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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
/*
* Implementation of the DOM Range object.
*/
#include "RangeBoundary.h"
#include "nscore.h"
#include "nsRange.h"
#include "nsDebug.h"
#include "nsString.h"
#include "nsReadableUtils.h"
#include "nsIContent.h"
#include "mozilla/dom/Document.h"
#include "nsError.h"
#include "nsINodeList.h"
#include "nsGkAtoms.h"
#include "nsContentUtils.h"
#include "nsFrameSelection.h"
#include "nsLayoutUtils.h"
#include "nsTextFrame.h"
#include "nsContainerFrame.h"
#include "mozilla/Assertions.h"
#include "mozilla/CheckedInt.h"
#include "mozilla/ContentIterator.h"
#include "mozilla/dom/CharacterData.h"
#include "mozilla/dom/ChildIterator.h"
#include "mozilla/dom/DOMRect.h"
#include "mozilla/dom/DOMStringList.h"
#include "mozilla/dom/DocumentFragment.h"
#include "mozilla/dom/DocumentType.h"
#include "mozilla/dom/RangeBinding.h"
#include "mozilla/dom/Selection.h"
#include "mozilla/dom/Text.h"
#include "mozilla/dom/TrustedTypeUtils.h"
#include "mozilla/dom/TrustedTypesConstants.h"
#include "mozilla/Logging.h"
#include "mozilla/Maybe.h"
#include "mozilla/PresShell.h"
#include "mozilla/RangeUtils.h"
#include "mozilla/Telemetry.h"
#include "mozilla/ToString.h"
#include "mozilla/UniquePtr.h"
#include "mozilla/Likely.h"
#include "nsCSSFrameConstructor.h"
#include "nsStyleStruct.h"
#include "nsStyleStructInlines.h"
#include "nsComputedDOMStyle.h"
#include "mozilla/dom/InspectorFontFace.h"
#ifdef ACCESSIBILITY
# include "nsAccessibilityService.h"
#endif
namespace mozilla {
extern LazyLogModule sSelectionAPILog;
extern void LogStackForSelectionAPI();
template <typename SPT, typename SRT, typename EPT, typename ERT>
static void LogSelectionAPI(const dom::Selection* aSelection,
const char* aFuncName, const char* aArgName1,
const RangeBoundaryBase<SPT, SRT>& aBoundary1,
const char* aArgName2,
const RangeBoundaryBase<EPT, ERT>& aBoundary2,
const char* aArgName3, bool aBoolArg) {
if (aBoundary1 == aBoundary2) {
MOZ_LOG(sSelectionAPILog, LogLevel::Info,
("%p nsRange::%s(%s=%s=%s, %s=%s)", aSelection, aFuncName,
aArgName1, aArgName2, ToString(aBoundary1).c_str(), aArgName3,
aBoolArg ? "true" : "false"));
} else {
MOZ_LOG(
sSelectionAPILog, LogLevel::Info,
("%p nsRange::%s(%s=%s, %s=%s, %s=%s)", aSelection, aFuncName,
aArgName1, ToString(aBoundary1).c_str(), aArgName2,
ToString(aBoundary2).c_str(), aArgName3, aBoolArg ? "true" : "false"));
}
}
} // namespace mozilla
using namespace mozilla;
using namespace mozilla::dom;
template already_AddRefed<nsRange> nsRange::Create(
const RangeBoundary& aStartBoundary, const RangeBoundary& aEndBoundary,
ErrorResult& aRv);
template already_AddRefed<nsRange> nsRange::Create(
const RangeBoundary& aStartBoundary, const RawRangeBoundary& aEndBoundary,
ErrorResult& aRv);
template already_AddRefed<nsRange> nsRange::Create(
const RawRangeBoundary& aStartBoundary, const RangeBoundary& aEndBoundary,
ErrorResult& aRv);
template already_AddRefed<nsRange> nsRange::Create(
const RawRangeBoundary& aStartBoundary,
const RawRangeBoundary& aEndBoundary, ErrorResult& aRv);
template nsresult nsRange::SetStartAndEnd(const RangeBoundary& aStartBoundary,
const RangeBoundary& aEndBoundary);
template nsresult nsRange::SetStartAndEnd(const RangeBoundary& aStartBoundary,
const RawRangeBoundary& aEndBoundary);
template nsresult nsRange::SetStartAndEnd(
const RawRangeBoundary& aStartBoundary, const RangeBoundary& aEndBoundary);
template nsresult nsRange::SetStartAndEnd(
const RawRangeBoundary& aStartBoundary,
const RawRangeBoundary& aEndBoundary);
template void nsRange::DoSetRange(const RangeBoundary& aStartBoundary,
const RangeBoundary& aEndBoundary,
nsINode* aRootNode, bool aNotInsertedYet,
RangeBehaviour aRangeBehaviour);
template void nsRange::DoSetRange(const RangeBoundary& aStartBoundary,
const RawRangeBoundary& aEndBoundary,
nsINode* aRootNode, bool aNotInsertedYet,
RangeBehaviour aRangeBehaviour);
template void nsRange::DoSetRange(const RawRangeBoundary& aStartBoundary,
const RangeBoundary& aEndBoundary,
nsINode* aRootNode, bool aNotInsertedYet,
RangeBehaviour aRangeBehaviour);
template void nsRange::DoSetRange(const RawRangeBoundary& aStartBoundary,
const RawRangeBoundary& aEndBoundary,
nsINode* aRootNode, bool aNotInsertedYet,
RangeBehaviour aRangeBehaviour);
template void nsRange::CreateOrUpdateCrossShadowBoundaryRangeIfNeeded(
const RangeBoundary& aStartBoundary, const RangeBoundary& aEndBoundary);
template void nsRange::CreateOrUpdateCrossShadowBoundaryRangeIfNeeded(
const RangeBoundary& aStartBoundary, const RawRangeBoundary& aEndBoundary);
template void nsRange::CreateOrUpdateCrossShadowBoundaryRangeIfNeeded(
const RawRangeBoundary& aStartBoundary, const RangeBoundary& aEndBoundary);
template void nsRange::CreateOrUpdateCrossShadowBoundaryRangeIfNeeded(
const RawRangeBoundary& aStartBoundary,
const RawRangeBoundary& aEndBoundary);
JSObject* nsRange::WrapObject(JSContext* aCx,
JS::Handle<JSObject*> aGivenProto) {
return Range_Binding::Wrap(aCx, this, aGivenProto);
}
DocGroup* nsRange::GetDocGroup() const {
return mOwner ? mOwner->GetDocGroup() : nullptr;
}
/******************************************************
* stack based utility class for managing monitor
******************************************************/
static void InvalidateAllFrames(nsINode* aNode) {
MOZ_ASSERT(aNode, "bad arg");
nsIFrame* frame = nullptr;
switch (aNode->NodeType()) {
case nsINode::TEXT_NODE:
case nsINode::ELEMENT_NODE: {
nsIContent* content = static_cast<nsIContent*>(aNode);
frame = content->GetPrimaryFrame();
break;
}
case nsINode::DOCUMENT_NODE: {
Document* doc = static_cast<Document*>(aNode);
PresShell* presShell = doc ? doc->GetPresShell() : nullptr;
frame = presShell ? presShell->GetRootFrame() : nullptr;
break;
}
}
for (nsIFrame* f = frame; f; f = f->GetNextContinuation()) {
f->InvalidateFrameSubtree();
}
}
/******************************************************
* constructor/destructor
******************************************************/
nsTArray<RefPtr<nsRange>>* nsRange::sCachedRanges = nullptr;
nsRange::~nsRange() {
NS_ASSERTION(!IsInAnySelection(), "deleting nsRange that is in use");
// we want the side effects (releases and list removals)
DoSetRange(RawRangeBoundary(), RawRangeBoundary(), nullptr);
}
nsRange::nsRange(nsINode* aNode)
: AbstractRange(aNode, /* aIsDynamicRange = */ true),
mNextStartRef(nullptr),
mNextEndRef(nullptr) {
// printf("Size of nsRange: %zu\n", sizeof(nsRange));
static_assert(sizeof(nsRange) <= 248,
"nsRange size shouldn't be increased as far as possible");
}
/* static */
already_AddRefed<nsRange> nsRange::Create(nsINode* aNode) {
MOZ_ASSERT(aNode);
if (!sCachedRanges || sCachedRanges->IsEmpty()) {
return do_AddRef(new nsRange(aNode));
}
RefPtr<nsRange> range = sCachedRanges->PopLastElement().forget();
range->Init(aNode);
return range.forget();
}
/* static */
template <typename SPT, typename SRT, typename EPT, typename ERT>
already_AddRefed<nsRange> nsRange::Create(
const RangeBoundaryBase<SPT, SRT>& aStartBoundary,
const RangeBoundaryBase<EPT, ERT>& aEndBoundary, ErrorResult& aRv) {
// If we fail to initialize the range a lot, nsRange should have a static
// initializer since the allocation cost is not cheap in hot path.
RefPtr<nsRange> range = nsRange::Create(aStartBoundary.Container());
aRv = range->SetStartAndEnd(aStartBoundary, aEndBoundary);
if (NS_WARN_IF(aRv.Failed())) {
return nullptr;
}
return range.forget();
}
/*
* When a new boundary is given to a nsRange, compare its position with other
* existing boundaries to see if we need to collapse the end points.
*
* aRange: The nsRange that aNewBoundary is being set to.
* aNewRoot: The shadow-including root of the container of aNewBoundary
* aNewBoundary: The new boundary
* aIsSetStart: true if GetRangeBehaviour is called by nsRange::SetStart,
* false otherwise
* aAllowCrossShadowBoundary: Indicates whether the boundaries allowed to cross
* shadow boundary or not
*/
static RangeBehaviour GetRangeBehaviour(
const nsRange* aRange, const nsINode* aNewRoot,
const RawRangeBoundary& aNewBoundary, const bool aIsSetStart,
AllowRangeCrossShadowBoundary aAllowCrossShadowBoundary) {
if (!aRange->IsPositioned()) {
return RangeBehaviour::CollapseDefaultRangeAndCrossShadowBoundaryRanges;
}
MOZ_ASSERT(aRange->GetRoot());
if (aNewRoot != aRange->GetRoot()) {
// Boundaries are in different document (or not connected), so collapse
// the both the default range and the crossBoundaryRange range.
if (aNewRoot->GetComposedDoc() != aRange->GetRoot()->GetComposedDoc()) {
return RangeBehaviour::CollapseDefaultRangeAndCrossShadowBoundaryRanges;
}
// Always collapse both ranges if the one of the roots is an UA widget
// regardless whether the boundaries are allowed to cross shadow boundary
// or not.
if (AbstractRange::IsRootUAWidget(aNewRoot) ||
AbstractRange::IsRootUAWidget(aRange->GetRoot())) {
return RangeBehaviour::CollapseDefaultRangeAndCrossShadowBoundaryRanges;
}
if (const CrossShadowBoundaryRange* crossShadowBoundaryRange =
aRange->GetCrossShadowBoundaryRange()) {
// Check if the existing-other-side boundary in
// aRange::mCrossShadowBoundaryRange has the same root
// as aNewRoot. If this is the case, it means default range
// is good enough to represent this range, so that we can
// merge the cross-shadow-boundary range and the default range.
const RangeBoundary& otherSideExistingBoundary =
aIsSetStart ? crossShadowBoundaryRange->EndRef()
: crossShadowBoundaryRange->StartRef();
const nsINode* otherSideRoot =
RangeUtils::ComputeRootNode(otherSideExistingBoundary.Container());
if (aNewRoot == otherSideRoot) {
return RangeBehaviour::MergeDefaultRangeAndCrossShadowBoundaryRanges;
}
}
// Different root, but same document. So we only collapse the
// default range if boundaries are allowed to cross shadow boundary.
return aAllowCrossShadowBoundary == AllowRangeCrossShadowBoundary::Yes
? RangeBehaviour::CollapseDefaultRange
: RangeBehaviour::
CollapseDefaultRangeAndCrossShadowBoundaryRanges;
}
const RangeBoundary& otherSideExistingBoundary =
aIsSetStart ? aRange->EndRef() : aRange->StartRef();
// Both bondaries are in the same root, now check for their position
const Maybe<int32_t> order =
aIsSetStart ? nsContentUtils::ComparePoints(aNewBoundary,
otherSideExistingBoundary)
: nsContentUtils::ComparePoints(otherSideExistingBoundary,
aNewBoundary);
if (order) {
if (*order != 1) {
// aNewBoundary is at a valid position.
//
// If aIsSetStart is true, this means
// aNewBoundary <= otherSideExistingBoundary which is
// good because aNewBoundary intends to be the start.
//
// If aIsSetStart is false, this means
// otherSideExistingBoundary <= aNewBoundary which is good because
// aNewBoundary intends to be the end.
//
// So no collapse for above cases.
return RangeBehaviour::KeepDefaultRangeAndCrossShadowBoundaryRanges;
}
if (!aRange->MayCrossShadowBoundary() ||
aAllowCrossShadowBoundary == AllowRangeCrossShadowBoundary::No) {
return RangeBehaviour::CollapseDefaultRangeAndCrossShadowBoundaryRanges;
}
const RangeBoundary& otherSideExistingCrossShadowBoundaryBoundary =
aIsSetStart ? aRange->MayCrossShadowBoundaryEndRef()
: aRange->MayCrossShadowBoundaryStartRef();
// Please see the comment for (*order != 1) to see what "valid" means.
//
// We reach to this line when (*order == 1), it means aNewBoundary is
// at an invalid position, so we need to collapse aNewBoundary with
// otherSideExistingBoundary. However, it's possible that aNewBoundary
// is valid with the otherSideExistingCrossShadowBoundaryBoundary.
const Maybe<int32_t> withCrossShadowBoundaryOrder =
aIsSetStart
? nsContentUtils::ComparePoints(
aNewBoundary, otherSideExistingCrossShadowBoundaryBoundary)
: nsContentUtils::ComparePoints(
otherSideExistingCrossShadowBoundaryBoundary, aNewBoundary);
// Valid to the cross boundary boundary.
if (withCrossShadowBoundaryOrder && *withCrossShadowBoundaryOrder != 1) {
return RangeBehaviour::CollapseDefaultRange;
}
// Not valid to both existing boundaries.
return RangeBehaviour::CollapseDefaultRangeAndCrossShadowBoundaryRanges;
}
MOZ_ASSERT_UNREACHABLE();
return RangeBehaviour::CollapseDefaultRangeAndCrossShadowBoundaryRanges;
}
/******************************************************
* nsISupports
******************************************************/
NS_IMPL_CYCLE_COLLECTING_ADDREF(nsRange)
NS_IMPL_CYCLE_COLLECTING_RELEASE_WITH_INTERRUPTABLE_LAST_RELEASE(
nsRange, DoSetRange(RawRangeBoundary(), RawRangeBoundary(), nullptr),
MaybeInterruptLastRelease())
// QueryInterface implementation for nsRange
NS_INTERFACE_MAP_BEGIN_CYCLE_COLLECTION(nsRange)
NS_INTERFACE_MAP_ENTRY(nsIMutationObserver)
NS_INTERFACE_MAP_END_INHERITING(AbstractRange)
NS_IMPL_CYCLE_COLLECTION_CLASS(nsRange)
NS_IMPL_CYCLE_COLLECTION_UNLINK_BEGIN_INHERITED(nsRange, AbstractRange)
// `Reset()` unlinks `mStart`, `mEnd` and `mRoot`.
NS_IMPL_CYCLE_COLLECTION_UNLINK(mCrossShadowBoundaryRange);
tmp->Reset();
NS_IMPL_CYCLE_COLLECTION_UNLINK_END
NS_IMPL_CYCLE_COLLECTION_TRAVERSE_BEGIN_INHERITED(nsRange, AbstractRange)
NS_IMPL_CYCLE_COLLECTION_TRAVERSE(mRoot)
NS_IMPL_CYCLE_COLLECTION_TRAVERSE(mCrossShadowBoundaryRange);
NS_IMPL_CYCLE_COLLECTION_TRAVERSE_END
NS_IMPL_CYCLE_COLLECTION_TRACE_BEGIN_INHERITED(nsRange, AbstractRange)
NS_IMPL_CYCLE_COLLECTION_TRACE_END
bool nsRange::MaybeInterruptLastRelease() {
bool interrupt = AbstractRange::MaybeCacheToReuse(*this);
ResetCrossShadowBoundaryRange();
MOZ_ASSERT(!interrupt || IsCleared());
return interrupt;
}
void nsRange::AdjustNextRefsOnCharacterDataSplit(
const nsIContent& aContent, const CharacterDataChangeInfo& aInfo) {
// If the splitted text node is immediately before a range boundary point
// that refers to a child index (i.e. its parent is the boundary container)
// then we need to adjust the corresponding boundary to account for the new
// text node that will be inserted. However, because the new sibling hasn't
// been inserted yet, that would result in an invalid boundary. Therefore,
// we store the new child in mNext*Ref to make sure we adjust the boundary
// in the next ContentInserted or ContentAppended call.
nsINode* parentNode = aContent.GetParentNode();
if (parentNode == mEnd.Container()) {
if (&aContent == mEnd.Ref()) {
MOZ_ASSERT(aInfo.mDetails->mNextSibling);
mNextEndRef = aInfo.mDetails->mNextSibling;
}
}
if (parentNode == mStart.Container()) {
if (&aContent == mStart.Ref()) {
MOZ_ASSERT(aInfo.mDetails->mNextSibling);
mNextStartRef = aInfo.mDetails->mNextSibling;
}
}
}
nsRange::RangeBoundariesAndRoot
nsRange::DetermineNewRangeBoundariesAndRootOnCharacterDataMerge(
nsIContent* aContent, const CharacterDataChangeInfo& aInfo) const {
RawRangeBoundary newStart;
RawRangeBoundary newEnd;
nsINode* newRoot = nullptr;
// normalize(), aInfo.mDetails->mNextSibling is the merged text node
// that will be removed
nsIContent* removed = aInfo.mDetails->mNextSibling;
if (removed == mStart.Container()) {
CheckedUint32 newStartOffset{
*mStart.Offset(RangeBoundary::OffsetFilter::kValidOrInvalidOffsets)};
newStartOffset += aInfo.mChangeStart;
// newStartOffset.isValid() isn't checked explicitly here, because
// newStartOffset.value() contains an assertion.
newStart = {aContent, newStartOffset.value()};
if (MOZ_UNLIKELY(removed == mRoot)) {
newRoot = RangeUtils::ComputeRootNode(newStart.Container());
}
}
if (removed == mEnd.Container()) {
CheckedUint32 newEndOffset{
*mEnd.Offset(RangeBoundary::OffsetFilter::kValidOrInvalidOffsets)};
newEndOffset += aInfo.mChangeStart;
// newEndOffset.isValid() isn't checked explicitly here, because
// newEndOffset.value() contains an assertion.
newEnd = {aContent, newEndOffset.value()};
if (MOZ_UNLIKELY(removed == mRoot)) {
newRoot = {RangeUtils::ComputeRootNode(newEnd.Container())};
}
}
// When the removed text node's parent is one of our boundary nodes we may
// need to adjust the offset to account for the removed node. However,
// there will also be a ContentRemoved notification later so the only cases
// we need to handle here is when the removed node is the text node after
// the boundary. (The m*Offset > 0 check is an optimization - a boundary
// point before the first child is never affected by normalize().)
nsINode* parentNode = aContent->GetParentNode();
if (parentNode == mStart.Container() &&
*mStart.Offset(RangeBoundary::OffsetFilter::kValidOrInvalidOffsets) > 0 &&
*mStart.Offset(RangeBoundary::OffsetFilter::kValidOrInvalidOffsets) <
parentNode->GetChildCount() &&
removed == mStart.GetChildAtOffset()) {
newStart = {aContent, aInfo.mChangeStart};
}
if (parentNode == mEnd.Container() &&
*mEnd.Offset(RangeBoundary::OffsetFilter::kValidOrInvalidOffsets) > 0 &&
*mEnd.Offset(RangeBoundary::OffsetFilter::kValidOrInvalidOffsets) <
parentNode->GetChildCount() &&
removed == mEnd.GetChildAtOffset()) {
newEnd = {aContent, aInfo.mChangeEnd};
}
return {newStart, newEnd, newRoot};
}
/******************************************************
* nsIMutationObserver implementation
******************************************************/
void nsRange::CharacterDataChanged(nsIContent* aContent,
const CharacterDataChangeInfo& aInfo) {
MOZ_ASSERT(aContent);
MOZ_ASSERT(mIsPositioned);
MOZ_ASSERT(!mNextEndRef);
MOZ_ASSERT(!mNextStartRef);
nsINode* newRoot = nullptr;
RawRangeBoundary newStart;
RawRangeBoundary newEnd;
if (aInfo.mDetails &&
aInfo.mDetails->mType == CharacterDataChangeInfo::Details::eSplit) {
AdjustNextRefsOnCharacterDataSplit(*aContent, aInfo);
}
// If the changed node contains our start boundary and the change starts
// before the boundary we'll need to adjust the offset.
if (aContent == mStart.Container() &&
aInfo.mChangeStart <
*mStart.Offset(RangeBoundary::OffsetFilter::kValidOrInvalidOffsets)) {
if (aInfo.mDetails) {
// splitText(), aInfo->mDetails->mNextSibling is the new text node
NS_ASSERTION(
aInfo.mDetails->mType == CharacterDataChangeInfo::Details::eSplit,
"only a split can start before the end");
NS_ASSERTION(
*mStart.Offset(RangeBoundary::OffsetFilter::kValidOrInvalidOffsets) <=
aInfo.mChangeEnd + 1,
"mStart.Offset() is beyond the end of this node");
const uint32_t newStartOffset =
*mStart.Offset(RangeBoundary::OffsetFilter::kValidOrInvalidOffsets) -
aInfo.mChangeStart;
newStart = {aInfo.mDetails->mNextSibling, newStartOffset};
if (MOZ_UNLIKELY(aContent == mRoot)) {
newRoot = RangeUtils::ComputeRootNode(newStart.Container());
}
bool isCommonAncestor =
IsInAnySelection() && mStart.Container() == mEnd.Container();
if (isCommonAncestor) {
UnregisterClosestCommonInclusiveAncestor(mStart.Container(), false);
RegisterClosestCommonInclusiveAncestor(newStart.Container());
}
if (mStart.Container()
->IsDescendantOfClosestCommonInclusiveAncestorForRangeInSelection()) {
newStart.Container()
->SetDescendantOfClosestCommonInclusiveAncestorForRangeInSelection();
}
} else {
newStart = ComputeNewBoundaryWhenBoundaryInsideChangedText(
aInfo, mStart.AsRaw());
}
}
// Do the same thing for the end boundary, except for splitText of a node
// with no parent then only switch to the new node if the start boundary
// did so too (otherwise the range would end up with disconnected nodes).
if (aContent == mEnd.Container() &&
aInfo.mChangeStart <
*mEnd.Offset(RangeBoundary::OffsetFilter::kValidOrInvalidOffsets)) {
if (aInfo.mDetails && (aContent->GetParentNode() || newStart.Container())) {
// splitText(), aInfo.mDetails->mNextSibling is the new text node
NS_ASSERTION(
aInfo.mDetails->mType == CharacterDataChangeInfo::Details::eSplit,
"only a split can start before the end");
MOZ_ASSERT(
*mEnd.Offset(RangeBoundary::OffsetFilter::kValidOrInvalidOffsets) <=
aInfo.mChangeEnd + 1,
"mEnd.Offset() is beyond the end of this node");
const uint32_t newEndOffset{
*mEnd.Offset(RangeBoundary::OffsetFilter::kValidOrInvalidOffsets) -
aInfo.mChangeStart};
newEnd = {aInfo.mDetails->mNextSibling, newEndOffset};
bool isCommonAncestor =
IsInAnySelection() && mStart.Container() == mEnd.Container();
if (isCommonAncestor && !newStart.Container()) {
// The split occurs inside the range.
UnregisterClosestCommonInclusiveAncestor(mStart.Container(), false);
RegisterClosestCommonInclusiveAncestor(
mStart.Container()->GetParentNode());
newEnd.Container()
->SetDescendantOfClosestCommonInclusiveAncestorForRangeInSelection();
} else if (
mEnd.Container()
->IsDescendantOfClosestCommonInclusiveAncestorForRangeInSelection()) {
newEnd.Container()
->SetDescendantOfClosestCommonInclusiveAncestorForRangeInSelection();
}
} else {
newEnd =
ComputeNewBoundaryWhenBoundaryInsideChangedText(aInfo, mEnd.AsRaw());
}
}
if (aInfo.mDetails &&
aInfo.mDetails->mType == CharacterDataChangeInfo::Details::eMerge) {
MOZ_ASSERT(!newStart.IsSet());
MOZ_ASSERT(!newEnd.IsSet());
RangeBoundariesAndRoot rangeBoundariesAndRoot =
DetermineNewRangeBoundariesAndRootOnCharacterDataMerge(aContent, aInfo);
newStart = rangeBoundariesAndRoot.mStart;
newEnd = rangeBoundariesAndRoot.mEnd;
newRoot = rangeBoundariesAndRoot.mRoot;
}
if (newStart.IsSet() || newEnd.IsSet()) {
if (!newStart.IsSet()) {
newStart.CopyFrom(mStart, RangeBoundaryIsMutationObserved::Yes);
}
if (!newEnd.IsSet()) {
newEnd.CopyFrom(mEnd, RangeBoundaryIsMutationObserved::Yes);
}
DoSetRange(newStart, newEnd, newRoot ? newRoot : mRoot.get(),
!newEnd.Container()->GetParentNode() ||
!newStart.Container()->GetParentNode());
} else {
nsRange::AssertIfMismatchRootAndRangeBoundaries(
mStart, mEnd, mRoot,
(mStart.IsSet() && !mStart.Container()->GetParentNode()) ||
(mEnd.IsSet() && !mEnd.Container()->GetParentNode()));
}
}
void nsRange::ContentAppended(nsIContent* aFirstNewContent) {
MOZ_ASSERT(mIsPositioned);
nsINode* container = aFirstNewContent->GetParentNode();
MOZ_ASSERT(container);
if (container->IsMaybeSelected() && IsInAnySelection()) {
nsINode* child = aFirstNewContent;
while (child) {
if (!child
->IsDescendantOfClosestCommonInclusiveAncestorForRangeInSelection()) {
MarkDescendants(*child);
child
->SetDescendantOfClosestCommonInclusiveAncestorForRangeInSelection();
}
child = child->GetNextSibling();
}
}
if (mNextStartRef || mNextEndRef) {
// A splitText has occurred, if any mNext*Ref was set, we need to adjust
// the range boundaries.
if (mNextStartRef) {
mStart = {mStart.Container(), mNextStartRef};
MOZ_ASSERT(mNextStartRef == aFirstNewContent);
mNextStartRef = nullptr;
}
if (mNextEndRef) {
mEnd = {mEnd.Container(), mNextEndRef};
MOZ_ASSERT(mNextEndRef == aFirstNewContent);
mNextEndRef = nullptr;
}
DoSetRange(mStart, mEnd, mRoot, true);
} else {
nsRange::AssertIfMismatchRootAndRangeBoundaries(mStart, mEnd, mRoot);
}
}
void nsRange::ContentInserted(nsIContent* aChild) {
MOZ_ASSERT(mIsPositioned);
bool updateBoundaries = false;
nsINode* container = aChild->GetParentNode();
MOZ_ASSERT(container);
RawRangeBoundary newStart(mStart, RangeBoundaryIsMutationObserved::Yes);
RawRangeBoundary newEnd(mEnd, RangeBoundaryIsMutationObserved::Yes);
MOZ_ASSERT(aChild->GetParentNode() == container);
// Invalidate boundary offsets if a child that may have moved them was
// inserted.
if (container == mStart.Container()) {
newStart.InvalidateOffset();
updateBoundaries = true;
}
if (container == mEnd.Container()) {
newEnd.InvalidateOffset();
updateBoundaries = true;
}
if (container->IsMaybeSelected() &&
!aChild
->IsDescendantOfClosestCommonInclusiveAncestorForRangeInSelection()) {
MarkDescendants(*aChild);
aChild->SetDescendantOfClosestCommonInclusiveAncestorForRangeInSelection();
}
if (mNextStartRef || mNextEndRef) {
if (mNextStartRef) {
newStart = {mStart.Container(), mNextStartRef};
MOZ_ASSERT(mNextStartRef == aChild);
mNextStartRef = nullptr;
}
if (mNextEndRef) {
newEnd = {mEnd.Container(), mNextEndRef};
MOZ_ASSERT(mNextEndRef == aChild);
mNextEndRef = nullptr;
}
updateBoundaries = true;
}
if (updateBoundaries) {
DoSetRange(newStart, newEnd, mRoot);
} else {
nsRange::AssertIfMismatchRootAndRangeBoundaries(mStart, mEnd, mRoot);
}
}
void nsRange::ContentWillBeRemoved(nsIContent* aChild) {
MOZ_ASSERT(mIsPositioned);
nsINode* container = aChild->GetParentNode();
MOZ_ASSERT(container);
nsINode* startContainer = mStart.Container();
nsINode* endContainer = mEnd.Container();
RawRangeBoundary newStart;
RawRangeBoundary newEnd;
Maybe<bool> gravitateStart;
bool gravitateEnd;
// Adjust position if a sibling was removed...
if (container == startContainer) {
// We're only interested if our boundary reference was removed, otherwise
// we can just invalidate the offset.
if (aChild == mStart.Ref()) {
newStart = {container, aChild->GetPreviousSibling()};
} else {
newStart.CopyFrom(mStart, RangeBoundaryIsMutationObserved::Yes);
newStart.InvalidateOffset();
}
} else {
gravitateStart = Some(startContainer->IsInclusiveDescendantOf(aChild));
if (gravitateStart.value()) {
newStart = {container, aChild->GetPreviousSibling()};
}
}
// Do same thing for end boundry.
if (container == endContainer) {
if (aChild == mEnd.Ref()) {
newEnd = {container, aChild->GetPreviousSibling()};
} else {
newEnd.CopyFrom(mEnd, RangeBoundaryIsMutationObserved::Yes);
newEnd.InvalidateOffset();
}
} else {
if (startContainer == endContainer && gravitateStart.isSome()) {
gravitateEnd = gravitateStart.value();
} else {
gravitateEnd = endContainer->IsInclusiveDescendantOf(aChild);
}
if (gravitateEnd) {
newEnd = {container, aChild->GetPreviousSibling()};
}
}
bool newStartIsSet = newStart.IsSet();
bool newEndIsSet = newEnd.IsSet();
if (newStartIsSet || newEndIsSet) {
DoSetRange(
newStartIsSet ? newStart : mStart.AsRaw(),
newEndIsSet ? newEnd : mEnd.AsRaw(), mRoot, false,
// CrossShadowBoundaryRange mutates content
// removal fot itself, so no need for nsRange to do anything with it.
RangeBehaviour::KeepDefaultRangeAndCrossShadowBoundaryRanges);
} else {
nsRange::AssertIfMismatchRootAndRangeBoundaries(mStart, mEnd, mRoot);
}
MOZ_ASSERT(mStart.Ref() != aChild);
MOZ_ASSERT(mEnd.Ref() != aChild);
if (container->IsMaybeSelected() &&
aChild
->IsDescendantOfClosestCommonInclusiveAncestorForRangeInSelection()) {
aChild
->ClearDescendantOfClosestCommonInclusiveAncestorForRangeInSelection();
UnmarkDescendants(*aChild);
}
}
void nsRange::ParentChainChanged(nsIContent* aContent) {
NS_ASSERTION(mRoot == aContent, "Wrong ParentChainChanged notification?");
nsINode* newRoot = RangeUtils::ComputeRootNode(mStart.Container());
NS_ASSERTION(newRoot, "No valid boundary or root found!");
if (newRoot != RangeUtils::ComputeRootNode(mEnd.Container())) {
// Sometimes ordering involved in cycle collection can lead to our
// start parent and/or end parent being disconnected from our root
// without our getting a ContentRemoved notification.
NS_ASSERTION(mEnd.Container()->IsInNativeAnonymousSubtree(),
"This special case should happen only with "
"native-anonymous content");
// When that happens, bail out and set pointers to null; since we're
// in cycle collection and unreachable it shouldn't matter.
Reset();
return;
}
// This is safe without holding a strong ref to self as long as the change
// of mRoot is the last thing in DoSetRange.
DoSetRange(mStart, mEnd, newRoot);
}
bool nsRange::IsShadowIncludingInclusiveDescendantOfCrossBoundaryRangeAncestor(
const nsINode& aContainer) const {
MOZ_ASSERT(mCrossShadowBoundaryRange &&
mCrossShadowBoundaryRange->GetCommonAncestor());
return aContainer.IsShadowIncludingInclusiveDescendantOf(
mCrossShadowBoundaryRange->GetCommonAncestor());
}
bool nsRange::IsPointComparableToRange(const nsINode& aContainer,
uint32_t aOffset,
bool aAllowCrossShadowBoundary,
ErrorResult& aRv) const {
// our range is in a good state?
if (!mIsPositioned) {
aRv.Throw(NS_ERROR_NOT_INITIALIZED);
return false;
}
const bool isContainerInRange =
aContainer.IsInclusiveDescendantOf(mRoot) ||
(aAllowCrossShadowBoundary && mCrossShadowBoundaryRange &&
IsShadowIncludingInclusiveDescendantOfCrossBoundaryRangeAncestor(
aContainer));
if (!isContainerInRange) {
// TODO(emilio): Switch to ThrowWrongDocumentError, but IsPointInRange
// relies on the error code right now in order to suppress the exception.
aRv.Throw(NS_ERROR_DOM_WRONG_DOCUMENT_ERR);
return false;
}
auto chromeOnlyAccess = mStart.Container()->ChromeOnlyAccess();
NS_ASSERTION(chromeOnlyAccess == mEnd.Container()->ChromeOnlyAccess(),
"Start and end of a range must be either both native anonymous "
"content or not.");
if (aContainer.ChromeOnlyAccess() != chromeOnlyAccess) {
aRv.ThrowInvalidNodeTypeError(
"Trying to compare restricted with unrestricted nodes");
return false;
}
if (aContainer.NodeType() == nsINode::DOCUMENT_TYPE_NODE) {
aRv.ThrowInvalidNodeTypeError("Trying to compare with a document");
return false;
}
if (aOffset > aContainer.Length()) {
aRv.ThrowIndexSizeError("Offset is out of bounds");
return false;
}
return true;
}
bool nsRange::IsPointInRange(const nsINode& aContainer, uint32_t aOffset,
ErrorResult& aRv,
bool aAllowCrossShadowBoundary) const {
int16_t compareResult =
ComparePoint(aContainer, aOffset, aRv, aAllowCrossShadowBoundary);
// If the node isn't in the range's document, it clearly isn't in the range.
if (aRv.ErrorCodeIs(NS_ERROR_DOM_WRONG_DOCUMENT_ERR)) {
aRv.SuppressException();
return false;
}
return compareResult == 0;
}
int16_t nsRange::ComparePoint(const nsINode& aContainer, uint32_t aOffset,
ErrorResult& aRv,
bool aAllowCrossShadowBoundary) const {
if (!IsPointComparableToRange(aContainer, aOffset, aAllowCrossShadowBoundary,
aRv)) {
return 0;
}
const RawRangeBoundary point{const_cast<nsINode*>(&aContainer), aOffset};
MOZ_ASSERT(point.IsSetAndValid());
if (Maybe<int32_t> order = nsContentUtils::ComparePoints(
point, aAllowCrossShadowBoundary ? MayCrossShadowBoundaryStartRef()
: StartRef());
order && *order <= 0) {
return int16_t(*order);
}
if (Maybe<int32_t> order = nsContentUtils::ComparePoints(
aAllowCrossShadowBoundary ? MayCrossShadowBoundaryEndRef() : EndRef(),
point);
order && *order == -1) {
return 1;
}
return 0;
}
bool nsRange::IntersectsNode(nsINode& aNode, ErrorResult& aRv) {
if (!mIsPositioned) {
aRv.Throw(NS_ERROR_NOT_INITIALIZED);
return false;
}
nsINode* parent = aNode.GetParentNode();
if (!parent) {
// |parent| is null, so |node|'s root is |node| itself.
return GetRoot() == &aNode;
}
const Maybe<uint32_t> nodeIndex = parent->ComputeIndexOf(&aNode);
if (nodeIndex.isNothing()) {
return false;
}
if (!IsPointComparableToRange(*parent, *nodeIndex,
false /* aAllowCrossShadowBoundary */,
IgnoreErrors())) {
return false;
}
const Maybe<int32_t> startOrder = nsContentUtils::ComparePoints(
mStart.Container(),
*mStart.Offset(RangeBoundary::OffsetFilter::kValidOffsets), parent,
*nodeIndex + 1u);
if (startOrder && (*startOrder < 0)) {
const Maybe<int32_t> endOrder = nsContentUtils::ComparePoints(
parent, *nodeIndex, mEnd.Container(),
*mEnd.Offset(RangeBoundary::OffsetFilter::kValidOffsets));
return endOrder && (*endOrder < 0);
}
return false;
}
void nsRange::NotifySelectionListenersAfterRangeSet() {
if (mSelections.IsEmpty()) {
return;
}
// Our internal code should not move focus with using this instance while
// it's calling Selection::NotifySelectionListeners() which may move focus
// or calls selection listeners. So, let's set mCalledByJS to false here
// since non-*JS() methods don't set it to false.
AutoCalledByJSRestore calledByJSRestorer(*this);
mCalledByJS = false;
// If this instance is not a proper range for selection, we need to remove
// this from selections.
const Document* const docForSelf =
mStart.Container() ? mStart.Container()->GetComposedDoc() : nullptr;
const nsFrameSelection* const frameSelection =
mSelections[0]->GetFrameSelection();
const Document* const docForSelection =
frameSelection && frameSelection->GetPresShell()
? frameSelection->GetPresShell()->GetDocument()
: nullptr;
if (!IsPositioned() || docForSelf != docForSelection) {
// XXX Why Selection::RemoveRangeAndUnselectFramesAndNotifyListeners() does
// not set whether the caller is JS or not?
if (IsPartOfOneSelectionOnly()) {
RefPtr<Selection> selection = mSelections[0].get();
selection->RemoveRangeAndUnselectFramesAndNotifyListeners(*this,
IgnoreErrors());
} else {
nsTArray<WeakPtr<Selection>> copiedSelections = mSelections.Clone();
for (const auto& weakSelection : copiedSelections) {
RefPtr<Selection> selection = weakSelection.get();
if (MOZ_LIKELY(selection)) {
selection->RemoveRangeAndUnselectFramesAndNotifyListeners(
*this, IgnoreErrors());
}
}
}
// FYI: NotifySelectionListeners() should be called by
// RemoveRangeAndUnselectFramesAndNotifyListeners() if it's required.
// Therefore, we need to do nothing anymore.
return;
}
// Notify all Selections. This may modify the range,
// remove it from the selection, or the selection itself may have gone after
// the call. Also, new selections may be added.
// To ensure that listeners are notified for all *current* selections,
// create a copy of the list of selections and use that for iterating. This
// way selections can be added or removed safely during iteration.
// To save allocation cost, the copy is only created if there is more than
// one Selection present (which will barely ever be the case).
if (IsPartOfOneSelectionOnly()) {
RefPtr<Selection> selection = mSelections[0].get();
#ifdef ACCESSIBILITY
a11y::SelectionManager::SelectionRangeChanged(selection->GetType(), *this);
#endif
selection->NotifySelectionListeners(calledByJSRestorer.SavedValue());
} else {
nsTArray<WeakPtr<Selection>> copiedSelections = mSelections.Clone();
for (const auto& weakSelection : copiedSelections) {
RefPtr<Selection> selection = weakSelection.get();
if (MOZ_LIKELY(selection)) {
#ifdef ACCESSIBILITY
a11y::SelectionManager::SelectionRangeChanged(selection->GetType(),
*this);
#endif
selection->NotifySelectionListeners(calledByJSRestorer.SavedValue());
}
}
}
}
/******************************************************
* Private helper routines
******************************************************/
// static
template <typename SPT, typename SRT, typename EPT, typename ERT>
void nsRange::AssertIfMismatchRootAndRangeBoundaries(
const RangeBoundaryBase<SPT, SRT>& aStartBoundary,
const RangeBoundaryBase<EPT, ERT>& aEndBoundary, const nsINode* aRootNode,
bool aNotInsertedYet /* = false */) {
#ifdef DEBUG
if (!aRootNode) {
MOZ_ASSERT(!aStartBoundary.IsSet());
MOZ_ASSERT(!aEndBoundary.IsSet());
return;
}
MOZ_ASSERT(aStartBoundary.IsSet());
MOZ_ASSERT(aEndBoundary.IsSet());
if (!aNotInsertedYet) {
// Compute temporary root for given range boundaries. If a range in native
// anonymous subtree is being removed, tempRoot may return the fragment's
// root content, but it shouldn't be used for new root node because the node
// may be bound to the root element again.
nsINode* tempRoot = RangeUtils::ComputeRootNode(aStartBoundary.Container());
// The new range should be in the temporary root node at least.
MOZ_ASSERT(tempRoot ==
RangeUtils::ComputeRootNode(aEndBoundary.Container()));
MOZ_ASSERT(aStartBoundary.Container()->IsInclusiveDescendantOf(tempRoot));
MOZ_ASSERT(aEndBoundary.Container()->IsInclusiveDescendantOf(tempRoot));
// If the new range is not disconnected or not in native anonymous subtree,
// the temporary root must be same as the new root node. Otherwise,
// aRootNode should be the parent of root of the NAC (e.g., `<input>` if the
// range is in NAC under `<input>`), but tempRoot is now root content node
// of the disconnected subtree (e.g., `<div>` element in `<input>` element).
const bool tempRootIsDisconnectedNAC =
tempRoot->IsInNativeAnonymousSubtree() && !tempRoot->GetParentNode();
MOZ_ASSERT_IF(!tempRootIsDisconnectedNAC, tempRoot == aRootNode);
}
MOZ_ASSERT(aRootNode->IsDocument() || aRootNode->IsAttr() ||
aRootNode->IsDocumentFragment() || aRootNode->IsContent());
#endif // #ifdef DEBUG
}
// It's important that all setting of the range start/end points
// go through this function, which will do all the right voodoo
// for content notification of range ownership.
// Calling DoSetRange with either parent argument null will collapse
// the range to have both endpoints point to the other node
template <typename SPT, typename SRT, typename EPT, typename ERT>
void nsRange::
DoSetRange(const RangeBoundaryBase<SPT, SRT>& aStartBoundary,
const RangeBoundaryBase<EPT, ERT>& aEndBoundary,
nsINode* aRootNode,
bool aNotInsertedYet /* = false */, RangeBehaviour aRangeBehaviour /* = CollapseDefaultRangeAndCrossShadowBoundaryRanges */) {
mIsPositioned = aStartBoundary.IsSetAndValid() &&
aEndBoundary.IsSetAndValid() && aRootNode;
MOZ_ASSERT_IF(!mIsPositioned, !aStartBoundary.IsSet());
MOZ_ASSERT_IF(!mIsPositioned, !aEndBoundary.IsSet());
MOZ_ASSERT_IF(!mIsPositioned, !aRootNode);
nsRange::AssertIfMismatchRootAndRangeBoundaries(aStartBoundary, aEndBoundary,
aRootNode, aNotInsertedYet);
if (mRoot != aRootNode) {
if (mRoot) {
mRoot->RemoveMutationObserver(this);
}
if (aRootNode) {
aRootNode->AddMutationObserver(this);
}
}
bool checkCommonAncestor =
(mStart.Container() != aStartBoundary.Container() ||
mEnd.Container() != aEndBoundary.Container()) &&
IsInAnySelection() && !aNotInsertedYet;
// GetClosestCommonInclusiveAncestor is unreliable while we're unlinking
// (could return null if our start/end have already been unlinked), so make
// sure to not use it here to determine our "old" current ancestor.
mStart.CopyFrom(aStartBoundary, RangeBoundaryIsMutationObserved::Yes);
mEnd.CopyFrom(aEndBoundary, RangeBoundaryIsMutationObserved::Yes);
if (aRangeBehaviour ==
RangeBehaviour::CollapseDefaultRangeAndCrossShadowBoundaryRanges) {
ResetCrossShadowBoundaryRange();
}
if (checkCommonAncestor) {
UpdateCommonAncestorIfNecessary();
}
// This needs to be the last thing this function does, other than notifying
// selection listeners. See comment in ParentChainChanged.
if (mRoot != aRootNode) {
mRoot = aRootNode;
}
// Notify any selection listeners. This has to occur last because otherwise
// the world could be observed by a selection listener while the range was in
// an invalid state. So we run it off of a script runner to ensure it runs
// after the mutation observers have finished running.
if (!mSelections.IsEmpty()) {
if (MOZ_LOG_TEST(sSelectionAPILog, LogLevel::Info)) {
for (const auto& selection : mSelections) {
if (selection && selection->Type() == SelectionType::eNormal) {
LogSelectionAPI(selection, __FUNCTION__, "aStartBoundary",
aStartBoundary, "aEndBoundary", aEndBoundary,
"aNotInsertedYet", aNotInsertedYet);
LogStackForSelectionAPI();
}
}
}
nsContentUtils::AddScriptRunner(
NewRunnableMethod("NotifySelectionListenersAfterRangeSet", this,
&nsRange::NotifySelectionListenersAfterRangeSet));
}
}
void nsRange::Reset() {
DoSetRange(RawRangeBoundary(), RawRangeBoundary(), nullptr);
}
/******************************************************
* public functionality
******************************************************/
void nsRange::SetStartJS(nsINode& aNode, uint32_t aOffset, ErrorResult& aErr) {
AutoCalledByJSRestore calledByJSRestorer(*this);
mCalledByJS = true;
SetStart(aNode, aOffset, aErr);
}
bool nsRange::CanAccess(const nsINode& aNode) const {
if (nsContentUtils::LegacyIsCallerNativeCode()) {
return true;
}
return nsContentUtils::CanCallerAccess(&aNode);
}
void nsRange::SetStart(
nsINode& aNode, uint32_t aOffset, ErrorResult& aRv,
AllowRangeCrossShadowBoundary aAllowCrossShadowBoundary) {
if (!CanAccess(aNode)) {
aRv.Throw(NS_ERROR_DOM_SECURITY_ERR);
return;
}
AutoInvalidateSelection atEndOfBlock(this);
SetStart(RawRangeBoundary(&aNode, aOffset), aRv, aAllowCrossShadowBoundary);
}
void nsRange::SetStart(
const RawRangeBoundary& aPoint, ErrorResult& aRv,
AllowRangeCrossShadowBoundary aAllowCrossShadowBoundary) {
nsINode* newRoot = RangeUtils::ComputeRootNode(aPoint.Container());
if (!newRoot) {
aRv.Throw(NS_ERROR_DOM_INVALID_NODE_TYPE_ERR);
return;
}
if (!aPoint.IsSetAndValid()) {
aRv.Throw(NS_ERROR_DOM_INDEX_SIZE_ERR);
return;
}
RangeBehaviour behaviour =
GetRangeBehaviour(this, newRoot, aPoint, true /* aIsSetStart= */,
aAllowCrossShadowBoundary);
switch (behaviour) {
case RangeBehaviour::KeepDefaultRangeAndCrossShadowBoundaryRanges:
// EndRef(..) may be same as mStart or not, depends on
// the value of mCrossShadowBoundaryRange->mEnd, We need to update
// mCrossShadowBoundaryRange and the default boundaries separately
if (aAllowCrossShadowBoundary == AllowRangeCrossShadowBoundary::Yes) {
if (MayCrossShadowBoundaryEndRef() != mEnd) {
CreateOrUpdateCrossShadowBoundaryRangeIfNeeded(
aPoint, MayCrossShadowBoundaryEndRef());
} else {
// The normal range is good enough for this case, just use that.
ResetCrossShadowBoundaryRange();
}
}
DoSetRange(aPoint, mEnd, mRoot, false, behaviour);
break;
case RangeBehaviour::CollapseDefaultRangeAndCrossShadowBoundaryRanges:
DoSetRange(aPoint, aPoint, newRoot, false, behaviour);
break;
case RangeBehaviour::CollapseDefaultRange:
MOZ_ASSERT(aAllowCrossShadowBoundary ==
AllowRangeCrossShadowBoundary::Yes);
CreateOrUpdateCrossShadowBoundaryRangeIfNeeded(
aPoint, MayCrossShadowBoundaryEndRef());
DoSetRange(aPoint, aPoint, newRoot, false, behaviour);
break;
case RangeBehaviour::MergeDefaultRangeAndCrossShadowBoundaryRanges:
DoSetRange(aPoint, MayCrossShadowBoundaryEndRef(), newRoot, false,
behaviour);
ResetCrossShadowBoundaryRange();
break;
default:
MOZ_ASSERT_UNREACHABLE();
}
}
void nsRange::SetStartAllowCrossShadowBoundary(nsINode& aNode, uint32_t aOffset,
ErrorResult& aErr) {
AutoCalledByJSRestore calledByJSRestorer(*this);
mCalledByJS = true;
SetStart(aNode, aOffset, aErr, AllowRangeCrossShadowBoundary::Yes);
}
void nsRange::SetStartBeforeJS(nsINode& aNode, ErrorResult& aErr) {
AutoCalledByJSRestore calledByJSRestorer(*this);
mCalledByJS = true;
SetStartBefore(aNode, aErr);
}
void nsRange::SetStartBefore(
nsINode& aNode, ErrorResult& aRv,
AllowRangeCrossShadowBoundary aAllowCrossShadowBoundary) {
if (!CanAccess(aNode)) {
aRv.Throw(NS_ERROR_DOM_SECURITY_ERR);
return;
}
AutoInvalidateSelection atEndOfBlock(this);
// If the node is being removed from its parent, GetRawRangeBoundaryBefore()
// returns unset instance. Then, SetStart() will throw
// NS_ERROR_DOM_INVALID_NODE_TYPE_ERR.
SetStart(RangeUtils::GetRawRangeBoundaryBefore(&aNode), aRv,
aAllowCrossShadowBoundary);
}
void nsRange::SetStartAfterJS(nsINode& aNode, ErrorResult& aErr) {
AutoCalledByJSRestore calledByJSRestorer(*this);
mCalledByJS = true;
SetStartAfter(aNode, aErr);
}
void nsRange::SetStartAfter(nsINode& aNode, ErrorResult& aRv) {
if (!CanAccess(aNode)) {
aRv.Throw(NS_ERROR_DOM_SECURITY_ERR);
return;
}
AutoInvalidateSelection atEndOfBlock(this);
// If the node is being removed from its parent, GetRawRangeBoundaryAfter()
// returns unset instance. Then, SetStart() will throw
// NS_ERROR_DOM_INVALID_NODE_TYPE_ERR.
SetStart(RangeUtils::GetRawRangeBoundaryAfter(&aNode), aRv);
}
void nsRange::SetEndJS(nsINode& aNode, uint32_t aOffset, ErrorResult& aErr) {
AutoCalledByJSRestore calledByJSRestorer(*this);
mCalledByJS = true;
SetEnd(aNode, aOffset, aErr);
}
void nsRange::SetEnd(nsINode& aNode, uint32_t aOffset, ErrorResult& aRv,
AllowRangeCrossShadowBoundary aAllowCrossShadowBoundary) {
if (!CanAccess(aNode)) {
aRv.Throw(NS_ERROR_DOM_SECURITY_ERR);
return;
}
AutoInvalidateSelection atEndOfBlock(this);
SetEnd(RawRangeBoundary(&aNode, aOffset), aRv, aAllowCrossShadowBoundary);
}
void nsRange::SetEnd(const RawRangeBoundary& aPoint, ErrorResult& aRv,
AllowRangeCrossShadowBoundary aAllowCrossShadowBoundary) {
nsINode* newRoot = RangeUtils::ComputeRootNode(aPoint.Container());
if (!newRoot) {
aRv.Throw(NS_ERROR_DOM_INVALID_NODE_TYPE_ERR);
return;
}
if (!aPoint.IsSetAndValid()) {
aRv.Throw(NS_ERROR_DOM_INDEX_SIZE_ERR);
return;
}
RangeBehaviour policy =
GetRangeBehaviour(this, newRoot, aPoint, false /* aIsStartStart */,
aAllowCrossShadowBoundary);
switch (policy) {
case RangeBehaviour::KeepDefaultRangeAndCrossShadowBoundaryRanges:
// StartRef(..) may be same as mStart or not, depends on
// the value of mCrossShadowBoundaryRange->mStart, so we need to update
// mCrossShadowBoundaryRange and the default boundaries separately
if (aAllowCrossShadowBoundary == AllowRangeCrossShadowBoundary::Yes) {
if (MayCrossShadowBoundaryStartRef() != mStart) {
CreateOrUpdateCrossShadowBoundaryRangeIfNeeded(
MayCrossShadowBoundaryStartRef(), aPoint);
} else {
// The normal range is good enough for this case, just use that.
ResetCrossShadowBoundaryRange();
}
}
DoSetRange(mStart, aPoint, mRoot, false, policy);
break;
case RangeBehaviour::CollapseDefaultRangeAndCrossShadowBoundaryRanges:
DoSetRange(aPoint, aPoint, newRoot, false, policy);
break;
case RangeBehaviour::CollapseDefaultRange:
MOZ_ASSERT(aAllowCrossShadowBoundary ==
AllowRangeCrossShadowBoundary::Yes);
CreateOrUpdateCrossShadowBoundaryRangeIfNeeded(
MayCrossShadowBoundaryStartRef(), aPoint);
DoSetRange(aPoint, aPoint, newRoot, false, policy);
break;
case RangeBehaviour::MergeDefaultRangeAndCrossShadowBoundaryRanges:
DoSetRange(MayCrossShadowBoundaryStartRef(), aPoint, newRoot, false,
policy);
ResetCrossShadowBoundaryRange();
break;
default:
MOZ_ASSERT_UNREACHABLE();
}
}
void nsRange::SetEndAllowCrossShadowBoundary(nsINode& aNode, uint32_t aOffset,
ErrorResult& aErr) {
AutoCalledByJSRestore calledByJSRestorer(*this);
mCalledByJS = true;
SetEnd(aNode, aOffset, aErr,
AllowRangeCrossShadowBoundary::Yes /* aAllowCrossShadowBoundary */);
}
void nsRange::SelectNodesInContainer(nsINode* aContainer,
nsIContent* aStartContent,
nsIContent* aEndContent) {
MOZ_ASSERT(aContainer);
MOZ_ASSERT(aContainer->ComputeIndexOf(aStartContent).valueOr(0) <=
aContainer->ComputeIndexOf(aEndContent).valueOr(0));
MOZ_ASSERT(aStartContent &&
aContainer->ComputeIndexOf(aStartContent).isSome());
MOZ_ASSERT(aEndContent && aContainer->ComputeIndexOf(aEndContent).isSome());
nsINode* newRoot = RangeUtils::ComputeRootNode(aContainer);
MOZ_ASSERT(newRoot);
if (!newRoot) {
return;
}
RawRangeBoundary start(aContainer, aStartContent->GetPreviousSibling());
RawRangeBoundary end(aContainer, aEndContent);
DoSetRange(start, end, newRoot);
}
void nsRange::SetEndBeforeJS(nsINode& aNode, ErrorResult& aErr) {
AutoCalledByJSRestore calledByJSRestorer(*this);
mCalledByJS = true;
SetEndBefore(aNode, aErr);
}
void nsRange::SetEndBefore(
nsINode& aNode, ErrorResult& aRv,
AllowRangeCrossShadowBoundary aAllowCrossShadowBoundary) {
if (!CanAccess(aNode)) {
aRv.Throw(NS_ERROR_DOM_SECURITY_ERR);
return;
}
AutoInvalidateSelection atEndOfBlock(this);
// If the node is being removed from its parent, GetRawRangeBoundaryBefore()
// returns unset instance. Then, SetEnd() will throw
// NS_ERROR_DOM_INVALID_NODE_TYPE_ERR.
SetEnd(RangeUtils::GetRawRangeBoundaryBefore(&aNode), aRv,
aAllowCrossShadowBoundary);
}
void nsRange::SetEndAfterJS(nsINode& aNode, ErrorResult& aErr) {
AutoCalledByJSRestore calledByJSRestorer(*this);
mCalledByJS = true;
SetEndAfter(aNode, aErr);
}
void nsRange::SetEndAfter(nsINode& aNode, ErrorResult& aRv) {
if (!CanAccess(aNode)) {
aRv.Throw(NS_ERROR_DOM_SECURITY_ERR);
return;
}
AutoInvalidateSelection atEndOfBlock(this);
// If the node is being removed from its parent, GetRawRangeBoundaryAfter()
// returns unset instance. Then, SetEnd() will throw
// NS_ERROR_DOM_INVALID_NODE_TYPE_ERR.
SetEnd(RangeUtils::GetRawRangeBoundaryAfter(&aNode), aRv);
}
void nsRange::Collapse(bool aToStart) {
if (!mIsPositioned) return;
AutoInvalidateSelection atEndOfBlock(this);
if (aToStart) {
DoSetRange(mStart, mStart, mRoot);
} else {
DoSetRange(mEnd, mEnd, mRoot);
}
}
void nsRange::CollapseJS(bool aToStart) {
AutoCalledByJSRestore calledByJSRestorer(*this);
mCalledByJS = true;
Collapse(aToStart);
}
void nsRange::SelectNodeJS(nsINode& aNode, ErrorResult& aErr) {
AutoCalledByJSRestore calledByJSRestorer(*this);
mCalledByJS = true;
SelectNode(aNode, aErr);
}
void nsRange::SelectNode(nsINode& aNode, ErrorResult& aRv) {
if (!CanAccess(aNode)) {
aRv.Throw(NS_ERROR_DOM_SECURITY_ERR);
return;
}
nsINode* container = aNode.GetParentNode();
nsINode* newRoot = RangeUtils::ComputeRootNode(container);
if (!newRoot) {
aRv.Throw(NS_ERROR_DOM_INVALID_NODE_TYPE_ERR);
return;
}
const Maybe<uint32_t> index = container->ComputeIndexOf(&aNode);
// MOZ_ASSERT(index.isSome());
// We need to compute the index here unfortunately, because, while we have
// support for XBL, |container| may be the node's binding parent without
// actually containing it.
if (MOZ_UNLIKELY(NS_WARN_IF(index.isNothing()))) {
aRv.Throw(NS_ERROR_DOM_INVALID_NODE_TYPE_ERR);
return;
}
AutoInvalidateSelection atEndOfBlock(this);
DoSetRange(RawRangeBoundary{container, *index},
RawRangeBoundary{container, *index + 1u}, newRoot);
}
void nsRange::SelectNodeContentsJS(nsINode& aNode, ErrorResult& aErr) {
AutoCalledByJSRestore calledByJSRestorer(*this);
mCalledByJS = true;
SelectNodeContents(aNode, aErr);
}
void nsRange::SelectNodeContents(nsINode& aNode, ErrorResult& aRv) {
if (!CanAccess(aNode)) {
aRv.Throw(NS_ERROR_DOM_SECURITY_ERR);
return;
}
nsINode* newRoot = RangeUtils::ComputeRootNode(&aNode);
if (!newRoot) {
aRv.Throw(NS_ERROR_DOM_INVALID_NODE_TYPE_ERR);
return;
}
AutoInvalidateSelection atEndOfBlock(this);
DoSetRange(RawRangeBoundary(&aNode, 0u),
RawRangeBoundary(&aNode, aNode.Length()), newRoot);
}
// The Subtree Content Iterator only returns subtrees that are
// completely within a given range. It doesn't return a CharacterData
// node that contains either the start or end point of the range.,
// nor does it return element nodes when nothing in the element is selected.
// We need an iterator that will also include these start/end points
// so that our methods/algorithms aren't cluttered with special
// case code that tries to include these points while iterating.
//
// The RangeSubtreeIterator class mimics the ContentSubtreeIterator
// methods we need, so should the Content Iterator support the
// start/end points in the future, we can switchover relatively
// easy.
class MOZ_STACK_CLASS RangeSubtreeIterator {
private:
enum RangeSubtreeIterState { eDone = 0, eUseStart, eUseIterator, eUseEnd };
Maybe<ContentSubtreeIterator> mSubtreeIter;
RangeSubtreeIterState mIterState;
nsCOMPtr<nsINode> mStart;
nsCOMPtr<nsINode> mEnd;
public:
RangeSubtreeIterator() : mIterState(eDone) {}
~RangeSubtreeIterator() = default;
nsresult Init(nsRange* aRange, AllowRangeCrossShadowBoundary =
AllowRangeCrossShadowBoundary::No);
already_AddRefed<nsINode> GetCurrentNode();
void First();
void Last();
void Next();
void Prev();
bool IsDone() { return mIterState == eDone; }
};
nsresult RangeSubtreeIterator::Init(
nsRange* aRange, AllowRangeCrossShadowBoundary aAllowCrossShadowBoundary) {
mIterState = eDone;
if (aRange->AreNormalRangeAndCrossShadowBoundaryRangeCollapsed()) {
return NS_OK;
}
// Grab the start point of the range and QI it to
// a CharacterData pointer. If it is CharacterData store
// a pointer to the node.
if (!aRange->IsPositioned()) {
return NS_ERROR_FAILURE;
}
nsINode* node = aRange->GetMayCrossShadowBoundaryStartContainer();
if (NS_WARN_IF(!node)) {
return NS_ERROR_FAILURE;
}
if (node->IsCharacterData() ||
(node->IsElement() && node->AsElement()->GetChildCount() ==
aRange->MayCrossShadowBoundaryStartOffset())) {
mStart = node;
}
// Grab the end point of the range and QI it to
// a CharacterData pointer. If it is CharacterData store
// a pointer to the node.
node = aRange->GetMayCrossShadowBoundaryEndContainer();
if (NS_WARN_IF(!node)) {
return NS_ERROR_FAILURE;
}
if (node->IsCharacterData() ||
(node->IsElement() && aRange->MayCrossShadowBoundaryEndOffset() == 0)) {
mEnd = node;
}
if (mStart && mStart == mEnd) {
// The range starts and stops in the same CharacterData
// node. Null out the end pointer so we only visit the
// node once!
mEnd = nullptr;
} else {
// Now create a Content Subtree Iterator to be used
// for the subtrees between the end points!
mSubtreeIter.emplace();
nsresult res =
aAllowCrossShadowBoundary == AllowRangeCrossShadowBoundary::Yes
? mSubtreeIter->InitWithAllowCrossShadowBoundary(aRange)
: mSubtreeIter->Init(aRange);
if (NS_FAILED(res)) return res;
if (mSubtreeIter->IsDone()) {
// The subtree iterator thinks there's nothing
// to iterate over, so just free it up so we
// don't accidentally call into it.
mSubtreeIter.reset();
}
}
// Initialize the iterator by calling First().
// Note that we are ignoring the return value on purpose!
First();
return NS_OK;
}
already_AddRefed<nsINode> RangeSubtreeIterator::GetCurrentNode() {
nsCOMPtr<nsINode> node;
if (mIterState == eUseStart && mStart) {
node = mStart;
} else if (mIterState == eUseEnd && mEnd) {
node = mEnd;
} else if (mIterState == eUseIterator && mSubtreeIter) {
node = mSubtreeIter->GetCurrentNode();
}
return node.forget();
}
void RangeSubtreeIterator::First() {
if (mStart)
mIterState = eUseStart;
else if (mSubtreeIter) {
mSubtreeIter->First();
mIterState = eUseIterator;
} else if (mEnd)
mIterState = eUseEnd;
else
mIterState = eDone;
}
void RangeSubtreeIterator::Last() {
if (mEnd)
mIterState = eUseEnd;
else if (mSubtreeIter) {
mSubtreeIter->Last();
mIterState = eUseIterator;
} else if (mStart)
mIterState = eUseStart;
else
mIterState = eDone;
}
void RangeSubtreeIterator::Next() {
if (mIterState == eUseStart) {
if (mSubtreeIter) {
mSubtreeIter->First();
mIterState = eUseIterator;
} else if (mEnd)
mIterState = eUseEnd;
else
mIterState = eDone;
} else if (mIterState == eUseIterator) {
mSubtreeIter->Next();
if (mSubtreeIter->IsDone()) {
if (mEnd)
mIterState = eUseEnd;
else
mIterState = eDone;
}
} else
mIterState = eDone;
}
void RangeSubtreeIterator::Prev() {
if (mIterState == eUseEnd) {
if (mSubtreeIter) {
mSubtreeIter->Last();
mIterState = eUseIterator;
} else if (mStart)
mIterState = eUseStart;
else
mIterState = eDone;
} else if (mIterState == eUseIterator) {
mSubtreeIter->Prev();
if (mSubtreeIter->IsDone()) {
if (mStart)
mIterState = eUseStart;
else
mIterState = eDone;
}
} else
mIterState = eDone;
}
// CollapseRangeAfterDelete() is a utility method that is used by
// DeleteContents() and ExtractContents() to collapse the range
// in the correct place, under the range's root container (the
// range end points common container) as outlined by the Range spec:
//
// The assumption made by this method is that the delete or extract
// has been done already, and left the range in a state where there is
// no content between the 2 end points.
static nsresult CollapseRangeAfterDelete(nsRange* aRange) {
NS_ENSURE_ARG_POINTER(aRange);
// Check if range gravity took care of collapsing the range for us!
if (aRange->Collapsed()) {
// aRange is collapsed so there's nothing for us to do.
//
// There are 2 possible scenarios here:
//
// 1. aRange could've been collapsed prior to the delete/extract,
// which would've resulted in nothing being removed, so aRange
// is already where it should be.
//
// 2. Prior to the delete/extract, aRange's start and end were in
// the same container which would mean everything between them
// was removed, causing range gravity to collapse the range.
return NS_OK;
}
// aRange isn't collapsed so figure out the appropriate place to collapse!
// First get both end points and their common ancestor.
if (!aRange->IsPositioned()) {
return NS_ERROR_NOT_INITIALIZED;
}
nsCOMPtr<nsINode> commonAncestor =
aRange->GetClosestCommonInclusiveAncestor();
nsCOMPtr<nsINode> startContainer = aRange->GetStartContainer();
nsCOMPtr<nsINode> endContainer = aRange->GetEndContainer();
// Collapse to one of the end points if they are already in the
// commonAncestor. This should work ok since this method is called
// immediately after a delete or extract that leaves no content
// between the 2 end points!
if (startContainer == commonAncestor) {
aRange->Collapse(true);
return NS_OK;
}
if (endContainer == commonAncestor) {
aRange->Collapse(false);
return NS_OK;
}
// End points are at differing levels. We want to collapse to the
// point that is between the 2 subtrees that contain each point,
// under the common ancestor.
nsCOMPtr<nsINode> nodeToSelect(startContainer);
while (nodeToSelect) {
nsCOMPtr<nsINode> parent = nodeToSelect->GetParentNode();
if (parent == commonAncestor) break; // We found the nodeToSelect!
nodeToSelect = parent;
}
if (!nodeToSelect) return NS_ERROR_FAILURE; // This should never happen!
ErrorResult error;
aRange->SelectNode(*nodeToSelect, error);
if (error.Failed()) {
return error.StealNSResult();
}
aRange->Collapse(false);
return NS_OK;
}
NS_IMETHODIMP
PrependChild(nsINode* aContainer, nsINode* aChild) {
nsCOMPtr<nsINode> first = aContainer->GetFirstChild();
ErrorResult rv;
aContainer->InsertBefore(*aChild, first, rv);
return rv.StealNSResult();
}
// Helper function for CutContents, making sure that the current node wasn't
static bool ValidateCurrentNode(nsRange* aRange, RangeSubtreeIterator& aIter) {
bool before, after;
nsCOMPtr<nsINode> node = aIter.GetCurrentNode();
if (!node) {
// We don't have to worry that the node was removed if it doesn't exist,
// e.g., the iterator is done.
return true;
}
nsresult rv = RangeUtils::CompareNodeToRange(node, aRange, &before, &after);
if (NS_WARN_IF(NS_FAILED(rv))) {
return false;
}
if (before || after) {
if (node->IsCharacterData()) {
// If we're dealing with the start/end container which is a character
// node, pretend that the node is in the range.
if (before && node == aRange->GetStartContainer()) {
before = false;
}
if (after && node == aRange->GetEndContainer()) {
after = false;
}
}
}
return !before && !after;
}
void nsRange::CutContents(DocumentFragment** aFragment, ErrorResult& aRv) {
if (aFragment) {
*aFragment = nullptr;
}
if (!CanAccess(*GetMayCrossShadowBoundaryStartContainer()) ||
!CanAccess(*GetMayCrossShadowBoundaryEndContainer())) {
aRv.Throw(NS_ERROR_DOM_SECURITY_ERR);
return;
}
nsCOMPtr<Document> doc = mStart.Container()->OwnerDoc();
nsCOMPtr<nsINode> commonAncestor = GetCommonAncestorContainer(
aRv, StaticPrefs::dom_shadowdom_selection_across_boundary_enabled()
? AllowRangeCrossShadowBoundary::Yes
: AllowRangeCrossShadowBoundary::No);
if (aRv.Failed()) {
return;
}
// If aFragment isn't null, create a temporary fragment to hold our return.
RefPtr<DocumentFragment> retval;
if (aFragment) {
retval =
new (doc->NodeInfoManager()) DocumentFragment(doc->NodeInfoManager());
}
nsCOMPtr<nsINode> commonCloneAncestor = retval.get();
// Batch possible DOMSubtreeModified events.
mozAutoSubtreeModified subtree(mRoot ? mRoot->OwnerDoc() : nullptr, nullptr);
// Save the range end points locally to avoid interference
// of Range gravity during our edits!
nsCOMPtr<nsINode> startContainer = GetMayCrossShadowBoundaryStartContainer();
// `GetCommonAncestorContainer()` above ensures the range is positioned, hence
// there have to be valid offsets.
const uint32_t startOffset = *MayCrossShadowBoundaryStartRef().Offset(
RangeBoundary::OffsetFilter::kValidOffsets);
nsCOMPtr<nsINode> endContainer = GetMayCrossShadowBoundaryEndContainer();
const uint32_t endOffset = *MayCrossShadowBoundaryEndRef().Offset(
RangeBoundary::OffsetFilter::kValidOffsets);
if (retval) {
// This can happen only if the common ancestor is a document, in which case
// we just need to find its doctype child and check if that's in the range.
nsCOMPtr<Document> commonAncestorDocument =
do_QueryInterface(commonAncestor);
if (commonAncestorDocument) {
RefPtr<DocumentType> doctype = commonAncestorDocument->GetDoctype();
// `GetCommonAncestorContainer()` above ensured the range is positioned.
// Hence, start and end are both set and valid. If available, `doctype`
// has a common ancestor with start and end, hence both have to be
// comparable to it.
if (doctype &&
*nsContentUtils::ComparePoints(startContainer, startOffset, doctype,
0) < 0 &&
*nsContentUtils::ComparePoints(doctype, 0, endContainer, endOffset) <
0) {
aRv.ThrowHierarchyRequestError("Start or end position isn't valid.");
return;
}
}
}
// Create and initialize a subtree iterator that will give
// us all the subtrees within the range.
RangeSubtreeIterator iter;
aRv = iter.Init(this,
StaticPrefs::dom_shadowdom_selection_across_boundary_enabled()
? AllowRangeCrossShadowBoundary::Yes
: AllowRangeCrossShadowBoundary::No);
if (aRv.Failed()) {
return;
}
if (iter.IsDone()) {
// There's nothing for us to delete.
aRv = CollapseRangeAfterDelete(this);
if (!aRv.Failed() && aFragment) {
retval.forget(aFragment);
}
return;
}
iter.First();
bool handled = false;
// With the exception of text nodes that contain one of the range
// end points, the subtree iterator should only give us back subtrees
// that are completely contained between the range's end points.
while (!iter.IsDone()) {
nsCOMPtr<nsINode> nodeToResult;
nsCOMPtr<nsINode> node = iter.GetCurrentNode();
// Before we delete anything, advance the iterator to the next node that's
// not a descendant of this one. XXX It's a bit silly to iterate through
// the descendants only to throw them out, we should use an iterator that
// skips the descendants to begin with.
iter.Next();
nsCOMPtr<nsINode> nextNode = iter.GetCurrentNode();
while (nextNode && nextNode->IsInclusiveDescendantOf(node)) {
iter.Next();
nextNode = iter.GetCurrentNode();
}
handled = false;
// If it's CharacterData, make sure we might need to delete
// part of the data, instead of removing the whole node.
//
// XXX_kin: We need to also handle ProcessingInstruction
// XXX_kin: according to the spec.
if (auto charData = CharacterData::FromNode(node)) {
uint32_t dataLength = 0;
if (node == startContainer) {
if (node == endContainer) {
// This range is completely contained within a single text node.
// Delete or extract the data between startOffset and endOffset.
if (endOffset > startOffset) {
if (retval) {
nsAutoString cutValue;
charData->SubstringData(startOffset, endOffset - startOffset,
cutValue, aRv);
if (NS_WARN_IF(aRv.Failed())) {
return;
}
nsCOMPtr<nsINode> clone = node->CloneNode(false, aRv);
if (NS_WARN_IF(aRv.Failed())) {
return;
}
clone->SetNodeValue(cutValue, aRv);
if (NS_WARN_IF(aRv.Failed())) {
return;
}
nodeToResult = clone;
}
nsMutationGuard guard;
charData->DeleteData(startOffset, endOffset - startOffset, aRv);
if (NS_WARN_IF(aRv.Failed())) {
return;
}
if (guard.Mutated(0) && !ValidateCurrentNode(this, iter)) {
aRv.Throw(NS_ERROR_UNEXPECTED);
return;
}
}
handled = true;
} else {
// Delete or extract everything after startOffset.
dataLength = charData->Length();
if (dataLength >= startOffset) {
if (retval) {
nsAutoString cutValue;
charData->SubstringData(startOffset, dataLength, cutValue, aRv);
if (NS_WARN_IF(aRv.Failed())) {
return;
}
nsCOMPtr<nsINode> clone = node->CloneNode(false, aRv);
if (NS_WARN_IF(aRv.Failed())) {
return;
}
clone->SetNodeValue(cutValue, aRv);
if (NS_WARN_IF(aRv.Failed())) {
return;
}
nodeToResult = clone;
}
nsMutationGuard guard;
charData->DeleteData(startOffset, dataLength, aRv);
if (NS_WARN_IF(aRv.Failed())) {
return;
}
if (guard.Mutated(0) && !ValidateCurrentNode(this, iter)) {
aRv.Throw(NS_ERROR_UNEXPECTED);
return;
}
}
handled = true;
}
} else if (node == endContainer) {
// Delete or extract everything before endOffset.
if (retval) {
nsAutoString cutValue;
charData->SubstringData(0, endOffset, cutValue, aRv);
if (NS_WARN_IF(aRv.Failed())) {
return;
}
nsCOMPtr<nsINode> clone = node->CloneNode(false, aRv);
if (NS_WARN_IF(aRv.Failed())) {
return;
}
clone->SetNodeValue(cutValue, aRv);
if (NS_WARN_IF(aRv.Failed())) {
return;
}
nodeToResult = clone;
}
nsMutationGuard guard;
charData->DeleteData(0, endOffset, aRv);
if (NS_WARN_IF(aRv.Failed())) {
return;
}
if (guard.Mutated(0) && !ValidateCurrentNode(this, iter)) {
aRv.Throw(NS_ERROR_UNEXPECTED);
return;
}
handled = true;
}
}
if (!handled && (node == endContainer || node == startContainer)) {
if (node && node->IsElement() &&
((node == endContainer && endOffset == 0) ||
(node == startContainer &&
node->AsElement()->GetChildCount() == startOffset))) {
if (retval) {
nodeToResult = node->CloneNode(false, aRv);
if (aRv.Failed()) {
return;
}
}
handled = true;
}
}
if (!handled) {
// node was not handled above, so it must be completely contained
// within the range. Just remove it from the tree!
nodeToResult = node;
}
uint32_t parentCount = 0;
// Set the result to document fragment if we have 'retval'.
if (retval) {
nsCOMPtr<nsINode> oldCommonAncestor = commonAncestor;
if (!iter.IsDone()) {
// Setup the parameters for the next iteration of the loop.
if (!nextNode) {
aRv.Throw(NS_ERROR_UNEXPECTED);
return;
}
// Get node's and nextNode's common parent. Do this before moving
// nodes from original DOM to result fragment.
commonAncestor =
nsContentUtils::GetClosestCommonInclusiveAncestor(node, nextNode);
if (!commonAncestor) {
aRv.Throw(NS_ERROR_UNEXPECTED);
return;
}
nsCOMPtr<nsINode> parentCounterNode = node;
while (parentCounterNode && parentCounterNode != commonAncestor) {
++parentCount;
parentCounterNode = parentCounterNode->GetParentNode();
if (!parentCounterNode) {
aRv.Throw(NS_ERROR_UNEXPECTED);
return;
}
}
}
// Clone the parent hierarchy between commonAncestor and node.
nsCOMPtr<nsINode> closestAncestor, farthestAncestor;
aRv = CloneParentsBetween(oldCommonAncestor, node,
getter_AddRefs(closestAncestor),
getter_AddRefs(farthestAncestor));
if (aRv.Failed()) {
return;
}
if (farthestAncestor) {
commonCloneAncestor->AppendChild(*farthestAncestor, aRv);
if (NS_WARN_IF(aRv.Failed())) {
return;
}
}
nsMutationGuard guard;
nsCOMPtr<nsINode> parent = nodeToResult->GetParentNode();
if (closestAncestor) {
closestAncestor->AppendChild(*nodeToResult, aRv);
} else {
commonCloneAncestor->AppendChild(*nodeToResult, aRv);
}
if (NS_WARN_IF(aRv.Failed())) {
return;
}
if (guard.Mutated(parent ? 2 : 1) && !ValidateCurrentNode(this, iter)) {
aRv.Throw(NS_ERROR_UNEXPECTED);
return;
}
} else if (nodeToResult) {
nsMutationGuard guard;
nsCOMPtr<nsINode> node = nodeToResult;
nsCOMPtr<nsINode> parent = node->GetParentNode();
if (parent) {
parent->RemoveChild(*node, aRv);
if (aRv.Failed()) {
return;
}
}
if (guard.Mutated(1) && !ValidateCurrentNode(this, iter)) {
aRv.Throw(NS_ERROR_UNEXPECTED);
return;
}
}
if (!iter.IsDone() && retval) {
// Find the equivalent of commonAncestor in the cloned tree.
nsCOMPtr<nsINode> newCloneAncestor = nodeToResult;
for (uint32_t i = parentCount; i; --i) {
newCloneAncestor = newCloneAncestor->GetParentNode();
if (!newCloneAncestor) {
aRv.Throw(NS_ERROR_UNEXPECTED);
return;
}
}
commonCloneAncestor = newCloneAncestor;
}
}
aRv = CollapseRangeAfterDelete(this);
if (!aRv.Failed() && aFragment) {
retval.forget(aFragment);
}
}
void nsRange::DeleteContents(ErrorResult& aRv) { CutContents(nullptr, aRv); }
already_AddRefed<DocumentFragment> nsRange::ExtractContents(ErrorResult& rv) {
RefPtr<DocumentFragment> fragment;
CutContents(getter_AddRefs(fragment), rv);
return fragment.forget();
}
int16_t nsRange::CompareBoundaryPoints(uint16_t aHow,
const nsRange& aOtherRange,
ErrorResult& aRv) {
if (!mIsPositioned || !aOtherRange.IsPositioned()) {
aRv.Throw(NS_ERROR_NOT_INITIALIZED);
return 0;
}
nsINode *ourNode, *otherNode;
uint32_t ourOffset, otherOffset;
switch (aHow) {
case Range_Binding::START_TO_START:
ourNode = mStart.Container();
ourOffset = *mStart.Offset(RangeBoundary::OffsetFilter::kValidOffsets);
otherNode = aOtherRange.GetStartContainer();
otherOffset = aOtherRange.StartOffset();
break;
case Range_Binding::START_TO_END:
ourNode = mEnd.Container();
ourOffset = *mEnd.Offset(RangeBoundary::OffsetFilter::kValidOffsets);
otherNode = aOtherRange.GetStartContainer();
otherOffset = aOtherRange.StartOffset();
break;
case Range_Binding::END_TO_START:
ourNode = mStart.Container();
ourOffset = *mStart.Offset(RangeBoundary::OffsetFilter::kValidOffsets);
otherNode = aOtherRange.GetEndContainer();
otherOffset = aOtherRange.EndOffset();
break;
case Range_Binding::END_TO_END:
ourNode = mEnd.Container();
ourOffset = *mEnd.Offset(RangeBoundary::OffsetFilter::kValidOffsets);
otherNode = aOtherRange.GetEndContainer();
otherOffset = aOtherRange.EndOffset();
break;
default:
// We were passed an illegal value
aRv.Throw(NS_ERROR_DOM_NOT_SUPPORTED_ERR);
return 0;
}
if (mRoot != aOtherRange.GetRoot()) {
aRv.Throw(NS_ERROR_DOM_WRONG_DOCUMENT_ERR);
return 0;
}
const Maybe<int32_t> order =
nsContentUtils::ComparePoints(ourNode, ourOffset, otherNode, otherOffset);
// `this` and `aOtherRange` share the same root and (ourNode, ourOffset),
// (otherNode, otherOffset) correspond to some of their boundaries. Hence,
// (ourNode, ourOffset) and (otherNode, otherOffset) have to be comparable.
return *order;
}
/* static */
nsresult nsRange::CloneParentsBetween(nsINode* aAncestor, nsINode* aNode,
nsINode** aClosestAncestor,
nsINode** aFarthestAncestor) {
NS_ENSURE_ARG_POINTER(
(aAncestor && aNode && aClosestAncestor && aFarthestAncestor));
*aClosestAncestor = nullptr;
*aFarthestAncestor = nullptr;
if (aAncestor == aNode) return NS_OK;
AutoTArray<nsCOMPtr<nsINode>, 16> parentStack;
nsCOMPtr<nsINode> parent = aNode->GetParentNode();
while (parent && parent != aAncestor) {
parentStack.AppendElement(parent);
parent = parent->GetParentNode();
}
nsCOMPtr<nsINode> firstParent;
nsCOMPtr<nsINode> lastParent;
for (int32_t i = parentStack.Length() - 1; i >= 0; i--) {
ErrorResult rv;
nsCOMPtr<nsINode> clone = parentStack[i]->CloneNode(false, rv);
if (rv.Failed()) {
return rv.StealNSResult();
}
if (!clone) {
return NS_ERROR_FAILURE;
}
if (!lastParent) {
lastParent = clone;
} else {
firstParent->AppendChild(*clone, rv);
if (rv.Failed()) {
return rv.StealNSResult();
}
}
firstParent = clone;
}
firstParent.forget(aClosestAncestor);
lastParent.forget(aFarthestAncestor);
return NS_OK;
}
already_AddRefed<DocumentFragment> nsRange::CloneContents(ErrorResult& aRv) {
nsCOMPtr<nsINode> commonAncestor = GetCommonAncestorContainer(aRv);
MOZ_ASSERT(!aRv.Failed(), "GetCommonAncestorContainer() shouldn't fail!");
nsCOMPtr<Document> doc = mStart.Container()->OwnerDoc();
NS_ASSERTION(doc, "CloneContents needs a document to continue.");
if (!doc) {
aRv.Throw(NS_ERROR_FAILURE);
return nullptr;
}
// Create a new document fragment in the context of this document,
// which might be null
RefPtr<DocumentFragment> clonedFrag =
new (doc->NodeInfoManager()) DocumentFragment(doc->NodeInfoManager());
if (Collapsed()) {
return clonedFrag.forget();
}
nsCOMPtr<nsINode> commonCloneAncestor = clonedFrag.get();
// Create and initialize a subtree iterator that will give
// us all the subtrees within the range.
RangeSubtreeIterator iter;
aRv = iter.Init(this);
if (aRv.Failed()) {
return nullptr;
}
if (iter.IsDone()) {
// There's nothing to add to the doc frag, we must be done!
return clonedFrag.forget();
}
iter.First();
// With the exception of text nodes that contain one of the range
// end points and elements which don't have any content selected the subtree
// iterator should only give us back subtrees that are completely contained
// between the range's end points.
//
// Unfortunately these subtrees don't contain the parent hierarchy/context
// that the Range spec requires us to return. This loop clones the
// parent hierarchy, adds a cloned version of the subtree, to it, then
// correctly places this new subtree into the doc fragment.
while (!iter.IsDone()) {
nsCOMPtr<nsINode> node = iter.GetCurrentNode();
bool deepClone =
!node->IsElement() ||
(!(node == mEnd.Container() &&
*mEnd.Offset(RangeBoundary::OffsetFilter::kValidOffsets) == 0) &&
!(node == mStart.Container() &&
*mStart.Offset(RangeBoundary::OffsetFilter::kValidOffsets) ==
node->AsElement()->GetChildCount()));
// Clone the current subtree!
nsCOMPtr<nsINode> clone = node->CloneNode(deepClone, aRv);
if (aRv.Failed()) {
return nullptr;
}
// If it's CharacterData, make sure we only clone what
// is in the range.
//
// XXX_kin: We need to also handle ProcessingInstruction
// XXX_kin: according to the spec.
if (auto charData = CharacterData::FromNode(clone)) {
if (node == mEnd.Container()) {
// We only need the data before mEndOffset, so get rid of any
// data after it.
uint32_t dataLength = charData->Length();
if (dataLength >
*mEnd.Offset(RangeBoundary::OffsetFilter::kValidOffsets)) {
charData->DeleteData(
*mEnd.Offset(RangeBoundary::OffsetFilter::kValidOffsets),
dataLength -
*mEnd.Offset(RangeBoundary::OffsetFilter::kValidOffsets),
aRv);
if (aRv.Failed()) {
return nullptr;
}
}
}
if (node == mStart.Container()) {
// We don't need any data before mStartOffset, so just
// delete it!
if (*mStart.Offset(RangeBoundary::OffsetFilter::kValidOffsets) > 0) {
charData->DeleteData(
0, *mStart.Offset(RangeBoundary::OffsetFilter::kValidOffsets),
aRv);
if (aRv.Failed()) {
return nullptr;
}
}
}
}
// Clone the parent hierarchy between commonAncestor and node.
nsCOMPtr<nsINode> closestAncestor, farthestAncestor;
aRv = CloneParentsBetween(commonAncestor, node,
getter_AddRefs(closestAncestor),
getter_AddRefs(farthestAncestor));
if (aRv.Failed()) {
return nullptr;
}
// Hook the parent hierarchy/context of the subtree into the clone tree.
if (farthestAncestor) {
commonCloneAncestor->AppendChild(*farthestAncestor, aRv);
if (aRv.Failed()) {
return nullptr;
}
}
// Place the cloned subtree into the cloned doc frag tree!
nsCOMPtr<nsINode> cloneNode = clone;
if (closestAncestor) {
// Append the subtree under closestAncestor since it is the
// immediate parent of the subtree.
closestAncestor->AppendChild(*cloneNode, aRv);
} else {
// If we get here, there is no missing parent hierarchy between
// commonAncestor and node, so just append clone to commonCloneAncestor.
commonCloneAncestor->AppendChild(*cloneNode, aRv);
}
if (aRv.Failed()) {
return nullptr;
}
// Get the next subtree to be processed. The idea here is to setup
// the parameters for the next iteration of the loop.
iter.Next();
if (iter.IsDone()) break; // We must be done!
nsCOMPtr<nsINode> nextNode = iter.GetCurrentNode();
if (!nextNode) {
aRv.Throw(NS_ERROR_FAILURE);
return nullptr;
}
// Get node and nextNode's common parent.
commonAncestor =
nsContentUtils::GetClosestCommonInclusiveAncestor(node, nextNode);
if (!commonAncestor) {
aRv.Throw(NS_ERROR_FAILURE);
return nullptr;
}
// Find the equivalent of commonAncestor in the cloned tree!
while (node && node != commonAncestor) {
node = node->GetParentNode();
if (aRv.Failed()) {
return nullptr;
}
if (!node) {
aRv.Throw(NS_ERROR_FAILURE);
return nullptr;
}
cloneNode = cloneNode->GetParentNode();
if (!cloneNode) {
aRv.Throw(NS_ERROR_FAILURE);
return nullptr;
}
}
commonCloneAncestor = cloneNode;
}
return clonedFrag.forget();
}
already_AddRefed<nsRange> nsRange::CloneRange() const {
RefPtr<nsRange> range = nsRange::Create(mOwner);
range->DoSetRange(mStart, mEnd, mRoot);
if (mCrossShadowBoundaryRange) {
range->CreateOrUpdateCrossShadowBoundaryRangeIfNeeded(
mCrossShadowBoundaryRange->StartRef(),
mCrossShadowBoundaryRange->EndRef());
}
return range.forget();
}
void nsRange::InsertNode(nsINode& aNode, ErrorResult& aRv) {
if (!CanAccess(aNode)) {
aRv.Throw(NS_ERROR_DOM_SECURITY_ERR);
return;
}
if (!IsPositioned()) {
aRv.Throw(NS_ERROR_NOT_INITIALIZED);
return;
}
uint32_t tStartOffset = StartOffset();
nsCOMPtr<nsINode> tStartContainer = GetStartContainer();
if (!CanAccess(*tStartContainer)) {
aRv.Throw(NS_ERROR_DOM_SECURITY_ERR);
return;
}
if (&aNode == tStartContainer) {
aRv.ThrowHierarchyRequestError(
"The inserted node can not be range's start node.");
return;
}
// This is the node we'll be inserting before, and its parent
nsCOMPtr<nsINode> referenceNode;
nsCOMPtr<nsINode> referenceParentNode = tStartContainer;
RefPtr<Text> startTextNode = tStartContainer->GetAsText();
nsCOMPtr<nsINodeList> tChildList;
if (startTextNode) {
referenceParentNode = tStartContainer->GetParentNode();
if (!referenceParentNode) {
aRv.ThrowHierarchyRequestError(
"Can not get range's start node's parent.");
return;
}
referenceParentNode->EnsurePreInsertionValidity(aNode, tStartContainer,
aRv);
if (aRv.Failed()) {
return;
}
RefPtr<Text> secondPart = startTextNode->SplitText(tStartOffset, aRv);
if (aRv.Failed()) {
return;
}
referenceNode = secondPart;
} else {
tChildList = tStartContainer->ChildNodes();
// find the insertion point in the DOM and insert the Node
referenceNode = tChildList->Item(tStartOffset);
tStartContainer->EnsurePreInsertionValidity(aNode, referenceNode, aRv);
if (aRv.Failed()) {
return;
}
}
// Ideally we'd only do this if needed, but it's tricky to know when it's
uint32_t newOffset;
if (referenceNode) {
Maybe<uint32_t> indexInParent = referenceNode->ComputeIndexInParentNode();
if (MOZ_UNLIKELY(NS_WARN_IF(indexInParent.isNothing()))) {
aRv.Throw(NS_ERROR_FAILURE);
return;
}
newOffset = *indexInParent;
} else {
newOffset = tChildList->Length();
}
if (aNode.NodeType() == nsINode::DOCUMENT_FRAGMENT_NODE) {
newOffset += aNode.GetChildCount();
} else {
newOffset++;
}
// Now actually insert the node
nsCOMPtr<nsINode> tResultNode;
tResultNode = referenceParentNode->InsertBefore(aNode, referenceNode, aRv);
if (aRv.Failed()) {
return;
}
if (Collapsed()) {
aRv = SetEnd(referenceParentNode, newOffset);
}
}
void nsRange::SurroundContents(nsINode& aNewParent, ErrorResult& aRv) {
if (!CanAccess(aNewParent)) {
aRv.Throw(NS_ERROR_DOM_SECURITY_ERR);
return;
}
if (!mRoot) {
aRv.Throw(NS_ERROR_DOM_INVALID_STATE_ERR);
return;
}
// INVALID_STATE_ERROR: Raised if the Range partially selects a non-text
// node.
if (mStart.Container() != mEnd.Container()) {
bool startIsText = mStart.Container()->IsText();
bool endIsText = mEnd.Container()->IsText();
nsINode* startGrandParent = mStart.Container()->GetParentNode();
nsINode* endGrandParent = mEnd.Container()->GetParentNode();
if (!((startIsText && endIsText && startGrandParent &&
startGrandParent == endGrandParent) ||
(startIsText && startGrandParent &&
startGrandParent == mEnd.Container()) ||
(endIsText && endGrandParent &&
endGrandParent == mStart.Container()))) {
aRv.Throw(NS_ERROR_DOM_INVALID_STATE_ERR);
return;
}
}
// INVALID_NODE_TYPE_ERROR if aNewParent is something that can't be inserted
// (Document, DocumentType, DocumentFragment)
uint16_t nodeType = aNewParent.NodeType();
if (nodeType == nsINode::DOCUMENT_NODE ||
nodeType == nsINode::DOCUMENT_TYPE_NODE ||
nodeType == nsINode::DOCUMENT_FRAGMENT_NODE) {
aRv.Throw(NS_ERROR_DOM_INVALID_NODE_TYPE_ERR);
return;
}
// Extract the contents within the range.
RefPtr<DocumentFragment> docFrag = ExtractContents(aRv);
if (aRv.Failed()) {
return;
}
if (!docFrag) {
aRv.Throw(NS_ERROR_FAILURE);
return;
}
// Spec says we need to remove all of aNewParent's
// children prior to insertion.
nsCOMPtr<nsINodeList> children = aNewParent.ChildNodes();
if (!children) {
aRv.Throw(NS_ERROR_FAILURE);
return;
}
uint32_t numChildren = children->Length();
while (numChildren) {
nsCOMPtr<nsINode> child = children->Item(--numChildren);
if (!child) {
aRv.Throw(NS_ERROR_FAILURE);
return;
}
aNewParent.RemoveChild(*child, aRv);
if (aRv.Failed()) {
return;
}
}
// Insert aNewParent at the range's start point.
InsertNode(aNewParent, aRv);
if (aRv.Failed()) {
return;
}
// Append the content we extracted under aNewParent.
aNewParent.AppendChild(*docFrag, aRv);
if (aRv.Failed()) {
return;
}
// Select aNewParent, and its contents.
SelectNode(aNewParent, aRv);
}
void nsRange::ToString(nsAString& aReturn, ErrorResult& aErr) {
// clear the string
aReturn.Truncate();
// If we're unpositioned, return the empty string
if (!mIsPositioned) {
return;
}
#ifdef DEBUG_range
printf("Range dump: -----------------------\n");
#endif /* DEBUG */
// effeciency hack for simple case
if (mStart.Container() == mEnd.Container()) {
Text* textNode =
mStart.Container() ? mStart.Container()->GetAsText() : nullptr;
if (textNode) {
#ifdef DEBUG_range
// If debug, dump it:
textNode->List(stdout);
printf("End Range dump: -----------------------\n");
#endif /* DEBUG */
// grab the text
textNode->SubstringData(
*mStart.Offset(RangeBoundary::OffsetFilter::kValidOffsets),
*mEnd.Offset(RangeBoundary::OffsetFilter::kValidOffsets) -
*mStart.Offset(RangeBoundary::OffsetFilter::kValidOffsets),
aReturn, aErr);
return;
}
}
/* complex case: mStart.Container() != mEnd.Container(), or mStartParent not a
text node revisit - there are potential optimizations here and also
tradeoffs.
*/
PostContentIterator postOrderIter;
nsresult rv = postOrderIter.Init(this);
if (NS_WARN_IF(NS_FAILED(rv))) {
aErr.Throw(rv);
return;
}
nsString tempString;
// loop through the content iterator, which returns nodes in the range in
// close tag order, and grab the text from any text node
for (; !postOrderIter.IsDone(); postOrderIter.Next()) {
nsINode* n = postOrderIter.GetCurrentNode();
#ifdef DEBUG_range
// If debug, dump it:
n->List(stdout);
#endif /* DEBUG */
Text* textNode = n->GetAsText();
if (textNode) // if it's a text node, get the text
{
if (n == mStart.Container()) { // only include text past start offset
uint32_t strLength = textNode->Length();
textNode->SubstringData(
*mStart.Offset(RangeBoundary::OffsetFilter::kValidOffsets),
strLength -
*mStart.Offset(RangeBoundary::OffsetFilter::kValidOffsets),
tempString, IgnoreErrors());
aReturn += tempString;
} else if (n ==
mEnd.Container()) { // only include text before end offset
textNode->SubstringData(
0, *mEnd.Offset(RangeBoundary::OffsetFilter::kValidOffsets),
tempString, IgnoreErrors());
aReturn += tempString;
} else { // grab the whole kit-n-kaboodle
textNode->GetData(tempString);
aReturn += tempString;
}
}
}
#ifdef DEBUG_range
printf("End Range dump: -----------------------\n");
#endif /* DEBUG */
}
void nsRange::Detach() {}
already_AddRefed<DocumentFragment> nsRange::CreateContextualFragment(
const nsAString& aFragment, ErrorResult& aRv) const {
if (!mIsPositioned) {
aRv.Throw(NS_ERROR_FAILURE);
return nullptr;
}
return nsContentUtils::CreateContextualFragment(mStart.Container(), aFragment,
false, aRv);
}
already_AddRefed<DocumentFragment> nsRange::CreateContextualFragment(
const TrustedHTMLOrString& aFragment, ErrorResult& aRv) const {
if (!mIsPositioned) {
aRv.Throw(NS_ERROR_FAILURE);
return nullptr;
}
MOZ_ASSERT(mStart.Container());
constexpr nsLiteralString sink = u"Range createContextualFragment"_ns;
Maybe<nsAutoString> compliantStringHolder;
nsCOMPtr<nsINode> node = mStart.Container();
const nsAString* compliantString =
TrustedTypeUtils::GetTrustedTypesCompliantString(
aFragment, sink, kTrustedTypesOnlySinkGroup, *node,
compliantStringHolder, aRv);
if (aRv.Failed()) {
return nullptr;
}
return nsContentUtils::CreateContextualFragment(mStart.Container(),
*compliantString, false, aRv);
}
static void ExtractRectFromOffset(nsIFrame* aFrame, const int32_t aOffset,
nsRect* aR, bool aFlushToOriginEdge,
bool aClampToEdge) {
MOZ_ASSERT(aFrame);
MOZ_ASSERT(aR);
nsPoint point;
aFrame->GetPointFromOffset(aOffset, &point);
// Determine if aFrame has a vertical writing mode, which will change our math
// on the output rect.
bool isVertical = aFrame->GetWritingMode().IsVertical();
if (!aClampToEdge && !aR->Contains(point)) {
// If point is outside aR, and we aren't clamping, output an empty rect
// with origin at the point.
if (isVertical) {
aR->SetHeight(0);
aR->y = point.y;
} else {
aR->SetWidth(0);
aR->x = point.x;
}
return;
}
if (aClampToEdge) {
point = aR->ClampPoint(point);
}
// point is within aR, and now we'll modify aR to output a rect that has point
// on one edge. But which edge?
if (aFlushToOriginEdge) {
// The output rect should be flush to the edge of aR that contains the
// origin.
if (isVertical) {
aR->SetHeight(point.y - aR->y);
} else {
aR->SetWidth(point.x - aR->x);
}
} else {
// The output rect should be flush to the edge of aR opposite the origin.
if (isVertical) {
aR->SetHeight(aR->YMost() - point.y);
aR->y = point.y;
} else {
aR->SetWidth(aR->XMost() - point.x);
aR->x = point.x;
}
}
}
static nsTextFrame* GetTextFrameForContent(nsIContent* aContent,
bool aFlushLayout) {
RefPtr<Document> doc = aContent->OwnerDoc();
PresShell* presShell = doc->GetPresShell();
if (!presShell) {
return nullptr;
}
// Try to un-suppress whitespace if needed, but only if we'll be able to flush
// to immediately see the results of the un-suppression. If we can't flush
// here, then calling EnsureFrameForTextNodeIsCreatedAfterFlush would be
// pointless anyway.
if (aFlushLayout) {
const bool frameWillBeUnsuppressed =
presShell->FrameConstructor()
->EnsureFrameForTextNodeIsCreatedAfterFlush(
static_cast<CharacterData*>(aContent));
if (frameWillBeUnsuppressed) {
doc->FlushPendingNotifications(FlushType::Layout);
}
}
nsIFrame* frame = aContent->GetPrimaryFrame();
if (!frame || !frame->IsTextFrame()) {
return nullptr;
}
return static_cast<nsTextFrame*>(frame);
}
static nsresult GetPartialTextRect(RectCallback* aCallback,
Sequence<nsString>* aTextList,
nsIContent* aContent, int32_t aStartOffset,
int32_t aEndOffset, bool aClampToEdge,
bool aFlushLayout) {
nsTextFrame* textFrame = GetTextFrameForContent(aContent, aFlushLayout);
if (textFrame) {
nsIFrame* relativeTo =
nsLayoutUtils::GetContainingBlockForClientRect(textFrame);
for (nsTextFrame* f = textFrame->FindContinuationForOffset(aStartOffset); f;
f = static_cast<nsTextFrame*>(f->GetNextContinuation())) {
int32_t fstart = f->GetContentOffset(), fend = f->GetContentEnd();
if (fend <= aStartOffset) {
continue;
}
if (fstart >= aEndOffset) {
break;
}
// Calculate the text content offsets we'll need if text is requested.
int32_t textContentStart = fstart;
int32_t textContentEnd = fend;
// overlapping with the offset we want
f->EnsureTextRun(nsTextFrame::eInflated);
NS_ENSURE_TRUE(f->GetTextRun(nsTextFrame::eInflated),
NS_ERROR_OUT_OF_MEMORY);
bool topLeftToBottomRight =
!f->GetTextRun(nsTextFrame::eInflated)->IsInlineReversed();
nsRect r = f->GetRectRelativeToSelf();
if (fstart < aStartOffset) {
// aStartOffset is within this frame
ExtractRectFromOffset(f, aStartOffset, &r, !topLeftToBottomRight,
aClampToEdge);
textContentStart = aStartOffset;
}
if (fend > aEndOffset) {
// aEndOffset is in the middle of this frame
ExtractRectFromOffset(f, aEndOffset, &r, topLeftToBottomRight,
aClampToEdge);
textContentEnd = aEndOffset;
}
r = nsLayoutUtils::TransformFrameRectToAncestor(f, r, relativeTo);
aCallback->AddRect(r);
// Finally capture the text, if requested.
if (aTextList) {
nsIFrame::RenderedText renderedText =
f->GetRenderedText(textContentStart, textContentEnd,
nsIFrame::TextOffsetType::OffsetsInContentText,
nsIFrame::TrailingWhitespace::DontTrim);
NS_ENSURE_TRUE(aTextList->AppendElement(renderedText.mString, fallible),
NS_ERROR_OUT_OF_MEMORY);
}
}
}
return NS_OK;
}
static void CollectClientRectsForSubtree(
nsINode* aNode, RectCallback* aCollector, Sequence<nsString>* aTextList,
nsINode* aStartContainer, uint32_t aStartOffset, nsINode* aEndContainer,
uint32_t aEndOffset, bool aClampToEdge, bool aFlushLayout, bool aTextOnly) {
auto* content = nsIContent::FromNode(aNode);
if (!content) {
return;
}
const bool isText = content->IsText();
if (isText) {
if (aNode == aStartContainer) {
int32_t offset = aStartContainer == aEndContainer
? static_cast<int32_t>(aEndOffset)
: content->AsText()->TextDataLength();
GetPartialTextRect(aCollector, aTextList, content,
static_cast<int32_t>(aStartOffset), offset,
aClampToEdge, aFlushLayout);
return;
}
if (aNode == aEndContainer) {
GetPartialTextRect(aCollector, aTextList, content, 0,
static_cast<int32_t>(aEndOffset), aClampToEdge,
aFlushLayout);
return;
}
}
if (nsIFrame* frame = content->GetPrimaryFrame()) {
if (!aTextOnly || isText) {
nsLayoutUtils::GetAllInFlowRectsAndTexts(
frame, nsLayoutUtils::GetContainingBlockForClientRect(frame),
aCollector, aTextList,
nsLayoutUtils::GetAllInFlowRectsFlag::AccountForTransforms);
if (isText) {
return;
}
aTextOnly = true;
// We just get the text when calling GetAllInFlowRectsAndTexts, so we
// don't need to call it again when visiting the children.
aTextList = nullptr;
}
} else if (!content->IsElement() ||
!content->AsElement()->IsDisplayContents()) {
return;
}
FlattenedChildIterator childIter(content);
for (nsIContent* child = childIter.GetNextChild(); child;
child = childIter.GetNextChild()) {
CollectClientRectsForSubtree(child, aCollector, aTextList, aStartContainer,
aStartOffset, aEndContainer, aEndOffset,
aClampToEdge, aFlushLayout, aTextOnly);
}
}
/* static */
void nsRange::CollectClientRectsAndText(
RectCallback* aCollector, Sequence<nsString>* aTextList, nsRange* aRange,
nsINode* aStartContainer, uint32_t aStartOffset, nsINode* aEndContainer,
uint32_t aEndOffset, bool aClampToEdge, bool aFlushLayout) {
// Currently, this method is called with start of end offset of nsRange.
// So, they must be between 0 - INT32_MAX.
MOZ_ASSERT(RangeUtils::IsValidOffset(aStartOffset));
MOZ_ASSERT(RangeUtils::IsValidOffset(aEndOffset));
// Hold strong pointers across the flush
nsCOMPtr<nsINode> startContainer = aStartContainer;
nsCOMPtr<nsINode> endContainer = aEndContainer;
// Flush out layout so our frames are up to date.
if (!aStartContainer->IsInComposedDoc()) {
return;
}
if (aFlushLayout) {
aStartContainer->OwnerDoc()->FlushPendingNotifications(FlushType::Layout);
// Recheck whether we're still in the document
if (!aStartContainer->IsInComposedDoc()) {
return;
}
}
RangeSubtreeIterator iter;
nsresult rv = iter.Init(aRange);
if (NS_FAILED(rv)) return;
if (iter.IsDone()) {
// the range is collapsed, only continue if the cursor is in a text node
if (aStartContainer->IsText()) {
nsTextFrame* textFrame =
GetTextFrameForContent(aStartContainer->AsText(), aFlushLayout);
if (textFrame) {
int32_t outOffset;
nsIFrame* outFrame;
textFrame->GetChildFrameContainingOffset(
static_cast<int32_t>(aStartOffset), false, &outOffset, &outFrame);
if (outFrame) {
nsIFrame* relativeTo =
nsLayoutUtils::GetContainingBlockForClientRect(outFrame);
nsRect r = outFrame->GetRectRelativeToSelf();
ExtractRectFromOffset(outFrame, static_cast<int32_t>(aStartOffset),
&r, false, aClampToEdge);
r.SetWidth(0);
r = nsLayoutUtils::TransformFrameRectToAncestor(outFrame, r,
relativeTo);
aCollector->AddRect(r);
}
}
}
return;
}
do {
nsCOMPtr<nsINode> node = iter.GetCurrentNode();
iter.Next();
CollectClientRectsForSubtree(node, aCollector, aTextList, aStartContainer,
aStartOffset, aEndContainer, aEndOffset,
aClampToEdge, aFlushLayout, false);
} while (!iter.IsDone());
}
already_AddRefed<DOMRect> nsRange::GetBoundingClientRect(bool aClampToEdge,
bool aFlushLayout) {
RefPtr<DOMRect> rect = new DOMRect(ToSupports(mOwner));
if (!mIsPositioned) {
return rect.forget();
}
nsLayoutUtils::RectAccumulator accumulator;
CollectClientRectsAndText(
&accumulator, nullptr, this, mStart.Container(),
*mStart.Offset(RangeBoundary::OffsetFilter::kValidOffsets),
mEnd.Container(),
*mEnd.Offset(RangeBoundary::OffsetFilter::kValidOffsets), aClampToEdge,
aFlushLayout);
nsRect r = accumulator.mResultRect.IsEmpty() ? accumulator.mFirstRect
: accumulator.mResultRect;
rect->SetLayoutRect(r);
return rect.forget();
}
already_AddRefed<DOMRectList> nsRange::GetClientRects(bool aClampToEdge,
bool aFlushLayout) {
return GetClientRectsInner(AllowRangeCrossShadowBoundary::No, aClampToEdge,
aFlushLayout);
}
already_AddRefed<DOMRectList> nsRange::GetAllowCrossShadowBoundaryClientRects(
bool aClampToEdge, bool aFlushLayout) {
return GetClientRectsInner(AllowRangeCrossShadowBoundary::Yes, aClampToEdge,
aFlushLayout);
}
already_AddRefed<DOMRectList> nsRange::GetClientRectsInner(
AllowRangeCrossShadowBoundary aAllowCrossShadowBoundaryRange,
bool aClampToEdge, bool aFlushLayout) {
if (!mIsPositioned) {
return nullptr;
}
RefPtr<DOMRectList> rectList = new DOMRectList(ToSupports(mOwner));
nsLayoutUtils::RectListBuilder builder(rectList);
const auto& startRef =
aAllowCrossShadowBoundaryRange == AllowRangeCrossShadowBoundary::Yes
? MayCrossShadowBoundaryStartRef()
: mStart;
const auto& endRef =
aAllowCrossShadowBoundaryRange == AllowRangeCrossShadowBoundary::Yes
? MayCrossShadowBoundaryEndRef()
: mEnd;
CollectClientRectsAndText(
&builder, nullptr, this, startRef.Container(),
*startRef.Offset(RangeBoundary::OffsetFilter::kValidOffsets),
endRef.Container(),
*endRef.Offset(RangeBoundary::OffsetFilter::kValidOffsets), aClampToEdge,
aFlushLayout);
return rectList.forget();
}
void nsRange::GetClientRectsAndTexts(mozilla::dom::ClientRectsAndTexts& aResult,
ErrorResult& aErr) {
if (!mIsPositioned) {
return;
}
aResult.mRectList = new DOMRectList(ToSupports(mOwner));
nsLayoutUtils::RectListBuilder builder(aResult.mRectList);
CollectClientRectsAndText(
&builder, &aResult.mTextList, this, mStart.Container(),
*mStart.Offset(RangeBoundary::OffsetFilter::kValidOffsets),
mEnd.Container(),
*mEnd.Offset(RangeBoundary::OffsetFilter::kValidOffsets), true, true);
}
nsresult nsRange::GetUsedFontFaces(nsLayoutUtils::UsedFontFaceList& aResult,
uint32_t aMaxRanges,
bool aSkipCollapsedWhitespace) {
NS_ENSURE_TRUE(mIsPositioned, NS_ERROR_UNEXPECTED);
nsCOMPtr<nsINode> startContainer = mStart.Container();
nsCOMPtr<nsINode> endContainer = mEnd.Container();
// Flush out layout so our frames are up to date.
Document* doc = mStart.Container()->OwnerDoc();
NS_ENSURE_TRUE(doc, NS_ERROR_UNEXPECTED);
doc->FlushPendingNotifications(FlushType::Frames);
// Recheck whether we're still in the document
NS_ENSURE_TRUE(mStart.Container()->IsInComposedDoc(), NS_ERROR_UNEXPECTED);
// A table to map gfxFontEntry objects to InspectorFontFace objects.
// This table does NOT own the InspectorFontFace objects, it only holds
// raw pointers to them. They are owned by the aResult array.
nsLayoutUtils::UsedFontFaceTable fontFaces;
RangeSubtreeIterator iter;
nsresult rv = iter.Init(this);
NS_ENSURE_SUCCESS(rv, rv);
while (!iter.IsDone()) {
// only collect anything if the range is not collapsed
nsCOMPtr<nsINode> node = iter.GetCurrentNode();
iter.Next();
nsCOMPtr<nsIContent> content = do_QueryInterface(node);
if (!content) {
continue;
}
nsIFrame* frame = content->GetPrimaryFrame();
if (!frame) {
continue;
}
if (content->IsText()) {
if (node == startContainer) {
int32_t offset =
startContainer == endContainer
? *mEnd.Offset(RangeBoundary::OffsetFilter::kValidOffsets)
: content->AsText()->TextDataLength();
nsLayoutUtils::GetFontFacesForText(
frame, *mStart.Offset(RangeBoundary::OffsetFilter::kValidOffsets),
offset, true, aResult, fontFaces, aMaxRanges,
aSkipCollapsedWhitespace);
continue;
}
if (node == endContainer) {
nsLayoutUtils::GetFontFacesForText(
frame, 0, *mEnd.Offset(RangeBoundary::OffsetFilter::kValidOffsets),
true, aResult, fontFaces, aMaxRanges, aSkipCollapsedWhitespace);
continue;
}
}
nsLayoutUtils::GetFontFacesForFrames(frame, aResult, fontFaces, aMaxRanges,
aSkipCollapsedWhitespace);
}
return NS_OK;
}
nsINode* nsRange::GetRegisteredClosestCommonInclusiveAncestor() {
MOZ_ASSERT(IsInAnySelection(),
"GetRegisteredClosestCommonInclusiveAncestor only valid for range "
"in selection");
MOZ_ASSERT(mRegisteredClosestCommonInclusiveAncestor);
return mRegisteredClosestCommonInclusiveAncestor;
}
/* static */
bool nsRange::AutoInvalidateSelection::sIsNested;
nsRange::AutoInvalidateSelection::~AutoInvalidateSelection() {
if (!mCommonAncestor) {
return;
}
sIsNested = false;
::InvalidateAllFrames(mCommonAncestor);
// Our range might not be in a selection anymore, because one of our selection
// listeners might have gone ahead and run script of various sorts that messed
// with selections, ranges, etc. But if it still is, we should check whether
// we have a different common ancestor now, and if so invalidate its subtree
// so it paints the selection it's in now.
if (mRange->IsInAnySelection()) {
nsINode* commonAncestor =
mRange->GetRegisteredClosestCommonInclusiveAncestor();
// XXXbz can commonAncestor really be null here? I wouldn't think so! If
// it _were_, then in a debug build
// GetRegisteredClosestCommonInclusiveAncestor() would have fatally
// asserted.
if (commonAncestor && commonAncestor != mCommonAncestor) {
::InvalidateAllFrames(commonAncestor);
}
}
}
/* static */
already_AddRefed<nsRange> nsRange::Constructor(const GlobalObject& aGlobal,
ErrorResult& aRv) {
nsCOMPtr<nsPIDOMWindowInner> window =
do_QueryInterface(aGlobal.GetAsSupports());
if (!window || !window->GetDoc()) {
aRv.Throw(NS_ERROR_FAILURE);
return nullptr;
}
return window->GetDoc()->CreateRange(aRv);
}
static bool ExcludeIfNextToNonSelectable(nsIContent* aContent) {
return aContent->IsText() &&
aContent->HasFlag(NS_CREATE_FRAME_IF_NON_WHITESPACE);
}
void nsRange::ExcludeNonSelectableNodes(nsTArray<RefPtr<nsRange>>* aOutRanges) {
if (!mIsPositioned) {
MOZ_ASSERT(false);
return;
}
MOZ_ASSERT(mEnd.Container());
MOZ_ASSERT(mStart.Container());
nsRange* range = this;
RefPtr<nsRange> newRange;
while (range) {
PreContentIterator preOrderIter;
nsresult rv = preOrderIter.Init(range);
if (NS_FAILED(rv)) {
return;
}
bool added = false;
bool seenSelectable = false;
// |firstNonSelectableContent| is the first node in a consecutive sequence
// of non-IsSelectable nodes. When we find a selectable node after such
// a sequence we'll end the last nsRange, create a new one and restart
// the outer loop.
nsIContent* firstNonSelectableContent = nullptr;
while (true) {
nsINode* node = preOrderIter.GetCurrentNode();
preOrderIter.Next();
bool selectable = true;
nsIContent* content =
node && node->IsContent() ? node->AsContent() : nullptr;
if (content) {
if (firstNonSelectableContent &&
ExcludeIfNextToNonSelectable(content)) {
// Ignorable whitespace next to a sequence of non-selectable nodes
selectable = false;
}
if (selectable) {
nsIFrame* frame = content->GetPrimaryFrame();
for (nsIContent* p = content; !frame && (p = p->GetParent());) {
frame = p->GetPrimaryFrame();
}
if (frame) {
selectable = frame->IsSelectable(nullptr);
}
}
}
if (!selectable) {
if (!firstNonSelectableContent) {
firstNonSelectableContent = content;
}
if (preOrderIter.IsDone()) {
if (seenSelectable) {
// The tail end of the initial range is non-selectable - truncate
// the current range before the first non-selectable node.
range->SetEndBefore(*firstNonSelectableContent, IgnoreErrors());
}
return;
}
continue;
}
if (firstNonSelectableContent) {
if (range == this && !seenSelectable) {
// This is the initial range and all its nodes until now are
// non-selectable so just trim them from the start.
IgnoredErrorResult err;
range->SetStartBefore(*node, err, AllowRangeCrossShadowBoundary::Yes);
if (err.Failed()) {
return;
}
break; // restart the same range with a new iterator
}
// Save the end point before truncating the range.
nsINode* endContainer = range->mEnd.Container();
const uint32_t endOffset =
*range->mEnd.Offset(RangeBoundary::OffsetFilter::kValidOffsets);
// Truncate the current range before the first non-selectable node.
IgnoredErrorResult err;
range->SetEndBefore(*firstNonSelectableContent, err,
AllowRangeCrossShadowBoundary::Yes);
// Store it in the result (strong ref) - do this before creating
// a new range in |newRange| below so we don't drop the last ref
// to the range created in the previous iteration.
if (!added && !err.Failed()) {
aOutRanges->AppendElement(range);
}
// Create a new range for the remainder.
nsINode* startContainer = node;
Maybe<uint32_t> startOffset = Some(0);
// Don't start *inside* a node with independent selection though
// (e.g. <input>).
if (content && content->HasIndependentSelection()) {
nsINode* parent = startContainer->GetParent();
if (parent) {
startOffset = parent->ComputeIndexOf(startContainer);
startContainer = parent;
}
}
newRange =
nsRange::Create(startContainer, startOffset.valueOr(UINT32_MAX),
endContainer, endOffset, IgnoreErrors());
if (!newRange || newRange->Collapsed()) {
newRange = nullptr;
}
range = newRange;
break; // create a new iterator for the new range, if any
}
seenSelectable = true;
if (!added) {
added = true;
aOutRanges->AppendElement(range);
}
if (preOrderIter.IsDone()) {
return;
}
}
}
}
struct InnerTextAccumulator {
explicit InnerTextAccumulator(mozilla::dom::DOMString& aValue)
: mString(aValue.AsAString()), mRequiredLineBreakCount(0) {}
void FlushLineBreaks() {
while (mRequiredLineBreakCount > 0) {
// Required line breaks at the start of the text are suppressed.
if (!mString.IsEmpty()) {
mString.Append('\n');
}
--mRequiredLineBreakCount;
}
}
void Append(char aCh) { Append(nsAutoString(aCh)); }
void Append(const nsAString& aString) {
if (aString.IsEmpty()) {
return;
}
FlushLineBreaks();
mString.Append(aString);
}
void AddRequiredLineBreakCount(int8_t aCount) {
mRequiredLineBreakCount = std::max(mRequiredLineBreakCount, aCount);
}
nsAString& mString;
int8_t mRequiredLineBreakCount;
};
static bool IsVisibleAndNotInReplacedElement(nsIFrame* aFrame) {
if (!aFrame || !aFrame->StyleVisibility()->IsVisible() ||
aFrame->HasAnyStateBits(NS_FRAME_IS_NONDISPLAY)) {
return false;
}
if (aFrame->HidesContent()) {
return false;
}
for (nsIFrame* f = aFrame->GetParent(); f; f = f->GetParent()) {
if (f->HidesContent()) {
return false;
}
if (f->IsReplaced() &&
!f->GetContent()->IsAnyOfHTMLElements(nsGkAtoms::button,
nsGkAtoms::select) &&
!f->GetContent()->IsSVGElement()) {
return false;
}
}
return true;
}
static void AppendTransformedText(InnerTextAccumulator& aResult,
nsIContent* aContainer) {
auto textNode = static_cast<CharacterData*>(aContainer);
nsIFrame* frame = textNode->GetPrimaryFrame();
if (!IsVisibleAndNotInReplacedElement(frame)) {
return;
}
nsIFrame::RenderedText text =
frame->GetRenderedText(0, aContainer->GetChildCount());
aResult.Append(text.mString);
}
/**
* States for tree traversal. AT_NODE means that we are about to enter
* the current DOM node. AFTER_NODE means that we have just finished traversing
* the children of the current DOM node and are about to apply any
* "after processing the node's children" steps before we finish visiting
* the node.
*/
enum TreeTraversalState { AT_NODE, AFTER_NODE };
static int8_t GetRequiredInnerTextLineBreakCount(nsIFrame* aFrame) {
if (aFrame->GetContent()->IsHTMLElement(nsGkAtoms::p)) {
return 2;
}
const nsStyleDisplay* styleDisplay = aFrame->StyleDisplay();
if (styleDisplay->IsBlockOutside(aFrame) ||
styleDisplay->mDisplay == StyleDisplay::TableCaption) {
return 1;
}
return 0;
}
static bool IsLastCellOfRow(nsIFrame* aFrame) {
LayoutFrameType type = aFrame->Type();
if (type != LayoutFrameType::TableCell) {
return true;
}
for (nsIFrame* c = aFrame; c; c = c->GetNextContinuation()) {
if (c->GetNextSibling()) {
return false;
}
}
return true;
}
static bool IsLastRowOfRowGroup(nsIFrame* aFrame) {
if (!aFrame->IsTableRowFrame()) {
return true;
}
for (nsIFrame* c = aFrame; c; c = c->GetNextContinuation()) {
if (c->GetNextSibling()) {
return false;
}
}
return true;
}
static bool IsLastNonemptyRowGroupOfTable(nsIFrame* aFrame) {
if (!aFrame->IsTableRowGroupFrame()) {
return true;
}
for (nsIFrame* c = aFrame; c; c = c->GetNextContinuation()) {
for (nsIFrame* next = c->GetNextSibling(); next;
next = next->GetNextSibling()) {
if (next->PrincipalChildList().FirstChild()) {
return false;
}
}
}
return true;
}
void nsRange::GetInnerTextNoFlush(DOMString& aValue, ErrorResult& aError,
nsIContent* aContainer) {
InnerTextAccumulator result(aValue);
if (aContainer->IsText()) {
AppendTransformedText(result, aContainer);
return;
}
nsIContent* currentNode = aContainer;
TreeTraversalState currentState = AFTER_NODE;
nsIContent* endNode = aContainer;
TreeTraversalState endState = AFTER_NODE;
nsIContent* firstChild = aContainer->GetFirstChild();
if (firstChild) {
currentNode = firstChild;
currentState = AT_NODE;
}
while (currentNode != endNode || currentState != endState) {
nsIFrame* f = currentNode->GetPrimaryFrame();
bool isVisibleAndNotReplaced = IsVisibleAndNotInReplacedElement(f);
if (currentState == AT_NODE) {
bool isText = currentNode->IsText();
if (isVisibleAndNotReplaced) {
result.AddRequiredLineBreakCount(GetRequiredInnerTextLineBreakCount(f));
if (isText) {
nsIFrame::RenderedText text = f->GetRenderedText();
result.Append(text.mString);
}
}
nsIContent* child = currentNode->GetFirstChild();
if (child) {
currentNode = child;
continue;
}
currentState = AFTER_NODE;
}
if (currentNode == endNode && currentState == endState) {
break;
}
if (isVisibleAndNotReplaced) {
if (currentNode->IsHTMLElement(nsGkAtoms::br)) {
result.Append('\n');
}
switch (f->StyleDisplay()->DisplayInside()) {
case StyleDisplayInside::TableCell:
if (!IsLastCellOfRow(f)) {
result.Append('\t');
}
break;
case StyleDisplayInside::TableRow:
if (!IsLastRowOfRowGroup(f) ||
!IsLastNonemptyRowGroupOfTable(f->GetParent())) {
result.Append('\n');
}
break;
default:
break; // Do nothing
}
result.AddRequiredLineBreakCount(GetRequiredInnerTextLineBreakCount(f));
}
nsIContent* next = currentNode->GetNextSibling();
if (next) {
currentNode = next;
currentState = AT_NODE;
} else {
currentNode = currentNode->GetParent();
}
}
// Do not flush trailing line breaks! Required breaks at the end of the text
// are suppressed.
}
template <typename SPT, typename SRT, typename EPT, typename ERT>
void nsRange::CreateOrUpdateCrossShadowBoundaryRangeIfNeeded(
const mozilla::RangeBoundaryBase<SPT, SRT>& aStartBoundary,
const mozilla::RangeBoundaryBase<EPT, ERT>& aEndBoundary) {
if (!StaticPrefs::dom_shadowdom_selection_across_boundary_enabled()) {
return;
}
MOZ_ASSERT(aStartBoundary.IsSetAndValid() && aEndBoundary.IsSetAndValid());
nsINode* startNode = aStartBoundary.Container();
nsINode* endNode = aEndBoundary.Container();
if (!startNode && !endNode) {
ResetCrossShadowBoundaryRange();
return;
}
// Nodes at least needs to be in the same document.
if (startNode && endNode &&
startNode->GetComposedDoc() != endNode->GetComposedDoc()) {
return;
}
auto CanBecomeCrossShadowBoundaryPoint = [](nsINode* aContainer) -> bool {
if (!aContainer) {
return true;
}
// Unlike normal ranges, shadow cross ranges don't work
// when the nodes aren't in document.
if (!aContainer->IsInComposedDoc()) {
return false;
}
// AbstractRange::GetClosestCommonInclusiveAncestor only supports
// Document and Content nodes.
return aContainer->IsDocument() || aContainer->IsContent();
};
if (!CanBecomeCrossShadowBoundaryPoint(startNode) ||
!CanBecomeCrossShadowBoundaryPoint(endNode)) {
ResetCrossShadowBoundaryRange();
return;
}
if (!mCrossShadowBoundaryRange) {
mCrossShadowBoundaryRange =
CrossShadowBoundaryRange::Create(aStartBoundary, aEndBoundary, this);
return;
}
mCrossShadowBoundaryRange->SetStartAndEnd(aStartBoundary, aEndBoundary);
}
RawRangeBoundary nsRange::ComputeNewBoundaryWhenBoundaryInsideChangedText(
const CharacterDataChangeInfo& aInfo, const RawRangeBoundary& aBoundary) {
MOZ_ASSERT(aInfo.mChangeStart <
*aBoundary.Offset(
RawRangeBoundary::OffsetFilter::kValidOrInvalidOffsets));
// If boundary is inside changed text, position it before change
// else adjust start offset for the change in length.
CheckedUint32 newOffset{0};
if (*aBoundary.Offset(
RawRangeBoundary::OffsetFilter::kValidOrInvalidOffsets) <=
aInfo.mChangeEnd) {
newOffset = aInfo.mChangeStart;
} else {
newOffset = *aBoundary.Offset(
RawRangeBoundary::OffsetFilter::kValidOrInvalidOffsets);
newOffset -= aInfo.LengthOfRemovedText();
newOffset += aInfo.mReplaceLength;
}
// newOffset.isValid() isn't checked explicitly here, because
// newOffset.value() contains an assertion.
return {aBoundary.Container(), newOffset.value()};
}