autodiff is a C++17 library that uses modern and advanced programming techniques to enable automatic computation of derivatives in an efficient, easy, and intuitive way.
Consider the following function f(x, y, z):
double f(double x, double y, double z)
{
return (x + y + z) * exp(x * y * z);
}
which we use use to evaluate the variable u = f(x, y, z):
double x = 1.0;
double y = 2.0;
double z = 3.0;
double u = f(x, y, z);
How can we minimally transform this code so that not only u, but also its derivatives ∂u/∂x, ∂u/∂y, and ∂u/∂z, can be computed?
The next two sections present how this can be achieved using two automatic differentiation algorithms implemented in autodiff: forward mode and reverse mode.
In a forward mode automatic differentiation algorithm, both output variables and one or more of their derivatives are computed together. For example, the function evaluation f(x, y, z) can be transformed in a way that it will not only produce the value of u, the output variable, but also one or more of its derivatives (∂u/∂x, ∂u/∂y, ∂u/∂z) with respect to the input variables (x, y, z).
Enabling forward automatic differentiation for the calculation of derivatives
using autodiff is relatively simple. For our previous function f, we only
need to replace the floating-point type double
with autodiff::dual
for both
input and output variables:
dual f(const dual& x, const dual& y, const dual& z)
{
return (x + y + z) * exp(x * y * z);
}
We can now compute the derivatives ∂u/∂x, ∂u/∂y, and ∂u/∂z as follows:
dual x = 1.0;
dual y = 2.0;
dual z = 3.0;
dual u = f(x, y, z);
double dudx = derivative(f, wrt(x), at(x, y, z));
double dudy = derivative(f, wrt(y), at(x, y, z));
double dudz = derivative(f, wrt(z), at(x, y, z));
The auxiliary function autodiff::wrt
, an acronym for with respect to,
is used to indicate which input variable (x, y, z) is the selected one to
compute the partial derivative of f. The auxiliary function autodiff::at
is used to indicate where (at which values of its parameters) the derivative
of f is evaluated.
In a reverse mode automatic differentiation algorithm, the output variable of a function is evaluated first. During this function evaluation, all mathematical operations between the input variables are "recorded" in an expression tree. By traversing this tree from top-level (output variable as the root node) to bottom-level (input variables as the leaf nodes), it is possible to compute the contribution of each branch on the derivatives of the output variable with respect to input variables.
Thus, a single pass in a reverse mode calculation computes all derivatives, in contrast with forward mode, which requires one pass for each input variable. Note, however, that it is possible to change the behavior of a forward pass so that many (perhaps even all) derivatives of an output variable are computed simultaneously (e.g., in a single forward pass, ∂u/∂x, ∂u/∂y, and ∂u/∂z are evaluated together with u, in contrast with three forward passes, each one computing the individual derivatives).
Similar as before, we can use autodiff to enable reverse automatic
differentiation for our function f by simply replacing type double
with
autodiff::var
as follows:
var f(var x, var y, var z)
{
return (x + y + z) * exp(x * y * z);
}
The code below demonstrates how the derivatives ∂u/∂x, ∂u/∂y, and ∂u/∂z can be calculated:
var x = 1.0;
var y = 2.0;
var z = 3.0;
var u = f(x, y, z);
Derivatives dud = derivatives(u);
double dudx = dud(x);
double dudy = dud(y);
double dudz = dud(z);
The function autodiff::derivatives
will traverse the expression tree stored
in variable u
and compute all its derivatives with respect to the input
variables (x, y, z), which are then stored in the object dud
. The
derivative of u
with respect to input variable x
(i.e., ∂u/∂x) can then
be extracted from dud
using dud(x)
. The operations dud(x)
, dud(y)
,
dud(z)
involve no computations! Just extraction of derivatives previously
computed with a call to function autodiff::derivatives
.
Check the documentation website for more details:
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Copyright (c) 2018–2023 Allan Leal
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