// N-D Array manipulations.
/*
Copyright (C) 1996, 1997 John W. Eaton
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 2, 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, write to the Free
Software Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA
02110-1301, USA.
*/
#if defined (__GNUG__) && defined (USE_PRAGMA_INTERFACE_IMPLEMENTATION)
#pragma implementation
#endif
#ifdef HAVE_CONFIG_H
#include <config.h>
#endif
#include <cfloat>
#include <vector>
#include "Array-util.h"
#include "dNDArray.h"
#include "mx-base.h"
#include "f77-fcn.h"
#include "lo-error.h"
#include "lo-ieee.h"
#include "lo-mappers.h"
#if defined (HAVE_FFTW3)
#include "oct-fftw.h"
ComplexNDArray
NDArray::fourier (int dim) const
{
dim_vector dv = dims ();
if (dim > dv.length () || dim < 0)
return ComplexNDArray ();
int stride = 1;
int n = dv(dim);
for (int i = 0; i < dim; i++)
stride *= dv(i);
int howmany = numel () / dv (dim);
howmany = (stride == 1 ? howmany : (howmany > stride ? stride : howmany));
int nloop = (stride == 1 ? 1 : numel () / dv (dim) / stride);
int dist = (stride == 1 ? n : 1);
const double *in (fortran_vec ());
ComplexNDArray retval (dv);
Complex *out (retval.fortran_vec ());
// Need to be careful here about the distance between fft's
for (int k = 0; k < nloop; k++)
octave_fftw::fft (in + k * stride * n, out + k * stride * n,
n, howmany, stride, dist);
return retval;
}
ComplexNDArray
NDArray::ifourier (int dim) const
{
dim_vector dv = dims ();
if (dim > dv.length () || dim < 0)
return ComplexNDArray ();
int stride = 1;
int n = dv(dim);
for (int i = 0; i < dim; i++)
stride *= dv(i);
int howmany = numel () / dv (dim);
howmany = (stride == 1 ? howmany : (howmany > stride ? stride : howmany));
int nloop = (stride == 1 ? 1 : numel () / dv (dim) / stride);
int dist = (stride == 1 ? n : 1);
ComplexNDArray retval (*this);
Complex *out (retval.fortran_vec ());
// Need to be careful here about the distance between fft's
for (int k = 0; k < nloop; k++)
octave_fftw::ifft (out + k * stride * n, out + k * stride * n,
n, howmany, stride, dist);
return retval;
}
ComplexNDArray
NDArray::fourier2d (void) const
{
dim_vector dv = dims();
if (dv.length () < 2)
return ComplexNDArray ();
dim_vector dv2(dv(0), dv(1));
const double *in = fortran_vec ();
ComplexNDArray retval (dv);
Complex *out = retval.fortran_vec ();
int howmany = numel() / dv(0) / dv(1);
int dist = dv(0) * dv(1);
for (int i=0; i < howmany; i++)
octave_fftw::fftNd (in + i*dist, out + i*dist, 2, dv2);
return retval;
}
ComplexNDArray
NDArray::ifourier2d (void) const
{
dim_vector dv = dims();
if (dv.length () < 2)
return ComplexNDArray ();
dim_vector dv2(dv(0), dv(1));
ComplexNDArray retval (*this);
Complex *out = retval.fortran_vec ();
int howmany = numel() / dv(0) / dv(1);
int dist = dv(0) * dv(1);
for (int i=0; i < howmany; i++)
octave_fftw::ifftNd (out + i*dist, out + i*dist, 2, dv2);
return retval;
}
ComplexNDArray
NDArray::fourierNd (void) const
{
dim_vector dv = dims ();
int rank = dv.length ();
const double *in (fortran_vec ());
ComplexNDArray retval (dv);
Complex *out (retval.fortran_vec ());
octave_fftw::fftNd (in, out, rank, dv);
return retval;
}
ComplexNDArray
NDArray::ifourierNd (void) const
{
dim_vector dv = dims ();
int rank = dv.length ();
ComplexNDArray tmp (*this);
Complex *in (tmp.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 (cffti, CFFTI) (const int&, Complex*);
F77_RET_T
F77_FUNC (cfftf, CFFTF) (const int&, Complex*, Complex*);
F77_RET_T
F77_FUNC (cfftb, CFFTB) (const int&, Complex*, Complex*);
}
ComplexNDArray
NDArray::fourier (int dim) const
{
dim_vector dv = dims ();
if (dim > dv.length () || dim < 0)
return ComplexNDArray ();
ComplexNDArray retval (dv);
int npts = dv(dim);
int nn = 4*npts+15;
Array<Complex> wsave (nn);
Complex *pwsave = wsave.fortran_vec ();
OCTAVE_LOCAL_BUFFER (Complex, tmp, npts);
int stride = 1;
for (int i = 0; i < dim; i++)
stride *= dv(i);
int howmany = numel () / npts;
howmany = (stride == 1 ? howmany : (howmany > stride ? stride : howmany));
int nloop = (stride == 1 ? 1 : numel () / npts / stride);
int dist = (stride == 1 ? npts : 1);
F77_FUNC (cffti, CFFTI) (npts, pwsave);
for (int k = 0; k < nloop; k++)
{
for (int j = 0; j < howmany; j++)
{
OCTAVE_QUIT;
for (int i = 0; i < npts; i++)
tmp[i] = elem((i + k*npts)*stride + j*dist);
F77_FUNC (cfftf, CFFTF) (npts, tmp, pwsave);
for (int i = 0; i < npts; i++)
retval ((i + k*npts)*stride + j*dist) = tmp[i];
}
}
return retval;
}
ComplexNDArray
NDArray::ifourier (int dim) const
{
dim_vector dv = dims ();
if (dim > dv.length () || dim < 0)
return ComplexNDArray ();
ComplexNDArray retval (dv);
int npts = dv(dim);
int nn = 4*npts+15;
Array<Complex> wsave (nn);
Complex *pwsave = wsave.fortran_vec ();
OCTAVE_LOCAL_BUFFER (Complex, tmp, npts);
int stride = 1;
for (int i = 0; i < dim; i++)
stride *= dv(i);
int howmany = numel () / npts;
howmany = (stride == 1 ? howmany : (howmany > stride ? stride : howmany));
int nloop = (stride == 1 ? 1 : numel () / npts / stride);
int dist = (stride == 1 ? npts : 1);
F77_FUNC (cffti, CFFTI) (npts, pwsave);
for (int k = 0; k < nloop; k++)
{
for (int j = 0; j < howmany; j++)
{
OCTAVE_QUIT;
for (int i = 0; i < npts; i++)
tmp[i] = elem((i + k*npts)*stride + j*dist);
F77_FUNC (cfftb, CFFTB) (npts, tmp, pwsave);
for (int i = 0; i < npts; i++)
retval ((i + k*npts)*stride + j*dist) = tmp[i] /
static_cast<double> (npts);
}
}
return retval;
}
ComplexNDArray
NDArray::fourier2d (void) const
{
dim_vector dv = dims();
dim_vector dv2 (dv(0), dv(1));
int rank = 2;
ComplexNDArray retval (*this);
int stride = 1;
for (int i = 0; i < rank; i++)
{
int npts = dv2(i);
int nn = 4*npts+15;
Array<Complex> wsave (nn);
Complex *pwsave = wsave.fortran_vec ();
Array<Complex> row (npts);
Complex *prow = row.fortran_vec ();
int howmany = numel () / npts;
howmany = (stride == 1 ? howmany :
(howmany > stride ? stride : howmany));
int nloop = (stride == 1 ? 1 : numel () / npts / stride);
int dist = (stride == 1 ? npts : 1);
F77_FUNC (cffti, CFFTI) (npts, pwsave);
for (int k = 0; k < nloop; k++)
{
for (int j = 0; j < howmany; j++)
{
OCTAVE_QUIT;
for (int l = 0; l < npts; l++)
prow[l] = retval ((l + k*npts)*stride + j*dist);
F77_FUNC (cfftf, CFFTF) (npts, prow, pwsave);
for (int l = 0; l < npts; l++)
retval ((l + k*npts)*stride + j*dist) = prow[l];
}
}
stride *= dv2(i);
}
return retval;
}
ComplexNDArray
NDArray::ifourier2d (void) const
{
dim_vector dv = dims();
dim_vector dv2 (dv(0), dv(1));
int rank = 2;
ComplexNDArray retval (*this);
int stride = 1;
for (int i = 0; i < rank; i++)
{
int npts = dv2(i);
int nn = 4*npts+15;
Array<Complex> wsave (nn);
Complex *pwsave = wsave.fortran_vec ();
Array<Complex> row (npts);
Complex *prow = row.fortran_vec ();
int howmany = numel () / npts;
howmany = (stride == 1 ? howmany :
(howmany > stride ? stride : howmany));
int nloop = (stride == 1 ? 1 : numel () / npts / stride);
int dist = (stride == 1 ? npts : 1);
F77_FUNC (cffti, CFFTI) (npts, pwsave);
for (int k = 0; k < nloop; k++)
{
for (int j = 0; j < howmany; j++)
{
OCTAVE_QUIT;
for (int l = 0; l < npts; l++)
prow[l] = retval ((l + k*npts)*stride + j*dist);
F77_FUNC (cfftb, CFFTB) (npts, prow, pwsave);
for (int l = 0; l < npts; l++)
retval ((l + k*npts)*stride + j*dist) = prow[l] /
static_cast<double> (npts);
}
}
stride *= dv2(i);
}
return retval;
}
ComplexNDArray
NDArray::fourierNd (void) const
{
dim_vector dv = dims ();
int rank = dv.length ();
ComplexNDArray retval (*this);
int stride = 1;
for (int i = 0; i < rank; i++)
{
int npts = dv(i);
int nn = 4*npts+15;
Array<Complex> wsave (nn);
Complex *pwsave = wsave.fortran_vec ();
Array<Complex> row (npts);
Complex *prow = row.fortran_vec ();
int howmany = numel () / npts;
howmany = (stride == 1 ? howmany :
(howmany > stride ? stride : howmany));
int nloop = (stride == 1 ? 1 : numel () / npts / stride);
int dist = (stride == 1 ? npts : 1);
F77_FUNC (cffti, CFFTI) (npts, pwsave);
for (int k = 0; k < nloop; k++)
{
for (int j = 0; j < howmany; j++)
{
OCTAVE_QUIT;
for (int l = 0; l < npts; l++)
prow[l] = retval ((l + k*npts)*stride + j*dist);
F77_FUNC (cfftf, CFFTF) (npts, prow, pwsave);
for (int l = 0; l < npts; l++)
retval ((l + k*npts)*stride + j*dist) = prow[l];
}
}
stride *= dv(i);
}
return retval;
}
ComplexNDArray
NDArray::ifourierNd (void) const
{
dim_vector dv = dims ();
int rank = dv.length ();
ComplexNDArray retval (*this);
int stride = 1;
for (int i = 0; i < rank; i++)
{
int npts = dv(i);
int nn = 4*npts+15;
Array<Complex> wsave (nn);
Complex *pwsave = wsave.fortran_vec ();
Array<Complex> row (npts);
Complex *prow = row.fortran_vec ();
int howmany = numel () / npts;
howmany = (stride == 1 ? howmany :
(howmany > stride ? stride : howmany));
int nloop = (stride == 1 ? 1 : numel () / npts / stride);
int dist = (stride == 1 ? npts : 1);
F77_FUNC (cffti, CFFTI) (npts, pwsave);
for (int k = 0; k < nloop; k++)
{
for (int j = 0; j < howmany; j++)
{
OCTAVE_QUIT;
for (int l = 0; l < npts; l++)
prow[l] = retval ((l + k*npts)*stride + j*dist);
F77_FUNC (cfftb, CFFTB) (npts, prow, pwsave);
for (int 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
NDArray::operator ! (void) const
{
boolNDArray b (dims ());
for (int i = 0; i < length (); i++)
b.elem (i) = ! elem (i);
return b;
}
bool
NDArray::any_element_is_negative (bool neg_zero) const
{
int nel = nelem ();
if (neg_zero)
{
for (int i = 0; i < nel; i++)
if (lo_ieee_signbit (elem (i)))
return true;
}
else
{
for (int i = 0; i < nel; i++)
if (elem (i) < 0)
return true;
}
return false;
}
bool
NDArray::any_element_is_inf_or_nan (void) const
{
int nel = nelem ();
for (int i = 0; i < nel; i++)
{
double val = elem (i);
if (xisinf (val) || xisnan (val))
return true;
}
return false;
}
bool
NDArray::all_elements_are_int_or_inf_or_nan (void) const
{
int nel = nelem ();
for (int i = 0; i < nel; i++)
{
double val = elem (i);
if (xisnan (val) || D_NINT (val) == val)
continue;
else
return false;
}
return true;
}
// Return nonzero if any element of M is not an integer. Also extract
// the largest and smallest values and return them in MAX_VAL and MIN_VAL.
bool
NDArray::all_integers (double& max_val, double& min_val) const
{
int nel = nelem ();
if (nel > 0)
{
max_val = elem (0);
min_val = elem (0);
}
else
return false;
for (int i = 0; i < nel; i++)
{
double val = elem (i);
if (val > max_val)
max_val = val;
if (val < min_val)
min_val = val;
if (D_NINT (val) != val)
return false;
}
return true;
}
bool
NDArray::too_large_for_float (void) const
{
int nel = nelem ();
for (int i = 0; i < nel; i++)
{
double val = elem (i);
if (! (octave_is_NaN_or_NA (val) || xisinf (val))
&& fabs (val) > FLT_MAX)
return true;
}
return false;
}
// XXX FIXME XXX -- this is not quite the right thing.
boolNDArray
NDArray::all (int dim) const
{
MX_ND_ANY_ALL_REDUCTION (MX_ND_ALL_EVAL (MX_ND_ALL_EXPR), true);
}
boolNDArray
NDArray::any (int dim) const
{
MX_ND_ANY_ALL_REDUCTION
(MX_ND_ANY_EVAL (elem (iter_idx) != 0
&& ! lo_ieee_isnan (elem (iter_idx))), false);
}
NDArray
NDArray::cumprod (int dim) const
{
MX_ND_CUMULATIVE_OP (NDArray, double, 1, *);
}
NDArray
NDArray::cumsum (int dim) const
{
MX_ND_CUMULATIVE_OP (NDArray, double, 0, +);
}
NDArray
NDArray::prod (int dim) const
{
MX_ND_REAL_OP_REDUCTION (*= elem (iter_idx), 1);
}
NDArray
NDArray::sumsq (int dim) const
{
MX_ND_REAL_OP_REDUCTION (+= std::pow (elem (iter_idx), 2), 0);
}
NDArray
NDArray::sum (int dim) const
{
MX_ND_REAL_OP_REDUCTION (+= elem (iter_idx), 0);
}
NDArray
NDArray::max (int dim) const
{
ArrayN<int> dummy_idx;
return max (dummy_idx, dim);
}
NDArray
NDArray::max (ArrayN<int>& idx_arg, int dim) const
{
dim_vector dv = dims ();
dim_vector dr = dims ();
if (dv.numel () == 0 || dim > dv.length () || dim < 0)
return NDArray ();
dr(dim) = 1;
NDArray result (dr);
idx_arg.resize (dr);
int x_stride = 1;
int x_len = dv(dim);
for (int i = 0; i < dim; i++)
x_stride *= dv(i);
for (int i = 0; i < dr.numel (); i++)
{
int x_offset;
if (x_stride == 1)
x_offset = i * x_len;
else
{
int x_offset2 = 0;
x_offset = i;
while (x_offset >= x_stride)
{
x_offset -= x_stride;
x_offset2++;
}
x_offset += x_offset2 * x_stride * x_len;
}
int idx_j;
double tmp_max = octave_NaN;
for (idx_j = 0; idx_j < x_len; idx_j++)
{
tmp_max = elem (idx_j * x_stride + x_offset);
if (! octave_is_NaN_or_NA (tmp_max))
break;
}
for (int j = idx_j+1; j < x_len; j++)
{
double tmp = elem (j * x_stride + x_offset);
if (octave_is_NaN_or_NA (tmp))
continue;
else if (tmp > tmp_max)
{
idx_j = j;
tmp_max = tmp;
}
}
result.elem (i) = tmp_max;
idx_arg.elem (i) = octave_is_NaN_or_NA (tmp_max) ? 0 : idx_j;
}
return result;
}
NDArray
NDArray::min (int dim) const
{
ArrayN<int> dummy_idx;
return min (dummy_idx, dim);
}
NDArray
NDArray::min (ArrayN<int>& idx_arg, int dim) const
{
dim_vector dv = dims ();
dim_vector dr = dims ();
if (dv.numel () == 0 || dim > dv.length () || dim < 0)
return NDArray ();
dr(dim) = 1;
NDArray result (dr);
idx_arg.resize (dr);
int x_stride = 1;
int x_len = dv(dim);
for (int i = 0; i < dim; i++)
x_stride *= dv(i);
for (int i = 0; i < dr.numel (); i++)
{
int x_offset;
if (x_stride == 1)
x_offset = i * x_len;
else
{
int x_offset2 = 0;
x_offset = i;
while (x_offset >= x_stride)
{
x_offset -= x_stride;
x_offset2++;
}
x_offset += x_offset2 * x_stride * x_len;
}
int idx_j;
double tmp_min = octave_NaN;
for (idx_j = 0; idx_j < x_len; idx_j++)
{
tmp_min = elem (idx_j * x_stride + x_offset);
if (! octave_is_NaN_or_NA (tmp_min))
break;
}
for (int j = idx_j+1; j < x_len; j++)
{
double tmp = elem (j * x_stride + x_offset);
if (octave_is_NaN_or_NA (tmp))
continue;
else if (tmp < tmp_min)
{
idx_j = j;
tmp_min = tmp;
}
}
result.elem (i) = tmp_min;
idx_arg.elem (i) = octave_is_NaN_or_NA (tmp_min) ? 0 : idx_j;
}
return result;
}
NDArray
NDArray::concat (const NDArray& rb, const Array<int>& ra_idx)
{
if (rb.numel () > 0)
insert (rb, ra_idx);
return *this;
}
ComplexNDArray
NDArray::concat (const ComplexNDArray& rb, const Array<int>& ra_idx)
{
ComplexNDArray retval (*this);
if (rb.numel () > 0)
retval.insert (rb, ra_idx);
return retval;
}
charNDArray
NDArray::concat (const charNDArray& rb, const Array<int>& ra_idx)
{
charNDArray retval (dims ());
int nel = numel ();
for (int i = 0; i < nel; i++)
{
double d = elem (i);
if (xisnan (d))
{
(*current_liboctave_error_handler)
("invalid conversion from NaN to character");
return retval;
}
else
{
int ival = NINT (d);
if (ival < 0 || ival > UCHAR_MAX)
// XXX FIXME XXX -- is there something
// better we could do? Should we warn the user?
ival = 0;
retval.elem (i) = static_cast<char>(ival);
}
}
if (rb.numel () == 0)
return retval;
retval.insert (rb, ra_idx);
return retval;
}
NDArray
real (const ComplexNDArray& a)
{
int a_len = a.length ();
NDArray retval;
if (a_len > 0)
retval = NDArray (mx_inline_real_dup (a.data (), a_len), a.dims ());
return retval;
}
NDArray
imag (const ComplexNDArray& a)
{
int a_len = a.length ();
NDArray retval;
if (a_len > 0)
retval = NDArray (mx_inline_imag_dup (a.data (), a_len), a.dims ());
return retval;
}
NDArray&
NDArray::insert (const NDArray& a, int r, int c)
{
Array<double>::insert (a, r, c);
return *this;
}
NDArray&
NDArray::insert (const NDArray& a, const Array<int>& ra_idx)
{
Array<double>::insert (a, ra_idx);
return *this;
}
NDArray
NDArray::abs (void) const
{
NDArray retval (dims ());
int nel = nelem ();
for (int i = 0; i < nel; i++)
retval(i) = fabs (elem (i));
return retval;
}
Matrix
NDArray::matrix_value (void) const
{
Matrix retval;
int nd = ndims ();
switch (nd)
{
case 1:
retval = Matrix (Array2<double> (*this, dimensions(0), 1));
break;
case 2:
retval = Matrix (Array2<double> (*this, dimensions(0), dimensions(1)));
break;
default:
(*current_liboctave_error_handler)
("invalid conversion of NDArray to Matrix");
break;
}
return retval;
}
void
NDArray::increment_index (Array<int>& ra_idx,
const dim_vector& dimensions,
int start_dimension)
{
::increment_index (ra_idx, dimensions, start_dimension);
}
int
NDArray::compute_index (Array<int>& ra_idx,
const dim_vector& dimensions)
{
return ::compute_index (ra_idx, dimensions);
}
// This contains no information on the array structure !!!
std::ostream&
operator << (std::ostream& os, const NDArray& a)
{
int nel = a.nelem ();
for (int i = 0; i < nel; i++)
{
os << " ";
octave_write_double (os, a.elem (i));
os << "\n";
}
return os;
}
std::istream&
operator >> (std::istream& is, NDArray& a)
{
int nel = a.nelem ();
if (nel < 1 )
is.clear (std::ios::badbit);
else
{
double tmp;
for (int i = 0; i < nel; i++)
{
tmp = octave_read_double (is);
if (is)
a.elem (i) = tmp;
else
goto done;
}
}
done:
return is;
}
// XXX FIXME XXX -- it would be nice to share code among the min/max
// functions below.
#define EMPTY_RETURN_CHECK(T) \
if (nel == 0) \
return T (dv);
NDArray
min (double d, const NDArray& m)
{
dim_vector dv = m.dims ();
int nel = dv.numel ();
EMPTY_RETURN_CHECK (NDArray);
NDArray result (dv);
for (int i = 0; i < nel; i++)
{
OCTAVE_QUIT;
result (i) = xmin (d, m (i));
}
return result;
}
NDArray
min (const NDArray& m, double d)
{
dim_vector dv = m.dims ();
int nel = dv.numel ();
EMPTY_RETURN_CHECK (NDArray);
NDArray result (dv);
for (int i = 0; i < nel; i++)
{
OCTAVE_QUIT;
result (i) = xmin (d, m (i));
}
return result;
}
NDArray
min (const NDArray& a, const NDArray& b)
{
dim_vector dv = a.dims ();
int nel = dv.numel ();
if (dv != b.dims ())
{
(*current_liboctave_error_handler)
("two-arg min expecting args of same size");
return NDArray ();
}
EMPTY_RETURN_CHECK (NDArray);
NDArray result (dv);
for (int i = 0; i < nel; i++)
{
OCTAVE_QUIT;
result (i) = xmin (a (i), b (i));
}
return result;
}
NDArray
max (double d, const NDArray& m)
{
dim_vector dv = m.dims ();
int nel = dv.numel ();
EMPTY_RETURN_CHECK (NDArray);
NDArray result (dv);
for (int i = 0; i < nel; i++)
{
OCTAVE_QUIT;
result (i) = xmax (d, m (i));
}
return result;
}
NDArray
max (const NDArray& m, double d)
{
dim_vector dv = m.dims ();
int nel = dv.numel ();
EMPTY_RETURN_CHECK (NDArray);
NDArray result (dv);
for (int i = 0; i < nel; i++)
{
OCTAVE_QUIT;
result (i) = xmax (d, m (i));
}
return result;
}
NDArray
max (const NDArray& a, const NDArray& b)
{
dim_vector dv = a.dims ();
int nel = dv.numel ();
if (dv != b.dims ())
{
(*current_liboctave_error_handler)
("two-arg max expecting args of same size");
return NDArray ();
}
EMPTY_RETURN_CHECK (NDArray);
NDArray result (dv);
for (int i = 0; i < nel; i++)
{
OCTAVE_QUIT;
result (i) = xmax (a (i), b (i));
}
return result;
}
NDS_CMP_OPS(NDArray, , double, )
NDS_BOOL_OPS(NDArray, double, 0.0)
SND_CMP_OPS(double, , NDArray, )
SND_BOOL_OPS(double, NDArray, 0.0)
NDND_CMP_OPS(NDArray, , NDArray, )
NDND_BOOL_OPS(NDArray, NDArray, 0.0)
/*
;;; Local Variables: ***
;;; mode: C++ ***
;;; End: ***
*/
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