12 inFile >> NumberOfPoints[0] >> NumberOfPoints[1] >> NumberOfPoints[2];
13 inFile >> ReferencePoint[0] >> ReferencePoint[1] >> ReferencePoint[2];
14 inFile >> BasicDistance0[0] >> BasicDistance0[1] >> BasicDistance0[2];
17 inFile >> NumberOfPoints[0] >> NumberOfPoints[1] >> NumberOfPoints[2];
18 inFile >> ReferencePoint[0] >> ReferencePoint[1] >> ReferencePoint[2];
19 inFile >> BasicDistance0[0] >> BasicDistance0[1] >> BasicDistance0[2];
20 inFile >> BasicDistance1[0][0] >> BasicDistance1[1][0] >> BasicDistance1[2][0];
21 inFile >> BasicDistance1[0][1] >> BasicDistance1[1][1] >> BasicDistance1[2][1];
22 inFile >> BasicDistance1[0][2] >> BasicDistance1[1][2] >> BasicDistance1[2][2];
23 inFile >> BasicDistance2[0][0] >> BasicDistance2[1][0] >> BasicDistance2[2][0];
24 inFile >> BasicDistance2[0][1] >> BasicDistance2[1][1] >> BasicDistance2[2][1];
25 inFile >> BasicDistance2[0][2] >> BasicDistance2[1][2] >> BasicDistance2[2][2];
26 inFile >> EasyCoordinate[0] >> EasyCoordinate[1] >> EasyCoordinate[2];
29 inFile >> NumberOfPoints[0] >> NumberOfPoints[1] >> NumberOfPoints[2];
30 inFile >> ReferencePoint[0] >> ReferencePoint[1] >> ReferencePoint[2];
31 inFile >> BasicDistance0[0] >> BasicDistance0[1] >> BasicDistance0[2];
34 inFile >> NumberOfPoints[0] >> NumberOfPoints[1] >> NumberOfPoints[2];
35 inFile >> ReferencePoint[0] >> ReferencePoint[1] >> ReferencePoint[2];
36 inFile >> BasicDistance0[0] >> BasicDistance0[1] >> BasicDistance0[2];
37 inFile >> BasicDistance1[0][0] >> BasicDistance1[1][0] >> BasicDistance1[2][0];
38 inFile >> BasicDistance1[0][1] >> BasicDistance1[1][1] >> BasicDistance1[2][1];
39 inFile >> BasicDistance1[0][2] >> BasicDistance1[1][2] >> BasicDistance1[2][2];
40 inFile >> BasicDistance2[0][0] >> BasicDistance2[1][0] >> BasicDistance2[2][0];
41 inFile >> BasicDistance2[0][1] >> BasicDistance2[1][1] >> BasicDistance2[2][1];
42 inFile >> BasicDistance2[0][2] >> BasicDistance2[1][2] >> BasicDistance2[2][2];
43 inFile >> EasyCoordinate[0] >> EasyCoordinate[1] >> EasyCoordinate[2];
46 inFile >> NumberOfPoints[0] >> NumberOfPoints[1] >> NumberOfPoints[2];
47 inFile >> ReferencePoint[0] >> ReferencePoint[1] >> ReferencePoint[2];
48 inFile >> BasicDistance0[0] >> BasicDistance0[1] >> BasicDistance0[2];
49 inFile >> RParAsFunOfPhi[0] >> RParAsFunOfPhi[1] >> RParAsFunOfPhi[2] >> RParAsFunOfPhi[3];
55 int nLines = NumberOfPoints[0]*NumberOfPoints[1]*NumberOfPoints[2];
56 FieldValues.reserve(nLines);
58 for (
int iLine=0; iLine<
nLines; ++iLine){
59 inFile >> Bx >> By >> Bz;
60 FieldEntry.
putB3(Bx,By,Bz);
61 FieldValues.push_back(FieldEntry);
67 if (lastEntry !=
"complete"){
69 cout <<
"error during file reading: file is not complete" << endl;
78 if (type == 0)
cout <<
" grid type = " << type <<
" --> not determined" << endl;
79 if (type == 1)
cout <<
" grid type = " << type <<
" --> (x,y,z) cube" << endl;
80 if (type == 2)
cout <<
" grid type = " << type <<
" --> (x,y,z) trapezoid" << endl;
81 if (type == 3)
cout <<
" grid type = " << type <<
" --> (r,phi,z) cube" << endl;
82 if (type == 4)
cout <<
" grid type = " << type <<
" --> (r,phi,z) trapezoid" << endl;
83 if (type == 5)
cout <<
" grid type = " << type <<
" --> (r,phi,z) 1/sin(phi)" << endl;
89 double dB[3] = {0.,0.,0.};
94 putCoordGetInd(X1,X2,X3,index[0],index[1],index[2]);
95 int index0[3] = {0,0,0};
96 int index1[3] = {0,0,0};
97 for (
int i=0;
i<3; ++
i){
98 if (NumberOfPoints[
i] > 1){
99 index0[
i] =
max(0,index[
i]);
100 if (index0[i] > NumberOfPoints[i]-2) index0[
i] = NumberOfPoints[
i]-2;
101 index1[
i] =
max(1,index[i]+1);
102 if (index1[i] > NumberOfPoints[i]-1) index1[
i] = NumberOfPoints[
i]-1;
109 putIndicesGetB(index0[0],index0[1],index0[2],tmpB[0],tmpB[1],tmpB[2]);
110 putIndGetCoord(index0[0],index0[1],index0[2],tmpX[0],tmpX[1],tmpX[2]);
111 MagInterpol.
defineCellPoint000(tmpX[0],tmpX[1],tmpX[2],
double(tmpB[0]),
double(tmpB[1]),
double(tmpB[2]));
112 putIndicesGetB(index1[0],index0[1],index0[2],tmpB[0],tmpB[1],tmpB[2]);
113 putIndGetCoord(index1[0],index0[1],index0[2],tmpX[0],tmpX[1],tmpX[2]);
114 MagInterpol.
defineCellPoint100(tmpX[0],tmpX[1],tmpX[2],
double(tmpB[0]),
double(tmpB[1]),
double(tmpB[2]));
115 putIndicesGetB(index0[0],index1[1],index0[2],tmpB[0],tmpB[1],tmpB[2]);
116 putIndGetCoord(index0[0],index1[1],index0[2],tmpX[0],tmpX[1],tmpX[2]);
117 MagInterpol.
defineCellPoint010(tmpX[0],tmpX[1],tmpX[2],
double(tmpB[0]),
double(tmpB[1]),
double(tmpB[2]));
118 putIndicesGetB(index1[0],index1[1],index0[2],tmpB[0],tmpB[1],tmpB[2]);
119 putIndGetCoord(index1[0],index1[1],index0[2],tmpX[0],tmpX[1],tmpX[2]);
120 MagInterpol.
defineCellPoint110(tmpX[0],tmpX[1],tmpX[2],
double(tmpB[0]),
double(tmpB[1]),
double(tmpB[2]));
121 putIndicesGetB(index0[0],index0[1],index1[2],tmpB[0],tmpB[1],tmpB[2]);
122 putIndGetCoord(index0[0],index0[1],index1[2],tmpX[0],tmpX[1],tmpX[2]);
123 MagInterpol.
defineCellPoint001(tmpX[0],tmpX[1],tmpX[2],
double(tmpB[0]),
double(tmpB[1]),
double(tmpB[2]));
124 putIndicesGetB(index1[0],index0[1],index1[2],tmpB[0],tmpB[1],tmpB[2]);
125 putIndGetCoord(index1[0],index0[1],index1[2],tmpX[0],tmpX[1],tmpX[2]);
126 MagInterpol.
defineCellPoint101(tmpX[0],tmpX[1],tmpX[2],
double(tmpB[0]),
double(tmpB[1]),
double(tmpB[2]));
127 putIndicesGetB(index0[0],index1[1],index1[2],tmpB[0],tmpB[1],tmpB[2]);
128 putIndGetCoord(index0[0],index1[1],index1[2],tmpX[0],tmpX[1],tmpX[2]);
129 MagInterpol.
defineCellPoint011(tmpX[0],tmpX[1],tmpX[2],
double(tmpB[0]),
double(tmpB[1]),
double(tmpB[2]));
130 putIndicesGetB(index1[0],index1[1],index1[2],tmpB[0],tmpB[1],tmpB[2]);
131 putIndGetCoord(index1[0],index1[1],index1[2],tmpX[0],tmpX[1],tmpX[2]);
132 MagInterpol.
defineCellPoint111(tmpX[0],tmpX[1],tmpX[2],
double(tmpB[0]),
double(tmpB[1]),
double(tmpB[2]));
146 double pnt[3] = {X1,X2,X3};
150 for (
int i=0;
i<3; ++
i){
151 index[
i] = int((pnt[
i]-ReferencePoint[
i])/BasicDistance0[i]);
156 for (
int i=0;
i<3; ++
i){
157 if (EasyCoordinate[
i]){
158 index[
i] = int((pnt[i]-ReferencePoint[i])/BasicDistance0[i]);
161 for (
int i=0;
i<3; ++
i){
162 if (!EasyCoordinate[
i]){
163 double stepSize = BasicDistance0[
i];
165 for (
int j=0;
j<3; ++
j){
166 stepSize += BasicDistance1[
i][
j]*index[
j];
167 offset += BasicDistance2[
i][
j]*index[
j];
169 index[
i] = int((pnt[i]-(ReferencePoint[i] + offset))/stepSize);
174 for (
int i=0;
i<3; ++
i){
175 index[
i] = int((pnt[
i]-ReferencePoint[
i])/BasicDistance0[i]);
180 for (
int i=0;
i<3; ++
i){
181 if (EasyCoordinate[
i]){
182 index[
i] = int((pnt[i]-ReferencePoint[i])/BasicDistance0[i]);
185 for (
int i=0;
i<3; ++
i){
186 if (!EasyCoordinate[
i]){
187 double stepSize = BasicDistance0[
i];
189 for (
int j=0;
j<3; ++
j){
190 stepSize += BasicDistance1[
i][
j]*index[
j];
191 offset += BasicDistance2[
i][
j]*index[
j];
193 index[
i] = int((pnt[i]-(ReferencePoint[i] + offset))/stepSize);
198 double sinPhi =
sin(pnt[1]);
199 double stepSize = RParAsFunOfPhi[0] + RParAsFunOfPhi[1]/sinPhi - RParAsFunOfPhi[2] - RParAsFunOfPhi[3]/sinPhi;
200 stepSize = stepSize/(NumberOfPoints[0]-1);
201 double startingPoint = RParAsFunOfPhi[2] + RParAsFunOfPhi[3]/sinPhi;
202 index[0] = int((pnt[0]-startingPoint)/stepSize);
203 index[1] = int((pnt[1]-ReferencePoint[1])/BasicDistance0[1]);
204 index[2] = int((pnt[2]-ReferencePoint[2])/BasicDistance0[2]);
215 FieldEntry = FieldValues.operator[](lineNumber(Index1, Index2, Index3));
216 Bx = FieldEntry.
bx();
217 By = FieldEntry.
by();
218 Bz = FieldEntry.
bz();
224 int index[3] = {Index1, Index2, Index3};
228 for (
int i=0;
i<3; ++
i){
229 pnt[
i] = ReferencePoint[
i] + BasicDistance0[
i]*index[
i];
233 for (
int i=0;
i<3; ++
i){
234 if (EasyCoordinate[
i]){
235 pnt[
i] = ReferencePoint[
i] + BasicDistance0[
i]*index[
i];
238 double stepSize = BasicDistance0[
i];
240 for (
int j=0;
j<3; ++
j){
241 stepSize += BasicDistance1[
i][
j]*index[
j];
242 offset += BasicDistance2[
i][
j]*index[
j];
244 pnt[
i] = ReferencePoint[
i] + offset + stepSize*index[
i];
249 for (
int i=0;
i<3; ++
i){
250 pnt[
i] = ReferencePoint[
i] + BasicDistance0[
i]*index[
i];
254 for (
int i=0;
i<3; ++
i){
255 if (EasyCoordinate[
i]){
256 pnt[
i] = ReferencePoint[
i] + BasicDistance0[
i]*index[
i];
259 double stepSize = BasicDistance0[
i];
261 for (
int j=0;
j<3; ++
j){
262 stepSize += BasicDistance1[
i][
j]*index[
j];
263 offset += BasicDistance2[
i][
j]*index[
j];
265 pnt[
i] = ReferencePoint[
i] + offset + stepSize*index[
i];
270 pnt[2] = ReferencePoint[2] + BasicDistance0[2]*index[2];
271 pnt[1] = ReferencePoint[1] + BasicDistance0[1]*index[1];
272 double sinPhi =
sin(pnt[1]);
273 double stepSize = RParAsFunOfPhi[0] + RParAsFunOfPhi[1]/sinPhi - RParAsFunOfPhi[2] - RParAsFunOfPhi[3]/sinPhi;
274 stepSize = stepSize/(NumberOfPoints[0]-1);
275 double startingPoint = RParAsFunOfPhi[2] + RParAsFunOfPhi[3]/sinPhi;
276 pnt[0] = startingPoint + stepSize*index[0];
286 return Index1*NumberOfPoints[1]*NumberOfPoints[2] + Index2*NumberOfPoints[2] + Index3;
void load(const std::string &name)
load grid binary file
void putCoordGetInd(double X1, double X2, double X3, int &Index1, int &Index2, int &Index3)
void defineCellPoint100(double X1, double X2, double X3, double F1, double F2, double F3)
void putB3(float Bx, float By, float Bz)
Sin< T >::type sin(const T &t)
int gridType()
returns value of GridType (and eventually prints the type + short description)
void defineCellPoint110(double X1, double X2, double X3, double F1, double F2, double F3)
void putIndGetCoord(int Index1, int Index2, int Index3, double &X1, double &X2, double &X3)
void defineCellPoint101(double X1, double X2, double X3, double F1, double F2, double F3)
void putSCoordGetVField(double X1, double X2, double X3, double &F1, double &F2, double &F3)
receive the interpolated field (out) at any point in space (in)
void defineCellPoint010(double X1, double X2, double X3, double F1, double F2, double F3)
int lineNumber(int Index1, int Index2, int Index3)
void defineCellPoint111(double X1, double X2, double X3, double F1, double F2, double F3)
unsigned int offset(bool)
void defineCellPoint000(double X1, double X2, double X3, double F1, double F2, double F3)
provide the interpolation algorithm with 8 points, where the field is known (in)
void putIndicesGetB(int Index1, int Index2, int Index3, float &Bx, float &By, float &Bz)
void defineCellPoint001(double X1, double X2, double X3, double F1, double F2, double F3)
void defineCellPoint011(double X1, double X2, double X3, double F1, double F2, double F3)
void interpolateAtPoint(double X1, double X2, double X3, float &Bx, float &By, float &Bz)
interpolates the magnetic field at input coordinate point and returns field values ...