NAME¶
perf-stat - Run a command and gather performance counter
statistics
SYNOPSIS¶
perf stat [-e <EVENT> | --event=EVENT] [-a] <command>
perf stat [-e <EVENT> | --event=EVENT] [-a] — <command> [<options>]
perf stat [-e <EVENT> | --event=EVENT] [-a] record [-o file] — <command> [<options>]
perf stat report [-i file]
DESCRIPTION¶
This command runs a command and gathers performance counter
statistics from it.
OPTIONS¶
<command>...
Any command you can specify in a shell.
record
See STAT RECORD.
report
See STAT REPORT.
-e, --event=
Select the PMU event. Selection can be:
•a symbolic event name (use perf list to
list all events)
•a raw PMU event (eventsel+umask) in the form of
rNNN where NNN is a hexadecimal event descriptor.
•a symbolically formed event like
pmu/param1=0x3,param2/ where param1 and param2 are defined as formats
for the PMU in /sys/bus/event_source/devices/<pmu>/format/*
'percore' is a event qualifier that sums up the event counts for both
hardware threads in a core. For example:
perf stat -A -a -e cpu/event,percore=1/,otherevent ...
•a symbolically formed event like
pmu/config=M,config1=N,config2=K/ where M, N, K are numbers (in
decimal, hex, octal format). Acceptable values for each of
config,
config1 and
config2 parameters are defined by corresponding
entries in /sys/bus/event_source/devices/<pmu>/format/*
Note that the last two syntaxes support prefix and glob matching in
the PMU name to simplify creation of events accross multiple instances
of the same type of PMU in large systems (e.g. memory controller PMUs).
Multiple PMU instances are typical for uncore PMUs, so the prefix
'uncore_' is also ignored when performing this match.
-i, --no-inherit
child tasks do not inherit counters
-p, --pid=<pid>
stat events on existing process id (comma separated
list)
-t, --tid=<tid>
stat events on existing thread id (comma separated
list)
-a, --all-cpus
system-wide collection from all CPUs (default if no
target is specified)
-c, --scale
scale/normalize counter values
-d, --detailed
print more detailed statistics, can be specified up to 3
times
-d: detailed events, L1 and LLC data cache
-d -d: more detailed events, dTLB and iTLB events
-d -d -d: very detailed events, adding prefetch events
-r, --repeat=<n>
repeat command and print average + stddev (max: 100). 0
means forever.
-B, --big-num
print large numbers with thousands' separators according
to locale
-C, --cpu=
Count only on the list of CPUs provided. Multiple CPUs
can be provided as a comma-separated list with no space: 0,1. Ranges of CPUs
are specified with -: 0-2. In per-thread mode, this option is ignored. The -a
option is still necessary to activate system-wide monitoring. Default is to
count on all CPUs.
-A, --no-aggr
Do not aggregate counts across all monitored CPUs.
-n, --null
null run - don’t start any counters
-v, --verbose
be more verbose (show counter open errors, etc)
-x SEP, --field-separator SEP
print counts using a CSV-style output to make it easy to
import directly into spreadsheets. Columns are separated by the string
specified in SEP.
--table
Display time for each run (-r option), in a table format,
e.g.:
$ perf stat --null -r 5 --table perf bench sched pipe
Performance counter stats for 'perf bench sched pipe' (5 runs):
# Table of individual measurements:
5.189 (-0.293) #
5.189 (-0.294) #
5.186 (-0.296) #
5.663 (+0.181) ##
6.186 (+0.703) ####
# Final result:
5.483 +- 0.198 seconds time elapsed ( +- 3.62% )
-G name, --cgroup name
monitor only in the container (cgroup) called
"name". This option is available only in per-cpu mode. The cgroup
filesystem must be mounted. All threads belonging to container
"name" are monitored when they run on the monitored CPUs. Multiple
cgroups can be provided. Each cgroup is applied to the corresponding event,
i.e., first cgroup to first event, second cgroup to second event and so on. It
is possible to provide an empty cgroup (monitor all the time) using, e.g., -G
foo,,bar. Cgroups must have corresponding events, i.e., they always refer to
events defined earlier on the command line. If the user wants to track
multiple events for a specific cgroup, the user can use -e e1 -e e2 -G
foo,foo or just use -e e1 -e e2 -G foo.
If wanting to monitor, say, cycles for a cgroup and also
for system wide, this command line can be used: perf stat -e cycles -G
cgroup_name -a -e cycles.
-o file, --output file
Print the output into the designated file.
--append
Append to the output file designated with the -o option.
Ignored if -o is not specified.
--log-fd
Log output to fd, instead of stderr. Complementary to
--output, and mutually exclusive with it. --append may be used here. Examples:
3>results perf stat --log-fd 3 — $cmd 3>>results perf stat
--log-fd 3 --append — $cmd
--pre, --post
Pre and post measurement hooks, e.g.:
perf stat --repeat 10 --null --sync --pre make -s
O=defconfig-build/clean — make -s -j64 O=defconfig-build/
bzImage
-I msecs, --interval-print msecs
Print count deltas every N milliseconds (minimum: 1ms)
The overhead percentage could be high in some cases, for instance with small,
sub 100ms intervals. Use with caution. example: perf stat -I 1000 -e cycles
-a sleep 5
--interval-count times
Print count deltas for fixed number of times. This option
should be used together with "-I" option. example: perf stat -I
1000 --interval-count 2 -e cycles -a
--interval-clear
Clear the screen before next interval.
--timeout msecs
Stop the perf stat session and print count deltas
after N milliseconds (minimum: 10 ms). This option is not supported with the
"-I" option. example: perf stat --time 2000 -e cycles
-a
--metric-only
Only print computed metrics. Print them in a single line.
Don’t show any raw values. Not supported with --per-thread.
--per-socket
Aggregate counts per processor socket for system-wide
mode measurements. This is a useful mode to detect imbalance between sockets.
To enable this mode, use --per-socket in addition to -a. (system-wide). The
output includes the socket number and the number of online processors on that
socket. This is useful to gauge the amount of aggregation.
--per-die
Aggregate counts per processor die for system-wide mode
measurements. This is a useful mode to detect imbalance between dies. To
enable this mode, use --per-die in addition to -a. (system-wide). The output
includes the die number and the number of online processors on that die. This
is useful to gauge the amount of aggregation.
--per-core
Aggregate counts per physical processor for system-wide
mode measurements. This is a useful mode to detect imbalance between physical
cores. To enable this mode, use --per-core in addition to -a. (system-wide).
The output includes the core number and the number of online logical
processors on that physical processor.
--per-thread
Aggregate counts per monitored threads, when monitoring
threads (-t option) or processes (-p option).
-D msecs, --delay msecs
After starting the program, wait msecs before measuring.
This is useful to filter out the startup phase of the program, which is often
very different.
-T, --transaction
Print statistics of transactional execution if
supported.
STAT RECORD¶
Stores stat data into perf data file.
-o file, --output file
Output file name.
STAT REPORT¶
Reads and reports stat data from perf data file.
-i file, --input file
Input file name.
--per-socket
Aggregate counts per processor socket for system-wide
mode measurements.
--per-die
Aggregate counts per processor die for system-wide mode
measurements.
--per-core
Aggregate counts per physical processor for system-wide
mode measurements.
-M, --metrics
Print metrics or metricgroups specified in a comma
separated list. For a group all metrics from the group are added. The events
from the metrics are automatically measured. See perf list output for the
possble metrics and metricgroups.
-A, --no-aggr
Do not aggregate counts across all monitored CPUs.
--topdown
Print top down level 1 metrics if supported by the CPU.
This allows to determine bottle necks in the CPU pipeline for CPU bound
workloads, by breaking the cycles consumed down into frontend bound, backend
bound, bad speculation and retiring.
Frontend bound means that the CPU cannot fetch and decode
instructions fast enough. Backend bound means that computation or memory
access is the bottle neck. Bad Speculation means that the CPU wasted cycles
due to branch mispredictions and similar issues. Retiring means that the CPU
computed without an apparently bottleneck. The bottleneck is only the real
bottleneck if the workload is actually bound by the CPU and not by something
else.
For best results it is usually a good idea to use it with interval
mode like -I 1000, as the bottleneck of workloads can change often.
The top down metrics are collected per core instead of per CPU
thread. Per core mode is automatically enabled and -a (global monitoring) is
needed, requiring root rights or perf.perf_event_paranoid=-1.
Topdown uses the full Performance Monitoring Unit, and needs
disabling of the NMI watchdog (as root): echo 0 >
/proc/sys/kernel/nmi_watchdog for best results. Otherwise the bottlenecks
may be inconsistent on workload with changing phases.
This enables --metric-only, unless overriden with
--no-metric-only.
To interpret the results it is usually needed to know on which
CPUs the workload runs on. If needed the CPUs can be forced using
taskset.
--no-merge
Do not merge results from same PMUs.
When multiple events are created from a single event
specification, stat will, by default, aggregate the event counts and show
the result in a single row. This option disables that behavior and shows the
individual events and counts.
Multiple events are created from a single event specification
when: 1. Prefix or glob matching is used for the PMU name. 2. Aliases, which
are listed immediately after the Kernel PMU events by perf list, are
used.
--smi-cost
Measure SMI cost if msr/aperf/ and msr/smi/ events are
supported.
During the measurement, the /sys/device/cpu/freeze_on_smi will be
set to freeze core counters on SMI. The aperf counter will not be effected
by the setting. The cost of SMI can be measured by (aperf - unhalted core
cycles).
In practice, the percentages of SMI cycles is very useful for
performance oriented analysis. --metric_only will be applied by default. The
output is SMI cycles%, equals to (aperf - unhalted core cycles) / aperf
Users who wants to get the actual value can apply
--no-metric-only.
EXAMPLES¶
$ perf stat — make
Performance counter stats for 'make':
83723.452481 task-clock:u (msec) # 1.004 CPUs utilized
0 context-switches:u # 0.000 K/sec
0 cpu-migrations:u # 0.000 K/sec
3,228,188 page-faults:u # 0.039 M/sec
229,570,665,834 cycles:u # 2.742 GHz
313,163,853,778 instructions:u # 1.36 insn per cycle
69,704,684,856 branches:u # 832.559 M/sec
2,078,861,393 branch-misses:u # 2.98% of all branches
83.409183620 seconds time elapsed
74.684747000 seconds user
8.739217000 seconds sys
TIMINGS¶
As displayed in the example above we can display 3 types of
timings. We always display the time the counters were enabled/alive:
83.409183620 seconds time elapsed
For workload sessions we also display time the workloads spent in
user/system lands:
74.684747000 seconds user
8.739217000 seconds sys
Those times are the very same as displayed by the time
tool.
With -x, perf stat is able to output a not-quite-CSV format output
Commas in the output are not put into "". To make it easy to parse
it is recommended to use a different character like -x \;
The fields are in this order:
•optional usec time stamp in fractions of second
(with -I xxx)
•optional CPU, core, or socket identifier
•optional number of logical CPUs aggregated
•counter value
•unit of the counter value or empty
•event name
•run time of counter
•percentage of measurement time the counter was
running
•optional variance if multiple values are
collected with -r
•optional metric value
•optional unit of metric
Additional metrics may be printed with all earlier fields being
empty.