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rel_ext.py
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rel_ext.py
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from collections import Counter, defaultdict, namedtuple
import gzip
import numpy as np
import os
import random
from sklearn.feature_extraction import DictVectorizer
from sklearn.linear_model import LogisticRegression
from sklearn.metrics import precision_recall_fscore_support
from sklearn.model_selection import train_test_split
__author__ = "Bill MacCartney and Christopher Potts"
__version__ = "CS224u, Stanford, Spring 2020"
Example = namedtuple('Example',
'entity_1, entity_2, left, mention_1, middle, mention_2, right, '
'left_POS, mention_1_POS, middle_POS, mention_2_POS, right_POS')
class Corpus(object):
"""Class for representing and working with the raw text we use
as evidence for making relation predictions.
Parameters
----------
src_filename_or_examples : str or list
If str, this is assumed to be the full path to the gzip file
that contains the examples to use. The method `read_examples`
is used to open it in that case. If this is a list, then it
should be a list of `Example` instances.
Attributes
----------
examples_by_entities : dict
A 2d dictionary mapping `ex.entity_1` to a dict mapping entity
`ex.entity_2` to the full `Example` instance `ex`. This is
created by the method `_index_examples_by_entities`.
"""
def __init__(self, src_filename_or_examples):
if isinstance(src_filename_or_examples, str):
self.examples = self.read_examples(src_filename_or_examples)
else:
self.examples = src_filename_or_examples
self.examples_by_entities = {}
self._index_examples_by_entities()
@staticmethod
def read_examples(src_filename):
"""Read `src_filename`, assumed to be a `gzip` file with
tab-separated lines that can be turned into `Example`
instances.
Parameters
----------
src_filename : str
Assumed to be the full path to the gzip file that contains
the examples.
Returns
-------
list of Example
"""
examples = []
with gzip.open(src_filename, mode='rt', encoding='utf8') as f:
for line in f:
fields = line[:-1].split('\t')
examples.append(Example(*fields))
return examples
def _index_examples_by_entities(self):
"""Fill `examples_by_entities` as a 2d dictionary mapping
`ex.entity_1` to a dict mapping entity `ex.entity_2` to the
full `Example` instance `ex`.
"""
for ex in self.examples:
if ex.entity_1 not in self.examples_by_entities:
self.examples_by_entities[ex.entity_1] = {}
if ex.entity_2 not in self.examples_by_entities[ex.entity_1]:
self.examples_by_entities[ex.entity_1][ex.entity_2] = []
self.examples_by_entities[ex.entity_1][ex.entity_2].append(ex)
def get_examples_for_entities(self, e1, e2):
"""Given two entities `e1` and `e2` as strings, return
examples from `self.examples_by_entities`, as a list of
`Example` instances."""
try:
return self.examples_by_entities[e1][e2]
except KeyError:
return []
def show_examples_for_pair(self, e1, e2):
"""Given two entities `e1` and `e2` as strings, print out their
first `Example`, if there is one, otherwise print out a message
saying there are no Example instances relating `e1` to `e2`."""
exs = self.get_examples_for_entities(e1, e2)
if exs:
print('The first of {0:,} examples for {1:} and {2:} is:'.format(
len(exs), e1, e2))
print(exs[0])
else:
print('No examples for {0:} and {1:}'.format(e1, e2))
def __str__(self):
return 'Corpus with {0:,} examples'.format(len(self.examples))
def __repr__(self):
return str(self)
def __len__(self):
return len(self.examples)
KBTriple = namedtuple('KBTriple', 'rel, sbj, obj')
class KB(object):
"""Class for representing and working with the knowledge base.
Parameters
----------
src_filename_or_triples : str or list
If str, this is assumed to be the full path to the gzip file
that contains the KB. The method `read_kb_triples` is used to
open it in that case. If this is a list, then it should be a
list of `KBTriple` instances.
Attributes
----------
all_relations : list
Built by `_index_kb_triples_by_relation` as a list of str.
all_entity_pairs : list
Built by `_collect_all_entity_pairs`, as a sorted list of
(subject, object) tuples.
kb_triples_by_relation : dict
Built by `_index_kb_triples_by_relation`, as a dict mapping
relations (str) to `KBTriple` lists.
kb_triples_by_entities : dict
Built by `_index_kb_triples_by_entities`, as a dict mapping
relations subject (str) to dict mapping object (str) to
`KBTriple` lists.
"""
def __init__(self, src_filename_or_triples):
if isinstance(src_filename_or_triples, str):
self.kb_triples = self.read_kb_triples(src_filename_or_triples)
else:
self.kb_triples = src_filename_or_triples
self.all_relations = []
self.all_entity_pairs = []
self.kb_triples_by_relation = {}
self.kb_triples_by_entities = {}
self._collect_all_entity_pairs()
self._index_kb_triples_by_relation()
self._index_kb_triples_by_entities()
@staticmethod
def read_kb_triples(src_filename):
"""Read `src_filename`, assumed to be a `gzip` file with
tab-separated lines that can be turned into `KBTriple`
instances.
Parameters
----------
src_filename : str
Assumed to be the full path to the gzip file that contains
the triples
Returns
-------
list of KBTriple
"""
kb_triples = []
with gzip.open(src_filename, mode='rt', encoding='utf8') as f:
for line in f:
rel, sbj, obj = line[:-1].split('\t')
kb_triples.append(KBTriple(rel, sbj, obj))
return kb_triples
def _collect_all_entity_pairs(self):
pairs = set()
for kbt in self.kb_triples:
pairs.add((kbt.sbj, kbt.obj))
self.all_entity_pairs = sorted(list(pairs))
def _index_kb_triples_by_relation(self):
for kbt in self.kb_triples:
if kbt.rel not in self.kb_triples_by_relation:
self.kb_triples_by_relation[kbt.rel] = []
self.kb_triples_by_relation[kbt.rel].append(kbt)
self.all_relations = sorted(list(self.kb_triples_by_relation))
def _index_kb_triples_by_entities(self):
for kbt in self.kb_triples:
if kbt.sbj not in self.kb_triples_by_entities:
self.kb_triples_by_entities[kbt.sbj] = {}
if kbt.obj not in self.kb_triples_by_entities[kbt.sbj]:
self.kb_triples_by_entities[kbt.sbj][kbt.obj] = []
self.kb_triples_by_entities[kbt.sbj][kbt.obj].append(kbt)
def get_triples_for_relation(self, rel):
""""Given a relation name (str), return all of the `KBTriple`
instances that involve it."""
try:
return self.kb_triples_by_relation[rel]
except KeyError:
return []
def get_triples_for_entities(self, e1, e2):
"""Given a pair of entities `e1` and `e2` (both str), return
all of the `KBTriple` instances that involve them."""
try:
return self.kb_triples_by_entities[e1][e2]
except KeyError:
return []
def __str__(self):
return 'KB with {0:,} triples'.format(len(self.kb_triples))
def __repr__(self):
return str(self)
def __len__(self):
return len(self.kb_triples)
class Dataset(object):
"""Class for unifying a `Corpus` and a `KB`.
Parameters
----------
corpus : `Corpus`
kb : `KB`
"""
def __init__(self, corpus, kb):
self.corpus = corpus
self.kb = kb
def find_unrelated_pairs(self):
unrelated_pairs = set()
for ex in self.corpus.examples:
if self.kb.get_triples_for_entities(ex.entity_1, ex.entity_2):
continue
if self.kb.get_triples_for_entities(ex.entity_2, ex.entity_1):
continue
unrelated_pairs.add((ex.entity_1, ex.entity_2))
unrelated_pairs.add((ex.entity_2, ex.entity_1))
return unrelated_pairs
def featurize(self, kbts_by_rel, featurizers, vectorizer=None, vectorize=True):
"""Featurize by relation.
Parameters
----------
kbts_by_rel : dict
A map from relation (str) to lists of `KBTriples`.
featurizers : list of func
Each function has to have the signature
`kbt, corpus, feature_counter`, where `kbt` is a `KBTriple`,
`corpus` is a `Corpus`, and `feature_counter` is a count
dictionary.
vectorizer : DictVectorizer or None:
If None, a new `DictVectorizer` is created and used via
`fit`. This is primarily for training. If not None, then
`transform` is used. This is primarily for testing.
vectorize: bool
If True, the feature functions in `featurizers` are presumed
to create feature dicts, and a `DictVectorizer` is used. If
False, then `featurizers` is required to have exactly one
function in it, and that function must return exactly the
sort of objects that the models in the model factory take
as inputs.
Returns
-------
feat_matrices_by_rel, vectorizer
where `feat_matrices_by_rel` is a dict mapping relation names
to (i) lists of representation if `vectorize=False`, else
to `np.array`s, and (ii) and `vectorizer` is a
`DictVectorizer` if `vectorize=True`, else None
"""
if not vectorize:
feat_matrices_by_rel = defaultdict(list)
if len(featurizers) != 1:
raise ValueError(
"If `vectorize=True`, the `featurizers` argument "
"must contain exactly one function.")
featurizer = featurizers[0]
for rel, kbts in kbts_by_rel.items():
for kbt in kbts:
rep = featurizer(kbt, self.corpus)
feat_matrices_by_rel[rel].append(rep)
return feat_matrices_by_rel, None
# Create feature counters for all instances (kbts).
feat_counters_by_rel = defaultdict(list)
for rel, kbts in kbts_by_rel.items():
for kbt in kbts:
feature_counter = Counter()
for featurizer in featurizers:
feature_counter = featurizer(kbt, self.corpus, feature_counter)
feat_counters_by_rel[rel].append(feature_counter)
feat_matrices_by_rel = defaultdict(list)
# If we haven't been given a Vectorizer, create one and fit
# it to all the feature counters.
if vectorizer is None:
vectorizer = DictVectorizer(sparse=True)
def traverse_dicts():
for dict_list in feat_counters_by_rel.values():
for d in dict_list:
yield d
vectorizer.fit(traverse_dicts())
# Now use the Vectorizer to transform feature dictionaries
# into feature matrices.
for rel, feat_counters in feat_counters_by_rel.items():
feat_matrices_by_rel[rel] = vectorizer.transform(feat_counters)
return feat_matrices_by_rel, vectorizer
def build_dataset(self, include_positive=True, sampling_rate=0.1, seed=1):
unrelated_pairs = self.find_unrelated_pairs()
random.seed(seed)
unrelated_pairs = random.sample(
unrelated_pairs, int(sampling_rate * len(unrelated_pairs)))
kbts_by_rel = defaultdict(list)
labels_by_rel = defaultdict(list)
for index, rel in enumerate(self.kb.all_relations):
if include_positive:
for kbt in self.kb.get_triples_for_relation(rel):
kbts_by_rel[rel].append(kbt)
labels_by_rel[rel].append(True)
for sbj, obj in unrelated_pairs:
kbts_by_rel[rel].append(KBTriple(rel, sbj, obj))
labels_by_rel[rel].append(False)
return kbts_by_rel, labels_by_rel
def build_splits(self,
split_names=['tiny', 'train', 'dev'],
split_fracs=[0.01, 0.74, 0.25],
seed=1):
if len(split_names) != len(split_fracs):
raise ValueError('split_names and split_fracs must be of equal length')
if sum(split_fracs) != 1.0:
raise ValueError('split_fracs must sum to 1')
n = len(split_fracs) # for convenience only
def split_list(xs):
xs = sorted(xs) # sorted for reproducibility
if seed:
random.seed(seed)
random.shuffle(xs)
split_points = [0] + [int(round(frac * len(xs)))
for frac in np.cumsum(split_fracs)]
return [xs[split_points[i]:split_points[i + 1]] for i in range(n)]
# first, split the entities that appear as subjects in the KB
sbjs = list(set([kbt.sbj for kbt in self.kb.kb_triples]))
sbj_splits = split_list(sbjs)
sbj_split_dict = {sbj: i for i, split in enumerate(sbj_splits)
for sbj in split}
# next, split the KB triples based on their subjects
kbt_splits = [[kbt for kbt in self.kb.kb_triples if sbj_split_dict[kbt.sbj] == i]
for i in range(n)]
# now split examples based on the entities they contain
ex_splits = [[] for i in range(n + 1)] # include an extra split
for ex in self.corpus.examples:
if ex.entity_1 in sbj_split_dict:
# if entity_1 is a sbj in the KB, assign example to split of that sbj
ex_splits[sbj_split_dict[ex.entity_1]].append(ex)
elif ex.entity_2 in sbj_split_dict:
# if entity_2 is a sbj in the KB, assign example to split of that sbj
ex_splits[sbj_split_dict[ex.entity_2]].append(ex)
else:
# otherwise, put in extra split to be redistributed
ex_splits[-1].append(ex)
# reallocate the examples that weren't assigned to a split on first pass
extra_ex_splits = split_list(ex_splits[-1])
ex_splits = [ex_splits[i] + extra_ex_splits[i] for i in range(n)]
# create a Corpus and a KB for each split
data = {}
for i in range(n):
data[split_names[i]] = Dataset(Corpus(ex_splits[i]), KB(kbt_splits[i]))
data['all'] = self
return data
def count_examples(self):
counter = Counter()
for rel in self.kb.all_relations:
for kbt in self.kb.get_triples_for_relation(rel):
# count examples in both forward and reverse directions
counter[rel] += len(self.corpus.get_examples_for_entities(kbt.sbj, kbt.obj))
counter[rel] += len(self.corpus.get_examples_for_entities(kbt.obj, kbt.sbj))
# report results
print('{:20s} {:>10s} {:>10s} {:>10s}'.format(
'', '', '', 'examples'))
print('{:20s} {:>10s} {:>10s} {:>10s}'.format(
'relation', 'examples', 'triples', '/triple'))
print('{:20s} {:>10s} {:>10s} {:>10s}'.format(
'--------', '--------', '-------', '-------'))
for rel in self.kb.all_relations:
nx = counter[rel]
nt = len(self.kb.get_triples_for_relation(rel))
print('{:20s} {:10d} {:10d} {:10.2f}'.format(
rel, nx, nt, 1.0 * nx / nt))
def count_relation_combinations(self):
counter = Counter()
for sbj, obj in self.kb.all_entity_pairs:
rels = tuple(sorted({kbt.rel for kbt in self.kb.get_triples_for_entities(sbj, obj)}))
if len(rels) > 1:
counter[rels] += 1
counts = sorted([(count, key) for key, count in counter.items()], reverse=True)
print('The most common relation combinations are:')
for count, key in counts:
print('{:10d} {}'.format(count, key))
def __str__(self):
return "{}; {}".format(self.corpus, self.kb)
def __repr__(self):
return str(self)
def print_statistics_header():
print('{:20s} {:>10s} {:>10s} {:>10s} {:>10s} {:>10s}'.format(
'relation', 'precision', 'recall', 'f-score', 'support', 'size'))
print('{:20s} {:>10s} {:>10s} {:>10s} {:>10s} {:>10s}'.format(
'-' * 18, '-' * 9, '-' * 9, '-' * 9, '-' * 9, '-' * 9))
def print_statistics_row(rel, result):
print('{:20s} {:10.3f} {:10.3f} {:10.3f} {:10d} {:10d}'.format(rel, *result))
def print_statistics_footer(avg_result):
print('{:20s} {:>10s} {:>10s} {:>10s} {:>10s} {:>10s}'.format(
'-' * 18, '-' * 9, '-' * 9, '-' * 9, '-' * 9, '-' * 9))
print('{:20s} {:10.3f} {:10.3f} {:10.3f} {:10d} {:10d}'.format('macro-average', *avg_result))
def macro_average_results(results):
avg_result = [np.average([r[i] for r in results.values()]) for i in range(3)]
avg_result.append(np.sum([r[3] for r in results.values()]))
avg_result.append(np.sum([r[4] for r in results.values()]))
return avg_result
def evaluate(splits, classifier, test_split='dev', sampling_rate=0.1, verbose=True):
test_kbts_by_rel, true_labels_by_rel = splits[test_split].build_dataset(sampling_rate=sampling_rate)
results = {}
if verbose:
print_statistics_header()
for rel in splits['all'].kb.all_relations:
pred_labels = classifier(test_kbts_by_rel[rel])
stats = precision_recall_fscore_support(true_labels_by_rel[rel], pred_labels, beta=0.5)
stats = [stat[1] for stat in stats] # stats[1] is the stat for label True
stats.append(len(pred_labels)) # number of examples
results[rel] = stats
if verbose:
print_statistics_row(rel, results[rel])
avg_result = macro_average_results(results)
if verbose:
print_statistics_footer(avg_result)
return avg_result[2] # return f_0.5 score as summary statistic
def train_models(
splits,
featurizers,
split_name='train',
model_factory=(lambda: LogisticRegression(
fit_intercept=True, solver='liblinear', random_state=42)),
sampling_rate=0.1,
vectorize=True,
verbose=True):
train_dataset = splits[split_name]
train_o, train_y = train_dataset.build_dataset(sampling_rate=sampling_rate)
train_X, vectorizer = train_dataset.featurize(
train_o, featurizers, vectorize=vectorize)
models = {}
for rel in splits['all'].kb.all_relations:
models[rel] = model_factory()
models[rel].fit(train_X[rel], train_y[rel])
return {
'featurizers': featurizers,
'vectorizer': vectorizer,
'models': models,
'all_relations': splits['all'].kb.all_relations,
'vectorize': vectorize}
def predict(splits, train_result, split_name='dev', sampling_rate=0.1, vectorize=True):
assess_dataset = splits[split_name]
assess_o, assess_y = assess_dataset.build_dataset(sampling_rate=sampling_rate)
test_X, _ = assess_dataset.featurize(
assess_o,
featurizers=train_result['featurizers'],
vectorizer=train_result['vectorizer'],
vectorize=vectorize)
predictions = {}
for rel in train_result['all_relations']:
predictions[rel] = train_result['models'][rel].predict(test_X[rel])
return predictions, assess_y
def evaluate_predictions(predictions, test_y, verbose=True):
results = {} # one result row for each relation
if verbose:
print_statistics_header()
for rel, preds in predictions.items():
stats = precision_recall_fscore_support(test_y[rel], preds, beta=0.5)
stats = [stat[1] for stat in stats] # stats[1] is the stat for label True
stats.append(len(test_y[rel]))
results[rel] = stats
if verbose:
print_statistics_row(rel, results[rel])
avg_result = macro_average_results(results)
if verbose:
print_statistics_footer(avg_result)
return avg_result[2] # return f_0.5 score as summary statistic
def experiment(
splits,
featurizers,
train_split='train',
test_split='dev',
model_factory=(lambda: LogisticRegression(
fit_intercept=True, solver='liblinear', random_state=42)),
train_sampling_rate=0.1,
test_sampling_rate=0.1,
vectorize=True,
verbose=True):
train_result = train_models(
splits,
featurizers=featurizers,
split_name=train_split,
model_factory=model_factory,
sampling_rate=train_sampling_rate,
vectorize=vectorize,
verbose=verbose)
predictions, test_y = predict(
splits,
train_result,
split_name=test_split,
sampling_rate=test_sampling_rate,
vectorize=vectorize)
evaluate_predictions(
predictions,
test_y,
verbose)
return train_result
def examine_model_weights(train_result, k=3, verbose=True):
vectorizer = train_result['vectorizer']
if vectorizer is None:
print("Model weights can be examined only if the featurizers "
"are based in dicts (i.e., if `vectorize=True`).")
return
feature_names = vectorizer.get_feature_names()
for rel, model in train_result['models'].items():
print('Highest and lowest feature weights for relation {}:\n'.format(rel))
try:
coefs = model.coef_.toarray()
except AttributeError:
coefs = model.coef_
sorted_weights = sorted([(wgt, idx) for idx, wgt in enumerate(coefs[0])], reverse=True)
for wgt, idx in sorted_weights[:k]:
print('{:10.3f} {}'.format(wgt, feature_names[idx]))
print('{:>10s} {}'.format('.....', '.....'))
for wgt, idx in sorted_weights[-k:]:
print('{:10.3f} {}'.format(wgt, feature_names[idx]))
print()
def find_new_relation_instances(
dataset,
featurizers,
train_split='train',
test_split='dev',
model_factory=(lambda: LogisticRegression(
fit_intercept=True, solver='liblinear', random_state=42)),
k=10,
vectorize=True,
verbose=True):
splits = dataset.build_splits()
# train models
train_result = train_models(
splits,
split_name=train_split,
featurizers=featurizers,
model_factory=model_factory,
vectorize=vectorize,
verbose=True)
test_split = splits[test_split]
neg_o, neg_y = test_split.build_dataset(
include_positive=False,
sampling_rate=1.0)
neg_X, _ = test_split.featurize(
neg_o,
featurizers=featurizers,
vectorizer=train_result['vectorizer'],
vectorize=vectorize)
# Report highest confidence predictions:
for rel, model in train_result['models'].items():
print('Highest probability examples for relation {}:\n'.format(rel))
probs = model.predict_proba(neg_X[rel])
probs = [prob[1] for prob in probs] # probability for class True
sorted_probs = sorted([(p, idx) for idx, p in enumerate(probs)], reverse=True)
for p, idx in sorted_probs[:k]:
print('{:10.3f} {}'.format(p, neg_o[rel][idx]))
print()
def bake_off_experiment(train_result, rel_ext_data_home, verbose=True):
test_corpus_filename = os.path.join(rel_ext_data_home, "corpus-test.tsv.gz")
test_kb_filename = os.path.join(rel_ext_data_home, "kb-test.tsv.gz")
corpus = Corpus(test_corpus_filename)
kb = KB(test_kb_filename)
test_dataset = Dataset(corpus, kb)
test_o, test_y = test_dataset.build_dataset()
test_X, _ = test_dataset.featurize(
test_o,
featurizers=train_result['featurizers'],
vectorizer=train_result['vectorizer'],
vectorize=train_result['vectorize'])
predictions = {}
for rel in train_result['all_relations']:
predictions[rel] = train_result['models'][rel].predict(test_X[rel])
evaluate_predictions(
predictions,
test_y,
verbose=verbose)