void SetXMLValueForKey(const char* pKey, const char* value, rapidxml::xml_document<>& doc, rapidxml::xml_node<>* parentNode)
{
// check the params
if (!pKey || !value || !parentNode)
{
return;
}
// find the node
rapidxml::xml_node<>* node = parentNode->first_node(pKey);
if (node)
{
if (node->first_node())
{
node->first_node()->value(doc.allocate_string(value));
}
else
{
node->value(doc.allocate_string(value));
}
}
else
{
parentNode->append_node(doc.allocate_node(rapidxml::node_element, doc.allocate_string(pKey), doc.allocate_string(value)));
}
}
void Genome::FillGenes(rapidxml::xml_document<>& doc, rapidxml::xml_node<>* chromosomeNode, Encoding& encoding){
for (rapidxml::xml_node<>* geneNode = chromosomeNode->first_node("Gene"); geneNode; geneNode = geneNode->next_sibling("Gene"))
{
char* pchRandomData = doc.allocate_string(encoding.RandomData(chromosomeNode).c_str());
geneNode->value(pchRandomData);
}
}
bool struct_xml(rapidxml::xml_node<> * & node, const ReqDeviceInfo & in, rapidxml::xml_document<> & doc)
{
node = doc.allocate_node(rapidxml::node_element, doc.allocate_string("ReqDeviceInfo"));
/* @generate [ userId:int ] begin @ */
{
auto node1 = doc.allocate_node(rapidxml::node_element, "userId", doc.allocate_string(get_string(in.userId).c_str()));
node->append_node(node1);
}
/* @generate [ userId:int ] end @ */
/* @generate [ deviceId:int ] begin @ */
{
auto node1 = doc.allocate_node(rapidxml::node_element, "deviceId", doc.allocate_string(get_string(in.deviceId).c_str()));
node->append_node(node1);
}
/* @generate [ deviceId:int ] end @ */
return true;
}
void XmlTree::appendRapidXmlNode( rapidxml::xml_document<char> &doc, rapidxml::xml_node<char> *parent ) const
{
rapidxml::node_type type;
switch( getNodeType() ) {
case XmlTree::NODE_ELEMENT: type = rapidxml::node_element; break;
case XmlTree::NODE_COMMENT: type = rapidxml::node_comment; break;
case XmlTree::NODE_CDATA: type = rapidxml::node_cdata; break;
case XmlTree::NODE_DATA: type = rapidxml::node_data; break;
default: throw ExcUnknownNodeType();
}
rapidxml::xml_node<char> *node = 0;
if( type == rapidxml::node_data ) {
node = doc.allocate_node( type, NULL, doc.allocate_string( getValue().c_str() ) );
}
else if( type == rapidxml::node_comment ) {
node = doc.allocate_node( type, doc.allocate_string( getTag().c_str() ), doc.allocate_string( getValue().c_str() ) );
}
else {
node = doc.allocate_node( type, doc.allocate_string( getTag().c_str() ), NULL );
if( ! getValue().empty() )
node->append_node( doc.allocate_node( rapidxml::node_data, NULL, doc.allocate_string( getValue().c_str() ) ) );
}
parent->append_node( node );
for( list<Attr>::const_iterator attrIt = mAttributes.begin(); attrIt != mAttributes.end(); ++attrIt )
node->append_attribute( doc.allocate_attribute( doc.allocate_string( attrIt->getName().c_str() ), doc.allocate_string( attrIt->getValue().c_str() ) ) );
for( Container::const_iterator childIt = mChildren.begin(); childIt != mChildren.end(); ++childIt )
(*childIt)->appendRapidXmlNode( doc, node );
}
void TacheUnitaire::xml_ajouterAttributs(rapidxml::xml_document<> & doc, rapidxml::xml_node<> & node_tache)
{
using namespace rapidxml;
xml_attribute<> * attribute = doc.allocate_attribute("type", "u");
node_tache.append_attribute(attribute);
if(getPreempte() == true) {
attribute = doc.allocate_attribute("pre", "true");
node_tache.append_attribute(attribute);
}
char * node_name = doc.allocate_string( duree.toChar() );
attribute = doc.allocate_attribute( "duree", node_name );
node_tache.append_attribute(attribute);
}
void Genome::GeneMutations(rapidxml::xml_document<>& doc, rapidxml::xml_node<>* geneNode, Mutation& mutation, MutationChance mutationChance){
char* pchMutatedData;
int nLow = 0;
int nHigh = RAND_MAX;
double dRandom;
dRandom = (double)((rand() % (nHigh - nLow + 1)) + nLow)/nHigh;
dRandom = dRandom * 100;
if(dRandom <= mutationChance.dBitString){
pchMutatedData = doc.allocate_string(mutation.BitString().c_str());
geneNode->value(pchMutatedData);
}
dRandom = (double)((rand() % (nHigh - nLow + 1)) + nLow)/nHigh;
dRandom = dRandom * 100;
if(dRandom <= mutationChance.dFlipBits){
pchMutatedData = doc.allocate_string(mutation.FlipBits().c_str());
geneNode->value(pchMutatedData);
}
dRandom = (double)((rand() % (nHigh - nLow + 1)) + nLow)/nHigh;
dRandom = dRandom * 100;
if(dRandom <= mutationChance.dBoundary){
pchMutatedData = doc.allocate_string(mutation.Boundary().c_str());
geneNode->value(pchMutatedData);
}
dRandom = (double)((rand() % (nHigh - nLow + 1)) + nLow)/nHigh;
dRandom = dRandom * 100;
if(dRandom <= mutationChance.dUniform){
pchMutatedData = doc.allocate_string(mutation.Uniform().c_str());
geneNode->value(pchMutatedData);
}
dRandom = (double)((rand() % (nHigh - nLow + 1)) + nLow)/nHigh;
dRandom = dRandom * 100;
if(dRandom <= mutationChance.dGaussian){
pchMutatedData = doc.allocate_string(mutation.Gaussian(mutationChance.dGaussianSigma).c_str());
geneNode->value(pchMutatedData);
}
dRandom = (double)((rand() % (nHigh - nLow + 1)) + nLow)/nHigh;
dRandom = dRandom * 100;
if(dRandom <= mutationChance.dDuplication){
pchMutatedData = doc.allocate_string(mutation.Duplication().c_str());
geneNode->value(pchMutatedData);
}
dRandom = (double)((rand() % (nHigh - nLow + 1)) + nLow)/nHigh;
dRandom = dRandom * 100;
if(dRandom <= mutationChance.dDeletion){
pchMutatedData = doc.allocate_string(mutation.Deletion().c_str());
geneNode->value(pchMutatedData);
}
dRandom = (double)((rand() % (nHigh - nLow + 1)) + nLow)/nHigh;
dRandom = dRandom * 100;
if(dRandom <= mutationChance.dInsertion){
pchMutatedData = doc.allocate_string(mutation.Insertion().c_str());
geneNode->value(pchMutatedData);
}
dRandom = (double)((rand() % (nHigh - nLow + 1)) + nLow)/nHigh;
dRandom = dRandom * 100;
if(dRandom <= mutationChance.dSwap){
pchMutatedData = doc.allocate_string(mutation.Swap().c_str());
geneNode->value(pchMutatedData);
}
}
void CTest::AddXMLAttributeValue( rapidxml::xml_document<>& pDoc, rapidxml::xml_node<>* pNode, const std::wstring& strwKey, const std::wstring& strwValue )
{
std::string straValue = wstr2str(strwValue, CP_UTF8);
std::string strakey = wstr2str(strwKey, CP_UTF8);
pNode->append_attribute(pDoc.allocate_attribute(pDoc.allocate_string(strakey.c_str()), pDoc.allocate_string(straValue.c_str()) ) );
}
bool struct_xml(rapidxml::xml_node<> * & node, const RetDeviceInfo & in, rapidxml::xml_document<> & doc)
{
node = doc.allocate_node(rapidxml::node_element, doc.allocate_string("RetDeviceInfo"));
/* @generate [ userId:int ] begin @ */
{
auto node1 = doc.allocate_node(rapidxml::node_element, "userId", doc.allocate_string(get_string(in.userId).c_str()));
node->append_node(node1);
}
/* @generate [ userId:int ] end @ */
/* @generate [ deviceId:int ] begin @ */
{
auto node1 = doc.allocate_node(rapidxml::node_element, "deviceId", doc.allocate_string(get_string(in.deviceId).c_str()));
node->append_node(node1);
}
/* @generate [ deviceId:int ] end @ */
/* @generate [ deviceInfos:std::vector< ReqDeviceInfo > ] begin @ */
{
auto node1 = doc.allocate_node(rapidxml::node_element, doc.allocate_string("deviceInfos"));
node->append_node(node1);
auto node2 = doc.allocate_node(rapidxml::node_element, doc.allocate_string("Vector"));
node1->append_node(node2);
for(auto i = in.deviceInfos.begin(); i != in.deviceInfos.end(); ++i)
{
rapidxml::xml_node<> * tmp = 0;
if(!struct_xml(tmp, *i, doc))
return false;
node2->append_node(tmp);
}
}
/* @generate [ deviceInfos:std::vector< ReqDeviceInfo > ] end @ */
/* @generate [ deviceInfos2:std::vector< int > ] begin @ */
{
auto node1 = doc.allocate_node(rapidxml::node_element, doc.allocate_string("deviceInfos2"));
node->append_node(node1);
auto node2 = doc.allocate_node(rapidxml::node_element, doc.allocate_string("Vector"));
node1->append_node(node2);
for(auto i = in.deviceInfos2.begin(); i != in.deviceInfos2.end(); ++i)
{
rapidxml::xml_node<> * tmp = 0;
if(!struct_xml(tmp, *i, doc))
return false;
node2->append_node(tmp);
}
}
/* @generate [ deviceInfos2:std::vector< int > ] end @ */
/* @generate [ deviceInfo:ReqDeviceInfo ] begin @ */
{
auto node1 = doc.allocate_node(rapidxml::node_element, "deviceInfo");
node->append_node(node1);
rapidxml::xml_node<> * node2 = 0;
if(!struct_xml(node2, in.deviceInfo, doc))
return false;
node1->append_node(node2);
}
/* @generate [ deviceInfo:ReqDeviceInfo ] end @ */
/* @generate [ time:int ] begin @ */
{
auto node1 = doc.allocate_node(rapidxml::node_element, "time", doc.allocate_string(get_string(in.time).c_str()));
node->append_node(node1);
}
/* @generate [ time:int ] end @ */
return true;
}
rapidxml::xml_node<char>* parsed_config()
{
ctext = doc.allocate_string(xml_config.c_str());
doc.parse< rapidxml::parse_no_data_nodes >(ctext);
return doc.first_node();
}