org.chocosolver.solver.constraints.nary.channeling.PropClauseChanneling Maven / Gradle / Ivy
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/*
* This file is part of choco-solver, http://choco-solver.org/
*
* Copyright (c) 2022, IMT Atlantique. All rights reserved.
*
* Licensed under the BSD 4-clause license.
*
* See LICENSE file in the project root for full license information.
*/
package org.chocosolver.solver.constraints.nary.channeling;
import org.chocosolver.memory.IStateInt;
import org.chocosolver.solver.constraints.Propagator;
import org.chocosolver.solver.constraints.PropagatorPriority;
import org.chocosolver.solver.exception.ContradictionException;
import org.chocosolver.solver.exception.SolverException;
import org.chocosolver.solver.variables.BoolVar;
import org.chocosolver.solver.variables.IntVar;
import org.chocosolver.solver.variables.delta.IIntDeltaMonitor;
import org.chocosolver.solver.variables.events.IntEventType;
import org.chocosolver.util.ESat;
import org.chocosolver.util.procedure.IntProcedure;
import org.chocosolver.util.tools.ArrayUtils;
/**
* A propagator which links an IntVar with two arrays of BoolVar, one for EQ relations, the other for LQ relations.
* Such a propagator is needed when clauses learning is on.
*
* Created by cprudhom on 14/01/15.
* Project: choco.
*/
public class PropClauseChanneling extends Propagator {
private final IntVar iv;
private final boolean bounded;
private final IIntDeltaMonitor dm;
private final BoolVar[] eqs; // EQ bool vars
private final BoolVar[] lqs; // LQ bool vars
private final IStateInt LB;
private final IStateInt UB; // keep trace of lb and ub of iv to ease propagation
private final int OFFSET;
private final int LENGTH;
public PropClauseChanneling(IntVar iv, BoolVar[] eb, BoolVar[] lb) {
super(ArrayUtils.append(new IntVar[]{iv}, eb, lb), PropagatorPriority.LINEAR, true);
this.iv = iv;
this.bounded = !iv.hasEnumeratedDomain();
this.eqs = eb;
this.lqs = lb;
this.OFFSET = iv.getLB();
this.LENGTH = iv.getUB() - iv.getLB() + 1;
this.LB = model.getEnvironment().makeInt();
this.UB = model.getEnvironment().makeInt(LENGTH);
this.dm = iv.hasEnumeratedDomain() ? iv.monitorDelta(this) : IIntDeltaMonitor.Default.NONE;
if (eb.length != LENGTH || lb.length != LENGTH) {
throw new SolverException("BoolVar[] wrong dimension");
}
}
@Override
public void propagate(int evtmask) throws ContradictionException {
if (iv.isInstantiated()) {
int value = iv.getValue() - OFFSET;
eqs[value].instantiateTo(1, this);
lqs[value].instantiateTo(1, this);
}
// values below current iv lb
int lb = iv.getLB() - OFFSET;
int ub = iv.getUB() - OFFSET;
for (int i = 0; i < lb; i++) {
eqs[i].instantiateTo(0, this);
lqs[i].instantiateTo(0, this);
}
// values above current iv ub
for (int i = ub + 1; i < LENGTH; i++) {
eqs[i].instantiateTo(0, this);
lqs[i].instantiateTo(1, this);
}
// first, update only eqs and iv
while (lb < LENGTH && eqs[lb].isInstantiated()) {
if (eqs[lb].isInstantiatedTo(0)) {
iv.removeValue(lb + OFFSET, this);
} else {
iv.instantiateTo(lb + OFFSET, this);
}
lb++;
}
while (ub > -1 && eqs[ub].isInstantiated()) {
if (eqs[ub].isInstantiatedTo(0)) {
iv.removeValue(ub + OFFSET, this);
} else {
iv.instantiateTo(ub + OFFSET, this);
}
ub--;
}
if (!bounded) {
for (int i = lb + 1; i < ub; i++) {
if (!iv.contains(i + OFFSET)) {
eqs[i].instantiateTo(0, this);
} else if (eqs[i].isInstantiated()) {
if (eqs[i].isInstantiatedTo(0)) {
iv.removeValue(i + OFFSET, this);
} else {
iv.instantiateTo(i + OFFSET, this);
}
}
}
}
// now iv and eqs are synchronized
// then, second pass to update lqs
while (lb < LENGTH && !iv.contains(lb + OFFSET)) {
lqs[lb++].instantiateTo(0, this);
}
while (ub > -1 && !iv.contains(ub + OFFSET)) {
lqs[ub--].instantiateTo(1, this);
}
if (ub > -1) lqs[ub].instantiateTo(1, this); // current UB needs to be instantiated to true
LB.set(lb);
UB.set(ub);
// finally delta monitor
dm.startMonitoring();
}
@Override
public void propagate(int vidx, int mask) throws ContradictionException {
if (vidx == 0) { //iv has been modified
if (IntEventType.isInstantiate(mask)) {
_inst(iv.getValue() - OFFSET);
} else {
int lb = LB.get();
int ub = UB.get();
if (IntEventType.isInclow(mask)) {
_ulb(iv.getLB() - OFFSET, lb);
}
if (IntEventType.isDecupp(mask)) {
_uub(iv.getUB() - OFFSET, ub);
}
// then deal with removed values
dm.forEachRemVal((IntProcedure) value -> {
value -= OFFSET;
if (value > lb && value < ub) {
eqs[value].instantiateTo(0, this);
}
});
}
} else {
vidx--; // idx in eqs or lqs
int act = 0;
if (vidx < LENGTH) { // then EQ bool var
if (eqs[vidx].getValue() != 1) {
if (vidx == LB.get()) {
act = 1;
} else if (vidx == UB.get()) {
act = 2;
vidx--;
} else {
act = 3;
}
}
} else { // then LQ bool var
vidx -= LENGTH;
if (lqs[vidx].getValue() == 1) {
act = 2;
} else {
act = 1;
}
}
switch (act) {
case 0: // instantiation
iv.instantiateTo(vidx + OFFSET, this);
_inst(vidx);
break;
case 1: // update lower bound
iv.updateLowerBound(vidx + OFFSET + 1, this);
if (iv.isInstantiated()) {
_inst(iv.getValue() - OFFSET);
} else {
_ulb(iv.getLB() - OFFSET, LB.get());
}
break;
case 2: // update upper bound
iv.updateUpperBound(vidx + OFFSET, this);
if (iv.isInstantiated()) {
_inst(iv.getValue() - OFFSET);
} else {
_uub(iv.getUB() - OFFSET, UB.get());
}
break;
case 3: // value removal
iv.removeValue(vidx + OFFSET, this);
if (iv.isInstantiated()) {
_inst(iv.getValue() - OFFSET);
} else {
_rem(vidx);
}
break;
}
}
}
/**
* Actions to apply on int var instantiation
*
* @param value instantiated value (offsetted)
* @throws ContradictionException when failure is detected
*/
private void _inst(int value) throws ContradictionException {
_ulb(value, LB.get());
eqs[value].instantiateTo(1, this);
lqs[value].instantiateTo(1, this);
_uub(value, UB.get());
}
/**
* Actions to apply on lower bound int var modification
*
* @param nlb new lower bound value (offsetted)
* @param olb old lower bound (offsetted)
* @throws ContradictionException when failure is detected
*/
private void _ulb(int nlb, int olb) throws ContradictionException {
for (int i = olb; i < nlb; i++) {
eqs[i].instantiateTo(0, this);
lqs[i].instantiateTo(0, this);
}
LB.set(nlb);
if (eqs[nlb].isInstantiatedTo(0)) {
nlb++;
while (nlb < LENGTH && eqs[nlb].isInstantiatedTo(0)) {
nlb++;
}
iv.updateLowerBound(nlb + OFFSET, this);
if (iv.isInstantiated()) {
_inst(iv.getValue() - OFFSET);
} else {
_ulb(iv.getLB() - OFFSET, LB.get());
}
}
}
/**
* Actions to apply on upper bound int var modification
*
* @param nub new upper bound value (offsetted)
* @param oub old upper bound (offsetted)
* @throws ContradictionException when failure is detected
*/
private void _uub(int nub, int oub) throws ContradictionException {
for (int i = oub; i > nub; i--) {
eqs[i].instantiateTo(0, this);
lqs[i].instantiateTo(1, this);
}
lqs[nub].instantiateTo(1, this);
UB.set(nub);
if (eqs[nub].isInstantiatedTo(0)) {
nub--;
while (nub > -1 && eqs[nub].isInstantiatedTo(0)) {
nub--;
}
iv.updateUpperBound(nub + OFFSET, this);
if (iv.isInstantiated()) {
_inst(iv.getValue() - OFFSET);
} else {
_uub(iv.getUB() - OFFSET, UB.get());
}
}
}
/**
* Actions to apply on value removal from int var
*
* @param value removed value (offsetted)
* @throws ContradictionException when failure is detected
*/
private void _rem(int value) throws ContradictionException {
eqs[value].instantiateTo(0, this);
if (iv.isInstantiated()) {
_inst(iv.getValue());
}
}
@Override
public ESat isEntailed() {
if (isCompletelyInstantiated()) {
int value = iv.getValue() - OFFSET;
// for all values below the current lower bound
for (int k = 0; k < value; k++) {
if (eqs[k].isInstantiatedTo(1) || lqs[k].isInstantiatedTo(1)) {
return ESat.FALSE;
}
}
if (eqs[value].isInstantiatedTo(0) || lqs[value].isInstantiatedTo(0)) return ESat.FALSE;
for (int k = value + 1; k < LENGTH; k++) {
if (eqs[k].isInstantiatedTo(1) || lqs[k].isInstantiatedTo(0)) {
return ESat.FALSE;
}
}
return ESat.TRUE;
}
return ESat.UNDEFINED;
}
}