/// <summary>
/// Returns the possible ways that a query term can unify with a program term
/// </summary>
public static IBindings Unify(this ILiteral query, ILiteral program, IBindings bindings = null)
{
var simpleUnifier = new SimpleUnifier();
var freeVariables = new HashSet<ILiteral>();
// Run the unifier
var queryFreeVars = simpleUnifier.QueryUnifier.Compile(query, bindings);
if (queryFreeVars == null) return null;
simpleUnifier.PrepareToRunProgram();
var programFreeVars = simpleUnifier.ProgramUnifier.Compile(program, bindings);
if (programFreeVars == null) return null;
freeVariables.UnionWith(queryFreeVars);
// Retrieve the unified value for the program
var result = simpleUnifier.UnifiedValue(query.UnificationKey ?? query);
// If the result was valid, return as the one value from this function
if (result != null)
{
var variableBindings = freeVariables.ToDictionary(variable => variable,
variable => simpleUnifier.UnifiedValue(variable));
return new BasicBinding(result, variableBindings);
}
else
{
return null;
}
}
/// <summary>
/// Compiles a literal for unification using a query unifier
/// </summary>
/// <returns>
/// The list of variables in the literal
/// </returns>
public static IEnumerable<ILiteral> Compile(this IQueryUnifier unifier, ILiteral literal, IBindings bindings = null)
{
if (unifier == null) throw new ArgumentNullException("unifier");
if (literal == null) throw new ArgumentNullException("literal");
// Flatten the literal
var assignments = literal.Flatten().ToList();
// Bind the variables in order
var freeVariables = unifier.Bind(assignments);
// Rebind the assignments if necessary
if (bindings != null)
{
assignments = assignments.BindVariables(bindings).ToList();
}
// Compile the result
if (!unifier.Compile(assignments))
{
return null;
}
return freeVariables;
}
public bool GetStructure(ILiteral termName, int termLength, ILiteral variable)
{
var variableIndex = _bindingForVariable[variable];
_usedVariables.Add(variableIndex);
_program.Write(Operation.GetStructure, termName, variableIndex, termLength);
return true;
}
/// <summary>
/// Adds a positive literal to a negative Horn clause
/// </summary>
public static IClause Then(this IClause negativeHornClause, ILiteral then)
{
if (negativeHornClause == null) throw new ArgumentNullException("negativeHornClause");
if (negativeHornClause.Implies != null) throw new ArgumentException("Clause already has an implication", "negativeHornClause");
if (then == null) throw new ArgumentNullException("then");
return new PositiveClause(negativeHornClause, then);
}
public void BindVariable(int index, ILiteral variableName)
{
while (_variables.Count <= index)
{
_variables.Add(new SimpleReference());
}
_addressForName[variableName] = _variables[index];
_indexForVariable[variableName] = index;
}
public bool GetValue(ILiteral variable1, ILiteral variable2)
{
var variableIndex1 = _bindingForVariable[variable1];
var variableIndex2 = _bindingForVariable[variable2];
_usedVariables.Add(variableIndex1);
_usedVariables.Add(variableIndex2);
_program.Write(Operation.GetValue, variableIndex1, variableIndex2);
return true;
}
public ILiteral GetValueForVariable(ILiteral variable)
{
ILiteral result;
if (_valueForVariable.TryGetValue(variable, out result))
{
return result;
}
else
{
return null;
}
}
/// <summary>
/// Returns the mapped version of a particular variable
/// </summary>
public ILiteral MapVariable(ILiteral variable)
{
ILiteral result;
if (_variableMapping.TryGetValue(variable, out result))
{
return result;
}
else
{
return variable;
}
}
/// <summary>
/// Retrieves an object representing the assignments for a particular literal when used as a predicate
/// </summary>
public static PredicateAssignmentList FromPredicate(ILiteral predicate)
{
var result = new PredicateAssignmentList();
if (predicate.UnificationKey != null)
{
foreach (var argument in predicate.Dependencies)
{
result.AddArgument(argument);
}
}
return result;
}
/// <summary>
/// Queries a solver for a goal
/// </summary>
public static IQueryResult Query(this ISolver solver, ILiteral goal)
{
// Result is false for something without a key
if (goal.UnificationKey == null)
{
return new BasicQueryResult(false, new EmptyBinding(null));
}
// Compile the query
var unifier = new SimpleUnifier();
var assignments = new PredicateAssignmentList();
// Assume we have a basic predicate
foreach (var arg in goal.Dependencies)
{
assignments.AddArgument(arg);
}
// Run through the unifier
var freeVariableNames = unifier.QueryUnifier.Bind(assignments.Assignments);
var freeVariables = freeVariableNames.Select(variable => unifier.GetVariableLocation(variable).Dereference());
unifier.QueryUnifier.Compile(assignments.Assignments);
// Call via the solver
var moveNext = solver.Call(goal.UnificationKey, unifier.GetArgumentVariables(assignments.CountArguments()));
Func<IQueryResult> nextResult = () =>
{
// Update the variables to the next result
var succeeded = moveNext();
// Nothing to do if we didn't succeed
if (!succeeded)
{
return new BasicQueryResult(false, new EmptyBinding(null));
}
// Bind the variables
var variableValues = freeVariables
.Select(varRef => varRef.Freeze())
.Zip(freeVariableNames, (value, name) => new { Value = value, Name = name }).ToArray();
var binding = new BasicBinding(null, variableValues.ToDictionary(val => val.Name, val => val.Value));
// Return the result
return new BasicQueryResult(true, binding);
};
// Chain to produce the final result
return new ChainedResult(nextResult(), () => Task.FromResult(nextResult()));
}
public ByteCodeExecutor(ByteCodePoint[] program, ILiteral[] literals, int maxVariableIndex)
{
if (program == null) throw new ArgumentNullException(nameof(program));
_program = program;
_literals = literals;
_programCounter = 0;
_environment = new ByteCodeEnvironment(0, 0, null);
_registers = new SimpleReference[maxVariableIndex];
for (var registerIndex = 0; registerIndex<_registers.Length; ++registerIndex)
{
_registers[registerIndex] = new SimpleReference();
}
}
/// <summary>
/// Binds the variables in the unifier for a set of assignments
/// </summary>
/// <returns>
/// The list of free variables in the assignments
/// </returns>
public static IEnumerable<ILiteral> Bind(this IBaseUnifier unifier, IEnumerable<IAssignmentLiteral> assignments, IEnumerable<ILiteral> permanentVariables = null)
{
if (unifier == null) throw new ArgumentNullException("unifier");
if (assignments == null) throw new ArgumentNullException("assignments");
if (permanentVariables == null) permanentVariables = new ILiteral[0];
var indexForPermanent = new Dictionary<ILiteral, int>();
var freeVariables = new List<ILiteral>();
var index = 0;
// Assign permanent variables to indexes starting from 0
// TODO: what if a permanent variable appears in an argument location?
foreach (var permVariable in permanentVariables)
{
indexForPermanent[permVariable] = index;
++index;
}
// Bind the assignments
foreach (var assign in assignments)
{
int variableIndex;
// If the assignment is of the form X1 = Y where Y is a permanent variable, use the permanent variable index
if (!indexForPermanent.TryGetValue(assign.Value, out variableIndex))
{
// For other assignments, use an increasing index
variableIndex = index;
++index;
}
if (assign.Value.UnificationKey == null)
{
// Values without a unification key are free variables (they can have any value)
freeVariables.Add(assign.Value);
unifier.BindVariable(variableIndex, assign.Value);
unifier.BindVariable(variableIndex, assign.Variable);
}
else
{
// Values with a unification key are not free
unifier.BindVariable(variableIndex, assign.Value.UnificationKey);
unifier.BindVariable(variableIndex, assign.Variable);
}
}
return freeVariables;
}
public void TestSafraExampleInPaper()
{
var ba = new BuchiAutomaton<AutomatonNode> (new AutomatonNodeFactory ());
var q = ba.AddNode ("qI");
var f = ba.AddNode ("f");
var g = ba.AddNode ("g");
var pa = new Proposition ("a");
var pb = new Proposition ("b");
var pc = new Proposition ("c");
var a = new ILiteral[] { pa };
var b = new ILiteral[] { pb };
var c = new ILiteral [] { pc };
// a,b from qI to qI
ba.AddTransition (q, q, a);
ba.AddTransition (q, q, b);
// c from f to f
ba.AddTransition (f, f, c);
// a from qI to f
ba.AddTransition (q, f, a);
// a from f to g
ba.AddTransition (f, g, a);
// a from g to g
ba.AddTransition (g, g, a);
// a from g to f
ba.AddTransition (g, f, a);
ba.SetInitialNode (q);
ba.SetAcceptanceCondition (new BuchiAcceptance<AutomatonNode> (new [] { f, g }));
var rabin = ba.Determinize ();
//var folder = new Fold<RabinAutomaton<AutomatonNode>, AutomatonNode> ();
//rabin = folder.Transform (rabin);
rabin.UnfoldTransitions ();
Console.WriteLine (rabin.ToDot ());
}
public Func<bool> Call(ILiteral predicate, params IReferenceLiteral[] arguments)
{
// Assume that predicate is correct
// Load the arguments into a simple unifier
var unifier = new SimpleUnifier();
unifier.LoadArguments(arguments);
// Unify using the predicate
unifier.ProgramUnifier.Bind(_clauseAssignments[0].Assignments);
if (!unifier.ProgramUnifier.Compile(_clauseAssignments[0].Assignments))
{
// Fail if we can't unify
return () => false;
}
// Call using the clauses
return SolveAllSubclauses(_clauseAssignments.Skip(1), unifier);
}
public Func<bool> Call(ILiteral predicate, params IReferenceLiteral[] arguments)
{
List<ISolver> solvers;
// Result is nothing if there are no solvers that match this key
if (!_solverForUnificationKey.TryGetValue(predicate, out solvers))
{
return () => false;
}
// Call each solver in turn
IEnumerator<ISolver> currentSolver = solvers.GetEnumerator();
Func<bool> currentResult = () => false;
return () =>
{
for (;;)
{
// Result is true if the current solver is still returning results
if (currentResult())
{
return true;
}
// Get the next result
if (!currentSolver.MoveNext())
{
// No more solvers to try
return false;
}
// Call the next solver
// TODO: one slight problem here is we expect the solver to backtrack the argument values before returning false
// (which is a performance loss for the very last solver)
currentResult = currentSolver.Current.Call(predicate, arguments);
}
};
}
public Task<IEnumerable<IClause>> CandidatesForLiteral(ILiteral literal)
{
if (literal == null) throw new ArgumentNullException("literal");
// Index by unification key
FillClauseCache();
// Result is all clauses if there is no unification key
if (literal.UnificationKey == null)
{
return Task.FromResult(Clauses);
}
// Result is the clauses for this value's unification key
IClause[] result;
if (!_unificationCandidates.TryGetValue(literal.UnificationKey, out result))
{
result = new IClause[0];
}
return Task.FromResult<IEnumerable<IClause>>(result);
}
public ILiteral GetValueForVariable(ILiteral variable)
{
return null;
}
public bool GetValue(ILiteral variable1, ILiteral variable2)
{
Unify(_addressForName[variable1], _addressForName[variable2]);
return(true);
}
public bool UnifyValue(ILiteral variable)
{
if (!_writeMode)
{
if (!Unify(_addressForName[variable], _structurePtr))
{
return false;
}
}
else
{
_lastArgument.SetTo(_addressForName[variable]);
_lastArgument = _lastArgument.NextArgument;
}
_structurePtr = _structurePtr.NextArgument;
return true;
}
/// <summary>
/// Write out given data as a Literal.
/// <param name="b">Literal representing data to write out</param>
/// </summary>
/// <returns>this</returns>
public Argument WriteBytes(ILiteral b)
{
items.Add(b);
return(this);
}
public IPropertyAssignment MakePropertyAssignment(ILiteral name, IExpression expression)
{
// TODO: Is calling ToString() adequate here?
return(new PropertyAssignment(((Literal)name).ToString(), (Expression)expression));
}
public BasicBinding(ILiteral result, Dictionary <ILiteral, ILiteral> valueForVariable)
{
_result = result;
_valueForVariable = valueForVariable;
}
public virtual void Visit(ILiteral instance)
{
}
public static bool TryGetLiteral(object value, out ILiteral literal)
{
literal = null;
if (value is bool b)
{
literal = new BooleanLiteral(b);
}
else if (value is byte by)
{
literal = new IntegerLiteral(by);
}
else if (value is sbyte sb)
{
literal = new IntegerLiteral(sb);
}
else if (value is short sh)
{
literal = new IntegerLiteral(sh);
}
else if (value is ushort us)
{
literal = new IntegerLiteral(us);
}
else if (value is int i)
{
literal = new IntegerLiteral(i);
}
else if (value is uint ui)
{
literal = new IntegerLiteral(ui);
}
else if (value is long l)
{
literal = new IntegerLiteral(l);
}
else if (value is ulong ul)
{
literal = new IntegerLiteral((long)ul);
}
else if (value is float f)
{
literal = new FloatLiteral(f);
}
else if (value is double d)
{
literal = new FloatLiteral(d);
}
else if (value is DateTime dt)
{
literal = new DateTimeLiteral(dt);
}
else if (value is Guid g)
{
literal = new StringLiteral(g.ToArasId());
}
else if (value is string str)
{
literal = new StringLiteral(str);
}
else
{
return(false);
}
return(true);
}
/// <summary>
/// Creates a new observable property access proxy
/// </summary>
/// <param name="modelElement">The model instance element for which to create the property access proxy</param>
public ValueProxy(ILiteral modelElement) :
base(modelElement, "Value")
{
}
public ILiteral UnifiedValue(ILiteral name)
{
return(_addressForName[name].Freeze());
}
protected virtual ILiteral VisitLiteral(ILiteral node)
{
return(node);
}
static void Main()
{
// Create the CP-SAT model.
CpModel model = new CpModel();
// Declare our primary variable.
IntVar x = model.NewIntVar(0, 20, "x");
// Create the expression variable and implement the step function
// Note it is not defined for var == 2.
//
// - 3
// -- -- --------- 2
// 1
// -- --- 0
// 0 ================ 20
//
IntVar expr = model.NewIntVar(0, 3, "expr");
// expr == 0 on [5, 6] U [8, 10]
ILiteral b0 = model.NewBoolVar("b0");
model.AddLinearConstraintWithBounds(
new IntVar[] { x },
new long[] { 1 },
new long[] { 5, 6, 8, 10 }).OnlyEnforceIf(b0);
model.Add(expr == 0).OnlyEnforceIf(b0);
// expr == 2 on [0, 1] U [3, 4] U [11, 20]
ILiteral b2 = model.NewBoolVar("b2");
model.AddLinearConstraintWithBounds(
new IntVar[] { x },
new long[] { 1 },
new long[] { 0, 1, 3, 4, 11, 20 }).OnlyEnforceIf(b2);
model.Add(expr == 2).OnlyEnforceIf(b2);
// expr == 3 when x == 7
ILiteral b3 = model.NewBoolVar("b3");
model.Add(x == 7).OnlyEnforceIf(b3);
model.Add(expr == 3).OnlyEnforceIf(b3);
// At least one bi is true. (we could use a sum == 1).
model.AddBoolOr(new ILiteral[] { b0, b2, b3 });
// Search for x values in increasing order.
model.AddDecisionStrategy(
new IntVar[] { x },
DecisionStrategyProto.Types.VariableSelectionStrategy.ChooseFirst,
DecisionStrategyProto.Types.DomainReductionStrategy.SelectMinValue);
// Create the solver.
CpSolver solver = new CpSolver();
// Force solver to follow the decision strategy exactly.
solver.StringParameters = "search_branching:FIXED_SEARCH";
VarArraySolutionPrinter cb =
new VarArraySolutionPrinter(new IntVar[] { x, expr });
solver.SearchAllSolutions(model, cb);
}
public IPropertyAssignment MakePropertySetAssignment(Scope scope, ILiteral name, IIdentifier paramName, IStatement body, Scope innerScope)
{
// TODO: Is calling ToString() adequate here?
// TODO: Implement properly. This is just a quick hack to get things semi-working.
var paramList = MakeIdentifierList();
paramList.Add(paramName);
var setterName = MakeIdentifier(innerScope, name.ToString(), ((Node)name).SourceOffset);
var setter = MakeFunctionExpression(scope, setterName, paramList, body, innerScope);
return new PropertyAssignment(name.ToString(), setter, null);
}
public Clause(ILiteral head) : this()
{
Head = head;
}
public Func<bool> Call(ILiteral predicate, params IReferenceLiteral[] arguments)
{
return () => false;
}
public void OnlyEnforceIf(ILiteral lit)
{
constraint_.EnforcementLiteral.Add(lit.GetIndex());
}
public bool HasVariable(ILiteral name)
{
return(_usedVariables.Contains(_indexForVariable[name]));
}
public IntervalVar NewOptionalIntervalVar <S, D, E>(S start, D duration, E end, ILiteral is_present, string name)
{
int i = is_present.GetIndex();
return(new IntervalVar(model_, GetOrCreateIndex(start), GetOrCreateIndex(duration), GetOrCreateIndex(end),
i, name));
}
/// <summary>
/// Returns a clause indicating that a literal is unconditionally true
/// </summary>
public static IClause Always(ILiteral always)
{
return(If().Then(always));
}
static void Main()
{
CpModel model = new CpModel();
IntVar x = model.NewBoolVar("x");
ILiteral not_x = x.Not();
}
public bool Equals(ILiteral other)
{
return(Equals(other as TermAssignment));
}
public IntervalVar NewOptionalIntervalVar <S, D, E>(S start, D duration, E end, ILiteral is_present, string name)
{
LinearExpr startExpr = GetLinearExpr(start);
LinearExpr durationExpr = GetLinearExpr(duration);
LinearExpr endExpr = GetLinearExpr(end);
Add(startExpr + durationExpr == endExpr).OnlyEnforceIf(is_present);
LinearExpressionProto startProto = GetLinearExpressionProto(startExpr);
LinearExpressionProto durationProto = GetLinearExpressionProto(durationExpr);
LinearExpressionProto endProto = GetLinearExpressionProto(endExpr);
return(new IntervalVar(model_, startProto, durationProto, endProto, is_present.GetIndex(), name));
}
/// <exception cref="IOException"></exception>
/// <exception cref="ProtocolException"></exception>
private void literal(ILiteral b, Protocol p)
{
b.WriteTo(startLiteral(p, b.Size));
}
public IntervalVar NewOptionalFixedSizeIntervalVar <S>(S start, long duration, ILiteral is_present, string name)
{
LinearExpr startExpr = GetLinearExpr(start);
LinearExpr durationExpr = GetLinearExpr(duration);
LinearExpr endExpr = LinearExpr.Sum(new LinearExpr[] { startExpr, durationExpr });
LinearExpressionProto startProto = GetLinearExpressionProto(startExpr);
LinearExpressionProto durationProto = GetLinearExpressionProto(durationExpr);
LinearExpressionProto endProto = GetLinearExpressionProto(endExpr);
return(new IntervalVar(model_, startProto, durationProto, endProto, is_present.GetIndex(), name));
}
public bool UnifyVariable(ILiteral variable)
{
// This variable becomes used
_usedVariables.Add(_indexForVariable[variable]);
if (!_writeMode)
{
// Just read the value of the variable
_addressForName[variable].SetTo(_structurePtr);
}
else
{
// Write the value of the variable
_addressForName[variable].SetTo(_lastArgument);
_lastArgument = _lastArgument.NextArgument;
}
_structurePtr = _structurePtr.NextArgument;
return true;
}
public void AddAssumption(ILiteral lit)
{
model_.Assumptions.Add(lit.GetIndex());
}
public EmptyBinding(ILiteral result)
{
Result = result;
}
/// <summary>
/// Constructs an instance.
/// </summary>
/// <param name="arrayLit">literal describing the referenced array</param>
/// <param name="array">array instance</param>
public FixedArrayRef(ILiteral arrayLit, Array array)
{
ArrayLit = arrayLit;
ArrayObj = array;
}
public IPropertyAssignment MakePropertyAssignment(ILiteral name, IExpression expression)
{
// TODO: Is calling ToString() adequate here?
return new PropertyAssignment(((Literal)name).ToString(), (Expression)expression);
}
/// <summary>
/// Adds a new argument to this object
/// </summary>
public void AddArgument(ILiteral argument)
{
// Get the assignments for this argument
var assignments = argument.Flatten().ToArray();
// The first assignment defines the argument value, and the rest are just other variables
var rootAssignment = assignments[0];
var variableAssignments = assignments.Skip(1);
// If the root assignment is a variable, use a variable argument assignment instead
if (rootAssignment.Value.UnificationKey == null)
{
var variableRoot = rootAssignment;
variableAssignments = variableAssignments.Concat(new[] { variableRoot });
rootAssignment = new ArgumentAssignment(new Variable(), variableRoot.Variable);
}
// Store the list of other assignments
_arguments.Add(rootAssignment);
_otherAssignments.AddRange(variableAssignments);
}
public object EvalLiteral(ILiteral lit)
{
throw new NotImplementedException();
}
public bool UnifyVariable(ILiteral variable)
{
var variableIndex = _bindingForVariable[variable];
_usedVariables.Add(variableIndex);
_program.Write(Operation.UnifyVariable, variableIndex);
return true;
}
/// <summary>
/// Constructs an instance.
/// </summary>
/// <param name="arrayLit">literal describing the referenced array</param>
/// <param name="array">array instance</param>
/// <param name="indices">constant indices</param>
public FixedArrayRef(ILiteral arrayLit, Array array, long[] indices)
{
ArrayLit = arrayLit;
ArrayObj = array;
Indices = indices;
}
static LiteralConversion FromLiteral(byte[] dest, ILiteral literal)
{
return(literal is INumberLiteral numberLiteral?FromNumberLiteral(dest, numberLiteral) : LiteralConversion.Failed);
}
public bool PutValue(ILiteral variable1, ILiteral variable2)
{
_addressForName[variable2].SetTo(_addressForName[variable1]);
return(true);
}
public IntVar NewOptionalEnumeratedIntVar(
IEnumerable <long> bounds, ILiteral is_present, string name)
{
return(new IntVar(model_, bounds, is_present.GetIndex(), name));
}
public bool HasVariable(ILiteral variable)
{
var variableIndex = _bindingForVariable[variable];
return _usedVariables.Contains(variableIndex);
}
public IntVar NewOptionalConstant(
long value, ILiteral is_present, string name)
{
long[] bounds = { value, value };
return(new IntVar(model_, bounds, is_present.GetIndex(), name));
}
public void BindVariable(int index, ILiteral variable)
{
_bindingForVariable[variable] = index;
}
static void RankTasks(CpModel model, IntVar[] starts, ILiteral[] presences, IntVar[] ranks)
{
int num_tasks = starts.Length;
// Creates precedence variables between pairs of intervals.
ILiteral[,] precedences = new ILiteral[num_tasks, num_tasks];
for (int i = 0; i < num_tasks; ++i)
{
for (int j = 0; j < num_tasks; ++j)
{
if (i == j)
{
precedences[i, i] = presences[i];
}
else
{
IntVar prec = model.NewBoolVar(String.Format("{0} before {1}", i, j));
precedences[i, j] = prec;
model.Add(starts[i] < starts[j]).OnlyEnforceIf(prec);
}
}
}
// Treats optional intervals.
for (int i = 0; i < num_tasks - 1; ++i)
{
for (int j = i + 1; j < num_tasks; ++j)
{
List <ILiteral> tmp_array = new List <ILiteral>();
tmp_array.Add(precedences[i, j]);
tmp_array.Add(precedences[j, i]);
tmp_array.Add(presences[i].Not());
// Makes sure that if i is not performed, all precedences are false.
model.AddImplication(presences[i].Not(), precedences[i, j].Not());
model.AddImplication(presences[i].Not(), precedences[j, i].Not());
tmp_array.Add(presences[j].Not());
// Makes sure that if j is not performed, all precedences are false.
model.AddImplication(presences[j].Not(), precedences[i, j].Not());
model.AddImplication(presences[j].Not(), precedences[j, i].Not());
// The following bool_or will enforce that for any two intervals:
// i precedes j or j precedes i or at least one interval is not
// performed.
model.AddBoolOr(tmp_array);
// Redundant constraint: it propagates early that at most one precedence
// is true.
model.AddImplication(precedences[i, j], precedences[j, i].Not());
model.AddImplication(precedences[j, i], precedences[i, j].Not());
}
}
// Links precedences and ranks.
for (int i = 0; i < num_tasks; ++i)
{
IntVar[] tmp_array = new IntVar[num_tasks];
for (int j = 0; j < num_tasks; ++j)
{
tmp_array[j] = (IntVar)precedences[j, i];
}
model.Add(ranks[i] == LinearExpr.Sum(tmp_array) - 1);
}
}
static void Main()
{
CpModel model = new CpModel();
// Three weeks.
int horizon = 100;
int num_tasks = 4;
IntVar[] starts = new IntVar[num_tasks];
IntVar[] ends = new IntVar[num_tasks];
IntervalVar[] intervals = new IntervalVar[num_tasks];
ILiteral[] presences = new ILiteral[num_tasks];
IntVar[] ranks = new IntVar[num_tasks];
IntVar true_var = model.NewConstant(1);
// Creates intervals, half of them are optional.
for (int t = 0; t < num_tasks; ++t)
{
starts[t] = model.NewIntVar(0, horizon, String.Format("start_{0}", t));
int duration = t + 1;
ends[t] = model.NewIntVar(0, horizon, String.Format("end_{0}", t));
if (t < num_tasks / 2)
{
intervals[t] = model.NewIntervalVar(starts[t], duration, ends[t], String.Format("interval_{0}", t));
presences[t] = true_var;
}
else
{
presences[t] = model.NewBoolVar(String.Format("presence_{0}", t));
intervals[t] = model.NewOptionalIntervalVar(starts[t], duration, ends[t], presences[t],
String.Format("o_interval_{0}", t));
}
// Ranks = -1 if and only if the tasks is not performed.
ranks[t] = model.NewIntVar(-1, num_tasks - 1, String.Format("rank_{0}", t));
}
// Adds NoOverlap constraint.
model.AddNoOverlap(intervals);
// Adds ranking constraint.
RankTasks(model, starts, presences, ranks);
// Adds a constraint on ranks.
model.Add(ranks[0] < ranks[1]);
// Creates makespan variable.
IntVar makespan = model.NewIntVar(0, horizon, "makespan");
for (int t = 0; t < num_tasks; ++t)
{
model.Add(ends[t] <= makespan).OnlyEnforceIf(presences[t]);
}
// Minimizes makespan - fixed gain per tasks performed.
// As the fixed cost is less that the duration of the last interval,
// the solver will not perform the last interval.
IntVar[] presences_as_int_vars = new IntVar[num_tasks];
for (int t = 0; t < num_tasks; ++t)
{
presences_as_int_vars[t] = (IntVar)presences[t];
}
model.Minimize(2 * makespan - 7 * LinearExpr.Sum(presences_as_int_vars));
// Creates a solver and solves the model.
CpSolver solver = new CpSolver();
CpSolverStatus status = solver.Solve(model);
if (status == CpSolverStatus.Optimal)
{
Console.WriteLine(String.Format("Optimal cost: {0}", solver.ObjectiveValue));
Console.WriteLine(String.Format("Makespan: {0}", solver.Value(makespan)));
for (int t = 0; t < num_tasks; ++t)
{
if (solver.BooleanValue(presences[t]))
{
Console.WriteLine(String.Format("Task {0} starts at {1} with rank {2}", t, solver.Value(starts[t]),
solver.Value(ranks[t])));
}
else
{
Console.WriteLine(
String.Format("Task {0} in not performed and ranked at {1}", t, solver.Value(ranks[t])));
}
}
}
else
{
Console.WriteLine(String.Format("Solver exited with nonoptimal status: {0}", status));
}
}
public Container(string parsedString, ILiteral value, PositionInText position)
: base(position)
{
this.Value = value;
this.parsedString = parsedString;
}
public IntVar NewOptionalIntVar(
long lb, long ub, ILiteral is_present, string name)
{
long[] bounds = { lb, ub };
return(new IntVar(model_, bounds, is_present.GetIndex(), name));
}
/// <summary>
/// Retrieves the storage location for the specified variable
/// </summary>
public IReferenceLiteral GetVariableLocation(ILiteral name)
{
return(_addressForName[name]);
}
