void NumericalIntegration::write_XML(tinyxml2::XMLPrinter& file_stream) const { std::ostringstream buffer; file_stream.OpenElement("NumericalIntegration"); // Numerical integration method file_stream.OpenElement("NumericalIntegrationMethod"); file_stream.PushText(write_numerical_integration_method().c_str()); file_stream.CloseElement(); // Display file_stream.OpenElement("Display"); buffer.str(""); buffer << display; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); file_stream.CloseElement(); }
void KappaCoefficientOptimizationThreshold::write_XML(tinyxml2::XMLPrinter& file_stream) const { std::ostringstream buffer; //file_stream.OpenElement("KappaCoefficientOptimizationThreshold"); // Minimum threshold file_stream.OpenElement("MinimumThreshold"); buffer.str(""); buffer << minimum_threshold; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); // Maximum threshold file_stream.OpenElement("MaximumThreshold"); buffer.str(""); buffer << maximum_threshold; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); // Step file_stream.OpenElement("Strep"); buffer.str(""); buffer << step; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); // Reserve function data file_stream.OpenElement("ReserveFunctionData"); buffer.str(""); buffer << reserve_function_data; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); //file_stream.CloseElement(); }
void Elevator::encodeXML(tinyxml2::XMLPrinter & xml) { Item::encodeXML(xml); xml.PushAttribute("height", size.y); for (std::set<int>::iterator i = unservicedFloors.begin(); i != unservicedFloors.end(); i++) { xml.OpenElement("unserviced"); xml.PushAttribute("floor", *i); xml.CloseElement(); } for (Cars::iterator c = cars.begin(); c != cars.end(); c++) { xml.OpenElement("car"); (*c)->encodeXML(xml); xml.CloseElement(); } }
void ActorFactory::print(tinyxml2::XMLPrinter& p_Printer, const InstanceBoundingVolume& p_Volume) { p_Printer.OpenElement("MeshPhysics"); p_Printer.PushAttribute("Mesh", p_Volume.meshName.c_str()); pushVector(p_Printer, "Scale", p_Volume.scale); p_Printer.CloseElement(); }
void ActorFactory::print(tinyxml2::XMLPrinter& p_Printer, const InstanceModel& p_Model) { p_Printer.OpenElement("Model"); p_Printer.PushAttribute("Mesh", p_Model.meshName.c_str()); pushVector(p_Printer, "Scale", p_Model.scale); p_Printer.CloseElement(); }
void BoundingLayer::write_XML(tinyxml2::XMLPrinter& file_stream) const { std::ostringstream buffer; file_stream.OpenElement("BoundingLayer"); // Lower bounds { file_stream.OpenElement("LowerBounds"); buffer.str(""); buffer << lower_bounds; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); } // Upper bounds { file_stream.OpenElement("UpperBounds"); buffer.str(""); buffer << upper_bounds; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); } // Display { file_stream.OpenElement("Display"); buffer.str(""); buffer << display; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); } file_stream.CloseElement(); }
void addEdge(tinyxml2::XMLPrinter& p_Printer, Vector3 p_Position, Vector3 p_Halfsize) { p_Printer.OpenElement("AABBPhysics"); p_Printer.PushAttribute("IsEdge", true); pushVector(p_Printer, "Halfsize", p_Halfsize); pushVector(p_Printer, "OffsetPosition", p_Position); p_Printer.CloseElement(); }
void LookComponent::serialize(tinyxml2::XMLPrinter& p_Printer) const { p_Printer.OpenElement("Look"); pushVector(p_Printer, "OffsetPosition", m_OffsetPosition); pushVector(p_Printer, "Forward", m_Forward); pushVector(p_Printer, "Up", m_Up); p_Printer.CloseElement(); }
void TrainingAlgorithm::write_XML(tinyxml2::XMLPrinter& file_stream) const { std::ostringstream buffer; file_stream.OpenElement("TrainingAlgorithm"); // Display file_stream.OpenElement("Display"); buffer.str(""); buffer << display; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); file_stream.CloseElement(); }
void NeuralParametersNorm::write_XML(tinyxml2::XMLPrinter& file_stream) const { std::ostringstream buffer; //file_stream.OpenElement("NeuralParametersNorm"); // Neural parameters norm weight file_stream.OpenElement("NeuralParametersNormWeight"); buffer.str(""); buffer << neural_parameters_norm_weight; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); //file_stream.CloseElement(); }
void MinkowskiError::write_XML(tinyxml2::XMLPrinter& file_stream) const { std::ostringstream buffer; //file_stream.OpenElement("MinkowskiError"); // Minkowski parameter file_stream.OpenElement("MinkowskiParameter"); buffer.str(""); buffer << Minkowski_parameter; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); //file_stream.CloseElement(); }
void RegularizationTerm::write_XML(tinyxml2::XMLPrinter& file_stream) const { file_stream.OpenElement("RegularizationTerm"); file_stream.CloseElement(); }
void ActorFactory::print(tinyxml2::XMLPrinter& p_Printer, const InstanceEdgeBox& p_Edge, Vector3 p_Scale) { p_Printer.OpenElement("OBBPhysics"); p_Printer.PushAttribute("Immovable", true); p_Printer.PushAttribute("Mass", 0.f); p_Printer.PushAttribute("IsEdge", true); using namespace DirectX; XMFLOAT3 position = p_Edge.offsetPosition; XMFLOAT3 rotation = p_Edge.offsetRotation; XMFLOAT3 halfSize = p_Edge.halfsize; if(p_Scale.x == p_Scale.y && p_Scale.x == p_Scale.z) { halfSize = p_Edge.halfsize * p_Scale.x; position = p_Edge.offsetPosition * p_Scale.x; } else { XMMATRIX rotMat , scalMat; rotMat = XMMatrixRotationRollPitchYaw(rotation.y, rotation.x, rotation.z); scalMat = XMMatrixScalingFromVector(XMLoadFloat3(&p_Scale)); float offsetValue = halfSize.x; int index = 0; float sideValue = halfSize.y; if(halfSize.x < halfSize.y) { offsetValue = halfSize.y; sideValue = halfSize.x; index = 1; } if(offsetValue < halfSize.z) { offsetValue = halfSize.z; index = 2; } XMVECTOR sizeVector = XMVectorZero(); sizeVector.m128_f32[index] = offsetValue; sizeVector = XMVector3Transform(sizeVector, rotMat); XMVECTOR pos1, pos2; XMVECTOR centerPos = XMLoadFloat3(&position); centerPos.m128_f32[3] = 1.0f; pos1 = centerPos + sizeVector; pos2 = centerPos - sizeVector; pos1 = XMVector3Transform(pos1, scalMat); pos2 = XMVector3Transform(pos2, scalMat); centerPos = (pos1 + pos2) * 0.5f; XMStoreFloat3(&position, centerPos); XMVECTOR dirVector = pos1 - centerPos; float length = XMVector3Length(dirVector).m128_f32[0]; halfSize.x = length; halfSize.y = sideValue; halfSize.z = sideValue; XMFLOAT3 direction; XMStoreFloat3(&direction,dirVector); rotation.x = -atan2f(direction.z, direction.x); rotation.y = 0; rotation.z = asinf(direction.y / length); } pushVector(p_Printer, "Halfsize", halfSize); pushVector(p_Printer, "OffsetPosition", position); pushRotation(p_Printer, "OffsetRotation", rotation); p_Printer.CloseElement(); }
void MissingValues::write_XML(tinyxml2::XMLPrinter& file_stream) const { std::ostringstream buffer; const size_t missing_values_number = get_missing_values_number(); file_stream.OpenElement("MissingValues"); // Instances number file_stream.OpenElement("InstancesNumber"); buffer.str(""); buffer << instances_number; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); // Variables number file_stream.OpenElement("VariablesNumber"); buffer.str(""); buffer << variables_number; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); // Scrubbing method file_stream.OpenElement("ScrubbingMethod"); file_stream.PushText(write_scrubbing_method().c_str()); file_stream.CloseElement(); // Missing values number file_stream.OpenElement("MissingValuesNumber"); buffer.str(""); buffer << missing_values_number; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); if(missing_values_number <= 0) { file_stream.CloseElement(); return; } std::string instances_indices_text; std::string variables_indices_text; for(size_t i = 0; i < missing_values_number; i++) { // Instance index const size_t instance_index = items[i].instance_index + 1; instances_indices_text.append(number_to_string(instance_index)); if(i != missing_values_number - 1) { instances_indices_text.append(" "); } // Variable index const size_t variable_index = items[i].variable_index + 1; variables_indices_text.append(number_to_string(variable_index)); if(i != missing_values_number - 1) { variables_indices_text.append(" "); } } // Instances indices file_stream.OpenElement("InstancesIndices"); file_stream.PushText(instances_indices_text.c_str()); file_stream.CloseElement(); // Variables indices file_stream.OpenElement("VariablesIndices"); file_stream.PushText(variables_indices_text.c_str()); file_stream.CloseElement(); file_stream.CloseElement(); }
void GoldenSectionOrder::write_XML(tinyxml2::XMLPrinter& file_stream) const { std::ostringstream buffer; //file_stream.OpenElement("GoldenSectionOrder"); // Minimum order file_stream.OpenElement("MinimumOrder"); buffer.str(""); buffer << minimum_order; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); // Maximum order file_stream.OpenElement("MaximumOrder"); buffer.str(""); buffer << maximum_order; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); // Parameters assays number file_stream.OpenElement("TrialsNumber"); buffer.str(""); buffer << trials_number; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); // Performance calculation method file_stream.OpenElement("PerformanceCalculationMethod"); file_stream.PushText(write_loss_calculation_method().c_str()); file_stream.CloseElement(); // Reserve parameters data file_stream.OpenElement("ReserveParametersData"); buffer.str(""); buffer << reserve_parameters_data; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); // Reserve loss data file_stream.OpenElement("ReservePerformanceHistory"); buffer.str(""); buffer << reserve_loss_data; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); // Reserve selection loss data file_stream.OpenElement("ReserveSelectionLossHistory"); buffer.str(""); buffer << reserve_selection_loss_data; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); // Reserve minimal parameters file_stream.OpenElement("ReserveMinimalParameters"); buffer.str(""); buffer << reserve_minimal_parameters; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); // Display file_stream.OpenElement("Display"); buffer.str(""); buffer << display; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); // selection loss goal file_stream.OpenElement("SelectionLossGoal"); buffer.str(""); buffer << selection_loss_goal; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); // Maximum iterations file_stream.OpenElement("MaximumIterationsNumber"); buffer.str(""); buffer << maximum_iterations_number; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); // Maximum time file_stream.OpenElement("MaximumTime"); buffer.str(""); buffer << maximum_time; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); // Tolerance file_stream.OpenElement("Tolerance"); buffer.str(""); buffer << tolerance; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); //file_stream.CloseElement(); }
void SimulatedAnnealingOrder::write_XML(tinyxml2::XMLPrinter& file_stream) const { std::ostringstream buffer; //file_stream.OpenElement("SimulatedAnnealingOrder"); // Minimum order file_stream.OpenElement("MinimumOrder"); buffer.str(""); buffer << minimum_order; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); // Maximum order file_stream.OpenElement("MaximumOrder"); buffer.str(""); buffer << maximum_order; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); // Cooling rate file_stream.OpenElement("CoolingRate"); buffer.str(""); buffer << cooling_rate; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); // Trials number file_stream.OpenElement("TrialsNumber"); buffer.str(""); buffer << trials_number; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); // Tolerance file_stream.OpenElement("Tolerance"); buffer.str(""); buffer << tolerance; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); // Selection performance goal file_stream.OpenElement("SelectionPerformanceGoal"); buffer.str(""); buffer << selection_performance_goal; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); // Minimum temperature file_stream.OpenElement("MinimumTemperature"); buffer.str(""); buffer << minimum_temperature; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); // Maximum iterations file_stream.OpenElement("MaximumIterationsNumber"); buffer.str(""); buffer << maximum_iterations_number; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); // Maximum time file_stream.OpenElement("MaximumTime"); buffer.str(""); buffer << maximum_time; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); // Reserve performance data file_stream.OpenElement("ReservePerformanceHistory"); buffer.str(""); buffer << reserve_performance_data; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); // Reserve selection performance data file_stream.OpenElement("ReserveSelectionPerformanceHistory"); buffer.str(""); buffer << reserve_selection_performance_data; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); //file_stream.CloseElement(); }
void PlugIn::write_XML(tinyxml2::XMLPrinter& file_stream) const { std::ostringstream buffer; file_stream.OpenElement("PlugIn"); // Independent variables number file_stream.OpenElement("IndependentVariablesNumber"); buffer.str(""); buffer << independent_variables_number; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); // Dependent variables number file_stream.OpenElement("DependentVariablesNumber"); buffer.str(""); buffer << dependent_variables_number; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); // Input method file_stream.OpenElement("InputMethod"); file_stream.PushText(write_input_method().c_str()); file_stream.CloseElement(); // Template file_name file_stream.OpenElement("TemplateFileName"); file_stream.PushText(template_file_name.c_str()); file_stream.CloseElement(); // Input file_name file_stream.OpenElement("InputFileName"); file_stream.PushText(input_file_name.c_str()); file_stream.CloseElement(); // Batch file_name file_stream.OpenElement("BatchFileName"); file_stream.PushText(script_file_name.c_str()); file_stream.CloseElement(); // Output file_name file_stream.OpenElement("OutputFileName"); file_stream.PushText(output_file_name.c_str()); file_stream.CloseElement(); // Input flags file_stream.OpenElement("InputFlags"); buffer.str(""); buffer << input_flags; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); // Output rows number file_stream.OpenElement("OutputRowsNumber"); buffer.str(""); buffer << output_rows_number; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); // Output columns number file_stream.OpenElement("OutputColumnsNumber"); buffer.str(""); buffer << output_columns_number; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); // Display file_stream.OpenElement("Display"); buffer.str(""); buffer << display; file_stream.PushText(buffer.str().c_str()); file_stream.CloseElement(); file_stream.CloseElement(); }