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Graph.h
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1 #ifndef DATA_FORMATS_MATH_GRAPH_H
2 #define DATA_FORMATS_MATH_GRAPH_H
3 
4 #include <iostream>
5 #include <map>
6 #include <vector>
7 
8 // Adjecencylist Graph
9 namespace math {
10 
11  // N,E must be concepts of default constructable, assignable, copyable, operator<
12  template <class N, class E>
13  class Graph {
14  public:
16  // (node-index target, edge)
17  using edge_type = std::pair<index_type, index_type>;
18  // (std::vector of edge_types for the adj_list)
19  using edge_list = std::vector<edge_type>;
20  // (node-index -> edge_list) the adjacency-list
21  using adj_list = std::vector<edge_list>;
22 
24  friend class Graph<N, E>;
25 
26  public:
30 
31  struct value_type {
32  friend class Graph<N, E>::const_iterator;
33  value_type(const Graph &g, index_type a, index_type e) : gr_(g), a_(a), e_(e) {}
34 
35  const N &from(void) const { return gr_.nodeData(a_); }
36  const N &to(void) const { return gr_.nodeData(gr_.adjl_[a_][e_].first); }
37  const E &edge(void) const { return gr_.edgeData(gr_.adjl_[a_][e_].second); }
38 
39  private:
40  const Graph &gr_;
42  };
43 
44  using reference = value_type &;
45  using pointer = value_type *;
46 
47  bool operator==(const const_iterator &i) const {
48  return ((vt_.a_ == i.vt_.a_) && (vt_.e_ == i.vt_.e_)) ? true : false;
49  }
50 
51  bool operator!=(const const_iterator &i) const {
52  return ((vt_.a_ == i.vt_.a_) && (vt_.e_ == i.vt_.e_)) ? false : true;
53  }
54 
55  void operator++() {
56  while (vt_.gr_.size() > vt_.a_) {
57  index_type i = vt_.gr_.adjl_[vt_.a_].size();
58  if (i > vt_.e_ + 1) {
59  ++vt_.e_;
60  return;
61  }
62  vt_.e_ = 0;
63  ++vt_.a_;
64  while (vt_.gr_.size() > vt_.a_) {
65  if (!vt_.gr_.adjl_[vt_.a_].empty()) {
66  return;
67  }
68  ++vt_.a_;
69  }
70  }
71  }
72 
73  const value_type &operator*() const { return vt_; }
74 
75  const value_type *operator->() const { return &vt_; }
76 
77  private:
78  explicit const_iterator(const Graph &g) : vt_(g, 0, 0) {}
79 
80  const_iterator(const Graph &g, index_type ait, index_type eit) : vt_(g, ait, eit) {}
81 
83 
84  bool operator<(const const_iterator &i) const { return (vt_.a_ < i.vt_.a_) && (vt_.e_ < i.vt_.e_); }
85 
86  bool operator>(const const_iterator &i) const { return (vt_.a_ > i.vt_.a_) && (vt_.e_ > i.vt_.e_); }
87  };
88 
89  // Graphtypes
90 
91  struct value_type {
92  value_type(const N &n, const E &e) : first(n), second(e) {}
93  const N &first;
94  const E &second;
95  N firstToValue() const { return first; }
96  E secondToValue() const { return second; }
97  };
98 
99  // (node-index -> node)
100  using node_list = std::vector<N>;
101  using edge_store = std::vector<E>;
102 
103  // (node-index -> edge_list) the adjacency-list
104  using adj_iterator = adj_list::iterator;
105  using const_adj_iterator = adj_list::const_iterator;
106 
107  // assigns a node-index to the node
108  using indexer_type = std::map<N, index_type>;
109  using indexer_iterator = typename indexer_type::iterator;
110  using const_indexer_iterator = typename indexer_type::const_iterator;
111 
112  // supported iterators and ranges
113  using edge_iterator = edge_list::iterator;
114  using const_edge_iterator = edge_list::const_iterator;
115  using edge_range = std::pair<edge_iterator, edge_iterator>;
116  using const_edge_range = std::pair<const_edge_iterator, const_edge_iterator>;
117  using index_result = std::pair<index_type, bool>;
118 
119  public:
120  // creation, deletion
121  Graph() : edges_(1) {}
122  ~Graph() {}
123 
124  // operations
125 
126  // O(log(n)), n...number of nodes
127  index_type addNode(const N &);
128  // O(log(n*e)), n,e...number of nodes,edges
129  void addEdge(const N &from, const N &to, const E &edge);
130 
131  // O(1)
132  //index_type addNode(const node_type &);
133  // O(log(e))
134  //index_type addEdge(const node_type & from, const node_type & to, const E & e);
135 
136  inline index_result nodeIndex(const N &) const;
137 
138  //index_type edgeIndex(const E &) const;
139 
140  // indexed edge_ranges, O(1) operation
143 
144  // indexed edge_ranges, O(log(n)) operation, n...number of nodes
145  inline edge_range edges(const N &);
146  inline const_edge_range edges(const N &) const;
147 
148  inline const N &nodeData(const edge_type &) const;
149  inline const N &nodeData(index_type) const;
150  inline const N &nodeData(const const_adj_iterator &) const;
151 
152  // replace oldNode by newNode O(log(n))
153  bool replace(const N &oldNode, const N &newNode);
154 
155  //replace oldEdge by newEdge
156  bool replaceEdge(const E &ldEdge, const E &newEdge);
157 
158  const E &edgeData(index_type i) const { return edges_[i]; }
159  // const N & nodeData(const adj_iterator &) const;
160  // index of a node (O(log(n))
161 
163  void clear();
164  // access to the linear-iterator
165  const_iterator begin_iter() const { return const_iterator(*this); }
166 
167  const_iterator end_iter() const { return const_iterator(*this, adjl_.size(), 0); }
168 
169  size_t edge_size() const { return edges_.size(); }
170 
171  // access to the adjacency-list
172  adj_iterator begin() { return adjl_.begin(); }
173  const_adj_iterator begin() const { return adjl_.begin(); }
174  adj_iterator end() { return adjl_.end(); }
175  const_adj_iterator end() const { return adjl_.end(); }
176  auto size() const -> adj_list::size_type { return adjl_.size(); }
177 
178  // finds all roots of the Graph and puts them into the edge_list
179  void findRoots(edge_list &) const;
180 
181  // inverts the directed Graph, i.e. edge(A,B) -> edge(B,A)
182  void invert(Graph &g) const;
183 
184  void swap(Graph<N, E> &);
185 
186  // Data
187  private:
188  // adjacency list
190 
191  // std::mapping of index to node
193 
194  // std::mapping of indes to edge
196 
197  // indexer for N and E
198  indexer_type indexer_; // eIndexer_;
199 
200  // dummy
202  };
203 
204  template <class N, class E>
206  index_type idx = indexer_.size(); // +1;
207  std::pair<indexer_iterator, bool> result = indexer_.insert(typename indexer_type::value_type(node, idx));
208 
209  if (result.second) { // new index!
210  nodes_.emplace_back(node);
211  adjl_.emplace_back(edge_list());
212  } else {
213  idx = result.first->second;
214  }
215  return idx;
216  }
217 
218  template <class N, class E>
219  typename Graph<N, E>::index_result Graph<N, E>::nodeIndex(const N &node) const {
220  typename indexer_type::const_iterator result = indexer_.find(node);
221  index_type idx = 0;
222  bool flag = false;
223  if (result != indexer_.end()) {
224  flag = true;
225  idx = result->second;
226  }
227  return index_result(idx, flag);
228  }
229 
230  template <class N, class E>
231  void Graph<N, E>::addEdge(const N &from, const N &to, const E &edge) {
232  index_type iFrom = addNode(from);
233  index_type iTo = addNode(to);
234 
235  adjl_[iFrom].emplace_back(edge_type(iTo, edges_.size()));
236  edges_.emplace_back(edge);
237  }
238 
239  template <class N, class E>
241  edge_list &edges = adjl_[nodeIndex];
242  return edge_range(edges.begin(), edges.end());
243  }
244 
245  template <class N, class E>
247  const edge_list &edges = adjl_[nodeIndex];
248  return const_edge_range(edges.begin(), edges.end());
249  }
250 
251  template <class N, class E>
253  index_result idxResult = nodeIndex(node);
254  edge_range result(emptyEdges_.begin(), emptyEdges_.end());
255  if (idxResult.second) {
256  result = edges(idxResult.first);
257  }
258  return result;
259  }
260 
261  template <class N, class E>
262  typename Graph<N, E>::const_edge_range Graph<N, E>::edges(const N &node) const {
263  index_result idxResult = nodeIndex(node);
264  const_edge_range result(emptyEdges_.begin(), emptyEdges_.end());
265  if (idxResult.second) {
266  result = edges(idxResult.first);
267  }
268  return result;
269  }
270 
271  template <class N, class E>
272  const N &Graph<N, E>::nodeData(const edge_type &edge) const {
273  return nodes_[edge.first];
274  }
275 
276  template <class N, class E>
278  return nodes_[i];
279  }
280 
281  template <class N, class E>
282  const N &Graph<N, E>::nodeData(const const_adj_iterator &it) const {
283  return nodes_[it - adjl_.begin()];
284  }
285 
286  template <class N, class E>
288  result.clear();
289 
290  const_adj_iterator it = begin();
291  const_adj_iterator ed = end();
292  std::vector<bool> rootCandidate(size(), true);
293 
294  for (; it != ed; ++it) {
295  const edge_list &el = *it;
296  for (auto const &el_it : el) {
297  rootCandidate[el_it.first] = false;
298  }
299  }
301  std::vector<bool>::size_type v_ed = rootCandidate.size();
302  for (; v_sz < v_ed; ++v_sz) {
303  if (rootCandidate[v_sz]) {
304  result.emplace_back(edge_type(v_sz, 0));
305  }
306  }
307  }
308 
309  template <class N, class E>
310  bool Graph<N, E>::replace(const N &oldNode, const N &newNode) {
311  typename indexer_type::iterator it = indexer_.find(oldNode);
312  if (it != indexer_.end()) {
313  index_type oldIndex = it->second;
314  nodes_[oldIndex] = newNode;
315  indexer_[newNode] = oldIndex;
316  indexer_.erase(it);
317  } else
318  throw(oldNode);
319  return true;
320  }
321 
322  template <class N, class E>
323  bool Graph<N, E>::replaceEdge(const E &oldEdge, const E &newEdge) {
324  typename edge_store::size_type it = 0;
325  typename edge_store::size_type ed = edges_.size();
326  bool result = false;
327  for (; it < ed; ++it) {
328  if (edges_[it] == oldEdge) {
329  result = true;
330  edges_[it] = newEdge;
331  break;
332  }
333  }
334  return result;
335  }
336 
337  template <class N, class E>
339  adjl_.clear();
340  nodes_.clear();
341  edges_.clear();
342  indexer_.clear();
343  }
344 
345  template <class N, class E>
347  adj_list::size_type it = 0;
348  adj_list::size_type ed = adjl_.size();
349  // loop over adjacency-list of this Graph
350  for (; it < ed; ++it) {
351  const edge_list &el = adjl_[it];
352  edge_list::size_type eit = 0;
353  edge_list::size_type eed = el.size();
354  // loop over edges of current node
355  for (; eit < eed; ++eit) {
356  const edge_type &e = el[eit];
357  g.addEdge(nodeData(e.first), nodeData(it), edgeData(e.second));
358  }
359  }
360  }
361 
362  template <class N, class E>
364  adjl_.swap(g.adjl_);
365  nodes_.swap(g.nodes_);
366  edges_.swap(g.edges_);
367  indexer_.swap(g.indexer_);
368  emptyEdges_.swap(g.emptyEdges_);
369  }
370 
371  template <typename T>
372  std::ostream &operator<<(std::ostream &o, const std::vector<std::vector<std::pair<T, T> > > v) {
373  typedef typename std::vector<std::vector<std::pair<T, T> > > v_t;
374  typedef typename std::vector<std::pair<T, T> > i_t;
375 
376  typename v_t::const_iterator it(v.begin()), ed(v.end());
377  for (; it != ed; ++it) {
378  typename i_t::const_iterator iit(it->begin()), ied(it->end());
379  for (; iit != ied; ++iit) {
380  o << iit->first << ':' << iit->second << std::endl;
381  }
382  }
383  return o;
384  }
385 
386 } // namespace math
387 
388 #endif
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