| RCU on Uniprocessor Systems |
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| A common misconception is that, on UP systems, the call_rcu() primitive |
| may immediately invoke its function. The basis of this misconception |
| is that since there is only one CPU, it should not be necessary to |
| wait for anything else to get done, since there are no other CPUs for |
| anything else to be happening on. Although this approach will -sort- -of- |
| work a surprising amount of the time, it is a very bad idea in general. |
| This document presents three examples that demonstrate exactly how bad |
| an idea this is. |
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| Example 1: softirq Suicide |
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| Suppose that an RCU-based algorithm scans a linked list containing |
| elements A, B, and C in process context, and can delete elements from |
| this same list in softirq context. Suppose that the process-context scan |
| is referencing element B when it is interrupted by softirq processing, |
| which deletes element B, and then invokes call_rcu() to free element B |
| after a grace period. |
| |
| Now, if call_rcu() were to directly invoke its arguments, then upon return |
| from softirq, the list scan would find itself referencing a newly freed |
| element B. This situation can greatly decrease the life expectancy of |
| your kernel. |
| |
| This same problem can occur if call_rcu() is invoked from a hardware |
| interrupt handler. |
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| Example 2: Function-Call Fatality |
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| Of course, one could avert the suicide described in the preceding example |
| by having call_rcu() directly invoke its arguments only if it was called |
| from process context. However, this can fail in a similar manner. |
| |
| Suppose that an RCU-based algorithm again scans a linked list containing |
| elements A, B, and C in process contexts, but that it invokes a function |
| on each element as it is scanned. Suppose further that this function |
| deletes element B from the list, then passes it to call_rcu() for deferred |
| freeing. This may be a bit unconventional, but it is perfectly legal |
| RCU usage, since call_rcu() must wait for a grace period to elapse. |
| Therefore, in this case, allowing call_rcu() to immediately invoke |
| its arguments would cause it to fail to make the fundamental guarantee |
| underlying RCU, namely that call_rcu() defers invoking its arguments until |
| all RCU read-side critical sections currently executing have completed. |
| |
| Quick Quiz #1: why is it -not- legal to invoke synchronize_rcu() in |
| this case? |
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| |
| Example 3: Death by Deadlock |
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| Suppose that call_rcu() is invoked while holding a lock, and that the |
| callback function must acquire this same lock. In this case, if |
| call_rcu() were to directly invoke the callback, the result would |
| be self-deadlock. |
| |
| In some cases, it would possible to restructure to code so that |
| the call_rcu() is delayed until after the lock is released. However, |
| there are cases where this can be quite ugly: |
| |
| 1. If a number of items need to be passed to call_rcu() within |
| the same critical section, then the code would need to create |
| a list of them, then traverse the list once the lock was |
| released. |
| |
| 2. In some cases, the lock will be held across some kernel API, |
| so that delaying the call_rcu() until the lock is released |
| requires that the data item be passed up via a common API. |
| It is far better to guarantee that callbacks are invoked |
| with no locks held than to have to modify such APIs to allow |
| arbitrary data items to be passed back up through them. |
| |
| If call_rcu() directly invokes the callback, painful locking restrictions |
| or API changes would be required. |
| |
| Quick Quiz #2: What locking restriction must RCU callbacks respect? |
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| Summary |
| |
| Permitting call_rcu() to immediately invoke its arguments breaks RCU, |
| even on a UP system. So do not do it! Even on a UP system, the RCU |
| infrastructure -must- respect grace periods, and -must- invoke callbacks |
| from a known environment in which no locks are held. |
| |
| Note that it -is- safe for synchronize_rcu() to return immediately on |
| UP systems, including !PREEMPT SMP builds running on UP systems. |
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| Quick Quiz #3: Why can't synchronize_rcu() return immediately on |
| UP systems running preemptable RCU? |
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| Answer to Quick Quiz #1: |
| Why is it -not- legal to invoke synchronize_rcu() in this case? |
| |
| Because the calling function is scanning an RCU-protected linked |
| list, and is therefore within an RCU read-side critical section. |
| Therefore, the called function has been invoked within an RCU |
| read-side critical section, and is not permitted to block. |
| |
| Answer to Quick Quiz #2: |
| What locking restriction must RCU callbacks respect? |
| |
| Any lock that is acquired within an RCU callback must be |
| acquired elsewhere using an _irq variant of the spinlock |
| primitive. For example, if "mylock" is acquired by an |
| RCU callback, then a process-context acquisition of this |
| lock must use something like spin_lock_irqsave() to |
| acquire the lock. |
| |
| If the process-context code were to simply use spin_lock(), |
| then, since RCU callbacks can be invoked from softirq context, |
| the callback might be called from a softirq that interrupted |
| the process-context critical section. This would result in |
| self-deadlock. |
| |
| This restriction might seem gratuitous, since very few RCU |
| callbacks acquire locks directly. However, a great many RCU |
| callbacks do acquire locks -indirectly-, for example, via |
| the kfree() primitive. |
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| Answer to Quick Quiz #3: |
| Why can't synchronize_rcu() return immediately on UP systems |
| running preemptable RCU? |
| |
| Because some other task might have been preempted in the middle |
| of an RCU read-side critical section. If synchronize_rcu() |
| simply immediately returned, it would prematurely signal the |
| end of the grace period, which would come as a nasty shock to |
| that other thread when it started running again. |