/* * * Template Numerical Toolkit (TNT) * * Mathematical and Computational Sciences Division * National Institute of Technology, * Gaithersburg, MD USA * * * This software was developed at the National Institute of Standards and * Technology (NIST) by employees of the Federal Government in the course * of their official duties. Pursuant to title 17 Section 105 of the * United States Code, this software is not subject to copyright protection * and is in the public domain. NIST assumes no responsibility whatsoever for * its use by other parties, and makes no guarantees, expressed or implied, * about its quality, reliability, or any other characteristic. * */ #ifndef TNT_FORTRAN_ARRAY3D_UTILS_H #define TNT_FORTRAN_ARRAY3D_UTILS_H #include #include namespace TNT { template std::ostream& operator<<(std::ostream &s, const Fortran_Array3D &A) { int M=A.dim1(); int N=A.dim2(); int K=A.dim3(); s << M << " " << N << " " << K << "\n"; for (int i=1; i<=M; i++) { for (int j=1; j<=N; j++) { for (int k=1; k<=K; k++) s << A(i,j,k) << " "; s << "\n"; } s << "\n"; } return s; } template std::istream& operator>>(std::istream &s, Fortran_Array3D &A) { int M, N, K; s >> M >> N >> K; Fortran_Array3D B(M,N,K); for (int i=1; i<=M; i++) for (int j=1; j<=N; j++) for (int k=1; k<=K; k++) s >> B(i,j,k); A = B; return s; } template Fortran_Array3D operator+(const Fortran_Array3D &A, const Fortran_Array3D &B) { int m = A.dim1(); int n = A.dim2(); int p = A.dim3(); if (B.dim1() != m || B.dim2() != n || B.dim3() != p ) return Fortran_Array3D(); else { Fortran_Array3D C(m,n,p); for (int i=1; i<=m; i++) for (int j=1; j<=n; j++) for (int k=1; k<=p; k++) C(i,j,k) = A(i,j,k)+ B(i,j,k); return C; } } template Fortran_Array3D operator-(const Fortran_Array3D &A, const Fortran_Array3D &B) { int m = A.dim1(); int n = A.dim2(); int p = A.dim3(); if (B.dim1() != m || B.dim2() != n || B.dim3() != p ) return Fortran_Array3D(); else { Fortran_Array3D C(m,n,p); for (int i=1; i<=m; i++) for (int j=1; j<=n; j++) for (int k=1; k<=p; k++) C(i,j,k) = A(i,j,k)- B(i,j,k); return C; } } template Fortran_Array3D operator*(const Fortran_Array3D &A, const Fortran_Array3D &B) { int m = A.dim1(); int n = A.dim2(); int p = A.dim3(); if (B.dim1() != m || B.dim2() != n || B.dim3() != p ) return Fortran_Array3D(); else { Fortran_Array3D C(m,n,p); for (int i=1; i<=m; i++) for (int j=1; j<=n; j++) for (int k=1; k<=p; k++) C(i,j,k) = A(i,j,k)* B(i,j,k); return C; } } template Fortran_Array3D operator/(const Fortran_Array3D &A, const Fortran_Array3D &B) { int m = A.dim1(); int n = A.dim2(); int p = A.dim3(); if (B.dim1() != m || B.dim2() != n || B.dim3() != p ) return Fortran_Array3D(); else { Fortran_Array3D C(m,n,p); for (int i=1; i<=m; i++) for (int j=1; j<=n; j++) for (int k=1; k<=p; k++) C(i,j,k) = A(i,j,k)/ B(i,j,k); return C; } } template Fortran_Array3D& operator+=(Fortran_Array3D &A, const Fortran_Array3D &B) { int m = A.dim1(); int n = A.dim2(); int p = A.dim3(); if (B.dim1() == m && B.dim2() == n && B.dim3() == p ) { for (int i=1; i<=m; i++) for (int j=1; j<=n; j++) for (int k=1; k<=p; k++) A(i,j,k) += B(i,j,k); } return A; } template Fortran_Array3D& operator-=(Fortran_Array3D &A, const Fortran_Array3D &B) { int m = A.dim1(); int n = A.dim2(); int p = A.dim3(); if (B.dim1() == m && B.dim2() == n && B.dim3() == p ) { for (int i=1; i<=m; i++) for (int j=1; j<=n; j++) for (int k=1; k<=p; k++) A(i,j,k) -= B(i,j,k); } return A; } template Fortran_Array3D& operator*=(Fortran_Array3D &A, const Fortran_Array3D &B) { int m = A.dim1(); int n = A.dim2(); int p = A.dim3(); if (B.dim1() == m && B.dim2() == n && B.dim3() == p ) { for (int i=1; i<=m; i++) for (int j=1; j<=n; j++) for (int k=1; k<=p; k++) A(i,j,k) *= B(i,j,k); } return A; } template Fortran_Array3D& operator/=(Fortran_Array3D &A, const Fortran_Array3D &B) { int m = A.dim1(); int n = A.dim2(); int p = A.dim3(); if (B.dim1() == m && B.dim2() == n && B.dim3() == p ) { for (int i=1; i<=m; i++) for (int j=1; j<=n; j++) for (int k=1; k<=p; k++) A(i,j,k) /= B(i,j,k); } return A; } } // namespace TNT #endif