VectorizedRNG
/badge.svg){kind=icon}
This library provides a vectorized Xoshiro256++ random number generator. The larger the host computers SIMD vector width, the better they will perform. On a machine with AVX-512, they are faster than SIMD-oriented Fast Mersenne Twister (SFMT). Base Julia used dSFMT, up to version 1.7, which in a few tests appears to outperform this library on AVX2 systems in generating uniformly distributed random numbers.
You can get a thread-local instance of the Xoshiro generator with local_rng(). Each parallel stream jumps ahead 2^128 samples, which should be more than enough samples per stream for any real calculation. Each thread gets 8 parallel streams with AVX, or 16 with AVX512, allowing there to be up to 2^125 or 2^124 threads with AVX512.
Testing on an old haswell machine (AVX2-only):
julia> using BenchmarkTools, Random, VectorizedRNG
julia> x = Vector{Float64}(undef, 1024);
julia> @benchmark randn!($x)
BenchmarkTools.Trial:
memory estimate: 0 bytes
allocs estimate: 0
--------------
minimum time: 7.235 μs (0.00% GC)
median time: 7.900 μs (0.00% GC)
mean time: 8.034 μs (0.00% GC)
maximum time: 233.290 μs (0.00% GC)
--------------
samples: 10000
evals/sample: 5
julia> @benchmark randn!(local_rng(), $x)
BenchmarkTools.Trial:
memory estimate: 0 bytes
allocs estimate: 0
--------------
minimum time: 3.744 μs (0.00% GC)
median time: 4.156 μs (0.00% GC)
mean time: 4.137 μs (0.00% GC)
maximum time: 59.169 μs (0.00% GC)
--------------
samples: 10000
evals/sample: 8The performance advantage is thanks primarily to a fast SIMD Box-Muller implementation; randn(::MersenneTwister) uses the ziggurat algorithm, which is more efficient for scalars. Performance is closer when only comparing random-uniform generation:
julia> @benchmark rand!($x)
BenchmarkTools.Trial:
memory estimate: 0 bytes
allocs estimate: 0
--------------
minimum time: 791.047 ns (0.00% GC)
median time: 904.541 ns (0.00% GC)
mean time: 915.753 ns (0.00% GC)
maximum time: 13.978 μs (0.00% GC)
--------------
samples: 10000
evals/sample: 85
julia> @benchmark rand!(local_rng(), $x)
BenchmarkTools.Trial:
memory estimate: 0 bytes
allocs estimate: 0
--------------
minimum time: 513.000 ns (0.00% GC)
median time: 568.578 ns (0.00% GC)
mean time: 571.597 ns (0.00% GC)
maximum time: 4.706 μs (0.00% GC)
--------------
samples: 10000
evals/sample: 192This library shines on a system with AVX512:
julia> using BenchmarkTools, Random, VectorizedRNG
julia> x = Vector{Float64}(undef, 1024);
julia> @benchmark randn!($x)
BenchmarkTools.Trial:
memory estimate: 0 bytes
allocs estimate: 0
--------------
minimum time: 1.676 μs (0.00% GC)
median time: 1.798 μs (0.00% GC)
mean time: 1.883 μs (0.00% GC)
maximum time: 5.769 μs (0.00% GC)
--------------
samples: 10000
evals/sample: 10
julia> @benchmark randn!(local_rng(), $x)
BenchmarkTools.Trial:
memory estimate: 0 bytes
allocs estimate: 0
--------------
minimum time: 854.446 ns (0.00% GC)
median time: 962.369 ns (0.00% GC)
mean time: 991.798 ns (0.00% GC)
maximum time: 1.818 μs (0.00% GC)
--------------
samples: 10000
evals/sample: 65
julia> @benchmark rand!($x)
BenchmarkTools.Trial:
memory estimate: 0 bytes
allocs estimate: 0
--------------
minimum time: 549.856 ns (0.00% GC)
median time: 567.626 ns (0.00% GC)
mean time: 603.958 ns (0.00% GC)
maximum time: 1.124 μs (0.00% GC)
--------------
samples: 10000
evals/sample: 187
julia> @benchmark rand!(local_rng(), $x)
BenchmarkTools.Trial:
memory estimate: 0 bytes
allocs estimate: 0
--------------
minimum time: 159.907 ns (0.00% GC)
median time: 171.258 ns (0.00% GC)
mean time: 174.272 ns (0.00% GC)
maximum time: 958.197 ns (0.00% GC)
--------------
samples: 10000
evals/sample: 788
julia> versioninfo()
Julia Version 1.6.0-DEV.1581
Commit 377aa809eb (2020-11-26 01:44 UTC)
Platform Info:
OS: Linux (x86_64-linux-gnu)
CPU: 11th Gen Intel(R) Core(TM) i7-1165G7 @ 2.80GHz
WORD_SIZE: 64
LIBM: libopenlibm
LLVM: libLLVM-11.0.0 (ORCJIT, tigerlake)Setting the seed
VectorizedRNG is initialized with a random seed (based on the default Random.GLOBAL_RNG) when loaded, but Random.seed! wont change the state of the VectorizedRNG. You can set the seed of the VectorizedRNG with VectorizedRNG.seed!.
julia> using VectorizedRNG
julia> rand(local_rng(), 15)'
1×15 LinearAlgebra.Adjoint{Float64,Array{Float64,1}}:
0.580812 0.813531 0.359055 0.590277 0.551968 0.635421 0.160614 0.312387 0.00787783 0.554571 0.368705 0.0219756 0.804188 0.0740875 0.939065
julia> VectorizedRNG.seed!(1)
julia> rand(local_rng(), 15)'
1×15 LinearAlgebra.Adjoint{Float64,Array{Float64,1}}:
0.371016 0.804553 0.243923 0.261726 0.875966 0.942672 0.875786 0.0255004 0.236359 0.59697 0.480488 0.790366 0.0263995 0.715227 0.514725
julia> rand(local_rng(), 15)'
1×15 LinearAlgebra.Adjoint{Float64,Array{Float64,1}}:
0.246595 0.326417 0.98997 0.335991 0.839723 0.628247 0.814513 0.924231 0.398405 0.604068 0.915064 0.984332 0.773448 0.325699 0.490881
julia> VectorizedRNG.seed!(1)
julia> rand(local_rng(), 15)'
1×15 LinearAlgebra.Adjoint{Float64,Array{Float64,1}}:
0.371016 0.804553 0.243923 0.261726 0.875966 0.942672 0.875786 0.0255004 0.236359 0.59697 0.480488 0.790366 0.0263995 0.715227 0.514725
julia> rand(local_rng(), 15)'
1×15 LinearAlgebra.Adjoint{Float64,Array{Float64,1}}:
0.246595 0.326417 0.98997 0.335991 0.839723 0.628247 0.814513 0.924231 0.398405 0.604068 0.915064 0.984332 0.773448 0.325699 0.490881BigCrush
The generators pass BigCrush. We can run BigCrush in a matter of minutes on a multicore system (10980XE CPU). Testing the uniform number generator:
julia> using Distributed; addprocs(); nprocs()
37
julia> @everywhere using RNGTest, VectorizedRNG, Random
julia> @everywhere struct U01 <: Random.AbstractRNG end
julia> @everywhere Random.rand!(r::U01, x::AbstractArray) = rand!(local_rng(), x)
julia> u01 = U01()
U01()
julia> rngunif = RNGTest.wrap(U01(), Float64);
julia> @time bcjunif = RNGTest.bigcrushJulia(rngunif);
511.531281 seconds (31.91 M allocations: 1.619 GiB, 0.10% gc time)
julia> minimum(minimum.(bcjunif))
0.004345184234132201
julia> maximum(maximum.(bcjunif))
0.99900365621945While not great looking minimum or maximum p-values. For comparison, the default MersenneTwister:
julia> wrappedtwister = RNGTest.wrap(MersenneTwister(), Float64);
julia> @time bcjmtwister = RNGTest.bigcrushJulia(wrappedtwister);
481.782432 seconds (9.73 M allocations: 508.753 MiB, 0.04% gc time)
julia> minimum(minimum.(bcjmtwister))
0.0015850804769910467
julia> maximum(maximum.(bcjmtwister))
0.9912021397939957Interestingly, this completed faster. I should've monitored clock speeds, but can say that (subjectively) the CPU fans were louder when running this benchmark, making me wonder if this is a case where downclocking of non-AVX code decreases performance.
Watch out when mixing vectorized and non-vectorized code.
On vectorization: the strategy is to simply have many distinct streams, and sample from them simultaneously via SIMD operations.