def test_fresh_const_name(self):
     ctx = SolverContext(z3.Context())
     name1 = ctx.fresh_constraint_name()
     name2 = ctx.fresh_constraint_name()
     self.assertTrue(isinstance(name1, basestring))
     self.assertTrue(isinstance(name2, basestring))
     self.assertFalse(name1 == name2)
 def test_create_var_prefix(self):
     # Arrange
     ctx = SolverContext(z3.Context())
     prefix = 'CustPrefix'
     # Act
     var = ctx.create_fresh_var(z3.IntSort(), value=10, name_prefix=prefix)
     # Assert
     self.assertTrue(isinstance(var, SMTVar))
     self.assertTrue(var.name.startswith(prefix))
 def test_get_constraints(self):
     var1 = SMTVar('var1', z3.IntSort())
     var2 = SMTVar('var1', z3.IntSort())
     const = var1.var + var2.var > 10
     name = 'cosnt1'
     ctx = SolverContext(z3.Context())
     ctx.register_constraint(const, name)
     self.assertIsNotNone(ctx.get_constraint(name))
     self.assertIsNotNone(ctx.get_constraints_info(name))
     with self.assertRaises(ValueError):
         ctx.get_constraint('NotRegistered')
     with self.assertRaises(ValueError):
         ctx.get_constraints_info('NotRegistered')
 def test_fresh_const_name_prefix(self):
     # Arrange
     ctx = SolverContext(z3.Context())
     prefix = 'CustPrefix'
     # Act
     name1 = ctx.fresh_constraint_name(prefix=prefix)
     name2 = ctx.fresh_constraint_name(prefix=prefix)
     # Assert
     self.assertTrue(isinstance(name1, basestring))
     self.assertTrue(isinstance(name2, basestring))
     self.assertFalse(name1 == name2)
     self.assertTrue(name1.startswith(prefix))
     self.assertTrue(name2.startswith(prefix))
 def test_read(self):
     concrete_anns = self.get_anns()
     ctx = SolverContext.create_context(concrete_anns)
     sym_anns = read_announcements(concrete_anns, ctx)
     self.assertEqual(len(sym_anns), len(concrete_anns))
     for sym_ann, con_ann in zip(sym_anns, concrete_anns):
         for attr in Announcement.attributes:
             if attr == 'communities':
                 for community in con_ann.communities:
                     con_val = con_ann.communities[community]
                     sym_val = sym_ann.communities[community]
                     if is_empty(con_val):
                         self.assertFalse(sym_val.is_concrete)
                     else:
                         self.assertTrue(sym_val.is_concrete)
                         self.assertEquals(sym_val.get_value(), con_val)
                 continue
             con_val = getattr(con_ann, attr)
             sym_val = getattr(sym_ann, attr)
             if is_empty(con_val):
                 self.assertFalse(sym_val.is_concrete)
             else:
                 self.assertTrue(sym_val.is_concrete)
                 if attr == 'as_path':
                     con_val = get_as_path_key(con_val)
                 sym_val_concrete = sym_val.get_value()
                 if attr == 'origin':
                     sym_val_concrete = BGP_ATTRS_ORIGIN.__members__[
                         sym_val_concrete]
                 self.assertEquals(sym_val_concrete, con_val)
 def test_create(self):
     # Arrange
     concrete_anns = self.get_anns()
     ctx = SolverContext.create_context(concrete_anns)
     # Act
     sym_anns = read_announcements(concrete_anns, ctx)
     # Assert
     self.assertEquals(len(sym_anns), 2)
 def test_compare_enum_type(self):
     # Arrange
     values = ['A', 'B', 'C']
     sort_name = 'TestType'
     ctx = SolverContext(z3.Context())
     solver = z3.Solver(ctx=ctx.z3_ctx)
     vsort = ctx.create_enum_type(sort_name, values)
     A, B, C = [vsort.get_symbolic_value(x) for x in values]
     GREATER, LESS, EQUAL, INCOMPLETE = ctx.compare_vars
     # Act
     func = ctx.create_enum_compare(sort_name)
     solver.add(func(A, A) == EQUAL)
     solver.add(func(A, B) == GREATER)
     solver.add(func(A, C) == GREATER)
     solver.add(func(B, B) == EQUAL)
     solver.add(func(C, C) == EQUAL)
     # Assert
     ret = ctx.check(solver)
     self.assertEquals(ret, z3.sat)
Exemple #8
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def create_context(reqs, g, announcements, create_as_paths=False):
    connected = ConnectedSyn([], g, full=True)
    connected.synthesize()
    next_hops_map = compute_next_hop_map(g)
    next_hops = extract_all_next_hops(next_hops_map)
    peers = [node for node in g.routers_iter() if g.is_bgp_enabled(node)]
    ctx = SolverContext.create_context(announcements,
                                       peer_list=peers,
                                       next_hop_list=next_hops,
                                       create_as_paths=create_as_paths)
    return ctx
 def test_sub(self):
     # Arrange
     concrete_anns = self.get_anns()
     ctx = SolverContext.create_context(concrete_anns)
     sym_anns = read_announcements(concrete_anns, ctx)
     mutator = self
     # Act
     new_anns = sym_anns.create_new([sym_anns[0]], mutator)
     new_anns2 = new_anns.create_new([new_anns[0]], mutator)
     self.assertEquals(len(sym_anns), 2)
     self.assertEquals(len(new_anns), 1)
     self.assertEquals(len(new_anns2), 1)
     self.assertEquals(sym_anns.mutators, [])
     self.assertEquals(new_anns.mutators, [mutator])
     self.assertEquals(new_anns2.mutators, [mutator, mutator])
 def test_register_const(self):
     # Arrange
     var1 = SMTVar('var1', z3.IntSort())
     var2 = SMTVar('var1', z3.IntSort())
     const = var1.var + var2.var > 10
     # Act
     ctx = SolverContext(z3.Context())
     name = ctx.register_constraint(const)
     with self.assertRaises(ValueError):
         ctx.register_constraint(const, name)
     constraints = list(ctx.constraints_itr())
     # Assert
     self.assertIsNotNone(ctx.get_constraint(name))
     self.assertIsNotNone(ctx.get_constraints_info(name))
     self.assertEquals(len(constraints), 1)
     self.assertEquals(constraints[0][0], name)
     self.assertEquals(constraints[0][1], const)
    def test_register_var(self):
        name = 'TestVar1'
        vsort = z3.IntSort()
        var = SMTVar(name, vsort)

        ctx = SolverContext(z3.Context())
        ctx._register_var(var)
        self.assertTrue(var.name in ctx._vars)
        with self.assertRaises(ValueError):
            ctx._register_var(var)
 def create_context(self, reqs, g):
     connected = ConnectedSyn(reqs, g, full=True)
     connected.synthesize()
     next_hops_map = compute_next_hop_map(g)
     next_hops = extract_all_next_hops(next_hops_map)
     peers = [node for node in g.routers_iter() if g.is_bgp_enabled(node)]
     anns = self.get_anns()
     for ann in anns:
         g.add_bgp_advertise(node=ann.peer,
                             announcement=ann,
                             loopback='lo0')
     ctx = SolverContext.create_context(anns,
                                        next_hop_list=next_hops,
                                        peer_list=peers,
                                        create_as_paths=False)
     return ctx
 def test_create_enum_type(self):
     # Arrange
     values = ['A', 'B', 'C']
     sort_name = 'TestType'
     ctx = SolverContext(z3.Context())
     # Act
     vsort = ctx.create_enum_type(sort_name, values)
     # Assert
     self.assertTrue(isinstance(vsort, EnumType))
     self.assertEquals(vsort.name, sort_name)
     self.assertEquals(vsort.concrete_values, values)
     with self.assertRaises(ValueError):
         ctx.create_enum_type(sort_name, values)
     with self.assertRaises(ValueError):
         ctx.create_enum_type("name2", values)
Exemple #14
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 def _create_context(self, create_as_paths=False):
     """
     Create the context to hold symbolic variables used in BGP synthesis
     :param create_as_paths:
     :return: SolverContext
     """
     next_hops_map = compute_next_hop_map(self.topo)
     next_hops = extract_all_next_hops(next_hops_map)
     peers = [
         node for node in self.topo.routers_iter()
         if self.topo.is_bgp_enabled(node)
     ]
     print "PEER", peers
     print "NEXTHOPS", next_hops
     ctx = SolverContext.create_context(self.announcements,
                                        peer_list=peers,
                                        next_hop_list=next_hops,
                                        create_as_paths=create_as_paths)
     return ctx
 def test_set_model(self):
     # Arrange
     values = ['A', 'B', 'C']
     sort_name = 'TestType'
     ctx = SolverContext(z3.Context())
     vsort = ctx.create_enum_type(sort_name, values)
     var1 = ctx.create_fresh_var(vsort)
     val1 = vsort.get_symbolic_value('A')
     var2 = ctx.create_fresh_var(z3.IntSort(ctx=ctx.z3_ctx))
     var3 = ctx.create_fresh_var(z3.BoolSort(ctx=ctx.z3_ctx))
     solver = z3.Solver(ctx=ctx.z3_ctx)
     solver.add(var1.var == val1)
     solver.add(var2.var == 10)
     solver.add(var3.var == True)
     solver.check()
     # Act
     ctx.set_model(solver.model())
     # Assert
     self.assertTrue(var1.is_concrete)
     self.assertTrue(var2.is_concrete)
     self.assertTrue(var3.is_concrete)
     self.assertEquals(var1.get_value(), 'A')
     self.assertEquals(var2.get_value(), 10)
     self.assertEquals(var3.get_value(), True)
 def test_create_var(self):
     ctx = SolverContext(z3.Context())
     var = ctx.create_fresh_var(z3.IntSort(), value=10)
     self.assertTrue(isinstance(var, SMTVar))
     with self.assertRaises(ValueError):
         var = ctx.create_fresh_var(z3.IntSort(), name=var.name, value=10)