def _test_adversarial():
triples = [('john', 'friendOf', 'mark'), ('mark', 'friendOf', 'aleksi'),
('mark', 'friendOf', 'dazdrasmygda')]
def fact(s, p, o):
return Fact(predicate_name=p, argument_names=[s, o])
facts = [fact(s, p, o) for s, p, o in triples]
parser = KnowledgeBaseParser(facts)
clauses = [parse_clause('friendOf(X, Y) :- friendOf(Y, X)')]
nb_entities = len(parser.entity_vocabulary)
nb_predicates = len(parser.predicate_vocabulary)
entity_embedding_size = 100
predicate_embedding_size = 100
entity_embedding_layer = tf.get_variable(
'entities',
shape=[nb_entities + 1, entity_embedding_size],
initializer=tf.contrib.layers.xavier_initializer())
predicate_embedding_layer = tf.get_variable(
'predicates',
shape=[nb_predicates + 1, predicate_embedding_size],
initializer=tf.contrib.layers.xavier_initializer())
model_class = models.get_function('TransE')
similarity_function = similarities.get_function('l1')
model_parameters = dict(similarity_function=similarity_function)
batch_size = 1000
adversarial = Adversarial(
clauses=clauses,
parser=parser,
entity_embedding_layer=entity_embedding_layer,
predicate_embedding_layer=predicate_embedding_layer,
model_class=model_class,
model_parameters=model_parameters,
batch_size=batch_size)
init_op = tf.global_variables_initializer()
with tf.Session() as session:
session.run(init_op)
assert len(adversarial.parameters) == 2
for violating_embeddings in adversarial.parameters:
shape = session.run(tf.shape(violating_embeddings))
assert (shape == (batch_size, entity_embedding_size)).all()
loss_value = session.run(adversarial.loss)
errors_value = session.run(adversarial.errors)
var1 = adversarial.parameters[0]
var2 = adversarial.parameters[1]
X_values = session.run(var1 if "X" in var1.name else var2)
Y_values = session.run(var2 if "Y" in var2.name else var1)
p_value = session.run(
tf.nn.embedding_lookup(predicate_embedding_layer, 1))
assert np.array(X_values.shape == (batch_size,
entity_embedding_size)).all()
assert np.array(Y_values.shape == (batch_size,
entity_embedding_size)).all()
assert np.array(p_value.shape == (predicate_embedding_size, ))
head_scores = -np.sum(np.abs((X_values + p_value) - Y_values), axis=1)
body_scores = -np.sum(np.abs((Y_values + p_value) - X_values), axis=1)
assert int(errors_value) == np.sum(
(head_scores < body_scores).astype(int))
linear_losses = body_scores - head_scores
np_loss_values = np.sum(linear_losses * (linear_losses > 0))
assert np.abs(loss_value - np_loss_values) < 1e-3
tf.reset_default_graph()
logger = logging.getLogger(__name__)
triples = [('a', 'p', 'b'), ('c', 'p', 'd'), ('a', 'q', 'b')]
facts = [Fact(predicate_name=p, argument_names=[s, o]) for s, p, o in triples]
parser = KnowledgeBaseParser(facts)
nb_entities = len(parser.entity_to_index)
nb_predicates = len(parser.predicate_to_index)
# Clauses
clause_str = 'q(X, Y) :- p(X, Y)'
clauses = [parse_clause(clause_str)]
# Instantiating the model parameters
model_class = models.get_function('TransE')
similarity_function = similarities.get_function('l2_sqr')
model_parameters = dict(similarity_function=similarity_function)
@pytest.mark.closedform
def test_transe_unit_cube():
for seed in range(32):
tf.reset_default_graph()
np.random.seed(seed)
tf.set_random_seed(seed)
entity_embedding_size = np.random.randint(low=1, high=5)
predicate_embedding_size = entity_embedding_size
logger = logging.getLogger(__name__)
triples = [('a', 'p', 'b'), ('c', 'p', 'd'), ('a', 'q', 'b')]
facts = [Fact(predicate_name=p, argument_names=[s, o]) for s, p, o in triples]
parser = KnowledgeBaseParser(facts)
nb_entities = len(parser.entity_to_index)
nb_predicates = len(parser.predicate_to_index)
# Clauses
clause_str = 'q(X, Y) :- p(Y, X)'
clauses = [parse_clause(clause_str)]
# Instantiating the model parameters
model_class = models.get_function('ComplEx')
similarity_function = similarities.get_function('dot')
model_parameters = dict(similarity_function=similarity_function)
@pytest.mark.closedform
def test_complex_unit_sphere():
for seed in range(32):
tf.reset_default_graph()
np.random.seed(seed)
tf.set_random_seed(seed)
entity_embedding_size = np.random.randint(low=1, high=5) * 2
predicate_embedding_size = entity_embedding_size
logger = logging.getLogger(__name__)
triples = [('a', 'p', 'b'), ('c', 'p', 'd'), ('a', 'q', 'b')]
facts = [Fact(predicate_name=p, argument_names=[s, o]) for s, p, o in triples]
parser = KnowledgeBaseParser(facts)
nb_entities = len(parser.entity_to_index)
nb_predicates = len(parser.predicate_to_index)
# Clauses
clause_str = 'q(X, Y) :- p(X, Y)'
clauses = [parse_clause(clause_str)]
# Instantiating the model parameters
model_class = models.get_function('DistMult')
similarity_function = similarities.get_function('dot')
model_parameters = dict(similarity_function=similarity_function)
@pytest.mark.closedform
def test_distmult_unit_sphere():
for seed in range(32):
tf.reset_default_graph()
np.random.seed(seed)
tf.set_random_seed(seed)
entity_embedding_size = np.random.randint(low=1, high=5)
predicate_embedding_size = entity_embedding_size
def test_losses():
hyperparam_configurations = list(cartesian_product(hyperparams))
for hyperparam_configuration in hyperparam_configurations:
# Clauses
clause = parse_clause(hyperparam_configuration['clause'])
# Instantiating the model parameters
model_class = models.get_function(hyperparam_configuration['model_name'])
similarity_function = similarities.get_function('dot')
unit_cube = hyperparam_configuration['unit_cube']
for seed in range(4):
print('Seed {}, Evaluating {}'.format(seed, str(hyperparam_configuration)))
tf.reset_default_graph()
np.random.seed(seed)
tf.set_random_seed(seed)
entity_embedding_size = np.random.randint(low=1, high=5) * 2
predicate_embedding_size = entity_embedding_size
# Instantiating entity and predicate embedding layers
entity_embedding_layer = tf.get_variable('entities',
shape=[nb_entities + 1, entity_embedding_size],
initializer=tf.contrib.layers.xavier_initializer())
predicate_embedding_layer = tf.get_variable('predicates',
shape=[nb_predicates + 1, predicate_embedding_size],
initializer=tf.contrib.layers.xavier_initializer())
entity_projection = constraints.unit_sphere(entity_embedding_layer, norm=1.0)
if unit_cube:
entity_projection = constraints.unit_cube(entity_embedding_layer)
entity_inputs = tf.placeholder(tf.int32, shape=[None, 2])
walk_inputs = tf.placeholder(tf.int32, shape=[None, None])
entity_embeddings = tf.nn.embedding_lookup(entity_embedding_layer, entity_inputs)
predicate_embeddings = tf.nn.embedding_lookup(predicate_embedding_layer, walk_inputs)
model_parameters = dict(entity_embeddings=entity_embeddings,
predicate_embeddings=predicate_embeddings,
similarity_function=similarity_function)
model = model_class(**model_parameters)
score = model()
closed_form_lifted = ClosedForm(parser=parser,
predicate_embedding_layer=predicate_embedding_layer,
model_class=model_class,
model_parameters=model_parameters,
is_unit_cube=unit_cube)
opt_adversarial_loss = closed_form_lifted(clause)
v_optimizer = tf.train.AdagradOptimizer(learning_rate=1e-2)
v_training_step = v_optimizer.minimize(opt_adversarial_loss, var_list=[predicate_embedding_layer])
init_op = tf.global_variables_initializer()
with tf.Session() as session:
session.run(init_op)
session.run([entity_projection])
def scoring_function(args):
return session.run(score, feed_dict={walk_inputs: args[0], entity_inputs: args[1]})
ground_loss = GroundLoss(clauses=[clause], parser=parser, scoring_function=scoring_function)
feed_dict = {'X': a_idx, 'Y': b_idx}
continuous_loss_0 = ground_loss.continuous_error(clause, feed_dict=feed_dict)
for epoch in range(1, 100 + 1):
_ = session.run([v_training_step])
print(ground_loss.continuous_error(clause, feed_dict=feed_dict))
continuous_loss_final = ground_loss.continuous_error(clause, feed_dict=feed_dict)
assert continuous_loss_0 <= .0 or continuous_loss_final <= continuous_loss_0
tf.reset_default_graph()
