void polyPrint2(double a[], int n) {
int i;
int first=1;
//adjust n for actual integer value
n--;
//first checks to make sure array is not empty
if (checkifempty(a, n)) {
for (i = n; i >= 0; i--) {
//if the value is 0 or 1, dont print it
if (a[i] != 1 && fabs(a[i]) >= 0) {
// if the value is greater than 0 than print it
if (a[i] < 0 && i==n && first) {
printf("-");
first=0;
}
if (fabs(a[i]) > 0&&a[i]!=-1) {
printf("%g", fabs(a[i]));
}
}
// if the number has a greater exponent than 1 and value isnt 0
if (i > 1 && a[i] != 0) {
printf("x^%d", i);
} else if (i == 1) {
//the cases if the value is x with exponent of 1
if (a[i] == 0)
continue;
else {
printf("x");
}
}
//handle placing signs
if (i > 0 &&a[i]!=0) {
//if it isnt empty than print accorind to the next sign
if (a[nextElement(a, i)] < 0)
printf(" - ");
else if (a[nextElement(a, i)] > 0)
printf(" + ");
else break;
i = nextElement(a, i)+1;
}
}
} else
printf("0");
//newline after creating polynomial
printf("\n");
}
int nextElementValue(char *name, FILE *fp) {
unsigned int value;
nextElement(name, fp);
fscanf(fp, "%u", &value);
reachChar('>', fp);
return value;
}
void Carousel::handleZoomAnimationEvent(const ZoomAnimationImage& element)
{
if (currentAnimation == ANIMATE_LEFT)
{
// Reset the order of the visible elements
remove(visibleElements[4]);
insert(&visibleElements[2], visibleElements[4]);
setSelectedElement(nextElement(selectedElement));
}
else if (currentAnimation == ANIMATE_RIGHT)
{
// Reset the order of the visible elements
remove(visibleElements[2]);
insert(&visibleElements[5], visibleElements[2]);
setSelectedElement(prevElement(selectedElement));
}
else if (currentAnimation == ANIMATE_ELEMENT_SELECTED)
{
}
currentAnimation = NO_ANIMATION;
if (carouselAnimationEndedAction && carouselAnimationEndedAction->isValid())
{
carouselAnimationEndedAction->execute(*this);
}
}
Vertex readVertex(FILE *fp, Edge *ep, int numberOfEdges, EdgePointer *EdgePointerStart) {
static int EdgePointerCount = 0;
Vertex v;
memset(&v, 0, sizeof(v));
char buf[BIG_BUFFER];
memset(buf, 0, BIG_BUFFER);
int value;
nextElement(buf, fp);
if (strcmp(buf, "vertex"))
error();
v.vertexId = nextElementValue(buf, fp);
memset(buf, 0 , BIG_BUFFER);
nextElement(buf, fp);
if (strcmp(buf, "coord"))
error();
v.x = nextElementValue(buf, fp);
v.y = nextElementValue(buf, fp);
nextElement(buf, fp);
memset(buf, 0, BIG_BUFFER);
nextElement(buf, fp);
if (strcmp(buf, "edges"))
error();
while (1) {
memset(buf, 0, BIG_BUFFER);
value = nextElementValue(buf, fp);
if (strcmp(buf, "edgeId") == 0) {
Edge *edgeP = getEp(ep, value, numberOfEdges);
assignEdge(&(v.ep), &EdgePointerStart[EdgePointerCount++], edgeP);
} else
break;
}
getFloorAndtype(v.vertexId , (int *) & (v.floorId) , (int *) & (v.type));
return v;
}
//vygeneruje XML subor
bool generateXML(Car *car, int n) {
FILE *xmlOut = fopen("cars.xml", "w");
int i;
if (xmlOut != NULL) {
fprintf(xmlOut, "<?xml version=\"1.0\" encoding=\"UTF - 8\"?>\n");
fprintf(xmlOut, "<cars>\n");
for (i = 0; i < n; i++) {
fprintf(xmlOut, "\n\t<car id=%d>\n", i + 1); //item start
nextElement(xmlOut, "type", car[i].type, "brand", car[i].brand, 2); //brand & type
nextElement(xmlOut, "color", getColor(car[i].color), NULL, NULL, 2); //color
nextElement(xmlOut, "year", getYear(car[i].year),NULL,NULL,2); //year
char temp[2]; //fuel
temp[0] = car[i].fuel;
temp[1] = '\0';
nextElement(xmlOut, "fuel", temp, NULL, NULL, 2);
//date
char **tags = (char**)malloc(sizeof(char*) * 3); //tags
tags[0] = (char*)malloc(sizeof(char) * 4);
strcpy(tags[0], "day\0");
tags[1] = (char*)malloc(sizeof(char) * 6);
strcpy(tags[1], "month\0");
tags[2] = (char*)malloc(sizeof(char) * 5);
strcpy(tags[2], "year\0");
char **values = (char**)malloc(sizeof(char*) * 3); //values
values[0] = (char*)malloc(sizeof(char) * (strlen(getDay(car[i].evidDate.day)) + 1));
strcpy(values[0], getDay(car[i].evidDate.day));
values[1] = (char*)malloc(sizeof(char) * (strlen(getMonth(car[i].evidDate.month)) + 1));
strcpy(values[1], getMonth(car[i].evidDate.month));
values[2] = (char*)malloc(sizeof(char) * (strlen(getYear(car[i].evidDate.year)) + 1));
strcpy(values[2], getYear(car[i].evidDate.year));
nextStructElement(xmlOut, "date", tags, values, 3, NULL, NULL, 2);
nextElement(xmlOut, "plate", car[i].licansePlate, NULL, NULL, 2); //licanse plate
fprintf(xmlOut, "\t<performance>%d KW</performance>\n", car[i].performance); //performance
fprintf(xmlOut, "\t<driven>%d km</driven>\n", car[i].driven); //driven
fprintf(xmlOut, "\t</car>\n"); //item end
}
fprintf(xmlOut, "\n</cars>\n");
return true;
}
return false;
}
/*!
@brief Free Objects related to VariableArray
*/
void VariableArrayCursor::finalize() {
reset();
if (getBaseOId() != UNDEF_OID) {
while (nextElement(true)) {
;
}
}
}
void readEdges(FILE *fp, Edge *edges, int numberOfEdges) {
char buf[MEDIUM_BUFFER];
memset(buf, 0, MEDIUM_BUFFER);
nextElement(buf, fp);
int i;
if (strcmp(buf, "edges"))
error();
for (i = 0; i < numberOfEdges; i++) {
edges[i] = readEdge(fp);
}
nextElement(buf, fp);
}
void ClassGenerator::generate()
{
BaseCodegenerator::generate();
// ++index;
nextElement();
}
void m_read()
{
m_ok = (m_enumeration && m_enumeration->hasMoreElements()) ? true : false;
if (m_ok)
{
m_enumeration->nextElement(m_value);
}
}
void readvertices(FILE *fp, Vertex *vertices, int numberOfvertices, Edge *ep, int numberOfEdges) {
char buf[MEDIUM_BUFFER];
memset(buf, 0, MEDIUM_BUFFER);
nextElement(buf, fp);
int i;
EdgePointer *EdgePointerStart = (EdgePointer *)(vertices + numberOfvertices);
if (strcmp(buf, "vertices"))
error();
for (i = 0; i < numberOfvertices; i++) {
vertices[i] = readVertex(fp, ep, numberOfEdges, EdgePointerStart);
}
nextElement(buf, fp);
}
Graph *readXml(FILE *fp) {
Floor *floors;
char c = 0;
char buf[SMALL_BUFFER];
int edgesCount, verticesCount, floorsCount;
while ((c = getc(fp)) != EOF) {
if (c == '<')
break;
}
fscanf(fp, "%6s", buf);
if (strcmp(buf, "graph")) {
error();
return NULL;
}
readDefaultAtributes(&edgesCount, &verticesCount, &floorsCount, fp);
unsigned long amountToAlloc = sizeof(Graph) + floorsCount * sizeof(Floor) +
verticesCount * sizeof(Vertex) +
edgesCount * sizeof(Edge) +
edgesCount * 2 * sizeof(EdgePointer);
Graph *graph = malloc(amountToAlloc);
memset(graph, 0, amountToAlloc);
floors = (void *)(graph + 1);
Edge *edges = (Edge *)(floors + floorsCount);
Vertex *vertices = (Vertex *)(edges + edgesCount);
reachChar('>', fp);
readEdges(fp, edges, edgesCount);
readvertices(fp, vertices, verticesCount, edges, edgesCount);
nextElement(buf, fp);
if (strcmp(buf, "graph"))
error();
crawlEdges(&edges, vertices, edgesCount, verticesCount);
crawVertices(&vertices, verticesCount, &floors);
crawlFloors(&floors, vertices, floorsCount, verticesCount);
graph->numOfVertices = verticesCount;
graph->numOfFloors = floorsCount;
graph->floors = floors;
return graph;
}
void nextStructElement(FILE *file, char *root_tag, char **child, char **values, int n, char *att, char *attValue, int step) {
level(file,step);
fprintf(file, "<%s ", root_tag);
if (att != NULL && attValue != NULL) {
fprintf(file, "%s=%s", att, attValue);
}
fprintf(file, ">\n");
int i = 0;
for (i; i < n; i++) {
nextElement(file, child[i], values[i], NULL, NULL, step + 1);
}
level(file, step);
fprintf(file, "</%s>\n", root_tag);
}
virtual void endElementEvent(const XMLCh *prefix, const XMLCh *uri, const XMLCh *localname,
const XMLCh *typeURI, const XMLCh *typeName)
{
assert(node_ && node_->getNodeType() == DOMNode::ELEMENT_NODE);
// Copy the element's type
const XMLCh *oldTypeURI, *oldTypeName;
XercesNodeImpl::typeUriAndName(node_, oldTypeURI, oldTypeName);
if(!XPath2Utils::equals(oldTypeName, typeName) ||
!XPath2Utils::equals(oldTypeURI, typeURI)) {
XercesSequenceBuilder::setElementTypeInfo((DOMElement *)node_, typeURI, typeName);
}
child_ = node_;
node_ = node_->getParentNode();
child_ = nextElement(child_->getNextSibling());
}
void Carousel::updateVisibleElements()
{
// Update the visibleElements to match the new selected element
uint8_t currentElement = prevElement(prevElement(prevElement(selectedElement)));
for (uint8_t i = 0; i < NUMBER_OF_VISIBLE_ELEMENTS; i++)
{
visibleElements[i].setBitmaps(elements[currentElement].smallBmp, elements[currentElement].mediumBmp, elements[currentElement].largeBmp);
visibleElements[i].setPosition(visibleElementPositions[i].x, visibleElementPositions[i].y, visibleElementPositions[i].width, visibleElementPositions[i].height);
visibleElements[i].setAlpha(255);
visibleElements[i].invalidate();
currentElement = nextElement(currentElement);
}
// The two elements in the end should be ready to be faded in when
// animation starts
visibleElements[0].setAlpha(0);
visibleElements[NUMBER_OF_VISIBLE_ELEMENTS-1].setAlpha(0);
}
void Menu::input()
{
InputHandler* input = InputHandler::getInstance();
if (!once){
//AudioManager::instance()->PlayGameSound("menuSong", false, 1, Vector2D(0, 0), 1);
once = true;
}
if (m_state == MENUSTATE::READY)
{
if (input->isPressed(InputHandler::DPAD_DOWN))
{
AudioManager::instance()->PlayGameSound("select", false, 0.3f, m_curr->getPosition(), 1);
nextElement();
}
else if (input->isPressed(InputHandler::DPAD_UP))
{
AudioManager::instance()->PlayGameSound("select", false, 0.3f, m_curr->getPosition(), 1);
previousElement();
}
else if (input->isPressed(InputHandler::DPAD_RIGHT))
{
AudioManager::instance()->PlayGameSound("select", false, 0.3f, m_curr->getPosition(), 1);
previousElement();
}
else if (input->isPressed(InputHandler::DPAD_LEFT))
{
AudioManager::instance()->PlayGameSound("select", false, 0.3f, m_curr->getPosition(), 1);
previousElement();
}
else if (input->isPressed(InputHandler::A))
{
AudioManager::instance()->PlayGameSound("click", false, 0.3f, m_curr->getPosition(), 1);
m_curr->invoke();
}
}
}
/*!
@brief Get field value Object
*/
void VariableArrayCursor::getField(
const ColumnInfo &columnInfo, BaseObject &baseObject) {
uint32_t variableColumnNum =
columnInfo.getColumnOffset();
uint32_t varColumnNth = 0;
while (nextElement()) {
;
if (varColumnNth == variableColumnNum) {
break;
}
++varColumnNth;
}
if (varColumnNth != variableColumnNum) {
assert(false);
GS_THROW_SYSTEM_ERROR(GS_ERROR_DS_DS_PARAMETER_INVALID,
"varColumnNth(" << varColumnNth << ") != variableColumnNum"
<< variableColumnNum);
}
baseObject.copyReference(curObject_.getBaseOId(), curObject_.getBaseAddr());
baseObject.moveCursor(
curObject_.getCursor<uint8_t>() - curObject_.getBaseAddr());
}
void nextPartialSolution(enumeration * e, bags *bag, int method){
if ( terminated(e) != 0)
{
int obj = nextElement(e);
switch(method){
case 1:
addFirstFit(obj, bag);
break;
case 2:
addNextFit(obj, bag);
break;
case 3:
addBestFit(obj, bag);
break;
}
}else{
printf("Plus d'objet. \n");
}
}
int main(){
Lol a,b,*z;
GenericField *k;
Queue *fila;
strcpy(a.c,"CASA1");
strcpy(b.c,"CASA2");
a.v=10;
b.v=20;
fila=createQueue();
insertElement(fila,&a,STRUCT1);
insertElement(fila,&b,STRUCT1);
do{
z=(Lol *)getFieldValue(getElement(fila));
if(z!=NULL){
printf("%d %s\n",z->v,z->c);
}
}while(nextElement(fila)==0);
clearQueue(fila);
getchar();
return 0;
}
Edge readEdge(FILE *fp) {
Edge ed;
unsigned int value, i;
char buf[BIG_BUFFER];
nextElement(buf, fp);
for (i = 0; i < 4; i++) {
memset(buf, 0, BIG_BUFFER);
value = nextElementValue(buf, fp);
if (strcmp(buf, "edgeId") == 0)
ed.edgeId = value;
if (strcmp(buf, "weight") == 0)
ed.weight = value;
if (strcmp(buf, "vertexId1") == 0)
ed.vertex1 = (Vertex *)(long)value;
if (strcmp(buf, "vertexId2") == 0)
ed.vertex2 = (Vertex *)(long)value;
}
reachChar('>', fp);
return ed;
}
Element* Marker::prevElement()
{
//it's the same barline
return nextElement();
}
/*!
@brief Clone
*/
OId VariableArrayCursor::clone(TransactionContext &txn,
const AllocateStrategy &allocateStrategy, OId neighborOId) {
if (UNDEF_OID == getBaseOId()) {
return UNDEF_OID;
}
OId currentNeighborOId = neighborOId;
OId linkOId = UNDEF_OID;
uint32_t srcDataLength = getArrayLength();
if (srcDataLength == 0) {
uint8_t *srcObj = getBaseAddr();
Size_t srcObjSize = getObjectManager()->getSize(srcObj);
BaseObject destObject(txn.getPartitionId(), *getObjectManager());
OId destOId = UNDEF_OID;
if (currentNeighborOId != UNDEF_OID) {
destObject.allocateNeighbor<uint8_t>(srcObjSize, allocateStrategy,
destOId, currentNeighborOId, OBJECT_TYPE_VARIANT);
}
else {
destObject.allocate<uint8_t>(
srcObjSize, allocateStrategy, destOId, OBJECT_TYPE_VARIANT);
}
memcpy(destObject.getBaseAddr(), srcObj, srcObjSize);
linkOId = destOId;
}
else {
OId srcOId = UNDEF_OID;
OId destOId = UNDEF_OID;
OId prevOId = UNDEF_OID;
uint8_t *srcObj = NULL;
BaseObject destObject(txn.getPartitionId(), *getObjectManager());
uint8_t *srcElem;
uint32_t srcElemSize;
uint32_t srcCount;
uint8_t *lastElem = NULL;
uint32_t lastElemSize = 0;
while (nextElement()) {
srcObj = data();
srcOId = getElementOId();
srcElem = getElement(srcElemSize, srcCount);
if (srcOId != prevOId) {
Size_t srcObjSize = getObjectManager()->getSize(srcObj);
if (currentNeighborOId != UNDEF_OID) {
destObject.allocateNeighbor<uint8_t>(srcObjSize,
allocateStrategy, destOId, currentNeighborOId,
OBJECT_TYPE_VARIANT);
}
else {
destObject.allocate<uint8_t>(srcObjSize, allocateStrategy,
destOId, OBJECT_TYPE_VARIANT);
}
currentNeighborOId =
destOId;
memcpy(destObject.getBaseAddr(), srcObj, srcObjSize);
if (UNDEF_OID == linkOId) {
linkOId = destOId;
}
else {
assert(lastElem > 0);
uint8_t *linkOIdAddr =
lastElem + lastElemSize +
ValueProcessor::getEncodedVarSize(lastElemSize);
uint64_t encodedOId =
ValueProcessor::encodeVarSizeOId(destOId);
memcpy(linkOIdAddr, &encodedOId, sizeof(uint64_t));
}
prevOId = srcOId;
}
lastElem = destObject.getBaseAddr() + (srcElem - srcObj);
lastElemSize = srcElemSize;
}
}
return linkOId;
}
Element* Jump::prevElement()
{
return nextElement();
}
Step *Step::nextStep()
{
const AbstractRangeElement *re = dynamic_cast<const AbstractRangeElement *>(this);
return dynamic_cast<Step *>(nextElement(re));
}
daeElementRef
daeLIBXMLPlugin::startParse(daeMetaElement* thisMetaElement, xmlTextReaderPtr reader)
{
// The original parsing system would drop everything up to the first element open, usually <COLLADA>
// This behavior will have to be replicated here till we have someplace to put the headers/comments
int ret = xmlTextReaderRead(reader);
if(ret != 1)
{
// empty or hit end of file
return NULL;
}
//printf("xmlTextReaderConstBaseUri is %s\n",xmlTextReaderConstBaseUri(reader));
//printf("xmlTextReaderConstNamespaceUri is %s\n",xmlTextReaderConstNamespaceUri(reader));
//printf("xmlTextReaderConstPrefix is %s\n",xmlTextReaderConstPrefix(reader));
//printf("xmlTextReaderName is %s\n",xmlTextReaderName(reader));
// Process the current element
// Skip over things we don't understand
while(xmlTextReaderNodeType(reader) != XML_READER_TYPE_ELEMENT)
{
ret = xmlTextReaderRead(reader);
if(ret != 1)
return(NULL);
}
// Create the element that we found
daeElementRef element = thisMetaElement->create((const daeString)xmlTextReaderConstName(reader));
if(!element)
{
char err[256];
memset( err, 0, 256 );
const xmlChar * mine =xmlTextReaderConstName(reader);
#if LIBXML_VERSION >= 20620
sprintf(err,"The DOM was unable to create an element type %s at line %d\nProbably a schema violation.\n", mine,xmlTextReaderGetParserLineNumber(reader));
#else
sprintf(err,"The DOM was unable to create an element type %s\nProbably a schema violation.\n", mine);
#endif
daeErrorHandler::get()->handleWarning( err );
xmlTextReaderNext(reader);
return NULL;
}
int currentDepth = xmlTextReaderDepth(reader);
//try and read attributes
readAttributes( element, reader );
//Check COLLADA Version
if ( strcmp( element->getTypeName(), "COLLADA" ) != 0 ) {
//invalid root
daeErrorHandler::get()->handleError("Loading document with invalid root element!");
return NULL;
}
daeURI *xmlns = (daeURI*)(element->getMeta()->getMetaAttribute( "xmlns" )->getWritableMemory( element ));
if ( strcmp( xmlns->getURI(), COLLADA_NAMESPACE ) != 0 ) {
//invalid COLLADA version
daeErrorHandler::get()->handleError("Trying to load an invalid COLLADA version for this DOM build!");
return NULL;
}
ret = xmlTextReaderRead(reader);
// If we're out of data, return the element
if(ret != 1)
return(element);
// Read all the tags that are part of this tag
bool trew = true;
while(trew)
{
int thisType = xmlTextReaderNodeType(reader);
if(thisType == XML_READER_TYPE_ELEMENT)
{
// Is the new element at the same depth as this one?
if(currentDepth == xmlTextReaderDepth(reader))
{
// Same depth means the current element ended in a /> so this is a sibling
// so we return and let our parent process it.
return(element);
}
else
{
// The element is a child of this one, so we recurse
if(!element->placeElement(nextElement(element->getMeta(), reader)))
{
char err[256];
memset( err, 0, 256 );
#if LIBXML_VERSION >= 20620
sprintf(err,"placeElement failed at line %d\n", xmlTextReaderGetParserLineNumber(reader));
#else
sprintf(err,"placeElement failed\n");
#endif
daeErrorHandler::get()->handleWarning(err);
ret = xmlTextReaderRead(reader);
if ( ret != 1 ) {
return element;
}
}
}
}
else if(thisType == XML_READER_TYPE_TEXT)
{
readValue( element, reader );
}
else if(thisType == XML_READER_TYPE_END_ELEMENT)
{
// Done with this element so read again and return
ret = xmlTextReaderRead(reader);
return(element);
}
else
{ // Skip element types we don't care about
ret = xmlTextReaderRead(reader);
// If we're out of data, return the element
if(ret != 1)
return(element);
}
}
// Return NULL on an error
return NULL;
}
virtual void startElementEvent(const XMLCh *prefix, const XMLCh *uri, const XMLCh *localname)
{
assert(child_ && child_->getNodeType() == DOMNode::ELEMENT_NODE);
node_ = child_;
child_ = nextElement(node_->getFirstChild());
}
void PrefabPlant::nextElement( const wstring & name, const wstring & prefix )
{
nextElement(name);
}
daeElementRef
daeLIBXMLPlugin::nextElement(daeMetaElement* thisMetaElement, xmlTextReaderPtr reader)
{
int ret;
// Process the current element
// Skip over things we don't understand
while(xmlTextReaderNodeType(reader) != XML_READER_TYPE_ELEMENT)
{
ret = xmlTextReaderRead(reader);
if(ret != 1)
return(NULL);
}
// Create the element that we found
daeElementRef element = thisMetaElement->create((const daeString)xmlTextReaderConstName(reader));
if(!element)
{
const xmlChar * mine =xmlTextReaderConstName(reader);
char err[256];
memset( err, 0, 256 );
#if LIBXML_VERSION >= 20620
sprintf(err,"The DOM was unable to create an element type %s at line %d\nProbably a schema violation.\n", mine,xmlTextReaderGetParserLineNumber(reader));
#else
sprintf(err,"The DOM was unable to create an element type %s\nProbably a schema violation.\n", mine);
#endif
daeErrorHandler::get()->handleWarning( err );
if ( xmlTextReaderNext(reader) == -1 ) {
int x = 12312412;
}
return NULL;
}
int currentDepth = xmlTextReaderDepth(reader);
//try and read attributes
readAttributes( element, reader );
ret = xmlTextReaderRead(reader);
// If we're out of data, return the element
if(ret != 1)
return(element);
// Read all the tags that are part of this tag
bool trew = true;
while(trew)
{
int thisType = xmlTextReaderNodeType(reader);
if(thisType == XML_READER_TYPE_ELEMENT)
{
// Is the new element at the same depth as this one?
if(currentDepth == xmlTextReaderDepth(reader))
{
// Same depth means the current element ended in a /> so this is a sibling
// so we return and let our parent process it.
return(element);
}
else
{
// The element is a child of this one, so we recurse
if(!element->placeElement(nextElement(element->getMeta(), reader)))
{
char err[256];
memset( err, 0, 256 );
#if LIBXML_VERSION >= 20620
sprintf(err,"placeElement failed at line %d\n", xmlTextReaderGetParserLineNumber(reader));
#else
sprintf(err,"placeElement failed\n");
#endif
daeErrorHandler::get()->handleWarning( err );
ret = xmlTextReaderRead(reader);
if ( ret != 1 ) {
return element;
}
}
}
}
else if(thisType == XML_READER_TYPE_TEXT)
{
readValue( element, reader );
}
else if(thisType == XML_READER_TYPE_END_ELEMENT)
{
// Done with this element so read again and return
ret = xmlTextReaderRead(reader);
return(element);
}
else
{ // Skip element types we don't care about
ret = xmlTextReaderRead(reader);
// If we're out of data, return the element
if(ret != 1)
return(element);
}
}
//program will never get here but this line is needed to supress a warning
return NULL;
}
virtual void startDocumentEvent(const XMLCh *documentURI, const XMLCh *encoding)
{
assert(child_ && child_->getNodeType() == DOMNode::DOCUMENT_NODE);
node_ = child_;
child_ = nextElement(node_->getFirstChild());
}
