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/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
/* vim: set ts=8 sts=2 et sw=2 tw=80: */
/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
/*
* Base class for all DOM nodes.
*/
#include "nsINode.h"
#include "AccessCheck.h"
#include "jsapi.h"
#include "js/ForOfIterator.h" // JS::ForOfIterator
#include "js/JSON.h" // JS_ParseJSON
#include "mozAutoDocUpdate.h"
#include "mozilla/AsyncEventDispatcher.h"
#include "mozilla/ClearOnShutdown.h"
#include "mozilla/CORSMode.h"
#include "mozilla/EventDispatcher.h"
#include "mozilla/EventListenerManager.h"
#include "mozilla/HTMLEditor.h"
#include "mozilla/InternalMutationEvent.h"
#include "mozilla/Likely.h"
#include "mozilla/Maybe.h"
#include "mozilla/MemoryReporting.h"
#include "mozilla/PresShell.h"
#include "mozilla/ServoBindings.h"
#include "mozilla/Telemetry.h"
#include "mozilla/TextControlElement.h"
#include "mozilla/TextEditor.h"
#include "mozilla/TimeStamp.h"
#include "mozilla/dom/BindContext.h"
#include "mozilla/dom/CharacterData.h"
#include "mozilla/dom/ChildIterator.h"
#include "mozilla/dom/CustomElementRegistry.h"
#include "mozilla/dom/DebuggerNotificationBinding.h"
#include "mozilla/dom/DocumentType.h"
#include "mozilla/dom/Element.h"
#include "mozilla/dom/ElementBinding.h"
#include "mozilla/dom/Event.h"
#include "mozilla/dom/Exceptions.h"
#include "mozilla/dom/Link.h"
#include "mozilla/dom/HTMLImageElement.h"
#include "mozilla/dom/HTMLMediaElement.h"
#include "mozilla/dom/HTMLTemplateElement.h"
#include "mozilla/dom/MutationObservers.h"
#include "mozilla/dom/Selection.h"
#include "mozilla/dom/ShadowRoot.h"
#include "mozilla/dom/SVGUseElement.h"
#include "mozilla/dom/ScriptSettings.h"
#include "mozilla/dom/L10nOverlays.h"
#include "mozilla/ProfilerLabels.h"
#include "mozilla/StaticPrefs_layout.h"
#include "nsAttrValueOrString.h"
#include "nsCCUncollectableMarker.h"
#include "nsContentCreatorFunctions.h"
#include "nsContentList.h"
#include "nsContentUtils.h"
#include "nsCOMArray.h"
#include "nsCycleCollectionParticipant.h"
#include "mozilla/dom/Attr.h"
#include "nsDOMAttributeMap.h"
#include "nsDOMCID.h"
#include "nsDOMCSSAttrDeclaration.h"
#include "nsError.h"
#include "nsExpirationTracker.h"
#include "nsDOMMutationObserver.h"
#include "nsDOMString.h"
#include "nsDOMTokenList.h"
#include "nsFocusManager.h"
#include "nsFrameSelection.h"
#include "nsGenericHTMLElement.h"
#include "nsGkAtoms.h"
#include "nsIAnonymousContentCreator.h"
#include "nsAtom.h"
#include "nsIContentInlines.h"
#include "mozilla/dom/Document.h"
#include "mozilla/dom/DocumentInlines.h"
#include "nsIFrameInlines.h"
#include "mozilla/dom/NodeInfo.h"
#include "mozilla/dom/NodeInfoInlines.h"
#include "nsIScriptGlobalObject.h"
#include "nsView.h"
#include "nsViewManager.h"
#include "nsIWidget.h"
#include "nsLayoutUtils.h"
#include "nsNameSpaceManager.h"
#include "nsNodeInfoManager.h"
#include "nsObjectLoadingContent.h"
#include "nsPIDOMWindow.h"
#include "nsPresContext.h"
#include "nsPrintfCString.h"
#include "nsRange.h"
#include "nsString.h"
#include "nsStyleConsts.h"
#include "nsTextNode.h"
#include "nsUnicharUtils.h"
#include "nsWindowSizes.h"
#include "mozilla/Preferences.h"
#include "xpcpublic.h"
#include "HTMLLegendElement.h"
#include "nsWrapperCacheInlines.h"
#include "WrapperFactory.h"
#include <algorithm>
#include "nsGlobalWindowInner.h"
#include "GeometryUtils.h"
#include "nsIAnimationObserver.h"
#include "nsChildContentList.h"
#include "mozilla/dom/NodeBinding.h"
#include "mozilla/dom/BindingDeclarations.h"
#include "mozilla/dom/AncestorIterator.h"
#include "xpcprivate.h"
#include "XPathGenerator.h"
#ifdef ACCESSIBILITY
# include "mozilla/dom/AccessibleNode.h"
#endif
using namespace mozilla;
using namespace mozilla::dom;
static bool ShouldUseNACScope(const nsINode* aNode) {
return aNode->IsInNativeAnonymousSubtree();
}
static bool ShouldUseUAWidgetScope(const nsINode* aNode) {
return aNode->HasBeenInUAWidget();
}
void* nsINode::operator new(size_t aSize, nsNodeInfoManager* aManager) {
if (StaticPrefs::dom_arena_allocator_enabled_AtStartup()) {
MOZ_ASSERT(aManager, "nsNodeInfoManager needs to be initialized");
return aManager->Allocate(aSize);
}
return ::operator new(aSize);
}
void nsINode::operator delete(void* aPtr) { free_impl(aPtr); }
bool nsINode::IsInclusiveDescendantOf(const nsINode* aNode) const {
MOZ_ASSERT(aNode, "The node is nullptr.");
if (aNode == this) {
return true;
}
if (!aNode->HasFlag(NODE_MAY_HAVE_ELEMENT_CHILDREN)) {
return GetParentNode() == aNode;
}
for (nsINode* node : Ancestors(*this)) {
if (node == aNode) {
return true;
}
}
return false;
}
bool nsINode::IsInclusiveFlatTreeDescendantOf(const nsINode* aNode) const {
MOZ_ASSERT(aNode, "The node is nullptr.");
for (nsINode* node : InclusiveFlatTreeAncestors(*this)) {
if (node == aNode) {
return true;
}
}
return false;
}
bool nsINode::IsShadowIncludingInclusiveDescendantOf(
const nsINode* aNode) const {
MOZ_ASSERT(aNode, "The node is nullptr.");
if (this->GetComposedDoc() == aNode) {
return true;
}
const nsINode* node = this;
do {
if (node == aNode) {
return true;
}
node = node->GetParentOrShadowHostNode();
} while (node);
return false;
}
nsINode::nsSlots::nsSlots() : mWeakReference(nullptr) {}
nsINode::nsSlots::~nsSlots() {
if (mChildNodes) {
mChildNodes->InvalidateCacheIfAvailable();
}
if (mWeakReference) {
mWeakReference->NoticeNodeDestruction();
}
}
void nsINode::nsSlots::Traverse(nsCycleCollectionTraversalCallback& cb) {
NS_CYCLE_COLLECTION_NOTE_EDGE_NAME(cb, "mSlots->mChildNodes");
cb.NoteXPCOMChild(mChildNodes);
for (auto& object : mBoundObjects) {
NS_CYCLE_COLLECTION_NOTE_EDGE_NAME(cb, "mSlots->mBoundObjects[i]");
cb.NoteXPCOMChild(object.mObject);
}
}
static void ClearBoundObjects(nsINode::nsSlots& aSlots, nsINode& aNode) {
auto objects = std::move(aSlots.mBoundObjects);
for (auto& object : objects) {
if (object.mDtor) {
object.mDtor(object.mObject, &aNode);
}
}
MOZ_ASSERT(aSlots.mBoundObjects.IsEmpty());
}
void nsINode::nsSlots::Unlink(nsINode& aNode) {
if (mChildNodes) {
mChildNodes->InvalidateCacheIfAvailable();
ImplCycleCollectionUnlink(mChildNodes);
}
ClearBoundObjects(*this, aNode);
}
//----------------------------------------------------------------------
#ifdef MOZILLA_INTERNAL_API
nsINode::nsINode(already_AddRefed<mozilla::dom::NodeInfo>&& aNodeInfo)
: mNodeInfo(std::move(aNodeInfo)),
mParent(nullptr)
# ifndef BOOL_FLAGS_ON_WRAPPER_CACHE
,
mBoolFlags(0)
# endif
,
mChildCount(0),
mPreviousOrLastSibling(nullptr),
mSubtreeRoot(this),
mSlots(nullptr) {
SetIsOnMainThread();
}
#endif
nsINode::~nsINode() {
MOZ_ASSERT(!HasSlots(), "LastRelease was not called?");
MOZ_ASSERT(mSubtreeRoot == this, "Didn't restore state properly?");
}
#ifdef MOZ_DIAGNOSTIC_ASSERT_ENABLED
void nsINode::AssertInvariantsOnNodeInfoChange() {
MOZ_DIAGNOSTIC_ASSERT(!IsInComposedDoc());
if (nsCOMPtr<Link> link = do_QueryInterface(this)) {
MOZ_DIAGNOSTIC_ASSERT(!link->HasPendingLinkUpdate());
}
}
#endif
#ifdef DEBUG
void nsINode::AssertIsRootElementSlow(bool aIsRoot) const {
const bool isRootSlow = this == OwnerDoc()->GetRootElement();
MOZ_ASSERT(aIsRoot == isRootSlow);
}
#endif
void* nsINode::GetProperty(const nsAtom* aPropertyName,
nsresult* aStatus) const {
if (!HasProperties()) { // a fast HasFlag() test
if (aStatus) {
*aStatus = NS_PROPTABLE_PROP_NOT_THERE;
}
return nullptr;
}
return OwnerDoc()->PropertyTable().GetProperty(this, aPropertyName, aStatus);
}
nsresult nsINode::SetProperty(nsAtom* aPropertyName, void* aValue,
NSPropertyDtorFunc aDtor, bool aTransfer) {
nsresult rv = OwnerDoc()->PropertyTable().SetProperty(
this, aPropertyName, aValue, aDtor, nullptr, aTransfer);
if (NS_SUCCEEDED(rv)) {
SetFlags(NODE_HAS_PROPERTIES);
}
return rv;
}
void nsINode::RemoveProperty(const nsAtom* aPropertyName) {
OwnerDoc()->PropertyTable().RemoveProperty(this, aPropertyName);
}
void* nsINode::TakeProperty(const nsAtom* aPropertyName, nsresult* aStatus) {
return OwnerDoc()->PropertyTable().TakeProperty(this, aPropertyName, aStatus);
}
nsIContentSecurityPolicy* nsINode::GetCsp() const {
return OwnerDoc()->GetCsp();
}
nsINode::nsSlots* nsINode::CreateSlots() { return new nsSlots(); }
static const nsINode* GetClosestCommonInclusiveAncestorForRangeInSelection(
const nsINode* aNode) {
while (aNode &&
!aNode->IsClosestCommonInclusiveAncestorForRangeInSelection()) {
const bool isNodeInShadowTree =
StaticPrefs::dom_shadowdom_selection_across_boundary_enabled() &&
aNode->IsInShadowTree();
if (!aNode
->IsDescendantOfClosestCommonInclusiveAncestorForRangeInSelection() &&
!isNodeInShadowTree) {
return nullptr;
}
aNode = StaticPrefs::dom_shadowdom_selection_across_boundary_enabled()
? aNode->GetParentOrShadowHostNode()
: aNode->GetParentNode();
}
return aNode;
}
/**
* A Comparator suitable for mozilla::BinarySearchIf for searching a collection
* of nsRange* for an overlap of (mNode, mStartOffset) .. (mNode, mEndOffset).
*/
class IsItemInRangeComparator {
public:
// @param aStartOffset has to be less or equal to aEndOffset.
IsItemInRangeComparator(const nsINode& aNode, const uint32_t aStartOffset,
const uint32_t aEndOffset,
nsContentUtils::NodeIndexCache* aCache)
: mNode(aNode),
mStartOffset(aStartOffset),
mEndOffset(aEndOffset),
mCache(aCache) {
MOZ_ASSERT(aStartOffset <= aEndOffset);
}
int operator()(const AbstractRange* const aRange) const {
int32_t cmp = nsContentUtils::ComparePoints_Deprecated(
&mNode, mEndOffset, aRange->GetMayCrossShadowBoundaryStartContainer(),
aRange->MayCrossShadowBoundaryStartOffset(), nullptr, mCache);
if (cmp == 1) {
cmp = nsContentUtils::ComparePoints_Deprecated(
&mNode, mStartOffset, aRange->GetMayCrossShadowBoundaryEndContainer(),
aRange->MayCrossShadowBoundaryEndOffset(), nullptr, mCache);
if (cmp == -1) {
return 0;
}
return 1;
}
return -1;
}
private:
const nsINode& mNode;
const uint32_t mStartOffset;
const uint32_t mEndOffset;
nsContentUtils::NodeIndexCache* mCache;
};
bool nsINode::IsSelected(const uint32_t aStartOffset, const uint32_t aEndOffset,
SelectionNodeCache* aCache) const {
MOZ_ASSERT(aStartOffset <= aEndOffset);
const nsINode* n = GetClosestCommonInclusiveAncestorForRangeInSelection(this);
NS_ASSERTION(n || !IsMaybeSelected(),
"A node without a common inclusive ancestor for a range in "
"Selection is for sure not selected.");
// Collect the selection objects for potential ranges.
AutoTArray<Selection*, 1> ancestorSelections;
for (; n; n = GetClosestCommonInclusiveAncestorForRangeInSelection(
n->GetParentNode())) {
const LinkedList<AbstractRange>* ranges =
n->GetExistingClosestCommonInclusiveAncestorRanges();
if (!ranges) {
continue;
}
for (const AbstractRange* range : *ranges) {
MOZ_ASSERT(range->IsInAnySelection(),
"Why is this range registered with a node?");
// Looks like that IsInSelection() assert fails sometimes...
if (range->IsInAnySelection()) {
for (const WeakPtr<Selection>& selection : range->GetSelections()) {
if (selection && !ancestorSelections.Contains(selection)) {
ancestorSelections.AppendElement(selection);
}
}
}
}
}
if (aCache && aCache->MaybeCollectNodesAndCheckIfFullySelectedInAnyOf(
this, ancestorSelections)) {
return true;
}
nsContentUtils::NodeIndexCache cache;
IsItemInRangeComparator comparator{*this, aStartOffset, aEndOffset, &cache};
for (Selection* selection : ancestorSelections) {
// Binary search the sorted ranges in this selection.
// (Selection::GetRangeAt returns its ranges ordered).
size_t low = 0;
size_t high = selection->RangeCount();
while (high != low) {
size_t middle = low + (high - low) / 2;
const AbstractRange* const range = selection->GetAbstractRangeAt(middle);
int result = comparator(range);
if (result == 0) {
if (!range->Collapsed()) {
return true;
}
if (range->MayCrossShadowBoundary()) {
MOZ_ASSERT(range->IsDynamicRange(),
"range->MayCrossShadowBoundary() can only return true for "
"dynamic range");
StaticRange* crossBoundaryRange =
range->AsDynamicRange()->GetCrossShadowBoundaryRange();
MOZ_ASSERT(crossBoundaryRange);
if (!crossBoundaryRange->Collapsed()) {
return true;
}
}
const AbstractRange* middlePlus1;
const AbstractRange* middleMinus1;
// if node end > start of middle+1, result = 1
if (middle + 1 < high &&
(middlePlus1 = selection->GetAbstractRangeAt(middle + 1)) &&
nsContentUtils::ComparePoints_Deprecated(
this, aEndOffset, middlePlus1->GetStartContainer(),
middlePlus1->StartOffset(), nullptr, &cache) > 0) {
result = 1;
// if node start < end of middle - 1, result = -1
} else if (middle >= 1 &&
(middleMinus1 = selection->GetAbstractRangeAt(middle - 1)) &&
nsContentUtils::ComparePoints_Deprecated(
this, aStartOffset, middleMinus1->GetEndContainer(),
middleMinus1->EndOffset(), nullptr, &cache) < 0) {
result = -1;
} else {
break;
}
}
if (result < 0) {
high = middle;
} else {
low = middle + 1;
}
}
}
return false;
}
Element* nsINode::GetAnonymousRootElementOfTextEditor(
TextEditor** aTextEditor) {
if (aTextEditor) {
*aTextEditor = nullptr;
}
RefPtr<TextControlElement> textControlElement;
if (IsInNativeAnonymousSubtree()) {
textControlElement = TextControlElement::FromNodeOrNull(
GetClosestNativeAnonymousSubtreeRootParentOrHost());
} else {
textControlElement = TextControlElement::FromNode(this);
}
if (!textControlElement) {
return nullptr;
}
RefPtr<TextEditor> textEditor = textControlElement->GetTextEditor();
if (!textEditor) {
// The found `TextControlElement` may be an input element which is not a
// text control element. In this case, such element must not be in a
// native anonymous tree of a `TextEditor` so this node is not in any
// `TextEditor`.
return nullptr;
}
Element* rootElement = textEditor->GetRoot();
if (aTextEditor) {
textEditor.forget(aTextEditor);
}
return rootElement;
}
void nsINode::QueueDevtoolsAnonymousEvent(bool aIsRemove) {
MOZ_ASSERT(IsRootOfNativeAnonymousSubtree());
MOZ_ASSERT(OwnerDoc()->DevToolsAnonymousAndShadowEventsEnabled());
AsyncEventDispatcher* dispatcher = new AsyncEventDispatcher(
this, aIsRemove ? u"anonymousrootremoved"_ns : u"anonymousrootcreated"_ns,
CanBubble::eYes, ChromeOnlyDispatch::eYes, Composed::eYes);
dispatcher->PostDOMEvent();
}
nsINode* nsINode::GetRootNode(const GetRootNodeOptions& aOptions) {
if (aOptions.mComposed) {
if (Document* doc = GetComposedDoc()) {
return doc;
}
nsINode* node = this;
while (node) {
node = node->SubtreeRoot();
ShadowRoot* shadow = ShadowRoot::FromNode(node);
if (!shadow) {
break;
}
node = shadow->GetHost();
}
return node;
}
return SubtreeRoot();
}
nsIContent* nsINode::GetFirstChildOfTemplateOrNode() {
if (IsTemplateElement()) {
DocumentFragment* frag = static_cast<HTMLTemplateElement*>(this)->Content();
return frag->GetFirstChild();
}
return GetFirstChild();
}
nsINode* nsINode::SubtreeRoot() const {
auto RootOfNode = [](const nsINode* aStart) -> nsINode* {
const nsINode* node = aStart;
const nsINode* iter = node;
while ((iter = iter->GetParentNode())) {
node = iter;
}
return const_cast<nsINode*>(node);
};
// There are four cases of interest here. nsINodes that are really:
// 1. Document nodes - Are always in the document.
// 2.a nsIContent nodes not in a shadow tree - Are either in the document,
// or mSubtreeRoot is updated in BindToTree/UnbindFromTree.
// 2.b nsIContent nodes in a shadow tree - Are never in the document,
// ignore mSubtreeRoot and return the containing shadow root.
// 4. Attr nodes - Are never in the document, and mSubtreeRoot
// is always 'this' (as set in nsINode's ctor).
nsINode* node;
if (IsInUncomposedDoc()) {
node = OwnerDocAsNode();
} else if (IsContent()) {
ShadowRoot* containingShadow = AsContent()->GetContainingShadow();
node = containingShadow ? containingShadow : mSubtreeRoot;
if (!node) {
NS_WARNING("Using SubtreeRoot() on unlinked element?");
node = RootOfNode(this);
}
} else {
node = mSubtreeRoot;
}
MOZ_ASSERT(node, "Should always have a node here!");
#ifdef DEBUG
{
const nsINode* slowNode = RootOfNode(this);
MOZ_ASSERT(slowNode == node, "These should always be in sync!");
}
#endif
return node;
}
static nsIContent* GetRootForContentSubtree(nsIContent* aContent) {
NS_ENSURE_TRUE(aContent, nullptr);
// Special case for ShadowRoot because the ShadowRoot itself is
// the root. This is necessary to prevent selection from crossing
// the ShadowRoot boundary.
//
// FIXME(emilio): The NAC check should probably be done before this? We can
// have NAC inside shadow DOM.
if (ShadowRoot* containingShadow = aContent->GetContainingShadow()) {
return containingShadow;
}
if (nsIContent* nativeAnonRoot =
aContent->GetClosestNativeAnonymousSubtreeRoot()) {
return nativeAnonRoot;
}
if (Document* doc = aContent->GetUncomposedDoc()) {
return doc->GetRootElement();
}
return nsIContent::FromNode(aContent->SubtreeRoot());
}
nsIContent* nsINode::GetSelectionRootContent(PresShell* aPresShell,
bool aAllowCrossShadowBoundary) {
NS_ENSURE_TRUE(aPresShell, nullptr);
const bool isContent = IsContent();
if (!isContent && !IsDocument()) {
return nullptr;
}
if (isContent) {
if (GetComposedDoc() != aPresShell->GetDocument()) {
return nullptr;
}
if (AsContent()->HasIndependentSelection() ||
IsInNativeAnonymousSubtree()) {
// This node should be an inclusive descendant of input/textarea editor.
// In that case, the anonymous <div> for TextEditor should be always the
// selection root.
// FIXME: If Selection for the document is collapsed in <input> or
// <textarea>, returning anonymous <div> may make the callers confused.
// Perhaps, we should do this only when this is in the native anonymous
// subtree unless the callers explicitly want to retrieve the anonymous
// <div> from a text control element.
if (Element* anonymousDivElement =
GetAnonymousRootElementOfTextEditor()) {
return anonymousDivElement;
}
}
}
if (nsPresContext* presContext = aPresShell->GetPresContext()) {
if (nsContentUtils::GetHTMLEditor(presContext)) {
// When there is an HTMLEditor, selection root should be one of focused
// editing host, <body> or root of the (sub)tree which this node belong.
// If this node is in design mode or this node is not editable, selection
// root should be the <body> if this node is not in any subtrees and there
// is a <body> or the root of the shadow DOM if this node is in a shadow
// or the document element.
// XXX If this node is not connected, it seems that this should return
// nullptr because this node is not selectable.
if (!IsInComposedDoc() || IsInDesignMode() ||
!HasFlag(NODE_IS_EDITABLE)) {
Element* const bodyOrDocumentElement = [&]() -> Element* {
if (Element* const bodyElement = OwnerDoc()->GetBodyElement()) {
return bodyElement;
}
return OwnerDoc()->GetDocumentElement();
}();
NS_ENSURE_TRUE(bodyOrDocumentElement, nullptr);
return nsContentUtils::IsInSameAnonymousTree(this,
bodyOrDocumentElement)
? bodyOrDocumentElement
: GetRootForContentSubtree(AsContent());
}
// If this node is editable but not in the design mode, this is always an
// editable node in an editing host of contenteditable. In this case,
// let's use the editing host element as selection root.
MOZ_ASSERT(IsEditable());
MOZ_ASSERT(!IsInDesignMode());
MOZ_ASSERT(IsContent());
return static_cast<nsIContent*>(this)->GetEditingHost();
}
}
if (!isContent) {
return nullptr;
}
RefPtr<nsFrameSelection> fs = aPresShell->FrameSelection();
nsCOMPtr<nsIContent> content = fs->GetLimiter();
if (!content) {
content = fs->GetAncestorLimiter();
if (!content) {
Document* doc = aPresShell->GetDocument();
NS_ENSURE_TRUE(doc, nullptr);
content = doc->GetRootElement();
if (!content) return nullptr;
}
}
// This node might be in another subtree, if so, we should find this subtree's
// root. Otherwise, we can return the content simply.
NS_ENSURE_TRUE(content, nullptr);
if (!nsContentUtils::IsInSameAnonymousTree(this, content)) {
content = GetRootForContentSubtree(AsContent());
// Fixup for ShadowRoot because the ShadowRoot itself does not have a frame.
// Use the host as the root.
if (ShadowRoot* shadowRoot = ShadowRoot::FromNode(content)) {
content = shadowRoot->GetHost();
if (content && aAllowCrossShadowBoundary) {
content = content->GetSelectionRootContent(aPresShell,
aAllowCrossShadowBoundary);
}
}
}
return content;
}
nsINodeList* nsINode::ChildNodes() {
nsSlots* slots = Slots();
if (!slots->mChildNodes) {
slots->mChildNodes = IsAttr() ? new nsAttrChildContentList(this)
: new nsParentNodeChildContentList(this);
}
return slots->mChildNodes;
}
nsIContent* nsINode::GetLastChild() const {
return mFirstChild ? mFirstChild->mPreviousOrLastSibling : nullptr;
}
void nsINode::InvalidateChildNodes() {
MOZ_ASSERT(!IsAttr());
nsSlots* slots = GetExistingSlots();
if (!slots || !slots->mChildNodes) {
return;
}
auto childNodes =
static_cast<nsParentNodeChildContentList*>(slots->mChildNodes.get());
childNodes->InvalidateCache();
}
void nsINode::GetTextContentInternal(nsAString& aTextContent,
OOMReporter& aError) {
SetDOMStringToNull(aTextContent);
}
DocumentOrShadowRoot* nsINode::GetContainingDocumentOrShadowRoot() const {
if (IsInUncomposedDoc()) {
return OwnerDoc();
}
if (IsInShadowTree()) {
return AsContent()->GetContainingShadow();
}
return nullptr;
}
DocumentOrShadowRoot* nsINode::GetUncomposedDocOrConnectedShadowRoot() const {
if (IsInUncomposedDoc()) {
return OwnerDoc();
}
if (IsInComposedDoc() && IsInShadowTree()) {
return AsContent()->GetContainingShadow();
}
return nullptr;
}
mozilla::SafeDoublyLinkedList<nsIMutationObserver>*
nsINode::GetMutationObservers() {
return HasSlots() ? &GetExistingSlots()->mMutationObservers : nullptr;
}
void nsINode::LastRelease() {
if (nsSlots* slots = GetExistingSlots()) {
if (!slots->mMutationObservers.isEmpty()) {
for (auto iter = slots->mMutationObservers.begin();
iter != slots->mMutationObservers.end(); ++iter) {
iter->NodeWillBeDestroyed(this);
}
}
ClearBoundObjects(*slots, *this);
if (IsContent()) {
nsIContent* content = AsContent();
if (HTMLSlotElement* slot = content->GetManualSlotAssignment()) {
content->SetManualSlotAssignment(nullptr);
slot->RemoveManuallyAssignedNode(*content);
}
}
if (Element* element = Element::FromNode(this)) {
if (CustomElementData* data = element->GetCustomElementData()) {
data->Unlink();
}
}
delete slots;
mSlots = nullptr;
}
// Kill properties first since that may run external code, so we want to
// be in as complete state as possible at that time.
if (IsDocument()) {
// Delete all properties before tearing down the document. Some of the
// properties are bound to nsINode objects and the destructor functions of
// the properties may want to use the owner document of the nsINode.
AsDocument()->RemoveAllProperties();
AsDocument()->DropStyleSet();
} else {
if (HasProperties()) {
// Strong reference to the document so that deleting properties can't
// delete the document.
nsCOMPtr<Document> document = OwnerDoc();
document->RemoveAllPropertiesFor(this);
}
if (HasFlag(ADDED_TO_FORM)) {
if (auto* formControl = nsGenericHTMLFormControlElement::FromNode(this)) {
// Tell the form (if any) this node is going away. Don't
// notify, since we're being destroyed in any case.
formControl->ClearForm(true, true);
} else if (auto* imageElem = HTMLImageElement::FromNode(this)) {
imageElem->ClearForm(true);
}
}
if (HasFlag(NODE_HAS_LISTENERMANAGER)) {
#ifdef DEBUG
if (nsContentUtils::IsInitialized()) {
EventListenerManager* manager =
nsContentUtils::GetExistingListenerManagerForNode(this);
if (!manager) {
NS_ERROR(
"Huh, our bit says we have a listener manager list, "
"but there's nothing in the hash!?!!");
}
}
#endif
nsContentUtils::RemoveListenerManager(this);
UnsetFlags(NODE_HAS_LISTENERMANAGER);
}
if (Element* element = Element::FromNode(this)) {
element->ClearAttributes();
}
}
UnsetFlags(NODE_HAS_PROPERTIES);
ReleaseWrapper(this);
FragmentOrElement::RemoveBlackMarkedNode(this);
}
std::ostream& operator<<(std::ostream& aStream, const nsINode& aNode) {
nsAutoString elemDesc;
const nsINode* curr = &aNode;
while (curr) {
nsString id;
if (curr->IsElement()) {
curr->AsElement()->GetId(id);
}
if (!elemDesc.IsEmpty()) {
elemDesc = elemDesc + u"."_ns;
}
if (!curr->LocalName().IsEmpty()) {
elemDesc.Append(curr->LocalName());
} else {
elemDesc.Append(curr->NodeName());
}
if (!id.IsEmpty()) {
elemDesc = elemDesc + u"['"_ns + id + u"']"_ns;
}
if (curr->IsElement() &&
curr->AsElement()->HasAttr(nsGkAtoms::contenteditable)) {
nsAutoString val;
curr->AsElement()->GetAttr(nsGkAtoms::contenteditable, val);
elemDesc = elemDesc + u"[contenteditable=\""_ns + val + u"\"]"_ns;
}
if (curr->IsDocument() && curr->IsInDesignMode()) {
elemDesc.Append(u"[designMode=\"on\"]"_ns);
}
curr = curr->GetParentNode();
}
NS_ConvertUTF16toUTF8 str(elemDesc);
return aStream << str.get();
}
nsIContent* nsINode::DoGetShadowHost() const {
MOZ_ASSERT(IsShadowRoot());
return static_cast<const ShadowRoot*>(this)->GetHost();
}
ShadowRoot* nsINode::GetContainingShadow() const {
if (!IsInShadowTree()) {
return nullptr;
}
return AsContent()->GetContainingShadow();
}
Element* nsINode::GetContainingShadowHost() const {
if (ShadowRoot* shadow = GetContainingShadow()) {
return shadow->GetHost();
}
return nullptr;
}
SVGUseElement* nsINode::DoGetContainingSVGUseShadowHost() const {
MOZ_ASSERT(IsInShadowTree());
return SVGUseElement::FromNodeOrNull(GetContainingShadowHost());
}
void nsINode::GetNodeValueInternal(nsAString& aNodeValue) {
SetDOMStringToNull(aNodeValue);
}
static const char* NodeTypeAsString(nsINode* aNode) {
static const char* NodeTypeStrings[] = {
"", // No nodes of type 0
"an Element",
"an Attribute",
"a Text",
"a CDATASection",
"an EntityReference",
"an Entity",
"a ProcessingInstruction",
"a Comment",
"a Document",
"a DocumentType",
"a DocumentFragment",
"a Notation",
};
static_assert(std::size(NodeTypeStrings) == nsINode::MAX_NODE_TYPE + 1,
"Max node type out of range for our array");
uint16_t nodeType = aNode->NodeType();
MOZ_RELEASE_ASSERT(nodeType < std::size(NodeTypeStrings),
"Uknown out-of-range node type");
return NodeTypeStrings[nodeType];
}
nsINode* nsINode::RemoveChild(nsINode& aOldChild, ErrorResult& aError) {
if (!aOldChild.IsContent()) {
// aOldChild can't be one of our children.
aError.ThrowNotFoundError(
"The node to be removed is not a child of this node");
return nullptr;
}
if (aOldChild.GetParentNode() == this) {
nsContentUtils::MaybeFireNodeRemoved(&aOldChild, this);
}
// Check again, we may not be the child's parent anymore.
// Can be triggered by dom/base/crashtests/293388-1.html
if (aOldChild.IsRootOfNativeAnonymousSubtree() ||
aOldChild.GetParentNode() != this) {
// aOldChild isn't one of our children.
aError.ThrowNotFoundError(
"The node to be removed is not a child of this node");
return nullptr;
}
RemoveChildNode(aOldChild.AsContent(), true);
return &aOldChild;
}
void nsINode::Normalize() {
// First collect list of nodes to be removed
AutoTArray<nsCOMPtr<nsIContent>, 50> nodes;
bool canMerge = false;
for (nsIContent* node = this->GetFirstChild(); node;
node = node->GetNextNode(this)) {
if (node->NodeType() != TEXT_NODE) {
canMerge = false;
continue;
}
if (canMerge || node->TextLength() == 0) {
// No need to touch canMerge. That way we can merge across empty
// textnodes if and only if the node before is a textnode
nodes.AppendElement(node);
} else {
canMerge = true;
}
// If there's no following sibling, then we need to ensure that we don't
// collect following siblings of our (grand)parent as to-be-removed
canMerge = canMerge && !!node->GetNextSibling();
}
if (nodes.IsEmpty()) {
return;
}
// We're relying on mozAutoSubtreeModified to keep the doc alive here.
RefPtr<Document> doc = OwnerDoc();
// Batch possible DOMSubtreeModified events.
mozAutoSubtreeModified subtree(doc, nullptr);
// Fire all DOMNodeRemoved events. Optimize the common case of there being
// no listeners
bool hasRemoveListeners = nsContentUtils::HasMutationListeners(
doc, NS_EVENT_BITS_MUTATION_NODEREMOVED);
if (hasRemoveListeners) {
for (nsCOMPtr<nsIContent>& node : nodes) {
// Node may have already been removed.
if (nsCOMPtr<nsINode> parentNode = node->GetParentNode()) {
nsContentUtils::MaybeFireNodeRemoved(MOZ_KnownLive(node), parentNode);
}
}
}
mozAutoDocUpdate batch(doc, true);
// Merge and remove all nodes
nsAutoString tmpStr;
for (uint32_t i = 0; i < nodes.Length(); ++i) {
nsIContent* node = nodes[i];
// Merge with previous node unless empty
const nsTextFragment* text = node->GetText();
if (text->GetLength()) {
nsIContent* target = node->GetPreviousSibling();
NS_ASSERTION(
(target && target->NodeType() == TEXT_NODE) || hasRemoveListeners,
"Should always have a previous text sibling unless "
"mutation events messed us up");
if (!hasRemoveListeners || (target && target->NodeType() == TEXT_NODE)) {
nsTextNode* t = static_cast<nsTextNode*>(target);
if (text->Is2b()) {
t->AppendTextForNormalize(text->Get2b(), text->GetLength(), true,
node);
} else {
tmpStr.Truncate();
text->AppendTo(tmpStr);
t->AppendTextForNormalize(tmpStr.get(), tmpStr.Length(), true, node);
}
}
}
// Remove node
nsCOMPtr<nsINode> parent = node->GetParentNode();
NS_ASSERTION(parent || hasRemoveListeners,
"Should always have a parent unless "
"mutation events messed us up");
if (parent) {
parent->RemoveChildNode(node, true);
}
}
}
nsresult nsINode::GetBaseURI(nsAString& aURI) const {
nsIURI* baseURI = GetBaseURI();
nsAutoCString spec;
if (baseURI) {
nsresult rv = baseURI->GetSpec(spec);
NS_ENSURE_SUCCESS(rv, rv);
}
CopyUTF8toUTF16(spec, aURI);
return NS_OK;
}
void nsINode::GetBaseURIFromJS(nsAString& aURI, CallerType aCallerType,
ErrorResult& aRv) const {
nsIURI* baseURI = GetBaseURI(aCallerType == CallerType::System);
nsAutoCString spec;
if (baseURI) {
nsresult res = baseURI->GetSpec(spec);
if (NS_FAILED(res)) {
aRv.Throw(res);
return;
}
}
CopyUTF8toUTF16(spec, aURI);
}
nsIURI* nsINode::GetBaseURIObject() const { return GetBaseURI(true); }
void nsINode::LookupPrefix(const nsAString& aNamespaceURI, nsAString& aPrefix) {
if (Element* nsElement = GetNameSpaceElement()) {
// XXX Waiting for DOM spec to list error codes.
// Trace up the content parent chain looking for the namespace
// declaration that defines the aNamespaceURI namespace. Once found,
// return the prefix (i.e. the attribute localName).
for (Element* element : nsElement->InclusiveAncestorsOfType<Element>()) {
uint32_t attrCount = element->GetAttrCount();
for (uint32_t i = 0; i < attrCount; ++i) {
const nsAttrName* name = element->GetAttrNameAt(i);
if (name->NamespaceEquals(kNameSpaceID_XMLNS) &&
element->AttrValueIs(kNameSpaceID_XMLNS, name->LocalName(),
aNamespaceURI, eCaseMatters)) {
// If the localName is "xmlns", the prefix we output should be
// null.
nsAtom* localName = name->LocalName();
if (localName != nsGkAtoms::xmlns) {
localName->ToString(aPrefix);
} else {
SetDOMStringToNull(aPrefix);
}
return;
}
}
}
}
SetDOMStringToNull(aPrefix);
}
uint16_t nsINode::CompareDocumentPosition(nsINode& aOtherNode,
Maybe<uint32_t>* aThisIndex,
Maybe<uint32_t>* aOtherIndex) const {
if (this == &aOtherNode) {
return 0;
}
if (GetPreviousSibling() == &aOtherNode) {
MOZ_ASSERT(GetParentNode() == aOtherNode.GetParentNode());
return Node_Binding::DOCUMENT_POSITION_PRECEDING;
}
if (GetNextSibling() == &aOtherNode) {
MOZ_ASSERT(GetParentNode() == aOtherNode.GetParentNode());
return Node_Binding::DOCUMENT_POSITION_FOLLOWING;
}
AutoTArray<const nsINode*, 32> parents1, parents2;
const nsINode* node1 = &aOtherNode;
const nsINode* node2 = this;
// Check if either node is an attribute
const Attr* attr1 = Attr::FromNode(node1);
if (attr1) {
const Element* elem = attr1->GetElement();
// If there is an owner element add the attribute
// to the chain and walk up to the element
if (elem) {
node1 = elem;
parents1.AppendElement(attr1);
}
}
if (auto* attr2 = Attr::FromNode(node2)) {
const Element* elem = attr2->GetElement();
if (elem == node1 && attr1) {
// Both nodes are attributes on the same element.
// Compare position between the attributes.
uint32_t i;
const nsAttrName* attrName;
for (i = 0; (attrName = elem->GetAttrNameAt(i)); ++i) {
if (attrName->Equals(attr1->NodeInfo())) {
NS_ASSERTION(!attrName->Equals(attr2->NodeInfo()),
"Different attrs at same position");
return Node_Binding::DOCUMENT_POSITION_IMPLEMENTATION_SPECIFIC |
Node_Binding::DOCUMENT_POSITION_PRECEDING;
}
if (attrName->Equals(attr2->NodeInfo())) {
return Node_Binding::DOCUMENT_POSITION_IMPLEMENTATION_SPECIFIC |
Node_Binding::DOCUMENT_POSITION_FOLLOWING;
}
}
MOZ_ASSERT_UNREACHABLE("neither attribute in the element");
return Node_Binding::DOCUMENT_POSITION_DISCONNECTED;
}
if (elem) {
node2 = elem;
parents2.AppendElement(attr2);
}
}
// We now know that both nodes are either nsIContents or Documents.
// If either node started out as an attribute, that attribute will have
// the same relative position as its ownerElement, except if the
// ownerElement ends up being the container for the other node
// Build the chain of parents
do {
parents1.AppendElement(node1);
node1 = node1->GetParentNode();
} while (node1);
do {
parents2.AppendElement(node2);
node2 = node2->GetParentNode();
} while (node2);
// Check if the nodes are disconnected.
uint32_t pos1 = parents1.Length();
uint32_t pos2 = parents2.Length();
const nsINode* top1 = parents1.ElementAt(--pos1);
const nsINode* top2 = parents2.ElementAt(--pos2);
if (top1 != top2) {
return top1 < top2
? (Node_Binding::DOCUMENT_POSITION_PRECEDING |
Node_Binding::DOCUMENT_POSITION_DISCONNECTED |
Node_Binding::DOCUMENT_POSITION_IMPLEMENTATION_SPECIFIC)
: (Node_Binding::DOCUMENT_POSITION_FOLLOWING |
Node_Binding::DOCUMENT_POSITION_DISCONNECTED |
Node_Binding::DOCUMENT_POSITION_IMPLEMENTATION_SPECIFIC);
}
// Find where the parent chain differs and check indices in the parent.
const nsINode* parent = top1;
uint32_t len;
for (len = std::min(pos1, pos2); len > 0; --len) {
const nsINode* child1 = parents1.ElementAt(--pos1);
const nsINode* child2 = parents2.ElementAt(--pos2);
if (child1 != child2) {
// child1 or child2 can be an attribute here. This will work fine since
// ComputeIndexOf will return Nothing for the attribute making the
// attribute be considered before any child.
Maybe<uint32_t> child1Index;
bool cachedChild1Index = false;
if (&aOtherNode == child1 && aOtherIndex) {
cachedChild1Index = true;
child1Index = aOtherIndex->isSome() ? *aOtherIndex
: parent->ComputeIndexOf(child1);
} else {
child1Index = parent->ComputeIndexOf(child1);
}
Maybe<uint32_t> child2Index;
bool cachedChild2Index = false;
if (this == child2 && aThisIndex) {
cachedChild2Index = true;
child2Index =
aThisIndex->isSome() ? *aThisIndex : parent->ComputeIndexOf(child2);
} else {
child2Index = parent->ComputeIndexOf(child2);
}
uint16_t retVal = child1Index < child2Index
? Node_Binding::DOCUMENT_POSITION_PRECEDING
: Node_Binding::DOCUMENT_POSITION_FOLLOWING;
if (cachedChild1Index) {
*aOtherIndex = child1Index;
}
if (cachedChild2Index) {
*aThisIndex = child2Index;
}
return retVal;
}
parent = child1;
}
// We hit the end of one of the parent chains without finding a difference
// between the chains. That must mean that one node is an ancestor of the
// other. The one with the shortest chain must be the ancestor.
return pos1 < pos2 ? (Node_Binding::DOCUMENT_POSITION_PRECEDING |
Node_Binding::DOCUMENT_POSITION_CONTAINS)
: (Node_Binding::DOCUMENT_POSITION_FOLLOWING |
Node_Binding::DOCUMENT_POSITION_CONTAINED_BY);
}
bool nsINode::IsSameNode(nsINode* other) { return other == this; }
bool nsINode::IsEqualNode(nsINode* aOther) {
if (!aOther) {
return false;
}
// Might as well do a quick check to avoid walking our kids if we're
// obviously the same.
if (aOther == this) {
return true;
}
nsAutoString string1, string2;
nsINode* node1 = this;
nsINode* node2 = aOther;
do {
uint16_t nodeType = node1->NodeType();
if (nodeType != node2->NodeType()) {
return false;
}
mozilla::dom::NodeInfo* nodeInfo1 = node1->mNodeInfo;
mozilla::dom::NodeInfo* nodeInfo2 = node2->mNodeInfo;
if (!nodeInfo1->Equals(nodeInfo2) ||
nodeInfo1->GetExtraName() != nodeInfo2->GetExtraName()) {
return false;
}
switch (nodeType) {
case ELEMENT_NODE: {
// Both are elements (we checked that their nodeinfos are equal). Do the
// check on attributes.
Element* element1 = node1->AsElement();
Element* element2 = node2->AsElement();
uint32_t attrCount = element1->GetAttrCount();
if (attrCount != element2->GetAttrCount()) {
return false;
}
// Iterate over attributes.
for (uint32_t i = 0; i < attrCount; ++i) {
const nsAttrName* attrName = element1->GetAttrNameAt(i);
#ifdef DEBUG
bool hasAttr =
#endif
element1->GetAttr(attrName->NamespaceID(), attrName->LocalName(),
string1);
NS_ASSERTION(hasAttr, "Why don't we have an attr?");
if (!element2->AttrValueIs(attrName->NamespaceID(),
attrName->LocalName(), string1,
eCaseMatters)) {
return false;
}
}
break;
}
case TEXT_NODE:
case COMMENT_NODE:
case CDATA_SECTION_NODE:
case PROCESSING_INSTRUCTION_NODE: {
MOZ_ASSERT(node1->IsCharacterData());
MOZ_ASSERT(node2->IsCharacterData());
auto* data1 = static_cast<CharacterData*>(node1);
auto* data2 = static_cast<CharacterData*>(node2);
if (!data1->TextEquals(data2)) {
return false;
}
break;
}
case DOCUMENT_NODE:
case DOCUMENT_FRAGMENT_NODE:
break;
case ATTRIBUTE_NODE: {
NS_ASSERTION(node1 == this && node2 == aOther,
"Did we come upon an attribute node while walking a "
"subtree?");
node1->GetNodeValue(string1);
node2->GetNodeValue(string2);
// Returning here as to not bother walking subtree. And there is no
// risk that we're half way through walking some other subtree since
// attribute nodes doesn't appear in subtrees.
return string1.Equals(string2);
}
case DOCUMENT_TYPE_NODE: {
DocumentType* docType1 = static_cast<DocumentType*>(node1);
DocumentType* docType2 = static_cast<DocumentType*>(node2);
// Public ID
docType1->GetPublicId(string1);
docType2->GetPublicId(string2);
if (!string1.Equals(string2)) {
return false;
}
// System ID
docType1->GetSystemId(string1);
docType2->GetSystemId(string2);
if (!string1.Equals(string2)) {
return false;
}
break;
}
default:
MOZ_ASSERT(false, "Unknown node type");
}
nsINode* nextNode = node1->GetFirstChild();
if (nextNode) {
node1 = nextNode;
node2 = node2->GetFirstChild();
} else {
if (node2->GetFirstChild()) {
// node2 has a firstChild, but node1 doesn't
return false;
}
// Find next sibling, possibly walking parent chain.
while (1) {
if (node1 == this) {
NS_ASSERTION(node2 == aOther,
"Should have reached the start node "
"for both trees at the same time");
return true;
}
nextNode = node1->GetNextSibling();
if (nextNode) {
node1 = nextNode;
node2 = node2->GetNextSibling();
break;
}
if (node2->GetNextSibling()) {
// node2 has a nextSibling, but node1 doesn't
return false;
}
node1 = node1->GetParentNode();
node2 = node2->GetParentNode();
NS_ASSERTION(node1 && node2, "no parent while walking subtree");
}
}
} while (node2);
return false;
}
void nsINode::LookupNamespaceURI(const nsAString& aNamespacePrefix,
nsAString& aNamespaceURI) {
Element* element = GetNameSpaceElement();
if (!element || NS_FAILED(element->LookupNamespaceURIInternal(
aNamespacePrefix, aNamespaceURI))) {
SetDOMStringToNull(aNamespaceURI);
}
}
mozilla::Maybe<mozilla::dom::EventCallbackDebuggerNotificationType>
nsINode::GetDebuggerNotificationType() const {
return mozilla::Some(
mozilla::dom::EventCallbackDebuggerNotificationType::Node);
}
bool nsINode::ComputeDefaultWantsUntrusted(ErrorResult& aRv) {
return !nsContentUtils::IsChromeDoc(OwnerDoc());
}
void nsINode::GetBoxQuads(const BoxQuadOptions& aOptions,
nsTArray<RefPtr<DOMQuad>>& aResult,
CallerType aCallerType, mozilla::ErrorResult& aRv) {
mozilla::GetBoxQuads(this, aOptions, aResult, aCallerType, aRv);
}
void nsINode::GetBoxQuadsFromWindowOrigin(const BoxQuadOptions& aOptions,
nsTArray<RefPtr<DOMQuad>>& aResult,
mozilla::ErrorResult& aRv) {
mozilla::GetBoxQuadsFromWindowOrigin(this, aOptions, aResult, aRv);
}
already_AddRefed<DOMQuad> nsINode::ConvertQuadFromNode(
DOMQuad& aQuad, const GeometryNode& aFrom,
const ConvertCoordinateOptions& aOptions, CallerType aCallerType,
ErrorResult& aRv) {
return mozilla::ConvertQuadFromNode(this, aQuad, aFrom, aOptions, aCallerType,
aRv);
}
already_AddRefed<DOMQuad> nsINode::ConvertRectFromNode(
DOMRectReadOnly& aRect, const GeometryNode& aFrom,
const ConvertCoordinateOptions& aOptions, CallerType aCallerType,
ErrorResult& aRv) {
return mozilla::ConvertRectFromNode(this, aRect, aFrom, aOptions, aCallerType,
aRv);
}
already_AddRefed<DOMPoint> nsINode::ConvertPointFromNode(
const DOMPointInit& aPoint, const GeometryNode& aFrom,
const ConvertCoordinateOptions& aOptions, CallerType aCallerType,
ErrorResult& aRv) {
return mozilla::ConvertPointFromNode(this, aPoint, aFrom, aOptions,
aCallerType, aRv);
}
bool nsINode::DispatchEvent(Event& aEvent, CallerType aCallerType,
ErrorResult& aRv) {
// XXX sXBL/XBL2 issue -- do we really want the owner here? What
// if that's the XBL document? Would we want its presshell? Or what?
nsCOMPtr<Document> document = OwnerDoc();
// Do nothing if the element does not belong to a document
if (!document) {
return true;
}
// Obtain a presentation shell
RefPtr<nsPresContext> context = document->GetPresContext();
nsEventStatus status = nsEventStatus_eIgnore;
nsresult rv = EventDispatcher::DispatchDOMEvent(this, nullptr, &aEvent,
context, &status);
bool retval = !aEvent.DefaultPrevented(aCallerType);
if (NS_FAILED(rv)) {
aRv.Throw(rv);
}
return retval;
}
nsresult nsINode::PostHandleEvent(EventChainPostVisitor& /*aVisitor*/) {
return NS_OK;
}
EventListenerManager* nsINode::GetOrCreateListenerManager() {
return nsContentUtils::GetListenerManagerForNode(this);
}
EventListenerManager* nsINode::GetExistingListenerManager() const {
return nsContentUtils::GetExistingListenerManagerForNode(this);
}
nsPIDOMWindowOuter* nsINode::GetOwnerGlobalForBindingsInternal() {
bool dummy;
// FIXME(bz): This cast is a bit bogus. See
auto* window = static_cast<nsGlobalWindowInner*>(
OwnerDoc()->GetScriptHandlingObject(dummy));
return window ? nsPIDOMWindowOuter::GetFromCurrentInner(window) : nullptr;
}
nsIGlobalObject* nsINode::GetOwnerGlobal() const {
bool dummy;
return OwnerDoc()->GetScriptHandlingObject(dummy);
}
bool nsINode::UnoptimizableCCNode() const {
return IsInNativeAnonymousSubtree() || IsAttr();
}
/* static */
bool nsINode::Traverse(nsINode* tmp, nsCycleCollectionTraversalCallback& cb) {
if (MOZ_LIKELY(!cb.WantAllTraces())) {
Document* currentDoc = tmp->GetComposedDoc();
if (currentDoc && nsCCUncollectableMarker::InGeneration(
currentDoc->GetMarkedCCGeneration())) {
return false;
}
if (nsCCUncollectableMarker::sGeneration) {
// If we're black no need to traverse.
if (tmp->HasKnownLiveWrapper() || tmp->InCCBlackTree()) {
return false;
}
if (!tmp->UnoptimizableCCNode()) {
// If we're in a black document, return early.
if ((currentDoc && currentDoc->HasKnownLiveWrapper())) {
return false;
}
// If we're not in anonymous content and we have a black parent,
// return early.
nsIContent* parent = tmp->GetParent();
if (parent && !parent->UnoptimizableCCNode() &&
parent->HasKnownLiveWrapper()) {
MOZ_ASSERT(parent->ComputeIndexOf(tmp).isSome(),
"Parent doesn't own us?");
return false;
}
}
}
}
NS_IMPL_CYCLE_COLLECTION_TRAVERSE(mNodeInfo)
NS_IMPL_CYCLE_COLLECTION_TRAVERSE(mFirstChild)
NS_IMPL_CYCLE_COLLECTION_TRAVERSE(mNextSibling)
NS_IMPL_CYCLE_COLLECTION_TRAVERSE_RAWPTR(GetParent())
if (nsSlots* slots = tmp->GetExistingSlots()) {
slots->Traverse(cb);
}
if (tmp->HasProperties()) {
#ifdef ACCESSIBILITY
auto* anode = static_cast<AccessibleNode*>(
tmp->GetProperty(nsGkAtoms::accessiblenode));
if (anode) {
cb.NoteXPCOMChild(anode);
}
#endif
}
if (tmp->NodeType() != DOCUMENT_NODE &&
tmp->HasFlag(NODE_HAS_LISTENERMANAGER)) {
nsContentUtils::TraverseListenerManager(tmp, cb);
}
return true;
}
/* static */
void nsINode::Unlink(nsINode* tmp) {
tmp->ReleaseWrapper(tmp);
if (nsSlots* slots = tmp->GetExistingSlots()) {
slots->Unlink(*tmp);
}
if (tmp->NodeType() != DOCUMENT_NODE &&
tmp->HasFlag(NODE_HAS_LISTENERMANAGER)) {
nsContentUtils::RemoveListenerManager(tmp);
tmp->UnsetFlags(NODE_HAS_LISTENERMANAGER);
}
if (tmp->HasProperties()) {
tmp->RemoveProperty(nsGkAtoms::accessiblenode);
}
}
static void AdoptNodeIntoOwnerDoc(nsINode* aParent, nsINode* aNode,
ErrorResult& aError) {
NS_ASSERTION(!aNode->GetParentNode(),
"Should have removed from parent already");
Document* doc = aParent->OwnerDoc();
DebugOnly<nsINode*> adoptedNode = doc->AdoptNode(*aNode, aError, true);
#ifdef DEBUG
if (!aError.Failed()) {
MOZ_ASSERT(aParent->OwnerDoc() == doc, "ownerDoc chainged while adopting");
MOZ_ASSERT(adoptedNode == aNode, "Uh, adopt node changed nodes?");
MOZ_ASSERT(aParent->OwnerDoc() == aNode->OwnerDoc(),
"ownerDocument changed again after adopting!");
}
#endif // DEBUG
}
static nsresult UpdateGlobalsInSubtree(nsIContent* aRoot) {
MOZ_ASSERT(ShouldUseNACScope(aRoot));
// Start off with no global so we don't fire any error events on failure.
AutoJSAPI jsapi;
jsapi.Init();
JSContext* cx = jsapi.cx();
ErrorResult rv;
JS::Rooted<JSObject*> reflector(cx);
for (nsIContent* cur = aRoot; cur; cur = cur->GetNextNode(aRoot)) {
if ((reflector = cur->GetWrapper())) {
JSAutoRealm ar(cx, reflector);
UpdateReflectorGlobal(cx, reflector, rv);
rv.WouldReportJSException();
if (rv.Failed()) {
// We _could_ consider BlastSubtreeToPieces here, but it's not really
// needed. Having some nodes in here accessible to content while others
// are not is probably OK. We just need to fail out of the actual
// insertion, so they're not in the DOM. Returning a failure here will
// do that.
return rv.StealNSResult();
}
}
}
return NS_OK;
}
void nsINode::InsertChildBefore(nsIContent* aKid, nsIContent* aBeforeThis,
bool aNotify, ErrorResult& aRv) {
if (!IsContainerNode()) {
aRv.ThrowHierarchyRequestError(
"Parent is not a Document, DocumentFragment, or Element node.");
return;
}
MOZ_ASSERT(!aKid->GetParentNode(), "Inserting node that already has parent");
MOZ_ASSERT(!IsAttr());
// The id-handling code, and in the future possibly other code, need to
// react to unexpected attribute changes.
nsMutationGuard::DidMutate();
// Do this before checking the child-count since this could cause mutations
mozAutoDocUpdate updateBatch(GetComposedDoc(), aNotify);
if (OwnerDoc() != aKid->OwnerDoc()) {
AdoptNodeIntoOwnerDoc(this, aKid, aRv);
if (NS_WARN_IF(aRv.Failed())) {
return;
}
}
if (!aBeforeThis) {
AppendChildToChildList(aKid);
} else {
InsertChildToChildList(aKid, aBeforeThis);
}
nsIContent* parent = IsContent() ? AsContent() : nullptr;
// XXXbz Do we even need this code anymore?
bool wasInNACScope = ShouldUseNACScope(aKid);
BindContext context(*this);
aRv = aKid->BindToTree(context, *this);
if (!aRv.Failed() && !wasInNACScope && ShouldUseNACScope(aKid)) {
MOZ_ASSERT(ShouldUseNACScope(this),
"Why does the kid need to use an the anonymous content scope?");
aRv = UpdateGlobalsInSubtree(aKid);
}
if (aRv.Failed()) {
DisconnectChild(aKid);
aKid->UnbindFromTree();
return;
}
// Invalidate cached array of child nodes
InvalidateChildNodes();
NS_ASSERTION(aKid->GetParentNode() == this,
"Did we run script inappropriately?");
if (aNotify) {
// Note that we always want to call ContentInserted when things are added
// as kids to documents
if (parent && !aBeforeThis) {
MutationObservers::NotifyContentAppended(parent, aKid);
} else {
MutationObservers::NotifyContentInserted(this, aKid);
}
if (nsContentUtils::WantMutationEvents(
aKid, NS_EVENT_BITS_MUTATION_NODEINSERTED, this)) {
InternalMutationEvent mutation(true, eLegacyNodeInserted);
mutation.mRelatedNode = this;
mozAutoSubtreeModified subtree(OwnerDoc(), this);
AsyncEventDispatcher::RunDOMEventWhenSafe(*aKid, mutation);
}
}
}
nsIContent* nsINode::GetPreviousSibling() const {
// Do not expose circular linked list
if (mPreviousOrLastSibling && !mPreviousOrLastSibling->mNextSibling) {
return nullptr;
}
return mPreviousOrLastSibling;
}
// CACHE_POINTER_SHIFT indicates how many steps to downshift the |this| pointer.
// It should be small enough to not cause collisions between adjecent objects,
// and large enough to make sure that all indexes are used.
#define CACHE_POINTER_SHIFT 6
#define CACHE_NUM_SLOTS 128
#define CACHE_CHILD_LIMIT 10
#define CACHE_GET_INDEX(_parent) \
((NS_PTR_TO_INT32(_parent) >> CACHE_POINTER_SHIFT) & (CACHE_NUM_SLOTS - 1))
struct IndexCacheSlot {
const nsINode* mParent;
const nsINode* mChild;
uint32_t mChildIndex;
};
static IndexCacheSlot sIndexCache[CACHE_NUM_SLOTS];
static inline void AddChildAndIndexToCache(const nsINode* aParent,
const nsINode* aChild,
uint32_t aChildIndex) {
uint32_t index = CACHE_GET_INDEX(aParent);
sIndexCache[index].mParent = aParent;
sIndexCache[index].mChild = aChild;
sIndexCache[index].mChildIndex = aChildIndex;
}
static inline void GetChildAndIndexFromCache(const nsINode* aParent,
const nsINode** aChild,
Maybe<uint32_t>* aChildIndex) {
uint32_t index = CACHE_GET_INDEX(aParent);
if (sIndexCache[index].mParent == aParent) {
*aChild = sIndexCache[index].mChild;
*aChildIndex = Some(sIndexCache[index].mChildIndex);
} else {
*aChild = nullptr;
*aChildIndex = Nothing();
}
}
static inline void RemoveFromCache(const nsINode* aParent) {
uint32_t index = CACHE_GET_INDEX(aParent);
if (sIndexCache[index].mParent == aParent) {
sIndexCache[index] = {nullptr, nullptr, UINT32_MAX};
}
}
void nsINode::AppendChildToChildList(nsIContent* aKid) {
MOZ_ASSERT(aKid);
MOZ_ASSERT(!aKid->mNextSibling);
RemoveFromCache(this);
if (mFirstChild) {
nsIContent* lastChild = GetLastChild();
lastChild->mNextSibling = aKid;
aKid->mPreviousOrLastSibling = lastChild;
} else {
mFirstChild = aKid;
}
// Maintain link to the last child
mFirstChild->mPreviousOrLastSibling = aKid;
++mChildCount;
}
void nsINode::InsertChildToChildList(nsIContent* aKid,
nsIContent* aNextSibling) {
MOZ_ASSERT(aKid);
MOZ_ASSERT(aNextSibling);
RemoveFromCache(this);
nsIContent* previousSibling = aNextSibling->mPreviousOrLastSibling;
aNextSibling->mPreviousOrLastSibling = aKid;
aKid->mPreviousOrLastSibling = previousSibling;
aKid->mNextSibling = aNextSibling;
if (aNextSibling == mFirstChild) {
MOZ_ASSERT(!previousSibling->mNextSibling);
mFirstChild = aKid;
} else {
previousSibling->mNextSibling = aKid;
}
++mChildCount;
}
void nsINode::DisconnectChild(nsIContent* aKid) {
MOZ_ASSERT(aKid);
MOZ_ASSERT(GetChildCount() > 0);
RemoveFromCache(this);
nsIContent* previousSibling = aKid->GetPreviousSibling();
nsCOMPtr<nsIContent> ref = aKid;
if (aKid->mNextSibling) {
aKid->mNextSibling->mPreviousOrLastSibling = aKid->mPreviousOrLastSibling;
} else {
// aKid is the last child in the list
mFirstChild->mPreviousOrLastSibling = aKid->mPreviousOrLastSibling;
}
aKid->mPreviousOrLastSibling = nullptr;
if (previousSibling) {
previousSibling->mNextSibling = std::move(aKid->mNextSibling);
} else {
// aKid is the first child in the list
mFirstChild = std::move(aKid->mNextSibling);
}
--mChildCount;
}
nsIContent* nsINode::GetChildAt_Deprecated(uint32_t aIndex) const {
if (aIndex >= GetChildCount()) {
return nullptr;
}
nsIContent* child = mFirstChild;
while (aIndex--) {
child = child->GetNextSibling();
}
return child;
}
int32_t nsINode::ComputeIndexOf_Deprecated(
const nsINode* aPossibleChild) const {
Maybe<uint32_t> maybeIndex = ComputeIndexOf(aPossibleChild);
if (!maybeIndex) {
return -1;
}
MOZ_ASSERT(*maybeIndex <= INT32_MAX,
"ComputeIndexOf_Deprecated() returns unsupported index value, use "
"ComputeIndex() instead");
return static_cast<int32_t>(*maybeIndex);
}
Maybe<uint32_t> nsINode::ComputeIndexOf(const nsINode* aPossibleChild) const {
if (!aPossibleChild) {
return Nothing();
}
if (aPossibleChild->GetParentNode() != this) {
return Nothing();
}
if (aPossibleChild == GetFirstChild()) {
return Some(0);
}
if (aPossibleChild == GetLastChild()) {
MOZ_ASSERT(GetChildCount());
return Some(GetChildCount() - 1);
}
if (mChildCount >= CACHE_CHILD_LIMIT) {
const nsINode* child;
Maybe<uint32_t> maybeChildIndex;
GetChildAndIndexFromCache(this, &child, &maybeChildIndex);
if (child) {
if (child == aPossibleChild) {
return maybeChildIndex;
}
uint32_t nextIndex = *maybeChildIndex;
uint32_t prevIndex = *maybeChildIndex;
nsINode* prev = child->GetPreviousSibling();
nsINode* next = child->GetNextSibling();
do {
if (next) {
MOZ_ASSERT(nextIndex < UINT32_MAX);
++nextIndex;
if (next == aPossibleChild) {
AddChildAndIndexToCache(this, aPossibleChild, nextIndex);
return Some(nextIndex);
}
next = next->GetNextSibling();
}
if (prev) {
MOZ_ASSERT(prevIndex > 0);
--prevIndex;
if (prev == aPossibleChild) {
AddChildAndIndexToCache(this, aPossibleChild, prevIndex);
return Some(prevIndex);
}
prev = prev->GetPreviousSibling();
}
} while (prev || next);
}
}
uint32_t index = 0u;
nsINode* current = mFirstChild;
while (current) {
MOZ_ASSERT(current->GetParentNode() == this);
if (current == aPossibleChild) {
if (mChildCount >= CACHE_CHILD_LIMIT) {
AddChildAndIndexToCache(this, current, index);
}
return Some(index);
}
current = current->GetNextSibling();
MOZ_ASSERT(index < UINT32_MAX);
++index;
}
return Nothing();
}
Maybe<uint32_t> nsINode::ComputeIndexInParentNode() const {
nsINode* parent = GetParentNode();
if (MOZ_UNLIKELY(!parent)) {
return Nothing();
}
return parent->ComputeIndexOf(this);
}
Maybe<uint32_t> nsINode::ComputeIndexInParentContent() const {
nsIContent* parent = GetParent();
if (MOZ_UNLIKELY(!parent)) {
return Nothing();
}
return parent->ComputeIndexOf(this);
}
static Maybe<uint32_t> DoComputeFlatTreeIndexOf(FlattenedChildIterator& aIter,
const nsINode* aPossibleChild) {
if (aPossibleChild->GetFlattenedTreeParentNode() != aIter.Parent()) {
return Nothing();
}
uint32_t index = 0u;
for (nsIContent* child = aIter.GetNextChild(); child;
child = aIter.GetNextChild()) {
if (child == aPossibleChild) {
return Some(index);
}
++index;
}
return Nothing();
}
Maybe<uint32_t> nsINode::ComputeFlatTreeIndexOf(
const nsINode* aPossibleChild) const {
if (!aPossibleChild) {
return Nothing();
}
if (!IsContent()) {
return ComputeIndexOf(aPossibleChild);
}
FlattenedChildIterator iter(AsContent());
if (!iter.ShadowDOMInvolved()) {
auto index = ComputeIndexOf(aPossibleChild);
MOZ_ASSERT(DoComputeFlatTreeIndexOf(iter, aPossibleChild) == index);
return index;
}
return DoComputeFlatTreeIndexOf(iter, aPossibleChild);
}
static already_AddRefed<nsINode> GetNodeFromNodeOrString(
const OwningNodeOrString& aNode, Document* aDocument) {
if (aNode.IsNode()) {
nsCOMPtr<nsINode> node = aNode.GetAsNode();
return node.forget();
}
if (aNode.IsString()) {
RefPtr<nsTextNode> textNode =
aDocument->CreateTextNode(aNode.GetAsString());
return textNode.forget();
}
MOZ_CRASH("Impossible type");
}
/**
* Implement the algorithm specified at
* |append()|, |before()|, |after()|, and |replaceWith()| APIs.
*/
MOZ_CAN_RUN_SCRIPT static already_AddRefed<nsINode>
ConvertNodesOrStringsIntoNode(const Sequence<OwningNodeOrString>& aNodes,
Document* aDocument, ErrorResult& aRv) {
if (aNodes.Length() == 1) {
return GetNodeFromNodeOrString(aNodes[0], aDocument);
}
nsCOMPtr<nsINode> fragment = aDocument->CreateDocumentFragment();
for (const auto& node : aNodes) {
nsCOMPtr<nsINode> childNode = GetNodeFromNodeOrString(node, aDocument);
fragment->AppendChild(*childNode, aRv);
if (aRv.Failed()) {
return nullptr;
}
}
return fragment.forget();
}
static void InsertNodesIntoHashset(const Sequence<OwningNodeOrString>& aNodes,
nsTHashSet<nsINode*>& aHashset) {
for (const auto& node : aNodes) {
if (node.IsNode()) {
aHashset.Insert(node.GetAsNode());
}
}
}
static nsINode* FindViablePreviousSibling(
const nsINode& aNode, const Sequence<OwningNodeOrString>& aNodes) {
nsTHashSet<nsINode*> nodeSet(16);
InsertNodesIntoHashset(aNodes, nodeSet);
nsINode* viablePreviousSibling = nullptr;
for (nsINode* sibling = aNode.GetPreviousSibling(); sibling;
sibling = sibling->GetPreviousSibling()) {
if (!nodeSet.Contains(sibling)) {
viablePreviousSibling = sibling;
break;
}
}
return viablePreviousSibling;
}
static nsINode* FindViableNextSibling(
const nsINode& aNode, const Sequence<OwningNodeOrString>& aNodes) {
nsTHashSet<nsINode*> nodeSet(16);
InsertNodesIntoHashset(aNodes, nodeSet);
nsINode* viableNextSibling = nullptr;
for (nsINode* sibling = aNode.GetNextSibling(); sibling;
sibling = sibling->GetNextSibling()) {
if (!nodeSet.Contains(sibling)) {
viableNextSibling = sibling;
break;
}
}
return viableNextSibling;
}
void nsINode::Before(const Sequence<OwningNodeOrString>& aNodes,
ErrorResult& aRv) {
nsCOMPtr<nsINode> parent = GetParentNode();
if (!parent) {
return;
}
nsCOMPtr<nsINode> viablePreviousSibling =
FindViablePreviousSibling(*this, aNodes);
nsCOMPtr<Document> doc = OwnerDoc();
nsCOMPtr<nsINode> node = ConvertNodesOrStringsIntoNode(aNodes, doc, aRv);
if (aRv.Failed()) {
return;
}
viablePreviousSibling = viablePreviousSibling
? viablePreviousSibling->GetNextSibling()
: parent->GetFirstChild();
parent->InsertBefore(*node, viablePreviousSibling, aRv);
}
void nsINode::After(const Sequence<OwningNodeOrString>& aNodes,
ErrorResult& aRv) {
nsCOMPtr<nsINode> parent = GetParentNode();
if (!parent) {
return;
}
nsCOMPtr<nsINode> viableNextSibling = FindViableNextSibling(*this, aNodes);
nsCOMPtr<Document> doc = OwnerDoc();
nsCOMPtr<nsINode> node = ConvertNodesOrStringsIntoNode(aNodes, doc, aRv);
if (aRv.Failed()) {
return;
}
parent->InsertBefore(*node, viableNextSibling, aRv);
}
void nsINode::ReplaceWith(const Sequence<OwningNodeOrString>& aNodes,
ErrorResult& aRv) {
nsCOMPtr<nsINode> parent = GetParentNode();
if (!parent) {
return;
}
nsCOMPtr<nsINode> viableNextSibling = FindViableNextSibling(*this, aNodes);
nsCOMPtr<Document> doc = OwnerDoc();
nsCOMPtr<nsINode> node = ConvertNodesOrStringsIntoNode(aNodes, doc, aRv);
if (aRv.Failed()) {
return;
}
if (parent == GetParentNode()) {
parent->ReplaceChild(*node, *this, aRv);
} else {
parent->InsertBefore(*node, viableNextSibling, aRv);
}
}
void nsINode::Remove() {
nsCOMPtr<nsINode> parent = GetParentNode();
if (!parent) {
return;
}
parent->RemoveChild(*this, IgnoreErrors());
}
Element* nsINode::GetFirstElementChild() const {
for (nsIContent* child = GetFirstChild(); child;
child = child->GetNextSibling()) {
if (child->IsElement()) {
return child->AsElement();
}
}
return nullptr;
}
Element* nsINode::GetLastElementChild() const {
for (nsIContent* child = GetLastChild(); child;
child = child->GetPreviousSibling()) {
if (child->IsElement()) {
return child->AsElement();
}
}
return nullptr;
}
static bool MatchAttribute(Element* aElement, int32_t aNamespaceID,
nsAtom* aAttrName, void* aData) {
MOZ_ASSERT(aElement, "Must have content node to work with!");
nsString* attrValue = static_cast<nsString*>(aData);
if (aNamespaceID != kNameSpaceID_Unknown &&
aNamespaceID != kNameSpaceID_Wildcard) {
return attrValue->EqualsLiteral("*")
? aElement->HasAttr(aNamespaceID, aAttrName)
: aElement->AttrValueIs(aNamespaceID, aAttrName, *attrValue,
eCaseMatters);
}
// Qualified name match. This takes more work.
uint32_t count = aElement->GetAttrCount();
for (uint32_t i = 0; i < count; ++i) {
const nsAttrName* name = aElement->GetAttrNameAt(i);
bool nameMatch;
if (name->IsAtom()) {
nameMatch = name->Atom() == aAttrName;
} else if (aNamespaceID == kNameSpaceID_Wildcard) {
nameMatch = name->NodeInfo()->Equals(aAttrName);
} else {
nameMatch = name->NodeInfo()->QualifiedNameEquals(aAttrName);
}
if (nameMatch) {
return attrValue->EqualsLiteral("*") ||
aElement->AttrValueIs(name->NamespaceID(), name->LocalName(),
*attrValue, eCaseMatters);
}
}
return false;
}
already_AddRefed<nsIHTMLCollection> nsINode::GetElementsByAttribute(
const nsAString& aAttribute, const nsAString& aValue) {
RefPtr<nsAtom> attrAtom(NS_Atomize(aAttribute));
RefPtr<nsContentList> list = new nsContentList(
this, MatchAttribute, nsContentUtils::DestroyMatchString,
new nsString(aValue), true, attrAtom, kNameSpaceID_Unknown);
return list.forget();
}
already_AddRefed<nsIHTMLCollection> nsINode::GetElementsByAttributeNS(
const nsAString& aNamespaceURI, const nsAString& aAttribute,
const nsAString& aValue, ErrorResult& aRv) {
RefPtr<nsAtom> attrAtom(NS_Atomize(aAttribute));
int32_t nameSpaceId = kNameSpaceID_Wildcard;
if (!aNamespaceURI.EqualsLiteral("*")) {
nsresult rv = nsNameSpaceManager::GetInstance()->RegisterNameSpace(
aNamespaceURI, nameSpaceId);
if (NS_FAILED(rv)) {
aRv.Throw(rv);
return nullptr;
}
}
RefPtr<nsContentList> list = new nsContentList(
this, MatchAttribute, nsContentUtils::DestroyMatchString,
new nsString(aValue), true, attrAtom, nameSpaceId);
return list.forget();
}
void nsINode::Prepend(const Sequence<OwningNodeOrString>& aNodes,
ErrorResult& aRv) {
nsCOMPtr<Document> doc = OwnerDoc();
nsCOMPtr<nsINode> node = ConvertNodesOrStringsIntoNode(aNodes, doc, aRv);
if (aRv.Failed()) {
return;
}
nsCOMPtr<nsIContent> refNode = mFirstChild;
InsertBefore(*node, refNode, aRv);
}
void nsINode::Append(const Sequence<OwningNodeOrString>& aNodes,
ErrorResult& aRv) {
nsCOMPtr<Document> doc = OwnerDoc();
nsCOMPtr<nsINode> node = ConvertNodesOrStringsIntoNode(aNodes, doc, aRv);
if (aRv.Failed()) {
return;
}
AppendChild(*node, aRv);
}
void nsINode::ReplaceChildren(const Sequence<OwningNodeOrString>& aNodes,
ErrorResult& aRv) {
nsCOMPtr<Document> doc = OwnerDoc();
nsCOMPtr<nsINode> node = ConvertNodesOrStringsIntoNode(aNodes, doc, aRv);
if (aRv.Failed()) {
return;
}
MOZ_ASSERT(node);
return ReplaceChildren(node, aRv);
}
void nsINode::ReplaceChildren(nsINode* aNode, ErrorResult& aRv) {
if (aNode) {
EnsurePreInsertionValidity(*aNode, nullptr, aRv);
if (aRv.Failed()) {
return;
}
}
nsCOMPtr<nsINode> node = aNode;
// Batch possible DOMSubtreeModified events.
mozAutoSubtreeModified subtree(OwnerDoc(), nullptr);
if (nsContentUtils::HasMutationListeners(
OwnerDoc(), NS_EVENT_BITS_MUTATION_NODEREMOVED)) {
FireNodeRemovedForChildren();
if (node) {
if (node->NodeType() == DOCUMENT_FRAGMENT_NODE) {
node->FireNodeRemovedForChildren();
} else if (nsCOMPtr<nsINode> parent = node->GetParentNode()) {
nsContentUtils::MaybeFireNodeRemoved(node, parent);
}
}
}
// Needed when used in combination with contenteditable (maybe)
mozAutoDocUpdate updateBatch(OwnerDoc(), true);
nsAutoMutationBatch mb(this, true, true);
// The code above explicitly dispatched DOMNodeRemoved events if needed.
nsAutoScriptBlockerSuppressNodeRemoved scriptBlocker;
// Replace all with node within this.
while (mFirstChild) {
RemoveChildNode(mFirstChild, true);
}
mb.RemovalDone();
if (aNode) {
AppendChild(*aNode, aRv);
mb.NodesAdded();
}
}
void nsINode::RemoveChildNode(nsIContent* aKid, bool aNotify) {
// NOTE: This function must not trigger any calls to
// Document::GetRootElement() calls until *after* it has removed aKid from
// aChildArray. Any calls before then could potentially restore a stale
// value for our cached root element, per note in
// Document::RemoveChildNode().
MOZ_ASSERT(aKid && aKid->GetParentNode() == this, "Bogus aKid");
MOZ_ASSERT(!IsAttr());
nsMutationGuard::DidMutate();
mozAutoDocUpdate updateBatch(GetComposedDoc(), aNotify);
if (aNotify) {
MutationObservers::NotifyContentWillBeRemoved(this, aKid);
}
// Since aKid is use also after DisconnectChild, ensure it stays alive.
nsCOMPtr<nsIContent> kungfuDeathGrip = aKid;
DisconnectChild(aKid);
// Invalidate cached array of child nodes
InvalidateChildNodes();
aKid->UnbindFromTree();
}
// When replacing, aRefChild is the content being replaced; when
// inserting it's the content before which we're inserting. In the
// latter case it may be null.
//
// If aRv is a failure after this call, the insertion should not happen.
//
// This implements the parts of
// depend on the child nodes or come after steps that depend on the child nodes
// (steps 2-6 in both cases).
static void EnsureAllowedAsChild(nsINode* aNewChild, nsINode* aParent,
bool aIsReplace, nsINode* aRefChild,
ErrorResult& aRv) {
MOZ_ASSERT(aNewChild, "Must have new child");
MOZ_ASSERT_IF(aIsReplace, aRefChild);
MOZ_ASSERT(aParent);
MOZ_ASSERT(aParent->IsDocument() || aParent->IsDocumentFragment() ||
aParent->IsElement(),
"Nodes that are not documents, document fragments or elements "
"can't be parents!");
// Step 2.
// A common case is that aNewChild has no kids, in which case
// aParent can't be a descendant of aNewChild unless they're
// actually equal to each other. Fast-path that case, since aParent
// could be pretty deep in the DOM tree.
if (aNewChild == aParent ||
((aNewChild->GetFirstChild() ||
// HTML template elements and ShadowRoot hosts need
// to be checked to ensure that they are not inserted into
// the hosted content.
aNewChild->NodeInfo()->NameAtom() == nsGkAtoms::_template ||
(aNewChild->IsElement() && aNewChild->AsElement()->GetShadowRoot())) &&
nsContentUtils::ContentIsHostIncludingDescendantOf(aParent,
aNewChild))) {
aRv.ThrowHierarchyRequestError(
"The new child is an ancestor of the parent");
return;
}
// Step 3.
if (aRefChild && aRefChild->GetParentNode() != aParent) {
if (aIsReplace) {
if (aNewChild->GetParentNode() == aParent) {
aRv.ThrowNotFoundError(
"New child already has this parent and old child does not. Please "
"check the order of replaceChild's arguments.");
} else {
aRv.ThrowNotFoundError(
"Child to be replaced is not a child of this node");
}
} else {
aRv.ThrowNotFoundError(
"Child to insert before is not a child of this node");
}
return;
}
// Step 4.
if (!aNewChild->IsContent()) {
aRv.ThrowHierarchyRequestError(nsPrintfCString(
"May not add %s as a child", NodeTypeAsString(aNewChild)));
return;
}
// Steps 5 and 6 combined.
// The allowed child nodes differ for documents and elements
switch (aNewChild->NodeType()) {
case nsINode::COMMENT_NODE:
case nsINode::PROCESSING_INSTRUCTION_NODE:
// OK in both cases
return;
case nsINode::TEXT_NODE:
case nsINode::CDATA_SECTION_NODE:
case nsINode::ENTITY_REFERENCE_NODE:
// Allowed under Elements and DocumentFragments
if (aParent->NodeType() == nsINode::DOCUMENT_NODE) {
aRv.ThrowHierarchyRequestError(
nsPrintfCString("Cannot insert %s as a child of a Document",
NodeTypeAsString(aNewChild)));
}
return;
case nsINode::ELEMENT_NODE: {
if (!aParent->IsDocument()) {
// Always ok to have elements under other elements or document fragments
return;
}
Document* parentDocument = aParent->AsDocument();
Element* rootElement = parentDocument->GetRootElement();
if (rootElement) {
// Already have a documentElement, so this is only OK if we're
// replacing it.
if (!aIsReplace || rootElement != aRefChild) {
aRv.ThrowHierarchyRequestError(
"Cannot have more than one Element child of a Document");
}
return;
}
// We don't have a documentElement yet. Our one remaining constraint is
// that the documentElement must come after the doctype.
if (!aRefChild) {
// Appending is just fine.
return;
}
nsIContent* docTypeContent = parentDocument->GetDoctype();
if (!docTypeContent) {
// It's all good.
return;
}
// The docTypeContent is retrived from the child list of the Document
// node so that doctypeIndex is never Nothing.
const Maybe<uint32_t> doctypeIndex =
aParent->ComputeIndexOf(docTypeContent);
MOZ_ASSERT(doctypeIndex.isSome());
// If aRefChild is an NAC, its index can be Nothing.
const Maybe<uint32_t> insertIndex = aParent->ComputeIndexOf(aRefChild);
// Now we're OK in the following two cases only:
// 1) We're replacing something that's not before the doctype
// 2) We're inserting before something that comes after the doctype
const bool ok = MOZ_LIKELY(insertIndex.isSome()) &&
(aIsReplace ? *insertIndex >= *doctypeIndex
: *insertIndex > *doctypeIndex);
if (!ok) {
aRv.ThrowHierarchyRequestError(
"Cannot insert a root element before the doctype");
}
return;
}
case nsINode::DOCUMENT_TYPE_NODE: {
if (!aParent->IsDocument()) {
// doctypes only allowed under documents
aRv.ThrowHierarchyRequestError(
nsPrintfCString("Cannot insert a DocumentType as a child of %s",
NodeTypeAsString(aParent)));
return;
}
Document* parentDocument = aParent->AsDocument();
nsIContent* docTypeContent = parentDocument->GetDoctype();
if (docTypeContent) {
// Already have a doctype, so this is only OK if we're replacing it
if (!aIsReplace || docTypeContent != aRefChild) {
aRv.ThrowHierarchyRequestError(
"Cannot have more than one DocumentType child of a Document");
}
return;
}
// We don't have a doctype yet. Our one remaining constraint is
// that the doctype must come before the documentElement.
Element* rootElement = parentDocument->GetRootElement();
if (!rootElement) {
// It's all good
return;
}
if (!aRefChild) {
// Trying to append a doctype, but have a documentElement
aRv.ThrowHierarchyRequestError(
"Cannot have a DocumentType node after the root element");
return;
}
// rootElement is now in the child list of the Document node so that
// ComputeIndexOf must success to find it.
const Maybe<uint32_t> rootIndex = aParent->ComputeIndexOf(rootElement);
MOZ_ASSERT(rootIndex.isSome());
const Maybe<uint32_t> insertIndex = aParent->ComputeIndexOf(aRefChild);
// Now we're OK if and only if insertIndex <= rootIndex. Indeed, either
// we end up replacing aRefChild or we end up before it. Either one is
// ok as long as aRefChild is not after rootElement.
if (MOZ_LIKELY(insertIndex.isSome()) && *insertIndex > *rootIndex) {
aRv.ThrowHierarchyRequestError(
"Cannot have a DocumentType node after the root element");
}
return;
}
case nsINode::DOCUMENT_FRAGMENT_NODE: {
// Note that for now we only allow nodes inside document fragments if
// they're allowed inside elements. If we ever change this to allow
// doctype nodes in document fragments, we'll need to update this code.
// Also, there's a version of this code in ReplaceOrInsertBefore. If you
// change this code, change that too.
if (!aParent->IsDocument()) {
// All good here
return;
}
bool sawElement = false;
for (nsIContent* child = aNewChild->GetFirstChild(); child;
child = child->GetNextSibling()) {
if (child->IsElement()) {
if (sawElement) {
// Can't put two elements into a document
aRv.ThrowHierarchyRequestError(
"Cannot have more than one Element child of a Document");
return;
}
sawElement = true;
}
// If we can put this content at the right place, we might be ok;
// if not, we bail out.
EnsureAllowedAsChild(child, aParent, aIsReplace, aRefChild, aRv);
if (aRv.Failed()) {
return;
}
}
// Everything in the fragment checked out ok, so we can stick it in here
return;
}
default:
/*
* aNewChild is of invalid type.
*/
break;
}
// XXXbz when can we reach this?
aRv.ThrowHierarchyRequestError(nsPrintfCString("Cannot insert %s inside %s",
NodeTypeAsString(aNewChild),
NodeTypeAsString(aParent)));
}
// Implements
void nsINode::EnsurePreInsertionValidity(nsINode& aNewChild, nsINode* aRefChild,
ErrorResult& aError) {
EnsurePreInsertionValidity1(aError);
if (aError.Failed()) {
return;
}
EnsurePreInsertionValidity2(false, aNewChild, aRefChild, aError);
}
// Implements the parts of
// evaluated before ever looking at the child nodes (step 1 in both cases).
void nsINode::EnsurePreInsertionValidity1(ErrorResult& aError) {
if (!IsDocument() && !IsDocumentFragment() && !IsElement()) {
aError.ThrowHierarchyRequestError(
nsPrintfCString("Cannot add children to %s", NodeTypeAsString(this)));
return;
}
}
void nsINode::EnsurePreInsertionValidity2(bool aReplace, nsINode& aNewChild,
nsINode* aRefChild,
ErrorResult& aError) {
if (aNewChild.IsRootOfNativeAnonymousSubtree()) {
// This is anonymous content. Don't allow its insertion
// anywhere, since it might have UnbindFromTree calls coming
// its way.
aError.ThrowNotSupportedError(
"Inserting anonymous content manually is not supported");
return;
}
// Make sure that the inserted node is allowed as a child of its new parent.
EnsureAllowedAsChild(&aNewChild, this, aReplace, aRefChild, aError);
}
nsINode* nsINode::ReplaceOrInsertBefore(bool aReplace, nsINode* aNewChild,
nsINode* aRefChild,
ErrorResult& aError) {
// XXXbz I wish I could assert that nsContentUtils::IsSafeToRunScript() so we
// could rely on scriptblockers going out of scope to actually run XBL
// teardown, but various crud adds nodes under scriptblockers (e.g. native
// anonymous content). The only good news is those insertions can't trigger
// the bad XBL cases.
MOZ_ASSERT_IF(aReplace, aRefChild);
// Before firing DOMNodeRemoved events, make sure this is actually an insert
// we plan to do.
EnsurePreInsertionValidity1(aError);
if (aError.Failed()) {
return nullptr;
}
EnsurePreInsertionValidity2(aReplace, *aNewChild, aRefChild, aError);
if (aError.Failed()) {
return nullptr;
}
uint16_t nodeType = aNewChild->NodeType();
// Before we do anything else, fire all DOMNodeRemoved mutation events
// We do this up front as to avoid having to deal with script running
// at random places further down.
// Scope firing mutation events so that we don't carry any state that
// might be stale
{
nsMutationGuard guard;
// If we're replacing, fire for node-to-be-replaced.
// If aRefChild == aNewChild then we'll fire for it in check below
if (aReplace && aRefChild != aNewChild) {
nsContentUtils::MaybeFireNodeRemoved(aRefChild, this);
}
// If the new node already has a parent, fire for removing from old
// parent
if (nsCOMPtr<nsINode> oldParent = aNewChild->GetParentNode()) {
nsContentUtils::MaybeFireNodeRemoved(aNewChild, oldParent);
}
// If we're inserting a fragment, fire for all the children of the
// fragment
if (nodeType == DOCUMENT_FRAGMENT_NODE) {
static_cast<FragmentOrElement*>(aNewChild)->FireNodeRemovedForChildren();
}
if (guard.Mutated(0)) {
// Re-check the parts of our pre-insertion validity that might depend on
// the tree shape.
EnsurePreInsertionValidity2(aReplace, *aNewChild, aRefChild, aError);
if (aError.Failed()) {
return nullptr;
}
}
}
// Record the node to insert before, if any
nsIContent* nodeToInsertBefore;
if (aReplace) {
nodeToInsertBefore = aRefChild->GetNextSibling();
} else {
// Since aRefChild is our child, it must be an nsIContent object.
nodeToInsertBefore = aRefChild ? aRefChild->AsContent() : nullptr;
}
if (nodeToInsertBefore == aNewChild) {
// We're going to remove aNewChild from its parent, so use its next sibling
// as the node to insert before.
nodeToInsertBefore = nodeToInsertBefore->GetNextSibling();
}
Maybe<AutoTArray<nsCOMPtr<nsIContent>, 50>> fragChildren;
// Remove the new child from the old parent if one exists
nsIContent* newContent = aNewChild->AsContent();
nsCOMPtr<nsINode> oldParent = newContent->GetParentNode();
if (oldParent) {
// Hold a strong ref to nodeToInsertBefore across the removal of newContent
nsCOMPtr<nsINode> kungFuDeathGrip = nodeToInsertBefore;
// Removing a child can run script, via XBL destructors.
nsMutationGuard guard;
// Scope for the mutation batch and scriptblocker, so they go away
// while kungFuDeathGrip is still alive.
{
mozAutoDocUpdate batch(newContent->GetComposedDoc(), true);
nsAutoMutationBatch mb(oldParent, true, true);
// ScriptBlocker ensures previous and next stay alive.
nsIContent* previous = aNewChild->GetPreviousSibling();
nsIContent* next = aNewChild->GetNextSibling();
oldParent->RemoveChildNode(aNewChild->AsContent(), true);
if (nsAutoMutationBatch::GetCurrentBatch() == &mb) {
mb.RemovalDone();
mb.SetPrevSibling(previous);
mb.SetNextSibling(next);
}
}
// We expect one mutation (the removal) to have happened.
if (guard.Mutated(1)) {
// XBL destructors, yuck.
// Verify that newContent has no parent.
if (newContent->GetParentNode()) {
aError.ThrowHierarchyRequestError(
"New child was inserted somewhere else");
return nullptr;
}
// And verify that newContent is still allowed as our child.
if (aNewChild == aRefChild) {
// We've already removed aRefChild. So even if we were doing a replace,
// now we're doing a simple insert before nodeToInsertBefore.
EnsureAllowedAsChild(newContent, this, false, nodeToInsertBefore,
aError);
if (aError.Failed()) {
return nullptr;
}
} else {
EnsureAllowedAsChild(newContent, this, aReplace, aRefChild, aError);
if (aError.Failed()) {
return nullptr;
}
// And recompute nodeToInsertBefore, just in case.
if (aReplace) {
nodeToInsertBefore = aRefChild->GetNextSibling();
} else {
nodeToInsertBefore = aRefChild ? aRefChild->AsContent() : nullptr;
}
}
}
} else if (nodeType == DOCUMENT_FRAGMENT_NODE) {
// Make sure to remove all the fragment's kids. We need to do this before
// we start inserting anything, so we will run out XBL destructors and
// binding teardown (GOD, I HATE THESE THINGS) before we insert anything
// into the DOM.
uint32_t count = newContent->GetChildCount();
fragChildren.emplace();
// Copy the children into a separate array to avoid having to deal with
// mutations to the fragment later on here.
fragChildren->SetCapacity(count);
for (nsIContent* child = newContent->GetFirstChild(); child;
child = child->GetNextSibling()) {
NS_ASSERTION(child->GetUncomposedDoc() == nullptr,
"How did we get a child with a current doc?");
fragChildren->AppendElement(child);
}
// Hold a strong ref to nodeToInsertBefore across the removals
nsCOMPtr<nsINode> kungFuDeathGrip = nodeToInsertBefore;
nsMutationGuard guard;
// Scope for the mutation batch and scriptblocker, so they go away
// while kungFuDeathGrip is still alive.
{
mozAutoDocUpdate batch(newContent->GetComposedDoc(), true);
nsAutoMutationBatch mb(newContent, false, true);
while (newContent->HasChildren()) {
newContent->RemoveChildNode(newContent->GetLastChild(), true);
}
}
// We expect |count| removals
if (guard.Mutated(count)) {
// XBL destructors, yuck.
// Verify that nodeToInsertBefore, if non-null, is still our child. If
// it's not, there's no way we can do this insert sanely; just bail out.
if (nodeToInsertBefore && nodeToInsertBefore->GetParent() != this) {
aError.ThrowHierarchyRequestError("Don't know where to insert child");
return nullptr;
}
// Verify that all the things in fragChildren have no parent.
for (uint32_t i = 0; i < count; ++i) {
if (fragChildren->ElementAt(i)->GetParentNode()) {
aError.ThrowHierarchyRequestError(
"New child was inserted somewhere else");
return nullptr;
}
}
// Note that unlike the single-element case above, none of our kids can
// be aRefChild, so we can always pass through aReplace in the
// EnsureAllowedAsChild checks below and don't have to worry about whether
// recomputing nodeToInsertBefore is OK.
// Verify that our aRefChild is still sensible
if (aRefChild && aRefChild->GetParent() != this) {
aError.ThrowHierarchyRequestError("Don't know where to insert child");
return nullptr;
}
// Recompute nodeToInsertBefore, just in case.
if (aReplace) {
nodeToInsertBefore = aRefChild->GetNextSibling();
} else {
// If aRefChild has 'this' as a parent, it must be an nsIContent.
nodeToInsertBefore = aRefChild ? aRefChild->AsContent() : nullptr;
}
// And verify that newContent is still allowed as our child. Sadly, we
// need to reimplement the relevant part of EnsureAllowedAsChild() because
// now our nodes are in an array and all. If you change this code,
// change the code there.
if (IsDocument()) {
bool sawElement = false;
for (uint32_t i = 0; i < count; ++i) {
nsIContent* child = fragChildren->ElementAt(i);
if (child->IsElement()) {
if (sawElement) {
// No good
aError.ThrowHierarchyRequestError(
"Cannot have more than one Element child of a Document");
return nullptr;
}
sawElement = true;
}
EnsureAllowedAsChild(child, this, aReplace, aRefChild, aError);
if (aError.Failed()) {
return nullptr;
}
}
}
}
}
mozAutoDocUpdate batch(GetComposedDoc(), true);
nsAutoMutationBatch mb;
// If we're replacing and we haven't removed aRefChild yet, do so now
if (aReplace && aRefChild != aNewChild) {
mb.Init(this, true, true);
// Since aRefChild is never null in the aReplace case, we know that at
// this point nodeToInsertBefore is the next sibling of aRefChild.
NS_ASSERTION(aRefChild->GetNextSibling() == nodeToInsertBefore,
"Unexpected nodeToInsertBefore");
nsIContent* toBeRemoved = nodeToInsertBefore
? nodeToInsertBefore->GetPreviousSibling()
: GetLastChild();
MOZ_ASSERT(toBeRemoved);
RemoveChildNode(toBeRemoved, true);
}
// Move new child over to our document if needed. Do this after removing
// it from its parent so that AdoptNode doesn't fire DOMNodeRemoved
// DocumentType nodes are the only nodes that can have a null
// ownerDocument according to the DOM spec, and we need to allow
// inserting them w/o calling AdoptNode().
Document* doc = OwnerDoc();
if (doc != newContent->OwnerDoc() && nodeType != DOCUMENT_FRAGMENT_NODE) {
AdoptNodeIntoOwnerDoc(this, aNewChild, aError);
if (aError.Failed()) {
return nullptr;
}
}
/*
* Check if we're inserting a document fragment. If we are, we need
* to actually add its children individually (i.e. we don't add the
* actual document fragment).
*/
nsINode* result = aReplace ? aRefChild : aNewChild;
if (nodeType == DOCUMENT_FRAGMENT_NODE) {
nsAutoMutationBatch* mutationBatch = nsAutoMutationBatch::GetCurrentBatch();
if (mutationBatch && mutationBatch != &mb) {
mutationBatch = nullptr;
} else if (!aReplace) {
mb.Init(this, true, true);
mutationBatch = nsAutoMutationBatch::GetCurrentBatch();
}
if (mutationBatch) {
mutationBatch->RemovalDone();
mutationBatch->SetPrevSibling(
nodeToInsertBefore ? nodeToInsertBefore->GetPreviousSibling()
: GetLastChild());
mutationBatch->SetNextSibling(nodeToInsertBefore);
}
uint32_t count = fragChildren->Length();
if (!count) {
return result;
}
bool appending = !IsDocument() && !nodeToInsertBefore;
nsIContent* firstInsertedContent = fragChildren->ElementAt(0);
// Iterate through the fragment's children, and insert them in the new
// parent
for (uint32_t i = 0; i < count; ++i) {
// XXXbz how come no reparenting here? That seems odd...
// Insert the child.
InsertChildBefore(fragChildren->ElementAt(i), nodeToInsertBefore,
!appending, aError);
if (aError.Failed()) {
// Make sure to notify on any children that we did succeed to insert
if (appending && i != 0) {
MutationObservers::NotifyContentAppended(
static_cast<nsIContent*>(this), firstInsertedContent);
}
return nullptr;
}
}
if (mutationBatch && !appending) {
mutationBatch->NodesAdded();
}
// Notify and fire mutation events when appending
if (appending) {
MutationObservers::NotifyContentAppended(static_cast<nsIContent*>(this),
firstInsertedContent);
if (mutationBatch) {
mutationBatch->NodesAdded();
}
// Optimize for the case when there are no listeners
if (nsContentUtils::HasMutationListeners(
doc, NS_EVENT_BITS_MUTATION_NODEINSERTED)) {
Element::FireNodeInserted(doc, this, *fragChildren);
}
}
} else {
// Not inserting a fragment but rather a single node.
// We need to reparent here for nodes for which the parent of their
// wrapper is not the wrapper for their ownerDocument (XUL elements,
// form controls, ...). Also applies in the fragment code above.
if (nsAutoMutationBatch::GetCurrentBatch() == &mb) {
mb.RemovalDone();
mb.SetPrevSibling(nodeToInsertBefore
? nodeToInsertBefore->GetPreviousSibling()
: GetLastChild());
mb.SetNextSibling(nodeToInsertBefore);
}
InsertChildBefore(newContent, nodeToInsertBefore, true, aError);
if (aError.Failed()) {
return nullptr;
}
}
return result;
}
void nsINode::BindObject(nsISupports* aObject, UnbindCallback aDtor) {
Slots()->mBoundObjects.EmplaceBack(aObject, aDtor);
}
void nsINode::UnbindObject(nsISupports* aObject) {
if (auto* slots = GetExistingSlots()) {
slots->mBoundObjects.RemoveElement(aObject);
}
}
already_AddRefed<AccessibleNode> nsINode::GetAccessibleNode() {
#ifdef ACCESSIBILITY
nsresult rv = NS_OK;
RefPtr<AccessibleNode> anode =
static_cast<AccessibleNode*>(GetProperty(nsGkAtoms::accessiblenode, &rv));
if (NS_FAILED(rv)) {
anode = new AccessibleNode(this);
RefPtr<AccessibleNode> temp = anode;
rv = SetProperty(nsGkAtoms::accessiblenode, temp.forget().take(),
nsPropertyTable::SupportsDtorFunc, true);
if (NS_FAILED(rv)) {
NS_WARNING("SetProperty failed");
return nullptr;
}
}
return anode.forget();
#else
return nullptr;
#endif
}
void nsINode::AddSizeOfExcludingThis(nsWindowSizes& aSizes,
size_t* aNodeSize) const {
EventListenerManager* elm = GetExistingListenerManager();
if (elm) {
*aNodeSize += elm->SizeOfIncludingThis(aSizes.mState.mMallocSizeOf);
}
// Measurement of the following members may be added later if DMD finds it is
// worthwhile:
// - mNodeInfo
// - mSlots
//
// The following members are not measured:
// - mParent, mNextSibling, mPreviousOrLastSibling, mFirstChild: because
// they're non-owning, from "exclusive ownership" point of view.
}
void nsINode::AddSizeOfIncludingThis(nsWindowSizes& aSizes,
size_t* aNodeSize) const {
*aNodeSize += aSizes.mState.mMallocSizeOf(this);
AddSizeOfExcludingThis(aSizes, aNodeSize);
}
bool nsINode::Contains(const nsINode* aOther) const {
if (aOther == this) {
return true;
}
if (!aOther || OwnerDoc() != aOther->OwnerDoc() ||
IsInUncomposedDoc() != aOther->IsInUncomposedDoc() ||
!aOther->IsContent() || !HasChildren()) {
return false;
}
if (IsDocument()) {
// document.contains(aOther) returns true if aOther is in the document,
// but is not in any anonymous subtree.
// IsInUncomposedDoc() check is done already before this.
return !aOther->IsInNativeAnonymousSubtree();
}
if (!IsElement() && !IsDocumentFragment()) {
return false;
}
if (IsInShadowTree() != aOther->IsInShadowTree() ||
IsInNativeAnonymousSubtree() != aOther->IsInNativeAnonymousSubtree()) {
return false;
}
if (IsInNativeAnonymousSubtree()) {
if (GetClosestNativeAnonymousSubtreeRoot() !=
aOther->GetClosestNativeAnonymousSubtreeRoot()) {
return false;
}
}
if (IsInShadowTree()) {
ShadowRoot* otherRoot = aOther->GetContainingShadow();
if (IsShadowRoot()) {
return otherRoot == this;
}
if (otherRoot != GetContainingShadow()) {
return false;
}
}
return aOther->IsInclusiveDescendantOf(this);
}
uint32_t nsINode::Length() const {
switch (NodeType()) {
case DOCUMENT_TYPE_NODE:
return 0;
case TEXT_NODE:
case CDATA_SECTION_NODE:
case PROCESSING_INSTRUCTION_NODE:
case COMMENT_NODE:
MOZ_ASSERT(IsContent());
return AsContent()->TextLength();
default:
return GetChildCount();
}
}
namespace {
class SelectorCacheKey {
public:
explicit SelectorCacheKey(const nsACString& aString) : mKey(aString) {
MOZ_COUNT_CTOR(SelectorCacheKey);
}
nsCString mKey;
nsExpirationState mState;
nsExpirationState* GetExpirationState() { return &mState; }
MOZ_COUNTED_DTOR(SelectorCacheKey)
};
class SelectorCache final : public nsExpirationTracker<SelectorCacheKey, 4> {
public:
using SelectorList = UniquePtr<StyleSelectorList>;
using Table = nsTHashMap<nsCStringHashKey, SelectorList>;
SelectorCache()
: nsExpirationTracker<SelectorCacheKey, 4>(
1000, "SelectorCache", GetMainThreadSerialEventTarget()) {}
void NotifyExpired(SelectorCacheKey* aSelector) final {
MOZ_ASSERT(NS_IsMainThread());
MOZ_ASSERT(aSelector);
// There is no guarantee that this method won't be re-entered when selector
// matching is ongoing because "memory-pressure" could be notified
// immediately when OOM happens according to the design of
// nsExpirationTracker. The perfect solution is to delete the |aSelector|
// and its StyleSelectorList in mTable asynchronously. We remove these
// objects synchronously for now because NotifyExpired() will never be
// triggered by "memory-pressure" which is not implemented yet in the stage
// 2 of mozalloc_handle_oom(). Once these objects are removed
// asynchronously, we should update the warning added in
// mozalloc_handle_oom() as well.
RemoveObject(aSelector);
mTable.Remove(aSelector->mKey);
delete aSelector;
}
// We do not call MarkUsed because it would just slow down lookups and
// because we're OK expiring things after a few seconds even if they're
// being used. Returns whether we actually had an entry for aSelector.
//
// If we have an entry and the selector list returned has a null
// StyleSelectorList*, that indicates that aSelector has already been
// parsed and is not a syntactically valid selector.
template <typename F>
StyleSelectorList* GetListOrInsertFrom(const nsACString& aSelector,
F&& aFrom) {
MOZ_ASSERT(NS_IsMainThread());
return mTable.LookupOrInsertWith(aSelector, std::forward<F>(aFrom)).get();
}
~SelectorCache() { AgeAllGenerations(); }
private:
Table mTable;
};
SelectorCache& GetSelectorCache(bool aChromeRulesEnabled) {
static StaticAutoPtr<SelectorCache> sSelectorCache;
static StaticAutoPtr<SelectorCache> sChromeSelectorCache;
auto& cache = aChromeRulesEnabled ? sChromeSelectorCache : sSelectorCache;
if (!cache) {
cache = new SelectorCache();
ClearOnShutdown(&cache);
}
return *cache;
}
} // namespace
const StyleSelectorList* nsINode::ParseSelectorList(
const nsACString& aSelectorString, ErrorResult& aRv) {
Document* doc = OwnerDoc();
const bool chromeRulesEnabled = doc->ChromeRulesEnabled();
SelectorCache& cache = GetSelectorCache(chromeRulesEnabled);
StyleSelectorList* list = cache.GetListOrInsertFrom(aSelectorString, [&] {
// Note that we want to cache even if null was returned, because we
// want to cache the "This is not a valid selector" result.
return WrapUnique(
Servo_SelectorList_Parse(&aSelectorString, chromeRulesEnabled));
});
if (!list) {
// Invalid selector.
aRv.ThrowSyntaxError("'"_ns + aSelectorString +
"' is not a valid selector"_ns);
}
return list;
}
// Given an id, find first element with that id under aRoot.
// If none found, return nullptr. aRoot must be in the document.
inline static Element* FindMatchingElementWithId(
const nsAString& aId, const Element& aRoot,
const DocumentOrShadowRoot& aContainingDocOrShadowRoot) {
MOZ_ASSERT(aRoot.SubtreeRoot() == &aContainingDocOrShadowRoot.AsNode());
MOZ_ASSERT(
aRoot.IsInUncomposedDoc() || aRoot.IsInShadowTree(),
"Don't call me if the root is not in the document or in a shadow tree");
const nsTArray<Element*>* elements =
aContainingDocOrShadowRoot.GetAllElementsForId(aId);
if (!elements) {
// Nothing to do; we're done
return nullptr;
}
// XXXbz: Should we fall back to the tree walk if |elements| is long,
// for some value of "long"?
for (Element* element : *elements) {
if (MOZ_UNLIKELY(element == &aRoot)) {
continue;
}
if (!element->IsInclusiveDescendantOf(&aRoot)) {
continue;
}
// We have an element with the right id and it's a strict descendant
// of aRoot.
return element;
}
return nullptr;
}
Element* nsINode::QuerySelector(const nsACString& aSelector,
ErrorResult& aResult) {
AUTO_PROFILER_LABEL_DYNAMIC_NSCSTRING_RELEVANT_FOR_JS(
"querySelector", LAYOUT_SelectorQuery, aSelector);
const StyleSelectorList* list = ParseSelectorList(aSelector, aResult);
if (!list) {
return nullptr;
}
const bool useInvalidation = false;
return const_cast<Element*>(
Servo_SelectorList_QueryFirst(this, list, useInvalidation));
}
already_AddRefed<nsINodeList> nsINode::QuerySelectorAll(
const nsACString& aSelector, ErrorResult& aResult) {
AUTO_PROFILER_LABEL_DYNAMIC_NSCSTRING_RELEVANT_FOR_JS(
"querySelectorAll", LAYOUT_SelectorQuery, aSelector);
RefPtr<nsSimpleContentList> contentList = new nsSimpleContentList(this);
const StyleSelectorList* list = ParseSelectorList(aSelector, aResult);
if (!list) {
return contentList.forget();
}
const bool useInvalidation = false;
Servo_SelectorList_QueryAll(this, list, contentList.get(), useInvalidation);
return contentList.forget();
}
Element* nsINode::GetElementById(const nsAString& aId) {
MOZ_ASSERT(!IsShadowRoot(), "Should use the faster version");
MOZ_ASSERT(IsElement() || IsDocumentFragment(),
"Bogus this object for GetElementById call");
if (IsInUncomposedDoc()) {
MOZ_ASSERT(IsElement(), "Huh? A fragment in a document?");
return FindMatchingElementWithId(aId, *AsElement(), *OwnerDoc());
}
if (ShadowRoot* containingShadow = AsContent()->GetContainingShadow()) {
MOZ_ASSERT(IsElement(), "Huh? A fragment in a ShadowRoot?");
return FindMatchingElementWithId(aId, *AsElement(), *containingShadow);
}
for (nsIContent* kid = GetFirstChild(); kid; kid = kid->GetNextNode(this)) {
if (!kid->IsElement()) {
continue;
}
nsAtom* id = kid->AsElement()->GetID();
if (id && id->Equals(aId)) {
return kid->AsElement();
}
}
return nullptr;
}
JSObject* nsINode::WrapObject(JSContext* aCx,
JS::Handle<JSObject*> aGivenProto) {
// Make sure one of these is true
// (1) our owner document has a script handling object,
// (2) Our owner document has had a script handling object, or has been marked
// to have had one,
// (3) we are running a privileged script.
// Event handling is possible only if (1). If (2) event handling is
// prevented.
// If the document has never had a script handling object, untrusted
// scripts (3) shouldn't touch it!
bool hasHadScriptHandlingObject = false;
if (!OwnerDoc()->GetScriptHandlingObject(hasHadScriptHandlingObject) &&
!hasHadScriptHandlingObject && !nsContentUtils::IsSystemCaller(aCx)) {
Throw(aCx, NS_ERROR_UNEXPECTED);
return nullptr;
}
JS::Rooted<JSObject*> obj(aCx, WrapNode(aCx, aGivenProto));
if (obj && ChromeOnlyAccess()) {
MOZ_RELEASE_ASSERT(
xpc::IsUnprivilegedJunkScope(JS::GetNonCCWObjectGlobal(obj)) ||
xpc::IsInUAWidgetScope(obj) || xpc::AccessCheck::isChrome(obj));
}
return obj;
}
already_AddRefed<nsINode> nsINode::CloneNode(bool aDeep, ErrorResult& aError) {
return Clone(aDeep, nullptr, aError);
}
nsDOMAttributeMap* nsINode::GetAttributes() {
if (!IsElement()) {
return nullptr;
}
return AsElement()->Attributes();
}
Element* nsINode::GetParentElementCrossingShadowRoot() const {
if (!mParent) {
return nullptr;
}
if (mParent->IsElement()) {
return mParent->AsElement();
}
if (ShadowRoot* shadowRoot = ShadowRoot::FromNode(mParent)) {
MOZ_ASSERT(shadowRoot->GetHost(), "ShowRoots should always have a host");
return shadowRoot->GetHost();
}
return nullptr;
}
bool nsINode::HasBoxQuadsSupport(JSContext* aCx, JSObject* /* unused */) {
return xpc::AccessCheck::isChrome(js::GetContextCompartment(aCx)) ||
StaticPrefs::layout_css_getBoxQuads_enabled();
}
nsINode* nsINode::GetScopeChainParent() const { return nullptr; }
Element* nsINode::GetParentFlexElement() {
if (!IsContent()) {
return nullptr;
}
nsIFrame* primaryFrame = AsContent()->GetPrimaryFrame(FlushType::Frames);
// Walk up the parent chain and pierce through any anonymous boxes
// that might be between this frame and a possible flex parent.
for (nsIFrame* f = primaryFrame; f; f = f->GetParent()) {
if (f != primaryFrame && !f->Style()->IsAnonBox()) {
// We hit a non-anonymous ancestor before finding a flex item.
// Bail out.
break;
}
if (f->IsFlexItem()) {
return f->GetParent()->GetContent()->AsElement();
}
}
return nullptr;
}
Element* nsINode::GetNearestInclusiveOpenPopover() const {
for (auto* el : InclusiveFlatTreeAncestorsOfType<Element>()) {
if (el->IsAutoPopover() && el->IsPopoverOpen()) {
return el;
}
}
return nullptr;
}
Element* nsINode::GetNearestInclusiveTargetPopoverForInvoker() const {
for (auto* el : InclusiveFlatTreeAncestorsOfType<Element>()) {
if (auto* popover = el->GetEffectiveInvokeTargetElement()) {
if (popover->IsAutoPopover() && popover->IsPopoverOpen()) {
return popover;
}
}
if (auto* popover = el->GetEffectivePopoverTargetElement()) {
if (popover->IsAutoPopover() && popover->IsPopoverOpen()) {
return popover;
}
}
}
return nullptr;
}
nsGenericHTMLElement* nsINode::GetEffectiveInvokeTargetElement() const {
if (!StaticPrefs::dom_element_invokers_enabled()) {
return nullptr;
}
const auto* formControl =
nsGenericHTMLFormControlElementWithState::FromNode(this);
if (!formControl || formControl->IsDisabled() ||
!formControl->IsButtonControl()) {
return nullptr;
}
if (auto* popover = nsGenericHTMLElement::FromNodeOrNull(
formControl->GetInvokeTargetElement())) {
if (popover->GetPopoverAttributeState() != PopoverAttributeState::None) {
return popover;
}
}
return nullptr;
}
nsGenericHTMLElement* nsINode::GetEffectivePopoverTargetElement() const {
const auto* formControl =
nsGenericHTMLFormControlElementWithState::FromNode(this);
if (!formControl || formControl->IsDisabled() ||
!formControl->IsButtonControl()) {
return nullptr;
}
if (auto* popover = nsGenericHTMLElement::FromNodeOrNull(
formControl->GetPopoverTargetElement())) {
if (popover->GetPopoverAttributeState() != PopoverAttributeState::None) {
return popover;
}
}
return nullptr;
}
Element* nsINode::GetTopmostClickedPopover() const {
Element* clickedPopover = GetNearestInclusiveOpenPopover();
Element* invokedPopover = GetNearestInclusiveTargetPopoverForInvoker();
if (!clickedPopover) {
return invokedPopover;
}
auto autoPopoverList = clickedPopover->OwnerDoc()->AutoPopoverList();
for (Element* el : Reversed(autoPopoverList)) {
if (el == clickedPopover || el == invokedPopover) {
return el;
}
}
return nullptr;
}
void nsINode::AddAnimationObserver(nsIAnimationObserver* aAnimationObserver) {
AddMutationObserver(aAnimationObserver);
OwnerDoc()->SetMayHaveAnimationObservers();
}
void nsINode::AddAnimationObserverUnlessExists(
nsIAnimationObserver* aAnimationObserver) {
AddMutationObserverUnlessExists(aAnimationObserver);
OwnerDoc()->SetMayHaveAnimationObservers();
}
already_AddRefed<nsINode> nsINode::CloneAndAdopt(
nsINode* aNode, bool aClone, bool aDeep,
nsNodeInfoManager* aNewNodeInfoManager,
JS::Handle<JSObject*> aReparentScope, nsINode* aParent,
ErrorResult& aError) {
MOZ_ASSERT((!aClone && aNewNodeInfoManager) || !aReparentScope,
"If cloning or not getting a new nodeinfo we shouldn't rewrap");
MOZ_ASSERT(!aParent || aNode->IsContent(),
"Can't insert document or attribute nodes into a parent");
// First deal with aNode and walk its attributes (and their children). Then,
// if aDeep is true, deal with aNode's children (and recurse into their
// attributes and children).
nsAutoScriptBlocker scriptBlocker;
nsNodeInfoManager* nodeInfoManager = aNewNodeInfoManager;
// aNode.
class NodeInfo* nodeInfo = aNode->mNodeInfo;
RefPtr<class NodeInfo> newNodeInfo;
if (nodeInfoManager) {
// Don't allow importing/adopting nodes from non-privileged "scriptable"
// documents to "non-scriptable" documents.
Document* newDoc = nodeInfoManager->GetDocument();
if (NS_WARN_IF(!newDoc)) {
aError.Throw(NS_ERROR_UNEXPECTED);
return nullptr;
}
bool hasHadScriptHandlingObject = false;
if (!newDoc->GetScriptHandlingObject(hasHadScriptHandlingObject) &&
!hasHadScriptHandlingObject) {
Document* currentDoc = aNode->OwnerDoc();
if (NS_WARN_IF(!nsContentUtils::IsChromeDoc(currentDoc) &&
(currentDoc->GetScriptHandlingObject(
hasHadScriptHandlingObject) ||
hasHadScriptHandlingObject))) {
aError.Throw(NS_ERROR_UNEXPECTED);
return nullptr;
}
}
newNodeInfo = nodeInfoManager->GetNodeInfo(
nodeInfo->NameAtom(), nodeInfo->GetPrefixAtom(),
nodeInfo->NamespaceID(), nodeInfo->NodeType(),
nodeInfo->GetExtraName());
nodeInfo = newNodeInfo;
}
Element* elem = Element::FromNode(aNode);
nsCOMPtr<nsINode> clone;
if (aClone) {
nsresult rv = aNode->Clone(nodeInfo, getter_AddRefs(clone));
if (NS_WARN_IF(NS_FAILED(rv))) {
aError.Throw(rv);
return nullptr;
}
if (aParent) {
// If we're cloning we need to insert the cloned children into the cloned
// parent.
aParent->AppendChildTo(static_cast<nsIContent*>(clone.get()),
/* aNotify = */ true, aError);
if (NS_WARN_IF(aError.Failed())) {
return nullptr;
}
} else if (aDeep && clone->IsDocument()) {
// After cloning the document itself, we want to clone the children into
// the cloned document (somewhat like cloning and importing them into the
// cloned document).
nodeInfoManager = clone->mNodeInfo->NodeInfoManager();
}
} else if (nodeInfoManager) {
Document* oldDoc = aNode->OwnerDoc();
DOMArena* domArenaToStore =
!aNode->HasFlag(NODE_KEEPS_DOMARENA)
? aNode->NodeInfo()->NodeInfoManager()->GetArenaAllocator()
: nullptr;
Document* newDoc = nodeInfoManager->GetDocument();
MOZ_ASSERT(newDoc);
bool wasRegistered = false;
if (elem) {
wasRegistered = oldDoc->UnregisterActivityObserver(elem);
}
const bool hadProperties = aNode->HasProperties();
if (hadProperties) {
// NOTE: We want this to happen before NodeInfoChanged so that
// NodeInfoChanged can use node properties normally.
//
// When this fails, it removes all properties for the node anyway, so no
// extra error handling needed.
Unused << oldDoc->PropertyTable().TransferOrRemoveAllPropertiesFor(
aNode, newDoc->PropertyTable());
}
aNode->mNodeInfo.swap(newNodeInfo);
aNode->NodeInfoChanged(oldDoc);
MOZ_ASSERT(newDoc != oldDoc);
if (elem) {
// Adopted callback must be enqueued whenever a node’s
// shadow-including inclusive descendants that is custom.
CustomElementData* data = elem->GetCustomElementData();
if (data && data->mState == CustomElementData::State::eCustom) {
LifecycleCallbackArgs args;
args.mOldDocument = oldDoc;
args.mNewDocument = newDoc;
nsContentUtils::EnqueueLifecycleCallback(ElementCallbackType::eAdopted,
elem, args);
}
}
// XXX what if oldDoc is null, we don't know if this should be
// registered or not! Can that really happen?
if (wasRegistered) {
newDoc->RegisterActivityObserver(aNode->AsElement());
}
if (nsPIDOMWindowInner* window = newDoc->GetInnerWindow()) {
EventListenerManager* elm = aNode->GetExistingListenerManager();
if (elm) {
window->SetMutationListeners(elm->MutationListenerBits());
if (elm->MayHaveDOMActivateListeners()) {
window->SetHasDOMActivateEventListeners();
}
if (elm->MayHavePaintEventListener()) {
window->SetHasPaintEventListeners();
}
if (elm->MayHaveTouchEventListener()) {
window->SetHasTouchEventListeners();
}
if (elm->MayHaveMouseEnterLeaveEventListener()) {
window->SetHasMouseEnterLeaveEventListeners();
}
if (elm->MayHavePointerEnterLeaveEventListener()) {
window->SetHasPointerEnterLeaveEventListeners();
}
if (elm->MayHaveSelectionChangeEventListener()) {
window->SetHasSelectionChangeEventListeners();
}
if (elm->MayHaveFormSelectEventListener()) {
window->SetHasFormSelectEventListeners();
}
if (elm->MayHaveTransitionEventListener()) {
window->SetHasTransitionEventListeners();
}
if (elm->MayHaveSMILTimeEventListener()) {
window->SetHasSMILTimeEventListeners();
}
}
}
if (wasRegistered) {
nsIContent* content = aNode->AsContent();
if (auto* mediaElem = HTMLMediaElement::FromNodeOrNull(content)) {
mediaElem->NotifyOwnerDocumentActivityChanged();
}
// HTMLImageElement::FromNode is insufficient since we need this for
// <svg:image> as well.
nsCOMPtr<nsIImageLoadingContent> imageLoadingContent =
do_QueryInterface(aNode);
if (imageLoadingContent) {
auto* ilc =
static_cast<nsImageLoadingContent*>(imageLoadingContent.get());
ilc->NotifyOwnerDocumentActivityChanged();
}
}
if (oldDoc->MayHaveDOMMutationObservers()) {
newDoc->SetMayHaveDOMMutationObservers();
}
if (oldDoc->MayHaveAnimationObservers()) {
newDoc->SetMayHaveAnimationObservers();
}
if (elem) {
elem->RecompileScriptEventListeners();
}
if (aReparentScope) {
AutoJSContext cx;
JS::Rooted<JSObject*> wrapper(cx);
if ((wrapper = aNode->GetWrapper())) {
MOZ_ASSERT(IsDOMObject(wrapper));
JSAutoRealm ar(cx, wrapper);
UpdateReflectorGlobal(cx, wrapper, aError);
if (aError.Failed()) {
if (wasRegistered) {
newDoc->UnregisterActivityObserver(aNode->AsElement());
}
if (hadProperties) {
// NOTE: When it fails it removes all properties for the node
// anyway, so no extra error handling needed.
Unused << newDoc->PropertyTable().TransferOrRemoveAllPropertiesFor(
aNode, oldDoc->PropertyTable());
}
aNode->mNodeInfo.swap(newNodeInfo);
aNode->NodeInfoChanged(newDoc);
if (wasRegistered) {
oldDoc->RegisterActivityObserver(aNode->AsElement());
}
return nullptr;
}
}
}
// At this point, a new node is added to the document, and this
// node isn't allocated by the NodeInfoManager of this document,
// so we need to do this SetArenaAllocator logic to bypass
// the !HasChildren() check in NodeInfoManager::Allocate.
if (mozilla::StaticPrefs::dom_arena_allocator_enabled_AtStartup()) {
if (!newDoc->NodeInfoManager()->HasAllocated()) {
if (DocGroup* docGroup = newDoc->GetDocGroup()) {
newDoc->NodeInfoManager()->SetArenaAllocator(
docGroup->ArenaAllocator());
}
}
if (domArenaToStore && newDoc->GetDocGroup() != oldDoc->GetDocGroup()) {
nsContentUtils::AddEntryToDOMArenaTable(aNode, domArenaToStore);
}
}
}
if (aDeep && (!aClone || !aNode->IsAttr())) {
// aNode's children.
for (nsIContent* cloneChild = aNode->GetFirstChild(); cloneChild;
cloneChild = cloneChild->GetNextSibling()) {
nsCOMPtr<nsINode> child =
CloneAndAdopt(cloneChild, aClone, true, nodeInfoManager,
aReparentScope, clone, aError);
if (NS_WARN_IF(aError.Failed())) {
return nullptr;
}
}
}
if (aDeep && aNode->IsElement()) {
if (aClone) {
if (nodeInfo->GetDocument()->IsStaticDocument()) {
// Clone any animations to the node in the static document, including
// the current timing. They will need to be paused later after the new
// document's pres shell gets initialized.
//
// This needs to be done here rather than in Element::CopyInnerTo
// because the animations clone code relies on the target (that is,
// `clone`) being connected already.
clone->AsElement()->CloneAnimationsFrom(*aNode->AsElement());
// Clone the Shadow DOM
ShadowRoot* originalShadowRoot = aNode->AsElement()->GetShadowRoot();
if (originalShadowRoot) {
RefPtr<ShadowRoot> newShadowRoot =
clone->AsElement()->AttachShadowWithoutNameChecks(
originalShadowRoot->Mode());
newShadowRoot->CloneInternalDataFrom(originalShadowRoot);
for (nsIContent* origChild = originalShadowRoot->GetFirstChild();
origChild; origChild = origChild->GetNextSibling()) {
nsCOMPtr<nsINode> child =
CloneAndAdopt(origChild, aClone, aDeep, nodeInfoManager,
aReparentScope, newShadowRoot, aError);
if (NS_WARN_IF(aError.Failed())) {
return nullptr;
}
}
}
}
} else {
if (ShadowRoot* shadowRoot = aNode->AsElement()->GetShadowRoot()) {
nsCOMPtr<nsINode> child =
CloneAndAdopt(shadowRoot, aClone, aDeep, nodeInfoManager,
aReparentScope, clone, aError);
if (NS_WARN_IF(aError.Failed())) {
return nullptr;
}
}
}
}
if (aClone && aNode->IsElement() &&
!nodeInfo->GetDocument()->IsStaticDocument()) {
// Clone the Shadow DOM
ShadowRoot* originalShadowRoot = aNode->AsElement()->GetShadowRoot();
if (originalShadowRoot && originalShadowRoot->Clonable()) {
ShadowRootInit init;
init.mMode = originalShadowRoot->Mode();
init.mDelegatesFocus = originalShadowRoot->DelegatesFocus();
init.mSlotAssignment = originalShadowRoot->SlotAssignment();
init.mClonable = true;
RefPtr<ShadowRoot> newShadowRoot =
clone->AsElement()->AttachShadow(init, aError);
if (NS_WARN_IF(aError.Failed())) {
return nullptr;
}
newShadowRoot->SetIsDeclarative(originalShadowRoot->IsDeclarative());
for (nsIContent* origChild = originalShadowRoot->GetFirstChild();
origChild; origChild = origChild->GetNextSibling()) {
nsCOMPtr<nsINode> child =
CloneAndAdopt(origChild, aClone, true, nodeInfoManager,
aReparentScope, newShadowRoot, aError);
if (NS_WARN_IF(aError.Failed())) {
return nullptr;
}
}
}
}
// Cloning template element.
if (aDeep && aClone && aNode->IsTemplateElement()) {
DocumentFragment* origContent =
static_cast<HTMLTemplateElement*>(aNode)->Content();
DocumentFragment* cloneContent =
static_cast<HTMLTemplateElement*>(clone.get())->Content();
// Clone the children into the clone's template content owner
// document's nodeinfo manager.
nsNodeInfoManager* ownerNodeInfoManager =
cloneContent->mNodeInfo->NodeInfoManager();
for (nsIContent* cloneChild = origContent->GetFirstChild(); cloneChild;
cloneChild = cloneChild->GetNextSibling()) {
nsCOMPtr<nsINode> child =
CloneAndAdopt(cloneChild, aClone, aDeep, ownerNodeInfoManager,
aReparentScope, cloneContent, aError);
if (NS_WARN_IF(aError.Failed())) {
return nullptr;
}
}
}
return clone.forget();
}
void nsINode::Adopt(nsNodeInfoManager* aNewNodeInfoManager,
JS::Handle<JSObject*> aReparentScope,
mozilla::ErrorResult& aError) {
if (aNewNodeInfoManager) {
Document* beforeAdoptDoc = OwnerDoc();
Document* afterAdoptDoc = aNewNodeInfoManager->GetDocument();
MOZ_ASSERT(beforeAdoptDoc);
MOZ_ASSERT(afterAdoptDoc);
MOZ_ASSERT(beforeAdoptDoc != afterAdoptDoc);
if (afterAdoptDoc->GetDocGroup() != beforeAdoptDoc->GetDocGroup()) {
// the restriction to chrome level documents because web extensions
// rely on content to content node adoption.
if (nsContentUtils::IsChromeDoc(afterAdoptDoc) ||
nsContentUtils::IsChromeDoc(beforeAdoptDoc)) {
return aError.ThrowSecurityError(
"Adopting nodes across docgroups in chrome documents "
"is unsupported");
}
}
}
// Just need to store the return value of CloneAndAdopt in a
// temporary nsCOMPtr to make sure we release it.
nsCOMPtr<nsINode> node = CloneAndAdopt(this, false, true, aNewNodeInfoManager,
aReparentScope, nullptr, aError);
nsMutationGuard::DidMutate();
}
already_AddRefed<nsINode> nsINode::Clone(bool aDeep,
nsNodeInfoManager* aNewNodeInfoManager,
ErrorResult& aError) {
return CloneAndAdopt(this, true, aDeep, aNewNodeInfoManager, nullptr, nullptr,
aError);
}
void nsINode::GenerateXPath(nsAString& aResult) {
XPathGenerator::Generate(this, aResult);
}
bool nsINode::IsApzAware() const { return IsNodeApzAware(); }
bool nsINode::IsNodeApzAwareInternal() const {
return EventTarget::IsApzAware();
}
DocGroup* nsINode::GetDocGroup() const { return OwnerDoc()->GetDocGroup(); }
nsINode* nsINode::GetFlattenedTreeParentNodeNonInline() const {
return GetFlattenedTreeParentNode();
}
ParentObject nsINode::GetParentObject() const {
ParentObject p(OwnerDoc());
// Note that mReflectionScope is a no-op for chrome, and other places where we
// don't check this value.
if (IsInNativeAnonymousSubtree()) {
if (ShouldUseUAWidgetScope(this)) {
p.mReflectionScope = ReflectionScope::UAWidget;
} else {
MOZ_ASSERT(ShouldUseNACScope(this));
p.mReflectionScope = ReflectionScope::NAC;
}
} else {
MOZ_ASSERT(!ShouldUseNACScope(this));
MOZ_ASSERT(!ShouldUseUAWidgetScope(this));
}
return p;
}
void nsINode::AddMutationObserver(
nsMultiMutationObserver* aMultiMutationObserver) {
if (aMultiMutationObserver) {
NS_ASSERTION(!aMultiMutationObserver->ContainsNode(this),
"Observer already in the list");
aMultiMutationObserver->AddMutationObserverToNode(this);
}
}
void nsINode::AddMutationObserverUnlessExists(
nsMultiMutationObserver* aMultiMutationObserver) {
if (aMultiMutationObserver && !aMultiMutationObserver->ContainsNode(this)) {
aMultiMutationObserver->AddMutationObserverToNode(this);
}
}
void nsINode::RemoveMutationObserver(
nsMultiMutationObserver* aMultiMutationObserver) {
if (aMultiMutationObserver) {
aMultiMutationObserver->RemoveMutationObserverFromNode(this);
}
}
void nsINode::FireNodeRemovedForChildren() {
Document* doc = OwnerDoc();
// Optimize the common case
if (!nsContentUtils::HasMutationListeners(
doc, NS_EVENT_BITS_MUTATION_NODEREMOVED)) {
return;
}
nsCOMPtr<nsINode> child;
for (child = GetFirstChild(); child && child->GetParentNode() == this;
child = child->GetNextSibling()) {
nsContentUtils::MaybeFireNodeRemoved(child, this);
}
}
ShadowRoot* nsINode::GetShadowRoot() const {
return IsContent() ? AsContent()->GetShadowRoot() : nullptr;
}
ShadowRoot* nsINode::GetShadowRootForSelection() const {
if (!StaticPrefs::dom_shadowdom_selection_across_boundary_enabled()) {
return nullptr;
}
ShadowRoot* shadowRoot = GetShadowRoot();
if (!shadowRoot) {
return nullptr;
}
// ie. <details> and <video>
if (shadowRoot->IsUAWidget()) {
return nullptr;
}
// ie. <use> element
if (IsElement() && !AsElement()->CanAttachShadowDOM()) {
return nullptr;
}
return shadowRoot;
}
NS_IMPL_ISUPPORTS(nsNodeWeakReference, nsIWeakReference)
nsNodeWeakReference::nsNodeWeakReference(nsINode* aNode)
: nsIWeakReference(aNode) {}
nsNodeWeakReference::~nsNodeWeakReference() {
nsINode* node = static_cast<nsINode*>(mObject);
if (node) {
NS_ASSERTION(node->Slots()->mWeakReference == this,
"Weak reference has wrong value");
node->Slots()->mWeakReference = nullptr;
}
}
NS_IMETHODIMP
nsNodeWeakReference::QueryReferentFromScript(const nsIID& aIID,
void** aInstancePtr) {
return QueryReferent(aIID, aInstancePtr);
}
size_t nsNodeWeakReference::SizeOfOnlyThis(
mozilla::MallocSizeOf aMallocSizeOf) {
return aMallocSizeOf(this);
}