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.TH STRESS-NG 1 "6 March 2022"
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.SH NAME
stress\-ng \- a tool to load and stress a computer system
.sp 1
.SH SYNOPSIS
.B stress\-ng
[\fIOPTION \fR[\fIARG\fR]] ...
.sp 1
.SH DESCRIPTION
stress\-ng will stress test a computer system in various selectable ways. It
was designed to exercise various physical subsystems of a computer as well
as the various operating system kernel interfaces.
stress\-ng also has a wide range of CPU specific stress tests that exercise
floating point, integer, bit manipulation and control flow.
.PP
stress\-ng was originally intended to make a machine work hard and trip
hardware issues such as thermal overruns as well as operating
system bugs that only occur when a system is being thrashed hard. Use
stress\-ng with caution as some of the tests can make a system run hot
on poorly designed hardware and also can cause excessive system thrashing
which may be difficult to stop.
.PP
stress\-ng can also measure test throughput rates; this can be
useful to observe performance changes across different
operating system releases or types of hardware. However, it has never been
intended to be used as a precise benchmark test suite, so do NOT use it
in this manner.
.PP
Running stress\-ng with root privileges will adjust out of memory settings
on Linux systems to make the stressors unkillable in low memory situations,
so use this judiciously.  With the appropriate privilege, stress\-ng can allow
the ionice class and ionice levels to be adjusted, again, this should be
used with care.
.PP
One can specify the number of processes to invoke per type of stress test;
specifying a zero value will select the number of processors
available as defined by sysconf(_SC_NPROCESSORS_CONF), if that can't be
determined then the number of online CPUs is used.  If the value is less
than zero then the number of online CPUs is used.
.SH OPTIONS
.PP
.B General stress\-ng control options:
.TP
.B \-\-abort
this option will force all running stressors to abort (terminate) if any
other stressor terminates prematurely because of a failure.
.TP
.B \-\-aggressive
enables more file, cache and memory aggressive options. This may slow tests
down, increase latencies and reduce the number of bogo ops as well as changing
the balance of user time vs system time used depending on the type of stressor
being used.
.TP
.B \-a N, \-\-all N, \-\-parallel N
start N instances of all stressors in parallel. If N is less than zero, then
the number of CPUs online is used for the number of instances.  If N is zero,
then the number of configured CPUs in the system is used.
.TP
.B \-b N, \-\-backoff N
wait N microseconds between the start of each stress worker process. This
allows one to ramp up the stress tests over time.
.TP
.B \-\-class name
specify the class of stressors to run. Stressors are classified into one or
more of the following classes: cpu, cpu-cache, device, io, interrupt,
filesystem, memory, network, os, pipe, scheduler and vm.  Some stressors fall
into just one class. For example the 'get' stressor is just in the 'os'
class. Other stressors fall into more than one class, for example,
the 'lsearch' stressor falls into the 'cpu', 'cpu-cache' and 'memory' classes
as it exercises all these three.  Selecting a specific class will run all
the stressors that fall into that class only when run with the \-\-sequential
option.

Specifying a name followed by a question mark (for example \-\-class vm?) will
print out all the stressors in that specific class.
.TP
.B \-n, \-\-dry\-run
parse options, but do not run stress tests. A no-op.
.TP
.B \-\-ftrace
enable kernel function call tracing (Linux only).  This will use the
kernel debugfs ftrace mechanism to record all the kernel functions
used on the system while stress-ng is running.  This is only as accurate
as the kernel ftrace output, so there may be some variability on the
data reported.
.TP
.B \-h, \-\-help
show help.
.TP
.B \-\-ignite\-cpu
alter kernel controls to try and maximize the CPU. This requires root
privilege to alter various /sys interface controls.  Currently this only
works for Intel P-State enabled x86 systems on Linux.
.TP
.B \-\-ionice\-class class
specify ionice class (only on Linux). Can be idle (default), besteffort, be,
realtime, rt.
.TP
.B \-\-ionice\-level level
specify ionice level (only on Linux). For idle, 0 is the only possible
option. For besteffort or realtime values 0 (highest priority) to 7 (lowest
priority). See ionice(1) for more details.
.TP
.B \-\-iostat S
every S seconds show I/O statistics on the device that stores the stress-ng
temporary files. This is either the device of the current working directory
or the \-\-temp\-path specified path. Currently a Linux only option.
The fields output are:
.TS
expand;
lB lB lB
l l s.
Column Heading	Explanation
T{
Inflight
T}	T{
number of I/O requests that have been issued to
the device driver but have not yet completed
T}
T{
Rd K/s
T}	T{
read rate in 1024 bytes per second
T}
T{
Wr K/s
T}	T{
write rate in 1024 bytes per second
T}
T{
Dscd K/s
T}	T{
discard rate in 1024 bytes per second
T}
T{
Rd/s
T}	T{
reads per second
T}
T{
Wr/s
T}	T{
writes per second
T}
T{
Dscd/s
T}	T{
discards per second
T}
.TE
.TP
.B \-\-job jobfile
run stressors using a jobfile.  The jobfile is essentially a file containing
stress-ng options (without the leading \-\-) with one option per line. Lines
may have comments with comment text proceeded by the # character. A simple
example is as follows:
.PP
.RS
.nf
run sequential   # run stressors sequentially
verbose          # verbose output
metrics-brief    # show metrics at end of run
timeout 60s      # stop each stressor after 60 seconds
#
# vm stressor options:
#
vm 2             # 2 vm stressors
vm-bytes 128M    # 128MB available memory
vm-keep          # keep vm mapping
vm-populate      # populate memory
#
# memcpy stressor options:
#
memcpy 5         # 5 memcpy stressors
.fi
.RE
.RS
.PP
The job file introduces the run command that specifies how to run the
stressors:
.PP
run sequential \- run stressors sequentially
.br
run parallel \- run stressors together in parallel
.PP
Note that 'run parallel' is the default.
.RE
.TP
.B \-\-keep\-files
do not remove files and directories created by the stressors. This can be
useful for debugging purposes. Not generally recommended as it can fill up
a file system.
.TP
.B \-k, \-\-keep\-name
by default, stress\-ng will attempt to change the name of the stress
processes according to their functionality; this option disables this and
keeps the process names to be the name of the parent process, that is,
stress\-ng.
.TP
.B \-\-klog\-check
check the kernel log for kernel error and warning messages and report these
as soon as they are detected. Linux only and requires root capability to read
the kernel log.
.TP
.B \-\-log\-brief
by default stress\-ng will report the name of the program, the message type
and the process id as a prefix to all output. The \-\-log\-brief option will
output messages without these fields to produce a less verbose output.
.TP
.B \-\-log\-file filename
write messages to the specified log file.
.TP
.B \-\-maximize
overrides the default stressor settings and instead sets these to the maximum
settings allowed.  These defaults can always be overridden by the per stressor
settings options if required.
.TP
.B \-\-max\-fd N
set the maximum limit on file descriptors (value or a % of system allowed
maximum).  By default, stress-ng can use all the available file descriptors;
this option sets the limit in the range from 10 up to the maximum limit of
RLIMIT_NOFILE.  One can use a % setting too, e.g. 50% is half the maximum
allowed file descriptors.  Note that stress-ng will use about 5 of the
available file descriptors so take this into consideration when using this
setting.
.TP
.B \-\-metrics
output number of bogo operations in total performed by the stress processes.
Note that these are not a reliable metric of performance or throughput and
have not been designed to be used for benchmarking whatsoever. The metrics are
just a useful way to observe how a system behaves when under various kinds of
load.
.RS
.PP
The following columns of information are output:
.TS
expand;
lB lB lB
l l s.
Column Heading	Explanation
T{
bogo ops
T}	T{
number of iterations of the stressor during the run. This is metric of
how much overall "work" has been achieved in bogo operations.
T}
T{
real time (secs)
T}	T{
average wall clock duration (in seconds) of the stressor. This is the total
wall clock time of all the instances of that particular stressor divided by
the number of these stressors being run.
T}
T{
usr time (secs)
T}	T{
total user time (in seconds) consumed running all the instances of the
stressor.
T}
T{
sys time (secs)
T}	T{
total system time (in seconds) consumed running all the instances of the
stressor.
T}
T{
bogo ops/s (real time)
T}	T{
total bogo operations per second based on wall clock run time. The wall clock
time reflects the apparent run time. The more processors one has on a system
the more the work load can be distributed onto these and hence the wall clock
time will reduce and the bogo ops rate will increase.  This is essentially
the "apparent" bogo ops rate of the system.
T}
T{
bogo ops/s (usr+sys time)
T}	T{
total bogo operations per second based on cumulative user and system time.
This is the real bogo ops rate of the system taking into consideration the
actual time execution time of the stressor across all the processors.
Generally this will decrease as one adds more concurrent stressors due to
contention on cache, memory, execution units, buses and I/O devices.
T}
T{
CPU used per instance (%)
T}	T{
total percentage of CPU used divided by number of stressor instances. 100%
is 1 full CPU. Some stressors run multiple threads so it is possible to have
a figure greater than 100%.
T}
.TE
.RE
.TP
.B \-\-metrics\-brief
show shorter list of stressor metrics (no CPU used per instance).
.TP
.B \-\-minimize
overrides the default stressor settings and instead sets these to the minimum
settings allowed.  These defaults can always be overridden by the per stressor
settings options if required.
.TP
.B \-\-no\-madvise
from version 0.02.26 stress\-ng automatically calls madvise(2) with random
advise options before each mmap and munmap to stress the vm subsystem a
little harder. The \-\-no\-advise option turns this default off.
.TP
.B \-\-no\-oom\-adjust
disable any form of out-of-memory score adjustments, keep the system defaults.
Normally stress-ng will adjust the out-of-memory scores on stressors to try
to create more memory pressure. This option disables the adjustments.
.TP
.B \-\-no\-rand\-seed
Do not seed the stress-ng pseudo-random number generator with a quasi random
start seed, but instead seed it with constant values. This forces tests to
run each time using the same start conditions which can be useful when one
requires reproducible stress tests.
.TP
.B \-\-oomable
Do not respawn a stressor if it gets killed by the Out-of-Memory (OOM) killer.
The default behaviour is to restart a new instance of a stressor if the kernel
OOM killer terminates the process. This option disables this default
behaviour.
.TP
.B \-\-page\-in
touch allocated pages that are not in core, forcing them to be paged back in.
This is a useful option to force all the allocated pages to be paged in when
using the bigheap, mmap and vm stressors.  It will severely degrade
performance when the memory in the system is less than the allocated buffer
sizes.  This uses mincore(2) to determine the pages that are not in core and
hence need touching to page them back in.
.TP
.B \-\-pathological
enable stressors that are known to hang systems.  Some stressors can quickly
consume resources in such a way that they can rapidly hang a system before
the kernel can OOM kill them. These stressors are not enabled by default,
this option enables them, but you probably don't want to do this. You have
been warned.
.TP
.B \-\-perf
measure processor and system activity using perf events. Linux only and
caveat emptor, according to perf_event_open(2): "Always double-check your
results! Various generalized events have had wrong values.".  Note that
with Linux 4.7 one needs to have CAP_SYS_ADMIN capabilities for this
option to work, or adjust  /proc/sys/kernel/perf_event_paranoid to below
2 to use this without CAP_SYS_ADMIN.
.TP
.B \-q, \-\-quiet
do not show any output.
.TP
.B \-r N, \-\-random N
start N random stress workers. If N is 0, then the number of configured
processors is used for N.
.TP
.B \-\-sched scheduler
select the named scheduler (only on Linux). To see the list of available
schedulers use: stress\-ng \-\-sched which
.TP
.B \-\-sched\-prio prio
select the scheduler priority level (only on Linux). If the scheduler does
not support this then the default priority level of 0 is chosen.
.TP
.B \-\-sched\-period period
select the period parameter for deadline scheduler (only on Linux). Default
value is 0 (in nanoseconds).
.TP
.B \-\-sched\-runtime runtime
select the runtime parameter for deadline scheduler (only on Linux). Default
value is 99999 (in nanoseconds).
.TP
.B \-\-sched\-deadline deadline
select the deadline parameter for deadline scheduler (only on Linux). Default
value is 100000 (in nanoseconds).
.TP
.B \-\-sched\-reclaim
use cpu bandwidth reclaim feature for deadline scheduler (only on Linux).
.TP
.B \-\-seed N
set the random number generate seed with a 64 bit value. Allows stressors to
use the same random number generator sequences on each invocation.
.TP
.B \-\-sequential N
sequentially run all the stressors one by one for a default of 60 seconds. The
number of instances of each of the individual stressors to be started is N.  If
N is less than zero, then the number of CPUs online is used for the number
of instances.  If N is zero, then the number of CPUs in the system is used.
Use the \-\-timeout option to specify the duration to run each stressor.
.TP
.B \-\-skip\-silent
silence messages that report that a stressor has been skipped because it
requires features not supported by the system, such as unimplemented system
calls, missing resources or processor specific features.
.TP
.B \-\-smart
scan the block devices for changes S.M.A.R.T. statistics (Linux only). This
requires root privileges to read the Self-Monitoring, Analysis and Reporting
Technology data from all block devies and will report any changes in the
statistics. One caveat is that device manufacturers provide different sets
of data, the exact meaning of the data can be vague and the data may be
inaccurate.
.TP
.B \-\-stdout
all output goes to stdout. By default all output goes to stderr (which
is a historical oversight that will cause breakage to users if it is
now changed). This option allows the output to be written to stdout.
.TP
.B \-\-stressors
output the names of the available stressors.
.TP
.B \-\-syslog
log output (except for verbose \-v messages) to the syslog.
.TP
.B \-\-taskset list
set CPU affinity based on the list of CPUs provided; stress-ng is bound to
just use these CPUs (Linux only). The CPUs to be used are specified by a
comma separated list of CPU (0 to N-1). One can specify a range of CPUs
using '-', for example: \-\-taskset 0,2-3,6,7-11
.TP
.B \-\-temp\-path path
specify a path for stress\-ng temporary directories and temporary files;
the default path is the current working directory.  This path must have
read and write access for the stress-ng stress processes.
.TP
.B \-\-thermalstat S
every S seconds show CPU and thermal load statistics. This option shows
average CPU frequency in GHz (average of online-CPUs), load averages (1 minute,
5 minute and 15 minutes) and available thermal zone temperatures in degrees
Centigrade.
.TP
.B \-\-thrash
This can only be used when running on Linux and with root privilege. This
option starts a background thrasher process that works through all the
processes on a system and tries to page as many pages in the processes
as possible. It also periodically drops the page cache, frees reclaimable
slab objects and pagecache. This will cause considerable amount of
thrashing of swap on an over-committed system.
.TP
.B \-t N, \-\-timeout T
run each stress test for at least T seconds. One can also specify the units
of time in seconds, minutes, hours, days or years with the suffix s, m, h,
d or y. Each stressor will be sent a SIGALRM signal at the timeout time, however
if the stress test is swapped out, in a non-interritable system call or
performing clean up (such as removing hundreds of test file) it may take a
while to finally terminate.  A 0 timeout will run stress-ng for ever with
no timeout.
.TP
.B \--timestamp
add a timestamp in hours, minutes, seconds and hundredths of a second to the
log output.
.TP
.B \-\-timer\-slack N
adjust the per process timer slack to N nanoseconds (Linux only). Increasing
the timer slack allows the kernel to coalesce timer events by adding some
fuzziness to timer expiration times and hence reduce wakeups.  Conversely,
decreasing the timer slack will increase wakeups.  A value of 0 for the
timer-slack will set the system default of 50,000 nanoseconds.
.TP
.B \-\-times
show the cumulative user and system times of all the child processes at the
end of the stress run.  The percentage of utilisation of available CPU time is
also calculated from the number of on-line CPUs in the system.
.TP
.B \-\-tz
collect temperatures from the available thermal zones on the machine (Linux
only).  Some devices may have one or more thermal zones, where as others may
have none.
.TP
.B \-v, \-\-verbose
show all debug, warnings and normal information output.
.TP
.B \-\-verify
verify results when a test is run. This is not available on all tests. This
will sanity check the computations or memory contents from a test run and
report to stderr any unexpected failures.
.TP
.B \-\-verifiable
print the names of stressors that can be verified with the \-\-verify option.
.TP
.B \-V, \-\-version
show version of stress-ng, version of toolchain used to build stress-ng
and system information.
.TP
.B \-\-vmstat S
every S seconds show statistics about processes, memory, paging, block I/O,
interrupts, context switches, disks and cpu activity.  The output is similar
that to the output from the vmstat(8) utility. Currently a Linux only option.
.TP
.B \-x, \-\-exclude list
specify a list of one or more stressors to exclude (that is, do not run them).
This is useful to exclude specific stressors when one selects many stressors
to run using the \-\-class option, \-\-sequential, \-\-all and \-\-random
options. Example, run the cpu class stressors concurrently and exclude the
numa and search stressors:
.IP
stress\-ng \-\-class cpu \-\-all 1 \-x numa,bsearch,hsearch,lsearch
.TP
.B \-Y, \-\-yaml filename
output gathered statistics to a YAML formatted file named 'filename'.
.br
.sp 2
.PP
.B Stressor specific options:
.TP
.B \-\-access N
start N workers that work through various settings of file mode bits
(read, write, execute) for the file owner and checks if the user permissions
of the file using access(2) and faccessat(2) are sane.
.TP
.B \-\-access\-ops N
stop access workers after N bogo access sanity checks.
.TP
.B \-\-affinity N
start N workers that run 16 processes that rapidly change CPU affinity
(only on Linux). Rapidly switching CPU affinity can contribute to
poor cache behaviour and high context switch rate.
.TP
.B \-\-affinity\-ops N
stop affinity workers after N bogo affinity operations. Note
that the counters across the 16 processes are not locked to improve affinity
test rates so the final number of bogo-ops will be equal or more than the
specified ops stop threshold because of racy unlocked bogo-op counting.
.TP
.B \-\-affinity\-delay N
delay for N nanoseconds before changing affinity to the next CPU.
The delay will spin on CPU scheduling yield operations for N nanoseconds
before the process is moved to another CPU. The default is 0 nanosconds.
.TP
.B \-\-affinity\-pin
pin all the 16 per stressor processes to a CPU. All 16 processes follow the
CPU chosen by the main parent stressor, forcing heavy per CPU loading.
.TP
.B \-\-affinity\-rand
switch CPU affinity randomly rather than the default of sequentially.
.TP
.B \-\-affinity\-sleep N
sleep for N nanoseconds before changing affinity to the next CPU.
.TP
.B \-\-af\-alg N
start N workers that exercise the AF_ALG socket domain by hashing and encrypting
various sized random messages. This exercises the available hashes, ciphers,
rng and aead crypto engines in the Linux kernel.
.TP
.B \-\-af\-alg\-ops N
stop af\-alg workers after N AF_ALG messages are hashed.
.TP
.B \-\-af\-alg\-dump
dump the internal list representing cryptographic algorithms
parsed from the /proc/crypto file to standard output (stdout).
.TP
.B \-\-aio N
start N workers that issue multiple small asynchronous I/O writes and reads on
a relatively small temporary file using the POSIX aio interface.  This will
just hit the file system cache and soak up a lot of user and kernel time in
issuing and handling I/O requests.  By default, each worker process will
handle 16 concurrent I/O requests.
.TP
.B \-\-aio\-ops N
stop POSIX asynchronous I/O workers after N bogo asynchronous I/O requests.
.TP
.B \-\-aio\-requests N
specify the number of POSIX asynchronous I/O requests each worker should issue,
the default is 16; 1 to 4096 are allowed.
.TP
.B \-\-aiol N
start N workers that issue multiple 4K random asynchronous I/O writes using
the Linux aio system calls io_setup(2), io_submit(2), io_getevents(2) and
io_destroy(2).  By default, each worker process will handle 16 concurrent I/O
requests.
.TP
.B \-\-aiol\-ops N
stop Linux asynchronous I/O workers after N bogo asynchronous I/O requests.
.TP
.B \-\-aiol\-requests N
specify the number of Linux asynchronous I/O requests each worker should issue,
the default is 16; 1 to 4096 are allowed.
.TP
.B \-\-alarm N
start N workers that exercise alarm(2) with MAXINT, 0 and random alarm and
sleep delays that get prematurely interrupted. Before each alarm is scheduled
any previous pending alarms are cancelled with zero second alarm calls.
.TP
.B \-\-alarm\-ops N
stop after N alarm bogo operations.
.TP
.B \-\-apparmor N
start N workers that exercise various parts of the AppArmor interface. Currently
one needs root permission to run this particular test. Only available
on Linux systems with AppArmor support and requires the CAP_MAC_ADMIN capability.
.TP
.B \-\-apparmor-ops
stop the AppArmor workers after N bogo operations.
.TP
.B \-\-atomic N
start N workers that exercise various GCC __atomic_*() built in operations
on 8, 16, 32 and 64 bit integers that are shared among the N workers. This
stressor is only available for builds using GCC 4.7.4 or higher. The stressor
forces many front end cache stalls and cache references.
.TP
.B \-\-atomic\-ops N
stop the atomic workers after N bogo atomic operations.
.TP
.B \-\-bad\-altstack N
start N workers that create broken alternative signal stacks for SIGSEGV
and SIGBUS handling that in turn create secondary SIGSEGV/SIGBUS errors.
A variety of randonly selected nefarious methods are used to create the stacks:
.PP
.RS
.PD 0
.IP \(bu 2
Unmapping the alternative signal stack, before triggering the signal handling.
.IP \(bu 2
Changing the alternative signal stack to just being read only, write only, execute only.
.IP \(bu 2
Using a NULL alternative signal stack.
.IP \(bu 2
Using the signal handler object as the alternative signal stack.
.IP \(bu 2
Unmapping the alternative signal stack during execution of the signal handler.
.IP \(bu 2
Using a read-only text segment for the alternative signal stack.
.IP \(bu 2
Using an undersized alternative signal stack.
.IP \(bu 2
Using the VDSO as an alternative signal stack.
.IP \(bu 2
Using an alternative stack mapped onto /dev/zero.
.IP \(bu 2
Using an alternative stack mapped to a zero sized temporary file to generate a SIGBUS error.
.PD
.RE
.TP
.B \-\-bad\-altstack\-ops N
stop the bad alternative stack stressors after N SIGSEGV bogo operations.
.TP
.TP
.B \-\-bad\-ioctl N
start N workers that perform a range of illegal bad read ioctls (using _IOR) across the
device drivers. This exercises page size, 64 bit, 32 bit, 16 bit and 8 bit reads as
well as NULL addresses, non-readable pages and PROT_NONE mapped pages. Currently only
for Linux and requires the --pathological option.
.TP
.B \-\-bad\-ioctl\-ops N
stop the bad ioctl stressors after N bogo ioctl operations.
.TP
.B \-B N, \-\-bigheap N
start N workers that grow their heaps by reallocating memory. If the out of
memory killer (OOM) on Linux kills the worker or the allocation fails then the
allocating process starts all over again.  Note that the OOM adjustment for the
worker is set so that the OOM killer will treat these workers as the first
candidate processes to kill.
.TP
.B \-\-bigheap\-ops N
stop the big heap workers after N bogo allocation operations are completed.
.TP
.B \-\-bigheap\-growth N
specify amount of memory to grow heap by per iteration. Size can be from 4K to
64MB. Default is 64K.
.TP
.B \-\-binderfs N
start N workers that mount, exercise and unmount binderfs. The binder control
device is exercised with 256 sequential BINDER_CTL_ADD ioctl calls per loop.
.TP
.B \-\-binderfs\-ops N
stop after N binderfs cycles.
.TP
.B \-\-bind\-mount N
start N workers that repeatedly bind mount / to / inside a user namespace. This
can consume resources rapidly, forcing out of memory situations. Do not use this
stressor unless you want to risk hanging your machine.
.TP
.B \-\-bind\-mount\-ops N
stop after N bind mount bogo operations.
.TP
.B \-\-branch N
start N workers that randomly branch to 1024 randomly selected locations and
hence exercise the CPU branch prediction logic.
.TP
.B \-\-branch\-ops N
stop the branch stressors after N \(mu 1024 branches
.TP
.B \-\-brk N
start N workers that grow the data segment by one page at a time using multiple
brk(2) calls. Each successfully allocated new page is touched to ensure it is
resident in memory.  If an out of memory condition occurs then the test will
reset the data segment to the point before it started and repeat the data
segment resizing over again.  The process adjusts the out of memory setting so
that it may be killed by the out of memory (OOM) killer before other processes.
If it is killed by the OOM killer then it will be automatically re-started by
a monitoring parent process.
.TP
.B \-\-brk\-ops N
stop the brk workers after N bogo brk operations.
.TP
.B \-\-brk\-mlock
attempt to mlock future brk pages into memory causing more memory pressure. If
mlock(MCL_FUTURE) is implemented then this will stop new brk pages from being
swapped out.
.TP
.B \-\-brk\-notouch
do not touch each newly allocated data segment page. This disables the default
of touching each newly allocated page and hence avoids the kernel from
necessarily backing the page with physical memory.
.TP
.B \-\-bsearch N
start N workers that binary search a sorted array of 32 bit integers using
bsearch(3). By default, there are 65536 elements in the array.  This is a
useful method to exercise random access of memory and processor cache.
.TP
.B \-\-bsearch\-ops N
stop the bsearch worker after N bogo bsearch operations are completed.
.TP
.B \-\-bsearch\-size N
specify the size (number of 32 bit integers) in the array to bsearch. Size can
be from 1K to 4M.
.TP
.B \-C N, \-\-cache N
start N workers that perform random wide spread memory read and writes to
thrash the CPU cache.  The code does not intelligently determine the CPU cache
configuration and so it may be sub-optimal in producing hit-miss read/write
activity for some processors.
.TP
.B \-\-cache\-cldemote
cache line demote (x86 only). This is a no-op for non-x86
architectures and older x86 processors that do not support this feature.
.TP
.B \-\-cache\-clflushopt
use optimized cache line flush (x86 only). This is a no-op for non-x86
architectures and older x86 processors that do not support this feature.
.TP
.B \-\-cache\-clwb
cache line writeback (x86 only). This is a no-op for non-x86
architectures and older x86 processors that do not support this feature.
.TP
.B \-\-cache\-enable\-all
where appropriate exercise the cache using cldemote, clflushopt, fence, flush, sfence and prefetch.
.TP
.B \-\-cache\-fence
force write serialization on each store operation (x86 only). This is a no-op
for non-x86 architectures.
.TP
.B \-\-cache\-flush
force flush cache on each store operation (x86 only). This is a no-op for
non-x86 architectures.
.TP
.B \-\-cache\-level N
specify level of cache to exercise (1=L1 cache, 2=L2 cache, 3=L3/LLC cache (the default)).
If the cache hierarchy cannot be determined, built-in defaults will apply.
.TP
.B \-\-cache\-no\-affinity
do not change processor affinity when
.B \-\-cache
is in effect.
.TP
.B \-\-cache\-sfence
force write serialization on each store operation using the sfence instruction
(x86 only). This is a no-op for non-x86 architectures.
.TP
.B \-\-cache\-ops N
stop cache thrash workers after N bogo cache thrash operations.
.TP
.B \-\-cache\-prefetch
force read prefetch on next read address on architectures that support
prefetching.
.TP
.B \-\-cache\-ways N
specify the number of cache ways to exercise. This allows a subset of
the overall cache size to be exercised.
.TP
.B \-\-cap N
start N workers that read per process capabilities via calls to capget(2)
(Linux only).
.TP
.B \-\-cap\-ops N
stop after N cap bogo operations.
.TP
.B \-\-chattr N
start N workers that attempt to exercise file attributes via the
EXT2_IOC_SETFLAGS ioctl. This is intended to be intentionally racy and
exercise a range of chattr attributes by enabling and disabling them on
a file shared amongst the N chattr stressor processes. (Linux only).
.TP
.B \-\-chattr\-ops N
stop after N chattr bogo operations.
.TP
.B \-\-chdir N
start N workers that change directory between directories using chdir(2).
.TP
.B \-\-chdir\-ops N
stop after N chdir bogo operations.
.TP
.B \-\-chdir\-dirs N
exercise chdir on N directories. The default is 8192 directories, this allows
64 to 65536 directories to be used instead.
.TP
.B \-\-chmod N
start N workers that change the file mode bits via chmod(2) and fchmod(2) on
the same file. The greater the value for N then the more contention on the
single file.  The stressor will work through all the combination of mode bits.
.TP
.B \-\-chmod\-ops N
stop after N chmod bogo operations.
.TP
.B \-\-chown N
start N workers that exercise chown(2) on the same file. The greater the
value for N then the more contention on the single file.
.TP
.B \-\-chown\-ops N
stop the chown workers after N bogo chown(2) operations.
.TP
.B \-\-chroot N
start N workers that exercise chroot(2) on various valid and invalid
chroot paths. Only available on Linux systems and requires the CAP_SYS_ADMIN
capability.
.TP
.B \-\-chroot\-ops N
stop the chroot workers after N bogo chroot(2) operations.
.TP
.B \-\-clock N
start N workers exercising clocks and POSIX timers. For all known clock types
this will exercise clock_getres(2), clock_gettime(2) and clock_nanosleep(2).
For all known timers it will create a 50000ns timer and busy poll this until
it expires.  This stressor will cause frequent context switching.
.TP
.B \-\-clock\-ops N
stop clock stress workers after N bogo operations.
.TP
.B \-\-clone N
start N workers that create clones (via the clone(2) and clone3() system calls).
This will rapidly try to create a default of 8192 clones that immediately die
and wait in a zombie state until they are reaped.  Once the maximum number of
clones is reached (or clone fails because one has reached the maximum allowed)
the oldest clone thread is reaped and a new clone is then created in a first-in
first-out manner, and then repeated.  A random clone flag is selected for each
clone to try to exercise different clone operations.  The clone stressor is a Linux
only option.
.TP
.B \-\-clone\-ops N
stop clone stress workers after N bogo clone operations.
.TP
.B \-\-clone\-max N
try to create as many as N clone threads. This may not be reached if the system
limit is less than N.
.TP
.B \-\-close N
start N workers that try to force race conditions on closing opened file
descriptors.  These file descriptors have been opened in various ways to try
and exercise different kernel close handlers.
.TP
.B \-\-close\-ops N
stop close workers after N bogo close operations.
.TP
.B \-\-context N
start N workers that run three threads that use swapcontext(3) to implement the
thread-to-thread context switching. This exercises rapid process context saving
and restoring and is bandwidth limited by register and memory save and restore
rates.
.TP
.B \-\-context\-ops N
stop context workers after N bogo context switches.  In this stressor, 1 bogo
op is equivalent to 1000 swapcontext calls.
.TP
.B \-\-copy\-file N
start N stressors that copy a file using the Linux copy_file_range(2) system
call. 2MB chunks of data are copied from random locations from one file to
random locations to a destination file.  By default, the files are 256 MB in
size. Data is sync'd to the filesystem after each copy_file_range(2) call.
.TP
.B \-\-copy\-file\-ops N
stop after N copy_file_range() calls.
.TP
.B \-\-copy\-file\-bytes N
copy file size, the default is 256 MB. One can specify the size as % of free
space on the file system or in units of Bytes, KBytes, MBytes and GBytes using
the suffix b, k, m or g.
.TP
.B \-c N, \-\-cpu N
start N workers exercising the CPU by sequentially working through all the
different CPU stress methods. Instead of exercising all the CPU stress methods,
one can specify a specific CPU stress method with the \-\-cpu\-method option.
.TP
.B \-\-cpu\-ops N
stop cpu stress workers after N bogo operations.
.TP
.B \-l P, \-\-cpu\-load P
load CPU with P percent loading for the CPU stress workers. 0 is effectively a
sleep (no load) and 100 is full loading.  The loading loop is broken into
compute time (load%) and sleep time (100% - load%). Accuracy depends on the
overall load of the processor and the responsiveness of the scheduler, so the
actual load may be different from the desired load.  Note that the number of
bogo CPU operations may not be linearly scaled with the load as some systems
employ CPU frequency scaling and so heavier loads produce an increased CPU
frequency and greater CPU bogo operations.

Note: This option only applies to the \-\-cpu stressor option and not to
all of the cpu class of stressors.
.TP
.B \-\-cpu\-load\-slice S
note \- this option is only useful when \-\-cpu\-load is less than 100%. The
CPU load is broken into multiple busy and idle cycles. Use this option to
specify the duration of a busy time slice.  A negative value for S specifies
the number of iterations to run before idling the CPU (e.g. -30 invokes 30
iterations of a CPU stress loop).  A zero value selects a random busy time
between 0 and 0.5 seconds.  A positive value for S specifies the number of
milliseconds to run before idling the CPU (e.g. 100 keeps the CPU busy for
0.1 seconds).  Specifying small values for S lends to small time slices and
smoother scheduling.  Setting \-\-cpu\-load as a relatively low value and
\-\-cpu\-load\-slice to be large will cycle the CPU between long idle and
busy cycles and exercise different CPU frequencies.  The thermal range of
the CPU is also cycled, so this is a good mechanism to exercise the scheduler,
frequency scaling and passive/active thermal cooling mechanisms.

Note: This option only applies to the \-\-cpu stressor option and not to
all of the cpu class of stressors.
.TP
.B \-\-cpu\-method method
specify a cpu stress method. By default, all the stress methods are exercised
sequentially, however one can specify just one method to be used if required.
Available cpu stress methods are described as follows:
.TS
expand;
lB2 lB lB
l l s.
Method	Description
all	T{
iterate over all the below cpu stress methods
T}
ackermann	T{
Ackermann function: compute A(3, 7), where:
 A(m, n) = n + 1 if m = 0;
 A(m - 1, 1) if m > 0 and n = 0;
 A(m - 1, A(m, n - 1)) if m > 0 and n > 0
T}
apery	T{
calculate Apery's constant \[*z](3); the sum of 1/(n \[ua] 3) to a precision of 1.0x10\[ua]14
T}
bitops	T{
various bit operations from bithack, namely: reverse bits, parity check, bit
count, round to nearest power of 2
T}
callfunc	T{
recursively call 8 argument C function to a depth of 1024 calls and unwind
T}
cfloat	T{
1000 iterations of a mix of floating point complex operations
T}
cdouble	T{
1000 iterations of a mix of double floating point complex operations
T}
clongdouble	T{
1000 iterations of a mix of long double floating point complex operations
T}
collatz	T{
compute the 1348 steps in the collatz sequence starting from number 989345275647.
Where f(n) = n / 2 (for even n) and f(n) = 3n + 1 (for odd n).
T}
correlate	T{
perform a 8192 \(mu 512 correlation of random doubles
T}
cpuid	T{
fetch cpu specific information using the cpuid instruction (x86 only)
T}
crc16	T{
compute 1024 rounds of CCITT CRC16 on random data
T}
decimal32	T{
1000 iterations of a mix of 32 bit decimal floating point operations (GCC only)
T}
decimal64	T{
1000 iterations of a mix of 64 bit decimal floating point operations (GCC only)
T}
decimal128	T{
1000 iterations of a mix of 128 bit decimal floating point operations (GCC
only)
T}
dither	T{
Floyd–Steinberg dithering of a 1024 \(mu 768 random image from 8 bits down to
1 bit of depth
T}
div16	T{
50,000 16 bit unsigned integer divisions
T}
div32	T{
50,000 32 bit unsigned integer divisions
T}
div64	T{
50,000 64 bit unsigned integer divisions
T}
double	T{
1000 iterations of a mix of double precision floating point operations
T}
euler	T{
compute e using n \[eq] (1 + (1 \[di] n)) \[ua] n
T}
explog	T{
iterate on n \[eq] exp(log(n) \[di] 1.00002)
T}
factorial	T{
find factorials from 1..150 using Stirling's and Ramanujan's approximations
T}
fibonacci	T{
compute Fibonacci sequence of 0, 1, 1, 2, 5, 8...
T}
fft	T{
4096 sample Fast Fourier Transform
T}
fletcher16	T{
1024 rounds of a na\[:i]ve implementation of a 16 bit Fletcher's checksum
T}
float	T{
1000 iterations of a mix of floating point operations
T}
float16	T{
1000 iterations of a mix of 16 bit floating point operations
T}
float32	T{
1000 iterations of a mix of 32 bit floating point operations
T}
float64	T{
1000 iterations of a mix of 64 bit floating point operations
T}
float80	T{
1000 iterations of a mix of 80 bit floating point operations
T}
float128	T{
1000 iterations of a mix of 128 bit floating point operations
T}
floatconversion	T{
perform 65536 iterations of floating point conversions between
float, double and long double floating point variables.
T}
gamma	T{
calculate the Euler\-Mascheroni constant \(*g using the limiting difference
between the harmonic series (1 + 1/2 + 1/3 + 1/4 + 1/5 ... + 1/n) and the
natural logarithm ln(n), for n = 80000.
T}
gcd	T{
compute GCD of integers
T}
gray	T{
calculate binary to gray code and gray code back to binary for integers
from 0 to 65535
T}
hamming	T{
compute Hamming H(8,4) codes on 262144 lots of 4 bit data. This turns 4 bit
data into 8 bit Hamming code containing 4 parity bits. For data bits d1..d4,
parity bits are computed as:
  p1 = d2 + d3 + d4
  p2 = d1 + d3 + d4
  p3 = d1 + d2 + d4
  p4 = d1 + d2 + d3
T}
hanoi	T{
solve a 21 disc Towers of Hanoi stack using the recursive solution
T}
hyperbolic	T{
compute sinh(\(*h) \(mu cosh(\(*h) + sinh(2\(*h) + cosh(3\(*h) for float,
double and long double hyperbolic sine and cosine functions where \(*h = 0
to 2\(*p in 1500 steps
T}
idct	T{
8 \(mu 8 IDCT (Inverse Discrete Cosine Transform).
T}
int8	T{
1000 iterations of a mix of 8 bit integer operations.
T}
int16	T{
1000 iterations of a mix of 16 bit integer operations.
T}
int32	T{
1000 iterations of a mix of 32 bit integer operations.
T}
int64	T{
1000 iterations of a mix of 64 bit integer operations.
T}
int128	T{
1000 iterations of a mix of 128 bit integer operations (GCC only).
T}
int32float	T{
1000 iterations of a mix of 32 bit integer and floating point operations.
T}
int32double	T{
1000 iterations of a mix of 32 bit integer and double precision floating point
operations.
T}
int32longdouble	T{
1000 iterations of a mix of 32 bit integer and long double precision floating
point operations.
T}
int64float	T{
1000 iterations of a mix of 64 bit integer and floating point operations.
T}
int64double	T{
1000 iterations of a mix of 64 bit integer and double precision floating point
operations.
T}
int64longdouble	T{
1000 iterations of a mix of 64 bit integer and long double precision floating
point operations.
T}
int128float	T{
1000 iterations of a mix of 128 bit integer and floating point operations
(GCC only).
T}
int128double	T{
1000 iterations of a mix of 128 bit integer and double precision floating point
operations (GCC only).
T}
int128longdouble	T{
1000 iterations of a mix of 128 bit integer and long double precision floating
point operations (GCC only).
T}
int128decimal32	T{
1000 iterations of a mix of 128 bit integer and 32 bit decimal floating point
operations (GCC only).
T}
int128decimal64	T{
1000 iterations of a mix of 128 bit integer and 64 bit decimal floating point
operations (GCC only).
T}
int128decimal128	T{
1000 iterations of a mix of 128 bit integer and 128 bit decimal floating point
operations (GCC only).
T}
intconversion	T{
perform 65536 iterations of integer conversions between
int16, int32 and int64 variables.
T}
ipv4checksum	T{
compute 1024 rounds of the 16 bit ones' complement IPv4 checksum.
T}
jmp	T{
Simple unoptimised compare >, <, == and jmp branching.
T}
lfsr32	T{
16384 iterations of a 32 bit Galois linear feedback shift register using
the polynomial x\[ua]32 + x\[ua]31 + x\[ua]29 + x + 1. This generates a
ring of 2\[ua]32 - 1 unique values (all 32 bit values except for 0).
T}
ln2	T{
compute ln(2) based on series:
 1 - 1/2 + 1/3 - 1/4 + 1/5 - 1/6 ...
T}
logmap	T{
16384 iterations computing chaotic double precision values using the logistic map
\[*X]n+1 = r \(mu  \[*X]n \(mu (1 - \[*X]n) where r > \[~~] 3.56994567
T}
longdouble	T{
1000 iterations of a mix of long double precision floating point operations.
T}
loop	T{
simple empty loop.
T}
matrixprod	T{
matrix product of two 128 \(mu 128 matrices of double floats. Testing on 64
bit x86 hardware shows that this is provides a good mix of memory, cache and
floating point operations and is probably the best CPU method to use to make
a CPU run hot.
T}
nsqrt	T{
compute sqrt() of long doubles using Newton-Raphson.
T}
omega	T{
compute the omega constant defined by \(*We\[ua]\(*W = 1 using efficient
iteration of \(*Wn+1 = (1 + \(*Wn) / (1 + e\[ua]\(*Wn).
T}
parity	T{
compute parity using various methods from the Standford Bit Twiddling Hacks.
Methods employed are: the na\[:i]ve way, the na\[:i]ve way with the Brian
Kernigan bit counting optimisation, the multiply way, the parallel way,
the lookup table ways (2 variations) and using the __builtin_parity function.
T}
phi	T{
compute the Golden Ratio \(*f using series.
T}
pi	T{
compute \(*p using the Srinivasa Ramanujan fast convergence algorithm.
T}
prime	T{
find the first 10000 prime numbers using a slightly optimised brute
force na\[:i]ve trial division search.
T}
psi	T{
compute \(*q (the reciprocal Fibonacci constant) using the sum of the
reciprocals of the Fibonacci numbers.
T}
queens	T{
compute all the solutions of the classic 8 queens problem for board sizes 1..11.
T}
rand	T{
16384 iterations of rand(), where rand is the MWC pseudo
random number generator.
The MWC random function concatenates two 16 bit multiply\-with\-carry
generators:
 x(n) = 36969 \(mu x(n - 1) + carry,
 y(n) = 18000 \(mu y(n - 1) + carry mod 2 \[ua] 16
.sp 1
and has period of around 2 \[ua] 60.
T}
rand48	T{
16384 iterations of drand48(3) and lrand48(3).
T}
rgb	T{
convert RGB to YUV and back to RGB (CCIR 601).
T}
sieve	T{
find the first 10000 prime numbers using the sieve of Eratosthenes.
T}
stats	T{
calculate minimum, maximum, arithmetic mean, geometric mean, harmoninc mean
and standard deviation on 250 randomly generated positive double precision
values.
T}
sqrt	T{
compute sqrt(rand()), where rand is the MWC pseudo random number generator.
T}
trig	T{
compute sin(\(*h) \(mu cos(\(*h) + sin(2\(*h) + cos(3\(*h) for float, double
and long double sine and cosine functions where \(*h = 0 to 2\(*p in 1500 steps.
T}
union	T{
perform integer arithmetic on a mix of bit fields in a C union.  This exercises
how well the compiler and CPU can perform integer bit field loads and stores.
T}
zeta	T{
compute the Riemann Zeta function \[*z](s) for s = 2.0..10.0
T}
.TE
.RS
.PP
Note that some of these methods try to exercise the CPU with computations found
in some real world use cases. However, the code has not been optimised on a
per-architecture basis, so may be a sub-optimal compared to hand-optimised code
used in some applications.  They do try to represent the typical instruction
mixes found in these use cases.
.RE
.TP
.B \-\-cpu\-online N
start N workers that put randomly selected CPUs offline and online. This Linux
only stressor requires root privilege to perform this action. By default the
first CPU (CPU 0) is never offlined as this has been found to be problematic
on some systems and can result in a shutdown.
.TP
.B \-\-cpu\-online\-all
The default is to never offline the first CPU.  This option will offline and
online all the CPUs include CPU 0. This may cause some systems to shutdown.
.TP
.B \-\-cpu\-online\-ops N
stop after offline/online operations.
.TP
.B \-\-crypt N
start N workers that encrypt a 16 character random password using crypt(3).
The password is encrypted using MD5, SHA-256 and SHA-512 encryption methods.
.TP
.B \-\-crypt\-ops N
stop after N bogo encryption operations.
.TP
.B \-\-cyclic N
start N workers that exercise the real time FIFO or Round Robin schedulers
with cyclic nanosecond sleeps. Normally one would just use 1 worker instance
with this stressor to get reliable statistics.  This stressor measures the
first 10 thousand latencies and calculates the mean, mode, minimum, maximum
latencies along with various latency percentiles for the just the first
cyclic stressor instance. One has to run this stressor with CAP_SYS_NICE
capability to enable the real time scheduling policies. The FIFO scheduling
policy is the default.
.TP
.B \-\-cyclic\-ops N
stop after N sleeps.
.TP
.B \-\-cyclic\-dist N
calculate and print a latency distribution with the interval of N nanoseconds.
This is helpful to see where the latencies are clustering.
.TP
.B \-\-cyclic\-method [ clock_ns | itimer | poll | posix_ns | pselect | usleep ]
specify the cyclic method to be used, the default is clock_ns. The available
cyclic methods are as follows:
.TS
expand;
lB2 lB lB
l l s.
Method	Description
clock_ns	T{
sleep for the specified time using the clock_nanosleep(2) high
resolution nanosleep and the CLOCK_REALTIME real time clock.
T}
itimer	T{
wakeup a paused process with a CLOCK_REALTIME itimer signal.
T}
poll	T{
delay for the specified time using a poll delay loop that checks
for time changes using clock_gettime(2) on the CLOCK_REALTIME clock.
T}
posix_ns	T{
sleep for the specified time using the POSIX nanosleep(2) high
resolution nanosleep.
T}
pselect	T{
sleep for the specified time using pselect(2) with null file descriptors.
T}
usleep	T{
sleep to the nearest microsecond using usleep(2).
T}
.TE
.TP
.B \-\-cyclic\-policy [ fifo | rr ]
specify the desired real time scheduling policy, ff (first-in, first-out)
or rr (round robin).
.TP
.B \-\-cyclic\-prio P
specify the scheduling priority P. Range from 1 (lowest) to 100 (highest).
.TP
.B \-\-cyclic\-sleep N
sleep for N nanoseconds per test cycle using clock_nanosleep(2) with the
CLOCK_REALTIME timer. Range from 1 to 1000000000 nanoseconds.
.TP
.B \-\-daemon N
start N workers that each create a daemon that dies immediately after creating
another daemon and so on. This effectively works through the process table with
short lived processes that do not have a parent and are waited for by init.
This puts pressure on init to do rapid child reaping.  The daemon processes
perform the usual mix of calls to turn into typical UNIX daemons, so this
artificially mimics very heavy daemon system stress.
.TP
.B \-\-daemon\-ops N
stop daemon workers after N daemons have been created.
.TP
.B \-\-dccp N
start N workers that send and receive data using the Datagram Congestion
Control Protocol (DCCP) (RFC4340). This involves a pair of client/server
processes performing rapid connect, send and receives and disconnects on
the local host.
.TP
.B \-\-dccp\-domain D
specify the domain to use, the default is ipv4. Currently ipv4 and ipv6
are supported.
.TP
.B \-\-dccp\-port P
start DCCP at port P. For N dccp worker processes, ports P to P - 1 are
used.
.TP
.B \-\-dccp\-ops N
stop dccp stress workers after N bogo operations.
.TP
.B \-\-dccp\-opts [ send | sendmsg | sendmmsg ]
by default, messages are sent using send(2). This option allows one to specify
the sending method using send(2), sendmsg(2) or sendmmsg(2).  Note that
sendmmsg is only available for Linux systems that support this system call.
.TP
.B \-\-dekker N
start N workers that exercises mutex exclusion between two processes using
shared memory with the Dekker Algorithm. Where possible this uses memory fencing
and falls back to using GCC __sync_synchronize if they are not available. The
stressors contain simple mutex and memory coherency sanity checks.
.TP
.B \-\-dekker\-ops N
stop dekker workers after N mutex operations.
.TP
.B \-D N, \-\-dentry N
start N workers that create and remove directory entries.  This should create
file system meta data activity. The directory entry names are suffixed by a
gray-code encoded number to try to mix up the hashing of the namespace.
.TP
.B \-\-dentry\-ops N
stop denty thrash workers after N bogo dentry operations.
.TP
.B \-\-dentry\-order [ forward | reverse | stride | random ]
specify unlink order of dentries, can be one of forward, reverse, stride
or random.
By default, dentries are unlinked in random order.  The forward
order will unlink them from first to last, reverse order will unlink
them from last to first, stride order will unlink them by stepping
around order in a quasi-random pattern and random order will randomly
select one of forward, reverse or stride orders.
.TP
.B \-\-dentries N
create N dentries per dentry thrashing loop, default is 2048.
.TP
.B \-\-dev N
start N workers that exercise the /dev devices. Each worker runs 5
concurrent threads that perform open(2), fstat(2), lseek(2), poll(2),
fcntl(2), mmap(2), munmap(2), fsync(2) and close(2) on each device.
Note that watchdog devices are not exercised.
.TP
.B \-\-dev\-ops N
stop dev workers after N bogo device exercising operations.
.TP
.B \-\-dev\-file filename
specify the device file to exercise, for example, /dev/null. By default
the stressor will work through all the device files it can fine, however,
this option allows a single device file to be exercised.
.TP
.B \-\-dev\-shm N
start N workers that fallocate large files in /dev/shm and then mmap
these into memory and touch all the pages. This exercises pages being
moved to/from the buffer cache. Linux only.
.TP
.B \-\-dev\-shm\-ops N
stop after N bogo allocation and mmap /dev/shm operations.
.TP
.B \-\-dir N
start N workers that create and remove directories using mkdir and rmdir.
.TP
.B \-\-dir\-ops N
stop directory thrash workers after N bogo directory operations.
.TP
.B \-\-dir\-dirs N
exercise dir on N directories. The default is 8192 directories, this allows
64 to 65536 directories to be used instead.
.TP
.B \-\-dirdeep N
start N workers that create a depth-first tree of directories to a maximum
depth as limited by PATH_MAX or ENAMETOOLONG (which ever occurs first).
By default, each level of the tree contains one directory, but this can
be increased to a maximum of 10 sub-trees using the \-\-dirdeep\-dir option.
To stress inode creation, a symlink and a hardlink to a file at the root
of the tree is created in each level.
.TP
.B \-\-dirdeep\-ops N
stop directory depth workers after N bogo directory operations.
.TP
.B \-\-dirdeep-bytes N
allocated file size, the default is 0. One can specify the size as % of free
space on the file system or in units of Bytes, KBytes, MBytes and GBytes using
the suffix b, k, m or g. Used in conjunction with the \-\-dirdeep\-files
option.
.TP
.B \-\-dirdeep\-dirs N
create N directories at each tree level. The default is just 1 but can be
increased to a maximum of 36 per level.
.TP
.B \-\-dirdeep\-files N
create N files  at each tree level. The default is 0 with the file size specified
by the \-\-dirdeep\-bytes option.
.TP
.B \-\-dirdeep\-inodes N
consume up to N inodes per dirdeep stressor while creating directories and
links. The value N can be the number of inodes or a percentage of the total
available free inodes on the filesystem being used.
.TP
.B \-\-dirmany N
start N stressors that create as many files in a directory as possible
and then remove them. The file creation phase stops when an error occurs
(for example, out of inodes, too many files, quota reached, etc.) and then
the files are removed. This cycles until the the run time is reached or the
file creation count bogo-ops metric is reached. This is a much faster and
light weight directory exercising stressor compared to the dentry stressor.
.TP
.B \-\-dirmany\-ops N
stop dirmany stressors after N empty files have been created.
.TP
.B \-\-dirmany\-bytes N
allocated file size, the default is 0. One can specify the size as % of free
space on the file system or in units of Bytes, KBytes, MBytes and GBytes using
the suffix b, k, m or g.
.TP
.B \-\-dnotify N
start N workers performing file system activities such as making/deleting
files/directories, renaming files, etc. to stress exercise the various dnotify
events (Linux only).
.TP
.B \-\-dnotify\-ops N
stop inotify stress workers after N dnotify bogo operations.
.TP
.B \-\-dup N
start N workers that perform dup(2) and then close(2) operations on /dev/zero.
The maximum opens at one time is system defined, so the test will run up to
this maximum, or 65536 open file descriptors, which ever comes first.
.TP
.B \-\-dup\-ops N
stop the dup stress workers after N bogo open operations.
.TP
.B \-\-dynlib N
start N workers that dynamically load and unload various shared libraries. This
exercises memory mapping and dynamic code loading and symbol lookups. See
dlopen(3) for more details of this mechanism.
.TP
.B \-\-dynlib\-ops N
stop workers after N bogo load/unload cycles.
.TP
.B \-\-efivar N
start N works that exercise the Linux /sys/firmware/efi/vars interface by
reading the EFI variables. This is a Linux only stress test for platforms
that support the EFI vars interface and requires the CAP_SYS_ADMIN
capability.
.TP
.B \-\-efivar-ops N
stop the efivar stressors after N EFI variable read operations.
.TP
.B \-\-enosys N
start N workers that exercise non-functional system call numbers. This calls
a wide range of system call numbers to see if it can break a system where these
are not wired up correctly.  It also keeps track of system calls that exist
(ones that don't return ENOSYS) so that it can focus on purely finding and
exercising non-functional system calls. This stressor exercises system calls
from 0 to __NR_syscalls + 1024, random system calls within constrained in the
ranges of 0 to 2^8, 2^16, 2^24, 2^32, 2^40, 2^48, 2^56 and 2^64 bits,
high system call numbers and various other bit patterns to try to get wide
coverage. To keep the environment clean, each system call being tested runs
in a child process with reduced capabilities.
.TP
.B \-\-enosys\-ops N
stop after N bogo enosys system call attempts
.TP
.B \-\-env N
start N workers that creates numerous large environment variables to try to
trigger out of memory conditions using setenv(3).  If ENOMEM occurs then the
environment is emptied and another memory filling retry occurs.  The process
is restarted if it is killed by the Out Of Memory (OOM) killer.
.TP
.B \-\-env\-ops N
stop after N bogo setenv/unsetenv attempts.
.TP
.B \-\-epoll N
start N workers that perform various related socket stress activity using
epoll_wait(2) to monitor and handle new connections. This involves
client/server processes performing rapid connect, send/receives and disconnects
on the local host.  Using epoll allows a large number of connections to be
efficiently handled, however, this can lead to the connection table filling up
and blocking further socket connections, hence impacting on the epoll bogo op
stats.  For ipv4 and ipv6 domains, multiple servers are spawned on multiple
ports. The epoll stressor is for Linux only.
.TP
.B \-\-epoll\-domain D
specify the domain to use, the default is unix (aka local). Currently ipv4,
ipv6 and unix are supported.
.TP
.B \-\-epoll\-port P
start at socket port P. For N epoll worker processes, ports P to (P * 4) - 1
are used for ipv4, ipv6 domains and ports P to P - 1 are used for the unix
domain.
.TP
.B \-\-epoll\-ops N
stop epoll workers after N bogo operations.
.TP
.B \-\-eventfd N
start N parent and child worker processes that read and write 8 byte event
messages between them via the eventfd mechanism (Linux only).
.TP
.B \-\-eventfd\-ops N
stop eventfd workers after N bogo operations.
.TP
.B \-\-eventfd\-nonblock N
enable EFD_NONBLOCK to allow non-blocking on the event file descriptor. This
will cause reads and writes to return with EAGAIN rather the blocking and hence
causing a high rate of polling I/O.
.TP
.B \-\-exec N
start N workers continually forking children that exec stress-ng and then exit
almost immediately. If a system has pthread support then 1 in 4 of the exec's
will be from inside a pthread to exercise exec'ing from inside a pthread
context.
.TP
.B \-\-exec\-ops N
stop exec stress workers after N bogo operations.
.TP
.B \-\-exec\-max P
create P child processes that exec stress-ng and then wait for them to exit per
iteration. The default is just 1; higher values will create many temporary
zombie processes that are waiting to be reaped. One can potentially fill up the
process table using high values for \-\-exec\-max and \-\-exec.
.TP
.B \-\-exit\-group N
start N workers that create 16 pthreads and terminate the pthreads and
the controlling child process using exit_group(2). (Linux only stressor).
.TP
.B \-\-exit\-group\-ops N
stop after N iterations of pthread creation and deletion loops.
.TP
.B \-F N, \-\-fallocate N
start N workers continually fallocating (preallocating file space) and
ftruncating (file truncating) temporary files.  If the file is larger than the
free space, fallocate will produce an ENOSPC error which is ignored by this
stressor.
.TP
.B \-\-fallocate\-bytes N
allocated file size, the default is 1 GB. One can specify the size as % of free
space on the file system or in units of Bytes, KBytes, MBytes and GBytes using
the suffix b, k, m or g.
.TP
.B \-\-fallocate\-ops N
stop fallocate stress workers after N bogo fallocate operations.
.TP
.B \-\-fanotify N
start N workers performing file system activities such as creating, opening,
writing, reading and unlinking files to exercise the fanotify event monitoring
interface (Linux only). Each stressor runs a child process to generate file
events and a parent process to read file events using fanotify. Has to be run
with CAP_SYS_ADMIN capability.
.TP
.B \-\-fanotify-ops N
stop fanotify stress workers after N bogo fanotify events.
.TP
.B \-\-fault N
start N workers that generates minor and major page faults.
.TP
.B \-\-fault\-ops N
stop the page fault workers after N bogo page fault operations.
.TP
.B \-\-fcntl N
start N workers that perform fcntl(2) calls with various commands.  The
exercised commands (if available) are: F_DUPFD, F_DUPFD_CLOEXEC, F_GETFD,
F_SETFD, F_GETFL, F_SETFL, F_GETOWN, F_SETOWN, F_GETOWN_EX, F_SETOWN_EX,
F_GETSIG, F_SETSIG, F_GETLK, F_SETLK, F_SETLKW, F_OFD_GETLK, F_OFD_SETLK
and F_OFD_SETLKW.
.TP
.B \-\-fcntl\-ops N
stop the fcntl workers after N bogo fcntl operations.
.TP
.B \-\-fiemap N
start N workers that each create a file with many randomly changing extents
and has 4 child processes per worker that gather the extent information using
the FS_IOC_FIEMAP ioctl(2).
.TP
.B \-\-fiemap\-ops N
stop after N fiemap bogo operations.
.TP
.B \-\-fiemap\-bytes N
specify the size of the fiemap'd file in bytes.  One can specify the size
as % of free space on the file system or in units of Bytes, KBytes, MBytes
and GBytes using the suffix b, k, m or g.  Larger files will contain more
extents, causing more stress when gathering extent information.
.TP
.B \-\-fifo N
start N workers that exercise a named pipe by transmitting 64 bit integers.
.TP
.B \-\-fifo-ops N
stop fifo workers after N bogo pipe write operations.
.TP
.B \-\-fifo-readers N
for each worker, create N fifo reader workers that read
the named pipe using simple blocking reads.
.TP
.B \-\-file\-ioctl N
start N workers that exercise various file specific ioctl(2) calls. This will
attempt to use the FIONBIO, FIOQSIZE, FIGETBSZ, FIOCLEX, FIONCLEX, FIONBIO,
FIOASYNC, FIOQSIZE, FIFREEZE, FITHAW, FICLONE, FICLONERANGE, FIONREAD,
FIONWRITE and FS_IOC_RESVSP ioctls if these are defined.
.TP
.B \-\-file\-ioctl\-ops N
stop file\-ioctl workers after N file ioctl bogo operations.
.TP
.B \-\-filename N
start N workers that exercise file creation using various length filenames
containing a range of allowed filename characters.  This will try to see if
it can exceed the file system allowed filename length was well as test
various filename lengths between 1 and the maximum allowed by the file system.
.TP
.B \-\-filename-ops N
stop filename workers after N bogo filename tests.
.TP
.B \-\-filename-opts opt
use characters in the filename based on option 'opt'. Valid options are:
.TS
expand;
lB lB lB lB
l l s s.
Option	Description
probe	T{
default option, probe the file system for valid allowed characters in a file name
and use these
T}
posix	T{
use characters as specified by The Open Group Base Specifications Issue 7,
POSIX.1-2008, 3.278 Portable Filename Character Set
T}
ext	T{
use characters allowed by the ext2, ext3, ext4 file systems, namely any 8
bit character apart from NUL and /
T}
.TE
.TP
.B \-\-flock N
start N workers locking on a single file.
.TP
.B \-\-flock\-ops N
stop flock stress workers after N bogo flock operations.
.TP
.B \-f N, \-\-fork N
start N workers continually forking children that immediately exit.
.TP
.B \-\-fork\-ops N
stop fork stress workers after N bogo operations.
.TP
.B \-\-fork\-max P
create P child processes and then wait for them to exit per iteration. The
default is just 1; higher values will create many temporary zombie processes
that are waiting to be reaped. One can potentially fill up the process
table using high values for \-\-fork\-max and \-\-fork.
.TP
.B \-\-fork\-vm
enable detrimental performance virtual memory advice using madvise on
all pages of the forked process. Where possible this will try to set
every page in the new process with using madvise MADV_MERGEABLE,
MADV_WILLNEED, MADV_HUGEPAGE and MADV_RANDOM flags. Linux only.
.TP
.B \-\-fp\-error N
start N workers that generate floating point exceptions. Computations are
performed to force and check for the FE_DIVBYZERO, FE_INEXACT, FE_INVALID,
FE_OVERFLOW and FE_UNDERFLOW exceptions.  EDOM and ERANGE errors are also
checked.
.TP
.B \-\-fp\-error\-ops N
stop after N bogo floating point exceptions.
.TP
.B \-\-fpunch N
start N workers that punch and fill holes in a 16 MB file using five
concurrent processes per stressor exercising on the same file. Where
available, this uses fallocate(2) FALLOC_FL_KEEP_SIZE,
FALLOC_FL_PUNCH_HOLE, FALLOC_FL_ZERO_RANGE, FALLOC_FL_COLLAPSE_RANGE
and FALLOC_FL_INSERT_RANGE to make and fill holes across the file
and breaks it into multiple extents.
.TP
.B \-\-fpunch\-ops N
stop fpunch workers after N punch and fill bogo operations.
.TP
.B \-\-fstat N
start N workers fstat'ing files in a directory (default is /dev).
.TP
.B \-\-fstat\-ops N
stop fstat stress workers after N bogo fstat operations.
.TP
.B \-\-fstat\-dir directory
specify the directory to fstat to override the default of /dev.
All the files in the directory will be fstat'd repeatedly.
.TP
.B \-\-full N
start N workers that exercise /dev/full.  This attempts to write to
the device (which should always get error ENOSPC), to read from the device
(which should always return a buffer of zeros) and to seek randomly on the
device (which should always succeed).  (Linux only).
.TP
.B \-\-full\-ops N
stop the stress full workers after N bogo I/O operations.
.TP
.B \-\-funccall N
start N workers that call functions of 1 through to 9 arguments. By default
functions with uint64_t arguments are called, however, this can be changed
using the \-\-funccall\-method option.
.TP
.B \-\-funccall\-ops N
stop the funccall workers after N bogo function call operations. Each bogo
operation is 1000 calls of functions of 1 through to 9 arguments of the chosen
argument type.
.TP
.B \-\-funccall\-method method
specify the method of funccall argument type to be used. The
default is uint64_t but can be one of bool, uint8, uint16, uint32, uint64,
uint128, float, double, longdouble, cfloat (complex float),
cdouble (complex double), clongdouble (complex long double), float16,
float32, float64, float80, float128, decimal32, decimal64 and decimal128.
Note that some of these types are only available with specific architectures
and compiler versions.
.TP
.B \-\-funcret N
start N workers that pass and return by value various small to large data
types.
.TP
.B \-\-funcret\-ops N
stop the funcret workers after N bogo function call operations.
.TP
.B \-\-funcret\-method method
specify the method of funcret argument type to be used. The
default is uint64_t but can be one of uint8 uint16 uint32 uint64 uint128
float double longdouble float80 float128 decimal32 decimal64 decimal128
uint8x32 uint8x128 uint64x128.
.TP
.B \-\-futex N
start N workers that rapidly exercise the futex system call. Each worker has
two processes, a futex waiter and a futex waker. The waiter waits with a very
small timeout to stress the timeout and rapid polled futex waiting. This is a
Linux specific stress option.
.TP
.B \-\-futex\-ops N
stop futex workers after N bogo successful futex wait operations.
.TP
.B \-\-get N
start N workers that call system calls that fetch data from the kernel,
currently these are: getpid, getppid, getcwd, getgid, getegid, getuid,
getgroups, getpgrp, getpgid, getpriority, getresgid, getresuid, getrlimit,
prlimit, getrusage, getsid, gettid, getcpu, gettimeofday, uname, adjtimex,
sysfs.  Some of these system calls are OS specific.
.TP
.B \-\-get\-ops N
stop get workers after N bogo get operations.
.TP
.B \-\-getdent N
start N workers that recursively read directories /proc, /dev/, /tmp, /sys
and /run using getdents and getdents64 (Linux only).
.TP
.B \-\-getdent\-ops N
stop getdent workers after N bogo getdent bogo operations.
.TP
.B \-\-getrandom N
start N workers that get 8192 random bytes from the /dev/urandom pool using
the getrandom(2) system call (Linux) or getentropy(2) (OpenBSD).
.TP
.B \-\-getrandom\-ops N
stop getrandom workers after N bogo get operations.
.TP
.B \-\-goto N
start N workers that perform 1024 forward branches (to next instruction) or
backward branches (to previous instruction) for each bogo operation loop.
By default, every 1024 branches the direction is randomly chosen to be
forward or backward.  This stressor exercises suboptimal pipelined execution
and branch prediction logic.
.TP
.B \-\-goto\-ops N
stop goto workers after N bogo loops of 1024 branch instructions.
.TP
.B \-\-goto\-direction [ forward | backward | random ]
select the branching direction in the stressor loop, forward for forward only
branching, backward for a backward only branching, random for a random choice
of forward or random branching every 1024 branches.
.TP
.B \-\-handle N
start N workers that exercise the name_to_handle_at(2) and open_by_handle_at(2)
system calls. (Linux only).
.TP
.B \-\-handle\-ops N
stop after N handle bogo operations.
.TP
.B \-\-hash N
start N workers that exercise various hashing functions. Random strings from
1 to 128 bytes are hashed and the hashing rate and chi squared is calculated
from the number of hashes performed over a period of time. The chi squared
value is the goodness-of-fit measure, it is the actual distribution of items
in hash buckets versus the expected distribution of items. Typically a chi
squared value of 0.95..1.05 indicates a good hash distribution.
.TP
.B \-\-hash\-ops N
stop after N hashing rounds
.TP
.B \-\-hash\-method M
specify the hashing method to use, by default all the hashing methods are
cycled through. Methods available are:
.TS
expand;
lB2 lB lB
l l s.
Method	Description
all	T{
cycle through all the hashing methods
T}
adler32	T{
Mark Adler checksum, a modification of the Fletcher checksum
T}
coffin	T{
xor and 5 bit rotate left hash
T}
coffin32	T{
xor and 5 bit rotate left hash with 32 bit fetch optimization
T}
crc32c	T{
compute CRC32C (Castagnoli CRC32) integer hash
T}
djb2a	T{
Dan Bernstein hash using the xor variant
T}
fnv1a	T{
FNV-1a Fowler-Noll-Vo hash using the xor then multiply variant
T}
jenkin	T{
Jenkin's integer hash
T}
kandr	T{
Kernighan and Richie's multiply by 31 and add hash from "The C Programming Language", 2nd Edition
T}
knuth	T{
Donald E. Knuth's hash from "The Art Of Computer Programming", Volume 3, chapter 6.4
T}
loselose	T{
Kernighan and Richie's simple hash from "The C Programming Language", 1st Edition
T}
mid5	T{
xor shift hash of the middle 5 characters of the string. Designed by Colin Ian King
T}
muladd32	T{
simple multiply and add hash using 32 bit math and xor folding of overflow
T}
muladd64	T{
simple multiply and add hash using 64 bit math and xor folding of overflow
T}
mulxror64	T{
64 bit multiply, xor and rotate right. Mangles 64 bits where possible. Designed by Colin Ian King
T}
murmur3_32	T{
murmur3_32 hash, Austin Appleby's Murmur3 hash, 32 bit variant
T}
nhash	T{
exim's nhash.
T}
pjw	T{
a non-cryptographic hash function created by Peter J. Weinberger of AT&T Bell Labs,
used in UNIX ELF object files
T}
sdbm	T{
sdbm hash as used in the SDBM database and GNU awk
T}
x17	T{
multiply by 17 and add. The multiplication can be optimized down to a fast right shift by 4
and add on some architectures
T}
xor	T{
simple rotate shift and xor of values
T}
xxhash	T{
the "Extremely fast" hash in non-streaming mode
T}
.TE
.TP
.B \-d N, \-\-hdd N
start N workers continually writing, reading and removing temporary files. The
default mode is to stress test sequential writes and reads.  With
the \-\-aggressive option enabled without any \-\-hdd\-opts options the
hdd stressor will work through all the \-\-hdd\-opt options one by one to
cover a range of I/O options.
.TP
.B \-\-hdd\-bytes N
write N bytes for each hdd process, the default is 1 GB. One can specify the
size as % of free space on the file system or in units of Bytes, KBytes, MBytes
and GBytes using the suffix b, k, m or g.
.TP
.B \-\-hdd\-opts list
specify various stress test options as a comma separated list. Options are as
follows:
.TS
expand;
lB lB lB lB
l l s s.
Option	Description
direct	T{
try to minimize cache effects of the I/O. File I/O writes are performed
directly from user space buffers and synchronous transfer is also attempted.
To guarantee synchronous I/O, also use the sync option.
T}
dsync	T{
ensure output has been transferred to underlying hardware and file metadata
has been updated (using the O_DSYNC open flag). This is equivalent to each
write(2) being followed by a call to fdatasync(2). See also the fdatasync
option.
T}
fadv\-dontneed	T{
advise kernel to expect the data will not be accessed in the near future.
T}
fadv\-noreuse	T{
advise kernel to expect the data to be accessed only once.
T}
fadv\-normal	T{
advise kernel there are no explicit access pattern for the data. This is the
default advice assumption.
T}
fadv\-rnd	T{
advise kernel to expect random access patterns for the data.
T}
fadv\-seq	T{
advise kernel to expect sequential access patterns for the data.
T}
fadv\-willneed	T{
advise kernel to expect the data to be accessed in the near future.
T}
fsync	T{
flush all modified in-core data after each write to the output device using an
explicit fsync(2) call.
T}
fdatasync	T{
similar to fsync, but do not flush the modified metadata unless metadata is
required for later data reads to be handled correctly. This uses an explicit
fdatasync(2) call.
T}
iovec	T{
use readv/writev multiple buffer I/Os rather than read/write. Instead of 1
read/write operation, the buffer is broken into an iovec of 16 buffers.
T}
noatime	T{
do not update the file last access timestamp, this can reduce metadata writes.
T}
sync	T{
ensure output has been transferred to underlying hardware (using the O_SYNC
open flag). This is equivalent to a each write(2) being followed by a call to
fsync(2). See also the fsync option.
T}
rd\-rnd	T{
read data randomly. By default, written data is not read back, however, this
option will force it to be read back randomly.
T}
rd\-seq	T{
read data sequentially. By default, written data is not read back, however,
this option will force it to be read back sequentially.
T}
syncfs	T{
write all buffered modifications of file metadata and data on the filesystem
that contains the hdd worker files.
T}
utimes	T{
force update of file timestamp which may increase metadata writes.
T}
wr\-rnd	T{
write data randomly. The wr\-seq option cannot be used at the same time.
T}
wr\-seq	T{
write data sequentially. This is the default if no write modes are specified.
T}
.TE
.RE
.PP
Note that some of these options are mutually exclusive, for example, there can
be only one method of writing or reading.  Also, fadvise flags may be mutually
exclusive, for example fadv-willneed cannot be used with fadv-dontneed.
.TP
.B \-\-hdd\-ops N
stop hdd stress workers after N bogo operations.
.TP
.B \-\-hdd\-write\-size N
specify size of each write in bytes. Size can be from 1 byte to 4MB.
.TP
.B \-\-heapsort N
start N workers that sort 32 bit integers using the BSD heapsort.
.TP
.B \-\-heapsort\-ops N
stop heapsort stress workers after N bogo heapsorts.
.TP
.B \-\-heapsort\-size N
specify number of 32 bit integers to sort, default is 262144 (256 \(mu 1024).
.TP
.B \-\-hrtimers N
start N workers that exercise high resolution times at a high frequency. Each
stressor starts 32 processes that run with random timer intervals of 0..499999
nanoseconds. Running this stressor with appropriate privilege will run these
with the SCHED_RR policy.
.TP
.B \-\-hrtimers\-ops N
stop hrtimers stressors after N timer event bogo operations
.TP
.B \-\-hrtimers\-adjust
enable automatic timer rate adjustment to try to maximize the hrtimer frequency.
The signal rate is measured every 0.1 seconds and the hrtimer delay is adjusted
to try and set the optimal hrtimer delay to generate the highest hrtimer rates.
.TP
.B \-\-hsearch N
start N workers that search a 80% full hash table using hsearch(3). By default,
there are 8192 elements inserted into the hash table.  This is a useful method
to exercise access of memory and processor cache.
.TP
.B \-\-hsearch\-ops N
stop the hsearch workers after N bogo hsearch operations are completed.
.TP
.B \-\-hsearch\-size N
specify the number of hash entries to be inserted into the hash table. Size can
be from 1K to 4M.
.TP
.B \-\-icache N
start N workers that stress the instruction cache by forcing instruction cache
reloads.  This is achieved by modifying an instruction cache line,  causing
the processor to reload it when we call a function in inside it. Currently
only verified and enabled for Intel x86 CPUs.
.TP
.B \-\-icache\-ops N
stop the icache workers after N bogo icache operations are completed.
.TP
.B \-\-icmp\-flood N
start N workers that flood localhost with randonly sized ICMP ping packets.
This stressor requires the CAP_NET_RAW capbility.
.TP
.B \-\-icmp\-flood\-ops N
stop icmp flood workers after N ICMP ping packets have been sent.
.TP
.B \-\-idle\-scan N
start N workers that scan the idle page bitmap across a range of physical
pages. This sets and checks for idle pages via the idle page tracking
interface /sys/kernel/mm/page_idle/bitmap.  This is for Linux only.
.TP
.B \-\-idle\-scan\-ops N
stop after N bogo page scan operations. Currently one bogo page scan
operation is equivalent to setting and checking 64 physical pages.
.TP
.B \-\-idle\-page N
start N workers that walks through every page exercising the Linux
/sys/kernel/mm/page_idle/bitmap interface. Requires CAP_SYS_RESOURCE
capability.
.TP
.B \-\-idle\-page\-ops N
stop after N bogo idle page operations.
.TP
.B \-\-inode-flags N
start N workers that exercise inode flags using the FS_IOC_GETFLAGS and
FS_IOC_SETFLAGS ioctl(2). This attempts to apply all the available inode
flags onto a directory and file even if the underlying file system may not
support these flags (errors are just ignored).  Each worker runs 4 threads
that exercise the flags on the same directory and file to try to force
races. This is a Linux only stressor, see ioctl_iflags(2) for more details.
.TP
.B \-\-inode-flags-ops N
stop the inode-flags workers after N ioctl flag setting attempts.
.TP
.B \-\-inotify N
start N workers performing file system activities such as making/deleting
files/directories, moving files, etc. to stress exercise the various inotify
events (Linux only).
.TP
.B \-\-inotify\-ops N
stop inotify stress workers after N inotify bogo operations.
.TP
.B \-i N, \-\-io N
start N workers continuously calling sync(2) to commit buffer cache to disk.
This can be used in conjunction with the \-\-hdd options.
.TP
.B \-\-io\-ops N
stop io stress workers after N bogo operations.
.TP
.B \-\-iomix N
start N workers that perform a mix of sequential, random and memory mapped
read/write operations as well as random copy file read/writes, forced
sync'ing and (if run as root) cache dropping.  Multiple child processes
are spawned to all share a single file and perform different I/O operations
on the same file.
.TP
.B \-\-iomix\-bytes N
write N bytes for each iomix worker process, the default is 1 GB. One can
specify the size as % of free space on the file system or in units of Bytes,
KBytes, MBytes and GBytes using the suffix b, k, m or g.
.TP
.B \-\-iomix\-ops N
stop iomix stress workers after N bogo iomix I/O operations.
.TP
.B \-\-ioport N
start N workers than perform bursts of 16 reads and 16 writes of ioport 0x80
(x86 Linux systems only).  I/O performed on x86 platforms on port 0x80 will
cause delays on the CPU performing the I/O.
.TP
.B \-\-ioport\-ops N
stop the ioport stressors after N bogo I/O operations
.TP
.B \-\-ioport\-opts [ in | out | inout ]
specify if port reads in, port read writes out or reads and writes are
to be performed.  The default is both in and out.
.TP
.B \-\-ioprio N
start N workers that exercise the ioprio_get(2) and ioprio_set(2) system calls
(Linux only).
.TP
.B \-\-ioprio\-ops N
stop after N io priority bogo operations.
.TP
.B \-\-io\-uring N
start N workers that perform iovec write and read I/O operations using the
Linux io-uring interface. On each bogo-loop 1024 \(mu 512 byte writes and
1024 \(mu reads are performed on a temporary file.
.TP
.B \-\-io\-uring\-ops
stop after N rounds of write and reads.
.TP
.B \-\-ipsec\-mb N
start N workers that perform cryptographic processing using the highly
optimized Intel Multi-Buffer Crypto for IPsec library. Depending on the
features available, SSE, AVX, AVX and AVX512 CPU features will be used
on data encrypted by SHA, DES, CMAC, CTR, HMAC MD5, HMAC SHA1 and
HMAC SHA512 cryptographic routines. This is only available for x86-64
modern Intel CPUs.
.TP
.B \-\-ipsec\-mb\-ops N
stop after N rounds of processing of data using the cryptographic
routines.
.TP
.B \-\-ipsec\-mb\-feature [ sse | avx | avx2 | avx512 ]
Just use the specified processor CPU feature. By default, all the available
features for the CPU are exercised.
.TP
.B \-\-itimer N
start N workers that exercise the system interval timers. This sets up an
ITIMER_PROF itimer that generates a SIGPROF signal.  The default frequency for
the itimer is 1 MHz, however, the Linux kernel will set this to be no more that
the jiffy setting, hence high frequency SIGPROF signals are not normally
possible.  A busy loop spins on getitimer(2) calls to consume CPU and hence
decrement the itimer based on amount of time spent in CPU and system time.
.TP
.B \-\-itimer\-ops N
stop itimer stress workers after N bogo itimer SIGPROF signals.
.TP
.B \-\-itimer\-freq F
run itimer at F Hz; range from 1 to 1000000 Hz. Normally the highest frequency
is limited by the number of jiffy ticks per second, so running above 1000 Hz
is difficult to attain in practice.
.TP
.B \-\-itimer\-rand
select an interval timer frequency based around the interval timer
frequency +/- 12.5% random jitter. This tries to force more variability in
the timer interval to make the scheduling less predictable.
.TP
.B \-\-jpeg N
start N workers that use jpeg compression on a machine generated plasma
field image. The default image is a plasma field, however different image
types may be selected. The starting raster line is changed on each compression
iteration to cycle around the data.
.TP
.B \-\-jpeg\-ops N
stop after N jpeg compression operations.
.TP
.B \-\-jpeg\-height H
use a RGB sample image height of H pixels. The default is 512 pixels.
.TP
.B \-\-jpeg\-image plasma | noise | gradient | xstripes | flat
select the source image type to be compressed. Available image types are:
.TS
expand;
lB2 lB lB
l l s.
Type	Description
plasma	T{
plasma field with smooth colour transitions and hard boundary edges.
T}
noise	T{
random white noise red, green, blue pixels.
T}
gradient	T{
linear gradient of the red, green and blue components across the width
and height of the image.
T}
xstripes	T{
a random colour for each horizontal line.
T}
flat	T{
a single random colour for the entire image.
T}
.TE
.TP
.B \-\-jpeg\-width H
use a RGB sample image width of H pixels. The default is 512 pixels.
.TP
.B \-\-jpeg\-quality Q
use the compression quality Q. The range is 1..100 (1 lowest, 100 highest), with a
default of 95
.TP
.B \-\-judy N
start N workers that insert, search and delete 32 bit integers in a Judy
array using a predictable yet sparse array index. By default,
there are 131072 integers used in the Judy array.  This is a useful method
to exercise random access of memory and processor cache.
.TP
.B \-\-judy\-ops N
stop the judy workers after N bogo judy operations are completed.
.TP
.B \-\-judy\-size N
specify the size (number of 32 bit integers) in the Judy array to exercise.
Size can be from 1K to 4M 32 bit integers.
.TP
.B \-\-kcmp N
start N workers that use kcmp(2) to compare parent and child processes to
determine if they share kernel resources. Supported only for Linux and
requires CAP_SYS_PTRACE capability.
.TP
.B \-\-kcmp\-ops N
stop kcmp workers after N bogo kcmp operations.
.TP
.B \-\-key N
start N workers that create and manipulate keys using add_key(2) and
ketctl(2). As many keys are created as the per user limit allows and then the
following keyctl commands are exercised on each key: KEYCTL_SET_TIMEOUT,
KEYCTL_DESCRIBE, KEYCTL_UPDATE, KEYCTL_READ, KEYCTL_CLEAR and
KEYCTL_INVALIDATE.
.TP
.B \-\-key\-ops N
stop key workers after N bogo key operations.
.TP
.B \-\-kill N
start N workers sending SIGUSR1 kill signals to a SIG_IGN signal handler
in the stressor and SIGUSR1 kill signal to a child stressor with a SIGUSR1
handler. Most of the process time will end up in kernel space.
.TP
.B \-\-kill\-ops N
stop kill workers after N bogo kill operations.
.TP
.B \-\-klog N
start N workers exercising the kernel syslog(2) system call.  This will
attempt to read the kernel log with various sized read buffers. Linux only.
.TP
.B \-\-klog\-ops N
stop klog workers after N syslog operations.
.TP
.B \-\-kvm N
start N workers that create, run and destroy a minimal virtual machine. The
virtual machine reads, increments and writes to port 0x80 in a spin loop
and the stressor handles the I/O transactions. Currently for x86 and Linux only.
.TP
.B \-\-kvm\-ops N
stop kvm stressors after N virtual machines have been created, run and destroyed.
.TP
.B \-\-l1cache N
start N workers that exercise the CPU level 1 cache with reads and writes. A cache
aligned buffer that is twice the level 1 cache size is read and then written
in level 1 cache set sized steps over each level 1 cache set. This is designed
to exercise cache block evictions. The bogo-op count measures the number of
million cache lines touched.  Where possible, the level 1 cache geometry is
determined from the kernel, however, this is not possible on some architectures
or kernels, so one may need to specify these manually. One can specify 3 out
of the 4 cache geometric parameters, these are as follows:
.TP
.B \-\-l1cache-line-size N
specify the level 1 cache line size (in bytes)
.TP
.B \-\-l1cache-sets N
specify the number of level 1 cache sets
.TP
.B \-\-l1cache-size N
specify the level 1 cache size (in bytes)
.TP
.B \-\-l1cache-ways N
specify the number of level 1 cache ways
.TP
.B \-\-landlock N
start N workers that exercise Linux 5.13 landlocking. A range of
landlock_create_ruleset flags are exercised with a read only file rule
to see if a directory can be accessed and a read-write file create can
be blocked. Each ruleset attempt is exercised in a new child context and
this is the limiting factor on the speed of the stressor.
.TP
.B \-\-landlock-ops N
stop the landlock stressors after N landlock ruleset bogo operations.
.TP
.B \-\-lease N
start N workers locking, unlocking and breaking leases via the fcntl(2)
F_SETLEASE operation. The parent processes continually lock and unlock a lease
on a file while a user selectable number of child processes open the file with
a non-blocking open to generate SIGIO lease breaking notifications to the
parent.  This stressor is only available if F_SETLEASE, F_WRLCK and F_UNLCK
support is provided by fcntl(2).
.TP
.B \-\-lease\-ops N
stop lease workers after N bogo operations.
.TP
.B \-\-lease\-breakers N
start N lease breaker child processes per lease worker.  Normally one child is
plenty to force many SIGIO lease breaking notification signals to the parent,
however, this option allows one to specify more child processes if required.
.TP
.B \-\-link N
start N workers creating and removing hardlinks.
.TP
.B \-\-link\-ops N
stop link stress workers after N bogo operations.
.TP
.B \-\-list N
start N workers that exercise list data structures. The default is
to add, find and remove 5,000 64 bit integers into circleq (doubly
linked circle queue), list (doubly linked list), slist (singly
linked list), slistt (singly linked list using tail), stailq (singly
linked tail queue) and tailq (doubly linked tail queue) lists. The
intention of this stressor is to exercise memory and cache with the
various list operations.
.TP
.B \-\-list\-ops N
stop list stressors after N bogo ops. A bogo op covers the addition,
finding and removing all the items into the list(s).
.TP
.B \-\-list\-size N
specify the size of the list, where N is the number of 64 bit integers
to be added into the list.
.TP
.B \-\-list\-method [ all | circleq | list | slist | stailq | tailq ]
specify the list to be used. By default, all the list methods are
used (the 'all' option).
.TP
.B \-\-loadavg N
start N workers that attempt to create thousands of pthreads that run
at the lowest nice priority to force very high load averages. Linux
systems will also perform some I/O writes as pending I/O is also
factored into system load accounting.
.TP
.B \-\-loadavg\-ops N
stop loadavg workers after N bogo scheduling yields by the pthreads
have been reached.
.TP
.B \-\-lockbus N
start N workers that rapidly lock and increment 64 bytes of randomly chosen
memory from a 16MB mmap'd region (Intel x86 and ARM CPUs only).  This will
cause cacheline misses and stalling of CPUs.
.TP
.B \-\-lockbus-ops N
stop lockbus workers after N bogo operations.
.TP
.B \-\-locka N
start N workers that randomly lock and unlock regions of a file using the
POSIX advisory locking mechanism (see fcntl(2), F_SETLK, F_GETLK). Each
worker creates a 1024 KB file and attempts to hold a maximum of 1024
concurrent locks with a child process that also tries to hold 1024
concurrent locks. Old locks are unlocked in a first-in, first-out basis.
.TP
.B \-\-locka\-ops N
stop locka workers after N bogo locka operations.
.TP
.B \-\-lockf N
start N workers that randomly lock and unlock regions of a file using the
POSIX lockf(3) locking mechanism. Each worker creates a 64 KB file and
attempts to hold a maximum of 1024 concurrent locks with a child process
that also tries to hold 1024 concurrent locks. Old locks are unlocked in
a first-in, first-out basis.
.TP
.B \-\-lockf\-ops N
stop lockf workers after N bogo lockf operations.
.TP
.B \-\-lockf\-nonblock
instead of using blocking F_LOCK lockf(3) commands, use non-blocking F_TLOCK
commands and re-try if the lock failed.  This creates extra system call
overhead and CPU utilisation as the number of lockf workers increases and
should increase locking contention.
.TP
.B \-\-lockofd N
start N workers that randomly lock and unlock regions of a file using the
Linux open file description locks (see fcntl(2), F_OFD_SETLK, F_OFD_GETLK).
Each worker creates a 1024 KB file and attempts to hold a maximum of 1024
concurrent locks with a child process that also tries to hold 1024
concurrent locks. Old locks are unlocked in a first-in, first-out basis.
.TP
.B \-\-lockofd\-ops N
stop lockofd workers after N bogo lockofd operations.
.TP
.B \-\-longjmp N
start N workers that exercise setjmp(3)/longjmp(3) by rapid looping on
longjmp calls.
.TP
.B \-\-longjmp-ops N
stop longjmp stress workers after N bogo longjmp operations (1 bogo op is 1000
longjmp calls).
.TP
.B \-\-loop N
start N workers that exercise the loopback control device. This creates 2MB
loopback devices, expands them to 4MB, performs some loopback status information
get and set operations and then destoys them. Linux only and requires
CAP_SYS_ADMIN capability.
.TP
.B \-\-loop\-ops N
stop after N bogo loopback creation/deletion operations.
.TP
.B \-\-lsearch N
start N workers that linear search a unsorted array of 32 bit integers using
lsearch(3). By default, there are 8192 elements in the array.  This is a
useful method to exercise sequential access of memory and processor cache.
.TP
.B \-\-lsearch\-ops N
stop the lsearch workers after N bogo lsearch operations are completed.
.TP
.B \-\-lsearch\-size N
specify the size (number of 32 bit integers) in the array to lsearch. Size can
be from 1K to 4M.
.TP
.B \-\-madvise N
start N workers that apply random madvise(2) advise settings on pages of
a 4MB file backed shared memory mapping.
.TP
.B \-\-madvise\-ops N
stop madvise stressors after N bogo madvise operations.
.TP
.B \-\-malloc N
start N workers continuously calling malloc(3), calloc(3), realloc(3) and
free(3). By default, up to 65536 allocations can be active at any point, but
this can be altered with the \-\-malloc\-max option.  Allocation, reallocation
and freeing are chosen at random; 50% of the time memory is allocation (via
malloc, calloc or realloc) and 50% of the time allocations are free'd.
Allocation sizes are also random, with the maximum allocation size controlled
by the \-\-malloc\-bytes option, the default size being 64K.  The worker is
re-started if it is killed by the out of memory (OOM) killer.
.TP
.B \-\-malloc\-bytes N
maximum per allocation/reallocation size. Allocations are randomly selected
from 1 to N bytes. One can specify the size as % of total available memory
or in units of Bytes, KBytes, MBytes and GBytes using the suffix b, k, m or
g.  Large allocation sizes cause the memory allocator to use mmap(2) rather
than expanding the heap using brk(2).
.TP
.B \-\-malloc\-max N
maximum number of active allocations allowed. Allocations are chosen at random
and placed in an allocation slot. Because about 50%/50% split between
allocation and freeing, typically half of the allocation slots are in use at
any one time.
.TP
.B \-\-malloc\-ops N
stop after N malloc bogo operations. One bogo operations relates to a
successful malloc(3), calloc(3) or realloc(3).
.TP
.B \-\-malloc\-pthreads N
specify number of malloc stressing concurrent pthreads to run. The default is
0 (just one main process, no pthreads). This option will do nothing if pthreads
are not supported.
.TP
.B \-\-malloc\-thresh N
specify the threshold where malloc uses mmap(2) instead of sbrk(2) to allocate
more memory. This is only available on systems that provide the GNU C
mallopt(3) tuning function.
.TP
.B \-\-malloc\-touch
touch every allocated page to force pages to be populated in memory. This will
increase the memory pressure and exercise the virtual memory harder. By default
the malloc stressor will madvise pages into memory or use mincore to check for
non-resident memory pages and try to force them into memory; this option
aggressively forces pages to be memory resident.
.TP
.B \-\-matrix N
start N workers that perform various matrix operations on floating point
values. Testing on 64 bit x86 hardware shows that this provides a good
mix of memory, cache and floating point operations and is an excellent way
to make a CPU run hot.

By default, this will exercise all the matrix stress methods one by
one.  One can specify a specific matrix stress method with the
\-\-matrix\-method option.
.TP
.B \-\-matrix\-ops N
stop matrix stress workers after N bogo operations.
.TP
.B \-\-matrix\-method method
specify a matrix stress method. Available matrix stress methods are described
as follows:
.TS
expand;
lB2 lB lB lB
l l s s.
Method	Description
all	T{
iterate over all the below matrix stress methods
T}
add	T{
add two N \(mu N matrices
T}
copy	T{
copy one N \(mu N matrix to another
T}
div	T{
divide an N \(mu N matrix by a scalar
T}
frobenius	T{
Frobenius product of two N \(mu N matrices
T}
hadamard	T{
Hadamard product of two N \(mu N matrices
T}
identity	T{
create an N \(mu N identity matrix
T}
mean	T{
arithmetic mean of two N \(mu N matrices
T}
mult	T{
multiply an N \(mu N matrix by a scalar
T}
negate	T{
negate an N \(mu N matrix
T}
prod	T{
product of two N \(mu N matrices
T}
sub	T{
subtract one N \(mu N matrix from another N \(mu N matrix
T}
square	T{
multiply an N \(mu N matrix by itself
T}
trans	T{
transpose an N \(mu N matrix
T}
zero	T{
zero an N \(mu N matrix
T}
.TE
.TP
.B \-\-matrix\-size N
specify the N \(mu N size of the matrices.  Smaller values result in a
floating point compute throughput bound stressor, where as large values result
in a cache and/or memory bandwidth bound stressor.
.TP
.B \-\-matrix\-yx
perform matrix operations in order y by x rather than the default x by y. This
is suboptimal ordering compared to the default and will perform more data
cache stalls.
.TP
.B \-\-matrix-3d N
start N workers that perform various 3D matrix operations on floating point
values. Testing on 64 bit x86 hardware shows that this provides a good
mix of memory, cache and floating point operations and is an excellent way
to make a CPU run hot.

By default, this will exercise all the 3D matrix stress methods one by
one.  One can specify a specific 3D matrix stress method with the
\-\-matrix\-3d\-method option.
.TP
.B \-\-matrix\-3d\-ops N
stop the 3D matrix stress workers after N bogo operations.
.TP
.B \-\-matrix\-3d\-method method
specify a 3D matrix stress method. Available 3D matrix stress methods are described
as follows:
.TS
expand;
lB2 lB lB lB
l l s s.
Method	Description
all	T{
iterate over all the below matrix stress methods
T}
add	T{
add two N \(mu N \(mu N matrices
T}
copy	T{
copy one N \(mu N \(mu N matrix to another
T}
div	T{
divide an N \(mu N \(mu N matrix by a scalar
T}
frobenius	T{
Frobenius product of two N \(mu N \(mu N matrices
T}
hadamard	T{
Hadamard product of two N \(mu N \(mu N matrices
T}
identity	T{
create an N \(mu N \(mu N identity matrix
T}
mean	T{
arithmetic mean of two N \(mu N \(mu N matrices
T}
mult	T{
multiply an N \(mu N \(mu N matrix by a scalar
T}
negate	T{
negate an N \(mu N \(mu N matrix
T}
sub	T{
subtract one N \(mu N \(mu N matrix from another N \(mu N \(mu N matrix
T}
trans	T{
transpose an N \(mu N \(mu N matrix
T}
zero	T{
zero an N \(mu N \(mu N matrix
T}
.TE
.TP
.B \-\-matrix\-3d\-size N
specify the N \(mu N \(mu N size of the matrices.  Smaller values result in a
floating point compute throughput bound stressor, where as large values result
in a cache and/or memory bandwidth bound stressor.
.TP
.B \-\-matrix\-3d\-zyx
perform matrix operations in order z by y by x rather than the default
x by y by z. This is suboptimal ordering compared to the default and will
perform more data cache stalls.
.TP
.B \-\-mcontend N
start N workers that produce memory contention read/write patterns. Each
stressor runs with 5 threads that read and write to two different mappings
of the same underlying physical page. Various caching operations are also
exercised to cause sub-optimal memory access patterns.  The threads also
randomly change CPU affinity to exercise CPU and memory migration stress.
.TP
.B \-\-mcontend\-ops N
stop mcontend stressors after N bogo read/write operations.
.TP
.B \-\-membarrier N
start N workers that exercise the membarrier system call (Linux only).
.TP
.B \-\-membarrier\-ops N
stop membarrier stress workers after N bogo membarrier operations.
.TP
.B \-\-memcpy N
start N workers that copy 2MB of data from a shared region to a buffer using
memcpy(3) and then move the data in the buffer with memmove(3) with 3
different alignments. This will exercise processor cache and system memory.
.TP
.B \-\-memcpy\-ops N
stop memcpy stress workers after N bogo memcpy operations.
.TP
.B \-\-memcpy\-method [ all | libc | builtin | naive ]
specify a memcpy copying method. Available memcpy methods are described
as follows:
.TS
expand;
lB2 lB lB lB
l l s s.
Method	Description
all	T{
use libc, builtin and na\[:i]ve methods
T}
libc	T{
use libc memcpy and memmove functions, this is the default
T}
builtin	T{
use the compiler built in optimized memcpy and memmove functions
T}
naive	T{
use na\[:i]ve byte by byte copying and memory moving build with default
compiler optimization flags
T}
naive_o0	T{
use unoptimized na\[:i]ve byte by byte copying and memory moving
T}
naive_o3	T{
use optimized na\[:i]ve byte by byte copying and memory moving build with -O3
optimization and where possible use CPU specific optimizations
T}
.TE
.TP
.B \-\-memfd N
start N workers that create allocations of 1024 pages using memfd_create(2)
and ftruncate(2) for allocation and mmap(2) to map the allocation into the
process address space.  (Linux only).
.TP
.B \-\-memfd\-bytes N
allocate N bytes per memfd stress worker, the default is 256MB. One can specify
the size in as % of total available memory or in units of Bytes, KBytes, MBytes
and GBytes using the suffix b, k, m or g.
.TP
.B \-\-memfd\-fds N
create N memfd file descriptors, the default is 256. One can select 8 to 4096
memfd file descriptions with this option.
.TP
.B \-\-memfd\-ops N
stop after N memfd-create(2) bogo operations.
.TP
.B \-\-memhotplug N
start N workers that offline and online memory hotplug regions. Linux only
and requires CAP_SYS_ADMIN capabilities.
.TP
.B \-\-memhotplug\-ops N
stop memhotplug stressors after N memory offline and online bogo operations.
.TP
.B \-\-memrate N
start N workers that exercise a buffer with 1024, 512, 256, 128, 64, 32, 16 and
8 bit reads and writes. 1024, 512 and 256 reads and writes are available with
compilers that support integer vectors.  x86-64 cpus that support uncached
(non-temporal "nt") writes also exercise 128, 64 and 32 writes providing
higher write rates than the normal cached writes. CPUs that support prefetching
reads also exercise 64 prefetched "pf" reads.
This memory stressor allows one to also specify the maximum read
and write rates. The stressors will run at maximum speed if no read or
write rates are specified.
.TP
.B \-\-memrate\-ops N
stop after N bogo memrate operations.
.TP
.B \-\-memrate\-bytes N
specify the size of the memory buffer being exercised. The default size
is 256MB. One can specify the size in units of Bytes, KBytes, MBytes and
GBytes using the suffix b, k, m or g.
.TP
.B \-\-memrate\-rd\-mbs N
specify the maximum allowed read rate in MB/sec. The actual read rate
is dependent on scheduling jitter and memory accesses from other running
processes.
.TP
.B \-\-memrate\-wr\-mbs N
specify the maximum allowed read rate in MB/sec. The actual write rate
is dependent on scheduling jitter and memory accesses from other running
processes.
.TP
.B \-\-memthrash N
start N workers that thrash and exercise a 16MB buffer in various ways to
try and trip thermal overrun.  Each stressor will start 1 or more threads.
The number of threads is chosen so that there will be at least 1 thread
per CPU. Note that the optimal choice for N is a value that divides into
the number of CPUs.
.TP
.B \-\-memthrash-ops N
stop after N memthrash bogo operations.
.TP
.B \-\-memthrash\-method method
specify a memthrash stress method. Available memthrash stress methods are described
as follows:
.TS
expand;
lB2 lB lB lB
l l s s.
Method	Description
all	T{
iterate over all the below memthrash methods
T}
chunk1	T{
memset 1 byte chunks of random data into random locations
T}
chunk8	T{
memset 8 byte chunks of random data into random locations
T}
chunk64	T{
memset 64 byte chunks of random data into random locations
T}
chunk256	T{
memset 256 byte chunks of random data into random locations
T}
chunkpage	T{
memset page size chunks of random data into random locations
T}
flip	T{
flip (invert) all bits in random locations
T}
flush	T{
flush cache line in random locations
T}
lock	T{
lock randomly choosing locations (Intel x86 and ARM CPUs only)
T}
matrix	T{
treat memory as a 2 \(mu 2 matrix and swap random elements
T}
memmove	T{
copy all the data in buffer to the next memory location
T}
memset	T{
memset the memory with random data
T}
memset64	T{
memset the memory with a random 64 bit value in 64 byte chunks using
non-temporal stores if possible or normal stores as a fallback
T}
mfence	T{
stores with write serialization
T}
prefetch	T{
prefetch data at random memory locations
T}
random	T{
randomly run any of the memthrash methods except for 'random' and 'all'
T}
spinread	T{
spin loop read the same random location 2^19 times
T}
spinwrite	T{
spin loop write the same random location 2^19 times
T}
swap	T{
step through memory swapping bytes in steps of 65 and 129 byte strides
T}
.TE
.TP
.B -\-mergesort N
start N workers that sort 32 bit integers using the BSD mergesort.
.TP
.B \-\-mergesort\-ops N
stop mergesort stress workers after N bogo mergesorts.
.TP
.B \-\-mergesort\-size N
specify number of 32 bit integers to sort, default is 262144 (256 \(mu 1024).
.TP
.B \-\-mincore N
start N workers that walk through all of memory 1 page at a time checking if
the page mapped and also is resident in memory using mincore(2). It also
maps and unmaps a page to check if the page is mapped or not using mincore(2).
.TP
.B \-\-mincore\-ops N
stop after N mincore bogo operations. One mincore bogo op is equivalent to a
300 mincore(2) calls.
.TE
.B \-\-mincore\-random
instead of walking through pages sequentially, select pages at random. The
chosen address is iterated over by shifting it right one place and checked by
mincore until the address is less or equal to the page size.
.TP
.B \-\-misaligned N
start N workers that perform misaligned read and writes. By default, this
will exercise 128 bit misaligned read and writes in 8 x 16 bits, 4 x 32 bits,
2 x 64 bits and 1 x 128 bits at the start of a page boundary, at the end
of a page boundary and over a cache boundary. Misaligned read and writes
operate at 1 byte offset from the natural alignment of the data
type. On some architectures this can cause SIGBUS, SIGILL or SIGSEGV, these are
handled and the misaligned stressor method causing the error is disabled.
.TP
.B \-\-misaligned\-ops N
stop after N misaligned bogo operation. A misaligned bogo op is equivalent
to 65536 x 128 bit reads or writes.
.TP
.B \-\-misaligned\-method M
Available misaligned stress methods are described as follows:
.TS
expand;
lB2 lB lB lB
l l s s.
Method	Description
all	iterate over all the following misaligned methods
int16rd	8 x 16 bit integer reads
int16wr	8 x 16 bit integer writes
int16inc	8 x 16 bit integer increments
int16atomic	8 x 16 bit atomic integer increments
int32rd	4 x 32 bit integer reads
int32wr	4 x 32 bit integer writes
int32wtnt	4 x 32 bit non-termporal stores (x86 only)
int32inc	4 x 32 bit integer increments
int32atomic	4 x 32 bit atomic integer increments
int64rd	2 x 64 bit integer reads
int64wr	2 x 64 bit integer writes
int64wtnt	4 x 64 bit non-termporal stores (x86 only)
int64inc	2 x 64 bit integer increments
int64atomic	2 x 64 bit atomic integer increments
int128rd	1 x 128 bit integer reads
int128wr	1 x 128 bit integer writes
int128inc	1 x 128 bit integer increments
int128atomic	1 x 128 bit atomic integer increments
.TE
.PP
Note that some of these options (128 bit integer and/or atomic operations) may
not be available on some systems.
.TP
.B \-\-mknod N
start N workers that create and remove fifos, empty files and named sockets
using mknod and unlink.
.TP
.B \-\-mknod\-ops N
stop directory thrash workers after N bogo mknod operations.
.TP
.B \-\-mlock N
start N workers that lock and unlock memory mapped pages using mlock(2),
munlock(2), mlockall(2) and munlockall(2). This is achieved by the mapping of
three contiguous pages and then locking the second page, hence ensuring
non-contiguous pages are locked . This is then repeated until the maximum
allowed mlocks or a maximum of 262144 mappings are made.  Next, all future
mappings are mlocked and the worker attempts to map 262144 pages, then all
pages are munlocked and the pages are unmapped.
.TP
.B \-\-mlock\-ops N
stop after N mlock bogo operations.
.TP
.B \-\-mlockmany N
start N workers that fork off a default of 1024 child processes in total;
each child will attempt to anonymously mmap and mlock the maximum allowed
mlockable memory size.  The stress test attempts to avoid swapping by
tracking low memory and swap allocations (but some swapping may occur). Once
either the maximum number of child process is reached or all mlockable in-core
memory is locked then child processes are killed and the stress test is
repeated.
.TP
.B \-\-mlockmany\-ops N
stop after N mlockmany (mmap and mlock) operations.
.TP
.B \-\-mlockmany\-procs N
set the number of child processes to create per stressor. The default is to
start a maximum of 1024 child processes in total across all the stressors. This
option allows the setting of N child processes per stressor.
.TP
.B \-\-mmap N
start N workers continuously calling mmap(2)/munmap(2).  The initial mapping
is a large chunk (size specified by \-\-mmap\-bytes) followed by pseudo-random
4K unmappings, then pseudo-random 4K mappings, and then linear 4K unmappings.
Note that this can cause systems to trip the kernel OOM killer on Linux
systems if not enough physical memory and swap is not available.  The
MAP_POPULATE option is used to populate pages into memory on systems that
support this.  By default, anonymous mappings are used, however, the
\-\-mmap\-file and \-\-mmap\-async options allow one to perform file based
mappings if desired.
.TP
.B \-\-mmap\-ops N
stop mmap stress workers after N bogo operations.
.TP
.B \-\-mmap\-async
enable file based memory mapping and use asynchronous msync'ing on each page,
see \-\-mmap\-file.
.TP
.B \-\-mmap\-bytes N
allocate N bytes per mmap stress worker, the default is 256MB. One can specify
the size as % of total available memory or in units of Bytes, KBytes, MBytes
and GBytes using the suffix b, k, m or g.
.TP
.B \-\-mmap\-file
enable file based memory mapping and by default use synchronous msync'ing on
each page.
.TP
.B \-\-mmap\-mmap2
use mmap2 for 4K page aligned offsets if mmap2 is available, otherwise fall back
to mmap.
.TP
.B \-\-mmap\-mprotect
change protection settings on each page of memory.  Each time a page or a
group of pages are mapped or remapped then this option will make the pages
read-only, write-only, exec-only, and read-write.
.TP
.B \-\-mmap\-odirect
enable file based memory mapping and use O_DIRECT direct I/O.
.TP
.B \-\-mmap\-osync
enable file based memory mapping and used O_SYNC synchronous I/O
integrity completion.
.TP
.B \-\-mmapaddr N
start N workers that memory map pages at a random memory location that is
not already mapped.  On 64 bit machines the random address is randomly
chosen 32 bit or 64 bit address. If the mapping works a second page is
memory mapped from the first mapped address. The stressor exercises
mmap/munmap, mincore and segfault handling.
.TP
.B \-\-mmapaddr\-ops N
stop after N random address mmap bogo operations.
.TP
.B \-\-mmapfork N
start N workers that each fork off 32 child processes, each of which tries to
allocate some of the free memory left in the system (and trying to avoid
any swapping).  The child processes then hint that the allocation will be
needed with madvise(2) and then memset it to zero and hint that it is no longer
needed with madvise before exiting.  This produces significant amounts of VM
activity, a lot of cache misses and with minimal swapping.
.TP
.B \-\-mmapfork\-ops N
stop after N mmapfork bogo operations.
.TP
.B \-\-mmapfixed N
start N workers that perform fixed address allocations from the top virtual
address down to 128K.  The allocated sizes are from 1 page to 8 pages and
various random mmap flags are used MAP_SHARED/MAP_PRIVATE, MAP_LOCKED,
MAP_NORESERVE, MAP_POPULATE. If successfully map'd then the allocation
is remap'd to an address that is several pages higher in memory. Mappings
and remappings are madvised with random madvise options to further exercise
the mappings.
.TP
.B \-\-mmapfixed\-ops N
stop after N mmapfixed memory mapping bogo operations.
.TP
.B \-\-mmaphuge N
start N workers that attempt to mmap a set of huge pages and large huge
page sized mappings. Successful mappings are madvised with MADV_NOHUGEPAGE
and MADV_HUGEPAGE settings and then 1/64th of the normal small page size pages
are touched. Finally, an attempt to unmap a small page size page at the
end of the mapping is made (these may fail on huge pages) before the set
of pages are unmapped. By default 8192 mappings are attempted per round
of mappings or until swapping is detected.
.TP
.B \-\-mmaphuge\-ops N
stop after N mmaphuge bogo operations
.TP
.B \-\-mmaphuge\-mmaps N
set the number of huge page mappings to attempt in each round of mappings. The
default is 8192 mappings.
.TP
.B \-\-mmapmany N
start N workers that attempt to create the maximum allowed per-process memory
mappings. This is achieved by mapping 3 contiguous pages and then unmapping the
middle page hence splitting the mapping into two. This is then repeated until
the maximum allowed mappings or a maximum of 262144 mappings are made.
.TP
.B \-\-mmapmany\-ops N
stop after N mmapmany bogo operations
.TP
.B \-\-mq N
start N sender and receiver processes that continually send and receive
messages using POSIX message queues. (Linux only).
.TP
.B \-\-mq\-ops N
stop after N bogo POSIX message send operations completed.
.TP
.B \-\-mq\-size N
specify size of POSIX message queue. The default size is 10 messages and most
Linux systems this is the maximum allowed size for normal users. If the given
size is greater than the allowed message queue size then a warning is issued
and the maximum allowed size is used instead.
.TP
.B \-\-mremap N
start N workers continuously calling mmap(2), mremap(2) and munmap(2).  The
initial anonymous mapping is a large chunk (size specified by
\-\-mremap\-bytes) and then iteratively halved in size by remapping all the
way down to a page size and then back up to the original size.  This worker
is only available for Linux.
.TP
.B \-\-mremap\-ops N
stop mremap stress workers after N bogo operations.
.TP
.B \-\-mremap\-bytes N
initially allocate N bytes per remap stress worker, the default is 256MB. One
can specify the size in units of Bytes, KBytes, MBytes and GBytes using the
suffix b, k, m or g.
.TP
.B \-\-mremap\-mlock
attempt to mlock remapped pages into memory prohibiting them from being
paged out.  This is a no-op if mlock(2) is not available.
.TP
.B \-\-msg N
start N sender and receiver processes that continually send and receive
messages using System V message IPC.
.TP
.B \-\-msg\-ops N
stop after N bogo message send operations completed.
.TP
.B \-\-msg\-types N
select the quality of message types (mtype) to use. By default, msgsnd sends
messages with a mtype of 1, this option allows one to send messages types
in the range 1..N to exercise the message queue receive ordering. This will
also impact throughput performance.
.TP
.B \-\-msync N
start N stressors that msync data from a file backed memory mapping from
memory back to the file and msync modified data from the file back to the
mapped memory. This exercises the msync(2) MS_SYNC and MS_INVALIDATE sync
operations.
.TP
.B \-\-msync\-ops N
stop after N msync bogo operations completed.
.TP
.B \-\-msync\-bytes N
allocate N bytes for the memory mapped file, the default is 256MB. One
can specify the size as % of total available memory or in units of Bytes,
KBytes, MBytes and GBytes using the suffix b, k, m or g.
.TP
.B \-\-msyncmany N
start N stressors that memory map up to 32768 pages on the same page of
a temporary file, change the first 32 bits in a page and msync the data back
to the file.  The other 32767 pages are examined to see if the 32 bit
check value is msync'd back to these pages.
.TP
.B \-\-msyncmany\-ops N
stop after N msync calls in the msyncmany stressors are completed.
.TP
.B \-\-munmap N
start N stressors that exercise unmapping of shared non-executable mapped
regions of child processes (Linux only). The unmappings map shared memory regions page
by page with a prime sized stride that creates many temporary mapping holes.
One the unmappings are complete the child will exit and a new one is started.
Note that this may trigger segmentation faults in the child process, these
are handled where possible by forcing the child process to call _exit(2).
.TP
.B \-\-munmap\-ops N
stop after N page unmappings.
.TP
.B \-\-mutex N
start N stressors that exercise pthread mutex locking and unlocking. If run
with enough privilege then the FIFO scheduler is used and a random priority between
0 and 80% of the maximum FIFO priority level is selected for the locking operation.
The minimum FIFO priority level is selected for the critical mutex section and
unlocking operation to exercise random inverted priority scheduling.
.TP
.B \-\-mutex\-ops N
stop after N bogo mutex lock/unlock operations.
.TP
.B \-\-mutex\-procs N
By default 2 threads are used for locking/unlocking on a single mutex. This option
allows the default to be changed to 2 to 64 concurrent threads.
.TP
.B \-\-nanosleep N
start N workers that each run 256 pthreads that call nanosleep with random
delays from 1 to 2^18 nanoseconds. This should exercise the high resolution
timers and scheduler.
.TP
.B \-\-nanosleep\-ops N
stop the nanosleep stressor after N bogo nanosleep operations.
.TP
.B \-\-netdev N
start N workers that exercise various netdevice ioctl commands across
all the available network devices. The ioctls exercised by this stressor
are as follows: SIOCGIFCONF, SIOCGIFINDEX, SIOCGIFNAME, SIOCGIFFLAGS,
SIOCGIFADDR, SIOCGIFNETMASK, SIOCGIFMETRIC, SIOCGIFMTU, SIOCGIFHWADDR,
SIOCGIFMAP and SIOCGIFTXQLEN. See netdevice(7) for more details of these
ioctl commands.
.TP
.B \-\-netdev\-ops N
stop after N netdev bogo operations completed.
.TP
.B \-\-netlink\-proc N
start N workers that spawn child processes and monitor fork/exec/exit
process events via the proc netlink connector. Each event received is counted
as a bogo op. This stressor can only be run on Linux and requires
CAP_NET_ADMIN capability.
.TP
.B \-\-netlink\-proc\-ops N
stop the proc netlink connector stressors after N bogo ops.
.TP
.B \-\-netlink\-task N
start N workers that collect task statistics via the netlink taskstats
interface.  This stressor can only be run on Linux and requires
CAP_NET_ADMIN capability.
.TP
.B \-\-netlink\-task\-ops N
stop the taskstats netlink connector stressors after N bogo ops.
.TP
.B \-\-nice N
start N cpu consuming workers that exercise the available nice levels. Each
iteration forks off a child process that runs through the all the nice levels
running a busy loop for 0.1 seconds per level and then exits.
.TP
.B \-\-nice\-ops N
stop after N nice bogo nice loops
.TP
.B \-\-nop N
start N workers that consume cpu cycles issuing no-op instructions. This
stressor is available if the assembler supports the "nop" instruction.
.TP
.B \-\-nop\-ops N
stop nop workers after N no-op bogo operations. Each bogo-operation is
equivalent to 256 loops of 256 no-op instructions.
.TP
.B \-\-nop\-instr INSTR
use alternative nop instruction INSTR. For x86 CPUs INSTR can be one
of nop, pause, nop2 (2 byte nop) through to nop11 (11 byte nop). For
ARM CPUs, INSTR can be one of nop or yield. For PPC64 CPUs, INSTR
can be one of nop, mdoio, mdoom or yield. For S390 CPUs, INSTR
can be one of nop or nopr. For other processors, INSTR
is only nop. The random INSTR option selects a randon mix of the
available nop instructions. If the chosen INSTR generates an SIGILL
signal, then the stressor falls back to the vanilla nop instruction.
.TP
.B \-\-null N
start N workers writing to /dev/null.
.TP
.B \-\-null\-ops N
stop null stress workers after N /dev/null bogo write operations.
.TP
.B \-\-numa N
start N workers that migrate stressors and a 4MB memory mapped buffer around
all the available NUMA nodes.  This uses migrate_pages(2) to move the stressors
and mbind(2) and move_pages(2) to move the pages of the mapped buffer. After
each move, the buffer is written to force activity over the bus which results
cache misses.  This test will only run on hardware with NUMA enabled and more
than 1 NUMA node.
.TP
.B \-\-numa\-ops N
stop NUMA stress workers after N bogo NUMA operations.
.TP
.B \-\-oom\-pipe N
start N workers that create as many pipes as allowed and exercise expanding
and shrinking the pipes from the largest pipe size down to a page size. Data
is written into the pipes and read out again to fill the pipe buffers. With
the \-\-aggressive mode enabled the data is not read out when the pipes are
shrunk, causing the kernel to OOM processes aggressively.  Running many
instances of this stressor will force kernel to OOM processes due to the
many large pipe buffer allocations.
.TP
.B \-\-oom\-pipe\-ops N
stop after N bogo pipe expand/shrink operations.
.TP
.B \-\-opcode N
start N workers that fork off children that execute randomly generated
executable code.  This will generate issues such as illegal instructions,
bus errors, segmentation faults, traps, floating point errors that are
handled gracefully by the stressor.
.TP
.B \-\-opcode\-ops N
stop after N attempts to execute illegal code.
.TP
.B \-\-opcode\-method [ inc | mixed | random | text ]
select the opcode generation method.  By default, random bytes are used to
generate the executable code. This option allows one to select one of the
three methods:
.TS
expand;
lBw(8n) lB lB
l l s.
Method	Description
inc	T{
use incrementing 32 bit opcode patterns from 0x00000000 to 0xfffffff inclusive.
T}
mixed	T{
use a mix of incrementing 32 bit opcode patterns and random 32 bit opcode patterns that
are also inverted, encoded with gray encoding and bit reversed.
T}
random	T{
generate opcodes using random bytes from a mwc random generator.
T}
text	T{
copies random chunks of code from the stress-ng text segment and randomly flips
single bits in a random choice of 1/8th of the code.
T}
.TE
.TP
.B \-o N, \-\-open N
start N workers that perform open(2) and then close(2) operations on
/dev/zero. The maximum opens at one time is system defined, so the test will
run up to this maximum, or 65536 open file descriptors, which ever comes first.
.TP
.B \-\-open\-ops N
stop the open stress workers after N bogo open operations.
.TP
.B \-\-open\-fd
run a child process that scans /proc/$PID/fd and attempts to open the files
that the stressor has opened. This exercises racing open/close operations
on the proc interface.
.TP
.B \-\-pageswap N
start N workers that exercise page swap in and swap out. Pages are allocated
and paged out using madvise MADV_PAGEOUT. One the maximum per process number
of mmaps are reached or 65536 pages are allocated the pages are read to
page them back in and unmapped in reverse mapping order.
.TP
.B \-\-pageswap-ops N
stop after N page allocation bogo operations.
.TP
.B \-\-pci N
exercise PCI sysfs by running N workers that read data (and mmap/unmap
PCI config or PCI resource files). Linux only. Running as root will allow
config and resource mmappings to be read and exercises PCI I/O mapping.
.TP
.B \-\-pci\-ops N
stop pci stress workers after N PCI subdirectory exercising operations.
.TP
.B \-\-personality N
start N workers that attempt to set personality and get all the available
personality types (process execution domain types) via the personality(2)
system call. (Linux only).
.TP
.B \-\-personality\-ops N
stop personality stress workers after N bogo personality operations.
.TP
.B \-\-peterson N
start N workers that exercises mutex exclusion between two processes using
shared memory with the Peterson Algorithm. Where possible this uses memory fencing
and falls back to using GCC __sync_synchronize if they are not available. The
stressors contain simple mutex and memory coherency sanity checks.
.TP
.B \-\-peterson\-ops N
stop peterson workers after N mutex operations.
.TP
.B \-\-physpage N
start N workers that use /proc/self/pagemap and /proc/kpagecount to determine
the physical page and page count of a virtual mapped page and a page that is
shared among all the stressors. Linux only and requires the CAP_SYS_ADMIN
capabilities.
.TP
.B \-\-physpage\-ops N
stop physpage stress workers after N bogo physical address lookups.
.TP
.B \-\-pidfd N
start N workers that exercise signal sending via the pidfd_send_signal system call.
This stressor creates child processes and checks if they exist and can be
stopped, restarted and killed using the pidfd_send_signal system call.
.TP
.B \-\-pidfd\-ops N
stop pidfd stress workers after N child processes have been created, tested
and killed with pidfd_send_signal.
.TP
.B \-\-ping\-sock N
start N workers that send small randomized ICMP messages to the localhost
across a range of ports (1024..65535) using a "ping" socket with an AF_INET
domain, a SOCK_DGRAM socket type and an IPPROTO_ICMP protocol.
.TP
.B \-\-ping\-sock\-ops N
stop the ping\-sock stress workers after N ICMP messages are sent.
.TP
.B \-p N, \-\-pipe N
start N workers that perform large pipe writes and reads to exercise pipe I/O.
This exercises memory write and reads as well as context switching.  Each
worker has two processes, a reader and a writer.
.TP
.B \-\-pipe\-ops N
stop pipe stress workers after N bogo pipe write operations.
.TP
.B \-\-pipe\-data\-size N
specifies the size in bytes of each write to the pipe (range from 4 bytes
to 4096 bytes). Setting a small data size will cause more writes to be
buffered in the pipe, hence reducing the context switch rate between the
pipe writer and pipe reader processes. Default size is the page size.
.TP
.B \-\-pipe\-size N
specifies the size of the pipe in bytes (for systems that support the
F_SETPIPE_SZ fcntl() command). Setting a small pipe size will cause the pipe
to fill and block more frequently, hence increasing the context switch rate
between the pipe writer and the pipe reader processes. Default size is 512
bytes.
.TP
.B \-\-pipeherd N
start N workers that pass a 64 bit token counter to/from 100 child processes
over a shared pipe. This forces a high context switch rate and can trigger
a "thundering herd" of wakeups on processes that are blocked on pipe waits.
.TP
.B \-\-pipeherd\-ops N
stop pipe stress workers after N bogo pipe write operations.
.TP
.B \-\-pipeherd\-yield
force a scheduling yield after each write, this increases the context
switch rate.
.TP
.B \-\-pkey N
start N workers that change memory protection using a protection key (pkey) and
the pkey_mprotect call (Linux only). This will try to allocate a pkey and
use this for the page protection, however, if this fails then the special
pkey -1 will be used (and the kernel will use the normal mprotect mechanism
instead).  Various page protection mixes of read/write/exec/none will
be cycled through on randomly chosen pre-allocated pages.
.TP
.B \-\-pkey\-ops N
stop after N pkey_mprotect page protection cycles.
.TP
.B \-P N, \-\-poll N
start N workers that perform zero timeout polling via the poll(2), ppoll(2),
select(2), pselect(2) and sleep(3) calls. This wastes system and user time
doing nothing.
.TP
.B \-\-poll\-ops N
stop poll stress workers after N bogo poll operations.
.TP
.B \-\-poll\-fds N
specify the number of file descriptors to poll/ppoll/select/pselect on.
The maximum number for select/pselect is limited by FD_SETSIZE and the
upper maximum is also limited by the maximum number of pipe open descriptors
allowed.
.TP
.B \-\-prctl N
start N workers that exercise the majority of the prctl(2) system call
options. Each batch of prctl calls is performed inside a new child process
to ensure the limit of prctl is contained inside a new process every time.
Some prctl options are architecture specific, however, this stressor will
exercise these even if they are not implemented.
.TP
.B \-\-prctl\-ops N
stop prctl workers after N batches of prctl calls
.TP
.B \-\-prefetch N
start N workers that benchmark prefetch and non-prefetch reads of a L3
cache sized buffer. The buffer is read with loops of 8 \(mu 64 bit reads
per iteration. In the prefetch cases, data is prefetched ahead of the
current read position by various sized offsets, from 64 bytes to 8K
to find the best memory read throughput. The stressor reports the
non-prefetch read rate and the best prefetched read rate. It also reports
the prefetch offset and an estimate of the amount of time between the
prefetch issue and the actual memory read operation. These statistics
will vary from run-to-run due to system noise and CPU frequency scaling.
.TP
.B \-\-prefetch-ops N
stop prefetch stressors after N benchmark operations
.TP
.B \-\-prefetch-l3-size N
specify the size of the l3 cache
.TP
.B \-\-procfs N
start N workers that read files from /proc and recursively read files from
/proc/self (Linux only).
.TP
.B \-\-procfs\-ops N
stop procfs reading after N bogo read operations. Note, since the number of
entries may vary between kernels, this bogo ops metric is probably very
misleading.
.TP
.B \-\-pthread N
start N workers that iteratively creates and terminates multiple pthreads
(the default is 1024 pthreads per worker). In each iteration, each newly
created pthread waits until the worker has created all the pthreads and then
they all terminate together.
.TP
.B \-\-pthread\-ops N
stop pthread workers after N bogo pthread create operations.
.TP
.B \-\-pthread\-max N
create N pthreads per worker. If the product of the number of pthreads by the
number of workers is greater than the soft limit of allowed pthreads then the
maximum is re-adjusted down to the maximum allowed.
.TP
.B \-\-ptrace N
start N workers that fork and trace system calls of a child process using
ptrace(2).
.TP
.B \-\-ptrace\-ops N
stop ptracer workers after N bogo system calls are traced.
.TP
.B \-\-pty N
start N workers that repeatedly attempt to open pseudoterminals and
perform various pty ioctls upon the ptys before closing them.
.TP
.B \-\-pty\-ops N
stop pty workers after N pty bogo operations.
.TP
.B \-\-pty\-max N
try to open a maximum of N pseudoterminals, the default is 65536. The allowed
range of this setting is 8..65536.
.TP
.B \-Q, \-\-qsort N
start N workers that sort 32 bit integers using qsort.
.TP
.B \-\-qsort\-ops N
stop qsort stress workers after N bogo qsorts.
.TP
.B \-\-qsort\-size N
specify number of 32 bit integers to sort, default is 262144 (256 \(mu 1024).
.TP
.B \-\-quota N
start N workers that exercise the Q_GETQUOTA, Q_GETFMT, Q_GETINFO, Q_GETSTATS
and Q_SYNC quotactl(2) commands on all the available mounted block based file
systems. Requires CAP_SYS_ADMIN capability to run.
.TP
.B \-\-\quota\-ops N
stop quota stress workers after N bogo quotactl operations.
.TP
.B \-\-radixsort N
start N workers that sort random 8 byte strings using radixsort.
.TP
.B \-\-radixsort\-ops N
stop radixsort stress workers after N bogo radixsorts.
.TP
.B \-\-radixsort\-size N
specify number of strings to sort, default is 262144 (256 \(mu 1024).
.TP
.B \-\-ramfs N
start N workers mounting a memory based file system using ramfs and
tmpfs (Linux only). This alternates between mounting and umounting a
ramfs or tmpfs file system using the traditional mount(2) and
umount(2) system call as well as the newer Linux 5.2 fsopen(2),
fsmount(2), fsconfig(2) and move_mount(2) system calls if they
are available. The default ram file system size is 2MB.
.TP
.B \-\-ramfs\-ops N
stop after N ramfs mount operations.
.TP
.B \-\-ramfs\-size N
set the ramfs size (must be multiples of the page size).
.TP
.B \-\-rawdev N
start N workers that read the underlying raw drive device using direct
IO reads. The device (with minor number 0) that stores the current working
directory is the raw device to be read by the stressor.  The read size is
exactly the size of the underlying device block size.  By default, this
stressor will exercise all the of the rawdev methods (see the
\-\-rawdev\-method option). This is a Linux only stressor and requires
root privilege to be able to read the raw device.
.TP
.B \-\-rawdev\-ops N
stop the rawdev stress workers after N raw device read bogo operations.
.TP
.B \-\-rawdev\-method M
Available rawdev stress methods are described as follows:
.TS
expand;
lB2 lB lB lB
l l s s.
Method	Description
all	T{
iterate over all the rawdev stress methods as listed below:
T}
sweep	T{
repeatedly read across the raw device from the 0th block to the end block in steps
of the number of blocks on the device / 128 and back to the start again.
T}
wiggle	T{
repeatedly read across the raw device in 128 evenly steps with each step reading
1024 blocks backwards from each step.
T}
ends	T{
repeatedly read the first and last 128 start and end blocks of the raw device
alternating from start of the device to the end of the device.
T}
random	T{
repeatedly read 256 random blocks
T}
burst	T{
repeatedly read 256 sequential blocks starting from a random block on the raw device.
T}
.TE
.TP
.B \-\-randlist N
start N workers that creates a list of objects in randomized memory order and traverses
the list setting and reading the objects. This is designed to exerise memory and cache
thrashing. Normally the objects are allocated on the heap, however for objects of page
size or larger there is a 1 in 16 chance of objects being allocated using shared
anonymous memory mapping to mix up the address spaces of the allocations to create more
TLB thrashing.
.TP
.B \-\-randlist\-ops N
stop randlist workers after N list traversals
.TP
.B \-\-randist\-compact
Allocate all the list objects using one large heap allocation and divide this up
for all the list objects. This removes the overhead of the heap keeping track of
each list object, hence uses less memory.
.TP
.B \-\-randlist\-items N
Allocate N items on the list. By default, 100,000 items are allocated.
.TP
.B \-\-randlist\-size N
Allocate each item to be N bytes in size. By default, the size is 64 bytes of
data payload plus the list handling pointer overhead.
.TP
.B \-\-rawsock N
start N workers that send and receive packet data using raw sockets on the
localhost. Requires CAP_NET_RAW to run.
.TP
.B \-\-rawsock-ops N
stop rawsock workers after N packets are received.
.TP
.B \-\-rawpkt N
start N workers that sends and receives ethernet packets
using raw packets on the localhost via the loopback device. Requires
CAP_NET_RAW to run.
.TP
.B \-\-rawpkt\-ops N
stop rawpkt workers after N packets from the sender process are received.
.TP
.B \-\-rawpkt\-port N
start at port P. For N rawpkt worker processes, ports P to (P * 4) - 1
are used. The default starting port is port 14000.
.TP
.B \-\-rawudp N
start N workers that send and receive UDP packets using raw sockets on the
localhost. Requires CAP_NET_RAW to run.
.TP
.B \-\-rawudp\-ops N
stop rawudp workers after N packets are received.
.TP
.B \-\-rawudp\-port N
start at port P. For N rawudp worker processes, ports P to (P * 4) - 1
are used. The default starting port is port 13000.
.TP
.B \-\-rdrand N
start N workers that read a random number from an on-chip random number generator
This uses the rdrand instruction on Intel x86 processors or the darn instruction
on Power9 processors.
.TP
.B \-\-rdrand\-ops N
stop rdrand stress workers after N bogo rdrand operations (1 bogo op = 2048
random bits successfully read).
.TP
.B \-\-rdrand\-seed
use rdseed instead of rdrand (x86 only).
.TP
.B \-\-readahead N
start N workers that randomly seek and perform 4096 byte read/write I/O
operations on a file with readahead. The default file size is 64 MB.  Readaheads
and reads are batched into 16 readaheads and then 16 reads.
.TP
.B \-\-readahead\-bytes N
set the size of readahead file, the default is 1 GB. One can specify the size
as % of free space on the file system or in units of Bytes, KBytes, MBytes and
GBytes using the suffix b, k, m or g.
.TP
.B \-\-readahead\-ops N
stop readahead stress workers after N bogo read operations.
.TP
.B \-\-reboot N
start N workers that exercise the reboot(2) system call. When possible, it
will create a process in a PID namespace and perform a reboot power off command
that should shutdown the process.  Also, the stressor exercises invalid
reboot magic values and invalid reboots when there are insufficient privileges
that will not actually reboot the system.
.TP
.B \-\-reboot\-ops N
stop the reboot stress workers after N bogo reboot cycles.
.TP
.B \-\-remap N
start N workers that map 512 pages and re-order these pages using the
deprecated system call remap_file_pages(2). Several page re-orderings are
exercised: forward, reverse, random and many pages to 1 page.
.TP
.B \-\-remap\-ops N
stop after N remapping bogo operations.
.TP
.B \-R N, \-\-rename N
start N workers that each create a file and then repeatedly rename it.
.TP
.B \-\-rename\-ops N
stop rename stress workers after N bogo rename operations.
.TP
.B \-\-resched N
start N workers that exercise process rescheduling. Each stressor spawns
a child process for each of the positive nice levels and iterates over the
nice levels from 0 to the lowest priority level (highest nice value). For
each of the nice levels 1024 iterations over 3 non-real time scheduling
polices SCHED_OTHER, SCHED_BATCH and SCHED_IDLE are set and a sched_yield
occurs to force heavy rescheduling activity.  When the -v verbose option
is used the distribution of the number of yields across the nice levels is
printed for the first stressor out of the N stressors.
.TP
.B \-\-resched\-ops N
stop after N rescheduling sched_yield calls.
.TP
.B \-\-resources N
start N workers that consume various system resources. Each worker will spawn
1024 child processes that iterate 1024 times consuming shared memory, heap,
stack, temporary files and various file descriptors (eventfds, memoryfds,
userfaultfds, pipes and sockets).
.TP
.B \-\-resources\-ops N
stop after N resource child forks.
.TP
.B \-\-revio N
start N workers continually writing in reverse position order to temporary
files. The default mode is to stress test reverse position ordered writes
with randomly sized sparse holes between each write.  With
the \-\-aggressive option enabled without any \-\-revio\-opts options the
revio stressor will work through all the \-\-revio\-opt options one by one to
cover a range of I/O options.
.TP
.B \-\-revio\-bytes N
write N bytes for each revio process, the default is 1 GB. One can specify the
size as % of free space on the file system or in units of Bytes, KBytes, MBytes
and GBytes using the suffix b, k, m or g.
.TP
.B \-\-revio\-opts list
specify various stress test options as a comma separated list. Options are the
same as \-\-hdd\-opts but without the iovec option.
.TP
.B \-\-revio\-ops N
stop revio stress workers after N bogo operations.
.TP
.B \-\-revio\-write\-size N
specify size of each write in bytes. Size can be from 1 byte to 4MB.
.TP
.B \-\-rlimit N
start N workers that exceed CPU and file size resource imits, generating
SIGXCPU and SIGXFSZ signals.
.TP
.B \-\-rlimit\-ops N
stop after N bogo resource limited SIGXCPU and SIGXFSZ signals have been caught.
.TP
.B \-\-rmap N
start N workers that exercise the VM reverse-mapping. This creates 16 processes
per worker that write/read multiple file-backed memory mappings. There are 64
lots of 4 page mappings made onto the file, with each mapping overlapping the
previous by 3 pages and at least 1 page of non-mapped memory between each
of the mappings. Data is synchronously msync'd to the file 1 in every
256 iterations in a random manner.
.TP
.B \-\-rmap\-ops N
stop after N bogo rmap memory writes/reads.
.TP
.B \-\-rseq N
start N workers that exercise restartable sequences via the rseq(2) system
call.  This loops over a long duration critical section that is likely to
be interrupted.  A rseq abort handler keeps count of the number of
interruptions and a SIGSEV handler also tracks any failed rseq aborts that
can occur if there is a mistmatch in a rseq check signature. Linux only.
.TP
.B \-\-rseq\-ops N
stop after N bogo rseq operations. Each bogo rseq operation is equivalent
to 10000 iterations over a long duration rseq handled critical section.
.TP
.B \-\-rtc N
start N workers that exercise the real time clock (RTC) interfaces via /dev/rtc
and /sys/class/rtc/rtc0. No destructive writes (modifications) are performed on
the RTC. This is a Linux only stressor.
.TP
.B \-\-rtc\-ops N
stop after N bogo RTC interface accesses.
.TP
.B \-\-schedpolicy N
start N workers that work set the worker to various available scheduling
policies out of SCHED_OTHER, SCHED_BATCH, SCHED_IDLE, SCHED_FIFO,
SCHED_RR and SCHED_DEADLINE.  For the real time scheduling policies a
random sched priority is selected between the minimum and maximum
scheduling priority settings.
.TP
.B \-\-schedpolicy\-ops N
stop after N bogo scheduling policy changes.
.TP
.B \-\-sctp N
start N workers that perform network sctp stress activity using the Stream
Control Transmission Protocol (SCTP).  This involves client/server processes
performing rapid connect, send/receives and disconnects on the local host.
.TP
.B \-\-sctp\-domain D
specify the domain to use, the default is ipv4. Currently ipv4 and ipv6
are supported.
.TP
.B \-\-sctp\-ops N
stop sctp workers after N bogo operations.
.TP
.B \-\-sctp\-port P
start at sctp port P. For N sctp worker processes, ports P to (P * 4) - 1
are used for ipv4, ipv6 domains and ports P to P - 1 are used for the unix
domain.
.TP
.B \-\-seal N
start N workers that exercise the fcntl(2) SEAL commands on a small anonymous
file created using memfd_create(2).  After each SEAL command is issued the
stressor also sanity checks if the seal operation has sealed the file correctly.
(Linux only).
.TP
.B \-\-seal\-ops N
stop after N bogo seal operations.
.TP
.B \-\-seccomp N
start N workers that exercise Secure Computing system call filtering. Each
worker creates child processes that write a short message to /dev/null and then
exits. 2% of the child processes have a seccomp filter that disallows
the write system call and hence it is killed by seccomp with a SIGSYS.  Note
that this stressor can generate many audit log messages each time the child is
killed.  Requires CAP_SYS_ADMIN to run.
.TP
.B \-\-seccomp-ops N
stop seccomp stress workers after N seccomp filter tests.
.TP
.B \-\-secretmem N
start N workers that mmap pages using file mapping off a memfd_secret file
descriptor. Each stress loop iteration will expand the mappable region by 3
pages using ftruncate and mmap and touches the pages. The pages are then
fragmented by unmapping the middle page and then umapping the first and
last pages. This tries to force page fragmentation and also trigger out of
memory (OOM) kills of the stressor when the secret memory is exhausted.
Note this is a Linux 5.11+ only stressor and the kernel needs to be booted
with "secretmem=" option to allocate a secret memory reservation.
.TP
.B \-\-secretmem-ops N
stop secretmem stress workers after N stress loop iterations.
.TP
.B \-\-seek N
start N workers that randomly seeks and performs 512 byte read/write I/O
operations on a file. The default file size is 16 GB.
.TP
.B \-\-seek\-ops N
stop seek stress workers after N bogo seek operations.
.TP
.B \-\-seek\-punch
punch randomly located 8K holes into the file to cause more extents to force
a more demanding seek stressor, (Linux only).
.TP
.B \-\-seek\-size N
specify the size of the file in bytes. Small file sizes allow the I/O to occur
in the cache, causing greater CPU load. Large file sizes force more I/O
operations to drive causing more wait time and more I/O on the drive. One can
specify the size in units of Bytes, KBytes, MBytes and GBytes using the suffix
b, k, m or g.
.TP
.B \-\-sem N
start N workers that perform POSIX semaphore wait and post operations. By
default, a parent and 4 children are started per worker to provide some
contention on the semaphore. This stresses fast semaphore operations and
produces rapid context switching.
.TP
.B \-\-sem\-ops N
stop semaphore stress workers after N bogo semaphore operations.
.TP
.B \-\-sem\-procs N
start N child workers per worker to provide contention on the semaphore, the
default is 4 and a maximum of 64 are allowed.
.TP
.B \-\-sem\-sysv N
start N workers that perform System V semaphore wait and post operations. By
default, a parent and 4 children are started per worker to provide some
contention on the semaphore. This stresses fast semaphore operations and
produces rapid context switching.
.TP
.B \-\-sem\-sysv\-ops N
stop semaphore stress workers after N bogo System V semaphore operations.
.TP
.B \-\-sem\-sysv\-procs N
start N child processes per worker to provide contention on the System V
semaphore, the default is 4 and a maximum of 64 are allowed.
.TP
.B \-\-sendfile N
start N workers that send an empty file to /dev/null. This operation spends
nearly all the time in the kernel.  The default sendfile size is 4MB.  The
sendfile options are for Linux only.
.TP
.B \-\-sendfile\-ops N
stop sendfile workers after N sendfile bogo operations.
.TP
.B \-\-sendfile\-size S
specify the size to be copied with each sendfile call. The default size is
4MB. One can specify the size in units of Bytes, KBytes, MBytes and GBytes
using the suffix b, k, m or g.
.TP
.B \-\-session N
start N workers that create child and grandchild processes that set and
get their session ids. 25% of the grandchild processes are not waited for
by the child to create orphaned sessions that need to be reaped by init.
.TP
.B \-\-session\-ops N
stop session workers after N child processes are spawned and reaped.
.TP
.B \-\-set N
start N workers that call system calls that try to set data in the kernel,
currently these are: setgid, sethostname, setpgid, setpgrp, setuid,
setgroups, setreuid, setregid, setresuid, setresgid and setrlimit.
Some of these system calls are OS specific.
.TP
.B \-\-set\-ops N
stop set workers after N bogo set operations.
.TP
.B \-\-shellsort N
start N workers that sort 32 bit integers using shellsort.
.TP
.B \-\-shellsort\-ops N
stop shellsort stress workers after N bogo shellsorts.
.TP
.B \-\-shellsort\-size N
specify number of 32 bit integers to sort, default is 262144 (256 \(mu 1024).
.TP
.B \-\-shm N
start N workers that open and allocate shared memory objects using the POSIX
shared memory interfaces.  By default, the test will repeatedly create and
destroy 32 shared memory objects, each of which is 8MB in size.
.TP
.B \-\-shm\-ops N
stop after N POSIX shared memory create and destroy bogo operations are
complete.
.TP
.B \-\-shm\-bytes N
specify the size of the POSIX shared memory objects to be created. One can
specify the size as % of total available memory or in units of Bytes, KBytes,
MBytes and GBytes using the suffix b, k, m or g.
.TP
.B \-\-shm\-objs N
specify the number of shared memory objects to be created.
.TP
.B \-\-shm\-sysv N
start N workers that allocate shared memory using the System V shared memory
interface.  By default, the test will repeatedly create and destroy 8 shared
memory segments, each of which is 8MB in size.
.TP
.B \-\-shm\-sysv\-ops N
stop after N shared memory create and destroy bogo operations are complete.
.TP
.B \-\-shm\-sysv\-bytes N
specify the size of the shared memory segment to be created. One can specify
the size as % of total available memory or in units of Bytes, KBytes, MBytes
and GBytes using the suffix b, k, m or g.
.TP
.B \-\-shm\-sysv\-segs N
specify the number of shared memory segments to be created. The default is
8 segments.
.TP
.B \-\-sigabrt N
start N workers that create children that are killed by SIGABRT signals or
by calling abort(3).
.TP
.B \-\-sigabrt\-ops N
stop the sigabrt workers after N SIGABRT signals are successfully handled.
.TP
.B \-\-sigchld N
start N workers that create children to generate SIGCHLD signals. This exercises
children that exit (CLD_EXITED), get killed (CLD_KILLED), get stopped
(CLD_STOPPED) or continued (CLD_CONTINUED).
.TP
.B \-\-sigchld\-ops N
stop the sigchld workers after N SIGCHLD signals are successfully handled.
.TP
.B \-\-sigfd N
start N workers that generate SIGRT signals and are handled by reads by a child
process using a file descriptor set up using signalfd(2).  (Linux only). This
will generate a heavy context switch load when all CPUs are fully loaded.
.TP
.B \-\-sigfd\-ops
stop sigfd workers after N bogo SIGUSR1 signals are sent.
.TP
.B \-\-sigfpe N
start N workers that rapidly cause division by zero SIGFPE faults.
.TP
.B \-\-sigfpe\-ops N
stop sigfpe stress workers after N bogo SIGFPE faults.
.TP
.B \-\-sigio N
start N workers that read data from a child process via a pipe and generate
SIGIO signals. This exercises asynchronous I/O via SIGIO.
.TP
.B \-\-sigio\-ops N
stop sigio stress workers after handling N SIGIO signals.
.TP
.B \-\-signal N
start N workers that exercise the signal system call three different signal
handlers, SIG_IGN (ignore), a SIGCHLD handler and SIG_DFL (default action).
For the SIGCHLD handler, the stressor sends itself a SIGCHLD signal and checks
if it has been handled. For other handlers, the stressor checks that the
SIGCHLD handler has not been called.  This stress test calls the signal system
call directly when possible and will try to avoid the C library attempt to
replace signal with the more modern sigaction system call.
.TP
.B \-\-signal\-ops N
stop signal stress workers after N rounds of signal handler setting.
.TP
.B \-\-signest N
start N workers that exercise nested signal handling. A signal is raised and
inside the signal handler a different signal is raised, working through a
list of signals to exercise. An alternative signal stack is used that is
large enough to handle all the nested signal calls.  The \-v option will
log the approximate size of the stack required and the average stack size
per nested call.
.TP
.B \-\-signest\-ops N
stop after handling N nested signals.
.TP
.B \-\-sigpending N
start N workers that check if SIGUSR1 signals are pending. This stressor masks
SIGUSR1, generates a SIGUSR1 signal and uses sigpending(2) to see if the signal
is pending. Then it unmasks the signal and checks if the signal is no longer
pending.
.TP
.B \-\-sigpending-ops N
stop sigpending stress workers after N bogo sigpending pending/unpending checks.
.TP
.B \-\-sigpipe N
start N workers that repeatedly spawn off child process that exits before a
parent can complete a pipe write, causing a SIGPIPE signal.  The child
process is either spawned using clone(2) if it is available or use the slower
fork(2) instead.
.TP
.B \-\-sigpipe\-ops N
stop N workers after N SIGPIPE signals have been caught and handled.
.TP
.B \-\-sigq N
start N workers that rapidly send SIGUSR1 signals using sigqueue(3) to child
processes that wait for the signal via sigwaitinfo(2).
.TP
.B \-\-sigq\-ops N
stop sigq stress workers after N bogo signal send operations.
.TP
.B \-\-sigrt N
start N workers that each create child processes to handle SIGRTMIN to
SIGRMAX real time signals. The parent sends each child process a RT signal
via siqueue(2) and the child process waits for this via sigwaitinfo(2).
When the child receives the signal it then sends a RT signal to one of the
other child processes also via sigqueue(2).
.TP
.B \-\-sigrt\-ops N
stop sigrt stress workers after N bogo sigqueue signal send operations.
.TP
.B \-\-sigsegv N
start N workers that rapidly create and catch segmentation faults.
.TP
.B \-\-sigsegv\-ops N
stop sigsegv stress workers after N bogo segmentation faults.
.TP
.B \-\-sigsuspend N
start N workers that each spawn off 4 child processes that wait for a SIGUSR1
signal from the parent using sigsuspend(2). The parent sends SIGUSR1 signals
to each child in rapid succession.  Each sigsuspend wakeup is counted as one
bogo operation.
.TP
.B \-\-sigsuspend-ops N
stop sigsuspend stress workers after N bogo sigsuspend wakeups.
.TP
.B \-\-sigtrap N
start N workers that exercise the SIGTRAP signal. For systems that support
SIGTRAP, the signal is generated using raise(SIGTRAP). Only x86 Linux systems
the SIGTRAP is also generated by an int 3 instruction.
.TP
.B \-\-sigtrap-ops N
stop sigtrap stress workers after N SIGTRAPs have been handled.
.TP
.B \-\-skiplist N
start N workers that store and then search for integers using a skiplist.
By default, 65536 integers are added and searched.  This is a useful method
to exercise random access of memory and processor cache.
.TP
.B \-\-skiplist\-ops N
stop the skiplist worker after N skiplist store and search cycles are completed.
.TP
.B \-\-skiplist\-size N
specify the size (number of integers) to store and search in the skiplist. Size can
be from 1K to 4M.
.TP
.B \-\-sleep N
start N workers that spawn off multiple threads that each perform multiple
sleeps of ranges 1us to 0.1s.  This creates multiple context switches and
timer interrupts.
.TP
.B \-\-sleep\-ops N
stop after N sleep bogo operations.
.TP
.B \-\-sleep\-max P
start P threads per worker. The default is 1024, the maximum allowed is
30000.
.TP
.B \-\-smi N
start N workers that attempt to generate system management interrupts (SMIs)
into the x86 ring -2 system management mode (SMM) by exercising the advanced
power management (APM) port 0xb2. This requires the --pathological option and
root privilege and is only implemented on x86 Linux platforms. This probably
does not work in a virtualized environment.  The stressor will attempt to
determine the time stolen by SMIs with some na\[:i]ve benchmarking.
.TP
.B \-\-smi\-ops N
stop after N attempts to trigger the SMI.
.TP
.B \-S N, \-\-sock N
start N workers that perform various socket stress activity. This involves a
pair of client/server processes performing rapid connect, send and receives
and disconnects on the local host.
.TP
.B \-\-sock\-domain D
specify the domain to use, the default is ipv4. Currently ipv4, ipv6 and unix
are supported.
.TP
.B \-\-sock\-nodelay
This disables the TCP Nagle algorithm, so data segments are always sent
as soon as possible.  This stops data from being buffered before being
transmitted, hence resulting in poorer network utilisation and more context
switches between the sender and receiver.
.TP
.B \-\-sock\-port P
start at socket port P. For N socket worker processes, ports P to P - 1 are
used.
.TP
.B \-\-sock\-protocol P
Use the specified protocol P, default is tcp. Options are tcp and mptcp (if
supported by the operating system).
.TP
.B \-\-sock\-ops N
stop socket stress workers after N bogo operations.
.TP
.B \-\-sock\-opts [ random | send | sendmsg | sendmmsg ]
by default, messages are sent using send(2). This option allows one to specify
the sending method using send(2), sendmsg(2), sendmmsg(2) or a random selection
of one of thse 3 on each iteration.  Note that sendmmsg is only available for
Linux systems that support this system call.
.TP
.B \-\-sock\-type [ stream | seqpacket ]
specify the socket type to use. The default type is stream. seqpacket currently
only works for the unix socket domain.
.TP
.B \-\-sock\-zerocopy
enable zerocopy for send and recv calls if the MSG_ZEROCOPY is supported.
.TP
.B \-\-sockabuse N
start N workers that abuse a socket file descriptor with various file based
system that don't normally act on sockets. The kernel should handle these
illegal and unexpected calls gracefully.
.TP
.B \-\-sockabuse\-ops N
stop after N iterations of the socket abusing stressor loop.
.TP
.B \-\-sockdiag N
start N workers that exercise the Linux sock_diag netlink socket diagnostics
(Linux only).  This currently requests diagnostics using UDIAG_SHOW_NAME,
UDIAG_SHOW_VFS, UDIAG_SHOW_PEER, UDIAG_SHOW_ICONS, UDIAG_SHOW_RQLEN and
UDIAG_SHOW_MEMINFO for the AF_UNIX family of socket connections.
.TP
.B \-\-sockdiag\-ops N
stop after receiving N sock_diag diagnostic messages.
.TP
.B \-\-sockfd N
start N workers that pass file descriptors over a UNIX domain socket using the
CMSG(3) ancillary data mechanism. For each worker, pair of client/server
processes are created, the server opens as many file descriptors on /dev/null
as possible and passing these over the socket to a client that reads these from
the CMSG data and immediately closes the files.
.TP
.B \-\-sockfd\-ops N
stop sockfd stress workers after N bogo operations.
.TP
.B \-\-sockfd\-port P
start at socket port P. For N socket worker processes, ports P to P - 1 are
used.
.TP
.B \-\-sockmany N
start N workers that use a client process to attempt to open as many as 100000
TCP/IP socket connections to a server on port 10000.
.TP
.B \-\-sockmany\-ops N
stop after N connections.
.TP
.B \-\-sockpair N
start N workers that perform socket pair I/O read/writes. This involves a pair
of client/server processes performing randomly sized socket I/O operations.
.TP
.B \-\-sockpair\-ops N
stop socket pair stress workers after N bogo operations.
.TP
.B \-\-softlockup N
start N workers that flip between with the "real-time" SCHED_FIO and SCHED_RR
scheduling policies at the highest priority to force softlockups. This can
only be run with CAP_SYS_NICE capability and for best results the number of
stressors should be at least the number of online CPUs. Once running, this is
practically impossible to stop and it will force softlockup issues and may
trigger watchdog timeout reboots.
.TP
.B \-\-softlockup\-ops N
stop softlockup stress workers after N bogo scheduler policy changes.
.TP
.B \-\-sparsematrix N
start N workers that exercise 3 different sparse matrix implementations
based on hashing, Judy array (for 64 bit systems), 2-d circular linked-lists,
memory mapped 2-d matrix (non-sparse), quick hashing (on preallocated nodes)
and red-black tree.
The sparse matrix is populated with values, random values potentially
non-existing values are read, known existing values are read and known
existing values are marked as zero. This default 500 x 500 sparse matrix
is used and 5000 items are put into the sparse matrix making it 2% utilized.
.TP
.B \-\-sparsematrix\-ops N
stop after N sparsematrix test iterations.
.TP
.B \-\-sparsematrix\-items N
populate the sparse matrix with N items. If N is greater than the number
of elements in the sparse matrix than N will be capped to create at 100%
full sparse matrix.
.TP
.B \-\-sparsematrix\-size N
use a N \(mu N sized sparse matrix
.TP
.B \-\-sparsematrix\-method [ all | hash | judy | list | mmap | qhash | rb ]
specify the type of sparse matrix implementation to use. The 'all' method
uses all the methods and is the default.
.TS
expand;
lB2 lB lB
l l s.
Method	Description
all	T{
exercise with all the sparsematrix stressor methods (see below):
T}
hash	T{
use a hash table and allocate nodes on the heap for each unique value at a (x, y)
matrix position.
T}
judy	T{
use a Judy array with a unique 1-to-1 mapping of (x, y) matrix position into
the array.
T}
list	T{
use a circular linked-list for sparse y positions each with circular linked-lists for
sparse x positions for the (x, y) matrix coordinates.
T}
mmap	T{
use a non-sparse mmap the entire 2-d matrix space. Only (x, y) matrix positions that
are referenced will get physically mapped. Note that large sparse matrices cannot be mmap'd
due to lack of virtual address limitations, and too many referenced pages can trigger
the out of memory killer on Linux.
T}
qhash	T{
use a hash table with pre-allocated nodes for each unique value. This is a quick hash
table implementation, nodes are not allocated each time with calloc and are allocated
from a pre-allocated pool leading to quicker hash table performance than the hash method.
T}
.TE
.TP
.B \-\-spawn N
start N workers continually spawn children using posix_spawn(3) that exec
stress-ng and then exit almost immediately. Currently Linux only.
.TP
.B \-\-spawn\-ops N
stop spawn stress workers after N bogo spawns.
.TP
.B \-\-splice N
move data from /dev/zero to /dev/null through a pipe without any copying
between kernel address space and user address space using splice(2). This is
only available for Linux.
.TP
.B \-\-splice-ops N
stop after N bogo splice operations.
.TP
.B \-\-splice-bytes N
transfer N bytes per splice call, the default is 64K. One can specify the size
as % of total available memory or in units of Bytes, KBytes, MBytes and GBytes
using the suffix b, k, m or g.
.TP
.B \-\-stack N
start N workers that rapidly cause and catch stack overflows by use of
large recursive stack allocations.  Much like the brk stressor, this can eat
up pages rapidly and may trigger the kernel OOM killer on the process,
however, the killed stressor is respawned again by a monitoring parent
process.
.TP
.B \-\-stack\-fill
the default action is to touch the lowest page on each stack allocation. This
option touches all the pages by filling the new stack allocation with zeros
which forces physical pages to be allocated and hence is more aggressive.
.TP
.B \-\-stack\-mlock
attempt to mlock stack pages into memory prohibiting them from being
paged out.  This is a no-op if mlock(2) is not available.
.TP
.B \-\-stack\-ops N
stop stack stress workers after N bogo stack overflows.
.TP
.B \-\-stackmmap N
start N workers that use a 2MB stack that is memory mapped onto a temporary
file. A recursive function works down the stack and flushes dirty stack pages
back to the memory mapped file using msync(2) until the end of the stack is
reached (stack overflow). This exercises dirty page and stack exception handling.
.TP
.B \-\-stackmmap\-ops N
stop workers after N stack overflows have occurred.
.TP
.B \-\-str N
start N workers that exercise various libc string functions on random strings.
.TP
.B \-\-str-method strfunc
select a specific libc string function to stress. Available string functions to
stress are: all, index, rindex, strcasecmp, strcat, strchr, strcoll, strcmp,
strcpy, strlen, strncasecmp, strncat, strncmp, strrchr and strxfrm.  See
string(3) for more information on these string functions.  The 'all' method is
the default and will exercise all the string methods.
.TP
.B \-\-str-ops N
stop after N bogo string operations.
.TP
.B \-\-stream N
start N workers exercising a memory bandwidth stressor loosely based on the
STREAM "Sustainable Memory Bandwidth in High Performance Computers" benchmarking
tool by John D. McCalpin, Ph.D.  This stressor allocates buffers that are at
least 4 times the size of the CPU L2 cache and continually performs rounds of
following computations on large arrays of double precision floating point numbers:
.TS
expand;
lB2 lB lB
l l s.
Operation	Description
copy	T{
c[i] = a[i]
T}
scale	T{
b[i] = scalar * c[i]
T}
add	T{
c[i] = a[i] + b[i]
T}
triad	T{
a[i] = b[i] + (c[i] * scalar)
T}
.TE
.RS
.PP
Since this is loosely based on a variant of the STREAM benchmark code,
DO NOT submit results based on this as it is intended to in stress-ng just
to stress memory and compute and NOT intended for STREAM accurate
tuned or non-tuned benchmarking whatsoever.  Use the official STREAM
benchmarking tool if you desire accurate and standardised STREAM benchmarks.
.RE
.TP
.B \-\-stream\-ops N
stop after N stream bogo operations, where a bogo operation is one round
of copy, scale, add and triad operations.
.TP
.B \-\-stream\-index N
specify number of stream indices used to index into the data arrays a, b and
c.  This adds indirection into the data lookup by using randomly shuffled
indexing into the three data arrays. Level 0 (no indexing) is the default,
and 3 is where all 3 arrays are indexed via 3 different randomly shuffled
indexes. The higher the index setting the more impact this has on L1, L2
and L3 caching and hence forces higher memory read/write latencies.
.TP
.B \-\-stream\-l3\-size N
Specify the CPU Level 3 cache size in bytes.  One can specify the size in
units of Bytes, KBytes, MBytes and GBytes using the suffix b, k, m or g.
If the L3 cache size is not provided, then stress-ng will attempt to
determine the cache size, and failing this, will default the size to 4MB.
.TP
.B \-\-stream\-madvise [ hugepage | nohugepage | normal ]
Specify the madvise options used on the memory mapped buffer used in the
stream stressor. Non-linux systems will only have the 'normal' madvise
advice. The default is 'normal'.
.TP
.B \-\-swap N
start N workers that add and remove small randomly sizes swap partitions
(Linux only).  Note that if too many swap partitions are added then the
stressors may exit with exit code 3 (not enough resources).  Requires
CAP_SYS_ADMIN to run.
.TP
.B \-\-swap\-ops N
stop the swap workers after N swapon/swapoff iterations.
.TP
.B \-s N, \-\-switch N
start N workers that force context switching between two mutually
blocking/unblocking tied processes. By default message passing over
a pipe is used, but different methods are available.
.TP
.B \-\-switch\-ops N
stop context switching workers after N bogo operations.
.TP
.B \-\-switch\-freq F
run the context switching at the frequency of F context switches per
second. Note that the specified switch rate may not be achieved
because of CPU speed and memory bandwidth limitations.
.TP
.B \-\-switch\-method [ mq | pipe | sem-sysv ]
select the preferred context switch block/run synchronization method, these
are as follows:
.TS
expand;
lB2 lB lB lB
l l s s.
Method	Description
mq	T{
use posix message queue with a 1 item size. Messages are passed between
a sender and receiver process.
T}
pipe	T{
single character messages are passed down a single character
sized pipe between a sender and receiver process.
T}
sem-sysv	T{
a SYSV semaphore is used to block/run two processes.
T}
.TE
.TP
.B \-\-symlink N
start N workers creating and removing symbolic links.
.TP
.B \-\-symlink\-ops N
stop symlink stress workers after N bogo operations.
.TP
.B \-\-sync\-file N
start N workers that perform a range of data syncs across a file using
sync_file_range(2).  Three mixes of syncs are performed, from start to the end
of the file,  from end of the file to the start, and a random mix. A random
selection of valid sync types are used, covering the SYNC_FILE_RANGE_WAIT_BEFORE,
SYNC_FILE_RANGE_WRITE and SYNC_FILE_RANGE_WAIT_AFTER flag bits.
.TP
.B \-\-sync\-file\-ops N
stop sync\-file workers after N bogo sync operations.
.TP
.B \-\-sync\-file\-bytes N
specify the size of the file to be sync'd. One can specify the size as % of free
space on the file system in units of Bytes, KBytes, MBytes and GBytes using the
suffix b, k, m or g.
.TP
.B \-\-syncload N
start N workers that produce sporadic short lived loads synchronized across N
stressor processes. By default repeated cycles of 125ms busy load followed by 62.5ms sleep
occur across all the workers in step to create bursts of load to exercise C state
transitions and CPU frequency scaling. The busy load and sleeps have +/-10% jitter
added to try exercising scheduling patterns.
.TP
.B \-\-syncload\-ops N
stop syncload workers after N load/sleep cycles.
.TP
.B \-\-syncload\-msbusy M
specify the busy load duration in milliseconds.
.TP
.B \-\-syncload\-mssleep M
specify the sleep duration in milliseconds.
.TP
.B \-\-sysbadaddr N
start N workers that pass bad addresses to system calls to exercise bad address
and fault handling. The addresses used are null pointers, read only pages,
write only pages, unmapped addresses, text only pages, unaligned addresses and top of
memory addresses.
.TP
.B \-\-sysbadaddr\-ops N
stop the sysbadaddr stressors after N bogo system calls.
.TP
.B \-\-sysinfo N
start N workers that continually read system and process specific information.
This reads the process user and system times using the times(2) system call.
For Linux systems, it also reads overall system statistics using the sysinfo(2)
system call and also the file system statistics for all mounted file systems
using statfs(2).
.TP
.B \-\-sysinfo\-ops N
stop the sysinfo workers after N bogo operations.
.TP
.B \-\-sysinval N
start N workers that exercise system calls in random order with permutations
of invalid arguments to force kernel error handling checks. The stress test
autodetects system calls that cause processes to crash or exit prematurely
and will blocklist these after several repeated breakages. System call
arguments that cause system calls to work successfully are also detected an
blocklisted too.  Linux only.
.TP
.B \-\-sysinval-ops N
stop sysinval workers after N system call attempts.
.TP
.B \-\-sysfs N
start N workers that recursively read files from /sys (Linux only).  This may
cause specific kernel drivers to emit messages into the kernel log.
.TP
.B \-\-sys\-ops N
stop sysfs reading after N bogo read operations. Note, since the number of
entries may vary between kernels, this bogo ops metric is probably very
misleading.
.TP
.B \-\-tee N
move data from a writer process to a reader process through pipes and to
/dev/null without any copying between kernel address space and user address
space using tee(2). This is only available for Linux.
.TP
.B \-\-tee-ops N
stop after N bogo tee operations.
.TP
.B \-T N, \-\-timer N
start N workers creating timer events at a default rate of 1 MHz (Linux only);
this can create a many thousands of timer clock interrupts. Each timer event
is caught by a signal handler and counted as a bogo timer op.
.TP
.B \-\-timer\-ops N
stop timer stress workers after N bogo timer events (Linux only).
.TP
.B \-\-timer\-freq F
run timers at F Hz; range from 1 to 1000000000 Hz (Linux only). By selecting
an appropriate frequency stress\-ng can generate hundreds of thousands of
interrupts per second.  Note: it is also worth using \-\-timer\-slack 0 for
high frequencies to stop the kernel from coalescing timer events.
.TP
.B \-\-timer\-rand
select a timer frequency based around the timer frequency +/- 12.5% random
jitter. This tries to force more variability in the timer interval to make the
scheduling less predictable.
.TP
.B \-\-timerfd N
start N workers creating timerfd events at a default rate of 1 MHz (Linux
only); this can create a many thousands of timer clock events. Timer events
are waited for on the timer file descriptor using select(2) and then read and
counted as a bogo timerfd op.
.TP
.B \-\-timerfd\-ops N
stop timerfd stress workers after N bogo timerfd events (Linux only).
.TP
.B \-\-timerfs\-fds N
try to use a maximum of N timerfd file descriptors per stressor.
.TP
.B \-\-timerfd\-freq F
run timers at F Hz; range from 1 to 1000000000 Hz (Linux only). By selecting
an appropriate frequency stress\-ng can generate hundreds of thousands of
interrupts per second.
.TP
.B \-\-timerfd\-rand
select a timerfd frequency based around the timer frequency +/- 12.5% random
jitter. This tries to force more variability in the timer interval to make the
scheduling less predictable.
.TP
.B \-\-tlb\-shootdown N
start N workers that force Translation Lookaside Buffer (TLB) shootdowns.
This is achieved by creating up to 16 child processes that all share a
region of memory and these processes are shared amongst the available
CPUs.  The processes adjust the page mapping settings causing TLBs to
be force flushed on the other processors, causing the TLB shootdowns.
.TP
.B \-\-tlb\-shootdown\-ops N
stop after N bogo TLB shootdown operations are completed.
.TP
.B \-\-tmpfs N
start N workers that create a temporary file on an available tmpfs
file system and perform various file based mmap operations upon it.
.TP
.B \-\-tmpfs\-ops N
stop tmpfs stressors after N bogo mmap operations.
.TP
.B \-\-tmpfs\-mmap\-async
enable file based memory mapping and use asynchronous msync'ing on each page,
see \-\-tmpfs\-mmap\-file.
.TP
.B \-\-tmpfs\-mmap\-file
enable tmpfs file based memory mapping and by default use synchronous
msync'ing on each page.
.TP
.B \-\-tree N
start N workers that exercise tree data structures. The default is
to add, find and remove 250,000 64 bit integers into AVL (avl),
Red-Black (rb), Splay (splay), btree and binary trees.  The intention of
this stressor is to exercise memory and cache with the various tree
operations.
.TP
.B \-\-tree\-ops N
stop tree stressors after N bogo ops. A bogo op covers the addition,
finding and removing all the items into the tree(s).
.TP
.B \-\-tree\-size N
specify the size of the tree, where N is the number of 64 bit integers
to be added into the tree.
.TP
.B \-\-tree\-method [ all | avl | binary | btree | rb | splay ]
specify the tree to be used. By default, all the trees are
used (the 'all' option).
.TP
.B \-\-tsc N
start N workers that read the Time Stamp Counter (TSC) 256 times per loop
iteration (bogo operation).  This exercises the tsc instruction for x86,
the mftb instruction for ppc64 and the rdcycle instruction for RISC-V.
.TP
.B \-\-tsc\-ops N
stop the tsc workers after N bogo operations are completed.
.TP
.B \-\-tsearch N
start N workers that insert, search and delete 32 bit integers on a binary
tree using tsearch(3), tfind(3) and tdelete(3). By default, there are 65536
randomized integers used in the tree.  This is a useful method to exercise
random access of memory and processor cache.
.TP
.B \-\-tsearch\-ops N
stop the tsearch workers after N bogo tree operations are completed.
.TP
.B \-\-tsearch\-size N
specify the size (number of 32 bit integers) in the array to tsearch. Size
can be from 1K to 4M.
.TP
.B \-\-tun N
start N workers that create a network tunnel device and sends and receives
packets over the tunnel using UDP and then destroys it. A new random
192.168.*.* IPv4 address is used each time a tunnel is created.
.TP
.B \-\-tun\-ops N
stop after N iterations of creating/sending/receiving/destroying a tunnel.
.TP
.B \-\-tun\-tap
use network tap device using level 2 frames (bridging) rather than a tun device
for level 3 raw packets (tunnelling).
.TP
.B \-\-udp N
start N workers that transmit data using UDP. This involves a pair of
client/server processes performing rapid connect, send and receives and
disconnects on the local host.
.TP
.B \-\-udp\-domain D
specify the domain to use, the default is ipv4. Currently ipv4, ipv6 and unix
are supported.
.TP
.B \-\-udp\-gro
enable UDP-GRO (Generic Receive Offload) if supported.
.TP
.B \-\-udp\-lite
use the UDP-Lite (RFC 3828) protocol (only for ipv4 and ipv6 domains).
.TP
.B \-\-udp\-ops N
stop udp stress workers after N bogo operations.
.TP
.B \-\-udp\-port P
start at port P. For N udp worker processes, ports P to P - 1 are used. By
default, ports 7000 upwards are used.
.TP
.B \-\-udp\-flood N
start N workers that attempt to flood the host with UDP packets to random
ports. The IP address of the packets are currently not spoofed. This is only
available on systems that support AF_PACKET.
.TP
.B \-\-udp\-flood\-domain D
specify the domain to use, the default is ipv4. Currently ipv4 and ipv6 are
supported.
.TP
.B \-\-udp\-flood\-ops N
stop udp-flood stress workers after N bogo operations.
.TP
.B \-\-unshare N
start N workers that each fork off 32 child processes, each of which exercises
the unshare(2) system call by disassociating parts of the process execution
context. (Linux only).
.TP
.B \-\-unshare\-ops N
stop after N bogo unshare operations.
.TP
.B \-\-uprobe N
start N workers that trace the entry to libc function getpid() using the
Linux uprobe kernel tracing mechanism. This requires CAP_SYS_ADMIN
capabilities and a modern Linux uprobe capable kernel.
.TP
.B \-\-uprobe\-ops N
stop uprobe tracing after N trace events of the function that is being traced.
.TP
.B \-u N, \-\-urandom N
start N workers reading /dev/urandom (Linux only). This will load the kernel
random number source.
.TP
.B \-\-urandom\-ops N
stop urandom stress workers after N urandom bogo read operations (Linux only).
.TP
.B \-\-userfaultfd N
start N workers that generate write page faults on a small anonymously mapped
memory region and handle these faults using the user space fault handling via
the userfaultfd mechanism.  This will generate a large quantity of major page
faults and also context switches during the handling of the page faults.
(Linux only).
.TP
.B \-\-userfaultfd-ops N
stop userfaultfd stress workers after N page faults.
.TP
.B \-\-userfaultfd-bytes N
mmap N bytes per userfaultfd worker to page fault on, the default is 16MB.
One can specify the size as % of total available memory or in units of Bytes,
KBytes, MBytes and GBytes using the suffix b, k, m or g.
.TP
.B \-\-usersyscall N
start N workers that exercise the Linux prctl userspace system call
mechanism. A userspace system call is handled by a SIGSYS signal handler
and exercised with the system call disabled (ENOSYS) and enabled
(via SIGSYS) using prctl PR_SET_SYSCALL_USER_DISPATCH.
.TP
.B \-\-usersyscall\-ops N
stop after N successful userspace syscalls via a SIGSYS signal handler.
.TP
.B \-\-utime N
start N workers updating file timestamps. This is mainly CPU bound when the
default is used as the system flushes metadata changes only periodically.
.TP
.B \-\-utime\-ops N
stop utime stress workers after N utime bogo operations.
.TP
.B \-\-utime\-fsync
force metadata changes on each file timestamp update to be flushed to disk.
This forces the test to become I/O bound and will result in many dirty metadata
writes.
.TP
.B \-\-vdso N
start N workers that repeatedly call each of the system call functions in the
vDSO (virtual dynamic shared object).  The vDSO is a shared library that the
kernel maps into the address space of all user-space applications to allow
fast access to kernel data to some system calls without the need of
performing an expensive system call.
.TP
.B \-\-vdso\-ops N
stop after N vDSO functions calls.
.TP
.B \-\-vdso\-func F
Instead of calling all the vDSO functions, just call the vDSO function F. The
functions depend on the kernel being used, but are typically clock_gettime,
getcpu, gettimeofday and time.
.TP
.B \-\-vecmath N
start N workers that perform various unsigned integer math operations on
various 128 bit vectors. A mix of vector math operations are performed on the
following vectors: 16 \(mu 8 bits, 8 \(mu 16 bits, 4 \(mu 32 bits, 2 \(mu 64
bits. The metrics produced by this mix depend on the processor architecture
and the vector math optimisations produced by the compiler.
.TP
.B \-\-vecmath\-ops N
stop after N bogo vector integer math operations.
.TP
.B \-\-vecwide N
start N workers that perform various 8 bit math operations on vectors
of 4, 8, 16, 32, 64, 128, 256, 512, 1024 and 2048 bytes. With the -v option
the relative compute performance vs the expected compute performance based
on total run time is shown for the first vecwide worker. The vecwide stressor
exercises various processor vector instruction mixes and how well the
compiler can map the vector operations to the target instruction set.
.TP
.B \-\-vecwide\-ops N
stop after N bogo vector operations (2048 iterations of a mix of vector
instruction operations).
.TP
.B \-\-verity N
start N workers that exercise read-only file based authenticy protection
using the verity ioctls FS_IOC_ENABLE_VERITY and FS_IOC_MEASURE_VERITY.
This requires file systems with verity support (currently ext4 and f2fs
on Linux) with the verity feature enabled. The test attempts to creates
a small file with multiple small extents and enables verity on the file
and verifies it. It also checks to see if the file has verity enabled
with the FS_VERITY_FL bit set on the file flags.
.TP
.B \-\-verity\-ops N
stop the verity workers after N file create, enable verity, check verity
and unlink cycles.
.TP
.B \-\-vfork N
start N workers continually vforking children that immediately exit.
.TP
.B \-\-vfork\-ops N
stop vfork stress workers after N bogo operations.
.TP
.B \-\-vfork\-max P
create P processes and then wait for them to exit per iteration. The default
is just 1; higher values will create many temporary zombie processes that are
waiting to be reaped. One can potentially fill up the process table using
high values for \-\-vfork\-max and \-\-vfork.
.TP
.B \-\-vfork\-vm
enable detrimental performance virtual memory advice using madvise on
all pages of the vforked process. Where possible this will try to set
every page in the new process with using madvise MADV_MERGEABLE,
MADV_WILLNEED, MADV_HUGEPAGE and MADV_RANDOM flags. Linux only.
.TP
.B \-\-vforkmany N
start N workers that spawn off a chain of vfork children until the process
table fills up and/or vfork fails.  vfork can rapidly create child processes
and the parent process has to wait until the child dies, so this stressor
rapidly fills up the process table.
.TP
.B \-\-vforkmany\-ops N
stop vforkmany stressors after N vforks have been made.
.TP
.B \-\-vforkmany\-vm
enable detrimental performance virtual memory advice using madvise on
all pages of the vforked process. Where possible this will try to set
every page in the new process with using madvise MADV_MERGEABLE,
MADV_WILLNEED, MADV_HUGEPAGE and MADV_RANDOM flags. Linux only.
.TP
.B \-m N, \-\-vm N
start N workers continuously calling mmap(2)/munmap(2) and writing to the
allocated memory. Note that this can cause systems to trip the kernel OOM
killer on Linux systems if not enough physical memory and swap is not
available.
.TP
.B \-\-vm\-bytes N
mmap N bytes per vm worker, the default is 256MB. One can specify the size
as % of total available memory or in units of Bytes, KBytes, MBytes and GBytes
using the suffix b, k, m or g.
.TP
.B \-\-vm\-ops N
stop vm workers after N bogo operations.
.TP
.B \-\-vm\-hang N
sleep N seconds before unmapping memory, the default is zero seconds.
Specifying 0 will do an infinite wait.
.TP
.B \-\-vm\-keep
do not continually unmap and map memory, just keep on re-writing to it.
.TP
.B \-\-vm\-locked
Lock the pages of the mapped region into memory using mmap MAP_LOCKED (since
Linux 2.5.37).  This is similar to locking memory as described in mlock(2).
.TP
.B \-\-vm\-madvise advice
Specify the madvise 'advice' option used on the memory mapped regions used in
the vm stressor. Non-linux systems will only have the 'normal' madvise
advice, linux systems support 'dontneed', 'hugepage', 'mergeable'
, 'nohugepage', 'normal', 'random', 'sequential', 'unmergeable'
and 'willneed' advice. If this option is not used then the default is to pick
random madvise advice for each mmap call. See madvise(2) for more details.
.TP
.B \-\-vm\-method m
specify a vm stress method. By default, all the stress methods are exercised
sequentially, however one can specify just one method to be used if required.
Each of the vm workers have 3 phases:
.RS
.PP
1. Initialised. The anonymously memory mapped region is set to a known pattern.
.PP
2. Exercised. Memory is modified in a known predictable way. Some vm workers
alter memory sequentially, some use small or large strides to step along memory.
.PP
3. Checked. The modified memory is checked to see if it matches the expected
result.
.PP
The vm methods containing 'prime' in their name have a stride of the largest
prime less than 2^64, allowing to them to thoroughly step through memory and
touch all locations just once while also doing without touching memory cells
next to each other. This strategy exercises the cache and page non-locality.
.PP
Since the memory being exercised is virtually mapped then there is no
guarantee of touching page addresses in any particular physical order.  These
workers should not be used to test that all the system's memory is working
correctly either, use tools such as memtest86 instead.
.PP
The vm stress methods are intended to exercise memory in ways to possibly find
memory issues and to try to force thermal errors.
.PP
Available vm stress methods are described as follows:
.TS
expand;
lB2 lB lB lB
l l s s.
Method	Description
all	T{
iterate over all the vm stress methods as listed below.
T}
cache-lines	T{
work through memory in 64 byte cache sized steps writing a single byte
per cache line. Once the write is complete, the memory is read to verify
the values are written correctly.
T}
cache-stripe	T{
work through memory in 64 byte cache sized chunks, writing in ascending
address order on even offsets and descending address order on odd offsets.
T}
flip	T{
sequentially work through memory 8 times, each time just one bit in memory
flipped (inverted). This will effectively invert each byte in 8 passes.
T}
galpat-0	T{
galloping pattern zeros. This sets all bits to 0 and flips just 1 in 4096 bits
to 1. It then checks to see if the 1s are pulled down to 0 by their neighbours
or of the neighbours have been pulled up to 1.
T}
galpat-1	T{
galloping pattern ones. This sets all bits to 1 and flips just 1 in 4096 bits
to 0. It then checks to see if the 0s are pulled up to 1 by their neighbours
or of the neighbours have been pulled down to 0.
T}
gray	T{
fill the memory with sequential gray codes (these only change 1 bit at a time
between adjacent bytes) and then check if they are set correctly.
T}
grayflip	T{
fill memory with adjacent bytes of gray code and inverted gray code pairs
to change as many bits at a time between adjacent bytes and check if
these are set correctly.
T}
incdec	T{
work sequentially through memory twice, the first pass increments each byte by
a specific value and the second pass decrements each byte back to the original
start value. The increment/decrement value changes on each invocation of the
stressor.
T}
inc-nybble	T{
initialise memory to a set value (that changes on each invocation of the
stressor) and then sequentially work through each byte incrementing the bottom
4 bits by 1 and the top 4 bits by 15.
T}
rand-set	T{
sequentially work through memory in 64 bit chunks setting bytes in the chunk
to the same 8 bit random value.  The random value changes on each chunk.
Check that the values have not changed.
T}
rand-sum	T{
sequentially set all memory to random values and then summate the number of
bits that have changed from the original set values.
T}
read64	T{
sequentially read memory using 32 x 64 bit reads per bogo loop. Each loop
equates to one bogo operation.  This exercises raw memory reads.
T}
ror	T{
fill memory with a random pattern and then sequentially rotate 64 bits of
memory right by one bit, then check the final load/rotate/stored values.
T}
swap	T{
fill memory in 64 byte chunks with random patterns. Then swap each 64 chunk
with a randomly chosen chunk. Finally, reverse the swap to put the chunks back
to their original place and check if the data is correct. This exercises
adjacent and random memory load/stores.
T}
move-inv	T{
sequentially fill memory 64 bits of memory at a time with random values, and
then check if the memory is set correctly.  Next, sequentially invert each 64
bit pattern and again check if the memory is set as expected.
T}
modulo-x	T{
fill memory over 23 iterations. Each iteration starts one byte further along
from the start of the memory and steps along in 23 byte strides. In each
stride, the first byte is set to a random pattern and all other bytes are set
to the inverse.  Then it checks see if the first byte contains the expected
random pattern. This exercises cache store/reads as well as seeing if
neighbouring cells influence each other.
T}
mscan	T{
fill each bit in each byte with 1s then check these are set, fill each bit
in each byte with 0s and check these are clear.
T}
prime-0	T{
iterate 8 times by stepping through memory in very large prime strides clearing
just on bit at a time in every byte. Then check to see if all bits are set to
zero.
T}
prime-1	T{
iterate 8 times by stepping through memory in very large prime strides setting
just on bit at a time in every byte. Then check to see if all bits are set to
one.
T}
prime-gray-0	T{
first step through memory in very large prime strides clearing just on bit
(based on a gray code) in every byte. Next, repeat this but clear the other
7 bits. Then check to see if all bits are set to zero.
T}
prime-gray-1	T{
first step through memory in very large prime strides setting just on bit
(based on a gray code) in every byte. Next, repeat this but set the other 7
bits. Then check to see if all bits are set to one.
T}
rowhammer	T{
try to force memory corruption using the rowhammer memory stressor. This
fetches two 32 bit integers from memory and forces a cache flush on the two
addresses multiple times. This has been known to force bit flipping on some
hardware, especially with lower frequency memory refresh cycles.
T}
walk-0d	T{
for each byte in memory, walk through each data line setting them to low (and
the others are set high) and check that the written value is as expected. This
checks if any data lines are stuck.
T}
walk-1d	T{
for each byte in memory, walk through each data line setting them to high (and
the others are set low) and check that the written value is as expected. This
checks if any data lines are stuck.
T}
walk-0a	T{
in the given memory mapping, work through a range of specially chosen addresses
working through address lines to see if any address lines are stuck low. This
works best with physical memory addressing, however, exercising these virtual
addresses has some value too.
T}
walk-1a	T{
in the given memory mapping, work through a range of specially chosen addresses
working through address lines to see if any address lines are stuck high. This
works best with physical memory addressing, however, exercising these virtual
addresses has some value too.
T}
write64	T{
sequentially write to memory using 32 x 64 bit writes per bogo loop. Each loop
equates to one bogo operation.  This exercises raw memory writes.  Note that
memory writes are not checked at the end of each test iteration.
T}
write64nt	T{
sequentially write to memory using 32 x 64 bit non-temporal writes per bogo loop.
Each loop equates to one bogo operation.  This exercises cacheless raw memory writes
and is only available on x86 sse2 capable systems built with gcc and clang
compilers.  Note that memory writes are not checked at the end of each test iteration.
T}
write1024v	T{
sequentially write to memory using 1 x 1024 bit vector write per bogo loop
(only available if the compiler supports vector types).
Each loop equates to one bogo operation.  This exercises raw memory writes.
Note that memory writes are not checked at the end of each test iteration.
T}
zero-one	T{
set all memory bits to zero and then check if any bits are not zero. Next, set
all the memory bits to one and check if any bits are not one.
T}
.TE
.RE
.TP
.B \-\-vm\-populate
populate (prefault) page tables for the memory mappings; this can stress
swapping. Only available on systems that support MAP_POPULATE (since Linux
2.5.46).
.TP
.B \-\-vm\-addr N
start N workers that exercise virtual memory addressing using various
methods to walk through a memory mapped address range. This will exercise
mapped private addresses from 8MB to 64MB per worker and try to generate
cache and TLB inefficient addressing patterns. Each method will set the
memory to a random pattern in a write phase and then sanity check this
in a read phase.
.TP
.B \-\-vm\-addr\-ops N
stop N workers after N bogo addressing passes.
.TP
.B \-\-vm\-addr\-method M
specify a vm address stress method. By default, all the stress methods are exercised
sequentially, however one can specify just one method to be used if required.
.RS
.PP
Available vm address stress methods are described as follows:
.TS
expand;
lB2 lB lB lB
l l s s.
Method	Description
all	T{
iterate over all the vm stress methods as listed below.
T}
pwr2	T{
work through memory addresses in steps of powers of two.
T}
pwr2inv	T{
like pwr2, but with the all relevant address bits inverted.
T}
gray	T{
work through memory with gray coded addresses so that each
change of address just changes 1 bit compared to the previous
address.
T}
grayinv	T{
like gray, but with the all relevant address bits inverted,
hence all bits change apart from 1 in the address range.
T}
rev	T{
work through the address range with the bits in the address
range reversed.
T}
revinv	T{
like rev, but with all the relevant address bits inverted.
T}
inc	T{
work through the address range forwards sequentially, byte
by byte.
T}
incinv 	T{
like inc, but with all the relevant address bits inverted.
T}
dec	T{
work through the address range backwards sequentially, byte
by byte.
T}
decinv	T{
like dec, but with all the relevant address bits inverted.
T}
.TE
.RE
.TP
.B \-\-vm\-rw N
start N workers that transfer memory to/from a parent/child using
process_vm_writev(2) and process_vm_readv(2). This is feature is only
supported on Linux.  Memory transfers are only verified if the \-\-verify
option is enabled.
.TP
.B \-\-vm\-rw\-ops N
stop vm\-rw workers after N memory read/writes.
.TP
.B \-\-vm\-rw\-bytes N
mmap N bytes per vm\-rw worker, the default is 16MB. One can specify the size
as % of total available memory or in units of Bytes, KBytes, MBytes and GBytes
using the suffix b, k, m or g.
.TP
.B \-\-vm\-segv N
start N workers that create a child process that unmaps its address space
causing a SIGSEGV on return from the unmap.
.TP
.B \-\-vm\-segv\-ops N
stop after N bogo vm\-segv SIGSEGV faults.
.TP
.B \-\-vm\-splice N
move data from memory to /dev/null through a pipe without any copying between
kernel address space and user address space using vmsplice(2) and splice(2).
This is only available for Linux.
.TP
.B \-\-vm\-splice-ops N
stop after N bogo vm\-splice operations.
.TP
.B \-\-vm\-splice-bytes N
transfer N bytes per vmsplice call, the default is 64K. One can specify the
size as % of total available memory or in units of Bytes, KBytes, MBytes and
GBytes using the suffix b, k, m or g.
.TP
.B \-\-wait N
start N workers that spawn off two children; one spins in a pause(2) loop, the
other continually stops and continues the first. The controlling process waits
on the first child to be resumed by the delivery of SIGCONT using waitpid(2)
and waitid(2).
.TP
.B \-\-wait\-ops N
stop after N bogo wait operations.
.TP
.B \-\-watchdog N
start N workers that exercising the /dev/watchdog watchdog interface by
opening it, perform various watchdog specific ioctl(2) commands on the
device and close it.  Before closing the special watchdog magic close
message is written to the device to try and force it to never trip a
watchdog reboot after the stressor has been run.  Note that this stressor
needs to be run as root with the \-\-pathological option and is only
available on Linux.
.TP
.B \-\-watchdog\-ops N
stop after N bogo operations on the watchdog device.
.TP
.B \-\-wcs N
start N workers that exercise various libc wide character string functions on
random strings.
.TP
.B \-\-wcs-method wcsfunc
select a specific libc wide character string function to stress. Available
string functions to stress are: all, wcscasecmp, wcscat, wcschr, wcscoll,
wcscmp, wcscpy, wcslen, wcsncasecmp, wcsncat, wcsncmp, wcsrchr and wcsxfrm.
The 'all' method is the default and will exercise all the string methods.
.TP
.B \-\-wcs-ops N
stop after N bogo wide character string operations.
.TP
.B \-\-x86syscall N
start N workers that repeatedly exercise the x86-64 syscall instruction to
call the getcpu(2), gettimeofday(2) and time(2) system using the Linux
vsyscall handler. Only for Linux.
.TP
.B \-\-x86syscall\-ops N
stop after N x86syscall system calls.
.TP
.B \-\-x86syscall\-func F
Instead of exercising the 3 syscall system calls, just call the syscall
function F. The function F must be one of getcpu, gettimeofday and time.
.TP
.B \-\-xattr N
start N workers that create, update and delete batches of extended attributes
on a file.
.TP
.B \-\-xattr\-ops N
stop after N bogo extended attribute operations.
.TP
.B \-y N, \-\-yield N
start N workers that call sched_yield(2). This stressor ensures that at
least 2 child processes per CPU exercise shield_yield(2) no matter how
many workers are specified, thus always ensuring rapid context switching.
.TP
.B \-\-yield\-ops N
stop yield stress workers after N sched_yield(2) bogo operations.
.TP
.B \-\-zero N
start N workers reading /dev/zero.
.TP
.B \-\-zero\-ops N
stop zero stress workers after N /dev/zero bogo read operations.
.TP
.B \-\-zlib N
start N workers compressing and decompressing random data using zlib. Each
worker has two processes, one that compresses random data and pipes it to
another process that decompresses the data. This stressor exercises CPU,
cache and memory.
.TP
.B \-\-zlib\-ops N
stop after N bogo compression operations, each bogo compression operation
is a compression of 64K of random data at the highest compression level.
.TP
.B \-\-zlib\-level L
specify the compression level (0..9), where 0 = no compression, 1 = fastest
compression and 9 = best compression.
.TP
.B \-\-zlib\-method method
specify the type of random data to send to the zlib library.  By default,
the data stream is created from a random selection of the different data
generation processes.  However one can specify just one method to be used if required.
Available zlib data generation methods are described as follows:
.TS
expand;
lB2 lB lB lB
l l s s.
Method	Description
00ff	T{
randomly distributed 0x00 and 0xFF values.
T}
ascii01	T{
randomly distributed ASCII 0 and 1 characters.
T}
asciidigits	T{
randomly distributed ASCII digits in the range of 0 and 9.
T}
bcd	T{
packed binary coded decimals, 0..99 packed into 2 4-bit nybbles.
T}
binary	T{
32 bit random numbers.
T}
brown	T{
8 bit brown noise (Brownian motion/Random Walk noise).
T}
double	T{
double precision floating point numbers from sin(\(*h).
T}
fixed	T{
data stream is repeated 0x04030201.
T}
gray	T{
16 bit gray codes generated from an incrementing counter.
T}
latin	T{
Random latin sentences from a sample of Lorem Ipsum text.
T}
logmap	T{
Values generated from a logistical map of the equation
\[*X]n+1 = r \(mu  \[*X]n \(mu (1 - \[*X]n) where r > \[~~] 3.56994567
to produce chaotic data. The values are scaled by a large arbitrary
value and the lower 8 bits of this value are compressed.
T}
lfsr32	T{
Values generated from a 32 bit Galois linear feedback shift register using
the polynomial  x\[ua]32 + x\[ua]31 + x\[ua]29 + x + 1. This generates a
ring of  2\[ua]32 - 1 unique values (all 32 bit values except for 0).
T}
lrand48	T{
Uniformly distributed pseudo-random 32 bit values generated from lrand48(3).
T}
morse	T{
Morse code generated from random latin sentences from a sample of Lorem Ipsum text.
T}
nybble	T{
randomly distributed bytes in the range of 0x00 to 0x0f.
T}
objcode	T{
object code selected from a random start point in the stress-ng text segment.
T}
parity	T{
7 bit binary data with 1 parity bit.
T}
pink	T{
pink noise in the range 0..255 generated using the Gardner method with
the McCartney selection tree optimization. Pink noise is where the power
spectral density is inversely proportional to the frequency of the signal
and hence is slightly compressible.
T}
random	T{
segments of the data stream are created by randomly calling the different data generation
methods.
T}
rarely1	T{
data that has a single 1 in every 32 bits, randomly located.
T}
rarely0	T{
data that has a single 0 in every 32 bits, randomly located.
T}
text	T{
random ASCII text.
T}
utf8	T{
random 8 bit data encoded to UTF-8.
T}
zero	T{
all zeros, compresses very easily.
T}
.TE
.TP
.B \-\-zlib\-window-bits W
specify the window bits used to specify the history buffer size. The value is
specified as the base two logarithm of the buffer size (e.g. value 9 is 2^9 =
512 bytes).
Default is 15.
.PP
.RS
.nf
Values:
-8-(-15): raw deflate format
    8-15: zlib format
   24-31: gzip format
   40-47: inflate auto format detection using zlib deflate format
.fi
.RE
.PP
.B \-\-zlib\-mem-level L
specify the reserved compression state memory for zlib.
Default is 8.
.PP
.RS
.nf
Values:
1 = minimum memory usage
9 = maximum memory usage
.fi
.RE
.TP
.B \-\-zlib\-strategy S
specifies the strategy to use when deflating data. This is used to tune the
compression algorithm.
Default is 0.
.PP
.RS
.nf
Values:
0: used for normal data (Z_DEFAULT_STRATEGY)
1: for data generated by a filter or predictor (Z_FILTERED)
2: forces huffman encoding (Z_HUFFMAN_ONLY)
3: Limit match distances to one run-length-encoding (Z_RLE)
4: prevents dynamic huffman codes (Z_FIXED)
.fi
.RE
.TP
.B \-\-zlib\-stream-bytes S
specify the amount of bytes to deflate until deflate should finish the block
and return with Z_STREAM_END. One can specify the size in units of Bytes,
KBytes, MBytes and GBytes using the suffix b, k, m or g.
Default is 0 which creates and endless stream until stressor ends.
.PP
.RS
.nf
Values:
0: creates an endless deflate stream until stressor stops
n: creates an stream of n bytes over and over again.
   Each block will be closed with Z_STREAM_END.
.fi
.RE
.TP
.TP
.B \-\-zombie N
start N workers that create zombie processes. This will rapidly try to create
a default of 8192 child processes that immediately die and wait in a zombie
state until they are reaped.  Once the maximum number of processes is reached
(or fork fails because one has reached the maximum allowed number of children)
the oldest child is reaped and a new process is then created in a first-in
first-out manner, and then repeated.
.TP
.B \-\-zombie\-ops N
stop zombie stress workers after N bogo zombie operations.
.TP
.B \-\-zombie\-max N
try to create as many as N zombie processes. This may not be reached if the
system limit is less than N.
.LP
.SH EXAMPLES
.LP
stress\-ng \-\-vm 8 \-\-vm\-bytes 80% -t 1h
.IP
run 8 virtual memory stressors that combined use 80% of the available memory
for 1 hour. Thus each stressor uses 10% of the available memory.
.LP
stress\-ng \-\-cpu 4 \-\-io 2 \-\-vm 1 \-\-vm\-bytes 1G \-\-timeout 60s
.IP
runs for 60 seconds with 4 cpu stressors, 2 io stressors and 1 vm stressor
using 1GB of virtual memory.
.LP
stress\-ng \-\-iomix 2 \-\-iomix\-bytes 10% -t 10m
.IP
runs 2 instances of the mixed I/O stressors using a total of 10% of the
available file system space for 10 minutes. Each stressor will use 5% of the
available file system space.
.LP
stress\-ng \-\-cyclic 1 \-\-cyclic\-dist 2500 \-\-cyclic\-method clock_ns \-\-cyclic\-prio 100 \-\-cyclic\-sleep 10000 \-\-hdd 0 -t 1m
.IP
measures real time scheduling latencies created by the hdd stressor. This
uses the high resolution nanosecond clock to measure latencies during
sleeps of 10,000 nanoseconds. At the end of 1 minute of stressing, the
latency distribution with 2500 ns intervals will be displayed. NOTE: this
must be run with the CAP_SYS_NICE capability to enable the real time scheduling
to get accurate measurements.
.LP
stress\-ng \-\-cpu 8 \-\-cpu\-ops 800000
.IP
runs 8 cpu stressors and stops after 800000 bogo operations.
.LP
stress\-ng \-\-sequential 2 \-\-timeout 2m \-\-metrics
.IP
run 2 simultaneous instances of all the stressors sequentially one by one,
each for 2 minutes and summarise with performance metrics at the end.
.LP
stress\-ng \-\-cpu 4 \-\-cpu-method fft \-\-cpu-ops 10000 \-\-metrics\-brief
.IP
run 4 FFT cpu stressors, stop after 10000 bogo operations and produce a
summary just for the FFT results.
.LP
stress\-ng \-\-cpu -1 \-\-cpu-method all \-t 1h \-\-cpu\-load 90
.IP
run cpu stressors on all online CPUs working through all the available CPU
stressors for 1 hour, loading the CPUs at 90% load capacity.
.LP
stress\-ng \-\-cpu 0 \-\-cpu-method all \-t 20m
.IP
run cpu stressors on all configured CPUs working through all the available CPU
stressors for 20 minutes
.LP
stress\-ng \-\-all 4 \-\-timeout 5m
.IP
run 4 instances of all the stressors for 5 minutes.
.LP
stress\-ng \-\-random 64
.IP
run 64 stressors that are randomly chosen from all the available stressors.
.LP
stress\-ng \-\-cpu 64 \-\-cpu\-method all \-\-verify \-t 10m \-\-metrics\-brief
.IP
run 64 instances of all the different cpu stressors and verify that the
computations are correct for 10 minutes with a bogo operations summary at the
end.
.LP
stress\-ng \-\-sequential -1 \-t 10m
.IP
run all the stressors one by one for 10 minutes, with the number of instances
of each stressor matching the number of online CPUs.
.LP
stress\-ng \-\-sequential 8 \-\-class io \-t 5m \-\-times
.IP
run all the stressors in the io class one by one for 5 minutes each, with 8
instances of each stressor running concurrently and show overall time
utilisation statistics at the end of the run.
.LP
stress\-ng \-\-all -1 \-\-maximize \-\-aggressive
.IP
run all the stressors (1 instance of each per online CPU) simultaneously, maximize
the settings (memory sizes, file allocations, etc.) and select the most
demanding/aggressive options.
.LP
stress\-ng \-\-random 32 \-x numa,hdd,key
.IP
run 32 randomly selected stressors and exclude the numa, hdd and key stressors
.LP
stress\-ng \-\-sequential 4 \-\-class vm \-\-exclude bigheap,brk,stack
.IP
run 4 instances of the VM stressors one after each other, excluding the
bigheap, brk and stack stressors
.LP
stress\-ng \-\-taskset 0,2-3 \-\-cpu 3
.IP
run 3 instances of the CPU stressor and pin them to CPUs 0, 2 and 3.
.SH EXIT STATUS
.TS
cBw(10) lBx
c l.
Status	Description
0	T{
Success.
T}
1	T{
Error; incorrect user options or a fatal resource issue in the stress-ng
stressor harness (for example, out of memory).
T}
2	T{
One or more stressors failed.
T}
3	T{
One or more stressors failed to initialise because of lack of resources,
for example ENOMEM (no memory), ENOSPC (no space on file system) or a
missing or unimplemented system call.
T}
4	T{
One or more stressors were not implemented on a specific architecture
or operating system.
T}
5	T{
A stressor has been killed by an unexpected signal.
T}
6	T{
A stressor exited by exit(2) which was not expected and timing metrics
could not be gathered.
T}
7	T{
The bogo ops metrics maybe untrustworthy. This is most likely to occur when
a stress test is terminated during the update of a bogo-ops counter such
as when it has been OOM killed. A less likely reason is that the counter
ready indicator has been corrupted.
T}
.TE
.SH BUGS
File bug reports at:
  https://github.com/ColinIanKing/stress-ng/issues
.SH SEE ALSO
.BR cpuburn (1),
.BR perf (1),
.BR stress (1),
.BR taskset (1)
.SH AUTHOR
stress\-ng was written by Colin Ian King <colin.i.king@gmail.com> and
is a clean room re-implementation and extension of the original
stress tool by Amos Waterland. Thanks also for
contributions from Abdul Haleem, Aboorva Devarajan, Adrian Ratiu,
André Wild, Alexander Kanavin, Baruch Siach, Carlos Santo,
Christian Ehrhardt, Chunyu Hu, Danilo Krummrich,
David Turner, Dominik B Czarnota, Fabien Malfoy, Fabrice Fontaine,
Helmut Grohne, James Hunt, James Wang, Jianshen Liu, Jim Rowan, John Kacur,
Joseph DeVincentis, Jules Maselbas, Khalid Elmously, Khem Raj,
Luca Pizzamiglio, Luis Henriques, Manoj Iyer, Matthew Tippett,
Mauricio Faria de Oliveira, Maxime Chevallier, Mike Koreneff, Piyush Goyal,
Ralf Ramsauer, Rob Colclaser, Thadeu Lima de Souza Cascardo,
Thia Wyrod, Tim Gardner, Tim Orling, Tommi Rantala, Witold Baryluk,
Zhiyi Sun and others.
.SH NOTES
Sending a SIGALRM, SIGINT or SIGHUP to stress-ng causes it to
terminate all the stressor processes and ensures temporary files and
shared memory segments are removed cleanly.
.PP
Sending a SIGUSR2 to stress-ng will dump out the current load average
and memory statistics.
.PP
Note that the stress\-ng cpu, io, vm and hdd tests are different
implementations of the original stress
tests and hence may produce different stress characteristics.
stress\-ng does not support any GPU stress tests.
.PP
The bogo operations metrics may change with each release  because of bug
fixes to the code, new features, compiler optimisations or changes in system
call performance.
.SH COPYRIGHT
Copyright \(co 2013-2021 Canonical Ltd, Copyright \(co 2021-2022 Colin Ian King.
.br
This is free software; see the source for copying conditions.  There is NO
warranty; not even for MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.