MySources/topologyenumerator.hpp

#ifndef TOPOLOGYENUMERATOR_HPP
#define TOPOLOGYENUMERATOR_HPP
#include "patternIO.hpp"
#include "trianglepatterngeometry.hpp"
#include "trianglepattterntopology.hpp"
#include <filesystem>
#include <fstream>
#include <iostream>
//#include <nlohmann/json.hpp>
#include <string>
#include <vector>

using GraphEdge = std::pair<size_t, size_t>;
/*
 * Represents a graph formed by slots on a triangle that can either be filled or
 * not. The slots are three and are: 1) one slot per vertex. Each slot can hold
 * a signle node. 2) one slot per edge. Each slot can hold many nodes. 3) one
 * slot in the inside of the triangle. Each slot can hold multiple nodes.
 * */
class TopologyEnumerator {
  /*
   * Holds the in a CCW order the vertex and the edge slots and then the face
   * slot. [0],[1],[2] can either be 0 or 1 [3],[4],[5] are integers in [0,n]
   * [6] an integer [0,n]
   * */

  /*
   reduced nodes per slot
        0
       /\
      /  \
     2    2
    /  4   \
   /        \
  1----3-----1

  nodes per slot
        0
       /\
      /  \
     3    5
    /  6   \
   /        \
  1----4-----2

  slot=0 -> vi=0
  slot=1 -> vi=1
  slot=2 -> vi=2
  ...
  see TrianglePatternGeometry::constructVertexVector

      */
  struct TopologicalStatistics {
    size_t numberOfPossibleEdges{0};
    size_t numberOfCoincideEdges{0};
    size_t numberOfDuplicateEdges{0};
    size_t numberOfValidEdges{0};
    size_t numberOfIntersectingEdgePairs{0};
    size_t numberOfPatterns{0};
    //    size_t numberOfIntersectingEdgesOverAllPatterns{0};
    size_t numberOfPatternsWithIntersectingEdges{0};
    size_t numberOfPatternsWithMoreThanASingleCC{0};
    size_t numberOfPatternsWithADanglingEdgeOrNode{0};
    size_t numberOfPatternsWithArticulationPoints{0};
    size_t numberOfValidPatterns{0};
    //    nlohmann::json convertToJson() const {
    //      nlohmann::json json;
    //      json["numPossibleEdges"] = numberOfPossibleEdges;
    //      json["numCoincideEdges"] = numberOfCoincideEdges;
    //      json["numDuplicateEdges"] = numberOfDuplicateEdges;
    //      json["numValidEdges"] = numberOfValidEdges;
    //      json["numIntersectingEdgePairs"] = numberOfIntersectingEdgePairs;
    //      json["numPatterns"] = numberOfPatterns;
    //      //      json["numIntersectingEdgesOverAllPatterns"] =
    //      //          numberOfIntersectingEdgesOverAllPatterns;
    //      json["numPatternsWithIntersectingEdges"] =
    //          numberOfPatternsWithIntersectingEdges;
    //      json["numPatternsWithNotASingleCC"] =
    //          numberOfPatternsWithMoreThanASingleCC;
    //      json["numPatternsWithDangling"] =
    //      numberOfPatternsWithADanglingEdgeOrNode;
    //      json["numPatternsWithArticulationPoints"] =
    //          numberOfPatternsWithArticulationPoints;
    //      json["numValidPatterns"] = numberOfValidPatterns;

    //      return json;
    //    }
    void print(const std::string &setupString,
               const std::filesystem::path &directoryPath) const {
      std::cout << "The setup " << setupString << std::endl;
      std::cout << "Has following statistics:" << std::endl;
      std::cout << numberOfPossibleEdges
                << " possible edges with the given arrangement of nodes"
                << std::endl;
      std::cout << numberOfCoincideEdges << " coincide edges" << std::endl;
      std::cout << numberOfDuplicateEdges << " duplicate edges" << std::endl;
      std::cout << numberOfValidEdges << " valid edges" << std::endl;
      std::cout << numberOfIntersectingEdgePairs << "intersecting edge pairs "
                << std::endl;
      std::cout << numberOfPatterns
                << " patterns can be generated with the given setup"
                << std::endl;
      //      std::cout << numberOfIntersectingEdgesOverAllPatterns
      //                << " intersecting edges found over all patterns" <<
      //                std::endl;
      std::cout << numberOfPatternsWithIntersectingEdges
                << " patterns found with intersecting edges" << std::endl;
      std::cout << numberOfPatternsWithMoreThanASingleCC
                << " patterns found with more than one connected components"
                << std::endl;
      std::cout << numberOfPatternsWithADanglingEdgeOrNode
                << " patterns found with a dangling node or edge" << std::endl;
      std::cout << numberOfPatternsWithArticulationPoints
                << " patterns found with an articulation point" << std::endl;
      std::cout << numberOfValidPatterns << " valid patterns were found"
                << std::endl;
      //      if (!directoryPath.empty()) {
      //        auto json = convertToJson();

      //        std::ofstream file;
      //        file.open(std::filesystem::path(directoryPath)
      //                      .append("statistics.csv")
      //                      .string());
      //        file << "setup," << setupString << "\n";
      //        for (const auto &el : json.items()) {
      //          file << el.key() << "," << el.value() << "\n";
      //        }
      //      }
    }
  };

  TopologicalStatistics statistics;
  std::vector<size_t> numberOfNodesPerSlot;
  size_t numberOfNodes;

  size_t
  computeCoincideEdges(const std::vector<size_t> &numberOfNodesPerSlot) const;
  size_t computeNumberOfPossibleEdges(
      const std::vector<size_t> &numberOfNodesPerSlot) const;

  void createLabelMesh(const std::vector<vcg::Point3d> vertices,
                       const std::filesystem::path &savePath) const;
  size_t getEdgeIndex(size_t ni0, size_t ni1) const;

public:
  TopologyEnumerator();

  void
  computeValidPatterns(const std::vector<size_t> &reducedNumberOfNodesPerSlot);

private:
  std::vector<size_t>
  getCoincideEdges(const std::vector<size_t> &edgeNodeIndices) const;
  bool isValidPattern(const std::string &patternIndex,
                      const std::vector<vcg::Point2i> &validEdges,
                      const size_t &numberOfDesiredEdges) const;
  std::vector<vcg::Point2i>
  getValidEdges(const std::vector<size_t> &numberOfNodesPerSlot,
                const std::filesystem::path &resultsPath,
                const FlatPatternGeometry &patternGeometryAllEdges,
                const std::vector<vcg::Point2i> &allPossibleEdges);
  std::unordered_set<size_t> computeDuplicateEdges();
  std::unordered_set<size_t>
  computeCoincideEdges(const std::vector<size_t> &numberOfNodesPerSlot);
  void computeEdgeNodes(const std::vector<size_t> &numberOfNodesPerSlot,
                        std::vector<size_t> &nodesEdge0,
                        std::vector<size_t> &nodesEdge1,
                        std::vector<size_t> &nodesEdge2);
  std::unordered_set<size_t>
  computeDuplicateEdges(const std::vector<size_t> &numberOfNodesPerSlot);
  void computeValidPatterns(
      const std::vector<size_t> &numberOfNodesPerSlot,
      const size_t &numberOfDesiredEdges,
      const std::filesystem::path &resultsPath,
      const std::vector<vcg::Point3d> &vertices,
      const std::unordered_map<size_t, std::unordered_set<size_t>>
          &intersectingEdges,
      const std::vector<vcg::Point2i> &validEdges, PatternSet &patternsSet);
};
#endif // TOPOLOGYENUMERATOR_HPP
Initial commit 2020-11-27 11:47:21 +01:00			`#ifndef TOPOLOGYENUMERATOR_HPP`
			`#define TOPOLOGYENUMERATOR_HPP`
			`#include "patternIO.hpp"`
			`#include "trianglepatterngeometry.hpp"`
			`#include "trianglepattterntopology.hpp"`
			`#include <filesystem>`
			`#include <fstream>`
			`#include <iostream>`
			`//#include <nlohmann/json.hpp>`
			`#include <string>`
			`#include <vector>`

			`using GraphEdge = std::pair<size_t, size_t>;`
			`/*`
			`* Represents a graph formed by slots on a triangle that can either be filled or`
			`* not. The slots are three and are: 1) one slot per vertex. Each slot can hold`
			`* a signle node. 2) one slot per edge. Each slot can hold many nodes. 3) one`
			`* slot in the inside of the triangle. Each slot can hold multiple nodes.`
			`* */`
			`class TopologyEnumerator {`
			`/*`
			`* Holds the in a CCW order the vertex and the edge slots and then the face`
			`* slot. [0],[1],[2] can either be 0 or 1 [3],[4],[5] are integers in [0,n]`
			`* [6] an integer [0,n]`
			`* */`

			`/*`
			`reduced nodes per slot`
			`0`
			`/\`
			`/ \`
			`2 2`
			`/ 4 \`
			`/ \`
			`1----3-----1`

			`nodes per slot`
			`0`
			`/\`
			`/ \`
			`3 5`
			`/ 6 \`
			`/ \`
			`1----4-----2`

			`slot=0 -> vi=0`
			`slot=1 -> vi=1`
			`slot=2 -> vi=2`
			`...`
			`see TrianglePatternGeometry::constructVertexVector`

			`*/`
			`struct TopologicalStatistics {`
			`size_t numberOfPossibleEdges{0};`
			`size_t numberOfCoincideEdges{0};`
			`size_t numberOfDuplicateEdges{0};`
			`size_t numberOfValidEdges{0};`
			`size_t numberOfIntersectingEdgePairs{0};`
			`size_t numberOfPatterns{0};`
			`// size_t numberOfIntersectingEdgesOverAllPatterns{0};`
			`size_t numberOfPatternsWithIntersectingEdges{0};`
			`size_t numberOfPatternsWithMoreThanASingleCC{0};`
			`size_t numberOfPatternsWithADanglingEdgeOrNode{0};`
			`size_t numberOfPatternsWithArticulationPoints{0};`
			`size_t numberOfValidPatterns{0};`
			`// nlohmann::json convertToJson() const {`
			`// nlohmann::json json;`
			`// json["numPossibleEdges"] = numberOfPossibleEdges;`
			`// json["numCoincideEdges"] = numberOfCoincideEdges;`
			`// json["numDuplicateEdges"] = numberOfDuplicateEdges;`
			`// json["numValidEdges"] = numberOfValidEdges;`
			`// json["numIntersectingEdgePairs"] = numberOfIntersectingEdgePairs;`
			`// json["numPatterns"] = numberOfPatterns;`
			`// // json["numIntersectingEdgesOverAllPatterns"] =`
			`// // numberOfIntersectingEdgesOverAllPatterns;`
			`// json["numPatternsWithIntersectingEdges"] =`
			`// numberOfPatternsWithIntersectingEdges;`
			`// json["numPatternsWithNotASingleCC"] =`
			`// numberOfPatternsWithMoreThanASingleCC;`
			`// json["numPatternsWithDangling"] =`
			`// numberOfPatternsWithADanglingEdgeOrNode;`
			`// json["numPatternsWithArticulationPoints"] =`
			`// numberOfPatternsWithArticulationPoints;`
			`// json["numValidPatterns"] = numberOfValidPatterns;`

			`// return json;`
			`// }`
			`void print(const std::string &setupString,`
			`const std::filesystem::path &directoryPath) const {`
			`std::cout << "The setup " << setupString << std::endl;`
			`std::cout << "Has following statistics:" << std::endl;`
			`std::cout << numberOfPossibleEdges`
			`<< " possible edges with the given arrangement of nodes"`
			`<< std::endl;`
			`std::cout << numberOfCoincideEdges << " coincide edges" << std::endl;`
			`std::cout << numberOfDuplicateEdges << " duplicate edges" << std::endl;`
			`std::cout << numberOfValidEdges << " valid edges" << std::endl;`
			`std::cout << numberOfIntersectingEdgePairs << "intersecting edge pairs "`
			`<< std::endl;`
			`std::cout << numberOfPatterns`
			`<< " patterns can be generated with the given setup"`
			`<< std::endl;`
			`// std::cout << numberOfIntersectingEdgesOverAllPatterns`
			`// << " intersecting edges found over all patterns" <<`
			`// std::endl;`
			`std::cout << numberOfPatternsWithIntersectingEdges`
			`<< " patterns found with intersecting edges" << std::endl;`
			`std::cout << numberOfPatternsWithMoreThanASingleCC`
			`<< " patterns found with more than one connected components"`
			`<< std::endl;`
			`std::cout << numberOfPatternsWithADanglingEdgeOrNode`
			`<< " patterns found with a dangling node or edge" << std::endl;`
			`std::cout << numberOfPatternsWithArticulationPoints`
			`<< " patterns found with an articulation point" << std::endl;`
			`std::cout << numberOfValidPatterns << " valid patterns were found"`
			`<< std::endl;`
			`// if (!directoryPath.empty()) {`
			`// auto json = convertToJson();`

			`// std::ofstream file;`
			`// file.open(std::filesystem::path(directoryPath)`
			`// .append("statistics.csv")`
			`// .string());`
			`// file << "setup," << setupString << "\n";`
			`// for (const auto &el : json.items()) {`
			`// file << el.key() << "," << el.value() << "\n";`
			`// }`
			`// }`
			`}`
			`};`

			`TopologicalStatistics statistics;`
			`std::vector<size_t> numberOfNodesPerSlot;`
			`size_t numberOfNodes;`

			`size_t`
			`computeCoincideEdges(const std::vector<size_t> &numberOfNodesPerSlot) const;`
			`size_t computeNumberOfPossibleEdges(`
			`const std::vector<size_t> &numberOfNodesPerSlot) const;`

			`void createLabelMesh(const std::vector<vcg::Point3d> vertices,`
			`const std::filesystem::path &savePath) const;`
			`size_t getEdgeIndex(size_t ni0, size_t ni1) const;`

			`public:`
			`TopologyEnumerator();`

			`void`
			`computeValidPatterns(const std::vector<size_t> &reducedNumberOfNodesPerSlot);`

			`private:`
			`std::vector<size_t>`
			`getCoincideEdges(const std::vector<size_t> &edgeNodeIndices) const;`
			`bool isValidPattern(const std::string &patternIndex,`
			`const std::vector<vcg::Point2i> &validEdges,`
			`const size_t &numberOfDesiredEdges) const;`
			`std::vector<vcg::Point2i>`
			`getValidEdges(const std::vector<size_t> &numberOfNodesPerSlot,`
Refactored code to compile under visual studio. 2021-02-04 13:58:41 +01:00			`const std::filesystem::path &resultsPath,`
Initial commit 2020-11-27 11:47:21 +01:00			`const FlatPatternGeometry &patternGeometryAllEdges,`
			`const std::vector<vcg::Point2i> &allPossibleEdges);`
			`std::unordered_set<size_t> computeDuplicateEdges();`
			`std::unordered_set<size_t>`
			`computeCoincideEdges(const std::vector<size_t> &numberOfNodesPerSlot);`
			`void computeEdgeNodes(const std::vector<size_t> &numberOfNodesPerSlot,`
			`std::vector<size_t> &nodesEdge0,`
			`std::vector<size_t> &nodesEdge1,`
			`std::vector<size_t> &nodesEdge2);`
			`std::unordered_set<size_t>`
			`computeDuplicateEdges(const std::vector<size_t> &numberOfNodesPerSlot);`
			`void computeValidPatterns(`
			`const std::vector<size_t> &numberOfNodesPerSlot,`
			`const size_t &numberOfDesiredEdges,`
			`const std::filesystem::path &resultsPath,`
			`const std::vector<vcg::Point3d> &vertices,`
			`const std::unordered_map<size_t, std::unordered_set<size_t>>`
			`&intersectingEdges,`
			`const std::vector<vcg::Point2i> &validEdges, PatternSet &patternsSet);`
			`};`
			`#endif // TOPOLOGYENUMERATOR_HPP`