Changeset 1016:18d009b23e42 in lemon-0.x
- Timestamp:
- 11/22/04 10:09:18 (20 years ago)
- Branch:
- default
- Phase:
- public
- Convert:
- svn:c9d7d8f5-90d6-0310-b91f-818b3a526b0e/lemon/trunk@1406
- Location:
- src
- Files:
-
- 4 edited
Legend:
- Unmodified
- Added
- Removed
-
src/lemon/graph_wrapper.h
r1013 r1016 1193 1193 1194 1194 // typename _Graph::template EdgeMap<T>::Reference 1195 T operator[](Edge e) {1195 T operator[](Edge e) const { 1196 1196 if (!e.backward) 1197 1197 return forward_map[e]; -
src/work/marci/makefile
r1007 r1016 2 2 CXX3=$(CXX) 3 3 BOOSTROOT ?= /home/marci/boost 4 INCLUDEDIRS ?= - I../{jacint,marci,alpar,klao,akos,athos} -I../.. -I.. -I$(BOOSTROOT)4 INCLUDEDIRS ?= -ftemplate-depth-50 -I../{jacint,marci,alpar,klao,akos,athos} -I../.. -I.. -I$(BOOSTROOT) 5 5 6 6 LEDABINARIES = leda_graph_demo leda_bfs_dfs max_bipartite_matching_demo -
src/work/marci/merge_node_graph_wrapper.h
r1013 r1016 271 271 into the node-set of one graph. 272 272 Specialization for the case when 273 _Graph1::Node are base and derived _Graph2::Node. 274 NOT YET IMPLEMENTED 273 _Graph1::Node is a base class and _Graph2::Node is derived from it. 275 274 */ 276 275 template <typename _Graph1, typename _Graph2> … … 290 289 MergeNodeGraphWrapperBase() { } 291 290 public: 292 class Node { }; 291 template <typename _Value> class NodeMap; 292 293 class Node : public Graph2Node { 294 friend class MergeNodeGraphWrapperBase<_Graph1, _Graph2>; 295 template <typename _Value> friend class NodeMap; 296 protected: 297 bool backward; //true, iff backward 298 public: 299 Node() { } 300 /// \todo =false is needed, or causes problems? 301 /// If \c _backward is false, then we get an edge corresponding to the 302 /// original one, otherwise its oppositely directed pair is obtained. 303 Node(const Graph1Node& n1, 304 const Graph2Node& n2, bool _backward) : 305 Graph2Node(n2), backward(_backward) { 306 if (!backward) *this=n1; 307 } 308 Node(Invalid i) : Graph2Node(i), backward(true) { } 309 bool operator==(const Node& v) const { 310 if (backward) 311 return (v.backward && 312 static_cast<Graph2Node>(*this)==static_cast<Graph2Node>(v)); 313 else 314 return (!v.backward && 315 static_cast<Graph1Node>(*this)==static_cast<Graph1Node>(v)); 316 } 317 bool operator!=(const Node& v) const { 318 return !(*this==v); 319 } 320 }; 321 322 //typedef void Edge; 293 323 class Edge { }; 294 void first() const; 295 void next() const; 324 325 void first(Node& i) const { 326 Parent1::graph->first(*static_cast<Graph1Node*>(&i)); 327 i.backward=false; 328 if (*static_cast<Graph1Node*>(&i)==INVALID) { 329 Parent2::graph->first(*static_cast<Graph2Node*>(&i)); 330 i.backward=true; 331 } 332 } 333 void next(Node& i) const { 334 if (!(i.backward)) { 335 Parent1::graph->next(*static_cast<Graph1Node*>(&i)); 336 if (*static_cast<Graph1Node*>(&i)==INVALID) { 337 Parent2::graph->first(*static_cast<Graph2Node*>(&i)); 338 i.backward=true; 339 } 340 } else { 341 Parent2::graph->next(*static_cast<Graph2Node*>(&i)); 342 } 343 } 344 345 int id(const Node& n) const { 346 if (!n.backward) 347 return this->Parent1::graph->id(n); 348 else 349 return this->Parent2::graph->id(n); 350 } 351 352 template <typename _Value> 353 class NodeMap { 354 protected: 355 typedef typename _Graph1::template NodeMap<_Value> ParentMap1; 356 typedef typename _Graph2::template NodeMap<_Value> ParentMap2; 357 ParentMap1 forward_map; 358 ParentMap2 backward_map; 359 public: 360 typedef _Value Value; 361 typedef Node Key; 362 NodeMap(const MergeNodeGraphWrapperBase<_Graph1, _Graph2>& gw) : 363 forward_map(*(gw.Parent1::graph)), 364 backward_map(*(gw.Parent2::graph)) { } 365 NodeMap(const MergeNodeGraphWrapperBase<_Graph1, _Graph2>& gw, 366 const _Value& value) : 367 forward_map(*(gw.Parent1::graph), value), 368 backward_map(*(gw.Parent2::graph), value) { } 369 _Value operator[](const Node& n) const { 370 if (!n.backward) 371 return forward_map[n]; 372 else 373 return backward_map[n]; 374 } 375 void set(const Node& n, const _Value& value) { 376 if (!n.backward) 377 forward_map.set(n, value); 378 else 379 backward_map.set(n, value); 380 } 381 // using ParentMap1::operator[]; 382 // using ParentMap2::operator[]; 383 }; 384 296 385 }; 297 386 298 //not yet working 387 388 /*! A graph wrapper base class 389 for merging the node-set of two node-disjoint graphs 390 into the node-set of one graph. 391 Specialized implementaton for the case when _Graph1::Node is derived 392 from _Graph2::Node. 393 */ 299 394 template <typename _Graph1, typename _Graph2> 300 395 class MergeNodeGraphWrapperBase< … … 313 408 MergeNodeGraphWrapperBase() { } 314 409 public: 315 class Node { }; 410 template <typename _Value> class NodeMap; 411 412 class Node : public Graph1Node { 413 friend class MergeNodeGraphWrapperBase<_Graph1, _Graph2>; 414 template <typename _Value> friend class NodeMap; 415 protected: 416 bool backward; //true, iff backward 417 public: 418 Node() { } 419 /// \todo =false is needed, or causes problems? 420 /// If \c _backward is false, then we get an edge corresponding to the 421 /// original one, otherwise its oppositely directed pair is obtained. 422 Node(const Graph1Node& n1, 423 const Graph2Node& n2, bool _backward) : 424 Graph1Node(n1), backward(_backward) { 425 if (backward) *this=n2; 426 } 427 Node(Invalid i) : Graph1Node(i), backward(true) { } 428 bool operator==(const Node& v) const { 429 if (backward) 430 return (v.backward && 431 static_cast<Graph2Node>(*this)==static_cast<Graph2Node>(v)); 432 else 433 return (!v.backward && 434 static_cast<Graph1Node>(*this)==static_cast<Graph1Node>(v)); 435 } 436 bool operator!=(const Node& v) const { 437 return !(*this==v); 438 } 439 }; 440 441 //typedef void Edge; 316 442 class Edge { }; 317 void first() const; 318 void next() const; 443 444 void first(Node& i) const { 445 Parent1::graph->first(*static_cast<Graph1Node*>(&i)); 446 i.backward=false; 447 if (*static_cast<Graph1Node*>(&i)==INVALID) { 448 Parent2::graph->first(*static_cast<Graph2Node*>(&i)); 449 i.backward=true; 450 } 451 } 452 void next(Node& i) const { 453 if (!(i.backward)) { 454 Parent1::graph->next(*static_cast<Graph1Node*>(&i)); 455 if (*static_cast<Graph1Node*>(&i)==INVALID) { 456 Parent2::graph->first(*static_cast<Graph2Node*>(&i)); 457 i.backward=true; 458 } 459 } else { 460 Parent2::graph->next(*static_cast<Graph2Node*>(&i)); 461 } 462 } 463 464 int id(const Node& n) const { 465 if (!n.backward) 466 return this->Parent1::graph->id(n); 467 else 468 return this->Parent2::graph->id(n); 469 } 470 471 template <typename _Value> 472 class NodeMap { 473 protected: 474 typedef typename _Graph1::template NodeMap<_Value> ParentMap1; 475 typedef typename _Graph2::template NodeMap<_Value> ParentMap2; 476 ParentMap1 forward_map; 477 ParentMap2 backward_map; 478 public: 479 typedef _Value Value; 480 typedef Node Key; 481 NodeMap(const MergeNodeGraphWrapperBase<_Graph1, _Graph2>& gw) : 482 forward_map(*(gw.Parent1::graph)), 483 backward_map(*(gw.Parent2::graph)) { } 484 NodeMap(const MergeNodeGraphWrapperBase<_Graph1, _Graph2>& gw, 485 const _Value& value) : 486 forward_map(*(gw.Parent1::graph), value), 487 backward_map(*(gw.Parent2::graph), value) { } 488 _Value operator[](const Node& n) const { 489 if (!n.backward) 490 return forward_map[n]; 491 else 492 return backward_map[n]; 493 } 494 void set(const Node& n, const _Value& value) { 495 if (!n.backward) 496 forward_map.set(n, value); 497 else 498 backward_map.set(n, value); 499 } 500 // using ParentMap1::operator[]; 501 // using ParentMap2::operator[]; 502 }; 503 319 504 }; 320 505 … … 533 718 class MergeEdgeGraphWrapperBase< 534 719 _Graph1, _Graph2, typename boost::enable_if< 535 boost::is_same<typename _Graph1:: Node, typename _Graph2::Node> >::type> :720 boost::is_same<typename _Graph1::Edge, typename _Graph2::Edge> >::type> : 536 721 public MergeNodeGraphWrapperBase<_Graph1, _Graph2> { 537 722 public: … … 701 886 702 887 888 /*! A grah wrapper base class 889 for merging the node-sets and edge-sets of 890 two node-disjoint graphs 891 into one graph. 892 Specialized implementation for the case 893 when _Graph1::Edge is a base class and _Graph2::Edge 894 is derived from it. 895 */ 896 template <typename _Graph1, typename _Graph2> 897 class MergeEdgeGraphWrapperBase< 898 _Graph1, _Graph2, typename boost::enable_if< 899 boost::is_base_and_derived<typename _Graph1::Edge, typename _Graph2::Edge> >::type> : 900 public MergeNodeGraphWrapperBase<_Graph1, _Graph2> { 901 public: 902 static void printEdge() { std::cout << "edge: 2nd is derived" << std::endl; } 903 typedef _Graph1 Graph1; 904 typedef _Graph2 Graph2; 905 typedef MergeNodeGraphWrapperBase<_Graph1, _Graph2> Parent; 906 typedef typename Parent::Parent1 Parent1; 907 typedef typename Parent::Parent2 Parent2; 908 // typedef P1<_Graph1> Parent1; 909 // typedef P2<_Graph2> Parent2; 910 typedef typename Parent1::Edge Graph1Edge; 911 typedef typename Parent2::Edge Graph2Edge; 912 protected: 913 MergeEdgeGraphWrapperBase() { } 914 public: 915 template <typename _Value> class EdgeMap; 916 917 typedef typename Parent::Node Node; 918 919 class Edge : public Graph2Edge { 920 friend class MergeEdgeGraphWrapperBase<_Graph1, _Graph2>; 921 template <typename _Value> friend class EdgeMap; 922 protected: 923 bool backward; //true, iff backward 924 public: 925 Edge() { } 926 /// \todo =false is needed, or causes problems? 927 /// If \c _backward is false, then we get an edge corresponding to the 928 /// original one, otherwise its oppositely directed pair is obtained. 929 Edge(const Graph1Edge& n1, 930 const Graph2Edge& n2, bool _backward) : 931 Graph2Edge(n2), backward(_backward) { 932 if (!backward) *this=n1; 933 } 934 Edge(Invalid i) : Graph2Edge(i), backward(true) { } 935 bool operator==(const Edge& v) const { 936 if (backward) 937 return (v.backward && 938 static_cast<Graph2Edge>(*this)==static_cast<Graph2Edge>(v)); 939 else 940 return (!v.backward && 941 static_cast<Graph1Edge>(*this)==static_cast<Graph1Edge>(v)); 942 } 943 bool operator!=(const Edge& v) const { 944 return !(*this==v); 945 } 946 }; 947 948 using Parent::first; 949 void first(Edge& i) const { 950 Parent1::graph->first(*static_cast<Graph1Edge*>(&i)); 951 i.backward=false; 952 if (*static_cast<Graph1Edge*>(&i)==INVALID) { 953 Parent2::graph->first(*static_cast<Graph2Edge*>(&i)); 954 i.backward=true; 955 } 956 } 957 void firstIn(Edge& i, const Node& n) const { 958 Parent1::graph->firstIn(*static_cast<Graph1Edge*>(&i), n); 959 i.backward=false; 960 if (*static_cast<Graph1Edge*>(&i)==INVALID) { 961 Parent2::graph->firstIn(*static_cast<Graph2Edge*>(&i), n); 962 i.backward=true; 963 } 964 } 965 void firstOut(Edge& i, const Node& n) const { 966 Parent1::graph->firstOut(*static_cast<Graph1Edge*>(&i), n); 967 i.backward=false; 968 if (*static_cast<Graph1Edge*>(&i)==INVALID) { 969 Parent2::graph->firstOut(*static_cast<Graph2Edge*>(&i), n); 970 i.backward=true; 971 } 972 } 973 974 using Parent::next; 975 void next(Edge& i) const { 976 if (!(i.backward)) { 977 Parent1::graph->next(*static_cast<Graph1Edge*>(&i)); 978 if (*static_cast<Graph1Edge*>(&i)==INVALID) { 979 Parent2::graph->first(*static_cast<Graph2Edge*>(&i)); 980 i.backward=true; 981 } 982 } else { 983 Parent2::graph->next(*static_cast<Graph2Edge*>(&i)); 984 } 985 } 986 void nextIn(Edge& i) const { 987 if (!(i.backward)) { 988 Parent1::graph->nextIn(*static_cast<Graph1Edge*>(&i)); 989 if (*static_cast<Graph1Edge*>(&i)==INVALID) { 990 Parent2::graph->first(*static_cast<Graph2Edge*>(&i)); 991 i.backward=true; 992 } 993 } else { 994 Parent2::graph->nextIn(*static_cast<Graph2Edge*>(&i)); 995 } 996 } 997 void nextOut(Edge& i) const { 998 if (!(i.backward)) { 999 Parent1::graph->nextOut(*static_cast<Graph1Edge*>(&i)); 1000 if (*static_cast<Graph1Edge*>(&i)==INVALID) { 1001 Parent2::graph->first(*static_cast<Graph2Edge*>(&i)); 1002 i.backward=true; 1003 } 1004 } else { 1005 Parent2::graph->nextOut(*static_cast<Graph2Edge*>(&i)); 1006 } 1007 } 1008 1009 Node source(const Edge& i) const { 1010 if (!(i.backward)) { 1011 return 1012 Node(Parent1::graph->source(i), INVALID, false); 1013 } else { 1014 return 1015 Node(INVALID, Parent2::graph->source(i), true); 1016 } 1017 } 1018 1019 Node target(const Edge& i) const { 1020 if (!(i.backward)) { 1021 return 1022 Node(Parent1::graph->target(i), INVALID, false); 1023 } else { 1024 return 1025 Node(INVALID, Parent2::graph->target(i), true); 1026 } 1027 } 1028 1029 using Parent::id; 1030 int id(const Edge& n) const { 1031 if (!n.backward) 1032 return this->Parent1::graph->id(n); 1033 else 1034 return this->Parent2::graph->id(n); 1035 } 1036 1037 template <typename _Value> 1038 class EdgeMap { 1039 protected: 1040 typedef typename Parent::Graph1::template EdgeMap<_Value> ParentMap1; 1041 typedef typename Parent::Graph2::template EdgeMap<_Value> ParentMap2; 1042 ParentMap1 forward_map; 1043 ParentMap2 backward_map; 1044 public: 1045 typedef _Value Value; 1046 typedef Edge Key; 1047 EdgeMap(const MergeEdgeGraphWrapperBase<_Graph1, _Graph2>& gw) : 1048 forward_map(*(gw.Parent1::graph)), 1049 backward_map(*(gw.Parent2::graph)) { } 1050 EdgeMap(const MergeEdgeGraphWrapperBase<_Graph1, _Graph2>& gw, 1051 const _Value& value) : 1052 forward_map(*(gw.Parent1::graph), value), 1053 backward_map(*(gw.Parent2::graph), value) { } 1054 _Value operator[](const Edge& n) const { 1055 if (!n.backward) 1056 return forward_map[n]; 1057 else 1058 return backward_map[n]; 1059 } 1060 void set(const Edge& n, const _Value& value) { 1061 if (!n.backward) 1062 forward_map.set(n, value); 1063 else 1064 backward_map.set(n, value); 1065 } 1066 // using ParentMap1::operator[]; 1067 // using ParentMap2::operator[]; 1068 }; 1069 1070 }; 1071 1072 1073 /*! A grah wrapper base class 1074 for merging the node-sets and edge-sets of 1075 two node-disjoint graphs 1076 into one graph. 1077 Specialized implementation for the case 1078 when _Graph1::Edge is derived from _Graph2::Edge. 1079 */ 1080 template <typename _Graph1, typename _Graph2> 1081 class MergeEdgeGraphWrapperBase< 1082 _Graph1, _Graph2, typename boost::enable_if< 1083 boost::is_base_and_derived<typename _Graph2::Edge, typename _Graph1::Edge> >::type> : 1084 public MergeNodeGraphWrapperBase<_Graph1, _Graph2> { 1085 public: 1086 static void printEdge() { std::cout << "edge: 1st is derived" << std::endl; } 1087 typedef _Graph1 Graph1; 1088 typedef _Graph2 Graph2; 1089 typedef MergeNodeGraphWrapperBase<_Graph1, _Graph2> Parent; 1090 typedef typename Parent::Parent1 Parent1; 1091 typedef typename Parent::Parent2 Parent2; 1092 // typedef P1<_Graph1> Parent1; 1093 // typedef P2<_Graph2> Parent2; 1094 typedef typename Parent1::Edge Graph1Edge; 1095 typedef typename Parent2::Edge Graph2Edge; 1096 protected: 1097 MergeEdgeGraphWrapperBase() { } 1098 public: 1099 template <typename _Value> class EdgeMap; 1100 1101 typedef typename Parent::Node Node; 1102 1103 class Edge : public Graph1Edge { 1104 friend class MergeEdgeGraphWrapperBase<_Graph1, _Graph2>; 1105 template <typename _Value> friend class EdgeMap; 1106 protected: 1107 bool backward; //true, iff backward 1108 public: 1109 Edge() { } 1110 /// \todo =false is needed, or causes problems? 1111 /// If \c _backward is false, then we get an edge corresponding to the 1112 /// original one, otherwise its oppositely directed pair is obtained. 1113 Edge(const Graph1Edge& n1, 1114 const Graph2Edge& n2, bool _backward) : 1115 Graph1Edge(n1), backward(_backward) { 1116 if (backward) *this=n2; 1117 } 1118 Edge(Invalid i) : Graph1Edge(i), backward(true) { } 1119 bool operator==(const Edge& v) const { 1120 if (backward) 1121 return (v.backward && 1122 static_cast<Graph2Edge>(*this)==static_cast<Graph2Edge>(v)); 1123 else 1124 return (!v.backward && 1125 static_cast<Graph1Edge>(*this)==static_cast<Graph1Edge>(v)); 1126 } 1127 bool operator!=(const Edge& v) const { 1128 return !(*this==v); 1129 } 1130 }; 1131 1132 using Parent::first; 1133 void first(Edge& i) const { 1134 Parent1::graph->first(*static_cast<Graph1Edge*>(&i)); 1135 i.backward=false; 1136 if (*static_cast<Graph1Edge*>(&i)==INVALID) { 1137 Parent2::graph->first(*static_cast<Graph2Edge*>(&i)); 1138 i.backward=true; 1139 } 1140 } 1141 void firstIn(Edge& i, const Node& n) const { 1142 Parent1::graph->firstIn(*static_cast<Graph1Edge*>(&i), n); 1143 i.backward=false; 1144 if (*static_cast<Graph1Edge*>(&i)==INVALID) { 1145 Parent2::graph->firstIn(*static_cast<Graph2Edge*>(&i), n); 1146 i.backward=true; 1147 } 1148 } 1149 void firstOut(Edge& i, const Node& n) const { 1150 Parent1::graph->firstOut(*static_cast<Graph1Edge*>(&i), n); 1151 i.backward=false; 1152 if (*static_cast<Graph1Edge*>(&i)==INVALID) { 1153 Parent2::graph->firstOut(*static_cast<Graph2Edge*>(&i), n); 1154 i.backward=true; 1155 } 1156 } 1157 1158 using Parent::next; 1159 void next(Edge& i) const { 1160 if (!(i.backward)) { 1161 Parent1::graph->next(*static_cast<Graph1Edge*>(&i)); 1162 if (*static_cast<Graph1Edge*>(&i)==INVALID) { 1163 Parent2::graph->first(*static_cast<Graph2Edge*>(&i)); 1164 i.backward=true; 1165 } 1166 } else { 1167 Parent2::graph->next(*static_cast<Graph2Edge*>(&i)); 1168 } 1169 } 1170 void nextIn(Edge& i) const { 1171 if (!(i.backward)) { 1172 Parent1::graph->nextIn(*static_cast<Graph1Edge*>(&i)); 1173 if (*static_cast<Graph1Edge*>(&i)==INVALID) { 1174 Parent2::graph->first(*static_cast<Graph2Edge*>(&i)); 1175 i.backward=true; 1176 } 1177 } else { 1178 Parent2::graph->nextIn(*static_cast<Graph2Edge*>(&i)); 1179 } 1180 } 1181 void nextOut(Edge& i) const { 1182 if (!(i.backward)) { 1183 Parent1::graph->nextOut(*static_cast<Graph1Edge*>(&i)); 1184 if (*static_cast<Graph1Edge*>(&i)==INVALID) { 1185 Parent2::graph->first(*static_cast<Graph2Edge*>(&i)); 1186 i.backward=true; 1187 } 1188 } else { 1189 Parent2::graph->nextOut(*static_cast<Graph2Edge*>(&i)); 1190 } 1191 } 1192 1193 Node source(const Edge& i) const { 1194 if (!(i.backward)) { 1195 return 1196 Node(Parent1::graph->source(i), INVALID, false); 1197 } else { 1198 return 1199 Node(INVALID, Parent2::graph->source(i), true); 1200 } 1201 } 1202 1203 Node target(const Edge& i) const { 1204 if (!(i.backward)) { 1205 return 1206 Node(Parent1::graph->target(i), INVALID, false); 1207 } else { 1208 return 1209 Node(INVALID, Parent2::graph->target(i), true); 1210 } 1211 } 1212 1213 using Parent::id; 1214 int id(const Edge& n) const { 1215 if (!n.backward) 1216 return this->Parent1::graph->id(n); 1217 else 1218 return this->Parent2::graph->id(n); 1219 } 1220 1221 template <typename _Value> 1222 class EdgeMap { 1223 protected: 1224 typedef typename Parent::Graph1::template EdgeMap<_Value> ParentMap1; 1225 typedef typename Parent::Graph2::template EdgeMap<_Value> ParentMap2; 1226 ParentMap1 forward_map; 1227 ParentMap2 backward_map; 1228 public: 1229 typedef _Value Value; 1230 typedef Edge Key; 1231 EdgeMap(const MergeEdgeGraphWrapperBase<_Graph1, _Graph2>& gw) : 1232 forward_map(*(gw.Parent1::graph)), 1233 backward_map(*(gw.Parent2::graph)) { } 1234 EdgeMap(const MergeEdgeGraphWrapperBase<_Graph1, _Graph2>& gw, 1235 const _Value& value) : 1236 forward_map(*(gw.Parent1::graph), value), 1237 backward_map(*(gw.Parent2::graph), value) { } 1238 _Value operator[](const Edge& n) const { 1239 if (!n.backward) 1240 return forward_map[n]; 1241 else 1242 return backward_map[n]; 1243 } 1244 void set(const Edge& n, const _Value& value) { 1245 if (!n.backward) 1246 forward_map.set(n, value); 1247 else 1248 backward_map.set(n, value); 1249 } 1250 // using ParentMap1::operator[]; 1251 // using ParentMap2::operator[]; 1252 }; 1253 1254 }; 1255 1256 703 1257 /*! A graph wrapper class 704 1258 for merging the node-sets and edge-sets of -
src/work/marci/merge_node_graph_wrapper_test.cc
r1013 r1016 49 49 MergeEdgeGraphWrapper<Graph1, Graph1>::printNode(); 50 50 MergeEdgeGraphWrapper<Graph1, Graph1>::printEdge(); 51 typedef ResGraphWrapper<Graph1, int, 52 ConstMap<Graph1, int>, ConstMap<Graph1, int> > Graph4; 53 checkConcept<StaticGraph, MergeEdgeGraphWrapper<Graph1, Graph4> >(); 54 MergeEdgeGraphWrapper<Graph1, Graph4>::printNode(); 55 MergeEdgeGraphWrapper<Graph1, Graph4>::printEdge(); 56 checkConcept<StaticGraph, MergeEdgeGraphWrapper<Graph4, Graph1> >(); 57 MergeEdgeGraphWrapper<Graph4, Graph1>::printNode(); 58 MergeEdgeGraphWrapper<Graph4, Graph1>::printEdge(); 51 59 } 52 60 … … 119 127 120 128 typedef ListGraph Graph3; 129 //typedef SmartGraph Graph3; 121 130 Graph3 g3; 122 131 GW::NodeMap<Graph3::Node> gwn(gw);
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