// 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/builtins.h" #include "src/api.h" #include "src/api-natives.h" #include "src/arguments.h" #include "src/base/once.h" #include "src/bootstrapper.h" #include "src/dateparser-inl.h" #include "src/elements.h" #include "src/frames-inl.h" #include "src/gdb-jit.h" #include "src/ic/handler-compiler.h" #include "src/ic/ic.h" #include "src/isolate-inl.h" #include "src/messages.h" #include "src/profiler/cpu-profiler.h" #include "src/property-descriptor.h" #include "src/prototype.h" #include "src/string-builder.h" #include "src/vm-state-inl.h" namespace v8 { namespace internal { namespace { // Arguments object passed to C++ builtins. template class BuiltinArguments : public Arguments { public: BuiltinArguments(int length, Object** arguments) : Arguments(length, arguments) { // Check we have at least the receiver. DCHECK_LE(1, this->length()); } Object*& operator[] (int index) { DCHECK(index < length()); return Arguments::operator[](index); } template Handle at(int index) { DCHECK(index < length()); return Arguments::at(index); } Handle atOrUndefined(Isolate* isolate, int index) { if (index >= length()) { return isolate->factory()->undefined_value(); } return at(index); } Handle receiver() { return Arguments::at(0); } Handle target(); Handle new_target(); // Gets the total number of arguments including the receiver (but // excluding extra arguments). int length() const; }; // Specialize BuiltinArguments for the extra arguments. template <> int BuiltinArguments::length() const { return Arguments::length(); } template <> int BuiltinArguments::length() const { return Arguments::length() - 1; } template <> Handle BuiltinArguments::target() { return Arguments::at(Arguments::length() - 1); } template <> int BuiltinArguments::length() const { return Arguments::length() - 1; } template <> Handle BuiltinArguments::new_target() { return Arguments::at(Arguments::length() - 1); } template <> int BuiltinArguments::length() const { return Arguments::length() - 2; } template <> Handle BuiltinArguments::target() { return Arguments::at(Arguments::length() - 2); } template <> Handle BuiltinArguments::new_target() { return Arguments::at(Arguments::length() - 1); } #define DEF_ARG_TYPE(name, spec) \ typedef BuiltinArguments name##ArgumentsType; BUILTIN_LIST_C(DEF_ARG_TYPE) #undef DEF_ARG_TYPE // ---------------------------------------------------------------------------- // Support macro for defining builtins in C++. // ---------------------------------------------------------------------------- // // A builtin function is defined by writing: // // BUILTIN(name) { // ... // } // // In the body of the builtin function the arguments can be accessed // through the BuiltinArguments object args. #define BUILTIN(name) \ MUST_USE_RESULT static Object* Builtin_Impl_##name( \ name##ArgumentsType args, Isolate* isolate); \ MUST_USE_RESULT static Object* Builtin_##name( \ int args_length, Object** args_object, Isolate* isolate) { \ name##ArgumentsType args(args_length, args_object); \ return Builtin_Impl_##name(args, isolate); \ } \ MUST_USE_RESULT static Object* Builtin_Impl_##name( \ name##ArgumentsType args, Isolate* isolate) // ---------------------------------------------------------------------------- #define CHECK_RECEIVER(Type, name, method) \ if (!args.receiver()->Is##Type()) { \ THROW_NEW_ERROR_RETURN_FAILURE( \ isolate, \ NewTypeError(MessageTemplate::kIncompatibleMethodReceiver, \ isolate->factory()->NewStringFromAsciiChecked(method), \ args.receiver())); \ } \ Handle name = Handle::cast(args.receiver()) inline bool ClampedToInteger(Object* object, int* out) { // This is an extended version of ECMA-262 7.1.11 handling signed values // Try to convert object to a number and clamp values to [kMinInt, kMaxInt] if (object->IsSmi()) { *out = Smi::cast(object)->value(); return true; } else if (object->IsHeapNumber()) { double value = HeapNumber::cast(object)->value(); if (std::isnan(value)) { *out = 0; } else if (value > kMaxInt) { *out = kMaxInt; } else if (value < kMinInt) { *out = kMinInt; } else { *out = static_cast(value); } return true; } else if (object->IsUndefined() || object->IsNull()) { *out = 0; return true; } else if (object->IsBoolean()) { *out = object->IsTrue(); return true; } return false; } inline bool GetSloppyArgumentsLength(Isolate* isolate, Handle object, int* out) { Map* arguments_map = isolate->native_context()->sloppy_arguments_map(); if (object->map() != arguments_map) return false; DCHECK(object->HasFastElements()); Object* len_obj = object->InObjectPropertyAt(Heap::kArgumentsLengthIndex); if (!len_obj->IsSmi()) return false; *out = Max(0, Smi::cast(len_obj)->value()); return *out <= object->elements()->length(); } inline bool PrototypeHasNoElements(PrototypeIterator* iter) { DisallowHeapAllocation no_gc; for (; !iter->IsAtEnd(); iter->Advance()) { if (iter->GetCurrent()->IsJSProxy()) return false; JSObject* current = iter->GetCurrent(); if (current->IsAccessCheckNeeded()) return false; if (current->HasIndexedInterceptor()) return false; if (current->elements()->length() != 0) return false; } return true; } inline bool IsJSArrayFastElementMovingAllowed(Isolate* isolate, JSArray* receiver) { DisallowHeapAllocation no_gc; // If the array prototype chain is intact (and free of elements), and if the // receiver's prototype is the array prototype, then we are done. Object* prototype = receiver->map()->prototype(); if (prototype->IsJSArray() && isolate->is_initial_array_prototype(JSArray::cast(prototype)) && isolate->IsFastArrayConstructorPrototypeChainIntact()) { return true; } // Slow case. PrototypeIterator iter(isolate, receiver); return PrototypeHasNoElements(&iter); } // Returns empty handle if not applicable. MUST_USE_RESULT inline MaybeHandle EnsureJSArrayWithWritableFastElements( Isolate* isolate, Handle receiver, Arguments* args, int first_added_arg) { if (!receiver->IsJSArray()) return MaybeHandle(); Handle array = Handle::cast(receiver); // If there may be elements accessors in the prototype chain, the fast path // cannot be used if there arguments to add to the array. Heap* heap = isolate->heap(); if (args != NULL && !IsJSArrayFastElementMovingAllowed(isolate, *array)) { return MaybeHandle(); } if (array->map()->is_observed()) return MaybeHandle(); if (!array->map()->is_extensible()) return MaybeHandle(); Handle elms(array->elements(), isolate); Map* map = elms->map(); if (map == heap->fixed_array_map()) { if (args == NULL || array->HasFastObjectElements()) return elms; } else if (map == heap->fixed_cow_array_map()) { elms = JSObject::EnsureWritableFastElements(array); if (args == NULL || array->HasFastObjectElements()) return elms; } else if (map == heap->fixed_double_array_map()) { if (args == NULL) return elms; } else { return MaybeHandle(); } // Adding elements to the array prototype would break code that makes sure // it has no elements. Handle that elsewhere. if (isolate->IsAnyInitialArrayPrototype(array)) { return MaybeHandle(); } // Need to ensure that the arguments passed in args can be contained in // the array. int args_length = args->length(); if (first_added_arg >= args_length) return handle(array->elements(), isolate); ElementsKind origin_kind = array->map()->elements_kind(); DCHECK(!IsFastObjectElementsKind(origin_kind)); ElementsKind target_kind = origin_kind; { DisallowHeapAllocation no_gc; int arg_count = args_length - first_added_arg; Object** arguments = args->arguments() - first_added_arg - (arg_count - 1); for (int i = 0; i < arg_count; i++) { Object* arg = arguments[i]; if (arg->IsHeapObject()) { if (arg->IsHeapNumber()) { target_kind = FAST_DOUBLE_ELEMENTS; } else { target_kind = FAST_ELEMENTS; break; } } } } if (target_kind != origin_kind) { JSObject::TransitionElementsKind(array, target_kind); return handle(array->elements(), isolate); } return elms; } MUST_USE_RESULT static Object* CallJsIntrinsic( Isolate* isolate, Handle function, BuiltinArguments args) { HandleScope handleScope(isolate); int argc = args.length() - 1; ScopedVector > argv(argc); for (int i = 0; i < argc; ++i) { argv[i] = args.at(i + 1); } Handle result; ASSIGN_RETURN_FAILURE_ON_EXCEPTION( isolate, result, Execution::Call(isolate, function, args.receiver(), argc, argv.start())); return *result; } } // namespace BUILTIN(Illegal) { UNREACHABLE(); return isolate->heap()->undefined_value(); // Make compiler happy. } BUILTIN(EmptyFunction) { return isolate->heap()->undefined_value(); } BUILTIN(ArrayPush) { HandleScope scope(isolate); Handle receiver = args.receiver(); MaybeHandle maybe_elms_obj = EnsureJSArrayWithWritableFastElements(isolate, receiver, &args, 1); Handle elms_obj; if (!maybe_elms_obj.ToHandle(&elms_obj)) { return CallJsIntrinsic(isolate, isolate->array_push(), args); } // Fast Elements Path int push_size = args.length() - 1; Handle array = Handle::cast(receiver); int len = Smi::cast(array->length())->value(); if (push_size == 0) { return Smi::FromInt(len); } if (push_size > 0 && JSArray::WouldChangeReadOnlyLength(array, len + push_size)) { return CallJsIntrinsic(isolate, isolate->array_push(), args); } DCHECK(!array->map()->is_observed()); ElementsAccessor* accessor = array->GetElementsAccessor(); int new_length = accessor->Push(array, elms_obj, &args, push_size); return Smi::FromInt(new_length); } BUILTIN(ArrayPop) { HandleScope scope(isolate); Handle receiver = args.receiver(); MaybeHandle maybe_elms_obj = EnsureJSArrayWithWritableFastElements(isolate, receiver, NULL, 0); Handle elms_obj; if (!maybe_elms_obj.ToHandle(&elms_obj)) { return CallJsIntrinsic(isolate, isolate->array_pop(), args); } Handle array = Handle::cast(receiver); DCHECK(!array->map()->is_observed()); uint32_t len = static_cast(Smi::cast(array->length())->value()); if (len == 0) return isolate->heap()->undefined_value(); if (JSArray::HasReadOnlyLength(array)) { return CallJsIntrinsic(isolate, isolate->array_pop(), args); } Handle result; if (IsJSArrayFastElementMovingAllowed(isolate, JSArray::cast(*receiver))) { // Fast Elements Path result = array->GetElementsAccessor()->Pop(array, elms_obj); } else { // Use Slow Lookup otherwise uint32_t new_length = len - 1; ASSIGN_RETURN_FAILURE_ON_EXCEPTION( isolate, result, Object::GetElement(isolate, array, new_length)); JSArray::SetLength(array, new_length); } return *result; } BUILTIN(ArrayShift) { HandleScope scope(isolate); Heap* heap = isolate->heap(); Handle receiver = args.receiver(); MaybeHandle maybe_elms_obj = EnsureJSArrayWithWritableFastElements(isolate, receiver, NULL, 0); Handle elms_obj; if (!maybe_elms_obj.ToHandle(&elms_obj) || !IsJSArrayFastElementMovingAllowed(isolate, JSArray::cast(*receiver))) { return CallJsIntrinsic(isolate, isolate->array_shift(), args); } Handle array = Handle::cast(receiver); DCHECK(!array->map()->is_observed()); int len = Smi::cast(array->length())->value(); if (len == 0) return heap->undefined_value(); if (JSArray::HasReadOnlyLength(array)) { return CallJsIntrinsic(isolate, isolate->array_shift(), args); } Handle first = array->GetElementsAccessor()->Shift(array, elms_obj); return *first; } BUILTIN(ArrayUnshift) { HandleScope scope(isolate); Handle receiver = args.receiver(); MaybeHandle maybe_elms_obj = EnsureJSArrayWithWritableFastElements(isolate, receiver, &args, 1); Handle elms_obj; if (!maybe_elms_obj.ToHandle(&elms_obj)) { return CallJsIntrinsic(isolate, isolate->array_unshift(), args); } Handle array = Handle::cast(receiver); DCHECK(!array->map()->is_observed()); int to_add = args.length() - 1; if (to_add == 0) { return array->length(); } // Currently fixed arrays cannot grow too big, so // we should never hit this case. DCHECK(to_add <= (Smi::kMaxValue - Smi::cast(array->length())->value())); if (to_add > 0 && JSArray::HasReadOnlyLength(array)) { return CallJsIntrinsic(isolate, isolate->array_unshift(), args); } ElementsAccessor* accessor = array->GetElementsAccessor(); int new_length = accessor->Unshift(array, elms_obj, &args, to_add); return Smi::FromInt(new_length); } BUILTIN(ArraySlice) { HandleScope scope(isolate); Handle receiver = args.receiver(); Handle object; Handle elms_obj; int len = -1; int relative_start = 0; int relative_end = 0; bool is_sloppy_arguments = false; // TODO(littledan): Look up @@species only once, not once here and // again in the JS builtin. Pass the species out? Handle species; ASSIGN_RETURN_FAILURE_ON_EXCEPTION( isolate, species, Object::ArraySpeciesConstructor(isolate, receiver)); if (*species != isolate->context()->native_context()->array_function()) { return CallJsIntrinsic(isolate, isolate->array_slice(), args); } if (receiver->IsJSArray()) { DisallowHeapAllocation no_gc; JSArray* array = JSArray::cast(*receiver); if (!array->HasFastElements() || !IsJSArrayFastElementMovingAllowed(isolate, array)) { AllowHeapAllocation allow_allocation; return CallJsIntrinsic(isolate, isolate->array_slice(), args); } len = Smi::cast(array->length())->value(); object = Handle::cast(receiver); elms_obj = handle(array->elements(), isolate); } else if (receiver->IsJSObject() && GetSloppyArgumentsLength(isolate, Handle::cast(receiver), &len)) { // Array.prototype.slice(arguments, ...) is quite a common idiom // (notably more than 50% of invocations in Web apps). // Treat it in C++ as well. is_sloppy_arguments = true; object = Handle::cast(receiver); elms_obj = handle(object->elements(), isolate); } else { AllowHeapAllocation allow_allocation; return CallJsIntrinsic(isolate, isolate->array_slice(), args); } DCHECK(len >= 0); int argument_count = args.length() - 1; // Note carefully chosen defaults---if argument is missing, // it's undefined which gets converted to 0 for relative_start // and to len for relative_end. relative_start = 0; relative_end = len; if (argument_count > 0) { DisallowHeapAllocation no_gc; if (!ClampedToInteger(args[1], &relative_start)) { AllowHeapAllocation allow_allocation; return CallJsIntrinsic(isolate, isolate->array_slice(), args); } if (argument_count > 1) { Object* end_arg = args[2]; // slice handles the end_arg specially if (end_arg->IsUndefined()) { relative_end = len; } else if (!ClampedToInteger(end_arg, &relative_end)) { AllowHeapAllocation allow_allocation; return CallJsIntrinsic(isolate, isolate->array_slice(), args); } } } // ECMAScript 232, 3rd Edition, Section 15.4.4.10, step 6. uint32_t actual_start = (relative_start < 0) ? Max(len + relative_start, 0) : Min(relative_start, len); // ECMAScript 232, 3rd Edition, Section 15.4.4.10, step 8. uint32_t actual_end = (relative_end < 0) ? Max(len + relative_end, 0) : Min(relative_end, len); if (actual_end <= actual_start) { Handle result_array = isolate->factory()->NewJSArray( GetPackedElementsKind(object->GetElementsKind()), 0, 0); return *result_array; } ElementsAccessor* accessor = object->GetElementsAccessor(); if (is_sloppy_arguments && !accessor->IsPacked(object, elms_obj, actual_start, actual_end)) { // Don't deal with arguments with holes in C++ AllowHeapAllocation allow_allocation; return CallJsIntrinsic(isolate, isolate->array_slice(), args); } Handle result_array = accessor->Slice(object, elms_obj, actual_start, actual_end); return *result_array; } BUILTIN(ArraySplice) { HandleScope scope(isolate); Handle receiver = args.receiver(); MaybeHandle maybe_elms_obj = EnsureJSArrayWithWritableFastElements(isolate, receiver, &args, 3); Handle elms_obj; if (!maybe_elms_obj.ToHandle(&elms_obj)) { return CallJsIntrinsic(isolate, isolate->array_splice(), args); } // TODO(littledan): Look up @@species only once, not once here and // again in the JS builtin. Pass the species out? Handle species; ASSIGN_RETURN_FAILURE_ON_EXCEPTION( isolate, species, Object::ArraySpeciesConstructor(isolate, receiver)); if (*species != isolate->context()->native_context()->array_function()) { return CallJsIntrinsic(isolate, isolate->array_splice(), args); } Handle array = Handle::cast(receiver); DCHECK(!array->map()->is_observed()); int argument_count = args.length() - 1; int relative_start = 0; if (argument_count > 0) { DisallowHeapAllocation no_gc; if (!ClampedToInteger(args[1], &relative_start)) { AllowHeapAllocation allow_allocation; return CallJsIntrinsic(isolate, isolate->array_splice(), args); } } int len = Smi::cast(array->length())->value(); // clip relative start to [0, len] int actual_start = (relative_start < 0) ? Max(len + relative_start, 0) : Min(relative_start, len); int actual_delete_count; if (argument_count == 1) { // SpiderMonkey, TraceMonkey and JSC treat the case where no delete count is // given as a request to delete all the elements from the start. // And it differs from the case of undefined delete count. // This does not follow ECMA-262, but we do the same for compatibility. DCHECK(len - actual_start >= 0); actual_delete_count = len - actual_start; } else { int delete_count = 0; DisallowHeapAllocation no_gc; if (argument_count > 1) { if (!ClampedToInteger(args[2], &delete_count)) { AllowHeapAllocation allow_allocation; return CallJsIntrinsic(isolate, isolate->array_splice(), args); } } actual_delete_count = Min(Max(delete_count, 0), len - actual_start); } int add_count = (argument_count > 1) ? (argument_count - 2) : 0; int new_length = len - actual_delete_count + add_count; if (new_length != len && JSArray::HasReadOnlyLength(array)) { AllowHeapAllocation allow_allocation; return CallJsIntrinsic(isolate, isolate->array_splice(), args); } ElementsAccessor* accessor = array->GetElementsAccessor(); Handle result_array = accessor->Splice( array, elms_obj, actual_start, actual_delete_count, &args, add_count); return *result_array; } // Array Concat ------------------------------------------------------------- namespace { /** * A simple visitor visits every element of Array's. * The backend storage can be a fixed array for fast elements case, * or a dictionary for sparse array. Since Dictionary is a subtype * of FixedArray, the class can be used by both fast and slow cases. * The second parameter of the constructor, fast_elements, specifies * whether the storage is a FixedArray or Dictionary. * * An index limit is used to deal with the situation that a result array * length overflows 32-bit non-negative integer. */ class ArrayConcatVisitor { public: ArrayConcatVisitor(Isolate* isolate, Handle storage, bool fast_elements) : isolate_(isolate), storage_(Handle::cast( isolate->global_handles()->Create(*storage))), index_offset_(0u), bit_field_(FastElementsField::encode(fast_elements) | ExceedsLimitField::encode(false)) {} ~ArrayConcatVisitor() { clear_storage(); } void visit(uint32_t i, Handle elm) { if (i >= JSObject::kMaxElementCount - index_offset_) { set_exceeds_array_limit(true); return; } uint32_t index = index_offset_ + i; if (fast_elements()) { if (index < static_cast(storage_->length())) { storage_->set(index, *elm); return; } // Our initial estimate of length was foiled, possibly by // getters on the arrays increasing the length of later arrays // during iteration. // This shouldn't happen in anything but pathological cases. SetDictionaryMode(); // Fall-through to dictionary mode. } DCHECK(!fast_elements()); Handle dict( SeededNumberDictionary::cast(*storage_)); // The object holding this backing store has just been allocated, so // it cannot yet be used as a prototype. Handle result = SeededNumberDictionary::AtNumberPut(dict, index, elm, false); if (!result.is_identical_to(dict)) { // Dictionary needed to grow. clear_storage(); set_storage(*result); } } void increase_index_offset(uint32_t delta) { if (JSObject::kMaxElementCount - index_offset_ < delta) { index_offset_ = JSObject::kMaxElementCount; } else { index_offset_ += delta; } // If the initial length estimate was off (see special case in visit()), // but the array blowing the limit didn't contain elements beyond the // provided-for index range, go to dictionary mode now. if (fast_elements() && index_offset_ > static_cast(FixedArrayBase::cast(*storage_)->length())) { SetDictionaryMode(); } } bool exceeds_array_limit() const { return ExceedsLimitField::decode(bit_field_); } Handle ToArray() { Handle array = isolate_->factory()->NewJSArray(0); Handle length = isolate_->factory()->NewNumber(static_cast(index_offset_)); Handle map = JSObject::GetElementsTransitionMap( array, fast_elements() ? FAST_HOLEY_ELEMENTS : DICTIONARY_ELEMENTS); array->set_map(*map); array->set_length(*length); array->set_elements(*storage_); return array; } private: // Convert storage to dictionary mode. void SetDictionaryMode() { DCHECK(fast_elements()); Handle current_storage(*storage_); Handle slow_storage( SeededNumberDictionary::New(isolate_, current_storage->length())); uint32_t current_length = static_cast(current_storage->length()); for (uint32_t i = 0; i < current_length; i++) { HandleScope loop_scope(isolate_); Handle element(current_storage->get(i), isolate_); if (!element->IsTheHole()) { // The object holding this backing store has just been allocated, so // it cannot yet be used as a prototype. Handle new_storage = SeededNumberDictionary::AtNumberPut(slow_storage, i, element, false); if (!new_storage.is_identical_to(slow_storage)) { slow_storage = loop_scope.CloseAndEscape(new_storage); } } } clear_storage(); set_storage(*slow_storage); set_fast_elements(false); } inline void clear_storage() { GlobalHandles::Destroy(Handle::cast(storage_).location()); } inline void set_storage(FixedArray* storage) { storage_ = Handle::cast(isolate_->global_handles()->Create(storage)); } class FastElementsField : public BitField {}; class ExceedsLimitField : public BitField {}; bool fast_elements() const { return FastElementsField::decode(bit_field_); } void set_fast_elements(bool fast) { bit_field_ = FastElementsField::update(bit_field_, fast); } void set_exceeds_array_limit(bool exceeds) { bit_field_ = ExceedsLimitField::update(bit_field_, exceeds); } Isolate* isolate_; Handle storage_; // Always a global handle. // Index after last seen index. Always less than or equal to // JSObject::kMaxElementCount. uint32_t index_offset_; uint32_t bit_field_; }; uint32_t EstimateElementCount(Handle array) { uint32_t length = static_cast(array->length()->Number()); int element_count = 0; switch (array->GetElementsKind()) { case FAST_SMI_ELEMENTS: case FAST_HOLEY_SMI_ELEMENTS: case FAST_ELEMENTS: case FAST_HOLEY_ELEMENTS: { // Fast elements can't have lengths that are not representable by // a 32-bit signed integer. DCHECK(static_cast(FixedArray::kMaxLength) >= 0); int fast_length = static_cast(length); Handle elements(FixedArray::cast(array->elements())); for (int i = 0; i < fast_length; i++) { if (!elements->get(i)->IsTheHole()) element_count++; } break; } case FAST_DOUBLE_ELEMENTS: case FAST_HOLEY_DOUBLE_ELEMENTS: { // Fast elements can't have lengths that are not representable by // a 32-bit signed integer. DCHECK(static_cast(FixedDoubleArray::kMaxLength) >= 0); int fast_length = static_cast(length); if (array->elements()->IsFixedArray()) { DCHECK(FixedArray::cast(array->elements())->length() == 0); break; } Handle elements( FixedDoubleArray::cast(array->elements())); for (int i = 0; i < fast_length; i++) { if (!elements->is_the_hole(i)) element_count++; } break; } case DICTIONARY_ELEMENTS: { Handle dictionary( SeededNumberDictionary::cast(array->elements())); int capacity = dictionary->Capacity(); for (int i = 0; i < capacity; i++) { Handle key(dictionary->KeyAt(i), array->GetIsolate()); if (dictionary->IsKey(*key)) { element_count++; } } break; } case FAST_SLOPPY_ARGUMENTS_ELEMENTS: case SLOW_SLOPPY_ARGUMENTS_ELEMENTS: #define TYPED_ARRAY_CASE(Type, type, TYPE, ctype, size) case TYPE##_ELEMENTS: TYPED_ARRAYS(TYPED_ARRAY_CASE) #undef TYPED_ARRAY_CASE // External arrays are always dense. return length; } // As an estimate, we assume that the prototype doesn't contain any // inherited elements. return element_count; } template void IterateTypedArrayElements(Isolate* isolate, Handle receiver, bool elements_are_ints, bool elements_are_guaranteed_smis, ArrayConcatVisitor* visitor) { Handle array( ExternalArrayClass::cast(receiver->elements())); uint32_t len = static_cast(array->length()); DCHECK(visitor != NULL); if (elements_are_ints) { if (elements_are_guaranteed_smis) { for (uint32_t j = 0; j < len; j++) { HandleScope loop_scope(isolate); Handle e(Smi::FromInt(static_cast(array->get_scalar(j))), isolate); visitor->visit(j, e); } } else { for (uint32_t j = 0; j < len; j++) { HandleScope loop_scope(isolate); int64_t val = static_cast(array->get_scalar(j)); if (Smi::IsValid(static_cast(val))) { Handle e(Smi::FromInt(static_cast(val)), isolate); visitor->visit(j, e); } else { Handle e = isolate->factory()->NewNumber(static_cast(val)); visitor->visit(j, e); } } } } else { for (uint32_t j = 0; j < len; j++) { HandleScope loop_scope(isolate); Handle e = isolate->factory()->NewNumber(array->get_scalar(j)); visitor->visit(j, e); } } } // Used for sorting indices in a List. int compareUInt32(const uint32_t* ap, const uint32_t* bp) { uint32_t a = *ap; uint32_t b = *bp; return (a == b) ? 0 : (a < b) ? -1 : 1; } void CollectElementIndices(Handle object, uint32_t range, List* indices) { Isolate* isolate = object->GetIsolate(); ElementsKind kind = object->GetElementsKind(); switch (kind) { case FAST_SMI_ELEMENTS: case FAST_ELEMENTS: case FAST_HOLEY_SMI_ELEMENTS: case FAST_HOLEY_ELEMENTS: { Handle elements(FixedArray::cast(object->elements())); uint32_t length = static_cast(elements->length()); if (range < length) length = range; for (uint32_t i = 0; i < length; i++) { if (!elements->get(i)->IsTheHole()) { indices->Add(i); } } break; } case FAST_HOLEY_DOUBLE_ELEMENTS: case FAST_DOUBLE_ELEMENTS: { if (object->elements()->IsFixedArray()) { DCHECK(object->elements()->length() == 0); break; } Handle elements( FixedDoubleArray::cast(object->elements())); uint32_t length = static_cast(elements->length()); if (range < length) length = range; for (uint32_t i = 0; i < length; i++) { if (!elements->is_the_hole(i)) { indices->Add(i); } } break; } case DICTIONARY_ELEMENTS: { Handle dict( SeededNumberDictionary::cast(object->elements())); uint32_t capacity = dict->Capacity(); for (uint32_t j = 0; j < capacity; j++) { HandleScope loop_scope(isolate); Handle k(dict->KeyAt(j), isolate); if (dict->IsKey(*k)) { DCHECK(k->IsNumber()); uint32_t index = static_cast(k->Number()); if (index < range) { indices->Add(index); } } } break; } #define TYPED_ARRAY_CASE(Type, type, TYPE, ctype, size) case TYPE##_ELEMENTS: TYPED_ARRAYS(TYPED_ARRAY_CASE) #undef TYPED_ARRAY_CASE { uint32_t length = static_cast( FixedArrayBase::cast(object->elements())->length()); if (range <= length) { length = range; // We will add all indices, so we might as well clear it first // and avoid duplicates. indices->Clear(); } for (uint32_t i = 0; i < length; i++) { indices->Add(i); } if (length == range) return; // All indices accounted for already. break; } case FAST_SLOPPY_ARGUMENTS_ELEMENTS: case SLOW_SLOPPY_ARGUMENTS_ELEMENTS: { ElementsAccessor* accessor = object->GetElementsAccessor(); for (uint32_t i = 0; i < range; i++) { if (accessor->HasElement(object, i)) { indices->Add(i); } } break; } } PrototypeIterator iter(isolate, object); if (!iter.IsAtEnd()) { // The prototype will usually have no inherited element indices, // but we have to check. CollectElementIndices(PrototypeIterator::GetCurrent(iter), range, indices); } } bool IterateElementsSlow(Isolate* isolate, Handle receiver, uint32_t length, ArrayConcatVisitor* visitor) { for (uint32_t i = 0; i < length; ++i) { HandleScope loop_scope(isolate); Maybe maybe = JSReceiver::HasElement(receiver, i); if (!maybe.IsJust()) return false; if (maybe.FromJust()) { Handle element_value; ASSIGN_RETURN_ON_EXCEPTION_VALUE(isolate, element_value, Object::GetElement(isolate, receiver, i), false); visitor->visit(i, element_value); } } visitor->increase_index_offset(length); return true; } /** * A helper function that visits "array" elements of a JSReceiver in numerical * order. * * The visitor argument called for each existing element in the array * with the element index and the element's value. * Afterwards it increments the base-index of the visitor by the array * length. * Returns false if any access threw an exception, otherwise true. */ bool IterateElements(Isolate* isolate, Handle receiver, ArrayConcatVisitor* visitor) { uint32_t length = 0; if (receiver->IsJSArray()) { Handle array = Handle::cast(receiver); length = static_cast(array->length()->Number()); } else { Handle val; Handle key = isolate->factory()->length_string(); ASSIGN_RETURN_ON_EXCEPTION_VALUE( isolate, val, Runtime::GetObjectProperty(isolate, receiver, key), false); ASSIGN_RETURN_ON_EXCEPTION_VALUE(isolate, val, Object::ToLength(isolate, val), false); // TODO(caitp): Support larger element indexes (up to 2^53-1). if (!val->ToUint32(&length)) { length = 0; } } if (!(receiver->IsJSArray() || receiver->IsJSTypedArray())) { // For classes which are not known to be safe to access via elements alone, // use the slow case. return IterateElementsSlow(isolate, receiver, length, visitor); } Handle array = Handle::cast(receiver); switch (array->GetElementsKind()) { case FAST_SMI_ELEMENTS: case FAST_ELEMENTS: case FAST_HOLEY_SMI_ELEMENTS: case FAST_HOLEY_ELEMENTS: { // Run through the elements FixedArray and use HasElement and GetElement // to check the prototype for missing elements. Handle elements(FixedArray::cast(array->elements())); int fast_length = static_cast(length); DCHECK(fast_length <= elements->length()); for (int j = 0; j < fast_length; j++) { HandleScope loop_scope(isolate); Handle element_value(elements->get(j), isolate); if (!element_value->IsTheHole()) { visitor->visit(j, element_value); } else { Maybe maybe = JSReceiver::HasElement(array, j); if (!maybe.IsJust()) return false; if (maybe.FromJust()) { // Call GetElement on array, not its prototype, or getters won't // have the correct receiver. ASSIGN_RETURN_ON_EXCEPTION_VALUE( isolate, element_value, Object::GetElement(isolate, array, j), false); visitor->visit(j, element_value); } } } break; } case FAST_HOLEY_DOUBLE_ELEMENTS: case FAST_DOUBLE_ELEMENTS: { // Empty array is FixedArray but not FixedDoubleArray. if (length == 0) break; // Run through the elements FixedArray and use HasElement and GetElement // to check the prototype for missing elements. if (array->elements()->IsFixedArray()) { DCHECK(array->elements()->length() == 0); break; } Handle elements( FixedDoubleArray::cast(array->elements())); int fast_length = static_cast(length); DCHECK(fast_length <= elements->length()); for (int j = 0; j < fast_length; j++) { HandleScope loop_scope(isolate); if (!elements->is_the_hole(j)) { double double_value = elements->get_scalar(j); Handle element_value = isolate->factory()->NewNumber(double_value); visitor->visit(j, element_value); } else { Maybe maybe = JSReceiver::HasElement(array, j); if (!maybe.IsJust()) return false; if (maybe.FromJust()) { // Call GetElement on array, not its prototype, or getters won't // have the correct receiver. Handle element_value; ASSIGN_RETURN_ON_EXCEPTION_VALUE( isolate, element_value, Object::GetElement(isolate, array, j), false); visitor->visit(j, element_value); } } } break; } case DICTIONARY_ELEMENTS: { // CollectElementIndices() can't be called when there's a JSProxy // on the prototype chain. for (PrototypeIterator iter(isolate, array); !iter.IsAtEnd(); iter.Advance()) { if (PrototypeIterator::GetCurrent(iter)->IsJSProxy()) { return IterateElementsSlow(isolate, array, length, visitor); } } Handle dict(array->element_dictionary()); List indices(dict->Capacity() / 2); // Collect all indices in the object and the prototypes less // than length. This might introduce duplicates in the indices list. CollectElementIndices(array, length, &indices); indices.Sort(&compareUInt32); int j = 0; int n = indices.length(); while (j < n) { HandleScope loop_scope(isolate); uint32_t index = indices[j]; Handle element; ASSIGN_RETURN_ON_EXCEPTION_VALUE( isolate, element, Object::GetElement(isolate, array, index), false); visitor->visit(index, element); // Skip to next different index (i.e., omit duplicates). do { j++; } while (j < n && indices[j] == index); } break; } case UINT8_CLAMPED_ELEMENTS: { Handle pixels( FixedUint8ClampedArray::cast(array->elements())); for (uint32_t j = 0; j < length; j++) { Handle e(Smi::FromInt(pixels->get_scalar(j)), isolate); visitor->visit(j, e); } break; } case INT8_ELEMENTS: { IterateTypedArrayElements(isolate, array, true, true, visitor); break; } case UINT8_ELEMENTS: { IterateTypedArrayElements(isolate, array, true, true, visitor); break; } case INT16_ELEMENTS: { IterateTypedArrayElements(isolate, array, true, true, visitor); break; } case UINT16_ELEMENTS: { IterateTypedArrayElements( isolate, array, true, true, visitor); break; } case INT32_ELEMENTS: { IterateTypedArrayElements(isolate, array, true, false, visitor); break; } case UINT32_ELEMENTS: { IterateTypedArrayElements( isolate, array, true, false, visitor); break; } case FLOAT32_ELEMENTS: { IterateTypedArrayElements(isolate, array, false, false, visitor); break; } case FLOAT64_ELEMENTS: { IterateTypedArrayElements( isolate, array, false, false, visitor); break; } case FAST_SLOPPY_ARGUMENTS_ELEMENTS: case SLOW_SLOPPY_ARGUMENTS_ELEMENTS: { for (uint32_t index = 0; index < length; index++) { HandleScope loop_scope(isolate); Handle element; ASSIGN_RETURN_ON_EXCEPTION_VALUE( isolate, element, Object::GetElement(isolate, array, index), false); visitor->visit(index, element); } break; } } visitor->increase_index_offset(length); return true; } bool HasConcatSpreadableModifier(Isolate* isolate, Handle obj) { DCHECK(isolate->IsFastArrayConstructorPrototypeChainIntact()); if (!FLAG_harmony_concat_spreadable) return false; Handle key(isolate->factory()->is_concat_spreadable_symbol()); Maybe maybe = JSReceiver::HasProperty(obj, key); return maybe.FromMaybe(false); } static Maybe IsConcatSpreadable(Isolate* isolate, Handle obj) { HandleScope handle_scope(isolate); if (!obj->IsJSReceiver()) return Just(false); if (FLAG_harmony_concat_spreadable) { Handle key(isolate->factory()->is_concat_spreadable_symbol()); Handle value; MaybeHandle maybeValue = i::Runtime::GetObjectProperty(isolate, obj, key); if (!maybeValue.ToHandle(&value)) return Nothing(); if (!value->IsUndefined()) return Just(value->BooleanValue()); } return Object::IsArray(obj); } Object* Slow_ArrayConcat(Arguments* args, Isolate* isolate) { int argument_count = args->length(); // Pass 1: estimate the length and number of elements of the result. // The actual length can be larger if any of the arguments have getters // that mutate other arguments (but will otherwise be precise). // The number of elements is precise if there are no inherited elements. ElementsKind kind = FAST_SMI_ELEMENTS; uint32_t estimate_result_length = 0; uint32_t estimate_nof_elements = 0; for (int i = 0; i < argument_count; i++) { HandleScope loop_scope(isolate); Handle obj((*args)[i], isolate); uint32_t length_estimate; uint32_t element_estimate; if (obj->IsJSArray()) { Handle array(Handle::cast(obj)); length_estimate = static_cast(array->length()->Number()); if (length_estimate != 0) { ElementsKind array_kind = GetPackedElementsKind(array->map()->elements_kind()); kind = GetMoreGeneralElementsKind(kind, array_kind); } element_estimate = EstimateElementCount(array); } else { if (obj->IsHeapObject()) { if (obj->IsNumber()) { kind = GetMoreGeneralElementsKind(kind, FAST_DOUBLE_ELEMENTS); } else { kind = GetMoreGeneralElementsKind(kind, FAST_ELEMENTS); } } length_estimate = 1; element_estimate = 1; } // Avoid overflows by capping at kMaxElementCount. if (JSObject::kMaxElementCount - estimate_result_length < length_estimate) { estimate_result_length = JSObject::kMaxElementCount; } else { estimate_result_length += length_estimate; } if (JSObject::kMaxElementCount - estimate_nof_elements < element_estimate) { estimate_nof_elements = JSObject::kMaxElementCount; } else { estimate_nof_elements += element_estimate; } } // If estimated number of elements is more than half of length, a // fixed array (fast case) is more time and space-efficient than a // dictionary. bool fast_case = (estimate_nof_elements * 2) >= estimate_result_length; if (fast_case && kind == FAST_DOUBLE_ELEMENTS) { Handle storage = isolate->factory()->NewFixedDoubleArray(estimate_result_length); int j = 0; bool failure = false; if (estimate_result_length > 0) { Handle double_storage = Handle::cast(storage); for (int i = 0; i < argument_count; i++) { Handle obj((*args)[i], isolate); if (obj->IsSmi()) { double_storage->set(j, Smi::cast(*obj)->value()); j++; } else if (obj->IsNumber()) { double_storage->set(j, obj->Number()); j++; } else { JSArray* array = JSArray::cast(*obj); uint32_t length = static_cast(array->length()->Number()); switch (array->map()->elements_kind()) { case FAST_HOLEY_DOUBLE_ELEMENTS: case FAST_DOUBLE_ELEMENTS: { // Empty array is FixedArray but not FixedDoubleArray. if (length == 0) break; FixedDoubleArray* elements = FixedDoubleArray::cast(array->elements()); for (uint32_t i = 0; i < length; i++) { if (elements->is_the_hole(i)) { // TODO(jkummerow/verwaest): We could be a bit more clever // here: Check if there are no elements/getters on the // prototype chain, and if so, allow creation of a holey // result array. // Same thing below (holey smi case). failure = true; break; } double double_value = elements->get_scalar(i); double_storage->set(j, double_value); j++; } break; } case FAST_HOLEY_SMI_ELEMENTS: case FAST_SMI_ELEMENTS: { FixedArray* elements(FixedArray::cast(array->elements())); for (uint32_t i = 0; i < length; i++) { Object* element = elements->get(i); if (element->IsTheHole()) { failure = true; break; } int32_t int_value = Smi::cast(element)->value(); double_storage->set(j, int_value); j++; } break; } case FAST_HOLEY_ELEMENTS: case FAST_ELEMENTS: case DICTIONARY_ELEMENTS: DCHECK_EQ(0u, length); break; default: UNREACHABLE(); } } if (failure) break; } } if (!failure) { Handle array = isolate->factory()->NewJSArray(0); Smi* length = Smi::FromInt(j); Handle map; map = JSObject::GetElementsTransitionMap(array, kind); array->set_map(*map); array->set_length(length); array->set_elements(*storage); return *array; } // In case of failure, fall through. } Handle storage; if (fast_case) { // The backing storage array must have non-existing elements to preserve // holes across concat operations. storage = isolate->factory()->NewFixedArrayWithHoles(estimate_result_length); } else { // TODO(126): move 25% pre-allocation logic into Dictionary::Allocate uint32_t at_least_space_for = estimate_nof_elements + (estimate_nof_elements >> 2); storage = Handle::cast( SeededNumberDictionary::New(isolate, at_least_space_for)); } ArrayConcatVisitor visitor(isolate, storage, fast_case); for (int i = 0; i < argument_count; i++) { Handle obj((*args)[i], isolate); Maybe spreadable = IsConcatSpreadable(isolate, obj); MAYBE_RETURN(spreadable, isolate->heap()->exception()); if (spreadable.FromJust()) { Handle object = Handle::cast(obj); if (!IterateElements(isolate, object, &visitor)) { return isolate->heap()->exception(); } } else { visitor.visit(0, obj); visitor.increase_index_offset(1); } } if (visitor.exceeds_array_limit()) { THROW_NEW_ERROR_RETURN_FAILURE( isolate, NewRangeError(MessageTemplate::kInvalidArrayLength)); } return *visitor.ToArray(); } MaybeHandle Fast_ArrayConcat(Isolate* isolate, Arguments* args) { if (!isolate->IsFastArrayConstructorPrototypeChainIntact()) { return MaybeHandle(); } int n_arguments = args->length(); int result_len = 0; { DisallowHeapAllocation no_gc; Object* array_proto = isolate->array_function()->prototype(); // Iterate through all the arguments performing checks // and calculating total length. for (int i = 0; i < n_arguments; i++) { Object* arg = (*args)[i]; if (!arg->IsJSArray()) return MaybeHandle(); Handle array(JSArray::cast(arg), isolate); if (!array->HasFastElements()) return MaybeHandle(); PrototypeIterator iter(isolate, arg); if (iter.GetCurrent() != array_proto) return MaybeHandle(); if (HasConcatSpreadableModifier(isolate, array)) { return MaybeHandle(); } int len = Smi::cast(array->length())->value(); // We shouldn't overflow when adding another len. const int kHalfOfMaxInt = 1 << (kBitsPerInt - 2); STATIC_ASSERT(FixedArray::kMaxLength < kHalfOfMaxInt); USE(kHalfOfMaxInt); result_len += len; DCHECK(result_len >= 0); // Throw an Error if we overflow the FixedArray limits if (FixedArray::kMaxLength < result_len) { THROW_NEW_ERROR(isolate, NewRangeError(MessageTemplate::kInvalidArrayLength), JSArray); } } } return ElementsAccessor::Concat(isolate, args, n_arguments); } } // namespace // ES6 22.1.3.1 Array.prototype.concat BUILTIN(ArrayConcat) { HandleScope scope(isolate); Handle receiver; if (!Object::ToObject(isolate, handle(args[0], isolate)) .ToHandle(&receiver)) { THROW_NEW_ERROR_RETURN_FAILURE( isolate, NewTypeError(MessageTemplate::kCalledOnNullOrUndefined, isolate->factory()->NewStringFromAsciiChecked( "Array.prototype.concat"))); } args[0] = *receiver; Handle result_array; if (Fast_ArrayConcat(isolate, &args).ToHandle(&result_array)) { return *result_array; } if (isolate->has_pending_exception()) return isolate->heap()->exception(); return Slow_ArrayConcat(&args, isolate); } // ES6 22.1.2.2 Array.isArray BUILTIN(ArrayIsArray) { HandleScope scope(isolate); DCHECK_EQ(2, args.length()); Handle object = args.at(1); Maybe result = Object::IsArray(object); MAYBE_RETURN(result, isolate->heap()->exception()); return *isolate->factory()->ToBoolean(result.FromJust()); } // ES6 19.1.2.1 Object.assign BUILTIN(ObjectAssign) { HandleScope scope(isolate); Handle target = args.atOrUndefined(isolate, 1); // 1. Let to be ? ToObject(target). ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, target, Execution::ToObject(isolate, target)); Handle to = Handle::cast(target); // 2. If only one argument was passed, return to. if (args.length() == 2) return *to; // 3. Let sources be the List of argument values starting with the // second argument. // 4. For each element nextSource of sources, in ascending index order, for (int i = 2; i < args.length(); ++i) { Handle next_source = args.at(i); // 4a. If nextSource is undefined or null, let keys be an empty List. if (next_source->IsUndefined() || next_source->IsNull()) continue; // 4b. Else, // 4b i. Let from be ToObject(nextSource). Handle from = Object::ToObject(isolate, next_source).ToHandleChecked(); // 4b ii. Let keys be ? from.[[OwnPropertyKeys]](). Handle keys; ASSIGN_RETURN_FAILURE_ON_EXCEPTION( isolate, keys, JSReceiver::GetKeys(from, JSReceiver::OWN_ONLY, ALL_PROPERTIES, KEEP_NUMBERS)); // 4c. Repeat for each element nextKey of keys in List order, for (int j = 0; j < keys->length(); ++j) { Handle next_key(keys->get(j), isolate); // 4c i. Let desc be ? from.[[GetOwnProperty]](nextKey). PropertyDescriptor desc; Maybe found = JSReceiver::GetOwnPropertyDescriptor(isolate, from, next_key, &desc); if (found.IsNothing()) return isolate->heap()->exception(); // 4c ii. If desc is not undefined and desc.[[Enumerable]] is true, then if (found.FromJust() && desc.enumerable()) { // 4c ii 1. Let propValue be ? Get(from, nextKey). Handle prop_value; ASSIGN_RETURN_FAILURE_ON_EXCEPTION( isolate, prop_value, Runtime::GetObjectProperty(isolate, from, next_key, STRICT)); // 4c ii 2. Let status be ? Set(to, nextKey, propValue, true). Handle status; ASSIGN_RETURN_FAILURE_ON_EXCEPTION( isolate, status, Runtime::SetObjectProperty(isolate, to, next_key, prop_value, STRICT)); } } } // 5. Return to. return *to; } // ES6 section 19.1.2.2 Object.create ( O [ , Properties ] ) BUILTIN(ObjectCreate) { HandleScope scope(isolate); Handle prototype = args.atOrUndefined(isolate, 1); if (!prototype->IsNull() && !prototype->IsJSReceiver()) { THROW_NEW_ERROR_RETURN_FAILURE( isolate, NewTypeError(MessageTemplate::kProtoObjectOrNull, prototype)); } // Generate the map with the specified {prototype} based on the Object // function's initial map from the current native context. // TODO(bmeurer): Use a dedicated cache for Object.create; think about // slack tracking for Object.create. Handle map(isolate->native_context()->object_function()->initial_map(), isolate); if (map->prototype() != *prototype) { map = Map::TransitionToPrototype(map, prototype, FAST_PROTOTYPE); } // Actually allocate the object. Handle object = isolate->factory()->NewJSObjectFromMap(map); // Define the properties if properties was specified and is not undefined. Handle properties = args.atOrUndefined(isolate, 2); if (!properties->IsUndefined()) { RETURN_FAILURE_ON_EXCEPTION( isolate, JSReceiver::DefineProperties(isolate, object, properties)); } return *object; } // ES6 section 19.1.2.5 Object.freeze ( O ) BUILTIN(ObjectFreeze) { HandleScope scope(isolate); Handle object = args.atOrUndefined(isolate, 1); if (object->IsJSReceiver()) { MAYBE_RETURN(JSReceiver::SetIntegrityLevel(Handle::cast(object), FROZEN, Object::THROW_ON_ERROR), isolate->heap()->exception()); } return *object; } // ES6 section 19.1.2.11 Object.isExtensible ( O ) BUILTIN(ObjectIsExtensible) { HandleScope scope(isolate); Handle object = args.atOrUndefined(isolate, 1); Maybe result = object->IsJSReceiver() ? JSReceiver::IsExtensible(Handle::cast(object)) : Just(false); MAYBE_RETURN(result, isolate->heap()->exception()); return isolate->heap()->ToBoolean(result.FromJust()); } // ES6 section 19.1.2.12 Object.isFrozen ( O ) BUILTIN(ObjectIsFrozen) { HandleScope scope(isolate); Handle object = args.atOrUndefined(isolate, 1); Maybe result = object->IsJSReceiver() ? JSReceiver::TestIntegrityLevel( Handle::cast(object), FROZEN) : Just(true); MAYBE_RETURN(result, isolate->heap()->exception()); return isolate->heap()->ToBoolean(result.FromJust()); } // ES6 section 19.1.2.13 Object.isSealed ( O ) BUILTIN(ObjectIsSealed) { HandleScope scope(isolate); Handle object = args.atOrUndefined(isolate, 1); Maybe result = object->IsJSReceiver() ? JSReceiver::TestIntegrityLevel( Handle::cast(object), SEALED) : Just(true); MAYBE_RETURN(result, isolate->heap()->exception()); return isolate->heap()->ToBoolean(result.FromJust()); } // ES6 section 19.1.2.14 Object.keys ( O ) BUILTIN(ObjectKeys) { HandleScope scope(isolate); Handle object = args.atOrUndefined(isolate, 1); Handle receiver; ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, receiver, Execution::ToObject(isolate, object)); Handle keys; int enum_length = receiver->map()->EnumLength(); if (enum_length != kInvalidEnumCacheSentinel && JSObject::cast(*receiver)->elements() == isolate->heap()->empty_fixed_array()) { DCHECK(receiver->IsJSObject()); DCHECK(!JSObject::cast(*receiver)->HasNamedInterceptor()); DCHECK(!JSObject::cast(*receiver)->IsAccessCheckNeeded()); DCHECK(!HeapObject::cast(receiver->map()->prototype()) ->map() ->is_hidden_prototype()); DCHECK(JSObject::cast(*receiver)->HasFastProperties()); if (enum_length == 0) { keys = isolate->factory()->empty_fixed_array(); } else { Handle cache( receiver->map()->instance_descriptors()->GetEnumCache()); keys = isolate->factory()->NewFixedArray(enum_length); for (int i = 0; i < enum_length; i++) { keys->set(i, cache->get(i)); } } } else { ASSIGN_RETURN_FAILURE_ON_EXCEPTION( isolate, keys, JSReceiver::GetKeys(receiver, JSReceiver::OWN_ONLY, ENUMERABLE_STRINGS, CONVERT_TO_STRING)); } return *isolate->factory()->NewJSArrayWithElements(keys, FAST_ELEMENTS); } // ES6 section 19.1.2.15 Object.preventExtensions ( O ) BUILTIN(ObjectPreventExtensions) { HandleScope scope(isolate); Handle object = args.atOrUndefined(isolate, 1); if (object->IsJSReceiver()) { MAYBE_RETURN(JSReceiver::PreventExtensions(Handle::cast(object), Object::THROW_ON_ERROR), isolate->heap()->exception()); } return *object; } // ES6 section 19.1.2.17 Object.seal ( O ) BUILTIN(ObjectSeal) { HandleScope scope(isolate); Handle object = args.atOrUndefined(isolate, 1); if (object->IsJSReceiver()) { MAYBE_RETURN(JSReceiver::SetIntegrityLevel(Handle::cast(object), SEALED, Object::THROW_ON_ERROR), isolate->heap()->exception()); } return *object; } namespace { bool CodeGenerationFromStringsAllowed(Isolate* isolate, Handle context) { DCHECK(context->allow_code_gen_from_strings()->IsFalse()); // Check with callback if set. AllowCodeGenerationFromStringsCallback callback = isolate->allow_code_gen_callback(); if (callback == NULL) { // No callback set and code generation disallowed. return false; } else { // Callback set. Let it decide if code generation is allowed. VMState state(isolate); return callback(v8::Utils::ToLocal(context)); } } MaybeHandle CompileString(Handle context, Handle source, ParseRestriction restriction) { Isolate* const isolate = context->GetIsolate(); Handle native_context(context->native_context(), isolate); // Check if native context allows code generation from // strings. Throw an exception if it doesn't. if (native_context->allow_code_gen_from_strings()->IsFalse() && !CodeGenerationFromStringsAllowed(isolate, native_context)) { Handle error_message = native_context->ErrorMessageForCodeGenerationFromStrings(); THROW_NEW_ERROR(isolate, NewEvalError(MessageTemplate::kCodeGenFromStrings, error_message), JSFunction); } // Compile source string in the native context. Handle outer_info(native_context->closure()->shared(), isolate); return Compiler::GetFunctionFromEval(source, outer_info, native_context, SLOPPY, restriction, RelocInfo::kNoPosition); } } // namespace // ES6 section 18.2.1 eval (x) BUILTIN(GlobalEval) { HandleScope scope(isolate); Handle x = args.atOrUndefined(isolate, 1); Handle target = args.target(); Handle target_global_proxy(target->global_proxy(), isolate); if (!x->IsString()) return *x; Handle function; ASSIGN_RETURN_FAILURE_ON_EXCEPTION( isolate, function, CompileString(handle(target->native_context(), isolate), Handle::cast(x), NO_PARSE_RESTRICTION)); Handle result; ASSIGN_RETURN_FAILURE_ON_EXCEPTION( isolate, result, Execution::Call(isolate, function, target_global_proxy, 0, nullptr)); return *result; } // ES6 section 26.1.3 Reflect.defineProperty BUILTIN(ReflectDefineProperty) { HandleScope scope(isolate); DCHECK_EQ(4, args.length()); Handle target = args.at(1); Handle key = args.at(2); Handle attributes = args.at(3); if (!target->IsJSReceiver()) { THROW_NEW_ERROR_RETURN_FAILURE( isolate, NewTypeError(MessageTemplate::kCalledOnNonObject, isolate->factory()->NewStringFromAsciiChecked( "Reflect.defineProperty"))); } Handle name; ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, name, Object::ToName(isolate, key)); PropertyDescriptor desc; if (!PropertyDescriptor::ToPropertyDescriptor(isolate, attributes, &desc)) { return isolate->heap()->exception(); } Maybe result = JSReceiver::DefineOwnProperty(isolate, Handle::cast(target), name, &desc, Object::DONT_THROW); MAYBE_RETURN(result, isolate->heap()->exception()); return *isolate->factory()->ToBoolean(result.FromJust()); } // ES6 section 26.1.4 Reflect.deleteProperty BUILTIN(ReflectDeleteProperty) { HandleScope scope(isolate); DCHECK_EQ(3, args.length()); Handle target = args.at(1); Handle key = args.at(2); if (!target->IsJSReceiver()) { THROW_NEW_ERROR_RETURN_FAILURE( isolate, NewTypeError(MessageTemplate::kCalledOnNonObject, isolate->factory()->NewStringFromAsciiChecked( "Reflect.deleteProperty"))); } Handle name; ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, name, Object::ToName(isolate, key)); Maybe result = JSReceiver::DeletePropertyOrElement( Handle::cast(target), name, SLOPPY); MAYBE_RETURN(result, isolate->heap()->exception()); return *isolate->factory()->ToBoolean(result.FromJust()); } // ES6 section 26.1.6 Reflect.get BUILTIN(ReflectGet) { HandleScope scope(isolate); Handle target = args.atOrUndefined(isolate, 1); Handle key = args.atOrUndefined(isolate, 2); Handle receiver = args.length() > 3 ? args.at(3) : target; if (!target->IsJSReceiver()) { THROW_NEW_ERROR_RETURN_FAILURE( isolate, NewTypeError(MessageTemplate::kCalledOnNonObject, isolate->factory()->NewStringFromAsciiChecked( "Reflect.get"))); } Handle name; ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, name, Object::ToName(isolate, key)); Handle result; ASSIGN_RETURN_FAILURE_ON_EXCEPTION( isolate, result, Object::GetPropertyOrElement( Handle::cast(target), name, receiver)); return *result; } // ES6 section 26.1.7 Reflect.getOwnPropertyDescriptor BUILTIN(ReflectGetOwnPropertyDescriptor) { HandleScope scope(isolate); DCHECK_EQ(3, args.length()); Handle target = args.at(1); Handle key = args.at(2); if (!target->IsJSReceiver()) { THROW_NEW_ERROR_RETURN_FAILURE( isolate, NewTypeError(MessageTemplate::kCalledOnNonObject, isolate->factory()->NewStringFromAsciiChecked( "Reflect.getOwnPropertyDescriptor"))); } Handle name; ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, name, Object::ToName(isolate, key)); PropertyDescriptor desc; Maybe found = JSReceiver::GetOwnPropertyDescriptor( isolate, Handle::cast(target), name, &desc); MAYBE_RETURN(found, isolate->heap()->exception()); if (!found.FromJust()) return isolate->heap()->undefined_value(); return *desc.ToObject(isolate); } // ES6 section 26.1.8 Reflect.getPrototypeOf BUILTIN(ReflectGetPrototypeOf) { HandleScope scope(isolate); DCHECK_EQ(2, args.length()); Handle target = args.at(1); if (!target->IsJSReceiver()) { THROW_NEW_ERROR_RETURN_FAILURE( isolate, NewTypeError(MessageTemplate::kCalledOnNonObject, isolate->factory()->NewStringFromAsciiChecked( "Reflect.getPrototypeOf"))); } Handle prototype; ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, prototype, Object::GetPrototype(isolate, target)); return *prototype; } // ES6 section 26.1.9 Reflect.has BUILTIN(ReflectHas) { HandleScope scope(isolate); DCHECK_EQ(3, args.length()); Handle target = args.at(1); Handle key = args.at(2); if (!target->IsJSReceiver()) { THROW_NEW_ERROR_RETURN_FAILURE( isolate, NewTypeError(MessageTemplate::kCalledOnNonObject, isolate->factory()->NewStringFromAsciiChecked( "Reflect.has"))); } Handle name; ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, name, Object::ToName(isolate, key)); Maybe result = JSReceiver::HasProperty(Handle::cast(target), name); return result.IsJust() ? *isolate->factory()->ToBoolean(result.FromJust()) : isolate->heap()->exception(); } // ES6 section 26.1.10 Reflect.isExtensible BUILTIN(ReflectIsExtensible) { HandleScope scope(isolate); DCHECK_EQ(2, args.length()); Handle target = args.at(1); if (!target->IsJSReceiver()) { THROW_NEW_ERROR_RETURN_FAILURE( isolate, NewTypeError(MessageTemplate::kCalledOnNonObject, isolate->factory()->NewStringFromAsciiChecked( "Reflect.isExtensible"))); } Maybe result = JSReceiver::IsExtensible(Handle::cast(target)); MAYBE_RETURN(result, isolate->heap()->exception()); return *isolate->factory()->ToBoolean(result.FromJust()); } // ES6 section 26.1.11 Reflect.ownKeys BUILTIN(ReflectOwnKeys) { HandleScope scope(isolate); DCHECK_EQ(2, args.length()); Handle target = args.at(1); if (!target->IsJSReceiver()) { THROW_NEW_ERROR_RETURN_FAILURE( isolate, NewTypeError(MessageTemplate::kCalledOnNonObject, isolate->factory()->NewStringFromAsciiChecked( "Reflect.ownKeys"))); } Handle keys; ASSIGN_RETURN_FAILURE_ON_EXCEPTION( isolate, keys, JSReceiver::GetKeys(Handle::cast(target), JSReceiver::OWN_ONLY, ALL_PROPERTIES, CONVERT_TO_STRING)); return *isolate->factory()->NewJSArrayWithElements(keys); } // ES6 section 26.1.12 Reflect.preventExtensions BUILTIN(ReflectPreventExtensions) { HandleScope scope(isolate); DCHECK_EQ(2, args.length()); Handle target = args.at(1); if (!target->IsJSReceiver()) { THROW_NEW_ERROR_RETURN_FAILURE( isolate, NewTypeError(MessageTemplate::kCalledOnNonObject, isolate->factory()->NewStringFromAsciiChecked( "Reflect.preventExtensions"))); } Maybe result = JSReceiver::PreventExtensions( Handle::cast(target), Object::DONT_THROW); MAYBE_RETURN(result, isolate->heap()->exception()); return *isolate->factory()->ToBoolean(result.FromJust()); } // ES6 section 26.1.13 Reflect.set BUILTIN(ReflectSet) { HandleScope scope(isolate); Handle target = args.atOrUndefined(isolate, 1); Handle key = args.atOrUndefined(isolate, 2); Handle value = args.atOrUndefined(isolate, 3); Handle receiver = args.length() > 4 ? args.at(4) : target; if (!target->IsJSReceiver()) { THROW_NEW_ERROR_RETURN_FAILURE( isolate, NewTypeError(MessageTemplate::kCalledOnNonObject, isolate->factory()->NewStringFromAsciiChecked( "Reflect.set"))); } Handle name; ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, name, Object::ToName(isolate, key)); LookupIterator it = LookupIterator::PropertyOrElement( isolate, receiver, name, Handle::cast(target)); Maybe result = Object::SetSuperProperty( &it, value, SLOPPY, Object::MAY_BE_STORE_FROM_KEYED); MAYBE_RETURN(result, isolate->heap()->exception()); return *isolate->factory()->ToBoolean(result.FromJust()); } // ES6 section 26.1.14 Reflect.setPrototypeOf BUILTIN(ReflectSetPrototypeOf) { HandleScope scope(isolate); DCHECK_EQ(3, args.length()); Handle target = args.at(1); Handle proto = args.at(2); if (!target->IsJSReceiver()) { THROW_NEW_ERROR_RETURN_FAILURE( isolate, NewTypeError(MessageTemplate::kCalledOnNonObject, isolate->factory()->NewStringFromAsciiChecked( "Reflect.setPrototypeOf"))); } if (!proto->IsJSReceiver() && !proto->IsNull()) { THROW_NEW_ERROR_RETURN_FAILURE( isolate, NewTypeError(MessageTemplate::kProtoObjectOrNull, proto)); } Maybe result = JSReceiver::SetPrototype( Handle::cast(target), proto, true, Object::DONT_THROW); MAYBE_RETURN(result, isolate->heap()->exception()); return *isolate->factory()->ToBoolean(result.FromJust()); } // ----------------------------------------------------------------------------- // ES6 section 20.3 Date Objects namespace { // ES6 section 20.3.1.1 Time Values and Time Range const double kMinYear = -1000000.0; const double kMaxYear = -kMinYear; const double kMinMonth = -10000000.0; const double kMaxMonth = -kMinMonth; // 20.3.1.2 Day Number and Time within Day const double kMsPerDay = 86400000.0; // ES6 section 20.3.1.11 Hours, Minutes, Second, and Milliseconds const double kMsPerSecond = 1000.0; const double kMsPerMinute = 60000.0; const double kMsPerHour = 3600000.0; // ES6 section 20.3.1.14 MakeDate (day, time) double MakeDate(double day, double time) { if (std::isfinite(day) && std::isfinite(time)) { return time + day * kMsPerDay; } return std::numeric_limits::quiet_NaN(); } // ES6 section 20.3.1.13 MakeDay (year, month, date) double MakeDay(double year, double month, double date) { if ((kMinYear <= year && year <= kMaxYear) && (kMinMonth <= month && month <= kMaxMonth) && std::isfinite(date)) { int y = FastD2I(year); int m = FastD2I(month); y += m / 12; m %= 12; if (m < 0) { m += 12; y -= 1; } DCHECK_LE(0, m); DCHECK_LT(m, 12); // kYearDelta is an arbitrary number such that: // a) kYearDelta = -1 (mod 400) // b) year + kYearDelta > 0 for years in the range defined by // ECMA 262 - 15.9.1.1, i.e. upto 100,000,000 days on either side of // Jan 1 1970. This is required so that we don't run into integer // division of negative numbers. // c) there shouldn't be an overflow for 32-bit integers in the following // operations. static const int kYearDelta = 399999; static const int kBaseDay = 365 * (1970 + kYearDelta) + (1970 + kYearDelta) / 4 - (1970 + kYearDelta) / 100 + (1970 + kYearDelta) / 400; int day_from_year = 365 * (y + kYearDelta) + (y + kYearDelta) / 4 - (y + kYearDelta) / 100 + (y + kYearDelta) / 400 - kBaseDay; if ((y % 4 != 0) || (y % 100 == 0 && y % 400 != 0)) { static const int kDayFromMonth[] = {0, 31, 59, 90, 120, 151, 181, 212, 243, 273, 304, 334}; day_from_year += kDayFromMonth[m]; } else { static const int kDayFromMonth[] = {0, 31, 60, 91, 121, 152, 182, 213, 244, 274, 305, 335}; day_from_year += kDayFromMonth[m]; } return static_cast(day_from_year - 1) + date; } return std::numeric_limits::quiet_NaN(); } // ES6 section 20.3.1.12 MakeTime (hour, min, sec, ms) double MakeTime(double hour, double min, double sec, double ms) { if (std::isfinite(hour) && std::isfinite(min) && std::isfinite(sec) && std::isfinite(ms)) { double const h = DoubleToInteger(hour); double const m = DoubleToInteger(min); double const s = DoubleToInteger(sec); double const milli = DoubleToInteger(ms); return h * kMsPerHour + m * kMsPerMinute + s * kMsPerSecond + milli; } return std::numeric_limits::quiet_NaN(); } // ES6 section 20.3.1.15 TimeClip (time) double TimeClip(double time) { if (-DateCache::kMaxTimeInMs <= time && time <= DateCache::kMaxTimeInMs) { return DoubleToInteger(time) + 0.0; } return std::numeric_limits::quiet_NaN(); } const char* kShortWeekDays[] = {"Sun", "Mon", "Tue", "Wed", "Thu", "Fri", "Sat"}; const char* kShortMonths[] = {"Jan", "Feb", "Mar", "Apr", "May", "Jun", "Jul", "Aug", "Sep", "Oct", "Nov", "Dec"}; // ES6 section 20.3.1.16 Date Time String Format double ParseDateTimeString(Handle str) { Isolate* const isolate = str->GetIsolate(); str = String::Flatten(str); // TODO(bmeurer): Change DateParser to not use the FixedArray. Handle tmp = isolate->factory()->NewFixedArray(DateParser::OUTPUT_SIZE); DisallowHeapAllocation no_gc; String::FlatContent str_content = str->GetFlatContent(); bool result; if (str_content.IsOneByte()) { result = DateParser::Parse(str_content.ToOneByteVector(), *tmp, isolate->unicode_cache()); } else { result = DateParser::Parse(str_content.ToUC16Vector(), *tmp, isolate->unicode_cache()); } if (!result) return std::numeric_limits::quiet_NaN(); double const day = MakeDay(tmp->get(0)->Number(), tmp->get(1)->Number(), tmp->get(2)->Number()); double const time = MakeTime(tmp->get(3)->Number(), tmp->get(4)->Number(), tmp->get(5)->Number(), tmp->get(6)->Number()); double date = MakeDate(day, time); if (tmp->get(7)->IsNull()) { if (!std::isnan(date)) { date = isolate->date_cache()->ToUTC(static_cast(date)); } } else { date -= tmp->get(7)->Number() * 1000.0; } return date; } enum ToDateStringMode { kDateOnly, kTimeOnly, kDateAndTime }; // ES6 section 20.3.4.41.1 ToDateString(tv) void ToDateString(double time_val, Vector str, DateCache* date_cache, ToDateStringMode mode = kDateAndTime) { if (std::isnan(time_val)) { SNPrintF(str, "Invalid Date"); return; } int64_t time_ms = static_cast(time_val); int64_t local_time_ms = date_cache->ToLocal(time_ms); int year, month, day, weekday, hour, min, sec, ms; date_cache->BreakDownTime(local_time_ms, &year, &month, &day, &weekday, &hour, &min, &sec, &ms); int timezone_offset = -date_cache->TimezoneOffset(time_ms); int timezone_hour = std::abs(timezone_offset) / 60; int timezone_min = std::abs(timezone_offset) % 60; const char* local_timezone = date_cache->LocalTimezone(time_ms); switch (mode) { case kDateOnly: SNPrintF(str, "%s %s %02d %4d", kShortWeekDays[weekday], kShortMonths[month], day, year); return; case kTimeOnly: SNPrintF(str, "%02d:%02d:%02d GMT%c%02d%02d (%s)", hour, min, sec, (timezone_offset < 0) ? '-' : '+', timezone_hour, timezone_min, local_timezone); return; case kDateAndTime: SNPrintF(str, "%s %s %02d %4d %02d:%02d:%02d GMT%c%02d%02d (%s)", kShortWeekDays[weekday], kShortMonths[month], day, year, hour, min, sec, (timezone_offset < 0) ? '-' : '+', timezone_hour, timezone_min, local_timezone); return; } UNREACHABLE(); } Object* SetLocalDateValue(Handle date, double time_val) { if (time_val >= -DateCache::kMaxTimeBeforeUTCInMs && time_val <= DateCache::kMaxTimeBeforeUTCInMs) { Isolate* const isolate = date->GetIsolate(); time_val = isolate->date_cache()->ToUTC(static_cast(time_val)); } else { time_val = std::numeric_limits::quiet_NaN(); } return *JSDate::SetValue(date, TimeClip(time_val)); } } // namespace // ES6 section 20.3.2 The Date Constructor for the [[Call]] case. BUILTIN(DateConstructor) { HandleScope scope(isolate); double const time_val = JSDate::CurrentTimeValue(isolate); char buffer[128]; Vector str(buffer, arraysize(buffer)); ToDateString(time_val, str, isolate->date_cache()); return *isolate->factory()->NewStringFromAsciiChecked(str.start()); } // ES6 section 20.3.2 The Date Constructor for the [[Construct]] case. BUILTIN(DateConstructor_ConstructStub) { HandleScope scope(isolate); int const argc = args.length() - 1; Handle target = args.target(); Handle new_target = Handle::cast(args.new_target()); double time_val; if (argc == 0) { time_val = JSDate::CurrentTimeValue(isolate); } else if (argc == 1) { Handle value = args.at(1); if (value->IsJSDate()) { time_val = Handle::cast(value)->value()->Number(); } else { ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, value, Object::ToPrimitive(value)); if (value->IsString()) { time_val = ParseDateTimeString(Handle::cast(value)); } else { ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, value, Object::ToNumber(value)); time_val = value->Number(); } } } else { Handle year_object; ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, year_object, Object::ToNumber(args.at(1))); Handle month_object; ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, month_object, Object::ToNumber(args.at(2))); double year = year_object->Number(); double month = month_object->Number(); double date = 1.0, hours = 0.0, minutes = 0.0, seconds = 0.0, ms = 0.0; if (argc >= 3) { Handle date_object; ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, date_object, Object::ToNumber(args.at(3))); date = date_object->Number(); if (argc >= 4) { Handle hours_object; ASSIGN_RETURN_FAILURE_ON_EXCEPTION( isolate, hours_object, Object::ToNumber(args.at(4))); hours = hours_object->Number(); if (argc >= 5) { Handle minutes_object; ASSIGN_RETURN_FAILURE_ON_EXCEPTION( isolate, minutes_object, Object::ToNumber(args.at(5))); minutes = minutes_object->Number(); if (argc >= 6) { Handle seconds_object; ASSIGN_RETURN_FAILURE_ON_EXCEPTION( isolate, seconds_object, Object::ToNumber(args.at(6))); seconds = seconds_object->Number(); if (argc >= 7) { Handle ms_object; ASSIGN_RETURN_FAILURE_ON_EXCEPTION( isolate, ms_object, Object::ToNumber(args.at(7))); ms = ms_object->Number(); } } } } } if (!std::isnan(year)) { double const y = DoubleToInteger(year); if (0.0 <= y && y <= 99) year = 1900 + y; } double const day = MakeDay(year, month, date); double const time = MakeTime(hours, minutes, seconds, ms); time_val = MakeDate(day, time); if (time_val >= -DateCache::kMaxTimeBeforeUTCInMs && time_val <= DateCache::kMaxTimeBeforeUTCInMs) { time_val = isolate->date_cache()->ToUTC(static_cast(time_val)); } else { time_val = std::numeric_limits::quiet_NaN(); } } Handle result; ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, result, JSDate::New(target, new_target, time_val)); return *result; } // ES6 section 20.3.3.1 Date.now ( ) BUILTIN(DateNow) { HandleScope scope(isolate); return *isolate->factory()->NewNumber(JSDate::CurrentTimeValue(isolate)); } // ES6 section 20.3.3.2 Date.parse ( string ) BUILTIN(DateParse) { HandleScope scope(isolate); Handle string; ASSIGN_RETURN_FAILURE_ON_EXCEPTION( isolate, string, Object::ToString(isolate, args.atOrUndefined(isolate, 1))); return *isolate->factory()->NewNumber(ParseDateTimeString(string)); } // ES6 section 20.3.3.4 Date.UTC (year,month,date,hours,minutes,seconds,ms) BUILTIN(DateUTC) { HandleScope scope(isolate); int const argc = args.length() - 1; double year = std::numeric_limits::quiet_NaN(); double month = std::numeric_limits::quiet_NaN(); double date = 1.0, hours = 0.0, minutes = 0.0, seconds = 0.0, ms = 0.0; if (argc >= 1) { Handle year_object; ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, year_object, Object::ToNumber(args.at(1))); year = year_object->Number(); if (argc >= 2) { Handle month_object; ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, month_object, Object::ToNumber(args.at(2))); month = month_object->Number(); if (argc >= 3) { Handle date_object; ASSIGN_RETURN_FAILURE_ON_EXCEPTION( isolate, date_object, Object::ToNumber(args.at(3))); date = date_object->Number(); if (argc >= 4) { Handle hours_object; ASSIGN_RETURN_FAILURE_ON_EXCEPTION( isolate, hours_object, Object::ToNumber(args.at(4))); hours = hours_object->Number(); if (argc >= 5) { Handle minutes_object; ASSIGN_RETURN_FAILURE_ON_EXCEPTION( isolate, minutes_object, Object::ToNumber(args.at(5))); minutes = minutes_object->Number(); if (argc >= 6) { Handle seconds_object; ASSIGN_RETURN_FAILURE_ON_EXCEPTION( isolate, seconds_object, Object::ToNumber(args.at(6))); seconds = seconds_object->Number(); if (argc >= 7) { Handle ms_object; ASSIGN_RETURN_FAILURE_ON_EXCEPTION( isolate, ms_object, Object::ToNumber(args.at(7))); ms = ms_object->Number(); } } } } } } } if (!std::isnan(year)) { double const y = DoubleToInteger(year); if (0.0 <= y && y <= 99) year = 1900 + y; } double const day = MakeDay(year, month, date); double const time = MakeTime(hours, minutes, seconds, ms); return *isolate->factory()->NewNumber(TimeClip(MakeDate(day, time))); } // ES6 section 20.3.4.20 Date.prototype.setDate ( date ) BUILTIN(DatePrototypeSetDate) { HandleScope scope(isolate); CHECK_RECEIVER(JSDate, date, "Date.prototype.setDate"); Handle value = args.atOrUndefined(isolate, 1); ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, value, Object::ToNumber(value)); double time_val = date->value()->Number(); if (!std::isnan(time_val)) { int64_t const time_ms = static_cast(time_val); int64_t local_time_ms = isolate->date_cache()->ToLocal(time_ms); int const days = isolate->date_cache()->DaysFromTime(local_time_ms); int time_within_day = isolate->date_cache()->TimeInDay(local_time_ms, days); int year, month, day; isolate->date_cache()->YearMonthDayFromDays(days, &year, &month, &day); time_val = MakeDate(MakeDay(year, month, value->Number()), time_within_day); } return SetLocalDateValue(date, time_val); } // ES6 section 20.3.4.21 Date.prototype.setFullYear (year, month, date) BUILTIN(DatePrototypeSetFullYear) { HandleScope scope(isolate); CHECK_RECEIVER(JSDate, date, "Date.prototype.setFullYear"); int const argc = args.length() - 1; Handle year = args.atOrUndefined(isolate, 1); ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, year, Object::ToNumber(year)); double y = year->Number(), m = 0.0, dt = 1.0; int time_within_day = 0; if (!std::isnan(date->value()->Number())) { int64_t const time_ms = static_cast(date->value()->Number()); int64_t local_time_ms = isolate->date_cache()->ToLocal(time_ms); int const days = isolate->date_cache()->DaysFromTime(local_time_ms); time_within_day = isolate->date_cache()->TimeInDay(local_time_ms, days); int year, month, day; isolate->date_cache()->YearMonthDayFromDays(days, &year, &month, &day); m = month; dt = day; } if (argc >= 2) { Handle month = args.at(2); ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, month, Object::ToNumber(month)); m = month->Number(); if (argc >= 3) { Handle date = args.at(3); ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, date, Object::ToNumber(date)); dt = date->Number(); } } double time_val = MakeDate(MakeDay(y, m, dt), time_within_day); return SetLocalDateValue(date, time_val); } // ES6 section 20.3.4.22 Date.prototype.setHours(hour, min, sec, ms) BUILTIN(DatePrototypeSetHours) { HandleScope scope(isolate); CHECK_RECEIVER(JSDate, date, "Date.prototype.setHours"); int const argc = args.length() - 1; Handle hour = args.atOrUndefined(isolate, 1); ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, hour, Object::ToNumber(hour)); double h = hour->Number(); double time_val = date->value()->Number(); if (!std::isnan(time_val)) { int64_t const time_ms = static_cast(time_val); int64_t local_time_ms = isolate->date_cache()->ToLocal(time_ms); int day = isolate->date_cache()->DaysFromTime(local_time_ms); int time_within_day = isolate->date_cache()->TimeInDay(local_time_ms, day); double m = (time_within_day / (60 * 1000)) % 60; double s = (time_within_day / 1000) % 60; double milli = time_within_day % 1000; if (argc >= 2) { Handle min = args.at(2); ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, min, Object::ToNumber(min)); m = min->Number(); if (argc >= 3) { Handle sec = args.at(3); ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, sec, Object::ToNumber(sec)); s = sec->Number(); if (argc >= 4) { Handle ms = args.at(4); ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, ms, Object::ToNumber(ms)); milli = ms->Number(); } } } time_val = MakeDate(day, MakeTime(h, m, s, milli)); } return SetLocalDateValue(date, time_val); } // ES6 section 20.3.4.23 Date.prototype.setMilliseconds(ms) BUILTIN(DatePrototypeSetMilliseconds) { HandleScope scope(isolate); CHECK_RECEIVER(JSDate, date, "Date.prototype.setMilliseconds"); Handle ms = args.atOrUndefined(isolate, 1); ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, ms, Object::ToNumber(ms)); double time_val = date->value()->Number(); if (!std::isnan(time_val)) { int64_t const time_ms = static_cast(time_val); int64_t local_time_ms = isolate->date_cache()->ToLocal(time_ms); int day = isolate->date_cache()->DaysFromTime(local_time_ms); int time_within_day = isolate->date_cache()->TimeInDay(local_time_ms, day); int h = time_within_day / (60 * 60 * 1000); int m = (time_within_day / (60 * 1000)) % 60; int s = (time_within_day / 1000) % 60; time_val = MakeDate(day, MakeTime(h, m, s, ms->Number())); } return SetLocalDateValue(date, time_val); } // ES6 section 20.3.4.24 Date.prototype.setMinutes ( min, sec, ms ) BUILTIN(DatePrototypeSetMinutes) { HandleScope scope(isolate); CHECK_RECEIVER(JSDate, date, "Date.prototype.setMinutes"); int const argc = args.length() - 1; Handle min = args.atOrUndefined(isolate, 1); ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, min, Object::ToNumber(min)); double time_val = date->value()->Number(); if (!std::isnan(time_val)) { int64_t const time_ms = static_cast(time_val); int64_t local_time_ms = isolate->date_cache()->ToLocal(time_ms); int day = isolate->date_cache()->DaysFromTime(local_time_ms); int time_within_day = isolate->date_cache()->TimeInDay(local_time_ms, day); int h = time_within_day / (60 * 60 * 1000); double m = min->Number(); double s = (time_within_day / 1000) % 60; double milli = time_within_day % 1000; if (argc >= 2) { Handle sec = args.at(2); ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, sec, Object::ToNumber(sec)); s = sec->Number(); if (argc >= 3) { Handle ms = args.at(3); ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, ms, Object::ToNumber(ms)); milli = ms->Number(); } } time_val = MakeDate(day, MakeTime(h, m, s, milli)); } return SetLocalDateValue(date, time_val); } // ES6 section 20.3.4.25 Date.prototype.setMonth ( month, date ) BUILTIN(DatePrototypeSetMonth) { HandleScope scope(isolate); CHECK_RECEIVER(JSDate, date, "Date.prototype.setMonth"); int const argc = args.length() - 1; Handle month = args.atOrUndefined(isolate, 1); ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, month, Object::ToNumber(month)); double time_val = date->value()->Number(); if (!std::isnan(time_val)) { int64_t const time_ms = static_cast(time_val); int64_t local_time_ms = isolate->date_cache()->ToLocal(time_ms); int days = isolate->date_cache()->DaysFromTime(local_time_ms); int time_within_day = isolate->date_cache()->TimeInDay(local_time_ms, days); int year, unused, day; isolate->date_cache()->YearMonthDayFromDays(days, &year, &unused, &day); double m = month->Number(); double dt = day; if (argc >= 2) { Handle date = args.at(2); ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, date, Object::ToNumber(date)); dt = date->Number(); } time_val = MakeDate(MakeDay(year, m, dt), time_within_day); } return SetLocalDateValue(date, time_val); } // ES6 section 20.3.4.26 Date.prototype.setSeconds ( sec, ms ) BUILTIN(DatePrototypeSetSeconds) { HandleScope scope(isolate); CHECK_RECEIVER(JSDate, date, "Date.prototype.setSeconds"); int const argc = args.length() - 1; Handle sec = args.atOrUndefined(isolate, 1); ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, sec, Object::ToNumber(sec)); double time_val = date->value()->Number(); if (!std::isnan(time_val)) { int64_t const time_ms = static_cast(time_val); int64_t local_time_ms = isolate->date_cache()->ToLocal(time_ms); int day = isolate->date_cache()->DaysFromTime(local_time_ms); int time_within_day = isolate->date_cache()->TimeInDay(local_time_ms, day); int h = time_within_day / (60 * 60 * 1000); double m = (time_within_day / (60 * 1000)) % 60; double s = sec->Number(); double milli = time_within_day % 1000; if (argc >= 2) { Handle ms = args.at(2); ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, ms, Object::ToNumber(ms)); milli = ms->Number(); } time_val = MakeDate(day, MakeTime(h, m, s, milli)); } return SetLocalDateValue(date, time_val); } // ES6 section 20.3.4.27 Date.prototype.setTime ( time ) BUILTIN(DatePrototypeSetTime) { HandleScope scope(isolate); CHECK_RECEIVER(JSDate, date, "Date.prototype.setTime"); Handle value = args.atOrUndefined(isolate, 1); ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, value, Object::ToNumber(value)); return *JSDate::SetValue(date, TimeClip(value->Number())); } // ES6 section 20.3.4.28 Date.prototype.setUTCDate ( date ) BUILTIN(DatePrototypeSetUTCDate) { HandleScope scope(isolate); CHECK_RECEIVER(JSDate, date, "Date.prototype.setUTCDate"); Handle value = args.atOrUndefined(isolate, 1); ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, value, Object::ToNumber(value)); if (std::isnan(date->value()->Number())) return date->value(); int64_t const time_ms = static_cast(date->value()->Number()); int const days = isolate->date_cache()->DaysFromTime(time_ms); int const time_within_day = isolate->date_cache()->TimeInDay(time_ms, days); int year, month, day; isolate->date_cache()->YearMonthDayFromDays(days, &year, &month, &day); double const time_val = MakeDate(MakeDay(year, month, value->Number()), time_within_day); return *JSDate::SetValue(date, TimeClip(time_val)); } // ES6 section 20.3.4.29 Date.prototype.setUTCFullYear (year, month, date) BUILTIN(DatePrototypeSetUTCFullYear) { HandleScope scope(isolate); CHECK_RECEIVER(JSDate, date, "Date.prototype.setUTCFullYear"); int const argc = args.length() - 1; Handle year = args.atOrUndefined(isolate, 1); ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, year, Object::ToNumber(year)); double y = year->Number(), m = 0.0, dt = 1.0; int time_within_day = 0; if (!std::isnan(date->value()->Number())) { int64_t const time_ms = static_cast(date->value()->Number()); int const days = isolate->date_cache()->DaysFromTime(time_ms); time_within_day = isolate->date_cache()->TimeInDay(time_ms, days); int year, month, day; isolate->date_cache()->YearMonthDayFromDays(days, &year, &month, &day); m = month; dt = day; } if (argc >= 2) { Handle month = args.at(2); ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, month, Object::ToNumber(month)); m = month->Number(); if (argc >= 3) { Handle date = args.at(3); ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, date, Object::ToNumber(date)); dt = date->Number(); } } double const time_val = MakeDate(MakeDay(y, m, dt), time_within_day); return *JSDate::SetValue(date, TimeClip(time_val)); } // ES6 section 20.3.4.30 Date.prototype.setUTCHours(hour, min, sec, ms) BUILTIN(DatePrototypeSetUTCHours) { HandleScope scope(isolate); CHECK_RECEIVER(JSDate, date, "Date.prototype.setUTCHours"); int const argc = args.length() - 1; Handle hour = args.atOrUndefined(isolate, 1); ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, hour, Object::ToNumber(hour)); double h = hour->Number(); double time_val = date->value()->Number(); if (!std::isnan(time_val)) { int64_t const time_ms = static_cast(time_val); int day = isolate->date_cache()->DaysFromTime(time_ms); int time_within_day = isolate->date_cache()->TimeInDay(time_ms, day); double m = (time_within_day / (60 * 1000)) % 60; double s = (time_within_day / 1000) % 60; double milli = time_within_day % 1000; if (argc >= 2) { Handle min = args.at(2); ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, min, Object::ToNumber(min)); m = min->Number(); if (argc >= 3) { Handle sec = args.at(3); ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, sec, Object::ToNumber(sec)); s = sec->Number(); if (argc >= 4) { Handle ms = args.at(4); ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, ms, Object::ToNumber(ms)); milli = ms->Number(); } } } time_val = MakeDate(day, MakeTime(h, m, s, milli)); } return *JSDate::SetValue(date, TimeClip(time_val)); } // ES6 section 20.3.4.31 Date.prototype.setUTCMilliseconds(ms) BUILTIN(DatePrototypeSetUTCMilliseconds) { HandleScope scope(isolate); CHECK_RECEIVER(JSDate, date, "Date.prototype.setUTCMilliseconds"); Handle ms = args.atOrUndefined(isolate, 1); ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, ms, Object::ToNumber(ms)); double time_val = date->value()->Number(); if (!std::isnan(time_val)) { int64_t const time_ms = static_cast(time_val); int day = isolate->date_cache()->DaysFromTime(time_ms); int time_within_day = isolate->date_cache()->TimeInDay(time_ms, day); int h = time_within_day / (60 * 60 * 1000); int m = (time_within_day / (60 * 1000)) % 60; int s = (time_within_day / 1000) % 60; time_val = MakeDate(day, MakeTime(h, m, s, ms->Number())); } return *JSDate::SetValue(date, TimeClip(time_val)); } // ES6 section 20.3.4.32 Date.prototype.setUTCMinutes ( min, sec, ms ) BUILTIN(DatePrototypeSetUTCMinutes) { HandleScope scope(isolate); CHECK_RECEIVER(JSDate, date, "Date.prototype.setUTCMinutes"); int const argc = args.length() - 1; Handle min = args.atOrUndefined(isolate, 1); ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, min, Object::ToNumber(min)); double time_val = date->value()->Number(); if (!std::isnan(time_val)) { int64_t const time_ms = static_cast(time_val); int day = isolate->date_cache()->DaysFromTime(time_ms); int time_within_day = isolate->date_cache()->TimeInDay(time_ms, day); int h = time_within_day / (60 * 60 * 1000); double m = min->Number(); double s = (time_within_day / 1000) % 60; double milli = time_within_day % 1000; if (argc >= 2) { Handle sec = args.at(2); ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, sec, Object::ToNumber(sec)); s = sec->Number(); if (argc >= 3) { Handle ms = args.at(3); ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, ms, Object::ToNumber(ms)); milli = ms->Number(); } } time_val = MakeDate(day, MakeTime(h, m, s, milli)); } return *JSDate::SetValue(date, TimeClip(time_val)); } // ES6 section 20.3.4.31 Date.prototype.setUTCMonth ( month, date ) BUILTIN(DatePrototypeSetUTCMonth) { HandleScope scope(isolate); CHECK_RECEIVER(JSDate, date, "Date.prototype.setUTCMonth"); int const argc = args.length() - 1; Handle month = args.atOrUndefined(isolate, 1); ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, month, Object::ToNumber(month)); double time_val = date->value()->Number(); if (!std::isnan(time_val)) { int64_t const time_ms = static_cast(time_val); int days = isolate->date_cache()->DaysFromTime(time_ms); int time_within_day = isolate->date_cache()->TimeInDay(time_ms, days); int year, unused, day; isolate->date_cache()->YearMonthDayFromDays(days, &year, &unused, &day); double m = month->Number(); double dt = day; if (argc >= 2) { Handle date = args.at(2); ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, date, Object::ToNumber(date)); dt = date->Number(); } time_val = MakeDate(MakeDay(year, m, dt), time_within_day); } return *JSDate::SetValue(date, TimeClip(time_val)); } // ES6 section 20.3.4.34 Date.prototype.setUTCSeconds ( sec, ms ) BUILTIN(DatePrototypeSetUTCSeconds) { HandleScope scope(isolate); CHECK_RECEIVER(JSDate, date, "Date.prototype.setUTCSeconds"); int const argc = args.length() - 1; Handle sec = args.atOrUndefined(isolate, 1); ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, sec, Object::ToNumber(sec)); double time_val = date->value()->Number(); if (!std::isnan(time_val)) { int64_t const time_ms = static_cast(time_val); int day = isolate->date_cache()->DaysFromTime(time_ms); int time_within_day = isolate->date_cache()->TimeInDay(time_ms, day); int h = time_within_day / (60 * 60 * 1000); double m = (time_within_day / (60 * 1000)) % 60; double s = sec->Number(); double milli = time_within_day % 1000; if (argc >= 2) { Handle ms = args.at(2); ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, ms, Object::ToNumber(ms)); milli = ms->Number(); } time_val = MakeDate(day, MakeTime(h, m, s, milli)); } return *JSDate::SetValue(date, TimeClip(time_val)); } // ES6 section 20.3.4.35 Date.prototype.toDateString ( ) BUILTIN(DatePrototypeToDateString) { HandleScope scope(isolate); CHECK_RECEIVER(JSDate, date, "Date.prototype.toDateString"); char buffer[128]; Vector str(buffer, arraysize(buffer)); ToDateString(date->value()->Number(), str, isolate->date_cache(), kDateOnly); return *isolate->factory()->NewStringFromAsciiChecked(str.start()); } // ES6 section 20.3.4.36 Date.prototype.toISOString ( ) BUILTIN(DatePrototypeToISOString) { HandleScope scope(isolate); CHECK_RECEIVER(JSDate, date, "Date.prototype.toISOString"); double const time_val = date->value()->Number(); if (std::isnan(time_val)) { THROW_NEW_ERROR_RETURN_FAILURE( isolate, NewRangeError(MessageTemplate::kInvalidTimeValue)); } int64_t const time_ms = static_cast(time_val); int year, month, day, weekday, hour, min, sec, ms; isolate->date_cache()->BreakDownTime(time_ms, &year, &month, &day, &weekday, &hour, &min, &sec, &ms); char buffer[128]; Vector str(buffer, arraysize(buffer)); if (year >= 0 && year <= 9999) { SNPrintF(str, "%04d-%02d-%02dT%02d:%02d:%02d.%03dZ", year, month + 1, day, hour, min, sec, ms); } else if (year < 0) { SNPrintF(str, "-%06d-%02d-%02dT%02d:%02d:%02d.%03dZ", -year, month + 1, day, hour, min, sec, ms); } else { SNPrintF(str, "+%06d-%02d-%02dT%02d:%02d:%02d.%03dZ", year, month + 1, day, hour, min, sec, ms); } return *isolate->factory()->NewStringFromAsciiChecked(str.start()); } // ES6 section 20.3.4.41 Date.prototype.toString ( ) BUILTIN(DatePrototypeToString) { HandleScope scope(isolate); CHECK_RECEIVER(JSDate, date, "Date.prototype.toString"); char buffer[128]; Vector str(buffer, arraysize(buffer)); ToDateString(date->value()->Number(), str, isolate->date_cache()); return *isolate->factory()->NewStringFromAsciiChecked(str.start()); } // ES6 section 20.3.4.42 Date.prototype.toTimeString ( ) BUILTIN(DatePrototypeToTimeString) { HandleScope scope(isolate); CHECK_RECEIVER(JSDate, date, "Date.prototype.toTimeString"); char buffer[128]; Vector str(buffer, arraysize(buffer)); ToDateString(date->value()->Number(), str, isolate->date_cache(), kTimeOnly); return *isolate->factory()->NewStringFromAsciiChecked(str.start()); } // ES6 section 20.3.4.43 Date.prototype.toUTCString ( ) BUILTIN(DatePrototypeToUTCString) { HandleScope scope(isolate); CHECK_RECEIVER(JSDate, date, "Date.prototype.toUTCString"); double const time_val = date->value()->Number(); if (std::isnan(time_val)) { return *isolate->factory()->NewStringFromAsciiChecked("Invalid Date"); } char buffer[128]; Vector str(buffer, arraysize(buffer)); int64_t time_ms = static_cast(time_val); int year, month, day, weekday, hour, min, sec, ms; isolate->date_cache()->BreakDownTime(time_ms, &year, &month, &day, &weekday, &hour, &min, &sec, &ms); SNPrintF(str, "%s, %02d %s %4d %02d:%02d:%02d GMT", kShortWeekDays[weekday], day, kShortMonths[month], year, hour, min, sec); return *isolate->factory()->NewStringFromAsciiChecked(str.start()); } // ES6 section 20.3.4.44 Date.prototype.valueOf ( ) BUILTIN(DatePrototypeValueOf) { HandleScope scope(isolate); CHECK_RECEIVER(JSDate, date, "Date.prototype.valueOf"); return date->value(); } // ES6 section 20.3.4.45 Date.prototype [ @@toPrimitive ] ( hint ) BUILTIN(DatePrototypeToPrimitive) { HandleScope scope(isolate); DCHECK_EQ(2, args.length()); CHECK_RECEIVER(JSReceiver, receiver, "Date.prototype [ @@toPrimitive ]"); Handle hint = args.at(1); Handle result; ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, result, JSDate::ToPrimitive(receiver, hint)); return *result; } // ES6 section B.2.4.1 Date.prototype.getYear ( ) BUILTIN(DatePrototypeGetYear) { HandleScope scope(isolate); CHECK_RECEIVER(JSDate, date, "Date.prototype.getYear"); double time_val = date->value()->Number(); if (std::isnan(time_val)) return date->value(); int64_t time_ms = static_cast(time_val); int64_t local_time_ms = isolate->date_cache()->ToLocal(time_ms); int days = isolate->date_cache()->DaysFromTime(local_time_ms); int year, month, day; isolate->date_cache()->YearMonthDayFromDays(days, &year, &month, &day); return Smi::FromInt(year - 1900); } // ES6 section B.2.4.2 Date.prototype.setYear ( year ) BUILTIN(DatePrototypeSetYear) { HandleScope scope(isolate); CHECK_RECEIVER(JSDate, date, "Date.prototype.setYear"); Handle year = args.atOrUndefined(isolate, 1); ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, year, Object::ToNumber(year)); double m = 0.0, dt = 1.0, y = year->Number(); if (0.0 <= y && y <= 99.0) { y = 1900.0 + DoubleToInteger(y); } int time_within_day = 0; if (!std::isnan(date->value()->Number())) { int64_t const time_ms = static_cast(date->value()->Number()); int64_t local_time_ms = isolate->date_cache()->ToLocal(time_ms); int const days = isolate->date_cache()->DaysFromTime(local_time_ms); time_within_day = isolate->date_cache()->TimeInDay(local_time_ms, days); int year, month, day; isolate->date_cache()->YearMonthDayFromDays(days, &year, &month, &day); m = month; dt = day; } double time_val = MakeDate(MakeDay(y, m, dt), time_within_day); return SetLocalDateValue(date, time_val); } // static void Builtins::Generate_DatePrototypeGetDate(MacroAssembler* masm) { Generate_DatePrototype_GetField(masm, JSDate::kDay); } // static void Builtins::Generate_DatePrototypeGetDay(MacroAssembler* masm) { Generate_DatePrototype_GetField(masm, JSDate::kWeekday); } // static void Builtins::Generate_DatePrototypeGetFullYear(MacroAssembler* masm) { Generate_DatePrototype_GetField(masm, JSDate::kYear); } // static void Builtins::Generate_DatePrototypeGetHours(MacroAssembler* masm) { Generate_DatePrototype_GetField(masm, JSDate::kHour); } // static void Builtins::Generate_DatePrototypeGetMilliseconds(MacroAssembler* masm) { Generate_DatePrototype_GetField(masm, JSDate::kMillisecond); } // static void Builtins::Generate_DatePrototypeGetMinutes(MacroAssembler* masm) { Generate_DatePrototype_GetField(masm, JSDate::kMinute); } // static void Builtins::Generate_DatePrototypeGetMonth(MacroAssembler* masm) { Generate_DatePrototype_GetField(masm, JSDate::kMonth); } // static void Builtins::Generate_DatePrototypeGetSeconds(MacroAssembler* masm) { Generate_DatePrototype_GetField(masm, JSDate::kSecond); } // static void Builtins::Generate_DatePrototypeGetTime(MacroAssembler* masm) { Generate_DatePrototype_GetField(masm, JSDate::kDateValue); } // static void Builtins::Generate_DatePrototypeGetTimezoneOffset(MacroAssembler* masm) { Generate_DatePrototype_GetField(masm, JSDate::kTimezoneOffset); } // static void Builtins::Generate_DatePrototypeGetUTCDate(MacroAssembler* masm) { Generate_DatePrototype_GetField(masm, JSDate::kDayUTC); } // static void Builtins::Generate_DatePrototypeGetUTCDay(MacroAssembler* masm) { Generate_DatePrototype_GetField(masm, JSDate::kWeekdayUTC); } // static void Builtins::Generate_DatePrototypeGetUTCFullYear(MacroAssembler* masm) { Generate_DatePrototype_GetField(masm, JSDate::kYearUTC); } // static void Builtins::Generate_DatePrototypeGetUTCHours(MacroAssembler* masm) { Generate_DatePrototype_GetField(masm, JSDate::kHourUTC); } // static void Builtins::Generate_DatePrototypeGetUTCMilliseconds(MacroAssembler* masm) { Generate_DatePrototype_GetField(masm, JSDate::kMillisecondUTC); } // static void Builtins::Generate_DatePrototypeGetUTCMinutes(MacroAssembler* masm) { Generate_DatePrototype_GetField(masm, JSDate::kMinuteUTC); } // static void Builtins::Generate_DatePrototypeGetUTCMonth(MacroAssembler* masm) { Generate_DatePrototype_GetField(masm, JSDate::kMonthUTC); } // static void Builtins::Generate_DatePrototypeGetUTCSeconds(MacroAssembler* masm) { Generate_DatePrototype_GetField(masm, JSDate::kSecondUTC); } namespace { // ES6 section 19.2.1.1.1 CreateDynamicFunction MaybeHandle CreateDynamicFunction( Isolate* isolate, BuiltinArguments args, const char* token) { // Compute number of arguments, ignoring the receiver. DCHECK_LE(1, args.length()); int const argc = args.length() - 1; // Build the source string. Handle source; { IncrementalStringBuilder builder(isolate); builder.AppendCharacter('('); builder.AppendCString(token); builder.AppendCharacter('('); bool parenthesis_in_arg_string = false; if (argc > 1) { for (int i = 1; i < argc; ++i) { if (i > 1) builder.AppendCharacter(','); Handle param; ASSIGN_RETURN_ON_EXCEPTION( isolate, param, Object::ToString(isolate, args.at(i)), JSFunction); param = String::Flatten(param); builder.AppendString(param); // If the formal parameters string include ) - an illegal // character - it may make the combined function expression // compile. We avoid this problem by checking for this early on. DisallowHeapAllocation no_gc; // Ensure vectors stay valid. String::FlatContent param_content = param->GetFlatContent(); for (int i = 0, length = param->length(); i < length; ++i) { if (param_content.Get(i) == ')') { parenthesis_in_arg_string = true; break; } } } // If the formal parameters include an unbalanced block comment, the // function must be rejected. Since JavaScript does not allow nested // comments we can include a trailing block comment to catch this. builder.AppendCString("\n/**/"); } builder.AppendCString(") {\n"); if (argc > 0) { Handle body; ASSIGN_RETURN_ON_EXCEPTION( isolate, body, Object::ToString(isolate, args.at(argc)), JSFunction); builder.AppendString(body); } builder.AppendCString("\n})"); ASSIGN_RETURN_ON_EXCEPTION(isolate, source, builder.Finish(), JSFunction); // The SyntaxError must be thrown after all the (observable) ToString // conversions are done. if (parenthesis_in_arg_string) { THROW_NEW_ERROR(isolate, NewSyntaxError(MessageTemplate::kParenthesisInArgString), JSFunction); } } // Compile the string in the constructor and not a helper so that errors to // come from here. Handle target = args.target(); Handle target_global_proxy(target->global_proxy(), isolate); Handle function; { ASSIGN_RETURN_ON_EXCEPTION( isolate, function, CompileString(handle(target->native_context(), isolate), source, ONLY_SINGLE_FUNCTION_LITERAL), JSFunction); Handle result; ASSIGN_RETURN_ON_EXCEPTION( isolate, result, Execution::Call(isolate, function, target_global_proxy, 0, nullptr), JSFunction); function = Handle::cast(result); function->shared()->set_name_should_print_as_anonymous(true); } // If new.target is equal to target then the function created // is already correctly setup and nothing else should be done // here. But if new.target is not equal to target then we are // have a Function builtin subclassing case and therefore the // function has wrong initial map. To fix that we create a new // function object with correct initial map. Handle unchecked_new_target = args.new_target(); if (!unchecked_new_target->IsUndefined() && !unchecked_new_target.is_identical_to(target)) { Handle new_target = Handle::cast(unchecked_new_target); Handle initial_map; ASSIGN_RETURN_ON_EXCEPTION( isolate, initial_map, JSFunction::GetDerivedMap(isolate, target, new_target), JSFunction); Handle shared_info(function->shared(), isolate); Handle map = Map::AsLanguageMode( initial_map, shared_info->language_mode(), shared_info->kind()); Handle context(function->context(), isolate); function = isolate->factory()->NewFunctionFromSharedFunctionInfo( map, shared_info, context, NOT_TENURED); } return function; } } // namespace // ES6 section 19.2.1.1 Function ( p1, p2, ... , pn, body ) BUILTIN(FunctionConstructor) { HandleScope scope(isolate); Handle result; ASSIGN_RETURN_FAILURE_ON_EXCEPTION( isolate, result, CreateDynamicFunction(isolate, args, "function")); return *result; } // ES6 section 19.2.3.2 Function.prototype.bind ( thisArg, ...args ) BUILTIN(FunctionPrototypeBind) { HandleScope scope(isolate); DCHECK_LE(1, args.length()); if (!args.receiver()->IsCallable()) { THROW_NEW_ERROR_RETURN_FAILURE( isolate, NewTypeError(MessageTemplate::kFunctionBind)); } // Allocate the bound function with the given {this_arg} and {args}. Handle target = args.at(0); Handle this_arg = isolate->factory()->undefined_value(); ScopedVector> argv(std::max(0, args.length() - 2)); if (args.length() > 1) { this_arg = args.at(1); for (int i = 2; i < args.length(); ++i) { argv[i - 2] = args.at(i); } } Handle function; ASSIGN_RETURN_FAILURE_ON_EXCEPTION( isolate, function, isolate->factory()->NewJSBoundFunction(target, this_arg, argv)); // TODO(bmeurer): Optimize the rest for the common cases where {target} is // a function with some initial map or even a bound function. // Setup the "length" property based on the "length" of the {target}. Handle length(Smi::FromInt(0), isolate); Maybe target_has_length = JSReceiver::HasOwnProperty(target, isolate->factory()->length_string()); if (!target_has_length.IsJust()) { return isolate->heap()->exception(); } else if (target_has_length.FromJust()) { Handle target_length; ASSIGN_RETURN_FAILURE_ON_EXCEPTION( isolate, target_length, JSReceiver::GetProperty(target, isolate->factory()->length_string())); if (target_length->IsNumber()) { length = isolate->factory()->NewNumber(std::max( 0.0, DoubleToInteger(target_length->Number()) - argv.length())); } } function->set_length(*length); // Setup the "name" property based on the "name" of the {target}. Handle target_name; ASSIGN_RETURN_FAILURE_ON_EXCEPTION( isolate, target_name, JSReceiver::GetProperty(target, isolate->factory()->name_string())); Handle name; if (!target_name->IsString()) { name = isolate->factory()->bound__string(); } else { ASSIGN_RETURN_FAILURE_ON_EXCEPTION( isolate, name, Name::ToFunctionName(Handle::cast(target_name))); ASSIGN_RETURN_FAILURE_ON_EXCEPTION( isolate, name, isolate->factory()->NewConsString( isolate->factory()->bound__string(), name)); } function->set_name(*name); return *function; } // ES6 section 19.2.3.5 Function.prototype.toString ( ) BUILTIN(FunctionPrototypeToString) { HandleScope scope(isolate); Handle receiver = args.receiver(); if (receiver->IsJSBoundFunction()) { return *JSBoundFunction::ToString(Handle::cast(receiver)); } else if (receiver->IsJSFunction()) { return *JSFunction::ToString(Handle::cast(receiver)); } THROW_NEW_ERROR_RETURN_FAILURE( isolate, NewTypeError(MessageTemplate::kNotGeneric, isolate->factory()->NewStringFromAsciiChecked( "Function.prototype.toString"))); } // ES6 section 25.2.1.1 GeneratorFunction (p1, p2, ... , pn, body) BUILTIN(GeneratorFunctionConstructor) { HandleScope scope(isolate); Handle result; ASSIGN_RETURN_FAILURE_ON_EXCEPTION( isolate, result, CreateDynamicFunction(isolate, args, "function*")); return *result; } // ES6 section 19.4.1.1 Symbol ( [ description ] ) for the [[Call]] case. BUILTIN(SymbolConstructor) { HandleScope scope(isolate); Handle result = isolate->factory()->NewSymbol(); Handle description = args.atOrUndefined(isolate, 1); if (!description->IsUndefined()) { ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, description, Object::ToString(isolate, description)); result->set_name(*description); } return *result; } // ES6 section 19.4.1.1 Symbol ( [ description ] ) for the [[Construct]] case. BUILTIN(SymbolConstructor_ConstructStub) { HandleScope scope(isolate); THROW_NEW_ERROR_RETURN_FAILURE( isolate, NewTypeError(MessageTemplate::kNotConstructor, isolate->factory()->Symbol_string())); } // ES6 19.1.3.6 Object.prototype.toString BUILTIN(ObjectProtoToString) { HandleScope scope(isolate); Handle object = args.at(0); Handle result; ASSIGN_RETURN_FAILURE_ON_EXCEPTION( isolate, result, JSObject::ObjectProtoToString(isolate, object)); return *result; } // ES6 section 24.1.2.1 ArrayBuffer ( length ) for the [[Call]] case. BUILTIN(ArrayBufferConstructor) { HandleScope scope(isolate); Handle target = args.target(); DCHECK(*target == target->native_context()->array_buffer_fun() || *target == target->native_context()->shared_array_buffer_fun()); THROW_NEW_ERROR_RETURN_FAILURE( isolate, NewTypeError(MessageTemplate::kConstructorNotFunction, handle(target->shared()->name(), isolate))); } // ES6 section 24.1.2.1 ArrayBuffer ( length ) for the [[Construct]] case. BUILTIN(ArrayBufferConstructor_ConstructStub) { HandleScope scope(isolate); Handle target = args.target(); Handle new_target = Handle::cast(args.new_target()); Handle length = args.atOrUndefined(isolate, 1); DCHECK(*target == target->native_context()->array_buffer_fun() || *target == target->native_context()->shared_array_buffer_fun()); Handle number_length; ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, number_length, Object::ToInteger(isolate, length)); if (number_length->Number() < 0.0) { THROW_NEW_ERROR_RETURN_FAILURE( isolate, NewRangeError(MessageTemplate::kInvalidArrayBufferLength)); } Handle initial_map; ASSIGN_RETURN_FAILURE_ON_EXCEPTION( isolate, initial_map, JSFunction::GetDerivedMap(isolate, target, new_target)); size_t byte_length; if (!TryNumberToSize(isolate, *number_length, &byte_length)) { THROW_NEW_ERROR_RETURN_FAILURE( isolate, NewRangeError(MessageTemplate::kInvalidArrayBufferLength)); } Handle result = Handle::cast( isolate->factory()->NewJSObjectFromMap(initial_map)); SharedFlag shared_flag = (*target == target->native_context()->array_buffer_fun()) ? SharedFlag::kNotShared : SharedFlag::kShared; if (!JSArrayBuffer::SetupAllocatingData(result, isolate, byte_length, true, shared_flag)) { THROW_NEW_ERROR_RETURN_FAILURE( isolate, NewRangeError(MessageTemplate::kArrayBufferAllocationFailed)); } return *result; } // ES6 section 24.1.3.1 ArrayBuffer.isView ( arg ) BUILTIN(ArrayBufferIsView) { SealHandleScope shs(isolate); DCHECK_EQ(2, args.length()); Object* arg = args[1]; return isolate->heap()->ToBoolean(arg->IsJSArrayBufferView()); } // ES6 section 26.2.1.1 Proxy ( target, handler ) for the [[Call]] case. BUILTIN(ProxyConstructor) { HandleScope scope(isolate); THROW_NEW_ERROR_RETURN_FAILURE( isolate, NewTypeError(MessageTemplate::kConstructorNotFunction, isolate->factory()->NewStringFromAsciiChecked("Proxy"))); } // ES6 section 26.2.1.1 Proxy ( target, handler ) for the [[Construct]] case. BUILTIN(ProxyConstructor_ConstructStub) { HandleScope scope(isolate); DCHECK(isolate->proxy_function()->IsConstructor()); Handle target = args.atOrUndefined(isolate, 1); Handle handler = args.atOrUndefined(isolate, 2); Handle result; ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, result, JSProxy::New(isolate, target, handler)); return *result; } // ----------------------------------------------------------------------------- // Throwers for restricted function properties and strict arguments object // properties BUILTIN(RestrictedFunctionPropertiesThrower) { HandleScope scope(isolate); THROW_NEW_ERROR_RETURN_FAILURE( isolate, NewTypeError(MessageTemplate::kRestrictedFunctionProperties)); } BUILTIN(RestrictedStrictArgumentsPropertiesThrower) { HandleScope scope(isolate); THROW_NEW_ERROR_RETURN_FAILURE( isolate, NewTypeError(MessageTemplate::kStrictPoisonPill)); } // ----------------------------------------------------------------------------- // namespace { template MUST_USE_RESULT MaybeHandle HandleApiCallHelper( Isolate* isolate, BuiltinArguments args) { HandleScope scope(isolate); Handle function = args.target(); DCHECK(args.receiver()->IsJSReceiver()); // TODO(ishell): turn this back to a DCHECK. CHECK(function->shared()->IsApiFunction()); Handle fun_data( function->shared()->get_api_func_data(), isolate); if (is_construct) { ASSIGN_RETURN_ON_EXCEPTION( isolate, fun_data, ApiNatives::ConfigureInstance(isolate, fun_data, Handle::cast(args.receiver())), Object); } if (!is_construct && !fun_data->accept_any_receiver()) { Handle receiver = args.at(0); if (receiver->IsJSObject() && receiver->IsAccessCheckNeeded()) { Handle js_receiver = Handle::cast(receiver); if (!isolate->MayAccess(handle(isolate->context()), js_receiver)) { isolate->ReportFailedAccessCheck(js_receiver); RETURN_EXCEPTION_IF_SCHEDULED_EXCEPTION(isolate, Object); } } } Object* raw_holder = fun_data->GetCompatibleReceiver(isolate, args[0]); if (raw_holder->IsNull()) { // This function cannot be called with the given receiver. Abort! THROW_NEW_ERROR(isolate, NewTypeError(MessageTemplate::kIllegalInvocation), Object); } Object* raw_call_data = fun_data->call_code(); if (!raw_call_data->IsUndefined()) { // TODO(ishell): remove this debugging code. CHECK(raw_call_data->IsCallHandlerInfo()); CallHandlerInfo* call_data = CallHandlerInfo::cast(raw_call_data); Object* callback_obj = call_data->callback(); v8::FunctionCallback callback = v8::ToCData(callback_obj); Object* data_obj = call_data->data(); LOG(isolate, ApiObjectAccess("call", JSObject::cast(*args.receiver()))); DCHECK(raw_holder->IsJSObject()); FunctionCallbackArguments custom(isolate, data_obj, *function, raw_holder, &args[0] - 1, args.length() - 1, is_construct); v8::Local value = custom.Call(callback); Handle result; if (value.IsEmpty()) { result = isolate->factory()->undefined_value(); } else { result = v8::Utils::OpenHandle(*value); result->VerifyApiCallResultType(); } RETURN_EXCEPTION_IF_SCHEDULED_EXCEPTION(isolate, Object); if (!is_construct || result->IsJSObject()) { return scope.CloseAndEscape(result); } } return scope.CloseAndEscape(args.receiver()); } } // namespace BUILTIN(HandleApiCall) { HandleScope scope(isolate); Handle result; ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, result, HandleApiCallHelper(isolate, args)); return *result; } BUILTIN(HandleApiCallConstruct) { HandleScope scope(isolate); Handle result; ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, result, HandleApiCallHelper(isolate, args)); return *result; } Handle Builtins::CallFunction(ConvertReceiverMode mode) { switch (mode) { case ConvertReceiverMode::kNullOrUndefined: return CallFunction_ReceiverIsNullOrUndefined(); case ConvertReceiverMode::kNotNullOrUndefined: return CallFunction_ReceiverIsNotNullOrUndefined(); case ConvertReceiverMode::kAny: return CallFunction_ReceiverIsAny(); } UNREACHABLE(); return Handle::null(); } Handle Builtins::Call(ConvertReceiverMode mode) { switch (mode) { case ConvertReceiverMode::kNullOrUndefined: return Call_ReceiverIsNullOrUndefined(); case ConvertReceiverMode::kNotNullOrUndefined: return Call_ReceiverIsNotNullOrUndefined(); case ConvertReceiverMode::kAny: return Call_ReceiverIsAny(); } UNREACHABLE(); return Handle::null(); } namespace { class RelocatableArguments : public BuiltinArguments, public Relocatable { public: RelocatableArguments(Isolate* isolate, int length, Object** arguments) : BuiltinArguments(length, arguments), Relocatable(isolate) {} virtual inline void IterateInstance(ObjectVisitor* v) { if (length() == 0) return; v->VisitPointers(lowest_address(), highest_address() + 1); } private: DISALLOW_COPY_AND_ASSIGN(RelocatableArguments); }; } // namespace MaybeHandle Builtins::InvokeApiFunction(Handle function, Handle receiver, int argc, Handle args[]) { // Construct BuiltinArguments object: function, arguments reversed, receiver. const int kBufferSize = 32; Object* small_argv[kBufferSize]; Object** argv; if (argc + 2 <= kBufferSize) { argv = small_argv; } else { argv = new Object* [argc + 2]; } argv[argc + 1] = *receiver; for (int i = 0; i < argc; ++i) { argv[argc - i] = *args[i]; } argv[0] = *function; MaybeHandle result; { auto isolate = function->GetIsolate(); RelocatableArguments arguments(isolate, argc + 2, &argv[argc + 1]); result = HandleApiCallHelper(isolate, arguments); } if (argv != small_argv) { delete[] argv; } return result; } // Helper function to handle calls to non-function objects created through the // API. The object can be called as either a constructor (using new) or just as // a function (without new). MUST_USE_RESULT static Object* HandleApiCallAsFunctionOrConstructor( Isolate* isolate, bool is_construct_call, BuiltinArguments args) { Heap* heap = isolate->heap(); Handle receiver = args.receiver(); // Get the object called. JSObject* obj = JSObject::cast(*receiver); // Get the invocation callback from the function descriptor that was // used to create the called object. DCHECK(obj->map()->is_callable()); JSFunction* constructor = JSFunction::cast(obj->map()->GetConstructor()); // TODO(ishell): turn this back to a DCHECK. CHECK(constructor->shared()->IsApiFunction()); Object* handler = constructor->shared()->get_api_func_data()->instance_call_handler(); DCHECK(!handler->IsUndefined()); // TODO(ishell): remove this debugging code. CHECK(handler->IsCallHandlerInfo()); CallHandlerInfo* call_data = CallHandlerInfo::cast(handler); Object* callback_obj = call_data->callback(); v8::FunctionCallback callback = v8::ToCData(callback_obj); // Get the data for the call and perform the callback. Object* result; { HandleScope scope(isolate); LOG(isolate, ApiObjectAccess("call non-function", obj)); FunctionCallbackArguments custom(isolate, call_data->data(), constructor, obj, &args[0] - 1, args.length() - 1, is_construct_call); v8::Local value = custom.Call(callback); if (value.IsEmpty()) { result = heap->undefined_value(); } else { result = *reinterpret_cast(*value); result->VerifyApiCallResultType(); } } // Check for exceptions and return result. RETURN_FAILURE_IF_SCHEDULED_EXCEPTION(isolate); return result; } // Handle calls to non-function objects created through the API. This delegate // function is used when the call is a normal function call. BUILTIN(HandleApiCallAsFunction) { return HandleApiCallAsFunctionOrConstructor(isolate, false, args); } // Handle calls to non-function objects created through the API. This delegate // function is used when the call is a construct call. BUILTIN(HandleApiCallAsConstructor) { return HandleApiCallAsFunctionOrConstructor(isolate, true, args); } static void Generate_LoadIC_Miss(MacroAssembler* masm) { LoadIC::GenerateMiss(masm); } static void Generate_LoadIC_Normal(MacroAssembler* masm) { LoadIC::GenerateNormal(masm, SLOPPY); } static void Generate_LoadIC_Normal_Strong(MacroAssembler* masm) { LoadIC::GenerateNormal(masm, STRONG); } static void Generate_LoadIC_Getter_ForDeopt(MacroAssembler* masm) { NamedLoadHandlerCompiler::GenerateLoadViaGetterForDeopt(masm); } static void Generate_LoadIC_Slow(MacroAssembler* masm) { LoadIC::GenerateRuntimeGetProperty(masm, SLOPPY); } static void Generate_LoadIC_Slow_Strong(MacroAssembler* masm) { LoadIC::GenerateRuntimeGetProperty(masm, STRONG); } static void Generate_KeyedLoadIC_Slow(MacroAssembler* masm) { KeyedLoadIC::GenerateRuntimeGetProperty(masm, SLOPPY); } static void Generate_KeyedLoadIC_Slow_Strong(MacroAssembler* masm) { KeyedLoadIC::GenerateRuntimeGetProperty(masm, STRONG); } static void Generate_KeyedLoadIC_Miss(MacroAssembler* masm) { KeyedLoadIC::GenerateMiss(masm); } static void Generate_KeyedLoadIC_Megamorphic(MacroAssembler* masm) { KeyedLoadIC::GenerateMegamorphic(masm, SLOPPY); } static void Generate_KeyedLoadIC_Megamorphic_Strong(MacroAssembler* masm) { KeyedLoadIC::GenerateMegamorphic(masm, STRONG); } static void Generate_StoreIC_Miss(MacroAssembler* masm) { StoreIC::GenerateMiss(masm); } static void Generate_StoreIC_Normal(MacroAssembler* masm) { StoreIC::GenerateNormal(masm); } static void Generate_StoreIC_Slow(MacroAssembler* masm) { NamedStoreHandlerCompiler::GenerateSlow(masm); } static void Generate_KeyedStoreIC_Slow(MacroAssembler* masm) { ElementHandlerCompiler::GenerateStoreSlow(masm); } static void Generate_StoreIC_Setter_ForDeopt(MacroAssembler* masm) { NamedStoreHandlerCompiler::GenerateStoreViaSetterForDeopt(masm); } static void Generate_KeyedStoreIC_Megamorphic(MacroAssembler* masm) { KeyedStoreIC::GenerateMegamorphic(masm, SLOPPY); } static void Generate_KeyedStoreIC_Megamorphic_Strict(MacroAssembler* masm) { KeyedStoreIC::GenerateMegamorphic(masm, STRICT); } static void Generate_KeyedStoreIC_Miss(MacroAssembler* masm) { KeyedStoreIC::GenerateMiss(masm); } static void Generate_KeyedStoreIC_Initialize(MacroAssembler* masm) { KeyedStoreIC::GenerateInitialize(masm); } static void Generate_KeyedStoreIC_Initialize_Strict(MacroAssembler* masm) { KeyedStoreIC::GenerateInitialize(masm); } static void Generate_KeyedStoreIC_PreMonomorphic(MacroAssembler* masm) { KeyedStoreIC::GeneratePreMonomorphic(masm); } static void Generate_KeyedStoreIC_PreMonomorphic_Strict(MacroAssembler* masm) { KeyedStoreIC::GeneratePreMonomorphic(masm); } static void Generate_Return_DebugBreak(MacroAssembler* masm) { DebugCodegen::GenerateDebugBreakStub(masm, DebugCodegen::SAVE_RESULT_REGISTER); } static void Generate_Slot_DebugBreak(MacroAssembler* masm) { DebugCodegen::GenerateDebugBreakStub(masm, DebugCodegen::IGNORE_RESULT_REGISTER); } static void Generate_FrameDropper_LiveEdit(MacroAssembler* masm) { DebugCodegen::GenerateFrameDropperLiveEdit(masm); } Builtins::Builtins() : initialized_(false) { memset(builtins_, 0, sizeof(builtins_[0]) * builtin_count); memset(names_, 0, sizeof(names_[0]) * builtin_count); } Builtins::~Builtins() { } #define DEF_ENUM_C(name, ignore) FUNCTION_ADDR(Builtin_##name), Address const Builtins::c_functions_[cfunction_count] = { BUILTIN_LIST_C(DEF_ENUM_C) }; #undef DEF_ENUM_C struct BuiltinDesc { byte* generator; byte* c_code; const char* s_name; // name is only used for generating log information. int name; Code::Flags flags; BuiltinExtraArguments extra_args; }; #define BUILTIN_FUNCTION_TABLE_INIT { V8_ONCE_INIT, {} } class BuiltinFunctionTable { public: BuiltinDesc* functions() { base::CallOnce(&once_, &Builtins::InitBuiltinFunctionTable); return functions_; } base::OnceType once_; BuiltinDesc functions_[Builtins::builtin_count + 1]; friend class Builtins; }; static BuiltinFunctionTable builtin_function_table = BUILTIN_FUNCTION_TABLE_INIT; // Define array of pointers to generators and C builtin functions. // We do this in a sort of roundabout way so that we can do the initialization // within the lexical scope of Builtins:: and within a context where // Code::Flags names a non-abstract type. void Builtins::InitBuiltinFunctionTable() { BuiltinDesc* functions = builtin_function_table.functions_; functions[builtin_count].generator = NULL; functions[builtin_count].c_code = NULL; functions[builtin_count].s_name = NULL; functions[builtin_count].name = builtin_count; functions[builtin_count].flags = static_cast(0); functions[builtin_count].extra_args = BuiltinExtraArguments::kNone; #define DEF_FUNCTION_PTR_C(aname, aextra_args) \ functions->generator = FUNCTION_ADDR(Generate_Adaptor); \ functions->c_code = FUNCTION_ADDR(Builtin_##aname); \ functions->s_name = #aname; \ functions->name = c_##aname; \ functions->flags = Code::ComputeFlags(Code::BUILTIN); \ functions->extra_args = BuiltinExtraArguments::aextra_args; \ ++functions; #define DEF_FUNCTION_PTR_A(aname, kind, state, extra) \ functions->generator = FUNCTION_ADDR(Generate_##aname); \ functions->c_code = NULL; \ functions->s_name = #aname; \ functions->name = k##aname; \ functions->flags = Code::ComputeFlags(Code::kind, state, extra); \ functions->extra_args = BuiltinExtraArguments::kNone; \ ++functions; #define DEF_FUNCTION_PTR_H(aname, kind) \ functions->generator = FUNCTION_ADDR(Generate_##aname); \ functions->c_code = NULL; \ functions->s_name = #aname; \ functions->name = k##aname; \ functions->flags = Code::ComputeHandlerFlags(Code::kind); \ functions->extra_args = BuiltinExtraArguments::kNone; \ ++functions; BUILTIN_LIST_C(DEF_FUNCTION_PTR_C) BUILTIN_LIST_A(DEF_FUNCTION_PTR_A) BUILTIN_LIST_H(DEF_FUNCTION_PTR_H) BUILTIN_LIST_DEBUG_A(DEF_FUNCTION_PTR_A) #undef DEF_FUNCTION_PTR_C #undef DEF_FUNCTION_PTR_A } void Builtins::SetUp(Isolate* isolate, bool create_heap_objects) { DCHECK(!initialized_); // Create a scope for the handles in the builtins. HandleScope scope(isolate); const BuiltinDesc* functions = builtin_function_table.functions(); // For now we generate builtin adaptor code into a stack-allocated // buffer, before copying it into individual code objects. Be careful // with alignment, some platforms don't like unaligned code. #ifdef DEBUG // We can generate a lot of debug code on Arm64. const size_t buffer_size = 32*KB; #elif V8_TARGET_ARCH_PPC64 // 8 KB is insufficient on PPC64 when FLAG_debug_code is on. const size_t buffer_size = 10 * KB; #else const size_t buffer_size = 8*KB; #endif union { int force_alignment; byte buffer[buffer_size]; } u; // Traverse the list of builtins and generate an adaptor in a // separate code object for each one. for (int i = 0; i < builtin_count; i++) { if (create_heap_objects) { MacroAssembler masm(isolate, u.buffer, sizeof u.buffer, CodeObjectRequired::kYes); // Generate the code/adaptor. typedef void (*Generator)(MacroAssembler*, int, BuiltinExtraArguments); Generator g = FUNCTION_CAST(functions[i].generator); // We pass all arguments to the generator, but it may not use all of // them. This works because the first arguments are on top of the // stack. DCHECK(!masm.has_frame()); g(&masm, functions[i].name, functions[i].extra_args); // Move the code into the object heap. CodeDesc desc; masm.GetCode(&desc); Code::Flags flags = functions[i].flags; Handle code = isolate->factory()->NewCode(desc, flags, masm.CodeObject()); // Log the event and add the code to the builtins array. PROFILE(isolate, CodeCreateEvent(Logger::BUILTIN_TAG, *code, functions[i].s_name)); builtins_[i] = *code; code->set_builtin_index(i); #ifdef ENABLE_DISASSEMBLER if (FLAG_print_builtin_code) { CodeTracer::Scope trace_scope(isolate->GetCodeTracer()); OFStream os(trace_scope.file()); os << "Builtin: " << functions[i].s_name << "\n"; code->Disassemble(functions[i].s_name, os); os << "\n"; } #endif } else { // Deserializing. The values will be filled in during IterateBuiltins. builtins_[i] = NULL; } names_[i] = functions[i].s_name; } // Mark as initialized. initialized_ = true; } void Builtins::TearDown() { initialized_ = false; } void Builtins::IterateBuiltins(ObjectVisitor* v) { v->VisitPointers(&builtins_[0], &builtins_[0] + builtin_count); } const char* Builtins::Lookup(byte* pc) { // may be called during initialization (disassembler!) if (initialized_) { for (int i = 0; i < builtin_count; i++) { Code* entry = Code::cast(builtins_[i]); if (entry->contains(pc)) { return names_[i]; } } } return NULL; } void Builtins::Generate_InterruptCheck(MacroAssembler* masm) { masm->TailCallRuntime(Runtime::kInterrupt); } void Builtins::Generate_StackCheck(MacroAssembler* masm) { masm->TailCallRuntime(Runtime::kStackGuard); } #define DEFINE_BUILTIN_ACCESSOR_C(name, ignore) \ Handle Builtins::name() { \ Code** code_address = \ reinterpret_cast(builtin_address(k##name)); \ return Handle(code_address); \ } #define DEFINE_BUILTIN_ACCESSOR_A(name, kind, state, extra) \ Handle Builtins::name() { \ Code** code_address = \ reinterpret_cast(builtin_address(k##name)); \ return Handle(code_address); \ } #define DEFINE_BUILTIN_ACCESSOR_H(name, kind) \ Handle Builtins::name() { \ Code** code_address = \ reinterpret_cast(builtin_address(k##name)); \ return Handle(code_address); \ } BUILTIN_LIST_C(DEFINE_BUILTIN_ACCESSOR_C) BUILTIN_LIST_A(DEFINE_BUILTIN_ACCESSOR_A) BUILTIN_LIST_H(DEFINE_BUILTIN_ACCESSOR_H) BUILTIN_LIST_DEBUG_A(DEFINE_BUILTIN_ACCESSOR_A) #undef DEFINE_BUILTIN_ACCESSOR_C #undef DEFINE_BUILTIN_ACCESSOR_A } // namespace internal } // namespace v8