/*############################################################################## ## Author: Shaun Reed ## ## Legal: All Content (c) 2022 Shaun Reed, all rights reserved ## ## About: Driver program to test object graph implementation ## ## ## ## Contact: shaunrd0@gmail.com | URL: www.shaunreed.com | GitHub: shaunrd0 ## ################################################################################ */ #include "lib-graph.hpp" int main (const int argc, const char * argv[]) { // We could initialize the graph with some localNodes... std::vector localNodes{ {1, {2, 5}}, // Node 1 {2, {1, 6}}, // Node 2 {3, {4, 6, 7}}, {4, {3, 7, 8}}, {5, {1}}, {6, {2, 3, 7}}, {7, {3, 4, 6, 8}}, {8, {4, 6}}, }; Graph bfsGraphInit(localNodes); std::cout << "\n\n##### Breadth First Search #####\n"; // Or we could use an initializer list... // Initialize a example graph for Breadth First Search Graph bfsGraph( { {1, {2, 5}}, // Node 1 {2, {1, 6}}, // Node 2... {3, {4, 6, 7}}, {4, {3, 7, 8}}, {5, {1}}, {6, {2, 3, 7}}, {7, {3, 4, 6, 8}}, {8, {4, 6}}, } ); // The graph traversed in this example is seen in MIT Intro to Algorithms // + Chapter 22, Figure 22.3 on BFS bfsGraph.BFS(bfsGraph.GetNodeCopy(2)); std::cout << "\nTesting finding a path between two nodes using BFS...\n"; // Test finding a path between two nodes using BFS auto path = bfsGraph.PathBFS( bfsGraph.GetNodeCopy(1), bfsGraph.GetNodeCopy(7) ); // If we were returned an empty path, it doesn't exist if (path.empty()) std::cout << "No valid path found!\n"; else { // If we were returned a path, print it std::cout << "\nValid path from " << path.front().number << " to " << path.back().number << ": "; for (const auto &node : path) { std::cout << node.number << " "; } std::cout << std::endl; } std::cout << "\n\n##### Depth First Search #####\n"; // Initialize an example graph for Depth First Search Graph dfsGraph( { {1, {2, 4}}, {2, {5}}, {3, {5, 6}}, {4, {2}}, {5, {4}}, {6, {6}}, } ); // The graph traversed in this example is seen in MIT Intro to Algorithms // + Chapter 22, Figure 22.4 on DFS dfsGraph.DFS(); std::cout << "\n\n##### Topological Sort #####\n"; // Initialize an example graph for Depth First Search // + The order of initialization is important // + To produce the same result as seen in the book // ++ If the order is changed, other valid topological orders will be found // The book starts on the 'shirt' node (with the number 6, in this example) Graph topologicalGraph ( { {1, {4, 5}}, // undershorts {2, {5}}, // socks {3, {}}, // watch {4, {5, 7}}, // pants {5, {}}, // shoes {6, {8, 7}}, // shirt {7, {9}}, // belt {8, {9}}, // tie {9, {}}, // jacket } ); // The graph traversed in this example is seen in MIT Intro to Algorithms // + Chapter 22, Figure 22.4 on DFS // Unlike the simple-graph example, this final result matches MIT Algorithms // + Aside from the placement of the watch node, which is not connected // + This is because the node is visited after all other nodes are finished std::vector order = topologicalGraph.TopologicalSort(topologicalGraph.GetNodeCopy(6)); std::cout << "\nTopological order: "; while (!order.empty()) { std::cout << order.back().number << " "; order.pop_back(); } std::cout << std::endl << std::endl; // If we want the topological order to match what is seen in the book // + We have to initialize the graph carefully to get this result - Graph topologicalGraph2 ( { {6, {8, 7}}, // shirt {8, {9}}, // tie {7, {9}}, // belt {9, {}}, // jacket {3, {}}, // watch {1, {4, 5}}, // undershorts {4, {5, 7}}, // pants {5, {}}, // shoes {2, {5}}, // socks } ); auto order2 = topologicalGraph2.TopologicalSort(*topologicalGraph2.NodeBegin()); std::cout << "\nTopological order: "; while (!order2.empty()) { std::cout << order2.back().number << " "; order2.pop_back(); } std::cout << std::endl; }