftImpl(Handle receiver) { return Subclass::RemoveElement(receiver, AT_START); } static uint32_t PushImpl(Handle receiver, Arguments* args, uint32_t push_size) { Handle backing_store(receiver->elements()); return Subclass::AddArguments(receiver, backing_store, args, push_size, AT_END); } static uint32_t UnshiftImpl(Handle receiver, Arguments* args, uint32_t unshift_size) { Handle backing_store(receiver->elements()); return Subclass::AddArguments(receiver, backing_store, args, unshift_size, AT_START); } static Handle SliceImpl(Handle receiver, uint32_t start, uint32_t end) { Isolate* isolate = receiver->GetIsolate(); Handle backing_store(receiver->elements(), isolate); int result_len = end < start ? 0u : end - start; Handle result_array = isolate->factory()->NewJSArray( KindTraits::Kind, result_len, result_len); DisallowHeapAllocation no_gc; Subclass::CopyElementsImpl(*backing_store, start, result_array->elements(), KindTraits::Kind, 0, kPackedSizeNotKnown, result_len); Subclass::TryTransitionResultArrayToPacked(result_array); return result_array; } static Handle SpliceImpl(Handle receiver, uint32_t start, uint32_t delete_count, Arguments* args, uint32_t add_count) { Isolate* isolate = receiver->GetIsolate(); Heap* heap = isolate->heap(); uint32_t length = Smi::cast(receiver->length())->value(); uint32_t new_length = length - delete_count + add_count; ElementsKind kind = KindTraits::Kind; if (new_length <= static_cast(receiver->elements()->length()) && IsFastSmiOrObjectElementsKind(kind)) { HandleScope scope(isolate); JSObject::EnsureWritableFastElements(receiver); } Handle backing_store(receiver->elements(), isolate); if (new_length == 0) { receiver->set_elements(heap->empty_fixed_array()); receiver->set_length(Smi::kZero); return isolate->factory()->NewJSArrayWithElements( backing_store, KindTraits::Kind, delete_count); } // Construct the result array which holds the deleted elements. Handle deleted_elements = isolate->factory()->NewJSArray( KindTraits::Kind, delete_count, delete_count); if (delete_count > 0) { DisallowHeapAllocation no_gc; Subclass::CopyElementsImpl(*backing_store, start, deleted_elements->elements(), KindTraits::Kind, 0, kPackedSizeNotKnown, delete_count); } // Delete and move elements to make space for add_count new elements. if (add_count < delete_count) { Subclass::SpliceShrinkStep(isolate, receiver, backing_store, start, delete_count, add_count, length, new_length); } else if (add_count > delete_count) { backing_store = Subclass::SpliceGrowStep(isolate, receiver, backing_store, start, delete_count, add_count, length, new_length); } // Copy over the arguments. Subclass::CopyArguments(args, backing_store, add_count, 3, start); receiver->set_length(Smi::FromInt(new_length)); Subclass::TryTransitionResultArrayToPacked(deleted_elements); return deleted_elements; } static Maybe CollectValuesOrEntriesImpl( Isolate* isolate, Handle object, Handle values_or_entries, bool get_entries, int* nof_items, PropertyFilter filter) { Handle elements(BackingStore::cast(object->elements()), isolate); int count = 0; uint32_t length = elements->length(); for (uint32_t index = 0; index < length; ++index) { if (!HasEntryImpl(isolate, *elements, index)) continue; Handle value = Subclass::GetImpl(isolate, *elements, index); if (get_entries) { value = MakeEntryPair(isolate, index, value); } values_or_entries->set(count++, *value); } *nof_items = count; return Just(true); } static void MoveElements(Isolate* isolate, Handle receiver, Handle backing_store, int dst_index, int src_index, int len, int hole_start, int hole_end) { Heap* heap = isolate->heap(); Handle dst_elms = Handle::cast(backing_store); if (heap->CanMoveObjectStart(*dst_elms) && dst_index == 0) { // Update all the copies of this backing_store handle. *dst_elms.location() = BackingStore::cast(heap->LeftTrimFixedArray(*dst_elms, src_index)); receiver->set_elements(*dst_elms); // Adjust the hole offset as the array has been shrunk. hole_end -= src_index; DCHECK_LE(hole_start, backing_store->length()); DCHECK_LE(hole_end, backing_store->length()); } else if (len != 0) { if (IsFastDoubleElementsKind(KindTraits::Kind)) { MemMove(dst_elms->data_start() + dst_index, dst_elms->data_start() + src_index, len * kDoubleSize); } else { DisallowHeapAllocation no_gc; heap->MoveElements(FixedArray::cast(*dst_elms), dst_index, src_index, len); } } if (hole_start != hole_end) { dst_elms->FillWithHoles(hole_start, hole_end); } } static Maybe IncludesValueImpl(Isolate* isolate, Handle receiver, Handle search_value, uint32_t start_from, uint32_t length) { DCHECK(JSObject::PrototypeHasNoElements(isolate, *receiver)); DisallowHeapAllocation no_gc; FixedArrayBase* elements_base = receiver->elements(); Object* the_hole = isolate->heap()->the_hole_value(); Object* undefined = isolate->heap()->undefined_value(); Object* value = *search_value; // Elements beyond the capacity of the backing store treated as undefined. if (value == undefined && static_cast(elements_base->length()) < length) { return Just(true); } if (start_from >= length) return Just(false); length = std::min(static_cast(elements_base->length()), length); if (!value->IsNumber()) { if (value == undefined) { // Only FAST_ELEMENTS, FAST_HOLEY_ELEMENTS, FAST_HOLEY_SMI_ELEMENTS, and // FAST_HOLEY_DOUBLE_ELEMENTS can have `undefined` as a value. if (!IsFastObjectElementsKind(Subclass::kind()) && !IsFastHoleyElementsKind(Subclass::kind())) { return Just(false); } // Search for `undefined` or The Hole in FAST_ELEMENTS, // FAST_HOLEY_ELEMENTS or FAST_HOLEY_SMI_ELEMENTS if (IsFastSmiOrObjectElementsKind(Subclass::kind())) { auto elements = FixedArray::cast(receiver->elements()); for (uint32_t k = start_from; k < length; ++k) { Object* element_k = elements->get(k); if (IsFastHoleyElementsKind(Subclass::kind()) && element_k == the_hole) { return Just(true); } if (IsFastObjectElementsKind(Subclass::kind()) && element_k == undefined) { return Just(true); } } return Just(false); } else { // Seach for The Hole in FAST_HOLEY_DOUBLE_ELEMENTS DCHECK_EQ(Subclass::kind(), FAST_HOLEY_DOUBLE_ELEMENTS); auto elements = FixedDoubleArray::cast(receiver->elements()); for (uint32_t k = start_from; k < length; ++k) { if (IsFastHoleyElementsKind(Subclass::kind()) && elements->is_the_hole(k)) { return Just(true); } } return Just(false); } } else if (!IsFastObjectElementsKind(Subclass::kind())) { // Search for non-number, non-Undefined value, with either // FAST_SMI_ELEMENTS, FAST_DOUBLE_ELEMENTS, FAST_HOLEY_SMI_ELEMENTS or // FAST_HOLEY_DOUBLE_ELEMENTS. Guaranteed to return false, since these // elements kinds can only contain Number values or undefined. return Just(false); } else { // Search for non-number, non-Undefined value with either // FAST_ELEMENTS or FAST_HOLEY_ELEMENTS. DCHECK(IsFastObjectElementsKind(Subclass::kind())); auto elements = FixedArray::cast(receiver->elements()); for (uint32_t k = start_from; k < length; ++k) { Object* element_k = elements->get(k); if (IsFastHoleyElementsKind(Subclass::kind()) && element_k == the_hole) { continue; } if (value->SameValueZero(element_k)) return Just(true); } return Just(false); } } else { if (!value->IsNaN()) { double search_value = value->Number(); if (IsFastDoubleElementsKind(Subclass::kind())) { // Search for non-NaN Number in FAST_DOUBLE_ELEMENTS or // FAST_HOLEY_DOUBLE_ELEMENTS --- Skip TheHole, and trust UCOMISD or // similar operation for result. auto elements = FixedDoubleArray::cast(receiver->elements()); for (uint32_t k = start_from; k < length; ++k) { if (IsFastHoleyElementsKind(Subclass::kind()) && elements->is_the_hole(k)) { continue; } if (elements->get_scalar(k) == search_value) return Just(true); } return Just(false); } else { // Search for non-NaN Number in FAST_ELEMENTS, FAST_HOLEY_ELEMENTS, // FAST_SMI_ELEMENTS or FAST_HOLEY_SMI_ELEMENTS --- Skip non-Numbers, // and trust UCOMISD or similar operation for result auto elements = FixedArray::cast(receiver->elements()); for (uint32_t k = start_from; k < length; ++k) { Object* element_k = elements->get(k); if (element_k->IsNumber() && element_k->Number() == search_value) { return Just(true); } } return Just(false); } } else { // Search for NaN --- NaN cannot be represented with Smi elements, so // abort if ElementsKind is FAST_SMI_ELEMENTS or FAST_HOLEY_SMI_ELEMENTS if (IsFastSmiElementsKind(Subclass::kind())) return Just(false); if (IsFastDoubleElementsKind(Subclass::kind())) { // Search for NaN in FAST_DOUBLE_ELEMENTS or // FAST_HOLEY_DOUBLE_ELEMENTS --- Skip The Hole and trust // std::isnan(elementK) for result auto elements = FixedDoubleArray::cast(receiver->elements()); for (uint32_t k = start_from; k < length; ++k) { if (IsFastHoleyElementsKind(Subclass::kind()) && elements->is_the_hole(k)) { continue; } if (std::isnan(elements->get_scalar(k))) return Just(true); } return Just(false); } else { // Search for NaN in FAST_ELEMENTS, FAST_HOLEY_ELEMENTS, // FAST_SMI_ELEMENTS or FAST_HOLEY_SMI_ELEMENTS. Return true if // elementK->IsHeapNumber() && std::isnan(elementK->Number()) DCHECK(IsFastSmiOrObjectElementsKind(Subclass::kind())); auto elements = FixedArray::cast(receiver->elements()); for (uint32_t k = start_from; k < length; ++k) { if (elements->get(k)->IsNaN()) return Just(true); } return Just(false); } } } } static Handle CreateListFromArrayImpl(Isolate* isolate, Handle array) { uint32_t length = 0; array->length()->ToArrayLength(&length); Handle result = isolate->factory()->NewFixedArray(length); Handle elements(array->elements(), isolate); for (uint32_t i = 0; i < length; i++) { if (!Subclass::HasElementImpl(isolate, array, i, elements)) continue; Handle value; value = Subclass::GetImpl(isolate, *elements, i); if (value->IsName()) { value = isolate->factory()->InternalizeName(Handle::cast(value)); } result->set(i, *value); } return result; } private: // SpliceShrinkStep might modify the backing_store. static void SpliceShrinkStep(Isolate* isolate, Handle receiver, Handle backing_store, uint32_t start, uint32_t delete_count, uint32_t add_count, uint32_t len, uint32_t new_length) { const int move_left_count = len - delete_count - start; const int move_left_dst_index = start + add_count; Subclass::MoveElements(isolate, receiver, backing_store, move_left_dst_index, start + delete_count, move_left_count, new_length, len); } // SpliceGrowStep might modify the backing_store. static Handle SpliceGrowStep( Isolate* isolate, Handle receiver, Handle backing_store, uint32_t start, uint32_t delete_count, uint32_t add_count, uint32_t length, uint32_t new_length) { // Check we do not overflow the new_length. DCHECK((add_count - delete_count) <= (Smi::kMaxValue - length)); // Check if backing_store is big enough. if (new_length <= static_cast(backing_store->length())) { Subclass::MoveElements(isolate, receiver, backing_store, start + add_count, start + delete_count, (length - delete_count - start), 0, 0); // MoveElements updates the backing_store in-place. return backing_store; } // New backing storage is needed. int capacity = JSObject::NewElementsCapacity(new_length); // Partially copy all elements up to start. Handle new_elms = Subclass::ConvertElementsWithCapacity( receiver, backing_store, KindTraits::Kind, capacity, start); // Copy the trailing elements after start + delete_count Subclass::CopyElementsImpl(*backing_store, start + delete_count, *new_elms, KindTraits::Kind, start + add_count, kPackedSizeNotKnown, ElementsAccessor::kCopyToEndAndInitializeToHole); receiver->set_elements(*new_elms); return new_elms; } static Handle RemoveElement(Handle receiver, Where remove_position) { Isolate* isolate = receiver->GetIsolate(); ElementsKind kind = KindTraits::Kind; if (IsFastSmiOrObjectElementsKind(kind)) { HandleScope scope(isolate); JSObject::EnsureWritableFastElements(receiver); } Handle backing_store(receiver->elements(), isolate); uint32_t length = static_cast(Smi::cast(receiver->length())->value()); DCHECK(length > 0); int new_length = length - 1; int remove_index = remove_position == AT_START ? 0 : new_length; Handle result = Subclass::GetImpl(isolate, *backing_store, remove_index); if (remove_position == AT_START) { Subclass::MoveElements(isolate, receiver, backing_store, 0, 1, new_length, 0, 0); } Subclass::SetLengthImpl(isolate, receiver, new_length, backing_store); if (IsHoleyElementsKind(kind) && result->IsTheHole(isolate)) { return isolate->factory()->undefined_value(); } return result; } static uint32_t AddArguments(Handle receiver, Handle backing_store, Arguments* args, uint32_t add_size, Where add_position) { uint32_t length = Smi::cast(receiver->length())->value(); DCHECK(0 < add_size); uint32_t elms_len = backing_store->length(); // Check we do not overflow the new_length. DCHECK(add_size <= static_cast(Smi::kMaxValue - length)); uint32_t new_length = length + add_size; if (new_length > elms_len) { // New backing storage is needed. uint32_t capacity = JSObject::NewElementsCapacity(new_length); // If we add arguments to the start we have to shift the existing objects. int copy_dst_index = add_position == AT_START ? add_size : 0; // Copy over all objects to a new backing_store. backing_store = Subclass::ConvertElementsWithCapacity( receiver, backing_store, KindTraits::Kind, capacity, 0, copy_dst_index, ElementsAccessor::kCopyToEndAndInitializeToHole); receiver->set_elements(*backing_store); } else if (add_position == AT_START) { // If the backing store has enough capacity and we add elements to the // start we have to shift the existing objects. Isolate* isolate = receiver->GetIsolate(); Subclass::MoveElements(isolate, receiver, backing_store, add_size, 0, length, 0, 0); } int insertion_index = add_position == AT_START ? 0 : length; // Copy the arguments to the start. Subclass::CopyArguments(args, backing_store, add_size, 1, insertion_index); // Set the length. receiver->set_length(Smi::FromInt(new_length)); return new_length; } static void CopyArguments(Arguments* args, Handle dst_store, uint32_t copy_size, uint32_t src_index, uint32_t dst_index) { // Add the provided values. DisallowHeapAllocation no_gc; FixedArrayBase* raw_backing_store = *dst_store; WriteBarrierMode mode = raw_backing_store->GetWriteBarrierMode(no_gc); for (uint32_t i = 0; i < copy_size; i++) { Object* argument = (*args)[src_index + i]; DCHECK(!argument->IsTheHole(raw_backing_store->GetIsolate())); Subclass::SetImpl(raw_backing_store, dst_index + i, argument, mode); } } }; template class FastSmiOrObjectElementsAccessor : public FastElementsAccessor { public: explicit FastSmiOrObjectElementsAccessor(const char* name) : FastElementsAccessor(name) {} static inline void SetImpl(Handle holder, uint32_t entry, Object* value) { SetImpl(holder->elements(), entry, value); } static inline void SetImpl(FixedArrayBase* backing_store, uint32_t entry, Object* value) { FixedArray::cast(backing_store)->set(entry, value); } static inline void SetImpl(FixedArrayBase* backing_store, uint32_t entry, Object* value, WriteBarrierMode mode) { FixedArray::cast(backing_store)->set(entry, value, mode); } static Object* GetRaw(FixedArray* backing_store, uint32_t entry) { uint32_t index = Subclass::GetIndexForEntryImpl(backing_store, entry); return backing_store->get(index); } // NOTE: this method violates the handlified function signature convention: // raw pointer parameters in the function that allocates. // See ElementsAccessor::CopyElements() for details. // This method could actually allocate if copying from double elements to // object elements. static void CopyElementsImpl(FixedArrayBase* from, uint32_t from_start, FixedArrayBase* to, ElementsKind from_kind, uint32_t to_start, int packed_size, int copy_size) { DisallowHeapAllocation no_gc; ElementsKind to_kind = KindTraits::Kind; switch (from_kind) { case FAST_SMI_ELEMENTS: case FAST_HOLEY_SMI_ELEMENTS: case FAST_ELEMENTS: case FAST_HOLEY_ELEMENTS: CopyObjectToObjectElements(from, from_kind, from_start, to, to_kind, to_start, copy_size); break; case FAST_DOUBLE_ELEMENTS: case FAST_HOLEY_DOUBLE_ELEMENTS: { AllowHeapAllocation allow_allocation; DCHECK(IsFastObjectElementsKind(to_kind)); CopyDoubleToObjectElements(from, from_start, to, to_start, copy_size); break; } case DICTIONARY_ELEMENTS: CopyDictionaryToObjectElements(from, from_start, to, to_kind, to_start, copy_size); break; case FAST_SLOPPY_ARGUMENTS_ELEMENTS: case SLOW_SLOPPY_ARGUMENTS_ELEMENTS: case FAST_STRING_WRAPPER_ELEMENTS: case SLOW_STRING_WRAPPER_ELEMENTS: #define TYPED_ARRAY_CASE(Type, type, TYPE, ctype, size) case TYPE##_ELEMENTS: TYPED_ARRAYS(TYPED_ARRAY_CASE) #undef TYPED_ARRAY_CASE // This function is currently only used for JSArrays with non-zero // length. UNREACHABLE(); break; case NO_ELEMENTS: break; // Nothing to do. } } static Maybe IndexOfValueImpl(Isolate* isolate, Handle receiver, Handle search_value, uint32_t start_from, uint32_t length) { DCHECK(JSObject::PrototypeHasNoElements(isolate, *receiver)); DisallowHeapAllocation no_gc; FixedArrayBase* elements_base = receiver->elements(); Object* value = *search_value; if (start_from >= length) return Just(-1); length = std::min(static_cast(elements_base->length()), length); // Only FAST_{,HOLEY_}ELEMENTS can store non-numbers. if (!value->IsNumber() && !IsFastObjectElementsKind(Subclass::kind())) { return Just(-1); } // NaN can never be found by strict equality. if (value->IsNaN()) return Just(-1); FixedArray* elements = FixedArray::cast(receiver->elements()); for (uint32_t k = start_from; k < length; ++k) { if (value->StrictEquals(elements->get(k))) return Just(k); } return Just(-1); } }; class FastPackedSmiElementsAccessor : public FastSmiOrObjectElementsAccessor< FastPackedSmiElementsAccessor, ElementsKindTraits > { public: explicit FastPackedSmiElementsAccessor(const char* name) : FastSmiOrObjectElementsAccessor< FastPackedSmiElementsAccessor, ElementsKindTraits >(name) {} }; class FastHoleySmiElementsAccessor : public FastSmiOrObjectElementsAccessor< FastHoleySmiElementsAccessor, ElementsKindTraits > { public: explicit FastHoleySmiElementsAccessor(const char* name) : FastSmiOrObjectElementsAccessor< FastHoleySmiElementsAccessor, ElementsKindTraits >(name) {} }; class FastPackedObjectElementsAccessor : public FastSmiOrObjectElementsAccessor< FastPackedObjectElementsAccessor, ElementsKindTraits > { public: explicit FastPackedObjectElementsAccessor(const char* name) : FastSmiOrObjectElementsAccessor< FastPackedObjectElementsAccessor, ElementsKindTraits >(name) {} }; class FastHoleyObjectElementsAccessor : public FastSmiOrObjectElementsAccessor< FastHoleyObjectElementsAccessor, ElementsKindTraits > { public: explicit FastHoleyObjectElementsAccessor(const char* name) : FastSmiOrObjectElementsAccessor< FastHoleyObjectElementsAccessor, ElementsKindTraits >(name) {} }; template class FastDoubleElementsAccessor : public FastElementsAccessor { public: explicit FastDoubleElementsAccessor(const char* name) : FastElementsAccessor(name) {} static Handle GetImpl(Isolate* isolate, FixedArrayBase* backing_store, uint32_t entry) { return FixedDoubleArray::get(FixedDoubleArray::cast(backing_store), entry, isolate); } static inline void SetImpl(Handle holder, uint32_t entry, Object* value) { SetImpl(holder->elements(), entry, value); } static inline void SetImpl(FixedArrayBase* backing_store, uint32_t entry, Object* value) { FixedDoubleArray::cast(backing_store)->set(entry, value->Number()); } static inline void SetImpl(FixedArrayBase* backing_store, uint32_t entry, Object* value, WriteBarrierMode mode) { FixedDoubleArray::cast(backing_store)->set(entry, value->Number()); } static void CopyElementsImpl(FixedArrayBase* from, uint32_t from_start, FixedArrayBase* to, ElementsKind from_kind, uint32_t to_start, int packed_size, int copy_size) { DisallowHeapAllocation no_allocation; switch (from_kind) { case FAST_SMI_ELEMENTS: CopyPackedSmiToDoubleElements(from, from_start, to, to_start, packed_size, copy_size); break; case FAST_HOLEY_SMI_ELEMENTS: CopySmiToDoubleElements(from, from_start, to, to_start, copy_size); break; case FAST_DOUBLE_ELEMENTS: case FAST_HOLEY_DOUBLE_ELEMENTS: CopyDoubleToDoubleElements(from, from_start, to, to_start, copy_size); break; case FAST_ELEMENTS: case FAST_HOLEY_ELEMENTS: CopyObjectToDoubleElements(from, from_start, to, to_start, copy_size); break; case DICTIONARY_ELEMENTS: CopyDictionaryToDoubleElements(from, from_start, to, to_start, copy_size); break; case FAST_SLOPPY_ARGUMENTS_ELEMENTS: case SLOW_SLOPPY_ARGUMENTS_ELEMENTS: case FAST_STRING_WRAPPER_ELEMENTS: case SLOW_STRING_WRAPPER_ELEMENTS: case NO_ELEMENTS: #define TYPED_ARRAY_CASE(Type, type, TYPE, ctype, size) case TYPE##_ELEMENTS: TYPED_ARRAYS(TYPED_ARRAY_CASE) #undef TYPED_ARRAY_CASE // This function is currently only used for JSArrays with non-zero // length. UNREACHABLE(); break; } } static Maybe IndexOfValueImpl(Isolate* isolate, Handle receiver, Handle search_value, uint32_t start_from, uint32_t length) { DCHECK(JSObject::PrototypeHasNoElements(isolate, *receiver)); DisallowHeapAllocation no_gc; FixedArrayBase* elements_base = receiver->elements(); Object* value = *search_value; length = std::min(static_cast(elements_base->length()), length); if (start_from >= length) return Just(-1); if (!value->IsNumber()) { return Just(-1); } if (value->IsNaN()) { return Just(-1); } double numeric_search_value = value->Number(); FixedDoubleArray* elements = FixedDoubleArray::cast(receiver->elements()); for (uint32_t k = start_from; k < length; ++k) { if (elements->is_the_hole(k)) { continue; } if (elements->get_scalar(k) == numeric_search_value) { return Just(k); } } return Just(-1); } }; class FastPackedDoubleElementsAccessor : public FastDoubleElementsAccessor< FastPackedDoubleElementsAccessor, ElementsKindTraits > { public: explicit FastPackedDoubleElementsAccessor(const char* name) : FastDoubleElementsAccessor< FastPackedDoubleElementsAccessor, ElementsKindTraits >(name) {} }; class FastHoleyDoubleElementsAccessor : public FastDoubleElementsAccessor< FastHoleyDoubleElementsAccessor, ElementsKindTraits > { public: explicit FastHoleyDoubleElementsAccessor(const char* name) : FastDoubleElementsAccessor< FastHoleyDoubleElementsAccessor, ElementsKindTraits >(name) {} }; // Super class for all external element arrays. template class TypedElementsAccessor : public ElementsAccessorBase, ElementsKindTraits> { public: explicit TypedElementsAccessor(const char* name) : ElementsAccessorBase >(name) {} typedef typename ElementsKindTraits::BackingStore BackingStore; typedef TypedElementsAccessor AccessorClass; static inline void SetImpl(Handle holder, uint32_t entry, Object* value) { SetImpl(holder->elements(), entry, value); } static inline void SetImpl(FixedArrayBase* backing_store, uint32_t entry, Object* value) { BackingStore::cast(backing_store)->SetValue(entry, value); } static inline void SetImpl(FixedArrayBase* backing_store, uint32_t entry, Object* value, WriteBarrierMode mode) { BackingStore::cast(backing_store)->SetValue(entry, value); } static Handle GetImpl(Isolate* isolate, FixedArrayBase* backing_store, uint32_t entry) { return BackingStore::get(BackingStore::cast(backing_store), entry); } static PropertyDetails GetDetailsImpl(JSObject* holder, uint32_t entry) { return PropertyDetails(kData, DONT_DELETE, 0, PropertyCellType::kNoCell); } static PropertyDetails GetDetailsImpl(FixedArrayBase* backing_store, uint32_t entry) { return PropertyDetails(kData, DONT_DELETE, 0, PropertyCellType::kNoCell); } static bool HasElementImpl(Isolate* isolate, Handle holder, uint32_t index, Handle backing_store, PropertyFilter filter) { return index < AccessorClass::GetCapacityImpl(*holder, *backing_store); } static bool HasAccessorsImpl(JSObject* holder, FixedArrayBase* backing_store) { return false; } static void SetLengthImpl(Isolate* isolate, Handle array, uint32_t length, Handle backing_store) { // External arrays do not support changing their length. UNREACHABLE(); } static void DeleteImpl(Handle obj, uint32_t entry) { UNREACHABLE(); } static uint32_t GetIndexForEntryImpl(FixedArrayBase* backing_store, uint32_t entry) { return entry; } static uint32_t GetEntryForIndexImpl(Isolate* isolate, JSObject* holder, FixedArrayBase* backing_store, uint32_t index, PropertyFilter filter) { return index < AccessorClass::GetCapacityImpl(holder, backing_store) ? index : kMaxUInt32; } static bool WasNeutered(JSObject* holder) { JSArrayBufferView* view = JSArrayBufferView::cast(holder); return view->WasNeutered(); } static uint32_t GetCapacityImpl(JSObject* holder, FixedArrayBase* backing_store) { if (WasNeutered(holder)) return 0; return backing_store->length(); } static uint32_t NumberOfElementsImpl(JSObject* receiver, FixedArrayBase* backing_store) { return AccessorClass::GetCapacityImpl(receiver, backing_store); } static void AddElementsToKeyAccumulatorImpl(Handle receiver, KeyAccumulator* accumulator, AddKeyConversion convert) { Isolate* isolate = receiver->GetIsolate(); Handle elements(receiver->elements()); uint32_t length = AccessorClass::GetCapacityImpl(*receiver, *elements); for (uint32_t i = 0; i < length; i++) { Handle value = AccessorClass::GetImpl(isolate, *elements, i); accumulator->AddKey(value, convert); } } static Maybe CollectValuesOrEntriesImpl( Isolate* isolate, Handle object, Handle values_or_entries, bool get_entries, int* nof_items, PropertyFilter filter) { int count = 0; if ((filter & ONLY_CONFIGURABLE) == 0) { Handle elements(object->elements()); uint32_t length = AccessorClass::GetCapacityImpl(*object, *elements); for (uint32_t index = 0; index < length; ++index) { Handle value = AccessorClass::GetImpl(isolate, *elements, index); if (get_entries) { value = MakeEntryPair(isolate, index, value); } values_or_entries->set(count++, *value); } } *nof_items = count; return Just(true); } static Maybe IncludesValueImpl(Isolate* isolate, Handle receiver, Handle value, uint32_t start_from, uint32_t length) { DCHECK(JSObject::PrototypeHasNoElements(isolate, *receiver)); DisallowHeapAllocation no_gc; // TODO(caitp): return Just(false) here when implementing strict throwing on // neutered views. if (WasNeutered(*receiver)) { return Just(value->IsUndefined(isolate) && length > start_from); } BackingStore* elements = BackingStore::cast(receiver->elements()); if (value->IsUndefined(isolate) && length > static_cast(elements->length())) { return Just(true); } if (!value->IsNumber()) return Just(false); double search_value = value->Number(); if (!std::isfinite(search_value)) { // Integral types cannot represent +Inf or NaN if (AccessorClass::kind() < FLOAT32_ELEMENTS || AccessorClass::kind() > FLOAT64_ELEMENTS) { return Just(false); } } else if (search_value < std::numeric_limits::lowest() || search_value > std::numeric_limits::max()) { // Return false if value can't be represented in this space return Just(false); } // Prototype has no elements, and not searching for the hole --- limit // search to backing store length. if (static_cast(elements->length()) < length) { length = elements->length(); } if (!std::isnan(search_value)) { for (uint32_t k = start_from; k < length; ++k) { double element_k = elements->get_scalar(k); if (element_k == search_value) return Just(true); } return Just(false); } else { for (uint32_t k = start_from; k < length; ++k) { double element_k = elements->get_scalar(k); if (std::isnan(element_k)) return Just(true); } return Just(false); } } static Maybe IndexOfValueImpl(Isolate* isolate, Handle receiver, Handle value, uint32_t start_from, uint32_t length) { DCHECK(JSObject::PrototypeHasNoElements(isolate, *receiver)); DisallowHeapAllocation no_gc; if (WasNeutered(*receiver)) return Just(-1); BackingStore* elements = BackingStore::cast(receiver->elements()); if (!value->IsNumber()) return Just(-1); double search_value = value->Number(); if (!std::isfinite(search_value)) { // Integral types cannot represent +Inf or NaN. if (AccessorClass::kind() < FLOAT32_ELEMENTS || AccessorClass::kind() > FLOAT64_ELEMENTS) { return Just(-1); } } else if (search_value < std::numeric_limits::lowest() || search_value > std::numeric_limits::max()) { // Return false if value can't be represented in this ElementsKind. return Just(-1); } // Prototype has no elements, and not searching for the hole --- limit // search to backing store length. if (static_cast(elements->length()) < length) { length = elements->length(); } if (std::isnan(search_value)) { return Just(-1); } ctype typed_search_value = static_cast(search_value); if (static_cast(typed_search_value) != search_value) { return Just(-1); // Loss of precision. } for (uint32_t k = start_from; k < length; ++k) { ctype element_k = elements->get_scalar(k); if (element_k == typed_search_value) return Just(k); } return Just(-1); } }; #define FIXED_ELEMENTS_ACCESSOR(Type, type, TYPE, ctype, size) \ typedef TypedElementsAccessor \ Fixed##Type##ElementsAccessor; TYPED_ARRAYS(FIXED_ELEMENTS_ACCESSOR) #undef FIXED_ELEMENTS_ACCESSOR template class SloppyArgumentsElementsAccessor : public ElementsAccessorBase { public: explicit SloppyArgumentsElementsAccessor(const char* name) : ElementsAccessorBase(name) { USE(KindTraits::Kind); } static Handle GetImpl(Isolate* isolate, FixedArrayBase* parameters, uint32_t entry) { Handle parameter_map(FixedArray::cast(parameters), isolate); uint32_t length = parameter_map->length() - 2; if (entry < length) { DisallowHeapAllocation no_gc; Object* probe = parameter_map->get(entry + 2); Context* context = Context::cast(parameter_map->get(0)); int context_entry = Smi::cast(probe)->value(); DCHECK(!context->get(context_entry)->IsTheHole(isolate)); return handle(context->get(context_entry), isolate); } else { // Object is not mapped, defer to the arguments. Handle result = ArgumentsAccessor::GetImpl( isolate, FixedArray::cast(parameter_map->get(1)), entry - length); // Elements of the arguments object in slow mode might be slow aliases. if (result->IsAliasedArgumentsEntry()) { DisallowHeapAllocation no_gc; AliasedArgumentsEntry* alias = AliasedArgumentsEntry::cast(*result); Context* context = Context::cast(parameter_map->get(0)); int context_entry = alias->aliased_context_slot(); DCHECK(!context->get(context_entry)->IsTheHole(isolate)); return handle(context->get(context_entry), isolate); } return result; } } static void TransitionElementsKindImpl(Handle object, Handle map) { UNREACHABLE(); } static void GrowCapacityAndConvertImpl(Handle object, uint32_t capacity) { UNREACHABLE(); } static inline void SetImpl(Handle holder, uint32_t entry, Object* value) { SetImpl(holder->elements(), entry, value); } static inline void SetImpl(FixedArrayBase* store, uint32_t entry, Object* value) { FixedArray* parameter_map = FixedArray::cast(store); uint32_t length = parameter_map->length() - 2; if (entry < length) { Object* probe = parameter_map->get(entry + 2); Context* context = Context::cast(parameter_map->get(0)); int context_entry = Smi::cast(probe)->value(); DCHECK(!context->get(context_entry)->IsTheHole(store->GetIsolate())); context->set(context_entry, value); } else { FixedArray* arguments = FixedArray::cast(parameter_map->get(1)); Object* current = ArgumentsAccessor::GetRaw(arguments, entry - length); if (current->IsAliasedArgumentsEntry()) { AliasedArgumentsEntry* alias = AliasedArgumentsEntry::cast(current); Context* context = Context::cast(parameter_map->get(0)); int context_entry = alias->aliased_context_slot(); DCHECK(!context->get(context_entry)->IsTheHole(store->GetIsolate())); context->set(context_entry, value); } else { ArgumentsAccessor::SetImpl(arguments, entry - length, value); } } } static void SetLengthImpl(Isolate* isolate, Handle array, uint32_t length, Handle parameter_map) { // Sloppy arguments objects are not arrays. UNREACHABLE(); } static uint32_t GetCapacityImpl(JSObject* holder, FixedArrayBase* backing_store) { FixedArray* parameter_map = FixedArray::cast(backing_store); FixedArrayBase* arguments = FixedArrayBase::cast(parameter_map->get(1)); return parameter_map->length() - 2 + ArgumentsAccessor::GetCapacityImpl(holder, arguments); } static uint32_t GetMaxNumberOfEntries(JSObject* holder, FixedArrayBase* backing_store) { FixedArray* parameter_map = FixedArray::cast(backing_store); FixedArrayBase* arguments = FixedArrayBase::cast(parameter_map->get(1)); return parameter_map->length() - 2 + ArgumentsAccessor::GetMaxNumberOfEntries(holder, arguments); } static uint32_t NumberOfElementsImpl(JSObject* receiver, FixedArrayBase* backing_store) { FixedArray* parameter_map = FixedArray::cast(backing_store); FixedArrayBase* arguments = FixedArrayBase::cast(parameter_map->get(1)); uint32_t nof_elements = 0; uint32_t length = parameter_map->length() - 2; for (uint32_t entry = 0; entry < length; entry++) { if (HasParameterMapArg(parameter_map, entry)) nof_elements++; } return nof_elements + ArgumentsAccessor::NumberOfElementsImpl(receiver, arguments); } static void AddElementsToKeyAccumulatorImpl(Handle receiver, KeyAccumulator* accumulator, AddKeyConversion convert) { Isolate* isolate = accumulator->isolate(); Handle elements(receiver->elements(), isolate); uint32_t length = GetCapacityImpl(*receiver, *elements); for (uint32_t entry = 0; entry < length; entry++) { if (!HasEntryImpl(isolate, *elements, entry)) continue; Handle value = GetImpl(isolate, *elements, entry); accumulator->AddKey(value, convert); } } static bool HasEntryImpl(Isolate* isolate, FixedArrayBase* parameters, uint32_t entry) { FixedArray* parameter_map = FixedArray::cast(parameters); uint32_t length = parameter_map->length() - 2; if (entry < length) { return HasParameterMapArg(parameter_map, entry); } FixedArrayBase* arguments = FixedArrayBase::cast(parameter_map->get(1)); return ArgumentsAccessor::HasEntryImpl(isolate, arguments, entry - length); } static bool HasAccessorsImpl(JSObject* holder, FixedArrayBase* backing_store) { FixedArray* parameter_map = FixedArray::cast(backing_store); FixedArrayBase* arguments = FixedArrayBase::cast(parameter_map->get(1)); return ArgumentsAccessor::HasAccessorsImpl(holder, arguments); } static uint32_t GetIndexForEntryImpl(FixedArrayBase* parameters, uint32_t entry) { FixedArray* parameter_map = FixedArray::cast(parameters); uint32_t length = parameter_map->length() - 2; if (entry < length) return entry; FixedArray* arguments = FixedArray::cast(parameter_map->get(1)); return ArgumentsAccessor::GetIndexForEntryImpl(arguments, entry - length); } static uint32_t GetEntryForIndexImpl(Isolate* isolate, JSObject* holder, FixedArrayBase* parameters, uint32_t index, PropertyFilter filter) { FixedArray* parameter_map = FixedArray::cast(parameters); if (HasParameterMapArg(parameter_map, index)) return index; FixedArray* arguments = FixedArray::cast(parameter_map->get(1)); uint32_t entry = ArgumentsAccessor::GetEntryForIndexImpl( isolate, holder, arguments, index, filter); if (entry == kMaxUInt32) return kMaxUInt32; return (parameter_map->length() - 2) + entry; } static PropertyDetails GetDetailsImpl(JSObject* holder, uint32_t entry) { FixedArray* parameter_map = FixedArray::cast(holder->elements()); uint32_t length = parameter_map->length() - 2; if (entry < length) { return PropertyDetails(kData, NONE, 0, PropertyCellType::kNoCell); } FixedArray* arguments = FixedArray::cast(parameter_map->get(1)); return ArgumentsAccessor::GetDetailsImpl(arguments, entry - length); } static bool HasParameterMapArg(FixedArray* parameter_map, uint32_t index) { uint32_t length = parameter_map->length() - 2; if (index >= length) return false; return !parameter_map->get(index + 2)->IsTheHole( parameter_map->GetIsolate()); } static void DeleteImpl(Handle obj, uint32_t entry) { FixedArray* parameter_map = FixedArray::cast(obj->elements()); uint32_t length = static_cast(parameter_map->length()) - 2; if (entry < length) { // TODO(kmillikin): We could check if this was the last aliased // parameter, and revert to normal elements in that case. That // would enable GC of the context. parameter_map->set_the_hole(entry + 2); } else { Subclass::DeleteFromArguments(obj, entry - length); } } static void CollectElementIndicesImpl(Handle object, Handle backing_store, KeyAccumulator* keys) { Isolate* isolate = keys->isolate(); uint32_t nof_indices = 0; Handle indices = isolate->factory()->NewFixedArray( GetCapacityImpl(*object, *backing_store)); DirectCollectElementIndicesImpl(isolate, object, backing_store, GetKeysConversion::kKeepNumbers, ENUMERABLE_STRINGS, indices, &nof_indices); SortIndices(indices, nof_indices); for (uint32_t i = 0; i < nof_indices; i++) { keys->AddKey(indices->get(i)); } } static Handle DirectCollectElementIndicesImpl( Isolate* isolate, Handle object, Handle backing_store, GetKeysConversion convert, PropertyFilter filter, Handle list, uint32_t* nof_indices, uint32_t insertion_index = 0) { Handle parameter_map(FixedArray::cast(*backing_store), isolate); uint32_t length = parameter_map->length() - 2; for (uint32_t i = 0; i < length; ++i) { if (parameter_map->get(i + 2)->IsTheHole(isolate)) continue; if (convert == GetKeysConversion::kConvertToString) { Handle index_string = isolate->factory()->Uint32ToString(i); list->set(insertion_index, *index_string); } else { list->set(insertion_index, Smi::FromInt(i), SKIP_WRITE_BARRIER); } insertion_index++; } Handle store(FixedArrayBase::cast(parameter_map->get(1))); return ArgumentsAccessor::DirectCollectElementIndicesImpl( isolate, object, store, convert, filter, list, nof_indices, insertion_index); } static Maybe IncludesValueImpl(Isolate* isolate, Handle object, Handle value, uint32_t start_from, uint32_t length) { DCHECK(JSObject::PrototypeHasNoElements(isolate, *object)); Handle original_map(object->map(), isolate); Handle parameter_map(FixedArray::cast(object->elements()), isolate); bool search_for_hole = value->IsUndefined(isolate); for (uint32_t k = start_from; k < length; ++k) { DCHECK_EQ(object->map(), *original_map); uint32_t entry = GetEntryForIndexImpl(isolate, *object, *parameter_map, k, ALL_PROPERTIES); if (entry == kMaxUInt32) { if (search_for_hole) return Just(true); continue; } Handle element_k = Subclass::GetImpl(isolate, *parameter_map, entry); if (element_k->IsAccessorPair()) { LookupIterator it(isolate, object, k, LookupIterator::OWN); DCHECK(it.IsFound()); DCHECK_EQ(it.state(), LookupIterator::ACCESSOR); ASSIGN_RETURN_ON_EXCEPTION_VALUE(isolate, element_k, Object::GetPropertyWithAccessor(&it), Nothing()); if (value->SameValueZero(*element_k)) return Just(true); if (object->map() != *original_map) { // Some mutation occurred in accessor. Abort "fast" path return IncludesValueSlowPath(isolate, object, value, k + 1, length); } } else if (value->SameValueZero(*element_k)) { return Just(true); } } return Just(false); } static Maybe IndexOfValueImpl(Isolate* isolate, Handle object, Handle value, uint32_t start_from, uint32_t length) { DCHECK(JSObject::PrototypeHasNoElements(isolate, *object)); Handle original_map(object->map(), isolate); Handle parameter_map(FixedArray::cast(object->elements()), isolate); for (uint32_t k = start_from; k < length; ++k) { DCHECK_EQ(object->map(), *original_map); uint32_t entry = GetEntryForIndexImpl(isolate, *object, *parameter_map, k, ALL_PROPERTIES); if (entry == kMaxUInt32) { continue; } Handle element_k = Subclass::GetImpl(isolate, *parameter_map, entry); if (element_k->IsAccessorPair()) { LookupIterator it(isolate, object, k, LookupIterator::OWN); DCHECK(it.IsFound()); DCHECK_EQ(it.state(), LookupIterator::ACCESSOR); ASSIGN_RETURN_ON_EXCEPTION_VALUE(isolate, element_k, Object::GetPropertyWithAccessor(&it), Nothing()); if (value->StrictEquals(*element_k)) { return Just(k); } if (object->map() != *original_map) { // Some mutation occurred in accessor. Abort "fast" path. return IndexOfValueSlowPath(isolate, object, value, k + 1, length); } } else if (value->StrictEquals(*element_k)) { return Just(k); } } return Just(-1); } }; class SlowSloppyArgumentsElementsAccessor : public SloppyArgumentsElementsAccessor< SlowSloppyArgumentsElementsAccessor, DictionaryElementsAccessor, ElementsKindTraits > { public: explicit SlowSloppyArgumentsElementsAccessor(const char* name) : SloppyArgumentsElementsAccessor< SlowSloppyArgumentsElementsAccessor, DictionaryElementsAccessor, ElementsKindTraits >(name) {} static void DeleteFromArguments(Handle obj, uint32_t entry) { Handle parameter_map(FixedArray::cast(obj->elements())); Handle dict( SeededNumberDictionary::cast(parameter_map->get(1))); // TODO(verwaest): Remove reliance on index in Shrink. uint32_t index = GetIndexForEntryImpl(*dict, entry); Handle result = SeededNumberDictionary::DeleteProperty(dict, entry); USE(result); DCHECK(result->IsTrue(dict->GetIsolate())); Handle new_elements = SeededNumberDictionary::Shrink(dict, index); parameter_map->set(1, *new_elements); } static void AddImpl(Handle object, uint32_t index, Handle value, PropertyAttributes attributes, uint32_t new_capacity) { Handle parameter_map(FixedArray::cast(object->elements())); Handle old_elements( FixedArrayBase::cast(parameter_map->get(1))); Handle dictionary = old_elements->IsSeededNumberDictionary() ? Handle::cast(old_elements) : JSObject::NormalizeElements(object); PropertyDetails details(kData, attributes, 0, PropertyCellType::kNoCell); Handle new_dictionary = SeededNumberDictionary::AddNumberEntry(dictionary, index, value, details, object); if (attributes != NONE) object->RequireSlowElements(*new_dictionary); if (*dictionary != *new_dictionary) { FixedArray::cast(object->elements())->set(1, *new_dictionary); } } static void ReconfigureImpl(Handle object, Handle store, uint32_t entry, Handle value, PropertyAttributes attributes) { Handle parameter_map = Handle::cast(store); uint32_t length = parameter_map->length() - 2; Isolate* isolate = store->GetIsolate(); if (entry < length) { Object* probe = parameter_map->get(entry + 2); DCHECK(!probe->IsTheHole(isolate)); Context* context = Context::cast(parameter_map->get(0)); int context_entry = Smi::cast(probe)->value(); DCHECK(!context->get(context_entry)->IsTheHole(isolate)); context->set(context_entry, *value); // Redefining attributes of an aliased element destroys fast aliasing. parameter_map->set_the_hole(isolate, entry + 2); // For elements that are still writable we re-establish slow aliasing. if ((attributes & READ_ONLY) == 0) { value = isolate->factory()->NewAliasedArgumentsEntry(context_entry); } PropertyDetails details(kData, attributes, 0, PropertyCellType::kNoCell); Handle arguments( SeededNumberDictionary::cast(parameter_map->get(1)), isolate); arguments = SeededNumberDictionary::AddNumberEntry( arguments, entry, value, details, object); // If the attributes were NONE, we would have called set rather than // reconfigure. DCHECK_NE(NONE, attributes); object->RequireSlowElements(*arguments); parameter_map->set(1, *arguments); } else { Handle arguments( FixedArrayBase::cast(parameter_map->get(1)), isolate); DictionaryElementsAccessor::ReconfigureImpl( object, arguments, entry - length, value, attributes); } } }; class FastSloppyArgumentsElementsAccessor : public SloppyArgumentsElementsAccessor< FastSloppyArgumentsElementsAccessor, FastHoleyObjectElementsAccessor, ElementsKindTraits > { public: explicit FastSloppyArgumentsElementsAccessor(const char* name) : SloppyArgumentsElementsAccessor< FastSloppyArgumentsElementsAccessor, FastHoleyObjectElementsAccessor, ElementsKindTraits >(name) {} static Handle GetArguments(Isolate* isolate, FixedArrayBase* backing_store) { FixedArray* parameter_map = FixedArray::cast(backing_store); return Handle(FixedArray::cast(parameter_map->get(1)), isolate); } static Handle SliceImpl(Handle receiver, uint32_t start, uint32_t end) { Isolate* isolate = receiver->GetIsolate(); uint32_t result_len = end < start ? 0u : end - start; Handle result_array = isolate->factory()->NewJSArray( FAST_HOLEY_ELEMENTS, result_len, result_len); DisallowHeapAllocation no_gc; FixedArray* elements = FixedArray::cast(result_array->elements()); FixedArray* parameters = FixedArray::cast(receiver->elements()); uint32_t insertion_index = 0; for (uint32_t i = start; i < end; i++) { uint32_t entry = GetEntryForIndexImpl(isolate, *receiver, parameters, i, ALL_PROPERTIES); if (entry != kMaxUInt32 && HasEntryImpl(isolate, parameters, entry)) { elements->set(insertion_index, *GetImpl(isolate, parameters, entry)); } else { elements->set_the_hole(isolate, insertion_index); } insertion_index++; } return result_array; } static Handle NormalizeImpl( Handle object, Handle elements) { Handle arguments = GetArguments(elements->GetIsolate(), *elements); return FastHoleyObjectElementsAccessor::NormalizeImpl(object, arguments); } static void DeleteFromArguments(Handle obj, uint32_t entry) { Handle arguments = GetArguments(obj->GetIsolate(), obj->elements()); FastHoleyObjectElementsAccessor::DeleteCommon(obj, entry, arguments); } static void AddImpl(Handle object, uint32_t index, Handle value, PropertyAttributes attributes, uint32_t new_capacity) { DCHECK_EQ(NONE, attributes); Handle parameter_map(FixedArray::cast(object->elements())); Handle old_elements( FixedArrayBase::cast(parameter_map->get(1))); if (old_elements->IsSeededNumberDictionary() || static_cast(old_elements->length()) < new_capacity) { GrowCapacityAndConvertImpl(object, new_capacity); } FixedArray* arguments = FixedArray::cast(parameter_map->get(1)); // For fast holey objects, the entry equals the index. The code above made // sure that there's enough space to store the value. We cannot convert // index to entry explicitly since the slot still contains the hole, so the // current EntryForIndex would indicate that it is "absent" by returning // kMaxUInt32. FastHoleyObjectElementsAccessor::SetImpl(arguments, index, *value); } static void ReconfigureImpl(Handle object, Handle store, uint32_t entry, Handle value, PropertyAttributes attributes) { Handle dictionary = JSObject::NormalizeElements(object); FixedArray::cast(*store)->set(1, *dictionary); uint32_t length = static_cast(store->length()) - 2; if (entry >= length) { entry = dictionary->FindEntry(entry - length) + length; } SlowSloppyArgumentsElementsAccessor::ReconfigureImpl(object, store, entry, value, attributes); } static void CopyElementsImpl(FixedArrayBase* from, uint32_t from_start, FixedArrayBase* to, ElementsKind from_kind, uint32_t to_start, int packed_size, int copy_size) { DCHECK(!to->IsDictionary()); if (from_kind == SLOW_SLOPPY_ARGUMENTS_ELEMENTS) { CopyDictionaryToObjectElements(from, from_start, to, FAST_HOLEY_ELEMENTS, to_start, copy_size); } else { DCHECK_EQ(FAST_SLOPPY_ARGUMENTS_ELEMENTS, from_kind); CopyObjectToObjectElements(from, FAST_HOLEY_ELEMENTS, from_start, to, FAST_HOLEY_ELEMENTS, to_start, copy_size); } } static void GrowCapacityAndConvertImpl(Handle object, uint32_t capacity) { Handle parameter_map(FixedArray::cast(object->elements())); Handle old_elements(FixedArray::cast(parameter_map->get(1))); ElementsKind from_kind = object->GetElementsKind(); // This method should only be called if there's a reason to update the // elements. DCHECK(from_kind == SLOW_SLOPPY_ARGUMENTS_ELEMENTS || static_cast(old_elements->length()) < capacity); Handle elements = ConvertElementsWithCapacity(object, old_elements, from_kind, capacity); Handle new_map = JSObject::GetElementsTransitionMap( object, FAST_SLOPPY_ARGUMENTS_ELEMENTS); JSObject::MigrateToMap(object, new_map); parameter_map->set(1, *elements); JSObject::ValidateElements(object); } }; template class StringWrapperElementsAccessor : public ElementsAccessorBase { public: explicit StringWrapperElementsAccessor(const char* name) : ElementsAccessorBase(name) { USE(KindTraits::Kind); } static Handle GetInternalImpl(Handle holder, uint32_t entry) { return GetImpl(holder, entry); } static Handle GetImpl(Handle holder, uint32_t entry) { Isolate* isolate = holder->GetIsolate(); Handle string(GetString(*holder), isolate); uint32_t length = static_cast(string->length()); if (entry < length) { return isolate->factory()->LookupSingleCharacterStringFromCode( String::Flatten(string)->Get(entry)); } return BackingStoreAccessor::GetImpl(isolate, holder->elements(), entry - length); } static Handle GetImpl(Isolate* isolate, FixedArrayBase* elements, uint32_t entry) { UNREACHABLE(); return Handle(); } static PropertyDetails GetDetailsImpl(JSObject* holder, uint32_t entry) { uint32_t length = static_cast(GetString(holder)->length()); if (entry < length) { PropertyAttributes attributes = static_cast(READ_ONLY | DONT_DELETE); return PropertyDetails(kData, attributes, 0, PropertyCellType::kNoCell); } return BackingStoreAccessor::GetDetailsImpl(holder, entry - length); } static uint32_t GetEntryForIndexImpl(Isolate* isolate, JSObject* holder, FixedArrayBase* backing_store, uint32_t index, PropertyFilter filter) { uint32_t length = static_cast(GetString(holder)->length()); if (index < length) return index; uint32_t backing_store_entry = BackingStoreAccessor::GetEntryForIndexImpl( isolate, holder, backing_store, index, filter); if (backing_store_entry == kMaxUInt32) return kMaxUInt32; DCHECK(backing_store_entry < kMaxUInt32 - length); return backing_store_entry + length; } static void DeleteImpl(Handle holder, uint32_t entry) { uint32_t length = static_cast(GetString(*holder)->length()); if (entry < length) { return; // String contents can't be deleted. } BackingStoreAccessor::DeleteImpl(holder, entry - length); } static void SetImpl(Handle holder, uint32_t entry, Object* value) { uint32_t length = static_cast(GetString(*holder)->length()); if (entry < length) { return; // String contents are read-only. } BackingStoreAccessor::SetImpl(holder->elements(), entry - length, value); } static void AddImpl(Handle object, uint32_t index, Handle value, PropertyAttributes attributes, uint32_t new_capacity) { DCHECK(index >= static_cast(GetString(*object)->length())); // Explicitly grow fast backing stores if needed. Dictionaries know how to // extend their capacity themselves. if (KindTraits::Kind == FAST_STRING_WRAPPER_ELEMENTS && (object->GetElementsKind() == SLOW_STRING_WRAPPER_ELEMENTS || BackingStoreAccessor::GetCapacityImpl(*object, object->elements()) != new_capacity)) { GrowCapacityAndConvertImpl(object, new_capacity); } BackingStoreAccessor::AddImpl(object, index, value, attributes, new_capacity); } static void ReconfigureImpl(Handle object, Handle store, uint32_t entry, Handle value, PropertyAttributes attributes) { uint32_t length = static_cast(GetString(*object)->length()); if (entry < length) { return; // String contents can't be reconfigured. } BackingStoreAccessor::ReconfigureImpl(object, store, entry - length, value, attributes); } static void AddElementsToKeyAccumulatorImpl(Handle receiver, KeyAccumulator* accumulator, AddKeyConversion convert) { Isolate* isolate = receiver->GetIsolate(); Handle string(GetString(*receiver), isolate); string = String::Flatten(string); uint32_t length = static_cast(string->length()); for (uint32_t i = 0; i < length; i++) { accumulator->AddKey( isolate->factory()->LookupSingleCharacterStringFromCode( string->Get(i)), convert); } BackingStoreAccessor::AddElementsToKeyAccumulatorImpl(receiver, accumulator, convert); } static void CollectElementIndicesImpl(Handle object, Handle backing_store, KeyAccumulator* keys) { uint32_t length = GetString(*object)->length(); Factory* factory = keys->isolate()->factory(); for (uint32_t i = 0; i < length; i++) { keys->AddKey(factory->NewNumberFromUint(i)); } BackingStoreAccessor::CollectElementIndicesImpl(object, backing_store, keys); } static void GrowCapacityAndConvertImpl(Handle object, uint32_t capacity) { Handle old_elements(object->elements()); ElementsKind from_kind = object->GetElementsKind(); // This method should only be called if there's a reason to update the // elements. DCHECK(from_kind == SLOW_STRING_WRAPPER_ELEMENTS || static_cast(old_elements->length()) < capacity); Subclass::BasicGrowCapacityAndConvertImpl(object, old_elements, from_kind, FAST_STRING_WRAPPER_ELEMENTS, capacity); } static void CopyElementsImpl(FixedArrayBase* from, uint32_t from_start, FixedArrayBase* to, ElementsKind from_kind, uint32_t to_start, int packed_size, int copy_size) { DCHECK(!to->IsDictionary()); if (from_kind == SLOW_STRING_WRAPPER_ELEMENTS) { CopyDictionaryToObjectElements(from, from_start, to, FAST_HOLEY_ELEMENTS, to_start, copy_size); } else { DCHECK_EQ(FAST_STRING_WRAPPER_ELEMENTS, from_kind); CopyObjectToObjectElements(from, FAST_HOLEY_ELEMENTS, from_start, to, FAST_HOLEY_ELEMENTS, to_start, copy_size); } } static uint32_t NumberOfElementsImpl(JSObject* object, FixedArrayBase* backing_store) { uint32_t length = GetString(object)->length(); return length + BackingStoreAccessor::NumberOfElementsImpl(object, backing_store); } private: static String* GetString(JSObject* holder) { DCHECK(holder->IsJSValue()); JSValue* js_value = JSValue::cast(holder); DCHECK(js_value->value()->IsString()); return String::cast(js_value->value()); } }; class FastStringWrapperElementsAccessor : public StringWrapperElementsAccessor< FastStringWrapperElementsAccessor, FastHoleyObjectElementsAccessor, ElementsKindTraits> { public: explicit FastStringWrapperElementsAccessor(const char* name) : StringWrapperElementsAccessor< FastStringWrapperElementsAccessor, FastHoleyObjectElementsAccessor, ElementsKindTraits>(name) {} static Handle NormalizeImpl( Handle object, Handle elements) { return FastHoleyObjectElementsAccessor::NormalizeImpl(object, elements); } }; class SlowStringWrapperElementsAccessor : public StringWrapperElementsAccessor< SlowStringWrapperElementsAccessor, DictionaryElementsAccessor, ElementsKindTraits> { public: explicit SlowStringWrapperElementsAccessor(const char* name) : StringWrapperElementsAccessor< SlowStringWrapperElementsAccessor, DictionaryElementsAccessor, ElementsKindTraits>(name) {} static bool HasAccessorsImpl(JSObject* holder, FixedArrayBase* backing_store) { return DictionaryElementsAccessor::HasAccessorsImpl(holder, backing_store); } }; } // namespace void CheckArrayAbuse(Handle obj, const char* op, uint32_t index, bool allow_appending) { DisallowHeapAllocation no_allocation; Object* raw_length = NULL; const char* elements_type = "array"; if (obj->IsJSArray()) { JSArray* array = JSArray::cast(*obj); raw_length = array->length(); } else { raw_length = Smi::FromInt(obj->elements()->length()); elements_type = "object"; } if (raw_length->IsNumber()) { double n = raw_length->Number(); if (FastI2D(FastD2UI(n)) == n) { int32_t int32_length = DoubleToInt32(n); uint32_t compare_length = static_cast(int32_length); if (allow_appending) compare_length++; if (index >= compare_length) { PrintF("[OOB %s %s (%s length = %d, element accessed = %d) in ", elements_type, op, elements_type, static_cast(int32_length), static_cast(index)); TraceTopFrame(obj->GetIsolate()); PrintF("]\n"); } } else { PrintF("[%s elements length not integer value in ", elements_type); TraceTopFrame(obj->GetIsolate()); PrintF("]\n"); } } else { PrintF("[%s elements length not a number in ", elements_type); TraceTopFrame(obj->GetIsolate()); PrintF("]\n"); } } MaybeHandle ArrayConstructInitializeElements(Handle array, Arguments* args) { if (args->length() == 0) { // Optimize the case where there are no parameters passed. JSArray::Initialize(array, JSArray::kPreallocatedArrayElements); return array; } else if (args->length() == 1 && args->at(0)->IsNumber()) { uint32_t length; if (!args->at(0)->ToArrayLength(&length)) { return ThrowArrayLengthRangeError(array->GetIsolate()); } // Optimize the case where there is one argument and the argument is a small // smi. if (length > 0 && length < JSArray::kInitialMaxFastElementArray) { ElementsKind elements_kind = array->GetElementsKind(); JSArray::Initialize(array, length, length); if (!IsFastHoleyElementsKind(elements_kind)) { elements_kind = GetHoleyElementsKind(elements_kind); JSObject::TransitionElementsKind(array, elements_kind); } } else if (length == 0) { JSArray::Initialize(array, JSArray::kPreallocatedArrayElements); } else { // Take the argument as the length. JSArray::Initialize(array, 0); JSArray::SetLength(array, length); } return array; } Factory* factory = array->GetIsolate()->factory(); // Set length and elements on the array. int number_of_elements = args->length(); JSObject::EnsureCanContainElements( array, args, 0, number_of_elements, ALLOW_CONVERTED_DOUBLE_ELEMENTS); // Allocate an appropriately typed elements array. ElementsKind elements_kind = array->GetElementsKind(); Handle elms; if (IsFastDoubleElementsKind(elements_kind)) { elms = Handle::cast( factory->NewFixedDoubleArray(number_of_elements)); } else { elms = Handle::cast( factory->NewFixedArrayWithHoles(number_of_elements)); } // Fill in the content switch (elements_kind) { case FAST_HOLEY_SMI_ELEMENTS: case FAST_SMI_ELEMENTS: { Handle smi_elms = Handle::cast(elms); for (int entry = 0; entry < number_of_elements; entry++) { smi_elms->set(entry, (*args)[entry], SKIP_WRITE_BARRIER); } break; } case FAST_HOLEY_ELEMENTS: case FAST_ELEMENTS: { DisallowHeapAllocation no_gc; WriteBarrierMode mode = elms->GetWriteBarrierMode(no_gc); Handle object_elms = Handle::cast(elms); for (int entry = 0; entry < number_of_elements; entry++) { object_elms->set(entry, (*args)[entry], mode); } break; } case FAST_HOLEY_DOUBLE_ELEMENTS: case FAST_DOUBLE_ELEMENTS: { Handle double_elms = Handle::cast(elms); for (int entry = 0; entry < number_of_elements; entry++) { double_elms->set(entry, (*args)[entry]->Number()); } break; } default: UNREACHABLE(); break; } array->set_elements(*elms); array->set_length(Smi::FromInt(number_of_elements)); return array; } void ElementsAccessor::InitializeOncePerProcess() { static ElementsAccessor* accessor_array[] = { #define ACCESSOR_ARRAY(Class, Kind, Store) new Class(#Kind), ELEMENTS_LIST(ACCESSOR_ARRAY) #undef ACCESSOR_ARRAY }; STATIC_ASSERT((sizeof(accessor_array) / sizeof(*accessor_array)) == kElementsKindCount); elements_accessors_ = accessor_array; } void ElementsAccessor::TearDown() { if (elements_accessors_ == NULL) return; #define ACCESSOR_DELETE(Class, Kind, Store) delete elements_accessors_[Kind]; ELEMENTS_LIST(ACCESSOR_DELETE) #undef ACCESSOR_DELETE elements_accessors_ = NULL; } Handle ElementsAccessor::Concat(Isolate* isolate, Arguments* args, uint32_t concat_size, uint32_t result_len) { ElementsKind result_elements_kind = GetInitialFastElementsKind(); bool has_raw_doubles = false; { DisallowHeapAllocation no_gc; bool is_holey = false; for (uint32_t i = 0; i < concat_size; i++) { Object* arg = (*args)[i]; ElementsKind arg_kind = JSArray::cast(arg)->GetElementsKind(); has_raw_doubles = has_raw_doubles || IsFastDoubleElementsKind(arg_kind); is_holey = is_holey || IsFastHoleyElementsKind(arg_kind); result_elements_kind = GetMoreGeneralElementsKind(result_elements_kind, arg_kind); } if (is_holey) { result_elements_kind = GetHoleyElementsKind(result_elements_kind); } } // If a double array is concatted into a fast elements array, the fast // elements array needs to be initialized to contain proper holes, since // boxing doubles may cause incremental marking. bool requires_double_boxing = has_raw_doubles && !IsFastDoubleElementsKind(result_elements_kind); ArrayStorageAllocationMode mode = requires_double_boxing ? INITIALIZE_ARRAY_ELEMENTS_WITH_HOLE : DONT_INITIALIZE_ARRAY_ELEMENTS; Handle result_array = isolate->factory()->NewJSArray( result_elements_kind, result_len, result_len, mode); if (result_len == 0) return result_array; uint32_t insertion_index = 0; Handle storage(result_array->elements(), isolate); ElementsAccessor* accessor = ElementsAccessor::ForKind(result_elements_kind); for (uint32_t i = 0; i < concat_size; i++) { // It is crucial to keep |array| in a raw pointer form to avoid // performance degradation. JSArray* array = JSArray::cast((*args)[i]); uint32_t len = 0; array->length()->ToArrayLength(&len); if (len == 0) continue; ElementsKind from_kind = array->GetElementsKind(); accessor->CopyElements(array, 0, from_kind, storage, insertion_index, len); insertion_index += len; } DCHECK_EQ(insertion_index, result_len); return result_array; } ElementsAccessor** ElementsAccessor::elements_accessors_ = NULL; } // namespace internal } // namespace v8