third_party/boost/include/boost/units/detail/static_rational_power.hpp - webm/webmlive - Git at Google

 // Boost.Units - A C++ library for zero-overhead dimensional analysis and
 // unit/quantity manipulation and conversion
 //
 // Copyright (C) 2003-2008 Matthias Christian Schabel
 // Copyright (C) 2007-2008 Steven Watanabe
 //
 // 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_UNITS_DETAIL_STATIC_RATIONAL_POWER_HPP
 #define BOOST_UNITS_DETAIL_STATIC_RATIONAL_POWER_HPP

 #include <boost/config/no_tr1/cmath.hpp>

 #include <boost/units/detail/one.hpp>
 #include <boost/units/operators.hpp>

 namespace boost {

 namespace units {

 template<long N,long D>
 class static_rational;

 namespace detail {

 namespace typeof_pow_adl_barrier {

 using std::pow;

 template<class Y>
 struct typeof_pow
 {
 #if defined(BOOST_UNITS_HAS_BOOST_TYPEOF)
     BOOST_TYPEOF_NESTED_TYPEDEF_TPL(nested, pow(typeof_::make<Y>(), 0.0))
     typedef typename nested::type type;
 #elif defined(BOOST_UNITS_HAS_MWERKS_TYPEOF)
     typedef __typeof__(pow(typeof_::make<Y>(), 0.0)) type;
 #elif defined(BOOST_UNITS_HAS_GNU_TYPEOF)
     typedef typeof(pow(typeof_::make<Y>(), 0.0)) type;
 #else
     typedef Y type;
 #endif
 };

 }

 template<class R, class Y>
 struct static_rational_power_impl
 {
     typedef typename typeof_pow_adl_barrier::typeof_pow<Y>::type type;
     static type call(const Y& y)
     {
         using std::pow;
         return(pow(y, static_cast<double>(R::Numerator) / static_cast<double>(R::Denominator)));
     }
 };

 template<class R>
 struct static_rational_power_impl<R, one>
 {
     typedef one type;
     static one call(const one&)
     {
         one result;
         return(result);
     }
 };

 template<long N>
 struct static_rational_power_impl<static_rational<N, 1>, one>
 {
     typedef one type;
     static one call(const one&)
     {
         one result;
         return(result);
     }
 };

 template<long N, bool = (N % 2 == 0)>
 struct static_int_power_impl;

 template<long N>
 struct static_int_power_impl<N, true>
 {
     template<class Y, class R>
     struct apply
     {
         typedef typename multiply_typeof_helper<Y, Y>::type square_type;
         typedef typename static_int_power_impl<(N >> 1)>::template apply<square_type, R> next;
         typedef typename next::type type;
         static type call(const Y& y, const R& r)
         {
             const Y square = y * y;
             return(next::call(square, r));
         }
     };
 };

 template<long N>
 struct static_int_power_impl<N, false>
 {
     template<class Y, class R>
     struct apply
     {
         typedef typename multiply_typeof_helper<Y, Y>::type square_type;
         typedef typename multiply_typeof_helper<Y, R>::type new_r;
         typedef typename static_int_power_impl<(N >> 1)>::template apply<square_type, new_r> next;
         typedef typename next::type type;
         static type call(const Y& y, const R& r)
         {
             const Y square = y * y;
             return(next::call(square, y * r));
         }
     };
 };

 template<>
 struct static_int_power_impl<1, false>
 {
     template<class Y, class R>
     struct apply
     {
         typedef typename multiply_typeof_helper<Y, R>::type type;
         static type call(const Y& y, const R& r)
         {
             return(y * r);
         }
     };
 };

 template<>
 struct static_int_power_impl<0, true>
 {
     template<class Y, class R>
     struct apply
     {
         typedef R type;
         static R call(const Y&, const R& r)
         {
             return(r);
         }
     };
 };

 template<int N, bool = (N < 0)>
 struct static_int_power_sign_impl;

 template<int N>
 struct static_int_power_sign_impl<N, false>
 {
     template<class Y>
     struct apply
     {
         typedef typename static_int_power_impl<N>::template apply<Y, one> impl;
         typedef typename impl::type type;
         static type call(const Y& y)
         {
             one result;
             return(impl::call(y, result));
         }
     };
 };

 template<int N>
 struct static_int_power_sign_impl<N, true>
 {
     template<class Y>
     struct apply
     {
         typedef typename static_int_power_impl<-N>::template apply<Y, one> impl;
         typedef typename divide_typeof_helper<one, typename impl::type>::type type;
         static type call(const Y& y)
         {
             one result;
             return(result/impl::call(y, result));
         }
     };
 };

 template<long N, class Y>
 struct static_rational_power_impl<static_rational<N, 1>, Y>
 {
     typedef typename static_int_power_sign_impl<N>::template apply<Y> impl;
     typedef typename impl::type type;
     static Y call(const Y& y)
     {
         return(impl::call(y));
     }
 };

 template<class R, class Y>
 typename detail::static_rational_power_impl<R, Y>::type static_rational_power(const Y& y)
 {
     return(detail::static_rational_power_impl<R, Y>::call(y));
 }

 } // namespace detail

 } // namespace units

 } // namespace boost

 #endif
	// Boost.Units - A C++ library for zero-overhead dimensional analysis and
	// unit/quantity manipulation and conversion
	//
	// Copyright (C) 2003-2008 Matthias Christian Schabel
	// Copyright (C) 2007-2008 Steven Watanabe
	//
	// 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_UNITS_DETAIL_STATIC_RATIONAL_POWER_HPP
	#define BOOST_UNITS_DETAIL_STATIC_RATIONAL_POWER_HPP

	#include <boost/config/no_tr1/cmath.hpp>

	#include <boost/units/detail/one.hpp>
	#include <boost/units/operators.hpp>

	namespace boost {

	namespace units {

	template<long N,long D>
	class static_rational;

	namespace detail {

	namespace typeof_pow_adl_barrier {

	using std::pow;

	template<class Y>
	struct typeof_pow
	{
	#if defined(BOOST_UNITS_HAS_BOOST_TYPEOF)
	BOOST_TYPEOF_NESTED_TYPEDEF_TPL(nested, pow(typeof_::make<Y>(), 0.0))
	typedef typename nested::type type;
	#elif defined(BOOST_UNITS_HAS_MWERKS_TYPEOF)
	typedef __typeof__(pow(typeof_::make<Y>(), 0.0)) type;
	#elif defined(BOOST_UNITS_HAS_GNU_TYPEOF)
	typedef typeof(pow(typeof_::make<Y>(), 0.0)) type;
	#else
	typedef Y type;
	#endif
	};

	}

	template<class R, class Y>
	struct static_rational_power_impl
	{
	typedef typename typeof_pow_adl_barrier::typeof_pow<Y>::type type;
	static type call(const Y& y)
	{
	using std::pow;
	return(pow(y, static_cast<double>(R::Numerator) / static_cast<double>(R::Denominator)));
	}
	};

	template<class R>
	struct static_rational_power_impl<R, one>
	{
	typedef one type;
	static one call(const one&)
	{
	one result;
	return(result);
	}
	};

	template<long N>
	struct static_rational_power_impl<static_rational<N, 1>, one>
	{
	typedef one type;
	static one call(const one&)
	{
	one result;
	return(result);
	}
	};

	template<long N, bool = (N % 2 == 0)>
	struct static_int_power_impl;

	template<long N>
	struct static_int_power_impl<N, true>
	{
	template<class Y, class R>
	struct apply
	{
	typedef typename multiply_typeof_helper<Y, Y>::type square_type;
	typedef typename static_int_power_impl<(N >> 1)>::template apply<square_type, R> next;
	typedef typename next::type type;
	static type call(const Y& y, const R& r)
	{
	const Y square = y * y;
	return(next::call(square, r));
	}
	};
	};

	template<long N>
	struct static_int_power_impl<N, false>
	{
	template<class Y, class R>
	struct apply
	{
	typedef typename multiply_typeof_helper<Y, Y>::type square_type;
	typedef typename multiply_typeof_helper<Y, R>::type new_r;
	typedef typename static_int_power_impl<(N >> 1)>::template apply<square_type, new_r> next;
	typedef typename next::type type;
	static type call(const Y& y, const R& r)
	{
	const Y square = y * y;
	return(next::call(square, y * r));
	}
	};
	};

	template<>
	struct static_int_power_impl<1, false>
	{
	template<class Y, class R>
	struct apply
	{
	typedef typename multiply_typeof_helper<Y, R>::type type;
	static type call(const Y& y, const R& r)
	{
	return(y * r);
	}
	};
	};

	template<>
	struct static_int_power_impl<0, true>
	{
	template<class Y, class R>
	struct apply
	{
	typedef R type;
	static R call(const Y&, const R& r)
	{
	return(r);
	}
	};
	};

	template<int N, bool = (N < 0)>
	struct static_int_power_sign_impl;

	template<int N>
	struct static_int_power_sign_impl<N, false>
	{
	template<class Y>
	struct apply
	{
	typedef typename static_int_power_impl<N>::template apply<Y, one> impl;
	typedef typename impl::type type;
	static type call(const Y& y)
	{
	one result;
	return(impl::call(y, result));
	}
	};
	};

	template<int N>
	struct static_int_power_sign_impl<N, true>
	{
	template<class Y>
	struct apply
	{
	typedef typename static_int_power_impl<-N>::template apply<Y, one> impl;
	typedef typename divide_typeof_helper<one, typename impl::type>::type type;
	static type call(const Y& y)
	{
	one result;
	return(result/impl::call(y, result));
	}
	};
	};

	template<long N, class Y>
	struct static_rational_power_impl<static_rational<N, 1>, Y>
	{
	typedef typename static_int_power_sign_impl<N>::template apply<Y> impl;
	typedef typename impl::type type;
	static Y call(const Y& y)
	{
	return(impl::call(y));
	}
	};

	template<class R, class Y>
	typename detail::static_rational_power_impl<R, Y>::type static_rational_power(const Y& y)
	{
	return(detail::static_rational_power_impl<R, Y>::call(y));
	}

	} // namespace detail

	} // namespace units

	} // namespace boost

	#endif