/**
* Ignores constraints which are not binary.
*/
private int countLostValues(CSP <VAR, VAL> csp, Assignment <VAR, VAL> assignment, VAR var, VAL value)
{
int result = 0;
Assignment <VAR, VAL> assign = new Assignment <VAR, VAL>();
assign.add(var, value);
foreach (IConstraint <VAR, VAL> constraint in csp.getConstraints(var))
{
if (constraint.getScope().Size() == 2)
{
VAR neighbor = csp.getNeighbor(var, constraint);
if (!assignment.contains(neighbor))
{
foreach (VAL nValue in csp.getDomain(neighbor))
{
assign.add(neighbor, nValue);
if (!constraint.isSatisfiedWith(assign))
{
++result;
}
}
}
}
}
return(result);
}
public override Assignment <VAR, VAL> solve(CSP <VAR, VAL> csp)
{
Assignment <VAR, VAL> assignment = new Assignment <VAR, VAL>();
// Select a root from the List of Variables
VAR root = _useRandom ? Util.selectRandomlyFromList(csp.getVariables()) : csp.getVariables().Get(0);
// Sort the variables in topological order
ICollection <VAR> orderedVars = CollectionFactory.CreateQueue <VAR>();
IMap <VAR, IConstraint <VAR, VAL> > parentConstraints = CollectionFactory.CreateInsertionOrderedMap <VAR, IConstraint <VAR, VAL> >();
topologicalSort(csp, root, orderedVars, parentConstraints);
if (csp.getDomain(root).isEmpty())
{
return(null); // CSP has no solution! (needed if orderedVars.size() == 1)
}
// Establish arc consistency from top to bottom (starting at the bottom).
csp = csp.copyDomains(); // do not change the original CSP!
for (int i = orderedVars.Size() - 1; i > 0; i--)
{
VAR var = orderedVars.Get(i);
IConstraint <VAR, VAL> constraint = parentConstraints.Get(var);
VAR parent = csp.getNeighbor(var, constraint);
if (makeArcConsistent(parent, var, constraint, csp))
{
fireStateChanged(csp, null, parent);
if (csp.getDomain(parent).isEmpty())
{
return(null); // CSP has no solution!
}
}
}
// Assign values to variables from top to bottom.
for (int i = 0; i < orderedVars.Size(); ++i)
{
VAR var = orderedVars.Get(i);
foreach (VAL value in csp.getDomain(var))
{
assignment.add(var, value);
if (assignment.isConsistent(csp.getConstraints(var)))
{
fireStateChanged(csp, assignment, var);
break;
}
}
}
return(assignment);
}
/**
* Computes an explicit representation of the tree structure and a total order which is consistent with the
* parent-child relations. If the provided CSP has not the required properties (CSP contains only binary
* constraints, constraint graph is tree-structured and connected), an exception is thrown.
*
* @param csp A CSP
* @param root A root variable
* @param orderedVars The computed total order (initially empty)
* @param parentConstraints The tree structure, maps a variable to the constraint representing the arc to the parent
* variable (initially empty)
*/
private void topologicalSort(CSP <VAR, VAL> csp, VAR root, ICollection <VAR> orderedVars,
IMap <VAR, IConstraint <VAR, VAL> > parentConstraints)
{
orderedVars.Add(root);
parentConstraints.Put(root, null);
int currParentIdx = -1;
while (currParentIdx < orderedVars.Size() - 1)
{
currParentIdx++;
VAR currParent = orderedVars.Get(currParentIdx);
int arcsPointingUpwards = 0;
foreach (IConstraint <VAR, VAL> constraint in csp.getConstraints(currParent))
{
VAR neighbor = csp.getNeighbor(currParent, constraint);
if (neighbor == null)
{
throw new IllegalArgumentException("Constraint " + constraint + " is not binary.");
}
if (parentConstraints.ContainsKey(neighbor))
{ // faster than orderedVars.contains(neighbor)!
arcsPointingUpwards++;
if (arcsPointingUpwards > 1)
{
throw new IllegalArgumentException("CSP is not tree-structured.");
}
}
else
{
orderedVars.Add(neighbor);
parentConstraints.Put(neighbor, constraint);
}
}
}
if (orderedVars.Size() < csp.getVariables().Size())
{
throw new IllegalArgumentException("Constraint graph is not connected.");
}
}