A lost update won't occur in the situation you describe, but it won't work properly either.
What will happen in the example you've given above is that given (say) 10 workers started simultaneously, all 10 of them will execute the subquery and get the same ID. They will all attempt to lock that ID. One of them will succeed; the others will block on the first one's lock. Once the first backend commits or rolls back, the 9 others will race for the lock. One will get it, re-check the WHERE clause and see that the
queue.status test no longer matches, and return without modifying any rows. The same will happen with the other 8. So you used 10 queries to do the work of one query.
If you fail to explicitly check the
UPDATE result and see that zero rows were updated you might think you were getting lost updates, but you aren't. You just have a concurrency bug in your application caused by a misunderstanding of the order-of-execution and isolation rules. All that's really happening is that you're effectively serializing your backends so that only one at a time actually makes forward progress.
The only way PostgreSQL could avoid having them all get the same queue item ID would be to serialize them, so it didn't start executing query #2 until query #1 finished. If you want to you can do this by
LOCKing the queue table ... but again, you might as well just have one worker then.
You can't get around this with advisory locks, not easily anyway. Hacks where you iterated down the queue using non-blocking lock attempts until you got the first lockable item would work, but would be slow and clumsy.
You are attempting to implement a work queue using the RDBMS. This will not work well. It will be slow, it will be painful, and getting it both correct and fast will be very very hard. Don't roll your own. Instead, use a well established, well tested system for reliable task queueing. Look at RabbitMQ, ZeroMQ, Apache ActiveMQ, Celery, etc. There's also PGQ from Skytools, a PostgreSQL-based solution.