18

First: I am only a few days in with Tensorflow, so please bear with me.

I started out from the cifar10 tutorial code and I am now using a combination of convolutions and eigenvalue decompositions that break the symbolic differentiation. I.e. the graph gets built, then upon calling train() the script halts with "No gradient defined for operation [...] (op type: SelfAdjointEig)". No surprise there.

The inputs to the subgraph in question are still only the input feature maps and the filters being used, and I have the formulas for the gradients at hand and they should be straight-forward to implement given the inputs to the subgraph and the gradient with respect to its output.

From what I can see in the docs, I can register a gradient method for custom Ops with RegisterGradient or override them with the experimental gradient_override_map. Both of those should give me access to exactly the things I need. For example, searching on Github I find a lot of examples that access the op's inputs as op.input[0] or such.

The problem I have is that I want to essentially "shortcut" a whole subgraph, not a single op, so I have no single op to decorate. Since this is happening in one of the convolutional layers of the cifar example I tried using the scope object for that layer. Conceptually, what enters and exits that scope's graph is exactly what I want so if I could somehow override the whole scope's gradients that would "already" do it.

I saw tf.Graph.create_op which (I think) I could use to register a new type of operation and I could then override that Operation type's gradient computation with aforementioned methods. But I don't see a way of defining that op's forward pass without writing it in C++...

Maybe I am approaching this the wrong way entirely? Since all of my forward or backward operations can be implemented with the python interface I obviously want to avoid implementing anything in C++.

2
  • Maybe you can override the gradient for a single op on top of your undifferentiable graph, and then use tf.stop_gradient() to prevent the gradient construction for that subgraph? stackoverflow.com/questions/33727935/… Apr 6, 2016 at 17:23
  • I can imagine locally defining a gradient function, then using the still in-scope inputs in that. But how would I tell tf which nodes' gradients I take as inputs to that gradient computation? This feels to me like I am fundamentally misusing the framework :P Apr 7, 2016 at 13:17

4 Answers 4

32

Here's a trick from Sergey Ioffe:

Suppose you want group of ops that behave as f(x) in forward mode, but as g(x) in the backward mode. You implement it as

t = g(x)
y = t + tf.stop_gradient(f(x) - t)

So in your case your g(x) could be an identity op, with a custom gradient using gradient_override_map

5
  • 2
    For comprehension: the stop_gradient call takes care of the automatic gradient bit, overriding the gradient for g gives me the ability to insert my own and the t + f(x) - t will be opimized away? Apr 12, 2016 at 16:26
  • 3
    Value of "t + f(x) - t" is equal to "f(x)". It's computationally equivalent in current version, but in future version it may be optimized away Apr 12, 2016 at 16:40
  • 2
    Finally was able to apply this, albeit not for the same function after all. But this does not generalize well to "compound operations" with multiple inputs because the "add-subtract" doesn't work, does it? The best I could think of (but didn't have to try after all) was somehow using tuples instead of an identity op. But I am a bit unclear on how the graph would look afterwards. Anyway, huge thank you :) Apr 25, 2016 at 9:26
  • Exactly what I needed. Maybe this should be a built-in? May 23, 2018 at 15:49
  • The given solution is neat if you assume that you can easily cancel-out (e.g. subtraction inside stop_gradient) the effect that the backward pass will have on the forward pass. However, assume that the forward function generates a set of random indices that are used to shuffle some features and/or labels used in the network/loss. In this case, a simple "subtraction" will not cancel the effect of calling the randomizer twice. How could we make the second (backward) call innocuous?
    – Peter
    Jun 12, 2018 at 21:39
2

From TensorFlow 1.7 onward, tf.custom_gradient is the way to go.

0

How about multiply and divide, instead of adding and subtracting t?

t = g(x)
y = tf.stop_gradient(f(x) / t) * t
1
  • 2
    dy/dt here is (f(x)/t)*dy - not what we wanted. stopping the gradient through the left hand side doesn't prevent the derivative of multiplication using the forward result.
    – lahwran
    May 12, 2017 at 16:42
0

Here is the approach which works for TensorFlow 2.0. Note that in 2.0 we are happy to have 2 different autodiff algorithms: GradientTape for eager mode and tf.gradient for the non-eager mode (here called "lazy"). We demonstrate that tf.custom_gradient works both ways.

import tensorflow as tf
assert tf.version.VERSION.startswith('2.')
import numpy as np
from tensorflow.python.framework.ops import disable_eager_execution, enable_eager_execution
from tensorflow.python.client.session import Session

@tf.custom_gradient
def mysquare(x):
  res = x * x
  def _grad(dy):
    return dy * (2*x)
  return res, _grad

def run_eager():
  enable_eager_execution()

  x = tf.constant(np.array([[1,2,3],[4,5,6]]).astype('float32'))
  with tf.GradientTape() as tape:
    tape.watch(x)
    y = tf.reduce_sum(mysquare(x))

    dy_dx = tape.gradient(y,x)
    print('Eager mode')
    print('x:\n',x.numpy())
    print('y:\n',y.numpy())
    print('dy_dx:\n',dy_dx.numpy())


def run_lazy():
  disable_eager_execution()

  x = tf.constant(np.array([[1,2,3],[4,5,6]]).astype('float32'))
  y = tf.reduce_sum(mysquare(x))
  dy_dx = tf.gradients(y,x)

  with Session() as s:
    print('Lazy mode')
    print('x:\n',x.eval(session=s))
    print('y:\n',y.eval(session=s))
    assert len(dy_dx)==1
    print('dy_dx:\n',dy_dx[0].eval(session=s))

if __name__ == '__main__':
  run_eager()
  run_lazy()

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

Not the answer you're looking for? Browse other questions tagged or ask your own question.