/// <summary>
/// Translates a domain constraint term to an N-ary DD vertex.
/// </summary>
internal override Vertex TranslateTermToVertex(TermExpr <DomainConstraint <T_Variable, T_Element> > term)
{
var range = term.Identifier.Range;
var domainVariable = term.Identifier.Variable;
var domain = domainVariable.Domain;
if (range.All(element => !domain.Contains(element)))
{
// trivially false
return(Vertex.Zero);
}
if (domain.All(element => range.Contains(element)))
{
// trivially true
return(Vertex.One);
}
// determine assignments for this constraints (if the range contains a value in the domain, '1', else '0')
Vertex[] children = domain.Select(element => range.Contains(element) ? Vertex.One : Vertex.Zero).ToArray();
// see if we know this variable
int robddVariable;
if (!_domainVariableToRobddVariableMap.TryGetValue(domainVariable, out robddVariable))
{
robddVariable = Solver.CreateVariable();
_domainVariableToRobddVariableMap[domainVariable] = robddVariable;
}
// create a new vertex with the given assignments
return(Solver.CreateLeafVertex(robddVariable, children));
}
internal override Literal <DomainConstraint <T_Variable, T_Element> > NegateLiteral(Literal <DomainConstraint <T_Variable, T_Element> > literal)
{
// negate the literal by inverting the range, rather than changing the sign
// of the literal
TermExpr <DomainConstraint <T_Variable, T_Element> > term = new TermExpr <DomainConstraint <T_Variable, T_Element> >(
literal.Term.Identifier.InvertDomainConstraint());
return(new Literal <DomainConstraint <T_Variable, T_Element> >(term, literal.IsTermPositive));
}
internal override Vertex TranslateTermToVertex(TermExpr <T_Identifier> term)
{
int variable;
if (!_variableMap.TryGetValue(term, out variable))
{
variable = Solver.CreateVariable();
_variableMap.Add(term, variable);
}
return(Solver.CreateLeafVertex(variable, Solver.BooleanVariableChildren));
}
internal override IEnumerable <LiteralVertexPair <T_Identifier> > GetSuccessors(Vertex vertex)
{
LiteralVertexPair <T_Identifier>[] successors = new LiteralVertexPair <T_Identifier> [2];
Debug.Assert(2 == vertex.Children.Length);
Vertex then = vertex.Children[0];
Vertex @else = vertex.Children[1];
// get corresponding term expression
InitializeInverseVariableMap();
TermExpr <T_Identifier> term = _inverseVariableMap[vertex.Variable];
// add positive successor (then)
Literal <T_Identifier> literal = new Literal <T_Identifier>(term, true);
successors[0] = new LiteralVertexPair <T_Identifier>(then, literal);
// add negative successor (else)
literal = literal.MakeNegated();
successors[1] = new LiteralVertexPair <T_Identifier>(@else, literal);
return(successors);
}
/// <summary> /// Given a term in BoolExpr, returns the corresponding decision diagram vertex. /// </summary> internal abstract Vertex TranslateTermToVertex(TermExpr <T_Identifier> term);
public bool Equals(TermExpr <T_Identifier> other)
{
return(_comparer.Equals(_identifier, other._identifier));
}
internal override BoolExpr <T_Identifier> VisitTerm(TermExpr <T_Identifier> expression)
{
return(expression);
}
internal abstract T_Return VisitTerm(TermExpr <T_Identifier> expression);
internal override Vertex VisitTerm(TermExpr <T_Identifier> expression)
{
return(_context.TranslateTermToVertex(expression));
}
internal override BoolExpr <T_To> VisitTerm(TermExpr <T_From> expression)
{
return(_translator(expression));
}
internal override bool VisitTerm(TermExpr <T_Identifier> expression)
{
_terms.Add(expression);
return(true);
}
internal override int VisitTerm(TermExpr <T_Identifier> expression)
{
return(1);
}
internal override BoolExpr <DomainConstraint <T_Variable, T_Element> > VisitTerm(TermExpr <DomainConstraint <T_Variable, T_Element> > expression)
{
return(new TermExpr <DomainConstraint <T_Variable, T_Element> >(expression.Identifier.InvertDomainConstraint()));
}
