net.sf.cpsolver.ifs.model
Class Constraint<V extends Variable<V,T>,T extends Value<V,T>>

java.lang.Object
  extended by net.sf.cpsolver.ifs.model.Constraint<V,T>
All Implemented Interfaces:
Comparable<Constraint<V,T>>
Direct Known Subclasses:
BinaryConstraint, ClassLimitConstraint, ExamDistributionConstraint, ExamInstructor, ExamRoom, ExamStudent, FlexibleConstraint, GlobalConstraint, GroupConstraint, IgnoreStudentConflictsConstraint, InstructorConstraint, Job, LinkedSections.LinkedSectionsConstraint, Machine, MinimizeNumberOfUsedGroupsOfTime, MinimizeNumberOfUsedRoomsConstraint, Resource, ResourceConstraint, RoomConstraint, SpreadConstraint, StudentConflict

public abstract class Constraint<V extends Variable<V,T>,T extends Value<V,T>>
extends Object
implements Comparable<Constraint<V,T>>

Generic constraint.

Like in other traditional Constraint Logic Programming (CLP) frameworks, the input problem consists of variables, values and constraints. Each constraint is defined over a subset of the problem variables and it prohibits some combinations of values which these variables can simultaneously take. In usual CSP problems, all constraints are binary (or the problem is transformed into an equivalent problem with only binary constrains before the search is started) since most of the consistency and filtering techniques are designed only for binary constraints. In such a case, the procedure computing conflicting variables is rather simple and it returns an unambiguous set of variables. It enumerates all the constraints which contain the selected variable and which are not consistent with the selected value. It returns all the variables of such constraints, different from the selected variable.

On the other hand, most of real problems have plenty of multi-variable constraints, like, for instance, resource constraint in timetabling. Such resource constraint enforces the rule that none of the variables which are using the given resource can be overlapping in time (if the resource has capacity one) or that the amount of the resource used at a time does not exceed its capacity. It is not very useful to replace such resource constraint by a set of binary constraints (e.g., prohibiting two overlapping placements in time of two particular events using the same resource), since this approach usually ends up with thousands of constraints. Also, there is usually a much more effective consistency and/or filtering technique working with the original constraint (for instance, "cumulative" constraint is usually used for modelling resource constraints in CLP).

Using multi-variable constraints, the set of conflicting variables returned by the procedure computing conflicting variables can differ according to its implementation. For instance, we can have a constraint A+B=C where A and C is already assigned to A=3 and C=5. Then if the assignment B=3 is selected, either A or B or both A and B can be unassigned to make the problem {A=3, B=3, C=5} consistent with the constraint A+B=C. Intuitively, there should be minimal number of variables unassigned in each iteration step (we are trying to increase the number of the assigned variables during the search). Also, for many constraints, it is possible to find inconsistencies even when not all variables of the constraint are yet assigned. For instance, if there are two lectures using the same room at the same time, we know that one of them needs to be unassigned even when there are unassigned lectures which will also need to be placed in that room.

In the current implementation, each hard constraint needs to implement the procedure computeConflicts(Value, Set) which returns all the already assigned values that are incompatible we the selected assignment (value which is to be assigned to its variable). This procedure is called for all constraints which contain the selected variable in an ordered manner. Furthermore, this order can be changed during the search. Moreover, the computed set of conflicting variables is passed to this computeConflicts(Value, Set) procedure as a parameter, so the constraint can "see" what variables are already selected for unassignment by previously processed constraints. This way, we are not computing the very minimal set of conflicting variables, however, we allow for computing this set in an efficient way. It can be also tuned for a particular problem by changing the order of constraints.

Also note that each constraint can keep its notion about the assigned variables. For instance, the resource constraint of a particular room can memorize a look-up table stating what lecture is assigned in what time slot(s), so for the computation of the conflicting lectures it only looks through the appropriate fields of this table. The implementation is based on assigned(long,Value) and unassigned(long,Value) methods that are responsible to keeping the problem consistent with the constraint. Also note that this default consistency technique is defined on a problem level and it can be changed by a more dedicated one, implemented for a particular problem.

Version:
IFS 1.2 (Iterative Forward Search)
Copyright (C) 2006 - 2010 Tomas Muller
muller@unitime.org
http://muller.unitime.org

This library is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 3 of the License, or (at your option) any later version.

This library is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details.

You should have received a copy of the GNU Lesser General Public License along with this library; if not see http://www.gnu.org/licenses/.
See Also:
Variable, Model, Solver

Field Summary
protected  Collection<V> iAssignedVariables
           
protected  List<ConstraintListener<T>> iConstraintListeners
           
protected  long iId
           
 
Constructor Summary
Constraint()
          Constructor
 
Method Summary
 void addConstraintListener(ConstraintListener<T> listener)
          Adds a constraint listener
 void addVariable(V variable)
          Add a variable to this constraint
 void assigned(long iteration, T value)
          Given value is to be assigned to its varable.
 Collection<V> assignedVariables()
          The list of variables of this constraint that are assigned
 int compareTo(Constraint<V,T> c)
           
abstract  void computeConflicts(T value, Set<T> conflicts)
          The only method which has to be implemented by any constraint.
 List<ConstraintListener<T>> constraintListeners()
          Returns the list of registered constraint listeners
 int countAssignedVariables()
          The number of variables of this constraint that are assigned
 int countVariables()
          The number of variables of this constraint
 boolean equals(Object o)
          Compare two constraints for equality (getId() is used)
 String getDescription()
          Constraint's description -- for printing purposes
 long getId()
          Unique id
 Model<V,T> getModel()
          The model which the constraint belongs to
 String getName()
          Constraint's name -- for printing purposes
 int hashCode()
           
 boolean inConflict(T value)
          Returns true if the given assignment is inconsistent with the existing assignments respecting this constraint.
 boolean isConsistent(T value1, T value2)
          Returns true if the given assignments are consistent respecting this constraint.
 boolean isHard()
          Returns true if the constraint is hard.
 void removeConstraintListener(ConstraintListener<T> listener)
          Removes a constraint listener
 void removeVariable(V variable)
          Remove a variable from this constraint
 void setModel(Model<V,T> model)
          Sets the model which the constraint belongs to
 void unassigned(long iteration, T value)
          Given value is unassigned from its variable.
 List<V> variables()
          The list of variables of this constraint
 
Methods inherited from class java.lang.Object
clone, finalize, getClass, notify, notifyAll, toString, wait, wait, wait
 

Field Detail

iId

protected long iId

iAssignedVariables

protected Collection<V extends Variable<V,T>> iAssignedVariables

iConstraintListeners

protected List<ConstraintListener<T extends Value<V,T>>> iConstraintListeners
Constructor Detail

Constraint

public Constraint()
Constructor

Method Detail

getModel

public Model<V,T> getModel()
The model which the constraint belongs to


setModel

public void setModel(Model<V,T> model)
Sets the model which the constraint belongs to


variables

public List<V> variables()
The list of variables of this constraint


assignedVariables

public Collection<V> assignedVariables()
The list of variables of this constraint that are assigned


countVariables

public int countVariables()
The number of variables of this constraint


countAssignedVariables

public int countAssignedVariables()
The number of variables of this constraint that are assigned


addVariable

public void addVariable(V variable)
Add a variable to this constraint


removeVariable

public void removeVariable(V variable)
Remove a variable from this constraint


computeConflicts

public abstract void computeConflicts(T value,
                                      Set<T> conflicts)
The only method which has to be implemented by any constraint. It returns the values which needs to be unassigned in order to make this constraint consistent with the given value if it is assigned to its variable. The computed list of conflicting values is added to the given set of conflicts.

Parameters:
value - value to be assigned to its varaible
conflicts - resultant set of conflicting values

isConsistent

public boolean isConsistent(T value1,
                            T value2)
Returns true if the given assignments are consistent respecting this constraint. This method is used by MAC (see MacPropagation).


inConflict

public boolean inConflict(T value)
Returns true if the given assignment is inconsistent with the existing assignments respecting this constraint. This method is used by MAC (see MacPropagation).


assigned

public void assigned(long iteration,
                     T value)
Given value is to be assigned to its varable. In this method, the constraint should unassigns all varaibles which are in conflict with the given assignment because of this constraint.


unassigned

public void unassigned(long iteration,
                       T value)
Given value is unassigned from its variable.


addConstraintListener

public void addConstraintListener(ConstraintListener<T> listener)
Adds a constraint listener


removeConstraintListener

public void removeConstraintListener(ConstraintListener<T> listener)
Removes a constraint listener


constraintListeners

public List<ConstraintListener<T>> constraintListeners()
Returns the list of registered constraint listeners


getId

public long getId()
Unique id


getName

public String getName()
Constraint's name -- for printing purposes


getDescription

public String getDescription()
Constraint's description -- for printing purposes


hashCode

public int hashCode()
Overrides:
hashCode in class Object

isHard

public boolean isHard()
Returns true if the constraint is hard. Only hard constraints are allowed to unassign a variable when there is a conflict with a value that is being assigned


equals

public boolean equals(Object o)
Compare two constraints for equality (getId() is used)

Overrides:
equals in class Object

compareTo

public int compareTo(Constraint<V,T> c)
Specified by:
compareTo in interface Comparable<Constraint<V extends Variable<V,T>,T extends Value<V,T>>>


Copyright © 2014 UniTime LLC. All Rights Reserved.