This sounds like a syncpoint issue. If the QMgr were to issue a COMMIT when a message is requeued inside of a unit of work it would affect all messages under syncpoint inside of that thread. This would cause serious problems if an application had performed several PUT or GET calls prior to hitting the poison message. Rather than issue a
COMMIT outside of the program's control, the QMgr just leaves the message on the backout queue inside the unit of work and waits for the program to issue the
COMMIT. This can lead to some unexpected behavior such as what you are seeing where a message lands back on the input queue.
If another message is in the queue behind the "bad" one and it is processed successfully by the same thread, everything works out perfectly. The app issues a
COMMIT on the new message and this also affects the poison message on the Backout Queue. However if the thread were to exit uncleanly (without an explicit disconnect or
COMMIT) then the transaction is rolled back and the poison message is returned to the input queue.
The usual way of dealing with this is that the next good message (or batch of messages if transactions are batched) in the input queue will force the COMMIT. However in some cases where the owning thread gets no new work (perhaps it was performing a
GET by Correlation ID) there is nothing to push the bad message through. In these cases, it is important to make sure that the application issues a
COMMIT before ending. One way to do this is to write the code to perform the
CORRELID with a wait interval. If the wait interval expires, the application would get a return code of 2033 and then issue a
COMMIT before closing the thread. If the reply message is legitimately late for whatever reason, the
COMMIT will have no effect. But if the message arrived and had been backed out and requeued, the
COMMIT will cause it to stay in the Backout Queue.
One way to see exactly what is going on is to run a trace against the queue in question. You can use the built-in trace function - strmqtrc - which has a few more options in V7 than does the V6 version. However if you want very fine grained control you can use the trace exit in SupportPac MA0W. With MA0W you can see exactly what API calls are made by the program and those made on its behalf.
[EDIT] Updating the response with some info from the PMR:
The following is from the WMQ V7 Infocenter:
MessageConsumers are single threaded below the Session level, and
any requeuing of poison messages
takes place within the current unit of
work. This does not affect the
operation of the application, however
when poison messages are requeued
under a transacted or
Client_acknowledge Session, the
requeue action itself will not be
committed until the current unit of
work is committed by the application
code or, if appropriate, the
application container code."
Hence, if it is important for the customer to have poison messages
committed immediately after they are
backed out, it is recommended they
either make use of the Application
(ConnectionConsumer) which can commit
the message immediately, or
another mechanism to move poison
messages from the queue.
Here is the link to this information in the V6 and V7 Information Centers. Since you are using the V6 client so you would want to refer to the V6 Infocenter. Note that with the V6 client, there is no mention in the Infocenter of ASF being able to commit the poison message immediately, even when using a ConnectionConsumer. The way I read it, this means you probably will need to upgrade to the V7 client to get the behavior you are looking for. Will be interested to see if the PMR results in a similar recommendation.