private void ThrowError(String s, int index_file, CgnsDriver cg)
{
if (cg.close(index_file) != (int)Error.CG_OK)
{
s = s + " " + cg.get_error();
}
throw new ApplicationException(s);
}
private void ThrowError(CgnsDriver cg)
{
throw new ApplicationException(cg.get_error());
}
/// <summary>
/// loads or saves an adf or hdf5 file from or to a specified path
/// </summary>
/// <param name="filePath"></param>
/// <param name="hdf5"></param>
/// <param name="context"></param>
public void Build(string filePath, bool hdf5, GridData context)
{
using (CgnsDriver cg = new CgnsDriver(hdf5)) {
int index_file = 0;
int index_base = 0;
int index_zone = 0;
int index_section = 0;
char[] basename = new char[100];
char[] zonename = new char[100];
char[] coordnameX = new char[100];
char[] coordnameY = new char[100];
char[] coordnameZ = new char[100];
char[] flow = new char[100];
char[] secname = new char[100];
char[] boconame;
char[] solname = new char[100];
int[,] isize = new int[3, 3];
int[] irmin = new int[3];
int[] irmax = new int[3];
int celldim, physdim; // zone definition
int start, end, nbndry; // element definition
DataType_t data_type;
// some header information
// =======================
basename = "Base".ToNullTermCharAry();
zonename = "Zone".ToNullTermCharAry();
coordnameX = "CoordinateX".ToNullTermCharAry();
coordnameY = "CoordinateY".ToNullTermCharAry();
coordnameZ = "CoordinateZ".ToNullTermCharAry();
flow = "VectorMagnitude".ToNullTermCharAry();
secname = "Section".ToNullTermCharAry();
boconame = "BoundaryCondition".ToNullTermCharAry();
solname = "FlowSolution".ToNullTermCharAry();
data_type = DataType_t.RealDouble;
int index_coord;
int index_flow;
int index_field;
if (cg.open(filePath.ToNullTermCharAry(), (int)Mode.MODE_WRITE, out index_file) != (int)Error.CG_OK)
{
ThrowError(index_file, cg);
}
celldim = physdim = context.Grid.SpatialDimension;
if (cg.base_write(index_file, basename, celldim, physdim, out index_base) != (int)Error.CG_OK)
{
ThrowError(index_file, cg);
}
cg.gopath(index_file, "/Base".ToNullTermCharAry());
cg.descriptor_write("Information".ToNullTermCharAry(), title.ToNullTermCharAry());
GridCommons grd = context.Grid;
ElementType_t bosss_element_type = ElementType_t.ElementTypeNull;
if (grd.RefElements.Length > 1)
{
throw new NotSupportedException("implementation todo");
}
var RefElm = grd.RefElements[0];
if (RefElm.GetType() == typeof(Line))
{
bosss_element_type = ElementType_t.BAR_2;
}
else if (RefElm.GetType() == typeof(Square))
{
bosss_element_type = ElementType_t.QUAD_4;
}
else if (RefElm.GetType() == typeof(Triangle))
{
bosss_element_type = ElementType_t.TRI_3;
}
else if (RefElm.GetType() == typeof(Cube))
{
bosss_element_type = ElementType_t.HEXA_8;
}
else if (RefElm.GetType() == typeof(Tetra))
{
bosss_element_type = ElementType_t.TETRA_4;
}
else
{
ThrowError("Unsupported BoSSS element type", index_file, cg);
}
if (!showJumps)
{
isize[0, 0] = totalVertices;
}
else
{
isize[0, 0] = NoOfCells * verticesPerCell;
}
isize[0, 1] = totalCells;
isize[0, 2] = 0;
if (cg.zone_write(index_file, index_base, zonename, isize, ZoneType_t.Unstructured, out index_zone) != (int)Error.CG_OK)
{
ThrowError(index_file, cg);
}
// write grid vertices
// ===================
double[, ,] x = null;
double[, ,] y = null;
double[, ,] z = null;
if (!showJumps)
{
x = new double[isize[0, 0], 1, 1];
for (int vertex = 0; vertex < isize[0, 0]; vertex++)
{
x[vertex, 0, 0] = vertices[vertex, 0];
}
if (cg.coord_write3(index_file, index_base, index_zone, data_type, coordnameX, x, out index_coord) != (int)Error.CG_OK)
{
ThrowError(index_file, cg);
}
y = new double[isize[0, 0], 1, 1];
for (int vertex = 0; vertex < isize[0, 0]; vertex++)
{
y[vertex, 0, 0] = vertices[vertex, 1];
}
if (cg.coord_write3(index_file, index_base, index_zone, data_type, coordnameY, y, out index_coord) != (int)Error.CG_OK)
{
ThrowError(index_file, cg);
}
if (celldim > 2)
{
z = new double[isize[0, 0], 1, 1];
for (int vertex = 0; vertex < isize[0, 0]; vertex++)
{
z[vertex, 0, 0] = vertices[vertex, 2];
}
if (cg.coord_write3(index_file, index_base, index_zone, data_type, coordnameZ, z, out index_coord) != (int)Error.CG_OK)
{
ThrowError(index_file, cg);
}
}
}
else
{
x = new double[isize[0, 0], 1, 1];
int cnt = 0;
for (int j = 0; j < NoOfCells; j++)
{
for (int i = 0; i < verticesPerCell; i++)
{
x[cnt, 0, 0] = verticeCoordinates[j, i, 0];
cnt++;
}
}
if (cg.coord_write3(index_file, index_base, index_zone, data_type, coordnameX, x, out index_coord) != (int)Error.CG_OK)
{
ThrowError(index_file, cg);
}
y = new double[isize[0, 0], 1, 1];
cnt = 0;
for (int j = 0; j < NoOfCells; j++)
{
for (int i = 0; i < verticesPerCell; i++)
{
y[cnt, 0, 0] = verticeCoordinates[j, i, 1];
cnt++;
}
}
if (cg.coord_write3(index_file, index_base, index_zone, data_type, coordnameY, y, out index_coord) != (int)Error.CG_OK)
{
ThrowError(index_file, cg);
}
if (celldim > 2)
{
z = new double[isize[0, 0], 1, 1];
cnt = 0;
for (int j = 0; j < NoOfCells; j++)
{
for (int i = 0; i < verticesPerCell; i++)
{
z[cnt, 0, 0] = verticeCoordinates[j, i, 2];
cnt++;
}
}
if (cg.coord_write3(index_file, index_base, index_zone, data_type, coordnameZ, z, out index_coord) != (int)Error.CG_OK)
{
ThrowError(index_file, cg);
}
}
}
if (cg.sol_write(index_file, index_base, index_zone, solname, GridLocation_t.Vertex, out index_flow) != (int)Error.CG_OK)
{
ThrowError(index_file, cg);
}
// write DG fields
// ===============
foreach (Field field in fields)
{
calculateField(field);
if (!showJumps)
{
cg.field_write1(index_file, index_base, index_zone, index_flow, data_type, field.ToString().ToNullTermCharAry(), smoothedResult, out index_field);
}
else
{
cg.field_write1(index_file, index_base, index_zone, index_flow, data_type, field.ToString().ToNullTermCharAry(), notSmoothedResult, out index_field);
}
}
// write cell connectivity
// =======================
int[] permutationTable = elementTypeToPermutationTableMap[bosss_element_type];
if (!showJumps)
{
int[,] permutedConnectivity = new int[isize[0, 1], connectivity.GetLength(1)];
for (int i = 0; i < isize[0, 1]; i++)
{
for (int j = 0; j < permutationTable.Length; j++)
{
permutedConnectivity[i, j] = 1 + connectivity[i, permutationTable[j]];
}
}
start = 1;
end = isize[0, 1];
nbndry = 0;
if (cg.section_write2(index_file, index_base, index_zone, secname, bosss_element_type, start, end, nbndry, permutedConnectivity, out index_section) != (int)Error.CG_OK)
{
ThrowError(index_file, cg);
}
}
else
{
int[, ,] permutedConnectivity = new int[NoOfCells, subdivisionsPerCell, permutationTable.Length];
for (int j = 0; j < NoOfCells; j++)
{
for (int jj = 0; jj < subdivisionsPerCell; jj++)
{
for (int i = 0; i < permutationTable.Length; i++)
{
permutedConnectivity[j, jj, i] = 1 + j * verticesPerCell + subdivisionTreeLeaves[jj].GlobalVerticeInd[permutationTable[i]];
}
}
}
start = 1;
end = isize[0, 1];
nbndry = 0;
if (cg.section_write3(index_file, index_base, index_zone, secname, bosss_element_type, start, end, nbndry, permutedConnectivity, out index_section) != (int)Error.CG_OK)
{
ThrowError(index_file, cg);
}
}
if (cg.close(index_file) != (int)Error.CG_OK)
{
ThrowError(cg);
}
}
}
