On Wed, 14 Dec 2005 08:53:21 -0500, George Macdonald
<fammacd=!SPAM^(E-Mail Removed)> wrote:
>On Wed, 14 Dec 2005 03:16:14 GMT, a?n?g?e?(E-Mail Removed)
>(The little lost angel) wrote:
>
>>Just a random question that came to my mind reading about the FB-DIMM
>>thing.
>>
>>With the added chip, it allows subsequent ram tech to use the same
>>interface and suppose to allow greater number of DIMM modules to be
>>used.
>>
>>Some time ago, I remember reading here that having pieces of plug-in
>>ram is more difficult than having them soldered on due to some
>>"loading" issue so boards are generally limited in the number of slots
>>they have.
>>
>>Does having a buffer chip means this loading issue goes away? Or is it
>>simply a case where the board still can't have more than say 4 slots
>>connected directly, but the chip presents effectively 1 slot to the
>>board and itself controls up to the max of 4 slots connected to it.
>>Hence with a limit of 4 slots, putting some kind of buffer chip into
>>each will allow 16 usable slots?
>>
>>Would this also mean that with some kind of buffer chip, we could in
>>theory add unlimited ram capacities to the board, ignoring physical
>>constraints i.e.
>
>The buffer chips in question, the AMBs, have a receiver and transmitter in
>both the northbound and southbound directions so it would appear that no
>external termination is needed for the signals - IOW in theory it would be
>possible to extend the bus as far as you want *BUT* all downstream data
>transfers pass through the upstream AMBs so the primary AMB is going to
>pass every single bit of data - maybe why it needs a heatpipe for cooling.
>
>Also, there is a variable latency mode, which I'm not sure is currently
>viable/implemented, and without it you have to use the same programmed
>latency for all DIMMs (remember DRDRAM ?) so the primary DIMM, next to the
>chipset, has to be set to the same latency as the furthest one
>downstream... so eventually the performance losses would get excessive.
>
>>board has 4 DIMM slots. Plug into each, a card with 4 DIMM slots and
>>an buffer chip, effectively creating 16 slots. Now plug such cards
>>into each of the expansion card slots, we get 64 slots. Or is it
>>impossible to do this due to the "loading" issue or something? This is
>>ignoring the physical impossibilities and assuming timings are
>>increased to accept the longer distance.
>
>If that works it would seem like a way to mitigate the excessive latency
>due to distance as a linear bus gets longer and longer with multiple DIMMs.
>Whether it's possible I dunno.:-).. but if daytripper is reading, he'd be
>the one to have the answer.
I think I understand his question, he's building a switched fbdimm memory
subsystem, instead of daisy-chaining, to beat the accumulated latency problem
(which, btw, Intel says "Is Not A Problem" - aka "Don't pay attention to that"
;-)
Yeah, you could probably do that, but you'd have to be implementing a really
exciting amount of memory to get much if any payback, and then there'd still
be conditions - and challenges. Assuming the SI and skew issues getting
through the active switch components and the extra connector layer(s) didn't
kill you dead....from a practical view, all the hard-wired shite inside the
only fbdimm-capable chipsets I've worked with to date (and at that, using
semi-functional AMBs - which, btw, will brown a burger better than a George
Foreman Grill can), would run out of capabilities way before any latency
improvement would be realized.
Not enough hardware to track all those fbdimms and DRAM banks, command fields
aren't wide enough, etc. Unless one had control of the host memory controller
design to broaden and deepen control structures, and was also willing to take
the platform cost hit to implement and amortize the switch components in a
near-commoditized marketplace for a likely-to-be-very-modest performance
improvement, I don't think this idea could gain traction...
Cheers
/daytripper
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