/* * Copyright (c) 2022, Andreas Kling * * SPDX-License-Identifier: BSD-2-Clause */ #include #include #include #include #include #include #include #include #include namespace Web::DOM { TreeWalker::TreeWalker(Node& root) : m_root(root) , m_current(root) { } // https://dom.spec.whatwg.org/#dom-document-createtreewalker NonnullRefPtr TreeWalker::create(Node& root, unsigned what_to_show, RefPtr filter) { // 1. Let walker be a new TreeWalker object. // 2. Set walker’s root and walker’s current to root. auto walker = adopt_ref(*new TreeWalker(root)); // 3. Set walker’s whatToShow to whatToShow. walker->m_what_to_show = what_to_show; // 4. Set walker’s filter to filter. walker->m_filter = move(filter); // 5. Return walker. return walker; } // https://dom.spec.whatwg.org/#dom-treewalker-currentnode NonnullRefPtr TreeWalker::current_node() const { return *m_current; } // https://dom.spec.whatwg.org/#dom-treewalker-currentnode void TreeWalker::set_current_node(Node& node) { m_current = node; } // https://dom.spec.whatwg.org/#dom-treewalker-parentnode JS::ThrowCompletionOr> TreeWalker::parent_node() { // 1. Let node be this’s current. RefPtr node = m_current; // 2. While node is non-null and is not this’s root: while (node && node != m_root) { // 1. Set node to node’s parent. node = node->parent(); // 2. If node is non-null and filtering node within this returns FILTER_ACCEPT, // then set this’s current to node and return node. if (node) { auto result = TRY(filter(*node)); if (result == NodeFilter::FILTER_ACCEPT) { m_current = *node; return node; } } } return nullptr; } // https://dom.spec.whatwg.org/#dom-treewalker-firstchild JS::ThrowCompletionOr> TreeWalker::first_child() { return traverse_children(ChildTraversalType::First); } // https://dom.spec.whatwg.org/#dom-treewalker-lastchild JS::ThrowCompletionOr> TreeWalker::last_child() { return traverse_children(ChildTraversalType::Last); } // https://dom.spec.whatwg.org/#dom-treewalker-previoussibling JS::ThrowCompletionOr> TreeWalker::previous_sibling() { return traverse_siblings(SiblingTraversalType::Previous); } // https://dom.spec.whatwg.org/#dom-treewalker-nextsibling JS::ThrowCompletionOr> TreeWalker::next_sibling() { return traverse_siblings(SiblingTraversalType::Next); } // https://dom.spec.whatwg.org/#dom-treewalker-previousnode JS::ThrowCompletionOr> TreeWalker::previous_node() { // 1. Let node be this’s current. RefPtr node = m_current; // 2. While node is not this’s root: while (node != m_root) { // 1. Let sibling be node’s previous sibling. RefPtr sibling = node->previous_sibling(); // 2. While sibling is non-null: while (sibling) { // 1. Set node to sibling. node = sibling; // 2. Let result be the result of filtering node within this. auto result = TRY(filter(*node)); // 3. While result is not FILTER_REJECT and node has a child: while (result != NodeFilter::FILTER_REJECT && node->has_children()) { // 1. Set node to node’s last child. node = node->last_child(); // 2. Set result to the result of filtering node within this. result = TRY(filter(*node)); } // 4. If result is FILTER_ACCEPT, then set this’s current to node and return node. if (result == NodeFilter::FILTER_ACCEPT) { m_current = *node; return node; } // 5. Set sibling to node’s previous sibling. sibling = node->previous_sibling(); } // 3. If node is this’s root or node’s parent is null, then return null. if (node == m_root || !node->parent()) return nullptr; // 4. Set node to node’s parent. node = node->parent(); // 5. If the return value of filtering node within this is FILTER_ACCEPT, then set this’s current to node and return node. if (TRY(filter(*node)) == NodeFilter::FILTER_ACCEPT) { m_current = *node; return node; } } // 3. Return null. return nullptr; } // https://dom.spec.whatwg.org/#dom-treewalker-nextnode JS::ThrowCompletionOr> TreeWalker::next_node() { // 1. Let node be this’s current. RefPtr node = m_current; // 2. Let result be FILTER_ACCEPT. auto result = NodeFilter::FILTER_ACCEPT; // 3. While true: while (true) { // 1. While result is not FILTER_REJECT and node has a child: while (result != NodeFilter::FILTER_REJECT && node->has_children()) { // 1. Set node to its first child. node = node->first_child(); // 2. Set result to the result of filtering node within this. auto result = TRY(filter(*node)); // 3. If result is FILTER_ACCEPT, then set this’s current to node and return node. if (result == NodeFilter::FILTER_ACCEPT) { m_current = *node; return node; } } // 2. Let sibling be null. RefPtr sibling = nullptr; // 3. Let temporary be node. RefPtr temporary = node; // 4. While temporary is non-null: while (temporary) { // 1. If temporary is this’s root, then return null. if (temporary == m_root) return nullptr; // 2. Set sibling to temporary’s next sibling. sibling = temporary->next_sibling(); // 3. If sibling is non-null, then set node to sibling and break. if (sibling) { node = sibling; break; } // 4. Set temporary to temporary’s parent. temporary = temporary->parent(); } // 5. Set result to the result of filtering node within this. result = TRY(filter(*node)); // 6. If result is FILTER_ACCEPT, then set this’s current to node and return node. if (result == NodeFilter::FILTER_ACCEPT) { m_current = *node; return node; } } } // https://dom.spec.whatwg.org/#concept-node-filter JS::ThrowCompletionOr TreeWalker::filter(Node& node) { VERIFY(wrapper()); auto& global_object = wrapper()->global_object(); // 1. If traverser’s active flag is set, then throw an "InvalidStateError" DOMException. if (m_active) return JS::throw_completion(wrap(global_object, InvalidStateError::create("NodeIterator is already active"))); // 2. Let n be node’s nodeType attribute value − 1. auto n = node.node_type() - 1; // 3. If the nth bit (where 0 is the least significant bit) of traverser’s whatToShow is not set, then return FILTER_SKIP. if (!(m_what_to_show & (1u << n))) return NodeFilter::FILTER_SKIP; // 4. If traverser’s filter is null, then return FILTER_ACCEPT. if (!m_filter) return NodeFilter::FILTER_ACCEPT; // 5. Set traverser’s active flag. m_active = true; // 6. Let result be the return value of call a user object’s operation with traverser’s filter, "acceptNode", and « node ». // If this throws an exception, then unset traverser’s active flag and rethrow the exception. auto result = Bindings::IDL::call_user_object_operation(m_filter->callback(), "acceptNode", {}, wrap(global_object, node)); if (result.is_abrupt()) { m_active = false; return result; } // 7. Unset traverser’s active flag. m_active = false; // 8. Return result. auto result_value = TRY(result.value()->to_i32(global_object)); return static_cast(result_value); } // https://dom.spec.whatwg.org/#concept-traverse-children JS::ThrowCompletionOr> TreeWalker::traverse_children(ChildTraversalType type) { // 1. Let node be walker’s current. RefPtr node = m_current; // 2. Set node to node’s first child if type is first, and node’s last child if type is last. node = type == ChildTraversalType::First ? node->first_child() : node->last_child(); // 3. While node is non-null: while (node) { // 1. Let result be the result of filtering node within walker. auto result = TRY(filter(*node)); // 2. If result is FILTER_ACCEPT, then set walker’s current to node and return node. if (result == NodeFilter::FILTER_ACCEPT) { m_current = *node; return node; } // 3. If result is FILTER_SKIP, then: if (result == NodeFilter::FILTER_SKIP) { // 1. Let child be node’s first child if type is first, and node’s last child if type is last. RefPtr child = type == ChildTraversalType::First ? node->first_child() : node->last_child(); // 2. If child is non-null, then set node to child and continue. if (child) { node = child.release_nonnull(); continue; } } // 4. While node is non-null: while (node) { // 1. Let sibling be node’s next sibling if type is first, and node’s previous sibling if type is last. RefPtr sibling = type == ChildTraversalType::First ? node->next_sibling() : node->previous_sibling(); // 2. If sibling is non-null, then set node to sibling and break. if (sibling) { node = sibling.release_nonnull(); break; } // 3. Let parent be node’s parent. RefPtr parent = node->parent(); // 4. If parent is null, walker’s root, or walker’s current, then return null. if (!parent || parent == m_root || parent == m_current) return nullptr; // 5. Set node to parent. node = parent.release_nonnull(); } } // 4. Return null. return nullptr; } // https://dom.spec.whatwg.org/#concept-traverse-siblings JS::ThrowCompletionOr> TreeWalker::traverse_siblings(SiblingTraversalType type) { // 1. Let node be walker’s current. RefPtr node = m_current; // 2. If node is root, then return null. if (node == m_root) return nullptr; // 3. While true: while (true) { // 1. Let sibling be node’s next sibling if type is next, and node’s previous sibling if type is previous. RefPtr sibling = type == SiblingTraversalType::Next ? node->next_sibling() : node->previous_sibling(); // 2. While sibling is non-null: while (sibling) { // 1. Set node to sibling. node = sibling; // 2. Let result be the result of filtering node within walker. auto result = TRY(filter(*node)); // 3. If result is FILTER_ACCEPT, then set walker’s current to node and return node. if (result == NodeFilter::FILTER_ACCEPT) { m_current = *node; return node; } // 4. Set sibling to node’s first child if type is next, and node’s last child if type is previous. sibling = type == SiblingTraversalType::Next ? node->first_child() : node->last_child(); // 5. If result is FILTER_REJECT or sibling is null, then set sibling to node’s next sibling if type is next, and node’s previous sibling if type is previous. if (result == NodeFilter::FILTER_REJECT || !sibling) sibling = type == SiblingTraversalType::Next ? node->next_sibling() : node->previous_sibling(); } // 3. Set node to node’s parent. node = node->parent(); // 4. If node is null or walker’s root, then return null. if (!node || node == m_root) return nullptr; // 5. If the return value of filtering node within walker is FILTER_ACCEPT, then return null. if (TRY(filter(*node)) == NodeFilter::FILTER_ACCEPT) return nullptr; } } }