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constraints.cc
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constraints.cc
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// Copyright 2010-2018 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 <string.h>
#include <algorithm>
#include <memory>
#include <string>
#include <utility>
#include <vector>
#include "absl/strings/str_cat.h"
#include "absl/strings/str_format.h"
#include "ortools/base/integral_types.h"
#include "ortools/base/logging.h"
#include "ortools/constraint_solver/constraint_solver.h"
#include "ortools/constraint_solver/constraint_solveri.h"
#include "ortools/util/saturated_arithmetic.h"
#include "ortools/util/string_array.h"
namespace operations_research {
Demon* Solver::MakeConstraintInitialPropagateCallback(Constraint* const ct) {
return MakeConstraintDemon0(this, ct, &Constraint::InitialPropagate,
"InitialPropagate");
}
Demon* Solver::MakeDelayedConstraintInitialPropagateCallback(
Constraint* const ct) {
return MakeDelayedConstraintDemon0(this, ct, &Constraint::InitialPropagate,
"InitialPropagate");
}
namespace {
class ActionDemon : public Demon {
public:
explicit ActionDemon(const Solver::Action& action) : action_(action) {
CHECK(action != nullptr);
}
~ActionDemon() override {}
void Run(Solver* const solver) override { action_(solver); }
private:
Solver::Action action_;
};
class ClosureDemon : public Demon {
public:
explicit ClosureDemon(const Solver::Closure& closure) : closure_(closure) {
CHECK(closure != nullptr);
}
~ClosureDemon() override {}
void Run(Solver* const solver) override { closure_(); }
private:
Solver::Closure closure_;
};
// ----- True and False Constraint -----
class TrueConstraint : public Constraint {
public:
explicit TrueConstraint(Solver* const s) : Constraint(s) {}
~TrueConstraint() override {}
void Post() override {}
void InitialPropagate() override {}
std::string DebugString() const override { return "TrueConstraint()"; }
void Accept(ModelVisitor* const visitor) const override {
visitor->BeginVisitConstraint(ModelVisitor::kTrueConstraint, this);
visitor->EndVisitConstraint(ModelVisitor::kTrueConstraint, this);
}
IntVar* Var() override { return solver()->MakeIntConst(1); }
};
class FalseConstraint : public Constraint {
public:
explicit FalseConstraint(Solver* const s) : Constraint(s) {}
FalseConstraint(Solver* const s, const std::string& explanation)
: Constraint(s), explanation_(explanation) {}
~FalseConstraint() override {}
void Post() override {}
void InitialPropagate() override { solver()->Fail(); }
std::string DebugString() const override {
return absl::StrCat("FalseConstraint(", explanation_, ")");
}
void Accept(ModelVisitor* const visitor) const override {
visitor->BeginVisitConstraint(ModelVisitor::kFalseConstraint, this);
visitor->EndVisitConstraint(ModelVisitor::kFalseConstraint, this);
}
IntVar* Var() override { return solver()->MakeIntConst(0); }
private:
const std::string explanation_;
};
// ----- Map Variable Domain to Boolean Var Array -----
// TODO(user) : optimize constraint to avoid ping pong.
// After a boolvar is set to 0, we remove the value from the var.
// There is no need to rescan the var to find the hole if the size at the end of
// UpdateActive() is the same as the size at the beginning of VarDomain().
class MapDomain : public Constraint {
public:
MapDomain(Solver* const s, IntVar* const var,
const std::vector<IntVar*>& actives)
: Constraint(s), var_(var), actives_(actives) {
holes_ = var->MakeHoleIterator(true);
}
~MapDomain() override {}
void Post() override {
Demon* vd = MakeConstraintDemon0(solver(), this, &MapDomain::VarDomain,
"VarDomain");
var_->WhenDomain(vd);
Demon* vb =
MakeConstraintDemon0(solver(), this, &MapDomain::VarBound, "VarBound");
var_->WhenBound(vb);
std::unique_ptr<IntVarIterator> domain_it(
var_->MakeDomainIterator(/*reversible=*/false));
for (const int64 index : InitAndGetValues(domain_it.get())) {
if (index >= 0 && index < actives_.size() && !actives_[index]->Bound()) {
Demon* d = MakeConstraintDemon1(
solver(), this, &MapDomain::UpdateActive, "UpdateActive", index);
actives_[index]->WhenDomain(d);
}
}
}
void InitialPropagate() override {
for (int i = 0; i < actives_.size(); ++i) {
actives_[i]->SetRange(int64{0}, int64{1});
if (!var_->Contains(i)) {
actives_[i]->SetValue(0);
} else if (actives_[i]->Max() == 0LL) {
var_->RemoveValue(i);
}
if (actives_[i]->Min() == 1LL) {
var_->SetValue(i);
}
}
if (var_->Bound()) {
VarBound();
}
}
void UpdateActive(int64 index) {
IntVar* const act = actives_[index];
if (act->Max() == 0) {
var_->RemoveValue(index);
} else if (act->Min() == 1) {
var_->SetValue(index);
}
}
void VarDomain() {
const int64 oldmin = var_->OldMin();
const int64 oldmax = var_->OldMax();
const int64 vmin = var_->Min();
const int64 vmax = var_->Max();
const int64 size = actives_.size();
for (int64 j = std::max(oldmin, int64{0}); j < std::min(vmin, size); ++j) {
actives_[j]->SetValue(0);
}
for (const int64 j : InitAndGetValues(holes_)) {
if (j >= 0 && j < size) {
actives_[j]->SetValue(0);
}
}
for (int64 j = std::max(vmax + int64{1}, int64{0});
j <= std::min(oldmax, size - int64{1}); ++j) {
actives_[j]->SetValue(int64{0});
}
}
void VarBound() {
const int64 val = var_->Min();
if (val >= 0 && val < actives_.size()) {
actives_[val]->SetValue(1);
}
}
std::string DebugString() const override {
return absl::StrFormat("MapDomain(%s, [%s])", var_->DebugString(),
JoinDebugStringPtr(actives_, ", "));
}
void Accept(ModelVisitor* const visitor) const override {
visitor->BeginVisitConstraint(ModelVisitor::kMapDomain, this);
visitor->VisitIntegerExpressionArgument(ModelVisitor::kTargetArgument,
var_);
visitor->VisitIntegerVariableArrayArgument(ModelVisitor::kVarsArgument,
actives_);
visitor->EndVisitConstraint(ModelVisitor::kMapDomain, this);
}
private:
IntVar* const var_;
std::vector<IntVar*> actives_;
IntVarIterator* holes_;
};
// ----- Lex constraint -----
class LexicalLess : public Constraint {
public:
LexicalLess(Solver* const s, const std::vector<IntVar*>& left,
const std::vector<IntVar*>& right, bool strict)
: Constraint(s),
left_(left),
right_(right),
active_var_(0),
strict_(strict),
demon_(nullptr) {
CHECK_EQ(left.size(), right.size());
}
~LexicalLess() override {}
void Post() override {
const int position = JumpEqualVariables(0);
active_var_.SetValue(solver(), position);
if (position < left_.size()) {
demon_ = solver()->MakeConstraintInitialPropagateCallback(this);
left_[position]->WhenRange(demon_);
right_[position]->WhenRange(demon_);
}
}
void InitialPropagate() override {
const int position = JumpEqualVariables(active_var_.Value());
if (position >= left_.size()) {
if (strict_) {
solver()->Fail();
}
return;
}
if (position != active_var_.Value()) {
left_[position]->WhenRange(demon_);
right_[position]->WhenRange(demon_);
active_var_.SetValue(solver(), position);
}
const int next_non_equal = JumpEqualVariables(position + 1);
if ((strict_ && next_non_equal == left_.size()) ||
(next_non_equal < left_.size() &&
left_[next_non_equal]->Min() > right_[next_non_equal]->Max())) {
// We need to be strict if we are the last in the array, or if
// the next one is impossible.
left_[position]->SetMax(right_[position]->Max() - 1);
right_[position]->SetMin(left_[position]->Min() + 1);
} else {
left_[position]->SetMax(right_[position]->Max());
right_[position]->SetMin(left_[position]->Min());
}
}
std::string DebugString() const override {
return absl::StrFormat(
"%s([%s], [%s])", strict_ ? "LexicalLess" : "LexicalLessOrEqual",
JoinDebugStringPtr(left_, ", "), JoinDebugStringPtr(right_, ", "));
}
void Accept(ModelVisitor* const visitor) const override {
visitor->BeginVisitConstraint(ModelVisitor::kLexLess, this);
visitor->VisitIntegerVariableArrayArgument(ModelVisitor::kLeftArgument,
left_);
visitor->VisitIntegerVariableArrayArgument(ModelVisitor::kRightArgument,
right_);
visitor->VisitIntegerArgument(ModelVisitor::kValueArgument, strict_);
visitor->EndVisitConstraint(ModelVisitor::kLexLess, this);
}
private:
int JumpEqualVariables(int start_position) const {
int position = start_position;
while (position < left_.size() && left_[position]->Bound() &&
right_[position]->Bound() &&
left_[position]->Min() == right_[position]->Min()) {
position++;
}
return position;
}
std::vector<IntVar*> left_;
std::vector<IntVar*> right_;
NumericalRev<int> active_var_;
const bool strict_;
Demon* demon_;
};
// ----- Inverse permutation constraint -----
class InversePermutationConstraint : public Constraint {
public:
InversePermutationConstraint(Solver* const s,
const std::vector<IntVar*>& left,
const std::vector<IntVar*>& right)
: Constraint(s),
left_(left),
right_(right),
left_hole_iterators_(left.size()),
left_domain_iterators_(left_.size()),
right_hole_iterators_(right_.size()),
right_domain_iterators_(right_.size()) {
CHECK_EQ(left_.size(), right_.size());
for (int i = 0; i < left_.size(); ++i) {
left_hole_iterators_[i] = left_[i]->MakeHoleIterator(true);
left_domain_iterators_[i] = left_[i]->MakeDomainIterator(true);
right_hole_iterators_[i] = right_[i]->MakeHoleIterator(true);
right_domain_iterators_[i] = right_[i]->MakeDomainIterator(true);
}
}
~InversePermutationConstraint() override {}
void Post() override {
for (int i = 0; i < left_.size(); ++i) {
Demon* const left_demon = MakeConstraintDemon1(
solver(), this,
&InversePermutationConstraint::PropagateHolesOfLeftVarToRight,
"PropagateHolesOfLeftVarToRight", i);
left_[i]->WhenDomain(left_demon);
Demon* const right_demon = MakeConstraintDemon1(
solver(), this,
&InversePermutationConstraint::PropagateHolesOfRightVarToLeft,
"PropagateHolesOfRightVarToLeft", i);
right_[i]->WhenDomain(right_demon);
}
solver()->AddConstraint(
solver()->MakeAllDifferent(left_, /*stronger_propagation=*/false));
solver()->AddConstraint(
solver()->MakeAllDifferent(right_, /*stronger_propagation=*/false));
}
void InitialPropagate() override {
const int size = left_.size();
for (int i = 0; i < size; ++i) {
left_[i]->SetRange(0, size - 1);
right_[i]->SetRange(0, size - 1);
}
for (int i = 0; i < size; ++i) {
PropagateDomain(i, left_[i], left_domain_iterators_[i], right_);
PropagateDomain(i, right_[i], right_domain_iterators_[i], left_);
}
}
void PropagateHolesOfLeftVarToRight(int index) {
PropagateHoles(index, left_[index], left_hole_iterators_[index], right_);
}
void PropagateHolesOfRightVarToLeft(int index) {
PropagateHoles(index, right_[index], right_hole_iterators_[index], left_);
}
std::string DebugString() const override {
return absl::StrFormat("InversePermutationConstraint([%s], [%s])",
JoinDebugStringPtr(left_, ", "),
JoinDebugStringPtr(right_, ", "));
}
void Accept(ModelVisitor* const visitor) const override {
visitor->BeginVisitConstraint(ModelVisitor::kInversePermutation, this);
visitor->VisitIntegerVariableArrayArgument(ModelVisitor::kLeftArgument,
left_);
visitor->VisitIntegerVariableArrayArgument(ModelVisitor::kRightArgument,
right_);
visitor->EndVisitConstraint(ModelVisitor::kInversePermutation, this);
}
private:
// See PropagateHolesOfLeftVarToRight() and PropagateHolesOfRightVarToLeft().
void PropagateHoles(int index, IntVar* const var, IntVarIterator* const holes,
const std::vector<IntVar*>& inverse) {
const int64 oldmin = std::max(var->OldMin(), int64{0});
const int64 oldmax =
std::min(var->OldMax(), static_cast<int64>(left_.size() - 1));
const int64 vmin = var->Min();
const int64 vmax = var->Max();
for (int64 value = oldmin; value < vmin; ++value) {
inverse[value]->RemoveValue(index);
}
for (const int64 hole : InitAndGetValues(holes)) {
if (hole >= 0 && hole < left_.size()) {
inverse[hole]->RemoveValue(index);
}
}
for (int64 value = vmax + 1; value <= oldmax; ++value) {
inverse[value]->RemoveValue(index);
}
}
void PropagateDomain(int index, IntVar* const var,
IntVarIterator* const domain,
const std::vector<IntVar*>& inverse) {
// Iterators are not safe w.r.t. removal. Postponing deletions.
tmp_removed_values_.clear();
for (const int64 value : InitAndGetValues(domain)) {
if (!inverse[value]->Contains(index)) {
tmp_removed_values_.push_back(value);
}
}
// Once we've finished iterating over the domain, we may call
// RemoveValues().
if (!tmp_removed_values_.empty()) {
var->RemoveValues(tmp_removed_values_);
}
}
std::vector<IntVar*> left_;
std::vector<IntVar*> right_;
std::vector<IntVarIterator*> left_hole_iterators_;
std::vector<IntVarIterator*> left_domain_iterators_;
std::vector<IntVarIterator*> right_hole_iterators_;
std::vector<IntVarIterator*> right_domain_iterators_;
// used only in PropagateDomain().
std::vector<int64> tmp_removed_values_;
};
// Index of first Max Value
class IndexOfFirstMaxValue : public Constraint {
public:
IndexOfFirstMaxValue(Solver* solver, IntVar* index,
const std::vector<IntVar*>& vars)
: Constraint(solver), index_(index), vars_(vars) {}
~IndexOfFirstMaxValue() override {}
void Post() override {
Demon* const demon =
solver()->MakeDelayedConstraintInitialPropagateCallback(this);
index_->WhenRange(demon);
for (IntVar* const var : vars_) {
var->WhenRange(demon);
}
}
void InitialPropagate() override {
const int64 vsize = vars_.size();
const int64 imin = std::max(int64{0}, index_->Min());
const int64 imax = std::min(vsize - 1, index_->Max());
int64 max_max = kint64min;
int64 max_min = kint64min;
// Compute min and max value in the current interval covered by index_.
for (int i = imin; i <= imax; ++i) {
max_max = std::max(max_max, vars_[i]->Max());
max_min = std::max(max_min, vars_[i]->Min());
}
// Propagate the fact that the first maximum value belongs to the
// [imin..imax].
for (int i = 0; i < imin; ++i) {
vars_[i]->SetMax(max_max - 1);
}
for (int i = imax + 1; i < vsize; ++i) {
vars_[i]->SetMax(max_max);
}
// Shave bounds for index_.
int64 min_index = imin;
while (vars_[min_index]->Max() < max_min) {
min_index++;
}
int64 max_index = imax;
while (vars_[max_index]->Max() < max_min) {
max_index--;
}
index_->SetRange(min_index, max_index);
}
std::string DebugString() const override {
return absl::StrFormat("IndexMax(%s, [%s])", index_->DebugString(),
JoinDebugStringPtr(vars_, ", "));
}
void Accept(ModelVisitor* const visitor) const override {
// TODO(user): Implement me.
}
private:
IntVar* const index_;
const std::vector<IntVar*> vars_;
};
} // namespace
// ----- API -----
Demon* Solver::MakeActionDemon(Solver::Action action) {
return RevAlloc(new ActionDemon(action));
}
Demon* Solver::MakeClosureDemon(Solver::Closure closure) {
return RevAlloc(new ClosureDemon(closure));
}
Constraint* Solver::MakeTrueConstraint() {
DCHECK(true_constraint_ != nullptr);
return true_constraint_;
}
Constraint* Solver::MakeFalseConstraint() {
DCHECK(false_constraint_ != nullptr);
return false_constraint_;
}
Constraint* Solver::MakeFalseConstraint(const std::string& explanation) {
return RevAlloc(new FalseConstraint(this, explanation));
}
void Solver::InitCachedConstraint() {
DCHECK(true_constraint_ == nullptr);
true_constraint_ = RevAlloc(new TrueConstraint(this));
DCHECK(false_constraint_ == nullptr);
false_constraint_ = RevAlloc(new FalseConstraint(this));
}
Constraint* Solver::MakeMapDomain(IntVar* const var,
const std::vector<IntVar*>& actives) {
return RevAlloc(new MapDomain(this, var, actives));
}
Constraint* Solver::MakeLexicalLess(const std::vector<IntVar*>& left,
const std::vector<IntVar*>& right) {
return RevAlloc(new LexicalLess(this, left, right, true));
}
Constraint* Solver::MakeLexicalLessOrEqual(const std::vector<IntVar*>& left,
const std::vector<IntVar*>& right) {
return RevAlloc(new LexicalLess(this, left, right, false));
}
Constraint* Solver::MakeInversePermutationConstraint(
const std::vector<IntVar*>& left, const std::vector<IntVar*>& right) {
return RevAlloc(new InversePermutationConstraint(this, left, right));
}
Constraint* Solver::MakeIndexOfFirstMaxValueConstraint(
IntVar* index, const std::vector<IntVar*>& vars) {
return RevAlloc(new IndexOfFirstMaxValue(this, index, vars));
}
Constraint* Solver::MakeIndexOfFirstMinValueConstraint(
IntVar* index, const std::vector<IntVar*>& vars) {
std::vector<IntVar*> opp_vars(vars.size());
for (int i = 0; i < vars.size(); ++i) {
opp_vars[i] = MakeOpposite(vars[i])->Var();
}
return RevAlloc(new IndexOfFirstMaxValue(this, index, opp_vars));
}
} // namespace operations_research