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GetFEM: src/getfem/dal_basic.h Source File
GetFEM  5.4.2
dal_basic.h
Go to the documentation of this file.
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4  Copyright (C) 1995-2020 Yves Renard
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30 ===========================================================================*/
31 
32 /**@file dal_basic.h
33  @author Yves Renard <Yves.Renard@insa-lyon.fr>
34  @date June 01, 1995.
35  @brief Dynamic array class.
36 */
37 #ifndef DAL_BASIC_H__
38 #define DAL_BASIC_H__
39 
40 #include <vector>
41 #include "dal_config.h"
42 #include "getfem_omp.h"
43 
44 /// Dynamic Array Library
45 namespace dal
46 {
47  template<class T, unsigned char pks = 5> class dynamic_array;
48 
49  /// Iterator class for dynamic array.
50  template<class T, unsigned char pks> struct dna_iterator {
51  typedef T value_type;
52  typedef value_type* pointer;
53  typedef value_type& reference;
54  typedef size_t size_type;
55  typedef ptrdiff_t difference_type;
56  typedef std::random_access_iterator_tag iterator_category;
57 
58 # define DNAMPKS__ ((size_type(1) << pks) - 1)
60  size_type in;
61  pointer pT;
62 
63  dna_iterator(void) {}
64  dna_iterator(dynamic_array<T,pks> &da, size_type ii)
65  { p = &da; in = ii; pT = p->pt_to(in); }
66 
67  inline size_type index(void) const { return in; }
68  /// next element.
70  dna_iterator tmp = *this;
71  if ((++in)&DNAMPKS__) pT++; else pT=p->pt_to(in); return tmp;
72  }
73  /// previous element.
75  dna_iterator tmp = *this;
76  if ((in--)&DNAMPKS__) pT--; else pT=p->pt_to(in); return tmp;
77  }
78  /// next element.
80  { if ((++in)&DNAMPKS__) pT++; else pT=p->pt_to(in); return *this; }
81  /// previous element.
83  { if ((in--)&DNAMPKS__) pT--; else pT=p->pt_to(in); return *this; }
84  /// go i elements forward.
85  dna_iterator &operator +=(difference_type i)
86  { in += i; pT=p->pt_to(in); return *this; }
87  /// go i elements backward.
88  dna_iterator &operator -=(difference_type i)
89  { in -= i; pT=p->pt_to(in); return *this; }
90  /// gives an iterator pointing i elements forward.
91  dna_iterator operator +(difference_type i) const
92  { dna_iterator it = *this; return (it += i); }
93  /// gives an iterator pointing i elements backward.
94  dna_iterator operator -(difference_type i) const
95  { dna_iterator it = *this; return (it -= i); }
96  /// Gives the difference, in term of elements between two iterators.
97  difference_type operator -(const dna_iterator &i) const
98  { return difference_type(in - i.in); }
99 
100  reference operator *() const { return (*pT); }
101  pointer operator ->() const { return pT; }
102  reference operator [](size_type ii) const { return (*p)[in+ii]; }
103 
104  bool operator ==(const dna_iterator &i) const { return (i.in==in);}
105  bool operator !=(const dna_iterator &i) const { return (i.in!=in);}
106  bool operator < (const dna_iterator &i) const { return ( in<i.in);}
107  };
108 
109  /// Constant iterator class for dynamic array.
110  template<class T, unsigned char pks> struct dna_const_iterator {
111  typedef T value_type;
112  typedef const value_type* pointer;
113  typedef const value_type& reference;
114  typedef size_t size_type;
115  typedef ptrdiff_t difference_type;
116  typedef std::random_access_iterator_tag iterator_category;
117 
118 # define DNAMPKS__ ((size_type(1) << pks) - 1)
119  const dynamic_array<T,pks> *p;
120  size_type in;
121  pointer pT;
122 
123  dna_const_iterator(void) {}
124  dna_const_iterator(const dynamic_array<T,pks> &da, size_type ii)
125  { p = &da; in = ii; pT = p->pt_to(in); }
127  : p(it.p), in(it.in), pT(it.pT) {}
128 
129  inline size_type index(void) const { return in; }
130  dna_const_iterator operator ++(int) {
131  dna_const_iterator tmp = *this;
132  if ((++in)&DNAMPKS__) pT++; else pT=p->pt_to(in); return tmp;
133  }
134  dna_const_iterator operator --(int) {
135  dna_const_iterator tmp = *this;
136  if ((in--)&DNAMPKS__) pT--; else pT=p->pt_to(in); return tmp;
137  }
138  dna_const_iterator &operator ++()
139  { if ((++in)&DNAMPKS__) pT++; else pT=p->pt_to(in); return *this; }
140  dna_const_iterator &operator --()
141  { if ((in--)&DNAMPKS__) pT--; else pT=p->pt_to(in); return *this; }
142  dna_const_iterator &operator +=(difference_type i)
143  { in += i; pT=p->pt_to(in); return *this; }
144  dna_const_iterator &operator -=(difference_type i)
145  { in -= i; pT=p->pt_to(in); return *this; }
146  dna_const_iterator operator +(difference_type i) const
147  { dna_const_iterator it = *this; return (it += i); }
148  dna_const_iterator operator -(difference_type i) const
149  { dna_const_iterator it = *this; return (it -= i); }
150  difference_type operator -(const dna_const_iterator &i) const
151  { return difference_type(in - i.in); }
152 
153  reference operator *() const { return (*pT); }
154  pointer operator ->() const { return pT; }
155  reference operator [](size_type ii) const { return (*p)[in+ii]; }
156 
157  bool operator ==(const dna_const_iterator &i) const
158  { return (i.in == in); }
159  bool operator !=(const dna_const_iterator &i) const
160  { return (i.in != in); }
161  bool operator < (const dna_const_iterator &i) const
162  { return (in < i.in); }
163  };
164 
165  /** Dynamic Array. Defines the basic container of the library which is
166  * dal::dynamic_array<T, pks>. This container is virtually an
167  * infinite array of element of type T. When a random acces tab[i] is
168  * called, a control is made on i and an allocation is made if
169  * needed. The allocation is made by blocks of n elements, where
170  * @f$n = 2^{pks}@f$. @f$pks@f$ is an optional parameter assumed to be 5.
171  * The structure of this container is similar to the one of std::deque<T>
172  * but with a faster random access.
173  *
174  *
175  * <h3>Example of code</h3>
176  * If T is any type (with or without trivial constructor/destructor,
177  * and with constructor T(0) and T(1)), the
178  * following code is valid:
179  * @code
180  * #include<dal_basic.h>
181  * dal::dynamic_array<T> tab;
182  * tab[50] = T(0); // 51 elements in tab.
183  * std::fill(tab.begin(), tab.end(), T(0)); // 51 elements initialized
184  * dal::dynamic_array<T>::iterator it = tab.begin();
185  * dal::dynamic_array<T>::iterator ite = it + 50;
186  * for( ; it != ite; ++it)
187  * { *it = T(1); } // only the 50 first elements are changed.
188  * @endcode
189  */
190  template<class T, unsigned char pks> class dynamic_array {
191  public :
192 
193  typedef T value_type;
194  typedef value_type* pointer;
195  typedef const value_type* const_pointer;
196  typedef value_type& reference;
197  typedef const value_type& const_reference;
198  typedef size_t size_type;
199  typedef ptrdiff_t difference_type;
200  typedef unsigned char pack_size_type;
201  typedef std::vector<std::unique_ptr<T[]>> pointer_array;
202  typedef dna_iterator<T, pks> iterator;
203  typedef dna_const_iterator<T, pks> const_iterator;
204  typedef std::reverse_iterator<const_iterator> const_reverse_iterator;
205  typedef std::reverse_iterator<iterator> reverse_iterator;
206 
207  protected :
208 
209 # define DNAMPKS__ ((size_type(1) << pks) - 1)
210  pointer_array array;
211  pack_size_type ppks; /* size of pointer packs (2^ppks). */
212  size_type m_ppks; /* = (2^ppks) - 1. */
213  size_type last_ind; /* allocated = 0 .. last_ind-1. */
214  size_type last_accessed; /* valid = 0 .. last_accessed-1. */
215 
216  public :
217 
218  /// Number of allocated elements.
219  size_type size(void) const { return last_accessed; }
220  size_type capacity(void) const { return last_ind; }
221  size_type max_size(void) const { return (size_type(-1)) / 2; }
222  /// True if no space is allocated.
223  bool empty(void) const { return last_accessed == 0; }
224  /// Iterator on the first element.
225  iterator begin(void) { return iterator(*this, 0); }
226  /// Constant iterator on the first element.
227  const_iterator begin(void) const { return const_iterator(*this, 0); }
228  /// Iterator on the last + 1 element.
229  iterator end(void) { return iterator(*this, size()); }
230  /// Constant iterator on the last + 1 element.
231  const_iterator end(void) const
232  { return const_iterator(*this, size()); }
233  reverse_iterator rbegin(void) { return reverse_iterator(end()); }
234  const_reverse_iterator rbegin(void) const
235  { return const_reverse_iterator(end()); }
236  reverse_iterator rend(void) { return reverse_iterator(begin()); }
237  const_reverse_iterator rend(void) const
238  { return const_reverse_iterator(begin()); }
239 
240  reference front(void) { return *begin(); }
241  const_reference front(void) const { return *begin(); }
242  reference back(void) { return *(end() - 1); }
243  const_reference back(void) const { return *(end() - 1); }
244 
245  void swap(dynamic_array<T,pks> &da);
246  /// Clear and desallocate all the elements.
247  void clear(void);
248  dynamic_array<T,pks> &operator =(const dynamic_array<T,pks> &da);
249 
250  protected:
251 
252  void init(void)
253  { last_accessed = last_ind = 0; array.resize(8); ppks = 3; m_ppks = 7; }
254 
255 
256  public:
257 
258  dynamic_array(const dynamic_array<T,pks> &da) { init(); *this = da; }
259  dynamic_array(void) { init(); }
260  // ~dynamic_array(void) { clear(); }
261  inline pointer pt_to(size_type ii) /* used by iterators. */
262  { return (ii >=last_ind) ? NULL : &((array[ii>>pks])[ii&DNAMPKS__]); }
263  inline const_pointer pt_to(size_type ii) const
264  { return (ii >=last_ind) ? NULL : &((array[ii>>pks])[ii&DNAMPKS__]); }
265 
266  /// Gives a constant reference on element ii.
267  const_reference operator [](size_type ii) const;
268  /// Gives a reference on element ii.
269  reference operator [](size_type ii);
270  void resize(size_type i) { (*this)[i-1]; }
271 
272  /// Gives the total memory occupied by the array.
273  size_type memsize(void) const {
274  return sizeof(pointer) * array.capacity()
275  + last_ind*sizeof(T) + sizeof(dynamic_array<T,pks>);
276  }
277 
278  /// Swap element i1 and i2.
279  void swap(size_type i1, size_type i2)
280  { std::swap((*this)[i1], (*this)[i2]); }
281  };
282 
283 
284  /* ********************************************************************* */
285  /* Member functions */
286  /* ********************************************************************* */
287 
288 
289  template<class T, unsigned char pks>
290  void dynamic_array<T,pks>::swap(dynamic_array<T,pks> &da) {
291  array.swap(da.array);
292  std::swap(last_ind, da.last_ind);
293  std::swap(last_accessed, da.last_accessed);
294  std::swap(ppks, da.ppks); std::swap(m_ppks, da.m_ppks);
295  }
296 
297  template<class T, unsigned char pks>
299  // typename pointer_array::iterator it = array.begin();
300  // typename pointer_array::iterator ite = it+ ((last_ind + DNAMPKS__) >> pks);
301  // while (it != ite) delete[] *it++;
302  array.clear(); init();
303  }
304 
305  template<class T, unsigned char pks> dynamic_array<T,pks>
307  array.resize(da.array.size());
308  last_ind = da.last_ind;
309  last_accessed = da.last_accessed;
310  ppks = da.ppks; m_ppks = da.m_ppks;
311  typename pointer_array::iterator it = array.begin();
312  typename pointer_array::const_iterator ita = da.array.begin();
313  typename pointer_array::iterator ite = it+ ((last_ind + DNAMPKS__) >> pks);
314  while (it != ite) {
315  *it = std::unique_ptr<T[]>(new T[DNAMPKS__+1]);// std::make_unique<T[]>(DNAMPKS__+1);
316  pointer p = it->get(); ++it;
317  pointer pe = p + (DNAMPKS__+1);
318  const_pointer pa = (ita++)->get();
319  while (p != pe) *p++ = *pa++;
320  }
321  return *this;
322  }
323 
324  template<class T, unsigned char pks>
325  typename dynamic_array<T,pks>::const_reference
326  dynamic_array<T,pks>::operator [](size_type ii) const {
327  THREAD_SAFE_STATIC T f;
328  return (ii<last_ind) ? (array[ii>>pks])[ii&DNAMPKS__] : f;
329  }
330 
331  template<class T, unsigned char pks> typename dynamic_array<T,pks>::reference
333  if (ii >= last_accessed) {
334  GMM_ASSERT2(ii < INT_MAX, "out of range");
335 
336  last_accessed = ii + 1;
337  if (ii >= last_ind) {
338  if ((ii >> (pks+ppks)) > 0) {
339  while ((ii >> (pks+ppks)) > 0) ppks++;
340  array.resize(m_ppks = (size_type(1) << ppks)); m_ppks--;
341  }
342  for (size_type jj = (last_ind >> pks); ii >= last_ind;
343  jj++, last_ind += (DNAMPKS__ + 1)){
344  array[jj] = std::unique_ptr<T[]>(new T[DNAMPKS__+1]);
345  } // std::make_unique<T[]>(DNAMPKS__ + 1); }
346  }
347  }
348  return (array[ii >> pks])[ii & DNAMPKS__];
349  }
350 
351 
352  /* ********************************************************************* */
353  /* Templates functions */
354  /* ********************************************************************* */
355 
356  template<class T, unsigned char pks>
357  bool operator==(const dynamic_array<T,pks> &x,
358  const dynamic_array<T,pks> &y) {
359  typename dynamic_array<T,pks>::const_iterator itxb=x.begin(), itxe=x.end();
360  typename dynamic_array<T,pks>::const_iterator ityb=y.begin(), itye=y.end();
361  typename dynamic_array<T,pks>::size_type d = std::min(itxe-itxb,itye-ityb);
362  typename dynamic_array<T,pks>::const_iterator itxc = itxb+d, ityc = ityb+d;
363 
364  if (!std::equal(itxb, itxc, ityb)) return false;
365  for (; itxc != itxe; itxc++) if (*itxc != T()) return false;
366  for (; ityc != itye; ityc++) if (*ityc != T()) return false;
367  return true;
368  }
369 
370  template<class T, unsigned char pks>
371  bool operator < (const dynamic_array<T,pks> &x,
372  const dynamic_array<T,pks> &y)
373  { return std::lexicographical_compare(x.begin(),x.end(),y.begin(),y.end()); }
374 
375  template<class T, unsigned char pks> inline
376  void swap(const dynamic_array<T,pks> &x, const dynamic_array<T,pks> &y)
377  { x.swap(y); }
378 
379 }
380 #endif /* DAL_BASIC_H__ */
dal::dna_iterator::operator--
dna_iterator & operator--()
previous element.
Definition: dal_basic.h:82
bgeot::size_type
size_t size_type
used as the common size type in the library
Definition: bgeot_poly.h:49
dal::dynamic_array::operator[]
const_reference operator[](size_type ii) const
Gives a constant reference on element ii.
Definition: dal_basic.h:326
dal
Dynamic Array Library.
Definition: dal_backtrace.cc:29
dal::dynamic_array::end
const_iterator end(void) const
Constant iterator on the last + 1 element.
Definition: dal_basic.h:231
dal::dna_iterator::operator-=
dna_iterator & operator-=(difference_type i)
go i elements backward.
Definition: dal_basic.h:88
dal::dynamic_array::begin
iterator begin(void)
Iterator on the first element.
Definition: dal_basic.h:225
dal::dna_const_iterator
Constant iterator class for dynamic array.
Definition: dal_basic.h:110
dal_config.h
defines and typedefs for namespace dal
dal::dynamic_array::clear
void clear(void)
Clear and desallocate all the elements.
Definition: dal_basic.h:298
dal::dynamic_array::memsize
size_type memsize(void) const
Gives the total memory occupied by the array.
Definition: dal_basic.h:273
getfem_omp.h
Tools for multithreaded, OpenMP and Boost based parallelization.
dal::dna_iterator::operator++
dna_iterator & operator++()
next element.
Definition: dal_basic.h:79
dal::dna_iterator::operator+=
dna_iterator & operator+=(difference_type i)
go i elements forward.
Definition: dal_basic.h:85
dal::dynamic_array
Dynamic Array.
Definition: dal_basic.h:47
dal::dynamic_array::empty
bool empty(void) const
True if no space is allocated.
Definition: dal_basic.h:223
dal::dynamic_array::swap
void swap(size_type i1, size_type i2)
Swap element i1 and i2.
Definition: dal_basic.h:279
dal::dna_iterator
Iterator class for dynamic array.
Definition: dal_basic.h:50
dal::dynamic_array::end
iterator end(void)
Iterator on the last + 1 element.
Definition: dal_basic.h:229
dal::dna_iterator::operator+
dna_iterator operator+(difference_type i) const
gives an iterator pointing i elements forward.
Definition: dal_basic.h:91
dal::dynamic_array::size
size_type size(void) const
Number of allocated elements.
Definition: dal_basic.h:219
dal::dna_iterator::operator-
dna_iterator operator-(difference_type i) const
gives an iterator pointing i elements backward.
Definition: dal_basic.h:94
dal::dynamic_array::begin
const_iterator begin(void) const
Constant iterator on the first element.
Definition: dal_basic.h:227