The primary part of the patchset will introduce multithread support for search
cmd to improve its performance. A search operation is mainly made up with 2
steps: 1) readmem data into pagebuf, 2) search specific values within the
pagebuf. A typical workflow of search is as follows:
for addr from low to high:
do
readmem(addr, pagebuf)
search_value(value, pagebuf)
addr += pagesize
done
There are 2 points which we can accelerate: 1) readmem don't have to wait
search_value, when search_value is working, readmem can read the next pagebuf
at the same time. 2) higher addr don't have to wait lower addr, they can be
processed at the same time if we carefully arrange the output order.
For point 1, we introduce zones for pagebuf, e.g. search_value can work on
zone 0 while readmem can prepare the data for zone 1. For point 2, we introduce
multiple search_value in threads, e.g. readmem will prepare 100 pages as a
batch, then we will have 4 threads of search_value, thread 0 handles page 1~25,
thread 2 handles page 26~50 page, thread 3 handles page 51~75, thread 4 handles
page 76~100.
A typical workflow of multithread search implemented in this patchset is as
follows, which removed thread synchronization:
pagebuf[ZONE][BATCH]
zone_index = buf_index = 0
create_thread(4, search_value)
for addr from low to high:
do
if buf_index < BATCH
readmem(addr, pagebuf[zone_index][buf_index++])
addr += pagesize
else
start_thread(pagebuf[zone_index], 0/4 * BATCH, 1/4 * BATCH)
start_thread(pagebuf[zone_index], 1/4 * BATCH, 2/4 * BATCH)
start_thread(pagebuf[zone_index], 2/4 * BATCH, 3/4 * BATCH)
start_thread(pagebuf[zone_index], 3/4 * BATCH, 4/4 * BATCH)
zone_index++
buf_index = 0
fi
done
readmem works in the main process and not multi-threaded, because readmem will
not only read data from vmcore, decompress it, but walk through page tables if
virtual address given. It is hard to reimplement it into thread safe version,
search_value is easier to be made thread-safe. By carefully choose batch size
and thread num, we can maximize the concurrency.
The last part of the patchset, is replacing lseek/read to pread for kcore and
diskdumped vmcore.
Here is the performance test result chart. Please note the vmcore and
kcore are tested seperately on 2 different machines. crash-orig is the
crash compiled with clean upstream code, crash-pread is the code with only
pread patch applied(patch 5), crash-multi is the code with only multithread
patches applied(patch 1~4).
ulong search:
$ time echo "search abcd" | ./crash-orig vmcore vmlinux > /dev/null
$ time echo "search abcd -f 4 -n 4" | ./crash-multi vmcore vmlinux >
/dev/null
45G vmcore 64G kcore
real user sys real user sys
crash-orig 16m56.595s 15m57.188s 0m56.698s 1m37.982s 0m51.625s 0m46.266s
crash-pread 16m46.366s 15m55.790s 0m48.894s 1m9.179s 0m36.646s 0m32.368s
crash-multi 16m26.713s 19m8.722s 1m29.263s 1m27.661s 0m57.789s 0m54.604s
string search:
$ time echo "search -c abcddbca" | ./crash-orig vmcore vmlinux >
/dev/null
$ time echo "search -c abcddbca -f 4 -n 4" | ./crash-multi vmcore vmlinux
> /dev/null
45G vmcore 64G kcore
real user sys real user sys
crash-orig 33m33.481s 32m38.321s 0m52.771s 8m32.034s 7m50.050s 0m41.478s
crash-pread 33m25.623s 32m35.019s 0m47.394s 8m4.347s 7m35.352s 0m28.479s
crash-multi 16m31.016s 38m27.456s 1m11.048s 5m11.725s 7m54.224s 0m44.186s
Discussion:
1) Either multithread and pread patches can improve the performance a
bit, so if both patches applied, the performance can be better.
2) Multi-thread search performs much better in search time consumptive
tasks, such as string search.
Tao Liu (5):
Introduce multi-thread to search_virtual
Introduce multi-thread to search_physical
Introduce multi-thread to string search
Introduce multi-thread options to search cmd
Replace lseek/read into pread for kcore and vmcore reading.
defs.h | 6 +
diskdump.c | 11 +-
help.c | 17 +-
memory.c | 1176 +++++++++++++++++++++++++++++++++++++++++-----------
netdump.c | 5 +-
task.c | 14 +
6 files changed, 969 insertions(+), 260 deletions(-)
--
2.33.1