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edmonds-matching-algorithm/src/edmonds.cpp

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#include "edmonds.h"
#include <iostream>
#include <stack>
#include <tuple>
#include "graph_attributes.h"
using namespace ED;
namespace Edmonds {
NodeId get_rho(GraphAttributes const & attrs, NodeId id)
{
while(attrs.rho_[id] != id)
{
id = attrs.rho_[id];
}
return id;
}
void check_integrity(GraphAttributes const & attrs)
{
for(NodeId id = 0; id < attrs.num_nodes(); ++id)
{
// Check that rho does not have any cycles
NodeId cur_rho_id = id;
size_t count = attrs.num_nodes();
while(attrs.rho_[cur_rho_id] != cur_rho_id and count--)
{
cur_rho_id = attrs.rho_[cur_rho_id];
}
assert(count != 0);
// Check that μ encodes a valid matching
NodeId matched = attrs.mu[id];
if(matched != id)
{
assert(attrs.mu[matched] == id);
}
if (attrs.is_out_of_forest(id))
{
assert(attrs.phi[id] == id);
assert(get_rho(attrs, id) == id);
}
else
{
// check for a path to the root, i.e. ρ(node)
NodeId cur_node = id;
while(cur_node != get_rho(attrs, cur_node))
{
// If the condition was true, then cur_node is outer, part of a blossom
// and we want to follow its path
// therefore, we check that both φ and μ are not the identity on this node
// and point to vertices that have the same rho
assert(attrs.mu[cur_node] != cur_node);
assert(attrs.phi[cur_node] != cur_node);
assert(get_rho(attrs,attrs.mu[cur_node]) == get_rho(attrs,cur_node));
assert(get_rho(attrs,attrs.phi[cur_node]) == get_rho(attrs,cur_node));
// now, walk along the matched edge
cur_node = attrs.mu[cur_node];
// now we want to walk along φ, this will again
// - not be the identity
// - result in a node that has the same rho
assert(attrs.phi[cur_node] != cur_node);
assert(get_rho(attrs, attrs.phi[cur_node]) == get_rho(attrs,cur_node));
cur_node = attrs.phi[cur_node];
}
}
if (not attrs.is_outer(id))
{
assert(get_rho(attrs,id) == id);
}
}
}
/**
* @return List of vertices of the x-r path, where r is the root of the
* special blossom forest component x belongs to.
*
* @note This assumes that the values of μ, φ and ρ represent a special
* blossom forest on the graph when this method is called.
* **/
__attribute__((noinline))
std::vector<NodeId> path_to_forest_root(GraphAttributes const & attrs, NodeId id)
{
std::vector<NodeId> retval;
retval.push_back(id);
while (attrs.mu[id] != id)
{
id = attrs.mu[id];
retval.push_back(id);
// Note that it is guaranteed that this does not produce a loop:
// We are traversing the path to a root of the forest,
// but we know that each root is exposed by M, so after traversing
// the matching edge, we cannot have reached a root.
id = attrs.phi[id];
retval.push_back(id);
}
return retval;
}
void collect_exposed_vertices(GraphAttributes & attrs, std::stack<NodeId> & container)
{
std::stack<NodeId>().swap(container);
for(NodeId id = 0; id < attrs.num_nodes(); id++)
{
if (attrs.mu[id] == id)
{
container.push(id);
attrs.scanned[id] = true;
}
}
}
__attribute__((noinline))
void augment(GraphAttributes & attrs, std::vector<NodeId> const & x_path, std::vector<NodeId> const & y_path,
std::stack<NodeId> & outer_unvisited_nodes)
{
//std::cout << "Augment" << std::endl;
// Paths are disjoint -> augment
attrs.mu[x_path.front()] = y_path.front();
attrs.mu[y_path.front()] = x_path.front();
// TODO: put this into own method?
for(size_t i = 1; i < x_path.size(); i += 2)
{
attrs.mu[x_path[i]] = x_path[i+1];
attrs.mu[x_path[i+1]] = x_path[i];
}
for(size_t i = 1; i < y_path.size(); i += 2)
{
attrs.mu[y_path[i]] = y_path[i+1];
attrs.mu[y_path[i+1]] = y_path[i];
}
attrs.reset_forest();
collect_exposed_vertices(attrs, outer_unvisited_nodes);
}
__attribute__((noinline))
std::tuple<NodeId, size_type, size_type> find_blossom_root_id(GraphAttributes & attrs, std::vector<NodeId> const & x_path, std::vector<NodeId> const & y_path)
{
size_t distance_from_x = x_path.size() - 1;
size_t distance_from_y = y_path.size() - 1;
while (distance_from_x > 0 and distance_from_y > 0 and \
x_path[distance_from_x - 1] == y_path[distance_from_y - 1])
{
--distance_from_x;
--distance_from_y;
}
// found first vertex of x_path \cap y_path
while (attrs.rho(x_path[distance_from_x]) != x_path[distance_from_x])
{
++distance_from_x;
++distance_from_y;
};
// found first vertex fixed by rho
return { x_path[distance_from_x], distance_from_x, distance_from_y };
}
__attribute__((noinline))
void update_phialong_blossom_paths(GraphAttributes & attrs, std::vector<NodeId> const & x_path, std::vector<NodeId> const & y_path,
std::tuple<NodeId, size_type, size_type> const & blossom_root)
{
auto const [blossom_root_id, distance_from_x, distance_from_y] = blossom_root;
// Update φ along the paths to encode the ear decomposition
for (size_t i = 1; i <= distance_from_x; i += 2)
{
if (attrs.rho(attrs.phi[x_path[i]]) != blossom_root_id)
{
attrs.phi[attrs.phi[x_path[i]]] = x_path[i];
}
}
for (size_t i = 1; i <= distance_from_y; i += 2)
{
if (attrs.rho(attrs.phi[y_path[i]]) != blossom_root_id)
{
attrs.phi[attrs.phi[y_path[i]]] = y_path[i];
}
}
// Link x and y
if (attrs.rho(x_path.front()) != blossom_root_id)
{
attrs.phi[x_path.front()] = y_path.front();
}
if (attrs.rho(y_path.front()) != blossom_root_id)
{
attrs.phi[y_path.front()] = x_path.front();
}
}
__attribute__((noinline))
void update_rho(GraphAttributes & attrs, std::vector<NodeId> const & x_path, std::vector<NodeId> const & y_path,
std::tuple<NodeId, size_type, size_type> const & blossom_root_description,
std::stack<NodeId> & outer_unvisited_nodes)
{
// Update root indices. We have to do this for all vertices v with
// ρ(v) in the paths from x or y to r
// We update ρ(v) first for the paths themselves, and then 'contract' ρ
// by updating ρ(v) to r for all vertices where ρ(ρ(v)) = r
// Also, while walking along the paths, we can add all vertices (which are now outer)
// to the stack.
auto const [blossom_root_id, distance_from_x, distance_from_y] = blossom_root_description;
for (size_t i = 0; i <= distance_from_x; ++i)
{
attrs.rho_[x_path[i]] = blossom_root_id;
if (not attrs.scanned[x_path[i]])
{
outer_unvisited_nodes.push(x_path[i]);
}
}
for (size_t i = 0; i <= distance_from_y; ++i)
{
attrs.rho_[y_path[i]] = blossom_root_id;
if (not attrs.scanned[y_path[i]])
{
outer_unvisited_nodes.push(y_path[i]);
}
}
}
__attribute__((noinline))
void contract_blossom(GraphAttributes & attrs, std::vector<NodeId> const & x_path, std::vector<NodeId> const & y_path,
std::stack<NodeId> & outer_unvisited_nodes)
{
//std::cout << "Contract blossom" << std::endl;
std::tuple<NodeId, size_type, size_type> const blossom_root_description = find_blossom_root_id(attrs, x_path, y_path);
update_phialong_blossom_paths(attrs, x_path, y_path, blossom_root_description);
check_integrity(attrs);
update_rho(attrs, x_path, y_path, blossom_root_description, outer_unvisited_nodes);
}
void maximum_matching_from_initial_matching(Graph const & graph, GraphAttributes & attrs)
{
attrs.reset_forest();
// Over the course of the algorithm, this will maintain all outer vertices
// that have not been scanned yet.
// Note that at the beginning, this is exactly the exposed edges.
// Throughout the algorithm, we push new ids whenever there are new outer vertices.
// Also note that we separately mark each node whether it has been collected to this stack.
// When this stack runs out, then we know that all vertices marked 'scanned' have already been processed,
// but also all vertices not marked 'scanned' are not outer vertices, so we can in fact terminate.
std::stack<NodeId> outer_unvisited_nodes;
collect_exposed_vertices(attrs, outer_unvisited_nodes);
while(not outer_unvisited_nodes.empty())
{
NodeId const id = outer_unvisited_nodes.top();
outer_unvisited_nodes.pop();
for(NodeId neighbor_id : graph.node(id).neighbors())
{
check_integrity(attrs);
//std::cout << "Check passed" << std::endl;
if (attrs.is_out_of_forest(neighbor_id))
{
// Grow Forest
attrs.phi[neighbor_id] = id;
assert(attrs.mu[neighbor_id] != neighbor_id);
outer_unvisited_nodes.push(attrs.mu[neighbor_id]);
}
else if (attrs.is_outer(neighbor_id) and attrs.rho(id) != attrs.rho(neighbor_id))
{
std::vector<NodeId> x_path = path_to_forest_root(attrs, id);
std::vector<NodeId> y_path = path_to_forest_root(attrs, neighbor_id);
if (x_path.back() != y_path.back())
{
// paths are disjoint -> can augment
augment(attrs, x_path, y_path, outer_unvisited_nodes);
break;
}
else
{
// Paths are not disjoint -> contract the new blossom
contract_blossom(attrs, x_path, y_path, outer_unvisited_nodes);
}
}
}
attrs.scanned[id] = true;
}
};
void find_greedy_matching(Graph const & graph, GraphAttributes & attrs)
{
attrs.reset_matching();
for(NodeId node_id = 0; node_id < graph.num_nodes(); ++node_id)
{
if (attrs.mu[node_id] == node_id) {
for(NodeId const neighbor_id : graph.node(node_id).neighbors())
{
if(attrs.mu[neighbor_id] == neighbor_id)
{
attrs.mu[neighbor_id] = node_id;
attrs.mu[node_id] = neighbor_id;
break;
}
}
}
}
}
Graph maximum_matching(Graph & graph) {
GraphAttributes attrs(graph.num_nodes());
attrs.reset_forest();
find_greedy_matching(graph, attrs);
check_integrity(attrs);
maximum_matching_from_initial_matching(graph, attrs);
ED::Graph matching = ED::Graph(graph.num_nodes());
for (NodeId id = 0; id < graph.num_nodes(); ++id)
{
if (attrs.mu[id] > id)
{
matching.add_edge(id, attrs.mu[id]);
}
}
return matching;
}
}
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