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/*
* This file is part of choco-solver, http://choco-solver.org/
*
* Copyright (c) 2023, 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.util.tools;
import org.chocosolver.solver.Model;
import org.chocosolver.solver.expression.continuous.arithmetic.RealIntervalConstant;
import org.chocosolver.solver.variables.IntVar;
import org.chocosolver.solver.variables.RealVar;
import org.chocosolver.solver.variables.Variable;
import org.chocosolver.util.objects.RealInterval;
import org.chocosolver.util.objects.setDataStructures.iterable.IntIterableRangeSet;
import org.chocosolver.util.objects.setDataStructures.iterable.IntIterableSetUtils;
import java.util.Arrays;
import java.util.Iterator;
import java.util.stream.IntStream;
import static java.util.Arrays.stream;
/**
*
* Project: choco-solver.
*
* @author Charles Prud'homme
* @since 28/04/2016.
*/
public class VariableUtils {
/**
* @param vars array of variables
* @return computes the bounds for the sum of vars
*/
public static int[] boundsForAddition(IntVar... vars) {
long[] bounds = new long[2];
IntStream.range(0, vars.length).forEach(i -> {
bounds[0] += vars[i].getLB();
bounds[1] += vars[i].getUB();
}
);
return new int[]{MathUtils.safeCast(bounds[0]), MathUtils.safeCast(bounds[1])};
}
/**
* @param vars array of variables
* @return computes the bounds for the sum of vars
*/
public static int[] boundsForScalar(IntVar[] vars, int[] coeffs) {
long[] bounds = new long[2];
for (int i = 0; i < vars.length; i++) {
int c = coeffs[i];
if (c >= 0) {
bounds[0] += (long) vars[i].getLB() * coeffs[i];
bounds[1] += (long) vars[i].getUB() * coeffs[i];
} else {
bounds[0] += (long) vars[i].getUB() * coeffs[i];
bounds[1] += (long) vars[i].getLB() * coeffs[i];
}
}
return new int[]{MathUtils.safeCast(bounds[0]), MathUtils.safeCast(bounds[1])};
}
/**
* @param vars array of variables
* @return computes the bounds for the sum of vars
*/
public static double[] boundsForAddition(RealVar... vars) {
double[] bounds = new double[2];
for (int i = 0; i < vars.length; i++) {
bounds[0] += vars[i].getLB();
bounds[1] += vars[i].getUB();
}
return bounds;
}
private static int[] bound(long... values) {
return new int[]{
MathUtils.safeCast(stream(values).min().getAsLong()),
MathUtils.safeCast(stream(values).max().getAsLong())
};
}
private static double[] bound(double... values) {
return new double[]{stream(values).min().getAsDouble(), stream(values).max().getAsDouble()};
}
/**
* @param x a variable
* @param y a variable
* @return computes the bounds for "x - y"
*/
public static int[] boundsForSubstraction(IntVar x, IntVar y) {
return new int[]{
MathUtils.safeCast(x.getLB() - y.getUB()),
MathUtils.safeCast(x.getUB() - y.getLB())};
}
/**
* @param x a variable
* @param y a variable
* @return computes the bounds for "x - y"
*/
public static double[] boundsForSubstraction(RealVar x, RealVar y) {
RealInterval res = RealUtils.sub(x, y);
return new double[]{res.getLB(), res.getUB()};
}
/**
* @param x a variable
* @param y a variable
* @return computes the bounds for "x * y"
*/
public static int[] boundsForMultiplication(IntVar x, IntVar y) {
return bound(
(long) x.getLB() * y.getLB(),
(long) x.getLB() * y.getUB(),
(long) x.getUB() * y.getLB(),
(long) x.getUB() * y.getUB()
);
}
/**
* @param x a variable
* @param y a variable
* @return computes the bounds for "x * y"
*/
public static double[] boundsForMultiplication(RealVar x, RealVar y) {
RealInterval res = RealUtils.mul(x, y);
return new double[]{res.getLB(), res.getUB()};
}
/**
* @param x a variable
* @param y a variable
* @return computes the bounds for "x / y"
*/
public static int[] boundsForDivision(IntVar x, IntVar y) {
int lx = x.getLB();
int ux = x.getUB();
int ly = y.getLB();
int uy = y.getUB();
if (ly == 0) {
ly++;
}
if (uy == 0) {
uy--;
}
if (ly < 0 && 0 < uy) {
ly = -1;
uy = 1;
}
return bound(
lx / ly,
lx / uy,
ux / ly,
ux / uy
);
}
/**
* @param x a variable
* @param y a variable
* @return computes the bounds for "x / y"
*/
public static double[] boundsForDivision(RealVar x, RealVar y) {
RealInterval res = RealUtils.odiv(x, y);
return new double[]{res.getLB(), res.getUB()};
}
/**
* @param x a variable
* @param y a variable
* @return computes the bounds for "x % y"
*/
public static int[] boundsForModulo(IntVar x, IntVar y) {
long[] vals = new long[4];
if (y.isInstantiatedTo(0)) {
vals[0] = Integer.MIN_VALUE;
vals[1] = Integer.MAX_VALUE;
vals[2] = 0;
vals[3] = 0;
} else {
int yl = y.getLB();
int yu = y.getUB();
vals[0] = 0;
vals[1] = 0;
vals[2] = 0;
if (yl >= 0) {
vals[3] = yu - 1;
} else if (yu <= 0) {
vals[3] = yl + 1;
} else {
vals[0] = Math.abs(yl) - 1;
vals[1] = Math.abs(yu) - 1;
vals[2] = -vals[0];
vals[3] = -vals[1];
}
}
return bound(vals);
}
/**
* @param x a variable
* @param y a variable (we consider that lb(y) >= 0
* @return computes the bounds for "x ^ y"
*/
public static int[] boundsForPow(IntVar x, IntVar y) {
return bound(0, 1,
MathUtils.pow(x.getLB(), y.getUB()),
MathUtils.pow(x.getUB(), y.getUB()),
MathUtils.pow(x.getLB() + 1, y.getUB()),
MathUtils.pow(x.getUB() - 1, y.getUB()),
MathUtils.pow(x.getLB(), Math.max(0, y.getUB() - 1)),
MathUtils.pow(x.getUB(), Math.max(0, y.getUB() - 1)),
MathUtils.pow(x.getLB() + 1, Math.max(0, y.getUB() - 1)),
MathUtils.pow(x.getUB() - 1, Math.max(0, y.getUB() - 1))
);
}
/**
* @param x a variable
* @param y a variable
* @return computes the bounds for "x ^ y"
*/
public static double[] boundsForPow(RealVar x, RealVar y) {
return bound(0,
Math.pow(x.getLB(), y.getLB()),
Math.pow(x.getLB(), y.getUB()),
Math.pow(x.getUB(), y.getLB()),
Math.pow(x.getUB(), y.getUB())
);
}
/**
* @param x a variable
* @param y a constant
* @return computes the bounds for "x ^ y"
*/
public static double[] boundsForPow(RealVar x, double y) {
if (y >= 0) {
return bound(0,
Math.pow(x.getLB(), y),
Math.pow(x.getUB(), y));
} else {
// bounds for 1/x^y when x < 0
double[] bounds = bound(0,
Math.pow(x.getLB(), Math.abs(y)),
Math.pow(x.getUB(), Math.abs(y)));
RealInterval boundsDiv = RealUtils.odiv(new RealIntervalConstant(1.0, 1.0), new RealIntervalConstant(bounds[0], bounds[1]));
return new double[]{boundsDiv.getLB(), boundsDiv.getUB()};
}
}
/**
* @param x a variable
* @param y a variable
* @return computes the bounds for "atan2(x , y)"
*/
public static double[] boundsForAtan2(RealVar x, RealVar y) {
return bound(
Math.atan2(x.getLB(), y.getLB()),
Math.atan2(x.getLB(), y.getUB()),
Math.atan2(x.getUB(), y.getLB()),
Math.atan2(x.getUB(), y.getUB())
);
}
/**
* @param vars array of variables
* @return computes the bounds for the minimum among vars
*/
public static int[] boundsForMinimum(IntVar... vars) {
int[] bounds = new int[]{Integer.MAX_VALUE, Integer.MAX_VALUE};
for (int i = 0; i < vars.length; i++) {
bounds[0] = Math.min(bounds[0], vars[i].getLB());
bounds[1] = Math.min(bounds[1], vars[i].getUB());
}
return bounds;
}
/**
* @param vars array of variables
* @return computes the bounds for the minimum among vars
*/
public static double[] boundsForMinimum(RealVar... vars) {
double[] bounds = new double[]{Double.POSITIVE_INFINITY, Double.POSITIVE_INFINITY};
for (int i = 0; i < vars.length; i++) {
bounds[0] = Math.min(bounds[0], vars[i].getLB());
bounds[1] = Math.min(bounds[1], vars[i].getUB());
}
return bounds;
}
/**
* @param vars array of variables
* @return computes the bounds for the maximum among vars
*/
public static int[] boundsForMaximum(IntVar... vars) {
int[] bounds = new int[]{Integer.MIN_VALUE, Integer.MIN_VALUE};
for (int i = 0; i < vars.length; i++) {
bounds[0] = Math.max(bounds[0], vars[i].getLB());
bounds[1] = Math.max(bounds[1], vars[i].getUB());
}
return bounds;
}
/**
* @param vars array of variables
* @return computes the bounds for the maximum among vars
*/
public static double[] boundsForMaximum(RealVar... vars) {
double[] bounds = new double[]{Double.NEGATIVE_INFINITY, Double.NEGATIVE_INFINITY};
for (int i = 0; i < vars.length; i++) {
bounds[0] = Math.max(bounds[0], vars[i].getLB());
bounds[1] = Math.max(bounds[1], vars[i].getUB());
}
return bounds;
}
/**
* @param vars an array of variables
* @return the variables' domain cardinality or {@link Integer#MAX_VALUE} if too large.
*/
public static long domainCardinality(IntVar... vars) {
long card = 1;
for (int i = 0; i < vars.length && card < Integer.MAX_VALUE; i++) {
card *= vars[i].getDomainSize();
}
return Math.min(Integer.MAX_VALUE, card);
}
/**
* Compute the search space size
*
* @return search space size
*/
public static double searchSpaceSize(IntVar[] vars) {
double size = 1;
for (int i = 0; i < vars.length && size > 0; i++) {
size *= vars[i].getDomainSize();
}
if (size <= 0 || size == Double.POSITIVE_INFINITY) {
size = Double.MAX_VALUE;
}
return size;
}
/**
* Compute the search space size
*
* @return search space size
*/
public static double searchSpaceSize(Iterator vars) {
double size = 1;
while (vars.hasNext() && size >= 0 && size < Double.POSITIVE_INFINITY) {
IntVar var = vars.next();
size *= var.getDomainSize();
}
if (size <= 0 || size == Double.POSITIVE_INFINITY) {
size = Double.MAX_VALUE;
}
return size;
}
/**
* @param x an int variable
* @param y another int variable
* @return true if the two domains intersect
*/
public static boolean intersect(IntVar x, IntVar y) {
int s1 = x.getDomainSize();
int s2 = y.getDomainSize();
int i = 0, j = 0;
int lbi, ubi, lbj, ubj;
lbi = x.getLB();
ubi = x.nextValueOut(lbi) - 1;
lbj = y.getLB();
ubj = y.nextValueOut(lbj) - 1;
while (i < s1 && j < s2) {
if ((lbi <= lbj && lbj <= ubi) || (lbj <= lbi && lbi <= ubj)) {
return true;
}
if (ubi <= ubj && ++i < s1) {
lbi = x.nextValue(ubi);
ubi = x.nextValueOut(lbi) - 1;
} else if (ubj <= ubi && ++j < s2) {
lbj = x.nextValue(ubj);
ubj = y.nextValueOut(lbj) - 1;
}
}
return false;
}
/**
* Create a set that stores the union of vars current domain.
*
* @param vars a list of variables
* @return the union of vars
*/
public static IntIterableRangeSet union(IntVar... vars) {
IntIterableRangeSet set = new IntIterableRangeSet();
if (vars.length == 0) {
return set;
}
for (IntVar var : vars) {
set.addAll(var);
}
return set;
}
/**
* Create a set that stores the intersection of vars current domain.
*
* @param vars a list of variables
* @return the intersection of vars
*/
public static IntIterableRangeSet intersection(IntVar... vars) {
IntIterableRangeSet set = new IntIterableRangeSet();
if (vars.length == 0) {
return set;
}
set.addAll(vars[0]);
IntIterableRangeSet set0 = new IntIterableRangeSet();
for (int i = 1; i < vars.length && set.size() > 0; i++) {
set0.clear();
set0.addAll(vars[i]);
set = IntIterableSetUtils.intersection(set0, set);
}
return set;
}
/**
* Transform an array of int to an array of fixed IntVar
*
* @param values array of ints
* @param model model to create IntVar
* @return
*/
public static IntVar[] toIntVar(Model model, int... values) {
return Arrays.stream(values).mapToObj(model::intVar).toArray(IntVar[]::new);
}
/**
* @param var a variable
* @return true if the variable is a constant, based on its type,
* false otherwise
*/
public static boolean isConstant(Variable var) {
return (var.getTypeAndKind() & Variable.CSTE) != 0;
}
/**
* @param var a variable
* @return true if the variable is a view, based on its type,
* false otherwise
*/
public static boolean isView(Variable var) {
return (var.getTypeAndKind() & Variable.VIEW) != 0;
}
/**
* @param var a variable
* @return true if the variable is an int variable, based on its kind,
* false otherwise
*/
public static boolean isInt(Variable var) {
return (var.getTypeAndKind() & Variable.INT) != 0;
}
/**
* @param var a variable
* @return true if the variable is a set variable, based on its kind,
* false otherwise
*/
public static boolean isSet(Variable var) {
return (var.getTypeAndKind() & Variable.SET) != 0;
}
/**
* @param var a variable
* @return true if the variable is a real variable, based on its kind,
* false otherwise
*/
public static boolean isReal(Variable var) {
return (var.getTypeAndKind() & Variable.REAL) != 0;
}
}