12:33 AM
which was about exactly that: they suggested that the RS snoops the linear address writeback bus in order to predict when the load will arrive (of course, splits are only one small thing, cache misses also cause a change in latency)
my guess is that the linear address never leaves the load unit, but that even no signal leaves: the replay is just detected in a generic way any time a replay occurs: by noting that the result didn't appear on the bus (or probably a dedicated bus containing the physical destination ID) in the expected cycle
so i expect all replay behavior to be more or less the same regardless of the trigger
it's interesting that the split latency is 11 cycles
it's interesting that the split latency is 11 cycles
I don't know if that's limited by the replay behavior, or it takes that long to resolve a split, I would have expected it to be more parallel
like 5 cycles, then a cycle to detect the need for a replay and another five cycles, driven by the replay, but of course I guess the load unit itself handles the split load: it doesn't need to wait for the RS to send another load uop for the second half (and here we confirm there is no second p23 uop)
1:19 AM
** Running group memory/load-serial-crossing : Cacheline crossing loads from fixed-size regions **
Benchmark Cycles Nanos
8-KiB serial loads 10.99 4.24
16-KiB serial loads 10.99 4.24
32-KiB serial loads 11.18 4.32
64-KiB serial loads 22.39 8.64
128-KiB serial loads 24.16 9.32
256-KiB serial loads 24.79 9.57
512-KiB serial loads 40.58 15.66
1024-KiB serial loads 44.16 17.04
2048-KiB serial loads 45.79 17.67
4096-KiB serial loads 59.10 22.81
Benchmark Cycles Nanos
8-KiB serial loads 10.99 4.24
16-KiB serial loads 10.99 4.24
32-KiB serial loads 11.18 4.32
64-KiB serial loads 22.39 8.64
128-KiB serial loads 24.16 9.32
256-KiB serial loads 24.79 9.57
512-KiB serial loads 40.58 15.66
1024-KiB serial loads 44.16 17.04
2048-KiB serial loads 45.79 17.67
4096-KiB serial loads 59.10 22.81
** Running group memory/load-serial : Random serial loads from fixed-size regions **
Benchmark Cycles Nanos
16-KiB serial loads 4.00 1.54
24-KiB serial loads 4.00 1.54
30-KiB serial loads 4.00 1.54
31-KiB serial loads 4.00 1.54
32-KiB serial loads 4.00 1.54
33-KiB serial loads 6.17 2.38
34-KiB serial loads 8.22 3.17
35-KiB serial loads 10.14 3.91
40-KiB serial loads 11.98 4.62
48-KiB serial loads 11.98 4.62
Benchmark Cycles Nanos
16-KiB serial loads 4.00 1.54
24-KiB serial loads 4.00 1.54
30-KiB serial loads 4.00 1.54
31-KiB serial loads 4.00 1.54
32-KiB serial loads 4.00 1.54
33-KiB serial loads 6.17 2.38
34-KiB serial loads 8.22 3.17
35-KiB serial loads 10.14 3.91
40-KiB serial loads 11.98 4.62
48-KiB serial loads 11.98 4.62
1:38 AM
@BeeOnRope Seems clear in hindsight, like so many things :P. I assumed that another load uop was needed to initiate the request for another line, and so the first load could get out of the load port's pipeline and make room for later loads. But if that was the case, then why would a page split be more expensive than any other line split? (Also, re-dispatch wouldn't be TLB coherent; you need both sides of the split to come from the same physical page, old or new but not torn, on non-page split
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