зеркало из https://github.com/mozilla/gecko-dev.git
612 строки
19 KiB
C++
612 строки
19 KiB
C++
/* -*- Mode: C++; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
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/* This Source Code Form is subject to the terms of the Mozilla Public
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* License, v. 2.0. If a copy of the MPL was not distributed with this
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* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
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#include "Pivot.h"
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#include "AccIterator.h"
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#include "LocalAccessible.h"
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#include "RemoteAccessible.h"
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#include "DocAccessible.h"
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#include "nsAccessibilityService.h"
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#include "nsAccUtils.h"
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#include "mozilla/dom/ChildIterator.h"
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#include "mozilla/dom/Element.h"
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using namespace mozilla;
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using namespace mozilla::a11y;
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////////////////////////////////////////////////////////////////////////////////
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// Pivot
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////////////////////////////////////////////////////////////////////////////////
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Pivot::Pivot(Accessible* aRoot) : mRoot(aRoot) { MOZ_COUNT_CTOR(Pivot); }
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Pivot::~Pivot() { MOZ_COUNT_DTOR(Pivot); }
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Accessible* Pivot::AdjustStartPosition(Accessible* aAnchor, PivotRule& aRule,
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uint16_t* aFilterResult) {
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Accessible* matched = aAnchor;
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*aFilterResult = aRule.Match(aAnchor);
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if (aAnchor && aAnchor != mRoot) {
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for (Accessible* temp = aAnchor->Parent(); temp && temp != mRoot;
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temp = temp->Parent()) {
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uint16_t filtered = aRule.Match(temp);
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if (filtered & nsIAccessibleTraversalRule::FILTER_IGNORE_SUBTREE) {
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*aFilterResult = filtered;
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matched = temp;
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}
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}
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}
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return matched;
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}
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Accessible* Pivot::SearchBackward(Accessible* aAnchor, PivotRule& aRule,
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bool aSearchCurrent) {
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// Initial position could be unset, in that case return null.
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if (!aAnchor) {
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return nullptr;
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}
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uint16_t filtered = nsIAccessibleTraversalRule::FILTER_IGNORE;
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Accessible* acc = AdjustStartPosition(aAnchor, aRule, &filtered);
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if (aSearchCurrent && (filtered & nsIAccessibleTraversalRule::FILTER_MATCH)) {
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return acc;
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}
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while (acc && acc != mRoot) {
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Accessible* parent = acc->Parent();
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int32_t idxInParent = acc->IndexInParent();
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while (idxInParent > 0 && parent) {
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acc = parent->ChildAt(--idxInParent);
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if (!acc) {
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continue;
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}
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filtered = aRule.Match(acc);
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Accessible* lastChild = acc->LastChild();
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while (!(filtered & nsIAccessibleTraversalRule::FILTER_IGNORE_SUBTREE) &&
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lastChild) {
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parent = acc;
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acc = lastChild;
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idxInParent = acc->IndexInParent();
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filtered = aRule.Match(acc);
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lastChild = acc->LastChild();
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}
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if (filtered & nsIAccessibleTraversalRule::FILTER_MATCH) {
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return acc;
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}
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}
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acc = parent;
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if (!acc) {
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break;
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}
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filtered = aRule.Match(acc);
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if (filtered & nsIAccessibleTraversalRule::FILTER_MATCH) {
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return acc;
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}
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}
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return nullptr;
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}
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Accessible* Pivot::SearchForward(Accessible* aAnchor, PivotRule& aRule,
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bool aSearchCurrent) {
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// Initial position could be not set, in that case begin search from root.
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Accessible* acc = aAnchor ? aAnchor : mRoot;
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uint16_t filtered = nsIAccessibleTraversalRule::FILTER_IGNORE;
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acc = AdjustStartPosition(acc, aRule, &filtered);
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if (aSearchCurrent && (filtered & nsIAccessibleTraversalRule::FILTER_MATCH)) {
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return acc;
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}
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while (acc) {
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Accessible* firstChild = acc->FirstChild();
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while (!(filtered & nsIAccessibleTraversalRule::FILTER_IGNORE_SUBTREE) &&
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firstChild) {
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acc = firstChild;
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filtered = aRule.Match(acc);
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if (filtered & nsIAccessibleTraversalRule::FILTER_MATCH) {
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return acc;
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}
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firstChild = acc->FirstChild();
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}
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Accessible* sibling = nullptr;
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Accessible* temp = acc;
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do {
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if (temp == mRoot) {
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break;
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}
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sibling = temp->NextSibling();
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if (sibling) {
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break;
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}
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temp = temp->Parent();
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} while (temp);
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if (!sibling) {
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break;
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}
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acc = sibling;
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filtered = aRule.Match(acc);
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if (filtered & nsIAccessibleTraversalRule::FILTER_MATCH) {
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return acc;
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}
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}
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return nullptr;
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}
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// TODO: This method does not work for proxy accessibles
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HyperTextAccessible* Pivot::SearchForText(LocalAccessible* aAnchor,
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bool aBackward) {
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if (!mRoot->IsLocal()) {
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return nullptr;
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}
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LocalAccessible* accessible = aAnchor;
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while (true) {
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LocalAccessible* child = nullptr;
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while ((child = (aBackward ? accessible->LocalLastChild()
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: accessible->LocalFirstChild()))) {
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accessible = child;
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if (child->IsHyperText()) {
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return child->AsHyperText();
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}
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}
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LocalAccessible* sibling = nullptr;
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LocalAccessible* temp = accessible;
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do {
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if (temp == mRoot->AsLocal()) {
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break;
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}
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// Unlike traditional pre-order traversal we revisit the parent
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// nodes when we go up the tree. This is because our starting point
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// may be a subtree or a leaf. If it's parent matches, it should
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// take precedent over a sibling.
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if (temp != aAnchor && temp->IsHyperText()) {
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return temp->AsHyperText();
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}
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if (sibling) {
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break;
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}
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sibling = aBackward ? temp->LocalPrevSibling() : temp->LocalNextSibling();
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} while ((temp = temp->LocalParent()));
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if (!sibling) {
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break;
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}
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accessible = sibling;
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if (accessible->IsHyperText()) {
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return accessible->AsHyperText();
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}
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}
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return nullptr;
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}
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Accessible* Pivot::Next(Accessible* aAnchor, PivotRule& aRule,
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bool aIncludeStart) {
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return SearchForward(aAnchor, aRule, aIncludeStart);
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}
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Accessible* Pivot::Prev(Accessible* aAnchor, PivotRule& aRule,
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bool aIncludeStart) {
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return SearchBackward(aAnchor, aRule, aIncludeStart);
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}
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Accessible* Pivot::First(PivotRule& aRule) {
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return SearchForward(mRoot, aRule, true);
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}
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Accessible* Pivot::Last(PivotRule& aRule) {
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Accessible* lastAcc = mRoot;
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// First go to the last accessible in pre-order
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while (lastAcc && lastAcc->HasChildren()) {
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lastAcc = lastAcc->LastChild();
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}
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// Search backwards from last accessible and find the last occurrence in the
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// doc
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return SearchBackward(lastAcc, aRule, true);
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}
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// TODO: This method does not work for proxy accessibles
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LocalAccessible* Pivot::NextText(LocalAccessible* aAnchor,
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int32_t* aStartOffset, int32_t* aEndOffset,
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int32_t aBoundaryType) {
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if (!mRoot->IsLocal()) {
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return nullptr;
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}
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int32_t tempStart = *aStartOffset, tempEnd = *aEndOffset;
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LocalAccessible* tempPosition = aAnchor;
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// if we're starting on a text leaf, translate the offsets to the
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// HyperTextAccessible parent and start from there.
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if (aAnchor->IsTextLeaf() && aAnchor->LocalParent() &&
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aAnchor->LocalParent()->IsHyperText()) {
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HyperTextAccessible* text = aAnchor->LocalParent()->AsHyperText();
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tempPosition = text;
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int32_t childOffset = text->GetChildOffset(aAnchor);
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if (tempEnd == -1) {
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tempStart = 0;
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tempEnd = 0;
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}
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tempStart += childOffset;
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tempEnd += childOffset;
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}
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while (true) {
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MOZ_ASSERT(tempPosition);
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LocalAccessible* curPosition = tempPosition;
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HyperTextAccessible* text = nullptr;
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// Find the nearest text node using a preorder traversal starting from
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// the current node.
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if (!(text = tempPosition->AsHyperText())) {
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text = SearchForText(tempPosition, false);
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if (!text) {
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return nullptr;
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}
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if (text != curPosition) {
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tempStart = tempEnd = -1;
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}
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tempPosition = text;
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}
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// If the search led to the parent of the node we started on (e.g. when
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// starting on a text leaf), start the text movement from the end of that
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// node, otherwise we just default to 0.
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if (tempEnd == -1) {
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tempEnd = text == curPosition->LocalParent()
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? text->GetChildOffset(curPosition)
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: 0;
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}
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// If there's no more text on the current node, try to find the next text
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// node; if there isn't one, bail out.
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if (tempEnd == static_cast<int32_t>(text->CharacterCount())) {
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if (tempPosition == mRoot->AsLocal()) {
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return nullptr;
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}
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// If we're currently sitting on a link, try move to either the next
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// sibling or the parent, whichever is closer to the current end
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// offset. Otherwise, do a forward search for the next node to land on
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// (we don't do this in the first case because we don't want to go to the
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// subtree).
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LocalAccessible* sibling = tempPosition->LocalNextSibling();
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if (tempPosition->IsLink()) {
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if (sibling && sibling->IsLink()) {
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tempStart = tempEnd = -1;
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tempPosition = sibling;
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} else {
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tempStart = tempPosition->StartOffset();
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tempEnd = tempPosition->EndOffset();
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tempPosition = tempPosition->LocalParent();
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}
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} else {
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tempPosition = SearchForText(tempPosition, false);
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if (!tempPosition) {
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return nullptr;
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}
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tempStart = tempEnd = -1;
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}
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continue;
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}
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AccessibleTextBoundary startBoundary, endBoundary;
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switch (aBoundaryType) {
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case nsIAccessiblePivot::CHAR_BOUNDARY:
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startBoundary = nsIAccessibleText::BOUNDARY_CHAR;
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endBoundary = nsIAccessibleText::BOUNDARY_CHAR;
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break;
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case nsIAccessiblePivot::WORD_BOUNDARY:
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startBoundary = nsIAccessibleText::BOUNDARY_WORD_START;
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endBoundary = nsIAccessibleText::BOUNDARY_WORD_END;
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break;
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case nsIAccessiblePivot::LINE_BOUNDARY:
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startBoundary = nsIAccessibleText::BOUNDARY_LINE_START;
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endBoundary = nsIAccessibleText::BOUNDARY_LINE_END;
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break;
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default:
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return nullptr;
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}
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nsAutoString unusedText;
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int32_t newStart = 0, newEnd = 0, currentEnd = tempEnd;
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text->TextAtOffset(tempEnd, endBoundary, &newStart, &tempEnd, unusedText);
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text->TextBeforeOffset(tempEnd, startBoundary, &newStart, &newEnd,
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unusedText);
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int32_t potentialStart = newEnd == tempEnd ? newStart : newEnd;
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tempStart = potentialStart > tempStart ? potentialStart : currentEnd;
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// The offset range we've obtained might have embedded characters in it,
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// limit the range to the start of the first occurrence of an embedded
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// character.
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LocalAccessible* childAtOffset = nullptr;
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for (int32_t i = tempStart; i < tempEnd; i++) {
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childAtOffset = text->GetChildAtOffset(i);
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if (childAtOffset && childAtOffset->IsHyperText()) {
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tempEnd = i;
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break;
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}
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}
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// If there's an embedded character at the very start of the range, we
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// instead want to traverse into it. So restart the movement with
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// the child as the starting point.
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if (childAtOffset && childAtOffset->IsHyperText() &&
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tempStart == static_cast<int32_t>(childAtOffset->StartOffset())) {
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tempPosition = childAtOffset;
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tempStart = tempEnd = -1;
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continue;
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}
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*aStartOffset = tempStart;
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*aEndOffset = tempEnd;
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MOZ_ASSERT(tempPosition);
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return tempPosition;
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}
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}
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// TODO: This method does not work for proxy accessibles
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LocalAccessible* Pivot::PrevText(LocalAccessible* aAnchor,
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int32_t* aStartOffset, int32_t* aEndOffset,
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int32_t aBoundaryType) {
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if (!mRoot->IsLocal()) {
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return nullptr;
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}
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int32_t tempStart = *aStartOffset, tempEnd = *aEndOffset;
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LocalAccessible* tempPosition = aAnchor;
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// if we're starting on a text leaf, translate the offsets to the
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// HyperTextAccessible parent and start from there.
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if (aAnchor->IsTextLeaf() && aAnchor->LocalParent() &&
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aAnchor->LocalParent()->IsHyperText()) {
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HyperTextAccessible* text = aAnchor->LocalParent()->AsHyperText();
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tempPosition = text;
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int32_t childOffset = text->GetChildOffset(aAnchor);
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if (tempStart == -1) {
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tempStart = nsAccUtils::TextLength(aAnchor);
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tempEnd = tempStart;
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}
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tempStart += childOffset;
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tempEnd += childOffset;
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}
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while (true) {
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MOZ_ASSERT(tempPosition);
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LocalAccessible* curPosition = tempPosition;
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HyperTextAccessible* text;
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// Find the nearest text node using a reverse preorder traversal starting
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// from the current node.
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if (!(text = tempPosition->AsHyperText())) {
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text = SearchForText(tempPosition, true);
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if (!text) {
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return nullptr;
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}
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if (text != curPosition) {
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tempStart = tempEnd = -1;
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}
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tempPosition = text;
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}
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// If the search led to the parent of the node we started on (e.g. when
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// starting on a text leaf), start the text movement from the end offset
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// of that node. Otherwise we just default to the last offset in the parent.
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if (tempStart == -1) {
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if (tempPosition != curPosition && text == curPosition->LocalParent()) {
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tempStart = text->GetChildOffset(curPosition) +
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nsAccUtils::TextLength(curPosition);
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} else {
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tempStart = text->CharacterCount();
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}
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}
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// If there's no more text on the current node, try to find the previous
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// text node; if there isn't one, bail out.
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if (tempStart == 0) {
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if (tempPosition == mRoot->AsLocal()) {
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return nullptr;
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}
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// If we're currently sitting on a link, try move to either the previous
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// sibling or the parent, whichever is closer to the current end
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// offset. Otherwise, do a forward search for the next node to land on
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// (we don't do this in the first case because we don't want to go to the
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// subtree).
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LocalAccessible* sibling = tempPosition->LocalPrevSibling();
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if (tempPosition->IsLink()) {
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if (sibling && sibling->IsLink()) {
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HyperTextAccessible* siblingText = sibling->AsHyperText();
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tempStart = tempEnd =
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siblingText ? siblingText->CharacterCount() : -1;
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tempPosition = sibling;
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} else {
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tempStart = tempPosition->StartOffset();
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tempEnd = tempPosition->EndOffset();
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tempPosition = tempPosition->LocalParent();
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}
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} else {
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HyperTextAccessible* tempText = SearchForText(tempPosition, true);
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if (!tempText) {
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return nullptr;
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}
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tempPosition = tempText;
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tempStart = tempEnd = tempText->CharacterCount();
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}
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continue;
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}
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AccessibleTextBoundary startBoundary, endBoundary;
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switch (aBoundaryType) {
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case nsIAccessiblePivot::CHAR_BOUNDARY:
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startBoundary = nsIAccessibleText::BOUNDARY_CHAR;
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endBoundary = nsIAccessibleText::BOUNDARY_CHAR;
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break;
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case nsIAccessiblePivot::WORD_BOUNDARY:
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startBoundary = nsIAccessibleText::BOUNDARY_WORD_START;
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endBoundary = nsIAccessibleText::BOUNDARY_WORD_END;
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break;
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case nsIAccessiblePivot::LINE_BOUNDARY:
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startBoundary = nsIAccessibleText::BOUNDARY_LINE_START;
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endBoundary = nsIAccessibleText::BOUNDARY_LINE_END;
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break;
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default:
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return nullptr;
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}
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nsAutoString unusedText;
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int32_t newStart = 0, newEnd = 0, currentStart = tempStart,
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potentialEnd = 0;
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text->TextBeforeOffset(tempStart, startBoundary, &newStart, &newEnd,
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unusedText);
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if (newStart < tempStart) {
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tempStart = newEnd >= currentStart ? newStart : newEnd;
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} else {
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// XXX: In certain odd cases newStart is equal to tempStart
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text->TextBeforeOffset(tempStart - 1, startBoundary, &newStart,
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&tempStart, unusedText);
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}
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text->TextAtOffset(tempStart, endBoundary, &newStart, &potentialEnd,
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unusedText);
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tempEnd = potentialEnd < tempEnd ? potentialEnd : currentStart;
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// The offset range we've obtained might have embedded characters in it,
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// limit the range to the start of the last occurrence of an embedded
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// character.
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LocalAccessible* childAtOffset = nullptr;
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for (int32_t i = tempEnd - 1; i >= tempStart; i--) {
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childAtOffset = text->GetChildAtOffset(i);
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if (childAtOffset && !childAtOffset->IsText()) {
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tempStart = childAtOffset->EndOffset();
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break;
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}
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}
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// If there's an embedded character at the very end of the range, we
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// instead want to traverse into it. So restart the movement with
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// the child as the starting point.
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if (childAtOffset && !childAtOffset->IsText() &&
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tempEnd == static_cast<int32_t>(childAtOffset->EndOffset())) {
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tempPosition = childAtOffset;
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tempStart = tempEnd = childAtOffset->AsHyperText()->CharacterCount();
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continue;
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}
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*aStartOffset = tempStart;
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*aEndOffset = tempEnd;
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MOZ_ASSERT(tempPosition);
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return tempPosition;
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}
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}
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Accessible* Pivot::AtPoint(int32_t aX, int32_t aY, PivotRule& aRule) {
|
|
Accessible* match = nullptr;
|
|
Accessible* child =
|
|
mRoot ? mRoot->ChildAtPoint(aX, aY,
|
|
Accessible::EWhichChildAtPoint::DeepestChild)
|
|
: nullptr;
|
|
while (child && (mRoot != child)) {
|
|
uint16_t filtered = aRule.Match(child);
|
|
|
|
// Ignore any matching nodes that were below this one
|
|
if (filtered & nsIAccessibleTraversalRule::FILTER_IGNORE_SUBTREE) {
|
|
match = nullptr;
|
|
}
|
|
|
|
// Match if no node below this is a match
|
|
if ((filtered & nsIAccessibleTraversalRule::FILTER_MATCH) && !match) {
|
|
nsIntRect childRect = child->IsLocal() ? child->AsLocal()->Bounds()
|
|
: child->AsRemote()->Bounds();
|
|
// Double-check child's bounds since the deepest child may have been out
|
|
// of bounds. This assures we don't return a false positive.
|
|
if (childRect.Contains(aX, aY)) {
|
|
match = child;
|
|
}
|
|
}
|
|
|
|
child = child->Parent();
|
|
}
|
|
|
|
return match;
|
|
}
|
|
|
|
// Role Rule
|
|
|
|
PivotRoleRule::PivotRoleRule(mozilla::a11y::role aRole)
|
|
: mRole(aRole), mDirectDescendantsFrom(nullptr) {}
|
|
|
|
PivotRoleRule::PivotRoleRule(mozilla::a11y::role aRole,
|
|
Accessible* aDirectDescendantsFrom)
|
|
: mRole(aRole), mDirectDescendantsFrom(aDirectDescendantsFrom) {}
|
|
|
|
uint16_t PivotRoleRule::Match(Accessible* aAcc) {
|
|
uint16_t result = nsIAccessibleTraversalRule::FILTER_IGNORE;
|
|
|
|
if (nsAccUtils::MustPrune(aAcc)) {
|
|
result |= nsIAccessibleTraversalRule::FILTER_IGNORE_SUBTREE;
|
|
}
|
|
|
|
if (mDirectDescendantsFrom && (aAcc != mDirectDescendantsFrom)) {
|
|
// If we've specified mDirectDescendantsFrom, we should ignore
|
|
// non-direct descendants of from the specified AoP. Because
|
|
// pivot performs a preorder traversal, the first aAcc
|
|
// object(s) that don't equal mDirectDescendantsFrom will be
|
|
// mDirectDescendantsFrom's children. We'll process them, but ignore
|
|
// their subtrees thereby processing direct descendants of
|
|
// mDirectDescendantsFrom only.
|
|
result |= nsIAccessibleTraversalRule::FILTER_IGNORE_SUBTREE;
|
|
}
|
|
|
|
if (aAcc && aAcc->Role() == mRole) {
|
|
result |= nsIAccessibleTraversalRule::FILTER_MATCH;
|
|
}
|
|
|
|
return result;
|
|
}
|
|
|
|
// LocalAccInSameDocRule
|
|
|
|
uint16_t LocalAccInSameDocRule::Match(Accessible* aAcc) {
|
|
LocalAccessible* acc = aAcc ? aAcc->AsLocal() : nullptr;
|
|
if (!acc) {
|
|
return nsIAccessibleTraversalRule::FILTER_IGNORE_SUBTREE;
|
|
}
|
|
if (acc->IsOuterDoc()) {
|
|
return nsIAccessibleTraversalRule::FILTER_MATCH |
|
|
nsIAccessibleTraversalRule::FILTER_IGNORE_SUBTREE;
|
|
}
|
|
return nsIAccessibleTraversalRule::FILTER_MATCH;
|
|
}
|