spaCy/examples/pipeline/wiki_entity_linking/wiki_nel_pipeline.py

298 lines
10 KiB
Python

# coding: utf-8
from __future__ import unicode_literals
import random
from spacy.util import minibatch, compounding
from examples.pipeline.wiki_entity_linking import wikipedia_processor as wp, kb_creator, training_set_creator, run_el
from examples.pipeline.wiki_entity_linking.kb_creator import DESC_WIDTH
import spacy
from spacy.vocab import Vocab
from spacy.kb import KnowledgeBase
import datetime
"""
Demonstrate how to build a knowledge base from WikiData and run an Entity Linking algorithm.
"""
PRIOR_PROB = 'C:/Users/Sofie/Documents/data/wikipedia/prior_prob.csv'
ENTITY_COUNTS = 'C:/Users/Sofie/Documents/data/wikipedia/entity_freq.csv'
ENTITY_DEFS = 'C:/Users/Sofie/Documents/data/wikipedia/entity_defs.csv'
ENTITY_DESCR = 'C:/Users/Sofie/Documents/data/wikipedia/entity_descriptions.csv'
KB_FILE = 'C:/Users/Sofie/Documents/data/wikipedia/kb_1/kb'
NLP_1_DIR = 'C:/Users/Sofie/Documents/data/wikipedia/nlp_1'
NLP_2_DIR = 'C:/Users/Sofie/Documents/data/wikipedia/nlp_2'
TRAINING_DIR = 'C:/Users/Sofie/Documents/data/wikipedia/training_data_nel/'
MAX_CANDIDATES = 10
MIN_PAIR_OCC = 5
DOC_CHAR_CUTOFF = 300
EPOCHS = 2
DROPOUT = 0.1
def run_pipeline():
print("START", datetime.datetime.now())
print()
nlp_1 = spacy.load('en_core_web_lg')
nlp_2 = None
kb_1 = None
kb_2 = None
# one-time methods to create KB and write to file
to_create_prior_probs = False
to_create_entity_counts = False
to_create_kb = True
# read KB back in from file
to_read_kb = True
to_test_kb = True
# create training dataset
create_wp_training = False
# train the EL pipe
train_pipe = False
measure_performance = False
# test the EL pipe on a simple example
to_test_pipeline = False
# write the NLP object, read back in and test again
test_nlp_io = False
# STEP 1 : create prior probabilities from WP
# run only once !
if to_create_prior_probs:
print("STEP 1: to_create_prior_probs", datetime.datetime.now())
wp.read_wikipedia_prior_probs(prior_prob_output=PRIOR_PROB)
print()
# STEP 2 : deduce entity frequencies from WP
# run only once !
if to_create_entity_counts:
print("STEP 2: to_create_entity_counts", datetime.datetime.now())
wp.write_entity_counts(prior_prob_input=PRIOR_PROB, count_output=ENTITY_COUNTS, to_print=False)
print()
# STEP 3 : create KB and write to file
# run only once !
if to_create_kb:
print("STEP 3a: to_create_kb", datetime.datetime.now())
kb_1 = kb_creator.create_kb(nlp_1,
max_entities_per_alias=MAX_CANDIDATES,
min_occ=MIN_PAIR_OCC,
entity_def_output=ENTITY_DEFS,
entity_descr_output=ENTITY_DESCR,
count_input=ENTITY_COUNTS,
prior_prob_input=PRIOR_PROB,
to_print=False)
print("kb entities:", kb_1.get_size_entities())
print("kb aliases:", kb_1.get_size_aliases())
print()
print("STEP 3b: write KB and NLP", datetime.datetime.now())
kb_1.dump(KB_FILE)
nlp_1.to_disk(NLP_1_DIR)
print()
# STEP 4 : read KB back in from file
if to_read_kb:
print("STEP 4: to_read_kb", datetime.datetime.now())
# my_vocab = Vocab()
# my_vocab.from_disk(VOCAB_DIR)
# my_kb = KnowledgeBase(vocab=my_vocab, entity_vector_length=64)
nlp_2 = spacy.load(NLP_1_DIR)
kb_2 = KnowledgeBase(vocab=nlp_2.vocab, entity_vector_length=DESC_WIDTH)
kb_2.load_bulk(KB_FILE)
print("kb entities:", kb_2.get_size_entities())
print("kb aliases:", kb_2.get_size_aliases())
print()
# test KB
if to_test_kb:
run_el.run_kb_toy_example(kb=kb_2)
print()
# STEP 5: create a training dataset from WP
if create_wp_training:
print("STEP 5: create training dataset", datetime.datetime.now())
training_set_creator.create_training(kb=kb_2, entity_def_input=ENTITY_DEFS, training_output=TRAINING_DIR)
# STEP 6: create the entity linking pipe
if train_pipe:
print("STEP 6: training Entity Linking pipe", datetime.datetime.now())
train_limit = 10
dev_limit = 5
print("Training on", train_limit, "articles")
print("Dev testing on", dev_limit, "articles")
print()
train_data = training_set_creator.read_training(nlp=nlp_2,
training_dir=TRAINING_DIR,
dev=False,
limit=train_limit,
to_print=False)
dev_data = training_set_creator.read_training(nlp=nlp_2,
training_dir=TRAINING_DIR,
dev=True,
limit=dev_limit,
to_print=False)
el_pipe = nlp_2.create_pipe(name='entity_linker', config={"doc_cutoff": DOC_CHAR_CUTOFF})
el_pipe.set_kb(kb_2)
nlp_2.add_pipe(el_pipe, last=True)
other_pipes = [pipe for pipe in nlp_2.pipe_names if pipe != "entity_linker"]
with nlp_2.disable_pipes(*other_pipes): # only train Entity Linking
nlp_2.begin_training()
for itn in range(EPOCHS):
random.shuffle(train_data)
losses = {}
batches = minibatch(train_data, size=compounding(4.0, 128.0, 1.001))
batchnr = 0
with nlp_2.disable_pipes(*other_pipes):
for batch in batches:
try:
docs, golds = zip(*batch)
nlp_2.update(
docs,
golds,
drop=DROPOUT,
losses=losses,
)
batchnr += 1
except Exception as e:
print("Error updating batch", e)
losses['entity_linker'] = losses['entity_linker'] / batchnr
print("Epoch, train loss", itn, round(losses['entity_linker'], 2))
if measure_performance:
print()
print("STEP 7: performance measurement of Entity Linking pipe", datetime.datetime.now())
print()
# print(" measuring accuracy 1-1")
el_pipe.context_weight = 1
el_pipe.prior_weight = 1
dev_acc_1_1 = _measure_accuracy(dev_data, el_pipe)
train_acc_1_1 = _measure_accuracy(train_data, el_pipe)
print("train/dev acc combo:", round(train_acc_1_1, 2), round(dev_acc_1_1, 2))
# baseline using only prior probabilities
el_pipe.context_weight = 0
el_pipe.prior_weight = 1
dev_acc_0_1 = _measure_accuracy(dev_data, el_pipe)
train_acc_0_1 = _measure_accuracy(train_data, el_pipe)
print("train/dev acc prior:", round(train_acc_0_1, 2), round(dev_acc_0_1, 2))
# using only context
el_pipe.context_weight = 1
el_pipe.prior_weight = 0
dev_acc_1_0 = _measure_accuracy(dev_data, el_pipe)
train_acc_1_0 = _measure_accuracy(train_data, el_pipe)
print("train/dev acc context:", round(train_acc_1_0, 2), round(dev_acc_1_0, 2))
print()
if to_test_pipeline:
print()
print("STEP 8: applying Entity Linking to toy example", datetime.datetime.now())
print()
run_el_toy_example(nlp=nlp_2)
print()
if test_nlp_io:
print()
print("STEP 9: testing NLP IO", datetime.datetime.now())
print()
print("writing to", NLP_2_DIR)
print(" vocab len nlp_2", len(nlp_2.vocab))
print(" vocab len kb_2", len(kb_2.vocab))
nlp_2.to_disk(NLP_2_DIR)
print()
print("reading from", NLP_2_DIR)
nlp_3 = spacy.load(NLP_2_DIR)
print(" vocab len nlp_3", len(nlp_3.vocab))
for pipe_name, pipe in nlp_3.pipeline:
if pipe_name == "entity_linker":
print(" vocab len kb_3", len(pipe.kb.vocab))
print()
print("running toy example with NLP 2")
run_el_toy_example(nlp=nlp_3)
print()
print("STOP", datetime.datetime.now())
def _measure_accuracy(data, el_pipe):
correct = 0
incorrect = 0
docs = [d for d, g in data if len(d) > 0]
docs = el_pipe.pipe(docs)
golds = [g for d, g in data if len(d) > 0]
for doc, gold in zip(docs, golds):
try:
correct_entries_per_article = dict()
for entity in gold.links:
start, end, gold_kb = entity
correct_entries_per_article[str(start) + "-" + str(end)] = gold_kb
for ent in doc.ents:
if ent.label_ == "PERSON": # TODO: expand to other types
pred_entity = ent.kb_id_
start = ent.start
end = ent.end
gold_entity = correct_entries_per_article.get(str(start) + "-" + str(end), None)
if gold_entity is not None:
if gold_entity == pred_entity:
correct += 1
else:
incorrect += 1
except Exception as e:
print("Error assessing accuracy", e)
if correct == incorrect == 0:
return 0
acc = correct / (correct + incorrect)
return acc
def run_el_toy_example(nlp):
text = "In The Hitchhiker's Guide to the Galaxy, written by Douglas Adams, " \
"Douglas reminds us to always bring our towel. " \
"The main character in Doug's novel is the man Arthur Dent, " \
"but Douglas doesn't write about George Washington or Homer Simpson."
doc = nlp(text)
for ent in doc.ents:
print("ent", ent.text, ent.label_, ent.kb_id_)
print()
# Q4426480 is her husband, Q3568763 her tutor
text = "Ada Lovelace loved her husband William King dearly. " \
"Ada Lovelace was tutored by her favorite physics tutor William King."
doc = nlp(text)
for ent in doc.ents:
print("ent", ent.text, ent.label_, ent.kb_id_)
if __name__ == "__main__":
run_pipeline()