/Zygote.jl

21st century AD

Primary LanguageJuliaOtherNOASSERTION

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] add Zygote

Zygote provides source-to-source automatic differentiation (AD) in Julia, and is the next-gen AD system for the Flux differentiable programming framework. For more details and benchmarks of Zygote's technique, see our paper. You may want to check out Flux for more interesting examples of Zygote usage; the documentation here focuses on internals and advanced AD usage.

Zygote supports Julia 1.0 onwards, but we highly recommend using Julia 1.3 or later.

julia> using Zygote

julia> f(x) = 5x + 3

julia> f(10), f'(10)
(53, 5.0)

julia> @code_llvm f'(10)
define i64 @"julia_#625_38792"(i64) {
top:
  ret i64 5
}

"Source-to-source" means that Zygote hooks into Julia's compiler, and generates the backwards pass for you – as if you had written it by hand.

Zygote supports the flexibility and dynamism of the Julia language, including control flow, recursion, closures, structs, dictionaries, and more. Mutation and exception handling are currently not supported.

julia> fs = Dict("sin" => sin, "cos" => cos, "tan" => tan);

julia> gradient(x -> fs[readline()](x), 1)
sin
0.5403023058681398

Zygote benefits from using the ChainRules.jl ruleset. Custom gradients can be defined by extending the ChainRulesCore.jl's rrule:

julia> using ChainRulesCore

julia> add(a, b) = a + b

julia> function ChainRulesCore.rrule(::typeof(add), a, b)
           add_pb(dy) = (NoTangent(), dy, dy)
           return add(a, b), add_pb
       end

To support large machine learning models with many parameters, Zygote can differentiate implicitly-used parameters, as opposed to just function arguments.

julia> W, b = rand(2, 3), rand(2);

julia> predict(x) = W*x .+ b;

julia> g = gradient(Params([W, b])) do
         sum(predict([1,2,3]))
       end
Grads(...)

julia> g[W], g[b]
([1.0 2.0 3.0; 1.0 2.0 3.0], [1.0, 1.0])