I'm working on a multi-threaded system which involves the thread notifying its parent of destruction of an object. The problem is, I need to allow that object to remain created long enough for this event to read this object, because I'm passing the object as one of the event's parameters. Currently, when this event is triggered, the object which is passed to the event is already destroyed from within the thread.
I don't want the thread to necessarily wait for this event to be completed, but rather know when this event has been triggered and then destroy the object. I want the code in the thread to continue no matter what, even if the object is still instantiated.
There's a list of these objects, and they're created from within a thread. The thread its self has events for when certain things happen to the objects in this list (specifically in this case the destruction of the object). I'm actually feeding these events into an event queue (a TList which contains record pointers to what event and what object). So somewhere inside the thread, I add a record to this event list.
The thread's execution then comes along and loops through the events in this list and triggers them accordingly (example below). So when the event was added to the list, it saved the object pointer as part of this event's record pointer. There could then be a long delay until the event is actually triggered. At that point, the object needs to still be instantiated so it can be read from outside the thread. Only then shall the object actually be destroyed.
The mechanism used for this event queue doesn't have any room for feedback to the thread. It's already a developed system and any addition for this event queue to tell the thread that the event has been triggered is out of the question, as it would require an entire re-write. Otherwise, I would simply tell the thread to destroy this object once my event has been called.
Here's some snippets, the system is actually very large so it's difficult to show all the functionality. The one thread's event sets off a chain of events through 4 more parent objects, passing this object through each. The goal is to prevent any code outside of the thread to handle this actual destruction. The thread should take full responsibility for waiting for this event before destroying...
type TJDNetSvrNode = class; TJDNetSvrThread = class; TNodeEvent = (neUnload); //And many more PNodeEventRec = ^TNodeEventRec; TNodeEventRec = record Event: TNodeEvent; Node: TJDNetSvrNode; end; TJDNetSvrNodeEvent = procedure(Sender: TObject; Node: TJDNetSvrNode) of object; TJDNetSvrNode = class(TObject) //Large object with no relevant members end; TJDNetSvrThread = class(TThread) private FNodeEvents: TList; FNodeEvent: PNodeEventRec; FOnNodeUnload: TJDNetSvrNodeEvent; procedure SYNC_OnUnload; public property OnNodeUnload: TJDNetSvrNodeEvent read FOnNodeUnload write FOnNodeUnload; end; //Much more in this class //Starting point of event - adds to event queue list procedure TJDNetSvrThread.NodeUnloaded(Sender: TObject; Node: TJDNetSvrNode); var E: PNodeEventRec; begin E:= New(PNodeEventRec); E.Event:= neUnload; E.Node:= Node; FNodeEvents.Add(E); end; //Called within thread to execute any events which are queued procedure TJDNetSvrThread.ProcessNodeEvents; begin while FNodeEvents.Count > 0 do begin FNodeEvent:= PNodeEventRec(FNodeEvents); FNodeEvents.Delete(0); case FNodeEvent.Event of neUnload: begin Synchronize(SYNC_OnUnload); end; //And many more end; Dispose(FNodeEvent); end; end; procedure TJDNetSvrThread.SYNC_OnUnload; begin if assigned(FOnNodeUnload) then FOnNodeUnload(Self, FNodeEvent.Node); //Parent also has to use "Node" for its event //NOW "Node" can be destroyed end;