使用Trace-Event解决系统不能深度睡眠
导读 最近遇到一个问题,系统不能睡眠到c7s, 只能睡眠到c3. (c-state不能到c7s, cpu的c-state, c0是运行态,其它状态都是idle态,睡眠的越深,c-state的值越大)。
使用Trace-Event解决系统不能深度睡眠使用Trace-Event解决系统不能深度睡眠
发现问题后,我的第一感觉是不是系统很忙导致, 使用pert top看一下耗cpu的进程和热点函数:
perf top -E 100 --stdio > perf-top.txt
19.85% perf [.] __symbols__insert
7.68% perf [.] rb_next
4.60% libc-2.26.so [.] __strcmp_sse2_unaligned
4.20% libelf-0.168.so [.] gelf_getsym
3.92% perf [.] dso__load_sym
3.86% libc-2.26.so [.] _int_malloc
3.60% libc-2.26.so [.] __libc_calloc
3.30% libc-2.26.so [.] vfprintf
2.95% perf [.] rb_insert_color
2.61% [kernel] [k] prepare_exit_to_usermode
2.51% perf [.] machine__map_x86_64_entry_trampolines
2.31% perf [.] symbol__new
2.22% [kernel] [k] do_syscall_64
2.11% libc-2.26.so [.] __strlen_avx2
发现系统中只有perf工具本身比较耗cpu :(
然后就想到是不是系统中某个进程搞的鬼,不让cpu睡眠到c7s. 这时候使用trace event监控一下系统中sched_switch事件. 使用trace-cmd工具监控所有cpu上的sched_switch(进程切换)事件30秒:
#trace-cmd record -e sched:sched_switch -M -1 sleep 30
CPU0 data recorded at offset=0x63e000
102400 bytes in size
CPU1 data recorded at offset=0x657000
8192 bytes in size
CPU2 data recorded at offset=0x659000
20480 bytes in size
CPU3 data recorded at offset=0x65e000
20480 bytes in size
使用trace-cmd report 查看一下监控结果,但是查看这样的原始数据不够直观,没有某个进程被切换到的统计信息:
#trace-cmd report
cpus=4
trace-cmd-19794 [001] 225127.464466: sched_switch: trace-cmd:19794 [120] S ==> swapper/1:0 [120]
trace-cmd-19795 [003] 225127.464601: sched_switch: trace-cmd:19795 [120] S ==> swapper/3:0 [120]
sleep-19796 [002] 225127.464792: sched_switch: sleep:19796 [120] S ==> swapper/2:0 [120]
-0 [003] 225127.471948: sched_switch: swapper/3:0 [120] R ==> rcu_sched:11 [120]
rcu_sched-11 [003] 225127.471950: sched_switch: rcu_sched:11 [120] W ==> swapper/3:0 [120]
-0 [003] 225127.479959: sched_switch: swapper/3:0 [120] R ==> rcu_sched:11 [120]
rcu_sched-11 [003] 225127.479960: sched_switch: rcu_sched:11 [120] W ==> swapper/3:0 [120]
-0 [003] 225127.487959: sched_switch: swapper/3:0 [120] R ==> rcu_sched:11 [120]
rcu_sched-11 [003] 225127.487961: sched_switch: rcu_sched:11 [120] W ==> swapper/3:0 [120]
-0 [002] 225127.491959: sched_switch: swapper/2:0 [120] R ==> kworker/2:2:19735 [120]
kworker/2:2-19735 [002] 225127.491972: sched_switch: kworker/2:2:19735 [120] W ==> swapper/2:0 [120]
trace-cmd report 的结果使用正则表达式过滤一下,然后排序统计:
trace-cmd report | grep -o '==> [^ ]\+:\?' | sort | uniq -c
3 ==> irqbalance:1034
3 ==> khugepaged:43
20 ==> ksoftirqd/0:10
1 ==> ksoftirqd/1:18
18 ==> ksoftirqd/3:30
1 ==> kthreadd:19798
1 ==> kthreadd:2
4 ==> kworker/0:0:19785
1 ==> kworker/0:1:19736
5 ==> kworker/0:1:19798
5 ==> kworker/0:1H:364
53 ==> kworker/0:2:19614
19 ==> kworker/1:1:7665
30 ==> tuned:19498
...
发现可疑线程tuned,30秒内被切换到运行了30次,其它线程都是常规线程。
此时查看一下系统中是否开启了tuned服务:
使用Trace-Event解决系统不能深度睡眠使用Trace-Event解决系统不能深度睡眠
果真是系统开启了tuned服务,然后拉起了名字为tuned的线程.
查看一下tuned服务的配置文件:
localhost:/home/jeff # tuned-adm active
Current active profile: sap-hana
localhost:/home/jeff # cat /usr/lib/tuned/sap-hana/tuned.conf
[main]
summary=Optimize for SAP NetWeaver, SAP HANA and HANA based products
[cpu]
force_latency = 70
发现关于cpu这一项,设置强制延迟时间为70秒 force_latency = 70 ,这个是为了优化HANA数据库。
到底force_latency怎样起作用,经过一顿搜索,发现这个值是被设置进了/dev/cpu_dma_latency
使用lsof /dev/cpu_dma_latency, 发现tuned线程确实是在操作这个文件
#lsof /dev/cpu_dma_latency
COMMAND PID USER FD TYPE DEVICE SIZE/OFF NODE NAME
tuned 18734 root 9w CHR 10,60 0t0 11400 /dev/cpu_dma_latency
而且Linux内核文档也说明了/dev/cpu_dma_latency文件,如果要对它进行写操作,要open之后写数据之后不close,如果释放掉了文件描述符它就又会恢复到默认值,这也印证了上面lsof /dev/cpu_dma_latency是有输出结果的.
https://github.com/torvalds/linux/blob/v5.8/Documentation/trace/coresight/coresight-cpu-debug.rst
As specified in the PM QoS documentation the requested parameter
will stay in effect until the file descriptor is released. For example:
# exec 3<> /dev/cpu_dma_latency; echo 0 >&3
...
Do some work...
...
# exec 3<>-
查看一下/dev/cpu_dma_latency文件的内容,确实是70,也就是(force_latency = 70)
localhost:/home/jeff # cat /dev/cpu_dma_latency | hexdump -Cv
00000000 46 00 00 00 |F...|
localhost:/home/jeff # echo $((0x46))
70
此时查看一下系统中cpu各个睡眠态的描述和延迟时间值:
# cd /sys/devices/system/cpu/cpu0/cpuidle/
# for state in * ; do
echo -e \
"STATE: $state\t\
DESC: $(cat $state/desc)\t\
NAME: $(cat $state/name)\t\
LATENCY: $(cat $state/latency)\t\
RESIDENCY: $(cat $state/residency)"
done
发现C3态的延迟时间是33微秒,C4的延时时间是133微秒,所以(force_latency = 70) ,
系统就只能睡眠到C3了 .(延迟时间就是从此睡眠态唤醒到运行态的时间)
STATE: state0 DESC: CPUIDLE CORE POLL IDLE NAME: POLL LATENCY: 0 RESIDENCY: 0
STATE: state1 DESC: MWAIT 0x00 NAME: C1 LATENCY: 2 RESIDENCY: 2
STATE: state2 DESC: MWAIT 0x01 NAME: C1E LATENCY: 10 RESIDENCY: 20
STATE: state3 DESC: MWAIT 0x10 NAME: C3 LATENCY: 33 RESIDENCY: 100
STATE: state4 DESC: MWAIT 0x20 NAME: C6 LATENCY: 133 RESIDENCY: 400
STATE: state5 DESC: MWAIT 0x32 NAME: C7s LATENCY: 166 RESIDENCY: 500
此时关闭tuned 服务, 再查看一下 /dev/cpu_dma_latency的值,变成了默认的2000秒
localhost:/home/jeff # tuned-adm off
localhost:/home/jeff # cat /dev/cpu_dma_latency | hexdump -Cv
00000000 00 94 35 77 |..5w|
localhost:/home/jeff # echo $((0x77359400))
2000000000
然后验证一下,此时系统可以睡眠到C7s了,此问题得到解决 :)
解决此问题,主要用到了Linux内核本身提供的trace-event.
所以任何一个功能都不能小看,内核就是这样,一般看上去很无聊的功能,被一些工程师用很认真的态度打磨出来之后,潜力还是非常大的:)Linux就该这么学