[Lguest] [PATCH RFC/RFB] x86_64, i386: interrupt dispatch changes

Sat Nov 29 07:48:10 EST 2008

On Thu, Nov 27, 2008 at 12:13:43PM +0200, Avi Kivity wrote:
> H. Peter Anvin wrote:
> >
> >>I suspect we could get it down to three bytes, by sharing the last 
> >>byte of the four-byte call sequence with the first byte of the next:
> >>
> >> 66 e8 ff 66 e8 fc 66 e8 f9 66 e8 f6 ...
> >>
> >>Every three bytes a new stub begins; it's a four-byte call to offset 
> >>0x6703 relative to the beginning of the first stub.
> >>
> >>Can anyone better 24 bits/stub?
> >
> >On the entirely silly level...
> >
> >CC xx
> 
> Nice.  Can actually go to zero, by pointing the IDT at (unmapped_area + 
> vector), and deducing the vector in the page fault handler from cr2.

Hi all,

We started the discussion with doing away with the whole jump
array entirely, by changing the value of the CS index in the
IDT. This needs the GDT to be extended with 256 entries, but an
entire page (space for 512 entries) was already reserved anyhow!
I think there is still some problem with the patch I sent due to
some code depending on certain values of the CS index, but the
system I've benchmarked on seemed to behave.

I did a set of benchmarks on an 8-way Xeon in 64-bit mode. The
system was loaded with an instance of bonnie++ pinned to processor
0, and all 8 processors were running a program doing (almost)
adjacent rdtsc's. Bonnie++ causes interrupts and the latencies
due to these show up as larger time intervals. Complete runs of
bonnie++ in fast mode were sampled this way for a current -rc6
kernel and an -rc6 kernel plus my patch. The total sampling time
was 30 minutes for each run. Per kernel I did one run as a warm-up
and another two runs to measure the latencies. The results for
measured latencies between 5 and 1000 microseconds are shown in
the attached graph. Above 1000 microseconds there is only one big
contribution: at 40000 microseconds ;). The surface below the graph
is a measure of time.

Observations (for this test load!):

Near 200, 250 and 350 microseconds, the peaks shift to longer
latencies for the cs-changing code by about 10 microseconds,
but the total time spent is pretty much constant.

The highest latencies for the cs-changing code are near 600
and 650 microseconds. The highest latencies for the current
code are near 800 and 850 microseconds.

The total surface of the graphs between 5 and 1000 microseconds
is within an error estimate of 1% equal for both cases, and is
about 0.69% of the total time.

Most time is spent measuring 'latencies' of less than 5 micro-
seconds, since bonnie++ is taking only about 5% cpu time on a
single cpu most of the time, and only up to 50% on a single cpu
during a short time in the file creation benchmark.

Greetings,
	Alexander
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