/*
* Copyright (C) 2004, 2005, 2006, 2009 Apple 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 "Position.h"
#include "CSSComputedStyleDeclaration.h"
#include "CString.h"
#include "CharacterNames.h"
#include "Logging.h"
#include "PositionIterator.h"
#include "RenderBlock.h"
#include "Text.h"
#include "TextIterator.h"
#include "VisiblePosition.h"
#include "htmlediting.h"
#include "visible_units.h"
#include <stdio.h>
namespace WebCore {
using namespace HTMLNames;
static Node* nextRenderedEditable(Node* node)
{
while (1) {
node = node->nextEditable();
if (!node)
return 0;
RenderObject* renderer = node->renderer();
if (!renderer)
continue;
if ((renderer->isBox() && toRenderBox(renderer)->inlineBoxWrapper()) || (renderer->isText() && toRenderText(renderer)->firstTextBox()))
return node;
}
return 0;
}
static Node* previousRenderedEditable(Node* node)
{
while (1) {
node = node->previousEditable();
if (!node)
return 0;
RenderObject* renderer = node->renderer();
if (!renderer)
continue;
if ((renderer->isBox() && toRenderBox(renderer)->inlineBoxWrapper()) || (renderer->isText() && toRenderText(renderer)->firstTextBox()))
return node;
}
return 0;
}
Position::Position(PassRefPtr<Node> anchorNode, int offset)
: m_anchorNode(anchorNode)
, m_offset(offset)
, m_anchorType(anchorTypeForLegacyEditingPosition(m_anchorNode.get(), m_offset))
, m_isLegacyEditingPosition(true)
{
}
Position::Position(PassRefPtr<Node> anchorNode, AnchorType anchorType)
: m_anchorNode(anchorNode)
, m_offset(0)
, m_anchorType(anchorType)
, m_isLegacyEditingPosition(false)
{
ASSERT(anchorType != PositionIsOffsetInAnchor);
}
Position::Position(PassRefPtr<Node> anchorNode, int offset, AnchorType anchorType)
: m_anchorNode(anchorNode)
, m_offset(offset)
, m_anchorType(anchorType)
, m_isLegacyEditingPosition(false)
{
ASSERT(anchorType == PositionIsOffsetInAnchor);
}
void Position::moveToPosition(PassRefPtr<Node> node, int offset)
{
ASSERT(anchorType() == PositionIsOffsetInAnchor || m_isLegacyEditingPosition);
m_anchorNode = node;
m_offset = offset;
if (m_isLegacyEditingPosition)
m_anchorType = anchorTypeForLegacyEditingPosition(m_anchorNode.get(), m_offset);
}
void Position::moveToOffset(int offset)
{
ASSERT(anchorType() == PositionIsOffsetInAnchor || m_isLegacyEditingPosition);
m_offset = offset;
if (m_isLegacyEditingPosition)
m_anchorType = anchorTypeForLegacyEditingPosition(m_anchorNode.get(), m_offset);
}
Node* Position::containerNode() const
{
if (!m_anchorNode)
return 0;
switch (anchorType()) {
case PositionIsOffsetInAnchor:
return m_anchorNode.get();
case PositionIsBeforeAnchor:
case PositionIsAfterAnchor:
return m_anchorNode->parentNode();
}
ASSERT_NOT_REACHED();
return 0;
}
int Position::computeOffsetInContainerNode() const
{
if (!m_anchorNode)
return 0;
switch (anchorType()) {
case PositionIsOffsetInAnchor:
return std::min(lastOffsetInNode(m_anchorNode.get()), m_offset);
case PositionIsBeforeAnchor:
return m_anchorNode->nodeIndex();
case PositionIsAfterAnchor:
return m_anchorNode->nodeIndex() + 1;
}
ASSERT_NOT_REACHED();
return 0;
}
Node* Position::computeNodeBeforePosition() const
{
if (!m_anchorNode)
return 0;
switch (anchorType()) {
case PositionIsOffsetInAnchor:
return m_anchorNode->childNode(m_offset - 1); // -1 converts to childNode((unsigned)-1) and returns null.
case PositionIsBeforeAnchor:
return m_anchorNode->previousSibling();
case PositionIsAfterAnchor:
return m_anchorNode.get();
}
ASSERT_NOT_REACHED();
return 0;
}
Node* Position::computeNodeAfterPosition() const
{
if (!m_anchorNode)
return 0;
switch (anchorType()) {
case PositionIsOffsetInAnchor:
return m_anchorNode->childNode(m_offset);
case PositionIsBeforeAnchor:
return m_anchorNode.get();
case PositionIsAfterAnchor:
return m_anchorNode->nextSibling();
}
ASSERT_NOT_REACHED();
return 0;
}
Position::AnchorType Position::anchorTypeForLegacyEditingPosition(Node* anchorNode, int offset)
{
if (anchorNode && editingIgnoresContent(anchorNode)) {
if (offset == 0)
return Position::PositionIsBeforeAnchor;
return Position::PositionIsAfterAnchor;
}
return Position::PositionIsOffsetInAnchor;
}
// FIXME: This method is confusing (does it return anchorNode() or containerNode()?) and should be renamed or removed
Element* Position::element() const
{
Node* n = anchorNode();
while (n && !n->isElementNode())
n = n->parentNode();
return static_cast<Element*>(n);
}
PassRefPtr<CSSComputedStyleDeclaration> Position::computedStyle() const
{
Element* elem = element();
if (!elem)
return 0;
return WebCore::computedStyle(elem);
}
Position Position::previous(PositionMoveType moveType) const
{
Node* n = node();
if (!n)
return *this;
int o = m_offset;
// FIXME: Negative offsets shouldn't be allowed. We should catch this earlier.
ASSERT(o >= 0);
if (o > 0) {
Node* child = n->childNode(o - 1);
if (child)
return lastDeepEditingPositionForNode(child);
// There are two reasons child might be 0:
// 1) The node is node like a text node that is not an element, and therefore has no children.
// Going backward one character at a time is correct.
// 2) The old offset was a bogus offset like (<br>, 1), and there is no child.
// Going from 1 to 0 is correct.
switch (moveType) {
case CodePoint:
return Position(n, o - 1);
case Character:
return Position(n, uncheckedPreviousOffset(n, o));
case BackwardDeletion:
return Position(n, uncheckedPreviousOffsetForBackwardDeletion(n, o));
}
}
Node* parent = n->parentNode();
if (!parent)
return *this;
return Position(parent, n->nodeIndex());
}
Position Position::next(PositionMoveType moveType) const
{
ASSERT(moveType != BackwardDeletion);
Node* n = node();
if (!n)
return *this;
int o = m_offset;
// FIXME: Negative offsets shouldn't be allowed. We should catch this earlier.
ASSERT(o >= 0);
Node* child = n->childNode(o);
if (child || (!n->hasChildNodes() && o < lastOffsetForEditing(n))) {
if (child)
return firstDeepEditingPositionForNode(child);
// There are two reasons child might be 0:
// 1) The node is node like a text node that is not an element, and therefore has no children.
// Going forward one character at a time is correct.
// 2) The new offset is a bogus offset like (<br>, 1), and there is no child.
// Going from 0 to 1 is correct.
return Position(n, (moveType == Character) ? uncheckedNextOffset(n, o) : o + 1);
}
Node* parent = n->parentNode();
if (!parent)
return *this;
return Position(parent, n->nodeIndex() + 1);
}
int Position::uncheckedPreviousOffset(const Node* n, int current)
{
return n->renderer() ? n->renderer()->previousOffset(current) : current - 1;
}
int Position::uncheckedPreviousOffsetForBackwardDeletion(const Node* n, int current)
{
return n->renderer() ? n->renderer()->previousOffsetForBackwardDeletion(current) : current - 1;
}
int Position::uncheckedNextOffset(const Node* n, int current)
{
return n->renderer() ? n->renderer()->nextOffset(current) : current + 1;
}
bool Position::atFirstEditingPositionForNode() const
{
if (isNull())
return true;
return m_offset <= 0;
}
bool Position::atLastEditingPositionForNode() const
{
if (isNull())
return true;
return m_offset >= lastOffsetForEditing(node());
}
// A position is considered at editing boundary if one of the following is true:
// 1. It is the first position in the node and the next visually equivalent position
// is non editable.
// 2. It is the last position in the node and the previous visually equivalent position
// is non editable.
// 3. It is an editable position and both the next and previous visually equivalent
// positions are both non editable.
bool Position::atEditingBoundary() const
{
Position nextPosition = downstream(CanCrossEditingBoundary);
if (atFirstEditingPositionForNode() && nextPosition.isNotNull() && !nextPosition.node()->isContentEditable())
return true;
Position prevPosition = upstream(CanCrossEditingBoundary);
if (atLastEditingPositionForNode() && prevPosition.isNotNull() && !prevPosition.node()->isContentEditable())
return true;
return nextPosition.isNotNull() && !nextPosition.node()->isContentEditable()
&& prevPosition.isNotNull() && !prevPosition.node()->isContentEditable();
}
bool Position::atStartOfTree() const
{
if (isNull())
return true;
return !node()->parentNode() && m_offset <= 0;
}
bool Position::atEndOfTree() const
{
if (isNull())
return true;
return !node()->parentNode() && m_offset >= lastOffsetForEditing(node());
}
int Position::renderedOffset() const
{
if (!node()->isTextNode())
return m_offset;
if (!node()->renderer())
return m_offset;
int result = 0;
RenderText *textRenderer = toRenderText(node()->renderer());
for (InlineTextBox *box = textRenderer->firstTextBox(); box; box = box->nextTextBox()) {
int start = box->start();
int end = box->start() + box->len();
if (m_offset < start)
return result;
if (m_offset <= end) {
result += m_offset - start;
return result;
}
result += box->len();
}
return result;
}
// return first preceding DOM position rendered at a different location, or "this"
Position Position::previousCharacterPosition(EAffinity affinity) const
{
if (isNull())
return Position();
Node *fromRootEditableElement = node()->rootEditableElement();
bool atStartOfLine = isStartOfLine(VisiblePosition(*this, affinity));
bool rendered = isCandidate();
Position currentPos = *this;
while (!currentPos.atStartOfTree()) {
currentPos = currentPos.previous();
if (currentPos.node()->rootEditableElement() != fromRootEditableElement)
return *this;
if (atStartOfLine || !rendered) {
if (currentPos.isCandidate())
return currentPos;
} else if (rendersInDifferentPosition(currentPos))
return currentPos;
}
return *this;
}
// return first following position rendered at a different location, or "this"
Position Position::nextCharacterPosition(EAffinity affinity) const
{
if (isNull())
return Position();
Node *fromRootEditableElement = node()->rootEditableElement();
bool atEndOfLine = isEndOfLine(VisiblePosition(*this, affinity));
bool rendered = isCandidate();
Position currentPos = *this;
while (!currentPos.atEndOfTree()) {
currentPos = currentPos.next();
if (currentPos.node()->rootEditableElement() != fromRootEditableElement)
return *this;
if (atEndOfLine || !rendered) {
if (currentPos.isCandidate())
return currentPos;
} else if (rendersInDifferentPosition(currentPos))
return currentPos;
}
return *this;
}
// Whether or not [node, 0] and [node, lastOffsetForEditing(node)] are their own VisiblePositions.
// If true, adjacent candidates are visually distinct.
// FIXME: Disregard nodes with renderers that have no height, as we do in isCandidate.
// FIXME: Share code with isCandidate, if possible.
static bool endsOfNodeAreVisuallyDistinctPositions(Node* node)
{
if (!node || !node->renderer())
return false;
if (!node->renderer()->isInline())
return true;
// Don't include inline tables.
if (node->hasTagName(tableTag))
return false;
// There is a VisiblePosition inside an empty inline-block container.
return node->renderer()->isReplaced() && canHaveChildrenForEditing(node) && toRenderBox(node->renderer())->height() != 0 && !node->firstChild();
}
static Node* enclosingVisualBoundary(Node* node)
{
while (node && !endsOfNodeAreVisuallyDistinctPositions(node))
node = node->parentNode();
return node;
}
// upstream() and downstream() want to return positions that are either in a
// text node or at just before a non-text node. This method checks for that.
static bool isStreamer(const PositionIterator& pos)
{
if (!pos.node())
return true;
if (isAtomicNode(pos.node()))
return true;
return pos.atStartOfNode();
}
// This function and downstream() are used for moving back and forth between visually equivalent candidates.
// For example, for the text node "foo bar" where whitespace is collapsible, there are two candidates
// that map to the VisiblePosition between 'b' and the space. This function will return the left candidate
// and downstream() will return the right one.
// Also, upstream() will return [boundary, 0] for any of the positions from [boundary, 0] to the first candidate
// in boundary, where endsOfNodeAreVisuallyDistinctPositions(boundary) is true.
Position Position::upstream(EditingBoundaryCrossingRule rule) const
{
Node* startNode = node();
if (!startNode)
return Position();
// iterate backward from there, looking for a qualified position
Node* boundary = enclosingVisualBoundary(startNode);
PositionIterator lastVisible = *this;
PositionIterator currentPos = lastVisible;
bool startEditable = startNode->isContentEditable();
Node* lastNode = startNode;
bool boundaryCrossed = false;
for (; !currentPos.atStart(); currentPos.decrement()) {
Node* currentNode = currentPos.node();
// Don't check for an editability change if we haven't moved to a different node,
// to avoid the expense of computing isContentEditable().
if (currentNode != lastNode) {
// Don't change editability.
bool currentEditable = currentNode->isContentEditable();
if (startEditable != currentEditable) {
if (rule == CannotCrossEditingBoundary)
break;
boundaryCrossed = true;
}
lastNode = currentNode;
}
// If we've moved to a position that is visually distinct, return the last saved position. There
// is code below that terminates early if we're *about* to move to a visually distinct position.
if (endsOfNodeAreVisuallyDistinctPositions(currentNode) && currentNode != boundary)
return lastVisible;
// skip position in unrendered or invisible node
RenderObject* renderer = currentNode->renderer();
if (!renderer || renderer->style()->visibility() != VISIBLE)
continue;
if (rule == CanCrossEditingBoundary && boundaryCrossed) {
lastVisible = currentPos;
break;
}
// track last visible streamer position
if (isStreamer(currentPos))
lastVisible = currentPos;
// Don't move past a position that is visually distinct. We could rely on code above to terminate and
// return lastVisible on the next iteration, but we terminate early to avoid doing a nodeIndex() call.
if (endsOfNodeAreVisuallyDistinctPositions(currentNode) && currentPos.atStartOfNode())
return lastVisible;
// Return position after tables and nodes which have content that can be ignored.
if (editingIgnoresContent(currentNode) || isTableElement(currentNode)) {
if (currentPos.atEndOfNode())
return lastDeepEditingPositionForNode(currentNode);
continue;
}
// return current position if it is in rendered text
if (renderer->isText() && toRenderText(renderer)->firstTextBox()) {
if (currentNode != startNode) {
// This assertion fires in layout tests in the case-transform.html test because
// of a mix-up between offsets in the text in the DOM tree with text in the
// render tree which can have a different length due to case transformation.
// Until we resolve that, disable this so we can run the layout tests!
//ASSERT(currentOffset >= renderer->caretMaxOffset());
return Position(currentNode, renderer->caretMaxOffset());
}
unsigned textOffset = currentPos.offsetInLeafNode();
RenderText* textRenderer = toRenderText(renderer);
InlineTextBox* lastTextBox = textRenderer->lastTextBox();
for (InlineTextBox* box = textRenderer->firstTextBox(); box; box = box->nextTextBox()) {
if (textOffset <= box->start() + box->len()) {
if (textOffset > box->start())
return currentPos;
continue;
}
if (box == lastTextBox || textOffset != box->start() + box->len() + 1)
continue;
// The text continues on the next line only if the last text box is not on this line and
// none of the boxes on this line have a larger start offset.
bool continuesOnNextLine = true;
InlineBox* otherBox = box;
while (continuesOnNextLine) {
otherBox = otherBox->nextLeafChild();
if (!otherBox)
break;
if (otherBox == lastTextBox || (otherBox->renderer() == textRenderer && static_cast<InlineTextBox*>(otherBox)->start() > textOffset))
continuesOnNextLine = false;
}
otherBox = box;
while (continuesOnNextLine) {
otherBox = otherBox->prevLeafChild();
if (!otherBox)
break;
if (otherBox == lastTextBox || (otherBox->renderer() == textRenderer && static_cast<InlineTextBox*>(otherBox)->start() > textOffset))
continuesOnNextLine = false;
}
if (continuesOnNextLine)
return currentPos;
}
}
}
return lastVisible;
}
// This function and upstream() are used for moving back and forth between visually equivalent candidates.
// For example, for the text node "foo bar" where whitespace is collapsible, there are two candidates
// that map to the VisiblePosition between 'b' and the space. This function will return the right candidate
// and upstream() will return the left one.
// Also, downstream() will return the last position in the last atomic node in boundary for all of the positions
// in boundary after the last candidate, where endsOfNodeAreVisuallyDistinctPositions(boundary).
Position Position::downstream(EditingBoundaryCrossingRule rule) const
{
Node* startNode = node();
if (!startNode)
return Position();
// iterate forward from there, looking for a qualified position
Node* boundary = enclosingVisualBoundary(startNode);
PositionIterator lastVisible = *this;
PositionIterator currentPos = lastVisible;
bool startEditable = startNode->isContentEditable();
Node* lastNode = startNode;
bool boundaryCrossed = false;
for (; !currentPos.atEnd(); currentPos.increment()) {
Node* currentNode = currentPos.node();
// Don't check for an editability change if we haven't moved to a different node,
// to avoid the expense of computing isContentEditable().
if (currentNode != lastNode) {
// Don't change editability.
bool currentEditable = currentNode->isContentEditable();
if (startEditable != currentEditable) {
if (rule == CannotCrossEditingBoundary)
break;
boundaryCrossed = true;
}
lastNode = currentNode;
}
// stop before going above the body, up into the head
// return the last visible streamer position
if (currentNode->hasTagName(bodyTag) && currentPos.atEndOfNode())
break;
// Do not move to a visually distinct position.
if (endsOfNodeAreVisuallyDistinctPositions(currentNode) && currentNode != boundary)
return lastVisible;
// Do not move past a visually disinct position.
// Note: The first position after the last in a node whose ends are visually distinct
// positions will be [boundary->parentNode(), originalBlock->nodeIndex() + 1].
if (boundary && boundary->parentNode() == currentNode)
return lastVisible;
// skip position in unrendered or invisible node
RenderObject* renderer = currentNode->renderer();
if (!renderer || renderer->style()->visibility() != VISIBLE)
continue;
if (rule == CanCrossEditingBoundary && boundaryCrossed) {
lastVisible = currentPos;
break;
}
// track last visible streamer position
if (isStreamer(currentPos))
lastVisible = currentPos;
// Return position before tables and nodes which have content that can be ignored.
if (editingIgnoresContent(currentNode) || isTableElement(currentNode)) {
if (currentPos.offsetInLeafNode() <= renderer->caretMinOffset())
return Position(currentNode, renderer->caretMinOffset());
continue;
}
// return current position if it is in rendered text
if (renderer->isText() && toRenderText(renderer)->firstTextBox()) {
if (currentNode != startNode) {
ASSERT(currentPos.atStartOfNode());
return Position(currentNode, renderer->caretMinOffset());
}
unsigned textOffset = currentPos.offsetInLeafNode();
RenderText* textRenderer = toRenderText(renderer);
InlineTextBox* lastTextBox = textRenderer->lastTextBox();
for (InlineTextBox* box = textRenderer->firstTextBox(); box; box = box->nextTextBox()) {
if (textOffset <= box->end()) {
if (textOffset >= box->start())
return currentPos;
continue;
}
if (box == lastTextBox || textOffset != box->start() + box->len())
continue;
// The text continues on the next line only if the last text box is not on this line and
// none of the boxes on this line have a larger start offset.
bool continuesOnNextLine = true;
InlineBox* otherBox = box;
while (continuesOnNextLine) {
otherBox = otherBox->nextLeafChild();
if (!otherBox)
break;
if (otherBox == lastTextBox || (otherBox->renderer() == textRenderer && static_cast<InlineTextBox*>(otherBox)->start() >= textOffset))
continuesOnNextLine = false;
}
otherBox = box;
while (continuesOnNextLine) {
otherBox = otherBox->prevLeafChild();
if (!otherBox)
break;
if (otherBox == lastTextBox || (otherBox->renderer() == textRenderer && static_cast<InlineTextBox*>(otherBox)->start() >= textOffset))
continuesOnNextLine = false;
}
if (continuesOnNextLine)
return currentPos;
}
}
}
return lastVisible;
}
bool Position::hasRenderedNonAnonymousDescendantsWithHeight(RenderObject* renderer)
{
RenderObject* stop = renderer->nextInPreOrderAfterChildren();
for (RenderObject *o = renderer->firstChild(); o && o != stop; o = o->nextInPreOrder())
if (o->node()) {
if ((o->isText() && toRenderText(o)->linesBoundingBox().height()) ||
(o->isBox() && toRenderBox(o)->borderBoundingBox().height()))
return true;
}
return false;
}
bool Position::nodeIsUserSelectNone(Node* node)
{
return node && node->renderer() && node->renderer()->style()->userSelect() == SELECT_NONE;
}
bool Position::isCandidate() const
{
if (isNull())
return false;
RenderObject *renderer = node()->renderer();
if (!renderer)
return false;
if (renderer->style()->visibility() != VISIBLE)
return false;
if (renderer->isBR())
return m_offset == 0 && !nodeIsUserSelectNone(node()->parent());
if (renderer->isText())
return inRenderedText() && !nodeIsUserSelectNone(node());
if (isTableElement(node()) || editingIgnoresContent(node()))
return (atFirstEditingPositionForNode() || atLastEditingPositionForNode()) && !nodeIsUserSelectNone(node()->parent());
if (m_anchorNode->hasTagName(htmlTag))
return false;
if (renderer->isBlockFlow()) {
if (toRenderBlock(renderer)->height() || m_anchorNode->hasTagName(bodyTag)) {
if (!Position::hasRenderedNonAnonymousDescendantsWithHeight(renderer))
return atFirstEditingPositionForNode() && !Position::nodeIsUserSelectNone(node());
return m_anchorNode->isContentEditable() && !Position::nodeIsUserSelectNone(node()) && atEditingBoundary();
}
} else
return m_anchorNode->isContentEditable() && !Position::nodeIsUserSelectNone(node()) && atEditingBoundary();
return false;
}
bool Position::inRenderedText() const
{
if (isNull() || !node()->isTextNode())
return false;
RenderObject *renderer = node()->renderer();
if (!renderer)
return false;
RenderText *textRenderer = toRenderText(renderer);
for (InlineTextBox *box = textRenderer->firstTextBox(); box; box = box->nextTextBox()) {
if (m_offset < static_cast<int>(box->start()) && !textRenderer->containsReversedText()) {
// The offset we're looking for is before this node
// this means the offset must be in content that is
// not rendered. Return false.
return false;
}
if (box->containsCaretOffset(m_offset))
// Return false for offsets inside composed characters.
return m_offset == 0 || m_offset == textRenderer->nextOffset(textRenderer->previousOffset(m_offset));
}
return false;
}
static unsigned caretMaxRenderedOffset(const Node* n)
{
RenderObject* r = n->renderer();
if (r)
return r->caretMaxRenderedOffset();
if (n->isCharacterDataNode())
return static_cast<const CharacterData*>(n)->length();
return 1;
}
bool Position::isRenderedCharacter() const
{
if (isNull() || !node()->isTextNode())
return false;
RenderObject* renderer = node()->renderer();
if (!renderer)
return false;
RenderText* textRenderer = toRenderText(renderer);
for (InlineTextBox* box = textRenderer->firstTextBox(); box; box = box->nextTextBox()) {
if (m_offset < static_cast<int>(box->start()) && !textRenderer->containsReversedText()) {
// The offset we're looking for is before this node
// this means the offset must be in content that is
// not rendered. Return false.
return false;
}
if (m_offset >= static_cast<int>(box->start()) && m_offset < static_cast<int>(box->start() + box->len()))
return true;
}
return false;
}
bool Position::rendersInDifferentPosition(const Position &pos) const
{
if (isNull() || pos.isNull())
return false;
RenderObject *renderer = node()->renderer();
if (!renderer)
return false;
RenderObject *posRenderer = pos.node()->renderer();
if (!posRenderer)
return false;
if (renderer->style()->visibility() != VISIBLE ||
posRenderer->style()->visibility() != VISIBLE)
return false;
if (node() == pos.node()) {
if (node()->hasTagName(brTag))
return false;
if (m_offset == pos.deprecatedEditingOffset())
return false;
if (!node()->isTextNode() && !pos.node()->isTextNode()) {
if (m_offset != pos.deprecatedEditingOffset())
return true;
}
}
if (node()->hasTagName(brTag) && pos.isCandidate())
return true;
if (pos.node()->hasTagName(brTag) && isCandidate())
return true;
if (node()->enclosingBlockFlowElement() != pos.node()->enclosingBlockFlowElement())
return true;
if (node()->isTextNode() && !inRenderedText())
return false;
if (pos.node()->isTextNode() && !pos.inRenderedText())
return false;
int thisRenderedOffset = renderedOffset();
int posRenderedOffset = pos.renderedOffset();
if (renderer == posRenderer && thisRenderedOffset == posRenderedOffset)
return false;
int ignoredCaretOffset;
InlineBox* b1;
getInlineBoxAndOffset(DOWNSTREAM, b1, ignoredCaretOffset);
InlineBox* b2;
pos.getInlineBoxAndOffset(DOWNSTREAM, b2, ignoredCaretOffset);
LOG(Editing, "renderer: %p [%p]\n", renderer, b1);
LOG(Editing, "thisRenderedOffset: %d\n", thisRenderedOffset);
LOG(Editing, "posRenderer: %p [%p]\n", posRenderer, b2);
LOG(Editing, "posRenderedOffset: %d\n", posRenderedOffset);
LOG(Editing, "node min/max: %d:%d\n", caretMinOffset(node()), caretMaxRenderedOffset(node()));
LOG(Editing, "pos node min/max: %d:%d\n", caretMinOffset(pos.node()), caretMaxRenderedOffset(pos.node()));
LOG(Editing, "----------------------------------------------------------------------\n");
if (!b1 || !b2) {
return false;
}
if (b1->root() != b2->root()) {
return true;
}
if (nextRenderedEditable(node()) == pos.node() &&
thisRenderedOffset == (int)caretMaxRenderedOffset(node()) && posRenderedOffset == 0) {
return false;
}
if (previousRenderedEditable(node()) == pos.node() &&
thisRenderedOffset == 0 && posRenderedOffset == (int)caretMaxRenderedOffset(pos.node())) {
return false;
}
return true;
}
// This assumes that it starts in editable content.
Position Position::leadingWhitespacePosition(EAffinity affinity, bool considerNonCollapsibleWhitespace) const
{
ASSERT(isEditablePosition(*this));
if (isNull())
return Position();
if (upstream().node()->hasTagName(brTag))
return Position();
Position prev = previousCharacterPosition(affinity);
if (prev != *this && prev.node()->inSameContainingBlockFlowElement(node()) && prev.node()->isTextNode()) {
String string = static_cast<Text *>(prev.node())->data();
UChar c = string[prev.deprecatedEditingOffset()];
if (considerNonCollapsibleWhitespace ? (isSpaceOrNewline(c) || c == noBreakSpace) : isCollapsibleWhitespace(c))
if (isEditablePosition(prev))
return prev;
}
return Position();
}
// This assumes that it starts in editable content.
Position Position::trailingWhitespacePosition(EAffinity, bool considerNonCollapsibleWhitespace) const
{
ASSERT(isEditablePosition(*this));
if (isNull())
return Position();
VisiblePosition v(*this);
UChar c = v.characterAfter();
// The space must not be in another paragraph and it must be editable.
if (!isEndOfParagraph(v) && v.next(true).isNotNull())
if (considerNonCollapsibleWhitespace ? (isSpaceOrNewline(c) || c == noBreakSpace) : isCollapsibleWhitespace(c))
return *this;
return Position();
}
void Position::getInlineBoxAndOffset(EAffinity affinity, InlineBox*& inlineBox, int& caretOffset) const
{
TextDirection primaryDirection = LTR;
for (RenderObject* r = node()->renderer(); r; r = r->parent()) {
if (r->isBlockFlow()) {
primaryDirection = r->style()->direction();
break;
}
}
getInlineBoxAndOffset(affinity, primaryDirection, inlineBox, caretOffset);
}
static bool isNonTextLeafChild(RenderObject* object)
{
if (object->firstChild())
return false;
if (object->isText())
return false;
return true;
}
static InlineTextBox* searchAheadForBetterMatch(RenderObject* renderer)
{
RenderBlock* container = renderer->containingBlock();
RenderObject* next = renderer;
while ((next = next->nextInPreOrder(container))) {
if (next->isRenderBlock())
return 0;
if (next->isBR())
return 0;
if (isNonTextLeafChild(next))
return 0;
if (next->isText()) {
InlineTextBox* match = 0;
int minOffset = INT_MAX;
for (InlineTextBox* box = toRenderText(next)->firstTextBox(); box; box = box->nextTextBox()) {
int caretMinOffset = box->caretMinOffset();
if (caretMinOffset < minOffset) {
match = box;
minOffset = caretMinOffset;
}
}
if (match)
return match;
}
}
return 0;
}
void Position::getInlineBoxAndOffset(EAffinity affinity, TextDirection primaryDirection, InlineBox*& inlineBox, int& caretOffset) const
{
caretOffset = m_offset;
RenderObject* renderer = node()->renderer();
if (!renderer->isText()) {
if (!renderer->isRenderButton() && renderer->isBlockFlow() && hasRenderedNonAnonymousDescendantsWithHeight(renderer)) {
bool lastPosition = caretOffset == lastOffsetInNode(node());
Node* startNode = lastPosition ? node()->childNode(caretOffset - 1) : node()->childNode(caretOffset);
while (startNode && (!startNode->renderer() || (startNode->isTextNode() && toRenderText(startNode->renderer())->isAllCollapsibleWhitespace())))
startNode = (lastPosition)? startNode->previousSibling(): startNode->nextSibling();
if (startNode) {
Position pos(startNode, 0);
pos = pos.downstream(CanCrossEditingBoundary);
pos.getInlineBoxAndOffset(UPSTREAM, primaryDirection, inlineBox, caretOffset);
if (lastPosition && inlineBox)
caretOffset = inlineBox->caretMaxOffset();
return;
}
}
inlineBox = 0;
if (renderer->isBox()) {
inlineBox = toRenderBox(renderer)->inlineBoxWrapper();
if (!inlineBox || (caretOffset > inlineBox->caretMinOffset() && caretOffset < inlineBox->caretMaxOffset()))
return;
} else if (node()->isContentEditable()) {
Position pos = positionInParentBeforeNode(node()).upstream();
pos.getInlineBoxAndOffset(DOWNSTREAM, primaryDirection, inlineBox, caretOffset);
return;
}
} else {
RenderText* textRenderer = toRenderText(renderer);
InlineTextBox* box;
InlineTextBox* candidate = 0;
for (box = textRenderer->firstTextBox(); box; box = box->nextTextBox()) {
int caretMinOffset = box->caretMinOffset();
int caretMaxOffset = box->caretMaxOffset();
if (caretOffset < caretMinOffset || caretOffset > caretMaxOffset || (caretOffset == caretMaxOffset && box->isLineBreak()))
continue;
if (caretOffset > caretMinOffset && caretOffset < caretMaxOffset) {
inlineBox = box;
return;
}
if ((caretOffset == caretMinOffset) ^ (affinity == UPSTREAM))
break;
candidate = box;
}
if (candidate && candidate == textRenderer->lastTextBox() && affinity == DOWNSTREAM) {
box = searchAheadForBetterMatch(textRenderer);
if (box)
caretOffset = box->caretMinOffset();
}
inlineBox = box ? box : candidate;
}
if (!inlineBox)
return;
unsigned char level = inlineBox->bidiLevel();
if (inlineBox->direction() == primaryDirection) {
if (caretOffset == inlineBox->caretRightmostOffset()) {
InlineBox* nextBox = inlineBox->nextLeafChild();
if (!nextBox || nextBox->bidiLevel() >= level)
return;
level = nextBox->bidiLevel();
InlineBox* prevBox = inlineBox;
do {
prevBox = prevBox->prevLeafChild();
} while (prevBox && prevBox->bidiLevel() > level);
if (prevBox && prevBox->bidiLevel() == level) // For example, abc FED 123 ^ CBA
return;
// For example, abc 123 ^ CBA
while (InlineBox* nextBox = inlineBox->nextLeafChild()) {
if (nextBox->bidiLevel() < level)
break;
inlineBox = nextBox;
}
caretOffset = inlineBox->caretRightmostOffset();
} else {
InlineBox* prevBox = inlineBox->prevLeafChild();
if (!prevBox || prevBox->bidiLevel() >= level)
return;
level = prevBox->bidiLevel();
InlineBox* nextBox = inlineBox;
do {
nextBox = nextBox->nextLeafChild();
} while (nextBox && nextBox->bidiLevel() > level);
if (nextBox && nextBox->bidiLevel() == level)
return;
while (InlineBox* prevBox = inlineBox->prevLeafChild()) {
if (prevBox->bidiLevel() < level)
break;
inlineBox = prevBox;
}
caretOffset = inlineBox->caretLeftmostOffset();
}
return;
}
if (caretOffset == inlineBox->caretLeftmostOffset()) {
InlineBox* prevBox = inlineBox->prevLeafChild();
if (!prevBox || prevBox->bidiLevel() < level) {
// Left edge of a secondary run. Set to the right edge of the entire run.
while (InlineBox* nextBox = inlineBox->nextLeafChild()) {
if (nextBox->bidiLevel() < level)
break;
inlineBox = nextBox;
}
caretOffset = inlineBox->caretRightmostOffset();
} else if (prevBox->bidiLevel() > level) {
// Right edge of a "tertiary" run. Set to the left edge of that run.
while (InlineBox* tertiaryBox = inlineBox->prevLeafChild()) {
if (tertiaryBox->bidiLevel() <= level)
break;
inlineBox = tertiaryBox;
}
caretOffset = inlineBox->caretLeftmostOffset();
}
} else {
InlineBox* nextBox = inlineBox->nextLeafChild();
if (!nextBox || nextBox->bidiLevel() < level) {
// Right edge of a secondary run. Set to the left edge of the entire run.
while (InlineBox* prevBox = inlineBox->prevLeafChild()) {
if (prevBox->bidiLevel() < level)
break;
inlineBox = prevBox;
}
caretOffset = inlineBox->caretLeftmostOffset();
} else if (nextBox->bidiLevel() > level) {
// Left edge of a "tertiary" run. Set to the right edge of that run.
while (InlineBox* tertiaryBox = inlineBox->nextLeafChild()) {
if (tertiaryBox->bidiLevel() <= level)
break;
inlineBox = tertiaryBox;
}
caretOffset = inlineBox->caretRightmostOffset();
}
}
}
void Position::debugPosition(const char* msg) const
{
if (isNull())
fprintf(stderr, "Position [%s]: null\n", msg);
else
fprintf(stderr, "Position [%s]: %s [%p] at %d\n", msg, node()->nodeName().utf8().data(), node(), m_offset);
}
#ifndef NDEBUG
void Position::formatForDebugger(char* buffer, unsigned length) const
{
String result;
if (isNull())
result = "<null>";
else {
char s[1024];
result += "offset ";
result += String::number(m_offset);
result += " of ";
node()->formatForDebugger(s, sizeof(s));
result += s;
}
strncpy(buffer, result.utf8().data(), length - 1);
}
void Position::showTreeForThis() const
{
if (node()) {
node()->showTreeForThis();
fprintf(stderr, "offset: %d\n", m_offset);
}
}
#endif
} // namespace WebCore
#ifndef NDEBUG
void showTree(const WebCore::Position& pos)
{
pos.showTreeForThis();
}
void showTree(const WebCore::Position* pos)
{
if (pos)
pos->showTreeForThis();
}
#endif