mirror of
https://github.com/NGSolve/netgen.git
synced 2024-12-27 14:20:34 +05:00
386 lines
8.6 KiB
C++
386 lines
8.6 KiB
C++
#include <mystdlib.h>
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#include <myadt.hpp>
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#include <meshing.hpp>
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#include <csg.hpp>
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#include <stlgeom.hpp>
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#include "fieldlines.hpp"
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namespace netgen
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{
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RKStepper :: ~RKStepper()
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{
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delete a;
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}
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RKStepper :: RKStepper(int type) : a(NULL), tolerance(1e100)
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{
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notrestarted = 0;
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if (type == 0) // explicit Euler
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{
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c.SetSize(1); c[0] = 0;
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b.SetSize(1); b[0] = 1;
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steps = order = 1;
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}
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else if (type == 1) // Euler-Cauchy
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{
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c.SetSize(2); c[0] = 0; c[1] = 0.5;
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b.SetSize(2); b[0] = 0; b[1] = 1;
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NgArray<int> size(2);
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size[0] = 0; size[1] = 1;
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a = new TABLE<double>(size);
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a->Set(2,1,0.5); // Set, Get: 1-based!
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steps = order = 2;
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}
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else if (type == 2) // Simpson
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{
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c.SetSize(3); c[0] = 0; c[1] = 1; c[2] = 0.5;
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b.SetSize(3); b[0] = b[1] = 1./6.; b[2] = 2./3.;
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NgArray<int> size(3);
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size[0] = 0; size[1] = 1; size[2] = 2;
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a = new TABLE<double>(size);
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a->Set(2,1,1);
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a->Set(3,1,0.25); a->Set(3,2,0.25);
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steps = order = 3;
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}
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else if (type == 3) // classical Runge-Kutta
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{
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c.SetSize(4); c[0] = 0; c[1] = c[2] = 0.5; c[3] = 1;
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b.SetSize(4); b[0] = b[3] = 1./6.; b[1] = b[2] = 1./3.;
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NgArray<int> size(4);
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size[0] = 0; size[1] = 1; size[2] = 2; size[3] = 3;
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a = new TABLE<double>(size);
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a->Set(2,1,0.5);
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a->Set(3,1,0); a->Set(3,2,0.5);
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a->Set(4,1,0); a->Set(4,2,0); a->Set(4,3,1);
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steps = order = 4;
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}
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K.SetSize(steps);
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}
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void RKStepper :: StartNextValCalc(const Point<3> & astartval, const double astartt, const double ah, const bool aadaptive)
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{
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//cout << "Starting RK-Step with h=" << ah << endl;
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stepcount = 0;
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h = ah;
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startt = astartt;
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startval = astartval;
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adaptive = aadaptive;
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adrun = 0;
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}
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bool RKStepper :: GetNextData(Point<3> & val, double & t, double & ah)
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{
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bool finished = false;
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if(stepcount <= steps && stepcount>0)
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{
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t = startt + c[stepcount-1]*h;
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val = startval;
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for(int i=0; i<stepcount-1; i++)
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val += h * a->Get(stepcount,i+1) * K[i];
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}
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if(stepcount == steps)
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{
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val = startval;
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for(int i=0; i<steps; i++)
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val += h * b[i] * K[i];
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if(adaptive)
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{
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if(adrun == 0)
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{
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stepcount = 0;
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h *= 0.5;
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adrun = 1;
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valh = val;
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}
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else if (adrun == 1)
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{
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stepcount = 0;
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startval_bak = startval;
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startval = val;
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startt_bak = startt;
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startt += h;//0.5*h;
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adrun = 2;
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}
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else if (adrun == 2)
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{
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Point<3> valh2 = val;
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val = valh2 + 1./(pow(2.,order)-1.) * (valh2 - valh);
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auto errvec = val - valh;
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double err = errvec.Length();
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double fac = 0.7 * pow(tolerance/err,1./(order+1.));
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if(fac > 1.3) fac = 1.3;
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if(fac < 1 || notrestarted >= 2)
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ah = 2.*h * fac;
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if(err < tolerance)
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{
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finished = true;
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notrestarted++;
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//(*testout) << "finished RK-Step, new h=" << ah << " tolerance " << tolerance << " err " << err << endl;
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}
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else
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{
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//ah *= 0.9;
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notrestarted = 0;
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//(*testout) << "restarting h " << 2.*h << " ah " << ah << " tolerance " << tolerance << " err " << err << endl;
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StartNextValCalc(startval_bak,startt_bak, ah, adaptive);
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}
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}
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}
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else
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{
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t = startt + h;
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finished = true;
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}
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}
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if(stepcount == 0)
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{
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t = startt + c[stepcount]*h;
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val = startval;
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for(int i=0; i<stepcount; i++)
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val += h * a->Get(stepcount,i) * K[i];
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}
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return finished;
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}
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bool RKStepper :: FeedNextF(const Vec<3> & f)
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{
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K[stepcount] = f;
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stepcount++;
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return true;
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}
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void FieldLineCalc :: GenerateFieldLines(Array<Point<3>> & potential_startpoints, const int numlines)
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{
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Array<Point<3>> line_points;
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Array<double> line_values;
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Array<bool> drawelems;
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Array<int> dirstart;
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pstart.SetSize0();
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pend.SetSize0();
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values.SetSize0();
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double crit = 1.0;
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if(randomized)
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{
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double sum = 0;
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double lami[3];
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Vec<3> v;
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for(int i=0; i<potential_startpoints.Size(); i++)
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{
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int elnr = mesh.GetElementOfPoint(potential_startpoints[i],lami,true) - 1;
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if(elnr == -1)
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continue;
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mesh.SetPointSearchStartElement(elnr);
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func(elnr, lami, v);
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sum += v.Length();
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}
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crit = sum/double(numlines);
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}
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int calculated = 0;
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cout << endl;
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for(int i=0; i<potential_startpoints.Size(); i++)
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{
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cout << "\rFieldline Calculation " << int(100.*i/potential_startpoints.Size()) << "%"; cout.flush();
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if(randomized)
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SetCriticalValue((double(rand())/RAND_MAX)*crit);
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if(calculated >= numlines) break;
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Calc(potential_startpoints[i],line_points,line_values,drawelems,dirstart);
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bool usable = false;
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for(int j=1; j<dirstart.Size(); j++)
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for(int k=dirstart[j-1]; k<dirstart[j]-1; k++)
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{
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if(!drawelems[k] || !drawelems[k+1]) continue;
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usable = true;
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pstart.Append(line_points[k]);
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pend.Append(line_points[k+1]);
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values.Append( 0.5*(line_values[k]+line_values[k+1]) );
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}
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if(usable) calculated++;
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}
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cout << "\rFieldline Calculation " << 100 << "%" << endl;
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}
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FieldLineCalc :: FieldLineCalc(const Mesh & amesh, const VectorFunction & afunc,
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const double rel_length, const int amaxpoints,
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const double rel_thickness, const double rel_tolerance, const int rk_type, const int adirection) :
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mesh(amesh), func(afunc), stepper(rk_type)
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{
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mesh.GetBox (pmin, pmax);
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rad = 0.5 * Dist (pmin, pmax);
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maxlength = (rel_length > 0) ? rel_length : 0.5;
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maxlength *= 2.*rad;
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thickness = (rel_thickness > 0) ? rel_thickness : 0.0015;
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thickness *= 2.*rad;
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double auxtolerance = (rel_tolerance > 0) ? rel_tolerance : 1.5e-3;
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auxtolerance *= 2.*rad;
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stepper.SetTolerance(auxtolerance);
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direction = adirection;
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maxpoints = amaxpoints;
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if(direction == 0)
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{
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maxlength *= 0.5;
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maxpoints /= 2;
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}
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critical_value = -1;
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randomized = false;
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}
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FieldLineCalc :: ~FieldLineCalc() {;}
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void FieldLineCalc :: Calc(const Point<3> & startpoint, Array<Point<3>> & points, Array<double> & vals, Array<bool> & drawelems, Array<int> & dirstart)
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{
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Vec<3> v = 0.0;
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double startlami[3] = {0.0, 0.0, 0.0};
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points.SetSize(0);
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vals.SetSize(0);
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drawelems.SetSize(0);
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dirstart.SetSize(0);
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dirstart.Append(0);
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int startelnr = mesh.GetElementOfPoint(startpoint,startlami,true) - 1;
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(*testout) << "p = " << startpoint << "; elnr = " << startelnr << endl;
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if (startelnr == -1)
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return;
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mesh.SetPointSearchStartElement(startelnr);
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Vec<3> startv;
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bool startdraw = func(startelnr, startlami, startv);
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double startval = startv.Length();
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if(critical_value > 0 && fabs(startval) < critical_value)
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return;
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//cout << "p = " << startpoint << "; elnr = " << startelnr << endl;
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for(int dir = 1; dir >= -1; dir -= 2)
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{
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if(dir*direction < 0) continue;
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points.Append(startpoint);
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vals.Append(startval);
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drawelems.Append(startdraw);
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double h = 0.001*rad/startval; // otherwise no nice lines; should be made accessible from outside
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v = startv;
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if(dir == -1) v *= -1.;
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int elnr = startelnr;
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double lami[3] = { startlami[0], startlami[1], startlami[2]};
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for(double length = 0; length < maxlength; length += h*vals.Last())
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{
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if(v.Length() < 1e-12*rad)
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{
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(*testout) << "Current fieldlinecalculation came to a stillstand at " << points.Last() << endl;
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break;
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}
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double dummyt{0};
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stepper.StartNextValCalc(points.Last(),dummyt,h,true);
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stepper.FeedNextF(v);
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bool drawelem = false;
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Point<3> newp;
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while(!stepper.GetNextData(newp,dummyt,h) && elnr != -1)
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{
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elnr = mesh.GetElementOfPoint(newp,lami,true) - 1;
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if(elnr != -1)
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{
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mesh.SetPointSearchStartElement(elnr);
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drawelem = func(elnr, lami, v);
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if(dir == -1) v *= -1.;
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stepper.FeedNextF(v);
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}
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}
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if (elnr == -1)
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{
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//cout << "direction " <<dir << " reached the wall." << endl;
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break;
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}
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points.Append(newp);
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vals.Append(v.Length());
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drawelems.Append(drawelem);
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if(points.Size() % 40 == 0 && points.Size() > 1)
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(*testout) << "Points in current fieldline: " << points.Size() << ", current position: " << newp << endl;
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if(maxpoints > 0 && points.Size() >= maxpoints)
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{
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break;
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}
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//cout << "length " << length << " h " << h << " vals.Last() " << vals.Last() << " maxlength " << maxlength << endl;
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}
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dirstart.Append(points.Size());
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}
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}
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}
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