/* This example illustrates using separate grid * and solution files. */ #include "TECIO.h" #include "MASTER.h" /* for defintion of NULL */ int main() { /* DOCSTART:gridsolution_grid_tecini.txt*/ INTEGER4 I; /* use to check return values */ INTEGER4 Debug = 1; INTEGER4 VIsDouble = 0; INTEGER4 FileType = 1; /* 1 = grid file. */ I = TECINI112((char*)"Example: Separate grid and solution files", (char*)"X Y Z", /* Defines the variables for the data file. * Each zone must contain each of the vars * listed here. The order of the variables * in the list is used to define the * variable number (e.g. X is Variable 1). * When referring to variables in other * TecIO functions, you will refer to the * variable by its number. */ (char*)"grid.plt", (char*)".", /* scratch directory */ &FileType, &Debug, &VIsDouble); /* DOCEND */ /* DOCSTART:gridsolution_grid_teczne.txt*/ /* TECZNE Parameters */ INTEGER4 ZoneType = 7; /* FE Polyhedron */ INTEGER4 NumPts = 20; /* the number of unique * nodes in the zone. */ INTEGER4 NumElems = 1; INTEGER4 NumFaces = 12; /* the number of unique * faces in the zone. */ INTEGER4 ICellMax = 0; /* not used */ INTEGER4 JCellMax = 0; /* not used */ INTEGER4 KCellMax = 0; /* not used */ double SolutionTime = 0.0; INTEGER4 StrandID = 1; /* time strand for * unsteady solution. */ INTEGER4 ParentZone = 0; INTEGER4 IsBlock = 1; INTEGER4 NumFaceConnections = 0; INTEGER4 FaceNeighborMode = 1; INTEGER4 SharConn = 0; /* For this zone, the total number of face nodes is * five times number of faces, because each face * is a pentagon. */ INTEGER4 TotalNumFaceNodes = 5 * NumFaces; /* This zone has no connected boundary faces. */ INTEGER4 TotalNumBndryFaces = 0; INTEGER4 TotalNumBndryConns = 0; I = TECZNE112((char*)"Dodecahedron", /* Name of the zone. */ &ZoneType, &NumPts, &NumElems, &NumFaces, &ICellMax, &JCellMax, &KCellMax, &SolutionTime, &StrandID, &ParentZone, &IsBlock, &NumFaceConnections, &FaceNeighborMode, &TotalNumFaceNodes, &TotalNumBndryFaces, &TotalNumBndryConns, NULL, NULL, /* All nodal variables */ NULL, &SharConn); /* DOCEND */ /* DOCSTART:gridsolution_grid_tecdat.txt*/ /* TECDAT Parameters */ double Phi = 0.5 * (1.0 + sqrt(5.0)); double Pi = 3.141592653578; double *X = new double[NumPts]; double *Y = new double[NumPts]; double *Z = new double[NumPts]; int Count = 0; for(int J = 0; J <= 4; J++) { X[Count] = 2.0 * cos(2.0 / 5.0 * Pi * J); Y[Count] = 2.0 * sin(2.0 / 5.0 * Pi * J); Z[Count] = Phi + 1.0; Count++; X[Count] = -X[Count - 1]; Y[Count] = -Y[Count - 1]; Z[Count] = -Z[Count - 1]; Count++; X[Count] = 2.0 * Phi * cos(2.0 / 5.0 * Pi * J); Y[Count] = 2.0 * Phi * sin(2.0 / 5.0 * Pi * J); Z[Count] = Phi - 1.0; Count++; X[Count] = -X[Count - 1]; Y[Count] = -Y[Count - 1]; Z[Count] = -Z[Count - 1]; Count++; } INTEGER4 IsDouble = 1; I = TECDAT112(&NumPts, X, &IsDouble); I = TECDAT112(&NumPts, Y, &IsDouble); I = TECDAT112(&NumPts, Z, &IsDouble); delete X; delete Y; delete Z; /* DOCEND */ /* DOCSTART:gridsolution_grid_facenodes.txt*/ /* TecPoly Parameters */ /* Create a FaceNodes array, dimensioned by the total number * of face nodes in the zone. */ INTEGER4 *FaceNodes = new INTEGER4[TotalNumFaceNodes]; int n = 0; /* Face Nodes for face 1 of the dodecahedron */ FaceNodes[n++] = 2; FaceNodes[n++] = 6; FaceNodes[n++] = 10; FaceNodes[n++] = 14; FaceNodes[n++] = 18; /* Face Nodes for face 2 */ FaceNodes[n++] = 6; FaceNodes[n++] = 8; FaceNodes[n++] = 19; FaceNodes[n++] = 12; FaceNodes[n++] = 10; /* Face Nodes for face 3 */ FaceNodes[n++] = 3; FaceNodes[n++] = 12; FaceNodes[n++] = 10; FaceNodes[n++] = 14; FaceNodes[n++] = 16; /* Face Nodes for face 4 */ FaceNodes[n++] = 7; FaceNodes[n++] = 16; FaceNodes[n++] = 14; FaceNodes[n++] = 18; FaceNodes[n++] = 20; /* Face Nodes for face 5 */ FaceNodes[n++] = 2; FaceNodes[n++] = 4; FaceNodes[n++] = 11; FaceNodes[n++] = 20; FaceNodes[n++] = 18; /* Face Nodes for face 6 */ FaceNodes[n++] = 2; FaceNodes[n++] = 4; FaceNodes[n++] = 15; FaceNodes[n++] = 8; FaceNodes[n++] = 6; /* Face Nodes for face 7 */ FaceNodes[n++] = 1; FaceNodes[n++] = 3; FaceNodes[n++] = 12; FaceNodes[n++] = 19; FaceNodes[n++] = 17; /* Face Nodes for face 8 */ FaceNodes[n++] = 1; FaceNodes[n++] = 3; FaceNodes[n++] = 16; FaceNodes[n++] = 7; FaceNodes[n++] = 5; /* Face Nodes for face 9 */ FaceNodes[n++] = 5; FaceNodes[n++] = 7; FaceNodes[n++] = 20; FaceNodes[n++] = 11; FaceNodes[n++] = 9; /* Face Nodes for face 10 */ FaceNodes[n++] = 4; FaceNodes[n++] = 11; FaceNodes[n++] = 9; FaceNodes[n++] = 13; FaceNodes[n++] = 15; /* Face Nodes for face 11 */ FaceNodes[n++] = 8; FaceNodes[n++] = 15; FaceNodes[n++] = 13; FaceNodes[n++] = 17; FaceNodes[n++] = 19; /* Face Nodes for face 12 */ FaceNodes[n++] = 1; FaceNodes[n++] = 5; FaceNodes[n++] = 9; FaceNodes[n++] = 13; FaceNodes[n++] = 17; /* DOCEND */ /* Specify the number of nodes for each face, and the right and * left neighboring elements. The neighboring elements can be * determined using the right-hand rule. For each face, curl * the fingers of your right hand in the direction of * incrementing node numbers (i.e. from Node 1 to Node 2 and * so on). Your thumb will point toward the right element. * A value of zero indicates that there is no * neighboring element on that side. A negative value * indicates that the neighboring element is in another zone. * In that case, the number is a pointer into the * FaceBndryConnectionElems and FaceBndryConnectionZones arrays. */ /* DOCSTART:gridsolution_grid_tecpoly.txt*/ INTEGER4 *FaceNodeCounts = new INTEGER4[NumFaces]; INTEGER4 *FaceLeftElems = new INTEGER4[NumFaces]; INTEGER4 *FaceRightElems = new INTEGER4[NumFaces]; /* For this particular zone, each face has the 5 nodes. */ for(int J = 0; J < NumFaces; J++) FaceNodeCounts[J] = 5; /* Set the right and left elements for each face. */ FaceRightElems[0] = 1; FaceRightElems[1] = 1; FaceRightElems[2] = 0; FaceRightElems[3] = 0; FaceRightElems[4] = 0; FaceRightElems[5] = 1; FaceRightElems[6] = 1; FaceRightElems[7] = 0; FaceRightElems[8] = 0; FaceRightElems[9] = 1; FaceRightElems[10] = 1; FaceRightElems[11] = 0; FaceLeftElems[0] = 0; FaceLeftElems[1] = 0; FaceLeftElems[2] = 1; FaceLeftElems[3] = 1; FaceLeftElems[4] = 1; FaceLeftElems[5] = 0; FaceLeftElems[6] = 0; FaceLeftElems[7] = 1; FaceLeftElems[8] = 1; FaceLeftElems[9] = 0; FaceLeftElems[10] = 0; FaceLeftElems[11] = 1; I = TECPOLY112(FaceNodeCounts, FaceNodes, FaceLeftElems, FaceRightElems, NULL, /* No boundary connections. */ NULL, NULL); delete FaceNodes; delete FaceLeftElems; delete FaceRightElems; /* DOCEND */ /* DOCSTART:gridsolution_grid_tecend.txt*/ I = TECEND112(); /* DOCEND */ /* DOCSTART:gridsolution_solution_tecini.txt*/ for(int J = 0; J < 5; J++) { char SolutionFileName[128]; sprintf(SolutionFileName, "solution%d.plt", J); /* DOCSTART:gridsolution_solution_tecini.txt*/ FileType = 2; /* 1 = solution file. */ I = TECINI112((char*)"Example: Separate grid and solution files", (char*)"P T", /* Defines the variables for the solution file. * Note that these are different variables from * the grid file. */ SolutionFileName, (char*)".", /* scratch directory */ &FileType, &Debug, &VIsDouble); /* DOCEND */ /* DOCSTART:gridsolution_solution_teczne.txt*/ /* TECZNE Parameters are mostly unchanged from creation of the grid file. */ TotalNumFaceNodes = 0; SolutionTime = J; char ZoneName[128]; sprintf(ZoneName, "Dodecahedron Time=%g", SolutionTime); I = TECZNE112(ZoneName, &ZoneType, &NumPts, &NumElems, &NumFaces, &ICellMax, &JCellMax, &KCellMax, &SolutionTime, &StrandID, &ParentZone, &IsBlock, &NumFaceConnections, &FaceNeighborMode, &TotalNumFaceNodes, &TotalNumBndryFaces, &TotalNumBndryConns, NULL, NULL, /* All nodal variables */ NULL, &SharConn); /* DOCEND */ /* DOCSTART:gridsolution_solution_tecdat.txt*/ /* TECDAT Parameters */ double *P = new double[NumPts]; double *T = new double[NumPts]; for(int K = 0; K < NumPts; K++) { P[K] = (double)(K + J); T[K] = 1.0 + K + K; } I = TECDAT112(&NumPts, P, &IsDouble); I = TECDAT112(&NumPts, T, &IsDouble); delete P; delete T; /* DOCEND */ /* DOCSTART:gridsolution_solution_tecend.txt*/ I = TECEND112(); /* DOCEND */ } return 0; }