boost_1_45_0/libs/math/tools/ibeta_data.cpp - nest-learning-thermostat/5.0/boost - Git at Google

 //  (C) Copyright John Maddock 2006.
 //  Use, modification and distribution are subject to 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)

 #include <boost/math/bindings/rr.hpp>
 #include <boost/test/included/test_exec_monitor.hpp>
 #include <boost/math/special_functions/gamma.hpp>
 #include <boost/math/special_functions/beta.hpp>
 #include <boost/math/constants/constants.hpp>
 #include <boost/math/tools/test.hpp>
 #include <boost/lexical_cast.hpp>
 #include <fstream>
 #include <map>

 #include <boost/math/tools/test_data.hpp>

 using namespace boost::math::tools;
 using namespace boost::math;
 using namespace std;

 template <class T>
 struct ibeta_fraction1_t
 {
    typedef std::pair<T, T> result_type;

    ibeta_fraction1_t(T a_, T b_, T x_) : a(a_), b(b_), x(x_), k(1) {}

    result_type operator()()
    {
       T aN;
       if(k & 1)
       {
          int m = (k - 1) / 2;
          aN = -(a + m) * (a + b + m) * x;
          aN /= a + 2*m;
          aN /= a + 2*m + 1;
       }
       else
       {
          int m = k / 2;
          aN = m * (b - m) *x;
          aN /= a + 2*m - 1;
          aN /= a + 2*m;
       }
       ++k;
       return std::make_pair(aN, T(1));
    }

 private:
    T a, b, x;
    int k;
 };

 //
 // This function caches previous calls to beta
 // just so we can speed things up a bit:
 //
 template <class T>
 T get_beta(T a, T b)
 {
    static std::map<std::pair<T, T>, T> m;

    if(a < b)
       std::swap(a, b);

    std::pair<T, T> p(a, b);
    typename std::map<std::pair<T, T>, T>::const_iterator i = m.find(p);
    if(i != m.end())
       return i->second;

    T r = beta(a, b);
    p.first = a;
    p.second = b;
    m[p] = r;

    return r;
 }

 //
 // compute the continued fraction:
 //
 template <class T>
 T get_ibeta_fraction1(T a, T b, T x)
 {
    ibeta_fraction1_t<T> f(a, b, x);
    T fract = boost::math::tools::continued_fraction_a(f, boost::math::policies::digits<T, boost::math::policies::policy<> >());
    T denom = (a * (fract + 1));
    T num = pow(x, a) * pow(1 - x, b);
    if(num == 0)
       return 0;
    else if(denom == 0)
       return -1;
    return num / denom;
 }
 //
 // calculate the incomplete beta from the fraction:
 //
 template <class T>
 std::pair<T,T> ibeta_fraction1(T a, T b, T x)
 {
    T bet = get_beta(a, b);
    if(x > ((a+1)/(a+b+2)))
    {
       T fract = get_ibeta_fraction1(b, a, 1-x);
       if(fract/bet > 0.75)
       {
          fract = get_ibeta_fraction1(a, b, x);
          return std::make_pair(fract, bet - fract);
       }
       return std::make_pair(bet - fract, fract);
    }
    T fract = get_ibeta_fraction1(a, b, x);
    if(fract/bet > 0.75)
    {
       fract = get_ibeta_fraction1(b, a, 1-x);
       return std::make_pair(bet - fract, fract);
    }
    return std::make_pair(fract, bet - fract);

 }
 //
 // calculate the regularised incomplete beta from the fraction:
 //
 template <class T>
 std::pair<T,T> ibeta_fraction1_regular(T a, T b, T x)
 {
    T bet = get_beta(a, b);
    if(x > ((a+1)/(a+b+2)))
    {
       T fract = get_ibeta_fraction1(b, a, 1-x);
       if(fract == 0)
          bet = 1;  // normalise so we don't get 0/0
       else if(bet == 0)
          return std::make_pair(T(-1), T(-1)); // Yikes!!
       if(fract / bet > 0.75)
       {
          fract = get_ibeta_fraction1(a, b, x);
          return std::make_pair(fract / bet, 1 - (fract / bet));
       }
       return std::make_pair(1 - (fract / bet), fract / bet);
    }
    T fract = get_ibeta_fraction1(a, b, x);
    if(fract / bet > 0.75)
    {
       fract = get_ibeta_fraction1(b, a, 1-x);
       return std::make_pair(1 - (fract / bet), fract / bet);
    }
    return std::make_pair(fract / bet, 1 - (fract / bet));
 }

 //
 // we absolutely must trunctate the input values to float
 // precision: we have to be certain that the input values
 // can be represented exactly in whatever width floating
 // point type we are testing, otherwise the output will
 // necessarily be off.
 //
 float external_f;
 float force_truncate(const float* f)
 {
    external_f = *f;
    return external_f;
 }

 float truncate_to_float(boost::math::ntl::RR r)
 {
    float f = boost::math::tools::real_cast<float>(r);
    return force_truncate(&f);
 }

 std::tr1::mt19937 rnd;
 std::tr1::uniform_real<float> ur_a(1.0F, 5.0F);
 std::tr1::variate_generator<std::tr1::mt19937, std::tr1::uniform_real<float> > gen(rnd, ur_a);
 std::tr1::uniform_real<float> ur_a2(0.0F, 100.0F);
 std::tr1::variate_generator<std::tr1::mt19937, std::tr1::uniform_real<float> > gen2(rnd, ur_a2);

 struct beta_data_generator
 {
    boost::math::tuple<boost::math::ntl::RR, boost::math::ntl::RR, boost::math::ntl::RR, boost::math::ntl::RR, boost::math::ntl::RR, boost::math::ntl::RR, boost::math::ntl::RR> operator()(boost::math::ntl::RR ap, boost::math::ntl::RR bp, boost::math::ntl::RR x_)
    {
       float a = truncate_to_float(real_cast<float>(gen() * pow(boost::math::ntl::RR(10), ap)));
       float b = truncate_to_float(real_cast<float>(gen() * pow(boost::math::ntl::RR(10), bp)));
       float x = truncate_to_float(real_cast<float>(x_));
       std::cout << a << " " << b << " " << x << std::endl;
       std::pair<boost::math::ntl::RR, boost::math::ntl::RR> ib_full = ibeta_fraction1(boost::math::ntl::RR(a), boost::math::ntl::RR(b), boost::math::ntl::RR(x));
       std::pair<boost::math::ntl::RR, boost::math::ntl::RR> ib_reg = ibeta_fraction1_regular(boost::math::ntl::RR(a), boost::math::ntl::RR(b), boost::math::ntl::RR(x));
       return boost::math::make_tuple(a, b, x, ib_full.first, ib_full.second, ib_reg.first, ib_reg.second);
    }
 };

 // medium sized values:
 struct beta_data_generator_medium
 {
    boost::math::tuple<boost::math::ntl::RR, boost::math::ntl::RR, boost::math::ntl::RR, boost::math::ntl::RR, boost::math::ntl::RR, boost::math::ntl::RR, boost::math::ntl::RR> operator()(boost::math::ntl::RR x_)
    {
       boost::math::ntl::RR a = gen2();
       boost::math::ntl::RR b = gen2();
       boost::math::ntl::RR x = x_;
       a = ConvPrec(a.value(), 22);
       b = ConvPrec(b.value(), 22);
       x = ConvPrec(x.value(), 22);
       std::cout << a << " " << b << " " << x << std::endl;
       //boost::math::ntl::RR exp_beta = boost::math::beta(a, b, x);
       std::pair<boost::math::ntl::RR, boost::math::ntl::RR> ib_full = ibeta_fraction1(boost::math::ntl::RR(a), boost::math::ntl::RR(b), boost::math::ntl::RR(x));
       /*exp_beta = boost::math::tools::relative_error(ib_full.first, exp_beta);
       if(exp_beta > 1e-40)
       {
          std::cout << exp_beta << std::endl;
       }*/
       std::pair<boost::math::ntl::RR, boost::math::ntl::RR> ib_reg = ibeta_fraction1_regular(boost::math::ntl::RR(a), boost::math::ntl::RR(b), boost::math::ntl::RR(x));
       return boost::math::make_tuple(a, b, x, ib_full.first, ib_full.second, ib_reg.first, ib_reg.second);
    }
 };

 struct beta_data_generator_small
 {
    boost::math::tuple<boost::math::ntl::RR, boost::math::ntl::RR, boost::math::ntl::RR, boost::math::ntl::RR, boost::math::ntl::RR, boost::math::ntl::RR, boost::math::ntl::RR> operator()(boost::math::ntl::RR x_)
    {
       float a = truncate_to_float(gen2()/10);
       float b = truncate_to_float(gen2()/10);
       float x = truncate_to_float(real_cast<float>(x_));
       std::cout << a << " " << b << " " << x << std::endl;
       std::pair<boost::math::ntl::RR, boost::math::ntl::RR> ib_full = ibeta_fraction1(boost::math::ntl::RR(a), boost::math::ntl::RR(b), boost::math::ntl::RR(x));
       std::pair<boost::math::ntl::RR, boost::math::ntl::RR> ib_reg = ibeta_fraction1_regular(boost::math::ntl::RR(a), boost::math::ntl::RR(b), boost::math::ntl::RR(x));
       return boost::math::make_tuple(a, b, x, ib_full.first, ib_full.second, ib_reg.first, ib_reg.second);
    }
 };

 struct beta_data_generator_int
 {
    boost::math::tuple<boost::math::ntl::RR, boost::math::ntl::RR, boost::math::ntl::RR, boost::math::ntl::RR, boost::math::ntl::RR, boost::math::ntl::RR, boost::math::ntl::RR> operator()(boost::math::ntl::RR a, boost::math::ntl::RR b, boost::math::ntl::RR x_)
    {
       float x = truncate_to_float(real_cast<float>(x_));
       std::cout << a << " " << b << " " << x << std::endl;
       std::pair<boost::math::ntl::RR, boost::math::ntl::RR> ib_full = ibeta_fraction1(a, b, boost::math::ntl::RR(x));
       std::pair<boost::math::ntl::RR, boost::math::ntl::RR> ib_reg = ibeta_fraction1_regular(a, b, boost::math::ntl::RR(x));
       return boost::math::make_tuple(a, b, x, ib_full.first, ib_full.second, ib_reg.first, ib_reg.second);
    }
 };

 int test_main(int, char* [])
 {
    boost::math::ntl::RR::SetPrecision(1000);
    boost::math::ntl::RR::SetOutputPrecision(40);

    parameter_info<boost::math::ntl::RR> arg1, arg2, arg3, arg4, arg5;
    test_data<boost::math::ntl::RR> data;

    std::cout << "Welcome.\n"
       "This program will generate spot tests for the incomplete beta functions:\n"
       "  beta(a, b, x) and ibeta(a, b, x)\n\n"
       "This is not an interactive program be prepared for a long wait!!!\n\n";

    arg1 = make_periodic_param(boost::math::ntl::RR(-5), boost::math::ntl::RR(6), 11);
    arg2 = make_periodic_param(boost::math::ntl::RR(-5), boost::math::ntl::RR(6), 11);
    arg3 = make_random_param(boost::math::ntl::RR(0.0001), boost::math::ntl::RR(1), 10);
    arg4 = make_random_param(boost::math::ntl::RR(0.0001), boost::math::ntl::RR(1), 100 /*500*/);
    arg5 = make_periodic_param(boost::math::ntl::RR(1), boost::math::ntl::RR(41), 10);

    arg1.type |= dummy_param;
    arg2.type |= dummy_param;
    arg3.type |= dummy_param;
    arg4.type |= dummy_param;
    arg5.type |= dummy_param;

    // comment out all but one of the following when running
    // or this program will take forever to complete!
    //data.insert(beta_data_generator(), arg1, arg2, arg3);
    //data.insert(beta_data_generator_medium(), arg4);
    //data.insert(beta_data_generator_small(), arg4);
    data.insert(beta_data_generator_int(), arg5, arg5, arg3);

    test_data<boost::math::ntl::RR>::const_iterator i, j;
    i = data.begin();
    j = data.end();
    while(i != j)
    {
       boost::math::ntl::RR v1 = beta((*i)[0], (*i)[1], (*i)[2]);
       boost::math::ntl::RR v2 = relative_error(v1, (*i)[3]);
       std::string s = boost::lexical_cast<std::string>((*i)[3]);
       boost::math::ntl::RR v3 = boost::lexical_cast<boost::math::ntl::RR>(s);
       boost::math::ntl::RR v4 = relative_error(v3, (*i)[3]);
       if(v2 > 1e-40)
       {
          std::cout << v2 << std::endl;
       }
       if(v4 > 1e-60)
       {
          std::cout << v4 << std::endl;
       }
       ++ i;
    }

    std::cout << "Enter name of test data file [default=ibeta_data.ipp]";
    std::string line;
    std::getline(std::cin, line);
    boost::algorithm::trim(line);
    if(line == "")
       line = "ibeta_data.ipp";
    std::ofstream ofs(line.c_str());
    write_code(ofs, data, "ibeta_data");

    return 0;
 }
	// (C) Copyright John Maddock 2006.
	// Use, modification and distribution are subject to 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)

	#include <boost/math/bindings/rr.hpp>
	#include <boost/test/included/test_exec_monitor.hpp>
	#include <boost/math/special_functions/gamma.hpp>
	#include <boost/math/special_functions/beta.hpp>
	#include <boost/math/constants/constants.hpp>
	#include <boost/math/tools/test.hpp>
	#include <boost/lexical_cast.hpp>
	#include <fstream>
	#include <map>

	#include <boost/math/tools/test_data.hpp>

	using namespace boost::math::tools;
	using namespace boost::math;
	using namespace std;

	template <class T>
	struct ibeta_fraction1_t
	{
	typedef std::pair<T, T> result_type;

	ibeta_fraction1_t(T a_, T b_, T x_) : a(a_), b(b_), x(x_), k(1) {}

	result_type operator()()
	{
	T aN;
	if(k & 1)
	{
	int m = (k - 1) / 2;
	aN = -(a + m) * (a + b + m) * x;
	aN /= a + 2*m;
	aN /= a + 2*m + 1;
	}
	else
	{
	int m = k / 2;
	aN = m * (b - m) *x;
	aN /= a + 2*m - 1;
	aN /= a + 2*m;
	}
	++k;
	return std::make_pair(aN, T(1));
	}

	private:
	T a, b, x;
	int k;
	};

	//
	// This function caches previous calls to beta
	// just so we can speed things up a bit:
	//
	template <class T>
	T get_beta(T a, T b)
	{
	static std::map<std::pair<T, T>, T> m;

	if(a < b)
	std::swap(a, b);

	std::pair<T, T> p(a, b);
	typename std::map<std::pair<T, T>, T>::const_iterator i = m.find(p);
	if(i != m.end())
	return i->second;

	T r = beta(a, b);
	p.first = a;
	p.second = b;
	m[p] = r;

	return r;
	}

	//
	// compute the continued fraction:
	//
	template <class T>
	T get_ibeta_fraction1(T a, T b, T x)
	{
	ibeta_fraction1_t<T> f(a, b, x);
	T fract = boost::math::tools::continued_fraction_a(f, boost::math::policies::digits<T, boost::math::policies::policy<> >());
	T denom = (a * (fract + 1));
	T num = pow(x, a) * pow(1 - x, b);
	if(num == 0)
	return 0;
	else if(denom == 0)
	return -1;
	return num / denom;
	}
	//
	// calculate the incomplete beta from the fraction:
	//
	template <class T>
	std::pair<T,T> ibeta_fraction1(T a, T b, T x)
	{
	T bet = get_beta(a, b);
	if(x > ((a+1)/(a+b+2)))
	{
	T fract = get_ibeta_fraction1(b, a, 1-x);
	if(fract/bet > 0.75)
	{
	fract = get_ibeta_fraction1(a, b, x);
	return std::make_pair(fract, bet - fract);
	}
	return std::make_pair(bet - fract, fract);
	}
	T fract = get_ibeta_fraction1(a, b, x);
	if(fract/bet > 0.75)
	{
	fract = get_ibeta_fraction1(b, a, 1-x);
	return std::make_pair(bet - fract, fract);
	}
	return std::make_pair(fract, bet - fract);

	}
	//
	// calculate the regularised incomplete beta from the fraction:
	//
	template <class T>
	std::pair<T,T> ibeta_fraction1_regular(T a, T b, T x)
	{
	T bet = get_beta(a, b);
	if(x > ((a+1)/(a+b+2)))
	{
	T fract = get_ibeta_fraction1(b, a, 1-x);
	if(fract == 0)
	bet = 1; // normalise so we don't get 0/0
	else if(bet == 0)
	return std::make_pair(T(-1), T(-1)); // Yikes!!
	if(fract / bet > 0.75)
	{
	fract = get_ibeta_fraction1(a, b, x);
	return std::make_pair(fract / bet, 1 - (fract / bet));
	}
	return std::make_pair(1 - (fract / bet), fract / bet);
	}
	T fract = get_ibeta_fraction1(a, b, x);
	if(fract / bet > 0.75)
	{
	fract = get_ibeta_fraction1(b, a, 1-x);
	return std::make_pair(1 - (fract / bet), fract / bet);
	}
	return std::make_pair(fract / bet, 1 - (fract / bet));
	}

	//
	// we absolutely must trunctate the input values to float
	// precision: we have to be certain that the input values
	// can be represented exactly in whatever width floating
	// point type we are testing, otherwise the output will
	// necessarily be off.
	//
	float external_f;
	float force_truncate(const float* f)
	{
	external_f = *f;
	return external_f;
	}

	float truncate_to_float(boost::math::ntl::RR r)
	{
	float f = boost::math::tools::real_cast<float>(r);
	return force_truncate(&f);
	}

	std::tr1::mt19937 rnd;
	std::tr1::uniform_real<float> ur_a(1.0F, 5.0F);
	std::tr1::variate_generator<std::tr1::mt19937, std::tr1::uniform_real<float> > gen(rnd, ur_a);
	std::tr1::uniform_real<float> ur_a2(0.0F, 100.0F);
	std::tr1::variate_generator<std::tr1::mt19937, std::tr1::uniform_real<float> > gen2(rnd, ur_a2);

	struct beta_data_generator
	{
	boost::math::tuple<boost::math::ntl::RR, boost::math::ntl::RR, boost::math::ntl::RR, boost::math::ntl::RR, boost::math::ntl::RR, boost::math::ntl::RR, boost::math::ntl::RR> operator()(boost::math::ntl::RR ap, boost::math::ntl::RR bp, boost::math::ntl::RR x_)
	{
	float a = truncate_to_float(real_cast<float>(gen() * pow(boost::math::ntl::RR(10), ap)));
	float b = truncate_to_float(real_cast<float>(gen() * pow(boost::math::ntl::RR(10), bp)));
	float x = truncate_to_float(real_cast<float>(x_));
	std::cout << a << " " << b << " " << x << std::endl;
	std::pair<boost::math::ntl::RR, boost::math::ntl::RR> ib_full = ibeta_fraction1(boost::math::ntl::RR(a), boost::math::ntl::RR(b), boost::math::ntl::RR(x));
	std::pair<boost::math::ntl::RR, boost::math::ntl::RR> ib_reg = ibeta_fraction1_regular(boost::math::ntl::RR(a), boost::math::ntl::RR(b), boost::math::ntl::RR(x));
	return boost::math::make_tuple(a, b, x, ib_full.first, ib_full.second, ib_reg.first, ib_reg.second);
	}
	};

	// medium sized values:
	struct beta_data_generator_medium
	{
	boost::math::tuple<boost::math::ntl::RR, boost::math::ntl::RR, boost::math::ntl::RR, boost::math::ntl::RR, boost::math::ntl::RR, boost::math::ntl::RR, boost::math::ntl::RR> operator()(boost::math::ntl::RR x_)
	{
	boost::math::ntl::RR a = gen2();
	boost::math::ntl::RR b = gen2();
	boost::math::ntl::RR x = x_;
	a = ConvPrec(a.value(), 22);
	b = ConvPrec(b.value(), 22);
	x = ConvPrec(x.value(), 22);
	std::cout << a << " " << b << " " << x << std::endl;
	//boost::math::ntl::RR exp_beta = boost::math::beta(a, b, x);
	std::pair<boost::math::ntl::RR, boost::math::ntl::RR> ib_full = ibeta_fraction1(boost::math::ntl::RR(a), boost::math::ntl::RR(b), boost::math::ntl::RR(x));
	/*exp_beta = boost::math::tools::relative_error(ib_full.first, exp_beta);
	if(exp_beta > 1e-40)
	{
	std::cout << exp_beta << std::endl;
	}*/
	std::pair<boost::math::ntl::RR, boost::math::ntl::RR> ib_reg = ibeta_fraction1_regular(boost::math::ntl::RR(a), boost::math::ntl::RR(b), boost::math::ntl::RR(x));
	return boost::math::make_tuple(a, b, x, ib_full.first, ib_full.second, ib_reg.first, ib_reg.second);
	}
	};

	struct beta_data_generator_small
	{
	boost::math::tuple<boost::math::ntl::RR, boost::math::ntl::RR, boost::math::ntl::RR, boost::math::ntl::RR, boost::math::ntl::RR, boost::math::ntl::RR, boost::math::ntl::RR> operator()(boost::math::ntl::RR x_)
	{
	float a = truncate_to_float(gen2()/10);
	float b = truncate_to_float(gen2()/10);
	float x = truncate_to_float(real_cast<float>(x_));
	std::cout << a << " " << b << " " << x << std::endl;
	std::pair<boost::math::ntl::RR, boost::math::ntl::RR> ib_full = ibeta_fraction1(boost::math::ntl::RR(a), boost::math::ntl::RR(b), boost::math::ntl::RR(x));
	std::pair<boost::math::ntl::RR, boost::math::ntl::RR> ib_reg = ibeta_fraction1_regular(boost::math::ntl::RR(a), boost::math::ntl::RR(b), boost::math::ntl::RR(x));
	return boost::math::make_tuple(a, b, x, ib_full.first, ib_full.second, ib_reg.first, ib_reg.second);
	}
	};

	struct beta_data_generator_int
	{
	boost::math::tuple<boost::math::ntl::RR, boost::math::ntl::RR, boost::math::ntl::RR, boost::math::ntl::RR, boost::math::ntl::RR, boost::math::ntl::RR, boost::math::ntl::RR> operator()(boost::math::ntl::RR a, boost::math::ntl::RR b, boost::math::ntl::RR x_)
	{
	float x = truncate_to_float(real_cast<float>(x_));
	std::cout << a << " " << b << " " << x << std::endl;
	std::pair<boost::math::ntl::RR, boost::math::ntl::RR> ib_full = ibeta_fraction1(a, b, boost::math::ntl::RR(x));
	std::pair<boost::math::ntl::RR, boost::math::ntl::RR> ib_reg = ibeta_fraction1_regular(a, b, boost::math::ntl::RR(x));
	return boost::math::make_tuple(a, b, x, ib_full.first, ib_full.second, ib_reg.first, ib_reg.second);
	}
	};

	int test_main(int, char* [])
	{
	boost::math::ntl::RR::SetPrecision(1000);
	boost::math::ntl::RR::SetOutputPrecision(40);

	parameter_info<boost::math::ntl::RR> arg1, arg2, arg3, arg4, arg5;
	test_data<boost::math::ntl::RR> data;

	std::cout << "Welcome.\n"
	"This program will generate spot tests for the incomplete beta functions:\n"
	" beta(a, b, x) and ibeta(a, b, x)\n\n"
	"This is not an interactive program be prepared for a long wait!!!\n\n";

	arg1 = make_periodic_param(boost::math::ntl::RR(-5), boost::math::ntl::RR(6), 11);
	arg2 = make_periodic_param(boost::math::ntl::RR(-5), boost::math::ntl::RR(6), 11);
	arg3 = make_random_param(boost::math::ntl::RR(0.0001), boost::math::ntl::RR(1), 10);
	arg4 = make_random_param(boost::math::ntl::RR(0.0001), boost::math::ntl::RR(1), 100 /500/);
	arg5 = make_periodic_param(boost::math::ntl::RR(1), boost::math::ntl::RR(41), 10);

	arg1.type \|= dummy_param;
	arg2.type \|= dummy_param;
	arg3.type \|= dummy_param;
	arg4.type \|= dummy_param;
	arg5.type \|= dummy_param;

	// comment out all but one of the following when running
	// or this program will take forever to complete!
	//data.insert(beta_data_generator(), arg1, arg2, arg3);
	//data.insert(beta_data_generator_medium(), arg4);
	//data.insert(beta_data_generator_small(), arg4);
	data.insert(beta_data_generator_int(), arg5, arg5, arg3);

	test_data<boost::math::ntl::RR>::const_iterator i, j;
	i = data.begin();
	j = data.end();
	while(i != j)
	{
	boost::math::ntl::RR v1 = beta((i)[0], (i)[1], (*i)[2]);
	boost::math::ntl::RR v2 = relative_error(v1, (*i)[3]);
	std::string s = boost::lexical_cast<std::string>((*i)[3]);
	boost::math::ntl::RR v3 = boost::lexical_cast<boost::math::ntl::RR>(s);
	boost::math::ntl::RR v4 = relative_error(v3, (*i)[3]);
	if(v2 > 1e-40)
	{
	std::cout << v2 << std::endl;
	}
	if(v4 > 1e-60)
	{
	std::cout << v4 << std::endl;
	}
	++ i;
	}

	std::cout << "Enter name of test data file [default=ibeta_data.ipp]";
	std::string line;
	std::getline(std::cin, line);
	boost::algorithm::trim(line);
	if(line == "")
	line = "ibeta_data.ipp";
	std::ofstream ofs(line.c_str());
	write_code(ofs, data, "ibeta_data");

	return 0;
	}