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logistic_mf.py
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logistic_mf.py
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import time
import numpy as np
def load_matrix(filename, num_users, num_items):
t0 = time.time()
counts = np.zeros((num_users, num_items))
total = 0.0
num_zeros = num_users * num_items
for i, line in enumerate(open(filename, 'r')):
user, item, count = line.strip().split('\t')
user = int(user)
item = int(item)
count = float(count)
counts[user][item] = count
total += count
num_zeros -= 1
alpha = num_zeros / total
print 'alpha %.2f' % alpha
counts *= alpha
t1 = time.time()
print 'Finished loading matrix in %f seconds' % (t1 - t0)
return counts
class LogisticMF():
def __init__(self, counts, num_factors, reg_param=0.6, gamma=1.0,
iterations=30):
self.counts = counts
self.num_users = counts.shape[0]
self.num_items = counts.shape[1]
self.num_factors = num_factors
self.iterations = iterations
self.reg_param = reg_param
self.gamma = gamma
def train_model(self):
self.ones = np.ones((self.num_users, self.num_items))
self.user_vectors = np.random.normal(size=(self.num_users,
self.num_factors))
self.item_vectors = np.random.normal(size=(self.num_items,
self.num_factors))
self.user_biases = np.random.normal(size=(self.num_users, 1))
self.item_biases = np.random.normal(size=(self.num_items, 1))
user_vec_deriv_sum = np.zeros((self.num_users, self.num_factors))
item_vec_deriv_sum = np.zeros((self.num_items, self.num_factors))
user_bias_deriv_sum = np.zeros((self.num_users, 1))
item_bias_deriv_sum = np.zeros((self.num_items, 1))
for i in range(self.iterations):
t0 = time.time()
# Fix items and solve for users
# take step towards gradient of deriv of log likelihood
# we take a step in positive direction because we are maximizing LL
user_vec_deriv, user_bias_deriv = self.deriv(True)
user_vec_deriv_sum += np.square(user_vec_deriv)
user_bias_deriv_sum += np.square(user_bias_deriv)
vec_step_size = self.gamma / np.sqrt(user_vec_deriv_sum)
bias_step_size = self.gamma / np.sqrt(user_bias_deriv_sum)
self.user_vectors += vec_step_size * user_vec_deriv
self.user_biases += bias_step_size * user_bias_deriv
# Fix users and solve for items
# take step towards gradient of deriv of log likelihood
# we take a step in positive direction because we are maximizing LL
item_vec_deriv, item_bias_deriv = self.deriv(False)
item_vec_deriv_sum += np.square(item_vec_deriv)
item_bias_deriv_sum += np.square(item_bias_deriv)
vec_step_size = self.gamma / np.sqrt(item_vec_deriv_sum)
bias_step_size = self.gamma / np.sqrt(item_bias_deriv_sum)
self.item_vectors += vec_step_size * item_vec_deriv
self.item_biases += bias_step_size * item_bias_deriv
t1 = time.time()
print 'iteration %i finished in %f seconds' % (i + 1, t1 - t0)
def deriv(self, user):
if user:
vec_deriv = np.dot(self.counts, self.item_vectors)
bias_deriv = np.expand_dims(np.sum(self.counts, axis=1), 1)
else:
vec_deriv = np.dot(self.counts.T, self.user_vectors)
bias_deriv = np.expand_dims(np.sum(self.counts, axis=0), 1)
A = np.dot(self.user_vectors, self.item_vectors.T)
A += self.user_biases
A += self.item_biases.T
A = np.exp(A)
A /= (A + self.ones)
A = (self.counts + self.ones) * A
if user:
vec_deriv -= np.dot(A, self.item_vectors)
bias_deriv -= np.expand_dims(np.sum(A, axis=1), 1)
# L2 regularization
vec_deriv -= self.reg_param * self.user_vectors
else:
vec_deriv -= np.dot(A.T, self.user_vectors)
bias_deriv -= np.expand_dims(np.sum(A, axis=0), 1)
# L2 regularization
vec_deriv -= self.reg_param * self.item_vectors
return (vec_deriv, bias_deriv)
def log_likelihood(self):
loglik = 0
A = np.dot(self.user_vectors, self.item_vectors.T)
A += self.user_biases
A += self.item_biases.T
B = A * self.counts
loglik += np.sum(B)
A = np.exp(A)
A += self.ones
A = np.log(A)
A = (self.counts + self.ones) * A
loglik -= np.sum(A)
# L2 regularization
loglik -= 0.5 * self.reg_param * np.sum(np.square(self.user_vectors))
loglik -= 0.5 * self.reg_param * np.sum(np.square(self.item_vectors))
return loglik
def print_vectors(self):
user_vecs_file = open('logmf-user-vecs-%i' % self.num_factors, 'w')
for i in range(self.num_users):
vec = ' '.join(map(str, self.user_vectors[i]))
line = '%i\t%s\n' % (i, vec)
user_vecs_file.write(line)
user_vecs_file.close()
item_vecs_file = open('logmf-item-vecs-%i' % self.num_factors, 'w')
for i in range(self.num_items):
vec = ' '.join(map(str, self.item_vectors[i]))
line = '%i\t%s\n' % (i, vec)
item_vecs_file.write(line)
item_vecs_file.close()