#ifndef BOOST_BIND_BIND_HPP_INCLUDED #define BOOST_BIND_BIND_HPP_INCLUDED // MS compatible compilers support #pragma once #if defined(_MSC_VER) && (_MSC_VER >= 1020) # pragma once #endif // // bind.hpp - binds function objects to arguments // // Copyright (c) 2001-2004 Peter Dimov and Multi Media Ltd. // Copyright (c) 2001 David Abrahams // Copyright (c) 2005 Peter Dimov // // 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/libs/bind/bind.html for documentation. // #include <boost/config.hpp> #include <boost/ref.hpp> #include <boost/mem_fn.hpp> #include <boost/type.hpp> #include <boost/is_placeholder.hpp> #include <boost/bind/arg.hpp> #include <boost/detail/workaround.hpp> #include <boost/visit_each.hpp> // Borland-specific bug, visit_each() silently fails to produce code #if defined(__BORLANDC__) # define BOOST_BIND_VISIT_EACH boost::visit_each #else # define BOOST_BIND_VISIT_EACH visit_each #endif #include <boost/bind/storage.hpp> #ifdef BOOST_MSVC # pragma warning(push) # pragma warning(disable: 4512) // assignment operator could not be generated #endif namespace boost { template<class T> class weak_ptr; namespace _bi // implementation details { // result_traits template<class R, class F> struct result_traits { typedef R type; }; #if !defined(BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION) && !defined(BOOST_NO_FUNCTION_TEMPLATE_ORDERING) struct unspecified {}; template<class F> struct result_traits<unspecified, F> { typedef typename F::result_type type; }; template<class F> struct result_traits< unspecified, reference_wrapper<F> > { typedef typename F::result_type type; }; #endif // ref_compare template<class T> bool ref_compare( T const & a, T const & b, long ) { return a == b; } template<int I> bool ref_compare( arg<I> const &, arg<I> const &, int ) { return true; } template<int I> bool ref_compare( arg<I> (*) (), arg<I> (*) (), int ) { return true; } template<class T> bool ref_compare( reference_wrapper<T> const & a, reference_wrapper<T> const & b, int ) { return a.get_pointer() == b.get_pointer(); } // bind_t forward declaration for listN template<class R, class F, class L> class bind_t; template<class R, class F, class L> bool ref_compare( bind_t<R, F, L> const & a, bind_t<R, F, L> const & b, int ) { return a.compare( b ); } // value template<class T> class value { public: value(T const & t): t_(t) {} T & get() { return t_; } T const & get() const { return t_; } bool operator==(value const & rhs) const { return t_ == rhs.t_; } private: T t_; }; // ref_compare for weak_ptr template<class T> bool ref_compare( value< weak_ptr<T> > const & a, value< weak_ptr<T> > const & b, int ) { return !(a.get() < b.get()) && !(b.get() < a.get()); } // type template<class T> class type {}; // unwrap template<class F> struct unwrapper { static inline F & unwrap( F & f, long ) { return f; } template<class F2> static inline F2 & unwrap( reference_wrapper<F2> rf, int ) { return rf.get(); } template<class R, class T> static inline _mfi::dm<R, T> unwrap( R T::* pm, int ) { return _mfi::dm<R, T>( pm ); } }; // listN class list0 { public: list0() {} template<class T> T & operator[] (_bi::value<T> & v) const { return v.get(); } template<class T> T const & operator[] (_bi::value<T> const & v) const { return v.get(); } template<class T> T & operator[] (reference_wrapper<T> const & v) const { return v.get(); } template<class R, class F, class L> typename result_traits<R, F>::type operator[] (bind_t<R, F, L> & b) const { return b.eval(*this); } template<class R, class F, class L> typename result_traits<R, F>::type operator[] (bind_t<R, F, L> const & b) const { return b.eval(*this); } template<class R, class F, class A> R operator()(type<R>, F & f, A &, long) { return unwrapper<F>::unwrap(f, 0)(); } template<class R, class F, class A> R operator()(type<R>, F const & f, A &, long) const { return unwrapper<F const>::unwrap(f, 0)(); } template<class F, class A> void operator()(type<void>, F & f, A &, int) { unwrapper<F>::unwrap(f, 0)(); } template<class F, class A> void operator()(type<void>, F const & f, A &, int) const { unwrapper<F const>::unwrap(f, 0)(); } template<class V> void accept(V &) const { } bool operator==(list0 const &) const { return true; } }; #ifdef BOOST_MSVC // MSVC is bright enough to realise that the parameter rhs // in operator==may be unused for some template argument types: #pragma warning(push) #pragma warning(disable:4100) #endif template< class A1 > class list1: private storage1< A1 > { private: typedef storage1< A1 > base_type; public: explicit list1( A1 a1 ): base_type( a1 ) {} A1 operator[] (boost::arg<1>) const { return base_type::a1_; } A1 operator[] (boost::arg<1> (*) ()) const { return base_type::a1_; } template<class T> T & operator[] ( _bi::value<T> & v ) const { return v.get(); } template<class T> T const & operator[] ( _bi::value<T> const & v ) const { return v.get(); } template<class T> T & operator[] (reference_wrapper<T> const & v) const { return v.get(); } template<class R, class F, class L> typename result_traits<R, F>::type operator[] (bind_t<R, F, L> & b) const { return b.eval(*this); } template<class R, class F, class L> typename result_traits<R, F>::type operator[] (bind_t<R, F, L> const & b) const { return b.eval(*this); } template<class R, class F, class A> R operator()(type<R>, F & f, A & a, long) { return unwrapper<F>::unwrap(f, 0)(a[base_type::a1_]); } template<class R, class F, class A> R operator()(type<R>, F const & f, A & a, long) const { return unwrapper<F const>::unwrap(f, 0)(a[base_type::a1_]); } template<class F, class A> void operator()(type<void>, F & f, A & a, int) { unwrapper<F>::unwrap(f, 0)(a[base_type::a1_]); } template<class F, class A> void operator()(type<void>, F const & f, A & a, int) const { unwrapper<F const>::unwrap(f, 0)(a[base_type::a1_]); } template<class V> void accept(V & v) const { base_type::accept(v); } bool operator==(list1 const & rhs) const { return ref_compare(base_type::a1_, rhs.a1_, 0); } }; struct logical_and; struct logical_or; template< class A1, class A2 > class list2: private storage2< A1, A2 > { private: typedef storage2< A1, A2 > base_type; public: list2( A1 a1, A2 a2 ): base_type( a1, a2 ) {} A1 operator[] (boost::arg<1>) const { return base_type::a1_; } A2 operator[] (boost::arg<2>) const { return base_type::a2_; } A1 operator[] (boost::arg<1> (*) ()) const { return base_type::a1_; } A2 operator[] (boost::arg<2> (*) ()) const { return base_type::a2_; } template<class T> T & operator[] (_bi::value<T> & v) const { return v.get(); } template<class T> T const & operator[] (_bi::value<T> const & v) const { return v.get(); } template<class T> T & operator[] (reference_wrapper<T> const & v) const { return v.get(); } template<class R, class F, class L> typename result_traits<R, F>::type operator[] (bind_t<R, F, L> & b) const { return b.eval(*this); } template<class R, class F, class L> typename result_traits<R, F>::type operator[] (bind_t<R, F, L> const & b) const { return b.eval(*this); } template<class R, class F, class A> R operator()(type<R>, F & f, A & a, long) { return unwrapper<F>::unwrap(f, 0)(a[base_type::a1_], a[base_type::a2_]); } template<class R, class F, class A> R operator()(type<R>, F const & f, A & a, long) const { return unwrapper<F const>::unwrap(f, 0)(a[base_type::a1_], a[base_type::a2_]); } template<class F, class A> void operator()(type<void>, F & f, A & a, int) { unwrapper<F>::unwrap(f, 0)(a[base_type::a1_], a[base_type::a2_]); } template<class F, class A> void operator()(type<void>, F const & f, A & a, int) const { unwrapper<F const>::unwrap(f, 0)(a[base_type::a1_], a[base_type::a2_]); } template<class A> bool operator()( type<bool>, logical_and & /*f*/, A & a, int ) { return a[ base_type::a1_ ] && a[ base_type::a2_ ]; } template<class A> bool operator()( type<bool>, logical_and const & /*f*/, A & a, int ) const { return a[ base_type::a1_ ] && a[ base_type::a2_ ]; } template<class A> bool operator()( type<bool>, logical_or & /*f*/, A & a, int ) { return a[ base_type::a1_ ] || a[ base_type::a2_ ]; } template<class A> bool operator()( type<bool>, logical_or const & /*f*/, A & a, int ) const { return a[ base_type::a1_ ] || a[ base_type::a2_ ]; } template<class V> void accept(V & v) const { base_type::accept(v); } bool operator==(list2 const & rhs) const { return ref_compare(base_type::a1_, rhs.a1_, 0) && ref_compare(base_type::a2_, rhs.a2_, 0); } }; template< class A1, class A2, class A3 > class list3: private storage3< A1, A2, A3 > { private: typedef storage3< A1, A2, A3 > base_type; public: list3( A1 a1, A2 a2, A3 a3 ): base_type( a1, a2, a3 ) {} A1 operator[] (boost::arg<1>) const { return base_type::a1_; } A2 operator[] (boost::arg<2>) const { return base_type::a2_; } A3 operator[] (boost::arg<3>) const { return base_type::a3_; } A1 operator[] (boost::arg<1> (*) ()) const { return base_type::a1_; } A2 operator[] (boost::arg<2> (*) ()) const { return base_type::a2_; } A3 operator[] (boost::arg<3> (*) ()) const { return base_type::a3_; } template<class T> T & operator[] (_bi::value<T> & v) const { return v.get(); } template<class T> T const & operator[] (_bi::value<T> const & v) const { return v.get(); } template<class T> T & operator[] (reference_wrapper<T> const & v) const { return v.get(); } template<class R, class F, class L> typename result_traits<R, F>::type operator[] (bind_t<R, F, L> & b) const { return b.eval(*this); } template<class R, class F, class L> typename result_traits<R, F>::type operator[] (bind_t<R, F, L> const & b) const { return b.eval(*this); } template<class R, class F, class A> R operator()(type<R>, F & f, A & a, long) { return unwrapper<F>::unwrap(f, 0)(a[base_type::a1_], a[base_type::a2_], a[base_type::a3_]); } template<class R, class F, class A> R operator()(type<R>, F const & f, A & a, long) const { return unwrapper<F const>::unwrap(f, 0)(a[base_type::a1_], a[base_type::a2_], a[base_type::a3_]); } template<class F, class A> void operator()(type<void>, F & f, A & a, int) { unwrapper<F>::unwrap(f, 0)(a[base_type::a1_], a[base_type::a2_], a[base_type::a3_]); } template<class F, class A> void operator()(type<void>, F const & f, A & a, int) const { unwrapper<F const>::unwrap(f, 0)(a[base_type::a1_], a[base_type::a2_], a[base_type::a3_]); } template<class V> void accept(V & v) const { base_type::accept(v); } bool operator==(list3 const & rhs) const { return ref_compare( base_type::a1_, rhs.a1_, 0 ) && ref_compare( base_type::a2_, rhs.a2_, 0 ) && ref_compare( base_type::a3_, rhs.a3_, 0 ); } }; template< class A1, class A2, class A3, class A4 > class list4: private storage4< A1, A2, A3, A4 > { private: typedef storage4< A1, A2, A3, A4 > base_type; public: list4( A1 a1, A2 a2, A3 a3, A4 a4 ): base_type( a1, a2, a3, a4 ) {} A1 operator[] (boost::arg<1>) const { return base_type::a1_; } A2 operator[] (boost::arg<2>) const { return base_type::a2_; } A3 operator[] (boost::arg<3>) const { return base_type::a3_; } A4 operator[] (boost::arg<4>) const { return base_type::a4_; } A1 operator[] (boost::arg<1> (*) ()) const { return base_type::a1_; } A2 operator[] (boost::arg<2> (*) ()) const { return base_type::a2_; } A3 operator[] (boost::arg<3> (*) ()) const { return base_type::a3_; } A4 operator[] (boost::arg<4> (*) ()) const { return base_type::a4_; } template<class T> T & operator[] (_bi::value<T> & v) const { return v.get(); } template<class T> T const & operator[] (_bi::value<T> const & v) const { return v.get(); } template<class T> T & operator[] (reference_wrapper<T> const & v) const { return v.get(); } template<class R, class F, class L> typename result_traits<R, F>::type operator[] (bind_t<R, F, L> & b) const { return b.eval(*this); } template<class R, class F, class L> typename result_traits<R, F>::type operator[] (bind_t<R, F, L> const & b) const { return b.eval(*this); } template<class R, class F, class A> R operator()(type<R>, F & f, A & a, long) { return unwrapper<F>::unwrap(f, 0)(a[base_type::a1_], a[base_type::a2_], a[base_type::a3_], a[base_type::a4_]); } template<class R, class F, class A> R operator()(type<R>, F const & f, A & a, long) const { return unwrapper<F const>::unwrap(f, 0)(a[base_type::a1_], a[base_type::a2_], a[base_type::a3_], a[base_type::a4_]); } template<class F, class A> void operator()(type<void>, F & f, A & a, int) { unwrapper<F>::unwrap(f, 0)(a[base_type::a1_], a[base_type::a2_], a[base_type::a3_], a[base_type::a4_]); } template<class F, class A> void operator()(type<void>, F const & f, A & a, int) const { unwrapper<F const>::unwrap(f, 0)(a[base_type::a1_], a[base_type::a2_], a[base_type::a3_], a[base_type::a4_]); } template<class V> void accept(V & v) const { base_type::accept(v); } bool operator==(list4 const & rhs) const { return ref_compare( base_type::a1_, rhs.a1_, 0 ) && ref_compare( base_type::a2_, rhs.a2_, 0 ) && ref_compare( base_type::a3_, rhs.a3_, 0 ) && ref_compare( base_type::a4_, rhs.a4_, 0 ); } }; template< class A1, class A2, class A3, class A4, class A5 > class list5: private storage5< A1, A2, A3, A4, A5 > { private: typedef storage5< A1, A2, A3, A4, A5 > base_type; public: list5( A1 a1, A2 a2, A3 a3, A4 a4, A5 a5 ): base_type( a1, a2, a3, a4, a5 ) {} A1 operator[] (boost::arg<1>) const { return base_type::a1_; } A2 operator[] (boost::arg<2>) const { return base_type::a2_; } A3 operator[] (boost::arg<3>) const { return base_type::a3_; } A4 operator[] (boost::arg<4>) const { return base_type::a4_; } A5 operator[] (boost::arg<5>) const { return base_type::a5_; } A1 operator[] (boost::arg<1> (*) ()) const { return base_type::a1_; } A2 operator[] (boost::arg<2> (*) ()) const { return base_type::a2_; } A3 operator[] (boost::arg<3> (*) ()) const { return base_type::a3_; } A4 operator[] (boost::arg<4> (*) ()) const { return base_type::a4_; } A5 operator[] (boost::arg<5> (*) ()) const { return base_type::a5_; } template<class T> T & operator[] (_bi::value<T> & v) const { return v.get(); } template<class T> T const & operator[] (_bi::value<T> const & v) const { return v.get(); } template<class T> T & operator[] (reference_wrapper<T> const & v) const { return v.get(); } template<class R, class F, class L> typename result_traits<R, F>::type operator[] (bind_t<R, F, L> & b) const { return b.eval(*this); } template<class R, class F, class L> typename result_traits<R, F>::type operator[] (bind_t<R, F, L> const & b) const { return b.eval(*this); } template<class R, class F, class A> R operator()(type<R>, F & f, A & a, long) { return unwrapper<F>::unwrap(f, 0)(a[base_type::a1_], a[base_type::a2_], a[base_type::a3_], a[base_type::a4_], a[base_type::a5_]); } template<class R, class F, class A> R operator()(type<R>, F const & f, A & a, long) const { return unwrapper<F const>::unwrap(f, 0)(a[base_type::a1_], a[base_type::a2_], a[base_type::a3_], a[base_type::a4_], a[base_type::a5_]); } template<class F, class A> void operator()(type<void>, F & f, A & a, int) { unwrapper<F>::unwrap(f, 0)(a[base_type::a1_], a[base_type::a2_], a[base_type::a3_], a[base_type::a4_], a[base_type::a5_]); } template<class F, class A> void operator()(type<void>, F const & f, A & a, int) const { unwrapper<F const>::unwrap(f, 0)(a[base_type::a1_], a[base_type::a2_], a[base_type::a3_], a[base_type::a4_], a[base_type::a5_]); } template<class V> void accept(V & v) const { base_type::accept(v); } bool operator==(list5 const & rhs) const { return ref_compare( base_type::a1_, rhs.a1_, 0 ) && ref_compare( base_type::a2_, rhs.a2_, 0 ) && ref_compare( base_type::a3_, rhs.a3_, 0 ) && ref_compare( base_type::a4_, rhs.a4_, 0 ) && ref_compare( base_type::a5_, rhs.a5_, 0 ); } }; template<class A1, class A2, class A3, class A4, class A5, class A6> class list6: private storage6< A1, A2, A3, A4, A5, A6 > { private: typedef storage6< A1, A2, A3, A4, A5, A6 > base_type; public: list6( A1 a1, A2 a2, A3 a3, A4 a4, A5 a5, A6 a6 ): base_type( a1, a2, a3, a4, a5, a6 ) {} A1 operator[] (boost::arg<1>) const { return base_type::a1_; } A2 operator[] (boost::arg<2>) const { return base_type::a2_; } A3 operator[] (boost::arg<3>) const { return base_type::a3_; } A4 operator[] (boost::arg<4>) const { return base_type::a4_; } A5 operator[] (boost::arg<5>) const { return base_type::a5_; } A6 operator[] (boost::arg<6>) const { return base_type::a6_; } A1 operator[] (boost::arg<1> (*) ()) const { return base_type::a1_; } A2 operator[] (boost::arg<2> (*) ()) const { return base_type::a2_; } A3 operator[] (boost::arg<3> (*) ()) const { return base_type::a3_; } A4 operator[] (boost::arg<4> (*) ()) const { return base_type::a4_; } A5 operator[] (boost::arg<5> (*) ()) const { return base_type::a5_; } A6 operator[] (boost::arg<6> (*) ()) const { return base_type::a6_; } template<class T> T & operator[] (_bi::value<T> & v) const { return v.get(); } template<class T> T const & operator[] (_bi::value<T> const & v) const { return v.get(); } template<class T> T & operator[] (reference_wrapper<T> const & v) const { return v.get(); } template<class R, class F, class L> typename result_traits<R, F>::type operator[] (bind_t<R, F, L> & b) const { return b.eval(*this); } template<class R, class F, class L> typename result_traits<R, F>::type operator[] (bind_t<R, F, L> const & b) const { return b.eval(*this); } template<class R, class F, class A> R operator()(type<R>, F & f, A & a, long) { return unwrapper<F>::unwrap(f, 0)(a[base_type::a1_], a[base_type::a2_], a[base_type::a3_], a[base_type::a4_], a[base_type::a5_], a[base_type::a6_]); } template<class R, class F, class A> R operator()(type<R>, F const & f, A & a, long) const { return unwrapper<F const>::unwrap(f, 0)(a[base_type::a1_], a[base_type::a2_], a[base_type::a3_], a[base_type::a4_], a[base_type::a5_], a[base_type::a6_]); } template<class F, class A> void operator()(type<void>, F & f, A & a, int) { unwrapper<F>::unwrap(f, 0)(a[base_type::a1_], a[base_type::a2_], a[base_type::a3_], a[base_type::a4_], a[base_type::a5_], a[base_type::a6_]); } template<class F, class A> void operator()(type<void>, F const & f, A & a, int) const { unwrapper<F const>::unwrap(f, 0)(a[base_type::a1_], a[base_type::a2_], a[base_type::a3_], a[base_type::a4_], a[base_type::a5_], a[base_type::a6_]); } template<class V> void accept(V & v) const { base_type::accept(v); } bool operator==(list6 const & rhs) const { return ref_compare( base_type::a1_, rhs.a1_, 0 ) && ref_compare( base_type::a2_, rhs.a2_, 0 ) && ref_compare( base_type::a3_, rhs.a3_, 0 ) && ref_compare( base_type::a4_, rhs.a4_, 0 ) && ref_compare( base_type::a5_, rhs.a5_, 0 ) && ref_compare( base_type::a6_, rhs.a6_, 0 ); } }; template<class A1, class A2, class A3, class A4, class A5, class A6, class A7> class list7: private storage7< A1, A2, A3, A4, A5, A6, A7 > { private: typedef storage7< A1, A2, A3, A4, A5, A6, A7 > base_type; public: list7( A1 a1, A2 a2, A3 a3, A4 a4, A5 a5, A6 a6, A7 a7 ): base_type( a1, a2, a3, a4, a5, a6, a7 ) {} A1 operator[] (boost::arg<1>) const { return base_type::a1_; } A2 operator[] (boost::arg<2>) const { return base_type::a2_; } A3 operator[] (boost::arg<3>) const { return base_type::a3_; } A4 operator[] (boost::arg<4>) const { return base_type::a4_; } A5 operator[] (boost::arg<5>) const { return base_type::a5_; } A6 operator[] (boost::arg<6>) const { return base_type::a6_; } A7 operator[] (boost::arg<7>) const { return base_type::a7_; } A1 operator[] (boost::arg<1> (*) ()) const { return base_type::a1_; } A2 operator[] (boost::arg<2> (*) ()) const { return base_type::a2_; } A3 operator[] (boost::arg<3> (*) ()) const { return base_type::a3_; } A4 operator[] (boost::arg<4> (*) ()) const { return base_type::a4_; } A5 operator[] (boost::arg<5> (*) ()) const { return base_type::a5_; } A6 operator[] (boost::arg<6> (*) ()) const { return base_type::a6_; } A7 operator[] (boost::arg<7> (*) ()) const { return base_type::a7_; } template<class T> T & operator[] (_bi::value<T> & v) const { return v.get(); } template<class T> T const & operator[] (_bi::value<T> const & v) const { return v.get(); } template<class T> T & operator[] (reference_wrapper<T> const & v) const { return v.get(); } template<class R, class F, class L> typename result_traits<R, F>::type operator[] (bind_t<R, F, L> & b) const { return b.eval(*this); } template<class R, class F, class L> typename result_traits<R, F>::type operator[] (bind_t<R, F, L> const & b) const { return b.eval(*this); } template<class R, class F, class A> R operator()(type<R>, F & f, A & a, long) { return unwrapper<F>::unwrap(f, 0)(a[base_type::a1_], a[base_type::a2_], a[base_type::a3_], a[base_type::a4_], a[base_type::a5_], a[base_type::a6_], a[base_type::a7_]); } template<class R, class F, class A> R operator()(type<R>, F const & f, A & a, long) const { return unwrapper<F const>::unwrap(f, 0)(a[base_type::a1_], a[base_type::a2_], a[base_type::a3_], a[base_type::a4_], a[base_type::a5_], a[base_type::a6_], a[base_type::a7_]); } template<class F, class A> void operator()(type<void>, F & f, A & a, int) { unwrapper<F>::unwrap(f, 0)(a[base_type::a1_], a[base_type::a2_], a[base_type::a3_], a[base_type::a4_], a[base_type::a5_], a[base_type::a6_], a[base_type::a7_]); } template<class F, class A> void operator()(type<void>, F const & f, A & a, int) const { unwrapper<F const>::unwrap(f, 0)(a[base_type::a1_], a[base_type::a2_], a[base_type::a3_], a[base_type::a4_], a[base_type::a5_], a[base_type::a6_], a[base_type::a7_]); } template<class V> void accept(V & v) const { base_type::accept(v); } bool operator==(list7 const & rhs) const { return ref_compare( base_type::a1_, rhs.a1_, 0 ) && ref_compare( base_type::a2_, rhs.a2_, 0 ) && ref_compare( base_type::a3_, rhs.a3_, 0 ) && ref_compare( base_type::a4_, rhs.a4_, 0 ) && ref_compare( base_type::a5_, rhs.a5_, 0 ) && ref_compare( base_type::a6_, rhs.a6_, 0 ) && ref_compare( base_type::a7_, rhs.a7_, 0 ); } }; template< class A1, class A2, class A3, class A4, class A5, class A6, class A7, class A8 > class list8: private storage8< A1, A2, A3, A4, A5, A6, A7, A8 > { private: typedef storage8< A1, A2, A3, A4, A5, A6, A7, A8 > base_type; public: list8( A1 a1, A2 a2, A3 a3, A4 a4, A5 a5, A6 a6, A7 a7, A8 a8 ): base_type( a1, a2, a3, a4, a5, a6, a7, a8 ) {} A1 operator[] (boost::arg<1>) const { return base_type::a1_; } A2 operator[] (boost::arg<2>) const { return base_type::a2_; } A3 operator[] (boost::arg<3>) const { return base_type::a3_; } A4 operator[] (boost::arg<4>) const { return base_type::a4_; } A5 operator[] (boost::arg<5>) const { return base_type::a5_; } A6 operator[] (boost::arg<6>) const { return base_type::a6_; } A7 operator[] (boost::arg<7>) const { return base_type::a7_; } A8 operator[] (boost::arg<8>) const { return base_type::a8_; } A1 operator[] (boost::arg<1> (*) ()) const { return base_type::a1_; } A2 operator[] (boost::arg<2> (*) ()) const { return base_type::a2_; } A3 operator[] (boost::arg<3> (*) ()) const { return base_type::a3_; } A4 operator[] (boost::arg<4> (*) ()) const { return base_type::a4_; } A5 operator[] (boost::arg<5> (*) ()) const { return base_type::a5_; } A6 operator[] (boost::arg<6> (*) ()) const { return base_type::a6_; } A7 operator[] (boost::arg<7> (*) ()) const { return base_type::a7_; } A8 operator[] (boost::arg<8> (*) ()) const { return base_type::a8_; } template<class T> T & operator[] (_bi::value<T> & v) const { return v.get(); } template<class T> T const & operator[] (_bi::value<T> const & v) const { return v.get(); } template<class T> T & operator[] (reference_wrapper<T> const & v) const { return v.get(); } template<class R, class F, class L> typename result_traits<R, F>::type operator[] (bind_t<R, F, L> & b) const { return b.eval(*this); } template<class R, class F, class L> typename result_traits<R, F>::type operator[] (bind_t<R, F, L> const & b) const { return b.eval(*this); } template<class R, class F, class A> R operator()(type<R>, F & f, A & a, long) { return unwrapper<F>::unwrap(f, 0)(a[base_type::a1_], a[base_type::a2_], a[base_type::a3_], a[base_type::a4_], a[base_type::a5_], a[base_type::a6_], a[base_type::a7_], a[base_type::a8_]); } template<class R, class F, class A> R operator()(type<R>, F const & f, A & a, long) const { return unwrapper<F const>::unwrap(f, 0)(a[base_type::a1_], a[base_type::a2_], a[base_type::a3_], a[base_type::a4_], a[base_type::a5_], a[base_type::a6_], a[base_type::a7_], a[base_type::a8_]); } template<class F, class A> void operator()(type<void>, F & f, A & a, int) { unwrapper<F>::unwrap(f, 0)(a[base_type::a1_], a[base_type::a2_], a[base_type::a3_], a[base_type::a4_], a[base_type::a5_], a[base_type::a6_], a[base_type::a7_], a[base_type::a8_]); } template<class F, class A> void operator()(type<void>, F const & f, A & a, int) const { unwrapper<F const>::unwrap(f, 0)(a[base_type::a1_], a[base_type::a2_], a[base_type::a3_], a[base_type::a4_], a[base_type::a5_], a[base_type::a6_], a[base_type::a7_], a[base_type::a8_]); } template<class V> void accept(V & v) const { base_type::accept(v); } bool operator==(list8 const & rhs) const { return ref_compare( base_type::a1_, rhs.a1_, 0 ) && ref_compare( base_type::a2_, rhs.a2_, 0 ) && ref_compare( base_type::a3_, rhs.a3_, 0 ) && ref_compare( base_type::a4_, rhs.a4_, 0 ) && ref_compare( base_type::a5_, rhs.a5_, 0 ) && ref_compare( base_type::a6_, rhs.a6_, 0 ) && ref_compare( base_type::a7_, rhs.a7_, 0 ) && ref_compare( base_type::a8_, rhs.a8_, 0 ); } }; template<class A1, class A2, class A3, class A4, class A5, class A6, class A7, class A8, class A9> class list9: private storage9< A1, A2, A3, A4, A5, A6, A7, A8, A9 > { private: typedef storage9< A1, A2, A3, A4, A5, A6, A7, A8, A9 > base_type; public: list9( A1 a1, A2 a2, A3 a3, A4 a4, A5 a5, A6 a6, A7 a7, A8 a8, A9 a9 ): base_type( a1, a2, a3, a4, a5, a6, a7, a8, a9 ) {} A1 operator[] (boost::arg<1>) const { return base_type::a1_; } A2 operator[] (boost::arg<2>) const { return base_type::a2_; } A3 operator[] (boost::arg<3>) const { return base_type::a3_; } A4 operator[] (boost::arg<4>) const { return base_type::a4_; } A5 operator[] (boost::arg<5>) const { return base_type::a5_; } A6 operator[] (boost::arg<6>) const { return base_type::a6_; } A7 operator[] (boost::arg<7>) const { return base_type::a7_; } A8 operator[] (boost::arg<8>) const { return base_type::a8_; } A9 operator[] (boost::arg<9>) const { return base_type::a9_; } A1 operator[] (boost::arg<1> (*) ()) const { return base_type::a1_; } A2 operator[] (boost::arg<2> (*) ()) const { return base_type::a2_; } A3 operator[] (boost::arg<3> (*) ()) const { return base_type::a3_; } A4 operator[] (boost::arg<4> (*) ()) const { return base_type::a4_; } A5 operator[] (boost::arg<5> (*) ()) const { return base_type::a5_; } A6 operator[] (boost::arg<6> (*) ()) const { return base_type::a6_; } A7 operator[] (boost::arg<7> (*) ()) const { return base_type::a7_; } A8 operator[] (boost::arg<8> (*) ()) const { return base_type::a8_; } A9 operator[] (boost::arg<9> (*) ()) const { return base_type::a9_; } template<class T> T & operator[] (_bi::value<T> & v) const { return v.get(); } template<class T> T const & operator[] (_bi::value<T> const & v) const { return v.get(); } template<class T> T & operator[] (reference_wrapper<T> const & v) const { return v.get(); } template<class R, class F, class L> typename result_traits<R, F>::type operator[] (bind_t<R, F, L> & b) const { return b.eval(*this); } template<class R, class F, class L> typename result_traits<R, F>::type operator[] (bind_t<R, F, L> const & b) const { return b.eval(*this); } template<class R, class F, class A> R operator()(type<R>, F & f, A & a, long) { return unwrapper<F>::unwrap(f, 0)(a[base_type::a1_], a[base_type::a2_], a[base_type::a3_], a[base_type::a4_], a[base_type::a5_], a[base_type::a6_], a[base_type::a7_], a[base_type::a8_], a[base_type::a9_]); } template<class R, class F, class A> R operator()(type<R>, F const & f, A & a, long) const { return unwrapper<F const>::unwrap(f, 0)(a[base_type::a1_], a[base_type::a2_], a[base_type::a3_], a[base_type::a4_], a[base_type::a5_], a[base_type::a6_], a[base_type::a7_], a[base_type::a8_], a[base_type::a9_]); } template<class F, class A> void operator()(type<void>, F & f, A & a, int) { unwrapper<F>::unwrap(f, 0)(a[base_type::a1_], a[base_type::a2_], a[base_type::a3_], a[base_type::a4_], a[base_type::a5_], a[base_type::a6_], a[base_type::a7_], a[base_type::a8_], a[base_type::a9_]); } template<class F, class A> void operator()(type<void>, F const & f, A & a, int) const { unwrapper<F const>::unwrap(f, 0)(a[base_type::a1_], a[base_type::a2_], a[base_type::a3_], a[base_type::a4_], a[base_type::a5_], a[base_type::a6_], a[base_type::a7_], a[base_type::a8_], a[base_type::a9_]); } template<class V> void accept(V & v) const { base_type::accept(v); } bool operator==(list9 const & rhs) const { return ref_compare( base_type::a1_, rhs.a1_, 0 ) && ref_compare( base_type::a2_, rhs.a2_, 0 ) && ref_compare( base_type::a3_, rhs.a3_, 0 ) && ref_compare( base_type::a4_, rhs.a4_, 0 ) && ref_compare( base_type::a5_, rhs.a5_, 0 ) && ref_compare( base_type::a6_, rhs.a6_, 0 ) && ref_compare( base_type::a7_, rhs.a7_, 0 ) && ref_compare( base_type::a8_, rhs.a8_, 0 ) && ref_compare( base_type::a9_, rhs.a9_, 0 ); } }; #ifdef BOOST_MSVC #pragma warning(pop) #endif // bind_t #ifndef BOOST_NO_VOID_RETURNS template<class R, class F, class L> class bind_t { public: typedef bind_t this_type; bind_t(F f, L const & l): f_(f), l_(l) {} #define BOOST_BIND_RETURN return #include <boost/bind/bind_template.hpp> #undef BOOST_BIND_RETURN }; #else template<class R> struct bind_t_generator { template<class F, class L> class implementation { public: typedef implementation this_type; implementation(F f, L const & l): f_(f), l_(l) {} #define BOOST_BIND_RETURN return #include <boost/bind/bind_template.hpp> #undef BOOST_BIND_RETURN }; }; template<> struct bind_t_generator<void> { template<class F, class L> class implementation { private: typedef void R; public: typedef implementation this_type; implementation(F f, L const & l): f_(f), l_(l) {} #define BOOST_BIND_RETURN #include <boost/bind/bind_template.hpp> #undef BOOST_BIND_RETURN }; }; template<class R2, class F, class L> class bind_t: public bind_t_generator<R2>::BOOST_NESTED_TEMPLATE implementation<F, L> { public: bind_t(F f, L const & l): bind_t_generator<R2>::BOOST_NESTED_TEMPLATE implementation<F, L>(f, l) {} }; #endif // function_equal #ifndef BOOST_NO_ARGUMENT_DEPENDENT_LOOKUP // put overloads in _bi, rely on ADL # ifndef BOOST_NO_FUNCTION_TEMPLATE_ORDERING template<class R, class F, class L> bool function_equal( bind_t<R, F, L> const & a, bind_t<R, F, L> const & b ) { return a.compare(b); } # else template<class R, class F, class L> bool function_equal_impl( bind_t<R, F, L> const & a, bind_t<R, F, L> const & b, int ) { return a.compare(b); } # endif // #ifndef BOOST_NO_FUNCTION_TEMPLATE_ORDERING #else // BOOST_NO_ARGUMENT_DEPENDENT_LOOKUP // put overloads in boost } // namespace _bi # ifndef BOOST_NO_FUNCTION_TEMPLATE_ORDERING template<class R, class F, class L> bool function_equal( _bi::bind_t<R, F, L> const & a, _bi::bind_t<R, F, L> const & b ) { return a.compare(b); } # else template<class R, class F, class L> bool function_equal_impl( _bi::bind_t<R, F, L> const & a, _bi::bind_t<R, F, L> const & b, int ) { return a.compare(b); } # endif // #ifndef BOOST_NO_FUNCTION_TEMPLATE_ORDERING namespace _bi { #endif // BOOST_NO_ARGUMENT_DEPENDENT_LOOKUP // add_value #if !defined(BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION) || (__SUNPRO_CC >= 0x530) #if defined( __BORLANDC__ ) && BOOST_WORKAROUND( __BORLANDC__, BOOST_TESTED_AT(0x582) ) template<class T> struct add_value { typedef _bi::value<T> type; }; #else template< class T, int I > struct add_value_2 { typedef boost::arg<I> type; }; template< class T > struct add_value_2< T, 0 > { typedef _bi::value< T > type; }; template<class T> struct add_value { typedef typename add_value_2< T, boost::is_placeholder< T >::value >::type type; }; #endif template<class T> struct add_value< value<T> > { typedef _bi::value<T> type; }; template<class T> struct add_value< reference_wrapper<T> > { typedef reference_wrapper<T> type; }; template<int I> struct add_value< arg<I> > { typedef boost::arg<I> type; }; template<int I> struct add_value< arg<I> (*) () > { typedef boost::arg<I> (*type) (); }; template<class R, class F, class L> struct add_value< bind_t<R, F, L> > { typedef bind_t<R, F, L> type; }; #else template<int I> struct _avt_0; template<> struct _avt_0<1> { template<class T> struct inner { typedef T type; }; }; template<> struct _avt_0<2> { template<class T> struct inner { typedef value<T> type; }; }; typedef char (&_avt_r1) [1]; typedef char (&_avt_r2) [2]; template<class T> _avt_r1 _avt_f(value<T>); template<class T> _avt_r1 _avt_f(reference_wrapper<T>); template<int I> _avt_r1 _avt_f(arg<I>); template<int I> _avt_r1 _avt_f(arg<I> (*) ()); template<class R, class F, class L> _avt_r1 _avt_f(bind_t<R, F, L>); _avt_r2 _avt_f(...); template<class T> struct add_value { static T t(); typedef typename _avt_0<sizeof(_avt_f(t()))>::template inner<T>::type type; }; #endif // list_av_N template<class A1> struct list_av_1 { typedef typename add_value<A1>::type B1; typedef list1<B1> type; }; template<class A1, class A2> struct list_av_2 { typedef typename add_value<A1>::type B1; typedef typename add_value<A2>::type B2; typedef list2<B1, B2> type; }; template<class A1, class A2, class A3> struct list_av_3 { typedef typename add_value<A1>::type B1; typedef typename add_value<A2>::type B2; typedef typename add_value<A3>::type B3; typedef list3<B1, B2, B3> type; }; template<class A1, class A2, class A3, class A4> struct list_av_4 { typedef typename add_value<A1>::type B1; typedef typename add_value<A2>::type B2; typedef typename add_value<A3>::type B3; typedef typename add_value<A4>::type B4; typedef list4<B1, B2, B3, B4> type; }; template<class A1, class A2, class A3, class A4, class A5> struct list_av_5 { typedef typename add_value<A1>::type B1; typedef typename add_value<A2>::type B2; typedef typename add_value<A3>::type B3; typedef typename add_value<A4>::type B4; typedef typename add_value<A5>::type B5; typedef list5<B1, B2, B3, B4, B5> type; }; template<class A1, class A2, class A3, class A4, class A5, class A6> struct list_av_6 { typedef typename add_value<A1>::type B1; typedef typename add_value<A2>::type B2; typedef typename add_value<A3>::type B3; typedef typename add_value<A4>::type B4; typedef typename add_value<A5>::type B5; typedef typename add_value<A6>::type B6; typedef list6<B1, B2, B3, B4, B5, B6> type; }; template<class A1, class A2, class A3, class A4, class A5, class A6, class A7> struct list_av_7 { typedef typename add_value<A1>::type B1; typedef typename add_value<A2>::type B2; typedef typename add_value<A3>::type B3; typedef typename add_value<A4>::type B4; typedef typename add_value<A5>::type B5; typedef typename add_value<A6>::type B6; typedef typename add_value<A7>::type B7; typedef list7<B1, B2, B3, B4, B5, B6, B7> type; }; template<class A1, class A2, class A3, class A4, class A5, class A6, class A7, class A8> struct list_av_8 { typedef typename add_value<A1>::type B1; typedef typename add_value<A2>::type B2; typedef typename add_value<A3>::type B3; typedef typename add_value<A4>::type B4; typedef typename add_value<A5>::type B5; typedef typename add_value<A6>::type B6; typedef typename add_value<A7>::type B7; typedef typename add_value<A8>::type B8; typedef list8<B1, B2, B3, B4, B5, B6, B7, B8> type; }; template<class A1, class A2, class A3, class A4, class A5, class A6, class A7, class A8, class A9> struct list_av_9 { typedef typename add_value<A1>::type B1; typedef typename add_value<A2>::type B2; typedef typename add_value<A3>::type B3; typedef typename add_value<A4>::type B4; typedef typename add_value<A5>::type B5; typedef typename add_value<A6>::type B6; typedef typename add_value<A7>::type B7; typedef typename add_value<A8>::type B8; typedef typename add_value<A9>::type B9; typedef list9<B1, B2, B3, B4, B5, B6, B7, B8, B9> type; }; // operator! struct logical_not { template<class V> bool operator()(V const & v) const { return !v; } }; template<class R, class F, class L> bind_t< bool, logical_not, list1< bind_t<R, F, L> > > operator! (bind_t<R, F, L> const & f) { typedef list1< bind_t<R, F, L> > list_type; return bind_t<bool, logical_not, list_type> ( logical_not(), list_type(f) ); } // relational operators #define BOOST_BIND_OPERATOR( op, name ) \ \ struct name \ { \ template<class V, class W> bool operator()(V const & v, W const & w) const { return v op w; } \ }; \ \ template<class R, class F, class L, class A2> \ bind_t< bool, name, list2< bind_t<R, F, L>, typename add_value<A2>::type > > \ operator op (bind_t<R, F, L> const & f, A2 a2) \ { \ typedef typename add_value<A2>::type B2; \ typedef list2< bind_t<R, F, L>, B2> list_type; \ return bind_t<bool, name, list_type> ( name(), list_type(f, a2) ); \ } BOOST_BIND_OPERATOR( ==, equal ) BOOST_BIND_OPERATOR( !=, not_equal ) BOOST_BIND_OPERATOR( <, less ) BOOST_BIND_OPERATOR( <=, less_equal ) BOOST_BIND_OPERATOR( >, greater ) BOOST_BIND_OPERATOR( >=, greater_equal ) BOOST_BIND_OPERATOR( &&, logical_and ) BOOST_BIND_OPERATOR( ||, logical_or ) #undef BOOST_BIND_OPERATOR #if defined(__GNUC__) && BOOST_WORKAROUND(__GNUC__, < 3) // resolve ambiguity with rel_ops #define BOOST_BIND_OPERATOR( op, name ) \ \ template<class R, class F, class L> \ bind_t< bool, name, list2< bind_t<R, F, L>, bind_t<R, F, L> > > \ operator op (bind_t<R, F, L> const & f, bind_t<R, F, L> const & g) \ { \ typedef list2< bind_t<R, F, L>, bind_t<R, F, L> > list_type; \ return bind_t<bool, name, list_type> ( name(), list_type(f, g) ); \ } BOOST_BIND_OPERATOR( !=, not_equal ) BOOST_BIND_OPERATOR( <=, less_equal ) BOOST_BIND_OPERATOR( >, greater ) BOOST_BIND_OPERATOR( >=, greater_equal ) #endif // visit_each, ADL #if !defined( BOOST_NO_ARGUMENT_DEPENDENT_LOOKUP ) && !defined( __BORLANDC__ ) \ && !(defined(__GNUC__) && __GNUC__ == 3 && __GNUC_MINOR__ <= 3) template<class V, class T> void visit_each( V & v, value<T> const & t, int ) { using boost::visit_each; BOOST_BIND_VISIT_EACH( v, t.get(), 0 ); } template<class V, class R, class F, class L> void visit_each( V & v, bind_t<R, F, L> const & t, int ) { t.accept( v ); } #endif } // namespace _bi // visit_each, no ADL #if defined( BOOST_NO_ARGUMENT_DEPENDENT_LOOKUP ) || defined( __BORLANDC__ ) \ || (defined(__GNUC__) && __GNUC__ == 3 && __GNUC_MINOR__ <= 3) template<class V, class T> void visit_each( V & v, _bi::value<T> const & t, int ) { BOOST_BIND_VISIT_EACH( v, t.get(), 0 ); } template<class V, class R, class F, class L> void visit_each( V & v, _bi::bind_t<R, F, L> const & t, int ) { t.accept( v ); } #endif // is_bind_expression template< class T > struct is_bind_expression { enum _vt { value = 0 }; }; #if !defined( BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION ) template< class R, class F, class L > struct is_bind_expression< _bi::bind_t< R, F, L > > { enum _vt { value = 1 }; }; #endif // bind #ifndef BOOST_BIND #define BOOST_BIND bind #endif // generic function objects template<class R, class F> _bi::bind_t<R, F, _bi::list0> BOOST_BIND(F f) { typedef _bi::list0 list_type; return _bi::bind_t<R, F, list_type> (f, list_type()); } template<class R, class F, class A1> _bi::bind_t<R, F, typename _bi::list_av_1<A1>::type> BOOST_BIND(F f, A1 a1) { typedef typename _bi::list_av_1<A1>::type list_type; return _bi::bind_t<R, F, list_type> (f, list_type(a1)); } template<class R, class F, class A1, class A2> _bi::bind_t<R, F, typename _bi::list_av_2<A1, A2>::type> BOOST_BIND(F f, A1 a1, A2 a2) { typedef typename _bi::list_av_2<A1, A2>::type list_type; return _bi::bind_t<R, F, list_type> (f, list_type(a1, a2)); } template<class R, class F, class A1, class A2, class A3> _bi::bind_t<R, F, typename _bi::list_av_3<A1, A2, A3>::type> BOOST_BIND(F f, A1 a1, A2 a2, A3 a3) { typedef typename _bi::list_av_3<A1, A2, A3>::type list_type; return _bi::bind_t<R, F, list_type>(f, list_type(a1, a2, a3)); } template<class R, class F, class A1, class A2, class A3, class A4> _bi::bind_t<R, F, typename _bi::list_av_4<A1, A2, A3, A4>::type> BOOST_BIND(F f, A1 a1, A2 a2, A3 a3, A4 a4) { typedef typename _bi::list_av_4<A1, A2, A3, A4>::type list_type; return _bi::bind_t<R, F, list_type>(f, list_type(a1, a2, a3, a4)); } template<class R, class F, class A1, class A2, class A3, class A4, class A5> _bi::bind_t<R, F, typename _bi::list_av_5<A1, A2, A3, A4, A5>::type> BOOST_BIND(F f, A1 a1, A2 a2, A3 a3, A4 a4, A5 a5) { typedef typename _bi::list_av_5<A1, A2, A3, A4, A5>::type list_type; return _bi::bind_t<R, F, list_type>(f, list_type(a1, a2, a3, a4, a5)); } template<class R, class F, class A1, class A2, class A3, class A4, class A5, class A6> _bi::bind_t<R, F, typename _bi::list_av_6<A1, A2, A3, A4, A5, A6>::type> BOOST_BIND(F f, A1 a1, A2 a2, A3 a3, A4 a4, A5 a5, A6 a6) { typedef typename _bi::list_av_6<A1, A2, A3, A4, A5, A6>::type list_type; return _bi::bind_t<R, F, list_type>(f, list_type(a1, a2, a3, a4, a5, a6)); } template<class R, class F, class A1, class A2, class A3, class A4, class A5, class A6, class A7> _bi::bind_t<R, F, typename _bi::list_av_7<A1, A2, A3, A4, A5, A6, A7>::type> BOOST_BIND(F f, A1 a1, A2 a2, A3 a3, A4 a4, A5 a5, A6 a6, A7 a7) { typedef typename _bi::list_av_7<A1, A2, A3, A4, A5, A6, A7>::type list_type; return _bi::bind_t<R, F, list_type>(f, list_type(a1, a2, a3, a4, a5, a6, a7)); } template<class R, class F, class A1, class A2, class A3, class A4, class A5, class A6, class A7, class A8> _bi::bind_t<R, F, typename _bi::list_av_8<A1, A2, A3, A4, A5, A6, A7, A8>::type> BOOST_BIND(F f, A1 a1, A2 a2, A3 a3, A4 a4, A5 a5, A6 a6, A7 a7, A8 a8) { typedef typename _bi::list_av_8<A1, A2, A3, A4, A5, A6, A7, A8>::type list_type; return _bi::bind_t<R, F, list_type>(f, list_type(a1, a2, a3, a4, a5, a6, a7, a8)); } template<class R, class F, class A1, class A2, class A3, class A4, class A5, class A6, class A7, class A8, class A9> _bi::bind_t<R, F, typename _bi::list_av_9<A1, A2, A3, A4, A5, A6, A7, A8, A9>::type> BOOST_BIND(F f, A1 a1, A2 a2, A3 a3, A4 a4, A5 a5, A6 a6, A7 a7, A8 a8, A9 a9) { typedef typename _bi::list_av_9<A1, A2, A3, A4, A5, A6, A7, A8, A9>::type list_type; return _bi::bind_t<R, F, list_type>(f, list_type(a1, a2, a3, a4, a5, a6, a7, a8, a9)); } // generic function objects, alternative syntax template<class R, class F> _bi::bind_t<R, F, _bi::list0> BOOST_BIND(boost::type<R>, F f) { typedef _bi::list0 list_type; return _bi::bind_t<R, F, list_type> (f, list_type()); } template<class R, class F, class A1> _bi::bind_t<R, F, typename _bi::list_av_1<A1>::type> BOOST_BIND(boost::type<R>, F f, A1 a1) { typedef typename _bi::list_av_1<A1>::type list_type; return _bi::bind_t<R, F, list_type> (f, list_type(a1)); } template<class R, class F, class A1, class A2> _bi::bind_t<R, F, typename _bi::list_av_2<A1, A2>::type> BOOST_BIND(boost::type<R>, F f, A1 a1, A2 a2) { typedef typename _bi::list_av_2<A1, A2>::type list_type; return _bi::bind_t<R, F, list_type> (f, list_type(a1, a2)); } template<class R, class F, class A1, class A2, class A3> _bi::bind_t<R, F, typename _bi::list_av_3<A1, A2, A3>::type> BOOST_BIND(boost::type<R>, F f, A1 a1, A2 a2, A3 a3) { typedef typename _bi::list_av_3<A1, A2, A3>::type list_type; return _bi::bind_t<R, F, list_type>(f, list_type(a1, a2, a3)); } template<class R, class F, class A1, class A2, class A3, class A4> _bi::bind_t<R, F, typename _bi::list_av_4<A1, A2, A3, A4>::type> BOOST_BIND(boost::type<R>, F f, A1 a1, A2 a2, A3 a3, A4 a4) { typedef typename _bi::list_av_4<A1, A2, A3, A4>::type list_type; return _bi::bind_t<R, F, list_type>(f, list_type(a1, a2, a3, a4)); } template<class R, class F, class A1, class A2, class A3, class A4, class A5> _bi::bind_t<R, F, typename _bi::list_av_5<A1, A2, A3, A4, A5>::type> BOOST_BIND(boost::type<R>, F f, A1 a1, A2 a2, A3 a3, A4 a4, A5 a5) { typedef typename _bi::list_av_5<A1, A2, A3, A4, A5>::type list_type; return _bi::bind_t<R, F, list_type>(f, list_type(a1, a2, a3, a4, a5)); } template<class R, class F, class A1, class A2, class A3, class A4, class A5, class A6> _bi::bind_t<R, F, typename _bi::list_av_6<A1, A2, A3, A4, A5, A6>::type> BOOST_BIND(boost::type<R>, F f, A1 a1, A2 a2, A3 a3, A4 a4, A5 a5, A6 a6) { typedef typename _bi::list_av_6<A1, A2, A3, A4, A5, A6>::type list_type; return _bi::bind_t<R, F, list_type>(f, list_type(a1, a2, a3, a4, a5, a6)); } template<class R, class F, class A1, class A2, class A3, class A4, class A5, class A6, class A7> _bi::bind_t<R, F, typename _bi::list_av_7<A1, A2, A3, A4, A5, A6, A7>::type> BOOST_BIND(boost::type<R>, F f, A1 a1, A2 a2, A3 a3, A4 a4, A5 a5, A6 a6, A7 a7) { typedef typename _bi::list_av_7<A1, A2, A3, A4, A5, A6, A7>::type list_type; return _bi::bind_t<R, F, list_type>(f, list_type(a1, a2, a3, a4, a5, a6, a7)); } template<class R, class F, class A1, class A2, class A3, class A4, class A5, class A6, class A7, class A8> _bi::bind_t<R, F, typename _bi::list_av_8<A1, A2, A3, A4, A5, A6, A7, A8>::type> BOOST_BIND(boost::type<R>, F f, A1 a1, A2 a2, A3 a3, A4 a4, A5 a5, A6 a6, A7 a7, A8 a8) { typedef typename _bi::list_av_8<A1, A2, A3, A4, A5, A6, A7, A8>::type list_type; return _bi::bind_t<R, F, list_type>(f, list_type(a1, a2, a3, a4, a5, a6, a7, a8)); } template<class R, class F, class A1, class A2, class A3, class A4, class A5, class A6, class A7, class A8, class A9> _bi::bind_t<R, F, typename _bi::list_av_9<A1, A2, A3, A4, A5, A6, A7, A8, A9>::type> BOOST_BIND(boost::type<R>, F f, A1 a1, A2 a2, A3 a3, A4 a4, A5 a5, A6 a6, A7 a7, A8 a8, A9 a9) { typedef typename _bi::list_av_9<A1, A2, A3, A4, A5, A6, A7, A8, A9>::type list_type; return _bi::bind_t<R, F, list_type>(f, list_type(a1, a2, a3, a4, a5, a6, a7, a8, a9)); } #if !defined(BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION) && !defined(BOOST_NO_FUNCTION_TEMPLATE_ORDERING) // adaptable function objects template<class F> _bi::bind_t<_bi::unspecified, F, _bi::list0> BOOST_BIND(F f) { typedef _bi::list0 list_type; return _bi::bind_t<_bi::unspecified, F, list_type> (f, list_type()); } template<class F, class A1> _bi::bind_t<_bi::unspecified, F, typename _bi::list_av_1<A1>::type> BOOST_BIND(F f, A1 a1) { typedef typename _bi::list_av_1<A1>::type list_type; return _bi::bind_t<_bi::unspecified, F, list_type> (f, list_type(a1)); } template<class F, class A1, class A2> _bi::bind_t<_bi::unspecified, F, typename _bi::list_av_2<A1, A2>::type> BOOST_BIND(F f, A1 a1, A2 a2) { typedef typename _bi::list_av_2<A1, A2>::type list_type; return _bi::bind_t<_bi::unspecified, F, list_type> (f, list_type(a1, a2)); } template<class F, class A1, class A2, class A3> _bi::bind_t<_bi::unspecified, F, typename _bi::list_av_3<A1, A2, A3>::type> BOOST_BIND(F f, A1 a1, A2 a2, A3 a3) { typedef typename _bi::list_av_3<A1, A2, A3>::type list_type; return _bi::bind_t<_bi::unspecified, F, list_type>(f, list_type(a1, a2, a3)); } template<class F, class A1, class A2, class A3, class A4> _bi::bind_t<_bi::unspecified, F, typename _bi::list_av_4<A1, A2, A3, A4>::type> BOOST_BIND(F f, A1 a1, A2 a2, A3 a3, A4 a4) { typedef typename _bi::list_av_4<A1, A2, A3, A4>::type list_type; return _bi::bind_t<_bi::unspecified, F, list_type>(f, list_type(a1, a2, a3, a4)); } template<class F, class A1, class A2, class A3, class A4, class A5> _bi::bind_t<_bi::unspecified, F, typename _bi::list_av_5<A1, A2, A3, A4, A5>::type> BOOST_BIND(F f, A1 a1, A2 a2, A3 a3, A4 a4, A5 a5) { typedef typename _bi::list_av_5<A1, A2, A3, A4, A5>::type list_type; return _bi::bind_t<_bi::unspecified, F, list_type>(f, list_type(a1, a2, a3, a4, a5)); } template<class F, class A1, class A2, class A3, class A4, class A5, class A6> _bi::bind_t<_bi::unspecified, F, typename _bi::list_av_6<A1, A2, A3, A4, A5, A6>::type> BOOST_BIND(F f, A1 a1, A2 a2, A3 a3, A4 a4, A5 a5, A6 a6) { typedef typename _bi::list_av_6<A1, A2, A3, A4, A5, A6>::type list_type; return _bi::bind_t<_bi::unspecified, F, list_type>(f, list_type(a1, a2, a3, a4, a5, a6)); } template<class F, class A1, class A2, class A3, class A4, class A5, class A6, class A7> _bi::bind_t<_bi::unspecified, F, typename _bi::list_av_7<A1, A2, A3, A4, A5, A6, A7>::type> BOOST_BIND(F f, A1 a1, A2 a2, A3 a3, A4 a4, A5 a5, A6 a6, A7 a7) { typedef typename _bi::list_av_7<A1, A2, A3, A4, A5, A6, A7>::type list_type; return _bi::bind_t<_bi::unspecified, F, list_type>(f, list_type(a1, a2, a3, a4, a5, a6, a7)); } template<class F, class A1, class A2, class A3, class A4, class A5, class A6, class A7, class A8> _bi::bind_t<_bi::unspecified, F, typename _bi::list_av_8<A1, A2, A3, A4, A5, A6, A7, A8>::type> BOOST_BIND(F f, A1 a1, A2 a2, A3 a3, A4 a4, A5 a5, A6 a6, A7 a7, A8 a8) { typedef typename _bi::list_av_8<A1, A2, A3, A4, A5, A6, A7, A8>::type list_type; return _bi::bind_t<_bi::unspecified, F, list_type>(f, list_type(a1, a2, a3, a4, a5, a6, a7, a8)); } template<class F, class A1, class A2, class A3, class A4, class A5, class A6, class A7, class A8, class A9> _bi::bind_t<_bi::unspecified, F, typename _bi::list_av_9<A1, A2, A3, A4, A5, A6, A7, A8, A9>::type> BOOST_BIND(F f, A1 a1, A2 a2, A3 a3, A4 a4, A5 a5, A6 a6, A7 a7, A8 a8, A9 a9) { typedef typename _bi::list_av_9<A1, A2, A3, A4, A5, A6, A7, A8, A9>::type list_type; return _bi::bind_t<_bi::unspecified, F, list_type>(f, list_type(a1, a2, a3, a4, a5, a6, a7, a8, a9)); } #endif // !defined(BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION) && !defined(BOOST_NO_FUNCTION_TEMPLATE_ORDERING) // function pointers #define BOOST_BIND_CC #define BOOST_BIND_ST #include <boost/bind/bind_cc.hpp> #undef BOOST_BIND_CC #undef BOOST_BIND_ST #ifdef BOOST_BIND_ENABLE_STDCALL #define BOOST_BIND_CC __stdcall #define BOOST_BIND_ST #include <boost/bind/bind_cc.hpp> #undef BOOST_BIND_CC #undef BOOST_BIND_ST #endif #ifdef BOOST_BIND_ENABLE_FASTCALL #define BOOST_BIND_CC __fastcall #define BOOST_BIND_ST #include <boost/bind/bind_cc.hpp> #undef BOOST_BIND_CC #undef BOOST_BIND_ST #endif #ifdef BOOST_BIND_ENABLE_PASCAL #define BOOST_BIND_ST pascal #define BOOST_BIND_CC #include <boost/bind/bind_cc.hpp> #undef BOOST_BIND_ST #undef BOOST_BIND_CC #endif // member function pointers #define BOOST_BIND_MF_NAME(X) X #define BOOST_BIND_MF_CC #include <boost/bind/bind_mf_cc.hpp> #include <boost/bind/bind_mf2_cc.hpp> #undef BOOST_BIND_MF_NAME #undef BOOST_BIND_MF_CC #ifdef BOOST_MEM_FN_ENABLE_CDECL #define BOOST_BIND_MF_NAME(X) X##_cdecl #define BOOST_BIND_MF_CC __cdecl #include <boost/bind/bind_mf_cc.hpp> #include <boost/bind/bind_mf2_cc.hpp> #undef BOOST_BIND_MF_NAME #undef BOOST_BIND_MF_CC #endif #ifdef BOOST_MEM_FN_ENABLE_STDCALL #define BOOST_BIND_MF_NAME(X) X##_stdcall #define BOOST_BIND_MF_CC __stdcall #include <boost/bind/bind_mf_cc.hpp> #include <boost/bind/bind_mf2_cc.hpp> #undef BOOST_BIND_MF_NAME #undef BOOST_BIND_MF_CC #endif #ifdef BOOST_MEM_FN_ENABLE_FASTCALL #define BOOST_BIND_MF_NAME(X) X##_fastcall #define BOOST_BIND_MF_CC __fastcall #include <boost/bind/bind_mf_cc.hpp> #include <boost/bind/bind_mf2_cc.hpp> #undef BOOST_BIND_MF_NAME #undef BOOST_BIND_MF_CC #endif // data member pointers #if defined(BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION) || defined(BOOST_NO_FUNCTION_TEMPLATE_ORDERING) \ || ( defined(__BORLANDC__) && BOOST_WORKAROUND( __BORLANDC__, BOOST_TESTED_AT( 0x620 ) ) ) template<class R, class T, class A1> _bi::bind_t< R, _mfi::dm<R, T>, typename _bi::list_av_1<A1>::type > BOOST_BIND(R T::*f, A1 a1) { typedef _mfi::dm<R, T> F; typedef typename _bi::list_av_1<A1>::type list_type; return _bi::bind_t<R, F, list_type>( F(f), list_type(a1) ); } #else namespace _bi { template< class Pm, int I > struct add_cref; template< class M, class T > struct add_cref< M T::*, 0 > { typedef M type; }; template< class M, class T > struct add_cref< M T::*, 1 > { #ifdef BOOST_MSVC #pragma warning(push) #pragma warning(disable:4180) #endif typedef M const & type; #ifdef BOOST_MSVC #pragma warning(pop) #endif }; template< class R, class T > struct add_cref< R (T::*) (), 1 > { typedef void type; }; #if !defined(__IBMCPP__) || __IBMCPP_FUNC_CV_TMPL_ARG_DEDUCTION template< class R, class T > struct add_cref< R (T::*) () const, 1 > { typedef void type; }; #endif // __IBMCPP__ template<class R> struct isref { enum value_type { value = 0 }; }; template<class R> struct isref< R& > { enum value_type { value = 1 }; }; template<class R> struct isref< R* > { enum value_type { value = 1 }; }; template<class Pm, class A1> struct dm_result { typedef typename add_cref< Pm, 1 >::type type; }; template<class Pm, class R, class F, class L> struct dm_result< Pm, bind_t<R, F, L> > { typedef typename bind_t<R, F, L>::result_type result_type; typedef typename add_cref< Pm, isref< result_type >::value >::type type; }; } // namespace _bi template< class A1, class M, class T > _bi::bind_t< typename _bi::dm_result< M T::*, A1 >::type, _mfi::dm<M, T>, typename _bi::list_av_1<A1>::type > BOOST_BIND( M T::*f, A1 a1 ) { typedef typename _bi::dm_result< M T::*, A1 >::type result_type; typedef _mfi::dm<M, T> F; typedef typename _bi::list_av_1<A1>::type list_type; return _bi::bind_t< result_type, F, list_type >( F( f ), list_type( a1 ) ); } #endif } // namespace boost #ifndef BOOST_BIND_NO_PLACEHOLDERS # include <boost/bind/placeholders.hpp> #endif #ifdef BOOST_MSVC # pragma warning(default: 4512) // assignment operator could not be generated # pragma warning(pop) #endif #endif // #ifndef BOOST_BIND_BIND_HPP_INCLUDED