Exemple #1
0
    def swizzle_randvars(self, btor: Boolector, ri: RandInfo, start_rs: int,
                         end_rs: int, bound_m: Dict[FieldModel,
                                                    VariableBoundModel]):

        # TODO: we must ignore fields that are otherwise being controlled

        rand_node_l = []
        x = start_rs
        while x < end_rs:
            # For each random variable, select a partition with it's known
            # domain and add the corresponding constraint
            rs = ri.randsets()[x]

            field_l = rs.fields_l()
            if len(field_l) == 1:
                # Go ahead and pick values in the domain, since there
                # are no other constraints
                f = field_l[0]
                e = self.create_single_var_domain_constraint(
                    field_l[0], bound_m[field_l[0]])

                if e is not None:
                    n = e.build(btor)
                    rand_node_l.append(n)
#                    btor.Assume(n)
            else:
                for f in field_l:
                    if f.is_used_rand and f in bound_m.keys():
                        f_bound = bound_m[f]

                        if not f_bound.isEmpty():
                            e = self.create_rand_domain_constraint(f, f_bound)
                            if e is not None:
                                n = e.build(btor)
                                rand_node_l.append(n)
#                                btor.Assume(n)
                        else:
                            # It's always possible that this value is already fixed.
                            # Just ignore.
                            #                            rand_node_l.append(None)
                            pass
            x += 1
        if len(rand_node_l) > 0:
            btor.Assume(*rand_node_l)

            if btor.Sat() != btor.SAT:
                # Remove any failing assumptions

                n_failed = 0
                for i, n in enumerate(rand_node_l):
                    if n is not None and btor.Failed(n):
                        rand_node_l[i] = None
                        n_failed += 1

                # Re-apply the constraints that succeeded
                btor.Assume(*filter(lambda n: n is not None, rand_node_l))

        if btor.Sat() != btor.SAT:
            raise Exception("failed to add in randomization")
Exemple #2
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    def build(self, btor: Boolector):
        ret = None

        if self.op == UnaryExprType.Not:
            ret = btor.Not(self.expr.build(btor))

        return ret
        ExprModel.build(self, btor)
Exemple #3
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    def build(self, btor: Boolector, ctx_width=-1):
        ret = None

        e_w = self.expr.width()
        if e_w > ctx_width:
            ctx_width = e_w

        if self.op == UnaryExprType.Not:
            ret = btor.Not(self.expr.build(btor, ctx_width))

        return ret
Exemple #4
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    def randomize(self, ri: RandInfo, bound_m: Dict[FieldModel,
                                                    VariableBoundModel]):
        """Randomize the variables and constraints in a RandInfo collection"""

        #         for rs in ri.randsets():
        #             print("RandSet")
        #             for f in rs.all_fields():
        #                 print("  " + f.name + " " + str(bound_m[f].domain.range_l))
        #         for uf in ri.unconstrained():
        #             print("Unconstrained: " + uf.name)

        rs_i = 0
        start_rs_i = 0
        max_fields = 20
        while rs_i < len(ri.randsets()):
            btor = Boolector()
            self.btor = btor
            btor.Set_opt(pyboolector.BTOR_OPT_INCREMENTAL, True)
            btor.Set_opt(pyboolector.BTOR_OPT_MODEL_GEN, True)

            start_rs_i = rs_i

            constraint_l = []
            # Collect up to max_fields fields to randomize at a time
            n_fields = 0
            while rs_i < len(ri.randsets()):
                rs = ri.randsets()[rs_i]
                try:
                    for f in rs.all_fields():
                        f.build(btor)
                        n_fields += 1
                except Exception as e:
                    for c in rs.constraints():
                        print("Constraint: " + self.pretty_printer.do_print(c))
                    raise e

                constraint_l.extend(
                    list(
                        map(
                            lambda c: (c, c.build(btor),
                                       isinstance(c, ConstraintSoftModel)),
                            rs.constraints())))

                rs_i += 1
                if n_fields > max_fields:
                    break

            for c in constraint_l:
                try:
                    btor.Assume(c[1])
                except Exception as e:
                    from ..visitors.model_pretty_printer import ModelPrettyPrinter
                    print("Exception: " + ModelPrettyPrinter.print(c[0]))
                    raise e

            soft_node_l = list(
                map(lambda c: c[1], filter(lambda c: c[2], constraint_l)))
            node_l = list(
                map(lambda c: c[1], filter(lambda c: not c[2], constraint_l)))

            # Perform an initial solve to establish correctness
            if btor.Sat() != btor.SAT:

                if len(soft_node_l) > 0:
                    # Try one more time before giving up
                    for i, f in enumerate(btor.Failed(*soft_node_l)):
                        if f:
                            soft_node_l[i] = None

                    # Add back the hard-constraint nodes and soft-constraints that
                    # didn't fail
                    for n in filter(lambda n: n is not None,
                                    node_l + soft_node_l):
                        btor.Assume(n)

                    # If we fail again, then we truly have a problem
                    if btor.Sat() != btor.SAT:

                        # Ensure we clean up
                        x = start_rs_i
                        while x < rs_i:
                            rs = ri.randsets()[x]
                            for f in rs.all_fields():
                                f.dispose()
                            x += 1

                        raise Exception("solve failure")
                    else:
                        # Still need to convert assumptions to assertions
                        for n in filter(lambda n: n is not None,
                                        node_l + soft_node_l):
                            btor.Assert(n)
                else:
                    print("Failed constraints:")
                    i = 1
                    for c in constraint_l:
                        if btor.Failed(c[1]):
                            print("[" + str(i) + "]: " +
                                  self.pretty_printer.do_print(c[0], False))
                            print("[" + str(i) + "]: " +
                                  self.pretty_printer.do_print(c[0], True))
                            i += 1

                    # Ensure we clean up
                    for rs in ri.randsets():
                        for f in rs.all_fields():
                            f.dispose()
                    print("Solve failure")
                    raise Exception("solve failure")
            else:
                # Still need to convert assumptions to assertions
                btor.Assert(*(node_l + soft_node_l))

            self.swizzle_randvars(btor, ri, start_rs_i, rs_i, bound_m)

            # Finalize the value of the field
            x = start_rs_i
            while x < rs_i:
                rs = ri.randsets()[x]
                for f in rs.all_fields():
                    f.post_randomize()
                    f.dispose(
                    )  # Get rid of the solver var, since we're done with it
                x += 1

        uc_rand = list(filter(lambda f: f.is_used_rand, ri.unconstrained()))
        for uf in uc_rand:
            bounds = bound_m[uf]
            range_l = bounds.domain.range_l

            if len(range_l) == 1:
                # Single (likely domain-based) range
                uf.set_val(self.randint(range_l[0][0], range_l[0][1]))
            else:
                # Most likely an enumerated type
                # TODO: are there any cases where these could be ranges?
                idx = self.randint(0, len(range_l) - 1)
                uf.set_val(range_l[idx][0])
import os
import pyboolector
from pyboolector import Boolector, BoolectorException

if __name__ == "__main__":
    b = Boolector()
    print("Boolector version " + b.Version())
    print("Boolector id " + b.GitId())
    print()
    print(b.Copyright())

    # Try pushing a context without enabling incremental usage,
    # raises Exception
    try:
        print("Expect exception to be raised (incremental usage not enabled).")
        b.Push()
    except BoolectorException as e:
        print("Caught exception: " + str(e))

    # Try popping a context without first having pushed a context,
    # raises Exception
    try:
        b.Set_opt(pyboolector.BTOR_OPT_INCREMENTAL, True)
        print("Expect exception to be raised (no context pushed).")
        b.Pop()
    except BoolectorException as e:
        print("Caught exception: " + str(e))

### Creating Boolector nodes

# Sorts
Exemple #6
0
    def randomize(self, ri : RandInfo, bound_m : Dict[FieldModel,VariableBoundModel]):
        """Randomize the variables and constraints in a RandInfo collection"""
        

        if self.debug > 0:
            for rs in ri.randsets():
                print("RandSet")
                for f in rs.all_fields():
                    if f in bound_m.keys():
                        print("  Field: " + f.fullname + " " + str(bound_m[f].domain.range_l))
                for c in rs.constraints():
                    print("  Constraint: " + self.pretty_printer.do_print(c, show_exp=True))
            for uf in ri.unconstrained():
                print("Unconstrained: " + uf.name)
               
        # Assign values to the unconstrained fields first
        uc_rand = list(filter(lambda f:f.is_used_rand, ri.unconstrained()))
        for uf in uc_rand:
            if self.debug > 0:
                print("Randomizing unconstrained: " + uf.fullname)
            bounds = bound_m[uf]
            range_l = bounds.domain.range_l
            
            if len(range_l) == 1:
                # Single (likely domain-based) range
                uf.set_val(
                    self.randint(range_l[0][0], range_l[0][1]))
            else:
                # Most likely an enumerated type
                # TODO: are there any cases where these could be ranges?
                idx = self.randint(0, len(range_l)-1)
                uf.set_val(range_l[idx][0])                
                
            # Lock so we don't overwrite
            uf.set_used_rand(False)

        rs_i = 0
        start_rs_i = 0
        max_fields = 20
        while rs_i < len(ri.randsets()):        
            btor = Boolector()
            self.btor = btor
            btor.Set_opt(pyboolector.BTOR_OPT_INCREMENTAL, True)
            btor.Set_opt(pyboolector.BTOR_OPT_MODEL_GEN, True)
            
            start_rs_i = rs_i

            constraint_l = []
            # Collect up to max_fields fields to randomize at a time
            n_fields = 0
            while rs_i < len(ri.randsets()):
                rs = ri.randsets()[rs_i]
                
                rs_node_builder = RandSetNodeBuilder(btor)

                all_fields = rs.all_fields()
                if self.debug > 0:
                    print("Pre-Randomize: RandSet")
                    for f in all_fields:
                        if f in bound_m.keys():
                            print("  Field: " + f.fullname + " " + str(bound_m[f].domain.range_l))
                    for c in rs.constraints():
                        print("  Constraint: " + self.pretty_printer.do_print(c, show_exp=True, print_values=True))

                rs_node_builder.build(rs)
                n_fields += len(all_fields)
                
                constraint_l.extend(list(map(lambda c:(c,c.build(btor),isinstance(c,ConstraintSoftModel)), rs.constraints())))
                
                rs_i += 1
                if n_fields > max_fields or rs.order != -1:
                    break
                
            for c in constraint_l:
                try:
                    btor.Assume(c[1])
                except Exception as e:
                    from ..visitors.model_pretty_printer import ModelPrettyPrinter
                    print("Exception: " + ModelPrettyPrinter.print(c[0]))
                    raise e
                
            soft_node_l = list(map(lambda c:c[1], filter(lambda c:c[2], constraint_l)))
            node_l = list(map(lambda c:c[1], filter(lambda c:not c[2], constraint_l)))

            # Perform an initial solve to establish correctness
            if btor.Sat() != btor.SAT:
                
                if len(soft_node_l) > 0:
                    # Try one more time before giving up
                    for i,f in enumerate(soft_node_l):
                        if btor.Failed(f):
                            soft_node_l[i] = None
                        
                    # Add back the hard-constraint nodes and soft-constraints that
                    # didn't fail                        
#                    for n in filter(lambda n:n is not None, node_l+soft_node_l):
                    for n in filter(lambda n:n is not None, node_l):
                        btor.Assume(n)
                        
                    for n in filter(lambda n:n is not None, soft_node_l):
                        btor.Assume(n)

                    # If we fail again, then we truly have a problem
                    if btor.Sat() != btor.SAT:
                    
                        # Ensure we clean up
#                        active_randsets = []
#                        x=start_rs_i
#                        while x < rs_i:
#                            rs = ri.randsets()[x]
#                            active_randsets.append(rs)
#                            for f in rs.all_fields():
#                                f.dispose()
#                            x += 1
                        active_randsets = []
                        for rs in ri.randsets():
                            active_randsets.append(rs)
                            for f in rs.all_fields():
                                f.dispose()
                            raise SolveFailure(
                                "solve failure",
                                self.create_diagnostics(active_randsets))

#                        raise SolveFailure(
#                            "solve failure", 
#                            self.create_diagnostics(active_randsets))
                    else:
                        # Still need to convert assumptions to assertions
                        for n in filter(lambda n:n is not None, node_l+soft_node_l):
                            btor.Assert(n)
                else:
#                    print("Failed constraints:")
#                    i=1
#                    for c in constraint_l:
#                        if btor.Failed(c[1]):
#                            print("[" + str(i) + "]: " + self.pretty_printer.do_print(c[0], False))
#                            print("[" + str(i) + "]: " + self.pretty_printer.do_print(c[0], True))
#                            i+=1
                            
                    # Ensure we clean up
                    active_randsets = []
                    for rs in ri.randsets():
                        active_randsets.append(rs)
                        for f in rs.all_fields():
                            f.dispose()
                    raise SolveFailure(
                        "solve failure",
                        self.create_diagnostics(active_randsets))
            else:
                # Still need to convert assumptions to assertions
                btor.Assert(*(node_l+soft_node_l))


            self.swizzle_randvars(btor, ri, start_rs_i, rs_i, bound_m)

        # Finalize the value of the field
            x = start_rs_i
            reset_v = DynamicExprResetVisitor()
            while x < rs_i:
                rs = ri.randsets()[x]
                for f in rs.all_fields():
                    f.post_randomize()
                    f.set_used_rand(False, 0)
                    f.dispose() # Get rid of the solver var, since we're done with it
                    f.accept(reset_v)
#                for f in rs.nontarget_field_s:
#                    f.dispose()
                for c in rs.constraints():
                    c.accept(reset_v)
                RandSetDisposeVisitor().dispose(rs)
                x += 1
                
                
        end = int(round(time.time() * 1000))
Exemple #7
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    def create_diagnostics(self, active_randsets) -> str:
        ret = ""
        
        btor = Boolector()
        btor.Set_opt(pyboolector.BTOR_OPT_INCREMENTAL, True)
        btor.Set_opt(pyboolector.BTOR_OPT_MODEL_GEN, True)
        
        diagnostic_constraint_l = [] 
        diagnostic_field_l = []
        
        # First, determine how many randsets are actually failing
        i = 0
        while i < len(active_randsets):
            rs = active_randsets[i]
            for f in rs.all_fields():
                f.build(btor)

            # Assume that we can omit all soft constraints, since they
            # will have already been omitted (?)                
            constraint_l = list(map(lambda c:(c,c.build(btor)), filter(lambda c:not isinstance(c,ConstraintSoftModel), rs.constraints())))
                
            for c in constraint_l:
                btor.Assume(c[1])

            if btor.Sat() != btor.SAT:
                # Save fields and constraints if the randset doesn't 
                # solve on its own
                diagnostic_constraint_l.extend(constraint_l)
                diagnostic_field_l.extend(rs.fields())
                
            i += 1

        problem_constraints = []
        solving_constraints = []
        # Okay, now perform a series of solves to identify
        # constraints that are actually a problem
        for c in diagnostic_constraint_l:
            btor.Assume(c[1])
            
            if btor.Sat() != btor.SAT:
                # This is a problematic constraint
                # Save it for later
                problem_constraints.append(c[0])
            else:
                # Not a problem. Assert it now
                btor.Assert(c[1])
                solving_constraints.append(c[0])
#                problem_constraints.append(c[0])
                
        if btor.Sat() != btor.SAT:
            raise Exception("internal error: system should solve")
        
        # Okay, we now have a constraint system that solves, and
        # a list of constraints that are a problem. We want to 
        # resolve the value of all variables referenced by the 
        # solving constraints so and then display the non-solving
        # constraints. This will (hopefully) help highlight the
        # reason for the failure
        for c in solving_constraints:
            c.accept(RefFieldsPostRandVisitor())

        ret += "Problem Constraints:\n"
        for i,pc in enumerate(problem_constraints):

            ret += "Constraint " + str(i+1) + ":\n"
            ret += ModelPrettyPrinter.print(pc, print_values=True)
            ret += ModelPrettyPrinter.print(pc, print_values=False)

        for rs in active_randsets:
            for f in rs.all_fields():
                f.dispose()
            
        return ret
Exemple #8
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    def swizzle_randvars(self, 
                btor     : Boolector, 
                ri       : RandInfo,
                start_rs : int,
                end_rs   : int,
                bound_m  : Dict[FieldModel,VariableBoundModel]):

        # TODO: we must ignore fields that are otherwise being controlled
        if self.debug > 0:
            print("--> swizzle_randvars")

        rand_node_l = []
        rand_e_l = []
        x=start_rs
        while x < end_rs:
            # For each random variable, select a partition with it's known 
            # domain and add the corresponding constraint
            rs = ri.randsets()[x]
            
            field_l = rs.rand_fields()
            
            if self.debug > 0:
                print("  " + str(len(field_l)) + " fields in randset")
            if len(field_l) == 1:
                # Go ahead and pick values in the domain, since there 
                # are no other constraints
                f = field_l[0]
                if f in bound_m.keys():
                    f_bound = bound_m[f]
                    if not f_bound.isEmpty():
                        e = self.create_rand_domain_constraint(f, f_bound)
                        if e is not None:
                            n = e.build(btor)
                            rand_node_l.append(n)
                            rand_e_l.append(e)
            elif len(field_l) > 0:
                field_idx = self.randint(0, len(field_l)-1)
                f = field_l[field_idx]
                if self.debug > 0:
                    print("Swizzling field " + f.name)
                if f in bound_m.keys():
                    f_bound = bound_m[f]
                 
                    if not f_bound.isEmpty():
                        e = self.create_rand_domain_constraint(f, f_bound)
                        if e is not None:
                            n = e.build(btor)
                            rand_node_l.append(n)
                            rand_e_l.append(e)
#                                btor.Assume(n)
                    else:
                        # It's always possible that this value is already fixed.
                        # Just ignore.
#                            rand_node_l.append(None)
                        pass
                else:
                    if self.debug > 0:
                        print("Note: no bounds found for field " + f.name)
            x += 1
            
        if len(rand_node_l) > 0:            
            btor.Assume(*rand_node_l)
#            btor.Assert(*rand_node_l)
     
            if btor.Sat() != btor.SAT:
                # Remove any failing assumptions
                
                if self.debug > 0:
                    print("Randomization constraint failed")
 
                n_failed = 0
                for i,n in enumerate(rand_node_l):
                    if n is not None and btor.Failed(n):
                        rand_node_l[i] = None
                        n_failed += 1

                # Sanity check                
                if n_failed == 0:
                    for e in rand_e_l:
                        print("Constraint: " + ModelPrettyPrinter.print(e))
                    raise Exception("UNSAT reported, but no failing assertions")
# 
                # Re-apply the constraints that succeeded
                btor.Assert(*filter(lambda n:n is not None, rand_node_l))
                if btor.Sat() != btor.SAT:
                    raise Exception("failed to add in randomization (2)")
        else:
            if btor.Sat() != btor.SAT:
                raise Exception("failed to add in randomization")
            
        if self.debug > 0:
            print("<-- swizzle_randvars")
Exemple #9
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    def __init__(self, quantized_model, btor=None, verbose=None, config=None):

        if btor is None:
            btor = Boolector()
            btor.Set_opt(pyboolector.BTOR_OPT_MODEL_GEN, 2)
        self.btor = btor
        self._debug_list = []
        self._verbose = verbose
        # This setting should yield the best results on average
        self.config = {
            "add_bound_constraints": True,
            "sat_engine_cadical": True,
            "rebalance_sum": True,
            "recursive_sum": True,
            "sort_sum": None,
            "propagate_bounds": True,
            "relu_simplify": True,
            "subsum_elimination":
            False,  # subsub elimination can hurt performance -> better not activate it
            "min_bits": True,
            "shift_elimination": True,
        }
        # Overwrite default config with argument
        if not config is None:
            for k, v in config.items():
                self.config[k] = v

        self._stats = {
            "constant_neurons": 0,
            "linear_neurons": 0,
            "unstable_neurons": 0,
            "reused_expressions": 0,
            "partially_stable_neurons": 0,
            "build_time": 0,
            "sat_time": 0,
            "total_time": 0,
        }

        self.dense_layers = []
        self.quantized_model = quantized_model

        self._last_layer_signed = quantized_model._last_layer_signed
        self.quantization_config = quantized_model.quantization_config

        current_bits = self.quantization_config["input_bits"]
        for i, l in enumerate(quantized_model.dense_layers):
            self.dense_layers.append(
                LayerEncoding(
                    layer_size=l.units,
                    btor=self.btor,
                    bit_width=self.quantization_config["quantization_bits"],
                    frac_bits=self.quantization_config["quantization_bits"] -
                    self.quantization_config["int_bits_activation"],
                    quantization_config=self.quantization_config,
                    signed_output=l.signed_output,
                ))
        # Create input vars
        input_size = quantized_model._input_shape[-1]
        self.input_layer = LayerEncoding(
            layer_size=input_size,
            btor=self.btor,
            bit_width=self.quantization_config["input_bits"],
            frac_bits=self.quantization_config["input_bits"] -
            self.quantization_config["int_bits_input"],
            quantization_config=self.quantization_config,
        )
        self.input_vars = self.input_layer.vars
        self.output_vars = self.dense_layers[-1].vars
Exemple #10
0
    def randomize(self, ri: RandInfo, bound_m: Dict[FieldModel,
                                                    VariableBoundModel]):
        """Randomize the variables and constraints in a RandInfo collection"""

        if self.solve_info is not None:
            self.solve_info.n_randsets = len(ri.randsets())

        if self.debug > 0:
            rs_i = 0
            while rs_i < len(ri.randsets()):
                rs = ri.randsets()[rs_i]
                print("RandSet[%d]" % rs_i)
                for f in rs.all_fields():
                    if f in bound_m.keys():
                        print("  Field: %s is_rand=%s %s" %
                              (f.fullname, str(f.is_used_rand),
                               str(bound_m[f].domain.range_l)))
                    else:
                        print("  Field: %s is_rand=%s (unbounded)" %
                              (f.fullname, str(f.is_used_rand)))

                for c in rs.constraints():
                    print("  Constraint: " +
                          self.pretty_printer.do_print(c, show_exp=True))
                for c in rs.soft_constraints():
                    print("  SoftConstraint: " +
                          self.pretty_printer.do_print(c, show_exp=True))

                rs_i += 1

            for uf in ri.unconstrained():
                print("Unconstrained: " + uf.fullname)

        # Assign values to the unconstrained fields first
        uc_rand = list(filter(lambda f: f.is_used_rand, ri.unconstrained()))
        for uf in uc_rand:
            if self.debug > 0:
                print("Randomizing unconstrained: " + uf.fullname)
            bounds = bound_m[uf]
            range_l = bounds.domain.range_l

            if len(range_l) == 1:
                # Single (likely domain-based) range
                uf.set_val(self.randstate.randint(range_l[0][0],
                                                  range_l[0][1]))
            else:
                # Most likely an enumerated type
                # TODO: are there any cases where these could be ranges?
                idx = self.randstate.randint(0, len(range_l) - 1)
                uf.set_val(range_l[idx][0])

            # Lock so we don't overwrite
            uf.set_used_rand(False)

        rs_i = 0
        start_rs_i = 0
        #        max_fields = 20
        max_fields = 0
        while rs_i < len(ri.randsets()):
            btor = Boolector()
            self.btor = btor
            btor.Set_opt(pyboolector.BTOR_OPT_INCREMENTAL, True)
            btor.Set_opt(pyboolector.BTOR_OPT_MODEL_GEN, True)

            start_rs_i = rs_i

            constraint_l = []
            soft_constraint_l = []

            # Collect up to max_fields fields to randomize at a time
            n_fields = 0
            while rs_i < len(ri.randsets()):
                rs = ri.randsets()[rs_i]

                rs_node_builder = RandSetNodeBuilder(btor)

                all_fields = rs.all_fields()
                if self.debug > 0:
                    print("Pre-Randomize: RandSet[%d]" % rs_i)
                    for f in all_fields:
                        if f in bound_m.keys():
                            print("  Field: %s is_rand=%s %s var=%s" %
                                  (f.fullname, str(f.is_used_rand),
                                   str(bound_m[f].domain.range_l), str(f.var)))
                        else:
                            print("  Field: %s is_rand=%s (unbounded)" %
                                  (f.fullname, str(f.is_used_rand)))
                    for c in rs.constraints():
                        print("  Constraint: " + self.pretty_printer.do_print(
                            c, show_exp=True, print_values=True))
                    for c in rs.soft_constraints():
                        print("  SoftConstraint: " +
                              self.pretty_printer.do_print(
                                  c, show_exp=True, print_values=True))

                if self.solve_info is not None:
                    self.solve_info.n_cfields += len(all_fields)

                rs_node_builder.build(rs)
                n_fields += len(all_fields)

                #                constraint_l.extend(list(map(lambda c:(c,c.build(btor),isinstance(c,ConstraintSoftModel)), rs.constraints())))
                constraint_l.extend(
                    list(map(lambda c: (c, c.build(btor)), rs.constraints())))
                soft_constraint_l.extend(
                    list(
                        map(lambda c: (c, c.build(btor)),
                            rs.soft_constraints())))

                # Sort the list in descending order so we know which constraints
                # to prioritize
                soft_constraint_l.sort(key=lambda c: c[0].priority,
                                       reverse=True)

                rs_i += 1
                if n_fields > max_fields or rs.order != -1:
                    break

            for c in constraint_l:
                try:
                    btor.Assume(c[1])
                except Exception as e:
                    print("Exception: " + self.pretty_printer.print(c[0]))
                    raise e

            if self.solve_info is not None:
                self.solve_info.n_sat_calls += 1

            if btor.Sat() != btor.SAT:
                # If the system doesn't solve with hard constraints added,
                # then we may as well bail now
                active_randsets = []
                for rs in ri.randsets():
                    active_randsets.append(rs)
                    for f in rs.all_fields():
                        f.dispose()

                if self.solve_fail_debug > 0:
                    raise SolveFailure(
                        "solve failure",
                        self.create_diagnostics(active_randsets))
                else:
                    raise SolveFailure(
                        "solve failure",
                        "Solve failure: set 'solve_fail_debug=1' for more details"
                    )
            else:
                # Lock down the hard constraints that are confirmed
                # to be valid
                for c in constraint_l:
                    btor.Assert(c[1])

            # If there are soft constraints, add these now
            if len(soft_constraint_l) > 0:
                for c in soft_constraint_l:
                    try:
                        btor.Assume(c[1])
                    except Exception as e:
                        from ..visitors.model_pretty_printer import ModelPrettyPrinter
                        print("Exception: " + ModelPrettyPrinter.print(c[0]))
                        raise e

                if self.solve_info is not None:
                    self.solve_info.n_sat_calls += 1
                if btor.Sat() != btor.SAT:
                    # All the soft constraints cannot be satisfied. We'll need to
                    # add them incrementally
                    if self.debug > 0:
                        print(
                            "Note: some of the %d soft constraints could not be satisfied"
                            % len(soft_constraint_l))

                    for c in soft_constraint_l:
                        btor.Assume(c[1])

                        if self.solve_info is not None:
                            self.solve_info.n_sat_calls += 1
                        if btor.Sat() == btor.SAT:
                            if self.debug > 0:
                                print("Note: soft constraint %s (%d) passed" %
                                      (self.pretty_printer.print(
                                          c[0]), c[0].priority))
                            btor.Assert(c[1])
                        else:
                            if self.debug > 0:
                                print("Note: soft constraint %s (%d) failed" %
                                      (self.pretty_printer.print(
                                          c[0]), c[0].priority))
                else:
                    # All the soft constraints could be satisfied. Assert them now
                    if self.debug > 0:
                        print(
                            "Note: all %d soft constraints could be satisfied"
                            % len(soft_constraint_l))
                    for c in soft_constraint_l:
                        btor.Assert(c[1])

#            btor.Sat()
            x = start_rs_i
            while x < rs_i:
                self.swizzler.swizzle(btor, ri.randsets()[x], bound_m)
                x += 1

            # Finalize the value of the field
            x = start_rs_i
            reset_v = DynamicExprResetVisitor()
            while x < rs_i:
                rs = ri.randsets()[x]
                for f in rs.all_fields():
                    f.post_randomize()
                    f.set_used_rand(False, 0)
                    f.dispose(
                    )  # Get rid of the solver var, since we're done with it
                    f.accept(reset_v)
#                for f in rs.nontarget_field_s:
#                    f.dispose()
                for c in rs.constraints():
                    c.accept(reset_v)
                RandSetDisposeVisitor().dispose(rs)

                if self.debug > 0:
                    print("Post-Randomize: RandSet[%d]" % x)
                    for f in all_fields:
                        if f in bound_m.keys():
                            print("  Field: %s %s" %
                                  (f.fullname, str(f.val.val)))
                        else:
                            print("  Field: %s (unbounded) %s" %
                                  (f.fullname, str(f.val.val)))

                    for c in rs.constraints():
                        print("  Constraint: " + self.pretty_printer.do_print(
                            c, show_exp=True, print_values=True))
                    for c in rs.soft_constraints():
                        print("  SoftConstraint: " +
                              self.pretty_printer.do_print(
                                  c, show_exp=True, print_values=True))

                x += 1

        end = int(round(time.time() * 1000))
Exemple #11
0
    def create_diagnostics(self, active_randsets) -> str:

        btor = Boolector()
        btor.Set_opt(pyboolector.BTOR_OPT_INCREMENTAL, True)
        btor.Set_opt(pyboolector.BTOR_OPT_MODEL_GEN, True)
        model_valid = False

        diagnostic_constraint_l = []
        diagnostic_field_l = []

        # First, determine how many randsets are actually failing
        i = 0
        while i < len(active_randsets):
            rs = active_randsets[i]
            for f in rs.all_fields():
                f.build(btor)

            # Assume that we can omit all soft constraints, since they
            # will have already been omitted (?)
            constraint_l = list(
                map(
                    lambda c: (c, c.build(btor)),
                    filter(lambda c: not isinstance(c, ConstraintSoftModel),
                           rs.constraints())))

            for c in constraint_l:
                btor.Assume(c[1])

            if btor.Sat() != btor.SAT:
                # Save fields and constraints if the randset doesn't
                # solve on its own
                diagnostic_constraint_l.extend(constraint_l)
                diagnostic_field_l.extend(rs.fields())

            i += 1

        problem_sets = []
        degree = 1

        while True:
            init_size = len(diagnostic_constraint_l)
            tmp_l = []

            ret = self._collect_failing_constraints(btor,
                                                    diagnostic_constraint_l, 0,
                                                    degree, tmp_l,
                                                    problem_sets)

            if len(diagnostic_constraint_l) == init_size and degree > 3:
                break
            else:
                degree += 1

        if Randomizer.EN_DEBUG > 0:
            print("%d constraints remaining ; %d problem sets" %
                  (len(diagnostic_constraint_l), len(problem_sets)))

        # Assert the remaining constraints
        for c in diagnostic_constraint_l:
            btor.Assert(c[1])

        if btor.Sat() != btor.SAT:
            raise Exception("internal error: system should solve")

        # Okay, we now have a constraint system that solves, and
        # a list of constraints that are a problem. We want to
        # resolve the value of all variables referenced by the
        # solving constraints so and then display the non-solving
        # constraints. This will (hopefully) help highlight the
        # reason for the failure

        ret = ""
        for ps in problem_sets:
            ret += ("Problem Set: %d constraints\n" % len(ps))
            for pc in ps:
                ret += "  %s:\n" % SourceInfo.toString(pc[0].srcinfo)
                ret += "    %s" % ModelPrettyPrinter.print(pc[0],
                                                           print_values=False)

            pc = []
            for c in ps:
                pc.append(c[0])

            lint_r = LintVisitor().lint([], pc)

            if lint_r != "":
                ret += "Lint Results:\n" + lint_r

        for rs in active_randsets:
            for f in rs.all_fields():
                f.dispose()

        return ret
Exemple #12
0
import os
import pyboolector
from pyboolector import Boolector, BoolectorException

if __name__ == "__main__":
    try:
        # Create Boolector instance
        btor = Boolector()
        # Enable model generation
        btor.Set_opt(pyboolector.BTOR_OPT_MODEL_GEN, True)
        # Create bit-vector sort of size 8
        bvsort8 = btor.BitVecSort(8)
        # Create expressions
        x = btor.Var(bvsort8, "x")
        y = btor.Var(bvsort8, "y")
        zero = btor.Const(0, 8)
        hundred = btor.Const(100, 8)
        # 0 < x
        ult_x = btor.Ult(zero, x)
        btor.Assert(ult_x)
        # x <= 100
        ulte_x = btor.Ulte(x, hundred)
        btor.Assert(ulte_x)
        # 0 < y
        ult_y = btor.Ult(zero, y)
        btor.Assert(ult_y)
        # y <= 100
        ulte_y = btor.Ulte(y, hundred)
        btor.Assert(ulte_y)
        # x * y
        mul = btor.Mul(x, y)
Exemple #13
0
import sys
from pyboolector import Boolector

if __name__ == '__main__':
    f_in = open(sys.argv[1], 'r')
    f_out = open('check', 'w')
    for line in f_in:
        if line[:7] != '(assert':
            f_out.write(line)
        else:
            f_out.write('(assert (xor (\n')
    f_in = open(sys.argv[2], 'r')
    for line in f_in:
        f_out.write(line)
    f_out.write('))')
    f_in.close()
    f_out.close()

    btor = Boolector()
    (res, status, error_msg) = btor.Parse('check')
    result = btor.Sat()
    if result != btor.SAT:
        print(sys.argv[1] + ': PASS')
    else:
        print(sys.argv[1] + ': NOT PASS')