def test_interchangeable_terms_in_factorgroup(self):
"""Fails whether the method is 'comparison' or '_verbose_comparison'"""
left = FactorGroup([
Statement(
predicate=Comparison(
content="the distance between $place1 and $place2 was",
truth=True,
sign="<=",
expression="35 foot",
),
terms=(
Entity(name="Scylla", generic=True, plural=False),
Entity(name="Charybdis", generic=True, plural=False),
),
),
Statement(
predicate=Comparison(
content=
"the distance between ${monster} and a boat used by ${hero} was",
truth=True,
sign="<=",
expression="5 foot",
),
terms=(
Entity(name="Scylla", generic=True, plural=False),
Entity(name="Ulysses", generic=True, plural=False),
),
),
])
right = FactorGroup([
Statement(
predicate=Comparison(
content="the distance between $place1 and $place2 was",
truth=True,
sign="<=",
expression="35 foot",
),
terms=(
Entity(name="Charybdis", generic=True, plural=False),
Entity(name="Scylla", generic=True, plural=False),
),
),
Statement(
predicate=Comparison(
content=
"the distance between $thing and a boat used by $person was",
truth=True,
sign="<=",
expression="5 foot",
),
terms=(
Entity(name="Scylla", generic=True, plural=False),
Entity(name="Ulysses", generic=True, plural=False),
),
),
])
gen = left.explanations_implication(right)
result = next(gen)
assert result
def test_contradiction_of_group(self):
lived_at = Predicate(content="$person lived at $residence")
bob_lived = Statement(
predicate=lived_at,
terms=[Entity(name="Bob"),
Entity(name="Bob's house")])
carl_lived = Statement(
predicate=lived_at,
terms=[Entity(name="Carl"),
Entity(name="Carl's house")])
distance_long = Comparison(
content="the distance from the center of $city to $residence was",
sign=">=",
expression="50 miles",
)
statement_long = Statement(
predicate=distance_long,
terms=[Entity(name="Houston"),
Entity(name="Bob's house")],
)
distance_short = Comparison(
content="the distance from the center of $city to $residence was",
sign="<=",
expression="10 kilometers",
)
statement_short = Statement(
predicate=distance_short,
terms=[Entity(name="El Paso"),
Entity(name="Carl's house")],
)
left = FactorGroup([bob_lived, statement_long])
right = FactorGroup([carl_lived, statement_short])
explanation = left.explain_contradiction(right)
assert explanation.context["<Houston>"].name == "El Paso"
assert contradicts(left, right)
def test_possible_context_different_terms(self):
left = Statement(predicate=self.bird, terms=Entity(name="Foghorn"))
right = Statement(predicate=self.bird, terms=Entity(name="Woody"))
contexts = list(left.possible_contexts(right))
assert len(contexts) == 1
assert contexts[0].check_match(Entity(name="Foghorn"),
Entity(name="Woody"))
def test_not_same_nonmatching_terms(self, make_statement):
left = FactorGroup([
Statement(
predicate=Predicate(content="$suburb was a suburb of $city"),
terms=(
Entity(name="Oakland"),
Entity(name="San Francisco"),
),
),
make_statement["more"],
Statement(predicate="$city was sunny",
terms=Entity(name="Oakland")),
])
right = FactorGroup([
Statement(
predicate=Predicate(content="$suburb was a suburb of $city"),
terms=(
Entity(name="San Francisco"),
Entity(name="Oakland"),
),
),
make_statement["more"],
Statement(predicate="$city was sunny",
terms=Entity(name="Oakland")),
])
assert not left.means(right)
def test_does_not_share_all_factors(self, make_statement):
left = FactorGroup([
Statement(
predicate=Predicate(content="$suburb was a suburb of $city"),
terms=(
Entity(name="Oakland"),
Entity(name="San Francisco"),
),
),
make_statement["more"],
Statement(predicate="$city was sunny",
terms=Entity(name="Oakland")),
])
right = FactorGroup([
Statement(
predicate=Predicate(content="$suburb was a suburb of $city"),
terms=(
Entity(name="San Francisco"),
Entity(name="Oakland"),
),
),
make_statement["more"],
Statement(predicate="$city was sunny",
terms=Entity(name="Oakland")),
])
assert not left.shares_all_factors_with(right)
def test_no_duplicate_explanations_consistent(self):
large_payments = FactorGroup([
Statement(
predicate=Comparison(
content=
"the number of dollars that $payer paid to $payee was",
sign=">",
expression=10000,
),
terms=[Entity(name="Alice"),
Entity(name="Bob")],
),
Statement(
predicate=Comparison(
content=
"the number of dollars that $payer paid to $payee was",
sign=">",
expression=1000,
),
terms=[Entity(name="Dan"),
Entity(name="Eve")],
),
])
small_payments = FactorGroup([
Statement(
predicate=Comparison(
content=
"the number of dollars that $payer paid to $payee was",
sign=">",
expression=100,
),
terms={
"payer": Entity(name="Fred"),
"payee": Entity(name="Greg")
},
),
Statement(
predicate=Comparison(
content=
"the number of dollars that $payer paid to $payee was",
sign=">",
expression=10,
),
terms={
"payer": Entity(name="Jim"),
"payee": Entity(name="Kim")
},
),
])
assert large_payments.consistent_with(small_payments)
all_explanations = list(
large_payments.explanations_consistent_with(small_payments))
assert len(all_explanations) == 24
limited_explanations = list(
large_payments.explanations_consistent_with(
small_payments,
context=([Entity(name="Alice")], [Entity(name="Jim")])))
assert len(limited_explanations) == 6
def test_entity_does_not_imply_statement(self):
entity = Entity(name="Bob")
statement = Statement(predicate="$person loves ice cream", terms=entity)
assert not entity.implies(statement)
assert not statement.implies(entity)
assert not entity >= statement
assert not statement >= entity
assert not entity > statement
assert not statement > entity
def test_all_possible_contexts_identical_factor(self):
left = Statement(predicate=self.paid,
terms=[Entity(name="Irene"),
Entity(name="Bob")])
contexts = list(left.possible_contexts(left))
assert len(contexts) == 2
assert any(
context.check_match(Entity(name="Irene"), Entity(name="Bob"))
for context in contexts)
def test_interchangeable_terms_in_different_orders(self):
more_than_100_yards = Comparison(
content="the distance between $site1 and $site2 was",
sign=">",
expression="100 yards",
)
less_than_1_mile = Comparison(
content="the distance between $site1 and $site2 was",
sign="<",
expression="1 mile",
)
protest_facts = FactorGroup([
Statement(
predicate=more_than_100_yards,
terms=[
Entity(name="the political convention"),
Entity(name="the police cordon"),
],
),
Statement(
predicate=less_than_1_mile,
terms=[
Entity(name="the police cordon"),
Entity(name="the political convention"),
],
),
])
assert "between <the political convention> and " in str(protest_facts)
more_than_50_meters = Comparison(
content="the distance between $site1 and $site2 was",
sign=">",
expression="50 meters",
)
less_than_2_km = Comparison(
content="the distance between $site1 and $site2 was",
sign="<=",
expression="2 km",
)
speech_zone_facts = FactorGroup([
Statement(
predicate=more_than_50_meters,
terms=[
Entity(name="the free speech zone"),
Entity(name="the courthouse"),
],
),
Statement(
predicate=less_than_2_km,
terms=[
Entity(name="the free speech zone"),
Entity(name="the courthouse"),
],
),
])
assert protest_facts.implies(speech_zone_facts)
def test_means_despite_plural(self):
directory = Entity(name="Rural's telephone directory", plural=False)
listings = Entity(name="Rural's telephone listings", plural=True)
directory_original = Statement(
predicate=Predicate(content="$thing was original"),
terms=directory)
listings_original = Statement(
predicate=Predicate(content="$thing were original"),
terms=listings)
assert directory_original.means(listings_original)
def test_context_register_empty(self, make_complex_fact):
"""
Yields no context_register because the Term in f1 doesn't imply
the Fact in f_relevant_murder.
"""
statement = Statement(predicate="$person was a defendant",
terms=Entity(name="Alice"))
complex_statement = make_complex_fact["relevant_murder"]
gen = statement._context_registers(complex_statement, operator.ge)
with pytest.raises(StopIteration):
next(gen)
def test_limited_possible_contexts_identical_factor(self):
statement = Statement(predicate=self.paid,
terms=[Entity(name="Al"),
Entity(name="Xu")])
context = ContextRegister()
context.insert_pair(Entity(name="Al"), Entity(name="Xu"))
contexts = list(statement.possible_contexts(statement,
context=context))
assert len(contexts) == 1
assert contexts[0].check_match(Entity(name="Al"), Entity(name="Xu"))
assert "Entity(name='Xu'" in repr(contexts)
def test_unequal_because_one_factor_is_absent(self, make_predicate):
left = Statement(
predicate=make_predicate["shooting"],
terms=[Entity(name="Al"), Entity(name="Bo")],
)
right = Statement(
predicate=make_predicate["shooting"],
terms=[Entity(name="Al"), Entity(name="Bob")],
absent=True,
)
assert not left.means(right)
def test_all_generic_terms_match_in_statement(self):
predicate = Predicate(content="the telescope pointed at $object")
morning = Statement(predicate=predicate,
terms=Entity(name="Morning Star"))
evening = Statement(predicate=predicate,
terms=Entity(name="Evening Star"))
left = FactorGroup(morning)
right = FactorGroup(evening)
context = ContextRegister()
context.insert_pair(Entity(name="Morning Star"),
Entity(name="Evening Star"))
assert left._all_generic_terms_match(right, context=context)
def test_term_outside_of_group(self):
speed = "${person}'s speed was"
comparison = Comparison(content=speed,
sign=">",
expression="36 kilometers per hour")
other = Comparison(content=speed,
sign=">",
expression="10 meters per second")
left = FactorGroup(
Statement(predicate=comparison, terms=Entity(name="Ann")))
right = Statement(predicate=other, terms=Entity(name="Bob"))
assert left.means(right)
def test_brackets_around_generic_terms(self, make_predicate):
statement = Statement(
predicate=make_predicate["shooting"],
terms=[Entity(name="Al"), Entity(name="Ed")],
)
assert "<Al> shot <Ed>" in str(statement)
absent = Statement(
predicate=make_predicate["shooting"],
terms=[Entity(name="Al"), Entity(name="Ed")],
absent=True,
)
assert "absence of the statement" in str(absent).lower()
def test_registers_for_interchangeable_context(self, make_statement):
"""
Test that _registers_for_interchangeable_context swaps the first two
items in the ContextRegister
"""
factor = Statement(
predicate="$person1 and $person2 met with each other",
terms=[Entity(name="Al"), Entity(name="Ed")],
)
first_pattern, second_pattern = list(factor.term_permutations())
assert first_pattern[0].name == second_pattern[1].name
assert first_pattern[1].name == second_pattern[0].name
assert first_pattern[0].name != first_pattern[1].name
def test_new_context_replace_fact(self):
changes = ContextRegister.from_lists(
[Entity(name="Death Star 3"),
Entity(name="Kylo Ren")],
[Entity(name="Death Star 1"),
Entity(name="Darth Vader")],
)
statement = Statement(
predicate="$person blew up a planet with $weapon",
terms=[Entity(name="Kylo Ren"),
Entity(name="Death Star 3")],
)
new = statement.new_context(changes)
assert "<Darth Vader> blew up" in new.short_string
def test_make_new_complex_fact(self, make_predicate, make_statement):
shooting = make_statement["shooting"]
murder = make_statement["murder"]
relevant = make_predicate["relevant"]
fact = Statement(predicate=relevant, terms=(shooting, murder))
assert fact.terms[0].name == ""
def test_include_of_in_string(self):
fact = Statement(predicate="$suspect stole bread",
terms=Entity(name="Valjean"))
accusation = Assertion(statement=fact, authority=Entity(name="Javert"))
assert (
"the assertion, by <Javert>, of the statement that <Valjean> stole bread"
in str(accusation))
def test_cannot_repeat_term_in_termsequence(self, make_predicate):
with pytest.raises(DuplicateTermError):
Statement(
predicate="$person1 shot $person2",
terms=[Entity(name="Al"), Entity(name="Al")],
)
def test_truth_param(self):
no_license = Statement(
predicate="$business was licensed as a money transmitting business",
truth=False,
terms=Entity(name="Helix"),
)
assert no_license.predicate.truth is False
def test_list_instead_of_group(self):
comparison = Comparison(
content="${person}'s speed was",
sign=">",
expression="36 kilometers per hour",
)
other_comparison = Comparison(content="${person}'s speed was",
sign=">",
expression="10 meters per second")
left = FactorGroup(
Statement(predicate=comparison, terms=Entity(name="Ann")))
right = [
Statement(predicate=other_comparison, terms=Entity(name="Bob"))
]
assert left.means(right)
assert "Because <Ann> is like <Bob>" in str(
left.explain_same_meaning(right))
def test_error_predicate_contradict_factor(self, make_comparison):
with pytest.raises(TypeError):
make_comparison["exact"].contradicts(
Statement(
make_comparison["exact"],
terms=[Entity(name="thing"), Entity(name="place")],
)
)
def test_length_with_specific_term(self):
statement = Statement(
predicate="$person paid tax to $state",
terms=[
Entity(name="Alice"),
Entity(name="the State of Texas", generic=False),
],
)
assert len(statement) == 1
def test_cannot_update_context_register_from_lists(self):
left = Statement(
predicate="$shooter shot $victim",
terms=[Entity(name="Alice"),
Entity(name="Bob")],
)
right = Statement(
predicate="$shooter shot $victim",
terms=[Entity(name="Craig"),
Entity(name="Dan")],
)
update = left.update_context_register(
right,
context=[[Entity(name="Alice")], [Entity(name="Craig")]],
comparison=means,
)
with pytest.raises(AttributeError):
next(update)
def test_repeating_entity_string(self):
three_entities = Predicate(
content="$planner told $intermediary to hire $shooter")
statement_3 = Statement(
predicate=three_entities,
terms=[Entity(name="Al"),
Entity(name="Bob"),
Entity(name="Cid")],
)
two_entities = Predicate(
content="$shooter told $intermediary to hire $shooter")
statement_2 = Statement(predicate=two_entities,
terms=[Entity(name="Al"),
Entity(name="Bob")])
assert ("statement that <Al> told <Bob> to hire <Cid>".lower()
in str(statement_3).lower())
assert ("statement that <Al> told <Bob> to hire <Al>".lower()
in str(statement_2).lower())
def test_implied_by(self):
left = FactorGroup([
Statement(
predicate=Predicate(
content=
"${rural_s_telephone_directory} was a compilation of facts"
),
terms=(Entity(name="Rural's telephone directory"), ),
)
])
right = FactorGroup([
Statement(
predicate=Predicate(
content="${rural_s_telephone_directory} was an idea"),
terms=(Entity(name="Rural's telephone directory"), ),
)
])
assert not left.implied_by(right)
def test_union_one_generic_not_matched(self):
"""
Here, both FactorGroups have "fact that <> was a computer program".
But they each have another generic that can't be matched:
that <the Java API> was a literal element of <the Java language>
and
that <the Lotus menu command hierarchy> provided the means by
which users controlled and operated <Lotus 1-2-3>
Tests that Factors from "left" should be keys and Factors from "right" values.
"""
language_program = Statement(
predicate="$program was a computer program",
terms=Entity(name="the Java language"),
)
lotus_program = Statement(
predicate="$program was a computer program",
terms=Entity(name="Lotus 1-2-3"),
)
controlled = Statement(
predicate=
"$part provided the means by which users controlled and operated $whole",
terms=[
Entity(name="the Lotus menu command hierarchy"),
Entity(name="Lotus 1-2-3"),
],
)
part = Statement(
predicate="$part was a literal element of $whole",
terms=[
Entity(name="the Java API"),
Entity(name="the Java language")
],
)
left = FactorGroup([lotus_program, controlled])
right = FactorGroup([language_program, part])
new = left | right
text = ("that <the Lotus menu command hierarchy> was a "
"literal element of <Lotus 1-2-3>")
assert text in new[0].short_string
def test_no_duplicate_context_interchangeable_terms(self):
left = Statement(
predicate=Predicate(
content="$country1 signed a treaty with $country2"),
terms=(Entity(name="Mexico"), Entity(name="USA")),
)
right = Statement(
predicate=Predicate(
content="$country3 signed a treaty with $country1"),
terms=(Entity(name="Germany"), Entity(name="UK")),
)
context = ContextRegister.from_lists([Entity(name="USA")],
[Entity(name="UK")])
gen = left._context_registers(right, operator.ge, context)
results = list(gen)
assert len(results) == 1