/usr/include/octave-4.0.0/octave/ov-complex.h is in liboctave-dev 4.0.0-3ubuntu9.
This file is owned by root:root, with mode 0o644.
The actual contents of the file can be viewed below.
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Copyright (C) 1996-2015 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 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/>.
*/
#if !defined (octave_ov_complex_h)
#define octave_ov_complex_h 1
#include <cstdlib>
#include <iosfwd>
#include <string>
#include "lo-ieee.h"
#include "mx-base.h"
#include "str-vec.h"
#include "gripes.h"
#include "error.h"
#include "ov-base.h"
#include "ov-cx-mat.h"
#include "ov-base-scalar.h"
#include "ov-typeinfo.h"
class octave_value_list;
class tree_walker;
// Complex scalar values.
class
OCTINTERP_API
octave_complex : public octave_base_scalar<Complex>
{
public:
octave_complex (void)
: octave_base_scalar<Complex> () { }
octave_complex (const Complex& c)
: octave_base_scalar<Complex> (c) { }
octave_complex (const octave_complex& c)
: octave_base_scalar<Complex> (c) { }
~octave_complex (void) { }
octave_base_value *clone (void) const { return new octave_complex (*this); }
// We return an octave_complex_matrix object here instead of an
// octave_complex object so that in expressions like A(2,2,2) = 2
// (for A previously undefined), A will be empty instead of a 1x1
// object.
octave_base_value *empty_clone (void) const
{ return new octave_complex_matrix (); }
type_conv_info numeric_demotion_function (void) const;
octave_base_value *try_narrowing_conversion (void);
octave_value do_index_op (const octave_value_list& idx,
bool resize_ok = false);
// Use this to give a more specific error message
idx_vector index_vector (bool /* require_integers */ = false) const
{
error ("attempted to use a complex scalar as an index\n"
" (forgot to initialize i or j?)");
return idx_vector ();
}
octave_value any (int = 0) const
{
return (scalar != Complex (0, 0)
&& ! (lo_ieee_isnan (std::real (scalar))
|| lo_ieee_isnan (std::imag (scalar))));
}
builtin_type_t builtin_type (void) const { return btyp_complex; }
bool is_complex_scalar (void) const { return true; }
bool is_complex_type (void) const { return true; }
bool is_double_type (void) const { return true; }
bool is_float_type (void) const { return true; }
double double_value (bool = false) const;
float float_value (bool = false) const;
double scalar_value (bool frc_str_conv = false) const
{ return double_value (frc_str_conv); }
float float_scalar_value (bool frc_str_conv = false) const
{ return float_value (frc_str_conv); }
Matrix matrix_value (bool = false) const;
FloatMatrix float_matrix_value (bool = false) const;
NDArray array_value (bool = false) const;
FloatNDArray float_array_value (bool = false) const;
SparseMatrix sparse_matrix_value (bool = false) const
{ return SparseMatrix (matrix_value ()); }
SparseComplexMatrix sparse_complex_matrix_value (bool = false) const
{ return SparseComplexMatrix (complex_matrix_value ()); }
octave_value resize (const dim_vector& dv, bool fill = false) const;
Complex complex_value (bool = false) const;
FloatComplex float_complex_value (bool = false) const;
ComplexMatrix complex_matrix_value (bool = false) const;
FloatComplexMatrix float_complex_matrix_value (bool = false) const;
ComplexNDArray complex_array_value (bool = false) const;
FloatComplexNDArray float_complex_array_value (bool = false) const;
bool bool_value (bool warn = false) const
{
if (xisnan (scalar))
gripe_nan_to_logical_conversion ();
else if (warn && scalar != 0.0 && scalar != 1.0)
gripe_logical_conversion ();
return scalar != 0.0;
}
boolNDArray bool_array_value (bool warn = false) const
{
if (xisnan (scalar))
gripe_nan_to_logical_conversion ();
else if (warn && scalar != 0.0 && scalar != 1.0)
gripe_logical_conversion ();
return boolNDArray (dim_vector (1, 1), scalar != 0.0);
}
octave_value diag (octave_idx_type m, octave_idx_type n) const;
void increment (void) { scalar += 1.0; }
void decrement (void) { scalar -= 1.0; }
bool save_ascii (std::ostream& os);
bool load_ascii (std::istream& is);
bool save_binary (std::ostream& os, bool& save_as_floats);
bool load_binary (std::istream& is, bool swap,
oct_mach_info::float_format fmt);
bool save_hdf5 (octave_hdf5_id loc_id, const char *name, bool save_as_floats);
bool load_hdf5 (octave_hdf5_id loc_id, const char *name);
int write (octave_stream& os, int block_size,
oct_data_conv::data_type output_type, int skip,
oct_mach_info::float_format flt_fmt) const
{
// Yes, for compatibility, we drop the imaginary part here.
return os.write (array_value (true), block_size, output_type,
skip, flt_fmt);
}
mxArray *as_mxArray (void) const;
octave_value map (unary_mapper_t umap) const;
private:
DECLARE_OV_TYPEID_FUNCTIONS_AND_DATA
};
typedef octave_complex octave_complex_scalar;
#endif
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