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======================================================
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A Tour Through TREE_RCU's Grace-Period Memory Ordering
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======================================================
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August 8, 2017
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This article was contributed by Paul E. McKenney
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Introduction
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============
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This document gives a rough visual overview of how Tree RCU's
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grace-period memory ordering guarantee is provided.
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What Is Tree RCU's Grace Period Memory Ordering Guarantee?
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==========================================================
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RCU grace periods provide extremely strong memory-ordering guarantees
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for non-idle non-offline code.
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Any code that happens after the end of a given RCU grace period is guaranteed
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to see the effects of all accesses prior to the beginning of that grace
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period that are within RCU read-side critical sections.
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Similarly, any code that happens before the beginning of a given RCU grace
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period is guaranteed to see the effects of all accesses following the end
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of that grace period that are within RCU read-side critical sections.
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Note well that RCU-sched read-side critical sections include any region
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of code for which preemption is disabled.
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Given that each individual machine instruction can be thought of as
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an extremely small region of preemption-disabled code, one can think of
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``synchronize_rcu()`` as ``smp_mb()`` on steroids.
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RCU updaters use this guarantee by splitting their updates into
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two phases, one of which is executed before the grace period and
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the other of which is executed after the grace period.
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In the most common use case, phase one removes an element from
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a linked RCU-protected data structure, and phase two frees that element.
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For this to work, any readers that have witnessed state prior to the
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phase-one update (in the common case, removal) must not witness state
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following the phase-two update (in the common case, freeing).
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The RCU implementation provides this guarantee using a network
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of lock-based critical sections, memory barriers, and per-CPU
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processing, as is described in the following sections.
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Tree RCU Grace Period Memory Ordering Building Blocks
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=====================================================
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The workhorse for RCU's grace-period memory ordering is the
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critical section for the ``rcu_node`` structure's
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``->lock``. These critical sections use helper functions for lock
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acquisition, including ``raw_spin_lock_rcu_node()``,
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``raw_spin_lock_irq_rcu_node()``, and ``raw_spin_lock_irqsave_rcu_node()``.
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Their lock-release counterparts are ``raw_spin_unlock_rcu_node()``,
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``raw_spin_unlock_irq_rcu_node()``, and
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``raw_spin_unlock_irqrestore_rcu_node()``, respectively.
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For completeness, a ``raw_spin_trylock_rcu_node()`` is also provided.
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The key point is that the lock-acquisition functions, including
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``raw_spin_trylock_rcu_node()``, all invoke ``smp_mb__after_unlock_lock()``
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immediately after successful acquisition of the lock.
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Therefore, for any given ``rcu_node`` structure, any access
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happening before one of the above lock-release functions will be seen
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by all CPUs as happening before any access happening after a later
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one of the above lock-acquisition functions.
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Furthermore, any access happening before one of the
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above lock-release function on any given CPU will be seen by all
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CPUs as happening before any access happening after a later one
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of the above lock-acquisition functions executing on that same CPU,
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even if the lock-release and lock-acquisition functions are operating
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on different ``rcu_node`` structures.
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Tree RCU uses these two ordering guarantees to form an ordering
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network among all CPUs that were in any way involved in the grace
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period, including any CPUs that came online or went offline during
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the grace period in question.
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The following litmus test exhibits the ordering effects of these
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lock-acquisition and lock-release functions::
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1 int x, y, z;
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2
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3 void task0(void)
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4 {
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5 raw_spin_lock_rcu_node(rnp);
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6 WRITE_ONCE(x, 1);
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7 r1 = READ_ONCE(y);
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8 raw_spin_unlock_rcu_node(rnp);
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9 }
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10
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11 void task1(void)
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12 {
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13 raw_spin_lock_rcu_node(rnp);
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14 WRITE_ONCE(y, 1);
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15 r2 = READ_ONCE(z);
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16 raw_spin_unlock_rcu_node(rnp);
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17 }
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18
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19 void task2(void)
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20 {
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21 WRITE_ONCE(z, 1);
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22 smp_mb();
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23 r3 = READ_ONCE(x);
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24 }
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25
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26 WARN_ON(r1 == 0 && r2 == 0 && r3 == 0);
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The ``WARN_ON()`` is evaluated at "the end of time",
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after all changes have propagated throughout the system.
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Without the ``smp_mb__after_unlock_lock()`` provided by the
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acquisition functions, this ``WARN_ON()`` could trigger, for example
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on PowerPC.
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The ``smp_mb__after_unlock_lock()`` invocations prevent this
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``WARN_ON()`` from triggering.
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This approach must be extended to include idle CPUs, which need
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RCU's grace-period memory ordering guarantee to extend to any
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RCU read-side critical sections preceding and following the current
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idle sojourn.
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This case is handled by calls to the strongly ordered
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``atomic_add_return()`` read-modify-write atomic operation that
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is invoked within ``rcu_dynticks_eqs_enter()`` at idle-entry
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time and within ``rcu_dynticks_eqs_exit()`` at idle-exit time.
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The grace-period kthread invokes ``rcu_dynticks_snap()`` and
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``rcu_dynticks_in_eqs_since()`` (both of which invoke
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an ``atomic_add_return()`` of zero) to detect idle CPUs.
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+-----------------------------------------------------------------------+
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| **Quick Quiz**: |
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+-----------------------------------------------------------------------+
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| But what about CPUs that remain offline for the entire grace period? |
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+-----------------------------------------------------------------------+
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| **Answer**: |
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+-----------------------------------------------------------------------+
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| Such CPUs will be offline at the beginning of the grace period, so |
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| the grace period won't expect quiescent states from them. Races |
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| between grace-period start and CPU-hotplug operations are mediated |
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| by the CPU's leaf ``rcu_node`` structure's ``->lock`` as described |
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| above. |
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+-----------------------------------------------------------------------+
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The approach must be extended to handle one final case, that of waking a
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task blocked in ``synchronize_rcu()``. This task might be affinitied to
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a CPU that is not yet aware that the grace period has ended, and thus
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might not yet be subject to the grace period's memory ordering.
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Therefore, there is an ``smp_mb()`` after the return from
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``wait_for_completion()`` in the ``synchronize_rcu()`` code path.
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+-----------------------------------------------------------------------+
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| **Quick Quiz**: |
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+-----------------------------------------------------------------------+
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| What? Where??? I don't see any ``smp_mb()`` after the return from |
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| ``wait_for_completion()``!!! |
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+-----------------------------------------------------------------------+
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| **Answer**: |
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+-----------------------------------------------------------------------+
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| That would be because I spotted the need for that ``smp_mb()`` during |
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| the creation of this documentation, and it is therefore unlikely to |
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| hit mainline before v4.14. Kudos to Lance Roy, Will Deacon, Peter |
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| Zijlstra, and Jonathan Cameron for asking questions that sensitized |
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| me to the rather elaborate sequence of events that demonstrate the |
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| need for this memory barrier. |
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+-----------------------------------------------------------------------+
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Tree RCU's grace--period memory-ordering guarantees rely most heavily on
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the ``rcu_node`` structure's ``->lock`` field, so much so that it is
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necessary to abbreviate this pattern in the diagrams in the next
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section. For example, consider the ``rcu_prepare_for_idle()`` function
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shown below, which is one of several functions that enforce ordering of
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newly arrived RCU callbacks against future grace periods:
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::
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1 static void rcu_prepare_for_idle(void)
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2 {
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3 bool needwake;
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4 struct rcu_data *rdp;
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5 struct rcu_dynticks *rdtp = this_cpu_ptr(&rcu_dynticks);
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6 struct rcu_node *rnp;
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7 struct rcu_state *rsp;
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8 int tne;
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9
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10 if (IS_ENABLED(CONFIG_RCU_NOCB_CPU_ALL) ||
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11 rcu_is_nocb_cpu(smp_processor_id()))
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12 return;
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13 tne = READ_ONCE(tick_nohz_active);
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14 if (tne != rdtp->tick_nohz_enabled_snap) {
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15 if (rcu_cpu_has_callbacks(NULL))
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16 invoke_rcu_core();
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17 rdtp->tick_nohz_enabled_snap = tne;
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18 return;
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19 }
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20 if (!tne)
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21 return;
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22 if (rdtp->all_lazy &&
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23 rdtp->nonlazy_posted != rdtp->nonlazy_posted_snap) {
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24 rdtp->all_lazy = false;
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25 rdtp->nonlazy_posted_snap = rdtp->nonlazy_posted;
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26 invoke_rcu_core();
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27 return;
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28 }
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29 if (rdtp->last_accelerate == jiffies)
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30 return;
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31 rdtp->last_accelerate = jiffies;
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32 for_each_rcu_flavor(rsp) {
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33 rdp = this_cpu_ptr(rsp->rda);
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34 if (rcu_segcblist_pend_cbs(&rdp->cblist))
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35 continue;
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36 rnp = rdp->mynode;
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37 raw_spin_lock_rcu_node(rnp);
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38 needwake = rcu_accelerate_cbs(rsp, rnp, rdp);
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39 raw_spin_unlock_rcu_node(rnp);
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40 if (needwake)
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41 rcu_gp_kthread_wake(rsp);
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42 }
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43 }
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But the only part of ``rcu_prepare_for_idle()`` that really matters for
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this discussion are lines 37–39. We will therefore abbreviate this
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function as follows:
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.. kernel-figure:: rcu_node-lock.svg
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The box represents the ``rcu_node`` structure's ``->lock`` critical
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section, with the double line on top representing the additional
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``smp_mb__after_unlock_lock()``.
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Tree RCU Grace Period Memory Ordering Components
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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Tree RCU's grace-period memory-ordering guarantee is provided by a
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number of RCU components:
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#. `Callback Registry`_
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#. `Grace-Period Initialization`_
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#. `Self-Reported Quiescent States`_
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#. `Dynamic Tick Interface`_
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#. `CPU-Hotplug Interface`_
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#. `Forcing Quiescent States`_
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#. `Grace-Period Cleanup`_
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#. `Callback Invocation`_
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Each of the following section looks at the corresponding component in
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detail.
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Callback Registry
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^^^^^^^^^^^^^^^^^
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If RCU's grace-period guarantee is to mean anything at all, any access
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that happens before a given invocation of ``call_rcu()`` must also
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happen before the corresponding grace period. The implementation of this
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portion of RCU's grace period guarantee is shown in the following
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figure:
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.. kernel-figure:: TreeRCU-callback-registry.svg
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Because ``call_rcu()`` normally acts only on CPU-local state, it
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provides no ordering guarantees, either for itself or for phase one of
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the update (which again will usually be removal of an element from an
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RCU-protected data structure). It simply enqueues the ``rcu_head``
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structure on a per-CPU list, which cannot become associated with a grace
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period until a later call to ``rcu_accelerate_cbs()``, as shown in the
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diagram above.
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One set of code paths shown on the left invokes ``rcu_accelerate_cbs()``
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via ``note_gp_changes()``, either directly from ``call_rcu()`` (if the
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current CPU is inundated with queued ``rcu_head`` structures) or more
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likely from an ``RCU_SOFTIRQ`` handler. Another code path in the middle
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is taken only in kernels built with ``CONFIG_RCU_FAST_NO_HZ=y``, which
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invokes ``rcu_accelerate_cbs()`` via ``rcu_prepare_for_idle()``. The
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final code path on the right is taken only in kernels built with
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``CONFIG_HOTPLUG_CPU=y``, which invokes ``rcu_accelerate_cbs()`` via
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``rcu_advance_cbs()``, ``rcu_migrate_callbacks``,
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``rcutree_migrate_callbacks()``, and ``takedown_cpu()``, which in turn
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is invoked on a surviving CPU after the outgoing CPU has been completely
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offlined.
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There are a few other code paths within grace-period processing that
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opportunistically invoke ``rcu_accelerate_cbs()``. However, either way,
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all of the CPU's recently queued ``rcu_head`` structures are associated
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with a future grace-period number under the protection of the CPU's lead
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``rcu_node`` structure's ``->lock``. In all cases, there is full
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ordering against any prior critical section for that same ``rcu_node``
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structure's ``->lock``, and also full ordering against any of the
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current task's or CPU's prior critical sections for any ``rcu_node``
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structure's ``->lock``.
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The next section will show how this ordering ensures that any accesses
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prior to the ``call_rcu()`` (particularly including phase one of the
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update) happen before the start of the corresponding grace period.
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+-----------------------------------------------------------------------+
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| **Quick Quiz**: |
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+-----------------------------------------------------------------------+
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| But what about ``synchronize_rcu()``? |
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+-----------------------------------------------------------------------+
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| **Answer**: |
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+-----------------------------------------------------------------------+
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| The ``synchronize_rcu()`` passes ``call_rcu()`` to ``wait_rcu_gp()``, |
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| which invokes it. So either way, it eventually comes down to |
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| ``call_rcu()``. |
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+-----------------------------------------------------------------------+
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Grace-Period Initialization
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^^^^^^^^^^^^^^^^^^^^^^^^^^^
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Grace-period initialization is carried out by the grace-period kernel
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thread, which makes several passes over the ``rcu_node`` tree within the
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``rcu_gp_init()`` function. This means that showing the full flow of
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ordering through the grace-period computation will require duplicating
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this tree. If you find this confusing, please note that the state of the
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``rcu_node`` changes over time, just like Heraclitus's river. However,
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to keep the ``rcu_node`` river tractable, the grace-period kernel
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thread's traversals are presented in multiple parts, starting in this
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section with the various phases of grace-period initialization.
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The first ordering-related grace-period initialization action is to
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advance the ``rcu_state`` structure's ``->gp_seq`` grace-period-number
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counter, as shown below:
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.. kernel-figure:: TreeRCU-gp-init-1.svg
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The actual increment is carried out using ``smp_store_release()``, which
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helps reject false-positive RCU CPU stall detection. Note that only the
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root ``rcu_node`` structure is touched.
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The first pass through the ``rcu_node`` tree updates bitmasks based on
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CPUs having come online or gone offline since the start of the previous
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grace period. In the common case where the number of online CPUs for
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this ``rcu_node`` structure has not transitioned to or from zero, this
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pass will scan only the leaf ``rcu_node`` structures. However, if the
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number of online CPUs for a given leaf ``rcu_node`` structure has
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transitioned from zero, ``rcu_init_new_rnp()`` will be invoked for the
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first incoming CPU. Similarly, if the number of online CPUs for a given
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leaf ``rcu_node`` structure has transitioned to zero,
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``rcu_cleanup_dead_rnp()`` will be invoked for the last outgoing CPU.
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The diagram below shows the path of ordering if the leftmost
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``rcu_node`` structure onlines its first CPU and if the next
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``rcu_node`` structure has no online CPUs (or, alternatively if the
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leftmost ``rcu_node`` structure offlines its last CPU and if the next
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``rcu_node`` structure has no online CPUs).
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.. kernel-figure:: TreeRCU-gp-init-1.svg
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The final ``rcu_gp_init()`` pass through the ``rcu_node`` tree traverses
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breadth-first, setting each ``rcu_node`` structure's ``->gp_seq`` field
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to the newly advanced value from the ``rcu_state`` structure, as shown
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in the following diagram.
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.. kernel-figure:: TreeRCU-gp-init-1.svg
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This change will also cause each CPU's next call to
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``__note_gp_changes()`` to notice that a new grace period has started,
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as described in the next section. But because the grace-period kthread
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started the grace period at the root (with the advancing of the
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``rcu_state`` structure's ``->gp_seq`` field) before setting each leaf
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``rcu_node`` structure's ``->gp_seq`` field, each CPU's observation of
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the start of the grace period will happen after the actual start of the
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grace period.
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+-----------------------------------------------------------------------+
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| **Quick Quiz**: |
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+-----------------------------------------------------------------------+
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| But what about the CPU that started the grace period? Why wouldn't it |
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| see the start of the grace period right when it started that grace |
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| period? |
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+-----------------------------------------------------------------------+
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| **Answer**: |
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+-----------------------------------------------------------------------+
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| In some deep philosophical and overly anthromorphized sense, yes, the |
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| CPU starting the grace period is immediately aware of having done so. |
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| However, if we instead assume that RCU is not self-aware, then even |
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| the CPU starting the grace period does not really become aware of the |
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| start of this grace period until its first call to |
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| ``__note_gp_changes()``. On the other hand, this CPU potentially gets |
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| early notification because it invokes ``__note_gp_changes()`` during |
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| its last ``rcu_gp_init()`` pass through its leaf ``rcu_node`` |
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| structure. |
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+-----------------------------------------------------------------------+
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Self-Reported Quiescent States
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^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
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When all entities that might block the grace period have reported
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quiescent states (or as described in a later section, had quiescent
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states reported on their behalf), the grace period can end. Online
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non-idle CPUs report their own quiescent states, as shown in the
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following diagram:
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.. kernel-figure:: TreeRCU-qs.svg
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This is for the last CPU to report a quiescent state, which signals the
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end of the grace period. Earlier quiescent states would push up the
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``rcu_node`` tree only until they encountered an ``rcu_node`` structure
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that is waiting for additional quiescent states. However, ordering is
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nevertheless preserved because some later quiescent state will acquire
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that ``rcu_node`` structure's ``->lock``.
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Any number of events can lead up to a CPU invoking ``note_gp_changes``
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(or alternatively, directly invoking ``__note_gp_changes()``), at which
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point that CPU will notice the start of a new grace period while holding
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its leaf ``rcu_node`` lock. Therefore, all execution shown in this
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diagram happens after the start of the grace period. In addition, this
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CPU will consider any RCU read-side critical section that started before
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the invocation of ``__note_gp_changes()`` to have started before the
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grace period, and thus a critical section that the grace period must
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wait on.
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+-----------------------------------------------------------------------+
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| **Quick Quiz**: |
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+-----------------------------------------------------------------------+
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| But a RCU read-side critical section might have started after the |
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| beginning of the grace period (the advancing of ``->gp_seq`` from |
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| earlier), so why should the grace period wait on such a critical |
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| section? |
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+-----------------------------------------------------------------------+
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| **Answer**: |
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+-----------------------------------------------------------------------+
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| It is indeed not necessary for the grace period to wait on such a |
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| critical section. However, it is permissible to wait on it. And it is |
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| furthermore important to wait on it, as this lazy approach is far |
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| more scalable than a “big bang” all-at-once grace-period start could |
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| possibly be. |
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+-----------------------------------------------------------------------+
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If the CPU does a context switch, a quiescent state will be noted by
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``rcu_note_context_switch()`` on the left. On the other hand, if the CPU
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takes a scheduler-clock interrupt while executing in usermode, a
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quiescent state will be noted by ``rcu_sched_clock_irq()`` on the right.
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Either way, the passage through a quiescent state will be noted in a
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per-CPU variable.
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The next time an ``RCU_SOFTIRQ`` handler executes on this CPU (for
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example, after the next scheduler-clock interrupt), ``rcu_core()`` will
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invoke ``rcu_check_quiescent_state()``, which will notice the recorded
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quiescent state, and invoke ``rcu_report_qs_rdp()``. If
|
||
``rcu_report_qs_rdp()`` verifies that the quiescent state really does
|
||
apply to the current grace period, it invokes ``rcu_report_rnp()`` which
|
||
traverses up the ``rcu_node`` tree as shown at the bottom of the
|
||
diagram, clearing bits from each ``rcu_node`` structure's ``->qsmask``
|
||
field, and propagating up the tree when the result is zero.
|
||
|
||
Note that traversal passes upwards out of a given ``rcu_node`` structure
|
||
only if the current CPU is reporting the last quiescent state for the
|
||
subtree headed by that ``rcu_node`` structure. A key point is that if a
|
||
CPU's traversal stops at a given ``rcu_node`` structure, then there will
|
||
be a later traversal by another CPU (or perhaps the same one) that
|
||
proceeds upwards from that point, and the ``rcu_node`` ``->lock``
|
||
guarantees that the first CPU's quiescent state happens before the
|
||
remainder of the second CPU's traversal. Applying this line of thought
|
||
repeatedly shows that all CPUs' quiescent states happen before the last
|
||
CPU traverses through the root ``rcu_node`` structure, the “last CPU”
|
||
being the one that clears the last bit in the root ``rcu_node``
|
||
structure's ``->qsmask`` field.
|
||
|
||
Dynamic Tick Interface
|
||
^^^^^^^^^^^^^^^^^^^^^^
|
||
|
||
Due to energy-efficiency considerations, RCU is forbidden from
|
||
disturbing idle CPUs. CPUs are therefore required to notify RCU when
|
||
entering or leaving idle state, which they do via fully ordered
|
||
value-returning atomic operations on a per-CPU variable. The ordering
|
||
effects are as shown below:
|
||
|
||
.. kernel-figure:: TreeRCU-dyntick.svg
|
||
|
||
The RCU grace-period kernel thread samples the per-CPU idleness variable
|
||
while holding the corresponding CPU's leaf ``rcu_node`` structure's
|
||
``->lock``. This means that any RCU read-side critical sections that
|
||
precede the idle period (the oval near the top of the diagram above)
|
||
will happen before the end of the current grace period. Similarly, the
|
||
beginning of the current grace period will happen before any RCU
|
||
read-side critical sections that follow the idle period (the oval near
|
||
the bottom of the diagram above).
|
||
|
||
Plumbing this into the full grace-period execution is described
|
||
`below <#Forcing%20Quiescent%20States>`__.
|
||
|
||
CPU-Hotplug Interface
|
||
^^^^^^^^^^^^^^^^^^^^^
|
||
|
||
RCU is also forbidden from disturbing offline CPUs, which might well be
|
||
powered off and removed from the system completely. CPUs are therefore
|
||
required to notify RCU of their comings and goings as part of the
|
||
corresponding CPU hotplug operations. The ordering effects are shown
|
||
below:
|
||
|
||
.. kernel-figure:: TreeRCU-hotplug.svg
|
||
|
||
Because CPU hotplug operations are much less frequent than idle
|
||
transitions, they are heavier weight, and thus acquire the CPU's leaf
|
||
``rcu_node`` structure's ``->lock`` and update this structure's
|
||
``->qsmaskinitnext``. The RCU grace-period kernel thread samples this
|
||
mask to detect CPUs having gone offline since the beginning of this
|
||
grace period.
|
||
|
||
Plumbing this into the full grace-period execution is described
|
||
`below <#Forcing%20Quiescent%20States>`__.
|
||
|
||
Forcing Quiescent States
|
||
^^^^^^^^^^^^^^^^^^^^^^^^
|
||
|
||
As noted above, idle and offline CPUs cannot report their own quiescent
|
||
states, and therefore the grace-period kernel thread must do the
|
||
reporting on their behalf. This process is called “forcing quiescent
|
||
states”, it is repeated every few jiffies, and its ordering effects are
|
||
shown below:
|
||
|
||
.. kernel-figure:: TreeRCU-gp-fqs.svg
|
||
|
||
Each pass of quiescent state forcing is guaranteed to traverse the leaf
|
||
``rcu_node`` structures, and if there are no new quiescent states due to
|
||
recently idled and/or offlined CPUs, then only the leaves are traversed.
|
||
However, if there is a newly offlined CPU as illustrated on the left or
|
||
a newly idled CPU as illustrated on the right, the corresponding
|
||
quiescent state will be driven up towards the root. As with
|
||
self-reported quiescent states, the upwards driving stops once it
|
||
reaches an ``rcu_node`` structure that has quiescent states outstanding
|
||
from other CPUs.
|
||
|
||
+-----------------------------------------------------------------------+
|
||
| **Quick Quiz**: |
|
||
+-----------------------------------------------------------------------+
|
||
| The leftmost drive to root stopped before it reached the root |
|
||
| ``rcu_node`` structure, which means that there are still CPUs |
|
||
| subordinate to that structure on which the current grace period is |
|
||
| waiting. Given that, how is it possible that the rightmost drive to |
|
||
| root ended the grace period? |
|
||
+-----------------------------------------------------------------------+
|
||
| **Answer**: |
|
||
+-----------------------------------------------------------------------+
|
||
| Good analysis! It is in fact impossible in the absence of bugs in |
|
||
| RCU. But this diagram is complex enough as it is, so simplicity |
|
||
| overrode accuracy. You can think of it as poetic license, or you can |
|
||
| think of it as misdirection that is resolved in the |
|
||
| `stitched-together diagram <#Putting%20It%20All%20Together>`__. |
|
||
+-----------------------------------------------------------------------+
|
||
|
||
Grace-Period Cleanup
|
||
^^^^^^^^^^^^^^^^^^^^
|
||
|
||
Grace-period cleanup first scans the ``rcu_node`` tree breadth-first
|
||
advancing all the ``->gp_seq`` fields, then it advances the
|
||
``rcu_state`` structure's ``->gp_seq`` field. The ordering effects are
|
||
shown below:
|
||
|
||
.. kernel-figure:: TreeRCU-gp-cleanup.svg
|
||
|
||
As indicated by the oval at the bottom of the diagram, once grace-period
|
||
cleanup is complete, the next grace period can begin.
|
||
|
||
+-----------------------------------------------------------------------+
|
||
| **Quick Quiz**: |
|
||
+-----------------------------------------------------------------------+
|
||
| But when precisely does the grace period end? |
|
||
+-----------------------------------------------------------------------+
|
||
| **Answer**: |
|
||
+-----------------------------------------------------------------------+
|
||
| There is no useful single point at which the grace period can be said |
|
||
| to end. The earliest reasonable candidate is as soon as the last CPU |
|
||
| has reported its quiescent state, but it may be some milliseconds |
|
||
| before RCU becomes aware of this. The latest reasonable candidate is |
|
||
| once the ``rcu_state`` structure's ``->gp_seq`` field has been |
|
||
| updated, but it is quite possible that some CPUs have already |
|
||
| completed phase two of their updates by that time. In short, if you |
|
||
| are going to work with RCU, you need to learn to embrace uncertainty. |
|
||
+-----------------------------------------------------------------------+
|
||
|
||
Callback Invocation
|
||
^^^^^^^^^^^^^^^^^^^
|
||
|
||
Once a given CPU's leaf ``rcu_node`` structure's ``->gp_seq`` field has
|
||
been updated, that CPU can begin invoking its RCU callbacks that were
|
||
waiting for this grace period to end. These callbacks are identified by
|
||
``rcu_advance_cbs()``, which is usually invoked by
|
||
``__note_gp_changes()``. As shown in the diagram below, this invocation
|
||
can be triggered by the scheduling-clock interrupt
|
||
(``rcu_sched_clock_irq()`` on the left) or by idle entry
|
||
(``rcu_cleanup_after_idle()`` on the right, but only for kernels build
|
||
with ``CONFIG_RCU_FAST_NO_HZ=y``). Either way, ``RCU_SOFTIRQ`` is
|
||
raised, which results in ``rcu_do_batch()`` invoking the callbacks,
|
||
which in turn allows those callbacks to carry out (either directly or
|
||
indirectly via wakeup) the needed phase-two processing for each update.
|
||
|
||
.. kernel-figure:: TreeRCU-callback-invocation.svg
|
||
|
||
Please note that callback invocation can also be prompted by any number
|
||
of corner-case code paths, for example, when a CPU notes that it has
|
||
excessive numbers of callbacks queued. In all cases, the CPU acquires
|
||
its leaf ``rcu_node`` structure's ``->lock`` before invoking callbacks,
|
||
which preserves the required ordering against the newly completed grace
|
||
period.
|
||
|
||
However, if the callback function communicates to other CPUs, for
|
||
example, doing a wakeup, then it is that function's responsibility to
|
||
maintain ordering. For example, if the callback function wakes up a task
|
||
that runs on some other CPU, proper ordering must in place in both the
|
||
callback function and the task being awakened. To see why this is
|
||
important, consider the top half of the `grace-period
|
||
cleanup <#Grace-Period%20Cleanup>`__ diagram. The callback might be
|
||
running on a CPU corresponding to the leftmost leaf ``rcu_node``
|
||
structure, and awaken a task that is to run on a CPU corresponding to
|
||
the rightmost leaf ``rcu_node`` structure, and the grace-period kernel
|
||
thread might not yet have reached the rightmost leaf. In this case, the
|
||
grace period's memory ordering might not yet have reached that CPU, so
|
||
again the callback function and the awakened task must supply proper
|
||
ordering.
|
||
|
||
Putting It All Together
|
||
~~~~~~~~~~~~~~~~~~~~~~~
|
||
|
||
A stitched-together diagram is here:
|
||
|
||
.. kernel-figure:: TreeRCU-gp.svg
|
||
|
||
Legal Statement
|
||
~~~~~~~~~~~~~~~
|
||
|
||
This work represents the view of the author and does not necessarily
|
||
represent the view of IBM.
|
||
|
||
Linux is a registered trademark of Linus Torvalds.
|
||
|
||
Other company, product, and service names may be trademarks or service
|
||
marks of others.
|