Element* next()
{
Element* current = m_currentElement;
ASSERT(current);
if (onlyRoots)
m_currentElement = nextInternal(ElementTraversal::nextSkippingChildren(*m_currentElement, &m_rootNode));
else
m_currentElement = nextInternal(ElementTraversal::next(*m_currentElement, &m_rootNode));
return current;
}
Node* next()
{
Node* current = m_currentElement;
ASSERT(current);
m_currentElement = nextInternal(ElementTraversal::nextSkippingChildren(m_currentElement, m_rootNode));
return current;
}
le_bool GlyphIterator::findFeatureTag()
{
while (nextInternal()) {
if (hasFeatureTag()) {
prevInternal();
return TRUE;
}
}
return FALSE;
}
le_bool GlyphIterator::findFeatureTag()
{
//glyphGroup = 0;
while (nextInternal()) {
if (hasFeatureTag(FALSE)) {
LEErrorCode success = LE_NO_ERROR;
glyphGroup = (glyphStorage.getAuxData(position, success) & LE_GLYPH_GROUP_MASK);
return TRUE;
}
}
return FALSE;
}
void GlyphIterator::resetCursiveLastExitPoint()
{
if ((lookupFlags & lfBaselineIsLogicalEnd) != 0 && cursiveFirstPosition >= 0 && cursiveLastPosition >= 0) {
le_int32 savePosition = position, saveLimit = nextLimit;
position = cursiveFirstPosition - direction;
nextLimit = cursiveLastPosition + direction;
while (nextInternal()) {
glyphPositionAdjustments[position].adjustYPlacement(-cursiveBaselineAdjustment);
}
position = savePosition;
nextLimit = saveLimit;
}
cursiveLastPosition = -1;
cursiveFirstPosition = -1;
cursiveBaselineAdjustment = 0;
}
ClassElementList(ContainerNode& rootNode, const AtomicString& className)
: m_className(className)
, m_rootNode(rootNode)
, m_currentElement(nextInternal(ElementTraversal::firstWithin(rootNode))) { }
explicit ClassRootNodeList(Node* rootNode, const AtomicString& className)
: m_className(className)
, m_rootNode(rootNode)
, m_currentElement(nextInternal(ElementTraversal::firstWithin(rootNode))) { }
le_bool GlyphIterator::next(le_uint32 delta)
{
return nextInternal(delta) && hasFeatureTag(TRUE);
}
