// Copyright 2006-2009 the V8 project authors. All rights reserved. // Redistribution and use in source and binary forms, with or without // modification, are permitted provided that the following conditions are // met: // // * Redistributions of source code must retain the above copyright // notice, this list of conditions and the following disclaimer. // * Redistributions in binary form must reproduce the above // copyright notice, this list of conditions and the following // disclaimer in the documentation and/or other materials provided // with the distribution. // * Neither the name of Google Inc. nor the names of its // contributors may be used to endorse or promote products derived // from this software without specific prior written permission. // // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT // OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT // LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. #include "v8.h" #include "api.h" #include "arguments.h" #include "bootstrapper.h" #include "debug.h" #include "execution.h" #include "objects-inl.h" #include "macro-assembler.h" #include "scanner.h" #include "scopeinfo.h" #include "string-stream.h" #include "utils.h" #ifdef ENABLE_DISASSEMBLER #include "disassembler.h" #endif namespace v8 { namespace internal { // Getters and setters are stored in a fixed array property. These are // constants for their indices. const int kGetterIndex = 0; const int kSetterIndex = 1; static Object* CreateJSValue(JSFunction* constructor, Object* value) { Object* result = Heap::AllocateJSObject(constructor); if (result->IsFailure()) return result; JSValue::cast(result)->set_value(value); return result; } Object* Object::ToObject(Context* global_context) { if (IsNumber()) { return CreateJSValue(global_context->number_function(), this); } else if (IsBoolean()) { return CreateJSValue(global_context->boolean_function(), this); } else if (IsString()) { return CreateJSValue(global_context->string_function(), this); } ASSERT(IsJSObject()); return this; } Object* Object::ToObject() { Context* global_context = Top::context()->global_context(); if (IsJSObject()) { return this; } else if (IsNumber()) { return CreateJSValue(global_context->number_function(), this); } else if (IsBoolean()) { return CreateJSValue(global_context->boolean_function(), this); } else if (IsString()) { return CreateJSValue(global_context->string_function(), this); } // Throw a type error. return Failure::InternalError(); } Object* Object::ToBoolean() { if (IsTrue()) return Heap::true_value(); if (IsFalse()) return Heap::false_value(); if (IsSmi()) { return Heap::ToBoolean(Smi::cast(this)->value() != 0); } if (IsUndefined() || IsNull()) return Heap::false_value(); // Undetectable object is false if (IsUndetectableObject()) { return Heap::false_value(); } if (IsString()) { return Heap::ToBoolean(String::cast(this)->length() != 0); } if (IsHeapNumber()) { return HeapNumber::cast(this)->HeapNumberToBoolean(); } return Heap::true_value(); } void Object::Lookup(String* name, LookupResult* result) { if (IsJSObject()) return JSObject::cast(this)->Lookup(name, result); Object* holder = NULL; Context* global_context = Top::context()->global_context(); if (IsString()) { holder = global_context->string_function()->instance_prototype(); } else if (IsNumber()) { holder = global_context->number_function()->instance_prototype(); } else if (IsBoolean()) { holder = global_context->boolean_function()->instance_prototype(); } ASSERT(holder != NULL); // Cannot handle null or undefined. JSObject::cast(holder)->Lookup(name, result); } Object* Object::GetPropertyWithReceiver(Object* receiver, String* name, PropertyAttributes* attributes) { LookupResult result; Lookup(name, &result); Object* value = GetProperty(receiver, &result, name, attributes); ASSERT(*attributes <= ABSENT); return value; } Object* Object::GetPropertyWithCallback(Object* receiver, Object* structure, String* name, Object* holder) { // To accommodate both the old and the new api we switch on the // data structure used to store the callbacks. Eventually proxy // callbacks should be phased out. if (structure->IsProxy()) { AccessorDescriptor* callback = reinterpret_cast<AccessorDescriptor*>(Proxy::cast(structure)->proxy()); Object* value = (callback->getter)(receiver, callback->data); RETURN_IF_SCHEDULED_EXCEPTION(); return value; } // api style callbacks. if (structure->IsAccessorInfo()) { AccessorInfo* data = AccessorInfo::cast(structure); Object* fun_obj = data->getter(); v8::AccessorGetter call_fun = v8::ToCData<v8::AccessorGetter>(fun_obj); HandleScope scope; JSObject* self = JSObject::cast(receiver); JSObject* holder_handle = JSObject::cast(holder); Handle<String> key(name); LOG(ApiNamedPropertyAccess("load", self, name)); CustomArguments args(data->data(), self, holder_handle); v8::AccessorInfo info(args.end()); v8::Handle<v8::Value> result; { // Leaving JavaScript. VMState state(EXTERNAL); result = call_fun(v8::Utils::ToLocal(key), info); } RETURN_IF_SCHEDULED_EXCEPTION(); if (result.IsEmpty()) return Heap::undefined_value(); return *v8::Utils::OpenHandle(*result); } // __defineGetter__ callback if (structure->IsFixedArray()) { Object* getter = FixedArray::cast(structure)->get(kGetterIndex); if (getter->IsJSFunction()) { return Object::GetPropertyWithDefinedGetter(receiver, JSFunction::cast(getter)); } // Getter is not a function. return Heap::undefined_value(); } UNREACHABLE(); return 0; } Object* Object::GetPropertyWithDefinedGetter(Object* receiver, JSFunction* getter) { HandleScope scope; Handle<JSFunction> fun(JSFunction::cast(getter)); Handle<Object> self(receiver); #ifdef ENABLE_DEBUGGER_SUPPORT // Handle stepping into a getter if step into is active. if (Debug::StepInActive()) { Debug::HandleStepIn(fun, Handle<Object>::null(), 0, false); } #endif bool has_pending_exception; Handle<Object> result = Execution::Call(fun, self, 0, NULL, &has_pending_exception); // Check for pending exception and return the result. if (has_pending_exception) return Failure::Exception(); return *result; } // Only deal with CALLBACKS and INTERCEPTOR Object* JSObject::GetPropertyWithFailedAccessCheck( Object* receiver, LookupResult* result, String* name, PropertyAttributes* attributes) { if (result->IsProperty()) { switch (result->type()) { case CALLBACKS: { // Only allow API accessors. Object* obj = result->GetCallbackObject(); if (obj->IsAccessorInfo()) { AccessorInfo* info = AccessorInfo::cast(obj); if (info->all_can_read()) { *attributes = result->GetAttributes(); return GetPropertyWithCallback(receiver, result->GetCallbackObject(), name, result->holder()); } } break; } case NORMAL: case FIELD: case CONSTANT_FUNCTION: { // Search ALL_CAN_READ accessors in prototype chain. LookupResult r; result->holder()->LookupRealNamedPropertyInPrototypes(name, &r); if (r.IsProperty()) { return GetPropertyWithFailedAccessCheck(receiver, &r, name, attributes); } break; } case INTERCEPTOR: { // If the object has an interceptor, try real named properties. // No access check in GetPropertyAttributeWithInterceptor. LookupResult r; result->holder()->LookupRealNamedProperty(name, &r); if (r.IsProperty()) { return GetPropertyWithFailedAccessCheck(receiver, &r, name, attributes); } break; } default: UNREACHABLE(); } } // No accessible property found. *attributes = ABSENT; Top::ReportFailedAccessCheck(this, v8::ACCESS_GET); return Heap::undefined_value(); } PropertyAttributes JSObject::GetPropertyAttributeWithFailedAccessCheck( Object* receiver, LookupResult* result, String* name, bool continue_search) { if (result->IsProperty()) { switch (result->type()) { case CALLBACKS: { // Only allow API accessors. Object* obj = result->GetCallbackObject(); if (obj->IsAccessorInfo()) { AccessorInfo* info = AccessorInfo::cast(obj); if (info->all_can_read()) { return result->GetAttributes(); } } break; } case NORMAL: case FIELD: case CONSTANT_FUNCTION: { if (!continue_search) break; // Search ALL_CAN_READ accessors in prototype chain. LookupResult r; result->holder()->LookupRealNamedPropertyInPrototypes(name, &r); if (r.IsProperty()) { return GetPropertyAttributeWithFailedAccessCheck(receiver, &r, name, continue_search); } break; } case INTERCEPTOR: { // If the object has an interceptor, try real named properties. // No access check in GetPropertyAttributeWithInterceptor. LookupResult r; if (continue_search) { result->holder()->LookupRealNamedProperty(name, &r); } else { result->holder()->LocalLookupRealNamedProperty(name, &r); } if (r.IsProperty()) { return GetPropertyAttributeWithFailedAccessCheck(receiver, &r, name, continue_search); } break; } default: UNREACHABLE(); } } Top::ReportFailedAccessCheck(this, v8::ACCESS_HAS); return ABSENT; } Object* JSObject::GetNormalizedProperty(LookupResult* result) { ASSERT(!HasFastProperties()); Object* value = property_dictionary()->ValueAt(result->GetDictionaryEntry()); if (IsGlobalObject()) { value = JSGlobalPropertyCell::cast(value)->value(); } ASSERT(!value->IsJSGlobalPropertyCell()); return value; } Object* JSObject::SetNormalizedProperty(LookupResult* result, Object* value) { ASSERT(!HasFastProperties()); if (IsGlobalObject()) { JSGlobalPropertyCell* cell = JSGlobalPropertyCell::cast( property_dictionary()->ValueAt(result->GetDictionaryEntry())); cell->set_value(value); } else { property_dictionary()->ValueAtPut(result->GetDictionaryEntry(), value); } return value; } Object* JSObject::SetNormalizedProperty(String* name, Object* value, PropertyDetails details) { ASSERT(!HasFastProperties()); int entry = property_dictionary()->FindEntry(name); if (entry == StringDictionary::kNotFound) { Object* store_value = value; if (IsGlobalObject()) { store_value = Heap::AllocateJSGlobalPropertyCell(value); if (store_value->IsFailure()) return store_value; } Object* dict = property_dictionary()->Add(name, store_value, details); if (dict->IsFailure()) return dict; set_properties(StringDictionary::cast(dict)); return value; } // Preserve enumeration index. details = PropertyDetails(details.attributes(), details.type(), property_dictionary()->DetailsAt(entry).index()); if (IsGlobalObject()) { JSGlobalPropertyCell* cell = JSGlobalPropertyCell::cast(property_dictionary()->ValueAt(entry)); cell->set_value(value); // Please note we have to update the property details. property_dictionary()->DetailsAtPut(entry, details); } else { property_dictionary()->SetEntry(entry, name, value, details); } return value; } Object* JSObject::DeleteNormalizedProperty(String* name, DeleteMode mode) { ASSERT(!HasFastProperties()); StringDictionary* dictionary = property_dictionary(); int entry = dictionary->FindEntry(name); if (entry != StringDictionary::kNotFound) { // If we have a global object set the cell to the hole. if (IsGlobalObject()) { PropertyDetails details = dictionary->DetailsAt(entry); if (details.IsDontDelete()) { if (mode != FORCE_DELETION) return Heap::false_value(); // When forced to delete global properties, we have to make a // map change to invalidate any ICs that think they can load // from the DontDelete cell without checking if it contains // the hole value. Object* new_map = map()->CopyDropDescriptors(); if (new_map->IsFailure()) return new_map; set_map(Map::cast(new_map)); } JSGlobalPropertyCell* cell = JSGlobalPropertyCell::cast(dictionary->ValueAt(entry)); cell->set_value(Heap::the_hole_value()); dictionary->DetailsAtPut(entry, details.AsDeleted()); } else { return dictionary->DeleteProperty(entry, mode); } } return Heap::true_value(); } bool JSObject::IsDirty() { Object* cons_obj = map()->constructor(); if (!cons_obj->IsJSFunction()) return true; JSFunction* fun = JSFunction::cast(cons_obj); if (!fun->shared()->function_data()->IsFunctionTemplateInfo()) return true; // If the object is fully fast case and has the same map it was // created with then no changes can have been made to it. return map() != fun->initial_map() || !HasFastElements() || !HasFastProperties(); } Object* Object::GetProperty(Object* receiver, LookupResult* result, String* name, PropertyAttributes* attributes) { // Make sure that the top context does not change when doing // callbacks or interceptor calls. AssertNoContextChange ncc; // Traverse the prototype chain from the current object (this) to // the holder and check for access rights. This avoid traversing the // objects more than once in case of interceptors, because the // holder will always be the interceptor holder and the search may // only continue with a current object just after the interceptor // holder in the prototype chain. Object* last = result->IsProperty() ? result->holder() : Heap::null_value(); for (Object* current = this; true; current = current->GetPrototype()) { if (current->IsAccessCheckNeeded()) { // Check if we're allowed to read from the current object. Note // that even though we may not actually end up loading the named // property from the current object, we still check that we have // access to it. JSObject* checked = JSObject::cast(current); if (!Top::MayNamedAccess(checked, name, v8::ACCESS_GET)) { return checked->GetPropertyWithFailedAccessCheck(receiver, result, name, attributes); } } // Stop traversing the chain once we reach the last object in the // chain; either the holder of the result or null in case of an // absent property. if (current == last) break; } if (!result->IsProperty()) { *attributes = ABSENT; return Heap::undefined_value(); } *attributes = result->GetAttributes(); Object* value; JSObject* holder = result->holder(); switch (result->type()) { case NORMAL: value = holder->GetNormalizedProperty(result); ASSERT(!value->IsTheHole() || result->IsReadOnly()); return value->IsTheHole() ? Heap::undefined_value() : value; case FIELD: value = holder->FastPropertyAt(result->GetFieldIndex()); ASSERT(!value->IsTheHole() || result->IsReadOnly()); return value->IsTheHole() ? Heap::undefined_value() : value; case CONSTANT_FUNCTION: return result->GetConstantFunction(); case CALLBACKS: return GetPropertyWithCallback(receiver, result->GetCallbackObject(), name, holder); case INTERCEPTOR: { JSObject* recvr = JSObject::cast(receiver); return holder->GetPropertyWithInterceptor(recvr, name, attributes); } default: UNREACHABLE(); return NULL; } } Object* Object::GetElementWithReceiver(Object* receiver, uint32_t index) { // Non-JS objects do not have integer indexed properties. if (!IsJSObject()) return Heap::undefined_value(); return JSObject::cast(this)->GetElementWithReceiver(JSObject::cast(receiver), index); } Object* Object::GetPrototype() { // The object is either a number, a string, a boolean, or a real JS object. if (IsJSObject()) return JSObject::cast(this)->map()->prototype(); Context* context = Top::context()->global_context(); if (IsNumber()) return context->number_function()->instance_prototype(); if (IsString()) return context->string_function()->instance_prototype(); if (IsBoolean()) { return context->boolean_function()->instance_prototype(); } else { return Heap::null_value(); } } void Object::ShortPrint() { HeapStringAllocator allocator; StringStream accumulator(&allocator); ShortPrint(&accumulator); accumulator.OutputToStdOut(); } void Object::ShortPrint(StringStream* accumulator) { if (IsSmi()) { Smi::cast(this)->SmiPrint(accumulator); } else if (IsFailure()) { Failure::cast(this)->FailurePrint(accumulator); } else { HeapObject::cast(this)->HeapObjectShortPrint(accumulator); } } void Smi::SmiPrint() { PrintF("%d", value()); } void Smi::SmiPrint(StringStream* accumulator) { accumulator->Add("%d", value()); } void Failure::FailurePrint(StringStream* accumulator) { accumulator->Add("Failure(%p)", reinterpret_cast<void*>(value())); } void Failure::FailurePrint() { PrintF("Failure(%p)", reinterpret_cast<void*>(value())); } Failure* Failure::RetryAfterGC(int requested_bytes, AllocationSpace space) { ASSERT((space & ~kSpaceTagMask) == 0); // TODO(X64): Stop using Smi validation for non-smi checks, even if they // happen to be identical at the moment. int requested = requested_bytes >> kObjectAlignmentBits; int value = (requested << kSpaceTagSize) | space; // We can't very well allocate a heap number in this situation, and if the // requested memory is so large it seems reasonable to say that this is an // out of memory situation. This fixes a crash in // js1_5/Regress/regress-303213.js. if (value >> kSpaceTagSize != requested || !Smi::IsValid(value) || value != ((value << kFailureTypeTagSize) >> kFailureTypeTagSize) || !Smi::IsValid(value << kFailureTypeTagSize)) { Top::context()->mark_out_of_memory(); return Failure::OutOfMemoryException(); } return Construct(RETRY_AFTER_GC, value); } // Should a word be prefixed by 'a' or 'an' in order to read naturally in // English? Returns false for non-ASCII or words that don't start with // a capital letter. The a/an rule follows pronunciation in English. // We don't use the BBC's overcorrect "an historic occasion" though if // you speak a dialect you may well say "an 'istoric occasion". static bool AnWord(String* str) { if (str->length() == 0) return false; // A nothing. int c0 = str->Get(0); int c1 = str->length() > 1 ? str->Get(1) : 0; if (c0 == 'U') { if (c1 > 'Z') { return true; // An Umpire, but a UTF8String, a U. } } else if (c0 == 'A' || c0 == 'E' || c0 == 'I' || c0 == 'O') { return true; // An Ape, an ABCBook. } else if ((c1 == 0 || (c1 >= 'A' && c1 <= 'Z')) && (c0 == 'F' || c0 == 'H' || c0 == 'M' || c0 == 'N' || c0 == 'R' || c0 == 'S' || c0 == 'X')) { return true; // An MP3File, an M. } return false; } Object* String::TryFlatten() { #ifdef DEBUG // Do not attempt to flatten in debug mode when allocation is not // allowed. This is to avoid an assertion failure when allocating. // Flattening strings is the only case where we always allow // allocation because no GC is performed if the allocation fails. if (!Heap::IsAllocationAllowed()) return this; #endif switch (StringShape(this).representation_tag()) { case kConsStringTag: { ConsString* cs = ConsString::cast(this); if (cs->second()->length() == 0) { return this; } // There's little point in putting the flat string in new space if the // cons string is in old space. It can never get GCed until there is // an old space GC. PretenureFlag tenure = Heap::InNewSpace(this) ? NOT_TENURED : TENURED; int len = length(); Object* object; String* result; if (IsAsciiRepresentation()) { object = Heap::AllocateRawAsciiString(len, tenure); if (object->IsFailure()) return object; result = String::cast(object); String* first = cs->first(); int first_length = first->length(); char* dest = SeqAsciiString::cast(result)->GetChars(); WriteToFlat(first, dest, 0, first_length); String* second = cs->second(); WriteToFlat(second, dest + first_length, 0, len - first_length); } else { object = Heap::AllocateRawTwoByteString(len, tenure); if (object->IsFailure()) return object; result = String::cast(object); uc16* dest = SeqTwoByteString::cast(result)->GetChars(); String* first = cs->first(); int first_length = first->length(); WriteToFlat(first, dest, 0, first_length); String* second = cs->second(); WriteToFlat(second, dest + first_length, 0, len - first_length); } cs->set_first(result); cs->set_second(Heap::empty_string()); return this; } default: return this; } } bool String::MakeExternal(v8::String::ExternalStringResource* resource) { #ifdef DEBUG if (FLAG_enable_slow_asserts) { // Assert that the resource and the string are equivalent. ASSERT(static_cast<size_t>(this->length()) == resource->length()); SmartPointer<uc16> smart_chars(NewArray<uc16>(this->length())); String::WriteToFlat(this, *smart_chars, 0, this->length()); ASSERT(memcmp(*smart_chars, resource->data(), resource->length() * sizeof(**smart_chars)) == 0); } #endif // DEBUG int size = this->Size(); // Byte size of the original string. if (size < ExternalString::kSize) { // The string is too small to fit an external String in its place. This can // only happen for zero length strings. return false; } ASSERT(size >= ExternalString::kSize); bool is_symbol = this->IsSymbol(); int length = this->length(); int hash_field = this->hash_field(); // Morph the object to an external string by adjusting the map and // reinitializing the fields. this->set_map(Heap::external_string_map()); ExternalTwoByteString* self = ExternalTwoByteString::cast(this); self->set_length(length); self->set_hash_field(hash_field); self->set_resource(resource); // Additionally make the object into an external symbol if the original string // was a symbol to start with. if (is_symbol) { self->Hash(); // Force regeneration of the hash value. // Now morph this external string into a external symbol. this->set_map(Heap::external_symbol_map()); } // Fill the remainder of the string with dead wood. int new_size = this->Size(); // Byte size of the external String object. Heap::CreateFillerObjectAt(this->address() + new_size, size - new_size); return true; } bool String::MakeExternal(v8::String::ExternalAsciiStringResource* resource) { #ifdef DEBUG if (FLAG_enable_slow_asserts) { // Assert that the resource and the string are equivalent. ASSERT(static_cast<size_t>(this->length()) == resource->length()); SmartPointer<char> smart_chars(NewArray<char>(this->length())); String::WriteToFlat(this, *smart_chars, 0, this->length()); ASSERT(memcmp(*smart_chars, resource->data(), resource->length()*sizeof(**smart_chars)) == 0); } #endif // DEBUG int size = this->Size(); // Byte size of the original string. if (size < ExternalString::kSize) { // The string is too small to fit an external String in its place. This can // only happen for zero length strings. return false; } ASSERT(size >= ExternalString::kSize); bool is_symbol = this->IsSymbol(); int length = this->length(); int hash_field = this->hash_field(); // Morph the object to an external string by adjusting the map and // reinitializing the fields. this->set_map(Heap::external_ascii_string_map()); ExternalAsciiString* self = ExternalAsciiString::cast(this); self->set_length(length); self->set_hash_field(hash_field); self->set_resource(resource); // Additionally make the object into an external symbol if the original string // was a symbol to start with. if (is_symbol) { self->Hash(); // Force regeneration of the hash value. // Now morph this external string into a external symbol. this->set_map(Heap::external_ascii_symbol_map()); } // Fill the remainder of the string with dead wood. int new_size = this->Size(); // Byte size of the external String object. Heap::CreateFillerObjectAt(this->address() + new_size, size - new_size); return true; } void String::StringShortPrint(StringStream* accumulator) { int len = length(); if (len > kMaxShortPrintLength) { accumulator->Add("<Very long string[%u]>", len); return; } if (!LooksValid()) { accumulator->Add("<Invalid String>"); return; } StringInputBuffer buf(this); bool truncated = false; if (len > kMaxShortPrintLength) { len = kMaxShortPrintLength; truncated = true; } bool ascii = true; for (int i = 0; i < len; i++) { int c = buf.GetNext(); if (c < 32 || c >= 127) { ascii = false; } } buf.Reset(this); if (ascii) { accumulator->Add("<String[%u]: ", length()); for (int i = 0; i < len; i++) { accumulator->Put(buf.GetNext()); } accumulator->Put('>'); } else { // Backslash indicates that the string contains control // characters and that backslashes are therefore escaped. accumulator->Add("<String[%u]\\: ", length()); for (int i = 0; i < len; i++) { int c = buf.GetNext(); if (c == '\n') { accumulator->Add("\\n"); } else if (c == '\r') { accumulator->Add("\\r"); } else if (c == '\\') { accumulator->Add("\\\\"); } else if (c < 32 || c > 126) { accumulator->Add("\\x%02x", c); } else { accumulator->Put(c); } } if (truncated) { accumulator->Put('.'); accumulator->Put('.'); accumulator->Put('.'); } accumulator->Put('>'); } return; } void JSObject::JSObjectShortPrint(StringStream* accumulator) { switch (map()->instance_type()) { case JS_ARRAY_TYPE: { double length = JSArray::cast(this)->length()->Number(); accumulator->Add("<JS array[%u]>", static_cast<uint32_t>(length)); break; } case JS_REGEXP_TYPE: { accumulator->Add("<JS RegExp>"); break; } case JS_FUNCTION_TYPE: { Object* fun_name = JSFunction::cast(this)->shared()->name(); bool printed = false; if (fun_name->IsString()) { String* str = String::cast(fun_name); if (str->length() > 0) { accumulator->Add("<JS Function "); accumulator->Put(str); accumulator->Put('>'); printed = true; } } if (!printed) { accumulator->Add("<JS Function>"); } break; } // All other JSObjects are rather similar to each other (JSObject, // JSGlobalProxy, JSGlobalObject, JSUndetectableObject, JSValue). default: { Object* constructor = map()->constructor(); bool printed = false; if (constructor->IsHeapObject() && !Heap::Contains(HeapObject::cast(constructor))) { accumulator->Add("!!!INVALID CONSTRUCTOR!!!"); } else { bool global_object = IsJSGlobalProxy(); if (constructor->IsJSFunction()) { if (!Heap::Contains(JSFunction::cast(constructor)->shared())) { accumulator->Add("!!!INVALID SHARED ON CONSTRUCTOR!!!"); } else { Object* constructor_name = JSFunction::cast(constructor)->shared()->name(); if (constructor_name->IsString()) { String* str = String::cast(constructor_name); if (str->length() > 0) { bool vowel = AnWord(str); accumulator->Add("<%sa%s ", global_object ? "Global Object: " : "", vowel ? "n" : ""); accumulator->Put(str); accumulator->Put('>'); printed = true; } } } } if (!printed) { accumulator->Add("<JS %sObject", global_object ? "Global " : ""); } } if (IsJSValue()) { accumulator->Add(" value = "); JSValue::cast(this)->value()->ShortPrint(accumulator); } accumulator->Put('>'); break; } } } void HeapObject::HeapObjectShortPrint(StringStream* accumulator) { // if (!Heap::InNewSpace(this)) PrintF("*", this); if (!Heap::Contains(this)) { accumulator->Add("!!!INVALID POINTER!!!"); return; } if (!Heap::Contains(map())) { accumulator->Add("!!!INVALID MAP!!!"); return; } accumulator->Add("%p ", this); if (IsString()) { String::cast(this)->StringShortPrint(accumulator); return; } if (IsJSObject()) { JSObject::cast(this)->JSObjectShortPrint(accumulator); return; } switch (map()->instance_type()) { case MAP_TYPE: accumulator->Add("<Map>"); break; case FIXED_ARRAY_TYPE: accumulator->Add("<FixedArray[%u]>", FixedArray::cast(this)->length()); break; case BYTE_ARRAY_TYPE: accumulator->Add("<ByteArray[%u]>", ByteArray::cast(this)->length()); break; case PIXEL_ARRAY_TYPE: accumulator->Add("<PixelArray[%u]>", PixelArray::cast(this)->length()); break; case EXTERNAL_BYTE_ARRAY_TYPE: accumulator->Add("<ExternalByteArray[%u]>", ExternalByteArray::cast(this)->length()); break; case EXTERNAL_UNSIGNED_BYTE_ARRAY_TYPE: accumulator->Add("<ExternalUnsignedByteArray[%u]>", ExternalUnsignedByteArray::cast(this)->length()); break; case EXTERNAL_SHORT_ARRAY_TYPE: accumulator->Add("<ExternalShortArray[%u]>", ExternalShortArray::cast(this)->length()); break; case EXTERNAL_UNSIGNED_SHORT_ARRAY_TYPE: accumulator->Add("<ExternalUnsignedShortArray[%u]>", ExternalUnsignedShortArray::cast(this)->length()); break; case EXTERNAL_INT_ARRAY_TYPE: accumulator->Add("<ExternalIntArray[%u]>", ExternalIntArray::cast(this)->length()); break; case EXTERNAL_UNSIGNED_INT_ARRAY_TYPE: accumulator->Add("<ExternalUnsignedIntArray[%u]>", ExternalUnsignedIntArray::cast(this)->length()); break; case EXTERNAL_FLOAT_ARRAY_TYPE: accumulator->Add("<ExternalFloatArray[%u]>", ExternalFloatArray::cast(this)->length()); break; case SHARED_FUNCTION_INFO_TYPE: accumulator->Add("<SharedFunctionInfo>"); break; #define MAKE_STRUCT_CASE(NAME, Name, name) \ case NAME##_TYPE: \ accumulator->Put('<'); \ accumulator->Add(#Name); \ accumulator->Put('>'); \ break; STRUCT_LIST(MAKE_STRUCT_CASE) #undef MAKE_STRUCT_CASE case CODE_TYPE: accumulator->Add("<Code>"); break; case ODDBALL_TYPE: { if (IsUndefined()) accumulator->Add("<undefined>"); else if (IsTheHole()) accumulator->Add("<the hole>"); else if (IsNull()) accumulator->Add("<null>"); else if (IsTrue()) accumulator->Add("<true>"); else if (IsFalse()) accumulator->Add("<false>"); else accumulator->Add("<Odd Oddball>"); break; } case HEAP_NUMBER_TYPE: accumulator->Add("<Number: "); HeapNumber::cast(this)->HeapNumberPrint(accumulator); accumulator->Put('>'); break; case PROXY_TYPE: accumulator->Add("<Proxy>"); break; case JS_GLOBAL_PROPERTY_CELL_TYPE: accumulator->Add("Cell for "); JSGlobalPropertyCell::cast(this)->value()->ShortPrint(accumulator); break; default: accumulator->Add("<Other heap object (%d)>", map()->instance_type()); break; } } int HeapObject::SlowSizeFromMap(Map* map) { // Avoid calling functions such as FixedArray::cast during GC, which // read map pointer of this object again. InstanceType instance_type = map->instance_type(); uint32_t type = static_cast<uint32_t>(instance_type); if (instance_type < FIRST_NONSTRING_TYPE && (StringShape(instance_type).IsSequential())) { if ((type & kStringEncodingMask) == kAsciiStringTag) { SeqAsciiString* seq_ascii_this = reinterpret_cast<SeqAsciiString*>(this); return seq_ascii_this->SeqAsciiStringSize(instance_type); } else { SeqTwoByteString* self = reinterpret_cast<SeqTwoByteString*>(this); return self->SeqTwoByteStringSize(instance_type); } } switch (instance_type) { case FIXED_ARRAY_TYPE: return reinterpret_cast<FixedArray*>(this)->FixedArraySize(); case BYTE_ARRAY_TYPE: return reinterpret_cast<ByteArray*>(this)->ByteArraySize(); case CODE_TYPE: return reinterpret_cast<Code*>(this)->CodeSize(); case MAP_TYPE: return Map::kSize; default: return map->instance_size(); } } void HeapObject::Iterate(ObjectVisitor* v) { // Handle header IteratePointer(v, kMapOffset); // Handle object body Map* m = map(); IterateBody(m->instance_type(), SizeFromMap(m), v); } void HeapObject::IterateBody(InstanceType type, int object_size, ObjectVisitor* v) { // Avoiding <Type>::cast(this) because it accesses the map pointer field. // During GC, the map pointer field is encoded. if (type < FIRST_NONSTRING_TYPE) { switch (type & kStringRepresentationMask) { case kSeqStringTag: break; case kConsStringTag: reinterpret_cast<ConsString*>(this)->ConsStringIterateBody(v); break; case kExternalStringTag: if ((type & kStringEncodingMask) == kAsciiStringTag) { reinterpret_cast<ExternalAsciiString*>(this)-> ExternalAsciiStringIterateBody(v); } else { reinterpret_cast<ExternalTwoByteString*>(this)-> ExternalTwoByteStringIterateBody(v); } break; } return; } switch (type) { case FIXED_ARRAY_TYPE: reinterpret_cast<FixedArray*>(this)->FixedArrayIterateBody(v); break; case JS_OBJECT_TYPE: case JS_CONTEXT_EXTENSION_OBJECT_TYPE: case JS_VALUE_TYPE: case JS_ARRAY_TYPE: case JS_REGEXP_TYPE: case JS_FUNCTION_TYPE: case JS_GLOBAL_PROXY_TYPE: case JS_GLOBAL_OBJECT_TYPE: case JS_BUILTINS_OBJECT_TYPE: reinterpret_cast<JSObject*>(this)->JSObjectIterateBody(object_size, v); break; case ODDBALL_TYPE: reinterpret_cast<Oddball*>(this)->OddballIterateBody(v); break; case PROXY_TYPE: reinterpret_cast<Proxy*>(this)->ProxyIterateBody(v); break; case MAP_TYPE: reinterpret_cast<Map*>(this)->MapIterateBody(v); break; case CODE_TYPE: reinterpret_cast<Code*>(this)->CodeIterateBody(v); break; case JS_GLOBAL_PROPERTY_CELL_TYPE: reinterpret_cast<JSGlobalPropertyCell*>(this) ->JSGlobalPropertyCellIterateBody(v); break; case HEAP_NUMBER_TYPE: case FILLER_TYPE: case BYTE_ARRAY_TYPE: case PIXEL_ARRAY_TYPE: case EXTERNAL_BYTE_ARRAY_TYPE: case EXTERNAL_UNSIGNED_BYTE_ARRAY_TYPE: case EXTERNAL_SHORT_ARRAY_TYPE: case EXTERNAL_UNSIGNED_SHORT_ARRAY_TYPE: case EXTERNAL_INT_ARRAY_TYPE: case EXTERNAL_UNSIGNED_INT_ARRAY_TYPE: case EXTERNAL_FLOAT_ARRAY_TYPE: break; case SHARED_FUNCTION_INFO_TYPE: { SharedFunctionInfo* shared = reinterpret_cast<SharedFunctionInfo*>(this); shared->SharedFunctionInfoIterateBody(v); break; } #define MAKE_STRUCT_CASE(NAME, Name, name) \ case NAME##_TYPE: STRUCT_LIST(MAKE_STRUCT_CASE) #undef MAKE_STRUCT_CASE IterateStructBody(object_size, v); break; default: PrintF("Unknown type: %d\n", type); UNREACHABLE(); } } void HeapObject::IterateStructBody(int object_size, ObjectVisitor* v) { IteratePointers(v, HeapObject::kHeaderSize, object_size); } Object* HeapNumber::HeapNumberToBoolean() { // NaN, +0, and -0 should return the false object switch (fpclassify(value())) { case FP_NAN: // fall through case FP_ZERO: return Heap::false_value(); default: return Heap::true_value(); } } void HeapNumber::HeapNumberPrint() { PrintF("%.16g", Number()); } void HeapNumber::HeapNumberPrint(StringStream* accumulator) { // The Windows version of vsnprintf can allocate when printing a %g string // into a buffer that may not be big enough. We don't want random memory // allocation when producing post-crash stack traces, so we print into a // buffer that is plenty big enough for any floating point number, then // print that using vsnprintf (which may truncate but never allocate if // there is no more space in the buffer). EmbeddedVector<char, 100> buffer; OS::SNPrintF(buffer, "%.16g", Number()); accumulator->Add("%s", buffer.start()); } String* JSObject::class_name() { if (IsJSFunction()) { return Heap::function_class_symbol(); } if (map()->constructor()->IsJSFunction()) { JSFunction* constructor = JSFunction::cast(map()->constructor()); return String::cast(constructor->shared()->instance_class_name()); } // If the constructor is not present, return "Object". return Heap::Object_symbol(); } String* JSObject::constructor_name() { if (IsJSFunction()) { return JSFunction::cast(this)->IsBoilerplate() ? Heap::function_class_symbol() : Heap::closure_symbol(); } if (map()->constructor()->IsJSFunction()) { JSFunction* constructor = JSFunction::cast(map()->constructor()); String* name = String::cast(constructor->shared()->name()); return name->length() > 0 ? name : constructor->shared()->inferred_name(); } // If the constructor is not present, return "Object". return Heap::Object_symbol(); } void JSObject::JSObjectIterateBody(int object_size, ObjectVisitor* v) { // Iterate over all fields in the body. Assumes all are Object*. IteratePointers(v, kPropertiesOffset, object_size); } Object* JSObject::AddFastPropertyUsingMap(Map* new_map, String* name, Object* value) { int index = new_map->PropertyIndexFor(name); if (map()->unused_property_fields() == 0) { ASSERT(map()->unused_property_fields() == 0); int new_unused = new_map->unused_property_fields(); Object* values = properties()->CopySize(properties()->length() + new_unused + 1); if (values->IsFailure()) return values; set_properties(FixedArray::cast(values)); } set_map(new_map); return FastPropertyAtPut(index, value); } Object* JSObject::AddFastProperty(String* name, Object* value, PropertyAttributes attributes) { // Normalize the object if the name is an actual string (not the // hidden symbols) and is not a real identifier. StringInputBuffer buffer(name); if (!Scanner::IsIdentifier(&buffer) && name != Heap::hidden_symbol()) { Object* obj = NormalizeProperties(CLEAR_INOBJECT_PROPERTIES, 0); if (obj->IsFailure()) return obj; return AddSlowProperty(name, value, attributes); } DescriptorArray* old_descriptors = map()->instance_descriptors(); // Compute the new index for new field. int index = map()->NextFreePropertyIndex(); // Allocate new instance descriptors with (name, index) added FieldDescriptor new_field(name, index, attributes); Object* new_descriptors = old_descriptors->CopyInsert(&new_field, REMOVE_TRANSITIONS); if (new_descriptors->IsFailure()) return new_descriptors; // Only allow map transition if the object's map is NOT equal to the // global object_function's map and there is not a transition for name. bool allow_map_transition = !old_descriptors->Contains(name) && (Top::context()->global_context()->object_function()->map() != map()); ASSERT(index < map()->inobject_properties() || (index - map()->inobject_properties()) < properties()->length() || map()->unused_property_fields() == 0); // Allocate a new map for the object. Object* r = map()->CopyDropDescriptors(); if (r->IsFailure()) return r; Map* new_map = Map::cast(r); if (allow_map_transition) { // Allocate new instance descriptors for the old map with map transition. MapTransitionDescriptor d(name, Map::cast(new_map), attributes); Object* r = old_descriptors->CopyInsert(&d, KEEP_TRANSITIONS); if (r->IsFailure()) return r; old_descriptors = DescriptorArray::cast(r); } if (map()->unused_property_fields() == 0) { if (properties()->length() > kMaxFastProperties) { Object* obj = NormalizeProperties(CLEAR_INOBJECT_PROPERTIES, 0); if (obj->IsFailure()) return obj; return AddSlowProperty(name, value, attributes); } // Make room for the new value Object* values = properties()->CopySize(properties()->length() + kFieldsAdded); if (values->IsFailure()) return values; set_properties(FixedArray::cast(values)); new_map->set_unused_property_fields(kFieldsAdded - 1); } else { new_map->set_unused_property_fields(map()->unused_property_fields() - 1); } // We have now allocated all the necessary objects. // All the changes can be applied at once, so they are atomic. map()->set_instance_descriptors(old_descriptors); new_map->set_instance_descriptors(DescriptorArray::cast(new_descriptors)); set_map(new_map); return FastPropertyAtPut(index, value); } Object* JSObject::AddConstantFunctionProperty(String* name, JSFunction* function, PropertyAttributes attributes) { ASSERT(!Heap::InNewSpace(function)); // Allocate new instance descriptors with (name, function) added ConstantFunctionDescriptor d(name, function, attributes); Object* new_descriptors = map()->instance_descriptors()->CopyInsert(&d, REMOVE_TRANSITIONS); if (new_descriptors->IsFailure()) return new_descriptors; // Allocate a new map for the object. Object* new_map = map()->CopyDropDescriptors(); if (new_map->IsFailure()) return new_map; DescriptorArray* descriptors = DescriptorArray::cast(new_descriptors); Map::cast(new_map)->set_instance_descriptors(descriptors); Map* old_map = map(); set_map(Map::cast(new_map)); // If the old map is the global object map (from new Object()), // then transitions are not added to it, so we are done. if (old_map == Top::context()->global_context()->object_function()->map()) { return function; } // Do not add CONSTANT_TRANSITIONS to global objects if (IsGlobalObject()) { return function; } // Add a CONSTANT_TRANSITION descriptor to the old map, // so future assignments to this property on other objects // of the same type will create a normal field, not a constant function. // Don't do this for special properties, with non-trival attributes. if (attributes != NONE) { return function; } ConstTransitionDescriptor mark(name); new_descriptors = old_map->instance_descriptors()->CopyInsert(&mark, KEEP_TRANSITIONS); if (new_descriptors->IsFailure()) { return function; // We have accomplished the main goal, so return success. } old_map->set_instance_descriptors(DescriptorArray::cast(new_descriptors)); return function; } // Add property in slow mode Object* JSObject::AddSlowProperty(String* name, Object* value, PropertyAttributes attributes) { ASSERT(!HasFastProperties()); StringDictionary* dict = property_dictionary(); Object* store_value = value; if (IsGlobalObject()) { // In case name is an orphaned property reuse the cell. int entry = dict->FindEntry(name); if (entry != StringDictionary::kNotFound) { store_value = dict->ValueAt(entry); JSGlobalPropertyCell::cast(store_value)->set_value(value); // Assign an enumeration index to the property and update // SetNextEnumerationIndex. int index = dict->NextEnumerationIndex(); PropertyDetails details = PropertyDetails(attributes, NORMAL, index); dict->SetNextEnumerationIndex(index + 1); dict->SetEntry(entry, name, store_value, details); return value; } store_value = Heap::AllocateJSGlobalPropertyCell(value); if (store_value->IsFailure()) return store_value; JSGlobalPropertyCell::cast(store_value)->set_value(value); } PropertyDetails details = PropertyDetails(attributes, NORMAL); Object* result = dict->Add(name, store_value, details); if (result->IsFailure()) return result; if (dict != result) set_properties(StringDictionary::cast(result)); return value; } Object* JSObject::AddProperty(String* name, Object* value, PropertyAttributes attributes) { ASSERT(!IsJSGlobalProxy()); if (HasFastProperties()) { // Ensure the descriptor array does not get too big. if (map()->instance_descriptors()->number_of_descriptors() < DescriptorArray::kMaxNumberOfDescriptors) { if (value->IsJSFunction() && !Heap::InNewSpace(value)) { return AddConstantFunctionProperty(name, JSFunction::cast(value), attributes); } else { return AddFastProperty(name, value, attributes); } } else { // Normalize the object to prevent very large instance descriptors. // This eliminates unwanted N^2 allocation and lookup behavior. Object* obj = NormalizeProperties(CLEAR_INOBJECT_PROPERTIES, 0); if (obj->IsFailure()) return obj; } } return AddSlowProperty(name, value, attributes); } Object* JSObject::SetPropertyPostInterceptor(String* name, Object* value, PropertyAttributes attributes) { // Check local property, ignore interceptor. LookupResult result; LocalLookupRealNamedProperty(name, &result); if (result.IsFound()) { // An existing property, a map transition or a null descriptor was // found. Use set property to handle all these cases. return SetProperty(&result, name, value, attributes); } // Add a new real property. return AddProperty(name, value, attributes); } Object* JSObject::ReplaceSlowProperty(String* name, Object* value, PropertyAttributes attributes) { StringDictionary* dictionary = property_dictionary(); int old_index = dictionary->FindEntry(name); int new_enumeration_index = 0; // 0 means "Use the next available index." if (old_index != -1) { // All calls to ReplaceSlowProperty have had all transitions removed. ASSERT(!dictionary->DetailsAt(old_index).IsTransition()); new_enumeration_index = dictionary->DetailsAt(old_index).index(); } PropertyDetails new_details(attributes, NORMAL, new_enumeration_index); return SetNormalizedProperty(name, value, new_details); } Object* JSObject::ConvertDescriptorToFieldAndMapTransition( String* name, Object* new_value, PropertyAttributes attributes) { Map* old_map = map(); Object* result = ConvertDescriptorToField(name, new_value, attributes); if (result->IsFailure()) return result; // If we get to this point we have succeeded - do not return failure // after this point. Later stuff is optional. if (!HasFastProperties()) { return result; } // Do not add transitions to the map of "new Object()". if (map() == Top::context()->global_context()->object_function()->map()) { return result; } MapTransitionDescriptor transition(name, map(), attributes); Object* new_descriptors = old_map->instance_descriptors()-> CopyInsert(&transition, KEEP_TRANSITIONS); if (new_descriptors->IsFailure()) return result; // Yes, return _result_. old_map->set_instance_descriptors(DescriptorArray::cast(new_descriptors)); return result; } Object* JSObject::ConvertDescriptorToField(String* name, Object* new_value, PropertyAttributes attributes) { if (map()->unused_property_fields() == 0 && properties()->length() > kMaxFastProperties) { Object* obj = NormalizeProperties(CLEAR_INOBJECT_PROPERTIES, 0); if (obj->IsFailure()) return obj; return ReplaceSlowProperty(name, new_value, attributes); } int index = map()->NextFreePropertyIndex(); FieldDescriptor new_field(name, index, attributes); // Make a new DescriptorArray replacing an entry with FieldDescriptor. Object* descriptors_unchecked = map()->instance_descriptors()-> CopyInsert(&new_field, REMOVE_TRANSITIONS); if (descriptors_unchecked->IsFailure()) return descriptors_unchecked; DescriptorArray* new_descriptors = DescriptorArray::cast(descriptors_unchecked); // Make a new map for the object. Object* new_map_unchecked = map()->CopyDropDescriptors(); if (new_map_unchecked->IsFailure()) return new_map_unchecked; Map* new_map = Map::cast(new_map_unchecked); new_map->set_instance_descriptors(new_descriptors); // Make new properties array if necessary. FixedArray* new_properties = 0; // Will always be NULL or a valid pointer. int new_unused_property_fields = map()->unused_property_fields() - 1; if (map()->unused_property_fields() == 0) { new_unused_property_fields = kFieldsAdded - 1; Object* new_properties_unchecked = properties()->CopySize(properties()->length() + kFieldsAdded); if (new_properties_unchecked->IsFailure()) return new_properties_unchecked; new_properties = FixedArray::cast(new_properties_unchecked); } // Update pointers to commit changes. // Object points to the new map. new_map->set_unused_property_fields(new_unused_property_fields); set_map(new_map); if (new_properties) { set_properties(FixedArray::cast(new_properties)); } return FastPropertyAtPut(index, new_value); } Object* JSObject::SetPropertyWithInterceptor(String* name, Object* value, PropertyAttributes attributes) { HandleScope scope; Handle<JSObject> this_handle(this); Handle<String> name_handle(name); Handle<Object> value_handle(value); Handle<InterceptorInfo> interceptor(GetNamedInterceptor()); if (!interceptor->setter()->IsUndefined()) { LOG(ApiNamedPropertyAccess("interceptor-named-set", this, name)); CustomArguments args(interceptor->data(), this, this); v8::AccessorInfo info(args.end()); v8::NamedPropertySetter setter = v8::ToCData<v8::NamedPropertySetter>(interceptor->setter()); v8::Handle<v8::Value> result; { // Leaving JavaScript. VMState state(EXTERNAL); Handle<Object> value_unhole(value->IsTheHole() ? Heap::undefined_value() : value); result = setter(v8::Utils::ToLocal(name_handle), v8::Utils::ToLocal(value_unhole), info); } RETURN_IF_SCHEDULED_EXCEPTION(); if (!result.IsEmpty()) return *value_handle; } Object* raw_result = this_handle->SetPropertyPostInterceptor(*name_handle, *value_handle, attributes); RETURN_IF_SCHEDULED_EXCEPTION(); return raw_result; } Object* JSObject::SetProperty(String* name, Object* value, PropertyAttributes attributes) { LookupResult result; LocalLookup(name, &result); return SetProperty(&result, name, value, attributes); } Object* JSObject::SetPropertyWithCallback(Object* structure, String* name, Object* value, JSObject* holder) { HandleScope scope; // We should never get here to initialize a const with the hole // value since a const declaration would conflict with the setter. ASSERT(!value->IsTheHole()); Handle<Object> value_handle(value); // To accommodate both the old and the new api we switch on the // data structure used to store the callbacks. Eventually proxy // callbacks should be phased out. if (structure->IsProxy()) { AccessorDescriptor* callback = reinterpret_cast<AccessorDescriptor*>(Proxy::cast(structure)->proxy()); Object* obj = (callback->setter)(this, value, callback->data); RETURN_IF_SCHEDULED_EXCEPTION(); if (obj->IsFailure()) return obj; return *value_handle; } if (structure->IsAccessorInfo()) { // api style callbacks AccessorInfo* data = AccessorInfo::cast(structure); Object* call_obj = data->setter(); v8::AccessorSetter call_fun = v8::ToCData<v8::AccessorSetter>(call_obj); if (call_fun == NULL) return value; Handle<String> key(name); LOG(ApiNamedPropertyAccess("store", this, name)); CustomArguments args(data->data(), this, JSObject::cast(holder)); v8::AccessorInfo info(args.end()); { // Leaving JavaScript. VMState state(EXTERNAL); call_fun(v8::Utils::ToLocal(key), v8::Utils::ToLocal(value_handle), info); } RETURN_IF_SCHEDULED_EXCEPTION(); return *value_handle; } if (structure->IsFixedArray()) { Object* setter = FixedArray::cast(structure)->get(kSetterIndex); if (setter->IsJSFunction()) { return SetPropertyWithDefinedSetter(JSFunction::cast(setter), value); } else { Handle<String> key(name); Handle<Object> holder_handle(holder); Handle<Object> args[2] = { key, holder_handle }; return Top::Throw(*Factory::NewTypeError("no_setter_in_callback", HandleVector(args, 2))); } } UNREACHABLE(); return 0; } Object* JSObject::SetPropertyWithDefinedSetter(JSFunction* setter, Object* value) { Handle<Object> value_handle(value); Handle<JSFunction> fun(JSFunction::cast(setter)); Handle<JSObject> self(this); #ifdef ENABLE_DEBUGGER_SUPPORT // Handle stepping into a setter if step into is active. if (Debug::StepInActive()) { Debug::HandleStepIn(fun, Handle<Object>::null(), 0, false); } #endif bool has_pending_exception; Object** argv[] = { value_handle.location() }; Execution::Call(fun, self, 1, argv, &has_pending_exception); // Check for pending exception and return the result. if (has_pending_exception) return Failure::Exception(); return *value_handle; } void JSObject::LookupCallbackSetterInPrototypes(String* name, LookupResult* result) { for (Object* pt = GetPrototype(); pt != Heap::null_value(); pt = pt->GetPrototype()) { JSObject::cast(pt)->LocalLookupRealNamedProperty(name, result); if (result->IsProperty()) { if (result->IsReadOnly()) { result->NotFound(); return; } if (result->type() == CALLBACKS) { return; } } } result->NotFound(); } Object* JSObject::LookupCallbackSetterInPrototypes(uint32_t index) { for (Object* pt = GetPrototype(); pt != Heap::null_value(); pt = pt->GetPrototype()) { if (!JSObject::cast(pt)->HasDictionaryElements()) { continue; } NumberDictionary* dictionary = JSObject::cast(pt)->element_dictionary(); int entry = dictionary->FindEntry(index); if (entry != NumberDictionary::kNotFound) { Object* element = dictionary->ValueAt(entry); PropertyDetails details = dictionary->DetailsAt(entry); if (details.type() == CALLBACKS) { // Only accessors allowed as elements. return FixedArray::cast(element)->get(kSetterIndex); } } } return Heap::undefined_value(); } void JSObject::LookupInDescriptor(String* name, LookupResult* result) { DescriptorArray* descriptors = map()->instance_descriptors(); int number = DescriptorLookupCache::Lookup(descriptors, name); if (number == DescriptorLookupCache::kAbsent) { number = descriptors->Search(name); DescriptorLookupCache::Update(descriptors, name, number); } if (number != DescriptorArray::kNotFound) { result->DescriptorResult(this, descriptors->GetDetails(number), number); } else { result->NotFound(); } } void JSObject::LocalLookupRealNamedProperty(String* name, LookupResult* result) { if (IsJSGlobalProxy()) { Object* proto = GetPrototype(); if (proto->IsNull()) return result->NotFound(); ASSERT(proto->IsJSGlobalObject()); return JSObject::cast(proto)->LocalLookupRealNamedProperty(name, result); } if (HasFastProperties()) { LookupInDescriptor(name, result); if (result->IsFound()) { // A property, a map transition or a null descriptor was found. // We return all of these result types because // LocalLookupRealNamedProperty is used when setting properties // where map transitions and null descriptors are handled. ASSERT(result->holder() == this && result->type() != NORMAL); // Disallow caching for uninitialized constants. These can only // occur as fields. if (result->IsReadOnly() && result->type() == FIELD && FastPropertyAt(result->GetFieldIndex())->IsTheHole()) { result->DisallowCaching(); } return; } } else { int entry = property_dictionary()->FindEntry(name); if (entry != StringDictionary::kNotFound) { Object* value = property_dictionary()->ValueAt(entry); if (IsGlobalObject()) { PropertyDetails d = property_dictionary()->DetailsAt(entry); if (d.IsDeleted()) { result->NotFound(); return; } value = JSGlobalPropertyCell::cast(value)->value(); } // Make sure to disallow caching for uninitialized constants // found in the dictionary-mode objects. if (value->IsTheHole()) result->DisallowCaching(); result->DictionaryResult(this, entry); return; } // Slow case object skipped during lookup. Do not use inline caching. if (!IsGlobalObject()) result->DisallowCaching(); } result->NotFound(); } void JSObject::LookupRealNamedProperty(String* name, LookupResult* result) { LocalLookupRealNamedProperty(name, result); if (result->IsProperty()) return; LookupRealNamedPropertyInPrototypes(name, result); } void JSObject::LookupRealNamedPropertyInPrototypes(String* name, LookupResult* result) { for (Object* pt = GetPrototype(); pt != Heap::null_value(); pt = JSObject::cast(pt)->GetPrototype()) { JSObject::cast(pt)->LocalLookupRealNamedProperty(name, result); if (result->IsProperty() && (result->type() != INTERCEPTOR)) return; } result->NotFound(); } // We only need to deal with CALLBACKS and INTERCEPTORS Object* JSObject::SetPropertyWithFailedAccessCheck(LookupResult* result, String* name, Object* value) { if (!result->IsProperty()) { LookupCallbackSetterInPrototypes(name, result); } if (result->IsProperty()) { if (!result->IsReadOnly()) { switch (result->type()) { case CALLBACKS: { Object* obj = result->GetCallbackObject(); if (obj->IsAccessorInfo()) { AccessorInfo* info = AccessorInfo::cast(obj); if (info->all_can_write()) { return SetPropertyWithCallback(result->GetCallbackObject(), name, value, result->holder()); } } break; } case INTERCEPTOR: { // Try lookup real named properties. Note that only property can be // set is callbacks marked as ALL_CAN_WRITE on the prototype chain. LookupResult r; LookupRealNamedProperty(name, &r); if (r.IsProperty()) { return SetPropertyWithFailedAccessCheck(&r, name, value); } break; } default: { break; } } } } Top::ReportFailedAccessCheck(this, v8::ACCESS_SET); return value; } Object* JSObject::SetProperty(LookupResult* result, String* name, Object* value, PropertyAttributes attributes) { // Make sure that the top context does not change when doing callbacks or // interceptor calls. AssertNoContextChange ncc; // Optimization for 2-byte strings often used as keys in a decompression // dictionary. We make these short keys into symbols to avoid constantly // reallocating them. if (!name->IsSymbol() && name->length() <= 2) { Object* symbol_version = Heap::LookupSymbol(name); if (!symbol_version->IsFailure()) name = String::cast(symbol_version); } // Check access rights if needed. if (IsAccessCheckNeeded() && !Top::MayNamedAccess(this, name, v8::ACCESS_SET)) { return SetPropertyWithFailedAccessCheck(result, name, value); } if (IsJSGlobalProxy()) { Object* proto = GetPrototype(); if (proto->IsNull()) return value; ASSERT(proto->IsJSGlobalObject()); return JSObject::cast(proto)->SetProperty(result, name, value, attributes); } if (!result->IsProperty() && !IsJSContextExtensionObject()) { // We could not find a local property so let's check whether there is an // accessor that wants to handle the property. LookupResult accessor_result; LookupCallbackSetterInPrototypes(name, &accessor_result); if (accessor_result.IsProperty()) { return SetPropertyWithCallback(accessor_result.GetCallbackObject(), name, value, accessor_result.holder()); } } if (!result->IsFound()) { // Neither properties nor transitions found. return AddProperty(name, value, attributes); } if (result->IsReadOnly() && result->IsProperty()) return value; // This is a real property that is not read-only, or it is a // transition or null descriptor and there are no setters in the prototypes. switch (result->type()) { case NORMAL: return SetNormalizedProperty(result, value); case FIELD: return FastPropertyAtPut(result->GetFieldIndex(), value); case MAP_TRANSITION: if (attributes == result->GetAttributes()) { // Only use map transition if the attributes match. return AddFastPropertyUsingMap(result->GetTransitionMap(), name, value); } return ConvertDescriptorToField(name, value, attributes); case CONSTANT_FUNCTION: // Only replace the function if necessary. if (value == result->GetConstantFunction()) return value; // Preserve the attributes of this existing property. attributes = result->GetAttributes(); return ConvertDescriptorToField(name, value, attributes); case CALLBACKS: return SetPropertyWithCallback(result->GetCallbackObject(), name, value, result->holder()); case INTERCEPTOR: return SetPropertyWithInterceptor(name, value, attributes); case CONSTANT_TRANSITION: // Replace with a MAP_TRANSITION to a new map with a FIELD, even // if the value is a function. return ConvertDescriptorToFieldAndMapTransition(name, value, attributes); case NULL_DESCRIPTOR: return ConvertDescriptorToFieldAndMapTransition(name, value, attributes); default: UNREACHABLE(); } UNREACHABLE(); return value; } // Set a real local property, even if it is READ_ONLY. If the property is not // present, add it with attributes NONE. This code is an exact clone of // SetProperty, with the check for IsReadOnly and the check for a // callback setter removed. The two lines looking up the LookupResult // result are also added. If one of the functions is changed, the other // should be. Object* JSObject::IgnoreAttributesAndSetLocalProperty( String* name, Object* value, PropertyAttributes attributes) { // Make sure that the top context does not change when doing callbacks or // interceptor calls. AssertNoContextChange ncc; LookupResult result; LocalLookup(name, &result); // Check access rights if needed. if (IsAccessCheckNeeded() && !Top::MayNamedAccess(this, name, v8::ACCESS_SET)) { return SetPropertyWithFailedAccessCheck(&result, name, value); } if (IsJSGlobalProxy()) { Object* proto = GetPrototype(); if (proto->IsNull()) return value; ASSERT(proto->IsJSGlobalObject()); return JSObject::cast(proto)->IgnoreAttributesAndSetLocalProperty( name, value, attributes); } // Check for accessor in prototype chain removed here in clone. if (!result.IsFound()) { // Neither properties nor transitions found. return AddProperty(name, value, attributes); } PropertyDetails details = PropertyDetails(attributes, NORMAL); // Check of IsReadOnly removed from here in clone. switch (result.type()) { case NORMAL: return SetNormalizedProperty(name, value, details); case FIELD: return FastPropertyAtPut(result.GetFieldIndex(), value); case MAP_TRANSITION: if (attributes == result.GetAttributes()) { // Only use map transition if the attributes match. return AddFastPropertyUsingMap(result.GetTransitionMap(), name, value); } return ConvertDescriptorToField(name, value, attributes); case CONSTANT_FUNCTION: // Only replace the function if necessary. if (value == result.GetConstantFunction()) return value; // Preserve the attributes of this existing property. attributes = result.GetAttributes(); return ConvertDescriptorToField(name, value, attributes); case CALLBACKS: case INTERCEPTOR: // Override callback in clone return ConvertDescriptorToField(name, value, attributes); case CONSTANT_TRANSITION: // Replace with a MAP_TRANSITION to a new map with a FIELD, even // if the value is a function. return ConvertDescriptorToFieldAndMapTransition(name, value, attributes); case NULL_DESCRIPTOR: return ConvertDescriptorToFieldAndMapTransition(name, value, attributes); default: UNREACHABLE(); } UNREACHABLE(); return value; } PropertyAttributes JSObject::GetPropertyAttributePostInterceptor( JSObject* receiver, String* name, bool continue_search) { // Check local property, ignore interceptor. LookupResult result; LocalLookupRealNamedProperty(name, &result); if (result.IsProperty()) return result.GetAttributes(); if (continue_search) { // Continue searching via the prototype chain. Object* pt = GetPrototype(); if (pt != Heap::null_value()) { return JSObject::cast(pt)-> GetPropertyAttributeWithReceiver(receiver, name); } } return ABSENT; } PropertyAttributes JSObject::GetPropertyAttributeWithInterceptor( JSObject* receiver, String* name, bool continue_search) { // Make sure that the top context does not change when doing // callbacks or interceptor calls. AssertNoContextChange ncc; HandleScope scope; Handle<InterceptorInfo> interceptor(GetNamedInterceptor()); Handle<JSObject> receiver_handle(receiver); Handle<JSObject> holder_handle(this); Handle<String> name_handle(name); CustomArguments args(interceptor->data(), receiver, this); v8::AccessorInfo info(args.end()); if (!interceptor->query()->IsUndefined()) { v8::NamedPropertyQuery query = v8::ToCData<v8::NamedPropertyQuery>(interceptor->query()); LOG(ApiNamedPropertyAccess("interceptor-named-has", *holder_handle, name)); v8::Handle<v8::Boolean> result; { // Leaving JavaScript. VMState state(EXTERNAL); result = query(v8::Utils::ToLocal(name_handle), info); } if (!result.IsEmpty()) { // Convert the boolean result to a property attribute // specification. return result->IsTrue() ? NONE : ABSENT; } } else if (!interceptor->getter()->IsUndefined()) { v8::NamedPropertyGetter getter = v8::ToCData<v8::NamedPropertyGetter>(interceptor->getter()); LOG(ApiNamedPropertyAccess("interceptor-named-get-has", this, name)); v8::Handle<v8::Value> result; { // Leaving JavaScript. VMState state(EXTERNAL); result = getter(v8::Utils::ToLocal(name_handle), info); } if (!result.IsEmpty()) return NONE; } return holder_handle->GetPropertyAttributePostInterceptor(*receiver_handle, *name_handle, continue_search); } PropertyAttributes JSObject::GetPropertyAttributeWithReceiver( JSObject* receiver, String* key) { uint32_t index = 0; if (key->AsArrayIndex(&index)) { if (HasElementWithReceiver(receiver, index)) return NONE; return ABSENT; } // Named property. LookupResult result; Lookup(key, &result); return GetPropertyAttribute(receiver, &result, key, true); } PropertyAttributes JSObject::GetPropertyAttribute(JSObject* receiver, LookupResult* result, String* name, bool continue_search) { // Check access rights if needed. if (IsAccessCheckNeeded() && !Top::MayNamedAccess(this, name, v8::ACCESS_HAS)) { return GetPropertyAttributeWithFailedAccessCheck(receiver, result, name, continue_search); } if (result->IsProperty()) { switch (result->type()) { case NORMAL: // fall through case FIELD: case CONSTANT_FUNCTION: case CALLBACKS: return result->GetAttributes(); case INTERCEPTOR: return result->holder()-> GetPropertyAttributeWithInterceptor(receiver, name, continue_search); default: UNREACHABLE(); } } return ABSENT; } PropertyAttributes JSObject::GetLocalPropertyAttribute(String* name) { // Check whether the name is an array index. uint32_t index = 0; if (name->AsArrayIndex(&index)) { if (HasLocalElement(index)) return NONE; return ABSENT; } // Named property. LookupResult result; LocalLookup(name, &result); return GetPropertyAttribute(this, &result, name, false); } Object* JSObject::NormalizeProperties(PropertyNormalizationMode mode, int expected_additional_properties) { if (!HasFastProperties()) return this; // The global object is always normalized. ASSERT(!IsGlobalObject()); // Allocate new content. int property_count = map()->NumberOfDescribedProperties(); if (expected_additional_properties > 0) { property_count += expected_additional_properties; } else { property_count += 2; // Make space for two more properties. } Object* obj = StringDictionary::Allocate(property_count * 2); if (obj->IsFailure()) return obj; StringDictionary* dictionary = StringDictionary::cast(obj); DescriptorArray* descs = map()->instance_descriptors(); for (int i = 0; i < descs->number_of_descriptors(); i++) { PropertyDetails details = descs->GetDetails(i); switch (details.type()) { case CONSTANT_FUNCTION: { PropertyDetails d = PropertyDetails(details.attributes(), NORMAL, details.index()); Object* value = descs->GetConstantFunction(i); Object* result = dictionary->Add(descs->GetKey(i), value, d); if (result->IsFailure()) return result; dictionary = StringDictionary::cast(result); break; } case FIELD: { PropertyDetails d = PropertyDetails(details.attributes(), NORMAL, details.index()); Object* value = FastPropertyAt(descs->GetFieldIndex(i)); Object* result = dictionary->Add(descs->GetKey(i), value, d); if (result->IsFailure()) return result; dictionary = StringDictionary::cast(result); break; } case CALLBACKS: { PropertyDetails d = PropertyDetails(details.attributes(), CALLBACKS, details.index()); Object* value = descs->GetCallbacksObject(i); Object* result = dictionary->Add(descs->GetKey(i), value, d); if (result->IsFailure()) return result; dictionary = StringDictionary::cast(result); break; } case MAP_TRANSITION: case CONSTANT_TRANSITION: case NULL_DESCRIPTOR: case INTERCEPTOR: break; default: UNREACHABLE(); } } // Copy the next enumeration index from instance descriptor. int index = map()->instance_descriptors()->NextEnumerationIndex(); dictionary->SetNextEnumerationIndex(index); // Allocate new map. obj = map()->CopyDropDescriptors(); if (obj->IsFailure()) return obj; Map* new_map = Map::cast(obj); // Clear inobject properties if needed by adjusting the instance size and // putting in a filler object instead of the inobject properties. if (mode == CLEAR_INOBJECT_PROPERTIES && map()->inobject_properties() > 0) { int instance_size_delta = map()->inobject_properties() * kPointerSize; int new_instance_size = map()->instance_size() - instance_size_delta; new_map->set_inobject_properties(0); new_map->set_instance_size(new_instance_size); Heap::CreateFillerObjectAt(this->address() + new_instance_size, instance_size_delta); } new_map->set_unused_property_fields(0); // We have now successfully allocated all the necessary objects. // Changes can now be made with the guarantee that all of them take effect. set_map(new_map); map()->set_instance_descriptors(Heap::empty_descriptor_array()); set_properties(dictionary); Counters::props_to_dictionary.Increment(); #ifdef DEBUG if (FLAG_trace_normalization) { PrintF("Object properties have been normalized:\n"); Print(); } #endif return this; } Object* JSObject::TransformToFastProperties(int unused_property_fields) { if (HasFastProperties()) return this; ASSERT(!IsGlobalObject()); return property_dictionary()-> TransformPropertiesToFastFor(this, unused_property_fields); } Object* JSObject::NormalizeElements() { ASSERT(!HasPixelElements() && !HasExternalArrayElements()); if (HasDictionaryElements()) return this; // Get number of entries. FixedArray* array = FixedArray::cast(elements()); // Compute the effective length. int length = IsJSArray() ? Smi::cast(JSArray::cast(this)->length())->value() : array->length(); Object* obj = NumberDictionary::Allocate(length); if (obj->IsFailure()) return obj; NumberDictionary* dictionary = NumberDictionary::cast(obj); // Copy entries. for (int i = 0; i < length; i++) { Object* value = array->get(i); if (!value->IsTheHole()) { PropertyDetails details = PropertyDetails(NONE, NORMAL); Object* result = dictionary->AddNumberEntry(i, array->get(i), details); if (result->IsFailure()) return result; dictionary = NumberDictionary::cast(result); } } // Switch to using the dictionary as the backing storage for elements. set_elements(dictionary); Counters::elements_to_dictionary.Increment(); #ifdef DEBUG if (FLAG_trace_normalization) { PrintF("Object elements have been normalized:\n"); Print(); } #endif return this; } Object* JSObject::DeletePropertyPostInterceptor(String* name, DeleteMode mode) { // Check local property, ignore interceptor. LookupResult result; LocalLookupRealNamedProperty(name, &result); if (!result.IsProperty()) return Heap::true_value(); // Normalize object if needed. Object* obj = NormalizeProperties(CLEAR_INOBJECT_PROPERTIES, 0); if (obj->IsFailure()) return obj; return DeleteNormalizedProperty(name, mode); } Object* JSObject::DeletePropertyWithInterceptor(String* name) { HandleScope scope; Handle<InterceptorInfo> interceptor(GetNamedInterceptor()); Handle<String> name_handle(name); Handle<JSObject> this_handle(this); if (!interceptor->deleter()->IsUndefined()) { v8::NamedPropertyDeleter deleter = v8::ToCData<v8::NamedPropertyDeleter>(interceptor->deleter()); LOG(ApiNamedPropertyAccess("interceptor-named-delete", *this_handle, name)); CustomArguments args(interceptor->data(), this, this); v8::AccessorInfo info(args.end()); v8::Handle<v8::Boolean> result; { // Leaving JavaScript. VMState state(EXTERNAL); result = deleter(v8::Utils::ToLocal(name_handle), info); } RETURN_IF_SCHEDULED_EXCEPTION(); if (!result.IsEmpty()) { ASSERT(result->IsBoolean()); return *v8::Utils::OpenHandle(*result); } } Object* raw_result = this_handle->DeletePropertyPostInterceptor(*name_handle, NORMAL_DELETION); RETURN_IF_SCHEDULED_EXCEPTION(); return raw_result; } Object* JSObject::DeleteElementPostInterceptor(uint32_t index, DeleteMode mode) { ASSERT(!HasPixelElements() && !HasExternalArrayElements()); switch (GetElementsKind()) { case FAST_ELEMENTS: { uint32_t length = IsJSArray() ? static_cast<uint32_t>(Smi::cast(JSArray::cast(this)->length())->value()) : static_cast<uint32_t>(FixedArray::cast(elements())->length()); if (index < length) { FixedArray::cast(elements())->set_the_hole(index); } break; } case DICTIONARY_ELEMENTS: { NumberDictionary* dictionary = element_dictionary(); int entry = dictionary->FindEntry(index); if (entry != NumberDictionary::kNotFound) { return dictionary->DeleteProperty(entry, mode); } break; } default: UNREACHABLE(); break; } return Heap::true_value(); } Object* JSObject::DeleteElementWithInterceptor(uint32_t index) { // Make sure that the top context does not change when doing // callbacks or interceptor calls. AssertNoContextChange ncc; HandleScope scope; Handle<InterceptorInfo> interceptor(GetIndexedInterceptor()); if (interceptor->deleter()->IsUndefined()) return Heap::false_value(); v8::IndexedPropertyDeleter deleter = v8::ToCData<v8::IndexedPropertyDeleter>(interceptor->deleter()); Handle<JSObject> this_handle(this); LOG(ApiIndexedPropertyAccess("interceptor-indexed-delete", this, index)); CustomArguments args(interceptor->data(), this, this); v8::AccessorInfo info(args.end()); v8::Handle<v8::Boolean> result; { // Leaving JavaScript. VMState state(EXTERNAL); result = deleter(index, info); } RETURN_IF_SCHEDULED_EXCEPTION(); if (!result.IsEmpty()) { ASSERT(result->IsBoolean()); return *v8::Utils::OpenHandle(*result); } Object* raw_result = this_handle->DeleteElementPostInterceptor(index, NORMAL_DELETION); RETURN_IF_SCHEDULED_EXCEPTION(); return raw_result; } Object* JSObject::DeleteElement(uint32_t index, DeleteMode mode) { // Check access rights if needed. if (IsAccessCheckNeeded() && !Top::MayIndexedAccess(this, index, v8::ACCESS_DELETE)) { Top::ReportFailedAccessCheck(this, v8::ACCESS_DELETE); return Heap::false_value(); } if (IsJSGlobalProxy()) { Object* proto = GetPrototype(); if (proto->IsNull()) return Heap::false_value(); ASSERT(proto->IsJSGlobalObject()); return JSGlobalObject::cast(proto)->DeleteElement(index, mode); } if (HasIndexedInterceptor()) { // Skip interceptor if forcing deletion. if (mode == FORCE_DELETION) { return DeleteElementPostInterceptor(index, mode); } return DeleteElementWithInterceptor(index); } switch (GetElementsKind()) { case FAST_ELEMENTS: { uint32_t length = IsJSArray() ? static_cast<uint32_t>(Smi::cast(JSArray::cast(this)->length())->value()) : static_cast<uint32_t>(FixedArray::cast(elements())->length()); if (index < length) { FixedArray::cast(elements())->set_the_hole(index); } break; } case PIXEL_ELEMENTS: case EXTERNAL_BYTE_ELEMENTS: case EXTERNAL_UNSIGNED_BYTE_ELEMENTS: case EXTERNAL_SHORT_ELEMENTS: case EXTERNAL_UNSIGNED_SHORT_ELEMENTS: case EXTERNAL_INT_ELEMENTS: case EXTERNAL_UNSIGNED_INT_ELEMENTS: case EXTERNAL_FLOAT_ELEMENTS: // Pixel and external array elements cannot be deleted. Just // silently ignore here. break; case DICTIONARY_ELEMENTS: { NumberDictionary* dictionary = element_dictionary(); int entry = dictionary->FindEntry(index); if (entry != NumberDictionary::kNotFound) { return dictionary->DeleteProperty(entry, mode); } break; } default: UNREACHABLE(); break; } return Heap::true_value(); } Object* JSObject::DeleteProperty(String* name, DeleteMode mode) { // ECMA-262, 3rd, 8.6.2.5 ASSERT(name->IsString()); // Check access rights if needed. if (IsAccessCheckNeeded() && !Top::MayNamedAccess(this, name, v8::ACCESS_DELETE)) { Top::ReportFailedAccessCheck(this, v8::ACCESS_DELETE); return Heap::false_value(); } if (IsJSGlobalProxy()) { Object* proto = GetPrototype(); if (proto->IsNull()) return Heap::false_value(); ASSERT(proto->IsJSGlobalObject()); return JSGlobalObject::cast(proto)->DeleteProperty(name, mode); } uint32_t index = 0; if (name->AsArrayIndex(&index)) { return DeleteElement(index, mode); } else { LookupResult result; LocalLookup(name, &result); if (!result.IsProperty()) return Heap::true_value(); // Ignore attributes if forcing a deletion. if (result.IsDontDelete() && mode != FORCE_DELETION) { return Heap::false_value(); } // Check for interceptor. if (result.type() == INTERCEPTOR) { // Skip interceptor if forcing a deletion. if (mode == FORCE_DELETION) { return DeletePropertyPostInterceptor(name, mode); } return DeletePropertyWithInterceptor(name); } // Normalize object if needed. Object* obj = NormalizeProperties(CLEAR_INOBJECT_PROPERTIES, 0); if (obj->IsFailure()) return obj; // Make sure the properties are normalized before removing the entry. return DeleteNormalizedProperty(name, mode); } } // Check whether this object references another object. bool JSObject::ReferencesObject(Object* obj) { AssertNoAllocation no_alloc; // Is the object the constructor for this object? if (map()->constructor() == obj) { return true; } // Is the object the prototype for this object? if (map()->prototype() == obj) { return true; } // Check if the object is among the named properties. Object* key = SlowReverseLookup(obj); if (key != Heap::undefined_value()) { return true; } // Check if the object is among the indexed properties. switch (GetElementsKind()) { case PIXEL_ELEMENTS: case EXTERNAL_BYTE_ELEMENTS: case EXTERNAL_UNSIGNED_BYTE_ELEMENTS: case EXTERNAL_SHORT_ELEMENTS: case EXTERNAL_UNSIGNED_SHORT_ELEMENTS: case EXTERNAL_INT_ELEMENTS: case EXTERNAL_UNSIGNED_INT_ELEMENTS: case EXTERNAL_FLOAT_ELEMENTS: // Raw pixels and external arrays do not reference other // objects. break; case FAST_ELEMENTS: { int length = IsJSArray() ? Smi::cast(JSArray::cast(this)->length())->value() : FixedArray::cast(elements())->length(); for (int i = 0; i < length; i++) { Object* element = FixedArray::cast(elements())->get(i); if (!element->IsTheHole() && element == obj) { return true; } } break; } case DICTIONARY_ELEMENTS: { key = element_dictionary()->SlowReverseLookup(obj); if (key != Heap::undefined_value()) { return true; } break; } default: UNREACHABLE(); break; } // For functions check the context. Boilerplate functions do // not have to be traversed since they have no real context. if (IsJSFunction() && !JSFunction::cast(this)->IsBoilerplate()) { // Get the constructor function for arguments array. JSObject* arguments_boilerplate = Top::context()->global_context()->arguments_boilerplate(); JSFunction* arguments_function = JSFunction::cast(arguments_boilerplate->map()->constructor()); // Get the context and don't check if it is the global context. JSFunction* f = JSFunction::cast(this); Context* context = f->context(); if (context->IsGlobalContext()) { return false; } // Check the non-special context slots. for (int i = Context::MIN_CONTEXT_SLOTS; i < context->length(); i++) { // Only check JS objects. if (context->get(i)->IsJSObject()) { JSObject* ctxobj = JSObject::cast(context->get(i)); // If it is an arguments array check the content. if (ctxobj->map()->constructor() == arguments_function) { if (ctxobj->ReferencesObject(obj)) { return true; } } else if (ctxobj == obj) { return true; } } } // Check the context extension if any. if (context->has_extension()) { return context->extension()->ReferencesObject(obj); } } // No references to object. return false; } // Tests for the fast common case for property enumeration: // - This object and all prototypes has an enum cache (which means that it has // no interceptors and needs no access checks). // - This object has no elements. // - No prototype has enumerable properties/elements. bool JSObject::IsSimpleEnum() { for (Object* o = this; o != Heap::null_value(); o = JSObject::cast(o)->GetPrototype()) { JSObject* curr = JSObject::cast(o); if (!curr->map()->instance_descriptors()->HasEnumCache()) return false; ASSERT(!curr->HasNamedInterceptor()); ASSERT(!curr->HasIndexedInterceptor()); ASSERT(!curr->IsAccessCheckNeeded()); if (curr->NumberOfEnumElements() > 0) return false; if (curr != this) { FixedArray* curr_fixed_array = FixedArray::cast(curr->map()->instance_descriptors()->GetEnumCache()); if (curr_fixed_array->length() > 0) return false; } } return true; } int Map::NumberOfDescribedProperties() { int result = 0; DescriptorArray* descs = instance_descriptors(); for (int i = 0; i < descs->number_of_descriptors(); i++) { if (descs->IsProperty(i)) result++; } return result; } int Map::PropertyIndexFor(String* name) { DescriptorArray* descs = instance_descriptors(); for (int i = 0; i < descs->number_of_descriptors(); i++) { if (name->Equals(descs->GetKey(i)) && !descs->IsNullDescriptor(i)) { return descs->GetFieldIndex(i); } } return -1; } int Map::NextFreePropertyIndex() { int max_index = -1; DescriptorArray* descs = instance_descriptors(); for (int i = 0; i < descs->number_of_descriptors(); i++) { if (descs->GetType(i) == FIELD) { int current_index = descs->GetFieldIndex(i); if (current_index > max_index) max_index = current_index; } } return max_index + 1; } AccessorDescriptor* Map::FindAccessor(String* name) { DescriptorArray* descs = instance_descriptors(); for (int i = 0; i < descs->number_of_descriptors(); i++) { if (name->Equals(descs->GetKey(i)) && descs->GetType(i) == CALLBACKS) { return descs->GetCallbacks(i); } } return NULL; } void JSObject::LocalLookup(String* name, LookupResult* result) { ASSERT(name->IsString()); if (IsJSGlobalProxy()) { Object* proto = GetPrototype(); if (proto->IsNull()) return result->NotFound(); ASSERT(proto->IsJSGlobalObject()); return JSObject::cast(proto)->LocalLookup(name, result); } // Do not use inline caching if the object is a non-global object // that requires access checks. if (!IsJSGlobalProxy() && IsAccessCheckNeeded()) { result->DisallowCaching(); } // Check __proto__ before interceptor. if (name->Equals(Heap::Proto_symbol()) && !IsJSContextExtensionObject()) { result->ConstantResult(this); return; } // Check for lookup interceptor except when bootstrapping. if (HasNamedInterceptor() && !Bootstrapper::IsActive()) { result->InterceptorResult(this); return; } LocalLookupRealNamedProperty(name, result); } void JSObject::Lookup(String* name, LookupResult* result) { // Ecma-262 3rd 8.6.2.4 for (Object* current = this; current != Heap::null_value(); current = JSObject::cast(current)->GetPrototype()) { JSObject::cast(current)->LocalLookup(name, result); if (result->IsProperty()) return; } result->NotFound(); } // Search object and it's prototype chain for callback properties. void JSObject::LookupCallback(String* name, LookupResult* result) { for (Object* current = this; current != Heap::null_value(); current = JSObject::cast(current)->GetPrototype()) { JSObject::cast(current)->LocalLookupRealNamedProperty(name, result); if (result->IsProperty() && result->type() == CALLBACKS) return; } result->NotFound(); } Object* JSObject::DefineGetterSetter(String* name, PropertyAttributes attributes) { // Make sure that the top context does not change when doing callbacks or // interceptor calls. AssertNoContextChange ncc; // Check access rights if needed. if (IsAccessCheckNeeded() && !Top::MayNamedAccess(this, name, v8::ACCESS_SET)) { Top::ReportFailedAccessCheck(this, v8::ACCESS_SET); return Heap::undefined_value(); } // Try to flatten before operating on the string. name->TryFlattenIfNotFlat(); // Check if there is an API defined callback object which prohibits // callback overwriting in this object or it's prototype chain. // This mechanism is needed for instance in a browser setting, where // certain accessors such as window.location should not be allowed // to be overwritten because allowing overwriting could potentially // cause security problems. LookupResult callback_result; LookupCallback(name, &callback_result); if (callback_result.IsFound()) { Object* obj = callback_result.GetCallbackObject(); if (obj->IsAccessorInfo() && AccessorInfo::cast(obj)->prohibits_overwriting()) { return Heap::undefined_value(); } } uint32_t index; bool is_element = name->AsArrayIndex(&index); if (is_element && IsJSArray()) return Heap::undefined_value(); if (is_element) { switch (GetElementsKind()) { case FAST_ELEMENTS: break; case PIXEL_ELEMENTS: case EXTERNAL_BYTE_ELEMENTS: case EXTERNAL_UNSIGNED_BYTE_ELEMENTS: case EXTERNAL_SHORT_ELEMENTS: case EXTERNAL_UNSIGNED_SHORT_ELEMENTS: case EXTERNAL_INT_ELEMENTS: case EXTERNAL_UNSIGNED_INT_ELEMENTS: case EXTERNAL_FLOAT_ELEMENTS: // Ignore getters and setters on pixel and external array // elements. return Heap::undefined_value(); case DICTIONARY_ELEMENTS: { // Lookup the index. NumberDictionary* dictionary = element_dictionary(); int entry = dictionary->FindEntry(index); if (entry != NumberDictionary::kNotFound) { Object* result = dictionary->ValueAt(entry); PropertyDetails details = dictionary->DetailsAt(entry); if (details.IsReadOnly()) return Heap::undefined_value(); if (details.type() == CALLBACKS) { // Only accessors allowed as elements. ASSERT(result->IsFixedArray()); return result; } } break; } default: UNREACHABLE(); break; } } else { // Lookup the name. LookupResult result; LocalLookup(name, &result); if (result.IsProperty()) { if (result.IsReadOnly()) return Heap::undefined_value(); if (result.type() == CALLBACKS) { Object* obj = result.GetCallbackObject(); if (obj->IsFixedArray()) { // The object might be in fast mode even though it has // a getter/setter. Object* ok = NormalizeProperties(CLEAR_INOBJECT_PROPERTIES, 0); if (ok->IsFailure()) return ok; PropertyDetails details = PropertyDetails(attributes, CALLBACKS); SetNormalizedProperty(name, obj, details); return obj; } } } } // Allocate the fixed array to hold getter and setter. Object* structure = Heap::AllocateFixedArray(2, TENURED); if (structure->IsFailure()) return structure; PropertyDetails details = PropertyDetails(attributes, CALLBACKS); if (is_element) { // Normalize object to make this operation simple. Object* ok = NormalizeElements(); if (ok->IsFailure()) return ok; // Update the dictionary with the new CALLBACKS property. Object* dict = element_dictionary()->Set(index, structure, details); if (dict->IsFailure()) return dict; // If name is an index we need to stay in slow case. NumberDictionary* elements = NumberDictionary::cast(dict); elements->set_requires_slow_elements(); // Set the potential new dictionary on the object. set_elements(NumberDictionary::cast(dict)); } else { // Normalize object to make this operation simple. Object* ok = NormalizeProperties(CLEAR_INOBJECT_PROPERTIES, 0); if (ok->IsFailure()) return ok; // For the global object allocate a new map to invalidate the global inline // caches which have a global property cell reference directly in the code. if (IsGlobalObject()) { Object* new_map = map()->CopyDropDescriptors(); if (new_map->IsFailure()) return new_map; set_map(Map::cast(new_map)); } // Update the dictionary with the new CALLBACKS property. return SetNormalizedProperty(name, structure, details); } return structure; } Object* JSObject::DefineAccessor(String* name, bool is_getter, JSFunction* fun, PropertyAttributes attributes) { // Check access rights if needed. if (IsAccessCheckNeeded() && !Top::MayNamedAccess(this, name, v8::ACCESS_HAS)) { Top::ReportFailedAccessCheck(this, v8::ACCESS_HAS); return Heap::undefined_value(); } if (IsJSGlobalProxy()) { Object* proto = GetPrototype(); if (proto->IsNull()) return this; ASSERT(proto->IsJSGlobalObject()); return JSObject::cast(proto)->DefineAccessor(name, is_getter, fun, attributes); } Object* array = DefineGetterSetter(name, attributes); if (array->IsFailure() || array->IsUndefined()) return array; FixedArray::cast(array)->set(is_getter ? 0 : 1, fun); return this; } Object* JSObject::LookupAccessor(String* name, bool is_getter) { // Make sure that the top context does not change when doing callbacks or // interceptor calls. AssertNoContextChange ncc; // Check access rights if needed. if (IsAccessCheckNeeded() && !Top::MayNamedAccess(this, name, v8::ACCESS_HAS)) { Top::ReportFailedAccessCheck(this, v8::ACCESS_HAS); return Heap::undefined_value(); } // Make the lookup and include prototypes. int accessor_index = is_getter ? kGetterIndex : kSetterIndex; uint32_t index; if (name->AsArrayIndex(&index)) { for (Object* obj = this; obj != Heap::null_value(); obj = JSObject::cast(obj)->GetPrototype()) { JSObject* js_object = JSObject::cast(obj); if (js_object->HasDictionaryElements()) { NumberDictionary* dictionary = js_object->element_dictionary(); int entry = dictionary->FindEntry(index); if (entry != NumberDictionary::kNotFound) { Object* element = dictionary->ValueAt(entry); PropertyDetails details = dictionary->DetailsAt(entry); if (details.type() == CALLBACKS) { // Only accessors allowed as elements. return FixedArray::cast(element)->get(accessor_index); } } } } } else { for (Object* obj = this; obj != Heap::null_value(); obj = JSObject::cast(obj)->GetPrototype()) { LookupResult result; JSObject::cast(obj)->LocalLookup(name, &result); if (result.IsProperty()) { if (result.IsReadOnly()) return Heap::undefined_value(); if (result.type() == CALLBACKS) { Object* obj = result.GetCallbackObject(); if (obj->IsFixedArray()) { return FixedArray::cast(obj)->get(accessor_index); } } } } } return Heap::undefined_value(); } Object* JSObject::SlowReverseLookup(Object* value) { if (HasFastProperties()) { DescriptorArray* descs = map()->instance_descriptors(); for (int i = 0; i < descs->number_of_descriptors(); i++) { if (descs->GetType(i) == FIELD) { if (FastPropertyAt(descs->GetFieldIndex(i)) == value) { return descs->GetKey(i); } } else if (descs->GetType(i) == CONSTANT_FUNCTION) { if (descs->GetConstantFunction(i) == value) { return descs->GetKey(i); } } } return Heap::undefined_value(); } else { return property_dictionary()->SlowReverseLookup(value); } } Object* Map::CopyDropDescriptors() { Object* result = Heap::AllocateMap(instance_type(), instance_size()); if (result->IsFailure()) return result; Map::cast(result)->set_prototype(prototype()); Map::cast(result)->set_constructor(constructor()); // Don't copy descriptors, so map transitions always remain a forest. // If we retained the same descriptors we would have two maps // pointing to the same transition which is bad because the garbage // collector relies on being able to reverse pointers from transitions // to maps. If properties need to be retained use CopyDropTransitions. Map::cast(result)->set_instance_descriptors(Heap::empty_descriptor_array()); // Please note instance_type and instance_size are set when allocated. Map::cast(result)->set_inobject_properties(inobject_properties()); Map::cast(result)->set_unused_property_fields(unused_property_fields()); // If the map has pre-allocated properties always start out with a descriptor // array describing these properties. if (pre_allocated_property_fields() > 0) { ASSERT(constructor()->IsJSFunction()); JSFunction* ctor = JSFunction::cast(constructor()); Object* descriptors = ctor->initial_map()->instance_descriptors()->RemoveTransitions(); if (descriptors->IsFailure()) return descriptors; Map::cast(result)->set_instance_descriptors( DescriptorArray::cast(descriptors)); Map::cast(result)->set_pre_allocated_property_fields( pre_allocated_property_fields()); } Map::cast(result)->set_bit_field(bit_field()); Map::cast(result)->set_bit_field2(bit_field2()); Map::cast(result)->ClearCodeCache(); return result; } Object* Map::CopyDropTransitions() { Object* new_map = CopyDropDescriptors(); if (new_map->IsFailure()) return new_map; Object* descriptors = instance_descriptors()->RemoveTransitions(); if (descriptors->IsFailure()) return descriptors; cast(new_map)->set_instance_descriptors(DescriptorArray::cast(descriptors)); return cast(new_map); } Object* Map::UpdateCodeCache(String* name, Code* code) { ASSERT(code->ic_state() == MONOMORPHIC); FixedArray* cache = code_cache(); // When updating the code cache we disregard the type encoded in the // flags. This allows call constant stubs to overwrite call field // stubs, etc. Code::Flags flags = Code::RemoveTypeFromFlags(code->flags()); // First check whether we can update existing code cache without // extending it. int length = cache->length(); int deleted_index = -1; for (int i = 0; i < length; i += 2) { Object* key = cache->get(i); if (key->IsNull()) { if (deleted_index < 0) deleted_index = i; continue; } if (key->IsUndefined()) { if (deleted_index >= 0) i = deleted_index; cache->set(i + 0, name); cache->set(i + 1, code); return this; } if (name->Equals(String::cast(key))) { Code::Flags found = Code::cast(cache->get(i + 1))->flags(); if (Code::RemoveTypeFromFlags(found) == flags) { cache->set(i + 1, code); return this; } } } // Reached the end of the code cache. If there were deleted // elements, reuse the space for the first of them. if (deleted_index >= 0) { cache->set(deleted_index + 0, name); cache->set(deleted_index + 1, code); return this; } // Extend the code cache with some new entries (at least one). int new_length = length + ((length >> 1) & ~1) + 2; ASSERT((new_length & 1) == 0); // must be a multiple of two Object* result = cache->CopySize(new_length); if (result->IsFailure()) return result; // Add the (name, code) pair to the new cache. cache = FixedArray::cast(result); cache->set(length + 0, name); cache->set(length + 1, code); set_code_cache(cache); return this; } Object* Map::FindInCodeCache(String* name, Code::Flags flags) { FixedArray* cache = code_cache(); int length = cache->length(); for (int i = 0; i < length; i += 2) { Object* key = cache->get(i); // Skip deleted elements. if (key->IsNull()) continue; if (key->IsUndefined()) return key; if (name->Equals(String::cast(key))) { Code* code = Code::cast(cache->get(i + 1)); if (code->flags() == flags) return code; } } return Heap::undefined_value(); } int Map::IndexInCodeCache(Code* code) { FixedArray* array = code_cache(); int len = array->length(); for (int i = 0; i < len; i += 2) { if (array->get(i + 1) == code) return i + 1; } return -1; } void Map::RemoveFromCodeCache(int index) { FixedArray* array = code_cache(); ASSERT(array->length() >= index && array->get(index)->IsCode()); // Use null instead of undefined for deleted elements to distinguish // deleted elements from unused elements. This distinction is used // when looking up in the cache and when updating the cache. array->set_null(index - 1); // key array->set_null(index); // code } void FixedArray::FixedArrayIterateBody(ObjectVisitor* v) { IteratePointers(v, kHeaderSize, kHeaderSize + length() * kPointerSize); } static bool HasKey(FixedArray* array, Object* key) { int len0 = array->length(); for (int i = 0; i < len0; i++) { Object* element = array->get(i); if (element->IsSmi() && key->IsSmi() && (element == key)) return true; if (element->IsString() && key->IsString() && String::cast(element)->Equals(String::cast(key))) { return true; } } return false; } Object* FixedArray::AddKeysFromJSArray(JSArray* array) { ASSERT(!array->HasPixelElements() && !array->HasExternalArrayElements()); switch (array->GetElementsKind()) { case JSObject::FAST_ELEMENTS: return UnionOfKeys(FixedArray::cast(array->elements())); case JSObject::DICTIONARY_ELEMENTS: { NumberDictionary* dict = array->element_dictionary(); int size = dict->NumberOfElements(); // Allocate a temporary fixed array. Object* object = Heap::AllocateFixedArray(size); if (object->IsFailure()) return object; FixedArray* key_array = FixedArray::cast(object); int capacity = dict->Capacity(); int pos = 0; // Copy the elements from the JSArray to the temporary fixed array. for (int i = 0; i < capacity; i++) { if (dict->IsKey(dict->KeyAt(i))) { key_array->set(pos++, dict->ValueAt(i)); } } // Compute the union of this and the temporary fixed array. return UnionOfKeys(key_array); } default: UNREACHABLE(); } UNREACHABLE(); return Heap::null_value(); // Failure case needs to "return" a value. } Object* FixedArray::UnionOfKeys(FixedArray* other) { int len0 = length(); int len1 = other->length(); // Optimize if either is empty. if (len0 == 0) return other; if (len1 == 0) return this; // Compute how many elements are not in this. int extra = 0; for (int y = 0; y < len1; y++) { Object* value = other->get(y); if (!value->IsTheHole() && !HasKey(this, value)) extra++; } if (extra == 0) return this; // Allocate the result Object* obj = Heap::AllocateFixedArray(len0 + extra); if (obj->IsFailure()) return obj; // Fill in the content AssertNoAllocation no_gc; FixedArray* result = FixedArray::cast(obj); WriteBarrierMode mode = result->GetWriteBarrierMode(no_gc); for (int i = 0; i < len0; i++) { result->set(i, get(i), mode); } // Fill in the extra keys. int index = 0; for (int y = 0; y < len1; y++) { Object* value = other->get(y); if (!value->IsTheHole() && !HasKey(this, value)) { result->set(len0 + index, other->get(y), mode); index++; } } ASSERT(extra == index); return result; } Object* FixedArray::CopySize(int new_length) { if (new_length == 0) return Heap::empty_fixed_array(); Object* obj = Heap::AllocateFixedArray(new_length); if (obj->IsFailure()) return obj; FixedArray* result = FixedArray::cast(obj); // Copy the content AssertNoAllocation no_gc; int len = length(); if (new_length < len) len = new_length; result->set_map(map()); WriteBarrierMode mode = result->GetWriteBarrierMode(no_gc); for (int i = 0; i < len; i++) { result->set(i, get(i), mode); } return result; } void FixedArray::CopyTo(int pos, FixedArray* dest, int dest_pos, int len) { AssertNoAllocation no_gc; WriteBarrierMode mode = dest->GetWriteBarrierMode(no_gc); for (int index = 0; index < len; index++) { dest->set(dest_pos+index, get(pos+index), mode); } } #ifdef DEBUG bool FixedArray::IsEqualTo(FixedArray* other) { if (length() != other->length()) return false; for (int i = 0 ; i < length(); ++i) { if (get(i) != other->get(i)) return false; } return true; } #endif Object* DescriptorArray::Allocate(int number_of_descriptors) { if (number_of_descriptors == 0) { return Heap::empty_descriptor_array(); } // Allocate the array of keys. Object* array = Heap::AllocateFixedArray(ToKeyIndex(number_of_descriptors)); if (array->IsFailure()) return array; // Do not use DescriptorArray::cast on incomplete object. FixedArray* result = FixedArray::cast(array); // Allocate the content array and set it in the descriptor array. array = Heap::AllocateFixedArray(number_of_descriptors << 1); if (array->IsFailure()) return array; result->set(kContentArrayIndex, array); result->set(kEnumerationIndexIndex, Smi::FromInt(PropertyDetails::kInitialIndex)); return result; } void DescriptorArray::SetEnumCache(FixedArray* bridge_storage, FixedArray* new_cache) { ASSERT(bridge_storage->length() >= kEnumCacheBridgeLength); if (HasEnumCache()) { FixedArray::cast(get(kEnumerationIndexIndex))-> set(kEnumCacheBridgeCacheIndex, new_cache); } else { if (IsEmpty()) return; // Do nothing for empty descriptor array. FixedArray::cast(bridge_storage)-> set(kEnumCacheBridgeCacheIndex, new_cache); fast_set(FixedArray::cast(bridge_storage), kEnumCacheBridgeEnumIndex, get(kEnumerationIndexIndex)); set(kEnumerationIndexIndex, bridge_storage); } } Object* DescriptorArray::CopyInsert(Descriptor* descriptor, TransitionFlag transition_flag) { // Transitions are only kept when inserting another transition. // This precondition is not required by this function's implementation, but // is currently required by the semantics of maps, so we check it. // Conversely, we filter after replacing, so replacing a transition and // removing all other transitions is not supported. bool remove_transitions = transition_flag == REMOVE_TRANSITIONS; ASSERT(remove_transitions == !descriptor->GetDetails().IsTransition()); ASSERT(descriptor->GetDetails().type() != NULL_DESCRIPTOR); // Ensure the key is a symbol. Object* result = descriptor->KeyToSymbol(); if (result->IsFailure()) return result; int transitions = 0; int null_descriptors = 0; if (remove_transitions) { for (int i = 0; i < number_of_descriptors(); i++) { if (IsTransition(i)) transitions++; if (IsNullDescriptor(i)) null_descriptors++; } } else { for (int i = 0; i < number_of_descriptors(); i++) { if (IsNullDescriptor(i)) null_descriptors++; } } int new_size = number_of_descriptors() - transitions - null_descriptors; // If key is in descriptor, we replace it in-place when filtering. // Count a null descriptor for key as inserted, not replaced. int index = Search(descriptor->GetKey()); const bool inserting = (index == kNotFound); const bool replacing = !inserting; bool keep_enumeration_index = false; if (inserting) { ++new_size; } if (replacing) { // We are replacing an existing descriptor. We keep the enumeration // index of a visible property. PropertyType t = PropertyDetails(GetDetails(index)).type(); if (t == CONSTANT_FUNCTION || t == FIELD || t == CALLBACKS || t == INTERCEPTOR) { keep_enumeration_index = true; } else if (remove_transitions) { // Replaced descriptor has been counted as removed if it is // a transition that will be replaced. Adjust count in this case. ++new_size; } } result = Allocate(new_size); if (result->IsFailure()) return result; DescriptorArray* new_descriptors = DescriptorArray::cast(result); // Set the enumeration index in the descriptors and set the enumeration index // in the result. int enumeration_index = NextEnumerationIndex(); if (!descriptor->GetDetails().IsTransition()) { if (keep_enumeration_index) { descriptor->SetEnumerationIndex( PropertyDetails(GetDetails(index)).index()); } else { descriptor->SetEnumerationIndex(enumeration_index); ++enumeration_index; } } new_descriptors->SetNextEnumerationIndex(enumeration_index); // Copy the descriptors, filtering out transitions and null descriptors, // and inserting or replacing a descriptor. uint32_t descriptor_hash = descriptor->GetKey()->Hash(); int from_index = 0; int to_index = 0; for (; from_index < number_of_descriptors(); from_index++) { String* key = GetKey(from_index); if (key->Hash() > descriptor_hash || key == descriptor->GetKey()) { break; } if (IsNullDescriptor(from_index)) continue; if (remove_transitions && IsTransition(from_index)) continue; new_descriptors->CopyFrom(to_index++, this, from_index); } new_descriptors->Set(to_index++, descriptor); if (replacing) from_index++; for (; from_index < number_of_descriptors(); from_index++) { if (IsNullDescriptor(from_index)) continue; if (remove_transitions && IsTransition(from_index)) continue; new_descriptors->CopyFrom(to_index++, this, from_index); } ASSERT(to_index == new_descriptors->number_of_descriptors()); SLOW_ASSERT(new_descriptors->IsSortedNoDuplicates()); return new_descriptors; } Object* DescriptorArray::RemoveTransitions() { // Remove all transitions and null descriptors. Return a copy of the array // with all transitions removed, or a Failure object if the new array could // not be allocated. // Compute the size of the map transition entries to be removed. int num_removed = 0; for (int i = 0; i < number_of_descriptors(); i++) { if (!IsProperty(i)) num_removed++; } // Allocate the new descriptor array. Object* result = Allocate(number_of_descriptors() - num_removed); if (result->IsFailure()) return result; DescriptorArray* new_descriptors = DescriptorArray::cast(result); // Copy the content. int next_descriptor = 0; for (int i = 0; i < number_of_descriptors(); i++) { if (IsProperty(i)) new_descriptors->CopyFrom(next_descriptor++, this, i); } ASSERT(next_descriptor == new_descriptors->number_of_descriptors()); return new_descriptors; } void DescriptorArray::Sort() { // In-place heap sort. int len = number_of_descriptors(); // Bottom-up max-heap construction. for (int i = 1; i < len; ++i) { int child_index = i; while (child_index > 0) { int parent_index = ((child_index + 1) >> 1) - 1; uint32_t parent_hash = GetKey(parent_index)->Hash(); uint32_t child_hash = GetKey(child_index)->Hash(); if (parent_hash < child_hash) { Swap(parent_index, child_index); } else { break; } child_index = parent_index; } } // Extract elements and create sorted array. for (int i = len - 1; i > 0; --i) { // Put max element at the back of the array. Swap(0, i); // Sift down the new top element. int parent_index = 0; while (true) { int child_index = ((parent_index + 1) << 1) - 1; if (child_index >= i) break; uint32_t child1_hash = GetKey(child_index)->Hash(); uint32_t child2_hash = GetKey(child_index + 1)->Hash(); uint32_t parent_hash = GetKey(parent_index)->Hash(); if (child_index + 1 >= i || child1_hash > child2_hash) { if (parent_hash > child1_hash) break; Swap(parent_index, child_index); parent_index = child_index; } else { if (parent_hash > child2_hash) break; Swap(parent_index, child_index + 1); parent_index = child_index + 1; } } } SLOW_ASSERT(IsSortedNoDuplicates()); } int DescriptorArray::BinarySearch(String* name, int low, int high) { uint32_t hash = name->Hash(); while (low <= high) { int mid = (low + high) / 2; String* mid_name = GetKey(mid); uint32_t mid_hash = mid_name->Hash(); if (mid_hash > hash) { high = mid - 1; continue; } if (mid_hash < hash) { low = mid + 1; continue; } // Found an element with the same hash-code. ASSERT(hash == mid_hash); // There might be more, so we find the first one and // check them all to see if we have a match. if (name == mid_name && !is_null_descriptor(mid)) return mid; while ((mid > low) && (GetKey(mid - 1)->Hash() == hash)) mid--; for (; (mid <= high) && (GetKey(mid)->Hash() == hash); mid++) { if (GetKey(mid)->Equals(name) && !is_null_descriptor(mid)) return mid; } break; } return kNotFound; } int DescriptorArray::LinearSearch(String* name, int len) { uint32_t hash = name->Hash(); for (int number = 0; number < len; number++) { String* entry = GetKey(number); if ((entry->Hash() == hash) && name->Equals(entry) && !is_null_descriptor(number)) { return number; } } return kNotFound; } #ifdef DEBUG bool DescriptorArray::IsEqualTo(DescriptorArray* other) { if (IsEmpty()) return other->IsEmpty(); if (other->IsEmpty()) return false; if (length() != other->length()) return false; for (int i = 0; i < length(); ++i) { if (get(i) != other->get(i) && i != kContentArrayIndex) return false; } return GetContentArray()->IsEqualTo(other->GetContentArray()); } #endif static StaticResource<StringInputBuffer> string_input_buffer; bool String::LooksValid() { if (!Heap::Contains(this)) return false; return true; } int String::Utf8Length() { if (IsAsciiRepresentation()) return length(); // Attempt to flatten before accessing the string. It probably // doesn't make Utf8Length faster, but it is very likely that // the string will be accessed later (for example by WriteUtf8) // so it's still a good idea. TryFlattenIfNotFlat(); Access<StringInputBuffer> buffer(&string_input_buffer); buffer->Reset(0, this); int result = 0; while (buffer->has_more()) result += unibrow::Utf8::Length(buffer->GetNext()); return result; } Vector<const char> String::ToAsciiVector() { ASSERT(IsAsciiRepresentation()); ASSERT(IsFlat()); int offset = 0; int length = this->length(); StringRepresentationTag string_tag = StringShape(this).representation_tag(); String* string = this; if (string_tag == kConsStringTag) { ConsString* cons = ConsString::cast(string); ASSERT(cons->second()->length() == 0); string = cons->first(); string_tag = StringShape(string).representation_tag(); } if (string_tag == kSeqStringTag) { SeqAsciiString* seq = SeqAsciiString::cast(string); char* start = seq->GetChars(); return Vector<const char>(start + offset, length); } ASSERT(string_tag == kExternalStringTag); ExternalAsciiString* ext = ExternalAsciiString::cast(string); const char* start = ext->resource()->data(); return Vector<const char>(start + offset, length); } Vector<const uc16> String::ToUC16Vector() { ASSERT(IsTwoByteRepresentation()); ASSERT(IsFlat()); int offset = 0; int length = this->length(); StringRepresentationTag string_tag = StringShape(this).representation_tag(); String* string = this; if (string_tag == kConsStringTag) { ConsString* cons = ConsString::cast(string); ASSERT(cons->second()->length() == 0); string = cons->first(); string_tag = StringShape(string).representation_tag(); } if (string_tag == kSeqStringTag) { SeqTwoByteString* seq = SeqTwoByteString::cast(string); return Vector<const uc16>(seq->GetChars() + offset, length); } ASSERT(string_tag == kExternalStringTag); ExternalTwoByteString* ext = ExternalTwoByteString::cast(string); const uc16* start = reinterpret_cast<const uc16*>(ext->resource()->data()); return Vector<const uc16>(start + offset, length); } SmartPointer<char> String::ToCString(AllowNullsFlag allow_nulls, RobustnessFlag robust_flag, int offset, int length, int* length_return) { ASSERT(NativeAllocationChecker::allocation_allowed()); if (robust_flag == ROBUST_STRING_TRAVERSAL && !LooksValid()) { return SmartPointer<char>(NULL); } // Negative length means the to the end of the string. if (length < 0) length = kMaxInt - offset; // Compute the size of the UTF-8 string. Start at the specified offset. Access<StringInputBuffer> buffer(&string_input_buffer); buffer->Reset(offset, this); int character_position = offset; int utf8_bytes = 0; while (buffer->has_more()) { uint16_t character = buffer->GetNext(); if (character_position < offset + length) { utf8_bytes += unibrow::Utf8::Length(character); } character_position++; } if (length_return) { *length_return = utf8_bytes; } char* result = NewArray<char>(utf8_bytes + 1); // Convert the UTF-16 string to a UTF-8 buffer. Start at the specified offset. buffer->Rewind(); buffer->Seek(offset); character_position = offset; int utf8_byte_position = 0; while (buffer->has_more()) { uint16_t character = buffer->GetNext(); if (character_position < offset + length) { if (allow_nulls == DISALLOW_NULLS && character == 0) { character = ' '; } utf8_byte_position += unibrow::Utf8::Encode(result + utf8_byte_position, character); } character_position++; } result[utf8_byte_position] = 0; return SmartPointer<char>(result); } SmartPointer<char> String::ToCString(AllowNullsFlag allow_nulls, RobustnessFlag robust_flag, int* length_return) { return ToCString(allow_nulls, robust_flag, 0, -1, length_return); } const uc16* String::GetTwoByteData() { return GetTwoByteData(0); } const uc16* String::GetTwoByteData(unsigned start) { ASSERT(!IsAsciiRepresentation()); switch (StringShape(this).representation_tag()) { case kSeqStringTag: return SeqTwoByteString::cast(this)->SeqTwoByteStringGetData(start); case kExternalStringTag: return ExternalTwoByteString::cast(this)-> ExternalTwoByteStringGetData(start); case kConsStringTag: UNREACHABLE(); return NULL; } UNREACHABLE(); return NULL; } SmartPointer<uc16> String::ToWideCString(RobustnessFlag robust_flag) { ASSERT(NativeAllocationChecker::allocation_allowed()); if (robust_flag == ROBUST_STRING_TRAVERSAL && !LooksValid()) { return SmartPointer<uc16>(); } Access<StringInputBuffer> buffer(&string_input_buffer); buffer->Reset(this); uc16* result = NewArray<uc16>(length() + 1); int i = 0; while (buffer->has_more()) { uint16_t character = buffer->GetNext(); result[i++] = character; } result[i] = 0; return SmartPointer<uc16>(result); } const uc16* SeqTwoByteString::SeqTwoByteStringGetData(unsigned start) { return reinterpret_cast<uc16*>( reinterpret_cast<char*>(this) - kHeapObjectTag + kHeaderSize) + start; } void SeqTwoByteString::SeqTwoByteStringReadBlockIntoBuffer(ReadBlockBuffer* rbb, unsigned* offset_ptr, unsigned max_chars) { unsigned chars_read = 0; unsigned offset = *offset_ptr; while (chars_read < max_chars) { uint16_t c = *reinterpret_cast<uint16_t*>( reinterpret_cast<char*>(this) - kHeapObjectTag + kHeaderSize + offset * kShortSize); if (c <= kMaxAsciiCharCode) { // Fast case for ASCII characters. Cursor is an input output argument. if (!unibrow::CharacterStream::EncodeAsciiCharacter(c, rbb->util_buffer, rbb->capacity, rbb->cursor)) { break; } } else { if (!unibrow::CharacterStream::EncodeNonAsciiCharacter(c, rbb->util_buffer, rbb->capacity, rbb->cursor)) { break; } } offset++; chars_read++; } *offset_ptr = offset; rbb->remaining += chars_read; } const unibrow::byte* SeqAsciiString::SeqAsciiStringReadBlock( unsigned* remaining, unsigned* offset_ptr, unsigned max_chars) { const unibrow::byte* b = reinterpret_cast<unibrow::byte*>(this) - kHeapObjectTag + kHeaderSize + *offset_ptr * kCharSize; *remaining = max_chars; *offset_ptr += max_chars; return b; } // This will iterate unless the block of string data spans two 'halves' of // a ConsString, in which case it will recurse. Since the block of string // data to be read has a maximum size this limits the maximum recursion // depth to something sane. Since C++ does not have tail call recursion // elimination, the iteration must be explicit. Since this is not an // -IntoBuffer method it can delegate to one of the efficient // *AsciiStringReadBlock routines. const unibrow::byte* ConsString::ConsStringReadBlock(ReadBlockBuffer* rbb, unsigned* offset_ptr, unsigned max_chars) { ConsString* current = this; unsigned offset = *offset_ptr; int offset_correction = 0; while (true) { String* left = current->first(); unsigned left_length = (unsigned)left->length(); if (left_length > offset && (max_chars <= left_length - offset || (rbb->capacity <= left_length - offset && (max_chars = left_length - offset, true)))) { // comma operator! // Left hand side only - iterate unless we have reached the bottom of // the cons tree. The assignment on the left of the comma operator is // in order to make use of the fact that the -IntoBuffer routines can // produce at most 'capacity' characters. This enables us to postpone // the point where we switch to the -IntoBuffer routines (below) in order // to maximize the chances of delegating a big chunk of work to the // efficient *AsciiStringReadBlock routines. if (StringShape(left).IsCons()) { current = ConsString::cast(left); continue; } else { const unibrow::byte* answer = String::ReadBlock(left, rbb, &offset, max_chars); *offset_ptr = offset + offset_correction; return answer; } } else if (left_length <= offset) { // Right hand side only - iterate unless we have reached the bottom of // the cons tree. String* right = current->second(); offset -= left_length; offset_correction += left_length; if (StringShape(right).IsCons()) { current = ConsString::cast(right); continue; } else { const unibrow::byte* answer = String::ReadBlock(right, rbb, &offset, max_chars); *offset_ptr = offset + offset_correction; return answer; } } else { // The block to be read spans two sides of the ConsString, so we call the // -IntoBuffer version, which will recurse. The -IntoBuffer methods // are able to assemble data from several part strings because they use // the util_buffer to store their data and never return direct pointers // to their storage. We don't try to read more than the buffer capacity // here or we can get too much recursion. ASSERT(rbb->remaining == 0); ASSERT(rbb->cursor == 0); current->ConsStringReadBlockIntoBuffer( rbb, &offset, max_chars > rbb->capacity ? rbb->capacity : max_chars); *offset_ptr = offset + offset_correction; return rbb->util_buffer; } } } uint16_t ExternalAsciiString::ExternalAsciiStringGet(int index) { ASSERT(index >= 0 && index < length()); return resource()->data()[index]; } const unibrow::byte* ExternalAsciiString::ExternalAsciiStringReadBlock( unsigned* remaining, unsigned* offset_ptr, unsigned max_chars) { // Cast const char* to unibrow::byte* (signedness difference). const unibrow::byte* b = reinterpret_cast<const unibrow::byte*>(resource()->data()) + *offset_ptr; *remaining = max_chars; *offset_ptr += max_chars; return b; } const uc16* ExternalTwoByteString::ExternalTwoByteStringGetData( unsigned start) { return resource()->data() + start; } uint16_t ExternalTwoByteString::ExternalTwoByteStringGet(int index) { ASSERT(index >= 0 && index < length()); return resource()->data()[index]; } void ExternalTwoByteString::ExternalTwoByteStringReadBlockIntoBuffer( ReadBlockBuffer* rbb, unsigned* offset_ptr, unsigned max_chars) { unsigned chars_read = 0; unsigned offset = *offset_ptr; const uint16_t* data = resource()->data(); while (chars_read < max_chars) { uint16_t c = data[offset]; if (c <= kMaxAsciiCharCode) { // Fast case for ASCII characters. Cursor is an input output argument. if (!unibrow::CharacterStream::EncodeAsciiCharacter(c, rbb->util_buffer, rbb->capacity, rbb->cursor)) break; } else { if (!unibrow::CharacterStream::EncodeNonAsciiCharacter(c, rbb->util_buffer, rbb->capacity, rbb->cursor)) break; } offset++; chars_read++; } *offset_ptr = offset; rbb->remaining += chars_read; } void SeqAsciiString::SeqAsciiStringReadBlockIntoBuffer(ReadBlockBuffer* rbb, unsigned* offset_ptr, unsigned max_chars) { unsigned capacity = rbb->capacity - rbb->cursor; if (max_chars > capacity) max_chars = capacity; memcpy(rbb->util_buffer + rbb->cursor, reinterpret_cast<char*>(this) - kHeapObjectTag + kHeaderSize + *offset_ptr * kCharSize, max_chars); rbb->remaining += max_chars; *offset_ptr += max_chars; rbb->cursor += max_chars; } void ExternalAsciiString::ExternalAsciiStringReadBlockIntoBuffer( ReadBlockBuffer* rbb, unsigned* offset_ptr, unsigned max_chars) { unsigned capacity = rbb->capacity - rbb->cursor; if (max_chars > capacity) max_chars = capacity; memcpy(rbb->util_buffer + rbb->cursor, resource()->data() + *offset_ptr, max_chars); rbb->remaining += max_chars; *offset_ptr += max_chars; rbb->cursor += max_chars; } // This method determines the type of string involved and then copies // a whole chunk of characters into a buffer, or returns a pointer to a buffer // where they can be found. The pointer is not necessarily valid across a GC // (see AsciiStringReadBlock). const unibrow::byte* String::ReadBlock(String* input, ReadBlockBuffer* rbb, unsigned* offset_ptr, unsigned max_chars) { ASSERT(*offset_ptr <= static_cast<unsigned>(input->length())); if (max_chars == 0) { rbb->remaining = 0; return NULL; } switch (StringShape(input).representation_tag()) { case kSeqStringTag: if (input->IsAsciiRepresentation()) { SeqAsciiString* str = SeqAsciiString::cast(input); return str->SeqAsciiStringReadBlock(&rbb->remaining, offset_ptr, max_chars); } else { SeqTwoByteString* str = SeqTwoByteString::cast(input); str->SeqTwoByteStringReadBlockIntoBuffer(rbb, offset_ptr, max_chars); return rbb->util_buffer; } case kConsStringTag: return ConsString::cast(input)->ConsStringReadBlock(rbb, offset_ptr, max_chars); case kExternalStringTag: if (input->IsAsciiRepresentation()) { return ExternalAsciiString::cast(input)->ExternalAsciiStringReadBlock( &rbb->remaining, offset_ptr, max_chars); } else { ExternalTwoByteString::cast(input)-> ExternalTwoByteStringReadBlockIntoBuffer(rbb, offset_ptr, max_chars); return rbb->util_buffer; } default: break; } UNREACHABLE(); return 0; } Relocatable* Relocatable::top_ = NULL; void Relocatable::PostGarbageCollectionProcessing() { Relocatable* current = top_; while (current != NULL) { current->PostGarbageCollection(); current = current->prev_; } } // Reserve space for statics needing saving and restoring. int Relocatable::ArchiveSpacePerThread() { return sizeof(top_); } // Archive statics that are thread local. char* Relocatable::ArchiveState(char* to) { *reinterpret_cast<Relocatable**>(to) = top_; top_ = NULL; return to + ArchiveSpacePerThread(); } // Restore statics that are thread local. char* Relocatable::RestoreState(char* from) { top_ = *reinterpret_cast<Relocatable**>(from); return from + ArchiveSpacePerThread(); } char* Relocatable::Iterate(ObjectVisitor* v, char* thread_storage) { Relocatable* top = *reinterpret_cast<Relocatable**>(thread_storage); Iterate(v, top); return thread_storage + ArchiveSpacePerThread(); } void Relocatable::Iterate(ObjectVisitor* v) { Iterate(v, top_); } void Relocatable::Iterate(ObjectVisitor* v, Relocatable* top) { Relocatable* current = top; while (current != NULL) { current->IterateInstance(v); current = current->prev_; } } FlatStringReader::FlatStringReader(Handle<String> str) : str_(str.location()), length_(str->length()) { PostGarbageCollection(); } FlatStringReader::FlatStringReader(Vector<const char> input) : str_(0), is_ascii_(true), length_(input.length()), start_(input.start()) { } void FlatStringReader::PostGarbageCollection() { if (str_ == NULL) return; Handle<String> str(str_); ASSERT(str->IsFlat()); is_ascii_ = str->IsAsciiRepresentation(); if (is_ascii_) { start_ = str->ToAsciiVector().start(); } else { start_ = str->ToUC16Vector().start(); } } void StringInputBuffer::Seek(unsigned pos) { Reset(pos, input_); } void SafeStringInputBuffer::Seek(unsigned pos) { Reset(pos, input_); } // This method determines the type of string involved and then copies // a whole chunk of characters into a buffer. It can be used with strings // that have been glued together to form a ConsString and which must cooperate // to fill up a buffer. void String::ReadBlockIntoBuffer(String* input, ReadBlockBuffer* rbb, unsigned* offset_ptr, unsigned max_chars) { ASSERT(*offset_ptr <= (unsigned)input->length()); if (max_chars == 0) return; switch (StringShape(input).representation_tag()) { case kSeqStringTag: if (input->IsAsciiRepresentation()) { SeqAsciiString::cast(input)->SeqAsciiStringReadBlockIntoBuffer(rbb, offset_ptr, max_chars); return; } else { SeqTwoByteString::cast(input)->SeqTwoByteStringReadBlockIntoBuffer(rbb, offset_ptr, max_chars); return; } case kConsStringTag: ConsString::cast(input)->ConsStringReadBlockIntoBuffer(rbb, offset_ptr, max_chars); return; case kExternalStringTag: if (input->IsAsciiRepresentation()) { ExternalAsciiString::cast(input)-> ExternalAsciiStringReadBlockIntoBuffer(rbb, offset_ptr, max_chars); } else { ExternalTwoByteString::cast(input)-> ExternalTwoByteStringReadBlockIntoBuffer(rbb, offset_ptr, max_chars); } return; default: break; } UNREACHABLE(); return; } const unibrow::byte* String::ReadBlock(String* input, unibrow::byte* util_buffer, unsigned capacity, unsigned* remaining, unsigned* offset_ptr) { ASSERT(*offset_ptr <= (unsigned)input->length()); unsigned chars = input->length() - *offset_ptr; ReadBlockBuffer rbb(util_buffer, 0, capacity, 0); const unibrow::byte* answer = ReadBlock(input, &rbb, offset_ptr, chars); ASSERT(rbb.remaining <= static_cast<unsigned>(input->length())); *remaining = rbb.remaining; return answer; } const unibrow::byte* String::ReadBlock(String** raw_input, unibrow::byte* util_buffer, unsigned capacity, unsigned* remaining, unsigned* offset_ptr) { Handle<String> input(raw_input); ASSERT(*offset_ptr <= (unsigned)input->length()); unsigned chars = input->length() - *offset_ptr; if (chars > capacity) chars = capacity; ReadBlockBuffer rbb(util_buffer, 0, capacity, 0); ReadBlockIntoBuffer(*input, &rbb, offset_ptr, chars); ASSERT(rbb.remaining <= static_cast<unsigned>(input->length())); *remaining = rbb.remaining; return rbb.util_buffer; } // This will iterate unless the block of string data spans two 'halves' of // a ConsString, in which case it will recurse. Since the block of string // data to be read has a maximum size this limits the maximum recursion // depth to something sane. Since C++ does not have tail call recursion // elimination, the iteration must be explicit. void ConsString::ConsStringReadBlockIntoBuffer(ReadBlockBuffer* rbb, unsigned* offset_ptr, unsigned max_chars) { ConsString* current = this; unsigned offset = *offset_ptr; int offset_correction = 0; while (true) { String* left = current->first(); unsigned left_length = (unsigned)left->length(); if (left_length > offset && max_chars <= left_length - offset) { // Left hand side only - iterate unless we have reached the bottom of // the cons tree. if (StringShape(left).IsCons()) { current = ConsString::cast(left); continue; } else { String::ReadBlockIntoBuffer(left, rbb, &offset, max_chars); *offset_ptr = offset + offset_correction; return; } } else if (left_length <= offset) { // Right hand side only - iterate unless we have reached the bottom of // the cons tree. offset -= left_length; offset_correction += left_length; String* right = current->second(); if (StringShape(right).IsCons()) { current = ConsString::cast(right); continue; } else { String::ReadBlockIntoBuffer(right, rbb, &offset, max_chars); *offset_ptr = offset + offset_correction; return; } } else { // The block to be read spans two sides of the ConsString, so we recurse. // First recurse on the left. max_chars -= left_length - offset; String::ReadBlockIntoBuffer(left, rbb, &offset, left_length - offset); // We may have reached the max or there may not have been enough space // in the buffer for the characters in the left hand side. if (offset == left_length) { // Recurse on the right. String* right = String::cast(current->second()); offset -= left_length; offset_correction += left_length; String::ReadBlockIntoBuffer(right, rbb, &offset, max_chars); } *offset_ptr = offset + offset_correction; return; } } } void ConsString::ConsStringIterateBody(ObjectVisitor* v) { IteratePointers(v, kFirstOffset, kSecondOffset + kPointerSize); } void JSGlobalPropertyCell::JSGlobalPropertyCellIterateBody(ObjectVisitor* v) { IteratePointers(v, kValueOffset, kValueOffset + kPointerSize); } uint16_t ConsString::ConsStringGet(int index) { ASSERT(index >= 0 && index < this->length()); // Check for a flattened cons string if (second()->length() == 0) { String* left = first(); return left->Get(index); } String* string = String::cast(this); while (true) { if (StringShape(string).IsCons()) { ConsString* cons_string = ConsString::cast(string); String* left = cons_string->first(); if (left->length() > index) { string = left; } else { index -= left->length(); string = cons_string->second(); } } else { return string->Get(index); } } UNREACHABLE(); return 0; } template <typename sinkchar> void String::WriteToFlat(String* src, sinkchar* sink, int f, int t) { String* source = src; int from = f; int to = t; while (true) { ASSERT(0 <= from && from <= to && to <= source->length()); switch (StringShape(source).full_representation_tag()) { case kAsciiStringTag | kExternalStringTag: { CopyChars(sink, ExternalAsciiString::cast(source)->resource()->data() + from, to - from); return; } case kTwoByteStringTag | kExternalStringTag: { const uc16* data = ExternalTwoByteString::cast(source)->resource()->data(); CopyChars(sink, data + from, to - from); return; } case kAsciiStringTag | kSeqStringTag: { CopyChars(sink, SeqAsciiString::cast(source)->GetChars() + from, to - from); return; } case kTwoByteStringTag | kSeqStringTag: { CopyChars(sink, SeqTwoByteString::cast(source)->GetChars() + from, to - from); return; } case kAsciiStringTag | kConsStringTag: case kTwoByteStringTag | kConsStringTag: { ConsString* cons_string = ConsString::cast(source); String* first = cons_string->first(); int boundary = first->length(); if (to - boundary >= boundary - from) { // Right hand side is longer. Recurse over left. if (from < boundary) { WriteToFlat(first, sink, from, boundary); sink += boundary - from; from = 0; } else { from -= boundary; } to -= boundary; source = cons_string->second(); } else { // Left hand side is longer. Recurse over right. if (to > boundary) { String* second = cons_string->second(); WriteToFlat(second, sink + boundary - from, 0, to - boundary); to = boundary; } source = first; } break; } } } } #define FIELD_ADDR(p, offset) \ (reinterpret_cast<byte*>(p) + offset - kHeapObjectTag) void ExternalAsciiString::ExternalAsciiStringIterateBody(ObjectVisitor* v) { typedef v8::String::ExternalAsciiStringResource Resource; v->VisitExternalAsciiString( reinterpret_cast<Resource**>(FIELD_ADDR(this, kResourceOffset))); } void ExternalTwoByteString::ExternalTwoByteStringIterateBody(ObjectVisitor* v) { typedef v8::String::ExternalStringResource Resource; v->VisitExternalTwoByteString( reinterpret_cast<Resource**>(FIELD_ADDR(this, kResourceOffset))); } #undef FIELD_ADDR template <typename IteratorA, typename IteratorB> static inline bool CompareStringContents(IteratorA* ia, IteratorB* ib) { // General slow case check. We know that the ia and ib iterators // have the same length. while (ia->has_more()) { uc32 ca = ia->GetNext(); uc32 cb = ib->GetNext(); if (ca != cb) return false; } return true; } // Compares the contents of two strings by reading and comparing // int-sized blocks of characters. template <typename Char> static inline bool CompareRawStringContents(Vector<Char> a, Vector<Char> b) { int length = a.length(); ASSERT_EQ(length, b.length()); const Char* pa = a.start(); const Char* pb = b.start(); int i = 0; #ifndef V8_HOST_CAN_READ_UNALIGNED // If this architecture isn't comfortable reading unaligned ints // then we have to check that the strings are aligned before // comparing them blockwise. const int kAlignmentMask = sizeof(uint32_t) - 1; // NOLINT uint32_t pa_addr = reinterpret_cast<uint32_t>(pa); uint32_t pb_addr = reinterpret_cast<uint32_t>(pb); if (((pa_addr & kAlignmentMask) | (pb_addr & kAlignmentMask)) == 0) { #endif const int kStepSize = sizeof(int) / sizeof(Char); // NOLINT int endpoint = length - kStepSize; // Compare blocks until we reach near the end of the string. for (; i <= endpoint; i += kStepSize) { uint32_t wa = *reinterpret_cast<const uint32_t*>(pa + i); uint32_t wb = *reinterpret_cast<const uint32_t*>(pb + i); if (wa != wb) { return false; } } #ifndef V8_HOST_CAN_READ_UNALIGNED } #endif // Compare the remaining characters that didn't fit into a block. for (; i < length; i++) { if (a[i] != b[i]) { return false; } } return true; } static StringInputBuffer string_compare_buffer_b; template <typename IteratorA> static inline bool CompareStringContentsPartial(IteratorA* ia, String* b) { if (b->IsFlat()) { if (b->IsAsciiRepresentation()) { VectorIterator<char> ib(b->ToAsciiVector()); return CompareStringContents(ia, &ib); } else { VectorIterator<uc16> ib(b->ToUC16Vector()); return CompareStringContents(ia, &ib); } } else { string_compare_buffer_b.Reset(0, b); return CompareStringContents(ia, &string_compare_buffer_b); } } static StringInputBuffer string_compare_buffer_a; bool String::SlowEquals(String* other) { // Fast check: negative check with lengths. int len = length(); if (len != other->length()) return false; if (len == 0) return true; // Fast check: if hash code is computed for both strings // a fast negative check can be performed. if (HasHashCode() && other->HasHashCode()) { if (Hash() != other->Hash()) return false; } if (StringShape(this).IsSequentialAscii() && StringShape(other).IsSequentialAscii()) { const char* str1 = SeqAsciiString::cast(this)->GetChars(); const char* str2 = SeqAsciiString::cast(other)->GetChars(); return CompareRawStringContents(Vector<const char>(str1, len), Vector<const char>(str2, len)); } if (this->IsFlat()) { if (IsAsciiRepresentation()) { Vector<const char> vec1 = this->ToAsciiVector(); if (other->IsFlat()) { if (other->IsAsciiRepresentation()) { Vector<const char> vec2 = other->ToAsciiVector(); return CompareRawStringContents(vec1, vec2); } else { VectorIterator<char> buf1(vec1); VectorIterator<uc16> ib(other->ToUC16Vector()); return CompareStringContents(&buf1, &ib); } } else { VectorIterator<char> buf1(vec1); string_compare_buffer_b.Reset(0, other); return CompareStringContents(&buf1, &string_compare_buffer_b); } } else { Vector<const uc16> vec1 = this->ToUC16Vector(); if (other->IsFlat()) { if (other->IsAsciiRepresentation()) { VectorIterator<uc16> buf1(vec1); VectorIterator<char> ib(other->ToAsciiVector()); return CompareStringContents(&buf1, &ib); } else { Vector<const uc16> vec2(other->ToUC16Vector()); return CompareRawStringContents(vec1, vec2); } } else { VectorIterator<uc16> buf1(vec1); string_compare_buffer_b.Reset(0, other); return CompareStringContents(&buf1, &string_compare_buffer_b); } } } else { string_compare_buffer_a.Reset(0, this); return CompareStringContentsPartial(&string_compare_buffer_a, other); } } bool String::MarkAsUndetectable() { if (StringShape(this).IsSymbol()) return false; Map* map = this->map(); if (map == Heap::string_map()) { this->set_map(Heap::undetectable_string_map()); return true; } else if (map == Heap::ascii_string_map()) { this->set_map(Heap::undetectable_ascii_string_map()); return true; } // Rest cannot be marked as undetectable return false; } bool String::IsEqualTo(Vector<const char> str) { int slen = length(); Access<Scanner::Utf8Decoder> decoder(Scanner::utf8_decoder()); decoder->Reset(str.start(), str.length()); int i; for (i = 0; i < slen && decoder->has_more(); i++) { uc32 r = decoder->GetNext(); if (Get(i) != r) return false; } return i == slen && !decoder->has_more(); } uint32_t String::ComputeAndSetHash() { // Should only be called if hash code has not yet been computed. ASSERT(!(hash_field() & kHashComputedMask)); // Compute the hash code. StringInputBuffer buffer(this); uint32_t field = ComputeHashField(&buffer, length()); // Store the hash code in the object. set_hash_field(field); // Check the hash code is there. ASSERT(hash_field() & kHashComputedMask); uint32_t result = field >> kHashShift; ASSERT(result != 0); // Ensure that the hash value of 0 is never computed. return result; } bool String::ComputeArrayIndex(unibrow::CharacterStream* buffer, uint32_t* index, int length) { if (length == 0 || length > kMaxArrayIndexSize) return false; uc32 ch = buffer->GetNext(); // If the string begins with a '0' character, it must only consist // of it to be a legal array index. if (ch == '0') { *index = 0; return length == 1; } // Convert string to uint32 array index; character by character. int d = ch - '0'; if (d < 0 || d > 9) return false; uint32_t result = d; while (buffer->has_more()) { d = buffer->GetNext() - '0'; if (d < 0 || d > 9) return false; // Check that the new result is below the 32 bit limit. if (result > 429496729U - ((d > 5) ? 1 : 0)) return false; result = (result * 10) + d; } *index = result; return true; } bool String::SlowAsArrayIndex(uint32_t* index) { if (length() <= kMaxCachedArrayIndexLength) { Hash(); // force computation of hash code uint32_t field = hash_field(); if ((field & kIsArrayIndexMask) == 0) return false; // Isolate the array index form the full hash field. *index = (kArrayIndexHashMask & field) >> kHashShift; return true; } else { StringInputBuffer buffer(this); return ComputeArrayIndex(&buffer, index, length()); } } static inline uint32_t HashField(uint32_t hash, bool is_array_index, int length = -1) { uint32_t result = (hash << String::kHashShift) | String::kHashComputedMask; if (is_array_index) { // For array indexes mix the length into the hash as an array index could // be zero. ASSERT(length > 0); ASSERT(TenToThe(String::kMaxCachedArrayIndexLength) < (1 << String::kArrayIndexValueBits)); result |= String::kIsArrayIndexMask; result |= length << String::kArrayIndexHashLengthShift; } return result; } uint32_t StringHasher::GetHashField() { ASSERT(is_valid()); if (length_ <= String::kMaxHashCalcLength) { if (is_array_index()) { return v8::internal::HashField(array_index(), true, length_); } else { return v8::internal::HashField(GetHash(), false); } uint32_t payload = v8::internal::HashField(GetHash(), false); return payload; } else { return v8::internal::HashField(length_, false); } } uint32_t String::ComputeHashField(unibrow::CharacterStream* buffer, int length) { StringHasher hasher(length); // Very long strings have a trivial hash that doesn't inspect the // string contents. if (hasher.has_trivial_hash()) { return hasher.GetHashField(); } // Do the iterative array index computation as long as there is a // chance this is an array index. while (buffer->has_more() && hasher.is_array_index()) { hasher.AddCharacter(buffer->GetNext()); } // Process the remaining characters without updating the array // index. while (buffer->has_more()) { hasher.AddCharacterNoIndex(buffer->GetNext()); } return hasher.GetHashField(); } Object* String::SubString(int start, int end) { if (start == 0 && end == length()) return this; Object* result = Heap::AllocateSubString(this, start, end); return result; } void String::PrintOn(FILE* file) { int length = this->length(); for (int i = 0; i < length; i++) { fprintf(file, "%c", Get(i)); } } void Map::CreateBackPointers() { DescriptorArray* descriptors = instance_descriptors(); for (int i = 0; i < descriptors->number_of_descriptors(); i++) { if (descriptors->GetType(i) == MAP_TRANSITION) { // Get target. Map* target = Map::cast(descriptors->GetValue(i)); #ifdef DEBUG // Verify target. Object* source_prototype = prototype(); Object* target_prototype = target->prototype(); ASSERT(source_prototype->IsJSObject() || source_prototype->IsMap() || source_prototype->IsNull()); ASSERT(target_prototype->IsJSObject() || target_prototype->IsNull()); ASSERT(source_prototype->IsMap() || source_prototype == target_prototype); #endif // Point target back to source. set_prototype() will not let us set // the prototype to a map, as we do here. *RawField(target, kPrototypeOffset) = this; } } } void Map::ClearNonLiveTransitions(Object* real_prototype) { // Live DescriptorArray objects will be marked, so we must use // low-level accessors to get and modify their data. DescriptorArray* d = reinterpret_cast<DescriptorArray*>( *RawField(this, Map::kInstanceDescriptorsOffset)); if (d == Heap::raw_unchecked_empty_descriptor_array()) return; Smi* NullDescriptorDetails = PropertyDetails(NONE, NULL_DESCRIPTOR).AsSmi(); FixedArray* contents = reinterpret_cast<FixedArray*>( d->get(DescriptorArray::kContentArrayIndex)); ASSERT(contents->length() >= 2); for (int i = 0; i < contents->length(); i += 2) { // If the pair (value, details) is a map transition, // check if the target is live. If not, null the descriptor. // Also drop the back pointer for that map transition, so that this // map is not reached again by following a back pointer from a // non-live object. PropertyDetails details(Smi::cast(contents->get(i + 1))); if (details.type() == MAP_TRANSITION) { Map* target = reinterpret_cast<Map*>(contents->get(i)); ASSERT(target->IsHeapObject()); if (!target->IsMarked()) { ASSERT(target->IsMap()); contents->set(i + 1, NullDescriptorDetails); contents->set_null(i); ASSERT(target->prototype() == this || target->prototype() == real_prototype); // Getter prototype() is read-only, set_prototype() has side effects. *RawField(target, Map::kPrototypeOffset) = real_prototype; } } } } void Map::MapIterateBody(ObjectVisitor* v) { // Assumes all Object* members are contiguously allocated! IteratePointers(v, kPrototypeOffset, kCodeCacheOffset + kPointerSize); } Object* JSFunction::SetInstancePrototype(Object* value) { ASSERT(value->IsJSObject()); if (has_initial_map()) { initial_map()->set_prototype(value); } else { // Put the value in the initial map field until an initial map is // needed. At that point, a new initial map is created and the // prototype is put into the initial map where it belongs. set_prototype_or_initial_map(value); } return value; } Object* JSFunction::SetPrototype(Object* value) { Object* construct_prototype = value; // If the value is not a JSObject, store the value in the map's // constructor field so it can be accessed. Also, set the prototype // used for constructing objects to the original object prototype. // See ECMA-262 13.2.2. if (!value->IsJSObject()) { // Copy the map so this does not affect unrelated functions. // Remove map transitions because they point to maps with a // different prototype. Object* new_map = map()->CopyDropTransitions(); if (new_map->IsFailure()) return new_map; set_map(Map::cast(new_map)); map()->set_constructor(value); map()->set_non_instance_prototype(true); construct_prototype = Top::context()->global_context()->initial_object_prototype(); } else { map()->set_non_instance_prototype(false); } return SetInstancePrototype(construct_prototype); } Object* JSFunction::SetInstanceClassName(String* name) { shared()->set_instance_class_name(name); return this; } Context* JSFunction::GlobalContextFromLiterals(FixedArray* literals) { return Context::cast(literals->get(JSFunction::kLiteralGlobalContextIndex)); } void Oddball::OddballIterateBody(ObjectVisitor* v) { // Assumes all Object* members are contiguously allocated! IteratePointers(v, kToStringOffset, kToNumberOffset + kPointerSize); } Object* Oddball::Initialize(const char* to_string, Object* to_number) { Object* symbol = Heap::LookupAsciiSymbol(to_string); if (symbol->IsFailure()) return symbol; set_to_string(String::cast(symbol)); set_to_number(to_number); return this; } bool SharedFunctionInfo::HasSourceCode() { return !script()->IsUndefined() && !Script::cast(script())->source()->IsUndefined(); } Object* SharedFunctionInfo::GetSourceCode() { HandleScope scope; if (script()->IsUndefined()) return Heap::undefined_value(); Object* source = Script::cast(script())->source(); if (source->IsUndefined()) return Heap::undefined_value(); return *SubString(Handle<String>(String::cast(source)), start_position(), end_position()); } int SharedFunctionInfo::CalculateInstanceSize() { int instance_size = JSObject::kHeaderSize + expected_nof_properties() * kPointerSize; if (instance_size > JSObject::kMaxInstanceSize) { instance_size = JSObject::kMaxInstanceSize; } return instance_size; } int SharedFunctionInfo::CalculateInObjectProperties() { return (CalculateInstanceSize() - JSObject::kHeaderSize) / kPointerSize; } bool SharedFunctionInfo::CanGenerateInlineConstructor(Object* prototype) { // Check the basic conditions for generating inline constructor code. if (!FLAG_inline_new || !has_only_simple_this_property_assignments() || this_property_assignments_count() == 0) { return false; } // If the prototype is null inline constructors cause no problems. if (!prototype->IsJSObject()) { ASSERT(prototype->IsNull()); return true; } // Traverse the proposed prototype chain looking for setters for properties of // the same names as are set by the inline constructor. for (Object* obj = prototype; obj != Heap::null_value(); obj = obj->GetPrototype()) { JSObject* js_object = JSObject::cast(obj); for (int i = 0; i < this_property_assignments_count(); i++) { LookupResult result; String* name = GetThisPropertyAssignmentName(i); js_object->LocalLookupRealNamedProperty(name, &result); if (result.IsProperty() && result.type() == CALLBACKS) { return false; } } } return true; } void SharedFunctionInfo::SetThisPropertyAssignmentsInfo( bool only_simple_this_property_assignments, FixedArray* assignments) { set_compiler_hints(BooleanBit::set(compiler_hints(), kHasOnlySimpleThisPropertyAssignments, only_simple_this_property_assignments)); set_this_property_assignments(assignments); set_this_property_assignments_count(assignments->length() / 3); } void SharedFunctionInfo::ClearThisPropertyAssignmentsInfo() { set_compiler_hints(BooleanBit::set(compiler_hints(), kHasOnlySimpleThisPropertyAssignments, false)); set_this_property_assignments(Heap::undefined_value()); set_this_property_assignments_count(0); } String* SharedFunctionInfo::GetThisPropertyAssignmentName(int index) { Object* obj = this_property_assignments(); ASSERT(obj->IsFixedArray()); ASSERT(index < this_property_assignments_count()); obj = FixedArray::cast(obj)->get(index * 3); ASSERT(obj->IsString()); return String::cast(obj); } bool SharedFunctionInfo::IsThisPropertyAssignmentArgument(int index) { Object* obj = this_property_assignments(); ASSERT(obj->IsFixedArray()); ASSERT(index < this_property_assignments_count()); obj = FixedArray::cast(obj)->get(index * 3 + 1); return Smi::cast(obj)->value() != -1; } int SharedFunctionInfo::GetThisPropertyAssignmentArgument(int index) { ASSERT(IsThisPropertyAssignmentArgument(index)); Object* obj = FixedArray::cast(this_property_assignments())->get(index * 3 + 1); return Smi::cast(obj)->value(); } Object* SharedFunctionInfo::GetThisPropertyAssignmentConstant(int index) { ASSERT(!IsThisPropertyAssignmentArgument(index)); Object* obj = FixedArray::cast(this_property_assignments())->get(index * 3 + 2); return obj; } // Support function for printing the source code to a StringStream // without any allocation in the heap. void SharedFunctionInfo::SourceCodePrint(StringStream* accumulator, int max_length) { // For some native functions there is no source. if (script()->IsUndefined() || Script::cast(script())->source()->IsUndefined()) { accumulator->Add("<No Source>"); return; } // Get the source for the script which this function came from. // Don't use String::cast because we don't want more assertion errors while // we are already creating a stack dump. String* script_source = reinterpret_cast<String*>(Script::cast(script())->source()); if (!script_source->LooksValid()) { accumulator->Add("<Invalid Source>"); return; } if (!is_toplevel()) { accumulator->Add("function "); Object* name = this->name(); if (name->IsString() && String::cast(name)->length() > 0) { accumulator->PrintName(name); } } int len = end_position() - start_position(); if (len > max_length) { accumulator->Put(script_source, start_position(), start_position() + max_length); accumulator->Add("...\n"); } else { accumulator->Put(script_source, start_position(), end_position()); } } void SharedFunctionInfo::SharedFunctionInfoIterateBody(ObjectVisitor* v) { IteratePointers(v, kNameOffset, kConstructStubOffset + kPointerSize); IteratePointers(v, kInstanceClassNameOffset, kScriptOffset + kPointerSize); IteratePointers(v, kDebugInfoOffset, kInferredNameOffset + kPointerSize); IteratePointers(v, kThisPropertyAssignmentsOffset, kThisPropertyAssignmentsOffset + kPointerSize); } void ObjectVisitor::VisitCodeTarget(RelocInfo* rinfo) { ASSERT(RelocInfo::IsCodeTarget(rinfo->rmode())); Object* target = Code::GetCodeFromTargetAddress(rinfo->target_address()); Object* old_target = target; VisitPointer(&target); CHECK_EQ(target, old_target); // VisitPointer doesn't change Code* *target. } void ObjectVisitor::VisitDebugTarget(RelocInfo* rinfo) { ASSERT(RelocInfo::IsJSReturn(rinfo->rmode()) && rinfo->IsPatchedReturnSequence()); Object* target = Code::GetCodeFromTargetAddress(rinfo->call_address()); Object* old_target = target; VisitPointer(&target); CHECK_EQ(target, old_target); // VisitPointer doesn't change Code* *target. } void Code::CodeIterateBody(ObjectVisitor* v) { int mode_mask = RelocInfo::kCodeTargetMask | RelocInfo::ModeMask(RelocInfo::EMBEDDED_OBJECT) | RelocInfo::ModeMask(RelocInfo::EXTERNAL_REFERENCE) | RelocInfo::ModeMask(RelocInfo::JS_RETURN) | RelocInfo::ModeMask(RelocInfo::RUNTIME_ENTRY); for (RelocIterator it(this, mode_mask); !it.done(); it.next()) { RelocInfo::Mode rmode = it.rinfo()->rmode(); if (rmode == RelocInfo::EMBEDDED_OBJECT) { v->VisitPointer(it.rinfo()->target_object_address()); } else if (RelocInfo::IsCodeTarget(rmode)) { v->VisitCodeTarget(it.rinfo()); } else if (rmode == RelocInfo::EXTERNAL_REFERENCE) { v->VisitExternalReference(it.rinfo()->target_reference_address()); #ifdef ENABLE_DEBUGGER_SUPPORT } else if (Debug::has_break_points() && RelocInfo::IsJSReturn(rmode) && it.rinfo()->IsPatchedReturnSequence()) { v->VisitDebugTarget(it.rinfo()); #endif } else if (rmode == RelocInfo::RUNTIME_ENTRY) { v->VisitRuntimeEntry(it.rinfo()); } } ScopeInfo<>::IterateScopeInfo(this, v); } void Code::Relocate(intptr_t delta) { for (RelocIterator it(this, RelocInfo::kApplyMask); !it.done(); it.next()) { it.rinfo()->apply(delta); } CPU::FlushICache(instruction_start(), instruction_size()); } void Code::CopyFrom(const CodeDesc& desc) { // copy code memmove(instruction_start(), desc.buffer, desc.instr_size); // fill gap with zero bytes { byte* p = instruction_start() + desc.instr_size; byte* q = relocation_start(); while (p < q) { *p++ = 0; } } // copy reloc info memmove(relocation_start(), desc.buffer + desc.buffer_size - desc.reloc_size, desc.reloc_size); // unbox handles and relocate intptr_t delta = instruction_start() - desc.buffer; int mode_mask = RelocInfo::kCodeTargetMask | RelocInfo::ModeMask(RelocInfo::EMBEDDED_OBJECT) | RelocInfo::kApplyMask; Assembler* origin = desc.origin; // Needed to find target_object on X64. for (RelocIterator it(this, mode_mask); !it.done(); it.next()) { RelocInfo::Mode mode = it.rinfo()->rmode(); if (mode == RelocInfo::EMBEDDED_OBJECT) { Handle<Object> p = it.rinfo()->target_object_handle(origin); it.rinfo()->set_target_object(*p); } else if (RelocInfo::IsCodeTarget(mode)) { // rewrite code handles in inline cache targets to direct // pointers to the first instruction in the code object Handle<Object> p = it.rinfo()->target_object_handle(origin); Code* code = Code::cast(*p); it.rinfo()->set_target_address(code->instruction_start()); } else { it.rinfo()->apply(delta); } } CPU::FlushICache(instruction_start(), instruction_size()); } // Locate the source position which is closest to the address in the code. This // is using the source position information embedded in the relocation info. // The position returned is relative to the beginning of the script where the // source for this function is found. int Code::SourcePosition(Address pc) { int distance = kMaxInt; int position = RelocInfo::kNoPosition; // Initially no position found. // Run through all the relocation info to find the best matching source // position. All the code needs to be considered as the sequence of the // instructions in the code does not necessarily follow the same order as the // source. RelocIterator it(this, RelocInfo::kPositionMask); while (!it.done()) { // Only look at positions after the current pc. if (it.rinfo()->pc() < pc) { // Get position and distance. int dist = static_cast<int>(pc - it.rinfo()->pc()); int pos = static_cast<int>(it.rinfo()->data()); // If this position is closer than the current candidate or if it has the // same distance as the current candidate and the position is higher then // this position is the new candidate. if ((dist < distance) || (dist == distance && pos > position)) { position = pos; distance = dist; } } it.next(); } return position; } // Same as Code::SourcePosition above except it only looks for statement // positions. int Code::SourceStatementPosition(Address pc) { // First find the position as close as possible using all position // information. int position = SourcePosition(pc); // Now find the closest statement position before the position. int statement_position = 0; RelocIterator it(this, RelocInfo::kPositionMask); while (!it.done()) { if (RelocInfo::IsStatementPosition(it.rinfo()->rmode())) { int p = static_cast<int>(it.rinfo()->data()); if (statement_position < p && p <= position) { statement_position = p; } } it.next(); } return statement_position; } #ifdef ENABLE_DISASSEMBLER // Identify kind of code. const char* Code::Kind2String(Kind kind) { switch (kind) { case FUNCTION: return "FUNCTION"; case STUB: return "STUB"; case BUILTIN: return "BUILTIN"; case LOAD_IC: return "LOAD_IC"; case KEYED_LOAD_IC: return "KEYED_LOAD_IC"; case STORE_IC: return "STORE_IC"; case KEYED_STORE_IC: return "KEYED_STORE_IC"; case CALL_IC: return "CALL_IC"; } UNREACHABLE(); return NULL; } const char* Code::ICState2String(InlineCacheState state) { switch (state) { case UNINITIALIZED: return "UNINITIALIZED"; case PREMONOMORPHIC: return "PREMONOMORPHIC"; case MONOMORPHIC: return "MONOMORPHIC"; case MONOMORPHIC_PROTOTYPE_FAILURE: return "MONOMORPHIC_PROTOTYPE_FAILURE"; case MEGAMORPHIC: return "MEGAMORPHIC"; case DEBUG_BREAK: return "DEBUG_BREAK"; case DEBUG_PREPARE_STEP_IN: return "DEBUG_PREPARE_STEP_IN"; } UNREACHABLE(); return NULL; } const char* Code::PropertyType2String(PropertyType type) { switch (type) { case NORMAL: return "NORMAL"; case FIELD: return "FIELD"; case CONSTANT_FUNCTION: return "CONSTANT_FUNCTION"; case CALLBACKS: return "CALLBACKS"; case INTERCEPTOR: return "INTERCEPTOR"; case MAP_TRANSITION: return "MAP_TRANSITION"; case CONSTANT_TRANSITION: return "CONSTANT_TRANSITION"; case NULL_DESCRIPTOR: return "NULL_DESCRIPTOR"; } UNREACHABLE(); return NULL; } void Code::Disassemble(const char* name) { PrintF("kind = %s\n", Kind2String(kind())); if (is_inline_cache_stub()) { PrintF("ic_state = %s\n", ICState2String(ic_state())); PrintF("ic_in_loop = %d\n", ic_in_loop() == IN_LOOP); if (ic_state() == MONOMORPHIC) { PrintF("type = %s\n", PropertyType2String(type())); } } if ((name != NULL) && (name[0] != '\0')) { PrintF("name = %s\n", name); } PrintF("Instructions (size = %d)\n", instruction_size()); Disassembler::Decode(NULL, this); PrintF("\n"); PrintF("RelocInfo (size = %d)\n", relocation_size()); for (RelocIterator it(this); !it.done(); it.next()) it.rinfo()->Print(); PrintF("\n"); } #endif // ENABLE_DISASSEMBLER void JSObject::SetFastElements(FixedArray* elems) { // We should never end in here with a pixel or external array. ASSERT(!HasPixelElements() && !HasExternalArrayElements()); #ifdef DEBUG // Check the provided array is filled with the_hole. uint32_t len = static_cast<uint32_t>(elems->length()); for (uint32_t i = 0; i < len; i++) ASSERT(elems->get(i)->IsTheHole()); #endif AssertNoAllocation no_gc; WriteBarrierMode mode = elems->GetWriteBarrierMode(no_gc); switch (GetElementsKind()) { case FAST_ELEMENTS: { FixedArray* old_elements = FixedArray::cast(elements()); uint32_t old_length = static_cast<uint32_t>(old_elements->length()); // Fill out the new array with this content and array holes. for (uint32_t i = 0; i < old_length; i++) { elems->set(i, old_elements->get(i), mode); } break; } case DICTIONARY_ELEMENTS: { NumberDictionary* dictionary = NumberDictionary::cast(elements()); for (int i = 0; i < dictionary->Capacity(); i++) { Object* key = dictionary->KeyAt(i); if (key->IsNumber()) { uint32_t entry = static_cast<uint32_t>(key->Number()); elems->set(entry, dictionary->ValueAt(i), mode); } } break; } default: UNREACHABLE(); break; } set_elements(elems); } Object* JSObject::SetSlowElements(Object* len) { // We should never end in here with a pixel or external array. ASSERT(!HasPixelElements() && !HasExternalArrayElements()); uint32_t new_length = static_cast<uint32_t>(len->Number()); switch (GetElementsKind()) { case FAST_ELEMENTS: { // Make sure we never try to shrink dense arrays into sparse arrays. ASSERT(static_cast<uint32_t>(FixedArray::cast(elements())->length()) <= new_length); Object* obj = NormalizeElements(); if (obj->IsFailure()) return obj; // Update length for JSArrays. if (IsJSArray()) JSArray::cast(this)->set_length(len); break; } case DICTIONARY_ELEMENTS: { if (IsJSArray()) { uint32_t old_length = static_cast<uint32_t>(JSArray::cast(this)->length()->Number()); element_dictionary()->RemoveNumberEntries(new_length, old_length), JSArray::cast(this)->set_length(len); } break; } default: UNREACHABLE(); break; } return this; } Object* JSArray::Initialize(int capacity) { ASSERT(capacity >= 0); set_length(Smi::FromInt(0)); FixedArray* new_elements; if (capacity == 0) { new_elements = Heap::empty_fixed_array(); } else { Object* obj = Heap::AllocateFixedArrayWithHoles(capacity); if (obj->IsFailure()) return obj; new_elements = FixedArray::cast(obj); } set_elements(new_elements); return this; } void JSArray::Expand(int required_size) { Handle<JSArray> self(this); Handle<FixedArray> old_backing(FixedArray::cast(elements())); int old_size = old_backing->length(); int new_size = required_size > old_size ? required_size : old_size; Handle<FixedArray> new_backing = Factory::NewFixedArray(new_size); // Can't use this any more now because we may have had a GC! for (int i = 0; i < old_size; i++) new_backing->set(i, old_backing->get(i)); self->SetContent(*new_backing); } // Computes the new capacity when expanding the elements of a JSObject. static int NewElementsCapacity(int old_capacity) { // (old_capacity + 50%) + 16 return old_capacity + (old_capacity >> 1) + 16; } static Object* ArrayLengthRangeError() { HandleScope scope; return Top::Throw(*Factory::NewRangeError("invalid_array_length", HandleVector<Object>(NULL, 0))); } Object* JSObject::SetElementsLength(Object* len) { // We should never end in here with a pixel or external array. ASSERT(!HasPixelElements() && !HasExternalArrayElements()); Object* smi_length = len->ToSmi(); if (smi_length->IsSmi()) { int value = Smi::cast(smi_length)->value(); if (value < 0) return ArrayLengthRangeError(); switch (GetElementsKind()) { case FAST_ELEMENTS: { int old_capacity = FixedArray::cast(elements())->length(); if (value <= old_capacity) { if (IsJSArray()) { int old_length = FastD2I(JSArray::cast(this)->length()->Number()); // NOTE: We may be able to optimize this by removing the // last part of the elements backing storage array and // setting the capacity to the new size. for (int i = value; i < old_length; i++) { FixedArray::cast(elements())->set_the_hole(i); } JSArray::cast(this)->set_length(Smi::cast(smi_length)); } return this; } int min = NewElementsCapacity(old_capacity); int new_capacity = value > min ? value : min; if (new_capacity <= kMaxFastElementsLength || !ShouldConvertToSlowElements(new_capacity)) { Object* obj = Heap::AllocateFixedArrayWithHoles(new_capacity); if (obj->IsFailure()) return obj; if (IsJSArray()) { JSArray::cast(this)->set_length(Smi::cast(smi_length)); } SetFastElements(FixedArray::cast(obj)); return this; } break; } case DICTIONARY_ELEMENTS: { if (IsJSArray()) { if (value == 0) { // If the length of a slow array is reset to zero, we clear // the array and flush backing storage. This has the added // benefit that the array returns to fast mode. initialize_elements(); } else { // Remove deleted elements. uint32_t old_length = static_cast<uint32_t>(JSArray::cast(this)->length()->Number()); element_dictionary()->RemoveNumberEntries(value, old_length); } JSArray::cast(this)->set_length(Smi::cast(smi_length)); } return this; } default: UNREACHABLE(); break; } } // General slow case. if (len->IsNumber()) { uint32_t length; if (Array::IndexFromObject(len, &length)) { return SetSlowElements(len); } else { return ArrayLengthRangeError(); } } // len is not a number so make the array size one and // set only element to len. Object* obj = Heap::AllocateFixedArray(1); if (obj->IsFailure()) return obj; FixedArray::cast(obj)->set(0, len); if (IsJSArray()) JSArray::cast(this)->set_length(Smi::FromInt(1)); set_elements(FixedArray::cast(obj)); return this; } Object* JSObject::SetPrototype(Object* value, bool skip_hidden_prototypes) { // Silently ignore the change if value is not a JSObject or null. // SpiderMonkey behaves this way. if (!value->IsJSObject() && !value->IsNull()) return value; // Before we can set the prototype we need to be sure // prototype cycles are prevented. // It is sufficient to validate that the receiver is not in the new prototype // chain. for (Object* pt = value; pt != Heap::null_value(); pt = pt->GetPrototype()) { if (JSObject::cast(pt) == this) { // Cycle detected. HandleScope scope; return Top::Throw(*Factory::NewError("cyclic_proto", HandleVector<Object>(NULL, 0))); } } JSObject* real_receiver = this; if (skip_hidden_prototypes) { // Find the first object in the chain whose prototype object is not // hidden and set the new prototype on that object. Object* current_proto = real_receiver->GetPrototype(); while (current_proto->IsJSObject() && JSObject::cast(current_proto)->map()->is_hidden_prototype()) { real_receiver = JSObject::cast(current_proto); current_proto = current_proto->GetPrototype(); } } // Set the new prototype of the object. Object* new_map = real_receiver->map()->CopyDropTransitions(); if (new_map->IsFailure()) return new_map; Map::cast(new_map)->set_prototype(value); real_receiver->set_map(Map::cast(new_map)); return value; } bool JSObject::HasElementPostInterceptor(JSObject* receiver, uint32_t index) { switch (GetElementsKind()) { case FAST_ELEMENTS: { uint32_t length = IsJSArray() ? static_cast<uint32_t> (Smi::cast(JSArray::cast(this)->length())->value()) : static_cast<uint32_t>(FixedArray::cast(elements())->length()); if ((index < length) && !FixedArray::cast(elements())->get(index)->IsTheHole()) { return true; } break; } case PIXEL_ELEMENTS: { // TODO(iposva): Add testcase. PixelArray* pixels = PixelArray::cast(elements()); if (index < static_cast<uint32_t>(pixels->length())) { return true; } break; } case EXTERNAL_BYTE_ELEMENTS: case EXTERNAL_UNSIGNED_BYTE_ELEMENTS: case EXTERNAL_SHORT_ELEMENTS: case EXTERNAL_UNSIGNED_SHORT_ELEMENTS: case EXTERNAL_INT_ELEMENTS: case EXTERNAL_UNSIGNED_INT_ELEMENTS: case EXTERNAL_FLOAT_ELEMENTS: { // TODO(kbr): Add testcase. ExternalArray* array = ExternalArray::cast(elements()); if (index < static_cast<uint32_t>(array->length())) { return true; } break; } case DICTIONARY_ELEMENTS: { if (element_dictionary()->FindEntry(index) != NumberDictionary::kNotFound) { return true; } break; } default: UNREACHABLE(); break; } // Handle [] on String objects. if (this->IsStringObjectWithCharacterAt(index)) return true; Object* pt = GetPrototype(); if (pt == Heap::null_value()) return false; return JSObject::cast(pt)->HasElementWithReceiver(receiver, index); } bool JSObject::HasElementWithInterceptor(JSObject* receiver, uint32_t index) { // Make sure that the top context does not change when doing // callbacks or interceptor calls. AssertNoContextChange ncc; HandleScope scope; Handle<InterceptorInfo> interceptor(GetIndexedInterceptor()); Handle<JSObject> receiver_handle(receiver); Handle<JSObject> holder_handle(this); CustomArguments args(interceptor->data(), receiver, this); v8::AccessorInfo info(args.end()); if (!interceptor->query()->IsUndefined()) { v8::IndexedPropertyQuery query = v8::ToCData<v8::IndexedPropertyQuery>(interceptor->query()); LOG(ApiIndexedPropertyAccess("interceptor-indexed-has", this, index)); v8::Handle<v8::Boolean> result; { // Leaving JavaScript. VMState state(EXTERNAL); result = query(index, info); } if (!result.IsEmpty()) return result->IsTrue(); } else if (!interceptor->getter()->IsUndefined()) { v8::IndexedPropertyGetter getter = v8::ToCData<v8::IndexedPropertyGetter>(interceptor->getter()); LOG(ApiIndexedPropertyAccess("interceptor-indexed-has-get", this, index)); v8::Handle<v8::Value> result; { // Leaving JavaScript. VMState state(EXTERNAL); result = getter(index, info); } if (!result.IsEmpty()) return true; } return holder_handle->HasElementPostInterceptor(*receiver_handle, index); } bool JSObject::HasLocalElement(uint32_t index) { // Check access rights if needed. if (IsAccessCheckNeeded() && !Top::MayIndexedAccess(this, index, v8::ACCESS_HAS)) { Top::ReportFailedAccessCheck(this, v8::ACCESS_HAS); return false; } // Check for lookup interceptor if (HasIndexedInterceptor()) { return HasElementWithInterceptor(this, index); } // Handle [] on String objects. if (this->IsStringObjectWithCharacterAt(index)) return true; switch (GetElementsKind()) { case FAST_ELEMENTS: { uint32_t length = IsJSArray() ? static_cast<uint32_t> (Smi::cast(JSArray::cast(this)->length())->value()) : static_cast<uint32_t>(FixedArray::cast(elements())->length()); return (index < length) && !FixedArray::cast(elements())->get(index)->IsTheHole(); } case PIXEL_ELEMENTS: { PixelArray* pixels = PixelArray::cast(elements()); return (index < static_cast<uint32_t>(pixels->length())); } case EXTERNAL_BYTE_ELEMENTS: case EXTERNAL_UNSIGNED_BYTE_ELEMENTS: case EXTERNAL_SHORT_ELEMENTS: case EXTERNAL_UNSIGNED_SHORT_ELEMENTS: case EXTERNAL_INT_ELEMENTS: case EXTERNAL_UNSIGNED_INT_ELEMENTS: case EXTERNAL_FLOAT_ELEMENTS: { ExternalArray* array = ExternalArray::cast(elements()); return (index < static_cast<uint32_t>(array->length())); } case DICTIONARY_ELEMENTS: { return element_dictionary()->FindEntry(index) != NumberDictionary::kNotFound; } default: UNREACHABLE(); break; } UNREACHABLE(); return Heap::null_value(); } bool JSObject::HasElementWithReceiver(JSObject* receiver, uint32_t index) { // Check access rights if needed. if (IsAccessCheckNeeded() && !Top::MayIndexedAccess(this, index, v8::ACCESS_HAS)) { Top::ReportFailedAccessCheck(this, v8::ACCESS_HAS); return false; } // Check for lookup interceptor if (HasIndexedInterceptor()) { return HasElementWithInterceptor(receiver, index); } switch (GetElementsKind()) { case FAST_ELEMENTS: { uint32_t length = IsJSArray() ? static_cast<uint32_t> (Smi::cast(JSArray::cast(this)->length())->value()) : static_cast<uint32_t>(FixedArray::cast(elements())->length()); if ((index < length) && !FixedArray::cast(elements())->get(index)->IsTheHole()) return true; break; } case PIXEL_ELEMENTS: { PixelArray* pixels = PixelArray::cast(elements()); if (index < static_cast<uint32_t>(pixels->length())) { return true; } break; } case EXTERNAL_BYTE_ELEMENTS: case EXTERNAL_UNSIGNED_BYTE_ELEMENTS: case EXTERNAL_SHORT_ELEMENTS: case EXTERNAL_UNSIGNED_SHORT_ELEMENTS: case EXTERNAL_INT_ELEMENTS: case EXTERNAL_UNSIGNED_INT_ELEMENTS: case EXTERNAL_FLOAT_ELEMENTS: { ExternalArray* array = ExternalArray::cast(elements()); if (index < static_cast<uint32_t>(array->length())) { return true; } break; } case DICTIONARY_ELEMENTS: { if (element_dictionary()->FindEntry(index) != NumberDictionary::kNotFound) { return true; } break; } default: UNREACHABLE(); break; } // Handle [] on String objects. if (this->IsStringObjectWithCharacterAt(index)) return true; Object* pt = GetPrototype(); if (pt == Heap::null_value()) return false; return JSObject::cast(pt)->HasElementWithReceiver(receiver, index); } Object* JSObject::SetElementWithInterceptor(uint32_t index, Object* value) { // Make sure that the top context does not change when doing // callbacks or interceptor calls. AssertNoContextChange ncc; HandleScope scope; Handle<InterceptorInfo> interceptor(GetIndexedInterceptor()); Handle<JSObject> this_handle(this); Handle<Object> value_handle(value); if (!interceptor->setter()->IsUndefined()) { v8::IndexedPropertySetter setter = v8::ToCData<v8::IndexedPropertySetter>(interceptor->setter()); LOG(ApiIndexedPropertyAccess("interceptor-indexed-set", this, index)); CustomArguments args(interceptor->data(), this, this); v8::AccessorInfo info(args.end()); v8::Handle<v8::Value> result; { // Leaving JavaScript. VMState state(EXTERNAL); result = setter(index, v8::Utils::ToLocal(value_handle), info); } RETURN_IF_SCHEDULED_EXCEPTION(); if (!result.IsEmpty()) return *value_handle; } Object* raw_result = this_handle->SetElementWithoutInterceptor(index, *value_handle); RETURN_IF_SCHEDULED_EXCEPTION(); return raw_result; } // Adding n elements in fast case is O(n*n). // Note: revisit design to have dual undefined values to capture absent // elements. Object* JSObject::SetFastElement(uint32_t index, Object* value) { ASSERT(HasFastElements()); FixedArray* elms = FixedArray::cast(elements()); uint32_t elms_length = static_cast<uint32_t>(elms->length()); if (!IsJSArray() && (index >= elms_length || elms->get(index)->IsTheHole())) { Object* setter = LookupCallbackSetterInPrototypes(index); if (setter->IsJSFunction()) { return SetPropertyWithDefinedSetter(JSFunction::cast(setter), value); } } // Check whether there is extra space in fixed array.. if (index < elms_length) { elms->set(index, value); if (IsJSArray()) { // Update the length of the array if needed. uint32_t array_length = 0; CHECK(Array::IndexFromObject(JSArray::cast(this)->length(), &array_length)); if (index >= array_length) { JSArray::cast(this)->set_length(Smi::FromInt(index + 1)); } } return value; } // Allow gap in fast case. if ((index - elms_length) < kMaxGap) { // Try allocating extra space. int new_capacity = NewElementsCapacity(index+1); if (new_capacity <= kMaxFastElementsLength || !ShouldConvertToSlowElements(new_capacity)) { ASSERT(static_cast<uint32_t>(new_capacity) > index); Object* obj = Heap::AllocateFixedArrayWithHoles(new_capacity); if (obj->IsFailure()) return obj; SetFastElements(FixedArray::cast(obj)); if (IsJSArray()) { JSArray::cast(this)->set_length(Smi::FromInt(index + 1)); } FixedArray::cast(elements())->set(index, value); return value; } } // Otherwise default to slow case. Object* obj = NormalizeElements(); if (obj->IsFailure()) return obj; ASSERT(HasDictionaryElements()); return SetElement(index, value); } Object* JSObject::SetElement(uint32_t index, Object* value) { // Check access rights if needed. if (IsAccessCheckNeeded() && !Top::MayIndexedAccess(this, index, v8::ACCESS_SET)) { Top::ReportFailedAccessCheck(this, v8::ACCESS_SET); return value; } if (IsJSGlobalProxy()) { Object* proto = GetPrototype(); if (proto->IsNull()) return value; ASSERT(proto->IsJSGlobalObject()); return JSObject::cast(proto)->SetElement(index, value); } // Check for lookup interceptor if (HasIndexedInterceptor()) { return SetElementWithInterceptor(index, value); } return SetElementWithoutInterceptor(index, value); } Object* JSObject::SetElementWithoutInterceptor(uint32_t index, Object* value) { switch (GetElementsKind()) { case FAST_ELEMENTS: // Fast case. return SetFastElement(index, value); case PIXEL_ELEMENTS: { PixelArray* pixels = PixelArray::cast(elements()); return pixels->SetValue(index, value); } case EXTERNAL_BYTE_ELEMENTS: { ExternalByteArray* array = ExternalByteArray::cast(elements()); return array->SetValue(index, value); } case EXTERNAL_UNSIGNED_BYTE_ELEMENTS: { ExternalUnsignedByteArray* array = ExternalUnsignedByteArray::cast(elements()); return array->SetValue(index, value); } case EXTERNAL_SHORT_ELEMENTS: { ExternalShortArray* array = ExternalShortArray::cast(elements()); return array->SetValue(index, value); } case EXTERNAL_UNSIGNED_SHORT_ELEMENTS: { ExternalUnsignedShortArray* array = ExternalUnsignedShortArray::cast(elements()); return array->SetValue(index, value); } case EXTERNAL_INT_ELEMENTS: { ExternalIntArray* array = ExternalIntArray::cast(elements()); return array->SetValue(index, value); } case EXTERNAL_UNSIGNED_INT_ELEMENTS: { ExternalUnsignedIntArray* array = ExternalUnsignedIntArray::cast(elements()); return array->SetValue(index, value); } case EXTERNAL_FLOAT_ELEMENTS: { ExternalFloatArray* array = ExternalFloatArray::cast(elements()); return array->SetValue(index, value); } case DICTIONARY_ELEMENTS: { // Insert element in the dictionary. FixedArray* elms = FixedArray::cast(elements()); NumberDictionary* dictionary = NumberDictionary::cast(elms); int entry = dictionary->FindEntry(index); if (entry != NumberDictionary::kNotFound) { Object* element = dictionary->ValueAt(entry); PropertyDetails details = dictionary->DetailsAt(entry); if (details.type() == CALLBACKS) { // Only accessors allowed as elements. FixedArray* structure = FixedArray::cast(element); if (structure->get(kSetterIndex)->IsJSFunction()) { JSFunction* setter = JSFunction::cast(structure->get(kSetterIndex)); return SetPropertyWithDefinedSetter(setter, value); } else { Handle<Object> self(this); Handle<Object> key(Factory::NewNumberFromUint(index)); Handle<Object> args[2] = { key, self }; return Top::Throw(*Factory::NewTypeError("no_setter_in_callback", HandleVector(args, 2))); } } else { dictionary->UpdateMaxNumberKey(index); dictionary->ValueAtPut(entry, value); } } else { // Index not already used. Look for an accessor in the prototype chain. if (!IsJSArray()) { Object* setter = LookupCallbackSetterInPrototypes(index); if (setter->IsJSFunction()) { return SetPropertyWithDefinedSetter(JSFunction::cast(setter), value); } } Object* result = dictionary->AtNumberPut(index, value); if (result->IsFailure()) return result; if (elms != FixedArray::cast(result)) { set_elements(FixedArray::cast(result)); } } // Update the array length if this JSObject is an array. if (IsJSArray()) { JSArray* array = JSArray::cast(this); Object* return_value = array->JSArrayUpdateLengthFromIndex(index, value); if (return_value->IsFailure()) return return_value; } // Attempt to put this object back in fast case. if (ShouldConvertToFastElements()) { uint32_t new_length = 0; if (IsJSArray()) { CHECK(Array::IndexFromObject(JSArray::cast(this)->length(), &new_length)); JSArray::cast(this)->set_length(Smi::FromInt(new_length)); } else { new_length = NumberDictionary::cast(elements())->max_number_key() + 1; } Object* obj = Heap::AllocateFixedArrayWithHoles(new_length); if (obj->IsFailure()) return obj; SetFastElements(FixedArray::cast(obj)); #ifdef DEBUG if (FLAG_trace_normalization) { PrintF("Object elements are fast case again:\n"); Print(); } #endif } return value; } default: UNREACHABLE(); break; } // All possible cases have been handled above. Add a return to avoid the // complaints from the compiler. UNREACHABLE(); return Heap::null_value(); } Object* JSArray::JSArrayUpdateLengthFromIndex(uint32_t index, Object* value) { uint32_t old_len = 0; CHECK(Array::IndexFromObject(length(), &old_len)); // Check to see if we need to update the length. For now, we make // sure that the length stays within 32-bits (unsigned). if (index >= old_len && index != 0xffffffff) { Object* len = Heap::NumberFromDouble(static_cast<double>(index) + 1); if (len->IsFailure()) return len; set_length(len); } return value; } Object* JSObject::GetElementPostInterceptor(JSObject* receiver, uint32_t index) { // Get element works for both JSObject and JSArray since // JSArray::length cannot change. switch (GetElementsKind()) { case FAST_ELEMENTS: { FixedArray* elms = FixedArray::cast(elements()); if (index < static_cast<uint32_t>(elms->length())) { Object* value = elms->get(index); if (!value->IsTheHole()) return value; } break; } case PIXEL_ELEMENTS: { // TODO(iposva): Add testcase and implement. UNIMPLEMENTED(); break; } case EXTERNAL_BYTE_ELEMENTS: case EXTERNAL_UNSIGNED_BYTE_ELEMENTS: case EXTERNAL_SHORT_ELEMENTS: case EXTERNAL_UNSIGNED_SHORT_ELEMENTS: case EXTERNAL_INT_ELEMENTS: case EXTERNAL_UNSIGNED_INT_ELEMENTS: case EXTERNAL_FLOAT_ELEMENTS: { // TODO(kbr): Add testcase and implement. UNIMPLEMENTED(); break; } case DICTIONARY_ELEMENTS: { NumberDictionary* dictionary = element_dictionary(); int entry = dictionary->FindEntry(index); if (entry != NumberDictionary::kNotFound) { Object* element = dictionary->ValueAt(entry); PropertyDetails details = dictionary->DetailsAt(entry); if (details.type() == CALLBACKS) { // Only accessors allowed as elements. FixedArray* structure = FixedArray::cast(element); Object* getter = structure->get(kGetterIndex); if (getter->IsJSFunction()) { return GetPropertyWithDefinedGetter(receiver, JSFunction::cast(getter)); } else { // Getter is not a function. return Heap::undefined_value(); } } return element; } break; } default: UNREACHABLE(); break; } // Continue searching via the prototype chain. Object* pt = GetPrototype(); if (pt == Heap::null_value()) return Heap::undefined_value(); return pt->GetElementWithReceiver(receiver, index); } Object* JSObject::GetElementWithInterceptor(JSObject* receiver, uint32_t index) { // Make sure that the top context does not change when doing // callbacks or interceptor calls. AssertNoContextChange ncc; HandleScope scope; Handle<InterceptorInfo> interceptor(GetIndexedInterceptor()); Handle<JSObject> this_handle(receiver); Handle<JSObject> holder_handle(this); if (!interceptor->getter()->IsUndefined()) { v8::IndexedPropertyGetter getter = v8::ToCData<v8::IndexedPropertyGetter>(interceptor->getter()); LOG(ApiIndexedPropertyAccess("interceptor-indexed-get", this, index)); CustomArguments args(interceptor->data(), receiver, this); v8::AccessorInfo info(args.end()); v8::Handle<v8::Value> result; { // Leaving JavaScript. VMState state(EXTERNAL); result = getter(index, info); } RETURN_IF_SCHEDULED_EXCEPTION(); if (!result.IsEmpty()) return *v8::Utils::OpenHandle(*result); } Object* raw_result = holder_handle->GetElementPostInterceptor(*this_handle, index); RETURN_IF_SCHEDULED_EXCEPTION(); return raw_result; } Object* JSObject::GetElementWithReceiver(JSObject* receiver, uint32_t index) { // Check access rights if needed. if (IsAccessCheckNeeded() && !Top::MayIndexedAccess(this, index, v8::ACCESS_GET)) { Top::ReportFailedAccessCheck(this, v8::ACCESS_GET); return Heap::undefined_value(); } if (HasIndexedInterceptor()) { return GetElementWithInterceptor(receiver, index); } // Get element works for both JSObject and JSArray since // JSArray::length cannot change. switch (GetElementsKind()) { case FAST_ELEMENTS: { FixedArray* elms = FixedArray::cast(elements()); if (index < static_cast<uint32_t>(elms->length())) { Object* value = elms->get(index); if (!value->IsTheHole()) return value; } break; } case PIXEL_ELEMENTS: { PixelArray* pixels = PixelArray::cast(elements()); if (index < static_cast<uint32_t>(pixels->length())) { uint8_t value = pixels->get(index); return Smi::FromInt(value); } break; } case EXTERNAL_BYTE_ELEMENTS: { ExternalByteArray* array = ExternalByteArray::cast(elements()); if (index < static_cast<uint32_t>(array->length())) { int8_t value = array->get(index); return Smi::FromInt(value); } break; } case EXTERNAL_UNSIGNED_BYTE_ELEMENTS: { ExternalUnsignedByteArray* array = ExternalUnsignedByteArray::cast(elements()); if (index < static_cast<uint32_t>(array->length())) { uint8_t value = array->get(index); return Smi::FromInt(value); } break; } case EXTERNAL_SHORT_ELEMENTS: { ExternalShortArray* array = ExternalShortArray::cast(elements()); if (index < static_cast<uint32_t>(array->length())) { int16_t value = array->get(index); return Smi::FromInt(value); } break; } case EXTERNAL_UNSIGNED_SHORT_ELEMENTS: { ExternalUnsignedShortArray* array = ExternalUnsignedShortArray::cast(elements()); if (index < static_cast<uint32_t>(array->length())) { uint16_t value = array->get(index); return Smi::FromInt(value); } break; } case EXTERNAL_INT_ELEMENTS: { ExternalIntArray* array = ExternalIntArray::cast(elements()); if (index < static_cast<uint32_t>(array->length())) { int32_t value = array->get(index); return Heap::NumberFromInt32(value); } break; } case EXTERNAL_UNSIGNED_INT_ELEMENTS: { ExternalUnsignedIntArray* array = ExternalUnsignedIntArray::cast(elements()); if (index < static_cast<uint32_t>(array->length())) { uint32_t value = array->get(index); return Heap::NumberFromUint32(value); } break; } case EXTERNAL_FLOAT_ELEMENTS: { ExternalFloatArray* array = ExternalFloatArray::cast(elements()); if (index < static_cast<uint32_t>(array->length())) { float value = array->get(index); return Heap::AllocateHeapNumber(value); } break; } case DICTIONARY_ELEMENTS: { NumberDictionary* dictionary = element_dictionary(); int entry = dictionary->FindEntry(index); if (entry != NumberDictionary::kNotFound) { Object* element = dictionary->ValueAt(entry); PropertyDetails details = dictionary->DetailsAt(entry); if (details.type() == CALLBACKS) { // Only accessors allowed as elements. FixedArray* structure = FixedArray::cast(element); Object* getter = structure->get(kGetterIndex); if (getter->IsJSFunction()) { return GetPropertyWithDefinedGetter(receiver, JSFunction::cast(getter)); } else { // Getter is not a function. return Heap::undefined_value(); } } return element; } break; } } Object* pt = GetPrototype(); if (pt == Heap::null_value()) return Heap::undefined_value(); return pt->GetElementWithReceiver(receiver, index); } bool JSObject::HasDenseElements() { int capacity = 0; int number_of_elements = 0; switch (GetElementsKind()) { case FAST_ELEMENTS: { FixedArray* elms = FixedArray::cast(elements()); capacity = elms->length(); for (int i = 0; i < capacity; i++) { if (!elms->get(i)->IsTheHole()) number_of_elements++; } break; } case PIXEL_ELEMENTS: case EXTERNAL_BYTE_ELEMENTS: case EXTERNAL_UNSIGNED_BYTE_ELEMENTS: case EXTERNAL_SHORT_ELEMENTS: case EXTERNAL_UNSIGNED_SHORT_ELEMENTS: case EXTERNAL_INT_ELEMENTS: case EXTERNAL_UNSIGNED_INT_ELEMENTS: case EXTERNAL_FLOAT_ELEMENTS: { return true; } case DICTIONARY_ELEMENTS: { NumberDictionary* dictionary = NumberDictionary::cast(elements()); capacity = dictionary->Capacity(); number_of_elements = dictionary->NumberOfElements(); break; } default: UNREACHABLE(); break; } if (capacity == 0) return true; return (number_of_elements > (capacity / 2)); } bool JSObject::ShouldConvertToSlowElements(int new_capacity) { ASSERT(HasFastElements()); // Keep the array in fast case if the current backing storage is // almost filled and if the new capacity is no more than twice the // old capacity. int elements_length = FixedArray::cast(elements())->length(); return !HasDenseElements() || ((new_capacity / 2) > elements_length); } bool JSObject::ShouldConvertToFastElements() { ASSERT(HasDictionaryElements()); NumberDictionary* dictionary = NumberDictionary::cast(elements()); // If the elements are sparse, we should not go back to fast case. if (!HasDenseElements()) return false; // If an element has been added at a very high index in the elements // dictionary, we cannot go back to fast case. if (dictionary->requires_slow_elements()) return false; // An object requiring access checks is never allowed to have fast // elements. If it had fast elements we would skip security checks. if (IsAccessCheckNeeded()) return false; // If the dictionary backing storage takes up roughly half as much // space as a fast-case backing storage would the array should have // fast elements. uint32_t length = 0; if (IsJSArray()) { CHECK(Array::IndexFromObject(JSArray::cast(this)->length(), &length)); } else { length = dictionary->max_number_key(); } return static_cast<uint32_t>(dictionary->Capacity()) >= (length / (2 * NumberDictionary::kEntrySize)); } // Certain compilers request function template instantiation when they // see the definition of the other template functions in the // class. This requires us to have the template functions put // together, so even though this function belongs in objects-debug.cc, // we keep it here instead to satisfy certain compilers. #ifdef DEBUG template<typename Shape, typename Key> void Dictionary<Shape, Key>::Print() { int capacity = HashTable<Shape, Key>::Capacity(); for (int i = 0; i < capacity; i++) { Object* k = HashTable<Shape, Key>::KeyAt(i); if (HashTable<Shape, Key>::IsKey(k)) { PrintF(" "); if (k->IsString()) { String::cast(k)->StringPrint(); } else { k->ShortPrint(); } PrintF(": "); ValueAt(i)->ShortPrint(); PrintF("\n"); } } } #endif template<typename Shape, typename Key> void Dictionary<Shape, Key>::CopyValuesTo(FixedArray* elements) { int pos = 0; int capacity = HashTable<Shape, Key>::Capacity(); AssertNoAllocation no_gc; WriteBarrierMode mode = elements->GetWriteBarrierMode(no_gc); for (int i = 0; i < capacity; i++) { Object* k = Dictionary<Shape, Key>::KeyAt(i); if (Dictionary<Shape, Key>::IsKey(k)) { elements->set(pos++, ValueAt(i), mode); } } ASSERT(pos == elements->length()); } InterceptorInfo* JSObject::GetNamedInterceptor() { ASSERT(map()->has_named_interceptor()); JSFunction* constructor = JSFunction::cast(map()->constructor()); Object* template_info = constructor->shared()->function_data(); Object* result = FunctionTemplateInfo::cast(template_info)->named_property_handler(); return InterceptorInfo::cast(result); } InterceptorInfo* JSObject::GetIndexedInterceptor() { ASSERT(map()->has_indexed_interceptor()); JSFunction* constructor = JSFunction::cast(map()->constructor()); Object* template_info = constructor->shared()->function_data(); Object* result = FunctionTemplateInfo::cast(template_info)->indexed_property_handler(); return InterceptorInfo::cast(result); } Object* JSObject::GetPropertyPostInterceptor(JSObject* receiver, String* name, PropertyAttributes* attributes) { // Check local property in holder, ignore interceptor. LookupResult result; LocalLookupRealNamedProperty(name, &result); if (result.IsProperty()) { return GetProperty(receiver, &result, name, attributes); } // Continue searching via the prototype chain. Object* pt = GetPrototype(); *attributes = ABSENT; if (pt == Heap::null_value()) return Heap::undefined_value(); return pt->GetPropertyWithReceiver(receiver, name, attributes); } Object* JSObject::GetLocalPropertyPostInterceptor( JSObject* receiver, String* name, PropertyAttributes* attributes) { // Check local property in holder, ignore interceptor. LookupResult result; LocalLookupRealNamedProperty(name, &result); if (result.IsProperty()) { return GetProperty(receiver, &result, name, attributes); } return Heap::undefined_value(); } Object* JSObject::GetPropertyWithInterceptor( JSObject* receiver, String* name, PropertyAttributes* attributes) { InterceptorInfo* interceptor = GetNamedInterceptor(); HandleScope scope; Handle<JSObject> receiver_handle(receiver); Handle<JSObject> holder_handle(this); Handle<String> name_handle(name); if (!interceptor->getter()->IsUndefined()) { v8::NamedPropertyGetter getter = v8::ToCData<v8::NamedPropertyGetter>(interceptor->getter()); LOG(ApiNamedPropertyAccess("interceptor-named-get", *holder_handle, name)); CustomArguments args(interceptor->data(), receiver, this); v8::AccessorInfo info(args.end()); v8::Handle<v8::Value> result; { // Leaving JavaScript. VMState state(EXTERNAL); result = getter(v8::Utils::ToLocal(name_handle), info); } RETURN_IF_SCHEDULED_EXCEPTION(); if (!result.IsEmpty()) { *attributes = NONE; return *v8::Utils::OpenHandle(*result); } } Object* result = holder_handle->GetPropertyPostInterceptor( *receiver_handle, *name_handle, attributes); RETURN_IF_SCHEDULED_EXCEPTION(); return result; } bool JSObject::HasRealNamedProperty(String* key) { // Check access rights if needed. if (IsAccessCheckNeeded() && !Top::MayNamedAccess(this, key, v8::ACCESS_HAS)) { Top::ReportFailedAccessCheck(this, v8::ACCESS_HAS); return false; } LookupResult result; LocalLookupRealNamedProperty(key, &result); return result.IsProperty() && (result.type() != INTERCEPTOR); } bool JSObject::HasRealElementProperty(uint32_t index) { // Check access rights if needed. if (IsAccessCheckNeeded() && !Top::MayIndexedAccess(this, index, v8::ACCESS_HAS)) { Top::ReportFailedAccessCheck(this, v8::ACCESS_HAS); return false; } // Handle [] on String objects. if (this->IsStringObjectWithCharacterAt(index)) return true; switch (GetElementsKind()) { case FAST_ELEMENTS: { uint32_t length = IsJSArray() ? static_cast<uint32_t>( Smi::cast(JSArray::cast(this)->length())->value()) : static_cast<uint32_t>(FixedArray::cast(elements())->length()); return (index < length) && !FixedArray::cast(elements())->get(index)->IsTheHole(); } case PIXEL_ELEMENTS: { PixelArray* pixels = PixelArray::cast(elements()); return index < static_cast<uint32_t>(pixels->length()); } case EXTERNAL_BYTE_ELEMENTS: case EXTERNAL_UNSIGNED_BYTE_ELEMENTS: case EXTERNAL_SHORT_ELEMENTS: case EXTERNAL_UNSIGNED_SHORT_ELEMENTS: case EXTERNAL_INT_ELEMENTS: case EXTERNAL_UNSIGNED_INT_ELEMENTS: case EXTERNAL_FLOAT_ELEMENTS: { ExternalArray* array = ExternalArray::cast(elements()); return index < static_cast<uint32_t>(array->length()); } case DICTIONARY_ELEMENTS: { return element_dictionary()->FindEntry(index) != NumberDictionary::kNotFound; } default: UNREACHABLE(); break; } // All possibilities have been handled above already. UNREACHABLE(); return Heap::null_value(); } bool JSObject::HasRealNamedCallbackProperty(String* key) { // Check access rights if needed. if (IsAccessCheckNeeded() && !Top::MayNamedAccess(this, key, v8::ACCESS_HAS)) { Top::ReportFailedAccessCheck(this, v8::ACCESS_HAS); return false; } LookupResult result; LocalLookupRealNamedProperty(key, &result); return result.IsProperty() && (result.type() == CALLBACKS); } int JSObject::NumberOfLocalProperties(PropertyAttributes filter) { if (HasFastProperties()) { DescriptorArray* descs = map()->instance_descriptors(); int result = 0; for (int i = 0; i < descs->number_of_descriptors(); i++) { PropertyDetails details = descs->GetDetails(i); if (details.IsProperty() && (details.attributes() & filter) == 0) { result++; } } return result; } else { return property_dictionary()->NumberOfElementsFilterAttributes(filter); } } int JSObject::NumberOfEnumProperties() { return NumberOfLocalProperties(static_cast<PropertyAttributes>(DONT_ENUM)); } void FixedArray::SwapPairs(FixedArray* numbers, int i, int j) { Object* temp = get(i); set(i, get(j)); set(j, temp); if (this != numbers) { temp = numbers->get(i); numbers->set(i, numbers->get(j)); numbers->set(j, temp); } } static void InsertionSortPairs(FixedArray* content, FixedArray* numbers, int len) { for (int i = 1; i < len; i++) { int j = i; while (j > 0 && (NumberToUint32(numbers->get(j - 1)) > NumberToUint32(numbers->get(j)))) { content->SwapPairs(numbers, j - 1, j); j--; } } } void HeapSortPairs(FixedArray* content, FixedArray* numbers, int len) { // In-place heap sort. ASSERT(content->length() == numbers->length()); // Bottom-up max-heap construction. for (int i = 1; i < len; ++i) { int child_index = i; while (child_index > 0) { int parent_index = ((child_index + 1) >> 1) - 1; uint32_t parent_value = NumberToUint32(numbers->get(parent_index)); uint32_t child_value = NumberToUint32(numbers->get(child_index)); if (parent_value < child_value) { content->SwapPairs(numbers, parent_index, child_index); } else { break; } child_index = parent_index; } } // Extract elements and create sorted array. for (int i = len - 1; i > 0; --i) { // Put max element at the back of the array. content->SwapPairs(numbers, 0, i); // Sift down the new top element. int parent_index = 0; while (true) { int child_index = ((parent_index + 1) << 1) - 1; if (child_index >= i) break; uint32_t child1_value = NumberToUint32(numbers->get(child_index)); uint32_t child2_value = NumberToUint32(numbers->get(child_index + 1)); uint32_t parent_value = NumberToUint32(numbers->get(parent_index)); if (child_index + 1 >= i || child1_value > child2_value) { if (parent_value > child1_value) break; content->SwapPairs(numbers, parent_index, child_index); parent_index = child_index; } else { if (parent_value > child2_value) break; content->SwapPairs(numbers, parent_index, child_index + 1); parent_index = child_index + 1; } } } } // Sort this array and the numbers as pairs wrt. the (distinct) numbers. void FixedArray::SortPairs(FixedArray* numbers, uint32_t len) { ASSERT(this->length() == numbers->length()); // For small arrays, simply use insertion sort. if (len <= 10) { InsertionSortPairs(this, numbers, len); return; } // Check the range of indices. uint32_t min_index = NumberToUint32(numbers->get(0)); uint32_t max_index = min_index; uint32_t i; for (i = 1; i < len; i++) { if (NumberToUint32(numbers->get(i)) < min_index) { min_index = NumberToUint32(numbers->get(i)); } else if (NumberToUint32(numbers->get(i)) > max_index) { max_index = NumberToUint32(numbers->get(i)); } } if (max_index - min_index + 1 == len) { // Indices form a contiguous range, unless there are duplicates. // Do an in-place linear time sort assuming distinct numbers, but // avoid hanging in case they are not. for (i = 0; i < len; i++) { uint32_t p; uint32_t j = 0; // While the current element at i is not at its correct position p, // swap the elements at these two positions. while ((p = NumberToUint32(numbers->get(i)) - min_index) != i && j++ < len) { SwapPairs(numbers, i, p); } } } else { HeapSortPairs(this, numbers, len); return; } } // Fill in the names of local properties into the supplied storage. The main // purpose of this function is to provide reflection information for the object // mirrors. void JSObject::GetLocalPropertyNames(FixedArray* storage, int index) { ASSERT(storage->length() >= (NumberOfLocalProperties(NONE) - index)); if (HasFastProperties()) { DescriptorArray* descs = map()->instance_descriptors(); for (int i = 0; i < descs->number_of_descriptors(); i++) { if (descs->IsProperty(i)) storage->set(index++, descs->GetKey(i)); } ASSERT(storage->length() >= index); } else { property_dictionary()->CopyKeysTo(storage); } } int JSObject::NumberOfLocalElements(PropertyAttributes filter) { return GetLocalElementKeys(NULL, filter); } int JSObject::NumberOfEnumElements() { // Fast case for objects with no elements. if (!IsJSValue() && HasFastElements()) { uint32_t length = IsJSArray() ? static_cast<uint32_t>( Smi::cast(JSArray::cast(this)->length())->value()) : static_cast<uint32_t>(FixedArray::cast(elements())->length()); if (length == 0) return 0; } // Compute the number of enumerable elements. return NumberOfLocalElements(static_cast<PropertyAttributes>(DONT_ENUM)); } int JSObject::GetLocalElementKeys(FixedArray* storage, PropertyAttributes filter) { int counter = 0; switch (GetElementsKind()) { case FAST_ELEMENTS: { int length = IsJSArray() ? Smi::cast(JSArray::cast(this)->length())->value() : FixedArray::cast(elements())->length(); for (int i = 0; i < length; i++) { if (!FixedArray::cast(elements())->get(i)->IsTheHole()) { if (storage != NULL) { storage->set(counter, Smi::FromInt(i)); } counter++; } } ASSERT(!storage || storage->length() >= counter); break; } case PIXEL_ELEMENTS: { int length = PixelArray::cast(elements())->length(); while (counter < length) { if (storage != NULL) { storage->set(counter, Smi::FromInt(counter)); } counter++; } ASSERT(!storage || storage->length() >= counter); break; } case EXTERNAL_BYTE_ELEMENTS: case EXTERNAL_UNSIGNED_BYTE_ELEMENTS: case EXTERNAL_SHORT_ELEMENTS: case EXTERNAL_UNSIGNED_SHORT_ELEMENTS: case EXTERNAL_INT_ELEMENTS: case EXTERNAL_UNSIGNED_INT_ELEMENTS: case EXTERNAL_FLOAT_ELEMENTS: { int length = ExternalArray::cast(elements())->length(); while (counter < length) { if (storage != NULL) { storage->set(counter, Smi::FromInt(counter)); } counter++; } ASSERT(!storage || storage->length() >= counter); break; } case DICTIONARY_ELEMENTS: { if (storage != NULL) { element_dictionary()->CopyKeysTo(storage, filter); } counter = element_dictionary()->NumberOfElementsFilterAttributes(filter); break; } default: UNREACHABLE(); break; } if (this->IsJSValue()) { Object* val = JSValue::cast(this)->value(); if (val->IsString()) { String* str = String::cast(val); if (storage) { for (int i = 0; i < str->length(); i++) { storage->set(counter + i, Smi::FromInt(i)); } } counter += str->length(); } } ASSERT(!storage || storage->length() == counter); return counter; } int JSObject::GetEnumElementKeys(FixedArray* storage) { return GetLocalElementKeys(storage, static_cast<PropertyAttributes>(DONT_ENUM)); } bool NumberDictionaryShape::IsMatch(uint32_t key, Object* other) { ASSERT(other->IsNumber()); return key == static_cast<uint32_t>(other->Number()); } uint32_t NumberDictionaryShape::Hash(uint32_t key) { return ComputeIntegerHash(key); } uint32_t NumberDictionaryShape::HashForObject(uint32_t key, Object* other) { ASSERT(other->IsNumber()); return ComputeIntegerHash(static_cast<uint32_t>(other->Number())); } Object* NumberDictionaryShape::AsObject(uint32_t key) { return Heap::NumberFromUint32(key); } bool StringDictionaryShape::IsMatch(String* key, Object* other) { // We know that all entries in a hash table had their hash keys created. // Use that knowledge to have fast failure. if (key->Hash() != String::cast(other)->Hash()) return false; return key->Equals(String::cast(other)); } uint32_t StringDictionaryShape::Hash(String* key) { return key->Hash(); } uint32_t StringDictionaryShape::HashForObject(String* key, Object* other) { return String::cast(other)->Hash(); } Object* StringDictionaryShape::AsObject(String* key) { return key; } // StringKey simply carries a string object as key. class StringKey : public HashTableKey { public: explicit StringKey(String* string) : string_(string), hash_(HashForObject(string)) { } bool IsMatch(Object* string) { // We know that all entries in a hash table had their hash keys created. // Use that knowledge to have fast failure. if (hash_ != HashForObject(string)) { return false; } return string_->Equals(String::cast(string)); } uint32_t Hash() { return hash_; } uint32_t HashForObject(Object* other) { return String::cast(other)->Hash(); } Object* AsObject() { return string_; } String* string_; uint32_t hash_; }; // StringSharedKeys are used as keys in the eval cache. class StringSharedKey : public HashTableKey { public: StringSharedKey(String* source, SharedFunctionInfo* shared) : source_(source), shared_(shared) { } bool IsMatch(Object* other) { if (!other->IsFixedArray()) return false; FixedArray* pair = FixedArray::cast(other); SharedFunctionInfo* shared = SharedFunctionInfo::cast(pair->get(0)); if (shared != shared_) return false; String* source = String::cast(pair->get(1)); return source->Equals(source_); } static uint32_t StringSharedHashHelper(String* source, SharedFunctionInfo* shared) { uint32_t hash = source->Hash(); if (shared->HasSourceCode()) { // Instead of using the SharedFunctionInfo pointer in the hash // code computation, we use a combination of the hash of the // script source code and the start and end positions. We do // this to ensure that the cache entries can survive garbage // collection. Script* script = Script::cast(shared->script()); hash ^= String::cast(script->source())->Hash(); hash += shared->start_position(); } return hash; } uint32_t Hash() { return StringSharedHashHelper(source_, shared_); } uint32_t HashForObject(Object* obj) { FixedArray* pair = FixedArray::cast(obj); SharedFunctionInfo* shared = SharedFunctionInfo::cast(pair->get(0)); String* source = String::cast(pair->get(1)); return StringSharedHashHelper(source, shared); } Object* AsObject() { Object* obj = Heap::AllocateFixedArray(2); if (obj->IsFailure()) return obj; FixedArray* pair = FixedArray::cast(obj); pair->set(0, shared_); pair->set(1, source_); return pair; } private: String* source_; SharedFunctionInfo* shared_; }; // RegExpKey carries the source and flags of a regular expression as key. class RegExpKey : public HashTableKey { public: RegExpKey(String* string, JSRegExp::Flags flags) : string_(string), flags_(Smi::FromInt(flags.value())) { } // Rather than storing the key in the hash table, a pointer to the // stored value is stored where the key should be. IsMatch then // compares the search key to the found object, rather than comparing // a key to a key. bool IsMatch(Object* obj) { FixedArray* val = FixedArray::cast(obj); return string_->Equals(String::cast(val->get(JSRegExp::kSourceIndex))) && (flags_ == val->get(JSRegExp::kFlagsIndex)); } uint32_t Hash() { return RegExpHash(string_, flags_); } Object* AsObject() { // Plain hash maps, which is where regexp keys are used, don't // use this function. UNREACHABLE(); return NULL; } uint32_t HashForObject(Object* obj) { FixedArray* val = FixedArray::cast(obj); return RegExpHash(String::cast(val->get(JSRegExp::kSourceIndex)), Smi::cast(val->get(JSRegExp::kFlagsIndex))); } static uint32_t RegExpHash(String* string, Smi* flags) { return string->Hash() + flags->value(); } String* string_; Smi* flags_; }; // Utf8SymbolKey carries a vector of chars as key. class Utf8SymbolKey : public HashTableKey { public: explicit Utf8SymbolKey(Vector<const char> string) : string_(string), hash_field_(0) { } bool IsMatch(Object* string) { return String::cast(string)->IsEqualTo(string_); } uint32_t Hash() { if (hash_field_ != 0) return hash_field_ >> String::kHashShift; unibrow::Utf8InputBuffer<> buffer(string_.start(), static_cast<unsigned>(string_.length())); chars_ = buffer.Length(); hash_field_ = String::ComputeHashField(&buffer, chars_); uint32_t result = hash_field_ >> String::kHashShift; ASSERT(result != 0); // Ensure that the hash value of 0 is never computed. return result; } uint32_t HashForObject(Object* other) { return String::cast(other)->Hash(); } Object* AsObject() { if (hash_field_ == 0) Hash(); return Heap::AllocateSymbol(string_, chars_, hash_field_); } Vector<const char> string_; uint32_t hash_field_; int chars_; // Caches the number of characters when computing the hash code. }; // SymbolKey carries a string/symbol object as key. class SymbolKey : public HashTableKey { public: explicit SymbolKey(String* string) : string_(string) { } bool IsMatch(Object* string) { return String::cast(string)->Equals(string_); } uint32_t Hash() { return string_->Hash(); } uint32_t HashForObject(Object* other) { return String::cast(other)->Hash(); } Object* AsObject() { // If the string is a cons string, attempt to flatten it so that // symbols will most often be flat strings. if (StringShape(string_).IsCons()) { ConsString* cons_string = ConsString::cast(string_); cons_string->TryFlatten(); if (cons_string->second()->length() == 0) { string_ = cons_string->first(); } } // Transform string to symbol if possible. Map* map = Heap::SymbolMapForString(string_); if (map != NULL) { string_->set_map(map); ASSERT(string_->IsSymbol()); return string_; } // Otherwise allocate a new symbol. StringInputBuffer buffer(string_); return Heap::AllocateInternalSymbol(&buffer, string_->length(), string_->hash_field()); } static uint32_t StringHash(Object* obj) { return String::cast(obj)->Hash(); } String* string_; }; template<typename Shape, typename Key> void HashTable<Shape, Key>::IteratePrefix(ObjectVisitor* v) { IteratePointers(v, 0, kElementsStartOffset); } template<typename Shape, typename Key> void HashTable<Shape, Key>::IterateElements(ObjectVisitor* v) { IteratePointers(v, kElementsStartOffset, kHeaderSize + length() * kPointerSize); } template<typename Shape, typename Key> Object* HashTable<Shape, Key>::Allocate(int at_least_space_for) { int capacity = RoundUpToPowerOf2(at_least_space_for); if (capacity < 4) { capacity = 4; // Guarantee min capacity. } else if (capacity > HashTable::kMaxCapacity) { return Failure::OutOfMemoryException(); } Object* obj = Heap::AllocateHashTable(EntryToIndex(capacity)); if (!obj->IsFailure()) { HashTable::cast(obj)->SetNumberOfElements(0); HashTable::cast(obj)->SetNumberOfDeletedElements(0); HashTable::cast(obj)->SetCapacity(capacity); } return obj; } // Find entry for key otherwise return kNotFound. template<typename Shape, typename Key> int HashTable<Shape, Key>::FindEntry(Key key) { uint32_t capacity = Capacity(); uint32_t entry = FirstProbe(Shape::Hash(key), capacity); uint32_t count = 1; // EnsureCapacity will guarantee the hash table is never full. while (true) { Object* element = KeyAt(entry); if (element->IsUndefined()) break; // Empty entry. if (!element->IsNull() && Shape::IsMatch(key, element)) return entry; entry = NextProbe(entry, count++, capacity); } return kNotFound; } template<typename Shape, typename Key> Object* HashTable<Shape, Key>::EnsureCapacity(int n, Key key) { int capacity = Capacity(); int nof = NumberOfElements() + n; int nod = NumberOfDeletedElements(); // Return if: // 50% is still free after adding n elements and // at most 50% of the free elements are deleted elements. if ((nof + (nof >> 1) <= capacity) && (nod <= (capacity - nof) >> 1)) return this; Object* obj = Allocate(nof * 2); if (obj->IsFailure()) return obj; AssertNoAllocation no_gc; HashTable* table = HashTable::cast(obj); WriteBarrierMode mode = table->GetWriteBarrierMode(no_gc); // Copy prefix to new array. for (int i = kPrefixStartIndex; i < kPrefixStartIndex + Shape::kPrefixSize; i++) { table->set(i, get(i), mode); } // Rehash the elements. for (int i = 0; i < capacity; i++) { uint32_t from_index = EntryToIndex(i); Object* k = get(from_index); if (IsKey(k)) { uint32_t hash = Shape::HashForObject(key, k); uint32_t insertion_index = EntryToIndex(table->FindInsertionEntry(hash)); for (int j = 0; j < Shape::kEntrySize; j++) { table->set(insertion_index + j, get(from_index + j), mode); } } } table->SetNumberOfElements(NumberOfElements()); table->SetNumberOfDeletedElements(0); return table; } template<typename Shape, typename Key> uint32_t HashTable<Shape, Key>::FindInsertionEntry(uint32_t hash) { uint32_t capacity = Capacity(); uint32_t entry = FirstProbe(hash, capacity); uint32_t count = 1; // EnsureCapacity will guarantee the hash table is never full. while (true) { Object* element = KeyAt(entry); if (element->IsUndefined() || element->IsNull()) break; entry = NextProbe(entry, count++, capacity); } return entry; } // Force instantiation of template instances class. // Please note this list is compiler dependent. template class HashTable<SymbolTableShape, HashTableKey*>; template class HashTable<CompilationCacheShape, HashTableKey*>; template class HashTable<MapCacheShape, HashTableKey*>; template class Dictionary<StringDictionaryShape, String*>; template class Dictionary<NumberDictionaryShape, uint32_t>; template Object* Dictionary<NumberDictionaryShape, uint32_t>::Allocate( int); template Object* Dictionary<StringDictionaryShape, String*>::Allocate( int); template Object* Dictionary<NumberDictionaryShape, uint32_t>::AtPut( uint32_t, Object*); template Object* Dictionary<NumberDictionaryShape, uint32_t>::SlowReverseLookup( Object*); template Object* Dictionary<StringDictionaryShape, String*>::SlowReverseLookup( Object*); template void Dictionary<NumberDictionaryShape, uint32_t>::CopyKeysTo( FixedArray*, PropertyAttributes); template Object* Dictionary<StringDictionaryShape, String*>::DeleteProperty( int, JSObject::DeleteMode); template Object* Dictionary<NumberDictionaryShape, uint32_t>::DeleteProperty( int, JSObject::DeleteMode); template void Dictionary<StringDictionaryShape, String*>::CopyKeysTo( FixedArray*); template int Dictionary<StringDictionaryShape, String*>::NumberOfElementsFilterAttributes( PropertyAttributes); template Object* Dictionary<StringDictionaryShape, String*>::Add( String*, Object*, PropertyDetails); template Object* Dictionary<StringDictionaryShape, String*>::GenerateNewEnumerationIndices(); template int Dictionary<NumberDictionaryShape, uint32_t>::NumberOfElementsFilterAttributes( PropertyAttributes); template Object* Dictionary<NumberDictionaryShape, uint32_t>::Add( uint32_t, Object*, PropertyDetails); template Object* Dictionary<NumberDictionaryShape, uint32_t>::EnsureCapacity( int, uint32_t); template Object* Dictionary<StringDictionaryShape, String*>::EnsureCapacity( int, String*); template Object* Dictionary<NumberDictionaryShape, uint32_t>::AddEntry( uint32_t, Object*, PropertyDetails, uint32_t); template Object* Dictionary<StringDictionaryShape, String*>::AddEntry( String*, Object*, PropertyDetails, uint32_t); template int Dictionary<NumberDictionaryShape, uint32_t>::NumberOfEnumElements(); template int Dictionary<StringDictionaryShape, String*>::NumberOfEnumElements(); template int HashTable<NumberDictionaryShape, uint32_t>::FindEntry(uint32_t); // Collates undefined and unexisting elements below limit from position // zero of the elements. The object stays in Dictionary mode. Object* JSObject::PrepareSlowElementsForSort(uint32_t limit) { ASSERT(HasDictionaryElements()); // Must stay in dictionary mode, either because of requires_slow_elements, // or because we are not going to sort (and therefore compact) all of the // elements. NumberDictionary* dict = element_dictionary(); HeapNumber* result_double = NULL; if (limit > static_cast<uint32_t>(Smi::kMaxValue)) { // Allocate space for result before we start mutating the object. Object* new_double = Heap::AllocateHeapNumber(0.0); if (new_double->IsFailure()) return new_double; result_double = HeapNumber::cast(new_double); } int capacity = dict->Capacity(); Object* obj = NumberDictionary::Allocate(dict->Capacity()); if (obj->IsFailure()) return obj; NumberDictionary* new_dict = NumberDictionary::cast(obj); AssertNoAllocation no_alloc; uint32_t pos = 0; uint32_t undefs = 0; for (int i = 0; i < capacity; i++) { Object* k = dict->KeyAt(i); if (dict->IsKey(k)) { ASSERT(k->IsNumber()); ASSERT(!k->IsSmi() || Smi::cast(k)->value() >= 0); ASSERT(!k->IsHeapNumber() || HeapNumber::cast(k)->value() >= 0); ASSERT(!k->IsHeapNumber() || HeapNumber::cast(k)->value() <= kMaxUInt32); Object* value = dict->ValueAt(i); PropertyDetails details = dict->DetailsAt(i); if (details.type() == CALLBACKS) { // Bail out and do the sorting of undefineds and array holes in JS. return Smi::FromInt(-1); } uint32_t key = NumberToUint32(k); if (key < limit) { if (value->IsUndefined()) { undefs++; } else { new_dict->AddNumberEntry(pos, value, details); pos++; } } else { new_dict->AddNumberEntry(key, value, details); } } } uint32_t result = pos; PropertyDetails no_details = PropertyDetails(NONE, NORMAL); while (undefs > 0) { new_dict->AddNumberEntry(pos, Heap::undefined_value(), no_details); pos++; undefs--; } set_elements(new_dict); if (result <= static_cast<uint32_t>(Smi::kMaxValue)) { return Smi::FromInt(static_cast<int>(result)); } ASSERT_NE(NULL, result_double); result_double->set_value(static_cast<double>(result)); return result_double; } // Collects all defined (non-hole) and non-undefined (array) elements at // the start of the elements array. // If the object is in dictionary mode, it is converted to fast elements // mode. Object* JSObject::PrepareElementsForSort(uint32_t limit) { ASSERT(!HasPixelElements() && !HasExternalArrayElements()); if (HasDictionaryElements()) { // Convert to fast elements containing only the existing properties. // Ordering is irrelevant, since we are going to sort anyway. NumberDictionary* dict = element_dictionary(); if (IsJSArray() || dict->requires_slow_elements() || dict->max_number_key() >= limit) { return PrepareSlowElementsForSort(limit); } // Convert to fast elements. PretenureFlag tenure = Heap::InNewSpace(this) ? NOT_TENURED: TENURED; Object* new_array = Heap::AllocateFixedArray(dict->NumberOfElements(), tenure); if (new_array->IsFailure()) { return new_array; } FixedArray* fast_elements = FixedArray::cast(new_array); dict->CopyValuesTo(fast_elements); set_elements(fast_elements); } ASSERT(HasFastElements()); // Collect holes at the end, undefined before that and the rest at the // start, and return the number of non-hole, non-undefined values. FixedArray* elements = FixedArray::cast(this->elements()); uint32_t elements_length = static_cast<uint32_t>(elements->length()); if (limit > elements_length) { limit = elements_length ; } if (limit == 0) { return Smi::FromInt(0); } HeapNumber* result_double = NULL; if (limit > static_cast<uint32_t>(Smi::kMaxValue)) { // Pessimistically allocate space for return value before // we start mutating the array. Object* new_double = Heap::AllocateHeapNumber(0.0); if (new_double->IsFailure()) return new_double; result_double = HeapNumber::cast(new_double); } AssertNoAllocation no_alloc; // Split elements into defined, undefined and the_hole, in that order. // Only count locations for undefined and the hole, and fill them afterwards. WriteBarrierMode write_barrier = elements->GetWriteBarrierMode(no_alloc); unsigned int undefs = limit; unsigned int holes = limit; // Assume most arrays contain no holes and undefined values, so minimize the // number of stores of non-undefined, non-the-hole values. for (unsigned int i = 0; i < undefs; i++) { Object* current = elements->get(i); if (current->IsTheHole()) { holes--; undefs--; } else if (current->IsUndefined()) { undefs--; } else { continue; } // Position i needs to be filled. while (undefs > i) { current = elements->get(undefs); if (current->IsTheHole()) { holes--; undefs--; } else if (current->IsUndefined()) { undefs--; } else { elements->set(i, current, write_barrier); break; } } } uint32_t result = undefs; while (undefs < holes) { elements->set_undefined(undefs); undefs++; } while (holes < limit) { elements->set_the_hole(holes); holes++; } if (result <= static_cast<uint32_t>(Smi::kMaxValue)) { return Smi::FromInt(static_cast<int>(result)); } ASSERT_NE(NULL, result_double); result_double->set_value(static_cast<double>(result)); return result_double; } Object* PixelArray::SetValue(uint32_t index, Object* value) { uint8_t clamped_value = 0; if (index < static_cast<uint32_t>(length())) { if (value->IsSmi()) { int int_value = Smi::cast(value)->value(); if (int_value < 0) { clamped_value = 0; } else if (int_value > 255) { clamped_value = 255; } else { clamped_value = static_cast<uint8_t>(int_value); } } else if (value->IsHeapNumber()) { double double_value = HeapNumber::cast(value)->value(); if (!(double_value > 0)) { // NaN and less than zero clamp to zero. clamped_value = 0; } else if (double_value > 255) { // Greater than 255 clamp to 255. clamped_value = 255; } else { // Other doubles are rounded to the nearest integer. clamped_value = static_cast<uint8_t>(double_value + 0.5); } } else { // Clamp undefined to zero (default). All other types have been // converted to a number type further up in the call chain. ASSERT(value->IsUndefined()); } set(index, clamped_value); } return Smi::FromInt(clamped_value); } template<typename ExternalArrayClass, typename ValueType> static Object* ExternalArrayIntSetter(ExternalArrayClass* receiver, uint32_t index, Object* value) { ValueType cast_value = 0; if (index < static_cast<uint32_t>(receiver->length())) { if (value->IsSmi()) { int int_value = Smi::cast(value)->value(); cast_value = static_cast<ValueType>(int_value); } else if (value->IsHeapNumber()) { double double_value = HeapNumber::cast(value)->value(); cast_value = static_cast<ValueType>(DoubleToInt32(double_value)); } else { // Clamp undefined to zero (default). All other types have been // converted to a number type further up in the call chain. ASSERT(value->IsUndefined()); } receiver->set(index, cast_value); } return Heap::NumberFromInt32(cast_value); } Object* ExternalByteArray::SetValue(uint32_t index, Object* value) { return ExternalArrayIntSetter<ExternalByteArray, int8_t> (this, index, value); } Object* ExternalUnsignedByteArray::SetValue(uint32_t index, Object* value) { return ExternalArrayIntSetter<ExternalUnsignedByteArray, uint8_t> (this, index, value); } Object* ExternalShortArray::SetValue(uint32_t index, Object* value) { return ExternalArrayIntSetter<ExternalShortArray, int16_t> (this, index, value); } Object* ExternalUnsignedShortArray::SetValue(uint32_t index, Object* value) { return ExternalArrayIntSetter<ExternalUnsignedShortArray, uint16_t> (this, index, value); } Object* ExternalIntArray::SetValue(uint32_t index, Object* value) { return ExternalArrayIntSetter<ExternalIntArray, int32_t> (this, index, value); } Object* ExternalUnsignedIntArray::SetValue(uint32_t index, Object* value) { uint32_t cast_value = 0; if (index < static_cast<uint32_t>(length())) { if (value->IsSmi()) { int int_value = Smi::cast(value)->value(); cast_value = static_cast<uint32_t>(int_value); } else if (value->IsHeapNumber()) { double double_value = HeapNumber::cast(value)->value(); cast_value = static_cast<uint32_t>(DoubleToUint32(double_value)); } else { // Clamp undefined to zero (default). All other types have been // converted to a number type further up in the call chain. ASSERT(value->IsUndefined()); } set(index, cast_value); } return Heap::NumberFromUint32(cast_value); } Object* ExternalFloatArray::SetValue(uint32_t index, Object* value) { float cast_value = 0; if (index < static_cast<uint32_t>(length())) { if (value->IsSmi()) { int int_value = Smi::cast(value)->value(); cast_value = static_cast<float>(int_value); } else if (value->IsHeapNumber()) { double double_value = HeapNumber::cast(value)->value(); cast_value = static_cast<float>(double_value); } else { // Clamp undefined to zero (default). All other types have been // converted to a number type further up in the call chain. ASSERT(value->IsUndefined()); } set(index, cast_value); } return Heap::AllocateHeapNumber(cast_value); } Object* GlobalObject::GetPropertyCell(LookupResult* result) { ASSERT(!HasFastProperties()); Object* value = property_dictionary()->ValueAt(result->GetDictionaryEntry()); ASSERT(value->IsJSGlobalPropertyCell()); return value; } Object* GlobalObject::EnsurePropertyCell(String* name) { ASSERT(!HasFastProperties()); int entry = property_dictionary()->FindEntry(name); if (entry == StringDictionary::kNotFound) { Object* cell = Heap::AllocateJSGlobalPropertyCell(Heap::the_hole_value()); if (cell->IsFailure()) return cell; PropertyDetails details(NONE, NORMAL); details = details.AsDeleted(); Object* dictionary = property_dictionary()->Add(name, cell, details); if (dictionary->IsFailure()) return dictionary; set_properties(StringDictionary::cast(dictionary)); return cell; } else { Object* value = property_dictionary()->ValueAt(entry); ASSERT(value->IsJSGlobalPropertyCell()); return value; } } Object* SymbolTable::LookupString(String* string, Object** s) { SymbolKey key(string); return LookupKey(&key, s); } // This class is used for looking up two character strings in the symbol table. // If we don't have a hit we don't want to waste much time so we unroll the // string hash calculation loop here for speed. Doesn't work if the two // characters form a decimal integer, since such strings have a different hash // algorithm. class TwoCharHashTableKey : public HashTableKey { public: TwoCharHashTableKey(uint32_t c1, uint32_t c2) : c1_(c1), c2_(c2) { // Char 1. uint32_t hash = c1 + (c1 << 10); hash ^= hash >> 6; // Char 2. hash += c2; hash += hash << 10; hash ^= hash >> 6; // GetHash. hash += hash << 3; hash ^= hash >> 11; hash += hash << 15; if (hash == 0) hash = 27; #ifdef DEBUG StringHasher hasher(2); hasher.AddCharacter(c1); hasher.AddCharacter(c2); // If this assert fails then we failed to reproduce the two-character // version of the string hashing algorithm above. One reason could be // that we were passed two digits as characters, since the hash // algorithm is different in that case. ASSERT_EQ(static_cast<int>(hasher.GetHash()), static_cast<int>(hash)); #endif hash_ = hash; } bool IsMatch(Object* o) { if (!o->IsString()) return false; String* other = String::cast(o); if (other->length() != 2) return false; if (other->Get(0) != c1_) return false; return other->Get(1) == c2_; } uint32_t Hash() { return hash_; } uint32_t HashForObject(Object* key) { if (!key->IsString()) return 0; return String::cast(key)->Hash(); } Object* AsObject() { // The TwoCharHashTableKey is only used for looking in the symbol // table, not for adding to it. UNREACHABLE(); return NULL; } private: uint32_t c1_; uint32_t c2_; uint32_t hash_; }; bool SymbolTable::LookupSymbolIfExists(String* string, String** symbol) { SymbolKey key(string); int entry = FindEntry(&key); if (entry == kNotFound) { return false; } else { String* result = String::cast(KeyAt(entry)); ASSERT(StringShape(result).IsSymbol()); *symbol = result; return true; } } bool SymbolTable::LookupTwoCharsSymbolIfExists(uint32_t c1, uint32_t c2, String** symbol) { TwoCharHashTableKey key(c1, c2); int entry = FindEntry(&key); if (entry == kNotFound) { return false; } else { String* result = String::cast(KeyAt(entry)); ASSERT(StringShape(result).IsSymbol()); *symbol = result; return true; } } Object* SymbolTable::LookupSymbol(Vector<const char> str, Object** s) { Utf8SymbolKey key(str); return LookupKey(&key, s); } Object* SymbolTable::LookupKey(HashTableKey* key, Object** s) { int entry = FindEntry(key); // Symbol already in table. if (entry != kNotFound) { *s = KeyAt(entry); return this; } // Adding new symbol. Grow table if needed. Object* obj = EnsureCapacity(1, key); if (obj->IsFailure()) return obj; // Create symbol object. Object* symbol = key->AsObject(); if (symbol->IsFailure()) return symbol; // If the symbol table grew as part of EnsureCapacity, obj is not // the current symbol table and therefore we cannot use // SymbolTable::cast here. SymbolTable* table = reinterpret_cast<SymbolTable*>(obj); // Add the new symbol and return it along with the symbol table. entry = table->FindInsertionEntry(key->Hash()); table->set(EntryToIndex(entry), symbol); table->ElementAdded(); *s = symbol; return table; } Object* CompilationCacheTable::Lookup(String* src) { StringKey key(src); int entry = FindEntry(&key); if (entry == kNotFound) return Heap::undefined_value(); return get(EntryToIndex(entry) + 1); } Object* CompilationCacheTable::LookupEval(String* src, Context* context) { StringSharedKey key(src, context->closure()->shared()); int entry = FindEntry(&key); if (entry == kNotFound) return Heap::undefined_value(); return get(EntryToIndex(entry) + 1); } Object* CompilationCacheTable::LookupRegExp(String* src, JSRegExp::Flags flags) { RegExpKey key(src, flags); int entry = FindEntry(&key); if (entry == kNotFound) return Heap::undefined_value(); return get(EntryToIndex(entry) + 1); } Object* CompilationCacheTable::Put(String* src, Object* value) { StringKey key(src); Object* obj = EnsureCapacity(1, &key); if (obj->IsFailure()) return obj; CompilationCacheTable* cache = reinterpret_cast<CompilationCacheTable*>(obj); int entry = cache->FindInsertionEntry(key.Hash()); cache->set(EntryToIndex(entry), src); cache->set(EntryToIndex(entry) + 1, value); cache->ElementAdded(); return cache; } Object* CompilationCacheTable::PutEval(String* src, Context* context, Object* value) { StringSharedKey key(src, context->closure()->shared()); Object* obj = EnsureCapacity(1, &key); if (obj->IsFailure()) return obj; CompilationCacheTable* cache = reinterpret_cast<CompilationCacheTable*>(obj); int entry = cache->FindInsertionEntry(key.Hash()); Object* k = key.AsObject(); if (k->IsFailure()) return k; cache->set(EntryToIndex(entry), k); cache->set(EntryToIndex(entry) + 1, value); cache->ElementAdded(); return cache; } Object* CompilationCacheTable::PutRegExp(String* src, JSRegExp::Flags flags, FixedArray* value) { RegExpKey key(src, flags); Object* obj = EnsureCapacity(1, &key); if (obj->IsFailure()) return obj; CompilationCacheTable* cache = reinterpret_cast<CompilationCacheTable*>(obj); int entry = cache->FindInsertionEntry(key.Hash()); // We store the value in the key slot, and compare the search key // to the stored value with a custon IsMatch function during lookups. cache->set(EntryToIndex(entry), value); cache->set(EntryToIndex(entry) + 1, value); cache->ElementAdded(); return cache; } // SymbolsKey used for HashTable where key is array of symbols. class SymbolsKey : public HashTableKey { public: explicit SymbolsKey(FixedArray* symbols) : symbols_(symbols) { } bool IsMatch(Object* symbols) { FixedArray* o = FixedArray::cast(symbols); int len = symbols_->length(); if (o->length() != len) return false; for (int i = 0; i < len; i++) { if (o->get(i) != symbols_->get(i)) return false; } return true; } uint32_t Hash() { return HashForObject(symbols_); } uint32_t HashForObject(Object* obj) { FixedArray* symbols = FixedArray::cast(obj); int len = symbols->length(); uint32_t hash = 0; for (int i = 0; i < len; i++) { hash ^= String::cast(symbols->get(i))->Hash(); } return hash; } Object* AsObject() { return symbols_; } private: FixedArray* symbols_; }; Object* MapCache::Lookup(FixedArray* array) { SymbolsKey key(array); int entry = FindEntry(&key); if (entry == kNotFound) return Heap::undefined_value(); return get(EntryToIndex(entry) + 1); } Object* MapCache::Put(FixedArray* array, Map* value) { SymbolsKey key(array); Object* obj = EnsureCapacity(1, &key); if (obj->IsFailure()) return obj; MapCache* cache = reinterpret_cast<MapCache*>(obj); int entry = cache->FindInsertionEntry(key.Hash()); cache->set(EntryToIndex(entry), array); cache->set(EntryToIndex(entry) + 1, value); cache->ElementAdded(); return cache; } template<typename Shape, typename Key> Object* Dictionary<Shape, Key>::Allocate(int at_least_space_for) { Object* obj = HashTable<Shape, Key>::Allocate(at_least_space_for); // Initialize the next enumeration index. if (!obj->IsFailure()) { Dictionary<Shape, Key>::cast(obj)-> SetNextEnumerationIndex(PropertyDetails::kInitialIndex); } return obj; } template<typename Shape, typename Key> Object* Dictionary<Shape, Key>::GenerateNewEnumerationIndices() { int length = HashTable<Shape, Key>::NumberOfElements(); // Allocate and initialize iteration order array. Object* obj = Heap::AllocateFixedArray(length); if (obj->IsFailure()) return obj; FixedArray* iteration_order = FixedArray::cast(obj); for (int i = 0; i < length; i++) { iteration_order->set(i, Smi::FromInt(i)); } // Allocate array with enumeration order. obj = Heap::AllocateFixedArray(length); if (obj->IsFailure()) return obj; FixedArray* enumeration_order = FixedArray::cast(obj); // Fill the enumeration order array with property details. int capacity = HashTable<Shape, Key>::Capacity(); int pos = 0; for (int i = 0; i < capacity; i++) { if (Dictionary<Shape, Key>::IsKey(Dictionary<Shape, Key>::KeyAt(i))) { enumeration_order->set(pos++, Smi::FromInt(DetailsAt(i).index())); } } // Sort the arrays wrt. enumeration order. iteration_order->SortPairs(enumeration_order, enumeration_order->length()); // Overwrite the enumeration_order with the enumeration indices. for (int i = 0; i < length; i++) { int index = Smi::cast(iteration_order->get(i))->value(); int enum_index = PropertyDetails::kInitialIndex + i; enumeration_order->set(index, Smi::FromInt(enum_index)); } // Update the dictionary with new indices. capacity = HashTable<Shape, Key>::Capacity(); pos = 0; for (int i = 0; i < capacity; i++) { if (Dictionary<Shape, Key>::IsKey(Dictionary<Shape, Key>::KeyAt(i))) { int enum_index = Smi::cast(enumeration_order->get(pos++))->value(); PropertyDetails details = DetailsAt(i); PropertyDetails new_details = PropertyDetails(details.attributes(), details.type(), enum_index); DetailsAtPut(i, new_details); } } // Set the next enumeration index. SetNextEnumerationIndex(PropertyDetails::kInitialIndex+length); return this; } template<typename Shape, typename Key> Object* Dictionary<Shape, Key>::EnsureCapacity(int n, Key key) { // Check whether there are enough enumeration indices to add n elements. if (Shape::kIsEnumerable && !PropertyDetails::IsValidIndex(NextEnumerationIndex() + n)) { // If not, we generate new indices for the properties. Object* result = GenerateNewEnumerationIndices(); if (result->IsFailure()) return result; } return HashTable<Shape, Key>::EnsureCapacity(n, key); } void NumberDictionary::RemoveNumberEntries(uint32_t from, uint32_t to) { // Do nothing if the interval [from, to) is empty. if (from >= to) return; int removed_entries = 0; Object* sentinel = Heap::null_value(); int capacity = Capacity(); for (int i = 0; i < capacity; i++) { Object* key = KeyAt(i); if (key->IsNumber()) { uint32_t number = static_cast<uint32_t>(key->Number()); if (from <= number && number < to) { SetEntry(i, sentinel, sentinel, Smi::FromInt(0)); removed_entries++; } } } // Update the number of elements. ElementsRemoved(removed_entries); } template<typename Shape, typename Key> Object* Dictionary<Shape, Key>::DeleteProperty(int entry, JSObject::DeleteMode mode) { PropertyDetails details = DetailsAt(entry); // Ignore attributes if forcing a deletion. if (details.IsDontDelete() && mode == JSObject::NORMAL_DELETION) { return Heap::false_value(); } SetEntry(entry, Heap::null_value(), Heap::null_value(), Smi::FromInt(0)); HashTable<Shape, Key>::ElementRemoved(); return Heap::true_value(); } template<typename Shape, typename Key> Object* Dictionary<Shape, Key>::AtPut(Key key, Object* value) { int entry = FindEntry(key); // If the entry is present set the value; if (entry != Dictionary<Shape, Key>::kNotFound) { ValueAtPut(entry, value); return this; } // Check whether the dictionary should be extended. Object* obj = EnsureCapacity(1, key); if (obj->IsFailure()) return obj; Object* k = Shape::AsObject(key); if (k->IsFailure()) return k; PropertyDetails details = PropertyDetails(NONE, NORMAL); return Dictionary<Shape, Key>::cast(obj)-> AddEntry(key, value, details, Shape::Hash(key)); } template<typename Shape, typename Key> Object* Dictionary<Shape, Key>::Add(Key key, Object* value, PropertyDetails details) { // Valdate key is absent. SLOW_ASSERT((FindEntry(key) == Dictionary<Shape, Key>::kNotFound)); // Check whether the dictionary should be extended. Object* obj = EnsureCapacity(1, key); if (obj->IsFailure()) return obj; return Dictionary<Shape, Key>::cast(obj)-> AddEntry(key, value, details, Shape::Hash(key)); } // Add a key, value pair to the dictionary. template<typename Shape, typename Key> Object* Dictionary<Shape, Key>::AddEntry(Key key, Object* value, PropertyDetails details, uint32_t hash) { // Compute the key object. Object* k = Shape::AsObject(key); if (k->IsFailure()) return k; uint32_t entry = Dictionary<Shape, Key>::FindInsertionEntry(hash); // Insert element at empty or deleted entry if (!details.IsDeleted() && details.index() == 0 && Shape::kIsEnumerable) { // Assign an enumeration index to the property and update // SetNextEnumerationIndex. int index = NextEnumerationIndex(); details = PropertyDetails(details.attributes(), details.type(), index); SetNextEnumerationIndex(index + 1); } SetEntry(entry, k, value, details); ASSERT((Dictionary<Shape, Key>::KeyAt(entry)->IsNumber() || Dictionary<Shape, Key>::KeyAt(entry)->IsString())); HashTable<Shape, Key>::ElementAdded(); return this; } void NumberDictionary::UpdateMaxNumberKey(uint32_t key) { // If the dictionary requires slow elements an element has already // been added at a high index. if (requires_slow_elements()) return; // Check if this index is high enough that we should require slow // elements. if (key > kRequiresSlowElementsLimit) { set_requires_slow_elements(); return; } // Update max key value. Object* max_index_object = get(kMaxNumberKeyIndex); if (!max_index_object->IsSmi() || max_number_key() < key) { FixedArray::set(kMaxNumberKeyIndex, Smi::FromInt(key << kRequiresSlowElementsTagSize)); } } Object* NumberDictionary::AddNumberEntry(uint32_t key, Object* value, PropertyDetails details) { UpdateMaxNumberKey(key); SLOW_ASSERT(FindEntry(key) == kNotFound); return Add(key, value, details); } Object* NumberDictionary::AtNumberPut(uint32_t key, Object* value) { UpdateMaxNumberKey(key); return AtPut(key, value); } Object* NumberDictionary::Set(uint32_t key, Object* value, PropertyDetails details) { int entry = FindEntry(key); if (entry == kNotFound) return AddNumberEntry(key, value, details); // Preserve enumeration index. details = PropertyDetails(details.attributes(), details.type(), DetailsAt(entry).index()); SetEntry(entry, NumberDictionaryShape::AsObject(key), value, details); return this; } template<typename Shape, typename Key> int Dictionary<Shape, Key>::NumberOfElementsFilterAttributes( PropertyAttributes filter) { int capacity = HashTable<Shape, Key>::Capacity(); int result = 0; for (int i = 0; i < capacity; i++) { Object* k = HashTable<Shape, Key>::KeyAt(i); if (HashTable<Shape, Key>::IsKey(k)) { PropertyDetails details = DetailsAt(i); if (details.IsDeleted()) continue; PropertyAttributes attr = details.attributes(); if ((attr & filter) == 0) result++; } } return result; } template<typename Shape, typename Key> int Dictionary<Shape, Key>::NumberOfEnumElements() { return NumberOfElementsFilterAttributes( static_cast<PropertyAttributes>(DONT_ENUM)); } template<typename Shape, typename Key> void Dictionary<Shape, Key>::CopyKeysTo(FixedArray* storage, PropertyAttributes filter) { ASSERT(storage->length() >= NumberOfEnumElements()); int capacity = HashTable<Shape, Key>::Capacity(); int index = 0; for (int i = 0; i < capacity; i++) { Object* k = HashTable<Shape, Key>::KeyAt(i); if (HashTable<Shape, Key>::IsKey(k)) { PropertyDetails details = DetailsAt(i); if (details.IsDeleted()) continue; PropertyAttributes attr = details.attributes(); if ((attr & filter) == 0) storage->set(index++, k); } } storage->SortPairs(storage, index); ASSERT(storage->length() >= index); } void StringDictionary::CopyEnumKeysTo(FixedArray* storage, FixedArray* sort_array) { ASSERT(storage->length() >= NumberOfEnumElements()); int capacity = Capacity(); int index = 0; for (int i = 0; i < capacity; i++) { Object* k = KeyAt(i); if (IsKey(k)) { PropertyDetails details = DetailsAt(i); if (details.IsDeleted() || details.IsDontEnum()) continue; storage->set(index, k); sort_array->set(index, Smi::FromInt(details.index())); index++; } } storage->SortPairs(sort_array, sort_array->length()); ASSERT(storage->length() >= index); } template<typename Shape, typename Key> void Dictionary<Shape, Key>::CopyKeysTo(FixedArray* storage) { ASSERT(storage->length() >= NumberOfElementsFilterAttributes( static_cast<PropertyAttributes>(NONE))); int capacity = HashTable<Shape, Key>::Capacity(); int index = 0; for (int i = 0; i < capacity; i++) { Object* k = HashTable<Shape, Key>::KeyAt(i); if (HashTable<Shape, Key>::IsKey(k)) { PropertyDetails details = DetailsAt(i); if (details.IsDeleted()) continue; storage->set(index++, k); } } ASSERT(storage->length() >= index); } // Backwards lookup (slow). template<typename Shape, typename Key> Object* Dictionary<Shape, Key>::SlowReverseLookup(Object* value) { int capacity = HashTable<Shape, Key>::Capacity(); for (int i = 0; i < capacity; i++) { Object* k = HashTable<Shape, Key>::KeyAt(i); if (Dictionary<Shape, Key>::IsKey(k)) { Object* e = ValueAt(i); if (e->IsJSGlobalPropertyCell()) { e = JSGlobalPropertyCell::cast(e)->value(); } if (e == value) return k; } } return Heap::undefined_value(); } Object* StringDictionary::TransformPropertiesToFastFor( JSObject* obj, int unused_property_fields) { // Make sure we preserve dictionary representation if there are too many // descriptors. if (NumberOfElements() > DescriptorArray::kMaxNumberOfDescriptors) return obj; // Figure out if it is necessary to generate new enumeration indices. int max_enumeration_index = NextEnumerationIndex() + (DescriptorArray::kMaxNumberOfDescriptors - NumberOfElements()); if (!PropertyDetails::IsValidIndex(max_enumeration_index)) { Object* result = GenerateNewEnumerationIndices(); if (result->IsFailure()) return result; } int instance_descriptor_length = 0; int number_of_fields = 0; // Compute the length of the instance descriptor. int capacity = Capacity(); for (int i = 0; i < capacity; i++) { Object* k = KeyAt(i); if (IsKey(k)) { Object* value = ValueAt(i); PropertyType type = DetailsAt(i).type(); ASSERT(type != FIELD); instance_descriptor_length++; if (type == NORMAL && (!value->IsJSFunction() || Heap::InNewSpace(value))) { number_of_fields += 1; } } } // Allocate the instance descriptor. Object* descriptors_unchecked = DescriptorArray::Allocate(instance_descriptor_length); if (descriptors_unchecked->IsFailure()) return descriptors_unchecked; DescriptorArray* descriptors = DescriptorArray::cast(descriptors_unchecked); int inobject_props = obj->map()->inobject_properties(); int number_of_allocated_fields = number_of_fields + unused_property_fields - inobject_props; // Allocate the fixed array for the fields. Object* fields = Heap::AllocateFixedArray(number_of_allocated_fields); if (fields->IsFailure()) return fields; // Fill in the instance descriptor and the fields. int next_descriptor = 0; int current_offset = 0; for (int i = 0; i < capacity; i++) { Object* k = KeyAt(i); if (IsKey(k)) { Object* value = ValueAt(i); // Ensure the key is a symbol before writing into the instance descriptor. Object* key = Heap::LookupSymbol(String::cast(k)); if (key->IsFailure()) return key; PropertyDetails details = DetailsAt(i); PropertyType type = details.type(); if (value->IsJSFunction() && !Heap::InNewSpace(value)) { ConstantFunctionDescriptor d(String::cast(key), JSFunction::cast(value), details.attributes(), details.index()); descriptors->Set(next_descriptor++, &d); } else if (type == NORMAL) { if (current_offset < inobject_props) { obj->InObjectPropertyAtPut(current_offset, value, UPDATE_WRITE_BARRIER); } else { int offset = current_offset - inobject_props; FixedArray::cast(fields)->set(offset, value); } FieldDescriptor d(String::cast(key), current_offset++, details.attributes(), details.index()); descriptors->Set(next_descriptor++, &d); } else if (type == CALLBACKS) { CallbacksDescriptor d(String::cast(key), value, details.attributes(), details.index()); descriptors->Set(next_descriptor++, &d); } else { UNREACHABLE(); } } } ASSERT(current_offset == number_of_fields); descriptors->Sort(); // Allocate new map. Object* new_map = obj->map()->CopyDropDescriptors(); if (new_map->IsFailure()) return new_map; // Transform the object. obj->set_map(Map::cast(new_map)); obj->map()->set_instance_descriptors(descriptors); obj->map()->set_unused_property_fields(unused_property_fields); obj->set_properties(FixedArray::cast(fields)); ASSERT(obj->IsJSObject()); descriptors->SetNextEnumerationIndex(NextEnumerationIndex()); // Check that it really works. ASSERT(obj->HasFastProperties()); return obj; } #ifdef ENABLE_DEBUGGER_SUPPORT // Check if there is a break point at this code position. bool DebugInfo::HasBreakPoint(int code_position) { // Get the break point info object for this code position. Object* break_point_info = GetBreakPointInfo(code_position); // If there is no break point info object or no break points in the break // point info object there is no break point at this code position. if (break_point_info->IsUndefined()) return false; return BreakPointInfo::cast(break_point_info)->GetBreakPointCount() > 0; } // Get the break point info object for this code position. Object* DebugInfo::GetBreakPointInfo(int code_position) { // Find the index of the break point info object for this code position. int index = GetBreakPointInfoIndex(code_position); // Return the break point info object if any. if (index == kNoBreakPointInfo) return Heap::undefined_value(); return BreakPointInfo::cast(break_points()->get(index)); } // Clear a break point at the specified code position. void DebugInfo::ClearBreakPoint(Handle<DebugInfo> debug_info, int code_position, Handle<Object> break_point_object) { Handle<Object> break_point_info(debug_info->GetBreakPointInfo(code_position)); if (break_point_info->IsUndefined()) return; BreakPointInfo::ClearBreakPoint( Handle<BreakPointInfo>::cast(break_point_info), break_point_object); } void DebugInfo::SetBreakPoint(Handle<DebugInfo> debug_info, int code_position, int source_position, int statement_position, Handle<Object> break_point_object) { Handle<Object> break_point_info(debug_info->GetBreakPointInfo(code_position)); if (!break_point_info->IsUndefined()) { BreakPointInfo::SetBreakPoint( Handle<BreakPointInfo>::cast(break_point_info), break_point_object); return; } // Adding a new break point for a code position which did not have any // break points before. Try to find a free slot. int index = kNoBreakPointInfo; for (int i = 0; i < debug_info->break_points()->length(); i++) { if (debug_info->break_points()->get(i)->IsUndefined()) { index = i; break; } } if (index == kNoBreakPointInfo) { // No free slot - extend break point info array. Handle<FixedArray> old_break_points = Handle<FixedArray>(FixedArray::cast(debug_info->break_points())); debug_info->set_break_points(*Factory::NewFixedArray( old_break_points->length() + Debug::kEstimatedNofBreakPointsInFunction)); Handle<FixedArray> new_break_points = Handle<FixedArray>(FixedArray::cast(debug_info->break_points())); for (int i = 0; i < old_break_points->length(); i++) { new_break_points->set(i, old_break_points->get(i)); } index = old_break_points->length(); } ASSERT(index != kNoBreakPointInfo); // Allocate new BreakPointInfo object and set the break point. Handle<BreakPointInfo> new_break_point_info = Handle<BreakPointInfo>::cast(Factory::NewStruct(BREAK_POINT_INFO_TYPE)); new_break_point_info->set_code_position(Smi::FromInt(code_position)); new_break_point_info->set_source_position(Smi::FromInt(source_position)); new_break_point_info-> set_statement_position(Smi::FromInt(statement_position)); new_break_point_info->set_break_point_objects(Heap::undefined_value()); BreakPointInfo::SetBreakPoint(new_break_point_info, break_point_object); debug_info->break_points()->set(index, *new_break_point_info); } // Get the break point objects for a code position. Object* DebugInfo::GetBreakPointObjects(int code_position) { Object* break_point_info = GetBreakPointInfo(code_position); if (break_point_info->IsUndefined()) { return Heap::undefined_value(); } return BreakPointInfo::cast(break_point_info)->break_point_objects(); } // Get the total number of break points. int DebugInfo::GetBreakPointCount() { if (break_points()->IsUndefined()) return 0; int count = 0; for (int i = 0; i < break_points()->length(); i++) { if (!break_points()->get(i)->IsUndefined()) { BreakPointInfo* break_point_info = BreakPointInfo::cast(break_points()->get(i)); count += break_point_info->GetBreakPointCount(); } } return count; } Object* DebugInfo::FindBreakPointInfo(Handle<DebugInfo> debug_info, Handle<Object> break_point_object) { if (debug_info->break_points()->IsUndefined()) return Heap::undefined_value(); for (int i = 0; i < debug_info->break_points()->length(); i++) { if (!debug_info->break_points()->get(i)->IsUndefined()) { Handle<BreakPointInfo> break_point_info = Handle<BreakPointInfo>(BreakPointInfo::cast( debug_info->break_points()->get(i))); if (BreakPointInfo::HasBreakPointObject(break_point_info, break_point_object)) { return *break_point_info; } } } return Heap::undefined_value(); } // Find the index of the break point info object for the specified code // position. int DebugInfo::GetBreakPointInfoIndex(int code_position) { if (break_points()->IsUndefined()) return kNoBreakPointInfo; for (int i = 0; i < break_points()->length(); i++) { if (!break_points()->get(i)->IsUndefined()) { BreakPointInfo* break_point_info = BreakPointInfo::cast(break_points()->get(i)); if (break_point_info->code_position()->value() == code_position) { return i; } } } return kNoBreakPointInfo; } // Remove the specified break point object. void BreakPointInfo::ClearBreakPoint(Handle<BreakPointInfo> break_point_info, Handle<Object> break_point_object) { // If there are no break points just ignore. if (break_point_info->break_point_objects()->IsUndefined()) return; // If there is a single break point clear it if it is the same. if (!break_point_info->break_point_objects()->IsFixedArray()) { if (break_point_info->break_point_objects() == *break_point_object) { break_point_info->set_break_point_objects(Heap::undefined_value()); } return; } // If there are multiple break points shrink the array ASSERT(break_point_info->break_point_objects()->IsFixedArray()); Handle<FixedArray> old_array = Handle<FixedArray>( FixedArray::cast(break_point_info->break_point_objects())); Handle<FixedArray> new_array = Factory::NewFixedArray(old_array->length() - 1); int found_count = 0; for (int i = 0; i < old_array->length(); i++) { if (old_array->get(i) == *break_point_object) { ASSERT(found_count == 0); found_count++; } else { new_array->set(i - found_count, old_array->get(i)); } } // If the break point was found in the list change it. if (found_count > 0) break_point_info->set_break_point_objects(*new_array); } // Add the specified break point object. void BreakPointInfo::SetBreakPoint(Handle<BreakPointInfo> break_point_info, Handle<Object> break_point_object) { // If there was no break point objects before just set it. if (break_point_info->break_point_objects()->IsUndefined()) { break_point_info->set_break_point_objects(*break_point_object); return; } // If the break point object is the same as before just ignore. if (break_point_info->break_point_objects() == *break_point_object) return; // If there was one break point object before replace with array. if (!break_point_info->break_point_objects()->IsFixedArray()) { Handle<FixedArray> array = Factory::NewFixedArray(2); array->set(0, break_point_info->break_point_objects()); array->set(1, *break_point_object); break_point_info->set_break_point_objects(*array); return; } // If there was more than one break point before extend array. Handle<FixedArray> old_array = Handle<FixedArray>( FixedArray::cast(break_point_info->break_point_objects())); Handle<FixedArray> new_array = Factory::NewFixedArray(old_array->length() + 1); for (int i = 0; i < old_array->length(); i++) { // If the break point was there before just ignore. if (old_array->get(i) == *break_point_object) return; new_array->set(i, old_array->get(i)); } // Add the new break point. new_array->set(old_array->length(), *break_point_object); break_point_info->set_break_point_objects(*new_array); } bool BreakPointInfo::HasBreakPointObject( Handle<BreakPointInfo> break_point_info, Handle<Object> break_point_object) { // No break point. if (break_point_info->break_point_objects()->IsUndefined()) return false; // Single beak point. if (!break_point_info->break_point_objects()->IsFixedArray()) { return break_point_info->break_point_objects() == *break_point_object; } // Multiple break points. FixedArray* array = FixedArray::cast(break_point_info->break_point_objects()); for (int i = 0; i < array->length(); i++) { if (array->get(i) == *break_point_object) { return true; } } return false; } // Get the number of break points. int BreakPointInfo::GetBreakPointCount() { // No break point. if (break_point_objects()->IsUndefined()) return 0; // Single beak point. if (!break_point_objects()->IsFixedArray()) return 1; // Multiple break points. return FixedArray::cast(break_point_objects())->length(); } #endif } } // namespace v8::internal