view liboctave/CNDArray.cc @ 12312:b10ea6efdc58 release-3-4-x ss-3-3-91

version is now 3.3.91
author John W. Eaton <jwe@octave.org>
date Mon, 31 Jan 2011 08:36:58 -0500
parents 12df7854fa7c
children 353c71c76f22
line wrap: on
line source

// N-D Array  manipulations.
/*

Copyright (C) 1996-2011 John W. Eaton
Copyright (C) 2009 VZLU Prague, a.s.

This file is part of Octave.

Octave is free software; you can redistribute it and/or modify it
under the terms of the GNU General Public License as published by the
Free Software Foundation; either version 3 of the License, or (at your
option) any later version.

Octave is distributed in the hope that it will be useful, but WITHOUT
ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
for more details.

You should have received a copy of the GNU General Public License
along with Octave; see the file COPYING.  If not, see
<http://www.gnu.org/licenses/>.

*/

#ifdef HAVE_CONFIG_H
#include <config.h>
#endif

#include <cfloat>

#include <vector>

#include "Array-util.h"
#include "CNDArray.h"
#include "f77-fcn.h"
#include "functor.h"
#include "lo-ieee.h"
#include "lo-mappers.h"
#include "MArray-defs.h"
#include "mx-base.h"
#include "mx-op-defs.h"
#include "oct-fftw.h"
#include "oct-locbuf.h"

#include "bsxfun-defs.cc"

ComplexNDArray::ComplexNDArray (const charNDArray& a)
  : MArray<Complex> (a.dims ())
{
  octave_idx_type n = a.numel ();
  for (octave_idx_type i = 0; i < n; i++)
    xelem (i) = static_cast<unsigned char> (a(i));
}

#if defined (HAVE_FFTW)

ComplexNDArray
ComplexNDArray::fourier (int dim) const
{
  dim_vector dv = dims ();

  if (dim > dv.length () || dim < 0)
    return ComplexNDArray ();

  octave_idx_type stride = 1;
  octave_idx_type n = dv(dim);

  for (int i = 0; i < dim; i++)
    stride *= dv(i);

  octave_idx_type howmany = numel () / dv (dim);
  howmany = (stride == 1 ? howmany : (howmany > stride ? stride : howmany));
  octave_idx_type nloop = (stride == 1 ? 1 : numel () / dv (dim) / stride);
  octave_idx_type dist = (stride == 1 ? n : 1);

  const Complex *in (fortran_vec ());
  ComplexNDArray retval (dv);
  Complex *out (retval.fortran_vec ());

  // Need to be careful here about the distance between fft's
  for (octave_idx_type k = 0; k < nloop; k++)
    octave_fftw::fft (in + k * stride * n, out + k * stride * n,
                      n, howmany, stride, dist);

  return retval;
}

ComplexNDArray
ComplexNDArray::ifourier (int dim) const
{
  dim_vector dv = dims ();

  if (dim > dv.length () || dim < 0)
    return ComplexNDArray ();

  octave_idx_type stride = 1;
  octave_idx_type n = dv(dim);

  for (int i = 0; i < dim; i++)
    stride *= dv(i);

  octave_idx_type howmany = numel () / dv (dim);
  howmany = (stride == 1 ? howmany : (howmany > stride ? stride : howmany));
  octave_idx_type nloop = (stride == 1 ? 1 : numel () / dv (dim) / stride);
  octave_idx_type dist = (stride == 1 ? n : 1);

  const Complex *in (fortran_vec ());
  ComplexNDArray retval (dv);
  Complex *out (retval.fortran_vec ());

  // Need to be careful here about the distance between fft's
  for (octave_idx_type k = 0; k < nloop; k++)
    octave_fftw::ifft (in + k * stride * n, out + k * stride * n,
                      n, howmany, stride, dist);

  return retval;
}

ComplexNDArray
ComplexNDArray::fourier2d (void) const
{
  dim_vector dv = dims();
  if (dv.length () < 2)
    return ComplexNDArray ();

  dim_vector dv2(dv(0), dv(1));
  const Complex *in = fortran_vec ();
  ComplexNDArray retval (dv);
  Complex *out = retval.fortran_vec ();
  octave_idx_type howmany = numel() / dv(0) / dv(1);
  octave_idx_type dist = dv(0) * dv(1);

  for (octave_idx_type i=0; i < howmany; i++)
    octave_fftw::fftNd (in + i*dist, out + i*dist, 2, dv2);

  return retval;
}

ComplexNDArray
ComplexNDArray::ifourier2d (void) const
{
  dim_vector dv = dims();
  if (dv.length () < 2)
    return ComplexNDArray ();

  dim_vector dv2(dv(0), dv(1));
  const Complex *in = fortran_vec ();
  ComplexNDArray retval (dv);
  Complex *out = retval.fortran_vec ();
  octave_idx_type howmany = numel() / dv(0) / dv(1);
  octave_idx_type dist = dv(0) * dv(1);

  for (octave_idx_type i=0; i < howmany; i++)
    octave_fftw::ifftNd (in + i*dist, out + i*dist, 2, dv2);

  return retval;
}

ComplexNDArray
ComplexNDArray::fourierNd (void) const
{
  dim_vector dv = dims ();
  int rank = dv.length ();

  const Complex *in (fortran_vec ());
  ComplexNDArray retval (dv);
  Complex *out (retval.fortran_vec ());

  octave_fftw::fftNd (in, out, rank, dv);

  return retval;
}

ComplexNDArray
ComplexNDArray::ifourierNd (void) const
{
  dim_vector dv = dims ();
  int rank = dv.length ();

  const Complex *in (fortran_vec ());
  ComplexNDArray retval (dv);
  Complex *out (retval.fortran_vec ());

  octave_fftw::ifftNd (in, out, rank, dv);

  return retval;
}

#else

extern "C"
{
  // Note that the original complex fft routines were not written for
  // double complex arguments.  They have been modified by adding an
  // implicit double precision (a-h,o-z) statement at the beginning of
  // each subroutine.

  F77_RET_T
  F77_FUNC (zffti, ZFFTI) (const octave_idx_type&, Complex*);

  F77_RET_T
  F77_FUNC (zfftf, ZFFTF) (const octave_idx_type&, Complex*, Complex*);

  F77_RET_T
  F77_FUNC (zfftb, ZFFTB) (const octave_idx_type&, Complex*, Complex*);
}

ComplexNDArray
ComplexNDArray::fourier (int dim) const
{
  dim_vector dv = dims ();

  if (dim > dv.length () || dim < 0)
    return ComplexNDArray ();

  ComplexNDArray retval (dv);
  octave_idx_type npts = dv(dim);
  octave_idx_type nn = 4*npts+15;
  Array<Complex> wsave (dim_vector (nn, 1));
  Complex *pwsave = wsave.fortran_vec ();

  OCTAVE_LOCAL_BUFFER (Complex, tmp, npts);

  octave_idx_type stride = 1;

  for (int i = 0; i < dim; i++)
    stride *= dv(i);

  octave_idx_type howmany = numel () / npts;
  howmany = (stride == 1 ? howmany : (howmany > stride ? stride : howmany));
  octave_idx_type nloop = (stride == 1 ? 1 : numel () / npts / stride);
  octave_idx_type dist = (stride == 1 ? npts : 1);

  F77_FUNC (zffti, ZFFTI) (npts, pwsave);

  for (octave_idx_type k = 0; k < nloop; k++)
    {
      for (octave_idx_type j = 0; j < howmany; j++)
        {
          octave_quit ();

          for (octave_idx_type i = 0; i < npts; i++)
            tmp[i] = elem((i + k*npts)*stride + j*dist);

          F77_FUNC (zfftf, ZFFTF) (npts, tmp, pwsave);

          for (octave_idx_type i = 0; i < npts; i++)
            retval ((i + k*npts)*stride + j*dist) = tmp[i];
        }
    }

  return retval;
}

ComplexNDArray
ComplexNDArray::ifourier (int dim) const
{
  dim_vector dv = dims ();

  if (dim > dv.length () || dim < 0)
    return ComplexNDArray ();

  ComplexNDArray retval (dv);
  octave_idx_type npts = dv(dim);
  octave_idx_type nn = 4*npts+15;
  Array<Complex> wsave (dim_vector (nn, 1));
  Complex *pwsave = wsave.fortran_vec ();

  OCTAVE_LOCAL_BUFFER (Complex, tmp, npts);

  octave_idx_type stride = 1;

  for (int i = 0; i < dim; i++)
    stride *= dv(i);

  octave_idx_type howmany = numel () / npts;
  howmany = (stride == 1 ? howmany : (howmany > stride ? stride : howmany));
  octave_idx_type nloop = (stride == 1 ? 1 : numel () / npts / stride);
  octave_idx_type dist = (stride == 1 ? npts : 1);

  F77_FUNC (zffti, ZFFTI) (npts, pwsave);

  for (octave_idx_type k = 0; k < nloop; k++)
    {
      for (octave_idx_type j = 0; j < howmany; j++)
        {
          octave_quit ();

          for (octave_idx_type i = 0; i < npts; i++)
            tmp[i] = elem((i + k*npts)*stride + j*dist);

          F77_FUNC (zfftb, ZFFTB) (npts, tmp, pwsave);

          for (octave_idx_type i = 0; i < npts; i++)
            retval ((i + k*npts)*stride + j*dist) = tmp[i] /
              static_cast<double> (npts);
        }
    }

  return retval;
}

ComplexNDArray
ComplexNDArray::fourier2d (void) const
{
  dim_vector dv = dims ();
  dim_vector dv2 (dv(0), dv(1));
  int rank = 2;
  ComplexNDArray retval (*this);
  octave_idx_type stride = 1;

  for (int i = 0; i < rank; i++)
    {
      octave_idx_type npts = dv2(i);
      octave_idx_type nn = 4*npts+15;
      Array<Complex> wsave (dim_vector (nn, 1));
      Complex *pwsave = wsave.fortran_vec ();
      Array<Complex> row (dim_vector (npts, 1));
      Complex *prow = row.fortran_vec ();

      octave_idx_type howmany = numel () / npts;
      howmany = (stride == 1 ? howmany :
                 (howmany > stride ? stride : howmany));
      octave_idx_type nloop = (stride == 1 ? 1 : numel () / npts / stride);
      octave_idx_type dist = (stride == 1 ? npts : 1);

      F77_FUNC (zffti, ZFFTI) (npts, pwsave);

      for (octave_idx_type k = 0; k < nloop; k++)
        {
          for (octave_idx_type j = 0; j < howmany; j++)
            {
              octave_quit ();

              for (octave_idx_type l = 0; l < npts; l++)
                prow[l] = retval ((l + k*npts)*stride + j*dist);

              F77_FUNC (zfftf, ZFFTF) (npts, prow, pwsave);

              for (octave_idx_type l = 0; l < npts; l++)
                retval ((l + k*npts)*stride + j*dist) = prow[l];
            }
        }

      stride *= dv2(i);
    }

  return retval;
}

ComplexNDArray
ComplexNDArray::ifourier2d (void) const
{
  dim_vector dv = dims();
  dim_vector dv2 (dv(0), dv(1));
  int rank = 2;
  ComplexNDArray retval (*this);
  octave_idx_type stride = 1;

  for (int i = 0; i < rank; i++)
    {
      octave_idx_type npts = dv2(i);
      octave_idx_type nn = 4*npts+15;
      Array<Complex> wsave (dim_vector (nn, 1));
      Complex *pwsave = wsave.fortran_vec ();
      Array<Complex> row (dim_vector (npts, 1));
      Complex *prow = row.fortran_vec ();

      octave_idx_type howmany = numel () / npts;
      howmany = (stride == 1 ? howmany :
                 (howmany > stride ? stride : howmany));
      octave_idx_type nloop = (stride == 1 ? 1 : numel () / npts / stride);
      octave_idx_type dist = (stride == 1 ? npts : 1);

      F77_FUNC (zffti, ZFFTI) (npts, pwsave);

      for (octave_idx_type k = 0; k < nloop; k++)
        {
          for (octave_idx_type j = 0; j < howmany; j++)
            {
              octave_quit ();

              for (octave_idx_type l = 0; l < npts; l++)
                prow[l] = retval ((l + k*npts)*stride + j*dist);

              F77_FUNC (zfftb, ZFFTB) (npts, prow, pwsave);

              for (octave_idx_type l = 0; l < npts; l++)
                retval ((l + k*npts)*stride + j*dist) = prow[l] /
                  static_cast<double> (npts);
            }
        }

      stride *= dv2(i);
    }

  return retval;
}

ComplexNDArray
ComplexNDArray::fourierNd (void) const
{
  dim_vector dv = dims ();
  int rank = dv.length ();
  ComplexNDArray retval (*this);
  octave_idx_type stride = 1;

  for (int i = 0; i < rank; i++)
    {
      octave_idx_type npts = dv(i);
      octave_idx_type nn = 4*npts+15;
      Array<Complex> wsave (dim_vector (nn, 1));
      Complex *pwsave = wsave.fortran_vec ();
      Array<Complex> row (dim_vector (npts, 1));
      Complex *prow = row.fortran_vec ();

      octave_idx_type howmany = numel () / npts;
      howmany = (stride == 1 ? howmany :
                 (howmany > stride ? stride : howmany));
      octave_idx_type nloop = (stride == 1 ? 1 : numel () / npts / stride);
      octave_idx_type dist = (stride == 1 ? npts : 1);

      F77_FUNC (zffti, ZFFTI) (npts, pwsave);

      for (octave_idx_type k = 0; k < nloop; k++)
        {
          for (octave_idx_type j = 0; j < howmany; j++)
            {
              octave_quit ();

              for (octave_idx_type l = 0; l < npts; l++)
                prow[l] = retval ((l + k*npts)*stride + j*dist);

              F77_FUNC (zfftf, ZFFTF) (npts, prow, pwsave);

              for (octave_idx_type l = 0; l < npts; l++)
                retval ((l + k*npts)*stride + j*dist) = prow[l];
            }
        }

      stride *= dv(i);
    }

  return retval;
}

ComplexNDArray
ComplexNDArray::ifourierNd (void) const
{
  dim_vector dv = dims ();
  int rank = dv.length ();
  ComplexNDArray retval (*this);
  octave_idx_type stride = 1;

  for (int i = 0; i < rank; i++)
    {
      octave_idx_type npts = dv(i);
      octave_idx_type nn = 4*npts+15;
      Array<Complex> wsave (dim_vector (nn, 1));
      Complex *pwsave = wsave.fortran_vec ();
      Array<Complex> row (dim_vector (npts, 1));
      Complex *prow = row.fortran_vec ();

      octave_idx_type howmany = numel () / npts;
      howmany = (stride == 1 ? howmany :
                 (howmany > stride ? stride : howmany));
      octave_idx_type nloop = (stride == 1 ? 1 : numel () / npts / stride);
      octave_idx_type dist = (stride == 1 ? npts : 1);

      F77_FUNC (zffti, ZFFTI) (npts, pwsave);

      for (octave_idx_type k = 0; k < nloop; k++)
        {
          for (octave_idx_type j = 0; j < howmany; j++)
            {
              octave_quit ();

              for (octave_idx_type l = 0; l < npts; l++)
                prow[l] = retval ((l + k*npts)*stride + j*dist);

              F77_FUNC (zfftb, ZFFTB) (npts, prow, pwsave);

              for (octave_idx_type l = 0; l < npts; l++)
                retval ((l + k*npts)*stride + j*dist) = prow[l] /
                  static_cast<double> (npts);
            }
        }

      stride *= dv(i);
    }

  return retval;
}

#endif

// unary operations

boolNDArray
ComplexNDArray::operator ! (void) const
{
  if (any_element_is_nan ())
    gripe_nan_to_logical_conversion ();

  return do_mx_unary_op<bool, Complex> (*this, mx_inline_not);
}

// FIXME -- this is not quite the right thing.

bool
ComplexNDArray::any_element_is_nan (void) const
{
  return do_mx_check<Complex> (*this, mx_inline_any_nan);
}

bool
ComplexNDArray::any_element_is_inf_or_nan (void) const
{
  return ! do_mx_check<Complex> (*this, mx_inline_all_finite);
}

// Return true if no elements have imaginary components.

bool
ComplexNDArray::all_elements_are_real (void) const
{
  return do_mx_check<Complex> (*this, mx_inline_all_real);
}

// Return nonzero if any element of CM has a non-integer real or
// imaginary part.  Also extract the largest and smallest (real or
// imaginary) values and return them in MAX_VAL and MIN_VAL.

bool
ComplexNDArray::all_integers (double& max_val, double& min_val) const
{
  octave_idx_type nel = nelem ();

  if (nel > 0)
    {
      Complex val = elem (0);

      double r_val = std::real (val);
      double i_val = std::imag (val);

      max_val = r_val;
      min_val = r_val;

      if (i_val > max_val)
        max_val = i_val;

      if (i_val < max_val)
        min_val = i_val;
    }
  else
    return false;

  for (octave_idx_type i = 0; i < nel; i++)
    {
      Complex val = elem (i);

      double r_val = std::real (val);
      double i_val = std::imag (val);

      if (r_val > max_val)
        max_val = r_val;

      if (i_val > max_val)
        max_val = i_val;

      if (r_val < min_val)
        min_val = r_val;

      if (i_val < min_val)
        min_val = i_val;

      if (D_NINT (r_val) != r_val || D_NINT (i_val) != i_val)
        return false;
    }

  return true;
}

bool
ComplexNDArray::too_large_for_float (void) const
{
  octave_idx_type nel = nelem ();

  for (octave_idx_type i = 0; i < nel; i++)
    {
      Complex val = elem (i);

      double r_val = std::real (val);
      double i_val = std::imag (val);

      if ((! (xisnan (r_val) || xisinf (r_val))
           && fabs (r_val) > FLT_MAX)
          || (! (xisnan (i_val) || xisinf (i_val))
              && fabs (i_val) > FLT_MAX))
        return true;
    }

  return false;
}

boolNDArray
ComplexNDArray::all (int dim) const
{
  return do_mx_red_op<bool, Complex> (*this, dim, mx_inline_all);
}

boolNDArray
ComplexNDArray::any (int dim) const
{
  return do_mx_red_op<bool, Complex> (*this, dim, mx_inline_any);
}

ComplexNDArray
ComplexNDArray::cumprod (int dim) const
{
  return do_mx_cum_op<Complex, Complex> (*this, dim, mx_inline_cumprod);
}

ComplexNDArray
ComplexNDArray::cumsum (int dim) const
{
  return do_mx_cum_op<Complex, Complex> (*this, dim, mx_inline_cumsum);
}

ComplexNDArray
ComplexNDArray::prod (int dim) const
{
  return do_mx_red_op<Complex, Complex> (*this, dim, mx_inline_prod);
}

ComplexNDArray
ComplexNDArray::sum (int dim) const
{
  return do_mx_red_op<Complex, Complex> (*this, dim, mx_inline_sum);
}

ComplexNDArray
ComplexNDArray::xsum (int dim) const
{
  return do_mx_red_op<Complex, Complex> (*this, dim, mx_inline_xsum);
}

ComplexNDArray
ComplexNDArray::sumsq (int dim) const
{
  return do_mx_red_op<double, Complex> (*this, dim, mx_inline_sumsq);
}

ComplexNDArray
ComplexNDArray::diff (octave_idx_type order, int dim) const
{
  return do_mx_diff_op<Complex> (*this, dim, order, mx_inline_diff);
}

ComplexNDArray
ComplexNDArray::concat (const ComplexNDArray& rb, const Array<octave_idx_type>& ra_idx)
{
  if (rb.numel () > 0)
    insert (rb, ra_idx);
  return *this;
}

ComplexNDArray
ComplexNDArray::concat (const NDArray& rb, const Array<octave_idx_type>& ra_idx)
{
  ComplexNDArray tmp (rb);
  if (rb.numel () > 0)
    insert (tmp, ra_idx);
  return *this;
}

ComplexNDArray
concat (NDArray& ra, ComplexNDArray& rb, const Array<octave_idx_type>& ra_idx)
{
  ComplexNDArray retval (ra);
  if (rb.numel () > 0)
    retval.insert (rb, ra_idx);
  return retval;
}

static const Complex Complex_NaN_result (octave_NaN, octave_NaN);

ComplexNDArray
ComplexNDArray::max (int dim) const
{
  return do_mx_minmax_op<Complex> (*this, dim, mx_inline_max);
}

ComplexNDArray
ComplexNDArray::max (Array<octave_idx_type>& idx_arg, int dim) const
{
  return do_mx_minmax_op<Complex> (*this, idx_arg, dim, mx_inline_max);
}

ComplexNDArray
ComplexNDArray::min (int dim) const
{
  return do_mx_minmax_op<Complex> (*this, dim, mx_inline_min);
}

ComplexNDArray
ComplexNDArray::min (Array<octave_idx_type>& idx_arg, int dim) const
{
  return do_mx_minmax_op<Complex> (*this, idx_arg, dim, mx_inline_min);
}

ComplexNDArray
ComplexNDArray::cummax (int dim) const
{
  return do_mx_cumminmax_op<Complex> (*this, dim, mx_inline_cummax);
}

ComplexNDArray
ComplexNDArray::cummax (Array<octave_idx_type>& idx_arg, int dim) const
{
  return do_mx_cumminmax_op<Complex> (*this, idx_arg, dim, mx_inline_cummax);
}

ComplexNDArray
ComplexNDArray::cummin (int dim) const
{
  return do_mx_cumminmax_op<Complex> (*this, dim, mx_inline_cummin);
}

ComplexNDArray
ComplexNDArray::cummin (Array<octave_idx_type>& idx_arg, int dim) const
{
  return do_mx_cumminmax_op<Complex> (*this, idx_arg, dim, mx_inline_cummin);
}

NDArray
ComplexNDArray::abs (void) const
{
  return do_mx_unary_map<double, Complex, std::abs> (*this);
}

boolNDArray
ComplexNDArray::isnan (void) const
{
  return do_mx_unary_map<bool, Complex, xisnan> (*this);
}

boolNDArray
ComplexNDArray::isinf (void) const
{
  return do_mx_unary_map<bool, Complex, xisinf> (*this);
}

boolNDArray
ComplexNDArray::isfinite (void) const
{
  return do_mx_unary_map<bool, Complex, xfinite> (*this);
}

ComplexNDArray
conj (const ComplexNDArray& a)
{
  return do_mx_unary_map<Complex, Complex, std::conj> (a);
}

ComplexNDArray&
ComplexNDArray::insert (const NDArray& a, octave_idx_type r, octave_idx_type c)
{
  dim_vector a_dv = a.dims ();

  int n = a_dv.length ();

  if (n == dimensions.length ())
    {
      Array<octave_idx_type> a_ra_idx (dim_vector (a_dv.length (), 1), 0);

      a_ra_idx.elem (0) = r;
      a_ra_idx.elem (1) = c;

      for (int i = 0; i < n; i++)
        {
          if (a_ra_idx (i) < 0 || (a_ra_idx (i) + a_dv (i)) > dimensions (i))
            {
              (*current_liboctave_error_handler)
                ("Array<T>::insert: range error for insert");
              return *this;
            }
        }

      a_ra_idx.elem (0) = 0;
      a_ra_idx.elem (1) = 0;

      octave_idx_type n_elt = a.numel ();

      // IS make_unique () NECCESSARY HERE??

      for (octave_idx_type i = 0; i < n_elt; i++)
        {
          Array<octave_idx_type> ra_idx = a_ra_idx;

          ra_idx.elem (0) = a_ra_idx (0) + r;
          ra_idx.elem (1) = a_ra_idx (1) + c;

          elem (ra_idx) = a.elem (a_ra_idx);

          increment_index (a_ra_idx, a_dv);
        }
    }
  else
    (*current_liboctave_error_handler)
      ("Array<T>::insert: invalid indexing operation");

  return *this;
}

ComplexNDArray&
ComplexNDArray::insert (const ComplexNDArray& a, octave_idx_type r, octave_idx_type c)
{
  Array<Complex>::insert (a, r, c);
  return *this;
}

ComplexNDArray&
ComplexNDArray::insert (const ComplexNDArray& a, const Array<octave_idx_type>& ra_idx)
{
  Array<Complex>::insert (a, ra_idx);
  return *this;
}

ComplexMatrix
ComplexNDArray::matrix_value (void) const
{
  ComplexMatrix retval;

  if (ndims () == 2)
      retval = ComplexMatrix (Array<Complex> (*this));
  else
    (*current_liboctave_error_handler)
      ("invalid conversion of ComplexNDArray to ComplexMatrix");

  return retval;
}

void
ComplexNDArray::increment_index (Array<octave_idx_type>& ra_idx,
                                 const dim_vector& dimensions,
                                 int start_dimension)
{
  ::increment_index (ra_idx, dimensions, start_dimension);
}

octave_idx_type
ComplexNDArray::compute_index (Array<octave_idx_type>& ra_idx,
                               const dim_vector& dimensions)
{
  return ::compute_index (ra_idx, dimensions);
}

ComplexNDArray
ComplexNDArray::diag (octave_idx_type k) const
{
  return MArray<Complex>::diag (k);
}

// This contains no information on the array structure !!!
std::ostream&
operator << (std::ostream& os, const ComplexNDArray& a)
{
  octave_idx_type nel = a.nelem ();

  for (octave_idx_type i = 0; i < nel; i++)
    {
      os << " ";
      octave_write_complex (os, a.elem (i));
      os << "\n";
    }
  return os;
}

std::istream&
operator >> (std::istream& is, ComplexNDArray& a)
{
  octave_idx_type nel = a.nelem ();

  if (nel > 0)
    {
      Complex tmp;
      for (octave_idx_type i = 0; i < nel; i++)
          {
            tmp = octave_read_value<Complex> (is);
            if (is)
              a.elem (i) = tmp;
            else
              goto done;
          }
    }

 done:

  return is;
}

MINMAX_FCNS (ComplexNDArray, Complex)

NDS_CMP_OPS (ComplexNDArray, Complex)
NDS_BOOL_OPS (ComplexNDArray, Complex)

SND_CMP_OPS (Complex, ComplexNDArray)
SND_BOOL_OPS (Complex, ComplexNDArray)

NDND_CMP_OPS (ComplexNDArray, ComplexNDArray)
NDND_BOOL_OPS (ComplexNDArray, ComplexNDArray)

ComplexNDArray& operator *= (ComplexNDArray& a, double s)
{
  if (a.is_shared ())
    a = a * s;
  else
    do_ms_inplace_op<Complex, double> (a, s, mx_inline_mul2);
  return a;
}

ComplexNDArray& operator /= (ComplexNDArray& a, double s)
{
  if (a.is_shared ())
    return a = a / s;
  else
    do_ms_inplace_op<Complex, double> (a, s, mx_inline_div2);
  return a;
}

BSXFUN_STDOP_DEFS_MXLOOP (ComplexNDArray)
BSXFUN_STDREL_DEFS_MXLOOP (ComplexNDArray)

BSXFUN_OP_DEF_MXLOOP (pow, ComplexNDArray, mx_inline_pow)