perf-record.txt

perf-record(1)
==============

NAME
----
perf-record - Run a command and record its profile into perf.data

SYNOPSIS
--------
[verse]
'perf record' [-e <EVENT> | --event=EVENT] [-l] [-a] <command>
'perf record' [-e <EVENT> | --event=EVENT] [-l] [-a] -- <command> [<options>]

DESCRIPTION
-----------
This command runs a command and gathers a performance counter profile
from it, into perf.data - without displaying anything.

This file can then be inspected later on, using 'perf report'.


OPTIONS
-------
<command>...::
	Any command you can specify in a shell.

-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 PMU event like 'pmu/param1=0x3,param2/' where
	  'param1', 'param2', etc are defined as formats for the PMU in
	  /sys/bus/event_sources/devices/<pmu>/format/*.

	- a symbolically formed event like 'pmu/config=M,config1=N,config3=K/'

          where M, N, K are numbers (in decimal, hex, octal format). Acceptable
          values for each of 'config', 'config1' and 'config2' are defined by
          corresponding entries in /sys/bus/event_sources/devices/<pmu>/format/*
          param1 and param2 are defined as formats for the PMU in:
          /sys/bus/event_sources/devices/<pmu>/format/*

        - a hardware breakpoint event in the form of '\mem:addr[/len][:access]'
          where addr is the address in memory you want to break in.
          Access is the memory access type (read, write, execute) it can
          be passed as follows: '\mem:addr[:[r][w][x]]'. len is the range,
          number of bytes from specified addr, which the breakpoint will cover.
          If you want to profile read-write accesses in 0x1000, just set
          'mem:0x1000:rw'.
          If you want to profile write accesses in [0x1000~1008), just set
          'mem:0x1000/8:w'.

	- a group of events surrounded by a pair of brace ("{event1,event2,...}").
	  Each event is separated by commas and the group should be quoted to
	  prevent the shell interpretation.  You also need to use --group on
	  "perf report" to view group events together.

--filter=<filter>::
        Event filter.

-a::
--all-cpus::
        System-wide collection from all CPUs.

-p::
--pid=::
	Record events on existing process ID (comma separated list).

-t::
--tid=::
        Record events on existing thread ID (comma separated list).
        This option also disables inheritance by default.  Enable it by adding
        --inherit.

-u::
--uid=::
        Record events in threads owned by uid. Name or number.

-r::
--realtime=::
	Collect data with this RT SCHED_FIFO priority.

--no-buffering::
	Collect data without buffering.

-c::
--count=::
	Event period to sample.

-o::
--output=::
	Output file name.

-i::
--no-inherit::
	Child tasks do not inherit counters.
-F::
--freq=::
	Profile at this frequency.

-m::
--mmap-pages=::
	Number of mmap data pages (must be a power of two) or size
	specification with appended unit character - B/K/M/G. The
	size is rounded up to have nearest pages power of two value.
	Also, by adding a comma, the number of mmap pages for AUX
	area tracing can be specified.

--group::
	Put all events in a single event group.  This precedes the --event
	option and remains only for backward compatibility.  See --event.

-g::
	Enables call-graph (stack chain/backtrace) recording.

--call-graph::
	Setup and enable call-graph (stack chain/backtrace) recording,
	implies -g.

	Allows specifying "fp" (frame pointer) or "dwarf"
	(DWARF's CFI - Call Frame Information) or "lbr"
	(Hardware Last Branch Record facility) as the method to collect
	the information used to show the call graphs.

	In some systems, where binaries are build with gcc
	--fomit-frame-pointer, using the "fp" method will produce bogus
	call graphs, using "dwarf", if available (perf tools linked to
	the libunwind library) should be used instead.
	Using the "lbr" method doesn't require any compiler options. It
	will produce call graphs from the hardware LBR registers. The
	main limition is that it is only available on new Intel
	platforms, such as Haswell. It can only get user call chain. It
	doesn't work with branch stack sampling at the same time.

-q::
--quiet::
	Don't print any message, useful for scripting.

-v::
--verbose::
	Be more verbose (show counter open errors, etc).

-s::
--stat::
	Record per-thread event counts.  Use it with 'perf report -T' to see
	the values.

-d::
--data::
	Record the sample addresses.

-T::
--timestamp::
	Record the sample timestamps. Use it with 'perf report -D' to see the
	timestamps, for instance.

-P::
--period::
	Record the sample period.

-n::
--no-samples::
	Don't sample.

-R::
--raw-samples::
Collect raw sample records from all opened counters (default for tracepoint counters).

-C::
--cpu::
Collect samples 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 with inheritance mode on (default), samples are captured only when
the thread executes on the designated CPUs. Default is to monitor all CPUs.

-N::
--no-buildid-cache::
Do not update the buildid cache. This saves some overhead in situations
where the information in the perf.data file (which includes buildids)
is sufficient.

-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.

-b::
--branch-any::
Enable taken branch stack sampling. Any type of taken branch may be sampled.
This is a shortcut for --branch-filter any. See --branch-filter for more infos.

-j::
--branch-filter::
Enable taken branch stack sampling. Each sample captures a series of consecutive
taken branches. The number of branches captured with each sample depends on the
underlying hardware, the type of branches of interest, and the executed code.
It is possible to select the types of branches captured by enabling filters. The
following filters are defined:

        - any:  any type of branches
        - any_call: any function call or system call
        - any_ret: any function return or system call return
        - ind_call: any indirect branch
        - u:  only when the branch target is at the user level
        - k: only when the branch target is in the kernel
        - hv: only when the target is at the hypervisor level
	- in_tx: only when the target is in a hardware transaction
	- no_tx: only when the target is not in a hardware transaction
	- abort_tx: only when the target is a hardware transaction abort
	- cond: conditional branches

+
The option requires at least one branch type among any, any_call, any_ret, ind_call, cond.
The privilege levels may be omitted, in which case, the privilege levels of the associated
event are applied to the branch filter. Both kernel (k) and hypervisor (hv) privilege
levels are subject to permissions.  When sampling on multiple events, branch stack sampling
is enabled for all the sampling events. The sampled branch type is the same for all events.
The various filters must be specified as a comma separated list: --branch-filter any_ret,u,k
Note that this feature may not be available on all processors.

--weight::
Enable weightened sampling. An additional weight is recorded per sample and can be
displayed with the weight and local_weight sort keys.  This currently works for TSX
abort events and some memory events in precise mode on modern Intel CPUs.

--transaction::
Record transaction flags for transaction related events.

--per-thread::
Use per-thread mmaps.  By default per-cpu mmaps are created.  This option
overrides that and uses per-thread mmaps.  A side-effect of that is that
inheritance is automatically disabled.  --per-thread is ignored with a warning
if combined with -a or -C options.

-D::
--delay=::
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.

-I::
--intr-regs::
Capture machine state (registers) at interrupt, i.e., on counter overflows for
each sample. List of captured registers depends on the architecture. This option
is off by default.

--running-time::
Record running and enabled time for read events (:S)

-k::
--clockid::
Sets the clock id to use for the various time fields in the perf_event_type
records. See clock_gettime(). In particular CLOCK_MONOTONIC and
CLOCK_MONOTONIC_RAW are supported, some events might also allow
CLOCK_BOOTTIME, CLOCK_REALTIME and CLOCK_TAI.

-S::
--snapshot::
Select AUX area tracing Snapshot Mode. This option is valid only with an
AUX area tracing event. Optionally the number of bytes to capture per
snapshot can be specified. In Snapshot Mode, trace data is captured only when
signal SIGUSR2 is received.

--proc-map-timeout::
When processing pre-existing threads /proc/XXX/mmap, it may take a long time,
because the file may be huge. A time out is needed in such cases.
This option sets the time out limit. The default value is 500 ms.

SEE ALSO
--------
linkperf:perf-stat[1], linkperf:perf-list[1]