571 lines
18 KiB
Plaintext
571 lines
18 KiB
Plaintext
This document provides "recipes", that is, litmus tests for commonly
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occurring situations, as well as a few that illustrate subtly broken but
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attractive nuisances. Many of these recipes include example code from
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v4.13 of the Linux kernel.
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The first section covers simple special cases, the second section
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takes off the training wheels to cover more involved examples,
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and the third section provides a few rules of thumb.
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Simple special cases
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====================
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This section presents two simple special cases, the first being where
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there is only one CPU or only one memory location is accessed, and the
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second being use of that old concurrency workhorse, locking.
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Single CPU or single memory location
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------------------------------------
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If there is only one CPU on the one hand or only one variable
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on the other, the code will execute in order. There are (as
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usual) some things to be careful of:
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1. Some aspects of the C language are unordered. For example,
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in the expression "f(x) + g(y)", the order in which f and g are
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called is not defined; the object code is allowed to use either
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order or even to interleave the computations.
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2. Compilers are permitted to use the "as-if" rule. That is, a
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compiler can emit whatever code it likes for normal accesses,
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as long as the results of a single-threaded execution appear
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just as if the compiler had followed all the relevant rules.
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To see this, compile with a high level of optimization and run
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the debugger on the resulting binary.
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3. If there is only one variable but multiple CPUs, that variable
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must be properly aligned and all accesses to that variable must
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be full sized. Variables that straddle cachelines or pages void
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your full-ordering warranty, as do undersized accesses that load
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from or store to only part of the variable.
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4. If there are multiple CPUs, accesses to shared variables should
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use READ_ONCE() and WRITE_ONCE() or stronger to prevent load/store
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tearing, load/store fusing, and invented loads and stores.
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There are exceptions to this rule, including:
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i. When there is no possibility of a given shared variable
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being updated by some other CPU, for example, while
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holding the update-side lock, reads from that variable
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need not use READ_ONCE().
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ii. When there is no possibility of a given shared variable
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being either read or updated by other CPUs, for example,
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when running during early boot, reads from that variable
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need not use READ_ONCE() and writes to that variable
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need not use WRITE_ONCE().
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Locking
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-------
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Locking is well-known and straightforward, at least if you don't think
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about it too hard. And the basic rule is indeed quite simple: Any CPU that
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has acquired a given lock sees any changes previously seen or made by any
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CPU before it released that same lock. Note that this statement is a bit
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stronger than "Any CPU holding a given lock sees all changes made by any
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CPU during the time that CPU was holding this same lock". For example,
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consider the following pair of code fragments:
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/* See MP+polocks.litmus. */
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void CPU0(void)
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{
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WRITE_ONCE(x, 1);
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spin_lock(&mylock);
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WRITE_ONCE(y, 1);
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spin_unlock(&mylock);
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}
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void CPU1(void)
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{
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spin_lock(&mylock);
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r0 = READ_ONCE(y);
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spin_unlock(&mylock);
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r1 = READ_ONCE(x);
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}
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The basic rule guarantees that if CPU0() acquires mylock before CPU1(),
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then both r0 and r1 must be set to the value 1. This also has the
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consequence that if the final value of r0 is equal to 1, then the final
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value of r1 must also be equal to 1. In contrast, the weaker rule would
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say nothing about the final value of r1.
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The converse to the basic rule also holds, as illustrated by the
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following litmus test:
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/* See MP+porevlocks.litmus. */
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void CPU0(void)
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{
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r0 = READ_ONCE(y);
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spin_lock(&mylock);
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r1 = READ_ONCE(x);
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spin_unlock(&mylock);
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}
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void CPU1(void)
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{
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spin_lock(&mylock);
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WRITE_ONCE(x, 1);
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spin_unlock(&mylock);
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WRITE_ONCE(y, 1);
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}
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This converse to the basic rule guarantees that if CPU0() acquires
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mylock before CPU1(), then both r0 and r1 must be set to the value 0.
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This also has the consequence that if the final value of r1 is equal
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to 0, then the final value of r0 must also be equal to 0. In contrast,
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the weaker rule would say nothing about the final value of r0.
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These examples show only a single pair of CPUs, but the effects of the
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locking basic rule extend across multiple acquisitions of a given lock
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across multiple CPUs.
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However, it is not necessarily the case that accesses ordered by
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locking will be seen as ordered by CPUs not holding that lock.
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Consider this example:
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/* See Z6.0+pooncerelease+poacquirerelease+fencembonceonce.litmus. */
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void CPU0(void)
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{
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spin_lock(&mylock);
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WRITE_ONCE(x, 1);
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WRITE_ONCE(y, 1);
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spin_unlock(&mylock);
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}
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void CPU1(void)
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{
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spin_lock(&mylock);
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r0 = READ_ONCE(y);
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WRITE_ONCE(z, 1);
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spin_unlock(&mylock);
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}
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void CPU2(void)
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{
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WRITE_ONCE(z, 2);
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smp_mb();
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r1 = READ_ONCE(x);
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}
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Counter-intuitive though it might be, it is quite possible to have
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the final value of r0 be 1, the final value of z be 2, and the final
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value of r1 be 0. The reason for this surprising outcome is that
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CPU2() never acquired the lock, and thus did not benefit from the
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lock's ordering properties.
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Ordering can be extended to CPUs not holding the lock by careful use
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of smp_mb__after_spinlock():
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/* See Z6.0+pooncelock+poonceLock+pombonce.litmus. */
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void CPU0(void)
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{
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spin_lock(&mylock);
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WRITE_ONCE(x, 1);
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WRITE_ONCE(y, 1);
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spin_unlock(&mylock);
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}
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void CPU1(void)
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{
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spin_lock(&mylock);
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smp_mb__after_spinlock();
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r0 = READ_ONCE(y);
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WRITE_ONCE(z, 1);
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spin_unlock(&mylock);
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}
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void CPU2(void)
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{
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WRITE_ONCE(z, 2);
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smp_mb();
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r1 = READ_ONCE(x);
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}
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This addition of smp_mb__after_spinlock() strengthens the lock acquisition
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sufficiently to rule out the counter-intuitive outcome.
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Taking off the training wheels
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==============================
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This section looks at more complex examples, including message passing,
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load buffering, release-acquire chains, store buffering.
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Many classes of litmus tests have abbreviated names, which may be found
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here: https://www.cl.cam.ac.uk/~pes20/ppc-supplemental/test6.pdf
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Message passing (MP)
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--------------------
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The MP pattern has one CPU execute a pair of stores to a pair of variables
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and another CPU execute a pair of loads from this same pair of variables,
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but in the opposite order. The goal is to avoid the counter-intuitive
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outcome in which the first load sees the value written by the second store
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but the second load does not see the value written by the first store.
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In the absence of any ordering, this goal may not be met, as can be seen
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in the MP+poonceonces.litmus litmus test. This section therefore looks at
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a number of ways of meeting this goal.
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Release and acquire
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~~~~~~~~~~~~~~~~~~~
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Use of smp_store_release() and smp_load_acquire() is one way to force
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the desired MP ordering. The general approach is shown below:
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/* See MP+pooncerelease+poacquireonce.litmus. */
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void CPU0(void)
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{
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WRITE_ONCE(x, 1);
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smp_store_release(&y, 1);
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}
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void CPU1(void)
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{
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r0 = smp_load_acquire(&y);
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r1 = READ_ONCE(x);
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}
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The smp_store_release() macro orders any prior accesses against the
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store, while the smp_load_acquire macro orders the load against any
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subsequent accesses. Therefore, if the final value of r0 is the value 1,
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the final value of r1 must also be the value 1.
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The init_stack_slab() function in lib/stackdepot.c uses release-acquire
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in this way to safely initialize of a slab of the stack. Working out
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the mutual-exclusion design is left as an exercise for the reader.
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Assign and dereference
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~~~~~~~~~~~~~~~~~~~~~~
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Use of rcu_assign_pointer() and rcu_dereference() is quite similar to the
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use of smp_store_release() and smp_load_acquire(), except that both
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rcu_assign_pointer() and rcu_dereference() operate on RCU-protected
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pointers. The general approach is shown below:
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/* See MP+onceassign+derefonce.litmus. */
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int z;
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int *y = &z;
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int x;
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void CPU0(void)
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{
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WRITE_ONCE(x, 1);
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rcu_assign_pointer(y, &x);
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}
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void CPU1(void)
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{
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rcu_read_lock();
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r0 = rcu_dereference(y);
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r1 = READ_ONCE(*r0);
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rcu_read_unlock();
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}
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In this example, if the final value of r0 is &x then the final value of
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r1 must be 1.
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The rcu_assign_pointer() macro has the same ordering properties as does
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smp_store_release(), but the rcu_dereference() macro orders the load only
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against later accesses that depend on the value loaded. A dependency
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is present if the value loaded determines the address of a later access
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(address dependency, as shown above), the value written by a later store
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(data dependency), or whether or not a later store is executed in the
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first place (control dependency). Note that the term "data dependency"
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is sometimes casually used to cover both address and data dependencies.
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In lib/prime_numbers.c, the expand_to_next_prime() function invokes
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rcu_assign_pointer(), and the next_prime_number() function invokes
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rcu_dereference(). This combination mediates access to a bit vector
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that is expanded as additional primes are needed.
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Write and read memory barriers
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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It is usually better to use smp_store_release() instead of smp_wmb()
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and to use smp_load_acquire() instead of smp_rmb(). However, the older
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smp_wmb() and smp_rmb() APIs are still heavily used, so it is important
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to understand their use cases. The general approach is shown below:
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/* See MP+fencewmbonceonce+fencermbonceonce.litmus. */
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void CPU0(void)
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{
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WRITE_ONCE(x, 1);
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smp_wmb();
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WRITE_ONCE(y, 1);
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}
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void CPU1(void)
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{
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r0 = READ_ONCE(y);
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smp_rmb();
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r1 = READ_ONCE(x);
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}
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The smp_wmb() macro orders prior stores against later stores, and the
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smp_rmb() macro orders prior loads against later loads. Therefore, if
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the final value of r0 is 1, the final value of r1 must also be 1.
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The xlog_state_switch_iclogs() function in fs/xfs/xfs_log.c contains
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the following write-side code fragment:
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log->l_curr_block -= log->l_logBBsize;
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ASSERT(log->l_curr_block >= 0);
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smp_wmb();
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log->l_curr_cycle++;
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And the xlog_valid_lsn() function in fs/xfs/xfs_log_priv.h contains
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the corresponding read-side code fragment:
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cur_cycle = READ_ONCE(log->l_curr_cycle);
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smp_rmb();
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cur_block = READ_ONCE(log->l_curr_block);
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Alternatively, consider the following comment in function
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perf_output_put_handle() in kernel/events/ring_buffer.c:
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* kernel user
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*
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* if (LOAD ->data_tail) { LOAD ->data_head
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* (A) smp_rmb() (C)
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* STORE $data LOAD $data
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* smp_wmb() (B) smp_mb() (D)
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* STORE ->data_head STORE ->data_tail
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* }
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The B/C pairing is an example of the MP pattern using smp_wmb() on the
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write side and smp_rmb() on the read side.
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Of course, given that smp_mb() is strictly stronger than either smp_wmb()
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or smp_rmb(), any code fragment that would work with smp_rmb() and
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smp_wmb() would also work with smp_mb() replacing either or both of the
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weaker barriers.
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Load buffering (LB)
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-------------------
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The LB pattern has one CPU load from one variable and then store to a
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second, while another CPU loads from the second variable and then stores
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to the first. The goal is to avoid the counter-intuitive situation where
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each load reads the value written by the other CPU's store. In the
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absence of any ordering it is quite possible that this may happen, as
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can be seen in the LB+poonceonces.litmus litmus test.
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One way of avoiding the counter-intuitive outcome is through the use of a
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control dependency paired with a full memory barrier:
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/* See LB+fencembonceonce+ctrlonceonce.litmus. */
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void CPU0(void)
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{
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r0 = READ_ONCE(x);
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if (r0)
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WRITE_ONCE(y, 1);
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}
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void CPU1(void)
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{
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r1 = READ_ONCE(y);
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smp_mb();
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WRITE_ONCE(x, 1);
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}
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This pairing of a control dependency in CPU0() with a full memory
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barrier in CPU1() prevents r0 and r1 from both ending up equal to 1.
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The A/D pairing from the ring-buffer use case shown earlier also
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illustrates LB. Here is a repeat of the comment in
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perf_output_put_handle() in kernel/events/ring_buffer.c, showing a
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control dependency on the kernel side and a full memory barrier on
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the user side:
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* kernel user
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*
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* if (LOAD ->data_tail) { LOAD ->data_head
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* (A) smp_rmb() (C)
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* STORE $data LOAD $data
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* smp_wmb() (B) smp_mb() (D)
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* STORE ->data_head STORE ->data_tail
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* }
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*
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* Where A pairs with D, and B pairs with C.
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The kernel's control dependency between the load from ->data_tail
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and the store to data combined with the user's full memory barrier
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between the load from data and the store to ->data_tail prevents
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the counter-intuitive outcome where the kernel overwrites the data
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before the user gets done loading it.
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Release-acquire chains
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----------------------
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Release-acquire chains are a low-overhead, flexible, and easy-to-use
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method of maintaining order. However, they do have some limitations that
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need to be fully understood. Here is an example that maintains order:
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/* See ISA2+pooncerelease+poacquirerelease+poacquireonce.litmus. */
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void CPU0(void)
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{
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WRITE_ONCE(x, 1);
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smp_store_release(&y, 1);
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}
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void CPU1(void)
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{
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r0 = smp_load_acquire(y);
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smp_store_release(&z, 1);
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}
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void CPU2(void)
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{
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r1 = smp_load_acquire(z);
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r2 = READ_ONCE(x);
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}
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In this case, if r0 and r1 both have final values of 1, then r2 must
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also have a final value of 1.
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The ordering in this example is stronger than it needs to be. For
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example, ordering would still be preserved if CPU1()'s smp_load_acquire()
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invocation was replaced with READ_ONCE().
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It is tempting to assume that CPU0()'s store to x is globally ordered
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before CPU1()'s store to z, but this is not the case:
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/* See Z6.0+pooncerelease+poacquirerelease+mbonceonce.litmus. */
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void CPU0(void)
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{
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WRITE_ONCE(x, 1);
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smp_store_release(&y, 1);
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}
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void CPU1(void)
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{
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r0 = smp_load_acquire(y);
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smp_store_release(&z, 1);
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}
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void CPU2(void)
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{
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WRITE_ONCE(z, 2);
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smp_mb();
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r1 = READ_ONCE(x);
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}
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One might hope that if the final value of r0 is 1 and the final value
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of z is 2, then the final value of r1 must also be 1, but it really is
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possible for r1 to have the final value of 0. The reason, of course,
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is that in this version, CPU2() is not part of the release-acquire chain.
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This situation is accounted for in the rules of thumb below.
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Despite this limitation, release-acquire chains are low-overhead as
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well as simple and powerful, at least as memory-ordering mechanisms go.
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Store buffering
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---------------
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Store buffering can be thought of as upside-down load buffering, so
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that one CPU first stores to one variable and then loads from a second,
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while another CPU stores to the second variable and then loads from the
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first. Preserving order requires nothing less than full barriers:
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/* See SB+fencembonceonces.litmus. */
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void CPU0(void)
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{
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WRITE_ONCE(x, 1);
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smp_mb();
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r0 = READ_ONCE(y);
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}
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void CPU1(void)
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{
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WRITE_ONCE(y, 1);
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smp_mb();
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r1 = READ_ONCE(x);
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}
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Omitting either smp_mb() will allow both r0 and r1 to have final
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values of 0, but providing both full barriers as shown above prevents
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this counter-intuitive outcome.
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This pattern most famously appears as part of Dekker's locking
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algorithm, but it has a much more practical use within the Linux kernel
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of ordering wakeups. The following comment taken from waitqueue_active()
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in include/linux/wait.h shows the canonical pattern:
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* CPU0 - waker CPU1 - waiter
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*
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* for (;;) {
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* @cond = true; prepare_to_wait(&wq_head, &wait, state);
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* smp_mb(); // smp_mb() from set_current_state()
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* if (waitqueue_active(wq_head)) if (@cond)
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* wake_up(wq_head); break;
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* schedule();
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* }
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* finish_wait(&wq_head, &wait);
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On CPU0, the store is to @cond and the load is in waitqueue_active().
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On CPU1, prepare_to_wait() contains both a store to wq_head and a call
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to set_current_state(), which contains an smp_mb() barrier; the load is
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"if (@cond)". The full barriers prevent the undesirable outcome where
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CPU1 puts the waiting task to sleep and CPU0 fails to wake it up.
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Note that use of locking can greatly simplify this pattern.
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Rules of thumb
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==============
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There might seem to be no pattern governing what ordering primitives are
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needed in which situations, but this is not the case. There is a pattern
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based on the relation between the accesses linking successive CPUs in a
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given litmus test. There are three types of linkage:
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1. Write-to-read, where the next CPU reads the value that the
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previous CPU wrote. The LB litmus-test patterns contain only
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this type of relation. In formal memory-modeling texts, this
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relation is called "reads-from" and is usually abbreviated "rf".
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2. Read-to-write, where the next CPU overwrites the value that the
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previous CPU read. The SB litmus test contains only this type
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of relation. In formal memory-modeling texts, this relation is
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often called "from-reads" and is sometimes abbreviated "fr".
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3. Write-to-write, where the next CPU overwrites the value written
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by the previous CPU. The Z6.0 litmus test pattern contains a
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write-to-write relation between the last access of CPU1() and
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the first access of CPU2(). In formal memory-modeling texts,
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this relation is often called "coherence order" and is sometimes
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abbreviated "co". In the C++ standard, it is instead called
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"modification order" and often abbreviated "mo".
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The strength of memory ordering required for a given litmus test to
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avoid a counter-intuitive outcome depends on the types of relations
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linking the memory accesses for the outcome in question:
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o If all links are write-to-read links, then the weakest
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possible ordering within each CPU suffices. For example, in
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the LB litmus test, a control dependency was enough to do the
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job.
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o If all but one of the links are write-to-read links, then a
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release-acquire chain suffices. Both the MP and the ISA2
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litmus tests illustrate this case.
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o If more than one of the links are something other than
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write-to-read links, then a full memory barrier is required
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between each successive pair of non-write-to-read links. This
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case is illustrated by the Z6.0 litmus tests, both in the
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locking and in the release-acquire sections.
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However, if you find yourself having to stretch these rules of thumb
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to fit your situation, you should consider creating a litmus test and
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running it on the model.
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