/* * Copyright (C) 2004, 2005, 2006 Apple Computer, Inc. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY APPLE COMPUTER, INC. ``AS IS'' AND ANY * EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL APPLE COMPUTER, INC. OR * CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, * EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR * PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY * OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #include "config.h" #include "VisibleSelection.h" #include "Document.h" #include "Element.h" #include "htmlediting.h" #include "TextIterator.h" #include "VisiblePosition.h" #include "visible_units.h" #include "Range.h" #include #include #include #include namespace WebCore { VisibleSelection::VisibleSelection() : m_affinity(DOWNSTREAM) , m_selectionType(NoSelection) , m_baseIsFirst(true) { } VisibleSelection::VisibleSelection(const Position& pos, EAffinity affinity) : m_base(pos) , m_extent(pos) , m_affinity(affinity) { validate(); } VisibleSelection::VisibleSelection(const Position& base, const Position& extent, EAffinity affinity) : m_base(base) , m_extent(extent) , m_affinity(affinity) { validate(); } VisibleSelection::VisibleSelection(const VisiblePosition& pos) : m_base(pos.deepEquivalent()) , m_extent(pos.deepEquivalent()) , m_affinity(pos.affinity()) { validate(); } VisibleSelection::VisibleSelection(const VisiblePosition& base, const VisiblePosition& extent) : m_base(base.deepEquivalent()) , m_extent(extent.deepEquivalent()) , m_affinity(base.affinity()) { validate(); } VisibleSelection::VisibleSelection(const Range* range, EAffinity affinity) : m_base(range->startPosition()) , m_extent(range->endPosition()) , m_affinity(affinity) { validate(); } VisibleSelection VisibleSelection::selectionFromContentsOfNode(Node* node) { ASSERT(!editingIgnoresContent(node)); return VisibleSelection(firstPositionInNode(node), lastPositionInNode(node), DOWNSTREAM); } void VisibleSelection::setBase(const Position& position) { m_base = position; validate(); } void VisibleSelection::setBase(const VisiblePosition& visiblePosition) { m_base = visiblePosition.deepEquivalent(); validate(); } void VisibleSelection::setExtent(const Position& position) { m_extent = position; validate(); } void VisibleSelection::setExtent(const VisiblePosition& visiblePosition) { m_extent = visiblePosition.deepEquivalent(); validate(); } PassRefPtr VisibleSelection::firstRange() const { if (isNone()) return 0; Position start = m_start.parentAnchoredEquivalent(); Position end = m_end.parentAnchoredEquivalent(); return Range::create(start.anchorNode()->document(), start, end); } PassRefPtr VisibleSelection::toNormalizedRange() const { if (isNone()) return 0; // Make sure we have an updated layout since this function is called // in the course of running edit commands which modify the DOM. // Failing to call this can result in equivalentXXXPosition calls returning // incorrect results. m_start.anchorNode()->document()->updateLayout(); // Check again, because updating layout can clear the selection. if (isNone()) return 0; Position s, e; if (isCaret()) { // If the selection is a caret, move the range start upstream. This helps us match // the conventions of text editors tested, which make style determinations based // on the character before the caret, if any. s = m_start.upstream().parentAnchoredEquivalent(); e = s; } else { // If the selection is a range, select the minimum range that encompasses the selection. // Again, this is to match the conventions of text editors tested, which make style // determinations based on the first character of the selection. // For instance, this operation helps to make sure that the "X" selected below is the // only thing selected. The range should not be allowed to "leak" out to the end of the // previous text node, or to the beginning of the next text node, each of which has a // different style. // // On a treasure map, X marks the spot. // ^ selected // ASSERT(isRange()); s = m_start.downstream(); e = m_end.upstream(); if (comparePositions(s, e) > 0) { // Make sure the start is before the end. // The end can wind up before the start if collapsed whitespace is the only thing selected. Position tmp = s; s = e; e = tmp; } s = s.parentAnchoredEquivalent(); e = e.parentAnchoredEquivalent(); } if (!s.containerNode() || !e.containerNode()) return 0; // VisibleSelections are supposed to always be valid. This constructor will ASSERT // if a valid range could not be created, which is fine for this callsite. return Range::create(s.anchorNode()->document(), s, e); } bool VisibleSelection::expandUsingGranularity(TextGranularity granularity) { if (isNone()) return false; validate(granularity); return true; } static PassRefPtr makeSearchRange(const Position& pos) { Node* n = pos.deprecatedNode(); if (!n) return 0; Document* d = n->document(); Node* de = d->documentElement(); if (!de) return 0; Node* boundary = n->enclosingBlockFlowElement(); if (!boundary) return 0; RefPtr searchRange(Range::create(d)); ExceptionCode ec = 0; Position start(pos.parentAnchoredEquivalent()); searchRange->selectNodeContents(boundary, ec); searchRange->setStart(start.containerNode(), start.offsetInContainerNode(), ec); ASSERT(!ec); if (ec) return 0; return searchRange.release(); } bool VisibleSelection::isAll(EditingBoundaryCrossingRule rule) const { return !shadowTreeRootNode() && visibleStart().previous(rule).isNull() && visibleEnd().next(rule).isNull(); } void VisibleSelection::appendTrailingWhitespace() { RefPtr searchRange = makeSearchRange(m_end); if (!searchRange) return; CharacterIterator charIt(searchRange.get(), TextIteratorEmitsCharactersBetweenAllVisiblePositions); for (; charIt.length(); charIt.advance(1)) { UChar c = charIt.characters()[0]; if ((!isSpaceOrNewline(c) && c != noBreakSpace) || c == '\n') break; m_end = charIt.range()->endPosition(); } } void VisibleSelection::setBaseAndExtentToDeepEquivalents() { // Move the selection to rendered positions, if possible. bool baseAndExtentEqual = m_base == m_extent; if (m_base.isNotNull()) { m_base = VisiblePosition(m_base, m_affinity).deepEquivalent(); if (baseAndExtentEqual) m_extent = m_base; } if (m_extent.isNotNull() && !baseAndExtentEqual) m_extent = VisiblePosition(m_extent, m_affinity).deepEquivalent(); // Make sure we do not have a dangling base or extent. if (m_base.isNull() && m_extent.isNull()) m_baseIsFirst = true; else if (m_base.isNull()) { m_base = m_extent; m_baseIsFirst = true; } else if (m_extent.isNull()) { m_extent = m_base; m_baseIsFirst = true; } else m_baseIsFirst = comparePositions(m_base, m_extent) <= 0; } void VisibleSelection::setStartAndEndFromBaseAndExtentRespectingGranularity(TextGranularity granularity) { if (m_baseIsFirst) { m_start = m_base; m_end = m_extent; } else { m_start = m_extent; m_end = m_base; } switch (granularity) { case CharacterGranularity: // Don't do any expansion. break; case WordGranularity: { // General case: Select the word the caret is positioned inside of, or at the start of (RightWordIfOnBoundary). // Edge case: If the caret is after the last word in a soft-wrapped line or the last word in // the document, select that last word (LeftWordIfOnBoundary). // Edge case: If the caret is after the last word in a paragraph, select from the the end of the // last word to the line break (also RightWordIfOnBoundary); VisiblePosition start = VisiblePosition(m_start, m_affinity); VisiblePosition originalEnd(m_end, m_affinity); EWordSide side = RightWordIfOnBoundary; if (isEndOfDocument(start) || (isEndOfLine(start) && !isStartOfLine(start) && !isEndOfParagraph(start))) side = LeftWordIfOnBoundary; m_start = startOfWord(start, side).deepEquivalent(); side = RightWordIfOnBoundary; if (isEndOfDocument(originalEnd) || (isEndOfLine(originalEnd) && !isStartOfLine(originalEnd) && !isEndOfParagraph(originalEnd))) side = LeftWordIfOnBoundary; VisiblePosition wordEnd(endOfWord(originalEnd, side)); VisiblePosition end(wordEnd); if (isEndOfParagraph(originalEnd) && !isEmptyTableCell(m_start.deprecatedNode())) { // Select the paragraph break (the space from the end of a paragraph to the start of // the next one) to match TextEdit. end = wordEnd.next(); if (Node* table = isFirstPositionAfterTable(end)) { // The paragraph break after the last paragraph in the last cell of a block table ends // at the start of the paragraph after the table. if (isBlock(table)) end = end.next(CannotCrossEditingBoundary); else end = wordEnd; } if (end.isNull()) end = wordEnd; } m_end = end.deepEquivalent(); break; } case SentenceGranularity: { m_start = startOfSentence(VisiblePosition(m_start, m_affinity)).deepEquivalent(); m_end = endOfSentence(VisiblePosition(m_end, m_affinity)).deepEquivalent(); break; } case LineGranularity: { m_start = startOfLine(VisiblePosition(m_start, m_affinity)).deepEquivalent(); VisiblePosition end = endOfLine(VisiblePosition(m_end, m_affinity)); // If the end of this line is at the end of a paragraph, include the space // after the end of the line in the selection. if (isEndOfParagraph(end)) { VisiblePosition next = end.next(); if (next.isNotNull()) end = next; } m_end = end.deepEquivalent(); break; } case LineBoundary: m_start = startOfLine(VisiblePosition(m_start, m_affinity)).deepEquivalent(); m_end = endOfLine(VisiblePosition(m_end, m_affinity)).deepEquivalent(); break; case ParagraphGranularity: { VisiblePosition pos(m_start, m_affinity); if (isStartOfLine(pos) && isEndOfDocument(pos)) pos = pos.previous(); m_start = startOfParagraph(pos).deepEquivalent(); VisiblePosition visibleParagraphEnd = endOfParagraph(VisiblePosition(m_end, m_affinity)); // Include the "paragraph break" (the space from the end of this paragraph to the start // of the next one) in the selection. VisiblePosition end(visibleParagraphEnd.next()); if (Node* table = isFirstPositionAfterTable(end)) { // The paragraph break after the last paragraph in the last cell of a block table ends // at the start of the paragraph after the table, not at the position just after the table. if (isBlock(table)) end = end.next(CannotCrossEditingBoundary); // There is no parargraph break after the last paragraph in the last cell of an inline table. else end = visibleParagraphEnd; } if (end.isNull()) end = visibleParagraphEnd; m_end = end.deepEquivalent(); break; } case DocumentBoundary: m_start = startOfDocument(VisiblePosition(m_start, m_affinity)).deepEquivalent(); m_end = endOfDocument(VisiblePosition(m_end, m_affinity)).deepEquivalent(); break; case ParagraphBoundary: m_start = startOfParagraph(VisiblePosition(m_start, m_affinity)).deepEquivalent(); m_end = endOfParagraph(VisiblePosition(m_end, m_affinity)).deepEquivalent(); break; case SentenceBoundary: m_start = startOfSentence(VisiblePosition(m_start, m_affinity)).deepEquivalent(); m_end = endOfSentence(VisiblePosition(m_end, m_affinity)).deepEquivalent(); break; case WebKitVisualWordGranularity: break; } // Make sure we do not have a dangling start or end. if (m_start.isNull()) m_start = m_end; if (m_end.isNull()) m_end = m_start; } void VisibleSelection::updateSelectionType() { if (m_start.isNull()) { ASSERT(m_end.isNull()); m_selectionType = NoSelection; } else if (m_start == m_end || m_start.upstream() == m_end.upstream()) { m_selectionType = CaretSelection; } else m_selectionType = RangeSelection; // Affinity only makes sense for a caret if (m_selectionType != CaretSelection) m_affinity = DOWNSTREAM; } void VisibleSelection::validate(TextGranularity granularity) { setBaseAndExtentToDeepEquivalents(); setStartAndEndFromBaseAndExtentRespectingGranularity(granularity); adjustSelectionToAvoidCrossingEditingBoundaries(); updateSelectionType(); if (selectionType() == RangeSelection) { // "Constrain" the selection to be the smallest equivalent range of nodes. // This is a somewhat arbitrary choice, but experience shows that it is // useful to make to make the selection "canonical" (if only for // purposes of comparing selections). This is an ideal point of the code // to do this operation, since all selection changes that result in a RANGE // come through here before anyone uses it. // FIXME: Canonicalizing is good, but haven't we already done it (when we // set these two positions to VisiblePosition deepEquivalent()s above)? m_start = m_start.downstream(); m_end = m_end.upstream(); } } // FIXME: This function breaks the invariant of this class. // But because we use VisibleSelection to store values in editing commands for use when // undoing the command, we need to be able to create a selection that while currently // invalid, will be valid once the changes are undone. This is a design problem. // To fix it we either need to change the invariants of VisibleSelection or create a new // class for editing to use that can manipulate selections that are not currently valid. void VisibleSelection::setWithoutValidation(const Position& base, const Position& extent) { ASSERT(!base.isNull()); ASSERT(!extent.isNull()); ASSERT(m_affinity == DOWNSTREAM); m_base = base; m_extent = extent; m_baseIsFirst = comparePositions(base, extent) <= 0; if (m_baseIsFirst) { m_start = base; m_end = extent; } else { m_start = extent; m_end = base; } m_selectionType = base == extent ? CaretSelection : RangeSelection; } void VisibleSelection::adjustSelectionToAvoidCrossingEditingBoundaries() { if (m_base.isNull() || m_start.isNull() || m_end.isNull()) return; Node* baseRoot = highestEditableRoot(m_base); Node* startRoot = highestEditableRoot(m_start); Node* endRoot = highestEditableRoot(m_end); Node* baseEditableAncestor = lowestEditableAncestor(m_base.containerNode()); // The base, start and end are all in the same region. No adjustment necessary. if (baseRoot == startRoot && baseRoot == endRoot) return; // The selection is based in editable content. if (baseRoot) { // If the start is outside the base's editable root, cap it at the start of that root. // If the start is in non-editable content that is inside the base's editable root, put it // at the first editable position after start inside the base's editable root. if (startRoot != baseRoot) { VisiblePosition first = firstEditablePositionAfterPositionInRoot(m_start, baseRoot); m_start = first.deepEquivalent(); if (m_start.isNull()) { ASSERT_NOT_REACHED(); m_start = m_end; } } // If the end is outside the base's editable root, cap it at the end of that root. // If the end is in non-editable content that is inside the base's root, put it // at the last editable position before the end inside the base's root. if (endRoot != baseRoot) { VisiblePosition last = lastEditablePositionBeforePositionInRoot(m_end, baseRoot); m_end = last.deepEquivalent(); if (m_end.isNull()) m_end = m_start; } // The selection is based in non-editable content. } else { // FIXME: Non-editable pieces inside editable content should be atomic, in the same way that editable // pieces in non-editable content are atomic. // The selection ends in editable content or non-editable content inside a different editable ancestor, // move backward until non-editable content inside the same lowest editable ancestor is reached. Node* endEditableAncestor = lowestEditableAncestor(m_end.containerNode()); if (endRoot || endEditableAncestor != baseEditableAncestor) { Position p = previousVisuallyDistinctCandidate(m_end); Node* shadowAncestor = endRoot ? endRoot->shadowAncestorNode() : 0; if (p.isNull() && endRoot && (shadowAncestor != endRoot)) p = positionAfterNode(shadowAncestor); while (p.isNotNull() && !(lowestEditableAncestor(p.containerNode()) == baseEditableAncestor && !isEditablePosition(p))) { Node* root = editableRootForPosition(p); shadowAncestor = root ? root->shadowAncestorNode() : 0; p = isAtomicNode(p.containerNode()) ? positionInParentBeforeNode(p.containerNode()) : previousVisuallyDistinctCandidate(p); if (p.isNull() && (shadowAncestor != root)) p = positionAfterNode(shadowAncestor); } VisiblePosition previous(p); if (previous.isNull()) { // The selection crosses an Editing boundary. This is a // programmer error in the editing code. Happy debugging! ASSERT_NOT_REACHED(); m_base = Position(); m_extent = Position(); validate(); return; } m_end = previous.deepEquivalent(); } // The selection starts in editable content or non-editable content inside a different editable ancestor, // move forward until non-editable content inside the same lowest editable ancestor is reached. Node* startEditableAncestor = lowestEditableAncestor(m_start.containerNode()); if (startRoot || startEditableAncestor != baseEditableAncestor) { Position p = nextVisuallyDistinctCandidate(m_start); Node* shadowAncestor = startRoot ? startRoot->shadowAncestorNode() : 0; if (p.isNull() && startRoot && (shadowAncestor != startRoot)) p = positionBeforeNode(shadowAncestor); while (p.isNotNull() && !(lowestEditableAncestor(p.containerNode()) == baseEditableAncestor && !isEditablePosition(p))) { Node* root = editableRootForPosition(p); shadowAncestor = root ? root->shadowAncestorNode() : 0; p = isAtomicNode(p.containerNode()) ? positionInParentAfterNode(p.containerNode()) : nextVisuallyDistinctCandidate(p); if (p.isNull() && (shadowAncestor != root)) p = positionBeforeNode(shadowAncestor); } VisiblePosition next(p); if (next.isNull()) { // The selection crosses an Editing boundary. This is a // programmer error in the editing code. Happy debugging! ASSERT_NOT_REACHED(); m_base = Position(); m_extent = Position(); validate(); return; } m_start = next.deepEquivalent(); } } // Correct the extent if necessary. if (baseEditableAncestor != lowestEditableAncestor(m_extent.containerNode())) m_extent = m_baseIsFirst ? m_end : m_start; } bool VisibleSelection::isContentEditable() const { return isEditablePosition(start()); } bool VisibleSelection::isContentRichlyEditable() const { return isRichlyEditablePosition(start()); } Element* VisibleSelection::rootEditableElement() const { return editableRootForPosition(start()); } Node* VisibleSelection::shadowTreeRootNode() const { return start().deprecatedNode() ? start().deprecatedNode()->shadowTreeRootNode() : 0; } #ifndef NDEBUG void VisibleSelection::debugPosition() const { fprintf(stderr, "VisibleSelection ===============\n"); if (!m_start.anchorNode()) fputs("pos: null", stderr); else if (m_start == m_end) { fprintf(stderr, "pos: %s ", m_start.anchorNode()->nodeName().utf8().data()); m_start.showAnchorTypeAndOffset(); } else { fprintf(stderr, "start: %s ", m_start.anchorNode()->nodeName().utf8().data()); m_start.showAnchorTypeAndOffset(); fprintf(stderr, "end: %s ", m_end.anchorNode()->nodeName().utf8().data()); m_end.showAnchorTypeAndOffset(); } fprintf(stderr, "================================\n"); } void VisibleSelection::formatForDebugger(char* buffer, unsigned length) const { String result; String s; if (isNone()) { result = ""; } else { const int FormatBufferSize = 1024; char s[FormatBufferSize]; result += "from "; start().formatForDebugger(s, FormatBufferSize); result += s; result += " to "; end().formatForDebugger(s, FormatBufferSize); result += s; } strncpy(buffer, result.utf8().data(), length - 1); } void VisibleSelection::showTreeForThis() const { if (start().anchorNode()) { start().anchorNode()->showTreeAndMark(start().anchorNode(), "S", end().anchorNode(), "E"); fputs("start: ", stderr); start().showAnchorTypeAndOffset(); fputs("end: ", stderr); end().showAnchorTypeAndOffset(); } } #endif } // namespace WebCore #ifndef NDEBUG void showTree(const WebCore::VisibleSelection& sel) { sel.showTreeForThis(); } void showTree(const WebCore::VisibleSelection* sel) { if (sel) sel->showTreeForThis(); } #endif