def build_sdd(self, q, test): i = 1 if test else 0 ground = self.engine[i].ground_all(self.problog_model[i], queries=[q]) sdd = SDD.create_from(ground) # print(sdd) # sdd.build_dd() # print(sdd) # shape = VectorShape(self, sdd) # semiring = SemiringGradient(self, shape) # evaluator = sdd.get_evaluator(semiring=semiring) return sdd
def solve(model, semiring, operator): ev = SDD.create_from(model, label_all=True).to_formula( ) if semiring.is_dsp() else LogicDAG.create_from(model, label_all=True) fe = FormulaEvaluatorNSP( ev, semiring) if semiring.is_nsp() else FormulaEvaluator(ev, semiring) weights = ev.extract_weights(semiring=semiring) fe.set_weights(weights) result = {} for n, q in ev.queries(): p = fe.evaluate(q) result[n] = (p, p.integrate(operator)) return result
def call_theorem_prover(theorem_prover, instance_id, question_id, theory, assertion, gold_label, print_log=True): """Function that takes a single theory/assertion example and runs it through the theorem prover to obtain a label. Returns the obtained label, elapsed time to solve it, and exception returned by the engine, if any. """ obtained_result = False millisecs_elapsed = 0 if print_log: print("=======ORIGINAL THEORY=========") theory_as_txt = theory.program(theorem_prover) if print_log: print(theory_as_txt) theory.preprocess(theorem_prover) theory_as_txt = theory.program(theorem_prover) if theorem_prover == "problog": assertion_lf = assertion.logical_form(theorem_prover, False) assertion_lf = f"query({assertion_lf})." program = f"{theory_as_txt}\n{assertion_lf}" if print_log: print("=======PROGRAM FROM PREPROCESSED THEORY=========") print(program) print("=======EXPECTED LABEL=========") print(f" {gold_label}") start_millisecs = current_milli_time() try: lf = LogicFormula.create_from(program) # ground the program dag = LogicDAG.create_from( lf) # break cycles in the ground program sdd = SDD.create_from(dag) result = sdd.evaluate() end_millisecs = current_milli_time() elapsed_millisecs = end_millisecs - start_millisecs result_tuples = [(k, v) for k, v in result.items()] obtained_result = result_tuples[0][1] != float(0) return obtained_result, elapsed_millisecs, None except (NegativeCycle, NonGroundProbabilisticClause, UnknownClause) as e: end_millisecs = current_milli_time() elapsed_millisecs = end_millisecs - start_millisecs if print_log: print( f"!!!Encountered Exception at instance id {instance_id}, question id {question_id}: {e}" ) exception_name = str(type(e)).lstrip("<class '").rstrip("'>") return None, elapsed_millisecs, exception_name return obtained_result, elapsed_millisecs, None
def run_theory_in_problog(theory, assertion): """Run the given theory and assertion through ProbLog engine to obtain a True/False label. If an exception is encountered, return None so that this example will not be part of output.""" theorem_prover = "problog" try: program = theory.program(theorem_prover, assertion) lf = LogicFormula.create_from(program) # ground the program dag = LogicDAG.create_from(lf) # break cycles in the ground program sdd = SDD.create_from(dag) result = sdd.evaluate() result_tuples = [(k, v) for k, v in result.items()] if len(result_tuples) == 0: return False return result_tuples[0][1] != 0.0 except (NegativeCycle, NonGroundProbabilisticClause, UnknownClause) as e: return None return None
def solve(model, semiring, operator): t = time.time() if semiring.is_dsp(): ev = SDD.create_from(model, label_all=True).to_formula() # for n, q in diagram.queries(): # diagram.get_manager().write_to_dot(diagram.get_inode(q), "examples/formula" + str(q) + ".gv") else: ev = LogicDAG.create_from(model, label_all=True) if semiring.is_nsp(): fe = FormulaEvaluatorNSP(ev, semiring) else: fe = FormulaEvaluator(ev, semiring) weights = ev.extract_weights(semiring=semiring) fe.set_weights(weights) result = {} print("inference time: {}".format(time.time() - t)) for n, q in ev.queries(): p = fe.evaluate(q) result[n] = (p, p.integrate(operator)) return result
def solve(model, semiring): t = time.time() if semiring.is_dsp(): ev = SDD.create_from(model, label_all=True).to_formula() print ev print "SDD time: {}".format(time.time() - t) exit(0) else: ev = LogicDAG.create_from(model, label_all=True) if semiring.is_nsp(): fe = FormulaEvaluatorNSP(ev, semiring) else: fe = FormulaEvaluator(ev, semiring) weights = ev.extract_weights(semiring=semiring) # print weights fe.set_weights(weights) result = {} [(n, q)] = ev.queries() p = fe.evaluate(q) result[n] = p return result
def main(argv, handle_output=None): args = argparser().parse_args(argv) verbose = args.verbose filename = args.filename if verbose: debug("Loading...") problog_model = PrologFile(filename, factory=ConstraintFactory()) engine = DefaultEngine() database = engine.prepare(problog_model) # Ground the constraints if verbose: debug("Grounding...") target = engine.ground(database, Term("constraint", None, None), label="constraint") queries = [q[0] for q in engine.query(database, Term("query", None))] for query in queries: target = engine.ground(database, query, label="query", target=target) if verbose > 1: print(target, file=sys.stderr) has_prob_constraint = False for name, index in target.get_names(label="constraint"): if index is not None: if name.args[1].functor == "ensure_prob": has_prob_constraint = True # Compile and turn into CP-problem if has_prob_constraint: if verbose: debug("Probabilistic constraints detected.") if verbose: debug("Compiling...") sdd = SDD.create_from(target) formula = sdd.to_formula() # Convert to flatzinc if verbose: debug("Converting...") fzn = formula_to_flatzinc_float(formula) sdd.clear_labeled("constraint") if verbose > 1: print(fzn, file=sys.stderr) # Solve the flatzinc model if verbose: debug("Solving...") sols = list(solve(fzn)) has_solution = False for i, res in enumerate(sols): if verbose: debug("Evaluating solution %s/%s..." % (i + 1, len(sols))) # target.lookup_evidence = {} weights = sdd.get_weights() # ev_nodes = [] for k, v in res.items(): sddvar = formula.get_node(k).identifier sddatom = sdd.var2atom[sddvar] sddname = sdd.get_name(sddatom) weights[sddatom] = v for k, v in sdd.evaluate().items(): if v > 0.0: print(k, v) print("----------") has_solution = True if has_solution: print("==========") else: print("=== UNSATISFIABLE ===") else: formula = LogicDAG() break_cycles(target, formula) if verbose: debug("Converting...") fzn = formula_to_flatzinc_bool(formula) if verbose > 1: print(fzn, file=sys.stderr) if verbose: debug("Solving...") sols = list(solve(fzn)) has_solution = False for i, res in enumerate(sols): if verbose: debug("Evaluating solution %s/%s..." % (i + 1, len(sols))) if verbose: debug("Compressing...") new_formula = compress(formula, res) if verbose: debug("Compiling...") sdd = SDD.create_from(new_formula) if verbose: debug("Evaluating...") for k, v in sdd.evaluate().items(): if v > 0.0: print(k, v) print("----------") has_solution = True if has_solution: print("==========") else: print("=== UNSATISFIABLE ===")
return new_weights, iters # Read in the progam with tunable parameters #ground_progam = file_to_string("test_learn.pl") # Assign to each tunable parameter a random initialization value #ground_progam_tunable = init_tunable(ground_progam) # Write back the prolog file with random initialized tunable probabilities #f = open('test_learn_tunable.pl', 'w') #f.write(ground_progam_tunable) pf = PrologFile("test_learn_tunable.pl") formula = LogicFormula.create_from(pf) sdd = SDD.create_from(formula) queries = [ Term('stress', Term('a')), Term('stress', Term('b')), Term('stress', Term('c')), Term('smokes', Term('a')), Term('smokes', Term('b')), Term('smokes', Term('c')) ] # File which holds all the evidence examples examples = file_to_string('data.pl') # Retrieve the amount of interpretations that has been specified interpretations_100 = get_interpretations(examples, 100)