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nqueens.cc
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nqueens.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.
//
// N-queens problem
//
// unique solutions: http://www.research.att.com/~njas/sequences/A000170
// distinct solutions: http://www.research.att.com/~njas/sequences/A002562
#include <cstdint>
#include <cstdio>
#include <map>
#include <vector>
#include "absl/container/flat_hash_map.h"
#include "absl/strings/str_format.h"
#include "ortools/base/commandlineflags.h"
#include "ortools/base/init_google.h"
#include "ortools/base/logging.h"
#include "ortools/base/map_util.h"
#include "ortools/base/types.h"
#include "ortools/constraint_solver/constraint_solveri.h"
ABSL_FLAG(bool, print, false, "If true, print one of the solution.");
ABSL_FLAG(bool, print_all, false, "If true, print all the solutions.");
ABSL_FLAG(int, nb_loops, 1,
"Number of solving loops to perform, for performance timing.");
ABSL_FLAG(
int, size, 0,
"Size of the problem. If equal to 0, will test several increasing sizes.");
ABSL_FLAG(bool, use_symmetry, false, "Use Symmetry Breaking methods");
ABSL_DECLARE_FLAG(bool, cp_disable_solve);
static const int kNumSolutions[] = {
1, 0, 0, 2, 10, 4, 40, 92, 352, 724, 2680, 14200, 73712, 365596, 2279184};
static const int kKnownSolutions = 15;
static const int kNumUniqueSolutions[] = {
1, 0, 0, 1, 2, 1, 6, 12, 46, 92,
341, 1787, 9233, 45752, 285053, 1846955, 11977939, 83263591, 621012754};
static const int kKnownUniqueSolutions = 19;
namespace operations_research {
class NQueenSymmetry : public SymmetryBreaker {
public:
NQueenSymmetry(Solver* const s, const std::vector<IntVar*>& vars)
: solver_(s), vars_(vars), size_(vars.size()) {
for (int i = 0; i < size_; ++i) {
indices_[vars[i]] = i;
}
}
~NQueenSymmetry() override = default;
protected:
int Index(IntVar* const var) const {
return gtl::FindWithDefault(indices_, var, -1);
}
IntVar* Var(int index) const {
DCHECK_GE(index, 0);
DCHECK_LT(index, size_);
return vars_[index];
}
int size() const { return size_; }
int symmetric(int index) const { return size_ - 1 - index; }
Solver* solver() const { return solver_; }
private:
Solver* const solver_;
const std::vector<IntVar*> vars_;
absl::flat_hash_map<const IntVar*, int> indices_;
const int size_;
};
// Symmetry vertical axis.
class SX : public NQueenSymmetry {
public:
SX(Solver* const s, const std::vector<IntVar*>& vars)
: NQueenSymmetry(s, vars) {}
~SX() override = default;
void VisitSetVariableValue(IntVar* const var, int64_t value) override {
const int index = Index(var);
IntVar* const other_var = Var(symmetric(index));
AddIntegerVariableEqualValueClause(other_var, value);
}
};
// Symmetry horizontal axis.
class SY : public NQueenSymmetry {
public:
SY(Solver* const s, const std::vector<IntVar*>& vars)
: NQueenSymmetry(s, vars) {}
~SY() override = default;
void VisitSetVariableValue(IntVar* const var, int64_t value) override {
AddIntegerVariableEqualValueClause(var, symmetric(value));
}
};
// Symmetry first diagonal axis.
class SD1 : public NQueenSymmetry {
public:
SD1(Solver* const s, const std::vector<IntVar*>& vars)
: NQueenSymmetry(s, vars) {}
~SD1() override = default;
void VisitSetVariableValue(IntVar* const var, int64_t value) override {
const int index = Index(var);
IntVar* const other_var = Var(value);
AddIntegerVariableEqualValueClause(other_var, index);
}
};
// Symmetry second diagonal axis.
class SD2 : public NQueenSymmetry {
public:
SD2(Solver* const s, const std::vector<IntVar*>& vars)
: NQueenSymmetry(s, vars) {}
~SD2() override = default;
void VisitSetVariableValue(IntVar* const var, int64_t value) override {
const int index = Index(var);
IntVar* const other_var = Var(symmetric(value));
AddIntegerVariableEqualValueClause(other_var, symmetric(index));
}
};
// Rotate 1/4 turn.
class R90 : public NQueenSymmetry {
public:
R90(Solver* const s, const std::vector<IntVar*>& vars)
: NQueenSymmetry(s, vars) {}
~R90() override = default;
void VisitSetVariableValue(IntVar* const var, int64_t value) override {
const int index = Index(var);
IntVar* const other_var = Var(value);
AddIntegerVariableEqualValueClause(other_var, symmetric(index));
}
};
// Rotate 1/2 turn.
class R180 : public NQueenSymmetry {
public:
R180(Solver* const s, const std::vector<IntVar*>& vars)
: NQueenSymmetry(s, vars) {}
~R180() override = default;
void VisitSetVariableValue(IntVar* const var, int64_t value) override {
const int index = Index(var);
IntVar* const other_var = Var(symmetric(index));
AddIntegerVariableEqualValueClause(other_var, symmetric(value));
}
};
// Rotate 3/4 turn.
class R270 : public NQueenSymmetry {
public:
R270(Solver* const s, const std::vector<IntVar*>& vars)
: NQueenSymmetry(s, vars) {}
~R270() override = default;
void VisitSetVariableValue(IntVar* const var, int64_t value) override {
const int index = Index(var);
IntVar* const other_var = Var(symmetric(value));
AddIntegerVariableEqualValueClause(other_var, index);
}
};
void CheckNumberOfSolutions(int size, int num_solutions) {
if (absl::GetFlag(FLAGS_use_symmetry)) {
if (size - 1 < kKnownUniqueSolutions) {
CHECK_EQ(num_solutions, kNumUniqueSolutions[size - 1]);
} else if (!absl::GetFlag(FLAGS_cp_disable_solve)) {
CHECK_GT(num_solutions, 0);
}
} else {
if (size - 1 < kKnownSolutions) {
CHECK_EQ(num_solutions, kNumSolutions[size - 1]);
} else if (!absl::GetFlag(FLAGS_cp_disable_solve)) {
CHECK_GT(num_solutions, 0);
}
}
}
void NQueens(int size) {
CHECK_GE(size, 1);
Solver s("nqueens");
// model
std::vector<IntVar*> queens;
for (int i = 0; i < size; ++i) {
queens.push_back(
s.MakeIntVar(0, size - 1, absl::StrFormat("queen%04d", i)));
}
s.AddConstraint(s.MakeAllDifferent(queens));
std::vector<IntVar*> vars(size);
for (int i = 0; i < size; ++i) {
vars[i] = s.MakeSum(queens[i], i)->Var();
}
s.AddConstraint(s.MakeAllDifferent(vars));
for (int i = 0; i < size; ++i) {
vars[i] = s.MakeSum(queens[i], -i)->Var();
}
s.AddConstraint(s.MakeAllDifferent(vars));
SolutionCollector* const solution_counter =
s.MakeAllSolutionCollector(nullptr);
SolutionCollector* const collector = s.MakeAllSolutionCollector();
collector->Add(queens);
std::vector<SearchMonitor*> monitors;
monitors.push_back(solution_counter);
monitors.push_back(collector);
DecisionBuilder* const db = s.MakePhase(queens, Solver::CHOOSE_FIRST_UNBOUND,
Solver::ASSIGN_MIN_VALUE);
if (absl::GetFlag(FLAGS_use_symmetry)) {
std::vector<SymmetryBreaker*> breakers;
NQueenSymmetry* const sx = s.RevAlloc(new SX(&s, queens));
breakers.push_back(sx);
NQueenSymmetry* const sy = s.RevAlloc(new SY(&s, queens));
breakers.push_back(sy);
NQueenSymmetry* const sd1 = s.RevAlloc(new SD1(&s, queens));
breakers.push_back(sd1);
NQueenSymmetry* const sd2 = s.RevAlloc(new SD2(&s, queens));
breakers.push_back(sd2);
NQueenSymmetry* const r90 = s.RevAlloc(new R90(&s, queens));
breakers.push_back(r90);
NQueenSymmetry* const r180 = s.RevAlloc(new R180(&s, queens));
breakers.push_back(r180);
NQueenSymmetry* const r270 = s.RevAlloc(new R270(&s, queens));
breakers.push_back(r270);
SearchMonitor* const symmetry_manager = s.MakeSymmetryManager(breakers);
monitors.push_back(symmetry_manager);
}
for (int loop = 0; loop < absl::GetFlag(FLAGS_nb_loops); ++loop) {
s.Solve(db, monitors); // go!
CheckNumberOfSolutions(size, solution_counter->solution_count());
}
const int num_solutions = solution_counter->solution_count();
if (num_solutions > 0 && size < kKnownSolutions) {
int print_max = absl::GetFlag(FLAGS_print_all) ? num_solutions
: absl::GetFlag(FLAGS_print) ? 1
: 0;
for (int n = 0; n < print_max; ++n) {
absl::PrintF("--- solution #%d\n", n);
for (int i = 0; i < size; ++i) {
const int pos = static_cast<int>(collector->Value(n, queens[i]));
for (int k = 0; k < pos; ++k) absl::PrintF(" . ");
absl::PrintF("%2d ", i);
for (int k = pos + 1; k < size; ++k) absl::PrintF(" . ");
absl::PrintF("\n");
}
}
}
absl::PrintF("========= number of solutions:%d\n", num_solutions);
absl::PrintF(" number of failures: %d\n", s.failures());
}
} // namespace operations_research
int main(int argc, char** argv) {
InitGoogle(argv[0], &argc, &argv, true);
if (absl::GetFlag(FLAGS_size) != 0) {
operations_research::NQueens(absl::GetFlag(FLAGS_size));
} else {
for (int n = 1; n < 12; ++n) {
operations_research::NQueens(n);
}
}
return 0;
}