/usr/include/octave-4.2.2/octave/oct-binmap.h is in liboctave-dev 4.2.2-1ubuntu1.
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) 2010-2017 VZLU Prague
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_oct_binmap_h)
#define octave_oct_binmap_h 1
#include "octave-config.h"
#include "Array.h"
#include "Sparse.h"
#include "Array-util.h"
#include "bsxfun.h"
// This source file implements a general binary maping function for arrays.
// The syntax is binmap<type> (a, b, f,[name]).
// type denotes the expected return type of the operation.
// a, b, should be one of the 6 combinations:
//
// Array-Array
// Array-scalar
// scalar-Array
// Sparse-Sparse
// Sparse-scalar
// scalar-Sparse
//
// If both operands are nonscalar, name must be supplied. It is used
// as the base for error message when operands are nonconforming.
//
// The operation needs not be homogeneous, i.e., a, b and the result
// may be of distinct types. f can have any of the four signatures:
//
// U f (T, R)
// U f (const T&, R)
// U f (T, const R&)
// U f (const T&, const R&)
//
// Additionally, f can be an arbitrary functor object.
//
// octave_quit() is called at appropriate places, hence the operation
// is breakable.
// The following template wrappers are provided for automatic bsxfun
// calls (see the function signature for do_bsxfun_op).
template <typename R, typename X, typename Y, typename F>
class bsxfun_wrapper
{
private:
static F f;
public:
static void
set_f (const F& f_in)
{
f = f_in;
}
static void
op_mm (size_t n, R* r, const X* x , const Y* y)
{
for (size_t i = 0; i < n; i++)
r[i] = f (x[i], y[i]);
}
static void
op_sm (size_t n, R* r, X x, const Y* y)
{
for (size_t i = 0; i < n; i++)
r[i] = f (x, y[i]);
}
static void
op_ms (size_t n , R* r, const X* x, Y y)
{
for (size_t i = 0; i < n; i++)
r[i] = f (x[i], y);
}
};
// Static init
template <typename R, typename X, typename Y, typename F>
F bsxfun_wrapper<R, X, Y, F>::f;
// scalar-Array
template <typename U, typename T, typename R, typename F>
Array<U>
binmap (const T& x, const Array<R>& ya, F fcn)
{
octave_idx_type len = ya.numel ();
const R *y = ya.data ();
Array<U> result (ya.dims ());
U *p = result.fortran_vec ();
octave_idx_type i;
for (i = 0; i < len - 3; i += 4)
{
octave_quit ();
p[i] = fcn (x, y[i]);
p[i+1] = fcn (x, y[i+1]);
p[i+2] = fcn (x, y[i+2]);
p[i+3] = fcn (x, y[i+3]);
}
octave_quit ();
for (; i < len; i++)
p[i] = fcn (x, y[i]);
return result;
}
// Array-scalar
template <typename U, typename T, typename R, typename F>
Array<U>
binmap (const Array<T>& xa, const R& y, F fcn)
{
octave_idx_type len = xa.numel ();
const R *x = xa.data ();
Array<U> result (xa.dims ());
U *p = result.fortran_vec ();
octave_idx_type i;
for (i = 0; i < len - 3; i += 4)
{
octave_quit ();
p[i] = fcn (x[i], y);
p[i+1] = fcn (x[i+1], y);
p[i+2] = fcn (x[i+2], y);
p[i+3] = fcn (x[i+3], y);
}
octave_quit ();
for (; i < len; i++)
p[i] = fcn (x[i], y);
return result;
}
// Array-Array (treats singletons as scalars)
template <typename U, typename T, typename R, typename F>
Array<U>
binmap (const Array<T>& xa, const Array<R>& ya, F fcn, const char *name)
{
dim_vector xad = xa.dims ();
dim_vector yad = ya.dims ();
if (xa.numel () == 1)
return binmap<U, T, R, F> (xa(0), ya, fcn);
else if (ya.numel () == 1)
return binmap<U, T, R, F> (xa, ya(0), fcn);
else if (xad != yad)
{
if (! is_valid_bsxfun (name, xad, yad))
octave::err_nonconformant (name, xad, yad);
bsxfun_wrapper<U, T, R, F>::set_f(fcn);
return do_bsxfun_op (xa, ya,
bsxfun_wrapper<U, T, R, F>::op_mm,
bsxfun_wrapper<U, T, R, F>::op_sm,
bsxfun_wrapper<U, T, R, F>::op_ms);
}
octave_idx_type len = xa.numel ();
const T *x = xa.data ();
const T *y = ya.data ();
Array<U> result (xa.dims ());
U *p = result.fortran_vec ();
octave_idx_type i;
for (i = 0; i < len - 3; i += 4)
{
octave_quit ();
p[i] = fcn (x[i], y[i]);
p[i+1] = fcn (x[i+1], y[i+1]);
p[i+2] = fcn (x[i+2], y[i+2]);
p[i+3] = fcn (x[i+3], y[i+3]);
}
octave_quit ();
for (; i < len; i++)
p[i] = fcn (x[i], y[i]);
return result;
}
// scalar-Sparse
template <typename U, typename T, typename R, typename F>
Sparse<U>
binmap (const T& x, const Sparse<R>& ys, F fcn)
{
R yzero = R ();
U fz = fcn (x, yzero);
if (fz == U ()) // Sparsity preserving fcn
{
octave_idx_type nz = ys.nnz ();
Sparse<U> retval (ys.rows (), ys.cols (), nz);
std::copy (ys.ridx (), ys.ridx () + nz, retval.ridx ());
std::copy (ys.cidx (), ys.cidx () + ys.cols () + 1, retval.cidx ());
for (octave_idx_type i = 0; i < nz; i++)
{
octave_quit ();
// FIXME: Could keep track of whether fcn call results in a 0.
// If no zeroes are created could skip maybe_compress()
retval.xdata (i) = fcn (x, ys.data (i));
}
octave_quit ();
retval.maybe_compress (true);
return retval;
}
else
return Sparse<U> (binmap<U, T, R, F> (x, ys.array_value (), fcn));
}
// Sparse-scalar
template <typename U, typename T, typename R, typename F>
Sparse<U>
binmap (const Sparse<T>& xs, const R& y, F fcn)
{
T xzero = T ();
U fz = fcn (xzero, y);
if (fz == U ()) // Sparsity preserving fcn
{
octave_idx_type nz = xs.nnz ();
Sparse<U> retval (xs.rows (), xs.cols (), nz);
std::copy (xs.ridx (), xs.ridx () + nz, retval.ridx ());
std::copy (xs.cidx (), xs.cidx () + xs.cols () + 1, retval.cidx ());
for (octave_idx_type i = 0; i < nz; i++)
{
octave_quit ();
// FIXME: Could keep track of whether fcn call results in a 0.
// If no zeroes are created could skip maybe_compress()
retval.xdata (i) = fcn (xs.data (i), y);
}
octave_quit ();
retval.maybe_compress (true);
return retval;
}
else
return Sparse<U> (binmap<U, T, R, F> (xs.array_value (), y, fcn));
}
// Sparse-Sparse (treats singletons as scalars)
template <typename U, typename T, typename R, typename F>
Sparse<U>
binmap (const Sparse<T>& xs, const Sparse<R>& ys, F fcn, const char *name)
{
if (xs.rows () == 1 && xs.cols () == 1)
return binmap<U, T, R, F> (xs(0,0), ys, fcn);
else if (ys.rows () == 1 && ys.cols () == 1)
return binmap<U, T, R, F> (xs, ys(0,0), fcn);
else if (xs.dims () != ys.dims ())
octave::err_nonconformant (name, xs.dims (), ys.dims ());
T xzero = T ();
R yzero = R ();
U fz = fcn (xzero, yzero);
if (fz == U ())
{
// Sparsity-preserving function. Do it efficiently.
octave_idx_type nr = xs.rows ();
octave_idx_type nc = xs.cols ();
Sparse<T> retval (nr, nc, xs.nnz () + ys.nnz ());
octave_idx_type nz = 0;
for (octave_idx_type j = 0; j < nc; j++)
{
octave_quit ();
octave_idx_type jx = xs.cidx (j);
octave_idx_type jx_max = xs.cidx (j+1);
bool jx_lt_max = jx < jx_max;
octave_idx_type jy = ys.cidx (j);
octave_idx_type jy_max = ys.cidx (j+1);
bool jy_lt_max = jy < jy_max;
while (jx_lt_max || jy_lt_max)
{
if (! jy_lt_max
|| (jx_lt_max && (xs.ridx (jx) < ys.ridx (jy))))
{
retval.xridx (nz) = xs.ridx (jx);
retval.xdata (nz) = fcn (xs.data (jx), yzero);
jx++;
jx_lt_max = jx < jx_max;
}
else if (! jx_lt_max
|| (jy_lt_max && (ys.ridx (jy) < xs.ridx (jx))))
{
retval.xridx (nz) = ys.ridx (jy);
retval.xdata (nz) = fcn (xzero, ys.data (jy));
jy++;
jy_lt_max = jy < jy_max;
}
else
{
retval.xridx (nz) = xs.ridx (jx);
retval.xdata (nz) = fcn (xs.data (jx), ys.data (jy));
jx++;
jx_lt_max = jx < jx_max;
jy++;
jy_lt_max = jy < jy_max;
}
nz++;
}
retval.xcidx (j+1) = nz;
}
retval.maybe_compress (true);
return retval;
}
else
return Sparse<U> (binmap<U, T, R, F> (xs.array_value (), ys.array_value (),
fcn, name));
}
// Overloads for function pointers.
// Signature (T, R)
template <typename U, typename T, typename R>
inline Array<U>
binmap (const Array<T>& xa, const Array<R>& ya, U (*fcn) (T, R),
const char *name)
{ return binmap<U, T, R, U (*) (T, R)> (xa, ya, fcn, name); }
template <typename U, typename T, typename R>
inline Array<U>
binmap (const T& x, const Array<R>& ya, U (*fcn) (T, R))
{ return binmap<U, T, R, U (*) (T, R)> (x, ya, fcn); }
template <typename U, typename T, typename R>
inline Array<U>
binmap (const Array<T>& xa, const R& y, U (*fcn) (T, R))
{ return binmap<U, T, R, U (*) (T, R)> (xa, y, fcn); }
template <typename U, typename T, typename R>
inline Sparse<U>
binmap (const Sparse<T>& xa, const Sparse<R>& ya, U (*fcn) (T, R),
const char *name)
{ return binmap<U, T, R, U (*) (T, R)> (xa, ya, fcn, name); }
template <typename U, typename T, typename R>
inline Sparse<U>
binmap (const T& x, const Sparse<R>& ya, U (*fcn) (T, R))
{ return binmap<U, T, R, U (*) (T, R)> (x, ya, fcn); }
template <typename U, typename T, typename R>
inline Sparse<U>
binmap (const Sparse<T>& xa, const R& y, U (*fcn) (T, R))
{ return binmap<U, T, R, U (*) (T, R)> (xa, y, fcn); }
// Signature (const T&, const R&)
template <typename U, typename T, typename R>
inline Array<U>
binmap (const Array<T>& xa, const Array<R>& ya, U (*fcn) (const T&, const R&),
const char *name)
{ return binmap<U, T, R, U (*) (const T&, const R&)> (xa, ya, fcn, name); }
template <typename U, typename T, typename R>
inline Array<U>
binmap (const T& x, const Array<R>& ya, U (*fcn) (const T&, const R&))
{ return binmap<U, T, R, U (*) (const T&, const R&)> (x, ya, fcn); }
template <typename U, typename T, typename R>
inline Array<U>
binmap (const Array<T>& xa, const R& y, U (*fcn) (const T&, const R&))
{ return binmap<U, T, R, U (*) (const T&, const R&)> (xa, y, fcn); }
template <typename U, typename T, typename R>
inline Sparse<U>
binmap (const Sparse<T>& xa, const Sparse<R>& ya, U (*fcn) (const T&, const R&),
const char *name)
{ return binmap<U, T, R, U (*) (const T&, const R&)> (xa, ya, fcn, name); }
template <typename U, typename T, typename R>
inline Sparse<U>
binmap (const T& x, const Sparse<R>& ya, U (*fcn) (const T&, const R&))
{ return binmap<U, T, R, U (*) (const T&, const R&)> (x, ya, fcn); }
template <typename U, typename T, typename R>
inline Sparse<U>
binmap (const Sparse<T>& xa, const R& y, U (*fcn) (const T&, const R&))
{ return binmap<U, T, R, U (*) (const T&, const R&)> (xa, y, fcn); }
// Signature (const T&, R)
template <typename U, typename T, typename R>
inline Array<U>
binmap (const Array<T>& xa, const Array<R>& ya, U (*fcn) (const T&, R),
const char *name)
{ return binmap<U, T, R, U (*) (const T&, R)> (xa, ya, fcn, name); }
template <typename U, typename T, typename R>
inline Array<U>
binmap (const T& x, const Array<R>& ya, U (*fcn) (const T&, R))
{ return binmap<U, T, R, U (*) (const T&, R)> (x, ya, fcn); }
template <typename U, typename T, typename R>
inline Array<U>
binmap (const Array<T>& xa, const R& y, U (*fcn) (const T&, R))
{ return binmap<U, T, R, U (*) (const T&, R)> (xa, y, fcn); }
template <typename U, typename T, typename R>
inline Sparse<U>
binmap (const Sparse<T>& xa, const Sparse<R>& ya, U (*fcn) (const T&, R),
const char *name)
{ return binmap<U, T, R, U (*) (const T&, R)> (xa, ya, fcn, name); }
template <typename U, typename T, typename R>
inline Sparse<U>
binmap (const T& x, const Sparse<R>& ya, U (*fcn) (const T&, R))
{ return binmap<U, T, R, U (*) (const T&, R)> (x, ya, fcn); }
template <typename U, typename T, typename R>
inline Sparse<U>
binmap (const Sparse<T>& xa, const R& y, U (*fcn) (const T&, R))
{ return binmap<U, T, R, U (*) (const T&, R)> (xa, y, fcn); }
// Signature (T, const R&)
template <typename U, typename T, typename R>
inline Array<U>
binmap (const Array<T>& xa, const Array<R>& ya, U (*fcn) (T, const R&),
const char *name)
{ return binmap<U, T, R, U (*) (T, const R&)> (xa, ya, fcn, name); }
template <typename U, typename T, typename R>
inline Array<U>
binmap (const T& x, const Array<R>& ya, U (*fcn) (T, const R&))
{ return binmap<U, T, R, U (*) (T, const R&)> (x, ya, fcn); }
template <typename U, typename T, typename R>
inline Array<U>
binmap (const Array<T>& xa, const R& y, U (*fcn) (T, const R&))
{ return binmap<U, T, R, U (*) (T, const R&)> (xa, y, fcn); }
template <typename U, typename T, typename R>
inline Sparse<U>
binmap (const Sparse<T>& xa, const Sparse<R>& ya, U (*fcn) (T, const R&),
const char *name)
{ return binmap<U, T, R, U (*) (T, const R&)> (xa, ya, fcn, name); }
template <typename U, typename T, typename R>
inline Sparse<U>
binmap (const T& x, const Sparse<R>& ya, U (*fcn) (T, const R&))
{ return binmap<U, T, R, U (*) (T, const R&)> (x, ya, fcn); }
template <typename U, typename T, typename R>
inline Sparse<U>
binmap (const Sparse<T>& xa, const R& y, U (*fcn) (T, const R&))
{ return binmap<U, T, R, U (*) (T, const R&)> (xa, y, fcn); }
#endif
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