class TestConsistent:
p_small_weight = Comparison(
content="the amount of gold $person possessed was",
sign="<",
expression=Q_("1 gram"),
)
p_large_weight = Comparison(
content="the amount of gold $person possessed was",
sign=">=",
expression=Q_("100 kilograms"),
)
small = Fact(predicate=p_large_weight, terms=Entity(name="Alice"))
big = Fact(predicate=p_small_weight, terms=Entity(name="Bob"))
def test_contradictory_facts_about_same_entity(self):
register = ContextRegister()
register.insert_pair(Entity(name="Alice"), Entity(name="Bob"))
assert not self.small.consistent_with(self.big, register)
explanations = list(
self.small.explanations_consistent_with(self.big,
context=register))
assert not explanations
def test_factor_consistent_with_none(self):
assert self.small.consistent_with(None)
def test_compare_intervals_different_units(self):
miles = Comparison(
content="the distance was", sign="<", expression=Q_("30 miles")
)
kilos = Comparison(
content="the distance was", sign="<", expression=Q_("40 kilometers")
)
assert kilos.quantity_range.implies(miles.quantity_range)
def test_no_contradiction_exact_different_unit(self):
acres = Comparison(
content="the size of the farm was", sign=">", expression=Q_("20 acres")
)
kilometers = Comparison(
content="the size of the farm was",
sign="=",
expression=Q_("100 square kilometers"),
)
assert not acres.contradicts(kilometers)
def test_predicate_not_same_with_interchangeable_terms(self):
interchangeable = Comparison(
content="the distance between $place1 and $place2 was",
sign="<",
expression=Q_("20 feet"),
)
not_interchangeable = Comparison(
content="the distance between $west and $east was",
sign="<",
expression=Q_("20 feet"),
)
assert not interchangeable.means(not_interchangeable)
def test_does_not_exclude_other_quantity(self):
comparison = Comparison(
content="the distance between $place1 and $place2 was",
sign=">",
expression=Q_("20 miles"),
)
comparison_opposite = Comparison(
content="the distance between $place1 and $place2 was",
sign="<",
expression=Q_("30 miles"),
)
left = comparison.quantity_range
right = comparison_opposite.quantity_range
assert left.contradicts(right.interval) is False
def test_convert_quantity_of_Comparison(self):
comparison = Comparison(
content="the distance between $place1 and $place2 was",
sign=">",
expression=Q_("20 miles"),
)
comparison_km = Comparison(
content="the distance between $place1 and $place2 was",
sign=">",
expression=Q_("30 kilometers"),
)
result = comparison.quantity_range.get_unit_converted_interval(
comparison_km.quantity_range
)
assert 18 < result.left < 19
def test_comparison_with_wrong_comparison_symbol(self):
with pytest.raises(ValueError):
_ = Comparison(
content="the height of {} was {}",
sign=">>",
expression=Q_("160 centimeters"),
)
def test_content_not_ending_with_was(self):
with pytest.raises(ValueError):
Comparison(
content="$person drove for",
sign=">=",
expression=Q_("20 miles"),
)
def test_no_contradiction_between_classes(self):
left = UnitRange(quantity=Q_("2000 days"), sign="<")
right = IntRange(quantity=2000, sign=">")
assert right.q == 2000
assert right.domain == S.Naturals0
assert str(right) == "greater than 2000"
assert left.magnitude == right.magnitude
assert not left.contradicts(right)
def test_comparison_interval(self):
comparison = Comparison(
content="the distance between $place1 and $place2 was",
sign=">",
expression=Q_("20 miles"),
)
assert comparison.interval == Interval(20, oo, left_open=True)
assert "quantity='20 mile'" in repr(comparison)
def test_factor_different_predicate_truth_contradicts(self):
predicate = Comparison(
content="the distance between $place1 and $place2 was",
sign=">",
expression=Q_("30 miles"),
)
predicate_opposite = Comparison(
content="the distance between $place1 and $place2 was",
sign="<",
expression=Q_("30 miles"),
)
terms = [Entity(name="New York"), Entity(name="Los Angeles")]
fact = Fact(predicate=predicate, terms=terms)
fact_opposite = Fact(predicate=predicate_opposite, terms=terms)
assert fact.contradicts(fact_opposite)
assert fact_opposite.contradicts(fact)
def test_dump_to_dict_with_units(self):
predicate = Comparison(
content="the distance between $place1 and $place2 was",
truth=True,
sign="<>",
expression=Q_("35 feet"),
)
dumped = predicate.dict()
assert dumped["quantity_range"]["quantity"] == "35 foot"
def test_comparison_not_equal(self):
comparison = Comparison(
content="the distance between $place1 and $place2 was",
sign="!=",
expression=Q_("20 miles"),
)
assert comparison.interval == sympy.Union(
Interval(0, 20, right_open=True), Interval(20, oo, left_open=True)
)
def test_absences_of_contradictory_facts_consistent(self):
predicate = Comparison(
content="the distance between $place1 and $place2 was",
sign=">",
expression=Q_("30 miles"),
)
predicate_opposite = Comparison(
content="the distance between $place1 and $place2 was",
sign="<",
expression=Q_("30 miles"),
)
terms = [Entity(name="New York"), Entity(name="Los Angeles")]
fact = Fact(predicate=predicate, terms=terms, absent=True)
fact_opposite = Fact(predicate=predicate_opposite,
terms=terms,
absent=True)
assert not fact.contradicts(fact_opposite)
assert not fact_opposite.contradicts(fact)
def test_broader_absent_factor_contradicts_quantity_statement(self):
predicate_less = Comparison(
content="${vehicle}'s speed was",
sign=">",
expression=Q_("30 miles per hour"),
)
predicate_more = Comparison(
content="${vehicle}'s speed was",
sign=">",
expression=Q_("60 miles per hour"),
)
terms = [Entity(name="the car")]
absent_general_fact = Fact(predicate=predicate_less,
terms=terms,
absent=True)
specific_fact = Fact(predicate=predicate_more, terms=terms)
assert absent_general_fact.contradicts(specific_fact)
assert specific_fact.contradicts(absent_general_fact)
def test_no_contradiction_with_more_specific_absent(self):
predicate_less = Comparison(
content="${vehicle}'s speed was",
sign="<",
expression=Q_("30 miles per hour"),
)
predicate_more = Comparison(
content="${vehicle}'s speed was",
sign="<",
expression=Q_("60 miles per hour"),
)
terms = [Entity(name="the car")]
general_fact = Fact(predicate=predicate_more, terms=terms)
absent_specific_fact = Fact(predicate=predicate_less,
terms=terms,
absent=True)
assert not general_fact.contradicts(absent_specific_fact)
assert not absent_specific_fact.contradicts(general_fact)
def test_factor_implies_because_of_quantity(self, make_statement):
meters = Comparison(
content="the distance between $place1 and $place2 was",
sign=">=",
expression=Q_("10 meters"),
)
left = Statement(predicate=meters,
terms=[Entity(name="Al"),
Entity(name="Bob")])
more = Comparison(
content="the distance between $place1 and $place2 was",
truth=True,
sign=">",
expression=Q_("30 feet"),
)
right = Statement(predicate=more,
terms=[Entity(name="Al"),
Entity(name="Bob")])
assert left > right
class TestAddition:
predicate_less = Comparison(
content="${vehicle}'s speed was",
sign=">",
expression=Q_("30 miles per hour"),
)
predicate_more = Comparison(
content="${vehicle}'s speed was",
sign=">=",
expression=Q_("60 miles per hour"),
)
general_fact = Fact(predicate=predicate_less, terms=Entity(name="the car"))
specific_fact = Fact(predicate=predicate_more,
terms=Entity(name="the motorcycle"))
def test_addition_returns_broader_operand(self):
answer = self.specific_fact + self.general_fact
assert answer.means(self.specific_fact)
def test_addition_uses_terms_from_left(self):
answer = self.general_fact + self.specific_fact
assert "<the car>" in str(answer)
def test_add_unrelated_factors(self):
murder = Fact(
predicate=Predicate(content="$person committed a murder"),
terms=Entity(name="Al"),
)
crime = Fact(
predicate=Predicate(content="$person committed a crime"),
terms=Entity(name="Al"),
)
assert murder + crime is None
def test_union_with_string_fails(self):
murder = Fact(
predicate=Predicate(content="$person committed a murder"),
terms=Entity(name="Al"),
)
with pytest.raises(TypeError):
murder | "a string"
def test_convert_false_statement_about_quantity_to_obverse(self):
distance = Comparison(
content="the distance between $place1 and $place2 was",
truth=False,
sign=">",
expression=Q_("35 feet"),
)
assert distance.truth is True
assert distance.sign == "<="
assert isinstance(distance.quantity, Quantity)
assert str(distance.quantity) == "35 foot"
def test_inconsistent_statements_about_different_entities(self):
"""
Alice and Bob are both generics. So it's possible to reach a
contradiction if you assume they correspond to one another.
"""
p_small_weight = Comparison(
content="the amount of gold $person possessed was",
sign="<",
expression=Q_("1 gram"),
)
p_large_weight = Comparison(
content="the amount of gold $person possessed was",
sign=">=",
expression=Q_("100 kilograms"),
)
alice = Entity(name="Alice")
bob = Entity(name="Bob")
alice_rich = Statement(predicate=p_large_weight, terms=alice)
bob_poor = Statement(predicate=p_small_weight, terms=bob)
assert alice_rich.contradicts(bob_poor)
def test_is_beard_implied(
self,
facial_hair_over_5mm,
facial_hair_on_or_below_chin,
facial_hair_uninterrupted,
outcome,
fake_beard_client,
make_beard_rule,
):
beard = Entity(name="a facial feature")
sec_4 = fake_beard_client.read("/test/acts/47/4/")
was_facial_hair = Predicate(content="$thing was facial hair")
fact_was_facial_hair = Fact(predicate=was_facial_hair, terms=beard)
hypothetical = Rule(
procedure=Procedure(
inputs=[
fact_was_facial_hair,
Fact(
predicate=Comparison(
content="the length of $thing was",
sign=">=",
expression=Q_("5 millimeters"),
truth=facial_hair_over_5mm,
),
terms=beard,
),
Fact(
predicate=Predicate(
content="$thing occurred on or below the chin",
truth=facial_hair_on_or_below_chin,
),
terms=beard,
),
Fact(
predicate=Predicate(
content=
"$thing existed in an uninterrupted line from the front "
"of one ear to the front of the other ear below the nose",
truth=facial_hair_uninterrupted,
),
terms=beard,
),
],
outputs=Fact(predicate=Predicate(content="$thing was a beard"),
terms=beard),
),
enactments=sec_4,
)
meets_chin_test = make_beard_rule[0].implies(hypothetical)
meets_ear_test = make_beard_rule[1].implies(hypothetical)
assert outcome == meets_chin_test or meets_ear_test
def test_cannot_convert_date_to_time_period(self):
time = Comparison(
content="the time $object took to biodegrade was",
sign=">",
expression=Q_("2000 years"),
)
day = Comparison(
content="the day was",
sign="=",
expression=date(2020, 1, 1),
)
with pytest.raises(TypeError):
time.quantity_range.get_unit_converted_interval(day.quantity_range)
def test_inconsistent_statements_about_corresponding_entities(self):
"""
Even though Alice and Bob are both generics, it's known that
Alice in the first context corresponds with Alice in the second.
So there's no contradiction.
"""
p_small_weight = Comparison(
content="the amount of gold $person possessed was",
sign="<",
expression=Q_("1 gram"),
)
p_large_weight = Comparison(
content="the amount of gold $person possessed was",
sign=">=",
expression=Q_("100 kilograms"),
)
alice = Entity(name="Alice")
bob = Entity(name="Bob")
alice_rich = Statement(predicate=p_large_weight, terms=alice)
bob_poor = Statement(predicate=p_small_weight, terms=bob)
register = ContextRegister()
register.insert_pair(alice, alice)
assert not alice_rich.contradicts(bob_poor, context=register)
def test_inconsistent_dimensionality_quantity(self):
number = Comparison(
content="the distance between $place1 and $place2 was",
sign=">",
expression=20,
)
distance = Comparison(
content="the distance between $place1 and $place2 was",
sign=">",
expression=Q_("20 miles"),
)
assert not number.quantity_range.consistent_dimensionality(
distance.quantity_range
)
assert not distance.quantity_range.consistent_dimensionality(
number.quantity_range
)
def make_comparison() -> Dict[str, Predicate]:
return {
"small_weight": Comparison(
content="the amount of gold $person possessed was",
sign=">=",
expression=Q_("1 gram"),
),
"large_weight": Comparison(
content="the amount of gold $person possessed was",
sign=">=",
expression=Q_("100 kilograms"),
),
"quantity=3": Comparison(
content="The number of mice was", sign="==", expression=3
),
"quantity>=4": Comparison(
content="The number of mice was", sign=">=", expression=4
),
"quantity>5": Comparison(
content="The number of mice was", sign=">", expression=5
),
"acres": Comparison(
content="the distance between $place1 and $place2 was",
sign=">=",
expression=Q_("10 acres"),
),
"exact": Comparison(
content="the distance between $place1 and $place2 was",
sign="==",
expression=Q_("25 feet"),
),
"float_distance": Comparison(
content="the distance between $place1 and $place2 was",
truth=True,
sign="<",
expression=20.0,
),
"higher_int": Comparison(
content="the distance between $place1 and $place2 was",
sign="<=",
expression=30,
),
"int_distance": Comparison(
content="the distance between $place1 and $place2 was",
truth=True,
sign="<",
expression=20,
),
"int_higher": Comparison(
content="the distance between $place1 and $place2 was",
sign="<=",
expression=30,
),
"less": Comparison(
content="the distance between $place1 and $place2 was",
truth=True,
sign="<",
expression=Q_("35 feet"),
),
"less_whether": Comparison(
content="the distance between $place1 and $place2 was",
truth=None,
sign="<",
expression=Q_("35 feet"),
),
"less_than_20": Comparison(
content="the distance between $place1 and $place2 was",
truth=True,
sign="<",
expression=Q_("20 feet"),
),
"meters": Comparison(
content="the distance between $place1 and $place2 was",
sign=">=",
expression=Q_("10 meters"),
),
"not_equal": Comparison(
content="the distance between $place1 and $place2 was",
truth=True,
sign="!=",
expression=Q_("35 feet"),
),
"more": Comparison(
content="the distance between $place1 and $place2 was",
truth=True,
sign=">=",
expression=Q_("35 feet"),
),
"not_more": Comparison(
content="the distance between $place1 and $place2 was",
truth=False,
sign=">",
expression=Q_("35 feet"),
),
"way_more": Comparison(
content="the distance between $place1 and $place2 was",
truth=True,
sign=">=",
expression=Q_("30 miles"),
),
}
class TestProcedureUnion:
def test_simple_union(self, make_opinion_with_holding):
feist = make_opinion_with_holding["feist_majority"]
procedure_from_union = feist.holdings[0].procedure | feist.holdings[2].procedure
procedure_from_adding = (
feist.holdings[0].procedure + feist.holdings[2].procedure.inputs[0]
)
assert procedure_from_union.means(procedure_from_adding)
p_small_weight = Comparison(
content="the amount of gold $person possessed was",
sign="<",
expression=Q_("1 gram"),
)
p_large_weight = Comparison(
content="the amount of gold $person possessed was",
sign=">=",
expression=Q_("100 kilograms"),
)
alice = Entity(name="Alice")
bob = Entity(name="Bob")
craig = Entity(name="Craig")
dan = Entity(name="Dan")
alice_rich = Fact(predicate=p_large_weight, terms=alice)
bob_poor = Fact(predicate=p_small_weight, terms=bob)
craig_rich = Fact(predicate=p_large_weight, terms=craig)
dan_poor = Fact(predicate=p_small_weight, terms=dan)
def test_unitregistry_imports_do_not_conflict(self, make_comparison):
left = UnitRange(quantity=Q_("20 meters"), sign=">")
right = make_comparison["meters"].quantity_range
assert left.implies(right)
assert left.pint_quantity == Q_("20 meters")
