poco/Foundation/include/Poco/AbstractEvent.h
2006-12-22 09:31:08 +00:00

313 lines
10 KiB
C++

//
// AbstractEvent.h
//
// $Id: //poco/Main/Foundation/include/Poco/AbstractEvent.h#8 $
//
// Library: Foundation
// Package: Events
// Module: AbstractEvent
//
// Definition of the AbstractEvent class.
//
// Copyright (c) 2006, Applied Informatics Software Engineering GmbH.
// and Contributors.
//
// Permission is hereby granted, free of charge, to any person or organization
// obtaining a copy of the software and accompanying documentation covered by
// this license (the "Software") to use, reproduce, display, distribute,
// execute, and transmit the Software, and to prepare derivative works of the
// Software, and to permit third-parties to whom the Software is furnished to
// do so, all subject to the following:
//
// The copyright notices in the Software and this entire statement, including
// the above license grant, this restriction and the following disclaimer,
// must be included in all copies of the Software, in whole or in part, and
// all derivative works of the Software, unless such copies or derivative
// works are solely in the form of machine-executable object code generated by
// a source language processor.
//
// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
// FITNESS FOR A PARTICULAR PURPOSE, TITLE AND NON-INFRINGEMENT. IN NO EVENT
// SHALL THE COPYRIGHT HOLDERS OR ANYONE DISTRIBUTING THE SOFTWARE BE LIABLE
// FOR ANY DAMAGES OR OTHER LIABILITY, WHETHER IN CONTRACT, TORT OR OTHERWISE,
// ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER
// DEALINGS IN THE SOFTWARE.
//
#ifndef Foundation_AbstractFoundation_INCLUDED
#define Foundation_AbstractFoundation_INCLUDED
#include "Poco/Foundation.h"
#include "Poco/SingletonHolder.h"
#include "Poco/SharedPtr.h"
#include "Poco/ActiveResult.h"
#include "Poco/ActiveMethod.h"
#include "Poco/Mutex.h"
namespace Poco {
template <class TArgs, class TStrategy, class TDelegate>
class AbstractEvent
/// An abstractEvent is the super-class of all events.
/// It works similar to the way C# handles notifications (aka events in C#).
/// Events can be used to send information to a set of observers
/// which are registered at the event. The type of the data is specified with
/// the template parameter TArgs. The TStrategy parameter must be a subclass
/// of NotificationStrategy. The parameter TDelegate can either be a subclass of AbstractDelegate
/// or of PriorityAbstractDelegate.
///
/// Note that AbstractEvent should never be used directly. One ought to use
/// one of its subclasses which set the TStrategy and TDelegate template parameters
/// to fixed values. For most use-cases the BasicEvent template will be sufficient.
///
/// Use events by adding them as public members to the object which is throwing notifications:
///
/// class MyData
/// {
/// public:
/// Poco::BasicEvent<int> AgeChanged;
///
/// MyData();
/// ...
/// };
///
/// Throwing the event can be done either by the events notify() or notifyAsync() method:
///
///
/// Alternatively, instead of notify(), operator () can be used.
///
/// void MyData::setAge(int i)
/// {
/// this->_age = i;
/// AgeChanged(this, this->_age);
/// }
///
/// Note that notify and notifyAsync do not catch exceptions, i.e. in case a delegate
/// throws an exception, the notify is immediately aborted and the exception is thrown
/// back to the caller.
///
/// Delegates can register methods at the event. In the case of a BasicEvent or FIFOEvent
/// the Delegate template is used, in case of an PriorityEvent a PriorityDelegate is used.
/// Mixing of observers, e.g. using a PriorityDelegate with a BasicEvent is not possible and
/// checked for during compile time.
/// Events require the observers to follow the following method signature:
///
/// void onEvent(const void* pSender, TArgs& args);
///
/// For performance reasons arguments are always sent by reference. This also allows observers
/// to modify the sent argument. To prevent that, use <const TArg> as template
/// parameter. A non-conformant method signature leads to compile errors.
///
/// Assuming that the observer meets the method signature requirement, it can register
/// this method with the += operator:
///
/// class MyController
/// {
/// protected:
/// MyData _data;
///
/// void onDataChanged(void* pSender, int& data);
/// ...
/// };
///
/// MyController::MyController()
/// {
/// _data.AgeChanged += Delegate<MyController, int>(this, &MyController::onDataChanged);
/// }
///
/// In some cases it might be desirable to work with automatically expiring registrations:
///
/// _data.DataChanged += Expire<int>(Delegate<MyController, int>(this, &MyController::onDataChanged), 1000);
///
/// This will add a delegate to the event which will automatically be removed in 1000 millisecs.
///
/// Unregistering happens via the -= operator. Forgetting to unregister a method will lead to
/// segmentation faults later, when one tries to send a notify to a no longer existing object.
///
/// MyController::~MyController()
/// {
/// _data.DataChanged -= Delegate<MyController, int>(this, &MyController::onDataChanged);
/// }
///
/// For further examples refer to the event testsuites.
{
public:
AbstractEvent():
_executeAsync(this, &AbstractEvent::executeAsyncImpl),
_enabled(true)
{
}
AbstractEvent(const TStrategy& strat):
_executeAsync(this, &AbstractEvent::executeAsyncImpl),
_strategy(strat),
_enabled(true)
{
}
virtual ~AbstractEvent()
{
}
void operator += (const TDelegate& aDelegate)
/// Adds a delegate to the event. If the observer is equal to an
/// already existing one (determined by the < operator),
/// it will simply replace the existing observer.
/// This behavior is determined by the TStrategy. Current implementations
/// (DefaultStrategy, FIFOStrategy) follow that guideline but future ones
/// can deviate.
{
FastMutex::ScopedLock lock(_mutex);
_strategy.add(aDelegate);
}
void operator -= (const TDelegate& aDelegate)
/// Removes a delegate from the event. If the delegate is equal to an
/// already existing one is determined by the < operator.
/// If the observer is not found, the unregister will be ignored
{
FastMutex::ScopedLock lock(_mutex);
_strategy.remove(aDelegate);
}
void operator () (const void* pSender, TArgs& args)
{
notify(pSender, args);
}
void notify(const void* pSender, TArgs& args)
/// Sends a notification to all registered delegates. The order is
/// determined by the TStrategy. This method is blocking. While executing,
/// other objects can change the list of delegates. These changes don't
/// influence the current active notifications but are activated with
/// the next notify. If one of the delegates throws an exception, the notify
/// method is immediately aborted and the exception is reported to the caller.
{
SharedPtr<TStrategy> ptrStrat;
bool enabled = false;
{
FastMutex::ScopedLock lock(_mutex);
enabled = _enabled;
if (_enabled)
{
// thread-safeness:
// copy should be faster and safer than blocking until
// execution ends
ptrStrat = new TStrategy(_strategy);
}
}
if (enabled)
{
ptrStrat->notify(pSender, args);
}
}
ActiveResult<TArgs> notifyAsync(const void* pSender, const TArgs& args)
/// Sends a notification to all registered delegates. The order is
/// determined by the TStrategy. This method is not blocking and will
/// immediately return. The delegates are invoked in a seperate thread.
/// Call activeResult.wait() to wait until the notification has ended.
/// While executing, other objects can change the delegate list. These changes don't
/// influence the current active notifications but are activated with
/// the next notify. If one of the delegates throws an exception, the execution
/// is aborted and the exception is reported to the caller.
{
NotifyAsyncParams params(pSender, args);
{
FastMutex::ScopedLock lock(_mutex);
// thread-safeness:
// copy should be faster and safer than blocking until
// execution ends
// make a copy of the strategy here to guarantee that
// between notifyAsync and the execution of the method no changes can occur
params.ptrStrat = SharedPtr<TStrategy>(new TStrategy(_strategy));
params.enabled = _enabled;
}
ActiveResult<TArgs> result = _executeAsync(params);
return result;
}
void enable()
/// Enables the event
{
FastMutex::ScopedLock lock(_mutex);
_enabled = true;
}
void disable()
/// Disables the event. notify and notifyAsnyc will be ignored,
/// but adding/removing delegates is still allowed.
{
FastMutex::ScopedLock lock(_mutex);
_enabled = false;
}
bool isEnabled() const
{
FastMutex::ScopedLock lock(_mutex);
return _enabled;
}
void clear()
/// Removes all delegates.
{
FastMutex::ScopedLock lock(_mutex);
_strategy.clear();
}
protected:
struct NotifyAsyncParams
{
SharedPtr<TStrategy> ptrStrat;
const void* pSender;
TArgs args;
bool enabled;
NotifyAsyncParams(const void* pSend, const TArgs& a):ptrStrat(), pSender(pSend), args(a), enabled(true)
/// default constructor reduces the need for TArgs to have an empty constructor, only copy constructor is needed.
{
}
};
ActiveMethod<TArgs, NotifyAsyncParams, AbstractEvent> _executeAsync;
TArgs executeAsyncImpl(const NotifyAsyncParams& par)
{
if (!par.enabled)
{
return par.args;
}
NotifyAsyncParams params = par;
TArgs retArgs(params.args);
params.ptrStrat->notify(params.pSender, retArgs);
return retArgs;
}
TStrategy _strategy; /// The strategy used to notify observers.
bool _enabled; /// Stores if an event is enabled. Notfies on disabled events have no effect
/// but it is possible to change the observers.
mutable FastMutex _mutex;
private:
AbstractEvent(const AbstractEvent& other);
AbstractEvent& operator = (const AbstractEvent& other);
};
} // namespace Poco
#endif