/* * Copyright (c) 2018-2020, Andreas Kling * Copyright (c) 2021, Linus Groh * Copyright (c) 2021, Luke Wilde * * SPDX-License-Identifier: BSD-2-Clause */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include namespace Web::DOM { static IDAllocator s_node_id_allocator; static HashMap s_node_directory; static i32 allocate_node_id(Node* node) { i32 id = s_node_id_allocator.allocate(); s_node_directory.set(id, node); return id; } static void deallocate_node_id(i32 node_id) { if (!s_node_directory.remove(node_id)) VERIFY_NOT_REACHED(); s_node_id_allocator.deallocate(node_id); } Node* Node::from_id(i32 node_id) { return s_node_directory.get(node_id).value_or(nullptr); } Node::Node(Document& document, NodeType type) : EventTarget(static_cast(document)) , m_document(&document) , m_type(type) , m_id(allocate_node_id(this)) { if (!is_document()) m_document->ref_from_node({}); } Node::~Node() { VERIFY(m_deletion_has_begun); if (layout_node() && layout_node()->parent()) layout_node()->parent()->remove_child(*layout_node()); if (!is_document()) m_document->unref_from_node({}); deallocate_node_id(m_id); } const HTML::HTMLAnchorElement* Node::enclosing_link_element() const { for (auto* node = this; node; node = node->parent()) { if (is(*node) && verify_cast(*node).has_attribute(HTML::AttributeNames::href)) return verify_cast(node); } return nullptr; } const HTML::HTMLElement* Node::enclosing_html_element() const { return first_ancestor_of_type(); } const HTML::HTMLElement* Node::enclosing_html_element_with_attribute(const FlyString& attribute) const { for (auto* node = this; node; node = node->parent()) { if (is(*node) && verify_cast(*node).has_attribute(attribute)) return verify_cast(node); } return nullptr; } // https://dom.spec.whatwg.org/#concept-descendant-text-content String Node::descendant_text_content() const { StringBuilder builder; for_each_in_subtree_of_type([&](auto& text_node) { builder.append(text_node.data()); return IterationDecision::Continue; }); return builder.to_string(); } // https://dom.spec.whatwg.org/#dom-node-textcontent String Node::text_content() const { if (is(this) || is(this)) return descendant_text_content(); else if (is(this)) return verify_cast(this)->data(); // FIXME: Else if this is an Attr node, return this's value. return {}; } // https://dom.spec.whatwg.org/#ref-for-dom-node-textcontent%E2%91%A0 void Node::set_text_content(String const& content) { if (is(this) || is(this)) { string_replace_all(content); } else if (is(this)) { // FIXME: CharacterData::set_data is not spec compliant. Make this match the spec when set_data becomes spec compliant. // Do note that this will make this function able to throw an exception. auto* character_data_node = verify_cast(this); character_data_node->set_data(content); } else { // FIXME: Else if this is an Attr node, set an existing attribute value with this and the given value. return; } set_needs_style_update(true); } RefPtr Node::create_layout_node() { return nullptr; } void Node::invalidate_style() { for_each_in_inclusive_subtree_of_type([&](auto& element) { element.set_needs_style_update(true); return IterationDecision::Continue; }); document().schedule_style_update(); } bool Node::is_link() const { return enclosing_link_element(); } String Node::child_text_content() const { if (!is(*this)) return String::empty(); StringBuilder builder; verify_cast(*this).for_each_child([&](auto& child) { if (is(child)) builder.append(verify_cast(child).text_content()); }); return builder.build(); } // https://dom.spec.whatwg.org/#concept-tree-root Node& Node::root() { Node* root = this; while (root->parent()) root = root->parent(); return *root; } // https://dom.spec.whatwg.org/#concept-shadow-including-root Node& Node::shadow_including_root() { auto& node_root = root(); if (is(node_root)) return verify_cast(node_root).host()->shadow_including_root(); return node_root; } // https://dom.spec.whatwg.org/#connected bool Node::is_connected() const { return shadow_including_root().is_document(); } Element* Node::parent_element() { if (!parent() || !is(parent())) return nullptr; return verify_cast(parent()); } const Element* Node::parent_element() const { if (!parent() || !is(parent())) return nullptr; return verify_cast(parent()); } // https://dom.spec.whatwg.org/#concept-node-ensure-pre-insertion-validity ExceptionOr Node::ensure_pre_insertion_validity(NonnullRefPtr node, RefPtr child) const { if (!is(this) && !is(this) && !is(this)) return DOM::HierarchyRequestError::create("Can only insert into a document, document fragment or element"); if (node->is_host_including_inclusive_ancestor_of(*this)) return DOM::HierarchyRequestError::create("New node is an ancestor of this node"); if (child && child->parent() != this) return DOM::NotFoundError::create("This node is not the parent of the given child"); // FIXME: All the following "Invalid node type for insertion" messages could be more descriptive. if (!is(*node) && !is(*node) && !is(*node) && !is(*node) && !is(*node) && !is(*node)) return DOM::HierarchyRequestError::create("Invalid node type for insertion"); if ((is(*node) && is(this)) || (is(*node) && !is(this))) return DOM::HierarchyRequestError::create("Invalid node type for insertion"); if (is(this)) { if (is(*node)) { auto node_element_child_count = verify_cast(*node).child_element_count(); if ((node_element_child_count > 1 || node->has_child_of_type()) || (node_element_child_count == 1 && (has_child_of_type() || is(child.ptr()) || (child && child->has_following_node_of_type_in_tree_order())))) { return DOM::HierarchyRequestError::create("Invalid node type for insertion"); } } else if (is(*node)) { if (has_child_of_type() || is(child.ptr()) || (child && child->has_following_node_of_type_in_tree_order())) return DOM::HierarchyRequestError::create("Invalid node type for insertion"); } else if (is(*node)) { if (has_child_of_type() || (child && child->has_preceding_node_of_type_in_tree_order()) || (!child && has_child_of_type())) return DOM::HierarchyRequestError::create("Invalid node type for insertion"); } } return {}; } // https://dom.spec.whatwg.org/#concept-node-insert void Node::insert_before(NonnullRefPtr node, RefPtr child, bool suppress_observers) { NonnullRefPtrVector nodes; if (is(*node)) nodes = verify_cast(*node).children_as_vector(); else nodes.append(node); auto count = nodes.size(); if (count == 0) return; if (is(*node)) { node->remove_all_children(true); // FIXME: Queue a tree mutation record for node with « », nodes, null, and null. } if (child) { // FIXME: For each live range whose start node is parent and start offset is greater than child’s index, increase its start offset by count. // FIXME: For each live range whose end node is parent and end offset is greater than child’s index, increase its end offset by count. } // FIXME: Let previousSibling be child’s previous sibling or parent’s last child if child is null. (Currently unused so not included) for (auto& node_to_insert : nodes) { // FIXME: In tree order document().adopt_node(node_to_insert); if (!child) TreeNode::append_child(node_to_insert); else TreeNode::insert_before(node_to_insert, child); // FIXME: If parent is a shadow host and node is a slottable, then assign a slot for node. // FIXME: If parent’s root is a shadow root, and parent is a slot whose assigned nodes is the empty list, then run signal a slot change for parent. // FIXME: Run assign slottables for a tree with node’s root. // FIXME: This should be shadow-including. node_to_insert.for_each_in_inclusive_subtree([&](Node& inclusive_descendant) { inclusive_descendant.inserted(); if (inclusive_descendant.is_connected()) { // FIXME: If inclusiveDescendant is custom, then enqueue a custom element callback reaction with inclusiveDescendant, // callback name "connectedCallback", and an empty argument list. // FIXME: Otherwise, try to upgrade inclusiveDescendant. } return IterationDecision::Continue; }); } if (!suppress_observers) { // FIXME: queue a tree mutation record for parent with nodes, « », previousSibling, and child. } children_changed(); } // https://dom.spec.whatwg.org/#concept-node-pre-insert ExceptionOr> Node::pre_insert(NonnullRefPtr node, RefPtr child) { auto validity_result = ensure_pre_insertion_validity(node, child); if (validity_result.is_exception()) return validity_result.exception(); auto reference_child = child; if (reference_child == node) reference_child = node->next_sibling(); insert_before(node, reference_child); return node; } // https://dom.spec.whatwg.org/#concept-node-pre-remove ExceptionOr> Node::pre_remove(NonnullRefPtr child) { if (child->parent() != this) return DOM::NotFoundError::create("Child does not belong to this node"); child->remove(); return child; } // https://dom.spec.whatwg.org/#concept-node-append ExceptionOr> Node::append_child(NonnullRefPtr node) { return pre_insert(node, nullptr); } // https://dom.spec.whatwg.org/#concept-node-remove void Node::remove(bool suppress_observers) { auto* parent = TreeNode::parent(); VERIFY(parent); // FIXME: Let index be node’s index. (Currently unused so not included) // FIXME: For each live range whose start node is an inclusive descendant of node, set its start to (parent, index). // FIXME: For each live range whose end node is an inclusive descendant of node, set its end to (parent, index). // FIXME: For each live range whose start node is parent and start offset is greater than index, decrease its start offset by 1. // FIXME: For each live range whose end node is parent and end offset is greater than index, decrease its end offset by 1. // FIXME: For each NodeIterator object iterator whose root’s node document is node’s node document, run the NodeIterator pre-removing steps given node and iterator. // FIXME: Let oldPreviousSibling be node’s previous sibling. (Currently unused so not included) // FIXME: Let oldNextSibling be node’s next sibling. (Currently unused so not included) parent->remove_child(*this); // FIXME: If node is assigned, then run assign slottables for node’s assigned slot. // FIXME: If parent’s root is a shadow root, and parent is a slot whose assigned nodes is the empty list, then run signal a slot change for parent. // FIXME: If node has an inclusive descendant that is a slot, then: // Run assign slottables for a tree with parent’s root. // Run assign slottables for a tree with node. removed_from(parent); // FIXME: Let isParentConnected be parent’s connected. (Currently unused so not included) // FIXME: If node is custom and isParentConnected is true, then enqueue a custom element callback reaction with node, // callback name "disconnectedCallback", and an empty argument list. // FIXME: This should be shadow-including. for_each_in_subtree([&](Node& descendant) { descendant.removed_from(nullptr); // FIXME: If descendant is custom and isParentConnected is true, then enqueue a custom element callback reaction with descendant, // callback name "disconnectedCallback", and an empty argument list. return IterationDecision::Continue; }); if (!suppress_observers) { // FIXME: queue a tree mutation record for parent with « », « node », oldPreviousSibling, and oldNextSibling. } parent->children_changed(); } // https://dom.spec.whatwg.org/#concept-node-replace ExceptionOr> Node::replace_child(NonnullRefPtr node, NonnullRefPtr child) { // NOTE: This differs slightly from ensure_pre_insertion_validity. if (!is(this) && !is(this) && !is(this)) return DOM::HierarchyRequestError::create("Can only insert into a document, document fragment or element"); if (node->is_host_including_inclusive_ancestor_of(*this)) return DOM::HierarchyRequestError::create("New node is an ancestor of this node"); if (child->parent() != this) return DOM::NotFoundError::create("This node is not the parent of the given child"); // FIXME: All the following "Invalid node type for insertion" messages could be more descriptive. if (!is(*node) && !is(*node) && !is(*node) && !is(*node) && !is(*node) && !is(*node)) return DOM::HierarchyRequestError::create("Invalid node type for insertion"); if ((is(*node) && is(this)) || (is(*node) && !is(this))) return DOM::HierarchyRequestError::create("Invalid node type for insertion"); if (is(this)) { if (is(*node)) { auto node_element_child_count = verify_cast(*node).child_element_count(); if ((node_element_child_count > 1 || node->has_child_of_type()) || (node_element_child_count == 1 && (first_child_of_type() != child || child->has_following_node_of_type_in_tree_order()))) { return DOM::HierarchyRequestError::create("Invalid node type for insertion"); } } else if (is(*node)) { if (first_child_of_type() != child || child->has_following_node_of_type_in_tree_order()) return DOM::HierarchyRequestError::create("Invalid node type for insertion"); } else if (is(*node)) { if (first_child_of_type() != node || child->has_preceding_node_of_type_in_tree_order()) return DOM::HierarchyRequestError::create("Invalid node type for insertion"); } } auto reference_child = child->next_sibling(); if (reference_child == node) reference_child = node->next_sibling(); // FIXME: Let previousSibling be child’s previous sibling. (Currently unused so not included) // FIXME: Let removedNodes be the empty set. (Currently unused so not included) if (child->parent()) { // FIXME: Set removedNodes to « child ». child->remove(true); } // FIXME: Let nodes be node’s children if node is a DocumentFragment node; otherwise « node ». (Currently unused so not included) insert_before(node, reference_child, true); // FIXME: Queue a tree mutation record for parent with nodes, removedNodes, previousSibling, and referenceChild. return child; } // https://dom.spec.whatwg.org/#concept-node-clone NonnullRefPtr Node::clone_node(Document* document, bool clone_children) { if (!document) document = m_document; RefPtr copy; if (is(this)) { auto& element = *verify_cast(this); auto element_copy = DOM::create_element(*document, element.local_name(), element.namespace_() /* FIXME: node’s namespace prefix, and node’s is value, with the synchronous custom elements flag unset */); element.for_each_attribute([&](auto& name, auto& value) { element_copy->set_attribute(name, value); }); copy = move(element_copy); } else if (is(this)) { auto document_ = verify_cast(this); auto document_copy = Document::create(document_->url()); document_copy->set_encoding(document_->encoding()); document_copy->set_content_type(document_->content_type()); document_copy->set_origin(document_->origin()); document_copy->set_quirks_mode(document_->mode()); // FIXME: Set type ("xml" or "html") copy = move(document_copy); } else if (is(this)) { auto document_type = verify_cast(this); auto document_type_copy = adopt_ref(*new DocumentType(*document)); document_type_copy->set_name(document_type->name()); document_type_copy->set_public_id(document_type->public_id()); document_type_copy->set_system_id(document_type->system_id()); copy = move(document_type_copy); } else if (is(this)) { auto text = verify_cast(this); auto text_copy = adopt_ref(*new Text(*document, text->data())); copy = move(text_copy); } else if (is(this)) { auto comment = verify_cast(this); auto comment_copy = adopt_ref(*new Comment(*document, comment->data())); copy = move(comment_copy); } else if (is(this)) { auto processing_instruction = verify_cast(this); auto processing_instruction_copy = adopt_ref(*new ProcessingInstruction(*document, processing_instruction->data(), processing_instruction->target())); copy = move(processing_instruction_copy); } else if (is(this)) { auto document_fragment_copy = adopt_ref(*new DocumentFragment(*document)); copy = move(document_fragment_copy); } else { dbgln("clone_node() not implemented for NodeType {}", (u16)m_type); TODO(); } // FIXME: 4. Set copy’s node document and document to copy, if copy is a document, and set copy’s node document to document otherwise. cloned(*copy, clone_children); if (clone_children) { for_each_child([&](auto& child) { copy->append_child(child.clone_node(document, true)); }); } return copy.release_nonnull(); } // https://dom.spec.whatwg.org/#dom-node-clonenode ExceptionOr> Node::clone_node_binding(bool deep) { if (is(*this)) return NotSupportedError::create("Cannot clone shadow root"); return clone_node(nullptr, deep); } void Node::set_document(Badge, Document& document) { if (m_document == &document) return; document.ref_from_node({}); m_document->unref_from_node({}); m_document = &document; if (needs_style_update() || child_needs_style_update()) { // NOTE: We unset and reset the "needs style update" flag here. // This ensures that there's a pending style update in the new document // that will eventually assign some style to this node if needed. set_needs_style_update(false); set_needs_style_update(true); } } bool Node::is_editable() const { return parent() && parent()->is_editable(); } JS::Object* Node::create_wrapper(JS::GlobalObject& global_object) { return wrap(global_object, *this); } void Node::removed_last_ref() { if (is(*this)) { verify_cast(*this).removed_last_ref(); return; } m_deletion_has_begun = true; delete this; } void Node::set_layout_node(Badge, Layout::Node* layout_node) const { if (layout_node) m_layout_node = layout_node->make_weak_ptr(); else m_layout_node = nullptr; } EventTarget* Node::get_parent(const Event&) { // FIXME: returns the node’s assigned slot, if node is assigned, and node’s parent otherwise. return parent(); } void Node::set_needs_style_update(bool value) { if (m_needs_style_update == value) return; m_needs_style_update = value; if (m_needs_style_update) { for (auto* ancestor = parent(); ancestor; ancestor = ancestor->parent()) { ancestor->m_child_needs_style_update = true; } document().schedule_style_update(); } } void Node::inserted() { set_needs_style_update(true); } ParentNode* Node::parent_or_shadow_host() { if (is(*this)) return verify_cast(*this).host(); return verify_cast(parent()); } NonnullRefPtr Node::child_nodes() { // FIXME: This should return the same LiveNodeList object every time, // but that would cause a reference cycle since NodeList refs the root. return LiveNodeList::create(*this, [this](auto& node) { return is_parent_of(node); }); } NonnullRefPtrVector Node::children_as_vector() const { NonnullRefPtrVector nodes; for_each_child([&](auto& child) { nodes.append(child); }); return nodes; } void Node::remove_all_children(bool suppress_observers) { while (RefPtr child = first_child()) child->remove(suppress_observers); } // https://dom.spec.whatwg.org/#dom-node-comparedocumentposition u16 Node::compare_document_position(RefPtr other) { enum Position : u16 { DOCUMENT_POSITION_EQUAL = 0, DOCUMENT_POSITION_DISCONNECTED = 1, DOCUMENT_POSITION_PRECEDING = 2, DOCUMENT_POSITION_FOLLOWING = 4, DOCUMENT_POSITION_CONTAINS = 8, DOCUMENT_POSITION_CONTAINED_BY = 16, DOCUMENT_POSITION_IMPLEMENTATION_SPECIFIC = 32, }; if (this == other) return DOCUMENT_POSITION_EQUAL; Node* node1 = other.ptr(); Node* node2 = this; // FIXME: Once LibWeb supports attribute nodes fix to follow the specification. VERIFY(node1->type() != NodeType::ATTRIBUTE_NODE && node2->type() != NodeType::ATTRIBUTE_NODE); if ((node1 == nullptr || node2 == nullptr) || (&node1->root() != &node2->root())) return DOCUMENT_POSITION_DISCONNECTED | DOCUMENT_POSITION_IMPLEMENTATION_SPECIFIC | (node1 > node2 ? DOCUMENT_POSITION_PRECEDING : DOCUMENT_POSITION_FOLLOWING); if (node1->is_ancestor_of(*node2)) return DOCUMENT_POSITION_CONTAINS | DOCUMENT_POSITION_PRECEDING; if (node2->is_ancestor_of(*node1)) return DOCUMENT_POSITION_CONTAINED_BY | DOCUMENT_POSITION_FOLLOWING; if (node1->is_before(*node2)) return DOCUMENT_POSITION_PRECEDING; else return DOCUMENT_POSITION_FOLLOWING; } // https://dom.spec.whatwg.org/#concept-tree-host-including-inclusive-ancestor bool Node::is_host_including_inclusive_ancestor_of(const Node& other) const { return is_inclusive_ancestor_of(other) || (is(other.root()) && verify_cast(other.root()).host() && is_inclusive_ancestor_of(*verify_cast(other.root()).host().ptr())); } // https://dom.spec.whatwg.org/#dom-node-ownerdocument RefPtr Node::owner_document() const { if (is_document()) return nullptr; return m_document; } // This function tells us whether a node is interesting enough to show up // in the DOM inspector. This hides two things: // - Non-rendered whitespace // - Rendered whitespace between block-level elements bool Node::is_uninteresting_whitespace_node() const { if (!is(*this)) return false; if (!static_cast(*this).data().is_whitespace()) return false; if (!layout_node()) return true; if (layout_node()->parent()->is_anonymous()) return true; return false; } void Node::serialize_tree_as_json(JsonObjectSerializer& object) const { object.add("name", node_name().view()); object.add("id", id()); if (is_document()) { object.add("type", "document"); } else if (is_element()) { object.add("type", "element"); auto const* element = static_cast(this); if (element->has_attributes()) { auto attributes = object.add_object("attributes"); element->for_each_attribute([&attributes](auto& name, auto& value) { attributes.add(name, value); }); } if (element->is_browsing_context_container()) { auto const* container = static_cast(element); if (auto const* content_document = container->content_document()) { auto children = object.add_array("children"); JsonObjectSerializer content_document_object = children.add_object(); content_document->serialize_tree_as_json(content_document_object); } } } else if (is_text()) { object.add("type", "text"); auto text_node = static_cast(this); object.add("text", text_node->data()); } else if (is_comment()) { object.add("type"sv, "comment"sv); object.add("data"sv, static_cast(*this).data()); } if (has_child_nodes()) { auto children = object.add_array("children"); for_each_child([&children](DOM::Node& child) { if (child.is_uninteresting_whitespace_node()) return; JsonObjectSerializer child_object = children.add_object(); child.serialize_tree_as_json(child_object); }); } } // https://html.spec.whatwg.org/multipage/webappapis.html#concept-n-noscript bool Node::is_scripting_disabled() const { // FIXME: or when scripting is disabled for its relevant settings object. return !document().browsing_context(); } // https://dom.spec.whatwg.org/#dom-node-contains bool Node::contains(RefPtr other) const { return other && other->is_inclusive_descendant_of(*this); } // https://dom.spec.whatwg.org/#concept-shadow-including-descendant bool Node::is_shadow_including_descendant_of(Node const& other) const { if (is_descendant_of(other)) return true; if (!is(root())) return false; auto& shadow_root = verify_cast(root()); // NOTE: While host is nullable because of inheriting from DocumentFragment, shadow roots always have a host. return shadow_root.host()->is_shadow_including_inclusive_descendant_of(other); } // https://dom.spec.whatwg.org/#concept-shadow-including-inclusive-descendant bool Node::is_shadow_including_inclusive_descendant_of(Node const& other) const { return &other == this || is_shadow_including_descendant_of(other); } // https://dom.spec.whatwg.org/#concept-shadow-including-ancestor bool Node::is_shadow_including_ancestor_of(Node const& other) const { return other.is_shadow_including_descendant_of(*this); } // https://dom.spec.whatwg.org/#concept-shadow-including-inclusive-ancestor bool Node::is_shadow_including_inclusive_ancestor_of(Node const& other) const { return other.is_shadow_including_inclusive_descendant_of(*this); } // https://dom.spec.whatwg.org/#concept-node-replace-all void Node::replace_all(RefPtr node) { // FIXME: Let removedNodes be parent’s children. (Current unused so not included) // FIXME: Let addedNodes be the empty set. (Currently unused so not included) // FIXME: If node is a DocumentFragment node, then set addedNodes to node’s children. // FIXME: Otherwise, if node is non-null, set addedNodes to « node ». remove_all_children(true); if (node) insert_before(*node, nullptr, true); // FIXME: If either addedNodes or removedNodes is not empty, then queue a tree mutation record for parent with addedNodes, removedNodes, null, and null. } // https://dom.spec.whatwg.org/#string-replace-all void Node::string_replace_all(String const& string) { RefPtr node; if (!string.is_empty()) node = make_ref_counted(document(), string); replace_all(node); } // https://w3c.github.io/DOM-Parsing/#dfn-fragment-serializing-algorithm String Node::serialize_fragment(/* FIXME: Requires well-formed flag */) const { // FIXME: Let context document be the value of node's node document. // FIXME: If context document is an HTML document, return an HTML serialization of node. // (We currently always do this) return HTML::HTMLParser::serialize_html_fragment(*this); // FIXME: Otherwise, context document is an XML document; return an XML serialization of node passing the flag require well-formed. } // https://dom.spec.whatwg.org/#dom-node-issamenode bool Node::is_same_node(Node const* other_node) const { return this == other_node; } // https://dom.spec.whatwg.org/#dom-node-isequalnode bool Node::is_equal_node(Node const* other_node) const { // The isEqualNode(otherNode) method steps are to return true if otherNode is non-null and this equals otherNode; otherwise false. if (!other_node) return false; // Fast path for testing a node against itself. if (this == other_node) return true; // A node A equals a node B if all of the following conditions are true: // A and B implement the same interfaces. if (node_name() != other_node->node_name()) return false; // The following are equal, switching on the interface A implements: switch (node_type()) { case (u16)NodeType::DOCUMENT_TYPE_NODE: { // Its name, public ID, and system ID. auto& this_doctype = verify_cast(*this); auto& other_doctype = verify_cast(*other_node); if (this_doctype.name() != other_doctype.name() || this_doctype.public_id() != other_doctype.public_id() || this_doctype.system_id() != other_doctype.system_id()) return false; break; } case (u16)NodeType::ELEMENT_NODE: { // Its namespace, namespace prefix, local name, and its attribute list’s size. auto& this_element = verify_cast(*this); auto& other_element = verify_cast(*other_node); if (this_element.namespace_() != other_element.namespace_() || this_element.prefix() != other_element.prefix() || this_element.local_name() != other_element.local_name() || this_element.attribute_list_size() != other_element.attribute_list_size()) return false; // If A is an element, each attribute in its attribute list has an attribute that equals an attribute in B’s attribute list. bool has_same_attributes = true; this_element.for_each_attribute([&](auto& name, auto& value) { if (other_element.get_attribute(name) != value) has_same_attributes = false; }); if (!has_same_attributes) return false; break; } case (u16)NodeType::COMMENT_NODE: case (u16)NodeType::TEXT_NODE: { // Its data. auto& this_cdata = verify_cast(*this); auto& other_cdata = verify_cast(*other_node); if (this_cdata.data() != other_cdata.data()) return false; break; } case (u16)NodeType::PROCESSING_INSTRUCTION_NODE: case (u16)NodeType::ATTRIBUTE_NODE: TODO(); default: break; } // A and B have the same number of children. size_t this_child_count = child_count(); size_t other_child_count = other_node->child_count(); if (this_child_count != other_child_count) return false; // Each child of A equals the child of B at the identical index. // FIXME: This can be made nicer. child_at_index() is O(n). for (size_t i = 0; i < this_child_count; ++i) { auto* this_child = child_at_index(i); auto* other_child = other_node->child_at_index(i); VERIFY(this_child); VERIFY(other_child); if (!this_child->is_equal_node(other_child)) return false; } return true; } // https://dom.spec.whatwg.org/#in-a-document-tree bool Node::in_a_document_tree() const { // An element is in a document tree if its root is a document. return root().is_document(); } // https://dom.spec.whatwg.org/#dom-node-getrootnode NonnullRefPtr Node::get_root_node(GetRootNodeOptions const& options) { // The getRootNode(options) method steps are to return this’s shadow-including root if options["composed"] is true; otherwise this’s root. if (options.composed) return shadow_including_root(); return root(); } }