internal/ceres/graph_algorithms.h - ceres-solver - Git at Google

 // Ceres Solver - A fast non-linear least squares minimizer
 // Copyright 2015 Google Inc. All rights reserved.
 // http://ceres-solver.org/
 //
 // Redistribution and use in source and binary forms, with or without
 // modification, are permitted provided that the following conditions are met:
 //
 // * Redistributions of source code must retain the above copyright notice,
 //   this list of conditions and the following disclaimer.
 // * Redistributions in binary form must reproduce the above copyright notice,
 //   this list of conditions and the following disclaimer in the documentation
 //   and/or other materials provided with the distribution.
 // * Neither the name of Google Inc. nor the names of its contributors may be
 //   used to endorse or promote products derived from this software without
 //   specific prior written permission.
 //
 // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
 // AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
 // IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
 // ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
 // LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
 // CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
 // SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
 // INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
 // CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
 // ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
 // POSSIBILITY OF SUCH DAMAGE.
 //
 // Author: sameeragarwal@google.com (Sameer Agarwal)
 //
 // Various algorithms that operate on undirected graphs.

 #ifndef CERES_INTERNAL_GRAPH_ALGORITHMS_H_
 #define CERES_INTERNAL_GRAPH_ALGORITHMS_H_

 #include <algorithm>
 #include <unordered_map>
 #include <unordered_set>
 #include <utility>
 #include <vector>

 #include "ceres/graph.h"
 #include "ceres/wall_time.h"
 #include "glog/logging.h"

 namespace ceres {
 namespace internal {

 // Compare two vertices of a graph by their degrees, if the degrees
 // are equal then order them by their ids.
 template <typename Vertex>
 class VertexTotalOrdering {
  public:
   explicit VertexTotalOrdering(const Graph<Vertex>& graph) : graph_(graph) {}

   bool operator()(const Vertex& lhs, const Vertex& rhs) const {
     if (graph_.Neighbors(lhs).size() == graph_.Neighbors(rhs).size()) {
       return lhs < rhs;
     }
     return graph_.Neighbors(lhs).size() < graph_.Neighbors(rhs).size();
   }

  private:
   const Graph<Vertex>& graph_;
 };

 template <typename Vertex>
 class VertexDegreeLessThan {
  public:
   explicit VertexDegreeLessThan(const Graph<Vertex>& graph) : graph_(graph) {}

   bool operator()(const Vertex& lhs, const Vertex& rhs) const {
     return graph_.Neighbors(lhs).size() < graph_.Neighbors(rhs).size();
   }

  private:
   const Graph<Vertex>& graph_;
 };

 // Order the vertices of a graph using its (approximately) largest
 // independent set, where an independent set of a graph is a set of
 // vertices that have no edges connecting them. The maximum
 // independent set problem is NP-Hard, but there are effective
 // approximation algorithms available. The implementation here uses a
 // breadth first search that explores the vertices in order of
 // increasing degree. The same idea is used by Saad & Li in "MIQR: A
 // multilevel incomplete QR preconditioner for large sparse
 // least-squares problems", SIMAX, 2007.
 //
 // Given a undirected graph G(V,E), the algorithm is a greedy BFS
 // search where the vertices are explored in increasing order of their
 // degree. The output vector ordering contains elements of S in
 // increasing order of their degree, followed by elements of V - S in
 // increasing order of degree. The return value of the function is the
 // cardinality of S.
 template <typename Vertex>
 int IndependentSetOrdering(const Graph<Vertex>& graph,
                            std::vector<Vertex>* ordering) {
   const std::unordered_set<Vertex>& vertices = graph.vertices();
   const int num_vertices = vertices.size();

   CHECK(ordering != nullptr);
   ordering->clear();
   ordering->reserve(num_vertices);

   // Colors for labeling the graph during the BFS.
   const char kWhite = 0;
   const char kGrey = 1;
   const char kBlack = 2;

   // Mark all vertices white.
   std::unordered_map<Vertex, char> vertex_color;
   std::vector<Vertex> vertex_queue;
   for (const Vertex& vertex : vertices) {
     vertex_color[vertex] = kWhite;
     vertex_queue.push_back(vertex);
   }

   std::sort(vertex_queue.begin(),
             vertex_queue.end(),
             VertexTotalOrdering<Vertex>(graph));

   // Iterate over vertex_queue. Pick the first white vertex, add it
   // to the independent set. Mark it black and its neighbors grey.
   for (const Vertex& vertex : vertex_queue) {
     if (vertex_color[vertex] != kWhite) {
       continue;
     }

     ordering->push_back(vertex);
     vertex_color[vertex] = kBlack;
     const std::unordered_set<Vertex>& neighbors = graph.Neighbors(vertex);
     for (const Vertex& neighbor : neighbors) {
       vertex_color[neighbor] = kGrey;
     }
   }

   int independent_set_size = ordering->size();

   // Iterate over the vertices and add all the grey vertices to the
   // ordering. At this stage there should only be black or grey
   // vertices in the graph.
   for (const Vertex& vertex : vertex_queue) {
     DCHECK(vertex_color[vertex] != kWhite);
     if (vertex_color[vertex] != kBlack) {
       ordering->push_back(vertex);
     }
   }

   CHECK_EQ(ordering->size(), num_vertices);
   return independent_set_size;
 }

 // Same as above with one important difference. The ordering parameter
 // is an input/output parameter which carries an initial ordering of
 // the vertices of the graph. The greedy independent set algorithm
 // starts by sorting the vertices in increasing order of their
 // degree. The input ordering is used to stabilize this sort, i.e., if
 // two vertices have the same degree then they are ordered in the same
 // order in which they occur in "ordering".
 //
 // This is useful in eliminating non-determinism from the Schur
 // ordering algorithm over all.
 template <typename Vertex>
 int StableIndependentSetOrdering(const Graph<Vertex>& graph,
                                  std::vector<Vertex>* ordering) {
   CHECK(ordering != nullptr);
   const std::unordered_set<Vertex>& vertices = graph.vertices();
   const int num_vertices = vertices.size();
   CHECK_EQ(vertices.size(), ordering->size());

   // Colors for labeling the graph during the BFS.
   const char kWhite = 0;
   const char kGrey = 1;
   const char kBlack = 2;

   std::vector<Vertex> vertex_queue(*ordering);

   std::stable_sort(vertex_queue.begin(),
                    vertex_queue.end(),
                    VertexDegreeLessThan<Vertex>(graph));

   // Mark all vertices white.
   std::unordered_map<Vertex, char> vertex_color;
   for (const Vertex& vertex : vertices) {
     vertex_color[vertex] = kWhite;
   }

   ordering->clear();
   ordering->reserve(num_vertices);
   // Iterate over vertex_queue. Pick the first white vertex, add it
   // to the independent set. Mark it black and its neighbors grey.
   for (int i = 0; i < vertex_queue.size(); ++i) {
     const Vertex& vertex = vertex_queue[i];
     if (vertex_color[vertex] != kWhite) {
       continue;
     }

     ordering->push_back(vertex);
     vertex_color[vertex] = kBlack;
     const std::unordered_set<Vertex>& neighbors = graph.Neighbors(vertex);
     for (const Vertex& neighbor : neighbors) {
       vertex_color[neighbor] = kGrey;
     }
   }

   int independent_set_size = ordering->size();

   // Iterate over the vertices and add all the grey vertices to the
   // ordering. At this stage there should only be black or grey
   // vertices in the graph.
   for (const Vertex& vertex : vertex_queue) {
     DCHECK(vertex_color[vertex] != kWhite);
     if (vertex_color[vertex] != kBlack) {
       ordering->push_back(vertex);
     }
   }

   CHECK_EQ(ordering->size(), num_vertices);
   return independent_set_size;
 }

 // Find the connected component for a vertex implemented using the
 // find and update operation for disjoint-set. Recursively traverse
 // the disjoint set structure till you reach a vertex whose connected
 // component has the same id as the vertex itself. Along the way
 // update the connected components of all the vertices. This updating
 // is what gives this data structure its efficiency.
 template <typename Vertex>
 Vertex FindConnectedComponent(const Vertex& vertex,
                               std::unordered_map<Vertex, Vertex>* union_find) {
   auto it = union_find->find(vertex);
   DCHECK(it != union_find->end());
   if (it->second != vertex) {
     it->second = FindConnectedComponent(it->second, union_find);
   }

   return it->second;
 }

 // Compute a degree two constrained Maximum Spanning Tree/forest of
 // the input graph. Caller owns the result.
 //
 // Finding degree 2 spanning tree of a graph is not always
 // possible. For example a star graph, i.e. a graph with n-nodes
 // where one node is connected to the other n-1 nodes does not have
 // a any spanning trees of degree less than n-1.Even if such a tree
 // exists, finding such a tree is NP-Hard.

 // We get around both of these problems by using a greedy, degree
 // constrained variant of Kruskal's algorithm. We start with a graph
 // G_T with the same vertex set V as the input graph G(V,E) but an
 // empty edge set. We then iterate over the edges of G in decreasing
 // order of weight, adding them to G_T if doing so does not create a
 // cycle in G_T} and the degree of all the vertices in G_T remains
 // bounded by two. This O(|E|) algorithm results in a degree-2
 // spanning forest, or a collection of linear paths that span the
 // graph G.
 template <typename Vertex>
 WeightedGraph<Vertex>* Degree2MaximumSpanningForest(
     const WeightedGraph<Vertex>& graph) {
   // Array of edges sorted in decreasing order of their weights.
   std::vector<std::pair<double, std::pair<Vertex, Vertex>>> weighted_edges;
   WeightedGraph<Vertex>* forest = new WeightedGraph<Vertex>();

   // Disjoint-set to keep track of the connected components in the
   // maximum spanning tree.
   std::unordered_map<Vertex, Vertex> disjoint_set;

   // Sort of the edges in the graph in decreasing order of their
   // weight. Also add the vertices of the graph to the Maximum
   // Spanning Tree graph and set each vertex to be its own connected
   // component in the disjoint_set structure.
   const std::unordered_set<Vertex>& vertices = graph.vertices();
   for (const Vertex& vertex1 : vertices) {
     forest->AddVertex(vertex1, graph.VertexWeight(vertex1));
     disjoint_set[vertex1] = vertex1;

     const std::unordered_set<Vertex>& neighbors = graph.Neighbors(vertex1);
     for (const Vertex& vertex2 : neighbors) {
       if (vertex1 >= vertex2) {
         continue;
       }
       const double weight = graph.EdgeWeight(vertex1, vertex2);
       weighted_edges.push_back(
           std::make_pair(weight, std::make_pair(vertex1, vertex2)));
     }
   }

   // The elements of this vector, are pairs<edge_weight,
   // edge>. Sorting it using the reverse iterators gives us the edges
   // in decreasing order of edges.
   std::sort(weighted_edges.rbegin(), weighted_edges.rend());

   // Greedily add edges to the spanning tree/forest as long as they do
   // not violate the degree/cycle constraint.
   for (int i = 0; i < weighted_edges.size(); ++i) {
     const std::pair<Vertex, Vertex>& edge = weighted_edges[i].second;
     const Vertex vertex1 = edge.first;
     const Vertex vertex2 = edge.second;

     // Check if either of the vertices are of degree 2 already, in
     // which case adding this edge will violate the degree 2
     // constraint.
     if ((forest->Neighbors(vertex1).size() == 2) ||
         (forest->Neighbors(vertex2).size() == 2)) {
       continue;
     }

     // Find the id of the connected component to which the two
     // vertices belong to. If the id is the same, it means that the
     // two of them are already connected to each other via some other
     // vertex, and adding this edge will create a cycle.
     Vertex root1 = FindConnectedComponent(vertex1, &disjoint_set);
     Vertex root2 = FindConnectedComponent(vertex2, &disjoint_set);

     if (root1 == root2) {
       continue;
     }

     // This edge can be added, add an edge in either direction with
     // the same weight as the original graph.
     const double edge_weight = graph.EdgeWeight(vertex1, vertex2);
     forest->AddEdge(vertex1, vertex2, edge_weight);
     forest->AddEdge(vertex2, vertex1, edge_weight);

     // Connected the two connected components by updating the
     // disjoint_set structure. Always connect the connected component
     // with the greater index with the connected component with the
     // smaller index. This should ensure shallower trees, for quicker
     // lookup.
     if (root2 < root1) {
       std::swap(root1, root2);
     }

     disjoint_set[root2] = root1;
   }
   return forest;
 }

 }  // namespace internal
 }  // namespace ceres

 #endif  // CERES_INTERNAL_GRAPH_ALGORITHMS_H_
	// Ceres Solver - A fast non-linear least squares minimizer
	// Copyright 2015 Google Inc. All rights reserved.
	// http://ceres-solver.org/
	//
	// Redistribution and use in source and binary forms, with or without
	// modification, are permitted provided that the following conditions are met:
	//
	// * Redistributions of source code must retain the above copyright notice,
	// this list of conditions and the following disclaimer.
	// * Redistributions in binary form must reproduce the above copyright notice,
	// this list of conditions and the following disclaimer in the documentation
	// and/or other materials provided with the distribution.
	// * Neither the name of Google Inc. nor the names of its contributors may be
	// used to endorse or promote products derived from this software without
	// specific prior written permission.
	//
	// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
	// AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
	// IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
	// ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
	// LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
	// CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
	// SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
	// INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
	// CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
	// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
	// POSSIBILITY OF SUCH DAMAGE.
	//
	// Author: sameeragarwal@google.com (Sameer Agarwal)
	//
	// Various algorithms that operate on undirected graphs.

	#ifndef CERES_INTERNAL_GRAPH_ALGORITHMS_H_
	#define CERES_INTERNAL_GRAPH_ALGORITHMS_H_

	#include <algorithm>
	#include <unordered_map>
	#include <unordered_set>
	#include <utility>
	#include <vector>

	#include "ceres/graph.h"
	#include "ceres/wall_time.h"
	#include "glog/logging.h"

	namespace ceres {
	namespace internal {

	// Compare two vertices of a graph by their degrees, if the degrees
	// are equal then order them by their ids.
	template <typename Vertex>
	class VertexTotalOrdering {
	public:
	explicit VertexTotalOrdering(const Graph<Vertex>& graph) : graph_(graph) {}

	bool operator()(const Vertex& lhs, const Vertex& rhs) const {
	if (graph_.Neighbors(lhs).size() == graph_.Neighbors(rhs).size()) {
	return lhs < rhs;
	}
	return graph_.Neighbors(lhs).size() < graph_.Neighbors(rhs).size();
	}

	private:
	const Graph<Vertex>& graph_;
	};

	template <typename Vertex>
	class VertexDegreeLessThan {
	public:
	explicit VertexDegreeLessThan(const Graph<Vertex>& graph) : graph_(graph) {}

	bool operator()(const Vertex& lhs, const Vertex& rhs) const {
	return graph_.Neighbors(lhs).size() < graph_.Neighbors(rhs).size();
	}

	private:
	const Graph<Vertex>& graph_;
	};

	// Order the vertices of a graph using its (approximately) largest
	// independent set, where an independent set of a graph is a set of
	// vertices that have no edges connecting them. The maximum
	// independent set problem is NP-Hard, but there are effective
	// approximation algorithms available. The implementation here uses a
	// breadth first search that explores the vertices in order of
	// increasing degree. The same idea is used by Saad & Li in "MIQR: A
	// multilevel incomplete QR preconditioner for large sparse
	// least-squares problems", SIMAX, 2007.
	//
	// Given a undirected graph G(V,E), the algorithm is a greedy BFS
	// search where the vertices are explored in increasing order of their
	// degree. The output vector ordering contains elements of S in
	// increasing order of their degree, followed by elements of V - S in
	// increasing order of degree. The return value of the function is the
	// cardinality of S.
	template <typename Vertex>
	int IndependentSetOrdering(const Graph<Vertex>& graph,
	std::vector<Vertex>* ordering) {
	const std::unordered_set<Vertex>& vertices = graph.vertices();
	const int num_vertices = vertices.size();

	CHECK(ordering != nullptr);
	ordering->clear();
	ordering->reserve(num_vertices);

	// Colors for labeling the graph during the BFS.
	const char kWhite = 0;
	const char kGrey = 1;
	const char kBlack = 2;

	// Mark all vertices white.
	std::unordered_map<Vertex, char> vertex_color;
	std::vector<Vertex> vertex_queue;
	for (const Vertex& vertex : vertices) {
	vertex_color[vertex] = kWhite;
	vertex_queue.push_back(vertex);
	}

	std::sort(vertex_queue.begin(),
	vertex_queue.end(),
	VertexTotalOrdering<Vertex>(graph));

	// Iterate over vertex_queue. Pick the first white vertex, add it
	// to the independent set. Mark it black and its neighbors grey.
	for (const Vertex& vertex : vertex_queue) {
	if (vertex_color[vertex] != kWhite) {
	continue;
	}

	ordering->push_back(vertex);
	vertex_color[vertex] = kBlack;
	const std::unordered_set<Vertex>& neighbors = graph.Neighbors(vertex);
	for (const Vertex& neighbor : neighbors) {
	vertex_color[neighbor] = kGrey;
	}
	}

	int independent_set_size = ordering->size();

	// Iterate over the vertices and add all the grey vertices to the
	// ordering. At this stage there should only be black or grey
	// vertices in the graph.
	for (const Vertex& vertex : vertex_queue) {
	DCHECK(vertex_color[vertex] != kWhite);
	if (vertex_color[vertex] != kBlack) {
	ordering->push_back(vertex);
	}
	}

	CHECK_EQ(ordering->size(), num_vertices);
	return independent_set_size;
	}

	// Same as above with one important difference. The ordering parameter
	// is an input/output parameter which carries an initial ordering of
	// the vertices of the graph. The greedy independent set algorithm
	// starts by sorting the vertices in increasing order of their
	// degree. The input ordering is used to stabilize this sort, i.e., if
	// two vertices have the same degree then they are ordered in the same
	// order in which they occur in "ordering".
	//
	// This is useful in eliminating non-determinism from the Schur
	// ordering algorithm over all.
	template <typename Vertex>
	int StableIndependentSetOrdering(const Graph<Vertex>& graph,
	std::vector<Vertex>* ordering) {
	CHECK(ordering != nullptr);
	const std::unordered_set<Vertex>& vertices = graph.vertices();
	const int num_vertices = vertices.size();
	CHECK_EQ(vertices.size(), ordering->size());

	// Colors for labeling the graph during the BFS.
	const char kWhite = 0;
	const char kGrey = 1;
	const char kBlack = 2;

	std::vector<Vertex> vertex_queue(*ordering);

	std::stable_sort(vertex_queue.begin(),
	vertex_queue.end(),
	VertexDegreeLessThan<Vertex>(graph));

	// Mark all vertices white.
	std::unordered_map<Vertex, char> vertex_color;
	for (const Vertex& vertex : vertices) {
	vertex_color[vertex] = kWhite;
	}

	ordering->clear();
	ordering->reserve(num_vertices);
	// Iterate over vertex_queue. Pick the first white vertex, add it
	// to the independent set. Mark it black and its neighbors grey.
	for (int i = 0; i < vertex_queue.size(); ++i) {
	const Vertex& vertex = vertex_queue[i];
	if (vertex_color[vertex] != kWhite) {
	continue;
	}

	ordering->push_back(vertex);
	vertex_color[vertex] = kBlack;
	const std::unordered_set<Vertex>& neighbors = graph.Neighbors(vertex);
	for (const Vertex& neighbor : neighbors) {
	vertex_color[neighbor] = kGrey;
	}
	}

	int independent_set_size = ordering->size();

	// Iterate over the vertices and add all the grey vertices to the
	// ordering. At this stage there should only be black or grey
	// vertices in the graph.
	for (const Vertex& vertex : vertex_queue) {
	DCHECK(vertex_color[vertex] != kWhite);
	if (vertex_color[vertex] != kBlack) {
	ordering->push_back(vertex);
	}
	}

	CHECK_EQ(ordering->size(), num_vertices);
	return independent_set_size;
	}

	// Find the connected component for a vertex implemented using the
	// find and update operation for disjoint-set. Recursively traverse
	// the disjoint set structure till you reach a vertex whose connected
	// component has the same id as the vertex itself. Along the way
	// update the connected components of all the vertices. This updating
	// is what gives this data structure its efficiency.
	template <typename Vertex>
	Vertex FindConnectedComponent(const Vertex& vertex,
	std::unordered_map<Vertex, Vertex>* union_find) {
	auto it = union_find->find(vertex);
	DCHECK(it != union_find->end());
	if (it->second != vertex) {
	it->second = FindConnectedComponent(it->second, union_find);
	}

	return it->second;
	}

	// Compute a degree two constrained Maximum Spanning Tree/forest of
	// the input graph. Caller owns the result.
	//
	// Finding degree 2 spanning tree of a graph is not always
	// possible. For example a star graph, i.e. a graph with n-nodes
	// where one node is connected to the other n-1 nodes does not have
	// a any spanning trees of degree less than n-1.Even if such a tree
	// exists, finding such a tree is NP-Hard.

	// We get around both of these problems by using a greedy, degree
	// constrained variant of Kruskal's algorithm. We start with a graph
	// G_T with the same vertex set V as the input graph G(V,E) but an
	// empty edge set. We then iterate over the edges of G in decreasing
	// order of weight, adding them to G_T if doing so does not create a
	// cycle in G_T} and the degree of all the vertices in G_T remains
	// bounded by two. This O(\|E\|) algorithm results in a degree-2
	// spanning forest, or a collection of linear paths that span the
	// graph G.
	template <typename Vertex>
	WeightedGraph<Vertex>* Degree2MaximumSpanningForest(
	const WeightedGraph<Vertex>& graph) {
	// Array of edges sorted in decreasing order of their weights.
	std::vector<std::pair<double, std::pair<Vertex, Vertex>>> weighted_edges;
	WeightedGraph<Vertex>* forest = new WeightedGraph<Vertex>();

	// Disjoint-set to keep track of the connected components in the
	// maximum spanning tree.
	std::unordered_map<Vertex, Vertex> disjoint_set;

	// Sort of the edges in the graph in decreasing order of their
	// weight. Also add the vertices of the graph to the Maximum
	// Spanning Tree graph and set each vertex to be its own connected
	// component in the disjoint_set structure.
	const std::unordered_set<Vertex>& vertices = graph.vertices();
	for (const Vertex& vertex1 : vertices) {
	forest->AddVertex(vertex1, graph.VertexWeight(vertex1));
	disjoint_set[vertex1] = vertex1;

	const std::unordered_set<Vertex>& neighbors = graph.Neighbors(vertex1);
	for (const Vertex& vertex2 : neighbors) {
	if (vertex1 >= vertex2) {
	continue;
	}
	const double weight = graph.EdgeWeight(vertex1, vertex2);
	weighted_edges.push_back(
	std::make_pair(weight, std::make_pair(vertex1, vertex2)));
	}
	}

	// The elements of this vector, are pairs<edge_weight,
	// edge>. Sorting it using the reverse iterators gives us the edges
	// in decreasing order of edges.
	std::sort(weighted_edges.rbegin(), weighted_edges.rend());

	// Greedily add edges to the spanning tree/forest as long as they do
	// not violate the degree/cycle constraint.
	for (int i = 0; i < weighted_edges.size(); ++i) {
	const std::pair<Vertex, Vertex>& edge = weighted_edges[i].second;
	const Vertex vertex1 = edge.first;
	const Vertex vertex2 = edge.second;

	// Check if either of the vertices are of degree 2 already, in
	// which case adding this edge will violate the degree 2
	// constraint.
	if ((forest->Neighbors(vertex1).size() == 2) \|\|
	(forest->Neighbors(vertex2).size() == 2)) {
	continue;
	}

	// Find the id of the connected component to which the two
	// vertices belong to. If the id is the same, it means that the
	// two of them are already connected to each other via some other
	// vertex, and adding this edge will create a cycle.
	Vertex root1 = FindConnectedComponent(vertex1, &disjoint_set);
	Vertex root2 = FindConnectedComponent(vertex2, &disjoint_set);

	if (root1 == root2) {
	continue;
	}

	// This edge can be added, add an edge in either direction with
	// the same weight as the original graph.
	const double edge_weight = graph.EdgeWeight(vertex1, vertex2);
	forest->AddEdge(vertex1, vertex2, edge_weight);
	forest->AddEdge(vertex2, vertex1, edge_weight);

	// Connected the two connected components by updating the
	// disjoint_set structure. Always connect the connected component
	// with the greater index with the connected component with the
	// smaller index. This should ensure shallower trees, for quicker
	// lookup.
	if (root2 < root1) {
	std::swap(root1, root2);
	}

	disjoint_set[root2] = root1;
	}
	return forest;
	}

	} // namespace internal
	} // namespace ceres

	#endif // CERES_INTERNAL_GRAPH_ALGORITHMS_H_