def visit_TheoryAtom(self, atom): """ Rewrites theory atoms related to parity constraints. """ if atom.term.type == _ast.ASTType.Function and len( atom.term.arguments) == 0: if atom.term.name in ["odd", "even"]: self.__remove = True i = _ast.Symbol(atom.location, _clingo.Number(self.__id)) ct = _ast.Symbol(atom.location, _clingo.Function(atom.term.name)) head = _ast.SymbolicAtom( _ast.Function(atom.location, g_aux_name, [i, ct], False)) head = _ast.Literal(atom.location, _ast.Sign.NoSign, head) self.__add(_ast.Rule(atom.location, head, [])) for element in atom.elements: head = _ast.Function( atom.location, "", [theory_term_to_term(t) for t in element.tuple], False) head = _ast.SymbolicAtom( _ast.Function(atom.location, g_aux_name, [i, ct, head], False)) head = _ast.Literal(atom.location, _ast.Sign.NoSign, head) body = element.condition self.__add(_ast.Rule(atom.location, head, body)) self.__id += 1 return atom
def transform(self, atom): loc = atom.location false = self.__false_atom(loc) atom, ranges = transform_theory_atom(atom) variables = get_variables(atom) param = time_parameter(loc) shift = _ast.Variable(loc, g_tel_shift_variable) aux = self.__aux_atom(loc, variables + [param]) saux = self.__aux_atom(loc, variables + [shift], inc=0) rules = [] if self.__false_external is None: rules.append(_tf.External(loc, false.atom, [])) rules.append(_ast.Rule(loc, atom, [aux])) if ranges: elems = [] for (lhs, rhs), heads in ranges: cond = [] diff = _ast.BinaryOperation(loc, _ast.BinaryOperator.Minus, param, shift) if lhs.ast_type != _ast.ASTType.SymbolicTerm or lhs.symbol.type != _clingo.SymbolType.Number or lhs.symbol.number > 0: cond.append(_ast.Literal(loc, _ast.Sign.NoSign, _ast.Comparison(_ast.ComparisonOperator.LessEqual, lhs, diff))) if rhs.ast_type != _ast.ASTType.SymbolicTerm or rhs.symbol.type != _clingo.SymbolType.Supremum: cond.append(_ast.Literal(loc, _ast.Sign.NoSign, _ast.Comparison(_ast.ComparisonOperator.LessEqual, diff, rhs))) elems.extend([_ast.ConditionalLiteral(loc, _ast.Literal(loc, _ast.Sign.NoSign, head), cond) for head in heads]) rules.append(_ast.Rule(loc, _ast.Disjunction(loc, elems), [saux, false])) return aux, rules
def visit_Rule(self, rule): """ Sets the state flags when visiting a rule. After that the head and body of the rule are visited in the right context. """ try: self.__head = True self.__max_shift = [0] self.__constraint = _tf.is_constraint(rule) self.__normal = _tf.is_normal(rule) rule.head = self.visit(rule.head) self.__head = False rule.body = self.visit(rule.body) if self.__max_shift[0] > 0 and not self.__final: last = _ast.Rule(rule.location, rule.head, rule.body[:]) self.__append_final(rule, _clingo.Function(_tf.g_time_parameter_name_alt)) self.__constraint_parts.setdefault((self.__part, self.__max_shift[0]), []).append((rule, last)) return None finally: self.__head = False self.__max_shift = [0] self.__constraint = False self.__normal = False return rule
def visit_Rule(self, rule): """ Shift constraints in integrity constraints and visit head/body literals. """ # Note: This implements clingcon's don't care propagation. We can shift # one constraint from the body of an integrity constraint to the head # of a rule. This way the constraint is no longer strict and can be # represented internally with less constraints. head = rule.head body = rule.body if self._shift and head.type == ast.ASTType.Literal and head.atom.type == ast.ASTType.BooleanConstant and not head.atom.value: for literal in body: if literal.type == ast.ASTType.Literal and literal.atom.type == ast.ASTType.TheoryAtom: atom = literal.atom term = atom.term if term.name in [ "sum", "diff", "in", "max", "min", "count" ] and not term.arguments: body = copy(body) body.remove(literal) if literal.sign != ast.Sign.Negation: atom = copy(atom) atom.guard = copy(atom.guard) atom.guard.operator_name = _negate_relation( atom.guard.operator_name) head = atom break # tag heads and bodies head = self.visit(head, loc="head") body = self.visit(body, loc="body") return ast.Rule(rule.location, head, body)
def control_add_facts(ctrl, facts): with ctrl.builder() as bldr: line = 1 for f in facts: raw = f.raw if isinstance(f, Predicate) else f floc = {"filename": "<input>", "line": line, "column": 1} location = {"begin": floc, "end": floc} r = ast.Rule( location, ast.Literal(location, ast.Sign.NoSign, ast.SymbolicAtom(ast.Symbol(location, raw))), []) bldr.add(r) line += 1
def visit_Literal_in_Head_Disjuntion(self, x, *args, **kwargs): if x.sign == ast.Sign.DoubleNegation: sign = self.__dnegative_term elif x.sign == ast.Sign.Negation: sign = self.__negative_term else: sign = self.__positive_term rule_id = ast.Symbol(x.location, self.__rule_id_number) sign = ast.Symbol(x.location, sign) fun = ast.Function(x.location, auxiliary_atom_name, [rule_id, sign, x.atom.term], False) new_literal = ast.Literal(x.location, ast.Sign.NoSign, ast.SymbolicAtom(fun)) self.__auxiliary_atoms.append(new_literal) rule = ast.Rule(x.location, head=x, body=[new_literal]) self.__auxiliary_rules.append(rule) return new_literal
def transform(inputs, callback): """ Transforms the given list of temporal programs in string form into an ASP program. Returns the future predicates whose atoms have to be set to false if referring to the future, and program parts that have to be regrounded if there are constraints referring to the future. Arguments: inputs -- The list of inputs. callback -- Callback for rewritten statements. """ loc = { 'begin': { 'line': 1, 'column': 1, 'filename': '<transform>' }, 'end': { 'line': 1, 'column': 1, 'filename': '<transform>' } } future_predicates = set() constraint_parts = {} time = _ast.Symbol(loc, _clingo.Function(_tf.g_time_parameter_name)) wrap_lit = lambda a: _ast.Literal(loc, _ast.Sign.NoSign, a) # apply transformer to program def append(s): if s is not None: callback(s) aux_rules = [] transformer = _prg.ProgramTransformer(future_predicates, constraint_parts, aux_rules) for i in inputs: _clingo.parse_program(i, lambda s: append(transformer.visit(s))) if aux_rules: callback( _ast.Program(loc, "always", [ _ast.Id(loc, _tf.g_time_parameter_name), _ast.Id(loc, _tf.g_time_parameter_name_alt) ])) for rule in aux_rules: callback(rule) # add auxiliary rules for future predicates future_sigs = [] if len(future_predicates) > 0: callback( _ast.Program(loc, "always", [ _ast.Id(loc, _tf.g_time_parameter_name), _ast.Id(loc, _tf.g_time_parameter_name_alt) ])) for name, arity, positive, shift in sorted(future_predicates): variables = [ _ast.Variable(loc, "{}{}".format(_tf.g_variable_prefix, i)) for i in range(arity) ] s = _ast.Symbol(loc, _clingo.Number(shift)) t_shifted = _ast.BinaryOperation(loc, _ast.BinaryOperator.Plus, time, s) add_sign = lambda lit: lit if positive else _ast.UnaryOperation( loc, _ast.UnaryOperator.Minus, lit) p_current = _ast.SymbolicAtom( add_sign(_ast.Function(loc, name, variables + [time], False))) f_current = _ast.SymbolicAtom( add_sign( _ast.Function(loc, _tf.g_future_prefix + name, variables + [s, time], False))) callback(_ast.Rule(loc, wrap_lit(p_current), [wrap_lit(f_current)])) future_sigs.append( (_tf.g_future_prefix + name, arity + 2, positive)) # gather rules for constraints referring to the future reground_parts = [] if len(constraint_parts) > 0: for (name, shift), rules in constraint_parts.items(): assert (shift > 0) params = [ _ast.Id(loc, _tf.g_time_parameter_name), _ast.Id(loc, _tf.g_time_parameter_name_alt) ] # parts to be regrounded part = "{}_0_{}".format(name, shift - 1) callback(_ast.Program(loc, part, params)) for p, l in rules: callback(p) reground_parts.append((name, part, range(shift))) # parts that no longer have to be regrounded last_part = "{}_{}".format(name, shift) callback(_ast.Program(loc, last_part, params)) for p, l in rules: callback(l) reground_parts.append((name, last_part, range(shift, shift + 1))) def add_part(part_name, atom_name, statement, wrap=lambda x: x): params = [ _ast.Id(loc, _tf.g_time_parameter_name), _ast.Id(loc, _tf.g_time_parameter_name_alt) ] callback(_ast.Program(loc, part_name, params)) atom = wrap( _ast.SymbolicAtom(_ast.Function(loc, atom_name, [time], False))) callback(statement(loc, atom, [])) add_part('initial', '__initial', _ast.Rule, wrap_lit) add_part('always', '__final', _tf.External) reground_parts.append(('always', 'always', range(1))) reground_parts.append(('dynamic', 'dynamic', range(1))) reground_parts.append(('initial', 'initial', range(1))) def no_program(s): if s.type != _ast.ASTType.Program: callback(s) _clingo.parse_program( _dedent('''\ #theory tel { formula_body { & : 7, unary; % prefix for keywords - : 7, unary; % classical negation + : 6, binary, left; % arithmetic + - : 6, binary, left; % arithmetic - ~ : 5, unary; % negation < : 5, unary; % previous < : 5, binary, right; % n x previous <: : 5, unary; % weak previous <: : 5, binary, right; % n x weak previous <? : 5, unary; % eventually- <* : 5, unary; % always- << : 5, unary; % initially > : 5, unary; % next > : 5, binary, right; % n x next >: : 5, unary; % weak next >: : 5, binary, right; % n x weak next >? : 5, unary; % eventually+ >* : 5, unary; % always+ >> : 5, unary; % finally >* : 4, binary, left; % release >? : 4, binary, left; % until <* : 4, binary, left; % trigger <? : 4, binary, left; % since & : 3, binary, left; % and | : 2, binary, left; % or <- : 1, binary, left; % left implication -> : 1, binary, left; % right implication <> : 1, binary, left; % equivalence ;> : 0, binary, right; % sequence next ;>: : 0, binary, right; % sequence weak next <; : 0, binary, left; % sequence previous <:; : 0, binary, left % sequence weak previous }; formula_head { & : 7, unary; % prefix for keywords - : 7, unary; % classical negation + : 6, binary, left; % arithmetic + - : 6, binary, left; % arithmetic - ~ : 5, unary; % negation > : 5, unary; % next > : 5, binary, right; % n x next >: : 5, unary; % weak next >: : 5, binary, right; % n x weak next >? : 5, unary; % eventually+ >* : 5, unary; % always+ >> : 5, unary; % finally >* : 4, binary, left; % release >? : 4, binary, left; % until & : 3, binary, left; % and | : 2, binary, left; % or ;> : 0, binary, right; % sequence next ;>: : 0, binary, right % sequence weak next }; &tel/1 : formula_body, body; &__tel_head/1 : formula_body, head }. '''), no_program) _clingo.parse_program( _dedent('''\ #theory del { formula_body { & : 7, unary; % prefix for keywords ? : 4, unary; % check * : 3, unary; % kleene star + : 2, binary, left; % choice ;; : 1, binary, left; % sequence .>? : 0, binary, right; % diamond (eventually) .>* : 0, binary, right % box (always) }; &del/1 : formula_body, body }. '''), no_program) return future_sigs, reground_parts
def _convert_rule(self, head, body): """ Converts the LPMLN rule using either the unsat atoms or the simplified approach without them (default setting) """ loc = head.location idx, constraint_weight, priority = self._get_constraint_parameters(loc) # Choice rules without bound can be skipped if str(head.ast_type) == 'ASTType.Aggregate': if head.left_guard is None and head.right_guard is None: return [ast.Rule(loc, head, body)] else: not_head = ast.Literal(loc, ast.Sign.Negation, head) else: not_head = ast.Literal(loc, ast.Sign.Negation, head.atom) # Create ASP rules # TODO: Better way to insert and delete items from body? if self.use_unsat: unsat, not_unsat = self._get_unsat_atoms(loc, idx) # Rule 1 (unsat :- Body, not Head) body.insert(0, not_head) asp_rule1 = ast.Rule(loc, unsat, body) # Rule 2 (Head :- Body, not unsat) del body[0] body.insert(0, not_unsat) asp_rule2 = ast.Rule(loc, head, body) # Rule 3 (weak constraint unsat) asp_rule3 = ast.Minimize(loc, constraint_weight, priority, [idx, self.global_variables], [unsat]) return [asp_rule1, asp_rule2, asp_rule3] else: asp_rules = [] # Choice rules with bounds, e.g. 'w : { a; b } = 1 :- B.' # get converted to two rules: # w : { a ; b } :- B. --> { a ; b } :- B. # w : :- not { a ; b } = 1. --> :~ B, not {a ; b} = 1. [w,id, X] if str(head.ast_type) == 'ASTType.Aggregate': agg1 = ast.Aggregate(loc, None, head.elements, None) asp_rules.append(ast.Rule(loc, agg1, body)) body.insert(0, not_head) # Convert integrity constraint 'w: #false :- B.' to weak constraint # of form: ':~ B. [w, idx, X]' elif str(head.atom.ast_type ) == 'ASTType.BooleanConstant' and not head.atom.value: pass # Convert normal rule 'w: H :- B.' to choice rule and weak # constraint of form: '{H} :- B.' and ':~ B, not H. [w, idx, X]' else: cond_head = ast.ConditionalLiteral(loc, head, []) choice_head = ast.Aggregate(loc, None, [cond_head], None) asp_rules.append(ast.Rule(loc, choice_head, body)) body.insert(0, not_head) # TODO: Should the two solve calls work with unsat as well? if self.two_solve_calls and str(priority) == '0': ext_helper_atom = ast.SymbolicAtom( ast.Function(loc, 'ext_helper', [], False)) ext_helper_atom = ast.Literal(loc, ast.Sign.NoSign, ext_helper_atom) body.insert(0, ext_helper_atom) weak_constraint = ast.Minimize(loc, constraint_weight, priority, [idx, self.global_variables], body) asp_rules.append(weak_constraint) return asp_rules