Exemplo n.º 1
0
    def test_constructor_full(self):
        eprint(
            ">> Continuum.__init__(self, min_value=None, max_value=None, min_included=None, max_included=None)"
        )

        for i in range(self.__nb_unit_test):

            # Valid continuum
            #-----------------
            min = random.uniform(self.__min_value, self.__max_value)
            max = random.uniform(min, self.__max_value)
            min_included = random.choice([True, False])
            max_included = random.choice([True, False])

            c = Continuum(min, max, min_included, max_included)

            self.assertFalse(c.is_empty())
            self.assertEqual(c.get_min_value(), min)
            self.assertEqual(c.get_max_value(), max)
            self.assertEqual(c.min_included(), min_included)
            self.assertEqual(c.max_included(), max_included)

            # Implicit emptyset
            #-------------------
            min = random.uniform(self.__min_value, self.__max_value)

            c = Continuum(min, min, False, False)

            self.assertTrue(c.is_empty())
            self.assertEqual(c.get_min_value(), None)
            self.assertEqual(c.get_max_value(), None)
            self.assertEqual(c.min_included(), None)
            self.assertEqual(c.max_included(), None)

            # Invalid Continuum
            #--------------------
            max = random.uniform(self.__min_value, min - 0.001)

            self.assertRaises(ValueError, Continuum, min, max, min_included,
                              max_included)

            # Invalid number of arguments
            #-------------------------------

            self.assertRaises(ValueError, Continuum, min)
            self.assertRaises(ValueError, Continuum, min, max)
            self.assertRaises(ValueError, Continuum, min, max, min_included)
            self.assertRaises(ValueError, Continuum, min, max, min_included,
                              max_included)
Exemplo n.º 2
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    def test_to_string(self):
        eprint(">> Continuum.to_string(self)")

        for i in range(self.__nb_unit_test):
            c = Continuum()

            self.assertEqual(c.to_string(), u"\u2205")

            c = Continuum.random(self.__min_value, self.__max_value)

            if c.is_empty():
                self.assertEqual(c.to_string(), u"\u2205")

            out = ""

            if c.min_included():
                out += "["
            else:
                out += "]"

            out += str(c.get_min_value()) + "," + str(c.get_max_value())

            if c.max_included():
                out += "]"
            else:
                out += "["

            self.assertEqual(c.to_string(), out)
            self.assertEqual(c.__str__(), out)
            self.assertEqual(c.__repr__(), out)
Exemplo n.º 3
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    def test_constructor_empty(self):
        eprint(">> Continuum.__init__(self)")

        for i in range(self.__nb_unit_test):
            c = Continuum()

            self.assertTrue(c.is_empty())
            self.assertEqual(c.get_min_value(), None)
            self.assertEqual(c.get_max_value(), None)
            self.assertEqual(c.min_included(), None)
            self.assertEqual(c.max_included(), None)
Exemplo n.º 4
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    def test_size(self):
        eprint(">> Continuum.size(self)")

        for i in range(self.__nb_unit_test):

            # empty set
            c = Continuum()
            self.assertEqual(c.size(), 0.0)

            # regular
            c = Continuum.random(self.__min_value, self.__max_value)

            if not c.is_empty():
                self.assertEqual(c.size(),
                                 c.get_max_value() - c.get_min_value())
Exemplo n.º 5
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    def least_revision(rule, state_1, state_2):
        """
        Compute the least revision of rule w.r.t. the transition (state_1, state_2)

        Agrs:
            rule: ContinuumRule
            state_1: list of float
            state_2: list of float

        Returns: list of ContinuumRule
            The least generalisation of the rule over its conclusion and
            the least specializations of the rule over each condition
        """

        # 0) Check Consistence
        #----------------------

        #Consistent rule
        if not rule.matches(state_1):
            raise ValueError(
                "Attempting to revise a consistent rule, revision would be itself, this call is useless in ACEDIA and must be an error"
            )

        # Consistent rule
        if rule.get_head_value().includes(state_2[rule.get_head_variable()]):
            raise ValueError(
                "Attempting to revise a consistent rule, revision would be itself, this call is useless in ACEDIA and must be an error"
            )

        # 1) Revise conclusion
        #----------------------
        head_var = rule.get_head_variable()
        next_value = state_2[head_var]
        revisions = []

        head_revision = rule.copy()
        head_value = head_revision.get_head_value()

        # Empty set head case
        if head_value.is_empty():
            head_value = Continuum(next_value, next_value, True, True)
        elif next_value <= head_value.get_min_value():
            head_value.set_lower_bound(next_value, True)
        else:
            head_value.set_upper_bound(next_value, True)

        head_revision.set_head_value(head_value)

        revisions.append(head_revision)

        # 2) Revise each condition
        #---------------------------
        for var, val in rule.get_body():
            state_value = state_1[var]

            # min revision
            min_revision = rule.copy()
            new_val = val.copy()
            new_val.set_lower_bound(state_value, False)
            if not new_val.is_empty():
                min_revision.set_condition(var, new_val)
                revisions.append(min_revision)

            # max revision
            max_revision = rule.copy()
            new_val = val.copy()
            new_val.set_upper_bound(state_value, False)
            if not new_val.is_empty():
                max_revision.set_condition(var, new_val)
                revisions.append(max_revision)

        return revisions
Exemplo n.º 6
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    def test_set_upper_bound(self):
        eprint(">> Continuum.set_upper_bound(self, value, included)")

        for i in range(self.__nb_unit_test):
            # Empty set
            c = Continuum()

            self.assertRaises(TypeError, c.set_upper_bound, "string", True)
            self.assertRaises(TypeError, c.set_upper_bound, "string", False)
            self.assertRaises(TypeError, c.set_upper_bound, 0.5, 10)

            value = random.uniform(self.__min_value, self.__max_value)

            # extend with exclusion gives empty set, mistake expected from user
            # or both min and max will be changed and constructor must be used
            self.assertRaises(ValueError, c.set_upper_bound, value, False)

            c.set_upper_bound(value, True)

            # Empty set to one value interval
            self.assertEqual(c, Continuum(value, value, True, True))

            # Regular continuum

            # over min value
            c = Continuum.random(self.__min_value, self.__max_value)
            value = random.uniform(self.__min_value, c.get_min_value())
            while value == c.get_min_value():
                value = random.uniform(self.__min_value, c.get_min_value())

            self.assertRaises(ValueError, c.set_upper_bound, value, True)
            self.assertRaises(ValueError, c.set_upper_bound, value, False)

            # on min value
            c = Continuum.random(self.__min_value, self.__max_value)
            c_old = c.copy()
            value = c.get_min_value()
            if not c.max_included() or not c.min_included():
                c.set_upper_bound(value, False)
                self.assertEqual(c,
                                 Continuum())  # continuum reduced to empty set
            else:
                c.set_upper_bound(value, True)
                self.assertEqual(c.get_max_value(), value)
                self.assertEqual(c.max_included(), True)
                self.assertEqual(c.get_max_value(), c.get_min_value())

                self.assertEqual(c.get_min_value(), c_old.get_min_value())
                self.assertEqual(c.min_included(), c_old.min_included())

            # other valid value
            c = Continuum.random(self.__min_value, self.__max_value)
            c_old = c.copy()
            value = random.uniform(c.get_min_value(), self.__max_value)
            while value == c.get_min_value():
                value = random.uniform(c.get_min_value(), self.__max_value)

            c.set_upper_bound(value, True)

            self.assertEqual(c.get_max_value(), value)
            self.assertEqual(c.max_included(), True)

            c = Continuum.random(self.__min_value, self.__max_value)
            c_old = c.copy()
            value = random.uniform(c.get_min_value(), self.__max_value)
            while value == c.get_min_value():
                value = random.uniform(c.get_min_value(), self.__max_value)

            c.set_upper_bound(value, False)

            self.assertEqual(c.get_max_value(), value)
            self.assertEqual(c.max_included(), False)
Exemplo n.º 7
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    def test__eq__(self):
        eprint(">> Continuum.__eq__(self, continuum)")

        for i in range(self.__nb_unit_test):

            # emptyset
            c = Continuum()

            self.assertTrue(Continuum() == Continuum())
            self.assertTrue(c == Continuum())
            self.assertTrue(c == c)

            self.assertFalse(Continuum() != Continuum())
            self.assertFalse(c != Continuum())
            self.assertFalse(c != c)

            c = Continuum.random(self.__min_value, self.__max_value)

            self.assertTrue(c == c)
            self.assertFalse(c != c)
            self.assertEqual(c == Continuum(), c.is_empty())

            c_ = Continuum.random(self.__min_value, self.__max_value)

            if c.is_empty() and c_.is_empty():
                self.assertTrue(c == c_)
                self.assertTrue(c != c_)

            if c.is_empty() != c_.is_empty():
                self.assertFalse(c == c_)
                self.assertTrue(c != c_)

            if c.get_min_value() != c_.get_min_value():
                self.assertFalse(c == c_)
                self.assertTrue(c != c_)

            if c.get_max_value() != c_.get_max_value():
                self.assertFalse(c == c_)
                self.assertTrue(c != c_)

            if c.min_included() != c_.min_included():
                self.assertFalse(c == c_)
                self.assertTrue(c != c_)

            if c.max_included() != c_.max_included():
                self.assertFalse(c == c_)
                self.assertTrue(c != c_)

            # exaustive modifications
            if not c.is_empty():
                c_ = c.copy()
                value = random.uniform(1, 100)
                c_.set_lower_bound(c.get_min_value() - value, True)
                self.assertFalse(c == c_)
                self.assertTrue(c != c_)
                c_.set_lower_bound(c.get_min_value() - value, False)
                self.assertFalse(c == c_)
                self.assertTrue(c != c_)

                c_ = c.copy()
                c_.set_lower_bound(c.get_min_value(), not c.min_included())
                self.assertFalse(c == c_)
                self.assertTrue(c != c_)

                c_ = c.copy()
                value = random.uniform(1, 100)
                c_.set_upper_bound(c.get_min_value() + value, True)
                self.assertFalse(c == c_)
                self.assertTrue(c != c_)
                c_.set_upper_bound(c.get_min_value() + value, False)
                self.assertFalse(c == c_)
                self.assertTrue(c != c_)

                c_ = c.copy()
                c_.set_upper_bound(c.get_max_value(), not c.max_included())
                self.assertFalse(c == c_)
                self.assertTrue(c != c_)

            # different type
            self.assertFalse(c == "test")
            self.assertFalse(c == 0)
            self.assertFalse(c == True)
            self.assertFalse(c == [])
Exemplo n.º 8
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    def test_intersects(self):
        eprint(">> Continuum.intersects(self, continuum)")

        for i in range(self.__nb_unit_test):
            c = Continuum.random(self.__min_value, self.__max_value)
            c_ = Continuum()

            # emptyset
            self.assertFalse(c.intersects(c_))
            self.assertFalse(c_.intersects(c))
            self.assertFalse(c_.intersects(c_))

            # stricly before
            c = Continuum.random(self.__min_value, self.__max_value)
            c_ = Continuum.random(c.get_min_value() - 100, c.get_min_value())
            self.assertFalse(c.intersects(c_))
            self.assertFalse(c_.intersects(c))

            # touching on lower bound
            c = Continuum.random(self.__min_value, self.__max_value)
            c_ = Continuum.random(c.get_min_value() - 100, c.get_min_value())
            c_.set_upper_bound(c.get_min_value(), True)

            self.assertEqual(c.intersects(c_), c.min_included())
            self.assertEqual(c_.intersects(c), c.min_included())

            c_.set_upper_bound(c.get_min_value(), False)

            self.assertFalse(c.intersects(c_))
            self.assertFalse(c_.intersects(c))

            # strictly after
            c = Continuum.random(self.__min_value, self.__max_value)
            c_ = Continuum.random(c.get_max_value(), c.get_max_value() + 100)
            self.assertFalse(c.intersects(c_))
            self.assertFalse(c_.intersects(c))

            # touching on lower bound
            c = Continuum.random(self.__min_value, self.__max_value)
            c_ = Continuum.random(c.get_max_value(), c.get_max_value() + 100)
            c_.set_lower_bound(c.get_max_value(), True)

            self.assertEqual(c.intersects(c_), c.max_included())
            self.assertEqual(c_.intersects(c), c.max_included())

            c_.set_lower_bound(c.get_max_value(), False)

            self.assertFalse(c.intersects(c_))
            self.assertFalse(c_.intersects(c))

            # same (not empty)
            c = Continuum.random(self.__min_value, self.__max_value)
            while c.is_empty():
                c = Continuum.random(self.__min_value, self.__max_value)
            self.assertTrue(c.includes(c))

            # smaller
            c_ = Continuum.random(c.get_min_value(), c.get_max_value())
            while c_.get_min_value() == c.get_min_value() and c_.get_max_value(
            ) == c.get_max_value():
                c_ = Continuum.random(c.get_min_value(), c.get_max_value())

            self.assertTrue(c.intersects(c_))
            self.assertTrue(c_.intersects(c))

            # bigger
            c_ = Continuum.random(c.get_min_value() - 100,
                                  c.get_max_value() + 100)
            while c_.get_min_value() >= c.get_min_value() or c_.get_max_value(
            ) <= c.get_max_value():
                c_ = Continuum.random(c.get_min_value() - 100,
                                      c.get_max_value() + 100)

            #eprint(c.to_string())
            #eprint(c_.to_string())
            self.assertTrue(c.intersects(c_))
            self.assertTrue(c_.intersects(c))
Exemplo n.º 9
0
    def test_includes(self):
        eprint(">> Continuum.includes(self, element)")

        for i in range(self.__nb_unit_test):

            # bad argument type
            c = Continuum.random(self.__min_value, self.__max_value)

            self.assertRaises(TypeError, c.includes, "test")

            # float argument
            #----------------

            # empty set includes nothing
            c = Continuum()
            value = random.uniform(self.__min_value, self.__max_value)
            self.assertFalse(c.includes(value))

            c = Continuum.random(self.__min_value, self.__max_value)

            # Before min
            value = c.get_min_value()
            while value == c.get_min_value():
                value = random.uniform(c.get_min_value() - 100.0,
                                       c.get_min_value())

            self.assertFalse(c.includes(value))

            # on min bound
            self.assertEqual(c.includes(c.get_min_value()), c.min_included())

            # Inside
            value = c.get_min_value()
            while value == c.get_min_value() or value == c.get_max_value():
                value = random.uniform(c.get_min_value(), c.get_max_value())

            self.assertTrue(c.includes(value))

            # on max bound
            self.assertEqual(c.includes(c.get_max_value()), c.max_included())

            # after max bound
            value = c.get_max_value()
            while value == c.get_max_value():
                value = random.uniform(c.get_max_value(),
                                       c.get_max_value() + 100.0)

            self.assertFalse(c.includes(value))

            # int argument
            #--------------

            # empty set includes nothing
            c = Continuum()
            value = random.randint(int(self.__min_value),
                                   int(self.__max_value))
            self.assertFalse(c.includes(value))

            c = Continuum.random(self.__min_value, self.__max_value)

            while int(c.get_max_value()) - int(c.get_min_value()) <= 1:
                min = random.uniform(self.__min_value, self.__max_value)
                max = random.uniform(min, self.__max_value)

                c = Continuum.random(min, max)

            #eprint(c.to_string())

            # Before min
            value = random.randint(int(c.get_min_value() - 100),
                                   int(c.get_min_value()) - 1)

            self.assertFalse(c.includes(value))

            # on min bound
            self.assertEqual(c.includes(c.get_min_value()), c.min_included())

            # Inside
            value = random.randint(
                int(c.get_min_value()) + 1,
                int(c.get_max_value()) - 1)

            #eprint(value)

            self.assertTrue(c.includes(value))

            # on max bound
            self.assertEqual(c.includes(c.get_max_value()), c.max_included())

            # after max bound
            value = random.randint(
                int(c.get_max_value()) + 1, int(c.get_max_value() + 100))

            self.assertFalse(c.includes(value))

            # continuum argument
            #--------------------

            # 0) c is empty set
            c = Continuum()
            c_ = Continuum()
            self.assertTrue(c.includes(c_))  # empty set VS empty set

            c_ = Continuum.random(self.__min_value, self.__max_value)
            while c_.is_empty():
                c_ = Continuum.random(self.__min_value, self.__max_value)
            self.assertFalse(c.includes(c_))  # empty set VS non empty

            # 1) c is non empty
            c = Continuum.random(self.__min_value, self.__max_value)

            self.assertTrue(c.includes(Continuum()))  # non empty VS empty set
            self.assertTrue(c.includes(c))  # includes itself

            # 1.1) Lower bound over
            c_ = Continuum.random(c.get_min_value(), self.__max_value)
            while c_.is_empty():
                c_ = Continuum.random(c.get_min_value(), self.__max_value)

            value = c.get_min_value()
            while value == c.get_min_value():
                value = random.uniform(c.get_min_value() - 100,
                                       c.get_min_value())

            c_.set_lower_bound(value, random.choice([True, False]))
            self.assertFalse(c.includes(c_))

            # 1.2) on min bound
            c_ = Continuum.random(c.get_min_value(), self.__max_value)
            while c_.is_empty():
                c_ = Continuum.random(c.get_min_value(), self.__max_value)
            c_.set_lower_bound(c.get_min_value(), random.choice([True, False]))

            if not c.min_included() and c_.min_included():  # one value over
                self.assertFalse(c.includes(c_))

            # 1.3) upper bound over
            c_ = Continuum.random(self.__min_value, c.get_max_value())
            while c_.is_empty():
                c_ = Continuum.random(self.__min_value, c.get_max_value())

            value = c.get_max_value()
            while value == c.get_max_value():
                value = random.uniform(c.get_max_value(),
                                       c.get_max_value() + 100)

            c_.set_upper_bound(value, random.choice([True, False]))

            self.assertFalse(c.includes(c_))

            # 1.4) on upper bound
            c_ = Continuum.random(self.__min_value, c.get_max_value())
            while c_.is_empty():
                c_ = Continuum.random(self.__min_value, c.get_max_value())
            c_.set_upper_bound(c.get_max_value(), random.choice([True, False]))

            if not c.max_included() and c_.max_included():  # one value over
                self.assertFalse(c.includes(c_))

            # 1.5) inside
            min = c.get_min_value()
            while min == c.get_min_value():
                min = random.uniform(c.get_min_value(), c.get_max_value())
            max = c.get_max_value()
            while max == c.get_max_value():
                max = random.uniform(min, c.get_max_value())
            c_ = Continuum(min, max, random.choice([True, False]),
                           random.choice([True, False]))

            self.assertTrue(c.includes(c_))
            self.assertFalse(c_.includes(c))
Exemplo n.º 10
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    def test_least_revision(self):
        eprint(">> ACEDIA.least_revision(rule, state_1, state_2)")

        for i in range(self.__nb_unit_test):
            variables, domains = self.random_system()

            state_1 = self.random_state(variables, domains)
            state_2 = self.random_state(variables, domains)

            # not matching
            #--------------
            rule = self.random_rule(variables, domains)
            while rule.matches(state_1):
                rule = self.random_rule(variables, domains)

            self.assertRaises(ValueError, ACEDIA.least_revision, rule, state_1,
                              state_2)

            # matching
            #--------------

            rule = self.random_rule(variables, domains)
            while not rule.matches(state_1):
                rule = self.random_rule(variables, domains)

            head_var = rule.get_head_variable()
            target_val = state_2[rule.get_head_variable()]

            # Consistent
            head_value = Continuum()
            while not head_value.includes(target_val):
                head_value = Continuum.random(
                    domains[head_var].get_min_value(),
                    domains[head_var].get_max_value())
            rule.set_head_value(head_value)
            self.assertRaises(ValueError, ACEDIA.least_revision, rule, state_1,
                              state_2)

            # Empty set head
            rule.set_head_value(Continuum())

            LR = ACEDIA.least_revision(rule, state_1, state_2)
            lg = rule.copy()
            lg.set_head_value(Continuum(target_val, target_val, True, True))
            self.assertTrue(lg in LR)

            nb_valid_revision = 1

            for var, val in rule.get_body():
                state_value = state_1[var]

                # min rev
                ls = rule.copy()
                new_val = val.copy()
                new_val.set_lower_bound(state_value, False)
                if not new_val.is_empty():
                    ls.set_condition(var, new_val)
                    self.assertTrue(ls in LR)
                    nb_valid_revision += 1

                # max rev
                ls = rule.copy()
                new_val = val.copy()
                new_val.set_upper_bound(state_value, False)
                if not new_val.is_empty():
                    ls.set_condition(var, new_val)
                    self.assertTrue(ls in LR)
                    nb_valid_revision += 1

            self.assertEqual(len(LR), nb_valid_revision)

            #eprint(nb_valid_revision)

            # usual head
            head_value = Continuum.random(domains[head_var].get_min_value(),
                                          domains[head_var].get_max_value())
            while head_value.includes(target_val):
                head_value = Continuum.random(
                    domains[head_var].get_min_value(),
                    domains[head_var].get_max_value())
            rule.set_head_value(head_value)

            LR = ACEDIA.least_revision(rule, state_1, state_2)

            lg = rule.copy()
            head_value = lg.get_head_value()
            if target_val <= head_value.get_min_value():
                head_value.set_lower_bound(target_val, True)
            else:
                head_value.set_upper_bound(target_val, True)
            lg.set_head_value(head_value)
            self.assertTrue(lg in LR)

            nb_valid_revision = 1

            for var, val in rule.get_body():
                state_value = state_1[var]

                # min rev
                ls = rule.copy()
                new_val = val.copy()
                new_val.set_lower_bound(state_value, False)
                if not new_val.is_empty():
                    ls.set_condition(var, new_val)
                    self.assertTrue(ls in LR)
                    nb_valid_revision += 1

                # max rev
                ls = rule.copy()
                new_val = val.copy()
                new_val.set_upper_bound(state_value, False)
                if not new_val.is_empty():
                    ls.set_condition(var, new_val)
                    self.assertTrue(ls in LR)
                    nb_valid_revision += 1

            self.assertEqual(len(LR), nb_valid_revision)