/* * Copyright (c) 2020, Andreas Kling * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * 1. Redistributions of source code must retain the above copyright notice, this * list of conditions and the following disclaimer. * * 2. 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. * * 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 HOLDER 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 #include #include #include namespace JS { Shape* Shape::create_unique_clone() const { auto* new_shape = heap().allocate(m_global_object, m_global_object); new_shape->m_unique = true; new_shape->m_prototype = m_prototype; ensure_property_table(); new_shape->ensure_property_table(); (*new_shape->m_property_table) = *m_property_table; return new_shape; } Shape* Shape::create_put_transition(const StringOrSymbol& property_name, PropertyAttributes attributes) { TransitionKey key { property_name, attributes }; if (auto* existing_shape = m_forward_transitions.get(key).value_or(nullptr)) return existing_shape; auto* new_shape = heap().allocate(m_global_object, *this, property_name, attributes, TransitionType::Put); m_forward_transitions.set(key, new_shape); return new_shape; } Shape* Shape::create_configure_transition(const StringOrSymbol& property_name, PropertyAttributes attributes) { TransitionKey key { property_name, attributes }; if (auto* existing_shape = m_forward_transitions.get(key).value_or(nullptr)) return existing_shape; auto* new_shape = heap().allocate(m_global_object, *this, property_name, attributes, TransitionType::Configure); m_forward_transitions.set(key, new_shape); return new_shape; } Shape* Shape::create_prototype_transition(Object* new_prototype) { return heap().allocate(m_global_object, *this, new_prototype); } Shape::Shape(GlobalObject& global_object) : m_global_object(global_object) { } Shape::Shape(Shape& previous_shape, const StringOrSymbol& property_name, PropertyAttributes attributes, TransitionType transition_type) : m_global_object(previous_shape.m_global_object) , m_previous(&previous_shape) , m_property_name(property_name) , m_attributes(attributes) , m_prototype(previous_shape.m_prototype) , m_transition_type(transition_type) { } Shape::Shape(Shape& previous_shape, Object* new_prototype) : m_global_object(previous_shape.m_global_object) , m_previous(&previous_shape) , m_prototype(new_prototype) , m_transition_type(TransitionType::Prototype) { } Shape::~Shape() { } void Shape::visit_children(Cell::Visitor& visitor) { Cell::visit_children(visitor); visitor.visit(&m_global_object); visitor.visit(m_prototype); visitor.visit(m_previous); m_property_name.visit_children(visitor); for (auto& it : m_forward_transitions) visitor.visit(it.value); ensure_property_table(); for (auto& it : *m_property_table) it.key.visit_children(visitor); } Optional Shape::lookup(const StringOrSymbol& property_name) const { auto property = property_table().get(property_name); if (!property.has_value()) return {}; return property; } const HashMap& Shape::property_table() const { ensure_property_table(); return *m_property_table; } size_t Shape::property_count() const { return property_table().size(); } Vector Shape::property_table_ordered() const { auto vec = Vector(); vec.resize(property_table().size()); for (auto& it : property_table()) { vec[it.value.offset] = { it.key, it.value }; } return vec; } void Shape::ensure_property_table() const { if (m_property_table) return; m_property_table = make>(); DeferGC defer(heap()); Vector transition_chain; for (auto* shape = this; shape->m_previous; shape = shape->m_previous) { transition_chain.append(shape); } u32 next_offset = 0; for (ssize_t i = transition_chain.size() - 1; i >= 0; --i) { auto* shape = transition_chain[i]; if (!shape->m_property_name.is_valid()) { // Ignore prototype transitions as they don't affect the key map. continue; } if (shape->m_transition_type == TransitionType::Put) { m_property_table->set(shape->m_property_name, { next_offset++, shape->m_attributes }); } else if (shape->m_transition_type == TransitionType::Configure) { auto it = m_property_table->find(shape->m_property_name); ASSERT(it != m_property_table->end()); it->value.attributes = shape->m_attributes; } } } void Shape::add_property_to_unique_shape(const StringOrSymbol& property_name, PropertyAttributes attributes) { ASSERT(is_unique()); ASSERT(m_property_table); ASSERT(!m_property_table->contains(property_name)); m_property_table->set(property_name, { m_property_table->size(), attributes }); } void Shape::reconfigure_property_in_unique_shape(const StringOrSymbol& property_name, PropertyAttributes attributes) { ASSERT(is_unique()); ASSERT(m_property_table); ASSERT(m_property_table->contains(property_name)); m_property_table->set(property_name, { m_property_table->size(), attributes }); } void Shape::remove_property_from_unique_shape(const StringOrSymbol& property_name, size_t offset) { ASSERT(is_unique()); ASSERT(m_property_table); m_property_table->remove(property_name); for (auto& it : *m_property_table) { ASSERT(it.value.offset != offset); if (it.value.offset > offset) --it.value.offset; } } }