DGtal 1.3.0
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NeighborhoodConvexityAnalyzer.h
1
17#pragma once
18
31#if defined(NeighborhoodConvexityAnalyzer_RECURSES)
32#error Recursive header files inclusion detected in NeighborhoodConvexityAnalyzer.h
33#else // defined(NeighborhoodConvexityAnalyzer_RECURSES)
35#define NeighborhoodConvexityAnalyzer_RECURSES
36
37#if !defined NeighborhoodConvexityAnalyzer_h
39#define NeighborhoodConvexityAnalyzer_h
40
42// Inclusions
43#include <iostream>
44#include <list>
45#include <vector>
46#include <string>
47#include <bitset>
48#include <unordered_set>
49#include "DGtal/base/Common.h"
50#include "DGtal/base/Clone.h"
51#include "DGtal/base/ConstExpressions.h"
52#include "DGtal/base/TimeStampMemoizer.h"
53#include "DGtal/kernel/CPointPredicate.h"
54#include "DGtal/kernel/CBoundedNumber.h"
55#include "DGtal/kernel/domains/HyperRectDomain.h"
56#include "DGtal/topology/CCellularGridSpaceND.h"
57#include "DGtal/topology/KhalimskySpaceND.h"
58#include "DGtal/geometry/volumes/DigitalConvexity.h"
60
61namespace DGtal
62{
63
65 // template class NeighborhoodConvexityAnalyzer
93 template < typename TKSpace, int K >
95 {
97
98 public:
100 typedef TKSpace KSpace;
101 typedef typename KSpace::Space Space;
102 typedef typename KSpace::Integer Integer;
103 typedef typename KSpace::Point Point;
104 typedef typename KSpace::Vector Vector;
105 typedef typename KSpace::Cell Cell;
106 typedef std::vector<Point> PointRange;
108 typedef std::size_t Size;
109
113 static const bool false_positive = ( dimension > 2 ) || ( K > 1 );
114
115 typedef std::bitset< functions::const_pow( 2*K+1, dimension ) > Configuration;
116 typedef std::bitset< 9 > BasicConfiguration;
117
118
119 // ------------------------- Standard services --------------------------------
120 public:
123
128
133
138 NeighborhoodConvexityAnalyzer ( const Self & other ) = default;
139
148 : myDigConv( aKSpace ), myMemoizer( memoizer_size )
149 {
150 myDomain = Domain( myDigConv.space().lowerBound(),
151 myDigConv.space().upperBound() );
152 myComputations = 0;
153 myResults = 0;
155 trace.info() << "Size=" << size() << " middle=" << middle << std::endl;
156 }
157
167 Size memoizer_size = 0 )
168 : myDomain( lo, hi ), myDigConv( lo, hi ), myMemoizer( memoizer_size )
169 {
170 myComputations = 0;
171 myResults = 0;
173 trace.info() << "Size=" << size() << " middle=" << middle << std::endl;
174 }
175
181 Self & operator= ( const Self & other ) = default;
182
184 const KSpace& space() const
185 {
186 return myDigConv.space();
187 }
188
190 const Domain& domain() const
191 {
192 return myDomain;
193 }
194
196 static int radius()
197 { return K; }
198
201 static Size size()
202 { return neigh_size; }
203
205
206 // -------------------- Neighborhood and convexity services -----------------------
207 public:
210
221 template < typename PointPredicate >
222 void setCenter( Point c, const PointPredicate& X );
223
225 Point center() const
226 {
227 return myCenter;
228 }
229
232 {
233 return myCfgX;
234 }
235
237 bool isCenterInX() const
238 {
239 return myCenterInX;
240 }
241
244 {
245 if ( isCenterInX() )
246 return ( myNbInX >= 1 ) // ( ! myLocalX.empty() )
247 && isFullyConvex( true )
248 && isFullyConvex( false );
249 else
250 return ( size() - myNbInX >= 2 ) // ( ! myLocalCompX.empty() )
252 && isComplementaryFullyConvex( false );
253 }
254
257 {
258 if ( isCenterInX() )
259 return ( myNbInX >= 1 ) // ( ! myLocalX.empty() )
260 && ! isFullyConvex( true )
261 && isFullyConvex( false )
263 else
264 return ( size() - myNbInX >= 2 ) // ( ! myLocalCompX.empty() )
265 && ! isComplementaryFullyConvex( true )
267 && isFullyConvex( true );
268 }
269
272 {
273 if ( isCenterInX() )
274 return ( myNbInX >= 1 ) // ( ! myLocalX.empty() )
275 && is0Convex( true )
276 && is0Convex( false );
277 else
278 return ( size() - myNbInX >= 2 ) // ( ! myLocalCompX.empty() )
279 && isComplementary0Convex( true )
280 && isComplementary0Convex( false );
281 }
282
288 bool isFullyConvex( bool with_center )
289 {
290 int mask = with_center
292 if ( myComputations & mask ) return bool( myResults & mask );
293 bool ok;
294 // Check memoizer
295 if ( myMemoizer.isValid() )
296 {
297 auto cfg = makeConfiguration( myCfgX, false, with_center );
298 auto p = myMemoizer.get( cfg );
299 ok = p.first; // may not be correct
300 bool memoized = p.second;
301 if ( ! memoized )
302 {
303 // Need to compute full convexity property
304 ok = checkBasicConfigurationsFullConvexity( false, with_center );
305 if ( ok && false_positive )
306 { // need to do the true computation.
307 std::vector< Point > localX;
308 getLocalX( localX, with_center );
309 ok = myDigConv.isFullyConvex( localX );
310 }
311 myMemoizer.set( cfg, ok );
312 }
313 }
314 else
315 {
316 ok = checkBasicConfigurationsFullConvexity( false, with_center );
317 if ( ok && false_positive )
318 { // need to do the true computation.
319 std::vector< Point > localX;
320 getLocalX( localX, with_center );
321 ok = myDigConv.isFullyConvex( localX );
322 }
323 }
324 // auto cfg = makeConfiguration( myCfgX, false, with_center );
325 // // Check memoizer
326 // if ( myMemoizer.isValid() )
327 // {
328 // auto p = myMemoizer.get( cfg );
329 // ok = p.first; // may not be correct
330 // memoized = p.second;
331 // }
332 // if ( ! memoized )
333 // {
334 // // Need to compute full convexity property
335 // ok = checkBasicConfigurationsFullConvexity( false, with_center );
336 // if ( ok && false_positive )
337 // { // need to do the true computation.
338 // std::vector< Point > localX;
339 // getLocalX( localX, with_center );
340 // ok = myDigConv.isFullyConvex( localX );
341 // }
342 // if ( myMemoizer.isValid() )
343 // myMemoizer.set( cfg, ok );
344 // }
345 myComputations |= mask;
346 if ( ok ) myResults |= mask;
347 return ok;
348 }
349
355 bool isComplementaryFullyConvex( bool with_center )
356 {
357 int mask = with_center
359 if ( myComputations & mask ) return bool( myResults & mask );
360 bool ok;
361 // Check memoizer
362 if ( myMemoizer.isValid() )
363 {
364 auto cfg = makeConfiguration( myCfgX, true, with_center );
365 auto p = myMemoizer.get( cfg );
366 ok = p.first; // may not be correct
367 bool memoized = p.second;
368 if ( ! memoized )
369 {
370 // Need to compute full convexity property
371 ok = checkBasicConfigurationsFullConvexity( true, with_center );
372 if ( ok && false_positive )
373 { // need to do the true computation.
374 std::vector< Point > localCompX;
375 getLocalCompX( localCompX, with_center );
376 ok = myDigConv.isFullyConvex( localCompX );
377 }
378 myMemoizer.set( cfg, ok );
379 }
380 }
381 else
382 {
383 // Need to compute full convexity property
384 ok = checkBasicConfigurationsFullConvexity( true, with_center );
385 if ( ok && false_positive )
386 { // need to do the true computation.
387 std::vector< Point > localCompX;
388 getLocalCompX( localCompX, with_center );
389 ok = myDigConv.isFullyConvex( localCompX );
390 }
391 }
392 // bool memoized = false;
393 // auto cfg = makeConfiguration( myCfgX, true, with_center );
394 // // Check memoizer
395 // if ( myMemoizer.isValid() )
396 // {
397 // auto p = myMemoizer.get( cfg );
398 // ok = p.first; // may not be correct
399 // memoized = p.second;
400 // }
401 // if ( ! memoized )
402 // {
403 // // Need to compute full convexity property
404 // ok = checkBasicConfigurationsFullConvexity( true, with_center );
405 // if ( ok && false_positive )
406 // { // need to do the true computation.
407 // std::vector< Point > localCompX;
408 // getLocalCompX( localCompX, with_center );
409 // ok = myDigConv.isFullyConvex( localCompX );
410 // }
411 // if ( myMemoizer.isValid() )
412 // myMemoizer.set( cfg, ok );
413 // }
414 myComputations |= mask;
415 if ( ok ) myResults |= mask;
416 return ok;
417 }
418
424 bool is0Convex( bool with_center )
425 {
426 int mask = with_center
428 if ( myComputations & mask ) return bool( myResults & mask );
429 // Need to compute full convexity property
430 bool ok = checkBasicConfigurations0Convexity( false, with_center );
431 if ( ok && false_positive )
432 { // need to do the true computation.
433 std::vector< Point > localX;
434 getLocalX( localX, with_center );
435 ok = myDigConv.is0Convex( localX );
436 }
437 myComputations |= mask;
438 if ( ok ) myResults |= mask;
439 return ok;
440 }
441
447 bool isComplementary0Convex( bool with_center )
448 {
449 int mask = with_center
451 if ( myComputations & mask ) return bool( myResults & mask );
452 // Need to compute full convexity property
453 bool ok = checkBasicConfigurations0Convexity( true, with_center );
454 if ( ok && false_positive )
455 { // need to do the true computation.
456 std::vector< Point > localCompX;
457 getLocalCompX( localCompX, with_center );
458 ok = myDigConv.is0Convex( localCompX );
459 }
460 myComputations |= mask;
461 if ( ok ) myResults |= mask;
462 return ok;
463 }
464
474 bool complement, bool with_center )
475 {
476 if ( complement )
477 {
478 current.flip(); // current = ~current;
479 if ( ! with_center ) current.reset( middle );
480 else current.set( middle );
481 }
482 else
483 {
484 if ( with_center ) current.set( middle );
485 }
486 return current;
487 }
488
493 void getLocalX( std::vector< Point >& localX, bool with_center ) const;
494
499 void getLocalCompX( std::vector< Point >& localCompX, bool with_center ) const;
500
502
503 // ------------------------- Protected Datas ------------------------------
504 protected:
520 std::vector< BasicConfiguration > myBasicCfgX;
521
523 std::bitset< 512 > myBasicFullConvexityTable;
525 std::bitset< 512 > myBasic0ConvexityTable;
526
537 };
542
543 // ------------------------- Private Datas --------------------------------
544 private:
545
546 // ------------------------- Internals ------------------------------------
547 private:
551
560 ( bool compX, bool with_center ) const;
561
570 ( bool compX, bool with_center ) const;
571
580 ( Configuration cfg, std::vector< BasicConfiguration > & result ) const;
581
592 ( Configuration cfg, Dimension i, Dimension j ) const;
593
594
595 }; // end of class NeighborhoodConvexityAnalyzer
596
597
598} // namespace DGtal
599
600
602// Includes inline functions.
603#include "NeighborhoodConvexityAnalyzer.ih"
604
605// //
607
608#endif // !defined NeighborhoodConvexityAnalyzer_h
609
610#undef NeighborhoodConvexityAnalyzer_RECURSES
611#endif // else defined(NeighborhoodConvexityAnalyzer_RECURSES)
Aim: This class encapsulates its parameter class to indicate that the given parameter is required to ...
Definition: Clone.h:267
Aim: A helper class to build polytopes from digital sets and to check digital k-convexity and full co...
bool isFullyConvex(const PointRange &X, bool convex0=false) const
bool is0Convex(const PointRange &X) const
const KSpace & space() const
Aim: Parallelepidec region of a digital space, model of a 'CDomain'.
TInteger Integer
Arithmetic ring induced by (+,-,*) and Integer numbers.
static const constexpr Dimension dimension
Aim: A class that models a neighborhood and that provides services to analyse the convexity properti...
Computation
Enum types indicating the possible type of local computations.
NeighborhoodConvexityAnalyzer(Clone< KSpace > aKSpace, Size memoizer_size=0)
BOOST_CONCEPT_ASSERT((concepts::CCellularGridSpaceND< TKSpace >))
static Configuration makeConfiguration(Configuration current, bool complement, bool with_center)
std::bitset< 512 > myBasicFullConvexityTable
Stores the full convexity property of the basic 3x3 neighborhood configurations.
NeighborhoodConvexityAnalyzer(Point lo, Point hi, Size memoizer_size=0)
int myComputations
Stores which properties have already been computed.
Domain myDomain
The bounded domain in which computations are carried out.
std::bitset< functions::const_pow(2 *K+1, dimension) > Configuration
void setCenter(Point c, const PointPredicate &X)
int myResults
Stores the properties boolean values.
bool checkBasicConfigurations0Convexity(bool compX, bool with_center) const
DigitalConvexity< KSpace > myDigConv
The digital convexity that is used for checking full convexity.
bool checkBasicConfigurationsFullConvexity(bool compX, bool with_center) const
bool myCenterInX
tells if the center belongs to X
void getLocalCompX(std::vector< Point > &localCompX, bool with_center) const
Size myNbInX
The number of points of the neighborhood that belongs to X (center omitted).
Configuration myCfgX
Stores the local configuration for X (without the center)
TimeStampMemoizer< Configuration, bool > myMemoizer
The memoizer.
std::bitset< 512 > myBasic0ConvexityTable
Stores the 0-convexity property of the basic 3x3 neighborhood configurations.
void getLocalX(std::vector< Point > &localX, bool with_center) const
Self & operator=(const Self &other)=default
bool isCenterInX() const
Tells if the current center belongs to the shape X.
Point myCenter
The current center of the neighborhood.
NeighborhoodConvexityAnalyzer< TKSpace, K > Self
void computeBasicConfigurations(Configuration cfg, std::vector< BasicConfiguration > &result) const
std::vector< BasicConfiguration > myBasicCfgX
Stores the basic local configurations associated to myCfgX, for speed-up.
BasicConfiguration computeCentralBasicConfiguration(Configuration cfg, Dimension i, Dimension j) const
NeighborhoodConvexityAnalyzer(const Self &other)=default
std::pair< Value, bool > get(const Key &key)
void set(const Key &key, const Value &value)
std::ostream & info()
constexpr T const_pow(T b, unsigned int e)
constexpr T const_middle(T K, unsigned int e)
DGtal is the top-level namespace which contains all DGtal functions and types.
DGtal::uint32_t Dimension
Definition: Common.h:137
Trace trace
Definition: Common.h:154
Aim: This concept describes a cellular grid space in nD. In these spaces obtained by cartesian produc...
KSpace K