+// Boost common_factor_ct.hpp header file ----------------------------------//

+

+// (C) Copyright Daryle Walker and Stephen Cleary 2001-2002.

+// 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)

+

+// See http://www.boost.org for updates, documentation, and revision history.

+

+#ifndef BOOST_MATH_COMMON_FACTOR_CT_HPP

+#define BOOST_MATH_COMMON_FACTOR_CT_HPP

+

+#include <boost/math_fwd.hpp> // self include

+#include <boost/config.hpp> // for BOOST_STATIC_CONSTANT, etc.

+#include <boost/mpl/integral_c.hpp>

+

+namespace boost

+{

+namespace math

+{

+

+// Implementation details --------------------------------------------------//

+

+namespace detail

+{

+#ifndef BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION

+ // Build GCD with Euclid's recursive algorithm

+ template < static_gcd_type Value1, static_gcd_type Value2 >

+ struct static_gcd_helper_t

+ {

+ private:

+ BOOST_STATIC_CONSTANT( static_gcd_type, new_value1 = Value2 );

+ BOOST_STATIC_CONSTANT( static_gcd_type, new_value2 = Value1 % Value2 );

+

+ #ifndef __BORLANDC__

+ #define BOOST_DETAIL_GCD_HELPER_VAL(Value) static_cast<static_gcd_type>(Value)

+ #else

+ typedef static_gcd_helper_t self_type;

+ #define BOOST_DETAIL_GCD_HELPER_VAL(Value) (self_type:: Value )

+ #endif

+

+ typedef static_gcd_helper_t< BOOST_DETAIL_GCD_HELPER_VAL(new_value1),

+ BOOST_DETAIL_GCD_HELPER_VAL(new_value2) > next_step_type;

+

+ #undef BOOST_DETAIL_GCD_HELPER_VAL

+

+ public:

+ BOOST_STATIC_CONSTANT( static_gcd_type, value = next_step_type::value );

+ };

+

+ // Non-recursive case

+ template < static_gcd_type Value1 >

+ struct static_gcd_helper_t< Value1, 0UL >

+ {

+ BOOST_STATIC_CONSTANT( static_gcd_type, value = Value1 );

+ };

+#else

+ // Use inner class template workaround from Peter Dimov

+ template < static_gcd_type Value1 >

+ struct static_gcd_helper2_t

+ {

+ template < static_gcd_type Value2 >

+ struct helper

+ {

+ BOOST_STATIC_CONSTANT( static_gcd_type, value

+ = static_gcd_helper2_t<Value2>::BOOST_NESTED_TEMPLATE

+ helper<Value1 % Value2>::value );

+ };

+

+ template < >

+ struct helper< 0UL >

+ {

+ BOOST_STATIC_CONSTANT( static_gcd_type, value = Value1 );

+ };

+ };

+

+ // Special case

+ template < >

+ struct static_gcd_helper2_t< 0UL >

+ {

+ template < static_gcd_type Value2 >

+ struct helper

+ {

+ BOOST_STATIC_CONSTANT( static_gcd_type, value = Value2 );

+ };

+ };

+

+ // Build the GCD from the above template(s)

+ template < static_gcd_type Value1, static_gcd_type Value2 >

+ struct static_gcd_helper_t

+ {

+ BOOST_STATIC_CONSTANT( static_gcd_type, value

+ = static_gcd_helper2_t<Value1>::BOOST_NESTED_TEMPLATE

+ helper<Value2>::value );

+ };

+#endif

+

+#ifndef BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION

+ // Build the LCM from the GCD

+ template < static_gcd_type Value1, static_gcd_type Value2 >

+ struct static_lcm_helper_t

+ {

+ typedef static_gcd_helper_t<Value1, Value2> gcd_type;

+

+ BOOST_STATIC_CONSTANT( static_gcd_type, value = Value1 / gcd_type::value

+ * Value2 );

+ };

+

+ // Special case for zero-GCD values

+ template < >

+ struct static_lcm_helper_t< 0UL, 0UL >

+ {

+ BOOST_STATIC_CONSTANT( static_gcd_type, value = 0UL );

+ };

+#else

+ // Adapt GCD's inner class template workaround for LCM

+ template < static_gcd_type Value1 >

+ struct static_lcm_helper2_t

+ {

+ template < static_gcd_type Value2 >

+ struct helper

+ {

+ typedef static_gcd_helper_t<Value1, Value2> gcd_type;

+

+ BOOST_STATIC_CONSTANT( static_gcd_type, value = Value1

+ / gcd_type::value * Value2 );

+ };

+

+ template < >

+ struct helper< 0UL >

+ {

+ BOOST_STATIC_CONSTANT( static_gcd_type, value = 0UL );

+ };

+ };

+

+ // Special case

+ template < >

+ struct static_lcm_helper2_t< 0UL >

+ {

+ template < static_gcd_type Value2 >

+ struct helper

+ {

+ BOOST_STATIC_CONSTANT( static_gcd_type, value = 0UL );

+ };

+ };

+

+ // Build the LCM from the above template(s)

+ template < static_gcd_type Value1, static_gcd_type Value2 >

+ struct static_lcm_helper_t

+ {

+ BOOST_STATIC_CONSTANT( static_gcd_type, value

+ = static_lcm_helper2_t<Value1>::BOOST_NESTED_TEMPLATE

+ helper<Value2>::value );

+ };

+#endif

+

+} // namespace detail

+

+

+// Compile-time greatest common divisor evaluator class declaration --------//

+

+template < static_gcd_type Value1, static_gcd_type Value2 >

+struct static_gcd : public mpl::integral_c<static_gcd_type, (detail::static_gcd_helper_t<Value1, Value2>::value) >

+{

+}; // boost::math::static_gcd

+

+

+// Compile-time least common multiple evaluator class declaration ----------//

+

+template < static_gcd_type Value1, static_gcd_type Value2 >

+struct static_lcm : public mpl::integral_c<static_gcd_type, (detail::static_lcm_helper_t<Value1, Value2>::value) >

+{

+}; // boost::math::static_lcm

+

+

+} // namespace math

+} // namespace boost

+

+

+#endif // BOOST_MATH_COMMON_FACTOR_CT_HPP

+// Boost common_factor_rt.hpp header file ----------------------------------//

+

+// (C) Copyright Daryle Walker and Paul Moore 2001-2002. Permission to copy,

+// use, modify, sell and distribute this software is granted provided this

+// copyright notice appears in all copies. This software is provided "as is"

+// without express or implied warranty, and with no claim as to its suitability

+// for any purpose.

+

+// boostinspect:nolicense (don't complain about the lack of a Boost license)

+// (Paul Moore hasn't been in contact for years, so there's no way to change the

+// license.)

+

+// See http://www.boost.org for updates, documentation, and revision history.

+

+#ifndef BOOST_MATH_COMMON_FACTOR_RT_HPP

+#define BOOST_MATH_COMMON_FACTOR_RT_HPP

+

+#include <boost/math_fwd.hpp> // self include

+

+#include <boost/config.hpp> // for BOOST_NESTED_TEMPLATE, etc.

+#include <boost/limits.hpp> // for std::numeric_limits

+#include <climits> // for CHAR_MIN

+#include <boost/detail/workaround.hpp>

+

+#ifdef BOOST_MSVC

+#pragma warning(push)

+#pragma warning(disable:4127 4244) // Conditional expression is constant

+#endif

+

+namespace boost

+{

+namespace math

+{

+

+

+// Forward declarations for function templates -----------------------------//

+

+template < typename IntegerType >

+ IntegerType gcd( IntegerType const &a, IntegerType const &b );

+

+template < typename IntegerType >

+ IntegerType lcm( IntegerType const &a, IntegerType const &b );

+

+

+// Greatest common divisor evaluator class declaration ---------------------//

+

+template < typename IntegerType >

+class gcd_evaluator

+{

+public:

+ // Types

+ typedef IntegerType result_type, first_argument_type, second_argument_type;

+

+ // Function object interface

+ result_type operator ()( first_argument_type const &a,

+ second_argument_type const &b ) const;

+

+}; // boost::math::gcd_evaluator

+

+

+// Least common multiple evaluator class declaration -----------------------//

+

+template < typename IntegerType >

+class lcm_evaluator

+{

+public:

+ // Types

+ typedef IntegerType result_type, first_argument_type, second_argument_type;

+

+ // Function object interface

+ result_type operator ()( first_argument_type const &a,

+ second_argument_type const &b ) const;

+

+}; // boost::math::lcm_evaluator

+

+

+// Implementation details --------------------------------------------------//

+

+namespace detail

+{

+ // Greatest common divisor for rings (including unsigned integers)

+ template < typename RingType >

+ RingType

+ gcd_euclidean

+ (

+ RingType a,

+ RingType b

+ )

+ {

+ // Avoid repeated construction

+ #ifndef __BORLANDC__

+ RingType const zero = static_cast<RingType>( 0 );

+ #else

+ RingType zero = static_cast<RingType>( 0 );

+ #endif

+

+ // Reduce by GCD-remainder property [GCD(a,b) == GCD(b,a MOD b)]

+ while ( true )

+ {

+ if ( a == zero )

+ return b;

+ b %= a;

+

+ if ( b == zero )

+ return a;

+ a %= b;

+ }

+ }

+

+ // Greatest common divisor for (signed) integers

+ template < typename IntegerType >

+ inline

+ IntegerType

+ gcd_integer

+ (

+ IntegerType const & a,

+ IntegerType const & b

+ )

+ {

+ // Avoid repeated construction

+ IntegerType const zero = static_cast<IntegerType>( 0 );

+ IntegerType const result = gcd_euclidean( a, b );

+

+ return ( result < zero ) ? static_cast<IntegerType>(-result) : result;

+ }

+

+ // Greatest common divisor for unsigned binary integers

+ template < typename BuiltInUnsigned >

+ BuiltInUnsigned

+ gcd_binary

+ (

+ BuiltInUnsigned u,

+ BuiltInUnsigned v

+ )

+ {

+ if ( u && v )

+ {

+ // Shift out common factors of 2

+ unsigned shifts = 0;

+

+ while ( !(u & 1u) && !(v & 1u) )

+ {

+ ++shifts;

+ u >>= 1;

+ v >>= 1;

+ }

+

+ // Start with the still-even one, if any

+ BuiltInUnsigned r[] = { u, v };

+ unsigned which = static_cast<bool>( u & 1u );

+

+ // Whittle down the values via their differences

+ do

+ {

+#if BOOST_WORKAROUND(__BORLANDC__, BOOST_TESTED_AT(0x582))

+ while ( !(r[ which ] & 1u) )

+ {

+ r[ which ] = (r[which] >> 1);

+ }

+#else

+ // Remove factors of two from the even one

+ while ( !(r[ which ] & 1u) )

+ {

+ r[ which ] >>= 1;

+ }

+#endif

+

+ // Replace the larger of the two with their difference

+ if ( r[!which] > r[which] )

+ {

+ which ^= 1u;

+ }

+

+ r[ which ] -= r[ !which ];

+ }

+ while ( r[which] );

+

+ // Shift-in the common factor of 2 to the residues' GCD

+ return r[ !which ] << shifts;

+ }

+ else

+ {

+ // At least one input is zero, return the other

+ // (adding since zero is the additive identity)

+ // or zero if both are zero.

+ return u + v;

+ }

+ }

+

+ // Least common multiple for rings (including unsigned integers)

+ template < typename RingType >

+ inline

+ RingType

+ lcm_euclidean

+ (

+ RingType const & a,

+ RingType const & b

+ )

+ {

+ RingType const zero = static_cast<RingType>( 0 );

+ RingType const temp = gcd_euclidean( a, b );

+

+ return ( temp != zero ) ? ( a / temp * b ) : zero;

+ }

+

+ // Least common multiple for (signed) integers

+ template < typename IntegerType >

+ inline

+ IntegerType

+ lcm_integer

+ (

+ IntegerType const & a,

+ IntegerType const & b

+ )

+ {

+ // Avoid repeated construction

+ IntegerType const zero = static_cast<IntegerType>( 0 );

+ IntegerType const result = lcm_euclidean( a, b );

+

+ return ( result < zero ) ? static_cast<IntegerType>(-result) : result;

+ }

+

+ // Function objects to find the best way of computing GCD or LCM

+#ifndef BOOST_NO_LIMITS_COMPILE_TIME_CONSTANTS

+#ifndef BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION

+ template < typename T, bool IsSpecialized, bool IsSigned >

+ struct gcd_optimal_evaluator_helper_t

+ {

+ T operator ()( T const &a, T const &b )

+ {

+ return gcd_euclidean( a, b );

+ }

+ };

+

+ template < typename T >

+ struct gcd_optimal_evaluator_helper_t< T, true, true >

+ {

+ T operator ()( T const &a, T const &b )

+ {

+ return gcd_integer( a, b );

+ }

+ };

+#else

+ template < bool IsSpecialized, bool IsSigned >

+ struct gcd_optimal_evaluator_helper2_t

+ {

+ template < typename T >

+ struct helper

+ {

+ T operator ()( T const &a, T const &b )

+ {

+ return gcd_euclidean( a, b );

+ }

+ };

+ };

+

+ template < >

+ struct gcd_optimal_evaluator_helper2_t< true, true >

+ {

+ template < typename T >

+ struct helper

+ {

+ T operator ()( T const &a, T const &b )

+ {

+ return gcd_integer( a, b );

+ }

+ };

+ };

+

+ template < typename T, bool IsSpecialized, bool IsSigned >

+ struct gcd_optimal_evaluator_helper_t

+ : gcd_optimal_evaluator_helper2_t<IsSpecialized, IsSigned>

+ ::BOOST_NESTED_TEMPLATE helper<T>

+ {

+ };

+#endif

+

+ template < typename T >

+ struct gcd_optimal_evaluator

+ {

+ T operator ()( T const &a, T const &b )

+ {

+ typedef ::std::numeric_limits<T> limits_type;

+

+ typedef gcd_optimal_evaluator_helper_t<T,

+ limits_type::is_specialized, limits_type::is_signed> helper_type;

+

+ helper_type solver;

+

+ return solver( a, b );

+ }

+ };

+#else // BOOST_NO_LIMITS_COMPILE_TIME_CONSTANTS

+ template < typename T >

+ struct gcd_optimal_evaluator

+ {

+ T operator ()( T const &a, T const &b )

+ {

+ return gcd_integer( a, b );

+ }

+ };

+#endif

+

+ // Specialize for the built-in integers

+#define BOOST_PRIVATE_GCD_UF( Ut ) \

+ template < > struct gcd_optimal_evaluator<Ut> \

+ { Ut operator ()( Ut a, Ut b ) const { return gcd_binary( a, b ); } }

+

+ BOOST_PRIVATE_GCD_UF( unsigned char );

+ BOOST_PRIVATE_GCD_UF( unsigned short );

+ BOOST_PRIVATE_GCD_UF( unsigned );

+ BOOST_PRIVATE_GCD_UF( unsigned long );

+

+#ifdef BOOST_HAS_LONG_LONG

+ BOOST_PRIVATE_GCD_UF( boost::ulong_long_type );

+#elif defined(BOOST_HAS_MS_INT64)

+ BOOST_PRIVATE_GCD_UF( unsigned __int64 );

+#endif

+

+#if CHAR_MIN == 0

+ BOOST_PRIVATE_GCD_UF( char ); // char is unsigned

+#endif

+

+#undef BOOST_PRIVATE_GCD_UF

+

+#define BOOST_PRIVATE_GCD_SF( St, Ut ) \

+ template < > struct gcd_optimal_evaluator<St> \

+ { St operator ()( St a, St b ) const { Ut const a_abs = \

+ static_cast<Ut>( a < 0 ? -a : +a ), b_abs = static_cast<Ut>( \

+ b < 0 ? -b : +b ); return static_cast<St>( \

+ gcd_optimal_evaluator<Ut>()(a_abs, b_abs) ); } }

+

+ BOOST_PRIVATE_GCD_SF( signed char, unsigned char );

+ BOOST_PRIVATE_GCD_SF( short, unsigned short );

+ BOOST_PRIVATE_GCD_SF( int, unsigned );

+ BOOST_PRIVATE_GCD_SF( long, unsigned long );

+

+#if CHAR_MIN < 0

+ BOOST_PRIVATE_GCD_SF( char, unsigned char ); // char is signed

+#endif

+

+#ifdef BOOST_HAS_LONG_LONG

+ BOOST_PRIVATE_GCD_SF( boost::long_long_type, boost::ulong_long_type );

+#elif defined(BOOST_HAS_MS_INT64)

+ BOOST_PRIVATE_GCD_SF( __int64, unsigned __int64 );

+#endif

+

+#undef BOOST_PRIVATE_GCD_SF

+

+#ifndef BOOST_NO_LIMITS_COMPILE_TIME_CONSTANTS

+#ifndef BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION

+ template < typename T, bool IsSpecialized, bool IsSigned >

+ struct lcm_optimal_evaluator_helper_t

+ {

+ T operator ()( T const &a, T const &b )

+ {

+ return lcm_euclidean( a, b );

+ }

+ };

+

+ template < typename T >

+ struct lcm_optimal_evaluator_helper_t< T, true, true >

+ {

+ T operator ()( T const &a, T const &b )

+ {

+ return lcm_integer( a, b );

+ }

+ };

+#else

+ template < bool IsSpecialized, bool IsSigned >

+ struct lcm_optimal_evaluator_helper2_t

+ {

+ template < typename T >

+ struct helper

+ {

+ T operator ()( T const &a, T const &b )

+ {

+ return lcm_euclidean( a, b );

+ }

+ };

+ };

+

+ template < >

+ struct lcm_optimal_evaluator_helper2_t< true, true >

+ {

+ template < typename T >

+ struct helper

+ {

+ T operator ()( T const &a, T const &b )

+ {

+ return lcm_integer( a, b );

+ }

+ };

+ };

+

+ template < typename T, bool IsSpecialized, bool IsSigned >

+ struct lcm_optimal_evaluator_helper_t

+ : lcm_optimal_evaluator_helper2_t<IsSpecialized, IsSigned>

+ ::BOOST_NESTED_TEMPLATE helper<T>

+ {

+ };

+#endif

+

+ template < typename T >

+ struct lcm_optimal_evaluator

+ {

+ T operator ()( T const &a, T const &b )

+ {

+ typedef ::std::numeric_limits<T> limits_type;

+

+ typedef lcm_optimal_evaluator_helper_t<T,

+ limits_type::is_specialized, limits_type::is_signed> helper_type;

+

+ helper_type solver;

+

+ return solver( a, b );

+ }

+ };

+#else // BOOST_NO_LIMITS_COMPILE_TIME_CONSTANTS

+ template < typename T >

+ struct lcm_optimal_evaluator

+ {

+ T operator ()( T const &a, T const &b )

+ {

+ return lcm_integer( a, b );

+ }

+ };

+#endif

+

+ // Functions to find the GCD or LCM in the best way

+ template < typename T >

+ inline

+ T

+ gcd_optimal

+ (

+ T const & a,

+ T const & b

+ )

+ {

+ gcd_optimal_evaluator<T> solver;

+

+ return solver( a, b );

+ }

+

+ template < typename T >

+ inline

+ T

+ lcm_optimal

+ (

+ T const & a,

+ T const & b

+ )

+ {

+ lcm_optimal_evaluator<T> solver;

+

+ return solver( a, b );

+ }

+

+} // namespace detail

+

+

+// Greatest common divisor evaluator member function definition ------------//

+

+template < typename IntegerType >

+inline

+typename gcd_evaluator<IntegerType>::result_type

+gcd_evaluator<IntegerType>::operator ()

+(

+ first_argument_type const & a,

+ second_argument_type const & b

+) const

+{

+ return detail::gcd_optimal( a, b );

+}

+

+

+// Least common multiple evaluator member function definition --------------//

+

+template < typename IntegerType >

+inline

+typename lcm_evaluator<IntegerType>::result_type

+lcm_evaluator<IntegerType>::operator ()

+(

+ first_argument_type const & a,

+ second_argument_type const & b

+) const

+{

+ return detail::lcm_optimal( a, b );

+}

+

+

+// Greatest common divisor and least common multiple function definitions --//

+

+template < typename IntegerType >

+inline

+IntegerType

+gcd

+(

+ IntegerType const & a,

+ IntegerType const & b

+)

+{

+ gcd_evaluator<IntegerType> solver;

+

+ return solver( a, b );

+}

+

+template < typename IntegerType >

+inline

+IntegerType

+lcm

+(

+ IntegerType const & a,

+ IntegerType const & b

+)

+{

+ lcm_evaluator<IntegerType> solver;

+

+ return solver( a, b );

+}

+

+

+} // namespace math

+} // namespace boost

+

+#ifdef BOOST_MSVC

+#pragma warning(pop)

+#endif

+

+#endif // BOOST_MATH_COMMON_FACTOR_RT_HPP

+// Copyright John Maddock 2007.

+// 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)

+

+#ifndef BOOST_MATH_POLICY_HPP

+#define BOOST_MATH_POLICY_HPP

+

+#include <boost/mpl/list.hpp>

+#include <boost/mpl/contains.hpp>

+#include <boost/mpl/if.hpp>

+#include <boost/mpl/find_if.hpp>

+#include <boost/mpl/remove_if.hpp>

+#include <boost/mpl/vector.hpp>

+#include <boost/mpl/push_back.hpp>

+#include <boost/mpl/at.hpp>

+#include <boost/mpl/size.hpp>

+#include <boost/mpl/comparison.hpp>

+#include <boost/type_traits/is_same.hpp>

+#include <boost/static_assert.hpp>

+#include <boost/assert.hpp>

+#include <boost/math/tools/config.hpp>

+#include <limits>

+// Sadly we do need the .h versions of these to be sure of getting

+// FLT_MANT_DIG etc.

+#include <limits.h>

+#include <stdlib.h>

+#include <stddef.h>

+#include <math.h>

+

+namespace boost{ namespace math{

+

+namespace tools{

+

+template <class T>

+int digits(BOOST_MATH_EXPLICIT_TEMPLATE_TYPE(T));

+template <class T>

+T epsilon(BOOST_MATH_EXPLICIT_TEMPLATE_TYPE(T));

+

+}

+

+namespace policies{

+

+//

+// Define macros for our default policies, if they're not defined already:

+//

+#ifndef BOOST_MATH_DOMAIN_ERROR_POLICY

+#define BOOST_MATH_DOMAIN_ERROR_POLICY throw_on_error

+#endif

+#ifndef BOOST_MATH_POLE_ERROR_POLICY

+#define BOOST_MATH_POLE_ERROR_POLICY throw_on_error

+#endif

+#ifndef BOOST_MATH_OVERFLOW_ERROR_POLICY

+#define BOOST_MATH_OVERFLOW_ERROR_POLICY throw_on_error

+#endif

+#ifndef BOOST_MATH_EVALUATION_ERROR_POLICY

+#define BOOST_MATH_EVALUATION_ERROR_POLICY throw_on_error

+#endif

+#ifndef BOOST_MATH_ROUNDING_ERROR_POLICY

+#define BOOST_MATH_ROUNDING_ERROR_POLICY throw_on_error

+#endif

+#ifndef BOOST_MATH_UNDERFLOW_ERROR_POLICY

+#define BOOST_MATH_UNDERFLOW_ERROR_POLICY ignore_error

+#endif

+#ifndef BOOST_MATH_DENORM_ERROR_POLICY

+#define BOOST_MATH_DENORM_ERROR_POLICY ignore_error

+#endif

+#ifndef BOOST_MATH_INDETERMINATE_RESULT_ERROR_POLICY

+#define BOOST_MATH_INDETERMINATE_RESULT_ERROR_POLICY ignore_error

+#endif

+#ifndef BOOST_MATH_DIGITS10_POLICY

+#define BOOST_MATH_DIGITS10_POLICY 0

+#endif

+#ifndef BOOST_MATH_PROMOTE_FLOAT_POLICY

+#define BOOST_MATH_PROMOTE_FLOAT_POLICY true

+#endif

+#ifndef BOOST_MATH_PROMOTE_DOUBLE_POLICY

+#ifdef BOOST_MATH_NO_LONG_DOUBLE_MATH_FUNCTIONS

+#define BOOST_MATH_PROMOTE_DOUBLE_POLICY false

+#else

+#define BOOST_MATH_PROMOTE_DOUBLE_POLICY true

+#endif

+#endif

+#ifndef BOOST_MATH_DISCRETE_QUANTILE_POLICY

+#define BOOST_MATH_DISCRETE_QUANTILE_POLICY integer_round_outwards

+#endif

+#ifndef BOOST_MATH_ASSERT_UNDEFINED_POLICY

+#define BOOST_MATH_ASSERT_UNDEFINED_POLICY true

+#endif

+#ifndef BOOST_MATH_MAX_SERIES_ITERATION_POLICY

+#define BOOST_MATH_MAX_SERIES_ITERATION_POLICY 1000000

+#endif

+#ifndef BOOST_MATH_MAX_ROOT_ITERATION_POLICY

+#define BOOST_MATH_MAX_ROOT_ITERATION_POLICY 200

+#endif

+

+#if !defined(__BORLANDC__) \

+ && !(defined(__GNUC__) && (__GNUC__ == 3) && (__GNUC_MINOR__ <= 2))

+#define BOOST_MATH_META_INT(type, name, Default)\

+ template <type N = Default> struct name : public boost::mpl::int_<N>{};\

+ namespace detail{\

+ template <type N>\

+ char test_is_valid_arg(const name<N>*);\

+ char test_is_default_arg(const name<Default>*);\

+ template <class T> struct is_##name##_imp\

+ {\

+ template <type N> static char test(const name<N>*);\

+ static double test(...);\

+ BOOST_STATIC_CONSTANT(bool, value = sizeof(test(static_cast<T*>(0))) == 1);\

+ };\

+ }\

+ template <class T> struct is_##name : public boost::mpl::bool_< ::boost::math::policies::detail::is_##name##_imp<T>::value>{};

+

+#define BOOST_MATH_META_BOOL(name, Default)\

+ template <bool N = Default> struct name : public boost::mpl::bool_<N>{};\

+ namespace detail{\

+ template <bool N>\

+ char test_is_valid_arg(const name<N>*);\

+ char test_is_default_arg(const name<Default>*);\

+ template <class T> struct is_##name##_imp\

+ {\

+ template <bool N> static char test(const name<N>*);\

+ static double test(...);\

+ BOOST_STATIC_CONSTANT(bool, value = sizeof(test(static_cast<T*>(0))) == 1);\

+ };\

+ }\

+ template <class T> struct is_##name : public boost::mpl::bool_< ::boost::math::policies::detail::is_##name##_imp<T>::value>{};

+#else

+#define BOOST_MATH_META_INT(Type, name, Default)\

+ template <Type N = Default> struct name : public boost::mpl::int_<N>{};\

+ namespace detail{\

+ template <Type N>\

+ char test_is_valid_arg(const name<N>*);\

+ char test_is_default_arg(const name<Default>*);\

+ template <class T> struct is_##name##_tester\

+ {\

+ template <Type N> static char test(const name<N>&);\

+ static double test(...);\

+ };\

+ template <class T> struct is_##name##_imp\

+ {\

+ static T inst;\

+ BOOST_STATIC_CONSTANT(bool, value = sizeof( ::boost::math::policies::detail::is_##name##_tester<T>::test(inst)) == 1);\

+ };\

+ }\

+ template <class T> struct is_##name : public boost::mpl::bool_< ::boost::math::policies::detail::is_##name##_imp<T>::value>\

+ {\

+ template <class U> struct apply{ typedef is_##name<U> type; };\

+ };

+

+#define BOOST_MATH_META_BOOL(name, Default)\

+ template <bool N = Default> struct name : public boost::mpl::bool_<N>{};\

+ namespace detail{\

+ template <bool N>\

+ char test_is_valid_arg(const name<N>*);\

+ char test_is_default_arg(const name<Default>*);\

+ template <class T> struct is_##name##_tester\

+ {\

+ template <bool N> static char test(const name<N>&);\

+ static double test(...);\

+ };\

+ template <class T> struct is_##name##_imp\

+ {\

+ static T inst;\

+ BOOST_STATIC_CONSTANT(bool, value = sizeof( ::boost::math::policies::detail::is_##name##_tester<T>::test(inst)) == 1);\

+ };\

+ }\

+ template <class T> struct is_##name : public boost::mpl::bool_< ::boost::math::policies::detail::is_##name##_imp<T>::value>\

+ {\

+ template <class U> struct apply{ typedef is_##name<U> type; };\

+ };

+#endif

+//

+// Begin by defining policy types for error handling:

+//

+enum error_policy_type

+{

+ throw_on_error = 0,

+ errno_on_error = 1,

+ ignore_error = 2,

+ user_error = 3

+};

+

+BOOST_MATH_META_INT(error_policy_type, domain_error, BOOST_MATH_DOMAIN_ERROR_POLICY)

+BOOST_MATH_META_INT(error_policy_type, pole_error, BOOST_MATH_POLE_ERROR_POLICY)

+BOOST_MATH_META_INT(error_policy_type, overflow_error, BOOST_MATH_OVERFLOW_ERROR_POLICY)

+BOOST_MATH_META_INT(error_policy_type, underflow_error, BOOST_MATH_UNDERFLOW_ERROR_POLICY)

+BOOST_MATH_META_INT(error_policy_type, denorm_error, BOOST_MATH_DENORM_ERROR_POLICY)

+BOOST_MATH_META_INT(error_policy_type, evaluation_error, BOOST_MATH_EVALUATION_ERROR_POLICY)

+BOOST_MATH_META_INT(error_policy_type, rounding_error, BOOST_MATH_ROUNDING_ERROR_POLICY)

+BOOST_MATH_META_INT(error_policy_type, indeterminate_result_error, BOOST_MATH_INDETERMINATE_RESULT_ERROR_POLICY)

+

+//

+// Policy types for internal promotion:

+//

+BOOST_MATH_META_BOOL(promote_float, BOOST_MATH_PROMOTE_FLOAT_POLICY)

+BOOST_MATH_META_BOOL(promote_double, BOOST_MATH_PROMOTE_DOUBLE_POLICY)

+BOOST_MATH_META_BOOL(assert_undefined, BOOST_MATH_ASSERT_UNDEFINED_POLICY)

+//

+// Policy types for discrete quantiles:

+//

+enum discrete_quantile_policy_type

+{

+ real,

+ integer_round_outwards,

+ integer_round_inwards,

+ integer_round_down,

+ integer_round_up,

+ integer_round_nearest

+};

+

+BOOST_MATH_META_INT(discrete_quantile_policy_type, discrete_quantile, BOOST_MATH_DISCRETE_QUANTILE_POLICY)

+//

+// Precision:

+//

+BOOST_MATH_META_INT(int, digits10, BOOST_MATH_DIGITS10_POLICY)

+BOOST_MATH_META_INT(int, digits2, 0)

+//

+// Iterations:

+//

+BOOST_MATH_META_INT(unsigned long, max_series_iterations, BOOST_MATH_MAX_SERIES_ITERATION_POLICY)

+BOOST_MATH_META_INT(unsigned long, max_root_iterations, BOOST_MATH_MAX_ROOT_ITERATION_POLICY)

+//

+// Define the names for each possible policy:

+//

+#define BOOST_MATH_PARAMETER(name)\

+ BOOST_PARAMETER_TEMPLATE_KEYWORD(name##_name)\

+ BOOST_PARAMETER_NAME(name##_name)

+

+struct default_policy{};

+

+namespace detail{

+//

+// Trait to work out bits precision from digits10 and digits2:

+//

+template <class Digits10, class Digits2>

+struct precision

+{

+ //

+ // Now work out the precision:

+ //

+ typedef typename mpl::if_c<

+ (Digits10::value == 0),

+ digits2<0>,

+ digits2<((Digits10::value + 1) * 1000L) / 301L>

+ >::type digits2_type;

+public:

+#ifdef __BORLANDC__

+ typedef typename mpl::if_c<

+ (Digits2::value > ::boost::math::policies::detail::precision<Digits10,Digits2>::digits2_type::value),

+ Digits2, digits2_type>::type type;

+#else

+ typedef typename mpl::if_c<

+ (Digits2::value > digits2_type::value),

+ Digits2, digits2_type>::type type;

+#endif

+};

+

+template <class A, class B, bool b>

+struct select_result

+{

+ typedef A type;

+};

+template <class A, class B>

+struct select_result<A, B, false>

+{

+ typedef typename mpl::deref<B>::type type;

+};

+

+template <class Seq, class Pred, class DefaultType>

+struct find_arg

+{

+private:

+ typedef typename mpl::find_if<Seq, Pred>::type iter;

+ typedef typename mpl::end<Seq>::type end_type;

+public:

+ typedef typename select_result<

+ DefaultType, iter,

+ ::boost::is_same<iter, end_type>::value>::type type;

+};

+

+double test_is_valid_arg(...);

+double test_is_default_arg(...);

+char test_is_valid_arg(const default_policy*);

+char test_is_default_arg(const default_policy*);

+

+template <class T>

+struct is_valid_policy_imp

+{

+ BOOST_STATIC_CONSTANT(bool, value = sizeof(::boost::math::policies::detail::test_is_valid_arg(static_cast<T*>(0))) == 1);

+};

+

+template <class T>

+struct is_default_policy_imp

+{

+ BOOST_STATIC_CONSTANT(bool, value = sizeof(::boost::math::policies::detail::test_is_default_arg(static_cast<T*>(0))) == 1);

+};

+

+template <class T> struct is_valid_policy

+: public mpl::bool_<

+ ::boost::math::policies::detail::is_valid_policy_imp<T>::value>

+{};

+

+template <class T> struct is_default_policy

+: public mpl::bool_<

+ ::boost::math::policies::detail::is_default_policy_imp<T>::value>

+{

+ template <class U>

+ struct apply

+ {

+ typedef is_default_policy<U> type;

+ };

+};

+

+template <class Seq, class T, int N>

+struct append_N

+{

+ typedef typename mpl::push_back<Seq, T>::type new_seq;

+ typedef typename append_N<new_seq, T, N-1>::type type;

+};

+

+template <class Seq, class T>

+struct append_N<Seq, T, 0>

+{

+ typedef Seq type;

+};

+

+//

+// Traits class to work out what template parameters our default

+// policy<> class will have when modified for forwarding:

+//

+template <bool f, bool d>

+struct default_args

+{

+ typedef promote_float<false> arg1;

+ typedef promote_double<false> arg2;

+};

+

+template <>

+struct default_args<false, false>

+{

+ typedef default_policy arg1;

+ typedef default_policy arg2;

+};

+

+template <>

+struct default_args<true, false>

+{

+ typedef promote_float<false> arg1;

+ typedef default_policy arg2;

+};

+

+template <>

+struct default_args<false, true>

+{

+ typedef promote_double<false> arg1;

+ typedef default_policy arg2;

+};

+

+typedef default_args<BOOST_MATH_PROMOTE_FLOAT_POLICY, BOOST_MATH_PROMOTE_DOUBLE_POLICY>::arg1 forwarding_arg1;

+typedef default_args<BOOST_MATH_PROMOTE_FLOAT_POLICY, BOOST_MATH_PROMOTE_DOUBLE_POLICY>::arg2 forwarding_arg2;

+

+} // detail

+//

+// Now define the policy type with enough arguments to handle all

+// the policies:

+//

+template <class A1 = default_policy,

+ class A2 = default_policy,

+ class A3 = default_policy,

+ class A4 = default_policy,

+ class A5 = default_policy,

+ class A6 = default_policy,

+ class A7 = default_policy,

+ class A8 = default_policy,

+ class A9 = default_policy,

+ class A10 = default_policy,

+ class A11 = default_policy,

+ class A12 = default_policy,

+ class A13 = default_policy>

+struct policy

+{

+private:

+ //

+ // Validate all our arguments:

+ //

+ BOOST_STATIC_ASSERT(::boost::math::policies::detail::is_valid_policy<A1>::value);

+ BOOST_STATIC_ASSERT(::boost::math::policies::detail::is_valid_policy<A2>::value);

+ BOOST_STATIC_ASSERT(::boost::math::policies::detail::is_valid_policy<A3>::value);

+ BOOST_STATIC_ASSERT(::boost::math::policies::detail::is_valid_policy<A4>::value);

+ BOOST_STATIC_ASSERT(::boost::math::policies::detail::is_valid_policy<A5>::value);

+ BOOST_STATIC_ASSERT(::boost::math::policies::detail::is_valid_policy<A6>::value);

+ BOOST_STATIC_ASSERT(::boost::math::policies::detail::is_valid_policy<A7>::value);

+ BOOST_STATIC_ASSERT(::boost::math::policies::detail::is_valid_policy<A8>::value);

+ BOOST_STATIC_ASSERT(::boost::math::policies::detail::is_valid_policy<A9>::value);

+ BOOST_STATIC_ASSERT(::boost::math::policies::detail::is_valid_policy<A10>::value);

+ BOOST_STATIC_ASSERT(::boost::math::policies::detail::is_valid_policy<A11>::value);

+ BOOST_STATIC_ASSERT(::boost::math::policies::detail::is_valid_policy<A12>::value);

+ BOOST_STATIC_ASSERT(::boost::math::policies::detail::is_valid_policy<A13>::value);

+ //

+ // Typelist of the arguments:

+ //

+ typedef mpl::list<A1,A2,A3,A4,A5,A6,A7,A8,A9,A10,A11,A12,A13> arg_list;

+

+public:

+ typedef typename detail::find_arg<arg_list, is_domain_error<mpl::_1>, domain_error<> >::type domain_error_type;

+ typedef typename detail::find_arg<arg_list, is_pole_error<mpl::_1>, pole_error<> >::type pole_error_type;

+ typedef typename detail::find_arg<arg_list, is_overflow_error<mpl::_1>, overflow_error<> >::type overflow_error_type;

+ typedef typename detail::find_arg<arg_list, is_underflow_error<mpl::_1>, underflow_error<> >::type underflow_error_type;

+ typedef typename detail::find_arg<arg_list, is_denorm_error<mpl::_1>, denorm_error<> >::type denorm_error_type;

+ typedef typename detail::find_arg<arg_list, is_evaluation_error<mpl::_1>, evaluation_error<> >::type evaluation_error_type;

+ typedef typename detail::find_arg<arg_list, is_rounding_error<mpl::_1>, rounding_error<> >::type rounding_error_type;

+ typedef typename detail::find_arg<arg_list, is_indeterminate_result_error<mpl::_1>, indeterminate_result_error<> >::type indeterminate_result_error_type;

+private:

+ //

+ // Now work out the precision:

+ //

+ typedef typename detail::find_arg<arg_list, is_digits10<mpl::_1>, digits10<> >::type digits10_type;

+ typedef typename detail::find_arg<arg_list, is_digits2<mpl::_1>, digits2<> >::type bits_precision_type;

+public:

+ typedef typename detail::precision<digits10_type, bits_precision_type>::type precision_type;

+ //

+ // Internal promotion:

+ //

+ typedef typename detail::find_arg<arg_list, is_promote_float<mpl::_1>, promote_float<> >::type promote_float_type;

+ typedef typename detail::find_arg<arg_list, is_promote_double<mpl::_1>, promote_double<> >::type promote_double_type;

+ //

+ // Discrete quantiles:

+ //

+ typedef typename detail::find_arg<arg_list, is_discrete_quantile<mpl::_1>, discrete_quantile<> >::type discrete_quantile_type;

+ //

+ // Mathematically undefined properties:

+ //

+ typedef typename detail::find_arg<arg_list, is_assert_undefined<mpl::_1>, assert_undefined<> >::type assert_undefined_type;

+ //

+ // Max iterations:

+ //

+ typedef typename detail::find_arg<arg_list, is_max_series_iterations<mpl::_1>, max_series_iterations<> >::type max_series_iterations_type;

+ typedef typename detail::find_arg<arg_list, is_max_root_iterations<mpl::_1>, max_root_iterations<> >::type max_root_iterations_type;

+};

+//

+// These full specializations are defined to reduce the amount of

+// template instantiations that have to take place when using the default

+// policies, they have quite a large impact on compile times:

+//

+template <>

+struct policy<default_policy, default_policy, default_policy, default_policy, default_policy, default_policy, default_policy, default_policy, default_policy, default_policy, default_policy>

+{

+public:

+ typedef domain_error<> domain_error_type;

+ typedef pole_error<> pole_error_type;

+ typedef overflow_error<> overflow_error_type;

+ typedef underflow_error<> underflow_error_type;

+ typedef denorm_error<> denorm_error_type;

+ typedef evaluation_error<> evaluation_error_type;

+ typedef rounding_error<> rounding_error_type;

+ typedef indeterminate_result_error<> indeterminate_result_error_type;

+#if BOOST_MATH_DIGITS10_POLICY == 0

+ typedef digits2<> precision_type;

+#else

+ typedef detail::precision<digits10<>, digits2<> >::type precision_type;

+#endif

+ typedef promote_float<> promote_float_type;

+ typedef promote_double<> promote_double_type;

+ typedef discrete_quantile<> discrete_quantile_type;

+ typedef assert_undefined<> assert_undefined_type;

+ typedef max_series_iterations<> max_series_iterations_type;

+ typedef max_root_iterations<> max_root_iterations_type;

+};

+

+template <>

+struct policy<detail::forwarding_arg1, detail::forwarding_arg2, default_policy, default_policy, default_policy, default_policy, default_policy, default_policy, default_policy, default_policy, default_policy>

+{

+public:

+ typedef domain_error<> domain_error_type;

+ typedef pole_error<> pole_error_type;

+ typedef overflow_error<> overflow_error_type;

+ typedef underflow_error<> underflow_error_type;

+ typedef denorm_error<> denorm_error_type;

+ typedef evaluation_error<> evaluation_error_type;

+ typedef rounding_error<> rounding_error_type;

+ typedef indeterminate_result_error<> indeterminate_result_error_type;

+#if BOOST_MATH_DIGITS10_POLICY == 0

+ typedef digits2<> precision_type;

+#else

+ typedef detail::precision<digits10<>, digits2<> >::type precision_type;

+#endif

+ typedef promote_float<false> promote_float_type;

+ typedef promote_double<false> promote_double_type;

+ typedef discrete_quantile<> discrete_quantile_type;

+ typedef assert_undefined<> assert_undefined_type;

+ typedef max_series_iterations<> max_series_iterations_type;

+ typedef max_root_iterations<> max_root_iterations_type;

+};

+

+template <class Policy,

+ class A1 = default_policy,

+ class A2 = default_policy,

+ class A3 = default_policy,

+ class A4 = default_policy,

+ class A5 = default_policy,

+ class A6 = default_policy,

+ class A7 = default_policy,

+ class A8 = default_policy,

+ class A9 = default_policy,

+ class A10 = default_policy,

+ class A11 = default_policy,

+ class A12 = default_policy,

+ class A13 = default_policy>

+struct normalise

+{

+private:

+ typedef mpl::list<A1,A2,A3,A4,A5,A6,A7,A8,A9,A10,A11,A12,A13> arg_list;

+ typedef typename detail::find_arg<arg_list, is_domain_error<mpl::_1>, typename Policy::domain_error_type >::type domain_error_type;

+ typedef typename detail::find_arg<arg_list, is_pole_error<mpl::_1>, typename Policy::pole_error_type >::type pole_error_type;

+ typedef typename detail::find_arg<arg_list, is_overflow_error<mpl::_1>, typename Policy::overflow_error_type >::type overflow_error_type;

+ typedef typename detail::find_arg<arg_list, is_underflow_error<mpl::_1>, typename Policy::underflow_error_type >::type underflow_error_type;

+ typedef typename detail::find_arg<arg_list, is_denorm_error<mpl::_1>, typename Policy::denorm_error_type >::type denorm_error_type;

+ typedef typename detail::find_arg<arg_list, is_evaluation_error<mpl::_1>, typename Policy::evaluation_error_type >::type evaluation_error_type;

+ typedef typename detail::find_arg<arg_list, is_rounding_error<mpl::_1>, typename Policy::rounding_error_type >::type rounding_error_type;

+ typedef typename detail::find_arg<arg_list, is_indeterminate_result_error<mpl::_1>, typename Policy::indeterminate_result_error_type >::type indeterminate_result_error_type;

+ //

+ // Now work out the precision:

+ //

+ typedef typename detail::find_arg<arg_list, is_digits10<mpl::_1>, digits10<> >::type digits10_type;

+ typedef typename detail::find_arg<arg_list, is_digits2<mpl::_1>, typename Policy::precision_type >::type bits_precision_type;

+ typedef typename detail::precision<digits10_type, bits_precision_type>::type precision_type;

+ //

+ // Internal promotion:

+ //

+ typedef typename detail::find_arg<arg_list, is_promote_float<mpl::_1>, typename Policy::promote_float_type >::type promote_float_type;

+ typedef typename detail::find_arg<arg_list, is_promote_double<mpl::_1>, typename Policy::promote_double_type >::type promote_double_type;

+ //

+ // Discrete quantiles:

+ //

+ typedef typename detail::find_arg<arg_list, is_discrete_quantile<mpl::_1>, typename Policy::discrete_quantile_type >::type discrete_quantile_type;

+ //

+ // Mathematically undefined properties:

+ //

+ typedef typename detail::find_arg<arg_list, is_assert_undefined<mpl::_1>, typename Policy::assert_undefined_type >::type assert_undefined_type;

+ //

+ // Max iterations:

+ //

+ typedef typename detail::find_arg<arg_list, is_max_series_iterations<mpl::_1>, typename Policy::max_series_iterations_type>::type max_series_iterations_type;

+ typedef typename detail::find_arg<arg_list, is_max_root_iterations<mpl::_1>, typename Policy::max_root_iterations_type>::type max_root_iterations_type;

+ //

+ // Define a typelist of the policies:

+ //

+ typedef mpl::vector<

+ domain_error_type,

+ pole_error_type,

+ overflow_error_type,

+ underflow_error_type,

+ denorm_error_type,

+ evaluation_error_type,

+ rounding_error_type,

+ indeterminate_result_error_type,

+ precision_type,

+ promote_float_type,

+ promote_double_type,

+ discrete_quantile_type,

+ assert_undefined_type,

+ max_series_iterations_type,

+ max_root_iterations_type> result_list;

+ //

+ // Remove all the policies that are the same as the default:

+ //

+ typedef typename mpl::remove_if<result_list, detail::is_default_policy<mpl::_> >::type reduced_list;

+ //

+ // Pad out the list with defaults:

+ //

+ typedef typename detail::append_N<reduced_list, default_policy, (14 - ::boost::mpl::size<reduced_list>::value)>::type result_type;

+public:

+ typedef policy<

+ typename mpl::at<result_type, mpl::int_<0> >::type,

+ typename mpl::at<result_type, mpl::int_<1> >::type,

+ typename mpl::at<result_type, mpl::int_<2> >::type,

+ typename mpl::at<result_type, mpl::int_<3> >::type,

+ typename mpl::at<result_type, mpl::int_<4> >::type,

+ typename mpl::at<result_type, mpl::int_<5> >::type,

+ typename mpl::at<result_type, mpl::int_<6> >::type,

+ typename mpl::at<result_type, mpl::int_<7> >::type,

+ typename mpl::at<result_type, mpl::int_<8> >::type,

+ typename mpl::at<result_type, mpl::int_<9> >::type,

+ typename mpl::at<result_type, mpl::int_<10> >::type,

+ typename mpl::at<result_type, mpl::int_<11> >::type,

+ typename mpl::at<result_type, mpl::int_<12> >::type > type;

+};

+//

+// Full specialisation to speed up compilation of the common case:

+//

+template <>

+struct normalise<policy<>,

+ promote_float<false>,

+ promote_double<false>,

+ discrete_quantile<>,

+ assert_undefined<>,

+ default_policy,

+ default_policy,

+ default_policy,

+ default_policy,

+ default_policy,

+ default_policy,

+ default_policy>

+{

+ typedef policy<detail::forwarding_arg1, detail::forwarding_arg2> type;

+};

+

+template <>

+struct normalise<policy<detail::forwarding_arg1, detail::forwarding_arg2>,

+ promote_float<false>,

+ promote_double<false>,

+ discrete_quantile<>,

+ assert_undefined<>,

+ default_policy,

+ default_policy,

+ default_policy,

+ default_policy,

+ default_policy,

+ default_policy,

+ default_policy>

+{

+ typedef policy<detail::forwarding_arg1, detail::forwarding_arg2> type;

+};

+

+inline policy<> make_policy()

+{ return policy<>(); }

+

+template <class A1>

+inline typename normalise<policy<>, A1>::type make_policy(const A1&)

+{

+ typedef typename normalise<policy<>, A1>::type result_type;

+ return result_type();

+}

+

+template <class A1, class A2>

+inline typename normalise<policy<>, A1, A2>::type make_policy(const A1&, const A2&)

+{

+ typedef typename normalise<policy<>, A1, A2>::type result_type;

+ return result_type();

+}

+

+template <class A1, class A2, class A3>

+inline typename normalise<policy<>, A1, A2, A3>::type make_policy(const A1&, const A2&, const A3&)

+{

+ typedef typename normalise<policy<>, A1, A2, A3>::type result_type;

+ return result_type();

+}

+

+template <class A1, class A2, class A3, class A4>

+inline typename normalise<policy<>, A1, A2, A3, A4>::type make_policy(const A1&, const A2&, const A3&, const A4&)

+{

+ typedef typename normalise<policy<>, A1, A2, A3, A4>::type result_type;

+ return result_type();

+}

+

+template <class A1, class A2, class A3, class A4, class A5>

+inline typename normalise<policy<>, A1, A2, A3, A4, A5>::type make_policy(const A1&, const A2&, const A3&, const A4&, const A5&)

+{

+ typedef typename normalise<policy<>, A1, A2, A3, A4, A5>::type result_type;

+ return result_type();

+}

+

+template <class A1, class A2, class A3, class A4, class A5, class A6>

+inline typename normalise<policy<>, A1, A2, A3, A4, A5, A6>::type make_policy(const A1&, const A2&, const A3&, const A4&, const A5&, const A6&)

+{

+ typedef typename normalise<policy<>, A1, A2, A3, A4, A5, A6>::type result_type;

+ return result_type();

+}

+

+template <class A1, class A2, class A3, class A4, class A5, class A6, class A7>

+inline typename normalise<policy<>, A1, A2, A3, A4, A5, A6, A7>::type make_policy(const A1&, const A2&, const A3&, const A4&, const A5&, const A6&, const A7&)

+{

+ typedef typename normalise<policy<>, A1, A2, A3, A4, A5, A6, A7>::type result_type;

+ return result_type();

+}

+

+template <class A1, class A2, class A3, class A4, class A5, class A6, class A7, class A8>

+inline typename normalise<policy<>, A1, A2, A3, A4, A5, A6, A7, A8>::type make_policy(const A1&, const A2&, const A3&, const A4&, const A5&, const A6&, const A7&, const A8&)

+{

+ typedef typename normalise<policy<>, A1, A2, A3, A4, A5, A6, A7, A8>::type result_type;

+ return result_type();

+}

+

+template <class A1, class A2, class A3, class A4, class A5, class A6, class A7, class A8, class A9>

+inline typename normalise<policy<>, A1, A2, A3, A4, A5, A6, A7, A8, A9>::type make_policy(const A1&, const A2&, const A3&, const A4&, const A5&, const A6&, const A7&, const A8&, const A9&)

+{

+ typedef typename normalise<policy<>, A1, A2, A3, A4, A5, A6, A7, A8, A9>::type result_type;

+ return result_type();

+}

+

+template <class A1, class A2, class A3, class A4, class A5, class A6, class A7, class A8, class A9, class A10>

+inline typename normalise<policy<>, A1, A2, A3, A4, A5, A6, A7, A8, A9, A10>::type make_policy(const A1&, const A2&, const A3&, const A4&, const A5&, const A6&, const A7&, const A8&, const A9&, const A10&)

+{

+ typedef typename normalise<policy<>, A1, A2, A3, A4, A5, A6, A7, A8, A9, A10>::type result_type;

+ return result_type();

+}

+

+template <class A1, class A2, class A3, class A4, class A5, class A6, class A7, class A8, class A9, class A10, class A11>

+inline typename normalise<policy<>, A1, A2, A3, A4, A5, A6, A7, A8, A9, A10, A11>::type make_policy(const A1&, const A2&, const A3&, const A4&, const A5&, const A6&, const A7&, const A8&, const A9&, const A10&, const A11&)

+{

+ typedef typename normalise<policy<>, A1, A2, A3, A4, A5, A6, A7, A8, A9, A10, A11>::type result_type;

+ return result_type();

+}

+

+//

+// Traits class to handle internal promotion:

+//

+template <class Real, class Policy>

+struct evaluation

+{

+ typedef Real type;

+};

+

+template <class Policy>

+struct evaluation<float, Policy>

+{

+ typedef typename mpl::if_<typename Policy::promote_float_type, double, float>::type type;

+};

+

+template <class Policy>

+struct evaluation<double, Policy>

+{

+ typedef typename mpl::if_<typename Policy::promote_double_type, long double, double>::type type;

+};

+

+#ifdef BOOST_NO_LIMITS_COMPILE_TIME_CONSTANTS

+

+template <class Real>

+struct basic_digits : public mpl::int_<0>{ };

+template <>

+struct basic_digits<float> : public mpl::int_<FLT_MANT_DIG>{ };

+template <>

+struct basic_digits<double> : public mpl::int_<DBL_MANT_DIG>{ };

+template <>

+struct basic_digits<long double> : public mpl::int_<LDBL_MANT_DIG>{ };

+

+template <class Real, class Policy>

+struct precision

+{

+ BOOST_STATIC_ASSERT( ::std::numeric_limits<Real>::radix == 2);

+ typedef typename Policy::precision_type precision_type;

+ typedef basic_digits<Real> digits_t;

+ typedef typename mpl::if_<

+ mpl::equal_to<digits_t, mpl::int_<0> >,

+ // Possibly unknown precision:

+ precision_type,

+ typename mpl::if_<

+ mpl::or_<mpl::less_equal<digits_t, precision_type>, mpl::less_equal<precision_type, mpl::int_<0> > >,

+ // Default case, full precision for RealType:

+ digits2< ::std::numeric_limits<Real>::digits>,

+ // User customised precision:

+ precision_type

+ >::type

+ >::type type;

+};

+

+template <class Policy>

+struct precision<float, Policy>

+{

+ typedef digits2<FLT_MANT_DIG> type;

+};

+template <class Policy>

+struct precision<double, Policy>

+{

+ typedef digits2<DBL_MANT_DIG> type;

+};

+template <class Policy>

+struct precision<long double, Policy>

+{

+ typedef digits2<LDBL_MANT_DIG> type;

+};

+

+#else

+

+template <class Real, class Policy>

+struct precision

+{

+ BOOST_STATIC_ASSERT((::std::numeric_limits<Real>::radix == 2) || ((::std::numeric_limits<Real>::is_specialized == 0) || (::std::numeric_limits<Real>::digits == 0)));

+#ifndef __BORLANDC__

+ typedef typename Policy::precision_type precision_type;

+ typedef typename mpl::if_c<

+ ((::std::numeric_limits<Real>::is_specialized == 0) || (::std::numeric_limits<Real>::digits == 0)),

+ // Possibly unknown precision:

+ precision_type,

+ typename mpl::if_c<

+ ((::std::numeric_limits<Real>::digits <= precision_type::value)

+ || (Policy::precision_type::value <= 0)),

+ // Default case, full precision for RealType:

+ digits2< ::std::numeric_limits<Real>::digits>,

+ // User customised precision:

+ precision_type

+ >::type

+ >::type type;

+#else

+ typedef typename Policy::precision_type precision_type;

+ typedef mpl::int_< ::std::numeric_limits<Real>::digits> digits_t;

+ typedef mpl::bool_< ::std::numeric_limits<Real>::is_specialized> spec_t;

+ typedef typename mpl::if_<

+ mpl::or_<mpl::equal_to<spec_t, mpl::false_>, mpl::equal_to<digits_t, mpl::int_<0> > >,

+ // Possibly unknown precision:

+ precision_type,

+ typename mpl::if_<

+ mpl::or_<mpl::less_equal<digits_t, precision_type>, mpl::less_equal<precision_type, mpl::int_<0> > >,

+ // Default case, full precision for RealType:

+ digits2< ::std::numeric_limits<Real>::digits>,

+ // User customised precision:

+ precision_type

+ >::type

+ >::type type;

+#endif

+};

+

+#endif

+

+namespace detail{

+

+template <class T, class Policy>

+inline int digits_imp(mpl::true_ const&)

+{

+#ifndef BOOST_NO_LIMITS_COMPILE_TIME_CONSTANTS

+ BOOST_STATIC_ASSERT( ::std::numeric_limits<T>::is_specialized);

+#else

+ BOOST_ASSERT(::std::numeric_limits<T>::is_specialized);

+#endif

+ typedef typename boost::math::policies::precision<T, Policy>::type p_t;

+ return p_t::value;

+}

+

+template <class T, class Policy>

+inline int digits_imp(mpl::false_ const&)

+{

+ return tools::digits<T>();

+}

+

+} // namespace detail

+

+template <class T, class Policy>

+inline int digits(BOOST_MATH_EXPLICIT_TEMPLATE_TYPE(T))

+{

+ typedef mpl::bool_< std::numeric_limits<T>::is_specialized > tag_type;

+ return detail::digits_imp<T, Policy>(tag_type());

+}

+

+template <class Policy>

+inline unsigned long get_max_series_iterations()

+{

+ typedef typename Policy::max_series_iterations_type iter_type;

+ return iter_type::value;

+}

+

+template <class Policy>

+inline unsigned long get_max_root_iterations()

+{

+ typedef typename Policy::max_root_iterations_type iter_type;

+ return iter_type::value;

+}

+

+namespace detail{

+

+template <class T, class Digits, class Small, class Default>

+struct series_factor_calc

+{

+ static T get()

+ {

+ return ldexp(T(1.0), 1 - Digits::value);

+ }

+};

+

+template <class T, class Digits>

+struct series_factor_calc<T, Digits, mpl::true_, mpl::true_>

+{

+ static T get()

+ {

+ return boost::math::tools::epsilon<T>();

+ }

+};

+template <class T, class Digits>

+struct series_factor_calc<T, Digits, mpl::true_, mpl::false_>

+{

+ static T get()

+ {

+ static const boost::uintmax_t v = static_cast<boost::uintmax_t>(1u) << (Digits::value - 1);

+ return 1 / static_cast<T>(v);

+ }

+};

+template <class T, class Digits>

+struct series_factor_calc<T, Digits, mpl::false_, mpl::true_>

+{

+ static T get()

+ {

+ return boost::math::tools::epsilon<T>();

+ }

+};

+

+template <class T, class Policy>

+inline T get_epsilon_imp(mpl::true_ const&)

+{

+#ifndef BOOST_NO_LIMITS_COMPILE_TIME_CONSTANTS

+ BOOST_STATIC_ASSERT( ::std::numeric_limits<T>::is_specialized);

+ BOOST_STATIC_ASSERT( ::std::numeric_limits<T>::radix == 2);

+#else

+ BOOST_ASSERT(::std::numeric_limits<T>::is_specialized);

+ BOOST_ASSERT(::std::numeric_limits<T>::radix == 2);

+#endif

+ typedef typename boost::math::policies::precision<T, Policy>::type p_t;

+ typedef mpl::bool_<p_t::value <= std::numeric_limits<boost::uintmax_t>::digits> is_small_int;

+ typedef mpl::bool_<p_t::value >= std::numeric_limits<T>::digits> is_default_value;

+ return series_factor_calc<T, p_t, is_small_int, is_default_value>::get();

+}

+

+template <class T, class Policy>

+inline T get_epsilon_imp(mpl::false_ const&)

+{

+ return tools::epsilon<T>();

+}

+

+} // namespace detail

+

+template <class T, class Policy>

+inline T get_epsilon(BOOST_MATH_EXPLICIT_TEMPLATE_TYPE(T))

+{

+ typedef mpl::bool_< (std::numeric_limits<T>::is_specialized && (std::numeric_limits<T>::radix == 2)) > tag_type;

+ return detail::get_epsilon_imp<T, Policy>(tag_type());

+}

+

+namespace detail{

+

+template <class A1,

+ class A2,

+ class A3,

+ class A4,

+ class A5,

+ class A6,

+ class A7,

+ class A8,

+ class A9,

+ class A10,

+ class A11>

+char test_is_policy(const policy<A1,A2,A3,A4,A5,A6,A7,A8,A9,A10,A11>*);

+double test_is_policy(...);

+

+template <class P>

+struct is_policy_imp

+{

+ BOOST_STATIC_CONSTANT(bool, value = (sizeof(::boost::math::policies::detail::test_is_policy(static_cast<P*>(0))) == 1));

+};

+

+}

+

+template <class P>

+struct is_policy : public mpl::bool_< ::boost::math::policies::detail::is_policy_imp<P>::value> {};

+

+//

+// Helper traits class for distribution error handling:

+//

+template <class Policy>

+struct constructor_error_check

+{

+ typedef typename Policy::domain_error_type domain_error_type;

+ typedef typename mpl::if_c<

+ (domain_error_type::value == throw_on_error) || (domain_error_type::value == user_error),

+ mpl::true_,

+ mpl::false_>::type type;

+};

+

+template <class Policy>

+struct method_error_check

+{

+ typedef typename Policy::domain_error_type domain_error_type;

+ typedef typename mpl::if_c<

+ (domain_error_type::value == throw_on_error) && (domain_error_type::value != user_error),

+ mpl::false_,

+ mpl::true_>::type type;

+};

+

+}}} // namespaces

+

+#endif // BOOST_MATH_POLICY_HPP

+

+

+

+// fp_traits.hpp

+

+#ifndef BOOST_MATH_FP_TRAITS_HPP

+#define BOOST_MATH_FP_TRAITS_HPP

+

+// Copyright (c) 2006 Johan Rade

+

+// 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)

+

+/*

+To support old compilers, care has been taken to avoid partial template

+specialization and meta function forwarding.

+With these techniques, the code could be simplified.

+*/

+

+#if defined(__vms) && defined(__DECCXX) && !__IEEE_FLOAT

+// The VAX floating point formats are used (for float and double)

+# define BOOST_FPCLASSIFY_VAX_FORMAT

+#endif

+

+#include <cstring>

+

+#include <boost/assert.hpp>

+#include <boost/cstdint.hpp>

+#include <boost/detail/endian.hpp>

+#include <boost/static_assert.hpp>

+#include <boost/type_traits/is_floating_point.hpp>

+

+#ifdef BOOST_NO_STDC_NAMESPACE

+ namespace std{ using ::memcpy; }

+#endif

+

+#ifndef FP_NORMAL

+

+#define FP_ZERO 0

+#define FP_NORMAL 1

+#define FP_INFINITE 2

+#define FP_NAN 3

+#define FP_SUBNORMAL 4

+

+#else

+

+#define BOOST_HAS_FPCLASSIFY

+

+#ifndef fpclassify

+# if (defined(__GLIBCPP__) || defined(__GLIBCXX__)) \

+ && defined(_GLIBCXX_USE_C99_MATH) \

+ && !(defined(_GLIBCXX_USE_C99_FP_MACROS_DYNAMIC) \

+ && (_GLIBCXX_USE_C99_FP_MACROS_DYNAMIC != 0))

+# ifdef _STLP_VENDOR_CSTD

+# if _STLPORT_VERSION >= 0x520

+# define BOOST_FPCLASSIFY_PREFIX ::__std_alias::

+# else

+# define BOOST_FPCLASSIFY_PREFIX ::_STLP_VENDOR_CSTD::

+# endif

+# else

+# define BOOST_FPCLASSIFY_PREFIX ::std::

+# endif

+# else

+# undef BOOST_HAS_FPCLASSIFY

+# define BOOST_FPCLASSIFY_PREFIX

+# endif

+#elif (defined(__HP_aCC) && !defined(__hppa))

+// aCC 6 appears to do "#define fpclassify fpclassify" which messes us up a bit!

+# define BOOST_FPCLASSIFY_PREFIX ::

+#else

+# define BOOST_FPCLASSIFY_PREFIX

+#endif

+

+#ifdef __MINGW32__

+# undef BOOST_HAS_FPCLASSIFY

+#endif

+

+#endif

+

+

+//------------------------------------------------------------------------------

+

+namespace boost {

+namespace math {

+namespace detail {

+

+//------------------------------------------------------------------------------

+

+/*

+The following classes are used to tag the different methods that are used

+for floating point classification

+*/

+

+struct native_tag {};

+template <bool has_limits>

+struct generic_tag {};

+struct ieee_tag {};

+struct ieee_copy_all_bits_tag : public ieee_tag {};

+struct ieee_copy_leading_bits_tag : public ieee_tag {};

+

+#ifdef BOOST_NO_LIMITS_COMPILE_TIME_CONSTANTS

+//

+// These helper functions are used only when numeric_limits<>

+// members are not compile time constants:

+//

+inline bool is_generic_tag_false(const generic_tag<false>*)

+{

+ return true;

+}

+inline bool is_generic_tag_false(const void*)

+{

+ return false;

+}

+#endif

+

+//------------------------------------------------------------------------------

+

+/*

+Most processors support three different floating point precisions:

+single precision (32 bits), double precision (64 bits)

+and extended double precision (80 - 128 bits, depending on the processor)

+

+Note that the C++ type long double can be implemented

+both as double precision and extended double precision.

+*/

+

+struct unknown_precision{};

+struct single_precision {};

+struct double_precision {};

+struct extended_double_precision {};

+

+// native_tag version --------------------------------------------------------------

+

+template<class T> struct fp_traits_native

+{

+ typedef native_tag method;

+};

+

+// generic_tag version -------------------------------------------------------------

+

+template<class T, class U> struct fp_traits_non_native

+{

+#ifndef BOOST_NO_LIMITS_COMPILE_TIME_CONSTANTS

+ typedef generic_tag<std::numeric_limits<T>::is_specialized> method;

+#else

+ typedef generic_tag<false> method;

+#endif

+};

+

+// ieee_tag versions ---------------------------------------------------------------

+

+/*

+These specializations of fp_traits_non_native contain information needed

+to "parse" the binary representation of a floating point number.

+

+Typedef members:

+

+ bits -- the target type when copying the leading bytes of a floating

+ point number. It is a typedef for uint32_t or uint64_t.

+

+ method -- tells us whether all bytes are copied or not.

+ It is a typedef for ieee_copy_all_bits_tag or ieee_copy_leading_bits_tag.

+

+Static data members:

+

+ sign, exponent, flag, significand -- bit masks that give the meaning of the

+ bits in the leading bytes.

+

+Static function members:

+

+ get_bits(), set_bits() -- provide access to the leading bytes.

+

+*/

+

+// ieee_tag version, float (32 bits) -----------------------------------------------

+

+#ifndef BOOST_FPCLASSIFY_VAX_FORMAT

+

+template<> struct fp_traits_non_native<float, single_precision>

+{

+ typedef ieee_copy_all_bits_tag method;

+

+ BOOST_STATIC_CONSTANT(uint32_t, sign = 0x80000000u);

+ BOOST_STATIC_CONSTANT(uint32_t, exponent = 0x7f800000);

+ BOOST_STATIC_CONSTANT(uint32_t, flag = 0x00000000);

+ BOOST_STATIC_CONSTANT(uint32_t, significand = 0x007fffff);

+

+ typedef uint32_t bits;

+ static void get_bits(float x, uint32_t& a) { std::memcpy(&a, &x, 4); }

+ static void set_bits(float& x, uint32_t a) { std::memcpy(&x, &a, 4); }

+};

+

+// ieee_tag version, double (64 bits) ----------------------------------------------

+

+#if defined(BOOST_NO_INT64_T) || defined(BOOST_NO_INCLASS_MEMBER_INITIALIZATION) \

+ || defined(__BORLANDC__) || defined(__CODEGEAR__)

+

+template<> struct fp_traits_non_native<double, double_precision>

+{

+ typedef ieee_copy_leading_bits_tag method;

+

+ BOOST_STATIC_CONSTANT(uint32_t, sign = 0x80000000u);

+ BOOST_STATIC_CONSTANT(uint32_t, exponent = 0x7ff00000);

+ BOOST_STATIC_CONSTANT(uint32_t, flag = 0);

+ BOOST_STATIC_CONSTANT(uint32_t, significand = 0x000fffff);

+

+ typedef uint32_t bits;

+

+ static void get_bits(double x, uint32_t& a)

+ {

+ std::memcpy(&a, reinterpret_cast<const unsigned char*>(&x) + offset_, 4);

+ }

+

+ static void set_bits(double& x, uint32_t a)

+ {

+ std::memcpy(reinterpret_cast<unsigned char*>(&x) + offset_, &a, 4);

+ }

+

+private:

+

+#if defined(BOOST_BIG_ENDIAN)

+ BOOST_STATIC_CONSTANT(int, offset_ = 0);

+#elif defined(BOOST_LITTLE_ENDIAN)

+ BOOST_STATIC_CONSTANT(int, offset_ = 4);

+#else

+ BOOST_STATIC_ASSERT(false);

+#endif

+};

+

+//..............................................................................

+

+#else

+

+template<> struct fp_traits_non_native<double, double_precision>

+{

+ typedef ieee_copy_all_bits_tag method;

+

+ static const uint64_t sign = ((uint64_t)0x80000000u) << 32;

+ static const uint64_t exponent = ((uint64_t)0x7ff00000) << 32;

+ static const uint64_t flag = 0;

+ static const uint64_t significand

+ = (((uint64_t)0x000fffff) << 32) + ((uint64_t)0xffffffffu);

+

+ typedef uint64_t bits;

+ static void get_bits(double x, uint64_t& a) { std::memcpy(&a, &x, 8); }

+ static void set_bits(double& x, uint64_t a) { std::memcpy(&x, &a, 8); }

+};

+

+#endif

+

+#endif // #ifndef BOOST_FPCLASSIFY_VAX_FORMAT

+

+// long double (64 bits) -------------------------------------------------------

+

+#if defined(BOOST_NO_INT64_T) || defined(BOOST_NO_INCLASS_MEMBER_INITIALIZATION)\

+ || defined(__BORLANDC__) || defined(__CODEGEAR__)

+

+template<> struct fp_traits_non_native<long double, double_precision>

+{

+ typedef ieee_copy_leading_bits_tag method;

+

+ BOOST_STATIC_CONSTANT(uint32_t, sign = 0x80000000u);

+ BOOST_STATIC_CONSTANT(uint32_t, exponent = 0x7ff00000);

+ BOOST_STATIC_CONSTANT(uint32_t, flag = 0);

+ BOOST_STATIC_CONSTANT(uint32_t, significand = 0x000fffff);

+

+ typedef uint32_t bits;

+

+ static void get_bits(long double x, uint32_t& a)

+ {

+ std::memcpy(&a, reinterpret_cast<const unsigned char*>(&x) + offset_, 4);

+ }

+

+ static void set_bits(long double& x, uint32_t a)

+ {

+ std::memcpy(reinterpret_cast<unsigned char*>(&x) + offset_, &a, 4);

+ }

+

+private:

+

+#if defined(BOOST_BIG_ENDIAN)

+ BOOST_STATIC_CONSTANT(int, offset_ = 0);

+#elif defined(BOOST_LITTLE_ENDIAN)

+ BOOST_STATIC_CONSTANT(int, offset_ = 4);

+#else

+ BOOST_STATIC_ASSERT(false);

+#endif

+};

+

+//..............................................................................

+

+#else

+

+template<> struct fp_traits_non_native<long double, double_precision>

+{

+ typedef ieee_copy_all_bits_tag method;

+

+ static const uint64_t sign = (uint64_t)0x80000000u << 32;

+ static const uint64_t exponent = (uint64_t)0x7ff00000 << 32;

+ static const uint64_t flag = 0;

+ static const uint64_t significand

+ = ((uint64_t)0x000fffff << 32) + (uint64_t)0xffffffffu;

+

+ typedef uint64_t bits;

+ static void get_bits(long double x, uint64_t& a) { std::memcpy(&a, &x, 8); }

+ static void set_bits(long double& x, uint64_t a) { std::memcpy(&x, &a, 8); }

+};

+

+#endif

+

+

+// long double (>64 bits), x86 and x64 -----------------------------------------

+

+#if defined(__i386) || defined(__i386__) || defined(_M_IX86) \

+ || defined(__amd64) || defined(__amd64__) || defined(_M_AMD64) \

+ || defined(__x86_64) || defined(__x86_64__) || defined(_M_X64)

+

+// Intel extended double precision format (80 bits)

+

+template<>

+struct fp_traits_non_native<long double, extended_double_precision>

+{

+ typedef ieee_copy_leading_bits_tag method;

+

+ BOOST_STATIC_CONSTANT(uint32_t, sign = 0x80000000u);

+ BOOST_STATIC_CONSTANT(uint32_t, exponent = 0x7fff0000);

+ BOOST_STATIC_CONSTANT(uint32_t, flag = 0x00008000);

+ BOOST_STATIC_CONSTANT(uint32_t, significand = 0x00007fff);

+

+ typedef uint32_t bits;

+

+ static void get_bits(long double x, uint32_t& a)

+ {

+ std::memcpy(&a, reinterpret_cast<const unsigned char*>(&x) + 6, 4);

+ }

+

+ static void set_bits(long double& x, uint32_t a)

+ {

+ std::memcpy(reinterpret_cast<unsigned char*>(&x) + 6, &a, 4);

+ }

+};

+

+

+// long double (>64 bits), Itanium ---------------------------------------------

+

+#elif defined(__ia64) || defined(__ia64__) || defined(_M_IA64)

+

+// The floating point format is unknown at compile time

+// No template specialization is provided.

+// The generic_tag definition is used.

+

+// The Itanium supports both

+// the Intel extended double precision format (80 bits) and

+// the IEEE extended double precision format with 15 exponent bits (128 bits).

+

+

+// long double (>64 bits), PowerPC ---------------------------------------------

+

+#elif defined(__powerpc) || defined(__powerpc__) || defined(__POWERPC__) \

+ || defined(__ppc) || defined(__ppc__) || defined(__PPC__)

+

+// PowerPC extended double precision format (128 bits)

+

+template<>

+struct fp_traits_non_native<long double, extended_double_precision>

+{

+ typedef ieee_copy_leading_bits_tag method;

+

+ BOOST_STATIC_CONSTANT(uint32_t, sign = 0x80000000u);

+ BOOST_STATIC_CONSTANT(uint32_t, exponent = 0x7ff00000);

+ BOOST_STATIC_CONSTANT(uint32_t, flag = 0x00000000);

+ BOOST_STATIC_CONSTANT(uint32_t, significand = 0x000fffff);

+

+ typedef uint32_t bits;

+

+ static void get_bits(long double x, uint32_t& a)

+ {

+ std::memcpy(&a, reinterpret_cast<const unsigned char*>(&x) + offset_, 4);

+ }

+

+ static void set_bits(long double& x, uint32_t a)

+ {

+ std::memcpy(reinterpret_cast<unsigned char*>(&x) + offset_, &a, 4);

+ }

+

+private:

+

+#if defined(BOOST_BIG_ENDIAN)

+ BOOST_STATIC_CONSTANT(int, offset_ = 0);

+#elif defined(BOOST_LITTLE_ENDIAN)

+ BOOST_STATIC_CONSTANT(int, offset_ = 12);

+#else

+ BOOST_STATIC_ASSERT(false);

+#endif

+};

+

+

+// long double (>64 bits), Motorola 68K ----------------------------------------

+

+#elif defined(__m68k) || defined(__m68k__) \

+ || defined(__mc68000) || defined(__mc68000__) \

+

+// Motorola extended double precision format (96 bits)

+

+// It is the same format as the Intel extended double precision format,

+// except that 1) it is big-endian, 2) the 3rd and 4th byte are padding, and

+// 3) the flag bit is not set for infinity

+

+template<>

+struct fp_traits_non_native<long double, extended_double_precision>

+{

+ typedef ieee_copy_leading_bits_tag method;

+

+ BOOST_STATIC_CONSTANT(uint32_t, sign = 0x80000000u);

+ BOOST_STATIC_CONSTANT(uint32_t, exponent = 0x7fff0000);

+ BOOST_STATIC_CONSTANT(uint32_t, flag = 0x00008000);

+ BOOST_STATIC_CONSTANT(uint32_t, significand = 0x00007fff);

+

+ // copy 1st, 2nd, 5th and 6th byte. 3rd and 4th byte are padding.

+

+ typedef uint32_t bits;

+

+ static void get_bits(long double x, uint32_t& a)

+ {

+ std::memcpy(&a, &x, 2);

+ std::memcpy(reinterpret_cast<unsigned char*>(&a) + 2,

+ reinterpret_cast<const unsigned char*>(&x) + 4, 2);

+ }

+

+ static void set_bits(long double& x, uint32_t a)

+ {

+ std::memcpy(&x, &a, 2);

+ std::memcpy(reinterpret_cast<unsigned char*>(&x) + 4,

+ reinterpret_cast<const unsigned char*>(&a) + 2, 2);

+ }

+};

+

+

+// long double (>64 bits), All other processors --------------------------------

+

+#else

+

+// IEEE extended double precision format with 15 exponent bits (128 bits)

+

+template<>

+struct fp_traits_non_native<long double, extended_double_precision>

+{

+ typedef ieee_copy_leading_bits_tag method;

+

+ BOOST_STATIC_CONSTANT(uint32_t, sign = 0x80000000u);

+ BOOST_STATIC_CONSTANT(uint32_t, exponent = 0x7fff0000);

+ BOOST_STATIC_CONSTANT(uint32_t, flag = 0x00000000);

+ BOOST_STATIC_CONSTANT(uint32_t, significand = 0x0000ffff);

+

+ typedef uint32_t bits;

+

+ static void get_bits(long double x, uint32_t& a)

+ {

+ std::memcpy(&a, reinterpret_cast<const unsigned char*>(&x) + offset_, 4);

+ }

+

+ static void set_bits(long double& x, uint32_t a)

+ {

+ std::memcpy(reinterpret_cast<unsigned char*>(&x) + offset_, &a, 4);

+ }

+

+private:

+

+#if defined(BOOST_BIG_ENDIAN)

+ BOOST_STATIC_CONSTANT(int, offset_ = 0);

+#elif defined(BOOST_LITTLE_ENDIAN)

+ BOOST_STATIC_CONSTANT(int, offset_ = 12);

+#else

+ BOOST_STATIC_ASSERT(false);

+#endif

+};

+

+#endif

+

+//------------------------------------------------------------------------------

+

+// size_to_precision is a type switch for converting a C++ floating point type

+// to the corresponding precision type.

+

+template<int n, bool fp> struct size_to_precision

+{

+ typedef unknown_precision type;

+};

+

+template<> struct size_to_precision<4, true>

+{

+ typedef single_precision type;

+};

+

+template<> struct size_to_precision<8, true>

+{

+ typedef double_precision type;

+};

+

+template<> struct size_to_precision<10, true>

+{

+ typedef extended_double_precision type;

+};

+

+template<> struct size_to_precision<12, true>

+{

+ typedef extended_double_precision type;

+};

+

+template<> struct size_to_precision<16, true>

+{

+ typedef extended_double_precision type;

+};

+

+//------------------------------------------------------------------------------

+//

+// Figure out whether to use native classification functions based on

+// whether T is a built in floating point type or not:

+//

+template <class T>

+struct select_native

+{

+ typedef BOOST_DEDUCED_TYPENAME size_to_precision<sizeof(T), ::boost::is_floating_point<T>::value>::type precision;

+ typedef fp_traits_non_native<T, precision> type;

+};

+template<>

+struct select_native<float>

+{

+ typedef fp_traits_native<float> type;

+};

+template<>

+struct select_native<double>

+{

+ typedef fp_traits_native<double> type;

+};

+template<>

+struct select_native<long double>

+{

+ typedef fp_traits_native<long double> type;

+};

+

+//------------------------------------------------------------------------------

+

+// fp_traits is a type switch that selects the right fp_traits_non_native

+

+#if (defined(BOOST_MATH_USE_C99) && !(defined(__GNUC__) && (__GNUC__ < 4))) \

+ && !defined(__hpux) \

+ && !defined(__DECCXX)\

+ && !defined(__osf__) \

+ && !defined(__SGI_STL_PORT) && !defined(_STLPORT_VERSION)\

+ && !defined(BOOST_MATH_DISABLE_STD_FPCLASSIFY)

+# define BOOST_MATH_USE_STD_FPCLASSIFY

+#endif

+

+template<class T> struct fp_traits

+{

+ typedef BOOST_DEDUCED_TYPENAME size_to_precision<sizeof(T), ::boost::is_floating_point<T>::value>::type precision;

+#if defined(BOOST_MATH_USE_STD_FPCLASSIFY) && !defined(BOOST_MATH_DISABLE_STD_FPCLASSIFY)

+ typedef typename select_native<T>::type type;

+#else

+ typedef fp_traits_non_native<T, precision> type;

+#endif

+ typedef fp_traits_non_native<T, precision> sign_change_type;

+};

+

+//------------------------------------------------------------------------------

+

+} // namespace detail

+} // namespace math

+} // namespace boost

+

+#endif

+// Copyright John Maddock 2008.

+

+// 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)

+

+#ifndef BOOST_MATH_SPECIAL_ROUND_FWD_HPP

+#define BOOST_MATH_SPECIAL_ROUND_FWD_HPP

+

+#include <boost/config.hpp>

+

+#ifdef _MSC_VER

+#pragma once

+#endif

+

+namespace boost

+{

+ namespace math

+ {

+

+ template <class T, class Policy>

+ T trunc(const T& v, const Policy& pol);

+ template <class T>

+ T trunc(const T& v);

+ template <class T, class Policy>

+ int itrunc(const T& v, const Policy& pol);

+ template <class T>

+ int itrunc(const T& v);

+ template <class T, class Policy>

+ long ltrunc(const T& v, const Policy& pol);

+ template <class T>

+ long ltrunc(const T& v);

+#ifdef BOOST_HAS_LONG_LONG

+ template <class T, class Policy>

+ boost::long_long_type lltrunc(const T& v, const Policy& pol);

+ template <class T>

+ boost::long_long_type lltrunc(const T& v);

+#endif

+ template <class T, class Policy>

+ T round(const T& v, const Policy& pol);

+ template <class T>

+ T round(const T& v);

+ template <class T, class Policy>

+ int iround(const T& v, const Policy& pol);

+ template <class T>

+ int iround(const T& v);

+ template <class T, class Policy>

+ long lround(const T& v, const Policy& pol);

+ template <class T>

+ long lround(const T& v);

+#ifdef BOOST_HAS_LONG_LONG

+ template <class T, class Policy>

+ boost::long_long_type llround(const T& v, const Policy& pol);

+ template <class T>

+ boost::long_long_type llround(const T& v);

+#endif

+ template <class T, class Policy>

+ T modf(const T& v, T* ipart, const Policy& pol);

+ template <class T>

+ T modf(const T& v, T* ipart);

+ template <class T, class Policy>

+ T modf(const T& v, int* ipart, const Policy& pol);

+ template <class T>

+ T modf(const T& v, int* ipart);

+ template <class T, class Policy>

+ T modf(const T& v, long* ipart, const Policy& pol);

+ template <class T>

+ T modf(const T& v, long* ipart);

+#ifdef BOOST_HAS_LONG_LONG

+ template <class T, class Policy>

+ T modf(const T& v, boost::long_long_type* ipart, const Policy& pol);

+ template <class T>

+ T modf(const T& v, boost::long_long_type* ipart);

+#endif

+

+ }

+}

+#endif // BOOST_MATH_SPECIAL_ROUND_FWD_HPP

+

+// Copyright John Maddock 2005-2008.

+// Copyright (c) 2006-2008 Johan Rade

+// 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)

+

+#ifndef BOOST_MATH_FPCLASSIFY_HPP

+#define BOOST_MATH_FPCLASSIFY_HPP

+

+#ifdef _MSC_VER

+#pragma once

+#endif

+

+#include <math.h>

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

+#include <boost/limits.hpp>

+#include <boost/math/tools/real_cast.hpp>

+#include <boost/type_traits/is_floating_point.hpp>

+#include <boost/math/special_functions/math_fwd.hpp>

+#include <boost/math/special_functions/detail/fp_traits.hpp>

+/*!

+ \file fpclassify.hpp

+ \brief Classify floating-point value as normal, subnormal, zero, infinite, or NaN.

+ \version 1.0

+ \author John Maddock

+ */

+

+/*

+

+1. If the platform is C99 compliant, then the native floating point

+classification functions are used. However, note that we must only

+define the functions which call std::fpclassify etc if that function

+really does exist: otherwise a compiler may reject the code even though

+the template is never instantiated.

+

+2. If the platform is not C99 compliant, and the binary format for

+a floating point type (float, double or long double) can be determined

+at compile time, then the following algorithm is used:

+

+ If all exponent bits, the flag bit (if there is one),

+ and all significand bits are 0, then the number is zero.

+

+ If all exponent bits and the flag bit (if there is one) are 0,

+ and at least one significand bit is 1, then the number is subnormal.

+

+ If all exponent bits are 1 and all significand bits are 0,

+ then the number is infinity.

+

+ If all exponent bits are 1 and at least one significand bit is 1,

+ then the number is a not-a-number.

+

+ Otherwise the number is normal.

+

+ This algorithm works for the IEEE 754 representation,

+ and also for several non IEEE 754 formats.

+

+ Most formats have the structure

+ sign bit + exponent bits + significand bits.

+

+ A few have the structure

+ sign bit + exponent bits + flag bit + significand bits.

+ The flag bit is 0 for zero and subnormal numbers,

+ and 1 for normal numbers and NaN.

+ It is 0 (Motorola 68K) or 1 (Intel) for infinity.

+

+ To get the bits, the four or eight most significant bytes are copied

+ into an uint32_t or uint64_t and bit masks are applied.

+ This covers all the exponent bits and the flag bit (if there is one),

+ but not always all the significand bits.

+ Some of the functions below have two implementations,

+ depending on whether all the significand bits are copied or not.

+

+3. If the platform is not C99 compliant, and the binary format for

+a floating point type (float, double or long double) can not be determined

+at compile time, then comparison with std::numeric_limits values

+is used.

+

+*/

+

+#if defined(_MSC_VER) || defined(__BORLANDC__)

+#include <float.h>

+#endif

+

+#ifdef BOOST_NO_STDC_NAMESPACE

+ namespace std{ using ::abs; using ::fabs; }

+#endif

+

+namespace boost{

+

+//

+// This must not be located in any namespace under boost::math

+// otherwise we can get into an infinite loop if isnan is

+// a #define for "isnan" !

+//

+namespace math_detail{

+

+template <class T>

+inline bool is_nan_helper(T t, const boost::true_type&)

+{

+#ifdef isnan

+ return isnan(t);

+#elif defined(BOOST_MATH_DISABLE_STD_FPCLASSIFY) || !defined(BOOST_HAS_FPCLASSIFY)

+ return false;

+#else // BOOST_HAS_FPCLASSIFY

+ return (BOOST_FPCLASSIFY_PREFIX fpclassify(t) == (int)FP_NAN);

+#endif

+}

+

+template <class T>

+inline bool is_nan_helper(T, const boost::false_type&)

+{

+ return false;

+}

+

+}

+

+namespace math{

+

+namespace detail{

+

+#ifdef BOOST_MATH_USE_STD_FPCLASSIFY

+template <class T>

+inline int fpclassify_imp BOOST_NO_MACRO_EXPAND(T t, const native_tag&)

+{

+ return (std::fpclassify)(t);

+}

+#endif

+

+template <class T>

+inline int fpclassify_imp BOOST_NO_MACRO_EXPAND(T t, const generic_tag<true>&)

+{

+ BOOST_MATH_INSTRUMENT_VARIABLE(t);

+

+ // whenever possible check for Nan's first:

+#if defined(BOOST_HAS_FPCLASSIFY) && !defined(BOOST_MATH_DISABLE_STD_FPCLASSIFY)

+ if(::boost::math_detail::is_nan_helper(t, ::boost::is_floating_point<T>()))

+ return FP_NAN;

+#elif defined(isnan)

+ if(boost::math_detail::is_nan_helper(t, ::boost::is_floating_point<T>()))

+ return FP_NAN;

+#elif defined(_MSC_VER) || defined(__BORLANDC__)

+ if(::_isnan(boost::math::tools::real_cast<double>(t)))

+ return FP_NAN;

+#endif

+ // std::fabs broken on a few systems especially for long long!!!!

+ T at = (t < T(0)) ? -t : t;

+

+ // Use a process of exclusion to figure out

+ // what kind of type we have, this relies on

+ // IEEE conforming reals that will treat

+ // Nan's as unordered. Some compilers

+ // don't do this once optimisations are

+ // turned on, hence the check for nan's above.

+ if(at <= (std::numeric_limits<T>::max)())

+ {

+ if(at >= (std::numeric_limits<T>::min)())

+ return FP_NORMAL;

+ return (at != 0) ? FP_SUBNORMAL : FP_ZERO;

+ }

+ else if(at > (std::numeric_limits<T>::max)())

+ return FP_INFINITE;

+ return FP_NAN;

+}

+

+template <class T>

+inline int fpclassify_imp BOOST_NO_MACRO_EXPAND(T t, const generic_tag<false>&)

+{

+#ifdef BOOST_NO_LIMITS_COMPILE_TIME_CONSTANTS

+ if(std::numeric_limits<T>::is_specialized)

+ return fpclassify_imp(t, generic_tag<true>());

+#endif

+ //

+ // An unknown type with no numeric_limits support,

+ // so what are we supposed to do we do here?

+ //

+ BOOST_MATH_INSTRUMENT_VARIABLE(t);

+

+ return t == 0 ? FP_ZERO : FP_NORMAL;

+}

+

+template<class T>

+int fpclassify_imp BOOST_NO_MACRO_EXPAND(T x, ieee_copy_all_bits_tag)

+{

+ typedef BOOST_DEDUCED_TYPENAME fp_traits<T>::type traits;

+

+ BOOST_MATH_INSTRUMENT_VARIABLE(x);

+

+ BOOST_DEDUCED_TYPENAME traits::bits a;

+ traits::get_bits(x,a);

+ BOOST_MATH_INSTRUMENT_VARIABLE(a);

+ a &= traits::exponent | traits::flag | traits::significand;

+ BOOST_MATH_INSTRUMENT_VARIABLE((traits::exponent | traits::flag | traits::significand));

+ BOOST_MATH_INSTRUMENT_VARIABLE(a);

+

+ if(a <= traits::significand) {

+ if(a == 0)

+ return FP_ZERO;

+ else

+ return FP_SUBNORMAL;

+ }

+

+ if(a < traits::exponent) return FP_NORMAL;

+

+ a &= traits::significand;

+ if(a == 0) return FP_INFINITE;

+

+ return FP_NAN;

+}

+

+template<class T>

+int fpclassify_imp BOOST_NO_MACRO_EXPAND(T x, ieee_copy_leading_bits_tag)

+{

+ typedef BOOST_DEDUCED_TYPENAME fp_traits<T>::type traits;

+

+ BOOST_MATH_INSTRUMENT_VARIABLE(x);

+

+ BOOST_DEDUCED_TYPENAME traits::bits a;

+ traits::get_bits(x,a);

+ a &= traits::exponent | traits::flag | traits::significand;

+

+ if(a <= traits::significand) {

+ if(x == 0)

+ return FP_ZERO;

+ else

+ return FP_SUBNORMAL;

+ }

+

+ if(a < traits::exponent) return FP_NORMAL;

+

+ a &= traits::significand;

+ traits::set_bits(x,a);

+ if(x == 0) return FP_INFINITE;

+

+ return FP_NAN;

+}

+

+#if defined(BOOST_MATH_USE_STD_FPCLASSIFY) && defined(BOOST_MATH_NO_NATIVE_LONG_DOUBLE_FP_CLASSIFY)

+template <>

+inline int fpclassify_imp<long double> BOOST_NO_MACRO_EXPAND(long double t, const native_tag&)

+{

+ return boost::math::detail::fpclassify_imp(t, generic_tag<true>());

+}

+#endif

+

+} // namespace detail

+

+template <class T>

+inline int fpclassify BOOST_NO_MACRO_EXPAND(T t)

+{

+ typedef typename detail::fp_traits<T>::type traits;

+ typedef typename traits::method method;

+ typedef typename tools::promote_args<T>::type value_type;

+#ifdef BOOST_NO_LIMITS_COMPILE_TIME_CONSTANTS

+ if(std::numeric_limits<T>::is_specialized && detail::is_generic_tag_false(static_cast<method*>(0)))

+ return detail::fpclassify_imp(static_cast<value_type>(t), detail::generic_tag<true>());

+ return detail::fpclassify_imp(static_cast<value_type>(t), method());

+#else

+ return detail::fpclassify_imp(static_cast<value_type>(t), method());

+#endif

+}

+

+namespace detail {

+

+#ifdef BOOST_MATH_USE_STD_FPCLASSIFY

+ template<class T>

+ inline bool isfinite_impl(T x, native_tag const&)

+ {

+ return (std::isfinite)(x);

+ }

+#endif

+

+ template<class T>

+ inline bool isfinite_impl(T x, generic_tag<true> const&)

+ {

+ return x >= -(std::numeric_limits<T>::max)()

+ && x <= (std::numeric_limits<T>::max)();

+ }

+

+ template<class T>

+ inline bool isfinite_impl(T x, generic_tag<false> const&)

+ {

+#ifdef BOOST_NO_LIMITS_COMPILE_TIME_CONSTANTS

+ if(std::numeric_limits<T>::is_specialized)

+ return isfinite_impl(x, generic_tag<true>());

+#endif

+ (void)x; // warning supression.

+ return true;

+ }

+

+ template<class T>

+ inline bool isfinite_impl(T x, ieee_tag const&)

+ {

+ typedef BOOST_DEDUCED_TYPENAME detail::fp_traits<T>::type traits;

+ BOOST_DEDUCED_TYPENAME traits::bits a;

+ traits::get_bits(x,a);

+ a &= traits::exponent;

+ return a != traits::exponent;

+ }

+

+#if defined(BOOST_MATH_USE_STD_FPCLASSIFY) && defined(BOOST_MATH_NO_NATIVE_LONG_DOUBLE_FP_CLASSIFY)

+template <>

+inline bool isfinite_impl<long double> BOOST_NO_MACRO_EXPAND(long double t, const native_tag&)

+{

+ return boost::math::detail::isfinite_impl(t, generic_tag<true>());

+}

+#endif

+

+}

+

+template<class T>

+inline bool (isfinite)(T x)

+{ //!< \brief return true if floating-point type t is finite.

+ typedef typename detail::fp_traits<T>::type traits;

+ typedef typename traits::method method;

+ typedef typename boost::is_floating_point<T>::type fp_tag;

+ typedef typename tools::promote_args<T>::type value_type;

+ return detail::isfinite_impl(static_cast<value_type>(x), method());

+}

+

+//------------------------------------------------------------------------------

+

+namespace detail {

+

+#ifdef BOOST_MATH_USE_STD_FPCLASSIFY

+ template<class T>

+ inline bool isnormal_impl(T x, native_tag const&)

+ {

+ return (std::isnormal)(x);

+ }

+#endif

+

+ template<class T>

+ inline bool isnormal_impl(T x, generic_tag<true> const&)

+ {

+ if(x < 0) x = -x;

+ return x >= (std::numeric_limits<T>::min)()

+ && x <= (std::numeric_limits<T>::max)();

+ }

+

+ template<class T>

+ inline bool isnormal_impl(T x, generic_tag<false> const&)

+ {

+#ifdef BOOST_NO_LIMITS_COMPILE_TIME_CONSTANTS

+ if(std::numeric_limits<T>::is_specialized)

+ return isnormal_impl(x, generic_tag<true>());

+#endif

+ return !(x == 0);

+ }

+

+ template<class T>

+ inline bool isnormal_impl(T x, ieee_tag const&)

+ {

+ typedef BOOST_DEDUCED_TYPENAME detail::fp_traits<T>::type traits;

+ BOOST_DEDUCED_TYPENAME traits::bits a;

+ traits::get_bits(x,a);

+ a &= traits::exponent | traits::flag;

+ return (a != 0) && (a < traits::exponent);

+ }

+

+#if defined(BOOST_MATH_USE_STD_FPCLASSIFY) && defined(BOOST_MATH_NO_NATIVE_LONG_DOUBLE_FP_CLASSIFY)

+template <>

+inline bool isnormal_impl<long double> BOOST_NO_MACRO_EXPAND(long double t, const native_tag&)

+{

+ return boost::math::detail::isnormal_impl(t, generic_tag<true>());

+}

+#endif

+

+}

+

+template<class T>

+inline bool (isnormal)(T x)

+{

+ typedef typename detail::fp_traits<T>::type traits;

+ typedef typename traits::method method;

+ typedef typename boost::is_floating_point<T>::type fp_tag;

+ typedef typename tools::promote_args<T>::type value_type;

+ return detail::isnormal_impl(static_cast<value_type>(x), method());

+}

+

+//------------------------------------------------------------------------------

+

+namespace detail {

+

+#ifdef BOOST_MATH_USE_STD_FPCLASSIFY

+ template<class T>

+ inline bool isinf_impl(T x, native_tag const&)

+ {

+ return (std::isinf)(x);

+ }

+#endif

+

+ template<class T>

+ inline bool isinf_impl(T x, generic_tag<true> const&)

+ {

+ (void)x; // in case the compiler thinks that x is unused because std::numeric_limits<T>::has_infinity is false

+ return std::numeric_limits<T>::has_infinity

+ && ( x == std::numeric_limits<T>::infinity()

+ || x == -std::numeric_limits<T>::infinity());

+ }

+

+ template<class T>

+ inline bool isinf_impl(T x, generic_tag<false> const&)

+ {

+#ifdef BOOST_NO_LIMITS_COMPILE_TIME_CONSTANTS

+ if(std::numeric_limits<T>::is_specialized)

+ return isinf_impl(x, generic_tag<true>());

+#endif

+ (void)x; // warning supression.

+ return false;

+ }

+

+ template<class T>

+ inline bool isinf_impl(T x, ieee_copy_all_bits_tag const&)

+ {

+ typedef BOOST_DEDUCED_TYPENAME fp_traits<T>::type traits;

+

+ BOOST_DEDUCED_TYPENAME traits::bits a;

+ traits::get_bits(x,a);

+ a &= traits::exponent | traits::significand;

+ return a == traits::exponent;

+ }

+

+ template<class T>

+ inline bool isinf_impl(T x, ieee_copy_leading_bits_tag const&)

+ {

+ typedef BOOST_DEDUCED_TYPENAME fp_traits<T>::type traits;

+

+ BOOST_DEDUCED_TYPENAME traits::bits a;

+ traits::get_bits(x,a);

+ a &= traits::exponent | traits::significand;

+ if(a != traits::exponent)

+ return false;

+

+ traits::set_bits(x,0);

+ return x == 0;

+ }

+

+#if defined(BOOST_MATH_USE_STD_FPCLASSIFY) && defined(BOOST_MATH_NO_NATIVE_LONG_DOUBLE_FP_CLASSIFY)

+template <>

+inline bool isinf_impl<long double> BOOST_NO_MACRO_EXPAND(long double t, const native_tag&)

+{

+ return boost::math::detail::isinf_impl(t, generic_tag<true>());

+}

+#endif

+

+} // namespace detail

+

+template<class T>

+inline bool (isinf)(T x)

+{

+ typedef typename detail::fp_traits<T>::type traits;

+ typedef typename traits::method method;

+ typedef typename boost::is_floating_point<T>::type fp_tag;

+ typedef typename tools::promote_args<T>::type value_type;

+ return detail::isinf_impl(static_cast<value_type>(x), method());

+}

+

+//------------------------------------------------------------------------------

+

+namespace detail {

+

+#ifdef BOOST_MATH_USE_STD_FPCLASSIFY

+ template<class T>

+ inline bool isnan_impl(T x, native_tag const&)

+ {

+ return (std::isnan)(x);

+ }

+#endif

+

+ template<class T>

+ inline bool isnan_impl(T x, generic_tag<true> const&)

+ {

+ return std::numeric_limits<T>::has_infinity

+ ? !(x <= std::numeric_limits<T>::infinity())

+ : x != x;

+ }

+

+ template<class T>

+ inline bool isnan_impl(T x, generic_tag<false> const&)

+ {

+#ifdef BOOST_NO_LIMITS_COMPILE_TIME_CONSTANTS

+ if(std::numeric_limits<T>::is_specialized)

+ return isnan_impl(x, generic_tag<true>());

+#endif

+ (void)x; // warning supression

+ return false;

+ }

+

+ template<class T>

+ inline bool isnan_impl(T x, ieee_copy_all_bits_tag const&)

+ {

+ typedef BOOST_DEDUCED_TYPENAME fp_traits<T>::type traits;

+

+ BOOST_DEDUCED_TYPENAME traits::bits a;

+ traits::get_bits(x,a);

+ a &= traits::exponent | traits::significand;

+ return a > traits::exponent;

+ }

+

+ template<class T>

+ inline bool isnan_impl(T x, ieee_copy_leading_bits_tag const&)

+ {

+ typedef BOOST_DEDUCED_TYPENAME fp_traits<T>::type traits;

+

+ BOOST_DEDUCED_TYPENAME traits::bits a;

+ traits::get_bits(x,a);

+

+ a &= traits::exponent | traits::significand;

+ if(a < traits::exponent)

+ return false;

+

+ a &= traits::significand;

+ traits::set_bits(x,a);

+ return x != 0;

+ }

+

+} // namespace detail

+

+template<class T> bool (isnan)(T x)

+{ //!< \brief return true if floating-point type t is NaN (Not A Number).

+ typedef typename detail::fp_traits<T>::type traits;

+ typedef typename traits::method method;

+ typedef typename boost::is_floating_point<T>::type fp_tag;

+ return detail::isnan_impl(x, method());

+}

+

+#ifdef isnan

+template <> inline bool isnan BOOST_NO_MACRO_EXPAND<float>(float t){ return ::boost::math_detail::is_nan_helper(t, boost::true_type()); }

+template <> inline bool isnan BOOST_NO_MACRO_EXPAND<double>(double t){ return ::boost::math_detail::is_nan_helper(t, boost::true_type()); }

+template <> inline bool isnan BOOST_NO_MACRO_EXPAND<long double>(long double t){ return ::boost::math_detail::is_nan_helper(t, boost::true_type()); }

+#endif

+

+} // namespace math

+} // namespace boost

+

+#endif // BOOST_MATH_FPCLASSIFY_HPP

+

+// math_fwd.hpp

+

+// TODO revise completely for new distribution classes.

+

+// Copyright Paul A. Bristow 2006.

+// 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)

+

+// Omnibus list of forward declarations of math special functions.

+

+// IT = Integer type.

+// RT = Real type (built-in floating-point types, float, double, long double) & User Defined Types

+// AT = Integer or Real type

+

+#ifndef BOOST_MATH_SPECIAL_MATH_FWD_HPP

+#define BOOST_MATH_SPECIAL_MATH_FWD_HPP

+

+#ifdef _MSC_VER

+#pragma once

+#endif

+

+#include <boost/math/special_functions/detail/round_fwd.hpp>

+#include <boost/math/tools/promotion.hpp> // for argument promotion.

+#include <boost/math/policies/policy.hpp>

+#include <boost/mpl/comparison.hpp>

+#include <boost/config/no_tr1/complex.hpp>

+

+#define BOOST_NO_MACRO_EXPAND /**/

+

+namespace boost

+{

+ namespace math

+ { // Math functions (in roughly alphabetic order).

+

+ // Beta functions.

+ template <class RT1, class RT2>

+ typename tools::promote_args<RT1, RT2>::type

+ beta(RT1 a, RT2 b); // Beta function (2 arguments).

+

+ template <class RT1, class RT2, class A>

+ typename tools::promote_args<RT1, RT2, A>::type

+ beta(RT1 a, RT2 b, A x); // Beta function (3 arguments).

+

+ template <class RT1, class RT2, class RT3, class Policy>

+ typename tools::promote_args<RT1, RT2, RT3>::type

+ beta(RT1 a, RT2 b, RT3 x, const Policy& pol); // Beta function (3 arguments).

+

+ template <class RT1, class RT2, class RT3>

+ typename tools::promote_args<RT1, RT2, RT3>::type

+ betac(RT1 a, RT2 b, RT3 x);

+

+ template <class RT1, class RT2, class RT3, class Policy>

+ typename tools::promote_args<RT1, RT2, RT3>::type

+ betac(RT1 a, RT2 b, RT3 x, const Policy& pol);

+

+ template <class RT1, class RT2, class RT3>

+ typename tools::promote_args<RT1, RT2, RT3>::type

+ ibeta(RT1 a, RT2 b, RT3 x); // Incomplete beta function.

+

+ template <class RT1, class RT2, class RT3, class Policy>

+ typename tools::promote_args<RT1, RT2, RT3>::type

+ ibeta(RT1 a, RT2 b, RT3 x, const Policy& pol); // Incomplete beta function.

+

+ template <class RT1, class RT2, class RT3>

+ typename tools::promote_args<RT1, RT2, RT3>::type

+ ibetac(RT1 a, RT2 b, RT3 x); // Incomplete beta complement function.

+

+ template <class RT1, class RT2, class RT3, class Policy>

+ typename tools::promote_args<RT1, RT2, RT3>::type

+ ibetac(RT1 a, RT2 b, RT3 x, const Policy& pol); // Incomplete beta complement function.

+

+ template <class T1, class T2, class T3, class T4>

+ typename tools::promote_args<T1, T2, T3, T4>::type

+ ibeta_inv(T1 a, T2 b, T3 p, T4* py);

+

+ template <class T1, class T2, class T3, class T4, class Policy>

+ typename tools::promote_args<T1, T2, T3, T4>::type

+ ibeta_inv(T1 a, T2 b, T3 p, T4* py, const Policy& pol);

+

+ template <class RT1, class RT2, class RT3>

+ typename tools::promote_args<RT1, RT2, RT3>::type

+ ibeta_inv(RT1 a, RT2 b, RT3 p); // Incomplete beta inverse function.

+

+ template <class RT1, class RT2, class RT3, class Policy>

+ typename tools::promote_args<RT1, RT2, RT3>::type

+ ibeta_inv(RT1 a, RT2 b, RT3 p, const Policy&); // Incomplete beta inverse function.

+

+ template <class RT1, class RT2, class RT3>

+ typename tools::promote_args<RT1, RT2, RT3>::type

+ ibeta_inva(RT1 a, RT2 b, RT3 p); // Incomplete beta inverse function.

+

+ template <class RT1, class RT2, class RT3, class Policy>

+ typename tools::promote_args<RT1, RT2, RT3>::type

+ ibeta_inva(RT1 a, RT2 b, RT3 p, const Policy&); // Incomplete beta inverse function.

+

+ template <class RT1, class RT2, class RT3>

+ typename tools::promote_args<RT1, RT2, RT3>::type

+ ibeta_invb(RT1 a, RT2 b, RT3 p); // Incomplete beta inverse function.

+

+ template <class RT1, class RT2, class RT3, class Policy>

+ typename tools::promote_args<RT1, RT2, RT3>::type

+ ibeta_invb(RT1 a, RT2 b, RT3 p, const Policy&); // Incomplete beta inverse function.

+

+ template <class T1, class T2, class T3, class T4>

+ typename tools::promote_args<T1, T2, T3, T4>::type

+ ibetac_inv(T1 a, T2 b, T3 q, T4* py);

+

+ template <class T1, class T2, class T3, class T4, class Policy>

+ typename tools::promote_args<T1, T2, T3, T4>::type

+ ibetac_inv(T1 a, T2 b, T3 q, T4* py, const Policy& pol);

+

+ template <class RT1, class RT2, class RT3>

+ typename tools::promote_args<RT1, RT2, RT3>::type

+ ibetac_inv(RT1 a, RT2 b, RT3 q); // Incomplete beta complement inverse function.

+

+ template <class RT1, class RT2, class RT3, class Policy>

+ typename tools::promote_args<RT1, RT2, RT3>::type

+ ibetac_inv(RT1 a, RT2 b, RT3 q, const Policy&); // Incomplete beta complement inverse function.

+

+ template <class RT1, class RT2, class RT3>

+ typename tools::promote_args<RT1, RT2, RT3>::type

+ ibetac_inva(RT1 a, RT2 b, RT3 q); // Incomplete beta complement inverse function.

+

+ template <class RT1, class RT2, class RT3, class Policy>

+ typename tools::promote_args<RT1, RT2, RT3>::type

+ ibetac_inva(RT1 a, RT2 b, RT3 q, const Policy&); // Incomplete beta complement inverse function.

+

+ template <class RT1, class RT2, class RT3>

+ typename tools::promote_args<RT1, RT2, RT3>::type

+ ibetac_invb(RT1 a, RT2 b, RT3 q); // Incomplete beta complement inverse function.

+

+ template <class RT1, class RT2, class RT3, class Policy>

+ typename tools::promote_args<RT1, RT2, RT3>::type

+ ibetac_invb(RT1 a, RT2 b, RT3 q, const Policy&); // Incomplete beta complement inverse function.

+

+ template <class RT1, class RT2, class RT3>

+ typename tools::promote_args<RT1, RT2, RT3>::type

+ ibeta_derivative(RT1 a, RT2 b, RT3 x); // derivative of incomplete beta

+

+ template <class RT1, class RT2, class RT3, class Policy>

+ typename tools::promote_args<RT1, RT2, RT3>::type

+ ibeta_derivative(RT1 a, RT2 b, RT3 x, const Policy& pol); // derivative of incomplete beta

+

+ // erf & erfc error functions.

+ template <class RT> // Error function.

+ typename tools::promote_args<RT>::type erf(RT z);

+ template <class RT, class Policy> // Error function.

+ typename tools::promote_args<RT>::type erf(RT z, const Policy&);

+

+ template <class RT>// Error function complement.

+ typename tools::promote_args<RT>::type erfc(RT z);

+ template <class RT, class Policy>// Error function complement.

+ typename tools::promote_args<RT>::type erfc(RT z, const Policy&);

+

+ template <class RT>// Error function inverse.

+ typename tools::promote_args<RT>::type erf_inv(RT z);

+ template <class RT, class Policy>// Error function inverse.

+ typename tools::promote_args<RT>::type erf_inv(RT z, const Policy& pol);

+

+ template <class RT>// Error function complement inverse.

+ typename tools::promote_args<RT>::type erfc_inv(RT z);

+ template <class RT, class Policy>// Error function complement inverse.

+ typename tools::promote_args<RT>::type erfc_inv(RT z, const Policy& pol);

+

+ // Polynomials:

+ template <class T1, class T2, class T3>

+ typename tools::promote_args<T1, T2, T3>::type

+ legendre_next(unsigned l, T1 x, T2 Pl, T3 Plm1);

+

+ template <class T>

+ typename tools::promote_args<T>::type

+ legendre_p(int l, T x);

+

+ template <class T, class Policy>

+ typename tools::promote_args<T>::type

+ legendre_p(int l, T x, const Policy& pol);

+

+ template <class T>

+ typename tools::promote_args<T>::type

+ legendre_q(unsigned l, T x);

+

+ template <class T, class Policy>

+ typename tools::promote_args<T>::type

+ legendre_q(unsigned l, T x, const Policy& pol);

+

+ template <class T1, class T2, class T3>

+ typename tools::promote_args<T1, T2, T3>::type

+ legendre_next(unsigned l, unsigned m, T1 x, T2 Pl, T3 Plm1);

+

+ template <class T>

+ typename tools::promote_args<T>::type

+ legendre_p(int l, int m, T x);

+

+ template <class T, class Policy>

+ typename tools::promote_args<T>::type

+ legendre_p(int l, int m, T x, const Policy& pol);

+

+ template <class T1, class T2, class T3>

+ typename tools::promote_args<T1, T2, T3>::type

+ laguerre_next(unsigned n, T1 x, T2 Ln, T3 Lnm1);

+

+ template <class T1, class T2, class T3>

+ typename tools::promote_args<T1, T2, T3>::type

+ laguerre_next(unsigned n, unsigned l, T1 x, T2 Pl, T3 Plm1);

+

+ template <class T>

+ typename tools::promote_args<T>::type

+ laguerre(unsigned n, T x);

+

+ template <class T, class Policy>

+ typename tools::promote_args<T>::type

+ laguerre(unsigned n, unsigned m, T x, const Policy& pol);

+

+ template <class T1, class T2>

+ struct laguerre_result

+ {

+ typedef typename mpl::if_<

+ policies::is_policy<T2>,

+ typename tools::promote_args<T1>::type,

+ typename tools::promote_args<T2>::type

+ >::type type;

+ };

+

+ template <class T1, class T2>

+ typename laguerre_result<T1, T2>::type

+ laguerre(unsigned n, T1 m, T2 x);

+

+ template <class T>

+ typename tools::promote_args<T>::type

+ hermite(unsigned n, T x);

+

+ template <class T, class Policy>

+ typename tools::promote_args<T>::type

+ hermite(unsigned n, T x, const Policy& pol);

+

+ template <class T1, class T2, class T3>

+ typename tools::promote_args<T1, T2, T3>::type

+ hermite_next(unsigned n, T1 x, T2 Hn, T3 Hnm1);

+

+ template <class T1, class T2>

+ std::complex<typename tools::promote_args<T1, T2>::type>

+ spherical_harmonic(unsigned n, int m, T1 theta, T2 phi);

+

+ template <class T1, class T2, class Policy>

+ std::complex<typename tools::promote_args<T1, T2>::type>

+ spherical_harmonic(unsigned n, int m, T1 theta, T2 phi, const Policy& pol);

+

+ template <class T1, class T2>

+ typename tools::promote_args<T1, T2>::type

+ spherical_harmonic_r(unsigned n, int m, T1 theta, T2 phi);

+

+ template <class T1, class T2, class Policy>

+ typename tools::promote_args<T1, T2>::type

+ spherical_harmonic_r(unsigned n, int m, T1 theta, T2 phi, const Policy& pol);

+

+ template <class T1, class T2>

+ typename tools::promote_args<T1, T2>::type

+ spherical_harmonic_i(unsigned n, int m, T1 theta, T2 phi);

+

+ template <class T1, class T2, class Policy>

+ typename tools::promote_args<T1, T2>::type

+ spherical_harmonic_i(unsigned n, int m, T1 theta, T2 phi, const Policy& pol);

+

+ // Elliptic integrals:

+ template <class T1, class T2, class T3>

+ typename tools::promote_args<T1, T2, T3>::type

+ ellint_rf(T1 x, T2 y, T3 z);

+

+ template <class T1, class T2, class T3, class Policy>

+ typename tools::promote_args<T1, T2, T3>::type

+ ellint_rf(T1 x, T2 y, T3 z, const Policy& pol);

+

+ template <class T1, class T2, class T3>

+ typename tools::promote_args<T1, T2, T3>::type

+ ellint_rd(T1 x, T2 y, T3 z);

+

+ template <class T1, class T2, class T3, class Policy>

+ typename tools::promote_args<T1, T2, T3>::type

+ ellint_rd(T1 x, T2 y, T3 z, const Policy& pol);

+

+ template <class T1, class T2>

+ typename tools::promote_args<T1, T2>::type

+ ellint_rc(T1 x, T2 y);

+

+ template <class T1, class T2, class Policy>

+ typename tools::promote_args<T1, T2>::type

+ ellint_rc(T1 x, T2 y, const Policy& pol);

+

+ template <class T1, class T2, class T3, class T4>

+ typename tools::promote_args<T1, T2, T3, T4>::type

+ ellint_rj(T1 x, T2 y, T3 z, T4 p);

+

+ template <class T1, class T2, class T3, class T4, class Policy>

+ typename tools::promote_args<T1, T2, T3, T4>::type

+ ellint_rj(T1 x, T2 y, T3 z, T4 p, const Policy& pol);

+

+ template <typename T>

+ typename tools::promote_args<T>::type ellint_2(T k);

+

+ template <class T1, class T2>

+ typename tools::promote_args<T1, T2>::type ellint_2(T1 k, T2 phi);

+

+ template <class T1, class T2, class Policy>

+ typename tools::promote_args<T1, T2>::type ellint_2(T1 k, T2 phi, const Policy& pol);

+

+ template <typename T>

+ typename tools::promote_args<T>::type ellint_1(T k);

+

+ template <class T1, class T2>

+ typename tools::promote_args<T1, T2>::type ellint_1(T1 k, T2 phi);

+

+ template <class T1, class T2, class Policy>

+ typename tools::promote_args<T1, T2>::type ellint_1(T1 k, T2 phi, const Policy& pol);

+

+ namespace detail{

+

+ template <class T, class U, class V>

+ struct ellint_3_result

+ {

+ typedef typename mpl::if_<

+ policies::is_policy<V>,

+ typename tools::promote_args<T, U>::type,

+ typename tools::promote_args<T, U, V>::type

+ >::type type;

+ };

+

+ } // namespace detail

+

+

+ template <class T1, class T2, class T3>

+ typename detail::ellint_3_result<T1, T2, T3>::type ellint_3(T1 k, T2 v, T3 phi);

+

+ template <class T1, class T2, class T3, class Policy>

+ typename tools::promote_args<T1, T2, T3>::type ellint_3(T1 k, T2 v, T3 phi, const Policy& pol);

+

+ template <class T1, class T2>

+ typename tools::promote_args<T1, T2>::type ellint_3(T1 k, T2 v);

+

+ // Factorial functions.

+ // Note: not for integral types, at present.

+ template <class RT>

+ struct max_factorial;

+ template <class RT>

+ RT factorial(unsigned int);

+ template <class RT, class Policy>

+ RT factorial(unsigned int, const Policy& pol);

+ template <class RT>

+ RT unchecked_factorial(unsigned int BOOST_MATH_APPEND_EXPLICIT_TEMPLATE_TYPE(RT));

+ template <class RT>

+ RT double_factorial(unsigned i);

+ template <class RT, class Policy>

+ RT double_factorial(unsigned i, const Policy& pol);

+

+ template <class RT>

+ typename tools::promote_args<RT>::type falling_factorial(RT x, unsigned n);

+

+ template <class RT, class Policy>

+ typename tools::promote_args<RT>::type falling_factorial(RT x, unsigned n, const Policy& pol);

+

+ template <class RT>

+ typename tools::promote_args<RT>::type rising_factorial(RT x, int n);

+

+ template <class RT, class Policy>

+ typename tools::promote_args<RT>::type rising_factorial(RT x, int n, const Policy& pol);

+

+ // Gamma functions.

+ template <class RT>

+ typename tools::promote_args<RT>::type tgamma(RT z);

+

+ template <class RT>

+ typename tools::promote_args<RT>::type tgamma1pm1(RT z);

+

+ template <class RT, class Policy>

+ typename tools::promote_args<RT>::type tgamma1pm1(RT z, const Policy& pol);

+

+ template <class RT1, class RT2>

+ typename tools::promote_args<RT1, RT2>::type tgamma(RT1 a, RT2 z);

+

+ template <class RT1, class RT2, class Policy>

+ typename tools::promote_args<RT1, RT2>::type tgamma(RT1 a, RT2 z, const Policy& pol);

+

+ template <class RT>

+ typename tools::promote_args<RT>::type lgamma(RT z, int* sign);

+

+ template <class RT, class Policy>

+ typename tools::promote_args<RT>::type lgamma(RT z, int* sign, const Policy& pol);

+

+ template <class RT>

+ typename tools::promote_args<RT>::type lgamma(RT x);

+

+ template <class RT, class Policy>

+ typename tools::promote_args<RT>::type lgamma(RT x, const Policy& pol);

+

+ template <class RT1, class RT2>

+ typename tools::promote_args<RT1, RT2>::type tgamma_lower(RT1 a, RT2 z);

+

+ template <class RT1, class RT2, class Policy>

+ typename tools::promote_args<RT1, RT2>::type tgamma_lower(RT1 a, RT2 z, const Policy&);

+

+ template <class RT1, class RT2>

+ typename tools::promote_args<RT1, RT2>::type gamma_q(RT1 a, RT2 z);

+

+ template <class RT1, class RT2, class Policy>

+ typename tools::promote_args<RT1, RT2>::type gamma_q(RT1 a, RT2 z, const Policy&);

+

+ template <class RT1, class RT2>

+ typename tools::promote_args<RT1, RT2>::type gamma_p(RT1 a, RT2 z);

+

+ template <class RT1, class RT2, class Policy>

+ typename tools::promote_args<RT1, RT2>::type gamma_p(RT1 a, RT2 z, const Policy&);

+

+ template <class T1, class T2>

+ typename tools::promote_args<T1, T2>::type tgamma_delta_ratio(T1 z, T2 delta);

+

+ template <class T1, class T2, class Policy>

+ typename tools::promote_args<T1, T2>::type tgamma_delta_ratio(T1 z, T2 delta, const Policy&);

+

+ template <class T1, class T2>

+ typename tools::promote_args<T1, T2>::type tgamma_ratio(T1 a, T2 b);

+

+ template <class T1, class T2, class Policy>

+ typename tools::promote_args<T1, T2>::type tgamma_ratio(T1 a, T2 b, const Policy&);

+

+ template <class T1, class T2>

+ typename tools::promote_args<T1, T2>::type gamma_p_derivative(T1 a, T2 x);

+

+ template <class T1, class T2, class Policy>

+ typename tools::promote_args<T1, T2>::type gamma_p_derivative(T1 a, T2 x, const Policy&);

+

+ // gamma inverse.

+ template <class T1, class T2>

+ typename tools::promote_args<T1, T2>::type gamma_p_inv(T1 a, T2 p);

+

+ template <class T1, class T2, class Policy>

+ typename tools::promote_args<T1, T2>::type gamma_p_inva(T1 a, T2 p, const Policy&);

+

+ template <class T1, class T2>

+ typename tools::promote_args<T1, T2>::type gamma_p_inva(T1 a, T2 p);

+

+ template <class T1, class T2, class Policy>

+ typename tools::promote_args<T1, T2>::type gamma_p_inv(T1 a, T2 p, const Policy&);

+

+ template <class T1, class T2>

+ typename tools::promote_args<T1, T2>::type gamma_q_inv(T1 a, T2 q);

+

+ template <class T1, class T2, class Policy>

+ typename tools::promote_args<T1, T2>::type gamma_q_inv(T1 a, T2 q, const Policy&);

+

+ template <class T1, class T2>

+ typename tools::promote_args<T1, T2>::type gamma_q_inva(T1 a, T2 q);

+

+ template <class T1, class T2, class Policy>

+ typename tools::promote_args<T1, T2>::type gamma_q_inva(T1 a, T2 q, const Policy&);

+

+ // digamma:

+ template <class T>

+ typename tools::promote_args<T>::type digamma(T x);

+

+ template <class T, class Policy>

+ typename tools::promote_args<T>::type digamma(T x, const Policy&);

+

+ // Hypotenuse function sqrt(x ^ 2 + y ^ 2).

+ template <class T1, class T2>

+ typename tools::promote_args<T1, T2>::type

+ hypot(T1 x, T2 y);

+

+ template <class T1, class T2, class Policy>

+ typename tools::promote_args<T1, T2>::type

+ hypot(T1 x, T2 y, const Policy&);

+

+ // cbrt - cube root.

+ template <class RT>

+ typename tools::promote_args<RT>::type cbrt(RT z);

+

+ template <class RT, class Policy>

+ typename tools::promote_args<RT>::type cbrt(RT z, const Policy&);

+

+ // log1p is log(x + 1)

+ template <class T>

+ typename tools::promote_args<T>::type log1p(T);

+

+ template <class T, class Policy>

+ typename tools::promote_args<T>::type log1p(T, const Policy&);

+

+ // log1pmx is log(x + 1) - x

+ template <class T>

+ typename tools::promote_args<T>::type log1pmx(T);

+

+ template <class T, class Policy>

+ typename tools::promote_args<T>::type log1pmx(T, const Policy&);

+

+ // Exp (x) minus 1 functions.

+ template <class T>

+ typename tools::promote_args<T>::type expm1(T);

+

+ template <class T, class Policy>

+ typename tools::promote_args<T>::type expm1(T, const Policy&);

+

+ // Power - 1

+ template <class T1, class T2>

+ typename tools::promote_args<T1, T2>::type

+ powm1(const T1 a, const T2 z);

+

+ template <class T1, class T2, class Policy>

+ typename tools::promote_args<T1, T2>::type

+ powm1(const T1 a, const T2 z, const Policy&);

+

+ // sqrt(1+x) - 1

+ template <class T>

+ typename tools::promote_args<T>::type sqrt1pm1(const T& val);

+

+ template <class T, class Policy>

+ typename tools::promote_args<T>::type sqrt1pm1(const T& val, const Policy&);

+

+ // sinus cardinals:

+ template <class T>

+ typename tools::promote_args<T>::type sinc_pi(T x);

+

+ template <class T, class Policy>

+ typename tools::promote_args<T>::type sinc_pi(T x, const Policy&);

+

+ template <class T>

+ typename tools::promote_args<T>::type sinhc_pi(T x);

+

+ template <class T, class Policy>

+ typename tools::promote_args<T>::type sinhc_pi(T x, const Policy&);

+

+ // inverse hyperbolics:

+ template<typename T>

+ typename tools::promote_args<T>::type asinh(T x);

+

+ template<typename T, class Policy>

+ typename tools::promote_args<T>::type asinh(T x, const Policy&);

+

+ template<typename T>

+ typename tools::promote_args<T>::type acosh(T x);

+

+ template<typename T, class Policy>

+ typename tools::promote_args<T>::type acosh(T x, const Policy&);

+

+ template<typename T>

+ typename tools::promote_args<T>::type atanh(T x);

+

+ template<typename T, class Policy>

+ typename tools::promote_args<T>::type atanh(T x, const Policy&);

+

+ namespace detail{

+

+ typedef mpl::int_<0> bessel_no_int_tag; // No integer optimisation possible.

+ typedef mpl::int_<1> bessel_maybe_int_tag; // Maybe integer optimisation.

+ typedef mpl::int_<2> bessel_int_tag; // Definite integer optimistaion.

+

+ template <class T1, class T2, class Policy>

+ struct bessel_traits

+ {

+ typedef typename tools::promote_args<

+ T1, T2

+ >::type result_type;

+

+ typedef typename policies::precision<result_type, Policy>::type precision_type;

+

+ typedef typename mpl::if_<

+ mpl::or_<

+ mpl::less_equal<precision_type, mpl::int_<0> >,

+ mpl::greater<precision_type, mpl::int_<64> > >,

+ bessel_no_int_tag,

+ typename mpl::if_<

+ is_integral<T1>,

+ bessel_int_tag,

+ bessel_maybe_int_tag

+ >::type

+ >::type optimisation_tag;

+ };

+ } // detail

+

+ // Bessel functions:

+ template <class T1, class T2, class Policy>

+ typename detail::bessel_traits<T1, T2, Policy>::result_type cyl_bessel_j(T1 v, T2 x, const Policy& pol);

+

+ template <class T1, class T2>

+ typename detail::bessel_traits<T1, T2, policies::policy<> >::result_type cyl_bessel_j(T1 v, T2 x);

+

+ template <class T, class Policy>

+ typename detail::bessel_traits<T, T, Policy>::result_type sph_bessel(unsigned v, T x, const Policy& pol);

+

+ template <class T>

+ typename detail::bessel_traits<T, T, policies::policy<> >::result_type sph_bessel(unsigned v, T x);

+

+ template <class T1, class T2, class Policy>

+ typename detail::bessel_traits<T1, T2, Policy>::result_type cyl_bessel_i(T1 v, T2 x, const Policy& pol);

+

+ template <class T1, class T2>

+ typename detail::bessel_traits<T1, T2, policies::policy<> >::result_type cyl_bessel_i(T1 v, T2 x);

+

+ template <class T1, class T2, class Policy>

+ typename detail::bessel_traits<T1, T2, Policy>::result_type cyl_bessel_k(T1 v, T2 x, const Policy& pol);

+

+ template <class T1, class T2>

+ typename detail::bessel_traits<T1, T2, policies::policy<> >::result_type cyl_bessel_k(T1 v, T2 x);

+

+ template <class T1, class T2, class Policy>

+ typename detail::bessel_traits<T1, T2, Policy>::result_type cyl_neumann(T1 v, T2 x, const Policy& pol);

+

+ template <class T1, class T2>

+ typename detail::bessel_traits<T1, T2, policies::policy<> >::result_type cyl_neumann(T1 v, T2 x);

+

+ template <class T, class Policy>

+ typename detail::bessel_traits<T, T, Policy>::result_type sph_neumann(unsigned v, T x, const Policy& pol);

+

+ template <class T>

+ typename detail::bessel_traits<T, T, policies::policy<> >::result_type sph_neumann(unsigned v, T x);

+

+ template <class T1, class T2, class Policy>

+ std::complex<typename detail::bessel_traits<T1, T2, Policy>::result_type> cyl_hankel_1(T1 v, T2 x, const Policy& pol);

+

+ template <class T1, class T2>

+ std::complex<typename detail::bessel_traits<T1, T2, policies::policy<> >::result_type> cyl_hankel_1(T1 v, T2 x);

+

+ template <class T1, class T2, class Policy>

+ std::complex<typename detail::bessel_traits<T1, T2, Policy>::result_type> cyl_hankel_2(T1 v, T2 x, const Policy& pol);

+

+ template <class T1, class T2>

+ std::complex<typename detail::bessel_traits<T1, T2, policies::policy<> >::result_type> cyl_hankel_2(T1 v, T2 x);

+

+ template <class T1, class T2, class Policy>

+ std::complex<typename detail::bessel_traits<T1, T2, Policy>::result_type> sph_hankel_1(T1 v, T2 x, const Policy& pol);

+

+ template <class T1, class T2>

+ std::complex<typename detail::bessel_traits<T1, T2, policies::policy<> >::result_type> sph_hankel_1(T1 v, T2 x);

+

+ template <class T1, class T2, class Policy>

+ std::complex<typename detail::bessel_traits<T1, T2, Policy>::result_type> sph_hankel_2(T1 v, T2 x, const Policy& pol);

+

+ template <class T1, class T2>

+ std::complex<typename detail::bessel_traits<T1, T2, policies::policy<> >::result_type> sph_hankel_2(T1 v, T2 x);

+

+ template <class T, class Policy>

+ typename tools::promote_args<T>::type airy_ai(T x, const Policy&);

+

+ template <class T>

+ typename tools::promote_args<T>::type airy_ai(T x);

+

+ template <class T, class Policy>

+ typename tools::promote_args<T>::type airy_bi(T x, const Policy&);

+

+ template <class T>

+ typename tools::promote_args<T>::type airy_bi(T x);

+

+ template <class T, class Policy>

+ typename tools::promote_args<T>::type airy_ai_prime(T x, const Policy&);

+

+ template <class T>

+ typename tools::promote_args<T>::type airy_ai_prime(T x);

+

+ template <class T, class Policy>

+ typename tools::promote_args<T>::type airy_bi_prime(T x, const Policy&);

+

+ template <class T>

+ typename tools::promote_args<T>::type airy_bi_prime(T x);

+

+ template <class T, class Policy>

+ typename tools::promote_args<T>::type sin_pi(T x, const Policy&);

+

+ template <class T>

+ typename tools::promote_args<T>::type sin_pi(T x);

+

+ template <class T, class Policy>

+ typename tools::promote_args<T>::type cos_pi(T x, const Policy&);

+

+ template <class T>

+ typename tools::promote_args<T>::type cos_pi(T x);

+

+ template <class T>

+ int fpclassify BOOST_NO_MACRO_EXPAND(T t);

+

+ template <class T>

+ bool isfinite BOOST_NO_MACRO_EXPAND(T z);

+

+ template <class T>

+ bool isinf BOOST_NO_MACRO_EXPAND(T t);

+

+ template <class T>

+ bool isnan BOOST_NO_MACRO_EXPAND(T t);

+

+ template <class T>

+ bool isnormal BOOST_NO_MACRO_EXPAND(T t);

+

+ template<class T>

+ int signbit BOOST_NO_MACRO_EXPAND(T x);

+

+ template <class T>

+ int sign BOOST_NO_MACRO_EXPAND(const T& z);

+

+ template <class T>

+ T copysign BOOST_NO_MACRO_EXPAND(const T& x, const T& y);

+

+ template <class T>

+ T changesign BOOST_NO_MACRO_EXPAND(const T& z);

+

+ // Exponential integrals:

+ namespace detail{

+

+ template <class T, class U>

+ struct expint_result

+ {

+ typedef typename mpl::if_<

+ policies::is_policy<U>,

+ typename tools::promote_args<T>::type,

+ typename tools::promote_args<U>::type

+ >::type type;

+ };

+

+ } // namespace detail

+

+ template <class T, class Policy>

+ typename tools::promote_args<T>::type expint(unsigned n, T z, const Policy&);

+

+ template <class T, class U>

+ typename detail::expint_result<T, U>::type expint(T const z, U const u);

+

+ template <class T>

+ typename tools::promote_args<T>::type expint(T z);

+

+ // Zeta:

+ template <class T, class Policy>

+ typename tools::promote_args<T>::type zeta(T s, const Policy&);

+

+ // Owen's T function:

+ template <class T1, class T2, class Policy>

+ typename tools::promote_args<T1, T2>::type owens_t(T1 h, T2 a, const Policy& pol);

+

+ template <class T1, class T2>

+ typename tools::promote_args<T1, T2>::type owens_t(T1 h, T2 a);

+

+ // Jacobi Functions:

+ template <class T, class Policy>

+ typename tools::promote_args<T>::type jacobi_elliptic(T k, T theta, T* pcn, T* pdn, const Policy&);

+

+ template <class T>

+ typename tools::promote_args<T>::type jacobi_elliptic(T k, T theta, T* pcn = 0, T* pdn = 0);

+

+ template <class U, class T, class Policy>

+ typename tools::promote_args<T, U>::type jacobi_sn(U k, T theta, const Policy& pol);

+

+ template <class U, class T>

+ typename tools::promote_args<T, U>::type jacobi_sn(U k, T theta);

+

+ template <class T, class U, class Policy>

+ typename tools::promote_args<T, U>::type jacobi_cn(T k, U theta, const Policy& pol);

+

+ template <class T, class U>

+ typename tools::promote_args<T, U>::type jacobi_cn(T k, U theta);

+

+ template <class T, class U, class Policy>

+ typename tools::promote_args<T, U>::type jacobi_dn(T k, U theta, const Policy& pol);

+

+ template <class T, class U>

+ typename tools::promote_args<T, U>::type jacobi_dn(T k, U theta);

+

+ template <class T, class U, class Policy>

+ typename tools::promote_args<T, U>::type jacobi_cd(T k, U theta, const Policy& pol);

+

+ template <class T, class U>

+ typename tools::promote_args<T, U>::type jacobi_cd(T k, U theta);

+

+ template <class T, class U, class Policy>

+ typename tools::promote_args<T, U>::type jacobi_dc(T k, U theta, const Policy& pol);

+

+ template <class T, class U>

+ typename tools::promote_args<T, U>::type jacobi_dc(T k, U theta);

+

+ template <class T, class U, class Policy>

+ typename tools::promote_args<T, U>::type jacobi_ns(T k, U theta, const Policy& pol);

+

+ template <class T, class U>

+ typename tools::promote_args<T, U>::type jacobi_ns(T k, U theta);

+

+ template <class T, class U, class Policy>

+ typename tools::promote_args<T, U>::type jacobi_sd(T k, U theta, const Policy& pol);

+

+ template <class T, class U>

+ typename tools::promote_args<T, U>::type jacobi_sd(T k, U theta);

+

+ template <class T, class U, class Policy>

+ typename tools::promote_args<T, U>::type jacobi_ds(T k, U theta, const Policy& pol);

+

+ template <class T, class U>

+ typename tools::promote_args<T, U>::type jacobi_ds(T k, U theta);

+

+ template <class T, class U, class Policy>

+ typename tools::promote_args<T, U>::type jacobi_nc(T k, U theta, const Policy& pol);

+

+ template <class T, class U>

+ typename tools::promote_args<T, U>::type jacobi_nc(T k, U theta);

+

+ template <class T, class U, class Policy>

+ typename tools::promote_args<T, U>::type jacobi_nd(T k, U theta, const Policy& pol);

+

+ template <class T, class U>

+ typename tools::promote_args<T, U>::type jacobi_nd(T k, U theta);

+

+ template <class T, class U, class Policy>

+ typename tools::promote_args<T, U>::type jacobi_sc(T k, U theta, const Policy& pol);

+

+ template <class T, class U>

+ typename tools::promote_args<T, U>::type jacobi_sc(T k, U theta);

+

+ template <class T, class U, class Policy>

+ typename tools::promote_args<T, U>::type jacobi_cs(T k, U theta, const Policy& pol);

+

+ template <class T, class U>

+ typename tools::promote_args<T, U>::type jacobi_cs(T k, U theta);

+

+

+ template <class T>

+ typename tools::promote_args<T>::type zeta(T s);

+

+ // pow:

+ template <int N, typename T, class Policy>

+ typename tools::promote_args<T>::type pow(T base, const Policy& policy);

+

+ template <int N, typename T>

+ typename tools::promote_args<T>::type pow(T base);

+

+ // next:

+ template <class T, class Policy>

+ T nextafter(const T&, const T&, const Policy&);

+ template <class T>

+ T nextafter(const T&, const T&);

+ template <class T, class Policy>

+ T float_next(const T&, const Policy&);

+ template <class T>

+ T float_next(const T&);

+ template <class T, class Policy>

+ T float_prior(const T&, const Policy&);

+ template <class T>

+ T float_prior(const T&);

+ template <class T, class Policy>

+ T float_distance(const T&, const T&, const Policy&);

+ template <class T>

+ T float_distance(const T&, const T&);

+

+ } // namespace math

+} // namespace boost

+

+#ifdef BOOST_HAS_LONG_LONG

+#define BOOST_MATH_DETAIL_LL_FUNC(Policy)\

+ \

+ template <class T>\

+ inline T modf(const T& v, boost::long_long_type* ipart){ using boost::math::modf; return modf(v, ipart, Policy()); }\

+ \

+ template <class T>\

+ inline boost::long_long_type lltrunc(const T& v){ using boost::math::lltrunc; return lltrunc(v, Policy()); }\

+ \

+ template <class T>\

+ inline boost::long_long_type llround(const T& v){ using boost::math::llround; return llround(v, Policy()); }\

+

+#else

+#define BOOST_MATH_DETAIL_LL_FUNC(Policy)

+#endif

+

+#define BOOST_MATH_DECLARE_SPECIAL_FUNCTIONS(Policy)\

+ \

+ BOOST_MATH_DETAIL_LL_FUNC(Policy)\

+ \

+ template <class RT1, class RT2>\

+ inline typename boost::math::tools::promote_args<RT1, RT2>::type \

+ beta(RT1 a, RT2 b) { return ::boost::math::beta(a, b, Policy()); }\

+\

+ template <class RT1, class RT2, class A>\

+ inline typename boost::math::tools::promote_args<RT1, RT2, A>::type \

+ beta(RT1 a, RT2 b, A x){ return ::boost::math::beta(a, b, x, Policy()); }\

+\

+ template <class RT1, class RT2, class RT3>\

+ inline typename boost::math::tools::promote_args<RT1, RT2, RT3>::type \

+ betac(RT1 a, RT2 b, RT3 x) { return ::boost::math::betac(a, b, x, Policy()); }\

+\

+ template <class RT1, class RT2, class RT3>\

+ inline typename boost::math::tools::promote_args<RT1, RT2, RT3>::type \

+ ibeta(RT1 a, RT2 b, RT3 x){ return ::boost::math::ibeta(a, b, x, Policy()); }\

+\

+ template <class RT1, class RT2, class RT3>\

+ inline typename boost::math::tools::promote_args<RT1, RT2, RT3>::type \

+ ibetac(RT1 a, RT2 b, RT3 x){ return ::boost::math::ibetac(a, b, x, Policy()); }\

+\

+ template <class T1, class T2, class T3, class T4>\

+ inline typename boost::math::tools::promote_args<T1, T2, T3, T4>::type \

+ ibeta_inv(T1 a, T2 b, T3 p, T4* py){ return ::boost::math::ibeta_inv(a, b, p, py, Policy()); }\

+\

+ template <class RT1, class RT2, class RT3>\

+ inline typename boost::math::tools::promote_args<RT1, RT2, RT3>::type \

+ ibeta_inv(RT1 a, RT2 b, RT3 p){ return ::boost::math::ibeta_inv(a, b, p, Policy()); }\

+\

+ template <class T1, class T2, class T3, class T4>\

+ inline typename boost::math::tools::promote_args<T1, T2, T3, T4>::type \

+ ibetac_inv(T1 a, T2 b, T3 q, T4* py){ return ::boost::math::ibetac_inv(a, b, q, py, Policy()); }\

+\

+ template <class RT1, class RT2, class RT3>\

+ inline typename boost::math::tools::promote_args<RT1, RT2, RT3>::type \

+ ibeta_inva(RT1 a, RT2 b, RT3 p){ return ::boost::math::ibeta_inva(a, b, p, Policy()); }\

+\

+ template <class T1, class T2, class T3>\

+ inline typename boost::math::tools::promote_args<T1, T2, T3>::type \

+ ibetac_inva(T1 a, T2 b, T3 q){ return ::boost::math::ibetac_inva(a, b, q, Policy()); }\

+\

+ template <class RT1, class RT2, class RT3>\

+ inline typename boost::math::tools::promote_args<RT1, RT2, RT3>::type \

+ ibeta_invb(RT1 a, RT2 b, RT3 p){ return ::boost::math::ibeta_invb(a, b, p, Policy()); }\

+\

+ template <class T1, class T2, class T3>\

+ inline typename boost::math::tools::promote_args<T1, T2, T3>::type \

+ ibetac_invb(T1 a, T2 b, T3 q){ return ::boost::math::ibetac_invb(a, b, q, Policy()); }\

+\

+ template <class RT1, class RT2, class RT3>\

+ inline typename boost::math::tools::promote_args<RT1, RT2, RT3>::type \

+ ibetac_inv(RT1 a, RT2 b, RT3 q){ return ::boost::math::ibetac_inv(a, b, q, Policy()); }\

+\

+ template <class RT1, class RT2, class RT3>\

+ inline typename boost::math::tools::promote_args<RT1, RT2, RT3>::type \

+ ibeta_derivative(RT1 a, RT2 b, RT3 x){ return ::boost::math::ibeta_derivative(a, b, x, Policy()); }\

+\

+ template <class RT>\

+ inline typename boost::math::tools::promote_args<RT>::type erf(RT z) { return ::boost::math::erf(z, Policy()); }\

+\

+ template <class RT>\

+ inline typename boost::math::tools::promote_args<RT>::type erfc(RT z){ return ::boost::math::erfc(z, Policy()); }\

+\

+ template <class RT>\

+ inline typename boost::math::tools::promote_args<RT>::type erf_inv(RT z) { return ::boost::math::erf_inv(z, Policy()); }\

+\

+ template <class RT>\

+ inline typename boost::math::tools::promote_args<RT>::type erfc_inv(RT z){ return ::boost::math::erfc_inv(z, Policy()); }\

+\

+ using boost::math::legendre_next;\

+\

+ template <class T>\

+ inline typename boost::math::tools::promote_args<T>::type \

+ legendre_p(int l, T x){ return ::boost::math::legendre_p(l, x, Policy()); }\

+\

+ template <class T>\

+ inline typename boost::math::tools::promote_args<T>::type \

+ legendre_q(unsigned l, T x){ return ::boost::math::legendre_q(l, x, Policy()); }\

+\

+ using ::boost::math::legendre_next;\

+\

+ template <class T>\

+ inline typename boost::math::tools::promote_args<T>::type \

+ legendre_p(int l, int m, T x){ return ::boost::math::legendre_p(l, m, x, Policy()); }\

+\

+ using ::boost::math::laguerre_next;\

+\

+ template <class T>\

+ inline typename boost::math::tools::promote_args<T>::type \

+ laguerre(unsigned n, T x){ return ::boost::math::laguerre(n, x, Policy()); }\

+\

+ template <class T1, class T2>\

+ inline typename boost::math::laguerre_result<T1, T2>::type \

+ laguerre(unsigned n, T1 m, T2 x) { return ::boost::math::laguerre(n, m, x, Policy()); }\

+\

+ template <class T>\

+ inline typename boost::math::tools::promote_args<T>::type \

+ hermite(unsigned n, T x){ return ::boost::math::hermite(n, x, Policy()); }\

+\

+ using boost::math::hermite_next;\

+\

+ template <class T1, class T2>\

+ inline std::complex<typename boost::math::tools::promote_args<T1, T2>::type> \

+ spherical_harmonic(unsigned n, int m, T1 theta, T2 phi){ return boost::math::spherical_harmonic(n, m, theta, phi, Policy()); }\

+\

+ template <class T1, class T2>\

+ inline typename boost::math::tools::promote_args<T1, T2>::type \

+ spherical_harmonic_r(unsigned n, int m, T1 theta, T2 phi){ return ::boost::math::spherical_harmonic_r(n, m, theta, phi, Policy()); }\

+\

+ template <class T1, class T2>\

+ inline typename boost::math::tools::promote_args<T1, T2>::type \

+ spherical_harmonic_i(unsigned n, int m, T1 theta, T2 phi){ return boost::math::spherical_harmonic_i(n, m, theta, phi, Policy()); }\

+\

+ template <class T1, class T2, class Policy>\

+ inline typename boost::math::tools::promote_args<T1, T2>::type \

+ spherical_harmonic_i(unsigned n, int m, T1 theta, T2 phi, const Policy& pol);\

+\

+ template <class T1, class T2, class T3>\

+ inline typename boost::math::tools::promote_args<T1, T2, T3>::type \

+ ellint_rf(T1 x, T2 y, T3 z){ return ::boost::math::ellint_rf(x, y, z, Policy()); }\

+\

+ template <class T1, class T2, class T3>\

+ inline typename boost::math::tools::promote_args<T1, T2, T3>::type \

+ ellint_rd(T1 x, T2 y, T3 z){ return ::boost::math::ellint_rd(x, y, z, Policy()); }\

+\

+ template <class T1, class T2>\

+ inline typename boost::math::tools::promote_args<T1, T2>::type \

+ ellint_rc(T1 x, T2 y){ return ::boost::math::ellint_rc(x, y, Policy()); }\

+\

+ template <class T1, class T2, class T3, class T4>\

+ inline typename boost::math::tools::promote_args<T1, T2, T3, T4>::type \

+ ellint_rj(T1 x, T2 y, T3 z, T4 p){ return boost::math::ellint_rj(x, y, z, p, Policy()); }\

+\

+ template <typename T>\

+ inline typename boost::math::tools::promote_args<T>::type ellint_2(T k){ return boost::math::ellint_2(k, Policy()); }\

+\

+ template <class T1, class T2>\

+ inline typename boost::math::tools::promote_args<T1, T2>::type ellint_2(T1 k, T2 phi){ return boost::math::ellint_2(k, phi, Policy()); }\

+\

+ template <typename T>\

+ inline typename boost::math::tools::promote_args<T>::type ellint_1(T k){ return boost::math::ellint_1(k, Policy()); }\

+\

+ template <class T1, class T2>\

+ inline typename boost::math::tools::promote_args<T1, T2>::type ellint_1(T1 k, T2 phi){ return boost::math::ellint_1(k, phi, Policy()); }\

+\

+ template <class T1, class T2, class T3>\

+ inline typename boost::math::tools::promote_args<T1, T2, T3>::type ellint_3(T1 k, T2 v, T3 phi){ return boost::math::ellint_3(k, v, phi, Policy()); }\

+\

+ template <class T1, class T2>\

+ inline typename boost::math::tools::promote_args<T1, T2>::type ellint_3(T1 k, T2 v){ return boost::math::ellint_3(k, v, Policy()); }\

+\

+ using boost::math::max_factorial;\

+ template <class RT>\

+ inline RT factorial(unsigned int i) { return boost::math::factorial<RT>(i, Policy()); }\

+ using boost::math::unchecked_factorial;\

+ template <class RT>\

+ inline RT double_factorial(unsigned i){ return boost::math::double_factorial<RT>(i, Policy()); }\

+ template <class RT>\

+ inline typename boost::math::tools::promote_args<RT>::type falling_factorial(RT x, unsigned n){ return boost::math::falling_factorial(x, n, Policy()); }\

+ template <class RT>\

+ inline typename boost::math::tools::promote_args<RT>::type rising_factorial(RT x, unsigned n){ return boost::math::rising_factorial(x, n, Policy()); }\

+\

+ template <class RT>\

+ inline typename boost::math::tools::promote_args<RT>::type tgamma(RT z){ return boost::math::tgamma(z, Policy()); }\

+\

+ template <class RT>\

+ inline typename boost::math::tools::promote_args<RT>::type tgamma1pm1(RT z){ return boost::math::tgamma1pm1(z, Policy()); }\

+\

+ template <class RT1, class RT2>\

+ inline typename boost::math::tools::promote_args<RT1, RT2>::type tgamma(RT1 a, RT2 z){ return boost::math::tgamma(a, z, Policy()); }\

+\

+ template <class RT>\

+ inline typename boost::math::tools::promote_args<RT>::type lgamma(RT z, int* sign){ return boost::math::lgamma(z, sign, Policy()); }\

+\

+ template <class RT>\

+ inline typename boost::math::tools::promote_args<RT>::type lgamma(RT x){ return boost::math::lgamma(x, Policy()); }\

+\

+ template <class RT1, class RT2>\

+ inline typename boost::math::tools::promote_args<RT1, RT2>::type tgamma_lower(RT1 a, RT2 z){ return boost::math::tgamma_lower(a, z, Policy()); }\

+\

+ template <class RT1, class RT2>\

+ inline typename boost::math::tools::promote_args<RT1, RT2>::type gamma_q(RT1 a, RT2 z){ return boost::math::gamma_q(a, z, Policy()); }\

+\

+ template <class RT1, class RT2>\

+ inline typename boost::math::tools::promote_args<RT1, RT2>::type gamma_p(RT1 a, RT2 z){ return boost::math::gamma_p(a, z, Policy()); }\

+\

+ template <class T1, class T2>\

+ inline typename boost::math::tools::promote_args<T1, T2>::type tgamma_delta_ratio(T1 z, T2 delta){ return boost::math::tgamma_delta_ratio(z, delta, Policy()); }\

+\

+ template <class T1, class T2>\

+ inline typename boost::math::tools::promote_args<T1, T2>::type tgamma_ratio(T1 a, T2 b) { return boost::math::tgamma_ratio(a, b, Policy()); }\

+\

+ template <class T1, class T2>\

+ inline typename boost::math::tools::promote_args<T1, T2>::type gamma_p_derivative(T1 a, T2 x){ return boost::math::gamma_p_derivative(a, x, Policy()); }\

+\

+ template <class T1, class T2>\

+ inline typename boost::math::tools::promote_args<T1, T2>::type gamma_p_inv(T1 a, T2 p){ return boost::math::gamma_p_inv(a, p, Policy()); }\

+\

+ template <class T1, class T2>\

+ inline typename boost::math::tools::promote_args<T1, T2>::type gamma_p_inva(T1 a, T2 p){ return boost::math::gamma_p_inva(a, p, Policy()); }\

+\

+ template <class T1, class T2>\

+ inline typename boost::math::tools::promote_args<T1, T2>::type gamma_q_inv(T1 a, T2 q){ return boost::math::gamma_q_inv(a, q, Policy()); }\

+\

+ template <class T1, class T2>\

+ inline typename boost::math::tools::promote_args<T1, T2>::type gamma_q_inva(T1 a, T2 q){ return boost::math::gamma_q_inva(a, q, Policy()); }\

+\

+ template <class T>\

+ inline typename boost::math::tools::promote_args<T>::type digamma(T x){ return boost::math::digamma(x, Policy()); }\

+\

+ template <class T1, class T2>\

+ inline typename boost::math::tools::promote_args<T1, T2>::type \

+ hypot(T1 x, T2 y){ return boost::math::hypot(x, y, Policy()); }\

+\

+ template <class RT>\

+ inline typename boost::math::tools::promote_args<RT>::type cbrt(RT z){ return boost::math::cbrt(z, Policy()); }\

+\

+ template <class T>\

+ inline typename boost::math::tools::promote_args<T>::type log1p(T x){ return boost::math::log1p(x, Policy()); }\

+\

+ template <class T>\

+ inline typename boost::math::tools::promote_args<T>::type log1pmx(T x){ return boost::math::log1pmx(x, Policy()); }\

+\

+ template <class T>\

+ inline typename boost::math::tools::promote_args<T>::type expm1(T x){ return boost::math::expm1(x, Policy()); }\

+\

+ template <class T1, class T2>\

+ inline typename boost::math::tools::promote_args<T1, T2>::type \

+ powm1(const T1 a, const T2 z){ return boost::math::powm1(a, z, Policy()); }\

+\

+ template <class T>\

+ inline typename boost::math::tools::promote_args<T>::type sqrt1pm1(const T& val){ return boost::math::sqrt1pm1(val, Policy()); }\

+\

+ template <class T>\

+ inline typename boost::math::tools::promote_args<T>::type sinc_pi(T x){ return boost::math::sinc_pi(x, Policy()); }\

+\

+ template <class T>\

+ inline typename boost::math::tools::promote_args<T>::type sinhc_pi(T x){ return boost::math::sinhc_pi(x, Policy()); }\

+\

+ template<typename T>\

+ inline typename boost::math::tools::promote_args<T>::type asinh(const T x){ return boost::math::asinh(x, Policy()); }\

+\

+ template<typename T>\

+ inline typename boost::math::tools::promote_args<T>::type acosh(const T x){ return boost::math::acosh(x, Policy()); }\

+\

+ template<typename T>\

+ inline typename boost::math::tools::promote_args<T>::type atanh(const T x){ return boost::math::atanh(x, Policy()); }\

+\

+ template <class T1, class T2>\

+ inline typename boost::math::detail::bessel_traits<T1, T2, Policy >::result_type cyl_bessel_j(T1 v, T2 x)\

+ { return boost::math::cyl_bessel_j(v, x, Policy()); }\

+\

+ template <class T>\

+ inline typename boost::math::detail::bessel_traits<T, T, Policy >::result_type sph_bessel(unsigned v, T x)\

+ { return boost::math::sph_bessel(v, x, Policy()); }\

+\

+ template <class T1, class T2>\

+ inline typename boost::math::detail::bessel_traits<T1, T2, Policy >::result_type \

+ cyl_bessel_i(T1 v, T2 x) { return boost::math::cyl_bessel_i(v, x, Policy()); }\

+\

+ template <class T1, class T2>\

+ inline typename boost::math::detail::bessel_traits<T1, T2, Policy >::result_type \

+ cyl_bessel_k(T1 v, T2 x) { return boost::math::cyl_bessel_k(v, x, Policy()); }\

+\

+ template <class T1, class T2>\

+ inline typename boost::math::detail::bessel_traits<T1, T2, Policy >::result_type \

+ cyl_neumann(T1 v, T2 x){ return boost::math::cyl_neumann(v, x, Policy()); }\

+\

+ template <class T>\

+ inline typename boost::math::detail::bessel_traits<T, T, Policy >::result_type \

+ sph_neumann(unsigned v, T x){ return boost::math::sph_neumann(v, x, Policy()); }\

+\

+ template <class T>\

+ inline typename boost::math::tools::promote_args<T>::type sin_pi(T x){ return boost::math::sin_pi(x); }\

+\

+ template <class T>\

+ inline typename boost::math::tools::promote_args<T>::type cos_pi(T x){ return boost::math::cos_pi(x); }\

+\

+ using boost::math::fpclassify;\

+ using boost::math::isfinite;\

+ using boost::math::isinf;\

+ using boost::math::isnan;\

+ using boost::math::isnormal;\

+ using boost::math::signbit;\

+ using boost::math::sign;\

+ using boost::math::copysign;\

+ using boost::math::changesign;\

+ \

+ template <class T, class U>\

+ inline typename boost::math::tools::promote_args<T,U>::type expint(T const& z, U const& u)\

+ { return boost::math::expint(z, u, Policy()); }\

+ \

+ template <class T>\

+ inline typename boost::math::tools::promote_args<T>::type expint(T z){ return boost::math::expint(z, Policy()); }\

+ \

+ template <class T>\

+ inline typename boost::math::tools::promote_args<T>::type zeta(T s){ return boost::math::zeta(s, Policy()); }\

+ \

+ template <class T>\

+ inline T round(const T& v){ using boost::math::round; return round(v, Policy()); }\

+ \

+ template <class T>\

+ inline int iround(const T& v){ using boost::math::iround; return iround(v, Policy()); }\

+ \

+ template <class T>\

+ inline long lround(const T& v){ using boost::math::lround; return lround(v, Policy()); }\

+ \

+ template <class T>\

+ inline T trunc(const T& v){ using boost::math::trunc; return trunc(v, Policy()); }\

+ \

+ template <class T>\

+ inline int itrunc(const T& v){ using boost::math::itrunc; return itrunc(v, Policy()); }\

+ \

+ template <class T>\

+ inline long ltrunc(const T& v){ using boost::math::ltrunc; return ltrunc(v, Policy()); }\

+ \

+ template <class T>\

+ inline T modf(const T& v, T* ipart){ using boost::math::modf; return modf(v, ipart, Policy()); }\

+ \

+ template <class T>\

+ inline T modf(const T& v, int* ipart){ using boost::math::modf; return modf(v, ipart, Policy()); }\

+ \

+ template <class T>\

+ inline T modf(const T& v, long* ipart){ using boost::math::modf; return modf(v, ipart, Policy()); }\

+ \

+ template <int N, class T>\

+ inline typename boost::math::tools::promote_args<T>::type pow(T v){ return boost::math::pow<N>(v, Policy()); }\

+ \

+ template <class T> T nextafter(const T& a, const T& b){ return boost::math::nextafter(a, b, Policy()); }\

+ template <class T> T float_next(const T& a){ return boost::math::float_next(a, Policy()); }\

+ template <class T> T float_prior(const T& a){ return boost::math::float_prior(a, Policy()); }\

+ template <class T> T float_distance(const T& a, const T& b){ return boost::math::float_distance(a, b, Policy()); }\

+ \

+ template <class RT1, class RT2>\

+ inline typename boost::math::tools::promote_args<RT1, RT2>::type owens_t(RT1 a, RT2 z){ return boost::math::owens_t(a, z, Policy()); }\

+ \

+ template <class T1, class T2>\

+ inline std::complex<typename boost::math::detail::bessel_traits<T1, T2, Policy >::result_type> cyl_hankel_1(T1 v, T2 x)\

+ { return boost::math::cyl_hankel_1(v, x, Policy()); }\

+ \

+ template <class T1, class T2>\

+ inline std::complex<typename boost::math::detail::bessel_traits<T1, T2, Policy >::result_type> cyl_hankel_2(T1 v, T2 x)\

+ { return boost::math::cyl_hankel_2(v, x, Policy()); }\

+ \

+ template <class T1, class T2>\

+ inline std::complex<typename boost::math::detail::bessel_traits<T1, T2, Policy >::result_type> sph_hankel_1(T1 v, T2 x)\

+ { return boost::math::sph_hankel_1(v, x, Policy()); }\

+ \

+ template <class T1, class T2>\

+ inline std::complex<typename boost::math::detail::bessel_traits<T1, T2, Policy >::result_type> sph_hankel_2(T1 v, T2 x)\

+ { return boost::math::sph_hankel_2(v, x, Policy()); }\

+ \

+ template <class T>\

+ inline typename boost::math::tools::promote_args<T>::type jacobi_elliptic(T k, T theta, T* pcn, T* pdn)\

+ { return boost::math::jacobi_elliptic(k, theta, pcn, pdn, Policy()); }\

+ \

+ template <class U, class T>\

+ inline typename boost::math::tools::promote_args<T, U>::type jacobi_sn(U k, T theta)\

+ { return boost::math::jacobi_sn(k, theta, Policy()); }\

+ \

+ template <class T, class U>\

+ inline typename boost::math::tools::promote_args<T, U>::type jacobi_cn(T k, U theta)\

+ { return boost::math::jacobi_cn(k, theta, Policy()); }\

+ \

+ template <class T, class U>\

+ inline typename boost::math::tools::promote_args<T, U>::type jacobi_dn(T k, U theta)\

+ { return boost::math::jacobi_dn(k, theta, Policy()); }\

+ \

+ template <class T, class U>\

+ inline typename boost::math::tools::promote_args<T, U>::type jacobi_cd(T k, U theta)\

+ { return boost::math::jacobi_cd(k, theta, Policy()); }\

+ \

+ template <class T, class U>\

+ inline typename boost::math::tools::promote_args<T, U>::type jacobi_dc(T k, U theta)\

+ { return boost::math::jacobi_dc(k, theta, Policy()); }\

+ \

+ template <class T, class U>\

+ inline typename boost::math::tools::promote_args<T, U>::type jacobi_ns(T k, U theta)\

+ { return boost::math::jacobi_ns(k, theta, Policy()); }\

+ \

+ template <class T, class U>\

+ inline typename boost::math::tools::promote_args<T, U>::type jacobi_sd(T k, U theta)\

+ { return boost::math::jacobi_sd(k, theta, Policy()); }\

+ \

+ template <class T, class U>\

+ inline typename boost::math::tools::promote_args<T, U>::type jacobi_ds(T k, U theta)\

+ { return boost::math::jacobi_ds(k, theta, Policy()); }\

+ \

+ template <class T, class U>\

+ inline typename boost::math::tools::promote_args<T, U>::type jacobi_nc(T k, U theta)\

+ { return boost::math::jacobi_nc(k, theta, Policy()); }\

+ \

+ template <class T, class U>\

+ inline typename boost::math::tools::promote_args<T, U>::type jacobi_nd(T k, U theta)\

+ { return boost::math::jacobi_nd(k, theta, Policy()); }\

+ \

+ template <class T, class U>\

+ inline typename boost::math::tools::promote_args<T, U>::type jacobi_sc(T k, U theta)\

+ { return boost::math::jacobi_sc(k, theta, Policy()); }\

+ \

+ template <class T, class U>\

+ inline typename boost::math::tools::promote_args<T, U>::type jacobi_cs(T k, U theta)\

+ { return boost::math::jacobi_cs(k, theta, Policy()); }\

+ \

+ template <class T>\

+ inline typename boost::math::tools::promote_args<T>::type airy_ai(T x)\

+ { return boost::math::airy_ai(x, Policy()); }\

+ \

+ template <class T>\

+ inline typename boost::math::tools::promote_args<T>::type airy_bi(T x)\

+ { return boost::math::airy_bi(x, Policy()); }\

+ \

+ template <class T>\

+ inline typename boost::math::tools::promote_args<T>::type airy_ai_prime(T x)\

+ { return boost::math::airy_ai_prime(x, Policy()); }\

+ \

+ template <class T>\

+ inline typename boost::math::tools::promote_args<T>::type airy_bi_prime(T x)\

+ { return boost::math::airy_bi_prime(x, Policy()); }\

+ \

+

+

+

+

+

+#endif // BOOST_MATH_SPECIAL_MATH_FWD_HPP

+

+

+// (C) Copyright John Maddock 2006.

+// (C) Copyright Johan Rade 2006.

+// (C) Copyright Paul A. Bristow 2011 (added changesign).

+

+// 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)

+

+#ifndef BOOST_MATH_TOOLS_SIGN_HPP

+#define BOOST_MATH_TOOLS_SIGN_HPP

+

+#ifdef _MSC_VER

+#pragma once

+#endif

+

+#include <boost/math/tools/config.hpp>

+#include <boost/math/special_functions/math_fwd.hpp>

+#include <boost/math/special_functions/detail/fp_traits.hpp>

+

+namespace boost{ namespace math{

+

+namespace detail {

+

+ // signbit

+

+#ifdef BOOST_MATH_USE_STD_FPCLASSIFY

+ template<class T>

+ inline int signbit_impl(T x, native_tag const&)

+ {

+ return (std::signbit)(x);

+ }

+#endif

+

+ template<class T>

+ inline int signbit_impl(T x, generic_tag<true> const&)

+ {

+ return x < 0;

+ }

+

+ template<class T>

+ inline int signbit_impl(T x, generic_tag<false> const&)

+ {

+ return x < 0;

+ }

+

+ template<class T>

+ inline int signbit_impl(T x, ieee_copy_all_bits_tag const&)

+ {

+ typedef BOOST_DEDUCED_TYPENAME fp_traits<T>::type traits;

+

+ BOOST_DEDUCED_TYPENAME traits::bits a;

+ traits::get_bits(x,a);

+ return a & traits::sign ? 1 : 0;

+ }

+

+ template<class T>

+ inline int signbit_impl(T x, ieee_copy_leading_bits_tag const&)

+ {

+ typedef BOOST_DEDUCED_TYPENAME fp_traits<T>::type traits;

+

+ BOOST_DEDUCED_TYPENAME traits::bits a;

+ traits::get_bits(x,a);

+

+ return a & traits::sign ? 1 : 0;

+ }

+

+ // Changesign

+

+ template<class T>

+ inline T (changesign_impl)(T x, generic_tag<true> const&)

+ {

+ return -x;

+ }

+

+ template<class T>

+ inline T (changesign_impl)(T x, generic_tag<false> const&)

+ {

+ return -x;

+ }

+

+

+ template<class T>

+ inline T changesign_impl(T x, ieee_copy_all_bits_tag const&)

+ {

+ typedef BOOST_DEDUCED_TYPENAME fp_traits<T>::sign_change_type traits;

+

+ BOOST_DEDUCED_TYPENAME traits::bits a;

+ traits::get_bits(x,a);

+ a ^= traits::sign;

+ traits::set_bits(x,a);

+ return x;

+ }

+

+ template<class T>

+ inline T (changesign_impl)(T x, ieee_copy_leading_bits_tag const&)

+ {

+ typedef BOOST_DEDUCED_TYPENAME fp_traits<T>::sign_change_type traits;

+

+ BOOST_DEDUCED_TYPENAME traits::bits a;

+ traits::get_bits(x,a);

+ a ^= traits::sign;

+ traits::set_bits(x,a);

+ return x;

+ }

+

+

+} // namespace detail

+

+template<class T> int (signbit)(T x)

+{

+ typedef typename detail::fp_traits<T>::type traits;

+ typedef typename traits::method method;

+ typedef typename boost::is_floating_point<T>::type fp_tag;

+ return detail::signbit_impl(x, method());

+}

+

+template <class T>

+inline int sign BOOST_NO_MACRO_EXPAND(const T& z)

+{

+ return (z == 0) ? 0 : (boost::math::signbit)(z) ? -1 : 1;

+}

+

+template<class T> T (changesign)(const T& x)

+{ //!< \brief return unchanged binary pattern of x, except for change of sign bit.

+ typedef typename detail::fp_traits<T>::sign_change_type traits;

+ typedef typename traits::method method;

+ typedef typename boost::is_floating_point<T>::type fp_tag;

+

+ return detail::changesign_impl(x, method());

+}

+

+template <class T>

+inline T copysign BOOST_NO_MACRO_EXPAND(const T& x, const T& y)

+{

+ BOOST_MATH_STD_USING

+ return (boost::math::signbit)(x) != (boost::math::signbit)(y) ? (boost::math::changesign)(x) : x;

+}

+

+} // namespace math

+} // namespace boost

+

+

+#endif // BOOST_MATH_TOOLS_SIGN_HPP

+

+

+// Copyright (c) 2006-7 John Maddock

+// 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)

+

+#ifndef BOOST_MATH_TOOLS_CONFIG_HPP

+#define BOOST_MATH_TOOLS_CONFIG_HPP

+

+#ifdef _MSC_VER

+#pragma once

+#endif

+

+#include <boost/config.hpp>

+#include <boost/cstdint.hpp> // for boost::uintmax_t

+#include <boost/detail/workaround.hpp>

+#include <algorithm> // for min and max

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

+#include <climits>

+#include <cfloat>

+#if (defined(macintosh) || defined(__APPLE__) || defined(__APPLE_CC__))

+# include <math.h>

+#endif

+

+#include <boost/math/tools/user.hpp>

+#include <boost/math/special_functions/detail/round_fwd.hpp>

+

+#if (defined(__CYGWIN__) || defined(__FreeBSD__) || defined(__NetBSD__) \

+ || (defined(__hppa) && !defined(__OpenBSD__)) || (defined(__NO_LONG_DOUBLE_MATH) && (DBL_MANT_DIG != LDBL_MANT_DIG))) \

+ && !defined(BOOST_MATH_NO_LONG_DOUBLE_MATH_FUNCTIONS)

+# define BOOST_MATH_NO_LONG_DOUBLE_MATH_FUNCTIONS

+#endif

+#if BOOST_WORKAROUND(__BORLANDC__, BOOST_TESTED_AT(0x582))

+//

+// Borland post 5.8.2 uses Dinkumware's std C lib which

+// doesn't have true long double precision. Earlier

+// versions are problematic too:

+//

+# define BOOST_MATH_NO_REAL_CONCEPT_TESTS

+# define BOOST_MATH_NO_LONG_DOUBLE_MATH_FUNCTIONS

+# define BOOST_MATH_CONTROL_FP _control87(MCW_EM,MCW_EM)

+# include <float.h>

+#endif

+#ifdef __IBMCPP__

+//

+// For reasons I don't unserstand, the tests with IMB's compiler all

+// pass at long double precision, but fail with real_concept, those tests

+// are disabled for now. (JM 2012).

+# define BOOST_MATH_NO_REAL_CONCEPT_TESTS

+#endif

+#if (defined(macintosh) || defined(__APPLE__) || defined(__APPLE_CC__)) && ((LDBL_MANT_DIG == 106) || (__LDBL_MANT_DIG__ == 106)) && !defined(BOOST_MATH_NO_LONG_DOUBLE_MATH_FUNCTIONS)

+//

+// Darwin's rather strange "double double" is rather hard to

+// support, it should be possible given enough effort though...

+//

+# define BOOST_MATH_NO_LONG_DOUBLE_MATH_FUNCTIONS

+#endif

+#if defined(unix) && defined(__INTEL_COMPILER) && (__INTEL_COMPILER <= 1000) && !defined(BOOST_MATH_NO_LONG_DOUBLE_MATH_FUNCTIONS)

+//

+// Intel compiler prior to version 10 has sporadic problems

+// calling the long double overloads of the std lib math functions:

+// calling ::powl is OK, but std::pow(long double, long double)

+// may segfault depending upon the value of the arguments passed

+// and the specific Linux distribution.

+//

+// We'll be conservative and disable long double support for this compiler.

+//

+// Comment out this #define and try building the tests to determine whether

+// your Intel compiler version has this issue or not.

+//

+# define BOOST_MATH_NO_LONG_DOUBLE_MATH_FUNCTIONS

+#endif

+#if defined(unix) && defined(__INTEL_COMPILER)

+//

+// Intel compiler has sporadic issues compiling std::fpclassify depending on

+// the exact OS version used. Use our own code for this as we know it works

+// well on Intel processors:

+//

+#define BOOST_MATH_DISABLE_STD_FPCLASSIFY

+#endif

+

+#if defined(BOOST_MSVC) && !defined(_WIN32_WCE)

+ // Better safe than sorry, our tests don't support hardware exceptions:

+# define BOOST_MATH_CONTROL_FP _control87(MCW_EM,MCW_EM)

+#endif

+

+#ifdef __IBMCPP__

+# define BOOST_MATH_NO_DEDUCED_FUNCTION_POINTERS

+#endif

+

+#if (defined(__STDC_VERSION__) && (__STDC_VERSION__ >= 199901))

+# define BOOST_MATH_USE_C99

+#endif

+

+#if (defined(__hpux) && !defined(__hppa))

+# define BOOST_MATH_USE_C99

+#endif

+

+#if defined(__GNUC__) && defined(_GLIBCXX_USE_C99)

+# define BOOST_MATH_USE_C99

+#endif

+

+#if defined(__CYGWIN__) || defined(__HP_aCC) || defined(BOOST_INTEL) \

+ || defined(BOOST_NO_NATIVE_LONG_DOUBLE_FP_CLASSIFY) \

+ || (defined(__GNUC__) && !defined(BOOST_MATH_USE_C99))

+# define BOOST_MATH_NO_NATIVE_LONG_DOUBLE_FP_CLASSIFY

+#endif

+

+#if defined(BOOST_NO_EXPLICIT_FUNCTION_TEMPLATE_ARGUMENTS) || BOOST_WORKAROUND(__SUNPRO_CC, <= 0x590)

+

+# include "boost/type.hpp"

+# include "boost/non_type.hpp"

+

+# define BOOST_MATH_EXPLICIT_TEMPLATE_TYPE(t) boost::type<t>* = 0

+# define BOOST_MATH_EXPLICIT_TEMPLATE_TYPE_SPEC(t) boost::type<t>*

+# define BOOST_MATH_EXPLICIT_TEMPLATE_NON_TYPE(t, v) boost::non_type<t, v>* = 0

+# define BOOST_MATH_EXPLICIT_TEMPLATE_NON_TYPE_SPEC(t, v) boost::non_type<t, v>*

+

+# define BOOST_MATH_APPEND_EXPLICIT_TEMPLATE_TYPE(t) \

+ , BOOST_MATH_EXPLICIT_TEMPLATE_TYPE(t)

+# define BOOST_MATH_APPEND_EXPLICIT_TEMPLATE_TYPE_SPEC(t) \

+ , BOOST_MATH_EXPLICIT_TEMPLATE_TYPE_SPEC(t)

+# define BOOST_MATH_APPEND_EXPLICIT_TEMPLATE_NON_TYPE(t, v) \

+ , BOOST_MATH_EXPLICIT_TEMPLATE_NON_TYPE(t, v)

+# define BOOST_MATH_APPEND_EXPLICIT_TEMPLATE_NON_TYPE_SPEC(t, v) \

+ , BOOST_MATH_EXPLICIT_TEMPLATE_NON_TYPE_SPEC(t, v)

+

+#else

+

+// no workaround needed: expand to nothing

+

+# define BOOST_MATH_EXPLICIT_TEMPLATE_TYPE(t)

+# define BOOST_MATH_EXPLICIT_TEMPLATE_TYPE_SPEC(t)

+# define BOOST_MATH_EXPLICIT_TEMPLATE_NON_TYPE(t, v)

+# define BOOST_MATH_EXPLICIT_TEMPLATE_NON_TYPE_SPEC(t, v)

+

+# define BOOST_MATH_APPEND_EXPLICIT_TEMPLATE_TYPE(t)

+# define BOOST_MATH_APPEND_EXPLICIT_TEMPLATE_TYPE_SPEC(t)

+# define BOOST_MATH_APPEND_EXPLICIT_TEMPLATE_NON_TYPE(t, v)

+# define BOOST_MATH_APPEND_EXPLICIT_TEMPLATE_NON_TYPE_SPEC(t, v)

+

+

+#endif // defined BOOST_NO_EXPLICIT_FUNCTION_TEMPLATE_ARGUMENTS

+

+#if (defined(__SUNPRO_CC) || defined(__hppa) || defined(__GNUC__)) && !defined(BOOST_MATH_SMALL_CONSTANT)

+// Sun's compiler emits a hard error if a constant underflows,

+// as does aCC on PA-RISC, while gcc issues a large number of warnings:

+# define BOOST_MATH_SMALL_CONSTANT(x) 0

+#else

+# define BOOST_MATH_SMALL_CONSTANT(x) x

+#endif

+

+

+#if BOOST_WORKAROUND(BOOST_MSVC, < 1400)

+//

+// Define if constants too large for a float cause "bad"

+// values to be stored in the data, rather than infinity

+// or a suitably large value.

+//

+# define BOOST_MATH_BUGGY_LARGE_FLOAT_CONSTANTS

+#endif

+//

+// Tune performance options for specific compilers:

+//

+#ifdef BOOST_MSVC

+# define BOOST_MATH_POLY_METHOD 2

+#elif defined(BOOST_INTEL)

+# define BOOST_MATH_POLY_METHOD 2

+# define BOOST_MATH_RATIONAL_METHOD 2

+#elif defined(__GNUC__)

+# define BOOST_MATH_POLY_METHOD 3

+# define BOOST_MATH_RATIONAL_METHOD 3

+# define BOOST_MATH_INT_TABLE_TYPE(RT, IT) RT

+# define BOOST_MATH_INT_VALUE_SUFFIX(RV, SUF) RV##.0L

+#endif

+

+#if defined(BOOST_NO_LONG_LONG) && !defined(BOOST_MATH_INT_TABLE_TYPE)

+# define BOOST_MATH_INT_TABLE_TYPE(RT, IT) RT

+# define BOOST_MATH_INT_VALUE_SUFFIX(RV, SUF) RV##.0L

+#endif

+

+//

+// The maximum order of polynomial that will be evaluated

+// via an unrolled specialisation:

+//

+#ifndef BOOST_MATH_MAX_POLY_ORDER

+# define BOOST_MATH_MAX_POLY_ORDER 17

+#endif

+//

+// Set the method used to evaluate polynomials and rationals:

+//

+#ifndef BOOST_MATH_POLY_METHOD

+# define BOOST_MATH_POLY_METHOD 1

+#endif

+#ifndef BOOST_MATH_RATIONAL_METHOD

+# define BOOST_MATH_RATIONAL_METHOD 0

+#endif

+//

+// decide whether to store constants as integers or reals:

+//

+#ifndef BOOST_MATH_INT_TABLE_TYPE

+# define BOOST_MATH_INT_TABLE_TYPE(RT, IT) IT

+#endif

+#ifndef BOOST_MATH_INT_VALUE_SUFFIX

+# define BOOST_MATH_INT_VALUE_SUFFIX(RV, SUF) RV##SUF

+#endif

+

+//

+// Helper macro for controlling the FP behaviour:

+//

+#ifndef BOOST_MATH_CONTROL_FP

+# define BOOST_MATH_CONTROL_FP

+#endif

+//

+// Helper macro for using statements:

+//

+#define BOOST_MATH_STD_USING \

+ using std::abs;\

+ using std::acos;\

+ using std::cos;\

+ using std::fmod;\

+ using std::modf;\

+ using std::tan;\

+ using std::asin;\

+ using std::cosh;\

+ using std::frexp;\

+ using std::pow;\

+ using std::tanh;\

+ using std::atan;\

+ using std::exp;\

+ using std::ldexp;\

+ using std::sin;\

+ using std::atan2;\

+ using std::fabs;\

+ using std::log;\

+ using std::sinh;\

+ using std::ceil;\

+ using std::floor;\

+ using std::log10;\

+ using std::sqrt;\

+ using boost::math::round;\

+ using boost::math::iround;\

+ using boost::math::lround;\

+ using boost::math::trunc;\

+ using boost::math::itrunc;\

+ using boost::math::ltrunc;\

+ using boost::math::modf;

+

+

+namespace boost{ namespace math{

+namespace tools

+{

+

+template <class T>

+inline T max BOOST_PREVENT_MACRO_SUBSTITUTION(T a, T b, T c)

+{

+ return (std::max)((std::max)(a, b), c);

+}

+

+template <class T>

+inline T max BOOST_PREVENT_MACRO_SUBSTITUTION(T a, T b, T c, T d)

+{

+ return (std::max)((std::max)(a, b), (std::max)(c, d));

+}

+

+} // namespace tools

+

+template <class T>

+void suppress_unused_variable_warning(const T&)

+{

+}

+

+}} // namespace boost namespace math

+

+#if ((defined(__linux__) && !defined(__UCLIBC__)) || defined(__QNX__) || defined(__IBMCPP__)) && !defined(BOOST_NO_FENV_H)

+

+ #include <boost/detail/fenv.hpp>

+

+# ifdef FE_ALL_EXCEPT

+

+namespace boost{ namespace math{

+ namespace detail

+ {

+ struct fpu_guard

+ {

+ fpu_guard()

+ {

+ fegetexceptflag(&m_flags, FE_ALL_EXCEPT);

+ feclearexcept(FE_ALL_EXCEPT);

+ }

+ ~fpu_guard()

+ {

+ fesetexceptflag(&m_flags, FE_ALL_EXCEPT);

+ }

+ private:

+ fexcept_t m_flags;

+ };

+

+ } // namespace detail

+ }} // namespaces

+

+# define BOOST_FPU_EXCEPTION_GUARD boost::math::detail::fpu_guard local_guard_object;

+# define BOOST_MATH_INSTRUMENT_FPU do{ fexcept_t cpu_flags; fegetexceptflag(&cpu_flags, FE_ALL_EXCEPT); BOOST_MATH_INSTRUMENT_VARIABLE(cpu_flags); } while(0);

+

+# else

+

+# define BOOST_FPU_EXCEPTION_GUARD

+# define BOOST_MATH_INSTRUMENT_FPU

+

+# endif

+

+#else // All other platforms.

+# define BOOST_FPU_EXCEPTION_GUARD

+# define BOOST_MATH_INSTRUMENT_FPU

+#endif

+

+#ifdef BOOST_MATH_INSTRUMENT

+#define BOOST_MATH_INSTRUMENT_CODE(x) \

+ std::cout << std::setprecision(35) << __FILE__ << ":" << __LINE__ << " " << x << std::endl;

+#define BOOST_MATH_INSTRUMENT_VARIABLE(name) BOOST_MATH_INSTRUMENT_CODE(BOOST_STRINGIZE(name) << " = " << name)

+#else

+#define BOOST_MATH_INSTRUMENT_CODE(x)

+#define BOOST_MATH_INSTRUMENT_VARIABLE(name)

+#endif

+

+#endif // BOOST_MATH_TOOLS_CONFIG_HPP

+

+

+

+

+

+// boost\math\tools\promotion.hpp

+

+// Copyright John Maddock 2006.

+// Copyright Paul A. Bristow 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)

+

+// Promote arguments functions to allow math functions to have arguments

+// provided as integer OR real (floating-point, built-in or UDT)

+// (called ArithmeticType in functions that use promotion)

+// that help to reduce the risk of creating multiple instantiations.

+// Allows creation of an inline wrapper that forwards to a foo(RT, RT) function,

+// so you never get to instantiate any mixed foo(RT, IT) functions.

+

+#ifndef BOOST_MATH_PROMOTION_HPP

+#define BOOST_MATH_PROMOTION_HPP

+

+#ifdef _MSC_VER

+#pragma once

+#endif

+

+// Boost type traits:

+#include <boost/math/tools/config.hpp>

+#include <boost/type_traits/is_floating_point.hpp> // for boost::is_floating_point;

+#include <boost/type_traits/is_integral.hpp> // for boost::is_integral

+#include <boost/type_traits/is_convertible.hpp> // for boost::is_convertible

+#include <boost/type_traits/is_same.hpp>// for boost::is_same

+#include <boost/type_traits/remove_cv.hpp>// for boost::remove_cv

+// Boost Template meta programming:

+#include <boost/mpl/if.hpp> // for boost::mpl::if_c.

+#include <boost/mpl/and.hpp> // for boost::mpl::if_c.

+#include <boost/mpl/or.hpp> // for boost::mpl::if_c.

+#include <boost/mpl/not.hpp> // for boost::mpl::if_c.

+

+#ifdef BOOST_MATH_NO_LONG_DOUBLE_MATH_FUNCTIONS

+#include <boost/static_assert.hpp>

+#endif

+

+namespace boost

+{

+ namespace math

+ {

+ namespace tools

+ {

+ // If either T1 or T2 is an integer type,

+ // pretend it was a double (for the purposes of further analysis).

+ // Then pick the wider of the two floating-point types

+ // as the actual signature to forward to.

+ // For example:

+ // foo(int, short) -> double foo(double, double);

+ // foo(int, float) -> double foo(double, double);

+ // Note: NOT float foo(float, float)

+ // foo(int, double) -> foo(double, double);

+ // foo(double, float) -> double foo(double, double);

+ // foo(double, float) -> double foo(double, double);

+ // foo(any-int-or-float-type, long double) -> foo(long double, long double);

+ // but ONLY float foo(float, float) is unchanged.

+ // So the only way to get an entirely float version is to call foo(1.F, 2.F),

+ // But since most (all?) the math functions convert to double internally,

+ // probably there would not be the hoped-for gain by using float here.

+

+ // This follows the C-compatible conversion rules of pow, etc

+ // where pow(int, float) is converted to pow(double, double).

+

+ template <class T>

+ struct promote_arg

+ { // If T is integral type, then promote to double.

+ typedef typename mpl::if_<is_integral<T>, double, T>::type type;

+ };

+ // These full specialisations reduce mpl::if_ usage and speed up

+ // compilation:

+ template <> struct promote_arg<float> { typedef float type; };

+ template <> struct promote_arg<double>{ typedef double type; };

+ template <> struct promote_arg<long double> { typedef long double type; };

+ template <> struct promote_arg<int> { typedef double type; };

+

+ template <class T1, class T2>

+ struct promote_args_2

+ { // Promote, if necessary, & pick the wider of the two floating-point types.

+ // for both parameter types, if integral promote to double.

+ typedef typename promote_arg<T1>::type T1P; // T1 perhaps promoted.

+ typedef typename promote_arg<T2>::type T2P; // T2 perhaps promoted.

+

+ typedef typename mpl::if_<

+ typename mpl::and_<is_floating_point<T1P>, is_floating_point<T2P> >::type, // both T1P and T2P are floating-point?

+ typename mpl::if_< typename mpl::or_<is_same<long double, T1P>, is_same<long double, T2P> >::type, // either long double?

+ long double, // then result type is long double.

+ typename mpl::if_< typename mpl::or_<is_same<double, T1P>, is_same<double, T2P> >::type, // either double?

+ double, // result type is double.

+ float // else result type is float.

+ >::type

+ >::type,

+ // else one or the other is a user-defined type:

+ typename mpl::if_< typename mpl::and_<mpl::not_<is_floating_point<T2P> >, ::boost::is_convertible<T1P, T2P> >, T2P, T1P>::type>::type type;

+ }; // promote_arg2

+ // These full specialisations reduce mpl::if_ usage and speed up

+ // compilation:

+ template <> struct promote_args_2<float, float> { typedef float type; };

+ template <> struct promote_args_2<double, double>{ typedef double type; };

+ template <> struct promote_args_2<long double, long double> { typedef long double type; };

+ template <> struct promote_args_2<int, int> { typedef double type; };

+ template <> struct promote_args_2<int, float> { typedef double type; };

+ template <> struct promote_args_2<float, int> { typedef double type; };

+ template <> struct promote_args_2<int, double> { typedef double type; };

+ template <> struct promote_args_2<double, int> { typedef double type; };

+ template <> struct promote_args_2<int, long double> { typedef long double type; };

+ template <> struct promote_args_2<long double, int> { typedef long double type; };

+ template <> struct promote_args_2<float, double> { typedef double type; };

+ template <> struct promote_args_2<double, float> { typedef double type; };

+ template <> struct promote_args_2<float, long double> { typedef long double type; };

+ template <> struct promote_args_2<long double, float> { typedef long double type; };

+ template <> struct promote_args_2<double, long double> { typedef long double type; };

+ template <> struct promote_args_2<long double, double> { typedef long double type; };

+

+ template <class T1, class T2=float, class T3=float, class T4=float, class T5=float, class T6=float>

+ struct promote_args

+ {

+ typedef typename promote_args_2<

+ typename remove_cv<T1>::type,

+ typename promote_args_2<

+ typename remove_cv<T2>::type,

+ typename promote_args_2<

+ typename remove_cv<T3>::type,

+ typename promote_args_2<

+ typename remove_cv<T4>::type,

+ typename promote_args_2<

+ typename remove_cv<T5>::type, typename remove_cv<T6>::type

+ >::type

+ >::type

+ >::type

+ >::type

+ >::type type;

+

+#ifdef BOOST_MATH_NO_LONG_DOUBLE_MATH_FUNCTIONS

+ //

+ // Guard against use of long double if it's not supported:

+ //

+ BOOST_STATIC_ASSERT((0 == ::boost::is_same<type, long double>::value));

+#endif

+ };

+

+ } // namespace tools

+ } // namespace math

+} // namespace boost

+

+#endif // BOOST_MATH_PROMOTION_HPP

+

+// 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)

+

+#ifndef BOOST_MATH_TOOLS_REAL_CAST_HPP

+#define BOOST_MATH_TOOLS_REAL_CAST_HPP

+

+#ifdef _MSC_VER

+#pragma once

+#endif

+

+namespace boost{ namespace math

+{

+ namespace tools

+ {

+ template <class To, class T>

+ inline To real_cast(T t)

+ {

+ return static_cast<To>(t);

+ }

+ } // namespace tools

+} // namespace math

+} // namespace boost

+

+#endif // BOOST_MATH_TOOLS_REAL_CAST_HPP

+

+

+

+// Copyright John Maddock 2007.

+// Copyright Paul A. Bristow 2007.

+

+// 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)

+

+#ifndef BOOST_MATH_TOOLS_USER_HPP

+#define BOOST_MATH_TOOLS_USER_HPP

+

+#ifdef _MSC_VER

+#pragma once

+#endif

+

+// This file can be modified by the user to change the default policies.

+// See "Changing the Policy Defaults" in documentation.

+

+// define this if the platform has no long double functions,

+// or if the long double versions have only double precision:

+//

+// #define BOOST_MATH_NO_LONG_DOUBLE_MATH_FUNCTIONS

+//

+// Performance tuning options:

+//

+// #define BOOST_MATH_POLY_METHOD 3

+// #define BOOST_MATH_RATIONAL_METHOD 3

+//

+// The maximum order of polynomial that will be evaluated

+// via an unrolled specialisation:

+//

+// #define BOOST_MATH_MAX_POLY_ORDER 17

+//

+// decide whether to store constants as integers or reals:

+//

+// #define BOOST_MATH_INT_TABLE_TYPE(RT, IT) IT

+

+//

+// Default policies follow:

+//

+// Domain errors:

+//

+// #define BOOST_MATH_DOMAIN_ERROR_POLICY throw_on_error

+//

+// Pole errors:

+//

+// #define BOOST_MATH_POLE_ERROR_POLICY throw_on_error

+//

+// Overflow Errors:

+//

+// #define BOOST_MATH_OVERFLOW_ERROR_POLICY throw_on_error

+//

+// Internal Evaluation Errors:

+//

+// #define BOOST_MATH_EVALUATION_ERROR_POLICY throw_on_error

+//

+// Underfow:

+//

+// #define BOOST_MATH_UNDERFLOW_ERROR_POLICY ignore_error

+//

+// Denorms:

+//

+// #define BOOST_MATH_DENORM_ERROR_POLICY ignore_error

+//

+// Max digits to use for internal calculations:

+//

+// #define BOOST_MATH_DIGITS10_POLICY 0

+//

+// Promote floats to doubles internally?

+//

+// #define BOOST_MATH_PROMOTE_FLOAT_POLICY true

+//

+// Promote doubles to long double internally:

+//

+// #define BOOST_MATH_PROMOTE_DOUBLE_POLICY true

+//

+// What do discrete quantiles return?

+//

+// #define BOOST_MATH_DISCRETE_QUANTILE_POLICY integer_round_outwards

+//

+// If a function is mathematically undefined

+// (for example the Cauchy distribution has no mean),

+// then do we stop the code from compiling?

+//

+// #define BOOST_MATH_ASSERT_UNDEFINED_POLICY true

+//

+// Maximum series iterstions permitted:

+//

+// #define BOOST_MATH_MAX_SERIES_ITERATION_POLICY 1000000

+//

+// Maximum root finding steps permitted:

+//

+// define BOOST_MATH_MAX_ROOT_ITERATION_POLICY 200

+

+#endif // BOOST_MATH_TOOLS_USER_HPP

+

+