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Open-source constraint solver.
/*
* This file is part of choco-solver, http://choco-solver.org/
*
* Copyright (c) 2019, 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.extension.nary;
import org.chocosolver.solver.constraints.extension.Tuples;
import org.chocosolver.solver.exception.ContradictionException;
import org.chocosolver.solver.variables.IntVar;
import org.chocosolver.solver.variables.events.PropagatorEventType;
import org.chocosolver.util.iterators.DisposableValueIterator;
import org.chocosolver.util.objects.setDataStructures.iterable.IntIterableBitSet;
import java.util.Arrays;
/**
*
*
* @author Charles Prud'homme, Hadrien Cambazard
* @since 24/04/2014
*/
public class PropLargeGAC3rm extends PropLargeCSP {
// Last valid supports Last(x_i, val) = supports( (blocks(i) + val) * size )
private int[] supports;
private int[] blocks;
// Cardinality
private int size;
// offsets(i) = Min(x_i)
private int[] offsets;
private DisposableValueIterator[] seekIter;
private final IntIterableBitSet vrms;
private PropLargeGAC3rm(IntVar[] vs, LargeRelation relation) {
super(vs, relation);
this.size = vs.length;
this.blocks = new int[size];
this.offsets = new int[size];
int nbElt = 0;
for (int i = 0; i < size; i++) {
offsets[i] = vs[i].getLB();
blocks[i] = nbElt;
if (!vars[i].hasEnumeratedDomain()) {
nbElt += 2;
} else nbElt += vars[i].getUB() - vars[i].getLB() + 1;
}
this.supports = new int[nbElt * size];
this.seekIter = new DisposableValueIterator[size];
for (int i = 0; i < size; i++) {
seekIter[i] = vars[i].getValueIterator(true);
}
Arrays.fill(supports, Integer.MIN_VALUE);
vrms = new IntIterableBitSet();
}
public PropLargeGAC3rm(IntVar[] vs, Tuples tuples) {
this(vs, RelationFactory.makeLargeRelation(tuples, vs));
}
@Override
public void propagate(int evtmask) throws ContradictionException {
if ((evtmask & PropagatorEventType.FULL_PROPAGATION.getMask()) != 0) {
for (int i = 0; i < vars.length; i++) {
initializeSupports(i);
}
}
for (int i = 0; i < size; i++)
reviseVar(i);
}
@Override
public void propagate(int idxVarInProp, int mask) throws ContradictionException {
for (int i = 0; i < size; i++)
if (idxVarInProp != i) reviseVar(i);
if (!vars[idxVarInProp].hasEnumeratedDomain()) {
reviseVar(idxVarInProp);
}
}
////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
/**
* initialize the supports of each value of indexVar
*
* @throws ContradictionException
*/
private void initializeSupports(int indexVar) throws ContradictionException {
int[] currentSupport;
int val;
if (vars[indexVar].hasEnumeratedDomain()) {
DisposableValueIterator it = vars[indexVar].getValueIterator(true);
vrms.clear();
vrms.setOffset(vars[indexVar].getLB());
try {
while (it.hasNext()) {
val = it.next();
if (lastSupport(indexVar, val)[0] == Integer.MIN_VALUE) { // no supports initialized yet for this value
currentSupport = seekNextSupport(indexVar, val);
if (currentSupport != null) {
setSupport(currentSupport);
} else {
vrms.add(val);
// vars[indexVar].removeVal(val, this, false);
}
}
}
vars[indexVar].removeValues(vrms, this);
} finally {
it.dispose();
}
} else {
for (val = vars[indexVar].getLB(); val <= vars[indexVar].getUB(); val++) {
currentSupport = seekNextSupport(indexVar, val);
if (currentSupport != null) {
setBoundSupport(indexVar, 0, currentSupport);
break; //stop at the first consistent lower bound !
}
}
vars[indexVar].updateLowerBound(val, this);
for (val = vars[indexVar].getUB(); val >= vars[indexVar].getLB(); val--) {
currentSupport = seekNextSupport(indexVar, val);
if (currentSupport != null) {
setBoundSupport(indexVar, 1, currentSupport);
break; //stop at the first consistent upper bound !
}
}
vars[indexVar].updateUpperBound(val, this);
}
}
// updates the support for all values in the domain of variable
// and remove unsupported values for variable
private void reviseVar(int indexVar) throws ContradictionException {
int[] currentSupport;
int val;
if (vars[indexVar].hasEnumeratedDomain()) {
DisposableValueIterator it = vars[indexVar].getValueIterator(true);
vrms.clear();
vrms.setOffset(vars[indexVar].getLB());
try {
while (it.hasNext()) {
val = it.next();
if (isInvalid(lastSupport(indexVar, val))) {
currentSupport = seekNextSupport(indexVar, val);
if (currentSupport != null) {
setSupport(currentSupport);
} else {
vrms.add(val);
// vars[indexVar].removeVal(val, this, false);
}
}
}
vars[indexVar].removeValues(vrms, this);
} finally {
it.dispose();
}
} else {
int[] inf_supports = lastBoundSupport(indexVar, 0);
if (vars[indexVar].getLB() != inf_supports[indexVar] || isInvalid(inf_supports)) {
for (val = vars[indexVar].getLB(); val <= vars[indexVar].getUB(); val++) {
currentSupport = seekNextSupport(indexVar, val);
if (currentSupport != null) {
setBoundSupport(indexVar, 0, currentSupport);
break; //stop at the first consistent lower bound !
}
}
vars[indexVar].updateLowerBound(val, this);
}
int[] sup_supports = lastBoundSupport(indexVar, 1);
if (vars[indexVar].getUB() != sup_supports[indexVar] || isInvalid(sup_supports)) {
for (val = vars[indexVar].getUB(); val >= vars[indexVar].getLB(); val--) {
currentSupport = seekNextSupport(indexVar, val);
if (currentSupport != null) {
setBoundSupport(indexVar, 1, currentSupport);
break; //stop at the first consistent upper bound !
}
}
vars[indexVar].updateUpperBound(val, this);
}
}
}
// Store Last(x_i, val) = support
private void setSupport(int[] support) {
for (int i = 0; i < vars.length; i++) {
if (vars[i].hasEnumeratedDomain())
setOneSupport(i, support[i], support);
}
}
private void setOneSupport(int indexVar, int value, int[] support) {
System.arraycopy(support, 0, supports, (blocks[indexVar] + value - offsets[indexVar]) * size, vars.length);
}
// Store Last(x_i, val) = support
private void setBoundSupport(int indexVar, int idxBound, int[] support) {
System.arraycopy(support, 0, supports, (blocks[indexVar] + idxBound) * size, vars.length);
}
// Get Last(x_i, val)
private int[] getUBport(int indexVar, int value) {
int[] resultat = new int[size];
System.arraycopy(supports, (blocks[indexVar] + value - offsets[indexVar]) * size, resultat, 0, size);
return resultat;
}
// return the support standing for the lower bound
// of indexVar if idxBound = 0 or upperbound if idxBound = 1
private int[] getBoundSupport(int indexVar, int idxBound) {
int[] resultat = new int[size];
System.arraycopy(supports, (blocks[indexVar] + idxBound) * size, resultat, 0, size);
return resultat;
}
// Get Last(x_i, val)
private int[] lastSupport(int indexVar, int value) {
return getUBport(indexVar, value);
}
// return the support standing for the lower bound
// of indexVar if idxBound = 0 or upperbound if idxBound = 1
private int[] lastBoundSupport(int indexVar, int idxBound) {
return getBoundSupport(indexVar, idxBound);
}
// Is tuple invalid ?
private boolean isInvalid(int[] tuple) {
for (int i = 0; i < size; i++)
if (!vars[i].contains(tuple[i])) return true;
return false;
}
// seek a new support for (variable, value), the smallest tuple greater than currentSupport
private int[] seekNextSupport(int indexVar, int val) {
int[] currentSupport = new int[size];
int k = 0;
for (int i = 0; i < size; i++) {
seekIter[i].dispose();
seekIter[i] = vars[i].getValueIterator(true);
if (i != indexVar)
currentSupport[i] = seekIter[i].next();
else currentSupport[i] = val;
}
if (relation.isConsistent(currentSupport)) {
return currentSupport;
}
while (k < vars.length) {
if (k == indexVar) k++;
if (k < vars.length) {
if (!seekIter[k].hasNext()) {
seekIter[k].dispose();
seekIter[k] = vars[k].getValueIterator(true);
currentSupport[k] = seekIter[k].next();
k++;
} else {
currentSupport[k] = seekIter[k].next();
if ((relation.isConsistent(currentSupport))) {
return currentSupport;
}
k = 0;
}
}
}
return null;
}
}