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77095901b8
The RCU-bh update API is now defined in terms of that of RCU-bh and RCU-sched, so this commit updates the documentation accordingly. In addition, although RCU-sched persists in !PREEMPT kernels, in the PREEMPT case its update API is now defined in terms of that of RCU-preempt, so this commit also updates the documentation accordingly. While in the area, this commit removes the documentation for the now-obsolete synchronize_rcu_mult() and clarifies the Tasks RCU documentation. Signed-off-by: Paul E. McKenney <paulmck@linux.vnet.ibm.com>
357 lines
13 KiB
Plaintext
357 lines
13 KiB
Plaintext
==========================================
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Reducing OS jitter due to per-cpu kthreads
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==========================================
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This document lists per-CPU kthreads in the Linux kernel and presents
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options to control their OS jitter. Note that non-per-CPU kthreads are
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not listed here. To reduce OS jitter from non-per-CPU kthreads, bind
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them to a "housekeeping" CPU dedicated to such work.
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References
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==========
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- Documentation/IRQ-affinity.txt: Binding interrupts to sets of CPUs.
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- Documentation/cgroup-v1: Using cgroups to bind tasks to sets of CPUs.
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- man taskset: Using the taskset command to bind tasks to sets
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of CPUs.
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- man sched_setaffinity: Using the sched_setaffinity() system
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call to bind tasks to sets of CPUs.
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- /sys/devices/system/cpu/cpuN/online: Control CPU N's hotplug state,
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writing "0" to offline and "1" to online.
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- In order to locate kernel-generated OS jitter on CPU N:
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cd /sys/kernel/debug/tracing
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echo 1 > max_graph_depth # Increase the "1" for more detail
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echo function_graph > current_tracer
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# run workload
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cat per_cpu/cpuN/trace
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kthreads
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========
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Name:
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ehca_comp/%u
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Purpose:
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Periodically process Infiniband-related work.
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To reduce its OS jitter, do any of the following:
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1. Don't use eHCA Infiniband hardware, instead choosing hardware
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that does not require per-CPU kthreads. This will prevent these
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kthreads from being created in the first place. (This will
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work for most people, as this hardware, though important, is
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relatively old and is produced in relatively low unit volumes.)
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2. Do all eHCA-Infiniband-related work on other CPUs, including
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interrupts.
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3. Rework the eHCA driver so that its per-CPU kthreads are
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provisioned only on selected CPUs.
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Name:
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irq/%d-%s
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Purpose:
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Handle threaded interrupts.
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To reduce its OS jitter, do the following:
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1. Use irq affinity to force the irq threads to execute on
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some other CPU.
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Name:
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kcmtpd_ctr_%d
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Purpose:
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Handle Bluetooth work.
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To reduce its OS jitter, do one of the following:
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1. Don't use Bluetooth, in which case these kthreads won't be
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created in the first place.
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2. Use irq affinity to force Bluetooth-related interrupts to
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occur on some other CPU and furthermore initiate all
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Bluetooth activity on some other CPU.
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Name:
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ksoftirqd/%u
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Purpose:
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Execute softirq handlers when threaded or when under heavy load.
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To reduce its OS jitter, each softirq vector must be handled
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separately as follows:
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TIMER_SOFTIRQ
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-------------
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Do all of the following:
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1. To the extent possible, keep the CPU out of the kernel when it
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is non-idle, for example, by avoiding system calls and by forcing
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both kernel threads and interrupts to execute elsewhere.
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2. Build with CONFIG_HOTPLUG_CPU=y. After boot completes, force
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the CPU offline, then bring it back online. This forces
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recurring timers to migrate elsewhere. If you are concerned
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with multiple CPUs, force them all offline before bringing the
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first one back online. Once you have onlined the CPUs in question,
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do not offline any other CPUs, because doing so could force the
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timer back onto one of the CPUs in question.
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NET_TX_SOFTIRQ and NET_RX_SOFTIRQ
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---------------------------------
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Do all of the following:
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1. Force networking interrupts onto other CPUs.
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2. Initiate any network I/O on other CPUs.
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3. Once your application has started, prevent CPU-hotplug operations
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from being initiated from tasks that might run on the CPU to
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be de-jittered. (It is OK to force this CPU offline and then
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bring it back online before you start your application.)
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BLOCK_SOFTIRQ
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-------------
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Do all of the following:
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1. Force block-device interrupts onto some other CPU.
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2. Initiate any block I/O on other CPUs.
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3. Once your application has started, prevent CPU-hotplug operations
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from being initiated from tasks that might run on the CPU to
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be de-jittered. (It is OK to force this CPU offline and then
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bring it back online before you start your application.)
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IRQ_POLL_SOFTIRQ
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----------------
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Do all of the following:
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1. Force block-device interrupts onto some other CPU.
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2. Initiate any block I/O and block-I/O polling on other CPUs.
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3. Once your application has started, prevent CPU-hotplug operations
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from being initiated from tasks that might run on the CPU to
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be de-jittered. (It is OK to force this CPU offline and then
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bring it back online before you start your application.)
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TASKLET_SOFTIRQ
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---------------
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Do one or more of the following:
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1. Avoid use of drivers that use tasklets. (Such drivers will contain
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calls to things like tasklet_schedule().)
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2. Convert all drivers that you must use from tasklets to workqueues.
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3. Force interrupts for drivers using tasklets onto other CPUs,
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and also do I/O involving these drivers on other CPUs.
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SCHED_SOFTIRQ
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-------------
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Do all of the following:
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1. Avoid sending scheduler IPIs to the CPU to be de-jittered,
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for example, ensure that at most one runnable kthread is present
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on that CPU. If a thread that expects to run on the de-jittered
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CPU awakens, the scheduler will send an IPI that can result in
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a subsequent SCHED_SOFTIRQ.
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2. CONFIG_NO_HZ_FULL=y and ensure that the CPU to be de-jittered
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is marked as an adaptive-ticks CPU using the "nohz_full="
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boot parameter. This reduces the number of scheduler-clock
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interrupts that the de-jittered CPU receives, minimizing its
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chances of being selected to do the load balancing work that
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runs in SCHED_SOFTIRQ context.
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3. To the extent possible, keep the CPU out of the kernel when it
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is non-idle, for example, by avoiding system calls and by
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forcing both kernel threads and interrupts to execute elsewhere.
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This further reduces the number of scheduler-clock interrupts
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received by the de-jittered CPU.
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HRTIMER_SOFTIRQ
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---------------
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Do all of the following:
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1. To the extent possible, keep the CPU out of the kernel when it
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is non-idle. For example, avoid system calls and force both
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kernel threads and interrupts to execute elsewhere.
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2. Build with CONFIG_HOTPLUG_CPU=y. Once boot completes, force the
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CPU offline, then bring it back online. This forces recurring
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timers to migrate elsewhere. If you are concerned with multiple
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CPUs, force them all offline before bringing the first one
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back online. Once you have onlined the CPUs in question, do not
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offline any other CPUs, because doing so could force the timer
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back onto one of the CPUs in question.
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RCU_SOFTIRQ
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-----------
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Do at least one of the following:
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1. Offload callbacks and keep the CPU in either dyntick-idle or
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adaptive-ticks state by doing all of the following:
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a. CONFIG_NO_HZ_FULL=y and ensure that the CPU to be
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de-jittered is marked as an adaptive-ticks CPU using the
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"nohz_full=" boot parameter. Bind the rcuo kthreads to
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housekeeping CPUs, which can tolerate OS jitter.
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b. To the extent possible, keep the CPU out of the kernel
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when it is non-idle, for example, by avoiding system
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calls and by forcing both kernel threads and interrupts
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to execute elsewhere.
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2. Enable RCU to do its processing remotely via dyntick-idle by
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doing all of the following:
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a. Build with CONFIG_NO_HZ=y and CONFIG_RCU_FAST_NO_HZ=y.
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b. Ensure that the CPU goes idle frequently, allowing other
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CPUs to detect that it has passed through an RCU quiescent
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state. If the kernel is built with CONFIG_NO_HZ_FULL=y,
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userspace execution also allows other CPUs to detect that
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the CPU in question has passed through a quiescent state.
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c. To the extent possible, keep the CPU out of the kernel
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when it is non-idle, for example, by avoiding system
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calls and by forcing both kernel threads and interrupts
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to execute elsewhere.
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Name:
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kworker/%u:%d%s (cpu, id, priority)
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Purpose:
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Execute workqueue requests
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To reduce its OS jitter, do any of the following:
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1. Run your workload at a real-time priority, which will allow
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preempting the kworker daemons.
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2. A given workqueue can be made visible in the sysfs filesystem
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by passing the WQ_SYSFS to that workqueue's alloc_workqueue().
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Such a workqueue can be confined to a given subset of the
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CPUs using the ``/sys/devices/virtual/workqueue/*/cpumask`` sysfs
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files. The set of WQ_SYSFS workqueues can be displayed using
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"ls sys/devices/virtual/workqueue". That said, the workqueues
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maintainer would like to caution people against indiscriminately
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sprinkling WQ_SYSFS across all the workqueues. The reason for
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caution is that it is easy to add WQ_SYSFS, but because sysfs is
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part of the formal user/kernel API, it can be nearly impossible
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to remove it, even if its addition was a mistake.
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3. Do any of the following needed to avoid jitter that your
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application cannot tolerate:
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a. Build your kernel with CONFIG_SLUB=y rather than
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CONFIG_SLAB=y, thus avoiding the slab allocator's periodic
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use of each CPU's workqueues to run its cache_reap()
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function.
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b. Avoid using oprofile, thus avoiding OS jitter from
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wq_sync_buffer().
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c. Limit your CPU frequency so that a CPU-frequency
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governor is not required, possibly enlisting the aid of
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special heatsinks or other cooling technologies. If done
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correctly, and if you CPU architecture permits, you should
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be able to build your kernel with CONFIG_CPU_FREQ=n to
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avoid the CPU-frequency governor periodically running
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on each CPU, including cs_dbs_timer() and od_dbs_timer().
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WARNING: Please check your CPU specifications to
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make sure that this is safe on your particular system.
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d. As of v3.18, Christoph Lameter's on-demand vmstat workers
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commit prevents OS jitter due to vmstat_update() on
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CONFIG_SMP=y systems. Before v3.18, is not possible
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to entirely get rid of the OS jitter, but you can
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decrease its frequency by writing a large value to
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/proc/sys/vm/stat_interval. The default value is HZ,
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for an interval of one second. Of course, larger values
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will make your virtual-memory statistics update more
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slowly. Of course, you can also run your workload at
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a real-time priority, thus preempting vmstat_update(),
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but if your workload is CPU-bound, this is a bad idea.
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However, there is an RFC patch from Christoph Lameter
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(based on an earlier one from Gilad Ben-Yossef) that
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reduces or even eliminates vmstat overhead for some
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workloads at https://lkml.org/lkml/2013/9/4/379.
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e. Boot with "elevator=noop" to avoid workqueue use by
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the block layer.
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f. If running on high-end powerpc servers, build with
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CONFIG_PPC_RTAS_DAEMON=n. This prevents the RTAS
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daemon from running on each CPU every second or so.
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(This will require editing Kconfig files and will defeat
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this platform's RAS functionality.) This avoids jitter
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due to the rtas_event_scan() function.
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WARNING: Please check your CPU specifications to
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make sure that this is safe on your particular system.
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g. If running on Cell Processor, build your kernel with
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CBE_CPUFREQ_SPU_GOVERNOR=n to avoid OS jitter from
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spu_gov_work().
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WARNING: Please check your CPU specifications to
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make sure that this is safe on your particular system.
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h. If running on PowerMAC, build your kernel with
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CONFIG_PMAC_RACKMETER=n to disable the CPU-meter,
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avoiding OS jitter from rackmeter_do_timer().
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Name:
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rcuc/%u
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Purpose:
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Execute RCU callbacks in CONFIG_RCU_BOOST=y kernels.
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To reduce its OS jitter, do at least one of the following:
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1. Build the kernel with CONFIG_PREEMPT=n. This prevents these
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kthreads from being created in the first place, and also obviates
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the need for RCU priority boosting. This approach is feasible
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for workloads that do not require high degrees of responsiveness.
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2. Build the kernel with CONFIG_RCU_BOOST=n. This prevents these
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kthreads from being created in the first place. This approach
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is feasible only if your workload never requires RCU priority
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boosting, for example, if you ensure frequent idle time on all
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CPUs that might execute within the kernel.
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3. Build with CONFIG_RCU_NOCB_CPU=y and boot with the rcu_nocbs=
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boot parameter offloading RCU callbacks from all CPUs susceptible
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to OS jitter. This approach prevents the rcuc/%u kthreads from
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having any work to do, so that they are never awakened.
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4. Ensure that the CPU never enters the kernel, and, in particular,
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avoid initiating any CPU hotplug operations on this CPU. This is
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another way of preventing any callbacks from being queued on the
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CPU, again preventing the rcuc/%u kthreads from having any work
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to do.
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Name:
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rcuop/%d and rcuos/%d
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Purpose:
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Offload RCU callbacks from the corresponding CPU.
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To reduce its OS jitter, do at least one of the following:
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1. Use affinity, cgroups, or other mechanism to force these kthreads
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to execute on some other CPU.
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2. Build with CONFIG_RCU_NOCB_CPU=n, which will prevent these
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kthreads from being created in the first place. However, please
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note that this will not eliminate OS jitter, but will instead
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shift it to RCU_SOFTIRQ.
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Name:
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watchdog/%u
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Purpose:
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Detect software lockups on each CPU.
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To reduce its OS jitter, do at least one of the following:
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1. Build with CONFIG_LOCKUP_DETECTOR=n, which will prevent these
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kthreads from being created in the first place.
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2. Boot with "nosoftlockup=0", which will also prevent these kthreads
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from being created. Other related watchdog and softlockup boot
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parameters may be found in Documentation/admin-guide/kernel-parameters.rst
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and Documentation/watchdog/watchdog-parameters.txt.
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3. Echo a zero to /proc/sys/kernel/watchdog to disable the
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watchdog timer.
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4. Echo a large number of /proc/sys/kernel/watchdog_thresh in
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order to reduce the frequency of OS jitter due to the watchdog
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timer down to a level that is acceptable for your workload.
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