public static UnityEngine.Material ToUnityMaterial(this Elements.Material material)
{
var uMaterial = new UnityEngine.Material(Shader.Find("Standard"));
uMaterial.name = material.Name;
uMaterial.color = material.Color.ToUnityColor();
uMaterial.SetInt("_Cull", (int)UnityEngine.Rendering.CullMode.Off);
if (material.Color.Alpha < 1.0f)
{
uMaterial.SetInt("_SrcBlend", (int)UnityEngine.Rendering.BlendMode.One);
uMaterial.SetInt("_DstBlend", (int)UnityEngine.Rendering.BlendMode.OneMinusSrcAlpha);
uMaterial.SetInt("_ZWrite", 0);
uMaterial.DisableKeyword("_ALPHATEST_ON");
uMaterial.DisableKeyword("_ALPHABLEND_ON");
uMaterial.EnableKeyword("_ALPHAPREMULTIPLY_ON");
uMaterial.SetFloat("_Glossiness", material.GlossinessFactor);
// uMaterial.SetFloat("_Metallic", material.SpecularFactor);
uMaterial.renderQueue = 3000;
}
return(uMaterial);
}
/// <summary>
/// The BallonaBridge function.
/// </summary>
/// <param name="model">The input model.</param>
/// <param name="input">The arguments to the execution.</param>
/// <returns>A BallonaBridgeOutputs instance containing computed results and the model with any new elements.</returns>
public static BallonaBridgeOutputs Execute(Dictionary <string, Model> inputModels, BallonaBridgeInputs input)
{
/// Your code here.
var output = new BallonaBridgeOutputs(1.0);
Elements.Material brdigeMaterial = null;
switch (input.Material)
{
case Material.Red:
brdigeMaterial = new Elements.Material("Red", Colors.Red, 0.0f, 0.0f);
break;
case Material.Steel:
brdigeMaterial = BuiltInMaterials.Steel;
break;
case Material.Wood:
brdigeMaterial = BuiltInMaterials.Wood;
break;
}
var beam = new Beam(input.CenterLine, Polygon.Rectangle(input.BridgeWidth, input.BridgeHeight), brdigeMaterial);
var offsetCrv = input.CenterLine.Offset(5, EndType.Square);
// output.model.AddElement(offsetCrv);
var grid = new Grid1d(offsetCrv[0]);
grid.DivideByApproximateLength(1.0);
foreach (var pt in grid.GetCellSeparators())
{
var column = new Column(pt, 5, Polygon.Rectangle(0.05, 0.05));
output.model.AddElement(column);
}
output.model.AddElement(beam);
return(output);
}
/// <summary>
/// The Testfunction1 function.
/// </summary>
/// <param name="model">The input model.</param>
/// <param name="input">The arguments to the execution.</param>
/// <returns>A Testfunction1Outputs instance containing computed results and the model with any new elements.</returns>
public static Testfunction1Outputs Execute(Dictionary <string, Model> inputModels, Testfunction1Inputs input)
{
/// Your code here.
var output = new Testfunction1Outputs(1.0);
List <ModelCurve> modelCurves = new List <ModelCurve>();
List <Curve> Curves = new List <Curve>();
Elements.Material brdigeMaterial = null;
switch (input.Material)
{
case Material.Red:
brdigeMaterial = new Elements.Material("Red", Colors.Red, 0.0f, 0.0f);
break;
case Material.Steel:
brdigeMaterial = BuiltInMaterials.Steel;
break;
case Material.Wood:
brdigeMaterial = BuiltInMaterials.Wood;
break;
}
var profile = WideFlangeProfileServer.Instance.GetProfileByType(WideFlangeProfileType.W10x100);
var pts = new List <Vector3>();
var centerCrv = input.CenterLine;
var offsetCrv = input.CenterLine.Offset(input.OffsetWidth, EndType.Square)[0];
var offsetCrv2 = input.CenterLine.Offset(input.OffsetWidth / 2, EndType.Square)[0];
var rebuildOffsetCrv = new Polygon(offsetCrv.Vertices);
var LGon = Polygon.L(15, 15, 5);
var ltransform = new Transform(15, 0, 0);
List <Polygon> testPoly = new List <Polygon>();
testPoly.AddRange(new[] { rebuildOffsetCrv, Polygon.Rectangle(15, 15), ltransform.OfPolygon(LGon) });
foreach (var poly in testPoly)
{
var beam = new Beam(poly, Polygon.Rectangle(input.BridgeWidth, input.BridgeHeight), brdigeMaterial);
// var beam = new Beam(poly, profile, brdigeMaterial);
output.Model.AddElement(beam);
var grid = new Grid1d(poly);
grid.DivideByApproximateLength(3);
foreach (var pt in grid.GetCellSeparators())
{
var column = new Column(pt, 5, Polygon.Rectangle(0.1, 0.1));
output.Model.AddElement(column);
}
}
var secLine = new Line(new Vector3(-input.OffsetWidth * 2, 0, 0), new Vector3(input.OffsetWidth * 2, 0, 0));
// List<Plane> planes = new List<Plane>();
List <Line> secLines = new List <Line>();
var crvSegments = centerCrv.Segments();
foreach (var crv in crvSegments)
{
var grid = new Grid1d(crv);
grid.DivideByApproximateLength(3);
foreach (var pt in grid.GetCellSeparators())
{
// planes.Add(new Plane(pt, Vector3.XAxis(pt)))
// pts.Add(pt);
var transform = new Transform(pt, crv.Direction());
secLines.Add(transform.OfLine(secLine));
// planes.Add(new Plane(pt, crv.Direction()));
var column = new Column(pt, 5, Polygon.Rectangle(0.1, 0.1));
output.Model.AddElement(column);
}
}
Curves.AddRange(new[] { centerCrv, offsetCrv, (Curve)secLine });
Curves.AddRange(secLines);
foreach (var crv in Curves)
{
modelCurves.Add(new ModelCurve(crv));
}
// var pink = new Elements.Material("pink", Colors.Pink);
// var modelPoints = new ModelPoints(pts, pink);
// var crvs = new List<Curve>{Polygon.Rectangle(10,10), offsetCrv[0]};
// foreach(var crv in crvs) {
// modelCurves.Add(new ModelCurve(crv));
// var grid = new Grid1d(crv);
// grid.DivideByApproximateLength(1.0);
// foreach(var pt in grid.GetCellSeparators())
// {
// var column = new Column(pt, 5, Polygon.Rectangle(0.05, 0.05));
// output.Model.AddElement(column);
// }
// }
// output.Model.AddElements(modelPoints);
output.Model.AddElements(modelCurves);
// output.Model.AddElement(beam);
return(output);
}
