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On a machine with 256 CPUs, running the recently added perf breakpoint benchmark results in: | $> perf bench -r 30 breakpoint thread -b 4 -p 64 -t 64 | # Running 'breakpoint/thread' benchmark: | # Created/joined 30 threads with 4 breakpoints and 64 parallelism | Total time: 236.418 [sec] | | 123134.794271 usecs/op | 7880626.833333 usecs/op/cpu The benchmark tests inherited breakpoint perf events across many threads. Looking at a perf profile, we can see that the majority of the time is spent in various hw_breakpoint.c functions, which execute within the 'nr_bp_mutex' critical sections which then results in contention on that mutex as well: 37.27% [kernel] [k] osq_lock 34.92% [kernel] [k] mutex_spin_on_owner 12.15% [kernel] [k] toggle_bp_slot 11.90% [kernel] [k] __reserve_bp_slot The culprit here is task_bp_pinned(), which has a runtime complexity of O(#tasks) due to storing all task breakpoints in the same list and iterating through that list looking for a matching task. Clearly, this does not scale to thousands of tasks. Instead, make use of the "rhashtable" variant "rhltable" which stores multiple items with the same key in a list. This results in average runtime complexity of O(1) for task_bp_pinned(). With the optimization, the benchmark shows: | $> perf bench -r 30 breakpoint thread -b 4 -p 64 -t 64 | # Running 'breakpoint/thread' benchmark: | # Created/joined 30 threads with 4 breakpoints and 64 parallelism | Total time: 0.208 [sec] | | 108.422396 usecs/op | 6939.033333 usecs/op/cpu On this particular setup that's a speedup of ~1135x. While one option would be to make task_struct a breakpoint list node, this would only further bloat task_struct for infrequently used data. Furthermore, after all optimizations in this series, there's no evidence it would result in better performance: later optimizations make the time spent looking up entries in the hash table negligible (we'll reach the theoretical ideal performance i.e. no constraints). Signed-off-by: Marco Elver <elver@google.com> Signed-off-by: Peter Zijlstra (Intel) <peterz@infradead.org> Reviewed-by: Dmitry Vyukov <dvyukov@google.com> Acked-by: Ian Rogers <irogers@google.com> Link: https://lore.kernel.org/r/20220829124719.675715-5-elver@google.com |
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arch | ||
block | ||
certs | ||
crypto | ||
Documentation | ||
drivers | ||
fs | ||
include | ||
init | ||
io_uring | ||
ipc | ||
kernel | ||
lib | ||
LICENSES | ||
mm | ||
net | ||
samples | ||
scripts | ||
security | ||
sound | ||
tools | ||
usr | ||
virt | ||
.clang-format | ||
.cocciconfig | ||
.get_maintainer.ignore | ||
.gitattributes | ||
.gitignore | ||
.mailmap | ||
COPYING | ||
CREDITS | ||
Kbuild | ||
Kconfig | ||
MAINTAINERS | ||
Makefile | ||
README |
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.