123456789101112131415161718192021222324252627282930313233343536373839404142434445464748495051525354555657585960616263646566676869707172737475767778798081828384858687888990919293949596979899100101102103104105106107108109110111112113114115116117118119120121122123124125126127128129130131132133134135136137138139140141142143144145146147148149150151152153154155156157158159160161162163164165166167168169170171172173174175176177178179180181182183184185186187188189190191192193194195196197198199200201202203204205206207208209210211212213214215216217218219220221222223224225226227228229230231232233234235236237238239240241242243244245246247248249250251252253254255256257258259260261262263264265266267268269270271272273274275276277278279280281282283284285286287288289290291292293294295296297298299300301302303304305 |
- /* Boost interval/arith2.hpp template implementation file
- *
- * This header provides some auxiliary arithmetic
- * functions: fmod, sqrt, square, pov, inverse and
- * a multi-interval division.
- *
- * Copyright 2002-2003 Hervé Brönnimann, Guillaume Melquiond, Sylvain Pion
- *
- * 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)
- */
- #ifndef BOOST_NUMERIC_INTERVAL_ARITH2_HPP
- #define BOOST_NUMERIC_INTERVAL_ARITH2_HPP
- #include <boost/config.hpp>
- #include <boost/numeric/interval/detail/interval_prototype.hpp>
- #include <boost/numeric/interval/detail/test_input.hpp>
- #include <boost/numeric/interval/detail/bugs.hpp>
- #include <boost/numeric/interval/detail/division.hpp>
- #include <boost/numeric/interval/arith.hpp>
- #include <boost/numeric/interval/policies.hpp>
- #include <algorithm>
- #include <cassert>
- #include <boost/config/no_tr1/cmath.hpp>
- namespace boost {
- namespace numeric {
- template<class T, class Policies> inline
- interval<T, Policies> fmod(const interval<T, Policies>& x,
- const interval<T, Policies>& y)
- {
- if (interval_lib::detail::test_input(x, y))
- return interval<T, Policies>::empty();
- typename Policies::rounding rnd;
- typedef typename interval_lib::unprotect<interval<T, Policies> >::type I;
- T const &yb = interval_lib::user::is_neg(x.lower()) ? y.lower() : y.upper();
- T n = rnd.int_down(rnd.div_down(x.lower(), yb));
- return (const I&)x - n * (const I&)y;
- }
- template<class T, class Policies> inline
- interval<T, Policies> fmod(const interval<T, Policies>& x, const T& y)
- {
- if (interval_lib::detail::test_input(x, y))
- return interval<T, Policies>::empty();
- typename Policies::rounding rnd;
- typedef typename interval_lib::unprotect<interval<T, Policies> >::type I;
- T n = rnd.int_down(rnd.div_down(x.lower(), y));
- return (const I&)x - n * I(y);
- }
- template<class T, class Policies> inline
- interval<T, Policies> fmod(const T& x, const interval<T, Policies>& y)
- {
- if (interval_lib::detail::test_input(x, y))
- return interval<T, Policies>::empty();
- typename Policies::rounding rnd;
- typedef typename interval_lib::unprotect<interval<T, Policies> >::type I;
- T const &yb = interval_lib::user::is_neg(x) ? y.lower() : y.upper();
- T n = rnd.int_down(rnd.div_down(x, yb));
- return x - n * (const I&)y;
- }
- namespace interval_lib {
- template<class T, class Policies> inline
- interval<T, Policies> division_part1(const interval<T, Policies>& x,
- const interval<T, Policies>& y, bool& b)
- {
- typedef interval<T, Policies> I;
- b = false;
- if (detail::test_input(x, y))
- return I::empty();
- if (zero_in(y))
- if (!user::is_zero(y.lower()))
- if (!user::is_zero(y.upper()))
- return detail::div_zero_part1(x, y, b);
- else
- return detail::div_negative(x, y.lower());
- else
- if (!user::is_zero(y.upper()))
- return detail::div_positive(x, y.upper());
- else
- return I::empty();
- else
- return detail::div_non_zero(x, y);
- }
- template<class T, class Policies> inline
- interval<T, Policies> division_part2(const interval<T, Policies>& x,
- const interval<T, Policies>& y, bool b = true)
- {
- if (!b) return interval<T, Policies>::empty();
- return detail::div_zero_part2(x, y);
- }
- template<class T, class Policies> inline
- interval<T, Policies> multiplicative_inverse(const interval<T, Policies>& x)
- {
- typedef interval<T, Policies> I;
- if (detail::test_input(x))
- return I::empty();
- T one = static_cast<T>(1);
- typename Policies::rounding rnd;
- if (zero_in(x)) {
- typedef typename Policies::checking checking;
- if (!user::is_zero(x.lower()))
- if (!user::is_zero(x.upper()))
- return I::whole();
- else
- return I(checking::neg_inf(), rnd.div_up(one, x.lower()), true);
- else
- if (!user::is_zero(x.upper()))
- return I(rnd.div_down(one, x.upper()), checking::pos_inf(), true);
- else
- return I::empty();
- } else
- return I(rnd.div_down(one, x.upper()), rnd.div_up(one, x.lower()), true);
- }
- namespace detail {
- template<class T, class Rounding> inline
- T pow_dn(const T& x_, int pwr, Rounding& rnd) // x and pwr are positive
- {
- T x = x_;
- T y = (pwr & 1) ? x_ : static_cast<T>(1);
- pwr >>= 1;
- while (pwr > 0) {
- x = rnd.mul_down(x, x);
- if (pwr & 1) y = rnd.mul_down(x, y);
- pwr >>= 1;
- }
- return y;
- }
- template<class T, class Rounding> inline
- T pow_up(const T& x_, int pwr, Rounding& rnd) // x and pwr are positive
- {
- T x = x_;
- T y = (pwr & 1) ? x_ : static_cast<T>(1);
- pwr >>= 1;
- while (pwr > 0) {
- x = rnd.mul_up(x, x);
- if (pwr & 1) y = rnd.mul_up(x, y);
- pwr >>= 1;
- }
- return y;
- }
- } // namespace detail
- } // namespace interval_lib
- template<class T, class Policies> inline
- interval<T, Policies> pow(const interval<T, Policies>& x, int pwr)
- {
- BOOST_USING_STD_MAX();
- using interval_lib::detail::pow_dn;
- using interval_lib::detail::pow_up;
- typedef interval<T, Policies> I;
- if (interval_lib::detail::test_input(x))
- return I::empty();
- if (pwr == 0)
- if (interval_lib::user::is_zero(x.lower())
- && interval_lib::user::is_zero(x.upper()))
- return I::empty();
- else
- return I(static_cast<T>(1));
- else if (pwr < 0)
- return interval_lib::multiplicative_inverse(pow(x, -pwr));
- typename Policies::rounding rnd;
-
- if (interval_lib::user::is_neg(x.upper())) { // [-2,-1]
- T yl = pow_dn(static_cast<T>(-x.upper()), pwr, rnd);
- T yu = pow_up(static_cast<T>(-x.lower()), pwr, rnd);
- if (pwr & 1) // [-2,-1]^1
- return I(-yu, -yl, true);
- else // [-2,-1]^2
- return I(yl, yu, true);
- } else if (interval_lib::user::is_neg(x.lower())) { // [-1,1]
- if (pwr & 1) { // [-1,1]^1
- return I(-pow_up(static_cast<T>(-x.lower()), pwr, rnd), pow_up(x.upper(), pwr, rnd), true);
- } else { // [-1,1]^2
- return I(static_cast<T>(0), pow_up(max BOOST_PREVENT_MACRO_SUBSTITUTION(static_cast<T>(-x.lower()), x.upper()), pwr, rnd), true);
- }
- } else { // [1,2]
- return I(pow_dn(x.lower(), pwr, rnd), pow_up(x.upper(), pwr, rnd), true);
- }
- }
- template<class T, class Policies> inline
- interval<T, Policies> sqrt(const interval<T, Policies>& x)
- {
- typedef interval<T, Policies> I;
- if (interval_lib::detail::test_input(x) || interval_lib::user::is_neg(x.upper()))
- return I::empty();
- typename Policies::rounding rnd;
- T l = !interval_lib::user::is_pos(x.lower()) ? static_cast<T>(0) : rnd.sqrt_down(x.lower());
- return I(l, rnd.sqrt_up(x.upper()), true);
- }
- template<class T, class Policies> inline
- interval<T, Policies> square(const interval<T, Policies>& x)
- {
- typedef interval<T, Policies> I;
- if (interval_lib::detail::test_input(x))
- return I::empty();
- typename Policies::rounding rnd;
- const T& xl = x.lower();
- const T& xu = x.upper();
- if (interval_lib::user::is_neg(xu))
- return I(rnd.mul_down(xu, xu), rnd.mul_up(xl, xl), true);
- else if (interval_lib::user::is_pos(x.lower()))
- return I(rnd.mul_down(xl, xl), rnd.mul_up(xu, xu), true);
- else
- return I(static_cast<T>(0), (-xl > xu ? rnd.mul_up(xl, xl) : rnd.mul_up(xu, xu)), true);
- }
- namespace interval_lib {
- namespace detail {
- template< class I > inline
- I root_aux(typename I::base_type const &x, int k) // x and k are bigger than one
- {
- typedef typename I::base_type T;
- T tk(k);
- I y(static_cast<T>(1), x, true);
- for(;;) {
- T y0 = median(y);
- I yy = intersect(y, y0 - (pow(I(y0, y0, true), k) - x) / (tk * pow(y, k - 1)));
- if (equal(y, yy)) return y;
- y = yy;
- }
- }
- template< class I > inline // x is positive and k bigger than one
- typename I::base_type root_aux_dn(typename I::base_type const &x, int k)
- {
- typedef typename I::base_type T;
- typedef typename I::traits_type Policies;
- typename Policies::rounding rnd;
- T one(1);
- if (x > one) return root_aux<I>(x, k).lower();
- if (x == one) return one;
- return rnd.div_down(one, root_aux<I>(rnd.div_up(one, x), k).upper());
- }
- template< class I > inline // x is positive and k bigger than one
- typename I::base_type root_aux_up(typename I::base_type const &x, int k)
- {
- typedef typename I::base_type T;
- typedef typename I::traits_type Policies;
- typename Policies::rounding rnd;
- T one(1);
- if (x > one) return root_aux<I>(x, k).upper();
- if (x == one) return one;
- return rnd.div_up(one, root_aux<I>(rnd.div_down(one, x), k).lower());
- }
- } // namespace detail
- } // namespace interval_lib
- template< class T, class Policies > inline
- interval<T, Policies> nth_root(interval<T, Policies> const &x, int k)
- {
- typedef interval<T, Policies> I;
- if (interval_lib::detail::test_input(x)) return I::empty();
- assert(k > 0);
- if (k == 1) return x;
- typename Policies::rounding rnd;
- typedef typename interval_lib::unprotect<I>::type R;
- if (!interval_lib::user::is_pos(x.upper())) {
- if (interval_lib::user::is_zero(x.upper())) {
- T zero(0);
- if (!(k & 1) || interval_lib::user::is_zero(x.lower())) // [-1,0]^/2 or [0,0]
- return I(zero, zero, true);
- else // [-1,0]^/3
- return I(-interval_lib::detail::root_aux_up<R>(-x.lower(), k), zero, true);
- } else if (!(k & 1)) // [-2,-1]^/2
- return I::empty();
- else { // [-2,-1]^/3
- return I(-interval_lib::detail::root_aux_up<R>(-x.lower(), k),
- -interval_lib::detail::root_aux_dn<R>(-x.upper(), k), true);
- }
- }
- T u = interval_lib::detail::root_aux_up<R>(x.upper(), k);
- if (!interval_lib::user::is_pos(x.lower()))
- if (!(k & 1) || interval_lib::user::is_zero(x.lower())) // [-1,1]^/2 or [0,1]
- return I(static_cast<T>(0), u, true);
- else // [-1,1]^/3
- return I(-interval_lib::detail::root_aux_up<R>(-x.lower(), k), u, true);
- else // [1,2]
- return I(interval_lib::detail::root_aux_dn<R>(x.lower(), k), u, true);
- }
- } // namespace numeric
- } // namespace boost
- #endif // BOOST_NUMERIC_INTERVAL_ARITH2_HPP
|