def to_fsm(self, alphabet=None): if alphabet is None: alphabet = self.alphabet() return reduce(lambda x, y: x | y, map(lambda x: x.to_fsm(alphabet), self.concs), fsm.null(alphabet))
def test_new_set_methods(a, b): # A whole bunch of new methods were added to the FSM module to enable FSMs to # function exactly as if they were sets of strings (symbol lists), see: # https://docs.python.org/3/library/stdtypes.html#set-types-set-frozenset # But do they work? assert len(a) == 1 assert len((a | b) * 4) == 16 try: len(a.star()) assert False except OverflowError: pass # "in" assert "a" in a assert not "a" in b assert "a" not in b # List comprehension! four = (a | b) * 2 for string in four: assert string == ["a", "a"] break assert [s for s in four] == [["a", "a"], ["a", "b"], ["b", "a"], ["b", "b"]] # set.union() imitation assert FSM.union(a, b) == a.union(b) assert len(FSM.union()) == 0 assert FSM.intersection(a, b) == a.intersection(b) # This takes a little explaining. In general, `a & b & c` is equivalent to # `EVERYTHING & a & b & c` where `EVERYTHING` is an FSM accepting every # possible string. Similarly `a` is equivalent to `EVERYTHING & a`, and the # intersection of no sets at all is... `EVERYTHING`. # However, since we compute the union of alphabets, and there are no # alphabets, the union is the empty set. So the only string which `EVERYTHING` # actually recognises is the empty string, [] (or "" if you prefer). int_none = FSM.intersection() assert len(int_none) == 1 assert [] in int_none assert (a | b).difference(a) == FSM.difference( (a | b), a) == (a | b) - a == b assert (a | b).difference(a, b) == FSM.difference( (a | b), a, b) == (a | b) - a - b == null("ab") assert a.symmetric_difference(b) == FSM.symmetric_difference(a, b) == a ^ b assert a.isdisjoint(b) assert a <= (a | b) assert a < (a | b) assert a != (a | b) assert (a | b) > a assert (a | b) >= a assert list(a.concatenate(a, a).strings()) == [["a", "a", "a"]] assert list(a.concatenate().strings()) == [["a"]] assert list(FSM.concatenate(b, a, b).strings()) == [["b", "a", "b"]] assert list(FSM.concatenate().strings()) == [] assert not a.copy() is a
def test_derive(a, b): # Just some basic tests because this is mainly a regex thing. assert a.derive("a") == epsilon({"a", "b"}) assert a.derive("b") == null({"a", "b"}) try: a.derive("c") assert False except KeyError: assert True assert (a * 3).derive("a") == a * 2 assert (a.star() - epsilon({"a", "b"})).derive("a") == a.star()
def test_builtins(): assert not null("a").accepts("a") assert epsilon("a").accepts("") assert not epsilon("a").accepts("a")
def test_alternation_a(a): altA = a | null({"a", "b"}) assert not altA.accepts("") assert altA.accepts("a")