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98 lines
4.6 KiB
98 lines
4.6 KiB
commit d3c57027470b78dba79c6d931e4e409b1fecfc80
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Author: Patrick McGehearty <patrick.mcgehearty@oracle.com>
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Date: Mon Sep 28 20:11:28 2020 +0000
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Reversing calculation of __x86_shared_non_temporal_threshold
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The __x86_shared_non_temporal_threshold determines when memcpy on x86
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uses non_temporal stores to avoid pushing other data out of the last
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level cache.
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This patch proposes to revert the calculation change made by H.J. Lu's
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patch of June 2, 2017.
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H.J. Lu's patch selected a threshold suitable for a single thread
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getting maximum performance. It was tuned using the single threaded
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large memcpy micro benchmark on an 8 core processor. The last change
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changes the threshold from using 3/4 of one thread's share of the
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cache to using 3/4 of the entire cache of a multi-threaded system
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before switching to non-temporal stores. Multi-threaded systems with
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more than a few threads are server-class and typically have many
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active threads. If one thread consumes 3/4 of the available cache for
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all threads, it will cause other active threads to have data removed
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from the cache. Two examples show the range of the effect. John
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McCalpin's widely parallel Stream benchmark, which runs in parallel
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and fetches data sequentially, saw a 20% slowdown with this patch on
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an internal system test of 128 threads. This regression was discovered
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when comparing OL8 performance to OL7. An example that compares
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normal stores to non-temporal stores may be found at
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https://vgatherps.github.io/2018-09-02-nontemporal/. A simple test
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shows performance loss of 400 to 500% due to a failure to use
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nontemporal stores. These performance losses are most likely to occur
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when the system load is heaviest and good performance is critical.
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The tunable x86_non_temporal_threshold can be used to override the
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default for the knowledgable user who really wants maximum cache
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allocation to a single thread in a multi-threaded system.
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The manual entry for the tunable has been expanded to provide
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more information about its purpose.
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modified: sysdeps/x86/cacheinfo.c
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modified: manual/tunables.texi
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Conflicts:
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manual/tunables.texi
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(Downstream uses the glibc.tune namespace, upstream uses
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glibc.cpu.)
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sysdeps/x86/cacheinfo.c
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(Downstream does not have rep_movsb_threshold,
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x86_rep_stosb_threshold tunables.)
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diff --git a/manual/tunables.texi b/manual/tunables.texi
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index 3dc6f9a44592c030..3e1e519dff153b09 100644
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--- a/manual/tunables.texi
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+++ b/manual/tunables.texi
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@@ -364,7 +364,11 @@ set shared cache size in bytes for use in memory and string routines.
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@deftp Tunable glibc.tune.x86_non_temporal_threshold
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The @code{glibc.tune.x86_non_temporal_threshold} tunable allows the user
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-to set threshold in bytes for non temporal store.
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+to set threshold in bytes for non temporal store. Non temporal stores
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+give a hint to the hardware to move data directly to memory without
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+displacing other data from the cache. This tunable is used by some
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+platforms to determine when to use non temporal stores in operations
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+like memmove and memcpy.
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This tunable is specific to i386 and x86-64.
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@end deftp
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diff --git a/sysdeps/x86/cacheinfo.c b/sysdeps/x86/cacheinfo.c
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index b9444ddd52051e05..42b468d0c4885bad 100644
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--- a/sysdeps/x86/cacheinfo.c
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+++ b/sysdeps/x86/cacheinfo.c
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@@ -778,14 +778,20 @@ intel_bug_no_cache_info:
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__x86_shared_cache_size = shared;
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}
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- /* The large memcpy micro benchmark in glibc shows that 6 times of
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- shared cache size is the approximate value above which non-temporal
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- store becomes faster on a 8-core processor. This is the 3/4 of the
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- total shared cache size. */
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+ /* The default setting for the non_temporal threshold is 3/4 of one
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+ thread's share of the chip's cache. For most Intel and AMD processors
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+ with an initial release date between 2017 and 2020, a thread's typical
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+ share of the cache is from 500 KBytes to 2 MBytes. Using the 3/4
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+ threshold leaves 125 KBytes to 500 KBytes of the thread's data
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+ in cache after a maximum temporal copy, which will maintain
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+ in cache a reasonable portion of the thread's stack and other
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+ active data. If the threshold is set higher than one thread's
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+ share of the cache, it has a substantial risk of negatively
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+ impacting the performance of other threads running on the chip. */
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__x86_shared_non_temporal_threshold
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= (cpu_features->non_temporal_threshold != 0
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? cpu_features->non_temporal_threshold
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- : __x86_shared_cache_size * threads * 3 / 4);
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+ : __x86_shared_cache_size * 3 / 4);
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}
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#endif
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