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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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1  
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. –  Hannes Ovrén Feb 24 '10 at 21:56

6 Answers 6

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

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
up vote 2 down vote accepted

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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2  
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
1  
I was going for readability, request denied. –  Tyler Brock May 27 '11 at 14:14
2  
this code will lose precision. Horner's rule is stabler (and also faster). –  Alexandre C. May 27 '11 at 19:04

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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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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The implementations of the normal CDF given here are single precision approximations that have had float replaced with double and hence are only accurate to 7 or 8 significant (decimal) figures.
For a VB implementation of Hart's double precision approximation, see figure 2 of West's Better approximations to cumulative normal functions.

Edit: My translation of West's implementation into C++:

double
phi(double x)
{
  static const double RT2PI = sqrt(4.0*acos(0.0));

  static const double SPLIT = 7.07106781186547;

  static const double N0 = 220.206867912376;
  static const double N1 = 221.213596169931;
  static const double N2 = 112.079291497871;
  static const double N3 = 33.912866078383;
  static const double N4 = 6.37396220353165;
  static const double N5 = 0.700383064443688;
  static const double N6 = 3.52624965998911e-02;
  static const double M0 = 440.413735824752;
  static const double M1 = 793.826512519948;
  static const double M2 = 637.333633378831;
  static const double M3 = 296.564248779674;
  static const double M4 = 86.7807322029461;
  static const double M5 = 16.064177579207;
  static const double M6 = 1.75566716318264;
  static const double M7 = 8.83883476483184e-02;

  const double z = fabs(x);
  double c = 0.0;

  if(z<=37.0)
  {
    const double e = exp(-z*z/2.0);
    if(z<SPLIT)
    {
      const double n = (((((N6*z + N5)*z + N4)*z + N3)*z + N2)*z + N1)*z + N0;
      const double d = ((((((M7*z + M6)*z + M5)*z + M4)*z + M3)*z + M2)*z + M1)*z + M0;
      c = e*n/d;
    }
    else
    {
      const double f = z + 1.0/(z + 2.0/(z + 3.0/(z + 4.0/(z + 13.0/20.0))));
      c = e/(RT2PI*f);
    }
  }
  return x<=0.0 ? c : 1-c;
}

Note that I have rearranged expressions into the more familiar forms for series and continued fraction approximations. The last magic number in West's code is the square root of 2π, which I've deferred to the compiler on the first line by exploiting the identity acos(0) = ½ π.
I've triple checked the magic numbers, but there's always the chance that I've mistyped something. If you spot a typo, please comment!

The results for the test data John Cook used in his answer are

 x               phi                Mathematica
-3     1.3498980316301150e-003    0.00134989803163
-1     1.5865525393145702e-001    0.158655253931
 0     5.0000000000000000e-001    0.5
0.5    6.9146246127401301e-001    0.691462461274
2.1    9.8213557943718344e-001    0.982135579437

I take some small comfort from the fact that they agree to all of the digits given for the Mathematica results.

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