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local_search.cc
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local_search.cc
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// Copyright 2010-2024 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 <algorithm>
#include <cmath>
#include <cstddef>
#include <cstdint>
#include <functional>
#include <limits>
#include <memory>
#include <numeric>
#include <optional>
#include <random>
#include <string>
#include <utility>
#include <vector>
#include "absl/algorithm/container.h"
#include "absl/container/flat_hash_map.h"
#include "absl/container/flat_hash_set.h"
#include "absl/flags/flag.h"
#include "absl/log/check.h"
#include "absl/random/distributions.h"
#include "absl/random/random.h"
#include "absl/strings/str_cat.h"
#include "absl/strings/str_format.h"
#include "absl/strings/string_view.h"
#include "absl/time/time.h"
#include "absl/types/span.h"
#include "ortools/base/iterator_adaptors.h"
#include "ortools/base/logging.h"
#include "ortools/base/map_util.h"
#include "ortools/base/strong_int.h"
#include "ortools/base/strong_vector.h"
#include "ortools/base/timer.h"
#include "ortools/constraint_solver/constraint_solver.h"
#include "ortools/constraint_solver/constraint_solveri.h"
#include "ortools/graph/hamiltonian_path.h"
#include "ortools/util/bitset.h"
#include "ortools/util/saturated_arithmetic.h"
ABSL_FLAG(int, cp_local_search_sync_frequency, 16,
"Frequency of checks for better solutions in the solution pool.");
ABSL_FLAG(int, cp_local_search_tsp_opt_size, 13,
"Size of TSPs solved in the TSPOpt operator.");
ABSL_FLAG(int, cp_local_search_tsp_lns_size, 10,
"Size of TSPs solved in the TSPLns operator.");
ABSL_FLAG(bool, cp_use_empty_path_symmetry_breaker, true,
"If true, equivalent empty paths are removed from the neighborhood "
"of PathOperators");
namespace operations_research {
// Utility methods to ensure the communication between local search and the
// search.
// Returns true if a local optimum has been reached and cannot be improved.
bool LocalOptimumReached(Search* search);
// Returns true if the search accepts the delta (actually checking this by
// calling AcceptDelta on the monitors of the search).
bool AcceptDelta(Search* search, Assignment* delta, Assignment* deltadelta);
// Notifies the search that a neighbor has been accepted by local search.
void AcceptNeighbor(Search* search);
void AcceptUncheckedNeighbor(Search* search);
// ----- Base operator class for operators manipulating IntVars -----
bool IntVarLocalSearchOperator::MakeNextNeighbor(Assignment* delta,
Assignment* deltadelta) {
CHECK(delta != nullptr);
VLOG(2) << DebugString() << "::MakeNextNeighbor(delta=("
<< delta->DebugString() << "), deltadelta=("
<< (deltadelta ? deltadelta->DebugString() : std::string("nullptr"));
while (true) {
RevertChanges(true);
if (!MakeOneNeighbor()) {
return false;
}
if (ApplyChanges(delta, deltadelta)) {
VLOG(2) << "Delta (" << DebugString() << ") = " << delta->DebugString();
return true;
}
}
return false;
}
// TODO(user): Make this a pure virtual.
bool IntVarLocalSearchOperator::MakeOneNeighbor() { return true; }
// ----- Base Large Neighborhood Search operator -----
BaseLns::BaseLns(const std::vector<IntVar*>& vars)
: IntVarLocalSearchOperator(vars) {}
BaseLns::~BaseLns() {}
bool BaseLns::MakeOneNeighbor() {
fragment_.clear();
if (NextFragment()) {
for (int candidate : fragment_) {
Deactivate(candidate);
}
return true;
}
return false;
}
void BaseLns::OnStart() { InitFragments(); }
void BaseLns::InitFragments() {}
void BaseLns::AppendToFragment(int index) {
if (index >= 0 && index < Size()) {
fragment_.push_back(index);
}
}
int BaseLns::FragmentSize() const { return fragment_.size(); }
// ----- Simple Large Neighborhood Search operator -----
// Frees number_of_variables (contiguous in vars) variables.
namespace {
class SimpleLns : public BaseLns {
public:
SimpleLns(const std::vector<IntVar*>& vars, int number_of_variables)
: BaseLns(vars), index_(0), number_of_variables_(number_of_variables) {
CHECK_GT(number_of_variables_, 0);
}
~SimpleLns() override {}
void InitFragments() override { index_ = 0; }
bool NextFragment() override;
std::string DebugString() const override { return "SimpleLns"; }
private:
int index_;
const int number_of_variables_;
};
bool SimpleLns::NextFragment() {
const int size = Size();
if (index_ < size) {
for (int i = index_; i < index_ + number_of_variables_; ++i) {
AppendToFragment(i % size);
}
++index_;
return true;
}
return false;
}
// ----- Random Large Neighborhood Search operator -----
// Frees up to number_of_variables random variables.
class RandomLns : public BaseLns {
public:
RandomLns(const std::vector<IntVar*>& vars, int number_of_variables,
int32_t seed)
: BaseLns(vars), rand_(seed), number_of_variables_(number_of_variables) {
CHECK_GT(number_of_variables_, 0);
CHECK_LE(number_of_variables_, Size());
}
~RandomLns() override {}
bool NextFragment() override;
std::string DebugString() const override { return "RandomLns"; }
private:
std::mt19937 rand_;
const int number_of_variables_;
};
bool RandomLns::NextFragment() {
DCHECK_GT(Size(), 0);
for (int i = 0; i < number_of_variables_; ++i) {
AppendToFragment(absl::Uniform<int>(rand_, 0, Size()));
}
return true;
}
} // namespace
LocalSearchOperator* Solver::MakeRandomLnsOperator(
const std::vector<IntVar*>& vars, int number_of_variables) {
return MakeRandomLnsOperator(vars, number_of_variables, CpRandomSeed());
}
LocalSearchOperator* Solver::MakeRandomLnsOperator(
const std::vector<IntVar*>& vars, int number_of_variables, int32_t seed) {
return RevAlloc(new RandomLns(vars, number_of_variables, seed));
}
// ----- Move Toward Target Local Search operator -----
// A local search operator that compares the current assignment with a target
// one, and that generates neighbors corresponding to a single variable being
// changed from its current value to its target value.
namespace {
class MoveTowardTargetLS : public IntVarLocalSearchOperator {
public:
MoveTowardTargetLS(const std::vector<IntVar*>& variables,
const std::vector<int64_t>& target_values)
: IntVarLocalSearchOperator(variables),
target_(target_values),
// Initialize variable_index_ at the number of the of variables minus
// one, so that the first to be tried (after one increment) is the one
// of index 0.
variable_index_(Size() - 1) {
CHECK_EQ(target_values.size(), variables.size()) << "Illegal arguments.";
}
~MoveTowardTargetLS() override {}
std::string DebugString() const override { return "MoveTowardTargetLS"; }
protected:
// Make a neighbor assigning one variable to its target value.
bool MakeOneNeighbor() override {
while (num_var_since_last_start_ < Size()) {
++num_var_since_last_start_;
variable_index_ = (variable_index_ + 1) % Size();
const int64_t target_value = target_.at(variable_index_);
const int64_t current_value = OldValue(variable_index_);
if (current_value != target_value) {
SetValue(variable_index_, target_value);
return true;
}
}
return false;
}
private:
void OnStart() override {
// Do not change the value of variable_index_: this way, we keep going from
// where we last modified something. This is because we expect that most
// often, the variables we have just checked are less likely to be able
// to be changed to their target values than the ones we have not yet
// checked.
//
// Consider the case where oddly indexed variables can be assigned to their
// target values (no matter in what order they are considered), while even
// indexed ones cannot. Restarting at index 0 each time an odd-indexed
// variable is modified will cause a total of Theta(n^2) neighbors to be
// generated, while not restarting will produce only Theta(n) neighbors.
CHECK_GE(variable_index_, 0);
CHECK_LT(variable_index_, Size());
num_var_since_last_start_ = 0;
}
// Target values
const std::vector<int64_t> target_;
// Index of the next variable to try to restore
int64_t variable_index_;
// Number of variables checked since the last call to OnStart().
int64_t num_var_since_last_start_;
};
} // namespace
LocalSearchOperator* Solver::MakeMoveTowardTargetOperator(
const Assignment& target) {
typedef std::vector<IntVarElement> Elements;
const Elements& elements = target.IntVarContainer().elements();
// Copy target values and construct the vector of variables
std::vector<IntVar*> vars;
std::vector<int64_t> values;
vars.reserve(target.NumIntVars());
values.reserve(target.NumIntVars());
for (const auto& it : elements) {
vars.push_back(it.Var());
values.push_back(it.Value());
}
return MakeMoveTowardTargetOperator(vars, values);
}
LocalSearchOperator* Solver::MakeMoveTowardTargetOperator(
const std::vector<IntVar*>& variables,
const std::vector<int64_t>& target_values) {
return RevAlloc(new MoveTowardTargetLS(variables, target_values));
}
// ----- ChangeValue Operators -----
ChangeValue::ChangeValue(const std::vector<IntVar*>& vars)
: IntVarLocalSearchOperator(vars), index_(0) {}
ChangeValue::~ChangeValue() {}
bool ChangeValue::MakeOneNeighbor() {
const int size = Size();
while (index_ < size) {
const int64_t value = ModifyValue(index_, Value(index_));
SetValue(index_, value);
++index_;
return true;
}
return false;
}
void ChangeValue::OnStart() { index_ = 0; }
// Increments the current value of variables.
namespace {
class IncrementValue : public ChangeValue {
public:
explicit IncrementValue(const std::vector<IntVar*>& vars)
: ChangeValue(vars) {}
~IncrementValue() override {}
int64_t ModifyValue(int64_t, int64_t value) override { return value + 1; }
std::string DebugString() const override { return "IncrementValue"; }
};
// Decrements the current value of variables.
class DecrementValue : public ChangeValue {
public:
explicit DecrementValue(const std::vector<IntVar*>& vars)
: ChangeValue(vars) {}
~DecrementValue() override {}
int64_t ModifyValue(int64_t, int64_t value) override { return value - 1; }
std::string DebugString() const override { return "DecrementValue"; }
};
} // namespace
// ----- Path-based Operators -----
PathOperator::PathOperator(const std::vector<IntVar*>& next_vars,
const std::vector<IntVar*>& path_vars,
IterationParameters iteration_parameters)
: IntVarLocalSearchOperator(next_vars, true),
number_of_nexts_(next_vars.size()),
ignore_path_vars_(path_vars.empty()),
base_nodes_(iteration_parameters.number_of_base_nodes),
base_alternatives_(iteration_parameters.number_of_base_nodes),
base_sibling_alternatives_(iteration_parameters.number_of_base_nodes),
end_nodes_(iteration_parameters.number_of_base_nodes),
base_paths_(iteration_parameters.number_of_base_nodes),
node_path_starts_(number_of_nexts_, -1),
node_path_ends_(number_of_nexts_, -1),
calls_per_base_node_(iteration_parameters.number_of_base_nodes, 0),
just_started_(false),
first_start_(true),
next_base_to_increment_(iteration_parameters.number_of_base_nodes),
iteration_parameters_(std::move(iteration_parameters)),
optimal_paths_enabled_(false),
active_paths_(number_of_nexts_),
alternative_index_(next_vars.size(), -1) {
DCHECK_GT(iteration_parameters_.number_of_base_nodes, 0);
if (!ignore_path_vars_) {
AddVars(path_vars);
}
path_basis_.push_back(0);
for (int i = 1; i < base_nodes_.size(); ++i) {
if (!OnSamePathAsPreviousBase(i)) path_basis_.push_back(i);
}
if ((path_basis_.size() > 2) ||
(!next_vars.empty() && !next_vars.back()
->solver()
->parameters()
.skip_locally_optimal_paths())) {
iteration_parameters_.skip_locally_optimal_paths = false;
}
}
void PathOperator::Reset() { active_paths_.Clear(); }
void PathOperator::OnStart() {
optimal_paths_enabled_ = false;
InitializeBaseNodes();
InitializeAlternatives();
OnNodeInitialization();
}
bool PathOperator::MakeOneNeighbor() {
while (IncrementPosition()) {
// Need to revert changes here since MakeNeighbor might have returned false
// and have done changes in the previous iteration.
RevertChanges(true);
if (MakeNeighbor()) {
return true;
}
}
return false;
}
bool PathOperator::SkipUnchanged(int index) const {
if (ignore_path_vars_) {
return true;
}
if (index < number_of_nexts_) {
int path_index = index + number_of_nexts_;
return Value(path_index) == OldValue(path_index);
}
int next_index = index - number_of_nexts_;
return Value(next_index) == OldValue(next_index);
}
bool PathOperator::MoveChain(int64_t before_chain, int64_t chain_end,
int64_t destination) {
if (destination == before_chain || destination == chain_end) return false;
DCHECK(CheckChainValidity(before_chain, chain_end, destination) &&
!IsPathEnd(chain_end) && !IsPathEnd(destination));
const int64_t destination_path = Path(destination);
const int64_t after_chain = Next(chain_end);
SetNext(chain_end, Next(destination), destination_path);
if (!ignore_path_vars_) {
int current = destination;
int next = Next(before_chain);
while (current != chain_end) {
SetNext(current, next, destination_path);
current = next;
next = Next(next);
}
} else {
SetNext(destination, Next(before_chain), destination_path);
}
SetNext(before_chain, after_chain, Path(before_chain));
return true;
}
bool PathOperator::ReverseChain(int64_t before_chain, int64_t after_chain,
int64_t* chain_last) {
if (CheckChainValidity(before_chain, after_chain, -1)) {
int64_t path = Path(before_chain);
int64_t current = Next(before_chain);
if (current == after_chain) {
return false;
}
int64_t current_next = Next(current);
SetNext(current, after_chain, path);
while (current_next != after_chain) {
const int64_t next = Next(current_next);
SetNext(current_next, current, path);
current = current_next;
current_next = next;
}
SetNext(before_chain, current, path);
*chain_last = current;
return true;
}
return false;
}
bool PathOperator::MakeActive(int64_t node, int64_t destination) {
if (!IsPathEnd(destination)) {
int64_t destination_path = Path(destination);
SetNext(node, Next(destination), destination_path);
SetNext(destination, node, destination_path);
return true;
}
return false;
}
bool PathOperator::MakeChainInactive(int64_t before_chain, int64_t chain_end) {
const int64_t kNoPath = -1;
if (CheckChainValidity(before_chain, chain_end, -1) &&
!IsPathEnd(chain_end)) {
const int64_t after_chain = Next(chain_end);
int64_t current = Next(before_chain);
while (current != after_chain) {
const int64_t next = Next(current);
SetNext(current, current, kNoPath);
current = next;
}
SetNext(before_chain, after_chain, Path(before_chain));
return true;
}
return false;
}
bool PathOperator::SwapActiveAndInactive(int64_t active, int64_t inactive) {
if (active == inactive) return false;
const int64_t prev = Prev(active);
return MakeChainInactive(prev, active) && MakeActive(inactive, prev);
}
bool PathOperator::IncrementPosition() {
const int base_node_size = iteration_parameters_.number_of_base_nodes;
if (just_started_) {
just_started_ = false;
return true;
}
const int number_of_paths = path_starts_.size();
// Finding next base node positions.
// Increment the position of inner base nodes first (higher index nodes);
// if a base node is at the end of a path, reposition it at the start
// of the path and increment the position of the preceding base node (this
// action is called a restart).
int last_restarted = base_node_size;
for (int i = base_node_size - 1; i >= 0; --i) {
if (base_nodes_[i] < number_of_nexts_ && i <= next_base_to_increment_) {
if (ConsiderAlternatives(i)) {
// Iterate on sibling alternatives.
const int sibling_alternative_index =
GetSiblingAlternativeIndex(base_nodes_[i]);
if (sibling_alternative_index >= 0) {
if (base_sibling_alternatives_[i] <
alternative_sets_[sibling_alternative_index].size() - 1) {
++base_sibling_alternatives_[i];
break;
}
base_sibling_alternatives_[i] = 0;
}
// Iterate on base alternatives.
const int alternative_index = alternative_index_[base_nodes_[i]];
if (alternative_index >= 0) {
if (base_alternatives_[i] <
alternative_sets_[alternative_index].size() - 1) {
++base_alternatives_[i];
break;
}
base_alternatives_[i] = 0;
base_sibling_alternatives_[i] = 0;
}
}
if (iteration_parameters_.get_neighbors != nullptr &&
++calls_per_base_node_[i] <
iteration_parameters_.get_neighbors(BaseNode(i), StartNode(i))
.size()) {
break;
}
calls_per_base_node_[i] = 0;
base_alternatives_[i] = 0;
base_sibling_alternatives_[i] = 0;
base_nodes_[i] = OldNext(base_nodes_[i]);
if (iteration_parameters_.accept_path_end_base ||
!IsPathEnd(base_nodes_[i]))
break;
}
calls_per_base_node_[i] = 0;
base_alternatives_[i] = 0;
base_sibling_alternatives_[i] = 0;
base_nodes_[i] = StartNode(i);
last_restarted = i;
}
next_base_to_increment_ = base_node_size;
// At the end of the loop, base nodes with indexes in
// [last_restarted, base_node_size[ have been restarted.
// Restarted base nodes are then repositioned by the virtual
// GetBaseNodeRestartPosition to reflect position constraints between
// base nodes (by default GetBaseNodeRestartPosition leaves the nodes
// at the start of the path).
// Base nodes are repositioned in ascending order to ensure that all
// base nodes "below" the node being repositioned have their final
// position.
for (int i = last_restarted; i < base_node_size; ++i) {
calls_per_base_node_[i] = 0;
base_alternatives_[i] = 0;
base_sibling_alternatives_[i] = 0;
base_nodes_[i] = GetBaseNodeRestartPosition(i);
}
if (last_restarted > 0) {
return CheckEnds();
}
// If all base nodes have been restarted, base nodes are moved to new paths.
// First we mark the current paths as locally optimal if they have been
// completely explored.
if (optimal_paths_enabled_ &&
iteration_parameters_.skip_locally_optimal_paths) {
if (path_basis_.size() > 1) {
for (int i = 1; i < path_basis_.size(); ++i) {
active_paths_.DeactivatePathPair(StartNode(path_basis_[i - 1]),
StartNode(path_basis_[i]));
}
} else {
active_paths_.DeactivatePathPair(StartNode(path_basis_[0]),
StartNode(path_basis_[0]));
}
}
std::vector<int> current_starts(base_node_size);
for (int i = 0; i < base_node_size; ++i) {
current_starts[i] = StartNode(i);
}
// Exploration of next paths can lead to locally optimal paths since we are
// exploring them from scratch.
optimal_paths_enabled_ = true;
while (true) {
for (int i = base_node_size - 1; i >= 0; --i) {
const int next_path_index = base_paths_[i] + 1;
if (next_path_index < number_of_paths) {
base_paths_[i] = next_path_index;
calls_per_base_node_[i] = 0;
base_alternatives_[i] = 0;
base_sibling_alternatives_[i] = 0;
base_nodes_[i] = path_starts_[next_path_index];
if (i == 0 || !OnSamePathAsPreviousBase(i)) {
break;
}
} else {
base_paths_[i] = 0;
calls_per_base_node_[i] = 0;
base_alternatives_[i] = 0;
base_sibling_alternatives_[i] = 0;
base_nodes_[i] = path_starts_[0];
}
}
if (!iteration_parameters_.skip_locally_optimal_paths) return CheckEnds();
// If the new paths have already been completely explored, we can
// skip them from now on.
if (path_basis_.size() > 1) {
for (int j = 1; j < path_basis_.size(); ++j) {
if (active_paths_.IsPathPairActive(StartNode(path_basis_[j - 1]),
StartNode(path_basis_[j]))) {
return CheckEnds();
}
}
} else {
if (active_paths_.IsPathPairActive(StartNode(path_basis_[0]),
StartNode(path_basis_[0]))) {
return CheckEnds();
}
}
// If we are back to paths we just iterated on or have reached the end
// of the neighborhood search space, we can stop.
if (!CheckEnds()) return false;
bool stop = true;
for (int i = 0; i < base_node_size; ++i) {
if (StartNode(i) != current_starts[i]) {
stop = false;
break;
}
}
if (stop) return false;
}
return CheckEnds();
}
void PathOperator::InitializePathStarts() {
// Detect nodes which do not have any possible predecessor in a path; these
// nodes are path starts.
int max_next = -1;
std::vector<bool> has_prevs(number_of_nexts_, false);
for (int i = 0; i < number_of_nexts_; ++i) {
const int next = OldNext(i);
if (next < number_of_nexts_) {
has_prevs[next] = true;
}
max_next = std::max(max_next, next);
}
// Update locally optimal paths.
if (iteration_parameters_.skip_locally_optimal_paths) {
active_paths_.Initialize(
/*is_start=*/[&has_prevs](int node) { return !has_prevs[node]; });
for (int i = 0; i < number_of_nexts_; ++i) {
if (!has_prevs[i]) {
int current = i;
while (!IsPathEnd(current)) {
if ((OldNext(current) != PrevNext(current))) {
active_paths_.ActivatePath(i);
break;
}
current = OldNext(current);
}
}
}
}
// Create a list of path starts, dropping equivalent path starts of
// currently empty paths.
std::vector<bool> empty_found(number_of_nexts_, false);
std::vector<int64_t> new_path_starts;
const bool use_empty_path_symmetry_breaker =
absl::GetFlag(FLAGS_cp_use_empty_path_symmetry_breaker);
for (int i = 0; i < number_of_nexts_; ++i) {
if (!has_prevs[i]) {
if (use_empty_path_symmetry_breaker && IsPathEnd(OldNext(i))) {
if (iteration_parameters_.start_empty_path_class != nullptr) {
if (empty_found[iteration_parameters_.start_empty_path_class(i)])
continue;
empty_found[iteration_parameters_.start_empty_path_class(i)] = true;
}
}
new_path_starts.push_back(i);
}
}
if (!first_start_) {
// Synchronizing base_paths_ with base node positions. When the last move
// was performed a base node could have been moved to a new route in which
// case base_paths_ needs to be updated. This needs to be done on the path
// starts before we re-adjust base nodes for new path starts.
std::vector<int> node_paths(max_next + 1, -1);
for (int i = 0; i < path_starts_.size(); ++i) {
int node = path_starts_[i];
while (!IsPathEnd(node)) {
node_paths[node] = i;
node = OldNext(node);
}
node_paths[node] = i;
}
for (int j = 0; j < iteration_parameters_.number_of_base_nodes; ++j) {
// Always restart from first alternative.
calls_per_base_node_[j] = 0;
base_alternatives_[j] = 0;
base_sibling_alternatives_[j] = 0;
if (IsInactive(base_nodes_[j]) || node_paths[base_nodes_[j]] == -1) {
// Base node was made inactive or was moved to a new path, reposition
// the base node to the start of the path on which it was.
base_nodes_[j] = path_starts_[base_paths_[j]];
} else {
base_paths_[j] = node_paths[base_nodes_[j]];
}
}
// Re-adjust current base_nodes and base_paths to take into account new
// path starts (there could be fewer if a new path was made empty, or more
// if nodes were added to a formerly empty path).
int new_index = 0;
absl::flat_hash_set<int> found_bases;
for (int i = 0; i < path_starts_.size(); ++i) {
int index = new_index;
// Note: old and new path starts are sorted by construction.
while (index < new_path_starts.size() &&
new_path_starts[index] < path_starts_[i]) {
++index;
}
const bool found = (index < new_path_starts.size() &&
new_path_starts[index] == path_starts_[i]);
if (found) {
new_index = index;
}
for (int j = 0; j < iteration_parameters_.number_of_base_nodes; ++j) {
if (base_paths_[j] == i && !found_bases.contains(j)) {
found_bases.insert(j);
base_paths_[j] = new_index;
// If the current position of the base node is a removed empty path,
// readjusting it to the last visited path start.
if (!found) {
base_nodes_[j] = new_path_starts[new_index];
}
}
}
}
}
path_starts_.swap(new_path_starts);
// For every base path, store the end corresponding to the path start.
// TODO(user): make this faster, maybe by pairing starts with ends.
path_ends_.clear();
path_ends_.reserve(path_starts_.size());
int64_t max_node_index = number_of_nexts_ - 1;
for (const int start_node : path_starts_) {
int64_t node = start_node;
while (!IsPathEnd(node)) node = OldNext(node);
path_ends_.push_back(node);
max_node_index = std::max(max_node_index, node);
}
node_path_starts_.assign(max_node_index + 1, -1);
node_path_ends_.assign(max_node_index + 1, -1);
for (int i = 0; i < path_starts_.size(); ++i) {
const int64_t start_node = path_starts_[i];
const int64_t end_node = path_ends_[i];
int64_t node = start_node;
while (!IsPathEnd(node)) {
node_path_starts_[node] = start_node;
node_path_ends_[node] = end_node;
node = OldNext(node);
}
node_path_starts_[node] = start_node;
node_path_ends_[node] = end_node;
}
}
void PathOperator::InitializeInactives() {
inactives_.clear();
for (int i = 0; i < number_of_nexts_; ++i) {
inactives_.push_back(OldNext(i) == i);
}
}
void PathOperator::InitializeBaseNodes() {
// Inactive nodes must be detected before determining new path starts.
InitializeInactives();
InitializePathStarts();
if (first_start_ || InitPosition()) {
// Only do this once since the following starts will continue from the
// preceding position
for (int i = 0; i < iteration_parameters_.number_of_base_nodes; ++i) {
base_paths_[i] = 0;
base_nodes_[i] = path_starts_[0];
}
first_start_ = false;
}
for (int i = 0; i < iteration_parameters_.number_of_base_nodes; ++i) {
// If base node has been made inactive, restart from path start.
int64_t base_node = base_nodes_[i];
if (RestartAtPathStartOnSynchronize() || IsInactive(base_node)) {
base_node = path_starts_[base_paths_[i]];
base_nodes_[i] = base_node;
}
end_nodes_[i] = base_node;
}
// Repair end_nodes_ in case some must be on the same path and are not anymore
// (due to other operators moving these nodes).
for (int i = 1; i < iteration_parameters_.number_of_base_nodes; ++i) {
if (OnSamePathAsPreviousBase(i) &&
!OnSamePath(base_nodes_[i - 1], base_nodes_[i])) {
const int64_t base_node = base_nodes_[i - 1];
base_nodes_[i] = base_node;
end_nodes_[i] = base_node;
base_paths_[i] = base_paths_[i - 1];
}
}
for (int i = 0; i < iteration_parameters_.number_of_base_nodes; ++i) {
base_alternatives_[i] = 0;
base_sibling_alternatives_[i] = 0;
calls_per_base_node_[i] = 0;
}
just_started_ = true;
}
void PathOperator::InitializeAlternatives() {
active_in_alternative_set_.resize(alternative_sets_.size(), -1);
for (int i = 0; i < alternative_sets_.size(); ++i) {
const int64_t current_active = active_in_alternative_set_[i];
if (current_active >= 0 && !IsInactive(current_active)) continue;
for (int64_t index : alternative_sets_[i]) {
if (!IsInactive(index)) {
active_in_alternative_set_[i] = index;
break;
}
}
}
}
bool PathOperator::OnSamePath(int64_t node1, int64_t node2) const {
if (IsInactive(node1) != IsInactive(node2)) {
return false;
}
for (int node = node1; !IsPathEnd(node); node = OldNext(node)) {
if (node == node2) {
return true;
}
}
for (int node = node2; !IsPathEnd(node); node = OldNext(node)) {
if (node == node1) {
return true;
}
}
return false;
}
// Rejects chain if chain_end is not after before_chain on the path or if
// the chain contains exclude. Given before_chain is the node before the
// chain, if before_chain and chain_end are the same the chain is rejected too.
// Also rejects cycles (cycle detection is detected through chain length
// overflow).
bool PathOperator::CheckChainValidity(int64_t before_chain, int64_t chain_end,
int64_t exclude) const {
if (before_chain == chain_end || before_chain == exclude) return false;
int64_t current = before_chain;
int chain_size = 0;
while (current != chain_end) {
if (chain_size > number_of_nexts_) {
return false;
}
if (IsPathEnd(current)) {
return false;
}
current = Next(current);
++chain_size;
if (current == exclude) {
return false;
}
}
return true;
}
// ----- 2Opt -----
// Reverses a sub-chain of a path. It is called 2Opt because it breaks
// 2 arcs on the path; resulting paths are called 2-optimal.
// Possible neighbors for the path 1 -> 2 -> 3 -> 4 -> 5
// (where (1, 5) are first and last nodes of the path and can therefore not be
// moved):
// 1 -> 3 -> 2 -> 4 -> 5
// 1 -> 4 -> 3 -> 2 -> 5
// 1 -> 2 -> 4 -> 3 -> 5
class TwoOpt : public PathOperator {
public:
TwoOpt(
const std::vector<IntVar*>& vars,
const std::vector<IntVar*>& secondary_vars,
std::function<int(int64_t)> start_empty_path_class,
std::function<const std::vector<int>&(int, int)> get_neighbors = nullptr)
: PathOperator(
vars, secondary_vars, get_neighbors == nullptr ? 2 : 1,
/*skip_locally_optimal_paths=*/true, /*accept_path_end_base=*/true,
std::move(start_empty_path_class), std::move(get_neighbors)),
last_base_(-1),
last_(-1) {}
~TwoOpt() override {}
bool MakeNeighbor() override;
bool IsIncremental() const override { return true; }
void Reset() override {
PathOperator::Reset();
// When using metaheuristics, path operators will reactivate optimal
// routes and iterating will start at route starts, which can
// potentially be out of sync with the last incremental moves. This requires
// resetting incrementalism.
last_ = -1;
}
std::string DebugString() const override { return "TwoOpt"; }
protected:
bool OnSamePathAsPreviousBase(int64_t /*base_index*/) override {
// Both base nodes have to be on the same path.
return true;
}
int64_t GetBaseNodeRestartPosition(int base_index) override {
return (base_index == 0) ? StartNode(0) : BaseNode(0);
}
private:
void OnNodeInitialization() override { last_ = -1; }
int64_t last_base_;
int64_t last_;
};
bool TwoOpt::MakeNeighbor() {
const int64_t node0 = BaseNode(0);
int64_t node1 = -1;
if (HasNeighbors()) {
const int64_t neighbor = GetNeighborForBaseNode(0);
if (IsInactive(neighbor)) return false;
if (CurrentNodePathStart(node0) != CurrentNodePathStart(neighbor)) {
return false;
}
node1 = Next(neighbor);
} else {
DCHECK_EQ(StartNode(0), StartNode(1));
node1 = BaseNode(1);
}
// Incrementality is disabled with neighbors.
if (last_base_ != node0 || last_ == -1 || HasNeighbors()) {
RevertChanges(false);
if (IsPathEnd(node0)) {
last_ = -1;
return false;
}
last_base_ = node0;
last_ = Next(node0);
int64_t chain_last;
if (ReverseChain(node0, node1, &chain_last)
// Check there are more than one node in the chain (reversing a
// single node is a NOP).
&& last_ != chain_last) {
return true;
}
last_ = -1;
return false;
}
const int64_t to_move = Next(last_);
DCHECK_EQ(Next(to_move), node1);
return MoveChain(last_, to_move, node0);
}
// ----- Relocate -----
// Moves a sub-chain of a path to another position; the specified chain length
// is the fixed length of the chains being moved. When this length is 1 the
// operator simply moves a node to another position.
// Possible neighbors for the path 1 -> 2 -> 3 -> 4 -> 5, for a chain length
// of 2 (where (1, 5) are first and last nodes of the path and can
// therefore not be moved):
// 1 -> 4 -> 2 -> 3 -> 5
// 1 -> 3 -> 4 -> 2 -> 5
//
// Using Relocate with chain lengths of 1, 2 and 3 together is equivalent to
// the OrOpt operator on a path. The OrOpt operator is a limited version of
// 3Opt (breaks 3 arcs on a path).
class Relocate : public PathOperator {
public:
Relocate(const std::vector<IntVar*>& vars,
const std::vector<IntVar*>& secondary_vars, const std::string& name,
std::function<int(int64_t)> start_empty_path_class,
std::function<const std::vector<int>&(int, int)> get_neighbors,
int64_t chain_length = 1LL, bool single_path = false)
: PathOperator(