Based on the comment thread in the question, this is likely the effect of the optimizer. This is really a problem with the design more than anything else - it assumes that the clocks between the producer and consumer are shared or tightly synchronized. This assumption seems reasonable until you need to distribute the processing between more than one computer.
Clocks are rarely (if ever) tightly synchronized between different computers. The common algorithm for synchronizing computers is the Network Time Protocol. You can achieve very close to millisecond synchronization on the local area network but even that is difficult.
There are two solutions to this problem that come to mind. The first is to have the producer's timestamp is passed through the client and into the receiver. If the receiver receives a timestamp that is earlier than it's notion of the current time, then it simply resets the timestamp to the current time. This type of normalization will allow assumptions about time being a monotonically increasing sequence continue to hold.
The other solution is to disable optimization and hope that the problem goes away. As you might expect, your mileage may vary considerably with this solution.
Depending on the problem that you are trying to solve you may be able to provide your own synchronized clock between the different threads. Use an atomically incrementing number instead of the wall time.
java.util.concurrent.atomic.AtomicInteger or one of its relatives can be used to provide a single number that is incremented every time that a message is generated. This allows the producer and receiver to have a shared value to use as a clock of sorts.
In any case, clocks are really hard to use correctly especially for synchronization purposes. If you can find some way to remove assumptions about time from distributed systems, your architectures and solutions will be more resilient and more deterministic.