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January 27, 2016 18:51
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A Speed Comparison Of C, Julia, Python, Numba, and Cython on LU Factorization
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| // lu.c | |
| inline int _(int row, int col, int rows){ | |
| return row*rows + col; | |
| } | |
| void det_by_lu(double *y, double *x, int N){ | |
| int i,j,k; | |
| *y = 1.; | |
| for(k = 0; k < N; ++k){ | |
| *y *= x[_(k,k,N)]; | |
| for(i = k+1; i < N; ++i){ | |
| x[_(i,k,N)] /= x[_(k,k,N)]; | |
| } | |
| for(i = k+1; i < N; ++i){ | |
| #pragma omp simd | |
| for(j = k+1; j < N; ++j){ | |
| x[_(i,j,N)] -= x[_(i,k,N)] * x[_(k,j,N)]; | |
| } | |
| } | |
| } | |
| } | |
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| function det_by_lu(y, x, N) | |
| y[1] = 1. | |
| for k = 1:N | |
| y[1] *= x[k,k] | |
| for i = k+1:N | |
| x[i,k] /= x[k,k] | |
| end | |
| for j = k+1:N | |
| for i = k+1:N | |
| x[i,j] -= x[i,k] * x[k,j] | |
| end | |
| end | |
| end | |
| end | |
| function run_julia(y,A,B,N) | |
| loops = max(10000000 // (N*N), 1) | |
| print(loops) | |
| for l in 1:loops | |
| B[:,:] = A | |
| det_by_lu(y, B, N) | |
| end | |
| end | |
| y = [0.0] | |
| N=5 | |
| A = rand(N,N) | |
| B = zeros(N,N) | |
| @time run_julia(y,A,B,N) | |
| N=5 | |
| A = rand(N,N) | |
| B = zeros(N,N) | |
| @time run_julia(y,A,B,N) | |
| N=10 | |
| A = rand(N,N) | |
| B = zeros(N,N) | |
| @time run_julia(y,A,B,N) | |
| N=30 | |
| A = rand(N,N) | |
| B = zeros(N,N) | |
| @time run_julia(y,A,B,N) | |
| N=100 | |
| A = rand(N,N) | |
| B = zeros(N,N) | |
| @time run_julia(y,A,B,N) | |
| N=200 | |
| A = rand(N,N) | |
| B = zeros(N,N) | |
| @time run_julia(y,A,B,N) | |
| N=300 | |
| A = rand(N,N) | |
| B = zeros(N,N) | |
| @time run_julia(y,A,B,N) | |
| N=400 | |
| A = rand(N,N) | |
| B = zeros(N,N) | |
| @time run_julia(y,A,B,N) | |
| N=600 | |
| A = rand(N,N) | |
| B = zeros(N,N) | |
| @time run_julia(y,A,B,N) | |
| N=1000 | |
| A = rand(N,N) | |
| B = zeros(N,N) | |
| @time run_julia(y,A,B,N) | |
A perfect exercise for beginners
But why do you compile Cython code without optimizations?
You should try the fast version of Julia, i.e.:
using LoopVectorization
function det_by_lu(y, x, N)
y[1] = 1.
@turbo for k = 1:N
y[1] *= x[k,k]
for i = k+1:N
x[i,k] /= x[k,k]
end
for j = k+1:N
for i = k+1:N
x[i,j] -= x[i,k] * x[k,j]
end
end
end
endThis is quite a bit faster.
Why don't also compare with Julia's lapack?
using LinearAlgebra
A = rand(1000,1000)
@elapsed lu(A)
The pure Julia RecursiveFactorization.jl is faster than LAPACK BTW. https://github.com/YingboMa/RecursiveFactorization.jl it would be nice to add it to the benchmarks.
And here's some improvements to your Julia code. The result of the last expression is vector of elapsed times.
You can also add @fastmath @simd in det_by_lu! after @inbounds it gives small speedup
function det_by_lu!(x::AbstractMatrix{T}, N = size(x, 2)) where T <: Number
y = one(T)
@inbounds for k in 1:N
y *= x[k,k]
@views x[k+1:N, k] ./= x[k,k]
for j in k+1:N, i in k+1:N
x[i,j] -= x[i,k] * x[k,j]
end
end
y
end
function run_julia(A, N = size(A, 2))
loops = max(10_000_000 ÷ N^2, 1)
B = similar(A)
elapsed = 0.
for _ in 1:loops
copy!(B, A)
elapsed += @elapsed det_by_lu!(B, N)
end
elapsed / loops
end
map([5, 10, 30, 100, 200, 300, 400, 600, 1000]) do N
run_julia(rand(N,N))
endUPD. Forgot to say that you may also take a look at BenchmarkTools.jl, that provides @benchmark and @btime macro
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I would be cool to see how PyPy performs.