// Copyright (C) 2006-2009, 2012 Alexander Nasonov // Copyright (C) 2012 Lorenzo Caminiti // Distributed under the Boost Software License, Version 1.0 // (see accompanying file LICENSE_1_0.txt or a copy at // http://www.boost.org/LICENSE_1_0.txt) // Home at http://www.boost.org/libs/scope_exit #ifndef FILE_boost_scope_exit_hpp_INCLUDED #define FILE_boost_scope_exit_hpp_INCLUDED #ifndef DOXYGEN #include <boost/local_function/detail/preprocessor/line_counter.hpp> #include <boost/local_function/detail/preprocessor/void_list.hpp> #include <boost/local_function/detail/preprocessor/keyword/thisunderscore.hpp> #include <boost/detail/workaround.hpp> #include <boost/mpl/assert.hpp> #include <boost/mpl/int.hpp> #include <boost/utility/enable_if.hpp> #include <boost/function.hpp> #include <boost/typeof/typeof.hpp> #include <boost/config.hpp> #include <boost/preprocessor/cat.hpp> #include <boost/preprocessor/control/iif.hpp> #include <boost/preprocessor/control/expr_iif.hpp> #include <boost/preprocessor/logical/bitor.hpp> #include <boost/preprocessor/logical/bitand.hpp> #include <boost/preprocessor/facilities/empty.hpp> #include <boost/preprocessor/facilities/is_empty.hpp> #include <boost/preprocessor/facilities/identity.hpp> #include <boost/preprocessor/punctuation/comma_if.hpp> #include <boost/preprocessor/punctuation/paren_if.hpp> #include <boost/preprocessor/seq/cat.hpp> #include <boost/preprocessor/tuple/elem.hpp> #include <boost/preprocessor/tuple/eat.hpp> #include <boost/preprocessor/list/append.hpp> #include <boost/preprocessor/list/fold_left.hpp> #include <boost/preprocessor/list/enum.hpp> #include <boost/preprocessor/list/adt.hpp> #include <boost/preprocessor/list/for_each_i.hpp> // PRIVATE/PROTECTED // // NOTE: AUX prefix and aux namespace mark "private" symbols that shall be used // only within this library; DETAIL prefix and detail namespace mark "protected" // symbols that can be used by other Boost libraries but not outside Boost. // WARNING: BOOST_SCOPE_EXIT_AUX_GCC also used by some regression test. #if defined(__GNUC__) && !defined(BOOST_INTEL) # define BOOST_SCOPE_EXIT_AUX_GCC (__GNUC__ * 100 + __GNUC_MINOR__) #else # define BOOST_SCOPE_EXIT_AUX_GCC 0 #endif #if BOOST_WORKAROUND(BOOST_SCOPE_EXIT_AUX_GCC, BOOST_TESTED_AT(413)) # define BOOST_SCOPE_EXIT_AUX_TPL_GCC_WORKAROUND_01 1 #else # define BOOST_SCOPE_EXIT_AUX_TPL_GCC_WORKAROUND_01 0 #endif #if BOOST_MSVC # define BOOST_SCOPE_EXIT_AUX_TYPEOF_THIS_MSVC_WORKAROUND_01 1 #else # define BOOST_SCOPE_EXIT_AUX_TYPEOF_THIS_MSVC_WORKAROUND_01 0 #endif // Steven Watanabe's trick with a modification suggested by Kim Barrett namespace boost { namespace scope_exit { namespace detail { // Type of a local BOOST_SCOPE_EXIT_AUX_ARGS variable. // First use in a local scope will declare the BOOST_SCOPE_EXIT_AUX_ARGS // variable, subsequent uses will be resolved as two comparisons // (cmp1 with 0 and cmp2 with BOOST_SCOPE_EXIT_AUX_ARGS). template<int Dummy = 0> struct declared { void* value; static int const cmp2 = 0; friend void operator>(int, declared const&) {} }; struct undeclared { declared<> dummy[2]; }; template<int> struct resolve; template<> struct resolve<sizeof(declared<>)> { static const int cmp1 = 0; }; template<> struct resolve<sizeof(undeclared)> { template<int> struct cmp1 { static int const cmp2 = 0; }; }; typedef void (*ref_tag)(int&); typedef void (*val_tag)(int ); template<class T, class Tag> struct member; template<class T> struct member<T,ref_tag> { T& value; #if !BOOST_SCOPE_EXIT_AUX_TPL_GCC_WORKAROUND_01 member(T& ref) : value(ref) {} #endif }; template<class T> struct member<T,val_tag> { T value; #if !BOOST_SCOPE_EXIT_AUX_TPL_GCC_WORKAROUND_01 member(T& val) : value(val) {} #endif }; template<class T> inline T& deref(T* p, ref_tag) { return *p; } template<class T> inline T& deref(T& r, val_tag) { return r; } template<class T> struct wrapper { typedef T type; }; template<class T> wrapper<T> wrap(T&); } } } // namespace #include BOOST_TYPEOF_INCREMENT_REGISTRATION_GROUP() BOOST_TYPEOF_REGISTER_TEMPLATE(boost::scope_exit::detail::wrapper, 1) #define BOOST_SCOPE_EXIT_AUX_ARGS boost_scope_exit_aux_args extern boost::scope_exit::detail::undeclared BOOST_SCOPE_EXIT_AUX_ARGS; #define BOOST_SCOPE_EXIT_AUX_GUARD(id) \ BOOST_PP_CAT(boost_se_guard_, id) #define BOOST_SCOPE_EXIT_AUX_GUARD_T(id) \ BOOST_PP_CAT(boost_se_guard_t_, id) #define BOOST_SCOPE_EXIT_AUX_PARAMS(id) \ BOOST_PP_CAT(boost_se_params_, id) #define BOOST_SCOPE_EXIT_AUX_THIS_T(id) \ BOOST_PP_CAT(boost_se_this_t_, id) #define BOOST_SCOPE_EXIT_AUX_THIS_CAPTURE_T(id) \ BOOST_PP_CAT(boost_se_this_capture_t_, id) #define BOOST_SCOPE_EXIT_DETAIL_PARAMS_T(id) \ BOOST_PP_CAT(boost_se_params_t_, id) #define BOOST_SCOPE_EXIT_DETAIL_TAG(id, i) \ BOOST_PP_SEQ_CAT( (boost_se_tag_)(i)(_)(id) ) #define BOOST_SCOPE_EXIT_DETAIL_PARAM_THIS(id) \ BOOST_PP_SEQ_CAT( (boost_se_param_this_)(id) ) #define BOOST_SCOPE_EXIT_DETAIL_PARAM(id, i, var) \ BOOST_PP_SEQ_CAT( (boost_se_param_)(i)(_)(id) ) #define BOOST_SCOPE_EXIT_DETAIL_PARAM_T(id, i, var) \ BOOST_PP_SEQ_CAT( (boost_se_param_t_)(i)(_)(id) ) #define BOOST_SCOPE_EXIT_DETAIL_CAPTURE_T(id, i, var) \ BOOST_PP_SEQ_CAT( (boost_se_capture_t_)(i)(_)(id) ) #define BOOST_SCOPE_EXIT_AUX_WRAPPED(id, i) \ BOOST_PP_SEQ_CAT( (boost_se_wrapped_t_)(i)(_)(id) ) #define BOOST_SCOPE_EXIT_AUX_DEREF(id, i, var) \ ::boost::scope_exit::detail::deref(var, \ static_cast<BOOST_SCOPE_EXIT_DETAIL_TAG(id, i)>(0)) #define BOOST_SCOPE_EXIT_AUX_MEMBER(r, id, i, var) \ ::boost::scope_exit::detail::member< \ BOOST_SCOPE_EXIT_DETAIL_PARAM_T(id, i, var), \ BOOST_SCOPE_EXIT_DETAIL_TAG(id, i) \ > BOOST_SCOPE_EXIT_DETAIL_PARAM(id, i, var); #define BOOST_SCOPE_EXIT_AUX_ARG_DECL(r, id_ty, i, var) \ BOOST_PP_COMMA_IF(i) \ BOOST_PP_TUPLE_ELEM(2, 1, id_ty) \ BOOST_SCOPE_EXIT_DETAIL_PARAMS_T(BOOST_PP_TUPLE_ELEM(2, 0, id_ty)):: \ BOOST_SCOPE_EXIT_DETAIL_PARAM_T(BOOST_PP_TUPLE_ELEM(2, 0, id_ty), \ i, var) \ var #define BOOST_SCOPE_EXIT_AUX_ARG(r, id, i, var) \ BOOST_PP_COMMA_IF(i) \ boost_se_params_->BOOST_SCOPE_EXIT_DETAIL_PARAM(id, i, var).value #define BOOST_SCOPE_EXIT_DETAIL_TAG_DECL(r, id, i, var) \ typedef void (*BOOST_SCOPE_EXIT_DETAIL_TAG(id, i))(int var); // Adam Butcher's workaround to deduce `this` type on MSVC revision < 10. // Boost.Typeof for VC71's typeid-based workaround does not work to determine // `this` type due to error C2355 being incorrectly reported. The typical // avoidance strategy implemented below is to make an indirect compile-time // constant by assigning an enum and use that as type-index-- this only works // with the sizeof() approach and not with the typeid() approach. Lorenzo // Caminiti extended this approach to work in type-of emulation mode. This code // is very similar (and somewhat of a duplication) of the code in // boost/typeof/msvc/typeof_impl.hpp). However, this code cannot be integrated // into Boost.Typeof because its final API has to be a `typedef ...` and it // cannot be a `typeof(...)`. #if BOOST_SCOPE_EXIT_AUX_TYPEOF_THIS_MSVC_WORKAROUND_01 #include <boost/config.hpp> #include <boost/detail/workaround.hpp> #include <boost/mpl/int.hpp> #include <boost/type_traits/is_function.hpp> #include <boost/utility/enable_if.hpp> #if BOOST_WORKAROUND(BOOST_MSVC, >= 1310) # include <typeinfo> #endif namespace boost { namespace scope_exit { namespace aux { namespace msvc_typeof_this { // compile-time constant code #if BOOST_WORKAROUND(BOOST_MSVC, >=1300) && defined(_MSC_EXTENSIONS) template<int N> struct the_counter; template<typename T,int N = 5 /* for similarity */> struct encode_counter { __if_exists(the_counter<N + 256>) { BOOST_STATIC_CONSTANT(unsigned, count=(encode_counter<T,N + 257>::count)); } __if_not_exists(the_counter<N + 256>) { __if_exists(the_counter<N + 64>) { BOOST_STATIC_CONSTANT(unsigned, count=(encode_counter<T,N + 65>::count)); } __if_not_exists(the_counter<N + 64>) { __if_exists(the_counter<N + 16>) { BOOST_STATIC_CONSTANT(unsigned, count=(encode_counter<T,N + 17>::count)); } __if_not_exists(the_counter<N + 16>) { __if_exists(the_counter<N + 4>) { BOOST_STATIC_CONSTANT(unsigned, count=(encode_counter<T,N + 5>::count)); } __if_not_exists(the_counter<N + 4>) { __if_exists(the_counter<N>) { BOOST_STATIC_CONSTANT(unsigned, count=(encode_counter<T,N + 1>::count)); } __if_not_exists(the_counter<N>) { BOOST_STATIC_CONSTANT(unsigned,count=N); typedef the_counter<N> type; } } } } } }; #else // compile-time constant code template<int N> struct encode_counter : encode_counter<N - 1> {}; template<> struct encode_counter<0> {}; #endif // compile-time constant code #if BOOST_WORKAROUND(BOOST_MSVC, == 1300) // type-of code template<typename ID> struct msvc_extract_type { template<bool> struct id2type_impl; typedef id2type_impl<true> id2type; }; template<typename T, typename ID> struct msvc_register_type : msvc_extract_type<ID> { template<> struct id2type_impl<true> { // VC7.0 specific bug-feature. typedef T type; }; }; #elif BOOST_WORKAROUND(BOOST_MSVC, >= 1400) // type-of code struct msvc_extract_type_default_param {}; template<typename ID, typename T = msvc_extract_type_default_param> struct msvc_extract_type; template<typename ID> struct msvc_extract_type<ID, msvc_extract_type_default_param> { template<bool> struct id2type_impl; typedef id2type_impl<true> id2type; }; template<typename ID, typename T> struct msvc_extract_type : msvc_extract_type<ID, msvc_extract_type_default_param> { template<> struct id2type_impl<true> { // VC8.0 specific bug-feature. typedef T type; }; template<bool> struct id2type_impl; typedef id2type_impl<true> id2type; }; template<typename T, typename ID> struct msvc_register_type : msvc_extract_type<ID, T> {}; #else // type-of code template<typename ID> struct msvc_extract_type { struct id2type; }; template<typename T, typename ID> struct msvc_register_type : msvc_extract_type<ID> { typedef msvc_extract_type<ID> base_type; struct base_type::id2type { // This uses nice VC6.5 and VC7.1 bug-features. typedef T type; }; }; #endif // typeof code template<int Id> struct msvc_typeid_wrapper { typedef typename msvc_extract_type<boost::mpl::int_<Id> >::id2type id2type; typedef typename id2type::type type; }; template<> struct msvc_typeid_wrapper<4> { typedef msvc_typeid_wrapper<4> type; }; template<typename T> struct encode_type { BOOST_STATIC_CONSTANT(unsigned, value = encode_counter<T>::count); typedef typename msvc_register_type<T, boost::mpl::int_<value> >::id2type type; BOOST_STATIC_CONSTANT(unsigned, next = value + 1); }; template<class T> struct sizer { typedef char(*type)[encode_type<T>::value]; }; template<typename T> typename boost::disable_if< typename boost::is_function<T>::type , typename sizer<T>::type >::type encode_start(T const&); template<typename T> typename boost::enable_if< typename boost::is_function<T>::type , typename sizer<T>::type >::type encode_start(T&); template<typename Organizer, typename T> msvc_register_type<T, Organizer> typeof_register_type(const T&, Organizer* = 0); } } } } // namespace #define BOOST_SCOPE_EXIT_AUX_TYPEDEF_TYPEOF_THIS_INDEX_(id) \ BOOST_PP_CAT(boost_se_thistype_index_, id) #define BOOST_SCOPE_EXIT_DETAIL_TYPEDEF_TYPEOF_THIS(id, ty, new_type) \ /* unfortunately, we need to go via this enum which causes this to be */ \ /* a typedef construct and not a typeof (so this code cannot be */ \ /* integrated into Boost.Typeof) */ \ enum { \ BOOST_SCOPE_EXIT_AUX_TYPEDEF_TYPEOF_THIS_INDEX_(id) = sizeof( \ *::boost::scope_exit::aux::msvc_typeof_this::encode_start(this)) \ }; \ typedef \ ty ::boost::scope_exit::aux::msvc_typeof_this::msvc_typeid_wrapper< \ BOOST_SCOPE_EXIT_AUX_TYPEDEF_TYPEOF_THIS_INDEX_(id) \ >::type \ new_type \ ; #else // TYPEOF_THIS_MSVC_WORKAROUND #define BOOST_SCOPE_EXIT_DETAIL_TYPEDEF_TYPEOF_THIS(id, ty, new_type) \ typedef /* trailing `EMPTY()` handles empty `ty` */ \ BOOST_PP_IIF(BOOST_PP_IS_EMPTY(ty BOOST_PP_EMPTY()), \ BOOST_TYPEOF \ , \ BOOST_TYPEOF_TPL \ )(this) \ new_type \ ; #endif // TYPEOF_THIS_MSVC_WORKAROUND #if BOOST_SCOPE_EXIT_AUX_TPL_GCC_WORKAROUND_01 #define BOOST_SCOPE_EXIT_AUX_PARAMS_T_CTOR(id, ty, captures, has_this) \ /* expand to nothing */ #define BOOST_SCOPE_EXIT_DETAIL_PARAM_INIT(r, id, i, var) \ BOOST_PP_COMMA_IF(i) { BOOST_SCOPE_EXIT_AUX_DEREF(id, i, var) } #define BOOST_SCOPE_EXIT_AUX_PARAMS_INIT(id, captures, has_this) \ BOOST_PP_EXPR_IIF(BOOST_PP_BITOR(has_this, \ BOOST_PP_LIST_IS_CONS(captures)), \ = { \ ) \ BOOST_PP_LIST_FOR_EACH_I(BOOST_SCOPE_EXIT_DETAIL_PARAM_INIT, id, captures) \ BOOST_PP_COMMA_IF(BOOST_PP_BITAND(BOOST_PP_LIST_IS_CONS(captures), \ has_this)) \ BOOST_PP_EXPR_IIF(has_this, this) /* no extra {...} needed here */ \ BOOST_PP_EXPR_IIF(BOOST_PP_BITOR(has_this, \ BOOST_PP_LIST_IS_CONS(captures)), \ } /* trailing `;` will be added by the caller */ \ ) #else // TPL_GCC_WORKAROUND #define BOOST_SCOPE_EXIT_AUX_CTOR_ARG(r, id, i, var) \ BOOST_PP_COMMA_IF(i) \ BOOST_SCOPE_EXIT_DETAIL_PARAM_T(id, i, var) & BOOST_PP_CAT(a, i) #define BOOST_SCOPE_EXIT_AUX_MEMBER_INIT(r, id, i, var) \ BOOST_PP_COMMA_IF(i) \ BOOST_SCOPE_EXIT_DETAIL_PARAM(id, i, var) ( BOOST_PP_CAT(a, i) ) #define BOOST_SCOPE_EXIT_AUX_CTOR_ARG_THIS_NAME(id) \ BOOST_PP_CAT(boost_se_this_arg_, id) #define BOOST_SCOPE_EXIT_AUX_CTOR_ARG_THIS(id, ty, comma01) \ BOOST_PP_COMMA_IF(comma01) \ ty BOOST_SCOPE_EXIT_DETAIL_PARAMS_T(id)::BOOST_SCOPE_EXIT_AUX_THIS_T(id) \ BOOST_SCOPE_EXIT_AUX_CTOR_ARG_THIS_NAME(id) /* ptr so no & */ #define BOOST_SCOPE_EXIT_AUX_MEMBER_THIS_INIT(id, comma01) \ BOOST_PP_COMMA_IF(comma01) \ BOOST_SCOPE_EXIT_DETAIL_PARAM_THIS(id)( \ BOOST_SCOPE_EXIT_AUX_CTOR_ARG_THIS_NAME(id)) #define BOOST_SCOPE_EXIT_AUX_PARAMS_T_CTOR(id, ty, captures, has_this) \ BOOST_SCOPE_EXIT_DETAIL_PARAMS_T(id)( \ BOOST_PP_LIST_FOR_EACH_I(BOOST_SCOPE_EXIT_AUX_CTOR_ARG, id, captures) \ BOOST_PP_IIF(has_this, \ BOOST_SCOPE_EXIT_AUX_CTOR_ARG_THIS \ , \ BOOST_PP_TUPLE_EAT(3) \ )(id, ty, BOOST_PP_LIST_IS_CONS(captures)) \ ) \ BOOST_PP_EXPR_IIF(BOOST_PP_BITOR(BOOST_PP_LIST_IS_CONS(captures), \ has_this), \ : \ ) \ BOOST_PP_LIST_FOR_EACH_I(BOOST_SCOPE_EXIT_AUX_MEMBER_INIT, id, \ captures) \ BOOST_PP_IIF(has_this, \ BOOST_SCOPE_EXIT_AUX_MEMBER_THIS_INIT \ , \ BOOST_PP_TUPLE_EAT(2) \ )(id, BOOST_PP_LIST_IS_CONS(captures)) \ {} #define BOOST_SCOPE_EXIT_DETAIL_PARAM_INIT(r, id, i, var) \ BOOST_PP_COMMA_IF(i) BOOST_SCOPE_EXIT_AUX_DEREF(id,i,var) #define BOOST_SCOPE_EXIT_AUX_PARAMS_INIT(id, captures, has_this) \ BOOST_PP_LPAREN_IF(BOOST_PP_BITOR(has_this, \ BOOST_PP_LIST_IS_CONS(captures))) \ BOOST_PP_LIST_FOR_EACH_I(BOOST_SCOPE_EXIT_DETAIL_PARAM_INIT, id, captures) \ BOOST_PP_COMMA_IF(BOOST_PP_BITAND(BOOST_PP_LIST_IS_CONS(captures), \ has_this)) \ BOOST_PP_EXPR_IIF(has_this, this) \ BOOST_PP_RPAREN_IF(BOOST_PP_BITOR(has_this, \ BOOST_PP_LIST_IS_CONS(captures))) #endif // TPL_GCC_WORKAROUND #if defined(BOOST_TYPEOF_EMULATION) #define BOOST_SCOPE_EXIT_DETAIL_CAPTURE_DECL(r, id_ty, i, var) \ struct BOOST_SCOPE_EXIT_AUX_WRAPPED(BOOST_PP_TUPLE_ELEM(2, 0, id_ty), i) \ /* no need to use TYPEOF_TPL here because it's within inheritance */ \ : BOOST_TYPEOF(::boost::scope_exit::detail::wrap( \ BOOST_SCOPE_EXIT_AUX_DEREF(BOOST_PP_TUPLE_ELEM(2, 0, id_ty), \ i, var))) \ {}; \ typedef BOOST_PP_TUPLE_ELEM(2, 1, id_ty) \ BOOST_SCOPE_EXIT_AUX_WRAPPED(BOOST_PP_TUPLE_ELEM(2, 0, id_ty), i)::type\ BOOST_SCOPE_EXIT_DETAIL_CAPTURE_T(BOOST_PP_TUPLE_ELEM(2, 0, id_ty), \ i, var) \ ; #elif defined(BOOST_INTEL) #define BOOST_SCOPE_EXIT_DETAIL_CAPTURE_DECL(r, id_ty, i, var) \ typedef \ /* no TYPEOF_TPL here because uses TYPEOF_KEYWORD directly */ \ BOOST_TYPEOF_KEYWORD(BOOST_SCOPE_EXIT_AUX_DEREF( \ BOOST_PP_TUPLE_ELEM(2, 0, id_ty), i, var)) \ BOOST_SCOPE_EXIT_DETAIL_CAPTURE_T(BOOST_PP_TUPLE_ELEM(2, 0, id_ty), \ i, var) \ ; #else #define BOOST_SCOPE_EXIT_DETAIL_CAPTURE_DECL(r, id_ty, i, var) \ typedef \ /* no need to use TYPEOF_TPL here because it's a typedef */ \ BOOST_TYPEOF(::boost::scope_exit::detail::wrap( \ BOOST_SCOPE_EXIT_AUX_DEREF(BOOST_PP_TUPLE_ELEM(2, 0, id_ty), \ i, var))) \ BOOST_SCOPE_EXIT_AUX_WRAPPED(BOOST_PP_TUPLE_ELEM(2, 0, id_ty), i) \ ; \ typedef BOOST_PP_TUPLE_ELEM(2, 1, id_ty) \ BOOST_SCOPE_EXIT_AUX_WRAPPED(BOOST_PP_TUPLE_ELEM(2, 0, id_ty), i)::type\ BOOST_SCOPE_EXIT_DETAIL_CAPTURE_T(BOOST_PP_TUPLE_ELEM(2, 0, id_ty), \ i, var) \ ; #endif #define BOOST_SCOPE_EXIT_DETAIL_PARAM_DECL(r, id_ty, i, var) \ typedef \ BOOST_SCOPE_EXIT_DETAIL_CAPTURE_T(BOOST_PP_TUPLE_ELEM(2, 0, id_ty), \ i, var) \ BOOST_SCOPE_EXIT_DETAIL_PARAM_T(BOOST_PP_TUPLE_ELEM(2, 0, id_ty), \ i, var) \ ; // Traits. #define BOOST_SCOPE_EXIT_AUX_TRAITS_OP_CAPTURE(d, captures, this01, capture) \ (BOOST_PP_LIST_APPEND(captures, (capture, BOOST_PP_NIL)), this01) #define BOOST_SCOPE_EXIT_AUX_TRAITS_OP_THIS(d, captures, this01, this_) \ (captures, 1 /* has this (note, no error if multiple this_) */) #define BOOST_SCOPE_EXIT_AUX_TRAITS_OP(d, captures_this, capture) \ BOOST_PP_IIF(BOOST_LOCAL_FUNCTION_DETAIL_PP_KEYWORD_IS_THISUNDERSCORE_BACK(\ capture), \ BOOST_SCOPE_EXIT_AUX_TRAITS_OP_THIS \ , \ BOOST_SCOPE_EXIT_AUX_TRAITS_OP_CAPTURE \ )(d, BOOST_PP_TUPLE_ELEM(2, 0, captures_this), \ BOOST_PP_TUPLE_ELEM(2, 1, captures_this), capture) // ref_val: & | = #define BOOST_SCOPE_EXIT_AUX_TRAITS_ALL_OP(ref_val, traits) \ ( \ BOOST_PP_LIST_APPEND((ref_val, BOOST_PP_NIL), \ BOOST_SCOPE_EXIT_AUX_TRAITS_CAPTURES(traits)) \ , \ BOOST_SCOPE_EXIT_AUX_TRAITS_HAS_THIS(traits) \ ) #define BOOST_SCOPE_EXIT_AUX_TRAITS(captures) \ BOOST_PP_LIST_FOLD_LEFT(BOOST_SCOPE_EXIT_AUX_TRAITS_OP, \ (BOOST_PP_NIL, 0), captures) #define BOOST_SCOPE_EXIT_AUX_TRAITS_ALL(captures) \ BOOST_SCOPE_EXIT_AUX_TRAITS_ALL_OP(BOOST_PP_LIST_FIRST(captures), \ BOOST_SCOPE_EXIT_AUX_TRAITS(BOOST_PP_LIST_REST(captures))) #define BOOST_SCOPE_EXIT_AUX_TRAITS_CAPTURES(traits) \ BOOST_PP_TUPLE_ELEM(2, 0, traits) #define BOOST_SCOPE_EXIT_AUX_TRAITS_HAS_THIS(traits) \ BOOST_PP_TUPLE_ELEM(2, 1, traits) #ifndef BOOST_NO_CXX11_LAMBDAS namespace boost { namespace scope_exit { namespace aux { template<typename This = void> struct guard { // With object `this_` (for backward compatibility). explicit guard(This _this) : this_(_this) {} ~guard() { if(f_) f_(this_); } template<typename Lambda> void operator=(Lambda f) { f_ = f; } private: This this_; boost::function<void (This)> f_; }; template<> struct guard<void> { // Without object `this_` (could capture `this` directly). ~guard() { if(f_) f_(); } template<typename Lambda> void operator=(Lambda f) { f_ = f; } private: boost::function<void (void)> f_; }; } } } // namespace #define BOOST_SCOPE_EXIT_AUX_LAMBDA_PARAMS(id) \ BOOST_PP_CAT(boost_se_lambda_params_, id) #define BOOST_SCOPE_EXIT_AUX_LAMBDA_THIS_CAPTURE_TYPE(id) \ BOOST_PP_CAT(boost_se_lambda_this_t_, id) #define BOOST_SCOPE_EXIT_AUX_LAMBDA_THIS_PARAM_TYPE(id) \ BOOST_PP_CAT(boost_se_lambda_this_capture_t_, id) #define BOOST_SCOPE_EXIT_AUX_LAMBDA_THIS_TYPE(id, ty) \ ty BOOST_SCOPE_EXIT_AUX_LAMBDA_PARAMS(id):: \ BOOST_SCOPE_EXIT_AUX_LAMBDA_THIS_PARAM_TYPE(id) // Precondition: HAS_THIS(traits). #define BOOST_SCOPE_EXIT_AUX_LAMBDA_THIS_TYPEDEFS(id, ty, traits) \ BOOST_SCOPE_EXIT_DETAIL_TYPEDEF_TYPEOF_THIS(id, ty, \ BOOST_SCOPE_EXIT_AUX_LAMBDA_THIS_CAPTURE_TYPE(id)) \ /* capture type for workaround GCC internal error (even on later C++11) */ \ struct BOOST_SCOPE_EXIT_AUX_LAMBDA_PARAMS(id) { \ typedef BOOST_SCOPE_EXIT_AUX_LAMBDA_THIS_CAPTURE_TYPE(id) \ BOOST_SCOPE_EXIT_AUX_LAMBDA_THIS_PARAM_TYPE(id); \ }; #define BOOST_SCOPE_EXIT_AUX_IMPL_LAMBDA(id, ty, traits) \ BOOST_PP_IIF(BOOST_SCOPE_EXIT_AUX_TRAITS_HAS_THIS(traits), \ /* no need for TYPEDEF THIS MSVC workaround on C++11 */ \ BOOST_SCOPE_EXIT_AUX_LAMBDA_THIS_TYPEDEFS \ , \ BOOST_PP_TUPLE_EAT(3) \ )(id, ty, traits) \ ::boost::scope_exit::aux::guard< \ BOOST_PP_IIF(BOOST_SCOPE_EXIT_AUX_TRAITS_HAS_THIS(traits), \ BOOST_SCOPE_EXIT_AUX_LAMBDA_THIS_TYPE \ , \ BOOST_PP_TUPLE_EAT(2) \ )(id, ty) \ > BOOST_SCOPE_EXIT_AUX_GUARD(id) \ BOOST_PP_EXPR_IIF(BOOST_SCOPE_EXIT_AUX_TRAITS_HAS_THIS(traits), \ (this) \ ) \ ; \ BOOST_SCOPE_EXIT_AUX_GUARD(id) = [ \ BOOST_PP_LIST_ENUM(BOOST_SCOPE_EXIT_AUX_TRAITS_CAPTURES(traits)) \ ]( \ BOOST_PP_IIF(BOOST_SCOPE_EXIT_AUX_TRAITS_HAS_THIS(traits), \ BOOST_SCOPE_EXIT_AUX_LAMBDA_THIS_TYPE \ , \ BOOST_PP_TUPLE_EAT(2) \ )(id, ty) \ BOOST_PP_EXPR_IIF(BOOST_SCOPE_EXIT_AUX_TRAITS_HAS_THIS(traits), this_) \ ) mutable /* can change value captures (as with SCOPE_EXIT) */ -> void #endif // Lambdas. #if defined(BOOST_SCOPE_EXIT_CONFIG_USE_LAMBDAS) && \ !defined(BOOST_NO_CXX11_LAMBDAS) // Use lambda for SCOPE_EXIT (not just _ALL). #define BOOST_SCOPE_EXIT_AUX_IMPL(id, ty, traits) \ BOOST_SCOPE_EXIT_AUX_IMPL_LAMBDA(id, ty, traits) #else // Not using lambdas. // ty: EMPTY() | typename #define BOOST_SCOPE_EXIT_AUX_IMPL(id, ty, traits) \ BOOST_PP_LIST_FOR_EACH_I(BOOST_SCOPE_EXIT_DETAIL_TAG_DECL, id, \ BOOST_SCOPE_EXIT_AUX_TRAITS_CAPTURES(traits)) \ BOOST_PP_LIST_FOR_EACH_I(BOOST_SCOPE_EXIT_DETAIL_CAPTURE_DECL, (id, ty), \ BOOST_SCOPE_EXIT_AUX_TRAITS_CAPTURES(traits)) \ BOOST_PP_IIF(BOOST_SCOPE_EXIT_AUX_TRAITS_HAS_THIS(traits), \ BOOST_SCOPE_EXIT_DETAIL_TYPEDEF_TYPEOF_THIS \ , \ BOOST_PP_TUPLE_EAT(3) \ )(id, ty, BOOST_SCOPE_EXIT_AUX_THIS_CAPTURE_T(id)) \ struct BOOST_SCOPE_EXIT_DETAIL_PARAMS_T(id) { \ /* interim capture types to workaround internal errors on old GCC */ \ BOOST_PP_LIST_FOR_EACH_I(BOOST_SCOPE_EXIT_DETAIL_PARAM_DECL, (id, ty), \ BOOST_SCOPE_EXIT_AUX_TRAITS_CAPTURES(traits)) \ BOOST_PP_EXPR_IIF(BOOST_SCOPE_EXIT_AUX_TRAITS_HAS_THIS(traits), \ typedef BOOST_SCOPE_EXIT_AUX_THIS_CAPTURE_T(id) \ BOOST_SCOPE_EXIT_AUX_THIS_T(id) ; \ ) \ BOOST_PP_LIST_FOR_EACH_I(BOOST_SCOPE_EXIT_AUX_MEMBER, id, \ BOOST_SCOPE_EXIT_AUX_TRAITS_CAPTURES(traits)) \ BOOST_PP_EXPR_IIF(BOOST_SCOPE_EXIT_AUX_TRAITS_HAS_THIS(traits), \ BOOST_SCOPE_EXIT_AUX_THIS_T(id) \ BOOST_SCOPE_EXIT_DETAIL_PARAM_THIS(id) ; \ ) \ BOOST_SCOPE_EXIT_AUX_PARAMS_T_CTOR(id, ty, \ BOOST_SCOPE_EXIT_AUX_TRAITS_CAPTURES(traits), \ BOOST_SCOPE_EXIT_AUX_TRAITS_HAS_THIS(traits)) \ } BOOST_SCOPE_EXIT_AUX_PARAMS(id) \ BOOST_SCOPE_EXIT_AUX_PARAMS_INIT(id, \ BOOST_SCOPE_EXIT_AUX_TRAITS_CAPTURES(traits), \ BOOST_SCOPE_EXIT_AUX_TRAITS_HAS_THIS(traits)) \ ; \ ::boost::scope_exit::detail::declared< \ ::boost::scope_exit::detail::resolve< \ sizeof(BOOST_SCOPE_EXIT_AUX_ARGS) \ >::cmp1<0>::cmp2 \ > BOOST_SCOPE_EXIT_AUX_ARGS; \ BOOST_SCOPE_EXIT_AUX_ARGS.value = &BOOST_SCOPE_EXIT_AUX_PARAMS(id); \ struct BOOST_SCOPE_EXIT_AUX_GUARD_T(id) { \ BOOST_SCOPE_EXIT_DETAIL_PARAMS_T(id)* boost_se_params_; \ BOOST_SCOPE_EXIT_AUX_GUARD_T(id) (void* boost_se_params) \ : boost_se_params_( \ (BOOST_SCOPE_EXIT_DETAIL_PARAMS_T(id)*)boost_se_params) \ {} \ ~BOOST_SCOPE_EXIT_AUX_GUARD_T(id)() { \ boost_se_body( \ BOOST_PP_LIST_FOR_EACH_I(BOOST_SCOPE_EXIT_AUX_ARG, id, \ BOOST_SCOPE_EXIT_AUX_TRAITS_CAPTURES(traits)) \ BOOST_PP_COMMA_IF(BOOST_PP_BITAND(BOOST_PP_LIST_IS_CONS( \ BOOST_SCOPE_EXIT_AUX_TRAITS_CAPTURES(traits)), \ BOOST_SCOPE_EXIT_AUX_TRAITS_HAS_THIS(traits))) \ BOOST_PP_EXPR_IIF(BOOST_SCOPE_EXIT_AUX_TRAITS_HAS_THIS( \ traits), \ boost_se_params_->BOOST_SCOPE_EXIT_DETAIL_PARAM_THIS(id) \ ) \ ); \ } \ static void boost_se_body( \ BOOST_PP_LIST_FOR_EACH_I(BOOST_SCOPE_EXIT_AUX_ARG_DECL, (id, ty), \ BOOST_SCOPE_EXIT_AUX_TRAITS_CAPTURES(traits)) \ BOOST_PP_COMMA_IF(BOOST_PP_BITAND(BOOST_PP_LIST_IS_CONS( \ BOOST_SCOPE_EXIT_AUX_TRAITS_CAPTURES(traits)), \ BOOST_SCOPE_EXIT_AUX_TRAITS_HAS_THIS(traits))) \ BOOST_PP_EXPR_IIF(BOOST_SCOPE_EXIT_AUX_TRAITS_HAS_THIS(traits), \ ty BOOST_SCOPE_EXIT_DETAIL_PARAMS_T(id):: \ BOOST_SCOPE_EXIT_AUX_THIS_T(id) this_ \ ) \ ) #endif // Using lambdas. // PUBLIC // #if defined(BOOST_NO_CXX11_VARIADIC_MACROS) // No variadic macros (sequences only). # define BOOST_SCOPE_EXIT_ID(id, void_or_seq) \ BOOST_SCOPE_EXIT_AUX_IMPL(id, BOOST_PP_EMPTY(), \ BOOST_SCOPE_EXIT_AUX_TRAITS( \ BOOST_LOCAL_FUNCTION_DETAIL_PP_VOID_LIST(void_or_seq))) # define BOOST_SCOPE_EXIT_ID_TPL(id, void_or_seq) \ BOOST_SCOPE_EXIT_AUX_IMPL(id, typename, \ BOOST_SCOPE_EXIT_AUX_TRAITS( \ BOOST_LOCAL_FUNCTION_DETAIL_PP_VOID_LIST(void_or_seq))) # define BOOST_SCOPE_EXIT(void_or_seq) \ BOOST_SCOPE_EXIT_ID(BOOST_LOCAL_FUNCTION_DETAIL_PP_LINE_COUNTER, \ void_or_seq) # define BOOST_SCOPE_EXIT_TPL(void_or_seq) \ BOOST_SCOPE_EXIT_ID_TPL(BOOST_LOCAL_FUNCTION_DETAIL_PP_LINE_COUNTER, \ void_or_seq) # if !defined(BOOST_NO_CXX11_LAMBDAS) # define BOOST_SCOPE_EXIT_ALL_ID(id, seq) \ BOOST_SCOPE_EXIT_AUX_IMPL_LAMBDA(id, \ /* C++11 allows to use typename outside templates so */ \ /* always typename here and no need for ..._ALL_TPL */ \ /* (if a C++11 compiler does not implement this use of */ \ /* typename, always use `this` instead of `this_`) */ \ typename, \ BOOST_SCOPE_EXIT_AUX_TRAITS_ALL( \ BOOST_LOCAL_FUNCTION_DETAIL_PP_NON_VOID_LIST(seq))) # define BOOST_SCOPE_EXIT_ALL(seq) \ BOOST_SCOPE_EXIT_ALL_ID( \ BOOST_LOCAL_FUNCTION_DETAIL_PP_LINE_COUNTER, seq) # endif #else // Variadic macros (both sequences and variadic tuples). # define BOOST_SCOPE_EXIT_ID(id, ...) \ BOOST_SCOPE_EXIT_AUX_IMPL(id, BOOST_PP_EMPTY(), \ BOOST_SCOPE_EXIT_AUX_TRAITS( \ BOOST_LOCAL_FUNCTION_DETAIL_PP_VOID_LIST(__VA_ARGS__))) # define BOOST_SCOPE_EXIT_ID_TPL(id, ...) \ BOOST_SCOPE_EXIT_AUX_IMPL(id, typename, \ BOOST_SCOPE_EXIT_AUX_TRAITS( \ BOOST_LOCAL_FUNCTION_DETAIL_PP_VOID_LIST(__VA_ARGS__))) # define BOOST_SCOPE_EXIT(...) \ BOOST_SCOPE_EXIT_ID(BOOST_LOCAL_FUNCTION_DETAIL_PP_LINE_COUNTER, \ __VA_ARGS__) # define BOOST_SCOPE_EXIT_TPL(...) \ BOOST_SCOPE_EXIT_ID_TPL(BOOST_LOCAL_FUNCTION_DETAIL_PP_LINE_COUNTER, \ __VA_ARGS__) # if !defined(BOOST_NO_CXX11_LAMBDAS) # define BOOST_SCOPE_EXIT_ALL_ID(id, ...) \ BOOST_SCOPE_EXIT_AUX_IMPL_LAMBDA(id, \ /* C++11 allows to use typename outside templates so */ \ /* always typename here and no need for ..._ALL_TPL */ \ /* (if a C++11 compiler does not implement this use of */ \ /* typename, always use `this` instead of `this_`) */ \ typename, \ BOOST_SCOPE_EXIT_AUX_TRAITS_ALL( \ BOOST_LOCAL_FUNCTION_DETAIL_PP_NON_VOID_LIST( \ __VA_ARGS__))) # define BOOST_SCOPE_EXIT_ALL(...) \ BOOST_SCOPE_EXIT_ALL_ID( \ BOOST_LOCAL_FUNCTION_DETAIL_PP_LINE_COUNTER, __VA_ARGS__) # endif #endif // Variadics. #if defined(BOOST_SCOPE_EXIT_CONFIG_USE_LAMBDAS) && \ !defined(BOOST_NO_CXX11_LAMBDAS) // Use lambdas for SCOPE_EXIT (not just ALL). # define BOOST_SCOPE_EXIT_END_ID(id) \ ; /* lambdas ended with just `;` */ #else // Not using lambdas. # define BOOST_SCOPE_EXIT_END_ID(id) \ } BOOST_SCOPE_EXIT_AUX_GUARD(id)(BOOST_SCOPE_EXIT_AUX_ARGS.value); #endif // Using lambdas. #define BOOST_SCOPE_EXIT_END \ BOOST_SCOPE_EXIT_END_ID(BOOST_LOCAL_FUNCTION_DETAIL_PP_LINE_COUNTER) // DOCUMENTATION // #else // DOXYGEN /** @file @brief Scope exits allow to execute arbitrary code when the enclosing scope exits. */ /** @brief This macro declares a scope exit. The scope exit declaration schedules the execution of the scope exit body at the exit of the enclosing scope: @code { // Some local scope. ... BOOST_SCOPE_EXIT(capture_list) { ... // Body code. } BOOST_SCOPE_EXIT_END ... } @endcode The enclosing scope must be local. If multiple scope exits are declared within the same enclosing scope, the scope exit bodies are executed in the reversed order of their declarations. Note how the end of the scope exit body must be marked by @RefMacro{BOOST_SCOPE_EXIT_END}. @Params @Param{capture_list, On compilers that support variadic macros (see also Boost.Config <c>BOOST_NO_CXX11_VARIADIC_MACROS</c>)\, the capture list syntax is defined by the following grammar: @code capture_list: void | capture_tuple | capture_sequence capture_tuple: capture\, capture\, ... capture_sequence: (capture) (capture) ... capture: [&]variable | this_ @endcode On compilers that do not support variadic macros\, <c>capture_tuple</c> cannot be used: @code capture_list: void | capture_sequence @endcode Furthermore\, if @RefMacro{BOOST_SCOPE_EXIT_CONFIG_USE_LAMBDAS} is defined on C++11 compilers that support lambda functions (i.e.\, Boost.Config's <c>BOOST_NO_CXX11_LAMBDAS</c> is not defined) then a semicolon <c>;</c> can be used instead of @RefMacro{BOOST_SCOPE_EXIT_END} and <c>this</c> can be used instead of <c>this_</c>: @code capture: [&]variable | this_ | this @endcode (Lexical conventions: <c>token1 | token2</c> means either <c>token1</c> or <c>token2</c>; <c>[token]</c> means either <c>token</c> or nothing; <c>{expression}</c> means the tokens resulting from the expression.) } @EndParams Note that on compilers that support variadic macros (most of moder compliers and all C++11 compilers), the capture list can be specified as a comma-separated list of tokens (this is the preferred syntax). However, on all compilers the same macro @RefMacro{BOOST_SCOPE_EXIT} also allows to specify the capture list as a Boost.Preprocessor sequence of tokens (for supporting compilers without variadic macros and for backward compatibility with older versions of this library). The name <c>variable</c> of each captured variable must be a valid name in the enclosing scope and it must appear exactly once in the capture list. If a capture starts with the ampersand sign <c>&</c>, the corresponding variable will be available by reference within the scope exit body; otherwise, a copy of the variable will be made at the point of the scope exit declaration and that copy will be available inside the scope exit body (in this case, the variable's type must be <c>CopyConstructible</c>). From within a member function, the object <c>this</c> can be captured using the special name <c>this_</c> in both the capture list and the scope exit body (using <c>this</c> instead of <c>this_</c> in the scope exit body leads to undefined behaviour). It is possible to capture no variable by specifying the capture list as <c>void</c> (regardless of variadic macro support). Only variables listed in the capture list, static variables, <c>extern</c> variables, global variables, functions, and enumerations from the enclosing scope can be used inside the scope exit body. On various GCC versions the special macro @RefMacro{BOOST_SCOPE_EXIT_TPL} must be used instead of @RefMacro{BOOST_SCOPE_EXIT} within templates (to maximize portability, it is recommended to always use @RefMacro{BOOST_SCOPE_EXIT_TPL} within templates). On C++11, it is possible capture all variables in scope without listing their names one-by-one using the macro @RefMacro{BOOST_SCOPE_EXIT_ALL}. In general, the special macro @RefMacro{BOOST_SCOPE_EXIT_ID} must be used instead of @RefMacro{BOOST_SCOPE_EXIT} when it is necessary to expand multiple scope exit declarations on the same line. @Warning The implementation executes the scope exit body within a destructor thus the scope exit body must never throw in order to comply with STL exception safety requirements. @Note The implementation uses Boost.Typeof to automatically deduce the types of the captured variables. In order to compile code in type-of emulation mode, all types must be properly registered with Boost.Typeof (see the @RefSect{getting_started, Getting Started} section). @See @RefSect{tutorial, Tutorial} section, @RefSect{getting_started, Getting Started} section, @RefSect{no_variadic_macros, No Variadic Macros} section, @RefMacro{BOOST_SCOPE_EXIT_TPL}, @RefMacro{BOOST_SCOPE_EXIT_ALL}, @RefMacro{BOOST_SCOPE_EXIT_END}, @RefMacro{BOOST_SCOPE_EXIT_ID}. */ #define BOOST_SCOPE_EXIT(capture_list) /** @brief This macro is a workaround for various versions of GCC to declare scope exits within templates. Various versions of the GCC compiler do not compile @RefMacro{BOOST_SCOPE_EXIT} inside function templates. As a workaround, @RefMacro{BOOST_SCOPE_EXIT_TPL} should be used instead of @RefMacro{BOOST_SCOPE_EXIT} in these cases: @code { // Some local scope. ... BOOST_SCOPE_EXIT_TPL(capture_list) { ... // Body code. } BOOST_SCOPE_EXIT_END ... } @endcode The syntax of @RefMacro{BOOST_SCOPE_EXIT_TPL} is the exact same as the one of @RefMacro{BOOST_SCOPE_EXIT} (see @RefMacro{BOOST_SCOPE_EXIT} for more information). On C++11 compilers, @RefMacro{BOOST_SCOPE_EXIT_TPL} is not needed because @RefMacro{BOOST_SCOPE_EXIT} always compiles on GCC versions that support C++11. However, @RefMacro{BOOST_SCOPE_EXIT_TPL} is still provided on C++11 so to write code that is portable between C++03 and C++11 compilers. It is recommended to always use @RefMacro{BOOST_SCOPE_EXIT_TPL} within templates so to maximize portability. In general, the special macro @RefMacro{BOOST_SCOPE_EXIT_ID_TPL} must be used instead of @RefMacro{BOOST_SCOPE_EXIT_TPL} when it is necessary to expand multiple scope exit declarations on the same line within templates. @Note The issue in compiling scope exit declarations that some GCC versions have is illustrated by the following code (see also <a href="http://gcc.gnu.org/bugzilla/show_bug.cgi?id=37920">GCC bug 37920</a>): @code template<class T> void f(T const& x) { int i = 0; struct local { typedef __typeof__(i) typeof_i; typedef __typeof__(x) typeof_x; }; typedef local::typeof_i i_type; typedef local::typeof_x x_type; } int main(void) { f(0); } @endcode This can be fixed by adding <c>typename</c> in front of <c>local::typeof_i</c> and <c>local::typeof_x</c> (which is the approach followed by the implementation of the @RefMacro{BOOST_SCOPE_EXIT_TPL} macro). @Note Although @RefMacro{BOOST_SCOPE_EXIT_TPL} has the same suffix as <c>BOOST_TYPEOF_TPL</c>, it does not follow the Boost.Typeof convention. @See @RefSect{tutorial, Tutorial} section, @RefMacro{BOOST_SCOPE_EXIT}, @RefMacro{BOOST_SCOPE_EXIT_END}, @RefMacro{BOOST_SCOPE_EXIT_ID_TPL}. */ #define BOOST_SCOPE_EXIT_TPL(capture_list) /** @brief This macro allows to expand multiple scope exit declarations on the same line. This macro is equivalent to @RefMacro{BOOST_SCOPE_EXIT} but it can be expanded multiple times on the same line if different identifiers <c>id</c> are provided for each expansion (see @RefMacro{BOOST_SCOPE_EXIT} for more information). @Params @Param{id, A unique identifier token which can be concatenated by the preprocessor (<c>__LINE__</c>\, <c>scope_exit_number_1_on_line_123</c>\, a combination of alphanumeric tokens\, etc). } @Param{capture_list, Same as the <c>capture_list</c> parameter of the @RefMacro{BOOST_SCOPE_EXIT} macro. } @EndParams @Note This macro can be useful when the scope exit macros are expanded within user-defined macros (because nested macros expand on the same line). On some compilers (e.g., MSVC which supports the non standard <c>__COUNTER__</c> macro) it might not be necessary to use this macro but the use of this macro is always necessary to ensure portability when expanding multiple scope exit declarations on the same line. @See @RefSect{tutorial, Tutorial} section, @RefMacro{BOOST_SCOPE_EXIT}, @RefMacro{BOOST_SCOPE_EXIT_END_ID}, @RefMacro{BOOST_SCOPE_EXIT_ALL_ID}, @RefMacro{BOOST_SCOPE_EXIT_ID_TPL}. */ #define BOOST_SCOPE_EXIT_ID(id, capture_list) /** @brief This macro is required to expand multiple scope exit declarations on the same line within templates on various versions of GCC. This macro is equivalent to @RefMacro{BOOST_SCOPE_EXIT_TPL} but it can be expanded multiple times on the same line if different identifiers <c>id</c> are provided for each expansion (see @RefMacro{BOOST_SCOPE_EXIT_TPL} for more information). As with @RefMacro{BOOST_SCOPE_EXIT_TPL}, it is recommended to always use this macro when expanding scope exits multiple times on the same line within templates. @Params @Param{id, A unique identifier token which can be concatenated by the preprocessor (<c>__LINE__</c>\, <c>scope_exit_number_1_on_line_123</c>\, a combination of alphanumeric tokens\, etc). } @Param{capture_list, Same as the <c>capture_list</c> parameter of the @RefMacro{BOOST_SCOPE_EXIT_TPL} macro. } @EndParams @Note This macro can be useful when the scope exit macros are expanded within user-defined macros (because nested macros expand on the same line). On some compilers (e.g., MSVC which supports the non standard <c>__COUNTER__</c> macro) it might not be necessary to use this macro but the use of this macro is always necessary to ensure portability when expanding multiple scope exit declarations on the same line. @See @RefSect{tutorial, Tutorial} section, @RefMacro{BOOST_SCOPE_EXIT_TPL}, @RefMacro{BOOST_SCOPE_EXIT_END_ID}, @RefMacro{BOOST_SCOPE_EXIT_ID}, @RefMacro{BOOST_SCOPE_EXIT_ALL_ID}. */ #define BOOST_SCOPE_EXIT_ID_TPL(id, capture_list) /** @brief This macro declares a scope exit that captures all variables in scope (C++11 only). This macro accepts a capture list starting with either <c>&</c> or <c>=</c> to capture all variables in scope by reference or value respectively (following the same syntax of C++11 lambdas). A part from that, this macro works like @RefMacro{BOOST_SCOPE_EXIT} (see @RefMacro{BOOST_SCOPE_EXIT} for more information): @code { // Some local scope. ... BOOST_SCOPE_EXIT_ALL(capture_list) { // C++11 only. ... // Body code. }; // Use `;` instead of `BOOST_SCOPE_EXIT_END` (C++11 only). ... } @endcode Note how the end of the scope exit body declared by this macro must be marked by a semi-column <c>;</c> (and not by @RefMacro{BOOST_SCOPE_EXIT_END}). @Warning This macro is only available on C++11 compilers (specifically, on C++11 compilers that do not define the Boost.Config <c>BOOST_NO_CXX11_LAMBDAS</c> macro). It is not defined on non-C++11 compilers so its use on non-C++11 compilers will generate a compiler error. @Params @Param{capture_list, On compilers that support variadic macros (see also Boost.Config <c>BOOST_NO_CXX11_VARIADIC_MACROS</c>)\, the capture list syntax is defined by the following grammar: @code capture_list: capture_tuple | capture_sequence capture_tuple: {& | =} [\, capture\, capture\, ...] capture_sequence: {(&) | (=)} [(capture) (capture) ...] capture: [&]variable | this_ @endcode On compilers that do not support variadic macros\, <c>capture_tuple</c> cannot be used: @code capture_list: void | capture_sequence @endcode Furthermore\, on C++11 compilers that support the use of <c>typename</c> outside templates\, also <c>this</c> can be used to capture the object at member function scope: @code capture: [&]variable | this_ | this @endcode (Lexical conventions: <c>token1 | token2</c> means either <c>token1</c> or <c>token2</c>; <c>[token]</c> means either <c>token</c> or nothing; <c>{expression}</c> means the token resulting from the expression.) } @EndParams Note that on compilers with variadic macro support (which should be all C++11 compilers), the capture list can be specified as a comma-separated list. On all compilers, the same macro @RefMacro{BOOST_SCOPE_EXIT_ALL} also allows to specify the capture list as a Boost.Preprocessor sequence. The capture list must always contain at least the leading <c>&</c> or <c>=</c> so it can never be <c>void</c> (<c>BOOST_SCOPE_EXIT(void)</c> should be used to program scope exits with an empty capture list). In general, the special macro @RefMacro{BOOST_SCOPE_EXIT_ALL_ID} must be used instead of @RefMacro{BOOST_SCOPE_EXIT_ALL} when it is necessary to expand multiple scope exit declarations on the same line. @Warning This macro capture list follows the exact same syntax of C++11 lambda captures which is unfortunately different from the syntax of @RefMacro{BOOST_SCOPE_EXIT} captures (unless programmers define the @RefMacro{BOOST_SCOPE_EXIT_CONFIG_USE_LAMBDAS} macro). For example, like C++11 lambda functions, @RefMacro{BOOST_SCOPE_EXIT_ALL} requires to capture data members by capturing the object <c>this</c> while @RefMacro{BOOST_SCOPE_EXIT} allows to capture data members directly and without capturing the object. @Warning The implementation executes the scope exit body within a destructor thus the scope exit body must never throw in order to comply with STL exception safety requirements. @Note This macro can always be used also within templates (so there is no need for a <c>BOOST_SCOPE_EXIT_ALL_TPL</c> macro). @See @RefSect{tutorial, Tutorial} section, @RefSect{no_variadic_macros, No Variadic Macros} section, @RefMacro{BOOST_SCOPE_EXIT}, @RefMacro{BOOST_SCOPE_EXIT_ALL_ID}. */ #define BOOST_SCOPE_EXIT_ALL(capture_list) /** @brief This macro allows to expand on the same line multiple scope exits that capture all variables in scope (C++11 only). This macro is equivalent to @RefMacro{BOOST_SCOPE_EXIT_ALL} but it can be expanded multiple times on the same line if different identifiers <c>id</c> are provided for each expansion (see @RefMacro{BOOST_SCOPE_EXIT_ALL} for more information). As with @RefMacro{BOOST_SCOPE_EXIT_ALL}, this macro is only available on C++11 compilers (specifically, on C++11 compilers that do not define the Boost.Config <c>BOOST_NO_CXX11_LAMBDAS</c> macro). @Params @Param{id, A unique identifier token which can be concatenated by the preprocessor (<c>__LINE__</c>\, <c>scope_exit_number_1_on_line_123</c>\, a combination of alphanumeric tokens\, etc). } @Param{capture_list, Same as the <c>capture_list</c> parameter of the @RefMacro{BOOST_SCOPE_EXIT_ALL} macro. } @EndParams @Note This macro can be useful when the scope exit macros are expanded within user-defined macros (because nested macros expand on the same line). On some compilers (e.g., MSVC which supports the non standard <c>__COUNTER__</c> macro) it might not be necessary to use this macro but the use of this macro is always necessary to ensure portability when expanding multiple scope exit declarations on the same line. @See @RefSect{tutorial, Tutorial} section, @RefMacro{BOOST_SCOPE_EXIT_ALL}, @RefMacro{BOOST_SCOPE_EXIT_ID}. */ #define BOOST_SCOPE_EXIT_ALL_ID(id, capture_list) /** @brief This macro marks the end of a scope exit body. This macro must follow the closing curly bracket <c>}</c> that ends the body of either @RefMacro{BOOST_SCOPE_EXIT} or @RefMacro{BOOST_SCOPE_EXIT_TPL}: @code { // Some local scope. ... BOOST_SCOPE_EXIT(capture_list) { ... // Body code. } BOOST_SCOPE_EXIT_END ... } @endcode In general, the special macro @RefMacro{BOOST_SCOPE_EXIT_END_ID} must be used instead of @RefMacro{BOOST_SCOPE_EXIT_END} when it is necessary to expand multiple scope exit bodies on the same line. @Note If programmers define the @RefMacro{BOOST_SCOPE_EXIT_CONFIG_USE_LAMBDAS} macro on C++11 compilers, a semicolon <c>;</c> can be used instead of this macro. However, to maximize portability, it is recommended to always use @RefMacro{BOOST_SCOPE_EXIT_END}. @See @RefSect{tutorial, Tutorial} section, @RefMacro{BOOST_SCOPE_EXIT}, @RefMacro{BOOST_SCOPE_EXIT_TPL}, @RefMacro{BOOST_SCOPE_EXIT_END_ID}. */ #define BOOST_SCOPE_EXIT_END /** @brief This macro allows to terminate multiple scope exit bodies on the same line. This macro is equivalent to @RefMacro{BOOST_SCOPE_EXIT_END} but it can be expanded multiple times on the same line if different identifiers <c>id</c> are provided for each expansion (see @RefMacro{BOOST_SCOPE_EXIT_END} for more information). @Params @Param{id, A unique identifier token which can be concatenated by the preprocessor (<c>__LINE__</c>\, <c>scope_exit_number_1_on_line_123</c>\, a combination of alphanumeric tokens\, etc). } @EndParams @Note This macro can be useful when the scope exit macros are expanded within user-defined macros (because macros all expand on the same line). On some compilers (e.g., MSVC which supports the non standard <c>__COUNTER__</c> macro) it might not be necessary to use this macro but the use of this macro is always necessary to ensure portability when expanding multiple scope exit macros on the same line (because this library can only portably use <c>__LINE__</c> to internally generate unique identifiers). @See @RefMacro{BOOST_SCOPE_EXIT_ID}, @RefMacro{BOOST_SCOPE_EXIT_ID_TPL}, @RefMacro{BOOST_SCOPE_EXIT_END}. */ #define BOOST_SCOPE_EXIT_END_ID(id) /** @brief Force to use C++11 lambda functions to implement scope exits. If programmers define this configuration macro on a C++11 compiler for which the Boost.Config macro <c>BOOST_NO_CXX11_LAMBDAS</c> is not defined, the @RefMacro{BOOST_SCOPE_EXIT} and @RefMacro{BOOST_SCOPE_EXIT_TPL} macros will use C++11 lambda functions to declare scope exits. By default this macro is not defined. @Warning When scope exits are implemented using lambda functions, the syntax of the capture list follows the exact same syntax of C++11 lambda captures which is in general different from the legacy capture syntax of this library. For example, C++11 lambdas require to capture data members by capturing the object <c>this</c> while this library always allowed to capture data members directly. Therefore, when this configuration macro is defined, @RefMacro{BOOST_SCOPE_EXIT} and @RefMacro{BOOST_SCOPE_EXIT_TPL} are no longer backward compatible (and this is why this macro is not defined by default). A semicolon <c>;</c> can be used instead of @RefMacro{BOOST_SCOPE_EXIT_END} when this configuration macro is defined (but it is recommended to always use @RefMacro{BOOST_SCOPE_EXIT_END} so to maximize portability). @Note This configuration macro does not control the definition of @RefMacro{BOOST_SCOPE_EXIT_ALL} which is always and automatically defined on compilers that support C++11 lambda functions. @See @RefMacro{BOOST_SCOPE_EXIT}, @RefMacro{BOOST_SCOPE_EXIT_TPL}, @RefMacro{BOOST_SCOPE_EXIT_END}. */ #define BOOST_SCOPE_EXIT_CONFIG_USE_LAMBDAS #endif // DOXYGEN #endif // #ifndef FILE_boost_scope_exit_hpp_INCLUDED