I've been looking at how the
TMonitor locks are implemented, and I finally made an interesting discovery. For a bit of drama, I'll first tell you how the locks work.
When you call any
TMonitor function on an
TObject, a new instance of the
TMonitor record is created and that instance is assigned to a
MonitorFld inside the object itself. This assignment is made in a thread-safe way, using
InterlockedCompareExchangePointer. Because of this trick the
TObject only contains one pointer-size amount of data for the support of
TMonitor, it doesn't contain the full TMonitor structure. And that's a good thing.
TMonitor structure contains a number of records. We'll start with the
FLockCount: Integer field. When the first thread uses
TMonitor.Enter() on any object, this combined lock-counter field will have the value ZERO. Again using a
InterlockedCompareExchange method the lock is acquired and the counter is initiated. There will be no locking for the calling thread, no context-switch since this is all done in-process.
When the second thread tries to
TMonitor.Enter() the same object, it's first attempt to lock will fail. When that happens Delphi follows two strategies:
- If the developer used
TMonitor.SetSpinCount() to set a number of "spins", then Delphi will do a busy-wait loop, spinning the given number of times. That's very nice for tiny locks because it allows acquiring the lock without doing a context-switch.
- If the spin-count expires (or there's no spin-count, and by default the spin count zero),
TMonitor.Enter() will initiate a Wait on the event returned by
TMonitor.GetEvent(). In other words it will not busy-wait wasting CPU cycles. Remember the
TMonitor.GetEvent() because that's very important.
Let's say we've got a thread that acquired the lock and a thread that tried to acquire the lock but is now waiting on the event returned by
TMonitor.GetEvent. When the first thread calls
TMonitor.Exit() it will notice (via the
FLockCount field) that there is at least one other thread blocking. So it immediately pulses what should normally be the previously allocated event (calls
TMonitor.GetEvent()). But since the two threads, the one that calls
TMonitor.Exit() and the one that called
TMonitor.Enter() might actually call
TMonitor.GetEvent() at the same time, tehre are a couple more tricks inside
TMonitor.GetEvent() to make sure that only one event is allocated, irrelevant of the order of operations.
For a few more fun moments we'll now delve into the way the
TMonitor.GetEvent() works. This thing lives inside the
System unit (you know, the one we can't recompile to play with), but it turns out it delegates the duty of actually allocated the Event to an other unit, through the
System.MonitorSupport pointer. That points to a record of type
TMonitorSupport that declares 5 function pointers:
NewSyncObject - allocates a new Event for Synchronization purposes
FreeSyncObject - deallocates the Event allocated for Synchronization purposes
NewWaitObject - allocates a new Event for Wait operations
FreeWaitObject - deallocates that Wait event
WaitAndOrSignalObject - well.. waits or signals.
It also turns out that the objects returned by the
NewXYZ functions could be anything, because they're only used for the call to
WaitXYZ and for the corresponding call to
FreeXyzObject. The way those functions are implemented in
SysUtils is designed to provide those locks with a minimum amount of locking and context-switching; Because of that the objects themselves (returned by
NewWaitObject) are not directly the Events returned by
CreateEvent(), but pointers to records in the
SyncEventCacheArray. It goes even further, actual Windows Events are not created until required. Because of that the records in the
SyncEventCacheArray contains a couple of records:
TSyncEventItem.Lock - this tells Delphi rather the Lock is being used for anything right now or not and
TSyncEventItem.Event - this holds the actual Event that'll be used for synchronization, if waiting is required.
When the application terminates, the
SysUtils.DoneMonitorSupport goes over all the records in the
SyncEventCacheArray and waits for the Lock to become ZERO, ie, waits for the lock to stop being used by anything. Theoretically, as long as that lock is NOT Zero, at least one thread out there might be using the lock - so the sane thing to do would be to wait, in order to NOT cause AccessViolations errors. And we finally got to our current question: HANGING in
Why an application might Hang in SysUtils.DoneMonitorSupport even if all it's threads terminated properly?
Because at least one Event allocated using any one of
NewWaitObject was not freed using it's corresponding
FreeWaitObject. And we go back to the
TMonitor.GetEvent() routine. The Event it allocates is saved in the
TMonitor record that corresponds to the object that was used for
TMonitor.Enter(). The pointer to that record is only kept in that object's instance data, and is kept there for the life of the application. Searching for the name of the field,
FLockEvent, we find this in the
if (MonitorSupport <> nil) and (FLockEvent <> nil) then
and a call to that record-destructor in here:
In other words, the final sync-event is only released when the object that was used for synchronization is freed!
Answer to OP's question:
The application hangs because at least one OBJECT that was used for
TMonitor.Enter() was not freed.
Unfortunately I don't like this. It's not right, I mean the penalty for not freeing a small object should be a small memory leak, not a hanging application! This is especially bad for Service applications where a service might simply hang for ever, not fully shut down but unable to respond to any request.
The solutions for the Delphi team? They should NOT hang in the finalization code of the
SysUtils unit, no-matter-what. They should probably ignore the
Lock and move to closing the Event handle. At that stage (finalization of the SysUtils unit), if there's still code running in some thread, it's in a real bad shape as most of the units got finalized, it's not running in the environment it was designed to run in.
For the delphi users? We can replace the
MonitorSupport with our own version, one that doesn't do those extensive tests at finalization time.