I am building and training a neural network model with Flux, and I am wondering if there is a way to take linear combinations of Zygote.Grads types.
Here is a minimalistic example. This is how it is typically done:
m = hcat(2.0); b = hcat(-1.0); # random 1 x 1 matrices
f(x) = m*x .+ b
ps = Flux.params(m, b) # parameters to be adjusted
inputs = [0.3 1.5] # random 1 x 2 matrix
loss(x) = sum( f(x).^2 )
gs = Flux.gradient(() -> loss(inputs), ps) # the typical way
@show gs[m], gs[b] # 5.76, 3.2
But I want to do the same calculation by computing gradients at a deeper level, and then assembling it at the end. For example:
input1 = hcat(inputs[1, 1]); input2 = hcat(inputs[1, 2]); # turn each input into a 1 x 1 matrix
grad1 = Flux.gradient(() -> f(input1)[1], ps) # df/dp using input1 (where p is m or b)
grad2 = Flux.gradient(() -> f(input2)[1], ps) # df/dp using input2 (where p is m or b)
predicted1 = f(input1)[1]
predicted2 = f(input2)[1]
myGrad_m = (2 * predicted1 * grad1[m]) + (2 * predicted2 * grad2[m]) # 5.76
myGrad_b = (2 * predicted1 * grad1[b]) + (2 * predicted2 * grad2[b]) # 3.2
Above, I used the chain rule and linearity of the derivative to decompose the gradient of the loss() function:
d(loss)/dp = d( sum(f^2) ) / dp = sum( d(f^2)/dp ) = sum( 2*f * df/dp )
Then, I calculated df/dp using Zygote.gradient, and then combined the results at the end.
But notice that I had to combine m and b separately. This was fine because there were only 2 parameters.
However, if there were a 1000 parameters, I would want to do something like this, which is a linear combination of the Zygote.Grads:
myGrad = (2 * predicted1 * grad1) + (2 * predicted2 * grad2)
But, I get an error saying that the + and * operators are not defined for these types. How can I get this shortcut to work?
