# Cumulative Normal Distribution Function in C/C++

I was wondering if there were statistics functions built into math libraries that are part of the standard C++ libraries like cmath. If not, can you guys recommend a good stats library that would have a cumulative normal distribution function? Thanks in advance.

More specifically, I am looking to use/create a cumulative distribution function.

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If the CDF of the normal distribution is all you need, why not just implement it yourself? It contains no magic so implementation is straight forward. –  kigurai Feb 24 '10 at 21:56
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## 5 Answers

Here's a stand-alone C++ implementation of the cumulative normal distribution in 14 lines of code.

http://www.johndcook.com/cpp_phi.html

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Thank you for providing this as well. –  Tyler Brock Mar 3 '10 at 17:55
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Boost is as good as the standard :D here you go: boost maths/statistical.

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Is there a standard one built in? –  Tyler Brock Feb 24 '10 at 18:05
No, the standard library does not yet have any. –  dirkgently Feb 24 '10 at 18:07
normal distribution, yes I think so. Or are you talking about built into the standard library -- in the latter case, no. –  Hassan Syed Feb 24 '10 at 18:07
Thanks, yes, the reason I'm asking is because I want to use as much of the standard stuff as possible. I guess there is no way getting around it in this case. –  Tyler Brock Feb 24 '10 at 18:09
3 reasons for using boost: 1) You can copy out libraries of your choosing using a utility that comes with boost. 2) the libraries tend to be header only. 3) most libraries work very well and work everywhere with a C++ compiler. –  Hassan Syed Feb 24 '10 at 18:12
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Theres is no straight function. But since the gaussian error function and its complementary function is related to the normal cumulative distribution function (see here) we can use the implemented c-function erfc:

double normalCFD(double value)
{
return 0.5 * erfc(-value * M_SQRT1_2);
}

I use it for statistical calculations and it works great. No need for using coefficients.

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I figured out how to do it using gsl, at the suggestion of the folks who answered before me, but then found a non-library solution (hopefully this helps many people out there who are looking for it like I was):

#ifndef Pi
#define Pi 3.141592653589793238462643
#endif

double cnd_manual(double x)
{
double L, K, w ;
/* constants */
double const a1 = 0.31938153, a2 = -0.356563782, a3 = 1.781477937;
double const a4 = -1.821255978, a5 = 1.330274429;

L = fabs(x);
K = 1.0 / (1.0 + 0.2316419 * L);
w = 1.0 - 1.0 / sqrt(2 * Pi) * exp(-L *L / 2) * (a1 * K + a2 * K *K + a3 * pow(K,3) + a4 * pow(K,4) + a5 * pow(K,5));

if (x < 0 ){
w= 1.0 - w;
}
return w;
}
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ouch... don't use pow, use Horner's rule. I downvote until this is corrected (please notify me). –  Alexandre C. Mar 11 '11 at 10:31
I was going for readability, request denied. –  Tyler Brock May 27 '11 at 14:14
this code will lose precision. Horner's rule is stabler (and also faster). –  Alexandre C. May 27 '11 at 19:04
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From NVIDIA CUDA samples:

static double CND(double d)
{
const double       A1 = 0.31938153;
const double       A2 = -0.356563782;
const double       A3 = 1.781477937;
const double       A4 = -1.821255978;
const double       A5 = 1.330274429;
const double RSQRT2PI = 0.39894228040143267793994605993438;

double
K = 1.0 / (1.0 + 0.2316419 * fabs(d));

double
cnd = RSQRT2PI * exp(- 0.5 * d * d) *
(K * (A1 + K * (A2 + K * (A3 + K * (A4 + K * A5)))));

if (d > 0)
cnd = 1.0 - cnd;

return cnd;
}

Copyright 1993-2012 NVIDIA Corporation. All rights reserved.

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