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++.

  • 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?… – Yaroslav Bulatov Apr 6 '16 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 – black_puppydog Apr 7 '16 at 13:17
up vote 28 down vote accepted

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

  • 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? – black_puppydog Apr 12 '16 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 – Yaroslav Bulatov Apr 12 '16 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 :) – black_puppydog Apr 25 '16 at 9:26
  • Exactly what I needed. Maybe this should be a built-in? – Paulo Costa May 23 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 at 21:39

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

t = g(x)
y = tf.stop_gradient(f(x) / t) * t
  • 1
    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 '17 at 16:42

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