GetFEM  5.4.2
dal_bit_vector.h
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30 ===========================================================================*/
31 
32 
33 #ifndef DAL_BIT_VECTOR_H__
34 #define DAL_BIT_VECTOR_H__
35 
36 
37 /** @file dal_bit_vector.h
38  @author Yves Renard <Yves.Renard@insa-lyon.fr>
39  @date June 01, 1995.
40  @brief Provide a dynamic bit container.
41 
42  Provide a dynamic bit container, which can also be considered as a
43  set of integers.
44 
45  As a convention, the default value of a bit is false. The main
46  member functions are dal::bit_vector::is_in,
47  dal::bit_vector::add, dal::bit_vector::sup. Iterate over the
48  bit_vector with dal::bv_visitor
49 */
50 
51 #include "dal_basic.h"
52 #include <limits.h>
53 #include <bitset>
54 #include <iterator>
55 #include <algorithm>
56 
57 namespace dal {
58 
59  typedef unsigned int bit_support;
60  static const bit_support WD_BIT = bit_support(CHAR_BIT*sizeof(bit_support));
61  static const bit_support WD_MASK = WD_BIT - 1;
62  typedef dynamic_array<bit_support, 4> bit_container;
63 
64  class bit_vector;
65 
66  struct APIDECL bit_reference {
67  typedef size_t size_type;
68 
69  bit_support* p;
70  bit_support mask;
71  size_type ind;
72  bit_vector* bv;
73 
74  bit_reference(bit_support* x, bit_support m, size_type y, bit_vector* z)
75  { p = x; ind = y; bv = z; mask = m; }
76  bit_reference(void) {}
77  operator bool(void) const { return (*p & mask) != 0; }
78  bit_reference& operator = (bool x);
79  bit_reference& operator=(const bit_reference& x)
80  { return *this = bool(x); }
81  bool operator==(const bit_reference& x) const
82  { return bool(*this) == bool(x); }
83  bool operator<(const bit_reference& x) const
84  { return bool(*this) < bool(x); }
85  void flip(void) { if (bool(*this)) *this = false; else *this = true; }
86  };
87 
88  struct APIDECL bit_iterator {
89  typedef bool value_type;
90  typedef bit_reference reference;
91  typedef bit_reference* pointer;
92  typedef size_t size_type;
93  typedef ptrdiff_t difference_type;
94  typedef std::random_access_iterator_tag iterator_category;
95 
96  size_type ind;
97  bit_support mask;
98  bit_container::iterator p;
99  bit_vector* bv;
100 
101  inline void bump_up()
102  { ind++; if (!(mask <<= 1)) { ++p; mask = 1;} }
103  inline void bump_down()
104  { ind--; if (!(mask >>= 1)) { --p; mask = 1; mask <<= WD_MASK; } }
105 
106  bit_iterator(void) {}
107  bit_iterator(bit_vector &b, size_type i);
108  reference operator*() const
109  { return reference(&(*p), mask, ind, bv); }
110  bit_iterator& operator++() { bump_up(); return *this; }
111  bit_iterator operator++(int)
112  { bit_iterator tmp=*this; bump_up(); return tmp; }
113  bit_iterator& operator--() { bump_down(); return *this; }
114  bit_iterator operator--(int)
115  { bit_iterator tmp = *this; bump_down(); return tmp; }
116  bit_iterator& operator+=(difference_type i);
117  bit_iterator& operator-=(difference_type i)
118  { *this += -i; return *this; }
119  bit_iterator operator+(difference_type i) const
120  { bit_iterator tmp = *this; return tmp += i; }
121  bit_iterator operator-(difference_type i) const
122  { bit_iterator tmp = *this; return tmp -= i; }
123  difference_type operator-(bit_iterator x) const { return ind - x.ind; }
124  reference operator[](difference_type i) { return *(*this + i); }
125  size_type index(void) const { return ind; }
126  bool operator==(const bit_iterator& x) const { return ind == x.ind; }
127  bool operator!=(const bit_iterator& x) const { return ind != x.ind; }
128  bool operator<(bit_iterator x) const { return ind < x.ind; }
129  };
130 
131  struct APIDECL bit_const_iterator {
132  typedef bool value_type;
133  typedef bool reference;
134  typedef const bool* pointer;
135  typedef size_t size_type;
136  typedef ptrdiff_t difference_type;
137  typedef std::random_access_iterator_tag iterator_category;
138 
139  size_type ind;
140  bit_support mask;
141  bit_container::const_iterator p;
142  const bit_vector* bv;
143 
144  inline void bump_up()
145  { ind++; if (!(mask <<= 1)) { ++p; mask = 1;} }
146  inline void bump_down()
147  { ind--; if (!(mask >>= 1)) { --p; mask = 1; mask <<= WD_MASK; } }
148 
149  bit_const_iterator() {}
150  bit_const_iterator(const bit_vector &b, size_type i);
151  bit_const_iterator(const bit_iterator& x)
152  : ind(x.ind), mask(x.mask), p(x.p), bv(x.bv) {}
153  reference operator*() const { return (*p & mask) != 0; }
154  bit_const_iterator& operator++() { bump_up(); return *this; }
155  bit_const_iterator operator++(int)
156  { bit_const_iterator tmp = *this; bump_up(); return tmp; }
157  bit_const_iterator& operator--() { bump_down(); return *this; }
158  bit_const_iterator operator--(int)
159  { bit_const_iterator tmp = *this; bump_down(); return tmp; }
160  bit_const_iterator& operator+=(difference_type i);
161  bit_const_iterator& operator-=(difference_type i)
162  { *this += -i; return *this; }
163  bit_const_iterator operator+(difference_type i) const
164  { bit_const_iterator tmp = *this; return tmp += i; }
165  bit_const_iterator operator-(difference_type i) const
166  { bit_const_iterator tmp = *this; return tmp -= i; }
167  difference_type operator-(bit_const_iterator x) const { return ind-x.ind; }
168  reference operator[](difference_type i) { return *(*this + i); }
169  size_type index(void) const { return ind; }
170  bool operator==(const bit_const_iterator& x) const { return ind == x.ind; }
171  bool operator!=(const bit_const_iterator& x) const { return ind != x.ind; }
172  bool operator<(bit_const_iterator x) const { return ind < x.ind; }
173  };
174 
175  ///Dynamic bit container.
176  class APIDECL bit_vector : public bit_container {
177  public :
178 
179  typedef bool value_type;
180  typedef size_t size_type;
181  typedef ptrdiff_t difference_type;
182  typedef bool const_reference;
183  typedef const bool* const_pointer;
184  typedef bit_reference reference;
185  typedef bit_reference* pointer;
186  typedef bit_iterator iterator;
187  typedef bit_const_iterator const_iterator;
188 
189  protected :
190 
191  mutable size_type ifirst_true, ilast_true;
192  mutable size_type ifirst_false, ilast_false;
193  mutable size_type icard;
194  mutable bool icard_valid;
195 
196  void fill_false(size_type i1, size_type i2);
197 
198  public :
199 
200  void change_for_true(size_type i) {
201  ifirst_true = std::min(ifirst_true, i);
202  ilast_true = std::max(ilast_true, i);
203  ++icard;
204  }
205  void change_for_false(size_type i) {
206  ifirst_false = std::min(ifirst_false, i);
207  ilast_false = std::max(ilast_false, i);
208  --icard;
209  }
210 
211  typedef std::reverse_iterator<const_iterator> const_reverse_iterator;
212  typedef std::reverse_iterator<iterator> reverse_iterator;
213  size_type size(void) const { return std::max(ilast_true, ilast_false)+1;}
214 
215  iterator begin(void) { return iterator(*this, 0); }
216  const_iterator begin(void) const { return const_iterator(*this, 0); }
217  iterator end(void) { return iterator(*this, size()); }
218  const_iterator end(void) const { return const_iterator(*this, size()); }
219 
220  reverse_iterator rbegin(void) { return reverse_iterator(end()); }
221  const_reverse_iterator rbegin(void) const
222  { return const_reverse_iterator(end()); }
223  reverse_iterator rend(void) { return reverse_iterator(begin()); }
224  const_reverse_iterator rend(void) const
225  { return const_reverse_iterator(begin()); }
226 
227  size_type capacity(void) const
228  { return bit_container::capacity() * WD_BIT; }
229  size_type max_size(void) const { return (size_type(-1)); }
230  // bool empty(void) const { return card() == 0; } /* ?? */
231  reference front(void) { return *begin(); }
232  const_reference front(void) const { return *begin(); }
233  reference back(void) { return *(end() - 1); }
234  const_reference back(void) const { return *(end() - 1); }
235 
236 
237  const_reference operator [](size_type ii) const
238  { return (ii >= size()) ? false : *const_iterator(*this, ii); }
239  reference operator [](size_type ii)
240  { if (ii >= size()) fill_false(size(),ii); return *iterator(*this, ii);}
241 
242  void swap(bit_vector &da);
243 
244  void clear(void) {
245  icard = 0; icard_valid = true;
246  ifirst_false = ilast_false = ifirst_true = ilast_true = 0;
247  fill_false(0,0);
248  }
249  void swap(size_type i1, size_type i2) {
250  if (i1 != i2) {
251  reference r1 = (*this)[i1], r2 = (*this)[i2];
252  bool tmp = r1; r1 = r2; r2 = tmp;
253  }
254  }
255  size_type memsize(void) const {
256  return bit_container::memsize() + sizeof(bit_vector)
257  - sizeof(bit_container);
258  }
259  size_type card(void) const;
260  /// index of first non-zero entry (size_type(-1) for an empty bit_vector)
261  size_type first_true(void) const;
262  /// index of first zero entry (size_type(0) for an empty bit_vector)
263  size_type first_false(void) const;
264  /// index of last non-zero entry (size_type(-1) for an empty bit_vector)
265  size_type last_true(void) const;
266  /// index of last zero entry (size_type(0) for an empty bit_vector)
267  size_type last_false(void) const;
268  /// remove all elements found in bv
269  bit_vector &setminus(const bit_vector &bv);
270  bit_vector &operator |=(const bit_vector &bv);
271  bit_vector &operator &=(const bit_vector &bv);
272 
273  bit_vector operator |(const bit_vector &bv) const
274  { bit_vector r(*this); r |= bv; return r; }
275  bit_vector operator &(const bit_vector &bv) const
276  { bit_vector r(*this); r &= bv; return r; }
277  bool operator ==(const bit_vector &bv) const;
278  bool operator !=(const bit_vector &bv) const
279  { return !((*this) == bv); }
280 
281  bit_vector(void) { clear(); }
282  template <size_t N> bit_vector(const std::bitset<N> &bs) {
283  clear();
284  for (size_type i=0; i < bs.size(); ++i) { if (bs[i]) add(i); }
285  }
286 
287  /// merges the integer values of the supplied container into the bit_vector
288  template <typename ICONT> dal::bit_vector& merge_from(const ICONT& c) {
289  for (typename ICONT::const_iterator it = c.begin(); it != c.end(); ++it)
290  add(*it);
291  return *this;
292  }
293  /** merges the integer values of the supplied iterator range into
294  * the bit_vector */
295  template <typename IT> dal::bit_vector& merge_from(IT b, IT e) {
296  while (b != e) { add(*b++); }
297  return *this;
298  }
299  /** return true if the supplied bit_vector is a subset of the current
300  * bit_vector */
301  bool contains(const dal::bit_vector &other) const;
302 
303  public :
304  /// return true if (*this)[i] == true
305  bool is_in(size_type i) const {
306  if (i < ifirst_true || i > ilast_true) return false;
307  else return (((*(const bit_container*)(this))[i / WD_BIT]) &
308  (bit_support(1) << (i & WD_MASK))) ? true : false; }
309  void add(size_type i) { (*this)[i] = true; }
310  /** set the interval [i .. i+nb-1] to true */
311  void add(size_type i, size_type nb);
312  void sup(size_type i) { (*this)[i] = false; } /* deprecated ...*/
313  void del(size_type i) { (*this)[i] = false; }
314  /** set the interval [i .. i+nb-1] to false */
315  void sup(size_type i, size_type nb); /* deprecated ...*/
316  void del(size_type i, size_type nb);
317  int first(void) const { return (card() == 0) ? -1 : int(first_true()); }
318  int last(void) const { return (card() == 0) ? -1 : int(last_true()); }
319  inline int take_first(void)
320  { int res = first(); if (res >= 0) sup(res); return res; }
321  inline int take_last(void)
322  { int res = last(); if (res >= 0) sup(res); return res; }
323  };
324 
325  /**
326  if you are only interested in indexes of true values of a bit_vector
327  (i.e. if you use it as an int set), use bv_visitor instead of
328  bit_vector::const_iterator (much faster)
329 
330  example:
331  @code
332  for (bv_visitor i(v); !i.finished(); ++i) {
333  .... (use i as an unsigned int)
334  }
335  @endcode
336  CAUTION: use bv_visitor_c instead of bv_visitor if the class bv_visitor
337  need to store a copy of the bit_vector
338  (if the original is destroyed just after the creation...)
339  */
340  class APIDECL bv_visitor {
342  bit_container::const_iterator it;
343  size_type ilast,ind;
344  bit_support v;
345  public:
346  bv_visitor(const dal::bit_vector& b) :
347  it(((const bit_container&)b).begin()+b.first()/WD_BIT),
348  ilast(b.last()+1), ind(b.first()), v(0) {
349  if (ind < ilast) { v = *it; v >>= (ind&WD_MASK); }
350  }
351  bool finished() const { return ind >= ilast; }
352  bool operator++();
353  operator size_type() const { return ind; }
354  };
355 
356  /**
357  bv_visitor with local copy of the bit_vector
358  */
359  class APIDECL bv_visitor_c {
360  bit_vector bv;
361  bv_visitor v; // no inheritance since v must be init after bv
362  public:
363  bv_visitor_c(const dal::bit_vector& b) : bv(b), v(bv) {}
364  bool finished() const { return v.finished(); }
365  bool operator++() { return ++v; }
366  operator dal::bit_vector::size_type() const
367  { return dal::bit_vector::size_type(v); }
368  };
369 
370  /// extract index of first entry in the bit_vector
371  inline int APIDECL &operator << (int &i, bit_vector &s)
372  { i = s.take_first(); return i; }
373  inline const int APIDECL &operator >> (const int &i, bit_vector &s)
374  { s.add(i); return i; }
375 
376  inline size_t APIDECL &operator << (size_t &i, bit_vector &s)
377  { i = s.take_first(); return i; }
378  inline const size_t &operator >> (const size_t &i, bit_vector &s)
379  { s.add(i); return i; }
380 
381  std::ostream APIDECL &operator <<(std::ostream &o, const bit_vector &s);
382 
383  /**Iterator class for bv_iterable and bv_iterable_c.*/
384  template<typename ITERABLE_BV>
385  class const_bv_iterator
386  {
388 
389  public:
390 
391  typedef std::forward_iterator_tag iterator_category;
392  typedef size_type value_type;
393  typedef size_type difference_type;
394  typedef size_type* pointer;
395  typedef size_type& reference;
396 
397  const_bv_iterator(const ITERABLE_BV* p_iterable, size_type pos)
398  : p_iterable_(const_cast<ITERABLE_BV*>(p_iterable)), pos_(pos)
399  {}
400 
401  bool operator!= (const const_bv_iterator &other) const{
402  return pos_ < other.pos_;
403  }
404 
405  size_type operator *() const{
406  return size_type(*p_iterable_);
407  }
408 
409  //difference of iterators
410  size_type operator-(const const_bv_iterator &other) const{
411  if (pos_ == other.pos_) return 0;
412 
413  auto &vector_this = p_iterable_->v_;
414  auto &vector_other = other.p_iterable_->v_;
415  bv_visitor v_this(vector_this), v_other(vector_other);
416  while (v_this < pos_) ++v_this;
417  while (v_other < other.pos_) ++v_other;
418  auto &v = (pos_ < other.pos_) ? v_this : v_other;
419  auto &v_end = (pos_ >= other.pos_) ? v_this : v_other;
420 
421  size_type count = 0;
422  while(v < v_end) { ++v; ++count;}
423  return count;
424  }
425 
426  const const_bv_iterator &operator++(){
427  ++*p_iterable_;
428  pos_ = *p_iterable_;
429  return *this;
430  }
431 
432  private:
433  ITERABLE_BV *p_iterable_;
434  size_type pos_;
435  };
436 
437 
438  /**
439  Wrapper class to make bit_vector iterable on true values.
440  It enables the use of c++11 range-based loop feature.
441  example:
442  @code
443  for (auto i : bv_iterable(bit_vector)) {
444  .... //(use i as an unsigned int)
445  }
446  */
447  class bv_iterable
448  {
449  public:
450  bv_iterable(const bit_vector &v) : v_(v), visitor_(v){}
451 
452  const_bv_iterator<bv_iterable> begin() const;
453  const_bv_iterator<bv_iterable> end() const;
454  inline bool operator++(){return ++visitor_;};
455  inline operator dal::bit_vector::size_type() const{return visitor_;};
456 
457  private:
458  const bit_vector& v_;
459  bv_visitor visitor_;
460  friend class const_bv_iterator<bv_iterable>;
461  };
462 
463  /***Same as bv_iterable class except the bit_vector is copied locally.*/
464  class bv_iterable_c
465  {
466  public:
467  bv_iterable_c(const bit_vector &v) : v_(v), visitor_(v_){}
468  const_bv_iterator<bv_iterable_c> begin() const;
469  const_bv_iterator<bv_iterable_c> end() const;
470  inline bool operator++(){return ++visitor_;};
471  inline operator dal::bit_vector::size_type() const{return visitor_;};
472 
473  private:
474  bit_vector v_;
475  bv_visitor visitor_;
476  friend class const_bv_iterator<bv_iterable_c>;
477  };
478 
479 }
480 
481 #endif /* DAL_BIT_VECTOR_H__ */
bgeot::size_type
size_t size_type
used as the common size type in the library
Definition: bgeot_poly.h:49
gmm::clear
void clear(L &l)
clear (fill with zeros) a vector or matrix.
Definition: gmm_blas.h:59
dal
Dynamic Array Library.
Definition: dal_backtrace.cc:29
dal_basic.h
Dynamic array class.
bgeot::operator+
rational_fraction< T > operator+(const polynomial< T > &P, const rational_fraction< T > &Q)
Add Q to P.
Definition: bgeot_poly.h:749
bgeot::operator==
bool operator==(const pconvex_structure &p1, const pconvex_structure &p2)
Stored objects must be compared by keys, because there is a possibility that they are duplicated in s...
Definition: bgeot_convex_structure.cc:111
bgeot::operator-
rational_fraction< T > operator-(const polynomial< T > &P, const rational_fraction< T > &Q)
Subtract Q from P.
Definition: bgeot_poly.h:756
gmm::add
void add(const L1 &l1, L2 &l2)
*‍/
Definition: gmm_blas.h:1268

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