kolibrios-gitea/programs/develop/libraries/menuetlibc/include/sigc++/slot.h

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// -*- c++ -*-
/* This is a generated file, do not edit. Generated from ../sigc++/macros/slot.h.m4 */
#ifndef SIGCXX_SLOT_H
#define SIGCXX_SLOT_H
/*
This file just gives the basic definition of Slots.
Callback# is the 4 byte data necessary for representing all
callback types.
CallData is a specific interpretation of the Callback data.
Slot_ is a pimple on SlotData containing an Object for
holding its referencees, a Dependency that removes the slot
when its caller or receiver die, and a Callback.
Slot is a handle to a Slot_.
*/
#include <sigc++config.h>
#include <sigc++/type.h>
#include <sigc++/object.h>
#include <sigc++/handle.h>
#ifdef SIGC_CXX_NAMESPACES
namespace SigC
{
#endif
// Base node for a polymorphic list of "extra" data needed
// by various slots.
struct LIBSIGC_API SlotNode
{
void *next_;
SlotNode();
virtual ~SlotNode()=0;
};
struct LIBSIGC_API SlotIterator_
{
typedef SlotNode NodeType;
typedef SlotIterator_ Iterator;
NodeType *node_;
NodeType* node() {return node_;}
const NodeType* node() const {return node_;}
NodeType& operator*()
{return *node_;
}
const NodeType& operator*() const
{return *node_;
}
bool operator==(const Iterator& i) const
{return node_==i.node_;
}
bool operator!=(const Iterator& i) const
{return node_!=i.node_;
}
Iterator& operator++()
{
if (node_)
node_=(NodeType*)node_->next_;
return *this;
}
Iterator operator++(int)
{Iterator tmp=*this;
++*this;
return tmp;
}
Iterator& operator= (const Iterator& i)
{
node_=i.node_;
return *this;
}
SlotIterator_():node_(0) {}
SlotIterator_(NodeType *node):node_(node) {}
};
// This is a list for storing internal data for slots
struct LIBSIGC_API SlotList_
{
typedef SlotNode NodeType;
typedef SlotIterator_ Iterator;
NodeType* head_;
Iterator begin() {return ((NodeType*)head_);}
Iterator end() {return Iterator();}
const Iterator begin() const {return ((NodeType*)head_);}
const Iterator end() const {return Iterator();}
// this is best used at the begining of list.
Iterator insert_direct(Iterator pos,NodeType *n);
void clear();
bool empty() const {return head_==0;}
SlotList_():head_(0)
{}
~SlotList_()
{clear();}
private:
SlotList_(const SlotList_&);
};
struct SlotData;
// SlotDependent is an internal of SlotData used to unreference the
// Slot when either the sender or receiver have gone away
struct LIBSIGC_API SlotDependent:public ScopeNode
{
struct LIBSIGC_API Dep: public ScopeNode
{
SlotData *parent;
virtual void erase();
Dep() {}
virtual ~Dep();
} dep;
ScopeNode* receiver() {return &dep;}
ScopeNode* sender() {return this;}
SlotData* parent() {return dep.parent;}
bool connected()
{return (next_!=this);}
virtual void erase();
void set_parent(SlotData *s)
{dep.parent=s;}
SlotDependent(SlotData &s)
{dep.parent=&s;}
SlotDependent()
{}
virtual ~SlotDependent();
};
// common data to all callbacks.
struct Callback_
{
// callback function
void* (*func_)(void*);
struct O;
struct C1
{
void* (*f1)(void*);
};
struct C2
{
O* o;
void (O::*v)(void);
};
// Object pointer or function pointer
union {C1 a1; C2 a2;};
};
// All slots have the same base
struct LIBSIGC_API SlotData:public ObjectScoped
{
typedef SlotList_ List;
SlotDependent dep_;
ScopeNode* receiver() {return dep_.receiver();}
ScopeNode* sender() {return dep_.sender();}
// Called from signals to tell slot object it is connected
// invalidates list and sets weak reference
void connect();
List list_;
Callback_ data_;
Callback_& callback() {return data_;}
SlotData()
{dep_.set_parent(this);}
virtual ~SlotData();
};
typedef Scopes::Extend SlotExtend;
#ifdef LIBSIGC_MSC
#pragma warning(disable: 4231)
LIBSIGC_TMPL template class LIBSIGC_API Handle<SlotData,SlotExtend>;
#endif
class LIBSIGC_API Connection:protected Handle<SlotData,SlotExtend>
{
typedef Handle<SlotData,SlotExtend> Base;
public:
// hides virtual method
void disconnect() {if (obj()) obj()->invalid();}
bool connected() {return Base::connected ();}
Connection():Base() {}
Connection(SlotData *s):Base(s) {}
Connection(const Connection& s):Base(s) { }
~Connection() {}
};
// possible casts of Callback
template <class C,class F>
struct CallDataFunc
{
C callback;
F func;
};
template <class C,class O>
struct CallDataObj2
{
C callback;
O *obj;
};
template <class C,class O,class F>
struct CallDataObj3
{
C callback;
O* obj;
F func;
};
// from Abstract_Slots we build abstract slots
// with various lengths of arguments
// A slot is not concrete til it has a call
/****************************************************************
***** Abstract Slot 0
****************************************************************/
template <class R>
struct Callback0:public Callback_
{
#ifdef SIGC_CXX_PARTIAL_SPEC
typedef R RType;
#else
typedef Trait<R>::type RType;
#endif
typedef RType (*Func)(void*);
inline RType call()
{return ((Func)(func_))((void*)this);}
inline RType operator()()
{return ((Func)(func_))((void*)this);}
};
template <class R>
class Slot0
:public Handle<SlotData,SlotExtend>
{
public:
typedef Handle<SlotData,SlotExtend> Base;
typedef Callback0<R> Callback;
typedef typename Callback::RType RType;
typedef RType (*Func)(void*);
SlotData* data() const {return (SlotData*)(scope_.object());}
Slot0() {}
Slot0(SlotData *s):Base(s) {}
Slot0(const Slot0& s):Base(s.obj()) {}
inline RType call()
{
if (connected())
return ((Callback&)(data()->callback())).call();
return RType();
}
inline RType operator()()
{
if (connected())
return ((Callback&)(data()->callback())).call();
return RType();
}
};
#ifndef SIGC_CXX_VOID_RETURN
#ifdef SIGC_CXX_PARTIAL_SPEC
template <>
struct Callback0<void>:public Callback_
{
typedef void RType;
typedef RType (*Func)(void*);
inline RType call()
{((Func)(func_))((void*)this);}
inline RType operator()()
{((Func)(func_))((void*)this);}
};
template <>
class Slot0<void>
:public Handle<SlotData,SlotExtend>
{
public:
typedef Handle<SlotData,SlotExtend> Base;
typedef Callback0<void> Callback;
typedef Callback::RType RType;
typedef RType (*Func)(void*);
SlotData* data() const {return (SlotData*)(scope_.object());}
Slot0() {}
Slot0(SlotData *s):Base(s) {}
Slot0(const Slot0& s):Base(s.obj()) {}
inline RType call()
{
if (connected())
((Callback&)(data()->callback())).call();
}
inline RType operator()()
{
if (connected())
((Callback&)(data()->callback())).call();
}
};
#endif
#endif
/****************************************************************
***** Abstract Slot 1
****************************************************************/
template <class R,class P1>
struct Callback1:public Callback_
{
#ifdef SIGC_CXX_PARTIAL_SPEC
typedef R RType;
#else
typedef Trait<R>::type RType;
#endif
typedef RType (*Func)(void*,P1);
inline RType call(typename Trait<P1>::ref p1)
{return ((Func)(func_))((void*)this,p1);}
inline RType operator()(typename Trait<P1>::ref p1)
{return ((Func)(func_))((void*)this,p1);}
};
template <class R,class P1>
class Slot1
:public Handle<SlotData,SlotExtend>
{
public:
typedef Handle<SlotData,SlotExtend> Base;
typedef Callback1<R,P1> Callback;
typedef typename Callback::RType RType;
typedef RType (*Func)(void*,P1);
SlotData* data() const {return (SlotData*)(scope_.object());}
Slot1() {}
Slot1(SlotData *s):Base(s) {}
Slot1(const Slot1& s):Base(s.obj()) {}
inline RType call(typename Trait<P1>::ref p1)
{
if (connected())
return ((Callback&)(data()->callback())).call(p1);
return RType();
}
inline RType operator()(typename Trait<P1>::ref p1)
{
if (connected())
return ((Callback&)(data()->callback())).call(p1);
return RType();
}
};
#ifndef SIGC_CXX_VOID_RETURN
#ifdef SIGC_CXX_PARTIAL_SPEC
template <class P1>
struct Callback1<void,P1>:public Callback_
{
typedef void RType;
typedef RType (*Func)(void*,P1);
inline RType call(typename Trait<P1>::ref p1)
{((Func)(func_))((void*)this,p1);}
inline RType operator()(typename Trait<P1>::ref p1)
{((Func)(func_))((void*)this,p1);}
};
template <class P1>
class Slot1<void,P1>
:public Handle<SlotData,SlotExtend>
{
public:
typedef Handle<SlotData,SlotExtend> Base;
typedef Callback1<void,P1> Callback;
typedef typename Callback::RType RType;
typedef RType (*Func)(void*,P1);
SlotData* data() const {return (SlotData*)(scope_.object());}
Slot1() {}
Slot1(SlotData *s):Base(s) {}
Slot1(const Slot1& s):Base(s.obj()) {}
inline RType call(typename Trait<P1>::ref p1)
{
if (connected())
((Callback&)(data()->callback())).call(p1);
}
inline RType operator()(typename Trait<P1>::ref p1)
{
if (connected())
((Callback&)(data()->callback())).call(p1);
}
};
#endif
#endif
/****************************************************************
***** Abstract Slot 2
****************************************************************/
template <class R,class P1,class P2>
struct Callback2:public Callback_
{
#ifdef SIGC_CXX_PARTIAL_SPEC
typedef R RType;
#else
typedef Trait<R>::type RType;
#endif
typedef RType (*Func)(void*,P1,P2);
inline RType call(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2)
{return ((Func)(func_))((void*)this,p1,p2);}
inline RType operator()(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2)
{return ((Func)(func_))((void*)this,p1,p2);}
};
template <class R,class P1,class P2>
class Slot2
:public Handle<SlotData,SlotExtend>
{
public:
typedef Handle<SlotData,SlotExtend> Base;
typedef Callback2<R,P1,P2> Callback;
typedef typename Callback::RType RType;
typedef RType (*Func)(void*,P1,P2);
SlotData* data() const {return (SlotData*)(scope_.object());}
Slot2() {}
Slot2(SlotData *s):Base(s) {}
Slot2(const Slot2& s):Base(s.obj()) {}
inline RType call(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2)
{
if (connected())
return ((Callback&)(data()->callback())).call(p1,p2);
return RType();
}
inline RType operator()(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2)
{
if (connected())
return ((Callback&)(data()->callback())).call(p1,p2);
return RType();
}
};
#ifndef SIGC_CXX_VOID_RETURN
#ifdef SIGC_CXX_PARTIAL_SPEC
template <class P1,class P2>
struct Callback2<void,P1,P2>:public Callback_
{
typedef void RType;
typedef RType (*Func)(void*,P1,P2);
inline RType call(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2)
{((Func)(func_))((void*)this,p1,p2);}
inline RType operator()(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2)
{((Func)(func_))((void*)this,p1,p2);}
};
template <class P1,class P2>
class Slot2<void,P1,P2>
:public Handle<SlotData,SlotExtend>
{
public:
typedef Handle<SlotData,SlotExtend> Base;
typedef Callback2<void,P1,P2> Callback;
typedef typename Callback::RType RType;
typedef RType (*Func)(void*,P1,P2);
SlotData* data() const {return (SlotData*)(scope_.object());}
Slot2() {}
Slot2(SlotData *s):Base(s) {}
Slot2(const Slot2& s):Base(s.obj()) {}
inline RType call(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2)
{
if (connected())
((Callback&)(data()->callback())).call(p1,p2);
}
inline RType operator()(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2)
{
if (connected())
((Callback&)(data()->callback())).call(p1,p2);
}
};
#endif
#endif
/****************************************************************
***** Abstract Slot 3
****************************************************************/
template <class R,class P1,class P2,class P3>
struct Callback3:public Callback_
{
#ifdef SIGC_CXX_PARTIAL_SPEC
typedef R RType;
#else
typedef Trait<R>::type RType;
#endif
typedef RType (*Func)(void*,P1,P2,P3);
inline RType call(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2,typename Trait<P3>::ref p3)
{return ((Func)(func_))((void*)this,p1,p2,p3);}
inline RType operator()(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2,typename Trait<P3>::ref p3)
{return ((Func)(func_))((void*)this,p1,p2,p3);}
};
template <class R,class P1,class P2,class P3>
class Slot3
:public Handle<SlotData,SlotExtend>
{
public:
typedef Handle<SlotData,SlotExtend> Base;
typedef Callback3<R,P1,P2,P3> Callback;
typedef typename Callback::RType RType;
typedef RType (*Func)(void*,P1,P2,P3);
SlotData* data() const {return (SlotData*)(scope_.object());}
Slot3() {}
Slot3(SlotData *s):Base(s) {}
Slot3(const Slot3& s):Base(s.obj()) {}
inline RType call(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2,typename Trait<P3>::ref p3)
{
if (connected())
return ((Callback&)(data()->callback())).call(p1,p2,p3);
return RType();
}
inline RType operator()(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2,typename Trait<P3>::ref p3)
{
if (connected())
return ((Callback&)(data()->callback())).call(p1,p2,p3);
return RType();
}
};
#ifndef SIGC_CXX_VOID_RETURN
#ifdef SIGC_CXX_PARTIAL_SPEC
template <class P1,class P2,class P3>
struct Callback3<void,P1,P2,P3>:public Callback_
{
typedef void RType;
typedef RType (*Func)(void*,P1,P2,P3);
inline RType call(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2,typename Trait<P3>::ref p3)
{((Func)(func_))((void*)this,p1,p2,p3);}
inline RType operator()(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2,typename Trait<P3>::ref p3)
{((Func)(func_))((void*)this,p1,p2,p3);}
};
template <class P1,class P2,class P3>
class Slot3<void,P1,P2,P3>
:public Handle<SlotData,SlotExtend>
{
public:
typedef Handle<SlotData,SlotExtend> Base;
typedef Callback3<void,P1,P2,P3> Callback;
typedef typename Callback::RType RType;
typedef RType (*Func)(void*,P1,P2,P3);
SlotData* data() const {return (SlotData*)(scope_.object());}
Slot3() {}
Slot3(SlotData *s):Base(s) {}
Slot3(const Slot3& s):Base(s.obj()) {}
inline RType call(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2,typename Trait<P3>::ref p3)
{
if (connected())
((Callback&)(data()->callback())).call(p1,p2,p3);
}
inline RType operator()(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2,typename Trait<P3>::ref p3)
{
if (connected())
((Callback&)(data()->callback())).call(p1,p2,p3);
}
};
#endif
#endif
/****************************************************************
***** Abstract Slot 4
****************************************************************/
template <class R,class P1,class P2,class P3,class P4>
struct Callback4:public Callback_
{
#ifdef SIGC_CXX_PARTIAL_SPEC
typedef R RType;
#else
typedef Trait<R>::type RType;
#endif
typedef RType (*Func)(void*,P1,P2,P3,P4);
inline RType call(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2,typename Trait<P3>::ref p3,typename Trait<P4>::ref p4)
{return ((Func)(func_))((void*)this,p1,p2,p3,p4);}
inline RType operator()(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2,typename Trait<P3>::ref p3,typename Trait<P4>::ref p4)
{return ((Func)(func_))((void*)this,p1,p2,p3,p4);}
};
template <class R,class P1,class P2,class P3,class P4>
class Slot4
:public Handle<SlotData,SlotExtend>
{
public:
typedef Handle<SlotData,SlotExtend> Base;
typedef Callback4<R,P1,P2,P3,P4> Callback;
typedef typename Callback::RType RType;
typedef RType (*Func)(void*,P1,P2,P3,P4);
SlotData* data() const {return (SlotData*)(scope_.object());}
Slot4() {}
Slot4(SlotData *s):Base(s) {}
Slot4(const Slot4& s):Base(s.obj()) {}
inline RType call(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2,typename Trait<P3>::ref p3,typename Trait<P4>::ref p4)
{
if (connected())
return ((Callback&)(data()->callback())).call(p1,p2,p3,p4);
return RType();
}
inline RType operator()(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2,typename Trait<P3>::ref p3,typename Trait<P4>::ref p4)
{
if (connected())
return ((Callback&)(data()->callback())).call(p1,p2,p3,p4);
return RType();
}
};
#ifndef SIGC_CXX_VOID_RETURN
#ifdef SIGC_CXX_PARTIAL_SPEC
template <class P1,class P2,class P3,class P4>
struct Callback4<void,P1,P2,P3,P4>:public Callback_
{
typedef void RType;
typedef RType (*Func)(void*,P1,P2,P3,P4);
inline RType call(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2,typename Trait<P3>::ref p3,typename Trait<P4>::ref p4)
{((Func)(func_))((void*)this,p1,p2,p3,p4);}
inline RType operator()(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2,typename Trait<P3>::ref p3,typename Trait<P4>::ref p4)
{((Func)(func_))((void*)this,p1,p2,p3,p4);}
};
template <class P1,class P2,class P3,class P4>
class Slot4<void,P1,P2,P3,P4>
:public Handle<SlotData,SlotExtend>
{
public:
typedef Handle<SlotData,SlotExtend> Base;
typedef Callback4<void,P1,P2,P3,P4> Callback;
typedef typename Callback::RType RType;
typedef RType (*Func)(void*,P1,P2,P3,P4);
SlotData* data() const {return (SlotData*)(scope_.object());}
Slot4() {}
Slot4(SlotData *s):Base(s) {}
Slot4(const Slot4& s):Base(s.obj()) {}
inline RType call(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2,typename Trait<P3>::ref p3,typename Trait<P4>::ref p4)
{
if (connected())
((Callback&)(data()->callback())).call(p1,p2,p3,p4);
}
inline RType operator()(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2,typename Trait<P3>::ref p3,typename Trait<P4>::ref p4)
{
if (connected())
((Callback&)(data()->callback())).call(p1,p2,p3,p4);
}
};
#endif
#endif
/****************************************************************
***** Abstract Slot 5
****************************************************************/
template <class R,class P1,class P2,class P3,class P4,class P5>
struct Callback5:public Callback_
{
#ifdef SIGC_CXX_PARTIAL_SPEC
typedef R RType;
#else
typedef Trait<R>::type RType;
#endif
typedef RType (*Func)(void*,P1,P2,P3,P4,P5);
inline RType call(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2,typename Trait<P3>::ref p3,typename Trait<P4>::ref p4,typename Trait<P5>::ref p5)
{return ((Func)(func_))((void*)this,p1,p2,p3,p4,p5);}
inline RType operator()(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2,typename Trait<P3>::ref p3,typename Trait<P4>::ref p4,typename Trait<P5>::ref p5)
{return ((Func)(func_))((void*)this,p1,p2,p3,p4,p5);}
};
template <class R,class P1,class P2,class P3,class P4,class P5>
class Slot5
:public Handle<SlotData,SlotExtend>
{
public:
typedef Handle<SlotData,SlotExtend> Base;
typedef Callback5<R,P1,P2,P3,P4,P5> Callback;
typedef typename Callback::RType RType;
typedef RType (*Func)(void*,P1,P2,P3,P4,P5);
SlotData* data() const {return (SlotData*)(scope_.object());}
Slot5() {}
Slot5(SlotData *s):Base(s) {}
Slot5(const Slot5& s):Base(s.obj()) {}
inline RType call(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2,typename Trait<P3>::ref p3,typename Trait<P4>::ref p4,typename Trait<P5>::ref p5)
{
if (connected())
return ((Callback&)(data()->callback())).call(p1,p2,p3,p4,p5);
return RType();
}
inline RType operator()(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2,typename Trait<P3>::ref p3,typename Trait<P4>::ref p4,typename Trait<P5>::ref p5)
{
if (connected())
return ((Callback&)(data()->callback())).call(p1,p2,p3,p4,p5);
return RType();
}
};
#ifndef SIGC_CXX_VOID_RETURN
#ifdef SIGC_CXX_PARTIAL_SPEC
template <class P1,class P2,class P3,class P4,class P5>
struct Callback5<void,P1,P2,P3,P4,P5>:public Callback_
{
typedef void RType;
typedef RType (*Func)(void*,P1,P2,P3,P4,P5);
inline RType call(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2,typename Trait<P3>::ref p3,typename Trait<P4>::ref p4,typename Trait<P5>::ref p5)
{((Func)(func_))((void*)this,p1,p2,p3,p4,p5);}
inline RType operator()(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2,typename Trait<P3>::ref p3,typename Trait<P4>::ref p4,typename Trait<P5>::ref p5)
{((Func)(func_))((void*)this,p1,p2,p3,p4,p5);}
};
template <class P1,class P2,class P3,class P4,class P5>
class Slot5<void,P1,P2,P3,P4,P5>
:public Handle<SlotData,SlotExtend>
{
public:
typedef Handle<SlotData,SlotExtend> Base;
typedef Callback5<void,P1,P2,P3,P4,P5> Callback;
typedef typename Callback::RType RType;
typedef RType (*Func)(void*,P1,P2,P3,P4,P5);
SlotData* data() const {return (SlotData*)(scope_.object());}
Slot5() {}
Slot5(SlotData *s):Base(s) {}
Slot5(const Slot5& s):Base(s.obj()) {}
inline RType call(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2,typename Trait<P3>::ref p3,typename Trait<P4>::ref p4,typename Trait<P5>::ref p5)
{
if (connected())
((Callback&)(data()->callback())).call(p1,p2,p3,p4,p5);
}
inline RType operator()(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2,typename Trait<P3>::ref p3,typename Trait<P4>::ref p4,typename Trait<P5>::ref p5)
{
if (connected())
((Callback&)(data()->callback())).call(p1,p2,p3,p4,p5);
}
};
#endif
#endif
/****************************************************************
***** Abstract Slot 6
****************************************************************/
template <class R,class P1,class P2,class P3,class P4,class P5,class P6>
struct Callback6:public Callback_
{
#ifdef SIGC_CXX_PARTIAL_SPEC
typedef R RType;
#else
typedef Trait<R>::type RType;
#endif
typedef RType (*Func)(void*,P1,P2,P3,P4,P5,P6);
inline RType call(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2,typename Trait<P3>::ref p3,typename Trait<P4>::ref p4,typename Trait<P5>::ref p5,typename Trait<P6>::ref p6)
{return ((Func)(func_))((void*)this,p1,p2,p3,p4,p5,p6);}
inline RType operator()(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2,typename Trait<P3>::ref p3,typename Trait<P4>::ref p4,typename Trait<P5>::ref p5,typename Trait<P6>::ref p6)
{return ((Func)(func_))((void*)this,p1,p2,p3,p4,p5,p6);}
};
template <class R,class P1,class P2,class P3,class P4,class P5,class P6>
class Slot6
:public Handle<SlotData,SlotExtend>
{
public:
typedef Handle<SlotData,SlotExtend> Base;
typedef Callback6<R,P1,P2,P3,P4,P5,P6> Callback;
typedef typename Callback::RType RType;
typedef RType (*Func)(void*,P1,P2,P3,P4,P5,P6);
SlotData* data() const {return (SlotData*)(scope_.object());}
Slot6() {}
Slot6(SlotData *s):Base(s) {}
Slot6(const Slot6& s):Base(s.obj()) {}
inline RType call(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2,typename Trait<P3>::ref p3,typename Trait<P4>::ref p4,typename Trait<P5>::ref p5,typename Trait<P6>::ref p6)
{
if (connected())
return ((Callback&)(data()->callback())).call(p1,p2,p3,p4,p5,p6);
return RType();
}
inline RType operator()(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2,typename Trait<P3>::ref p3,typename Trait<P4>::ref p4,typename Trait<P5>::ref p5,typename Trait<P6>::ref p6)
{
if (connected())
return ((Callback&)(data()->callback())).call(p1,p2,p3,p4,p5,p6);
return RType();
}
};
#ifndef SIGC_CXX_VOID_RETURN
#ifdef SIGC_CXX_PARTIAL_SPEC
template <class P1,class P2,class P3,class P4,class P5,class P6>
struct Callback6<void,P1,P2,P3,P4,P5,P6>:public Callback_
{
typedef void RType;
typedef RType (*Func)(void*,P1,P2,P3,P4,P5,P6);
inline RType call(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2,typename Trait<P3>::ref p3,typename Trait<P4>::ref p4,typename Trait<P5>::ref p5,typename Trait<P6>::ref p6)
{((Func)(func_))((void*)this,p1,p2,p3,p4,p5,p6);}
inline RType operator()(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2,typename Trait<P3>::ref p3,typename Trait<P4>::ref p4,typename Trait<P5>::ref p5,typename Trait<P6>::ref p6)
{((Func)(func_))((void*)this,p1,p2,p3,p4,p5,p6);}
};
template <class P1,class P2,class P3,class P4,class P5,class P6>
class Slot6<void,P1,P2,P3,P4,P5,P6>
:public Handle<SlotData,SlotExtend>
{
public:
typedef Handle<SlotData,SlotExtend> Base;
typedef Callback6<void,P1,P2,P3,P4,P5,P6> Callback;
typedef typename Callback::RType RType;
typedef RType (*Func)(void*,P1,P2,P3,P4,P5,P6);
SlotData* data() const {return (SlotData*)(scope_.object());}
Slot6() {}
Slot6(SlotData *s):Base(s) {}
Slot6(const Slot6& s):Base(s.obj()) {}
inline RType call(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2,typename Trait<P3>::ref p3,typename Trait<P4>::ref p4,typename Trait<P5>::ref p5,typename Trait<P6>::ref p6)
{
if (connected())
((Callback&)(data()->callback())).call(p1,p2,p3,p4,p5,p6);
}
inline RType operator()(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2,typename Trait<P3>::ref p3,typename Trait<P4>::ref p4,typename Trait<P5>::ref p5,typename Trait<P6>::ref p6)
{
if (connected())
((Callback&)(data()->callback())).call(p1,p2,p3,p4,p5,p6);
}
};
#endif
#endif
/****************************************************************
***** Abstract Slot 7
****************************************************************/
template <class R,class P1,class P2,class P3,class P4,class P5,class P6,class P7>
struct Callback7:public Callback_
{
#ifdef SIGC_CXX_PARTIAL_SPEC
typedef R RType;
#else
typedef Trait<R>::type RType;
#endif
typedef RType (*Func)(void*,P1,P2,P3,P4,P5,P6,P7);
inline RType call(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2,typename Trait<P3>::ref p3,typename Trait<P4>::ref p4,typename Trait<P5>::ref p5,typename Trait<P6>::ref p6,typename Trait<P7>::ref p7)
{return ((Func)(func_))((void*)this,p1,p2,p3,p4,p5,p6,p7);}
inline RType operator()(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2,typename Trait<P3>::ref p3,typename Trait<P4>::ref p4,typename Trait<P5>::ref p5,typename Trait<P6>::ref p6,typename Trait<P7>::ref p7)
{return ((Func)(func_))((void*)this,p1,p2,p3,p4,p5,p6,p7);}
};
template <class R,class P1,class P2,class P3,class P4,class P5,class P6,class P7>
class Slot7
:public Handle<SlotData,SlotExtend>
{
public:
typedef Handle<SlotData,SlotExtend> Base;
typedef Callback7<R,P1,P2,P3,P4,P5,P6,P7> Callback;
typedef typename Callback::RType RType;
typedef RType (*Func)(void*,P1,P2,P3,P4,P5,P6,P7);
SlotData* data() const {return (SlotData*)(scope_.object());}
Slot7() {}
Slot7(SlotData *s):Base(s) {}
Slot7(const Slot7& s):Base(s.obj()) {}
inline RType call(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2,typename Trait<P3>::ref p3,typename Trait<P4>::ref p4,typename Trait<P5>::ref p5,typename Trait<P6>::ref p6,typename Trait<P7>::ref p7)
{
if (connected())
return ((Callback&)(data()->callback())).call(p1,p2,p3,p4,p5,p6,p7);
return RType();
}
inline RType operator()(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2,typename Trait<P3>::ref p3,typename Trait<P4>::ref p4,typename Trait<P5>::ref p5,typename Trait<P6>::ref p6,typename Trait<P7>::ref p7)
{
if (connected())
return ((Callback&)(data()->callback())).call(p1,p2,p3,p4,p5,p6,p7);
return RType();
}
};
#ifndef SIGC_CXX_VOID_RETURN
#ifdef SIGC_CXX_PARTIAL_SPEC
template <class P1,class P2,class P3,class P4,class P5,class P6,class P7>
struct Callback7<void,P1,P2,P3,P4,P5,P6,P7>:public Callback_
{
typedef void RType;
typedef RType (*Func)(void*,P1,P2,P3,P4,P5,P6,P7);
inline RType call(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2,typename Trait<P3>::ref p3,typename Trait<P4>::ref p4,typename Trait<P5>::ref p5,typename Trait<P6>::ref p6,typename Trait<P7>::ref p7)
{((Func)(func_))((void*)this,p1,p2,p3,p4,p5,p6,p7);}
inline RType operator()(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2,typename Trait<P3>::ref p3,typename Trait<P4>::ref p4,typename Trait<P5>::ref p5,typename Trait<P6>::ref p6,typename Trait<P7>::ref p7)
{((Func)(func_))((void*)this,p1,p2,p3,p4,p5,p6,p7);}
};
template <class P1,class P2,class P3,class P4,class P5,class P6,class P7>
class Slot7<void,P1,P2,P3,P4,P5,P6,P7>
:public Handle<SlotData,SlotExtend>
{
public:
typedef Handle<SlotData,SlotExtend> Base;
typedef Callback7<void,P1,P2,P3,P4,P5,P6,P7> Callback;
typedef typename Callback::RType RType;
typedef RType (*Func)(void*,P1,P2,P3,P4,P5,P6,P7);
SlotData* data() const {return (SlotData*)(scope_.object());}
Slot7() {}
Slot7(SlotData *s):Base(s) {}
Slot7(const Slot7& s):Base(s.obj()) {}
inline RType call(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2,typename Trait<P3>::ref p3,typename Trait<P4>::ref p4,typename Trait<P5>::ref p5,typename Trait<P6>::ref p6,typename Trait<P7>::ref p7)
{
if (connected())
((Callback&)(data()->callback())).call(p1,p2,p3,p4,p5,p6,p7);
}
inline RType operator()(typename Trait<P1>::ref p1,typename Trait<P2>::ref p2,typename Trait<P3>::ref p3,typename Trait<P4>::ref p4,typename Trait<P5>::ref p5,typename Trait<P6>::ref p6,typename Trait<P7>::ref p7)
{
if (connected())
((Callback&)(data()->callback())).call(p1,p2,p3,p4,p5,p6,p7);
}
};
#endif
#endif
#ifdef SIGC_CXX_NAMESPACES
} // namespace
#endif
#endif // SIGCXX_SLOT_H