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update Octave Project Developers copyright for the new year In files that have the "Octave Project Developers" copyright notice, update for 2021. In all .txi and .texi files except gpl.txi and gpl.texi in the doc/liboctave and doc/interpreter directories, change the copyright to "Octave Project Developers", the same as used for other source files. Update copyright notices for 2022 (not done since 2019). For gpl.txi and gpl.texi, change the copyright notice to be "Free Software Foundation, Inc." and leave the date at 2007 only because this file only contains the text of the GPL, not anything created by the Octave Project Developers. Add Paul Thomas to contributors.in.
author John W. Eaton <jwe@octave.org>
date Tue, 28 Dec 2021 18:22:40 -0500
parents adda9f3ac61f
children aac27ad79be6
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////////////////////////////////////////////////////////////////////////
//
// Copyright (C) 1994-2022 The Octave Project Developers
//
// See the file COPYRIGHT.md in the top-level directory of this
// distribution or <https://octave.org/copyright/>.
//
// 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
// <https://www.gnu.org/licenses/>.
//
////////////////////////////////////////////////////////////////////////

#if ! defined (octave_oct_map_h)
#define octave_oct_map_h 1

#include "octave-config.h"

#include <algorithm>
#include <map>

#include "oct-refcount.h"

#include "Cell.h"
#include "ovl.h"

class string_vector;

// A class holding a map field->index.  Supports reference-counting.
class OCTINTERP_API
octave_fields
{
  class fields_rep : public std::map<std::string, octave_idx_type>
  {
  public:
    fields_rep (void) : std::map<std::string, octave_idx_type> (), m_count (1) { }
    fields_rep (const fields_rep& other)
      : std::map<std::string, octave_idx_type> (other), m_count (1) { }

    octave::refcount<octave_idx_type> m_count;

  private:
    fields_rep& operator = (const fields_rep&); // no assignment!
  };

  fields_rep *m_rep;

  static fields_rep *nil_rep (void);

public:

  octave_fields (void) : m_rep (nil_rep ()) { m_rep->m_count++; }
  octave_fields (const string_vector&);
  octave_fields (const char * const *);

  ~octave_fields (void)
  {
    if (--m_rep->m_count == 0)
      delete m_rep;
  }

  void make_unique (void)
  {
    if (m_rep->m_count > 1)
      {
        fields_rep *r = new fields_rep (*m_rep);

        if (--m_rep->m_count == 0)
          delete m_rep;

        m_rep = r;
      }
  }

  octave_fields (const octave_fields& o) : m_rep (o.m_rep) { m_rep->m_count++; }

  octave_fields&
  operator = (const octave_fields& o)
  {
    if (&o != this)
      {
        o.m_rep->m_count++;
        if (--m_rep->m_count == 0)
          delete m_rep;
        m_rep = o.m_rep;
      }

    return *this;
  }

  // constant iteration support. non-const iteration intentionally unsupported.

  typedef std::map<std::string, octave_idx_type>::const_iterator const_iterator;
  typedef const_iterator iterator;

  const_iterator begin (void) const { return m_rep->begin (); }
  const_iterator end (void) const { return m_rep->end (); }

  const_iterator cbegin (void) const { return m_rep->cbegin (); }
  const_iterator cend (void) const { return m_rep->cend (); }

  std::string key (const_iterator p) const { return p->first; }
  octave_idx_type index (const_iterator p) const { return p->second; }

  const_iterator seek (const std::string& k) const
  { return m_rep->find (k); }

  // high-level methods.

  // number of fields.
  octave_idx_type nfields (void) const { return m_rep->size (); }

  // check whether a field exists.
  bool isfield (const std::string& name) const;

  // get index of field.  return -1 if not exist
  octave_idx_type getfield (const std::string& name) const;
  // get index of field.  add if not exist
  octave_idx_type getfield (const std::string& name);
  // remove field and return the index. -1 if didn't exist.
  octave_idx_type rmfield (const std::string& name);

  // order the fields of this map.
  // creates a permutation used to order the fields.
  void orderfields (Array<octave_idx_type>& perm);

  // compares two instances for equality up to order of fields.
  // returns a permutation needed to bring the fields of *other*
  // into the order of *this*.
  bool equal_up_to_order (const octave_fields& other,
                          octave_idx_type *perm) const;

  bool equal_up_to_order (const octave_fields& other,
                          Array<octave_idx_type>& perm) const;

  bool is_same (const octave_fields& other) const
  { return m_rep == other.m_rep; }

  // Returns the fields as a vector of strings.
  string_vector fieldnames (void) const;

  void clear (void)
  {
    *this = octave_fields ();
  }
};

class OCTINTERP_API
octave_scalar_map
{
public:

  octave_scalar_map (const octave_fields& k)
    : m_keys (k), m_vals (k.nfields ()) { }

  octave_scalar_map (void) : m_keys (), m_vals () { }

  octave_scalar_map (const string_vector& k)
    : m_keys (k), m_vals (k.numel ()) { }

  octave_scalar_map (const octave_scalar_map& m)
    : m_keys (m.m_keys), m_vals (m.m_vals) { }

  octave_scalar_map (const std::map<std::string, octave_value>& m);

  octave_scalar_map& operator = (const octave_scalar_map& m)
  {
    m_keys = m.m_keys;
    m_vals = m.m_vals;

    return *this;
  }

  // iteration support.
  // note that both const and non-const iterators are the same.
  // The const/non-const distinction is made by the key & contents method.
  typedef octave_fields::const_iterator const_iterator;
  typedef const_iterator iterator;

  const_iterator begin (void) const { return m_keys.begin (); }
  const_iterator end (void) const { return m_keys.end (); }

  const_iterator cbegin (void) const { return m_keys.cbegin (); }
  const_iterator cend (void) const { return m_keys.cend (); }

  const_iterator seek (const std::string& k) const { return m_keys.seek (k); }

  std::string key (const_iterator p) const
  { return m_keys.key (p); }
  octave_idx_type index (const_iterator p) const
  { return m_keys.index (p); }

  const octave_value& contents (const_iterator p) const
  { return m_vals[m_keys.index (p)]; }

  octave_value& contents (iterator p)
  { return m_vals[m_keys.index (p)]; }

  const octave_value& contents (octave_idx_type i) const
  { return m_vals[i]; }

  octave_value& contents (octave_idx_type i)
  { return m_vals[i]; }

  // number of fields.
  octave_idx_type nfields (void) const { return m_keys.nfields (); }

  // check whether a field exists.
  bool isfield (const std::string& name) const
  { return m_keys.isfield (name); }

  bool contains (const std::string& name) const
  { return isfield (name); }

  string_vector fieldnames (void) const
  { return m_keys.fieldnames (); }

  string_vector keys (void) const
  { return fieldnames (); }

  // get contents of a given field.  empty value if not exist.
  octave_value getfield (const std::string& key) const;

  // set contents of a given field.  add if not exist.
  void setfield (const std::string& key, const octave_value& val);
  void assign (const std::string& k, const octave_value& val)
  { setfield (k, val); }

  // remove a given field.  do nothing if not exist.
  void rmfield (const std::string& key);
  void del (const std::string& k) { rmfield (k); }

  // return a copy with fields ordered, optionally along with permutation.
  octave_scalar_map orderfields (void) const;
  octave_scalar_map orderfields (Array<octave_idx_type>& perm) const;
  octave_scalar_map orderfields (const octave_scalar_map& other,
                                 Array<octave_idx_type>& perm) const;

  // aka getfield/setfield, but the latter returns a reference.
  octave_value contents (const std::string& k) const;
  octave_value& contents (const std::string& k);

  void clear (void)
  {
    m_keys.clear ();
    m_vals.clear ();
  }

  friend class octave_map;

private:

  octave_fields m_keys;
  std::vector<octave_value> m_vals;

};

template <>
inline octave_scalar_map
octave_value_extract<octave_scalar_map> (const octave_value& v)
{ return v.scalar_map_value (); }

class OCTINTERP_API
octave_map
{
public:

  octave_map (const octave_fields& k)
    : m_keys (k), m_vals (k.nfields ()), m_dimensions () { }

  octave_map (const dim_vector& dv, const octave_fields& k)
    : m_keys (k), m_vals (k.nfields (), Cell (dv)), m_dimensions (dv) { }

  typedef octave_scalar_map element_type;

  octave_map (void) : m_keys (), m_vals (), m_dimensions () { }

  octave_map (const dim_vector& dv) : m_keys (), m_vals (), m_dimensions (dv) { }

  octave_map (const string_vector& k)
    : m_keys (k), m_vals (k.numel (), Cell (1, 1)), m_dimensions (1, 1) { }

  octave_map (const dim_vector& dv, const string_vector& k)
    : m_keys (k), m_vals (k.numel (), Cell (dv)), m_dimensions (dv) { }

  octave_map (const octave_map& m)
    : m_keys (m.m_keys), m_vals (m.m_vals), m_dimensions (m.m_dimensions) { }

  octave_map (const octave_scalar_map& m);

  octave_map& operator = (const octave_map& m)
  {
    m_keys = m.m_keys;
    m_vals = m.m_vals;
    m_dimensions = m.m_dimensions;

    return *this;
  }

  // iteration support.
  // note that both const and non-const iterators are the same.
  // The const/non-const distinction is made by the key & contents method.
  typedef octave_fields::const_iterator const_iterator;
  typedef const_iterator iterator;

  const_iterator begin (void) const { return m_keys.begin (); }
  const_iterator end (void) const { return m_keys.end (); }

  const_iterator cbegin (void) const { return m_keys.cbegin (); }
  const_iterator cend (void) const { return m_keys.cend (); }

  const_iterator seek (const std::string& k) const { return m_keys.seek (k); }

  std::string key (const_iterator p) const
  { return m_keys.key (p); }
  octave_idx_type index (const_iterator p) const
  { return m_keys.index (p); }

  const Cell& contents (const_iterator p) const
  { return m_vals[m_keys.index (p)]; }

  Cell& contents (iterator p)
  { return m_vals[m_keys.index (p)]; }

  const Cell& contents (octave_idx_type i) const
  { return m_vals[i]; }

  Cell& contents (octave_idx_type i)
  { return m_vals[i]; }

  // number of fields.
  octave_idx_type nfields (void) const { return m_keys.nfields (); }

  // check whether a field exists.
  bool isfield (const std::string& name) const
  { return m_keys.isfield (name); }

  bool contains (const std::string& name) const
  { return isfield (name); }

  string_vector fieldnames (void) const
  { return m_keys.fieldnames (); }

  string_vector keys (void) const
  { return fieldnames (); }

  // get contents of a given field.  empty value if not exist.
  Cell getfield (const std::string& key) const;

  // set contents of a given field.  add if not exist.  checks for
  // correct m_dimensions.
  void setfield (const std::string& key, const Cell& val);
  void assign (const std::string& k, const Cell& val)
  { setfield (k, val); }

  // remove a given field. do nothing if not exist.
  void rmfield (const std::string& key);
  void del (const std::string& k) { rmfield (k); }

  // return a copy with fields ordered, optionally along with permutation.
  octave_map orderfields (void) const;
  octave_map orderfields (Array<octave_idx_type>& perm) const;
  octave_map orderfields (const octave_map& other,
                          Array<octave_idx_type>& perm) const;

  // aka getfield/setfield, but the latter returns a reference.
  Cell contents (const std::string& k) const;
  Cell& contents (const std::string& k);

  void clear (void)
  {
    m_keys.clear ();
    m_vals.clear ();
  }

  // The Array-like methods.
  octave_idx_type numel (void) const { return m_dimensions.numel (); }
  octave_idx_type length (void) const { return numel (); }
  bool isempty (void) const { return m_dimensions.any_zero (); }

  octave_idx_type rows (void) const { return m_dimensions(0); }
  octave_idx_type cols (void) const { return m_dimensions(1); }
  octave_idx_type columns (void) const { return m_dimensions(1); }

  // Extract a scalar substructure.
  // FIXME: actually check something.
  octave_scalar_map checkelem (octave_idx_type n) const
  { return elem (n); }

  // FIXME: actually check something.
  octave_scalar_map checkelem (octave_idx_type i, octave_idx_type j) const
  { return elem (i, j); }

  // FIXME: actually check something.
  octave_scalar_map checkelem (const Array<octave_idx_type>& ra_idx) const
  { return elem (ra_idx); }

  octave_scalar_map elem (octave_idx_type n) const;

  octave_scalar_map elem (octave_idx_type i, octave_idx_type j) const;

  octave_scalar_map elem (const Array<octave_idx_type>& ra_idx) const;

  octave_scalar_map operator () (octave_idx_type n) const
  { return elem (n); }

  octave_scalar_map operator () (octave_idx_type i, octave_idx_type j) const
  { return elem (i, j); }

  octave_scalar_map
  operator () (const Array<octave_idx_type>& ra_idx) const
  { return elem (ra_idx); }

  octave_map squeeze (void) const;

  octave_map permute (const Array<int>& vec, bool inv = false) const;

  dim_vector dims (void) const { return m_dimensions; }

  int ndims (void) const { return m_dimensions.ndims (); }

  octave_map transpose (void) const;

  octave_map reshape (const dim_vector& dv) const;

  void resize (const dim_vector& dv, bool fill = false);

  static octave_map
  cat (int dim, octave_idx_type n, const octave_scalar_map *map_list);

  static octave_map
  cat (int dim, octave_idx_type n, const octave_map *map_list);

  octave_map index (const octave::idx_vector& i, bool resize_ok = false) const;

  octave_map index (const octave::idx_vector& i, const octave::idx_vector& j,
                    bool resize_ok = false) const;

  octave_map index (const Array<octave::idx_vector>& ia,
                    bool resize_ok = false) const;

  octave_map index (const octave_value_list&, bool resize_ok = false) const;

  octave_map column (octave_idx_type k) const;
  octave_map page (octave_idx_type k) const;

  void assign (const octave::idx_vector& i, const octave_map& rhs);

  void assign (const octave::idx_vector& i, const octave::idx_vector& j,
               const octave_map& rhs);

  void assign (const Array<octave::idx_vector>& ia, const octave_map& rhs);

  void assign (const octave_value_list&, const octave_map& rhs);

  void assign (const octave_value_list& idx, const std::string& k,
               const Cell& rhs);

  void delete_elements (const octave::idx_vector& i);

  void delete_elements (int dim, const octave::idx_vector& i);

  void delete_elements (const Array<octave::idx_vector>& ia);

  void delete_elements (const octave_value_list&);

  octave_map concat (const octave_map& rb,
                     const Array<octave_idx_type>& ra_idx);

  // like checkelem, but no check.
  octave_scalar_map fast_elem_extract (octave_idx_type n) const;

  // element assignment, no bounds check
  bool fast_elem_insert (octave_idx_type n, const octave_scalar_map& rhs);

private:

  octave_fields m_keys;
  std::vector<Cell> m_vals;
  dim_vector m_dimensions;

  void optimize_dimensions (void);
  void extract_scalar (octave_scalar_map& dest,
                       octave_idx_type index) const;
  static void do_cat (int dim, octave_idx_type n,
                      const octave_scalar_map *map_list, octave_map& retval);
  static void do_cat (int dim, octave_idx_type n,
                      const octave_map *map_list, octave_map& retval);
};

template <>
inline octave_map octave_value_extract<octave_map> (const octave_value& v)
{ return v.map_value (); }

#endif