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279 lines
9.4 KiB
C++
279 lines
9.4 KiB
C++
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// distribution_construction.cpp
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// Copyright Paul A. Bristow 2007, 2010, 2012.
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// Use, modification and distribution are subject to the
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// Boost Software License, Version 1.0.
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// (See accompanying file LICENSE_1_0.txt
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// or copy at http://www.boost.org/LICENSE_1_0.txt)
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// Caution: this file contains Quickbook markup as well as code
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// and comments, don't change any of the special comment markups!
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#ifdef _MSC_VER
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# pragma warning (disable : 4996) // disable -D_SCL_SECURE_NO_WARNINGS C++ 'Checked Iterators'
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#endif
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#include <iostream>
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#include <exception>
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//[distribution_construction_1
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/*`
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The structure of distributions is rather different from some other statistical libraries,
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for example, those written in less object-oriented language like FORTRAN and C:
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these provide a few arguments to each free function.
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Boost.Math library provides each distribution as a template C++ class.
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A distribution is constructed with a few arguments, and then
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member and non-member functions are used to find values of the
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distribution, often a function of a random variate.
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For this demonstration, first we need some includes to access the
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negative binomial distribution (and the binomial, beta and gamma distributions too).
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To demonstrate the use with a high precision User-defined floating-point type
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`cpp_dec_float` we also need an include from Boost.Multiprecision.
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*/
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#include <boost/math/distributions/negative_binomial.hpp> // for negative_binomial_distribution
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using boost::math::negative_binomial_distribution; // default type is double.
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using boost::math::negative_binomial; // typedef provides default type is double.
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#include <boost/math/distributions/binomial.hpp> // for binomial_distribution.
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#include <boost/math/distributions/beta.hpp> // for beta_distribution.
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#include <boost/math/distributions/gamma.hpp> // for gamma_distribution.
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#include <boost/math/distributions/normal.hpp> // for normal_distribution.
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#include <boost/multiprecision/cpp_dec_float.hpp> // for cpp_dec_float_100
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/*`
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Several examples of constructing distributions follow:
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*/
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//] [/distribution_construction_1 end of Quickbook in C++ markup]
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int main()
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{
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try
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{
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//[distribution_construction_2
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/*`
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First, a negative binomial distribution with 8 successes
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and a success fraction 0.25, 25% or 1 in 4, is constructed like this:
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*/
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boost::math::negative_binomial_distribution<double> mydist0(8., 0.25);
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/*`
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But this is inconveniently long, so we might be tempted to write
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*/
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using namespace boost::math;
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/*`
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but this might risk ambiguity with names in `std random` so
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[*much] better is explicit `using boost::math::` statements, for example:
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*/
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using boost::math::negative_binomial_distribution;
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/*`
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and we can still reduce typing.
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Since the vast majority of applications use will be using `double` precision,
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the template argument to the distribution (`RealType`) defaults
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to type `double`, so we can also write:
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*/
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negative_binomial_distribution<> mydist9(8., 0.25); // Uses default `RealType = double`.
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/*`
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But the name `negative_binomial_distribution` is still inconveniently long,
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so, for most distributions, a convenience `typedef` is provided, for example:
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typedef negative_binomial_distribution<double> negative_binomial; // Reserved name of type double.
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[caution
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This convenience typedef is [*not provided] if a clash would occur
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with the name of a function: currently only `beta` and `gamma`
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fall into this category.
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]
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So, after a using statement,
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*/
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using boost::math::negative_binomial;
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/*`
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we have a convenient typedef to `negative_binomial_distribution<double>`:
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*/
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negative_binomial mydist(8., 0.25);
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/*`
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Some more examples using the convenience typedef:
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*/
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negative_binomial mydist10(5., 0.4); // Both arguments double.
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/*`
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And automatic conversion takes place, so you can use integers and floats:
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*/
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negative_binomial mydist11(5, 0.4); // Using provided typedef double, int and double arguments.
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/*`
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This is probably the most common usage.
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*/
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negative_binomial mydist12(5., 0.4F); // Double and float arguments.
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negative_binomial mydist13(5, 1); // Both arguments integer.
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/*`
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Similarly for most other distributions like the binomial.
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*/
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binomial mybinomial(1, 0.5); // is more concise than
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binomial_distribution<> mybinomd1(1, 0.5);
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/*`
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For cases when the typdef distribution name would clash with a math special function
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(currently only beta and gamma)
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the typedef is deliberately not provided, and the longer version of the name
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must be used. For example do not use:
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using boost::math::beta;
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beta mybetad0(1, 0.5); // Error beta is a math FUNCTION!
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Which produces the error messages:
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[pre
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error C2146: syntax error : missing ';' before identifier 'mybetad0'
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warning C4551: function call missing argument list
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error C3861: 'mybetad0': identifier not found
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]
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Instead you should use:
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*/
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using boost::math::beta_distribution;
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beta_distribution<> mybetad1(1, 0.5);
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/*`
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or for the gamma distribution:
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*/
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gamma_distribution<> mygammad1(1, 0.5);
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/*`
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We can, of course, still provide the type explicitly thus:
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*/
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// Explicit double precision: both arguments are double:
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negative_binomial_distribution<double> mydist1(8., 0.25);
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// Explicit float precision, double arguments are truncated to float:
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negative_binomial_distribution<float> mydist2(8., 0.25);
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// Explicit float precision, integer & double arguments converted to float:
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negative_binomial_distribution<float> mydist3(8, 0.25);
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// Explicit float precision, float arguments, so no conversion:
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negative_binomial_distribution<float> mydist4(8.F, 0.25F);
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// Explicit float precision, integer arguments promoted to float.
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negative_binomial_distribution<float> mydist5(8, 1);
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// Explicit double precision:
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negative_binomial_distribution<double> mydist6(8., 0.25);
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// Explicit long double precision:
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negative_binomial_distribution<long double> mydist7(8., 0.25);
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/*`
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And you can use your own RealType,
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for example, `boost::math::cpp_dec_float_50` (an arbitrary 50 decimal digits precision type),
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then we can write:
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*/
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using namespace boost::multiprecision;
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negative_binomial_distribution<cpp_dec_float_50> mydist8(8, 0.25);
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// `integer` arguments are promoted to your RealType exactly, but
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// `double` argument are converted to RealType,
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// possibly losing precision, so don't write:
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negative_binomial_distribution<cpp_dec_float_50> mydist20(8, 0.23456789012345678901234567890);
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// to avoid truncation of second parameter to `0.2345678901234567`.
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negative_binomial_distribution<cpp_dec_float_50> mydist21(8, cpp_dec_float_50("0.23456789012345678901234567890") );
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// Ensure that all potentially significant digits are shown.
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std::cout.precision(std::numeric_limits<cpp_dec_float_50>::digits10);
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cpp_dec_float_50 x("1.23456789012345678901234567890");
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std::cout << pdf(mydist8, x) << std::endl;
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/*` showing 0.00012630010495970320103876754721976419438231705359935
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[warning When using multiprecision, it is all too easy to get accidental truncation!]
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For example, if you write
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*/
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std::cout << pdf(mydist8, 1.23456789012345678901234567890) << std::endl;
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/*`
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showing 0.00012630010495970318465064569310967179576805651692929,
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which is wrong at about the 17th decimal digit!
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This is because the value provided is truncated to a `double`, effectively
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`double x = 1.23456789012345678901234567890;`
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Then the now `double x` is passed to function `pdf`,
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and this truncated `double` value is finally promoted to `cpp_dec_float_50`.
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Another way of quietly getting the wrong answer is to write:
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*/
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std::cout << pdf(mydist8, cpp_dec_float_50(1.23456789012345678901234567890)) << std::endl;
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/*`
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A correct way from a multi-digit string value is
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*/
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std::cout << pdf(mydist8, cpp_dec_float_50("1.23456789012345678901234567890")) << std::endl;
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/*`
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[tip Getting about 17 decimal digits followed by many zeros is often a sign of accidental truncation.]
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*/
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/*`
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[h4 Default arguments to distribution constructors.]
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Note that default constructor arguments are only provided for some distributions.
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So if you wrongly assume a default argument, you will get an error message, for example:
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negative_binomial_distribution<> mydist8;
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[pre error C2512 no appropriate default constructor available.]
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No default constructors are provided for the `negative binomial` distribution,
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because it is difficult to chose any sensible default values for this distribution.
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For other distributions, like the normal distribution,
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it is obviously very useful to provide 'standard'
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defaults for the mean (zero) and standard deviation (unity) thus:
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normal_distribution(RealType mean = 0, RealType sd = 1);
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So in this case we can write:
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*/
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using boost::math::normal;
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normal norm1; // Standard normal distribution.
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normal norm2(2); // Mean = 2, std deviation = 1.
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normal norm3(2, 3); // Mean = 2, std deviation = 3.
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}
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catch(std::exception &ex)
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{
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std::cout << ex.what() << std::endl;
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}
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return 0;
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} // int main()
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/*`There is no useful output from this demonstration program, of course. */
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//] [/end of distribution_construction_2]
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/*
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//[distribution_construction_output
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0.00012630010495970320103876754721976419438231705359935
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0.00012630010495970318465064569310967179576805651692929
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0.00012630010495970318465064569310967179576805651692929
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0.00012630010495970320103876754721976419438231705359935
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//] [/distribution_construction_output]
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*/
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