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ladder.py
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ladder.py
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import tensorflow as tf
import input_data
import math
import os
import csv
from tqdm import tqdm
layer_sizes = [784, 1000, 500, 250, 250, 250, 10]
L = len(layer_sizes) - 1 # number of layers
num_examples = 60000
num_epochs = 150
num_labeled = 100
starter_learning_rate = 0.02
decay_after = 15 # epoch after which to begin learning rate decay
batch_size = 100
num_iter = (num_examples/batch_size) * num_epochs # number of loop iterations
inputs = tf.placeholder(tf.float32, shape=(None, layer_sizes[0]))
outputs = tf.placeholder(tf.float32)
def bi(inits, size, name):
return tf.Variable(inits * tf.ones([size]), name=name)
def wi(shape, name):
return tf.Variable(tf.random_normal(shape, name=name)) / math.sqrt(shape[0])
shapes = zip(layer_sizes[:-1], layer_sizes[1:]) # shapes of linear layers
weights = {'W': [wi(s, "W") for s in shapes], # Encoder weights
'V': [wi(s[::-1], "V") for s in shapes], # Decoder weights
# batch normalization parameter to shift the normalized value
'beta': [bi(0.0, layer_sizes[l+1], "beta") for l in range(L)],
# batch normalization parameter to scale the normalized value
'gamma': [bi(1.0, layer_sizes[l+1], "beta") for l in range(L)]}
noise_std = 0.3 # scaling factor for noise used in corrupted encoder
# hyperparameters that denote the importance of each layer
denoising_cost = [1000.0, 10.0, 0.10, 0.10, 0.10, 0.10, 0.10]
join = lambda l, u: tf.concat([l, u], 0)
labeled = lambda x: tf.slice(x, [0, 0], [batch_size, -1]) if x is not None else x
unlabeled = lambda x: tf.slice(x, [batch_size, 0], [-1, -1]) if x is not None else x
split_lu = lambda x: (labeled(x), unlabeled(x))
training = tf.placeholder(tf.bool)
ewma = tf.train.ExponentialMovingAverage(decay=0.99) # to calculate the moving averages of mean and variance
bn_assigns = [] # this list stores the updates to be made to average mean and variance
def batch_normalization(batch, mean=None, var=None):
if mean is None or var is None:
mean, var = tf.nn.moments(batch, axes=[0])
return (batch - mean) / tf.sqrt(var + tf.constant(1e-10))
# average mean and variance of all layers
running_mean = [tf.Variable(tf.constant(0.0, shape=[l]), trainable=False) for l in layer_sizes[1:]]
running_var = [tf.Variable(tf.constant(1.0, shape=[l]), trainable=False) for l in layer_sizes[1:]]
def update_batch_normalization(batch, l):
"batch normalize + update average mean and variance of layer l"
mean, var = tf.nn.moments(batch, axes=[0])
assign_mean = running_mean[l-1].assign(mean)
assign_var = running_var[l-1].assign(var)
bn_assigns.append(ewma.apply([running_mean[l-1], running_var[l-1]]))
with tf.control_dependencies([assign_mean, assign_var]):
return (batch - mean) / tf.sqrt(var + 1e-10)
def encoder(inputs, noise_std):
h = inputs + tf.random_normal(tf.shape(inputs)) * noise_std # add noise to input
d = {} # to store the pre-activation, activation, mean and variance for each layer
# The data for labeled and unlabeled examples are stored separately
d['labeled'] = {'z': {}, 'm': {}, 'v': {}, 'h': {}}
d['unlabeled'] = {'z': {}, 'm': {}, 'v': {}, 'h': {}}
d['labeled']['z'][0], d['unlabeled']['z'][0] = split_lu(h)
for l in range(1, L+1):
print "Layer ", l, ": ", layer_sizes[l-1], " -> ", layer_sizes[l]
d['labeled']['h'][l-1], d['unlabeled']['h'][l-1] = split_lu(h)
z_pre = tf.matmul(h, weights['W'][l-1]) # pre-activation
z_pre_l, z_pre_u = split_lu(z_pre) # split labeled and unlabeled examples
m, v = tf.nn.moments(z_pre_u, axes=[0])
# if training:
def training_batch_norm():
# Training batch normalization
# batch normalization for labeled and unlabeled examples is performed separately
if noise_std > 0:
# Corrupted encoder
# batch normalization + noise
z = join(batch_normalization(z_pre_l), batch_normalization(z_pre_u, m, v))
z += tf.random_normal(tf.shape(z_pre)) * noise_std
else:
# Clean encoder
# batch normalization + update the average mean and variance using batch mean and variance of labeled examples
z = join(update_batch_normalization(z_pre_l, l), batch_normalization(z_pre_u, m, v))
return z
# else:
def eval_batch_norm():
# Evaluation batch normalization
# obtain average mean and variance and use it to normalize the batch
mean = ewma.average(running_mean[l-1])
var = ewma.average(running_var[l-1])
z = batch_normalization(z_pre, mean, var)
# Instead of the above statement, the use of the following 2 statements containing a typo
# consistently produces a 0.2% higher accuracy for unclear reasons.
# m_l, v_l = tf.nn.moments(z_pre_l, axes=[0])
# z = join(batch_normalization(z_pre_l, m_l, mean, var), batch_normalization(z_pre_u, mean, var))
return z
# perform batch normalization according to value of boolean "training" placeholder:
z = tf.cond(training, training_batch_norm, eval_batch_norm)
if l == L:
# use softmax activation in output layer
h = tf.nn.softmax(weights['gamma'][l-1] * (z + weights["beta"][l-1]))
else:
# use ReLU activation in hidden layers
h = tf.nn.relu(z + weights["beta"][l-1])
d['labeled']['z'][l], d['unlabeled']['z'][l] = split_lu(z)
d['unlabeled']['m'][l], d['unlabeled']['v'][l] = m, v # save mean and variance of unlabeled examples for decoding
d['labeled']['h'][l], d['unlabeled']['h'][l] = split_lu(h)
return h, d
print "=== Corrupted Encoder ==="
y_c, corr = encoder(inputs, noise_std)
print "=== Clean Encoder ==="
y, clean = encoder(inputs, 0.0) # 0.0 -> do not add noise
print "=== Decoder ==="
def g_gauss(z_c, u, size):
"gaussian denoising function proposed in the original paper"
wi = lambda inits, name: tf.Variable(inits * tf.ones([size]), name=name)
a1 = wi(0., 'a1')
a2 = wi(1., 'a2')
a3 = wi(0., 'a3')
a4 = wi(0., 'a4')
a5 = wi(0., 'a5')
a6 = wi(0., 'a6')
a7 = wi(1., 'a7')
a8 = wi(0., 'a8')
a9 = wi(0., 'a9')
a10 = wi(0., 'a10')
mu = a1 * tf.sigmoid(a2 * u + a3) + a4 * u + a5
v = a6 * tf.sigmoid(a7 * u + a8) + a9 * u + a10
z_est = (z_c - mu) * v + mu
return z_est
# Decoder
z_est = {}
d_cost = [] # to store the denoising cost of all layers
for l in range(L, -1, -1):
print "Layer ", l, ": ", layer_sizes[l+1] if l+1 < len(layer_sizes) else None, " -> ", layer_sizes[l], ", denoising cost: ", denoising_cost[l]
z, z_c = clean['unlabeled']['z'][l], corr['unlabeled']['z'][l]
m, v = clean['unlabeled']['m'].get(l, 0), clean['unlabeled']['v'].get(l, 1-1e-10)
if l == L:
u = unlabeled(y_c)
else:
u = tf.matmul(z_est[l+1], weights['V'][l])
u = batch_normalization(u)
z_est[l] = g_gauss(z_c, u, layer_sizes[l])
z_est_bn = (z_est[l] - m) / v
# append the cost of this layer to d_cost
d_cost.append((tf.reduce_mean(tf.reduce_sum(tf.square(z_est_bn - z), 1)) / layer_sizes[l]) * denoising_cost[l])
# calculate total unsupervised cost by adding the denoising cost of all layers
u_cost = tf.add_n(d_cost)
y_N = labeled(y_c)
cost = -tf.reduce_mean(tf.reduce_sum(outputs*tf.log(y_N), 1)) # supervised cost
loss = cost + u_cost # total cost
pred_cost = -tf.reduce_mean(tf.reduce_sum(outputs*tf.log(y), 1)) # cost used for prediction
correct_prediction = tf.equal(tf.argmax(y, 1), tf.argmax(outputs, 1)) # no of correct predictions
accuracy = tf.reduce_mean(tf.cast(correct_prediction, "float")) * tf.constant(100.0)
learning_rate = tf.Variable(starter_learning_rate, trainable=False)
train_step = tf.train.AdamOptimizer(learning_rate).minimize(loss)
# add the updates of batch normalization statistics to train_step
bn_updates = tf.group(*bn_assigns)
with tf.control_dependencies([train_step]):
train_step = tf.group(bn_updates)
print "=== Loading Data ==="
mnist = input_data.read_data_sets("MNIST_data", n_labeled=num_labeled, one_hot=True)
saver = tf.train.Saver()
print "=== Starting Session ==="
sess = tf.Session()
i_iter = 0
ckpt = tf.train.get_checkpoint_state('checkpoints/') # get latest checkpoint (if any)
if ckpt and ckpt.model_checkpoint_path:
# if checkpoint exists, restore the parameters and set epoch_n and i_iter
saver.restore(sess, ckpt.model_checkpoint_path)
epoch_n = int(ckpt.model_checkpoint_path.split('-')[1])
i_iter = (epoch_n+1) * (num_examples/batch_size)
print "Restored Epoch ", epoch_n
else:
# no checkpoint exists. create checkpoints directory if it does not exist.
if not os.path.exists('checkpoints'):
os.makedirs('checkpoints')
init = tf.global_variables_initializer()
sess.run(init)
print "=== Training ==="
print "Initial Accuracy: ", sess.run(accuracy, feed_dict={inputs: mnist.test.images, outputs: mnist.test.labels, training: False}), "%"
for i in tqdm(range(i_iter, num_iter)):
images, labels = mnist.train.next_batch(batch_size)
sess.run(train_step, feed_dict={inputs: images, outputs: labels, training: True})
if (i > 1) and ((i+1) % (num_iter/num_epochs) == 0):
epoch_n = i/(num_examples/batch_size)
if (epoch_n+1) >= decay_after:
# decay learning rate
# learning_rate = starter_learning_rate * ((num_epochs - epoch_n) / (num_epochs - decay_after))
ratio = 1.0 * (num_epochs - (epoch_n+1)) # epoch_n + 1 because learning rate is set for next epoch
ratio = max(0, ratio / (num_epochs - decay_after))
sess.run(learning_rate.assign(starter_learning_rate * ratio))
saver.save(sess, 'checkpoints/model.ckpt', epoch_n)
# print "Epoch ", epoch_n, ", Accuracy: ", sess.run(accuracy, feed_dict={inputs: mnist.test.images, outputs:mnist.test.labels, training: False}), "%"
with open('train_log', 'ab') as train_log:
# write test accuracy to file "train_log"
train_log_w = csv.writer(train_log)
log_i = [epoch_n] + sess.run([accuracy], feed_dict={inputs: mnist.test.images, outputs: mnist.test.labels, training: False})
train_log_w.writerow(log_i)
print "Final Accuracy: ", sess.run(accuracy, feed_dict={inputs: mnist.test.images, outputs: mnist.test.labels, training: False}), "%"
sess.close()