/* * Copyright (c) 2020-2024, Andreas Kling * * SPDX-License-Identifier: BSD-2-Clause */ #include #include #include namespace JS { GC_DEFINE_ALLOCATOR(Shape); GC_DEFINE_ALLOCATOR(PrototypeChainValidity); static HashTable> s_all_prototype_shapes; Shape::~Shape() { if (m_is_prototype_shape) s_all_prototype_shapes.remove(this); } GC::Ref Shape::create_cacheable_dictionary_transition() { auto new_shape = heap().allocate(m_realm); new_shape->m_dictionary = true; new_shape->m_cacheable = true; new_shape->m_prototype = m_prototype; invalidate_prototype_if_needed_for_new_prototype(new_shape); ensure_property_table(); new_shape->ensure_property_table(); (*new_shape->m_property_table) = *m_property_table; new_shape->m_property_count = new_shape->m_property_table->size(); return new_shape; } GC::Ref Shape::create_uncacheable_dictionary_transition() { auto new_shape = heap().allocate(m_realm); new_shape->m_dictionary = true; new_shape->m_cacheable = true; new_shape->m_prototype = m_prototype; invalidate_prototype_if_needed_for_new_prototype(new_shape); ensure_property_table(); new_shape->ensure_property_table(); (*new_shape->m_property_table) = *m_property_table; new_shape->m_property_count = new_shape->m_property_table->size(); return new_shape; } GC::Ptr Shape::get_or_prune_cached_forward_transition(TransitionKey const& key) { if (m_is_prototype_shape) return nullptr; if (!m_forward_transitions) return nullptr; auto it = m_forward_transitions->find(key); if (it == m_forward_transitions->end()) return nullptr; if (!it->value) { // The cached forward transition has gone stale (from garbage collection). Prune it. m_forward_transitions->remove(it); return nullptr; } return it->value.ptr(); } GC::Ptr Shape::get_or_prune_cached_delete_transition(StringOrSymbol const& key) { if (m_is_prototype_shape) return nullptr; if (!m_delete_transitions) return nullptr; auto it = m_delete_transitions->find(key); if (it == m_delete_transitions->end()) return nullptr; if (!it->value) { // The cached delete transition has gone stale (from garbage collection). Prune it. m_delete_transitions->remove(it); return nullptr; } return it->value.ptr(); } GC::Ptr Shape::get_or_prune_cached_prototype_transition(Object* prototype) { if (m_is_prototype_shape) return nullptr; if (!m_prototype_transitions) return nullptr; auto it = m_prototype_transitions->find(prototype); if (it == m_prototype_transitions->end()) return nullptr; if (!it->value) { // The cached prototype transition has gone stale (from garbage collection). Prune it. m_prototype_transitions->remove(it); return nullptr; } return it->value.ptr(); } GC::Ref Shape::create_put_transition(StringOrSymbol const& property_key, PropertyAttributes attributes) { TransitionKey key { property_key, attributes }; if (auto existing_shape = get_or_prune_cached_forward_transition(key)) return *existing_shape; auto new_shape = heap().allocate(*this, property_key, attributes, TransitionType::Put); invalidate_prototype_if_needed_for_new_prototype(new_shape); if (!m_is_prototype_shape) { if (!m_forward_transitions) m_forward_transitions = make>>(); m_forward_transitions->set(key, new_shape.ptr()); } return new_shape; } GC::Ref Shape::create_configure_transition(StringOrSymbol const& property_key, PropertyAttributes attributes) { TransitionKey key { property_key, attributes }; if (auto existing_shape = get_or_prune_cached_forward_transition(key)) return *existing_shape; auto new_shape = heap().allocate(*this, property_key, attributes, TransitionType::Configure); invalidate_prototype_if_needed_for_new_prototype(new_shape); if (!m_is_prototype_shape) { if (!m_forward_transitions) m_forward_transitions = make>>(); m_forward_transitions->set(key, new_shape.ptr()); } return new_shape; } GC::Ref Shape::create_prototype_transition(Object* new_prototype) { if (new_prototype) new_prototype->convert_to_prototype_if_needed(); if (auto existing_shape = get_or_prune_cached_prototype_transition(new_prototype)) return *existing_shape; auto new_shape = heap().allocate(*this, new_prototype); invalidate_prototype_if_needed_for_new_prototype(new_shape); if (!m_is_prototype_shape) { if (!m_prototype_transitions) m_prototype_transitions = make, WeakPtr>>(); m_prototype_transitions->set(new_prototype, new_shape.ptr()); } return new_shape; } Shape::Shape(Realm& realm) : m_realm(realm) { } Shape::Shape(Shape& previous_shape, StringOrSymbol const& property_key, PropertyAttributes attributes, TransitionType transition_type) : m_realm(previous_shape.m_realm) , m_previous(&previous_shape) , m_property_key(property_key) , m_prototype(previous_shape.m_prototype) , m_property_count(transition_type == TransitionType::Put ? previous_shape.m_property_count + 1 : previous_shape.m_property_count) , m_attributes(attributes) , m_transition_type(transition_type) { } Shape::Shape(Shape& previous_shape, StringOrSymbol const& property_key, TransitionType transition_type) : m_realm(previous_shape.m_realm) , m_previous(&previous_shape) , m_property_key(property_key) , m_prototype(previous_shape.m_prototype) , m_property_count(previous_shape.m_property_count - 1) , m_transition_type(transition_type) { VERIFY(transition_type == TransitionType::Delete); } Shape::Shape(Shape& previous_shape, Object* new_prototype) : m_realm(previous_shape.m_realm) , m_previous(&previous_shape) , m_prototype(new_prototype) , m_property_count(previous_shape.m_property_count) , m_transition_type(TransitionType::Prototype) { } void Shape::visit_edges(Cell::Visitor& visitor) { Base::visit_edges(visitor); visitor.visit(m_realm); visitor.visit(m_prototype); visitor.visit(m_previous); m_property_key.visit_edges(visitor); // NOTE: We don't need to mark the keys in the property table, since they are guaranteed // to also be marked by the chain of shapes leading up to this one. visitor.ignore(m_prototype_transitions); // FIXME: The forward transition keys should be weak, but we have to mark them for now in case they go stale. if (m_forward_transitions) { for (auto& it : *m_forward_transitions) it.key.property_key.visit_edges(visitor); } // FIXME: The delete transition keys should be weak, but we have to mark them for now in case they go stale. if (m_delete_transitions) { for (auto& it : *m_delete_transitions) it.key.visit_edges(visitor); } visitor.visit(m_prototype_chain_validity); } Optional Shape::lookup(StringOrSymbol const& property_key) const { if (m_property_count == 0) return {}; auto property = property_table().get(property_key); if (!property.has_value()) return {}; return property; } FLATTEN OrderedHashMap const& Shape::property_table() const { ensure_property_table(); return *m_property_table; } void Shape::ensure_property_table() const { if (m_property_table) return; m_property_table = make>(); u32 next_offset = 0; Vector transition_chain; transition_chain.append(*this); for (auto shape = m_previous; shape; shape = shape->m_previous) { if (shape->m_property_table) { *m_property_table = *shape->m_property_table; next_offset = shape->m_property_count; break; } transition_chain.append(*shape); } for (auto const& shape : transition_chain.in_reverse()) { if (!shape.m_property_key.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_key, { next_offset++, shape.m_attributes }); } else if (shape.m_transition_type == TransitionType::Configure) { auto it = m_property_table->find(shape.m_property_key); VERIFY(it != m_property_table->end()); it->value.attributes = shape.m_attributes; } else if (shape.m_transition_type == TransitionType::Delete) { auto remove_it = m_property_table->find(shape.m_property_key); VERIFY(remove_it != m_property_table->end()); auto removed_offset = remove_it->value.offset; m_property_table->remove(remove_it); for (auto& it : *m_property_table) { if (it.value.offset > removed_offset) --it.value.offset; } --next_offset; } } } GC::Ref Shape::create_delete_transition(StringOrSymbol const& property_key) { if (auto existing_shape = get_or_prune_cached_delete_transition(property_key)) return *existing_shape; auto new_shape = heap().allocate(*this, property_key, TransitionType::Delete); invalidate_prototype_if_needed_for_new_prototype(new_shape); if (!m_delete_transitions) m_delete_transitions = make>>(); m_delete_transitions->set(property_key, new_shape.ptr()); return new_shape; } void Shape::add_property_without_transition(StringOrSymbol const& property_key, PropertyAttributes attributes) { ensure_property_table(); if (m_property_table->set(property_key, { m_property_count, attributes }) == AK::HashSetResult::InsertedNewEntry) { VERIFY(m_property_count < NumericLimits::max()); ++m_property_count; } } FLATTEN void Shape::add_property_without_transition(PropertyKey const& property_key, PropertyAttributes attributes) { add_property_without_transition(property_key.to_string_or_symbol(), attributes); } void Shape::set_property_attributes_without_transition(StringOrSymbol const& property_key, PropertyAttributes attributes) { VERIFY(is_dictionary()); VERIFY(m_property_table); auto it = m_property_table->find(property_key); VERIFY(it != m_property_table->end()); it->value.attributes = attributes; m_property_table->set(property_key, it->value); } void Shape::remove_property_without_transition(StringOrSymbol const& property_key, u32 offset) { VERIFY(is_uncacheable_dictionary()); VERIFY(m_property_table); if (m_property_table->remove(property_key)) --m_property_count; for (auto& it : *m_property_table) { VERIFY(it.value.offset != offset); if (it.value.offset > offset) --it.value.offset; } } GC::Ref Shape::create_for_prototype(GC::Ref realm, GC::Ptr prototype) { auto new_shape = realm->heap().allocate(realm); s_all_prototype_shapes.set(new_shape); new_shape->m_is_prototype_shape = true; new_shape->m_prototype = prototype; new_shape->m_prototype_chain_validity = realm->heap().allocate(); return new_shape; } GC::Ref Shape::clone_for_prototype() { VERIFY(!m_is_prototype_shape); VERIFY(!m_prototype_chain_validity); auto new_shape = heap().allocate(m_realm); s_all_prototype_shapes.set(new_shape); new_shape->m_is_prototype_shape = true; new_shape->m_prototype = m_prototype; ensure_property_table(); new_shape->ensure_property_table(); (*new_shape->m_property_table) = *m_property_table; new_shape->m_property_count = new_shape->m_property_table->size(); new_shape->m_prototype_chain_validity = heap().allocate(); return new_shape; } void Shape::set_prototype_without_transition(Object* new_prototype) { VERIFY(new_prototype); new_prototype->convert_to_prototype_if_needed(); m_prototype = new_prototype; } void Shape::set_prototype_shape() { VERIFY(!m_is_prototype_shape); s_all_prototype_shapes.set(this); m_is_prototype_shape = true; m_prototype_chain_validity = heap().allocate(); } void Shape::invalidate_prototype_if_needed_for_new_prototype(GC::Ref new_prototype_shape) { if (!m_is_prototype_shape) return; new_prototype_shape->set_prototype_shape(); m_prototype_chain_validity->set_valid(false); invalidate_all_prototype_chains_leading_to_this(); } void Shape::invalidate_all_prototype_chains_leading_to_this() { HashTable shapes_to_invalidate; for (auto& candidate : s_all_prototype_shapes) { if (!candidate->m_prototype) continue; for (auto* current_prototype_shape = &candidate->m_prototype->shape(); current_prototype_shape; current_prototype_shape = current_prototype_shape->prototype() ? ¤t_prototype_shape->prototype()->shape() : nullptr) { if (current_prototype_shape == this) { VERIFY(candidate->m_is_prototype_shape); shapes_to_invalidate.set(candidate); break; } } } if (shapes_to_invalidate.is_empty()) return; for (auto* shape : shapes_to_invalidate) { shape->m_prototype_chain_validity->set_valid(false); shape->m_prototype_chain_validity = heap().allocate(); } } }