Mercurial > hg > segmenter-vamp-plugin
view armadillo-2.4.4/include/armadillo_bits/op_cx_scalar_meat.hpp @ 0:8b6102e2a9b0
Armadillo Library
| author | maxzanoni76 <max.zanoni@eecs.qmul.ac.uk> |
|---|---|
| date | Wed, 11 Apr 2012 09:27:06 +0100 |
| parents | |
| children |
line wrap: on
line source
// Copyright (C) 2008-2010 NICTA (www.nicta.com.au) // Copyright (C) 2008-2010 Conrad Sanderson // // This file is part of the Armadillo C++ library. // It is provided without any warranty of fitness // for any purpose. You can redistribute this file // and/or modify it under the terms of the GNU // Lesser General Public License (LGPL) as published // by the Free Software Foundation, either version 3 // of the License or (at your option) any later version. // (see http://www.opensource.org/licenses for more info) //! \addtogroup op_cx_scalar //! @{ template<typename T1> inline void op_cx_scalar_times::apply ( Mat< typename std::complex<typename T1::pod_type> >& out, const mtOp<typename std::complex<typename T1::pod_type>, T1, op_cx_scalar_times>& X ) { arma_extra_debug_sigprint(); typedef typename std::complex<typename T1::pod_type> eT; typedef typename T1::pod_type T; const Proxy<T1> A(X.m); out.set_size(A.get_n_rows(), A.get_n_cols()); const eT k = X.aux_out_eT; const uword n_elem = out.n_elem; eT* out_mem = out.memptr(); for(uword i=0; i<n_elem; ++i) { out_mem[i] = A[i] * k; } } template<typename T1> inline void op_cx_scalar_plus::apply ( Mat< typename std::complex<typename T1::pod_type> >& out, const mtOp<typename std::complex<typename T1::pod_type>, T1, op_cx_scalar_plus>& X ) { arma_extra_debug_sigprint(); typedef typename std::complex<typename T1::pod_type> eT; typedef typename T1::pod_type T; const Proxy<T1> A(X.m); out.set_size(A.get_n_rows(), A.get_n_cols()); const eT k = X.aux_out_eT; const uword n_elem = out.n_elem; eT* out_mem = out.memptr(); for(uword i=0; i<n_elem; ++i) { out_mem[i] = A[i] + k; } } template<typename T1> inline void op_cx_scalar_minus_pre::apply ( Mat< typename std::complex<typename T1::pod_type> >& out, const mtOp<typename std::complex<typename T1::pod_type>, T1, op_cx_scalar_minus_pre>& X ) { arma_extra_debug_sigprint(); typedef typename std::complex<typename T1::pod_type> eT; typedef typename T1::pod_type T; const Proxy<T1> A(X.m); out.set_size(A.get_n_rows(), A.get_n_cols()); const eT k = X.aux_out_eT; const uword n_elem = out.n_elem; eT* out_mem = out.memptr(); for(uword i=0; i<n_elem; ++i) { out_mem[i] = k - A[i]; } } template<typename T1> inline void op_cx_scalar_minus_post::apply ( Mat< typename std::complex<typename T1::pod_type> >& out, const mtOp<typename std::complex<typename T1::pod_type>, T1, op_cx_scalar_minus_post>& X ) { arma_extra_debug_sigprint(); typedef typename std::complex<typename T1::pod_type> eT; typedef typename T1::pod_type T; const Proxy<T1> A(X.m); out.set_size(A.get_n_rows(), A.get_n_cols()); const eT k = X.aux_out_eT; const uword n_elem = out.n_elem; eT* out_mem = out.memptr(); for(uword i=0; i<n_elem; ++i) { out_mem[i] = A[i] - k; } } template<typename T1> inline void op_cx_scalar_div_pre::apply ( Mat< typename std::complex<typename T1::pod_type> >& out, const mtOp<typename std::complex<typename T1::pod_type>, T1, op_cx_scalar_div_pre>& X ) { arma_extra_debug_sigprint(); typedef typename std::complex<typename T1::pod_type> eT; typedef typename T1::pod_type T; const Proxy<T1> A(X.m); out.set_size(A.get_n_rows(), A.get_n_cols()); const eT k = X.aux_out_eT; const uword n_elem = out.n_elem; eT* out_mem = out.memptr(); for(uword i=0; i<n_elem; ++i) { out_mem[i] = k / A[i]; } } template<typename T1> inline void op_cx_scalar_div_post::apply ( Mat< typename std::complex<typename T1::pod_type> >& out, const mtOp<typename std::complex<typename T1::pod_type>, T1, op_cx_scalar_div_post>& X ) { arma_extra_debug_sigprint(); typedef typename std::complex<typename T1::pod_type> eT; typedef typename T1::pod_type T; const Proxy<T1> A(X.m); out.set_size(A.get_n_rows(), A.get_n_cols()); const eT k = X.aux_out_eT; const uword n_elem = out.n_elem; eT* out_mem = out.memptr(); for(uword i=0; i<n_elem; ++i) { out_mem[i] = A[i] / k; } } // // // template<typename T1> inline void op_cx_scalar_times::apply ( Cube< typename std::complex<typename T1::pod_type> >& out, const mtOpCube<typename std::complex<typename T1::pod_type>, T1, op_cx_scalar_times>& X ) { arma_extra_debug_sigprint(); typedef typename std::complex<typename T1::pod_type> eT; typedef typename T1::pod_type T; const ProxyCube<T1> A(X.m); out.set_size(A.get_n_rows(), A.get_n_cols(), A.get_n_slices()); const eT k = X.aux_out_eT; const uword n_elem = out.n_elem; eT* out_mem = out.memptr(); for(uword i=0; i<n_elem; ++i) { out_mem[i] = A[i] * k; } } template<typename T1> inline void op_cx_scalar_plus::apply ( Cube< typename std::complex<typename T1::pod_type> >& out, const mtOpCube<typename std::complex<typename T1::pod_type>, T1, op_cx_scalar_plus>& X ) { arma_extra_debug_sigprint(); typedef typename std::complex<typename T1::pod_type> eT; typedef typename T1::pod_type T; const ProxyCube<T1> A(X.m); out.set_size(A.get_n_rows(), A.get_n_cols(), A.get_n_slices()); const eT k = X.aux_out_eT; const uword n_elem = out.n_elem; eT* out_mem = out.memptr(); for(uword i=0; i<n_elem; ++i) { out_mem[i] = A[i] + k; } } template<typename T1> inline void op_cx_scalar_minus_pre::apply ( Cube< typename std::complex<typename T1::pod_type> >& out, const mtOpCube<typename std::complex<typename T1::pod_type>, T1, op_cx_scalar_minus_pre>& X ) { arma_extra_debug_sigprint(); typedef typename std::complex<typename T1::pod_type> eT; typedef typename T1::pod_type T; const ProxyCube<T1> A(X.m); out.set_size(A.get_n_rows(), A.get_n_cols(), A.get_n_slices()); const eT k = X.aux_out_eT; const uword n_elem = out.n_elem; eT* out_mem = out.memptr(); for(uword i=0; i<n_elem; ++i) { out_mem[i] = k - A[i]; } } template<typename T1> inline void op_cx_scalar_minus_post::apply ( Cube< typename std::complex<typename T1::pod_type> >& out, const mtOpCube<typename std::complex<typename T1::pod_type>, T1, op_cx_scalar_minus_post>& X ) { arma_extra_debug_sigprint(); typedef typename std::complex<typename T1::pod_type> eT; typedef typename T1::pod_type T; const ProxyCube<T1> A(X.m); out.set_size(A.get_n_rows(), A.get_n_cols(), A.get_n_slices()); const eT k = X.aux_out_eT; const uword n_elem = out.n_elem; eT* out_mem = out.memptr(); for(uword i=0; i<n_elem; ++i) { out_mem[i] = A[i] - k; } } template<typename T1> inline void op_cx_scalar_div_pre::apply ( Cube< typename std::complex<typename T1::pod_type> >& out, const mtOpCube<typename std::complex<typename T1::pod_type>, T1, op_cx_scalar_div_pre>& X ) { arma_extra_debug_sigprint(); typedef typename std::complex<typename T1::pod_type> eT; typedef typename T1::pod_type T; const ProxyCube<T1> A(X.m); out.set_size(A.get_n_rows(), A.get_n_cols(), A.get_n_slices()); const eT k = X.aux_out_eT; const uword n_elem = out.n_elem; eT* out_mem = out.memptr(); for(uword i=0; i<n_elem; ++i) { out_mem[i] = k / A[i]; } } template<typename T1> inline void op_cx_scalar_div_post::apply ( Cube< typename std::complex<typename T1::pod_type> >& out, const mtOpCube<typename std::complex<typename T1::pod_type>, T1, op_cx_scalar_div_post>& X ) { arma_extra_debug_sigprint(); typedef typename std::complex<typename T1::pod_type> eT; typedef typename T1::pod_type T; const ProxyCube<T1> A(X.m); out.set_size(A.get_n_rows(), A.get_n_cols(), A.get_n_slices()); const eT k = X.aux_out_eT; const uword n_elem = out.n_elem; eT* out_mem = out.memptr(); for(uword i=0; i<n_elem; ++i) { out_mem[i] = A[i] / k; } } //! @}