In PyTorch, you commonly have to zero our the gradients before doing back propagation. Is this the case in Flux? If so, what is the programatic way of doing this?
1 Answer
tl;dr
No, there is no need.
explanation
Flux used to use Tracker, a differentiation system in which each tracked array may hold a gradient. I think this is a similar design to pytorch. Back-propagating twice can lead to the problem which zeroing is intended to avoid (although the defaults try to protect you):
julia> using Tracker
julia> x_tr = Tracker.param([1 2 3])
Tracked 1×3 Matrix{Float64}:
1.0 2.0 3.0
julia> y_tr = sum(abs2, x_tr)
14.0 (tracked)
julia> Tracker.back!(y_tr, 1; once=false)
julia> x_tr.grad
1×3 Matrix{Float64}:
2.0 4.0 6.0
julia> Tracker.back!(y_tr, 1; once=false) # by default (i.e. with once=true) this would be an error
julia> x_tr.grad
1×3 Matrix{Float64}:
4.0 8.0 12.0
Now it uses Zygote, which does not use tracked array types. Instead, the evaluation to be traced must happen with the call to Zygote.gradient
, it can then see and manipulate the source code to write new code for the gradient. Repeated calls to this generate the same gradients each time; there is no stored state to need cleaning up.
julia> using Zygote
julia> x = [1 2 3] # an ordinary Array
1×3 Matrix{Int64}:
1 2 3
julia> Zygote.gradient(x -> sum(abs2, x), x)
([2 4 6],)
julia> Zygote.gradient(x -> sum(abs2, x), x)
([2 4 6],)
julia> y, bk = Zygote.pullback(x -> sum(abs2, x), x);
julia> bk(1.0)
([2.0 4.0 6.0],)
julia> bk(1.0)
([2.0 4.0 6.0],)
Tracker can also be used this way, rather than handling param
and back!
yourself:
julia> Tracker.gradient(x -> sum(abs2, x), [1, 2, 3])
([2.0, 4.0, 6.0] (tracked),)