* Copyright 2002, The libsigc++ Development Team
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2.1 of the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*
*/
#ifndef _SIGC_SIGNAL_BASE_H_
#define _SIGC_SIGNAL_BASE_H_
#include <list>
#include <sigc++config.h>
#include <sigc++/type_traits.h>
#include <sigc++/trackable.h>
#include <sigc++/functors/slot.h>
#include <sigc++/functors/mem_fun.h>
namespace sigc
{
namespace internal
{
* signal_impl manages a list of slots. When a slot becomes
* invalid (because some referred object dies), notify() is executed.
* notify() either calls sweep() directly or defers the execution of
* sweep() when the signal is being emitted. sweep() removes all
* invalid slot from the list.
*/
struct SIGC_API signal_impl
{
typedef size_t size_type;
typedef std::list<slot_base> slot_list;
typedef slot_list::iterator iterator_type;
typedef slot_list::const_iterator const_iterator_type;
signal_impl();
#ifdef SIGC_NEW_DELETE_IN_LIBRARY_ONLY
void* operator new(size_t size_);
void operator delete(void* p);
#endif
inline void reference()
{ ++ref_count_; }
inline void reference_exec()
{ ++ref_count_; ++exec_count_; }
* The object is deleted when the reference counter reaches zero.
*/
inline void unreference()
{ if (!(--ref_count_)) delete this; }
* Invokes sweep() if the execution counter reaches zero and the
* removal of one or more slots has been deferred.
*/
inline void unreference_exec()
{
if (!(--ref_count_)) delete this;
else if (!(--exec_count_) && deferred_) sweep();
}
* @return @p true if the list of slots is empty.
*/
inline bool empty() const
{ return slots_.empty(); }
void clear();
* @return The number of slots in the list.
*/
size_type size() const;
* @param slot_ The slot to add to the list of slots.
* @return An iterator pointing to the new slot in the list.
*/
iterator_type connect(const slot_base& slot_);
* @param i An iterator indicating the position where @p slot_ should be inserted.
* @param slot_ The slot to add to the list of slots.
* @return An iterator pointing to the new slot in the list.
*/
iterator_type insert(iterator_type i, const slot_base& slot_);
* @param i An iterator pointing to the slot to be removed.
* @return An iterator pointing to the slot in the list after the one removed.
*/
iterator_type erase(iterator_type i);
void sweep();
* This callback is registered in every slot when inserted into
* the list of slots. It is executed when a slot becomes invalid
* because of some referred object being destroyed.
* It either calls sweep() directly or defers the execution of
* sweep() when the signal is being emitted.
* @param d The signal object (@p this).
*/
static void* notify(void* d);
* The object is destroyed when @em ref_count_ reaches zero.
*/
short ref_count_;
* Indicates whether the signal is being emitted.
*/
short exec_count_;
bool deferred_;
std::list<slot_base> slots_;
};
struct SIGC_API signal_exec
{
signal_impl* sig_;
* @param sig The parent sigc::signal_impl object.
*/
inline signal_exec(const signal_impl* sig)
: sig_(const_cast<signal_impl*>(sig) )
{ sig_->reference_exec(); }
inline ~signal_exec()
{ sig_->unreference_exec(); }
};
* Through evolution this class is slightly misnamed. It is now
* an index into the slot_list passed into it. It simply keeps track
* of where the end of this list was at construction, and pretends that's
* the end of your list. This way you may connect during emittion without
* inadvertently entering an infinite loop, as well as make other
* modifications to the slot_list at your own risk.
*/
struct temp_slot_list
{
typedef signal_impl::slot_list slot_list;
typedef signal_impl::iterator_type iterator;
typedef signal_impl::const_iterator_type const_iterator;
temp_slot_list(slot_list &slots) : slots_(slots)
{
placeholder = slots_.insert(slots_.end(), slot_base());
}
~temp_slot_list()
{
slots_.erase(placeholder);
}
iterator begin() { return slots_.begin(); }
iterator end() { return placeholder; }
const_iterator begin() const { return slots_.begin(); }
const_iterator end() const { return placeholder; }
private:
slot_list &slots_;
slot_list::iterator placeholder;
};
}
* Use sigc::signal::connect() with sigc::mem_fun() and sigc::ptr_fun() to connect a method or function with a signal.
*
* @code
* signal_clicked.connect( sigc::mem_fun(*this, &MyWindow::on_clicked) );
* @endcode
*
* When the signal is emitted your method will be called.
*
* signal::connect() returns a connection, which you can later use to disconnect your method.
* If the type of your object inherits from sigc::trackable the method is disconnected
* automatically when your object is destroyed.
*
* When signals are copied they share the underlying information,
* so you can have a protected/private sigc::signal member and a public accessor method.
*
* signal and slot objects provide the core functionality of this
* library. A slot is a container for an arbitrary functor.
* A signal is a list of slots that are executed on emission.
* For compile time type safety a list of template arguments
* must be provided for the signal template that determines the
* parameter list for emission. Functors and closures are converted
* into slots implicitely on connection, triggering compiler errors
* if the given functor or closure cannot be invoked with the
* parameter list of the signal to connect to.
*/
* signal_base integrates most of the interface of the derived sigc::signal#
* templates. The implementation, however, resides in sigc::internal::signal_impl.
* A sigc::internal::signal_impl object is dynamically allocated from signal_base
* when first connecting a slot to the signal. This ensures that empty signals
* don't waste memory.
*
* @ingroup signal
*/
struct SIGC_API signal_base : public trackable
{
typedef size_t size_type;
signal_base();
signal_base(const signal_base& src);
~signal_base();
signal_base& operator = (const signal_base& src);
* @return @p true if the list of slots is empty.
*/
inline bool empty() const
{ return (!impl_ || impl_->empty()); }
void clear();
* @return The number of slots in the list.
*/
size_type size() const;
protected:
typedef internal::signal_impl::iterator_type iterator_type;
* With connect(), slots can also be added during signal emission.
* In this case, they won't be executed until the next emission occurs.
* @param slot_ The slot to add to the list of slots.
* @return An iterator pointing to the new slot in the list.
*/
iterator_type connect(const slot_base& slot_);
* Note that this function does not work during signal emission!
* @param i An iterator indicating the position where @e slot_ should be inserted.
* @param slot_ The slot to add to the list of slots.
* @return An iterator pointing to the new slot in the list.
*/
iterator_type insert(iterator_type i, const slot_base& slot_);
* Note that this function does not work during signal emission!
* @param i An iterator pointing to the slot to be removed.
* @return An iterator pointing to the slot in the list after the one removed.
*/
iterator_type erase(iterator_type i);
* @return The signal_impl object encapsulating the list of slots.
*/
internal::signal_impl* impl() const;
mutable internal::signal_impl* impl_;
};
}
#endif