DUNE PDELab (2.8)

basearray.hh
Go to the documentation of this file.
1// -*- tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 2 -*-
2// vi: set et ts=4 sw=2 sts=2:
3#ifndef DUNE_ISTL_BASEARRAY_HH
4#define DUNE_ISTL_BASEARRAY_HH
5
6#include "assert.h"
7#include <cmath>
8#include <cstddef>
9#include <memory>
10#include <algorithm>
11
12#include "istlexception.hh"
14
19namespace Dune {
20
22namespace Imp {
23
48 template<class B, class A=std::allocator<B> >
49 class base_array_unmanaged
50 {
51 public:
52
53 //===== type definitions and constants
54
56 typedef B member_type;
57
59 typedef A allocator_type;
60
62 typedef typename A::size_type size_type;
63
65 using reference = B&;
66
68 using const_reference = const B&;
69
70 //===== access to components
71
73 reference operator[] (size_type i)
74 {
75#ifdef DUNE_ISTL_WITH_CHECKING
76 if (i>=n) DUNE_THROW(ISTLError,"index out of range");
77#endif
78 return p[i];
79 }
80
82 const_reference operator[] (size_type i) const
83 {
84#ifdef DUNE_ISTL_WITH_CHECKING
85 if (i>=n) DUNE_THROW(ISTLError,"index out of range");
86#endif
87 return p[i];
88 }
89
91 template<class T>
92 class RealIterator
93 : public RandomAccessIteratorFacade<RealIterator<T>, T>
94 {
95 public:
97 typedef typename std::remove_const<T>::type ValueType;
98
99 friend class RandomAccessIteratorFacade<RealIterator<const ValueType>, const ValueType>;
100 friend class RandomAccessIteratorFacade<RealIterator<ValueType>, ValueType>;
101 friend class RealIterator<const ValueType>;
102 friend class RealIterator<ValueType>;
103
105 RealIterator ()
106 : p(0), i(0)
107 {}
108
109 RealIterator (const B* _p, B* _i) : p(_p), i(_i)
110 { }
111
112 RealIterator(const RealIterator<ValueType>& it)
113 : p(it.p), i(it.i)
114 {}
115
117 size_type index () const
118 {
119 return i-p;
120 }
121
123 bool equals (const RealIterator<ValueType>& other) const
124 {
125 assert(other.p==p);
126 return i==other.i;
127 }
128
130 bool equals (const RealIterator<const ValueType>& other) const
131 {
132 assert(other.p==p);
133 return i==other.i;
134 }
135
136 std::ptrdiff_t distanceTo(const RealIterator& o) const
137 {
138 return o.i-i;
139 }
140
141 private:
143 void increment()
144 {
145 ++i;
146 }
147
149 void decrement()
150 {
151 --i;
152 }
153
154 // Needed for operator[] of the iterator
155 reference elementAt (std::ptrdiff_t offset) const
156 {
157 return *(i+offset);
158 }
159
161 reference dereference () const
162 {
163 return *i;
164 }
165
166 void advance(std::ptrdiff_t d)
167 {
168 i+=d;
169 }
170
171 const B* p;
172 B* i;
173 };
174
176 typedef RealIterator<B> iterator;
177
178
180 iterator begin ()
181 {
182 return iterator(p,p);
183 }
184
186 iterator end ()
187 {
188 return iterator(p,p+n);
189 }
190
193 iterator beforeEnd ()
194 {
195 return iterator(p,p+n-1);
196 }
197
200 iterator beforeBegin ()
201 {
202 return iterator(p,p-1);
203 }
204
206 iterator find (size_type i)
207 {
208 return iterator(p,p+std::min(i,n));
209 }
210
212 typedef RealIterator<const B> const_iterator;
213
215 const_iterator begin () const
216 {
217 return const_iterator(p,p+0);
218 }
219
221 const_iterator end () const
222 {
223 return const_iterator(p,p+n);
224 }
225
228 const_iterator beforeEnd () const
229 {
230 return const_iterator(p,p+n-1);
231 }
232
235 const_iterator beforeBegin () const
236 {
237 return const_iterator(p,p-1);
238 }
239
241 const_iterator find (size_type i) const
242 {
243 return const_iterator(p,p+std::min(i,n));
244 }
245
246
247 //===== sizes
248
250 size_type size () const
251 {
252 return n;
253 }
254
256 const B* data() const
257 {
258 return p;
259 }
260
262 B* data()
263 {
264 return p;
265 }
266
267 protected:
269 base_array_unmanaged ()
270 : n(0), p(0)
271 {}
273 base_array_unmanaged (size_type n_, B* p_)
274 : n(n_), p(p_)
275 {}
276 size_type n; // number of elements in array
277 B *p; // pointer to dynamically allocated built-in array
278 };
279
280
281
303 template<class B, class A=std::allocator<B> >
304 class compressed_base_array_unmanaged
305 {
306 public:
307
308 //===== type definitions and constants
309
311 typedef B member_type;
312
314 typedef A allocator_type;
315
317 typedef typename A::size_type size_type;
318
320 using reference = B&;
321
323 using const_reference = const B&;
324
325 //===== access to components
326
328 reference operator[] (size_type i)
329 {
330 const size_type* lb = std::lower_bound(j, j+n, i);
331 if (lb == j+n || *lb != i)
332 DUNE_THROW(ISTLError,"index "<<i<<" not in compressed array");
333 return p[lb-j];
334 }
335
337 const_reference operator[] (size_type i) const
338 {
339 const size_type* lb = std::lower_bound(j, j+n, i);
340 if (lb == j+n || *lb != i)
341 DUNE_THROW(ISTLError,"index "<<i<<" not in compressed array");
342 return p[lb-j];
343 }
344
346 template<class T>
347 class RealIterator
348 : public BidirectionalIteratorFacade<RealIterator<T>, T>
349 {
350 public:
352 typedef typename std::remove_const<T>::type ValueType;
353
354 friend class BidirectionalIteratorFacade<RealIterator<const ValueType>, const ValueType>;
355 friend class BidirectionalIteratorFacade<RealIterator<ValueType>, ValueType>;
356 friend class RealIterator<const ValueType>;
357 friend class RealIterator<ValueType>;
358
360 RealIterator ()
361 : p(0), j(0), i(0)
362 {}
363
365 RealIterator (B* _p, size_type* _j, size_type _i)
366 : p(_p), j(_j), i(_i)
367 { }
368
372 RealIterator(const RealIterator<ValueType>& it)
373 : p(it.p), j(it.j), i(it.i)
374 {}
375
376
378 bool equals (const RealIterator<ValueType>& it) const
379 {
380 assert(p==it.p);
381 return (i)==(it.i);
382 }
383
385 bool equals (const RealIterator<const ValueType>& it) const
386 {
387 assert(p==it.p);
388 return (i)==(it.i);
389 }
390
391
393 size_type index () const
394 {
395 return j[i];
396 }
397
399 void setindex (size_type k)
400 {
401 return j[i] = k;
402 }
403
411 size_type offset () const
412 {
413 return i;
414 }
415
416 private:
418 void increment()
419 {
420 ++i;
421 }
422
424 void decrement()
425 {
426 --i;
427 }
428
430 reference dereference () const
431 {
432 return p[i];
433 }
434
435 B* p;
436 size_type* j;
437 size_type i;
438 };
439
441 typedef RealIterator<B> iterator;
442
444 iterator begin ()
445 {
446 return iterator(p,j,0);
447 }
448
450 iterator end ()
451 {
452 return iterator(p,j,n);
453 }
454
457 iterator beforeEnd ()
458 {
459 return iterator(p,j,n-1);
460 }
461
464 iterator beforeBegin ()
465 {
466 return iterator(p,j,-1);
467 }
468
470 iterator find (size_type i)
471 {
472 const size_type* lb = std::lower_bound(j, j+n, i);
473 return (lb != j+n && *lb == i)
474 ? iterator(p,j,lb-j)
475 : end();
476 }
477
479 typedef RealIterator<const B> const_iterator;
480
482 const_iterator begin () const
483 {
484 return const_iterator(p,j,0);
485 }
486
488 const_iterator end () const
489 {
490 return const_iterator(p,j,n);
491 }
492
495 const_iterator beforeEnd () const
496 {
497 return const_iterator(p,j,n-1);
498 }
499
502 const_iterator beforeBegin () const
503 {
504 return const_iterator(p,j,-1);
505 }
506
508 const_iterator find (size_type i) const
509 {
510 const size_type* lb = std::lower_bound(j, j+n, i);
511 return (lb != j+n && *lb == i)
512 ? const_iterator(p,j,lb-j)
513 : end();
514 }
515
516 //===== sizes
517
519 size_type size () const
520 {
521 return n;
522 }
523
524 protected:
526 compressed_base_array_unmanaged ()
527 : n(0), p(0), j(0)
528 {}
529
530 size_type n; // number of elements in array
531 B *p; // pointer to dynamically allocated built-in array
532 size_type* j; // the index set
533 };
534
535} // end namespace Imp
536
537} // end namespace
538
539#endif
#define DUNE_THROW(E, m)
Definition: exceptions.hh:216
constexpr auto equals(T1 &&t1, T2 &&t2)
Equality comparison.
Definition: hybridutilities.hh:400
constexpr decltype(auto) elementAt(Container &&c, Index &&i)
Get element at given position from container.
Definition: hybridutilities.hh:133
auto min(ADLTag< 0 >, const V &v1, const V &v2)
implements binary Simd::min()
Definition: defaults.hh:87
This file implements iterator facade classes for writing stl conformant iterators.
Dune namespace.
Definition: alignedallocator.hh:11
Creative Commons License   |  Legal Statements / Impressum  |  Hosted by TU Dresden  |  generated with Hugo v0.111.3 (Dec 21, 23:30, 2024)