Understanding torch.nn.Parameter
Question:
How does torch.nn.Parameter() work?
Answers:
I will break it down for you. Tensors, as you might know, are multi dimensional matrices. Parameter, in its raw form, is a tensor i.e. a multi dimensional matrix. It sub-classes the Variable class.
The difference between a Variable and a Parameter comes in when associated with a module. When a Parameter is associated with a module as a model attribute, it gets added to the parameter list automatically and can be accessed using the ‘parameters’ iterator.
Initially in Torch, a Variable (which could for example be an intermediate state) would also get added as a parameter of the model upon assignment. Later on there were use cases identified where a need to cache the variables instead of having them added to the parameter list was identified.
One such case, as mentioned in the documentation is that of RNN, where in you need to save the last hidden state so you don’t have to pass it again and again. The need to cache a Variable instead of having it automatically register as a parameter to the model is why we have an explicit way of registering parameters to our model i.e. nn.Parameter class.
For instance, run the following code –
import torch
import torch.nn as nn
from torch.optim import Adam
class NN_Network(nn.Module):
def __init__(self,in_dim,hid,out_dim):
super(NN_Network, self).__init__()
self.linear1 = nn.Linear(in_dim,hid)
self.linear2 = nn.Linear(hid,out_dim)
self.linear1.weight = torch.nn.Parameter(torch.zeros(in_dim,hid))
self.linear1.bias = torch.nn.Parameter(torch.ones(hid))
self.linear2.weight = torch.nn.Parameter(torch.zeros(in_dim,hid))
self.linear2.bias = torch.nn.Parameter(torch.ones(hid))
def forward(self, input_array):
h = self.linear1(input_array)
y_pred = self.linear2(h)
return y_pred
in_d = 5
hidn = 2
out_d = 3
net = NN_Network(in_d, hidn, out_d)
Now, check the parameter list associated with this model –
for param in net.parameters():
print(type(param.data), param.size())
""" Output
<class 'torch.FloatTensor'> torch.Size([5, 2])
<class 'torch.FloatTensor'> torch.Size([2])
<class 'torch.FloatTensor'> torch.Size([5, 2])
<class 'torch.FloatTensor'> torch.Size([2])
"""
Or try,
list(net.parameters())
This can easily be fed to your optimizer –
opt = Adam(net.parameters(), learning_rate=0.001)
Also, note that Parameters have require_grad set by default.
Recent PyTorch releases just have Tensors, it came out the concept of the Variable has been deprecated.
Parameters are just Tensors limited to the module they are defined in (in the module constructor __init__ method).
They will appear inside module.parameters().
This comes handy when you build your custom modules that learn thanks to these parameters gradient descent.
Anything that is true for the PyTorch tensors is true for parameters, since they are tensors.
Additionally, if a module goes to the GPU, parameters go as well. If a module is saved parameters will also be saved.
There is a similar concept to model parameters called buffers.
These are named tensors inside the module, but these tensors are not meant to learn via gradient descent, instead you can think these are like variables. You will update your named buffers inside module forward() as you like.
For buffers, it is also true they will go to the GPU with the module, and they will be saved together with the module.
How does torch.nn.Parameter() work?
I will break it down for you. Tensors, as you might know, are multi dimensional matrices. Parameter, in its raw form, is a tensor i.e. a multi dimensional matrix. It sub-classes the Variable class.
The difference between a Variable and a Parameter comes in when associated with a module. When a Parameter is associated with a module as a model attribute, it gets added to the parameter list automatically and can be accessed using the ‘parameters’ iterator.
Initially in Torch, a Variable (which could for example be an intermediate state) would also get added as a parameter of the model upon assignment. Later on there were use cases identified where a need to cache the variables instead of having them added to the parameter list was identified.
One such case, as mentioned in the documentation is that of RNN, where in you need to save the last hidden state so you don’t have to pass it again and again. The need to cache a Variable instead of having it automatically register as a parameter to the model is why we have an explicit way of registering parameters to our model i.e. nn.Parameter class.
For instance, run the following code –
import torch
import torch.nn as nn
from torch.optim import Adam
class NN_Network(nn.Module):
def __init__(self,in_dim,hid,out_dim):
super(NN_Network, self).__init__()
self.linear1 = nn.Linear(in_dim,hid)
self.linear2 = nn.Linear(hid,out_dim)
self.linear1.weight = torch.nn.Parameter(torch.zeros(in_dim,hid))
self.linear1.bias = torch.nn.Parameter(torch.ones(hid))
self.linear2.weight = torch.nn.Parameter(torch.zeros(in_dim,hid))
self.linear2.bias = torch.nn.Parameter(torch.ones(hid))
def forward(self, input_array):
h = self.linear1(input_array)
y_pred = self.linear2(h)
return y_pred
in_d = 5
hidn = 2
out_d = 3
net = NN_Network(in_d, hidn, out_d)
Now, check the parameter list associated with this model –
for param in net.parameters():
print(type(param.data), param.size())
""" Output
<class 'torch.FloatTensor'> torch.Size([5, 2])
<class 'torch.FloatTensor'> torch.Size([2])
<class 'torch.FloatTensor'> torch.Size([5, 2])
<class 'torch.FloatTensor'> torch.Size([2])
"""
Or try,
list(net.parameters())
This can easily be fed to your optimizer –
opt = Adam(net.parameters(), learning_rate=0.001)
Also, note that Parameters have require_grad set by default.
Recent PyTorch releases just have Tensors, it came out the concept of the Variable has been deprecated.
Parameters are just Tensors limited to the module they are defined in (in the module constructor __init__ method).
They will appear inside module.parameters().
This comes handy when you build your custom modules that learn thanks to these parameters gradient descent.
Anything that is true for the PyTorch tensors is true for parameters, since they are tensors.
Additionally, if a module goes to the GPU, parameters go as well. If a module is saved parameters will also be saved.
There is a similar concept to model parameters called buffers.
These are named tensors inside the module, but these tensors are not meant to learn via gradient descent, instead you can think these are like variables. You will update your named buffers inside module forward() as you like.
For buffers, it is also true they will go to the GPU with the module, and they will be saved together with the module.