/usr/include/octave-3.8.1/octave/dim-vector.h is in liboctave-dev 3.8.1-1ubuntu1.
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) 2003-2013 John W. Eaton
Copyirght (C) 2009, 2010 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_dim_vector_h)
#define octave_dim_vector_h 1
#include <cassert>
#include <limits>
#include <sstream>
#include <string>
#include "lo-error.h"
#include "lo-macros.h"
#include "oct-refcount.h"
// Rationale: This implementation is more tricky than Array, but the
// big plus is that dim_vector requires only one allocation instead of
// two. It is (slightly) patterned after GCC's basic_string
// implementation. rep is a pointer to an array of memory, comprising
// count, length, and the data:
//
// <count>
// <ndims>
// rep --> <dims[0]>
// <dims[1]>
// ...
//
// The inlines count(), ndims() recover this data from the rep. Note
// that rep points to the beginning of dims to grant faster access
// (reinterpret_cast is assumed to be an inexpensive operation).
class
OCTAVE_API
dim_vector
{
private:
octave_idx_type *rep;
octave_idx_type& ndims (void) const { return rep[-1]; }
octave_idx_type& count (void) const { return rep[-2]; }
// Construct a new rep with count = 1 and ndims given.
static octave_idx_type *newrep (int ndims)
{
octave_idx_type *r = new octave_idx_type [ndims + 2];
*r++ = 1;
*r++ = ndims;
return r;
}
// Clone this->rep.
octave_idx_type *clonerep (void)
{
int l = ndims ();
octave_idx_type *r = new octave_idx_type [l + 2];
*r++ = 1;
*r++ = l;
for (int i = 0; i < l; i++)
r[i] = rep[i];
return r;
}
// Clone and resize this->rep to length n, filling by given value.
octave_idx_type *resizerep (int n, octave_idx_type fill_value)
{
int l = ndims ();
if (n < 2)
n = 2;
octave_idx_type *r = new octave_idx_type [n + 2];
*r++ = 1;
*r++ = n;
if (l > n)
l = n;
int j;
for (j = 0; j < l; j++)
r[j] = rep[j];
for (; j < n; j++)
r[j] = fill_value;
return r;
}
// Free the rep.
void freerep (void)
{
assert (count () == 0);
delete [] (rep - 2);
}
void make_unique (void)
{
if (count () > 1)
{
octave_idx_type *new_rep = clonerep ();
if (OCTREFCOUNT_ATOMIC_DECREMENT(&(count())) == 0)
freerep ();
rep = new_rep;
}
}
public:
// The constructor
//
// dim_vector (n)
//
// creates an dimension vector with N rows and 1 column. It is
// deprecated because of the potentiol for confusion that it causes.
// Additional constructors of the form
//
// dim_vector (r, c)
// dim_vector (r, c, p)
// dim_vector (d1, d2, d3, d4, ...)
//
// are available for up to 7 dimensions.
explicit dim_vector (octave_idx_type n) GCC_ATTR_DEPRECATED
: rep (newrep (2))
{
rep[0] = n;
rep[1] = 1;
}
#define ASSIGN_REP(i) rep[i] = d ## i;
#define DIM_VECTOR_CTOR(N) \
dim_vector (OCT_MAKE_DECL_LIST (octave_idx_type, d, N)) \
: rep (newrep (N)) \
{ \
OCT_ITERATE_MACRO (ASSIGN_REP, N) \
}
// Add more if needed.
DIM_VECTOR_CTOR (2)
DIM_VECTOR_CTOR (3)
DIM_VECTOR_CTOR (4)
DIM_VECTOR_CTOR (5)
DIM_VECTOR_CTOR (6)
DIM_VECTOR_CTOR (7)
#undef ASSIGN_REP
#undef DIM_VECTOR_CTOR
octave_idx_type& elem (int i)
{
#ifdef BOUNDS_CHECKING
assert (i >= 0 && i < ndims ());
#endif
make_unique ();
return rep[i];
}
octave_idx_type elem (int i) const
{
#ifdef BOUNDS_CHECKING
assert (i >= 0 && i < ndims ());
#endif
return rep[i];
}
void chop_trailing_singletons (void)
{
int l = ndims ();
if (l > 2 && rep[l-1] == 1)
{
make_unique ();
do
l--;
while (l > 2 && rep[l-1] == 1);
ndims () = l;
}
}
void chop_all_singletons (void);
// WARNING: Only call by jit
octave_idx_type *to_jit (void) const
{
return rep;
}
private:
static octave_idx_type *nil_rep (void)
{
static dim_vector zv (0, 0);
return zv.rep;
}
public:
static octave_idx_type dim_max (void);
explicit dim_vector (void) : rep (nil_rep ())
{ OCTREFCOUNT_ATOMIC_INCREMENT (&(count())); }
dim_vector (const dim_vector& dv) : rep (dv.rep)
{ OCTREFCOUNT_ATOMIC_INCREMENT (&(count())); }
// FIXME: Should be private, but required by array constructor for jit
explicit dim_vector (octave_idx_type *r) : rep (r) { }
static dim_vector alloc (int n)
{
return dim_vector (newrep (n < 2 ? 2 : n));
}
dim_vector& operator = (const dim_vector& dv)
{
if (&dv != this)
{
if (OCTREFCOUNT_ATOMIC_DECREMENT (&(count())) == 0)
freerep ();
rep = dv.rep;
OCTREFCOUNT_ATOMIC_INCREMENT (&(count()));
}
return *this;
}
~dim_vector (void)
{
if (OCTREFCOUNT_ATOMIC_DECREMENT (&(count())) == 0)
freerep ();
}
int length (void) const { return ndims (); }
octave_idx_type& operator () (int i) { return elem (i); }
octave_idx_type operator () (int i) const { return elem (i); }
void resize (int n, int fill_value = 0)
{
int len = length ();
if (n != len)
{
octave_idx_type *r = resizerep (n, fill_value);
if (OCTREFCOUNT_ATOMIC_DECREMENT (&(count())) == 0)
freerep ();
rep = r;
}
}
std::string str (char sep = 'x') const;
bool all_zero (void) const
{
bool retval = true;
for (int i = 0; i < length (); i++)
{
if (elem (i) != 0)
{
retval = false;
break;
}
}
return retval;
}
bool empty_2d (void) const
{
return length () == 2 && (elem (0) == 0 || elem (1) == 0);
}
bool zero_by_zero (void) const
{
return length () == 2 && elem (0) == 0 && elem (1) == 0;
}
bool any_zero (void) const
{
bool retval = false;
for (int i = 0; i < length (); i++)
{
if (elem (i) == 0)
{
retval = true;
break;
}
}
return retval;
}
int num_ones (void) const;
bool all_ones (void) const
{
return (num_ones () == length ());
}
// Return the number of elements that a matrix with this dimension
// vector would have, NOT the number of dimensions (elements in the
// dimension vector).
octave_idx_type numel (int n = 0) const
{
int n_dims = length ();
octave_idx_type retval = 1;
for (int i = n; i < n_dims; i++)
retval *= elem (i);
return retval;
}
// The following function will throw a std::bad_alloc ()
// exception if the requested size is larger than can be indexed by
// octave_idx_type. This may be smaller than the actual amount of
// memory that can be safely allocated on a system. However, if we
// don't fail here, we can end up with a mysterious crash inside a
// function that is iterating over an array using octave_idx_type
// indices.
octave_idx_type safe_numel (void) const;
bool any_neg (void) const
{
int n_dims = length ();
int i;
for (i = 0; i < n_dims; i++)
if (elem (i) < 0)
break;
return i < n_dims;
}
dim_vector squeeze (void) const;
// This corresponds to cat().
bool concat (const dim_vector& dvb, int dim);
// This corresponds to [,] (horzcat, dim = 0) and [;] (vertcat, dim = 1).
// The rules are more relaxed here.
bool hvcat (const dim_vector& dvb, int dim);
// Force certain dimensionality, preserving numel (). Missing
// dimensions are set to 1, redundant are folded into the trailing
// one. If n = 1, the result is 2d and the second dim is 1
// (dim_vectors are always at least 2D).
dim_vector redim (int n) const;
dim_vector as_column (void) const
{
if (length () == 2 && elem (1) == 1)
return *this;
else
return dim_vector (numel (), 1);
}
dim_vector as_row (void) const
{
if (length () == 2 && elem (0) == 1)
return *this;
else
return dim_vector (1, numel ());
}
bool is_vector (void) const
{
return (length () == 2 && (elem (0) == 1 || elem (1) == 1));
}
int first_non_singleton (int def = 0) const
{
for (int i = 0; i < length (); i++)
{
if (elem (i) != 1)
return i;
}
return def;
}
// Compute a linear index from an index tuple.
octave_idx_type compute_index (const octave_idx_type *idx) const
{
octave_idx_type k = 0;
for (int i = length () - 1; i >= 0; i--)
k = k * rep[i] + idx[i];
return k;
}
// Ditto, but the tuple may be incomplete (nidx < length ()).
octave_idx_type compute_index (const octave_idx_type *idx, int nidx) const
{
octave_idx_type k = 0;
for (int i = nidx - 1; i >= 0; i--)
k = k * rep[i] + idx[i];
return k;
}
// Increment a multi-dimensional index tuple, optionally starting
// from an offset position and return the index of the last index
// position that was changed, or length () if just cycled over.
int increment_index (octave_idx_type *idx, int start = 0) const
{
int i;
for (i = start; i < length (); i++)
{
if (++(*idx) == rep[i])
*idx++ = 0;
else
break;
}
return i;
}
// Return cumulative dimensions.
dim_vector cumulative (void) const
{
int nd = length ();
dim_vector retval = alloc (nd);
octave_idx_type k = 1;
for (int i = 0; i < nd; i++)
retval.rep[i] = k *= rep[i];
return retval;
}
// Compute a linear index from an index tuple. Dimensions are
// required to be cumulative.
octave_idx_type cum_compute_index (const octave_idx_type *idx) const
{
octave_idx_type k = idx[0];
for (int i = 1; i < length (); i++)
k += rep[i-1] * idx[i];
return k;
}
friend bool operator == (const dim_vector& a, const dim_vector& b);
};
inline bool
operator == (const dim_vector& a, const dim_vector& b)
{
// Fast case.
if (a.rep == b.rep)
return true;
bool retval = true;
int a_len = a.length ();
int b_len = b.length ();
if (a_len != b_len)
retval = false;
else
{
for (int i = 0; i < a_len; i++)
{
if (a(i) != b(i))
{
retval = false;
break;
}
}
}
return retval;
}
inline bool
operator != (const dim_vector& a, const dim_vector& b)
{
return ! operator == (a, b);
}
#endif
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