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// named parameter version template <typename Graph, typename ComponentMap, typename OutputIterator, typename P, typename T, typename R> std::pair<std::size_t, OutputIterator> biconnected_components(const Graph& g, ComponentMap comp, OutputIterator out, const bgl_named_params<P, T, R>& params) template <typename Graph, typename ComponentMap, typename P, typename T, typename R> std::size_t biconnected_components(const Graph& g, ComponentMap comp, const bgl_named_params<P, T, R>& params) template <typename Graph, typename OutputIterator, typename P, typename T, typename R> OutputIterator articulation_points(const Graph& g, OutputIterator out, const bgl_named_params<P, T, R>& params) // non-named parameter version template <typename Graph, typename ComponentMap, typename OutputIterator, typename DiscoverTimeMap, typename LowPointMap> std::pair<std::size_t, OutputIterator> biconnected_components(const Graph& g, ComponentMap comp, OutputIterator out, DiscoverTimeMap discover_time, LowPointMap lowpt); template <typename Graph, typename ComponentMap, typename OutputIterator> std::pair<std::size_t, OutputIterator> biconnected_components(const Graph& g, ComponentMap comp, OutputIterator out); template <typename Graph, typename ComponentMap> std::size_t biconnected_components(const Graph& g, ComponentMap comp); template <typename Graph, typename OutputIterator> OutputIterator articulation_points(const Graph& g, OutputIterator out);
A connected graph is biconnected if the removal of any single vertex (and all edges incident on that vertex) can not disconnect the graph. More generally, the biconnected components of a graph are the maximal subsets of vertices such that the removal of a vertex from a particular component will not disconnect the component. Unlike connected components, vertices may belong to multiple biconnected components: those vertices that belong to more than one biconnected component are called articulation points or, equivalently, cut vertices. Articulation points are vertices whose removal would increase the number of connected components in the graph. Thus, a graph without articulation points is biconnected. The following figure illustrates the articulation points and biconnected components of a small graph:
Vertices can be present in multiple biconnected components, but each edge can only be contained in a single biconnected component. The output of the biconnected_components algorithm records the biconnected component number of each edge in the property map comp. Articulation points will be emitted to the (optional) output iterator argument to biconnected_components, or can be computed without the use of a biconnected component number map via articulation_points. These functions return the number of biconnected components, the articulation point output iterator, or a pair of these quantities, depending on what information was recorded.
The algorithm implemented is due to Tarjan [41].
boost/graph/biconnected_components.hpp
An undirected graph. The graph type must be a model of Vertex List Graph and Incidence Graph.OUT: ComponentMap c
Python: The parameter is named graph.
The algorithm computes how many biconnected components are in the graph, and assigning each component an integer label. The algorithm then records which component each edge in the graph belongs to by recording the component number in the component property map. The ComponentMap type must be a model of Writable Property Map. The value type should be an integer type, preferably the same as the edges_size_type of the graph. The key type must be the graph's edge descriptor type.OUT: OutputIterator out
Default: dummy_property_map.
Python: Must be an edge_int_map for the graph.
Python default: graph.get_edge_int_map("bicomponent")
The algorithm writes articulation points via this output iterator and returns the resulting iterator.
Default: a dummy iterator that ignores values written to it.
Python: this parameter is not used in Python. Instead, both algorithms return a Python list containing the articulation points.
This maps each vertex to an integer in the range [0, num_vertices(g)). The type VertexIndexMap must be a model of Readable Property Map. The value type of the map must be an integer type. The vertex descriptor type of the graph needs to be usable as the key type of the map.UTIL/OUT: discover_time_map(DiscoverTimeMap discover_time)
Default: get(vertex_index, g)
Python: Unsupported parameter.
The discovery time of each vertex in the depth-first search. The type DiscoverTimeMap must be a model of Read/Write Property Map. The value type of the map must be an integer type. The vertex descriptor type of the graph needs to be usable as the key type of the map.UTIL/OUT: lowpoint_map(LowPointMap lowpt)
Default: an iterator_property_map created from a std::vector of vertices_size_type of size num_vertices(g) and using get(vertex_index, g) for the index map.
Python: Unsupported parameter.
The low point of each vertex in the depth-first search, which is the smallest vertex reachable from a given vertex with at most one back edge. The type LowPointMap must be a model of Read/Write Property Map. The value type of the map must be an integer type. The vertex descriptor type of the graph needs to be usable as the key type of the map.UTIL/OUT: predecessor_map(PredecessorMap p_map)
Default: an iterator_property_map created from a std::vector of vertices_size_type of size num_vertices(g) and using get(vertex_index, g) for the index map.
Python: Unsupported parameter.
The predecessor map records the depth first search tree. The PredecessorMap type must be a Read/Write Property Map whose key and value types are the same as the vertex descriptor type of the graph.IN: visitor(DFSVisitor vis)
Default: an iterator_property_map created from a std::vector of vertex_descriptor of size num_vertices(g) and using get(vertex_index, g) for the index map.
Python: Must be a vertex_vertex_map for the graph.
A visitor object that is invoked inside the algorithm at the event-points specified by the DFS Visitor concept. The visitor object is passed by value [1].
Default: dfs_visitor<null_visitor>
Python: The parameter should be an object that derives from the DFSVisitor type of the graph.
The time complexity for the biconnected components and articulation points algorithms O(V + E).
The file examples/biconnected_components.cpp contains an example of calculating the biconnected components and articulation points of an undirected graph.
[1]
Since the visitor parameter is passed by value, if your visitor
contains state then any changes to the state during the algorithm
will be made to a copy of the visitor object, not the visitor object
passed in. Therefore you may want the visitor to hold this state by
pointer or reference.
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