always-cautious/ortools-clone
1
0
Fork 0
Code Issues Pull Requests Actions Packages Projects Releases Wiki Activity
Files
e5cb0df1cabc3ea03935dcdb08c48401515b866b
ortools-clone/constraint_solver/expr_array.cc
lperron@google.com af60f38cc2 This should complete the reimplementation/extension of SequenceVar. 
Now it should be possible to do meaningful LS and LNS on sequence variables.

Move RevBitSet to constraint_solveri.h.
Extend sequence with RankLast/RankNotLast.
Change assignment element on sequence to take 3 vectors:
  - rank_firsts.
  - rank_lasts.
 	  - unperformed.
Changed FillSequence accordingly.
Change proto accordingly.
Add trace event on SequenceVar::RankSequence.
Add trace event on SequenceVar::RankLast/RankNotLast.
Added a RankSequence which take as input these 3 vectors.
Add RevArray<T> template.
Generalize use of Rev<T> and RevArray<T> in the code.

Add API to discover and collect the decision variables of the model.
Test it in model_util.
2011-12-16 21:02:59 +00:00

2917 lines
87 KiB
C++
Raw Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

// Copyright 2010-2011 Google
// 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.
//
// Array Expression constraints
#include <string.h>
#include <algorithm>
#include <string>
#include <vector>
#include "base/integral_types.h"
#include "base/logging.h"
#include "base/scoped_ptr.h"
#include "base/stringprintf.h"
#include "constraint_solver/constraint_solver.h"
#include "constraint_solver/constraint_solveri.h"
#include "util/string_array.h"
namespace operations_research {
namespace {
// ---------- Base array classes used for code factorization ----------
// ----- Array Constraint -----
class ArrayConstraint : public CastConstraint {
public:
ArrayConstraint(Solver* const s,
const IntVar* const * vars,
int size,
IntVar* const var)
: CastConstraint(s, var), vars_(new IntVar*[size]), size_(size) {
CHECK_GT(size, 0);
CHECK_NOTNULL(vars);
memcpy(vars_.get(), vars, size_ * sizeof(*vars));
}
virtual ~ArrayConstraint() {}
protected:
string DebugStringInternal(const string& name) const {
return StringPrintf("%s(%s) == %s",
name.c_str(),
DebugStringArray(vars_.get(), size_, ", ").c_str(),
target_var_->DebugString().c_str());
}
void AcceptInternal(const string& name, ModelVisitor* const visitor) const {
visitor->BeginVisitConstraint(name, this);
visitor->VisitIntegerVariableArrayArgument(ModelVisitor::kVarsArgument,
vars_.get(),
size_);
visitor->VisitIntegerExpressionArgument(ModelVisitor::kTargetArgument,
target_var_);
visitor->EndVisitConstraint(name, this);
}
scoped_array<IntVar*> vars_;
const int size_;
};
// ----- ArrayExpr -----
class ArrayExpr : public BaseIntExpr {
public:
ArrayExpr(Solver* const s, const IntVar* const* vars, int size)
: BaseIntExpr(s), vars_(new IntVar*[size]), size_(size) {
CHECK_GT(size, 0);
CHECK_NOTNULL(vars);
memcpy(vars_.get(), vars, size_ * sizeof(*vars));
}
virtual ~ArrayExpr() {}
protected:
string DebugStringInternal(const string& name) const {
return StringPrintf("%s(%s)",
name.c_str(),
DebugStringArray(vars_.get(), size_, ", ").c_str());
}
void AcceptInternal(const string& name, ModelVisitor* const visitor) const {
visitor->BeginVisitIntegerExpression(name, this);
visitor->VisitIntegerVariableArrayArgument(ModelVisitor::kVarsArgument,
vars_.get(),
size_);
visitor->EndVisitIntegerExpression(name, this);
}
scoped_array<IntVar*> vars_;
const int size_;
};
// ----- Tree Array Constraint -----
// Helper class
class TreeArrayConstraint : public ArrayConstraint {
public:
TreeArrayConstraint(Solver* const solver,
IntVar* const* vars,
int size,
IntVar* const sum_var)
: ArrayConstraint(solver, vars, size, sum_var),
block_size_(solver->parameters().array_split_size) {
std::vector<int> lengths;
lengths.push_back(size_);
while (lengths.back() > 1) {
const int current = lengths.back();
lengths.push_back((current + block_size_ - 1) / block_size_);
}
tree_.resize(lengths.size());
for (int i = 0; i < lengths.size(); ++i) {
tree_[i].resize(lengths[lengths.size() - i - 1]);
}
DCHECK_GE(tree_.size(), 1);
DCHECK_EQ(1, tree_[0].size());
root_node_ = &tree_[0][0];
}
// Increases min by delta_min, reduces max by delta_max.
void ReduceRange(int depth, int position, int64 delta_min, int64 delta_max) {
NodeInfo* const info = &tree_[depth][position];
if (delta_min > 0) {
info->node_min.SetValue(solver(), info->node_min.Value() + delta_min);
}
if (delta_max > 0) {
info->node_max.SetValue(solver(), info->node_max.Value() - delta_max);
}
}
void InitLeaf(Solver* const solver,
int position,
int64 var_min,
int64 var_max) {
InitNode(solver, MaxDepth(), position, var_min, var_max);
}
void InitNode(Solver* const solver,
int depth,
int position,
int64 node_min,
int64 node_max) {
tree_[depth][position].node_min.SetValue(solver, node_min);
tree_[depth][position].node_max.SetValue(solver, node_max);
}
int64 Min(int depth, int position) const {
return tree_[depth][position].node_min.Value();
}
int64 Max(int depth, int position) const {
return tree_[depth][position].node_max.Value();
}
int64 RootMin() const {
return root_node_->node_min.Value();
}
int64 RootMax() const {
return root_node_->node_max.Value();
}
int Parent(int position) const {
return position / block_size_;
}
int ChildStart(int position) const {
return position * block_size_;
}
int ChildEnd(int depth, int position) const {
DCHECK_LT(depth + 1, tree_.size());
return std::min((position + 1) * block_size_ - 1, Width(depth + 1) - 1);
}
bool IsLeaf(int depth) const {
return depth == MaxDepth();
}
int MaxDepth() const {
return tree_.size() - 1;
}
int Width(int depth) const {
return tree_[depth].size();
}
private:
struct NodeInfo {
NodeInfo() : node_min(0), node_max(0) {}
Rev<int64> node_min;
Rev<int64> node_max;
};
std::vector<std::vector<NodeInfo> > tree_;
const int block_size_;
NodeInfo* root_node_;
};
// ---------- Sum Array ----------
// Some of these optimizations here are described in:
// "Bounds consistency techniques for long linear constraints". In
// Workshop on Techniques for Implementing Constraint Programming
// Systems (TRICS), a workshop of CP 2002, N. Beldiceanu, W. Harvey,
// Martin Henz, Francois Laburthe, Eric Monfroy, Tobias Müller,
// Laurent Perron and Christian Schulte editors, pages 3946, 2002.
// ----- SumConstraint -----
// This constraint implements sum(vars) == sum_var.
class SumConstraint : public TreeArrayConstraint {
public:
SumConstraint(Solver* const solver,
IntVar* const * vars,
int size,
IntVar* const sum_var)
: TreeArrayConstraint(solver, vars, size, sum_var), sum_demon_(NULL) {}
virtual ~SumConstraint() {}
virtual void Post() {
for (int i = 0; i < size_; ++i) {
Demon* const demon = MakeConstraintDemon1(solver(),
this,
&SumConstraint::LeafChanged,
"LeafChanged",
i);
vars_[i]->WhenRange(demon);
}
sum_demon_ = solver()->RegisterDemon(
MakeDelayedConstraintDemon0(solver(),
this,
&SumConstraint::SumChanged,
"SumChanged"));
target_var_->WhenRange(sum_demon_);
}
virtual void InitialPropagate() {
// Copy vars to leaf nodes.
for (int i = 0; i < size_; ++i) {
InitLeaf(solver(), i, vars_[i]->Min(), vars_[i]->Max());
}
// Compute up.
for (int i = MaxDepth() - 1; i >= 0; --i) {
for (int j = 0; j < Width(i); ++j) {
int64 sum_min = 0;
int64 sum_max = 0;
const int block_start = ChildStart(j);
const int block_end = ChildEnd(i, j);
for (int k = block_start; k <= block_end; ++k) {
sum_min += Min(i + 1, k);
sum_max += Max(i + 1, k);
}
InitNode(solver(), i, j, sum_min, sum_max);
}
}
// Propagate to sum_var.
target_var_->SetRange(RootMin(), RootMax());
// Push down.
SumChanged();
}
void SumChanged() {
if (target_var_->Max() == RootMin()) {
// We can fix all terms to min.
for (int i = 0; i < size_; ++i) {
vars_[i]->SetValue(vars_[i]->Min());
}
} else if (target_var_->Min() == RootMax()) {
// We can fix all terms to max.
for (int i = 0; i < size_; ++i) {
vars_[i]->SetValue(vars_[i]->Max());
}
} else {
PushDown(0, 0, target_var_->Min(), target_var_->Max());
}
}
void PushDown(int depth, int position, int64 new_min, int64 new_max) {
// Nothing to do?
if (new_min <= Min(depth, position) && new_max >= Max(depth, position)) {
return;
}
// Leaf node -> push to leaf var.
if (IsLeaf(depth)) {
vars_[position]->SetRange(new_min, new_max);
return;
}
// Standard propagation from the bounds of the sum to the
// individuals terms.
// These are maintained automatically in the tree structure.
const int64 sum_min = Min(depth, position);
const int64 sum_max = Max(depth, position);
// Intersect the new bounds with the computed bounds.
new_max = std::min(sum_max, new_max);
new_min = std::max(sum_min, new_min);
// Detect failure early.
if (new_max < sum_min || new_min > sum_max) {
solver()->Fail();
}
// Push to children nodes.
const int block_start = ChildStart(position);
const int block_end = ChildEnd(depth, position);
for (int i = block_start; i <= block_end; ++i) {
const int64 target_var_min = Min(depth + 1, i);
const int64 target_var_max = Max(depth + 1, i);
const int64 residual_min = sum_min - target_var_min;
const int64 residual_max = sum_max - target_var_max;
PushDown(depth + 1, i, new_min - residual_max, new_max - residual_min);
}
// TODO(user) : Is the diameter optimization (see reference
// above, rule 5) useful?
}
void LeafChanged(int term_index) {
IntVar* const var = vars_[term_index];
PushUp(term_index, var->Min() - var->OldMin(), var->OldMax() - var->Max());
Enqueue(sum_demon_); // TODO(user): Is this needed?
}
void PushUp(int position, int64 delta_min, int64 delta_max) {
DCHECK_GE(delta_max, 0);
DCHECK_GE(delta_min, 0);
DCHECK_GT(delta_min + delta_max, 0);
for (int depth = MaxDepth(); depth >= 0; --depth) {
ReduceRange(depth, position, delta_min, delta_max);
position = Parent(position);
}
DCHECK_EQ(0, position);
target_var_->SetRange(RootMin(), RootMax());
}
string DebugString() const {
return DebugStringInternal("Sum");
}
virtual void Accept(ModelVisitor* const visitor) const {
AcceptInternal(ModelVisitor::kSumEqual, visitor);
}
private:
Demon* sum_demon_;
};
// ---------- Min Array ----------
// ----- Min Bool Array Ct -----
// This constraint implements min(vars) == var. It is delayed such
// that propagation only occurs when all variables have been touched.
class MinBoolArrayCt : public ArrayConstraint {
public:
MinBoolArrayCt(Solver* const s, const IntVar* const * vars, int size,
IntVar* var);
virtual ~MinBoolArrayCt() {}
virtual void Post();
virtual void InitialPropagate();
void Update(int index);
void UpdateVar();
virtual string DebugString() const;
virtual void Accept(ModelVisitor* const visitor) const {
AcceptInternal(ModelVisitor::kMinEqual, visitor);
}
private:
SmallRevBitSet bits_;
RevSwitch inhibited_;
};
MinBoolArrayCt::MinBoolArrayCt(Solver* const s,
const IntVar* const * vars,
int size,
IntVar* var)
: ArrayConstraint(s, vars, size, var), bits_(size) {}
void MinBoolArrayCt::Post() {
for (int i = 0; i < size_; ++i) {
Demon* d = MakeConstraintDemon1(solver(),
this,
&MinBoolArrayCt::Update,
"Update",
i);
vars_[i]->WhenRange(d);
}
Demon* uv = MakeConstraintDemon0(solver(),
this,
&MinBoolArrayCt::UpdateVar,
"UpdateVar");
target_var_->WhenRange(uv);
}
void MinBoolArrayCt::InitialPropagate() {
if (target_var_->Min() == 1LL) {
for (int i = 0; i < size_; ++i) {
vars_[i]->SetMin(1LL);
}
inhibited_.Switch(solver());
} else {
for (int i = 0; i < size_; ++i) {
IntVar* const var = vars_[i];
if (var->Max() == 0LL) {
target_var_->SetMax(0LL);
inhibited_.Switch(solver());
return;
}
if (var->Min() == 0LL) {
bits_.SetToOne(solver(), i);
}
}
if (bits_.IsCardinalityZero()) {
target_var_->SetValue(1LL);
inhibited_.Switch(solver());
} else if (target_var_->Max() == 0LL && bits_.IsCardinalityOne()) {
vars_[bits_.GetFirstOne()]->SetValue(0LL);
inhibited_.Switch(solver());
}
}
}
void MinBoolArrayCt::Update(int index) {
if (!inhibited_.Switched()) {
if (vars_[index]->Max() == 0LL) { // Bound to 0.
target_var_->SetValue(0LL);
inhibited_.Switch(solver());
} else {
bits_.SetToZero(solver(), index);
if (bits_.IsCardinalityZero()) {
target_var_->SetValue(1LL);
inhibited_.Switch(solver());
} else if (target_var_->Max() == 0LL && bits_.IsCardinalityOne()) {
vars_[bits_.GetFirstOne()]->SetValue(0LL);
inhibited_.Switch(solver());
}
}
}
}
void MinBoolArrayCt::UpdateVar() {
if (!inhibited_.Switched()) {
if (target_var_->Min() == 1LL) {
for (int i = 0; i < size_; ++i) {
vars_[i]->SetMin(1LL);
}
inhibited_.Switch(solver());
} else {
if (bits_.IsCardinalityOne()) {
vars_[bits_.GetFirstOne()]->SetValue(0LL);
inhibited_.Switch(solver());
}
}
}
}
string MinBoolArrayCt::DebugString() const {
return DebugStringInternal("MinBoolArrayCt");
}
// ----- MinBoolArray -----
class MinBoolArray : public ArrayExpr {
public:
// This constructor will copy the array. The caller can safely delete the
// exprs array himself
MinBoolArray(Solver* const s, const IntVar* const* exprs, int size);
virtual ~MinBoolArray();
virtual int64 Min() const;
virtual void SetMin(int64 m);
virtual int64 Max() const;
virtual void SetMax(int64 m);
virtual string DebugString() const;
virtual void WhenRange(Demon* d);
virtual IntVar* CastToVar() {
Solver* const s = solver();
int64 vmin = 0LL;
int64 vmax = 0LL;
Range(&vmin, &vmax);
IntVar* var = solver()->MakeIntVar(vmin, vmax);
CastConstraint* const ct =
s->RevAlloc(new MinBoolArrayCt(s, vars_.get(), size_, var));
s->AddCastConstraint(ct, var, this);
return var;
}
virtual void Accept(ModelVisitor* const visitor) const {
AcceptInternal(ModelVisitor::kMin, visitor);
}
};
MinBoolArray::~MinBoolArray() {}
MinBoolArray::MinBoolArray(Solver* const s, const IntVar* const* vars, int size)
: ArrayExpr(s, vars, size) {}
int64 MinBoolArray::Min() const {
for (int i = 0; i < size_; ++i) {
const int64 vmin = vars_[i]->Min();
if (vmin == 0LL) {
return 0LL;
}
}
return 1LL;
}
void MinBoolArray::SetMin(int64 m) {
if (m <= 0) {
return;
}
if (m > 1) {
solver()->Fail();
}
for (int i = 0; i < size_; ++i) {
vars_[i]->SetMin(1LL);
}
}
int64 MinBoolArray::Max() const {
for (int i = 0; i < size_; ++i) {
const int64 vmax = vars_[i]->Max();
if (vmax == 0LL) {
return 0LL;
}
}
return 1LL;
}
void MinBoolArray::SetMax(int64 m) {
if (m < 0) {
solver()->Fail();
} else if (m >= 1) {
return;
}
DCHECK_EQ(m, 0LL);
int active = 0;
int curr = -1;
for (int i = 0; i < size_; ++i) {
if (vars_[i]->Min() == 0LL) {
active++;
curr = i;
}
}
if (active == 0) {
solver()->Fail();
}
if (active == 1) {
vars_[curr]->SetMax(0LL);
}
}
string MinBoolArray::DebugString() const {
return DebugStringInternal("MinBoolArray");
}
void MinBoolArray::WhenRange(Demon* d) {
for (int i = 0; i < size_; ++i) {
vars_[i]->WhenRange(d);
}
}
// ----- Min Array Ct -----
// This constraint implements min(vars) == var. It is delayed such
// that propagation only occurs when all variables have been touched.
class MinArrayCt : public ArrayConstraint {
public:
MinArrayCt(Solver* const s, const IntVar* const * vars, int size,
IntVar* var);
virtual ~MinArrayCt() {}
virtual void Post();
virtual void InitialPropagate();
void Update(int index);
void UpdateVar();
virtual string DebugString() const;
virtual void Accept(ModelVisitor* const visitor) const {
AcceptInternal(ModelVisitor::kMinEqual, visitor);
}
private:
Rev<int> min_support_;
};
MinArrayCt::MinArrayCt(Solver* const s,
const IntVar* const * vars,
int size,
IntVar* var)
: ArrayConstraint(s, vars, size, var), min_support_(0) {}
void MinArrayCt::Post() {
for (int i = 0; i < size_; ++i) {
Demon* d = MakeConstraintDemon1(solver(),
this,
&MinArrayCt::Update,
"Update",
i);
vars_[i]->WhenRange(d);
}
Demon* uv = MakeConstraintDemon0(solver(),
this,
&MinArrayCt::UpdateVar,
"UpdateVar");
target_var_->WhenRange(uv);
}
void MinArrayCt::InitialPropagate() {
int64 vmin = target_var_->Min();
int64 vmax = target_var_->Max();
int64 cmin = kint64max;
int64 cmax = kint64max;
int min_support = -1;
for (int i = 0; i < size_; ++i) {
IntVar* const var = vars_[i];
var->SetMin(vmin);
const int64 tmin = var->Min();
const int64 tmax = var->Max();
if (tmin < cmin) {
cmin = tmin;
min_support = i;
}
if (tmax < cmax) {
cmax = tmax;
}
}
min_support_.SetValue(solver(), min_support);
target_var_->SetRange(cmin, cmax);
vmin = target_var_->Min();
vmax = target_var_->Max();
int active = 0;
int curr = -1;
for (int i = 0; i < size_; ++i) {
if (vars_[i]->Min() <= vmax) {
if (active++ >= 1) {
return;
}
curr = i;
}
}
if (active == 0) {
solver()->Fail();
}
if (active == 1) {
vars_[curr]->SetMax(vmax);
}
}
void MinArrayCt::Update(int index) {
IntVar* const modified = vars_[index];
if (modified->OldMax() != modified->Max()) {
target_var_->SetMax(modified->Max());
}
if (index == min_support_.Value() && modified->OldMin() != modified->Min()) {
// TODO(user) : can we merge this code with above into
// ComputeMinSupport?
int64 cmin = kint64max;
int min_support = -1;
for (int i = 0; i < size_; ++i) {
const int64 tmin = vars_[i]->Min();
if (tmin < cmin) {
cmin = tmin;
min_support = i;
}
}
min_support_.SetValue(solver(), min_support);
target_var_->SetMin(cmin);
}
}
void MinArrayCt::UpdateVar() {
const int64 vmin = target_var_->Min();
if (vmin != target_var_->OldMin()) {
for (int i = 0; i < size_; ++i) {
vars_[i]->SetMin(vmin);
}
}
const int64 vmax = target_var_->Max();
if (vmax != target_var_->OldMax()) {
int active = 0;
int curr = -1;
for (int i = 0; i < size_; ++i) {
if (vars_[i]->Min() <= vmax) {
if (active++ >= 1) {
return;
}
curr = i;
}
}
if (active == 0) {
solver()->Fail();
}
if (active == 1) {
vars_[curr]->SetMax(vmax);
}
}
}
string MinArrayCt::DebugString() const {
return DebugStringInternal("MinArrayCt");
}
// Array Min: the min of all the elements. More efficient that using just
// binary MinIntExpr operators when the array grows
class MinArray : public ArrayExpr {
public:
// this constructor will copy the array. The caller can safely delete the
// exprs array himself
MinArray(Solver* const s, const IntVar* const* exprs, int size);
virtual ~MinArray();
virtual int64 Min() const;
virtual void SetMin(int64 m);
virtual int64 Max() const;
virtual void SetMax(int64 m);
virtual string DebugString() const;
virtual void WhenRange(Demon* d);
virtual IntVar* CastToVar() {
Solver* const s = solver();
int64 vmin = 0LL;
int64 vmax = 0LL;
Range(&vmin, &vmax);
IntVar* var = solver()->MakeIntVar(vmin, vmax);
CastConstraint* const ct =
s->RevAlloc(new MinArrayCt(s, vars_.get(), size_, var));
s->AddCastConstraint(ct, var, this);
return var;
}
virtual void Accept(ModelVisitor* const visitor) const {
AcceptInternal(ModelVisitor::kMin, visitor);
}
};
MinArray::~MinArray() {}
MinArray::MinArray(Solver* const s, const IntVar* const* vars, int size)
: ArrayExpr(s, vars, size) {}
int64 MinArray::Min() const {
int64 min = kint64max;
for (int i = 0; i < size_; ++i) {
const int64 vmin = vars_[i]->Min();
if (min > vmin) {
min = vmin;
}
}
return min;
}
void MinArray::SetMin(int64 m) {
for (int i = 0; i < size_; ++i) {
vars_[i]->SetMin(m);
}
}
int64 MinArray::Max() const {
int64 max = kint64max;
for (int i = 0; i < size_; ++i) {
const int64 vmax = vars_[i]->Max();
if (max > vmax) {
max = vmax;
}
}
return max;
}
void MinArray::SetMax(int64 m) {
int active = 0;
int curr = -1;
for (int i = 0; i < size_; ++i) {
if (vars_[i]->Min() <= m) {
if (active++ >= 1) {
return;
}
curr = i;
}
}
if (active == 0) {
solver()->Fail();
}
if (active == 1) {
vars_[curr]->SetMax(m);
}
}
string MinArray::DebugString() const {
return DebugStringInternal("MinArray");
}
void MinArray::WhenRange(Demon* d) {
for (int i = 0; i < size_; ++i) {
vars_[i]->WhenRange(d);
}
}
// ---------- Max Array ----------
// ----- Max Array Ct -----
// This constraint implements max(vars) == var.
class MaxArrayCt : public ArrayConstraint {
public:
MaxArrayCt(Solver* const s, const IntVar* const * vars, int size,
IntVar* var);
virtual ~MaxArrayCt() {}
virtual void Post();
virtual void InitialPropagate();
void Update(int index);
void UpdateVar();
virtual string DebugString() const;
virtual void Accept(ModelVisitor* const visitor) const {
AcceptInternal(ModelVisitor::kMaxEqual, visitor);
}
private:
Rev<int> max_support_;
};
MaxArrayCt::MaxArrayCt(Solver* const s,
const IntVar* const * vars,
int size,
IntVar* var)
: ArrayConstraint(s, vars, size, var), max_support_(0) {}
void MaxArrayCt::Post() {
for (int i = 0; i < size_; ++i) {
Demon* d = MakeConstraintDemon1(solver(),
this,
&MaxArrayCt::Update,
"Update",
i);
vars_[i]->WhenRange(d);
}
Demon* uv = MakeConstraintDemon0(solver(),
this,
&MaxArrayCt::UpdateVar,
"UpdateVar");
target_var_->WhenRange(uv);
}
void MaxArrayCt::InitialPropagate() {
int64 vmin = target_var_->Min();
int64 vmax = target_var_->Max();
int64 cmin = kint64min;
int64 cmax = kint64min;
int max_support = -1;
for (int i = 0; i < size_; ++i) {
IntVar* const var = vars_[i];
var->SetMax(vmax);
const int64 tmin = var->Min();
const int64 tmax = var->Max();
if (tmin > cmin) {
cmin = tmin;
}
if (tmax > cmax) {
cmax = tmax;
max_support = i;
}
}
max_support_.SetValue(solver(), max_support);
target_var_->SetRange(cmin, cmax);
vmin = target_var_->Min();
vmax = target_var_->Max();
int active = 0;
int curr = -1;
for (int i = 0; i < size_; ++i) {
if (vars_[i]->Max() >= vmin) {
if (active++ >= 1) {
return;
}
curr = i;
}
}
if (active == 0) {
solver()->Fail();
}
if (active == 1) {
vars_[curr]->SetMin(vmin);
}
}
void MaxArrayCt::Update(int index) {
IntVar* const modified = vars_[index];
if (modified->OldMin() != modified->Min()) {
target_var_->SetMin(modified->Min());
}
const int64 oldmax = modified->OldMax();
if (index == max_support_.Value() && oldmax != modified->Max()) {
// TODO(user) : can we merge this code with above into
// ComputeMaxSupport?
int64 cmax = kint64min;
int max_support = -1;
for (int i = 0; i < size_; ++i) {
const int64 tmax = vars_[i]->Max();
if (tmax > cmax) {
cmax = tmax;
max_support = i;
}
}
max_support_.SetValue(solver(), max_support);
target_var_->SetMax(cmax);
}
}
void MaxArrayCt::UpdateVar() {
const int64 vmax = target_var_->Max();
if (vmax != target_var_->OldMax()) {
for (int i = 0; i < size_; ++i) {
vars_[i]->SetMax(vmax);
}
}
const int64 vmin = target_var_->Min();
if (vmin != target_var_->OldMin()) {
int active = 0;
int curr = -1;
for (int i = 0; i < size_; ++i) {
if (vars_[i]->Max() >= vmin) {
if (active++ >= 1) {
return;
}
curr = i;
}
}
if (active == 0) {
solver()->Fail();
}
if (active == 1) {
vars_[curr]->SetMin(vmin);
}
}
}
string MaxArrayCt::DebugString() const {
return DebugStringInternal("MaxArrayCt");
}
// Array Max: the max of all the elements. More efficient that using just
// binary MaxIntExpr operators when the array grows
class MaxArray : public ArrayExpr {
public:
// this constructor will copy the array. The caller can safely delete the
// exprs array himself
MaxArray(Solver* const s, const IntVar* const* exprs, int size);
virtual ~MaxArray();
virtual int64 Min() const;
virtual void SetMin(int64 m);
virtual int64 Max() const;
virtual void SetMax(int64 m);
virtual string DebugString() const;
virtual void WhenRange(Demon* d);
virtual IntVar* CastToVar() {
Solver* const s = solver();
int64 vmin = Min();
int64 vmax = Max();
IntVar* var = solver()->MakeIntVar(vmin, vmax);
CastConstraint* const ct =
s->RevAlloc(new MaxArrayCt(s, vars_.get(), size_, var));
s->AddCastConstraint(ct, var, this);
return var;
}
virtual void Accept(ModelVisitor* const visitor) const {
AcceptInternal(ModelVisitor::kMax, visitor);
}
};
MaxArray::~MaxArray() {}
MaxArray::MaxArray(Solver* const s, const IntVar* const* vars, int size)
: ArrayExpr(s, vars, size) {}
int64 MaxArray::Min() const {
int64 min = kint64min;
for (int i = 0; i < size_; ++i) {
const int64 vmin = vars_[i]->Min();
if (min < vmin) {
min = vmin;
}
}
return min;
}
void MaxArray::SetMin(int64 m) {
int active = 0;
int curr = -1;
for (int i = 0; i < size_; ++i) {
if (vars_[i]->Max() >= m) {
active++;
curr = i;
}
}
if (active == 0) {
solver()->Fail();
}
if (active == 1) {
vars_[curr]->SetMin(m);
}
}
int64 MaxArray::Max() const {
int64 max = kint64min;
for (int i = 0; i < size_; ++i) {
const int64 vmax = vars_[i]->Max();
if (max < vmax) {
max = vmax;
}
}
return max;
}
void MaxArray::SetMax(int64 m) {
for (int i = 0; i < size_; ++i) {
vars_[i]->SetMax(m);
}
}
string MaxArray::DebugString() const {
return DebugStringInternal("MaxArray");
}
void MaxArray::WhenRange(Demon* d) {
for (int i = 0; i < size_; ++i) {
vars_[i]->WhenRange(d);
}
}
// ----- Max Bool Array Ct -----
// This constraint implements max(vars) == var. It is delayed such
// that propagation only occurs when all variables have been touched.
class MaxBoolArrayCt : public ArrayConstraint {
public:
MaxBoolArrayCt(Solver* const s, const IntVar* const * vars, int size,
IntVar* var);
virtual ~MaxBoolArrayCt() {}
virtual void Post();
virtual void InitialPropagate();
void Update(int index);
void UpdateVar();
virtual string DebugString() const;
virtual void Accept(ModelVisitor* const visitor) const {
AcceptInternal(ModelVisitor::kMaxEqual, visitor);
}
private:
SmallRevBitSet bits_;
RevSwitch inhibited_;
};
MaxBoolArrayCt::MaxBoolArrayCt(Solver* const s,
const IntVar* const * vars,
int size,
IntVar* var)
: ArrayConstraint(s, vars, size, var), bits_(size) {}
void MaxBoolArrayCt::Post() {
for (int i = 0; i < size_; ++i) {
Demon* d = MakeConstraintDemon1(solver(),
this,
&MaxBoolArrayCt::Update,
"Update",
i);
vars_[i]->WhenRange(d);
}
Demon* uv = MakeConstraintDemon0(solver(),
this,
&MaxBoolArrayCt::UpdateVar,
"UpdateVar");
target_var_->WhenRange(uv);
}
void MaxBoolArrayCt::InitialPropagate() {
if (target_var_->Max() == 0) {
for (int i = 0; i < size_; ++i) {
vars_[i]->SetMax(0LL);
}
inhibited_.Switch(solver());
} else {
for (int i = 0; i < size_; ++i) {
IntVar* const var = vars_[i];
if (var->Min() == 1LL) {
target_var_->SetMin(1LL);
inhibited_.Switch(solver());
return;
}
if (var->Max() == 1LL) {
bits_.SetToOne(solver(), i);
}
}
if (bits_.IsCardinalityZero()) {
target_var_->SetValue(0LL);
inhibited_.Switch(solver());
} else if (target_var_->Min() == 1LL && bits_.IsCardinalityOne()) {
vars_[bits_.GetFirstOne()]->SetValue(1LL);
inhibited_.Switch(solver());
}
}
}
void MaxBoolArrayCt::Update(int index) {
if (!inhibited_.Switched()) {
if (vars_[index]->Min() == 1LL) { // Bound to 1.
target_var_->SetValue(1LL);
inhibited_.Switch(solver());
} else {
bits_.SetToZero(solver(), index);
if (bits_.IsCardinalityZero()) {
target_var_->SetValue(0LL);
inhibited_.Switch(solver());
} else if (target_var_->Min() == 1LL && bits_.IsCardinalityOne()) {
vars_[bits_.GetFirstOne()]->SetValue(1LL);
inhibited_.Switch(solver());
}
}
}
}
void MaxBoolArrayCt::UpdateVar() {
if (!inhibited_.Switched()) {
if (target_var_->Max() == 0) {
for (int i = 0; i < size_; ++i) {
vars_[i]->SetMax(0LL);
}
inhibited_.Switch(solver());
} else {
if (bits_.IsCardinalityOne()) {
vars_[bits_.GetFirstOne()]->SetValue(1LL);
inhibited_.Switch(solver());
}
}
}
}
string MaxBoolArrayCt::DebugString() const {
return DebugStringInternal("MaxBoolArrayCt");
}
// ----- MaxBoolArray -----
class MaxBoolArray : public ArrayExpr {
public:
// this constructor will copy the array. The caller can safely delete the
// exprs array himself
MaxBoolArray(Solver* const s, const IntVar* const* exprs, int size);
virtual ~MaxBoolArray();
virtual int64 Min() const;
virtual void SetMin(int64 m);
virtual int64 Max() const;
virtual void SetMax(int64 m);
virtual string DebugString() const;
virtual void WhenRange(Demon* d);
virtual IntVar* CastToVar() {
Solver* const s = solver();
int64 vmin = Min();
int64 vmax = Max();
IntVar* var = solver()->MakeIntVar(vmin, vmax);
CastConstraint* const ct =
s->RevAlloc(new MaxBoolArrayCt(s, vars_.get(), size_, var));
s->AddCastConstraint(ct, var, this);
return var;
}
virtual void Accept(ModelVisitor* const visitor) const {
AcceptInternal(ModelVisitor::kMax, visitor);
}
};
MaxBoolArray::~MaxBoolArray() {}
MaxBoolArray::MaxBoolArray(Solver* const s, const IntVar* const* vars, int size)
: ArrayExpr(s, vars, size) {}
int64 MaxBoolArray::Min() const {
for (int i = 0; i < size_; ++i) {
const int64 vmin = vars_[i]->Min();
if (vmin == 1LL) {
return 1LL;
}
}
return 0LL;
}
void MaxBoolArray::SetMin(int64 m) {
if (m > 1) {
solver()->Fail();
} else if (m <= 0) {
return;
}
DCHECK_EQ(m, 1LL);
int active = 0;
int curr = -1;
for (int i = 0; i < size_; ++i) {
if (vars_[i]->Max() == 1LL) {
active++;
curr = i;
}
}
if (active == 0) {
solver()->Fail();
}
if (active == 1) {
vars_[curr]->SetMin(1LL);
}
}
int64 MaxBoolArray::Max() const {
for (int i = 0; i < size_; ++i) {
const int64 vmax = vars_[i]->Max();
if (vmax == 1LL) {
return 1LL;
}
}
return 0LL;
}
void MaxBoolArray::SetMax(int64 m) {
for (int i = 0; i < size_; ++i) {
vars_[i]->SetMax(m);
}
}
string MaxBoolArray::DebugString() const {
return DebugStringInternal("MaxBoolArray");
}
void MaxBoolArray::WhenRange(Demon* d) {
for (int i = 0; i < size_; ++i) {
vars_[i]->WhenRange(d);
}
}
// ----- Builders -----
void ScanArray(IntVar* const* vars, int size, int* bound,
int64* amin, int64* amax, int64* min_max, int64* max_min) {
*amin = kint64max; // Max of the array.
*min_max = kint64max; // Smallest max in the array.
*max_min = kint64min; // Biggest min in the array.
*amax = kint64min; // Min of the array.
*bound = 0;
for (int i = 0; i < size; ++i) {
const int64 vmin = vars[i]->Min();
const int64 vmax = vars[i]->Max();
if (vmin < *amin) {
*amin = vmin;
}
if (vmax > *amax) {
*amax = vmax;
}
if (vmax < *min_max) {
*min_max = vmax;
}
if (vmin > *max_min) {
*max_min = vmin;
}
if (vmin == vmax) {
(*bound)++;
}
}
}
IntExpr* BuildMinArray(Solver* const s, IntVar* const* vars, int size) {
int64 amin = 0, amax = 0, min_max = 0, max_min = 0;
int bound = 0;
ScanArray(vars, size, &bound, &amin, &amax, &min_max, &max_min);
if (bound == size || amin == min_max) { // Bound min(array)
return s->MakeIntConst(amin);
}
if (amin == 0 && amax == 1) {
return s->RegisterIntExpr(s->RevAlloc(new MinBoolArray(s, vars, size)));
}
return s->RegisterIntExpr(s->RevAlloc(new MinArray(s, vars, size)));
}
IntExpr* BuildMaxArray(Solver* const s, IntVar* const* vars, int size) {
int64 amin = 0, amax = 0, min_max = 0, max_min = 0;
int bound = 0;
ScanArray(vars, size, &bound, &amin, &amax, &min_max, &max_min);
if (bound == size || amax == max_min) { // Bound max(array)
return s->MakeIntConst(amax);
}
if (amin == 0 && amax == 1) {
return s->RegisterIntExpr(s->RevAlloc(new MaxBoolArray(s, vars, size)));
}
return s->RegisterIntExpr(s->RevAlloc(new MaxArray(s, vars, size)));
}
enum BuildOp { MIN_OP, MAX_OP };
IntExpr* BuildLogSplitArray(Solver* const s,
IntVar* const* vars,
int size,
BuildOp op) {
const int split_size = s->parameters().array_split_size;
if (size == 0) {
return s->MakeIntConst(0LL);
} else if (size == 1) {
return vars[0];
} else if (size == 2) {
switch (op) {
case MIN_OP:
return s->MakeMin(vars[0], vars[1]);
case MAX_OP:
return s->MakeMax(vars[0], vars[1]);
};
} else if (size > split_size) {
const int nb_blocks = (size - 1) / split_size + 1;
const int block_size = (size + nb_blocks - 1) / nb_blocks;
std::vector<IntVar*> top_vector;
int start = 0;
while (start < size) {
int real_size = (start + block_size > size ? size - start : block_size);
IntVar* intermediate = NULL;
switch (op) {
case MIN_OP:
intermediate = s->MakeMin(vars + start, real_size)->Var();
break;
case MAX_OP:
intermediate = s->MakeMax(vars + start, real_size)->Var();
break;
}
top_vector.push_back(intermediate);
start += real_size;
}
switch (op) {
case MIN_OP:
return s->MakeMin(top_vector);
case MAX_OP:
return s->MakeMax(top_vector);
};
} else {
for (int i = 0; i < size; ++i) {
CHECK_EQ(s, vars[i]->solver());
}
switch (op) {
case MIN_OP:
return BuildMinArray(s, vars, size);
case MAX_OP:
return BuildMaxArray(s, vars, size);
};
}
LOG(FATAL) << "Unknown operator";
return NULL;
}
IntExpr* BuildLogSplitArray(Solver* const s,
const std::vector<IntVar*>& vars,
BuildOp op) {
return BuildLogSplitArray(s, vars.data(), vars.size(), op);
}
} // namespace
IntExpr* Solver::MakeSum(const std::vector<IntVar*>& vars) {
return MakeSum(vars.data(), vars.size());
}
IntExpr* Solver::MakeSum(IntVar* const* vars, int size) {
if (size == 0) {
return MakeIntConst(0LL);
} else if (size == 1) {
return vars[0];
} else if (size == 2) {
return MakeSum(vars[0], vars[1]);
} else {
int64 sum_min = 0;
int64 sum_max = 0;
for (int i = 0; i < size; ++i) {
sum_min += vars[i]->Min();
sum_max += vars[i]->Max();
}
IntVar* const sum_var = MakeIntVar(sum_min, sum_max);
AddCastConstraint(RevAlloc(new SumConstraint(this, vars, size, sum_var)),
sum_var,
NULL);
return sum_var;
}
}
IntExpr* Solver::MakeMin(const std::vector<IntVar*>& vars) {
return BuildLogSplitArray(this, vars, MIN_OP);
}
IntExpr* Solver::MakeMin(IntVar* const* vars, int size) {
return BuildLogSplitArray(this, vars, size, MIN_OP);
}
IntExpr* Solver::MakeMax(const std::vector<IntVar*>& vars) {
return BuildLogSplitArray(this, vars, MAX_OP);
}
IntExpr* Solver::MakeMax(IntVar* const* vars, int size) {
return BuildLogSplitArray(this, vars, size, MAX_OP);
}
// ---------- Specialized cases ----------
namespace {
bool AreAllBooleans(const IntVar* const* vars, int size) {
for (int i = 0; i < size; ++i) {
const IntVar* var = vars[i];
if (var->Min() < 0 || var->Max() > 1) {
return false;
}
}
return true;
}
template<class T> bool AreAllPositive(const T* const values, int size) {
for (int i = 0; i < size; ++i) {
if (values[i] < 0) {
return false;
}
}
return true;
}
template<class T> bool AreAllNull(const T* const values, int size) {
for (int i = 0; i < size; ++i) {
if (values[i] != 0) {
return false;
}
}
return true;
}
template <class T> bool AreAllBoundOrNull(const IntVar* const * vars,
const T* const values,
int size) {
for (int i = 0; i < size; ++i) {
if (values[i] != 0 && !vars[i]->Bound()) {
return false;
}
}
return true;
}
class BaseSumBooleanConstraint : public Constraint {
public:
BaseSumBooleanConstraint(Solver* const s,
const IntVar* const* vars,
int size)
: Constraint(s), vars_(new IntVar*[size]), size_(size) {
CHECK_GT(size_, 0);
CHECK(vars != NULL);
memcpy(vars_.get(), vars, size_ * sizeof(*vars));
}
virtual ~BaseSumBooleanConstraint() {}
protected:
string DebugStringInternal(const string& name) const;
const scoped_array<IntVar*> vars_;
const int size_;
RevSwitch inactive_;
};
string BaseSumBooleanConstraint::DebugStringInternal(const string& name) const {
string out = name + "(";
for (int i = 0; i < size_; ++i) {
if (i > 0) {
out += ", ";
}
out += vars_[i]->DebugString();
}
out += ")";
return out;
}
// ----- Sum of Boolean <= 1 -----
class SumBooleanLessOrEqualToOne : public BaseSumBooleanConstraint {
public:
SumBooleanLessOrEqualToOne(Solver* const s,
const IntVar* const* vars,
int size)
: BaseSumBooleanConstraint(s, vars, size) {}
virtual ~SumBooleanLessOrEqualToOne() {}
virtual void Post() {
for (int i = 0; i < size_; ++i) {
if (!vars_[i]->Bound()) {
Demon* u = MakeConstraintDemon1(solver(),
this,
&SumBooleanLessOrEqualToOne::Update,
"Update",
i);
vars_[i]->WhenBound(u);
}
}
}
virtual void InitialPropagate() {
for (int i = 0; i < size_; ++i) {
if (vars_[i]->Min() == 1) {
PushAllToZeroExcept(i);
return;
}
}
}
void Update(int index) {
if (!inactive_.Switched()) {
DCHECK(vars_[index]->Bound());
if (vars_[index]->Min() == 1) {
PushAllToZeroExcept(index);
}
}
}
void PushAllToZeroExcept(int index) {
inactive_.Switch(solver());
for (int i = 0; i < size_; ++i) {
if (i != index && vars_[i]->Max() != 0) {
vars_[i]->SetMax(0);
}
}
}
virtual string DebugString() const {
return DebugStringInternal("SumBooleanLessOrEqualToOne");
}
virtual void Accept(ModelVisitor* const visitor) const {
visitor->BeginVisitConstraint(ModelVisitor::kSumLessOrEqual, this);
visitor->VisitIntegerVariableArrayArgument(ModelVisitor::kVarsArgument,
vars_.get(),
size_);
visitor->VisitIntegerArgument(ModelVisitor::kValueArgument, 1);
visitor->EndVisitConstraint(ModelVisitor::kSumLessOrEqual, this);
}
};
// ----- Sum of Boolean >= 1 -----
// We implement this one as a Max(array) == 1.
class SumBooleanGreaterOrEqualToOne : public BaseSumBooleanConstraint {
public:
SumBooleanGreaterOrEqualToOne(Solver* const s, const IntVar* const * vars,
int size);
virtual ~SumBooleanGreaterOrEqualToOne() {}
virtual void Post();
virtual void InitialPropagate();
void Update(int index);
void UpdateVar();
virtual string DebugString() const;
virtual void Accept(ModelVisitor* const visitor) const {
visitor->BeginVisitConstraint(ModelVisitor::kSumGreaterOrEqual, this);
visitor->VisitIntegerVariableArrayArgument(ModelVisitor::kVarsArgument,
vars_.get(),
size_);
visitor->VisitIntegerArgument(ModelVisitor::kValueArgument, 1);
visitor->EndVisitConstraint(ModelVisitor::kSumGreaterOrEqual, this);
}
private:
RevBitSet bits_;
};
SumBooleanGreaterOrEqualToOne::SumBooleanGreaterOrEqualToOne(
Solver* const s,
const IntVar* const * vars,
int size)
: BaseSumBooleanConstraint(s, vars, size), bits_(size) {}
void SumBooleanGreaterOrEqualToOne::Post() {
for (int i = 0; i < size_; ++i) {
Demon* d = MakeConstraintDemon1(solver(),
this,
&SumBooleanGreaterOrEqualToOne::Update,
"Update",
i);
vars_[i]->WhenRange(d);
}
}
void SumBooleanGreaterOrEqualToOne::InitialPropagate() {
for (int i = 0; i < size_; ++i) {
IntVar* const var = vars_[i];
if (var->Min() == 1LL) {
inactive_.Switch(solver());
return;
}
if (var->Max() == 1LL) {
bits_.SetToOne(solver(), i);
}
}
if (bits_.IsCardinalityZero()) {
solver()->Fail();
} else if (bits_.IsCardinalityOne()) {
vars_[bits_.GetFirstBit(0)]->SetValue(1LL);
inactive_.Switch(solver());
}
}
void SumBooleanGreaterOrEqualToOne::Update(int index) {
if (!inactive_.Switched()) {
if (vars_[index]->Min() == 1LL) { // Bound to 1.
inactive_.Switch(solver());
} else {
bits_.SetToZero(solver(), index);
if (bits_.IsCardinalityZero()) {
solver()->Fail();
} else if (bits_.IsCardinalityOne()) {
vars_[bits_.GetFirstBit(0)]->SetValue(1LL);
inactive_.Switch(solver());
}
}
}
}
string SumBooleanGreaterOrEqualToOne::DebugString() const {
return DebugStringInternal("SumBooleanGreaterOrEqualToOne");
}
// ----- Sum of Boolean == 1 -----
class SumBooleanEqualToOne : public BaseSumBooleanConstraint {
public:
SumBooleanEqualToOne(Solver* const s,
IntVar* const* vars,
int size)
: BaseSumBooleanConstraint(s, vars, size), active_vars_(0) {}
virtual ~SumBooleanEqualToOne() {}
virtual void Post() {
for (int i = 0; i < size_; ++i) {
Demon* u = MakeConstraintDemon1(solver(),
this,
&SumBooleanEqualToOne::Update,
"Update",
i);
vars_[i]->WhenBound(u);
}
}
virtual void InitialPropagate() {
int min1 = 0;
int max1 = 0;
int index_min = -1;
int index_max = -1;
for (int i = 0; i < size_; ++i) {
const IntVar* const var = vars_[i];
if (var->Min() == 1) {
min1++;
index_min = i;
}
if (var->Max() == 1) {
max1++;
index_max = i;
}
}
if (min1 > 1 || max1 == 0) {
solver()->Fail();
} else if (min1 == 1) {
DCHECK_NE(-1, index_min);
PushAllToZeroExcept(index_min);
} else if (max1 == 1) {
DCHECK_NE(-1, index_max);
vars_[index_max]->SetValue(1);
inactive_.Switch(solver());
} else {
active_vars_.SetValue(solver(), max1);
}
}
void Update(int index) {
if (!inactive_.Switched()) {
DCHECK(vars_[index]->Bound());
const int64 value = vars_[index]->Min(); // Faster than Value().
if (value == 0) {
active_vars_.Decr(solver());
DCHECK_GE(active_vars_.Value(), 0);
if (active_vars_.Value() == 0) {
solver()->Fail();
} else if (active_vars_.Value() == 1) {
bool found = false;
for (int i = 0; i < size_; ++i) {
IntVar* const var = vars_[i];
if (var->Max() == 1) {
var->SetValue(1);
PushAllToZeroExcept(i);
found = true;
break;
}
}
if (!found) {
solver()->Fail();
}
}
} else {
PushAllToZeroExcept(index);
}
}
}
void PushAllToZeroExcept(int index) {
inactive_.Switch(solver());
for (int i = 0; i < size_; ++i) {
if (i != index && vars_[i]->Max() != 0) {
vars_[i]->SetMax(0);
}
}
}
virtual string DebugString() const {
return DebugStringInternal("SumBooleanEqualToOne");
}
virtual void Accept(ModelVisitor* const visitor) const {
visitor->BeginVisitConstraint(ModelVisitor::kSumEqual, this);
visitor->VisitIntegerVariableArrayArgument(ModelVisitor::kVarsArgument,
vars_.get(),
size_);
visitor->VisitIntegerArgument(ModelVisitor::kValueArgument, 1);
visitor->EndVisitConstraint(ModelVisitor::kSumEqual, this);
}
private:
NumericalRev<int> active_vars_;
};
// ----- Sum of Boolean Equal To Var -----
class SumBooleanEqualToVar : public BaseSumBooleanConstraint {
public:
SumBooleanEqualToVar(Solver* const s,
IntVar* const* bool_vars,
int size,
IntVar* const sum_var)
: BaseSumBooleanConstraint(s, bool_vars, size),
num_possible_true_vars_(0),
num_always_true_vars_(0),
sum_var_(sum_var) {}
virtual ~SumBooleanEqualToVar() {}
virtual void Post() {
for (int i = 0; i < size_; ++i) {
Demon* const u = MakeConstraintDemon1(solver(),
this,
&SumBooleanEqualToVar::Update,
"Update",
i);
vars_[i]->WhenBound(u);
}
if (!sum_var_->Bound()) {
Demon* const u = MakeConstraintDemon0(solver(),
this,
&SumBooleanEqualToVar::UpdateVar,
"UpdateVar");
sum_var_->WhenRange(u);
}
}
virtual void InitialPropagate() {
int num_always_true_vars = 0;
int possible_true = 0;
for (int i = 0; i < size_; ++i) {
const IntVar* const var = vars_[i];
if (var->Min() == 1) {
num_always_true_vars++;
}
if (var->Max() == 1) {
possible_true++;
}
}
sum_var_->SetRange(num_always_true_vars, possible_true);
const int64 var_min = sum_var_->Min();
const int64 var_max = sum_var_->Max();
if (num_always_true_vars == var_max && possible_true > var_max) {
PushAllUnboundToZero();
} else if (possible_true == var_min && num_always_true_vars < var_min) {
PushAllUnboundToOne();
} else {
num_possible_true_vars_.SetValue(solver(), possible_true);
num_always_true_vars_.SetValue(solver(), num_always_true_vars);
}
}
void UpdateVar() {
if (num_possible_true_vars_.Value() == sum_var_->Min()) {
PushAllUnboundToOne();
} else if (num_always_true_vars_.Value() == sum_var_->Max()) {
PushAllUnboundToZero();
}
}
void Update(int index) {
if (!inactive_.Switched()) {
DCHECK(vars_[index]->Bound());
const int64 value = vars_[index]->Min(); // Faster than Value().
if (value == 0) {
num_possible_true_vars_.Decr(solver());
if (num_possible_true_vars_.Value() == sum_var_->Min()) {
PushAllUnboundToOne();
}
} else {
DCHECK_EQ(1, value);
num_always_true_vars_.Incr(solver());
if (num_always_true_vars_.Value() == sum_var_->Max()) {
PushAllUnboundToZero();
}
}
}
}
void PushAllUnboundToZero() {
int64 counter = 0;
inactive_.Switch(solver());
for (int i = 0; i < size_; ++i) {
if (vars_[i]->Min() == 0) {
vars_[i]->SetValue(0);
} else {
counter++;
}
}
if (counter < sum_var_->Min() || counter > sum_var_->Max()) {
solver()->Fail();
}
}
void PushAllUnboundToOne() {
int64 counter = 0;
inactive_.Switch(solver());
for (int i = 0; i < size_; ++i) {
if (vars_[i]->Max() == 1) {
vars_[i]->SetValue(1);
counter++;
}
}
if (counter < sum_var_->Min() || counter > sum_var_->Max()) {
solver()->Fail();
}
}
virtual string DebugString() const {
return DebugStringInternal("SumBooleanEqualToVar");
}
virtual void Accept(ModelVisitor* const visitor) const {
visitor->BeginVisitConstraint(ModelVisitor::kSumEqual, this);
visitor->VisitIntegerVariableArrayArgument(ModelVisitor::kVarsArgument,
vars_.get(),
size_);
visitor->VisitIntegerExpressionArgument(ModelVisitor::kTargetArgument,
sum_var_);
visitor->EndVisitConstraint(ModelVisitor::kSumEqual, this);
}
private:
NumericalRev<int> num_possible_true_vars_;
NumericalRev<int> num_always_true_vars_;
IntVar* const sum_var_;
};
// ---------- ScalProd ----------
// ----- Boolean Scal Prod -----
struct Container {
IntVar* var;
int64 coef;
Container(IntVar* v, int64 c) : var(v), coef(c) {}
bool operator<(const Container& c) const { return (coef < c.coef); }
};
// This method will sort both vars and coefficients in increasing
// coefficient order. Vars with null coefficients will be
// removed. Bound vars will be collected and the sum of the
// corresponding products (when the var is bound to 1) is returned by
// this method.
// If keep_inside is true, the constant will be added back into the
// scalprod as IntConst(1) * constant.
int64 SortBothChangeConstant(IntVar** const vars,
int64* const coefs,
int* const size,
bool keep_inside) {
CHECK_NOTNULL(vars);
CHECK_NOTNULL(coefs);
CHECK_NOTNULL(size);
if (*size == 0) {
return 0;
}
int64 cst = 0;
std::vector<Container> to_sort;
for (int index = 0; index < *size; ++index) {
if (vars[index]->Bound()) {
cst += coefs[index] * vars[index]->Min();
} else if (coefs[index] != 0) {
to_sort.push_back(Container(vars[index], coefs[index]));
}
}
if (keep_inside && cst != 0) {
CHECK_LT(to_sort.size(), *size);
Solver* const solver = vars[0]->solver();
to_sort.push_back(Container(solver->MakeIntConst(1), cst));
cst = 0;
}
std::sort(to_sort.begin(), to_sort.end());
*size = to_sort.size();
for (int index = 0; index < *size; ++index) {
vars[index] = to_sort[index].var;
coefs[index] = to_sort[index].coef;
}
return cst;
}
// This constraint implements sum(vars) == var. It is delayed such
// that propagation only occurs when all variables have been touched.
class BooleanScalProdLessConstant : public Constraint {
public:
BooleanScalProdLessConstant(Solver* const s,
const IntVar* const * vars,
int size,
const int64* const coefs,
int64 upper_bound)
: Constraint(s),
vars_(new IntVar*[size]),
size_(size),
coefs_(new int64[size]),
upper_bound_(upper_bound),
first_unbound_backward_(size_ - 1),
sum_of_bound_variables_(0LL),
max_coefficient_(0) {
CHECK_GT(size, 0);
CHECK(vars != NULL);
CHECK(coefs != NULL);
memcpy(vars_.get(), vars, size_ * sizeof(*vars));
memcpy(coefs_.get(), coefs, size_ * sizeof(*coefs));
for (int i = 0; i < size_; ++i) {
DCHECK_GE(coefs_[i], 0);
}
upper_bound_ -= SortBothChangeConstant(vars_.get(),
coefs_.get(),
&size_,
false);
max_coefficient_.SetValue(s, coefs_[size_ - 1]);
}
BooleanScalProdLessConstant(Solver* const s,
const IntVar* const * vars,
int size,
const int* const coefs,
int64 upper_bound)
: Constraint(s),
vars_(new IntVar*[size]),
size_(size),
coefs_(new int64[size]),
upper_bound_(upper_bound),
first_unbound_backward_(size_ - 1),
sum_of_bound_variables_(0LL),
max_coefficient_(0) {
CHECK_GT(size, 0);
CHECK(vars != NULL);
CHECK(coefs != NULL);
memcpy(vars_.get(), vars, size_ * sizeof(*vars));
for (int i = 0; i < size_; ++i) {
DCHECK_GE(coefs[i], 0);
coefs_[i] = coefs[i];
}
upper_bound_ -= SortBothChangeConstant(vars_.get(),
coefs_.get(),
&size_,
false);
max_coefficient_.SetValue(s, coefs_[size_ - 1]);
}
virtual ~BooleanScalProdLessConstant() {}
virtual void Post() {
for (int var_index = 0; var_index < size_; ++var_index) {
if (vars_[var_index]->Bound()) {
continue;
}
Demon* d = MakeConstraintDemon1(
solver(),
this,
&BooleanScalProdLessConstant::Update,
"InitialPropagate",
var_index);
vars_[var_index]->WhenRange(d);
}
}
void PushFromTop() {
const int64 slack = upper_bound_ - sum_of_bound_variables_.Value();
if (slack < 0) {
solver()->Fail();
}
if (slack < max_coefficient_.Value()) {
int64 last_unbound = first_unbound_backward_.Value();
for (; last_unbound >= 0; --last_unbound) {
if (!vars_[last_unbound]->Bound()) {
if (coefs_[last_unbound] <= slack) {
max_coefficient_.SetValue(solver(), coefs_[last_unbound]);
break;
} else {
vars_[last_unbound]->SetValue(0);
}
}
}
first_unbound_backward_.SetValue(solver(), last_unbound);
}
}
virtual void InitialPropagate() {
Solver* const s = solver();
int last_unbound = -1;
int64 sum = 0LL;
for (int index = 0; index < size_; ++index) {
if (vars_[index]->Bound()) {
const int64 value = vars_[index]->Min();
sum += value * coefs_[index];
} else {
last_unbound = index;
}
}
sum_of_bound_variables_.SetValue(s, sum);
first_unbound_backward_.SetValue(s, last_unbound);
PushFromTop();
}
void Update(int var_index) {
if (vars_[var_index]->Min() == 1) {
sum_of_bound_variables_.SetValue(
solver(), sum_of_bound_variables_.Value() + coefs_[var_index]);
PushFromTop();
}
}
virtual string DebugString() const {
return StringPrintf("BooleanScalProd([%s], [%s]) <= %" GG_LL_FORMAT "d)",
DebugStringArray(vars_.get(), size_, ", ").c_str(),
Int64ArrayToString(coefs_.get(), size_, ", ").c_str(),
upper_bound_);
}
void Accept(ModelVisitor* const visitor) const {
visitor->BeginVisitConstraint(ModelVisitor::kScalProdLessOrEqual, this);
visitor->VisitIntegerVariableArrayArgument(ModelVisitor::kVarsArgument,
vars_.get(),
size_);
visitor->VisitIntegerArrayArgument(ModelVisitor::kCoefficientsArgument,
coefs_.get(),
size_);
visitor->VisitIntegerArgument(ModelVisitor::kValueArgument,
upper_bound_);
visitor->EndVisitConstraint(ModelVisitor::kScalProdLessOrEqual, this);
}
private:
scoped_array<IntVar*> vars_;
int size_;
scoped_array<int64> coefs_;
int64 upper_bound_;
Rev<int> first_unbound_backward_;
Rev<int64> sum_of_bound_variables_;
Rev<int64> max_coefficient_;
};
// ----- PositiveBooleanScalProdEqVar -----
class PositiveBooleanScalProdEqVar : public CastConstraint {
public:
PositiveBooleanScalProdEqVar(Solver* const s,
const IntVar* const * vars,
int size,
const int64* const coefs,
IntVar* const var)
: CastConstraint(s, var),
size_(size),
vars_(new IntVar*[size_]),
coefs_(new int64[size_]),
first_unbound_backward_(size_ - 1),
sum_of_bound_variables_(0LL),
sum_of_all_variables_(0LL),
max_coefficient_(0) {
CHECK_GT(size, 0);
CHECK(vars != NULL);
CHECK(coefs != NULL);
memcpy(vars_.get(), vars, size_ * sizeof(*vars));
memcpy(coefs_.get(), coefs, size_ * sizeof(*coefs));
SortBothChangeConstant(vars_.get(), coefs_.get(), &size_, true);
max_coefficient_.SetValue(s, coefs_[size_ - 1]);
}
virtual ~PositiveBooleanScalProdEqVar() {}
virtual void Post() {
for (int var_index = 0; var_index < size_; ++var_index) {
if (vars_[var_index]->Bound()) {
continue;
}
Demon* const d =
MakeConstraintDemon1(solver(),
this,
&PositiveBooleanScalProdEqVar::Update,
"Update",
var_index);
vars_[var_index]->WhenRange(d);
}
if (!target_var_->Bound()) {
Demon* const uv =
MakeConstraintDemon0(solver(),
this,
&PositiveBooleanScalProdEqVar::Propagate,
"Propagate");
target_var_->WhenRange(uv);
}
}
void Propagate() {
target_var_->SetRange(sum_of_bound_variables_.Value(),
sum_of_all_variables_.Value());
const int64 slack_up = target_var_->Max() - sum_of_bound_variables_.Value();
const int64 slack_down = sum_of_all_variables_.Value() - target_var_->Min();
const int64 max_coeff = max_coefficient_.Value();
if (slack_down < max_coeff || slack_up < max_coeff) {
int64 last_unbound = first_unbound_backward_.Value();
for (; last_unbound >= 0; --last_unbound) {
if (!vars_[last_unbound]->Bound()) {
if (coefs_[last_unbound] > slack_up) {
vars_[last_unbound]->SetValue(0);
} else if (coefs_[last_unbound] > slack_down) {
vars_[last_unbound]->SetValue(1);
} else {
max_coefficient_.SetValue(solver(), coefs_[last_unbound]);
break;
}
}
}
first_unbound_backward_.SetValue(solver(), last_unbound);
}
}
virtual void InitialPropagate() {
Solver* const s = solver();
int last_unbound = -1;
int64 sum_bound = 0;
int64 sum_all = 0;
for (int index = 0; index < size_; ++index) {
const int64 value = vars_[index]->Max() * coefs_[index];
sum_all += value;
if (vars_[index]->Bound()) {
sum_bound += value;
} else {
last_unbound = index;
}
}
sum_of_bound_variables_.SetValue(s, sum_bound);
sum_of_all_variables_.SetValue(s, sum_all);
first_unbound_backward_.SetValue(s, last_unbound);
Propagate();
}
void Update(int var_index) {
if (vars_[var_index]->Min() == 1) {
sum_of_bound_variables_.SetValue(
solver(), sum_of_bound_variables_.Value() + coefs_[var_index]);
} else {
sum_of_all_variables_.SetValue(
solver(), sum_of_all_variables_.Value() - coefs_[var_index]);
}
Propagate();
}
virtual string DebugString() const {
return StringPrintf(
"PositiveBooleanScal([%s], [%s]) == %s",
DebugStringArray(vars_.get(), size_, ", ").c_str(),
Int64ArrayToString(coefs_.get(), size_, ", ").c_str(),
target_var_->DebugString().c_str());
}
void Accept(ModelVisitor* const visitor) const {
visitor->BeginVisitConstraint(ModelVisitor::kScalProdEqual, this);
visitor->VisitIntegerVariableArrayArgument(ModelVisitor::kVarsArgument,
vars_.get(),
size_);
visitor->VisitIntegerArrayArgument(ModelVisitor::kCoefficientsArgument,
coefs_.get(),
size_);
visitor->VisitIntegerExpressionArgument(ModelVisitor::kTargetArgument,
target_var_);
visitor->EndVisitConstraint(ModelVisitor::kScalProdEqual, this);
}
private:
int size_;
scoped_array<IntVar*> vars_;
scoped_array<int64> coefs_;
Rev<int> first_unbound_backward_;
Rev<int64> sum_of_bound_variables_;
Rev<int64> sum_of_all_variables_;
Rev<int64> max_coefficient_;
};
// ----- PositiveBooleanScalProd -----
class PositiveBooleanScalProd : public BaseIntExpr {
public:
// this constructor will copy the array. The caller can safely delete the
// exprs array himself
PositiveBooleanScalProd(Solver* const s,
const IntVar* const* vars,
int size,
const int64* const coefs)
: BaseIntExpr(s),
size_(size),
vars_(new IntVar*[size_]),
coefs_(new int64[size_]) {
CHECK_GT(size_, 0);
CHECK(vars != NULL);
CHECK(coefs != NULL);
memcpy(vars_.get(), vars, size_ * sizeof(*vars));
memcpy(coefs_.get(), coefs, size_ * sizeof(*coefs));
SortBothChangeConstant(vars_.get(), coefs_.get(), &size_, true);
for (int i = 0; i < size_; ++i) {
DCHECK_GE(coefs_[i], 0);
}
}
PositiveBooleanScalProd(Solver* const s,
const IntVar* const* vars,
int size,
const int* const coefs)
: BaseIntExpr(s),
size_(size),
vars_(new IntVar*[size_]),
coefs_(new int64[size_]) {
CHECK_GT(size_, 0);
CHECK(vars != NULL);
CHECK(coefs != NULL);
memcpy(vars_.get(), vars, size_ * sizeof(*vars));
for (int i = 0; i < size_; ++i) {
coefs_[i] = coefs[i];
DCHECK_GE(coefs_[i], 0);
}
SortBothChangeConstant(vars_.get(), coefs_.get(), &size_, true);
}
virtual ~PositiveBooleanScalProd() {}
virtual int64 Min() const {
int64 min = 0;
for (int i = 0; i < size_; ++i) {
if (vars_[i]->Min()) {
min += coefs_[i];
}
}
return min;
}
virtual void SetMin(int64 m) {
SetRange(m, kint64max);
}
virtual int64 Max() const {
int64 max = 0;
for (int i = 0; i < size_; ++i) {
if (vars_[i]->Max()) {
max += coefs_[i];
}
}
return max;
}
virtual void SetMax(int64 m) {
SetRange(kint64min, m);
}
virtual void SetRange(int64 l, int64 u) {
int64 current_min = 0;
int64 current_max = 0;
int64 diameter = -1;
for (int i = 0; i < size_; ++i) {
const int64 coefficient = coefs_[i];
const int64 var_min = vars_[i]->Min() * coefficient;
const int64 var_max = vars_[i]->Max() * coefficient;
current_min += var_min;
current_max += var_max;
if (var_min != var_max) { // Coefficients are increasing.
diameter = var_max - var_min;
}
}
if (u >= current_max && l <= current_min) {
return;
}
if (u < current_min || l > current_max) {
solver()->Fail();
}
u = std::min(current_max, u);
l = std::max(l, current_min);
if (u - l > diameter) {
return;
}
for (int i = 0; i < size_; ++i) {
const int64 coefficient = coefs_[i];
IntVar* const var = vars_[i];
const int64 new_min = l - current_max + var->Max() * coefficient;
const int64 new_max = u - current_min + var->Min() * coefficient;
if (new_max < 0 || new_min > coefficient || new_min > new_max) {
solver()->Fail();
}
if (new_min > 0LL) {
var->SetMin(1LL);
} else if (new_max < coefficient) {
var->SetMax(0LL);
}
}
}
virtual string DebugString() const {
return StringPrintf(
"PositiveBooleanScalProd([%s], [%s])",
DebugStringArray(vars_.get(), size_, ", ").c_str(),
Int64ArrayToString(coefs_.get(), size_, ", ").c_str());
}
virtual void WhenRange(Demon* d) {
for (int i = 0; i < size_; ++i) {
vars_[i]->WhenRange(d);
}
}
virtual IntVar* CastToVar() {
Solver* const s = solver();
int64 vmin = 0LL;
int64 vmax = 0LL;
Range(&vmin, &vmax);
IntVar* const var = solver()->MakeIntVar(vmin, vmax);
if (size_ > 0) {
CastConstraint* const ct = s->RevAlloc(
new PositiveBooleanScalProdEqVar(s,
vars_.get(),
size_,
coefs_.get(),
var));
s->AddCastConstraint(ct, var, this);
}
return var;
}
void Accept(ModelVisitor* const visitor) const {
visitor->BeginVisitIntegerExpression(ModelVisitor::kScalProd, this);
visitor->VisitIntegerVariableArrayArgument(ModelVisitor::kVarsArgument,
vars_.get(),
size_);
visitor->VisitIntegerArrayArgument(ModelVisitor::kCoefficientsArgument,
coefs_.get(),
size_);
visitor->EndVisitIntegerExpression(ModelVisitor::kScalProd, this);
}
private:
int size_;
scoped_array<IntVar*> vars_;
scoped_array<int64> coefs_;
};
// ----- PositiveBooleanScalProdEqCst ----- (all constants >= 0)
class PositiveBooleanScalProdEqCst : public Constraint {
public:
PositiveBooleanScalProdEqCst(Solver* const s,
const IntVar* const * vars,
int size,
const int64* const coefs,
int64 constant)
: Constraint(s),
size_(size),
vars_(new IntVar*[size_]),
coefs_(new int64[size_]),
first_unbound_backward_(size_ - 1),
sum_of_bound_variables_(0LL),
sum_of_all_variables_(0LL),
constant_(constant),
max_coefficient_(0) {
CHECK_GT(size, 0);
CHECK(vars != NULL);
CHECK(coefs != NULL);
memcpy(vars_.get(), vars, size_ * sizeof(*vars));
memcpy(coefs_.get(), coefs, size_ * sizeof(*coefs));
constant_ -= SortBothChangeConstant(vars_.get(),
coefs_.get(),
&size_,
false);
max_coefficient_.SetValue(s, coefs_[size_ - 1]);
}
PositiveBooleanScalProdEqCst(Solver* const s,
const IntVar* const * vars,
int size,
const int* const coefs,
int64 constant)
: Constraint(s),
size_(size),
vars_(new IntVar*[size_]),
coefs_(new int64[size_]),
first_unbound_backward_(size_ - 1),
sum_of_bound_variables_(0LL),
sum_of_all_variables_(0LL),
constant_(constant),
max_coefficient_(0) {
CHECK_GT(size, 0);
CHECK(vars != NULL);
CHECK(coefs != NULL);
memcpy(vars_.get(), vars, size_ * sizeof(*vars));
for (int i = 0; i < size; ++i) {
coefs_[i] = coefs[i];
}
constant_ -= SortBothChangeConstant(vars_.get(),
coefs_.get(),
&size_,
false);
max_coefficient_.SetValue(s, coefs_[size_ - 1]);
}
virtual ~PositiveBooleanScalProdEqCst() {}
virtual void Post() {
for (int var_index = 0; var_index < size_; ++var_index) {
if (!vars_[var_index]->Bound()) {
Demon* const d =
MakeConstraintDemon1(solver(),
this,
&PositiveBooleanScalProdEqCst::Update,
"Update",
var_index);
vars_[var_index]->WhenRange(d);
}
}
}
void Propagate() {
if (sum_of_bound_variables_.Value() > constant_ ||
sum_of_all_variables_.Value() < constant_) {
solver()->Fail();
}
const int64 slack_up = constant_ - sum_of_bound_variables_.Value();
const int64 slack_down = sum_of_all_variables_.Value() - constant_;
const int64 max_coeff = max_coefficient_.Value();
if (slack_down < max_coeff || slack_up < max_coeff) {
int64 last_unbound = first_unbound_backward_.Value();
for (; last_unbound >= 0; --last_unbound) {
if (!vars_[last_unbound]->Bound()) {
if (coefs_[last_unbound] > slack_up) {
vars_[last_unbound]->SetValue(0);
} else if (coefs_[last_unbound] > slack_down) {
vars_[last_unbound]->SetValue(1);
} else {
max_coefficient_.SetValue(solver(), coefs_[last_unbound]);
break;
}
}
}
first_unbound_backward_.SetValue(solver(), last_unbound);
}
}
virtual void InitialPropagate() {
Solver* const s = solver();
int last_unbound = -1;
int64 sum_bound = 0LL;
int64 sum_all = 0LL;
for (int index = 0; index < size_; ++index) {
const int64 value = vars_[index]->Max() * coefs_[index];
sum_all += value;
if (vars_[index]->Bound()) {
sum_bound += value;
} else {
last_unbound = index;
}
}
sum_of_bound_variables_.SetValue(s, sum_bound);
sum_of_all_variables_.SetValue(s, sum_all);
first_unbound_backward_.SetValue(s, last_unbound);
Propagate();
}
void Update(int var_index) {
if (vars_[var_index]->Min() == 1) {
sum_of_bound_variables_.SetValue(
solver(), sum_of_bound_variables_.Value() + coefs_[var_index]);
} else {
sum_of_all_variables_.SetValue(
solver(), sum_of_all_variables_.Value() - coefs_[var_index]);
}
Propagate();
}
virtual string DebugString() const {
return StringPrintf(
"PositiveBooleanScalProd([%s], [%s]) == %" GG_LL_FORMAT "d",
DebugStringArray(vars_.get(), size_, ", ").c_str(),
Int64ArrayToString(coefs_.get(), size_, ", ").c_str(),
constant_);
}
void Accept(ModelVisitor* const visitor) const {
visitor->BeginVisitConstraint(ModelVisitor::kScalProdEqual, this);
visitor->VisitIntegerVariableArrayArgument(ModelVisitor::kVarsArgument,
vars_.get(),
size_);
visitor->VisitIntegerArrayArgument(ModelVisitor::kCoefficientsArgument,
coefs_.get(),
size_);
visitor->VisitIntegerArgument(ModelVisitor::kValueArgument,
constant_);
visitor->EndVisitConstraint(ModelVisitor::kScalProdEqual, this);
}
private:
int size_;
scoped_array<IntVar*> vars_;
scoped_array<int64> coefs_;
Rev<int> first_unbound_backward_;
Rev<int64> sum_of_bound_variables_;
Rev<int64> sum_of_all_variables_;
int64 constant_;
Rev<int64> max_coefficient_;
};
// ----- API -----
} // namespace
Constraint* Solver::MakeSumLessOrEqual(const std::vector<IntVar*>& vars, int64 cst) {
return MakeSumLessOrEqual(vars.data(), vars.size(), cst);
}
Constraint* Solver::MakeSumLessOrEqual(IntVar* const* vars,
int size,
int64 cst) {
if (cst == 1LL && AreAllBooleans(vars, size) && size > 2) {
return RevAlloc(new SumBooleanLessOrEqualToOne(this, vars, size));
} else {
return MakeLessOrEqual(MakeSum(vars, size), cst);
}
}
Constraint* Solver::MakeSumGreaterOrEqual(const std::vector<IntVar*>& vars,
int64 cst) {
return MakeSumGreaterOrEqual(vars.data(), vars.size(), cst);
}
Constraint* Solver::MakeSumGreaterOrEqual(IntVar* const* vars,
int size,
int64 cst) {
if (cst == 1LL && AreAllBooleans(vars, size) && size > 2) {
return RevAlloc(new SumBooleanGreaterOrEqualToOne(this, vars, size));
} else {
return MakeGreaterOrEqual(MakeSum(vars, size), cst);
}
}
Constraint* Solver::MakeSumEquality(const std::vector<IntVar*>& vars, int64 cst) {
return MakeSumEquality(vars.data(), vars.size(), cst);
}
Constraint* Solver::MakeSumEquality(IntVar* const* vars,
int size,
int64 cst) {
if (AreAllBooleans(vars, size) && size > 2) {
if (cst == 1) {
return RevAlloc(new SumBooleanEqualToOne(this, vars, size));
} else if (cst < 0 || cst > size) {
return MakeFalseConstraint();
} else {
return RevAlloc(new SumBooleanEqualToVar(this,
vars,
size,
MakeIntConst(cst)));
}
} else {
return RevAlloc(new SumConstraint(this, vars, size, MakeIntConst(cst)));
}
}
Constraint* Solver::MakeSumEquality(const std::vector<IntVar*>& vars,
IntVar* const var) {
return MakeSumEquality(vars.data(), vars.size(), var);
}
Constraint* Solver::MakeSumEquality(IntVar* const* vars,
int size,
IntVar* const var) {
if (AreAllBooleans(vars, size) && size > 2) {
return RevAlloc(new SumBooleanEqualToVar(this, vars, size, var));
} else {
return RevAlloc(new SumConstraint(this, vars, size, var));
}
}
Constraint* Solver::MakeScalProdEquality(const std::vector<IntVar*>& vars,
const std::vector<int64>& coefficients,
int64 cst) {
DCHECK_EQ(vars.size(), coefficients.size());
return MakeScalProdEquality(vars.data(),
vars.size(),
coefficients.data(),
cst);
}
Constraint* Solver::MakeScalProdEquality(const std::vector<IntVar*>& vars,
const std::vector<int>& coefficients,
int64 cst) {
DCHECK_EQ(vars.size(), coefficients.size());
return MakeScalProdEquality(vars.data(),
vars.size(),
coefficients.data(),
cst);
}
namespace {
template<class T> Constraint* MakeScalProdEqualityFct(Solver* const solver,
IntVar* const * vars,
int size,
T const * coefficients,
int64 cst) {
if (size == 0 || AreAllNull<T>(coefficients, size)) {
return cst == 0 ? solver->MakeTrueConstraint()
: solver->MakeFalseConstraint();
}
if (AreAllBooleans(vars, size) && AreAllPositive<T>(coefficients, size)) {
// TODO(user) : bench BooleanScalProdEqVar with IntConst.
return solver->RevAlloc(new PositiveBooleanScalProdEqCst(solver,
vars,
size,
coefficients,
cst));
}
std::vector<IntVar*> terms;
for (int i = 0; i < size; ++i) {
terms.push_back(solver->MakeProd(vars[i], coefficients[i])->Var());
}
return solver->MakeEquality(solver->MakeSum(terms), cst);
}
} // namespace
Constraint* Solver::MakeScalProdEquality(IntVar* const * vars,
int size,
int64 const * coefficients,
int64 cst) {
return MakeScalProdEqualityFct<int64>(this, vars, size, coefficients, cst);
}
Constraint* Solver::MakeScalProdEquality(IntVar* const * vars,
int size,
int const * coefficients,
int64 cst) {
return MakeScalProdEqualityFct<int>(this, vars, size, coefficients, cst);
}
Constraint* Solver::MakeScalProdGreaterOrEqual(const std::vector<IntVar*>& vars,
const std::vector<int64>& coeffs,
int64 cst) {
DCHECK_EQ(vars.size(), coeffs.size());
return MakeScalProdGreaterOrEqual(vars.data(),
vars.size(),
coeffs.data(),
cst);
}
Constraint* Solver::MakeScalProdGreaterOrEqual(const std::vector<IntVar*>& vars,
const std::vector<int>& coeffs,
int64 cst) {
DCHECK_EQ(vars.size(), coeffs.size());
return MakeScalProdGreaterOrEqual(vars.data(),
vars.size(),
coeffs.data(),
cst);
}
namespace {
template<class T>
Constraint* MakeScalProdGreaterOrEqualFct(Solver* solver,
IntVar* const * vars,
int size,
T const * coefficients,
int64 cst) {
if (size == 0 || AreAllNull<T>(coefficients, size)) {
return cst <= 0 ? solver->MakeTrueConstraint()
: solver->MakeFalseConstraint();
}
std::vector<IntVar*> terms;
for (int i = 0; i < size; ++i) {
terms.push_back(solver->MakeProd(vars[i], coefficients[i])->Var());
}
return solver->MakeGreaterOrEqual(solver->MakeSum(terms), cst);
}
} // namespace
Constraint* Solver::MakeScalProdGreaterOrEqual(IntVar* const * vars,
int size,
int64 const * coefficients,
int64 cst) {
return MakeScalProdGreaterOrEqualFct<int64>(this,
vars, size, coefficients, cst);
}
Constraint* Solver::MakeScalProdGreaterOrEqual(IntVar* const * vars,
int size,
int const * coefficients,
int64 cst) {
return MakeScalProdGreaterOrEqualFct<int>(this,
vars, size, coefficients, cst);
}
Constraint* Solver::MakeScalProdLessOrEqual(const std::vector<IntVar*>& vars,
const std::vector<int64>& coefficients,
int64 cst) {
DCHECK_EQ(vars.size(), coefficients.size());
return MakeScalProdLessOrEqual(vars.data(),
vars.size(),
coefficients.data(),
cst);
}
Constraint* Solver::MakeScalProdLessOrEqual(const std::vector<IntVar*>& vars,
const std::vector<int>& coefficients,
int64 cst) {
DCHECK_EQ(vars.size(), coefficients.size());
return MakeScalProdLessOrEqual(vars.data(),
vars.size(),
coefficients.data(),
cst);
}
namespace {
template<class T> Constraint* MakeScalProdLessOrEqualFct(Solver* solver,
IntVar* const * vars,
int size,
T const * coefficients,
int64 upper_bound) {
if (size == 0 || AreAllNull<T>(coefficients, size)) {
return upper_bound >= 0 ? solver->MakeTrueConstraint()
: solver->MakeFalseConstraint();
}
// TODO(user) : compute constant on the fly.
if (AreAllBoundOrNull(vars, coefficients, size)) {
int64 cst = 0;
for (int i = 0; i < size; ++i) {
cst += vars[i]->Min() * coefficients[i];
}
return cst <= upper_bound ?
solver->MakeTrueConstraint() :
solver->MakeFalseConstraint();
}
if (AreAllBooleans(vars, size) && AreAllPositive<T>(coefficients, size)) {
return solver->RevAlloc(new BooleanScalProdLessConstant(solver,
vars,
size,
coefficients,
upper_bound));
}
std::vector<IntVar*> terms;
for (int i = 0; i < size; ++i) {
terms.push_back(solver->MakeProd(vars[i], coefficients[i])->Var());
}
return solver->MakeLessOrEqual(solver->MakeSum(terms), upper_bound);
}
} // namespace
Constraint* Solver::MakeScalProdLessOrEqual(IntVar* const * vars,
int size,
int64 const * coefficients,
int64 cst) {
return MakeScalProdLessOrEqualFct<int64>(this, vars, size, coefficients, cst);
}
Constraint* Solver::MakeScalProdLessOrEqual(IntVar* const * vars,
int size,
int const * coefficients,
int64 cst) {
return MakeScalProdLessOrEqualFct<int>(this, vars, size, coefficients, cst);
}
IntExpr* Solver::MakeScalProd(const std::vector<IntVar*>& vars,
const std::vector<int64>& coefs) {
DCHECK_EQ(vars.size(), coefs.size());
return MakeScalProd(vars.data(), coefs.data(), vars.size());
}
IntExpr* Solver::MakeScalProd(const std::vector<IntVar*>& vars,
const std::vector<int>& coefs) {
DCHECK_EQ(vars.size(), coefs.size());
return MakeScalProd(vars.data(), coefs.data(), vars.size());
}
namespace {
template<class T> IntExpr* MakeScalProdFct(Solver* solver,
IntVar* const * vars,
const T* const coefs,
int size) {
if (size == 0 || AreAllNull<T>(coefs, size)) {
return solver->MakeIntConst(0LL);
}
if (AreAllBoundOrNull(vars, coefs, size)) {
int64 cst = 0;
for (int i = 0; i < size; ++i) {
cst += vars[i]->Min() * coefs[i];
}
return solver->MakeIntConst(cst);
}
if (AreAllBooleans(vars, size)) {
if (AreAllPositive<T>(coefs, size)) {
return solver->RegisterIntExpr(solver->RevAlloc(
new PositiveBooleanScalProd(solver, vars, size, coefs)));
} else {
// If some coefficients are non-positive, partition coefficients in two
// sets, one for the positive coefficients P and one for the negative
// ones N.
// Create two PositiveBooleanScalProd expressions, one on P (s1), the
// other on Opposite(N) (s2).
// The final expression is then s1 - s2.
// If P is empty, the expression is Opposite(s2).
std::vector<T> positive_coefs;
std::vector<T> negative_coefs;
std::vector<IntVar*> positive_coef_vars;
std::vector<IntVar*> negative_coef_vars;
for (int i = 0; i < size; ++i) {
const T coef = coefs[i];
if (coef > 0) {
positive_coefs.push_back(coef);
positive_coef_vars.push_back(vars[i]);
} else if (coef < 0) {
negative_coefs.push_back(-coef);
negative_coef_vars.push_back(vars[i]);
}
}
CHECK_GT(negative_coef_vars.size(), 0);
IntExpr* const negatives =
solver->RegisterIntExpr(solver->RevAlloc(
new PositiveBooleanScalProd(solver,
negative_coef_vars.data(),
negative_coef_vars.size(),
negative_coefs.data())));
if (!positive_coefs.empty()) {
IntExpr* const positives =
solver->RegisterIntExpr(solver->RevAlloc(
new PositiveBooleanScalProd(solver,
positive_coef_vars.data(),
positive_coef_vars.size(),
positive_coefs.data())));
// Cast to var to avoid slow propagation; all operations on the expr are
// O(n)!
return solver->MakeDifference(positives->Var(), negatives->Var());
} else {
return solver->MakeOpposite(negatives);
}
}
}
std::vector<IntVar*> terms;
for (int i = 0; i < size; ++i) {
terms.push_back(solver->MakeProd(vars[i], coefs[i])->Var());
}
return solver->MakeSum(terms);
}
} // namespace
IntExpr* Solver::MakeScalProd(IntVar* const * vars,
const int64* const coefs,
int size) {
return MakeScalProdFct<int64>(this, vars, coefs, size);
}
IntExpr* Solver::MakeScalProd(IntVar* const * vars,
const int* const coefs,
int size) {
return MakeScalProdFct<int>(this, vars, coefs, size);
}
} // namespace operations_research
Reference in New Issue View Git Blame Copy Permalink