Namespace List

Here is a list of all namespaces with brief descriptions:

[detail level 1234]

►Nboost
CDefaultConstructible	Go to http://www.sgi.com/tech/stl/DefaultConstructible.html
CAssignable	Go to http://www.sgi.com/tech/stl/Assignable.html
CCopyConstructible	Go to http://www.sgi.com/tech/stl/CopyConstructible.html
CInputIterator	Go to http://www.sgi.com/tech/stl/InputIterator.html
COutputIterator	Go to http://www.sgi.com/tech/stl/OutputIterator.html
CForwardIterator	Go to http://www.sgi.com/tech/stl/ForwardIterator.html
CBidirectionalIterator	Go to http://www.sgi.com/tech/stl/BidirectionalIterator.html
CRandomAccessIterator	Go to http://www.sgi.com/tech/stl/RandomAccessIterator.html
CEqualityComparable	Go to http://www.sgi.com/tech/stl/EqualityComparable.html
CLessThanComparable	Go to http://www.sgi.com/tech/stl/LessThanComparable.html
CSignedInteger	Go to http://www.sgi.com/tech/stl/SignedInteger.html
CUnsignedInteger	Go to http://www.boost.org/libs/concept_check/reference.htm
CInteger	Go to http://www.boost.org/libs/concept_check/reference.htm
CConvertible	Go to http://www.boost.org/libs/concept_check/reference.htm
CSGIAssignable	Go to http://www.boost.org/libs/concept_check/reference.htm
CMutable_ForwardIterator	Go to http://www.boost.org/libs/concept_check/reference.htm
CMutable_BidirectionalIterator	Go to http://www.boost.org/libs/concept_check/reference.htm
CMutable_RandomAccessIterator	Go to http://www.boost.org/libs/concept_check/reference.htm
CGenerator	Go to http://www.sgi.com/tech/stl/Generator.html
CUnaryFunction	Go to http://www.sgi.com/tech/stl/UnaryFunction.html
CBinaryFunction	Go to http://www.sgi.com/tech/stl/BinaryFunction.html
CUnaryPredicate	Go to http://www.sgi.com/tech/stl/Predicate.html
CBinaryPredicate	Go to http://www.sgi.com/tech/stl/BinaryPredicate.html
CConst_BinaryPredicate	Go to http://www.boost.org/libs/concept_check/reference.htm
CAdaptableGenerator	Go to http://www.sgi.com/tech/stl/AdaptableGenerator.html
CAdaptableUnaryFunction	Go to http://www.sgi.com/tech/stl/AdaptableUnaryFunction.html
CAdaptableBinaryFunction	Go to http://www.sgi.com/tech/stl/AdaptableBinaryFunction.html
CAdaptablePredicate	Go to http://www.sgi.com/tech/stl/AdaptablePredicate.html
CAdaptableBinaryPredicate	Go to http://www.sgi.com/tech/stl/AdaptableBinaryPredicate.html
CContainer	Go to http://www.sgi.com/tech/stl/Container.html
CMutable_Container	Go to http://www.boost.org/libs/concept_check/reference.htm
CForwardContainer	Go to http://www.sgi.com/tech/stl/ForwardContainer.html
CMutable_ForwardContainer	Go to http://www.boost.org/libs/concept_check/reference.htm
CReversibleContainer	Go to http://www.sgi.com/tech/stl/ReversibleContainer.html
CMutable_ReversibleContainer	Go to http://www.boost.org/libs/concept_check/reference.htm
CRandomAccessContainer	Go to http://www.sgi.com/tech/stl/RandomAccessContainer.html
CMutable_RandomAccessContainer	Go to http://www.boost.org/libs/concept_check/reference.htm
CSequence	Go to http://www.sgi.com/tech/stl/Sequence.html
CFrontInsertionSequence	Go to http://www.sgi.com/tech/stl/FrontInsertionSequence.html
CBackInsertionSequence	Go to http://www.sgi.com/tech/stl/BackInsertionSequence.html
CAssociativeContainer	Go to http://www.sgi.com/tech/stl/AssociativeContainer.html
CUniqueAssociativeContainer	Go to http://www.sgi.com/tech/stl/UniqueAssociativeContainer.html
CMultipleAssociativeContainer	Go to http://www.sgi.com/tech/stl/MultipleAssociativeContainer.html
CSimpleAssociativeContainer	Go to http://www.sgi.com/tech/stl/SimpleAssociativeContainer.html
CPairAssociativeContainer	Go to http://www.sgi.com/tech/stl/PairAssociativeContainer.html
CSortedAssociativeContainer	Go to http://www.sgi.com/tech/stl/SortedAssociativeContainer.html
CCollection	Go to http://www.sgi.com/tech/stl/Collection.html
CGraphConcept	Go to http://www.boost.org/doc/libs/1_52_0/libs/graph/doc/Graph.html
CVertexListGraphConcept	Go to http://www.boost.org/doc/libs/1_52_0/libs/graph/doc/VertexListGraph.html
CAdjacencyGraphConcept	Go to http://www.boost.org/doc/libs/1_52_0/libs/graph/doc/AdjacencyGraph.html
CIncidenceGraphConcept	Go to http://www.boost.org/doc/libs/1_52_0/libs/graph/doc/IncidenceGraph.html
CEdgeListGraphConcept	Go to http://www.boost.org/doc/libs/1_52_0/libs/graph/doc/EdgeListGraph.html
CMultiPassInputIterator	Go to http://www.boost.org/doc/libs/1_52_0/libs/utility/MultiPassInputIterator.html
Cis_integral	Go to http://www.boost.org/doc/libs/1_52_0/libs/type_traits/doc/html/index.html
Cis_unsigned	Go to http://www.boost.org/doc/libs/1_52_0/libs/type_traits/doc/html/index.html
►Cgraph_traits< DGtal::DigitalSurface< TDigitalSurfaceContainer > >
Cadjacency_iterator
Cedge_iterator
Cout_edge_iterator
►Cgraph_traits< DGtal::Object< TDigitalTopology, TDigitalSet > >
Cadjacency_iterator
Cedge_iterator
Cout_edge_iterator
Chash< DGtal::BigInteger >
CDigitalSurface_graph_traversal_category
Chash< DGtal::KhalimskyCell< dim, TInteger > >	Extend boost namespace to define a boost::hash function on DGtal::KhalimskyCell
Chash< DGtal::SignedKhalimskyCell< dim, TInteger > >	Extend boost namespace to define a boost::hash function on DGtal::SignedKhalimskyCell
CObject_graph_traversal_category
►Nboost_concepts
CReadableIteratorConcept	Go to http://www.boost.org/doc/libs/1_52_0/libs/iterator/doc/ReadableIterator.html
CWritableIteratorConcept	Go to http://www.boost.org/doc/libs/1_52_0/libs/iterator/doc/WritableIterator.html
CSwappableIteratorConcept	Go to http://www.boost.org/doc/libs/1_52_0/libs/iterator/doc/SwappableIterator.html
CLvalueIteratorConcept	Go to http://www.boost.org/doc/libs/1_52_0/libs/iterator/doc/LvalueIteratorConcept.html
CIncrementableIteratorConcept	Go to http://www.boost.org/doc/libs/1_52_0/libs/iterator/doc/IncrementableIterator.html
CSinglePassIteratorConcept	Go to http://www.boost.org/doc/libs/1_52_0/libs/iterator/doc/SinglePassIterator.html
CForwardTraversalConcept	Go to http://www.boost.org/doc/libs/1_52_0/libs/iterator/doc/ForwardTraversal.html
CBidirectionalTraversalConcept	Go to http://www.boost.org/doc/libs/1_52_0/libs/iterator/doc/BidirectionalTraversal.html
CRandomAccessTraversalConcept	Go to http://www.boost.org/doc/libs/1_52_0/libs/iterator/doc/RandomAccessTraversal.html
CInteroperableIteratorConcept	Go to http://www.boost.org/doc/libs/1_52_0/libs/iterator/doc/InteroperableIterator.html
►NDGtal	DGtal is the top-level namespace which contains all DGtal functions and types
►Nconcepts	Aim: Gathers several functions useful for concept checks
►NConceptUtils
CSameType
CSameType< T, T >
CCheckTrue
CCheckTrue< TagTrue >
CCheckFalse
CCheckUnknown
CCheckUnknown< TagUnknown >
CCheckTrueOrFalse
CCheckTag
CCPositiveIrreducibleFraction	Aim: Defines positive irreducible fractions, i.e. fraction p/q, p and q non-negative integers, with gcd(p,q)=1
CCBackInsertable	Aim: Represents types for which a std::back_insert_iterator can be constructed with std::back_inserter. Back Insertion Sequence are refinements of CBackInsertable. They require more services than CBackInsertable, for instance read services or erase services
CCBidirectionalRange	Aim: Defines the concept describing a bidirectional range
CCBidirectionalRangeFromPoint	Aim: refined concept of single pass range with a begin() method from a point
CCBidirectionalRangeWithWritableIterator	Aim: refined concept of bidirectional range which require that a reverse output iterator exists
CCBidirectionalRangeWithWritableIteratorFromPoint	Aim: refined concept of single pass range with an routputIterator() method from a point
CCConstBidirectionalRange	Aim: Defines the concept describing a bidirectional const range
CCConstBidirectionalRangeFromPoint	Aim: refined concept of const bidirectional range with a begin() method from a point
CCConstSinglePassRange	Aim: Defines the concept describing a const single pass range
CCConstSinglePassRangeFromPoint	Aim: refined concept of const single pass range with a begin() method from a point
CCLabel	Aim: Define the concept of DGtal labels. Models of CLabel can be default-constructible, assignable and equality comparable
CCPredicate	Aim: Defines a predicate function, ie. a functor mapping a domain into the set of booleans
CCQuantity	Aim: defines the concept of quantity in DGtal
CCSinglePassRange	Aim: Defines the concept describing a range
CCSinglePassRangeFromPoint	Aim: refined concept of single pass range with a begin() method from a point
CCSinglePassRangeWithWritableIterator	Aim: refined concept of const single pass range which require that an output iterator exists
CCSinglePassRangeWithWritableIteratorFromPoint	Aim: refined concept of single pass range with a outputIterator() method from a point
CCStack	Aim: This concept gathers classes that provide a stack interface
CCSTLAssociativeContainer	Aim: Defines the concept describing an Associative Container of the STL (https://www.sgi.com/tech/stl/AssociativeContainer.html)
CCUnaryFunctor	Aim: Defines a unary functor, which associates arguments to results
CCUnaryFunctor< X, A &, R & >
CCDiscreteExteriorCalculusVectorSpace	Aim: Lift linear algebra container concept into the dec package
CCBidirectionalSegmentComputer	Aim: Defines the concept describing a bidirectional segment computer, ie. a model of concepts::CSegment that can extend itself in the two possible directions
CCDynamicBidirectionalSegmentComputer	Aim: Defines the concept describing a dynamic and bidirectional segment computer, ie. a model of concepts::CSegment that can extend and retract itself in either direction
CCDynamicSegmentComputer	Aim: Defines the concept describing a dynamic segment computer, ie. a model of CSegment that can extend and retract itself (in the direction that is relative to the underlying iterator).
CCForwardSegmentComputer	Aim: Defines the concept describing a forward segment computer. Like any model of CIncrementalSegmentComputer, it can control its own extension (in the direction that is relative to the underlying iterator) so that an implicit predicate P remains true. However, contrary to models of CIncrementalSegmentComputer, it garantees that P is also true for any subrange of the whole segment at any time. This extra constraint is necessary to be able to incrementally check whether or not the segment is maximal
CCIncrementalSegmentComputer	Aim: Defines the concept describing an incremental segment computer, ie. a model of CSegmentFactory that can, in addition, incrementally check whether or not an implicit predicate P is true. In other words, it can control its own extension from a range of one element (in the direction that is relative to the underlying iterator) so that an implicit predicate P remains true.
CCSegment	Aim: Defines the concept describing a segment, ie. a valid and not empty range
CCSegmentFactory	Aim: Defines the concept describing a segment ie. a valid and not empty subrange, which can construct instances of its own type or of derived type
CCCurveLocalGeometricEstimator	Aim: This concept describes an object that can process a range so as to return one estimated quantity for each element of the range (or a given subrange)
CCGlobalGeometricEstimator	Aim: This concept describes an object that can process a range so as to return one estimated quantity for the whole range
CCLMSTDSSFilter	Aim: Defines the concept describing a functor which filters DSSes for L-MST calculations
CCLMSTTangentFromDSS	Aim: Defines the concept describing a functor which calculates a direction of the 2D DSS and an eccentricity [74] of a given point in this DSS
CCSegmentComputerEstimator	Aim: This concept is a refinement of CCurveLocalGeometricEstimator devoted to the estimation of a geometric quantiy along a segment detected by a segment computer
CC3DParametricCurve	Aim:
CC3DParametricCurveDecorator	Aim:
CCAdditivePrimitiveComputer	Aim: Defines the concept describing an object that computes some primitive from input points given group by group, while keeping some internal state. At any moment, the object is supposed to store at least one valid primitive for the formerly given input points. A primitive is an informal word that describes some family of objects that share common characteristics. Often, the primitives are geometric, e.g. digital planes
CCIncrementalPrimitiveComputer	Aim: Defines the concept describing an object that computes some primitive from input points given one at a time, while keeping some internal state. At any moment, the object is supposed to store at least one valid primitive for the formerly given input points. A primitive is an informal word that describes some family of objects that share common characteristics. Often, the primitives are geometric, e.g. digital planes
CCPrimitiveComputer	Aim: Defines the concept describing an object that computes some primitive from input points, while keeping some internal state. At any moment, the object is supposed to store at least one valid primitive for the formerly given input points. A primitive is an informal word that describes some family of objects that share common characteristics. Often, the primitives are geometric, e.g. digital planes
CCDigitalSurfaceLocalEstimator	Aim: This concept describes an object that can process a range over some generic digital surface so as to return one estimated quantity for each element of the range (or a given subrange)
CCNormalVectorEstimator	Aim: Represents the concept of estimator of normal vector along digital surfaces
CCSurfelLocalEstimator	Aim: This concept describes an object that can process a range of surfels (that are supposed to belong to some (abstract) surface) so as to return one estimated quantity for each element of the range (or a given subrange)
CCLocalEstimatorFromSurfelFunctor	Aim: this concept describes functors on digtal surface surfel which can be used to define local estimator using the adapter LocalEstimatorFromSurfelFunctorAdapter
CCPolarPointComparator2D	Aim: This concept gathers classes that are able to compare the position of two given points \( P, Q \) around a pole \( O \). More precisely, they compare the oriented angles lying between the horizontal line passing by \( O \) and the rays \( [OP) \) and \( [OQ) \) (in a counter-clockwise orientation). This is equivalent to compare the angle in radians from 0 (included) to 2 π (excluded)
CCOrientationFunctor	Aim: This concept gathers models implementing an orientation test of \( k+1 \) points in a space of dimension \( n \)
CCOrientationFunctor2	Aim: This concept is a refinement of COrientationFunctor, useful for simple algebraic curves that can be uniquely defined by only two points.
CCDigitalMetricSpace	Aim: defines the concept of digital metric spaces
CCMetricSpace	Aim: defines the concept of metric spaces
CCPowerMetric	Aim: defines the concept of special weighted metrics, so called power metrics
CCPowerSeparableMetric	Aim: defines the concept of separable metrics
CCSeparableMetric	Aim: defines the concept of separable metrics
CCGraphVisitor	Aim: Defines the concept of a visitor onto a graph, that is an object that traverses vertices of the graph according to some order. The user can either use the visitor as is, or even constrain the traversal with a given predicate
CCUndirectedSimpleGraph	Aim: Represents the concept of local graph: each vertex has neighboring vertices, but we do not necessarily know all the vertices
►CCUndirectedSimpleLocalGraph	Aim: Represents the concept of local graph: each vertex has neighboring vertices, but we do not necessarily know all the vertices
CVertexMap
CCVertexMap	Aim: models of CVertexMap concept implement mapping between graph vertices and values
CCVertexPredicate	Aim: Defines a predicate on a vertex
CCVertexPredicateArchetype	Aim: Defines a an archetype for concept CVertexPredicate
CCConstImage	Aim: Defines the concept describing a read-only image, which is a refinement of CPointFunctor
CCImage	Aim: Defines the concept describing a read/write image, having an output iterator
CCImageCacheReadPolicy	Aim: Defines the concept describing a cache read policy
CCImageCacheWritePolicy	Aim: Defines the concept describing a cache write policy
CCImageFactory	Aim: Defines the concept describing an image factory
CCTrivialConstImage	Aim: Defines the concept describing a read-only image, which is a refinement of CPointFunctor
CCTrivialImage	Aim: Defines the concept describing an image without extra ranges, which is a refinement of CTrivialConstImage
CCDrawableWithBoard2D	Aim: The concept CDrawableWithBoard2D specifies what are the classes that admit an export with Board2D
CBoard3DTo2D	Aim: The concept CDrawableWithBoard3DTo2D specifies what are the classes that admit an export with Board3DTo2D
CCDrawableWithBoard3DTo2D
CDisplay3D	Aim: The concept CDrawableWithDisplay3D specifies what are the classes that admit an export with Display3D
CCDrawableWithDisplay3D
CCColorMap	Aim: Defines the concept describing a color map. A color map converts a value within a given range into an RGB triple
CCDrawableWithViewer3D	Aim: The concept CDrawableWithViewer3D specifies what are the classes that admit an export with Viewer3D
CCBoundedNumber	Aim: The concept CBoundedNumber specifies what are the bounded numbers. Models of this concept should be listed in NumberTraits class and should have the isBounded property
CCCommutativeRing	Aim: Defines the mathematical concept equivalent to a unitary commutative ring
CCEuclideanRing	Aim: Defines the mathematical concept equivalent to a unitary commutative ring with a division operator
CCInteger	Aim: Concept checking for Integer Numbers. More precisely, this concept is a refinement of both CEuclideanRing and CIntegralNumber
CCIntegralNumber	Aim: Concept checking for Integral Numbers. Models of this concept should be listed in NumberTraits class and should have the isIntegral property
CCPointEmbedder	Aim: A point embedder is a mapping from digital points to Euclidean points. It adds inner types to functor
CCPointFunctor	Aim: Defines a functor on points
CCPointPredicate	Aim: Defines a predicate on a point
CCSignedNumber	Aim: Concept checking for Signed Numbers. Models of this concept should be listed in NumberTraits class and should have the isSigned property
CCSpace	Aim: Defines the concept describing a digital space, ie a cartesian product of integer lines
CCUnsignedNumber	Aim: Concept checking for Unsigned numbers. Models of this concept should be listed in NumberTraits class and should have the isUnsigned property
CCWithGradientMap	Aim: Such object provides a gradient map that associates to each argument some real vector
CCDomain	Aim: This concept represents a digital domain, i.e. a non mutable subset of points of the given digital space
CCDomainArchetype	Aim: The archetype of a class that represents a digital domain, i.e. a non mutable subset of points of the given digital space
CCDigitalSet	Aim: Represents a set of points within the given domain. This set of points is modifiable by the user. It is thus very close to the STL concept of simple associative container (like set std::set<Point>), except that there is a notion of maximal set of points (the whole domain)
CCDigitalSetArchetype	Aim: The archetype of a container class for storing sets of digital points within some given domain
CCBinner	Aim: Represents an object that places a quantity into a bin, i.e. a functor that associates a natural integer to a continuous value
CCDenseMatrix	Aim: Represent any dynamic or static sized matrix having dense representation
CCDenseVector	Aim: Represent any dynamic or static sized matrix having dense representation
CCDynamicMatrix	Aim: Represent any dynamic sized matrix having sparse or dense representation
CCDynamicVector	Aim: Represent any dynamic sized column vector having sparse or dense representation
CCLinearAlgebra	Aim: Check right multiplication between matrix and vector and internal matrix multiplication. Matrix and vector scalar types should be the same
CCLinearAlgebraSolver	Aim: Describe a linear solver defined over a linear algebra. Problems are of the form:
CCMatrix	Aim: Represent any static or dynamic sized matrix having sparse or dense representation
CCSparseMatrix	Aim: Represent any dynamic or static sized matrix having sparse representation
CCStaticMatrix	Aim: Represent any static sized matrix having sparse or dense representation
CCStaticVector	Aim: Represent any static sized column vector having sparse or dense representation
CCVector	Aim: Represent any static or dynamic sized column vector having sparse or dense representation
CCVectorSpace	Aim: Base concept for vector space structure
CCDigitalBoundedShape	Aim: designs the concept of bounded shapes in DGtal (shape for which upper and lower bounding bounds are available)
CCDigitalOrientedShape	Aim: characterizes models of digital oriented shapes. For example, models should provide an orientation method for points on a SpaceND. Returned value type corresponds to DGtal::Orientation
CCEuclideanBoundedShape
CCEuclideanOrientedShape	Aim: characterizes models of digital oriented shapes. For example, models should provide an orientation method for real points. Returned value type corresponds to DGtal::Orientation
CCImplicitFunction	Aim: Describes any function of the form f(x), where x is some real point in the given space, and f(x) is some value
CCImplicitFunctionDiff1	Aim: Describes a 1-differentiable function of the form f(x), where x is some real point in the given space, and f(x) is some value
CCAdjacency	Aim: The concept CAdjacency defines an elementary adjacency relation between points of a digital space
CCCellEmbedder	Aim: A cell embedder is a mapping from unsigned cells to Euclidean points. It adds inner types to functor
CCCellFunctor	Aim: Defines a functor on cells
CCCellularGridSpaceND	Aim: This concept describes a cellular grid space in nD. In these spaces obtained by cartesian product, cells have a cubic shape that depends on the dimension: 0-cells are points, 1-cells are unit segments, 2-cells are squares, 3-cells are cubes, and so on
CCDigitalSurfaceContainer	Aim: The digital surface container concept describes a minimal set of inner types and methods so as to describe the data of digital surfaces
CCDigitalSurfaceEmbedder	Aim: A digital surface embedder is a specialized mapping from signed cells to Euclidean points. It adds inner types to functor as well as a method to access the digital surface
CCDigitalSurfaceTracker	Aim:
CCDomainAdjacency	Aim: Refines the concept CAdjacency by telling that the adjacency is specific to a given domain of the embedding digital space
CCPreCellularGridSpaceND	Aim: This concept describes an unbounded cellular grid space in nD. In these spaces obtained by cartesian product, cells have a cubic shape that depends on the dimension: 0-cells are points, 1-cells are unit segments, 2-cells are squares, 3-cells are cubes, and so on
CCSCellEmbedder	Aim: A cell embedder is a mapping from signed cells to Euclidean points. It adds inner types to functor
CCSurfelPredicate	Aim: Defines a predicate on a surfel
Ndec_helper	Namespace for functions useful to Discrete Exterior Calculus package
►Ndeprecated	Deprecated functions and types of the DGtal library
►Nconcepts
CCConvolutionWeights	Aim: defines models of centered convolution kernel used for normal vector integration for instance
CConstantConvolutionWeights	Aim: implement a trivial constant convolution kernel which returns 1 to each distance
CGaussianConvolutionWeights	Aim: implement a Gaussian centered convolution kernel
►CIntegralInvariantNormalVectorEstimator	Aim: This class implement an Integral Invariant normal vector estimator
CCovarianceMatrix2NormalDirectionFunctor
CLocalConvolutionNormalVectorEstimator	Aim: Computes the normal vector at a surface element by convolution of elementary normal vector to adjacent surfel
CSetPredicate	Aim: The predicate returning true iff the point is in the set given at construction. The set given at construction is aliased in the predicate and not cloned, which means that the lifetime of the set should exceed the lifetime of the predicate
CDigitalShapesUnion	Aim: Union between two models of CDigitalBoundedShape and CDigitalOrientedShape
CDigitalShapesIntersection	Aim: Intersection between two models of CDigitalBoundedShape and CDigitalOrientedShape
CDigitalShapesMinus	Aim: Minus between two models of CDigitalBoundedShape and CDigitalOrientedShape
CEuclideanShapesUnion	Aim: Union between two models of CEuclideanBoundedShape and CEuclideanOrientedShape
CEuclideanShapesIntersection	Aim: Intersection between two models of CEuclideanBoundedShape and CEuclideanOrientedShape
CEuclideanShapesMinus	Aim: Minus between two models of CEuclideanBoundedShape and CEuclideanOrientedShape
CDomainMetricAdjacency	Aim: Describes digital adjacencies in a digital domain that are defined with the 1-norm and the infinity-norm
►Ndetail	detail namespace gathers internal classes and functions
CHasNestedTypeCategory	Aim: Checks whether type T has a nested type called 'Category' or not. NB: from en.wikipedia.org/wiki/Substitution_failure_is_not_an_error NB: to avoid various compiler issues, we use BOOST_STATIC_CONSTANT according to http://www.boost.org/development/int_const_guidelines.html
CIsContainerFromCategory
CIsSequenceContainerFromCategory
CIsAssociativeContainerFromCategory
CIsOrderedAssociativeContainerFromCategory
CIsUnorderedAssociativeContainerFromCategory
CIsSimpleAssociativeContainerFromCategory
CIsPairAssociativeContainerFromCategory
CIsUniqueAssociativeContainerFromCategory
CIsMultipleAssociativeContainerFromCategory
CHasNestedTypeType	Aim: Checks whether type IC has a nested type called 'Type' or not. NB: from en.wikipedia.org/wiki/Substitution_failure_is_not_an_error NB: to avoid various compiler issues, we use BOOST_STATIC_CONSTANT according to http://www.boost.org/development/int_const_guidelines.html
CIsCirculatorFromType	Aim: In order to check whether type IC is a circular or a classical iterator, the nested type called 'Type' is read.
CIsCirculatorFromType< IC, CirculatorType >
CIsCirculator	Aim: Checks whether type IC is a circular or a classical iterator. Static value set to 'true' for a circulator, 'false' otherwise. 1) if type IC has no nested type 'Type', it is a classical iterator and 'false' is returned. 2) if type IC has a nested type 'Type', 'true' is returned is 'Type' is CirculatorType, 'false' otherwise
CIsCirculator< IC, true >
CIteratorCirculatorTypeImpl	Aim: Defines the Iterator or Circulator type as a nested type according to the value of b
CIteratorCirculatorTypeImpl< true >
CLabelledMapMemFunctor
CEqualPredicateFromLessThanComparator
CKeyComparatorForPairKeyData
CComparatorAdapter
CComparatorAdapter< Container, true, true, false >	Set-like adapter
CComparatorAdapter< Container, true, true, true >	Map-like adapter
CComparatorAdapter< Container, true, false, false >	Unordered set-like adapter
CComparatorAdapter< Container, true, false, true >	Unordered map-like adapter
CSetFunctionsImpl	Aim: Specialize set operations (union, intersection, difference, symmetric_difference) according to the given type of container. It uses standard algorithms when containers are ordered, otherwise it provides a default implementation
CSetFunctionsImpl< Container, true, false >
CSetFunctionsImpl< Container, true, true >
CSetFunctionsImpl< Container, false, true >
CtoCoordinateImpl	Aim: Define a simple functor that can cast a signed integer (possibly a DGtal::BigInteger) into another
CtoCoordinateImpl< DGtal::BigInteger, TOutput >
CtoCoordinateImpl< DGtal::BigInteger, DGtal::BigInteger >
CPosIndepScaleIndepSCEstimator
CPosIndepScaleDepSCEstimator
CPosDepScaleIndepSCEstimator
CPosDepScaleDepSCEstimator
CTangentAngleFromDSS
CNormalizedTangentVectorFromDSS
CTangentVectorFromDSS
CCurvatureFromDCA
CCurvatureFromDCA< false >
CNormalVectorFromDCA
CTangentVectorFromDCA
CDistanceFromDCA
CCurvatureFromDSSLength
CCurvatureFromDSSLengthAndWidth
CCurvatureFromDSSBaseEstimator
CDSSDecorator	Aim: Abstract DSSDecorator for ArithmeticalDSSComputer. Has 2 virtual methods returning the first and last leaning point:
CDSSDecorator4ConvexPart	Aim: adapter for TDSS used by FP in CONVEX parts. Has 2 methods:
CDSSDecorator4ConcavePart	Aim: adapter for TDSS used by FP in CONCAVE parts. Has 2 methods:
CPointOnProbingRay	A ray consists of a permutation \( \sigma \) and an integer index \( \lambda \) (position on the ray). For a triplet of vectors \( (m_k)_{0 \leq k \leq 2} \) and a point \( q \), a point on the ray is defined as: \( q - m_{\sigma(0)} + m_{\sigma(1)} + \lambda m_{\sigma(2)} \). \( q - m_{\sigma(0)} + m_{\sigma(1)} \) is called the base point
CGridPoint	A grid point consists of a couple of nonnegative coordinates \( (x,y) \) and an integer index \( k \) that determines a point used as origin. For a triplet of vectors \( (m_k)_{0 \leq k \leq 2} \) and a point \( q \), a grid point is defined as: \( q - m_{k} + x m_{(k+1)\bmod 3} + y m_{(k+2)\bmod 3} \). \( q - m_{k} \), called base point, is used as origin
CGridPointOnProbingRay	Aim: Represents a grid point along a discrete ray defined on a grid
CEuclideanDivisionHelper	Aim: Small stucture that provides a static method returning the Euclidean division of two integers
CEuclideanDivisionHelper< float >
CEuclideanDivisionHelper< double >
CEuclideanDivisionHelper< long double >
CBoundedLatticePolytopeSpecializer	Aim: It is just a helper class for BoundedLatticePolytope to add dimension specific static methods
CBoundedLatticePolytopeSpecializer< 3, TInteger >	Aim: 3D specialization for BoundedLatticePolytope to add dimension specific static methods
CBoundedRationalPolytopeSpecializer	Aim: It is just a helper class for BoundedRationalPolytope to add dimension specific static methods
CBoundedRationalPolytopeSpecializer< 3, TInteger >	Aim: 3D specialization for BoundedRationalPolytope to add dimension specific static methods
CConvexityHelperInternalInteger
CConvexityHelperInternalInteger< DGtal::int32_t, true >
CConvexityHelperInternalInteger< DGtal::int32_t, false >
CConvexityHelperInternalInteger< DGtal::int64_t, true >
CConvexityHelperInternalInteger< DGtal::int64_t, false >
CConvexityHelperInternalInteger< DGtal::BigInteger, safe >
CPointValueCompare	Aim: Small binary predicate to order candidates points according to their (absolute) distance value
CRecursivePConvexity
CRecursivePConvexity< 1, TInteger >
CValueConverter	Generic definition of a class for converting type X toward type Y
CValueConverter< std::string, double >	Specialized definitions of a class for converting type X toward type Y
CValueConverter< std::string, float >	Specialized definitions of a class for converting type X toward type Y
CValueConverter< std::string, int >	Specialized definitions of a class for converting type X toward type Y
CValueConverter< X, std::string >	Specialized definitions of a class for converting type X toward type Y
Cpower_node
Cmonomial_node
Ctop_node
CFFTWComplexCast	Facility to cast to the complex type used by fftw
CFFTWWrapper	Wrapper to fftw functions depending on value type
CFFTWWrapper< double >
CFFTWWrapper< float >
CFFTWWrapper< long double >
►Ndetails
CBoolToTag	Convert a boolean to the corresponding DGtal tag (TagTrue or TagFalse)
CBoolToTag< false >
CNumberTraitsImplFundamental	NumberTraits common part for fundamental integer and floating-point types
►Nexperimental	Experimental functions and types of the DGtal library
►CChamferNorm2D	Aim: implements a model of CSeparableMetric for Chamfer and path based norms
CLessOrEqThanAngular
CLessThanAngular
►CImageContainerByHashTree	Model of CImageContainer implementing the association key<->Value using a hash tree. This class provides a built-in iterator
CIterator	Built-in iterator on an HashTree. This iterator visits all node in the tree
CNode
►Nfunctions	functions namespace gathers all DGtal functionsxs
Ndec
NHull2D	Hull2D namespace gathers useful functions to compute and return the convex hull or the alpha-shape of a range of 2D points
Nsetops
►Nfunctors	functors namespace gathers all DGtal functors
►Ndeprecated
CSCellToMidPoint	Aim: transforms a scell into a real point (the coordinates are divided by 2)
►NShapeGeometricFunctors
CShapePositionFunctor	Aim: A functor RealPoint -> Quantity that returns the position of the point itself
CShapeNormalVectorFunctor	Aim: A functor RealPoint -> Quantity that returns the normal vector at given point
CShapeMeanCurvatureFunctor	Aim: A functor RealPoint -> Quantity that returns the mean curvature at given point
CShapeGaussianCurvatureFunctor	Aim: A functor RealPoint -> Quantity that returns the gaussian curvature at given point
CShapeFirstPrincipalCurvatureFunctor	Aim: A functor RealPoint -> Quantity that returns the first principal curvature at given point (i.e. smallest principal curvature)
CShapeSecondPrincipalCurvatureFunctor	Aim: A functor RealPoint -> Quantity that returns the second principal curvature at given point (i.e. greatest principal curvature)
CShapeFirstPrincipalDirectionFunctor	Aim: A functor RealPoint -> RealVector that returns the first principal direction at given point (i.e. direction of smallest principal curvature)
CShapeSecondPrincipalDirectionFunctor	Aim: A functor RealPoint -> RealVector that returns the second principal direction at given point (i.e. direction of second/greatest principal curvature)
CShapePrincipalCurvaturesAndDirectionsFunctor	Aim: A functor RealPoint -> (Scalar,Scalar,RealVector,RealVector that returns the principal curvatures and the principal directions as a tuple at given point (k1,k2,d1,d2)
CTrueBoolFct0
CFalseBoolFct0
CIdentityBoolFct1
CNotBoolFct1
CAndBoolFct2
COrBoolFct2
CXorBoolFct2
CImpliesBoolFct2
CMin	Duplicated STL functors
CMax
CMinus
CAbs
CUnaryMinus
CMultiplicationByScalar
CRound	Functor that rounds to the nearest integer
CRound< void >	Functor that rounds to the nearest integer
CFloor	Functor that rounds down
CFloor< void >	Functor that rounds down
CCeil	Functor that rounds up
CCeil< void >	Functor that rounds up
CTrunc	Functor that rounds towards zero
CTrunc< void >	Functor that rounds towards zero
CIdentity	Aim: Define a simple default functor that just returns its argument
CConstValue	Aim: Define a simple functor that returns a constant value (0 by default)
CConstValueCell	Aim: Define a simple functor that returns a constant quantity (0 by default)
CCast	Aim: Define a simple functor using the static cast operator
CComposer	Aim: Define a new Functor from the composition of two other functors
CThresholder	Aim: A small functor with an operator () that compares one value to a threshold value according to two bool template parameters
CThresholder< T, false, false >
CThresholder< T, false, true >
CThresholder< T, true, false >
CThresholder< T, true, true >
CPredicateCombiner	Aim: The predicate returns true when the given binary functor returns true for the two Predicates given at construction
CIntervalThresholder	Aim: A small functor with an operator () that compares one value to an interval
CPair1st	Aim: Define a simple functor that returns the first member of a pair
CPair2nd	Aim: Define a simple functor that returns the second member of a pair
CPair1stMutator	Aim: Define a simple unary functor that returns a reference on the first member of a pair in order to update it
CPair2ndMutator	Aim: Define a simple unary functor that returns a reference on the first member of a pair in order to update it
CRescaling	Aim: Functor allowing to rescale a value. Values of the initial scale [initMin,initMax] are rescaled to the new scale [newMin,newMax]
CGaussianKernel	Aim: defines a functor on double numbers which corresponds to a Gaussian convolution kernel. This functor acts from [0,1] to [0,1]
CFunctorHolder	Aim: hold any callable object (function, functor, lambda, ...) as a C(Unary)Functor model
CEmbedderFromNormalVectors	Functor that projects a face vertex of a surface mesh onto the tangent plane given by a per-face normal vector. This functor can be used in PolygonalCalculus to correct the embedding of digital surfaces using an estimated normal vector field (see [26])
CPositionFunctorFrom2DPoint	Functor that returns the position of any point/vector with respect to a digital straight line of shift myShift. We recall that the shift vector is a vector translating a point of remainder \( r \) to a point of remainder \( r + \omega \). See Digital straight lines and segments for further details
CLargeTruncationFunctor	Binary functor that returns the algebraic quotient i of a/b with any fractional part discarded (truncation toward zero). Note that \( |i| \leq |a/b| \)
CStrictTruncationFunctor	BinaryFunctor that computes the algebraic quotient i of a/b with any non zero fractional part discarded (truncation toward zero), and that returns i+1 (resp. i-1) if a is negative (resp. positive) if b divides a. Since we assume that a is not equal to 0, we have \( |i| < |a/b| \). See also LargeTruncationFunctor
CLambda64Function
CLambdaSinFromPiFunction
CLambdaExponentialFunction
CDummyEstimatorFromSurfels
CElementaryConvolutionNormalVectorEstimator	Aim: Estimates normal vector by convolution of elementary normal vector to adjacent surfel
CLinearLeastSquareFittingNormalVectorEstimator	Aim: Estimates normal vector using CGAL linear least squares plane fitting
CMongeJetFittingGaussianCurvatureEstimator	Aim: Estimates Gaussian curvature using CGAL Jet Fitting and Monge Form
CMongeJetFittingMeanCurvatureEstimator	Aim: Estimates Mean curvature using CGAL Jet Fitting and Monge Form
CMongeJetFittingNormalVectorEstimator	Aim: Estimates normal vector using CGAL Jet Fitting and Monge Form
CMongeJetFittingPrincipalCurvaturesEstimator	Aim: Estimates Gaussian curvature using CGAL Jet Fitting and Monge Form
►CSphereFittingEstimator	Aim: Use Patate library to perform a local sphere fitting
CPatatePoint
CQuantity	Quantity type: a 3-sphere (model of CQuantity)
CSphericalHoughNormalVectorEstimator	Aim: This functor estimates normal vector for a collection of surfels using spherical accumulator based Hough voting
CTensorVotingFeatureExtraction	Aim: Implements a functor to detect feature points from normal tensor voting strategy
CIINormalDirectionFunctor	Aim: A functor Matrix -> RealVector that returns the normal direction by diagonalizing the given covariance matrix
CIITangentDirectionFunctor	Aim: A functor Matrix -> RealVector that returns the tangent direction by diagonalizing the given covariance matrix. This functor is valid only in 2D space
CIIFirstPrincipalDirectionFunctor	Aim: A functor Matrix -> RealVector that returns the first principal curvature direction by diagonalizing the given covariance matrix. This functor is valid starting from 2D space and is equivalent to IITangentDirectionFunctor in 2D. Note that by first we mean the direction with greatest curvature in absolute value
CIISecondPrincipalDirectionFunctor	Aim: A functor Matrix -> RealVector that returns the second principal curvature direction by diagonalizing the given covariance matrix. This functor is valid starting from 3D space. Note that by second we mean the direction with second greatest curvature in absolute value
CIIPrincipalDirectionsFunctor	Aim: A functor Matrix -> std::pair<RealVector,RealVector> that returns the first and the second principal curvature directions by diagonalizing the given covariance matrix. This functor is valid starting from 3D space. Note that by second we mean the direction with second greatest curvature in absolute value
CIIPrincipalCurvaturesAndDirectionsFunctor	Aim: A functor Matrix -> std::pair<RealVector,RealVector> that returns the first and the second principal curvature directions by diagonalizing the given covariance matrix. This functor is valid only for 3D space. Note that by second we mean the direction with second greatest curvature in absolute value
CIICurvatureFunctor	Aim: A functor Real -> Real that returns the 2d curvature by transforming the given volume. This functor is valid only in 2D space
CIIMeanCurvature3DFunctor	Aim: A functor Real -> Real that returns the 3d mean curvature by transforming the given volume. This functor is valid only in 3D space
CIIGaussianCurvature3DFunctor	Aim: A functor Matrix -> Real that returns the Gaussian curvature by diagonalizing the given covariance matrix. This functor is valid starting from 3D space. Note that the Gaussian curvature is computed by multiplying the two gretest curvature values in absolute value
CIIFirstPrincipalCurvature3DFunctor	Aim: A functor Matrix -> Real that returns the first principal curvature value by diagonalizing the given covariance matrix. This functor is valid starting from 3D space. Note that by first we mean the value with first greatest curvature in absolute value
CIISecondPrincipalCurvature3DFunctor	Aim: A functor Matrix -> Real that returns the second principal curvature value by diagonalizing the given covariance matrix. This functor is valid starting from 3D space. Note that by second we mean the value with second greatest curvature in absolute value
CIIPrincipalCurvatures3DFunctor	Aim: A functor Matrix -> std::pair<Real,Real> that returns the first and the second principal curvature value by diagonalizing the given covariance matrix. This functor is valid starting from 3D space. Note that by first we mean the value with first greatest curvature in absolute value
CVCMNormalVectorFunctor	Aim: A functor Surfel -> Quantity that returns the outer normal vector at given surfel
CVCMAbsoluteCurvatureFunctor	Aim: A functor Surfel -> Quantity that returns the absolute curvature at given surfel. This class has meaning only in 2D
CVCMFirstPrincipalAbsoluteCurvatureFunctor	Aim: A functor Surfel -> Quantity that returns the first principal absolute curvature (greatest curvature) at given surfel. This class has meaning only in 3D
CVCMSecondPrincipalAbsoluteCurvatureFunctor	Aim: A functor Surfel -> Quantity that returns the second principal absolute curvature (smallest curvature) at given surfel. This class has meaning only in 3D
CVCMMeanAbsoluteCurvatures3DFunctor	Aim: A functor Surfel -> Quantity that returns the mean of absolute curvatures at given surfel: (abs(k1)+abs(k2))/2. This class has meaning only in 3D
CPolarPointComparatorBy2x2DetComputer	Aim: Class that implements a binary point predicate, which is able to compare the position of two given points \( P, Q \) around a pole \( O \). More precisely, it compares the oriented angles lying between the horizontal line passing by \( O \) and the rays \( [OP) \) and \( [OQ) \) (in a counter-clockwise orientation)
►CConstImageFunctorHolder	Transform a point-dependent (and possibly domain-dependent) functor into a constant image
CConstRange	Constant range on a ConstImageFunctorHolder
CIntervalForegroundPredicate	Aim: Define a simple Foreground predicate thresholding image values between two constant values (the first one being excluded)
CForwardRigidTransformation2D	Aim: implements forward rigid transformation of point in the 2D integer space. Warring: This version uses closest neighbor interpolation
CBackwardRigidTransformation2D	Aim: implements backward rigid transformation of point in the 2D integer space. Warring: This version uses closest neighbor interpolation
CDomainRigidTransformation2D	Aim: implements bounds of transformed domain
CForwardRigidTransformation3D	Aim: implements forward rigid transformation of point in 3D integer space around any arbitrary axis. This implementation uses the Rodrigues' rotation formula. Warring: This version uses closest neighbor interpolation
CBackwardRigidTransformation3D	Aim: implements backward rigid transformation of point in 3D integer space around any arbitrary axis. This implementation uses the Rodrigues' rotation formula. Warring: This version uses closest neighbor interpolation
CDomainRigidTransformation3D	Aim: implements bounds of transformed domain
CSimpleThresholdForegroundPredicate	Aim: Define a simple Foreground predicate thresholding image values given a single thresold. More precisely, the functor operator() returns true if the value is greater than a given threshold
CRedChannel
CBlueChannel
CGreenChannel
CMeanChannels
CColorRGBEncoder
CProjector	Aim: Functor that maps a point P of dimension i to a point Q of dimension j. The member myDims is an array containing the coordinates - (0, 1, ..., j-1) by default - that are copied from P to Q
CSliceRotator2D	Special Point Functor that adds one dimension to a 2D point and apply on it a rotation of angle alpha according to a given direction and the domain center. It also checks if the resulting point is inside the 3D domain, else it returns a particular point (by default the point at domain origin (from the domain method lowerBound())
CPoint2DEmbedderIn3D	Aim: Functor that embeds a 2D point into a 3D space from two axis vectors and an origin point given in the 3D space
CPointFunctorFromPointPredicateAndDomain	Create a point functor from a point predicate and a domain
CBasicDomainSubSampler	Aim: Functor that subsamples an initial domain by given a grid size and a shift vector. By this way, for a given point considered in a new domain, it allows to recover the point coordinates in the source domain. Such functor can be usefull to apply basic image subsampling in any dimensions by using ImageAdapter class
CFlipDomainAxis	Aim: Functor that flips the domain coordinate system from some selected axis. For instance, if a flip on the y axis is applied on a domain of bounds (0, 0, 0) (MaxX, MaxY, MaxZ), then the coordinate of P(x,y,z) will transformed in P(x, MaxY-y, z)
CVectorRounding
CConstantPointPredicate	Aim: The predicate that returns always the same value boolCst
CTruePointPredicate	Aim: The predicate that returns always true
CFalsePointPredicate	Aim: The predicate that returns always false
CIsLowerPointPredicate	Aim: The predicate returns true when the point is below (or equal) the given upper bound
CIsUpperPointPredicate	Aim: The predicate returns true when the point is above (or equal) the given lower bound
CIsWithinPointPredicate	Aim: The predicate returns true when the point is within the given bounds
CNotPointPredicate	Aim: The predicate returns true when the point predicate given at construction return false. Thus inverse a predicate: NOT operator
CEqualPointPredicate	Aim: The predicate returns true when the point given as argument equals the reference point given at construction
CBinaryPointPredicate	Aim: The predicate returns true when the given binary functor returns true for the two PointPredicates given at construction
CBinaryPointPredicate< TPointPredicate1, TPointPredicate2, AndBoolFct2 >
CBinaryPointPredicate< TPointPredicate1, TPointPredicate2, OrBoolFct2 >
CPointFunctorPredicate	Aim: The predicate returns true when the predicate returns true for the value assigned to a given point in the point functor
CDomainPredicate	Aim: The predicate returning true iff the point is in the domain given at construction. It is just a wrapper class around the methods Domain::isInside( const Point & ), where Domain stands for any model of CDomain
CHatPointFunction
CBallConstantPointFunction
CPointFunctorHolder	Aim: hold any object callable on points as a DGtal::concepts::CPointFunctor model
CHatFunction
CBallConstantFunction
CPoint2ShapePredicate
CPoint2ShapePredicateComparator	Aim: A small struct with an operator that compares two values according to two bool template parameters
CPoint2ShapePredicateComparator< T, false, false >	Aim: A small struct with an operator that compares two values (<)
CPoint2ShapePredicateComparator< T, false, true >	Aim: A small struct with an operator that compares two values (<=)
CPoint2ShapePredicateComparator< T, true, false >	Aim: A small struct with an operator that compares two values (>)
CPoint2ShapePredicateComparator< T, true, true >	Aim: A small struct with an operator that compares two values (>=)
CBoundaryPredicate	Aim: The predicate on surfels that represents the frontier between a region and its complementary in an image. It can be used with ExplicitDigitalSurface or LightExplicitDigitalSurface so as to define a digital surface. Such surfaces may of course be open
CFrontierPredicate	Aim: The predicate on surfels that represents the frontier between two regions in an image. It can be used with ExplicitDigitalSurface or LightExplicitDigitalSurface so as to define a digital surface. Such surfaces may of course be open
CSCellToPoint	Aim: transforms a scell into a point
CSCellToArrow	Aim: transforms a signed cell into an arrow, ie. a pair point-vector
CSCellToInnerPoint	Aim: transforms a signed cell c into a point corresponding to the signed cell of greater dimension that is indirectly incident to c
CSCellToOuterPoint	Aim: transforms a signed cell c into a point corresponding to the signed cell of greater dimension that is directly incident to c
CSCellToIncidentPoints	Aim: transforms a signed cell c into a pair of points corresponding to the signed cells of greater dimension that are indirectly and directly incident to c
CSCellToCode	Aim: transforms a 2d signed cell, basically a linel, into a code (0,1,2 or 3),
CSurfelSetPredicate	Aim: The predicate returning true iff the point is in the domain given at construction
NZ2i	Z2i this namespace gathers the standard of types for 2D imagery
NZ3i	Z3i this namespace gathers the standard of types for 3D imagery
CClosedIntegerHalfPlane	Aim: A half-space specified by a vector N and a constant c. The half-space is the set \( \{ P \in Z^2, N.P \le c \} \)
CIntegerComputer	Aim: This class gathers several types and methods to make computation with integers
CLatticePolytope2D	Aim: Represents a 2D polytope, i.e. a convex polygon, in the two-dimensional digital plane. The list of points must follow the clockwise ordering
►CLighterSternBrocot	Aim: The Stern-Brocot tree is the tree of irreducible fractions. This class allows to construct it progressively and to navigate within fractions in O(1) time for most operations. It is well known that the structure of this tree is a coding of the continued fraction representation of fractions
CFraction	This fraction is a model of CPositiveIrreducibleFraction
CNode
►CLightSternBrocot	Aim: The Stern-Brocot tree is the tree of irreducible fractions. This class allows to construct it progressively and to navigate within fractions in O(1) time for most operations. It is well known that the structure of this tree is a coding of the continued fraction representation of fractions
CFraction	This fraction is a model of CPositiveIrreducibleFraction
CNode
CModuloComputer	Implements basic functions on modular arithmetic
CPattern	Aim: This class represents a pattern, i.e. the path between two consecutive upper leaning points on a digital straight line
►CStandardDSLQ0	Aim: Represents a digital straight line with slope in the first quadrant (Q0: x >= 0, y >= 0 )
CConstIterator
►CSternBrocot	Aim: The Stern-Brocot tree is the tree of irreducible fractions. This class allows to construct it progressively and to navigate within fractions in O(1) time for most operations. It is well known that the structure of this tree is a coding of the continued fraction representation of fractions
CFraction	This fraction is a model of CPositiveIrreducibleFraction
CNode
CAlias	Aim: This class encapsulates its parameter class so that to indicate to the user that the object/pointer will be only aliased. Therefore the user is reminded that the argument parameter is given to the function without any additional cost and may be modified, while he is aware that the lifetime of the argument parameter must be at least as long as the object itself. Note that an instance of Alias<T> is itself a light object (it holds only an enum and a pointer)
CBackInsertionSequenceToStackAdapter	Aim: This class implements a dynamic adapter to an instance of a model of back insertion sequence in order to get a stack interface. This class is a model of CStack
CCSinglePassIteratorArchetype	An archetype of SingePassIterator
CCBidirectionalIteratorArchetype	An archetype of BidirectionalIterator
CCConstBidirectionalIteratorArchetype	An archetype of ConstBidirectionalIterator
CCForwardIteratorArchetype	An archetype of ForwardIterator
CBits
CCirculator	Aim: Provides an adapter for classical iterators that can iterate through the underlying data structure as in a loop. The increment (resp. decrement) operator encapsulates the validity test and the assignement to the begin (resp. end) iterator of a given range, when the end (resp. beginning) has been reached. For instance, the pre-increment operator does:
CClock
►CClone	Aim: This class encapsulates its parameter class to indicate that the given parameter is required to be duplicated (generally, this is done to have a longer lifetime than the function itself). On one hand, the user is reminded of the possible cost of duplicating the argument parameter, while he is also aware that the lifetime of the parameter is not a problem for the function. On the other hand, the Clone class is smart enough to enforce duplication only if needed. Substantial speed-up can be achieve through this mechanism
CTempPtr	Internal class that is used for a late deletion of an acquired pointer
►CDisplay3D	Aim: This semi abstract class defines the stream mechanism to display 3d primitive (like BallVector, DigitalSetBySTLSet, Object ...). The class Viewer3D and Board3DTo2D implement two different ways to display 3D objects. The first one (Viewer3D), permits an interactive visualisation (based on OpenGL ) and the second one (Board3dto2d) provides 3D visualisation from 2D vectorial display (based on the CAIRO library)
CBallD3D
CClippingPlaneD3D
CCommonD3D
CCubeD3D
CLineD3D
CPolygonD3D
CQuadD3D
CSelectCallbackFctStore
CTriangleD3D
CBoard3DTo2D	Class for PDF, PNG, PS, EPS, SVG export drawings with Cairo with 3D->2D projection
CDrawableWithBoard3DTo2D
CDrawableWithDisplay3D
CDrawableWithBoard2D
CTagFalse
CTagTrue
CTagUnknown
CNegate
CNegate< TagTrue >
CNegate< TagFalse >
CDummyObject
CConstAlias	Aim: This class encapsulates its parameter class so that to indicate to the user that the object/pointer will be only const aliased (and hence left unchanged). Therefore the user is reminded that the argument parameter is given to the function without any additional cost and may not be modified, while he is aware that the lifetime of the argument parameter must be at least as long as the object itself. Note that an instance of ConstAlias<T> is itself a light object (it holds only an enum and a pointer)
CConstIteratorAdapter	This class adapts any iterator so that operator* returns another element than the one pointed to by the iterator
CConstRangeAdapter	Aim: model of CConstBidirectionalRange that adapts any range of elements bounded by two iterators [itb, ite) and provides services to (circularly)iterate over it (in a read-only manner)
CConstRangeFromPointAdapter	Aim: model of CConstBidirectionalRangeFromPoint that adapts any bidirectional range and provides services to iterate over it (in a read-only manner)
CNotContainerCategory
CContainerCategory
CSequenceCategory
CAssociativeCategory
CSimpleAssociativeCategory
CPairAssociativeCategory
CUniqueAssociativeCategory
CMultipleAssociativeCategory
COrderedAssociativeCategory
CUnorderedAssociativeCategory
CSetAssociativeCategory
CMultisetAssociativeCategory
CMapAssociativeCategory
CMultimapAssociativeCategory
CUnorderedSetAssociativeCategory
CUnorderedMultisetAssociativeCategory
CUnorderedMapAssociativeCategory
CUnorderedMultimapAssociativeCategory
CContainerTraits	Defines default container traits for arbitrary types
CContainerTraits< std::vector< T, Alloc > >	Defines container traits for std::vector<>
CContainerTraits< std::list< T, Alloc > >	Defines container traits for std::list<>
CContainerTraits< std::deque< T, Alloc > >	Defines container traits for std::deque<>
CContainerTraits< std::forward_list< T, Alloc > >	Defines container traits for std::forward_list<>
CContainerTraits< std::array< T, N > >	Defines container traits for std::array<>
CContainerTraits< std::set< T, Compare, Alloc > >	Defines container traits for std::set<>
CContainerTraits< std::map< Key, T, Compare, Alloc > >	Defines container traits for std::map<>
CContainerTraits< std::multiset< T, Compare, Alloc > >	Defines container traits for std::multiset<>
CContainerTraits< std::multimap< Key, T, Compare, Alloc > >	Defines container traits for std::multimap<>
CContainerTraits< boost::unordered_set< Value, Hash, Pred, Alloc > >	Defines container traits for boost::unordered_set<>
CContainerTraits< boost::unordered_multiset< Value, Hash, Pred, Alloc > >	Defines container traits for boost::unordered_multiset<>
CContainerTraits< boost::unordered_map< Value, T, Hash, Pred, Alloc > >	Defines container traits for boost::unordered_map<>
CContainerTraits< boost::unordered_multimap< Value, T, Hash, Pred, Alloc > >	Defines container traits for boost::unordered_multimap<>
CContainerTraits< std::unordered_set< Key, Hash, Pred, Alloc > >	Defines container traits for std::unordered_set<>
CContainerTraits< std::unordered_multiset< Key, Hash, Pred, Alloc > >	Defines container traits for std::unordered_multiset<>
CContainerTraits< std::unordered_map< Key, T, Hash, Pred, Alloc > >	Defines container traits for std::unordered_map<>
CContainerTraits< std::unordered_multimap< Key, T, Hash, Pred, Alloc > >	Defines container traits for std::unordered_multimap<>
CIsContainer
CIsSequenceContainer
CIsAssociativeContainer
CIsOrderedAssociativeContainer
CIsUnorderedAssociativeContainer
CIsSimpleAssociativeContainer
CIsPairAssociativeContainer
CIsUniqueAssociativeContainer
CIsMultipleAssociativeContainer
CCountedConstPtrOrConstPtr	Aim: Smart or simple const pointer on T. It can be a smart pointer based on reference counts or a simple pointer on T depending either on a boolean value given at construction or on the constructor used. In the first case, we will call this pointer object smart, otherwise we will call it simple
CCountedPtrOrPtr	Aim: Smart or simple pointer on T. It can be a smart pointer based on reference counts or a simple pointer on T depending either on a boolean value given at construction or on the constructor used. In the first case, we will call this pointer object smart, otherwise we will call it simple
►CCountedPtr	Aim: Smart pointer based on reference counts
CCounter
CCowPtr	Aim: Copy on write shared pointer
CIOException
CInputException
CConnectivityException
CMemoryException
CInfiniteNumberException
CPOW
CPOW< X, 1 >
CPOW< X, 0 >
CLOG2
CLOG2< 2 >
CLOG2< 1 >
CFrontInsertionSequenceToStackAdapter	Aim: This class implements a dynamic adapter to an instance of a model of front insertion sequence in order to get a stack interface. This class is a model of CStack
►CIndexedListWithBlocks	Aim: Represents a mixed list/array structure which is useful in some context. It is essentially a list of blocks
CAnyBlock
CBlockPointer	Forward declaration
CConstIterator
CFirstBlock
CIterator
CValueOrBlockPointer	Used in blocks to finish it or to point to the next block
CInputIteratorWithRankOnSequence	Aim: Useful to create an iterator that returns a pair (value,rank) when visiting a sequence. The sequence is smartly copied within the iterator. Hence, the given sequence need not to persist during the visit. Since it is only an input sequence, it is not necessary to give a valid sequence when creating the end() iterator
CIntegerSequenceIterator	Aim: It is a simple class that mimics a (non mutable) iterator over integers. You can increment it, decrement it, displace it, compare it, etc. It is useful if you have a collection of consecutive integers, and you wish to create an iterator over it. It is used in the class TriangulatedSurface for example, since vertices are numbers from 0 to nbVertices - 1
CIteratorAdapter	This class adapts any lvalue iterator so that operator* returns a member on the element pointed to by the iterator, instead the element itself
CIteratorType
CCirculatorType
CForwardCategory
CBidirectionalCategory
CRandomAccessCategory
CIsCirculator	Aim: Checks whether type IC is a circular or a classical iterator. Static value set to 'true' for a circulator, 'false' otherwise.
CIteratorCirculatorType	Aim: Provides the type of IC as a nested type: either IteratorType or CirculatorType
CToDGtalCategory	Aim: Provides the DGtal category matching C {ForwardCategory,BidirectionalCategory,RandomAccessCategory}
CToDGtalCategory< std::forward_iterator_tag >
CToDGtalCategory< std::bidirectional_iterator_tag >
CToDGtalCategory< std::random_access_iterator_tag >
CToDGtalCategory< boost::forward_traversal_tag >
CToDGtalCategory< boost::bidirectional_traversal_tag >
CToDGtalCategory< boost::random_access_traversal_tag >
CToDGtalCategory< boost::iterators::detail::iterator_category_with_traversal< std::input_iterator_tag, boost::forward_traversal_tag > >
CToDGtalCategory< boost::iterators::detail::iterator_category_with_traversal< std::input_iterator_tag, boost::bidirectional_traversal_tag > >
CToDGtalCategory< boost::iterators::detail::iterator_category_with_traversal< std::input_iterator_tag, boost::random_access_traversal_tag > >
CIteratorCirculatorTraits	Aim: Provides nested types for both iterators and circulators: Type, Category, Value, Difference, Pointer and Reference
CIteratorCirculatorTraits< T * >
CIteratorCirculatorTraits< T const * >
CIteratorCompletionTraits	Aim: Traits that must be specialized for each IteratorCompletion derived class
CIteratorCompletion	Aim: Class that uses CRTP to add reverse iterators and ranges to a derived class
►CLabelledMap	Aim: Represents a map label -> data, where the label is an integer between 0 and a constant L-1. It is based on a binary coding of labels and a mixed list/array structure. The assumption is that the number of used labels is much less than L. The objective is to minimize the memory usage
C__AnyBlock
C__FirstBlock
CBlockConstIterator
CBlockIterator
CBlockPointer	Forward declaration
CConstIterator
CDataOrBlockPointer	Used in first block to finish it or to point to the next block
CKeyCompare	Key comparator class. Always natural ordering
CValueCompare	Value comparator class. Always natural ordering between keys
►CLabels	Aim: Stores a set of labels in {O..L-1} as a sequence of bits
CConstEnumerator
COneItemOutputIterator	Aim: model of output iterator, ie incrementable and writable iterator, which only stores in a variable the last assigned item
COpInSTLContainers
COpInSTLContainers< Container, std::reverse_iterator< typename Container::iterator > >
COrderedAlphabet	Aim: Describes an alphabet over an interval of (ascii) letters, where the lexicographic order can be changed (shifted, reversed, ...). Useful for the arithmetic minimum length polygon (AMLP)
COutputIteratorAdapter	Aim: Adapts an output iterator i with a unary functor f, both given at construction, so that the element pointed to by i is updated with a given value through f
COwningOrAliasingPtr	Aim: This class describes a smart pointer that is, given the constructor called by the user, either an alias pointer on existing data or an owning pointer on a copy
CReverseIterator	This class adapts any bidirectional iterator so that operator++ calls operator-- and vice versa
CSimpleConstRange	Aim: model of CConstRange that adapts any range of elements bounded by two iterators [itb, ite) and provides services to (circularly)iterate over it (in a read-only manner)
CSimpleRandomAccessConstRangeFromPoint	Aim: model of CConstBidirectionalRangeFromPoint that adapts any range of elements bounded by two iterators [itb, ite) and provides services to (circularly)iterate over it (in a read-only manner)
CSimpleRandomAccessRangeFromPoint	Aim: model of CBidirectionalRangeFromPoint that adapts any range of elements bounded by two iterators [itb, ite) and provides services to (circularly)iterate over it (in a read-only manner)
►CStdMapRebinder
CRebinder
CTiledImageBidirectionalConstRangeFromPoint	Aim: model of CConstBidirectionalRangeFromPoint that adapts a TiledImage range of elements bounded by two iterators [itb, ite) and provides services to (circularly)iterate over it (in a read-only manner)
CTiledImageBidirectionalRangeFromPoint	Aim: model of CBidirectionalRangeFromPoint that adapts a TiledImage range of elements bounded by two iterators [itb, ite) and provides services to (circularly)iterate over it
CTimeStampMemoizer	Aim: A generic class to store a given maximum number of pairs (key, value). The class tends to memorize pairs which are accessed more frequently than others. It is thus a memoizer, which is used to memorize the result of costly computations. The memoization principle is simple: a timestamp is attached to a pair (key,value). Each time a query is made, if the item was memoized, the result is returned while the timestamp of the item is updated. User can also add or update a value in the memoizer, which updates also its timestamp. After adding a pair (key,value), if the maximal number of items is reached, at least the oldest half (or a fraction) of the items are deleted, leaving space for storing new pairs (key,value)
CTrace	Implementation of basic methods to trace out messages with indentation levels
CTraceWriter	Virtual Class to implement trace writers
CTraceWriterFile
CTraceWriterTerm	Implements trace prefix for color terminals
CATSolver2D	Aim: This class solves Ambrosio-Tortorelli functional on a two-dimensional digital space (a 2D grid or 2D digital surface) for a piecewise smooth scalar/vector function u represented as one/several 2-form(s) and a discontinuity function v represented as a 0-form. The 2-form(s) u is a regularized approximation of an input vector data g, while v represents the set of discontinuities of u. The norm chosen for u is the \( l_2 \)-norm
CDiscreteExteriorCalculusFactory	Aim: This class provides static members to create DEC structures from various other DGtal structures
►CDiscreteExteriorCalculus	Aim: DiscreteExteriorCalculus represents a calculus in the dec package. This is the main structure in the dec package. This is used to describe the space on which the dec is build and to compute various operators. Once operators or kforms are created, this structure should not be modified
CProperty	Holds size 'primal_size', 'dual_size', 'index' and 'flipped' for each cell of the DEC object. To avoid inserting both positive and negative cells in a DEC object, only non signed cells are stored internally
CDiscreteExteriorCalculusSolver	Aim: This wraps a linear algebra solver around a discrete exterior calculus
COppositeDuality
COppositeDuality< PRIMAL >
COppositeDuality< DUAL >
CGeodesicsInHeat	This class implements [41] on polygonal surfaces (using Discrete differential calculus on polygonal surfaces)
CKForm	Aim: KForm represents discrete kforms in the dec package
CLinearOperator	Aim: LinearOperator represents discrete linear operator between discrete kforms in the DEC package
CPolygonalCalculus	Implements differential operators on polygonal surfaces from [45]
CVectorField	Aim: VectorField represents a discrete vector field in the dec package. Vector field values are attached to 0-cells with the same duality as the vector field
CVectorsInHeat	This class implements [114] on polygonal surfaces (using Discrete differential calculus on polygonal surfaces)
►CAlphaThickSegmentComputer	Aim: This class is devoted to the recognition of alpha thick segments as described in [51] . From a maximal diagonal alphaMax thickness, it recognizes thick segments and may thus take into account some noise in the input contour. Moreover points of the segment may not be (digitally) connected and may have floating point coordinates. Connection is only given by the order of the points
CState
CArithDSSIterator	Aim: An iterator on the points of a Digital Straight Segment. Template parameters are the integer type and the connectivity of the DSS (8-connectivity as default value)
CArithmeticalDSS	Aim: This class represents a naive (resp. standard) digital straight segment (DSS), ie. the sequence of simply 8- (resp. 4-)connected digital points contained in a naive (resp. standard) digital straight line (DSL) between two points of it
►CArithmeticalDSL	Aim: This class represents a naive (resp. standard) digital straight line (DSL), ie. the set of digital points \( (x,y) \in \mathbb{Z}^2 \) such that \( \mu \leq ax - by < \mu + \omega \) with \( a,b,\mu,\omega \in \mathbb{Z} \), \( \gcd(a,b) = 1 \) and \( \omega = \max(|a|,|b|) \) (resp. \( \omega = |a| + |b| \)). Note that any DSL such that \( \omega = \max(|a|,|b|) \) (resp. \( \omega = |a| + |b| \)) is simply 8-connected (resp. 4-connected)
CConstIterator	Aim: This class aims at representing an iterator that provides a way to scan the points of a DSL. It is both a model of readable iterator and of bidirectional iterator
CStandardDSL	Aim: This class is an alias of ArithmeticalDSS for standard DSL. It represents a standard digital straight line (DSL), ie. the set of digital points \( (x,y) \in \mathbb{Z}^2 \) such that \( \mu \leq ax - by < \mu + \omega \) with \( a,b,\mu,\omega \in \mathbb{Z} \), \( \gcd(a,b) = 1 \) and \( \omega = |a| + |b| \). Note that any DSL such that \( \omega = |a| + |b| \) is simply 4-connected
CNaiveDSL	Aim: This class is an alias of ArithmeticalDSS for naive DSL. It represents a naive digital straight line (DSL), ie. the set of digital points \( (x,y) \in \mathbb{Z}^2 \) such that \( \mu \leq ax - by < \mu + \omega \) with \( a,b,\mu,\omega \in \mathbb{Z} \), \( \gcd(a,b) = 1 \) and \( \omega = \max(|a|,|b|) \). Note that any DSL such that \( \omega = \max(|a|,|b|) \) is simply 8-connected
CArithmeticalDSLKernel	Aim: Small class that contains the code that depends on the arithmetical thickness (either naive or standard) of a digital straight line (DSL). It provides mainly two static methods:
CArithmeticalDSLKernel< TCoordinate, 4 >
CStandardDSS4	Aim: This class represents a standard digital straight segment (DSS), ie. the sequence of simply 4-connected digital points contained in a standard digital straight line (DSL) between two points of it. This class is an alias of ArithmeticalDSS
CNaiveDSS8	Aim: This class represents a standard digital straight segment (DSS), ie. the sequence of simply 8-connected digital points contained in a naive digital straight line (DSL) between two points of it. This class is an alias of ArithmeticalDSS
CArithmeticalDSSComputer	Aim: This class is a wrapper around ArithmeticalDSS that is devoted to the dynamic recognition of digital straight segments (DSS) along any sequence of digital points
CArithmeticalDSSFactory	Aim: Set of static methods that create digital straight segments (DSS) from some input parameters, eg. patterns (or reversed patterns) from two upper leaning points (or lower leaning points)
CBinomialConvolver	Aim: This class represents a 2D contour convolved by some binomial. It computes first and second order derivatives so as to be able to estimate tangent and curvature. In particular, it smoothes digital contours but could be used for other kind of contours
CTangentFromBinomialConvolverFunctor	Aim: This class is a functor for getting the tangent vector of a binomial convolver
CCurvatureFromBinomialConvolverFunctor	Aim: This class is a functor for getting the curvature of a binomial convolver
CBinomialConvolverEstimator	Aim: This class encapsulates a BinomialConvolver and a functor on BinomialConvolver so as to be a model of CCurveLocalGeometricEstimator
►CDSLSubsegment	Aim: Given a Digital Straight line and two endpoints A and B on this line, compute the minimal characteristics of the digital subsegment [AB] in logarithmic time. Two algorithms are implemented: one is based on the local computation of lower and upper convex hulls, the other is based on a dual transformation and uses the Farey fan. Implementation requires that the DSL lies in the first octant (0 <= a <= b)
CRayC
CBLUELocalLengthEstimator	Aim: Best Linear Unbiased Two step length estimator
CCompareLocalEstimators	Aim: Functor to compare two local geometric estimators
CDSSLengthEstimator	Aim: a model of CGlobalCurveEstimator that segments the digital curve into DSS and computes the length of the resulting (not uniquely defined) polygon
CFPLengthEstimator	Aim: a model of CGlobalCurveEstimator that computes the length of a digital curve using its FP (faithful polygon)
►CTangentFromDSS2DFunctor
CValue
►CTangentFromDSS3DFunctor
CValue
CDSSMuteFilter
CDSSLengthLessEqualFilter
CL1LengthEstimator	Aim: a simple model of CGlobalCurveEstimator that compute the length of a curve using the l_1 metric (just add 1/h for every step)
CLambdaMST2DEstimator
CLambdaMST2D	Aim: Simplify creation of Lambda MST tangent estimator
CLambdaMST3DEstimator
CLambdaMST3D	Aim: Simplify creation of Lambda MST tangent estimator
CLambdaMST3DBy2DEstimator
CTangentFromDSS3DBy2DFunctor
CLambdaMST3DBy2D	Aim: Simplify creation of Lambda MST tangent estimator
CMLPLengthEstimator	Aim: a model of CGlobalCurveEstimator that computes the length of a digital curve using its MLP (given by the FP)
CMostCenteredMaximalSegmentEstimator	Aim: A model of CLocalCurveGeometricEstimator that assigns to each element of a (sub)range a quantity estimated from the most centered maximal segment passing through this element
CParametricShapeArcLengthFunctor	Aim: implements a functor that estimates the arc length of a paramtric curve
CParametricShapeCurvatureFunctor	Aim: implements a functor that computes the curvature at a given point of a parametric shape
CParametricShapeTangentFunctor	Aim: implements a functor that computes the tangent vector at a given point of a parametric shape
CRosenProffittLocalLengthEstimator	Aim: Rosen-Proffitt Length Estimator
CTangentFromDSSEstimator
CTangentVectorFromDSSEstimator
CTangentAngleFromDSSEstimator
CCurvatureFromDCAEstimator
CNormalFromDCAEstimator
CTangentFromDCAEstimator
CDistanceFromDCAEstimator
CCurvatureFromDSSLengthEstimator
CCurvatureFromDSSEstimator
CTrueGlobalEstimatorOnPoints	Aim: Computes the true quantity associated to a parametric shape or to a subrange associated to a parametric shape
CTrueLocalEstimatorOnPoints	Aim: Computes the true quantity to each element of a range associated to a parametric shape
CTwoStepLocalLengthEstimator	Aim: a simple model of CGlobalCurveEstimator that compute the length of a curve using the l_1 metric (just add 1/h for every step)
CFP	Aim: Computes the faithful polygon (FP) of a range of 4/8-connected 2D Points
►CFrechetShortcut	Aim: On-line computation Computation of the longest shortcut according to the Fréchet distance for a given error. See related article: Sivignon, I., (2011). A Near-Linear Time Guaranteed Algorithm for Digital Curve Simplification under the Fréchet Distance. DGCI 2011. Retrieved from http://link.springer.com/chapter/10.1007/978-3-642-19867-0_28
►CBackpath
Cocculter_attributes
CCone
CTools
►CFreemanChain
CCodesRange	Aim: model of CRange that provides services to (circularly)iterate over the letters of the freeman chain
CConstIterator
►CGreedySegmentation	Aim: Computes the greedy segmentation of a range given by a pair of ConstIterators. The last element of a given segment is the first one one of the next segment
CSegmentComputerIterator	Aim: Specific iterator to visit all the segments of a greedy segmentation
CGridCurve	Aim: describes, in a cellular space of dimension n, a closed or open sequence of signed d-cells (or d-scells), d being either equal to 1 or (n-1)
CNaive3DDSSComputer	Aim: Dynamic recognition of a 3d-digital straight segment (DSS)
►COneBalancedWordComputer	Aim:
CCodeHandler
CCodeHandler< TIterator, BidirectionalCategory >
CCodeHandler< TIterator, RandomAccessCategory >
CConstPointIterator
CDecoratorParametricCurveTransformation	Aim: Implements a decorator for applying transformations to parametric curves
CEllipticHelix	Aim: Implement a parametric curve – elliptic helix
CKnot_3_1	Aim: Implement a parametrized knot 3, 1
CKnot_3_2	Aim: Implement a parametrized knot 3, 2
CKnot_4_1	Aim: Implement a parametrized knot 4, 1
CKnot_4_3	Aim: Implement a parametrized knot 4, 3
CKnot_5_1	Aim: Implement a parametrized knot 5, 1
CKnot_5_2	Aim: Implement a parametrized knot 5, 2
CKnot_6_2	Aim: Implement a parametrized knot 6, 2
CKnot_7_4	Aim: Implement a parametrized knot 7, 4
►CNaiveParametricCurveDigitizer3D	Aim: Digitization of 3D parametric curves. This method produces, for good parameters step and k_next, a 26-connected digital curves obtained from a digitization process of 3D parametric curves
CKConstIter	A structure used for making iterations over digital curve with respect to K_NEXT
CKIter	A structure used for making iterations over digital curve with respect to K_NEXT
►CSaturatedSegmentation	Aim: Computes the saturated segmentation, that is the whole set of maximal segments within a range given by a pair of ConstIterators (maximal segments are segments that cannot be included in greater segments)
CSegmentComputerIterator	Aim: Specific iterator to visit all the maximal segments of a saturated segmentation
CForwardSegmentComputer
CBidirectionalSegmentComputer
CDynamicSegmentComputer
CDynamicBidirectionalSegmentComputer
CSegmentComputerTraits	Aim: Provides the category of the segment computer {ForwardSegmentComputer,BidirectionalSegmentComputer, DynamicSegmentComputer, DynamicBidirectionalSegmentComputer}
CStabbingCircleComputer	Aim: On-line recognition of a digital circular arcs (DCA) defined as a sequence of connected grid edges such that there is at least one (Euclidean) circle that separates the centers of the two incident pixels of each grid edge
CStabbingLineComputer	Aim: On-line recognition of a digital straight segment (DSS) defined as a sequence of connected grid edges such that there is at least one straight line that separates the centers of the two incident pixels of each grid edge
CStandardDSS6Computer	Aim: Dynamic recognition of a 3d-digital straight segment (DSS)
CContourHelper	Aim: a helper class to process sequences of points
CCorrectedNormalCurrentComputer	Aim: Utility class to compute curvature measures induced by (1) a corrected normal current defined by a surface mesh with prescribed normals and (2) the standard Lipschitz-Killing invariant forms of area and curvatures
CCorrectedNormalCurrentFormula	Aim: A helper class that provides static methods to compute corrected normal current formulas of curvatures
CNormalCycleComputer	Aim: Utility class to compute curvatures measures induced by (1) the normal cycle induced by a SurfaceMesh, (2) the standard Lipschitz-Killing invariant forms of area and curvatures
CNormalCycleFormula	Aim: A helper class that provides static methods to compute normal cycle formulas of curvatures
CSurfaceMeshMeasure	Aim: stores an arbitrary measure on a SurfaceMesh object. The measure can be spread onto its vertices, edges, or faces. This class is notably used by CorrectedNormalCurrentComputer and NormalCycleComputer to store the curvature measures, which may be located on different cells. The measure can be scalar or any other summable type (see template parameter TValue)
►CArithmeticalDSSComputerOnSurfels	Aim: This class is a wrapper around ArithmeticalDSS that is devoted to the dynamic recognition of digital straight segments (DSS) along a sequence of surfels lying on a slice of the digital surface (i.e., the orthogonal direction of all surfels belong to a same plane, most pairs of consecutive surfels share a common linel)
CDirectPairExtractor
CIndirectPairExtractor
CChordGenericNaivePlaneComputer	Aim: A class that recognizes pieces of digital planes of given axis width. When the width is 1, it corresponds to naive planes. Contrary to ChordNaivePlaneComputer, the axis is not specified at initialization of the object. This class uses three instances of ChordNaivePlaneComputer, one per axis
►CChordGenericStandardPlaneComputer	Aim: A class that recognizes pieces of digital planes of given diagonal width. When the width is \(1 \times \sqrt{3}\), it corresponds to standard planes. Contrary to ChordStandardPlaneComputer, the axis is not specified at initialization of the object. This class uses four instances of ChordStandardPlaneComputer of axis z, by transforming points \((x,y,z)\) to \((x \pm z, y \pm z, z)\)
CTransform
►CChordNaivePlaneComputer	Aim: A class that contains the chord-based algorithm for recognizing pieces of digital planes of given axis width [ Gerard, Debled-Rennesson, Zimmermann, 2005 ]. When the width is 1, it corresponds to naive planes. The axis is specified at initialization of the object
CState
CCOBAGenericNaivePlaneComputer	Aim: A class that recognizes pieces of digital planes of given axis width. When the width is 1, it corresponds to naive planes. Contrary to COBANaivePlaneComputer, the axis is not specified at initialization of the object. This class uses three instances of COBANaivePlaneComputer, one per axis
►CCOBAGenericStandardPlaneComputer	Aim: A class that recognizes pieces of digital planes of given axis width. When the diagonal width is \( 1 \times \sqrt{3} \), it corresponds to standard planes. Contrary to COBANaivePlaneComputer, the axis is not specified at initialization of the object. This class uses four instances of COBANaivePlaneComputer of axis z, by transforming points \((x,y,z)\) to \((x \pm z, y \pm z, z)\)
CTransform
►CCOBANaivePlaneComputer	Aim: A class that contains the COBA algorithm (Emilie Charrier, Lilian Buzer, DGCI2008) for recognizing pieces of digital planes of given axis width. When the width is 1, it corresponds to naive planes. The axis is specified at initialization of the object
CState
CDigitalPlanePredicate	Aim: Representing digital planes, which are digitizations of Euclidean planes, as point predicates
CDigitalSurfaceConvolver
CDigitalSurfaceConvolver< TFunctor, TKernelFunctor, TKSpace, TDigitalKernel, 2 >
CDigitalSurfaceConvolver< TFunctor, TKernelFunctor, TKSpace, TDigitalKernel, 3 >
CDigitalSurfacePredicate	Aim: A point predicate which tells whether a point belongs to the set of pointels of a given digital surface or not
CDigitalSurfaceRegularization	Aim: Implements Digital Surface Regularization as described in [31]
CDigitalSurfaceEmbedderWithNormalVectorEstimatorGradientMap
CDigitalSurfaceEmbedderWithNormalVectorEstimator	Aim: Combines a digital surface embedder with a normal vector estimator to get a model of CDigitalSurfaceEmbedder and CWithGradientMap. (also default constructible, copy constructible, assignable)
CEstimatorCache	Aim: this class adapts any local surface estimator to cache the estimated values in a associative container (Surfel <-> estimated value)
CIntegralInvariantCovarianceEstimator	Aim: This class implement an Integral Invariant estimator which computes for each surfel the covariance matrix of the intersection of the shape with a ball of given radius centered on the surfel
CIntegralInvariantVolumeEstimator	Aim: This class implement an Integral Invariant estimator which computes for each surfel the volume of the intersection of the shape with a ball of given radius centered on the surfel
CLocalEstimatorFromSurfelFunctorAdapter	Aim: this class adapts any local functor on digital surface element to define a local estimator. This class is model of CDigitalSurfaceLocalEstimator
CMaximalSegmentSliceEstimation	Aim:
CNormalVectorEstimatorLinearCellEmbedder	Aim: model of cellular embedder for normal vector estimators on digital surface, (default constructible, copy constructible, assignable)
►CPlaneProbingDigitalSurfaceLocalEstimator	Aim: Adapt a plane-probing estimator on a digital surface to estimate normal vectors
CProbingFrame
CPlaneProbingHNeighborhood	Aim: Represent a way to probe the H-neighborhood
►CPlaneProbingLNeighborhood	Aim: Represents a way to probe the L-neighborhood, see [87] for details
CClosestGridPoint	Aim: Used to store the closest grid point associated to a vertex of the triangle and two extra boolean values about the local configuration at that vertex
►CPlaneProbingNeighborhood	Aim: A base virtual class that represents a way to probe a neighborhood, used in the plane probing based estimators, see DGtal::PlaneProbingTetrahedronEstimator or DGtal::PlaneProbingParallelepipedEstimator
CUpdateOperation
►CPlaneProbingParallelepipedEstimator	Aim:
CNotAbovePredicate
CPlaneProbingR1Neighborhood	Aim: Represent a way to probe the R-neighborhood, with the R1 optimization, see [106] for details
CPlaneProbingRNeighborhood	Aim: Represent a way to probe the R-neighborhood
CPlaneProbingTetrahedronEstimator	Aim: A class that locally estimates a normal on a digital set using only a predicate "does a point x belong to the digital set or not?"
CTrueDigitalSurfaceLocalEstimator	Aim: An estimator on digital surfaces that returns the reference local geometric quantity. This is used for comparing estimators
CVCMDigitalSurfaceLocalEstimator	Aim: This class adapts a VoronoiCovarianceMeasureOnDigitalSurface to be a model of CDigitalSurfaceLocalEstimator. It uses the Voronoi Covariance Measure to estimate geometric quantities. The type TVCMGeometricFunctor specifies which is the estimated quantity. For instance, VCMGeometricFunctors::VCMNormalVectorFunctor returns the estimated VCM surface outward normal for given surfels
►CVoronoiCovarianceMeasureOnDigitalSurface	Aim: This class specializes the Voronoi covariance measure for digital surfaces. It adds notably the embedding of surface elements, the diagonalisation of the VCM, and the orientation of the first VCM eigenvector toward the interior of the surface
CEigenStructure	Structure to hold a diagonalized matrix
CNormals	Structure to hold the normals for each surfel (the VCM one and the trivial one)
CFunctorOnCells	Aim: Convert a functor on Digital Point to a Functor on Khalimsky Cell
CParallelStrip	Aim: A parallel strip in the space is the intersection of two parallel half-planes such that each half-plane includes the other
CShroudsRegularization	Aim: Implements the Shrouds Regularization algorithm of Nielson et al [95]
CAvnaimEtAl2x2DetSignComputer	Aim: Class that provides a way of computing the sign of the determinant of a 2x2 matrix from its four coefficients, ie
CC2x2DetComputer	Aim: This concept gathers all models that are able to compute the (sign of the) determinant of a 2x2 matrix with integral entries
CFiltered2x2DetComputer	Aim: Class that provides a way of computing the sign of the determinant of a 2x2 matrix from its four coefficients, ie
CInGeneralizedDiskOfGivenRadius	Aim: This class implements an orientation functor that provides a way to determine the position of a given point with respect to the unique circle passing by the same two given points and whose radius and orientation is given
CInHalfPlaneBy2x2DetComputer	Aim: Class that implements an orientation functor, ie. it provides a way to compute the orientation of three given 2d points. More precisely, it returns:
CInHalfPlaneBySimple3x3Matrix	Aim: Class that implements an orientation functor, ie. it provides a way to compute the orientation of three given 2d points. More precisely, it returns:
CPredicateFromOrientationFunctor2	Aim: Small adapter to models of COrientationFunctor2. It is a model of concepts::CPointPredicate. It is also a ternary predicate on points, useful for basic geometric tasks such as convex hull computation
CSimple2x2DetComputer	Aim: Small class useful to compute the determinant of a 2x2 matrix from its four coefficients, ie. \( \begin{vmatrix} a & x \\ b & y \end{vmatrix} \)
CSimpleIncremental2x2DetComputer	Aim: Small class useful to compute, in an incremental way, the determinant of a 2x2 matrix from its four coefficients, ie. \( \begin{vmatrix} a & x \\ b & y \end{vmatrix} \)
CMelkmanConvexHull	Aim: This class implements the on-line algorithm of Melkman for the computation of the convex hull of a simple polygonal line (without self-intersection) [Melkman, 1987: [90]]
CPreimage2D	Aim: Computes the preimage of the 2D Euclidean shapes crossing a sequence of n straigth segments in O(n), with the algorithm of O'Rourke (1981)
►CQuickHull	Aim: Implements the quickhull algorithm by Barber et al. [9], a famous arbitrary dimensional convex hull computation algorithm. It relies on dedicated geometric kernels for computing and comparing facet geometries
CFacet
►CConvexHullCommonKernel	Aim: the common part of all geometric kernels for computing the convex hull or Delaunay triangulation of a range of points
CHalfSpace
CConvexHullIntegralKernel	Aim: a geometric kernel to compute the convex hull of digital points with integer-only arithmetic
CDelaunayIntegralKernel	Aim: a geometric kernel to compute the Delaunay triangulation of digital points with integer-only arithmetic. It casts lattice point into a higher dimensional space and computes its convex hull. Facets pointing toward the bottom form the simplices of the Delaunay triangulation
CConvexHullRationalKernel	Aim: a geometric kernel to compute the convex hull of floating points with integer-only arithmetic. Floating points are approximated with rational points with fixed precision (a given number of bits). All remaining computations are exact, as long as there is no overflow
CDelaunayRationalKernel	Aim: a geometric kernel to compute the Delaunay triangulation of a range of floating points with integer-only arithmetic. Floating points are approximated with rational points with fixed precision (a given number of bits), which are cast in a higher dimensional space and lifted onto the "norm" paraboloid, as classically done when computing a Delaunay triangulation from a convex hull. All remaining computations are exact, as long as there is no overflow
CRayIntersectionPredicate	This class implements various intersection predicates between a ray and a triangle, a quad or a surfel in dimension 3
CSpatialCubicalSubdivision	Aim: This class is a data structure that subdivides a rectangular domains into cubical domains of size \( r^n \) in order to store points into different bins (each cubical domain is a bin, characterized by one coordinate). This data structure may be used for proximity queries, generally to get the points at distance r from a given point
CSphericalAccumulator	Aim: implements an accumulator (as histograms for 1D scalars) adapted to spherical point samples
CSphericalTriangle	Aim: Represent a triangle drawn onto a sphere of radius 1
►CBoundedLatticePolytope	Aim: Represents an nD lattice polytope, i.e. a convex polyhedron bounded with vertices with integer coordinates, as a set of inequalities. Otherwise said, it is a H-representation of a polytope (as an intersection of half-spaces). A limitation is that we model only bounded polytopes, i.e. polytopes that can be included in a finite bounding box
CLeftStrictUnitCell
CLeftStrictUnitSegment
CRightStrictUnitCell
CRightStrictUnitSegment
CUnitCell
CUnitSegment
CBoundedLatticePolytopeCounter	Aim: Useful to compute quickly the lattice points within a polytope, i.e. a convex polyhedron
►CBoundedRationalPolytope	Aim: Represents an nD rational polytope, i.e. a convex polyhedron bounded by vertices with rational coordinates, as a set of inequalities. Otherwise said, it is a H-representation of a polytope (as an intersection of half-spaces). A limitation is that we model only bounded polytopes, i.e. polytopes that can be included in a finite bounding box
CRational
CUnitCell
CUnitSegment
CCellGeometry	Aim: Computes and stores sets of cells and provides methods to compute intersections of lattice and rational polytopes with cells
CCellGeometryFunctions
CCellGeometryFunctions< TKSpace, 1, 2 >
CCellGeometryFunctions< TKSpace, 1, 3 >
CCellGeometryFunctions< TKSpace, 2, 2 >
CCellGeometryFunctions< TKSpace, 2, 3 >
CCellGeometryFunctions< TKSpace, 3, 3 >
CConvexCellComplex	Aim: represents a d-dimensional complex in a d-dimensional space with the following properties and restrictions:
CConvexityHelper	Aim: Provides a set of functions to facilitate the computation of convex hulls and polytopes, as well as shortcuts to build cell complex representing a Delaunay complex
CDigitalConvexity	Aim: A helper class to build polytopes from digital sets and to check digital k-convexity and full convexity
CDigitalMetricAdapter	Aim: simple adapter class which adapts any models of concepts::CMetricSpace to a model of concepts::CDigitalMetricSpace
CDistanceTransformation	Aim: Implementation of the linear in time distance transformation for separable metrics
CExactPredicateLpPowerSeparableMetric	Aim: implements weighted separable l_p metrics with exact predicates
CExactPredicateLpPowerSeparableMetric< TSpace, 2, TPromoted >
CExactPredicateLpSeparableMetric	Aim: implements separable l_p metrics with exact predicates
CExactPredicateLpSeparableMetric< TSpace, 2, TRawValue >
CFMM	Aim: Fast Marching Method (FMM) for nd distance transforms
CL2FirstOrderLocalDistance	Aim: Class for the computation of the Euclidean distance at some point p, from the available distance values of some points lying in the 1-neighborhood of p (ie. points at a L1-distance to p equal to 1)
CL2SecondOrderLocalDistance	Aim: Class for the computation of the Euclidean distance at some point p, from the available distance values of some points lying in the neighborhood of p, such that only one of their coordinate differ from the coordinates of p by at most two
CLInfLocalDistance	Aim: Class for the computation of the LInf-distance at some point p, from the available distance values of some points lying in the 1-neighborhood of p (ie. points at a L1-distance to p equal to 1)
CL1LocalDistance	Aim: Class for the computation of the L1-distance at some point p, from the available distance values of some points lying in the 1-neighborhood of p (ie. points at a L1-distance to p equal to 1)
CL2FirstOrderLocalDistanceFromCells	Aim: Class for the computation of the Euclidean distance at some point p, from the available distance values in the neighborhood of p. Contrary to L2FirstOrderLocalDistance, the distance values are not available from the points adjacent to p but instead from the (d-1)-cells lying between p and these points.
CSpeedExtrapolator	Aim: Class for the computation of the a speed value at some point p, from the available distance values and speed values of some points lying in the 1-neighborhood of p (ie. points at a L1-distance to p equal to 1) in order to extrapolate a speed field in the normal direction to the interface
CInexactPredicateLpSeparableMetric	Aim: implements separable l_p metrics with approximated predicates
CLpMetric	Aim: implements l_p metrics
CPowerMap	Aim: Implementation of the linear in time Power map construction
CReducedMedialAxis	Aim: Implementation of the separable medial axis extraction
CReverseDistanceTransformation	Aim: Implementation of the linear in time reverse distance transformation for separable metrics
CSeparableMetricAdapter	Aim: Adapts any model of CMetric to construct a separable metric (model of CSeparableMetric)
CVoronoiMap	Aim: Implementation of the linear in time Voronoi map construction
CVoronoiMapComplete	Aim: Implementation of the linear in time Voronoi map construction
CEhrhartPolynomial	Aim: This class implements the class Ehrhart Polynomial which is related to lattice point enumeration in bounded lattice polytopes
CMeasure	Aim: Implements a simple measure computation (in the Lesbegue sens) of a set. In dimension 2, it corresponds to the area of the set, to the volume in dimension 3,..
►CVoronoiCovarianceMeasure	Aim: This class precomputes the Voronoi Covariance Measure of a set of points. It can compute the covariance measure of an arbitrary function with given support
CCharacteristicSetPredicate
CKanungoNoise	Aim: From a point predicate (model of concepts::CPointPredicate), this class constructs another point predicate as a noisy version of the input one
CNeighborhoodConvexityAnalyzer	Aim: A class that models a \( (2k+1)^d \) neighborhood and that provides services to analyse the convexity properties of a digital set within this neighborhood
CPConvexity	Aim: A class to check if digital sets are P-convex. The P-convexity is defined as follows: A digital set X subset of \( \mathbb{Z}^d \) is P-convex iff
►CTangencyComputer	Aim: A class that computes tangency to a given digital set. It provides services to compute all the cotangent points to a given point, or to compute shortest paths
►CShortestPaths
CComparator
CBreadthFirstVisitor	Aim: This class is useful to perform a breadth-first exploration of a graph given a starting point or set (called initial core)
CDepthFirstVisitor	Aim: This class is useful to perform a depth-first exploration of a graph given a starting point or set (called initial core)
►CDistanceBreadthFirstVisitor	Aim: This class is useful to perform an exploration of a graph given a starting point or set (called initial core) and a distance criterion
CNode
CExpander	Aim: This class is useful to visit an object by adjacencies, layer by layer
►CGraphVisitorRange	Aim: Transforms a graph visitor into a single pass input range
CGenericConstIterator
CNodeAccessor
CVertexAccessor
CSTLMapToVertexMapAdapter	Aim: This class adapts any map of the STL to match with the CVertexMap concept
CParameterValue
CParameters
►CShortcuts	Aim: This class is used to simplify shape and surface creation. With it, you can create new shapes and surface with few lines of code. The drawback is that you use specific types or objects, which could lead to faster code or more compact data structures
CCellReader
CCellWriter
CSCellReader
CSCellWriter
CValueReader
CValueWriter
CShortcutsGeometry	Aim: This class is used to simplify shape and surface creation. With it, you can create new shapes and surface in a few lines. The drawback is that you use specific types or objects, which could lead to faster code or more compact data structures
CArrayImageAdapter< TArrayIterator, HyperRectDomain< TSpace > >	Aim: Image adapter for generic arrays with sub-domain view capability
►CIteratorCompletionTraits< ArrayImageAdapter< TArrayIterator, TDomain > >	[IteratorCompletionTraits]
CDistanceFunctor
CArrayImageIterator	Aim: Random access iterator over an image given his definition domain and viewable domain
CConstImageAdapter	Aim: implements a const image adapter with a given domain (i.e. a subdomain) and 2 functors : g for domain, f for accessing point values
CDefaultConstImageRange	Aim: model of CConstBidirectionalRangeFromPoint that adapts the domain of an image in order to iterate over the values associated to its domain points (in a read-only as well as a write-only manner).
CDefaultImageRange	Aim: model of CConstBidirectionalRangeFromPoint and CBidirectionalRangeWithWritableIteratorFromPoint that adapts the domain of an image in order to iterate over the values associated to its domain points (in a read-only as well as a write-only manner).
CImage	Aim: implements association bewteen points lying in a digital domain and values
CImageAdapter	Aim: implements an image adapter with a given domain (i.e. a subdomain) and 3 functors : g for domain, f for accessing point values and f-1 for writing point values
CImageCache	Aim: implements an images cache with 'read and write' policies
CImageCacheReadPolicyLAST	Aim: implements a 'LAST' read policy cache
CImageCacheReadPolicyFIFO	Aim: implements a 'FIFO' read policy cache
CImageCacheWritePolicyWT	Aim: implements a 'WT (Write-through)' write policy cache
CImageCacheWritePolicyWB	Aim: implements a 'WB (Write-back or Write-behind)' write policy cache
CImageContainerByITKImage	Aim: implements a model of CImageContainer using a ITK Image
CImageContainerBySTLMap
CDistanceFunctorFromPoint
►CImageContainerBySTLVector
CSpanIterator
CH5DSpecializations	Aim: implements HDF5 reading and writing for specialized type T
CH5DSpecializations< TImageFactory, DGtal::uint8_t >	Aim: implements HDF5 reading and writing for specialized type DGtal::uint8_t
CH5DSpecializations< TImageFactory, DGtal::int32_t >	Aim: implements HDF5 reading and writing for specialized type DGtal::int32_t
CH5DSpecializations< TImageFactory, DGtal::int64_t >	Aim: implements HDF5 reading and writing for specialized type DGtal::int64_t
CH5DSpecializations< TImageFactory, double >	Aim: implements HDF5 reading and writing for specialized type double
CImageFactoryFromHDF5	Aim: implements a factory from an HDF5 file
CImageFactoryFromImage	Aim: implements a factory to produce images from a "bigger/original" one according to a given domain
CImageToConstantFunctor
CImageLinearCellEmbedder	Aim: a cellular embedder for images. (default constructible, copy constructible, assignable). Model of CCellEmbedder
CImageSelector	Aim: Automatically defines an adequate image type according to the hints given by the user.
CImageFromSet	Aim: Define utilities to convert a digital set into an image
CSetFromImage	Aim: Define utilities to convert a digital set into an image
CMorton	Aim: Implements the binary Morton code construction in nD
CSetValueIterator	Aim: implements an output iterator, which is able to write values in an underlying image, by calling its setValue method
►CTiledImage	Aim: implements a tiled image from a "bigger/original" one from an ImageFactory
CTiledIterator
CBoard2D	Aim: This class specializes a 'Board' class so as to display DGtal objects more naturally (with <<). The user has simply to declare a Board2D object and uses stream operators to display most digital objects. Furthermore, one can use this class to modify the current style for drawing
CDrawWithBoardModifier
CCustomStyle
CSetMode	Modifier class in a Board2D stream. Useful to choose your own mode for a given class. Realizes the concept CDrawableWithBoard2D
CCustomColors	Custom style class redefining the pen color and the fill color. You may use Board2D::Color::None for transparent color
CCustomPenColor	Custom style class redefining the pen color. You may use Board2D::Color::None for transparent color
CCustomFillColor	Custom style class redefining the fill color. You may use Board2D::Color::None for transparent color
CCustomPen	Custom style class redefining the pen attributes. You may use Board2D::Color::None for transparent color
CBoard3D	The class Board3D is a type of Display3D which export the figures in the format OBJ/MTL when calling the method saveOBJ
CBoard3DTo2DFactory	Factory for GPL Display3D:
CDrawWithBoard3DTo2DModifier	Base class specifying the methods for classes which intend to modify a Viewer3D stream
CCameraPosition	CameraPosition class to set camera position
CCameraDirection	CameraDirection class to set camera direction
CCameraUpVector	CameraUpVector class to set camera up-vector
CCameraZNearFar	CameraZNearFar class to set near and far distance
CColor	Structure representing an RGB triple with alpha component
CColorBrightnessColorMap	Aim: This class template may be used to (linearly) convert scalar values in a given range into a color with given lightness
CGradientColorMap	Aim: This class template may be used to (linearly) convert scalar values in a given range into a color in a gradient defined by two or more colors
CGrayscaleColorMap	Aim: This class template may be used to (linearly) convert scalar values in a given range into gray levels
CHueShadeColorMap	Aim: This class template may be used to (linearly) convert scalar values in a given range into a color in a cyclic hue shade colormap, maybe aka rainbow color map. This color map is suitable, for example, to colorize distance functions. By default, only one hue cycle is used
CQuantifiedColorMap	Aim: A modifier class that quantifies any colormap into a given number of colors. It is particularly useful when rendering colored objects, since for instance blender is very slow to load many different materials
CRandomColorMap	Aim: access to random color from a gradientColorMap
CSimpleDistanceColorMap	Aim: simple blue to red colormap for distance information for instance
CTickedColorMap	Aim: This class adapts any colormap to add "ticks" in the colormap colors
CDisplay2DFactory	Factory for Display2D:
CDisplay3DFactory	Factory for GPL Display3D:
CDrawWithDisplay3DModifier	Base class specifying the methods for classes which intend to modify a Viewer3D stream
CSetMode3D	Modifier class in a Display3D stream. Useful to choose your own mode for a given class. Realizes the concept CDrawableWithDisplay3D
CCustomStyle3D	Modifier class in a Display3D stream. Useful to choose your own style for a given class. Realizes the concept CDrawableWithDisplay3D
CCustomColors3D
CClippingPlane	Class for adding a Clipping plane through the Viewer3D stream. Realizes the concept CDrawableWithViewer3D
CTransformedPrism	Class to modify the position and scale to construct better illustration mode
CSetName3D
CSetSelectCallback3D
CITKIOTrait	Aim: Provide type trait for ITK reader and ITK writer
CITKIOTrait< bool >
►CDicomReader	Aim: Import a 3D DICOM image from file series
CAux
CAux< ImageContainerByITKImage< Domain, OutPixelType >, Domain, OutPixelType, PixelType >
CGenericReader	Aim: Provide a mechanism to load with the bestloader according to an image (2D or 3D) filename (by parsing the extension)
CGenericReader< TContainer, 3, TValue >
CGenericReader< TContainer, 3, DGtal::uint32_t >
CGenericReader< TContainer, 3, DGtal::uint64_t >
CGenericReader< TContainer, 2, TValue >
CGenericReader< TContainer, 2, DGtal::uint32_t >
CHDF5Reader	Aim: Import a HDF5 file
►CITKDicomReader	Aim: Import a 2D/3D DICOM Image from file series
CAux
CAux< ImageContainerByITKImage< Domain, Value >, Domain, OrigValue, TFunctor, Value >
►CITKReader	Aim: Import a 2D/3D Image using the ITK formats
CAux
CAux< ImageContainerByITKImage< Domain, Value >, Domain, OrigValue, TFunctor, Value >
►CLongvolReader	Aim: implements methods to read a "Longvol" file format (with DGtal::uint64_t value type)
CHeaderField
CMeshReader	Aim: Defined to import OFF and OFS surface mesh. It allows to import a Mesh object and takes into accouts the optional color faces
CMPolynomialGrammar
►CMPolynomialReader	Aim: This class converts a string polynomial expression in a multivariate polynomial
CExprNodeMaker
CPGMReader	Aim: Import a 2D or 3D using the Netpbm formats (ASCII mode)
CPointListReader	Aim: Implements method to read a set of points represented in each line of a file
CPPMReader	Aim: Import a 2D or 3D using the Netpbm formats (ASCII mode)
CRawReader	Aim: Raw binary import of an Image
CSTBReader	Aim: Image reader using the stb_image.h header only code
CSurfaceMeshReader	Aim: An helper class for reading mesh files (Wavefront OBJ at this point) and creating a SurfaceMesh
CTableReader	Aim: Implements method to read a set of numbers represented in each line of a file
►CVolReader	Aim: implements methods to read a "Vol" file format
CHeaderField
CStyle2DFactory
CDrawWithViewer3DModifier	Base class specifying the methods for classes which intend to modify a Viewer3D stream
CUpdateImage3DEmbedding	Class to modify the 3d embedding of the image (useful to display not only 2D slice images). The embdding can be explicitly given from the 3D position of the four bounding points
CUpdateImagePosition	Class to modify the position and orientation of an textured 2D image
CAddTextureImage2DWithFunctor	Class to insert a custom 2D textured image by using a conversion functor and allows to change the default mode (GrayScale mode) to color mode
CAddTextureImage3DWithFunctor	Class to insert a custom 3D textured image by using a conversion functor and allows to change the default mode (GrayScale mode) to color mode
CUpdateLastImagePosition	Class to modify the position and orientation of an textured 2D image
CUpdateImageData	Class to modify the data of an given image and also the possibility to translate it (optional)
CTranslate2DDomain	Class to modify the data of an given image and also the possibility to translate it (optional)
CUpdate2DDomainPosition	Class to modify the position and orientation of an 2D domain
►CViewer3D
CCompFarthestPolygonFromCamera
CCompFarthestSurfelFromCamera
CCompFarthestTriangleFromCamera
CCompFarthestVoxelFromCamera
CExtension
CGLTextureImage
CImage2DDomainD3D
CTextureImage
CViewer3DFactory	Factory for GPL Viewer3D:
CGenericWriter	Aim: Provide a mechanism to save image (2D or 3D) into file with the best saver loader according to an filename (by parsing the extension)
CGenericWriter< TContainer, 3, unsigned char, TFunctor >
CGenericWriter< TContainer, 3, DGtal::uint64_t, TFunctor >
CGenericWriter< TContainer, 3, TValue, TFunctor >
CGenericWriter< TContainer, 2, TValue, TFunctor >
CGenericWriter< TContainer, 2, DGtal::Color, TFunctor >
CGenericWriter< TContainer, 2, unsigned char, TFunctor >
CHDF5Writer	Aim: Export an Image with the HDF5 format
CITKWriter	Export a 2D/3D Image using the ITK formats
CITKWriter< ImageContainerByITKImage< TDomain, TValue >, TFunctor >
CLongvolWriter	Aim: Export a 3D Image using the Longvol formats (volumetric image with DGtal::uint64_t value type)
CMeshWriter	Aim: Export a Mesh (Mesh object) in different format as OFF and OBJ)
CPGMWriter	Aim: Export a 2D and a 3D Image using the Netpbm PGM formats (ASCII mode)
CPPMWriter	Aim: Export a 2D and a 3D Image using the Netpbm PPM formats (ASCII mode)
CRawWriter	Aim: Raw binary export of an Image
CSTBWriter	Aim: Image Writer using the stb_image.h header only code
CSurfaceMeshWriter	Aim: An helper class for writing mesh file formats (Waverfront OBJ at this point) and creating a SurfaceMesh
CVolWriter	Aim: Export a 3D Image using the Vol formats
CArithmeticConversionTraits	Aim: Trait class to get result type of arithmetic binary operators between two given types
CArithmeticConversionTraits< T, U, typename std::enable_if< ! std::is_same< T, typename std::remove_cv< typename std::remove_reference< T >::type >::type >::value||! std::is_same< U, typename std::remove_cv< typename std::remove_reference< U >::type >::type >::value >::type >	Specialization in order to remove const specifiers and references from given types
CArithmeticConversionTraits< T, U, typename std::enable_if< std::is_arithmetic< T >::value &&std::is_arithmetic< U >::value >::type >	Specialization for (fundamental) arithmetic types
CIsArithmeticConversionValid	Helper to determine if an arithmetic operation between two given types has a valid result type (ie is valid)
CIsArithmeticConversionValid< T, U, typename std::conditional< false, ArithmeticConversionType< T, U >, void >::type >	Specialization when arithmetic operation between the two given type is valid
CArithmeticConversionTraits< T, __gmp_expr< GMP1, GMP2 >, typename std::enable_if< std::is_integral< T >::value >::type >	Specialization when first operand is a BigInteger
CArithmeticConversionTraits< __gmp_expr< GMP1, GMP2 >, U, typename std::enable_if< std::is_integral< U >::value >::type >	Specialization when second operand is a BigInteger
CArithmeticConversionTraits< __gmp_expr< GMPL1, GMPL2 >, __gmp_expr< GMPR1, GMPR2 > >	Specialization when both operands are BigInteger
CCanonicEmbedder	Aim: A trivial embedder for digital points, which corresponds to the canonic injection of Zn into Rn
►CHyperRectDomain	Aim: Parallelepidec region of a digital space, model of a 'CDomain'
CConstSubRange	Aim: range through some subdomain of all the points in the domain. Defines a constructor taking a domain in parameter plus some additional parameters to specify the subdomain, begin and end methods returning ConstIterator, and rbegin and rend methods returning ConstReverseIterator
CHyperRectDomain_ReverseIterator	Reverse iterator for HyperRectDomain
CHyperRectDomain_Iterator	Iterator for HyperRectDomain
CHyperRectDomain_subIterator
CRowMajorStorage	Tag (empty structure) specifying a row-major storage order
CColMajorStorage	Tag (empty structure) specifying a col-major storage order
CLinearizer	Aim: Linearization and de-linearization interface for domains
CLinearizer< HyperRectDomain< TSpace >, TStorageOrder >	Aim: Linearization and de-linearization interface for HyperRectDomain
CIntegerConverter	----------— INTEGER/POINT CONVERSION SERVICES -----------------—
CIntegerConverter< dim, DGtal::int32_t >
CIntegerConverter< dim, DGtal::int64_t >
CIntegerConverter< dim, DGtal::BigInteger >
CIntegralIntervals	Aim:
CLatticeSetByIntervals	Aim:
CLinearAlgebra	Aim: A utility class that contains methods to perform integral linear algebra
CNumberTraitsImpl	Aim: The traits class for all models of Cinteger (implementation)
CNumberTraitsImpl< T, typename std::enable_if< std::is_integral< T >::value >::type >	Specialization of NumberTraitsImpl for fundamental integer types
CNumberTraitsImpl< T, typename std::enable_if< std::is_floating_point< T >::value >::type >	Specialization of NumberTraitsImpl for fundamental floating-point types
CNumberTraitsImpl< DGtal::BigInteger, Enable >	Specialization of NumberTraitsImpl for DGtal::BigInteger
CNumberTraits	Aim: The traits class for all models of Cinteger
CWarning_promote_trait_not_specialized_for_this_case
Cpromote_trait
Cpromote_trait< int32_t, int64_t >
CPointVector	Aim: Implements basic operations that will be used in Point and Vector classes
CIsAPointVector	Type trait to check if a given type is a PointVector
CIsAPointVector< PointVector< dim, TEuclideanRing, TContainer > >	Specialization of IsAPointVector for a PointVector
CArithmeticConversionTraits< PointVector< dim, LeftEuclideanRing, LeftContainer >, PointVector< dim, RightEuclideanRing, RightContainer >, typename std::enable_if< IsArithmeticConversionValid< LeftEuclideanRing, RightEuclideanRing >::value >::type >	Specialization of ArithmeticConversionTraits when both operands are PointVector
CArithmeticConversionTraits< PointVector< dim, LeftEuclideanRing, LeftContainer >, RightEuclideanRing, typename std::enable_if< IsArithmeticConversionValid< LeftEuclideanRing, RightEuclideanRing >::value &&! IsAPointVector< RightEuclideanRing >::value >::type >	Specialization of ArithmeticConversionTraits when left operand is a PointVector
CArithmeticConversionTraits< LeftEuclideanRing, PointVector< dim, RightEuclideanRing, RightContainer >, typename std::enable_if< IsArithmeticConversionValid< LeftEuclideanRing, RightEuclideanRing >::value &&! IsAPointVector< LeftEuclideanRing >::value >::type >	Specialization of ArithmeticConversionTraits when right operand is a PointVector
CRegularPointEmbedder	Aim: A simple point embedder where grid steps are given for each axis. Note that the real point (0,...,0) is mapped onto the digital point (0,...,0)
CDigitalSetByAssociativeContainer	Aim: A wrapper class around a STL associative container for storing sets of digital points within some given domain
CDigitalSetBySTLSet	Aim: A container class for storing sets of digital points within some given domain
CDigitalSetBySTLVector	Aim: Realizes the concept CDigitalSet by using the STL container std::vector
CDigitalSetConverter	Aim: Utility class to convert between types of sets
CDigitalSetDomain	Aim: Constructs a domain limited to the given digital set
CDigitalSetFromMap	Aim: An adapter for viewing an associative image container like ImageContainerBySTLMap as a simple digital set. This class is merely based on an aliasing pointer on the image, which must exists elsewhere.
CDigitalSetInserter	Aim: this output iterator class is designed to allow algorithms to insert points in the digital set. Using the assignment operator, even when dereferenced, causes the digital set to insert a point
CDigitalSetSelector	Aim: Automatically defines an adequate digital set type according to the hints given by the user
►CSpaceND
CSubcospace	Define the type of a sub co-Space
CSubspace	Define the type of a subspace
CSplitter
►CUnorderedSetByBlock
Cconst_iterator	Read iterator on set elements. Model of ForwardIterator
Citerator	Read-write iterator on set elements. Model of ForwardIterator
CAngleComputer
►CAngleLinearMinimizer	Aim: Used to minimize the angle variation between different angles while taking into accounts min and max constraints. Example (
CValueInfo
CAngleLinearMinimizerByRelaxation
CAngleLinearMinimizerByGradientDescent
CAngleLinearMinimizerByAdaptiveStepGradientDescent
CRegularBinner	Aim: Represents an elementary functor that partitions quantities into regular intervals, given a range [min,max] range and a number nb of intervals (each interval is called a bin)
CHistogram	Aim: Represents a typical histogram in statistics, which is a discrete estimate of the probability distribution of a continuous variable
CLagrangeInterpolation	Aim: This class implements Lagrange basis functions and Lagrange interpolation
CDirichletConditions	Aim: A helper class to solve a system with Dirichlet boundary conditions
CEigenDecomposition	Aim: This class provides methods to compute the eigen decomposition of a matrix. Its objective is to replace a specialized matrix library when none are available
CEigenLinearAlgebraBackend	Aim: Provide linear algebra backend using Eigen dense and sparse matrix as well as dense vector. 6 linear solvers available:
CSimpleMatrix	Aim: implements basic MxN Matrix services (M,N>=1)
CSimpleMatrixSpecializations	Aim: Implement internal matrix services for specialized matrix size
CSimpleMatrixSpecializations< TMatrix, 2, 2 >	Aim:
CSimpleMatrixSpecializations< TMatrix, 1, 1 >	Aim:
CSimpleMatrixSpecializations< TMatrix, 3, 3 >	Aim:
CMeaningfulScaleAnalysis	Aim: This class implements different methods used to define the meaningful scale analysis as proposed in [67] . In particular, it uses the Profile class to represent a multi-scale profile and to compute a meaningful scale. It also permits to get a noise estimation from the given profile
CMeasureOfStraightLines	The aim of this class is to compute the measure in the Lebesgues sense of the set of straight lines associated to domains defined as polygons in the (a,b)-parameter space. This parameter space maps the line $ax-y+b=0$ to the point $(a,b)$
CMPolynomial	Aim: Represents a multivariate polynomial, i.e. an element of \( K[X_0, ..., X_{n-1}] \), where K is some ring or field
CMPolynomialDerivativeComputer
CMPolynomialEvaluator
►CMPolynomialEvaluatorImpl
CEvalFun
CEvalFun2
►CMPolynomialEvaluatorImpl< 1, TRing, TOwner, TAlloc, TX >
CEvalFun
CMPolynomialEvaluator< 1, TRing, TAlloc, TX >
CMPolynomial< 0, TRing, TAlloc >	Aim: Specialization of MPolynomial for degree 0
CIVector
CIVector< T, TAlloc, true >
CXe_kComputer
CXe_kComputer< 0, Ring, Alloc >
CMPolynomialDerivativeComputer< 0, n, Ring, Alloc >
CMPolynomialDerivativeComputer< 0, 0, Ring, Alloc >
CMPolynomialDerivativeComputer< N, 0, Ring, Alloc >
CMultiStatistics	Aim: This class stores a set of sample values for several variables and can then compute different statistics, like sample mean, sample variance, sample unbiased variance, etc
COrderedLinearRegression	Description of class 'OrderedLinearRegression'
CProfile	Aim: This class can be used to represent a profile (PX, PY) defined from an input set of samples (Xi, Yi). For all sample (Xk, Yk) having the same value Xk, the associated value PY is computed (by default) by the mean of the values Yk. Note that other definitions can be used (MAX, MIN or MEDIAN). Internally each sample abscissa is an instance of DGtal::Statistic
CRealFFT< HyperRectDomain< TSpace >, T >
CSignalData
CSignal	Aim: Represents a discrete signal, periodic or not. The signal can be passed by value since it is only cloned when modified
CSimpleLinearRegression	Description of class 'SimpleLinearRegression'
CStatistic	Aim: This class processes a set of sample values for one variable and can then compute different statistics, like sample mean, sample variance, sample unbiased variance, etc. It is minimalistic for space efficiency. For multiple variables, sample storage and others, see Statistics class
CDigitalShapesCSG	Aim: Constructive Solid Geometry (CSG) between models of CDigitalBoundedShape and CDigitalOrientedShape Use CSG operation (union, intersection, minus) from a shape of Type ShapeA with one (or more) shapes of Type ShapeB. Can combine differents operations. Limitations: Since we don't have a class derived by all shapes, operations can be done by only one type of shapes. Use CSG of CSG to go beyond this limitation
CEuclideanShapesCSG	Aim: Constructive Solid Geometry (CSG) between models of CEuclideanBoundedShape and CEuclideanOrientedShape Use CSG operation (union, intersection, minus) from a shape of Type ShapeA with one (or more) shapes of Type ShapeB. Can combine differents operations. Limitations: Since we don't have a class derived by all shapes, operations can be done by only one type of shapes. Use CSG of CSG to go beyond this limitation
CCircleFrom2Points	Aim: Represents a circle that passes through a given point and that is thus uniquely defined by two other points. It is able to return for any given point its signed distance to itself
CCircleFrom3Points	Aim: Represents a circle uniquely defined by three 2D points and that is able to return for any given 2D point its signed distance to itself
CStraightLineFrom2Points	Aim: Represents a straight line uniquely defined by two 2D points and that is able to return for any given 2D point its signed distance to itself
CGaussDigitizer	Aim: A class for computing the Gauss digitization of some Euclidean shape, i.e. its intersection with some \( h_1 Z \times h_2 Z \times \cdots \times h_n Z \). Note that the real point (0,...,0) is mapped onto the digital point (0,...,0)
CImplicitBall	Aim: model of CEuclideanOrientedShape and CEuclideanBoundedShape concepts to create a ball in nD.
CImplicitFunctionDiff1LinearCellEmbedderGradientMap	Forward declaration
CImplicitFunctionDiff1LinearCellEmbedder	Aim: a cellular embedder for implicit functions, (default constructible, copy constructible, assignable). Model of CCellEmbedder and CWithGradientMap
CImplicitFunctionLinearCellEmbedder	Aim: a cellular embedder for implicit functions, (default constructible, copy constructible, assignable). Model of CCellEmbedder
CImplicitHyperCube	Aim: model of CEuclideanOrientedShape and CEuclideanBoundedShape concepts to create an hypercube in nD.
CImplicitNorm1Ball	Aim: model of CEuclideanOrientedShape and CEuclideanBoundedShape concepts to create a ball for the L_1 norm in nD
CImplicitPolynomial3Shape	Aim: model of CEuclideanOrientedShape concepts to create a shape from a polynomial
CImplicitRoundedHyperCube	Aim: model of CEuclideanOrientedShape and CEuclideanBoundedShape concepts to create a rounded hypercube in nD.
►CIntersectionTargetTrait	Aim: A class for intersection target used for voxelization
CEdge	Internal Edge structure
CIntersectionTarget	Internal intersection target structure
CIntersectionTarget< Space, 26, 1 >
CIntersectionTarget< Space, 6, 1 >
►CMesh	Aim: This class is defined to represent a surface mesh through a set of vertices and faces. By using the default constructor, the mesh does not store any color information (it can be changed by setting the default constructor parameter saveFaceColor to 'true')
CCompPoints
CMeshHelpers	Aim: Static class that provides builder and converters between meshes
CMeshVoxelizer	Aim: A class for computing the digitization of a triangle or a Mesh
CAccFlower2D	Aim: Model of the concept StarShaped represents any accelerated flower in the plane
CAstroid2D	Aim: Model of the concept StarShaped represents an astroid
CBall2D	Aim: Model of the concept StarShaped represents any circle in the plane
CBall3D	Aim: Model of the concept StarShaped3D represents any Sphere in the space
CEllipse2D	Aim: Model of the concept StarShaped represents any ellipse in the plane
CFlower2D	Aim: Model of the concept StarShaped represents any flower with k-petals in the plane
CLemniscate2D	Aim: Model of the concept StarShaped represents a lemniscate
CNGon2D	Aim: Model of the concept StarShaped represents any regular k-gon in the plane
CStarShaped2D
CStarShaped3D
►CPolygonalSurface	Aim: Represents a polygon mesh, i.e. a 2-dimensional combinatorial surface whose faces are (topologically at least) simple polygons. The topology is stored with a half-edge data structure. This object stored the positions of vertices in space. If you need further data attached to the surface, you may use property maps (see PolygonalSurface::makeVertexMap)
CIndexedPropertyMap
CVertexMap
CShapes	Aim: A utility class for constructing different shapes (balls, diamonds, and others)
►CSurfaceMesh	Aim: Represents an embedded mesh as faces and a list of vertices. Vertices may be shared among faces but no specific topology is required. However, you also have methods to navigate between neighbor vertices, faces, etc. The mesh can be equipped with normals at faces and/or vertices
CVertexMap
CSurfaceMeshHelper	Aim: An helper class for building classical meshes
►CTriangulatedSurface	Aim: Represents a triangulated surface. The topology is stored with a half-edge data structure. This object stored the positions of vertices in space. If you need further data attached to the surface, you may use property maps (see TriangulatedSurface::makeVertexMap)
CIndexedPropertyMap
CVertexMap
CWindingNumbersShape	Aim: model of a CEuclideanOrientedShape from an implicit function from an oriented point cloud. The implicit function is given by the generalized winding number of the oriented point cloud [10] . We use the libIGL implementation
CCanonicCellEmbedder	Aim: A trivial embedder for signed and unsigned cell, which corresponds to the canonic injection of cell centroids into Rn
CCanonicDigitalSurfaceEmbedder	Aim: A trivial embedder for digital surfaces, which corresponds to the canonic injection of cell centroids into Rn
CCanonicSCellEmbedder	Aim: A trivial embedder for signed cell, which corresponds to the canonic injection of cell centroids into Rn
CCubicalCellData
►CCubicalComplex	Aim: This class represents an arbitrary cubical complex living in some Khalimsky space. Cubical complexes are sets of cells of different dimensions related together with incidence relations. Two cells in a cubical complex are incident if and only if they are incident in the surrounding Khalimsky space. In other words, cubical complexes are defined here as subsets of Khalimsky spaces
CConstIterator
CDefaultCellMapIteratorPriority
CIterator
CContainerTraits< CubicalComplex< TKSpace, TCellContainer > >
►CDigitalSetBoundary	Aim: A model of CDigitalSurfaceContainer which defines the digital surface as the boundary of a given digital set
CTracker
►CDigitalSurface	Aim: Represents a set of n-1-cells in a nD space, together with adjacency relation between these cells. Therefore, a digital surface is a pure cubical complex (model of CCubicalComplex), made of k-cells, 0 <= k < n. This complex is generally not a manifold (i.e. a kind of surface), except when it has the property of being well-composed
CArc
CEdge
CFace
CSurfelMap
CVertexMap
CDigitalSurface2DSlice	Aim: Represents a 2-dimensional slice in a DigitalSurface. In a sense, it is a 4-connected contour, open or not. To be valid, it must be connected to some digital surface and a starting surfel
CDigitalTopology	Aim: Represents a digital topology as a couple of adjacency relations
CDigitalTopologyTraits	Aim: the traits classes for DigitalTopology types
CDigitalTopologyTraits< MetricAdjacency< TSpace, 1 >, MetricAdjacency< TSpace, 2 >, 2 >	Aim: Specialization of the traits classes for DigitalTopology types for any 2D Space, for topology (4,8)
CDigitalTopologyTraits< MetricAdjacency< TSpace, 2 >, MetricAdjacency< TSpace, 1 >, 2 >	Aim: Specialization of the traits classes for DigitalTopology types for any 2D Space, for topology (8,4)
CDigitalTopologyTraits< MetricAdjacency< TSpace, 1 >, MetricAdjacency< TSpace, 3 >, 3 >	Aim: Specialization of the traits classes for DigitalTopology types for any 2D Space, for topology (6,26)
CDigitalTopologyTraits< MetricAdjacency< TSpace, 1 >, MetricAdjacency< TSpace, 2 >, 3 >	Aim: Specialization of the traits classes for DigitalTopology types for any 2D Space, for topology (6,18)
CDigitalTopologyTraits< MetricAdjacency< TSpace, 2 >, MetricAdjacency< TSpace, 1 >, 3 >	Aim: Specialization of the traits classes for DigitalTopology types for any 2D Space, for topology (18,6)
CDigitalTopologyTraits< MetricAdjacency< TSpace, 3 >, MetricAdjacency< TSpace, 1 >, 3 >	Aim: Specialization of the traits classes for DigitalTopology types for any 2D Space, for topology (26,6)
►CDomainAdjacency	Aim: Given a domain and an adjacency, limits the given adjacency to the specified domain for all adjacency and neighborhood computations
CVertexMap
►CExplicitDigitalSurface	Aim: A model of CDigitalSurfaceContainer which defines the digital surface as connected surfels. The shape is determined by a predicate telling whether a given surfel belongs or not to the shape boundary. Compute once the boundary of the surface with a tracking
CTracker
►CHalfEdgeDataStructure	Aim: This class represents an half-edge data structure, which is a structure for representing the topology of a combinatorial 2-dimensional surface or an embedding of a planar graph in the plane. It does not store any geometry. As a minimal example, these lines of code build two triangles connected by the edge {1,2}
CEdge
CHalfEdge
CTriangle	Represents an unoriented triangle as three vertices
CSurfaces	Aim: A utility class for constructing surfaces (i.e. set of (n-1)-cells)
►CImplicitDigitalSurface	Aim: A model of CDigitalSurfaceContainer which defines the digital surface as the boundary of an implicitly define shape. Compute once the boundary of the surface with a tracking
CTracker
►CIndexedDigitalSurface	Aim: Represents a digital surface with the topology of its dual surface. Its aim is to mimick the standard DigitalSurface, but to optimize its traversal and topology services. The idea is simply to number all its vertices (ie surfels), arcs, and faces and to store its topology with an half-edge data structure. It is essentially a PolygonalSurface but with services specific to DigitalSurface, like a tracker, a DigitalSurfaceContainer, etc. In theory, it can replace a DigitalSurface in many algorithms, and is more efficient if you need to do a lot of traversal on it (like many k-ring operations)
CIndexedPropertyMap
CVertexMap
►CKhalimskyPreSpaceND	Aim: This class is a model of CPreCellularGridSpaceND. It represents the cubical grid as a cell complex, whose cells are defined as an array of integers. The topology of the cells is defined by the parity of the coordinates (even: closed, odd: open)
CAnyCellCollection
CCellMap
CSCellMap
CSurfelMap
CKhalimskyPreCell	Represents an unsigned cell in an unbounded cellular grid space by its Khalimsky coordinates
CSignedKhalimskyPreCell	Represents a signed cell in an unbounded cellular grid space by its Khalimsky coordinates and a boolean value
CPreCellDirectionIterator	This class is useful for looping on all "interesting" coordinates of a pre-cell
►CKhalimskySpaceND	Aim: This class is a model of CCellularGridSpaceND. It represents the cubical grid as a cell complex, whose cells are defined as an array of integers. The topology of the cells is defined by the parity of the coordinates (even: closed, odd: open)
CCellMap
CSCellMap
CSurfelMap
CKhalimskySpaceNDHelper	Internal class of KhalimskySpaceND that provides some optimizations depending on the space type
CKhalimskyCell	Represents an (unsigned) cell in a cellular grid space by its Khalimsky coordinates
CSignedKhalimskyCell	Represents a signed cell in a cellular grid space by its Khalimsky coordinates and a boolean value
►CLightExplicitDigitalSurface	Aim: A model of CDigitalSurfaceContainer which defines the digital surface as connected surfels. The shape is determined by a predicate telling whether a given surfel belongs or not to the shape boundary. The whole boundary is not precomputed nor stored. You may use an iterator to visit it
CTracker
CVertexMap
►CLightImplicitDigitalSurface	Aim: A model of CDigitalSurfaceContainer which defines the digital surface as the boundary of an implicitly define shape. The whole boundary is not precomputed nor stored. You may use an iterator to visit it
CTracker
CVertexMap
►CMetricAdjacency	Aim: Describes digital adjacencies in digital spaces that are defined with the 1-norm and the infinity-norm
CVertexMap
►CObject	Aim: An object (or digital object) represents a set in some digital space associated with a digital topology
CEdge
CVertexMap
CParDirCollapse	Aim: Implements thinning algorithms in cubical complexes. The implementation supports any model of cubical complex, for instance a DGtal::CubicalComplex< KhalimskySpaceND< 3, int > >. Three approaches are provided. The first—ParDirCollapse—bases on directional collapse of free pairs of faces. Second—CollapseSurface—is an extension of ParDirCollapse such that faces of dimension one lower than the dimension of the complex are kept. The last approach —CollapseIsthmus—is also an extension of ParDirCollapse such that faces of dimension one lower than the complex are preserved when they do not contain free faces of dimension two lower than the complex. Paper: Chaussard, J. and Couprie, M., Surface Thinning in 3D Cubical Complexes, Combinatorial Image Analysis, (2009)
►CSetOfSurfels	Aim: A model of CDigitalSurfaceContainer which defines the digital surface as connected surfels. The shape is determined by the set of surfels that composed the surface. The set of surfels is stored in this container
CTracker
CSurfelAdjacency	Aim: Represent adjacencies between surfel elements, telling if it follows an interior to exterior ordering or exterior to interior ordering. It allows tracking of boundaries and of surfaces
CSurfelNeighborhood	Aim: This helper class is useful to compute the neighboring surfels of a given surfel, especially over a digital surface or over an object boundary. Two signed surfels are incident if they share a common n-2 cell. This class uses a SurfelAdjacency so as to determine adjacent surfels (either looking for them from interior to exterior or inversely)
►CUmbrellaComputer	Aim: Useful for computing umbrellas on 'DigitalSurface's, ie set of n-1 cells around a n-3 cell
CState
CVoxelComplex	This class represents a voxel complex living in some Khalimsky space. Voxel complexes are derived from
►CSymmetricConvexExpander	Aim: SymmetricConvexExpander computes symmetric fully convex subsets of a given digital set
CNodeComparator
►NLibBoard
NFonts
►CBoard	Class for EPS, FIG or SVG drawings
CState
CPath	A path, according to Postscript and SVG definition
CPoint	Struct representing a 2D point
CRect	Struct representing a rectangle on the plane
CShapeList	A group of shapes
CGroup	A group of shapes. A group is basically a ShapeList except that when rendered in either an SVG of a FIG file, it is a true compound element
CShape	Abstract structure for a 2D shape
CDot	A line between two points
CLine	A line between two points
CArrow	A line between two points with an arrow at one extremity
CPolyline	A polygonal line described by a series of 2D points
CRectangle	A rectangle
CImage	Used to draw image in figure
CTriangle	A triangle. Basically a Polyline with a convenient constructor
CQuadraticBezierCurve	A quadratic Bezier curve having 3 control points. NB. It is also a parabola arc
CGouraudTriangle	A triangle with shaded filling according to colors given for each vertex
CEllipse	An ellipse
CCircle	A circle
CArc	An arc
CText	A piece of text
CMessageStream
CTransform	Base class for transforms
CTransformEPS	Structure representing a scaling and translation suitable for an EPS output
CTransformFIG	Structure representing a scaling and translation suitable for an XFig output
CTransformSVG	Structure representing a scaling and translation suitable for an SVG output
CTransformCairo	Structure representing a scaling and translation suitable for an Cairo output
CTransformTikZ	Structure representing a scaling and translation suitable for an TikZ output
►Nstd	STL namespace
Chash< DGtal::PointVector< dim, EuclideanRing, Container > >
Chash< DGtal::BigInteger >
Chash< DGtal::KhalimskyCell< dim, TInteger > >	Extend std namespace to define a std::hash function on DGtal::KhalimskyCell
Chash< DGtal::SignedKhalimskyCell< dim, TInteger > >	Extend std namespace to define a std::hash function on DGtal::SignedKhalimskyCell