Generate random numbers following a normal distribution in C/C++

Does anyone know how I could easily generate random numbers following a normal distribution in C/C++ ?

http://www.mathworks.com/access/helpdesk/help/toolbox/stats/normrnd.html

I don't want to use any of Boost.

I know that Knuth talks about this at length but I don't have his books at hand right now.

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Duplicate of one or the other of stackoverflow.com/questions/75677/… and stackoverflow.com/questions/1109446/… – dmckee Feb 24 '10 at 17:48

The Box-Muller transform is what is commonly used. This correctly produces values with a normal distribution.

http://en.wikipedia.org/wiki/Normal_distribution#Generating_values_from_normal_distribution

http://en.wikipedia.org/wiki/Box_Muller_transform

The math is easy. You generate two uniform numbers and from those you get two normally distributed numbers. Return one, save the other for the next request of a random number.

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If you need speed, then the polar method is faster, though. And the Ziggurat algorithm even more (albeit much more complex to write). – Joey Feb 24 '10 at 12:15
found an implementation of the Ziggurat here people.sc.fsu.edu/~jburkardt/c_src/ziggurat/ziggurat.html It's quite complete. – dwbrito May 19 '13 at 16:54
Note, C++11 adds `std::normal_distribution` which does exactly what you ask for without delving into mathematical details. – user283145 Aug 28 '13 at 9:50
std::normal_distribution is not guaranteed to be consistent across all platforms. I'm doing the tests now, and MSVC provides a different set of values from, for example, Clang. The C++11 engines seem to generate the same sequences (given the same seed), but the C++11 distributions seem to be implemented using different algorithms on different platforms. – Arno Duvenhage Jan 20 at 13:36

EDIT: Since 12 August 2011 we have C++11 which directly offers `std::normal_distribution`, which is the way I would go today.

Here are some solutions ordered by ascending complexity.

1. Add 12 uniform numbers from 0-1 and subtract 6. This will match mean and standard deviation of a normale variable. An obvious drawback is that the range is limited to +/-6 - unlike a true normal distribution.

2. Box-Muller transform - was listed above, and is relatively simple to implement. If you need very precise samples however, be aware that the Box-Muller transform combined with some uniform generators suffers from an anomaly called Neave Effect.

H. R. Neave, “On using the Box-Muller transformation with multiplicative congruential pseudorandom number generators,” Applied Statistics, 22, 92-97, 1973

3. For best precision I suggest drawing uniforms and applying the inverse cumulative normal distribution to arrive at normally distributed variates. You can find a very good algorithm for the inverse cumulative normal distribution at

http://home.online.no/~pjacklam/notes/invnorm/#Overview

Hope that helps

Peter

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by any chance would you have another link to the pdf on the Neave effect? or the original journal article reference? thank you – pyCthon Nov 2 '11 at 13:30
@stonybrooknick The original reference is added. Cool remark: While googling "box muller neave" to find the reference, this very stackoverflow question came up on the first result page! – Peter G. Nov 2 '11 at 17:18
yeah its not every well known outside certain small communities and interest groups – pyCthon Nov 4 '11 at 18:55
@Peter G. Why would anyone downvote your answer? - possibly the same person did my comment below too, which I'm fine with, but I thought your answer was very good. It would be good if SO made downvotes force a real comment..I suspect most downvotes of old topics are just frivolous and trolly. – Pete855217 Nov 18 '13 at 23:35
"Add 12 uniform numbers from 0-1 and subtract 6." -- distribution of this variable will have normal distribution? Can you provide a link with derivation, because during derivation central limit theorem, n->+inf is very need assumption. – bruziuz Jan 10 at 22:05

A quick and easy method is just to sum a number of evenly distributed random numbers and take their average. See the Central Limit Theorem for a full explanation of why this works.

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+1 Very interesting approach. Is it verified to really give normally distributed sub ensembles for smaller groups? – Morlock Feb 24 '10 at 12:53
@Morlock The larger the number of samples you average the closer you get to a Gaussian distribution. If your application has strict requirements for the accuracy of the distribution then you might be better off using something more rigorous, like Box-Muller, but for many applications, e.g. generating white noise for audio applications, you can get away with a fairly small number of averaged samples (e.g. 16). – Paul R Feb 24 '10 at 13:25
Plus, how do you parametrize this to get a certain amount of variance, say you want a mean of 10 with a standard deviation of 1? – Morlock Feb 24 '10 at 13:26
@Morlock: To get a given mean and SD you scale your underlying samples properly. Generally, the underlying samples, u, are uniform over 0 to 1. Make them uniform over -1 to +1 (compute 2 u -1). You can then add the desired mean and multiply to get the desired standard deviation. – S.Lott Feb 24 '10 at 13:39
@Morlock If you scale your PRNG to give random numbers in the range -1.0 to +1.0 then you get a mean of 0.0 and a variance of 0.5 when you take a sufficiently large average. You can just linearly shift and scale either the input numbers or the output average to get whatever mean and variance you need. – Paul R Feb 24 '10 at 13:39

Use `std::tr1::normal_distribution`.

The std::tr1 namespace is not a part of boost. It's the namespace that contains the library additions from the C++ Technical Report 1 and is available in up to date Microsoft compilers and gcc, independently of boost.

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TR1 is not boost. – Joe Gauterin Feb 24 '10 at 11:31
TR1 is not standard, either. – anon Feb 24 '10 at 11:39
He didn't ask for standard, he asked for 'not boost'. – Joe Gauterin Feb 24 '10 at 11:43
TR1 is standardized. – Ben Voigt Jan 6 '14 at 23:50

Here's a C++ example, based on some of the references. This is quick and dirty, you are better off not re-inventing and using the boost library.

``````#include "math.h" // for RAND, and rand
double sampleNormal() {
double u = ((double) rand() / (RAND_MAX)) * 2 - 1;
double v = ((double) rand() / (RAND_MAX)) * 2 - 1;
double r = u * u + v * v;
if (r == 0 || r > 1) return sampleNormal();
double c = sqrt(-2 * log(r) / r);
return u * c;
}
``````

You can use a Q-Q plot to examine the results and see how well it approximates a real normal distribution (rank your samples 1..x, turn the ranks into proportions of total count of x ie. how many samples, get the z-values and plot them. An upwards straight line is the desired result).

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What is sampleNormalManual()? – solvingPuzzles Jul 22 '12 at 0:17
@solvingPuzzles - sorry, corrected the code. It's a recursive call. – Pete855217 Jul 26 '12 at 9:16
This is bound to crash at some rare event (showcasing application to your boss rings a bell?). This should be implemented using a loop, not using recursion. The method looks unfamiliar. What is the source / how is it called? – the swine Nov 18 '13 at 17:00
Box-Muller transcribed from a java implementation. As I said, it's quick and dirty, feel free to fix it. – Pete855217 Nov 18 '13 at 23:28
Seems perfectly reasonable and gives good results. I implemented this in javascript (and tested the distribution). – Octopus Nov 23 '15 at 18:50

This is how you generate the samples on a modern C++ compiler.

``````#include <random>
...
std::mt19937 generator;
double mean = 0.0;
double stddev  = 1.0;
std::normal_distribution<double> normal(mean, stddev);
cerr << "Normal: " << normal(generator) << endl;
``````
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the `generator` should really be seeded. – Walter Nov 19 '15 at 13:51
It is always seeded. There is a default seed. – Petter Nov 21 '15 at 11:36

You can use the GSL. Some complete examples are given to demonstrate how to use it.

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Have a look on: http://www.cplusplus.com/reference/random/normal_distribution/. It's the simplest way to produce normal distributions.

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Lone link is bad. – Austin Henley Dec 16 '12 at 4:48

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.

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If you're using C++11, you can use `std::normal_distribution`:

``````#include <random>

std::default_random_engine generator;
std::normal_distribution<double> distribution(/*mean=*/0.0, /*stddev=*/1.0);

double randomNumber = distribution(generator);
``````

There are many other distributions you can use to transform the output of the random number engine.

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That's already been mentioned by Ben (stackoverflow.com/a/11977979/635608) – Mat Apr 21 '13 at 12:14

I've followed the definition of the PDF given in http://www.mathworks.com/help/stats/normal-distribution.html and came up with this:

``````const double DBL_EPS_COMP = 1 - DBL_EPSILON; // DBL_EPSILON is defined in <limits.h>.
inline double RandU() {
return DBL_EPSILON + ((double) rand()/RAND_MAX);
}
inline double RandN2(double mu, double sigma) {
return mu + (rand()%2 ? -1.0 : 1.0)*sigma*pow(-log(DBL_EPS_COMP*RandU()), 0.5);
}
inline double RandN() {
return RandN2(0, 1.0);
}
``````

It is maybe not the best approach, but it's quite simple.

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-1 Not working for e.g. RANDN2(0.0, d + 1.0). Macros are notorious for this. – Petter Oct 11 '13 at 11:28
The macro will fail if `rand()` of `RANDU` returns a zero, since Ln(0) is undefined. – interDist Dec 20 '13 at 19:37
Have you actually tried this code? It looks like you have created a function that generates numbers which are Rayleigh distributed. Compare to the Box–Muller transform, where they multiply with `cos(2*pi*rand/RAND_MAX)`, whereas you multiply with `(rand()%2 ? -1.0 : 1.0)`. – HelloGoodbye Mar 4 '14 at 15:01

Take a look at what I found.

This library uses the Ziggurat algorithm.

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1. Computer is deterministic device. There is no randomness in calculation. Moreover arithmetic device in CPU can evaluate summ over some finite set of integer numbers and finite set of real rational numbers. And also performed bitwise operations. Math take a deal with more great sets like [0.0, 1.0] with infinite number of points.

From real point of view: You can listen some wire inside of computer with some controller, but would it have uniform distributions? I don't know. But if assumed that it's signal is the the result of accumulate values huge amount of independent random variables then you will receive approximately normal distributed random variable (It was proved in Probability Theory)

1. There is exist algorithms called - pseudo random generator. As I feeled the purpose of pseudo random generator is to emulate randomness. And the criteria of goodnes is:

• the empirical distribution is converged (in some sense) to theoretical
• values that you receive from random generator are seemed to be idependent (of course it's not true from 'real point of view')
2. One of the popular method - you can summ 12 i.r.v with uniform distributions....But during derivation Central Limit Theorem with helping of Fourier Transform, Taylor Series, I needed n->+inf assumptions couple times. So for example theoreticaly - I don't undersand how people perform summ of 12 i.r.v. with uniform distribution.

3. I don't know any methods which mentioned in other answers. But I had probility theory in university. And particulary for me it is just a math question. In university I solved it (with helped from proffesor) as combination of Rayleigh and uniform distribution:

``````double generateUniform(double a, double b)
{
return uniformGen.generateReal(a, b);
}

double generateRelei(double sigma)
{
return sigma * sqrt(-2 * log(1.0 - uniformGen.generateReal(0.0, 1.0 -kEps)));
}
double generateNorm(double m, double sigma)
{
double y2 = generateUniform(0.0, 2 * kPi);
double y1 = generateRelei(1.0);
double x1 = y1 * cos(y2);
return sigma*x1 + m;
}
``````

I think that such questions can be discussed in mathematical probability theory course. It is more math question then software.)

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