def initialize_graph(self):
self.hypergraph = TensorflowHypergraphRepresentation(self.variables, edge_dropout_rate=self.model_settings["edge_dropout"])
self.add_component(self.hypergraph)
self.lstms = [BiLstm(self.variables, self.model_settings["word_embedding_dimension"]+1, self.model_settings["lstm_hidden_state_dimension"], variable_prefix="lstm_" + str(i)) for i in
range(self.model_settings["n_lstms"])]
for lstm in self.lstms:
self.add_component(lstm)
self.word_embedding = SequenceEmbedding(self.word_indexer, self.variables, variable_prefix="word", word_dropout_rate=self.model_settings["word_dropout"], is_static=self.model_settings["static_word_embeddings"])
self.add_component(self.word_embedding)
#self.attention = Attention(self.model_settings["word_embedding_dimension"], self.variables, variable_prefix="attention", strategy="constant_query")
self.attention = MultiheadAttention(self.model_settings["lstm_hidden_state_dimension"], self.variables, attention_heads=4,
variable_prefix="attention", strategy="constant_query", attention_dropout=self.model_settings["attention_dropout"])
self.add_component(self.attention)
self.target_comparator = TargetComparator(self.variables, variable_prefix="comparison_to_sentence", comparison="concat")
self.add_component(self.target_comparator)
self.decoder = SoftmaxDecoder(self.variables, self.model_settings["loss"])
self.add_component(self.decoder)
self.candidate_scorer = NeuralNetworkOrFactorizationScorer(self.model_settings, self.variables, variable_prefix="scorer")
self.add_component(self.candidate_scorer)
self.hypergraph_gcn_propagation_units = [None] * self.model_settings["n_layers"]
for layer in range(self.model_settings["n_layers"]):
self.hypergraph_gcn_propagation_units[layer] = HypergraphGcnPropagationUnit("layer_" + str(layer),
self.facts,
self.variables,
self.model_settings["entity_embedding_dimension"],
self.hypergraph,
weights="identity",
biases="relation_specific",
self_weight="identity",
self_bias="zero",
add_inverse_relations=True)
self.add_component(self.hypergraph_gcn_propagation_units[layer])
self.sentence_to_graph_mapper = EmbeddingRetriever(self.variables, duplicate_policy="sum", variable_prefix="mapper")
self.add_component(self.sentence_to_graph_mapper)
self.final_transformation = MultilayerPerceptron([int(self.model_settings["lstm_hidden_state_dimension"]/2) + self.model_settings["entity_embedding_dimension"],
self.model_settings["nn_hidden_state_dimension"],
1],
self.variables,
variable_prefix="transformation",
l2_scale=self.model_settings["regularization_scale"])
self.add_component(self.final_transformation)
def initialize_graph(self):
if not self.model_settings["static_entity_embeddings"]:
self.entity_embedding = VectorEmbedding(self.entity_indexer,
self.variables,
variable_prefix="entity")
self.add_component(self.entity_embedding)
else:
self.entity_embedding = StaticVectorEmbedding(
self.entity_indexer, self.variables, variable_prefix="entity")
self.add_component(self.entity_embedding)
self.hypergraph = TensorflowHypergraphRepresentation(self.variables)
self.add_component(self.hypergraph)
#self.question_sentence = TensorflowSentenceRepresentation(self.variables)
#self.add_component(self.question_sentence)
self.word_embedding = SequenceEmbedding(self.word_indexer,
self.variables,
variable_prefix="word")
self.add_component(self.word_embedding)
self.target_comparator = TargetComparator(
self.variables, variable_prefix="comparison_to_sentence")
self.add_component(self.target_comparator)
self.decoder = SoftmaxDecoder(self.variables)
self.add_component(self.decoder)
self.sentence_to_graph_mapper = EmbeddingRetriever(
self.variables, duplicate_policy="sum", variable_prefix="mapper")
self.add_component(self.sentence_to_graph_mapper)
if self.model_settings["use_transformation"]:
self.transformation = MultilayerPerceptron(
[
self.model_settings["word_embedding_dimension"],
self.model_settings["entity_embedding_dimension"]
],
self.variables,
variable_prefix="transformation",
l2_scale=self.model_settings["regularization_scale"])
self.centroid_transformation = MultilayerPerceptron(
[
self.model_settings["entity_embedding_dimension"],
self.model_settings["word_embedding_dimension"]
],
self.variables,
variable_prefix="centroid_transformation",
l2_scale=self.model_settings["regularization_scale"])
self.add_component(self.centroid_transformation)
self.add_component(self.transformation)
class PathBagWithGatesVsLstm(AbstractTensorflowModel):
def get_preprocessor_stack_types(self):
preprocessor_stack_types = ["hypergraph", "gold", "sentence"]
if self.model_settings["static_entity_embeddings"]:
preprocessor_stack_types += ["static_entity_embeddings"]
return preprocessor_stack_types
def initialize_graph(self):
self.hypergraph = TensorflowHypergraphRepresentation(self.variables, edge_dropout_rate=self.model_settings["edge_dropout"])
self.add_component(self.hypergraph)
self.lstms = [BiLstm(self.variables, self.model_settings["word_embedding_dimension"]+1, self.model_settings["lstm_hidden_state_dimension"], variable_prefix="lstm_" + str(i)) for i in
range(self.model_settings["n_lstms"])]
for lstm in self.lstms:
self.add_component(lstm)
self.word_embedding = SequenceEmbedding(self.word_indexer, self.variables, variable_prefix="word", word_dropout_rate=self.model_settings["word_dropout"], is_static=self.model_settings["static_word_embeddings"])
self.add_component(self.word_embedding)
#self.attention = Attention(self.model_settings["word_embedding_dimension"], self.variables, variable_prefix="attention", strategy="constant_query")
self.attention = MultiheadAttention(self.model_settings["lstm_hidden_state_dimension"], self.variables, attention_heads=self.model_settings["n_attention_heads"],
variable_prefix="attention", strategy="constant_query", attention_dropout=self.model_settings["attention_dropout"])
self.add_component(self.attention)
self.target_comparator = TargetComparator(self.variables, variable_prefix="comparison_to_sentence", comparison="concat")
self.add_component(self.target_comparator)
self.decoder = SoftmaxDecoder(self.variables)
self.add_component(self.decoder)
self.candidate_scorer = NeuralNetworkOrFactorizationScorer(self.model_settings, self.variables, variable_prefix="scorer")
self.add_component(self.candidate_scorer)
if self.model_settings["gate_input"] == "GCN":
gate_input_dim = self.model_settings["gate_input_dim"]
self.gate_transform = MultilayerPerceptron([1, gate_input_dim],
self.variables,
variable_prefix="gate_transformation",
l2_scale=self.model_settings["regularization_scale"],
dropout_rate=self.model_settings["transform_dropout"])
self.add_component(self.gate_transform)
self.gate_gcns = [None] * self.model_settings["gate_input_layers"]
for layer in range(self.model_settings["gate_input_layers"]):
self.gate_gcns[layer] = HypergraphGcnPropagationUnit("gate_layer_" + str(layer),
self.facts,
self.variables,
gate_input_dim,
self.hypergraph,
weights="single",
biases="constant",
self_weight="full",
self_bias="constant",
add_inverse_relations=True,)
self.add_component(self.gate_gcns[layer])
else:
gate_input_dim = 1
self.hypergraph_gcn_propagation_units = [None] * self.model_settings["n_layers"]
for layer in range(self.model_settings["n_layers"]):
self.hypergraph_gcn_propagation_units[layer] = HypergraphGcnPropagationUnit("layer_" + str(layer),
self.facts,
self.variables,
self.model_settings["entity_embedding_dimension"],
self.hypergraph,
weights="identity",
biases="relation_specific",
self_weight="identity",
self_bias="zero",
add_inverse_relations=True,
gate_mode="features_given",
gate_input_dim=gate_input_dim)
self.add_component(self.hypergraph_gcn_propagation_units[layer])
self.sentence_to_graph_mapper = EmbeddingRetriever(self.variables, duplicate_policy="sum", variable_prefix="mapper")
self.add_component(self.sentence_to_graph_mapper)
if False: #self.model_settings["use_transformation"]:
self.transformation = MultilayerPerceptron([self.model_settings["word_embedding_dimension"],
self.model_settings["entity_embedding_dimension"]],
self.variables,
variable_prefix="transformation",
l2_scale=self.model_settings["regularization_scale"])
self.centroid_transformation = MultilayerPerceptron([self.model_settings["entity_embedding_dimension"],
self.model_settings["word_embedding_dimension"]],
self.variables,
variable_prefix="centroid_transformation",
l2_scale=self.model_settings["regularization_scale"])
self.add_component(self.centroid_transformation)
self.add_component(self.transformation)
self.final_transformation = MultilayerPerceptron([int(self.model_settings["lstm_hidden_state_dimension"]/2) + self.model_settings["entity_embedding_dimension"],
self.model_settings["nn_hidden_state_dimension"],
1],
self.variables,
variable_prefix="transformation",
l2_scale=self.model_settings["regularization_scale"])
self.add_component(self.final_transformation)
def set_indexers(self, indexers):
self.word_indexer = indexers.word_indexer
self.relation_indexer = indexers.relation_indexer
self.entity_indexer = indexers.entity_indexer
def compute_entity_scores(self, mode="train"):
#entity_vertex_embeddings = self.entity_embedding.get_representations()
#word_embedding_shape = tf.shape(word_embeddings)
#word_embeddings = tf.reshape(word_embeddings, [-1, self.model_settings["word_embedding_dimension"]])
#centroid_embeddings = self.sentence_to_graph_mapper.get_forward_embeddings(entity_vertex_embeddings)
#centroid_embeddings = self.centroid_transformation.transform(centroid_embeddings)
#word_embeddings += self.sentence_to_graph_mapper.map_backwards(centroid_embeddings)
#word_embeddings = tf.reshape(word_embeddings, word_embedding_shape)
if self.model_settings["gate_input"] == "GCN":
v_features = self.gate_transform.transform(tf.expand_dims(self.hypergraph.get_vertex_scores(),1), mode=mode)
e_features = self.gate_transform.transform(tf.expand_dims(self.hypergraph.get_event_scores(),1), mode=mode)
self.hypergraph.update_entity_embeddings(v_features, self.model_settings["gate_input_dim"])
self.hypergraph.update_event_embeddings(e_features, self.model_settings["gate_input_dim"])
for gate_layer in self.gate_gcns:
gate_layer.propagate()
v_features = self.hypergraph.entity_vertex_embeddings
e_features = self.hypergraph.event_vertex_embeddings
else:
v_features = tf.expand_dims(self.hypergraph.get_vertex_scores(),1)
e_features = tf.expand_dims(self.hypergraph.get_event_scores(),1)
self.hypergraph.initialize_zero_embeddings(self.model_settings["entity_embedding_dimension"])
for hgpu in self.hypergraph_gcn_propagation_units:
hgpu.set_gate_features(v_features, "entities")
hgpu.set_gate_features(e_features, "events")
hgpu.propagate()
entity_scores = self.hypergraph.entity_vertex_embeddings
entity_scores = tf.concat([entity_scores, tf.expand_dims(self.hypergraph.get_vertex_scores(),1)], axis=1)
word_embeddings = self.word_embedding.get_representations(mode=mode)
###
word_embedding_shape = tf.shape(word_embeddings)
word_embeddings = tf.reshape(word_embeddings, [-1, self.model_settings["word_embedding_dimension"]])
centroid_embeddings = self.sentence_to_graph_mapper.get_forward_embeddings(tf.ones([tf.shape(entity_scores)[0], 1]))
word_embeddings = tf.concat([word_embeddings, self.sentence_to_graph_mapper.map_backwards(centroid_embeddings)], axis=1)
word_embeddings = tf.reshape(word_embeddings, [word_embedding_shape[0],-1,self.model_settings["word_embedding_dimension"]+1])
###
for lstm in self.lstms:
word_embeddings = lstm.transform_sequences(word_embeddings)
sentence_vector = self.attention.attend(word_embeddings, mode=mode)
return self.candidate_scorer.score(sentence_vector, entity_scores, mode=mode)
#if self.model_settings["use_transformation"]:
# bag_of_words = self.transformation.transform(bag_of_words)
#hidden = self.target_comparator.get_comparison_scores(sentence_vector, entity_scores)
#entity_scores = tf.squeeze(self.final_transformation.transform(hidden))
#entity_scores = self.target_comparator.get_comparison_scores(bag_of_words,
# entity_scores)
#return entity_scores
def initialize_graph(self):
self.hypergraph = TensorflowHypergraphRepresentation(
self.variables,
edge_dropout_rate=self.model_settings["edge_dropout"])
self.add_component(self.hypergraph)
self.lstms = [
BiLstm(self.variables,
self.model_settings["word_embedding_dimension"] + 1,
self.model_settings["lstm_hidden_state_dimension"],
variable_prefix="lstm_" + str(i))
for i in range(self.model_settings["n_lstms"])
]
for lstm in self.lstms:
self.add_component(lstm)
self.word_embedding = SequenceEmbedding(
self.word_indexer,
self.variables,
variable_prefix="word",
word_dropout_rate=self.model_settings["word_dropout"],
is_static=self.model_settings["static_word_embeddings"])
self.add_component(self.word_embedding)
#self.attention = Attention(self.model_settings["word_embedding_dimension"], self.variables, variable_prefix="attention", strategy="constant_query")
self.attention = MultiheadAttention(
self.model_settings["lstm_hidden_state_dimension"],
self.variables,
attention_heads=self.model_settings["n_attention_heads"],
variable_prefix="attention",
strategy="constant_query",
attention_dropout=self.model_settings["attention_dropout"])
self.add_component(self.attention)
self.target_comparator = TargetComparator(
self.variables,
variable_prefix="comparison_to_sentence",
comparison="concat")
self.add_component(self.target_comparator)
self.decoder = SoftmaxDecoder(self.variables,
self.model_settings["loss"])
self.add_component(self.decoder)
self.candidate_scorer = NeuralNetworkOrFactorizationScorer(
self.model_settings, self.variables, variable_prefix="scorer")
self.add_component(self.candidate_scorer)
gcn_factory = GcnFactory()
gcn_settings = {
"n_layers":
self.model_settings["n_layers"],
"embedding_dimension":
self.model_settings["entity_embedding_dimension"],
"n_relation_types":
self.facts.number_of_relation_types
}
self.hypergraph_gcn_propagation_units = gcn_factory.get_gated_type_only_gcn(
self.hypergraph, self.variables, gcn_settings)
for layer in self.hypergraph_gcn_propagation_units:
self.add_component(layer)
self.sentence_to_graph_mapper = EmbeddingRetriever(
self.variables, duplicate_policy="sum", variable_prefix="mapper")
self.add_component(self.sentence_to_graph_mapper)
self.final_transformation = MultilayerPerceptron(
[
int(self.model_settings["lstm_hidden_state_dimension"] / 2) +
self.model_settings["entity_embedding_dimension"],
self.model_settings["nn_hidden_state_dimension"], 1
],
self.variables,
variable_prefix="transformation",
l2_scale=self.model_settings["regularization_scale"])
self.add_component(self.final_transformation)
class PathBagWithTypeGatesVsLstm(AbstractTensorflowModel):
def get_preprocessor_stack_types(self):
preprocessor_stack_types = ["hypergraph", "gold", "sentence"]
if self.model_settings["static_entity_embeddings"]:
preprocessor_stack_types += ["static_entity_embeddings"]
return preprocessor_stack_types
edge_gates = None
def get_edge_gates(self):
if self.edge_gates is None:
self.edge_gates = [
hpgu.get_edge_gates()
for hpgu in self.hypergraph_gcn_propagation_units
]
return self.edge_gates
def initialize_graph(self):
self.hypergraph = TensorflowHypergraphRepresentation(
self.variables,
edge_dropout_rate=self.model_settings["edge_dropout"])
self.add_component(self.hypergraph)
self.lstms = [
BiLstm(self.variables,
self.model_settings["word_embedding_dimension"] + 1,
self.model_settings["lstm_hidden_state_dimension"],
variable_prefix="lstm_" + str(i))
for i in range(self.model_settings["n_lstms"])
]
for lstm in self.lstms:
self.add_component(lstm)
self.word_embedding = SequenceEmbedding(
self.word_indexer,
self.variables,
variable_prefix="word",
word_dropout_rate=self.model_settings["word_dropout"],
is_static=self.model_settings["static_word_embeddings"])
self.add_component(self.word_embedding)
#self.attention = Attention(self.model_settings["word_embedding_dimension"], self.variables, variable_prefix="attention", strategy="constant_query")
self.attention = MultiheadAttention(
self.model_settings["lstm_hidden_state_dimension"],
self.variables,
attention_heads=self.model_settings["n_attention_heads"],
variable_prefix="attention",
strategy="constant_query",
attention_dropout=self.model_settings["attention_dropout"])
self.add_component(self.attention)
self.target_comparator = TargetComparator(
self.variables,
variable_prefix="comparison_to_sentence",
comparison="concat")
self.add_component(self.target_comparator)
self.decoder = SoftmaxDecoder(self.variables,
self.model_settings["loss"])
self.add_component(self.decoder)
self.candidate_scorer = NeuralNetworkOrFactorizationScorer(
self.model_settings, self.variables, variable_prefix="scorer")
self.add_component(self.candidate_scorer)
gcn_factory = GcnFactory()
gcn_settings = {
"n_layers":
self.model_settings["n_layers"],
"embedding_dimension":
self.model_settings["entity_embedding_dimension"],
"n_relation_types":
self.facts.number_of_relation_types
}
self.hypergraph_gcn_propagation_units = gcn_factory.get_gated_type_only_gcn(
self.hypergraph, self.variables, gcn_settings)
for layer in self.hypergraph_gcn_propagation_units:
self.add_component(layer)
self.sentence_to_graph_mapper = EmbeddingRetriever(
self.variables, duplicate_policy="sum", variable_prefix="mapper")
self.add_component(self.sentence_to_graph_mapper)
self.final_transformation = MultilayerPerceptron(
[
int(self.model_settings["lstm_hidden_state_dimension"] / 2) +
self.model_settings["entity_embedding_dimension"],
self.model_settings["nn_hidden_state_dimension"], 1
],
self.variables,
variable_prefix="transformation",
l2_scale=self.model_settings["regularization_scale"])
self.add_component(self.final_transformation)
def set_indexers(self, indexers):
self.word_indexer = indexers.word_indexer
self.relation_indexer = indexers.relation_indexer
self.entity_indexer = indexers.entity_indexer
def compute_entity_scores(self, mode="train"):
self.hypergraph.initialize_zero_embeddings(
self.model_settings["entity_embedding_dimension"])
word_embeddings = self.word_embedding.get_representations(mode=mode)
word_embedding_shape = tf.shape(word_embeddings)
word_embeddings = tf.reshape(
word_embeddings,
[-1, self.model_settings["word_embedding_dimension"]])
centroid_embeddings = self.sentence_to_graph_mapper.get_forward_embeddings(
tf.ones([tf.shape(self.hypergraph.entity_vertex_embeddings)[0],
1]))
word_embeddings = tf.concat([
word_embeddings,
self.sentence_to_graph_mapper.map_backwards(centroid_embeddings)
],
axis=1)
word_embeddings = tf.reshape(word_embeddings, [
word_embedding_shape[0], -1,
self.model_settings["word_embedding_dimension"] + 1
])
for lstm in self.lstms:
word_embeddings = lstm.transform_sequences(word_embeddings)
sentence_vector = self.attention.attend(word_embeddings, mode=mode)
for hgpu in self.hypergraph_gcn_propagation_units:
hgpu.set_gate_key(sentence_vector)
hgpu.propagate()
entity_scores = self.hypergraph.entity_vertex_embeddings
if self.model_settings["concatenate_scores"]:
entity_scores = tf.concat([
entity_scores,
tf.expand_dims(self.hypergraph.get_vertex_scores(), 1)
],
axis=1)
return self.candidate_scorer.score(sentence_vector,
entity_scores,
mode=mode)
def initialize_graph(self):
if not self.model_settings["static_entity_embeddings"]:
self.entity_embedding = VectorEmbedding(self.entity_indexer,
self.variables,
variable_prefix="entity")
self.add_component(self.entity_embedding)
else:
self.entity_embedding = StaticVectorEmbedding(
self.entity_indexer, self.variables, variable_prefix="entity")
self.add_component(self.entity_embedding)
self.hypergraph = TensorflowHypergraphRepresentation(self.variables)
self.add_component(self.hypergraph)
self.word_embedding = SequenceEmbedding(self.word_indexer,
self.variables,
variable_prefix="word")
self.add_component(self.word_embedding)
self.target_comparator = TargetComparator(
self.variables,
variable_prefix="comparison_to_sentence",
comparison="concat")
self.add_component(self.target_comparator)
self.decoder = SoftmaxDecoder(self.variables)
self.add_component(self.decoder)
self.hypergraph_gcn_propagation_units = [
None
] * self.model_settings["n_layers"]
for layer in range(self.model_settings["n_layers"]):
self.hypergraph_gcn_propagation_units[
layer] = HypergraphGcnPropagationUnit(
"layer_" + str(layer),
self.facts,
self.variables,
self.model_settings["entity_embedding_dimension"],
self.hypergraph,
weights="identity",
biases="relation_specific",
self_weight="identity",
self_bias="zero",
add_inverse_relations=False)
self.add_component(self.hypergraph_gcn_propagation_units[layer])
self.sentence_to_graph_mapper = EmbeddingRetriever(
self.variables, duplicate_policy="sum", variable_prefix="mapper")
self.add_component(self.sentence_to_graph_mapper)
if False: #self.model_settings["use_transformation"]:
self.transformation = MultilayerPerceptron(
[
self.model_settings["word_embedding_dimension"],
self.model_settings["entity_embedding_dimension"]
],
self.variables,
variable_prefix="transformation",
l2_scale=self.model_settings["regularization_scale"])
self.centroid_transformation = MultilayerPerceptron(
[
self.model_settings["entity_embedding_dimension"],
self.model_settings["word_embedding_dimension"]
],
self.variables,
variable_prefix="centroid_transformation",
l2_scale=self.model_settings["regularization_scale"])
self.add_component(self.centroid_transformation)
self.add_component(self.transformation)
self.final_transformation = MultilayerPerceptron(
[
self.model_settings["word_embedding_dimension"] +
self.model_settings["entity_embedding_dimension"],
4 * self.model_settings["entity_embedding_dimension"], 1
],
self.variables,
variable_prefix="transformation",
l2_scale=self.model_settings["regularization_scale"])
self.add_component(self.final_transformation)
class PathBagVsBagOfWords(AbstractTensorflowModel):
def get_preprocessor_stack_types(self):
preprocessor_stack_types = ["hypergraph", "gold", "sentence"]
if self.model_settings["static_entity_embeddings"]:
preprocessor_stack_types += ["static_entity_embeddings"]
return preprocessor_stack_types
def initialize_graph(self):
if not self.model_settings["static_entity_embeddings"]:
self.entity_embedding = VectorEmbedding(self.entity_indexer,
self.variables,
variable_prefix="entity")
self.add_component(self.entity_embedding)
else:
self.entity_embedding = StaticVectorEmbedding(
self.entity_indexer, self.variables, variable_prefix="entity")
self.add_component(self.entity_embedding)
self.hypergraph = TensorflowHypergraphRepresentation(self.variables)
self.add_component(self.hypergraph)
self.word_embedding = SequenceEmbedding(self.word_indexer,
self.variables,
variable_prefix="word")
self.add_component(self.word_embedding)
self.target_comparator = TargetComparator(
self.variables,
variable_prefix="comparison_to_sentence",
comparison="concat")
self.add_component(self.target_comparator)
self.decoder = SoftmaxDecoder(self.variables)
self.add_component(self.decoder)
self.hypergraph_gcn_propagation_units = [
None
] * self.model_settings["n_layers"]
for layer in range(self.model_settings["n_layers"]):
self.hypergraph_gcn_propagation_units[
layer] = HypergraphGcnPropagationUnit(
"layer_" + str(layer),
self.facts,
self.variables,
self.model_settings["entity_embedding_dimension"],
self.hypergraph,
weights="identity",
biases="relation_specific",
self_weight="identity",
self_bias="zero",
add_inverse_relations=False)
self.add_component(self.hypergraph_gcn_propagation_units[layer])
self.sentence_to_graph_mapper = EmbeddingRetriever(
self.variables, duplicate_policy="sum", variable_prefix="mapper")
self.add_component(self.sentence_to_graph_mapper)
if False: #self.model_settings["use_transformation"]:
self.transformation = MultilayerPerceptron(
[
self.model_settings["word_embedding_dimension"],
self.model_settings["entity_embedding_dimension"]
],
self.variables,
variable_prefix="transformation",
l2_scale=self.model_settings["regularization_scale"])
self.centroid_transformation = MultilayerPerceptron(
[
self.model_settings["entity_embedding_dimension"],
self.model_settings["word_embedding_dimension"]
],
self.variables,
variable_prefix="centroid_transformation",
l2_scale=self.model_settings["regularization_scale"])
self.add_component(self.centroid_transformation)
self.add_component(self.transformation)
self.final_transformation = MultilayerPerceptron(
[
self.model_settings["word_embedding_dimension"] +
self.model_settings["entity_embedding_dimension"],
4 * self.model_settings["entity_embedding_dimension"], 1
],
self.variables,
variable_prefix="transformation",
l2_scale=self.model_settings["regularization_scale"])
self.add_component(self.final_transformation)
def set_indexers(self, indexers):
self.word_indexer = indexers.word_indexer
self.relation_indexer = indexers.relation_indexer
self.entity_indexer = indexers.entity_indexer
def compute_entity_scores(self):
#entity_vertex_embeddings = self.entity_embedding.get_representations()
word_embeddings = self.word_embedding.get_representations()
#word_embedding_shape = tf.shape(word_embeddings)
#word_embeddings = tf.reshape(word_embeddings, [-1, self.model_settings["word_embedding_dimension"]])
#centroid_embeddings = self.sentence_to_graph_mapper.get_forward_embeddings(entity_vertex_embeddings)
#centroid_embeddings = self.centroid_transformation.transform(centroid_embeddings)
#word_embeddings += self.sentence_to_graph_mapper.map_backwards(centroid_embeddings)
#word_embeddings = tf.reshape(word_embeddings, word_embedding_shape)
self.hypergraph.initialize_zero_embeddings(
self.model_settings["entity_embedding_dimension"])
for hgpu in self.hypergraph_gcn_propagation_units:
hgpu.propagate()
entity_scores = self.hypergraph.entity_vertex_embeddings
bag_of_words = tf.reduce_sum(word_embeddings, 1)
#if self.model_settings["use_transformation"]:
# bag_of_words = self.transformation.transform(bag_of_words)
hidden = self.target_comparator.get_comparison_scores(
bag_of_words, entity_scores)
entity_scores = tf.squeeze(self.final_transformation.transform(hidden))
#entity_scores = tf.Print(entity_scores, [entity_scores], summarize=25, message="entity_scores: ")
#entity_scores = self.target_comparator.get_comparison_scores(bag_of_words,
# entity_scores)
return entity_scores
