tools/syscount_example.txt - platform/external/bcc - Git at Google

 Demonstrations of syscount, the Linux/eBPF version.


 syscount summarizes syscall counts across the system or a specific process,
 with optional latency information. It is very useful for general workload
 characterization, for example:

 # syscount
 Tracing syscalls, printing top 10... Ctrl+C to quit.
 [09:39:04]
 SYSCALL             COUNT
 write               10739
 read                10584
 wait4                1460
 nanosleep            1457
 select                795
 rt_sigprocmask        689
 clock_gettime         653
 rt_sigaction          128
 futex                  86
 ioctl                  83
 ^C

 These are the top 10 entries; you can get more by using the -T switch. Here,
 the output indicates that the write and read syscalls were very common, followed
 immediately by wait4, nanosleep, and so on. By default, syscount counts across
 the entire system, but we can point it to a specific process of interest:

 # syscount -p $(pidof dd)
 Tracing syscalls, printing top 10... Ctrl+C to quit.
 [09:40:21]
 SYSCALL             COUNT
 read              7878397
 write             7878397
 ^C

 Indeed, dd's workload is a bit easier to characterize. Occasionally, the count
 of syscalls is not enough, and you'd also want an aggregate latency:

 # syscount -L
 Tracing syscalls, printing top 10... Ctrl+C to quit.
 [09:41:32]
 SYSCALL                   COUNT        TIME (us)
 select                       16      3415860.022
 nanosleep                   291        12038.707
 ftruncate                     1          122.939
 write                         4           63.389
 stat                          1           23.431
 fstat                         1            5.088
 [unknown: 321]               32            4.965
 timerfd_settime               1            4.830
 ioctl                         3            4.802
 kill                          1            4.342
 ^C

 The select and nanosleep calls are responsible for a lot of time, but remember
 these are blocking calls. This output was taken from a mostly idle system. Note
 the "unknown" entry -- syscall 321 is the bpf() syscall, which is not in the
 table used by this tool (borrowed from strace sources).

 Another direction would be to understand which processes are making a lot of
 syscalls, thus responsible for a lot of activity. This is what the -P switch
 does:

 # syscount -P
 Tracing syscalls, printing top 10... Ctrl+C to quit.
 [09:58:13]
 PID    COMM               COUNT
 13820  vim                  548
 30216  sshd                 149
 29633  bash                  72
 25188  screen                70
 25776  mysqld                30
 31285  python                10
 529    systemd-udevd          9
 1      systemd                8
 494    systemd-journal        5
 ^C

 This is again from a mostly idle system over an interval of a few seconds.

 Sometimes, you'd only care about failed syscalls -- these are the ones that
 might be worth investigating with follow-up tools like opensnoop, execsnoop,
 or trace. Use the -x switch for this; the following example also demonstrates
 the -i switch, for printing at predefined intervals:

 # syscount -x -i 5
 Tracing failed syscalls, printing top 10... Ctrl+C to quit.
 [09:44:16]
 SYSCALL             COUNT
 futex                  13
 getxattr               10
 stat                    8
 open                    6
 wait4                   3
 access                  2
 [unknown: 321]          1

 [09:44:21]
 SYSCALL             COUNT
 futex                  12
 getxattr               10
 [unknown: 321]          2
 wait4                   1
 access                  1
 pause                   1
 ^C

 Similar to -x/--failures, sometimes you only care about certain syscall
 errors like EPERM or ENONET -- these are the ones that might be worth
 investigating with follow-up tools like opensnoop, execsnoop, or
 trace. Use the -e/--errno switch for this; the following example also
 demonstrates the -e switch, for printing ENOENT failures at predefined intervals:

 # syscount -e ENOENT -i 5
 Tracing syscalls, printing top 10... Ctrl+C to quit.
 [13:15:57]
 SYSCALL                   COUNT
 stat                       4669
 open                       1951
 access                      561
 lstat                        62
 openat                       42
 readlink                      8
 execve                        4
 newfstatat                    1

 [13:16:02]
 SYSCALL                   COUNT
 lstat                     18506
 stat                      13087
 open                       2907
 access                      412
 openat                       19
 readlink                     12
 execve                        7
 connect                       6
 unlink                        1
 rmdir                         1
 ^C

 USAGE:
 # syscount -h
 usage: syscount.py [-h] [-p PID] [-i INTERVAL] [-T TOP] [-x] [-e ERRNO] [-L]
                    [-m] [-P] [-l]

 Summarize syscall counts and latencies.

 optional arguments:
   -h, --help            show this help message and exit
   -p PID, --pid PID     trace only this pid
   -i INTERVAL, --interval INTERVAL
                         print summary at this interval (seconds)
   -d DURATION, --duration DURATION
 			total duration of trace, in seconds
   -T TOP, --top TOP     print only the top syscalls by count or latency
   -x, --failures        trace only failed syscalls (return < 0)
   -e ERRNO, --errno ERRNO
                         trace only syscalls that return this error (numeric or
                         EPERM, etc.)
   -L, --latency         collect syscall latency
   -m, --milliseconds    display latency in milliseconds (default:
                         microseconds)
   -P, --process         count by process and not by syscall
   -l, --list            print list of recognized syscalls and exit
	Demonstrations of syscount, the Linux/eBPF version.


	syscount summarizes syscall counts across the system or a specific process,
	with optional latency information. It is very useful for general workload
	characterization, for example:

	# syscount
	Tracing syscalls, printing top 10... Ctrl+C to quit.
	[09:39:04]
	SYSCALL COUNT
	write 10739
	read 10584
	wait4 1460
	nanosleep 1457
	select 795
	rt_sigprocmask 689
	clock_gettime 653
	rt_sigaction 128
	futex 86
	ioctl 83
	^C

	These are the top 10 entries; you can get more by using the -T switch. Here,
	the output indicates that the write and read syscalls were very common, followed
	immediately by wait4, nanosleep, and so on. By default, syscount counts across
	the entire system, but we can point it to a specific process of interest:

	# syscount -p $(pidof dd)
	Tracing syscalls, printing top 10... Ctrl+C to quit.
	[09:40:21]
	SYSCALL COUNT
	read 7878397
	write 7878397
	^C

	Indeed, dd's workload is a bit easier to characterize. Occasionally, the count
	of syscalls is not enough, and you'd also want an aggregate latency:

	# syscount -L
	Tracing syscalls, printing top 10... Ctrl+C to quit.
	[09:41:32]
	SYSCALL COUNT TIME (us)
	select 16 3415860.022
	nanosleep 291 12038.707
	ftruncate 1 122.939
	write 4 63.389
	stat 1 23.431
	fstat 1 5.088
	[unknown: 321] 32 4.965
	timerfd_settime 1 4.830
	ioctl 3 4.802
	kill 1 4.342
	^C

	The select and nanosleep calls are responsible for a lot of time, but remember
	these are blocking calls. This output was taken from a mostly idle system. Note
	the "unknown" entry -- syscall 321 is the bpf() syscall, which is not in the
	table used by this tool (borrowed from strace sources).

	Another direction would be to understand which processes are making a lot of
	syscalls, thus responsible for a lot of activity. This is what the -P switch
	does:

	# syscount -P
	Tracing syscalls, printing top 10... Ctrl+C to quit.
	[09:58:13]
	PID COMM COUNT
	13820 vim 548
	30216 sshd 149
	29633 bash 72
	25188 screen 70
	25776 mysqld 30
	31285 python 10
	529 systemd-udevd 9
	1 systemd 8
	494 systemd-journal 5
	^C

	This is again from a mostly idle system over an interval of a few seconds.

	Sometimes, you'd only care about failed syscalls -- these are the ones that
	might be worth investigating with follow-up tools like opensnoop, execsnoop,
	or trace. Use the -x switch for this; the following example also demonstrates
	the -i switch, for printing at predefined intervals:

	# syscount -x -i 5
	Tracing failed syscalls, printing top 10... Ctrl+C to quit.
	[09:44:16]
	SYSCALL COUNT
	futex 13
	getxattr 10
	stat 8
	open 6
	wait4 3
	access 2
	[unknown: 321] 1

	[09:44:21]
	SYSCALL COUNT
	futex 12
	getxattr 10
	[unknown: 321] 2
	wait4 1
	access 1
	pause 1
	^C

	Similar to -x/--failures, sometimes you only care about certain syscall
	errors like EPERM or ENONET -- these are the ones that might be worth
	investigating with follow-up tools like opensnoop, execsnoop, or
	trace. Use the -e/--errno switch for this; the following example also
	demonstrates the -e switch, for printing ENOENT failures at predefined intervals:

	# syscount -e ENOENT -i 5
	Tracing syscalls, printing top 10... Ctrl+C to quit.
	[13:15:57]
	SYSCALL COUNT
	stat 4669
	open 1951
	access 561
	lstat 62
	openat 42
	readlink 8
	execve 4
	newfstatat 1

	[13:16:02]
	SYSCALL COUNT
	lstat 18506
	stat 13087
	open 2907
	access 412
	openat 19
	readlink 12
	execve 7
	connect 6
	unlink 1
	rmdir 1
	^C

	USAGE:
	# syscount -h
	usage: syscount.py [-h] [-p PID] [-i INTERVAL] [-T TOP] [-x] [-e ERRNO] [-L]
	[-m] [-P] [-l]

	Summarize syscall counts and latencies.

	optional arguments:
	-h, --help show this help message and exit
	-p PID, --pid PID trace only this pid
	-i INTERVAL, --interval INTERVAL
	print summary at this interval (seconds)
	-d DURATION, --duration DURATION
	total duration of trace, in seconds
	-T TOP, --top TOP print only the top syscalls by count or latency
	-x, --failures trace only failed syscalls (return < 0)
	-e ERRNO, --errno ERRNO
	trace only syscalls that return this error (numeric or
	EPERM, etc.)
	-L, --latency collect syscall latency
	-m, --milliseconds display latency in milliseconds (default:
	microseconds)
	-P, --process count by process and not by syscall
	-l, --list print list of recognized syscalls and exit