Based on a patch by Mark Hemment <markhemm@googlemail.com> and
incorporating very sane suggestions from Linus.
The point here is to have the default case with FSRM - which is supposed
to be the majority of x86 hw out there - if not now then soon - be
directly inlined into the instruction stream so that no function call
overhead is taking place.
Drop the early clobbers from the @size and @addr operands as those are
not needed anymore since we have single instruction alternatives.
The benchmarks I ran would show very small improvements and a PF
benchmark would even show weird things like slowdowns with higher core
counts.
So for a ~6m running the git test suite, the function gets called under
700K times, all from padzero():
<...>-2536 [006] ..... 261.208801: padzero: to: 0x55b0663ed214, size: 3564, cycles: 21900
<...>-2536 [006] ..... 261.208819: padzero: to: 0x7f061adca078, size: 3976, cycles: 17160
<...>-2537 [008] ..... 261.211027: padzero: to: 0x5572d019e240, size: 3520, cycles: 23850
<...>-2537 [008] ..... 261.211049: padzero: to: 0x7f1288dc9078, size: 3976, cycles: 15900
...
which is around 1%-ish of the total time and which is consistent with
the benchmark numbers.
So Mel gave me the idea to simply measure how fast the function becomes.
I.e.:
start = rdtsc_ordered();
ret = __clear_user(to, n);
end = rdtsc_ordered();
Computing the mean average of all the samples collected during the test
suite run then shows some improvement:
clear_user_original:
Amean: 9219.71 (Sum: 6340154910, samples: 687674)
fsrm:
Amean: 8030.63 (Sum: 5522277720, samples: 687652)
That's on Zen3.
The situation looks a lot more confusing on Intel:
Icelake:
clear_user_original:
Amean: 19679.4 (Sum: 13652560764, samples: 693750)
Amean: 19743.7 (Sum: 13693470604, samples: 693562)
(I ran it twice just to be sure.)
ERMS:
Amean: 20374.3 (Sum: 13910601024, samples: 682752)
Amean: 20453.7 (Sum: 14186223606, samples: 693576)
FSRM:
Amean: 20458.2 (Sum: 13918381386, sample s: 680331)
The original microbenchmark which people were complaining about:
for i in $(seq 1 10); do dd if=/dev/zero of=/dev/null bs=1M status=progress count=65536; done 2>&1 | grep copied
32207011840 bytes (32 GB, 30 GiB) copied, 1 s, 32.2 GB/s
68719476736 bytes (69 GB, 64 GiB) copied, 1.93069 s, 35.6 GB/s
37597741056 bytes (38 GB, 35 GiB) copied, 1 s, 37.6 GB/s
68719476736 bytes (69 GB, 64 GiB) copied, 1.78017 s, 38.6 GB/s
62020124672 bytes (62 GB, 58 GiB) copied, 2 s, 31.0 GB/s
68719476736 bytes (69 GB, 64 GiB) copied, 2.13716 s, 32.2 GB/s
60010004480 bytes (60 GB, 56 GiB) copied, 1 s, 60.0 GB/s
68719476736 bytes (69 GB, 64 GiB) copied, 1.14129 s, 60.2 GB/s
53212086272 bytes (53 GB, 50 GiB) copied, 1 s, 53.2 GB/s
68719476736 bytes (69 GB, 64 GiB) copied, 1.28398 s, 53.5 GB/s
55698259968 bytes (56 GB, 52 GiB) copied, 1 s, 55.7 GB/s
68719476736 bytes (69 GB, 64 GiB) copied, 1.22507 s, 56.1 GB/s
55306092544 bytes (55 GB, 52 GiB) copied, 1 s, 55.3 GB/s
68719476736 bytes (69 GB, 64 GiB) copied, 1.23647 s, 55.6 GB/s
54387539968 bytes (54 GB, 51 GiB) copied, 1 s, 54.4 GB/s
68719476736 bytes (69 GB, 64 GiB) copied, 1.25693 s, 54.7 GB/s
50566529024 bytes (51 GB, 47 GiB) copied, 1 s, 50.6 GB/s
68719476736 bytes (69 GB, 64 GiB) copied, 1.35096 s, 50.9 GB/s
58308165632 bytes (58 GB, 54 GiB) copied, 1 s, 58.3 GB/s
68719476736 bytes (69 GB, 64 GiB) copied, 1.17394 s, 58.5 GB/s
Now the same thing with smaller buffers:
for i in $(seq 1 10); do dd if=/dev/zero of=/dev/null bs=1M status=progress count=8192; done 2>&1 | grep copied
8589934592 bytes (8.6 GB, 8.0 GiB) copied, 0.28485 s, 30.2 GB/s
8589934592 bytes (8.6 GB, 8.0 GiB) copied, 0.276112 s, 31.1 GB/s
8589934592 bytes (8.6 GB, 8.0 GiB) copied, 0.29136 s, 29.5 GB/s
8589934592 bytes (8.6 GB, 8.0 GiB) copied, 0.283803 s, 30.3 GB/s
8589934592 bytes (8.6 GB, 8.0 GiB) copied, 0.306503 s, 28.0 GB/s
8589934592 bytes (8.6 GB, 8.0 GiB) copied, 0.349169 s, 24.6 GB/s
8589934592 bytes (8.6 GB, 8.0 GiB) copied, 0.276912 s, 31.0 GB/s
8589934592 bytes (8.6 GB, 8.0 GiB) copied, 0.265356 s, 32.4 GB/s
8589934592 bytes (8.6 GB, 8.0 GiB) copied, 0.28464 s, 30.2 GB/s
8589934592 bytes (8.6 GB, 8.0 GiB) copied, 0.242998 s, 35.3 GB/s
is also not conclusive because it all depends on the buffer sizes,
their alignments and when the microcode detects that cachelines can be
aggregated properly and copied in bigger sizes.
Signed-off-by: Borislav Petkov <bp@suse.de>
Link: https://lore.kernel.org/r/CAHk-=wh=Mu_EYhtOmPn6AxoQZyEh-4fo2Zx3G7rBv1g7vwoKiw@mail.gmail.com
Linux kernel
============
There are several guides for kernel developers and users. These guides can
be rendered in a number of formats, like HTML and PDF. Please read
Documentation/admin-guide/README.rst first.
In order to build the documentation, use ``make htmldocs`` or
``make pdfdocs``. The formatted documentation can also be read online at:
https://www.kernel.org/doc/html/latest/
There are various text files in the Documentation/ subdirectory,
several of them using the Restructured Text markup notation.
Please read the Documentation/process/changes.rst file, as it contains the
requirements for building and running the kernel, and information about
the problems which may result by upgrading your kernel.
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