// -*- c++ -*- /* Do not edit! -- generated file */ #ifndef _SIGC_SIGNAL_H_ #define _SIGC_SIGNAL_H_ #include #include #include #include #include #include //SIGC_TYPEDEF_REDEFINE_ALLOWED: // TODO: This should have its own test, but I can not create one that gives the error instead of just a warning. murrayc. // I have just used this because there is a correlation between these two problems. #ifdef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD //Compilers, such as older versions of SUN Forte C++, that do not allow this also often //do not allow a typedef to have the same name as a class in the typedef's definition. //For Sun Forte CC 5.7 (SUN Workshop 10), comment this out to fix the build. #define SIGC_TYPEDEF_REDEFINE_ALLOWED 1 #endif namespace sigc { /** STL-style iterator for slot_list. * * @ingroup signal */ template struct slot_iterator { typedef size_t size_type; typedef ptrdiff_t difference_type; typedef std::bidirectional_iterator_tag iterator_category; typedef T_slot slot_type; typedef T_slot value_type; typedef T_slot* pointer; typedef T_slot& reference; typedef typename internal::signal_impl::iterator_type iterator_type; slot_iterator() {} explicit slot_iterator(const iterator_type& i) : i_(i) {} reference operator*() const { return static_cast(*i_); } pointer operator->() const { return &(operator*()); } slot_iterator& operator++() { ++i_; return *this; } slot_iterator operator++(int) { slot_iterator __tmp(*this); ++i_; return __tmp; } slot_iterator& operator--() { --i_; return *this; } slot_iterator operator--(int) { slot_iterator __tmp(*this); --i_; return __tmp; } bool operator == (const slot_iterator& other) const { return i_ == other.i_; } bool operator != (const slot_iterator& other) const { return i_ != other.i_; } iterator_type i_; }; /** STL-style const iterator for slot_list. * * @ingroup signal */ template struct slot_const_iterator { typedef size_t size_type; typedef ptrdiff_t difference_type; typedef std::bidirectional_iterator_tag iterator_category; typedef T_slot slot_type; typedef T_slot value_type; typedef const T_slot* pointer; typedef const T_slot& reference; typedef typename internal::signal_impl::const_iterator_type iterator_type; slot_const_iterator() {} explicit slot_const_iterator(const iterator_type& i) : i_(i) {} reference operator*() const { return static_cast(*i_); } pointer operator->() const { return &(operator*()); } slot_const_iterator& operator++() { ++i_; return *this; } slot_const_iterator operator++(int) { slot_const_iterator __tmp(*this); ++i_; return __tmp; } slot_const_iterator& operator--() { --i_; return *this; } slot_const_iterator operator--(int) { slot_const_iterator __tmp(*this); --i_; return __tmp; } bool operator == (const slot_const_iterator& other) const { return i_ == other.i_; } bool operator != (const slot_const_iterator& other) const { return i_ != other.i_; } iterator_type i_; }; /** STL-style list interface for sigc::signal#. * slot_list can be used to iterate over the list of slots that * is managed by a signal. Slots can be added or removed from * the list while existing iterators stay valid. A slot_list * object can be retrieved from the signal's slots() function. * * @ingroup signal */ template struct slot_list { typedef T_slot slot_type; typedef slot_type& reference; typedef const slot_type& const_reference; typedef slot_iterator iterator; typedef slot_const_iterator const_iterator; #ifndef SIGC_HAVE_SUN_REVERSE_ITERATOR typedef std::reverse_iterator reverse_iterator; typedef std::reverse_iterator const_reverse_iterator; #else typedef std::reverse_iterator reverse_iterator; typedef std::reverse_iterator const_reverse_iterator; #endif /* SIGC_HAVE_SUN_REVERSE_ITERATOR */ slot_list() : list_(0) {} explicit slot_list(internal::signal_impl* __list) : list_(__list) {} iterator begin() { return iterator(list_->slots_.begin()); } const_iterator begin() const { return const_iterator(list_->slots_.begin()); } iterator end() { return iterator(list_->slots_.end()); } const_iterator end() const { return const_iterator(list_->slots_.end()); } reverse_iterator rbegin() { return reverse_iterator(end()); } const_reverse_iterator rbegin() const { return const_reverse_iterator(end()); } reverse_iterator rend() { return reverse_iterator(begin()); } const_reverse_iterator rend() const { return const_reverse_iterator(begin()); } reference front() { return *begin(); } const_reference front() const { return *begin(); } reference back() { return *(--end()); } const_reference back() const { return *(--end()); } iterator insert(iterator i, const slot_type& slot_) { return iterator(list_->insert(i.i_, static_cast(slot_))); } void push_front(const slot_type& c) { insert(begin(), c); } void push_back(const slot_type& c) { insert(end(), c); } iterator erase(iterator i) { return iterator(list_->erase(i.i_)); } iterator erase(iterator first_, iterator last_) { while (first_ != last_) first_ = erase(first_); return last_; } void pop_front() { erase(begin()); } void pop_back() { iterator tmp_ = end(); erase(--tmp_); } protected: internal::signal_impl* list_; }; namespace internal { /** Special iterator over sigc::internal::signal_impl's slot list that holds extra data. * This iterators is for use in accumulators. operator*() executes * the slot. The return value is buffered, so that in an expression * like @code a = (*i) * (*i); @endcode the slot is executed only once. */ template struct slot_iterator_buf { typedef size_t size_type; typedef ptrdiff_t difference_type; typedef std::bidirectional_iterator_tag iterator_category; //These are needed just to make this a proper C++ iterator, //that can be used with standard C++ algorithms. typedef T_result value_type; typedef T_result& reference; typedef T_result* pointer; typedef T_emitter emitter_type; typedef T_result result_type; typedef typename T_emitter::slot_type slot_type; typedef signal_impl::const_iterator_type iterator_type; slot_iterator_buf() : c_(0), invoked_(false) {} slot_iterator_buf(const iterator_type& i, const emitter_type* c) : i_(i), c_(c), invoked_(false) {} result_type operator*() const { if (!i_->empty() && !i_->blocked() && !invoked_) { r_ = (*c_)(static_cast(*i_)); invoked_ = true; } return r_; } slot_iterator_buf& operator++() { ++i_; invoked_ = false; return *this; } slot_iterator_buf operator++(int) { slot_iterator_buf __tmp(*this); ++i_; invoked_ = false; return __tmp; } slot_iterator_buf& operator--() { --i_; invoked_ = false; return *this; } slot_iterator_buf operator--(int) { slot_iterator_buf __tmp(*this); --i_; invoked_ = false; return __tmp; } bool operator == (const slot_iterator_buf& other) const { return (!c_ || (i_ == other.i_)); } /* If '!c_' the iterators are empty. * Unfortunately, empty stl iterators are not equal. * We are forcing equality so that 'first==last' * in the accumulator's emit function yields true. */ bool operator != (const slot_iterator_buf& other) const { return (c_ && (i_ != other.i_)); } private: iterator_type i_; const emitter_type* c_; mutable result_type r_; mutable bool invoked_; }; /** Template specialization of slot_iterator_buf for void return signals. */ template struct slot_iterator_buf { typedef size_t size_type; typedef ptrdiff_t difference_type; typedef std::bidirectional_iterator_tag iterator_category; typedef T_emitter emitter_type; typedef void result_type; typedef typename T_emitter::slot_type slot_type; typedef signal_impl::const_iterator_type iterator_type; slot_iterator_buf() : c_(0), invoked_(false) {} slot_iterator_buf(const iterator_type& i, const emitter_type* c) : i_(i), c_(c), invoked_(false) {} void operator*() const { if (!i_->empty() && !i_->blocked() && !invoked_) { (*c_)(static_cast(*i_)); invoked_ = true; } } slot_iterator_buf& operator++() { ++i_; invoked_ = false; return *this; } slot_iterator_buf operator++(int) { slot_iterator_buf __tmp(*this); ++i_; invoked_ = false; return __tmp; } slot_iterator_buf& operator--() { --i_; invoked_ = false; return *this; } slot_iterator_buf operator--(int) { slot_iterator_buf __tmp(*this); --i_; invoked_ = false; return __tmp; } bool operator == (const slot_iterator_buf& other) const { return i_ == other.i_; } bool operator != (const slot_iterator_buf& other) const { return i_ != other.i_; } private: iterator_type i_; const emitter_type* c_; mutable bool invoked_; }; /** Reverse version of sigc::internal::slot_iterator_buf. */ template struct slot_reverse_iterator_buf { typedef size_t size_type; typedef ptrdiff_t difference_type; typedef std::bidirectional_iterator_tag iterator_category; //These are needed just to make this a proper C++ iterator, //that can be used with standard C++ algorithms. typedef T_result value_type; typedef T_result& reference; typedef T_result* pointer; typedef T_emitter emitter_type; typedef T_result result_type; typedef typename T_emitter::slot_type slot_type; typedef signal_impl::const_iterator_type iterator_type; slot_reverse_iterator_buf() : c_(0), invoked_(false) {} slot_reverse_iterator_buf(const iterator_type& i, const emitter_type* c) : i_(i), c_(c), invoked_(false) {} result_type operator*() const { iterator_type __tmp(i_); --__tmp; if (!__tmp->empty() && !__tmp->blocked() && !invoked_) { r_ = (*c_)(static_cast(*__tmp)); invoked_ = true; } return r_; } slot_reverse_iterator_buf& operator++() { --i_; invoked_ = false; return *this; } slot_reverse_iterator_buf operator++(int) { slot_reverse_iterator_buf __tmp(*this); --i_; invoked_ = false; return __tmp; } slot_reverse_iterator_buf& operator--() { ++i_; invoked_ = false; return *this; } slot_reverse_iterator_buf operator--(int) { slot_reverse_iterator_buf __tmp(*this); ++i_; invoked_ = false; return __tmp; } bool operator == (const slot_reverse_iterator_buf& other) const { return (!c_ || (i_ == other.i_)); } /* If '!c_' the iterators are empty. * Unfortunately, empty stl iterators are not equal. * We are forcing equality so that 'first==last' * in the accumulator's emit function yields true. */ bool operator != (const slot_reverse_iterator_buf& other) const { return (c_ && (i_ != other.i_)); } private: iterator_type i_; const emitter_type* c_; mutable result_type r_; mutable bool invoked_; }; /** Template specialization of slot_reverse_iterator_buf for void return signals. */ template struct slot_reverse_iterator_buf { typedef size_t size_type; typedef ptrdiff_t difference_type; typedef std::bidirectional_iterator_tag iterator_category; typedef T_emitter emitter_type; typedef void result_type; typedef typename T_emitter::slot_type slot_type; typedef signal_impl::const_iterator_type iterator_type; slot_reverse_iterator_buf() : c_(0), invoked_(false) {} slot_reverse_iterator_buf(const iterator_type& i, const emitter_type* c) : i_(i), c_(c), invoked_(false) {} void operator*() const { iterator_type __tmp(i_); --__tmp; if (!__tmp->empty() && !__tmp->blocked() && !invoked_) { (*c_)(static_cast(*__tmp)); invoked_ = true; } } slot_reverse_iterator_buf& operator++() { --i_; invoked_ = false; return *this; } slot_reverse_iterator_buf operator++(int) { slot_reverse_iterator_buf __tmp(*this); --i_; invoked_ = false; return __tmp; } slot_reverse_iterator_buf& operator--() { ++i_; invoked_ = false; return *this; } slot_reverse_iterator_buf operator--(int) { slot_reverse_iterator_buf __tmp(*this); ++i_; invoked_ = false; return __tmp; } bool operator == (const slot_reverse_iterator_buf& other) const { return i_ == other.i_; } bool operator != (const slot_reverse_iterator_buf& other) const { return i_ != other.i_; } private: iterator_type i_; const emitter_type* c_; mutable bool invoked_; }; /** Abstracts signal emission. * This template implements the emit() function of signal0. * Template specializations are available to optimize signal * emission when no accumulator is used, i.e. the template * argument @e T_accumulator is @p nil. */ template struct signal_emit0 { typedef signal_emit0 self_type; typedef typename T_accumulator::result_type result_type; typedef slot slot_type; typedef internal::slot_iterator_buf slot_iterator_buf_type; typedef internal::slot_reverse_iterator_buf slot_reverse_iterator_buf_type; typedef signal_impl::const_iterator_type iterator_type; signal_emit0() {} /** Invokes a slot. * @param _A_slot Some slot to invoke. * @return The slot's return value. */ T_return operator()(const slot_type& _A_slot) const { return (reinterpret_cast(_A_slot.rep_->call_))(_A_slot.rep_); } /** Executes a list of slots using an accumulator of type @e T_accumulator. * @return The accumulated return values of the slot invocations as processed by the accumulator. */ static result_type emit(signal_impl* impl) { T_accumulator accumulator; if (!impl) return accumulator(slot_iterator_buf_type(), slot_iterator_buf_type()); signal_exec exec(impl); temp_slot_list slots(impl->slots_); self_type self ; return accumulator(slot_iterator_buf_type(slots.begin(), &self), slot_iterator_buf_type(slots.end(), &self)); } /** Executes a list of slots using an accumulator of type @e T_accumulator in reverse order. * @return The accumulated return values of the slot invocations as processed by the accumulator. */ static result_type emit_reverse(signal_impl* impl) { T_accumulator accumulator; if (!impl) return accumulator(slot_iterator_buf_type(), slot_iterator_buf_type()); signal_exec exec(impl); temp_slot_list slots(impl->slots_); self_type self ; return accumulator(slot_reverse_iterator_buf_type(slots.end(), &self), slot_reverse_iterator_buf_type(slots.begin(), &self)); } }; /** Abstracts signal emission. * This template specialization implements an optimized emit() * function for the case that no accumulator is used. */ template struct signal_emit0 { typedef signal_emit0 self_type; typedef T_return result_type; typedef slot slot_type; typedef signal_impl::const_iterator_type iterator_type; typedef typename slot_type::call_type call_type; /** Executes a list of slots using an accumulator of type @e T_accumulator. * The return value of the last slot invoked is returned. * @param first An iterator pointing to the first slot in the list. * @param last An iterator pointing to the last slot in the list. * @return The return value of the last slot invoked. */ static result_type emit(signal_impl* impl) { if (!impl || impl->slots_.empty()) return T_return(); signal_exec exec(impl); T_return r_ = T_return(); //Use this scope to make sure that "slots" is destroyed before "exec" is destroyed. //This avoids a leak on MSVC++ - see http://bugzilla.gnome.org/show_bug.cgi?id=306249 { temp_slot_list slots(impl->slots_); iterator_type it = slots.begin(); for (; it != slots.end(); ++it) if (!it->empty() && !it->blocked()) break; if (it == slots.end()) return T_return(); // note that 'T_return r_();' doesn't work => define 'r_' after this line and initialize as follows: r_ = (reinterpret_cast(it->rep_->call_))(it->rep_); for (++it; it != slots.end(); ++it) { if (it->empty() || it->blocked()) continue; r_ = (reinterpret_cast(it->rep_->call_))(it->rep_); } } return r_; } /** Executes a list of slots using an accumulator of type @e T_accumulator in reverse order. * The return value of the last slot invoked is returned. * @param first An iterator pointing to the first slot in the list. * @param last An iterator pointing to the last slot in the list. * @return The return value of the last slot invoked. */ static result_type emit_reverse(signal_impl* impl) { if (!impl || impl->slots_.empty()) return T_return(); signal_exec exec(impl); T_return r_ = T_return(); //Use this scope to make sure that "slots" is destroyed before "exec" is destroyed. //This avoids a leak on MSVC++ - see http://bugzilla.gnome.org/show_bug.cgi?id=306249 { #ifndef SIGC_HAVE_SUN_REVERSE_ITERATOR typedef std::reverse_iterator reverse_iterator_type; #else typedef std::reverse_iterator reverse_iterator_type; #endif temp_slot_list slots(impl->slots_); reverse_iterator_type it(slots.end()); for (; it != reverse_iterator_type(slots.begin()); ++it) if (!it->empty() && !it->blocked()) break; if (it == reverse_iterator_type(slots.begin())) return T_return(); // note that 'T_return r_();' doesn't work => define 'r_' after this line and initialize as follows: r_ = (reinterpret_cast(it->rep_->call_))(it->rep_); for (++it; it != reverse_iterator_type(slots.begin()); ++it) { if (it->empty() || it->blocked()) continue; r_ = (reinterpret_cast(it->rep_->call_))(it->rep_); } } return r_; } }; /** Abstracts signal emission. * This template specialization implements an optimized emit() * function for the case that no accumulator is used and the * return type is @p void. */ template <> struct signal_emit0 { typedef signal_emit0 self_type; typedef void result_type; typedef slot slot_type; typedef signal_impl::const_iterator_type iterator_type; typedef void (*call_type)(slot_rep*); /** Executes a list of slots using an accumulator of type @e T_accumulator. * @param first An iterator pointing to the first slot in the list. * @param last An iterator pointing to the last slot in the list. */ static result_type emit(signal_impl* impl) { if (!impl || impl->slots_.empty()) return; signal_exec exec(impl); temp_slot_list slots(impl->slots_); for (iterator_type it = slots.begin(); it != slots.end(); ++it) { if (it->empty() || it->blocked()) continue; (reinterpret_cast(it->rep_->call_))(it->rep_); } } /** Executes a list of slots using an accumulator of type @e T_accumulator in reverse order. * @param first An iterator pointing to the first slot in the list. * @param last An iterator pointing to the last slot in the list. */ static result_type emit_reverse(signal_impl* impl) { if (!impl || impl->slots_.empty()) return; signal_exec exec(impl); temp_slot_list slots(impl->slots_); #ifndef SIGC_HAVE_SUN_REVERSE_ITERATOR typedef std::reverse_iterator reverse_iterator_type; #else typedef std::reverse_iterator reverse_iterator_type; #endif for (reverse_iterator_type it = reverse_iterator_type(slots.end()); it != reverse_iterator_type(slots.begin()); ++it) { if (it->empty() || it->blocked()) continue; (reinterpret_cast(it->rep_->call_))(it->rep_); } } }; /** Abstracts signal emission. * This template implements the emit() function of signal1. * Template specializations are available to optimize signal * emission when no accumulator is used, i.e. the template * argument @e T_accumulator is @p nil. */ template struct signal_emit1 { typedef signal_emit1 self_type; typedef typename T_accumulator::result_type result_type; typedef slot slot_type; typedef internal::slot_iterator_buf slot_iterator_buf_type; typedef internal::slot_reverse_iterator_buf slot_reverse_iterator_buf_type; typedef signal_impl::const_iterator_type iterator_type; /** Instantiates the class. * The parameters are stored in member variables. operator()() passes * the values on to some slot. */ signal_emit1(typename type_trait::take _A_a1) : _A_a1_(_A_a1) {} /** Invokes a slot using the buffered parameter values. * @param _A_slot Some slot to invoke. * @return The slot's return value. */ T_return operator()(const slot_type& _A_slot) const { return (reinterpret_cast(_A_slot.rep_->call_))(_A_slot.rep_, _A_a1_); } /** Executes a list of slots using an accumulator of type @e T_accumulator. * The arguments are buffered in a temporary instance of signal_emit1. * @param _A_a1 Argument to be passed on to the slots. * @return The accumulated return values of the slot invocations as processed by the accumulator. */ static result_type emit(signal_impl* impl, typename type_trait::take _A_a1) { T_accumulator accumulator; if (!impl) return accumulator(slot_iterator_buf_type(), slot_iterator_buf_type()); signal_exec exec(impl); temp_slot_list slots(impl->slots_); self_type self (_A_a1); return accumulator(slot_iterator_buf_type(slots.begin(), &self), slot_iterator_buf_type(slots.end(), &self)); } /** Executes a list of slots using an accumulator of type @e T_accumulator in reverse order. * The arguments are buffered in a temporary instance of signal_emit1. * @param _A_a1 Argument to be passed on to the slots. * @return The accumulated return values of the slot invocations as processed by the accumulator. */ static result_type emit_reverse(signal_impl* impl, typename type_trait::take _A_a1) { T_accumulator accumulator; if (!impl) return accumulator(slot_iterator_buf_type(), slot_iterator_buf_type()); signal_exec exec(impl); temp_slot_list slots(impl->slots_); self_type self (_A_a1); return accumulator(slot_reverse_iterator_buf_type(slots.end(), &self), slot_reverse_iterator_buf_type(slots.begin(), &self)); } typename type_trait::take _A_a1_; }; /** Abstracts signal emission. * This template specialization implements an optimized emit() * function for the case that no accumulator is used. */ template struct signal_emit1 { typedef signal_emit1 self_type; typedef T_return result_type; typedef slot slot_type; typedef signal_impl::const_iterator_type iterator_type; typedef typename slot_type::call_type call_type; /** Executes a list of slots using an accumulator of type @e T_accumulator. * The arguments are passed directly on to the slots. * The return value of the last slot invoked is returned. * @param first An iterator pointing to the first slot in the list. * @param last An iterator pointing to the last slot in the list. * @param _A_a1 Argument to be passed on to the slots. * @return The return value of the last slot invoked. */ static result_type emit(signal_impl* impl, typename type_trait::take _A_a1) { if (!impl || impl->slots_.empty()) return T_return(); signal_exec exec(impl); T_return r_ = T_return(); //Use this scope to make sure that "slots" is destroyed before "exec" is destroyed. //This avoids a leak on MSVC++ - see http://bugzilla.gnome.org/show_bug.cgi?id=306249 { temp_slot_list slots(impl->slots_); iterator_type it = slots.begin(); for (; it != slots.end(); ++it) if (!it->empty() && !it->blocked()) break; if (it == slots.end()) return T_return(); // note that 'T_return r_();' doesn't work => define 'r_' after this line and initialize as follows: r_ = (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1); for (++it; it != slots.end(); ++it) { if (it->empty() || it->blocked()) continue; r_ = (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1); } } return r_; } /** Executes a list of slots using an accumulator of type @e T_accumulator in reverse order. * The arguments are passed directly on to the slots. * The return value of the last slot invoked is returned. * @param first An iterator pointing to the first slot in the list. * @param last An iterator pointing to the last slot in the list. * @param _A_a1 Argument to be passed on to the slots. * @return The return value of the last slot invoked. */ static result_type emit_reverse(signal_impl* impl, typename type_trait::take _A_a1) { if (!impl || impl->slots_.empty()) return T_return(); signal_exec exec(impl); T_return r_ = T_return(); //Use this scope to make sure that "slots" is destroyed before "exec" is destroyed. //This avoids a leak on MSVC++ - see http://bugzilla.gnome.org/show_bug.cgi?id=306249 { #ifndef SIGC_HAVE_SUN_REVERSE_ITERATOR typedef std::reverse_iterator reverse_iterator_type; #else typedef std::reverse_iterator reverse_iterator_type; #endif temp_slot_list slots(impl->slots_); reverse_iterator_type it(slots.end()); for (; it != reverse_iterator_type(slots.begin()); ++it) if (!it->empty() && !it->blocked()) break; if (it == reverse_iterator_type(slots.begin())) return T_return(); // note that 'T_return r_();' doesn't work => define 'r_' after this line and initialize as follows: r_ = (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1); for (++it; it != reverse_iterator_type(slots.begin()); ++it) { if (it->empty() || it->blocked()) continue; r_ = (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1); } } return r_; } }; /** Abstracts signal emission. * This template specialization implements an optimized emit() * function for the case that no accumulator is used and the * return type is @p void. */ template struct signal_emit1 { typedef signal_emit1 self_type; typedef void result_type; typedef slot slot_type; typedef signal_impl::const_iterator_type iterator_type; typedef typename slot_type::call_type call_type; /** Executes a list of slots using an accumulator of type @e T_accumulator. * The arguments are passed directly on to the slots. * @param first An iterator pointing to the first slot in the list. * @param last An iterator pointing to the last slot in the list. * @param _A_a1 Argument to be passed on to the slots. */ static result_type emit(signal_impl* impl, typename type_trait::take _A_a1) { if (!impl || impl->slots_.empty()) return; signal_exec exec(impl); temp_slot_list slots(impl->slots_); for (iterator_type it = slots.begin(); it != slots.end(); ++it) { if (it->empty() || it->blocked()) continue; (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1); } } /** Executes a list of slots using an accumulator of type @e T_accumulator in reverse order. * The arguments are passed directly on to the slots. * @param first An iterator pointing to the first slot in the list. * @param last An iterator pointing to the last slot in the list. * @param _A_a1 Argument to be passed on to the slots. */ static result_type emit_reverse(signal_impl* impl, typename type_trait::take _A_a1) { if (!impl || impl->slots_.empty()) return; signal_exec exec(impl); temp_slot_list slots(impl->slots_); #ifndef SIGC_HAVE_SUN_REVERSE_ITERATOR typedef std::reverse_iterator reverse_iterator_type; #else typedef std::reverse_iterator reverse_iterator_type; #endif for (reverse_iterator_type it = reverse_iterator_type(slots.end()); it != reverse_iterator_type(slots.begin()); ++it) { if (it->empty() || it->blocked()) continue; (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1); } } }; /** Abstracts signal emission. * This template implements the emit() function of signal2. * Template specializations are available to optimize signal * emission when no accumulator is used, i.e. the template * argument @e T_accumulator is @p nil. */ template struct signal_emit2 { typedef signal_emit2 self_type; typedef typename T_accumulator::result_type result_type; typedef slot slot_type; typedef internal::slot_iterator_buf slot_iterator_buf_type; typedef internal::slot_reverse_iterator_buf slot_reverse_iterator_buf_type; typedef signal_impl::const_iterator_type iterator_type; /** Instantiates the class. * The parameters are stored in member variables. operator()() passes * the values on to some slot. */ signal_emit2(typename type_trait::take _A_a1, typename type_trait::take _A_a2) : _A_a1_(_A_a1), _A_a2_(_A_a2) {} /** Invokes a slot using the buffered parameter values. * @param _A_slot Some slot to invoke. * @return The slot's return value. */ T_return operator()(const slot_type& _A_slot) const { return (reinterpret_cast(_A_slot.rep_->call_))(_A_slot.rep_, _A_a1_, _A_a2_); } /** Executes a list of slots using an accumulator of type @e T_accumulator. * The arguments are buffered in a temporary instance of signal_emit2. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. * @return The accumulated return values of the slot invocations as processed by the accumulator. */ static result_type emit(signal_impl* impl, typename type_trait::take _A_a1, typename type_trait::take _A_a2) { T_accumulator accumulator; if (!impl) return accumulator(slot_iterator_buf_type(), slot_iterator_buf_type()); signal_exec exec(impl); temp_slot_list slots(impl->slots_); self_type self (_A_a1, _A_a2); return accumulator(slot_iterator_buf_type(slots.begin(), &self), slot_iterator_buf_type(slots.end(), &self)); } /** Executes a list of slots using an accumulator of type @e T_accumulator in reverse order. * The arguments are buffered in a temporary instance of signal_emit2. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. * @return The accumulated return values of the slot invocations as processed by the accumulator. */ static result_type emit_reverse(signal_impl* impl, typename type_trait::take _A_a1, typename type_trait::take _A_a2) { T_accumulator accumulator; if (!impl) return accumulator(slot_iterator_buf_type(), slot_iterator_buf_type()); signal_exec exec(impl); temp_slot_list slots(impl->slots_); self_type self (_A_a1, _A_a2); return accumulator(slot_reverse_iterator_buf_type(slots.end(), &self), slot_reverse_iterator_buf_type(slots.begin(), &self)); } typename type_trait::take _A_a1_; typename type_trait::take _A_a2_; }; /** Abstracts signal emission. * This template specialization implements an optimized emit() * function for the case that no accumulator is used. */ template struct signal_emit2 { typedef signal_emit2 self_type; typedef T_return result_type; typedef slot slot_type; typedef signal_impl::const_iterator_type iterator_type; typedef typename slot_type::call_type call_type; /** Executes a list of slots using an accumulator of type @e T_accumulator. * The arguments are passed directly on to the slots. * The return value of the last slot invoked is returned. * @param first An iterator pointing to the first slot in the list. * @param last An iterator pointing to the last slot in the list. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. * @return The return value of the last slot invoked. */ static result_type emit(signal_impl* impl, typename type_trait::take _A_a1, typename type_trait::take _A_a2) { if (!impl || impl->slots_.empty()) return T_return(); signal_exec exec(impl); T_return r_ = T_return(); //Use this scope to make sure that "slots" is destroyed before "exec" is destroyed. //This avoids a leak on MSVC++ - see http://bugzilla.gnome.org/show_bug.cgi?id=306249 { temp_slot_list slots(impl->slots_); iterator_type it = slots.begin(); for (; it != slots.end(); ++it) if (!it->empty() && !it->blocked()) break; if (it == slots.end()) return T_return(); // note that 'T_return r_();' doesn't work => define 'r_' after this line and initialize as follows: r_ = (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1, _A_a2); for (++it; it != slots.end(); ++it) { if (it->empty() || it->blocked()) continue; r_ = (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1, _A_a2); } } return r_; } /** Executes a list of slots using an accumulator of type @e T_accumulator in reverse order. * The arguments are passed directly on to the slots. * The return value of the last slot invoked is returned. * @param first An iterator pointing to the first slot in the list. * @param last An iterator pointing to the last slot in the list. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. * @return The return value of the last slot invoked. */ static result_type emit_reverse(signal_impl* impl, typename type_trait::take _A_a1, typename type_trait::take _A_a2) { if (!impl || impl->slots_.empty()) return T_return(); signal_exec exec(impl); T_return r_ = T_return(); //Use this scope to make sure that "slots" is destroyed before "exec" is destroyed. //This avoids a leak on MSVC++ - see http://bugzilla.gnome.org/show_bug.cgi?id=306249 { #ifndef SIGC_HAVE_SUN_REVERSE_ITERATOR typedef std::reverse_iterator reverse_iterator_type; #else typedef std::reverse_iterator reverse_iterator_type; #endif temp_slot_list slots(impl->slots_); reverse_iterator_type it(slots.end()); for (; it != reverse_iterator_type(slots.begin()); ++it) if (!it->empty() && !it->blocked()) break; if (it == reverse_iterator_type(slots.begin())) return T_return(); // note that 'T_return r_();' doesn't work => define 'r_' after this line and initialize as follows: r_ = (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1, _A_a2); for (++it; it != reverse_iterator_type(slots.begin()); ++it) { if (it->empty() || it->blocked()) continue; r_ = (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1, _A_a2); } } return r_; } }; /** Abstracts signal emission. * This template specialization implements an optimized emit() * function for the case that no accumulator is used and the * return type is @p void. */ template struct signal_emit2 { typedef signal_emit2 self_type; typedef void result_type; typedef slot slot_type; typedef signal_impl::const_iterator_type iterator_type; typedef typename slot_type::call_type call_type; /** Executes a list of slots using an accumulator of type @e T_accumulator. * The arguments are passed directly on to the slots. * @param first An iterator pointing to the first slot in the list. * @param last An iterator pointing to the last slot in the list. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. */ static result_type emit(signal_impl* impl, typename type_trait::take _A_a1, typename type_trait::take _A_a2) { if (!impl || impl->slots_.empty()) return; signal_exec exec(impl); temp_slot_list slots(impl->slots_); for (iterator_type it = slots.begin(); it != slots.end(); ++it) { if (it->empty() || it->blocked()) continue; (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1, _A_a2); } } /** Executes a list of slots using an accumulator of type @e T_accumulator in reverse order. * The arguments are passed directly on to the slots. * @param first An iterator pointing to the first slot in the list. * @param last An iterator pointing to the last slot in the list. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. */ static result_type emit_reverse(signal_impl* impl, typename type_trait::take _A_a1, typename type_trait::take _A_a2) { if (!impl || impl->slots_.empty()) return; signal_exec exec(impl); temp_slot_list slots(impl->slots_); #ifndef SIGC_HAVE_SUN_REVERSE_ITERATOR typedef std::reverse_iterator reverse_iterator_type; #else typedef std::reverse_iterator reverse_iterator_type; #endif for (reverse_iterator_type it = reverse_iterator_type(slots.end()); it != reverse_iterator_type(slots.begin()); ++it) { if (it->empty() || it->blocked()) continue; (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1, _A_a2); } } }; /** Abstracts signal emission. * This template implements the emit() function of signal3. * Template specializations are available to optimize signal * emission when no accumulator is used, i.e. the template * argument @e T_accumulator is @p nil. */ template struct signal_emit3 { typedef signal_emit3 self_type; typedef typename T_accumulator::result_type result_type; typedef slot slot_type; typedef internal::slot_iterator_buf slot_iterator_buf_type; typedef internal::slot_reverse_iterator_buf slot_reverse_iterator_buf_type; typedef signal_impl::const_iterator_type iterator_type; /** Instantiates the class. * The parameters are stored in member variables. operator()() passes * the values on to some slot. */ signal_emit3(typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3) : _A_a1_(_A_a1), _A_a2_(_A_a2), _A_a3_(_A_a3) {} /** Invokes a slot using the buffered parameter values. * @param _A_slot Some slot to invoke. * @return The slot's return value. */ T_return operator()(const slot_type& _A_slot) const { return (reinterpret_cast(_A_slot.rep_->call_))(_A_slot.rep_, _A_a1_, _A_a2_, _A_a3_); } /** Executes a list of slots using an accumulator of type @e T_accumulator. * The arguments are buffered in a temporary instance of signal_emit3. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. * @param _A_a3 Argument to be passed on to the slots. * @return The accumulated return values of the slot invocations as processed by the accumulator. */ static result_type emit(signal_impl* impl, typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3) { T_accumulator accumulator; if (!impl) return accumulator(slot_iterator_buf_type(), slot_iterator_buf_type()); signal_exec exec(impl); temp_slot_list slots(impl->slots_); self_type self (_A_a1, _A_a2, _A_a3); return accumulator(slot_iterator_buf_type(slots.begin(), &self), slot_iterator_buf_type(slots.end(), &self)); } /** Executes a list of slots using an accumulator of type @e T_accumulator in reverse order. * The arguments are buffered in a temporary instance of signal_emit3. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. * @param _A_a3 Argument to be passed on to the slots. * @return The accumulated return values of the slot invocations as processed by the accumulator. */ static result_type emit_reverse(signal_impl* impl, typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3) { T_accumulator accumulator; if (!impl) return accumulator(slot_iterator_buf_type(), slot_iterator_buf_type()); signal_exec exec(impl); temp_slot_list slots(impl->slots_); self_type self (_A_a1, _A_a2, _A_a3); return accumulator(slot_reverse_iterator_buf_type(slots.end(), &self), slot_reverse_iterator_buf_type(slots.begin(), &self)); } typename type_trait::take _A_a1_; typename type_trait::take _A_a2_; typename type_trait::take _A_a3_; }; /** Abstracts signal emission. * This template specialization implements an optimized emit() * function for the case that no accumulator is used. */ template struct signal_emit3 { typedef signal_emit3 self_type; typedef T_return result_type; typedef slot slot_type; typedef signal_impl::const_iterator_type iterator_type; typedef typename slot_type::call_type call_type; /** Executes a list of slots using an accumulator of type @e T_accumulator. * The arguments are passed directly on to the slots. * The return value of the last slot invoked is returned. * @param first An iterator pointing to the first slot in the list. * @param last An iterator pointing to the last slot in the list. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. * @param _A_a3 Argument to be passed on to the slots. * @return The return value of the last slot invoked. */ static result_type emit(signal_impl* impl, typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3) { if (!impl || impl->slots_.empty()) return T_return(); signal_exec exec(impl); T_return r_ = T_return(); //Use this scope to make sure that "slots" is destroyed before "exec" is destroyed. //This avoids a leak on MSVC++ - see http://bugzilla.gnome.org/show_bug.cgi?id=306249 { temp_slot_list slots(impl->slots_); iterator_type it = slots.begin(); for (; it != slots.end(); ++it) if (!it->empty() && !it->blocked()) break; if (it == slots.end()) return T_return(); // note that 'T_return r_();' doesn't work => define 'r_' after this line and initialize as follows: r_ = (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1, _A_a2, _A_a3); for (++it; it != slots.end(); ++it) { if (it->empty() || it->blocked()) continue; r_ = (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1, _A_a2, _A_a3); } } return r_; } /** Executes a list of slots using an accumulator of type @e T_accumulator in reverse order. * The arguments are passed directly on to the slots. * The return value of the last slot invoked is returned. * @param first An iterator pointing to the first slot in the list. * @param last An iterator pointing to the last slot in the list. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. * @param _A_a3 Argument to be passed on to the slots. * @return The return value of the last slot invoked. */ static result_type emit_reverse(signal_impl* impl, typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3) { if (!impl || impl->slots_.empty()) return T_return(); signal_exec exec(impl); T_return r_ = T_return(); //Use this scope to make sure that "slots" is destroyed before "exec" is destroyed. //This avoids a leak on MSVC++ - see http://bugzilla.gnome.org/show_bug.cgi?id=306249 { #ifndef SIGC_HAVE_SUN_REVERSE_ITERATOR typedef std::reverse_iterator reverse_iterator_type; #else typedef std::reverse_iterator reverse_iterator_type; #endif temp_slot_list slots(impl->slots_); reverse_iterator_type it(slots.end()); for (; it != reverse_iterator_type(slots.begin()); ++it) if (!it->empty() && !it->blocked()) break; if (it == reverse_iterator_type(slots.begin())) return T_return(); // note that 'T_return r_();' doesn't work => define 'r_' after this line and initialize as follows: r_ = (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1, _A_a2, _A_a3); for (++it; it != reverse_iterator_type(slots.begin()); ++it) { if (it->empty() || it->blocked()) continue; r_ = (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1, _A_a2, _A_a3); } } return r_; } }; /** Abstracts signal emission. * This template specialization implements an optimized emit() * function for the case that no accumulator is used and the * return type is @p void. */ template struct signal_emit3 { typedef signal_emit3 self_type; typedef void result_type; typedef slot slot_type; typedef signal_impl::const_iterator_type iterator_type; typedef typename slot_type::call_type call_type; /** Executes a list of slots using an accumulator of type @e T_accumulator. * The arguments are passed directly on to the slots. * @param first An iterator pointing to the first slot in the list. * @param last An iterator pointing to the last slot in the list. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. * @param _A_a3 Argument to be passed on to the slots. */ static result_type emit(signal_impl* impl, typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3) { if (!impl || impl->slots_.empty()) return; signal_exec exec(impl); temp_slot_list slots(impl->slots_); for (iterator_type it = slots.begin(); it != slots.end(); ++it) { if (it->empty() || it->blocked()) continue; (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1, _A_a2, _A_a3); } } /** Executes a list of slots using an accumulator of type @e T_accumulator in reverse order. * The arguments are passed directly on to the slots. * @param first An iterator pointing to the first slot in the list. * @param last An iterator pointing to the last slot in the list. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. * @param _A_a3 Argument to be passed on to the slots. */ static result_type emit_reverse(signal_impl* impl, typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3) { if (!impl || impl->slots_.empty()) return; signal_exec exec(impl); temp_slot_list slots(impl->slots_); #ifndef SIGC_HAVE_SUN_REVERSE_ITERATOR typedef std::reverse_iterator reverse_iterator_type; #else typedef std::reverse_iterator reverse_iterator_type; #endif for (reverse_iterator_type it = reverse_iterator_type(slots.end()); it != reverse_iterator_type(slots.begin()); ++it) { if (it->empty() || it->blocked()) continue; (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1, _A_a2, _A_a3); } } }; /** Abstracts signal emission. * This template implements the emit() function of signal4. * Template specializations are available to optimize signal * emission when no accumulator is used, i.e. the template * argument @e T_accumulator is @p nil. */ template struct signal_emit4 { typedef signal_emit4 self_type; typedef typename T_accumulator::result_type result_type; typedef slot slot_type; typedef internal::slot_iterator_buf slot_iterator_buf_type; typedef internal::slot_reverse_iterator_buf slot_reverse_iterator_buf_type; typedef signal_impl::const_iterator_type iterator_type; /** Instantiates the class. * The parameters are stored in member variables. operator()() passes * the values on to some slot. */ signal_emit4(typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3, typename type_trait::take _A_a4) : _A_a1_(_A_a1), _A_a2_(_A_a2), _A_a3_(_A_a3), _A_a4_(_A_a4) {} /** Invokes a slot using the buffered parameter values. * @param _A_slot Some slot to invoke. * @return The slot's return value. */ T_return operator()(const slot_type& _A_slot) const { return (reinterpret_cast(_A_slot.rep_->call_))(_A_slot.rep_, _A_a1_, _A_a2_, _A_a3_, _A_a4_); } /** Executes a list of slots using an accumulator of type @e T_accumulator. * The arguments are buffered in a temporary instance of signal_emit4. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. * @param _A_a3 Argument to be passed on to the slots. * @param _A_a4 Argument to be passed on to the slots. * @return The accumulated return values of the slot invocations as processed by the accumulator. */ static result_type emit(signal_impl* impl, typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3, typename type_trait::take _A_a4) { T_accumulator accumulator; if (!impl) return accumulator(slot_iterator_buf_type(), slot_iterator_buf_type()); signal_exec exec(impl); temp_slot_list slots(impl->slots_); self_type self (_A_a1, _A_a2, _A_a3, _A_a4); return accumulator(slot_iterator_buf_type(slots.begin(), &self), slot_iterator_buf_type(slots.end(), &self)); } /** Executes a list of slots using an accumulator of type @e T_accumulator in reverse order. * The arguments are buffered in a temporary instance of signal_emit4. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. * @param _A_a3 Argument to be passed on to the slots. * @param _A_a4 Argument to be passed on to the slots. * @return The accumulated return values of the slot invocations as processed by the accumulator. */ static result_type emit_reverse(signal_impl* impl, typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3, typename type_trait::take _A_a4) { T_accumulator accumulator; if (!impl) return accumulator(slot_iterator_buf_type(), slot_iterator_buf_type()); signal_exec exec(impl); temp_slot_list slots(impl->slots_); self_type self (_A_a1, _A_a2, _A_a3, _A_a4); return accumulator(slot_reverse_iterator_buf_type(slots.end(), &self), slot_reverse_iterator_buf_type(slots.begin(), &self)); } typename type_trait::take _A_a1_; typename type_trait::take _A_a2_; typename type_trait::take _A_a3_; typename type_trait::take _A_a4_; }; /** Abstracts signal emission. * This template specialization implements an optimized emit() * function for the case that no accumulator is used. */ template struct signal_emit4 { typedef signal_emit4 self_type; typedef T_return result_type; typedef slot slot_type; typedef signal_impl::const_iterator_type iterator_type; typedef typename slot_type::call_type call_type; /** Executes a list of slots using an accumulator of type @e T_accumulator. * The arguments are passed directly on to the slots. * The return value of the last slot invoked is returned. * @param first An iterator pointing to the first slot in the list. * @param last An iterator pointing to the last slot in the list. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. * @param _A_a3 Argument to be passed on to the slots. * @param _A_a4 Argument to be passed on to the slots. * @return The return value of the last slot invoked. */ static result_type emit(signal_impl* impl, typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3, typename type_trait::take _A_a4) { if (!impl || impl->slots_.empty()) return T_return(); signal_exec exec(impl); T_return r_ = T_return(); //Use this scope to make sure that "slots" is destroyed before "exec" is destroyed. //This avoids a leak on MSVC++ - see http://bugzilla.gnome.org/show_bug.cgi?id=306249 { temp_slot_list slots(impl->slots_); iterator_type it = slots.begin(); for (; it != slots.end(); ++it) if (!it->empty() && !it->blocked()) break; if (it == slots.end()) return T_return(); // note that 'T_return r_();' doesn't work => define 'r_' after this line and initialize as follows: r_ = (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1, _A_a2, _A_a3, _A_a4); for (++it; it != slots.end(); ++it) { if (it->empty() || it->blocked()) continue; r_ = (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1, _A_a2, _A_a3, _A_a4); } } return r_; } /** Executes a list of slots using an accumulator of type @e T_accumulator in reverse order. * The arguments are passed directly on to the slots. * The return value of the last slot invoked is returned. * @param first An iterator pointing to the first slot in the list. * @param last An iterator pointing to the last slot in the list. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. * @param _A_a3 Argument to be passed on to the slots. * @param _A_a4 Argument to be passed on to the slots. * @return The return value of the last slot invoked. */ static result_type emit_reverse(signal_impl* impl, typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3, typename type_trait::take _A_a4) { if (!impl || impl->slots_.empty()) return T_return(); signal_exec exec(impl); T_return r_ = T_return(); //Use this scope to make sure that "slots" is destroyed before "exec" is destroyed. //This avoids a leak on MSVC++ - see http://bugzilla.gnome.org/show_bug.cgi?id=306249 { #ifndef SIGC_HAVE_SUN_REVERSE_ITERATOR typedef std::reverse_iterator reverse_iterator_type; #else typedef std::reverse_iterator reverse_iterator_type; #endif temp_slot_list slots(impl->slots_); reverse_iterator_type it(slots.end()); for (; it != reverse_iterator_type(slots.begin()); ++it) if (!it->empty() && !it->blocked()) break; if (it == reverse_iterator_type(slots.begin())) return T_return(); // note that 'T_return r_();' doesn't work => define 'r_' after this line and initialize as follows: r_ = (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1, _A_a2, _A_a3, _A_a4); for (++it; it != reverse_iterator_type(slots.begin()); ++it) { if (it->empty() || it->blocked()) continue; r_ = (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1, _A_a2, _A_a3, _A_a4); } } return r_; } }; /** Abstracts signal emission. * This template specialization implements an optimized emit() * function for the case that no accumulator is used and the * return type is @p void. */ template struct signal_emit4 { typedef signal_emit4 self_type; typedef void result_type; typedef slot slot_type; typedef signal_impl::const_iterator_type iterator_type; typedef typename slot_type::call_type call_type; /** Executes a list of slots using an accumulator of type @e T_accumulator. * The arguments are passed directly on to the slots. * @param first An iterator pointing to the first slot in the list. * @param last An iterator pointing to the last slot in the list. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. * @param _A_a3 Argument to be passed on to the slots. * @param _A_a4 Argument to be passed on to the slots. */ static result_type emit(signal_impl* impl, typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3, typename type_trait::take _A_a4) { if (!impl || impl->slots_.empty()) return; signal_exec exec(impl); temp_slot_list slots(impl->slots_); for (iterator_type it = slots.begin(); it != slots.end(); ++it) { if (it->empty() || it->blocked()) continue; (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1, _A_a2, _A_a3, _A_a4); } } /** Executes a list of slots using an accumulator of type @e T_accumulator in reverse order. * The arguments are passed directly on to the slots. * @param first An iterator pointing to the first slot in the list. * @param last An iterator pointing to the last slot in the list. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. * @param _A_a3 Argument to be passed on to the slots. * @param _A_a4 Argument to be passed on to the slots. */ static result_type emit_reverse(signal_impl* impl, typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3, typename type_trait::take _A_a4) { if (!impl || impl->slots_.empty()) return; signal_exec exec(impl); temp_slot_list slots(impl->slots_); #ifndef SIGC_HAVE_SUN_REVERSE_ITERATOR typedef std::reverse_iterator reverse_iterator_type; #else typedef std::reverse_iterator reverse_iterator_type; #endif for (reverse_iterator_type it = reverse_iterator_type(slots.end()); it != reverse_iterator_type(slots.begin()); ++it) { if (it->empty() || it->blocked()) continue; (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1, _A_a2, _A_a3, _A_a4); } } }; /** Abstracts signal emission. * This template implements the emit() function of signal5. * Template specializations are available to optimize signal * emission when no accumulator is used, i.e. the template * argument @e T_accumulator is @p nil. */ template struct signal_emit5 { typedef signal_emit5 self_type; typedef typename T_accumulator::result_type result_type; typedef slot slot_type; typedef internal::slot_iterator_buf slot_iterator_buf_type; typedef internal::slot_reverse_iterator_buf slot_reverse_iterator_buf_type; typedef signal_impl::const_iterator_type iterator_type; /** Instantiates the class. * The parameters are stored in member variables. operator()() passes * the values on to some slot. */ signal_emit5(typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3, typename type_trait::take _A_a4, typename type_trait::take _A_a5) : _A_a1_(_A_a1), _A_a2_(_A_a2), _A_a3_(_A_a3), _A_a4_(_A_a4), _A_a5_(_A_a5) {} /** Invokes a slot using the buffered parameter values. * @param _A_slot Some slot to invoke. * @return The slot's return value. */ T_return operator()(const slot_type& _A_slot) const { return (reinterpret_cast(_A_slot.rep_->call_))(_A_slot.rep_, _A_a1_, _A_a2_, _A_a3_, _A_a4_, _A_a5_); } /** Executes a list of slots using an accumulator of type @e T_accumulator. * The arguments are buffered in a temporary instance of signal_emit5. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. * @param _A_a3 Argument to be passed on to the slots. * @param _A_a4 Argument to be passed on to the slots. * @param _A_a5 Argument to be passed on to the slots. * @return The accumulated return values of the slot invocations as processed by the accumulator. */ static result_type emit(signal_impl* impl, typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3, typename type_trait::take _A_a4, typename type_trait::take _A_a5) { T_accumulator accumulator; if (!impl) return accumulator(slot_iterator_buf_type(), slot_iterator_buf_type()); signal_exec exec(impl); temp_slot_list slots(impl->slots_); self_type self (_A_a1, _A_a2, _A_a3, _A_a4, _A_a5); return accumulator(slot_iterator_buf_type(slots.begin(), &self), slot_iterator_buf_type(slots.end(), &self)); } /** Executes a list of slots using an accumulator of type @e T_accumulator in reverse order. * The arguments are buffered in a temporary instance of signal_emit5. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. * @param _A_a3 Argument to be passed on to the slots. * @param _A_a4 Argument to be passed on to the slots. * @param _A_a5 Argument to be passed on to the slots. * @return The accumulated return values of the slot invocations as processed by the accumulator. */ static result_type emit_reverse(signal_impl* impl, typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3, typename type_trait::take _A_a4, typename type_trait::take _A_a5) { T_accumulator accumulator; if (!impl) return accumulator(slot_iterator_buf_type(), slot_iterator_buf_type()); signal_exec exec(impl); temp_slot_list slots(impl->slots_); self_type self (_A_a1, _A_a2, _A_a3, _A_a4, _A_a5); return accumulator(slot_reverse_iterator_buf_type(slots.end(), &self), slot_reverse_iterator_buf_type(slots.begin(), &self)); } typename type_trait::take _A_a1_; typename type_trait::take _A_a2_; typename type_trait::take _A_a3_; typename type_trait::take _A_a4_; typename type_trait::take _A_a5_; }; /** Abstracts signal emission. * This template specialization implements an optimized emit() * function for the case that no accumulator is used. */ template struct signal_emit5 { typedef signal_emit5 self_type; typedef T_return result_type; typedef slot slot_type; typedef signal_impl::const_iterator_type iterator_type; typedef typename slot_type::call_type call_type; /** Executes a list of slots using an accumulator of type @e T_accumulator. * The arguments are passed directly on to the slots. * The return value of the last slot invoked is returned. * @param first An iterator pointing to the first slot in the list. * @param last An iterator pointing to the last slot in the list. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. * @param _A_a3 Argument to be passed on to the slots. * @param _A_a4 Argument to be passed on to the slots. * @param _A_a5 Argument to be passed on to the slots. * @return The return value of the last slot invoked. */ static result_type emit(signal_impl* impl, typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3, typename type_trait::take _A_a4, typename type_trait::take _A_a5) { if (!impl || impl->slots_.empty()) return T_return(); signal_exec exec(impl); T_return r_ = T_return(); //Use this scope to make sure that "slots" is destroyed before "exec" is destroyed. //This avoids a leak on MSVC++ - see http://bugzilla.gnome.org/show_bug.cgi?id=306249 { temp_slot_list slots(impl->slots_); iterator_type it = slots.begin(); for (; it != slots.end(); ++it) if (!it->empty() && !it->blocked()) break; if (it == slots.end()) return T_return(); // note that 'T_return r_();' doesn't work => define 'r_' after this line and initialize as follows: r_ = (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1, _A_a2, _A_a3, _A_a4, _A_a5); for (++it; it != slots.end(); ++it) { if (it->empty() || it->blocked()) continue; r_ = (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1, _A_a2, _A_a3, _A_a4, _A_a5); } } return r_; } /** Executes a list of slots using an accumulator of type @e T_accumulator in reverse order. * The arguments are passed directly on to the slots. * The return value of the last slot invoked is returned. * @param first An iterator pointing to the first slot in the list. * @param last An iterator pointing to the last slot in the list. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. * @param _A_a3 Argument to be passed on to the slots. * @param _A_a4 Argument to be passed on to the slots. * @param _A_a5 Argument to be passed on to the slots. * @return The return value of the last slot invoked. */ static result_type emit_reverse(signal_impl* impl, typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3, typename type_trait::take _A_a4, typename type_trait::take _A_a5) { if (!impl || impl->slots_.empty()) return T_return(); signal_exec exec(impl); T_return r_ = T_return(); //Use this scope to make sure that "slots" is destroyed before "exec" is destroyed. //This avoids a leak on MSVC++ - see http://bugzilla.gnome.org/show_bug.cgi?id=306249 { #ifndef SIGC_HAVE_SUN_REVERSE_ITERATOR typedef std::reverse_iterator reverse_iterator_type; #else typedef std::reverse_iterator reverse_iterator_type; #endif temp_slot_list slots(impl->slots_); reverse_iterator_type it(slots.end()); for (; it != reverse_iterator_type(slots.begin()); ++it) if (!it->empty() && !it->blocked()) break; if (it == reverse_iterator_type(slots.begin())) return T_return(); // note that 'T_return r_();' doesn't work => define 'r_' after this line and initialize as follows: r_ = (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1, _A_a2, _A_a3, _A_a4, _A_a5); for (++it; it != reverse_iterator_type(slots.begin()); ++it) { if (it->empty() || it->blocked()) continue; r_ = (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1, _A_a2, _A_a3, _A_a4, _A_a5); } } return r_; } }; /** Abstracts signal emission. * This template specialization implements an optimized emit() * function for the case that no accumulator is used and the * return type is @p void. */ template struct signal_emit5 { typedef signal_emit5 self_type; typedef void result_type; typedef slot slot_type; typedef signal_impl::const_iterator_type iterator_type; typedef typename slot_type::call_type call_type; /** Executes a list of slots using an accumulator of type @e T_accumulator. * The arguments are passed directly on to the slots. * @param first An iterator pointing to the first slot in the list. * @param last An iterator pointing to the last slot in the list. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. * @param _A_a3 Argument to be passed on to the slots. * @param _A_a4 Argument to be passed on to the slots. * @param _A_a5 Argument to be passed on to the slots. */ static result_type emit(signal_impl* impl, typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3, typename type_trait::take _A_a4, typename type_trait::take _A_a5) { if (!impl || impl->slots_.empty()) return; signal_exec exec(impl); temp_slot_list slots(impl->slots_); for (iterator_type it = slots.begin(); it != slots.end(); ++it) { if (it->empty() || it->blocked()) continue; (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1, _A_a2, _A_a3, _A_a4, _A_a5); } } /** Executes a list of slots using an accumulator of type @e T_accumulator in reverse order. * The arguments are passed directly on to the slots. * @param first An iterator pointing to the first slot in the list. * @param last An iterator pointing to the last slot in the list. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. * @param _A_a3 Argument to be passed on to the slots. * @param _A_a4 Argument to be passed on to the slots. * @param _A_a5 Argument to be passed on to the slots. */ static result_type emit_reverse(signal_impl* impl, typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3, typename type_trait::take _A_a4, typename type_trait::take _A_a5) { if (!impl || impl->slots_.empty()) return; signal_exec exec(impl); temp_slot_list slots(impl->slots_); #ifndef SIGC_HAVE_SUN_REVERSE_ITERATOR typedef std::reverse_iterator reverse_iterator_type; #else typedef std::reverse_iterator reverse_iterator_type; #endif for (reverse_iterator_type it = reverse_iterator_type(slots.end()); it != reverse_iterator_type(slots.begin()); ++it) { if (it->empty() || it->blocked()) continue; (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1, _A_a2, _A_a3, _A_a4, _A_a5); } } }; /** Abstracts signal emission. * This template implements the emit() function of signal6. * Template specializations are available to optimize signal * emission when no accumulator is used, i.e. the template * argument @e T_accumulator is @p nil. */ template struct signal_emit6 { typedef signal_emit6 self_type; typedef typename T_accumulator::result_type result_type; typedef slot slot_type; typedef internal::slot_iterator_buf slot_iterator_buf_type; typedef internal::slot_reverse_iterator_buf slot_reverse_iterator_buf_type; typedef signal_impl::const_iterator_type iterator_type; /** Instantiates the class. * The parameters are stored in member variables. operator()() passes * the values on to some slot. */ signal_emit6(typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3, typename type_trait::take _A_a4, typename type_trait::take _A_a5, typename type_trait::take _A_a6) : _A_a1_(_A_a1), _A_a2_(_A_a2), _A_a3_(_A_a3), _A_a4_(_A_a4), _A_a5_(_A_a5), _A_a6_(_A_a6) {} /** Invokes a slot using the buffered parameter values. * @param _A_slot Some slot to invoke. * @return The slot's return value. */ T_return operator()(const slot_type& _A_slot) const { return (reinterpret_cast(_A_slot.rep_->call_))(_A_slot.rep_, _A_a1_, _A_a2_, _A_a3_, _A_a4_, _A_a5_, _A_a6_); } /** Executes a list of slots using an accumulator of type @e T_accumulator. * The arguments are buffered in a temporary instance of signal_emit6. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. * @param _A_a3 Argument to be passed on to the slots. * @param _A_a4 Argument to be passed on to the slots. * @param _A_a5 Argument to be passed on to the slots. * @param _A_a6 Argument to be passed on to the slots. * @return The accumulated return values of the slot invocations as processed by the accumulator. */ static result_type emit(signal_impl* impl, typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3, typename type_trait::take _A_a4, typename type_trait::take _A_a5, typename type_trait::take _A_a6) { T_accumulator accumulator; if (!impl) return accumulator(slot_iterator_buf_type(), slot_iterator_buf_type()); signal_exec exec(impl); temp_slot_list slots(impl->slots_); self_type self (_A_a1, _A_a2, _A_a3, _A_a4, _A_a5, _A_a6); return accumulator(slot_iterator_buf_type(slots.begin(), &self), slot_iterator_buf_type(slots.end(), &self)); } /** Executes a list of slots using an accumulator of type @e T_accumulator in reverse order. * The arguments are buffered in a temporary instance of signal_emit6. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. * @param _A_a3 Argument to be passed on to the slots. * @param _A_a4 Argument to be passed on to the slots. * @param _A_a5 Argument to be passed on to the slots. * @param _A_a6 Argument to be passed on to the slots. * @return The accumulated return values of the slot invocations as processed by the accumulator. */ static result_type emit_reverse(signal_impl* impl, typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3, typename type_trait::take _A_a4, typename type_trait::take _A_a5, typename type_trait::take _A_a6) { T_accumulator accumulator; if (!impl) return accumulator(slot_iterator_buf_type(), slot_iterator_buf_type()); signal_exec exec(impl); temp_slot_list slots(impl->slots_); self_type self (_A_a1, _A_a2, _A_a3, _A_a4, _A_a5, _A_a6); return accumulator(slot_reverse_iterator_buf_type(slots.end(), &self), slot_reverse_iterator_buf_type(slots.begin(), &self)); } typename type_trait::take _A_a1_; typename type_trait::take _A_a2_; typename type_trait::take _A_a3_; typename type_trait::take _A_a4_; typename type_trait::take _A_a5_; typename type_trait::take _A_a6_; }; /** Abstracts signal emission. * This template specialization implements an optimized emit() * function for the case that no accumulator is used. */ template struct signal_emit6 { typedef signal_emit6 self_type; typedef T_return result_type; typedef slot slot_type; typedef signal_impl::const_iterator_type iterator_type; typedef typename slot_type::call_type call_type; /** Executes a list of slots using an accumulator of type @e T_accumulator. * The arguments are passed directly on to the slots. * The return value of the last slot invoked is returned. * @param first An iterator pointing to the first slot in the list. * @param last An iterator pointing to the last slot in the list. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. * @param _A_a3 Argument to be passed on to the slots. * @param _A_a4 Argument to be passed on to the slots. * @param _A_a5 Argument to be passed on to the slots. * @param _A_a6 Argument to be passed on to the slots. * @return The return value of the last slot invoked. */ static result_type emit(signal_impl* impl, typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3, typename type_trait::take _A_a4, typename type_trait::take _A_a5, typename type_trait::take _A_a6) { if (!impl || impl->slots_.empty()) return T_return(); signal_exec exec(impl); T_return r_ = T_return(); //Use this scope to make sure that "slots" is destroyed before "exec" is destroyed. //This avoids a leak on MSVC++ - see http://bugzilla.gnome.org/show_bug.cgi?id=306249 { temp_slot_list slots(impl->slots_); iterator_type it = slots.begin(); for (; it != slots.end(); ++it) if (!it->empty() && !it->blocked()) break; if (it == slots.end()) return T_return(); // note that 'T_return r_();' doesn't work => define 'r_' after this line and initialize as follows: r_ = (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1, _A_a2, _A_a3, _A_a4, _A_a5, _A_a6); for (++it; it != slots.end(); ++it) { if (it->empty() || it->blocked()) continue; r_ = (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1, _A_a2, _A_a3, _A_a4, _A_a5, _A_a6); } } return r_; } /** Executes a list of slots using an accumulator of type @e T_accumulator in reverse order. * The arguments are passed directly on to the slots. * The return value of the last slot invoked is returned. * @param first An iterator pointing to the first slot in the list. * @param last An iterator pointing to the last slot in the list. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. * @param _A_a3 Argument to be passed on to the slots. * @param _A_a4 Argument to be passed on to the slots. * @param _A_a5 Argument to be passed on to the slots. * @param _A_a6 Argument to be passed on to the slots. * @return The return value of the last slot invoked. */ static result_type emit_reverse(signal_impl* impl, typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3, typename type_trait::take _A_a4, typename type_trait::take _A_a5, typename type_trait::take _A_a6) { if (!impl || impl->slots_.empty()) return T_return(); signal_exec exec(impl); T_return r_ = T_return(); //Use this scope to make sure that "slots" is destroyed before "exec" is destroyed. //This avoids a leak on MSVC++ - see http://bugzilla.gnome.org/show_bug.cgi?id=306249 { #ifndef SIGC_HAVE_SUN_REVERSE_ITERATOR typedef std::reverse_iterator reverse_iterator_type; #else typedef std::reverse_iterator reverse_iterator_type; #endif temp_slot_list slots(impl->slots_); reverse_iterator_type it(slots.end()); for (; it != reverse_iterator_type(slots.begin()); ++it) if (!it->empty() && !it->blocked()) break; if (it == reverse_iterator_type(slots.begin())) return T_return(); // note that 'T_return r_();' doesn't work => define 'r_' after this line and initialize as follows: r_ = (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1, _A_a2, _A_a3, _A_a4, _A_a5, _A_a6); for (++it; it != reverse_iterator_type(slots.begin()); ++it) { if (it->empty() || it->blocked()) continue; r_ = (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1, _A_a2, _A_a3, _A_a4, _A_a5, _A_a6); } } return r_; } }; /** Abstracts signal emission. * This template specialization implements an optimized emit() * function for the case that no accumulator is used and the * return type is @p void. */ template struct signal_emit6 { typedef signal_emit6 self_type; typedef void result_type; typedef slot slot_type; typedef signal_impl::const_iterator_type iterator_type; typedef typename slot_type::call_type call_type; /** Executes a list of slots using an accumulator of type @e T_accumulator. * The arguments are passed directly on to the slots. * @param first An iterator pointing to the first slot in the list. * @param last An iterator pointing to the last slot in the list. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. * @param _A_a3 Argument to be passed on to the slots. * @param _A_a4 Argument to be passed on to the slots. * @param _A_a5 Argument to be passed on to the slots. * @param _A_a6 Argument to be passed on to the slots. */ static result_type emit(signal_impl* impl, typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3, typename type_trait::take _A_a4, typename type_trait::take _A_a5, typename type_trait::take _A_a6) { if (!impl || impl->slots_.empty()) return; signal_exec exec(impl); temp_slot_list slots(impl->slots_); for (iterator_type it = slots.begin(); it != slots.end(); ++it) { if (it->empty() || it->blocked()) continue; (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1, _A_a2, _A_a3, _A_a4, _A_a5, _A_a6); } } /** Executes a list of slots using an accumulator of type @e T_accumulator in reverse order. * The arguments are passed directly on to the slots. * @param first An iterator pointing to the first slot in the list. * @param last An iterator pointing to the last slot in the list. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. * @param _A_a3 Argument to be passed on to the slots. * @param _A_a4 Argument to be passed on to the slots. * @param _A_a5 Argument to be passed on to the slots. * @param _A_a6 Argument to be passed on to the slots. */ static result_type emit_reverse(signal_impl* impl, typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3, typename type_trait::take _A_a4, typename type_trait::take _A_a5, typename type_trait::take _A_a6) { if (!impl || impl->slots_.empty()) return; signal_exec exec(impl); temp_slot_list slots(impl->slots_); #ifndef SIGC_HAVE_SUN_REVERSE_ITERATOR typedef std::reverse_iterator reverse_iterator_type; #else typedef std::reverse_iterator reverse_iterator_type; #endif for (reverse_iterator_type it = reverse_iterator_type(slots.end()); it != reverse_iterator_type(slots.begin()); ++it) { if (it->empty() || it->blocked()) continue; (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1, _A_a2, _A_a3, _A_a4, _A_a5, _A_a6); } } }; /** Abstracts signal emission. * This template implements the emit() function of signal7. * Template specializations are available to optimize signal * emission when no accumulator is used, i.e. the template * argument @e T_accumulator is @p nil. */ template struct signal_emit7 { typedef signal_emit7 self_type; typedef typename T_accumulator::result_type result_type; typedef slot slot_type; typedef internal::slot_iterator_buf slot_iterator_buf_type; typedef internal::slot_reverse_iterator_buf slot_reverse_iterator_buf_type; typedef signal_impl::const_iterator_type iterator_type; /** Instantiates the class. * The parameters are stored in member variables. operator()() passes * the values on to some slot. */ signal_emit7(typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3, typename type_trait::take _A_a4, typename type_trait::take _A_a5, typename type_trait::take _A_a6, typename type_trait::take _A_a7) : _A_a1_(_A_a1), _A_a2_(_A_a2), _A_a3_(_A_a3), _A_a4_(_A_a4), _A_a5_(_A_a5), _A_a6_(_A_a6), _A_a7_(_A_a7) {} /** Invokes a slot using the buffered parameter values. * @param _A_slot Some slot to invoke. * @return The slot's return value. */ T_return operator()(const slot_type& _A_slot) const { return (reinterpret_cast(_A_slot.rep_->call_))(_A_slot.rep_, _A_a1_, _A_a2_, _A_a3_, _A_a4_, _A_a5_, _A_a6_, _A_a7_); } /** Executes a list of slots using an accumulator of type @e T_accumulator. * The arguments are buffered in a temporary instance of signal_emit7. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. * @param _A_a3 Argument to be passed on to the slots. * @param _A_a4 Argument to be passed on to the slots. * @param _A_a5 Argument to be passed on to the slots. * @param _A_a6 Argument to be passed on to the slots. * @param _A_a7 Argument to be passed on to the slots. * @return The accumulated return values of the slot invocations as processed by the accumulator. */ static result_type emit(signal_impl* impl, typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3, typename type_trait::take _A_a4, typename type_trait::take _A_a5, typename type_trait::take _A_a6, typename type_trait::take _A_a7) { T_accumulator accumulator; if (!impl) return accumulator(slot_iterator_buf_type(), slot_iterator_buf_type()); signal_exec exec(impl); temp_slot_list slots(impl->slots_); self_type self (_A_a1, _A_a2, _A_a3, _A_a4, _A_a5, _A_a6, _A_a7); return accumulator(slot_iterator_buf_type(slots.begin(), &self), slot_iterator_buf_type(slots.end(), &self)); } /** Executes a list of slots using an accumulator of type @e T_accumulator in reverse order. * The arguments are buffered in a temporary instance of signal_emit7. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. * @param _A_a3 Argument to be passed on to the slots. * @param _A_a4 Argument to be passed on to the slots. * @param _A_a5 Argument to be passed on to the slots. * @param _A_a6 Argument to be passed on to the slots. * @param _A_a7 Argument to be passed on to the slots. * @return The accumulated return values of the slot invocations as processed by the accumulator. */ static result_type emit_reverse(signal_impl* impl, typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3, typename type_trait::take _A_a4, typename type_trait::take _A_a5, typename type_trait::take _A_a6, typename type_trait::take _A_a7) { T_accumulator accumulator; if (!impl) return accumulator(slot_iterator_buf_type(), slot_iterator_buf_type()); signal_exec exec(impl); temp_slot_list slots(impl->slots_); self_type self (_A_a1, _A_a2, _A_a3, _A_a4, _A_a5, _A_a6, _A_a7); return accumulator(slot_reverse_iterator_buf_type(slots.end(), &self), slot_reverse_iterator_buf_type(slots.begin(), &self)); } typename type_trait::take _A_a1_; typename type_trait::take _A_a2_; typename type_trait::take _A_a3_; typename type_trait::take _A_a4_; typename type_trait::take _A_a5_; typename type_trait::take _A_a6_; typename type_trait::take _A_a7_; }; /** Abstracts signal emission. * This template specialization implements an optimized emit() * function for the case that no accumulator is used. */ template struct signal_emit7 { typedef signal_emit7 self_type; typedef T_return result_type; typedef slot slot_type; typedef signal_impl::const_iterator_type iterator_type; typedef typename slot_type::call_type call_type; /** Executes a list of slots using an accumulator of type @e T_accumulator. * The arguments are passed directly on to the slots. * The return value of the last slot invoked is returned. * @param first An iterator pointing to the first slot in the list. * @param last An iterator pointing to the last slot in the list. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. * @param _A_a3 Argument to be passed on to the slots. * @param _A_a4 Argument to be passed on to the slots. * @param _A_a5 Argument to be passed on to the slots. * @param _A_a6 Argument to be passed on to the slots. * @param _A_a7 Argument to be passed on to the slots. * @return The return value of the last slot invoked. */ static result_type emit(signal_impl* impl, typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3, typename type_trait::take _A_a4, typename type_trait::take _A_a5, typename type_trait::take _A_a6, typename type_trait::take _A_a7) { if (!impl || impl->slots_.empty()) return T_return(); signal_exec exec(impl); T_return r_ = T_return(); //Use this scope to make sure that "slots" is destroyed before "exec" is destroyed. //This avoids a leak on MSVC++ - see http://bugzilla.gnome.org/show_bug.cgi?id=306249 { temp_slot_list slots(impl->slots_); iterator_type it = slots.begin(); for (; it != slots.end(); ++it) if (!it->empty() && !it->blocked()) break; if (it == slots.end()) return T_return(); // note that 'T_return r_();' doesn't work => define 'r_' after this line and initialize as follows: r_ = (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1, _A_a2, _A_a3, _A_a4, _A_a5, _A_a6, _A_a7); for (++it; it != slots.end(); ++it) { if (it->empty() || it->blocked()) continue; r_ = (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1, _A_a2, _A_a3, _A_a4, _A_a5, _A_a6, _A_a7); } } return r_; } /** Executes a list of slots using an accumulator of type @e T_accumulator in reverse order. * The arguments are passed directly on to the slots. * The return value of the last slot invoked is returned. * @param first An iterator pointing to the first slot in the list. * @param last An iterator pointing to the last slot in the list. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. * @param _A_a3 Argument to be passed on to the slots. * @param _A_a4 Argument to be passed on to the slots. * @param _A_a5 Argument to be passed on to the slots. * @param _A_a6 Argument to be passed on to the slots. * @param _A_a7 Argument to be passed on to the slots. * @return The return value of the last slot invoked. */ static result_type emit_reverse(signal_impl* impl, typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3, typename type_trait::take _A_a4, typename type_trait::take _A_a5, typename type_trait::take _A_a6, typename type_trait::take _A_a7) { if (!impl || impl->slots_.empty()) return T_return(); signal_exec exec(impl); T_return r_ = T_return(); //Use this scope to make sure that "slots" is destroyed before "exec" is destroyed. //This avoids a leak on MSVC++ - see http://bugzilla.gnome.org/show_bug.cgi?id=306249 { #ifndef SIGC_HAVE_SUN_REVERSE_ITERATOR typedef std::reverse_iterator reverse_iterator_type; #else typedef std::reverse_iterator reverse_iterator_type; #endif temp_slot_list slots(impl->slots_); reverse_iterator_type it(slots.end()); for (; it != reverse_iterator_type(slots.begin()); ++it) if (!it->empty() && !it->blocked()) break; if (it == reverse_iterator_type(slots.begin())) return T_return(); // note that 'T_return r_();' doesn't work => define 'r_' after this line and initialize as follows: r_ = (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1, _A_a2, _A_a3, _A_a4, _A_a5, _A_a6, _A_a7); for (++it; it != reverse_iterator_type(slots.begin()); ++it) { if (it->empty() || it->blocked()) continue; r_ = (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1, _A_a2, _A_a3, _A_a4, _A_a5, _A_a6, _A_a7); } } return r_; } }; /** Abstracts signal emission. * This template specialization implements an optimized emit() * function for the case that no accumulator is used and the * return type is @p void. */ template struct signal_emit7 { typedef signal_emit7 self_type; typedef void result_type; typedef slot slot_type; typedef signal_impl::const_iterator_type iterator_type; typedef typename slot_type::call_type call_type; /** Executes a list of slots using an accumulator of type @e T_accumulator. * The arguments are passed directly on to the slots. * @param first An iterator pointing to the first slot in the list. * @param last An iterator pointing to the last slot in the list. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. * @param _A_a3 Argument to be passed on to the slots. * @param _A_a4 Argument to be passed on to the slots. * @param _A_a5 Argument to be passed on to the slots. * @param _A_a6 Argument to be passed on to the slots. * @param _A_a7 Argument to be passed on to the slots. */ static result_type emit(signal_impl* impl, typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3, typename type_trait::take _A_a4, typename type_trait::take _A_a5, typename type_trait::take _A_a6, typename type_trait::take _A_a7) { if (!impl || impl->slots_.empty()) return; signal_exec exec(impl); temp_slot_list slots(impl->slots_); for (iterator_type it = slots.begin(); it != slots.end(); ++it) { if (it->empty() || it->blocked()) continue; (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1, _A_a2, _A_a3, _A_a4, _A_a5, _A_a6, _A_a7); } } /** Executes a list of slots using an accumulator of type @e T_accumulator in reverse order. * The arguments are passed directly on to the slots. * @param first An iterator pointing to the first slot in the list. * @param last An iterator pointing to the last slot in the list. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. * @param _A_a3 Argument to be passed on to the slots. * @param _A_a4 Argument to be passed on to the slots. * @param _A_a5 Argument to be passed on to the slots. * @param _A_a6 Argument to be passed on to the slots. * @param _A_a7 Argument to be passed on to the slots. */ static result_type emit_reverse(signal_impl* impl, typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3, typename type_trait::take _A_a4, typename type_trait::take _A_a5, typename type_trait::take _A_a6, typename type_trait::take _A_a7) { if (!impl || impl->slots_.empty()) return; signal_exec exec(impl); temp_slot_list slots(impl->slots_); #ifndef SIGC_HAVE_SUN_REVERSE_ITERATOR typedef std::reverse_iterator reverse_iterator_type; #else typedef std::reverse_iterator reverse_iterator_type; #endif for (reverse_iterator_type it = reverse_iterator_type(slots.end()); it != reverse_iterator_type(slots.begin()); ++it) { if (it->empty() || it->blocked()) continue; (reinterpret_cast(it->rep_->call_))(it->rep_, _A_a1, _A_a2, _A_a3, _A_a4, _A_a5, _A_a6, _A_a7); } } }; } /* namespace internal */ /** Signal declaration. * signal0 can be used to connect() slots that are invoked * during subsequent calls to emit(). Any functor or slot * can be passed into connect(). It is converted into a slot * implicitely. * * If you want to connect one signal to another, use make_slot() * to retrieve a functor that emits the signal when invoked. * * Be careful if you directly pass one signal into the connect() * method of another: a shallow copy of the signal is made and * the signal's slots are not disconnected until both the signal * and its clone are destroyed which is probably not what you want! * * An STL-style list interface for the signal's list of slots * can be retrieved with slots(). This interface supports * iteration, insertion and removal of slots. * * The following template arguments are used: * - @e T_return The desired return type for the emit() function (may be overridden by the accumulator). * - @e T_accumulator The accumulator type used for emission. The default @p nil means that no accumulator should be used, i.e. signal emission returns the return value of the last slot invoked. * * You should use the more convenient unnumbered sigc::signal template. * * @ingroup signal */ template class signal0 : public signal_base { public: typedef internal::signal_emit0 emitter_type; typedef typename emitter_type::result_type result_type; typedef slot slot_type; typedef slot_list slot_list_type; typedef typename slot_list_type::iterator iterator; typedef typename slot_list_type::const_iterator const_iterator; typedef typename slot_list_type::reverse_iterator reverse_iterator; typedef typename slot_list_type::const_reverse_iterator const_reverse_iterator; /** Add a slot to the list of slots. * Any functor or slot may be passed into connect(). * It will be converted into a slot implicitely. * The returned iterator may be stored for disconnection * of the slot at some later point. It stays valid until * the slot is removed from the list of slots. The iterator * can also be implicitely converted into a sigc::connection object * that may be used safely beyond the life time of the slot. * @param slot_ The slot to add to the list of slots. * @return An iterator pointing to the new slot in the list. */ iterator connect(const slot_type& slot_) { return iterator(signal_base::connect(static_cast(slot_))); } /** Triggers the emission of the signal. * During signal emission all slots that have been connected * to the signal are invoked unless they are manually set into * a blocking state. The parameters are passed on to the slots. * If @e T_accumulated is not @p nil, an accumulator of this type * is used to process the return values of the slot invocations. * Otherwise, the return value of the last slot invoked is returned. * @return The accumulated return values of the slot invocations. */ result_type emit() const { return emitter_type::emit(impl_); } /** Triggers the emission of the signal in reverse order (see emit()). */ result_type emit_reverse() const { return emitter_type::emit_reverse(impl_); } /** Triggers the emission of the signal (see emit()). */ result_type operator()() const { return emit(); } /** Creates a functor that calls emit() on this signal. * @code * sigc::mem_fun(mysignal, &sigc::signal0::emit) * @endcode * yields the same result. * @return A functor that calls emit() on this signal. */ bound_const_mem_functor0 make_slot() const { return bound_const_mem_functor0(this, &signal0::emit); } /** Creates an STL-style interface for the signal's list of slots. * This interface supports iteration, insertion and removal of slots. * @return An STL-style interface for the signal's list of slots. */ slot_list_type slots() { return slot_list_type(impl()); } /** Creates an STL-style interface for the signal's list of slots. * This interface supports iteration, insertion and removal of slots. * @return An STL-style interface for the signal's list of slots. */ const slot_list_type slots() const { return slot_list_type(const_cast(this)->impl()); } signal0() {} signal0(const signal0& src) : signal_base(src) {} }; /** Signal declaration. * signal1 can be used to connect() slots that are invoked * during subsequent calls to emit(). Any functor or slot * can be passed into connect(). It is converted into a slot * implicitely. * * If you want to connect one signal to another, use make_slot() * to retrieve a functor that emits the signal when invoked. * * Be careful if you directly pass one signal into the connect() * method of another: a shallow copy of the signal is made and * the signal's slots are not disconnected until both the signal * and its clone are destroyed which is probably not what you want! * * An STL-style list interface for the signal's list of slots * can be retrieved with slots(). This interface supports * iteration, insertion and removal of slots. * * The following template arguments are used: * - @e T_return The desired return type for the emit() function (may be overridden by the accumulator). * - @e T_arg1 Argument type used in the definition of emit(). * - @e T_accumulator The accumulator type used for emission. The default @p nil means that no accumulator should be used, i.e. signal emission returns the return value of the last slot invoked. * * You should use the more convenient unnumbered sigc::signal template. * * @ingroup signal */ template class signal1 : public signal_base { public: typedef internal::signal_emit1 emitter_type; typedef typename emitter_type::result_type result_type; typedef slot slot_type; typedef slot_list slot_list_type; typedef typename slot_list_type::iterator iterator; typedef typename slot_list_type::const_iterator const_iterator; typedef typename slot_list_type::reverse_iterator reverse_iterator; typedef typename slot_list_type::const_reverse_iterator const_reverse_iterator; /** Add a slot to the list of slots. * Any functor or slot may be passed into connect(). * It will be converted into a slot implicitely. * The returned iterator may be stored for disconnection * of the slot at some later point. It stays valid until * the slot is removed from the list of slots. The iterator * can also be implicitely converted into a sigc::connection object * that may be used safely beyond the life time of the slot. * @param slot_ The slot to add to the list of slots. * @return An iterator pointing to the new slot in the list. */ iterator connect(const slot_type& slot_) { return iterator(signal_base::connect(static_cast(slot_))); } /** Triggers the emission of the signal. * During signal emission all slots that have been connected * to the signal are invoked unless they are manually set into * a blocking state. The parameters are passed on to the slots. * If @e T_accumulated is not @p nil, an accumulator of this type * is used to process the return values of the slot invocations. * Otherwise, the return value of the last slot invoked is returned. * @param _A_a1 Argument to be passed on to the slots. * @return The accumulated return values of the slot invocations. */ result_type emit(typename type_trait::take _A_a1) const { return emitter_type::emit(impl_, _A_a1); } /** Triggers the emission of the signal in reverse order (see emit()). */ result_type emit_reverse(typename type_trait::take _A_a1) const { return emitter_type::emit_reverse(impl_, _A_a1); } /** Triggers the emission of the signal (see emit()). */ result_type operator()(typename type_trait::take _A_a1) const { return emit(_A_a1); } /** Creates a functor that calls emit() on this signal. * @code * sigc::mem_fun(mysignal, &sigc::signal1::emit) * @endcode * yields the same result. * @return A functor that calls emit() on this signal. */ bound_const_mem_functor1::take> make_slot() const { return bound_const_mem_functor1::take>(this, &signal1::emit); } /** Creates an STL-style interface for the signal's list of slots. * This interface supports iteration, insertion and removal of slots. * @return An STL-style interface for the signal's list of slots. */ slot_list_type slots() { return slot_list_type(impl()); } /** Creates an STL-style interface for the signal's list of slots. * This interface supports iteration, insertion and removal of slots. * @return An STL-style interface for the signal's list of slots. */ const slot_list_type slots() const { return slot_list_type(const_cast(this)->impl()); } signal1() {} signal1(const signal1& src) : signal_base(src) {} }; /** Signal declaration. * signal2 can be used to connect() slots that are invoked * during subsequent calls to emit(). Any functor or slot * can be passed into connect(). It is converted into a slot * implicitely. * * If you want to connect one signal to another, use make_slot() * to retrieve a functor that emits the signal when invoked. * * Be careful if you directly pass one signal into the connect() * method of another: a shallow copy of the signal is made and * the signal's slots are not disconnected until both the signal * and its clone are destroyed which is probably not what you want! * * An STL-style list interface for the signal's list of slots * can be retrieved with slots(). This interface supports * iteration, insertion and removal of slots. * * The following template arguments are used: * - @e T_return The desired return type for the emit() function (may be overridden by the accumulator). * - @e T_arg1 Argument type used in the definition of emit(). * - @e T_arg2 Argument type used in the definition of emit(). * - @e T_accumulator The accumulator type used for emission. The default @p nil means that no accumulator should be used, i.e. signal emission returns the return value of the last slot invoked. * * You should use the more convenient unnumbered sigc::signal template. * * @ingroup signal */ template class signal2 : public signal_base { public: typedef internal::signal_emit2 emitter_type; typedef typename emitter_type::result_type result_type; typedef slot slot_type; typedef slot_list slot_list_type; typedef typename slot_list_type::iterator iterator; typedef typename slot_list_type::const_iterator const_iterator; typedef typename slot_list_type::reverse_iterator reverse_iterator; typedef typename slot_list_type::const_reverse_iterator const_reverse_iterator; /** Add a slot to the list of slots. * Any functor or slot may be passed into connect(). * It will be converted into a slot implicitely. * The returned iterator may be stored for disconnection * of the slot at some later point. It stays valid until * the slot is removed from the list of slots. The iterator * can also be implicitely converted into a sigc::connection object * that may be used safely beyond the life time of the slot. * @param slot_ The slot to add to the list of slots. * @return An iterator pointing to the new slot in the list. */ iterator connect(const slot_type& slot_) { return iterator(signal_base::connect(static_cast(slot_))); } /** Triggers the emission of the signal. * During signal emission all slots that have been connected * to the signal are invoked unless they are manually set into * a blocking state. The parameters are passed on to the slots. * If @e T_accumulated is not @p nil, an accumulator of this type * is used to process the return values of the slot invocations. * Otherwise, the return value of the last slot invoked is returned. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. * @return The accumulated return values of the slot invocations. */ result_type emit(typename type_trait::take _A_a1, typename type_trait::take _A_a2) const { return emitter_type::emit(impl_, _A_a1, _A_a2); } /** Triggers the emission of the signal in reverse order (see emit()). */ result_type emit_reverse(typename type_trait::take _A_a1, typename type_trait::take _A_a2) const { return emitter_type::emit_reverse(impl_, _A_a1, _A_a2); } /** Triggers the emission of the signal (see emit()). */ result_type operator()(typename type_trait::take _A_a1, typename type_trait::take _A_a2) const { return emit(_A_a1, _A_a2); } /** Creates a functor that calls emit() on this signal. * @code * sigc::mem_fun(mysignal, &sigc::signal2::emit) * @endcode * yields the same result. * @return A functor that calls emit() on this signal. */ bound_const_mem_functor2::take, typename type_trait::take> make_slot() const { return bound_const_mem_functor2::take, typename type_trait::take>(this, &signal2::emit); } /** Creates an STL-style interface for the signal's list of slots. * This interface supports iteration, insertion and removal of slots. * @return An STL-style interface for the signal's list of slots. */ slot_list_type slots() { return slot_list_type(impl()); } /** Creates an STL-style interface for the signal's list of slots. * This interface supports iteration, insertion and removal of slots. * @return An STL-style interface for the signal's list of slots. */ const slot_list_type slots() const { return slot_list_type(const_cast(this)->impl()); } signal2() {} signal2(const signal2& src) : signal_base(src) {} }; /** Signal declaration. * signal3 can be used to connect() slots that are invoked * during subsequent calls to emit(). Any functor or slot * can be passed into connect(). It is converted into a slot * implicitely. * * If you want to connect one signal to another, use make_slot() * to retrieve a functor that emits the signal when invoked. * * Be careful if you directly pass one signal into the connect() * method of another: a shallow copy of the signal is made and * the signal's slots are not disconnected until both the signal * and its clone are destroyed which is probably not what you want! * * An STL-style list interface for the signal's list of slots * can be retrieved with slots(). This interface supports * iteration, insertion and removal of slots. * * The following template arguments are used: * - @e T_return The desired return type for the emit() function (may be overridden by the accumulator). * - @e T_arg1 Argument type used in the definition of emit(). * - @e T_arg2 Argument type used in the definition of emit(). * - @e T_arg3 Argument type used in the definition of emit(). * - @e T_accumulator The accumulator type used for emission. The default @p nil means that no accumulator should be used, i.e. signal emission returns the return value of the last slot invoked. * * You should use the more convenient unnumbered sigc::signal template. * * @ingroup signal */ template class signal3 : public signal_base { public: typedef internal::signal_emit3 emitter_type; typedef typename emitter_type::result_type result_type; typedef slot slot_type; typedef slot_list slot_list_type; typedef typename slot_list_type::iterator iterator; typedef typename slot_list_type::const_iterator const_iterator; typedef typename slot_list_type::reverse_iterator reverse_iterator; typedef typename slot_list_type::const_reverse_iterator const_reverse_iterator; /** Add a slot to the list of slots. * Any functor or slot may be passed into connect(). * It will be converted into a slot implicitely. * The returned iterator may be stored for disconnection * of the slot at some later point. It stays valid until * the slot is removed from the list of slots. The iterator * can also be implicitely converted into a sigc::connection object * that may be used safely beyond the life time of the slot. * @param slot_ The slot to add to the list of slots. * @return An iterator pointing to the new slot in the list. */ iterator connect(const slot_type& slot_) { return iterator(signal_base::connect(static_cast(slot_))); } /** Triggers the emission of the signal. * During signal emission all slots that have been connected * to the signal are invoked unless they are manually set into * a blocking state. The parameters are passed on to the slots. * If @e T_accumulated is not @p nil, an accumulator of this type * is used to process the return values of the slot invocations. * Otherwise, the return value of the last slot invoked is returned. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. * @param _A_a3 Argument to be passed on to the slots. * @return The accumulated return values of the slot invocations. */ result_type emit(typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3) const { return emitter_type::emit(impl_, _A_a1, _A_a2, _A_a3); } /** Triggers the emission of the signal in reverse order (see emit()). */ result_type emit_reverse(typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3) const { return emitter_type::emit_reverse(impl_, _A_a1, _A_a2, _A_a3); } /** Triggers the emission of the signal (see emit()). */ result_type operator()(typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3) const { return emit(_A_a1, _A_a2, _A_a3); } /** Creates a functor that calls emit() on this signal. * @code * sigc::mem_fun(mysignal, &sigc::signal3::emit) * @endcode * yields the same result. * @return A functor that calls emit() on this signal. */ bound_const_mem_functor3::take, typename type_trait::take, typename type_trait::take> make_slot() const { return bound_const_mem_functor3::take, typename type_trait::take, typename type_trait::take>(this, &signal3::emit); } /** Creates an STL-style interface for the signal's list of slots. * This interface supports iteration, insertion and removal of slots. * @return An STL-style interface for the signal's list of slots. */ slot_list_type slots() { return slot_list_type(impl()); } /** Creates an STL-style interface for the signal's list of slots. * This interface supports iteration, insertion and removal of slots. * @return An STL-style interface for the signal's list of slots. */ const slot_list_type slots() const { return slot_list_type(const_cast(this)->impl()); } signal3() {} signal3(const signal3& src) : signal_base(src) {} }; /** Signal declaration. * signal4 can be used to connect() slots that are invoked * during subsequent calls to emit(). Any functor or slot * can be passed into connect(). It is converted into a slot * implicitely. * * If you want to connect one signal to another, use make_slot() * to retrieve a functor that emits the signal when invoked. * * Be careful if you directly pass one signal into the connect() * method of another: a shallow copy of the signal is made and * the signal's slots are not disconnected until both the signal * and its clone are destroyed which is probably not what you want! * * An STL-style list interface for the signal's list of slots * can be retrieved with slots(). This interface supports * iteration, insertion and removal of slots. * * The following template arguments are used: * - @e T_return The desired return type for the emit() function (may be overridden by the accumulator). * - @e T_arg1 Argument type used in the definition of emit(). * - @e T_arg2 Argument type used in the definition of emit(). * - @e T_arg3 Argument type used in the definition of emit(). * - @e T_arg4 Argument type used in the definition of emit(). * - @e T_accumulator The accumulator type used for emission. The default @p nil means that no accumulator should be used, i.e. signal emission returns the return value of the last slot invoked. * * You should use the more convenient unnumbered sigc::signal template. * * @ingroup signal */ template class signal4 : public signal_base { public: typedef internal::signal_emit4 emitter_type; typedef typename emitter_type::result_type result_type; typedef slot slot_type; typedef slot_list slot_list_type; typedef typename slot_list_type::iterator iterator; typedef typename slot_list_type::const_iterator const_iterator; typedef typename slot_list_type::reverse_iterator reverse_iterator; typedef typename slot_list_type::const_reverse_iterator const_reverse_iterator; /** Add a slot to the list of slots. * Any functor or slot may be passed into connect(). * It will be converted into a slot implicitely. * The returned iterator may be stored for disconnection * of the slot at some later point. It stays valid until * the slot is removed from the list of slots. The iterator * can also be implicitely converted into a sigc::connection object * that may be used safely beyond the life time of the slot. * @param slot_ The slot to add to the list of slots. * @return An iterator pointing to the new slot in the list. */ iterator connect(const slot_type& slot_) { return iterator(signal_base::connect(static_cast(slot_))); } /** Triggers the emission of the signal. * During signal emission all slots that have been connected * to the signal are invoked unless they are manually set into * a blocking state. The parameters are passed on to the slots. * If @e T_accumulated is not @p nil, an accumulator of this type * is used to process the return values of the slot invocations. * Otherwise, the return value of the last slot invoked is returned. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. * @param _A_a3 Argument to be passed on to the slots. * @param _A_a4 Argument to be passed on to the slots. * @return The accumulated return values of the slot invocations. */ result_type emit(typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3, typename type_trait::take _A_a4) const { return emitter_type::emit(impl_, _A_a1, _A_a2, _A_a3, _A_a4); } /** Triggers the emission of the signal in reverse order (see emit()). */ result_type emit_reverse(typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3, typename type_trait::take _A_a4) const { return emitter_type::emit_reverse(impl_, _A_a1, _A_a2, _A_a3, _A_a4); } /** Triggers the emission of the signal (see emit()). */ result_type operator()(typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3, typename type_trait::take _A_a4) const { return emit(_A_a1, _A_a2, _A_a3, _A_a4); } /** Creates a functor that calls emit() on this signal. * @code * sigc::mem_fun(mysignal, &sigc::signal4::emit) * @endcode * yields the same result. * @return A functor that calls emit() on this signal. */ bound_const_mem_functor4::take, typename type_trait::take, typename type_trait::take, typename type_trait::take> make_slot() const { return bound_const_mem_functor4::take, typename type_trait::take, typename type_trait::take, typename type_trait::take>(this, &signal4::emit); } /** Creates an STL-style interface for the signal's list of slots. * This interface supports iteration, insertion and removal of slots. * @return An STL-style interface for the signal's list of slots. */ slot_list_type slots() { return slot_list_type(impl()); } /** Creates an STL-style interface for the signal's list of slots. * This interface supports iteration, insertion and removal of slots. * @return An STL-style interface for the signal's list of slots. */ const slot_list_type slots() const { return slot_list_type(const_cast(this)->impl()); } signal4() {} signal4(const signal4& src) : signal_base(src) {} }; /** Signal declaration. * signal5 can be used to connect() slots that are invoked * during subsequent calls to emit(). Any functor or slot * can be passed into connect(). It is converted into a slot * implicitely. * * If you want to connect one signal to another, use make_slot() * to retrieve a functor that emits the signal when invoked. * * Be careful if you directly pass one signal into the connect() * method of another: a shallow copy of the signal is made and * the signal's slots are not disconnected until both the signal * and its clone are destroyed which is probably not what you want! * * An STL-style list interface for the signal's list of slots * can be retrieved with slots(). This interface supports * iteration, insertion and removal of slots. * * The following template arguments are used: * - @e T_return The desired return type for the emit() function (may be overridden by the accumulator). * - @e T_arg1 Argument type used in the definition of emit(). * - @e T_arg2 Argument type used in the definition of emit(). * - @e T_arg3 Argument type used in the definition of emit(). * - @e T_arg4 Argument type used in the definition of emit(). * - @e T_arg5 Argument type used in the definition of emit(). * - @e T_accumulator The accumulator type used for emission. The default @p nil means that no accumulator should be used, i.e. signal emission returns the return value of the last slot invoked. * * You should use the more convenient unnumbered sigc::signal template. * * @ingroup signal */ template class signal5 : public signal_base { public: typedef internal::signal_emit5 emitter_type; typedef typename emitter_type::result_type result_type; typedef slot slot_type; typedef slot_list slot_list_type; typedef typename slot_list_type::iterator iterator; typedef typename slot_list_type::const_iterator const_iterator; typedef typename slot_list_type::reverse_iterator reverse_iterator; typedef typename slot_list_type::const_reverse_iterator const_reverse_iterator; /** Add a slot to the list of slots. * Any functor or slot may be passed into connect(). * It will be converted into a slot implicitely. * The returned iterator may be stored for disconnection * of the slot at some later point. It stays valid until * the slot is removed from the list of slots. The iterator * can also be implicitely converted into a sigc::connection object * that may be used safely beyond the life time of the slot. * @param slot_ The slot to add to the list of slots. * @return An iterator pointing to the new slot in the list. */ iterator connect(const slot_type& slot_) { return iterator(signal_base::connect(static_cast(slot_))); } /** Triggers the emission of the signal. * During signal emission all slots that have been connected * to the signal are invoked unless they are manually set into * a blocking state. The parameters are passed on to the slots. * If @e T_accumulated is not @p nil, an accumulator of this type * is used to process the return values of the slot invocations. * Otherwise, the return value of the last slot invoked is returned. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. * @param _A_a3 Argument to be passed on to the slots. * @param _A_a4 Argument to be passed on to the slots. * @param _A_a5 Argument to be passed on to the slots. * @return The accumulated return values of the slot invocations. */ result_type emit(typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3, typename type_trait::take _A_a4, typename type_trait::take _A_a5) const { return emitter_type::emit(impl_, _A_a1, _A_a2, _A_a3, _A_a4, _A_a5); } /** Triggers the emission of the signal in reverse order (see emit()). */ result_type emit_reverse(typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3, typename type_trait::take _A_a4, typename type_trait::take _A_a5) const { return emitter_type::emit_reverse(impl_, _A_a1, _A_a2, _A_a3, _A_a4, _A_a5); } /** Triggers the emission of the signal (see emit()). */ result_type operator()(typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3, typename type_trait::take _A_a4, typename type_trait::take _A_a5) const { return emit(_A_a1, _A_a2, _A_a3, _A_a4, _A_a5); } /** Creates a functor that calls emit() on this signal. * @code * sigc::mem_fun(mysignal, &sigc::signal5::emit) * @endcode * yields the same result. * @return A functor that calls emit() on this signal. */ bound_const_mem_functor5::take, typename type_trait::take, typename type_trait::take, typename type_trait::take, typename type_trait::take> make_slot() const { return bound_const_mem_functor5::take, typename type_trait::take, typename type_trait::take, typename type_trait::take, typename type_trait::take>(this, &signal5::emit); } /** Creates an STL-style interface for the signal's list of slots. * This interface supports iteration, insertion and removal of slots. * @return An STL-style interface for the signal's list of slots. */ slot_list_type slots() { return slot_list_type(impl()); } /** Creates an STL-style interface for the signal's list of slots. * This interface supports iteration, insertion and removal of slots. * @return An STL-style interface for the signal's list of slots. */ const slot_list_type slots() const { return slot_list_type(const_cast(this)->impl()); } signal5() {} signal5(const signal5& src) : signal_base(src) {} }; /** Signal declaration. * signal6 can be used to connect() slots that are invoked * during subsequent calls to emit(). Any functor or slot * can be passed into connect(). It is converted into a slot * implicitely. * * If you want to connect one signal to another, use make_slot() * to retrieve a functor that emits the signal when invoked. * * Be careful if you directly pass one signal into the connect() * method of another: a shallow copy of the signal is made and * the signal's slots are not disconnected until both the signal * and its clone are destroyed which is probably not what you want! * * An STL-style list interface for the signal's list of slots * can be retrieved with slots(). This interface supports * iteration, insertion and removal of slots. * * The following template arguments are used: * - @e T_return The desired return type for the emit() function (may be overridden by the accumulator). * - @e T_arg1 Argument type used in the definition of emit(). * - @e T_arg2 Argument type used in the definition of emit(). * - @e T_arg3 Argument type used in the definition of emit(). * - @e T_arg4 Argument type used in the definition of emit(). * - @e T_arg5 Argument type used in the definition of emit(). * - @e T_arg6 Argument type used in the definition of emit(). * - @e T_accumulator The accumulator type used for emission. The default @p nil means that no accumulator should be used, i.e. signal emission returns the return value of the last slot invoked. * * You should use the more convenient unnumbered sigc::signal template. * * @ingroup signal */ template class signal6 : public signal_base { public: typedef internal::signal_emit6 emitter_type; typedef typename emitter_type::result_type result_type; typedef slot slot_type; typedef slot_list slot_list_type; typedef typename slot_list_type::iterator iterator; typedef typename slot_list_type::const_iterator const_iterator; typedef typename slot_list_type::reverse_iterator reverse_iterator; typedef typename slot_list_type::const_reverse_iterator const_reverse_iterator; /** Add a slot to the list of slots. * Any functor or slot may be passed into connect(). * It will be converted into a slot implicitely. * The returned iterator may be stored for disconnection * of the slot at some later point. It stays valid until * the slot is removed from the list of slots. The iterator * can also be implicitely converted into a sigc::connection object * that may be used safely beyond the life time of the slot. * @param slot_ The slot to add to the list of slots. * @return An iterator pointing to the new slot in the list. */ iterator connect(const slot_type& slot_) { return iterator(signal_base::connect(static_cast(slot_))); } /** Triggers the emission of the signal. * During signal emission all slots that have been connected * to the signal are invoked unless they are manually set into * a blocking state. The parameters are passed on to the slots. * If @e T_accumulated is not @p nil, an accumulator of this type * is used to process the return values of the slot invocations. * Otherwise, the return value of the last slot invoked is returned. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. * @param _A_a3 Argument to be passed on to the slots. * @param _A_a4 Argument to be passed on to the slots. * @param _A_a5 Argument to be passed on to the slots. * @param _A_a6 Argument to be passed on to the slots. * @return The accumulated return values of the slot invocations. */ result_type emit(typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3, typename type_trait::take _A_a4, typename type_trait::take _A_a5, typename type_trait::take _A_a6) const { return emitter_type::emit(impl_, _A_a1, _A_a2, _A_a3, _A_a4, _A_a5, _A_a6); } /** Triggers the emission of the signal in reverse order (see emit()). */ result_type emit_reverse(typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3, typename type_trait::take _A_a4, typename type_trait::take _A_a5, typename type_trait::take _A_a6) const { return emitter_type::emit_reverse(impl_, _A_a1, _A_a2, _A_a3, _A_a4, _A_a5, _A_a6); } /** Triggers the emission of the signal (see emit()). */ result_type operator()(typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3, typename type_trait::take _A_a4, typename type_trait::take _A_a5, typename type_trait::take _A_a6) const { return emit(_A_a1, _A_a2, _A_a3, _A_a4, _A_a5, _A_a6); } /** Creates a functor that calls emit() on this signal. * @code * sigc::mem_fun(mysignal, &sigc::signal6::emit) * @endcode * yields the same result. * @return A functor that calls emit() on this signal. */ bound_const_mem_functor6::take, typename type_trait::take, typename type_trait::take, typename type_trait::take, typename type_trait::take, typename type_trait::take> make_slot() const { return bound_const_mem_functor6::take, typename type_trait::take, typename type_trait::take, typename type_trait::take, typename type_trait::take, typename type_trait::take>(this, &signal6::emit); } /** Creates an STL-style interface for the signal's list of slots. * This interface supports iteration, insertion and removal of slots. * @return An STL-style interface for the signal's list of slots. */ slot_list_type slots() { return slot_list_type(impl()); } /** Creates an STL-style interface for the signal's list of slots. * This interface supports iteration, insertion and removal of slots. * @return An STL-style interface for the signal's list of slots. */ const slot_list_type slots() const { return slot_list_type(const_cast(this)->impl()); } signal6() {} signal6(const signal6& src) : signal_base(src) {} }; /** Signal declaration. * signal7 can be used to connect() slots that are invoked * during subsequent calls to emit(). Any functor or slot * can be passed into connect(). It is converted into a slot * implicitely. * * If you want to connect one signal to another, use make_slot() * to retrieve a functor that emits the signal when invoked. * * Be careful if you directly pass one signal into the connect() * method of another: a shallow copy of the signal is made and * the signal's slots are not disconnected until both the signal * and its clone are destroyed which is probably not what you want! * * An STL-style list interface for the signal's list of slots * can be retrieved with slots(). This interface supports * iteration, insertion and removal of slots. * * The following template arguments are used: * - @e T_return The desired return type for the emit() function (may be overridden by the accumulator). * - @e T_arg1 Argument type used in the definition of emit(). * - @e T_arg2 Argument type used in the definition of emit(). * - @e T_arg3 Argument type used in the definition of emit(). * - @e T_arg4 Argument type used in the definition of emit(). * - @e T_arg5 Argument type used in the definition of emit(). * - @e T_arg6 Argument type used in the definition of emit(). * - @e T_arg7 Argument type used in the definition of emit(). * - @e T_accumulator The accumulator type used for emission. The default @p nil means that no accumulator should be used, i.e. signal emission returns the return value of the last slot invoked. * * You should use the more convenient unnumbered sigc::signal template. * * @ingroup signal */ template class signal7 : public signal_base { public: typedef internal::signal_emit7 emitter_type; typedef typename emitter_type::result_type result_type; typedef slot slot_type; typedef slot_list slot_list_type; typedef typename slot_list_type::iterator iterator; typedef typename slot_list_type::const_iterator const_iterator; typedef typename slot_list_type::reverse_iterator reverse_iterator; typedef typename slot_list_type::const_reverse_iterator const_reverse_iterator; /** Add a slot to the list of slots. * Any functor or slot may be passed into connect(). * It will be converted into a slot implicitely. * The returned iterator may be stored for disconnection * of the slot at some later point. It stays valid until * the slot is removed from the list of slots. The iterator * can also be implicitely converted into a sigc::connection object * that may be used safely beyond the life time of the slot. * @param slot_ The slot to add to the list of slots. * @return An iterator pointing to the new slot in the list. */ iterator connect(const slot_type& slot_) { return iterator(signal_base::connect(static_cast(slot_))); } /** Triggers the emission of the signal. * During signal emission all slots that have been connected * to the signal are invoked unless they are manually set into * a blocking state. The parameters are passed on to the slots. * If @e T_accumulated is not @p nil, an accumulator of this type * is used to process the return values of the slot invocations. * Otherwise, the return value of the last slot invoked is returned. * @param _A_a1 Argument to be passed on to the slots. * @param _A_a2 Argument to be passed on to the slots. * @param _A_a3 Argument to be passed on to the slots. * @param _A_a4 Argument to be passed on to the slots. * @param _A_a5 Argument to be passed on to the slots. * @param _A_a6 Argument to be passed on to the slots. * @param _A_a7 Argument to be passed on to the slots. * @return The accumulated return values of the slot invocations. */ result_type emit(typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3, typename type_trait::take _A_a4, typename type_trait::take _A_a5, typename type_trait::take _A_a6, typename type_trait::take _A_a7) const { return emitter_type::emit(impl_, _A_a1, _A_a2, _A_a3, _A_a4, _A_a5, _A_a6, _A_a7); } /** Triggers the emission of the signal in reverse order (see emit()). */ result_type emit_reverse(typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3, typename type_trait::take _A_a4, typename type_trait::take _A_a5, typename type_trait::take _A_a6, typename type_trait::take _A_a7) const { return emitter_type::emit_reverse(impl_, _A_a1, _A_a2, _A_a3, _A_a4, _A_a5, _A_a6, _A_a7); } /** Triggers the emission of the signal (see emit()). */ result_type operator()(typename type_trait::take _A_a1, typename type_trait::take _A_a2, typename type_trait::take _A_a3, typename type_trait::take _A_a4, typename type_trait::take _A_a5, typename type_trait::take _A_a6, typename type_trait::take _A_a7) const { return emit(_A_a1, _A_a2, _A_a3, _A_a4, _A_a5, _A_a6, _A_a7); } /** Creates a functor that calls emit() on this signal. * @code * sigc::mem_fun(mysignal, &sigc::signal7::emit) * @endcode * yields the same result. * @return A functor that calls emit() on this signal. */ bound_const_mem_functor7::take, typename type_trait::take, typename type_trait::take, typename type_trait::take, typename type_trait::take, typename type_trait::take, typename type_trait::take> make_slot() const { return bound_const_mem_functor7::take, typename type_trait::take, typename type_trait::take, typename type_trait::take, typename type_trait::take, typename type_trait::take, typename type_trait::take>(this, &signal7::emit); } /** Creates an STL-style interface for the signal's list of slots. * This interface supports iteration, insertion and removal of slots. * @return An STL-style interface for the signal's list of slots. */ slot_list_type slots() { return slot_list_type(impl()); } /** Creates an STL-style interface for the signal's list of slots. * This interface supports iteration, insertion and removal of slots. * @return An STL-style interface for the signal's list of slots. */ const slot_list_type slots() const { return slot_list_type(const_cast(this)->impl()); } signal7() {} signal7(const signal7& src) : signal_base(src) {} }; /** Convenience wrapper for the numbered sigc::signal# templates. * signal can be used to connect() slots that are invoked * during subsequent calls to emit(). Any functor or slot * can be passed into connect(). It is converted into a slot * implicitly. * * If you want to connect one signal to another, use make_slot() * to retrieve a functor that emits the signal when invoked. * * Be careful if you directly pass one signal into the connect() * method of another: a shallow copy of the signal is made and * the signal's slots are not disconnected until both the signal * and its clone are destroyed which is probably not what you want! * * An STL-style list interface for the signal's list of slots * can be retrieved with slots(). This interface supports * iteration, insertion and removal of slots. * * The template arguments determine the function signature of * the emit() function: * - @e T_return The desired return type of the emit() function. * - @e T_arg1 Argument type used in the definition of emit(). The default @p nil means no argument. * - @e T_arg2 Argument type used in the definition of emit(). The default @p nil means no argument. * - @e T_arg3 Argument type used in the definition of emit(). The default @p nil means no argument. * - @e T_arg4 Argument type used in the definition of emit(). The default @p nil means no argument. * - @e T_arg5 Argument type used in the definition of emit(). The default @p nil means no argument. * - @e T_arg6 Argument type used in the definition of emit(). The default @p nil means no argument. * - @e T_arg7 Argument type used in the definition of emit(). The default @p nil means no argument. * * To specify an accumulator type the nested class signal::accumulated can be used. * * @par Example: * @code * void foo(int) {} * sigc::signal sig; * sig.connect(sigc::ptr_fun(&foo)); * sig.emit(19); * @endcode * * @ingroup signal */ template class signal : public signal7 { public: /** Convenience wrapper for the numbered sigc::signal# templates. * Like sigc::signal but the additional template parameter @e T_accumulator * defines the accumulator type that should be used. * * An accumulator is a functor that uses a pair of special iterators * to step through a list of slots and calculate a return value * from the results of the slot invokations. The iterators' operator*() * executes the slot. The return value is buffered, so that in an expression * like @code a = (*i) * (*i); @endcode the slot is executed only once. * The accumulator must define its return value as @p result_type. * * @par Example 1: * This accumulator calculates the arithmetic mean value: * @code * struct arithmetic_mean_accumulator * { * typedef double result_type; * template * result_type operator()(T_iterator first, T_iterator last) const * { * result_type value_ = 0; * int n_ = 0; * for (; first != last; ++first, ++n_) * value_ += *first; * return value_ / n_; * } * }; * @endcode * * @par Example 2: * This accumulator stops signal emission when a slot returns zero: * @code * struct interruptable_accumulator * { * typedef bool result_type; * template * result_type operator()(T_iterator first, T_iterator last) const * { * for (; first != last; ++first, ++n_) * if (!*first) return false; * return true; * } * }; * @endcode * * @ingroup signal */ template class accumulated : public signal7 { public: accumulated() {} accumulated(const accumulated& src) : signal7(src) {} }; signal() {} signal(const signal& src) : signal7(src) {} }; /** Convenience wrapper for the numbered sigc::signal0 template. * See the base class for useful methods. * This is the template specialization of the unnumbered sigc::signal * template for 0 argument(s). */ template class signal : public signal0 { public: /** Convenience wrapper for the numbered sigc::signal0 template. * Like sigc::signal but the additional template parameter @e T_accumulator * defines the accumulator type that should be used. */ template class accumulated : public signal0 { public: accumulated() {} accumulated(const accumulated& src) : signal0(src) {} }; signal() {} signal(const signal& src) : signal0(src) {} }; /** Convenience wrapper for the numbered sigc::signal1 template. * See the base class for useful methods. * This is the template specialization of the unnumbered sigc::signal * template for 1 argument(s). */ template class signal : public signal1 { public: /** Convenience wrapper for the numbered sigc::signal1 template. * Like sigc::signal but the additional template parameter @e T_accumulator * defines the accumulator type that should be used. */ template class accumulated : public signal1 { public: accumulated() {} accumulated(const accumulated& src) : signal1(src) {} }; signal() {} signal(const signal& src) : signal1(src) {} }; /** Convenience wrapper for the numbered sigc::signal2 template. * See the base class for useful methods. * This is the template specialization of the unnumbered sigc::signal * template for 2 argument(s). */ template class signal : public signal2 { public: /** Convenience wrapper for the numbered sigc::signal2 template. * Like sigc::signal but the additional template parameter @e T_accumulator * defines the accumulator type that should be used. */ template class accumulated : public signal2 { public: accumulated() {} accumulated(const accumulated& src) : signal2(src) {} }; signal() {} signal(const signal& src) : signal2(src) {} }; /** Convenience wrapper for the numbered sigc::signal3 template. * See the base class for useful methods. * This is the template specialization of the unnumbered sigc::signal * template for 3 argument(s). */ template class signal : public signal3 { public: /** Convenience wrapper for the numbered sigc::signal3 template. * Like sigc::signal but the additional template parameter @e T_accumulator * defines the accumulator type that should be used. */ template class accumulated : public signal3 { public: accumulated() {} accumulated(const accumulated& src) : signal3(src) {} }; signal() {} signal(const signal& src) : signal3(src) {} }; /** Convenience wrapper for the numbered sigc::signal4 template. * See the base class for useful methods. * This is the template specialization of the unnumbered sigc::signal * template for 4 argument(s). */ template class signal : public signal4 { public: /** Convenience wrapper for the numbered sigc::signal4 template. * Like sigc::signal but the additional template parameter @e T_accumulator * defines the accumulator type that should be used. */ template class accumulated : public signal4 { public: accumulated() {} accumulated(const accumulated& src) : signal4(src) {} }; signal() {} signal(const signal& src) : signal4(src) {} }; /** Convenience wrapper for the numbered sigc::signal5 template. * See the base class for useful methods. * This is the template specialization of the unnumbered sigc::signal * template for 5 argument(s). */ template class signal : public signal5 { public: /** Convenience wrapper for the numbered sigc::signal5 template. * Like sigc::signal but the additional template parameter @e T_accumulator * defines the accumulator type that should be used. */ template class accumulated : public signal5 { public: accumulated() {} accumulated(const accumulated& src) : signal5(src) {} }; signal() {} signal(const signal& src) : signal5(src) {} }; /** Convenience wrapper for the numbered sigc::signal6 template. * See the base class for useful methods. * This is the template specialization of the unnumbered sigc::signal * template for 6 argument(s). */ template class signal : public signal6 { public: /** Convenience wrapper for the numbered sigc::signal6 template. * Like sigc::signal but the additional template parameter @e T_accumulator * defines the accumulator type that should be used. */ template class accumulated : public signal6 { public: accumulated() {} accumulated(const accumulated& src) : signal6(src) {} }; signal() {} signal(const signal& src) : signal6(src) {} }; } /* namespace sigc */ #endif /* _SIGC_SIGNAL_H_ */