AnalysisSystemForRadionuclide_qt_alg/include/armadillo_bits/op_misc_meat.hpp

// Copyright (C) 2008-2015 National ICT Australia (NICTA)
// 
// This Source Code Form is subject to the terms of the Mozilla Public
// License, v. 2.0. If a copy of the MPL was not distributed with this
// file, You can obtain one at http://mozilla.org/MPL/2.0/.
// -------------------------------------------------------------------
// 
// Written by Conrad Sanderson - http://conradsanderson.id.au


//! \addtogroup op_misc
//! @{



template<typename T1>
inline
void
op_real::apply( Mat<typename T1::pod_type>& out, const mtOp<typename T1::pod_type, T1, op_real>& X )
  {
  arma_extra_debug_sigprint();
  
  typedef typename T1::pod_type T;
  
  const Proxy<T1> P(X.m);
  
  const uword n_rows = P.get_n_rows();
  const uword n_cols = P.get_n_cols();
    
  out.set_size(n_rows, n_cols);
  
  T* out_mem = out.memptr();
  
  if(Proxy<T1>::prefer_at_accessor == false)
    {
    typedef typename Proxy<T1>::ea_type ea_type;
    
    const uword   n_elem  = P.get_n_elem();
          ea_type A       = P.get_ea();
    
    for(uword i=0; i < n_elem; ++i)
      {
      out_mem[i] = std::real( A[i] );
      }
    }
  else
    {
    for(uword col=0; col < n_cols; ++col)
    for(uword row=0; row < n_rows; ++row)
      {
      *out_mem = std::real( P.at(row,col) );
      out_mem++;
      }
    }
  }



template<typename T1>
inline
void
op_real::apply( Cube<typename T1::pod_type>& out, const mtOpCube<typename T1::pod_type, T1, op_real>& X )
  {
  arma_extra_debug_sigprint();
  
  typedef typename T1::pod_type T;
  
  const ProxyCube<T1> P(X.m);
  
  const uword n_rows   = P.get_n_rows();
  const uword n_cols   = P.get_n_cols();
  const uword n_slices = P.get_n_slices();
    
  out.set_size(n_rows, n_cols, n_slices);
  
  T* out_mem = out.memptr();

  if(ProxyCube<T1>::prefer_at_accessor == false)
    {
    typedef typename ProxyCube<T1>::ea_type ea_type;
    
    const uword   n_elem  = P.get_n_elem();
          ea_type A       = P.get_ea();
    
    for(uword i=0; i < n_elem; ++i)
      {
      out_mem[i] = std::real( A[i] );
      }
    }
  else
    {
    for(uword slice=0; slice < n_slices; ++slice)
    for(uword col=0;   col   < n_cols;   ++col  )
    for(uword row=0;   row   < n_rows;   ++row  )
      {
      *out_mem = std::real( P.at(row,col,slice) );
      out_mem++;
      }
    }
  }



template<typename T1>
inline
void
op_imag::apply( Mat<typename T1::pod_type>& out, const mtOp<typename T1::pod_type, T1, op_imag>& X )
  {
  arma_extra_debug_sigprint();
  
  typedef typename T1::pod_type T;
  
  const Proxy<T1> P(X.m);
  
  const uword n_rows = P.get_n_rows();
  const uword n_cols = P.get_n_cols();
    
  out.set_size(n_rows, n_cols);
  
  T* out_mem = out.memptr();
  
  if(Proxy<T1>::prefer_at_accessor == false)
    {
    typedef typename Proxy<T1>::ea_type ea_type;
    
    const uword   n_elem  = P.get_n_elem();
          ea_type A       = P.get_ea();
    
    for(uword i=0; i < n_elem; ++i)
      {
      out_mem[i] = std::imag( A[i] );
      }
    }
  else
    {
    for(uword col=0; col < n_cols; ++col)
    for(uword row=0; row < n_rows; ++row)
      {
      *out_mem = std::imag( P.at(row,col) );
      out_mem++;
      }
    }
  }



template<typename T1>
inline
void
op_imag::apply( Cube<typename T1::pod_type>& out, const mtOpCube<typename T1::pod_type, T1, op_imag>& X )
  {
  arma_extra_debug_sigprint();
  
  typedef typename T1::pod_type T;
  
  const ProxyCube<T1> P(X.m);
  
  const uword n_rows   = P.get_n_rows();
  const uword n_cols   = P.get_n_cols();
  const uword n_slices = P.get_n_slices();
    
  out.set_size(n_rows, n_cols, n_slices);
  
  T* out_mem = out.memptr();

  if(ProxyCube<T1>::prefer_at_accessor == false)
    {
    typedef typename ProxyCube<T1>::ea_type ea_type;
    
    const uword   n_elem  = P.get_n_elem();
          ea_type A       = P.get_ea();
    
    for(uword i=0; i < n_elem; ++i)
      {
      out_mem[i] = std::imag( A[i] );
      }
    }
  else
    {
    for(uword slice=0; slice < n_slices; ++slice)
    for(uword col=0;   col   < n_cols;   ++col  )
    for(uword row=0;   row   < n_rows;   ++row  )
      {
      *out_mem = std::imag( P.at(row,col,slice) );
      out_mem++;
      }
    }
  }



template<typename T1>
inline
void
op_abs::apply( Mat<typename T1::pod_type>& out, const mtOp<typename T1::pod_type, T1, op_abs>& X )
  {
  arma_extra_debug_sigprint();
  
  typedef typename T1::pod_type T;
  
  const Proxy<T1> P(X.m);
  
  const uword n_rows = P.get_n_rows();
  const uword n_cols = P.get_n_cols();
    
  out.set_size(n_rows, n_cols);
  
  T* out_mem = out.memptr();
  
  if(Proxy<T1>::prefer_at_accessor == false)
    {
    typedef typename Proxy<T1>::ea_type ea_type;
    
    const uword   n_elem  = P.get_n_elem();
          ea_type A       = P.get_ea();
    
    for(uword i=0; i < n_elem; ++i)
      {
      out_mem[i] = std::abs( A[i] );
      }
    }
  else
    {
    for(uword col=0; col < n_cols; ++col)
    for(uword row=0; row < n_rows; ++row)
      {
      *out_mem = std::abs( P.at(row,col) );
      out_mem++;
      }
    }
  }



template<typename T1>
inline
void
op_abs::apply( Cube<typename T1::pod_type>& out, const mtOpCube<typename T1::pod_type, T1, op_abs>& X )
  {
  arma_extra_debug_sigprint();
  
  typedef typename T1::pod_type T;
  
  const ProxyCube<T1> P(X.m);
  
  const uword n_rows   = P.get_n_rows();
  const uword n_cols   = P.get_n_cols();
  const uword n_slices = P.get_n_slices();
    
  out.set_size(n_rows, n_cols, n_slices);
  
  T* out_mem = out.memptr();

  if(ProxyCube<T1>::prefer_at_accessor == false)
    {
    typedef typename ProxyCube<T1>::ea_type ea_type;
    
    const uword   n_elem  = P.get_n_elem();
          ea_type A       = P.get_ea();
    
    for(uword i=0; i < n_elem; ++i)
      {
      out_mem[i] = std::abs( A[i] );
      }
    }
  else
    {
    for(uword slice=0; slice < n_slices; ++slice)
    for(uword col=0;   col   < n_cols;   ++col  )
    for(uword row=0;   row   < n_rows;   ++row  )
      {
      *out_mem = std::abs( P.at(row,col,slice) );
      out_mem++;
      }
    }
  }



template<typename T1>
inline
void
op_orth::apply( Mat<typename T1::elem_type>& out, const Op<T1, op_orth>& expr )
  {
  arma_extra_debug_sigprint();
  
  typedef typename T1::elem_type eT;
  typedef typename T1::pod_type   T;
  
  T tol = access::tmp_real(expr.aux);
  
  arma_debug_check((tol < T(0)), "orth(): tolerance must be >= 0");
  
  const unwrap<T1>   tmp(expr.m);
  const Mat<eT>& X = tmp.M;
  
  Mat<eT> U;
  Col< T> s;
  Mat<eT> V;
  
  const bool status = auxlib::svd_dc(U, s, V, X);
  
  V.reset();
  
  if(status == false)  { out.reset(); arma_bad("orth(): svd failed"); return; }
  
  if(s.is_empty())  { out.reset(); return; }
  
  const uword s_n_elem = s.n_elem;
  const T*    s_mem    = s.memptr();
  
  // set tolerance to default if it hasn't been specified
  if(tol == T(0))  { tol = (std::max)(X.n_rows, X.n_cols) * s_mem[0] * std::numeric_limits<T>::epsilon(); }
  
  uword count = 0;
  
  for(uword i=0; i < s_n_elem; ++i)  { count += (s_mem[i] > tol) ? uword(1) : uword(0); }
  
  if(count > 0)
    {
    out = U.head_cols(count);  // out *= eT(-1);
    }
  else
    {
    out.set_size(X.n_rows, 0);
    }
  }



template<typename T1>
inline
void
op_null::apply( Mat<typename T1::elem_type>& out, const Op<T1, op_null>& expr )
  {
  arma_extra_debug_sigprint();
  
  typedef typename T1::elem_type eT;
  typedef typename T1::pod_type   T;
  
  T tol = access::tmp_real(expr.aux);
  
  arma_debug_check((tol < T(0)), "null(): tolerance must be >= 0");
  
  const unwrap<T1>   tmp(expr.m);
  const Mat<eT>& X = tmp.M;
  
  Mat<eT> U;
  Col< T> s;
  Mat<eT> V;
  
  const bool status = auxlib::svd_dc(U, s, V, X);
  
  U.reset();
  
  if(status == false)  { out.reset(); arma_bad("null(): svd failed"); return; }
  
  if(s.is_empty())  { out.reset(); return; }
  
  const uword s_n_elem = s.n_elem;
  const T*    s_mem    = s.memptr();
  
  // set tolerance to default if it hasn't been specified
  if(tol == T(0))  { tol = (std::max)(X.n_rows, X.n_cols) * s_mem[0] * std::numeric_limits<T>::epsilon(); }
  
  uword count = 0;
  
  for(uword i=0; i < s_n_elem; ++i)  { count += (s_mem[i] > tol) ? uword(1) : uword(0); }
  
  if(count < X.n_cols)
    {
    out = V.tail_cols(X.n_cols - count);
    
    const uword out_n_elem = out.n_elem;
          eT*   out_mem    = out.memptr();
    
    for(uword i=0; i<out_n_elem; ++i)
      {
      if(std::abs(out_mem[i]) < std::numeric_limits<T>::epsilon())  { out_mem[i] = eT(0); }
      }
    }
  else
    {
    out.set_size(X.n_cols, 0);
    }
  }



//! @}