protected override void FindBoundary()
{
bool output = false;
//float acceptanceRatio = 0.9f;
//float maxTimeDistance = 0.5f;
// ~~~~~~~~~~~ Variable Initializations ~~~~~~~~~~~~~ \\
// Find out: Where do we want the boundary to be?
// "One day": Take Okubo etc as predictor.
int preferredBoundaryTime = SliceTimeMain + (24 * RedSea.Singleton.NumSubsteps) / _everyNthTimestep;
float maxTimeDistance = 1.0f;
float maxRadius = 12;
float minRadius = 1;
float radiusGrowth = StepSize * 3;
float stepSizeStreamlines = StepSize;
PointSet<Point> boundaryOW = OkuboBoundary(preferredBoundaryTime);
// At which point did we find the Boundary?
int[] boundaryIndices, boundaryIndicesLast;
// At which point did we find the Boundary last time? Initalize 0.
boundaryIndicesLast = new int[LineX];
for (int i = 0; i < boundaryIndicesLast.Length; i++)
boundaryIndicesLast[i] = int.MaxValue;
// Keep the chosen lines in here.
LineSet chosenPathlines = new LineSet(new Line[LineX]);
// These are lines that do not fullfill the criteria, but are the best ones we got so far.
Line[] bestPathlines = new Line[LineX];
float[] bestTimeDistance = new float[LineX];
for (int i = 0; i < bestTimeDistance.Length; i++)
bestTimeDistance[i] = float.MaxValue;
// ~~~~~~~~~~~~ Inner Circle ~~~~~~~~~~~~~~~~~~~~~~~~ \\
//for (float offsetInnerCircle = 7; offsetInnerCircle < 10; offsetInnerCircle += 0.1f)
float offsetInnerCircle = AlphaStable;
{
chosenPathlines = new LineSet(new Line[LineX]);
Console.WriteLine("Current offset: {0}", offsetInnerCircle);
// float offsetInnerCircle = AlphaStable;
// Save where to transit steady -> unsteady integration.
float[] offsetSeeds = new float[LineX];
for (int i = 0; i < offsetSeeds.Length; i++)
offsetSeeds[i] = offsetInnerCircle;
// Create small circle around selection.
Point[] circle = new Point[LineX];
// Seeds for pathlines.
PointSet<Point> seeds = boundaryOW; //new PointSet<Point>(circle);
// ~~~~~~~~~~~~ Integrate Pathlines and Adapt ~~~~~~~~~~~~~~~~~~~~~~~~ \\
// Setup integrator.
Integrator pathlineIntegrator = Integrator.CreateIntegrator(null, IntegrationType, _cores[_selectedCore], _repulsion);
pathlineIntegrator.StepSize = StepSize;
// Count out the runs for debugging.
int run = 0;
//while (seeds.Length > 0)
//{
// if (output)
Console.WriteLine("Starting run {0}, {1} seeds left.", run++, seeds.Length);
// ~~~~~~~~~~~~ Integrate Pathlines ~~~~~~~~~~~~~~~~~~~~~~~~ \\
#region IntegratePathlines
// Do we need to load a field first?
if (_velocity.TimeOrigin > preferredBoundaryTime - 1 || _velocity.TimeOrigin + _velocity.Size.T < preferredBoundaryTime + 1)
LoadField(Math.Max(preferredBoundaryTime - STEPS_IN_MEMORY / 2, 0), MemberMain, STEPS_IN_MEMORY);
int startStep = (int)_velocity.TimeOrigin;
// Integrate first few steps.
pathlineIntegrator.Field = _velocity;
pathlineIntegrator.Direction = Sign.POSITIVE;
LineSet[] pathlines = pathlineIntegrator.Integrate(seeds, true);
// Append integrated lines of next loaded vectorfield time slices.
float timeLength = RedSea.Singleton.NumSubstepsTotal / _everyNthTimestep; //preferredBoundaryTime * 2;
while (_currentEndStep + 1 < timeLength)
{
// Don't load more steps than we need to!
int numSteps = (int)Math.Min(timeLength - _currentEndStep, STEPS_IN_MEMORY);
pathlineIntegrator.Field = null;
LoadField(_currentEndStep, MemberMain, numSteps);
// Integrate further.
pathlineIntegrator.Field = _velocity;
pathlineIntegrator.IntegrateFurther(pathlines[0]);
}
// Now, integrate backwards.
pathlineIntegrator.Direction = Sign.NEGATIVE;
while (startStep > 0)
{
// Don't load more steps than we need to!
int numSteps = (int)Math.Min(startStep + 1, STEPS_IN_MEMORY);
pathlineIntegrator.Field = null;
LoadField(startStep - numSteps + 1, MemberMain, numSteps);
startStep = (int)_velocity.TimeOrigin;
// Integrate further.
pathlineIntegrator.Field = _velocity;
pathlineIntegrator.IntegrateFurther(pathlines[1]);
}
pathlines[1].Reverse();
pathlines[1].Append(pathlines[0]);
chosenPathlines = pathlines[1];
#endregion IntegratePathlines
// // ~~~~~~~~~~~~ Get Boundary ~~~~~~~~~~~~~~~~~~~~~~~~ \\
// #region GetBoundary
// // The two needes functions.
// Line[] distances = FieldAnalysis.GetGraph(_cores[_selectedCore], _selection, pathlines[0], StepSize, _everyNthTimestep, true);
// Line[] angles = FieldAnalysis.GetGraph(_cores[_selectedCore], _selection, pathlines[0], StepSize, _everyNthTimestep, false);
// // Find the boundary based on angle and distance.
// FieldAnalysis.FindBoundaryFromDistanceAngleDonut(distances, angles, out boundaryIndices);
// #endregion GetBoundary
// // ~~~~~~~~~~~~ Chose or Offset Pathlines ~~~~~~~~~~~~ \\
// int numNewSeeds = 0;
// int numPathlines = 0;
// float avgTimeDistance = 0;
// // Recompute start points.
// for (int idx = 0; idx < LineX; ++idx)
// {
// // We already have an optimal line here. Continue.
// if (chosenPathlines[idx] != null)
// continue;
// // Should we save this line?
// Vector3 pos;
// // Save this point
// if (boundaryIndices[numPathlines] >= 0)
// {
// pos = pathlines[numPathlines][boundaryIndices[numPathlines]];
// _allBoundaryPoints.Add(new Point(pos) { Color = new Vector3(0.1f, pos.Z * _everyNthTimestep / RedSea.Singleton.NumSubstepsTotal, 0.1f) });
// }
// // Finally found it?
// // TODOD: DEBUG!!!!!!!!!!!!!!!!111!!!!!!!!!!!!!!!!!!elf!!!!!!!!!!!!!!!!
// float timeDistance = Math.Abs((boundaryIndices[numPathlines] * StepSize) - preferredBoundaryTime);
// avgTimeDistance += timeDistance;
// if (timeDistance < maxTimeDistance || run >= 100) // We reached the spot! Take this line!
// {
// chosenPathlines[idx] = pathlines[numPathlines];
// if (output)
// Console.WriteLine("Line {0} was chosen because it is perfect!", idx);
// }
// else
// {
// // Add new seed to seed list.
// float scale = boundaryIndices[numPathlines] / preferredBoundaryTime;
// float newOffset = offsetSeeds[numPathlines] + ((scale > 1) ? radiusGrowth : -radiusGrowth);
// newOffset = Math.Max(minRadius, newOffset);
// newOffset = Math.Min(maxRadius, newOffset);
// // We are stuck. Take best value we reached so far and go on.
// if (newOffset == offsetSeeds[numPathlines] && bestPathlines[idx] != null)
// {
// chosenPathlines[idx] = bestPathlines[idx];
// continue;
// }
// if (timeDistance < bestTimeDistance[idx])
// {
// bestPathlines[idx] = pathlines[numPathlines];
// bestTimeDistance[idx] = timeDistance;
// }
// offsetSeeds[numPathlines] = newOffset;
// // Recompute position on circle.
// float x = (float)(Math.Sin(angleDiff * idx + Math.PI / 2));
// float y = (float)(Math.Cos(angleDiff * idx + Math.PI / 2));
// // Take the selection as center.
// seeds.Points[numNewSeeds] = new Point() { Position = new Vector3(_selection.X + x * offsetSeeds[numNewSeeds], _selection.Y + y * offsetSeeds[numNewSeeds], SliceTimeMain) };
// // Count up number of new seeds.
// numNewSeeds++;
// }
// // We do not count up this value if there is a chosen pathline at this index already.
// numPathlines++;
// }
// // We maybe need less seeds now?
// if (numNewSeeds < seeds.Length)
// Array.Resize(ref seeds.Points, numNewSeeds);
// Console.WriteLine("Average time distance: {0}", avgTimeDistance / numPathlines);
// }
}
// ~~~~~~~~~~~~ Get Boundary for Rendering~~~~~~~~~~~~~~~~~~~~~~~~ \\
// The two needes functions.
_coreDistanceGraph = FieldAnalysis.GetGraph(_cores[_selectedCore], _selection, chosenPathlines, StepSize, _everyNthTimestep, true);
_coreAngleGraph = FieldAnalysis.GetGraph(_cores[_selectedCore], _selection, chosenPathlines, StepSize, _everyNthTimestep, false);
// Find the boundary based on angle and distance.
_boundaryBallFunction = new LineBall(_linePlane, new LineSet(new Line[] { FieldAnalysis.FindBoundaryFromDistanceAngleDonut(_coreDistanceGraph, _coreAngleGraph, out boundaryIndices) }));
// Find the boundary in space-time.
int time = SliceTimeMain;
_boundariesSpacetime[time] = new Line() { Positions = new Vector3[LineX + 1] };
for (int l = 0; l < LineX; ++l)
{
Vector3 pos = chosenPathlines[l][boundaryIndices[l]];
_allBoundaryPoints.Add(new Point(pos) { Color = Vector3.UnitY * pos.Z / RedSea.Singleton.NumSubstepsTotal * _everyNthTimestep });
_allBoundaryPoints.Add(boundaryOW.Points[l]);
_boundariesSpacetime[time][l] = pos;
}
_boundariesSpacetime[time][LineX] = _boundariesSpacetime[time][0];
_boundaryBallSpacetime = new LineBall(_linePlane, _boundariesSpacetime, LineBall.RenderEffect.HEIGHT, Colormap);
// Pathlines for rendering.
_pathlinesTime = chosenPathlines;
_pathlines = new LineBall(_linePlane, chosenPathlines, LineBall.RenderEffect.HEIGHT, ColorMapping.GetComplementary(Colormap), Flat);
Console.WriteLine("Khalas. Boundary indices:");
float sumTime = 0;
for (int i = 0; i < chosenPathlines.Length; i++)
{
float atTime = chosenPathlines[i][boundaryIndices[i]].Z;
sumTime += atTime;
Console.WriteLine("\tTime at {0}: {1}", i, atTime);
}
Console.WriteLine("Average time: {0}", sumTime / chosenPathlines.Length);
_boundaryCloud = new PointCloud(_linePlane, new PointSet<Point>(_allBoundaryPoints.ToArray()));
LineSet set = new LineSet(_coreAngleGraph);
GeometryWriter.WriteHeightCSV(RedSea.Singleton.DonutFileName + "Angle.csv", set);
GeometryWriter.WriteToFile(RedSea.Singleton.DonutFileName + ".angle", set);
set = new LineSet(_coreDistanceGraph);
GeometryWriter.WriteHeightCSV(RedSea.Singleton.DonutFileName + "Distance.csv", set);
GeometryWriter.WriteToFile(RedSea.Singleton.DonutFileName + ".distance", set);
}
protected void BuildGraph()
{
// Compute ftle.
if (LineX == 0)
return;
//for (int seed = 0; seed < _numSeeds; ++seed)
//{
// // Smaller field: the difference diminishes it by one line.
// float[] fx = new float[LineX - 1];
// float[] x = new float[LineX - 1];
// for (int e = 0; e < fx.Length; ++e)
// {
// // Inbetween graphs, there is one useless one.
// int index = seed * LineX + e;
// if (_distanceDistance[index].Length <= 1)
// {
// fx[e] = float.MaxValue;
// x[e] = _distanceDistance[index].Offset;
// }
// else
// {
// fx[e] = _distanceDistance[index].RelativeSumOver(IntegrationTime);// / _distanceDistance[index].Length;
// x[e] = _distanceDistance[index].Offset;
// }
// }
// _errorGraph[seed] = new Graph2D(x, fx);
// int errorBound = FieldAnalysis.FindBoundaryInError(_errorGraph[seed]);
// if (errorBound >= 0)
// _allBoundaryPoints.Add(new Point(_pathlinesTime[seed * LineX + errorBound][0]));
//}
//// GeometryWriter.WriteGraphCSV(RedSea.Singleton.DonutFileName + "Error.csv", _errorGraph);
//Console.WriteLine("Radii without boundary point: {0} of {1}", _numSeeds - _allBoundaryPoints.Count, _numSeeds);
//_boundaryCloud = new PointCloud(_graphPlane, new PointSet<Point>(_allBoundaryPoints.ToArray()));
////int errorBound = FieldAnalysis.FindBoundaryInError(_errorGraph[0]);
////_pathlinesTime.Cut(errorBound);
//// ~~~~~~~~~~~~ Get Boundary for Rendering ~~~~~~~~~~~~ \\
//_pathlinesTime.Thickness *= 0.1f;
//_pathlines = new LineBall(_linePlane, _pathlinesTime, LineBall.RenderEffect.HEIGHT, ColorMapping.GetComplementary(Colormap), Flat);
//// _graph = new LineBall(_graphPlane, FieldAnalysis.WriteGraphsToCircles(_distanceAngleGraph, new Vector3(_selection.X, _selection.Y, SliceTimeMain)), LineBall.RenderEffect.HEIGHT, Colormap, false);
_graph = new LineBall(_graphPlane, FieldAnalysis.WriteGraphToSun(_ftle, new Vector3(_selection.X, _selection.Y, 0)), LineBall.RenderEffect.HEIGHT, Colormap, Flat);
_rebuilt = false;
}
protected override void UpdateBoundary()
{
if (_lastSetting != null && (_rebuilt || FlatChanged || GraphChanged) && _errorGraph != null) // && (Flat && !Graph))
{
//Graph2D[] dist = FieldAnalysis.GraphDifferenceForward(_distanceTauGraph);
//Plane zPlane = new Plane(_graphPlane, Vector3.UnitZ * 2);
_graph = new LineBall(_graphPlane, FieldAnalysis.WriteGraphToSun(_errorGraph, new Vector3(_selection.X, _selection.Y, 0)), LineBall.RenderEffect.HEIGHT, Colormap, Flat);
// _graph = new LineBall(zPlane, FieldAnalysis.WriteGraphsToCircles(dist, new Vector3(_selection.X, _selection.Y, SliceTimeMain)), LineBall.RenderEffect.HEIGHT, Colormap, false);
_rebuilt = false;
}
if (_lastSetting != null && (IntegrationTimeChanged || _rebuilt || Graph && GraphChanged && Flat))
BuildGraph();
//_graph = new LineBall(_graphPlane, FieldAnalysis.WriteGraphToSun(_errorGraph, new Vector3(_selection.X, _selection.Y, 0)), LineBall.RenderEffect.HEIGHT, Colormap, false);
// new LineBall(_graphPlane, FieldAnalysis.WriteGraphsToCircles(_distanceAngleGraph, new Vector3(_selection.X, _selection.Y, SliceTimeMain)), LineBall.RenderEffect.HEIGHT, Colormap, false);
//LineSet cutLines;
////if (SliceTimeReference > SliceTimeMain)
////{
//// // _graph = cut version of _coreAngleGraph.
//// int length = SliceTimeReference - SliceTimeMain;
//// length = (int)((float)length / StepSize + 0.5f);
//// cutLines = FieldAnalysis.CutLength(new LineSet(_coreDistanceGraph), length);
////}
////else
//// cutLines = new LineSet(_coreDistanceGraph);
//cutLines = new LineSet(FieldAnalysis.);
//_graph = new LineBall[] { new LineBall(_graphPlane, cutLines, LineBall.RenderEffect.HEIGHT, Colormap) };
}
protected List<Renderable> Map()
{
List<Renderable> output = new List<Renderable>(2);
bool update = false;
if (_lastSetting == null ||
SliceTimeMainChanged)
{
GeometryWriter.ReadFromFile(RedSea.Singleton.DonutFileName + ".angle", out _loadedAngle);
GeometryWriter.ReadFromFile(RedSea.Singleton.DonutFileName + ".distance", out _loadedDistance);
_loadedBall = new LineBall(Plane, _loadedAngle, LineBall.RenderEffect.HEIGHT);
int[] indices;
_boundaryLoaded = FieldAnalysis.FindBoundaryFromDistanceAngleDonut(_loadedDistance.Lines, _loadedAngle.Lines, out indices);
_blockData = FieldAnalysis.PlotLines2D(_loadedAngle);
_boundaryBlock = FieldAnalysis.FindBoundaryFromDistanceDonut(_blockData.Lines);
update = true;
}
if (update ||
FlatChanged)
{
_loadedBall = new LineBall(Plane, _loadedAngle, LineBall.RenderEffect.HEIGHT, Colormap, Flat);
_boundaryLoadedBall = new LineBall(_fightPlane, new LineSet(new Line[] { _boundaryLoaded }) { Thickness = 0.2f }, LineBall.RenderEffect.HEIGHT, Colormap, Flat);
_blockBall = new LineBall(Plane, _blockData, LineBall.RenderEffect.HEIGHT, Colormap, Flat);
_boundaryBlockBall = new LineBall(_fightPlane, new LineSet(new Line[] { _boundaryBlock }) { Thickness = 0.2f }, LineBall.RenderEffect.HEIGHT, Colormap, Flat);
update = true;
}
if (_lastSetting == null ||
WindowStartChanged ||
WindowWidthChanged ||
ColormapChanged ||
update)
{
_loadedBall.LowerBound = WindowStart;
_loadedBall.UpperBound = WindowWidth + WindowStart;
_loadedBall.UsedMap = Colormap;
_blockBall.LowerBound = WindowStart;
_blockBall.UpperBound = WindowWidth + WindowStart;
_blockBall.UsedMap = Colormap;
_boundaryBlockBall.LowerBound = WindowStart;
_boundaryBlockBall.UpperBound = WindowWidth + WindowStart;
_boundaryBlockBall.UsedMap = ColorMapping.GetComplementary(Colormap);
_boundaryLoadedBall.LowerBound = WindowStart;
_boundaryLoadedBall.UpperBound = WindowWidth + WindowStart;
_boundaryLoadedBall.UsedMap = ColorMapping.GetComplementary(Colormap);
}
output.Add(Graph ? _blockBall : _loadedBall);
output.Add(Graph ? _boundaryBlockBall : _boundaryLoadedBall);
return output;
}
protected void BuildGraph()
{
float cutValue = 2000.0f;
// Compute error.
if (LineX == 0)
return;
_errorGraph = new Graph2D[_numSeeds];
_allBoundaryPoints = new List<Point>();
for (int seed = 0; seed < _numSeeds; ++seed)
{
// Smaller field: the difference diminishes it by one line.
float[] fx = new float[LineX - 1];
float[] x = new float[LineX - 1];
for (int e = 0; e < fx.Length; ++e)
{
if (_lineDistance[seed][e].Length <= 1)
{
fx[e] = float.MaxValue;
x[e] = _lineDistance[seed][e].Offset;
}
else
{
fx[e] = _lineDistance[seed][e].RelativeSumOver(IntegrationTime);// / _distanceDistance[index].Length;
x[e] = _lineDistance[seed][e].Offset;
if (fx[e] > cutValue)
{
Array.Resize(ref fx, e);
Array.Resize(ref x, e);
break;
}
}
}
_errorGraph[seed] = new Graph2D(x, fx);
_errorGraph[seed].SmoothLaplacian(0.8f);
_errorGraph[seed].SmoothLaplacian(0.8f);
//var maxs = _errorGraph[seed].Maxima();
//float angle = (float)((float)seed * Math.PI * 2 / _errorGraph.Length);
//foreach (int p in maxs)
//{
// float px = _errorGraph[seed].X[p];
// _allBoundaryPoints.Add(new Point(new Vector3(_selection.X + (float)(Math.Sin(angle + Math.PI / 2)) * px, _selection.Y + (float)(Math.Cos(angle + Math.PI / 2)) * px, cutValue)) { Color = Vector3.UnitX });
//}
//int[] errorBound = FieldAnalysis.FindBoundaryInError(_errorGraph[seed]);
//foreach (int bound in errorBound)
// _allBoundaryPoints.Add(new Point(_pathlinesTime[seed * LineX + bound][0]));
}
//_boundariesSpacetime = FieldAnalysis.FindBoundaryInErrors(_errorGraph, new Vector3(_selection, SliceTimeMain));
//_boundaryBallSpacetime = new LineBall(_linePlane, _boundariesSpacetime, LineBall.RenderEffect.HEIGHT, ColorMapping.GetComplementary(Colormap));
//if (errorBound >= 0)
// _allBoundaryPoints.Add(new Point(_pathlinesTime[seed * LineX + errorBound][0]));
// GeometryWriter.WriteGraphCSV(RedSea.Singleton.DonutFileName + "Error.csv", _errorGraph);
Console.WriteLine("Radii without boundary point: {0} of {1}", _numSeeds - _allBoundaryPoints.Count, _numSeeds);
// _graphPlane.ZAxis = Plane.ZAxis * WindowWidth;
// _boundaryCloud = new PointCloud(_graphPlane, new PointSet<Point>(_allBoundaryPoints.ToArray()));
//LineSet lineCpy = new LineSet(_pathlinesTime);
//lineCpy.CutAllHeight(_repulsion);
//_pathlines = new LineBall(_linePlane, lineCpy, LineBall.RenderEffect.HEIGHT, Colormap, false);
//int errorBound = FieldAnalysis.FindBoundaryInError(_errorGraph[0]);
//_pathlinesTime.Cut(errorBound);
// ~~~~~~~~~~~~ Get Boundary for Rendering ~~~~~~~~~~~~ \\
// _pathlines = new LineBall(_linePlane, _pathlinesTime, LineBall.RenderEffect.HEIGHT, ColorMapping.GetComplementary(Colormap), Flat);
// _graph = new LineBall(_graphPlane, FieldAnalysis.WriteGraphsToCircles(_distanceAngleGraph, new Vector3(_selection.X, _selection.Y, SliceTimeMain)), LineBall.RenderEffect.HEIGHT, Colormap, false);
_graph = new LineBall(_graphPlane, FieldAnalysis.WriteGraphToSun(_errorGraph, new Vector3(_selection.X, _selection.Y, 0)), LineBall.RenderEffect.HEIGHT, Colormap, Flat);
_rebuilt = false;
}
