void ReferenceFrame2D::GetElementData(ElementDataContainer& edc) //fill in all element data
{
Body2D::GetElementData(edc);
//IVector FFRFelements; //elements connected to ReferenceFrame
//SearchTree searchtree; //for optimized node fill
//TArray<Node*> nodes;
//int resortconstraint; //activates resorting of the DOF of the reference frame into the constraint part
//int isACRS; //absolute coordinates reduced strain --> the frame rotation and translation is not taken into account in GetPos2D() etc.
ElementData ed;
SetElemDataIVector(edc, FFRFelements, "FFRF_elements");
ed.SetBool(draw_frame, "Draw_Frame"); edc.Add(ed);
}
void MathFunction::GetElementData(ElementDataContainer& edc) //fill in all element data
{
ElementData ed;
//structure of ElementData:
//Mathfunction
//{
// piecewise_mode = 0/1/2 %modus for piecewise interpolation: -1=not piecewise==>use parsed function, 0=constant, 1=linear, 2=quadratic
// piecewise_points = [ ... ] %supporting points (e.g. time or place) for piecewise interpolation
// piecewise_values = [ ... ] %values at supporting points
// piecewise_diff_values = [ ... ] %differential values at supporting points - for quadratic interpolation
// parsed_function = " ... " %string representing parsed function, e.g. "A*sin(omega*t)"
// parsed_function_parameter = " ... " %string representing parameter of parsed function, e.g. "t"
// user_defined_function = yes %not editable, hard-coded userdefined function!
//}
int piecewise_mode = -1;
//if (funcmode == TMFpiecewiseconst || funcmode == TMFpiecewiselinear || funcmode == TMFpiecewisequad)
//{
//}
if (funcmode == TMFpiecewiseconst)
{
piecewise_mode = 0;
}
else if (funcmode == TMFpiecewiselinear)
{
piecewise_mode = 1;
}
else if (funcmode == TMFpiecewisequad)
{
piecewise_mode = 2;
}
ed.SetInt(piecewise_mode, "piecewise_mode", -1, 2);
ed.SetToolTipText("modus for piecewise interpolation: -1=not piecewise, 0=constant, 1=linear, 2=quadratic");
edc.Add(ed);
ed.SetVector(vectime.GetVecPtr(), vectime.Length(), "piecewise_points");
ed.SetVariableLength();
ed.SetToolTipText("supporting points (e.g. time or place) for piecewise interpolation");
edc.Add(ed);
ed.SetVector(valX.GetVecPtr(), valX.Length(), "piecewise_values");
ed.SetVariableLength();
ed.SetToolTipText("values at supporting points");
edc.Add(ed);
ed.SetVector(valY.GetVecPtr(), valY.Length(), "piecewise_diff_values");
ed.SetVariableLength();
ed.SetToolTipText("differential values at supporting points - for quadratic interpolation");
edc.Add(ed);
if (funcmode == TMFexpression)
{
ed.SetText(parsedFunctionExpression.c_str(), "parsed_function");
ed.SetToolTipText("string representing parsed function, e.g. 'A*sin(omega*t)'");
edc.Add(ed);
ed.SetText(parsedFunctionVariables.c_str(), "parsed_function_parameter");
ed.SetToolTipText("string representing parameter of parsed function, e.g. 't'");
edc.Add(ed);
}
else
{
//initialize with zero strings:
ed.SetText("", "parsed_function");
ed.SetToolTipText("string representing parsed function, e.g. 'A*sin(omega*t)'");
edc.Add(ed);
ed.SetText("", "parsed_function_parameter");
ed.SetToolTipText("string representing parameter of parsed function, e.g. 't'");
edc.Add(ed);
}
if (funcmode == TMFuserdefined)
{
ed.SetBool(1,"user_defined_function");
ed.SetLocked(1);
ed.SetToolTipText("not editable, hard-coded userdefined function!");
edc.Add(ed);
}
}
