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usbloadergx/source/GUI/sigslot.h
dimok321 72d8c9dc2e *Created an automatic resource list generation script which is executed when files are added/removed 
*Created an own class for the homebrew prompt
*Created scrollbar class which is now used on every browser
*Created a checkbox browser list class
*Changed the category prompts to the new list mode
*Improved B-Button scrolling
*Fixed horizontal text scrolling
*Fixed possible crash on long text display
*Many internal gui changes and navigation changes
*Fixed booting games by argument (headless id) (Issue 1930)
*Fixed SD Reload button to really reload the SD after it was ejected (Issue 1923)
*Added booting with arguements from meta.xml for homebrews (Issue 1926)
*Added some arguments acception from meta.xml to our app. "-ios=xxx" and "-usbport=x" or "--ios=xxx" and "--usbport=x" can be used. -usbport is for Hermes cIOS to decide which usb port to use on startup. The ios is the boot IOS on startup, it always overrides the compiled boot IOS into the application.
2011-06-14 17:53:19 +00:00

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// sigslot.h: Signal/Slot classes
//
// Written by Sarah Thompson (sarah@telergy.com) 2002.
//
// License: Public domain. You are free to use this code however you like, with the proviso that
// the author takes on no responsibility or liability for any use.
//
// QUICK DOCUMENTATION
//
// (see also the full documentation at http://sigslot.sourceforge.net/)
//
// #define switches
// SIGSLOT_PURE_ISO - Define this to force ISO C++ compliance. This also disables
// all of the thread safety support on platforms where it is
// available.
//
// SIGSLOT_USE_POSIX_THREADS - Force use of Posix threads when using a C++ compiler other than
// gcc on a platform that supports Posix threads. (When using gcc,
// this is the default - use SIGSLOT_PURE_ISO to disable this if
// necessary)
//
// SIGSLOT_DEFAULT_MT_POLICY - Where thread support is enabled, this defaults to multi_threaded_global.
// Otherwise, the default is single_threaded. #define this yourself to
// override the default. In pure ISO mode, anything other than
// single_threaded will cause a compiler error.
//
// PLATFORM NOTES
//
// Win32 - On Win32, the WIN32 symbol must be #defined. Most mainstream
// compilers do this by default, but you may need to define it
// yourself if your build environment is less standard. This causes
// the Win32 thread support to be compiled in and used automatically.
//
// Unix/Linux/BSD, etc. - If you're using gcc, it is assumed that you have Posix threads
// available, so they are used automatically. You can override this
// (as under Windows) with the SIGSLOT_PURE_ISO switch. If you're using
// something other than gcc but still want to use Posix threads, you
// need to #define SIGSLOT_USE_POSIX_THREADS.
//
// ISO C++ - If none of the supported platforms are detected, or if
// SIGSLOT_PURE_ISO is defined, all multithreading support is turned off,
// along with any code that might cause a pure ISO C++ environment to
// complain. Before you ask, gcc -ansi -pedantic won't compile this
// library, but gcc -ansi is fine. Pedantic mode seems to throw a lot of
// errors that aren't really there. If you feel like investigating this,
// please contact the author.
//
//
// THREADING MODES
//
// single_threaded - Your program is assumed to be single threaded from the point of view
// of signal/slot usage (i.e. all objects using signals and slots are
// created and destroyed from a single thread). Behaviour if objects are
// destroyed concurrently is undefined (i.e. you'll get the occasional
// segmentation fault/memory exception).
//
// multi_threaded_global - Your program is assumed to be multi threaded. Objects using signals and
// slots can be safely created and destroyed from any thread, even when
// connections exist. In multi_threaded_global mode, this is achieved by a
// single global mutex (actually a critical section on Windows because they
// are faster). This option uses less OS resources, but results in more
// opportunities for contention, possibly resulting in more context switches
// than are strictly necessary.
//
// multi_threaded_local - Behaviour in this mode is essentially the same as multi_threaded_global,
// except that each signal, and each object that inherits has_slots, all
// have their own mutex/critical section. In practice, this means that
// mutex collisions (and hence context switches) only happen if they are
// absolutely essential. However, on some platforms, creating a lot of
// mutexes can slow down the whole OS, so use this option with care.
//
// USING THE LIBRARY
//
// See the full documentation at http://sigslot.sourceforge.net/
//
//
#ifndef SIGSLOT_H__
#define SIGSLOT_H__
#include <set>
#include <list>
#if defined(SIGSLOT_PURE_ISO) || (!defined(WIN32) && !defined(__GNUG__) && !defined(SIGSLOT_USE_POSIX_THREADS) && !defined(SIGSLOT_USE_LWP_THREADS))
# define _SIGSLOT_SINGLE_THREADED
#elif defined(WIN32)
# define _SIGSLOT_HAS_WIN32_THREADS
# include <windows.h>
#elif (defined(__GNUG__) && defined(__GCCORE_H__)) || defined(SIGSLOT_USE_LWP_THREADS)
# define _SIGSLOT_SINGLE_THREADED
#elif defined(__GNUG__) || defined(SIGSLOT_USE_POSIX_THREADS)
# define _SIGSLOT_HAS_POSIX_THREADS
# include <pthread.h>
#else
# define _SIGSLOT_SINGLE_THREADED
#endif
#ifndef SIGSLOT_DEFAULT_MT_POLICY
# ifdef _SIGSLOT_SINGLE_THREADED
# define SIGSLOT_DEFAULT_MT_POLICY single_threaded
# else
# define SIGSLOT_DEFAULT_MT_POLICY multi_threaded_global
# endif
#endif
namespace sigslot {
class single_threaded
{
public:
single_threaded()
{
;
}
virtual ~single_threaded()
{
;
}
virtual void lock()
{
;
}
virtual void unlock()
{
;
}
};
#ifdef _SIGSLOT_HAS_WIN32_THREADS
// The multi threading policies only get compiled in if they are enabled.
class multi_threaded_global
{
public:
multi_threaded_global()
{
static bool isinitialised = false;
if(!isinitialised)
{
InitializeCriticalSection(get_critsec());
isinitialised = true;
}
}
multi_threaded_global(const multi_threaded_global&)
{
;
}
virtual ~multi_threaded_global()
{
;
}
virtual void lock()
{
EnterCriticalSection(get_critsec());
}
virtual void unlock()
{
LeaveCriticalSection(get_critsec());
}
private:
CRITICAL_SECTION* get_critsec()
{
static CRITICAL_SECTION g_critsec;
return &g_critsec;
}
};
class multi_threaded_local
{
public:
multi_threaded_local()
{
InitializeCriticalSection(&m_critsec);
}
multi_threaded_local(const multi_threaded_local&)
{
InitializeCriticalSection(&m_critsec);
}
virtual ~multi_threaded_local()
{
DeleteCriticalSection(&m_critsec);
}
virtual void lock()
{
EnterCriticalSection(&m_critsec);
}
virtual void unlock()
{
LeaveCriticalSection(&m_critsec);
}
private:
CRITICAL_SECTION m_critsec;
};
#endif // _SIGSLOT_HAS_WIN32_THREADS
#ifdef _SIGSLOT_HAS_POSIX_THREADS
// The multi threading policies only get compiled in if they are enabled.
class multi_threaded_global
{
public:
multi_threaded_global()
{
pthread_mutex_init(get_mutex(), NULL);
}
multi_threaded_global(const multi_threaded_global&)
{
;
}
virtual ~multi_threaded_global()
{
;
}
virtual void lock()
{
pthread_mutex_lock(get_mutex());
}
virtual void unlock()
{
pthread_mutex_unlock(get_mutex());
}
private:
pthread_mutex_t* get_mutex()
{
static pthread_mutex_t g_mutex;
return &g_mutex;
}
};
class multi_threaded_local
{
public:
multi_threaded_local()
{
pthread_mutex_init(&m_mutex, NULL);
}
multi_threaded_local(const multi_threaded_local&)
{
pthread_mutex_init(&m_mutex, NULL);
}
virtual ~multi_threaded_local()
{
pthread_mutex_destroy(&m_mutex);
}
virtual void lock()
{
pthread_mutex_lock(&m_mutex);
}
virtual void unlock()
{
pthread_mutex_unlock(&m_mutex);
}
private:
pthread_mutex_t m_mutex;
};
#endif // _SIGSLOT_HAS_POSIX_THREADS
#ifdef _SIGSLOT_HAS_LWP_THREADS
// The multi threading policies only get compiled in if they are enabled.
//!making mutex static because libogc only supports up to 64 mutex - Dimok
static mutex_t g_mutex = LWP_MUTEX_NULL;
class multi_threaded_global
{
public:
multi_threaded_global()
{
if(g_mutex == LWP_MUTEX_NULL)
LWP_MutexInit(&g_mutex, NULL);
}
multi_threaded_global(const multi_threaded_global&)
{
;
}
virtual ~multi_threaded_global()
{
;
}
virtual void lock()
{
LWP_MutexLock(g_mutex);
}
virtual void unlock()
{
LWP_MutexUnlock(g_mutex);
}
};
class multi_threaded_local
{
public:
multi_threaded_local()
{
;
}
multi_threaded_local(const multi_threaded_local&)
{
;
}
virtual ~multi_threaded_local()
{
}
virtual void lock()
{
;
}
virtual void unlock()
{
;
}
};
#endif // _SIGSLOT_HAS_LWP_THREADS
template<class mt_policy>
class lock_block
{
public:
mt_policy *m_mutex;
lock_block(mt_policy *mtx)
: m_mutex(mtx)
{
m_mutex->lock();
}
~lock_block()
{
m_mutex->unlock();
}
};
template<class mt_policy>
class has_slots;
template<class mt_policy>
class _connection_base0
{
public:
virtual ~_connection_base0() { ; }
virtual has_slots<mt_policy>* getdest() const = 0;
virtual void emit() = 0;
virtual _connection_base0* clone() = 0;
virtual _connection_base0* duplicate(has_slots<mt_policy>* pnewdest) = 0;
};
template<class arg1_type, class mt_policy>
class _connection_base1
{
public:
virtual ~_connection_base1() { ; }
virtual has_slots<mt_policy>* getdest() const = 0;
virtual void emit(arg1_type) = 0;
virtual _connection_base1<arg1_type, mt_policy>* clone() = 0;
virtual _connection_base1<arg1_type, mt_policy>* duplicate(has_slots<mt_policy>* pnewdest) = 0;
};
template<class arg1_type, class arg2_type, class mt_policy>
class _connection_base2
{
public:
virtual ~_connection_base2() { ; }
virtual has_slots<mt_policy>* getdest() const = 0;
virtual void emit(arg1_type, arg2_type) = 0;
virtual _connection_base2<arg1_type, arg2_type, mt_policy>* clone() = 0;
virtual _connection_base2<arg1_type, arg2_type, mt_policy>* duplicate(has_slots<mt_policy>* pnewdest) = 0;
};
template<class arg1_type, class arg2_type, class arg3_type, class mt_policy>
class _connection_base3
{
public:
virtual ~_connection_base3() { ; }
virtual has_slots<mt_policy>* getdest() const = 0;
virtual void emit(arg1_type, arg2_type, arg3_type) = 0;
virtual _connection_base3<arg1_type, arg2_type, arg3_type, mt_policy>* clone() = 0;
virtual _connection_base3<arg1_type, arg2_type, arg3_type, mt_policy>* duplicate(has_slots<mt_policy>* pnewdest) = 0;
};
template<class arg1_type, class arg2_type, class arg3_type, class arg4_type, class mt_policy>
class _connection_base4
{
public:
virtual ~_connection_base4() { ; }
virtual has_slots<mt_policy>* getdest() const = 0;
virtual void emit(arg1_type, arg2_type, arg3_type, arg4_type) = 0;
virtual _connection_base4<arg1_type, arg2_type, arg3_type, arg4_type, mt_policy>* clone() = 0;
virtual _connection_base4<arg1_type, arg2_type, arg3_type, arg4_type, mt_policy>* duplicate(has_slots<mt_policy>* pnewdest) = 0;
};
template<class arg1_type, class arg2_type, class arg3_type, class arg4_type,
class arg5_type, class mt_policy>
class _connection_base5
{
public:
virtual ~_connection_base5() { ; }
virtual has_slots<mt_policy>* getdest() const = 0;
virtual void emit(arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type) = 0;
virtual _connection_base5<arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, mt_policy>* clone() = 0;
virtual _connection_base5<arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, mt_policy>* duplicate(has_slots<mt_policy>* pnewdest) = 0;
};
template<class arg1_type, class arg2_type, class arg3_type, class arg4_type,
class arg5_type, class arg6_type, class mt_policy>
class _connection_base6
{
public:
virtual ~_connection_base6() { ; }
virtual has_slots<mt_policy>* getdest() const = 0;
virtual void emit(arg1_type, arg2_type, arg3_type, arg4_type, arg5_type,
arg6_type) = 0;
virtual _connection_base6<arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, arg6_type, mt_policy>* clone() = 0;
virtual _connection_base6<arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, arg6_type, mt_policy>* duplicate(has_slots<mt_policy>* pnewdest) = 0;
};
template<class arg1_type, class arg2_type, class arg3_type, class arg4_type,
class arg5_type, class arg6_type, class arg7_type, class mt_policy>
class _connection_base7
{
public:
virtual ~_connection_base7() { ; }
virtual has_slots<mt_policy>* getdest() const = 0;
virtual void emit(arg1_type, arg2_type, arg3_type, arg4_type, arg5_type,
arg6_type, arg7_type) = 0;
virtual _connection_base7<arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, arg6_type, arg7_type, mt_policy>* clone() = 0;
virtual _connection_base7<arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, arg6_type, arg7_type, mt_policy>* duplicate(has_slots<mt_policy>* pnewdest) = 0;
};
template<class arg1_type, class arg2_type, class arg3_type, class arg4_type,
class arg5_type, class arg6_type, class arg7_type, class arg8_type, class mt_policy>
class _connection_base8
{
public:
virtual ~_connection_base8() { ; }
virtual has_slots<mt_policy>* getdest() const = 0;
virtual void emit(arg1_type, arg2_type, arg3_type, arg4_type, arg5_type,
arg6_type, arg7_type, arg8_type) = 0;
virtual _connection_base8<arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, arg6_type, arg7_type, arg8_type, mt_policy>* clone() = 0;
virtual _connection_base8<arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, arg6_type, arg7_type, arg8_type, mt_policy>* duplicate(has_slots<mt_policy>* pnewdest) = 0;
};
template<class mt_policy>
class _signal_base : public mt_policy
{
public:
virtual void slot_disconnect(has_slots<mt_policy>* pslot) = 0;
virtual void slot_duplicate(const has_slots<mt_policy>* poldslot, has_slots<mt_policy>* pnewslot) = 0;
};
template<class mt_policy = SIGSLOT_DEFAULT_MT_POLICY>
class has_slots : public mt_policy
{
private:
typedef typename std::set<_signal_base<mt_policy> *> sender_set;
typedef typename sender_set::const_iterator const_iterator;
public:
has_slots()
{
;
}
has_slots(const has_slots& hs)
: mt_policy(hs)
{
lock_block<mt_policy> lock(this);
const_iterator it = hs.m_senders.begin();
const_iterator itEnd = hs.m_senders.end();
while(it != itEnd)
{
(*it)->slot_duplicate(&hs, this);
m_senders.insert(*it);
++it;
}
}
void signal_connect(_signal_base<mt_policy>* sender)
{
lock_block<mt_policy> lock(this);
m_senders.insert(sender);
}
void signal_disconnect(_signal_base<mt_policy>* sender)
{
lock_block<mt_policy> lock(this);
m_senders.erase(sender);
}
virtual ~has_slots()
{
disconnect_all();
}
void disconnect_all()
{
lock_block<mt_policy> lock(this);
const_iterator it = m_senders.begin();
const_iterator itEnd = m_senders.end();
while(it != itEnd)
{
(*it)->slot_disconnect(this);
++it;
}
m_senders.erase(m_senders.begin(), m_senders.end());
}
private:
sender_set m_senders;
};
template<class mt_policy>
class _signal_base0 : public _signal_base<mt_policy>
{
public:
typedef typename std::list<_connection_base0<mt_policy> *> connections_list;
typedef typename connections_list::const_iterator const_iterator;
typedef typename connections_list::iterator iterator;
_signal_base0()
{
;
}
_signal_base0(const _signal_base0& s)
: _signal_base<mt_policy>(s)
{
lock_block<mt_policy> lock(this);
const_iterator it = s.m_connected_slots.begin();
const_iterator itEnd = s.m_connected_slots.end();
while(it != itEnd)
{
(*it)->getdest()->signal_connect(this);
m_connected_slots.push_back((*it)->clone());
++it;
}
}
~_signal_base0()
{
disconnect_all();
}
void disconnect_all()
{
lock_block<mt_policy> lock(this);
const_iterator it = m_connected_slots.begin();
const_iterator itEnd = m_connected_slots.end();
while(it != itEnd)
{
(*it)->getdest()->signal_disconnect(this);
delete *it;
++it;
}
m_connected_slots.erase(m_connected_slots.begin(), m_connected_slots.end());
}
void disconnect(has_slots<mt_policy>* pclass)
{
lock_block<mt_policy> lock(this);
iterator it = m_connected_slots.begin();
iterator itEnd = m_connected_slots.end();
while(it != itEnd)
{
if((*it)->getdest() == pclass)
{
delete *it;
m_connected_slots.erase(it);
pclass->signal_disconnect(this);
return;
}
++it;
}
}
bool connected()
{
return m_connected_slots.size() != 0;
}
void slot_disconnect(has_slots<mt_policy>* pslot)
{
lock_block<mt_policy> lock(this);
iterator it = m_connected_slots.begin();
iterator itEnd = m_connected_slots.end();
while(it != itEnd)
{
iterator itNext = it;
++itNext;
if((*it)->getdest() == pslot)
{
delete *it;
m_connected_slots.erase(it);
// delete *it;
}
it = itNext;
}
}
void slot_duplicate(const has_slots<mt_policy>* oldtarget, has_slots<mt_policy>* newtarget)
{
lock_block<mt_policy> lock(this);
iterator it = m_connected_slots.begin();
iterator itEnd = m_connected_slots.end();
while(it != itEnd)
{
if((*it)->getdest() == oldtarget)
{
m_connected_slots.push_back((*it)->duplicate(newtarget));
}
++it;
}
}
protected:
connections_list m_connected_slots;
};
template<class arg1_type, class mt_policy>
class _signal_base1 : public _signal_base<mt_policy>
{
public:
typedef typename std::list<_connection_base1<arg1_type, mt_policy> *> connections_list;
typedef typename connections_list::const_iterator const_iterator;
typedef typename connections_list::iterator iterator;
_signal_base1()
{
;
}
_signal_base1(const _signal_base1<arg1_type, mt_policy>& s)
: _signal_base<mt_policy>(s)
{
lock_block<mt_policy> lock(this);
const_iterator it = s.m_connected_slots.begin();
const_iterator itEnd = s.m_connected_slots.end();
while(it != itEnd)
{
(*it)->getdest()->signal_connect(this);
m_connected_slots.push_back((*it)->clone());
++it;
}
}
void slot_duplicate(const has_slots<mt_policy>* oldtarget, has_slots<mt_policy>* newtarget)
{
lock_block<mt_policy> lock(this);
iterator it = m_connected_slots.begin();
iterator itEnd = m_connected_slots.end();
while(it != itEnd)
{
if((*it)->getdest() == oldtarget)
{
m_connected_slots.push_back((*it)->duplicate(newtarget));
}
++it;
}
}
~_signal_base1()
{
disconnect_all();
}
void disconnect_all()
{
lock_block<mt_policy> lock(this);
const_iterator it = m_connected_slots.begin();
const_iterator itEnd = m_connected_slots.end();
while(it != itEnd)
{
(*it)->getdest()->signal_disconnect(this);
delete *it;
++it;
}
m_connected_slots.erase(m_connected_slots.begin(), m_connected_slots.end());
}
void disconnect(has_slots<mt_policy>* pclass)
{
lock_block<mt_policy> lock(this);
iterator it = m_connected_slots.begin();
iterator itEnd = m_connected_slots.end();
while(it != itEnd)
{
if((*it)->getdest() == pclass)
{
delete *it;
m_connected_slots.erase(it);
pclass->signal_disconnect(this);
return;
}
++it;
}
}
bool connected()
{
return m_connected_slots.size() != 0;
}
void slot_disconnect(has_slots<mt_policy>* pslot)
{
lock_block<mt_policy> lock(this);
iterator it = m_connected_slots.begin();
iterator itEnd = m_connected_slots.end();
while(it != itEnd)
{
iterator itNext = it;
++itNext;
if((*it)->getdest() == pslot)
{
delete *it;
m_connected_slots.erase(it);
// delete *it;
}
it = itNext;
}
}
protected:
connections_list m_connected_slots;
};
template<class arg1_type, class arg2_type, class mt_policy>
class _signal_base2 : public _signal_base<mt_policy>
{
public:
typedef typename std::list<_connection_base2<arg1_type, arg2_type, mt_policy> *>
connections_list;
typedef typename connections_list::const_iterator const_iterator;
typedef typename connections_list::iterator iterator;
_signal_base2()
{
;
}
_signal_base2(const _signal_base2<arg1_type, arg2_type, mt_policy>& s)
: _signal_base<mt_policy>(s)
{
lock_block<mt_policy> lock(this);
const_iterator it = s.m_connected_slots.begin();
const_iterator itEnd = s.m_connected_slots.end();
while(it != itEnd)
{
(*it)->getdest()->signal_connect(this);
m_connected_slots.push_back((*it)->clone());
++it;
}
}
void slot_duplicate(const has_slots<mt_policy>* oldtarget, has_slots<mt_policy>* newtarget)
{
lock_block<mt_policy> lock(this);
iterator it = m_connected_slots.begin();
iterator itEnd = m_connected_slots.end();
while(it != itEnd)
{
if((*it)->getdest() == oldtarget)
{
m_connected_slots.push_back((*it)->duplicate(newtarget));
}
++it;
}
}
~_signal_base2()
{
disconnect_all();
}
void disconnect_all()
{
lock_block<mt_policy> lock(this);
const_iterator it = m_connected_slots.begin();
const_iterator itEnd = m_connected_slots.end();
while(it != itEnd)
{
(*it)->getdest()->signal_disconnect(this);
delete *it;
++it;
}
m_connected_slots.erase(m_connected_slots.begin(), m_connected_slots.end());
}
void disconnect(has_slots<mt_policy>* pclass)
{
lock_block<mt_policy> lock(this);
iterator it = m_connected_slots.begin();
iterator itEnd = m_connected_slots.end();
while(it != itEnd)
{
if((*it)->getdest() == pclass)
{
delete *it;
m_connected_slots.erase(it);
pclass->signal_disconnect(this);
return;
}
++it;
}
}
bool connected()
{
return m_connected_slots.size() != 0;
}
void slot_disconnect(has_slots<mt_policy>* pslot)
{
lock_block<mt_policy> lock(this);
iterator it = m_connected_slots.begin();
iterator itEnd = m_connected_slots.end();
while(it != itEnd)
{
iterator itNext = it;
++itNext;
if((*it)->getdest() == pslot)
{
delete *it;
m_connected_slots.erase(it);
// delete *it;
}
it = itNext;
}
}
protected:
connections_list m_connected_slots;
};
template<class arg1_type, class arg2_type, class arg3_type, class mt_policy>
class _signal_base3 : public _signal_base<mt_policy>
{
public:
typedef std::list<_connection_base3<arg1_type, arg2_type, arg3_type, mt_policy> *>
connections_list;
typedef typename connections_list::const_iterator const_iterator;
typedef typename connections_list::iterator iterator;
_signal_base3()
{
;
}
_signal_base3(const _signal_base3<arg1_type, arg2_type, arg3_type, mt_policy>& s)
: _signal_base<mt_policy>(s)
{
lock_block<mt_policy> lock(this);
const_iterator it = s.m_connected_slots.begin();
const_iterator itEnd = s.m_connected_slots.end();
while(it != itEnd)
{
(*it)->getdest()->signal_connect(this);
m_connected_slots.push_back((*it)->clone());
++it;
}
}
void slot_duplicate(const has_slots<mt_policy>* oldtarget, has_slots<mt_policy>* newtarget)
{
lock_block<mt_policy> lock(this);
iterator it = m_connected_slots.begin();
iterator itEnd = m_connected_slots.end();
while(it != itEnd)
{
if((*it)->getdest() == oldtarget)
{
m_connected_slots.push_back((*it)->duplicate(newtarget));
}
++it;
}
}
~_signal_base3()
{
disconnect_all();
}
void disconnect_all()
{
lock_block<mt_policy> lock(this);
const_iterator it = m_connected_slots.begin();
const_iterator itEnd = m_connected_slots.end();
while(it != itEnd)
{
(*it)->getdest()->signal_disconnect(this);
delete *it;
++it;
}
m_connected_slots.erase(m_connected_slots.begin(), m_connected_slots.end());
}
void disconnect(has_slots<mt_policy>* pclass)
{
lock_block<mt_policy> lock(this);
iterator it = m_connected_slots.begin();
iterator itEnd = m_connected_slots.end();
while(it != itEnd)
{
if((*it)->getdest() == pclass)
{
delete *it;
m_connected_slots.erase(it);
pclass->signal_disconnect(this);
return;
}
++it;
}
}
bool connected()
{
return m_connected_slots.size() != 0;
}
void slot_disconnect(has_slots<mt_policy>* pslot)
{
lock_block<mt_policy> lock(this);
iterator it = m_connected_slots.begin();
iterator itEnd = m_connected_slots.end();
while(it != itEnd)
{
iterator itNext = it;
++itNext;
if((*it)->getdest() == pslot)
{
delete *it;
m_connected_slots.erase(it);
// delete *it;
}
it = itNext;
}
}
protected:
connections_list m_connected_slots;
};
template<class arg1_type, class arg2_type, class arg3_type, class arg4_type, class mt_policy>
class _signal_base4 : public _signal_base<mt_policy>
{
public:
typedef std::list<_connection_base4<arg1_type, arg2_type, arg3_type,
arg4_type, mt_policy> *> connections_list;
typedef typename connections_list::const_iterator const_iterator;
typedef typename connections_list::iterator iterator;
_signal_base4()
{
;
}
_signal_base4(const _signal_base4<arg1_type, arg2_type, arg3_type, arg4_type, mt_policy>& s)
: _signal_base<mt_policy>(s)
{
lock_block<mt_policy> lock(this);
const_iterator it = s.m_connected_slots.begin();
const_iterator itEnd = s.m_connected_slots.end();
while(it != itEnd)
{
(*it)->getdest()->signal_connect(this);
m_connected_slots.push_back((*it)->clone());
++it;
}
}
void slot_duplicate(const has_slots<mt_policy>* oldtarget, has_slots<mt_policy>* newtarget)
{
lock_block<mt_policy> lock(this);
iterator it = m_connected_slots.begin();
iterator itEnd = m_connected_slots.end();
while(it != itEnd)
{
if((*it)->getdest() == oldtarget)
{
m_connected_slots.push_back((*it)->duplicate(newtarget));
}
++it;
}
}
~_signal_base4()
{
disconnect_all();
}
void disconnect_all()
{
lock_block<mt_policy> lock(this);
const_iterator it = m_connected_slots.begin();
const_iterator itEnd = m_connected_slots.end();
while(it != itEnd)
{
(*it)->getdest()->signal_disconnect(this);
delete *it;
++it;
}
m_connected_slots.erase(m_connected_slots.begin(), m_connected_slots.end());
}
void disconnect(has_slots<mt_policy>* pclass)
{
lock_block<mt_policy> lock(this);
iterator it = m_connected_slots.begin();
iterator itEnd = m_connected_slots.end();
while(it != itEnd)
{
if((*it)->getdest() == pclass)
{
delete *it;
this->m_connected_slots.erase(it);
pclass->signal_disconnect(this);
return;
}
++it;
}
}
bool connected()
{
return m_connected_slots.size() != 0;
}
void slot_disconnect(has_slots<mt_policy>* pslot)
{
lock_block<mt_policy> lock(this);
iterator it = m_connected_slots.begin();
iterator itEnd = m_connected_slots.end();
while(it != itEnd)
{
iterator itNext = it;
++itNext;
if((*it)->getdest() == pslot)
{
delete *it;
m_connected_slots.erase(it);
// delete *it;
}
it = itNext;
}
}
protected:
connections_list m_connected_slots;
};
template<class arg1_type, class arg2_type, class arg3_type, class arg4_type,
class arg5_type, class mt_policy>
class _signal_base5 : public _signal_base<mt_policy>
{
public:
typedef std::list<_connection_base5<arg1_type, arg2_type, arg3_type,
arg4_type, arg5_type, mt_policy> *> connections_list;
typedef typename connections_list::const_iterator const_iterator;
typedef typename connections_list::iterator iterator;
_signal_base5()
{
;
}
_signal_base5(const _signal_base5<arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, mt_policy>& s)
: _signal_base<mt_policy>(s)
{
lock_block<mt_policy> lock(this);
const_iterator it = s.m_connected_slots.begin();
const_iterator itEnd = s.m_connected_slots.end();
while(it != itEnd)
{
(*it)->getdest()->signal_connect(this);
m_connected_slots.push_back((*it)->clone());
++it;
}
}
void slot_duplicate(const has_slots<mt_policy>* oldtarget, has_slots<mt_policy>* newtarget)
{
lock_block<mt_policy> lock(this);
iterator it = m_connected_slots.begin();
iterator itEnd = m_connected_slots.end();
while(it != itEnd)
{
if((*it)->getdest() == oldtarget)
{
m_connected_slots.push_back((*it)->duplicate(newtarget));
}
++it;
}
}
~_signal_base5()
{
disconnect_all();
}
void disconnect_all()
{
lock_block<mt_policy> lock(this);
const_iterator it = m_connected_slots.begin();
const_iterator itEnd = m_connected_slots.end();
while(it != itEnd)
{
(*it)->getdest()->signal_disconnect(this);
delete *it;
++it;
}
m_connected_slots.erase(m_connected_slots.begin(), m_connected_slots.end());
}
void disconnect(has_slots<mt_policy>* pclass)
{
lock_block<mt_policy> lock(this);
iterator it = m_connected_slots.begin();
iterator itEnd = m_connected_slots.end();
while(it != itEnd)
{
if((*it)->getdest() == pclass)
{
delete *it;
m_connected_slots.erase(it);
pclass->signal_disconnect(this);
return;
}
++it;
}
}
bool connected()
{
return m_connected_slots.size() != 0;
}
void slot_disconnect(has_slots<mt_policy>* pslot)
{
lock_block<mt_policy> lock(this);
iterator it = m_connected_slots.begin();
iterator itEnd = m_connected_slots.end();
while(it != itEnd)
{
iterator itNext = it;
++itNext;
if((*it)->getdest() == pslot)
{
delete *it;
m_connected_slots.erase(it);
// delete *it;
}
it = itNext;
}
}
protected:
connections_list m_connected_slots;
};
template<class arg1_type, class arg2_type, class arg3_type, class arg4_type,
class arg5_type, class arg6_type, class mt_policy>
class _signal_base6 : public _signal_base<mt_policy>
{
public:
typedef std::list<_connection_base6<arg1_type, arg2_type, arg3_type,
arg4_type, arg5_type, arg6_type, mt_policy> *> connections_list;
typedef typename connections_list::const_iterator const_iterator;
typedef typename connections_list::iterator iterator;
_signal_base6()
{
;
}
_signal_base6(const _signal_base6<arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, arg6_type, mt_policy>& s)
: _signal_base<mt_policy>(s)
{
lock_block<mt_policy> lock(this);
const_iterator it = s.m_connected_slots.begin();
const_iterator itEnd = s.m_connected_slots.end();
while(it != itEnd)
{
(*it)->getdest()->signal_connect(this);
m_connected_slots.push_back((*it)->clone());
++it;
}
}
void slot_duplicate(const has_slots<mt_policy>* oldtarget, has_slots<mt_policy>* newtarget)
{
lock_block<mt_policy> lock(this);
iterator it = m_connected_slots.begin();
iterator itEnd = m_connected_slots.end();
while(it != itEnd)
{
if((*it)->getdest() == oldtarget)
{
m_connected_slots.push_back((*it)->duplicate(newtarget));
}
++it;
}
}
~_signal_base6()
{
disconnect_all();
}
void disconnect_all()
{
lock_block<mt_policy> lock(this);
const_iterator it = m_connected_slots.begin();
const_iterator itEnd = m_connected_slots.end();
while(it != itEnd)
{
(*it)->getdest()->signal_disconnect(this);
delete *it;
++it;
}
m_connected_slots.erase(m_connected_slots.begin(), m_connected_slots.end());
}
void disconnect(has_slots<mt_policy>* pclass)
{
lock_block<mt_policy> lock(this);
iterator it = m_connected_slots.begin();
iterator itEnd = m_connected_slots.end();
while(it != itEnd)
{
if((*it)->getdest() == pclass)
{
delete *it;
m_connected_slots.erase(it);
pclass->signal_disconnect(this);
return;
}
++it;
}
}
bool connected()
{
return m_connected_slots.size() != 0;
}
void slot_disconnect(has_slots<mt_policy>* pslot)
{
lock_block<mt_policy> lock(this);
iterator it = m_connected_slots.begin();
iterator itEnd = m_connected_slots.end();
while(it != itEnd)
{
iterator itNext = it;
++itNext;
if((*it)->getdest() == pslot)
{
delete *it;
m_connected_slots.erase(it);
// delete *it;
}
it = itNext;
}
}
protected:
connections_list m_connected_slots;
};
template<class arg1_type, class arg2_type, class arg3_type, class arg4_type,
class arg5_type, class arg6_type, class arg7_type, class mt_policy>
class _signal_base7 : public _signal_base<mt_policy>
{
public:
typedef std::list<_connection_base7<arg1_type, arg2_type, arg3_type,
arg4_type, arg5_type, arg6_type, arg7_type, mt_policy> *> connections_list;
typedef typename connections_list::const_iterator const_iterator;
typedef typename connections_list::iterator iterator;
_signal_base7()
{
;
}
_signal_base7(const _signal_base7<arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, arg6_type, arg7_type, mt_policy>& s)
: _signal_base<mt_policy>(s)
{
lock_block<mt_policy> lock(this);
const_iterator it = s.m_connected_slots.begin();
const_iterator itEnd = s.m_connected_slots.end();
while(it != itEnd)
{
(*it)->getdest()->signal_connect(this);
m_connected_slots.push_back((*it)->clone());
++it;
}
}
void slot_duplicate(const has_slots<mt_policy>* oldtarget, has_slots<mt_policy>* newtarget)
{
lock_block<mt_policy> lock(this);
iterator it = m_connected_slots.begin();
iterator itEnd = m_connected_slots.end();
while(it != itEnd)
{
if((*it)->getdest() == oldtarget)
{
m_connected_slots.push_back((*it)->duplicate(newtarget));
}
++it;
}
}
~_signal_base7()
{
disconnect_all();
}
void disconnect_all()
{
lock_block<mt_policy> lock(this);
const_iterator it = m_connected_slots.begin();
const_iterator itEnd = m_connected_slots.end();
while(it != itEnd)
{
(*it)->getdest()->signal_disconnect(this);
delete *it;
++it;
}
m_connected_slots.erase(m_connected_slots.begin(), m_connected_slots.end());
}
void disconnect(has_slots<mt_policy>* pclass)
{
lock_block<mt_policy> lock(this);
iterator it = m_connected_slots.begin();
iterator itEnd = m_connected_slots.end();
while(it != itEnd)
{
if((*it)->getdest() == pclass)
{
delete *it;
m_connected_slots.erase(it);
pclass->signal_disconnect(this);
return;
}
++it;
}
}
bool connected()
{
return m_connected_slots.size() != 0;
}
void slot_disconnect(has_slots<mt_policy>* pslot)
{
lock_block<mt_policy> lock(this);
iterator it = m_connected_slots.begin();
iterator itEnd = m_connected_slots.end();
while(it != itEnd)
{
iterator itNext = it;
++itNext;
if((*it)->getdest() == pslot)
{
delete *it;
m_connected_slots.erase(it);
// delete *it;
}
it = itNext;
}
}
protected:
connections_list m_connected_slots;
};
template<class arg1_type, class arg2_type, class arg3_type, class arg4_type,
class arg5_type, class arg6_type, class arg7_type, class arg8_type, class mt_policy>
class _signal_base8 : public _signal_base<mt_policy>
{
public:
typedef std::list<_connection_base8<arg1_type, arg2_type, arg3_type,
arg4_type, arg5_type, arg6_type, arg7_type, arg8_type, mt_policy> *>
connections_list;
typedef typename connections_list::const_iterator const_iterator;
typedef typename connections_list::iterator iterator;
_signal_base8()
{
;
}
_signal_base8(const _signal_base8<arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, arg6_type, arg7_type, arg8_type, mt_policy>& s)
: _signal_base<mt_policy>(s)
{
lock_block<mt_policy> lock(this);
const_iterator it = s.m_connected_slots.begin();
const_iterator itEnd = s.m_connected_slots.end();
while(it != itEnd)
{
(*it)->getdest()->signal_connect(this);
m_connected_slots.push_back((*it)->clone());
++it;
}
}
void slot_duplicate(const has_slots<mt_policy>* oldtarget, has_slots<mt_policy>* newtarget)
{
lock_block<mt_policy> lock(this);
iterator it = m_connected_slots.begin();
iterator itEnd = m_connected_slots.end();
while(it != itEnd)
{
if((*it)->getdest() == oldtarget)
{
m_connected_slots.push_back((*it)->duplicate(newtarget));
}
++it;
}
}
~_signal_base8()
{
disconnect_all();
}
void disconnect_all()
{
lock_block<mt_policy> lock(this);
const_iterator it = m_connected_slots.begin();
const_iterator itEnd = m_connected_slots.end();
while(it != itEnd)
{
(*it)->getdest()->signal_disconnect(this);
delete *it;
++it;
}
m_connected_slots.erase(m_connected_slots.begin(), m_connected_slots.end());
}
void disconnect(has_slots<mt_policy>* pclass)
{
lock_block<mt_policy> lock(this);
iterator it = m_connected_slots.begin();
iterator itEnd = m_connected_slots.end();
while(it != itEnd)
{
if((*it)->getdest() == pclass)
{
delete *it;
m_connected_slots.erase(it);
pclass->signal_disconnect(this);
return;
}
++it;
}
}
bool connected()
{
return m_connected_slots.size() != 0;
}
void slot_disconnect(has_slots<mt_policy>* pslot)
{
lock_block<mt_policy> lock(this);
iterator it = m_connected_slots.begin();
iterator itEnd = m_connected_slots.end();
while(it != itEnd)
{
iterator itNext = it;
++itNext;
if((*it)->getdest() == pslot)
{
delete *it;
m_connected_slots.erase(it);
// delete *it;
}
it = itNext;
}
}
protected:
connections_list m_connected_slots;
};
template<class dest_type, class mt_policy>
class _connection0 : public _connection_base0<mt_policy>
{
public:
_connection0()
{
this->pobject = NULL;
this->pmemfun = NULL;
}
_connection0(dest_type* pobject, void (dest_type::*pmemfun)())
{
m_pobject = pobject;
m_pmemfun = pmemfun;
}
virtual ~_connection0()
{
;
}
virtual _connection_base0<mt_policy>* clone()
{
return new _connection0<dest_type, mt_policy>(*this);
}
virtual _connection_base0<mt_policy>* duplicate(has_slots<mt_policy>* pnewdest)
{
return new _connection0<dest_type, mt_policy>((dest_type *)pnewdest, m_pmemfun);
}
virtual void emit()
{
(m_pobject->*m_pmemfun)();
}
virtual has_slots<mt_policy>* getdest() const
{
return m_pobject;
}
private:
dest_type* m_pobject;
void (dest_type::* m_pmemfun)();
};
template<class dest_type, class arg1_type, class mt_policy>
class _connection1 : public _connection_base1<arg1_type, mt_policy>
{
public:
_connection1()
{
this->pobject = NULL;
this->pmemfun = NULL;
}
_connection1(dest_type* pobject, void (dest_type::*pmemfun)(arg1_type))
{
m_pobject = pobject;
m_pmemfun = pmemfun;
}
virtual ~_connection1()
{
;
}
virtual _connection_base1<arg1_type, mt_policy>* clone()
{
return new _connection1<dest_type, arg1_type, mt_policy>(*this);
}
virtual _connection_base1<arg1_type, mt_policy>* duplicate(has_slots<mt_policy>* pnewdest)
{
return new _connection1<dest_type, arg1_type, mt_policy>((dest_type *)pnewdest, m_pmemfun);
}
virtual void emit(arg1_type a1)
{
(m_pobject->*m_pmemfun)(a1);
}
virtual has_slots<mt_policy>* getdest() const
{
return m_pobject;
}
private:
dest_type* m_pobject;
void (dest_type::* m_pmemfun)(arg1_type);
};
template<class dest_type, class arg1_type, class arg2_type, class mt_policy>
class _connection2 : public _connection_base2<arg1_type, arg2_type, mt_policy>
{
public:
_connection2()
{
this->pobject = NULL;
this->pmemfun = NULL;
}
_connection2(dest_type* pobject, void (dest_type::*pmemfun)(arg1_type,
arg2_type))
{
m_pobject = pobject;
m_pmemfun = pmemfun;
}
virtual ~_connection2()
{
;
}
virtual _connection_base2<arg1_type, arg2_type, mt_policy>* clone()
{
return new _connection2<dest_type, arg1_type, arg2_type, mt_policy>(*this);
}
virtual _connection_base2<arg1_type, arg2_type, mt_policy>* duplicate(has_slots<mt_policy>* pnewdest)
{
return new _connection2<dest_type, arg1_type, arg2_type, mt_policy>((dest_type *)pnewdest, m_pmemfun);
}
virtual void emit(arg1_type a1, arg2_type a2)
{
(m_pobject->*m_pmemfun)(a1, a2);
}
virtual has_slots<mt_policy>* getdest() const
{
return m_pobject;
}
private:
dest_type* m_pobject;
void (dest_type::* m_pmemfun)(arg1_type, arg2_type);
};
template<class dest_type, class arg1_type, class arg2_type, class arg3_type, class mt_policy>
class _connection3 : public _connection_base3<arg1_type, arg2_type, arg3_type, mt_policy>
{
public:
_connection3()
{
this->pobject = NULL;
this->pmemfun = NULL;
}
_connection3(dest_type* pobject, void (dest_type::*pmemfun)(arg1_type,
arg2_type, arg3_type))
{
m_pobject = pobject;
m_pmemfun = pmemfun;
}
virtual ~_connection3()
{
;
}
virtual _connection_base3<arg1_type, arg2_type, arg3_type, mt_policy>* clone()
{
return new _connection3<dest_type, arg1_type, arg2_type, arg3_type, mt_policy>(*this);
}
virtual _connection_base3<arg1_type, arg2_type, arg3_type, mt_policy>* duplicate(has_slots<mt_policy>* pnewdest)
{
return new _connection3<dest_type, arg1_type, arg2_type, arg3_type, mt_policy>((dest_type *)pnewdest, m_pmemfun);
}
virtual void emit(arg1_type a1, arg2_type a2, arg3_type a3)
{
(m_pobject->*m_pmemfun)(a1, a2, a3);
}
virtual has_slots<mt_policy>* getdest() const
{
return m_pobject;
}
private:
dest_type* m_pobject;
void (dest_type::* m_pmemfun)(arg1_type, arg2_type, arg3_type);
};
template<class dest_type, class arg1_type, class arg2_type, class arg3_type,
class arg4_type, class mt_policy>
class _connection4 : public _connection_base4<arg1_type, arg2_type,
arg3_type, arg4_type, mt_policy>
{
public:
_connection4()
{
this->pobject = NULL;
this->pmemfun = NULL;
}
_connection4(dest_type* pobject, void (dest_type::*pmemfun)(arg1_type,
arg2_type, arg3_type, arg4_type))
{
m_pobject = pobject;
m_pmemfun = pmemfun;
}
virtual ~_connection4()
{
;
}
virtual _connection_base4<arg1_type, arg2_type, arg3_type, arg4_type, mt_policy>* clone()
{
return new _connection4<dest_type, arg1_type, arg2_type, arg3_type, arg4_type, mt_policy>(*this);
}
virtual _connection_base4<arg1_type, arg2_type, arg3_type, arg4_type, mt_policy>* duplicate(has_slots<mt_policy>* pnewdest)
{
return new _connection4<dest_type, arg1_type, arg2_type, arg3_type, arg4_type, mt_policy>((dest_type *)pnewdest, m_pmemfun);
}
virtual void emit(arg1_type a1, arg2_type a2, arg3_type a3,
arg4_type a4)
{
(m_pobject->*m_pmemfun)(a1, a2, a3, a4);
}
virtual has_slots<mt_policy>* getdest() const
{
return m_pobject;
}
private:
dest_type* m_pobject;
void (dest_type::* m_pmemfun)(arg1_type, arg2_type, arg3_type,
arg4_type);
};
template<class dest_type, class arg1_type, class arg2_type, class arg3_type,
class arg4_type, class arg5_type, class mt_policy>
class _connection5 : public _connection_base5<arg1_type, arg2_type,
arg3_type, arg4_type, arg5_type, mt_policy>
{
public:
_connection5()
{
this->pobject = NULL;
this->pmemfun = NULL;
}
_connection5(dest_type* pobject, void (dest_type::*pmemfun)(arg1_type,
arg2_type, arg3_type, arg4_type, arg5_type))
{
m_pobject = pobject;
m_pmemfun = pmemfun;
}
virtual ~_connection5()
{
;
}
virtual _connection_base5<arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, mt_policy>* clone()
{
return new _connection5<dest_type, arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, mt_policy>(*this);
}
virtual _connection_base5<arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, mt_policy>* duplicate(has_slots<mt_policy>* pnewdest)
{
return new _connection5<dest_type, arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, mt_policy>((dest_type *)pnewdest, m_pmemfun);
}
virtual void emit(arg1_type a1, arg2_type a2, arg3_type a3, arg4_type a4,
arg5_type a5)
{
(m_pobject->*m_pmemfun)(a1, a2, a3, a4, a5);
}
virtual has_slots<mt_policy>* getdest() const
{
return m_pobject;
}
private:
dest_type* m_pobject;
void (dest_type::* m_pmemfun)(arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type);
};
template<class dest_type, class arg1_type, class arg2_type, class arg3_type,
class arg4_type, class arg5_type, class arg6_type, class mt_policy>
class _connection6 : public _connection_base6<arg1_type, arg2_type,
arg3_type, arg4_type, arg5_type, arg6_type, mt_policy>
{
public:
_connection6()
{
this->pobject = NULL;
this->pmemfun = NULL;
}
_connection6(dest_type* pobject, void (dest_type::*pmemfun)(arg1_type,
arg2_type, arg3_type, arg4_type, arg5_type, arg6_type))
{
m_pobject = pobject;
m_pmemfun = pmemfun;
}
virtual ~_connection6()
{
;
}
virtual _connection_base6<arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, arg6_type, mt_policy>* clone()
{
return new _connection6<dest_type, arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, arg6_type, mt_policy>(*this);
}
virtual _connection_base6<arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, arg6_type, mt_policy>* duplicate(has_slots<mt_policy>* pnewdest)
{
return new _connection6<dest_type, arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, arg6_type, mt_policy>((dest_type *)pnewdest, m_pmemfun);
}
virtual void emit(arg1_type a1, arg2_type a2, arg3_type a3, arg4_type a4,
arg5_type a5, arg6_type a6)
{
(m_pobject->*m_pmemfun)(a1, a2, a3, a4, a5, a6);
}
virtual has_slots<mt_policy>* getdest() const
{
return m_pobject;
}
private:
dest_type* m_pobject;
void (dest_type::* m_pmemfun)(arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, arg6_type);
};
template<class dest_type, class arg1_type, class arg2_type, class arg3_type,
class arg4_type, class arg5_type, class arg6_type, class arg7_type, class mt_policy>
class _connection7 : public _connection_base7<arg1_type, arg2_type,
arg3_type, arg4_type, arg5_type, arg6_type, arg7_type, mt_policy>
{
public:
_connection7()
{
this->pobject = NULL;
this->pmemfun = NULL;
}
_connection7(dest_type* pobject, void (dest_type::*pmemfun)(arg1_type,
arg2_type, arg3_type, arg4_type, arg5_type, arg6_type, arg7_type))
{
m_pobject = pobject;
m_pmemfun = pmemfun;
}
virtual ~_connection7()
{
;
}
virtual _connection_base7<arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, arg6_type, arg7_type, mt_policy>* clone()
{
return new _connection7<dest_type, arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, arg6_type, arg7_type, mt_policy>(*this);
}
virtual _connection_base7<arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, arg6_type, arg7_type, mt_policy>* duplicate(has_slots<mt_policy>* pnewdest)
{
return new _connection7<dest_type, arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, arg6_type, arg7_type, mt_policy>((dest_type *)pnewdest, m_pmemfun);
}
virtual void emit(arg1_type a1, arg2_type a2, arg3_type a3, arg4_type a4,
arg5_type a5, arg6_type a6, arg7_type a7)
{
(m_pobject->*m_pmemfun)(a1, a2, a3, a4, a5, a6, a7);
}
virtual has_slots<mt_policy>* getdest() const
{
return m_pobject;
}
private:
dest_type* m_pobject;
void (dest_type::* m_pmemfun)(arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, arg6_type, arg7_type);
};
template<class dest_type, class arg1_type, class arg2_type, class arg3_type,
class arg4_type, class arg5_type, class arg6_type, class arg7_type,
class arg8_type, class mt_policy>
class _connection8 : public _connection_base8<arg1_type, arg2_type,
arg3_type, arg4_type, arg5_type, arg6_type, arg7_type, arg8_type, mt_policy>
{
public:
_connection8()
{
this->pobject = NULL;
this->pmemfun = NULL;
}
_connection8(dest_type* pobject, void (dest_type::*pmemfun)(arg1_type,
arg2_type, arg3_type, arg4_type, arg5_type, arg6_type,
arg7_type, arg8_type))
{
m_pobject = pobject;
m_pmemfun = pmemfun;
}
virtual ~_connection8()
{
;
}
virtual _connection_base8<arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, arg6_type, arg7_type, arg8_type, mt_policy>* clone()
{
return new _connection8<dest_type, arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, arg6_type, arg7_type, arg8_type, mt_policy>(*this);
}
virtual _connection_base8<arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, arg6_type, arg7_type, arg8_type, mt_policy>* duplicate(has_slots<mt_policy>* pnewdest)
{
return new _connection8<dest_type, arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, arg6_type, arg7_type, arg8_type, mt_policy>((dest_type *)pnewdest, m_pmemfun);
}
virtual void emit(arg1_type a1, arg2_type a2, arg3_type a3, arg4_type a4,
arg5_type a5, arg6_type a6, arg7_type a7, arg8_type a8)
{
(m_pobject->*m_pmemfun)(a1, a2, a3, a4, a5, a6, a7, a8);
}
virtual has_slots<mt_policy>* getdest() const
{
return m_pobject;
}
private:
dest_type* m_pobject;
void (dest_type::* m_pmemfun)(arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, arg6_type, arg7_type, arg8_type);
};
template<class mt_policy = SIGSLOT_DEFAULT_MT_POLICY>
class signal0 : public _signal_base0<mt_policy>
{
public:
typedef typename _signal_base0<mt_policy>::connections_list::const_iterator const_iterator;
signal0()
{
;
}
signal0(const signal0<mt_policy>& s)
: _signal_base0<mt_policy>(s)
{
;
}
virtual ~signal0()
{
;
}
template<class desttype>
void connect(desttype* pclass, void (desttype::*pmemfun)())
{
lock_block<mt_policy> lock(this);
_connection0<desttype, mt_policy>* conn =
new _connection0<desttype, mt_policy>(pclass, pmemfun);
this->m_connected_slots.push_back(conn);
pclass->signal_connect(this);
}
void emit()
{
lock_block<mt_policy> lock(this);
const_iterator itNext, it = this->m_connected_slots.begin();
const_iterator itEnd = this->m_connected_slots.end();
while(it != itEnd)
{
itNext = it;
++itNext;
(*it)->emit();
it = itNext;
}
}
void operator()()
{
lock_block<mt_policy> lock(this);
const_iterator itNext, it = this->m_connected_slots.begin();
const_iterator itEnd = this->m_connected_slots.end();
while(it != itEnd)
{
itNext = it;
++itNext;
(*it)->emit();
it = itNext;
}
}
};
template<class arg1_type, class mt_policy = SIGSLOT_DEFAULT_MT_POLICY>
class signal1 : public _signal_base1<arg1_type, mt_policy>
{
public:
typedef typename _signal_base1<arg1_type, mt_policy>::connections_list::const_iterator const_iterator;
signal1()
{
;
}
signal1(const signal1<arg1_type, mt_policy>& s)
: _signal_base1<arg1_type, mt_policy>(s)
{
;
}
virtual ~signal1()
{
;
}
template<class desttype>
void connect(desttype* pclass, void (desttype::*pmemfun)(arg1_type))
{
lock_block<mt_policy> lock(this);
_connection1<desttype, arg1_type, mt_policy>* conn =
new _connection1<desttype, arg1_type, mt_policy>(pclass, pmemfun);
this->m_connected_slots.push_back(conn);
pclass->signal_connect(this);
}
void emit(arg1_type a1)
{
lock_block<mt_policy> lock(this);
const_iterator itNext, it = this->m_connected_slots.begin();
const_iterator itEnd = this->m_connected_slots.end();
while(it != itEnd)
{
itNext = it;
++itNext;
(*it)->emit(a1);
it = itNext;
}
}
void operator()(arg1_type a1)
{
lock_block<mt_policy> lock(this);
const_iterator itNext, it = this->m_connected_slots.begin();
const_iterator itEnd = this->m_connected_slots.end();
while(it != itEnd)
{
itNext = it;
++itNext;
(*it)->emit(a1);
it = itNext;
}
}
};
template<class arg1_type, typename arg2_type, typename mt_policy = SIGSLOT_DEFAULT_MT_POLICY>
class signal2 : public _signal_base2<arg1_type, arg2_type, mt_policy>
{
public:
typedef typename _signal_base2<arg1_type, arg2_type, mt_policy>::connections_list::const_iterator const_iterator;
signal2()
{
;
}
signal2(const signal2<arg1_type, arg2_type, mt_policy>& s)
: _signal_base2<arg1_type, arg2_type, mt_policy>(s)
{
;
}
virtual ~signal2()
{
;
}
template<class desttype>
void connect(desttype* pclass, void (desttype::*pmemfun)(arg1_type,
arg2_type))
{
lock_block<mt_policy> lock(this);
_connection2<desttype, arg1_type, arg2_type, mt_policy>* conn = new
_connection2<desttype, arg1_type, arg2_type, mt_policy>(pclass, pmemfun);
this->m_connected_slots.push_back(conn);
pclass->signal_connect(this);
}
void emit(arg1_type a1, arg2_type a2)
{
lock_block<mt_policy> lock(this);
const_iterator itNext, it = this->m_connected_slots.begin();
const_iterator itEnd = this->m_connected_slots.end();
while(it != itEnd)
{
itNext = it;
++itNext;
(*it)->emit(a1, a2);
it = itNext;
}
}
void operator()(arg1_type a1, arg2_type a2)
{
lock_block<mt_policy> lock(this);
const_iterator itNext, it = this->m_connected_slots.begin();
const_iterator itEnd = this->m_connected_slots.end();
while(it != itEnd)
{
itNext = it;
++itNext;
(*it)->emit(a1, a2);
it = itNext;
}
}
};
template<class arg1_type, typename arg2_type, typename arg3_type, typename mt_policy = SIGSLOT_DEFAULT_MT_POLICY>
class signal3 : public _signal_base3<arg1_type, arg2_type, arg3_type, mt_policy>
{
public:
typedef typename _signal_base3<arg1_type, arg2_type, arg3_type, mt_policy>::connections_list::const_iterator const_iterator;
signal3()
{
;
}
signal3(const signal3<arg1_type, arg2_type, arg3_type, mt_policy>& s)
: _signal_base3<arg1_type, arg2_type, arg3_type, mt_policy>(s)
{
;
}
virtual ~signal3()
{
;
}
template<class desttype>
void connect(desttype* pclass, void (desttype::*pmemfun)(arg1_type,
arg2_type, arg3_type))
{
lock_block<mt_policy> lock(this);
_connection3<desttype, arg1_type, arg2_type, arg3_type, mt_policy>* conn =
new _connection3<desttype, arg1_type, arg2_type, arg3_type, mt_policy>(pclass,
pmemfun);
this->m_connected_slots.push_back(conn);
pclass->signal_connect(this);
}
void emit(arg1_type a1, arg2_type a2, arg3_type a3)
{
lock_block<mt_policy> lock(this);
const_iterator itNext, it = this->m_connected_slots.begin();
const_iterator itEnd = this->m_connected_slots.end();
while(it != itEnd)
{
itNext = it;
++itNext;
(*it)->emit(a1, a2, a3);
it = itNext;
}
}
void operator()(arg1_type a1, arg2_type a2, arg3_type a3)
{
lock_block<mt_policy> lock(this);
const_iterator itNext, it = this->m_connected_slots.begin();
const_iterator itEnd = this->m_connected_slots.end();
while(it != itEnd)
{
itNext = it;
++itNext;
(*it)->emit(a1, a2, a3);
it = itNext;
}
}
};
template<class arg1_type, class arg2_type, class arg3_type, class arg4_type, class mt_policy = SIGSLOT_DEFAULT_MT_POLICY>
class signal4 : public _signal_base4<arg1_type, arg2_type, arg3_type,
arg4_type, mt_policy>
{
public:
typedef typename _signal_base4<arg1_type, arg2_type, arg3_type, arg4_type, mt_policy>::connections_list::const_iterator const_iterator;
signal4()
{
;
}
signal4(const signal4<arg1_type, arg2_type, arg3_type, arg4_type, mt_policy>& s)
: _signal_base4<arg1_type, arg2_type, arg3_type, arg4_type, mt_policy>(s)
{
;
}
virtual ~signal4()
{
;
}
template<class desttype>
void connect(desttype* pclass, void (desttype::*pmemfun)(arg1_type,
arg2_type, arg3_type, arg4_type))
{
lock_block<mt_policy> lock(this);
_connection4<desttype, arg1_type, arg2_type, arg3_type, arg4_type, mt_policy>*
conn = new _connection4<desttype, arg1_type, arg2_type, arg3_type,
arg4_type, mt_policy>(pclass, pmemfun);
this->m_connected_slots.push_back(conn);
pclass->signal_connect(this);
}
void emit(arg1_type a1, arg2_type a2, arg3_type a3, arg4_type a4)
{
lock_block<mt_policy> lock(this);
const_iterator itNext, it = this->m_connected_slots.begin();
const_iterator itEnd = this->m_connected_slots.end();
while(it != itEnd)
{
itNext = it;
++itNext;
(*it)->emit(a1, a2, a3, a4);
it = itNext;
}
}
void operator()(arg1_type a1, arg2_type a2, arg3_type a3, arg4_type a4)
{
lock_block<mt_policy> lock(this);
const_iterator itNext, it = this->m_connected_slots.begin();
const_iterator itEnd = this->m_connected_slots.end();
while(it != itEnd)
{
itNext = it;
++itNext;
(*it)->emit(a1, a2, a3, a4);
it = itNext;
}
}
};
template<class arg1_type, class arg2_type, class arg3_type, class arg4_type,
class arg5_type, class mt_policy = SIGSLOT_DEFAULT_MT_POLICY>
class signal5 : public _signal_base5<arg1_type, arg2_type, arg3_type,
arg4_type, arg5_type, mt_policy>
{
public:
typedef typename _signal_base5<arg1_type, arg2_type, arg3_type, arg4_type, arg5_type, mt_policy>::connections_list::const_iterator const_iterator;
signal5()
{
;
}
signal5(const signal5<arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, mt_policy>& s)
: _signal_base5<arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, mt_policy>(s)
{
;
}
virtual ~signal5()
{
;
}
template<class desttype>
void connect(desttype* pclass, void (desttype::*pmemfun)(arg1_type,
arg2_type, arg3_type, arg4_type, arg5_type))
{
lock_block<mt_policy> lock(this);
_connection5<desttype, arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, mt_policy>* conn = new _connection5<desttype, arg1_type, arg2_type,
arg3_type, arg4_type, arg5_type, mt_policy>(pclass, pmemfun);
this->m_connected_slots.push_back(conn);
pclass->signal_connect(this);
}
void emit(arg1_type a1, arg2_type a2, arg3_type a3, arg4_type a4,
arg5_type a5)
{
lock_block<mt_policy> lock(this);
const_iterator itNext, it = this->m_connected_slots.begin();
const_iterator itEnd = this->m_connected_slots.end();
while(it != itEnd)
{
itNext = it;
++itNext;
(*it)->emit(a1, a2, a3, a4, a5);
it = itNext;
}
}
void operator()(arg1_type a1, arg2_type a2, arg3_type a3, arg4_type a4,
arg5_type a5)
{
lock_block<mt_policy> lock(this);
const_iterator itNext, it = this->m_connected_slots.begin();
const_iterator itEnd = this->m_connected_slots.end();
while(it != itEnd)
{
itNext = it;
++itNext;
(*it)->emit(a1, a2, a3, a4, a5);
it = itNext;
}
}
};
template<class arg1_type, class arg2_type, class arg3_type, class arg4_type,
class arg5_type, class arg6_type, class mt_policy = SIGSLOT_DEFAULT_MT_POLICY>
class signal6 : public _signal_base6<arg1_type, arg2_type, arg3_type,
arg4_type, arg5_type, arg6_type, mt_policy>
{
public:
typedef typename _signal_base6<arg1_type, arg2_type, arg3_type,
arg4_type, arg5_type, arg6_type, mt_policy>::connections_list::const_iterator const_iterator;
signal6()
{
;
}
signal6(const signal6<arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, arg6_type, mt_policy>& s)
: _signal_base6<arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, arg6_type, mt_policy>(s)
{
;
}
virtual ~signal6()
{
;
}
template<class desttype>
void connect(desttype* pclass, void (desttype::*pmemfun)(arg1_type,
arg2_type, arg3_type, arg4_type, arg5_type, arg6_type))
{
lock_block<mt_policy> lock(this);
_connection6<desttype, arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, arg6_type, mt_policy>* conn =
new _connection6<desttype, arg1_type, arg2_type, arg3_type,
arg4_type, arg5_type, arg6_type, mt_policy>(pclass, pmemfun);
this->m_connected_slots.push_back(conn);
pclass->signal_connect(this);
}
void emit(arg1_type a1, arg2_type a2, arg3_type a3, arg4_type a4,
arg5_type a5, arg6_type a6)
{
lock_block<mt_policy> lock(this);
const_iterator itNext, it = this->m_connected_slots.begin();
const_iterator itEnd = this->m_connected_slots.end();
while(it != itEnd)
{
itNext = it;
++itNext;
(*it)->emit(a1, a2, a3, a4, a5, a6);
it = itNext;
}
}
void operator()(arg1_type a1, arg2_type a2, arg3_type a3, arg4_type a4,
arg5_type a5, arg6_type a6)
{
lock_block<mt_policy> lock(this);
const_iterator itNext, it = this->m_connected_slots.begin();
const_iterator itEnd = this->m_connected_slots.end();
while(it != itEnd)
{
itNext = it;
++itNext;
(*it)->emit(a1, a2, a3, a4, a5, a6);
it = itNext;
}
}
};
template<class arg1_type, class arg2_type, class arg3_type, class arg4_type,
class arg5_type, class arg6_type, class arg7_type, class mt_policy = SIGSLOT_DEFAULT_MT_POLICY>
class signal7 : public _signal_base7<arg1_type, arg2_type, arg3_type,
arg4_type, arg5_type, arg6_type, arg7_type, mt_policy>
{
public:
typedef typename _signal_base7<arg1_type, arg2_type, arg3_type,
arg4_type, arg5_type, arg6_type, arg7_type, mt_policy>::connections_list::const_iterator const_iterator;
signal7()
{
;
}
signal7(const signal7<arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, arg6_type, arg7_type, mt_policy>& s)
: _signal_base7<arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, arg6_type, arg7_type, mt_policy>(s)
{
;
}
virtual ~signal7()
{
;
}
template<class desttype>
void connect(desttype* pclass, void (desttype::*pmemfun)(arg1_type,
arg2_type, arg3_type, arg4_type, arg5_type, arg6_type,
arg7_type))
{
lock_block<mt_policy> lock(this);
_connection7<desttype, arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, arg6_type, arg7_type, mt_policy>* conn =
new _connection7<desttype, arg1_type, arg2_type, arg3_type,
arg4_type, arg5_type, arg6_type, arg7_type, mt_policy>(pclass, pmemfun);
this->m_connected_slots.push_back(conn);
pclass->signal_connect(this);
}
void emit(arg1_type a1, arg2_type a2, arg3_type a3, arg4_type a4,
arg5_type a5, arg6_type a6, arg7_type a7)
{
lock_block<mt_policy> lock(this);
const_iterator itNext, it = this->m_connected_slots.begin();
const_iterator itEnd = this->m_connected_slots.end();
while(it != itEnd)
{
itNext = it;
++itNext;
(*it)->emit(a1, a2, a3, a4, a5, a6, a7);
it = itNext;
}
}
void operator()(arg1_type a1, arg2_type a2, arg3_type a3, arg4_type a4,
arg5_type a5, arg6_type a6, arg7_type a7)
{
lock_block<mt_policy> lock(this);
const_iterator itNext, it = this->m_connected_slots.begin();
const_iterator itEnd = this->m_connected_slots.end();
while(it != itEnd)
{
itNext = it;
++itNext;
(*it)->emit(a1, a2, a3, a4, a5, a6, a7);
it = itNext;
}
}
};
template<class arg1_type, class arg2_type, class arg3_type, class arg4_type,
class arg5_type, class arg6_type, class arg7_type, class arg8_type, class mt_policy = SIGSLOT_DEFAULT_MT_POLICY>
class signal8 : public _signal_base8<arg1_type, arg2_type, arg3_type,
arg4_type, arg5_type, arg6_type, arg7_type, arg8_type, mt_policy>
{
public:
typedef typename _signal_base8<arg1_type, arg2_type, arg3_type,
arg4_type, arg5_type, arg6_type, arg7_type, arg8_type, mt_policy>::connections_list::const_iterator const_iterator;
signal8()
{
;
}
signal8(const signal8<arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, arg6_type, arg7_type, arg8_type, mt_policy>& s)
: _signal_base8<arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, arg6_type, arg7_type, arg8_type, mt_policy>(s)
{
;
}
virtual ~signal8()
{
;
}
template<class desttype>
void connect(desttype* pclass, void (desttype::*pmemfun)(arg1_type,
arg2_type, arg3_type, arg4_type, arg5_type, arg6_type,
arg7_type, arg8_type))
{
lock_block<mt_policy> lock(this);
_connection8<desttype, arg1_type, arg2_type, arg3_type, arg4_type,
arg5_type, arg6_type, arg7_type, arg8_type, mt_policy>* conn =
new _connection8<desttype, arg1_type, arg2_type, arg3_type,
arg4_type, arg5_type, arg6_type, arg7_type,
arg8_type, mt_policy>(pclass, pmemfun);
this->m_connected_slots.push_back(conn);
pclass->signal_connect(this);
}
void emit(arg1_type a1, arg2_type a2, arg3_type a3, arg4_type a4,
arg5_type a5, arg6_type a6, arg7_type a7, arg8_type a8)
{
lock_block<mt_policy> lock(this);
const_iterator itNext, it = this->m_connected_slots.begin();
const_iterator itEnd = this->m_connected_slots.end();
while(it != itEnd)
{
itNext = it;
++itNext;
(*it)->emit(a1, a2, a3, a4, a5, a6, a7, a8);
it = itNext;
}
}
void operator()(arg1_type a1, arg2_type a2, arg3_type a3, arg4_type a4,
arg5_type a5, arg6_type a6, arg7_type a7, arg8_type a8)
{
lock_block<mt_policy> lock(this);
const_iterator itNext, it = this->m_connected_slots.begin();
const_iterator itEnd = this->m_connected_slots.end();
while(it != itEnd)
{
itNext = it;
++itNext;
(*it)->emit(a1, a2, a3, a4, a5, a6, a7, a8);
it = itNext;
}
}
};
}; // namespace sigslot
#endif // SIGSLOT_H__
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