487 lines
17 KiB
ReStructuredText
487 lines
17 KiB
ReStructuredText
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.. _rcu_dereference_doc:
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PROPER CARE AND FEEDING OF RETURN VALUES FROM rcu_dereference()
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===============================================================
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Most of the time, you can use values from rcu_dereference() or one of
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the similar primitives without worries. Dereferencing (prefix "*"),
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field selection ("->"), assignment ("="), address-of ("&"), addition and
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subtraction of constants, and casts all work quite naturally and safely.
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It is nevertheless possible to get into trouble with other operations.
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Follow these rules to keep your RCU code working properly:
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- You must use one of the rcu_dereference() family of primitives
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to load an RCU-protected pointer, otherwise CONFIG_PROVE_RCU
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will complain. Worse yet, your code can see random memory-corruption
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bugs due to games that compilers and DEC Alpha can play.
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Without one of the rcu_dereference() primitives, compilers
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can reload the value, and won't your code have fun with two
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different values for a single pointer! Without rcu_dereference(),
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DEC Alpha can load a pointer, dereference that pointer, and
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return data preceding initialization that preceded the store
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of the pointer. (As noted later, in recent kernels READ_ONCE()
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also prevents DEC Alpha from playing these tricks.)
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In addition, the volatile cast in rcu_dereference() prevents the
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compiler from deducing the resulting pointer value. Please see
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the section entitled "EXAMPLE WHERE THE COMPILER KNOWS TOO MUCH"
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for an example where the compiler can in fact deduce the exact
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value of the pointer, and thus cause misordering.
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- In the special case where data is added but is never removed
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while readers are accessing the structure, READ_ONCE() may be used
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instead of rcu_dereference(). In this case, use of READ_ONCE()
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takes on the role of the lockless_dereference() primitive that
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was removed in v4.15.
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- You are only permitted to use rcu_dereference() on pointer values.
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The compiler simply knows too much about integral values to
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trust it to carry dependencies through integer operations.
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There are a very few exceptions, namely that you can temporarily
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cast the pointer to uintptr_t in order to:
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- Set bits and clear bits down in the must-be-zero low-order
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bits of that pointer. This clearly means that the pointer
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must have alignment constraints, for example, this does
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*not* work in general for char* pointers.
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- XOR bits to translate pointers, as is done in some
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classic buddy-allocator algorithms.
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It is important to cast the value back to pointer before
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doing much of anything else with it.
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- Avoid cancellation when using the "+" and "-" infix arithmetic
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operators. For example, for a given variable "x", avoid
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"(x-(uintptr_t)x)" for char* pointers. The compiler is within its
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rights to substitute zero for this sort of expression, so that
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subsequent accesses no longer depend on the rcu_dereference(),
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again possibly resulting in bugs due to misordering.
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Of course, if "p" is a pointer from rcu_dereference(), and "a"
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and "b" are integers that happen to be equal, the expression
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"p+a-b" is safe because its value still necessarily depends on
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the rcu_dereference(), thus maintaining proper ordering.
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- If you are using RCU to protect JITed functions, so that the
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"()" function-invocation operator is applied to a value obtained
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(directly or indirectly) from rcu_dereference(), you may need to
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interact directly with the hardware to flush instruction caches.
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This issue arises on some systems when a newly JITed function is
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using the same memory that was used by an earlier JITed function.
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- Do not use the results from relational operators ("==", "!=",
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">", ">=", "<", or "<=") when dereferencing. For example,
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the following (quite strange) code is buggy::
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int *p;
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int *q;
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...
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p = rcu_dereference(gp)
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q = &global_q;
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q += p > &oom_p;
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r1 = *q; /* BUGGY!!! */
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As before, the reason this is buggy is that relational operators
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are often compiled using branches. And as before, although
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weak-memory machines such as ARM or PowerPC do order stores
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after such branches, but can speculate loads, which can again
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result in misordering bugs.
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- Be very careful about comparing pointers obtained from
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rcu_dereference() against non-NULL values. As Linus Torvalds
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explained, if the two pointers are equal, the compiler could
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substitute the pointer you are comparing against for the pointer
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obtained from rcu_dereference(). For example::
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p = rcu_dereference(gp);
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if (p == &default_struct)
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do_default(p->a);
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Because the compiler now knows that the value of "p" is exactly
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the address of the variable "default_struct", it is free to
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transform this code into the following::
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p = rcu_dereference(gp);
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if (p == &default_struct)
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do_default(default_struct.a);
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On ARM and Power hardware, the load from "default_struct.a"
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can now be speculated, such that it might happen before the
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rcu_dereference(). This could result in bugs due to misordering.
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However, comparisons are OK in the following cases:
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- The comparison was against the NULL pointer. If the
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compiler knows that the pointer is NULL, you had better
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not be dereferencing it anyway. If the comparison is
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non-equal, the compiler is none the wiser. Therefore,
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it is safe to compare pointers from rcu_dereference()
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against NULL pointers.
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- The pointer is never dereferenced after being compared.
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Since there are no subsequent dereferences, the compiler
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cannot use anything it learned from the comparison
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to reorder the non-existent subsequent dereferences.
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This sort of comparison occurs frequently when scanning
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RCU-protected circular linked lists.
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Note that if the pointer comparison is done outside
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of an RCU read-side critical section, and the pointer
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is never dereferenced, rcu_access_pointer() should be
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used in place of rcu_dereference(). In most cases,
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it is best to avoid accidental dereferences by testing
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the rcu_access_pointer() return value directly, without
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assigning it to a variable.
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Within an RCU read-side critical section, there is little
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reason to use rcu_access_pointer().
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- The comparison is against a pointer that references memory
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that was initialized "a long time ago." The reason
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this is safe is that even if misordering occurs, the
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misordering will not affect the accesses that follow
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the comparison. So exactly how long ago is "a long
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time ago"? Here are some possibilities:
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- Compile time.
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- Boot time.
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- Module-init time for module code.
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- Prior to kthread creation for kthread code.
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- During some prior acquisition of the lock that
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we now hold.
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- Before mod_timer() time for a timer handler.
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There are many other possibilities involving the Linux
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kernel's wide array of primitives that cause code to
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be invoked at a later time.
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- The pointer being compared against also came from
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rcu_dereference(). In this case, both pointers depend
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on one rcu_dereference() or another, so you get proper
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ordering either way.
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That said, this situation can make certain RCU usage
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bugs more likely to happen. Which can be a good thing,
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at least if they happen during testing. An example
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of such an RCU usage bug is shown in the section titled
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"EXAMPLE OF AMPLIFIED RCU-USAGE BUG".
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- All of the accesses following the comparison are stores,
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so that a control dependency preserves the needed ordering.
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That said, it is easy to get control dependencies wrong.
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Please see the "CONTROL DEPENDENCIES" section of
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Documentation/memory-barriers.txt for more details.
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- The pointers are not equal *and* the compiler does
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not have enough information to deduce the value of the
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pointer. Note that the volatile cast in rcu_dereference()
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will normally prevent the compiler from knowing too much.
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However, please note that if the compiler knows that the
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pointer takes on only one of two values, a not-equal
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comparison will provide exactly the information that the
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compiler needs to deduce the value of the pointer.
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- Disable any value-speculation optimizations that your compiler
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might provide, especially if you are making use of feedback-based
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optimizations that take data collected from prior runs. Such
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value-speculation optimizations reorder operations by design.
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There is one exception to this rule: Value-speculation
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optimizations that leverage the branch-prediction hardware are
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safe on strongly ordered systems (such as x86), but not on weakly
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ordered systems (such as ARM or Power). Choose your compiler
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command-line options wisely!
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EXAMPLE OF AMPLIFIED RCU-USAGE BUG
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----------------------------------
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Because updaters can run concurrently with RCU readers, RCU readers can
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see stale and/or inconsistent values. If RCU readers need fresh or
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consistent values, which they sometimes do, they need to take proper
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precautions. To see this, consider the following code fragment::
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struct foo {
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int a;
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int b;
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int c;
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};
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struct foo *gp1;
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struct foo *gp2;
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void updater(void)
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{
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struct foo *p;
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p = kmalloc(...);
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if (p == NULL)
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deal_with_it();
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p->a = 42; /* Each field in its own cache line. */
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p->b = 43;
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p->c = 44;
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rcu_assign_pointer(gp1, p);
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p->b = 143;
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p->c = 144;
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rcu_assign_pointer(gp2, p);
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}
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void reader(void)
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{
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struct foo *p;
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struct foo *q;
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int r1, r2;
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rcu_read_lock();
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p = rcu_dereference(gp2);
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if (p == NULL)
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return;
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r1 = p->b; /* Guaranteed to get 143. */
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q = rcu_dereference(gp1); /* Guaranteed non-NULL. */
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if (p == q) {
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/* The compiler decides that q->c is same as p->c. */
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r2 = p->c; /* Could get 44 on weakly order system. */
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} else {
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r2 = p->c - r1; /* Unconditional access to p->c. */
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}
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rcu_read_unlock();
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do_something_with(r1, r2);
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}
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You might be surprised that the outcome (r1 == 143 && r2 == 44) is possible,
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but you should not be. After all, the updater might have been invoked
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a second time between the time reader() loaded into "r1" and the time
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that it loaded into "r2". The fact that this same result can occur due
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to some reordering from the compiler and CPUs is beside the point.
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But suppose that the reader needs a consistent view?
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Then one approach is to use locking, for example, as follows::
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struct foo {
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int a;
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int b;
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int c;
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spinlock_t lock;
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};
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struct foo *gp1;
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struct foo *gp2;
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void updater(void)
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{
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struct foo *p;
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p = kmalloc(...);
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if (p == NULL)
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deal_with_it();
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spin_lock(&p->lock);
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p->a = 42; /* Each field in its own cache line. */
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p->b = 43;
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p->c = 44;
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spin_unlock(&p->lock);
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rcu_assign_pointer(gp1, p);
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spin_lock(&p->lock);
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p->b = 143;
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p->c = 144;
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spin_unlock(&p->lock);
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rcu_assign_pointer(gp2, p);
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}
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void reader(void)
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{
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struct foo *p;
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struct foo *q;
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int r1, r2;
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rcu_read_lock();
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p = rcu_dereference(gp2);
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if (p == NULL)
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return;
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spin_lock(&p->lock);
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r1 = p->b; /* Guaranteed to get 143. */
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q = rcu_dereference(gp1); /* Guaranteed non-NULL. */
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if (p == q) {
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/* The compiler decides that q->c is same as p->c. */
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r2 = p->c; /* Locking guarantees r2 == 144. */
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} else {
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spin_lock(&q->lock);
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r2 = q->c - r1;
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spin_unlock(&q->lock);
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}
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rcu_read_unlock();
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spin_unlock(&p->lock);
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do_something_with(r1, r2);
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}
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As always, use the right tool for the job!
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EXAMPLE WHERE THE COMPILER KNOWS TOO MUCH
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-----------------------------------------
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If a pointer obtained from rcu_dereference() compares not-equal to some
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other pointer, the compiler normally has no clue what the value of the
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first pointer might be. This lack of knowledge prevents the compiler
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from carrying out optimizations that otherwise might destroy the ordering
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guarantees that RCU depends on. And the volatile cast in rcu_dereference()
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should prevent the compiler from guessing the value.
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But without rcu_dereference(), the compiler knows more than you might
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expect. Consider the following code fragment::
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struct foo {
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int a;
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int b;
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};
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static struct foo variable1;
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static struct foo variable2;
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static struct foo *gp = &variable1;
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void updater(void)
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{
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initialize_foo(&variable2);
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rcu_assign_pointer(gp, &variable2);
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/*
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* The above is the only store to gp in this translation unit,
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* and the address of gp is not exported in any way.
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*/
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}
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int reader(void)
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{
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struct foo *p;
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p = gp;
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barrier();
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if (p == &variable1)
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return p->a; /* Must be variable1.a. */
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else
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return p->b; /* Must be variable2.b. */
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}
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Because the compiler can see all stores to "gp", it knows that the only
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possible values of "gp" are "variable1" on the one hand and "variable2"
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on the other. The comparison in reader() therefore tells the compiler
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the exact value of "p" even in the not-equals case. This allows the
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compiler to make the return values independent of the load from "gp",
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in turn destroying the ordering between this load and the loads of the
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return values. This can result in "p->b" returning pre-initialization
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garbage values on weakly ordered systems.
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In short, rcu_dereference() is *not* optional when you are going to
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dereference the resulting pointer.
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WHICH MEMBER OF THE rcu_dereference() FAMILY SHOULD YOU USE?
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------------------------------------------------------------
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First, please avoid using rcu_dereference_raw() and also please avoid
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using rcu_dereference_check() and rcu_dereference_protected() with a
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second argument with a constant value of 1 (or true, for that matter).
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With that caution out of the way, here is some guidance for which
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member of the rcu_dereference() to use in various situations:
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1. If the access needs to be within an RCU read-side critical
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section, use rcu_dereference(). With the new consolidated
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RCU flavors, an RCU read-side critical section is entered
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using rcu_read_lock(), anything that disables bottom halves,
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anything that disables interrupts, or anything that disables
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preemption.
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2. If the access might be within an RCU read-side critical section
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on the one hand, or protected by (say) my_lock on the other,
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use rcu_dereference_check(), for example::
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p1 = rcu_dereference_check(p->rcu_protected_pointer,
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lockdep_is_held(&my_lock));
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3. If the access might be within an RCU read-side critical section
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on the one hand, or protected by either my_lock or your_lock on
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the other, again use rcu_dereference_check(), for example::
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p1 = rcu_dereference_check(p->rcu_protected_pointer,
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lockdep_is_held(&my_lock) ||
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lockdep_is_held(&your_lock));
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4. If the access is on the update side, so that it is always protected
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by my_lock, use rcu_dereference_protected()::
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p1 = rcu_dereference_protected(p->rcu_protected_pointer,
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lockdep_is_held(&my_lock));
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This can be extended to handle multiple locks as in #3 above,
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and both can be extended to check other conditions as well.
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5. If the protection is supplied by the caller, and is thus unknown
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to this code, that is the rare case when rcu_dereference_raw()
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is appropriate. In addition, rcu_dereference_raw() might be
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appropriate when the lockdep expression would be excessively
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complex, except that a better approach in that case might be to
|
||
|
take a long hard look at your synchronization design. Still,
|
||
|
there are data-locking cases where any one of a very large number
|
||
|
of locks or reference counters suffices to protect the pointer,
|
||
|
so rcu_dereference_raw() does have its place.
|
||
|
|
||
|
However, its place is probably quite a bit smaller than one
|
||
|
might expect given the number of uses in the current kernel.
|
||
|
Ditto for its synonym, rcu_dereference_check( ... , 1), and
|
||
|
its close relative, rcu_dereference_protected(... , 1).
|
||
|
|
||
|
|
||
|
SPARSE CHECKING OF RCU-PROTECTED POINTERS
|
||
|
-----------------------------------------
|
||
|
|
||
|
The sparse static-analysis tool checks for non-RCU access to RCU-protected
|
||
|
pointers, which can result in "interesting" bugs due to compiler
|
||
|
optimizations involving invented loads and perhaps also load tearing.
|
||
|
For example, suppose someone mistakenly does something like this::
|
||
|
|
||
|
p = q->rcu_protected_pointer;
|
||
|
do_something_with(p->a);
|
||
|
do_something_else_with(p->b);
|
||
|
|
||
|
If register pressure is high, the compiler might optimize "p" out
|
||
|
of existence, transforming the code to something like this::
|
||
|
|
||
|
do_something_with(q->rcu_protected_pointer->a);
|
||
|
do_something_else_with(q->rcu_protected_pointer->b);
|
||
|
|
||
|
This could fatally disappoint your code if q->rcu_protected_pointer
|
||
|
changed in the meantime. Nor is this a theoretical problem: Exactly
|
||
|
this sort of bug cost Paul E. McKenney (and several of his innocent
|
||
|
colleagues) a three-day weekend back in the early 1990s.
|
||
|
|
||
|
Load tearing could of course result in dereferencing a mashup of a pair
|
||
|
of pointers, which also might fatally disappoint your code.
|
||
|
|
||
|
These problems could have been avoided simply by making the code instead
|
||
|
read as follows::
|
||
|
|
||
|
p = rcu_dereference(q->rcu_protected_pointer);
|
||
|
do_something_with(p->a);
|
||
|
do_something_else_with(p->b);
|
||
|
|
||
|
Unfortunately, these sorts of bugs can be extremely hard to spot during
|
||
|
review. This is where the sparse tool comes into play, along with the
|
||
|
"__rcu" marker. If you mark a pointer declaration, whether in a structure
|
||
|
or as a formal parameter, with "__rcu", which tells sparse to complain if
|
||
|
this pointer is accessed directly. It will also cause sparse to complain
|
||
|
if a pointer not marked with "__rcu" is accessed using rcu_dereference()
|
||
|
and friends. For example, ->rcu_protected_pointer might be declared as
|
||
|
follows::
|
||
|
|
||
|
struct foo __rcu *rcu_protected_pointer;
|
||
|
|
||
|
Use of "__rcu" is opt-in. If you choose not to use it, then you should
|
||
|
ignore the sparse warnings.
|