This is just a hypothetical scenario to illustrate my question. Suppose that there are two threads and one TVar shared between them. In one thread there is an atomically block that reads the TVar and takes 10s to complete. In another thread is an atomically block that modifies the TVar every second. Will the first atomically block ever complete? Surely it will just keep going back to the beginning, because the log is perpetually in an inconsistent state?
As others have said: in theory there is no guarantee of progress. In practice there is also no guarantee of progress:
The above never says "Done with long STM" in my tests.
Obviously if you think the computation is still going to be valid/pertinent then you would want to either
STM prevents deadlock, but is still vulnerable to starvation. It is possible in a pathological case for the 1s atomic action to always aquire the resource.
However, the changes of this happening are very rare -- I don't believe I've ever seen it in practice.
For the semantics, see Composable Memory Transactions, section 6.5 "Progress". STM in Haskell guarantees only that a running transaction will successfully commit (i.e. no deadlock), but in the worst case an infinite transaction will block others.
No, it would work fine. Exactly how the two threads would interact depends on the retry logic.
For example, let's say you have:
So the "
Note that you can't directly control how long these computations will take inside the STM monad. That would be a side-effect, and side-effects are not allowed in STM calculations. The only way to communicate with the outside world is via values passed through transactional memory.
And that means that if the "baton-passing" logic through transactional memory is correct, the program will work correctly independently of the exact amount of time any part of it takes. That's part of the guarantee of STM.