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utils.py
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utils.py
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import collections
import numpy as np
import re
def tokenize_string(sample):
return tuple(sample.lower().split(' '))
class NgramLanguageModel(object):
def __init__(self, n, samples, tokenize=False):
if tokenize:
tokenized_samples = []
for sample in samples:
tokenized_samples.append(tokenize_string(sample))
samples = tokenized_samples
self._n = n
self._samples = samples
self._ngram_counts = collections.defaultdict(int)
self._total_ngrams = 0
for ngram in self.ngrams():
self._ngram_counts[ngram] += 1
self._total_ngrams += 1
def ngrams(self):
n = self._n
for sample in self._samples:
for i in xrange(len(sample)-n+1):
yield sample[i:i+n]
def unique_ngrams(self):
return set(self._ngram_counts.keys())
def log_likelihood(self, ngram):
if ngram not in self._ngram_counts:
return -np.inf
else:
return np.log(self._ngram_counts[ngram]) - np.log(self._total_ngrams)
def kl_to(self, p):
# p is another NgramLanguageModel
log_likelihood_ratios = []
for ngram in p.ngrams():
log_likelihood_ratios.append(p.log_likelihood(ngram) - self.log_likelihood(ngram))
return np.mean(log_likelihood_ratios)
def cosine_sim_with(self, p):
# p is another NgramLanguageModel
p_dot_q = 0.
p_norm = 0.
q_norm = 0.
for ngram in p.unique_ngrams():
p_i = np.exp(p.log_likelihood(ngram))
q_i = np.exp(self.log_likelihood(ngram))
p_dot_q += p_i * q_i
p_norm += p_i**2
for ngram in self.unique_ngrams():
q_i = np.exp(self.log_likelihood(ngram))
q_norm += q_i**2
return p_dot_q / (np.sqrt(p_norm) * np.sqrt(q_norm))
def precision_wrt(self, p):
# p is another NgramLanguageModel
num = 0.
denom = 0
p_ngrams = p.unique_ngrams()
for ngram in self.unique_ngrams():
if ngram in p_ngrams:
num += self._ngram_counts[ngram]
denom += self._ngram_counts[ngram]
return float(num) / denom
def recall_wrt(self, p):
return p.precision_wrt(self)
def js_with(self, p):
log_p = np.array([p.log_likelihood(ngram) for ngram in p.unique_ngrams()])
log_q = np.array([self.log_likelihood(ngram) for ngram in p.unique_ngrams()])
log_m = np.logaddexp(log_p - np.log(2), log_q - np.log(2))
kl_p_m = np.sum(np.exp(log_p) * (log_p - log_m))
log_p = np.array([p.log_likelihood(ngram) for ngram in self.unique_ngrams()])
log_q = np.array([self.log_likelihood(ngram) for ngram in self.unique_ngrams()])
log_m = np.logaddexp(log_p - np.log(2), log_q - np.log(2))
kl_q_m = np.sum(np.exp(log_q) * (log_q - log_m))
return 0.5*(kl_p_m + kl_q_m) / np.log(2)
def load_dataset(path, max_length, tokenize=False, max_vocab_size=2048):
lines = []
with open(path, 'r') as f:
for line in f:
line = line[:-1]
if tokenize:
line = tokenize_string(line)
else:
line = tuple(line)
if len(line) > max_length:
line = line[:max_length]
continue # don't include this sample, its too long
# right pad with ` character
lines.append(line + ( ("`",)*(max_length-len(line)) ) )
np.random.shuffle(lines)
import collections
counts = collections.Counter(char for line in lines for char in line)
charmap = {'unk':0}
inv_charmap = ['unk']
for char,count in counts.most_common(max_vocab_size-1):
if char not in charmap:
charmap[char] = len(inv_charmap)
inv_charmap.append(char)
filtered_lines = []
for line in lines:
filtered_line = []
for char in line:
if char in charmap:
filtered_line.append(char)
else:
filtered_line.append('unk')
filtered_lines.append(tuple(filtered_line))
# for i in xrange(100):
# print filtered_lines[i]
print "loaded {} lines in dataset".format(len(lines))
return filtered_lines, charmap, inv_charmap