Note
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Autograd¶
Autograd is now a core torch package for automatic differentiation. It uses a tape based system for automatic differentiation.
In the forward phase, the autograd tape will remember all the operations it executed, and in the backward phase, it will replay the operations.
Tensors that track history¶
In autograd, if any input Tensor
of an operation has requires_grad=True
,
the computation will be tracked. After computing the backward pass, a gradient
w.r.t. this tensor is accumulated into .grad
attribute.
There’s one more class which is very important for autograd
implementation - a Function
. Tensor
and Function
are
interconnected and build up an acyclic graph, that encodes a complete
history of computation. Each variable has a .grad_fn
attribute that
references a function that has created a function (except for Tensors
created by the user - these have None
as .grad_fn
).
If you want to compute the derivatives, you can call .backward()
on
a Tensor
. If Tensor
is a scalar (i.e. it holds a one element
tensor), you don’t need to specify any arguments to backward()
,
however if it has more elements, you need to specify a grad_output
argument that is a tensor of matching shape.
import torch
Create a tensor and set requires_grad=True to track computation with it
x = torch.ones(2, 2, requires_grad=True)
print(x)
print(x.data)
print(x.grad)
print(x.grad_fn) # we've created x ourselves
Do an operation of x:
y = x + 2
print(y)
y was created as a result of an operation, so it has a grad_fn
print(y.grad_fn)
More operations on y:
z = y * y * 3
out = z.mean()
print(z, out)
.requires_grad_( ... )
changes an existing Tensor’s requires_grad
flag in-place. The input flag defaults to True
if not given.
a = torch.randn(2, 2)
a = ((a * 3) / (a - 1))
print(a.requires_grad)
a.requires_grad_(True)
print(a.requires_grad)
b = (a * a).sum()
print(b.grad_fn)
Gradients¶
let’s backprop now and print gradients d(out)/dx
out.backward()
print(x.grad)
By default, gradient computation flushes all the internal buffers
contained in the graph, so if you even want to do the backward on some
part of the graph twice, you need to pass in retain_variables = True
during the first pass.
x = torch.ones(2, 2, requires_grad=True)
y = x + 2
y.backward(torch.ones(2, 2), retain_graph=True)
# the retain_variables flag will prevent the internal buffers from being freed
print(x.grad)
z = y * y
print(z)
just backprop random gradients
gradient = torch.randn(2, 2)
# this would fail if we didn't specify
# that we want to retain variables
y.backward(gradient)
print(x.grad)
You can also stops autograd from tracking history on Tensors
with requires_grad=True by wrapping the code block in
with torch.no_grad():
print(x.requires_grad)
print((x ** 2).requires_grad)
with torch.no_grad():
print((x ** 2).requires_grad)
Total running time of the script: ( 0 minutes 0.000 seconds)