/** * This file is part of the DOM implementation for KDE. * * Copyright (C) 1999 Lars Knoll (knoll@kde.org) * (C) 1999 Antti Koivisto (koivisto@kde.org) * (C) 2001 Dirk Mueller (mueller@kde.org) * Copyright (C) 2004, 2005, 2006 Apple Computer, Inc. * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Library General Public * License as published by the Free Software Foundation; either * version 2 of the License, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Library General Public License for more details. * * You should have received a copy of the GNU Library General Public License * along with this library; see the file COPYING.LIB. If not, write to * the Free Software Foundation, Inc., 59 Temple Place - Suite 330, * Boston, MA 02111-1307, USA. */ #include "config.h" #include "Node.h" #include "ChildNodeList.h" #include "DOMImplementation.h" #include "Document.h" #include "ExceptionCode.h" #include "Frame.h" #include "NamedAttrMap.h" #include "Text.h" #include "htmlediting.h" #include "HTMLNames.h" #include "kjs_binding.h" #include "RenderObject.h" #include "TextStream.h" #include #include "HTMLElement.h" namespace WebCore { using namespace HTMLNames; /** * NodeList which lists all Nodes in a document with a given tag name */ class TagNodeList : public NodeList { public: TagNodeList(Node *n, const AtomicString& namespaceURI, const AtomicString& localName); // DOM methods overridden from parent classes virtual unsigned length() const; virtual Node *item (unsigned index) const; // Other methods (not part of DOM) protected: virtual bool nodeMatches(Node *testNode) const; AtomicString m_namespaceURI; AtomicString m_localName; }; TagNodeList::TagNodeList(Node *n, const AtomicString& namespaceURI, const AtomicString& localName) : NodeList(n), m_namespaceURI(namespaceURI), m_localName(localName) { } unsigned TagNodeList::length() const { return recursiveLength(); } Node *TagNodeList::item(unsigned index) const { return recursiveItem(index); } bool TagNodeList::nodeMatches(Node *testNode) const { if (!testNode->isElementNode()) return false; if (m_namespaceURI != starAtom && m_namespaceURI != testNode->namespaceURI()) return false; return m_localName == starAtom || m_localName == testNode->localName(); } #ifndef NDEBUG struct NodeImplCounter { static int count; ~NodeImplCounter() { if (count != 0) fprintf(stderr, "LEAK: %d Node\n", count); } }; int NodeImplCounter::count = 0; static NodeImplCounter nodeImplCounter; #endif Node::Node(Document *doc) : m_document(doc), m_previous(0), m_next(0), m_renderer(0), m_nodeLists(0), m_tabIndex(0), m_hasId(false), m_hasClass(false), m_hasStyle(false), m_attached(false), m_changed(false), m_hasChangedChild(false), m_inDocument(false), m_isLink(false), m_specified(false), m_focused(false), m_active(false), m_hovered(false), m_inActiveChain(false), m_styleElement(false), m_implicit(false), m_inDetach(false) { #ifndef NDEBUG ++NodeImplCounter::count; #endif } void Node::setDocument(Document *doc) { if (inDocument()) return; m_document = doc; } Node::~Node() { #ifndef NDEBUG --NodeImplCounter::count; #endif if (renderer()) detach(); delete m_nodeLists; if (m_previous) m_previous->setNextSibling(0); if (m_next) m_next->setPreviousSibling(0); } String Node::nodeValue() const { return String(); } void Node::setNodeValue( const String &/*_nodeValue*/, ExceptionCode& ec) { // NO_MODIFICATION_ALLOWED_ERR: Raised when the node is readonly if (isReadOnlyNode()) { ec = NO_MODIFICATION_ALLOWED_ERR; return; } // be default nodeValue is null, so setting it has no effect } PassRefPtr Node::childNodes() { return new ChildNodeList(this); } Node *Node::firstChild() const { return 0; } Node *Node::lastChild() const { return 0; } Node *Node::lastDescendant() const { Node *n = const_cast(this); while (n && n->lastChild()) n = n->lastChild(); return n; } Node* Node::firstDescendant() const { Node *n = const_cast(this); while (n && n->firstChild()) n = n->firstChild(); return n; } bool Node::insertBefore(PassRefPtr, Node*, ExceptionCode& ec) { ec = HIERARCHY_REQUEST_ERR; return false; } bool Node::replaceChild(PassRefPtr, Node*, ExceptionCode& ec) { ec = HIERARCHY_REQUEST_ERR; return false; } bool Node::removeChild(Node*, ExceptionCode& ec) { ec = NOT_FOUND_ERR; return false; } bool Node::appendChild(PassRefPtr, ExceptionCode& ec) { ec = HIERARCHY_REQUEST_ERR; return false; } void Node::remove(ExceptionCode& ec) { ref(); if (Node *p = parentNode()) p->removeChild(this, ec); else ec = HIERARCHY_REQUEST_ERR; deref(); } bool Node::hasChildNodes( ) const { return false; } void Node::normalize () { ExceptionCode ec = 0; Node *child = firstChild(); if (isElementNode()) { // Normalize any attribute children we might have Element *element = static_cast(this); NamedAttrMap *attrMap = element->attributes(); if (attrMap) { unsigned numAttrs = attrMap->length(); for (unsigned i = 0; i < numAttrs; i++) { Attribute *attribute = attrMap->attributeItem(i); Attr *attr = attribute->attr(); if (attr) attr->normalize(); } } } // Recursively go through the subtree beneath us, normalizing all nodes. In the case // where there are two adjacent text nodes, they are merged together while (child) { Node *nextChild = child->nextSibling(); if (nextChild && child->nodeType() == TEXT_NODE && nextChild->nodeType() == TEXT_NODE) { // Current child and the next one are both text nodes... merge them Text *currentText = static_cast(child); Text *nextText = static_cast(nextChild); currentText->appendData(nextText->data(),ec); if (ec) return; nextChild->remove(ec); if (ec) return; } else { child->normalize(); child = nextChild; } } // Check if we have a single empty text node left and remove it if so child = firstChild(); if (child && !child->nextSibling() && child->isTextNode()) { Text *text = static_cast(child); if (text->data().isEmpty()) child->remove(ec); } } const AtomicString& Node::prefix() const { // For nodes other than elements and attributes, the prefix is always null return nullAtom; } void Node::setPrefix(const AtomicString &/*_prefix*/, ExceptionCode& ec) { // The spec says that for nodes other than elements and attributes, prefix is always null. // It does not say what to do when the user tries to set the prefix on another type of // node, however mozilla throws a NAMESPACE_ERR exception ec = NAMESPACE_ERR; } const AtomicString& Node::localName() const { return emptyAtom; } const AtomicString& Node::namespaceURI() const { return nullAtom; } ContainerNode* Node::addChild(PassRefPtr) { return 0; } bool Node::isContentEditable() const { return parent() && parent()->isContentEditable(); } bool Node::isContentRichlyEditable() const { Node* root = rootEditableElement(); return root && root->renderer() && root->renderer()->style()->userModify() != READ_WRITE_PLAINTEXT_ONLY; } IntRect Node::getRect() const { int _x, _y; if (renderer() && renderer()->absolutePosition(_x, _y)) return IntRect( _x, _y, renderer()->width(), renderer()->height() + renderer()->borderTopExtra() + renderer()->borderBottomExtra()); return IntRect(); } void Node::setChanged(bool b) { if (b && !attached()) // changed compared to what? return; m_changed = b; if ( b ) { Node *p = parentNode(); while ( p ) { p->setHasChangedChild( true ); p = p->parentNode(); } document()->setDocumentChanged(true); } } bool Node::isFocusable() const { return false; } bool Node::isKeyboardFocusable() const { return isFocusable(); } bool Node::isMouseFocusable() const { return isFocusable(); } unsigned Node::nodeIndex() const { Node *_tempNode = previousSibling(); unsigned count=0; for( count=0; _tempNode; count++ ) _tempNode = _tempNode->previousSibling(); return count; } void Node::registerNodeList(NodeList* list) { if (!m_nodeLists) m_nodeLists = new NodeListSet; m_nodeLists->add(list); } void Node::unregisterNodeList(NodeList* list) { if (!m_nodeLists) return; m_nodeLists->remove(list); } void Node::notifyLocalNodeListsAttributeChanged() { if (!m_nodeLists) return; NodeListSet::iterator end = m_nodeLists->end(); for (NodeListSet::iterator i = m_nodeLists->begin(); i != end; ++i) (*i)->rootNodeAttributeChanged(); } void Node::notifyNodeListsAttributeChanged() { for (Node *n = this; n; n = n->parentNode()) n->notifyLocalNodeListsAttributeChanged(); } void Node::notifyLocalNodeListsChildrenChanged() { if (!m_nodeLists) return; NodeListSet::iterator end = m_nodeLists->end(); for (NodeListSet::iterator i = m_nodeLists->begin(); i != end; ++i) (*i)->rootNodeChildrenChanged(); } void Node::notifyNodeListsChildrenChanged() { for (Node *n = this; n; n = n->parentNode()) n->notifyLocalNodeListsChildrenChanged(); } unsigned Node::childNodeCount() const { return 0; } Node *Node::childNode(unsigned /*index*/) const { return 0; } Node *Node::traverseNextNode(const Node *stayWithin) const { if (firstChild()) { assert(!stayWithin || firstChild()->isAncestor(stayWithin)); return firstChild(); } if (this == stayWithin) return 0; if (nextSibling()) { assert(!stayWithin || nextSibling()->isAncestor(stayWithin)); return nextSibling(); } const Node *n = this; while (n && !n->nextSibling() && (!stayWithin || n->parentNode() != stayWithin)) n = n->parentNode(); if (n) { assert(!stayWithin || !n->nextSibling() || n->nextSibling()->isAncestor(stayWithin)); return n->nextSibling(); } return 0; } Node *Node::traverseNextSibling(const Node *stayWithin) const { if (this == stayWithin) return 0; if (nextSibling()) { assert(!stayWithin || nextSibling()->isAncestor(stayWithin)); return nextSibling(); } const Node *n = this; while (n && !n->nextSibling() && (!stayWithin || n->parentNode() != stayWithin)) n = n->parentNode(); if (n) { assert(!stayWithin || !n->nextSibling() || n->nextSibling()->isAncestor(stayWithin)); return n->nextSibling(); } return 0; } Node *Node::traversePreviousNode(const Node *stayWithin) const { if (this == stayWithin) return 0; if (previousSibling()) { Node *n = previousSibling(); while (n->lastChild()) n = n->lastChild(); return n; } return parentNode(); } Node *Node::traversePreviousNodePostOrder(const Node *stayWithin) const { if (lastChild()) { assert(!stayWithin || lastChild()->isAncestor(stayWithin)); return lastChild(); } if (this == stayWithin) return 0; if (previousSibling()) { assert(!stayWithin || previousSibling()->isAncestor(stayWithin)); return previousSibling(); } const Node *n = this; while (n && !n->previousSibling() && (!stayWithin || n->parentNode() != stayWithin)) n = n->parentNode(); if (n) { assert(!stayWithin || !n->previousSibling() || n->previousSibling()->isAncestor(stayWithin)); return n->previousSibling(); } return 0; } void Node::checkSetPrefix(const AtomicString &_prefix, ExceptionCode& ec) { // Perform error checking as required by spec for setting Node.prefix. Used by // Element::setPrefix() and Attr::setPrefix() // FIXME: Implement support for INVALID_CHARACTER_ERR: Raised if the specified prefix contains an illegal character. // NO_MODIFICATION_ALLOWED_ERR: Raised if this node is readonly. if (isReadOnlyNode()) { ec = NO_MODIFICATION_ALLOWED_ERR; return; } // FIXME: Implement NAMESPACE_ERR: - Raised if the specified prefix is malformed // We have to comment this out, since it's used for attributes and tag names, and we've only // switched one over. /* // - if the namespaceURI of this node is null, // - if the specified prefix is "xml" and the namespaceURI of this node is different from // "http://www.w3.org/XML/1998/namespace", // - if this node is an attribute and the specified prefix is "xmlns" and // the namespaceURI of this node is different from "http://www.w3.org/2000/xmlns/", // - or if this node is an attribute and the qualifiedName of this node is "xmlns" [Namespaces]. if ((namespacePart(id()) == noNamespace && id() > ID_LAST_TAG) || (_prefix == "xml" && String(document()->namespaceURI(id())) != "http://www.w3.org/XML/1998/namespace")) { ec = NAMESPACE_ERR; return; }*/ } void Node::checkAddChild(Node *newChild, ExceptionCode& ec) { // Perform error checking as required by spec for adding a new child. Used by // appendChild(), replaceChild() and insertBefore() // Not mentioned in spec: throw NOT_FOUND_ERR if newChild is null if (!newChild) { ec = NOT_FOUND_ERR; return; } // NO_MODIFICATION_ALLOWED_ERR: Raised if this node is readonly if (isReadOnlyNode()) { ec = NO_MODIFICATION_ALLOWED_ERR; return; } bool shouldAdoptChild = false; // WRONG_DOCUMENT_ERR: Raised if newChild was created from a different document than the one that // created this node. // We assume that if newChild is a DocumentFragment, all children are created from the same document // as the fragment itself (otherwise they could not have been added as children) if (newChild->document() != document()) { // but if the child is not in a document yet then loosen the // restriction, so that e.g. creating an element with the Option() // constructor and then adding it to a different document works, // as it does in Mozilla and Mac IE. if (!newChild->inDocument()) { shouldAdoptChild = true; } else { ec = WRONG_DOCUMENT_ERR; return; } } // HIERARCHY_REQUEST_ERR: Raised if this node is of a type that does not allow children of the type of the // newChild node, or if the node to append is one of this node's ancestors. // check for ancestor/same node if (newChild == this || isAncestor(newChild)) { ec = HIERARCHY_REQUEST_ERR; return; } if (newChild->nodeType() != DOCUMENT_FRAGMENT_NODE) { if (!childTypeAllowed(newChild->nodeType())) { ec = HIERARCHY_REQUEST_ERR; return; } } else { for (Node *n = newChild->firstChild(); n; n = n->nextSibling()) { if (!childTypeAllowed(n->nodeType())) { ec = HIERARCHY_REQUEST_ERR; return; } } } // change the document pointer of newChild and all of its children to be the new document if (shouldAdoptChild) { for (Node* node = newChild; node; node = node->traverseNextNode(newChild)) { KJS::ScriptInterpreter::updateDOMNodeDocument(node, node->document(), document()); node->setDocument(document()); } } } bool Node::isAncestor(const Node *other) const { // Return true if other is an ancestor of this, otherwise false if (!other) return false; for (const Node *n = parentNode(); n; n = n->parentNode()) { if (n == other) return true; } return false; } bool Node::childAllowed( Node *newChild ) { return childTypeAllowed(newChild->nodeType()); } Node::StyleChange Node::diff( RenderStyle *s1, RenderStyle *s2 ) const { // FIXME: The behavior of this function is just totally wrong. It doesn't handle // explicit inheritance of non-inherited properties and so you end up not re-resolving // style in cases where you need to. StyleChange ch = NoInherit; EDisplay display1 = s1 ? s1->display() : NONE; bool fl1 = s1 && s1->hasPseudoStyle(RenderStyle::FIRST_LETTER); EDisplay display2 = s2 ? s2->display() : NONE; bool fl2 = s2 && s2->hasPseudoStyle(RenderStyle::FIRST_LETTER); if (display1 != display2 || fl1 != fl2) ch = Detach; else if (!s1 || !s2) ch = Inherit; else if (*s1 == *s2) ch = NoChange; else if (s1->inheritedNotEqual(s2)) ch = Inherit; // If the pseudoStyles have changed, we want any StyleChange that is not NoChange // because setStyle will do the right thing with anything else. if (ch == NoChange && s1->hasPseudoStyle(RenderStyle::BEFORE)) { RenderStyle* ps2 = s2->getPseudoStyle(RenderStyle::BEFORE); if (!ps2) ch = NoInherit; else { RenderStyle* ps1 = s1->getPseudoStyle(RenderStyle::BEFORE); ch = ps1 && *ps1 == *ps2 ? NoChange : NoInherit; } } if (ch == NoChange && s1->hasPseudoStyle(RenderStyle::AFTER)) { RenderStyle* ps2 = s2->getPseudoStyle(RenderStyle::AFTER); if (!ps2) ch = NoInherit; else { RenderStyle* ps1 = s1->getPseudoStyle(RenderStyle::AFTER); ch = ps2 && *ps1 == *ps2 ? NoChange : NoInherit; } } return ch; } #ifndef NDEBUG void Node::dump(TextStream *stream, DeprecatedString ind) const { // ### implement dump() for all appropriate subclasses if (m_hasId) { *stream << " hasId"; } if (m_hasClass) { *stream << " hasClass"; } if (m_hasStyle) { *stream << " hasStyle"; } if (m_specified) { *stream << " specified"; } if (m_focused) { *stream << " focused"; } if (m_active) { *stream << " active"; } if (m_styleElement) { *stream << " styleElement"; } if (m_implicit) { *stream << " implicit"; } *stream << " tabIndex=" << m_tabIndex; *stream << endl; Node *child = firstChild(); while(child) { *stream << ind << child->nodeName().deprecatedString().ascii() << ": "; child->dump(stream,ind+" "); child = child->nextSibling(); } } #endif void Node::attach() { assert(!attached()); assert(!renderer() || (renderer()->style() && renderer()->parent())); document()->incDOMTreeVersion(); m_attached = true; } void Node::willRemove() { } void Node::detach() { m_inDetach = true; // assert(m_attached); if (renderer()) renderer()->destroy(); setRenderer(0); Document* doc = document(); if (m_hovered) doc->hoveredNodeDetached(this); if (m_inActiveChain) doc->activeChainNodeDetached(this); doc->incDOMTreeVersion(); m_active = false; m_hovered = false; m_inActiveChain = false; m_attached = false; m_inDetach = false; } void Node::insertedIntoDocument() { setInDocument(true); insertedIntoTree(false); } void Node::removedFromDocument() { setInDocument(false); removedFromTree(false); } void Node::childrenChanged() { } bool Node::isReadOnlyNode() { // Entity & Entity Reference nodes and their descendants are read-only Node *n = this; while (n) { if (n->nodeType() == ENTITY_NODE || n->nodeType() == ENTITY_REFERENCE_NODE) return true; n = n->parentNode(); } return false; } Node *Node::previousEditable() const { Node *node = previousLeafNode(); while (node) { if (node->isContentEditable()) return node; node = node->previousLeafNode(); } return 0; } // Offset specifies the child node to start at. If it is past // the last child, it specifies to start at next sibling. Node *Node::nextEditable(int offset) const { assert(offset>=0); Node *node; if (hasChildNodes()) node = (offset >= (int)childNodeCount()) ? nextSibling() : childNode(offset)->nextLeafNode(); else node = nextLeafNode(); while (node) { if (node->isContentEditable()) return node; node = node->nextLeafNode(); } return 0; } Node *Node::nextEditable() const { Node *node = nextLeafNode(); while (node) { if (node->isContentEditable()) return node; node = node->nextLeafNode(); } return 0; } RenderObject * Node::previousRenderer() { for (Node *n = previousSibling(); n; n = n->previousSibling()) { if (n->renderer()) return n->renderer(); } return 0; } RenderObject * Node::nextRenderer() { // Avoid an O(n^2) problem with this function by not checking for nextRenderer() when the parent element hasn't even // been attached yet. if (parent() && !parent()->attached()) return 0; for (Node *n = nextSibling(); n; n = n->nextSibling()) { if (n->renderer()) return n->renderer(); } return 0; } // FIXME: This code is used by editing. Seems like it could move over there and not pollute Node. Node *Node::previousNodeConsideringAtomicNodes() const { if (previousSibling()) { Node *n = previousSibling(); while (!isAtomicNode(n) && n->lastChild()) n = n->lastChild(); return n; } else if (parentNode()) { return parentNode(); } else { return 0; } } Node *Node::nextNodeConsideringAtomicNodes() const { if (!isAtomicNode(this) && firstChild()) return firstChild(); if (nextSibling()) return nextSibling(); const Node *n = this; while (n && !n->nextSibling()) n = n->parentNode(); if (n) return n->nextSibling(); return 0; } Node *Node::previousLeafNode() const { Node *node = previousNodeConsideringAtomicNodes(); while (node) { if (isAtomicNode(node)) return node; node = node->previousNodeConsideringAtomicNodes(); } return 0; } Node *Node::nextLeafNode() const { Node *node = nextNodeConsideringAtomicNodes(); while (node) { if (isAtomicNode(node)) return node; node = node->nextNodeConsideringAtomicNodes(); } return 0; } void Node::createRendererIfNeeded() { if (!document()->shouldCreateRenderers()) return; assert(!attached()); assert(!renderer()); Node *parent = parentNode(); assert(parent); RenderObject *parentRenderer = parent->renderer(); if (parentRenderer && parentRenderer->canHaveChildren() #if SVG_SUPPORT && parent->childShouldCreateRenderer(this) #endif ) { RenderStyle* style = styleForRenderer(parentRenderer); #ifndef KHTML_NO_XBL bool resolveStyle = false; if (document()->bindingManager()->loadBindings(this, style->bindingURIs(), true, &resolveStyle) && rendererIsNeeded(style)) { if (resolveStyle) { style->deref(document()->renderArena()); style = styleForRenderer(parentRenderer); } #else if (rendererIsNeeded(style)) { #endif setRenderer(createRenderer(document()->renderArena(), style)); if (renderer()) { renderer()->setStyle(style); parentRenderer->addChild(renderer(), nextRenderer()); } #ifndef KHTML_NO_XBL } // avoid confusing the change log code parser by having two close braces to match the two open braces above #else } #endif style->deref(document()->renderArena()); } } RenderStyle *Node::styleForRenderer(RenderObject *parent) { RenderStyle *style = parent->style(); style->ref(); return style; } bool Node::rendererIsNeeded(RenderStyle *style) { return (document()->documentElement() == this) || (style->display() != NONE); } RenderObject *Node::createRenderer(RenderArena *arena, RenderStyle *style) { assert(false); return 0; } RenderStyle* Node::renderStyle() const { return m_renderer ? m_renderer->style() : 0; } void Node::setRenderStyle(RenderStyle* s) { if (m_renderer) m_renderer->setStyle(s); } int Node::maxOffset() const { return 1; } // FIXME: Shouldn't these functions be in the editing code? Code that asks questions about HTML in the core DOM class // is obviously misplaced. int Node::caretMinOffset() const { return renderer() ? renderer()->caretMinOffset() : 0; } int Node::caretMaxOffset() const { return renderer() ? renderer()->caretMaxOffset() : 1; } unsigned Node::caretMaxRenderedOffset() const { return renderer() ? renderer()->caretMaxRenderedOffset() : 1; } int Node::previousOffset (int current) const { return renderer() ? renderer()->previousOffset(current) : current - 1; } int Node::nextOffset (int current) const { return renderer() ? renderer()->nextOffset(current) : current + 1; } Node* Node::shadowAncestorNode() { Node *n = this; while (n) { if (n->isShadowNode()) return n->shadowParentNode(); n = n->parentNode(); } return this; } bool Node::isBlockFlow() const { return renderer() && renderer()->isBlockFlow(); } bool Node::isBlockFlowOrBlockTable() const { return renderer() && (renderer()->isBlockFlow() || renderer()->isTable() && !renderer()->isInline()); } bool Node::isEditableBlock() const { return isContentEditable() && isBlockFlow(); } Element *Node::enclosingBlockFlowOrTableElement() const { Node *n = const_cast(this); if (isBlockFlowOrBlockTable()) return static_cast(n); while (1) { n = n->parentNode(); if (!n) break; if (n->isBlockFlowOrBlockTable() || n->hasTagName(bodyTag)) return static_cast(n); } return 0; } Element *Node::enclosingBlockFlowElement() const { Node *n = const_cast(this); if (isBlockFlow()) return static_cast(n); while (1) { n = n->parentNode(); if (!n) break; if (n->isBlockFlow() || n->hasTagName(bodyTag)) return static_cast(n); } return 0; } Element *Node::enclosingInlineElement() const { Node *n = const_cast(this); Node *p; while (1) { p = n->parentNode(); if (!p || p->isBlockFlow() || p->hasTagName(bodyTag)) return static_cast(n); // Also stop if any previous sibling is a block for (Node *sibling = n->previousSibling(); sibling; sibling = sibling->previousSibling()) { if (sibling->isBlockFlow()) return static_cast(n); } n = p; } ASSERT_NOT_REACHED(); return 0; } Element* Node::rootEditableElement() const { Element* result = 0; for (Node* n = const_cast(this); n && n->isContentEditable(); n = n->parentNode()) { if (n->isElementNode()) result = static_cast(n); if (n->hasTagName(bodyTag)) break; } return result; } bool Node::inSameRootEditableElement(Node *n) { return n ? rootEditableElement() == n->rootEditableElement() : false; } bool Node::inSameContainingBlockFlowElement(Node *n) { return n ? enclosingBlockFlowElement() == n->enclosingBlockFlowElement() : false; } // FIXME: End of obviously misplaced HTML editing functions. Try to move these out of Node. PassRefPtr Node::getElementsByTagName(const String& name) { return getElementsByTagNameNS("*", name); } PassRefPtr Node::getElementsByTagNameNS(const String &namespaceURI, const String &localName) { if (namespaceURI.isNull() || localName.isNull()) return 0; // FIXME: Who relies on getting 0 instead of a node list in this case? String name = localName; if (document()->isHTMLDocument()) name = localName.lower(); return new TagNodeList(this, AtomicString(namespaceURI), AtomicString(name)); } bool Node::willRespondToMouseMoveEvents() { return false; } bool Node::willRespondToMouseWheelEvents() { return false; } bool Node::willRespondToMouseClickEvents() { return isContentEditable(); } bool Node::isSupported(const String &feature, const String &version) { return DOMImplementation::instance()->hasFeature(feature, version); } Document *Node::ownerDocument() const { Document *doc = document(); return doc == this ? 0 : doc; } bool Node::hasAttributes() const { return false; } NamedAttrMap *Node::attributes() const { return 0; } bool Node::isEqualNode(Node *other) const { if (!other) return false; if (nodeType() != other->nodeType()) return false; if (nodeName() != other->nodeName()) return false; if (localName() != other->localName()) return false; if (namespaceURI() != other->namespaceURI()) return false; if (prefix() != other->prefix()) return false; if (nodeValue() != other->nodeValue()) return false; NamedAttrMap *attrs = attributes(); NamedAttrMap *otherAttrs = other->attributes(); if (!attrs && otherAttrs) return false; if (attrs && !attrs->mapsEquivalent(otherAttrs)) return false; Node *child = firstChild(); Node *otherChild = other->firstChild(); while (child) { if (!child->isEqualNode(otherChild)) return false; child = child->nextSibling(); otherChild = otherChild->nextSibling(); } if (otherChild) return false; // FIXME: For DocumentType nodes we should check equality on // the entities and notations NamedNodeMaps as well. return true; } bool Node::isDefaultNamespace(const String &namespaceURI) const { // Implemented according to // http://www.w3.org/TR/2004/REC-DOM-Level-3-Core-20040407/namespaces-algorithms.html#isDefaultNamespaceAlgo switch (nodeType()) { case ELEMENT_NODE: { const Element *elem = static_cast(this); if (elem->prefix().isNull()) return elem->namespaceURI() == namespaceURI; if (elem->hasAttributes()) { NamedAttrMap *attrs = elem->attributes(); for (unsigned i = 0; i < attrs->length(); i++) { Attribute *attr = attrs->attributeItem(i); if (attr->localName() == "xmlns") return attr->value() == namespaceURI; } } if (Element* ancestor = ancestorElement()) return ancestor->isDefaultNamespace(namespaceURI); return false; } case DOCUMENT_NODE: return static_cast (this)->documentElement()->isDefaultNamespace(namespaceURI); case ENTITY_NODE: case NOTATION_NODE: case DOCUMENT_TYPE_NODE: case DOCUMENT_FRAGMENT_NODE: return false; case ATTRIBUTE_NODE: { const Attr *attr = static_cast(this); if (attr->ownerElement()) return attr->ownerElement()->isDefaultNamespace(namespaceURI); return false; } default: if (Element* ancestor = ancestorElement()) return ancestor->isDefaultNamespace(namespaceURI); return false; } } String Node::lookupPrefix(const String &namespaceURI) const { // Implemented according to // http://www.w3.org/TR/2004/REC-DOM-Level-3-Core-20040407/namespaces-algorithms.html#lookupNamespacePrefixAlgo if (namespaceURI.isEmpty()) return String(); switch (nodeType()) { case ELEMENT_NODE: return lookupNamespacePrefix(namespaceURI, static_cast(this)); case DOCUMENT_NODE: return static_cast(this)->documentElement()->lookupPrefix(namespaceURI); case ENTITY_NODE: case NOTATION_NODE: case DOCUMENT_FRAGMENT_NODE: case DOCUMENT_TYPE_NODE: return String(); case ATTRIBUTE_NODE: { const Attr *attr = static_cast(this); if (attr->ownerElement()) return attr->ownerElement()->lookupPrefix(namespaceURI); return String(); } default: if (Element* ancestor = ancestorElement()) return ancestor->lookupPrefix(namespaceURI); return String(); } } String Node::lookupNamespaceURI(const String &prefix) const { // Implemented according to // http://www.w3.org/TR/2004/REC-DOM-Level-3-Core-20040407/namespaces-algorithms.html#lookupNamespaceURIAlgo if (!prefix.isNull() && prefix.isEmpty()) return String(); switch (nodeType()) { case ELEMENT_NODE: { const Element *elem = static_cast(this); if (!elem->namespaceURI().isNull() && elem->prefix() == prefix) return elem->namespaceURI(); if (elem->hasAttributes()) { NamedAttrMap *attrs = elem->attributes(); for (unsigned i = 0; i < attrs->length(); i++) { Attribute *attr = attrs->attributeItem(i); if (attr->prefix() == "xmlns" && attr->localName() == prefix) { if (!attr->value().isEmpty()) return attr->value(); return String(); } else if (attr->localName() == "xmlns" && prefix.isNull()) { if (!attr->value().isEmpty()) return attr->value(); return String(); } } } if (Element* ancestor = ancestorElement()) return ancestor->lookupNamespaceURI(prefix); return String(); } case DOCUMENT_NODE: return static_cast(this)->documentElement()->lookupNamespaceURI(prefix); case ENTITY_NODE: case NOTATION_NODE: case DOCUMENT_TYPE_NODE: case DOCUMENT_FRAGMENT_NODE: return String(); case ATTRIBUTE_NODE: { const Attr *attr = static_cast(this); if (attr->ownerElement()) return attr->ownerElement()->lookupNamespaceURI(prefix); else return String(); } default: if (Element* ancestor = ancestorElement()) return ancestor->lookupNamespaceURI(prefix); return String(); } } String Node::lookupNamespacePrefix(const String &_namespaceURI, const Element *originalElement) const { if (_namespaceURI.isNull()) return String(); if (originalElement->lookupNamespaceURI(prefix()) == _namespaceURI) return prefix(); if (hasAttributes()) { NamedAttrMap *attrs = attributes(); for (unsigned i = 0; i < attrs->length(); i++) { Attribute *attr = attrs->attributeItem(i); if (attr->prefix() == "xmlns" && attr->value() == _namespaceURI && originalElement->lookupNamespaceURI(attr->localName()) == _namespaceURI) return attr->localName(); } } if (Element* ancestor = ancestorElement()) return ancestor->lookupNamespacePrefix(_namespaceURI, originalElement); return String(); } String Node::textContent(bool convertBRsToNewlines) const { switch (nodeType()) { case TEXT_NODE: case CDATA_SECTION_NODE: case COMMENT_NODE: case PROCESSING_INSTRUCTION_NODE: return nodeValue(); case ELEMENT_NODE: if (hasTagName(brTag) && convertBRsToNewlines) return "\n"; case ATTRIBUTE_NODE: case ENTITY_NODE: case ENTITY_REFERENCE_NODE: case DOCUMENT_FRAGMENT_NODE: { String s = ""; for (Node *child = firstChild(); child; child = child->nextSibling()) { if (child->nodeType() == COMMENT_NODE || child->nodeType() == PROCESSING_INSTRUCTION_NODE) continue; s += child->textContent(convertBRsToNewlines); } return s; } case DOCUMENT_NODE: case DOCUMENT_TYPE_NODE: case NOTATION_NODE: default: return String(); } } void Node::setTextContent(const String &text, ExceptionCode& ec) { switch (nodeType()) { case TEXT_NODE: case CDATA_SECTION_NODE: case COMMENT_NODE: case PROCESSING_INSTRUCTION_NODE: setNodeValue(text, ec); break; case ELEMENT_NODE: case ATTRIBUTE_NODE: case ENTITY_NODE: case ENTITY_REFERENCE_NODE: case DOCUMENT_FRAGMENT_NODE: { ContainerNode *container = static_cast(this); container->removeChildren(); if (!text.isEmpty()) appendChild(document()->createTextNode(text), ec); break; } case DOCUMENT_NODE: case DOCUMENT_TYPE_NODE: case NOTATION_NODE: default: // Do nothing break; } } Element* Node::ancestorElement() const { // In theory, there can be EntityReference nodes between elements, but this is currently not supported. for (Node* n = parentNode(); n; n = n->parentNode()) { if (n->isElementNode()) return static_cast(n); } return 0; } bool Node::offsetInCharacters() const { return false; } #ifndef NDEBUG static void appendAttributeDesc(const Node *node, String &string, const QualifiedName& name, DeprecatedString attrDesc) { if (node->isElementNode()) { String attr = static_cast(node)->getAttribute(name); if (!attr.isEmpty()) { string += attrDesc; string += attr; } } } void Node::showNode(const char* prefix) const { if (!prefix) prefix = ""; if (isTextNode()) { DeprecatedString value = nodeValue().deprecatedString(); value.replace('\\', "\\\\"); value.replace('\n', "\\n"); fprintf(stderr, "%s%s\t%p \"%s\"\n", prefix, nodeName().deprecatedString().utf8().data(), this, value.utf8().data()); } else { String attrs = ""; appendAttributeDesc(this, attrs, classAttr, " CLASS="); appendAttributeDesc(this, attrs, styleAttr, " STYLE="); fprintf(stderr, "%s%s\t%p%s\n", prefix, nodeName().deprecatedString().utf8().data(), this, attrs.deprecatedString().ascii()); } } void Node::showTreeForThis() const { showTreeAndMark(this, "*"); } void Node::showTreeAndMark(const Node* markedNode1, const char* markedLabel1, const Node* markedNode2, const char * markedLabel2) const { const Node* rootNode; const Node* node = this; while (node->parentNode() && !node->hasTagName(bodyTag)) node = node->parentNode(); rootNode = node; for (node = rootNode; node; node = node->traverseNextNode()) { if (node == markedNode1) fprintf(stderr, "%s", markedLabel1); if (node == markedNode2) fprintf(stderr, "%s", markedLabel2); for (const Node* tmpNode = node; tmpNode && tmpNode != rootNode; tmpNode = tmpNode->parentNode()) fprintf(stderr, "\t"); node->showNode(); } } void Node::formatForDebugger(char *buffer, unsigned length) const { String result; String s; s = nodeName(); if (s.length() == 0) result += ""; else result += s; strncpy(buffer, result.deprecatedString().latin1(), length - 1); } #endif } #ifndef NDEBUG void showTree(const WebCore::Node* node) { if (node) node->showTreeForThis(); } #endif