boost/function/function_template.hpp
// Boost.Function library // Copyright Douglas Gregor 2001-2003. Use, modification and // distribution is 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) // For more information, see http://www.boost.org // Note: this header is a header template and must NOT have multiple-inclusion // protection. #include <boost/function/detail/prologue.hpp> #define BOOST_FUNCTION_TEMPLATE_PARMS BOOST_PP_ENUM_PARAMS(BOOST_FUNCTION_NUM_ARGS, typename T) #define BOOST_FUNCTION_TEMPLATE_ARGS BOOST_PP_ENUM_PARAMS(BOOST_FUNCTION_NUM_ARGS, T) #define BOOST_FUNCTION_PARM(J,I,D) BOOST_PP_CAT(T,I) BOOST_PP_CAT(a,I) #define BOOST_FUNCTION_PARMS BOOST_PP_ENUM(BOOST_FUNCTION_NUM_ARGS,BOOST_FUNCTION_PARM,BOOST_PP_EMPTY) #define BOOST_FUNCTION_ARGS BOOST_PP_ENUM_PARAMS(BOOST_FUNCTION_NUM_ARGS, a) #define BOOST_FUNCTION_ARG_TYPE(J,I,D) \ typedef BOOST_PP_CAT(T,I) BOOST_PP_CAT(arg, BOOST_PP_CAT(BOOST_PP_INC(I),_type)); #define BOOST_FUNCTION_ARG_TYPES BOOST_PP_REPEAT(BOOST_FUNCTION_NUM_ARGS,BOOST_FUNCTION_ARG_TYPE,BOOST_PP_EMPTY) // Type of the default allocator #ifndef BOOST_NO_STD_ALLOCATOR # define BOOST_FUNCTION_DEFAULT_ALLOCATOR std::allocator<function_base> #else # define BOOST_FUNCTION_DEFAULT_ALLOCATOR int #endif // BOOST_NO_STD_ALLOCATOR // Comma if nonzero number of arguments #if BOOST_FUNCTION_NUM_ARGS == 0 # define BOOST_FUNCTION_COMMA #else # define BOOST_FUNCTION_COMMA , #endif // BOOST_FUNCTION_NUM_ARGS > 0 // Class names used in this version of the code #define BOOST_FUNCTION_FUNCTION BOOST_JOIN(function,BOOST_FUNCTION_NUM_ARGS) #define BOOST_FUNCTION_FUNCTION_INVOKER \ BOOST_JOIN(function_invoker,BOOST_FUNCTION_NUM_ARGS) #define BOOST_FUNCTION_VOID_FUNCTION_INVOKER \ BOOST_JOIN(void_function_invoker,BOOST_FUNCTION_NUM_ARGS) #define BOOST_FUNCTION_FUNCTION_OBJ_INVOKER \ BOOST_JOIN(function_obj_invoker,BOOST_FUNCTION_NUM_ARGS) #define BOOST_FUNCTION_VOID_FUNCTION_OBJ_INVOKER \ BOOST_JOIN(void_function_obj_invoker,BOOST_FUNCTION_NUM_ARGS) #define BOOST_FUNCTION_STATELESS_FUNCTION_OBJ_INVOKER \ BOOST_JOIN(stateless_function_obj_invoker,BOOST_FUNCTION_NUM_ARGS) #define BOOST_FUNCTION_STATELESS_VOID_FUNCTION_OBJ_INVOKER \ BOOST_JOIN(stateless_void_function_obj_invoker,BOOST_FUNCTION_NUM_ARGS) #define BOOST_FUNCTION_GET_FUNCTION_INVOKER \ BOOST_JOIN(get_function_invoker,BOOST_FUNCTION_NUM_ARGS) #define BOOST_FUNCTION_GET_FUNCTION_OBJ_INVOKER \ BOOST_JOIN(get_function_obj_invoker,BOOST_FUNCTION_NUM_ARGS) #define BOOST_FUNCTION_GET_STATELESS_FUNCTION_OBJ_INVOKER \ BOOST_JOIN(get_stateless_function_obj_invoker,BOOST_FUNCTION_NUM_ARGS) namespace boost { namespace detail { namespace function { template< typename FunctionPtr, typename R BOOST_FUNCTION_COMMA BOOST_FUNCTION_TEMPLATE_PARMS > struct BOOST_FUNCTION_FUNCTION_INVOKER { static R invoke(any_pointer function_ptr BOOST_FUNCTION_COMMA BOOST_FUNCTION_PARMS) { FunctionPtr f = reinterpret_cast<FunctionPtr>(function_ptr.func_ptr); return f(BOOST_FUNCTION_ARGS); } }; template< typename FunctionPtr, typename R BOOST_FUNCTION_COMMA BOOST_FUNCTION_TEMPLATE_PARMS > struct BOOST_FUNCTION_VOID_FUNCTION_INVOKER { static unusable invoke(any_pointer function_ptr BOOST_FUNCTION_COMMA BOOST_FUNCTION_PARMS) { FunctionPtr f = reinterpret_cast<FunctionPtr>(function_ptr.func_ptr); f(BOOST_FUNCTION_ARGS); return unusable(); } }; template< typename FunctionObj, typename R BOOST_FUNCTION_COMMA BOOST_FUNCTION_TEMPLATE_PARMS > struct BOOST_FUNCTION_FUNCTION_OBJ_INVOKER { static R invoke(any_pointer function_obj_ptr BOOST_FUNCTION_COMMA BOOST_FUNCTION_PARMS) { FunctionObj* f = (FunctionObj*)(function_obj_ptr.obj_ptr); return (*f)(BOOST_FUNCTION_ARGS); } }; template< typename FunctionObj, typename R BOOST_FUNCTION_COMMA BOOST_FUNCTION_TEMPLATE_PARMS > struct BOOST_FUNCTION_VOID_FUNCTION_OBJ_INVOKER { static unusable invoke(any_pointer function_obj_ptr BOOST_FUNCTION_COMMA BOOST_FUNCTION_PARMS) { FunctionObj* f = (FunctionObj*)(function_obj_ptr.obj_ptr); (*f)(BOOST_FUNCTION_ARGS); return unusable(); } }; template< typename FunctionObj, typename R BOOST_FUNCTION_COMMA BOOST_FUNCTION_TEMPLATE_PARMS > struct BOOST_FUNCTION_STATELESS_FUNCTION_OBJ_INVOKER { static R invoke(any_pointer BOOST_FUNCTION_COMMA BOOST_FUNCTION_PARMS) { FunctionObj f = FunctionObj(); return f(BOOST_FUNCTION_ARGS); } }; template< typename FunctionObj, typename R BOOST_FUNCTION_COMMA BOOST_FUNCTION_TEMPLATE_PARMS > struct BOOST_FUNCTION_STATELESS_VOID_FUNCTION_OBJ_INVOKER { static unusable invoke(any_pointer BOOST_FUNCTION_COMMA BOOST_FUNCTION_PARMS) { FunctionObj f = FunctionObj(); f(BOOST_FUNCTION_ARGS); return unusable(); } }; template< typename FunctionPtr, typename R BOOST_FUNCTION_COMMA BOOST_FUNCTION_TEMPLATE_PARMS > struct BOOST_FUNCTION_GET_FUNCTION_INVOKER { typedef typename ct_if<(is_void<R>::value), BOOST_FUNCTION_VOID_FUNCTION_INVOKER< FunctionPtr, R BOOST_FUNCTION_COMMA BOOST_FUNCTION_TEMPLATE_ARGS >, BOOST_FUNCTION_FUNCTION_INVOKER< FunctionPtr, R BOOST_FUNCTION_COMMA BOOST_FUNCTION_TEMPLATE_ARGS > >::type type; }; template< typename FunctionObj, typename R BOOST_FUNCTION_COMMA BOOST_FUNCTION_TEMPLATE_PARMS > struct BOOST_FUNCTION_GET_FUNCTION_OBJ_INVOKER { typedef typename ct_if<(is_void<R>::value), BOOST_FUNCTION_VOID_FUNCTION_OBJ_INVOKER< FunctionObj, R BOOST_FUNCTION_COMMA BOOST_FUNCTION_TEMPLATE_ARGS >, BOOST_FUNCTION_FUNCTION_OBJ_INVOKER< FunctionObj, R BOOST_FUNCTION_COMMA BOOST_FUNCTION_TEMPLATE_ARGS > >::type type; }; template< typename FunctionObj, typename R BOOST_FUNCTION_COMMA BOOST_FUNCTION_TEMPLATE_PARMS > struct BOOST_FUNCTION_GET_STATELESS_FUNCTION_OBJ_INVOKER { typedef typename ct_if<(is_void<R>::value), BOOST_FUNCTION_STATELESS_VOID_FUNCTION_OBJ_INVOKER< FunctionObj, R BOOST_FUNCTION_COMMA BOOST_FUNCTION_TEMPLATE_ARGS >, BOOST_FUNCTION_STATELESS_FUNCTION_OBJ_INVOKER< FunctionObj, R BOOST_FUNCTION_COMMA BOOST_FUNCTION_TEMPLATE_ARGS > >::type type; }; } // end namespace function } // end namespace detail template< typename R BOOST_FUNCTION_COMMA BOOST_FUNCTION_TEMPLATE_PARMS, typename Allocator = BOOST_FUNCTION_DEFAULT_ALLOCATOR > class BOOST_FUNCTION_FUNCTION : public function_base { public: typedef typename detail::function::function_return_type<R>::type internal_result_type; private: struct clear_type {}; public: BOOST_STATIC_CONSTANT(int, args = BOOST_FUNCTION_NUM_ARGS); // add signature for boost::lambda template<typename Args> struct sig { typedef internal_result_type type; }; #if BOOST_FUNCTION_NUM_ARGS == 1 typedef T0 argument_type; #elif BOOST_FUNCTION_NUM_ARGS == 2 typedef T0 first_argument_type; typedef T1 second_argument_type; #endif BOOST_STATIC_CONSTANT(int, arity = BOOST_FUNCTION_NUM_ARGS); BOOST_FUNCTION_ARG_TYPES #ifndef BOOST_NO_VOID_RETURNS typedef R result_type; #else typedef internal_result_type result_type; #endif // BOOST_NO_VOID_RETURNS typedef Allocator allocator_type; typedef BOOST_FUNCTION_FUNCTION self_type; BOOST_FUNCTION_FUNCTION() : function_base() , invoker(0) {} // MSVC chokes if the following two constructors are collapsed into // one with a default parameter. template<typename Functor> BOOST_FUNCTION_FUNCTION(Functor BOOST_FUNCTION_TARGET_FIX(const &) f #ifndef BOOST_NO_SFINAE ,typename enable_if_c< (::boost::type_traits::ice_not< (is_integral<Functor>::value)>::value), int>::type = 0 #endif // BOOST_NO_SFINAE ) : function_base(), invoker(0) { this->assign_to(f); } #ifndef BOOST_NO_SFINAE BOOST_FUNCTION_FUNCTION(clear_type*) : function_base(), invoker(0) {} #else BOOST_FUNCTION_FUNCTION(int zero) : function_base(), invoker(0) { BOOST_ASSERT(zero == 0); } #endif BOOST_FUNCTION_FUNCTION(const BOOST_FUNCTION_FUNCTION& f) : function_base(), invoker(0) { this->assign_to_own(f); } ~BOOST_FUNCTION_FUNCTION() { clear(); } #if BOOST_WORKAROUND(BOOST_MSVC, <= 1200) // MSVC 6.0 and prior require all definitions to be inline, but // these definitions can become very costly. result_type operator()(BOOST_FUNCTION_PARMS) const { if (this->empty()) boost::throw_exception(bad_function_call()); internal_result_type result = invoker(this->functor BOOST_FUNCTION_COMMA BOOST_FUNCTION_ARGS); #ifndef BOOST_NO_VOID_RETURNS return static_cast<result_type>(result); #else return result; #endif // BOOST_NO_VOID_RETURNS } #else result_type operator()(BOOST_FUNCTION_PARMS) const; #endif // The distinction between when to use BOOST_FUNCTION_FUNCTION and // when to use self_type is obnoxious. MSVC cannot handle self_type as // the return type of these assignment operators, but Borland C++ cannot // handle BOOST_FUNCTION_FUNCTION as the type of the temporary to // construct. template<typename Functor> #ifndef BOOST_NO_SFINAE typename enable_if_c< (::boost::type_traits::ice_not< (is_integral<Functor>::value)>::value), BOOST_FUNCTION_FUNCTION&>::type #else BOOST_FUNCTION_FUNCTION& #endif operator=(Functor BOOST_FUNCTION_TARGET_FIX(const &) f) { self_type(f).swap(*this); return *this; } #ifndef BOOST_NO_SFINAE BOOST_FUNCTION_FUNCTION& operator=(clear_type*) { this->clear(); return *this; } #else BOOST_FUNCTION_FUNCTION& operator=(int zero) { BOOST_ASSERT(zero == 0); this->clear(); return *this; } #endif // Assignment from another BOOST_FUNCTION_FUNCTION BOOST_FUNCTION_FUNCTION& operator=(const BOOST_FUNCTION_FUNCTION& f) { if (&f == this) return *this; self_type(f).swap(*this); return *this; } void swap(BOOST_FUNCTION_FUNCTION& other) { if (&other == this) return; std::swap(this->manager, other.manager); std::swap(this->functor, other.functor); std::swap(invoker, other.invoker); } // Clear out a target, if there is one void clear() { if (this->manager) { function_base::functor = this->manager(this->functor, detail::function::destroy_functor_tag); } this->manager = 0; invoker = 0; } #if (defined __SUNPRO_CC) && (__SUNPRO_CC <= 0x530) && !(defined BOOST_NO_COMPILER_CONFIG) // Sun C++ 5.3 can't handle the safe_bool idiom, so don't use it operator bool () const { return !this->empty(); } #else private: struct dummy { void nonnull() {}; }; typedef void (dummy::*safe_bool)(); public: operator safe_bool () const { return (this->empty())? 0 : &dummy::nonnull; } bool operator!() const { return this->empty(); } #endif private: void assign_to_own(const BOOST_FUNCTION_FUNCTION& f) { if (!f.empty()) { invoker = f.invoker; this->manager = f.manager; this->functor = f.manager(f.functor, detail::function::clone_functor_tag); } } template<typename Functor> void assign_to(Functor f) { typedef typename detail::function::get_function_tag<Functor>::type tag; this->assign_to(f, tag()); } template<typename FunctionPtr> void assign_to(FunctionPtr f, detail::function::function_ptr_tag) { clear(); if (f) { typedef typename detail::function::BOOST_FUNCTION_GET_FUNCTION_INVOKER< FunctionPtr, R BOOST_FUNCTION_COMMA BOOST_FUNCTION_TEMPLATE_ARGS >::type actual_invoker_type; invoker = &actual_invoker_type::invoke; this->manager = &detail::function::functor_manager<FunctionPtr, Allocator>::manage; this->functor = this->manager(detail::function::make_any_pointer( // should be a reinterpret cast, but some compilers // insist on giving cv-qualifiers to free functions (void (*)())(f) ), detail::function::clone_functor_tag); } } #if BOOST_FUNCTION_NUM_ARGS > 0 template<typename MemberPtr> void assign_to(MemberPtr f, detail::function::member_ptr_tag) { this->assign_to(mem_fn(f)); } #endif // BOOST_FUNCTION_NUM_ARGS > 0 template<typename FunctionObj> void assign_to(FunctionObj f, detail::function::function_obj_tag) { if (!detail::function::has_empty_target(addressof(f))) { typedef typename detail::function::BOOST_FUNCTION_GET_FUNCTION_OBJ_INVOKER< FunctionObj, R BOOST_FUNCTION_COMMA BOOST_FUNCTION_TEMPLATE_ARGS >::type actual_invoker_type; invoker = &actual_invoker_type::invoke; this->manager = &detail::function::functor_manager< FunctionObj, Allocator>::manage; #ifndef BOOST_NO_STD_ALLOCATOR typedef typename Allocator::template rebind<FunctionObj>::other rebound_allocator_type; typedef typename rebound_allocator_type::pointer pointer_type; rebound_allocator_type allocator; pointer_type copy = allocator.allocate(1); allocator.construct(copy, f); // Get back to the original pointer type FunctionObj* new_f = static_cast<FunctionObj*>(copy); #else FunctionObj* new_f = new FunctionObj(f); #endif // BOOST_NO_STD_ALLOCATOR this->functor = detail::function::make_any_pointer(static_cast<void*>(new_f)); } } template<typename FunctionObj> void assign_to(const reference_wrapper<FunctionObj>& f, detail::function::function_obj_ref_tag) { if (!detail::function::has_empty_target(f.get_pointer())) { typedef typename detail::function::BOOST_FUNCTION_GET_FUNCTION_OBJ_INVOKER< FunctionObj, R BOOST_FUNCTION_COMMA BOOST_FUNCTION_TEMPLATE_ARGS >::type actual_invoker_type; invoker = &actual_invoker_type::invoke; this->manager = &detail::function::trivial_manager<FunctionObj>::get; this->functor = this->manager( detail::function::make_any_pointer( const_cast<FunctionObj*>(f.get_pointer())), detail::function::clone_functor_tag); } } template<typename FunctionObj> void assign_to(FunctionObj, detail::function::stateless_function_obj_tag) { typedef typename detail::function:: BOOST_FUNCTION_GET_STATELESS_FUNCTION_OBJ_INVOKER< FunctionObj, R BOOST_FUNCTION_COMMA BOOST_FUNCTION_TEMPLATE_ARGS >::type actual_invoker_type; invoker = &actual_invoker_type::invoke; this->manager = &detail::function::trivial_manager<FunctionObj>::get; this->functor = detail::function::make_any_pointer(this); } typedef internal_result_type (*invoker_type)(detail::function::any_pointer BOOST_FUNCTION_COMMA BOOST_FUNCTION_TEMPLATE_ARGS); invoker_type invoker; }; template<typename R BOOST_FUNCTION_COMMA BOOST_FUNCTION_TEMPLATE_PARMS , typename Allocator> inline void swap(BOOST_FUNCTION_FUNCTION< R BOOST_FUNCTION_COMMA BOOST_FUNCTION_TEMPLATE_ARGS , Allocator >& f1, BOOST_FUNCTION_FUNCTION< R BOOST_FUNCTION_COMMA BOOST_FUNCTION_TEMPLATE_ARGS, Allocator >& f2) { f1.swap(f2); } #if !BOOST_WORKAROUND(BOOST_MSVC, <= 1200) template<typename R BOOST_FUNCTION_COMMA BOOST_FUNCTION_TEMPLATE_PARMS, typename Allocator> typename BOOST_FUNCTION_FUNCTION< R BOOST_FUNCTION_COMMA BOOST_FUNCTION_TEMPLATE_ARGS, Allocator>::result_type BOOST_FUNCTION_FUNCTION<R BOOST_FUNCTION_COMMA BOOST_FUNCTION_TEMPLATE_ARGS, Allocator> ::operator()(BOOST_FUNCTION_PARMS) const { if (this->empty()) boost::throw_exception(bad_function_call()); internal_result_type result = invoker(this->functor BOOST_FUNCTION_COMMA BOOST_FUNCTION_ARGS); # ifndef BOOST_NO_VOID_RETURNS return static_cast<result_type>(result); # else return result; # endif // BOOST_NO_VOID_RETURNS } #endif // Poison comparisons between boost::function objects of the same type. template<typename R BOOST_FUNCTION_COMMA BOOST_FUNCTION_TEMPLATE_PARMS , typename Allocator> void operator==(const BOOST_FUNCTION_FUNCTION< R BOOST_FUNCTION_COMMA BOOST_FUNCTION_TEMPLATE_ARGS , Allocator>&, const BOOST_FUNCTION_FUNCTION< R BOOST_FUNCTION_COMMA BOOST_FUNCTION_TEMPLATE_ARGS , Allocator>&); template<typename R BOOST_FUNCTION_COMMA BOOST_FUNCTION_TEMPLATE_PARMS , typename Allocator> void operator!=(const BOOST_FUNCTION_FUNCTION< R BOOST_FUNCTION_COMMA BOOST_FUNCTION_TEMPLATE_ARGS , Allocator>&, const BOOST_FUNCTION_FUNCTION< R BOOST_FUNCTION_COMMA BOOST_FUNCTION_TEMPLATE_ARGS , Allocator>&); #if !defined(BOOST_FUNCTION_NO_FUNCTION_TYPE_SYNTAX) #if BOOST_FUNCTION_NUM_ARGS == 0 #define BOOST_FUNCTION_PARTIAL_SPEC R (void) #else #define BOOST_FUNCTION_PARTIAL_SPEC R (BOOST_PP_ENUM_PARAMS(BOOST_FUNCTION_NUM_ARGS,T)) #endif template<typename R BOOST_FUNCTION_COMMA BOOST_FUNCTION_TEMPLATE_PARMS, typename Allocator> class function<BOOST_FUNCTION_PARTIAL_SPEC, Allocator> : public BOOST_FUNCTION_FUNCTION<R, BOOST_FUNCTION_TEMPLATE_ARGS BOOST_FUNCTION_COMMA Allocator> { typedef BOOST_FUNCTION_FUNCTION<R, BOOST_FUNCTION_TEMPLATE_ARGS BOOST_FUNCTION_COMMA Allocator> base_type; typedef function self_type; struct clear_type {}; public: typedef typename base_type::allocator_type allocator_type; function() : base_type() {} template<typename Functor> function(Functor f #ifndef BOOST_NO_SFINAE ,typename enable_if_c< (::boost::type_traits::ice_not< (is_integral<Functor>::value)>::value), int>::type = 0 #endif ) : base_type(f) { } #ifndef BOOST_NO_SFINAE function(clear_type*) : base_type() {} #endif function(const self_type& f) : base_type(static_cast<const base_type&>(f)){} function(const base_type& f) : base_type(static_cast<const base_type&>(f)){} self_type& operator=(const self_type& f) { self_type(f).swap(*this); return *this; } template<typename Functor> #ifndef BOOST_NO_SFINAE typename enable_if_c< (::boost::type_traits::ice_not< (is_integral<Functor>::value)>::value), self_type&>::type #else self_type& #endif operator=(Functor f) { self_type(f).swap(*this); return *this; } #ifndef BOOST_NO_SFINAE self_type& operator=(clear_type*) { this->clear(); return *this; } #endif self_type& operator=(const base_type& f) { self_type(f).swap(*this); return *this; } }; #undef BOOST_FUNCTION_PARTIAL_SPEC #endif // have partial specialization } // end namespace boost // Cleanup after ourselves... #undef BOOST_FUNCTION_DEFAULT_ALLOCATOR #undef BOOST_FUNCTION_COMMA #undef BOOST_FUNCTION_FUNCTION #undef BOOST_FUNCTION_FUNCTION_INVOKER #undef BOOST_FUNCTION_VOID_FUNCTION_INVOKER #undef BOOST_FUNCTION_FUNCTION_OBJ_INVOKER #undef BOOST_FUNCTION_VOID_FUNCTION_OBJ_INVOKER #undef BOOST_FUNCTION_STATELESS_FUNCTION_OBJ_INVOKER #undef BOOST_FUNCTION_STATELESS_VOID_FUNCTION_OBJ_INVOKER #undef BOOST_FUNCTION_GET_FUNCTION_INVOKER #undef BOOST_FUNCTION_GET_FUNCTION_OBJ_INVOKER #undef BOOST_FUNCTION_GET_STATELESS_FUNCTION_OBJ_INVOKER #undef BOOST_FUNCTION_GET_MEM_FUNCTION_INVOKER #undef BOOST_FUNCTION_TEMPLATE_PARMS #undef BOOST_FUNCTION_TEMPLATE_ARGS #undef BOOST_FUNCTION_PARMS #undef BOOST_FUNCTION_PARM #undef BOOST_FUNCTION_ARGS #undef BOOST_FUNCTION_ARG_TYPE #undef BOOST_FUNCTION_ARG_TYPES