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I'm trying to learn how autograd works in PyTorch. In the simple program below, I don't understand why gradients of loss w.r.t W1 and W2 are None. As far as I understand from the documentation, W1 and W2 are volatile, therefore gradients cannot be computed. Is that it? I mean, how I cannot take derivative of the loss w.r.t intermediate nodes? Can anyone explain me what I am missing here?

import torch
import torch.autograd as tau

W = tau.Variable(torch.FloatTensor([[0, 1]]), requires_grad=True)
a = tau.Variable(torch.FloatTensor([[2, 2]]), requires_grad=False)
b = tau.Variable(torch.FloatTensor([[3, 3]]), requires_grad=False)

W1 = W  + a * a
W2 = W1 - b * b * b
Z = W2 * W2

print 'W:', W
print 'W1:', W1
print 'W2:', W2
print 'Z:', Z

loss = torch.sum((Z - 3) * (Z - 3))
print 'loss:', loss

# free W gradient buffer in case you are running this cell more than 2 times
if W.grad is not None: W.grad.data.zero_()

loss.backward()
print 'W.grad:', W.grad

# all of them are None
print 'W1.grad:', W1.grad
print 'W2.grad:', W2.grad
print 'a.grad:', a.grad
print 'b.grad:', b.grad
print 'Z.grad:', Z.grad

1 Answer 1

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When required, intermediate gradients are accumulated in a C++ buffer but in order to save memory they are not retained by default (exposed in python object). Only gradients of leaf Variables set with requires_grad=True will be retained (so Win your example)

One way to retain intermediate gradients is to register a hook. One hook for this job is retain_grad() (see PR) In your example, if you write W2.retain_grad(), intermediate gradient of W2 will be exposed in W2.grad

W1 and W2 are not volatile (you can check by accessing their volatile attribute (ie: W1.volatile)) and cannot be because they are not leaf variables (such as W, a and b). On the contrary, the computation of their gradients is required, see their requires_grad attribute. If only one leaf variable is volatile, the whole backward graph is not constructed (You can check by making a volatile and look at the loss gradient function)

a = tau.Variable(torch.FloatTensor([[2, 2]]), volatile=True)
# ...
assert loss.grad_fn is None

To sum up

  • Volatility implies no gradient computation: Useful in inference mode
    • Only one leaf variable set volatile disable gradient computation
  • Requiring gradients implies gradient computation. Intermediate ones are exposed or not
    • Only one leaf variable requiring grad enable gradient computation
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  • Thank you for your answer. It's much more clear now. Jan 2, 2018 at 5:43
  • Hi, which pytorch version is that? In 0.3 and 0.4 even if I set W2.retain_grad=True, I don't get W2.grad.
    – aerin
    Aug 1, 2018 at 2:05
  • Hi, I think it was v0.3. In order to retain an intermediate gradient on W2, have you tried to init the W variable with requires_grad=True (as in OP' question) and to call retain_grad() on W2 ? (Also, setting W2.retain_grad to True will override the method aiming at effectively retaining the gradient through a hook)
    – x0s
    Aug 2, 2018 at 9:41

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