private void UpdateIntegration(List <GH_Point> points, List <GH_Vector> vectors, DynamicSettings settings)
{
// only integrate if we have a vector field to work with
if (points.Count > 0)
{
// integration
var bases = new List <Basis>();
for (int i = 0; i < points.Count; i++)
{
bases.Add(new Basis(points[i], vectors[i]));
}
var ptSampling = (points.Count != 0);
var staticSettings = ConvertDynSettingsToStatic(settings);
for (int i = 0; i < particles.Count; i++)
{
var p = particles[i];
var traveller = p.Current.Point;
var startBasis = p.Start;
var vecLast = p.Current.Vector;
var outBasis = new Basis();
if (points.Count != 0 &&
!Algos.SampleForNextPoint(bases, traveller.Value, startBasis, vecLast, staticSettings, out outBasis))
{
break;
}
p.Current.Point = outBasis.Point;
p.Current.Vector = outBasis.Vector;
}
}
}
protected override void SolveInstance(IGH_DataAccess DA)
{
// inputs
var points = new List <GH_Point>();
var vectors = new List <GH_Vector>();
var startPoints = new List <GH_Point>();
var reset = new GH_Boolean();
var settings = new GH_ObjectWrapper();
if (DA.GetDataList(0, points) && points == null)
{
this.AddRuntimeMessage(GH_RuntimeMessageLevel.Error, "Invalid points list. Operation canceled.");
return;
}
if (DA.GetDataList(1, vectors) && vectors == null)
{
this.AddRuntimeMessage(GH_RuntimeMessageLevel.Error, "Invalid vector list. Operation canceled.");
return;
}
if (vectors.Count != points.Count)
{
this.AddRuntimeMessage(GH_RuntimeMessageLevel.Error, "Vector list size mismatch with points list, they must be equal in length. Operation canceled.");
return;
}
if (DA.GetDataList(2, startPoints) && startPoints == null)
{
this.AddRuntimeMessage(GH_RuntimeMessageLevel.Error, "Invalid travelling points. Operation canceled.");
return;
}
// spm parameters component is optional, we use its defaults if it is not available
SPM_Parameters spm_settings = new SPM_Parameters();
if (DA.GetData(3, ref settings))
{
// if getdata succeeded but the settings var is null we had bad input
if (settings == null)
{
this.AddRuntimeMessage(GH_RuntimeMessageLevel.Error, "Invalid settings input. Operation canceled.");
return;
}
// otherwise cast from gh_objectwrapper and continue
spm_settings = (SPM_Parameters)settings.Value;
}
if (DA.GetData(4, ref reset) && reset == null)
{
this.AddRuntimeMessage(GH_RuntimeMessageLevel.Error, "Invalid reset input. Operation canceled.");
return;
}
if (startBasis == null || reset.Value)
{
var count = startPoints.Count;
startBasis = new Basis[count];
lastVecs = new GH_Vector[count];
xy = new double[count];
yz = new double[count];
xz = new double[count];
for (int i = 0; i < count; i++)
{
startBasis[i] = new Basis(startPoints[i]);
lastVecs[i] = new GH_Vector();
xy[i] = 0;
yz[i] = 0;
xz[i] = 0;
}
}
if (moving == null || reset.Value)
{
moving = startPoints;
return;
}
int steps = spm_settings.steps;
if (steps == 0)
{
steps = 1;
}
var bases = new List <Basis>();
for (int i = 0; i < points.Count; i++)
{
bases.Add(new Basis(points[i], vectors[i]));
}
// find each next point based on an averaging formula and iterate
for (int i = 0; i < startPoints.Count; i++)
{
for (int j = 0; j < steps; j++)
{
bool add = false;
var outBasis = new Basis();
bool working = Algos.SampleForNextPoint(bases, moving[i].Value, startBasis[i], lastVecs[i], spm_settings, out outBasis, out add);
if (spm_settings.stop && spm_settings.windAngle != 0.0d)
{
if (!lastVecs[i].Value.IsZero)
{
double cxy = xy[i];
double cyz = yz[i];
double cxz = xz[i];
if (Algos.IsWoundPast(outBasis.Vector.Value, lastVecs[i].Value, spm_settings.windAngle, ref cxy, ref cyz, ref cxz))
{
break;
}
xy[i] = cxy;
yz[i] = cyz;
xz[i] = cxz;
}
}
lastVecs[i] = outBasis.Vector;
if (working && startBasis[i].Vector.Value.IsZero)
{
startBasis[i].Vector.Value = moving[i].Value - startBasis[i].Point.Value;
}
if (add)
{
moving[i] = outBasis.Point;
}
if (!working)
{
moving[i] = startPoints[i];
}
}
}
DA.SetDataList(0, moving);
}
protected override void SolveInstance(IGH_DataAccess DA)
{
var tensors = new List <Basis>();
var xaxis = new List <GH_Vector>();
var yaxis = new List <GH_Vector>();
var zaxis = new List <GH_Vector>();
if (DA.GetDataList(0, xaxis) && xaxis == null)
{
this.AddRuntimeMessage(GH_RuntimeMessageLevel.Error, "Invalid X axis vector list. Operation canceled.");
return;
}
if (DA.GetDataList(1, yaxis) && yaxis == null)
{
this.AddRuntimeMessage(GH_RuntimeMessageLevel.Error, "Invalid Y axis vector list. Operation canceled.");
return;
}
if (DA.GetDataList(2, zaxis) && zaxis == null)
{
this.AddRuntimeMessage(GH_RuntimeMessageLevel.Error, "Invalid Z axis vector list. Operation canceled.");
return;
}
var xc = xaxis.Count;
var yc = yaxis.Count;
var zc = zaxis.Count;
// the lists can either be length 0, or the same length as every other vector list
var xym = Math.Max(xc, yc);
var max = Math.Max(xym, zc);
if (xc != 0 && xc != max)
{
this.AddRuntimeMessage(GH_RuntimeMessageLevel.Error, "X list is not parallel to Y and Z. Operation canceled.");
return;
}
if (yc != 0 && yc != max)
{
this.AddRuntimeMessage(GH_RuntimeMessageLevel.Error, "Y list is not parallel to X and Z. Operation canceled.");
return;
}
if (zc != 0 && zc != max)
{
this.AddRuntimeMessage(GH_RuntimeMessageLevel.Error, "Z list is not parallel to X and Y. Operation canceled.");
return;
}
for (int i = 0; i < max; i++)
{
Basis tensor = new Basis();
if (xc != 0)
{
tensor.Vectors[0].Value = xaxis[i].Value;
}
else
{
tensor.Vectors[0].Value = new Rhino.Geometry.Vector3d();
}
if (yc != 0)
{
tensor.Vectors[1].Value = yaxis[i].Value;
}
else
{
tensor.Vectors[1].Value = new Rhino.Geometry.Vector3d();
}
if (zc != 0)
{
tensor.Vectors[2].Value = zaxis[i].Value;
}
else
{
tensor.Vectors[2].Value = new Rhino.Geometry.Vector3d();
}
tensors.Add(tensor);
}
var output = new List <GH_ObjectWrapper>();
foreach (var t in tensors)
{
output.Add(new GH_ObjectWrapper(t));
}
DA.SetDataList(0, output);
}
public void Process(List <GH_Point> points, List <GH_Vector> vectors, GH_Surface surface)
{
var planes = Param["Pl"] as List <GH_Plane>;
var h = (double)Param["h"];
var k = (double)Param["k"];
var a = (double)Param["a"];
var e = (bool)Param["e"];
var funnel = (bool)Param["F"];
var reverse = (bool)Param["r"];
var nv = new GH_Vector();
double u1, v1, u2, v2;
u1 = u2 = v1 = v2 = 0.0d;
for (int i = 0; i < points.Count; i++)
{
foreach (var pl in planes)
{
var o = pl.Value.Origin;
var currP = points[i].Value;
if (surface.IsValid)
{
if (!e)
{
surface.Face.ClosestPoint(currP, out u1, out v1);
var surfPl = new Plane(currP, surface.Face.NormalAt(u1, v1));
Point3d remap;
surfPl.RemapToPlaneSpace(pl.Value.Origin, out remap);
var dir = surfPl.PointAt(remap.X, remap.Y) - surfPl.Origin;
dir.Unitize();
surface.Face.ClosestPoint(pl.Value.Origin, out u2, out v2);
Point2d uv1 = new Point2d(u1, v1);
Point2d uv2 = new Point2d(u2, v2);
var dis = uv1.DistanceTo(uv2);
dir *= (k / Math.Pow(dis, h));
var tan = Vector3d.CrossProduct(dir, surface.Face.NormalAt(u1, v1));
tan.Unitize();
tan *= a / dis;
Vector3d rotation = dir + tan;
rotation.Unitize();
Basis offCheck = new Basis(new GH_Point(currP + rotation));
if (!Algos.CheckIfOffSurface(offCheck, surface))
{
nv.Value += rotation;
}
}
else
{
surface.Face.ClosestPoint(currP, out u1, out v1);
surface.Face.ClosestPoint(o, out u2, out v2);
var p1 = new Point2d(u1, v1);
var p2 = new Point2d(u2, v2);
var c = surface.Face.ShortPath(p1, p2, 0.001d);
var v = c.TangentAtStart;
nv = new GH_Vector(v);
nv.Value.Unitize();
nv.Value *= (k / Math.Pow(c.GetLength(), 1d + h));
var sn = surface.Face.NormalAt(u1, v1);
var sncv = Vector3d.CrossProduct(sn, v);
sncv.Unitize();
sncv *= a / c.GetLength();
nv.Value += sncv;
}
if (reverse)
{
surface.Face.ClosestPoint(currP, out u1, out v1);
var surfN = surface.Face.NormalAt(u1, v1);
var v = Vector3d.CrossProduct(surfN, nv.Value);
v.Unitize();
v *= nv.Value.Length;
nv.Value = v;
}
}
else
{
nv = new GH_Vector(o - currP);
nv.Value.Unitize();
nv.Value *= (k / Math.Pow(currP.DistanceTo(o), 1d + h));
if (funnel)
{
Point3d outP;
pl.Value.RemapToPlaneSpace(currP, out outP);
nv.Value *= Math.Sign(outP.Z);
}
Point3d sign;
pl.Value.RemapToPlaneSpace(currP, out sign);
if (sign.X != 0 && sign.Y != 0)
{
Vector3d tan;
tan = new Vector3d(-sign.Y, sign.X, 0);
var tanAtPl = pl.Value.PointAt(tan.X, tan.Y, 0);
var tanAtO = tanAtPl - o;
tanAtO *= a / Math.Pow(tan.Length, 2d + h);
nv.Value += tanAtO;
}
}
vectors[i].Value += nv.Value;
}
}
}
protected override void SolveInstance(IGH_DataAccess DA)
{
// inputs
var points = new List <GH_Point>();
var planes = new List <GH_Plane>();
var vectors = new List <GH_Vector>();
var traveller = new GH_Point();
var settings = new GH_ObjectWrapper();
var dynamicsWrapped = new List <GH_ObjectWrapper>();
var dynamics = new List <IDynamic>();
// outputs
var linePoints = new List <GH_Point>();
var lineVecs = new List <GH_Vector>();
// gather and validate inputs
if (DA.GetDataList(0, points) && points == null)
{
this.AddRuntimeMessage(GH_RuntimeMessageLevel.Error, "Invalid points list. Operation canceled.");
return;
}
if (DA.GetData(2, ref traveller) && traveller == null)
{
this.AddRuntimeMessage(GH_RuntimeMessageLevel.Error, "Invalid travelling point. Operation canceled.");
return;
}
if (DA.GetDataList(3, dynamicsWrapped) && dynamicsWrapped == null)
{
this.AddRuntimeMessage(GH_RuntimeMessageLevel.Error, "Invalid dynamics list. Operation canceled.");
return;
}
dynamics = (from d in dynamicsWrapped select d.Value as IDynamic).ToList();
Algos.SortDynamicsByPriority(dynamics);
// spm parameters component is optional, we use its defaults if it is not available
StaticSettings spm_settings = new StaticSettings();
if (DA.GetData(4, ref settings))
{
// if getdata succeeded but the settings var is null we had bad input
if (settings == null)
{
this.AddRuntimeMessage(GH_RuntimeMessageLevel.Error, "Invalid settings input. Operation canceled.");
return;
}
// otherwise cast from gh_objectwrapper and continue
spm_settings = (StaticSettings)settings.Value;
}
var bases = new List <Basis>();
var basesWrapper = new List <GH_ObjectWrapper>();
// we need to get the vector field information after settings, for tensor settings
if (spm_settings.tensor && (spm_settings.tensorDir >= 0 && spm_settings.tensorDir <= 2))
{
if (DA.GetDataList(1, basesWrapper) && basesWrapper == null)
{
this.AddRuntimeMessage(GH_RuntimeMessageLevel.Error, "Invalid tensor field. Operation canceled.");
return;
}
for (int i = 0; i < basesWrapper.Count; i++)
{
Basis b = basesWrapper[i].Value as Basis;
bases.Add(new Basis(points[i], b.Vectors));
bases[i].Axes = spm_settings.tensorAxes;
}
}
else
{
if (DA.GetDataList(1, vectors) && vectors == null)
{
this.AddRuntimeMessage(GH_RuntimeMessageLevel.Error, "Invalid vector list. Operation canceled.");
return;
}
if (vectors.Count != points.Count && vectors.Count != 0)
{
this.AddRuntimeMessage(GH_RuntimeMessageLevel.Error, "Vector list size mismatch with points list, they must be equal in length (or empty if you wish to integrate using just dynamics). Operation canceled.");
return;
}
// if vectors list is empty we'll populate it with empty vectors to match each point
if (vectors.Count == 0)
{
foreach (var i in Enumerable.Range(0, points.Count))
{
vectors.Add(new GH_Vector());
}
}
for (int i = 0; i < points.Count; i++)
{
bases.Add(new Basis(points[i], vectors[i]));
}
}
int steps = spm_settings.steps;
if (steps == 0)
{
steps = MAX_ITERATIONS;
}
var startBasis = new Basis(traveller);
var vecLast = new GH_Vector();
double xy = 0;
double yz = 0;
double xz = 0;
// add start point to output
linePoints.Add(startBasis.Point);
Algos.ClearDynamics(dynamics);
// find each next point based on an averaging formula and iterate
for (int i = 0; i < steps; i++)
{
bool add = false;
var outBasis = new Basis();
if (points.Count != 0 &&
!Algos.SampleForNextPoint(bases, traveller.Value, startBasis, vecLast, spm_settings, out outBasis))
{
break;
}
if (dynamics.Count > 0)
{
traveller = Algos.GetPointModifiedByDynamics(traveller, outBasis, dynamics, spm_settings);
outBasis.Point = traveller;
}
else
{
traveller = outBasis.Point;
}
// this step must be done oustide of the regular halting checks as we must store the axes rotations
if (spm_settings.windAngle != 0.0d && !vecLast.Value.IsZero &&
Algos.IsWoundPast(outBasis.Vector.Value, vecLast.Value, spm_settings.windAngle, ref xy, ref yz, ref xz))
{
break;
}
var working = Algos.CheckHaltingConditions(traveller, startBasis, outBasis, vecLast.Value, out add, spm_settings);
traveller = outBasis.Point;
vecLast = outBasis.Vector;
// cache the vector between start and start+1
if (i == 0 && working)
{
startBasis.Vector.Value = traveller.Value - startBasis.Point.Value;
}
if (add)
{
linePoints.Add(traveller);
lineVecs.Add(vecLast);
}
if (!working)
{
break;
}
}
DA.SetDataList(0, linePoints);
DA.SetDataList(1, lineVecs);
}
public void Reset()
{
Current = new Basis(new GH_Point(Start.Point), new GH_Vector(Start.Vector));
LifeLeft = LifeTime;
}
