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cliques.cc
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cliques.cc
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// Copyright 2010-2022 Google LLC
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
#include "ortools/graph/cliques.h"
#include <algorithm>
#include <functional>
#include <memory>
#include <utility>
#include <vector>
#include "absl/container/flat_hash_set.h"
#include "ortools/base/hash.h"
namespace operations_research {
namespace {
// Encapsulates graph() to make all nodes self-connected.
inline bool Connects(std::function<bool(int, int)> graph, int i, int j) {
return i == j || graph(i, j);
}
// Implements the recursive step of the Bron-Kerbosch algorithm with pivoting.
// - graph is a callback such that graph->Run(i, j) returns true iff there is an
// arc between i and j.
// - callback is a callback called for all maximal cliques discovered by the
// algorithm.
// - input_candidates is an array that contains the list of nodes connected to
// all nodes in the current clique. It is composed of two parts; the first
// part contains the "not" set (nodes that were already processed and must not
// be added to the clique - see the description of the algorithm in the
// paper), and nodes that are candidates for addition. The candidates from the
// "not" set are at the beginning of the array.
// - first_candidate_index elements is the index of the first candidate that is
// not in the "not" set (which is also the number of candidates in the "not"
// set).
// - num_input_candidates is the number of elements in input_candidates,
// including both the "not" set and the actual candidates.
// - current_clique is the current clique discovered by the algorithm.
// - stop is a stopping condition for the algorithm; if the value it points to
// is true, the algorithm stops further exploration and returns.
// TODO(user) : rewrite this algorithm without recursion.
void Search(std::function<bool(int, int)> graph,
std::function<bool(const std::vector<int>&)> callback,
int* input_candidates, int first_candidate_index,
int num_input_candidates, std::vector<int>* current_clique,
bool* stop) {
// The pivot is a node from input_candidates that is disconnected from the
// minimal number of nodes in the actual candidates (excluding the "not" set);
// the algorithm then selects only candidates that are disconnected from the
// pivot (and the pivot itself), to reach the termination condition as quickly
// as possible (see the original paper for more details).
int pivot = 0;
// A node that is disconnected from the selected pivot. This node is selected
// during the pivot matching phase to speed up the first iteration of the
// recursive call.
int disconnected_node = 0;
// The number of candidates (that are not in "not") disconnected from the
// selected pivot. The value is computed during pivot selection. In the
// "recursive" phase, we only need to do explore num_disconnected_candidates
// nodes, because after this step, all remaining candidates will all be
// connected to the pivot node (which is in "not"), so they can't form a
// maximal clique.
int num_disconnected_candidates = num_input_candidates;
// If the selected pivot is not in "not", we need to process one more
// candidate (the pivot itself). pre_increment is added to
// num_disconnected_candidates to compensate for this fact.
int pre_increment = 0;
// Find Pivot.
for (int i = 0; i < num_input_candidates && num_disconnected_candidates != 0;
++i) {
int pivot_candidate = input_candidates[i];
// Count is the number of candidates (not including nodes in the "not" set)
// that are disconnected from the pivot candidate.
int count = 0;
// The index of a candidate node that is not connected to pivot_candidate.
// This node will be used to quickly start the nested iteration (we keep
// track of the index so that we don't have to find a node that is
// disconnected from the pivot later in the iteration).
int disconnected_node_candidate = 0;
// Compute the number of candidate nodes that are disconnected from
// pivot_candidate. Note that this computation is the same for the "not"
// candidates and the normal candidates.
for (int j = first_candidate_index;
j < num_input_candidates && count < num_disconnected_candidates; ++j) {
if (!Connects(graph, pivot_candidate, input_candidates[j])) {
count++;
disconnected_node_candidate = j;
}
}
// Update the pivot candidate if we found a new minimum for
// num_disconnected_candidates.
if (count < num_disconnected_candidates) {
pivot = pivot_candidate;
num_disconnected_candidates = count;
if (i < first_candidate_index) {
disconnected_node = disconnected_node_candidate;
} else {
disconnected_node = i;
// The pivot candidate is not in the "not" set. We need to pre-increment
// the counter for the node to compensate for that.
pre_increment = 1;
}
}
}
std::vector<int> new_candidates;
new_candidates.reserve(num_input_candidates);
for (int remaining_candidates = num_disconnected_candidates + pre_increment;
remaining_candidates >= 1; remaining_candidates--) {
// Swap a node that is disconnected from the pivot (or the pivot itself)
// with the first candidate, so that we can later move it to "not" simply by
// increasing the index of the first candidate that is not in "not".
const int selected = input_candidates[disconnected_node];
std::swap(input_candidates[disconnected_node],
input_candidates[first_candidate_index]);
// Fill the list of candidates and the "not" set for the recursive call:
new_candidates.clear();
for (int i = 0; i < first_candidate_index; ++i) {
if (Connects(graph, selected, input_candidates[i])) {
new_candidates.push_back(input_candidates[i]);
}
}
const int new_first_candidate_index = new_candidates.size();
for (int i = first_candidate_index + 1; i < num_input_candidates; ++i) {
if (Connects(graph, selected, input_candidates[i])) {
new_candidates.push_back(input_candidates[i]);
}
}
const int new_candidate_size = new_candidates.size();
// Add the selected candidate to the current clique.
current_clique->push_back(selected);
// If there are no remaining candidates, we have found a maximal clique.
// Otherwise, do the recursive step.
if (new_candidate_size == 0) {
*stop = callback(*current_clique);
} else {
if (new_first_candidate_index < new_candidate_size) {
Search(graph, callback, new_candidates.data(),
new_first_candidate_index, new_candidate_size, current_clique,
stop);
if (*stop) {
return;
}
}
}
// Remove the selected candidate from the current clique.
current_clique->pop_back();
// Add the selected candidate to the set "not" - we've already processed
// all possible maximal cliques that use this node in 'current_clique'. The
// current candidate is the element of the new candidate set, so we can move
// it to "not" simply by increasing first_candidate_index.
first_candidate_index++;
// Find the next candidate that is disconnected from the pivot.
if (remaining_candidates > 1) {
disconnected_node = first_candidate_index;
while (disconnected_node < num_input_candidates &&
Connects(graph, pivot, input_candidates[disconnected_node])) {
disconnected_node++;
}
}
}
}
class FindAndEliminate {
public:
FindAndEliminate(std::function<bool(int, int)> graph, int node_count,
std::function<bool(const std::vector<int>&)> callback)
: graph_(graph), node_count_(node_count), callback_(callback) {}
bool GraphCallback(int node1, int node2) {
if (visited_.find(
std::make_pair(std::min(node1, node2), std::max(node1, node2))) !=
visited_.end()) {
return false;
}
return Connects(graph_, node1, node2);
}
bool SolutionCallback(const std::vector<int>& solution) {
const int size = solution.size();
if (size > 1) {
for (int i = 0; i < size - 1; ++i) {
for (int j = i + 1; j < size; ++j) {
visited_.insert(std::make_pair(std::min(solution[i], solution[j]),
std::max(solution[i], solution[j])));
}
}
callback_(solution);
}
return false;
}
private:
std::function<bool(int, int)> graph_;
int node_count_;
std::function<bool(const std::vector<int>&)> callback_;
absl::flat_hash_set<std::pair<int, int>> visited_;
};
} // namespace
// This method implements the 'version2' of the Bron-Kerbosch
// algorithm to find all maximal cliques in a undirected graph.
void FindCliques(std::function<bool(int, int)> graph, int node_count,
std::function<bool(const std::vector<int>&)> callback) {
std::unique_ptr<int[]> initial_candidates(new int[node_count]);
std::vector<int> actual;
for (int c = 0; c < node_count; ++c) {
initial_candidates[c] = c;
}
bool stop = false;
Search(graph, callback, initial_candidates.get(), 0, node_count, &actual,
&stop);
}
void CoverArcsByCliques(std::function<bool(int, int)> graph, int node_count,
std::function<bool(const std::vector<int>&)> callback) {
FindAndEliminate cache(graph, node_count, callback);
std::unique_ptr<int[]> initial_candidates(new int[node_count]);
std::vector<int> actual;
std::function<bool(int, int)> cached_graph = [&cache](int i, int j) {
return cache.GraphCallback(i, j);
};
std::function<bool(const std::vector<int>&)> cached_callback =
[&cache](const std::vector<int>& res) {
return cache.SolutionCallback(res);
};
for (int c = 0; c < node_count; ++c) {
initial_candidates[c] = c;
}
bool stop = false;
Search(cached_graph, cached_callback, initial_candidates.get(), 0, node_count,
&actual, &stop);
}
} // namespace operations_research