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sat_cnf_reader.h
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sat_cnf_reader.h
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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.
#ifndef OR_TOOLS_SAT_SAT_CNF_READER_H_
#define OR_TOOLS_SAT_SAT_CNF_READER_H_
#include <algorithm>
#include <cstdint>
#include <string>
#include <utility>
#include <vector>
#include "absl/container/btree_map.h"
#include "absl/log/check.h"
#include "absl/strings/numbers.h"
#include "absl/strings/str_split.h"
#include "absl/strings/string_view.h"
#include "absl/types/span.h"
#include "ortools/base/logging.h"
#include "ortools/sat/boolean_problem.pb.h"
#include "ortools/sat/cp_model.pb.h"
#include "ortools/util/filelineiter.h"
namespace operations_research {
namespace sat {
// This implement the implicit contract needed by the SatCnfReader class.
class LinearBooleanProblemWrapper {
public:
explicit LinearBooleanProblemWrapper(LinearBooleanProblem* p) : problem_(p) {}
// In the new 2022 .wcnf format, we don't know the number of variable before
// hand (no header). So when this is called (after all the constraint have
// been added), we need to re-index the slack so that they are after the
// variable of the original problem.
void SetSizeAndPostprocess(int num_variables, int num_slacks) {
problem_->set_num_variables(num_variables + num_slacks);
problem_->set_original_num_variables(num_variables);
for (const int c : to_postprocess_) {
auto* literals = problem_->mutable_constraints(c)->mutable_literals();
const int last_index = literals->size() - 1;
const int last = (*literals)[last_index];
(*literals)[last_index] =
last >= 0 ? last + num_variables : last - num_variables;
}
}
// If last_is_slack is true, then the last literal is assumed to be a slack
// with index in [-num_slacks, num_slacks]. We will re-index it at the end in
// SetSizeAndPostprocess().
void AddConstraint(absl::Span<const int> clause, bool last_is_slack = false) {
if (last_is_slack)
to_postprocess_.push_back(problem_->constraints().size());
LinearBooleanConstraint* constraint = problem_->add_constraints();
constraint->mutable_literals()->Reserve(clause.size());
constraint->mutable_coefficients()->Reserve(clause.size());
constraint->set_lower_bound(1);
for (const int literal : clause) {
constraint->add_literals(literal);
constraint->add_coefficients(1);
}
}
void AddObjectiveTerm(int literal, int64_t value) {
CHECK_GE(literal, 0) << "Negative literal not supported.";
problem_->mutable_objective()->add_literals(literal);
problem_->mutable_objective()->add_coefficients(value);
}
void SetObjectiveOffset(int64_t offset) {
problem_->mutable_objective()->set_offset(offset);
}
private:
LinearBooleanProblem* problem_;
std::vector<int> to_postprocess_;
};
// This implement the implicit contract needed by the SatCnfReader class.
class CpModelProtoWrapper {
public:
explicit CpModelProtoWrapper(CpModelProto* p) : problem_(p) {}
void SetSizeAndPostprocess(int num_variables, int num_slacks) {
for (int i = 0; i < num_variables + num_slacks; ++i) {
IntegerVariableProto* variable = problem_->add_variables();
variable->add_domain(0);
variable->add_domain(1);
}
for (const int c : to_postprocess_) {
auto* literals = problem_->mutable_constraints(c)
->mutable_bool_or()
->mutable_literals();
const int last_index = literals->size() - 1;
const int last = (*literals)[last_index];
(*literals)[last_index] =
last >= 0 ? last + num_variables : last - num_variables;
}
}
int LiteralToRef(int signed_value) {
return signed_value > 0 ? signed_value - 1 : signed_value;
}
void AddConstraint(absl::Span<const int> clause, bool last_is_slack = false) {
if (last_is_slack)
to_postprocess_.push_back(problem_->constraints().size());
auto* constraint = problem_->add_constraints()->mutable_bool_or();
constraint->mutable_literals()->Reserve(clause.size());
for (const int literal : clause) {
constraint->add_literals(LiteralToRef(literal));
}
}
void AddObjectiveTerm(int literal, int64_t value) {
CHECK_GE(literal, 0) << "Negative literal not supported.";
problem_->mutable_objective()->add_vars(LiteralToRef(literal));
problem_->mutable_objective()->add_coeffs(value);
}
void SetObjectiveOffset(int64_t offset) {
problem_->mutable_objective()->set_offset(offset);
}
private:
CpModelProto* problem_;
std::vector<int> to_postprocess_;
};
// This class loads a file in cnf file format into a SatProblem.
// The format is described here:
// http://people.sc.fsu.edu/~jburkardt/data/cnf/cnf.html
//
// It also support the wcnf input format for partial weighted max-sat problems.
class SatCnfReader {
public:
explicit SatCnfReader(bool wcnf_use_strong_slack = true)
: interpret_cnf_as_max_sat_(false),
wcnf_use_strong_slack_(wcnf_use_strong_slack) {}
// This type is neither copyable nor movable.
SatCnfReader(const SatCnfReader&) = delete;
SatCnfReader& operator=(const SatCnfReader&) = delete;
// If called with true, then a cnf file will be converted to the max-sat
// problem: Try to minimize the number of unsatisfiable clauses.
void InterpretCnfAsMaxSat(bool v) { interpret_cnf_as_max_sat_ = v; }
// Loads the given cnf filename into the given proto.
bool Load(const std::string& filename, LinearBooleanProblem* problem) {
problem->Clear();
problem->set_name(ExtractProblemName(filename));
LinearBooleanProblemWrapper wrapper(problem);
return LoadInternal(filename, &wrapper);
}
bool Load(const std::string& filename, CpModelProto* problem) {
problem->Clear();
problem->set_name(ExtractProblemName(filename));
CpModelProtoWrapper wrapper(problem);
return LoadInternal(filename, &wrapper);
}
private:
template <class Problem>
bool LoadInternal(const std::string& filename, Problem* problem) {
is_wcnf_ = false;
objective_offset_ = 0;
positive_literal_to_weight_.clear();
end_marker_seen_ = false;
hard_weight_ = 0;
num_skipped_soft_clauses_ = 0;
num_singleton_soft_clauses_ = 0;
num_added_clauses_ = 0;
num_slack_variables_ = 0;
num_variables_ = 0;
num_clauses_ = 0;
actual_num_variables_ = 0;
int num_lines = 0;
for (const std::string& line : FileLines(filename)) {
++num_lines;
ProcessNewLine(line, problem);
}
if (num_lines == 0) {
LOG(FATAL) << "File '" << filename << "' is empty or can't be read.";
}
if (num_variables_ > 0 && num_variables_ != actual_num_variables_) {
LOG(ERROR) << "Wrong number of variables ! Expected:" << num_variables_
<< " Seen:" << actual_num_variables_;
}
problem->SetSizeAndPostprocess(actual_num_variables_, num_slack_variables_);
// Fill the objective.
if (!positive_literal_to_weight_.empty() ||
!slack_literal_to_weight_.empty()) {
for (const std::pair<int, int64_t> p : positive_literal_to_weight_) {
if (p.second != 0) {
problem->AddObjectiveTerm(p.first, p.second);
}
}
for (const std::pair<int, int64_t> p : slack_literal_to_weight_) {
if (p.second != 0) {
problem->AddObjectiveTerm(actual_num_variables_ + p.first, p.second);
}
}
problem->SetObjectiveOffset(objective_offset_);
}
// Some file from the max-sat competition seems to have the wrong number of
// clause !? I checked manually, so still parse them with best effort.
const int total_seen = num_added_clauses_ + num_singleton_soft_clauses_ +
num_skipped_soft_clauses_;
if (num_clauses_ > 0 && num_clauses_ != total_seen) {
LOG(ERROR) << "Wrong number of clauses ! Expected:" << num_clauses_
<< " Seen:" << total_seen;
}
return true;
}
// Since the problem name is not stored in the cnf format, we infer it from
// the file name.
static std::string ExtractProblemName(const std::string& filename) {
const int found = filename.find_last_of('/');
const std::string problem_name =
found != std::string::npos ? filename.substr(found + 1) : filename;
return problem_name;
}
void ProcessHeader(const std::string& line) {
static const char kWordDelimiters[] = " ";
words_ = absl::StrSplit(line, kWordDelimiters, absl::SkipEmpty());
CHECK_EQ(words_[0], "p");
if (words_[1] == "cnf" || words_[1] == "wcnf") {
CHECK(absl::SimpleAtoi(words_[2], &num_variables_));
CHECK(absl::SimpleAtoi(words_[3], &num_clauses_));
if (words_[1] == "wcnf") {
is_wcnf_ = true;
hard_weight_ = 0;
if (words_.size() > 4) {
CHECK(absl::SimpleAtoi(words_[4], &hard_weight_));
}
}
} else {
LOG(FATAL) << "Unknown file type: " << words_[1];
}
}
template <class Problem>
void ProcessNewLine(const std::string& line, Problem* problem) {
if (line.empty() || end_marker_seen_) return;
if (line[0] == 'c') return;
if (line[0] == '%') {
end_marker_seen_ = true;
return;
}
if (line[0] == 'p') {
ProcessHeader(line);
return;
}
// The new wcnf format do not have header p line anymore.
if (num_variables_ == 0) {
is_wcnf_ = true;
}
static const char kWordDelimiters[] = " ";
auto splitter = absl::StrSplit(line, kWordDelimiters, absl::SkipEmpty());
tmp_clause_.clear();
int64_t weight =
(!is_wcnf_ && interpret_cnf_as_max_sat_) ? 1 : hard_weight_;
bool first = true;
bool end_marker_seen = false;
for (const absl::string_view word : splitter) {
if (first && is_wcnf_) {
first = false;
if (word == "h") {
// Hard clause in the new 2022 format.
// Note that hard_weight_ == 0 here.
weight = hard_weight_;
} else {
CHECK(absl::SimpleAtoi(word, &weight));
CHECK_GE(weight, 0);
// A soft clause of weight 0 can be removed.
if (weight == 0) {
++num_skipped_soft_clauses_;
return;
}
}
continue;
}
int signed_value;
CHECK(absl::SimpleAtoi(word, &signed_value));
if (signed_value == 0) {
end_marker_seen = true;
break; // end of clause.
}
actual_num_variables_ = std::max(actual_num_variables_,
std::max(signed_value, -signed_value));
tmp_clause_.push_back(signed_value);
}
if (!end_marker_seen) return;
if (weight == hard_weight_) {
++num_added_clauses_;
problem->AddConstraint(tmp_clause_);
} else {
if (tmp_clause_.size() == 1) {
// The max-sat formulation of an optimization sat problem with a
// linear objective introduces many singleton soft clauses. Because we
// natively work with a linear objective, we can just add the cost to
// the unique variable of such clause and remove the clause.
++num_singleton_soft_clauses_;
const int literal = -tmp_clause_[0];
if (literal > 0) {
positive_literal_to_weight_[literal] += weight;
} else {
positive_literal_to_weight_[-literal] -= weight;
objective_offset_ += weight;
}
} else {
// The +1 is because a positive literal is the same as the 1-based
// variable index.
const int slack_literal = ++num_slack_variables_;
slack_literal_to_weight_[slack_literal] += weight;
tmp_clause_.push_back(slack_literal);
++num_added_clauses_;
problem->AddConstraint(tmp_clause_, /*last_is_slack=*/true);
if (wcnf_use_strong_slack_) {
// Add the binary implications slack_literal true => all the other
// clause literals are false.
for (int i = 0; i + 1 < tmp_clause_.size(); ++i) {
problem->AddConstraint({-tmp_clause_[i], -slack_literal},
/*last_is_slack=*/true);
}
}
}
}
}
bool interpret_cnf_as_max_sat_;
const bool wcnf_use_strong_slack_;
int num_clauses_ = 0;
int num_variables_ = 0;
int actual_num_variables_ = 0;
// Temporary storage for ProcessNewLine().
std::vector<absl::string_view> words_;
// We stores the objective in a map because we want the variables to appear
// only once in the LinearObjective proto.
int64_t objective_offset_;
absl::btree_map<int, int64_t> positive_literal_to_weight_;
absl::btree_map<int, int64_t> slack_literal_to_weight_;
// Used for the wcnf format.
bool is_wcnf_;
// Some files have text after %. This indicates if we have seen the '%'.
bool end_marker_seen_;
int64_t hard_weight_ = 0;
int num_slack_variables_;
int num_skipped_soft_clauses_;
int num_singleton_soft_clauses_;
int num_added_clauses_;
std::vector<int> tmp_clause_;
};
} // namespace sat
} // namespace operations_research
#endif // OR_TOOLS_SAT_SAT_CNF_READER_H_