Clojure's STM does not care about the present. By the time an observation is made, the present has already moved. Clojure's STM only cares about capturing a consistent snapshot of state.
This is not very obvious from the example because we know a single read would always be a consistent snapshot. But, if you are only ever using
dosync on a single
ref, then you probably shouldn't be using
refs at all, but
So, imagine instead we are reading from an
a and a
b and trying to return their sum. We don't care that
b are current when we return the sum -- trying to keep up with the present is futile. All we are about is that
b are from a consistent period of time.
If while in a
dosync block, we read
a and then
b was updated in between the two reads, we have an
b from inconsistent points in time. We have to try again -- start all over again and try to read
b from the near present.
Unless... Suppose we kept a history of
b for every change to
b. As before, suppose we read
a and then
b but an update to
b occurs before we're done. Since we saved a history of
b, we can go back in time to before
b changed and find a consistent
b. Then, with a consistent
b from the near past, we can return a consistent sum. We don't have to retry (and potentially fail again) with new values from the near present.
Consistency is maintained by comparing a snapshot taken when entering
dosync to a snaphshot when exiting. Under this model, any change to the relevant data in between would require a retry. The default is optimistic that this will be the case. When a failure occurs, it is marked on the applicable
ref so the next time a change is made a history is kept. Now, consistency is maintained whenever the snapshot taken when entering can be compared to a snapshot when exiting or the single past history retained. So, now a single change on that
ref during the
dosync will not cause a failure. Two changes still will because the history will be exhausted. If another failure does occur, this is marked again and now a history of length two is maintained.
With the example, pretend that we are trying to coordinate multiple refs. The default initial history length is 0 with a maximum of 10.
(let [a (ref 0 :min-history min-hist :max-history max-hist)]
(future (dotimes [_ 500] (dosync (Thread/sleep 20) (alter a inc))))
(dosync (Thread/sleep 1000) @a)))
So the default would be
(stm-experiment 0 10)
;=> 500 (probably)
The updates to
a occur every 20 milliseconds and the read occurs after 1000 milliseconds. Therefore, 50 updates to
a occur before each attempted read. The default tunings of min-history and max-history is that optimistically 0 updates will happen to
a and that at most 10 will. That is, we start with no history on
a and each time a failure occurs, we grow the history of
a one longer, but only up to 10. Since 50 updates are occuring, this will never be enough.
(stm-experiment 50 100)
;=> 0 (quite possibly, multicore)
With a history of 50, all 50 changes to
a are kept in a history, therefore the state of
a that we captured on entry is still there at the very end of the history queue upon exit.
(stm-experiment 48 100)
;=> 100 (or thereabouts, multicore)
With an initial history length of 48, the 50 changes to
a will cause the history to be exhausted and a read fault. But, this read fault will lengthen the history to 49. This still isn't enough, so another read fault occurs and the history is lengthened to 50. Now an
a consistent to the
a at the beginning of the
dosync can be found in the history and success occurs after two attempts during which
a was updated
50 x 2 = 100 times.
(stm-experiment 48 48)
With a cap of 48 on the history length, we can never find the value of
a we started with before 50 updates occured.