Integrals.jl

Integrals.jl is an instantiation of the SciML common IntegralProblem interface for the common numerical integration packages of Julia, including both those based upon quadrature as well as Monte-Carlo approaches. By using Integrals.jl, you get a single predictable interface where many of the arguments are standardized throughout the various integrator libraries. This can be useful for benchmarking or for library implementations, since libraries which internally use a quadrature can easily accept a integration method as an argument.

Tutorials and Documentation

For information on using the package, see the stable documentation. Use the in-development documentation for the version of the documentation, which contains the unreleased features.

Examples

To perform one-dimensional quadrature, we can simply construct an IntegralProblem. The code below evaluates $\int_{-2}^5 \sin(xp)~\mathrm{d}x$ with $p = 1.7$. This argument $p$ is passed into the problem as the fourth argument of IntegralProblem.

using Integrals
f(x, p) = sin(x * p)
p = 1.7
domain = (-2, 5) # (lb, ub)
prob = IntegralProblem(f, domain, p)
sol = solve(prob, QuadGKJL())

For basic multidimensional quadrature we can construct and solve a IntegralProblem. Since we are using no arguments p in this example, we omit the fourth argument of IntegralProblem from above. The lower and upper bounds are now passed as vectors, with the ith elements of the bounds giving the interval of integration for x[i].

using Integrals
f(x, p) = sum(sin.(x))
domain = (ones(2), 3ones(2)) # (lb, ub)
prob = IntegralProblem(f, domain)
sol = solve(prob, HCubatureJL(), reltol = 1e-3, abstol = 1e-3)

If we would like to parallelize the computation, we can use the batch interface to compute multiple points at once. For example, here we do allocation-free multithreading with Cubature.jl:

using Integrals, Cubature, Base.Threads
function f(dx, x, p)
    Threads.@threads for i in 1:size(x, 2)
        dx[i] = sum(sin, @view(x[:, i]))
    end
end
domain = (ones(2), 3ones(2)) # (lb, ub)
prob = IntegralProblem(BatchIntegralFunction(f, zeros(0)), domain)
sol = solve(prob, CubatureJLh(), reltol = 1e-3, abstol = 1e-3)

If we would like to compare the results against Cuba.jl's Cuhre method, then the change is a one-argument change:

using Cuba
sol = solve(prob, CubaCuhre(), reltol = 1e-3, abstol = 1e-3)