I created a C++ open source project for normally distributed random number generation benchmark.

It compares several algorithms, including

- Central limit theorem method
- Box-Muller transform
- Marsaglia polar method
- Ziggurat algorithm
- Inverse transform sampling method.
`cpp11random`

uses C++11 `std::normal_distribution`

with `std::minstd_rand`

(it is actually Box-Muller transform in clang).

The results of single-precision (`float`

) version on iMac Corei5-3330S@2.70GHz , clang 6.1, 64-bit:

For correctness, the program verifies the mean, standard deviation, skewness and kurtosis of the samples. It was found that CLT method by summing 4, 8 or 16 uniform numbers do not have good kurtosis as the other methods.

Ziggurat algorithm has better performance than the others. However, it does not suitable for SIMD parallelism as it needs table lookup and branches. Box-Muller with SSE2/AVX instruction set is much faster (x1.79, x2.99) than non-SIMD version of ziggurat algorithm.

Therefore, I will suggest using Box-Muller for architecture with SIMD instruction sets, and may be ziggurat otherwise.

P.S. the benchmark uses a simplest LCG PRNG for generating uniform distributed random numbers. So it may not be sufficient for some applications. But the performance comparison should be fair because all implementations uses the same PRNG, so the benchmark mainly tests the performance of the transformation.