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main.py
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main.py
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import torch
import torch.nn as nn
import torch.nn.functional as F
from torch.autograd import Variable
import torch.optim as optim
from torchvision import datasets, transforms
from tqdm import tqdm
import os
from tensorboardX import SummaryWriter
glo_batch_size = 100
data_transform = transforms.Compose([
transforms.ToTensor(),
transforms.Normalize((0.1307,),(0.3081,))
])
train_loader = torch.utils.data.DataLoader(datasets.MNIST('mnist', train = True, download = True, transform = data_transform),
batch_size = glo_batch_size, shuffle = True
)
test_loader = torch.utils.data.DataLoader(datasets.MNIST('mnist', train = False, download = True, transform = data_transform),
batch_size = glo_batch_size, shuffle = True
)
class CapsNet(nn.Module):
conv1_kernel_size = 9
conv1_kernel_num = 256
conv1_stride = 1
caps1_conv_kernel_size = 9
caps1_conv_kernel_num = 32
caps1_conv1_stride = 2
caps1_num = 8
output_num = 10
output_size = 16
batch_size = glo_batch_size
def __init__(self, dataloader):
super(CapsNet, self).__init__()
self.dataloader = dataloader
self.build()
def create_cell_fn(self):
"""
create sub-network inside a capsule.
:return:
"""
conv1 = nn.Conv2d(self.conv1_kernel_num, self.caps1_conv_kernel_num, kernel_size = self.caps1_conv_kernel_size, stride = self.caps1_conv1_stride)
#relu = nn.ReLU(inplace = True)
#net = nn.Sequential(conv1, relu)
return conv1
def build(self):
conv1 = nn.Conv2d(1, self.conv1_kernel_num, kernel_size = self.conv1_kernel_size, stride = self.conv1_stride)
relu1 = nn.ReLU(inplace = True)
caps1_cells = [self.create_cell_fn() for i in range(self.caps1_num)]
cap1 = Caps(caps1_cells)
route1 = Route(self.caps1_num, 6*6*self.caps1_conv_kernel_num, self.output_num, self.output_size, batch_size = self.batch_size)
self.net = nn.Sequential(conv1, relu1, cap1, route1)
def forward(self, input):
return self.net(input)
def margin_loss(self, input, target):
v_mod = torch.sqrt(torch.mul(input,input).sum(dim = 2, keepdim = True))
m_plus = 0.9
m_minus = 0.1
zero_val = Variable(torch.zeros(1)).cuda()
max_l = torch.max(m_plus - v_mod, zero_val).view(self.batch_size, -1)
max_r = torch.max(v_mod - m_minus, zero_val).view(self.batch_size, -1)
Lc = target * max_l + 0.5 * (1 - target) * (max_r)
Lc = Lc.sum(dim = 1).mean()
return Lc
class Route(nn.Module):
def __init__(self, in_caps_num, in_caps_size, out_caps_num, out_caps_size, batch_size):
super(Route, self).__init__()
self.in_caps_num = in_caps_num
self.in_caps_size = in_caps_size
self.out_caps_num = out_caps_num
self.out_caps_size = out_caps_size
self.batch_size = glo_batch_size
#we can not use batch_size for W parameters as the network does not include batch factor.
self.W = nn.Parameter(torch.randn(1, in_caps_size, out_caps_num, out_caps_size, in_caps_num))
def softmax(self, input, dim):
input_ex = torch.exp(input)
return input_ex / input_ex.sum(dim, keepdim = True)
def squash(self, input):
mod_sq = torch.sum(input**2, dim = 2, keepdim = True)
mod = torch.sqrt(mod_sq)
return (mod / (1 + mod)) * (input / mod_sq)
def forward(self, input):
#input (batch, in_caps_num, in_caps_size) => (batch, in_caps_size, in_caps_num)
input = torch.transpose(input, 1, 2)
#input (batch, vectorsin_caps_size, in_caps_num) =.(batch, in_caps_size, out_caps_num, in_caps_num, 1)
input = torch.stack([input]*self.out_caps_num, dim = 2).unsqueeze(4)
#u_hat : (batch, in_caps_size, out_caps_num, out_caps_size, 1)
# = (batch, in_caps_size, out_caps_num, out_caps_size, in_caps_num)
# * (batch, in_caps_size, out_caps_num, in_caps_num, 1)
u_hat = torch.matmul(torch.cat([self.W] * self.batch_size, 0) , input)
#initialzie b_ij according to prior prob distribution
#b_ij (1, in_caps_size, out_caps_num, 1), do not include batch_size
b_ij = Variable(torch.zeros(1, self.in_caps_size, self.out_caps_num, 1)).cuda()
#start routing now.
for _ in range(3):
#convert to coupling parameters, (batch_size, in_caps_size, out_caps_num, 1)
c_ij = self.softmax(b_ij, dim = 2)
c_ij = torch.cat([c_ij] * self.batch_size, dim = 0).unsqueeze(4)
#Here using broadcasting mechnism.
#s_j : (batch, in_caps_size, out_caps_num, out_caps_size, 1)
# = (batch, in_caps_size, out_caps_num, 1, 1)
# * (batch, in_caps_size, out_caps_num, out_caps_size, 1)
#sum: (batch, 1 , out_caps_num, out_caps_size, 1)
s_j = torch.mul(c_ij, u_hat).sum(dim = 1, keepdim = True)
#squash s_j to v_j (batch, 1, out_caps_num, out_caps_size, 1)
v_j = self.squash(s_j)
#in order to satifiy u_hat * v_j, we expand its dimension
#=> (batch, in_caps_size, out_caps_num, out_caps_size, 1)
v_j_ext = torch.cat([v_j] * self.in_caps_size, dim = 1)
#u_hat transpose => (batch, in_caps_size, out_caps_num, 1, out_caps_size)
#v_j_ext (batch, in_caps_size, out_caps_num, out_caps_size, 1)
#matmul => (batch, in_caps_size, out_caps_num, 1 , 1)
#seueeze => (batch, in_caps_size, out_caps_num, 1)
#mean => ( 1 , in_caps_size, out_caps_num, 1)
uv = torch.matmul(u_hat.transpose(3,4), v_j_ext).squeeze(4).mean(dim = 0, keepdim = True)
#update b_ij
b_ij = b_ij + uv
#return (batch, out_caps_num, out_caps_size, 1)
return v_j.squeeze(1)
class Caps(nn.Module):
"""
Capsule layer, this layer is a wrapper of any kinds of sub-layer inside single capsule. When initialized, it received a create_cell_fn to create each
sub network for each capsules and compute each capsule output.
In the feature, we can put all current network as a capsule unit.
"""
def __init__(self, cells):
super(Caps, self).__init__()
self.cells = cells
self.caps_num = len(cells)
for i, cell in enumerate(cells):
self.add_module("subnet"+str(i),cell)
def forward(self, input):
#u=[val] : val: (batch, channels, height, width)
u = [self.cells[i](input) for i in range(self.caps_num)]
# stack the caps_num axis before channels axis.
#=> (batch, caps_num, channels, height, width)
u = torch.stack(u, dim = 1)
#flat to (batch, caps_num, output)
u = u.view(input.size(0), self.caps_num, -1)
#squash output
return self.squash(u)
def squash(self, input):
mod_sq = torch.sum(input**2, dim = 2, keepdim = True)
mod = torch.sqrt(mod_sq)
return (mod / (1 + mod)) * (input / mod_sq)
def to_one_hot(x, length):
batch_size = x.size(0)
x_one_hot = torch.zeros(batch_size, length)
for i in range(batch_size):
x_one_hot[i, x[i]] = 1.0
return x_one_hot
if __name__ == '__main__':
net = CapsNet(train_loader)
net.cuda()
print(net)
optimizer = optim.Adam(net.parameters(), lr = 1e-3)
tb = SummaryWriter()
if os.path.exists('mdl'):
with open('mdl','rb') as f:
net = torch.load('mdl')
print('load mdl yet.')
for epoch in range(30):
net.train()
for batch_idx, (data, target) in enumerate(tqdm(train_loader, total = len(train_loader), ncols=100, leave=False, unit='b'+str(epoch))):
target_onehot = to_one_hot(target, 10)
data, target = Variable(data).cuda(), Variable(target_onehot).cuda()
optimizer.zero_grad()
output = net(data)
loss = net.margin_loss(output, target)
loss.backward()
optimizer.step()
if batch_idx % 50 == 0 and batch_idx != 0:
tb.add_scalar('loss', loss.data[0])
net.eval()
correct_prediction = 0.0
total_counter = 0
for batch_idx, (data, target) in enumerate(test_loader):
data, target = Variable(data).cuda(), Variable(target.type(torch.LongTensor)).cuda()
#pred [batch, out_caps_num, out_caps_size, 1]
pred = net(data)
# pred_mod [batch, out_caps_num, 1, 1] => [batch, out_caps_num]
pred_mod = pred.mul(pred).sum(dim = 2).sqrt().squeeze(2)
# v1 [batch]
_ , v1 = torch.max(pred_mod , dim = 1)
correct_prediction += target.eq(v1).sum().data.cpu().numpy()[0]
total_counter += glo_batch_size
if batch_idx % 100 == 0:
tb.add_scalar('accuracy', correct_prediction/(total_counter))
break
print(epoch, 'test accuracy:', correct_prediction/(total_counter))
torch.save(net, 'mdl')
print('saved to mol file.')
tb.close()