in fact, I asked this question because of an argument I had with someone

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

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

my original theory was 11 was just 5 + 5 + 1

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)

hi @AndreasAbel :)

@BeeOnRope Perhaps the 2nd load is dependent on the first in some way, as a way to make sure that the 2nd load gets valid data from the other side of the line-split register? (aka buffer, the buffers that when you run out of gives you counts for ld_blocks.no_sr.)

@PeterCordes - yeah maybe

IIRC correctly on some earlier uarch like SNB this may have been as fast as 9 cycles

hence under the 5+5 limit

Andreas Abel (uops.info guy) stopped in for a second, heh

@BeeOnRope But presumably there's some way to get memory-level parallelism if both sides of a split miss; you don't want the 2nd half to wait until the first half is ready if that includes a miss. I haven't tested that, though.

i have

up to L2 misses it's 2x latency

so 11 cycles for L1, ~24 cycles for L2

after that, the pattern changes, it's like L3 + ~10 cycles for L3

since that's also the same pattern I saw for replays, I thought it had something to do with replays

@PeterCordes - maybe it doesn't want to waste a request if there is no split SR?

so it sends out the first half, then the second half when it comes back

that doesn't explain why the pattern stops with l3 tho

@BeeOnRope Huh, last time I tested, split loads did give extra counts in uops_dispatched. But apparently I'm dumb and tested with dependent loads. I just re-tested with times 4 mov ecx, [rdi + 63] and +4094 and you're right, no extra uops even for a 4k split, just a throughput penalty.

Same deal with split stores: no extra uops for port4 or p237

i also tested it the same way

that's why for the last two years i've been saying load uops replay

I thought maybe you said it because i said it even

but this whole time it has been the dependent ops replaying

it makes sense in a way: how would a re-dispatch help? the load unit is already doing its thing

it is just taking longer: it's not really a replay

there you can see the pattern: 11 cycle (exactly) for split L1, ~24-25ish for L2, then about nominal + 10 for L3

that pattern holds beyond that

@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

yeah, exactly, obvious in hindsight

@PeterCordes - maybe the L3 and ram results are explained by adjacent line prefetching

maybe, internally, it really is two serial loads but adjacent line saves it

@BeeOnRope Can we test that by having the other hyperthread keep it too busy with demand loads for that prefetcher to activate? But not so busy that it makes demand loads much slower? Probably not, might have to disable that PF for testing.

i am just turning off the prefetcher

it will take me a couple minutes

no that wasn't it, same timing with next-line PF off

with all PF off, to be precise