Fix: changed logic in modified-postOrderTraversal to match default

postOrderTraversal Refactor: make postOrderTraversal functions single responsibility only
2024-02-20 17:00:51 +09:00 · 2024-02-20 17:00:51 +09:00 · 54b51b002d
parent 00ce484c58
commit 54b51b002d
6 changed files with 121 additions and 134 deletions
--- a/README.md
+++ b/README.md
@ -0,0 +1 @@
 This branch tests the idea of using fuzzing to choose the direction of mutation
--- a/deferred_planarity_test/include/mps.h
+++ b/deferred_planarity_test/include/mps.h
@ -153,10 +153,12 @@ public:
 	node* get_new_node(node_type t);
    void read_from_gml(string input_file);
 	int output_removed_edge_size();
-	vector<int> postOrderTraversal();
+    vector<int> return_post_order();
-	vector<int> mutatedPostOrderTraversal(vector<int> post_order);
+	void postOrderTraversal();
 	void guidedPostOrderTraversal(vector<int> post_order);
-    void set_post_order(vector<int> post_order);
+	void mutatedPostOrderTraversal(vector<int> post_order);
    // void set_post_order(vector<int> post_order);
    void print_post_order();
 	void sort_adj_list();
 	void determine_edges();
 	void back_edge_traversal();
--- a/deferred_planarity_test/src/main.cpp
+++ b/deferred_planarity_test/src/main.cpp
@ -22,43 +22,25 @@ int compute_removed_edge_size(string input_file, vector<int> post_order);
 vector<int> generate_post_order(string input_file);
 vector<int> generate_mutated_post_order(string input_file, vector<int> post_order);
 double temp_decay(int k, int k_max) {
    return 1.0 - ((k + 1.0) / (k_max));
 }
-vector<int> sa_solve(string input_file, int k_max) {
+vector<int> repeated_mutation(string input_file, int k_max) {
    // create sampling function
    std::random_device rd;
    std::mt19937 rng(rd());
    std::uniform_real_distribution<> distribution(0.0, 1.0);
    // generate first state
    vector<int> state_old = generate_post_order(input_file);
    vector<int> state_new;
-    int e_old = compute_removed_edge_size(input_file, state_old);
+    int num_removed_edges;
    int e_new = 0;
    int delta = 0;
    // initialize terms
    double temp;
    for (int k = 0; k < k_max; ++k) {
        temp = START_TEMP * temp_decay(k, k_max);
        state_new = generate_mutated_post_order(input_file, state_old);
-        e_new = compute_removed_edge_size(input_file, state_new);
+        num_removed_edges = compute_removed_edge_size(input_file, state_new);
        delta = e_new - e_old;
        if (std::exp( -(delta) / temp) > distribution(rng)) {
            state_old = state_new; 
            e_old = e_new;
    }
    return state_new;
 }
-    return state_old;
+void test_correctness(string input_file) {
-
+    vector<int> state_old = generate_post_order(input_file);
    int num_removed_edges;
    num_removed_edges = compute_removed_edge_size(input_file, state_old);
 }
 int get_graph_size(string input_file) {
    ogdf::Graph G;
@ -80,14 +62,15 @@ int main(int argc, char* argv[]) {
    int k_max = std::stoi(argv[2]);
    // generate order here
-    vector<int> post_order = sa_solve(input_file, k_max);
+    // vector<int> post_order = repeated_mutation(input_file, k_max);
    test_correctness(input_file);
-    // std::copy(post_order.begin(), post_order.end(), std::ostream_iterator<int>(std::cout, " "));
+    // // print final order and number of edges
    // // print post_order
    // std::copy(post_order.begin(), post_order.end(), std::ostream_iterator<int>(std::cout, ","));
    // std::cout << std::endl;
-
+    // int removed_edges = compute_removed_edge_size(input_file, post_order);
-    // print order
+    // std::cout << "Number of removed edges: " << removed_edges << std::endl;
    int removed_edges = compute_removed_edge_size(input_file, post_order);
    std::cout << "Number of removed edges: " << removed_edges << std::endl;
 	return 0;
 }
--- a/deferred_planarity_test/src/mps.cpp
+++ b/deferred_planarity_test/src/mps.cpp
@ -3,6 +3,9 @@
 //-----------------------------------------------------------------------------------
 #include "mps.h"
 #include <iterator>
 // #define DEBUG
 // constructor can be made empty
 maximal_planar_subgraph_finder::maximal_planar_subgraph_finder() {}
@ -19,17 +22,8 @@ maximal_planar_subgraph_finder::get_new_node(node_type t) {
 	return _new_node_list[_new_node_list.size()-1];
 }
 //Determine the post-order-list by a DFS-traversal.
 vector<int>
-maximal_planar_subgraph_finder::postOrderTraversal() {
+maximal_planar_subgraph_finder::return_post_order() {
 	node::init_mark();
 	int postOrderID = 0;
 	for (int i = 0; i < _node_list.size(); ++i) {
 		if (!_node_list[i]->is_marked()) {
 			_node_list[i]->DFS_visit(_post_order_list, postOrderID);
 		}
 	}
    vector<int> post_order;
    for (int i = 0; i < _post_order_list.size(); ++i) {
        post_order.push_back(_post_order_list[i]->node_id());
@ -37,8 +31,23 @@ maximal_planar_subgraph_finder::postOrderTraversal() {
    return post_order;
 }
 //Determine the post-order-list by a DFS-traversal.
 void
 maximal_planar_subgraph_finder::postOrderTraversal() {
 	node::init_mark();
    // always start with node 0
 	int postOrderID = 0;
 	for (int i = 0; i < _node_list.size(); ++i) {
 		if (!_node_list[i]->is_marked()) {
 			_node_list[i]->DFS_visit(_post_order_list, postOrderID);
 		}
 	}
 }
 // Determine the post-order-list by a DFS-traversal.
 // take in a post-order argument then traces the graph in the same order
 // return is by reference via _post_order_list
 void 
 maximal_planar_subgraph_finder::guidedPostOrderTraversal(vector<int> post_order) {
 	node::init_mark();
@ -62,7 +71,6 @@ maximal_planar_subgraph_finder::guidedPostOrderTraversal(vector<int> post_order)
            }
            break;
        }
        // std::cout << _node_list[i]->node_id() << ", " << !_node_list[i]->is_marked() << std::endl;
        if (!_node_list[i]->is_marked())
        {
            _node_list[i]->guided_DFS_visit(_post_order_list, _node_list, postOrderID, rev_post_order);
@ -72,7 +80,9 @@ maximal_planar_subgraph_finder::guidedPostOrderTraversal(vector<int> post_order)
 }
 //Determine the post-order-list by a DFS-traversal.
-vector<int> 
+// take in a post-order argument then traces the graph in the same order
 // return is by reference via _post_order_list
 void
 maximal_planar_subgraph_finder::mutatedPostOrderTraversal(vector<int> post_order) {
 	node::init_mark();
@ -105,6 +115,8 @@ maximal_planar_subgraph_finder::mutatedPostOrderTraversal(vector<int> post_order
    int end_condition = _node_list.size();
    // this loop assumes start is not from 0
    // if starting index is not 0, it just increments and loops around until it encounters the element before it
    while (true)
    {
        if (((start > 0) && (i == (start - 1))) || ((start == 0 ) && (i == end_condition - 1)))
@ -115,35 +127,34 @@ maximal_planar_subgraph_finder::mutatedPostOrderTraversal(vector<int> post_order
            }
            break;
        }
        // std::cout << _node_list[i]->node_id() << ", " << !_node_list[i]->is_marked() << std::endl;
        if (!_node_list[i]->is_marked())
        {
            _node_list[i]->mutated_DFS_visit(_post_order_list, _node_list, postOrderID, rev_post_order, mutate_point);
        }
        i = (i + 1) % end_condition;
    }
    vector<int> return_order;
    for (int i = 0; i < _post_order_list.size(); ++i) {
        return_order.push_back(_post_order_list[i]->node_id());
 }
    // we have to reverse the order as we add to list in the forward direction of recursion
    // unlike that of previous methods where we add to list in the return direction of recursion
    std::reverse(return_order.begin(), return_order.end());
    return return_order;
 }
 //Set the post-order-list via given list
 void
-maximal_planar_subgraph_finder::set_post_order(vector<int> post_order) {
+maximal_planar_subgraph_finder::print_post_order() {
-    for (int i = 0; i < _node_list.size(); ++i) {
+    int current_index;
-        _node_list[i]->set_post_order_index(post_order[i]);
+    for (int i = 0; i < _post_order_list.size(); ++i) {
        current_index = _post_order_list[i]->node_id();
        std::cout << current_index << ",";
    }
    std::cout << std::endl;
 }
 // this function is not used anywhere
 //Set the post-order-list via given list
 // void
 // maximal_planar_subgraph_finder::set_post_order(vector<int> post_order) {
 //     for (int i = 0; i < _node_list.size(); ++i) {
 //         _node_list[i]->set_post_order_index(post_order[i]);
 //     }
 // }
 //Sort the adj-list of every node increasingly according to post-order-index.
 void
 maximal_planar_subgraph_finder::sort_adj_list() {
--- a/deferred_planarity_test/src/mps_test.cpp
+++ b/deferred_planarity_test/src/mps_test.cpp
@ -5,6 +5,8 @@
 #include "mps.h"
 #include <ogdf/fileformats/GraphIO.h>
 #define DEBUG
 //-----------------------------------------------------------------------------------
 // Finding MPS
 //-----------------------------------------------------------------------------------
@ -37,6 +39,11 @@ vector<int> generate_mutated_post_order(string input_file, vector<int> post_orde
 int maximal_planar_subgraph_finder::find_mps(string input_file) {
 	read_from_gml(input_file);
 	postOrderTraversal();
    #ifdef DEBUG
    print_post_order();
    #endif
 	sort_adj_list();
 	determine_edges();
 	back_edge_traversal();
@ -45,12 +52,25 @@ int maximal_planar_subgraph_finder::find_mps(string input_file) {
 vector<int> maximal_planar_subgraph_finder::generate_post_order(string input_file) {
    read_from_gml(input_file);
-    return postOrderTraversal();
+    postOrderTraversal();
    #ifdef DEBUG
    print_post_order();
    #endif
    return return_post_order();
 }
 // result of this will be used as input to "compute_removed_edge_size"
 vector<int> maximal_planar_subgraph_finder::generate_mutated_post_order(string input_file, vector<int> post_order) {
    read_from_gml(input_file);
-    return mutatedPostOrderTraversal(post_order);
+    mutatedPostOrderTraversal(post_order);
    #ifdef DEBUG
    print_post_order();
    #endif
    return return_post_order();
 }
@ -58,18 +78,14 @@ int maximal_planar_subgraph_finder::compute_removed_edge_size(string input_file,
 	read_from_gml(input_file);
    guidedPostOrderTraversal(post_order);
-    // let's reverse the order
+    // set post_order_index
    std::reverse(_post_order_list.begin(), _post_order_list.end());
    // then set post_order_index
    for (int i = 0; i < _post_order_list.size(); ++i) {
        _node_list[_post_order_list[i]->node_id()]->set_post_order_index(i);
    }
-    // std::cout << "check order of duplicated traversal" << std::endl;
+    #ifdef DEBUG
-    // for (int i = 0; i < _post_order_list.size(); ++i) {
+    print_post_order();
-    //     std::cout << _post_order_list[i]->node_id() << " ";
+    #endif
    // }
    // std::cout << std::endl;
 	sort_adj_list();
 	determine_edges();
--- a/deferred_planarity_test/src/node.cpp
+++ b/deferred_planarity_test/src/node.cpp
@ -4,6 +4,8 @@
 #include "mps.h"
 // #define DEBUG
 //-----------------------------------------------------------------------------------
 // CONSTRUCTOR
 //-----------------------------------------------------------------------------------
@ -69,32 +71,17 @@ void node::DFS_visit(vector<node*> &dfsList, int &index) {
 void node::guided_DFS_visit(vector<node*> &dfsList, vector<node*> &node_list, int &index, vector<int> rev_post_order) {
 	mark();
-    // you will want to sort the neighbor nodes by the order they appear in the rev_post_order
+
    // purpose of this block: create list of neighbors
    vector<node *> neighbor_list;
    std::unordered_set<int> neighbor_set; 
    // create an unordered set to efficiently check for presence of an element
    for (int i = 0; i < _adj_list.size(); ++i) {
-        neighbor_set.insert(_adj_list[i]->node_id());
+        // we get the neighbors via _adj_list
        // we get the id's of the neighbor nodes, then we use the id's to get the actual nodes via node_list
        // node_list maps id to the actual node
        neighbor_list.push_back(node_list[_adj_list[i]->node_id()]);
    }
    // when an element in rev_post_order is found in neighbor_set, we add that to neighbor_list
    for (int i = 0; i < rev_post_order.size(); ++i) {
        if (neighbor_set.find(rev_post_order[i]) != neighbor_set.end()) {
            neighbor_list.push_back(node_list[rev_post_order[i]]);
        }
    }
    // print the neighbors
    // std::cout << "current index: " << this->node_id() << std::endl;
    // for (int i = 0; i < neighbor_list.size(); ++i) {
    //     std::cout << neighbor_list[i]->node_id() << " ";
    // }
    // std::cout << std::endl;
 	set_post_order_index(index);
 	dfsList.push_back(this);
 	++index;
 	for (int i = 0; i < neighbor_list.size(); ++i) {
 		if (!neighbor_list[i]->is_marked()) {
@ -102,38 +89,29 @@ void node::guided_DFS_visit(vector<node*> &dfsList, vector<node*> &node_list, in
 			neighbor_list[i]->guided_DFS_visit(dfsList, node_list, index, rev_post_order);
 		}
 	}
 }
 void node::mutated_DFS_visit(vector<node*> &dfsList, vector<node*> &node_list, int &index, vector<int> rev_post_order, int &mutate_point) {
 	mark();
    // you will want to sort the neighbor nodes by the order they appear in the rev_post_order
    vector<node *> neighbor_list;
    std::unordered_set<int> neighbor_set; 
    // create an unordered set to efficiently check for presence of an element
    for (int i = 0; i < _adj_list.size(); ++i) {
        neighbor_set.insert(_adj_list[i]->node_id());
    }
    // when an element in rev_post_order is found in neighbor_set, we add that to neighbor_list
    for (int i = 0; i < rev_post_order.size(); ++i) {
        if (neighbor_set.find(rev_post_order[i]) != neighbor_set.end()) {
            neighbor_list.push_back(node_list[rev_post_order[i]]);
        }
    }
    // print the neighbors
    // std::cout << "current index: " << this->node_id() << std::endl;
    // for (int i = 0; i < neighbor_list.size(); ++i) {
    //     std::cout << neighbor_list[i]->node_id() << " ";
    // }
    // std::cout << std::endl;
    set_post_order_index(index);
 	dfsList.push_back(this);
 	++index;
 }
 void node::mutated_DFS_visit(vector<node*> &dfsList, vector<node*> &node_list, int &index, vector<int> rev_post_order, int &mutate_point) {
    // mark current node
 	mark();
    // purpose of this block: create list of neighbors
    vector<node *> neighbor_list;
    for (int i = 0; i < _adj_list.size(); ++i) {
        // we get the neighbors via _adj_list
        // we get the id's of the neighbor nodes, then we use the id's to get the actual nodes via node_list
        // node_list maps id to the actual node
        neighbor_list.push_back(node_list[_adj_list[i]->node_id()]);
    }
    // since we increment the index before this line, the current index is "index - 1"
    // if the current index matches the mutate_point, then we know this is the cycle to mutate
    if (index - 1 == mutate_point) {
        // Create a random number generator and seed it
        // std::cout << "mutated at index: " << index - 1<< "and at mutate point: " << mutate_point << std::endl;
@ -141,14 +119,6 @@ void node::mutated_DFS_visit(vector<node*> &dfsList, vector<node*> &node_list, i
        std::mt19937 rng(rd());
        // Use std::shuffle to shuffle the elements in the vector
        std::shuffle(neighbor_list.begin(), neighbor_list.end(), rng);
        // // print the neighbors
        // std::cout << "order after mutation: " << std::endl;
        // std::cout << "current index: " << this->node_id() << std::endl;
        // for (int i = 0; i < neighbor_list.size(); ++i)
        // {
        //     std::cout << neighbor_list[i]->node_id() << " ";
        // }
        // std::cout << std::endl;
    } 
    for (int i = 0; i < neighbor_list.size(); ++i)
@ -159,6 +129,10 @@ void node::mutated_DFS_visit(vector<node*> &dfsList, vector<node*> &node_list, i
            neighbor_list[i]->mutated_DFS_visit(dfsList, node_list, index, rev_post_order, mutate_point);
        }
    }
 	set_post_order_index(index);
 	dfsList.push_back(this);
 	++index;
 }
		`@ -0,0 +1 @@`
							`This branch tests the idea of using fuzzing to choose the direction of mutation`