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ortools-clone/ortools/sat/disjunctive.h
Corentin Le Molgat 1b4d75ceb3 sat: backport from main
2025-11-05 13:55:12 +01:00

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// Copyright 2010-2025 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 ORTOOLS_SAT_DISJUNCTIVE_H_
#define ORTOOLS_SAT_DISJUNCTIVE_H_
#include <algorithm>
#include <cstdint>
#include <memory>
#include <string>
#include <utility>
#include <vector>
#include "absl/log/log.h"
#include "absl/log/vlog_is_on.h"
#include "absl/strings/str_cat.h"
#include "absl/types/span.h"
#include "ortools/sat/integer.h"
#include "ortools/sat/integer_base.h"
#include "ortools/sat/model.h"
#include "ortools/sat/precedences.h"
#include "ortools/sat/sat_base.h"
#include "ortools/sat/scheduling_helpers.h"
#include "ortools/sat/synchronization.h"
#include "ortools/sat/util.h"
#include "ortools/util/scheduling.h"
#include "ortools/util/strong_integers.h"
#include "ortools/util/time_limit.h"
namespace operations_research {
namespace sat {
// Enforces a disjunctive (or no overlap) constraint on the given interval
// variables. The intervals are interpreted as [start, end) and the constraint
// enforces that no time point belongs to two intervals.
//
// TODO(user): This is not completely true for empty intervals (start == end).
// Make sure such intervals are ignored by the constraint.
void AddDisjunctive(const std::vector<Literal>& enforcement_literals,
const std::vector<IntervalVariable>& intervals,
Model* model);
// Creates Boolean variables for all the possible precedences of the form (task
// i is before task j) and forces that, for each couple of task (i,j), either i
// is before j or j is before i. Do not create any other propagators.
void AddDisjunctiveWithBooleanPrecedencesOnly(
absl::Span<const IntervalVariable> intervals, Model* model);
// Helper class to compute the end-min of a set of tasks given their start-min
// and size-min. In Petr Vilim's PhD "Global Constraints in Scheduling",
// this corresponds to his Theta-tree except that we use a O(n) implementation
// for most of the function here, not a O(log(n)) one.
class TaskSet {
public:
using Entry = SchedulingConstraintHelper::TaskInfo;
explicit TaskSet(FixedCapacityVector<Entry>& storage)
: sorted_tasks_(storage) {}
// Insertion and modification. These leave sorted_tasks_ sorted.
void Clear() {
sorted_tasks_.clear();
optimized_restart_ = 0;
}
void AddEntry(const Entry& e);
// Same as AddEntry({t, helper->ShiftedStartMin(t), helper->SizeMin(t)}).
// This is a minor optimization to not call SizeMin(t) twice.
void AddShiftedStartMinEntry(const SchedulingConstraintHelper& helper, int t);
// Advanced usage, if the entry is present, this assumes that its start_min is
// >= the end min without it, and update the datastructure accordingly.
void NotifyEntryIsNowLastIfPresent(const Entry& e);
// Advanced usage. Instead of calling many AddEntry(), it is more efficient to
// call AddUnsortedEntry() instead, but then Sort() MUST be called just after
// the insertions. Nothing is checked here, so it is up to the client to do
// that properly.
void AddUnsortedEntry(const Entry& e) { sorted_tasks_.push_back(e); }
void Sort() { std::sort(sorted_tasks_.begin(), sorted_tasks_.end()); }
// Returns the end-min for the task in the set. The time profile of the tasks
// packed to the left will always be a set of contiguous tasks separated by
// empty space:
//
// [Bunch of tasks] ... [Bunch of tasks] ... [critical tasks].
//
// We call "critical tasks" the last group. These tasks will be solely
// responsible for the end-min of the whole set. The returned
// critical_index will be the index of the first critical task in
// SortedTasks().
//
// A reason for the min end is:
// - The size-min of all the critical tasks.
// - The fact that all critical tasks have a start-min greater or equal to the
// first of them, that is SortedTasks()[critical_index].start_min.
//
// It is possible to behave like if one task was not in the set by setting
// task_to_ignore to the id of this task. This returns 0 if the set is empty
// in which case critical_index will be left unchanged.
IntegerValue ComputeEndMin(int task_to_ignore, int* critical_index) const;
IntegerValue ComputeEndMin() const;
// Warning, this is only valid if ComputeEndMin() was just called. It is the
// same index as if one called ComputeEndMin(-1, &critical_index), but saves
// another unneeded loop.
int GetCriticalIndex() const { return optimized_restart_; }
absl::Span<const Entry> SortedTasks() const { return sorted_tasks_; }
private:
FixedCapacityVector<Entry>& sorted_tasks_;
mutable int optimized_restart_ = 0;
};
// Simple class to display statistics at the end if --v=1.
struct PropagationStatistics {
explicit PropagationStatistics(std::string _name, Model* model = nullptr)
: name(_name),
shared_stats(model == nullptr
? nullptr
: model->GetOrCreate<SharedStatistics>()) {};
~PropagationStatistics() {
if (shared_stats == nullptr) return;
if (!VLOG_IS_ON(1)) return;
std::vector<std::pair<std::string, int64_t>> stats;
stats.push_back({absl::StrCat(name, "/num_calls"), num_calls});
stats.push_back({absl::StrCat(name, "/num_calls_with_propagation"),
num_calls_with_propagation});
stats.push_back(
{absl::StrCat(name, "/num_calls_with_conflicts"), num_conflicts});
stats.push_back(
{absl::StrCat(name, "/num_propagations"), num_propagations});
shared_stats->AddStats(stats);
}
void OnPropagate() {
++num_calls;
saved_num_propag = num_propagations;
}
void EndWithoutConflicts() {
if (num_propagations > saved_num_propag) {
++num_calls_with_propagation;
}
}
const std::string name;
SharedStatistics* shared_stats;
int64_t saved_num_propag;
int64_t num_calls = 0;
int64_t num_calls_with_propagation = 0; // Only count if we did something.
int64_t num_conflicts = 0;
int64_t num_propagations = 0;
};
// ============================================================================
// Below are many of the known propagation techniques for the disjunctive, each
// implemented in only one time direction and in its own propagator class. The
// Disjunctive() model function above will instantiate the used ones (according
// to the solver parameters) in both time directions.
//
// See Petr Vilim PhD "Global Constraints in Scheduling" for a description of
// some of the algorithm.
// ============================================================================
class DisjunctiveOverloadChecker : public PropagatorInterface {
public:
explicit DisjunctiveOverloadChecker(SchedulingConstraintHelper* helper,
Model* model = nullptr)
: helper_(helper),
task_to_event_(new int[helper->NumTasks()]),
stats_("DisjunctiveOverloadChecker", model) {
// This is just needed to prevent use of uninitialized values.
std::fill(task_to_event_.get(), task_to_event_.get() + helper->NumTasks(),
-1);
}
bool Propagate() final;
int RegisterWith(GenericLiteralWatcher* watcher);
private:
bool PropagateSubwindow(absl::Span<TaskTime> sub_window,
IntegerValue global_window_end,
absl::Span<const CachedTaskBounds>*
task_by_increasing_negated_shifted_end_max);
SchedulingConstraintHelper* helper_;
// Size assigned at construction, stay fixed afterwards.
std::unique_ptr<int[]> task_to_event_;
ThetaLambdaTree<IntegerValue> theta_tree_;
PropagationStatistics stats_;
};
// This one is a simpler version of DisjunctiveDetectablePrecedences, it
// detect all implied precedences between TWO tasks and push bounds accordingly.
// If we created all pairwise precedence Booleans, this would already be
// propagated and in this case we don't create this propagator.
//
// Otherwise, this generate short reason and is good to do early as it
// propagates a lot.
class DisjunctiveSimplePrecedences : public PropagatorInterface {
public:
explicit DisjunctiveSimplePrecedences(SchedulingConstraintHelper* helper,
Model* model = nullptr)
: helper_(helper), stats_("DisjunctiveSimplePrecedences", model) {}
bool Propagate() final;
int RegisterWith(GenericLiteralWatcher* watcher);
private:
bool PropagateOneDirection();
bool Push(TaskTime before, int t);
SchedulingConstraintHelper* helper_;
PropagationStatistics stats_;
};
class DisjunctiveDetectablePrecedences : public PropagatorInterface {
public:
DisjunctiveDetectablePrecedences(bool time_direction,
SchedulingConstraintHelper* helper,
Model* model = nullptr)
: time_direction_(time_direction),
helper_(helper),
stats_("DisjunctiveDetectablePrecedences", model) {
ranks_.resize(helper->NumTasks());
to_add_.ClearAndReserve(helper->NumTasks());
}
bool Propagate() final;
int RegisterWith(GenericLiteralWatcher* watcher);
private:
bool PropagateWithRanks();
bool Push(IntegerValue task_set_end_min, int t, TaskSet& task_set);
FixedCapacityVector<int> to_add_;
std::vector<int> ranks_;
const bool time_direction_;
SchedulingConstraintHelper* helper_;
PropagationStatistics stats_;
};
// This propagates the same things as DisjunctiveDetectablePrecedences, except
// that it only sort the full set of intervals once and then work on a combined
// set of disjunctives.
template <bool time_direction>
class CombinedDisjunctive : public PropagatorInterface {
public:
explicit CombinedDisjunctive(Model* model);
// After creation, this must be called for all the disjunctive constraints
// in the model which have no enforcement literals.
void AddNoOverlap(absl::Span<const IntervalVariable> var);
bool Propagate() final;
private:
SchedulingConstraintHelper* helper_;
std::vector<std::vector<int>> task_to_disjunctives_;
std::vector<bool> task_is_added_;
std::vector<TaskSet> task_sets_;
std::vector<FixedCapacityVector<TaskSet::Entry>> task_set_storage_;
std::vector<IntegerValue> end_mins_;
};
class DisjunctiveNotLast : public PropagatorInterface {
public:
DisjunctiveNotLast(bool time_direction, SchedulingConstraintHelper* helper,
Model* model = nullptr)
: time_direction_(time_direction),
helper_(helper),
stats_("DisjunctiveNotLast", model) {}
bool Propagate() final;
int RegisterWith(GenericLiteralWatcher* watcher);
private:
bool PropagateSubwindow(TaskSet& task_set,
absl::Span<TaskTime> task_by_increasing_start_max,
absl::Span<TaskTime> task_by_increasing_end_max);
const bool time_direction_;
SchedulingConstraintHelper* helper_;
PropagationStatistics stats_;
};
class DisjunctiveEdgeFinding : public PropagatorInterface {
public:
DisjunctiveEdgeFinding(bool time_direction,
SchedulingConstraintHelper* helper,
Model* model = nullptr)
: time_direction_(time_direction),
helper_(helper),
stats_("DisjunctiveEdgeFinding", model) {
event_size_.ClearAndReserve(helper->NumTasks());
}
bool Propagate() final;
int RegisterWith(GenericLiteralWatcher* watcher);
private:
bool PropagateSubwindow(
IntegerValue window_end_min, absl::Span<const TaskTime> window,
FixedCapacityVector<TaskTime>& task_by_increasing_end_max);
const bool time_direction_;
SchedulingConstraintHelper* helper_;
// All these member are indexed in the same way.
ThetaLambdaTree<IntegerValue> theta_tree_;
FixedCapacityVector<IntegerValue> event_size_;
// Task indexed.
std::vector<int> non_gray_task_to_event_;
std::vector<bool> is_gray_;
PropagationStatistics stats_;
};
// Exploits the precedences relations of the form "this set of disjoint
// IntervalVariables must be performed before a given IntegerVariable". The
// relations are computed with PrecedencesPropagator::ComputePrecedences().
class DisjunctivePrecedences : public PropagatorInterface {
public:
DisjunctivePrecedences(bool time_direction,
SchedulingConstraintHelper* helper, Model* model)
: time_direction_(time_direction),
helper_(helper),
integer_trail_(*model->GetOrCreate<IntegerTrail>()),
precedence_relations_(model->GetOrCreate<EnforcedLinear2Bounds>()),
linear2_bounds_(model->GetOrCreate<Linear2Bounds>()),
time_limit_(model->GetOrCreate<TimeLimit>()),
stats_("DisjunctivePrecedences", model) {
index_to_end_vars_.ClearAndReserve(helper->NumTasks());
indices_before_.ClearAndReserve(helper->NumTasks());
}
bool Propagate() final;
int RegisterWith(GenericLiteralWatcher* watcher);
private:
bool PropagateSubwindow(absl::Span<TaskTime> window);
const bool time_direction_;
SchedulingConstraintHelper* helper_;
const IntegerTrail& integer_trail_;
EnforcedLinear2Bounds* precedence_relations_;
Linear2Bounds* linear2_bounds_;
TimeLimit* time_limit_;
FixedCapacityVector<IntegerVariable> index_to_end_vars_;
FixedCapacityVector<std::pair<int, LinearExpression2Index>> indices_before_;
std::vector<bool> skip_;
std::vector<EnforcedLinear2Bounds::PrecedenceData> before_;
PropagationStatistics stats_;
};
// This is an optimization for the case when we have a big number of such
// pairwise constraints. This should be roughly equivalent to what the general
// disjunctive case is doing, but it dealt with variable size better and has a
// lot less overhead.
class DisjunctiveWithTwoItems : public PropagatorInterface {
public:
explicit DisjunctiveWithTwoItems(SchedulingConstraintHelper* helper)
: helper_(helper) {}
bool Propagate() final;
int RegisterWith(GenericLiteralWatcher* watcher);
private:
SchedulingConstraintHelper* helper_;
};
} // namespace sat
} // namespace operations_research
#endif // ORTOOLS_SAT_DISJUNCTIVE_H_
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