Note
Click here to download the full example code
Neural Networks¶
Neural networks can be constructed using the torch.nn
package.
Now that you had a glimpse of autograd
, nn
depends on
autograd
to define models and differentiate them.
An nn.Module
contains layers, and a method forward(input)
that
returns the output
.
For example, look at this network that classifies digit images:
It is a simple feed-forward network. It takes the input, feeds it through several layers one after the other, and then finally gives the output.
A typical training procedure for a neural network is as follows:
- Define the neural network that has some learnable parameters (or weights)
- Iterate over a dataset of inputs
- Process input through the network
- Compute the loss (how far is the output from being correct)
- Propagate gradients back into the network’s parameters
- Update the weights of the network, typically using a simple update rule:
weight = weight - learning_rate * gradient
Define the network¶
Let’s define this network:
import torch
import torch.nn as nn
import torch.nn.functional as F
class Net(nn.Module):
def __init__(self):
super(Net, self).__init__()
# 1 input image channel, 6 output channels, 5x5 square convolution
# kernel
self.conv1 = nn.Conv2d(1, 6, 5)
self.conv2 = nn.Conv2d(6, 16, 5)
# an affine operation: y = Wx + b
self.fc1 = nn.Linear(16 * 5 * 5, 120)
self.fc2 = nn.Linear(120, 84)
self.fc3 = nn.Linear(84, 10)
def forward(self, x):
# Max pooling over a (2, 2) window
x = F.max_pool2d(F.relu(self.conv1(x)), (2, 2))
# If the size is a square you can only specify a single number
x = F.max_pool2d(F.relu(self.conv2(x)), 2)
x = x.view(-1, self.num_flat_features(x))
x = F.relu(self.fc1(x))
x = F.relu(self.fc2(x))
x = self.fc3(x)
return x
def num_flat_features(self, x):
size = x.size()[1:] # all dimensions except the batch dimension
num_features = 1
for s in size:
num_features *= s
return num_features
net = Net()
print(net)
Out:
Net(
(conv1): Conv2d(1, 6, kernel_size=(5, 5), stride=(1, 1))
(conv2): Conv2d(6, 16, kernel_size=(5, 5), stride=(1, 1))
(fc1): Linear(in_features=400, out_features=120, bias=True)
(fc2): Linear(in_features=120, out_features=84, bias=True)
(fc3): Linear(in_features=84, out_features=10, bias=True)
)
You just have to define the forward
function, and the backward
function (where gradients are computed) is automatically defined for you
using autograd
.
You can use any of the Tensor operations in the forward
function.
The learnable parameters of a model are returned by net.parameters()
params = list(net.parameters())
print(len(params))
print(params[0].size()) # conv1's .weight
Out:
10
torch.Size([6, 1, 5, 5])
Let try a random 32x32 input Note: Expected input size to this net(LeNet) is 32x32. To use this net on MNIST dataset, please resize the images from the dataset to 32x32.
input = torch.randn(1, 1, 32, 32)
out = net(input)
print(out)
Out:
tensor([[ 0.1246, -0.0511, 0.0235, 0.1766, -0.0359, -0.0334, 0.1161, 0.0534,
0.0282, -0.0202]], grad_fn=<AddmmBackward>)
Zero the gradient buffers of all parameters and backprops with random gradients:
net.zero_grad()
out.backward(torch.randn(1, 10))
Note
torch.nn
only supports mini-batches. The entire torch.nn
package only supports inputs that are a mini-batch of samples, and not
a single sample.
For example, nn.Conv2d
will take in a 4D Tensor of
nSamples x nChannels x Height x Width
.
If you have a single sample, just use input.unsqueeze(0)
to add
a fake batch dimension.
Before proceeding further, let’s recap all the classes you’ve seen so far.
- Recap:
torch.Tensor
- A multi-dimensional array with support for autograd operations likebackward()
. Also holds the gradient w.r.t. the tensor.nn.Module
- Neural network module. Convenient way of encapsulating parameters, with helpers for moving them to GPU, exporting, loading, etc.nn.Parameter
- A kind of Tensor, that is automatically registered as a parameter when assigned as an attribute to aModule
.autograd.Function
- Implements forward and backward definitions of an autograd operation. EveryTensor
operation, creates at least a singleFunction
node, that connects to functions that created aTensor
and encodes its history.
- At this point, we covered:
- Defining a neural network
- Processing inputs and calling backward
- Still Left:
- Computing the loss
- Updating the weights of the network
Loss Function¶
A loss function takes the (output, target) pair of inputs, and computes a value that estimates how far away the output is from the target.
There are several different
loss functions under the
nn package .
A simple loss is: nn.MSELoss
which computes the mean-squared error
between the input and the target.
For example:
output = net(input)
target = torch.randn(10) # a dummy target, for example
target = target.view(1, -1) # make it the same shape as output
criterion = nn.MSELoss()
loss = criterion(output, target)
print(loss)
Out:
tensor(1.3638, grad_fn=<MseLossBackward>)
Now, if you follow loss
in the backward direction, using its
.grad_fn
attribute, you will see a graph of computations that looks
like this:
input -> conv2d -> relu -> maxpool2d -> conv2d -> relu -> maxpool2d
-> view -> linear -> relu -> linear -> relu -> linear
-> MSELoss
-> loss
So, when we call loss.backward()
, the whole graph is differentiated
w.r.t. the loss, and all Tensors in the graph that has requires_grad=True
will have their .grad
Tensor accumulated with the gradient.
For illustration, let us follow a few steps backward:
print(loss.grad_fn) # MSELoss
print(loss.grad_fn.next_functions[0][0]) # Linear
print(loss.grad_fn.next_functions[0][0].next_functions[0][0]) # ReLU
Out:
<MseLossBackward object at 0x7f82bad9ce80>
<AddmmBackward object at 0x7f82bad9ee80>
<AccumulateGrad object at 0x7f82bad9ce80>
Backprop¶
To backpropagate the error all we have to do is to loss.backward()
.
You need to clear the existing gradients though, else gradients will be
accumulated to existing gradients.
Now we shall call loss.backward()
, and have a look at conv1’s bias
gradients before and after the backward.
net.zero_grad() # zeroes the gradient buffers of all parameters
print('conv1.bias.grad before backward')
print(net.conv1.bias.grad)
loss.backward()
print('conv1.bias.grad after backward')
print(net.conv1.bias.grad)
Out:
conv1.bias.grad before backward
tensor([0., 0., 0., 0., 0., 0.])
conv1.bias.grad after backward
tensor([ 0.0181, -0.0048, -0.0229, -0.0138, -0.0088, -0.0107])
Now, we have seen how to use loss functions.
Read Later:
The neural network package contains various modules and loss functions that form the building blocks of deep neural networks. A full list with documentation is here.
The only thing left to learn is:
- Updating the weights of the network
Update the weights¶
The simplest update rule used in practice is the Stochastic Gradient Descent (SGD):
weight = weight - learning_rate * gradient
We can implement this using simple python code:
learning_rate = 0.01
for f in net.parameters():
f.data.sub_(f.grad.data * learning_rate)
However, as you use neural networks, you want to use various different
update rules such as SGD, Nesterov-SGD, Adam, RMSProp, etc.
To enable this, we built a small package: torch.optim
that
implements all these methods. Using it is very simple:
import torch.optim as optim
# create your optimizer
optimizer = optim.SGD(net.parameters(), lr=0.01)
# in your training loop:
optimizer.zero_grad() # zero the gradient buffers
output = net(input)
loss = criterion(output, target)
loss.backward()
optimizer.step() # Does the update
Note
Observe how gradient buffers had to be manually set to zero using
optimizer.zero_grad()
. This is because gradients are accumulated
as explained in Backprop section.
Total running time of the script: ( 0 minutes 0.157 seconds)