// SOLVER
protected override void SolveInstance(IGH_DataAccess DA)
{
StructureType structuretype = new StormCloud.Types.StructureType();
//List<decimal> inputval = new List<decimal>();
if (!DA.GetData(0, ref structuretype))
{
return;
}
//if (!DA.GetDataList(1, inputval)) { return; }
ComputedStructure comp = structuretype.Value;
compstruc = (ComputedStructure)structuretype.Value.CloneImpl();
//paramval = inputval;
DesignView.UpdateCurrentModel(comp);
}
protected override void SolveInstance(IGH_DataAccess DA)
{
/* Declare variables to contain all inputs
* We can assign initial values (or not) that are either indicative or sensible */
//AllocConsole();
List <Rhino.Geometry.Line> lines = new List <Line>();
Types.MaterialType materialtype = new Types.MaterialType();
String sectiontype = "";
Boolean isframe = true;
/* Use the DA object to retrieve the data inside the input parameters
* If the retrieval fails (e.g. there is no data), abort*/
if (!DA.GetDataList(0, lines))
{
return;
}
if (!DA.GetData(1, ref materialtype))
{
return;
}
if (!DA.GetData(2, ref sectiontype))
{
return;
}
if (!DA.GetData(3, ref isframe))
{
return;
}
// material
StructureEngine.Model.Material material = materialtype.Value;
// section
ISection SectionType = new RodSection();
if (sectiontype == "Square")
{
SectionType = new SquareSection();
}
//if (!DA.GetData(1, ref Material)) { return; }
//if (!DA.GetData(2, ref Section)) { return; }
// if (!DA.GetData(1, ref tolerance)) { return; }
/* If the tolerance is not a valid number, abort */
// if (!Rhino.RhinoMath.IsValidDouble(tolerance)) { return; }
/*Retrieve coordinates of start and end points*/
List <Rhino.Geometry.Point3d> pts = new List <Rhino.Geometry.Point3d>();
List <Node> Nodes = new List <Node>();
List <Member> Members = new List <Member>();
foreach (Line line in lines)
{
Point3d start = line.From;
Point3d end = line.To;
int index1 = Nodes.FindIndex(n => n.IsAtPoint(start));
int index2 = Nodes.FindIndex(n => n.IsAtPoint(end));
Node n1 = new Node(start, isframe);
Node n2 = new Node(end, isframe);
if (index1 == -1 && index2 == -1)
{
n1.SetIndex(Nodes.Count);
Nodes.Add(n1);
n2.SetIndex(Nodes.Count + 1);
Nodes.Add(n2);
}
else if (index1 != -1 && index2 == -1)
{
n1 = Nodes[index1];
n2.SetIndex(Nodes.Count);
Nodes.Add(n2);
}
else if (index1 == -1 && index2 != -1)
{
n1.SetIndex(Nodes.Count);
Nodes.Add(n1);
n2 = Nodes[index2];
}
if (!(index1 != -1 && index2 != -1))
{
Member m = new Member(n1, n2);
m.Material = material;
m.SectionType = SectionType;
//m.Material = Material.MaterialValue;
//m.Section = Section.SectionValue;
// Add member and nodes to respective list
Members.Add(m);
}
}
//Console.WriteLine(5);
//foreach (Rhino.Geometry.Line line in lines)
//{
// pts.Add(line.From);
// pts.Add(line.To);
// int n1Index = pts.Count - 2;
// int n2Index = pts.Count - 1;
// // Define start node, eliminate dup if necessary
// for (int i = 0; i < pts.Count - 2; i++) // < should become <= (or not?)
// {
// if (Rhino.Geometry.Point3d.Equals(pts[pts.Count - 2], pts[i]))
// {
// pts.RemoveAt(pts.Count - 2);
// n1Index = i;
// n2Index = n2Index - 1; // test
// }
// }
// DOF x1 = new DOF(pts[n1Index].X);
// DOF y1 = new DOF(pts[n1Index].Y);
// DOF z1 = new DOF(pts[n1Index].Z);
// DOF[] coor1 = new DOF[] { x1, y1, z1, new DOF(0,isframe), new DOF(0,isframe), new DOF(0,isframe) };
// Node n1 = new Node(coor1);
// n1.Index = n1Index;
// check that it is a new node
// Define end node, eliminate dup if necessary
// for (int i = 0; i < pts.Count - 1; i++)
// {
// if (Rhino.Geometry.Point3d.Equals(pts[pts.Count - 1], pts[i]))
// {
// pts.RemoveAt(pts.Count - 1);
// n2Index = i;
// }
// }
// DOF x2 = new DOF(pts[n2Index].X);
// DOF y2 = new DOF(pts[n2Index].Y);
// DOF z2 = new DOF(pts[n2Index].Z);
// DOF[] coor2 = new DOF[] {x2, y2, z2, new DOF(0, isframe), new DOF(0, isframe), new DOF(0, isframe)};
// Node n2 = new Node(coor2);
// n2.Index = n2Index;
// // Define member
// Member m = new Member(n1, n2);
// m.Material = material;
// m.SectionType = SectionType;
// //m.Material = Material.MaterialValue;
// //m.Section = Section.SectionValue;
// // Add member and nodes to respective list
// Nodes.Add(n1);
// Nodes.Add(n2);
// Members.Add(m);
//}
Structure Structure = new Structure(Nodes, Members);
ComputedStructure CompStructure = new ComputedStructure(Structure);
Types.StructureType Structure_GHrep = new Types.StructureType(CompStructure);
/*Assign the outputs via the DA object*/
DA.SetDataList(0, pts);
DA.SetData(1, Structure_GHrep);
}
