boost_1_45_0/libs/numeric/interval/examples/newton-raphson.cpp - nest-learning-thermostat/5.0/boost - Git at Google

 /* Boost example/newton-raphson.cpp
  * Newton iteration for intervals
  *
  * Copyright 2003 Guillaume Melquiond
  *
  * 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)
  */

 #include <boost/numeric/interval.hpp>
 #include <vector>
 #include <algorithm>
 #include <utility>
 #include <iostream>
 #include <iomanip>

 template <class I> I f(const I& x)
 { return x * (x - 1.) * (x - 2.) * (x - 3.) * (x - 4.); }
 template <class I> I f_diff(const I& x)
 { return (((5. * x - 40.) * x + 105.) * x - 100.) * x + 24.; }

 static const double max_width = 1e-10;
 static const double alpha = 0.75;

 using namespace boost;
 using namespace numeric;
 using namespace interval_lib;

 // First method: no empty intervals

 typedef interval<double> I1_aux;
 typedef unprotect<I1_aux>::type I1;

 std::vector<I1> newton_raphson(const I1& xs) {
   std::vector<I1> l, res;
   I1 vf, vd, x, x1, x2;
   l.push_back(xs);
   while (!l.empty()) {
     x = l.back();
     l.pop_back();
     bool x2_used;
     double xx = median(x);
     vf = f<I1>(xx);
     vd = f_diff<I1>(x);
     if (zero_in(vf) && zero_in(vd)) {
       x1 = I1::whole();
       x2_used = false;
     } else {
       x1 = xx - division_part1(vf, vd, x2_used);
       if (x2_used) x2 = xx - division_part2(vf, vd);
     }
     if (overlap(x1, x)) x1 = intersect(x, x1);
     else if (x2_used) { x1 = x2; x2_used = false; }
     else continue;
     if (x2_used)
       if (overlap(x2, x)) x2 = intersect(x, x2);
       else x2_used = false;
     if (x2_used && width(x2) > width(x1)) std::swap(x1, x2);
     if (!zero_in(f(x1)))
       if (x2_used) { x1 = x2; x2_used = false; }
       else continue;
     if (width(x1) < max_width) res.push_back(x1);
     else if (width(x1) > alpha * width(x)) {
       std::pair<I1, I1> p = bisect(x);
       if (zero_in(f(p.first))) l.push_back(p.first);
       x2 = p.second;
       x2_used = true;
     } else l.push_back(x1);
     if (x2_used && zero_in(f(x2)))
       if (width(x2) < max_width) res.push_back(x2);
       else l.push_back(x2);
   }
   return res;
 }

 // Second method: with empty intervals

 typedef change_checking<I1_aux, checking_no_nan<double> >::type I2_aux;
 typedef unprotect<I2_aux>::type I2;

 std::vector<I2> newton_raphson(const I2& xs) {
   std::vector<I2> l, res;
   I2 vf, vd, x, x1, x2;
   l.push_back(xs);
   while (!l.empty()) {
     x = l.back();
     l.pop_back();
     double xx = median(x);
     vf = f<I2>(xx);
     vd = f_diff<I2>(x);
     if (zero_in(vf) && zero_in(vd)) {
       x1 = x;
       x2 = I2::empty();
     } else {
       bool x2_used;
       x1 = intersect(x, xx - division_part1(vf, vd, x2_used));
       x2 = intersect(x, xx - division_part2(vf, vd, x2_used));
     }
     if (width(x2) > width(x1)) std::swap(x1, x2);
     if (empty(x1) || !zero_in(f(x1)))
       if (!empty(x2)) { x1 = x2; x2 = I2::empty(); }
       else continue;
     if (width(x1) < max_width) res.push_back(x1);
     else if (width(x1) > alpha * width(x)) {
       std::pair<I2, I2> p = bisect(x);
       if (zero_in(f(p.first))) l.push_back(p.first);
       x2 = p.second;
     } else l.push_back(x1);
     if (!empty(x2) && zero_in(f(x2)))
       if (width(x2) < max_width) res.push_back(x2);
       else l.push_back(x2);
   }
   return res;
 }

 template<class T, class Policies>
 std::ostream &operator<<(std::ostream &os,
                          const boost::numeric::interval<T, Policies> &x) {
   os << "[" << x.lower() << ", " << x.upper() << "]";
   return os;
 }

 int main() {
   {
     I1_aux::traits_type::rounding rnd;
     std::vector<I1> res = newton_raphson(I1(-1, 5.1));
     std::cout << "Results: " << std::endl << std::setprecision(12);
     for(std::vector<I1>::const_iterator i = res.begin(); i != res.end(); ++i)
       std::cout << "  " << *i << std::endl;
     std::cout << std::endl;
   }
   {
     I2_aux::traits_type::rounding rnd;
     std::vector<I2> res = newton_raphson(I2(-1, 5.1));
     std::cout << "Results: " << std::endl << std::setprecision(12);
     for(std::vector<I2>::const_iterator i = res.begin(); i != res.end(); ++i)
       std::cout << "  " << *i << std::endl;
     std::cout << std::endl;
   }
 }
	/* Boost example/newton-raphson.cpp
	* Newton iteration for intervals
	*
	* Copyright 2003 Guillaume Melquiond
	*
	* 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)
	*/

	#include <boost/numeric/interval.hpp>
	#include <vector>
	#include <algorithm>
	#include <utility>
	#include <iostream>
	#include <iomanip>

	template <class I> I f(const I& x)
	{ return x * (x - 1.) * (x - 2.) * (x - 3.) * (x - 4.); }
	template <class I> I f_diff(const I& x)
	{ return (((5. * x - 40.) * x + 105.) * x - 100.) * x + 24.; }

	static const double max_width = 1e-10;
	static const double alpha = 0.75;

	using namespace boost;
	using namespace numeric;
	using namespace interval_lib;

	// First method: no empty intervals

	typedef interval<double> I1_aux;
	typedef unprotect<I1_aux>::type I1;

	std::vector<I1> newton_raphson(const I1& xs) {
	std::vector<I1> l, res;
	I1 vf, vd, x, x1, x2;
	l.push_back(xs);
	while (!l.empty()) {
	x = l.back();
	l.pop_back();
	bool x2_used;
	double xx = median(x);
	vf = f<I1>(xx);
	vd = f_diff<I1>(x);
	if (zero_in(vf) && zero_in(vd)) {
	x1 = I1::whole();
	x2_used = false;
	} else {
	x1 = xx - division_part1(vf, vd, x2_used);
	if (x2_used) x2 = xx - division_part2(vf, vd);
	}
	if (overlap(x1, x)) x1 = intersect(x, x1);
	else if (x2_used) { x1 = x2; x2_used = false; }
	else continue;
	if (x2_used)
	if (overlap(x2, x)) x2 = intersect(x, x2);
	else x2_used = false;
	if (x2_used && width(x2) > width(x1)) std::swap(x1, x2);
	if (!zero_in(f(x1)))
	if (x2_used) { x1 = x2; x2_used = false; }
	else continue;
	if (width(x1) < max_width) res.push_back(x1);
	else if (width(x1) > alpha * width(x)) {
	std::pair<I1, I1> p = bisect(x);
	if (zero_in(f(p.first))) l.push_back(p.first);
	x2 = p.second;
	x2_used = true;
	} else l.push_back(x1);
	if (x2_used && zero_in(f(x2)))
	if (width(x2) < max_width) res.push_back(x2);
	else l.push_back(x2);
	}
	return res;
	}

	// Second method: with empty intervals

	typedef change_checking<I1_aux, checking_no_nan<double> >::type I2_aux;
	typedef unprotect<I2_aux>::type I2;

	std::vector<I2> newton_raphson(const I2& xs) {
	std::vector<I2> l, res;
	I2 vf, vd, x, x1, x2;
	l.push_back(xs);
	while (!l.empty()) {
	x = l.back();
	l.pop_back();
	double xx = median(x);
	vf = f<I2>(xx);
	vd = f_diff<I2>(x);
	if (zero_in(vf) && zero_in(vd)) {
	x1 = x;
	x2 = I2::empty();
	} else {
	bool x2_used;
	x1 = intersect(x, xx - division_part1(vf, vd, x2_used));
	x2 = intersect(x, xx - division_part2(vf, vd, x2_used));
	}
	if (width(x2) > width(x1)) std::swap(x1, x2);
	if (empty(x1) \|\| !zero_in(f(x1)))
	if (!empty(x2)) { x1 = x2; x2 = I2::empty(); }
	else continue;
	if (width(x1) < max_width) res.push_back(x1);
	else if (width(x1) > alpha * width(x)) {
	std::pair<I2, I2> p = bisect(x);
	if (zero_in(f(p.first))) l.push_back(p.first);
	x2 = p.second;
	} else l.push_back(x1);
	if (!empty(x2) && zero_in(f(x2)))
	if (width(x2) < max_width) res.push_back(x2);
	else l.push_back(x2);
	}
	return res;
	}

	template<class T, class Policies>
	std::ostream &operator<<(std::ostream &os,
	const boost::numeric::interval<T, Policies> &x) {
	os << "[" << x.lower() << ", " << x.upper() << "]";
	return os;
	}

	int main() {
	{
	I1_aux::traits_type::rounding rnd;
	std::vector<I1> res = newton_raphson(I1(-1, 5.1));
	std::cout << "Results: " << std::endl << std::setprecision(12);
	for(std::vector<I1>::const_iterator i = res.begin(); i != res.end(); ++i)
	std::cout << " " << *i << std::endl;
	std::cout << std::endl;
	}
	{
	I2_aux::traits_type::rounding rnd;
	std::vector<I2> res = newton_raphson(I2(-1, 5.1));
	std::cout << "Results: " << std::endl << std::setprecision(12);
	for(std::vector<I2>::const_iterator i = res.begin(); i != res.end(); ++i)
	std::cout << " " << *i << std::endl;
	std::cout << std::endl;
	}
	}