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vae.py
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vae.py
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import numpy as np
from scipy.stats import norm
import matplotlib.pyplot as plt
import dezero
import dezero.functions as F
import dezero.layers as L
from dezero import DataLoader
from dezero.models import Model
from dezero.optimizers import Adam
use_gpu = dezero.cuda.gpu_enable
max_epoch = 10
batch_size = 16
latent_size = 2
class Encoder(Model):
def __init__(self, latent_size):
super().__init__()
self.latent_size = latent_size
self.conv1 = L.Conv2d(32, kernel_size=3, stride=1, pad=1)
self.conv2 = L.Conv2d(64, kernel_size=3, stride=2, pad=1)
self.conv3 = L.Conv2d(64, kernel_size=3, stride=1, pad=1)
self.conv4 = L.Conv2d(64, kernel_size=3, stride=1, pad=1)
self.linear1 = L.Linear(32)
self.linear2 = L.Linear(latent_size)
self.linear3 = L.Linear(latent_size)
def forward(self, x):
x = F.relu(self.conv1(x))
x = F.relu(self.conv2(x))
x = F.relu(self.conv3(x))
x = F.relu(self.conv4(x))
x = F.flatten(x)
x = F.relu(self.linear1(x))
z_mean = self.linear2(x)
z_log_var = self.linear3(x)
return z_mean, z_log_var
def sampling(self, z_mean, z_log_var):
batch_size = len(z_mean)
xp = dezero.cuda.get_array_module(z_mean.data)
epsilon = xp.random.randn(batch_size, self.latent_size)
return z_mean + F.exp(z_log_var) * epsilon
class Decoder(Model):
def __init__(self):
super().__init__()
self.to_shape = (64, 14, 14) # (C, H, W)
self.linear = L.Linear(np.prod(self.to_shape))
self.deconv = L.Deconv2d(32, kernel_size=4, stride=2, pad=1)
self.conv = L.Conv2d(1, kernel_size=3, stride=1, pad=1)
def forward(self, x):
x = F.relu(self.linear(x))
x = F.reshape(x, (-1,) + self.to_shape) # reshape to (-1, C, H, W)
x = F.relu(self.deconv(x))
x = self.conv(x)
x = F.sigmoid(x)
return x
class VAE(Model):
def __init__(self, latent_size):
super().__init__()
self.encoder = Encoder(latent_size)
self.decoder = Decoder()
def forward(self, x, C=1.0, k=1):
"""Call loss function of VAE.
The loss value is equal to ELBO (Evidence Lower Bound)
multiplied by -1.
Args:
x (Variable or ndarray): Input variable.
C (int): Usually this is 1.0. Can be changed to control the
second term of ELBO bound, which works as regularization.
k (int): Number of Monte Carlo samples used in encoded vector.
"""
z_mean, z_log_var = self.encoder(x)
rec_loss = 0
for l in range(k):
z = self.encoder.sampling(z_mean, z_log_var)
y = self.decoder(z)
rec_loss += F.binary_cross_entropy(F.flatten(y), F.flatten(x)) / k
kl_loss = C * (z_mean ** 2 + F.exp(z_log_var) - z_log_var - 1) * 0.5
kl_loss = F.sum(kl_loss) / len(x)
return rec_loss + kl_loss
def show_digits(epoch=0):
"""Display a 2D manifold of the digits"""
n = 15 # 15x15 digits
digit_size = 28
figure = np.zeros((digit_size * n, digit_size * n))
grid_x = norm.ppf(np.linspace(0.05, 0.95, n))
grid_y = norm.ppf(np.linspace(0.05, 0.95, n))
for i, yi in enumerate(grid_x):
for j, xi in enumerate(grid_y):
z_sample = np.array([[xi, yi]])
if use_gpu:
z_sample = dezero.cuda.as_cupy(z_sample)
with dezero.no_grad():
x_decoded = vae.decoder(z_sample)
if use_gpu:
x_decoded.data = dezero.cuda.as_numpy(x_decoded.data)
digit = x_decoded.data.reshape(digit_size, digit_size)
figure[i * digit_size: (i + 1) * digit_size,
j * digit_size: (j + 1) * digit_size] = digit
plt.figure(figsize=(10, 10))
plt.axis('off')
plt.imshow(figure, cmap='Greys_r')
plt.show()
#plt.savefig('vae_{}.png'.format(epoch))
vae = VAE(latent_size)
optimizer = Adam().setup(vae)
transform = lambda x: (x / 255.0).astype(np.float32)
train_set = dezero.datasets.MNIST(train=True, transform=transform)
train_loader = DataLoader(train_set, batch_size)
if use_gpu:
vae.to_gpu()
train_loader.to_gpu()
xp = dezero.cuda.cupy
else:
xp = np
for epoch in range(max_epoch):
avg_loss = 0
cnt = 0
for x, t in train_loader:
cnt += 1
loss = vae(x)
vae.cleargrads()
loss.backward()
optimizer.update()
avg_loss += loss.data
interval = 100 if use_gpu else 10
if cnt % interval == 0:
epoch_detail = epoch + cnt / train_loader.max_iter
print('epoch: {:.2f}, loss: {:.4f}'.format(epoch_detail,
float(avg_loss/cnt)))
show_digits(epoch)