boost_1_45_0/libs/random/test/histogram.cpp - nest-learning-thermostat/5.0/boost - Git at Google

 /* boost histogram.cpp graphical verification of distribution functions
  *
  * Copyright Jens Maurer 2000
  * Distributed under the Boost Software License, Version 1.0. (See
  * accompanying file LICENSE_1_0.txt or copy at
  * http://www.boost.org/LICENSE_1_0.txt)
  *
  * $Id: histogram.cpp 60755 2010-03-22 00:45:06Z steven_watanabe $
  *
  * This test program allows to visibly examine the results of the
  * distribution functions.
  */

 #include <iostream>
 #include <iomanip>
 #include <vector>
 #include <algorithm>
 #include <cmath>
 #include <string>
 #include <boost/random.hpp>


 void plot_histogram(const std::vector<int>& slots, int samples,
                     double from, double to)
 {
   int m = *std::max_element(slots.begin(), slots.end());
   const int nRows = 20;
   std::cout.setf(std::ios::fixed|std::ios::left);
   std::cout.precision(5);
   for(int r = 0; r < nRows; r++) {
     double y = ((nRows - r) * double(m))/(nRows * samples);
     std::cout << std::setw(10) << y << "  ";
     for(unsigned int col = 0; col < slots.size(); col++) {
       char out = ' ';
       if(slots[col]/double(samples) >= y)
         out = 'x';
       std::cout << out;
     }
     std::cout << std::endl;
   }
   std::cout << std::setw(12) << " "
             << std::setw(10) << from;
   std::cout.setf(std::ios::right, std::ios::adjustfield);
   std::cout << std::setw(slots.size()-10) << to << std::endl;
 }

 // I am not sure whether these two should be in the library as well

 // maintain sum of NumberGenerator results
 template<class NumberGenerator,
   class Sum = typename NumberGenerator::result_type>
 class sum_result
 {
 public:
   typedef NumberGenerator base_type;
   typedef typename base_type::result_type result_type;
   explicit sum_result(const base_type & g) : gen(g), _sum(0) { }
   result_type operator()() { result_type r = gen(); _sum += r; return r; }
   base_type & base() { return gen; }
   Sum sum() const { return _sum; }
   void reset() { _sum = 0; }
 private:
   base_type gen;
   Sum _sum;
 };


 // maintain square sum of NumberGenerator results
 template<class NumberGenerator,
   class Sum = typename NumberGenerator::result_type>
 class squaresum_result
 {
 public:
   typedef NumberGenerator base_type;
   typedef typename base_type::result_type result_type;
   explicit squaresum_result(const base_type & g) : gen(g), _sum(0) { }
   result_type operator()() { result_type r = gen(); _sum += r*r; return r; }
   base_type & base() { return gen; }
   Sum squaresum() const { return _sum; }
   void reset() { _sum = 0; }
 private:
   base_type gen;
   Sum _sum;
 };


 template<class RNG>
 void histogram(RNG base, int samples, double from, double to,
                const std::string & name)
 {
   typedef squaresum_result<sum_result<RNG, double>, double > SRNG;
   SRNG gen((sum_result<RNG, double>(base)));
   const int nSlots = 60;
   std::vector<int> slots(nSlots,0);
   for(int i = 0; i < samples; i++) {
     double val = gen();
     if(val < from || val >= to)    // early check avoids overflow
       continue;
     int slot = int((val-from)/(to-from) * nSlots);
     if(slot < 0 || slot > (int)slots.size())
       continue;
     slots[slot]++;
   }
   std::cout << name << std::endl;
   plot_histogram(slots, samples, from, to);
   double mean = gen.base().sum() / samples;
   std::cout << "mean: " << mean
             << " sigma: " << std::sqrt(gen.squaresum()/samples-mean*mean)
             << "\n" << std::endl;
 }

 template<class PRNG, class Dist>
 inline boost::variate_generator<PRNG&, Dist> make_gen(PRNG & rng, Dist d)
 {
   return boost::variate_generator<PRNG&, Dist>(rng, d);
 }

 template<class PRNG>
 void histograms()
 {
   PRNG rng;
   using namespace boost;
   histogram(make_gen(rng, uniform_smallint<>(0, 5)), 100000, -1, 6,
             "uniform_smallint(0,5)");
   histogram(make_gen(rng, uniform_int<>(0, 5)), 100000, -1, 6,
             "uniform_int(0,5)");
   histogram(make_gen(rng, uniform_real<>(0,1)), 100000, -0.5, 1.5,
             "uniform_real(0,1)");
   histogram(make_gen(rng, bernoulli_distribution<>(0.2)), 100000, -0.5, 1.5,
             "bernoulli(0.2)");
   histogram(make_gen(rng, binomial_distribution<>(4, 0.2)), 100000, -1, 5,
             "binomial(4, 0.2)");
   histogram(make_gen(rng, triangle_distribution<>(1, 2, 8)), 100000, 0, 10,
             "triangle(1,2,8)");
   histogram(make_gen(rng, geometric_distribution<>(5.0/6.0)), 100000, 0, 10,
             "geometric(5/6)");
   histogram(make_gen(rng, exponential_distribution<>(0.3)), 100000, 0, 10,
             "exponential(0.3)");
   histogram(make_gen(rng, cauchy_distribution<>()), 100000, -5, 5,
             "cauchy");
   histogram(make_gen(rng, lognormal_distribution<>(3, 2)), 100000, 0, 10,
             "lognormal");
   histogram(make_gen(rng, normal_distribution<>()), 100000, -3, 3,
             "normal");
   histogram(make_gen(rng, normal_distribution<>(0.5, 0.5)), 100000, -3, 3,
             "normal(0.5, 0.5)");
   histogram(make_gen(rng, poisson_distribution<>(1.5)), 100000, 0, 5,
             "poisson(1.5)");
   histogram(make_gen(rng, poisson_distribution<>(10)), 100000, 0, 20,
             "poisson(10)");
   histogram(make_gen(rng, gamma_distribution<>(0.5)), 100000, 0, 0.5,
             "gamma(0.5)");
   histogram(make_gen(rng, gamma_distribution<>(1)), 100000, 0, 3,
             "gamma(1)");
   histogram(make_gen(rng, gamma_distribution<>(2)), 100000, 0, 6,
             "gamma(2)");
 }


 int main()
 {
   histograms<boost::mt19937>();
   // histograms<boost::lagged_fibonacci607>();
 }
	/* boost histogram.cpp graphical verification of distribution functions
	*
	* Copyright Jens Maurer 2000
	* Distributed under the Boost Software License, Version 1.0. (See
	* accompanying file LICENSE_1_0.txt or copy at
	* http://www.boost.org/LICENSE_1_0.txt)
	*
	* $Id: histogram.cpp 60755 2010-03-22 00:45:06Z steven_watanabe $
	*
	* This test program allows to visibly examine the results of the
	* distribution functions.
	*/

	#include <iostream>
	#include <iomanip>
	#include <vector>
	#include <algorithm>
	#include <cmath>
	#include <string>
	#include <boost/random.hpp>


	void plot_histogram(const std::vector<int>& slots, int samples,
	double from, double to)
	{
	int m = *std::max_element(slots.begin(), slots.end());
	const int nRows = 20;
	std::cout.setf(std::ios::fixed\|std::ios::left);
	std::cout.precision(5);
	for(int r = 0; r < nRows; r++) {
	double y = ((nRows - r) * double(m))/(nRows * samples);
	std::cout << std::setw(10) << y << " ";
	for(unsigned int col = 0; col < slots.size(); col++) {
	char out = ' ';
	if(slots[col]/double(samples) >= y)
	out = 'x';
	std::cout << out;
	}
	std::cout << std::endl;
	}
	std::cout << std::setw(12) << " "
	<< std::setw(10) << from;
	std::cout.setf(std::ios::right, std::ios::adjustfield);
	std::cout << std::setw(slots.size()-10) << to << std::endl;
	}

	// I am not sure whether these two should be in the library as well

	// maintain sum of NumberGenerator results
	template<class NumberGenerator,
	class Sum = typename NumberGenerator::result_type>
	class sum_result
	{
	public:
	typedef NumberGenerator base_type;
	typedef typename base_type::result_type result_type;
	explicit sum_result(const base_type & g) : gen(g), _sum(0) { }
	result_type operator()() { result_type r = gen(); _sum += r; return r; }
	base_type & base() { return gen; }
	Sum sum() const { return _sum; }
	void reset() { _sum = 0; }
	private:
	base_type gen;
	Sum _sum;
	};


	// maintain square sum of NumberGenerator results
	template<class NumberGenerator,
	class Sum = typename NumberGenerator::result_type>
	class squaresum_result
	{
	public:
	typedef NumberGenerator base_type;
	typedef typename base_type::result_type result_type;
	explicit squaresum_result(const base_type & g) : gen(g), _sum(0) { }
	result_type operator()() { result_type r = gen(); _sum += r*r; return r; }
	base_type & base() { return gen; }
	Sum squaresum() const { return _sum; }
	void reset() { _sum = 0; }
	private:
	base_type gen;
	Sum _sum;
	};


	template<class RNG>
	void histogram(RNG base, int samples, double from, double to,
	const std::string & name)
	{
	typedef squaresum_result<sum_result<RNG, double>, double > SRNG;
	SRNG gen((sum_result<RNG, double>(base)));
	const int nSlots = 60;
	std::vector<int> slots(nSlots,0);
	for(int i = 0; i < samples; i++) {
	double val = gen();
	if(val < from \|\| val >= to) // early check avoids overflow
	continue;
	int slot = int((val-from)/(to-from) * nSlots);
	if(slot < 0 \|\| slot > (int)slots.size())
	continue;
	slots[slot]++;
	}
	std::cout << name << std::endl;
	plot_histogram(slots, samples, from, to);
	double mean = gen.base().sum() / samples;
	std::cout << "mean: " << mean
	<< " sigma: " << std::sqrt(gen.squaresum()/samples-mean*mean)
	<< "\n" << std::endl;
	}

	template<class PRNG, class Dist>
	inline boost::variate_generator<PRNG&, Dist> make_gen(PRNG & rng, Dist d)
	{
	return boost::variate_generator<PRNG&, Dist>(rng, d);
	}

	template<class PRNG>
	void histograms()
	{
	PRNG rng;
	using namespace boost;
	histogram(make_gen(rng, uniform_smallint<>(0, 5)), 100000, -1, 6,
	"uniform_smallint(0,5)");
	histogram(make_gen(rng, uniform_int<>(0, 5)), 100000, -1, 6,
	"uniform_int(0,5)");
	histogram(make_gen(rng, uniform_real<>(0,1)), 100000, -0.5, 1.5,
	"uniform_real(0,1)");
	histogram(make_gen(rng, bernoulli_distribution<>(0.2)), 100000, -0.5, 1.5,
	"bernoulli(0.2)");
	histogram(make_gen(rng, binomial_distribution<>(4, 0.2)), 100000, -1, 5,
	"binomial(4, 0.2)");
	histogram(make_gen(rng, triangle_distribution<>(1, 2, 8)), 100000, 0, 10,
	"triangle(1,2,8)");
	histogram(make_gen(rng, geometric_distribution<>(5.0/6.0)), 100000, 0, 10,
	"geometric(5/6)");
	histogram(make_gen(rng, exponential_distribution<>(0.3)), 100000, 0, 10,
	"exponential(0.3)");
	histogram(make_gen(rng, cauchy_distribution<>()), 100000, -5, 5,
	"cauchy");
	histogram(make_gen(rng, lognormal_distribution<>(3, 2)), 100000, 0, 10,
	"lognormal");
	histogram(make_gen(rng, normal_distribution<>()), 100000, -3, 3,
	"normal");
	histogram(make_gen(rng, normal_distribution<>(0.5, 0.5)), 100000, -3, 3,
	"normal(0.5, 0.5)");
	histogram(make_gen(rng, poisson_distribution<>(1.5)), 100000, 0, 5,
	"poisson(1.5)");
	histogram(make_gen(rng, poisson_distribution<>(10)), 100000, 0, 20,
	"poisson(10)");
	histogram(make_gen(rng, gamma_distribution<>(0.5)), 100000, 0, 0.5,
	"gamma(0.5)");
	histogram(make_gen(rng, gamma_distribution<>(1)), 100000, 0, 3,
	"gamma(1)");
	histogram(make_gen(rng, gamma_distribution<>(2)), 100000, 0, 6,
	"gamma(2)");
	}


	int main()
	{
	histograms<boost::mt19937>();
	// histograms<boost::lagged_fibonacci607>();
	}