/* * Copyright (c) 2020, Matthew Olsson * * SPDX-License-Identifier: BSD-2-Clause */ #include #include #include namespace JS { constexpr const size_t SPARSE_ARRAY_HOLE_THRESHOLD = 200; constexpr const size_t LENGTH_SETTER_GENERIC_STORAGE_THRESHOLD = 4 * MiB; SimpleIndexedPropertyStorage::SimpleIndexedPropertyStorage(Vector&& initial_values) : m_array_size(initial_values.size()) , m_packed_elements(move(initial_values)) { } bool SimpleIndexedPropertyStorage::has_index(u32 index) const { return index < m_array_size && !m_packed_elements[index].is_empty(); } Optional SimpleIndexedPropertyStorage::get(u32 index) const { if (index >= m_array_size) return {}; return ValueAndAttributes { m_packed_elements[index], default_attributes }; } void SimpleIndexedPropertyStorage::grow_storage_if_needed() { if (m_array_size <= m_packed_elements.size()) return; // Grow storage by 25% at a time. m_packed_elements.resize(m_array_size + (m_array_size / 4)); } void SimpleIndexedPropertyStorage::put(u32 index, Value value, PropertyAttributes attributes) { VERIFY(attributes == default_attributes); if (index >= m_array_size) { m_array_size = index + 1; grow_storage_if_needed(); } m_packed_elements[index] = value; } void SimpleIndexedPropertyStorage::remove(u32 index) { if (index < m_array_size) m_packed_elements[index] = {}; } void SimpleIndexedPropertyStorage::insert(u32 index, Value value, PropertyAttributes attributes) { VERIFY(attributes == default_attributes); m_array_size++; m_packed_elements.insert(index, value); } ValueAndAttributes SimpleIndexedPropertyStorage::take_first() { m_array_size--; return { m_packed_elements.take_first(), default_attributes }; } ValueAndAttributes SimpleIndexedPropertyStorage::take_last() { m_array_size--; auto last_element = m_packed_elements[m_array_size]; m_packed_elements[m_array_size] = {}; return { last_element, default_attributes }; } void SimpleIndexedPropertyStorage::set_array_like_size(size_t new_size) { m_array_size = new_size; m_packed_elements.resize(new_size); } GenericIndexedPropertyStorage::GenericIndexedPropertyStorage(SimpleIndexedPropertyStorage&& storage) { m_array_size = storage.array_like_size(); for (size_t i = 0; i < storage.m_packed_elements.size(); ++i) { m_sparse_elements.set(i, { storage.m_packed_elements[i], default_attributes }); } } bool GenericIndexedPropertyStorage::has_index(u32 index) const { return m_sparse_elements.contains(index); } Optional GenericIndexedPropertyStorage::get(u32 index) const { if (index >= m_array_size) return {}; return m_sparse_elements.get(index); } void GenericIndexedPropertyStorage::put(u32 index, Value value, PropertyAttributes attributes) { if (index >= m_array_size) m_array_size = index + 1; m_sparse_elements.set(index, { value, attributes }); } void GenericIndexedPropertyStorage::remove(u32 index) { if (index >= m_array_size) return; if (index + 1 == m_array_size) { take_last(); return; } m_sparse_elements.remove(index); } void GenericIndexedPropertyStorage::insert(u32 index, Value value, PropertyAttributes attributes) { if (index >= m_array_size) { put(index, value, attributes); return; } m_array_size++; if (!m_sparse_elements.is_empty()) { HashMap new_sparse_elements; for (auto& entry : m_sparse_elements) new_sparse_elements.set(entry.key >= index ? entry.key + 1 : entry.key, entry.value); m_sparse_elements = move(new_sparse_elements); } m_sparse_elements.set(index, { value, attributes }); } ValueAndAttributes GenericIndexedPropertyStorage::take_first() { VERIFY(m_array_size > 0); m_array_size--; auto indices = m_sparse_elements.keys(); quick_sort(indices); auto it = m_sparse_elements.find(indices.first()); auto first_element = it->value; m_sparse_elements.remove(it); return first_element; } ValueAndAttributes GenericIndexedPropertyStorage::take_last() { VERIFY(m_array_size > 0); m_array_size--; auto result = m_sparse_elements.get(m_array_size); if (!result.has_value()) return {}; m_sparse_elements.remove(m_array_size); return result.value(); } void GenericIndexedPropertyStorage::set_array_like_size(size_t new_size) { m_array_size = new_size; HashMap new_sparse_elements; for (auto& entry : m_sparse_elements) { if (entry.key < new_size) new_sparse_elements.set(entry.key, entry.value); } m_sparse_elements = move(new_sparse_elements); } IndexedPropertyIterator::IndexedPropertyIterator(const IndexedProperties& indexed_properties, u32 staring_index, bool skip_empty) : m_indexed_properties(indexed_properties) , m_index(staring_index) , m_skip_empty(skip_empty) { if (m_skip_empty) skip_empty_indices(); } IndexedPropertyIterator& IndexedPropertyIterator::operator++() { m_index++; if (m_skip_empty) skip_empty_indices(); return *this; } IndexedPropertyIterator& IndexedPropertyIterator::operator*() { return *this; } bool IndexedPropertyIterator::operator!=(const IndexedPropertyIterator& other) const { return m_index != other.m_index; } ValueAndAttributes IndexedPropertyIterator::value_and_attributes(Object* this_object, AllowSideEffects allow_side_effects) { if (m_index < m_indexed_properties.array_like_size()) return m_indexed_properties.get(this_object, m_index, allow_side_effects).value_or({}); return {}; } void IndexedPropertyIterator::skip_empty_indices() { auto indices = m_indexed_properties.indices(); for (auto i : indices) { if (i < m_index) continue; m_index = i; return; } m_index = m_indexed_properties.array_like_size(); } Optional IndexedProperties::get(Object* this_object, u32 index, AllowSideEffects allow_side_effects) const { auto result = m_storage->get(index); if (allow_side_effects == AllowSideEffects::No) return result; if (!result.has_value()) return {}; auto& value = result.value(); if (value.value.is_accessor()) { VERIFY(this_object); auto& accessor = value.value.as_accessor(); return ValueAndAttributes { accessor.call_getter(this_object), value.attributes }; } return result; } void IndexedProperties::put(Object* this_object, u32 index, Value value, PropertyAttributes attributes, AllowSideEffects allow_side_effects) { if (m_storage->is_simple_storage() && (attributes != default_attributes || index > (array_like_size() + SPARSE_ARRAY_HOLE_THRESHOLD))) { switch_to_generic_storage(); } if (m_storage->is_simple_storage() || allow_side_effects == AllowSideEffects::No) { m_storage->put(index, value, attributes); return; } auto value_here = m_storage->get(index); if (value_here.has_value() && value_here.value().value.is_accessor()) { VERIFY(this_object); value_here.value().value.as_accessor().call_setter(this_object, value); } else { m_storage->put(index, value, attributes); } } bool IndexedProperties::remove(u32 index) { auto result = m_storage->get(index); if (!result.has_value()) return true; if (!result.value().attributes.is_configurable()) return false; m_storage->remove(index); return true; } void IndexedProperties::insert(u32 index, Value value, PropertyAttributes attributes) { if (m_storage->is_simple_storage()) { if (attributes != default_attributes || index > (array_like_size() + SPARSE_ARRAY_HOLE_THRESHOLD)) { switch_to_generic_storage(); } } m_storage->insert(index, value, attributes); } ValueAndAttributes IndexedProperties::take_first(Object* this_object) { auto first = m_storage->take_first(); if (first.value.is_accessor()) return { first.value.as_accessor().call_getter(this_object), first.attributes }; return first; } ValueAndAttributes IndexedProperties::take_last(Object* this_object) { auto last = m_storage->take_last(); if (last.value.is_accessor()) return { last.value.as_accessor().call_getter(this_object), last.attributes }; return last; } void IndexedProperties::set_array_like_size(size_t new_size) { auto current_array_like_size = array_like_size(); // We can't use simple storage for lengths that don't fit in an i32. // Also, to avoid gigantic unused storage allocations, let's put an (arbitrary) 4M cap on simple storage here. // This prevents something like "a = []; a.length = 0x80000000;" from allocating 2G entries. if (m_storage->is_simple_storage() && (new_size > NumericLimits::max() || (current_array_like_size < LENGTH_SETTER_GENERIC_STORAGE_THRESHOLD && new_size > LENGTH_SETTER_GENERIC_STORAGE_THRESHOLD))) { switch_to_generic_storage(); } m_storage->set_array_like_size(new_size); } Vector IndexedProperties::indices() const { if (m_storage->is_simple_storage()) { const auto& storage = static_cast(*m_storage); const auto& elements = storage.elements(); Vector indices; indices.ensure_capacity(storage.array_like_size()); for (size_t i = 0; i < elements.size(); ++i) { if (!elements.at(i).is_empty()) indices.unchecked_append(i); } return indices; } const auto& storage = static_cast(*m_storage); auto indices = storage.sparse_elements().keys(); quick_sort(indices); return indices; } void IndexedProperties::switch_to_generic_storage() { auto& storage = static_cast(*m_storage); m_storage = make(move(storage)); } }