EDIT : the problem with my implementation was trying to extract my output, IE a one-hot vector, directly from the hidden state. I added a dense layer on top instead and it works fine.


I'm trying to make an LSTM from more primitive operations in PyTorch, and use torch.autograd features to backprop errors. I'd like it to be "online", in that h and c accumulate their state over time, and at each timestep there's 1 character in, and 1 out.

This is a character-level rnn, so:

  • my vocablulary is 30 characters (lowercase a-z, and some punctuation)

  • inp is a onehot vector of length 30.

  • h and c are of length 30 + 100. The first 30 of h is my "output"

  • my loss compares the target char, one-hot encoded, against those first 30 indices of h.

  • I accumulate loss over 10 steps, and then don't know how to properly backprop it. The following is a (poor) attempt.

TL;DR. How do I properly backprop for this LSTM?

    def ff(inp, h, c):
        xh = torch.cat((inp, h), 0)
        f = (xh @ Wf + bf).sigmoid()
        i = (xh @ Wi + bi).sigmoid()
        g = (xh @ Wg + bg).tanh() # C-bar, in some literature
        c = f * c + i * g
        o = (xh @ Wo + bo).sigmoid()
        h = o * c.tanh()
        return h, c

    loss = torch.zeros(1)
    def bp(out, target, lr):
        global Wf, Wi, Wg, Wo
        global bf, bi, bg, bo
        global h, c
        global loss

        # Accumulate loss every step
        loss += (-target * out[:out_n].softmax(dim=0).log()).sum()

        # Every 10 chars, run backprop
        if i % 10 == 0:
            loss.backward()

            with torch.no_grad():
                for param in [Wf, Wi, Wg, Wo, bf, bi, bg, bo]:
                    param -= lr * param.grad
                    param.grad.zero_()

            h.detach_()
            c.detach_()
            loss.detach_()
            loss = torch.zeros(1)

        return loss
  • 1
    What is the problem you have with this implementation? Correctness of implementation aside, this should work with autograd just fine. – Jatentaki 2 days ago
  • @Jatentaki The loss drops a little, not much, and bottoms out far from the point where samples make sense. I think I've implemented it improperly. I think the idea of using h like output = h[:out_size], and using that for the loss is unique. Also the idea of 1-in, 1-out, and backproping over 10 steps is unique, so, I'm afraid I've been too unique. – Josh.F 2 days ago
  • Right, so I also believe you implemented it incorrectly, but it is not an issue with backprogation itself. It's just that the math is broken somewhere. I would suggest you rewrite the code in object-oriented fashion, avoiding using global variables (they are very error-prone). Since you're using global variables and pasting only part of the code, it's very hard to reason about it in its current state. – Jatentaki 2 days ago

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