522 lines
27 KiB
ReStructuredText
522 lines
27 KiB
ReStructuredText
=================================================
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A Tour Through TREE_RCU's Expedited Grace Periods
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=================================================
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Introduction
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============
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This document describes RCU's expedited grace periods.
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Unlike RCU's normal grace periods, which accept long latencies to attain
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high efficiency and minimal disturbance, expedited grace periods accept
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lower efficiency and significant disturbance to attain shorter latencies.
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There are two flavors of RCU (RCU-preempt and RCU-sched), with an earlier
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third RCU-bh flavor having been implemented in terms of the other two.
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Each of the two implementations is covered in its own section.
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Expedited Grace Period Design
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=============================
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The expedited RCU grace periods cannot be accused of being subtle,
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given that they for all intents and purposes hammer every CPU that
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has not yet provided a quiescent state for the current expedited
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grace period.
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The one saving grace is that the hammer has grown a bit smaller
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over time: The old call to ``try_stop_cpus()`` has been
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replaced with a set of calls to ``smp_call_function_single()``,
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each of which results in an IPI to the target CPU.
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The corresponding handler function checks the CPU's state, motivating
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a faster quiescent state where possible, and triggering a report
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of that quiescent state.
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As always for RCU, once everything has spent some time in a quiescent
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state, the expedited grace period has completed.
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The details of the ``smp_call_function_single()`` handler's
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operation depend on the RCU flavor, as described in the following
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sections.
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RCU-preempt Expedited Grace Periods
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===================================
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``CONFIG_PREEMPTION=y`` kernels implement RCU-preempt.
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The overall flow of the handling of a given CPU by an RCU-preempt
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expedited grace period is shown in the following diagram:
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.. kernel-figure:: ExpRCUFlow.svg
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The solid arrows denote direct action, for example, a function call.
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The dotted arrows denote indirect action, for example, an IPI
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or a state that is reached after some time.
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If a given CPU is offline or idle, ``synchronize_rcu_expedited()``
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will ignore it because idle and offline CPUs are already residing
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in quiescent states.
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Otherwise, the expedited grace period will use
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``smp_call_function_single()`` to send the CPU an IPI, which
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is handled by ``rcu_exp_handler()``.
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However, because this is preemptible RCU, ``rcu_exp_handler()``
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can check to see if the CPU is currently running in an RCU read-side
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critical section.
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If not, the handler can immediately report a quiescent state.
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Otherwise, it sets flags so that the outermost ``rcu_read_unlock()``
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invocation will provide the needed quiescent-state report.
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This flag-setting avoids the previous forced preemption of all
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CPUs that might have RCU read-side critical sections.
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In addition, this flag-setting is done so as to avoid increasing
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the overhead of the common-case fastpath through the scheduler.
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Again because this is preemptible RCU, an RCU read-side critical section
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can be preempted.
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When that happens, RCU will enqueue the task, which will the continue to
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block the current expedited grace period until it resumes and finds its
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outermost ``rcu_read_unlock()``.
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The CPU will report a quiescent state just after enqueuing the task because
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the CPU is no longer blocking the grace period.
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It is instead the preempted task doing the blocking.
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The list of blocked tasks is managed by ``rcu_preempt_ctxt_queue()``,
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which is called from ``rcu_preempt_note_context_switch()``, which
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in turn is called from ``rcu_note_context_switch()``, which in
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turn is called from the scheduler.
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+-----------------------------------------------------------------------+
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| **Quick Quiz**: |
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+-----------------------------------------------------------------------+
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| Why not just have the expedited grace period check the state of all |
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| the CPUs? After all, that would avoid all those real-time-unfriendly |
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| IPIs. |
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+-----------------------------------------------------------------------+
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| **Answer**: |
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+-----------------------------------------------------------------------+
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| Because we want the RCU read-side critical sections to run fast, |
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| which means no memory barriers. Therefore, it is not possible to |
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| safely check the state from some other CPU. And even if it was |
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| possible to safely check the state, it would still be necessary to |
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| IPI the CPU to safely interact with the upcoming |
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| ``rcu_read_unlock()`` invocation, which means that the remote state |
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| testing would not help the worst-case latency that real-time |
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| applications care about. |
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| |
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| One way to prevent your real-time application from getting hit with |
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| these IPIs is to build your kernel with ``CONFIG_NO_HZ_FULL=y``. RCU |
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| would then perceive the CPU running your application as being idle, |
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| and it would be able to safely detect that state without needing to |
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| IPI the CPU. |
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+-----------------------------------------------------------------------+
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Please note that this is just the overall flow: Additional complications
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can arise due to races with CPUs going idle or offline, among other
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things.
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RCU-sched Expedited Grace Periods
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---------------------------------
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``CONFIG_PREEMPTION=n`` kernels implement RCU-sched. The overall flow of
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the handling of a given CPU by an RCU-sched expedited grace period is
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shown in the following diagram:
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.. kernel-figure:: ExpSchedFlow.svg
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As with RCU-preempt, RCU-sched's ``synchronize_rcu_expedited()`` ignores
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offline and idle CPUs, again because they are in remotely detectable
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quiescent states. However, because the ``rcu_read_lock_sched()`` and
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``rcu_read_unlock_sched()`` leave no trace of their invocation, in
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general it is not possible to tell whether or not the current CPU is in
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an RCU read-side critical section. The best that RCU-sched's
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``rcu_exp_handler()`` can do is to check for idle, on the off-chance
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that the CPU went idle while the IPI was in flight. If the CPU is idle,
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then ``rcu_exp_handler()`` reports the quiescent state.
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Otherwise, the handler forces a future context switch by setting the
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NEED_RESCHED flag of the current task's thread flag and the CPU preempt
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counter. At the time of the context switch, the CPU reports the
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quiescent state. Should the CPU go offline first, it will report the
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quiescent state at that time.
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Expedited Grace Period and CPU Hotplug
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--------------------------------------
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The expedited nature of expedited grace periods require a much tighter
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interaction with CPU hotplug operations than is required for normal
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grace periods. In addition, attempting to IPI offline CPUs will result
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in splats, but failing to IPI online CPUs can result in too-short grace
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periods. Neither option is acceptable in production kernels.
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The interaction between expedited grace periods and CPU hotplug
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operations is carried out at several levels:
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#. The number of CPUs that have ever been online is tracked by the
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``rcu_state`` structure's ``->ncpus`` field. The ``rcu_state``
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structure's ``->ncpus_snap`` field tracks the number of CPUs that
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have ever been online at the beginning of an RCU expedited grace
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period. Note that this number never decreases, at least in the
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absence of a time machine.
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#. The identities of the CPUs that have ever been online is tracked by
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the ``rcu_node`` structure's ``->expmaskinitnext`` field. The
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``rcu_node`` structure's ``->expmaskinit`` field tracks the
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identities of the CPUs that were online at least once at the
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beginning of the most recent RCU expedited grace period. The
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``rcu_state`` structure's ``->ncpus`` and ``->ncpus_snap`` fields are
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used to detect when new CPUs have come online for the first time,
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that is, when the ``rcu_node`` structure's ``->expmaskinitnext``
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field has changed since the beginning of the last RCU expedited grace
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period, which triggers an update of each ``rcu_node`` structure's
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``->expmaskinit`` field from its ``->expmaskinitnext`` field.
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#. Each ``rcu_node`` structure's ``->expmaskinit`` field is used to
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initialize that structure's ``->expmask`` at the beginning of each
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RCU expedited grace period. This means that only those CPUs that have
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been online at least once will be considered for a given grace
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period.
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#. Any CPU that goes offline will clear its bit in its leaf ``rcu_node``
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structure's ``->qsmaskinitnext`` field, so any CPU with that bit
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clear can safely be ignored. However, it is possible for a CPU coming
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online or going offline to have this bit set for some time while
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``cpu_online`` returns ``false``.
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#. For each non-idle CPU that RCU believes is currently online, the
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grace period invokes ``smp_call_function_single()``. If this
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succeeds, the CPU was fully online. Failure indicates that the CPU is
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in the process of coming online or going offline, in which case it is
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necessary to wait for a short time period and try again. The purpose
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of this wait (or series of waits, as the case may be) is to permit a
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concurrent CPU-hotplug operation to complete.
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#. In the case of RCU-sched, one of the last acts of an outgoing CPU is
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to invoke ``rcu_report_dead()``, which reports a quiescent state for
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that CPU. However, this is likely paranoia-induced redundancy.
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+-----------------------------------------------------------------------+
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| **Quick Quiz**: |
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+-----------------------------------------------------------------------+
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| Why all the dancing around with multiple counters and masks tracking |
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| CPUs that were once online? Why not just have a single set of masks |
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| tracking the currently online CPUs and be done with it? |
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+-----------------------------------------------------------------------+
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| **Answer**: |
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+-----------------------------------------------------------------------+
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| Maintaining single set of masks tracking the online CPUs *sounds* |
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| easier, at least until you try working out all the race conditions |
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| between grace-period initialization and CPU-hotplug operations. For |
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| example, suppose initialization is progressing down the tree while a |
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| CPU-offline operation is progressing up the tree. This situation can |
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| result in bits set at the top of the tree that have no counterparts |
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| at the bottom of the tree. Those bits will never be cleared, which |
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| will result in grace-period hangs. In short, that way lies madness, |
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| to say nothing of a great many bugs, hangs, and deadlocks. |
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| In contrast, the current multi-mask multi-counter scheme ensures that |
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| grace-period initialization will always see consistent masks up and |
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| down the tree, which brings significant simplifications over the |
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| single-mask method. |
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| |
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| This is an instance of `deferring work in order to avoid |
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| synchronization <http://www.cs.columbia.edu/~library/TR-repository/re |
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| ports/reports-1992/cucs-039-92.ps.gz>`__. |
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| Lazily recording CPU-hotplug events at the beginning of the next |
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| grace period greatly simplifies maintenance of the CPU-tracking |
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| bitmasks in the ``rcu_node`` tree. |
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+-----------------------------------------------------------------------+
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Expedited Grace Period Refinements
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----------------------------------
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Idle-CPU Checks
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~~~~~~~~~~~~~~~
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Each expedited grace period checks for idle CPUs when initially forming
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the mask of CPUs to be IPIed and again just before IPIing a CPU (both
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checks are carried out by ``sync_rcu_exp_select_cpus()``). If the CPU is
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idle at any time between those two times, the CPU will not be IPIed.
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Instead, the task pushing the grace period forward will include the idle
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CPUs in the mask passed to ``rcu_report_exp_cpu_mult()``.
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For RCU-sched, there is an additional check: If the IPI has interrupted
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the idle loop, then ``rcu_exp_handler()`` invokes
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``rcu_report_exp_rdp()`` to report the corresponding quiescent state.
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For RCU-preempt, there is no specific check for idle in the IPI handler
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(``rcu_exp_handler()``), but because RCU read-side critical sections are
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not permitted within the idle loop, if ``rcu_exp_handler()`` sees that
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the CPU is within RCU read-side critical section, the CPU cannot
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possibly be idle. Otherwise, ``rcu_exp_handler()`` invokes
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``rcu_report_exp_rdp()`` to report the corresponding quiescent state,
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regardless of whether or not that quiescent state was due to the CPU
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being idle.
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In summary, RCU expedited grace periods check for idle when building the
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bitmask of CPUs that must be IPIed, just before sending each IPI, and
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(either explicitly or implicitly) within the IPI handler.
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Batching via Sequence Counter
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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If each grace-period request was carried out separately, expedited grace
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periods would have abysmal scalability and problematic high-load
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characteristics. Because each grace-period operation can serve an
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unlimited number of updates, it is important to *batch* requests, so
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that a single expedited grace-period operation will cover all requests
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in the corresponding batch.
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This batching is controlled by a sequence counter named
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``->expedited_sequence`` in the ``rcu_state`` structure. This counter
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has an odd value when there is an expedited grace period in progress and
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an even value otherwise, so that dividing the counter value by two gives
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the number of completed grace periods. During any given update request,
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the counter must transition from even to odd and then back to even, thus
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indicating that a grace period has elapsed. Therefore, if the initial
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value of the counter is ``s``, the updater must wait until the counter
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reaches at least the value ``(s+3)&~0x1``. This counter is managed by
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the following access functions:
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#. ``rcu_exp_gp_seq_start()``, which marks the start of an expedited
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grace period.
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#. ``rcu_exp_gp_seq_end()``, which marks the end of an expedited grace
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period.
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#. ``rcu_exp_gp_seq_snap()``, which obtains a snapshot of the counter.
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#. ``rcu_exp_gp_seq_done()``, which returns ``true`` if a full expedited
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grace period has elapsed since the corresponding call to
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``rcu_exp_gp_seq_snap()``.
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Again, only one request in a given batch need actually carry out a
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grace-period operation, which means there must be an efficient way to
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identify which of many concurrent requests will initiate the grace
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period, and that there be an efficient way for the remaining requests to
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wait for that grace period to complete. However, that is the topic of
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the next section.
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Funnel Locking and Wait/Wakeup
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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The natural way to sort out which of a batch of updaters will initiate
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the expedited grace period is to use the ``rcu_node`` combining tree, as
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implemented by the ``exp_funnel_lock()`` function. The first updater
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corresponding to a given grace period arriving at a given ``rcu_node``
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structure records its desired grace-period sequence number in the
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``->exp_seq_rq`` field and moves up to the next level in the tree.
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Otherwise, if the ``->exp_seq_rq`` field already contains the sequence
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number for the desired grace period or some later one, the updater
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blocks on one of four wait queues in the ``->exp_wq[]`` array, using the
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second-from-bottom and third-from bottom bits as an index. An
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``->exp_lock`` field in the ``rcu_node`` structure synchronizes access
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to these fields.
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An empty ``rcu_node`` tree is shown in the following diagram, with the
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white cells representing the ``->exp_seq_rq`` field and the red cells
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representing the elements of the ``->exp_wq[]`` array.
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.. kernel-figure:: Funnel0.svg
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The next diagram shows the situation after the arrival of Task A and
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Task B at the leftmost and rightmost leaf ``rcu_node`` structures,
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respectively. The current value of the ``rcu_state`` structure's
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``->expedited_sequence`` field is zero, so adding three and clearing the
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bottom bit results in the value two, which both tasks record in the
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``->exp_seq_rq`` field of their respective ``rcu_node`` structures:
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.. kernel-figure:: Funnel1.svg
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Each of Tasks A and B will move up to the root ``rcu_node`` structure.
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Suppose that Task A wins, recording its desired grace-period sequence
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number and resulting in the state shown below:
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.. kernel-figure:: Funnel2.svg
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Task A now advances to initiate a new grace period, while Task B moves
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up to the root ``rcu_node`` structure, and, seeing that its desired
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sequence number is already recorded, blocks on ``->exp_wq[1]``.
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+-----------------------------------------------------------------------+
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| **Quick Quiz**: |
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+-----------------------------------------------------------------------+
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| Why ``->exp_wq[1]``? Given that the value of these tasks' desired |
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| sequence number is two, so shouldn't they instead block on |
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| ``->exp_wq[2]``? |
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+-----------------------------------------------------------------------+
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| **Answer**: |
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+-----------------------------------------------------------------------+
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| No. |
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| Recall that the bottom bit of the desired sequence number indicates |
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| whether or not a grace period is currently in progress. It is |
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| therefore necessary to shift the sequence number right one bit |
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| position to obtain the number of the grace period. This results in |
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| ``->exp_wq[1]``. |
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+-----------------------------------------------------------------------+
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If Tasks C and D also arrive at this point, they will compute the same
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desired grace-period sequence number, and see that both leaf
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``rcu_node`` structures already have that value recorded. They will
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therefore block on their respective ``rcu_node`` structures'
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``->exp_wq[1]`` fields, as shown below:
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.. kernel-figure:: Funnel3.svg
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Task A now acquires the ``rcu_state`` structure's ``->exp_mutex`` and
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initiates the grace period, which increments ``->expedited_sequence``.
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Therefore, if Tasks E and F arrive, they will compute a desired sequence
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number of 4 and will record this value as shown below:
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.. kernel-figure:: Funnel4.svg
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Tasks E and F will propagate up the ``rcu_node`` combining tree, with
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Task F blocking on the root ``rcu_node`` structure and Task E wait for
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Task A to finish so that it can start the next grace period. The
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resulting state is as shown below:
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.. kernel-figure:: Funnel5.svg
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Once the grace period completes, Task A starts waking up the tasks
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waiting for this grace period to complete, increments the
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``->expedited_sequence``, acquires the ``->exp_wake_mutex`` and then
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releases the ``->exp_mutex``. This results in the following state:
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.. kernel-figure:: Funnel6.svg
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Task E can then acquire ``->exp_mutex`` and increment
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``->expedited_sequence`` to the value three. If new tasks G and H arrive
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and moves up the combining tree at the same time, the state will be as
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follows:
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.. kernel-figure:: Funnel7.svg
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Note that three of the root ``rcu_node`` structure's waitqueues are now
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occupied. However, at some point, Task A will wake up the tasks blocked
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on the ``->exp_wq`` waitqueues, resulting in the following state:
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.. kernel-figure:: Funnel8.svg
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Execution will continue with Tasks E and H completing their grace
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periods and carrying out their wakeups.
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+-----------------------------------------------------------------------+
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| **Quick Quiz**: |
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+-----------------------------------------------------------------------+
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| What happens if Task A takes so long to do its wakeups that Task E's |
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| grace period completes? |
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+-----------------------------------------------------------------------+
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| **Answer**: |
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+-----------------------------------------------------------------------+
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| Then Task E will block on the ``->exp_wake_mutex``, which will also |
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| prevent it from releasing ``->exp_mutex``, which in turn will prevent |
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| the next grace period from starting. This last is important in |
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| preventing overflow of the ``->exp_wq[]`` array. |
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+-----------------------------------------------------------------------+
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Use of Workqueues
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~~~~~~~~~~~~~~~~~
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In earlier implementations, the task requesting the expedited grace
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period also drove it to completion. This straightforward approach had
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the disadvantage of needing to account for POSIX signals sent to user
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tasks, so more recent implementations use the Linux kernel's
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workqueues (see Documentation/core-api/workqueue.rst).
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The requesting task still does counter snapshotting and funnel-lock
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processing, but the task reaching the top of the funnel lock does a
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``schedule_work()`` (from ``_synchronize_rcu_expedited()`` so that a
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workqueue kthread does the actual grace-period processing. Because
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workqueue kthreads do not accept POSIX signals, grace-period-wait
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processing need not allow for POSIX signals. In addition, this approach
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allows wakeups for the previous expedited grace period to be overlapped
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with processing for the next expedited grace period. Because there are
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only four sets of waitqueues, it is necessary to ensure that the
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previous grace period's wakeups complete before the next grace period's
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wakeups start. This is handled by having the ``->exp_mutex`` guard
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expedited grace-period processing and the ``->exp_wake_mutex`` guard
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wakeups. The key point is that the ``->exp_mutex`` is not released until
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the first wakeup is complete, which means that the ``->exp_wake_mutex``
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has already been acquired at that point. This approach ensures that the
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previous grace period's wakeups can be carried out while the current
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grace period is in process, but that these wakeups will complete before
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the next grace period starts. This means that only three waitqueues are
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required, guaranteeing that the four that are provided are sufficient.
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Stall Warnings
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~~~~~~~~~~~~~~
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|
||
Expediting grace periods does nothing to speed things up when RCU
|
||
readers take too long, and therefore expedited grace periods check for
|
||
stalls just as normal grace periods do.
|
||
|
||
+-----------------------------------------------------------------------+
|
||
| **Quick Quiz**: |
|
||
+-----------------------------------------------------------------------+
|
||
| But why not just let the normal grace-period machinery detect the |
|
||
| stalls, given that a given reader must block both normal and |
|
||
| expedited grace periods? |
|
||
+-----------------------------------------------------------------------+
|
||
| **Answer**: |
|
||
+-----------------------------------------------------------------------+
|
||
| Because it is quite possible that at a given time there is no normal |
|
||
| grace period in progress, in which case the normal grace period |
|
||
| cannot emit a stall warning. |
|
||
+-----------------------------------------------------------------------+
|
||
|
||
The ``synchronize_sched_expedited_wait()`` function loops waiting for
|
||
the expedited grace period to end, but with a timeout set to the current
|
||
RCU CPU stall-warning time. If this time is exceeded, any CPUs or
|
||
``rcu_node`` structures blocking the current grace period are printed.
|
||
Each stall warning results in another pass through the loop, but the
|
||
second and subsequent passes use longer stall times.
|
||
|
||
Mid-boot operation
|
||
~~~~~~~~~~~~~~~~~~
|
||
|
||
The use of workqueues has the advantage that the expedited grace-period
|
||
code need not worry about POSIX signals. Unfortunately, it has the
|
||
corresponding disadvantage that workqueues cannot be used until they are
|
||
initialized, which does not happen until some time after the scheduler
|
||
spawns the first task. Given that there are parts of the kernel that
|
||
really do want to execute grace periods during this mid-boot “dead
|
||
zone”, expedited grace periods must do something else during this time.
|
||
|
||
What they do is to fall back to the old practice of requiring that the
|
||
requesting task drive the expedited grace period, as was the case before
|
||
the use of workqueues. However, the requesting task is only required to
|
||
drive the grace period during the mid-boot dead zone. Before mid-boot, a
|
||
synchronous grace period is a no-op. Some time after mid-boot,
|
||
workqueues are used.
|
||
|
||
Non-expedited non-SRCU synchronous grace periods must also operate
|
||
normally during mid-boot. This is handled by causing non-expedited grace
|
||
periods to take the expedited code path during mid-boot.
|
||
|
||
The current code assumes that there are no POSIX signals during the
|
||
mid-boot dead zone. However, if an overwhelming need for POSIX signals
|
||
somehow arises, appropriate adjustments can be made to the expedited
|
||
stall-warning code. One such adjustment would reinstate the
|
||
pre-workqueue stall-warning checks, but only during the mid-boot dead
|
||
zone.
|
||
|
||
With this refinement, synchronous grace periods can now be used from
|
||
task context pretty much any time during the life of the kernel. That
|
||
is, aside from some points in the suspend, hibernate, or shutdown code
|
||
path.
|
||
|
||
Summary
|
||
~~~~~~~
|
||
|
||
Expedited grace periods use a sequence-number approach to promote
|
||
batching, so that a single grace-period operation can serve numerous
|
||
requests. A funnel lock is used to efficiently identify the one task out
|
||
of a concurrent group that will request the grace period. All members of
|
||
the group will block on waitqueues provided in the ``rcu_node``
|
||
structure. The actual grace-period processing is carried out by a
|
||
workqueue.
|
||
|
||
CPU-hotplug operations are noted lazily in order to prevent the need for
|
||
tight synchronization between expedited grace periods and CPU-hotplug
|
||
operations. The dyntick-idle counters are used to avoid sending IPIs to
|
||
idle CPUs, at least in the common case. RCU-preempt and RCU-sched use
|
||
different IPI handlers and different code to respond to the state
|
||
changes carried out by those handlers, but otherwise use common code.
|
||
|
||
Quiescent states are tracked using the ``rcu_node`` tree, and once all
|
||
necessary quiescent states have been reported, all tasks waiting on this
|
||
expedited grace period are awakened. A pair of mutexes are used to allow
|
||
one grace period's wakeups to proceed concurrently with the next grace
|
||
period's processing.
|
||
|
||
This combination of mechanisms allows expedited grace periods to run
|
||
reasonably efficiently. However, for non-time-critical tasks, normal
|
||
grace periods should be used instead because their longer duration
|
||
permits much higher degrees of batching, and thus much lower per-request
|
||
overheads.
|